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Merge branch 'master' into release-docs

Browse Source 
It's been a very long time, so I think a merge will be better than
a rebase.  There was only one simple conflict.
This commit is contained in:
Vladimír Čunát 2019-10-27 10:29:58 +01:00
commit d9c5d584cd
16639 changed files with 759088 additions and 489746 deletions
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.dir-locals.el
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@ -1,8 +0,0 @@
;;; Directory Local Variables
;;; For more information see (info "(emacs) Directory Variables")
((nil
(bug-reference-bug-regexp . "\\(\\(?:[Ii]ssue \\|[Ff]ixe[ds] \\|[Rr]esolve[ds]? \\|[Cc]lose[ds]? \\|[Pp]\\(?:ull [Rr]equest\\|[Rr]\\) \\|(\\)#\\([0-9]+\\))?\\)")
(bug-reference-url-format . "https://github.com/NixOS/nixpkgs/issues/%s"))
(nix-mode
(tab-width . 2)))

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.github/CODEOWNERS vendored
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@ -12,7 +12,7 @@
# Libraries
/lib @edolstra @nbp
/lib/systems @nbp @ericson2314
/lib/systems @nbp @ericson2314 @matthewbauer
/lib/generators.nix @edolstra @nbp @Profpatsch
/lib/debug.nix @edolstra @nbp @Profpatsch
@ -20,9 +20,11 @@
/default.nix @nbp
/pkgs/top-level/default.nix @nbp @Ericson2314
/pkgs/top-level/impure.nix @nbp @Ericson2314
/pkgs/top-level/stage.nix @nbp @Ericson2314
/pkgs/stdenv/generic @Ericson2314
/pkgs/stdenv/cross @Ericson2314
/pkgs/top-level/stage.nix @nbp @Ericson2314 @matthewbauer
/pkgs/top-level/splice.nix @Ericson2314 @matthewbauer
/pkgs/top-level/release-cross.nix @Ericson2314 @matthewbauer
/pkgs/stdenv/generic @Ericson2314 @matthewbauer
/pkgs/stdenv/cross @Ericson2314 @matthewbauer
/pkgs/build-support/cc-wrapper @Ericson2314 @orivej
/pkgs/build-support/bintools-wrapper @Ericson2314 @orivej
/pkgs/build-support/setup-hooks @Ericson2314
@ -45,27 +47,35 @@
/nixos/doc/manual/man-nixos-option.xml @nbp
/nixos/modules/installer/tools/nixos-option.sh @nbp
# New NixOS modules
/nixos/modules/module-list.nix @Infinisil
# Python-related code and docs
/maintainers/scripts/update-python-libraries @FRidh
/pkgs/top-level/python-packages.nix @FRidh
/pkgs/top-level/python-packages.nix @FRidh @jonringer
/pkgs/development/interpreters/python @FRidh
/pkgs/development/python-modules @FRidh
/doc/languages-frameworks/python.md @FRidh
/pkgs/development/python-modules @FRidh @jonringer
/doc/languages-frameworks/python.section.md @FRidh
# Haskell
/pkgs/development/compilers/ghc @peti @ryantm @basvandijk
/pkgs/development/haskell-modules @peti @ryantm @basvandijk
/pkgs/development/haskell-modules/default.nix @peti @ryantm @basvandijk
/pkgs/development/haskell-modules/generic-builder.nix @peti @ryantm @basvandijk
/pkgs/development/haskell-modules/hoogle.nix @peti @ryantm @basvandijk
/pkgs/development/compilers/ghc @basvandijk @cdepillabout
/pkgs/development/haskell-modules @basvandijk @cdepillabout
/pkgs/development/haskell-modules/default.nix @basvandijk @cdepillabout
/pkgs/development/haskell-modules/generic-builder.nix @basvandijk @cdepillabout
/pkgs/development/haskell-modules/hoogle.nix @basvandijk @cdepillabout
# Perl
/pkgs/development/interpreters/perl @volth
/pkgs/top-level/perl-packages.nix @volth
/pkgs/development/perl-modules @volth
# R
/pkgs/applications/science/math/R @peti
/pkgs/development/r-modules @peti
# Ruby
/pkgs/development/interpreters/ruby @zimbatm
/pkgs/development/ruby-modules @zimbatm
/pkgs/development/interpreters/ruby @alyssais @zimbatm
/pkgs/development/ruby-modules @alyssais @zimbatm
# Rust
/pkgs/development/compilers/rust @Mic92 @LnL7
@ -74,6 +84,14 @@
/pkgs/stdenv/darwin @NixOS/darwin-maintainers
/pkgs/os-specific/darwin @NixOS/darwin-maintainers
# C compilers
/pkgs/development/compilers/gcc @matthewbauer
/pkgs/development/compilers/llvm @matthewbauer
# Compatibility stuff
/pkgs/top-level/unix-tools.nix @matthewbauer
/pkgs/development/tools/xcbuild @matthewbauer
# Beam-related (Erlang, Elixir, LFE, etc)
/pkgs/development/beam-modules @gleber
/pkgs/development/interpreters/erlang @gleber
@ -89,11 +107,57 @@
# Eclipse
/pkgs/applications/editors/eclipse @rycee
# https://github.com/NixOS/nixpkgs/issues/31401
/lib/licenses.nix @ghost
# Licenses
/lib/licenses.nix @alyssais
# Qt / KDE
/pkgs/applications/kde @ttuegel
/pkgs/desktops/plasma-5 @ttuegel
/pkgs/development/libraries/kde-frameworks @ttuegel
/pkgs/development/libraries/qt-5 @ttuegel
# PostgreSQL and related stuff
/pkgs/servers/sql/postgresql @thoughtpolice
/nixos/modules/services/databases/postgresql.xml @thoughtpolice
/nixos/modules/services/databases/postgresql.nix @thoughtpolice
/nixos/tests/postgresql.nix @thoughtpolice
# Hardened profile & related modules
/nixos/modules/profiles/hardened.nix @joachifm
/nixos/modules/security/hidepid.nix @joachifm
/nixos/modules/security/lock-kernel-modules.nix @joachifm
/nixos/modules/security/misc.nix @joachifm
/nixos/tests/hardened.nix @joachifm
/pkgs/os-specific/linux/kernel/hardened-config.nix @joachifm
# Network Time Daemons
/pkgs/tools/networking/chrony @thoughtpolice
/pkgs/tools/networking/ntp @thoughtpolice
/pkgs/tools/networking/openntpd @thoughtpolice
/nixos/modules/services/networking/ntp @thoughtpolice
# Dhall
/pkgs/development/dhall-modules @Gabriel439 @Profpatsch
/pkgs/development/interpreters/dhall @Gabriel439 @Profpatsch
# Idris
/pkgs/development/idris-modules @Infinisil
# Bazel
/pkgs/development/tools/build-managers/bazel @mboes @Profpatsch
# NixOS modules for e-mail and dns services
/nixos/modules/services/mail/mailman.nix @peti
/nixos/modules/services/mail/postfix.nix @peti
/nixos/modules/services/networking/bind.nix @peti
/nixos/modules/services/mail/rspamd.nix @peti
# Emacs
/pkgs/applications/editors/emacs-modes @adisbladis
/pkgs/applications/editors/emacs @adisbladis
/pkgs/top-level/emacs-packages.nix @adisbladis
# Prometheus exporter modules and tests
/nixos/modules/services/monitoring/prometheus/exporters.nix @WilliButz
/nixos/modules/services/monitoring/prometheus/exporters.xml @WilliButz
/nixos/tests/prometheus-exporters.nix @WilliButz

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.github/CONTRIBUTING.md vendored
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@ -20,6 +20,8 @@ under the terms of [COPYING](../COPYING), which is an MIT-like license.
(Motivation for change. Additional information.)
```
For consistency, there should not be a period at the end of the commit message's summary line (the first line of the commit message).
Examples:
* nginx: init at 2.0.1

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.github/ISSUE_TEMPLATE.md vendored
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@ -8,5 +8,4 @@
## Technical details
Please run `nix-shell -p nix-info --run "nix-info -m"` and paste the
results.
Please run `nix run nixpkgs.nix-info -c nix-info -m` and paste the result.

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.github/ISSUE_TEMPLATE/bug_report.md vendored Normal file
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@ -0,0 +1,37 @@
---
name: Bug report
about: Create a report to help us improve
title: ''
labels: '0.kind: bug'
assignees: ''
---
**Describe the bug**
A clear and concise description of what the bug is.
**To Reproduce**
Steps to reproduce the behavior:
1. ...
2. ...
3. ...
**Expected behavior**
A clear and concise description of what you expected to happen.
**Screenshots**
If applicable, add screenshots to help explain your problem.
**Additional context**
Add any other context about the problem here.
**Metadata**
Please run `nix run nixpkgs.nix-info -c nix-info -m` and paste the result.
Maintainer information:
```yaml
# a list of nixpkgs attributes affected by the problem
attribute:
# a list of nixos modules affected by the problem
module:
```

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@ -0,0 +1,18 @@
---
name: Packaging requests
about: For packages that are missing
title: ''
labels: '0.kind: packaging request'
assignees: ''
---
**Project description**
_describe the project a little_
**Metadata**
* homepage URL:
* source URL:
* license: mit, bsd, gpl2+ , ...
* platforms: unix, linux, darwin, ...

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.github/PULL_REQUEST_TEMPLATE.md vendored
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@ -1,3 +1,4 @@
<!-- Nixpkgs has a lot of new incoming Pull Requests, but not enough people to review this constant stream. Even if you aren't a committer, we would appreciate reviews of other PRs, especially simple ones like package updates. Just testing the relevant package/service and leaving a comment saying what you tested, how you tested it and whether it worked would be great. List of open PRs: <https://github.com/NixOS/nixpkgs/pulls>, for more about reviewing contributions: <https://hydra.nixos.org/job/nixpkgs/trunk/manual/latest/download/1/nixpkgs/manual.html#sec-reviewing-contributions>. Reviewing isn't mandatory, but it would help out a lot and reduce the average time-to-merge for all of us. Thanks a lot if you do! -->
###### Motivation for this change
@ -11,10 +12,12 @@
- [ ] macOS
- [ ] other Linux distributions
- [ ] Tested via one or more NixOS test(s) if existing and applicable for the change (look inside [nixos/tests](https://github.com/NixOS/nixpkgs/blob/master/nixos/tests))
- [ ] Tested compilation of all pkgs that depend on this change using `nix-shell -p nox --run "nox-review wip"`
- [ ] Tested compilation of all pkgs that depend on this change using `nix-shell -p nix-review --run "nix-review wip"`
- [ ] Tested execution of all binary files (usually in `./result/bin/`)
- [ ] Determined the impact on package closure size (by running `nix path-info -S` before and after)
- [ ] Ensured that relevant documentation is up to date
- [ ] Fits [CONTRIBUTING.md](https://github.com/NixOS/nixpkgs/blob/master/.github/CONTRIBUTING.md).
---
###### Notify maintainers
cc @

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.gitignore vendored
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@ -13,4 +13,5 @@ result-*
.DS_Store
/pkgs/development/libraries/qt-5/*/tmp/
/pkgs/desktops/kde-5/*/tmp/
/pkgs/desktops/kde-5/*/tmp/
/pkgs/development/mobile/androidenv/xml/*

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.version
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@ -1 +1 @@
19.03
20.03

11
COPYING
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@ -1,4 +1,4 @@
Copyright (c) 2003-2018 Eelco Dolstra and the Nixpkgs/NixOS contributors
Copyright (c) 2003-2019 Eelco Dolstra and the Nixpkgs/NixOS contributors
Permission is hereby granted, free of charge, to any person obtaining
a copy of this software and associated documentation files (the
@ -18,12 +18,3 @@ NONINFRINGEMENT. IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE
LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION
OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION
WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
======================================================================
Note: the license above does not apply to the packages built by the
Nix Packages collection, merely to the package descriptions (i.e., Nix
expressions, build scripts, etc.). It also might not apply to patches
included in Nixpkgs, which may be derivative works of the packages to
which they apply. The aforementioned artifacts are all covered by the
licenses of the respective packages.

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README.md
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@ -1,41 +1,111 @@
[<img src="https://nixos.org/logo/nixos-hires.png" width="500px" alt="logo" />](https://nixos.org/nixos)
<p align="center">
<a href="https://nixos.org/nixos"><img src="https://nixos.org/logo/nixos-hires.png" width="500px" alt="NixOS logo" /></a>
</p>
[![Code Triagers Badge](https://www.codetriage.com/nixos/nixpkgs/badges/users.svg)](https://www.codetriage.com/nixos/nixpkgs)
<p align="center">
<a href="https://www.codetriage.com/nixos/nixpkgs"><img src="https://www.codetriage.com/nixos/nixpkgs/badges/users.svg" alt="Code Triagers badge" /></a>
<a href="https://opencollective.com/nixos"><img src="https://opencollective.com/nixos/tiers/supporter/badge.svg?label=Supporter&color=brightgreen" alt="Open Collective supporters" /></a>
</p>
Nixpkgs is a collection of packages for the [Nix](https://nixos.org/nix/) package
manager. It is periodically built and tested by the [Hydra](https://hydra.nixos.org/)
build daemon as so-called channels. To get channel information via git, add
[nixpkgs-channels](https://github.com/NixOS/nixpkgs-channels.git) as a remote:
[Nixpkgs](https://github.com/nixos/nixpkgs) is a collection of over
40,000 software packages that can be installed with the
[Nix](https://nixos.org/nix/) package manager. It also implements
[NixOS](https://nixos.org/nixos/), a purely-functional Linux distribution.
```
% git remote add channels https://github.com/NixOS/nixpkgs-channels.git
```
# Manuals
For stability and maximum binary package support, it is recommended to maintain
custom changes on top of one of the channels, e.g. `nixos-18.09` for the latest
release and `nixos-unstable` for the latest successful build of master:
* [NixOS Manual](https://nixos.org/nixos/manual) - how to install, configure, and maintain a purely-functional Linux distribution
* [Nixpkgs Manual](https://nixos.org/nixpkgs/manual/) - contributing to Nixpkgs and using programming-language-specific Nix expressions
* [Nix Package Manager Manual](https://nixos.org/nix/manual) - how to write Nix expresssions (programs), and how to use Nix command line tools
```
% git remote update channels
% git rebase channels/nixos-18.09
```
For pull-requests, please rebase onto nixpkgs `master`.
[NixOS](https://nixos.org/nixos/) Linux distribution source code is located inside
`nixos/` folder.
* [NixOS installation instructions](https://nixos.org/nixos/manual/#ch-installation)
* [Documentation (Nix Expression Language chapter)](https://nixos.org/nix/manual/#ch-expression-language)
* [Manual (How to write packages for Nix)](https://nixos.org/nixpkgs/manual/)
* [Manual (NixOS)](https://nixos.org/nixos/manual/)
* [Community maintained wiki](https://nixos.wiki/)
* [Continuous package builds for unstable/master](https://hydra.nixos.org/jobset/nixos/trunk-combined)
* [Continuous package builds for 18.09 release](https://hydra.nixos.org/jobset/nixos/release-18.09)
* [Tests for unstable/master](https://hydra.nixos.org/job/nixos/trunk-combined/tested#tabs-constituents)
* [Tests for 18.09 release](https://hydra.nixos.org/job/nixos/release-18.09/tested#tabs-constituents)
Communication:
# Community
* [Discourse Forum](https://discourse.nixos.org/)
* [IRC - #nixos on freenode.net](irc://irc.freenode.net/#nixos)
* [NixOS Weekly](https://weekly.nixos.org/)
* [Community-maintained wiki](https://nixos.wiki/)
# Other Project Repositories
The sources of all offical Nix-related projects are in the [NixOS
organization on GitHub](https://github.com/NixOS/). Here are some of
the main ones:
* [Nix](https://github.com/NixOS/nix) - the purely functional package manager
* [NixOps](https://github.com/NixOS/nixops) - the tool to remotely deploy NixOS machines
* [Nix RFCs](https://github.com/NixOS/rfcs) - the formal process for making substantial changes to the community
* [NixOS homepage](https://github.com/NixOS/nixos-homepage) - the [NixOS.org](https://nixos.org) website
* [hydra](https://github.com/NixOS/hydra) - our continuous integration system
* [NixOS Artwork](https://github.com/NixOS/nixos-artwork) - NixOS artwork
# Continuous Integration and Distribution
Nixpkgs and NixOS are built and tested by our continuous integration
system, [Hydra](https://hydra.nixos.org/).
* [Continuous package builds for unstable/master](https://hydra.nixos.org/jobset/nixos/trunk-combined)
* [Continuous package builds for the NixOS 19.09 release](https://hydra.nixos.org/jobset/nixos/release-19.09)
* [Tests for unstable/master](https://hydra.nixos.org/job/nixos/trunk-combined/tested#tabs-constituents)
* [Tests for the NixOS 19.09 release](https://hydra.nixos.org/job/nixos/release-19.09/tested#tabs-constituents)
Artifacts successfully built with Hydra are published to cache at
https://cache.nixos.org/. When successful build and test criteria are
met, the Nixpkgs expressions are distributed via [Nix
channels](https://nixos.org/nix/manual/#sec-channels).
# Contributing
Nixpkgs is among the most active projects on GitHub. While thousands
of open issues and pull requests might seem a lot at first, it helps
consider it in the context of the scope of the project. Nixpkgs
describes how to build over 40,000 pieces of software and implements a
Linux distribution. The [GitHub Insights](https://github.com/NixOS/nixpkgs/pulse)
page gives a sense of the project activity.
Community contributions are always welcome through GitHub Issues and
Pull Requests. When pull requests are made, our tooling automation bot,
[OfBorg](https://github.com/NixOS/ofborg) will perform various checks
to help ensure expression quality.
The *Nixpkgs maintainers* are people who have assigned themselves to
maintain specific individual packages. We encourage people who care
about a package to assign themselves as a maintainer. When a pull
request is made against a package, OfBorg will notify the appropriate
maintainer(s). The *Nixpkgs committers* are people who have been given
permission to merge.
Most contributions are based on and merged into these branches:
* `master` is the main branch where all small contributions go
* `staging` is branched from master, changes that have a big impact on
Hydra builds go to this branch
* `staging-next` is branched from staging and only fixes to stabilize
and security fixes with a big impact on Hydra builds should be
contributed to this branch. This branch is merged into master when
deemed of sufficiently high quality
For more information about contributing to the project, please visit
the [contributing page](https://github.com/NixOS/nixpkgs/blob/master/.github/CONTRIBUTING.md).
# Donations
The infrastructure for NixOS and related projects is maintained by a
nonprofit organization, the [NixOS
Foundation](https://nixos.org/nixos/foundation.html). To ensure the
continuity and expansion of the NixOS infrastructure, we are looking
for donations to our organization.
You can donate to the NixOS foundation by using Open Collective:
<a href="https://opencollective.com/nixos#support"><img src="https://opencollective.com/nixos/tiers/supporter.svg?width=890" /></a>
# License
Nixpkgs is licensed under the [MIT License](COPYING).
Note: MIT license does not apply to the packages built by Nixpkgs,
merely to the files in this repository (the Nix expressions, build
scripts, NixOS modules, etc.). It also might not apply to patches
included in Nixpkgs, which may be derivative works of the packages to
which they apply. The aforementioned artifacts are all covered by the
licenses of the respective packages.

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@ -18,7 +18,7 @@ if ! builtins ? nixVersion || builtins.compareVersions requiredVersion builtins.
For more information, please see the NixOS release notes at
https://nixos.org/nixos/manual or locally at
${toString ./doc/manual/release-notes}.
${toString ./nixos/doc/manual/release-notes}.
If you need further help, see https://nixos.org/nixos/support.html
''

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@ -1,7 +1,8 @@
*.chapter.xml
*.section.xml
.version
out
manual-full.xml
highlightjs
functions/library/generated
functions/library/locations.xml
highlightjs
manual-full.xml
out

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doc/Makefile
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@ -8,9 +8,11 @@ debug:
nix-shell --run "xmloscopy --docbook5 ./manual.xml ./manual-full.xml"
.PHONY: format
format:
find . -iname '*.xml' -type f -print0 | xargs -0 -I{} -n1 \
xmlformat --config-file "$$XMLFORMAT_CONFIG" -i {}
format: doc-support/result
find . -iname '*.xml' -type f | while read f; do \
echo $$f ;\
xmlformat --config-file "doc-support/result/xmlformat.conf" -i $$f ;\
done
.PHONY: fix-misc-xml
fix-misc-xml:
@ -19,19 +21,19 @@ fix-misc-xml:
.PHONY: clean
clean:
rm -f ${MD_TARGETS} .version manual-full.xml functions/library/locations.xml
rm -f ${MD_TARGETS} doc-support/result .version manual-full.xml functions/library/locations.xml functions/library/generated
rm -rf ./out/ ./highlightjs
.PHONY: validate
validate: manual-full.xml
jing "$$RNG" manual-full.xml
validate: manual-full.xml doc-support/result
jing doc-support/result/docbook.rng manual-full.xml
out/html/index.html: manual-full.xml style.css highlightjs
out/html/index.html: doc-support/result manual-full.xml style.css highlightjs
mkdir -p out/html
xsltproc ${xsltFlags} \
xsltproc \
--nonet --xinclude \
--output $@ \
"$$XSL/docbook/xhtml/docbook.xsl" \
doc-support/result/xhtml.xsl \
./manual-full.xml
mkdir -p out/html/highlightjs/
@ -41,44 +43,48 @@ out/html/index.html: manual-full.xml style.css highlightjs
cp ./style.css out/html/style.css
mkdir -p out/html/images/callouts
cp "$$XSL/docbook/images/callouts/"*.svg out/html/images/callouts/
cp doc-support/result/xsl/docbook/images/callouts/*.svg out/html/images/callouts/
chmod u+w -R out/html/
out/epub/manual.epub: manual-full.xml
mkdir -p out/epub/scratch
xsltproc ${xsltFlags} --nonet \
xsltproc --nonet \
--output out/epub/scratch/ \
"$$XSL/docbook/epub/docbook.xsl" \
doc-support/result/epub.xsl \
./manual-full.xml
cp ./overrides.css out/epub/scratch/OEBPS
cp ./style.css out/epub/scratch/OEBPS
mkdir -p out/epub/scratch/OEBPS/images/callouts/
cp "$$XSL/docbook/images/callouts/"*.svg out/epub/scratch/OEBPS/images/callouts/
cp doc-support/result/xsl/docbook/images/callouts/*.svg out/epub/scratch/OEBPS/images/callouts/
echo "application/epub+zip" > mimetype
zip -0Xq "out/epub/manual.epub" mimetype
rm mimetype
cd "out/epub/scratch/" && zip -Xr9D "../manual.epub" *
rm -rf "out/epub/scratch/"
highlightjs:
highlightjs: doc-support/result
mkdir -p highlightjs
cp -r "$$HIGHLIGHTJS/highlight.pack.js" highlightjs/
cp -r "$$HIGHLIGHTJS/LICENSE" highlightjs/
cp -r "$$HIGHLIGHTJS/mono-blue.css" highlightjs/
cp -r "$$HIGHLIGHTJS/loader.js" highlightjs/
cp -r doc-support/result/highlightjs/highlight.pack.js highlightjs/
cp -r doc-support/result/highlightjs/LICENSE highlightjs/
cp -r doc-support/result/highlightjs/mono-blue.css highlightjs/
cp -r doc-support/result/highlightjs/loader.js highlightjs/
manual-full.xml: ${MD_TARGETS} .version functions/library/locations.xml *.xml **/*.xml **/**/*.xml
manual-full.xml: ${MD_TARGETS} .version functions/library/locations.xml functions/library/generated *.xml **/*.xml **/**/*.xml
xmllint --nonet --xinclude --noxincludenode manual.xml --output manual-full.xml
.version:
nix-instantiate --eval \
-E '(import ../lib).version' > .version
.version: doc-support/result
ln -rfs ./doc-support/result/version .version
functions/library/locations.xml:
nix-build ./lib-function-locations.nix \
--out-link ./functions/library/locations.xml
doc-support/result: doc-support/default.nix
(cd doc-support; nix-build)
functions/library/locations.xml: doc-support/result
ln -rfs ./doc-support/result/function-locations.xml functions/library/locations.xml
functions/library/generated: doc-support/result
ln -rfs ./doc-support/result/function-docs functions/library/generated
%.section.xml: %.section.md
pandoc $^ -w docbook+smart \

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@ -0,0 +1,148 @@
<chapter xmlns="http://docbook.org/ns/docbook"
xmlns:xlink="http://www.w3.org/1999/xlink"
xmlns:xi="http://www.w3.org/2001/XInclude"
xml:id="chap-pkgs-fetchers">
<title>Fetchers</title>
<para>
When using Nix, you will frequently need to download source code and other files from the internet. Nixpkgs comes with a few helper functions that allow you to fetch fixed-output derivations in a structured way.
</para>
<para>
The two fetcher primitives are <function>fetchurl</function> and <function>fetchzip</function>. Both of these have two required arguments, a URL and a hash. The hash is typically <literal>sha256</literal>, although many more hash algorithms are supported. Nixpkgs contributors are currently recommended to use <literal>sha256</literal>. This hash will be used by Nix to identify your source. A typical usage of fetchurl is provided below.
</para>
<programlisting><![CDATA[
{ stdenv, fetchurl }:
stdenv.mkDerivation {
name = "hello";
src = fetchurl {
url = "http://www.example.org/hello.tar.gz";
sha256 = "1111111111111111111111111111111111111111111111111111";
};
}
]]></programlisting>
<para>
The main difference between <function>fetchurl</function> and <function>fetchzip</function> is in how they store the contents. <function>fetchurl</function> will store the unaltered contents of the URL within the Nix store. <function>fetchzip</function> on the other hand will decompress the archive for you, making files and directories directly accessible in the future. <function>fetchzip</function> can only be used with archives. Despite the name, <function>fetchzip</function> is not limited to .zip files and can also be used with any tarball.
</para>
<para>
<function>fetchpatch</function> works very similarly to <function>fetchurl</function> with the same arguments expected. It expects patch files as a source and and performs normalization on them before computing the checksum. For example it will remove comments or other unstable parts that are sometimes added by version control systems and can change over time.
</para>
<para>
Other fetcher functions allow you to add source code directly from a VCS such as subversion or git. These are mostly straightforward names based on the name of the command used with the VCS system. Because they give you a working repository, they act most like <function>fetchzip</function>.
</para>
<variablelist>
<varlistentry>
<term>
<literal>fetchsvn</literal>
</term>
<listitem>
<para>
Used with Subversion. Expects <literal>url</literal> to a Subversion directory, <literal>rev</literal>, and <literal>sha256</literal>.
</para>
</listitem>
</varlistentry>
<varlistentry>
<term>
<literal>fetchgit</literal>
</term>
<listitem>
<para>
Used with Git. Expects <literal>url</literal> to a Git repo, <literal>rev</literal>, and <literal>sha256</literal>. <literal>rev</literal> in this case can be full the git commit id (SHA1 hash) or a tag name like <literal>refs/tags/v1.0</literal>.
</para>
</listitem>
</varlistentry>
<varlistentry>
<term>
<literal>fetchfossil</literal>
</term>
<listitem>
<para>
Used with Fossil. Expects <literal>url</literal> to a Fossil archive, <literal>rev</literal>, and <literal>sha256</literal>.
</para>
</listitem>
</varlistentry>
<varlistentry>
<term>
<literal>fetchcvs</literal>
</term>
<listitem>
<para>
Used with CVS. Expects <literal>cvsRoot</literal>, <literal>tag</literal>, and <literal>sha256</literal>.
</para>
</listitem>
</varlistentry>
<varlistentry>
<term>
<literal>fetchhg</literal>
</term>
<listitem>
<para>
Used with Mercurial. Expects <literal>url</literal>, <literal>rev</literal>, and <literal>sha256</literal>.
</para>
</listitem>
</varlistentry>
</variablelist>
<para>
A number of fetcher functions wrap part of <function>fetchurl</function> and <function>fetchzip</function>. They are mainly convenience functions intended for commonly used destinations of source code in Nixpkgs. These wrapper fetchers are listed below.
</para>
<variablelist>
<varlistentry>
<term>
<literal>fetchFromGitHub</literal>
</term>
<listitem>
<para>
<function>fetchFromGitHub</function> expects four arguments. <literal>owner</literal> is a string corresponding to the GitHub user or organization that controls this repository. <literal>repo</literal> corresponds to the name of the software repository. These are located at the top of every GitHub HTML page as <literal>owner</literal>/<literal>repo</literal>. <literal>rev</literal> corresponds to the Git commit hash or tag (e.g <literal>v1.0</literal>) that will be downloaded from Git. Finally, <literal>sha256</literal> corresponds to the hash of the extracted directory. Again, other hash algorithms are also available but <literal>sha256</literal> is currently preferred.
</para>
</listitem>
</varlistentry>
<varlistentry>
<term>
<literal>fetchFromGitLab</literal>
</term>
<listitem>
<para>
This is used with GitLab repositories. The arguments expected are very similar to fetchFromGitHub above.
</para>
</listitem>
</varlistentry>
<varlistentry>
<term>
<literal>fetchFromBitbucket</literal>
</term>
<listitem>
<para>
This is used with BitBucket repositories. The arguments expected are very similar to fetchFromGitHub above.
</para>
</listitem>
</varlistentry>
<varlistentry>
<term>
<literal>fetchFromSavannah</literal>
</term>
<listitem>
<para>
This is used with Savannah repositories. The arguments expected are very similar to fetchFromGitHub above.
</para>
</listitem>
</varlistentry>
<varlistentry>
<term>
<literal>fetchFromRepoOrCz</literal>
</term>
<listitem>
<para>
This is used with repo.or.cz repositories. The arguments expected are very similar to fetchFromGitHub above.
</para>
</listitem>
</varlistentry>
</variablelist>
</chapter>

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<chapter xmlns="http://docbook.org/ns/docbook"
xmlns:xi="http://www.w3.org/2001/XInclude"
xml:id="chap-images">
<title>Images</title>
<para>
This chapter describes tools for creating various types of images.
</para>
<xi:include href="images/appimagetools.xml" />
<xi:include href="images/dockertools.xml" />
<xi:include href="images/ocitools.xml" />
<xi:include href="images/snaptools.xml" />
</chapter>

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<section xmlns="http://docbook.org/ns/docbook"
xmlns:xlink="http://www.w3.org/1999/xlink"
xmlns:xi="http://www.w3.org/2001/XInclude"
xml:id="sec-pkgs-appimageTools">
<title>pkgs.appimageTools</title>
<para>
<varname>pkgs.appimageTools</varname> is a set of functions for extracting and wrapping <link xlink:href="https://appimage.org/">AppImage</link> files. They are meant to be used if traditional packaging from source is infeasible, or it would take too long. To quickly run an AppImage file, <literal>pkgs.appimage-run</literal> can be used as well.
</para>
<warning>
<para>
The <varname>appimageTools</varname> API is unstable and may be subject to backwards-incompatible changes in the future.
</para>
</warning>
<section xml:id="ssec-pkgs-appimageTools-formats">
<title>AppImage formats</title>
<para>
There are different formats for AppImages, see <link xlink:href="https://github.com/AppImage/AppImageSpec/blob/74ad9ca2f94bf864a4a0dac1f369dd4f00bd1c28/draft.md#image-format">the specification</link> for details.
</para>
<itemizedlist>
<listitem>
<para>
Type 1 images are ISO 9660 files that are also ELF executables.
</para>
</listitem>
<listitem>
<para>
Type 2 images are ELF executables with an appended filesystem.
</para>
</listitem>
</itemizedlist>
<para>
They can be told apart with <command>file -k</command>:
</para>
<screen>
<prompt>$ </prompt>file -k type1.AppImage
type1.AppImage: ELF 64-bit LSB executable, x86-64, version 1 (SYSV) ISO 9660 CD-ROM filesystem data 'AppImage' (Lepton 3.x), scale 0-0,
spot sensor temperature 0.000000, unit celsius, color scheme 0, calibration: offset 0.000000, slope 0.000000, dynamically linked, interpreter /lib64/ld-linux-x86-64.so.2, for GNU/Linux 2.6.18, BuildID[sha1]=d629f6099d2344ad82818172add1d38c5e11bc6d, stripped\012- data
<prompt>$ </prompt>file -k type2.AppImage
type2.AppImage: ELF 64-bit LSB executable, x86-64, version 1 (SYSV) (Lepton 3.x), scale 232-60668, spot sensor temperature -4.187500, color scheme 15, show scale bar, calibration: offset -0.000000, slope 0.000000 (Lepton 2.x), scale 4111-45000, spot sensor temperature 412442.250000, color scheme 3, minimum point enabled, calibration: offset -75402534979642766821519867692934234112.000000, slope 5815371847733706829839455140374904832.000000, dynamically linked, interpreter /lib64/ld-linux-x86-64.so.2, for GNU/Linux 2.6.18, BuildID[sha1]=79dcc4e55a61c293c5e19edbd8d65b202842579f, stripped\012- data
</screen>
<para>
Note how the type 1 AppImage is described as an <literal>ISO 9660 CD-ROM filesystem</literal>, and the type 2 AppImage is not.
</para>
</section>
<section xml:id="ssec-pkgs-appimageTools-wrapping">
<title>Wrapping</title>
<para>
Depending on the type of AppImage you're wrapping, you'll have to use <varname>wrapType1</varname> or <varname>wrapType2</varname>.
</para>
<programlisting>
appimageTools.wrapType2 { # or wrapType1
name = "patchwork"; <co xml:id='ex-appimageTools-wrapping-1' />
src = fetchurl { <co xml:id='ex-appimageTools-wrapping-2' />
url = https://github.com/ssbc/patchwork/releases/download/v3.11.4/Patchwork-3.11.4-linux-x86_64.AppImage;
sha256 = "1blsprpkvm0ws9b96gb36f0rbf8f5jgmw4x6dsb1kswr4ysf591s";
};
extraPkgs = pkgs: with pkgs; [ ]; <co xml:id='ex-appimageTools-wrapping-3' />
}</programlisting>
<calloutlist>
<callout arearefs='ex-appimageTools-wrapping-1'>
<para>
<varname>name</varname> specifies the name of the resulting image.
</para>
</callout>
<callout arearefs='ex-appimageTools-wrapping-2'>
<para>
<varname>src</varname> specifies the AppImage file to extract.
</para>
</callout>
<callout arearefs='ex-appimageTools-wrapping-2'>
<para>
<varname>extraPkgs</varname> allows you to pass a function to include additional packages inside the FHS environment your AppImage is going to run in. There are a few ways to learn which dependencies an application needs:
<itemizedlist>
<listitem>
<para>
Looking through the extracted AppImage files, reading its scripts and running <command>patchelf</command> and <command>ldd</command> on its executables. This can also be done in <command>appimage-run</command>, by setting <command>APPIMAGE_DEBUG_EXEC=bash</command>.
</para>
</listitem>
<listitem>
<para>
Running <command>strace -vfefile</command> on the wrapped executable, looking for libraries that can't be found.
</para>
</listitem>
</itemizedlist>
</para>
</callout>
</calloutlist>
</section>
</section>

484
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<section xmlns="http://docbook.org/ns/docbook"
xmlns:xlink="http://www.w3.org/1999/xlink"
xmlns:xi="http://www.w3.org/2001/XInclude"
xml:id="sec-pkgs-dockerTools">
<title>pkgs.dockerTools</title>
<para>
<varname>pkgs.dockerTools</varname> is a set of functions for creating and manipulating Docker images according to the <link xlink:href="https://github.com/moby/moby/blob/master/image/spec/v1.2.md#docker-image-specification-v120"> Docker Image Specification v1.2.0 </link>. Docker itself is not used to perform any of the operations done by these functions.
</para>
<warning>
<para>
The <varname>dockerTools</varname> API is unstable and may be subject to backwards-incompatible changes in the future.
</para>
</warning>
<section xml:id="ssec-pkgs-dockerTools-buildImage">
<title>buildImage</title>
<para>
This function is analogous to the <command>docker build</command> command, in that it can be used to build a Docker-compatible repository tarball containing a single image with one or multiple layers. As such, the result is suitable for being loaded in Docker with <command>docker load</command>.
</para>
<para>
The parameters of <varname>buildImage</varname> with relative example values are described below:
</para>
<example xml:id='ex-dockerTools-buildImage'>
<title>Docker build</title>
<programlisting>
buildImage {
name = "redis"; <co xml:id='ex-dockerTools-buildImage-1' />
tag = "latest"; <co xml:id='ex-dockerTools-buildImage-2' />
fromImage = someBaseImage; <co xml:id='ex-dockerTools-buildImage-3' />
fromImageName = null; <co xml:id='ex-dockerTools-buildImage-4' />
fromImageTag = "latest"; <co xml:id='ex-dockerTools-buildImage-5' />
contents = pkgs.redis; <co xml:id='ex-dockerTools-buildImage-6' />
runAsRoot = '' <co xml:id='ex-dockerTools-buildImage-runAsRoot' />
#!${pkgs.runtimeShell}
mkdir -p /data
'';
config = { <co xml:id='ex-dockerTools-buildImage-8' />
Cmd = [ "/bin/redis-server" ];
WorkingDir = "/data";
Volumes = {
"/data" = {};
};
};
}
</programlisting>
</example>
<para>
The above example will build a Docker image <literal>redis/latest</literal> from the given base image. Loading and running this image in Docker results in <literal>redis-server</literal> being started automatically.
</para>
<calloutlist>
<callout arearefs='ex-dockerTools-buildImage-1'>
<para>
<varname>name</varname> specifies the name of the resulting image. This is the only required argument for <varname>buildImage</varname>.
</para>
</callout>
<callout arearefs='ex-dockerTools-buildImage-2'>
<para>
<varname>tag</varname> specifies the tag of the resulting image. By default it's <literal>null</literal>, which indicates that the nix output hash will be used as tag.
</para>
</callout>
<callout arearefs='ex-dockerTools-buildImage-3'>
<para>
<varname>fromImage</varname> is the repository tarball containing the base image. It must be a valid Docker image, such as exported by <command>docker save</command>. By default it's <literal>null</literal>, which can be seen as equivalent to <literal>FROM scratch</literal> of a <filename>Dockerfile</filename>.
</para>
</callout>
<callout arearefs='ex-dockerTools-buildImage-4'>
<para>
<varname>fromImageName</varname> can be used to further specify the base image within the repository, in case it contains multiple images. By default it's <literal>null</literal>, in which case <varname>buildImage</varname> will peek the first image available in the repository.
</para>
</callout>
<callout arearefs='ex-dockerTools-buildImage-5'>
<para>
<varname>fromImageTag</varname> can be used to further specify the tag of the base image within the repository, in case an image contains multiple tags. By default it's <literal>null</literal>, in which case <varname>buildImage</varname> will peek the first tag available for the base image.
</para>
</callout>
<callout arearefs='ex-dockerTools-buildImage-6'>
<para>
<varname>contents</varname> is a derivation that will be copied in the new layer of the resulting image. This can be similarly seen as <command>ADD contents/ /</command> in a <filename>Dockerfile</filename>. By default it's <literal>null</literal>.
</para>
</callout>
<callout arearefs='ex-dockerTools-buildImage-runAsRoot'>
<para>
<varname>runAsRoot</varname> is a bash script that will run as root in an environment that overlays the existing layers of the base image with the new resulting layer, including the previously copied <varname>contents</varname> derivation. This can be similarly seen as <command>RUN ...</command> in a <filename>Dockerfile</filename>.
<note>
<para>
Using this parameter requires the <literal>kvm</literal> device to be available.
</para>
</note>
</para>
</callout>
<callout arearefs='ex-dockerTools-buildImage-8'>
<para>
<varname>config</varname> is used to specify the configuration of the containers that will be started off the built image in Docker. The available options are listed in the <link xlink:href="https://github.com/moby/moby/blob/master/image/spec/v1.2.md#image-json-field-descriptions"> Docker Image Specification v1.2.0 </link>.
</para>
</callout>
</calloutlist>
<para>
After the new layer has been created, its closure (to which <varname>contents</varname>, <varname>config</varname> and <varname>runAsRoot</varname> contribute) will be copied in the layer itself. Only new dependencies that are not already in the existing layers will be copied.
</para>
<para>
At the end of the process, only one new single layer will be produced and added to the resulting image.
</para>
<para>
The resulting repository will only list the single image <varname>image/tag</varname>. In the case of <xref linkend='ex-dockerTools-buildImage'/> it would be <varname>redis/latest</varname>.
</para>
<para>
It is possible to inspect the arguments with which an image was built using its <varname>buildArgs</varname> attribute.
</para>
<note>
<para>
If you see errors similar to <literal>getProtocolByName: does not exist (no such protocol name: tcp)</literal> you may need to add <literal>pkgs.iana-etc</literal> to <varname>contents</varname>.
</para>
</note>
<note>
<para>
If you see errors similar to <literal>Error_Protocol ("certificate has unknown CA",True,UnknownCa)</literal> you may need to add <literal>pkgs.cacert</literal> to <varname>contents</varname>.
</para>
</note>
<example xml:id="example-pkgs-dockerTools-buildImage-creation-date">
<title>Impurely Defining a Docker Layer's Creation Date</title>
<para>
By default <function>buildImage</function> will use a static date of one second past the UNIX Epoch. This allows <function>buildImage</function> to produce binary reproducible images. When listing images with <command>docker images</command>, the newly created images will be listed like this:
</para>
<screen><![CDATA[
$ docker images
REPOSITORY TAG IMAGE ID CREATED SIZE
hello latest 08c791c7846e 48 years ago 25.2MB
]]></screen>
<para>
You can break binary reproducibility but have a sorted, meaningful <literal>CREATED</literal> column by setting <literal>created</literal> to <literal>now</literal>.
</para>
<programlisting><![CDATA[
pkgs.dockerTools.buildImage {
name = "hello";
tag = "latest";
created = "now";
contents = pkgs.hello;
config.Cmd = [ "/bin/hello" ];
}
]]></programlisting>
<para>
and now the Docker CLI will display a reasonable date and sort the images as expected:
<screen><![CDATA[
$ docker images
REPOSITORY TAG IMAGE ID CREATED SIZE
hello latest de2bf4786de6 About a minute ago 25.2MB
]]></screen>
however, the produced images will not be binary reproducible.
</para>
</example>
</section>
<section xml:id="ssec-pkgs-dockerTools-buildLayeredImage">
<title>buildLayeredImage</title>
<para>
Create a Docker image with many of the store paths being on their own layer to improve sharing between images.
</para>
<variablelist>
<varlistentry>
<term>
<varname>name</varname>
</term>
<listitem>
<para>
The name of the resulting image.
</para>
</listitem>
</varlistentry>
<varlistentry>
<term>
<varname>tag</varname> <emphasis>optional</emphasis>
</term>
<listitem>
<para>
Tag of the generated image.
</para>
<para>
<emphasis>Default:</emphasis> the output path's hash
</para>
</listitem>
</varlistentry>
<varlistentry>
<term>
<varname>contents</varname> <emphasis>optional</emphasis>
</term>
<listitem>
<para>
Top level paths in the container. Either a single derivation, or a list of derivations.
</para>
<para>
<emphasis>Default:</emphasis> <literal>[]</literal>
</para>
</listitem>
</varlistentry>
<varlistentry>
<term>
<varname>config</varname> <emphasis>optional</emphasis>
</term>
<listitem>
<para>
Run-time configuration of the container. A full list of the options are available at in the <link xlink:href="https://github.com/moby/moby/blob/master/image/spec/v1.2.md#image-json-field-descriptions"> Docker Image Specification v1.2.0 </link>.
</para>
<para>
<emphasis>Default:</emphasis> <literal>{}</literal>
</para>
</listitem>
</varlistentry>
<varlistentry>
<term>
<varname>created</varname> <emphasis>optional</emphasis>
</term>
<listitem>
<para>
Date and time the layers were created. Follows the same <literal>now</literal> exception supported by <literal>buildImage</literal>.
</para>
<para>
<emphasis>Default:</emphasis> <literal>1970-01-01T00:00:01Z</literal>
</para>
</listitem>
</varlistentry>
<varlistentry>
<term>
<varname>maxLayers</varname> <emphasis>optional</emphasis>
</term>
<listitem>
<para>
Maximum number of layers to create.
</para>
<para>
<emphasis>Default:</emphasis> <literal>100</literal>
</para>
<para>
<emphasis>Maximum:</emphasis> <literal>125</literal>
</para>
</listitem>
</varlistentry>
<varlistentry>
<term>
<varname>extraCommands</varname> <emphasis>optional</emphasis>
</term>
<listitem>
<para>
Shell commands to run while building the final layer, without access to most of the layer contents. Changes to this layer are "on top" of all the other layers, so can create additional directories and files.
</para>
</listitem>
</varlistentry>
</variablelist>
<section xml:id="dockerTools-buildLayeredImage-arg-contents">
<title>Behavior of <varname>contents</varname> in the final image</title>
<para>
Each path directly listed in <varname>contents</varname> will have a symlink in the root of the image.
</para>
<para>
For example:
<programlisting><![CDATA[
pkgs.dockerTools.buildLayeredImage {
name = "hello";
contents = [ pkgs.hello ];
}
]]></programlisting>
will create symlinks for all the paths in the <literal>hello</literal> package:
<screen><![CDATA[
/bin/hello -> /nix/store/h1zb1padqbbb7jicsvkmrym3r6snphxg-hello-2.10/bin/hello
/share/info/hello.info -> /nix/store/h1zb1padqbbb7jicsvkmrym3r6snphxg-hello-2.10/share/info/hello.info
/share/locale/bg/LC_MESSAGES/hello.mo -> /nix/store/h1zb1padqbbb7jicsvkmrym3r6snphxg-hello-2.10/share/locale/bg/LC_MESSAGES/hello.mo
]]></screen>
</para>
</section>
<section xml:id="dockerTools-buildLayeredImage-arg-config">
<title>Automatic inclusion of <varname>config</varname> references</title>
<para>
The closure of <varname>config</varname> is automatically included in the closure of the final image.
</para>
<para>
This allows you to make very simple Docker images with very little code. This container will start up and run <command>hello</command>:
<programlisting><![CDATA[
pkgs.dockerTools.buildLayeredImage {
name = "hello";
config.Cmd = [ "${pkgs.hello}/bin/hello" ];
}
]]></programlisting>
</para>
</section>
<section xml:id="dockerTools-buildLayeredImage-arg-maxLayers">
<title>Adjusting <varname>maxLayers</varname></title>
<para>
Increasing the <varname>maxLayers</varname> increases the number of layers which have a chance to be shared between different images.
</para>
<para>
Modern Docker installations support up to 128 layers, however older versions support as few as 42.
</para>
<para>
If the produced image will not be extended by other Docker builds, it is safe to set <varname>maxLayers</varname> to <literal>128</literal>. However it will be impossible to extend the image further.
</para>
<para>
The first (<literal>maxLayers-2</literal>) most "popular" paths will have their own individual layers, then layer #<literal>maxLayers-1</literal> will contain all the remaining "unpopular" paths, and finally layer #<literal>maxLayers</literal> will contain the Image configuration.
</para>
<para>
Docker's Layers are not inherently ordered, they are content-addressable and are not explicitly layered until they are composed in to an Image.
</para>
</section>
</section>
<section xml:id="ssec-pkgs-dockerTools-fetchFromRegistry">
<title>pullImage</title>
<para>
This function is analogous to the <command>docker pull</command> command, in that it can be used to pull a Docker image from a Docker registry. By default <link xlink:href="https://hub.docker.com/">Docker Hub</link> is used to pull images.
</para>
<para>
Its parameters are described in the example below:
</para>
<example xml:id='ex-dockerTools-pullImage'>
<title>Docker pull</title>
<programlisting>
pullImage {
imageName = "nixos/nix"; <co xml:id='ex-dockerTools-pullImage-1' />
imageDigest = "sha256:20d9485b25ecfd89204e843a962c1bd70e9cc6858d65d7f5fadc340246e2116b"; <co xml:id='ex-dockerTools-pullImage-2' />
finalImageName = "nix"; <co xml:id='ex-dockerTools-pullImage-3' />
finalImageTag = "1.11"; <co xml:id='ex-dockerTools-pullImage-4' />
sha256 = "0mqjy3zq2v6rrhizgb9nvhczl87lcfphq9601wcprdika2jz7qh8"; <co xml:id='ex-dockerTools-pullImage-5' />
os = "linux"; <co xml:id='ex-dockerTools-pullImage-6' />
arch = "x86_64"; <co xml:id='ex-dockerTools-pullImage-7' />
}
</programlisting>
</example>
<calloutlist>
<callout arearefs='ex-dockerTools-pullImage-1'>
<para>
<varname>imageName</varname> specifies the name of the image to be downloaded, which can also include the registry namespace (e.g. <literal>nixos</literal>). This argument is required.
</para>
</callout>
<callout arearefs='ex-dockerTools-pullImage-2'>
<para>
<varname>imageDigest</varname> specifies the digest of the image to be downloaded. This argument is required.
</para>
</callout>
<callout arearefs='ex-dockerTools-pullImage-3'>
<para>
<varname>finalImageName</varname>, if specified, this is the name of the image to be created. Note it is never used to fetch the image since we prefer to rely on the immutable digest ID. By default it's equal to <varname>imageName</varname>.
</para>
</callout>
<callout arearefs='ex-dockerTools-pullImage-4'>
<para>
<varname>finalImageTag</varname>, if specified, this is the tag of the image to be created. Note it is never used to fetch the image since we prefer to rely on the immutable digest ID. By default it's <literal>latest</literal>.
</para>
</callout>
<callout arearefs='ex-dockerTools-pullImage-5'>
<para>
<varname>sha256</varname> is the checksum of the whole fetched image. This argument is required.
</para>
</callout>
<callout arearefs='ex-dockerTools-pullImage-6'>
<para>
<varname>os</varname>, if specified, is the operating system of the fetched image. By default it's <literal>linux</literal>.
</para>
</callout>
<callout arearefs='ex-dockerTools-pullImage-7'>
<para>
<varname>arch</varname>, if specified, is the cpu architecture of the fetched image. By default it's <literal>x86_64</literal>.
</para>
</callout>
</calloutlist>
<para>
<literal>nix-prefetch-docker</literal> command can be used to get required image parameters:
<screen>
<prompt>$ </prompt>nix run nixpkgs.nix-prefetch-docker -c nix-prefetch-docker --image-name mysql --image-tag 5
</screen>
Since a given <varname>imageName</varname> may transparently refer to a manifest list of images which support multiple architectures and/or operating systems, you can supply the <option>--os</option> and <option>--arch</option> arguments to specify exactly which image you want. By default it will match the OS and architecture of the host the command is run on.
<screen>
<prompt>$ </prompt>nix-prefetch-docker --image-name mysql --image-tag 5 --arch x86_64 --os linux
</screen>
Desired image name and tag can be set using <option>--final-image-name</option> and <option>--final-image-tag</option> arguments:
<screen>
<prompt>$ </prompt>nix-prefetch-docker --image-name mysql --image-tag 5 --final-image-name eu.gcr.io/my-project/mysql --final-image-tag prod
</screen>
</para>
</section>
<section xml:id="ssec-pkgs-dockerTools-exportImage">
<title>exportImage</title>
<para>
This function is analogous to the <command>docker export</command> command, in that it can be used to flatten a Docker image that contains multiple layers. It is in fact the result of the merge of all the layers of the image. As such, the result is suitable for being imported in Docker with <command>docker import</command>.
</para>
<note>
<para>
Using this function requires the <literal>kvm</literal> device to be available.
</para>
</note>
<para>
The parameters of <varname>exportImage</varname> are the following:
</para>
<example xml:id='ex-dockerTools-exportImage'>
<title>Docker export</title>
<programlisting>
exportImage {
fromImage = someLayeredImage;
fromImageName = null;
fromImageTag = null;
name = someLayeredImage.name;
}
</programlisting>
</example>
<para>
The parameters relative to the base image have the same synopsis as described in <xref linkend='ssec-pkgs-dockerTools-buildImage'/>, except that <varname>fromImage</varname> is the only required argument in this case.
</para>
<para>
The <varname>name</varname> argument is the name of the derivation output, which defaults to <varname>fromImage.name</varname>.
</para>
</section>
<section xml:id="ssec-pkgs-dockerTools-shadowSetup">
<title>shadowSetup</title>
<para>
This constant string is a helper for setting up the base files for managing users and groups, only if such files don't exist already. It is suitable for being used in a <varname>runAsRoot</varname> <xref linkend='ex-dockerTools-buildImage-runAsRoot'/> script for cases like in the example below:
</para>
<example xml:id='ex-dockerTools-shadowSetup'>
<title>Shadow base files</title>
<programlisting>
buildImage {
name = "shadow-basic";
runAsRoot = ''
#!${pkgs.runtimeShell}
${shadowSetup}
groupadd -r redis
useradd -r -g redis redis
mkdir /data
chown redis:redis /data
'';
}
</programlisting>
</example>
<para>
Creating base files like <literal>/etc/passwd</literal> or <literal>/etc/login.defs</literal> is necessary for shadow-utils to manipulate users and groups.
</para>
</section>
</section>

62
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@ -0,0 +1,62 @@
<section xmlns="http://docbook.org/ns/docbook"
xmlns:xlink="http://www.w3.org/1999/xlink"
xmlns:xi="http://www.w3.org/2001/XInclude"
xml:id="sec-pkgs-ociTools">
<title>pkgs.ociTools</title>
<para>
<varname>pkgs.ociTools</varname> is a set of functions for creating containers according to the <link xlink:href="https://github.com/opencontainers/runtime-spec">OCI container specification v1.0.0</link>. Beyond that it makes no assumptions about the container runner you choose to use to run the created container.
</para>
<section xml:id="ssec-pkgs-ociTools-buildContainer">
<title>buildContainer</title>
<para>
This function creates a simple OCI container that runs a single command inside of it. An OCI container consists of a <varname>config.json</varname> and a rootfs directory.The nix store of the container will contain all referenced dependencies of the given command.
</para>
<para>
The parameters of <varname>buildContainer</varname> with an example value are described below:
</para>
<example xml:id='ex-ociTools-buildContainer'>
<title>Build Container</title>
<programlisting>
buildContainer {
args = [ (with pkgs; writeScript "run.sh" ''
#!${bash}/bin/bash
${coreutils}/bin/exec ${bash}/bin/bash
'').outPath ]; <co xml:id='ex-ociTools-buildContainer-1' />
mounts = {
"/data" = {
type = "none";
source = "/var/lib/mydata";
options = [ "bind" ];
};
};<co xml:id='ex-ociTools-buildContainer-2' />
readonly = false; <co xml:id='ex-ociTools-buildContainer-3' />
}
</programlisting>
<calloutlist>
<callout arearefs='ex-ociTools-buildContainer-1'>
<para>
<varname>args</varname> specifies a set of arguments to run inside the container. This is the only required argument for <varname>buildContainer</varname>. All referenced packages inside the derivation will be made available inside the container
</para>
</callout>
<callout arearefs='ex-ociTools-buildContainer-2'>
<para>
<varname>mounts</varname> specifies additional mount points chosen by the user. By default only a minimal set of necessary filesystems are mounted into the container (e.g procfs, cgroupfs)
</para>
</callout>
<callout arearefs='ex-ociTools-buildContainer-3'>
<para>
<varname>readonly</varname> makes the container's rootfs read-only if it is set to true. The default value is false <literal>false</literal>.
</para>
</callout>
</calloutlist>
</example>
</section>
</section>

28
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@ -0,0 +1,28 @@
let
inherit (import <nixpkgs> { }) snapTools firefox;
in snapTools.makeSnap {
meta = {
name = "nix-example-firefox";
summary = firefox.meta.description;
architectures = [ "amd64" ];
apps.nix-example-firefox = {
command = "${firefox}/bin/firefox";
plugs = [
"pulseaudio"
"camera"
"browser-support"
"avahi-observe"
"cups-control"
"desktop"
"desktop-legacy"
"gsettings"
"home"
"network"
"mount-observe"
"removable-media"
"x11"
];
};
confinement = "strict";
};
}

12
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@ -0,0 +1,12 @@
let
inherit (import <nixpkgs> { }) snapTools hello;
in snapTools.makeSnap {
meta = {
name = "hello";
summary = hello.meta.description;
description = hello.meta.longDescription;
architectures = [ "amd64" ];
confinement = "strict";
apps.hello.command = "${hello}/bin/hello";
};
}

59
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@ -0,0 +1,59 @@
<section xmlns="http://docbook.org/ns/docbook"
xmlns:xlink="http://www.w3.org/1999/xlink"
xmlns:xi="http://www.w3.org/2001/XInclude"
xml:id="sec-pkgs-snapTools">
<title>pkgs.snapTools</title>
<para>
<varname>pkgs.snapTools</varname> is a set of functions for creating Snapcraft images. Snap and Snapcraft is not used to perform these operations.
</para>
<section xml:id="ssec-pkgs-snapTools-makeSnap-signature">
<title>The makeSnap Function</title>
<para>
<function>makeSnap</function> takes a single named argument, <parameter>meta</parameter>. This argument mirrors <link xlink:href="https://docs.snapcraft.io/snap-format">the upstream <filename>snap.yaml</filename> format</link> exactly.
</para>
<para>
The <parameter>base</parameter> should not be be specified, as <function>makeSnap</function> will force set it.
</para>
<para>
Currently, <function>makeSnap</function> does not support creating GUI stubs.
</para>
</section>
<section xml:id="ssec-pkgs-snapTools-build-a-snap-hello">
<title>Build a Hello World Snap</title>
<example xml:id="ex-snapTools-buildSnap-hello">
<title>Making a Hello World Snap</title>
<para>
The following expression packages GNU Hello as a Snapcraft snap.
</para>
<programlisting><xi:include href="./snap/example-hello.nix" parse="text" /></programlisting>
<para>
<command>nix-build</command> this expression and install it with <command>snap install ./result --dangerous</command>. <command>hello</command> will now be the Snapcraft version of the package.
</para>
</example>
</section>
<section xml:id="ssec-pkgs-snapTools-build-a-snap-firefox">
<title>Build a Hello World Snap</title>
<example xml:id="ex-snapTools-buildSnap-firefox">
<title>Making a Graphical Snap</title>
<para>
Graphical programs require many more integrations with the host. This example uses Firefox as an example, because it is one of the most complicated programs we could package.
</para>
<programlisting><xi:include href="./snap/example-firefox.nix" parse="text" /></programlisting>
<para>
<command>nix-build</command> this expression and install it with <command>snap install ./result --dangerous</command>. <command>nix-example-firefox</command> will now be the Snapcraft version of the Firefox package.
</para>
<para>
The specific meaning behind plugs can be looked up in the <link xlink:href="https://docs.snapcraft.io/supported-interfaces">Snapcraft interface documentation</link>.
</para>
</example>
</section>
</section>

12
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@ -0,0 +1,12 @@
<chapter xmlns="http://docbook.org/ns/docbook"
xmlns:xi="http://www.w3.org/2001/XInclude"
xml:id="chap-special">
<title>Special builders</title>
<para>
This chapter describes several special builders.
</para>
<xi:include href="special/fhs-environments.xml" />
<xi:include href="special/mkshell.xml" />
</chapter>

122
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@ -0,0 +1,122 @@
<section xmlns="http://docbook.org/ns/docbook"
xmlns:xlink="http://www.w3.org/1999/xlink"
xmlns:xi="http://www.w3.org/2001/XInclude"
xml:id="sec-fhs-environments">
<title>buildFHSUserEnv</title>
<para>
<function>buildFHSUserEnv</function> provides a way to build and run FHS-compatible lightweight sandboxes. It creates an isolated root with bound <filename>/nix/store</filename>, so its footprint in terms of disk space needed is quite small. This allows one to run software which is hard or unfeasible to patch for NixOS -- 3rd-party source trees with FHS assumptions, games distributed as tarballs, software with integrity checking and/or external self-updated binaries. It uses Linux namespaces feature to create temporary lightweight environments which are destroyed after all child processes exit, without root user rights requirement. Accepted arguments are:
</para>
<variablelist>
<varlistentry>
<term>
<literal>name</literal>
</term>
<listitem>
<para>
Environment name.
</para>
</listitem>
</varlistentry>
<varlistentry>
<term>
<literal>targetPkgs</literal>
</term>
<listitem>
<para>
Packages to be installed for the main host's architecture (i.e. x86_64 on x86_64 installations). Along with libraries binaries are also installed.
</para>
</listitem>
</varlistentry>
<varlistentry>
<term>
<literal>multiPkgs</literal>
</term>
<listitem>
<para>
Packages to be installed for all architectures supported by a host (i.e. i686 and x86_64 on x86_64 installations). Only libraries are installed by default.
</para>
</listitem>
</varlistentry>
<varlistentry>
<term>
<literal>extraBuildCommands</literal>
</term>
<listitem>
<para>
Additional commands to be executed for finalizing the directory structure.
</para>
</listitem>
</varlistentry>
<varlistentry>
<term>
<literal>extraBuildCommandsMulti</literal>
</term>
<listitem>
<para>
Like <literal>extraBuildCommands</literal>, but executed only on multilib architectures.
</para>
</listitem>
</varlistentry>
<varlistentry>
<term>
<literal>extraOutputsToInstall</literal>
</term>
<listitem>
<para>
Additional derivation outputs to be linked for both target and multi-architecture packages.
</para>
</listitem>
</varlistentry>
<varlistentry>
<term>
<literal>extraInstallCommands</literal>
</term>
<listitem>
<para>
Additional commands to be executed for finalizing the derivation with runner script.
</para>
</listitem>
</varlistentry>
<varlistentry>
<term>
<literal>runScript</literal>
</term>
<listitem>
<para>
A command that would be executed inside the sandbox and passed all the command line arguments. It defaults to <literal>bash</literal>.
</para>
</listitem>
</varlistentry>
</variablelist>
<para>
One can create a simple environment using a <literal>shell.nix</literal> like that:
</para>
<programlisting><![CDATA[
{ pkgs ? import <nixpkgs> {} }:
(pkgs.buildFHSUserEnv {
name = "simple-x11-env";
targetPkgs = pkgs: (with pkgs;
[ udev
alsaLib
]) ++ (with pkgs.xorg;
[ libX11
libXcursor
libXrandr
]);
multiPkgs = pkgs: (with pkgs;
[ udev
alsaLib
]);
runScript = "bash";
}).env
]]></programlisting>
<para>
Running <literal>nix-shell</literal> would then drop you into a shell with these libraries and binaries available. You can use this to run closed-source applications which expect FHS structure without hassles: simply change <literal>runScript</literal> to the application path, e.g. <filename>./bin/start.sh</filename> -- relative paths are supported.
</para>
</section>

24
doc/builders/special/mkshell.xml Normal file
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@ -0,0 +1,24 @@
<section xmlns="http://docbook.org/ns/docbook"
xmlns:xlink="http://www.w3.org/1999/xlink"
xmlns:xi="http://www.w3.org/2001/XInclude"
xml:id="sec-pkgs-mkShell">
<title>pkgs.mkShell</title>
<para>
<function>pkgs.mkShell</function> is a special kind of derivation that is only useful when using it combined with <command>nix-shell</command>. It will in fact fail to instantiate when invoked with <command>nix-build</command>.
</para>
<section xml:id="sec-pkgs-mkShell-usage">
<title>Usage</title>
<programlisting><![CDATA[
{ pkgs ? import <nixpkgs> {} }:
pkgs.mkShell {
# this will make all the build inputs from hello and gnutar
# available to the shell environment
inputsFrom = with pkgs; [ hello gnutar ];
buildInputs = [ pkgs.gnumake ];
}
]]></programlisting>
</section>
</section>

79
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@ -0,0 +1,79 @@
<chapter xmlns="http://docbook.org/ns/docbook"
xmlns:xlink="http://www.w3.org/1999/xlink"
xmlns:xi="http://www.w3.org/2001/XInclude"
xml:id="chap-trivial-builders">
<title>Trivial builders</title>
<para>
Nixpkgs provides a couple of functions that help with building derivations. The most important one, <function>stdenv.mkDerivation</function>, has already been documented above. The following functions wrap <function>stdenv.mkDerivation</function>, making it easier to use in certain cases.
</para>
<variablelist>
<varlistentry>
<term>
<literal>runCommand</literal>
</term>
<listitem>
<para>
This takes three arguments, <literal>name</literal>, <literal>env</literal>, and <literal>buildCommand</literal>. <literal>name</literal> is just the name that Nix will append to the store path in the same way that <literal>stdenv.mkDerivation</literal> uses its <literal>name</literal> attribute. <literal>env</literal> is an attribute set specifying environment variables that will be set for this derivation. These attributes are then passed to the wrapped <literal>stdenv.mkDerivation</literal>. <literal>buildCommand</literal> specifies the commands that will be run to create this derivation. Note that you will need to create <literal>$out</literal> for Nix to register the command as successful.
</para>
<para>
An example of using <literal>runCommand</literal> is provided below.
</para>
<programlisting>
(import &lt;nixpkgs&gt; {}).runCommand "my-example" {} ''
echo My example command is running
mkdir $out
echo I can write data to the Nix store > $out/message
echo I can also run basic commands like:
echo ls
ls
echo whoami
whoami
echo date
date
''
</programlisting>
</listitem>
</varlistentry>
<varlistentry>
<term>
<literal>runCommandCC</literal>
</term>
<listitem>
<para>
This works just like <literal>runCommand</literal>. The only difference is that it also provides a C compiler in <literal>buildCommand</literal>s environment. To minimize your dependencies, you should only use this if you are sure you will need a C compiler as part of running your command.
</para>
</listitem>
</varlistentry>
<varlistentry>
<term>
<literal>writeTextFile</literal>, <literal>writeText</literal>, <literal>writeTextDir</literal>, <literal>writeScript</literal>, <literal>writeScriptBin</literal>
</term>
<listitem>
<para>
These functions write <literal>text</literal> to the Nix store. This is useful for creating scripts from Nix expressions. <literal>writeTextFile</literal> takes an attribute set and expects two arguments, <literal>name</literal> and <literal>text</literal>. <literal>name</literal> corresponds to the name used in the Nix store path. <literal>text</literal> will be the contents of the file. You can also set <literal>executable</literal> to true to make this file have the executable bit set.
</para>
<para>
Many more commands wrap <literal>writeTextFile</literal> including <literal>writeText</literal>, <literal>writeTextDir</literal>, <literal>writeScript</literal>, and <literal>writeScriptBin</literal>. These are convenience functions over <literal>writeTextFile</literal>.
</para>
</listitem>
</varlistentry>
<varlistentry>
<term>
<literal>symlinkJoin</literal>
</term>
<listitem>
<para>
This can be used to put many derivations into the same directory structure. It works by creating a new derivation and adding symlinks to each of the paths listed. It expects two arguments, <literal>name</literal>, and <literal>paths</literal>. <literal>name</literal> is the name used in the Nix store path for the created derivation. <literal>paths</literal> is a list of paths that will be symlinked. These paths can be to Nix store derivations or any other subdirectory contained within.
</para>
</listitem>
</varlistentry>
</variablelist>
</chapter>

363
doc/coding-conventions.xml
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@ -8,24 +8,17 @@
<itemizedlist>
<listitem>
<para>
Use 2 spaces of indentation per indentation level in Nix expressions, 4
spaces in shell scripts.
Use 2 spaces of indentation per indentation level in Nix expressions, 4 spaces in shell scripts.
</para>
</listitem>
<listitem>
<para>
Do not use tab characters, i.e. configure your editor to use soft tabs.
For instance, use <literal>(setq-default indent-tabs-mode nil)</literal>
in Emacs. Everybody has different tab settings so its asking for
trouble.
Do not use tab characters, i.e. configure your editor to use soft tabs. For instance, use <literal>(setq-default indent-tabs-mode nil)</literal> in Emacs. Everybody has different tab settings so its asking for trouble.
</para>
</listitem>
<listitem>
<para>
Use <literal>lowerCamelCase</literal> for variable names, not
<literal>UpperCamelCase</literal>. Note, this rule does not apply to
package attribute names, which instead follow the rules in
<xref linkend="sec-package-naming"/>.
Use <literal>lowerCamelCase</literal> for variable names, not <literal>UpperCamelCase</literal>. Note, this rule does not apply to package attribute names, which instead follow the rules in <xref linkend="sec-package-naming"/>.
</para>
</listitem>
<listitem>
@ -52,29 +45,33 @@ foo { arg = ...; }
</listitem>
<listitem>
<para>
In attribute sets or lists that span multiple lines, the attribute names
or list elements should be aligned:
In attribute sets or lists that span multiple lines, the attribute names or list elements should be aligned:
<programlisting>
# A long list.
list =
[ elem1
elem2
elem3
];
list = [
elem1
elem2
elem3
];
# A long attribute set.
attrs =
{ attr1 = short_expr;
attr2 =
if true then big_expr else big_expr;
};
# Alternatively:
attrs = {
attr1 = short_expr;
attr2 =
if true then big_expr else big_expr;
};
# Combined
listOfAttrs = [
{
attr1 = 3;
attr2 = "fff";
}
{
attr1 = 5;
attr2 = "ggg";
}
];
</programlisting>
</para>
</listitem>
@ -92,8 +89,7 @@ attrs = { x = 1280; y = 1024; };
</listitem>
<listitem>
<para>
Breaking in the middle of a function argument can give hard-to-read code,
like
Breaking in the middle of a function argument can give hard-to-read code, like
<programlisting>
someFunction { x = 1280;
y = 1024; } otherArg
@ -118,8 +114,7 @@ in someFunction res otherArg yetAnotherArg
</listitem>
<listitem>
<para>
The bodies of functions, asserts, and withs are not indented to prevent a
lot of superfluous indentation levels, i.e.
The bodies of functions, asserts, and withs are not indented to prevent a lot of superfluous indentation levels, i.e.
<programlisting>
{ arg1, arg2 }:
assert system == "i686-linux";
@ -151,8 +146,7 @@ stdenv.mkDerivation { ...
</listitem>
<listitem>
<para>
Functions should list their expected arguments as precisely as possible.
That is, write
Functions should list their expected arguments as precisely as possible. That is, write
<programlisting>
{ stdenv, fetchurl, perl }: <replaceable>...</replaceable>
</programlisting>
@ -166,9 +160,7 @@ args: with args; <replaceable>...</replaceable>
</programlisting>
</para>
<para>
For functions that are truly generic in the number of arguments (such as
wrappers around <varname>mkDerivation</varname>) that have some required
arguments, you should write them using an <literal>@</literal>-pattern:
For functions that are truly generic in the number of arguments (such as wrappers around <varname>mkDerivation</varname>) that have some required arguments, you should write them using an <literal>@</literal>-pattern:
<programlisting>
{ stdenv, doCoverageAnalysis ? false, ... } @ args:
@ -192,24 +184,20 @@ args.stdenv.mkDerivation (args // {
<title>Package naming</title>
<para>
In Nixpkgs, there are generally three different names associated with a
package:
The key words <emphasis>must</emphasis>, <emphasis>must not</emphasis>, <emphasis>required</emphasis>, <emphasis>shall</emphasis>, <emphasis>shall not</emphasis>, <emphasis>should</emphasis>, <emphasis>should not</emphasis>, <emphasis>recommended</emphasis>, <emphasis>may</emphasis>, and <emphasis>optional</emphasis> in this section are to be interpreted as described in <link xlink:href="https://tools.ietf.org/html/rfc2119">RFC 2119</link>. Only <emphasis>emphasized</emphasis> words are to be interpreted in this way.
</para>
<para>
In Nixpkgs, there are generally three different names associated with a package:
<itemizedlist>
<listitem>
<para>
The <varname>name</varname> attribute of the derivation (excluding the
version part). This is what most users see, in particular when using
<command>nix-env</command>.
The <varname>name</varname> attribute of the derivation (excluding the version part). This is what most users see, in particular when using <command>nix-env</command>.
</para>
</listitem>
<listitem>
<para>
The variable name used for the instantiated package in
<filename>all-packages.nix</filename>, and when passing it as a
dependency to other functions. Typically this is called the
<emphasis>package attribute name</emphasis>. This is what Nix expression
authors see. It can also be used when installing using <command>nix-env
-iA</command>.
The variable name used for the instantiated package in <filename>all-packages.nix</filename>, and when passing it as a dependency to other functions. Typically this is called the <emphasis>package attribute name</emphasis>. This is what Nix expression authors see. It can also be used when installing using <command>nix-env -iA</command>.
</para>
</listitem>
<listitem>
@ -218,12 +206,7 @@ args.stdenv.mkDerivation (args // {
</para>
</listitem>
</itemizedlist>
Most of the time, these are the same. For instance, the package
<literal>e2fsprogs</literal> has a <varname>name</varname> attribute
<literal>"e2fsprogs-<replaceable>version</replaceable>"</literal>, is bound
to the variable name <varname>e2fsprogs</varname> in
<filename>all-packages.nix</filename>, and the Nix expression is in
<filename>pkgs/os-specific/linux/e2fsprogs/default.nix</filename>.
Most of the time, these are the same. For instance, the package <literal>e2fsprogs</literal> has a <varname>name</varname> attribute <literal>"e2fsprogs-<replaceable>version</replaceable>"</literal>, is bound to the variable name <varname>e2fsprogs</varname> in <filename>all-packages.nix</filename>, and the Nix expression is in <filename>pkgs/os-specific/linux/e2fsprogs/default.nix</filename>.
</para>
<para>
@ -231,49 +214,32 @@ args.stdenv.mkDerivation (args // {
<itemizedlist>
<listitem>
<para>
Generally, try to stick to the upstream package name.
The <literal>name</literal> attribute <emphasis>should</emphasis> be identical to the upstream package name.
</para>
</listitem>
<listitem>
<para>
Dont use uppercase letters in the <literal>name</literal> attribute
— e.g., <literal>"mplayer-1.0rc2"</literal> instead of
<literal>"MPlayer-1.0rc2"</literal>.
The <literal>name</literal> attribute <emphasis>must not</emphasis> contain uppercase letters — e.g., <literal>"mplayer-1.0rc2"</literal> instead of <literal>"MPlayer-1.0rc2"</literal>.
</para>
</listitem>
<listitem>
<para>
The version part of the <literal>name</literal> attribute
<emphasis>must</emphasis> start with a digit (following a dash) — e.g.,
<literal>"hello-0.3.1rc2"</literal>.
The version part of the <literal>name</literal> attribute <emphasis>must</emphasis> start with a digit (following a dash) — e.g., <literal>"hello-0.3.1rc2"</literal>.
</para>
</listitem>
<listitem>
<para>
If a package is not a release but a commit from a repository, then the
version part of the name <emphasis>must</emphasis> be the date of that
(fetched) commit. The date must be in <literal>"YYYY-MM-DD"</literal>
format. Also append <literal>"unstable"</literal> to the name - e.g.,
<literal>"pkgname-unstable-2014-09-23"</literal>.
If a package is not a release but a commit from a repository, then the version part of the name <emphasis>must</emphasis> be the date of that (fetched) commit. The date <emphasis>must</emphasis> be in <literal>"YYYY-MM-DD"</literal> format. Also append <literal>"unstable"</literal> to the name - e.g., <literal>"pkgname-unstable-2014-09-23"</literal>.
</para>
</listitem>
<listitem>
<para>
Dashes in the package name should be preserved in new variable names,
rather than converted to underscores or camel cased — e.g.,
<varname>http-parser</varname> instead of <varname>http_parser</varname>
or <varname>httpParser</varname>. The hyphenated style is preferred in
all three package names.
Dashes in the package name <emphasis>should</emphasis> be preserved in new variable names, rather than converted to underscores or camel cased — e.g., <varname>http-parser</varname> instead of <varname>http_parser</varname> or <varname>httpParser</varname>. The hyphenated style is preferred in all three package names.
</para>
</listitem>
<listitem>
<para>
If there are multiple versions of a package, this should be reflected in
the variable names in <filename>all-packages.nix</filename>, e.g.
<varname>json-c-0-9</varname> and <varname>json-c-0-11</varname>. If
there is an obvious “default” version, make an attribute like
<literal>json-c = json-c-0-9;</literal>. See also
<xref linkend="sec-versioning" />
If there are multiple versions of a package, this <emphasis>should</emphasis> be reflected in the variable names in <filename>all-packages.nix</filename>, e.g. <varname>json-c-0-9</varname> and <varname>json-c-0-11</varname>. If there is an obvious “default” version, make an attribute like <literal>json-c = json-c-0-9;</literal>. See also <xref linkend="sec-versioning" />
</para>
</listitem>
</itemizedlist>
@ -283,31 +249,18 @@ args.stdenv.mkDerivation (args // {
<title>File naming and organisation</title>
<para>
Names of files and directories should be in lowercase, with dashes between
words — not in camel case. For instance, it should be
<filename>all-packages.nix</filename>, not
<filename>allPackages.nix</filename> or
<filename>AllPackages.nix</filename>.
Names of files and directories should be in lowercase, with dashes between words — not in camel case. For instance, it should be <filename>all-packages.nix</filename>, not <filename>allPackages.nix</filename> or <filename>AllPackages.nix</filename>.
</para>
<section xml:id="sec-hierarchy">
<title>Hierarchy</title>
<para>
Each package should be stored in its own directory somewhere in the
<filename>pkgs/</filename> tree, i.e. in
<filename>pkgs/<replaceable>category</replaceable>/<replaceable>subcategory</replaceable>/<replaceable>...</replaceable>/<replaceable>pkgname</replaceable></filename>.
Below are some rules for picking the right category for a package. Many
packages fall under several categories; what matters is the
<emphasis>primary</emphasis> purpose of a package. For example, the
<literal>libxml2</literal> package builds both a library and some tools;
but its a library foremost, so it goes under
<filename>pkgs/development/libraries</filename>.
Each package should be stored in its own directory somewhere in the <filename>pkgs/</filename> tree, i.e. in <filename>pkgs/<replaceable>category</replaceable>/<replaceable>subcategory</replaceable>/<replaceable>...</replaceable>/<replaceable>pkgname</replaceable></filename>. Below are some rules for picking the right category for a package. Many packages fall under several categories; what matters is the <emphasis>primary</emphasis> purpose of a package. For example, the <literal>libxml2</literal> package builds both a library and some tools; but its a library foremost, so it goes under <filename>pkgs/development/libraries</filename>.
</para>
<para>
When in doubt, consider refactoring the <filename>pkgs/</filename> tree,
e.g. creating new categories or splitting up an existing category.
When in doubt, consider refactoring the <filename>pkgs/</filename> tree, e.g. creating new categories or splitting up an existing category.
</para>
<variablelist>
@ -323,8 +276,7 @@ args.stdenv.mkDerivation (args // {
</term>
<listitem>
<para>
<filename>development/libraries</filename> (e.g.
<filename>libxml2</filename>)
<filename>development/libraries</filename> (e.g. <filename>libxml2</filename>)
</para>
</listitem>
</varlistentry>
@ -334,8 +286,7 @@ args.stdenv.mkDerivation (args // {
</term>
<listitem>
<para>
<filename>development/compilers</filename> (e.g.
<filename>gcc</filename>)
<filename>development/compilers</filename> (e.g. <filename>gcc</filename>)
</para>
</listitem>
</varlistentry>
@ -345,8 +296,7 @@ args.stdenv.mkDerivation (args // {
</term>
<listitem>
<para>
<filename>development/interpreters</filename> (e.g.
<filename>guile</filename>)
<filename>development/interpreters</filename> (e.g. <filename>guile</filename>)
</para>
</listitem>
</varlistentry>
@ -362,8 +312,7 @@ args.stdenv.mkDerivation (args // {
</term>
<listitem>
<para>
<filename>development/tools/parsing</filename> (e.g.
<filename>bison</filename>, <filename>flex</filename>)
<filename>development/tools/parsing</filename> (e.g. <filename>bison</filename>, <filename>flex</filename>)
</para>
</listitem>
</varlistentry>
@ -373,8 +322,7 @@ args.stdenv.mkDerivation (args // {
</term>
<listitem>
<para>
<filename>development/tools/build-managers</filename> (e.g.
<filename>gnumake</filename>)
<filename>development/tools/build-managers</filename> (e.g. <filename>gnumake</filename>)
</para>
</listitem>
</varlistentry>
@ -384,8 +332,7 @@ args.stdenv.mkDerivation (args // {
</term>
<listitem>
<para>
<filename>development/tools/misc</filename> (e.g.
<filename>binutils</filename>)
<filename>development/tools/misc</filename> (e.g. <filename>binutils</filename>)
</para>
</listitem>
</varlistentry>
@ -411,8 +358,7 @@ args.stdenv.mkDerivation (args // {
</term>
<listitem>
<para>
(A tool is a relatively small program, especially one intended to be
used non-interactively.)
(A tool is a relatively small program, especially one intended to be used non-interactively.)
</para>
<variablelist>
<varlistentry>
@ -421,8 +367,7 @@ args.stdenv.mkDerivation (args // {
</term>
<listitem>
<para>
<filename>tools/networking</filename> (e.g.
<filename>wget</filename>)
<filename>tools/networking</filename> (e.g. <filename>wget</filename>)
</para>
</listitem>
</varlistentry>
@ -452,8 +397,7 @@ args.stdenv.mkDerivation (args // {
</term>
<listitem>
<para>
<filename>tools/archivers</filename> (e.g. <filename>zip</filename>,
<filename>tar</filename>)
<filename>tools/archivers</filename> (e.g. <filename>zip</filename>, <filename>tar</filename>)
</para>
</listitem>
</varlistentry>
@ -463,8 +407,7 @@ args.stdenv.mkDerivation (args // {
</term>
<listitem>
<para>
<filename>tools/compression</filename> (e.g.
<filename>gzip</filename>, <filename>bzip2</filename>)
<filename>tools/compression</filename> (e.g. <filename>gzip</filename>, <filename>bzip2</filename>)
</para>
</listitem>
</varlistentry>
@ -474,8 +417,7 @@ args.stdenv.mkDerivation (args // {
</term>
<listitem>
<para>
<filename>tools/security</filename> (e.g. <filename>nmap</filename>,
<filename>gnupg</filename>)
<filename>tools/security</filename> (e.g. <filename>nmap</filename>, <filename>gnupg</filename>)
</para>
</listitem>
</varlistentry>
@ -514,8 +456,7 @@ args.stdenv.mkDerivation (args // {
</term>
<listitem>
<para>
<filename>servers/http</filename> (e.g.
<filename>apache-httpd</filename>)
<filename>servers/http</filename> (e.g. <filename>apache-httpd</filename>)
</para>
</listitem>
</varlistentry>
@ -525,8 +466,7 @@ args.stdenv.mkDerivation (args // {
</term>
<listitem>
<para>
<filename>servers/x11</filename> (e.g. <filename>xorg</filename>
this includes the client libraries and programs)
<filename>servers/x11</filename> (e.g. <filename>xorg</filename> — this includes the client libraries and programs)
</para>
</listitem>
</varlistentry>
@ -549,8 +489,7 @@ args.stdenv.mkDerivation (args // {
</term>
<listitem>
<para>
<filename>desktops</filename> (e.g. <filename>kde</filename>,
<filename>gnome</filename>, <filename>enlightenment</filename>)
<filename>desktops</filename> (e.g. <filename>kde</filename>, <filename>gnome</filename>, <filename>enlightenment</filename>)
</para>
</listitem>
</varlistentry>
@ -560,8 +499,7 @@ args.stdenv.mkDerivation (args // {
</term>
<listitem>
<para>
<filename>applications/window-managers</filename> (e.g.
<filename>awesome</filename>, <filename>stumpwm</filename>)
<filename>applications/window-managers</filename> (e.g. <filename>awesome</filename>, <filename>stumpwm</filename>)
</para>
</listitem>
</varlistentry>
@ -571,8 +509,7 @@ args.stdenv.mkDerivation (args // {
</term>
<listitem>
<para>
A (typically large) program with a distinct user interface, primarily
used interactively.
A (typically large) program with a distinct user interface, primarily used interactively.
</para>
<variablelist>
<varlistentry>
@ -581,8 +518,7 @@ args.stdenv.mkDerivation (args // {
</term>
<listitem>
<para>
<filename>applications/version-management</filename> (e.g.
<filename>subversion</filename>)
<filename>applications/version-management</filename> (e.g. <filename>subversion</filename>)
</para>
</listitem>
</varlistentry>
@ -592,8 +528,7 @@ args.stdenv.mkDerivation (args // {
</term>
<listitem>
<para>
<filename>applications/video</filename> (e.g.
<filename>vlc</filename>)
<filename>applications/video</filename> (e.g. <filename>vlc</filename>)
</para>
</listitem>
</varlistentry>
@ -603,8 +538,7 @@ args.stdenv.mkDerivation (args // {
</term>
<listitem>
<para>
<filename>applications/graphics</filename> (e.g.
<filename>gimp</filename>)
<filename>applications/graphics</filename> (e.g. <filename>gimp</filename>)
</para>
</listitem>
</varlistentry>
@ -620,8 +554,7 @@ args.stdenv.mkDerivation (args // {
</term>
<listitem>
<para>
<filename>applications/networking/mailreaders</filename> (e.g.
<filename>thunderbird</filename>)
<filename>applications/networking/mailreaders</filename> (e.g. <filename>thunderbird</filename>)
</para>
</listitem>
</varlistentry>
@ -631,8 +564,7 @@ args.stdenv.mkDerivation (args // {
</term>
<listitem>
<para>
<filename>applications/networking/newsreaders</filename> (e.g.
<filename>pan</filename>)
<filename>applications/networking/newsreaders</filename> (e.g. <filename>pan</filename>)
</para>
</listitem>
</varlistentry>
@ -642,8 +574,7 @@ args.stdenv.mkDerivation (args // {
</term>
<listitem>
<para>
<filename>applications/networking/browsers</filename> (e.g.
<filename>firefox</filename>)
<filename>applications/networking/browsers</filename> (e.g. <filename>firefox</filename>)
</para>
</listitem>
</varlistentry>
@ -701,8 +632,7 @@ args.stdenv.mkDerivation (args // {
</term>
<listitem>
<para>
<filename>data/sgml+xml/schemas/xml-dtd</filename> (e.g.
<filename>docbook</filename>)
<filename>data/sgml+xml/schemas/xml-dtd</filename> (e.g. <filename>docbook</filename>)
</para>
</listitem>
</varlistentry>
@ -715,8 +645,7 @@ args.stdenv.mkDerivation (args // {
(Okay, these are executable...)
</para>
<para>
<filename>data/sgml+xml/stylesheets/xslt</filename> (e.g.
<filename>docbook-xsl</filename>)
<filename>data/sgml+xml/stylesheets/xslt</filename> (e.g. <filename>docbook-xsl</filename>)
</para>
</listitem>
</varlistentry>
@ -753,36 +682,15 @@ args.stdenv.mkDerivation (args // {
<title>Versioning</title>
<para>
Because every version of a package in Nixpkgs creates a potential
maintenance burden, old versions of a package should not be kept unless
there is a good reason to do so. For instance, Nixpkgs contains several
versions of GCC because other packages dont build with the latest
version of GCC. Other examples are having both the latest stable and latest
pre-release version of a package, or to keep several major releases of an
application that differ significantly in functionality.
Because every version of a package in Nixpkgs creates a potential maintenance burden, old versions of a package should not be kept unless there is a good reason to do so. For instance, Nixpkgs contains several versions of GCC because other packages dont build with the latest version of GCC. Other examples are having both the latest stable and latest pre-release version of a package, or to keep several major releases of an application that differ significantly in functionality.
</para>
<para>
If there is only one version of a package, its Nix expression should be
named <filename>e2fsprogs/default.nix</filename>. If there are multiple
versions, this should be reflected in the filename, e.g.
<filename>e2fsprogs/1.41.8.nix</filename> and
<filename>e2fsprogs/1.41.9.nix</filename>. The version in the filename
should leave out unnecessary detail. For instance, if we keep the latest
Firefox 2.0.x and 3.5.x versions in Nixpkgs, they should be named
<filename>firefox/2.0.nix</filename> and
<filename>firefox/3.5.nix</filename>, respectively (which, at a given
point, might contain versions <literal>2.0.0.20</literal> and
<literal>3.5.4</literal>). If a version requires many auxiliary files, you
can use a subdirectory for each version, e.g.
<filename>firefox/2.0/default.nix</filename> and
<filename>firefox/3.5/default.nix</filename>.
If there is only one version of a package, its Nix expression should be named <filename>e2fsprogs/default.nix</filename>. If there are multiple versions, this should be reflected in the filename, e.g. <filename>e2fsprogs/1.41.8.nix</filename> and <filename>e2fsprogs/1.41.9.nix</filename>. The version in the filename should leave out unnecessary detail. For instance, if we keep the latest Firefox 2.0.x and 3.5.x versions in Nixpkgs, they should be named <filename>firefox/2.0.nix</filename> and <filename>firefox/3.5.nix</filename>, respectively (which, at a given point, might contain versions <literal>2.0.0.20</literal> and <literal>3.5.4</literal>). If a version requires many auxiliary files, you can use a subdirectory for each version, e.g. <filename>firefox/2.0/default.nix</filename> and <filename>firefox/3.5/default.nix</filename>.
</para>
<para>
All versions of a package <emphasis>must</emphasis> be included in
<filename>all-packages.nix</filename> to make sure that they evaluate
correctly.
All versions of a package <emphasis>must</emphasis> be included in <filename>all-packages.nix</filename> to make sure that they evaluate correctly.
</para>
</section>
</section>
@ -790,25 +698,15 @@ args.stdenv.mkDerivation (args // {
<title>Fetching Sources</title>
<para>
There are multiple ways to fetch a package source in nixpkgs. The general
guideline is that you should package sources with a high degree of
availability. Right now there is only one fetcher which has mirroring
support and that is <literal>fetchurl</literal>. Note that you should also
prefer protocols which have a corresponding proxy environment variable.
There are multiple ways to fetch a package source in nixpkgs. The general guideline is that you should package reproducible sources with a high degree of availability. Right now there is only one fetcher which has mirroring support and that is <literal>fetchurl</literal>. Note that you should also prefer protocols which have a corresponding proxy environment variable.
</para>
<para>
You can find many source fetch helpers in
<literal>pkgs/build-support/fetch*</literal>.
You can find many source fetch helpers in <literal>pkgs/build-support/fetch*</literal>.
</para>
<para>
In the file <literal>pkgs/top-level/all-packages.nix</literal> you can find
fetch helpers, these have names on the form <literal>fetchFrom*</literal>.
The intention of these are to provide snapshot fetches but using the same
api as some of the version controlled fetchers from
<literal>pkgs/build-support/</literal>. As an example going from bad to
good:
In the file <literal>pkgs/top-level/all-packages.nix</literal> you can find fetch helpers, these have names on the form <literal>fetchFrom*</literal>. The intention of these are to provide snapshot fetches but using the same api as some of the version controlled fetchers from <literal>pkgs/build-support/</literal>. As an example going from bad to good:
<itemizedlist>
<listitem>
<para>
@ -842,20 +740,109 @@ src = fetchFromGitHub {
owner = "NixOS";
repo = "nix";
rev = "1f795f9f44607cc5bec70d1300150bfefcef2aae";
sha256 = "04yri911rj9j19qqqn6m82266fl05pz98inasni0vxr1cf1gdgv9";
sha256 = "1i2yxndxb6yc9l6c99pypbd92lfq5aac4klq7y2v93c9qvx2cgpc";
}
</programlisting>
Find the value to put as <literal>sha256</literal> by running <literal>nix run -f '&lt;nixpkgs&gt;' nix-prefetch-github -c nix-prefetch-github --rev 1f795f9f44607cc5bec70d1300150bfefcef2aae NixOS nix</literal> or <literal>nix-prefetch-url --unpack https://github.com/NixOS/nix/archive/1f795f9f44607cc5bec70d1300150bfefcef2aae.tar.gz</literal>.
</para>
</listitem>
</itemizedlist>
</para>
</section>
<section xml:id="sec-source-hashes">
<title>Obtaining source hash</title>
<para>
Preferred source hash type is sha256. There are several ways to get it.
</para>
<orderedlist>
<listitem>
<para>
Prefetch URL (with <literal>nix-prefetch-<replaceable>XXX</replaceable> <replaceable>URL</replaceable></literal>, where <replaceable>XXX</replaceable> is one of <literal>url</literal>, <literal>git</literal>, <literal>hg</literal>, <literal>cvs</literal>, <literal>bzr</literal>, <literal>svn</literal>). Hash is printed to stdout.
</para>
</listitem>
<listitem>
<para>
Prefetch by package source (with <literal>nix-prefetch-url '&lt;nixpkgs&gt;' -A <replaceable>PACKAGE</replaceable>.src</literal>, where <replaceable>PACKAGE</replaceable> is package attribute name). Hash is printed to stdout.
</para>
<para>
This works well when you've upgraded existing package version and want to find out new hash, but is useless if package can't be accessed by attribute or package has multiple sources (<literal>.srcs</literal>, architecture-dependent sources, etc).
</para>
</listitem>
<listitem>
<para>
Upstream provided hash: use it when upstream provides <literal>sha256</literal> or <literal>sha512</literal> (when upstream provides <literal>md5</literal>, don't use it, compute <literal>sha256</literal> instead).
</para>
<para>
A little nuance is that <literal>nix-prefetch-*</literal> tools produce hash encoded with <literal>base32</literal>, but upstream usually provides hexadecimal (<literal>base16</literal>) encoding. Fetchers understand both formats. Nixpkgs does not standardize on any one format.
</para>
<para>
You can convert between formats with nix-hash, for example:
<screen>
<prompt>$ </prompt>nix-hash --type sha256 --to-base32 <replaceable>HASH</replaceable>
</screen>
</para>
</listitem>
<listitem>
<para>
Extracting hash from local source tarball can be done with <literal>sha256sum</literal>. Use <literal>nix-prefetch-url file:///path/to/tarball </literal> if you want base32 hash.
</para>
</listitem>
<listitem>
<para>
Fake hash: set fake hash in package expression, perform build and extract correct hash from error Nix prints.
</para>
<para>
For package updates it is enough to change one symbol to make hash fake. For new packages, you can use <literal>lib.fakeSha256</literal>, <literal>lib.fakeSha512</literal> or any other fake hash.
</para>
<para>
This is last resort method when reconstructing source URL is non-trivial and <literal>nix-prefetch-url -A</literal> isn't applicable (for example, <link xlink:href="https://github.com/NixOS/nixpkgs/blob/d2ab091dd308b99e4912b805a5eb088dd536adb9/pkgs/applications/video/kodi/default.nix#L73"> one of <literal>kodi</literal> dependencies</link>). The easiest way then would be replace hash with a fake one and rebuild. Nix build will fail and error message will contain desired hash.
</para>
<warning>
<para>
This method has security problems. Check below for details.
</para>
</warning>
</listitem>
</orderedlist>
<section xml:id="sec-source-hashes-security">
<title>Obtaining hashes securely</title>
<para>
Let's say Man-in-the-Middle (MITM) sits close to your network. Then instead of fetching source you can fetch malware, and instead of source hash you get hash of malware. Here are security considerations for this scenario:
</para>
<itemizedlist>
<listitem>
<para>
<literal>http://</literal> URLs are not secure to prefetch hash from;
</para>
</listitem>
<listitem>
<para>
hashes from upstream (in method 3) should be obtained via secure protocol;
</para>
</listitem>
<listitem>
<para>
<literal>https://</literal> URLs are secure in methods 1, 2, 3;
</para>
</listitem>
<listitem>
<para>
<literal>https://</literal> URLs are not secure in method 5. When obtaining hashes with fake hash method, TLS checks are disabled. So refetch source hash from several different networks to exclude MITM scenario. Alternatively, use fake hash method to make Nix error, but instead of extracting hash from error, extract <literal>https://</literal> URL and prefetch it with method 1.
</para>
</listitem>
</itemizedlist>
</section>
</section>
<section xml:id="sec-patches">
<title>Patches</title>
<para>
Patches available online should be retrieved using
<literal>fetchpatch</literal>.
Patches available online should be retrieved using <literal>fetchpatch</literal>.
</para>
<para>
@ -871,10 +858,7 @@ patches = [
</para>
<para>
Otherwise, you can add a <literal>.patch</literal> file to the
<literal>nixpkgs</literal> repository. In the interest of keeping our
maintenance burden to a minimum, only patches that are unique to
<literal>nixpkgs</literal> should be added in this way.
Otherwise, you can add a <literal>.patch</literal> file to the <literal>nixpkgs</literal> repository. In the interest of keeping our maintenance burden to a minimum, only patches that are unique to <literal>nixpkgs</literal> should be added in this way.
</para>
<para>
@ -884,36 +868,33 @@ patches = [ ./0001-changes.patch ];
</para>
<para>
If you do need to do create this sort of patch file, one way to do so is
with git:
If you do need to do create this sort of patch file, one way to do so is with git:
<orderedlist>
<listitem>
<para>
Move to the root directory of the source code you're patching.
<screen>
$ cd the/program/source</screen>
<prompt>$ </prompt>cd the/program/source</screen>
</para>
</listitem>
<listitem>
<para>
If a git repository is not already present, create one and stage all of
the source files.
If a git repository is not already present, create one and stage all of the source files.
<screen>
$ git init
$ git add .</screen>
<prompt>$ </prompt>git init
<prompt>$ </prompt>git add .</screen>
</para>
</listitem>
<listitem>
<para>
Edit some files to make whatever changes need to be included in the
patch.
Edit some files to make whatever changes need to be included in the patch.
</para>
</listitem>
<listitem>
<para>
Use git to create a diff, and pipe the output to a patch file:
<screen>
$ git diff > nixpkgs/pkgs/the/package/0001-changes.patch</screen>
<prompt>$ </prompt>git diff > nixpkgs/pkgs/the/package/0001-changes.patch</screen>
</para>
</listitem>
</orderedlist>

228
doc/configuration.xml
View File

@ -3,49 +3,38 @@
xml:id="chap-packageconfig">
<title>Global configuration</title>
<para>
Nix comes with certain defaults about what packages can and cannot be
installed, based on a package's metadata. By default, Nix will prevent
installation if any of the following criteria are true:
Nix comes with certain defaults about what packages can and cannot be installed, based on a package's metadata. By default, Nix will prevent installation if any of the following criteria are true:
</para>
<itemizedlist>
<listitem>
<para>
The package is thought to be broken, and has had its
<literal>meta.broken</literal> set to <literal>true</literal>.
The package is thought to be broken, and has had its <literal>meta.broken</literal> set to <literal>true</literal>.
</para>
</listitem>
<listitem>
<para>
The package isn't intended to run on the given system, as none of its
<literal>meta.platforms</literal> match the given system.
The package isn't intended to run on the given system, as none of its <literal>meta.platforms</literal> match the given system.
</para>
</listitem>
<listitem>
<para>
The package's <literal>meta.license</literal> is set to a license which is
considered to be unfree.
The package's <literal>meta.license</literal> is set to a license which is considered to be unfree.
</para>
</listitem>
<listitem>
<para>
The package has known security vulnerabilities but has not or can not be
updated for some reason, and a list of issues has been entered in to the
package's <literal>meta.knownVulnerabilities</literal>.
The package has known security vulnerabilities but has not or can not be updated for some reason, and a list of issues has been entered in to the package's <literal>meta.knownVulnerabilities</literal>.
</para>
</listitem>
</itemizedlist>
<para>
Note that all this is checked during evaluation already, and the check
includes any package that is evaluated. In particular, all build-time
dependencies are checked. <literal>nix-env -qa</literal> will (attempt to)
hide any packages that would be refused.
Note that all this is checked during evaluation already, and the check includes any package that is evaluated. In particular, all build-time dependencies are checked. <literal>nix-env -qa</literal> will (attempt to) hide any packages that would be refused.
</para>
<para>
Each of these criteria can be altered in the nixpkgs configuration.
</para>
<para>
The nixpkgs configuration for a NixOS system is set in the
<literal>configuration.nix</literal>, as in the following example:
The nixpkgs configuration for a NixOS system is set in the <literal>configuration.nix</literal>, as in the following example:
<programlisting>
{
nixpkgs.config = {
@ -53,13 +42,10 @@
};
}
</programlisting>
However, this does not allow unfree software for individual users. Their
configurations are managed separately.
However, this does not allow unfree software for individual users. Their configurations are managed separately.
</para>
<para>
A user's of nixpkgs configuration is stored in a user-specific configuration
file located at <filename>~/.config/nixpkgs/config.nix</filename>. For
example:
A user's nixpkgs configuration is stored in a user-specific configuration file located at <filename>~/.config/nixpkgs/config.nix</filename>. For example:
<programlisting>
{
allowUnfree = true;
@ -67,31 +53,25 @@
</programlisting>
</para>
<para>
Note that we are not able to test or build unfree software on Hydra due to
policy. Most unfree licenses prohibit us from either executing or
distributing the software.
Note that we are not able to test or build unfree software on Hydra due to policy. Most unfree licenses prohibit us from either executing or distributing the software.
</para>
<section xml:id="sec-allow-broken">
<title>Installing broken packages</title>
<para>
There are two ways to try compiling a package which has been marked as
broken.
There are two ways to try compiling a package which has been marked as broken.
</para>
<itemizedlist>
<listitem>
<para>
For allowing the build of a broken package once, you can use an
environment variable for a single invocation of the nix tools:
For allowing the build of a broken package once, you can use an environment variable for a single invocation of the nix tools:
<programlisting>$ export NIXPKGS_ALLOW_BROKEN=1</programlisting>
</para>
</listitem>
<listitem>
<para>
For permanently allowing broken packages to be built, you may add
<literal>allowBroken = true;</literal> to your user's configuration file,
like this:
For permanently allowing broken packages to be built, you may add <literal>allowBroken = true;</literal> to your user's configuration file, like this:
<programlisting>
{
allowBroken = true;
@ -105,23 +85,19 @@
<title>Installing packages on unsupported systems</title>
<para>
There are also two ways to try compiling a package which has been marked as
unsuported for the given system.
There are also two ways to try compiling a package which has been marked as unsuported for the given system.
</para>
<itemizedlist>
<listitem>
<para>
For allowing the build of a broken package once, you can use an
environment variable for a single invocation of the nix tools:
For allowing the build of a broken package once, you can use an environment variable for a single invocation of the nix tools:
<programlisting>$ export NIXPKGS_ALLOW_UNSUPPORTED_SYSTEM=1</programlisting>
</para>
</listitem>
<listitem>
<para>
For permanently allowing broken packages to be built, you may add
<literal>allowUnsupportedSystem = true;</literal> to your user's
configuration file, like this:
For permanently allowing broken packages to be built, you may add <literal>allowUnsupportedSystem = true;</literal> to your user's configuration file, like this:
<programlisting>
{
allowUnsupportedSystem = true;
@ -132,42 +108,29 @@
</itemizedlist>
<para>
The difference between an a package being unsupported on some system and
being broken is admittedly a bit fuzzy. If a program
<emphasis>ought</emphasis> to work on a certain platform, but doesn't, the
platform should be included in <literal>meta.platforms</literal>, but marked
as broken with e.g. <literal>meta.broken =
!hostPlatform.isWindows</literal>. Of course, this begs the question of what
"ought" means exactly. That is left to the package maintainer.
The difference between a package being unsupported on some system and being broken is admittedly a bit fuzzy. If a program <emphasis>ought</emphasis> to work on a certain platform, but doesn't, the platform should be included in <literal>meta.platforms</literal>, but marked as broken with e.g. <literal>meta.broken = !hostPlatform.isWindows</literal>. Of course, this begs the question of what "ought" means exactly. That is left to the package maintainer.
</para>
</section>
<section xml:id="sec-allow-unfree">
<title>Installing unfree packages</title>
<para>
There are several ways to tweak how Nix handles a package which has been
marked as unfree.
There are several ways to tweak how Nix handles a package which has been marked as unfree.
</para>
<itemizedlist>
<listitem>
<para>
To temporarily allow all unfree packages, you can use an environment
variable for a single invocation of the nix tools:
To temporarily allow all unfree packages, you can use an environment variable for a single invocation of the nix tools:
<programlisting>$ export NIXPKGS_ALLOW_UNFREE=1</programlisting>
</para>
</listitem>
<listitem>
<para>
It is possible to permanently allow individual unfree packages, while
still blocking unfree packages by default using the
<literal>allowUnfreePredicate</literal> configuration option in the user
configuration file.
It is possible to permanently allow individual unfree packages, while still blocking unfree packages by default using the <literal>allowUnfreePredicate</literal> configuration option in the user configuration file.
</para>
<para>
This option is a function which accepts a package as a parameter, and
returns a boolean. The following example configuration accepts a package
and always returns false:
This option is a function which accepts a package as a parameter, and returns a boolean. The following example configuration accepts a package and always returns false:
<programlisting>
{
allowUnfreePredicate = (pkg: false);
@ -175,25 +138,24 @@
</programlisting>
</para>
<para>
A more useful example, the following configuration allows only allows
flash player and visual studio code:
For a more useful example, try the following. This configuration only allows unfree packages named flash player and visual studio code:
<programlisting>
{
allowUnfreePredicate = (pkg: elem (builtins.parseDrvName pkg.name).name [ "flashplayer" "vscode" ]);
allowUnfreePredicate = (pkg: builtins.elem
(builtins.parseDrvName pkg.name).name [
"flashplayer"
"vscode"
]);
}
</programlisting>
</para>
</listitem>
<listitem>
<para>
It is also possible to whitelist and blacklist licenses that are
specifically acceptable or not acceptable, using
<literal>whitelistedLicenses</literal> and
<literal>blacklistedLicenses</literal>, respectively.
It is also possible to whitelist and blacklist licenses that are specifically acceptable or not acceptable, using <literal>whitelistedLicenses</literal> and <literal>blacklistedLicenses</literal>, respectively.
</para>
<para>
The following example configuration whitelists the licenses
<literal>amd</literal> and <literal>wtfpl</literal>:
The following example configuration whitelists the licenses <literal>amd</literal> and <literal>wtfpl</literal>:
<programlisting>
{
whitelistedLicenses = with stdenv.lib.licenses; [ amd wtfpl ];
@ -201,8 +163,7 @@
</programlisting>
</para>
<para>
The following example configuration blacklists the <literal>gpl3</literal>
and <literal>agpl3</literal> licenses:
The following example configuration blacklists the <literal>gpl3</literal> and <literal>agpl3</literal> licenses:
<programlisting>
{
blacklistedLicenses = with stdenv.lib.licenses; [ agpl3 gpl3 ];
@ -213,37 +174,29 @@
</itemizedlist>
<para>
A complete list of licenses can be found in the file
<filename>lib/licenses.nix</filename> of the nixpkgs tree.
A complete list of licenses can be found in the file <filename>lib/licenses.nix</filename> of the nixpkgs tree.
</para>
</section>
<section xml:id="sec-allow-insecure">
<title>Installing insecure packages</title>
<para>
There are several ways to tweak how Nix handles a package which has been
marked as insecure.
There are several ways to tweak how Nix handles a package which has been marked as insecure.
</para>
<itemizedlist>
<listitem>
<para>
To temporarily allow all insecure packages, you can use an environment
variable for a single invocation of the nix tools:
To temporarily allow all insecure packages, you can use an environment variable for a single invocation of the nix tools:
<programlisting>$ export NIXPKGS_ALLOW_INSECURE=1</programlisting>
</para>
</listitem>
<listitem>
<para>
It is possible to permanently allow individual insecure packages, while
still blocking other insecure packages by default using the
<literal>permittedInsecurePackages</literal> configuration option in the
user configuration file.
It is possible to permanently allow individual insecure packages, while still blocking other insecure packages by default using the <literal>permittedInsecurePackages</literal> configuration option in the user configuration file.
</para>
<para>
The following example configuration permits the installation of the
hypothetically insecure package <literal>hello</literal>, version
<literal>1.2.3</literal>:
The following example configuration permits the installation of the hypothetically insecure package <literal>hello</literal>, version <literal>1.2.3</literal>:
<programlisting>
{
permittedInsecurePackages = [
@ -255,18 +208,13 @@
</listitem>
<listitem>
<para>
It is also possible to create a custom policy around which insecure
packages to allow and deny, by overriding the
<literal>allowInsecurePredicate</literal> configuration option.
It is also possible to create a custom policy around which insecure packages to allow and deny, by overriding the <literal>allowInsecurePredicate</literal> configuration option.
</para>
<para>
The <literal>allowInsecurePredicate</literal> option is a function which
accepts a package and returns a boolean, much like
<literal>allowUnfreePredicate</literal>.
The <literal>allowInsecurePredicate</literal> option is a function which accepts a package and returns a boolean, much like <literal>allowUnfreePredicate</literal>.
</para>
<para>
The following configuration example only allows insecure packages with
very short names:
The following configuration example only allows insecure packages with very short names:
<programlisting>
{
allowInsecurePredicate = (pkg: (builtins.stringLength (builtins.parseDrvName pkg.name).name) &lt;= 5);
@ -274,8 +222,7 @@
</programlisting>
</para>
<para>
Note that <literal>permittedInsecurePackages</literal> is only checked if
<literal>allowInsecurePredicate</literal> is not specified.
Note that <literal>permittedInsecurePackages</literal> is only checked if <literal>allowInsecurePredicate</literal> is not specified.
</para>
</listitem>
</itemizedlist>
@ -285,10 +232,7 @@
<title>Modify packages via <literal>packageOverrides</literal></title>
<para>
You can define a function called <varname>packageOverrides</varname> in your
local <filename>~/.config/nixpkgs/config.nix</filename> to override nix
packages. It must be a function that takes pkgs as an argument and return
modified set of packages.
You can define a function called <varname>packageOverrides</varname> in your local <filename>~/.config/nixpkgs/config.nix</filename> to override Nix packages. It must be a function that takes pkgs as an argument and returns a modified set of packages.
<programlisting>
{
packageOverrides = pkgs: rec {
@ -305,15 +249,7 @@
<title>Build an environment</title>
<para>
Using <literal>packageOverrides</literal>, it is possible to manage
packages declaratively. This means that we can list all of our desired
packages within a declarative Nix expression. For example, to have
<literal>aspell</literal>, <literal>bc</literal>,
<literal>ffmpeg</literal>, <literal>coreutils</literal>,
<literal>gdb</literal>, <literal>nixUnstable</literal>,
<literal>emscripten</literal>, <literal>jq</literal>,
<literal>nox</literal>, and <literal>silver-searcher</literal>, we could
use the following in <filename>~/.config/nixpkgs/config.nix</filename>:
Using <literal>packageOverrides</literal>, it is possible to manage packages declaratively. This means that we can list all of our desired packages within a declarative Nix expression. For example, to have <literal>aspell</literal>, <literal>bc</literal>, <literal>ffmpeg</literal>, <literal>coreutils</literal>, <literal>gdb</literal>, <literal>nixUnstable</literal>, <literal>emscripten</literal>, <literal>jq</literal>, <literal>nox</literal>, and <literal>silver-searcher</literal>, we could use the following in <filename>~/.config/nixpkgs/config.nix</filename>:
</para>
<screen>
@ -321,20 +257,25 @@
packageOverrides = pkgs: with pkgs; {
myPackages = pkgs.buildEnv {
name = "my-packages";
paths = [ aspell bc coreutils gdb ffmpeg nixUnstable emscripten jq nox silver-searcher ];
paths = [
aspell
bc
coreutils
gdb
ffmpeg
nixUnstable
emscripten
jq
nox
silver-searcher
];
};
};
}
</screen>
<para>
To install it into our environment, you can just run <literal>nix-env -iA
nixpkgs.myPackages</literal>. If you want to load the packages to be built
from a working copy of <literal>nixpkgs</literal> you just run
<literal>nix-env -f. -iA myPackages</literal>. To explore what's been
installed, just look through <filename>~/.nix-profile/</filename>. You can
see that a lot of stuff has been installed. Some of this stuff is useful
some of it isn't. Let's tell Nixpkgs to only link the stuff that we want:
To install it into our environment, you can just run <literal>nix-env -iA nixpkgs.myPackages</literal>. If you want to load the packages to be built from a working copy of <literal>nixpkgs</literal> you just run <literal>nix-env -f. -iA myPackages</literal>. To explore what's been installed, just look through <filename>~/.nix-profile/</filename>. You can see that a lot of stuff has been installed. Some of this stuff is useful some of it isn't. Let's tell Nixpkgs to only link the stuff that we want:
</para>
<screen>
@ -342,7 +283,18 @@
packageOverrides = pkgs: with pkgs; {
myPackages = pkgs.buildEnv {
name = "my-packages";
paths = [ aspell bc coreutils gdb ffmpeg nixUnstable emscripten jq nox silver-searcher ];
paths = [
aspell
bc
coreutils
gdb
ffmpeg
nixUnstable
emscripten
jq
nox
silver-searcher
];
pathsToLink = [ "/share" "/bin" ];
};
};
@ -350,12 +302,7 @@
</screen>
<para>
<literal>pathsToLink</literal> tells Nixpkgs to only link the paths listed
which gets rid of the extra stuff in the profile. <filename>/bin</filename>
and <filename>/share</filename> are good defaults for a user environment,
getting rid of the clutter. If you are running on Nix on MacOS, you may
want to add another path as well, <filename>/Applications</filename>, that
makes GUI apps available.
<literal>pathsToLink</literal> tells Nixpkgs to only link the paths listed which gets rid of the extra stuff in the profile. <filename>/bin</filename> and <filename>/share</filename> are good defaults for a user environment, getting rid of the clutter. If you are running on Nix on MacOS, you may want to add another path as well, <filename>/Applications</filename>, that makes GUI apps available.
</para>
</section>
@ -363,13 +310,7 @@
<title>Getting documentation</title>
<para>
After building that new environment, look through
<filename>~/.nix-profile</filename> to make sure everything is there that
we wanted. Discerning readers will note that some files are missing. Look
inside <filename>~/.nix-profile/share/man/man1/</filename> to verify this.
There are no man pages for any of the Nix tools! This is because some
packages like Nix have multiple outputs for things like documentation (see
section 4). Let's make Nix install those as well.
After building that new environment, look through <filename>~/.nix-profile</filename> to make sure everything is there that we wanted. Discerning readers will note that some files are missing. Look inside <filename>~/.nix-profile/share/man/man1/</filename> to verify this. There are no man pages for any of the Nix tools! This is because some packages like Nix have multiple outputs for things like documentation (see section 4). Let's make Nix install those as well.
</para>
<screen>
@ -377,7 +318,17 @@
packageOverrides = pkgs: with pkgs; {
myPackages = pkgs.buildEnv {
name = "my-packages";
paths = [ aspell bc coreutils ffmpeg nixUnstable emscripten jq nox silver-searcher ];
paths = [
aspell
bc
coreutils
ffmpeg
nixUnstable
emscripten
jq
nox
silver-searcher
];
pathsToLink = [ "/share/man" "/share/doc" "/bin" ];
extraOutputsToInstall = [ "man" "doc" ];
};
@ -386,9 +337,7 @@
</screen>
<para>
This provides us with some useful documentation for using our packages.
However, if we actually want those manpages to be detected by man, we need
to set up our environment. This can also be managed within Nix expressions.
This provides us with some useful documentation for using our packages. However, if we actually want those manpages to be detected by man, we need to set up our environment. This can also be managed within Nix expressions.
</para>
<screen>
@ -424,9 +373,7 @@
</screen>
<para>
For this to work fully, you must also have this script sourced when you are
logged in. Try adding something like this to your
<filename>~/.profile</filename> file:
For this to work fully, you must also have this script sourced when you are logged in. Try adding something like this to your <filename>~/.profile</filename> file:
</para>
<screen>
@ -441,8 +388,7 @@ fi
</screen>
<para>
Now just run <literal>source $HOME/.profile</literal> and you can starting
loading man pages from your environent.
Now just run <literal>source $HOME/.profile</literal> and you can starting loading man pages from your environent.
</para>
</section>
@ -450,9 +396,7 @@ fi
<title>GNU info setup</title>
<para>
Configuring GNU info is a little bit trickier than man pages. To work
correctly, info needs a database to be generated. This can be done with
some small modifications to our environment scripts.
Configuring GNU info is a little bit trickier than man pages. To work correctly, info needs a database to be generated. This can be done with some small modifications to our environment scripts.
</para>
<screen>
@ -498,11 +442,7 @@ fi
</screen>
<para>
<literal>postBuild</literal> tells Nixpkgs to run a command after building
the environment. In this case, <literal>install-info</literal> adds the
installed info pages to <literal>dir</literal> which is GNU info's default
root node. Note that <literal>texinfoInteractive</literal> is added to the
environment to give the <literal>install-info</literal> command.
<literal>postBuild</literal> tells Nixpkgs to run a command after building the environment. In this case, <literal>install-info</literal> adds the installed info pages to <literal>dir</literal> which is GNU info's default root node. Note that <literal>texinfoInteractive</literal> is added to the environment to give the <literal>install-info</literal> command.
</para>
</section>
</section>

30
doc/contributing-to-documentation.xml Normal file
View File

@ -0,0 +1,30 @@
<chapter xmlns="http://docbook.org/ns/docbook"
xmlns:xlink="http://www.w3.org/1999/xlink"
xml:id="chap-contributing">
<title>Contributing to this documentation</title>
<para>
The DocBook sources of the Nixpkgs manual are in the <filename
xlink:href="https://github.com/NixOS/nixpkgs/tree/master/doc">doc</filename> subdirectory of the Nixpkgs repository.
</para>
<para>
You can quickly check your edits with <command>make</command>:
</para>
<screen>
<prompt>$ </prompt>cd /path/to/nixpkgs/doc
<prompt>$ </prompt>nix-shell
<prompt>[nix-shell]$ </prompt>make
</screen>
<para>
If you experience problems, run <command>make debug</command> to help understand the docbook errors.
</para>
<para>
After making modifications to the manual, it's important to build it before committing. You can do that as follows:
<screen>
<prompt>$ </prompt>cd /path/to/nixpkgs/doc
<prompt>$ </prompt>nix-shell
<prompt>[nix-shell]$ </prompt>make clean
<prompt>[nix-shell]$ </prompt>nix-build .
</screen>
If the build succeeds, the manual will be in <filename>./result/share/doc/nixpkgs/manual.html</filename>.
</para>
</chapter>

35
doc/contributing.xml
View File

@ -1,35 +0,0 @@
<chapter xmlns="http://docbook.org/ns/docbook"
xmlns:xlink="http://www.w3.org/1999/xlink"
xml:id="chap-contributing">
<title>Contributing to this documentation</title>
<para>
The DocBook sources of the Nixpkgs manual are in the
<filename
xlink:href="https://github.com/NixOS/nixpkgs/tree/master/doc">doc</filename>
subdirectory of the Nixpkgs repository.
</para>
<para>
You can quickly check your edits with <command>make</command>:
</para>
<screen>
$ cd /path/to/nixpkgs/doc
$ nix-shell
[nix-shell]$ make
</screen>
<para>
If you experience problems, run <command>make debug</command> to help
understand the docbook errors.
</para>
<para>
After making modifications to the manual, it's important to build it before
committing. You can do that as follows:
<screen>
$ cd /path/to/nixpkgs/doc
$ nix-shell
[nix-shell]$ make clean
[nix-shell]$ nix-build .
</screen>
If the build succeeds, the manual will be in
<filename>./result/share/doc/nixpkgs/manual.html</filename>.
</para>
</chapter>

441
doc/cross-compilation.xml
View File

@ -6,51 +6,27 @@
<title>Introduction</title>
<para>
"Cross-compilation" means compiling a program on one machine for another
type of machine. For example, a typical use of cross compilation is to
compile programs for embedded devices. These devices often don't have the
computing power and memory to compile their own programs. One might think
that cross-compilation is a fairly niche concern, but there are advantages
to being rigorous about distinguishing build-time vs run-time environments
even when one is developing and deploying on the same machine. Nixpkgs is
increasingly adopting the opinion that packages should be written with
cross-compilation in mind, and nixpkgs should evaluate in a similar way (by
minimizing cross-compilation-specific special cases) whether or not one is
cross-compiling.
"Cross-compilation" means compiling a program on one machine for another type of machine. For example, a typical use of cross-compilation is to compile programs for embedded devices. These devices often don't have the computing power and memory to compile their own programs. One might think that cross-compilation is a fairly niche concern. However, there are significant advantages to rigorously distinguishing between build-time and run-time environments! Significant, because the benefits apply even when one is developing and deploying on the same machine. Nixpkgs is increasingly adopting the opinion that packages should be written with cross-compilation in mind, and nixpkgs should evaluate in a similar way (by minimizing cross-compilation-specific special cases) whether or not one is cross-compiling.
</para>
<para>
This chapter will be organized in three parts. First, it will describe the
basics of how to package software in a way that supports cross-compilation.
Second, it will describe how to use Nixpkgs when cross-compiling. Third, it
will describe the internal infrastructure supporting cross-compilation.
This chapter will be organized in three parts. First, it will describe the basics of how to package software in a way that supports cross-compilation. Second, it will describe how to use Nixpkgs when cross-compiling. Third, it will describe the internal infrastructure supporting cross-compilation.
</para>
</section>
<!--============================================================-->
<section xml:id="sec-cross-packaging">
<title>Packaging in a cross-friendly manner</title>
<section xml:id="sec-cross-platform-parameters">
<section xml:id="ssec-cross-platform-parameters">
<title>Platform parameters</title>
<para>
Nixpkgs follows the
<link xlink:href="https://gcc.gnu.org/onlinedocs/gccint/Configure-Terms.html">common
historical convention of GNU autoconf</link> of distinguishing between 3
types of platform: <wordasword>build</wordasword>,
<wordasword>host</wordasword>, and <wordasword>target</wordasword>. In
summary, <wordasword>build</wordasword> is the platform on which a package
is being built, <wordasword>host</wordasword> is the platform on which it
is to run. The third attribute, <wordasword>target</wordasword>, is
relevant only for certain specific compilers and build tools.
Nixpkgs follows the <link
xlink:href="https://gcc.gnu.org/onlinedocs/gccint/Configure-Terms.html">conventions of GNU autoconf</link>. We distinguish between 3 types of platforms when building a derivation: <wordasword>build</wordasword>, <wordasword>host</wordasword>, and <wordasword>target</wordasword>. In summary, <wordasword>build</wordasword> is the platform on which a package is being built, <wordasword>host</wordasword> is the platform on which it will run. The third attribute, <wordasword>target</wordasword>, is relevant only for certain specific compilers and build tools.
</para>
<para>
In Nixpkgs, these three platforms are defined as attribute sets under the
names <literal>buildPlatform</literal>, <literal>hostPlatform</literal>,
and <literal>targetPlatform</literal>. They are always defined as
attributes in the standard environment. That means one can access them
like:
In Nixpkgs, these three platforms are defined as attribute sets under the names <literal>buildPlatform</literal>, <literal>hostPlatform</literal>, and <literal>targetPlatform</literal>. They are always defined as attributes in the standard environment. That means one can access them like:
<programlisting>{ stdenv, fooDep, barDep, .. }: ...stdenv.buildPlatform...</programlisting>
.
</para>
@ -62,9 +38,7 @@
</term>
<listitem>
<para>
The "build platform" is the platform on which a package is built. Once
someone has a built package, or pre-built binary package, the build
platform should not matter and be safe to ignore.
The "build platform" is the platform on which a package is built. Once someone has a built package, or pre-built binary package, the build platform should not matter and can be ignored.
</para>
</listitem>
</varlistentry>
@ -74,9 +48,7 @@
</term>
<listitem>
<para>
The "host platform" is the platform on which a package will be run. This
is the simplest platform to understand, but also the one with the worst
name.
The "host platform" is the platform on which a package will be run. This is the simplest platform to understand, but also the one with the worst name.
</para>
</listitem>
</varlistentry>
@ -86,44 +58,23 @@
</term>
<listitem>
<para>
The "target platform" attribute is, unlike the other two attributes, not
actually fundamental to the process of building software. Instead, it is
only relevant for compatibility with building certain specific compilers
and build tools. It can be safely ignored for all other packages.
The "target platform" attribute is, unlike the other two attributes, not actually fundamental to the process of building software. Instead, it is only relevant for compatibility with building certain specific compilers and build tools. It can be safely ignored for all other packages.
</para>
<para>
The build process of certain compilers is written in such a way that the
compiler resulting from a single build can itself only produce binaries
for a single platform. The task specifying this single "target platform"
is thus pushed to build time of the compiler. The root cause of this
mistake is often that the compiler (which will be run on the host) and
the the standard library/runtime (which will be run on the target) are
built by a single build process.
The build process of certain compilers is written in such a way that the compiler resulting from a single build can itself only produce binaries for a single platform. The task of specifying this single "target platform" is thus pushed to build time of the compiler. The root cause of this is that the compiler (which will be run on the host) and the standard library/runtime (which will be run on the target) are built by a single build process.
</para>
<para>
There is no fundamental need to think about a single target ahead of
time like this. If the tool supports modular or pluggable backends, both
the need to specify the target at build time and the constraint of
having only a single target disappear. An example of such a tool is
LLVM.
There is no fundamental need to think about a single target ahead of time like this. If the tool supports modular or pluggable backends, both the need to specify the target at build time and the constraint of having only a single target disappear. An example of such a tool is LLVM.
</para>
<para>
Although the existence of a "target platfom" is arguably a historical
mistake, it is a common one: examples of tools that suffer from it are
GCC, Binutils, GHC and Autoconf. Nixpkgs tries to avoid sharing in the
mistake where possible. Still, because the concept of a target platform
is so ingrained, it is best to support it as is.
Although the existence of a "target platfom" is arguably a historical mistake, it is a common one: examples of tools that suffer from it are GCC, Binutils, GHC and Autoconf. Nixpkgs tries to avoid sharing in the mistake where possible. Still, because the concept of a target platform is so ingrained, it is best to support it as is.
</para>
</listitem>
</varlistentry>
</variablelist>
<para>
The exact schema these fields follow is a bit ill-defined due to a long and
convoluted evolution, but this is slowly being cleaned up. You can see
examples of ones used in practice in
<literal>lib.systems.examples</literal>; note how they are not all very
consistent. For now, here are few fields can count on them containing:
The exact schema these fields follow is a bit ill-defined due to a long and convoluted evolution, but this is slowly being cleaned up. You can see examples of ones used in practice in <literal>lib.systems.examples</literal>; note how they are not all very consistent. For now, here are few fields can count on them containing:
</para>
<variablelist>
@ -133,11 +84,7 @@
</term>
<listitem>
<para>
This is a two-component shorthand for the platform. Examples of this
would be "x86_64-darwin" and "i686-linux"; see
<literal>lib.systems.doubles</literal> for more. This format isn't very
standard, but has built-in support in Nix, such as the
<varname>builtins.currentSystem</varname> impure string.
This is a two-component shorthand for the platform. Examples of this would be "x86_64-darwin" and "i686-linux"; see <literal>lib.systems.doubles</literal> for more. The first component corresponds to the CPU architecture of the platform and the second to the operating system of the platform (<literal>[cpu]-[os]</literal>). This format has built-in support in Nix, such as the <varname>builtins.currentSystem</varname> impure string.
</para>
</listitem>
</varlistentry>
@ -147,14 +94,7 @@
</term>
<listitem>
<para>
This is a 3- or 4- component shorthand for the platform. Examples of
this would be "x86_64-unknown-linux-gnu" and "aarch64-apple-darwin14".
This is a standard format called the "LLVM target triple", as they are
pioneered by LLVM and traditionally just used for the
<varname>targetPlatform</varname>. This format is strictly more
informative than the "Nix host double", as the previous format could
analogously be termed. This needs a better name than
<varname>config</varname>!
This is a 3- or 4- component shorthand for the platform. Examples of this would be <literal>x86_64-unknown-linux-gnu</literal> and <literal>aarch64-apple-darwin14</literal>. This is a standard format called the "LLVM target triple", as they are pioneered by LLVM. In the 4-part form, this corresponds to <literal>[cpu]-[vendor]-[os]-[abi]</literal>. This format is strictly more informative than the "Nix host double", as the previous format could analogously be termed. This needs a better name than <varname>config</varname>!
</para>
</listitem>
</varlistentry>
@ -164,12 +104,7 @@
</term>
<listitem>
<para>
This is a nix representation of a parsed LLVM target triple with
white-listed components. This can be specified directly, or actually
parsed from the <varname>config</varname>. [Technically, only one need
be specified and the others can be inferred, though the precision of
inference may not be very good.] See
<literal>lib.systems.parse</literal> for the exact representation.
This is a Nix representation of a parsed LLVM target triple with white-listed components. This can be specified directly, or actually parsed from the <varname>config</varname>. See <literal>lib.systems.parse</literal> for the exact representation.
</para>
</listitem>
</varlistentry>
@ -179,10 +114,7 @@
</term>
<listitem>
<para>
This is a string identifying the standard C library used. Valid
identifiers include "glibc" for GNU libc, "libSystem" for Darwin's
Libsystem, and "uclibc" for µClibc. It should probably be refactored to
use the module system, like <varname>parse</varname>.
This is a string identifying the standard C library used. Valid identifiers include "glibc" for GNU libc, "libSystem" for Darwin's Libsystem, and "uclibc" for µClibc. It should probably be refactored to use the module system, like <varname>parse</varname>.
</para>
</listitem>
</varlistentry>
@ -192,10 +124,7 @@
</term>
<listitem>
<para>
These predicates are defined in <literal>lib.systems.inspect</literal>,
and slapped on every platform. They are superior to the ones in
<varname>stdenv</varname> as they force the user to be explicit about
which platform they are inspecting. Please use these instead of those.
These predicates are defined in <literal>lib.systems.inspect</literal>, and slapped onto every platform. They are superior to the ones in <varname>stdenv</varname> as they force the user to be explicit about which platform they are inspecting. Please use these instead of those.
</para>
</listitem>
</varlistentry>
@ -205,120 +134,99 @@
</term>
<listitem>
<para>
This is, quite frankly, a dumping ground of ad-hoc settings (it's an
attribute set). See <literal>lib.systems.platforms</literal> for
examples—there's hopefully one in there that will work verbatim for
each platform that is working. Please help us triage these flags and
give them better homes!
This is, quite frankly, a dumping ground of ad-hoc settings (it's an attribute set). See <literal>lib.systems.platforms</literal> for examples—there's hopefully one in there that will work verbatim for each platform that is working. Please help us triage these flags and give them better homes!
</para>
</listitem>
</varlistentry>
</variablelist>
</section>
<section xml:id="sec-cross-specifying-dependencies">
<title>Specifying Dependencies</title>
<para>
In this section we explore the relationship between both runtime and
buildtime dependencies and the 3 Autoconf platforms.
</para>
<para>
A runtime dependency between 2 packages implies that between them both the
host and target platforms match. This is directly implied by the meaning of
"host platform" and "runtime dependency": The package dependency exists
while both packages are running on a single host platform.
</para>
<para>
A build time dependency, however, implies a shift in platforms between the
depending package and the depended-on package. The meaning of a build time
dependency is that to build the depending package we need to be able to run
the depended-on's package. The depending package's build platform is
therefore equal to the depended-on package's host platform. Analogously,
the depending package's host platform is equal to the depended-on package's
target platform.
</para>
<para>
In this manner, given the 3 platforms for one package, we can determine the
three platforms for all its transitive dependencies. This is the most
important guiding principle behind cross-compilation with Nixpkgs, and will
be called the <wordasword>sliding window principle</wordasword>.
</para>
<para>
Some examples will probably make this clearer. If a package is being built
with a <literal>(build, host, target)</literal> platform triple of
<literal>(foo, bar, bar)</literal>, then its build-time dependencies would
have a triple of <literal>(foo, foo, bar)</literal>, and <emphasis>those
packages'</emphasis> build-time dependencies would have triple of
<literal>(foo, foo, foo)</literal>. In other words, it should take two
"rounds" of following build-time dependency edges before one reaches a
fixed point where, by the sliding window principle, the platform triple no
longer changes. Indeed, this happens with cross compilation, where only
rounds of native dependencies starting with the second necessarily coincide
with native packages.
</para>
<section xml:id="ssec-cross-dependency-categorization">
<title>Theory of dependency categorization</title>
<note>
<para>
The depending package's target platform is unconstrained by the sliding
window principle, which makes sense in that one can in principle build
cross compilers targeting arbitrary platforms.
This is a rather philosophical description that isn't very Nixpkgs-specific. For an overview of all the relevant attributes given to <varname>mkDerivation</varname>, see <xref
linkend="ssec-stdenv-dependencies"/>. For a description of how everything is implemented, see <xref linkend="ssec-cross-dependency-implementation" />.
</para>
</note>
<para>
How does this work in practice? Nixpkgs is now structured so that
build-time dependencies are taken from <varname>buildPackages</varname>,
whereas run-time dependencies are taken from the top level attribute set.
For example, <varname>buildPackages.gcc</varname> should be used at build
time, while <varname>gcc</varname> should be used at run time. Now, for
most of Nixpkgs's history, there was no <varname>buildPackages</varname>,
and most packages have not been refactored to use it explicitly. Instead,
one can use the six (<emphasis>gasp</emphasis>) attributes used for
specifying dependencies as documented in
<xref linkend="ssec-stdenv-dependencies"/>. We "splice" together the
run-time and build-time package sets with <varname>callPackage</varname>,
and then <varname>mkDerivation</varname> for each of four attributes pulls
the right derivation out. This splicing can be skipped when not cross
compiling as the package sets are the same, but is a bit slow for cross
compiling. Because of this, a best-of-both-worlds solution is in the works
with no splicing or explicit access of <varname>buildPackages</varname>
needed. For now, feel free to use either method.
In this section we explore the relationship between both runtime and build-time dependencies and the 3 Autoconf platforms.
</para>
<note>
<para>
There is also a "backlink" <varname>targetPackages</varname>, yielding a
package set whose <varname>buildPackages</varname> is the current package
set. This is a hack, though, to accommodate compilers with lousy build
systems. Please do not use this unless you are absolutely sure you are
packaging such a compiler and there is no other way.
</para>
</note>
<para>
A run time dependency between two packages requires that their host platforms match. This is directly implied by the meaning of "host platform" and "runtime dependency": The package dependency exists while both packages are running on a single host platform.
</para>
<para>
A build time dependency, however, has a shift in platforms between the depending package and the depended-on package. "build time dependency" means that to build the depending package we need to be able to run the depended-on's package. The depending package's build platform is therefore equal to the depended-on package's host platform.
</para>
<para>
If both the dependency and depending packages aren't compilers or other machine-code-producing tools, we're done. And indeed <varname>buildInputs</varname> and <varname>nativeBuildInputs</varname> have covered these simpler build-time and run-time (respectively) changes for many years. But if the dependency does produce machine code, we might need to worry about its target platform too. In principle, that target platform might be any of the depending package's build, host, or target platforms, but we prohibit dependencies from a "later" platform to an earlier platform to limit confusion because we've never seen a legitimate use for them.
</para>
<para>
Finally, if the depending package is a compiler or other machine-code-producing tool, it might need dependencies that run at "emit time". This is for compilers that (regrettably) insist on being built together with their source langauges' standard libraries. Assuming build != host != target, a run-time dependency of the standard library cannot be run at the compiler's build time or run time, but only at the run time of code emitted by the compiler.
</para>
<para>
Putting this all together, that means we have dependencies in the form "host → target", in at most the following six combinations:
<table>
<caption>Possible dependency types</caption>
<thead>
<tr>
<th>Dependency's host platform</th>
<th>Dependency's target platform</th>
</tr>
</thead>
<tbody>
<tr>
<td>build</td>
<td>build</td>
</tr>
<tr>
<td>build</td>
<td>host</td>
</tr>
<tr>
<td>build</td>
<td>target</td>
</tr>
<tr>
<td>host</td>
<td>host</td>
</tr>
<tr>
<td>host</td>
<td>target</td>
</tr>
<tr>
<td>target</td>
<td>target</td>
</tr>
</tbody>
</table>
</para>
<para>
Some examples will make this table clearer. Suppose there's some package that is being built with a <literal>(build, host, target)</literal> platform triple of <literal>(foo, bar, baz)</literal>. If it has a build-time library dependency, that would be a "host → build" dependency with a triple of <literal>(foo, foo, *)</literal> (the target platform is irrelevant). If it needs a compiler to be built, that would be a "build → host" dependency with a triple of <literal>(foo, foo, *)</literal> (the target platform is irrelevant). That compiler, would be built with another compiler, also "build → host" dependency, with a triple of <literal>(foo, foo, foo)</literal>.
</para>
</section>
<section xml:id="sec-cross-cookbook">
<section xml:id="ssec-cross-cookbook">
<title>Cross packaging cookbook</title>
<para>
Some frequently problems when packaging for cross compilation are good to
just spell and answer. Ideally the information above is exhaustive, so this
section cannot provide any new information, but its ludicrous and cruel to
expect everyone to spend effort working through the interaction of many
features just to figure out the same answer to the same common problem.
Feel free to add to this list!
Some frequently encountered problems when packaging for cross-compilation should be answered here. Ideally, the information above is exhaustive, so this section cannot provide any new information, but it is ludicrous and cruel to expect everyone to spend effort working through the interaction of many features just to figure out the same answer to the same common problem. Feel free to add to this list!
</para>
<qandaset>
<qandaentry xml:id="cross-qa-build-c-program-in-build-environment">
<question>
<para>
What if my package's build system needs to build a C program to be run
under the build environment?
What if my package's build system needs to build a C program to be run under the build environment?
</para>
</question>
<answer>
@ -336,11 +244,7 @@
</question>
<answer>
<para>
Many packages assume that an unprefixed <command>ar</command> is
available, but Nix doesn't provide one. It only provides a prefixed one,
just as it only does for all the other binutils programs. It may be
necessary to patch the package to fix the build system to use a prefixed
`ar`.
Many packages assume that an unprefixed <command>ar</command> is available, but Nix doesn't provide one. It only provides a prefixed one, just as it only does for all the other binutils programs. It may be necessary to patch the package to fix the build system to use a prefixed `ar`.
</para>
</answer>
</qandaentry>
@ -364,112 +268,127 @@
<section xml:id="sec-cross-usage">
<title>Cross-building packages</title>
<note>
<para>
More information needs to moved from the old wiki, especially
<link xlink:href="https://nixos.org/wiki/CrossCompiling" />, for this
section.
</para>
</note>
<para>
Nixpkgs can be instantiated with <varname>localSystem</varname> alone, in
which case there is no cross compiling and everything is built by and for
that system, or also with <varname>crossSystem</varname>, in which case
packages run on the latter, but all building happens on the former. Both
parameters take the same schema as the 3 (build, host, and target) platforms
defined in the previous section. As mentioned above,
<literal>lib.systems.examples</literal> has some platforms which are used as
arguments for these parameters in practice. You can use them
programmatically, or on the command line:
Nixpkgs can be instantiated with <varname>localSystem</varname> alone, in which case there is no cross-compiling and everything is built by and for that system, or also with <varname>crossSystem</varname>, in which case packages run on the latter, but all building happens on the former. Both parameters take the same schema as the 3 (build, host, and target) platforms defined in the previous section. As mentioned above, <literal>lib.systems.examples</literal> has some platforms which are used as arguments for these parameters in practice. You can use them programmatically, or on the command line:
<programlisting>
nix-build &lt;nixpkgs&gt; --arg crossSystem '(import &lt;nixpkgs/lib&gt;).systems.examples.fooBarBaz' -A whatever</programlisting>
nix-build '&lt;nixpkgs&gt;' --arg crossSystem '(import &lt;nixpkgs/lib&gt;).systems.examples.fooBarBaz' -A whatever</programlisting>
</para>
<note>
<para>
Eventually we would like to make these platform examples an unnecessary
convenience so that
Eventually we would like to make these platform examples an unnecessary convenience so that
<programlisting>
nix-build &lt;nixpkgs&gt; --arg crossSystem.config '&lt;arch&gt;-&lt;os&gt;-&lt;vendor&gt;-&lt;abi&gt;' -A whatever</programlisting>
works in the vast majority of cases. The problem today is dependencies on
other sorts of configuration which aren't given proper defaults. We rely on
the examples to crudely to set those configuration parameters in some
vaguely sane manner on the users behalf. Issue
<link xlink:href="https://github.com/NixOS/nixpkgs/issues/34274">#34274</link>
tracks this inconvenience along with its root cause in crufty configuration
options.
nix-build '&lt;nixpkgs&gt;' --arg crossSystem '{ config = "&lt;arch&gt;-&lt;os&gt;-&lt;vendor&gt;-&lt;abi&gt;"; }' -A whatever</programlisting>
works in the vast majority of cases. The problem today is dependencies on other sorts of configuration which aren't given proper defaults. We rely on the examples to crudely to set those configuration parameters in some vaguely sane manner on the users behalf. Issue <link xlink:href="https://github.com/NixOS/nixpkgs/issues/34274">#34274</link> tracks this inconvenience along with its root cause in crufty configuration options.
</para>
</note>
<para>
While one is free to pass both parameters in full, there's a lot of logic to
fill in missing fields. As discussed in the previous section, only one of
<varname>system</varname>, <varname>config</varname>, and
<varname>parsed</varname> is needed to infer the other two. Additionally,
<varname>libc</varname> will be inferred from <varname>parse</varname>.
Finally, <literal>localSystem.system</literal> is also
<emphasis>impurely</emphasis> inferred based on the platform evaluation
occurs. This means it is often not necessary to pass
<varname>localSystem</varname> at all, as in the command-line example in the
previous paragraph.
While one is free to pass both parameters in full, there's a lot of logic to fill in missing fields. As discussed in the previous section, only one of <varname>system</varname>, <varname>config</varname>, and <varname>parsed</varname> is needed to infer the other two. Additionally, <varname>libc</varname> will be inferred from <varname>parse</varname>. Finally, <literal>localSystem.system</literal> is also <emphasis>impurely</emphasis> inferred based on the platform evaluation occurs. This means it is often not necessary to pass <varname>localSystem</varname> at all, as in the command-line example in the previous paragraph.
</para>
<note>
<para>
Many sources (manual, wiki, etc) probably mention passing
<varname>system</varname>, <varname>platform</varname>, along with the
optional <varname>crossSystem</varname> to nixpkgs: <literal>import
&lt;nixpkgs&gt; { system = ..; platform = ..; crossSystem = ..;
}</literal>. Passing those two instead of <varname>localSystem</varname> is
still supported for compatibility, but is discouraged. Indeed, much of the
inference we do for these parameters is motivated by compatibility as much
as convenience.
Many sources (manual, wiki, etc) probably mention passing <varname>system</varname>, <varname>platform</varname>, along with the optional <varname>crossSystem</varname> to nixpkgs: <literal>import &lt;nixpkgs&gt; { system = ..; platform = ..; crossSystem = ..; }</literal>. Passing those two instead of <varname>localSystem</varname> is still supported for compatibility, but is discouraged. Indeed, much of the inference we do for these parameters is motivated by compatibility as much as convenience.
</para>
</note>
<para>
One would think that <varname>localSystem</varname> and
<varname>crossSystem</varname> overlap horribly with the three
<varname>*Platforms</varname> (<varname>buildPlatform</varname>,
<varname>hostPlatform,</varname> and <varname>targetPlatform</varname>; see
<varname>stage.nix</varname> or the manual). Actually, those identifiers are
purposefully not used here to draw a subtle but important distinction: While
the granularity of having 3 platforms is necessary to properly *build*
packages, it is overkill for specifying the user's *intent* when making a
build plan or package set. A simple "build vs deploy" dichotomy is adequate:
the sliding window principle described in the previous section shows how to
interpolate between the these two "end points" to get the 3 platform triple
for each bootstrapping stage. That means for any package a given package
set, even those not bound on the top level but only reachable via
dependencies or <varname>buildPackages</varname>, the three platforms will
be defined as one of <varname>localSystem</varname> or
<varname>crossSystem</varname>, with the former replacing the latter as one
traverses build-time dependencies. A last simple difference then is
<varname>crossSystem</varname> should be null when one doesn't want to
cross-compile, while the <varname>*Platform</varname>s are always non-null.
<varname>localSystem</varname> is always non-null.
One would think that <varname>localSystem</varname> and <varname>crossSystem</varname> overlap horribly with the three <varname>*Platforms</varname> (<varname>buildPlatform</varname>, <varname>hostPlatform,</varname> and <varname>targetPlatform</varname>; see <varname>stage.nix</varname> or the manual). Actually, those identifiers are purposefully not used here to draw a subtle but important distinction: While the granularity of having 3 platforms is necessary to properly *build* packages, it is overkill for specifying the user's *intent* when making a build plan or package set. A simple "build vs deploy" dichotomy is adequate: the sliding window principle described in the previous section shows how to interpolate between the these two "end points" to get the 3 platform triple for each bootstrapping stage. That means for any package a given package set, even those not bound on the top level but only reachable via dependencies or <varname>buildPackages</varname>, the three platforms will be defined as one of <varname>localSystem</varname> or <varname>crossSystem</varname>, with the former replacing the latter as one traverses build-time dependencies. A last simple difference is that <varname>crossSystem</varname> should be null when one doesn't want to cross-compile, while the <varname>*Platform</varname>s are always non-null. <varname>localSystem</varname> is always non-null.
</para>
</section>
<!--============================================================-->
<section xml:id="sec-cross-infra">
<title>Cross-compilation infrastructure</title>
<para>
To be written.
</para>
<section xml:id="ssec-cross-dependency-implementation">
<title>Implementation of dependencies</title>
<note>
<para>
If one explores nixpkgs, they will see derivations with names like
<literal>gccCross</literal>. Such <literal>*Cross</literal> derivations is
a holdover from before we properly distinguished between the host and
target platforms —the derivation with "Cross" in the name covered the
<literal>build = host != target</literal> case, while the other covered the
<literal>host = target</literal>, with build platform the same or not based
on whether one was using its <literal>.nativeDrv</literal> or
<literal>.crossDrv</literal>. This ugliness will disappear soon.
The categorizes of dependencies developed in <xref
linkend="ssec-cross-dependency-categorization"/> are specified as lists of derivations given to <varname>mkDerivation</varname>, as documented in <xref linkend="ssec-stdenv-dependencies"/>. In short, each list of dependencies for "host → target" of "foo → bar" is called <varname>depsFooBar</varname>, with exceptions for backwards compatibility that <varname>depsBuildHost</varname> is instead called <varname>nativeBuildInputs</varname> and <varname>depsHostTarget</varname> is instead called <varname>buildInputs</varname>. Nixpkgs is now structured so that each <varname>depsFooBar</varname> is automatically taken from <varname>pkgsFooBar</varname>. (These <varname>pkgsFooBar</varname>s are quite new, so there is no special case for <varname>nativeBuildInputs</varname> and <varname>buildInputs</varname>.) For example, <varname>pkgsBuildHost.gcc</varname> should be used at build-time, while <varname>pkgsHostTarget.gcc</varname> should be used at run-time.
</para>
</note>
<para>
Now, for most of Nixpkgs's history, there were no <varname>pkgsFooBar</varname> attributes, and most packages have not been refactored to use it explicitly. Prior to those, there were just <varname>buildPackages</varname>, <varname>pkgs</varname>, and <varname>targetPackages</varname>. Those are now redefined as aliases to <varname>pkgsBuildHost</varname>, <varname>pkgsHostTarget</varname>, and <varname>pkgsTargetTarget</varname>. It is acceptable, even recommended, to use them for libraries to show that the host platform is irrelevant.
</para>
<para>
But before that, there was just <varname>pkgs</varname>, even though both <varname>buildInputs</varname> and <varname>nativeBuildInputs</varname> existed. [Cross barely worked, and those were implemented with some hacks on <varname>mkDerivation</varname> to override dependencies.] What this means is the vast majority of packages do not use any explicit package set to populate their dependencies, just using whatever <varname>callPackage</varname> gives them even if they do correctly sort their dependencies into the multiple lists described above. And indeed, asking that users both sort their dependencies, <emphasis>and</emphasis> take them from the right attribute set, is both too onerous and redundant, so the recommended approach (for now) is to continue just categorizing by list and not using an explicit package set.
</para>
<para>
To make this work, we "splice" together the six <varname>pkgsFooBar</varname> package sets and have <varname>callPackage</varname> actually take its arguments from that. This is currently implemented in <filename>pkgs/top-level/splice.nix</filename>. <varname>mkDerivation</varname> then, for each dependency attribute, pulls the right derivation out from the splice. This splicing can be skipped when not cross-compiling as the package sets are the same, but still is a bit slow for cross-compiling. We'd like to do something better, but haven't come up with anything yet.
</para>
</section>
<section xml:id="ssec-bootstrapping">
<title>Bootstrapping</title>
<para>
Each of the package sets described above come from a single bootstrapping stage. While <filename>pkgs/top-level/default.nix</filename>, coordinates the composition of stages at a high level, <filename>pkgs/top-level/stage.nix</filename> "ties the knot" (creates the fixed point) of each stage. The package sets are defined per-stage however, so they can be thought of as edges between stages (the nodes) in a graph. Compositions like <literal>pkgsBuildTarget.targetPackages</literal> can be thought of as paths to this graph.
</para>
<para>
While there are many package sets, and thus many edges, the stages can also be arranged in a linear chain. In other words, many of the edges are redundant as far as connectivity is concerned. This hinges on the type of bootstrapping we do. Currently for cross it is:
<orderedlist>
<listitem>
<para>
<literal>(native, native, native)</literal>
</para>
</listitem>
<listitem>
<para>
<literal>(native, native, foreign)</literal>
</para>
</listitem>
<listitem>
<para>
<literal>(native, foreign, foreign)</literal>
</para>
</listitem>
</orderedlist>
In each stage, <varname>pkgsBuildHost</varname> refers the the previous stage, <varname>pkgsBuildBuild</varname> refers to the one before that, and <varname>pkgsHostTarget</varname> refers to the current one, and <varname>pkgsTargetTarget</varname> refers to the next one. When there is no previous or next stage, they instead refer to the current stage. Note how all the invariants regarding the mapping between dependency and depending packages' build host and target platforms are preserved. <varname>pkgsBuildTarget</varname> and <varname>pkgsHostHost</varname> are more complex in that the stage fitting the requirements isn't always a fixed chain of "prevs" and "nexts" away (modulo the "saturating" self-references at the ends). We just special case each instead. All the primary edges are implemented is in <filename>pkgs/stdenv/booter.nix</filename>, and secondarily aliases in <filename>pkgs/top-level/stage.nix</filename>.
</para>
<note>
<para>
Note the native stages are bootstrapped in legacy ways that predate the current cross implementation. This is why the the bootstrapping stages leading up to the final stages are ignored inthe previous paragraph.
</para>
</note>
<para>
If one looks at the 3 platform triples, one can see that they overlap such that one could put them together into a chain like:
<programlisting>
(native, native, native, foreign, foreign)
</programlisting>
If one imagines the saturating self references at the end being replaced with infinite stages, and then overlays those platform triples, one ends up with the infinite tuple:
<programlisting>
(native..., native, native, native, foreign, foreign, foreign...)
</programlisting>
On can then imagine any sequence of platforms such that there are bootstrap stages with their 3 platforms determined by "sliding a window" that is the 3 tuple through the sequence. This was the original model for bootstrapping. Without a target platform (assume a better world where all compilers are multi-target and all standard libraries are built in their own derivation), this is sufficient. Conversely if one wishes to cross compile "faster", with a "Canadian Cross" bootstraping stage where <literal>build != host != target</literal>, more bootstrapping stages are needed since no sliding window providess the pesky <varname>pkgsBuildTarget</varname> package set since it skips the Canadian cross stage's "host".
</para>
<note>
<para>
It is much better to refer to <varname>buildPackages</varname> than <varname>targetPackages</varname>, or more broadly package sets that do not mention "target". There are three reasons for this.
</para>
<para>
First, it is because bootstrapping stages do not have a unique <varname>targetPackages</varname>. For example a <literal>(x86-linux, x86-linux, arm-linux)</literal> and <literal>(x86-linux, x86-linux, x86-windows)</literal> package set both have a <literal>(x86-linux, x86-linux, x86-linux)</literal> package set. Because there is no canonical <varname>targetPackages</varname> for such a native (<literal>build == host == target</literal>) package set, we set their <varname>targetPackages</varname>
</para>
<para>
Second, it is because this is a frequent source of hard-to-follow "infinite recursions" / cycles. When only package sets that don't mention target are used, the package set forms a directed acyclic graph. This means that all cycles that exist are confined to one stage. This means they are a lot smaller, and easier to follow in the code or a backtrace. It also means they are present in native and cross builds alike, and so more likely to be caught by CI and other users.
</para>
<para>
Thirdly, it is because everything target-mentioning only exists to accommodate compilers with lousy build systems that insist on the compiler itself and standard library being built together. Of course that is bad because bigger derivations means longer rebuilds. It is also problematic because it tends to make the standard libraries less like other libraries than they could be, complicating code and build systems alike. Because of the other problems, and because of these innate disadvantages, compilers ought to be packaged another way where possible.
</para>
</note>
<note>
<para>
If one explores Nixpkgs, they will see derivations with names like <literal>gccCross</literal>. Such <literal>*Cross</literal> derivations is a holdover from before we properly distinguished between the host and target platforms—the derivation with "Cross" in the name covered the <literal>build = host != target</literal> case, while the other covered the <literal>host = target</literal>, with build platform the same or not based on whether one was using its <literal>.nativeDrv</literal> or <literal>.crossDrv</literal>. This ugliness will disappear soon.
</para>
</note>
</section>
</section>
</chapter>

28
doc/default.nix
View File

@ -1,38 +1,16 @@
{ pkgs ? (import ./.. { }), nixpkgs ? { }}:
let
lib = pkgs.lib;
locationsXml = import ./lib-function-locations.nix { inherit pkgs nixpkgs; };
in
pkgs.stdenv.mkDerivation {
doc-support = import ./doc-support { inherit pkgs nixpkgs; };
in pkgs.stdenv.mkDerivation {
name = "nixpkgs-manual";
buildInputs = with pkgs; [ pandoc libxml2 libxslt zip jing xmlformat ];
src = ./.;
# Hacking on these variables? Make sure to close and open
# nix-shell between each test, maybe even:
# $ nix-shell --run "make clean all"
# otherwise they won't reapply :)
HIGHLIGHTJS = pkgs.documentation-highlighter;
XSL = "${pkgs.docbook_xsl_ns}/xml/xsl";
RNG = "${pkgs.docbook5}/xml/rng/docbook/docbook.rng";
XMLFORMAT_CONFIG = ../nixos/doc/xmlformat.conf;
xsltFlags = lib.concatStringsSep " " [
"--param section.autolabel 1"
"--param section.label.includes.component.label 1"
"--stringparam html.stylesheet 'style.css overrides.css highlightjs/mono-blue.css'"
"--stringparam html.script './highlightjs/highlight.pack.js ./highlightjs/loader.js'"
"--param xref.with.number.and.title 1"
"--param toc.section.depth 3"
"--stringparam admon.style ''"
"--stringparam callout.graphics.extension .svg"
];
postPatch = ''
rm -rf ./functions/library/locations.xml
ln -s ${locationsXml} ./functions/library/locations.xml
echo ${lib.version} > .version
ln -s ${doc-support} ./doc-support/result
'';
installPhase = ''

45
doc/doc-support/default.nix Normal file
View File

@ -0,0 +1,45 @@
{ pkgs ? (import ../.. {}), nixpkgs ? { }}:
let
locationsXml = import ./lib-function-locations.nix { inherit pkgs nixpkgs; };
functionDocs = import ./lib-function-docs.nix { inherit locationsXml pkgs; };
version = pkgs.lib.version;
epub-xsl = pkgs.writeText "epub.xsl" ''
<?xml version='1.0'?>
<xsl:stylesheet
xmlns:xsl="http://www.w3.org/1999/XSL/Transform"
version="1.0">
<xsl:import href="${pkgs.docbook_xsl_ns}/xml/xsl/docbook/epub/docbook.xsl" />
<xsl:import href="${./parameters.xml}"/>
</xsl:stylesheet>
'';
xhtml-xsl = pkgs.writeText "xhtml.xsl" ''
<?xml version='1.0'?>
<xsl:stylesheet
xmlns:xsl="http://www.w3.org/1999/XSL/Transform"
version="1.0">
<xsl:import href="${pkgs.docbook_xsl_ns}/xml/xsl/docbook/xhtml/docbook.xsl" />
<xsl:import href="${./parameters.xml}"/>
</xsl:stylesheet>
'';
in pkgs.runCommand "doc-support" {}
''
mkdir result
(
cd result
ln -s ${locationsXml} ./function-locations.xml
ln -s ${functionDocs} ./function-docs
ln -s ${pkgs.docbook5}/xml/rng/docbook/docbook.rng ./docbook.rng
ln -s ${pkgs.docbook_xsl_ns}/xml/xsl ./xsl
ln -s ${epub-xsl} ./epub.xsl
ln -s ${xhtml-xsl} ./xhtml.xsl
ln -s ${../../nixos/doc/xmlformat.conf} ./xmlformat.conf
ln -s ${pkgs.documentation-highlighter} ./highlightjs
echo -n "${version}" > ./version
)
mv result $out
''

26
doc/doc-support/lib-function-docs.nix Normal file
View File

@ -0,0 +1,26 @@
# Generates the documentation for library functons via nixdoc. To add
# another library function file to this list, the include list in the
# file `doc/functions/library.xml` must also be updated.
{ pkgs ? import ./.. {}, locationsXml }:
with pkgs; stdenv.mkDerivation {
name = "nixpkgs-lib-docs";
src = ./../../lib;
buildInputs = [ nixdoc ];
installPhase = ''
function docgen {
nixdoc -c "$1" -d "$2" -f "../lib/$1.nix" > "$out/$1.xml"
}
mkdir -p $out
ln -s ${locationsXml} $out/locations.xml
docgen strings 'String manipulation functions'
docgen trivial 'Miscellaneous functions'
docgen lists 'List manipulation functions'
docgen debug 'Debugging functions'
docgen options 'NixOS / nixpkgs option handling'
'';
}

4
doc/lib-function-locations.nix → doc/doc-support/lib-function-locations.nix
View File

@ -14,10 +14,10 @@ let
builtins.map
(subsetname: {
subsetname = subsetname;
functions = libDefPos toplib."${subsetname}";
functions = libDefPos toplib.${subsetname};
})
(builtins.filter
(name: builtins.isAttrs toplib."${name}")
(name: builtins.isAttrs toplib.${name})
(builtins.attrNames toplib));
nixpkgsLib = pkgs.lib;

14
doc/doc-support/parameters.xml Normal file
View File

@ -0,0 +1,14 @@
<?xml version='1.0'?>
<xsl:stylesheet
xmlns:xsl="http://www.w3.org/1999/XSL/Transform"
version="1.0">
<xsl:param name="section.autolabel" select="1" />
<xsl:param name="section.label.includes.component.label" select="1" />
<xsl:param name="html.stylesheet" select="'style.css overrides.css highlightjs/mono-blue.css'" />
<xsl:param name="html.script" select="'./highlightjs/highlight.pack.js ./highlightjs/loader.js'" />
<xsl:param name="xref.with.number.and.title" select="1" />
<xsl:param name="use.id.as.filename" select="1" />
<xsl:param name="toc.section.depth" select="0" />
<xsl:param name="admon.style" select="''" />
<xsl:param name="callout.graphics.extension" select="'.svg'" />
</xsl:stylesheet>

9
doc/functions.xml
View File

@ -4,14 +4,11 @@
xml:id="chap-functions">
<title>Functions reference</title>
<para>
The nixpkgs repository has several utility functions to manipulate Nix
expressions.
The nixpkgs repository has several utility functions to manipulate Nix expressions.
</para>
<xi:include href="functions/library.xml" />
<xi:include href="functions/overrides.xml" />
<xi:include href="functions/generators.xml" />
<xi:include href="functions/debug.xml" />
<xi:include href="functions/fhs-environments.xml" />
<xi:include href="functions/shell.xml" />
<xi:include href="functions/dockertools.xml" />
<xi:include href="functions/prefer-remote-fetch.xml" />
<xi:include href="functions/nix-gitignore.xml" />
</chapter>

11
doc/functions/debug.xml
View File

@ -5,17 +5,10 @@
<title>Debugging Nix Expressions</title>
<para>
Nix is a unityped, dynamic language, this means every value can potentially
appear anywhere. Since it is also non-strict, evaluation order and what
ultimately is evaluated might surprise you. Therefore it is important to be
able to debug nix expressions.
Nix is a unityped, dynamic language, this means every value can potentially appear anywhere. Since it is also non-strict, evaluation order and what ultimately is evaluated might surprise you. Therefore it is important to be able to debug nix expressions.
</para>
<para>
In the <literal>lib/debug.nix</literal> file you will find a number of
functions that help (pretty-)printing values while evaluation is runnnig. You
can even specify how deep these values should be printed recursively, and
transform them on the fly. Please consult the docstrings in
<literal>lib/debug.nix</literal> for usage information.
In the <literal>lib/debug.nix</literal> file you will find a number of functions that help (pretty-)printing values while evaluation is runnnig. You can even specify how deep these values should be printed recursively, and transform them on the fly. Please consult the docstrings in <literal>lib/debug.nix</literal> for usage information.
</para>
</section>

564
doc/functions/dockertools.xml
View File

@ -1,564 +0,0 @@
<section xmlns="http://docbook.org/ns/docbook"
xmlns:xlink="http://www.w3.org/1999/xlink"
xmlns:xi="http://www.w3.org/2001/XInclude"
xml:id="sec-pkgs-dockerTools">
<title>pkgs.dockerTools</title>
<para>
<varname>pkgs.dockerTools</varname> is a set of functions for creating and
manipulating Docker images according to the
<link xlink:href="https://github.com/moby/moby/blob/master/image/spec/v1.2.md#docker-image-specification-v120">
Docker Image Specification v1.2.0 </link>. Docker itself is not used to
perform any of the operations done by these functions.
</para>
<warning>
<para>
The <varname>dockerTools</varname> API is unstable and may be subject to
backwards-incompatible changes in the future.
</para>
</warning>
<section xml:id="ssec-pkgs-dockerTools-buildImage">
<title>buildImage</title>
<para>
This function is analogous to the <command>docker build</command> command,
in that can used to build a Docker-compatible repository tarball containing
a single image with one or multiple layers. As such, the result is suitable
for being loaded in Docker with <command>docker load</command>.
</para>
<para>
The parameters of <varname>buildImage</varname> with relative example values
are described below:
</para>
<example xml:id='ex-dockerTools-buildImage'>
<title>Docker build</title>
<programlisting>
buildImage {
name = "redis"; <co xml:id='ex-dockerTools-buildImage-1' />
tag = "latest"; <co xml:id='ex-dockerTools-buildImage-2' />
fromImage = someBaseImage; <co xml:id='ex-dockerTools-buildImage-3' />
fromImageName = null; <co xml:id='ex-dockerTools-buildImage-4' />
fromImageTag = "latest"; <co xml:id='ex-dockerTools-buildImage-5' />
contents = pkgs.redis; <co xml:id='ex-dockerTools-buildImage-6' />
runAsRoot = '' <co xml:id='ex-dockerTools-buildImage-runAsRoot' />
#!${stdenv.shell}
mkdir -p /data
'';
config = { <co xml:id='ex-dockerTools-buildImage-8' />
Cmd = [ "/bin/redis-server" ];
WorkingDir = "/data";
Volumes = {
"/data" = {};
};
};
}
</programlisting>
</example>
<para>
The above example will build a Docker image <literal>redis/latest</literal>
from the given base image. Loading and running this image in Docker results
in <literal>redis-server</literal> being started automatically.
</para>
<calloutlist>
<callout arearefs='ex-dockerTools-buildImage-1'>
<para>
<varname>name</varname> specifies the name of the resulting image. This is
the only required argument for <varname>buildImage</varname>.
</para>
</callout>
<callout arearefs='ex-dockerTools-buildImage-2'>
<para>
<varname>tag</varname> specifies the tag of the resulting image. By
default it's <literal>null</literal>, which indicates that the nix output
hash will be used as tag.
</para>
</callout>
<callout arearefs='ex-dockerTools-buildImage-3'>
<para>
<varname>fromImage</varname> is the repository tarball containing the base
image. It must be a valid Docker image, such as exported by
<command>docker save</command>. By default it's <literal>null</literal>,
which can be seen as equivalent to <literal>FROM scratch</literal> of a
<filename>Dockerfile</filename>.
</para>
</callout>
<callout arearefs='ex-dockerTools-buildImage-4'>
<para>
<varname>fromImageName</varname> can be used to further specify the base
image within the repository, in case it contains multiple images. By
default it's <literal>null</literal>, in which case
<varname>buildImage</varname> will peek the first image available in the
repository.
</para>
</callout>
<callout arearefs='ex-dockerTools-buildImage-5'>
<para>
<varname>fromImageTag</varname> can be used to further specify the tag of
the base image within the repository, in case an image contains multiple
tags. By default it's <literal>null</literal>, in which case
<varname>buildImage</varname> will peek the first tag available for the
base image.
</para>
</callout>
<callout arearefs='ex-dockerTools-buildImage-6'>
<para>
<varname>contents</varname> is a derivation that will be copied in the new
layer of the resulting image. This can be similarly seen as <command>ADD
contents/ /</command> in a <filename>Dockerfile</filename>. By default
it's <literal>null</literal>.
</para>
</callout>
<callout arearefs='ex-dockerTools-buildImage-runAsRoot'>
<para>
<varname>runAsRoot</varname> is a bash script that will run as root in an
environment that overlays the existing layers of the base image with the
new resulting layer, including the previously copied
<varname>contents</varname> derivation. This can be similarly seen as
<command>RUN ...</command> in a <filename>Dockerfile</filename>.
<note>
<para>
Using this parameter requires the <literal>kvm</literal> device to be
available.
</para>
</note>
</para>
</callout>
<callout arearefs='ex-dockerTools-buildImage-8'>
<para>
<varname>config</varname> is used to specify the configuration of the
containers that will be started off the built image in Docker. The
available options are listed in the
<link xlink:href="https://github.com/moby/moby/blob/master/image/spec/v1.2.md#image-json-field-descriptions">
Docker Image Specification v1.2.0 </link>.
</para>
</callout>
</calloutlist>
<para>
After the new layer has been created, its closure (to which
<varname>contents</varname>, <varname>config</varname> and
<varname>runAsRoot</varname> contribute) will be copied in the layer itself.
Only new dependencies that are not already in the existing layers will be
copied.
</para>
<para>
At the end of the process, only one new single layer will be produced and
added to the resulting image.
</para>
<para>
The resulting repository will only list the single image
<varname>image/tag</varname>. In the case of
<xref linkend='ex-dockerTools-buildImage'/> it would be
<varname>redis/latest</varname>.
</para>
<para>
It is possible to inspect the arguments with which an image was built using
its <varname>buildArgs</varname> attribute.
</para>
<note>
<para>
If you see errors similar to <literal>getProtocolByName: does not exist (no
such protocol name: tcp)</literal> you may need to add
<literal>pkgs.iana-etc</literal> to <varname>contents</varname>.
</para>
</note>
<note>
<para>
If you see errors similar to <literal>Error_Protocol ("certificate has
unknown CA",True,UnknownCa)</literal> you may need to add
<literal>pkgs.cacert</literal> to <varname>contents</varname>.
</para>
</note>
<example xml:id="example-pkgs-dockerTools-buildImage-creation-date">
<title>Impurely Defining a Docker Layer's Creation Date</title>
<para>
By default <function>buildImage</function> will use a static date of one
second past the UNIX Epoch. This allows <function>buildImage</function> to
produce binary reproducible images. When listing images with
<command>docker list images</command>, the newly created images will be
listed like this:
</para>
<screen><![CDATA[
$ docker image list
REPOSITORY TAG IMAGE ID CREATED SIZE
hello latest 08c791c7846e 48 years ago 25.2MB
]]></screen>
<para>
You can break binary reproducibility but have a sorted, meaningful
<literal>CREATED</literal> column by setting <literal>created</literal> to
<literal>now</literal>.
</para>
<programlisting><![CDATA[
pkgs.dockerTools.buildImage {
name = "hello";
tag = "latest";
created = "now";
contents = pkgs.hello;
config.Cmd = [ "/bin/hello" ];
}
]]></programlisting>
<para>
and now the Docker CLI will display a reasonable date and sort the images
as expected:
<screen><![CDATA[
$ docker image list
REPOSITORY TAG IMAGE ID CREATED SIZE
hello latest de2bf4786de6 About a minute ago 25.2MB
]]></screen>
however, the produced images will not be binary reproducible.
</para>
</example>
</section>
<section xml:id="ssec-pkgs-dockerTools-buildLayeredImage">
<title>buildLayeredImage</title>
<para>
Create a Docker image with many of the store paths being on their own layer
to improve sharing between images.
</para>
<variablelist>
<varlistentry>
<term>
<varname>name</varname>
</term>
<listitem>
<para>
The name of the resulting image.
</para>
</listitem>
</varlistentry>
<varlistentry>
<term>
<varname>tag</varname> <emphasis>optional</emphasis>
</term>
<listitem>
<para>
Tag of the generated image.
</para>
<para>
<emphasis>Default:</emphasis> the output path's hash
</para>
</listitem>
</varlistentry>
<varlistentry>
<term>
<varname>contents</varname> <emphasis>optional</emphasis>
</term>
<listitem>
<para>
Top level paths in the container. Either a single derivation, or a list
of derivations.
</para>
<para>
<emphasis>Default:</emphasis> <literal>[]</literal>
</para>
</listitem>
</varlistentry>
<varlistentry>
<term>
<varname>config</varname> <emphasis>optional</emphasis>
</term>
<listitem>
<para>
Run-time configuration of the container. A full list of the options are
available at in the
<link xlink:href="https://github.com/moby/moby/blob/master/image/spec/v1.2.md#image-json-field-descriptions">
Docker Image Specification v1.2.0 </link>.
</para>
<para>
<emphasis>Default:</emphasis> <literal>{}</literal>
</para>
</listitem>
</varlistentry>
<varlistentry>
<term>
<varname>created</varname> <emphasis>optional</emphasis>
</term>
<listitem>
<para>
Date and time the layers were created. Follows the same
<literal>now</literal> exception supported by
<literal>buildImage</literal>.
</para>
<para>
<emphasis>Default:</emphasis> <literal>1970-01-01T00:00:01Z</literal>
</para>
</listitem>
</varlistentry>
<varlistentry>
<term>
<varname>maxLayers</varname> <emphasis>optional</emphasis>
</term>
<listitem>
<para>
Maximum number of layers to create.
</para>
<para>
<emphasis>Default:</emphasis> <literal>24</literal>
</para>
</listitem>
</varlistentry>
</variablelist>
<section xml:id="dockerTools-buildLayeredImage-arg-contents">
<title>Behavior of <varname>contents</varname> in the final image</title>
<para>
Each path directly listed in <varname>contents</varname> will have a
symlink in the root of the image.
</para>
<para>
For example:
<programlisting><![CDATA[
pkgs.dockerTools.buildLayeredImage {
name = "hello";
contents = [ pkgs.hello ];
}
]]></programlisting>
will create symlinks for all the paths in the <literal>hello</literal>
package:
<screen><![CDATA[
/bin/hello -> /nix/store/h1zb1padqbbb7jicsvkmrym3r6snphxg-hello-2.10/bin/hello
/share/info/hello.info -> /nix/store/h1zb1padqbbb7jicsvkmrym3r6snphxg-hello-2.10/share/info/hello.info
/share/locale/bg/LC_MESSAGES/hello.mo -> /nix/store/h1zb1padqbbb7jicsvkmrym3r6snphxg-hello-2.10/share/locale/bg/LC_MESSAGES/hello.mo
]]></screen>
</para>
</section>
<section xml:id="dockerTools-buildLayeredImage-arg-config">
<title>Automatic inclusion of <varname>config</varname> references</title>
<para>
The closure of <varname>config</varname> is automatically included in the
closure of the final image.
</para>
<para>
This allows you to make very simple Docker images with very little code.
This container will start up and run <command>hello</command>:
<programlisting><![CDATA[
pkgs.dockerTools.buildLayeredImage {
name = "hello";
config.Cmd = [ "${pkgs.hello}/bin/hello" ];
}
]]></programlisting>
</para>
</section>
<section xml:id="dockerTools-buildLayeredImage-arg-maxLayers">
<title>Adjusting <varname>maxLayers</varname></title>
<para>
Increasing the <varname>maxLayers</varname> increases the number of layers
which have a chance to be shared between different images.
</para>
<para>
Modern Docker installations support up to 128 layers, however older
versions support as few as 42.
</para>
<para>
If the produced image will not be extended by other Docker builds, it is
safe to set <varname>maxLayers</varname> to <literal>128</literal>. However
it will be impossible to extend the image further.
</para>
<para>
The first (<literal>maxLayers-2</literal>) most "popular" paths will have
their own individual layers, then layer #<literal>maxLayers-1</literal>
will contain all the remaining "unpopular" paths, and finally layer
#<literal>maxLayers</literal> will contain the Image configuration.
</para>
<para>
Docker's Layers are not inherently ordered, they are content-addressable
and are not explicitly layered until they are composed in to an Image.
</para>
</section>
</section>
<section xml:id="ssec-pkgs-dockerTools-fetchFromRegistry">
<title>pullImage</title>
<para>
This function is analogous to the <command>docker pull</command> command, in
that can be used to pull a Docker image from a Docker registry. By default
<link xlink:href="https://hub.docker.com/">Docker Hub</link> is used to pull
images.
</para>
<para>
Its parameters are described in the example below:
</para>
<example xml:id='ex-dockerTools-pullImage'>
<title>Docker pull</title>
<programlisting>
pullImage {
imageName = "nixos/nix"; <co xml:id='ex-dockerTools-pullImage-1' />
imageDigest = "sha256:20d9485b25ecfd89204e843a962c1bd70e9cc6858d65d7f5fadc340246e2116b"; <co xml:id='ex-dockerTools-pullImage-2' />
finalImageTag = "1.11"; <co xml:id='ex-dockerTools-pullImage-3' />
sha256 = "0mqjy3zq2v6rrhizgb9nvhczl87lcfphq9601wcprdika2jz7qh8"; <co xml:id='ex-dockerTools-pullImage-4' />
os = "linux"; <co xml:id='ex-dockerTools-pullImage-5' />
arch = "x86_64"; <co xml:id='ex-dockerTools-pullImage-6' />
}
</programlisting>
</example>
<calloutlist>
<callout arearefs='ex-dockerTools-pullImage-1'>
<para>
<varname>imageName</varname> specifies the name of the image to be
downloaded, which can also include the registry namespace (e.g.
<literal>nixos</literal>). This argument is required.
</para>
</callout>
<callout arearefs='ex-dockerTools-pullImage-2'>
<para>
<varname>imageDigest</varname> specifies the digest of the image to be
downloaded. Skopeo can be used to get the digest of an image, with its
<varname>inspect</varname> subcommand. Since a given
<varname>imageName</varname> may transparently refer to a manifest list of
images which support multiple architectures and/or operating systems,
supply the `--override-os` and `--override-arch` arguments to specify
exactly which image you want. By default it will match the OS and
architecture of the host the command is run on.
<programlisting>
$ nix-shell --packages skopeo jq --command "skopeo --override-os linux --override-arch x86_64 inspect docker://docker.io/nixos/nix:1.11 | jq -r '.Digest'"
sha256:20d9485b25ecfd89204e843a962c1bd70e9cc6858d65d7f5fadc340246e2116b
</programlisting>
This argument is required.
</para>
</callout>
<callout arearefs='ex-dockerTools-pullImage-3'>
<para>
<varname>finalImageTag</varname>, if specified, this is the tag of the
image to be created. Note it is never used to fetch the image since we
prefer to rely on the immutable digest ID. By default it's
<literal>latest</literal>.
</para>
</callout>
<callout arearefs='ex-dockerTools-pullImage-4'>
<para>
<varname>sha256</varname> is the checksum of the whole fetched image. This
argument is required.
</para>
</callout>
<callout arearefs='ex-dockerTools-pullImage-5'>
<para>
<varname>os</varname>, if specified, is the operating system of the
fetched image. By default it's <literal>linux</literal>.
</para>
</callout>
<callout arearefs='ex-dockerTools-pullImage-6'>
<para>
<varname>arch</varname>, if specified, is the cpu architecture of the
fetched image. By default it's <literal>x86_64</literal>.
</para>
</callout>
</calloutlist>
</section>
<section xml:id="ssec-pkgs-dockerTools-exportImage">
<title>exportImage</title>
<para>
This function is analogous to the <command>docker export</command> command,
in that can used to flatten a Docker image that contains multiple layers. It
is in fact the result of the merge of all the layers of the image. As such,
the result is suitable for being imported in Docker with <command>docker
import</command>.
</para>
<note>
<para>
Using this function requires the <literal>kvm</literal> device to be
available.
</para>
</note>
<para>
The parameters of <varname>exportImage</varname> are the following:
</para>
<example xml:id='ex-dockerTools-exportImage'>
<title>Docker export</title>
<programlisting>
exportImage {
fromImage = someLayeredImage;
fromImageName = null;
fromImageTag = null;
name = someLayeredImage.name;
}
</programlisting>
</example>
<para>
The parameters relative to the base image have the same synopsis as
described in <xref linkend='ssec-pkgs-dockerTools-buildImage'/>, except that
<varname>fromImage</varname> is the only required argument in this case.
</para>
<para>
The <varname>name</varname> argument is the name of the derivation output,
which defaults to <varname>fromImage.name</varname>.
</para>
</section>
<section xml:id="ssec-pkgs-dockerTools-shadowSetup">
<title>shadowSetup</title>
<para>
This constant string is a helper for setting up the base files for managing
users and groups, only if such files don't exist already. It is suitable for
being used in a <varname>runAsRoot</varname>
<xref linkend='ex-dockerTools-buildImage-runAsRoot'/> script for cases like
in the example below:
</para>
<example xml:id='ex-dockerTools-shadowSetup'>
<title>Shadow base files</title>
<programlisting>
buildImage {
name = "shadow-basic";
runAsRoot = ''
#!${stdenv.shell}
${shadowSetup}
groupadd -r redis
useradd -r -g redis redis
mkdir /data
chown redis:redis /data
'';
}
</programlisting>
</example>
<para>
Creating base files like <literal>/etc/passwd</literal> or
<literal>/etc/login.defs</literal> are necessary for shadow-utils to
manipulate users and groups.
</para>
</section>
</section>

142
doc/functions/fhs-environments.xml
View File

@ -1,142 +0,0 @@
<section xmlns="http://docbook.org/ns/docbook"
xmlns:xlink="http://www.w3.org/1999/xlink"
xmlns:xi="http://www.w3.org/2001/XInclude"
xml:id="sec-fhs-environments">
<title>buildFHSUserEnv</title>
<para>
<function>buildFHSUserEnv</function> provides a way to build and run
FHS-compatible lightweight sandboxes. It creates an isolated root with bound
<filename>/nix/store</filename>, so its footprint in terms of disk space
needed is quite small. This allows one to run software which is hard or
unfeasible to patch for NixOS -- 3rd-party source trees with FHS assumptions,
games distributed as tarballs, software with integrity checking and/or
external self-updated binaries. It uses Linux namespaces feature to create
temporary lightweight environments which are destroyed after all child
processes exit, without root user rights requirement. Accepted arguments are:
</para>
<variablelist>
<varlistentry>
<term>
<literal>name</literal>
</term>
<listitem>
<para>
Environment name.
</para>
</listitem>
</varlistentry>
<varlistentry>
<term>
<literal>targetPkgs</literal>
</term>
<listitem>
<para>
Packages to be installed for the main host's architecture (i.e. x86_64 on
x86_64 installations). Along with libraries binaries are also installed.
</para>
</listitem>
</varlistentry>
<varlistentry>
<term>
<literal>multiPkgs</literal>
</term>
<listitem>
<para>
Packages to be installed for all architectures supported by a host (i.e.
i686 and x86_64 on x86_64 installations). Only libraries are installed by
default.
</para>
</listitem>
</varlistentry>
<varlistentry>
<term>
<literal>extraBuildCommands</literal>
</term>
<listitem>
<para>
Additional commands to be executed for finalizing the directory structure.
</para>
</listitem>
</varlistentry>
<varlistentry>
<term>
<literal>extraBuildCommandsMulti</literal>
</term>
<listitem>
<para>
Like <literal>extraBuildCommands</literal>, but executed only on multilib
architectures.
</para>
</listitem>
</varlistentry>
<varlistentry>
<term>
<literal>extraOutputsToInstall</literal>
</term>
<listitem>
<para>
Additional derivation outputs to be linked for both target and
multi-architecture packages.
</para>
</listitem>
</varlistentry>
<varlistentry>
<term>
<literal>extraInstallCommands</literal>
</term>
<listitem>
<para>
Additional commands to be executed for finalizing the derivation with
runner script.
</para>
</listitem>
</varlistentry>
<varlistentry>
<term>
<literal>runScript</literal>
</term>
<listitem>
<para>
A command that would be executed inside the sandbox and passed all the
command line arguments. It defaults to <literal>bash</literal>.
</para>
</listitem>
</varlistentry>
</variablelist>
<para>
One can create a simple environment using a <literal>shell.nix</literal> like
that:
</para>
<programlisting><![CDATA[
{ pkgs ? import <nixpkgs> {} }:
(pkgs.buildFHSUserEnv {
name = "simple-x11-env";
targetPkgs = pkgs: (with pkgs;
[ udev
alsaLib
]) ++ (with pkgs.xorg;
[ libX11
libXcursor
libXrandr
]);
multiPkgs = pkgs: (with pkgs;
[ udev
alsaLib
]);
runScript = "bash";
}).env
]]></programlisting>
<para>
Running <literal>nix-shell</literal> would then drop you into a shell with
these libraries and binaries available. You can use this to run closed-source
applications which expect FHS structure without hassles: simply change
<literal>runScript</literal> to the application path, e.g.
<filename>./bin/start.sh</filename> -- relative paths are supported.
</para>
</section>

25
doc/functions/generators.xml
View File

@ -5,28 +5,15 @@
<title>Generators</title>
<para>
Generators are functions that create file formats from nix data structures,
e.g. for configuration files. There are generators available for:
<literal>INI</literal>, <literal>JSON</literal> and <literal>YAML</literal>
Generators are functions that create file formats from nix data structures, e.g. for configuration files. There are generators available for: <literal>INI</literal>, <literal>JSON</literal> and <literal>YAML</literal>
</para>
<para>
All generators follow a similar call interface: <code>generatorName
configFunctions data</code>, where <literal>configFunctions</literal> is an
attrset of user-defined functions that format nested parts of the content.
They each have common defaults, so often they do not need to be set manually.
An example is <code>mkSectionName ? (name: libStr.escape [ "[" "]" ]
name)</code> from the <literal>INI</literal> generator. It receives the name
of a section and sanitizes it. The default <literal>mkSectionName</literal>
escapes <literal>[</literal> and <literal>]</literal> with a backslash.
All generators follow a similar call interface: <code>generatorName configFunctions data</code>, where <literal>configFunctions</literal> is an attrset of user-defined functions that format nested parts of the content. They each have common defaults, so often they do not need to be set manually. An example is <code>mkSectionName ? (name: libStr.escape [ "[" "]" ] name)</code> from the <literal>INI</literal> generator. It receives the name of a section and sanitizes it. The default <literal>mkSectionName</literal> escapes <literal>[</literal> and <literal>]</literal> with a backslash.
</para>
<para>
Generators can be fine-tuned to produce exactly the file format required by
your application/service. One example is an INI-file format which uses
<literal>: </literal> as separator, the strings
<literal>"yes"</literal>/<literal>"no"</literal> as boolean values and
requires all string values to be quoted:
Generators can be fine-tuned to produce exactly the file format required by your application/service. One example is an INI-file format which uses <literal>: </literal> as separator, the strings <literal>"yes"</literal>/<literal>"no"</literal> as boolean values and requires all string values to be quoted:
</para>
<programlisting>
@ -77,13 +64,11 @@ merge:"diff3"
<note>
<para>
Nix store paths can be converted to strings by enclosing a derivation
attribute like so: <code>"${drv}"</code>.
Nix store paths can be converted to strings by enclosing a derivation attribute like so: <code>"${drv}"</code>.
</para>
</note>
<para>
Detailed documentation for each generator can be found in
<literal>lib/generators.nix</literal>.
Detailed documentation for each generator can be found in <literal>lib/generators.nix</literal>.
</para>
</section>

17
doc/functions/library.xml
View File

@ -5,11 +5,24 @@
<title>Nixpkgs Library Functions</title>
<para>
Nixpkgs provides a standard library at <varname>pkgs.lib</varname>, or
through <code>import &lt;nixpkgs/lib&gt;</code>.
Nixpkgs provides a standard library at <varname>pkgs.lib</varname>, or through <code>import &lt;nixpkgs/lib&gt;</code>.
</para>
<xi:include href="./library/asserts.xml" />
<xi:include href="./library/attrsets.xml" />
<!-- These docs are generated via nixdoc. To add another generated
library function file to this list, the file
`lib-function-docs.nix` must also be updated. -->
<xi:include href="./library/generated/strings.xml" />
<xi:include href="./library/generated/trivial.xml" />
<xi:include href="./library/generated/lists.xml" />
<xi:include href="./library/generated/debug.xml" />
<xi:include href="./library/generated/options.xml" />
</section>

13
doc/functions/library/asserts.xml
View File

@ -27,8 +27,7 @@
</term>
<listitem>
<para>
Condition under which the <varname>msg</varname> should
<emphasis>not</emphasis> be printed.
Condition under which the <varname>msg</varname> should <emphasis>not</emphasis> be printed.
</para>
</listitem>
</varlistentry>
@ -64,9 +63,7 @@ stderr> assert failed
<xi:include href="./locations.xml" xpointer="lib.asserts.assertOneOf" />
<para>
Specialized <function>asserts.assertMsg</function> for checking if
<varname>val</varname> is one of the elements of <varname>xs</varname>.
Useful for checking enums.
Specialized <function>asserts.assertMsg</function> for checking if <varname>val</varname> is one of the elements of <varname>xs</varname>. Useful for checking enums.
</para>
<variablelist>
@ -76,8 +73,7 @@ stderr> assert failed
</term>
<listitem>
<para>
The name of the variable the user entered <varname>val</varname> into,
for inclusion in the error message.
The name of the variable the user entered <varname>val</varname> into, for inclusion in the error message.
</para>
</listitem>
</varlistentry>
@ -87,8 +83,7 @@ stderr> assert failed
</term>
<listitem>
<para>
The value of what the user provided, to be compared against the values in
<varname>xs</varname>.
The value of what the user provided, to be compared against the values in <varname>xs</varname>.
</para>
</listitem>
</varlistentry>

824
doc/functions/library/attrsets.xml
View File

@ -23,8 +23,7 @@
</term>
<listitem>
<para>
A list of strings representing the path through the nested attribute set
<varname>set</varname>.
A list of strings representing the path through the nested attribute set <varname>set</varname>.
</para>
</listitem>
</varlistentry>
@ -34,8 +33,7 @@
</term>
<listitem>
<para>
Default value if <varname>attrPath</varname> does not resolve to an
existing value.
Default value if <varname>attrPath</varname> does not resolve to an existing value.
</para>
</listitem>
</varlistentry>
@ -88,8 +86,7 @@ lib.attrsets.attrByPath [ "a" "b" ] 0 {}
</term>
<listitem>
<para>
A list of strings representing the path through the nested attribute set
<varname>set</varname>.
A list of strings representing the path through the nested attribute set <varname>set</varname>.
</para>
</listitem>
</varlistentry>
@ -125,8 +122,7 @@ lib.attrsets.hasAttrByPath
<xi:include href="./locations.xml" xpointer="lib.attrsets.setAttrByPath" />
<para>
Create a new attribute set with <varname>value</varname> set at the nested
attribute location specified in <varname>attrPath</varname>.
Create a new attribute set with <varname>value</varname> set at the nested attribute location specified in <varname>attrPath</varname>.
</para>
<variablelist>
@ -146,8 +142,7 @@ lib.attrsets.hasAttrByPath
</term>
<listitem>
<para>
The value to set at the location described by
<varname>attrPath</varname>.
The value to set at the location described by <varname>attrPath</varname>.
</para>
</listitem>
</varlistentry>
@ -171,8 +166,7 @@ lib.attrsets.setAttrByPath [ "a" "b" ] 3
<xi:include href="./locations.xml" xpointer="lib.attrsets.getAttrFromPath" />
<para>
Like <xref linkend="function-library-lib.attrsets.attrByPath" /> except
without a default, and it will throw if the value doesn't exist.
Like <xref linkend="function-library-lib.attrsets.attrByPath" /> except without a default, and it will throw if the value doesn't exist.
</para>
<variablelist>
@ -182,8 +176,7 @@ lib.attrsets.setAttrByPath [ "a" "b" ] 3
</term>
<listitem>
<para>
A list of strings representing the path through the nested attribute set
<varname>set</varname>.
A list of strings representing the path through the nested attribute set <varname>set</varname>.
</para>
</listitem>
</varlistentry>
@ -235,8 +228,7 @@ lib.attrsets.getAttrFromPath [ "x" "y" ] { }
</term>
<listitem>
<para>
The list of attributes to fetch from <varname>set</varname>. Each
attribute name must exist on the attrbitue set.
The list of attributes to fetch from <varname>set</varname>. Each attribute name must exist on the attrbitue set.
</para>
</listitem>
</varlistentry>
@ -282,8 +274,7 @@ error: attribute 'd' missing
</para>
<para>
Provides a backwards-compatible interface of
<function>builtins.attrValues</function> for Nix version older than 1.8.
Provides a backwards-compatible interface of <function>builtins.attrValues</function> for Nix version older than 1.8.
</para>
<variablelist>
@ -317,14 +308,11 @@ lib.attrsets.attrValues { a = 1; b = 2; c = 3; }
<xi:include href="./locations.xml" xpointer="lib.attrsets.catAttrs" />
<para>
Collect each attribute named `attr' from the list of attribute sets,
<varname>sets</varname>. Sets that don't contain the named attribute are
ignored.
Collect each attribute named `attr' from the list of attribute sets, <varname>sets</varname>. Sets that don't contain the named attribute are ignored.
</para>
<para>
Provides a backwards-compatible interface of
<function>builtins.catAttrs</function> for Nix version older than 1.9.
Provides a backwards-compatible interface of <function>builtins.catAttrs</function> for Nix version older than 1.9.
</para>
<variablelist>
@ -334,8 +322,7 @@ lib.attrsets.attrValues { a = 1; b = 2; c = 3; }
</term>
<listitem>
<para>
Attribute name to select from each attribute set in
<varname>sets</varname>.
Attribute name to select from each attribute set in <varname>sets</varname>.
</para>
</listitem>
</varlistentry>
@ -372,8 +359,7 @@ catAttrs "a" [{a = 1;} {b = 0;} {a = 2;}]
<xi:include href="./locations.xml" xpointer="lib.attrsets.filterAttrs" />
<para>
Filter an attribute set by removing all attributes for which the given
predicate return false.
Filter an attribute set by removing all attributes for which the given predicate return false.
</para>
<variablelist>
@ -386,8 +372,7 @@ catAttrs "a" [{a = 1;} {b = 0;} {a = 2;}]
<literal>String -> Any -> Bool</literal>
</para>
<para>
Predicate which returns true to include an attribute, or returns false to
exclude it.
Predicate which returns true to include an attribute, or returns false to exclude it.
</para>
<variablelist>
<varlistentry>
@ -412,8 +397,7 @@ catAttrs "a" [{a = 1;} {b = 0;} {a = 2;}]
</varlistentry>
</variablelist>
<para>
Returns <literal>true</literal> to include the attribute,
<literal>false</literal> to exclude the attribute.
Returns <literal>true</literal> to include the attribute, <literal>false</literal> to exclude the attribute.
</para>
</listitem>
</varlistentry>
@ -447,8 +431,7 @@ filterAttrs (n: v: n == "foo") { foo = 1; bar = 2; }
<xi:include href="./locations.xml" xpointer="lib.attrsets.filterAttrsRecursive" />
<para>
Filter an attribute set recursively by removing all attributes for which the
given predicate return false.
Filter an attribute set recursively by removing all attributes for which the given predicate return false.
</para>
<variablelist>
@ -461,8 +444,7 @@ filterAttrs (n: v: n == "foo") { foo = 1; bar = 2; }
<literal>String -> Any -> Bool</literal>
</para>
<para>
Predicate which returns true to include an attribute, or returns false to
exclude it.
Predicate which returns true to include an attribute, or returns false to exclude it.
</para>
<variablelist>
<varlistentry>
@ -487,8 +469,7 @@ filterAttrs (n: v: n == "foo") { foo = 1; bar = 2; }
</varlistentry>
</variablelist>
<para>
Returns <literal>true</literal> to include the attribute,
<literal>false</literal> to exclude the attribute.
Returns <literal>true</literal> to include the attribute, <literal>false</literal> to exclude the attribute.
</para>
</listitem>
</varlistentry>
@ -557,8 +538,7 @@ lib.attrsets.filterAttrsRecursive
<literal>Any -> Any -> Any</literal>
</para>
<para>
Given a value <varname>val</varname> and a collector
<varname>col</varname>, combine the two.
Given a value <varname>val</varname> and a collector <varname>col</varname>, combine the two.
</para>
<variablelist>
<varlistentry>
@ -578,8 +558,7 @@ lib.attrsets.filterAttrsRecursive
<listitem>
<!-- TODO: make this not bad, use more fold-ey terms -->
<para>
The result of previous <function>op</function> calls with other values
and <function>nul</function>.
The result of previous <function>op</function> calls with other values and <function>nul</function>.
</para>
</listitem>
</varlistentry>
@ -632,9 +611,7 @@ lib.attrsets.foldAttrs
<xi:include href="./locations.xml" xpointer="lib.attrsets.collect" />
<para>
Recursively collect sets that verify a given predicate named
<varname>pred</varname> from the set <varname>attrs</varname>. The recursion
stops when <varname>pred</varname> returns <literal>true</literal>.
Recursively collect sets that verify a given predicate named <varname>pred</varname> from the set <varname>attrs</varname>. The recursion stops when <varname>pred</varname> returns <literal>true</literal>.
</para>
<variablelist>
@ -702,8 +679,7 @@ collect (x: x ? outPath)
<xi:include href="./locations.xml" xpointer="lib.attrsets.nameValuePair" />
<para>
Utility function that creates a <literal>{name, value}</literal> pair as
expected by <function>builtins.listToAttrs</function>.
Utility function that creates a <literal>{name, value}</literal> pair as expected by <function>builtins.listToAttrs</function>.
</para>
<variablelist>
@ -747,13 +723,11 @@ nameValuePair "some" 6
<xi:include href="./locations.xml" xpointer="lib.attrsets.mapAttrs" />
<para>
Apply a function to each element in an attribute set, creating a new
attribute set.
Apply a function to each element in an attribute set, creating a new attribute set.
</para>
<para>
Provides a backwards-compatible interface of
<function>builtins.mapAttrs</function> for Nix version older than 2.1.
Provides a backwards-compatible interface of <function>builtins.mapAttrs</function> for Nix version older than 2.1.
</para>
<variablelist>
@ -814,9 +788,7 @@ lib.attrsets.mapAttrs
<xi:include href="./locations.xml" xpointer="lib.attrsets.mapAttrs-prime" />
<para>
Like <function>mapAttrs</function>, but allows the name of each attribute to
be changed in addition to the value. The applied function should return both
the new name and value as a <function>nameValuePair</function>.
Like <function>mapAttrs</function>, but allows the name of each attribute to be changed in addition to the value. The applied function should return both the new name and value as a <function>nameValuePair</function>.
</para>
<variablelist>
@ -829,10 +801,8 @@ lib.attrsets.mapAttrs
<literal>String -> Any -> { name = String; value = Any }</literal>
</para>
<para>
Given an attribute's name and value, return a new
<link
linkend="function-library-lib.attrsets.nameValuePair">name
value pair</link>.
Given an attribute's name and value, return a new <link
linkend="function-library-lib.attrsets.nameValuePair">name value pair</link>.
</para>
<variablelist>
<varlistentry>
@ -891,8 +861,7 @@ lib.attrsets.mapAttrs' (name: value: lib.attrsets.nameValuePair ("foo_" + name)
<xi:include href="./locations.xml" xpointer="lib.attrsets.mapAttrsToList" />
<para>
Call <varname>fn</varname> for each attribute in the given
<varname>set</varname> and return the result in a list.
Call <varname>fn</varname> for each attribute in the given <varname>set</varname> and return the result in a list.
</para>
<variablelist>
@ -962,9 +931,740 @@ lib.attrsets.mapAttrsToList (name: value: "${name}=${value}")
<xi:include href="./locations.xml" xpointer="lib.attrsets.mapAttrsRecursive" />
<para>
Like <function>mapAttrs</function>, except that it recursively applies
itself to attribute sets. Also, the first argument of the argument function
is a <emphasis>list</emphasis> of the names of the containing attributes.
Like <function>mapAttrs</function>, except that it recursively applies itself to attribute sets. Also, the first argument of the argument function is a <emphasis>list</emphasis> of the names of the containing attributes.
</para>
<variablelist>
<varlistentry>
<term>
<varname>f</varname>
</term>
<listitem>
<para>
<literal>[ String ] -> Any -> Any</literal>
</para>
<para>
Given a list of attribute names and value, return a new value.
</para>
<variablelist>
<varlistentry>
<term>
<varname>name_path</varname>
</term>
<listitem>
<para>
The list of attribute names to this value.
</para>
<para>
For example, the <varname>name_path</varname> for the <literal>example</literal> string in the attribute set <literal>{ foo = { bar = "example"; }; }</literal> is <literal>[ "foo" "bar" ]</literal>.
</para>
</listitem>
</varlistentry>
<varlistentry>
<term>
<varname>value</varname>
</term>
<listitem>
<para>
The attribute's value.
</para>
</listitem>
</varlistentry>
</variablelist>
</listitem>
</varlistentry>
<varlistentry>
<term>
<varname>set</varname>
</term>
<listitem>
<para>
The attribute set to recursively map over.
</para>
</listitem>
</varlistentry>
</variablelist>
<example xml:id="function-library-lib.attrsets.mapAttrsRecursive-example">
<title>A contrived example of using <function>lib.attrsets.mapAttrsRecursive</function></title>
<programlisting><![CDATA[
mapAttrsRecursive
(path: value: concatStringsSep "-" (path ++ [value]))
{
n = {
a = "A";
m = {
b = "B";
c = "C";
};
};
d = "D";
}
=> {
n = {
a = "n-a-A";
m = {
b = "n-m-b-B";
c = "n-m-c-C";
};
};
d = "d-D";
}
]]></programlisting>
</example>
</section>
<section xml:id="function-library-lib.attrsets.mapAttrsRecursiveCond">
<title><function>lib.attrsets.mapAttrsRecursiveCond</function></title>
<subtitle><literal>mapAttrsRecursiveCond :: (AttrSet -> Bool) -> ([ String ] -> Any -> Any) -> AttrSet -> AttrSet</literal>
</subtitle>
<xi:include href="./locations.xml" xpointer="lib.attrsets.mapAttrsRecursiveCond" />
<para>
Like <function>mapAttrsRecursive</function>, but it takes an additional predicate function that tells it whether to recursive into an attribute set. If it returns false, <function>mapAttrsRecursiveCond</function> does not recurse, but does apply the map function. It is returns true, it does recurse, and does not apply the map function.
</para>
<variablelist>
<varlistentry>
<term>
<varname>cond</varname>
</term>
<listitem>
<para>
<literal>(AttrSet -> Bool)</literal>
</para>
<para>
Determine if <function>mapAttrsRecursive</function> should recurse deeper in to the attribute set.
</para>
<variablelist>
<varlistentry>
<term>
<varname>attributeset</varname>
</term>
<listitem>
<para>
An attribute set.
</para>
</listitem>
</varlistentry>
</variablelist>
</listitem>
</varlistentry>
<varlistentry>
<term>
<varname>f</varname>
</term>
<listitem>
<para>
<literal>[ String ] -> Any -> Any</literal>
</para>
<para>
Given a list of attribute names and value, return a new value.
</para>
<variablelist>
<varlistentry>
<term>
<varname>name_path</varname>
</term>
<listitem>
<para>
The list of attribute names to this value.
</para>
<para>
For example, the <varname>name_path</varname> for the <literal>example</literal> string in the attribute set <literal>{ foo = { bar = "example"; }; }</literal> is <literal>[ "foo" "bar" ]</literal>.
</para>
</listitem>
</varlistentry>
<varlistentry>
<term>
<varname>value</varname>
</term>
<listitem>
<para>
The attribute's value.
</para>
</listitem>
</varlistentry>
</variablelist>
</listitem>
</varlistentry>
<varlistentry>
<term>
<varname>set</varname>
</term>
<listitem>
<para>
The attribute set to recursively map over.
</para>
</listitem>
</varlistentry>
</variablelist>
<example xml:id="function-library-lib.attrsets.mapAttrsRecursiveCond-example">
<title>Only convert attribute values to JSON if the containing attribute set is marked for recursion</title>
<programlisting><![CDATA[
lib.attrsets.mapAttrsRecursiveCond
({ recurse ? false, ... }: recurse)
(name: value: builtins.toJSON value)
{
dorecur = {
recurse = true;
hello = "there";
};
dontrecur = {
converted-to- = "json";
};
}
=> {
dorecur = {
hello = "\"there\"";
recurse = "true";
};
dontrecur = "{\"converted-to\":\"json\"}";
}
]]></programlisting>
</example>
</section>
<section xml:id="function-library-lib.attrsets.genAttrs">
<title><function>lib.attrsets.genAttrs</function></title>
<subtitle><literal>genAttrs :: [ String ] -> (String -> Any) -> AttrSet</literal>
</subtitle>
<xi:include href="./locations.xml" xpointer="lib.attrsets.genAttrs" />
<para>
Generate an attribute set by mapping a function over a list of attribute names.
</para>
<variablelist>
<varlistentry>
<term>
<varname>names</varname>
</term>
<listitem>
<para>
Names of values in the resulting attribute set.
</para>
</listitem>
</varlistentry>
<varlistentry>
<term>
<varname>f</varname>
</term>
<listitem>
<para>
<literal>String -> Any</literal>
</para>
<para>
Takes the name of the attribute and return the attribute's value.
</para>
<variablelist>
<varlistentry>
<term>
<varname>name</varname>
</term>
<listitem>
<para>
The name of the attribute to generate a value for.
</para>
</listitem>
</varlistentry>
</variablelist>
</listitem>
</varlistentry>
</variablelist>
<example xml:id="function-library-lib.attrsets.genAttrs-example">
<title>Generate an attrset based on names only</title>
<programlisting><![CDATA[
lib.attrsets.genAttrs [ "foo" "bar" ] (name: "x_${name}")
=> { foo = "x_foo"; bar = "x_bar"; }
]]></programlisting>
</example>
</section>
<section xml:id="function-library-lib.attrsets.isDerivation">
<title><function>lib.attrsets.isDerivation</function></title>
<subtitle><literal>isDerivation :: Any -> Bool</literal>
</subtitle>
<xi:include href="./locations.xml" xpointer="lib.attrsets.isDerivation" />
<para>
Check whether the argument is a derivation. Any set with <code>{ type = "derivation"; }</code> counts as a derivation.
</para>
<variablelist>
<varlistentry>
<term>
<varname>value</varname>
</term>
<listitem>
<para>
The value which is possibly a derivation.
</para>
</listitem>
</varlistentry>
</variablelist>
<example xml:id="function-library-lib.attrsets.isDerivation-example-true">
<title>A package is a derivation</title>
<programlisting><![CDATA[
lib.attrsets.isDerivation (import <nixpkgs> {}).ruby
=> true
]]></programlisting>
</example>
<example xml:id="function-library-lib.attrsets.isDerivation-example-false">
<title>Anything else is not a derivation</title>
<programlisting><![CDATA[
lib.attrsets.isDerivation "foobar"
=> false
]]></programlisting>
</example>
</section>
<section xml:id="function-library-lib.attrsets.toDerivation">
<title><function>lib.attrsets.toDerivation</function></title>
<subtitle><literal>toDerivation :: Path -> Derivation</literal>
</subtitle>
<xi:include href="./locations.xml" xpointer="lib.attrsets.toDerivation" />
<para>
Converts a store path to a fake derivation.
</para>
<variablelist>
<varlistentry>
<term>
<varname>path</varname>
</term>
<listitem>
<para>
A store path to convert to a derivation.
</para>
</listitem>
</varlistentry>
</variablelist>
</section>
<section xml:id="function-library-lib.attrsets.optionalAttrs">
<title><function>lib.attrsets.optionalAttrs</function></title>
<subtitle><literal>optionalAttrs :: Bool -> AttrSet</literal>
</subtitle>
<xi:include href="./locations.xml" xpointer="lib.attrsets.optionalAttrs" />
<para>
Conditionally return an attribute set or an empty attribute set.
</para>
<variablelist>
<varlistentry>
<term>
<varname>cond</varname>
</term>
<listitem>
<para>
Condition under which the <varname>as</varname> attribute set is returned.
</para>
</listitem>
</varlistentry>
<varlistentry>
<term>
<varname>as</varname>
</term>
<listitem>
<para>
The attribute set to return if <varname>cond</varname> is true.
</para>
</listitem>
</varlistentry>
</variablelist>
<example xml:id="function-library-lib.attrsets.optionalAttrs-example-true">
<title>Return the provided attribute set when <varname>cond</varname> is true</title>
<programlisting><![CDATA[
lib.attrsets.optionalAttrs true { my = "set"; }
=> { my = "set"; }
]]></programlisting>
</example>
<example xml:id="function-library-lib.attrsets.optionalAttrs-example-false">
<title>Return an empty attribute set when <varname>cond</varname> is false</title>
<programlisting><![CDATA[
lib.attrsets.optionalAttrs false { my = "set"; }
=> { }
]]></programlisting>
</example>
</section>
<section xml:id="function-library-lib.attrsets.zipAttrsWithNames">
<title><function>lib.attrsets.zipAttrsWithNames</function></title>
<subtitle><literal>zipAttrsWithNames :: [ String ] -> (String -> [ Any ] -> Any) -> [ AttrSet ] -> AttrSet</literal>
</subtitle>
<xi:include href="./locations.xml" xpointer="lib.attrsets.zipAttrsWithNames" />
<para>
Merge sets of attributes and use the function <varname>f</varname> to merge attribute values where the attribute name is in <varname>names</varname>.
</para>
<variablelist>
<varlistentry>
<term>
<varname>names</varname>
</term>
<listitem>
<para>
A list of attribute names to zip.
</para>
</listitem>
</varlistentry>
<varlistentry>
<term>
<varname>f</varname>
</term>
<listitem>
<para>
<literal>(String -> [ Any ] -> Any</literal>
</para>
<para>
Accepts an attribute name, all the values, and returns a combined value.
</para>
<variablelist>
<varlistentry>
<term>
<varname>name</varname>
</term>
<listitem>
<para>
The name of the attribute each value came from.
</para>
</listitem>
</varlistentry>
<varlistentry>
<term>
<varname>vs</varname>
</term>
<listitem>
<para>
A list of values collected from the list of attribute sets.
</para>
</listitem>
</varlistentry>
</variablelist>
</listitem>
</varlistentry>
<varlistentry>
<term>
<varname>sets</varname>
</term>
<listitem>
<para>
A list of attribute sets to zip together.
</para>
</listitem>
</varlistentry>
</variablelist>
<example xml:id="function-library-lib.attrsets.zipAttrsWithNames-example">
<title>Summing a list of attribute sets of numbers</title>
<programlisting><![CDATA[
lib.attrsets.zipAttrsWithNames
[ "a" "b" ]
(name: vals: "${name} ${toString (builtins.foldl' (a: b: a + b) 0 vals)}")
[
{ a = 1; b = 1; c = 1; }
{ a = 10; }
{ b = 100; }
{ c = 1000; }
]
=> { a = "a 11"; b = "b 101"; }
]]></programlisting>
</example>
</section>
<section xml:id="function-library-lib.attrsets.zipAttrsWith">
<title><function>lib.attrsets.zipAttrsWith</function></title>
<subtitle><literal>zipAttrsWith :: (String -> [ Any ] -> Any) -> [ AttrSet ] -> AttrSet</literal>
</subtitle>
<xi:include href="./locations.xml" xpointer="lib.attrsets.zipAttrsWith" />
<para>
Merge sets of attributes and use the function <varname>f</varname> to merge attribute values. Similar to <xref
linkend="function-library-lib.attrsets.zipAttrsWithNames" /> where all key names are passed for <varname>names</varname>.
</para>
<variablelist>
<varlistentry>
<term>
<varname>f</varname>
</term>
<listitem>
<para>
<literal>(String -> [ Any ] -> Any</literal>
</para>
<para>
Accepts an attribute name, all the values, and returns a combined value.
</para>
<variablelist>
<varlistentry>
<term>
<varname>name</varname>
</term>
<listitem>
<para>
The name of the attribute each value came from.
</para>
</listitem>
</varlistentry>
<varlistentry>
<term>
<varname>vs</varname>
</term>
<listitem>
<para>
A list of values collected from the list of attribute sets.
</para>
</listitem>
</varlistentry>
</variablelist>
</listitem>
</varlistentry>
<varlistentry>
<term>
<varname>sets</varname>
</term>
<listitem>
<para>
A list of attribute sets to zip together.
</para>
</listitem>
</varlistentry>
</variablelist>
<example xml:id="function-library-lib.attrsets.zipAttrsWith-example">
<title>Summing a list of attribute sets of numbers</title>
<programlisting><![CDATA[
lib.attrsets.zipAttrsWith
(name: vals: "${name} ${toString (builtins.foldl' (a: b: a + b) 0 vals)}")
[
{ a = 1; b = 1; c = 1; }
{ a = 10; }
{ b = 100; }
{ c = 1000; }
]
=> { a = "a 11"; b = "b 101"; c = "c 1001"; }
]]></programlisting>
</example>
</section>
<section xml:id="function-library-lib.attrsets.zipAttrs">
<title><function>lib.attrsets.zipAttrs</function></title>
<subtitle><literal>zipAttrsWith :: [ AttrSet ] -> AttrSet</literal>
</subtitle>
<xi:include href="./locations.xml" xpointer="lib.attrsets.zipAttrs" />
<para>
Merge sets of attributes and combine each attribute value in to a list. Similar to <xref linkend="function-library-lib.attrsets.zipAttrsWith" /> where the merge function returns a list of all values.
</para>
<variablelist>
<varlistentry>
<term>
<varname>sets</varname>
</term>
<listitem>
<para>
A list of attribute sets to zip together.
</para>
</listitem>
</varlistentry>
</variablelist>
<example xml:id="function-library-lib.attrsets.zipAttrs-example">
<title>Combining a list of attribute sets</title>
<programlisting><![CDATA[
lib.attrsets.zipAttrs
[
{ a = 1; b = 1; c = 1; }
{ a = 10; }
{ b = 100; }
{ c = 1000; }
]
=> { a = [ 1 10 ]; b = [ 1 100 ]; c = [ 1 1000 ]; }
]]></programlisting>
</example>
</section>
<section xml:id="function-library-lib.attrsets.recursiveUpdateUntil">
<title><function>lib.attrsets.recursiveUpdateUntil</function></title>
<subtitle><literal>recursiveUpdateUntil :: ( [ String ] -> AttrSet -> AttrSet -> Bool ) -> AttrSet -> AttrSet -> AttrSet</literal>
</subtitle>
<xi:include href="./locations.xml" xpointer="lib.attrsets.recursiveUpdateUntil" />
<para>
Does the same as the update operator <literal>//</literal> except that attributes are merged until the given predicate is verified. The predicate should accept 3 arguments which are the path to reach the attribute, a part of the first attribute set and a part of the second attribute set. When the predicate is verified, the value of the first attribute set is replaced by the value of the second attribute set.
</para>
<variablelist>
<varlistentry>
<term>
<varname>pred</varname>
</term>
<listitem>
<para>
<literal>[ String ] -> AttrSet -> AttrSet -> Bool</literal>
</para>
<variablelist>
<varlistentry>
<term>
<varname>path</varname>
</term>
<listitem>
<para>
The path to the values in the left and right hand sides.
</para>
</listitem>
</varlistentry>
<varlistentry>
<term>
<varname>l</varname>
</term>
<listitem>
<para>
The left hand side value.
</para>
</listitem>
</varlistentry>
<varlistentry>
<term>
<varname>r</varname>
</term>
<listitem>
<para>
The right hand side value.
</para>
</listitem>
</varlistentry>
</variablelist>
</listitem>
</varlistentry>
<varlistentry>
<term>
<varname>lhs</varname>
</term>
<listitem>
<para>
The left hand attribute set of the merge.
</para>
</listitem>
</varlistentry>
<varlistentry>
<term>
<varname>rhs</varname>
</term>
<listitem>
<para>
The right hand attribute set of the merge.
</para>
</listitem>
</varlistentry>
</variablelist>
<example xml:id="function-library-lib.attrsets.recursiveUpdateUntil-example">
<title>Recursively merging two attribute sets</title>
<programlisting><![CDATA[
lib.attrsets.recursiveUpdateUntil (path: l: r: path == ["foo"])
{
# first attribute set
foo.bar = 1;
foo.baz = 2;
bar = 3;
}
{
#second attribute set
foo.bar = 1;
foo.quz = 2;
baz = 4;
}
=> {
foo.bar = 1; # 'foo.*' from the second set
foo.quz = 2; #
bar = 3; # 'bar' from the first set
baz = 4; # 'baz' from the second set
}
]]></programlisting>
</example>
</section>
<section xml:id="function-library-lib.attrsets.recursiveUpdate">
<title><function>lib.attrsets.recursiveUpdate</function></title>
<subtitle><literal>recursiveUpdate :: AttrSet -> AttrSet -> AttrSet</literal>
</subtitle>
<xi:include href="./locations.xml" xpointer="lib.attrsets.recursiveUpdate" />
<para>
A recursive variant of the update operator <literal>//</literal>. The recursion stops when one of the attribute values is not an attribute set, in which case the right hand side value takes precedence over the left hand side value.
</para>
<variablelist>
<varlistentry>
<term>
<varname>lhs</varname>
</term>
<listitem>
<para>
The left hand attribute set of the merge.
</para>
</listitem>
</varlistentry>
<varlistentry>
<term>
<varname>rhs</varname>
</term>
<listitem>
<para>
The right hand attribute set of the merge.
</para>
</listitem>
</varlistentry>
</variablelist>
<example xml:id="function-library-lib.attrsets.recursiveUpdate-example">
<title>Recursively merging two attribute sets</title>
<programlisting><![CDATA[
recursiveUpdate
{
boot.loader.grub.enable = true;
boot.loader.grub.device = "/dev/hda";
}
{
boot.loader.grub.device = "";
}
=> {
boot.loader.grub.enable = true;
boot.loader.grub.device = "";
}
]]></programlisting>
</example>
</section>
</section>

70
doc/functions/nix-gitignore.xml Normal file
View File

@ -0,0 +1,70 @@
<section xmlns="http://docbook.org/ns/docbook"
xmlns:xlink="http://www.w3.org/1999/xlink"
xmlns:xi="http://www.w3.org/2001/XInclude"
xml:id="sec-pkgs-nix-gitignore">
<title>pkgs.nix-gitignore</title>
<para>
<function>pkgs.nix-gitignore</function> is a function that acts similarly to <literal>builtins.filterSource</literal> but also allows filtering with the help of the gitignore format.
</para>
<section xml:id="sec-pkgs-nix-gitignore-usage">
<title>Usage</title>
<para>
<literal>pkgs.nix-gitignore</literal> exports a number of functions, but you'll most likely need either <literal>gitignoreSource</literal> or <literal>gitignoreSourcePure</literal>. As their first argument, they both accept either 1. a file with gitignore lines or 2. a string with gitignore lines, or 3. a list of either of the two. They will be concatenated into a single big string.
</para>
<programlisting><![CDATA[
{ pkgs ? import <nixpkgs> {} }:
nix-gitignore.gitignoreSource [] ./source
# Simplest version
nix-gitignore.gitignoreSource "supplemental-ignores\n" ./source
# This one reads the ./source/.gitignore and concats the auxiliary ignores
nix-gitignore.gitignoreSourcePure "ignore-this\nignore-that\n" ./source
# Use this string as gitignore, don't read ./source/.gitignore.
nix-gitignore.gitignoreSourcePure ["ignore-this\nignore-that\n", ~/.gitignore] ./source
# It also accepts a list (of strings and paths) that will be concatenated
# once the paths are turned to strings via readFile.
]]></programlisting>
<para>
These functions are derived from the <literal>Filter</literal> functions by setting the first filter argument to <literal>(_: _: true)</literal>:
</para>
<programlisting><![CDATA[
gitignoreSourcePure = gitignoreFilterSourcePure (_: _: true);
gitignoreSource = gitignoreFilterSource (_: _: true);
]]></programlisting>
<para>
Those filter functions accept the same arguments the <literal>builtins.filterSource</literal> function would pass to its filters, thus <literal>fn: gitignoreFilterSourcePure fn ""</literal> should be extensionally equivalent to <literal>filterSource</literal>. The file is blacklisted iff it's blacklisted by either your filter or the gitignoreFilter.
</para>
<para>
If you want to make your own filter from scratch, you may use
</para>
<programlisting><![CDATA[
gitignoreFilter = ign: root: filterPattern (gitignoreToPatterns ign) root;
]]></programlisting>
</section>
<section xml:id="sec-pkgs-nix-gitignore-usage-recursive">
<title>gitignore files in subdirectories</title>
<para>
If you wish to use a filter that would search for .gitignore files in subdirectories, just like git does by default, use this function:
</para>
<programlisting><![CDATA[
gitignoreFilterRecursiveSource = filter: patterns: root:
# OR
gitignoreRecursiveSource = gitignoreFilterSourcePure (_: _: true);
]]></programlisting>
</section>
</section>

203
doc/functions/overrides.xml
View File

@ -1,203 +0,0 @@
<section xmlns="http://docbook.org/ns/docbook"
xmlns:xlink="http://www.w3.org/1999/xlink"
xmlns:xi="http://www.w3.org/2001/XInclude"
xml:id="sec-overrides">
<title>Overriding</title>
<para>
Sometimes one wants to override parts of <literal>nixpkgs</literal>, e.g.
derivation attributes, the results of derivations or even the whole package
set.
</para>
<section xml:id="sec-pkg-override">
<title>&lt;pkg&gt;.override</title>
<para>
The function <varname>override</varname> is usually available for all the
derivations in the nixpkgs expression (<varname>pkgs</varname>).
</para>
<para>
It is used to override the arguments passed to a function.
</para>
<para>
Example usages:
<programlisting>pkgs.foo.override { arg1 = val1; arg2 = val2; ... }</programlisting>
<programlisting>
import pkgs.path { overlays = [ (self: super: {
foo = super.foo.override { barSupport = true ; };
})]};
</programlisting>
<programlisting>
mypkg = pkgs.callPackage ./mypkg.nix {
mydep = pkgs.mydep.override { ... };
}
</programlisting>
</para>
<para>
In the first example, <varname>pkgs.foo</varname> is the result of a
function call with some default arguments, usually a derivation. Using
<varname>pkgs.foo.override</varname> will call the same function with the
given new arguments.
</para>
</section>
<section xml:id="sec-pkg-overrideAttrs">
<title>&lt;pkg&gt;.overrideAttrs</title>
<para>
The function <varname>overrideAttrs</varname> allows overriding the
attribute set passed to a <varname>stdenv.mkDerivation</varname> call,
producing a new derivation based on the original one. This function is
available on all derivations produced by the
<varname>stdenv.mkDerivation</varname> function, which is most packages in
the nixpkgs expression <varname>pkgs</varname>.
</para>
<para>
Example usage:
<programlisting>
helloWithDebug = pkgs.hello.overrideAttrs (oldAttrs: rec {
separateDebugInfo = true;
});
</programlisting>
</para>
<para>
In the above example, the <varname>separateDebugInfo</varname> attribute is
overridden to be true, thus building debug info for
<varname>helloWithDebug</varname>, while all other attributes will be
retained from the original <varname>hello</varname> package.
</para>
<para>
The argument <varname>oldAttrs</varname> is conventionally used to refer to
the attr set originally passed to <varname>stdenv.mkDerivation</varname>.
</para>
<note>
<para>
Note that <varname>separateDebugInfo</varname> is processed only by the
<varname>stdenv.mkDerivation</varname> function, not the generated, raw Nix
derivation. Thus, using <varname>overrideDerivation</varname> will not work
in this case, as it overrides only the attributes of the final derivation.
It is for this reason that <varname>overrideAttrs</varname> should be
preferred in (almost) all cases to <varname>overrideDerivation</varname>,
i.e. to allow using <varname>sdenv.mkDerivation</varname> to process input
arguments, as well as the fact that it is easier to use (you can use the
same attribute names you see in your Nix code, instead of the ones
generated (e.g. <varname>buildInputs</varname> vs
<varname>nativeBuildInputs</varname>, and involves less typing.
</para>
</note>
</section>
<section xml:id="sec-pkg-overrideDerivation">
<title>&lt;pkg&gt;.overrideDerivation</title>
<warning>
<para>
You should prefer <varname>overrideAttrs</varname> in almost all cases, see
its documentation for the reasons why.
<varname>overrideDerivation</varname> is not deprecated and will continue
to work, but is less nice to use and does not have as many abilities as
<varname>overrideAttrs</varname>.
</para>
</warning>
<warning>
<para>
Do not use this function in Nixpkgs as it evaluates a Derivation before
modifying it, which breaks package abstraction and removes error-checking
of function arguments. In addition, this evaluation-per-function
application incurs a performance penalty, which can become a problem if
many overrides are used. It is only intended for ad-hoc customisation, such
as in <filename>~/.config/nixpkgs/config.nix</filename>.
</para>
</warning>
<para>
The function <varname>overrideDerivation</varname> creates a new derivation
based on an existing one by overriding the original's attributes with the
attribute set produced by the specified function. This function is available
on all derivations defined using the <varname>makeOverridable</varname>
function. Most standard derivation-producing functions, such as
<varname>stdenv.mkDerivation</varname>, are defined using this function,
which means most packages in the nixpkgs expression,
<varname>pkgs</varname>, have this function.
</para>
<para>
Example usage:
<programlisting>
mySed = pkgs.gnused.overrideDerivation (oldAttrs: {
name = "sed-4.2.2-pre";
src = fetchurl {
url = ftp://alpha.gnu.org/gnu/sed/sed-4.2.2-pre.tar.bz2;
sha256 = "11nq06d131y4wmf3drm0yk502d2xc6n5qy82cg88rb9nqd2lj41k";
};
patches = [];
});
</programlisting>
</para>
<para>
In the above example, the <varname>name</varname>, <varname>src</varname>,
and <varname>patches</varname> of the derivation will be overridden, while
all other attributes will be retained from the original derivation.
</para>
<para>
The argument <varname>oldAttrs</varname> is used to refer to the attribute
set of the original derivation.
</para>
<note>
<para>
A package's attributes are evaluated *before* being modified by the
<varname>overrideDerivation</varname> function. For example, the
<varname>name</varname> attribute reference in <varname>url =
"mirror://gnu/hello/${name}.tar.gz";</varname> is filled-in *before* the
<varname>overrideDerivation</varname> function modifies the attribute set.
This means that overriding the <varname>name</varname> attribute, in this
example, *will not* change the value of the <varname>url</varname>
attribute. Instead, we need to override both the <varname>name</varname>
*and* <varname>url</varname> attributes.
</para>
</note>
</section>
<section xml:id="sec-lib-makeOverridable">
<title>lib.makeOverridable</title>
<para>
The function <varname>lib.makeOverridable</varname> is used to make the
result of a function easily customizable. This utility only makes sense for
functions that accept an argument set and return an attribute set.
</para>
<para>
Example usage:
<programlisting>
f = { a, b }: { result = a+b; };
c = lib.makeOverridable f { a = 1; b = 2; };
</programlisting>
</para>
<para>
The variable <varname>c</varname> is the value of the <varname>f</varname>
function applied with some default arguments. Hence the value of
<varname>c.result</varname> is <literal>3</literal>, in this example.
</para>
<para>
The variable <varname>c</varname> however also has some additional
functions, like <link linkend="sec-pkg-override">c.override</link> which can
be used to override the default arguments. In this example the value of
<varname>(c.override { a = 4; }).result</varname> is 6.
</para>
</section>
</section>

21
doc/functions/prefer-remote-fetch.xml Normal file
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@ -0,0 +1,21 @@
<section xmlns="http://docbook.org/ns/docbook"
xmlns:xlink="http://www.w3.org/1999/xlink"
xmlns:xi="http://www.w3.org/2001/xinclude"
xml:id="sec-prefer-remote-fetch">
<title>prefer-remote-fetch overlay</title>
<para>
<function>prefer-remote-fetch</function> is an overlay that download sources on remote builder. This is useful when the evaluating machine has a slow upload while the builder can fetch faster directly from the source. To use it, put the following snippet as a new overlay:
<programlisting>
self: super:
(super.prefer-remote-fetch self super)
</programlisting>
A full configuration example for that sets the overlay up for your own account, could look like this
<screen>
<prompt>$ </prompt>mkdir ~/.config/nixpkgs/overlays/
<prompt>$ </prompt>cat &gt; ~/.config/nixpkgs/overlays/prefer-remote-fetch.nix &lt;&lt;EOF
self: super: super.prefer-remote-fetch self super
EOF
</screen>
</para>
</section>

26
doc/functions/shell.xml
View File

@ -1,26 +0,0 @@
<section xmlns="http://docbook.org/ns/docbook"
xmlns:xlink="http://www.w3.org/1999/xlink"
xmlns:xi="http://www.w3.org/2001/XInclude"
xml:id="sec-pkgs-mkShell">
<title>pkgs.mkShell</title>
<para>
<function>pkgs.mkShell</function> is a special kind of derivation that is
only useful when using it combined with <command>nix-shell</command>. It will
in fact fail to instantiate when invoked with <command>nix-build</command>.
</para>
<section xml:id="sec-pkgs-mkShell-usage">
<title>Usage</title>
<programlisting><![CDATA[
{ pkgs ? import <nixpkgs> {} }:
pkgs.mkShell {
# this will make all the build inputs from hello and gnutar
# available to the shell environment
inputsFrom = with pkgs; [ hello gnutar ];
buildInputs = [ pkgs.gnumake ];
}
]]></programlisting>
</section>
</section>

4
doc/introduction.chapter.md
View File

@ -47,5 +47,5 @@ which also builds binary packages from the Nix expressions in Nixpkgs for
The binaries are made available via a [binary cache](https://cache.nixos.org).
The current Nix expressions of the channels are available in the
[`nixpkgs-channels`](https://github.com/NixOS/nixpkgs-channels) repository,
which has branches corresponding to the available channels.
[`nixpkgs`](https://github.com/NixOS/nixpkgs) repository in branches
that correspond to the channel names (e.g. `nixos-19.09-small`).

239
doc/languages-frameworks/android.section.md Normal file
View File

@ -0,0 +1,239 @@
---
title: Android
author: Sander van der Burg
date: 2018-11-18
---
# Android
The Android build environment provides three major features and a number of
supporting features.
Deploying an Android SDK installation with plugins
--------------------------------------------------
The first use case is deploying the SDK with a desired set of plugins or subsets
of an SDK.
```nix
with import <nixpkgs> {};
let
androidComposition = androidenv.composeAndroidPackages {
toolsVersion = "25.2.5";
platformToolsVersion = "27.0.1";
buildToolsVersions = [ "27.0.3" ];
includeEmulator = false;
emulatorVersion = "27.2.0";
platformVersions = [ "24" ];
includeSources = false;
includeDocs = false;
includeSystemImages = false;
systemImageTypes = [ "default" ];
abiVersions = [ "armeabi-v7a" ];
lldbVersions = [ "2.0.2558144" ];
cmakeVersions = [ "3.6.4111459" ];
includeNDK = false;
ndkVersion = "16.1.4479499";
useGoogleAPIs = false;
useGoogleTVAddOns = false;
includeExtras = [
"extras;google;gcm"
];
};
in
androidComposition.androidsdk
```
The above function invocation states that we want an Android SDK with the above
specified plugin versions. By default, most plugins are disabled. Notable
exceptions are the tools, platform-tools and build-tools sub packages.
The following parameters are supported:
* `toolsVersion`, specifies the version of the tools package to use
* `platformsToolsVersion` specifies the version of the `platform-tools` plugin
* `buildToolsVersion` specifies the versions of the `build-tools` plugins to
use.
* `includeEmulator` specifies whether to deploy the emulator package (`false`
by default). When enabled, the version of the emulator to deploy can be
specified by setting the `emulatorVersion` parameter.
* `includeDocs` specifies whether the documentation catalog should be included.
* `lldbVersions` specifies what LLDB versions should be deployed.
* `cmakeVersions` specifies which CMake versions should be deployed.
* `includeNDK` specifies that the Android NDK bundle should be included.
Defaults to: `false`.
* `ndkVersion` specifies the NDK version that we want to use.
* `includeExtras` is an array of identifier strings referring to arbitrary
add-on packages that should be installed.
* `platformVersions` specifies which platform SDK versions should be included.
For each platform version that has been specified, we can apply the following
options:
* `includeSystemImages` specifies whether a system image for each platform SDK
should be included.
* `includeSources` specifies whether the sources for each SDK version should be
included.
* `useGoogleAPIs` specifies that for each selected platform version the
Google API should be included.
* `useGoogleTVAddOns` specifies that for each selected platform version the
Google TV add-on should be included.
For each requested system image we can specify the following options:
* `systemImageTypes` specifies what kind of system images should be included.
Defaults to: `default`.
* `abiVersions` specifies what kind of ABI version of each system image should
be included. Defaults to: `armeabi-v7a`.
Most of the function arguments have reasonable default settings.
When building the above expression with:
```bash
$ nix-build
```
The Android SDK gets deployed with all desired plugin versions.
We can also deploy subsets of the Android SDK. For example, to only the the
`platform-tools` package, you can evaluate the following expression:
```nix
with import <nixpkgs> {};
let
androidComposition = androidenv.composeAndroidPackages {
# ...
};
in
androidComposition.platform-tools
```
Using predefine Android package compositions
--------------------------------------------
In addition to composing an Android package set manually, it is also possible
to use a predefined composition that contains all basic packages for a specific
Android version, such as version 9.0 (API-level 28).
The following Nix expression can be used to deploy the entire SDK with all basic
plugins:
```nix
with import <nixpkgs> {};
androidenv.androidPkgs_9_0.androidsdk
```
It is also possible to use one plugin only:
```nix
with import <nixpkgs> {};
androidenv.androidPkgs_9_0.platform-tools
```
Building an Android application
-------------------------------
In addition to the SDK, it is also possible to build an Ant-based Android
project and automatically deploy all the Android plugins that a project
requires.
```nix
with import <nixpkgs> {};
androidenv.buildApp {
name = "MyAndroidApp";
src = ./myappsources;
release = true;
# If release is set to true, you need to specify the following parameters
keyStore = ./keystore;
keyAlias = "myfirstapp";
keyStorePassword = "mykeystore";
keyAliasPassword = "myfirstapp";
# Any Android SDK parameters that install all the relevant plugins that a
# build requires
platformVersions = [ "24" ];
# When we include the NDK, then ndk-build is invoked before Ant gets invoked
includeNDK = true;
}
```
Aside from the app-specific build parameters (`name`, `src`, `release` and
keystore parameters), the `buildApp {}` function supports all the function
parameters that the SDK composition function (the function shown in the
previous section) supports.
This build function is particularly useful when it is desired to use
[Hydra](http://nixos.org/hydra): the Nix-based continuous integration solution
to build Android apps. An Android APK gets exposed as a build product and can be
installed on any Android device with a web browser by navigating to the build
result page.
Spawning emulator instances
---------------------------
For testing purposes, it can also be quite convenient to automatically generate
scripts that spawn emulator instances with all desired configuration settings.
An emulator spawn script can be configured by invoking the `emulateApp {}`
function:
```nix
with import <nixpkgs> {};
androidenv.emulateApp {
name = "emulate-MyAndroidApp";
platformVersion = "28";
abiVersion = "x86_64"; # armeabi-v7a, mips, x86
systemImageType = "google_apis_playstore";
}
```
It is also possible to specify an APK to deploy inside the emulator
and the package and activity names to launch it:
```nix
with import <nixpkgs> {};
androidenv.emulateApp {
name = "emulate-MyAndroidApp";
platformVersion = "24";
abiVersion = "armeabi-v7a"; # mips, x86, x86_64
systemImageType = "default";
useGoogleAPIs = false;
app = ./MyApp.apk;
package = "MyApp";
activity = "MainActivity";
}
```
In addition to prebuilt APKs, you can also bind the APK parameter to a
`buildApp {}` function invocation shown in the previous example.
Querying the available versions of each plugin
----------------------------------------------
When using any of the previously shown functions, it may be a bit inconvenient
to find out what options are supported, since the Android SDK provides many
plugins.
A shell script in the `pkgs/development/mobile/androidenv/` sub directory can be used to retrieve all
possible options:
```bash
sh ./querypackages.sh packages build-tools
```
The above command-line instruction queries all build-tools versions in the
generated `packages.nix` expression.
Updating the generated expressions
----------------------------------
Most of the Nix expressions are generated from XML files that the Android
package manager uses. To update the expressions run the `generate.sh` script
that is stored in the `pkgs/development/mobile/androidenv/` sub directory:
```bash
sh ./generate.sh
```

408
doc/languages-frameworks/beam.xml
View File

@ -7,12 +7,7 @@
<title>Introduction</title>
<para>
In this document and related Nix expressions, we use the term,
<emphasis>BEAM</emphasis>, to describe the environment. BEAM is the name of
the Erlang Virtual Machine and, as far as we're concerned, from a packaging
perspective, all languages that run on the BEAM are interchangeable. That
which varies, like the build system, is transparent to users of any given
BEAM package, so we make no distinction.
In this document and related Nix expressions, we use the term, <emphasis>BEAM</emphasis>, to describe the environment. BEAM is the name of the Erlang Virtual Machine and, as far as we're concerned, from a packaging perspective, all languages that run on the BEAM are interchangeable. That which varies, like the build system, is transparent to users of any given BEAM package, so we make no distinction.
</para>
</section>
@ -20,57 +15,36 @@
<title>Structure</title>
<para>
All BEAM-related expressions are available via the top-level
<literal>beam</literal> attribute, which includes:
All BEAM-related expressions are available via the top-level <literal>beam</literal> attribute, which includes:
</para>
<itemizedlist>
<listitem>
<para>
<literal>interpreters</literal>: a set of compilers running on the BEAM,
including multiple Erlang/OTP versions
(<literal>beam.interpreters.erlangR19</literal>, etc), Elixir
(<literal>beam.interpreters.elixir</literal>) and LFE
(<literal>beam.interpreters.lfe</literal>).
<literal>interpreters</literal>: a set of compilers running on the BEAM, including multiple Erlang/OTP versions (<literal>beam.interpreters.erlangR19</literal>, etc), Elixir (<literal>beam.interpreters.elixir</literal>) and LFE (<literal>beam.interpreters.lfe</literal>).
</para>
</listitem>
<listitem>
<para>
<literal>packages</literal>: a set of package sets, each compiled with a
specific Erlang/OTP version, e.g.
<literal>beam.packages.erlangR19</literal>.
<literal>packages</literal>: a set of package sets, each compiled with a specific Erlang/OTP version, e.g. <literal>beam.packages.erlangR19</literal>.
</para>
</listitem>
</itemizedlist>
<para>
The default Erlang compiler, defined by
<literal>beam.interpreters.erlang</literal>, is aliased as
<literal>erlang</literal>. The default BEAM package set is defined by
<literal>beam.packages.erlang</literal> and aliased at the top level as
<literal>beamPackages</literal>.
The default Erlang compiler, defined by <literal>beam.interpreters.erlang</literal>, is aliased as <literal>erlang</literal>. The default BEAM package set is defined by <literal>beam.packages.erlang</literal> and aliased at the top level as <literal>beamPackages</literal>.
</para>
<para>
To create a package set built with a custom Erlang version, use the lambda,
<literal>beam.packagesWith</literal>, which accepts an Erlang/OTP derivation
and produces a package set similar to
<literal>beam.packages.erlang</literal>.
To create a package set built with a custom Erlang version, use the lambda, <literal>beam.packagesWith</literal>, which accepts an Erlang/OTP derivation and produces a package set similar to <literal>beam.packages.erlang</literal>.
</para>
<para>
Many Erlang/OTP distributions available in
<literal>beam.interpreters</literal> have versions with ODBC and/or Java
enabled. For example, there's
<literal>beam.interpreters.erlangR19_odbc_javac</literal>, which corresponds
to <literal>beam.interpreters.erlangR19</literal>.
Many Erlang/OTP distributions available in <literal>beam.interpreters</literal> have versions with ODBC and/or Java enabled. For example, there's <literal>beam.interpreters.erlangR19_odbc_javac</literal>, which corresponds to <literal>beam.interpreters.erlangR19</literal>.
</para>
<para xml:id="erlang-call-package">
We also provide the lambda,
<literal>beam.packages.erlang.callPackage</literal>, which simplifies
writing BEAM package definitions by injecting all packages from
<literal>beam.packages.erlang</literal> into the top-level context.
We also provide the lambda, <literal>beam.packages.erlang.callPackage</literal>, which simplifies writing BEAM package definitions by injecting all packages from <literal>beam.packages.erlang</literal> into the top-level context.
</para>
</section>
@ -81,28 +55,7 @@
<title>Rebar3</title>
<para>
By default, Rebar3 wants to manage its own dependencies. This is perfectly
acceptable in the normal, non-Nix setup, but in the Nix world, it is not.
To rectify this, we provide two versions of Rebar3:
<itemizedlist>
<listitem>
<para>
<literal>rebar3</literal>: patched to remove the ability to download
anything. When not running it via <literal>nix-shell</literal> or
<literal>nix-build</literal>, it's probably not going to work as
desired.
</para>
</listitem>
<listitem>
<para>
<literal>rebar3-open</literal>: the normal, unmodified Rebar3. It should
work exactly as would any other version of Rebar3. Any Erlang package
should rely on <literal>rebar3</literal> instead. See
<xref
linkend="rebar3-packages"/>.
</para>
</listitem>
</itemizedlist>
We provide a version of Rebar3, which is the normal, unmodified Rebar3, under <literal>rebar3</literal>. We also provide a helper to fetch Rebar3 dependencies from a lockfile under <literal>fetchRebar3Deps</literal>.
</para>
</section>
@ -110,10 +63,7 @@
<title>Mix &amp; Erlang.mk</title>
<para>
Both Mix and Erlang.mk work exactly as expected. There is a bootstrap
process that needs to be run for both, however, which is supported by the
<literal>buildMix</literal> and <literal>buildErlangMk</literal>
derivations, respectively.
Both Mix and Erlang.mk work exactly as expected. There is a bootstrap process that needs to be run for both, however, which is supported by the <literal>buildMix</literal> and <literal>buildErlangMk</literal> derivations, respectively.
</para>
</section>
</section>
@ -122,17 +72,11 @@
<title>How to Install BEAM Packages</title>
<para>
BEAM packages are not registered at the top level, simply because they are
not relevant to the vast majority of Nix users. They are installable using
the <literal>beam.packages.erlang</literal> attribute set (aliased as
<literal>beamPackages</literal>), which points to packages built by the
default Erlang/OTP version in Nixpkgs, as defined by
<literal>beam.interpreters.erlang</literal>. To list the available packages
in <literal>beamPackages</literal>, use the following command:
BEAM packages are not registered at the top level, simply because they are not relevant to the vast majority of Nix users. They are installable using the <literal>beam.packages.erlang</literal> attribute set (aliased as <literal>beamPackages</literal>), which points to packages built by the default Erlang/OTP version in Nixpkgs, as defined by <literal>beam.interpreters.erlang</literal>. To list the available packages in <literal>beamPackages</literal>, use the following command:
</para>
<programlisting>
$ nix-env -f &quot;&lt;nixpkgs&gt;&quot; -qaP -A beamPackages
<screen>
<prompt>$ </prompt>nix-env -f &quot;&lt;nixpkgs&gt;&quot; -qaP -A beamPackages
beamPackages.esqlite esqlite-0.2.1
beamPackages.goldrush goldrush-0.1.7
beamPackages.ibrowse ibrowse-4.2.2
@ -140,21 +84,18 @@ beamPackages.jiffy jiffy-0.14.5
beamPackages.lager lager-3.0.2
beamPackages.meck meck-0.8.3
beamPackages.rebar3-pc pc-1.1.0
</programlisting>
</screen>
<para>
To install any of those packages into your profile, refer to them by their
attribute path (first column):
To install any of those packages into your profile, refer to them by their attribute path (first column):
</para>
<programlisting>
$ nix-env -f &quot;&lt;nixpkgs&gt;&quot; -iA beamPackages.ibrowse
</programlisting>
<screen>
<prompt>$ </prompt>nix-env -f &quot;&lt;nixpkgs&gt;&quot; -iA beamPackages.ibrowse
</screen>
<para>
The attribute path of any BEAM package corresponds to the name of that
particular package in <link xlink:href="https://hex.pm">Hex</link> or its
OTP Application/Release name.
The attribute path of any BEAM package corresponds to the name of that particular package in <link xlink:href="https://hex.pm">Hex</link> or its OTP Application/Release name.
</para>
</section>
@ -168,53 +109,39 @@ $ nix-env -f &quot;&lt;nixpkgs&gt;&quot; -iA beamPackages.ibrowse
<title>Rebar3 Packages</title>
<para>
The Nix function, <literal>buildRebar3</literal>, defined in
<literal>beam.packages.erlang.buildRebar3</literal> and aliased at the top
level, can be used to build a derivation that understands how to build a
Rebar3 project. For example, we can build
<link
xlink:href="https://github.com/erlang-nix/hex2nix">hex2nix</link>
as follows:
The Nix function, <literal>buildRebar3</literal>, defined in <literal>beam.packages.erlang.buildRebar3</literal> and aliased at the top level, can be used to build a derivation that understands how to build a Rebar3 project. For example, we can build <link
xlink:href="https://github.com/erlang-nix/hex2nix">hex2nix</link> as follows:
</para>
<programlisting>
{ stdenv, fetchFromGitHub, buildRebar3, ibrowse, jsx, erlware_commons }:
{ stdenv, fetchFromGitHub, buildRebar3, ibrowse, jsx, erlware_commons }:
buildRebar3 rec {
name = "hex2nix";
version = "0.0.1";
buildRebar3 rec {
name = "hex2nix";
version = "0.0.1";
src = fetchFromGitHub {
owner = "ericbmerritt";
repo = "hex2nix";
rev = "${version}";
sha256 = "1w7xjidz1l5yjmhlplfx7kphmnpvqm67w99hd2m7kdixwdxq0zqg";
};
src = fetchFromGitHub {
owner = "ericbmerritt";
repo = "hex2nix";
rev = "${version}";
sha256 = "1w7xjidz1l5yjmhlplfx7kphmnpvqm67w99hd2m7kdixwdxq0zqg";
};
beamDeps = [ ibrowse jsx erlware_commons ];
}
</programlisting>
beamDeps = [ ibrowse jsx erlware_commons ];
}
</programlisting>
<para>
Such derivations are callable with
<literal>beam.packages.erlang.callPackage</literal> (see
<xref
linkend="erlang-call-package"/>). To call this package using
the normal <literal>callPackage</literal>, refer to dependency packages
via <literal>beamPackages</literal>, e.g.
<literal>beamPackages.ibrowse</literal>.
Such derivations are callable with <literal>beam.packages.erlang.callPackage</literal> (see <xref
linkend="erlang-call-package"/>). To call this package using the normal <literal>callPackage</literal>, refer to dependency packages via <literal>beamPackages</literal>, e.g. <literal>beamPackages.ibrowse</literal>.
</para>
<para>
Notably, <literal>buildRebar3</literal> includes
<literal>beamDeps</literal>, while <literal>stdenv.mkDerivation</literal>
does not. BEAM dependencies added there will be correctly handled by the
system.
Notably, <literal>buildRebar3</literal> includes <literal>beamDeps</literal>, while <literal>stdenv.mkDerivation</literal> does not. BEAM dependencies added there will be correctly handled by the system.
</para>
<para>
If a package needs to compile native code via Rebar3's port compilation
mechanism, add <literal>compilePort = true;</literal> to the derivation.
If a package needs to compile native code via Rebar3's port compilation mechanism, add <literal>compilePort = true;</literal> to the derivation.
</para>
</section>
@ -222,96 +149,93 @@ $ nix-env -f &quot;&lt;nixpkgs&gt;&quot; -iA beamPackages.ibrowse
<title>Erlang.mk Packages</title>
<para>
Erlang.mk functions similarly to Rebar3, except we use
<literal>buildErlangMk</literal> instead of
<literal>buildRebar3</literal>.
Erlang.mk functions similarly to Rebar3, except we use <literal>buildErlangMk</literal> instead of <literal>buildRebar3</literal>.
</para>
<programlisting>
{ buildErlangMk, fetchHex, cowlib, ranch }:
{ buildErlangMk, fetchHex, cowlib, ranch }:
buildErlangMk {
name = "cowboy";
version = "1.0.4";
buildErlangMk {
name = "cowboy";
version = "1.0.4";
src = fetchHex {
pkg = "cowboy";
version = "1.0.4";
sha256 = "6a0edee96885fae3a8dd0ac1f333538a42e807db638a9453064ccfdaa6b9fdac";
};
src = fetchHex {
pkg = "cowboy";
version = "1.0.4";
sha256 = "6a0edee96885fae3a8dd0ac1f333538a42e807db638a9453064ccfdaa6b9fdac";
};
beamDeps = [ cowlib ranch ];
beamDeps = [ cowlib ranch ];
meta = {
description = ''
Small, fast, modular HTTP server written in Erlang
'';
license = stdenv.lib.licenses.isc;
homepage = https://github.com/ninenines/cowboy;
};
}
</programlisting>
meta = {
description = ''
Small, fast, modular HTTP server written in Erlang
'';
license = stdenv.lib.licenses.isc;
homepage = https://github.com/ninenines/cowboy;
};
}
</programlisting>
</section>
<section xml:id="mix-packages">
<title>Mix Packages</title>
<para>
Mix functions similarly to Rebar3, except we use
<literal>buildMix</literal> instead of <literal>buildRebar3</literal>.
Mix functions similarly to Rebar3, except we use <literal>buildMix</literal> instead of <literal>buildRebar3</literal>.
</para>
<programlisting>
{ buildMix, fetchHex, plug, absinthe }:
{ buildMix, fetchHex, plug, absinthe }:
buildMix {
name = "absinthe_plug";
version = "1.0.0";
buildMix {
name = "absinthe_plug";
version = "1.0.0";
src = fetchHex {
pkg = "absinthe_plug";
version = "1.0.0";
sha256 = "08459823fe1fd4f0325a8bf0c937a4520583a5a26d73b193040ab30a1dfc0b33";
};
src = fetchHex {
pkg = "absinthe_plug";
version = "1.0.0";
sha256 = "08459823fe1fd4f0325a8bf0c937a4520583a5a26d73b193040ab30a1dfc0b33";
};
beamDeps = [ plug absinthe ];
beamDeps = [ plug absinthe ];
meta = {
description = ''
A plug for Absinthe, an experimental GraphQL toolkit
'';
license = stdenv.lib.licenses.bsd3;
homepage = https://github.com/CargoSense/absinthe_plug;
};
}
</programlisting>
meta = {
description = ''
A plug for Absinthe, an experimental GraphQL toolkit
'';
license = stdenv.lib.licenses.bsd3;
homepage = https://github.com/CargoSense/absinthe_plug;
};
}
</programlisting>
<para>
Alternatively, we can use <literal>buildHex</literal> as a shortcut:
</para>
<programlisting>
{ buildHex, buildMix, plug, absinthe }:
{ buildHex, buildMix, plug, absinthe }:
buildHex {
name = "absinthe_plug";
version = "1.0.0";
buildHex {
name = "absinthe_plug";
version = "1.0.0";
sha256 = "08459823fe1fd4f0325a8bf0c937a4520583a5a26d73b193040ab30a1dfc0b33";
sha256 = "08459823fe1fd4f0325a8bf0c937a4520583a5a26d73b193040ab30a1dfc0b33";
builder = buildMix;
builder = buildMix;
beamDeps = [ plug absinthe ];
beamDeps = [ plug absinthe ];
meta = {
description = ''
A plug for Absinthe, an experimental GraphQL toolkit
'';
license = stdenv.lib.licenses.bsd3;
homepage = https://github.com/CargoSense/absinthe_plug;
};
}
</programlisting>
meta = {
description = ''
A plug for Absinthe, an experimental GraphQL toolkit
'';
license = stdenv.lib.licenses.bsd3;
homepage = https://github.com/CargoSense/absinthe_plug;
};
}
</programlisting>
</section>
</section>
</section>
@ -323,58 +247,53 @@ $ nix-env -f &quot;&lt;nixpkgs&gt;&quot; -iA beamPackages.ibrowse
<title>Accessing an Environment</title>
<para>
Often, we simply want to access a valid environment that contains a
specific package and its dependencies. We can accomplish that with the
<literal>env</literal> attribute of a derivation. For example, let's say we
want to access an Erlang REPL with <literal>ibrowse</literal> loaded up. We
could do the following:
Often, we simply want to access a valid environment that contains a specific package and its dependencies. We can accomplish that with the <literal>env</literal> attribute of a derivation. For example, let's say we want to access an Erlang REPL with <literal>ibrowse</literal> loaded up. We could do the following:
</para>
<programlisting>
$ nix-shell -A beamPackages.ibrowse.env --run "erl"
Erlang/OTP 18 [erts-7.0] [source] [64-bit] [smp:4:4] [async-threads:10] [hipe] [kernel-poll:false]
<screen>
<prompt>$ </prompt><userinput>nix-shell -A beamPackages.ibrowse.env --run "erl"</userinput>
<computeroutput>Erlang/OTP 18 [erts-7.0] [source] [64-bit] [smp:4:4] [async-threads:10] [hipe] [kernel-poll:false]
Eshell V7.0 (abort with ^G)
1> m(ibrowse).
Module: ibrowse
MD5: 3b3e0137d0cbb28070146978a3392945
Compiled: January 10 2016, 23:34
Object file: /nix/store/g1rlf65rdgjs4abbyj4grp37ry7ywivj-ibrowse-4.2.2/lib/erlang/lib/ibrowse-4.2.2/ebin/ibrowse.beam
Compiler options: [{outdir,"/tmp/nix-build-ibrowse-4.2.2.drv-0/hex-source-ibrowse-4.2.2/_build/default/lib/ibrowse/ebin"},
debug_info,debug_info,nowarn_shadow_vars,
warn_unused_import,warn_unused_vars,warnings_as_errors,
{i,"/tmp/nix-build-ibrowse-4.2.2.drv-0/hex-source-ibrowse-4.2.2/_build/default/lib/ibrowse/include"}]
Exports:
add_config/1 send_req_direct/7
all_trace_off/0 set_dest/3
code_change/3 set_max_attempts/3
get_config_value/1 set_max_pipeline_size/3
get_config_value/2 set_max_sessions/3
get_metrics/0 show_dest_status/0
get_metrics/2 show_dest_status/1
handle_call/3 show_dest_status/2
handle_cast/2 spawn_link_worker_process/1
handle_info/2 spawn_link_worker_process/2
init/1 spawn_worker_process/1
module_info/0 spawn_worker_process/2
module_info/1 start/0
rescan_config/0 start_link/0
rescan_config/1 stop/0
send_req/3 stop_worker_process/1
send_req/4 stream_close/1
send_req/5 stream_next/1
send_req/6 terminate/2
send_req_direct/4 trace_off/0
send_req_direct/5 trace_off/2
send_req_direct/6 trace_on/0
trace_on/2
ok
2>
</programlisting>
Eshell V7.0 (abort with ^G)</computeroutput>
<prompt>1> </prompt><userinput>m(ibrowse).</userinput>
<computeroutput>Module: ibrowse
MD5: 3b3e0137d0cbb28070146978a3392945
Compiled: January 10 2016, 23:34
Object file: /nix/store/g1rlf65rdgjs4abbyj4grp37ry7ywivj-ibrowse-4.2.2/lib/erlang/lib/ibrowse-4.2.2/ebin/ibrowse.beam
Compiler options: [{outdir,"/tmp/nix-build-ibrowse-4.2.2.drv-0/hex-source-ibrowse-4.2.2/_build/default/lib/ibrowse/ebin"},
debug_info,debug_info,nowarn_shadow_vars,
warn_unused_import,warn_unused_vars,warnings_as_errors,
{i,"/tmp/nix-build-ibrowse-4.2.2.drv-0/hex-source-ibrowse-4.2.2/_build/default/lib/ibrowse/include"}]
Exports:
add_config/1 send_req_direct/7
all_trace_off/0 set_dest/3
code_change/3 set_max_attempts/3
get_config_value/1 set_max_pipeline_size/3
get_config_value/2 set_max_sessions/3
get_metrics/0 show_dest_status/0
get_metrics/2 show_dest_status/1
handle_call/3 show_dest_status/2
handle_cast/2 spawn_link_worker_process/1
handle_info/2 spawn_link_worker_process/2
init/1 spawn_worker_process/1
module_info/0 spawn_worker_process/2
module_info/1 start/0
rescan_config/0 start_link/0
rescan_config/1 stop/0
send_req/3 stop_worker_process/1
send_req/4 stream_close/1
send_req/5 stream_next/1
send_req/6 terminate/2
send_req_direct/4 trace_off/0
send_req_direct/5 trace_off/2
send_req_direct/6 trace_on/0
trace_on/2
ok</computeroutput>
<prompt>2></prompt>
</screen>
<para>
Notice the <literal>-A beamPackages.ibrowse.env</literal>. That is the key
to this functionality.
Notice the <literal>-A beamPackages.ibrowse.env</literal>. That is the key to this functionality.
</para>
</section>
@ -382,11 +301,7 @@ $ nix-env -f &quot;&lt;nixpkgs&gt;&quot; -iA beamPackages.ibrowse
<title>Creating a Shell</title>
<para>
Getting access to an environment often isn't enough to do real development.
Usually, we need to create a <literal>shell.nix</literal> file and do our
development inside of the environment specified therein. This file looks a
lot like the packaging described above, except that <literal>src</literal>
points to the project root and we call the package directly.
Getting access to an environment often isn't enough to do real development. Usually, we need to create a <literal>shell.nix</literal> file and do our development inside of the environment specified therein. This file looks a lot like the packaging described above, except that <literal>src</literal> points to the project root and we call the package directly.
</para>
<programlisting>
@ -408,14 +323,13 @@ let
in
drv
</programlisting>
</programlisting>
<section xml:id="building-in-a-shell">
<title>Building in a Shell (for Mix Projects)</title>
<para>
We can leverage the support of the derivation, irrespective of the build
derivation, by calling the commands themselves.
We can leverage the support of the derivation, irrespective of the build derivation, by calling the commands themselves.
</para>
<programlisting>
@ -474,15 +388,11 @@ plt:
analyze: build plt
$(NIX_SHELL) --run "mix dialyzer --no-compile"
</programlisting>
</programlisting>
<para>
Using a <literal>shell.nix</literal> as described (see
<xref
linkend="creating-a-shell"/>) should just work. Aside from
<literal>test</literal>, <literal>plt</literal>, and
<literal>analyze</literal>, the Make targets work just fine for all of the
build derivations.
Using a <literal>shell.nix</literal> as described (see <xref
linkend="creating-a-shell"/>) should just work. Aside from <literal>test</literal>, <literal>plt</literal>, and <literal>analyze</literal>, the Make targets work just fine for all of the build derivations.
</para>
</section>
</section>
@ -492,37 +402,23 @@ analyze: build plt
<title>Generating Packages from Hex with <literal>hex2nix</literal></title>
<para>
Updating the <link xlink:href="https://hex.pm">Hex</link> package set
requires
<link
xlink:href="https://github.com/erlang-nix/hex2nix">hex2nix</link>.
Given the path to the Erlang modules (usually
<literal>pkgs/development/erlang-modules</literal>), it will dump a file
called <literal>hex-packages.nix</literal>, containing all the packages that
use a recognized build system in
<link
xlink:href="https://hex.pm">Hex</link>. It can't be determined,
however, whether every package is buildable.
Updating the <link xlink:href="https://hex.pm">Hex</link> package set requires <link
xlink:href="https://github.com/erlang-nix/hex2nix">hex2nix</link>. Given the path to the Erlang modules (usually <literal>pkgs/development/erlang-modules</literal>), it will dump a file called <literal>hex-packages.nix</literal>, containing all the packages that use a recognized build system in <link
xlink:href="https://hex.pm">Hex</link>. It can't be determined, however, whether every package is buildable.
</para>
<para>
To make life easier for our users, try to build every
<link
xlink:href="https://hex.pm">Hex</link> package and remove those
that fail. To do that, simply run the following command in the root of your
<literal>nixpkgs</literal> repository:
To make life easier for our users, try to build every <link
xlink:href="https://hex.pm">Hex</link> package and remove those that fail. To do that, simply run the following command in the root of your <literal>nixpkgs</literal> repository:
</para>
<programlisting>
$ nix-build -A beamPackages
</programlisting>
<screen>
<prompt>$ </prompt>nix-build -A beamPackages
</screen>
<para>
That will attempt to build every package in <literal>beamPackages</literal>.
Then manually remove those that fail. Hopefully, someone will improve
<link
xlink:href="https://github.com/erlang-nix/hex2nix">hex2nix</link>
in the future to automate the process.
That will attempt to build every package in <literal>beamPackages</literal>. Then manually remove those that fail. Hopefully, someone will improve <link
xlink:href="https://github.com/erlang-nix/hex2nix">hex2nix</link> in the future to automate the process.
</para>
</section>
</section>

71
doc/languages-frameworks/bower.xml
View File

@ -4,32 +4,22 @@
<title>Bower</title>
<para>
<link xlink:href="http://bower.io">Bower</link> is a package manager for web
site front-end components. Bower packages (comprising of build artefacts and
sometimes sources) are stored in <command>git</command> repositories,
typically on Github. The package registry is run by the Bower team with
package metadata coming from the <filename>bower.json</filename> file within
each package.
<link xlink:href="http://bower.io">Bower</link> is a package manager for web site front-end components. Bower packages (comprising of build artefacts and sometimes sources) are stored in <command>git</command> repositories, typically on Github. The package registry is run by the Bower team with package metadata coming from the <filename>bower.json</filename> file within each package.
</para>
<para>
The end result of running Bower is a <filename>bower_components</filename>
directory which can be included in the web app's build process.
The end result of running Bower is a <filename>bower_components</filename> directory which can be included in the web app's build process.
</para>
<para>
Bower can be run interactively, by installing
<varname>nodePackages.bower</varname>. More interestingly, the Bower
components can be declared in a Nix derivation, with the help of
<varname>nodePackages.bower2nix</varname>.
Bower can be run interactively, by installing <varname>nodePackages.bower</varname>. More interestingly, the Bower components can be declared in a Nix derivation, with the help of <varname>nodePackages.bower2nix</varname>.
</para>
<section xml:id="ssec-bower2nix-usage">
<title><command>bower2nix</command> usage</title>
<para>
Suppose you have a <filename>bower.json</filename> with the following
contents:
Suppose you have a <filename>bower.json</filename> with the following contents:
<example xml:id="ex-bowerJson">
<title><filename>bower.json</filename></title>
<programlisting language="json">
@ -45,8 +35,7 @@
</para>
<para>
Running <command>bower2nix</command> will produce something like the
following output:
Running <command>bower2nix</command> will produce something like the following output:
<programlisting language="nix">
<![CDATA[{ fetchbower, buildEnv }:
buildEnv { name = "bower-env"; ignoreCollisions = true; paths = [
@ -58,15 +47,11 @@ buildEnv { name = "bower-env"; ignoreCollisions = true; paths = [
</para>
<para>
Using the <command>bower2nix</command> command line arguments, the output
can be redirected to a file. A name like
<filename>bower-packages.nix</filename> would be fine.
Using the <command>bower2nix</command> command line arguments, the output can be redirected to a file. A name like <filename>bower-packages.nix</filename> would be fine.
</para>
<para>
The resulting derivation is a union of all the downloaded Bower packages
(and their dependencies). To use it, they still need to be linked together
by Bower, which is where <varname>buildBowerComponents</varname> is useful.
The resulting derivation is a union of all the downloaded Bower packages (and their dependencies). To use it, they still need to be linked together by Bower, which is where <varname>buildBowerComponents</varname> is useful.
</para>
</section>
@ -74,10 +59,7 @@ buildEnv { name = "bower-env"; ignoreCollisions = true; paths = [
<title><varname>buildBowerComponents</varname> function</title>
<para>
The function is implemented in
<link xlink:href="https://github.com/NixOS/nixpkgs/blob/master/pkgs/development/bower-modules/generic/default.nix">
<filename>pkgs/development/bower-modules/generic/default.nix</filename></link>.
Example usage:
The function is implemented in <link xlink:href="https://github.com/NixOS/nixpkgs/blob/master/pkgs/development/bower-modules/generic/default.nix"> <filename>pkgs/development/bower-modules/generic/default.nix</filename></link>. Example usage:
<example xml:id="ex-buildBowerComponents">
<title>buildBowerComponents</title>
<programlisting language="nix">
@ -91,34 +73,27 @@ bowerComponents = buildBowerComponents {
</para>
<para>
In <xref linkend="ex-buildBowerComponents" />, the following arguments are
of special significance to the function:
In <xref linkend="ex-buildBowerComponents" />, the following arguments are of special significance to the function:
<calloutlist>
<callout arearefs="ex-buildBowerComponents-1">
<para>
<varname>generated</varname> specifies the file which was created by
<command>bower2nix</command>.
<varname>generated</varname> specifies the file which was created by <command>bower2nix</command>.
</para>
</callout>
<callout arearefs="ex-buildBowerComponents-2">
<para>
<varname>src</varname> is your project's sources. It needs to contain a
<filename>bower.json</filename> file.
<varname>src</varname> is your project's sources. It needs to contain a <filename>bower.json</filename> file.
</para>
</callout>
</calloutlist>
</para>
<para>
<varname>buildBowerComponents</varname> will run Bower to link together the
output of <command>bower2nix</command>, resulting in a
<filename>bower_components</filename> directory which can be used.
<varname>buildBowerComponents</varname> will run Bower to link together the output of <command>bower2nix</command>, resulting in a <filename>bower_components</filename> directory which can be used.
</para>
<para>
Here is an example of a web frontend build process using
<command>gulp</command>. You might use <command>grunt</command>, or anything
else.
Here is an example of a web frontend build process using <command>gulp</command>. You might use <command>grunt</command>, or anything else.
</para>
<example xml:id="ex-bowerGulpFile">
@ -174,21 +149,17 @@ pkgs.stdenv.mkDerivation {
<calloutlist>
<callout arearefs="ex-buildBowerComponentsDefault-1">
<para>
The result of <varname>buildBowerComponents</varname> is an input to the
frontend build.
The result of <varname>buildBowerComponents</varname> is an input to the frontend build.
</para>
</callout>
<callout arearefs="ex-buildBowerComponentsDefault-2">
<para>
Whether to symlink or copy the <filename>bower_components</filename>
directory depends on the build tool in use. In this case a copy is used
to avoid <command>gulp</command> silliness with permissions.
Whether to symlink or copy the <filename>bower_components</filename> directory depends on the build tool in use. In this case a copy is used to avoid <command>gulp</command> silliness with permissions.
</para>
</callout>
<callout arearefs="ex-buildBowerComponentsDefault-3">
<para>
<command>gulp</command> requires <varname>HOME</varname> to refer to a
writeable directory.
<command>gulp</command> requires <varname>HOME</varname> to refer to a writeable directory.
</para>
</callout>
<callout arearefs="ex-buildBowerComponentsDefault-4">
@ -210,17 +181,13 @@ pkgs.stdenv.mkDerivation {
</term>
<listitem>
<para>
This means that Bower was looking for a package version which doesn't
exist in the generated <filename>bower-packages.nix</filename>.
This means that Bower was looking for a package version which doesn't exist in the generated <filename>bower-packages.nix</filename>.
</para>
<para>
If <filename>bower.json</filename> has been updated, then run
<command>bower2nix</command> again.
If <filename>bower.json</filename> has been updated, then run <command>bower2nix</command> again.
</para>
<para>
It could also be a bug in <command>bower2nix</command> or
<command>fetchbower</command>. If possible, try reformulating the version
specification in <filename>bower.json</filename>.
It could also be a bug in <command>bower2nix</command> or <command>fetchbower</command>. If possible, try reformulating the version specification in <filename>bower.json</filename>.
</para>
</listitem>
</varlistentry>

21
doc/languages-frameworks/coq.xml
View File

@ -4,32 +4,19 @@
<title>Coq</title>
<para>
Coq libraries should be installed in
<literal>$(out)/lib/coq/${coq.coq-version}/user-contrib/</literal>. Such
directories are automatically added to the <literal>$COQPATH</literal>
environment variable by the hook defined in the Coq derivation.
Coq libraries should be installed in <literal>$(out)/lib/coq/${coq.coq-version}/user-contrib/</literal>. Such directories are automatically added to the <literal>$COQPATH</literal> environment variable by the hook defined in the Coq derivation.
</para>
<para>
Some libraries require OCaml and sometimes also Camlp5 or findlib. The exact
versions that were used to build Coq are saved in the
<literal>coq.ocaml</literal> and <literal>coq.camlp5</literal> and
<literal>coq.findlib</literal> attributes.
Some extensions (plugins) might require OCaml and sometimes other OCaml packages. The <literal>coq.ocamlPackages</literal> attribute can be used to depend on the same package set Coq was built against.
</para>
<para>
Coq libraries may be compatible with some specific versions of Coq only. The
<literal>compatibleCoqVersions</literal> attribute is used to precisely
select those versions of Coq that are compatible with this derivation.
Coq libraries may be compatible with some specific versions of Coq only. The <literal>compatibleCoqVersions</literal> attribute is used to precisely select those versions of Coq that are compatible with this derivation.
</para>
<para>
Here is a simple package example. It is a pure Coq library, thus it depends
on Coq. It builds on the Mathematical Components library, thus it also takes
<literal>mathcomp</literal> as <literal>buildInputs</literal>. Its
<literal>Makefile</literal> has been generated using
<literal>coq_makefile</literal> so we only have to set the
<literal>$COQLIB</literal> variable at install time.
Here is a simple package example. It is a pure Coq library, thus it depends on Coq. It builds on the Mathematical Components library, thus it also takes <literal>mathcomp</literal> as <literal>buildInputs</literal>. Its <literal>Makefile</literal> has been generated using <literal>coq_makefile</literal> so we only have to set the <literal>$COQLIB</literal> variable at install time.
</para>
<programlisting>

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# Crystal
## Building a Crystal package
This section uses [Mint](https://github.com/mint-lang/mint) as an example for how to build a Crystal package.
If the Crystal project has any dependencies, the first step is to get a `shards.nix` file encoding those. Get a copy of the project and go to its root directory such that its `shard.lock` file is in the current directory, then run `crystal2nix` in it
```bash
$ git clone https://github.com/mint-lang/mint
$ cd mint
$ git checkout 0.5.0
$ nix-shell -p crystal2nix --run crystal2nix
```
This should have generated a `shards.nix` file.
Next create a Nix file for your derivation and use `pkgs.crystal.buildCrystalPackage` as follows:
```nix
with import <nixpkgs> {};
crystal.buildCrystalPackage rec {
pname = "mint";
version = "0.5.0";
src = fetchFromGitHub {
owner = "mint-lang";
repo = "mint";
rev = version;
sha256 = "0vxbx38c390rd2ysvbwgh89v2232sh5rbsp3nk9wzb70jybpslvl";
};
# Insert the path to your shards.nix file here
shardsFile = ./shards.nix;
...
}
```
This won't build anything yet, because we haven't told it what files build. We can specify a mapping from binary names to source files with the `crystalBinaries` attribute. The project's compilation instructions should show this. For Mint, the binary is called "mint", which is compiled from the source file `src/mint.cr`, so we'll specify this as follows:
```nix
crystalBinaries.mint.src = "src/mint.cr";
# ...
```
Additionally you can override the default `crystal build` options (which are currently `--release --progress --no-debug --verbose`) with
```nix
crystalBinaries.mint.options = [ "--release" "--verbose" ];
```
Depending on the project, you might need additional steps to get it to compile successfully. In Mint's case, we need to link against openssl, so in the end the Nix file looks as follows:
```nix
with import <nixpkgs> {};
crystal.buildCrystalPackage rec {
version = "0.5.0";
pname = "mint";
src = fetchFromGitHub {
owner = "mint-lang";
repo = "mint";
rev = version;
sha256 = "0vxbx38c390rd2ysvbwgh89v2232sh5rbsp3nk9wzb70jybpslvl";
};
shardsFile = ./shards.nix;
crystalBinaries.mint.src = "src/mint.cr";
buildInputs = [ openssl_1_0_2 ];
}
```

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@ -1,4 +1,4 @@
# User's Guide to Emscripten in Nixpkgs
# Emscripten
[Emscripten](https://github.com/kripken/emscripten): An LLVM-to-JavaScript Compiler

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<section xmlns="http://docbook.org/ns/docbook" xmlns:xlink="http://www.w3.org/1999/xlink" xml:id="sec-language-gnome">
<title>GNOME</title>
<section xml:id="ssec-gnome-packaging">
<title>Packaging GNOME applications</title>
<para>
Programs in the GNOME universe are written in various languages but they all use GObject-based libraries like GLib, GTK or GStreamer. These libraries are often modular, relying on looking into certain directories to find their modules. However, due to Nixs specific file system organization, this will fail without our intervention. Fortunately, the libraries usually allow overriding the directories through environment variables, either natively or thanks to a patch in nixpkgs. <link xlink:href="#fun-wrapProgram">Wrapping</link> the executables to ensure correct paths are available to the application constitutes a significant part of packaging a modern desktop application. In this section, we will describe various modules needed by such applications, environment variables needed to make the modules load, and finally a script that will do the work for us.
</para>
<section xml:id="ssec-gnome-settings">
<title>Settings</title>
<para>
<link xlink:href="https://developer.gnome.org/gio/stable/GSettings.html">GSettings</link> API is often used for storing settings. GSettings schemas are required, to know the type and other metadata of the stored values. GLib looks for <filename>glib-2.0/schemas/gschemas.compiled</filename> files inside the directories of <envar>XDG_DATA_DIRS</envar>.
</para>
<para>
On Linux, GSettings API is implemented using <link xlink:href="https://wiki.gnome.org/Projects/dconf">dconf</link> backend. You will need to add <literal>dconf</literal> GIO module to <envar>GIO_EXTRA_MODULES</envar> variable, otherwise the <literal>memory</literal> backend will be used and the saved settings will not be persistent.
</para>
<para>
Last you will need the dconf database D-Bus service itself. You can enable it using <option>programs.dconf.enable</option>.
</para>
<para>
Some applications will also require <package>gsettings-desktop-schemas</package> for things like reading proxy configuration or user interface customization. This dependency is often not mentioned by upstream, you should grep for <literal>org.gnome.desktop</literal> and <literal>org.gnome.system</literal> to see if the schemas are needed.
</para>
</section>
<section xml:id="ssec-gnome-icons">
<title>Icons</title>
<para>
When an application uses icons, an icon theme should be available in <envar>XDG_DATA_DIRS</envar> during runtime. The package for the default, icon-less <link xlink:href="https://www.freedesktop.org/wiki/Software/icon-theme/">hicolor-icon-theme</link> (should be propagated by every icon theme) contains <link linkend="ssec-gnome-hooks-hicolor-icon-theme">a setup hook</link> that will pick up icon themes from <literal>buildInputs</literal> and pass it to our wrapper. Unfortunately, relying on that would mean every user has to download the theme included in the package expression no matter their preference. For that reason, we leave the installation of icon theme on the user. If you use one of the desktop environments, you probably already have an icon theme installed.
</para>
<para>
To avoid costly file system access when locating icons, GTK, <link xlink:href="https://woboq.com/blog/qicon-reads-gtk-icon-cache-in-qt57.html">as well as Qt</link>, can rely on <filename>icon-theme.cache</filename> files from the themes top-level directories. These files are generated using <command>gtk-update-icon-cache</command>, which is expected to be run whenever an icon is added or removed to an icon theme (typically an application icon into <literal>hicolor</literal> theme) and some programs do indeed run this after icon installation. However, since packages are installed into their own prefix by Nix, this would lead to conflicts. For that reason, <package>gtk3</package> provides a <link xlink:href="#ssec-gnome-hooks-gtk-drop-icon-theme-cache">setup hook</link> that will clean the file from installation. Since most applications only ship their own icon that will be loaded on start-up, it should not affect them too much. On the other hand, icon themes are much larger and more widely used so we need to cache them. Because we recommend installing icon themes globally, we will generate the cache files from all packages in a profile using a NixOS module. You can enable the cache generation using <option>gtk.iconCache.enable</option> option if your desktop environment does not already do that.
</para>
</section>
<section xml:id="ssec-gnome-themes">
<title>GTK Themes</title>
<para>
Previously, a GTK theme needed to be in <envar>XDG_DATA_DIRS</envar>. This is no longer necessary for most programs since GTK incorporated Adwaita theme. Some programs (for example, those designed for <link xlink:href="https://elementary.io/docs/human-interface-guidelines#human-interface-guidelines">elementary HIG</link>) might require a special theme like <package>pantheon.elementary-gtk-theme</package>.
</para>
</section>
<section xml:id="ssec-gnome-typelibs">
<title>GObject introspection typelibs</title>
<para>
<link xlink:href="https://wiki.gnome.org/Projects/GObjectIntrospection">GObject introspection</link> allows applications to use C libraries in other languages easily. It does this through <literal>typelib</literal> files searched in <envar>GI_TYPELIB_PATH</envar>.
</para>
</section>
<section xml:id="ssec-gnome-plugins">
<title>Various plug-ins</title>
<para>
If your application uses <link xlink:href="https://gstreamer.freedesktop.org/">GStreamer</link> or <link xlink:href="https://wiki.gnome.org/Projects/Grilo">Grilo</link>, you should set <envar>GST_PLUGIN_SYSTEM_PATH_1_0</envar> and <envar>GRL_PLUGIN_PATH</envar>, respectively.
</para>
</section>
</section>
<section xml:id="ssec-gnome-hooks">
<title>Onto <package>wrapGAppsHook</package></title>
<para>
Given the requirements above, the package expression would become messy quickly:
<programlisting>
preFixup = ''
for f in $(find $out/bin/ $out/libexec/ -type f -executable); do
wrapProgram "$f" \
--prefix GIO_EXTRA_MODULES : "${getLib gnome3.dconf}/lib/gio/modules" \
--prefix XDG_DATA_DIRS : "$out/share" \
--prefix XDG_DATA_DIRS : "$out/share/gsettings-schemas/${name}" \
--prefix XDG_DATA_DIRS : "${gsettings-desktop-schemas}/share/gsettings-schemas/${gsettings-desktop-schemas.name}" \
--prefix XDG_DATA_DIRS : "${hicolor-icon-theme}/share" \
--prefix GI_TYPELIB_PATH : "${lib.makeSearchPath "lib/girepository-1.0" [ pango json-glib ]}"
done
'';
</programlisting>
Fortunately, there is <package>wrapGAppsHook</package>, that does the wrapping for us. In particular, it works in conjunction with other setup hooks that will populate the variable:
<itemizedlist>
<listitem xml:id="ssec-gnome-hooks-wrapgappshook">
<para>
<package>wrapGAppsHook</package> itself will add the packages <filename>share</filename> directory to <envar>XDG_DATA_DIRS</envar>.
</para>
</listitem>
<listitem xml:id="ssec-gnome-hooks-glib">
<para>
<package>glib</package> setup hook will populate <envar>GSETTINGS_SCHEMAS_PATH</envar> and then <package>wrapGAppsHook</package> will prepend it to <envar>XDG_DATA_DIRS</envar>.
</para>
</listitem>
<listitem xml:id="ssec-gnome-hooks-gtk-drop-icon-theme-cache">
<para>
One of <package>gtk3</package>s setup hooks will remove <filename>icon-theme.cache</filename> files from packages icon theme directories to avoid conflicts. Icon theme packages should prevent this with <code>dontDropIconThemeCache = true;</code>.
</para>
</listitem>
<listitem xml:id="ssec-gnome-hooks-dconf">
<para>
<package>gnome3.dconf.lib</package> is a dependency of <package>wrapGAppsHook</package>, which then also adds it to the <envar>GIO_EXTRA_MODULES</envar> variable.
</para>
</listitem>
<listitem xml:id="ssec-gnome-hooks-hicolor-icon-theme">
<para>
<package>hicolor-icon-theme</package>s setup hook will add icon themes to <envar>XDG_ICON_DIRS</envar> which is prepended to <envar>XDG_DATA_DIRS</envar> by <package>wrapGAppsHook</package>.
</para>
</listitem>
<listitem xml:id="ssec-gnome-hooks-gobject-introspection">
<para>
<package>gobject-introspection</package> setup hook populates <envar>GI_TYPELIB_PATH</envar> variable with <filename>lib/girepository-1.0</filename> directories of dependencies, which is then added to wrapper by <package>wrapGAppsHook</package>. It also adds <filename>share</filename> directories of dependencies to <envar>XDG_DATA_DIRS</envar>, which is intended to promote GIR files but it also <link xlink:href="https://github.com/NixOS/nixpkgs/issues/32790">pollutes the closures</link> of packages using <package>wrapGAppsHook</package>.
</para>
<warning>
<para>
The setup hook <link xlink:href="https://github.com/NixOS/nixpkgs/issues/56943">currently</link> does not work in expressions with <literal>strictDeps</literal> enabled, like Python packages. In those cases, you will need to disable it with <code>strictDeps = false;</code>.
</para>
</warning>
</listitem>
<listitem xml:id="ssec-gnome-hooks-gst-grl-plugins">
<para>
Setup hooks of <package>gst_all_1.gstreamer</package> and <package>gnome3.grilo</package> will populate the <envar>GST_PLUGIN_SYSTEM_PATH_1_0</envar> and <envar>GRL_PLUGIN_PATH</envar> variables, respectively, which will then be added to the wrapper by <literal>wrapGAppsHook</literal>.
</para>
</listitem>
</itemizedlist>
</para>
<para>
You can also pass additional arguments to <literal>makeWrapper</literal> using <literal>gappsWrapperArgs</literal> in <literal>preFixup</literal> hook:
<programlisting>
preFixup = ''
gappsWrapperArgs+=(
# Thumbnailers
--prefix XDG_DATA_DIRS : "${gdk-pixbuf}/share"
--prefix XDG_DATA_DIRS : "${librsvg}/share"
--prefix XDG_DATA_DIRS : "${shared-mime-info}/share"
)
'';
</programlisting>
</para>
</section>
<section xml:id="ssec-gnome-updating">
<title>Updating GNOME packages</title>
<para>
Most GNOME package offer <link linkend="var-passthru-updateScript"><literal>updateScript</literal></link>, it is therefore possible to update to latest source tarball by running <command>nix-shell maintainers/scripts/update.nix --argstr package gnome3.nautilus</command> or even en masse with <command>nix-shell maintainers/scripts/update.nix --argstr path gnome3</command>. Read the packages <filename>NEWS</filename> file to see what changed.
</para>
</section>
<section xml:id="ssec-gnome-common-issues">
<title>Frequently encountered issues</title>
<variablelist>
<varlistentry xml:id="ssec-gnome-common-issues-no-schemas">
<term>
<computeroutput>GLib-GIO-ERROR **: <replaceable>06:04:50.903</replaceable>: No GSettings schemas are installed on the system</computeroutput>
</term>
<listitem>
<para>
There are no schemas avalable in <envar>XDG_DATA_DIRS</envar>. Temporarily add a random package containing schemas like <package>gsettings-desktop-schemas</package> to <literal>buildInputs</literal>. <link linkend="ssec-gnome-hooks-glib"><package>glib</package></link> and <link linkend="ssec-gnome-hooks-wrapgappshook"><package>wrapGAppsHook</package></link> setup hooks will take care of making the schemas available to application and you will see the actual missing schemas with the <link linkend="ssec-gnome-common-issues-missing-schema">next error</link>. Or you can try looking through the source code for the actual schemas used.
</para>
</listitem>
</varlistentry>
<varlistentry xml:id="ssec-gnome-common-issues-missing-schema">
<term>
<computeroutput>GLib-GIO-ERROR **: <replaceable>06:04:50.903</replaceable>: Settings schema <replaceable>org.gnome.foo</replaceable> is not installed</computeroutput>
</term>
<listitem>
<para>
Package is missing some GSettings schemas. You can find out the package containing the schema with <command>nix-locate <replaceable>org.gnome.foo</replaceable>.gschema.xml</command> and let the hooks handle the wrapping as <link linkend="ssec-gnome-common-issues-no-schemas">above</link>.
</para>
</listitem>
</varlistentry>
<varlistentry xml:id="ssec-gnome-common-issues-double-wrapped">
<term>
When using <package>wrapGAppsHook</package> with special derivers you can end up with double wrapped binaries.
</term>
<listitem>
<para>
This is because derivers like <function>python.pkgs.buildPythonApplication</function> or <function>qt5.mkDerivation</function> have setup-hooks automatically added that produce wrappers with <package>makeWrapper</package>. The simplest way to workaround that is to disable the <package>wrapGAppsHook</package> automatic wrapping with <code>dontWrapGApps = true;</code> and pass the arguments it intended to pass to <package>makeWrapper</package> to another.
</para>
<para>
In the case of a Python application it could look like:
<programlisting>
python3.pkgs.buildPythonApplication {
pname = "gnome-music";
version = "3.32.2";
nativeBuildInputs = [
wrapGAppsHook
gobject-introspection
...
];
dontWrapGApps = true;
# Arguments to be passed to `makeWrapper`, only used by buildPython*
makeWrapperArgs = [
"\${gappsWrapperArgs[@]}"
];
}
</programlisting>
And for a QT app like:
<programlisting>
mkDerivation {
pname = "calibre";
version = "3.47.0";
nativeBuildInputs = [
wrapGAppsHook
qmake
...
];
dontWrapGApps = true;
# Arguments to be passed to `makeWrapper`, only used by qt5s mkDerivation
qtWrapperArgs = [
"\${gappsWrapperArgs[@]}"
];
}
</programlisting>
</para>
</listitem>
</varlistentry>
<varlistentry xml:id="ssec-gnome-common-issues-unwrappable-package">
<term>
I am packaging a project that cannot be wrapped, like a library or GNOME Shell extension.
</term>
<listitem>
<para>
You can rely on applications depending on the library set the necessary environment variables but that it often easy to miss. Instead we recommend to patch the paths in the source code whenever possible. Here are some examples:
<itemizedlist>
<listitem xml:id="ssec-gnome-common-issues-unwrappable-package-gnome-shell-ext">
<para>
<link xlink:href="https://github.com/NixOS/nixpkgs/blob/7bb8f05f12ca3cff9da72b56caa2f7472d5732bc/pkgs/desktops/gnome-3/core/gnome-shell-extensions/default.nix#L21-L24">Replacing a <envar>GI_TYPELIB_PATH</envar> in GNOME Shell extension</link> we are using <function>substituteAll</function> to include the path to a typelib into a patch.
</para>
</listitem>
<listitem xml:id="ssec-gnome-common-issues-unwrappable-package-gsettings">
<para>
The following examples are hardcoding GSettings schema paths. To get the schema paths we use the functions
<itemizedlist>
<listitem>
<para>
<function>glib.getSchemaPath</function> Takes a nix package attribute as an argument.
</para>
</listitem>
<listitem>
<para>
<function>glib.makeSchemaPath</function> Takes a package output like <literal>$out</literal> and a derivation name. You should use this if the schemas you need to hardcode are in the same derivation.
</para>
</listitem>
</itemizedlist>
</para>
<para xml:id="ssec-gnome-common-issues-unwrappable-package-gsettings-vala">
<link xlink:href="https://github.com/NixOS/nixpkgs/blob/7bb8f05f12ca3cff9da72b56caa2f7472d5732bc/pkgs/desktops/pantheon/apps/elementary-files/default.nix#L78-L86">Hard-coding GSettings schema path in Vala plug-in (dynamically loaded library)</link> here, <function>substituteAll</function> cannot be used since the schema comes from the same package preventing us from pass its path to the function, probably due to a <link xlink:href="https://github.com/NixOS/nix/issues/1846">Nix bug</link>.
</para>
<para xml:id="ssec-gnome-common-issues-unwrappable-package-gsettings-c">
<link xlink:href="https://github.com/NixOS/nixpkgs/blob/29c120c065d03b000224872251bed93932d42412/pkgs/development/libraries/glib-networking/default.nix#L31-L34">Hard-coding GSettings schema path in C library</link> nothing special other than using <link xlink:href="https://github.com/NixOS/nixpkgs/pull/67957#issuecomment-527717467">Coccinelle patch</link> to generate the patch itself.
</para>
</listitem>
</itemizedlist>
</para>
</listitem>
</varlistentry>
<varlistentry xml:id="ssec-gnome-common-issues-weird-location">
<term>
I need to wrap a binary outside <filename>bin</filename> and <filename>libexec</filename> directories.
</term>
<listitem>
<para>
You can manually trigger the wrapping with <function>wrapGApp</function> in <literal>preFixup</literal> phase. It takes a path to a program as a first argument; the remaining arguments are passed directly to <function xlink:href="#fun-wrapProgram">wrapProgram</function> function.
</para>
</listitem>
</varlistentry>
</variablelist>
</section>
</section>

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@ -3,12 +3,80 @@
xml:id="sec-language-go">
<title>Go</title>
<para>
The function <varname>buildGoPackage</varname> builds standard Go programs.
</para>
<section xml:id="ssec-go-modules">
<title>Go modules</title>
<example xml:id='ex-buildGoPackage'>
<title>buildGoPackage</title>
<para>
The function <varname> buildGoModule </varname> builds Go programs managed with Go modules. It builds a <link xlink:href="https://github.com/golang/go/wiki/Modules">Go modules</link> through a two phase build:
<itemizedlist>
<listitem>
<para>
An intermediate fetcher derivation. This derivation will be used to fetch all of the dependencies of the Go module.
</para>
</listitem>
<listitem>
<para>
A final derivation will use the output of the intermediate derivation to build the binaries and produce the final output.
</para>
</listitem>
</itemizedlist>
</para>
<example xml:id='ex-buildGoModule'>
<title>buildGoModule</title>
<programlisting>
pet = buildGoModule rec {
name = "pet-${version}";
version = "0.3.4";
src = fetchFromGitHub {
owner = "knqyf263";
repo = "pet";
rev = "v${version}";
sha256 = "0m2fzpqxk7hrbxsgqplkg7h2p7gv6s1miymv3gvw0cz039skag0s";
};
modSha256 = "1879j77k96684wi554rkjxydrj8g3hpp0kvxz03sd8dmwr3lh83j"; <co xml:id='ex-buildGoModule-1' />
subPackages = [ "." ]; <co xml:id='ex-buildGoModule-2' />
meta = with lib; {
description = "Simple command-line snippet manager, written in Go";
homepage = https://github.com/knqyf263/pet;
license = licenses.mit;
maintainers = with maintainers; [ kalbasit ];
platforms = platforms.linux ++ platforms.darwin;
};
}
</programlisting>
</example>
<para>
<xref linkend='ex-buildGoModule'/> is an example expression using buildGoModule, the following arguments are of special significance to the function:
<calloutlist>
<callout arearefs='ex-buildGoModule-1'>
<para>
<varname>modSha256</varname> is the hash of the output of the intermediate fetcher derivation.
</para>
</callout>
<callout arearefs='ex-buildGoModule-2'>
<para>
<varname>subPackages</varname> limits the builder from building child packages that have not been listed. If <varname>subPackages</varname> is not specified, all child packages will be built.
</para>
</callout>
</calloutlist>
</para>
</section>
<section xml:id="ssec-go-legacy">
<title>Go legacy</title>
<para>
The function <varname> buildGoPackage </varname> builds legacy Go programs, not supporting Go modules.
</para>
<example xml:id='ex-buildGoPackage'>
<title>buildGoPackage</title>
<programlisting>
deis = buildGoPackage rec {
name = "deis-${version}";
@ -29,56 +97,43 @@ deis = buildGoPackage rec {
buildFlags = "--tags release"; <co xml:id='ex-buildGoPackage-4' />
}
</programlisting>
</example>
</example>
<para>
<xref linkend='ex-buildGoPackage'/> is an example expression using
buildGoPackage, the following arguments are of special significance to the
function:
<calloutlist>
<callout arearefs='ex-buildGoPackage-1'>
<para>
<varname>goPackagePath</varname> specifies the package's canonical Go
import path.
</para>
</callout>
<callout arearefs='ex-buildGoPackage-2'>
<para>
<varname>subPackages</varname> limits the builder from building child
packages that have not been listed. If <varname>subPackages</varname> is
not specified, all child packages will be built.
</para>
<para>
In this example only <literal>github.com/deis/deis/client</literal> will
be built.
</para>
</callout>
<callout arearefs='ex-buildGoPackage-3'>
<para>
<varname>goDeps</varname> is where the Go dependencies of a Go program are
listed as a list of package source identified by Go import path. It could
be imported as a separate <varname>deps.nix</varname> file for
readability. The dependency data structure is described below.
</para>
</callout>
<callout arearefs='ex-buildGoPackage-4'>
<para>
<varname>buildFlags</varname> is a list of flags passed to the go build
command.
</para>
</callout>
</calloutlist>
</para>
<para>
<xref linkend='ex-buildGoPackage'/> is an example expression using buildGoPackage, the following arguments are of special significance to the function:
<calloutlist>
<callout arearefs='ex-buildGoPackage-1'>
<para>
<varname>goPackagePath</varname> specifies the package's canonical Go import path.
</para>
</callout>
<callout arearefs='ex-buildGoPackage-2'>
<para>
<varname>subPackages</varname> limits the builder from building child packages that have not been listed. If <varname>subPackages</varname> is not specified, all child packages will be built.
</para>
<para>
In this example only <literal>github.com/deis/deis/client</literal> will be built.
</para>
</callout>
<callout arearefs='ex-buildGoPackage-3'>
<para>
<varname>goDeps</varname> is where the Go dependencies of a Go program are listed as a list of package source identified by Go import path. It could be imported as a separate <varname>deps.nix</varname> file for readability. The dependency data structure is described below.
</para>
</callout>
<callout arearefs='ex-buildGoPackage-4'>
<para>
<varname>buildFlags</varname> is a list of flags passed to the go build command.
</para>
</callout>
</calloutlist>
</para>
<para>
The <varname>goDeps</varname> attribute can be imported from a separate
<varname>nix</varname> file that defines which Go libraries are needed and
should be included in <varname>GOPATH</varname> for
<varname>buildPhase</varname>.
</para>
<para>
The <varname>goDeps</varname> attribute can be imported from a separate <varname>nix</varname> file that defines which Go libraries are needed and should be included in <varname>GOPATH</varname> for <varname>buildPhase</varname>.
</para>
<example xml:id='ex-goDeps'>
<title>deps.nix</title>
<example xml:id='ex-goDeps'>
<title>deps.nix</title>
<programlisting>
[ <co xml:id='ex-goDeps-1' />
{
@ -101,60 +156,51 @@ deis = buildGoPackage rec {
}
]
</programlisting>
</example>
</example>
<para>
<calloutlist>
<callout arearefs='ex-goDeps-1'>
<para>
<varname>goDeps</varname> is a list of Go dependencies.
</para>
</callout>
<callout arearefs='ex-goDeps-2'>
<para>
<varname>goPackagePath</varname> specifies Go package import path.
</para>
</callout>
<callout arearefs='ex-goDeps-3'>
<para>
<varname>fetch type</varname> that needs to be used to get package source.
If <varname>git</varname> is used there should be <varname>url</varname>,
<varname>rev</varname> and <varname>sha256</varname> defined next to it.
</para>
</callout>
</calloutlist>
</para>
<para>
<calloutlist>
<callout arearefs='ex-goDeps-1'>
<para>
<varname>goDeps</varname> is a list of Go dependencies.
</para>
</callout>
<callout arearefs='ex-goDeps-2'>
<para>
<varname>goPackagePath</varname> specifies Go package import path.
</para>
</callout>
<callout arearefs='ex-goDeps-3'>
<para>
<varname>fetch type</varname> that needs to be used to get package source. If <varname>git</varname> is used there should be <varname>url</varname>, <varname>rev</varname> and <varname>sha256</varname> defined next to it.
</para>
</callout>
</calloutlist>
</para>
<para>
To extract dependency information from a Go package in automated way use
<link xlink:href="https://github.com/kamilchm/go2nix">go2nix</link>. It can
produce complete derivation and <varname>goDeps</varname> file for Go
programs.
</para>
<para>
To extract dependency information from a Go package in automated way use <link xlink:href="https://github.com/kamilchm/go2nix">go2nix</link>. It can produce complete derivation and <varname>goDeps</varname> file for Go programs.
</para>
<para>
<varname>buildGoPackage</varname> produces
<xref linkend='chap-multiple-output' xrefstyle="select: title" /> where
<varname>bin</varname> includes program binaries. You can test build a Go
binary as follows:
<para>
<varname>buildGoPackage</varname> produces <xref linkend='chap-multiple-output' xrefstyle="select: title" /> where <varname>bin</varname> includes program binaries. You can test build a Go binary as follows:
<screen>
$ nix-build -A deis.bin
</screen>
or build all outputs with:
<prompt>$ </prompt>nix-build -A deis.bin
</screen>
or build all outputs with:
<screen>
$ nix-build -A deis.all
</screen>
<varname>bin</varname> output will be installed by default with
<varname>nix-env -i</varname> or <varname>systemPackages</varname>.
</para>
<prompt>$ </prompt>nix-build -A deis.all
</screen>
<varname>bin</varname> output will be installed by default with <varname>nix-env -i</varname> or <varname>systemPackages</varname>.
</para>
<para>
You may use Go packages installed into the active Nix profiles by adding the
following to your ~/.bashrc:
<para>
You may use Go packages installed into the active Nix profiles by adding the following to your ~/.bashrc:
<screen>
for p in $NIX_PROFILES; do
GOPATH="$p/share/go:$GOPATH"
done
</screen>
</para>
</para>
</section>
</section>

20
doc/languages-frameworks/haskell.section.md
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@ -3,7 +3,7 @@ title: User's Guide for Haskell in Nixpkgs
author: Peter Simons
date: 2015-06-01
---
# User's Guide to the Haskell Infrastructure
# Haskell
## How to install Haskell packages
@ -55,7 +55,7 @@ package `haskell-pandoc`, for example, installs both a library and an
application. You can install and use Haskell executables just like any other
program in Nixpkgs, but using Haskell libraries for development is a bit
trickier and we'll address that subject in great detail in section [How to
create a development environment].
create a development environment](#how-to-create-a-development-environment).
Attribute paths are deterministic inside of Nixpkgs, but the path necessary to
reach Nixpkgs varies from system to system. We dodged that problem by giving
@ -127,7 +127,7 @@ Also, the attributes `haskell.compiler.ghcXYC` and
A simple development environment consists of a Haskell compiler and one or both
of the tools `cabal-install` and `stack`. We saw in section
[How to install Haskell packages] how you can install those programs into your
[How to install Haskell packages](#how-to-install-haskell-packages) how you can install those programs into your
user profile:
```shell
nix-env -f "<nixpkgs>" -iA haskellPackages.ghc haskellPackages.cabal-install
@ -162,7 +162,7 @@ nix-shell -p haskell.compiler.ghc784
to bring GHC 7.8.4 into `$PATH`. Alternatively, you can use Stack instead of
`nix-shell` directly to select compiler versions and other build tools
per-project. It uses `nix-shell` under the hood when Nix support is turned on.
See [How to build a Haskell project using Stack].
See [How to build a Haskell project using Stack](#how-to-build-a-haskell-project-using-stack).
If you're using `cabal-install`, re-running `cabal configure` inside the spawned
shell switches your build to use that compiler instead. If you're working on
@ -352,9 +352,9 @@ you want them to come from. Add the following to `configuration.nix`.
```nix
services.hoogle = {
enable = true;
packages = (hpkgs: with hpkgs; [text cryptonite]);
haskellPackages = pkgs.haskellPackages;
enable = true;
packages = (hpkgs: with hpkgs; [text cryptonite]);
haskellPackages = pkgs.haskellPackages;
};
```
@ -366,7 +366,7 @@ automatically select the right version of GHC and other build tools to build,
test and execute apps in an existing project downloaded from somewhere on the
Internet. Pass the `--nix` flag to any `stack` command to do so, e.g.
```shell
git clone --recursive http://github.com/yesodweb/wai
git clone --recursive https://github.com/yesodweb/wai
cd wai
stack --nix build
```
@ -935,7 +935,7 @@ The implementation can be found in the
[integer-gmp](http://hackage.haskell.org/package/integer-gmp) package.
A potential problem with this is that GMP is licensed under the
[GNU Lesser General Public License (LGPL)](http://www.gnu.org/copyleft/lesser.html),
[GNU Lesser General Public License (LGPL)](https://www.gnu.org/copyleft/lesser.html),
a kind of "copyleft" license. According to the terms of the LGPL, paragraph 5,
you may distribute a program that is designed to be compiled and dynamically
linked with the library under the terms of your choice (i.e., commercially) but
@ -953,7 +953,7 @@ is essentially a "free software" license (BSD3), according to
paragraph 2 of the LGPL, GHC must be distributed under the terms of the LGPL!
To work around these problems GHC can be build with a slower but LGPL-free
alternative implemention for Integer called
alternative implementation for Integer called
[integer-simple](http://hackage.haskell.org/package/integer-simple).
To get a GHC compiler build with `integer-simple` instead of `integer-gmp` use

161
doc/languages-frameworks/idris.section.md
View File

@ -1,39 +1,144 @@
Idris packages
==============
# Idris
This directory contains build rules for idris packages. In addition,
it contains several functions to build and compose those packages.
Everything is exposed to the user via the `idrisPackages` attribute.
## Installing Idris
callPackage
------------
The easiest way to get a working idris version is to install the `idris` attribute:
This is like the normal nixpkgs callPackage function, specialized to
idris packages.
```
$ # On NixOS
$ nix-env -i nixos.idris
$ # On non-NixOS
$ nix-env -i nixpkgs.idris
```
builtins
---------
This however only provides the `prelude` and `base` libraries. To install idris with additional libraries, you can use the `idrisPackages.with-packages` function, e.g. in an overlay in `~/.config/nixpkgs/overlays/my-idris.nix`:
This is a list of all of the libraries that come packaged with Idris
itself.
```nix
self: super: {
myIdris = with self.idrisPackages; with-packages [ contrib pruviloj ];
}
```
build-idris-package
--------------------
And then:
A function to build an idris package. Its sole argument is a set like
you might pass to `stdenv.mkDerivation`, except `build-idris-package`
sets several attributes for you. See `build-idris-package.nix` for
details.
```
$ # On NixOS
$ nix-env -iA nixos.myIdris
$ # On non-NixOS
$ nix-env -iA nixpkgs.myIdris
```
build-builtin-package
----------------------
To see all available Idris packages:
```
$ # On NixOS
$ nix-env -qaPA nixos.idrisPackages
$ # On non-NixOS
$ nix-env -qaPA nixpkgs.idrisPackages
```
A version of `build-idris-package` specialized to builtin libraries.
Mostly for internal use.
Similarly, entering a `nix-shell`:
```
$ nix-shell -p 'idrisPackages.with-packages (with idrisPackages; [ contrib pruviloj ])'
```
with-packages
-------------
## Starting Idris with library support
Bundle idris together with a list of packages. Because idris currently
only supports a single directory in its library path, you must include
all desired libraries here, including `prelude` and `base`.
To have access to these libraries in idris, call it with an argument `-p <library name>` for each library:
```
$ nix-shell -p 'idrisPackages.with-packages (with idrisPackages; [ contrib pruviloj ])'
[nix-shell:~]$ idris -p contrib -p pruviloj
```
A listing of all available packages the Idris binary has access to is available via `--listlibs`:
```
$ idris --listlibs
00prelude-idx.ibc
pruviloj
base
contrib
prelude
00pruviloj-idx.ibc
00base-idx.ibc
00contrib-idx.ibc
```
## Building an Idris project with Nix
As an example of how a Nix expression for an Idris package can be created, here is the one for `idrisPackages.yaml`:
```nix
{ build-idris-package
, fetchFromGitHub
, contrib
, lightyear
, lib
}:
build-idris-package {
name = "yaml";
version = "2018-01-25";
# This is the .ipkg file that should be built, defaults to the package name
# In this case it should build `Yaml.ipkg` instead of `yaml.ipkg`
# This is only necessary because the yaml packages ipkg file is
# different from its package name here.
ipkgName = "Yaml";
# Idris dependencies to provide for the build
idrisDeps = [ contrib lightyear ];
src = fetchFromGitHub {
owner = "Heather";
repo = "Idris.Yaml";
rev = "5afa51ffc839844862b8316faba3bafa15656db4";
sha256 = "1g4pi0swmg214kndj85hj50ccmckni7piprsxfdzdfhg87s0avw7";
};
meta = {
description = "Idris YAML lib";
homepage = https://github.com/Heather/Idris.Yaml;
license = lib.licenses.mit;
maintainers = [ lib.maintainers.brainrape ];
};
}
```
Assuming this file is saved as `yaml.nix`, it's buildable using
```
$ nix-build -E '(import <nixpkgs> {}).idrisPackages.callPackage ./yaml.nix {}'
```
Or it's possible to use
```nix
with import <nixpkgs> {};
{
yaml = idrisPackages.callPackage ./yaml.nix {};
}
```
in another file (say `default.nix`) to be able to build it with
```
$ nix-build -A yaml
```
## Passing options to `idris` commands
The `build-idris-package` function provides also optional input values to set additional options for the used `idris` commands.
Specifically, you can set `idrisBuildOptions`, `idrisTestOptions`, `idrisInstallOptions` and `idrisDocOptions` to provide additional options to the `idris` command respectively when building, testing, installing and generating docs for your package.
For example you could set
```
build-idris-package {
idrisBuildOptions = [ "--log" "1" "--verbose" ]
...
}
```
to require verbose output during `idris` build phase.

17
doc/languages-frameworks/index.xml
View File

@ -1,24 +1,25 @@
<chapter xmlns="http://docbook.org/ns/docbook"
xmlns:xi="http://www.w3.org/2001/XInclude"
xml:id="chap-language-support">
<title>Support for specific programming languages and frameworks</title>
<title>Languages and frameworks</title>
<para>
The <link linkend="chap-stdenv">standard build environment</link> makes it
easy to build typical Autotools-based packages with very little code. Any
other kind of package can be accomodated by overriding the appropriate phases
of <literal>stdenv</literal>. However, there are specialised functions in
Nixpkgs to easily build packages for other programming languages, such as
Perl or Haskell. These are described in this chapter.
The <link linkend="chap-stdenv">standard build environment</link> makes it easy to build typical Autotools-based packages with very little code. Any other kind of package can be accomodated by overriding the appropriate phases of <literal>stdenv</literal>. However, there are specialised functions in Nixpkgs to easily build packages for other programming languages, such as Perl or Haskell. These are described in this chapter.
</para>
<xi:include href="android.section.xml" />
<xi:include href="beam.xml" />
<xi:include href="bower.xml" />
<xi:include href="coq.xml" />
<xi:include href="crystal.section.xml" />
<xi:include href="emscripten.section.xml" />
<xi:include href="gnome.xml" />
<xi:include href="go.xml" />
<xi:include href="haskell.section.xml" />
<xi:include href="idris.section.xml" />
<xi:include href="ios.section.xml" />
<xi:include href="java.xml" />
<xi:include href="lua.xml" />
<xi:include href="node.section.xml" />
<xi:include href="ocaml.xml" />
<xi:include href="perl.xml" />
<xi:include href="python.section.xml" />
<xi:include href="qt.xml" />
@ -26,6 +27,6 @@
<xi:include href="ruby.xml" />
<xi:include href="rust.section.xml" />
<xi:include href="texlive.xml" />
<xi:include href="titanium.section.xml" />
<xi:include href="vim.section.xml" />
<xi:include href="emscripten.section.xml" />
</chapter>

219
doc/languages-frameworks/ios.section.md Normal file
View File

@ -0,0 +1,219 @@
---
title: iOS
author: Sander van der Burg
date: 2018-11-18
---
# iOS
This component is basically a wrapper/workaround that makes it possible to
expose an Xcode installation as a Nix package by means of symlinking to the
relevant executables on the host system.
Since Xcode can't be packaged with Nix, nor we can publish it as a Nix package
(because of its license) this is basically the only integration strategy
making it possible to do iOS application builds that integrate with other
components of the Nix ecosystem
The primary objective of this project is to use the Nix expression language to
specify how iOS apps can be built from source code, and to automatically spawn
iOS simulator instances for testing.
This component also makes it possible to use [Hydra](http://nixos.org/hydra),
the Nix-based continuous integration server to regularly build iOS apps and to
do wireless ad-hoc installations of enterprise IPAs on iOS devices through
Hydra.
The Xcode build environment implements a number of features.
Deploying a proxy component wrapper exposing Xcode
--------------------------------------------------
The first use case is deploying a Nix package that provides symlinks to the Xcode
installation on the host system. This package can be used as a build input to
any build function implemented in the Nix expression language that requires
Xcode.
```nix
let
pkgs = import <nixpkgs> {};
xcodeenv = import ./xcodeenv {
inherit (pkgs) stdenv;
};
in
xcodeenv.composeXcodeWrapper {
version = "9.2";
xcodeBaseDir = "/Applications/Xcode.app";
}
```
By deploying the above expression with `nix-build` and inspecting its content
you will notice that several Xcode-related executables are exposed as a Nix
package:
```bash
$ ls result/bin
lrwxr-xr-x 1 sander staff 94 1 jan 1970 Simulator -> /Applications/Xcode.app/Contents/Developer/Applications/Simulator.app/Contents/MacOS/Simulator
lrwxr-xr-x 1 sander staff 17 1 jan 1970 codesign -> /usr/bin/codesign
lrwxr-xr-x 1 sander staff 17 1 jan 1970 security -> /usr/bin/security
lrwxr-xr-x 1 sander staff 21 1 jan 1970 xcode-select -> /usr/bin/xcode-select
lrwxr-xr-x 1 sander staff 61 1 jan 1970 xcodebuild -> /Applications/Xcode.app/Contents/Developer/usr/bin/xcodebuild
lrwxr-xr-x 1 sander staff 14 1 jan 1970 xcrun -> /usr/bin/xcrun
```
Building an iOS application
---------------------------
We can build an iOS app executable for the simulator, or an IPA/xcarchive file
for release purposes, e.g. ad-hoc, enterprise or store installations, by
executing the `xcodeenv.buildApp {}` function:
```nix
let
pkgs = import <nixpkgs> {};
xcodeenv = import ./xcodeenv {
inherit (pkgs) stdenv;
};
in
xcodeenv.buildApp {
name = "MyApp";
src = ./myappsources;
sdkVersion = "11.2";
target = null; # Corresponds to the name of the app by default
configuration = null; # Release for release builds, Debug for debug builds
scheme = null; # -scheme will correspond to the app name by default
sdk = null; # null will set it to 'iphonesimulator` for simulator builds or `iphoneos` to real builds
xcodeFlags = "";
release = true;
certificateFile = ./mycertificate.p12;
certificatePassword = "secret";
provisioningProfile = ./myprovisioning.profile;
signMethod = "ad-hoc"; # 'enterprise' or 'store'
generateIPA = true;
generateXCArchive = false;
enableWirelessDistribution = true;
installURL = "/installipa.php";
bundleId = "mycompany.myapp";
appVersion = "1.0";
# Supports all xcodewrapper parameters as well
xcodeBaseDir = "/Applications/Xcode.app";
}
```
The above function takes a variety of parameters:
* The `name` and `src` parameters are mandatory and specify the name of the app
and the location where the source code resides
* `sdkVersion` specifies which version of the iOS SDK to use.
It also possile to adjust the `xcodebuild` parameters. This is only needed in
rare circumstances. In most cases the default values should suffice:
* Specifies which `xcodebuild` target to build. By default it takes the target
that has the same name as the app.
* The `configuration` parameter can be overridden if desired. By default, it
will do a debug build for the simulator and a release build for real devices.
* The `scheme` parameter specifies which `-scheme` parameter to propagate to
`xcodebuild`. By default, it corresponds to the app name.
* The `sdk` parameter specifies which SDK to use. By default, it picks
`iphonesimulator` for simulator builds and `iphoneos` for release builds.
* The `xcodeFlags` parameter specifies arbitrary command line parameters that
should be propagated to `xcodebuild`.
By default, builds are carried out for the iOS simulator. To do release builds
(builds for real iOS devices), you must set the `release` parameter to `true`.
In addition, you need to set the following parameters:
* `certificateFile` refers to a P12 certificate file.
* `certificatePassword` specifies the password of the P12 certificate.
* `provisioningProfile` refers to the provision profile needed to sign the app
* `signMethod` should refer to `ad-hoc` for signing the app with an ad-hoc
certificate, `enterprise` for enterprise certificates and `app-store` for App
store certificates.
* `generateIPA` specifies that we want to produce an IPA file (this is probably
what you want)
* `generateXCArchive` specifies thet we want to produce an xcarchive file.
When building IPA files on Hydra and when it is desired to allow iOS devices to
install IPAs by browsing to the Hydra build products page, you can enable the
`enableWirelessDistribution` parameter.
When enabled, you need to configure the following options:
* The `installURL` parameter refers to the URL of a PHP script that composes the
`itms-services://` URL allowing iOS devices to install the IPA file.
* `bundleId` refers to the bundle ID value of the app
* `appVersion` refers to the app's version number
To use wireless adhoc distributions, you must also install the corresponding
PHP script on a web server (see section: 'Installing the PHP script for wireless
ad hoc installations from Hydra' for more information).
In addition to the build parameters, you can also specify any parameters that
the `xcodeenv.composeXcodeWrapper {}` function takes. For example, the
`xcodeBaseDir` parameter can be overridden to refer to a different Xcode
version.
Spawning simulator instances
----------------------------
In addition to building iOS apps, we can also automatically spawn simulator
instances:
```nix
let
pkgs = import <nixpkgs> {};
xcodeenv = import ./xcodeenv {
inherit (pkgs) stdenv;
};
in
xcode.simulateApp {
name = "simulate";
# Supports all xcodewrapper parameters as well
xcodeBaseDir = "/Applications/Xcode.app";
}
```
The above expression produces a script that starts the simulator from the
provided Xcode installation. The script can be started as follows:
```bash
./result/bin/run-test-simulator
```
By default, the script will show an overview of UDID for all available simulator
instances and asks you to pick one. You can also provide a UDID as a
command-line parameter to launch an instance automatically:
```bash
./result/bin/run-test-simulator 5C93129D-CF39-4B1A-955F-15180C3BD4B8
```
You can also extend the simulator script to automatically deploy and launch an
app in the requested simulator instance:
```nix
let
pkgs = import <nixpkgs> {};
xcodeenv = import ./xcodeenv {
inherit (pkgs) stdenv;
};
in
xcode.simulateApp {
name = "simulate";
bundleId = "mycompany.myapp";
app = xcode.buildApp {
# ...
};
# Supports all xcodewrapper parameters as well
xcodeBaseDir = "/Applications/Xcode.app";
}
```
By providing the result of an `xcode.buildApp {}` function and configuring the
app bundle id, the app gets deployed automatically and started.

51
doc/languages-frameworks/java.xml
View File

@ -10,43 +10,31 @@ stdenv.mkDerivation {
name = "...";
src = fetchurl { ... };
buildInputs = [ jdk ant ];
nativeBuildInputs = [ jdk ant ];
buildPhase = "ant";
}
</programlisting>
Note that <varname>jdk</varname> is an alias for the OpenJDK (self-built
where available, or pre-built via Zulu). Platforms with OpenJDK not (yet) in
Nixpkgs (<literal>Aarch32</literal>, <literal>Aarch64</literal>) point to the
(unfree) <literal>oraclejdk</literal>.
Note that <varname>jdk</varname> is an alias for the OpenJDK (self-built where available, or pre-built via Zulu). Platforms with OpenJDK not (yet) in Nixpkgs (<literal>Aarch32</literal>, <literal>Aarch64</literal>) point to the (unfree) <literal>oraclejdk</literal>.
</para>
<para>
JAR files that are intended to be used by other packages should be installed
in <filename>$out/share/java</filename>. JDKs have a stdenv setup hook that
add any JARs in the <filename>share/java</filename> directories of the build
inputs to the <envar>CLASSPATH</envar> environment variable. For instance, if
the package <literal>libfoo</literal> installs a JAR named
<filename>foo.jar</filename> in its <filename>share/java</filename>
directory, and another package declares the attribute
JAR files that are intended to be used by other packages should be installed in <filename>$out/share/java</filename>. JDKs have a stdenv setup hook that add any JARs in the <filename>share/java</filename> directories of the build inputs to the <envar>CLASSPATH</envar> environment variable. For instance, if the package <literal>libfoo</literal> installs a JAR named <filename>foo.jar</filename> in its <filename>share/java</filename> directory, and another package declares the attribute
<programlisting>
buildInputs = [ jdk libfoo ];
buildInputs = [ libfoo ];
nativeBuildInputs = [ jdk ];
</programlisting>
then <envar>CLASSPATH</envar> will be set to
<filename>/nix/store/...-libfoo/share/java/foo.jar</filename>.
then <envar>CLASSPATH</envar> will be set to <filename>/nix/store/...-libfoo/share/java/foo.jar</filename>.
</para>
<para>
Private JARs should be installed in a location like
<filename>$out/share/<replaceable>package-name</replaceable></filename>.
Private JARs should be installed in a location like <filename>$out/share/<replaceable>package-name</replaceable></filename>.
</para>
<para>
If your Java package provides a program, you need to generate a wrapper
script to run it using the OpenJRE. You can use
<literal>makeWrapper</literal> for this:
If your Java package provides a program, you need to generate a wrapper script to run it using the OpenJRE. You can use <literal>makeWrapper</literal> for this:
<programlisting>
buildInputs = [ makeWrapper ];
nativeBuildInputs = [ makeWrapper ];
installPhase =
''
@ -55,30 +43,21 @@ installPhase =
--add-flags "-cp $out/share/java/foo.jar org.foo.Main"
'';
</programlisting>
Note the use of <literal>jre</literal>, which is the part of the OpenJDK
package that contains the Java Runtime Environment. By using
<literal>${jre}/bin/java</literal> instead of
<literal>${jdk}/bin/java</literal>, you prevent your package from depending
on the JDK at runtime.
Note the use of <literal>jre</literal>, which is the part of the OpenJDK package that contains the Java Runtime Environment. By using <literal>${jre}/bin/java</literal> instead of <literal>${jdk}/bin/java</literal>, you prevent your package from depending on the JDK at runtime.
</para>
<para>
Note all JDKs passthru <literal>home</literal>, so if your application
requires environment variables like <envar>JAVA_HOME</envar> being set, that
can be done in a generic fashion with the <literal>--set</literal> argument
of <literal>makeWrapper</literal>:
Note all JDKs passthru <literal>home</literal>, so if your application requires environment variables like <envar>JAVA_HOME</envar> being set, that can be done in a generic fashion with the <literal>--set</literal> argument of <literal>makeWrapper</literal>:
<programlisting>
--set JAVA_HOME ${jdk.home}
--set JAVA_HOME ${jdk.home}
</programlisting>
</para>
<para>
It is possible to use a different Java compiler than <command>javac</command>
from the OpenJDK. For instance, to use the GNU Java Compiler:
It is possible to use a different Java compiler than <command>javac</command> from the OpenJDK. For instance, to use the GNU Java Compiler:
<programlisting>
buildInputs = [ gcj ant ];
nativeBuildInputs = [ gcj ant ];
</programlisting>
Here, Ant will automatically use <command>gij</command> (the GNU Java
Runtime) instead of the OpenJRE.
Here, Ant will automatically use <command>gij</command> (the GNU Java Runtime) instead of the OpenJRE.
</para>
</section>

22
doc/languages-frameworks/lua.xml
View File

@ -4,18 +4,11 @@
<title>Lua</title>
<para>
Lua packages are built by the <varname>buildLuaPackage</varname> function.
This function is implemented in
<link xlink:href="https://github.com/NixOS/nixpkgs/blob/master/pkgs/development/lua-modules/generic/default.nix">
<filename>pkgs/development/lua-modules/generic/default.nix</filename></link>
and works similarly to <varname>buildPerlPackage</varname>. (See
<xref linkend="sec-language-perl"/> for details.)
Lua packages are built by the <varname>buildLuaPackage</varname> function. This function is implemented in <link xlink:href="https://github.com/NixOS/nixpkgs/blob/master/pkgs/development/lua-modules/generic/default.nix"> <filename>pkgs/development/lua-modules/generic/default.nix</filename></link> and works similarly to <varname>buildPerlPackage</varname>. (See <xref linkend="sec-language-perl"/> for details.)
</para>
<para>
Lua packages are defined in
<link xlink:href="https://github.com/NixOS/nixpkgs/blob/master/pkgs/top-level/lua-packages.nix"><filename>pkgs/top-level/lua-packages.nix</filename></link>.
Most of them are simple. For example:
Lua packages are defined in <link xlink:href="https://github.com/NixOS/nixpkgs/blob/master/pkgs/top-level/lua-packages.nix"><filename>pkgs/top-level/lua-packages.nix</filename></link>. Most of them are simple. For example:
<programlisting>
fileSystem = buildLuaPackage {
name = "filesystem-1.6.2";
@ -29,20 +22,15 @@ fileSystem = buildLuaPackage {
maintainers = with maintainers; [ flosse ];
};
};
</programlisting>
</programlisting>
</para>
<para>
Though, more complicated package should be placed in a seperate file in
<link
Though, more complicated package should be placed in a seperate file in <link
xlink:href="https://github.com/NixOS/nixpkgs/blob/master/pkgs/development/lua-modules"><filename>pkgs/development/lua-modules</filename></link>.
</para>
<para>
Lua packages accept additional parameter <varname>disabled</varname>, which
defines the condition of disabling package from luaPackages. For example, if
package has <varname>disabled</varname> assigned to <literal>lua.luaversion
!= "5.1"</literal>, it will not be included in any luaPackages except
lua51Packages, making it only be built for lua 5.1.
Lua packages accept additional parameter <varname>disabled</varname>, which defines the condition of disabling package from luaPackages. For example, if package has <varname>disabled</varname> assigned to <literal>lua.luaversion != "5.1"</literal>, it will not be included in any luaPackages except lua51Packages, making it only be built for lua 5.1.
</para>
</section>

14
doc/languages-frameworks/node.section.md
View File

@ -1,5 +1,5 @@
Node.js packages
================
Node.js
=======
The `pkgs/development/node-packages` folder contains a generated collection of
[NPM packages](https://npmjs.com/) that can be installed with the Nix package
manager.
@ -14,7 +14,7 @@ project.
The package set also provides support for multiple Node.js versions. The policy
is that a new package should be added to the collection for the latest stable LTS
release (which is currently 8.x), unless there is an explicit reason to support
release (which is currently 10.x), unless there is an explicit reason to support
a different release.
If your package uses native addons, you need to examine what kind of native
@ -26,7 +26,7 @@ build system it uses. Here are some examples:
After you have identified the correct system, you need to override your package
expression while adding in build system as a build input. For example, `dat`
requires `node-gyp-build`, so we override its expression in `default-v8.nix`:
requires `node-gyp-build`, so we override its expression in `default-v10.nix`:
```nix
dat = nodePackages.dat.override (oldAttrs: {
@ -36,9 +36,9 @@ dat = nodePackages.dat.override (oldAttrs: {
To add a package from NPM to nixpkgs:
1. Modify `pkgs/development/node-packages/node-packages-v8.json` to add, update
or remove package entries. (Or `pkgs/development/node-packages/node-packages-v10.json`
for packages depending on Node.js 10.x)
1. Modify `pkgs/development/node-packages/node-packages-v10.json` to add, update
or remove package entries. (Or `pkgs/development/node-packages/node-packages-v8.json`
for packages depending on Node.js 8.x)
2. Run the script: `(cd pkgs/development/node-packages && ./generate.sh)`.
3. Build your new package to test your changes:
`cd /path/to/nixpkgs && nix-build -A nodePackages.<new-or-updated-package>`.

73
doc/languages-frameworks/ocaml.xml Normal file
View File

@ -0,0 +1,73 @@
<section xmlns="http://docbook.org/ns/docbook"
xmlns:xlink="http://www.w3.org/1999/xlink"
xml:id="sec-language-ocaml">
<title>OCaml</title>
<para>
OCaml libraries should be installed in <literal>$(out)/lib/ocaml/${ocaml.version}/site-lib/</literal>. Such directories are automatically added to the <literal>$OCAMLPATH</literal> environment variable when building another package that depends on them or when opening a <literal>nix-shell</literal>.
</para>
<para>
Given that most of the OCaml ecosystem is now built with dune, nixpkgs includes a convenience build support function called <literal>buildDunePackage</literal> that will build an OCaml package using dune, OCaml and findlib and any additional dependencies provided as <literal>buildInputs</literal> or <literal>propagatedBuildInputs</literal>.
</para>
<para>
Here is a simple package example. It defines an (optional) attribute <literal>minimumOCamlVersion</literal> that will be used to throw a descriptive evaluation error if building with an older OCaml is attempted. It uses the <literal>fetchFromGitHub</literal> fetcher to get its source. It sets the <literal>doCheck</literal> (optional) attribute to <literal>true</literal> which means that tests will be run with <literal>dune runtest -p angstrom</literal> after the build (<literal>dune build -p angstrom</literal>) is complete. It uses <literal>alcotest</literal> as a build input (because it is needed to run the tests) and <literal>bigstringaf</literal> and <literal>result</literal> as propagated build inputs (thus they will also be available to libraries depending on this library). The library will be installed using the <literal>angstrom.install</literal> file that dune generates.
</para>
<programlisting>
{ stdenv, fetchFromGitHub, buildDunePackage, alcotest, result, bigstringaf }:
buildDunePackage rec {
pname = "angstrom";
version = "0.10.0";
minimumOCamlVersion = "4.03";
src = fetchFromGitHub {
owner = "inhabitedtype";
repo = pname;
rev = version;
sha256 = "0lh6024yf9ds0nh9i93r9m6p5psi8nvrqxl5x7jwl13zb0r9xfpw";
};
buildInputs = [ alcotest ];
propagatedBuildInputs = [ bigstringaf result ];
doCheck = true;
meta = {
homepage = https://github.com/inhabitedtype/angstrom;
description = "OCaml parser combinators built for speed and memory efficiency";
license = stdenv.lib.licenses.bsd3;
maintainers = with stdenv.lib.maintainers; [ sternenseemann ];
};
}
</programlisting>
<para>
Here is a second example, this time using a source archive generated with <literal>dune-release</literal>. It is a good idea to use this archive when it is available as it will usually contain substituted variables such as a <literal>%%VERSION%%</literal> field. This library does not depend on any other OCaml library and no tests are run after building it.
</para>
<programlisting>
{ stdenv, fetchurl, buildDunePackage }:
buildDunePackage rec {
pname = "wtf8";
version = "1.0.1";
minimumOCamlVersion = "4.01";
src = fetchurl {
url = "https://github.com/flowtype/ocaml-${pname}/releases/download/v${version}/${pname}-${version}.tbz";
sha256 = "1msg3vycd3k8qqj61sc23qks541cxpb97vrnrvrhjnqxsqnh6ygq";
};
meta = with stdenv.lib; {
homepage = https://github.com/flowtype/ocaml-wtf8;
description = "WTF-8 is a superset of UTF-8 that allows unpaired surrogates.";
license = licenses.mit;
maintainers = [ maintainers.eqyiel ];
};
}
</programlisting>
</section>

117
doc/languages-frameworks/perl.xml
View File

@ -4,24 +4,13 @@
<title>Perl</title>
<para>
Nixpkgs provides a function <varname>buildPerlPackage</varname>, a generic
package builder function for any Perl package that has a standard
<varname>Makefile.PL</varname>. Its implemented in
<link
Nixpkgs provides a function <varname>buildPerlPackage</varname>, a generic package builder function for any Perl package that has a standard <varname>Makefile.PL</varname>. Its implemented in <link
xlink:href="https://github.com/NixOS/nixpkgs/blob/master/pkgs/development/perl-modules/generic"><filename>pkgs/development/perl-modules/generic</filename></link>.
</para>
<para>
Perl packages from CPAN are defined in
<link
xlink:href="https://github.com/NixOS/nixpkgs/blob/master/pkgs/top-level/perl-packages.nix"><filename>pkgs/top-level/perl-packages.nix</filename></link>,
rather than <filename>pkgs/all-packages.nix</filename>. Most Perl packages
are so straight-forward to build that they are defined here directly, rather
than having a separate function for each package called from
<filename>perl-packages.nix</filename>. However, more complicated packages
should be put in a separate file, typically in
<filename>pkgs/development/perl-modules</filename>. Here is an example of the
former:
Perl packages from CPAN are defined in <link
xlink:href="https://github.com/NixOS/nixpkgs/blob/master/pkgs/top-level/perl-packages.nix"><filename>pkgs/top-level/perl-packages.nix</filename></link>, rather than <filename>pkgs/all-packages.nix</filename>. Most Perl packages are so straight-forward to build that they are defined here directly, rather than having a separate function for each package called from <filename>perl-packages.nix</filename>. However, more complicated packages should be put in a separate file, typically in <filename>pkgs/development/perl-modules</filename>. Here is an example of the former:
<programlisting>
ClassC3 = buildPerlPackage rec {
name = "Class-C3-0.21";
@ -31,32 +20,22 @@ ClassC3 = buildPerlPackage rec {
};
};
</programlisting>
Note the use of <literal>mirror://cpan/</literal>, and the
<literal>${name}</literal> in the URL definition to ensure that the name
attribute is consistent with the source that were actually downloading.
Perl packages are made available in <filename>all-packages.nix</filename>
through the variable <varname>perlPackages</varname>. For instance, if you
have a package that needs <varname>ClassC3</varname>, you would typically
write
Note the use of <literal>mirror://cpan/</literal>, and the <literal>${name}</literal> in the URL definition to ensure that the name attribute is consistent with the source that were actually downloading. Perl packages are made available in <filename>all-packages.nix</filename> through the variable <varname>perlPackages</varname>. For instance, if you have a package that needs <varname>ClassC3</varname>, you would typically write
<programlisting>
foo = import ../path/to/foo.nix {
inherit stdenv fetchurl ...;
inherit (perlPackages) ClassC3;
};
</programlisting>
in <filename>all-packages.nix</filename>. You can test building a Perl
package as follows:
in <filename>all-packages.nix</filename>. You can test building a Perl package as follows:
<screen>
$ nix-build -A perlPackages.ClassC3
<prompt>$ </prompt>nix-build -A perlPackages.ClassC3
</screen>
<varname>buildPerlPackage</varname> adds <literal>perl-</literal> to the
start of the name attribute, so the package above is actually called
<literal>perl-Class-C3-0.21</literal>. So to install it, you can say:
<varname>buildPerlPackage</varname> adds <literal>perl-</literal> to the start of the name attribute, so the package above is actually called <literal>perl-Class-C3-0.21</literal>. So to install it, you can say:
<screen>
$ nix-env -i perl-Class-C3
<prompt>$ </prompt>nix-env -i perl-Class-C3
</screen>
(Of course you can also install using the attribute name: <literal>nix-env -i
-A perlPackages.ClassC3</literal>.)
(Of course you can also install using the attribute name: <literal>nix-env -i -A perlPackages.ClassC3</literal>.)
</para>
<para>
@ -64,39 +43,24 @@ $ nix-env -i perl-Class-C3
<orderedlist>
<listitem>
<para>
In the configure phase, it calls <literal>perl Makefile.PL</literal> to
generate a Makefile. You can set the variable
<varname>makeMakerFlags</varname> to pass flags to
<filename>Makefile.PL</filename>
In the configure phase, it calls <literal>perl Makefile.PL</literal> to generate a Makefile. You can set the variable <varname>makeMakerFlags</varname> to pass flags to <filename>Makefile.PL</filename>
</para>
</listitem>
<listitem>
<para>
It adds the contents of the <envar>PERL5LIB</envar> environment variable
to <literal>#! .../bin/perl</literal> line of Perl scripts as
<literal>-I<replaceable>dir</replaceable></literal> flags. This ensures
that a script can find its dependencies.
It adds the contents of the <envar>PERL5LIB</envar> environment variable to <literal>#! .../bin/perl</literal> line of Perl scripts as <literal>-I<replaceable>dir</replaceable></literal> flags. This ensures that a script can find its dependencies. (This can cause this shebang line to become too long for Darwin to handle; see the note below.)
</para>
</listitem>
<listitem>
<para>
In the fixup phase, it writes the propagated build inputs
(<varname>propagatedBuildInputs</varname>) to the file
<filename>$out/nix-support/propagated-user-env-packages</filename>.
<command>nix-env</command> recursively installs all packages listed in
this file when you install a package that has it. This ensures that a Perl
package can find its dependencies.
In the fixup phase, it writes the propagated build inputs (<varname>propagatedBuildInputs</varname>) to the file <filename>$out/nix-support/propagated-user-env-packages</filename>. <command>nix-env</command> recursively installs all packages listed in this file when you install a package that has it. This ensures that a Perl package can find its dependencies.
</para>
</listitem>
</orderedlist>
</para>
<para>
<varname>buildPerlPackage</varname> is built on top of
<varname>stdenv</varname>, so everything can be customised in the usual way.
For instance, the <literal>BerkeleyDB</literal> module has a
<varname>preConfigure</varname> hook to generate a configuration file used by
<filename>Makefile.PL</filename>:
<varname>buildPerlPackage</varname> is built on top of <varname>stdenv</varname>, so everything can be customised in the usual way. For instance, the <literal>BerkeleyDB</literal> module has a <varname>preConfigure</varname> hook to generate a configuration file used by <filename>Makefile.PL</filename>:
<programlisting>
{ buildPerlPackage, fetchurl, db }:
@ -117,12 +81,7 @@ buildPerlPackage rec {
</para>
<para>
Dependencies on other Perl packages can be specified in the
<varname>buildInputs</varname> and <varname>propagatedBuildInputs</varname>
attributes. If something is exclusively a build-time dependency, use
<varname>buildInputs</varname>; if its (also) a runtime dependency, use
<varname>propagatedBuildInputs</varname>. For instance, this builds a Perl
module that has runtime dependencies on a bunch of other modules:
Dependencies on other Perl packages can be specified in the <varname>buildInputs</varname> and <varname>propagatedBuildInputs</varname> attributes. If something is exclusively a build-time dependency, use <varname>buildInputs</varname>; if its (also) a runtime dependency, use <varname>propagatedBuildInputs</varname>. For instance, this builds a Perl module that has runtime dependencies on a bunch of other modules:
<programlisting>
ClassC3Componentised = buildPerlPackage rec {
name = "Class-C3-Componentised-1.0004";
@ -137,26 +96,44 @@ ClassC3Componentised = buildPerlPackage rec {
</programlisting>
</para>
<para>
On Darwin, if a script has too many <literal>-I<replaceable>dir</replaceable></literal> flags in its first line (its “shebang line”), it will not run. This can be worked around by calling the <literal>shortenPerlShebang</literal> function from the <literal>postInstall</literal> phase:
<programlisting>
{ stdenv, buildPerlPackage, fetchurl, shortenPerlShebang }:
ImageExifTool = buildPerlPackage {
pname = "Image-ExifTool";
version = "11.50";
src = fetchurl {
url = "https://www.sno.phy.queensu.ca/~phil/exiftool/Image-ExifTool-11.50.tar.gz";
sha256 = "0d8v48y94z8maxkmw1rv7v9m0jg2dc8xbp581njb6yhr7abwqdv3";
};
buildInputs = stdenv.lib.optional stdenv.isDarwin shortenPerlShebang;
postInstall = stdenv.lib.optional stdenv.isDarwin ''
shortenPerlShebang $out/bin/exiftool
'';
};
</programlisting>
This will remove the <literal>-I</literal> flags from the shebang line, rewrite them in the <literal>use lib</literal> form, and put them on the next line instead. This function can be given any number of Perl scripts as arguments; it will modify them in-place.
</para>
<section xml:id="ssec-generation-from-CPAN">
<title>Generation from CPAN</title>
<para>
Nix expressions for Perl packages can be generated (almost) automatically
from CPAN. This is done by the program
<command>nix-generate-from-cpan</command>, which can be installed as
follows:
Nix expressions for Perl packages can be generated (almost) automatically from CPAN. This is done by the program <command>nix-generate-from-cpan</command>, which can be installed as follows:
</para>
<screen>
$ nix-env -i nix-generate-from-cpan
<prompt>$ </prompt>nix-env -i nix-generate-from-cpan
</screen>
<para>
This program takes a Perl module name, looks it up on CPAN, fetches and
unpacks the corresponding package, and prints a Nix expression on standard
output. For example:
This program takes a Perl module name, looks it up on CPAN, fetches and unpacks the corresponding package, and prints a Nix expression on standard output. For example:
<screen>
$ nix-generate-from-cpan XML::Simple
<prompt>$ </prompt>nix-generate-from-cpan XML::Simple
XMLSimple = buildPerlPackage rec {
name = "XML-Simple-2.22";
src = fetchurl {
@ -170,9 +147,7 @@ $ nix-generate-from-cpan XML::Simple
};
};
</screen>
The output can be pasted into
<filename>pkgs/top-level/perl-packages.nix</filename> or wherever else you
need it.
The output can be pasted into <filename>pkgs/top-level/perl-packages.nix</filename> or wherever else you need it.
</para>
</section>
@ -180,13 +155,7 @@ $ nix-generate-from-cpan XML::Simple
<title>Cross-compiling modules</title>
<para>
Nixpkgs has experimental support for cross-compiling Perl modules. In many
cases, it will just work out of the box, even for modules with native
extensions. Sometimes, however, the Makefile.PL for a module may
(indirectly) import a native module. In that case, you will need to make a
stub for that module that will satisfy the Makefile.PL and install it into
<filename>lib/perl5/site_perl/cross_perl/${perl.version}</filename>. See the
<varname>postInstall</varname> for <varname>DBI</varname> for an example.
Nixpkgs has experimental support for cross-compiling Perl modules. In many cases, it will just work out of the box, even for modules with native extensions. Sometimes, however, the Makefile.PL for a module may (indirectly) import a native module. In that case, you will need to make a stub for that module that will satisfy the Makefile.PL and install it into <filename>lib/perl5/site_perl/cross_perl/${perl.version}</filename>. See the <varname>postInstall</varname> for <varname>DBI</varname> for an example.
</para>
</section>
</section>

358
doc/languages-frameworks/python.section.md
View File

@ -186,25 +186,24 @@ building Python libraries is `buildPythonPackage`. Let's see how we can build th
`toolz` package.
```nix
{ # ...
{ lib, buildPythonPackage, fetchPypi }:
toolz = buildPythonPackage rec {
pname = "toolz";
version = "0.7.4";
buildPythonPackage rec {
pname = "toolz";
version = "0.7.4";
src = fetchPypi {
inherit pname version;
sha256 = "43c2c9e5e7a16b6c88ba3088a9bfc82f7db8e13378be7c78d6c14a5f8ed05afd";
};
src = fetchPypi {
inherit pname version;
sha256 = "43c2c9e5e7a16b6c88ba3088a9bfc82f7db8e13378be7c78d6c14a5f8ed05afd";
};
doCheck = false;
doCheck = false;
meta = {
homepage = "https://github.com/pytoolz/toolz/";
description = "List processing tools and functional utilities";
license = licenses.bsd3;
maintainers = with maintainers; [ fridh ];
};
meta = with lib; {
homepage = https://github.com/pytoolz/toolz;
description = "List processing tools and functional utilities";
license = licenses.bsd3;
maintainers = with maintainers; [ fridh ];
};
}
```
@ -267,43 +266,43 @@ that we introduced with the `let` expression.
#### Handling dependencies
Our example, `toolz`, does not have any dependencies on other Python
packages or system libraries. According to the manual, `buildPythonPackage`
uses the arguments `buildInputs` and `propagatedBuildInputs` to specify dependencies. If something is
exclusively a build-time dependency, then the dependency should be included as a
`buildInput`, but if it is (also) a runtime dependency, then it should be added
to `propagatedBuildInputs`. Test dependencies are considered build-time dependencies.
Our example, `toolz`, does not have any dependencies on other Python packages or
system libraries. According to the manual, `buildPythonPackage` uses the
arguments `buildInputs` and `propagatedBuildInputs` to specify dependencies. If
something is exclusively a build-time dependency, then the dependency should be
included as a `buildInput`, but if it is (also) a runtime dependency, then it
should be added to `propagatedBuildInputs`. Test dependencies are considered
build-time dependencies and passed to `checkInputs`.
The following example shows which arguments are given to `buildPythonPackage` in
order to build [`datashape`](https://github.com/blaze/datashape).
```nix
{ # ...
{ lib, buildPythonPackage, fetchPypi, numpy, multipledispatch, dateutil, pytest }:
datashape = buildPythonPackage rec {
pname = "datashape";
version = "0.4.7";
buildPythonPackage rec {
pname = "datashape";
version = "0.4.7";
src = fetchPypi {
inherit pname version;
sha256 = "14b2ef766d4c9652ab813182e866f493475e65e558bed0822e38bf07bba1a278";
};
src = fetchPypi {
inherit pname version;
sha256 = "14b2ef766d4c9652ab813182e866f493475e65e558bed0822e38bf07bba1a278";
};
checkInputs = with self; [ pytest ];
propagatedBuildInputs = with self; [ numpy multipledispatch dateutil ];
checkInputs = [ pytest ];
propagatedBuildInputs = [ numpy multipledispatch dateutil ];
meta = {
homepage = https://github.com/ContinuumIO/datashape;
description = "A data description language";
license = licenses.bsd2;
maintainers = with maintainers; [ fridh ];
};
meta = with lib; {
homepage = https://github.com/ContinuumIO/datashape;
description = "A data description language";
license = licenses.bsd2;
maintainers = with maintainers; [ fridh ];
};
}
```
We can see several runtime dependencies, `numpy`, `multipledispatch`, and
`dateutil`. Furthermore, we have one `buildInput`, i.e. `pytest`. `pytest` is a
`dateutil`. Furthermore, we have one `checkInputs`, i.e. `pytest`. `pytest` is a
test runner and is only used during the `checkPhase` and is therefore not added
to `propagatedBuildInputs`.
@ -313,25 +312,24 @@ Python bindings to `libxml2` and `libxslt`. These libraries are only required
when building the bindings and are therefore added as `buildInputs`.
```nix
{ # ...
{ lib, pkgs, buildPythonPackage, fetchPypi }:
lxml = buildPythonPackage rec {
pname = "lxml";
version = "3.4.4";
buildPythonPackage rec {
pname = "lxml";
version = "3.4.4";
src = fetchPypi {
inherit pname version;
sha256 = "16a0fa97hym9ysdk3rmqz32xdjqmy4w34ld3rm3jf5viqjx65lxk";
};
src = fetchPypi {
inherit pname version;
sha256 = "16a0fa97hym9ysdk3rmqz32xdjqmy4w34ld3rm3jf5viqjx65lxk";
};
buildInputs = with self; [ pkgs.libxml2 pkgs.libxslt ];
buildInputs = [ pkgs.libxml2 pkgs.libxslt ];
meta = {
description = "Pythonic binding for the libxml2 and libxslt libraries";
homepage = https://lxml.de;
license = licenses.bsd3;
maintainers = with maintainers; [ sjourdois ];
};
meta = with lib; {
description = "Pythonic binding for the libxml2 and libxslt libraries";
homepage = https://lxml.de;
license = licenses.bsd3;
maintainers = with maintainers; [ sjourdois ];
};
}
```
@ -347,35 +345,34 @@ find each of them in a different folder, and therefore we have to set `LDFLAGS`
and `CFLAGS`.
```nix
{ # ...
{ lib, pkgs, buildPythonPackage, fetchPypi, numpy, scipy }:
pyfftw = buildPythonPackage rec {
pname = "pyFFTW";
version = "0.9.2";
buildPythonPackage rec {
pname = "pyFFTW";
version = "0.9.2";
src = fetchPypi {
inherit pname version;
sha256 = "f6bbb6afa93085409ab24885a1a3cdb8909f095a142f4d49e346f2bd1b789074";
};
src = fetchPypi {
inherit pname version;
sha256 = "f6bbb6afa93085409ab24885a1a3cdb8909f095a142f4d49e346f2bd1b789074";
};
buildInputs = [ pkgs.fftw pkgs.fftwFloat pkgs.fftwLongDouble];
buildInputs = [ pkgs.fftw pkgs.fftwFloat pkgs.fftwLongDouble];
propagatedBuildInputs = with self; [ numpy scipy ];
propagatedBuildInputs = [ numpy scipy ];
# Tests cannot import pyfftw. pyfftw works fine though.
doCheck = false;
# Tests cannot import pyfftw. pyfftw works fine though.
doCheck = false;
preConfigure = ''
export LDFLAGS="-L${pkgs.fftw.dev}/lib -L${pkgs.fftwFloat.out}/lib -L${pkgs.fftwLongDouble.out}/lib"
export CFLAGS="-I${pkgs.fftw.dev}/include -I${pkgs.fftwFloat.dev}/include -I${pkgs.fftwLongDouble.dev}/include"
'';
preConfigure = ''
export LDFLAGS="-L${pkgs.fftw.dev}/lib -L${pkgs.fftwFloat.out}/lib -L${pkgs.fftwLongDouble.out}/lib"
export CFLAGS="-I${pkgs.fftw.dev}/include -I${pkgs.fftwFloat.dev}/include -I${pkgs.fftwLongDouble.dev}/include"
'';
meta = {
description = "A pythonic wrapper around FFTW, the FFT library, presenting a unified interface for all the supported transforms";
homepage = http://hgomersall.github.com/pyFFTW/;
license = with licenses; [ bsd2 bsd3 ];
maintainers = with maintainers; [ fridh ];
};
meta = with lib; {
description = "A pythonic wrapper around FFTW, the FFT library, presenting a unified interface for all the supported transforms";
homepage = http://hgomersall.github.com/pyFFTW;
license = with licenses; [ bsd2 bsd3 ];
maintainers = with maintainers; [ fridh ];
};
}
```
@ -403,7 +400,7 @@ Indeed, we can just add any package we like to have in our environment to `propa
```nix
with import <nixpkgs> {};
with pkgs.python35Packages;
with python35Packages;
buildPythonPackage rec {
name = "mypackage";
@ -436,7 +433,7 @@ Let's split the package definition from the environment definition.
We first create a function that builds `toolz` in `~/path/to/toolz/release.nix`
```nix
{ lib, pkgs, buildPythonPackage }:
{ lib, buildPythonPackage }:
buildPythonPackage rec {
pname = "toolz";
@ -448,7 +445,7 @@ buildPythonPackage rec {
};
meta = with lib; {
homepage = "http://github.com/pytoolz/toolz/";
homepage = "https://github.com/pytoolz/toolz/";
description = "List processing tools and functional utilities";
license = licenses.bsd3;
maintainers = with maintainers; [ fridh ];
@ -456,18 +453,17 @@ buildPythonPackage rec {
}
```
It takes two arguments, `pkgs` and `buildPythonPackage`.
It takes an argument `buildPythonPackage`.
We now call this function using `callPackage` in the definition of our environment
```nix
with import <nixpkgs> {};
( let
toolz = pkgs.callPackage /path/to/toolz/release.nix {
pkgs = pkgs;
buildPythonPackage = pkgs.python35Packages.buildPythonPackage;
toolz = callPackage /path/to/toolz/release.nix {
buildPythonPackage = python35Packages.buildPythonPackage;
};
in pkgs.python35.withPackages (ps: [ ps.numpy toolz ])
in python35.withPackages (ps: [ ps.numpy toolz ])
).env
```
@ -478,18 +474,18 @@ don't explicitly define which `python` derivation should be used. In the above
example we use `buildPythonPackage` that is part of the set `python35Packages`,
and in this case the `python35` interpreter is automatically used.
## Reference
### Interpreters
Versions 2.7, 3.4, 3.5, 3.6 and 3.7 of the CPython interpreter are available as
respectively `python27`, `python34`, `python35` and `python36`. The PyPy interpreter
is available as `pypy`. The aliases `python2` and `python3` correspond to respectively `python27` and
`python35`. The default interpreter, `python`, maps to `python2`.
The Nix expressions for the interpreters can be found in
`pkgs/development/interpreters/python`.
Versions 2.7, 3.5, 3.6 and 3.7 of the CPython interpreter are available as
respectively `python27`, `python35`, `python36` and `python37`. The aliases
`python2` and `python3` correspond to respectively `python27` and
`python37`. The default interpreter, `python`, maps to `python2`. The PyPy
interpreters compatible with Python 2.7 and 3 are available as `pypy27` and
`pypy3`, with aliases `pypy2` mapping to `pypy27` and `pypy` mapping to
`pypy2`. The Nix expressions for the interpreters can be
found in `pkgs/development/interpreters/python`.
All packages depending on any Python interpreter get appended
`out/{python.sitePackages}` to `$PYTHONPATH` if such directory
@ -508,13 +504,13 @@ Each interpreter has the following attributes:
- `buildEnv`. Function to build python interpreter environments with extra packages bundled together. See section *python.buildEnv function* for usage and documentation.
- `withPackages`. Simpler interface to `buildEnv`. See section *python.withPackages function* for usage and documentation.
- `sitePackages`. Alias for `lib/${libPrefix}/site-packages`.
- `executable`. Name of the interpreter executable, e.g. `python3.4`.
- `executable`. Name of the interpreter executable, e.g. `python3.7`.
- `pkgs`. Set of Python packages for that specific interpreter. The package set can be modified by overriding the interpreter and passing `packageOverrides`.
### Building packages and applications
Python libraries and applications that use `setuptools` or
`distutils` are typically build with respectively the `buildPythonPackage` and
`distutils` are typically built with respectively the `buildPythonPackage` and
`buildPythonApplication` functions. These two functions also support installing a `wheel`.
All Python packages reside in `pkgs/top-level/python-packages.nix` and all
@ -530,7 +526,6 @@ attribute set is created for each available Python interpreter. The available
sets are
* `pkgs.python27Packages`
* `pkgs.python34Packages`
* `pkgs.python35Packages`
* `pkgs.python36Packages`
* `pkgs.python37Packages`
@ -539,41 +534,42 @@ sets are
and the aliases
* `pkgs.python2Packages` pointing to `pkgs.python27Packages`
* `pkgs.python3Packages` pointing to `pkgs.python36Packages`
* `pkgs.python3Packages` pointing to `pkgs.python37Packages`
* `pkgs.pythonPackages` pointing to `pkgs.python2Packages`
#### `buildPythonPackage` function
The `buildPythonPackage` function is implemented in
`pkgs/development/interpreters/python/build-python-package.nix`
`pkgs/development/interpreters/python/mk-python-derivation`
using setup hooks.
The following is an example:
```nix
{ lib, buildPythonPackage, fetchPypi, hypothesis, setuptools_scm, attrs, py, setuptools, six, pluggy }:
buildPythonPackage rec {
version = "3.3.1";
pname = "pytest";
preCheck = ''
# don't test bash builtins
rm testing/test_argcomplete.py
'';
version = "3.3.1";
src = fetchPypi {
inherit pname version;
sha256 = "cf8436dc59d8695346fcd3ab296de46425ecab00d64096cebe79fb51ecb2eb93";
};
postPatch = ''
# don't test bash builtins
rm testing/test_argcomplete.py
'';
checkInputs = [ hypothesis ];
buildInputs = [ setuptools_scm ];
nativeBuildInputs = [ setuptools_scm ];
propagatedBuildInputs = [ attrs py setuptools six pluggy ];
meta = with stdenv.lib; {
meta = with lib; {
maintainers = with maintainers; [ domenkozar lovek323 madjar lsix ];
description = "Framework for writing tests";
};
}
```
The `buildPythonPackage` mainly does four things:
@ -586,11 +582,6 @@ The `buildPythonPackage` mainly does four things:
environment variable and add dependent libraries to script's `sys.path`.
* In the `installCheck` phase, `${python.interpreter} setup.py test` is ran.
As in Perl, dependencies on other Python packages can be specified in the
`buildInputs` and `propagatedBuildInputs` attributes. If something is
exclusively a build-time dependency, use `buildInputs`; if it is (also) a runtime
dependency, use `propagatedBuildInputs`.
By default tests are run because `doCheck = true`. Test dependencies, like
e.g. the test runner, should be added to `checkInputs`.
@ -602,19 +593,28 @@ as the interpreter unless overridden otherwise.
All parameters from `stdenv.mkDerivation` function are still supported. The following are specific to `buildPythonPackage`:
* `catchConflicts ? true`: If `true`, abort package build if a package name appears more than once in dependency tree. Default is `true`.
* `checkInputs ? []`: Dependencies needed for running the `checkPhase`. These are added to `buildInputs` when `doCheck = true`.
* `disabled` ? false: If `true`, package is not build for the particular Python interpreter version.
* `disabled` ? false: If `true`, package is not built for the particular Python interpreter version.
* `dontWrapPythonPrograms ? false`: Skip wrapping of python programs.
* `installFlags ? []`: A list of strings. Arguments to be passed to `pip install`. To pass options to `python setup.py install`, use `--install-option`. E.g., `installFlags=["--install-option='--cpp_implementation'"].
* `format ? "setuptools"`: Format of the source. Valid options are `"setuptools"`, `"flit"`, `"wheel"`, and `"other"`. `"setuptools"` is for when the source has a `setup.py` and `setuptools` is used to build a wheel, `flit`, in case `flit` should be used to build a wheel, and `wheel` in case a wheel is provided. Use `other` when a custom `buildPhase` and/or `installPhase` is needed.
* `permitUserSite ? false`: Skip setting the `PYTHONNOUSERSITE` environment variable in wrapped programs.
* `installFlags ? []`: A list of strings. Arguments to be passed to `pip install`. To pass options to `python setup.py install`, use `--install-option`. E.g., `installFlags=["--install-option='--cpp_implementation'"]`.
* `format ? "setuptools"`: Format of the source. Valid options are `"setuptools"`, `"pyproject"`, `"flit"`, `"wheel"`, and `"other"`. `"setuptools"` is for when the source has a `setup.py` and `setuptools` is used to build a wheel, `flit`, in case `flit` should be used to build a wheel, and `wheel` in case a wheel is provided. Use `other` when a custom `buildPhase` and/or `installPhase` is needed.
* `makeWrapperArgs ? []`: A list of strings. Arguments to be passed to `makeWrapper`, which wraps generated binaries. By default, the arguments to `makeWrapper` set `PATH` and `PYTHONPATH` environment variables before calling the binary. Additional arguments here can allow a developer to set environment variables which will be available when the binary is run. For example, `makeWrapperArgs = ["--set FOO BAR" "--set BAZ QUX"]`.
* `namePrefix`: Prepends text to `${name}` parameter. In case of libraries, this defaults to `"python3.5-"` for Python 3.5, etc., and in case of applications to `""`.
* `pythonPath ? []`: List of packages to be added into `$PYTHONPATH`. Packages in `pythonPath` are not propagated (contrary to `propagatedBuildInputs`).
* `preShellHook`: Hook to execute commands before `shellHook`.
* `postShellHook`: Hook to execute commands after `shellHook`.
* `removeBinByteCode ? true`: Remove bytecode from `/bin`. Bytecode is only created when the filenames end with `.py`.
* `setupPyGlobalFlags ? []`: List of flags passed to `setup.py` command.
* `setupPyBuildFlags ? []`: List of flags passed to `setup.py build_ext` command.
The `stdenv.mkDerivation` function accepts various parameters for describing build inputs (see "Specifying dependencies"). The following are of special
interest for Python packages, either because these are primarily used, or because their behaviour is different:
* `nativeBuildInputs ? []`: Build-time only dependencies. Typically executables as well as the items listed in `setup_requires`.
* `buildInputs ? []`: Build and/or run-time dependencies that need to be be compiled for the host machine. Typically non-Python libraries which are being linked.
* `checkInputs ? []`: Dependencies needed for running the `checkPhase`. These are added to `nativeBuildInputs` when `doCheck = true`. Items listed in `tests_require` go here.
* `propagatedBuildInputs ? []`: Aside from propagating dependencies, `buildPythonPackage` also injects code into and wraps executables with the paths included in this list. Items listed in `install_requires` go here.
##### Overriding Python packages
The `buildPythonPackage` function has a `overridePythonAttrs` method that
@ -638,7 +638,7 @@ with import <nixpkgs> {};
};
});
};
in pkgs.python3.override {inherit packageOverrides;};
in pkgs.python3.override {inherit packageOverrides; self = python;};
in python.withPackages(ps: [ps.blaze])).env
```
@ -655,6 +655,39 @@ Another difference is that `buildPythonPackage` by default prefixes the names of
the packages with the version of the interpreter. Because this is irrelevant for
applications, the prefix is omitted.
When packaging a python application with `buildPythonApplication`, it should be
called with `callPackage` and passed `python` or `pythonPackages` (possibly
specifying an interpreter version), like this:
```nix
{ lib, python3Packages }:
python3Packages.buildPythonApplication rec {
pname = "luigi";
version = "2.7.9";
src = python3Packages.fetchPypi {
inherit pname version;
sha256 = "035w8gqql36zlan0xjrzz9j4lh9hs0qrsgnbyw07qs7lnkvbdv9x";
};
propagatedBuildInputs = with python3Packages; [ tornado_4 python-daemon ];
meta = with lib; {
...
};
}
```
This is then added to `all-packages.nix` just as any other application would be.
```nix
luigi = callPackage ../applications/networking/cluster/luigi { };
```
Since the package is an application, a consumer doesn't need to care about
python versions or modules, which is why they don't go in `pythonPackages`.
#### `toPythonApplication` function
A distinction is made between applications and libraries, however, sometimes a
@ -694,7 +727,7 @@ Saving the following as `default.nix`
with import <nixpkgs> {};
python.buildEnv.override {
extraLibs = [ pkgs.pythonPackages.pyramid ];
extraLibs = [ pythonPackages.pyramid ];
ignoreCollisions = true;
}
```
@ -726,6 +759,7 @@ specified packages in its path.
* `extraLibs`: List of packages installed inside the environment.
* `postBuild`: Shell command executed after the build of environment.
* `ignoreCollisions`: Ignore file collisions inside the environment (default is `false`).
* `permitUserSite`: Skip setting the `PYTHONNOUSERSITE` environment variable in wrapped binaries in the environment.
#### `python.withPackages` function
@ -764,6 +798,22 @@ such as `ignoreCollisions = true` or `postBuild`. If you need them, you have to
Python 2 namespace packages may provide `__init__.py` that collide. In that case `python.buildEnv`
should be used with `ignoreCollisions = true`.
#### Setup hooks
The following are setup hooks specifically for Python packages. Most of these are
used in `buildPythonPackage`.
- `flitBuildHook` to build a wheel using `flit`.
- `pipBuildHook` to build a wheel using `pip` and PEP 517. Note a build system (e.g. `setuptools` or `flit`) should still be added as `nativeBuildInput`.
- `pipInstallHook` to install wheels.
- `pytestCheckHook` to run tests with `pytest`.
- `pythonCatchConflictsHook` to check whether a Python package is not already existing.
- `pythonImportsCheckHook` to check whether importing the listed modules works.
- `pythonRemoveBinBytecode` to remove bytecode from the `/bin` folder.
- `setuptoolsBuildHook` to build a wheel using `setuptools`.
- `setuptoolsCheckHook` to run tests with `python setup.py test`.
- `wheelUnpackHook` to move a wheel to the correct folder so it can be installed with the `pipInstallHook`.
### Development mode
Development or editable mode is supported. To develop Python packages
@ -776,11 +826,12 @@ Given a `default.nix`:
```nix
with import <nixpkgs> {};
buildPythonPackage { name = "myproject";
pythonPackages.buildPythonPackage {
name = "myproject";
buildInputs = with pythonPackages; [ pyramid ];
buildInputs = with pkgs.pythonPackages; [ pyramid ];
src = ./.; }
src = ./.;
}
```
Running `nix-shell` with no arguments should give you
@ -799,13 +850,12 @@ Note: There is a boolean value `lib.inNixShell` set to `true` if nix-shell is in
Packages inside nixpkgs are written by hand. However many tools exist in
community to help save time. No tool is preferred at the moment.
- [python2nix](https://github.com/proger/python2nix) by Vladimir Kirillov
- [pypi2nix](https://github.com/garbas/pypi2nix) by Rok Garbas
- [pypi2nix](https://github.com/offlinehacker/pypi2nix) by Jaka Hudoklin
- [pypi2nix](https://github.com/nix-community/pypi2nix): Generate Nix expressions for your Python project. Note that [sharing derivations from pypi2nix with nixpkgs is possible but not encouraged](https://github.com/nix-community/pypi2nix/issues/222#issuecomment-443497376).
- [python2nix](https://github.com/proger/python2nix) by Vladimir Kirillov.
### Deterministic builds
Python 2.7, 3.5 and 3.6 are now built deterministically and 3.4 mostly.
The Python interpreters are now built deterministically.
Minor modifications had to be made to the interpreters in order to generate
deterministic bytecode. This has security implications and is relevant for
those using Python in a `nix-shell`.
@ -841,7 +891,6 @@ example of such a situation is when `py.test` is used.
'';
}
```
- Unicode issues can typically be fixed by including `glibcLocales` in `buildInputs` and exporting `LC_ALL=en_US.utf-8`.
- Tests that attempt to access `$HOME` can be fixed by using the following work-around before running tests (e.g. `preCheck`): `export HOME=$(mktemp -d)`
## FAQ
@ -967,10 +1016,13 @@ Create this `default.nix` file, together with a `requirements.txt` and simply ex
```nix
with import <nixpkgs> {};
with pkgs.python27Packages;
with python27Packages;
stdenv.mkDerivation {
name = "impurePythonEnv";
src = null;
buildInputs = [
# these packages are required for virtualenv and pip to work:
#
@ -990,14 +1042,15 @@ stdenv.mkDerivation {
libxslt
libzip
stdenv
zlib ];
src = null;
zlib
];
shellHook = ''
# set SOURCE_DATE_EPOCH so that we can use python wheels
SOURCE_DATE_EPOCH=$(date +%s)
virtualenv --no-setuptools venv
export PATH=$PWD/venv/bin:$PATH
pip install -r requirements.txt
# set SOURCE_DATE_EPOCH so that we can use python wheels
SOURCE_DATE_EPOCH=$(date +%s)
virtualenv --no-setuptools venv
export PATH=$PWD/venv/bin:$PATH
pip install -r requirements.txt
'';
}
```
@ -1047,8 +1100,7 @@ To modify only a Python package set instead of a whole Python derivation, use th
Use the following overlay template:
```nix
self: super:
{
self: super: {
python = super.python.override {
packageOverrides = python-self: python-super: {
zerobin = python-super.zerobin.overrideAttrs (oldAttrs: {
@ -1063,6 +1115,42 @@ self: super:
}
```
### How to use Intel's MKL with numpy and scipy?
A `site.cfg` is created that configures BLAS based on the `blas` parameter
of the `numpy` derivation. By passing in `mkl`, `numpy` and packages depending
on `numpy` will be built with `mkl`.
The following is an overlay that configures `numpy` to use `mkl`:
```nix
self: super: {
python37 = super.python37.override {
packageOverrides = python-self: python-super: {
numpy = python-super.numpy.override {
blas = super.pkgs.mkl;
};
};
};
}
```
`mkl` requires an `openmp` implementation when running with multiple processors.
By default, `mkl` will use Intel's `iomp` implementation if no other is
specified, but this is a runtime-only dependency and binary compatible with the
LLVM implementation. To use that one instead, Intel recommends users set it with
`LD_PRELOAD`.
Note that `mkl` is only available on `x86_64-{linux,darwin}` platforms;
moreover, Hydra is not building and distributing pre-compiled binaries using it.
### What inputs do `setup_requires`, `install_requires` and `tests_require` map to?
In a `setup.py` or `setup.cfg` it is common to declare dependencies:
* `setup_requires` corresponds to `nativeBuildInputs`
* `install_requires` corresponds to `propagatedBuildInputs`
* `tests_require` corresponds to `checkInputs`
## Contributing
### Contributing guidelines

183
doc/languages-frameworks/qt.xml
View File

@ -4,71 +4,146 @@
<title>Qt</title>
<para>
Qt is a comprehensive desktop and mobile application development toolkit for
C++. Legacy support is available for Qt 3 and Qt 4, but all current
development uses Qt 5. The Qt 5 packages in Nixpkgs are updated frequently to
take advantage of new features, but older versions are typically retained
until their support window ends. The most important consideration in
packaging Qt-based software is ensuring that each package and all its
dependencies use the same version of Qt 5; this consideration motivates most
of the tools described below.
This section describes the differences between Nix expressions for Qt libraries and applications and Nix expressions for other C++ software. Some knowledge of the latter is assumed. There are primarily two problems which the Qt infrastructure is designed to address: ensuring consistent versioning of all dependencies and finding dependencies at runtime.
</para>
<section xml:id="ssec-qt-libraries">
<title>Packaging Libraries for Nixpkgs</title>
<example xml:id='qt-default-nix'>
<title>Nix expression for a Qt package (<filename>default.nix</filename>)</title>
<programlisting>
{ mkDerivation, lib, qtbase }: <co xml:id='qt-default-nix-co-1' />
mkDerivation { <co xml:id='qt-default-nix-co-2' />
pname = "myapp";
version = "1.0";
buildInputs = [ qtbase ]; <co xml:id='qt-default-nix-co-3' />
}
</programlisting>
</example>
<calloutlist>
<callout arearefs='qt-default-nix-co-1'>
<para>
Import <literal>mkDerivation</literal> and Qt (such as <literal>qtbase</literal> modules directly. <emphasis>Do not</emphasis> import Qt package sets; the Qt versions of dependencies may not be coherent, causing build and runtime failures.
</para>
</callout>
<callout arearefs='qt-default-nix-co-2'>
<para>
Use <literal>mkDerivation</literal> instead of <literal>stdenv.mkDerivation</literal>. <literal>mkDerivation</literal> is a wrapper around <literal>stdenv.mkDerivation</literal> which applies some Qt-specific settings. This deriver accepts the same arguments as <literal>stdenv.mkDerivation</literal>; refer to <xref linkend='chap-stdenv' /> for details.
</para>
<para>
To use another deriver instead of <literal>stdenv.mkDerivation</literal>, use <literal>mkDerivationWith</literal>:
<programlisting>
mkDerivationWith myDeriver {
# ...
}
</programlisting>
If you cannot use <literal>mkDerivationWith</literal>, please refer to <xref linkend='qt-runtime-dependencies' />.
</para>
</callout>
<callout arearefs='qt-default-nix-co-3'>
<para>
<literal>mkDerivation</literal> accepts the same arguments as <literal>stdenv.mkDerivation</literal>, such as <literal>buildInputs</literal>.
</para>
</callout>
</calloutlist>
<formalpara xml:id='qt-runtime-dependencies'>
<title>Locating runtime dependencies</title>
<para>
Whenever possible, libraries that use Qt 5 should be built with each
available version. Packages providing libraries should be added to the
top-level function <varname>mkLibsForQt5</varname>, which is used to build a
set of libraries for every Qt 5 version. A special
<varname>callPackage</varname> function is used in this scope to ensure that
the entire dependency tree uses the same Qt 5 version. Import dependencies
unqualified, i.e., <literal>qtbase</literal> not
<literal>qt5.qtbase</literal>. <emphasis>Do not</emphasis> import a package
set such as <literal>qt5</literal> or <literal>libsForQt5</literal>.
</para>
Qt applications need to be wrapped to find runtime dependencies. If you cannot use <literal>mkDerivation</literal> or <literal>mkDerivationWith</literal> above, include <literal>wrapQtAppsHook</literal> in <literal>nativeBuildInputs</literal>:
<programlisting>
stdenv.mkDerivation {
# ...
nativeBuildInputs = [ wrapQtAppsHook ];
}
</programlisting>
</para>
</formalpara>
<para>
Entries added to <literal>qtWrapperArgs</literal> are used to modify the wrappers created by <literal>wrapQtAppsHook</literal>. The entries are passed as arguments to <xref linkend='fun-wrapProgram' />.
<programlisting>
mkDerivation {
# ...
qtWrapperArgs = [ ''--prefix PATH : /path/to/bin'' ];
}
</programlisting>
</para>
<para>
Set <literal>dontWrapQtApps</literal> to stop applications from being wrapped automatically. It is required to wrap applications manually with <literal>wrapQtApp</literal>, using the syntax of <xref linkend='fun-wrapProgram' />:
<programlisting>
mkDerivation {
# ...
dontWrapQtApps = true;
preFixup = ''
wrapQtApp "$out/bin/myapp" --prefix PATH : /path/to/bin
'';
}
</programlisting>
</para>
<note>
<para>
If a library does not support a particular version of Qt 5, it is best to
mark it as broken by setting its <literal>meta.broken</literal> attribute. A
package may be marked broken for certain versions by testing the
<literal>qtbase.version</literal> attribute, which will always give the
current Qt 5 version.
<literal>wrapQtAppsHook</literal> ignores files that are non-ELF executables. This means that scripts won't be automatically wrapped so you'll need to manually wrap them as previously mentioned. An example of when you'd always need to do this is with Python applications that use PyQT.
</para>
</section>
</note>
<section xml:id="ssec-qt-applications">
<title>Packaging Applications for Nixpkgs</title>
<para>
Libraries are built with every available version of Qt. Use the <literal>meta.broken</literal> attribute to disable the package for unsupported Qt versions:
<programlisting>
mkDerivation {
# ...
# Disable this library with Qt &lt; 5.9.0
meta.broken = builtins.compareVersions qtbase.version "5.9.0" &lt; 0;
}
</programlisting>
</para>
<formalpara>
<title>Adding a library to Nixpkgs</title>
<para>
Call your application expression using
<literal>libsForQt5.callPackage</literal> instead of
<literal>callPackage</literal>. Import dependencies unqualified, i.e.,
<literal>qtbase</literal> not <literal>qt5.qtbase</literal>. <emphasis>Do
not</emphasis> import a package set such as <literal>qt5</literal> or
<literal>libsForQt5</literal>.
</para>
Add a Qt library to <filename>all-packages.nix</filename> by adding it to the collection inside <literal>mkLibsForQt5</literal>. This ensures that the library is built with every available version of Qt as needed.
<example xml:id='qt-library-all-packages-nix'>
<title>Adding a Qt library to <filename>all-packages.nix</filename></title>
<programlisting>
{
# ...
<para>
Qt 5 maintains strict backward compatibility, so it is generally best to
build an application package against the latest version using the
<varname>libsForQt5</varname> library set. In case a package does not build
with the latest Qt version, it is possible to pick a set pinned to a
particular version, e.g. <varname>libsForQt55</varname> for Qt 5.5, if that
is the latest version the package supports. If a package must be pinned to
an older Qt version, be sure to file a bug upstream; because Qt is strictly
backwards-compatible, any incompatibility is by definition a bug in the
application.
</para>
mkLibsForQt5 = self: with self; {
# ...
<para>
When testing applications in Nixpkgs, it is a common practice to build the
package with <literal>nix-build</literal> and run it using the created
symbolic link. This will not work with Qt applications, however, because
they have many hard runtime requirements that can only be guaranteed if the
package is actually installed. To test a Qt application, install it with
<literal>nix-env</literal> or run it inside <literal>nix-shell</literal>.
mylib = callPackage ../path/to/mylib {};
};
# ...
}
</programlisting>
</example>
</para>
</section>
</formalpara>
<formalpara>
<title>Adding an application to Nixpkgs</title>
<para>
Add a Qt application to <filename>all-packages.nix</filename> using <literal>libsForQt5.callPackage</literal> instead of the usual <literal>callPackage</literal>. The former ensures that all dependencies are built with the same version of Qt.
<example xml:id='qt-application-all-packages-nix'>
<title>Adding a Qt application to <filename>all-packages.nix</filename></title>
<programlisting>
{
# ...
myapp = libsForQt5.callPackage ../path/to/myapp/ {};
# ...
}
</programlisting>
</example>
</para>
</formalpara>
</section>

4
doc/languages-frameworks/r.section.md
View File

@ -1,5 +1,5 @@
R packages
==========
R
=
## Installation

365
doc/languages-frameworks/ruby.section.md Normal file
View File

@ -0,0 +1,365 @@
---
title: Ruby
author: Michael Fellinger
date: 2019-05-23
---
# Ruby
## User Guide
### Using Ruby
#### Overview
Several versions of Ruby interpreters are available on Nix, as well as over 250 gems and many applications written in Ruby.
The attribute `ruby` refers to the default Ruby interpreter, which is currently
MRI 2.5. It's also possible to refer to specific versions, e.g. `ruby_2_6`, `jruby`, or `mruby`.
In the nixpkgs tree, Ruby packages can be found throughout, depending on what
they do, and are called from the main package set. Ruby gems, however are
separate sets, and there's one default set for each interpreter (currently MRI
only).
There are two main approaches for using Ruby with gems.
One is to use a specifically locked `Gemfile` for an application that has very strict dependencies.
The other is to depend on the common gems, which we'll explain further down, and
rely on them being updated regularly.
The interpreters have common attributes, namely `gems`, and `withPackages`. So
you can refer to `ruby.gems.nokogiri`, or `ruby_2_5.gems.nokogiri` to get the
Nokogiri gem already compiled and ready to use.
Since not all gems have executables like `nokogiri`, it's usually more
convenient to use the `withPackages` function like this:
`ruby.withPackages (p: with p; [ nokogiri ])`. This will also make sure that the
Ruby in your environment will be able to find the gem and it can be used in your
Ruby code (for example via `ruby` or `irb` executables) via `require "nokogiri"`
as usual.
#### Temporary Ruby environment with `nix-shell`
Rather than having a single Ruby environment shared by all Ruby
development projects on a system, Nix allows you to create separate
environments per project. `nix-shell` gives you the possibility to
temporarily load another environment akin to a combined `chruby` or
`rvm` and `bundle exec`.
There are two methods for loading a shell with Ruby packages. The first and
recommended method is to create an environment with `ruby.withPackages` and load
that.
```shell
nix-shell -p "ruby.withPackages (ps: with ps; [ nokogiri pry ])"
```
The other method, which is not recommended, is to create an environment and list
all the packages directly.
```shell
nix-shell -p ruby.gems.nokogiri ruby.gems.pry
```
Again, it's possible to launch the interpreter from the shell. The Ruby
interpreter has the attribute `gems` which contains all Ruby gems for that
specific interpreter.
##### Load environment from `.nix` expression
As explained in the Nix manual, `nix-shell` can also load an expression from a
`.nix` file. Say we want to have Ruby 2.5, `nokogori`, and `pry`. Consider a
`shell.nix` file with:
```nix
with import <nixpkgs> {};
ruby.withPackages (ps: with ps; [ nokogiri pry ])
```
What's happening here?
1. We begin with importing the Nix Packages collections. `import <nixpkgs>`
imports the `<nixpkgs>` function, `{}` calls it and the `with` statement
brings all attributes of `nixpkgs` in the local scope. These attributes form
the main package set.
2. Then we create a Ruby environment with the `withPackages` function.
3. The `withPackages` function expects us to provide a function as an argument
that takes the set of all ruby gems and returns a list of packages to include
in the environment. Here, we select the packages `nokogiri` and `pry` from
the package set.
##### Execute command with `--run`
A convenient flag for `nix-shell` is `--run`. It executes a command in the
`nix-shell`. We can e.g. directly open a `pry` REPL:
```shell
nix-shell -p "ruby.withPackages (ps: with ps; [ nokogiri pry ])" --run "pry"
```
Or immediately require `nokogiri` in pry:
```shell
nix-shell -p "ruby.withPackages (ps: with ps; [ nokogiri pry ])" --run "pry -rnokogiri"
```
Or run a script using this environment:
```shell
nix-shell -p "ruby.withPackages (ps: with ps; [ nokogiri pry ])" --run "ruby example.rb"
```
##### Using `nix-shell` as shebang
In fact, for the last case, there is a more convenient method. You can add a
[shebang](https://en.wikipedia.org/wiki/Shebang_(Unix)) to your script
specifying which dependencies `nix-shell` needs. With the following shebang, you
can just execute `./example.rb`, and it will run with all dependencies.
```ruby
#! /usr/bin/env nix-shell
#! nix-shell -i ruby -p "ruby.withPackages (ps: with ps; [ nokogiri rest-client ])"
require 'nokogiri'
require 'rest-client'
body = RestClient.get('http://example.com').body
puts Nokogiri::HTML(body).at('h1').text
```
### Developing with Ruby
#### Using an existing Gemfile
In most cases, you'll already have a `Gemfile.lock` listing all your dependencies.
This can be used to generate a `gemset.nix` which is used to fetch the gems and
combine them into a single environment.
The reason why you need to have a separate file for this, is that Nix requires
you to have a checksum for each input to your build.
Since the `Gemfile.lock` that `bundler` generates doesn't provide us with
checksums, we have to first download each gem, calculate its SHA256, and store
it in this separate file.
So the steps from having just a `Gemfile` to a `gemset.nix` are:
```shell
bundle lock
bundix
```
If you already have a `Gemfile.lock`, you can simply run `bundix` and it will
work the same.
To update the gems in your `Gemfile.lock`, you may use the `bundix -l` flag,
which will create a new `Gemfile.lock` in case the `Gemfile` has a more recent
time of modification.
Once the `gemset.nix` is generated, it can be used in a
`bundlerEnv` derivation. Here is an example you could use for your `shell.nix`:
```nix
# ...
let
gems = bundlerEnv {
name = "gems-for-some-project";
gemdir = ./.;
};
in mkShell { buildInputs = [ gems gems.wrappedRuby ]; }
```
With this file in your directory, you can run `nix-shell` to build and use the gems.
The important parts here are `bundlerEnv` and `wrappedRuby`.
The `bundlerEnv` is a wrapper over all the gems in your gemset. This means that
all the `/lib` and `/bin` directories will be available, and the executables of
all gems (even of indirect dependencies) will end up in your `$PATH`.
The `wrappedRuby` provides you with all executables that come with Ruby itself,
but wrapped so they can easily find the gems in your gemset.
One common issue that you might have is that you have Ruby 2.6, but also
`bundler` in your gemset. That leads to a conflict for `/bin/bundle` and
`/bin/bundler`. You can resolve this by wrapping either your Ruby or your gems
in a `lowPrio` call. So in order to give the `bundler` from your gemset
priority, it would be used like this:
```nix
# ...
mkShell { buildInputs = [ gems (lowPrio gems.wrappedRuby) ]; }
```
#### Gem-specific configurations and workarounds
In some cases, especially if the gem has native extensions, you might need to
modify the way the gem is built.
This is done via a common configuration file that includes all of the
workarounds for each gem.
This file lives at `/pkgs/development/ruby-modules/gem-config/default.nix`,
since it already contains a lot of entries, it should be pretty easy to add the
modifications you need for your needs.
In the meanwhile, or if the modification is for a private gem, you can also add
the configuration to only your own environment.
Two places that allow this modification are the `ruby` derivation, or `bundlerEnv`.
Here's the `ruby` one:
```nix
{ pg_version ? "10", pkgs ? import <nixpkgs> { } }:
let
myRuby = pkgs.ruby.override {
defaultGemConfig = pkgs.defaultGemConfig // {
pg = attrs: {
buildFlags =
[ "--with-pg-config=${pkgs."postgresql_${pg_version}"}/bin/pg_config" ];
};
};
};
in myRuby.withPackages (ps: with ps; [ pg ])
```
And an example with `bundlerEnv`:
```nix
{ pg_version ? "10", pkgs ? import <nixpkgs> { } }:
let
gems = pkgs.bundlerEnv {
name = "gems-for-some-project";
gemdir = ./.;
gemConfig = pkgs.defaultGemConfig // {
pg = attrs: {
buildFlags =
[ "--with-pg-config=${pkgs."postgresql_${pg_version}"}/bin/pg_config" ];
};
};
};
in mkShell { buildInputs = [ gems gems.wrappedRuby ]; }
```
And finally via overlays:
```nix
{ pg_version ? "10" }:
let
pkgs = import <nixpkgs> {
overlays = [
(self: super: {
defaultGemConfig = super.defaultGemConfig // {
pg = attrs: {
buildFlags = [
"--with-pg-config=${
pkgs."postgresql_${pg_version}"
}/bin/pg_config"
];
};
};
})
];
};
in pkgs.ruby.withPackages (ps: with ps; [ pg ])
```
Then we can get whichever postgresql version we desire and the `pg` gem will
always reference it correctly:
```shell
$ nix-shell --argstr pg_version 9_4 --run 'ruby -rpg -e "puts PG.library_version"'
90421
$ nix-shell --run 'ruby -rpg -e "puts PG.library_version"'
100007
```
Of course for this use-case one could also use overlays since the configuration
for `pg` depends on the `postgresql` alias, but for demonstration purposes this
has to suffice.
#### Adding a gem to the default gemset
Now that you know how to get a working Ruby environment with Nix, it's time to
go forward and start actually developing with Ruby.
We will first have a look at how Ruby gems are packaged on Nix. Then, we will
look at how you can use development mode with your code.
All gems in the standard set are automatically generated from a single
`Gemfile`. The dependency resolution is done with `bundler` and makes it more
likely that all gems are compatible to each other.
In order to add a new gem to nixpkgs, you can put it into the
`/pkgs/development/ruby-modules/with-packages/Gemfile` and run
`./maintainers/scripts/update-ruby-packages`.
To test that it works, you can then try using the gem with:
```shell
NIX_PATH=nixpkgs=$PWD nix-shell -p "ruby.withPackages (ps: with ps; [ name-of-your-gem ])"
```
#### Packaging applications
A common task is to add a ruby executable to nixpkgs, popular examples would be
`chef`, `jekyll`, or `sass`. A good way to do that is to use the `bundlerApp`
function, that allows you to make a package that only exposes the listed
executables, otherwise the package may cause conflicts through common paths like
`bin/rake` or `bin/bundler` that aren't meant to be used.
The absolute easiest way to do that is to write a
`Gemfile` along these lines:
```ruby
source 'https://rubygems.org' do
gem 'mdl'
end
```
If you want to package a specific version, you can use the standard Gemfile
syntax for that, e.g. `gem 'mdl', '0.5.0'`, but if you want the latest stable
version anyway, it's easier to update by simply running the `bundle lock` and
`bundix` steps again.
Now you can also also make a `default.nix` that looks like this:
```nix
{ lib, bundlerApp }:
bundlerApp {
pname = "mdl";
gemdir = ./.;
exes = [ "mdl" ];
}
```
All that's left to do is to generate the corresponding `Gemfile.lock` and
`gemset.nix` as described above in the `Using an existing Gemfile` section.
##### Packaging executables that require wrapping
Sometimes your app will depend on other executables at runtime, and tries to
find it through the `PATH` environment variable.
In this case, you can provide a `postBuild` hook to `bundlerApp` that wraps the
gem in another script that prefixes the `PATH`.
Of course you could also make a custom `gemConfig` if you know exactly how to
patch it, but it's usually much easier to maintain with a simple wrapper so the
patch doesn't have to be adjusted for each version.
Here's another example:
```nix
{ lib, bundlerApp, makeWrapper, git, gnutar, gzip }:
bundlerApp {
pname = "r10k";
gemdir = ./.;
exes = [ "r10k" ];
buildInputs = [ makeWrapper ];
postBuild = ''
wrapProgram $out/bin/r10k --prefix PATH : ${lib.makeBinPath [ git gnutar gzip ]}
'';
}
```

48
doc/languages-frameworks/ruby.xml
View File

@ -4,11 +4,7 @@
<title>Ruby</title>
<para>
There currently is support to bundle applications that are packaged as Ruby
gems. The utility "bundix" allows you to write a
<filename>Gemfile</filename>, let bundler create a
<filename>Gemfile.lock</filename>, and then convert this into a nix
expression that contains all Gem dependencies automatically.
There currently is support to bundle applications that are packaged as Ruby gems. The utility "bundix" allows you to write a <filename>Gemfile</filename>, let bundler create a <filename>Gemfile.lock</filename>, and then convert this into a nix expression that contains all Gem dependencies automatically.
</para>
<para>
@ -45,16 +41,22 @@ bundlerEnv rec {
</screen>
<para>
Please check in the <filename>Gemfile</filename>,
<filename>Gemfile.lock</filename> and the <filename>gemset.nix</filename> so
future updates can be run easily.
Please check in the <filename>Gemfile</filename>, <filename>Gemfile.lock</filename> and the <filename>gemset.nix</filename> so future updates can be run easily.
</para>
<para>
For tools written in Ruby - i.e. where the desire is to install a package and
then execute e.g. <command>rake</command> at the command line, there is an
alternative builder called <literal>bundlerApp</literal>. Set up the
<filename>gemset.nix</filename> the same way, and then, for example:
Updating Ruby packages can then be done like this:
</para>
<screen>
<![CDATA[$ cd pkgs/servers/monitoring/sensu
$ nix-shell -p bundler --run 'bundle lock --update'
$ nix-shell -p bundix --run 'bundix'
]]>
</screen>
<para>
For tools written in Ruby - i.e. where the desire is to install a package and then execute e.g. <command>rake</command> at the command line, there is an alternative builder called <literal>bundlerApp</literal>. Set up the <filename>gemset.nix</filename> the same way, and then, for example:
</para>
<screen>
@ -76,29 +78,11 @@ bundlerApp {
</screen>
<para>
The chief advantage of <literal>bundlerApp</literal> over
<literal>bundlerEnv</literal> is the executables introduced in the
environment are precisely those selected in the <literal>exes</literal> list,
as opposed to <literal>bundlerEnv</literal> which adds all the executables
made available by gems in the gemset, which can mean e.g.
<command>rspec</command> or <command>rake</command> in unpredictable versions
available from various packages.
The chief advantage of <literal>bundlerApp</literal> over <literal>bundlerEnv</literal> is the executables introduced in the environment are precisely those selected in the <literal>exes</literal> list, as opposed to <literal>bundlerEnv</literal> which adds all the executables made available by gems in the gemset, which can mean e.g. <command>rspec</command> or <command>rake</command> in unpredictable versions available from various packages.
</para>
<para>
Resulting derivations for both builders also have two helpful attributes,
<literal>env</literal> and <literal>wrappedRuby</literal>. The first one
allows one to quickly drop into <command>nix-shell</command> with the
specified environment present. E.g. <command>nix-shell -A sensu.env</command>
would give you an environment with Ruby preset so it has all the libraries
necessary for <literal>sensu</literal> in its paths. The second one can be
used to make derivations from custom Ruby scripts which have
<filename>Gemfile</filename>s with their dependencies specified. It is a
derivation with <command>ruby</command> wrapped so it can find all the needed
dependencies. For example, to make a derivation <literal>my-script</literal>
for a <filename>my-script.rb</filename> (which should be placed in
<filename>bin</filename>) you should run <command>bundix</command> as
specified above and then use <literal>bundlerEnv</literal> like this:
Resulting derivations for both builders also have two helpful attributes, <literal>env</literal> and <literal>wrappedRuby</literal>. The first one allows one to quickly drop into <command>nix-shell</command> with the specified environment present. E.g. <command>nix-shell -A sensu.env</command> would give you an environment with Ruby preset so it has all the libraries necessary for <literal>sensu</literal> in its paths. The second one can be used to make derivations from custom Ruby scripts which have <filename>Gemfile</filename>s with their dependencies specified. It is a derivation with <command>ruby</command> wrapped so it can find all the needed dependencies. For example, to make a derivation <literal>my-script</literal> for a <filename>my-script.rb</filename> (which should be placed in <filename>bin</filename>) you should run <command>bundix</command> as specified above and then use <literal>bundlerEnv</literal> like this:
</para>
<programlisting>

22
doc/languages-frameworks/rust.section.md
View File

@ -4,7 +4,7 @@ author: Matthias Beyer
date: 2017-03-05
---
# User's Guide to the Rust Infrastructure
# Rust
To install the rust compiler and cargo put
@ -43,6 +43,7 @@ rustPlatform.buildRustPackage rec {
};
cargoSha256 = "0q68qyl2h6i0qsz82z840myxlnjay8p1w5z7hfyr8fqp7wgwa9cx";
verifyCargoDeps = true;
meta = with stdenv.lib; {
description = "A fast line-oriented regex search tool, similar to ag and ack";
@ -64,6 +65,9 @@ When the `Cargo.lock`, provided by upstream, is not in sync with the
added in `cargoPatches` will also be prepended to the patches in `patches` at
build-time.
When `verifyCargoDeps` is set to `true`, the build will also verify that the
`cargoSha256` is not out of date by comparing the `Cargo.lock` file in both the `cargoDeps` and `src`. Note that this option changes the value of `cargoSha256` since it also copies the `Cargo.lock` in it. To avoid breaking backward-compatibility this option is not enabled by default but hopefully will be in the future.
## Compiling Rust crates using Nix instead of Cargo
### Simple operation
@ -303,11 +307,15 @@ with import <nixpkgs> {};
stdenv.mkDerivation {
name = "rust-env";
buildInputs = [
nativeBuildInputs = [
rustc cargo
# Example Additional Dependencies
pkgconfig openssl
# Example Build-time Additional Dependencies
pkgconfig
];
buildInputs = [
# Example Run-time Additional Dependencies
openssl
];
# Set Environment Variables
@ -332,9 +340,9 @@ with import <nixpkgs> {};
let src = fetchFromGitHub {
owner = "mozilla";
repo = "nixpkgs-mozilla";
# commit from: 2018-03-27
rev = "2945b0b6b2fd19e7d23bac695afd65e320efcebe";
sha256 = "034m1dryrzh2lmjvk3c0krgip652dql46w5yfwpvh7gavd3iypyw";
# commit from: 2019-05-15
rev = "9f35c4b09fd44a77227e79ff0c1b4b6a69dff533";
sha256 = "18h0nvh55b5an4gmlgfbvwbyqj91bklf1zymis6lbdh75571qaz0";
};
in
with import "${src.out}/rust-overlay.nix" pkgs pkgs;

43
doc/languages-frameworks/texlive.xml
View File

@ -4,8 +4,7 @@
<title>TeX Live</title>
<para>
Since release 15.09 there is a new TeX Live packaging that lives entirely
under attribute <varname>texlive</varname>.
Since release 15.09 there is a new TeX Live packaging that lives entirely under attribute <varname>texlive</varname>.
</para>
<section xml:id="sec-language-texlive-users-guide">
@ -14,28 +13,23 @@
<itemizedlist>
<listitem>
<para>
For basic usage just pull <varname>texlive.combined.scheme-basic</varname>
for an environment with basic LaTeX support.
For basic usage just pull <varname>texlive.combined.scheme-basic</varname> for an environment with basic LaTeX support.
</para>
</listitem>
<listitem>
<para>
It typically won't work to use separately installed packages together.
Instead, you can build a custom set of packages like this:
It typically won't work to use separately installed packages together. Instead, you can build a custom set of packages like this:
<programlisting>
texlive.combine {
inherit (texlive) scheme-small collection-langkorean algorithms cm-super;
}
</programlisting>
There are all the schemes, collections and a few thousand packages, as
defined upstream (perhaps with tiny differences).
</programlisting>
There are all the schemes, collections and a few thousand packages, as defined upstream (perhaps with tiny differences).
</para>
</listitem>
<listitem>
<para>
By default you only get executables and files needed during runtime, and a
little documentation for the core packages. To change that, you need to
add <varname>pkgFilter</varname> function to <varname>combine</varname>.
By default you only get executables and files needed during runtime, and a little documentation for the core packages. To change that, you need to add <varname>pkgFilter</varname> function to <varname>combine</varname>.
<programlisting>
texlive.combine {
# inherit (texlive) whatever-you-want;
@ -44,25 +38,22 @@ texlive.combine {
# elem tlType [ "run" "bin" "doc" "source" ]
# there are also other attributes: version, name
}
</programlisting>
</programlisting>
</para>
</listitem>
<listitem>
<para>
You can list packages e.g. by <command>nix-repl</command>.
<programlisting>
$ nix-repl
nix-repl> :l &lt;nixpkgs>
nix-repl> texlive.collection-&lt;TAB>
</programlisting>
You can list packages e.g. by <command>nix repl</command>.
<programlisting><![CDATA[
$ nix repl
nix-repl> :l <nixpkgs>
nix-repl> texlive.collection-<TAB>
]]></programlisting>
</para>
</listitem>
<listitem>
<para>
Note that the wrapper assumes that the result has a chance to be useful.
For example, the core executables should be present, as well as some core
data files. The supported way of ensuring this is by including some
scheme, for example <varname>scheme-basic</varname>, into the combination.
Note that the wrapper assumes that the result has a chance to be useful. For example, the core executables should be present, as well as some core data files. The supported way of ensuring this is by including some scheme, for example <varname>scheme-basic</varname>, into the combination.
</para>
</listitem>
</itemizedlist>
@ -84,14 +75,12 @@ nix-repl> texlive.collection-&lt;TAB>
</listitem>
<listitem>
<para>
feature/bug: when a package is rejected by <varname>pkgFilter</varname>,
its dependencies are still propagated;
feature/bug: when a package is rejected by <varname>pkgFilter</varname>, its dependencies are still propagated;
</para>
</listitem>
<listitem>
<para>
in case of any bugs or feature requests, file a github issue or better a
pull request and /cc @vcunat.
in case of any bugs or feature requests, file a github issue or better a pull request and /cc @vcunat.
</para>
</listitem>
</itemizedlist>

115
doc/languages-frameworks/titanium.section.md Normal file
View File

@ -0,0 +1,115 @@
---
title: Titanium
author: Sander van der Burg
date: 2018-11-18
---
# Titanium
The Nixpkgs repository contains facilities to deploy a variety of versions of
the [Titanium SDK](https://www.appcelerator.com) versions, a cross-platform
mobile app development framework using JavaScript as an implementation language,
and includes a function abstraction making it possible to build Titanium
applications for Android and iOS devices from source code.
Not all Titanium features supported -- currently, it can only be used to build
Android and iOS apps.
Building a Titanium app
-----------------------
We can build a Titanium app from source for Android or iOS and for debugging or
release purposes by invoking the `titaniumenv.buildApp {}` function:
```nix
titaniumenv.buildApp {
name = "myapp";
src = ./myappsource;
preBuild = "";
target = "android"; # or 'iphone'
tiVersion = "7.1.0.GA";
release = true;
androidsdkArgs = {
platformVersions = [ "25" "26" ];
};
androidKeyStore = ./keystore;
androidKeyAlias = "myfirstapp";
androidKeyStorePassword = "secret";
xcodeBaseDir = "/Applications/Xcode.app";
xcodewrapperArgs = {
version = "9.3";
};
iosMobileProvisioningProfile = ./myprovisioning.profile;
iosCertificateName = "My Company";
iosCertificate = ./mycertificate.p12;
iosCertificatePassword = "secret";
iosVersion = "11.3";
iosBuildStore = false;
enableWirelessDistribution = true;
installURL = "/installipa.php";
}
```
The `titaniumenv.buildApp {}` function takes the following parameters:
* The `name` parameter refers to the name in the Nix store.
* The `src` parameter refers to the source code location of the app that needs
to be built.
* `preRebuild` contains optional build instructions that are carried out before
the build starts.
* `target` indicates for which device the app must be built. Currently only
'android' and 'iphone' (for iOS) are supported.
* `tiVersion` can be used to optionally override the requested Titanium version
in `tiapp.xml`. If not specified, it will use the version in `tiapp.xml`.
* `release` should be set to true when building an app for submission to the
Google Playstore or Apple Appstore. Otherwise, it should be false.
When the `target` has been set to `android`, we can configure the following
parameters:
* The `androidSdkArgs` parameter refers to an attribute set that propagates all
parameters to the `androidenv.composeAndroidPackages {}` function. This can
be used to install all relevant Android plugins that may be needed to perform
the Android build. If no parameters are given, it will deploy the platform
SDKs for API-levels 25 and 26 by default.
When the `release` parameter has been set to true, you need to provide
parameters to sign the app:
* `androidKeyStore` is the path to the keystore file
* `androidKeyAlias` is the key alias
* `androidKeyStorePassword` refers to the password to open the keystore file.
When the `target` has been set to `iphone`, we can configure the following
parameters:
* The `xcodeBaseDir` parameter refers to the location where Xcode has been
installed. When none value is given, the above value is the default.
* The `xcodewrapperArgs` parameter passes arbitrary parameters to the
`xcodeenv.composeXcodeWrapper {}` function. This can, for example, be used
to adjust the default version of Xcode.
When `release` has been set to true, you also need to provide the following
parameters:
* `iosMobileProvisioningProfile` refers to a mobile provisioning profile needed
for signing.
* `iosCertificateName` refers to the company name in the P12 certificate.
* `iosCertificate` refers to the path to the P12 file.
* `iosCertificatePassword` contains the password to open the P12 file.
* `iosVersion` refers to the iOS SDK version to use. It defaults to the latest
version.
* `iosBuildStore` should be set to `true` when building for the Apple Appstore
submission. For enterprise or ad-hoc builds it should be set to `false`.
When `enableWirelessDistribution` has been enabled, you must also provide the
path of the PHP script (`installURL`) (that is included with the iOS build
environment) to enable wireless ad-hoc installations.
Emulating or simulating the app
-------------------------------
It is also possible to simulate the correspond iOS simulator build by using
`xcodeenv.simulateApp {}` and emulate an Android APK by using
`androidenv.emulateApp {}`.

180
doc/languages-frameworks/vim.section.md
View File

@ -3,7 +3,7 @@ title: User's Guide for Vim in Nixpkgs
author: Marc Weber
date: 2016-06-25
---
# User's Guide to Vim Plugins/Addons/Bundles/Scripts in Nixpkgs
# Vim
Both Neovim and Vim can be configured to include your favorite plugins
and additional libraries.
@ -21,8 +21,9 @@ At the moment we support three different methods for managing plugins:
Adding custom .vimrc lines can be done using the following code:
```
```nix
vim_configurable.customize {
# `name` specifies the name of the executable and package
name = "vim-with-plugins";
vimrcConfig.customRC = ''
@ -31,9 +32,11 @@ vim_configurable.customize {
}
```
This configuration is used when Vim is invoked with the command specified as name, in this case `vim-with-plugins`.
For Neovim the `configure` argument can be overridden to achieve the same:
```
```nix
neovim.override {
configure = {
customRC = ''
@ -43,16 +46,33 @@ neovim.override {
}
```
If you want to use `neovim-qt` as a graphical editor, you can configure it by overriding Neovim in an overlay
or passing it an overridden Neovimn:
```nix
neovim-qt.override {
neovim = neovim.override {
configure = {
customRC = ''
# your custom configuration
'';
};
};
}
```
## Managing plugins with Vim packages
To store you plugins in Vim packages the following example can be used:
To store you plugins in Vim packages (the native Vim plugin manager, see `:help packages`) the following example can be used:
```
```nix
vim_configurable.customize {
vimrcConfig.packages.myVimPackage = with pkgs.vimPlugins; {
# loaded on launch
start = [ youcompleteme fugitive ];
# manually loadable by calling `:packadd $plugin-name`
# however, if a Vim plugin has a dependency that is not explicitly listed in
# opt that dependency will always be added to start to avoid confusion.
opt = [ phpCompletion elm-vim ];
# To automatically load a plugin when opening a filetype, add vimrc lines like:
# autocmd FileType php :packadd phpCompletion
@ -60,9 +80,10 @@ vim_configurable.customize {
}
```
`myVimPackage` is an arbitrary name for the generated package. You can choose any name you like.
For Neovim the syntax is:
```
```nix
neovim.override {
configure = {
customRC = ''
@ -71,6 +92,8 @@ neovim.override {
packages.myVimPackage = with pkgs.vimPlugins; {
# see examples below how to use custom packages
start = [ ];
# If a Vim plugin has a dependency that is not explicitly listed in
# opt that dependency will always be added to start to avoid confusion.
opt = [ ];
};
};
@ -79,10 +102,11 @@ neovim.override {
The resulting package can be added to `packageOverrides` in `~/.nixpkgs/config.nix` to make it installable:
```
```nix
{
packageOverrides = pkgs: with pkgs; {
myVim = vim_configurable.customize {
# `name` specifies the name of the executable and package
name = "vim-with-plugins";
# add here code from the example section
};
@ -102,7 +126,7 @@ After that you can install your special grafted `myVim` or `myNeovim` packages.
To use [vim-plug](https://github.com/junegunn/vim-plug) to manage your Vim
plugins the following example can be used:
```
```nix
vim_configurable.customize {
vimrcConfig.packages.myVimPackage = with pkgs.vimPlugins; {
# loaded on launch
@ -113,7 +137,7 @@ vim_configurable.customize {
For Neovim the syntax is:
```
```nix
neovim.override {
configure = {
customRC = ''
@ -137,95 +161,117 @@ assuming that "using latest version" is ok most of the time.
First create a vim-scripts file having one plugin name per line. Example:
"tlib"
{'name': 'vim-addon-sql'}
{'filetype_regex': '\%(vim)$', 'names': ['reload', 'vim-dev-plugin']}
```
"tlib"
{'name': 'vim-addon-sql'}
{'filetype_regex': '\%(vim)$', 'names': ['reload', 'vim-dev-plugin']}
```
Such vim-scripts file can be read by VAM as well like this:
call vam#Scripts(expand('~/.vim-scripts'), {})
```vim
call vam#Scripts(expand('~/.vim-scripts'), {})
```
Create a default.nix file:
{ nixpkgs ? import <nixpkgs> {}, compiler ? "ghc7102" }:
nixpkgs.vim_configurable.customize { name = "vim"; vimrcConfig.vam.pluginDictionaries = [ "vim-addon-vim2nix" ]; }
```nix
{ nixpkgs ? import <nixpkgs> {}, compiler ? "ghc7102" }:
nixpkgs.vim_configurable.customize { name = "vim"; vimrcConfig.vam.pluginDictionaries = [ "vim-addon-vim2nix" ]; }
```
Create a generate.vim file:
ActivateAddons vim-addon-vim2nix
let vim_scripts = "vim-scripts"
call nix#ExportPluginsForNix({
\ 'path_to_nixpkgs': eval('{"'.substitute(substitute(substitute($NIX_PATH, ':', ',', 'g'), '=',':', 'g'), '\([:,]\)', '"\1"',"g").'"}')["nixpkgs"],
\ 'cache_file': '/tmp/vim2nix-cache',
\ 'try_catch': 0,
\ 'plugin_dictionaries': ["vim-addon-manager"]+map(readfile(vim_scripts), 'eval(v:val)')
\ })
```vim
ActivateAddons vim-addon-vim2nix
let vim_scripts = "vim-scripts"
call nix#ExportPluginsForNix({
\ 'path_to_nixpkgs': eval('{"'.substitute(substitute(substitute($NIX_PATH, ':', ',', 'g'), '=',':', 'g'), '\([:,]\)', '"\1"',"g").'"}')["nixpkgs"],
\ 'cache_file': '/tmp/vim2nix-cache',
\ 'try_catch': 0,
\ 'plugin_dictionaries': ["vim-addon-manager"]+map(readfile(vim_scripts), 'eval(v:val)')
\ })
```
Then run
nix-shell -p vimUtils.vim_with_vim2nix --command "vim -c 'source generate.vim'"
```bash
nix-shell -p vimUtils.vim_with_vim2nix --command "vim -c 'source generate.vim'"
```
You should get a Vim buffer with the nix derivations (output1) and vam.pluginDictionaries (output2).
You can add your vim to your system's configuration file like this and start it by "vim-my":
You can add your Vim to your system's configuration file like this and start it by "vim-my":
my-vim =
let plugins = let inherit (vimUtils) buildVimPluginFrom2Nix; in {
copy paste output1 here
}; in vim_configurable.customize {
name = "vim-my";
```
my-vim =
let plugins = let inherit (vimUtils) buildVimPluginFrom2Nix; in {
copy paste output1 here
}; in vim_configurable.customize {
name = "vim-my";
vimrcConfig.vam.knownPlugins = plugins; # optional
vimrcConfig.vam.pluginDictionaries = [
copy paste output2 here
];
# Pathogen would be
# vimrcConfig.pathogen.knownPlugins = plugins; # plugins
# vimrcConfig.pathogen.pluginNames = ["tlib"];
};
vimrcConfig.vam.knownPlugins = plugins; # optional
vimrcConfig.vam.pluginDictionaries = [
copy paste output2 here
];
# Pathogen would be
# vimrcConfig.pathogen.knownPlugins = plugins; # plugins
# vimrcConfig.pathogen.pluginNames = ["tlib"];
};
```
Sample output1:
"reload" = buildVimPluginFrom2Nix { # created by nix#NixDerivation
name = "reload";
src = fetchgit {
url = "git://github.com/xolox/vim-reload";
rev = "0a601a668727f5b675cb1ddc19f6861f3f7ab9e1";
sha256 = "0vb832l9yxj919f5hfg6qj6bn9ni57gnjd3bj7zpq7d4iv2s4wdh";
};
dependencies = ["nim-misc"];
```
"reload" = buildVimPluginFrom2Nix { # created by nix#NixDerivation
name = "reload";
src = fetchgit {
url = "git://github.com/xolox/vim-reload";
rev = "0a601a668727f5b675cb1ddc19f6861f3f7ab9e1";
sha256 = "0vb832l9yxj919f5hfg6qj6bn9ni57gnjd3bj7zpq7d4iv2s4wdh";
};
dependencies = ["nim-misc"];
};
[...]
};
[...]
```
Sample output2:
[
''vim-addon-manager''
''tlib''
{ "name" = ''vim-addon-sql''; }
{ "filetype_regex" = ''\%(vim)$$''; "names" = [ ''reload'' ''vim-dev-plugin'' ]; }
]
```nix
[
''vim-addon-manager''
''tlib''
{ "name" = ''vim-addon-sql''; }
{ "filetype_regex" = ''\%(vim)$$''; "names" = [ ''reload'' ''vim-dev-plugin'' ]; }
]
```
## Adding new plugins to nixpkgs
In `pkgs/misc/vim-plugins/vim-plugin-names` we store the plugin names
for all vim plugins we automatically generate plugins for.
The format of this file `github username/github repository`:
For example https://github.com/scrooloose/nerdtree becomes `scrooloose/nerdtree`.
After adding your plugin to this file run the `./update.py` in the same folder.
This will updated a file called `generated.nix` and make your plugin accessible in the
`vimPlugins` attribute set (`vimPlugins.nerdtree` in our example).
If additional steps to the build process of the plugin are required, add an
override to the `pkgs/misc/vim-plugins/default.nix` in the same directory.
Nix expressions for Vim plugins are stored in [pkgs/misc/vim-plugins](/pkgs/misc/vim-plugins). For the vast majority of plugins, Nix expressions are automatically generated by running [`./update.py`](/pkgs/misc/vim-plugins/update.py). This creates a [generated.nix](/pkgs/misc/vim-plugins/generated.nix) file based on the plugins listed in [vim-plugin-names](/pkgs/misc/vim-plugins/vim-plugin-names). Plugins are listed in alphabetical order in `vim-plugin-names` using the format `[github username]/[repository]`. For example https://github.com/scrooloose/nerdtree becomes `scrooloose/nerdtree`.
Some plugins require overrides in order to function properly. Overrides are placed in [overrides.nix](/pkgs/misc/vim-plugins/overrides.nix). Overrides are most often required when a plugin requires some dependencies, or extra steps are required during the build process. For example `deoplete-fish` requires both `deoplete-nvim` and `vim-fish`, and so the following override was added:
```
deoplete-fish = super.deoplete-fish.overrideAttrs(old: {
dependencies = with super; [ deoplete-nvim vim-fish ];
});
```
Sometimes plugins require an override that must be changed when the plugin is updated. This can cause issues when Vim plugins are auto-updated but the associated override isn't updated. For these plugins, the override should be written so that it specifies all information required to install the plugin, and running `./update.py` doesn't change the derivation for the plugin. Manually updating the override is required to update these types of plugins. An example of such a plugin is `LanguageClient-neovim`.
To add a new plugin:
1. run `./update.py` and create a commit named "vimPlugins: Update",
2. add the new plugin to [vim-plugin-names](/pkgs/misc/vim-plugins/vim-plugin-names) and add overrides if required to [overrides.nix](/pkgs/misc/vim-plugins/overrides.nix),
3. run `./update.py` again and create a commit named "vimPlugins.[name]: init at [version]" (where `name` and `version` can be found in [generated.nix](/pkgs/misc/vim-plugins/generated.nix)), and
4. create a pull request.
## Important repositories
- [vim-pi](https://bitbucket.org/vimcommunity/vim-pi) is a plugin repository
from VAM plugin manager meant to be used by others as well used by
- [vim2nix](http://github.com/MarcWeber/vim-addon-vim2nix) which generates the
- [vim2nix](https://github.com/MarcWeber/vim-addon-vim2nix) which generates the
.nix code

49
doc/manual.xml
View File

@ -1,24 +1,41 @@
<book xmlns="http://docbook.org/ns/docbook"
xmlns:xi="http://www.w3.org/2001/XInclude">
<info>
<title>Nixpkgs Contributors Guide</title>
<title>Nixpkgs Users and Contributors Guide</title>
<subtitle>Version <xi:include href=".version" parse="text" />
</subtitle>
</info>
<xi:include href="introduction.chapter.xml" />
<xi:include href="quick-start.xml" />
<xi:include href="stdenv.xml" />
<xi:include href="multiple-output.xml" />
<xi:include href="cross-compilation.xml" />
<xi:include href="configuration.xml" />
<xi:include href="functions.xml" />
<xi:include href="meta.xml" />
<xi:include href="languages-frameworks/index.xml" />
<xi:include href="platform-notes.xml" />
<xi:include href="package-notes.xml" />
<xi:include href="overlays.xml" />
<xi:include href="coding-conventions.xml" />
<xi:include href="submitting-changes.xml" />
<xi:include href="reviewing-contributions.xml" />
<xi:include href="contributing.xml" />
<part>
<title>Using Nixpkgs</title>
<xi:include href="configuration.xml" />
<xi:include href="overlays.xml" />
<xi:include href="overrides.xml" />
<xi:include href="functions.xml" />
</part>
<part>
<title>Standard environment</title>
<xi:include href="stdenv.xml" />
<xi:include href="meta.xml" />
<xi:include href="multiple-output.xml" />
<xi:include href="cross-compilation.xml" />
<xi:include href="platform-notes.xml" />
</part>
<part>
<title>Builders</title>
<xi:include href="builders/fetchers.xml" />
<xi:include href="builders/trivial-builders.xml" />
<xi:include href="builders/special.xml" />
<xi:include href="builders/images.xml" />
<xi:include href="languages-frameworks/index.xml" />
<xi:include href="packages/index.xml" />
</part>
<part>
<title>Contributing to Nixpkgs</title>
<xi:include href="quick-start.xml" />
<xi:include href="coding-conventions.xml" />
<xi:include href="submitting-changes.xml" />
<xi:include href="reviewing-contributions.xml" />
<xi:include href="contributing-to-documentation.xml" />
</part>
</book>

191
doc/meta.xml
View File

@ -3,10 +3,7 @@
xml:id="chap-meta">
<title>Meta-attributes</title>
<para>
Nix packages can declare <emphasis>meta-attributes</emphasis> that contain
information about a package such as a description, its homepage, its license,
and so on. For instance, the GNU Hello package has a <varname>meta</varname>
declaration like this:
Nix packages can declare <emphasis>meta-attributes</emphasis> that contain information about a package such as a description, its homepage, its license, and so on. For instance, the GNU Hello package has a <varname>meta</varname> declaration like this:
<programlisting>
meta = with stdenv.lib; {
description = "A program that produces a familiar, friendly greeting";
@ -14,7 +11,7 @@ meta = with stdenv.lib; {
GNU Hello is a program that prints "Hello, world!" when you run it.
It is fully customizable.
'';
homepage = http://www.gnu.org/software/hello/manual/;
homepage = https://www.gnu.org/software/hello/manual/;
license = licenses.gpl3Plus;
maintainers = [ maintainers.eelco ];
platforms = platforms.all;
@ -22,20 +19,17 @@ meta = with stdenv.lib; {
</programlisting>
</para>
<para>
Meta-attributes are not passed to the builder of the package. Thus, a change
to a meta-attribute doesnt trigger a recompilation of the package. The
value of a meta-attribute must be a string.
Meta-attributes are not passed to the builder of the package. Thus, a change to a meta-attribute doesnt trigger a recompilation of the package. The value of a meta-attribute must be a string.
</para>
<para>
The meta-attributes of a package can be queried from the command-line using
<command>nix-env</command>:
The meta-attributes of a package can be queried from the command-line using <command>nix-env</command>:
<screen>
$ nix-env -qa hello --json
<prompt>$ </prompt>nix-env -qa hello --json
{
"hello": {
"meta": {
"description": "A program that produces a familiar, friendly greeting",
"homepage": "http://www.gnu.org/software/hello/manual/",
"homepage": "https://www.gnu.org/software/hello/manual/",
"license": {
"fullName": "GNU General Public License version 3 or later",
"shortName": "GPLv3+",
@ -67,10 +61,9 @@ $ nix-env -qa hello --json
</screen>
<command>nix-env</command> knows about the <varname>description</varname>
field specifically:
<command>nix-env</command> knows about the <varname>description</varname> field specifically:
<screen>
$ nix-env -qa hello --description
<prompt>$ </prompt>nix-env -qa hello --description
hello-2.3 A program that produces a familiar, friendly greeting
</screen>
</para>
@ -88,18 +81,13 @@ hello-2.3 A program that produces a familiar, friendly greeting
</term>
<listitem>
<para>
A short (one-line) description of the package. This is shown by
<command>nix-env -q --description</command> and also on the Nixpkgs
release pages.
A short (one-line) description of the package. This is shown by <command>nix-env -q --description</command> and also on the Nixpkgs release pages.
</para>
<para>
Dont include a period at the end. Dont include newline characters.
Capitalise the first character. For brevity, dont repeat the name of
package — just describe what it does.
Dont include a period at the end. Dont include newline characters. Capitalise the first character. For brevity, dont repeat the name of package — just describe what it does.
</para>
<para>
Wrong: <literal>"libpng is a library that allows you to decode PNG
images."</literal>
Wrong: <literal>"libpng is a library that allows you to decode PNG images."</literal>
</para>
<para>
Right: <literal>"A library for decoding PNG images"</literal>
@ -122,9 +110,7 @@ hello-2.3 A program that produces a familiar, friendly greeting
</term>
<listitem>
<para>
Release branch. Used to specify that a package is not going to receive
updates that are not in this branch; for example, Linux kernel 3.0 is
supposed to be updated to 3.0.X, not 3.1.
Release branch. Used to specify that a package is not going to receive updates that are not in this branch; for example, Linux kernel 3.0 is supposed to be updated to 3.0.X, not 3.1.
</para>
</listitem>
</varlistentry>
@ -134,8 +120,7 @@ hello-2.3 A program that produces a familiar, friendly greeting
</term>
<listitem>
<para>
The packages homepage. Example:
<literal>http://www.gnu.org/software/hello/manual/</literal>
The packages homepage. Example: <literal>https://www.gnu.org/software/hello/manual/</literal>
</para>
</listitem>
</varlistentry>
@ -145,8 +130,17 @@ hello-2.3 A program that produces a familiar, friendly greeting
</term>
<listitem>
<para>
The page where a link to the current version can be found. Example:
<literal>http://ftp.gnu.org/gnu/hello/</literal>
The page where a link to the current version can be found. Example: <literal>https://ftp.gnu.org/gnu/hello/</literal>
</para>
</listitem>
</varlistentry>
<varlistentry>
<term>
<varname>changelog</varname>
</term>
<listitem>
<para>
A link or a list of links to the location of Changelog for a package. A link may use expansion to refer to the correct changelog version. Example: <literal>"https://git.savannah.gnu.org/cgit/hello.git/plain/NEWS?h=v${version}"</literal>
</para>
</listitem>
</varlistentry>
@ -156,46 +150,32 @@ hello-2.3 A program that produces a familiar, friendly greeting
</term>
<listitem>
<para>
The license, or licenses, for the package. One from the attribute set
defined in
<link
xlink:href="https://github.com/NixOS/nixpkgs/blob/master/lib/licenses.nix">
<filename>nixpkgs/lib/licenses.nix</filename></link>. At this moment
using both a list of licenses and a single license is valid. If the
license field is in the form of a list representation, then it means that
parts of the package are licensed differently. Each license should
preferably be referenced by their attribute. The non-list attribute value
can also be a space delimited string representation of the contained
attribute shortNames or spdxIds. The following are all valid examples:
The license, or licenses, for the package. One from the attribute set defined in <link
xlink:href="https://github.com/NixOS/nixpkgs/blob/master/lib/licenses.nix"> <filename>nixpkgs/lib/licenses.nix</filename></link>. At this moment using both a list of licenses and a single license is valid. If the license field is in the form of a list representation, then it means that parts of the package are licensed differently. Each license should preferably be referenced by their attribute. The non-list attribute value can also be a space delimited string representation of the contained attribute shortNames or spdxIds. The following are all valid examples:
<itemizedlist>
<listitem>
<para>
Single license referenced by attribute (preferred)
<literal>stdenv.lib.licenses.gpl3</literal>.
Single license referenced by attribute (preferred) <literal>stdenv.lib.licenses.gpl3</literal>.
</para>
</listitem>
<listitem>
<para>
Single license referenced by its attribute shortName (frowned upon)
<literal>"gpl3"</literal>.
Single license referenced by its attribute shortName (frowned upon) <literal>"gpl3"</literal>.
</para>
</listitem>
<listitem>
<para>
Single license referenced by its attribute spdxId (frowned upon)
<literal>"GPL-3.0"</literal>.
Single license referenced by its attribute spdxId (frowned upon) <literal>"GPL-3.0"</literal>.
</para>
</listitem>
<listitem>
<para>
Multiple licenses referenced by attribute (preferred) <literal>with
stdenv.lib.licenses; [ asl20 free ofl ]</literal>.
Multiple licenses referenced by attribute (preferred) <literal>with stdenv.lib.licenses; [ asl20 free ofl ]</literal>.
</para>
</listitem>
<listitem>
<para>
Multiple licenses referenced as a space delimited string of attribute
shortNames (frowned upon) <literal>"asl20 free ofl"</literal>.
Multiple licenses referenced as a space delimited string of attribute shortNames (frowned upon) <literal>"asl20 free ofl"</literal>.
</para>
</listitem>
</itemizedlist>
@ -209,13 +189,8 @@ hello-2.3 A program that produces a familiar, friendly greeting
</term>
<listitem>
<para>
A list of names and e-mail addresses of the maintainers of this Nix
expression. If you would like to be a maintainer of a package, you may
want to add yourself to
<link
xlink:href="https://github.com/NixOS/nixpkgs/blob/master/maintainers/maintainer-list.nix"><filename>nixpkgs/maintainers/maintainer-list.nix</filename></link>
and write something like <literal>[ stdenv.lib.maintainers.alice
stdenv.lib.maintainers.bob ]</literal>.
A list of names and e-mail addresses of the maintainers of this Nix expression. If you would like to be a maintainer of a package, you may want to add yourself to <link
xlink:href="https://github.com/NixOS/nixpkgs/blob/master/maintainers/maintainer-list.nix"><filename>nixpkgs/maintainers/maintainer-list.nix</filename></link> and write something like <literal>[ stdenv.lib.maintainers.alice stdenv.lib.maintainers.bob ]</literal>.
</para>
</listitem>
</varlistentry>
@ -225,10 +200,7 @@ hello-2.3 A program that produces a familiar, friendly greeting
</term>
<listitem>
<para>
The <emphasis>priority</emphasis> of the package, used by
<command>nix-env</command> to resolve file name conflicts between
packages. See the Nix manual page for <command>nix-env</command> for
details. Example: <literal>"10"</literal> (a low-priority package).
The <emphasis>priority</emphasis> of the package, used by <command>nix-env</command> to resolve file name conflicts between packages. See the Nix manual page for <command>nix-env</command> for details. Example: <literal>"10"</literal> (a low-priority package).
</para>
</listitem>
</varlistentry>
@ -238,15 +210,48 @@ hello-2.3 A program that produces a familiar, friendly greeting
</term>
<listitem>
<para>
The list of Nix platform types on which the package is supported. Hydra
builds packages according to the platform specified. If no platform is
specified, the package does not have prebuilt binaries. An example is:
The list of Nix platform types on which the package is supported. Hydra builds packages according to the platform specified. If no platform is specified, the package does not have prebuilt binaries. An example is:
<programlisting>
meta.platforms = stdenv.lib.platforms.linux;
</programlisting>
Attribute Set <varname>stdenv.lib.platforms</varname> defines
<link xlink:href="https://github.com/NixOS/nixpkgs/blob/master/lib/systems/doubles.nix">
various common lists</link> of platforms types.
Attribute Set <varname>stdenv.lib.platforms</varname> defines <link xlink:href="https://github.com/NixOS/nixpkgs/blob/master/lib/systems/doubles.nix"> various common lists</link> of platforms types.
</para>
</listitem>
</varlistentry>
<varlistentry>
<term>
<varname>tests</varname>
</term>
<listitem>
<warning>
<para>
This attribute is special in that it is not actually under the <literal>meta</literal> attribute set but rather under the <literal>passthru</literal> attribute set. This is due to how <literal>meta</literal> attributes work, and the fact that they are supposed to contain only metadata, not derivations.
</para>
</warning>
<para>
An attribute set with as values tests. A test is a derivation, which builds successfully when the test passes, and fails to build otherwise. A derivation that is a test needs to have <literal>meta.timeout</literal> defined.
</para>
<para>
The NixOS tests are available as <literal>nixosTests</literal> in parameters of derivations. For instance, the OpenSMTPD derivation includes lines similar to:
<programlisting>
{ /* ... */, nixosTests }:
{
# ...
passthru.tests = {
basic-functionality-and-dovecot-integration = nixosTests.opensmtpd;
};
}
</programlisting>
</para>
</listitem>
</varlistentry>
<varlistentry>
<term>
<varname>timeout</varname>
</term>
<listitem>
<para>
A timeout (in seconds) for building the derivation. If the derivation takes longer than this time to build, it can fail due to breaking the timeout. However, all computers do not have the same computing power, hence some builders may decide to apply a multiplicative factor to this value. When filling this value in, try to keep it approximately consistent with other values already present in <literal>nixpkgs</literal>.
</para>
</listitem>
</varlistentry>
@ -256,13 +261,7 @@ meta.platforms = stdenv.lib.platforms.linux;
</term>
<listitem>
<para>
The list of Nix platform types for which the Hydra instance at
<literal>hydra.nixos.org</literal> will build the package. (Hydra is the
Nix-based continuous build system.) It defaults to the value of
<varname>meta.platforms</varname>. Thus, the only reason to set
<varname>meta.hydraPlatforms</varname> is if you want
<literal>hydra.nixos.org</literal> to build the package on a subset of
<varname>meta.platforms</varname>, or not at all, e.g.
The list of Nix platform types for which the Hydra instance at <literal>hydra.nixos.org</literal> will build the package. (Hydra is the Nix-based continuous build system.) It defaults to the value of <varname>meta.platforms</varname>. Thus, the only reason to set <varname>meta.hydraPlatforms</varname> is if you want <literal>hydra.nixos.org</literal> to build the package on a subset of <varname>meta.platforms</varname>, or not at all, e.g.
<programlisting>
meta.platforms = stdenv.lib.platforms.linux;
meta.hydraPlatforms = [];
@ -276,10 +275,7 @@ meta.hydraPlatforms = [];
</term>
<listitem>
<para>
If set to <literal>true</literal>, the package is marked as “broken”,
meaning that it wont show up in <literal>nix-env -qa</literal>, and
cannot be built or installed. Such packages should be removed from
Nixpkgs eventually unless they are fixed.
If set to <literal>true</literal>, the package is marked as “broken”, meaning that it wont show up in <literal>nix-env -qa</literal>, and cannot be built or installed. Such packages should be removed from Nixpkgs eventually unless they are fixed.
</para>
</listitem>
</varlistentry>
@ -289,12 +285,7 @@ meta.hydraPlatforms = [];
</term>
<listitem>
<para>
If set to <literal>true</literal>, the package is tested to be updated
correctly by the <literal>update-walker.sh</literal> script without
additional settings. Such packages have <varname>meta.version</varname>
set and their homepage (or the page specified by
<varname>meta.downloadPage</varname>) contains a direct link to the
package tarball.
If set to <literal>true</literal>, the package is tested to be updated correctly by the <literal>update-walker.sh</literal> script without additional settings. Such packages have <varname>meta.version</varname> set and their homepage (or the page specified by <varname>meta.downloadPage</varname>) contains a direct link to the package tarball.
</para>
</listitem>
</varlistentry>
@ -304,17 +295,11 @@ meta.hydraPlatforms = [];
<title>Licenses</title>
<para>
The <varname>meta.license</varname> attribute should preferrably contain a
value from <varname>stdenv.lib.licenses</varname> defined in
<link xlink:href="https://github.com/NixOS/nixpkgs/blob/master/lib/licenses.nix">
<filename>nixpkgs/lib/licenses.nix</filename></link>, or in-place license
description of the same format if the license is unlikely to be useful in
another expression.
The <varname>meta.license</varname> attribute should preferrably contain a value from <varname>stdenv.lib.licenses</varname> defined in <link xlink:href="https://github.com/NixOS/nixpkgs/blob/master/lib/licenses.nix"> <filename>nixpkgs/lib/licenses.nix</filename></link>, or in-place license description of the same format if the license is unlikely to be useful in another expression.
</para>
<para>
Although it's typically better to indicate the specific license, a few
generic options are available:
Although it's typically better to indicate the specific license, a few generic options are available:
<variablelist>
<varlistentry>
<term>
@ -332,18 +317,10 @@ meta.hydraPlatforms = [];
</term>
<listitem>
<para>
Unfree package that can be redistributed in binary form. That is, its
legal to redistribute the <emphasis>output</emphasis> of the derivation.
This means that the package can be included in the Nixpkgs channel.
Unfree package that can be redistributed in binary form. That is, its legal to redistribute the <emphasis>output</emphasis> of the derivation. This means that the package can be included in the Nixpkgs channel.
</para>
<para>
Sometimes proprietary software can only be redistributed unmodified.
Make sure the builder doesnt actually modify the original binaries;
otherwise were breaking the license. For instance, the NVIDIA X11
drivers can be redistributed unmodified, but our builder applies
<command>patchelf</command> to make them work. Thus, its license is
<varname>"unfree"</varname> and it cannot be included in the Nixpkgs
channel.
Sometimes proprietary software can only be redistributed unmodified. Make sure the builder doesnt actually modify the original binaries; otherwise were breaking the license. For instance, the NVIDIA X11 drivers can be redistributed unmodified, but our builder applies <command>patchelf</command> to make them work. Thus, its license is <varname>"unfree"</varname> and it cannot be included in the Nixpkgs channel.
</para>
</listitem>
</varlistentry>
@ -353,9 +330,7 @@ meta.hydraPlatforms = [];
</term>
<listitem>
<para>
Unfree package that cannot be redistributed. You can build it yourself,
but you cannot redistribute the output of the derivation. Thus it cannot
be included in the Nixpkgs channel.
Unfree package that cannot be redistributed. You can build it yourself, but you cannot redistribute the output of the derivation. Thus it cannot be included in the Nixpkgs channel.
</para>
</listitem>
</varlistentry>
@ -365,9 +340,7 @@ meta.hydraPlatforms = [];
</term>
<listitem>
<para>
This package supplies unfree, redistributable firmware. This is a
separate value from <varname>unfree-redistributable</varname> because
not everybody cares whether firmware is free.
This package supplies unfree, redistributable firmware. This is a separate value from <varname>unfree-redistributable</varname> because not everybody cares whether firmware is free.
</para>
</listitem>
</varlistentry>

157
doc/multiple-output.xml
View File

@ -10,31 +10,16 @@
<title>Introduction</title>
<para>
The Nix language allows a derivation to produce multiple outputs, which is
similar to what is utilized by other Linux distribution packaging systems.
The outputs reside in separate nix store paths, so they can be mostly
handled independently of each other, including passing to build inputs,
garbage collection or binary substitution. The exception is that building
from source always produces all the outputs.
The Nix language allows a derivation to produce multiple outputs, which is similar to what is utilized by other Linux distribution packaging systems. The outputs reside in separate Nix store paths, so they can be mostly handled independently of each other, including passing to build inputs, garbage collection or binary substitution. The exception is that building from source always produces all the outputs.
</para>
<para>
The main motivation is to save disk space by reducing runtime closure sizes;
consequently also sizes of substituted binaries get reduced. Splitting can
be used to have more granular runtime dependencies, for example the typical
reduction is to split away development-only files, as those are typically
not needed during runtime. As a result, closure sizes of many packages can
get reduced to a half or even much less.
The main motivation is to save disk space by reducing runtime closure sizes; consequently also sizes of substituted binaries get reduced. Splitting can be used to have more granular runtime dependencies, for example the typical reduction is to split away development-only files, as those are typically not needed during runtime. As a result, closure sizes of many packages can get reduced to a half or even much less.
</para>
<note>
<para>
The reduction effects could be instead achieved by building the parts in
completely separate derivations. That would often additionally reduce
build-time closures, but it tends to be much harder to write such
derivations, as build systems typically assume all parts are being built at
once. This compromise approach of single source package producing multiple
binary packages is also utilized often by rpm and deb.
The reduction effects could be instead achieved by building the parts in completely separate derivations. That would often additionally reduce build-time closures, but it tends to be much harder to write such derivations, as build systems typically assume all parts are being built at once. This compromise approach of single source package producing multiple binary packages is also utilized often by rpm and deb.
</para>
</note>
</section>
@ -42,23 +27,18 @@
<title>Installing a split package</title>
<para>
When installing a package via <varname>systemPackages</varname> or
<command>nix-env</command> you have several options:
When installing a package via <varname>systemPackages</varname> or <command>nix-env</command> you have several options:
</para>
<itemizedlist>
<listitem>
<para>
You can install particular outputs explicitly, as each is available in the
Nix language as an attribute of the package. The
<varname>outputs</varname> attribute contains a list of output names.
You can install particular outputs explicitly, as each is available in the Nix language as an attribute of the package. The <varname>outputs</varname> attribute contains a list of output names.
</para>
</listitem>
<listitem>
<para>
You can let it use the default outputs. These are handled by
<varname>meta.outputsToInstall</varname> attribute that contains a list of
output names.
You can let it use the default outputs. These are handled by <varname>meta.outputsToInstall</varname> attribute that contains a list of output names.
</para>
<para>
TODO: more about tweaking the attribute, etc.
@ -66,19 +46,11 @@
</listitem>
<listitem>
<para>
NixOS provides configuration option
<varname>environment.extraOutputsToInstall</varname> that allows adding
extra outputs of <varname>environment.systemPackages</varname> atop the
default ones. It's mainly meant for documentation and debug symbols, and
it's also modified by specific options.
NixOS provides configuration option <varname>environment.extraOutputsToInstall</varname> that allows adding extra outputs of <varname>environment.systemPackages</varname> atop the default ones. It's mainly meant for documentation and debug symbols, and it's also modified by specific options.
</para>
<note>
<para>
At this moment there is no similar configurability for packages installed
by <command>nix-env</command>. You can still use approach from
<xref linkend="sec-modify-via-packageOverrides" /> to override
<varname>meta.outputsToInstall</varname> attributes, but that's a rather
inconvenient way.
At this moment there is no similar configurability for packages installed by <command>nix-env</command>. You can still use approach from <xref linkend="sec-modify-via-packageOverrides" /> to override <varname>meta.outputsToInstall</varname> attributes, but that's a rather inconvenient way.
</para>
</note>
</listitem>
@ -88,18 +60,15 @@
<title>Using a split package</title>
<para>
In the Nix language the individual outputs can be reached explicitly as
attributes, e.g. <varname>coreutils.info</varname>, but the typical case is
just using packages as build inputs.
In the Nix language the individual outputs can be reached explicitly as attributes, e.g. <varname>coreutils.info</varname>, but the typical case is just using packages as build inputs.
</para>
<para>
When a multiple-output derivation gets into a build input of another
derivation, the <varname>dev</varname> output is added if it exists,
otherwise the first output is added. In addition to that,
<varname>propagatedBuildOutputs</varname> of that package which by default
contain <varname>$outputBin</varname> and <varname>$outputLib</varname> are
also added. (See <xref linkend="multiple-output-file-type-groups" />.)
When a multiple-output derivation gets into a build input of another derivation, the <varname>dev</varname> output is added if it exists, otherwise the first output is added. In addition to that, <varname>propagatedBuildOutputs</varname> of that package which by default contain <varname>$outputBin</varname> and <varname>$outputLib</varname> are also added. (See <xref linkend="multiple-output-file-type-groups" />.)
</para>
<para>
In some cases it may be desirable to combine different outputs under a single store path. A function <literal>symlinkJoin</literal> can be used to do this. (Note that it may negate some closure size benefits of using a multiple-output package.)
</para>
</section>
<section xml:id="sec-multiple-outputs-">
@ -110,29 +79,18 @@
</para>
<para>
In nixpkgs there is a framework supporting multiple-output derivations. It
tries to cover most cases by default behavior. You can find the source
separated in
&lt;<filename>nixpkgs/pkgs/build-support/setup-hooks/multiple-outputs.sh</filename>&gt;;
it's relatively well-readable. The whole machinery is triggered by defining
the <varname>outputs</varname> attribute to contain the list of desired
output names (strings).
In nixpkgs there is a framework supporting multiple-output derivations. It tries to cover most cases by default behavior. You can find the source separated in &lt;<filename>nixpkgs/pkgs/build-support/setup-hooks/multiple-outputs.sh</filename>&gt;; it's relatively well-readable. The whole machinery is triggered by defining the <varname>outputs</varname> attribute to contain the list of desired output names (strings).
</para>
<programlisting>outputs = [ "bin" "dev" "out" "doc" ];</programlisting>
<para>
Often such a single line is enough. For each output an equally named
environment variable is passed to the builder and contains the path in nix
store for that output. Typically you also want to have the main
<varname>out</varname> output, as it catches any files that didn't get
elsewhere.
Often such a single line is enough. For each output an equally named environment variable is passed to the builder and contains the path in nix store for that output. Typically you also want to have the main <varname>out</varname> output, as it catches any files that didn't get elsewhere.
</para>
<note>
<para>
There is a special handling of the <varname>debug</varname> output,
described at <xref linkend="stdenv-separateDebugInfo" />.
There is a special handling of the <varname>debug</varname> output, described at <xref linkend="stdenv-separateDebugInfo" />.
</para>
</note>
@ -140,36 +98,15 @@
<title><quote>Binaries first</quote></title>
<para>
A commonly adopted convention in <literal>nixpkgs</literal> is that
executables provided by the package are contained within its first output.
This convention allows the dependent packages to reference the executables
provided by packages in a uniform manner. For instance, provided with the
knowledge that the <literal>perl</literal> package contains a
<literal>perl</literal> executable it can be referenced as
<literal>${pkgs.perl}/bin/perl</literal> within a Nix derivation that needs
to execute a Perl script.
A commonly adopted convention in <literal>nixpkgs</literal> is that executables provided by the package are contained within its first output. This convention allows the dependent packages to reference the executables provided by packages in a uniform manner. For instance, provided with the knowledge that the <literal>perl</literal> package contains a <literal>perl</literal> executable it can be referenced as <literal>${pkgs.perl}/bin/perl</literal> within a Nix derivation that needs to execute a Perl script.
</para>
<para>
The <literal>glibc</literal> package is a deliberate single exception to
the <quote>binaries first</quote> convention. The <literal>glibc</literal>
has <literal>libs</literal> as its first output allowing the libraries
provided by <literal>glibc</literal> to be referenced directly (e.g.
<literal>${stdenv.glibc}/lib/ld-linux-x86-64.so.2</literal>). The
executables provided by <literal>glibc</literal> can be accessed via its
<literal>bin</literal> attribute (e.g.
<literal>${stdenv.glibc.bin}/bin/ldd</literal>).
The <literal>glibc</literal> package is a deliberate single exception to the <quote>binaries first</quote> convention. The <literal>glibc</literal> has <literal>libs</literal> as its first output allowing the libraries provided by <literal>glibc</literal> to be referenced directly (e.g. <literal>${stdenv.glibc}/lib/ld-linux-x86-64.so.2</literal>). The executables provided by <literal>glibc</literal> can be accessed via its <literal>bin</literal> attribute (e.g. <literal>${stdenv.glibc.bin}/bin/ldd</literal>).
</para>
<para>
The reason for why <literal>glibc</literal> deviates from the convention is
because referencing a library provided by <literal>glibc</literal> is a
very common operation among Nix packages. For instance, third-party
executables packaged by Nix are typically patched and relinked with the
relevant version of <literal>glibc</literal> libraries from Nix packages
(please see the documentation on
<link xlink:href="https://nixos.org/patchelf.html">patchelf</link> for more
details).
The reason for why <literal>glibc</literal> deviates from the convention is because referencing a library provided by <literal>glibc</literal> is a very common operation among Nix packages. For instance, third-party executables packaged by Nix are typically patched and relinked with the relevant version of <literal>glibc</literal> libraries from Nix packages (please see the documentation on <link xlink:href="https://nixos.org/patchelf.html">patchelf</link> for more details).
</para>
</section>
@ -177,13 +114,7 @@
<title>File type groups</title>
<para>
The support code currently recognizes some particular kinds of outputs and
either instructs the build system of the package to put files into their
desired outputs or it moves the files during the fixup phase. Each group of
file types has an <varname>outputFoo</varname> variable specifying the
output name where they should go. If that variable isn't defined by the
derivation writer, it is guessed &ndash; a default output name is defined,
falling back to other possibilities if the output isn't defined.
The support code currently recognizes some particular kinds of outputs and either instructs the build system of the package to put files into their desired outputs or it moves the files during the fixup phase. Each group of file types has an <varname>outputFoo</varname> variable specifying the output name where they should go. If that variable isn't defined by the derivation writer, it is guessed &ndash; a default output name is defined, falling back to other possibilities if the output isn't defined.
</para>
<variablelist>
@ -193,9 +124,7 @@
</term>
<listitem>
<para>
is for development-only files. These include C(++) headers, pkg-config,
cmake and aclocal files. They go to <varname>dev</varname> or
<varname>out</varname> by default.
is for development-only files. These include C(++) headers, pkg-config, cmake and aclocal files. They go to <varname>dev</varname> or <varname>out</varname> by default.
</para>
</listitem>
</varlistentry>
@ -205,8 +134,7 @@
</term>
<listitem>
<para>
is meant for user-facing binaries, typically residing in bin/. They go
to <varname>bin</varname> or <varname>out</varname> by default.
is meant for user-facing binaries, typically residing in bin/. They go to <varname>bin</varname> or <varname>out</varname> by default.
</para>
</listitem>
</varlistentry>
@ -216,9 +144,7 @@
</term>
<listitem>
<para>
is meant for libraries, typically residing in <filename>lib/</filename>
and <filename>libexec/</filename>. They go to <varname>lib</varname> or
<varname>out</varname> by default.
is meant for libraries, typically residing in <filename>lib/</filename> and <filename>libexec/</filename>. They go to <varname>lib</varname> or <varname>out</varname> by default.
</para>
</listitem>
</varlistentry>
@ -228,9 +154,7 @@
</term>
<listitem>
<para>
is for user documentation, typically residing in
<filename>share/doc/</filename>. It goes to <varname>doc</varname> or
<varname>out</varname> by default.
is for user documentation, typically residing in <filename>share/doc/</filename>. It goes to <varname>doc</varname> or <varname>out</varname> by default.
</para>
</listitem>
</varlistentry>
@ -240,10 +164,7 @@
</term>
<listitem>
<para>
is for <emphasis>developer</emphasis> documentation. Currently we count
gtk-doc and devhelp books in there. It goes to <varname>devdoc</varname>
or is removed (!) by default. This is because e.g. gtk-doc tends to be
rather large and completely unused by nixpkgs users.
is for <emphasis>developer</emphasis> documentation. Currently we count gtk-doc and devhelp books in there. It goes to <varname>devdoc</varname> or is removed (!) by default. This is because e.g. gtk-doc tends to be rather large and completely unused by nixpkgs users.
</para>
</listitem>
</varlistentry>
@ -253,8 +174,7 @@
</term>
<listitem>
<para>
is for man pages (except for section 3). They go to
<varname>man</varname> or <varname>$outputBin</varname> by default.
is for man pages (except for section 3). They go to <varname>man</varname> or <varname>$outputBin</varname> by default.
</para>
</listitem>
</varlistentry>
@ -264,8 +184,7 @@
</term>
<listitem>
<para>
is for section 3 man pages. They go to <varname>devman</varname> or
<varname>$outputMan</varname> by default.
is for section 3 man pages. They go to <varname>devman</varname> or <varname>$outputMan</varname> by default.
</para>
</listitem>
</varlistentry>
@ -275,8 +194,7 @@
</term>
<listitem>
<para>
is for info pages. They go to <varname>info</varname> or
<varname>$outputBin</varname> by default.
is for info pages. They go to <varname>info</varname> or <varname>$outputBin</varname> by default.
</para>
</listitem>
</varlistentry>
@ -289,31 +207,22 @@
<itemizedlist>
<listitem>
<para>
Some configure scripts don't like some of the parameters passed by
default by the framework, e.g. <literal>--docdir=/foo/bar</literal>. You
can disable this by setting <literal>setOutputFlags = false;</literal>.
Some configure scripts don't like some of the parameters passed by default by the framework, e.g. <literal>--docdir=/foo/bar</literal>. You can disable this by setting <literal>setOutputFlags = false;</literal>.
</para>
</listitem>
<listitem>
<para>
The outputs of a single derivation can retain references to each other,
but note that circular references are not allowed. (And each
strongly-connected component would act as a single output anyway.)
The outputs of a single derivation can retain references to each other, but note that circular references are not allowed. (And each strongly-connected component would act as a single output anyway.)
</para>
</listitem>
<listitem>
<para>
Most of split packages contain their core functionality in libraries.
These libraries tend to refer to various kind of data that typically gets
into <varname>out</varname>, e.g. locale strings, so there is often no
advantage in separating the libraries into <varname>lib</varname>, as
keeping them in <varname>out</varname> is easier.
Most of split packages contain their core functionality in libraries. These libraries tend to refer to various kind of data that typically gets into <varname>out</varname>, e.g. locale strings, so there is often no advantage in separating the libraries into <varname>lib</varname>, as keeping them in <varname>out</varname> is easier.
</para>
</listitem>
<listitem>
<para>
Some packages have hidden assumptions on install paths, which complicates
splitting.
Some packages have hidden assumptions on install paths, which complicates splitting.
</para>
</listitem>
</itemizedlist>

200
doc/overlays.xml
View File

@ -3,114 +3,109 @@
xml:id="chap-overlays">
<title>Overlays</title>
<para>
This chapter describes how to extend and change Nixpkgs packages using
overlays. Overlays are used to add layers in the fix-point used by Nixpkgs to
compose the set of all packages.
This chapter describes how to extend and change Nixpkgs using overlays. Overlays are used to add layers in the fixed-point used by Nixpkgs to compose the set of all packages.
</para>
<para>
Nixpkgs can be configured with a list of overlays, which are applied in
order. This means that the order of the overlays can be significant if
multiple layers override the same package.
Nixpkgs can be configured with a list of overlays, which are applied in order. This means that the order of the overlays can be significant if multiple layers override the same package.
</para>
<!--============================================================-->
<section xml:id="sec-overlays-install">
<title>Installing overlays</title>
<para>
The list of overlays is determined as follows.
The list of overlays can be set either explicitly in a Nix expression, or through <literal>&lt;nixpkgs-overlays></literal> or user configuration files.
</para>
<para>
If the <varname>overlays</varname> argument is not provided explicitly, we
look for overlays in a path. The path is determined as follows:
<orderedlist>
<listitem>
<para>
First, if an <varname>overlays</varname> argument to the nixpkgs function
itself is given, then that is used.
</para>
<para>
This can be passed explicitly when importing nipxkgs, for example
<literal>import &lt;nixpkgs> { overlays = [ overlay1 overlay2 ];
}</literal>.
</para>
</listitem>
<listitem>
<para>
Otherwise, if the Nix path entry <literal>&lt;nixpkgs-overlays></literal>
exists, we look for overlays at that path, as described below.
</para>
<para>
See the section on <literal>NIX_PATH</literal> in the Nix manual for more
details on how to set a value for
<literal>&lt;nixpkgs-overlays>.</literal>
</para>
</listitem>
<listitem>
<para>
If one of <filename>~/.config/nixpkgs/overlays.nix</filename> and
<filename>~/.config/nixpkgs/overlays/</filename> exists, then we look for
overlays at that path, as described below. It is an error if both exist.
</para>
</listitem>
</orderedlist>
</para>
<section xml:id="sec-overlays-argument">
<title>Set overlays in NixOS or Nix expressions</title>
<para>
If we are looking for overlays at a path, then there are two cases:
<itemizedlist>
<listitem>
<para>
If the path is a file, then the file is imported as a Nix expression and
used as the list of overlays.
</para>
</listitem>
<listitem>
<para>
If the path is a directory, then we take the content of the directory,
order it lexicographically, and attempt to interpret each as an overlay
by:
<itemizedlist>
<listitem>
<para>
Importing the file, if it is a <literal>.nix</literal> file.
</para>
</listitem>
<listitem>
<para>
Importing a top-level <filename>default.nix</filename> file, if it is
a directory.
</para>
</listitem>
</itemizedlist>
</para>
</listitem>
</itemizedlist>
</para>
<para>
On a NixOS system the value of the <literal>nixpkgs.overlays</literal> option, if present, is passed to the system Nixpkgs directly as an argument. Note that this does not affect the overlays for non-NixOS operations (e.g. <literal>nix-env</literal>), which are <link xlink:href="#sec-overlays-lookup">looked</link> up independently.
</para>
<para>
On a NixOS system the value of the <literal>nixpkgs.overlays</literal>
option, if present, is passed to the system Nixpkgs directly as an argument.
Note that this does not affect the overlays for non-NixOS operations (e.g.
<literal>nix-env</literal>), which are looked up independently.
</para>
<para>
The list of overlays can be passed explicitly when importing nixpkgs, for example <literal>import &lt;nixpkgs> { overlays = [ overlay1 overlay2 ]; }</literal>.
</para>
<para>
The <filename>overlays.nix</filename> option therefore provides a convenient
way to use the same overlays for a NixOS system configuration and user
configuration: the same file can be used as
<filename>overlays.nix</filename> and imported as the value of
<literal>nixpkgs.overlays</literal>.
</para>
<para>
Further overlays can be added by calling the <literal>pkgs.extend</literal> or <literal>pkgs.appendOverlays</literal>, although it is often preferable to avoid these functions, because they recompute the Nixpkgs fixpoint, which is somewhat expensive to do.
</para>
</section>
<section xml:id="sec-overlays-lookup">
<title>Install overlays via configuration lookup</title>
<para>
The list of overlays is determined as follows.
</para>
<para>
<orderedlist>
<listitem>
<para>
First, if an <link xlink:href="#sec-overlays-argument"><varname>overlays</varname> argument</link> to the Nixpkgs function itself is given, then that is used and no path lookup will be performed.
</para>
</listitem>
<listitem>
<para>
Otherwise, if the Nix path entry <literal>&lt;nixpkgs-overlays></literal> exists, we look for overlays at that path, as described below.
</para>
<para>
See the section on <literal>NIX_PATH</literal> in the Nix manual for more details on how to set a value for <literal>&lt;nixpkgs-overlays>.</literal>
</para>
</listitem>
<listitem>
<para>
If one of <filename>~/.config/nixpkgs/overlays.nix</filename> and <filename>~/.config/nixpkgs/overlays/</filename> exists, then we look for overlays at that path, as described below. It is an error if both exist.
</para>
</listitem>
</orderedlist>
</para>
<para>
If we are looking for overlays at a path, then there are two cases:
<itemizedlist>
<listitem>
<para>
If the path is a file, then the file is imported as a Nix expression and used as the list of overlays.
</para>
</listitem>
<listitem>
<para>
If the path is a directory, then we take the content of the directory, order it lexicographically, and attempt to interpret each as an overlay by:
<itemizedlist>
<listitem>
<para>
Importing the file, if it is a <literal>.nix</literal> file.
</para>
</listitem>
<listitem>
<para>
Importing a top-level <filename>default.nix</filename> file, if it is a directory.
</para>
</listitem>
</itemizedlist>
</para>
</listitem>
</itemizedlist>
</para>
<para>
Because overlays that are set in NixOS configuration do not affect non-NixOS operations such as <literal>nix-env</literal>, the <filename>overlays.nix</filename> option provides a convenient way to use the same overlays for a NixOS system configuration and user configuration: the same file can be used as <filename>overlays.nix</filename> and imported as the value of <literal>nixpkgs.overlays</literal>.
</para>
<!-- TODO: Example of sharing overlays between NixOS configuration
and configuration lookup. Also reference the example
from the sec-overlays-argument paragraph about NixOS.
-->
</section>
</section>
<!--============================================================-->
<section xml:id="sec-overlays-definition">
<title>Defining overlays</title>
<para>
Overlays are Nix functions which accept two arguments, conventionally called
<varname>self</varname> and <varname>super</varname>, and return a set of
packages. For example, the following is a valid overlay.
Overlays are Nix functions which accept two arguments, conventionally called <varname>self</varname> and <varname>super</varname>, and return a set of packages. For example, the following is a valid overlay.
</para>
<programlisting>
@ -127,38 +122,19 @@ self: super:
</programlisting>
<para>
The first argument (<varname>self</varname>) corresponds to the final
package set. You should use this set for the dependencies of all packages
specified in your overlay. For example, all the dependencies of
<varname>rr</varname> in the example above come from
<varname>self</varname>, as well as the overridden dependencies used in the
<varname>boost</varname> override.
The first argument (<varname>self</varname>) corresponds to the final package set. You should use this set for the dependencies of all packages specified in your overlay. For example, all the dependencies of <varname>rr</varname> in the example above come from <varname>self</varname>, as well as the overridden dependencies used in the <varname>boost</varname> override.
</para>
<para>
The second argument (<varname>super</varname>) corresponds to the result of
the evaluation of the previous stages of Nixpkgs. It does not contain any of
the packages added by the current overlay, nor any of the following
overlays. This set should be used either to refer to packages you wish to
override, or to access functions defined in Nixpkgs. For example, the
original recipe of <varname>boost</varname> in the above example, comes from
<varname>super</varname>, as well as the <varname>callPackage</varname>
function.
The second argument (<varname>super</varname>) corresponds to the result of the evaluation of the previous stages of Nixpkgs. It does not contain any of the packages added by the current overlay, nor any of the following overlays. This set should be used either to refer to packages you wish to override, or to access functions defined in Nixpkgs. For example, the original recipe of <varname>boost</varname> in the above example, comes from <varname>super</varname>, as well as the <varname>callPackage</varname> function.
</para>
<para>
The value returned by this function should be a set similar to
<filename>pkgs/top-level/all-packages.nix</filename>, containing overridden
and/or new packages.
The value returned by this function should be a set similar to <filename>pkgs/top-level/all-packages.nix</filename>, containing overridden and/or new packages.
</para>
<para>
Overlays are similar to other methods for customizing Nixpkgs, in particular
the <literal>packageOverrides</literal> attribute described in
<xref linkend="sec-modify-via-packageOverrides"/>. Indeed,
<literal>packageOverrides</literal> acts as an overlay with only the
<varname>super</varname> argument. It is therefore appropriate for basic
use, but overlays are more powerful and easier to distribute.
Overlays are similar to other methods for customizing Nixpkgs, in particular the <literal>packageOverrides</literal> attribute described in <xref linkend="sec-modify-via-packageOverrides"/>. Indeed, <literal>packageOverrides</literal> acts as an overlay with only the <varname>super</varname> argument. It is therefore appropriate for basic use, but overlays are more powerful and easier to distribute.
</para>
</section>
</chapter>

151
doc/overrides.xml Normal file
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@ -0,0 +1,151 @@
<chapter xmlns="http://docbook.org/ns/docbook"
xmlns:xlink="http://www.w3.org/1999/xlink"
xmlns:xi="http://www.w3.org/2001/XInclude"
xml:id="chap-overrides">
<title>Overriding</title>
<para>
Sometimes one wants to override parts of <literal>nixpkgs</literal>, e.g. derivation attributes, the results of derivations.
</para>
<para>
These functions are used to make changes to packages, returning only single packages. <link xlink:href="#chap-overlays">Overlays</link>, on the other hand, can be used to combine the overridden packages across the entire package set of Nixpkgs.
</para>
<section xml:id="sec-pkg-override">
<title>&lt;pkg&gt;.override</title>
<para>
The function <varname>override</varname> is usually available for all the derivations in the nixpkgs expression (<varname>pkgs</varname>).
</para>
<para>
It is used to override the arguments passed to a function.
</para>
<para>
Example usages:
<programlisting>pkgs.foo.override { arg1 = val1; arg2 = val2; ... }</programlisting>
<!-- TODO: move below programlisting to a new section about extending and overlays
and reference it
-->
<programlisting>
import pkgs.path { overlays = [ (self: super: {
foo = super.foo.override { barSupport = true ; };
})]};
</programlisting>
<programlisting>
mypkg = pkgs.callPackage ./mypkg.nix {
mydep = pkgs.mydep.override { ... };
}
</programlisting>
</para>
<para>
In the first example, <varname>pkgs.foo</varname> is the result of a function call with some default arguments, usually a derivation. Using <varname>pkgs.foo.override</varname> will call the same function with the given new arguments.
</para>
</section>
<section xml:id="sec-pkg-overrideAttrs">
<title>&lt;pkg&gt;.overrideAttrs</title>
<para>
The function <varname>overrideAttrs</varname> allows overriding the attribute set passed to a <varname>stdenv.mkDerivation</varname> call, producing a new derivation based on the original one. This function is available on all derivations produced by the <varname>stdenv.mkDerivation</varname> function, which is most packages in the nixpkgs expression <varname>pkgs</varname>.
</para>
<para>
Example usage:
<programlisting>
helloWithDebug = pkgs.hello.overrideAttrs (oldAttrs: rec {
separateDebugInfo = true;
});
</programlisting>
</para>
<para>
In the above example, the <varname>separateDebugInfo</varname> attribute is overridden to be true, thus building debug info for <varname>helloWithDebug</varname>, while all other attributes will be retained from the original <varname>hello</varname> package.
</para>
<para>
The argument <varname>oldAttrs</varname> is conventionally used to refer to the attr set originally passed to <varname>stdenv.mkDerivation</varname>.
</para>
<note>
<para>
Note that <varname>separateDebugInfo</varname> is processed only by the <varname>stdenv.mkDerivation</varname> function, not the generated, raw Nix derivation. Thus, using <varname>overrideDerivation</varname> will not work in this case, as it overrides only the attributes of the final derivation. It is for this reason that <varname>overrideAttrs</varname> should be preferred in (almost) all cases to <varname>overrideDerivation</varname>, i.e. to allow using <varname>stdenv.mkDerivation</varname> to process input arguments, as well as the fact that it is easier to use (you can use the same attribute names you see in your Nix code, instead of the ones generated (e.g. <varname>buildInputs</varname> vs <varname>nativeBuildInputs</varname>), and it involves less typing).
</para>
</note>
</section>
<section xml:id="sec-pkg-overrideDerivation">
<title>&lt;pkg&gt;.overrideDerivation</title>
<warning>
<para>
You should prefer <varname>overrideAttrs</varname> in almost all cases, see its documentation for the reasons why. <varname>overrideDerivation</varname> is not deprecated and will continue to work, but is less nice to use and does not have as many abilities as <varname>overrideAttrs</varname>.
</para>
</warning>
<warning>
<para>
Do not use this function in Nixpkgs as it evaluates a Derivation before modifying it, which breaks package abstraction and removes error-checking of function arguments. In addition, this evaluation-per-function application incurs a performance penalty, which can become a problem if many overrides are used. It is only intended for ad-hoc customisation, such as in <filename>~/.config/nixpkgs/config.nix</filename>.
</para>
</warning>
<para>
The function <varname>overrideDerivation</varname> creates a new derivation based on an existing one by overriding the original's attributes with the attribute set produced by the specified function. This function is available on all derivations defined using the <varname>makeOverridable</varname> function. Most standard derivation-producing functions, such as <varname>stdenv.mkDerivation</varname>, are defined using this function, which means most packages in the nixpkgs expression, <varname>pkgs</varname>, have this function.
</para>
<para>
Example usage:
<programlisting>
mySed = pkgs.gnused.overrideDerivation (oldAttrs: {
name = "sed-4.2.2-pre";
src = fetchurl {
url = ftp://alpha.gnu.org/gnu/sed/sed-4.2.2-pre.tar.bz2;
sha256 = "11nq06d131y4wmf3drm0yk502d2xc6n5qy82cg88rb9nqd2lj41k";
};
patches = [];
});
</programlisting>
</para>
<para>
In the above example, the <varname>name</varname>, <varname>src</varname>, and <varname>patches</varname> of the derivation will be overridden, while all other attributes will be retained from the original derivation.
</para>
<para>
The argument <varname>oldAttrs</varname> is used to refer to the attribute set of the original derivation.
</para>
<note>
<para>
A package's attributes are evaluated *before* being modified by the <varname>overrideDerivation</varname> function. For example, the <varname>name</varname> attribute reference in <varname>url = "mirror://gnu/hello/${name}.tar.gz";</varname> is filled-in *before* the <varname>overrideDerivation</varname> function modifies the attribute set. This means that overriding the <varname>name</varname> attribute, in this example, *will not* change the value of the <varname>url</varname> attribute. Instead, we need to override both the <varname>name</varname> *and* <varname>url</varname> attributes.
</para>
</note>
</section>
<section xml:id="sec-lib-makeOverridable">
<title>lib.makeOverridable</title>
<para>
The function <varname>lib.makeOverridable</varname> is used to make the result of a function easily customizable. This utility only makes sense for functions that accept an argument set and return an attribute set.
</para>
<para>
Example usage:
<programlisting>
f = { a, b }: { result = a+b; };
c = lib.makeOverridable f { a = 1; b = 2; };
</programlisting>
</para>
<para>
The variable <varname>c</varname> is the value of the <varname>f</varname> function applied with some default arguments. Hence the value of <varname>c.result</varname> is <literal>3</literal>, in this example.
</para>
<para>
The variable <varname>c</varname> however also has some additional functions, like <link linkend="sec-pkg-override">c.override</link> which can be used to override the default arguments. In this example the value of <varname>(c.override { a = 4; }).result</varname> is 6.
</para>
</section>
</chapter>

892
doc/package-notes.xml
View File

@ -1,892 +0,0 @@
<chapter xmlns="http://docbook.org/ns/docbook"
xmlns:xlink="http://www.w3.org/1999/xlink"
xml:id="chap-package-notes">
<title>Package Notes</title>
<para>
This chapter contains information about how to use and maintain the Nix
expressions for a number of specific packages, such as the Linux kernel or
X.org.
</para>
<!--============================================================-->
<section xml:id="sec-linux-kernel">
<title>Linux kernel</title>
<para>
The Nix expressions to build the Linux kernel are in
<link
xlink:href="https://github.com/NixOS/nixpkgs/blob/master/pkgs/os-specific/linux/kernel"><filename>pkgs/os-specific/linux/kernel</filename></link>.
</para>
<para>
The function that builds the kernel has an argument
<varname>kernelPatches</varname> which should be a list of <literal>{name,
patch, extraConfig}</literal> attribute sets, where <varname>name</varname>
is the name of the patch (which is included in the kernels
<varname>meta.description</varname> attribute), <varname>patch</varname> is
the patch itself (possibly compressed), and <varname>extraConfig</varname>
(optional) is a string specifying extra options to be concatenated to the
kernel configuration file (<filename>.config</filename>).
</para>
<para>
The kernel derivation exports an attribute <varname>features</varname>
specifying whether optional functionality is or isnt enabled. This is
used in NixOS to implement kernel-specific behaviour. For instance, if the
kernel has the <varname>iwlwifi</varname> feature (i.e. has built-in support
for Intel wireless chipsets), then NixOS doesnt have to build the
external <varname>iwlwifi</varname> package:
<programlisting>
modulesTree = [kernel]
++ pkgs.lib.optional (!kernel.features ? iwlwifi) kernelPackages.iwlwifi
++ ...;
</programlisting>
</para>
<para>
How to add a new (major) version of the Linux kernel to Nixpkgs:
<orderedlist>
<listitem>
<para>
Copy the old Nix expression (e.g. <filename>linux-2.6.21.nix</filename>)
to the new one (e.g. <filename>linux-2.6.22.nix</filename>) and update
it.
</para>
</listitem>
<listitem>
<para>
Add the new kernel to <filename>all-packages.nix</filename> (e.g., create
an attribute <varname>kernel_2_6_22</varname>).
</para>
</listitem>
<listitem>
<para>
Now were going to update the kernel configuration. First unpack the
kernel. Then for each supported platform (<literal>i686</literal>,
<literal>x86_64</literal>, <literal>uml</literal>) do the following:
<orderedlist>
<listitem>
<para>
Make an copy from the old config (e.g.
<filename>config-2.6.21-i686-smp</filename>) to the new one (e.g.
<filename>config-2.6.22-i686-smp</filename>).
</para>
</listitem>
<listitem>
<para>
Copy the config file for this platform (e.g.
<filename>config-2.6.22-i686-smp</filename>) to
<filename>.config</filename> in the kernel source tree.
</para>
</listitem>
<listitem>
<para>
Run <literal>make oldconfig
ARCH=<replaceable>{i386,x86_64,um}</replaceable></literal> and answer
all questions. (For the uml configuration, also add
<literal>SHELL=bash</literal>.) Make sure to keep the configuration
consistent between platforms (i.e. dont enable some feature on
<literal>i686</literal> and disable it on <literal>x86_64</literal>).
</para>
</listitem>
<listitem>
<para>
If needed you can also run <literal>make menuconfig</literal>:
<screen>
$ nix-env -i ncurses
$ export NIX_CFLAGS_LINK=-lncurses
$ make menuconfig ARCH=<replaceable>arch</replaceable></screen>
</para>
</listitem>
<listitem>
<para>
Copy <filename>.config</filename> over the new config file (e.g.
<filename>config-2.6.22-i686-smp</filename>).
</para>
</listitem>
</orderedlist>
</para>
</listitem>
<listitem>
<para>
Test building the kernel: <literal>nix-build -A kernel_2_6_22</literal>.
If it compiles, ship it! For extra credit, try booting NixOS with it.
</para>
</listitem>
<listitem>
<para>
It may be that the new kernel requires updating the external kernel
modules and kernel-dependent packages listed in the
<varname>linuxPackagesFor</varname> function in
<filename>all-packages.nix</filename> (such as the NVIDIA drivers, AUFS,
etc.). If the updated packages arent backwards compatible with older
kernels, you may need to keep the older versions around.
</para>
</listitem>
</orderedlist>
</para>
</section>
<!--============================================================-->
<section xml:id="sec-xorg">
<title>X.org</title>
<para>
The Nix expressions for the X.org packages reside in
<filename>pkgs/servers/x11/xorg/default.nix</filename>. This file is
automatically generated from lists of tarballs in an X.org release. As such
it should not be modified directly; rather, you should modify the lists, the
generator script or the file
<filename>pkgs/servers/x11/xorg/overrides.nix</filename>, in which you can
override or add to the derivations produced by the generator.
</para>
<para>
The generator is invoked as follows:
<screen>
$ cd pkgs/servers/x11/xorg
$ cat tarballs-7.5.list extra.list old.list \
| perl ./generate-expr-from-tarballs.pl
</screen>
For each of the tarballs in the <filename>.list</filename> files, the script
downloads it, unpacks it, and searches its <filename>configure.ac</filename>
and <filename>*.pc.in</filename> files for dependencies. This information is
used to generate <filename>default.nix</filename>. The generator caches
downloaded tarballs between runs. Pay close attention to the <literal>NOT
FOUND: <replaceable>name</replaceable></literal> messages at the end of the
run, since they may indicate missing dependencies. (Some might be optional
dependencies, however.)
</para>
<para>
A file like <filename>tarballs-7.5.list</filename> contains all tarballs in
a X.org release. It can be generated like this:
<screen>
$ export i="mirror://xorg/X11R7.4/src/everything/"
$ cat $(PRINT_PATH=1 nix-prefetch-url $i | tail -n 1) \
| perl -e 'while (&lt;>) { if (/(href|HREF)="([^"]*.bz2)"/) { print "$ENV{'i'}$2\n"; }; }' \
| sort > tarballs-7.4.list
</screen>
<filename>extra.list</filename> contains libraries that arent part of
X.org proper, but are closely related to it, such as
<literal>libxcb</literal>. <filename>old.list</filename> contains some
packages that were removed from X.org, but are still needed by some people
or by other packages (such as <varname>imake</varname>).
</para>
<para>
If the expression for a package requires derivation attributes that the
generator cannot figure out automatically (say, <varname>patches</varname>
or a <varname>postInstall</varname> hook), you should modify
<filename>pkgs/servers/x11/xorg/overrides.nix</filename>.
</para>
</section>
<!--============================================================-->
<!--
<section xml:id="sec-package-notes-gnome">
<title>Gnome</title>
<para>* Expression is auto-generated</para>
<para>* How to update</para>
</section>
-->
<!--============================================================-->
<!--
<section xml:id="sec-package-notes-gcc">
<title>GCC</title>
<para></para>
</section>
-->
<!--============================================================-->
<section xml:id="sec-eclipse">
<title>Eclipse</title>
<para>
The Nix expressions related to the Eclipse platform and IDE are in
<link xlink:href="https://github.com/NixOS/nixpkgs/blob/master/pkgs/applications/editors/eclipse"><filename>pkgs/applications/editors/eclipse</filename></link>.
</para>
<para>
Nixpkgs provides a number of packages that will install Eclipse in its
various forms, these range from the bare-bones Eclipse Platform to the more
fully featured Eclipse SDK or Scala-IDE packages and multiple version are
often available. It is possible to list available Eclipse packages by
issuing the command:
<screen>
$ nix-env -f '&lt;nixpkgs&gt;' -qaP -A eclipses --description
</screen>
Once an Eclipse variant is installed it can be run using the
<command>eclipse</command> command, as expected. From within Eclipse it is
then possible to install plugins in the usual manner by either manually
specifying an Eclipse update site or by installing the Marketplace Client
plugin and using it to discover and install other plugins. This installation
method provides an Eclipse installation that closely resemble a manually
installed Eclipse.
</para>
<para>
If you prefer to install plugins in a more declarative manner then Nixpkgs
also offer a number of Eclipse plugins that can be installed in an
<emphasis>Eclipse environment</emphasis>. This type of environment is
created using the function <varname>eclipseWithPlugins</varname> found
inside the <varname>nixpkgs.eclipses</varname> attribute set. This function
takes as argument <literal>{ eclipse, plugins ? [], jvmArgs ? [] }</literal>
where <varname>eclipse</varname> is a one of the Eclipse packages described
above, <varname>plugins</varname> is a list of plugin derivations, and
<varname>jvmArgs</varname> is a list of arguments given to the JVM running
the Eclipse. For example, say you wish to install the latest Eclipse
Platform with the popular Eclipse Color Theme plugin and also allow Eclipse
to use more RAM. You could then add
<screen>
packageOverrides = pkgs: {
myEclipse = with pkgs.eclipses; eclipseWithPlugins {
eclipse = eclipse-platform;
jvmArgs = [ "-Xmx2048m" ];
plugins = [ plugins.color-theme ];
};
}
</screen>
to your Nixpkgs configuration
(<filename>~/.config/nixpkgs/config.nix</filename>) and install it by
running <command>nix-env -f '&lt;nixpkgs&gt;' -iA myEclipse</command> and
afterward run Eclipse as usual. It is possible to find out which plugins are
available for installation using <varname>eclipseWithPlugins</varname> by
running
<screen>
$ nix-env -f '&lt;nixpkgs&gt;' -qaP -A eclipses.plugins --description
</screen>
</para>
<para>
If there is a need to install plugins that are not available in Nixpkgs then
it may be possible to define these plugins outside Nixpkgs using the
<varname>buildEclipseUpdateSite</varname> and
<varname>buildEclipsePlugin</varname> functions found in the
<varname>nixpkgs.eclipses.plugins</varname> attribute set. Use the
<varname>buildEclipseUpdateSite</varname> function to install a plugin
distributed as an Eclipse update site. This function takes <literal>{ name,
src }</literal> as argument where <literal>src</literal> indicates the
Eclipse update site archive. All Eclipse features and plugins within the
downloaded update site will be installed. When an update site archive is not
available then the <varname>buildEclipsePlugin</varname> function can be
used to install a plugin that consists of a pair of feature and plugin JARs.
This function takes an argument <literal>{ name, srcFeature, srcPlugin
}</literal> where <literal>srcFeature</literal> and
<literal>srcPlugin</literal> are the feature and plugin JARs, respectively.
</para>
<para>
Expanding the previous example with two plugins using the above functions we
have
<screen>
packageOverrides = pkgs: {
myEclipse = with pkgs.eclipses; eclipseWithPlugins {
eclipse = eclipse-platform;
jvmArgs = [ "-Xmx2048m" ];
plugins = [
plugins.color-theme
(plugins.buildEclipsePlugin {
name = "myplugin1-1.0";
srcFeature = fetchurl {
url = "http://…/features/myplugin1.jar";
sha256 = "123…";
};
srcPlugin = fetchurl {
url = "http://…/plugins/myplugin1.jar";
sha256 = "123…";
};
});
(plugins.buildEclipseUpdateSite {
name = "myplugin2-1.0";
src = fetchurl {
stripRoot = false;
url = "http://…/myplugin2.zip";
sha256 = "123…";
};
});
];
};
}
</screen>
</para>
</section>
<section xml:id="sec-elm">
<title>Elm</title>
<para>
The Nix expressions for Elm reside in
<filename>pkgs/development/compilers/elm</filename>. They are generated
automatically by <command>update-elm.rb</command> script. One should specify
versions of Elm packages inside the script, clear the
<filename>packages</filename> directory and run the script from inside it.
<literal>elm-reactor</literal> is special because it also has Elm package
dependencies. The process is not automated very much for now -- you should
get the <literal>elm-reactor</literal> source tree (e.g. with
<command>nix-shell</command>) and run <command>elm2nix.rb</command> inside
it. Place the resulting <filename>package.nix</filename> file into
<filename>packages/elm-reactor-elm.nix</filename>.
</para>
</section>
<section xml:id="sec-shell-helpers">
<title>Interactive shell helpers</title>
<para>
Some packages provide the shell integration to be more useful. But unlike
other systems, nix doesn't have a standard share directory location. This is
why a bunch <command>PACKAGE-share</command> scripts are shipped that print
the location of the corresponding shared folder. Current list of such
packages is as following:
<itemizedlist>
<listitem>
<para>
<literal>autojump</literal>: <command>autojump-share</command>
</para>
</listitem>
<listitem>
<para>
<literal>fzf</literal>: <command>fzf-share</command>
</para>
</listitem>
</itemizedlist>
E.g. <literal>autojump</literal> can then used in the .bashrc like this:
<screen>
source "$(autojump-share)/autojump.bash"
</screen>
</para>
</section>
<section xml:id="sec-steam">
<title>Steam</title>
<section xml:id="sec-steam-nix">
<title>Steam in Nix</title>
<para>
Steam is distributed as a <filename>.deb</filename> file, for now only as
an i686 package (the amd64 package only has documentation). When unpacked,
it has a script called <filename>steam</filename> that in ubuntu (their
target distro) would go to <filename>/usr/bin </filename>. When run for the
first time, this script copies some files to the user's home, which include
another script that is the ultimate responsible for launching the steam
binary, which is also in $HOME.
</para>
<para>
Nix problems and constraints:
<itemizedlist>
<listitem>
<para>
We don't have <filename>/bin/bash</filename> and many scripts point
there. Similarly for <filename>/usr/bin/python</filename> .
</para>
</listitem>
<listitem>
<para>
We don't have the dynamic loader in <filename>/lib </filename>.
</para>
</listitem>
<listitem>
<para>
The <filename>steam.sh</filename> script in $HOME can not be patched, as
it is checked and rewritten by steam.
</para>
</listitem>
<listitem>
<para>
The steam binary cannot be patched, it's also checked.
</para>
</listitem>
</itemizedlist>
</para>
<para>
The current approach to deploy Steam in NixOS is composing a FHS-compatible
chroot environment, as documented
<link xlink:href="http://sandervanderburg.blogspot.nl/2013/09/composing-fhs-compatible-chroot.html">here</link>.
This allows us to have binaries in the expected paths without disrupting
the system, and to avoid patching them to work in a non FHS environment.
</para>
</section>
<section xml:id="sec-steam-play">
<title>How to play</title>
<para>
For 64-bit systems it's important to have
<programlisting>hardware.opengl.driSupport32Bit = true;</programlisting>
in your <filename>/etc/nixos/configuration.nix</filename>. You'll also need
<programlisting>hardware.pulseaudio.support32Bit = true;</programlisting>
if you are using PulseAudio - this will enable 32bit ALSA apps integration.
To use the Steam controller or other Steam supported controllers such as the DualShock 4 or Nintendo Switch Pro, you need to add
<programlisting>hardware.steam-hardware.enable = true;</programlisting>
to your configuration.
</para>
</section>
<section xml:id="sec-steam-troub">
<title>Troubleshooting</title>
<para>
<variablelist>
<varlistentry>
<term>
Steam fails to start. What do I do?
</term>
<listitem>
<para>
Try to run
<programlisting>strace steam</programlisting>
to see what is causing steam to fail.
</para>
</listitem>
</varlistentry>
<varlistentry>
<term>
Using the FOSS Radeon or nouveau (nvidia) drivers
</term>
<listitem>
<itemizedlist>
<listitem>
<para>
The <literal>newStdcpp</literal> parameter was removed since NixOS
17.09 and should not be needed anymore.
</para>
</listitem>
<listitem>
<para>
Steam ships statically linked with a version of libcrypto that
conflics with the one dynamically loaded by radeonsi_dri.so. If you
get the error
<programlisting>steam.sh: line 713: 7842 Segmentation fault (core dumped)</programlisting>
have a look at
<link xlink:href="https://github.com/NixOS/nixpkgs/pull/20269">this
pull request</link>.
</para>
</listitem>
</itemizedlist>
</listitem>
</varlistentry>
<varlistentry>
<term>
Java
</term>
<listitem>
<orderedlist>
<listitem>
<para>
There is no java in steam chrootenv by default. If you get a message
like
<programlisting>/home/foo/.local/share/Steam/SteamApps/common/towns/towns.sh: line 1: java: command not found</programlisting>
You need to add
<programlisting> steam.override { withJava = true; };</programlisting>
to your configuration.
</para>
</listitem>
</orderedlist>
</listitem>
</varlistentry>
</variablelist>
</para>
</section>
<section xml:id="sec-steam-run">
<title>steam-run</title>
<para>
The FHS-compatible chroot used for steam can also be used to run other
linux games that expect a FHS environment. To do it, add
<programlisting>pkgs.(steam.override {
nativeOnly = true;
newStdcpp = true;
}).run</programlisting>
to your configuration, rebuild, and run the game with
<programlisting>steam-run ./foo</programlisting>
</para>
</section>
</section>
<section xml:id="sec-emacs">
<title>Emacs</title>
<section xml:id="sec-emacs-config">
<title>Configuring Emacs</title>
<para>
The Emacs package comes with some extra helpers to make it easier to
configure. <varname>emacsWithPackages</varname> allows you to manage
packages from ELPA. This means that you will not have to install that
packages from within Emacs. For instance, if you wanted to use
<literal>company</literal>, <literal>counsel</literal>,
<literal>flycheck</literal>, <literal>ivy</literal>,
<literal>magit</literal>, <literal>projectile</literal>, and
<literal>use-package</literal> you could use this as a
<filename>~/.config/nixpkgs/config.nix</filename> override:
</para>
<screen>
{
packageOverrides = pkgs: with pkgs; {
myEmacs = emacsWithPackages (epkgs: (with epkgs.melpaStablePackages; [
company
counsel
flycheck
ivy
magit
projectile
use-package
]));
}
}
</screen>
<para>
You can install it like any other packages via <command>nix-env -iA
myEmacs</command>. However, this will only install those packages. It will
not <literal>configure</literal> them for us. To do this, we need to
provide a configuration file. Luckily, it is possible to do this from
within Nix! By modifying the above example, we can make Emacs load a custom
config file. The key is to create a package that provide a
<filename>default.el</filename> file in
<filename>/share/emacs/site-start/</filename>. Emacs knows to load this
file automatically when it starts.
</para>
<screen>
{
packageOverrides = pkgs: with pkgs; rec {
myEmacsConfig = writeText "default.el" ''
;; initialize package
(require 'package)
(package-initialize 'noactivate)
(eval-when-compile
(require 'use-package))
;; load some packages
(use-package company
:bind ("&lt;C-tab&gt;" . company-complete)
:diminish company-mode
:commands (company-mode global-company-mode)
:defer 1
:config
(global-company-mode))
(use-package counsel
:commands (counsel-descbinds)
:bind (([remap execute-extended-command] . counsel-M-x)
("C-x C-f" . counsel-find-file)
("C-c g" . counsel-git)
("C-c j" . counsel-git-grep)
("C-c k" . counsel-ag)
("C-x l" . counsel-locate)
("M-y" . counsel-yank-pop)))
(use-package flycheck
:defer 2
:config (global-flycheck-mode))
(use-package ivy
:defer 1
:bind (("C-c C-r" . ivy-resume)
("C-x C-b" . ivy-switch-buffer)
:map ivy-minibuffer-map
("C-j" . ivy-call))
:diminish ivy-mode
:commands ivy-mode
:config
(ivy-mode 1))
(use-package magit
:defer
:if (executable-find "git")
:bind (("C-x g" . magit-status)
("C-x G" . magit-dispatch-popup))
:init
(setq magit-completing-read-function 'ivy-completing-read))
(use-package projectile
:commands projectile-mode
:bind-keymap ("C-c p" . projectile-command-map)
:defer 5
:config
(projectile-global-mode))
'';
myEmacs = emacsWithPackages (epkgs: (with epkgs.melpaStablePackages; [
(runCommand "default.el" {} ''
mkdir -p $out/share/emacs/site-lisp
cp ${myEmacsConfig} $out/share/emacs/site-lisp/default.el
'')
company
counsel
flycheck
ivy
magit
projectile
use-package
]));
};
}
</screen>
<para>
This provides a fairly full Emacs start file. It will load in addition to
the user's presonal config. You can always disable it by passing
<command>-q</command> to the Emacs command.
</para>
<para>
Sometimes <varname>emacsWithPackages</varname> is not enough, as this
package set has some priorities imposed on packages (with the lowest
priority assigned to Melpa Unstable, and the highest for packages manually
defined in <filename>pkgs/top-level/emacs-packages.nix</filename>). But you
can't control this priorities when some package is installed as a
dependency. You can override it on per-package-basis, providing all the
required dependencies manually - but it's tedious and there is always a
possibility that an unwanted dependency will sneak in through some other
package. To completely override such a package you can use
<varname>overrideScope'</varname>.
</para>
<screen>
overrides = self: super: rec {
haskell-mode = self.melpaPackages.haskell-mode;
...
};
((emacsPackagesNgGen emacs).overrideScope' overrides).emacsWithPackages (p: with p; [
# here both these package will use haskell-mode of our own choice
ghc-mod
dante
])
</screen>
</section>
</section>
<section xml:id="sec-weechat">
<title>Weechat</title>
<para>
Weechat can be configured to include your choice of plugins, reducing its
closure size from the default configuration which includes all available
plugins. To make use of this functionality, install an expression that
overrides its configuration such as
<programlisting>weechat.override {configure = {availablePlugins, ...}: {
plugins = with availablePlugins; [ python perl ];
}
}</programlisting>
If the <literal>configure</literal> function returns an attrset without the
<literal>plugins</literal> attribute, <literal>availablePlugins</literal>
will be used automatically.
</para>
<para>
The plugins currently available are <literal>python</literal>,
<literal>perl</literal>, <literal>ruby</literal>, <literal>guile</literal>,
<literal>tcl</literal> and <literal>lua</literal>.
</para>
<para>
The python plugin allows the addition of extra libraries. For instance, the
<literal>inotify.py</literal> script in weechat-scripts requires D-Bus or
libnotify, and the <literal>fish.py</literal> script requires pycrypto. To
use these scripts, use the <literal>python</literal> plugin's
<literal>withPackages</literal> attribute:
<programlisting>weechat.override { configure = {availablePlugins, ...}: {
plugins = with availablePlugins; [
(python.withPackages (ps: with ps; [ pycrypto python-dbus ]))
];
};
}
</programlisting>
</para>
<para>
In order to also keep all default plugins installed, it is possible to use
the following method:
<programlisting>weechat.override { configure = { availablePlugins, ... }: {
plugins = builtins.attrValues (availablePlugins // {
python = availablePlugins.python.withPackages (ps: with ps; [ pycrypto python-dbus ]);
});
}; }
</programlisting>
</para>
<para>
WeeChat allows to set defaults on startup using the
<literal>--run-command</literal>. The <literal>configure</literal> method
can be used to pass commands to the program:
<programlisting>weechat.override {
configure = { availablePlugins, ... }: {
init = ''
/set foo bar
/server add freenode chat.freenode.org
'';
};
}</programlisting>
Further values can be added to the list of commands when running
<literal>weechat --run-command "your-commands"</literal>.
</para>
<para>
Additionally it's possible to specify scripts to be loaded when starting
<literal>weechat</literal>. These will be loaded before the commands from
<literal>init</literal>:
<programlisting>weechat.override {
configure = { availablePlugins, ... }: {
scripts = with pkgs.weechatScripts; [
weechat-xmpp weechat-matrix-bridge wee-slack
];
init = ''
/set plugins.var.python.jabber.key "val"
'':
};
}</programlisting>
</para>
<para>
In <literal>nixpkgs</literal> there's a subpackage which contains
derivations for WeeChat scripts. Such derivations expect a
<literal>passthru.scripts</literal> attribute which contains a list of all
scripts inside the store path. Furthermore all scripts have to live in
<literal>$out/share</literal>. An exemplary derivation looks like this:
<programlisting>{ stdenv, fetchurl }:
stdenv.mkDerivation {
name = "exemplary-weechat-script";
src = fetchurl {
url = "https://scripts.tld/your-scripts.tar.gz";
sha256 = "...";
};
passthru.scripts = [ "foo.py" "bar.lua" ];
installPhase = ''
mkdir $out/share
cp foo.py $out/share
cp bar.lua $out/share
'';
}</programlisting>
</para>
</section>
<section xml:id="sec-citrix">
<title>Citrix Receiver</title>
<para>
The <link xlink:href="https://www.citrix.com/products/receiver/">Citrix
Receiver</link> is a remote desktop viewer which provides access to
<link xlink:href="https://www.citrix.com/products/xenapp-xendesktop/">XenDesktop</link>
installations.
</para>
<section xml:id="sec-citrix-base">
<title>Basic usage</title>
<para>
The tarball archive needs to be downloaded manually as the licenses
agreements of the vendor need to be accepted first. This is available at
the
<link xlink:href="https://www.citrix.com/downloads/citrix-receiver/">download
page at citrix.com</link>. Then run <literal>nix-prefetch-url
file://$PWD/linuxx64-$version.tar.gz</literal>. With the archive available
in the store the package can be built and installed with Nix.
</para>
<para>
<emphasis>Note: it's recommended to install <literal>Citrix
Receiver</literal> using <literal>nix-env -i</literal> or globally to
ensure that the <literal>.desktop</literal> files are installed properly
into <literal>$XDG_CONFIG_DIRS</literal>. Otherwise it won't be possible to
open <literal>.ica</literal> files automatically from the browser to start
a Citrix connection.</emphasis>
</para>
</section>
<section xml:id="sec-citrix-custom-certs">
<title>Custom certificates</title>
<para>
The <literal>Citrix Receiver</literal> in <literal>nixpkgs</literal> trusts
several certificates
<link xlink:href="https://curl.haxx.se/docs/caextract.html">from the
Mozilla database</link> by default. However several companies using Citrix
might require their own corporate certificate. On distros with imperative
packaging these certs can be stored easily in
<link xlink:href="https://developer-docs.citrix.com/projects/receiver-for-linux-command-reference/en/13.7/"><literal>$ICAROOT</literal></link>,
however this directory is a store path in <literal>nixpkgs</literal>. In
order to work around this issue the package provides a simple mechanism to
add custom certificates without rebuilding the entire package using
<literal>symlinkJoin</literal>:
<programlisting>
<![CDATA[with import <nixpkgs> { config.allowUnfree = true; };
let extraCerts = [ ./custom-cert-1.pem ./custom-cert-2.pem /* ... */ ]; in
citrix_receiver.override {
inherit extraCerts;
}]]>
</programlisting>
</para>
</section>
</section>
<section xml:id="sec-ibus-typing-booster">
<title>ibus-engines.typing-booster</title>
<para>
This package is an ibus-based completion method to speed up typing.
</para>
<section xml:id="sec-ibus-typing-booster-activate">
<title>Activating the engine</title>
<para>
IBus needs to be configured accordingly to activate
<literal>typing-booster</literal>. The configuration depends on the desktop
manager in use. For detailed instructions, please refer to the
<link xlink:href="https://mike-fabian.github.io/ibus-typing-booster/documentation.html">upstream
docs</link>.
</para>
<para>
On NixOS you need to explicitly enable <literal>ibus</literal> with given
engines before customizing your desktop to use
<literal>typing-booster</literal>. This can be achieved using the
<literal>ibus</literal> module:
<programlisting>{ pkgs, ... }: {
i18n.inputMethod = {
enabled = "ibus";
ibus.engines = with pkgs.ibus-engines; [ typing-booster ];
};
}</programlisting>
</para>
</section>
<section xml:id="sec-ibus-typing-booster-customize-hunspell">
<title>Using custom hunspell dictionaries</title>
<para>
The IBus engine is based on <literal>hunspell</literal> to support
completion in many languages. By default the dictionaries
<literal>de-de</literal>, <literal>en-us</literal>,
<literal>es-es</literal>, <literal>it-it</literal>,
<literal>sv-se</literal> and <literal>sv-fi</literal> are in use. To add
another dictionary, the package can be overridden like this:
<programlisting>ibus-engines.typing-booster.override {
langs = [ "de-at" "en-gb" ];
}</programlisting>
</para>
<para>
<emphasis>Note: each language passed to <literal>langs</literal> must be an
attribute name in <literal>pkgs.hunspellDicts</literal>.</emphasis>
</para>
</section>
<section xml:id="sec-ibus-typing-booster-emoji-picker">
<title>Built-in emoji picker</title>
<para>
The <literal>ibus-engines.typing-booster</literal> package contains a
program named <literal>emoji-picker</literal>. To display all emojis
correctly, a special font such as <literal>noto-fonts-emoji</literal> is
needed:
</para>
<para>
On NixOS it can be installed using the following expression:
<programlisting>{ pkgs, ... }: {
fonts.fonts = with pkgs; [ noto-fonts-emoji ];
}</programlisting>
</para>
</section>
</section>
</chapter>

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<section xmlns="http://docbook.org/ns/docbook"
xmlns:xlink="http://www.w3.org/1999/xlink"
xml:id="sec-citrix">
<title>Citrix Workspace</title>
<para>
<note>
<para>
Please note that the <literal>citrix_receiver</literal> package has been deprecated since its development was <link xlink:href="https://docs.citrix.com/en-us/citrix-workspace-app.html">discontinued by upstream</link> and has been replaced by <link xlink:href="https://www.citrix.com/products/workspace-app/">the citrix workspace app</link>.
</para>
</note>
<link xlink:href="https://www.citrix.com/products/receiver/">Citrix Receiver</link> and <link xlink:href="https://www.citrix.com/products/workspace-app/">Citrix Workspace App</link> are a remote desktop viewers which provide access to <link xlink:href="https://www.citrix.com/products/xenapp-xendesktop/">XenDesktop</link> installations.
</para>
<section xml:id="sec-citrix-base">
<title>Basic usage</title>
<para>
The tarball archive needs to be downloaded manually as the license agreements of the vendor for <link xlink:href="https://www.citrix.com/downloads/citrix-receiver/">Citrix Receiver</link> or <link xlink:href="https://www.citrix.de/downloads/workspace-app/linux/workspace-app-for-linux-latest.html">Citrix Workspace</link> need to be accepted first. Then run <command>nix-prefetch-url file://$PWD/linuxx64-$version.tar.gz</command>. With the archive available in the store the package can be built and installed with Nix.
</para>
<warning>
<title>Caution with <command>nix-shell</command> installs</title>
<para>
It's recommended to install <literal>Citrix Receiver</literal> and/or <literal>Citrix Workspace</literal> using <literal>nix-env -i</literal> or globally to ensure that the <literal>.desktop</literal> files are installed properly into <literal>$XDG_CONFIG_DIRS</literal>. Otherwise it won't be possible to open <literal>.ica</literal> files automatically from the browser to start a Citrix connection.
</para>
</warning>
</section>
<section xml:id="sec-citrix-custom-certs">
<title>Custom certificates</title>
<para>
The <literal>Citrix Workspace App</literal> in <literal>nixpkgs</literal> trust several certificates <link xlink:href="https://curl.haxx.se/docs/caextract.html">from the Mozilla database</link> by default. However several companies using Citrix might require their own corporate certificate. On distros with imperative packaging these certs can be stored easily in <link xlink:href="https://developer-docs.citrix.com/projects/receiver-for-linux-command-reference/en/13.7/"><literal>$ICAROOT</literal></link>, however this directory is a store path in <literal>nixpkgs</literal>. In order to work around this issue the package provides a simple mechanism to add custom certificates without rebuilding the entire package using <literal>symlinkJoin</literal>:
<programlisting>
<![CDATA[with import <nixpkgs> { config.allowUnfree = true; };
let extraCerts = [ ./custom-cert-1.pem ./custom-cert-2.pem /* ... */ ]; in
citrix_workspace.override {
inherit extraCerts;
}]]>
</programlisting>
</para>
</section>
</section>

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<section xmlns="http://docbook.org/ns/docbook"
xmlns:xlink="http://www.w3.org/1999/xlink"
xml:id="dlib">
<title>DLib</title>
<para>
<link xlink:href="http://dlib.net/">DLib</link> is a modern, C++-based toolkit which provides several machine learning algorithms.
</para>
<section xml:id="compiling-without-avx-support">
<title>Compiling without AVX support</title>
<para>
Especially older CPUs don't support <link xlink:href="https://en.wikipedia.org/wiki/Advanced_Vector_Extensions">AVX</link> (<abbrev>Advanced Vector Extensions</abbrev>) instructions that are used by DLib to optimize their algorithms.
</para>
<para>
On the affected hardware errors like <literal>Illegal instruction</literal> will occur. In those cases AVX support needs to be disabled:
<programlisting>self: super: {
dlib = super.dlib.override { avxSupport = false; };
}</programlisting>
</para>
</section>
</section>

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<section xmlns="http://docbook.org/ns/docbook"
xmlns:xlink="http://www.w3.org/1999/xlink"
xml:id="sec-eclipse">
<title>Eclipse</title>
<para>
The Nix expressions related to the Eclipse platform and IDE are in <link xlink:href="https://github.com/NixOS/nixpkgs/blob/master/pkgs/applications/editors/eclipse"><filename>pkgs/applications/editors/eclipse</filename></link>.
</para>
<para>
Nixpkgs provides a number of packages that will install Eclipse in its various forms. These range from the bare-bones Eclipse Platform to the more fully featured Eclipse SDK or Scala-IDE packages and multiple version are often available. It is possible to list available Eclipse packages by issuing the command:
<screen>
<prompt>$ </prompt>nix-env -f '&lt;nixpkgs&gt;' -qaP -A eclipses --description
</screen>
Once an Eclipse variant is installed it can be run using the <command>eclipse</command> command, as expected. From within Eclipse it is then possible to install plugins in the usual manner by either manually specifying an Eclipse update site or by installing the Marketplace Client plugin and using it to discover and install other plugins. This installation method provides an Eclipse installation that closely resemble a manually installed Eclipse.
</para>
<para>
If you prefer to install plugins in a more declarative manner then Nixpkgs also offer a number of Eclipse plugins that can be installed in an <emphasis>Eclipse environment</emphasis>. This type of environment is created using the function <varname>eclipseWithPlugins</varname> found inside the <varname>nixpkgs.eclipses</varname> attribute set. This function takes as argument <literal>{ eclipse, plugins ? [], jvmArgs ? [] }</literal> where <varname>eclipse</varname> is a one of the Eclipse packages described above, <varname>plugins</varname> is a list of plugin derivations, and <varname>jvmArgs</varname> is a list of arguments given to the JVM running the Eclipse. For example, say you wish to install the latest Eclipse Platform with the popular Eclipse Color Theme plugin and also allow Eclipse to use more RAM. You could then add
<screen>
packageOverrides = pkgs: {
myEclipse = with pkgs.eclipses; eclipseWithPlugins {
eclipse = eclipse-platform;
jvmArgs = [ "-Xmx2048m" ];
plugins = [ plugins.color-theme ];
};
}
</screen>
to your Nixpkgs configuration (<filename>~/.config/nixpkgs/config.nix</filename>) and install it by running <command>nix-env -f '&lt;nixpkgs&gt;' -iA myEclipse</command> and afterward run Eclipse as usual. It is possible to find out which plugins are available for installation using <varname>eclipseWithPlugins</varname> by running
<screen>
<prompt>$ </prompt>nix-env -f '&lt;nixpkgs&gt;' -qaP -A eclipses.plugins --description
</screen>
</para>
<para>
If there is a need to install plugins that are not available in Nixpkgs then it may be possible to define these plugins outside Nixpkgs using the <varname>buildEclipseUpdateSite</varname> and <varname>buildEclipsePlugin</varname> functions found in the <varname>nixpkgs.eclipses.plugins</varname> attribute set. Use the <varname>buildEclipseUpdateSite</varname> function to install a plugin distributed as an Eclipse update site. This function takes <literal>{ name, src }</literal> as argument where <literal>src</literal> indicates the Eclipse update site archive. All Eclipse features and plugins within the downloaded update site will be installed. When an update site archive is not available then the <varname>buildEclipsePlugin</varname> function can be used to install a plugin that consists of a pair of feature and plugin JARs. This function takes an argument <literal>{ name, srcFeature, srcPlugin }</literal> where <literal>srcFeature</literal> and <literal>srcPlugin</literal> are the feature and plugin JARs, respectively.
</para>
<para>
Expanding the previous example with two plugins using the above functions we have
<screen>
packageOverrides = pkgs: {
myEclipse = with pkgs.eclipses; eclipseWithPlugins {
eclipse = eclipse-platform;
jvmArgs = [ "-Xmx2048m" ];
plugins = [
plugins.color-theme
(plugins.buildEclipsePlugin {
name = "myplugin1-1.0";
srcFeature = fetchurl {
url = "http://…/features/myplugin1.jar";
sha256 = "123…";
};
srcPlugin = fetchurl {
url = "http://…/plugins/myplugin1.jar";
sha256 = "123…";
};
});
(plugins.buildEclipseUpdateSite {
name = "myplugin2-1.0";
src = fetchurl {
stripRoot = false;
url = "http://…/myplugin2.zip";
sha256 = "123…";
};
});
];
};
}
</screen>
</para>
</section>

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<section xmlns="http://docbook.org/ns/docbook"
xmlns:xlink="http://www.w3.org/1999/xlink"
xml:id="sec-elm">
<title>Elm</title>
<para>
To start a development environment do <command>nix-shell -p elmPackages.elm elmPackages.elm-format</command>
</para>
<para>
To update Elm compiler, see <filename>nixpkgs/pkgs/development/compilers/elm/README.md</filename>.
</para>
<para>
To package Elm applications, <link xlink:href="https://github.com/hercules-ci/elm2nix#elm2nix">read about elm2nix</link>.
</para>
</section>

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<section xmlns="http://docbook.org/ns/docbook"
xmlns:xlink="http://www.w3.org/1999/xlink"
xml:id="sec-emacs">
<title>Emacs</title>
<section xml:id="sec-emacs-config">
<title>Configuring Emacs</title>
<para>
The Emacs package comes with some extra helpers to make it easier to configure. <varname>emacsWithPackages</varname> allows you to manage packages from ELPA. This means that you will not have to install that packages from within Emacs. For instance, if you wanted to use <literal>company</literal>, <literal>counsel</literal>, <literal>flycheck</literal>, <literal>ivy</literal>, <literal>magit</literal>, <literal>projectile</literal>, and <literal>use-package</literal> you could use this as a <filename>~/.config/nixpkgs/config.nix</filename> override:
</para>
<screen>
{
packageOverrides = pkgs: with pkgs; {
myEmacs = emacsWithPackages (epkgs: (with epkgs.melpaStablePackages; [
company
counsel
flycheck
ivy
magit
projectile
use-package
]));
}
}
</screen>
<para>
You can install it like any other packages via <command>nix-env -iA myEmacs</command>. However, this will only install those packages. It will not <literal>configure</literal> them for us. To do this, we need to provide a configuration file. Luckily, it is possible to do this from within Nix! By modifying the above example, we can make Emacs load a custom config file. The key is to create a package that provide a <filename>default.el</filename> file in <filename>/share/emacs/site-start/</filename>. Emacs knows to load this file automatically when it starts.
</para>
<screen>
{
packageOverrides = pkgs: with pkgs; rec {
myEmacsConfig = writeText "default.el" ''
;; initialize package
(require 'package)
(package-initialize 'noactivate)
(eval-when-compile
(require 'use-package))
;; load some packages
(use-package company
:bind ("&lt;C-tab&gt;" . company-complete)
:diminish company-mode
:commands (company-mode global-company-mode)
:defer 1
:config
(global-company-mode))
(use-package counsel
:commands (counsel-descbinds)
:bind (([remap execute-extended-command] . counsel-M-x)
("C-x C-f" . counsel-find-file)
("C-c g" . counsel-git)
("C-c j" . counsel-git-grep)
("C-c k" . counsel-ag)
("C-x l" . counsel-locate)
("M-y" . counsel-yank-pop)))
(use-package flycheck
:defer 2
:config (global-flycheck-mode))
(use-package ivy
:defer 1
:bind (("C-c C-r" . ivy-resume)
("C-x C-b" . ivy-switch-buffer)
:map ivy-minibuffer-map
("C-j" . ivy-call))
:diminish ivy-mode
:commands ivy-mode
:config
(ivy-mode 1))
(use-package magit
:defer
:if (executable-find "git")
:bind (("C-x g" . magit-status)
("C-x G" . magit-dispatch-popup))
:init
(setq magit-completing-read-function 'ivy-completing-read))
(use-package projectile
:commands projectile-mode
:bind-keymap ("C-c p" . projectile-command-map)
:defer 5
:config
(projectile-global-mode))
'';
myEmacs = emacsWithPackages (epkgs: (with epkgs.melpaStablePackages; [
(runCommand "default.el" {} ''
mkdir -p $out/share/emacs/site-lisp
cp ${myEmacsConfig} $out/share/emacs/site-lisp/default.el
'')
company
counsel
flycheck
ivy
magit
projectile
use-package
]));
};
}
</screen>
<para>
This provides a fairly full Emacs start file. It will load in addition to the user's presonal config. You can always disable it by passing <command>-q</command> to the Emacs command.
</para>
<para>
Sometimes <varname>emacsWithPackages</varname> is not enough, as this package set has some priorities imposed on packages (with the lowest priority assigned to Melpa Unstable, and the highest for packages manually defined in <filename>pkgs/top-level/emacs-packages.nix</filename>). But you can't control this priorities when some package is installed as a dependency. You can override it on per-package-basis, providing all the required dependencies manually - but it's tedious and there is always a possibility that an unwanted dependency will sneak in through some other package. To completely override such a package you can use <varname>overrideScope'</varname>.
</para>
<screen>
overrides = self: super: rec {
haskell-mode = self.melpaPackages.haskell-mode;
...
};
((emacsPackagesGen emacs).overrideScope' overrides).emacsWithPackages (p: with p; [
# here both these package will use haskell-mode of our own choice
ghc-mod
dante
])
</screen>
</section>
</section>

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<section xmlns="http://docbook.org/ns/docbook"
xmlns:xlink="http://www.w3.org/1999/xlink"
xml:id="sec-ibus-typing-booster">
<title>ibus-engines.typing-booster</title>
<para>
This package is an ibus-based completion method to speed up typing.
</para>
<section xml:id="sec-ibus-typing-booster-activate">
<title>Activating the engine</title>
<para>
IBus needs to be configured accordingly to activate <literal>typing-booster</literal>. The configuration depends on the desktop manager in use. For detailed instructions, please refer to the <link xlink:href="https://mike-fabian.github.io/ibus-typing-booster/documentation.html">upstream docs</link>.
</para>
<para>
On NixOS you need to explicitly enable <literal>ibus</literal> with given engines before customizing your desktop to use <literal>typing-booster</literal>. This can be achieved using the <literal>ibus</literal> module:
<programlisting>{ pkgs, ... }: {
i18n.inputMethod = {
enabled = "ibus";
ibus.engines = with pkgs.ibus-engines; [ typing-booster ];
};
}</programlisting>
</para>
</section>
<section xml:id="sec-ibus-typing-booster-customize-hunspell">
<title>Using custom hunspell dictionaries</title>
<para>
The IBus engine is based on <literal>hunspell</literal> to support completion in many languages. By default the dictionaries <literal>de-de</literal>, <literal>en-us</literal>, <literal>fr-moderne</literal> <literal>es-es</literal>, <literal>it-it</literal>, <literal>sv-se</literal> and <literal>sv-fi</literal> are in use. To add another dictionary, the package can be overridden like this:
<programlisting>ibus-engines.typing-booster.override {
langs = [ "de-at" "en-gb" ];
}</programlisting>
</para>
<para>
<emphasis>Note: each language passed to <literal>langs</literal> must be an attribute name in <literal>pkgs.hunspellDicts</literal>.</emphasis>
</para>
</section>
<section xml:id="sec-ibus-typing-booster-emoji-picker">
<title>Built-in emoji picker</title>
<para>
The <literal>ibus-engines.typing-booster</literal> package contains a program named <literal>emoji-picker</literal>. To display all emojis correctly, a special font such as <literal>noto-fonts-emoji</literal> is needed:
</para>
<para>
On NixOS it can be installed using the following expression:
<programlisting>{ pkgs, ... }: {
fonts.fonts = with pkgs; [ noto-fonts-emoji ];
}</programlisting>
</para>
</section>
</section>

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<chapter xmlns="http://docbook.org/ns/docbook"
xmlns:xi="http://www.w3.org/2001/XInclude"
xml:id="chap-packages">
<title>Packages</title>
<para>
This chapter contains information about how to use and maintain the Nix expressions for a number of specific packages, such as the Linux kernel or X.org.
</para>
<xi:include href="citrix.xml" />
<xi:include href="dlib.xml" />
<xi:include href="eclipse.xml" />
<xi:include href="elm.xml" />
<xi:include href="emacs.xml" />
<xi:include href="ibus.xml" />
<xi:include href="kakoune.xml" />
<xi:include href="linux.xml" />
<xi:include href="locales.xml" />
<xi:include href="nginx.xml" />
<xi:include href="opengl.xml" />
<xi:include href="shell-helpers.xml" />
<xi:include href="steam.xml" />
<xi:include href="weechat.xml" />
<xi:include href="xorg.xml" />
</chapter>

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<section xmlns="http://docbook.org/ns/docbook"
xmlns:xlink="http://www.w3.org/1999/xlink"
xml:id="sec-kakoune">
<title>Kakoune</title>
<para>
Kakoune can be built to autoload plugins:
<programlisting>(kakoune.override {
configure = {
plugins = with pkgs.kakounePlugins; [ parinfer-rust ];
};
})</programlisting>
</para>
</section>

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<section xmlns="http://docbook.org/ns/docbook"
xmlns:xlink="http://www.w3.org/1999/xlink"
xml:id="sec-linux-kernel">
<title>Linux kernel</title>
<para>
The Nix expressions to build the Linux kernel are in <link
xlink:href="https://github.com/NixOS/nixpkgs/blob/master/pkgs/os-specific/linux/kernel"><filename>pkgs/os-specific/linux/kernel</filename></link>.
</para>
<para>
The function that builds the kernel has an argument <varname>kernelPatches</varname> which should be a list of <literal>{name, patch, extraConfig}</literal> attribute sets, where <varname>name</varname> is the name of the patch (which is included in the kernels <varname>meta.description</varname> attribute), <varname>patch</varname> is the patch itself (possibly compressed), and <varname>extraConfig</varname> (optional) is a string specifying extra options to be concatenated to the kernel configuration file (<filename>.config</filename>).
</para>
<para>
The kernel derivation exports an attribute <varname>features</varname> specifying whether optional functionality is or isnt enabled. This is used in NixOS to implement kernel-specific behaviour. For instance, if the kernel has the <varname>iwlwifi</varname> feature (i.e. has built-in support for Intel wireless chipsets), then NixOS doesnt have to build the external <varname>iwlwifi</varname> package:
<programlisting>
modulesTree = [kernel]
++ pkgs.lib.optional (!kernel.features ? iwlwifi) kernelPackages.iwlwifi
++ ...;
</programlisting>
</para>
<para>
How to add a new (major) version of the Linux kernel to Nixpkgs:
<orderedlist>
<listitem>
<para>
Copy the old Nix expression (e.g. <filename>linux-2.6.21.nix</filename>) to the new one (e.g. <filename>linux-2.6.22.nix</filename>) and update it.
</para>
</listitem>
<listitem>
<para>
Add the new kernel to <filename>all-packages.nix</filename> (e.g., create an attribute <varname>kernel_2_6_22</varname>).
</para>
</listitem>
<listitem>
<para>
Now were going to update the kernel configuration. First unpack the kernel. Then for each supported platform (<literal>i686</literal>, <literal>x86_64</literal>, <literal>uml</literal>) do the following:
<orderedlist>
<listitem>
<para>
Make an copy from the old config (e.g. <filename>config-2.6.21-i686-smp</filename>) to the new one (e.g. <filename>config-2.6.22-i686-smp</filename>).
</para>
</listitem>
<listitem>
<para>
Copy the config file for this platform (e.g. <filename>config-2.6.22-i686-smp</filename>) to <filename>.config</filename> in the kernel source tree.
</para>
</listitem>
<listitem>
<para>
Run <literal>make oldconfig ARCH=<replaceable>{i386,x86_64,um}</replaceable></literal> and answer all questions. (For the uml configuration, also add <literal>SHELL=bash</literal>.) Make sure to keep the configuration consistent between platforms (i.e. dont enable some feature on <literal>i686</literal> and disable it on <literal>x86_64</literal>).
</para>
</listitem>
<listitem>
<para>
If needed you can also run <literal>make menuconfig</literal>:
<screen>
<prompt>$ </prompt>nix-env -i ncurses
<prompt>$ </prompt>export NIX_CFLAGS_LINK=-lncurses
<prompt>$ </prompt>make menuconfig ARCH=<replaceable>arch</replaceable></screen>
</para>
</listitem>
<listitem>
<para>
Copy <filename>.config</filename> over the new config file (e.g. <filename>config-2.6.22-i686-smp</filename>).
</para>
</listitem>
</orderedlist>
</para>
</listitem>
<listitem>
<para>
Test building the kernel: <literal>nix-build -A kernel_2_6_22</literal>. If it compiles, ship it! For extra credit, try booting NixOS with it.
</para>
</listitem>
<listitem>
<para>
It may be that the new kernel requires updating the external kernel modules and kernel-dependent packages listed in the <varname>linuxPackagesFor</varname> function in <filename>all-packages.nix</filename> (such as the NVIDIA drivers, AUFS, etc.). If the updated packages arent backwards compatible with older kernels, you may need to keep the older versions around.
</para>
</listitem>
</orderedlist>
</para>
</section>

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<section xmlns="http://docbook.org/ns/docbook"
xmlns:xlink="http://www.w3.org/1999/xlink"
xml:id="locales">
<title>Locales</title>
<para>
To allow simultaneous use of packages linked against different versions of <literal>glibc</literal> with different locale archive formats Nixpkgs patches <literal>glibc</literal> to rely on <literal>LOCALE_ARCHIVE</literal> environment variable.
</para>
<para>
On non-NixOS distributions this variable is obviously not set. This can cause regressions in language support or even crashes in some Nixpkgs-provided programs. The simplest way to mitigate this problem is exporting the <literal>LOCALE_ARCHIVE</literal> variable pointing to <literal>${glibcLocales}/lib/locale/locale-archive</literal>. The drawback (and the reason this is not the default) is the relatively large (a hundred MiB) size of the full set of locales. It is possible to build a custom set of locales by overriding parameters <literal>allLocales</literal> and <literal>locales</literal> of the package.
</para>
</section>

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<section xmlns="http://docbook.org/ns/docbook"
xmlns:xlink="http://www.w3.org/1999/xlink"
xml:id="sec-nginx">
<title>Nginx</title>
<para>
<link xlink:href="https://nginx.org/">Nginx</link> is a reverse proxy and lightweight webserver.
</para>
<section xml:id="sec-nginx-etag">
<title>ETags on static files served from the Nix store</title>
<para>
HTTP has a couple different mechanisms for caching to prevent clients from having to download the same content repeatedly if a resource has not changed since the last time it was requested. When nginx is used as a server for static files, it implements the caching mechanism based on the <link xlink:href="https://developer.mozilla.org/en-US/docs/Web/HTTP/Headers/Last-Modified"><literal>Last-Modified</literal></link> response header automatically; unfortunately, it works by using filesystem timestamps to determine the value of the <literal>Last-Modified</literal> header. This doesn't give the desired behavior when the file is in the Nix store, because all file timestamps are set to 0 (for reasons related to build reproducibility).
</para>
<para>
Fortunately, HTTP supports an alternative (and more effective) caching mechanism: the <link xlink:href="https://developer.mozilla.org/en-US/docs/Web/HTTP/Headers/ETag"><literal>ETag</literal></link> response header. The value of the <literal>ETag</literal> header specifies some identifier for the particular content that the server is sending (e.g. a hash). When a client makes a second request for the same resource, it sends that value back in an <literal>If-None-Match</literal> header. If the ETag value is unchanged, then the server does not need to resend the content.
</para>
<para>
As of NixOS 19.09, the nginx package in Nixpkgs is patched such that when nginx serves a file out of <filename>/nix/store</filename>, the hash in the store path is used as the <literal>ETag</literal> header in the HTTP response, thus providing proper caching functionality. This happens automatically; you do not need to do modify any configuration to get this behavior.
</para>
</section>
</section>

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<section xmlns="http://docbook.org/ns/docbook"
xmlns:xlink="http://www.w3.org/1999/xlink"
xml:id="sec-opengl">
<title>OpenGL</title>
<para>
Packages that use OpenGL have NixOS desktop as their primary target. The current solution for loading the GPU-specific drivers is based on <literal>libglvnd</literal> and looks for the driver implementation in <literal>LD_LIBRARY_PATH</literal>. If you are using a non-NixOS GNU/Linux/X11 desktop with free software video drivers, consider launching OpenGL-dependent programs from Nixpkgs with Nixpkgs versions of <literal>libglvnd</literal> and <literal>mesa_drivers</literal> in <literal>LD_LIBRARY_PATH</literal>. For proprietary video drivers you might have luck with also adding the corresponding video driver package.
</para>
</section>

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<section xmlns="http://docbook.org/ns/docbook"
xmlns:xlink="http://www.w3.org/1999/xlink"
xml:id="sec-shell-helpers">
<title>Interactive shell helpers</title>
<para>
Some packages provide the shell integration to be more useful. But unlike other systems, nix doesn't have a standard share directory location. This is why a bunch <command>PACKAGE-share</command> scripts are shipped that print the location of the corresponding shared folder. Current list of such packages is as following:
<itemizedlist>
<listitem>
<para>
<literal>autojump</literal>: <command>autojump-share</command>
</para>
</listitem>
<listitem>
<para>
<literal>fzf</literal>: <command>fzf-share</command>
</para>
</listitem>
</itemizedlist>
E.g. <literal>autojump</literal> can then used in the .bashrc like this:
<screen>
source "$(autojump-share)/autojump.bash"
</screen>
</para>
</section>

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<section xmlns="http://docbook.org/ns/docbook"
xmlns:xlink="http://www.w3.org/1999/xlink"
xml:id="sec-steam">
<title>Steam</title>
<section xml:id="sec-steam-nix">
<title>Steam in Nix</title>
<para>
Steam is distributed as a <filename>.deb</filename> file, for now only as an i686 package (the amd64 package only has documentation). When unpacked, it has a script called <filename>steam</filename> that in Ubuntu (their target distro) would go to <filename>/usr/bin </filename>. When run for the first time, this script copies some files to the user's home, which include another script that is the ultimate responsible for launching the steam binary, which is also in $HOME.
</para>
<para>
Nix problems and constraints:
<itemizedlist>
<listitem>
<para>
We don't have <filename>/bin/bash</filename> and many scripts point there. Similarly for <filename>/usr/bin/python</filename> .
</para>
</listitem>
<listitem>
<para>
We don't have the dynamic loader in <filename>/lib </filename>.
</para>
</listitem>
<listitem>
<para>
The <filename>steam.sh</filename> script in $HOME can not be patched, as it is checked and rewritten by steam.
</para>
</listitem>
<listitem>
<para>
The steam binary cannot be patched, it's also checked.
</para>
</listitem>
</itemizedlist>
</para>
<para>
The current approach to deploy Steam in NixOS is composing a FHS-compatible chroot environment, as documented <link xlink:href="http://sandervanderburg.blogspot.nl/2013/09/composing-fhs-compatible-chroot.html">here</link>. This allows us to have binaries in the expected paths without disrupting the system, and to avoid patching them to work in a non FHS environment.
</para>
</section>
<section xml:id="sec-steam-play">
<title>How to play</title>
<para>
For 64-bit systems it's important to have
<programlisting>hardware.opengl.driSupport32Bit = true;</programlisting>
in your <filename>/etc/nixos/configuration.nix</filename>. You'll also need
<programlisting>hardware.pulseaudio.support32Bit = true;</programlisting>
if you are using PulseAudio - this will enable 32bit ALSA apps integration. To use the Steam controller or other Steam supported controllers such as the DualShock 4 or Nintendo Switch Pro, you need to add
<programlisting>hardware.steam-hardware.enable = true;</programlisting>
to your configuration.
</para>
</section>
<section xml:id="sec-steam-troub">
<title>Troubleshooting</title>
<para>
<variablelist>
<varlistentry>
<term>
Steam fails to start. What do I do?
</term>
<listitem>
<para>
Try to run
<programlisting>strace steam</programlisting>
to see what is causing steam to fail.
</para>
</listitem>
</varlistentry>
<varlistentry>
<term>
Using the FOSS Radeon or nouveau (nvidia) drivers
</term>
<listitem>
<itemizedlist>
<listitem>
<para>
The <literal>newStdcpp</literal> parameter was removed since NixOS 17.09 and should not be needed anymore.
</para>
</listitem>
<listitem>
<para>
Steam ships statically linked with a version of libcrypto that conflics with the one dynamically loaded by radeonsi_dri.so. If you get the error
<programlisting>steam.sh: line 713: 7842 Segmentation fault (core dumped)</programlisting>
have a look at <link xlink:href="https://github.com/NixOS/nixpkgs/pull/20269">this pull request</link>.
</para>
</listitem>
</itemizedlist>
</listitem>
</varlistentry>
<varlistentry>
<term>
Java
</term>
<listitem>
<orderedlist>
<listitem>
<para>
There is no java in steam chrootenv by default. If you get a message like
<programlisting>/home/foo/.local/share/Steam/SteamApps/common/towns/towns.sh: line 1: java: command not found</programlisting>
You need to add
<programlisting> steam.override { withJava = true; };</programlisting>
to your configuration.
</para>
</listitem>
</orderedlist>
</listitem>
</varlistentry>
</variablelist>
</para>
</section>
<section xml:id="sec-steam-run">
<title>steam-run</title>
<para>
The FHS-compatible chroot used for steam can also be used to run other linux games that expect a FHS environment. To do it, add
<programlisting>pkgs.(steam.override {
nativeOnly = true;
newStdcpp = true;
}).run</programlisting>
to your configuration, rebuild, and run the game with
<programlisting>steam-run ./foo</programlisting>
</para>
</section>
</section>

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<section xmlns="http://docbook.org/ns/docbook"
xmlns:xlink="http://www.w3.org/1999/xlink"
xml:id="unfree-software">
<title>Unfree software</title>
<para>
All users of Nixpkgs are free software users, and many users (and developers) of Nixpkgs want to limit and tightly control their exposure to unfree software. At the same time, many users need (or want) to run some specific pieces of proprietary software. Nixpkgs includes some expressions for unfree software packages. By default unfree software cannot be installed and doesnt show up in searches. To allow installing unfree software in a single Nix invocation one can export <literal>NIXPKGS_ALLOW_UNFREE=1</literal>. For a persistent solution, users can set <literal>allowUnfree</literal> in the Nixpkgs configuration.
</para>
<para>
Fine-grained control is possible by defining <literal>allowUnfreePredicate</literal> function in config; it takes the <literal>mkDerivation</literal> parameter attrset and returns <literal>true</literal> for unfree packages that should be allowed.
</para>
</section>

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<section xmlns="http://docbook.org/ns/docbook"
xmlns:xlink="http://www.w3.org/1999/xlink"
xml:id="sec-weechat">
<title>Weechat</title>
<para>
Weechat can be configured to include your choice of plugins, reducing its closure size from the default configuration which includes all available plugins. To make use of this functionality, install an expression that overrides its configuration such as
<programlisting>weechat.override {configure = {availablePlugins, ...}: {
plugins = with availablePlugins; [ python perl ];
}
}</programlisting>
If the <literal>configure</literal> function returns an attrset without the <literal>plugins</literal> attribute, <literal>availablePlugins</literal> will be used automatically.
</para>
<para>
The plugins currently available are <literal>python</literal>, <literal>perl</literal>, <literal>ruby</literal>, <literal>guile</literal>, <literal>tcl</literal> and <literal>lua</literal>.
</para>
<para>
The python and perl plugins allows the addition of extra libraries. For instance, the <literal>inotify.py</literal> script in weechat-scripts requires D-Bus or libnotify, and the <literal>fish.py</literal> script requires pycrypto. To use these scripts, use the plugin's <literal>withPackages</literal> attribute:
<programlisting>weechat.override { configure = {availablePlugins, ...}: {
plugins = with availablePlugins; [
(python.withPackages (ps: with ps; [ pycrypto python-dbus ]))
];
};
}
</programlisting>
</para>
<para>
In order to also keep all default plugins installed, it is possible to use the following method:
<programlisting>weechat.override { configure = { availablePlugins, ... }: {
plugins = builtins.attrValues (availablePlugins // {
python = availablePlugins.python.withPackages (ps: with ps; [ pycrypto python-dbus ]);
});
}; }
</programlisting>
</para>
<para>
WeeChat allows to set defaults on startup using the <literal>--run-command</literal>. The <literal>configure</literal> method can be used to pass commands to the program:
<programlisting>weechat.override {
configure = { availablePlugins, ... }: {
init = ''
/set foo bar
/server add freenode chat.freenode.org
'';
};
}</programlisting>
Further values can be added to the list of commands when running <literal>weechat --run-command "your-commands"</literal>.
</para>
<para>
Additionally it's possible to specify scripts to be loaded when starting <literal>weechat</literal>. These will be loaded before the commands from <literal>init</literal>:
<programlisting>weechat.override {
configure = { availablePlugins, ... }: {
scripts = with pkgs.weechatScripts; [
weechat-xmpp weechat-matrix-bridge wee-slack
];
init = ''
/set plugins.var.python.jabber.key "val"
'':
};
}</programlisting>
</para>
<para>
In <literal>nixpkgs</literal> there's a subpackage which contains derivations for WeeChat scripts. Such derivations expect a <literal>passthru.scripts</literal> attribute which contains a list of all scripts inside the store path. Furthermore all scripts have to live in <literal>$out/share</literal>. An exemplary derivation looks like this:
<programlisting>{ stdenv, fetchurl }:
stdenv.mkDerivation {
name = "exemplary-weechat-script";
src = fetchurl {
url = "https://scripts.tld/your-scripts.tar.gz";
sha256 = "...";
};
passthru.scripts = [ "foo.py" "bar.lua" ];
installPhase = ''
mkdir $out/share
cp foo.py $out/share
cp bar.lua $out/share
'';
}</programlisting>
</para>
</section>

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<section xmlns="http://docbook.org/ns/docbook"
xmlns:xlink="http://www.w3.org/1999/xlink"
xml:id="sec-xorg">
<title>X.org</title>
<para>
The Nix expressions for the X.org packages reside in <filename>pkgs/servers/x11/xorg/default.nix</filename>. This file is automatically generated from lists of tarballs in an X.org release. As such it should not be modified directly; rather, you should modify the lists, the generator script or the file <filename>pkgs/servers/x11/xorg/overrides.nix</filename>, in which you can override or add to the derivations produced by the generator.
</para>
<para>
The generator is invoked as follows:
<screen>
<prompt>$ </prompt>cd pkgs/servers/x11/xorg
<prompt>$ </prompt>cat tarballs-7.5.list extra.list old.list \
| perl ./generate-expr-from-tarballs.pl
</screen>
For each of the tarballs in the <filename>.list</filename> files, the script downloads it, unpacks it, and searches its <filename>configure.ac</filename> and <filename>*.pc.in</filename> files for dependencies. This information is used to generate <filename>default.nix</filename>. The generator caches downloaded tarballs between runs. Pay close attention to the <literal>NOT FOUND: <replaceable>name</replaceable></literal> messages at the end of the run, since they may indicate missing dependencies. (Some might be optional dependencies, however.)
</para>
<para>
A file like <filename>tarballs-7.5.list</filename> contains all tarballs in a X.org release. It can be generated like this:
<screen>
<prompt>$ </prompt>export i="mirror://xorg/X11R7.4/src/everything/"
<prompt>$ </prompt>cat $(PRINT_PATH=1 nix-prefetch-url $i | tail -n 1) \
| perl -e 'while (&lt;>) { if (/(href|HREF)="([^"]*.bz2)"/) { print "$ENV{'i'}$2\n"; }; }' \
| sort > tarballs-7.4.list
</screen>
<filename>extra.list</filename> contains libraries that arent part of X.org proper, but are closely related to it, such as <literal>libxcb</literal>. <filename>old.list</filename> contains some packages that were removed from X.org, but are still needed by some people or by other packages (such as <varname>imake</varname>).
</para>
<para>
If the expression for a package requires derivation attributes that the generator cannot figure out automatically (say, <varname>patches</varname> or a <varname>postInstall</varname> hook), you should modify <filename>pkgs/servers/x11/xorg/overrides.nix</filename>.
</para>
</section>

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<chapter xmlns="http://docbook.org/ns/docbook"
xmlns:xlink="http://www.w3.org/1999/xlink"
xml:id="chap-platform-nodes">
xml:id="chap-platform-notes">
<title>Platform Notes</title>
<section xml:id="sec-darwin">
<title>Darwin (macOS)</title>
<para>
Some common issues when packaging software for darwin:
Some common issues when packaging software for Darwin:
</para>
<itemizedlist>
<listitem>
<para>
The darwin <literal>stdenv</literal> uses clang instead of gcc. When
referring to the compiler <varname>$CC</varname> or <command>cc</command>
will work in both cases. Some builds hardcode gcc/g++ in their build
scripts, that can usually be fixed with using something like
<literal>makeFlags = [ "CC=cc" ];</literal> or by patching the build
scripts.
The Darwin <literal>stdenv</literal> uses clang instead of gcc. When referring to the compiler <varname>$CC</varname> or <command>cc</command> will work in both cases. Some builds hardcode gcc/g++ in their build scripts, that can usually be fixed with using something like <literal>makeFlags = [ "CC=cc" ];</literal> or by patching the build scripts.
</para>
<programlisting>
stdenv.mkDerivation {
name = "libfoo-1.2.3";
# ...
buildPhase = ''
$CC -o hello hello.c
'';
}
</programlisting>
stdenv.mkDerivation {
name = "libfoo-1.2.3";
# ...
buildPhase = ''
$CC -o hello hello.c
'';
}
</programlisting>
</listitem>
<listitem>
<para>
On darwin libraries are linked using absolute paths, libraries are
resolved by their <literal>install_name</literal> at link time. Sometimes
packages won't set this correctly causing the library lookups to fail at
runtime. This can be fixed by adding extra linker flags or by running
<command>install_name_tool -id</command> during the
<function>fixupPhase</function>.
On Darwin, libraries are linked using absolute paths, libraries are resolved by their <literal>install_name</literal> at link time. Sometimes packages won't set this correctly causing the library lookups to fail at runtime. This can be fixed by adding extra linker flags or by running <command>install_name_tool -id</command> during the <function>fixupPhase</function>.
</para>
<programlisting>
stdenv.mkDerivation {
name = "libfoo-1.2.3";
# ...
makeFlags = stdenv.lib.optional stdenv.isDarwin "LDFLAGS=-Wl,-install_name,$(out)/lib/libfoo.dylib";
}
</programlisting>
stdenv.mkDerivation {
name = "libfoo-1.2.3";
# ...
makeFlags = stdenv.lib.optional stdenv.isDarwin "LDFLAGS=-Wl,-install_name,$(out)/lib/libfoo.dylib";
}
</programlisting>
</listitem>
<listitem>
<para>
Even if the libraries are linked using absolute paths and resolved via
their <literal>install_name</literal> correctly, tests can sometimes fail
to run binaries. This happens because the <varname>checkPhase</varname>
runs before the libraries are installed.
Even if the libraries are linked using absolute paths and resolved via their <literal>install_name</literal> correctly, tests can sometimes fail to run binaries. This happens because the <varname>checkPhase</varname> runs before the libraries are installed.
</para>
<para>
This can usually be solved by running the tests after the
<varname>installPhase</varname> or alternatively by using
<varname>DYLD_LIBRARY_PATH</varname>. More information about this variable
can be found in the <citerefentry>
This can usually be solved by running the tests after the <varname>installPhase</varname> or alternatively by using <varname>DYLD_LIBRARY_PATH</varname>. More information about this variable can be found in the <citerefentry>
<refentrytitle>dyld</refentrytitle>
<manvolnum>1</manvolnum></citerefentry> manpage.
</para>
<programlisting>
dyld: Library not loaded: /nix/store/7hnmbscpayxzxrixrgxvvlifzlxdsdir-jq-1.5-lib/lib/libjq.1.dylib
Referenced from: /private/tmp/nix-build-jq-1.5.drv-0/jq-1.5/tests/../jq
Reason: image not found
./tests/jqtest: line 5: 75779 Abort trap: 6
</programlisting>
dyld: Library not loaded: /nix/store/7hnmbscpayxzxrixrgxvvlifzlxdsdir-jq-1.5-lib/lib/libjq.1.dylib
Referenced from: /private/tmp/nix-build-jq-1.5.drv-0/jq-1.5/tests/../jq
Reason: image not found
./tests/jqtest: line 5: 75779 Abort trap: 6
</programlisting>
<programlisting>
stdenv.mkDerivation {
name = "libfoo-1.2.3";
# ...
doInstallCheck = true;
installCheckTarget = "check";
}
</programlisting>
stdenv.mkDerivation {
name = "libfoo-1.2.3";
# ...
doInstallCheck = true;
installCheckTarget = "check";
}
</programlisting>
</listitem>
<listitem>
<para>
Some packages assume xcode is available and use <command>xcrun</command>
to resolve build tools like <command>clang</command>, etc. This causes
errors like <code>xcode-select: error: no developer tools were found at
'/Applications/Xcode.app'</code> while the build doesn't actually depend
on xcode.
Some packages assume xcode is available and use <command>xcrun</command> to resolve build tools like <command>clang</command>, etc. This causes errors like <code>xcode-select: error: no developer tools were found at '/Applications/Xcode.app'</code> while the build doesn't actually depend on xcode.
</para>
<programlisting>
stdenv.mkDerivation {
name = "libfoo-1.2.3";
# ...
prePatch = ''
substituteInPlace Makefile \
--replace '/usr/bin/xcrun clang' clang
'';
}
</programlisting>
stdenv.mkDerivation {
name = "libfoo-1.2.3";
# ...
prePatch = ''
substituteInPlace Makefile \
--replace '/usr/bin/xcrun clang' clang
'';
}
</programlisting>
<para>
The package <literal>xcbuild</literal> can be used to build projects that
really depend on Xcode, however projects that build some kind of graphical
interface won't work without using Xcode in an impure way.
The package <literal>xcbuild</literal> can be used to build projects that really depend on Xcode. However, this replacement is not 100% compatible with Xcode and can occasionally cause issues.
</para>
</listitem>
</itemizedlist>

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<para>
Checkout the Nixpkgs source tree:
<screen>
$ git clone https://github.com/NixOS/nixpkgs
$ cd nixpkgs</screen>
<prompt>$ </prompt>git clone https://github.com/NixOS/nixpkgs
<prompt>$ </prompt>cd nixpkgs</screen>
</para>
</listitem>
<listitem>
<para>
Find a good place in the Nixpkgs tree to add the Nix expression for your
package. For instance, a library package typically goes into
<filename>pkgs/development/libraries/<replaceable>pkgname</replaceable></filename>,
while a web browser goes into
<filename>pkgs/applications/networking/browsers/<replaceable>pkgname</replaceable></filename>.
See <xref linkend="sec-organisation" /> for some hints on the tree
organisation. Create a directory for your package, e.g.
Find a good place in the Nixpkgs tree to add the Nix expression for your package. For instance, a library package typically goes into <filename>pkgs/development/libraries/<replaceable>pkgname</replaceable></filename>, while a web browser goes into <filename>pkgs/applications/networking/browsers/<replaceable>pkgname</replaceable></filename>. See <xref linkend="sec-organisation" /> for some hints on the tree organisation. Create a directory for your package, e.g.
<screen>
$ mkdir pkgs/development/libraries/libfoo</screen>
<prompt>$ </prompt>mkdir pkgs/development/libraries/libfoo</screen>
</para>
</listitem>
<listitem>
<para>
In the package directory, create a Nix expression — a piece of code that
describes how to build the package. In this case, it should be a
<emphasis>function</emphasis> that is called with the package dependencies
as arguments, and returns a build of the package in the Nix store. The
expression should usually be called <filename>default.nix</filename>.
In the package directory, create a Nix expression — a piece of code that describes how to build the package. In this case, it should be a <emphasis>function</emphasis> that is called with the package dependencies as arguments, and returns a build of the package in the Nix store. The expression should usually be called <filename>default.nix</filename>.
<screen>
$ emacs pkgs/development/libraries/libfoo/default.nix
$ git add pkgs/development/libraries/libfoo/default.nix</screen>
<prompt>$ </prompt>emacs pkgs/development/libraries/libfoo/default.nix
<prompt>$ </prompt>git add pkgs/development/libraries/libfoo/default.nix</screen>
</para>
<para>
You can have a look at the existing Nix expressions under
<filename>pkgs/</filename> to see how its done. Here are some good
ones:
You can have a look at the existing Nix expressions under <filename>pkgs/</filename> to see how its done. Here are some good ones:
<itemizedlist>
<listitem>
<para>
GNU Hello:
<link
xlink:href="https://github.com/NixOS/nixpkgs/blob/master/pkgs/applications/misc/hello/default.nix"><filename>pkgs/applications/misc/hello/default.nix</filename></link>.
Trivial package, which specifies some <varname>meta</varname>
attributes which is good practice.
GNU Hello: <link
xlink:href="https://github.com/NixOS/nixpkgs/blob/master/pkgs/applications/misc/hello/default.nix"><filename>pkgs/applications/misc/hello/default.nix</filename></link>. Trivial package, which specifies some <varname>meta</varname> attributes which is good practice.
</para>
</listitem>
<listitem>
<para>
GNU cpio:
<link
xlink:href="https://github.com/NixOS/nixpkgs/blob/master/pkgs/tools/archivers/cpio/default.nix"><filename>pkgs/tools/archivers/cpio/default.nix</filename></link>.
Also a simple package. The generic builder in <varname>stdenv</varname>
does everything for you. It has no dependencies beyond
<varname>stdenv</varname>.
GNU cpio: <link
xlink:href="https://github.com/NixOS/nixpkgs/blob/master/pkgs/tools/archivers/cpio/default.nix"><filename>pkgs/tools/archivers/cpio/default.nix</filename></link>. Also a simple package. The generic builder in <varname>stdenv</varname> does everything for you. It has no dependencies beyond <varname>stdenv</varname>.
</para>
</listitem>
<listitem>
<para>
GNU Multiple Precision arithmetic library (GMP):
<link
xlink:href="https://github.com/NixOS/nixpkgs/blob/master/pkgs/development/libraries/gmp/5.1.x.nix"><filename>pkgs/development/libraries/gmp/5.1.x.nix</filename></link>.
Also done by the generic builder, but has a dependency on
<varname>m4</varname>.
GNU Multiple Precision arithmetic library (GMP): <link
xlink:href="https://github.com/NixOS/nixpkgs/blob/master/pkgs/development/libraries/gmp/5.1.x.nix"><filename>pkgs/development/libraries/gmp/5.1.x.nix</filename></link>. Also done by the generic builder, but has a dependency on <varname>m4</varname>.
</para>
</listitem>
<listitem>
<para>
Pan, a GTK-based newsreader:
<link
xlink:href="https://github.com/NixOS/nixpkgs/blob/master/pkgs/applications/networking/newsreaders/pan/default.nix"><filename>pkgs/applications/networking/newsreaders/pan/default.nix</filename></link>.
Has an optional dependency on <varname>gtkspell</varname>, which is
only built if <varname>spellCheck</varname> is <literal>true</literal>.
Pan, a GTK-based newsreader: <link
xlink:href="https://github.com/NixOS/nixpkgs/blob/master/pkgs/applications/networking/newsreaders/pan/default.nix"><filename>pkgs/applications/networking/newsreaders/pan/default.nix</filename></link>. Has an optional dependency on <varname>gtkspell</varname>, which is only built if <varname>spellCheck</varname> is <literal>true</literal>.
</para>
</listitem>
<listitem>
<para>
Apache HTTPD:
<link
xlink:href="https://github.com/NixOS/nixpkgs/blob/master/pkgs/servers/http/apache-httpd/2.4.nix"><filename>pkgs/servers/http/apache-httpd/2.4.nix</filename></link>.
A bunch of optional features, variable substitutions in the configure
flags, a post-install hook, and miscellaneous hackery.
Apache HTTPD: <link
xlink:href="https://github.com/NixOS/nixpkgs/blob/master/pkgs/servers/http/apache-httpd/2.4.nix"><filename>pkgs/servers/http/apache-httpd/2.4.nix</filename></link>. A bunch of optional features, variable substitutions in the configure flags, a post-install hook, and miscellaneous hackery.
</para>
</listitem>
<listitem>
<para>
Thunderbird:
<link
xlink:href="https://github.com/NixOS/nixpkgs/blob/master/pkgs/applications/networking/mailreaders/thunderbird/default.nix"><filename>pkgs/applications/networking/mailreaders/thunderbird/default.nix</filename></link>.
Lots of dependencies.
Thunderbird: <link
xlink:href="https://github.com/NixOS/nixpkgs/blob/master/pkgs/applications/networking/mailreaders/thunderbird/default.nix"><filename>pkgs/applications/networking/mailreaders/thunderbird/default.nix</filename></link>. Lots of dependencies.
</para>
</listitem>
<listitem>
<para>
JDiskReport, a Java utility:
<link
xlink:href="https://github.com/NixOS/nixpkgs/blob/master/pkgs/tools/misc/jdiskreport/default.nix"><filename>pkgs/tools/misc/jdiskreport/default.nix</filename></link>
(and the
<link
xlink:href="https://github.com/NixOS/nixpkgs/blob/master/pkgs/tools/misc/jdiskreport/builder.sh">builder</link>).
Nixpkgs doesnt have a decent <varname>stdenv</varname> for Java yet
so this is pretty ad-hoc.
JDiskReport, a Java utility: <link
xlink:href="https://github.com/NixOS/nixpkgs/blob/master/pkgs/tools/misc/jdiskreport/default.nix"><filename>pkgs/tools/misc/jdiskreport/default.nix</filename></link> (and the <link
xlink:href="https://github.com/NixOS/nixpkgs/blob/master/pkgs/tools/misc/jdiskreport/builder.sh">builder</link>). Nixpkgs doesnt have a decent <varname>stdenv</varname> for Java yet so this is pretty ad-hoc.
</para>
</listitem>
<listitem>
<para>
XML::Simple, a Perl module:
<link
xlink:href="https://github.com/NixOS/nixpkgs/blob/master/pkgs/top-level/perl-packages.nix"><filename>pkgs/top-level/perl-packages.nix</filename></link>
(search for the <varname>XMLSimple</varname> attribute). Most Perl
modules are so simple to build that they are defined directly in
<filename>perl-packages.nix</filename>; no need to make a separate file
for them.
XML::Simple, a Perl module: <link
xlink:href="https://github.com/NixOS/nixpkgs/blob/master/pkgs/top-level/perl-packages.nix"><filename>pkgs/top-level/perl-packages.nix</filename></link> (search for the <varname>XMLSimple</varname> attribute). Most Perl modules are so simple to build that they are defined directly in <filename>perl-packages.nix</filename>; no need to make a separate file for them.
</para>
</listitem>
<listitem>
<para>
Adobe Reader:
<link
xlink:href="https://github.com/NixOS/nixpkgs/blob/master/pkgs/applications/misc/adobe-reader/default.nix"><filename>pkgs/applications/misc/adobe-reader/default.nix</filename></link>.
Shows how binary-only packages can be supported. In particular the
<link
xlink:href="https://github.com/NixOS/nixpkgs/blob/master/pkgs/applications/misc/adobe-reader/builder.sh">builder</link>
uses <command>patchelf</command> to set the RUNPATH and ELF interpreter
of the executables so that the right libraries are found at runtime.
Adobe Reader: <link
xlink:href="https://github.com/NixOS/nixpkgs/blob/master/pkgs/applications/misc/adobe-reader/default.nix"><filename>pkgs/applications/misc/adobe-reader/default.nix</filename></link>. Shows how binary-only packages can be supported. In particular the <link
xlink:href="https://github.com/NixOS/nixpkgs/blob/master/pkgs/applications/misc/adobe-reader/builder.sh">builder</link> uses <command>patchelf</command> to set the RUNPATH and ELF interpreter of the executables so that the right libraries are found at runtime.
</para>
</listitem>
</itemizedlist>
@ -138,80 +93,59 @@ $ git add pkgs/development/libraries/libfoo/default.nix</screen>
<itemizedlist>
<listitem>
<para>
All <varname linkend="chap-meta">meta</varname> attributes are
optional, but its still a good idea to provide at least the
<varname>description</varname>, <varname>homepage</varname> and
<varname
All <varname linkend="chap-meta">meta</varname> attributes are optional, but its still a good idea to provide at least the <varname>description</varname>, <varname>homepage</varname> and <varname
linkend="sec-meta-license">license</varname>.
</para>
</listitem>
<listitem>
<para>
You can use <command>nix-prefetch-url</command> (or similar
nix-prefetch-git, etc) <replaceable>url</replaceable> to get the
SHA-256 hash of source distributions. There are similar commands as
<command>nix-prefetch-git</command> and
<command>nix-prefetch-hg</command> available in
<literal>nix-prefetch-scripts</literal> package.
You can use <command>nix-prefetch-url</command> <replaceable>url</replaceable> to get the SHA-256 hash of source distributions. There are similar commands as <command>nix-prefetch-git</command> and <command>nix-prefetch-hg</command> available in <literal>nix-prefetch-scripts</literal> package.
</para>
</listitem>
<listitem>
<para>
A list of schemes for <literal>mirror://</literal> URLs can be found in
<link
A list of schemes for <literal>mirror://</literal> URLs can be found in <link
xlink:href="https://github.com/NixOS/nixpkgs/blob/master/pkgs/build-support/fetchurl/mirrors.nix"><filename>pkgs/build-support/fetchurl/mirrors.nix</filename></link>.
</para>
</listitem>
</itemizedlist>
</para>
<para>
The exact syntax and semantics of the Nix expression language, including
the built-in function, are described in the Nix manual in the
<link
xlink:href="http://hydra.nixos.org/job/nix/trunk/tarball/latest/download-by-type/doc/manual/#chap-writing-nix-expressions">chapter
on writing Nix expressions</link>.
The exact syntax and semantics of the Nix expression language, including the built-in function, are described in the Nix manual in the <link
xlink:href="http://hydra.nixos.org/job/nix/trunk/tarball/latest/download-by-type/doc/manual/#chap-writing-nix-expressions">chapter on writing Nix expressions</link>.
</para>
</listitem>
<listitem>
<para>
Add a call to the function defined in the previous step to
<link
xlink:href="https://github.com/NixOS/nixpkgs/blob/master/pkgs/top-level/all-packages.nix"><filename>pkgs/top-level/all-packages.nix</filename></link>
with some descriptive name for the variable, e.g.
<varname>libfoo</varname>.
Add a call to the function defined in the previous step to <link
xlink:href="https://github.com/NixOS/nixpkgs/blob/master/pkgs/top-level/all-packages.nix"><filename>pkgs/top-level/all-packages.nix</filename></link> with some descriptive name for the variable, e.g. <varname>libfoo</varname>.
<screen>
$ emacs pkgs/top-level/all-packages.nix</screen>
<prompt>$ </prompt>emacs pkgs/top-level/all-packages.nix</screen>
</para>
<para>
The attributes in that file are sorted by category (like “Development /
Libraries”) that more-or-less correspond to the directory structure of
Nixpkgs, and then by attribute name.
The attributes in that file are sorted by category (like “Development / Libraries”) that more-or-less correspond to the directory structure of Nixpkgs, and then by attribute name.
</para>
</listitem>
<listitem>
<para>
To test whether the package builds, run the following command from the
root of the nixpkgs source tree:
To test whether the package builds, run the following command from the root of the nixpkgs source tree:
<screen>
$ nix-build -A libfoo</screen>
where <varname>libfoo</varname> should be the variable name defined in the
previous step. You may want to add the flag <option>-K</option> to keep
the temporary build directory in case something fails. If the build
succeeds, a symlink <filename>./result</filename> to the package in the
Nix store is created.
<prompt>$ </prompt>nix-build -A libfoo</screen>
where <varname>libfoo</varname> should be the variable name defined in the previous step. You may want to add the flag <option>-K</option> to keep the temporary build directory in case something fails. If the build succeeds, a symlink <filename>./result</filename> to the package in the Nix store is created.
</para>
</listitem>
<listitem>
<para>
If you want to install the package into your profile (optional), do
<screen>
$ nix-env -f . -iA libfoo</screen>
<prompt>$ </prompt>nix-env -f . -iA libfoo</screen>
</para>
</listitem>
<listitem>
<para>
Optionally commit the new package and open a pull request, or send a patch
to <literal>https://groups.google.com/forum/#!forum/nix-devel</literal>.
Optionally commit the new package and open a pull request <link
xlink:href="https://github.com/NixOS/nixpkgs/pulls">to nixpkgs</link>, or use <link
xlink:href="https://discourse.nixos.org/t/about-the-patches-category/477"> the Patches category</link> on Discourse for sending a patch without a GitHub account.
</para>
</listitem>
</orderedlist>

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