drgn/libdrgn/memory_reader.c
Omar Sandoval c8406e1ea0 libdrgn: require semicolon after DEFINE_{HASH,VECTOR,BINARY_SEARCH_TREE}*
The lack of a semicolon after these macros has always confused tooling
like cscope. We could add semicolons everywhere now, but let's enforce
it for the future, too. Let's add a dummy struct forward declaration at
the end of each macro that enforces this requirement and also provides a
useful error message.

Signed-off-by: Omar Sandoval <osandov@osandov.com>
2023-08-02 14:54:59 -07:00

315 lines
8.8 KiB
C

// Copyright (c) Meta Platforms, Inc. and affiliates.
// SPDX-License-Identifier: LGPL-2.1-or-later
#include <assert.h>
#include <errno.h>
#include <stdlib.h>
#include <string.h>
#include <unistd.h>
#include "memory_reader.h"
#include "minmax.h"
/** Memory segment in a @ref drgn_memory_reader. */
struct drgn_memory_segment {
struct binary_tree_node node;
/** Address range of the segment in memory (inclusive). */
uint64_t min_address, max_address;
/**
* The address of the segment when it was added, before any truncations.
*
* This is always less than or equal to @ref
* drgn_memory_segment::min_address.
*/
uint64_t orig_min_address;
/** Read callback. */
drgn_memory_read_fn read_fn;
/** Argument to pass to @ref drgn_memory_segment::read_fn. */
void *arg;
};
static inline uint64_t
drgn_memory_segment_to_key(const struct drgn_memory_segment *entry)
{
return entry->min_address;
}
DEFINE_BINARY_SEARCH_TREE_FUNCTIONS(drgn_memory_segment_tree, node,
drgn_memory_segment_to_key,
binary_search_tree_scalar_cmp, splay);
void drgn_memory_reader_init(struct drgn_memory_reader *reader)
{
drgn_memory_segment_tree_init(&reader->virtual_segments);
drgn_memory_segment_tree_init(&reader->physical_segments);
}
static void free_memory_segment_tree(struct drgn_memory_segment_tree *tree)
{
struct drgn_memory_segment_tree_iterator it;
it = drgn_memory_segment_tree_first_post_order(tree);
while (it.entry) {
struct drgn_memory_segment *entry = it.entry;
it = drgn_memory_segment_tree_next_post_order(it);
free(entry);
}
}
void drgn_memory_reader_deinit(struct drgn_memory_reader *reader)
{
free_memory_segment_tree(&reader->physical_segments);
free_memory_segment_tree(&reader->virtual_segments);
}
bool drgn_memory_reader_empty(struct drgn_memory_reader *reader)
{
return (drgn_memory_segment_tree_empty(&reader->virtual_segments) &&
drgn_memory_segment_tree_empty(&reader->physical_segments));
}
struct drgn_error *
drgn_memory_reader_add_segment(struct drgn_memory_reader *reader,
uint64_t min_address, uint64_t max_address,
drgn_memory_read_fn read_fn, void *arg,
bool physical)
{
assert(min_address <= max_address);
struct drgn_memory_segment_tree *tree = (physical ?
&reader->physical_segments :
&reader->virtual_segments);
/*
* This is split into two steps: the first step handles an overlapping
* segment with address <= new address, and the second step handles
* overlapping segments with address > new address. In some cases, we
* can steal an existing segment instead of allocating a new one.
*/
struct drgn_memory_segment *stolen = NULL, *segment;
struct drgn_memory_segment *truncate_head = NULL, *truncate_tail = NULL;
struct drgn_memory_segment_tree_iterator it =
drgn_memory_segment_tree_search_le(tree, &min_address);
if (it.entry) {
if (max_address < it.entry->max_address) {
/*
* The new segment lies entirely within an existing
* segment, and part of the existing segment extends
* after the new segment (a "tail").
*/
struct drgn_memory_segment *tail =
malloc(sizeof(*tail));
if (!tail)
return &drgn_enomem;
if (it.entry->min_address == min_address) {
/*
* The new segment starts at the same address as
* the existing segment, so we can steal the
* existing segment and just add the tail.
*/
stolen = segment = it.entry;
} else {
/*
* Part of the existing segment extends before
* the new segment. We have to create the new
* segment and truncate the existing segment.
*/
segment = malloc(sizeof(*segment));
if (!segment) {
free(tail);
return &drgn_enomem;
}
truncate_tail = it.entry;
}
tail->min_address = max_address + 1;
tail->max_address = it.entry->max_address;
tail->orig_min_address = it.entry->orig_min_address;
tail->read_fn = it.entry->read_fn;
tail->arg = it.entry->arg;
drgn_memory_segment_tree_insert(tree, tail, NULL);
goto insert;
}
if (it.entry->min_address == min_address) {
/*
* The new segment subsumes an existing segment at the
* same address. We can steal the existing segment.
*/
stolen = it.entry;
} else if (min_address <= it.entry->max_address) {
/*
* The new segment overlaps an existing segment before
* it, and part of the existing segment extends before
* the new segment. We need to truncate the existing
* segment.
*/
truncate_tail = it.entry;
} else {
/*
* The new segment does not overlap any existing
* segments before it.
*/
}
it = drgn_memory_segment_tree_next(it);
} else {
/* The new segment will be the new first segment. */
it = drgn_memory_segment_tree_first(tree);
}
while (it.entry) {
if (max_address >= it.entry->max_address) {
/*
* The new segment subsumes an existing segment after
* it.
*/
if (stolen) {
/*
* We already stole a segment. We can delete the
* existing segment. Since we won't try to
* allocate a new segment later, it's safe to
* modify the tree now.
*/
struct drgn_memory_segment *existing_segment = it.entry;
it = drgn_memory_segment_tree_delete_iterator(tree, it);
free(existing_segment);
} else {
/*
* We haven't stolen a segment yet, so steal
* this one.
*
* This segment is the first existing segment
* that starts after the new segment, and the
* previous existing segment must start before
* the new segment (otherwise we would've stolen
* it). Therefore, this won't disturb the tree
* order.
*/
stolen = it.entry;
it = drgn_memory_segment_tree_next(it);
}
continue;
}
if (max_address >= it.entry->min_address) {
/*
* The new segment overlaps an existing segment after
* it, and part of the existing segment extends after
* the new segment. We need to truncate the beginning of
* the existing segment.
*/
truncate_head = it.entry;
}
/*
* The existing segment ends after the new segment ends. We're
* done.
*/
break;
}
if (stolen) {
segment = stolen;
} else {
segment = malloc(sizeof(*segment));
if (!segment)
return &drgn_enomem;
}
insert:
/*
* Now that we've allocated the new segment if necessary, we can safely
* modify the tree.
*/
if (truncate_head)
truncate_head->min_address = max_address + 1;
if (truncate_tail)
truncate_tail->max_address = min_address - 1;
segment->min_address = segment->orig_min_address = min_address;
segment->max_address = max_address;
segment->read_fn = read_fn;
segment->arg = arg;
/* If the segment is stolen, then it's already in the tree. */
if (!stolen)
drgn_memory_segment_tree_insert(tree, segment, NULL);
return NULL;
}
struct drgn_error *drgn_memory_reader_read(struct drgn_memory_reader *reader,
void *buf, uint64_t address,
size_t count, bool physical)
{
assert(count == 0 || count - 1 <= UINT64_MAX - address);
struct drgn_error *err;
struct drgn_memory_segment_tree *tree = (physical ?
&reader->physical_segments :
&reader->virtual_segments);
char *p = buf;
while (count > 0) {
struct drgn_memory_segment *segment =
drgn_memory_segment_tree_search_le(tree,
&address).entry;
if (!segment || segment->max_address < address) {
return drgn_error_create_fault("could not find memory segment",
address);
}
size_t n = min((uint64_t)(count - 1),
segment->max_address - address) + 1;
err = segment->read_fn(p, address, n,
address - segment->orig_min_address,
segment->arg, physical);
if (err)
return err;
p += n;
address += n;
count -= n;
}
return NULL;
}
struct drgn_error *drgn_read_memory_file(void *buf, uint64_t address,
size_t count, uint64_t offset,
void *arg, bool physical)
{
struct drgn_memory_file_segment *file_segment = arg;
size_t file_count;
if (offset < file_segment->file_size) {
file_count = min((uint64_t)count,
file_segment->file_size - offset);
} else {
file_count = 0;
}
size_t zero_count = count - file_count;
if (!file_segment->zerofill && zero_count > 0) {
return drgn_error_create_fault("memory not saved in core dump",
address + file_count);
}
uint64_t file_offset = file_segment->file_offset + offset;
char *p = buf;
while (file_count) {
ssize_t ret = pread(file_segment->fd, p, file_count, file_offset);
if (ret == -1) {
if (errno == EINTR) {
continue;
} else if (errno == EIO && file_segment->eio_is_fault) {
return drgn_error_create_fault("could not read memory",
address);
} else {
return drgn_error_create_os("pread", errno, NULL);
}
} else if (ret == 0) {
return drgn_error_create_fault("short read from memory file",
address);
}
p += ret;
address += ret;
file_count -= ret;
file_offset += ret;
}
memset(p, '\0', zero_count);
return NULL;
}