storj/satellite/satellitedb/orders.go

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// Copyright (C) 2019 Storj Labs, Inc.
// See LICENSE for copying information.
package satellitedb
import (
"context"
"database/sql"
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"time"
"github.com/lib/pq"
"github.com/skyrings/skyring-common/tools/uuid"
"github.com/zeebo/errs"
"go.uber.org/zap"
"storj.io/common/pb"
"storj.io/common/storj"
"storj.io/storj/private/dbutil"
"storj.io/storj/private/dbutil/pgutil"
"storj.io/storj/satellite/orders"
"storj.io/storj/satellite/satellitedb/dbx"
)
const defaultIntervalSeconds = int(time.Hour / time.Second)
var (
// ErrDifferentStorageNodes is returned when ProcessOrders gets orders from different storage nodes.
ErrDifferentStorageNodes = errs.Class("different storage nodes")
)
type ordersDB struct {
satellite/satellitedb: unexport satellitedb.DB Backstory: I needed a better way to pass around information about the underlying driver and implementation to all the various db-using things in satellitedb (at least until some new "cockroach driver" support makes it to DBX). After hitting a few dead ends, I decided I wanted to have a type that could act like a *dbx.DB but which would also carry information about the implementation, etc. Then I could pass around that type to all the things in satellitedb that previously wanted *dbx.DB. But then I realized that *satellitedb.DB was, essentially, exactly that already. One thing that might have kept *satellitedb.DB from being directly usable was that embedding a *dbx.DB inside it would make a lot of dbx methods publicly available on a *satellitedb.DB instance that previously were nicely encapsulated and hidden. But after a quick look, I realized that _nothing_ outside of satellite/satellitedb even needs to use satellitedb.DB at all. It didn't even need to be exported, except for some trivially-replaceable code in migrate_postgres_test.go. And once I made it unexported, any concerns about exposing new methods on it were entirely moot. So I have here changed the exported *satellitedb.DB type into the unexported *satellitedb.satelliteDB type, and I have changed all the places here that wanted raw dbx.DB handles to use this new type instead. Now they can just take a gander at the implementation member on it and know all they need to know about the underlying database. This will make it possible for some other pending code here to differentiate between postgres and cockroach backends. Change-Id: I27af99f8ae23b50782333da5277b553b34634edc
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db *satelliteDB
reportedRollupsReadBatchSize int
}
// CreateSerialInfo creates serial number entry in database.
func (db *ordersDB) CreateSerialInfo(ctx context.Context, serialNumber storj.SerialNumber, bucketID []byte, limitExpiration time.Time) (err error) {
defer mon.Task()(&ctx)(&err)
return db.db.CreateNoReturn_SerialNumber(
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ctx,
dbx.SerialNumber_SerialNumber(serialNumber.Bytes()),
dbx.SerialNumber_BucketId(bucketID),
dbx.SerialNumber_ExpiresAt(limitExpiration.UTC()),
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)
}
// DeleteExpiredSerials deletes all expired serials in serial_number and used_serials table.
func (db *ordersDB) DeleteExpiredSerials(ctx context.Context, now time.Time) (_ int, err error) {
defer mon.Task()(&ctx)(&err)
count, err := db.db.Delete_SerialNumber_By_ExpiresAt_LessOrEqual(ctx, dbx.SerialNumber_ExpiresAt(now.UTC()))
if err != nil {
return 0, err
}
return int(count), nil
}
// DeleteExpiredConsumedSerials deletes all expired serials in the consumed_serials table.
func (db *ordersDB) DeleteExpiredConsumedSerials(ctx context.Context, now time.Time) (_ int, err error) {
defer mon.Task()(&ctx, now)(&err)
count, err := db.db.Delete_ConsumedSerial_By_ExpiresAt_LessOrEqual(ctx, dbx.ConsumedSerial_ExpiresAt(now))
if err != nil {
return 0, err
}
return int(count), nil
}
// UseSerialNumber creates a used serial number entry in database from an
// existing serial number.
// It returns the bucket ID associated to serialNumber.
func (db *ordersDB) UseSerialNumber(ctx context.Context, serialNumber storj.SerialNumber, storageNodeID storj.NodeID) (_ []byte, err error) {
defer mon.Task()(&ctx)(&err)
statement := db.db.Rebind(
`INSERT INTO used_serials (serial_number_id, storage_node_id)
SELECT id, ? FROM serial_numbers WHERE serial_number = ?`,
)
_, err = db.db.ExecContext(ctx, statement, storageNodeID.Bytes(), serialNumber.Bytes())
if err != nil {
if pgutil.IsConstraintError(err) {
return nil, orders.ErrUsingSerialNumber.New("serial number already used")
}
return nil, err
}
dbxSerialNumber, err := db.db.Find_SerialNumber_By_SerialNumber(
ctx,
dbx.SerialNumber_SerialNumber(serialNumber.Bytes()),
)
if err != nil {
return nil, err
}
if dbxSerialNumber == nil {
return nil, orders.ErrUsingSerialNumber.New("serial number not found")
}
return dbxSerialNumber.BucketId, nil
}
// UpdateBucketBandwidthAllocation updates 'allocated' bandwidth for given bucket.
func (db *ordersDB) UpdateBucketBandwidthAllocation(ctx context.Context, projectID uuid.UUID, bucketName []byte, action pb.PieceAction, amount int64, intervalStart time.Time) (err error) {
defer mon.Task()(&ctx)(&err)
statement := db.db.Rebind(
`INSERT INTO bucket_bandwidth_rollups (bucket_name, project_id, interval_start, interval_seconds, action, inline, allocated, settled)
VALUES (?, ?, ?, ?, ?, ?, ?, ?)
ON CONFLICT(bucket_name, project_id, interval_start, action)
DO UPDATE SET allocated = bucket_bandwidth_rollups.allocated + ?`,
)
_, err = db.db.ExecContext(ctx, statement,
bucketName, projectID[:], intervalStart.UTC(), defaultIntervalSeconds, action, 0, uint64(amount), 0, uint64(amount),
)
if err != nil {
return err
}
return nil
}
// UpdateBucketBandwidthSettle updates 'settled' bandwidth for given bucket.
func (db *ordersDB) UpdateBucketBandwidthSettle(ctx context.Context, projectID uuid.UUID, bucketName []byte, action pb.PieceAction, amount int64, intervalStart time.Time) (err error) {
defer mon.Task()(&ctx)(&err)
statement := db.db.Rebind(
`INSERT INTO bucket_bandwidth_rollups (bucket_name, project_id, interval_start, interval_seconds, action, inline, allocated, settled)
VALUES (?, ?, ?, ?, ?, ?, ?, ?)
ON CONFLICT(bucket_name, project_id, interval_start, action)
DO UPDATE SET settled = bucket_bandwidth_rollups.settled + ?`,
)
_, err = db.db.ExecContext(ctx, statement,
bucketName, projectID[:], intervalStart.UTC(), defaultIntervalSeconds, action, 0, 0, uint64(amount), uint64(amount),
)
if err != nil {
return err
}
return nil
}
// UpdateBucketBandwidthInline updates 'inline' bandwidth for given bucket.
func (db *ordersDB) UpdateBucketBandwidthInline(ctx context.Context, projectID uuid.UUID, bucketName []byte, action pb.PieceAction, amount int64, intervalStart time.Time) (err error) {
defer mon.Task()(&ctx)(&err)
statement := db.db.Rebind(
`INSERT INTO bucket_bandwidth_rollups (bucket_name, project_id, interval_start, interval_seconds, action, inline, allocated, settled)
VALUES (?, ?, ?, ?, ?, ?, ?, ?)
ON CONFLICT(bucket_name, project_id, interval_start, action)
DO UPDATE SET inline = bucket_bandwidth_rollups.inline + ?`,
)
_, err = db.db.ExecContext(ctx, statement,
bucketName, projectID[:], intervalStart.UTC(), defaultIntervalSeconds, action, uint64(amount), 0, 0, uint64(amount),
)
if err != nil {
return err
}
return nil
}
// UpdateStoragenodeBandwidthSettle updates 'settled' bandwidth for given storage node for the given intervalStart time.
func (db *ordersDB) UpdateStoragenodeBandwidthSettle(ctx context.Context, storageNode storj.NodeID, action pb.PieceAction, amount int64, intervalStart time.Time) (err error) {
defer mon.Task()(&ctx)(&err)
statement := db.db.Rebind(
`INSERT INTO storagenode_bandwidth_rollups (storagenode_id, interval_start, interval_seconds, action, settled)
VALUES (?, ?, ?, ?, ?)
ON CONFLICT(storagenode_id, interval_start, action)
DO UPDATE SET settled = storagenode_bandwidth_rollups.settled + ?`,
)
_, err = db.db.ExecContext(ctx, statement,
storageNode.Bytes(), intervalStart.UTC(), defaultIntervalSeconds, action, uint64(amount), uint64(amount),
)
if err != nil {
return err
}
return nil
}
// GetBucketBandwidth gets total bucket bandwidth from period of time.
func (db *ordersDB) GetBucketBandwidth(ctx context.Context, projectID uuid.UUID, bucketName []byte, from, to time.Time) (_ int64, err error) {
defer mon.Task()(&ctx)(&err)
var sum *int64
query := `SELECT SUM(settled) FROM bucket_bandwidth_rollups WHERE bucket_name = ? AND project_id = ? AND interval_start > ? AND interval_start <= ?`
err = db.db.QueryRow(ctx, db.db.Rebind(query), bucketName, projectID[:], from.UTC(), to.UTC()).Scan(&sum)
if err == sql.ErrNoRows || sum == nil {
return 0, nil
}
return *sum, Error.Wrap(err)
}
// GetStorageNodeBandwidth gets total storage node bandwidth from period of time.
func (db *ordersDB) GetStorageNodeBandwidth(ctx context.Context, nodeID storj.NodeID, from, to time.Time) (_ int64, err error) {
defer mon.Task()(&ctx)(&err)
var sum *int64
query := `SELECT SUM(settled) FROM storagenode_bandwidth_rollups WHERE storagenode_id = ? AND interval_start > ? AND interval_start <= ?`
err = db.db.QueryRow(ctx, db.db.Rebind(query), nodeID.Bytes(), from.UTC(), to.UTC()).Scan(&sum)
if err == sql.ErrNoRows || sum == nil {
return 0, nil
}
return *sum, err
}
// UnuseSerialNumber removes pair serial number -> storage node id from database.
func (db *ordersDB) UnuseSerialNumber(ctx context.Context, serialNumber storj.SerialNumber, storageNodeID storj.NodeID) (err error) {
defer mon.Task()(&ctx)(&err)
statement := `DELETE FROM used_serials WHERE storage_node_id = ? AND
serial_number_id IN (SELECT id FROM serial_numbers WHERE serial_number = ?)`
_, err = db.db.ExecContext(ctx, db.db.Rebind(statement), storageNodeID.Bytes(), serialNumber.Bytes())
return err
}
// ProcessOrders take a list of order requests and inserts them into the pending serials queue.
//
// ProcessOrders requires that all orders come from the same storage node.
func (db *ordersDB) ProcessOrders(ctx context.Context, requests []*orders.ProcessOrderRequest) (responses []*orders.ProcessOrderResponse, err error) {
defer mon.Task()(&ctx)(&err)
if len(requests) == 0 {
return nil, nil
}
// check that all requests are from the same storage node
storageNodeID := requests[0].OrderLimit.StorageNodeId
for _, req := range requests[1:] {
if req.OrderLimit.StorageNodeId != storageNodeID {
return nil, ErrDifferentStorageNodes.New("requests from different storage nodes %v and %v", storageNodeID, req.OrderLimit.StorageNodeId)
}
}
// Do a read first to get all the project id/bucket ids. We could combine this with the
// upsert below by doing a join, but there isn't really any need for special consistency
// semantics between these two queries, and it should make things easier on the database
// (particularly cockroachDB) to have the freedom to perform them separately.
//
// We don't expect the serial_number -> bucket_id relationship ever to change, as long as a
// serial_number exists. There is a possibility of a serial_number being deleted between
// this query and the next, but that is ok too (rows in reported_serials may end up having
// serial numbers that no longer exist in serial_numbers, but that shouldn't break
// anything.)
bucketIDs, err := func() (bucketIDs [][]byte, err error) {
bucketIDs = make([][]byte, len(requests))
serialNums := make([][]byte, len(requests))
for i, request := range requests {
serialNums[i] = request.Order.SerialNumber.Bytes()
}
rows, err := db.db.QueryContext(ctx, `
SELECT request.i, sn.bucket_id
FROM
serial_numbers sn,
unnest($1::bytea[]) WITH ORDINALITY AS request(serial_number, i)
WHERE request.serial_number = sn.serial_number
`, pq.ByteaArray(serialNums))
if err != nil {
return nil, Error.Wrap(err)
}
defer func() { err = errs.Combine(err, rows.Err(), rows.Close()) }()
for rows.Next() {
var index int
var bucketID []byte
err = rows.Scan(&index, &bucketID)
if err != nil {
return nil, Error.Wrap(err)
}
bucketIDs[index-1] = bucketID
}
return bucketIDs, nil
}()
if err != nil {
return nil, Error.Wrap(err)
}
// perform all of the upserts into reported serials table
expiresAtArray := make([]time.Time, 0, len(requests))
bucketIDArray := make([][]byte, 0, len(requests))
actionArray := make([]pb.PieceAction, 0, len(requests))
serialNumArray := make([][]byte, 0, len(requests))
settledArray := make([]int64, 0, len(requests))
// remove duplicate bucket_id, serial_number pairs sent in the same request.
// postgres will complain.
type requestKey struct {
BucketID string
SerialNumber storj.SerialNumber
}
seenRequests := make(map[requestKey]struct{})
for i, request := range requests {
if bucketIDs[i] == nil {
responses = append(responses, &orders.ProcessOrderResponse{
SerialNumber: request.Order.SerialNumber,
Status: pb.SettlementResponse_REJECTED,
})
continue
}
// Filter duplicate requests and reject them.
key := requestKey{
BucketID: string(bucketIDs[i]),
SerialNumber: request.Order.SerialNumber,
}
if _, seen := seenRequests[key]; seen {
responses = append(responses, &orders.ProcessOrderResponse{
SerialNumber: request.Order.SerialNumber,
Status: pb.SettlementResponse_REJECTED,
})
continue
}
seenRequests[key] = struct{}{}
expiresAtArray = append(expiresAtArray, request.OrderLimit.OrderExpiration)
bucketIDArray = append(bucketIDArray, bucketIDs[i])
actionArray = append(actionArray, request.OrderLimit.Action)
serialNumCopy := request.Order.SerialNumber
serialNumArray = append(serialNumArray, serialNumCopy[:])
settledArray = append(settledArray, request.Order.Amount)
responses = append(responses, &orders.ProcessOrderResponse{
SerialNumber: request.Order.SerialNumber,
Status: pb.SettlementResponse_ACCEPTED,
})
}
var stmt string
switch db.db.implementation {
case dbutil.Postgres:
stmt = `
INSERT INTO pending_serial_queue (
storage_node_id, bucket_id, serial_number, action, settled, expires_at
)
SELECT
$1::bytea,
unnest($2::bytea[]),
unnest($3::bytea[]),
unnest($4::integer[]),
unnest($5::bigint[]),
unnest($6::timestamptz[])
ON CONFLICT ( storage_node_id, bucket_id, serial_number )
DO UPDATE SET
action = EXCLUDED.action,
settled = EXCLUDED.settled,
expires_at = EXCLUDED.expires_at
`
case dbutil.Cockroach:
stmt = `
UPSERT INTO pending_serial_queue (
storage_node_id, bucket_id, serial_number, action, settled, expires_at
)
SELECT
$1::bytea,
unnest($2::bytea[]),
unnest($3::bytea[]),
unnest($4::integer[]),
unnest($5::bigint[]),
unnest($6::timestamptz[])
`
default:
return nil, Error.New("invalid dbType: %v", db.db.driver)
}
_, err = db.db.ExecContext(ctx, stmt,
storageNodeID.Bytes(),
pq.ByteaArray(bucketIDArray),
pq.ByteaArray(serialNumArray),
pq.Array(actionArray),
pq.Array(settledArray),
pq.Array(expiresAtArray),
)
if err != nil {
return nil, Error.Wrap(err)
}
return responses, nil
}
//
// transaction/batch methods
//
type ordersDBTx struct {
tx *dbx.Tx
db *satelliteDB
log *zap.Logger
}
func (db *ordersDB) WithTransaction(ctx context.Context, cb func(ctx context.Context, tx orders.Transaction) error) (err error) {
defer mon.Task()(&ctx)(&err)
return db.db.WithTx(ctx, func(ctx context.Context, tx *dbx.Tx) error {
return cb(ctx, &ordersDBTx{tx: tx, db: db.db, log: db.db.log})
})
}
func (tx *ordersDBTx) UpdateBucketBandwidthBatch(ctx context.Context, intervalStart time.Time, rollups []orders.BucketBandwidthRollup) (err error) {
defer mon.Task()(&ctx)(&err)
if len(rollups) == 0 {
return nil
}
orders.SortBucketBandwidthRollups(rollups)
intervalStart = intervalStart.UTC()
intervalStart = time.Date(intervalStart.Year(), intervalStart.Month(), intervalStart.Day(), intervalStart.Hour(), 0, 0, 0, time.UTC)
var bucketNames [][]byte
var projectIDs [][]byte
var actionSlice []int32
var inlineSlice []int64
var allocatedSlice []int64
var settledSlice []int64
for _, rollup := range rollups {
rollup := rollup
bucketNames = append(bucketNames, []byte(rollup.BucketName))
projectIDs = append(projectIDs, rollup.ProjectID[:])
actionSlice = append(actionSlice, int32(rollup.Action))
inlineSlice = append(inlineSlice, rollup.Inline)
allocatedSlice = append(allocatedSlice, rollup.Allocated)
settledSlice = append(settledSlice, rollup.Settled)
}
_, err = tx.tx.Tx.ExecContext(ctx, `
INSERT INTO bucket_bandwidth_rollups (
bucket_name, project_id,
interval_start, interval_seconds,
action, inline, allocated, settled)
SELECT
unnest($1::bytea[]), unnest($2::bytea[]),
$3, $4,
unnest($5::bigint[]), unnest($6::bigint[]), unnest($7::bigint[]), unnest($8::bigint[])
ON CONFLICT(bucket_name, project_id, interval_start, action)
DO UPDATE SET
allocated = bucket_bandwidth_rollups.allocated + EXCLUDED.allocated,
inline = bucket_bandwidth_rollups.inline + EXCLUDED.inline,
settled = bucket_bandwidth_rollups.settled + EXCLUDED.settled`,
pq.ByteaArray(bucketNames), pq.ByteaArray(projectIDs),
intervalStart, defaultIntervalSeconds,
pq.Array(actionSlice), pq.Array(inlineSlice), pq.Array(allocatedSlice), pq.Array(settledSlice))
if err != nil {
tx.log.Error("Bucket bandwidth rollup batch flush failed.", zap.Error(err))
}
return err
}
func (tx *ordersDBTx) UpdateStoragenodeBandwidthBatch(ctx context.Context, intervalStart time.Time, rollups []orders.StoragenodeBandwidthRollup) (err error) {
defer mon.Task()(&ctx)(&err)
if len(rollups) == 0 {
return nil
}
orders.SortStoragenodeBandwidthRollups(rollups)
var storageNodeIDs []storj.NodeID
var actionSlice []int32
var allocatedSlice []int64
var settledSlice []int64
intervalStart = intervalStart.UTC()
intervalStart = time.Date(intervalStart.Year(), intervalStart.Month(), intervalStart.Day(), intervalStart.Hour(), 0, 0, 0, time.UTC)
for i := range rollups {
rollup := &rollups[i]
storageNodeIDs = append(storageNodeIDs, rollup.NodeID)
actionSlice = append(actionSlice, int32(rollup.Action))
allocatedSlice = append(allocatedSlice, rollup.Allocated)
settledSlice = append(settledSlice, rollup.Settled)
}
_, err = tx.tx.Tx.ExecContext(ctx, `
INSERT INTO storagenode_bandwidth_rollups(
storagenode_id,
interval_start, interval_seconds,
action, allocated, settled)
SELECT
unnest($1::bytea[]),
$2, $3,
unnest($4::bigint[]), unnest($5::bigint[]), unnest($6::bigint[])
ON CONFLICT(storagenode_id, interval_start, action)
DO UPDATE SET
allocated = storagenode_bandwidth_rollups.allocated + EXCLUDED.allocated,
settled = storagenode_bandwidth_rollups.settled + EXCLUDED.settled`,
postgresNodeIDList(storageNodeIDs),
intervalStart, defaultIntervalSeconds,
pq.Array(actionSlice), pq.Array(allocatedSlice), pq.Array(settledSlice))
if err != nil {
tx.log.Error("Storagenode bandwidth rollup batch flush failed.", zap.Error(err))
}
return err
}
// CreateConsumedSerialsBatch creates a batch of consumed serial entries.
func (tx *ordersDBTx) CreateConsumedSerialsBatch(ctx context.Context, consumedSerials []orders.ConsumedSerial) (err error) {
defer mon.Task()(&ctx)(&err)
if len(consumedSerials) == 0 {
return nil
}
var storageNodeIDSlice [][]byte
var serialNumberSlice [][]byte
var expiresAtSlice []time.Time
for _, consumedSerial := range consumedSerials {
consumedSerial := consumedSerial
storageNodeIDSlice = append(storageNodeIDSlice, consumedSerial.NodeID.Bytes())
serialNumberSlice = append(serialNumberSlice, consumedSerial.SerialNumber.Bytes())
expiresAtSlice = append(expiresAtSlice, consumedSerial.ExpiresAt)
}
var stmt string
switch tx.db.implementation {
case dbutil.Postgres:
stmt = `
INSERT INTO consumed_serials (
storage_node_id, serial_number, expires_at
)
SELECT unnest($1::bytea[]), unnest($2::bytea[]), unnest($3::timestamptz[])
ON CONFLICT ( storage_node_id, serial_number ) DO NOTHING
`
case dbutil.Cockroach:
stmt = `
UPSERT INTO consumed_serials (
storage_node_id, serial_number, expires_at
)
SELECT unnest($1::bytea[]), unnest($2::bytea[]), unnest($3::timestamptz[])
`
default:
return Error.New("invalid dbType: %v", tx.db.driver)
}
_, err = tx.tx.Tx.ExecContext(ctx, stmt,
pq.ByteaArray(storageNodeIDSlice),
pq.ByteaArray(serialNumberSlice),
pq.Array(expiresAtSlice),
)
return Error.Wrap(err)
}
func (tx *ordersDBTx) HasConsumedSerial(ctx context.Context, nodeID storj.NodeID, serialNumber storj.SerialNumber) (exists bool, err error) {
defer mon.Task()(&ctx)(&err)
exists, err = tx.tx.Has_ConsumedSerial_By_StorageNodeId_And_SerialNumber(ctx,
dbx.ConsumedSerial_StorageNodeId(nodeID.Bytes()),
dbx.ConsumedSerial_SerialNumber(serialNumber.Bytes()))
return exists, Error.Wrap(err)
}
//
// transaction/batch methods
//
type rawPendingSerial struct {
nodeID []byte
bucketID []byte
serialNumber []byte
}
type ordersDBQueue struct {
db *satelliteDB
log *zap.Logger
produced []rawPendingSerial
}
func (db *ordersDB) WithQueue(ctx context.Context, cb func(ctx context.Context, queue orders.Queue) error) (err error) {
defer mon.Task()(&ctx)(&err)
queue := &ordersDBQueue{
db: db.db,
log: db.db.log,
}
err = cb(ctx, queue)
if err != nil {
return errs.Wrap(err)
}
var nodeIDs, bucketIDs, serialNumbers [][]byte
for _, pending := range queue.produced {
nodeIDs = append(nodeIDs, pending.nodeID)
bucketIDs = append(bucketIDs, pending.bucketID)
serialNumbers = append(serialNumbers, pending.serialNumber)
}
_, err = db.db.ExecContext(ctx, `
DELETE FROM pending_serial_queue WHERE (
storage_node_id, bucket_id, serial_number
) IN (
SELECT
unnest($1::bytea[]),
unnest($2::bytea[]),
unnest($3::bytea[])
)
`,
pq.ByteaArray(nodeIDs),
pq.ByteaArray(bucketIDs),
pq.ByteaArray(serialNumbers))
if err != nil {
return Error.Wrap(err)
}
return nil
}
func (queue *ordersDBQueue) GetPendingSerialsBatch(ctx context.Context, size int) (pendingSerials []orders.PendingSerial, done bool, err error) {
defer mon.Task()(&ctx)(&err)
var cont rawPendingSerial
if len(queue.produced) > 0 {
cont = queue.produced[len(queue.produced)-1]
}
// TODO: this might end up being WORSE on cockroach because it does a hash-join after a
// full scan of the consumed_serials table, but it's massively better on postgres because
// it does an indexed anti-join. hopefully we can get rid of the entire serials system
// before it matters.
rows, err := queue.db.Query(ctx, `
SELECT storage_node_id, bucket_id, serial_number, action, settled, expires_at,
coalesce((
SELECT 1
FROM consumed_serials
WHERE
consumed_serials.storage_node_id = pending_serial_queue.storage_node_id
AND consumed_serials.serial_number = pending_serial_queue.serial_number
), 0) as consumed
FROM pending_serial_queue
WHERE (storage_node_id, bucket_id, serial_number) > ($1, $2, $3)
ORDER BY storage_node_id, bucket_id, serial_number
LIMIT $4
`, cont.nodeID, cont.bucketID, cont.serialNumber, size)
if err != nil {
return nil, false, Error.Wrap(err)
}
defer func() { err = errs.Combine(err, Error.Wrap(rows.Close())) }()
for rows.Next() {
var consumed int
var rawPending rawPendingSerial
var pendingSerial orders.PendingSerial
err := rows.Scan(
&rawPending.nodeID,
&rawPending.bucketID,
&rawPending.serialNumber,
&pendingSerial.Action,
&pendingSerial.Settled,
&pendingSerial.ExpiresAt,
&consumed,
)
if err != nil {
return nil, false, Error.Wrap(err)
}
queue.produced = append(queue.produced, rawPending)
size--
if consumed != 0 {
continue
}
pendingSerial.NodeID, err = storj.NodeIDFromBytes(rawPending.nodeID)
if err != nil {
queue.log.Error("Invalid storage node id in pending serials queue",
zap.Binary("id", rawPending.nodeID),
zap.Error(errs.Wrap(err)))
continue
}
pendingSerial.BucketID = rawPending.bucketID
pendingSerial.SerialNumber, err = storj.SerialNumberFromBytes(rawPending.serialNumber)
if err != nil {
queue.log.Error("Invalid serial number in pending serials queue",
zap.Binary("id", rawPending.serialNumber),
zap.Error(errs.Wrap(err)))
continue
}
pendingSerials = append(pendingSerials, pendingSerial)
}
if err := rows.Err(); err != nil {
return nil, false, Error.Wrap(err)
}
return pendingSerials, size > 0, nil
}