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302 lines
11 KiB
302 lines
11 KiB
// Copyright 2018 The go-ethereum Authors
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// This file is part of the go-ethereum library.
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//
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// The go-ethereum library is free software: you can redistribute it and/or modify
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// it under the terms of the GNU Lesser General Public License as published by
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// the Free Software Foundation, either version 3 of the License, or
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// (at your option) any later version.
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//
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// The go-ethereum library is distributed in the hope that it will be useful,
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// but WITHOUT ANY WARRANTY; without even the implied warranty of
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// MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
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// GNU Lesser General Public License for more details.
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//
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// You should have received a copy of the GNU Lesser General Public License
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// along with the go-ethereum library. If not, see <http://www.gnu.org/licenses/>.
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/*
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Counting number of items in garbage collection index
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The number of items in garbage collection index is not the same as the number of
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chunks in retrieval index (total number of stored chunks). Chunk can be garbage
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collected only when it is set to a synced state by ModSetSync, and only then can
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be counted into garbage collection size, which determines whether a number of
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chunk should be removed from the storage by the garbage collection. This opens a
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possibility that the storage size exceeds the limit if files are locally
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uploaded and the node is not connected to other nodes or there is a problem with
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syncing.
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Tracking of garbage collection size (gcSize) is focused on performance. Key
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points:
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1. counting the number of key/value pairs in LevelDB takes around 0.7s for 1e6
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on a very fast ssd (unacceptable long time in reality)
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2. locking leveldb batch writes with a global mutex (serial batch writes) is
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not acceptable, we should use locking per chunk address
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Because of point 1. we cannot count the number of items in garbage collection
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index in New constructor as it could last very long for realistic scenarios
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where limit is 5e6 and nodes are running on slower hdd disks or cloud providers
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with low IOPS.
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Point 2. is a performance optimization to allow parallel batch writes with
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getters, putters and setters. Every single batch that they create contain only
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information related to a single chunk, no relations with other chunks or shared
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statistical data (like gcSize). This approach avoids race conditions on writing
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batches in parallel, but creates a problem of synchronizing statistical data
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values like gcSize. With global mutex lock, any data could be written by any
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batch, but would not use utilize the full potential of leveldb parallel writes.
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To mitigate this two problems, the implementation of counting and persisting
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gcSize is split into two parts. One is the in-memory value (gcSize) that is fast
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to read and write with a dedicated mutex (gcSizeMu) if the batch which adds or
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removes items from garbage collection index is successful. The second part is
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the reliable persistence of this value to leveldb database, as storedGCSize
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field. This database field is saved by writeGCSizeWorker and writeGCSize
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functions when in-memory gcSize variable is changed, but no too often to avoid
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very frequent database writes. This database writes are triggered by
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writeGCSizeTrigger when a call is made to function incGCSize. Trigger ensures
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that no database writes are done only when gcSize is changed (contrary to a
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simpler periodic writes or checks). A backoff of 10s in writeGCSizeWorker
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ensures that no frequent batch writes are made. Saving the storedGCSize on
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database Close function ensures that in-memory gcSize is persisted when database
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is closed.
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This persistence must be resilient to failures like panics. For this purpose, a
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collection of hashes that are added to the garbage collection index, but still
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not persisted to storedGCSize, must be tracked to count them in when DB is
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constructed again with New function after the failure (swarm node restarts). On
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every batch write that adds a new item to garbage collection index, the same
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hash is added to gcUncountedHashesIndex. This ensures that there is a persisted
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information which hashes were added to the garbage collection index. But, when
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the storedGCSize is saved by writeGCSize function, this values are removed in
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the same batch in which storedGCSize is changed to ensure consistency. When the
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panic happen, or database Close method is not saved. The database storage
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contains all information to reliably and efficiently get the correct number of
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items in garbage collection index. This is performed in the New function when
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all hashes in gcUncountedHashesIndex are counted, added to the storedGCSize and
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saved to the disk before the database is constructed again. Index
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gcUncountedHashesIndex is acting as dirty bit for recovery that provides
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information what needs to be corrected. With a simple dirty bit, the whole
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garbage collection index should me counted on recovery instead only the items in
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gcUncountedHashesIndex. Because of the triggering mechanizm of writeGCSizeWorker
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and relatively short backoff time, the number of hashes in
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gcUncountedHashesIndex should be low and it should take a very short time to
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recover from the previous failure. If there was no failure and
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gcUncountedHashesIndex is empty, which is the usual case, New function will take
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the minimal time to return.
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*/
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package localstore
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import (
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"time"
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"github.com/ethereum/go-ethereum/log"
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"github.com/ethereum/go-ethereum/swarm/shed"
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"github.com/syndtr/goleveldb/leveldb"
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)
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var (
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// gcTargetRatio defines the target number of items
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// in garbage collection index that will not be removed
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// on garbage collection. The target number of items
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// is calculated by gcTarget function. This value must be
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// in range (0,1]. For example, with 0.9 value,
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// garbage collection will leave 90% of defined capacity
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// in database after its run. This prevents frequent
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// garbage collection runs.
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gcTargetRatio = 0.9
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// gcBatchSize limits the number of chunks in a single
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// leveldb batch on garbage collection.
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gcBatchSize int64 = 1000
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)
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// collectGarbageWorker is a long running function that waits for
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// collectGarbageTrigger channel to signal a garbage collection
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// run. GC run iterates on gcIndex and removes older items
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// form retrieval and other indexes.
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func (db *DB) collectGarbageWorker() {
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for {
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select {
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case <-db.collectGarbageTrigger:
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// run a single collect garbage run and
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// if done is false, gcBatchSize is reached and
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// another collect garbage run is needed
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collectedCount, done, err := db.collectGarbage()
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if err != nil {
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log.Error("localstore collect garbage", "err", err)
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}
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// check if another gc run is needed
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if !done {
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db.triggerGarbageCollection()
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}
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if testHookCollectGarbage != nil {
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testHookCollectGarbage(collectedCount)
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}
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case <-db.close:
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return
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}
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}
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}
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// collectGarbage removes chunks from retrieval and other
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// indexes if maximal number of chunks in database is reached.
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// This function returns the number of removed chunks. If done
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// is false, another call to this function is needed to collect
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// the rest of the garbage as the batch size limit is reached.
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// This function is called in collectGarbageWorker.
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func (db *DB) collectGarbage() (collectedCount int64, done bool, err error) {
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batch := new(leveldb.Batch)
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target := db.gcTarget()
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done = true
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err = db.gcIndex.Iterate(func(item shed.Item) (stop bool, err error) {
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// protect parallel updates
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unlock, err := db.lockAddr(item.Address)
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if err != nil {
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return false, err
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}
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defer unlock()
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gcSize := db.getGCSize()
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if gcSize-collectedCount <= target {
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return true, nil
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}
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// delete from retrieve, pull, gc
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db.retrievalDataIndex.DeleteInBatch(batch, item)
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db.retrievalAccessIndex.DeleteInBatch(batch, item)
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db.pullIndex.DeleteInBatch(batch, item)
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db.gcIndex.DeleteInBatch(batch, item)
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collectedCount++
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if collectedCount >= gcBatchSize {
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// bach size limit reached,
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// another gc run is needed
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done = false
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return true, nil
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}
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return false, nil
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}, nil)
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if err != nil {
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return 0, false, err
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}
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err = db.shed.WriteBatch(batch)
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if err != nil {
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return 0, false, err
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}
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// batch is written, decrement gcSize
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db.incGCSize(-collectedCount)
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return collectedCount, done, nil
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}
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// gcTrigger retruns the absolute value for garbage collection
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// target value, calculated from db.capacity and gcTargetRatio.
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func (db *DB) gcTarget() (target int64) {
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return int64(float64(db.capacity) * gcTargetRatio)
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}
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// incGCSize increments gcSize by the provided number.
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// If count is negative, it will decrement gcSize.
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func (db *DB) incGCSize(count int64) {
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if count == 0 {
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return
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}
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db.gcSizeMu.Lock()
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new := db.gcSize + count
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db.gcSize = new
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db.gcSizeMu.Unlock()
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select {
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case db.writeGCSizeTrigger <- struct{}{}:
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default:
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}
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if new >= db.capacity {
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db.triggerGarbageCollection()
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}
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}
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// getGCSize returns gcSize value by locking it
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// with gcSizeMu mutex.
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func (db *DB) getGCSize() (count int64) {
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db.gcSizeMu.RLock()
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count = db.gcSize
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db.gcSizeMu.RUnlock()
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return count
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}
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// triggerGarbageCollection signals collectGarbageWorker
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// to call collectGarbage.
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func (db *DB) triggerGarbageCollection() {
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select {
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case db.collectGarbageTrigger <- struct{}{}:
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case <-db.close:
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default:
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}
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}
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// writeGCSizeWorker writes gcSize on trigger event
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// and waits writeGCSizeDelay after each write.
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// It implements a linear backoff with delay of
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// writeGCSizeDelay duration to avoid very frequent
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// database operations.
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func (db *DB) writeGCSizeWorker() {
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for {
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select {
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case <-db.writeGCSizeTrigger:
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err := db.writeGCSize(db.getGCSize())
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if err != nil {
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log.Error("localstore write gc size", "err", err)
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}
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// Wait some time before writing gc size in the next
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// iteration. This prevents frequent I/O operations.
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select {
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case <-time.After(10 * time.Second):
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case <-db.close:
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return
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}
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case <-db.close:
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return
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}
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}
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}
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// writeGCSize stores the number of items in gcIndex.
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// It removes all hashes from gcUncountedHashesIndex
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// not to include them on the next DB initialization
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// (New function) when gcSize is counted.
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func (db *DB) writeGCSize(gcSize int64) (err error) {
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const maxBatchSize = 1000
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batch := new(leveldb.Batch)
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db.storedGCSize.PutInBatch(batch, uint64(gcSize))
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batchSize := 1
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// use only one iterator as it acquires its snapshot
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// not to remove hashes from index that are added
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// after stored gc size is written
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err = db.gcUncountedHashesIndex.Iterate(func(item shed.Item) (stop bool, err error) {
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db.gcUncountedHashesIndex.DeleteInBatch(batch, item)
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batchSize++
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if batchSize >= maxBatchSize {
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err = db.shed.WriteBatch(batch)
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if err != nil {
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return false, err
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}
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batch.Reset()
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batchSize = 0
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}
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return false, nil
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}, nil)
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if err != nil {
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return err
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}
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return db.shed.WriteBatch(batch)
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}
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// testHookCollectGarbage is a hook that can provide
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// information when a garbage collection run is done
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// and how many items it removed.
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var testHookCollectGarbage func(collectedCount int64)
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