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table_cache.go
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table_cache.go
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// Copyright 2020 The LevelDB-Go and Pebble Authors. All rights reserved. Use
// of this source code is governed by a BSD-style license that can be found in
// the LICENSE file.
package pebble
import (
"bytes"
"context"
"fmt"
"io"
"runtime/debug"
"runtime/pprof"
"sync"
"sync/atomic"
"unsafe"
"github.com/cockroachdb/errors"
"github.com/cockroachdb/pebble/internal/base"
"github.com/cockroachdb/pebble/internal/invariants"
"github.com/cockroachdb/pebble/internal/keyspan"
"github.com/cockroachdb/pebble/internal/manifest"
"github.com/cockroachdb/pebble/internal/private"
"github.com/cockroachdb/pebble/objstorage"
"github.com/cockroachdb/pebble/objstorage/objstorageprovider/objiotracing"
"github.com/cockroachdb/pebble/sstable"
)
var emptyIter = &errorIter{err: nil}
var emptyKeyspanIter = &errorKeyspanIter{err: nil}
// filteredAll is a singleton internalIterator implementation used when an
// sstable does contain point keys, but all the keys are filtered by the active
// PointKeyFilters set in the iterator's IterOptions.
//
// filteredAll implements filteredIter, ensuring the level iterator recognizes
// when it may need to return file boundaries to keep the rangeDelIter open
// during mergingIter operation.
var filteredAll = &filteredAllKeysIter{errorIter: errorIter{err: nil}}
var _ filteredIter = filteredAll
type filteredAllKeysIter struct {
errorIter
}
func (s *filteredAllKeysIter) MaybeFilteredKeys() bool {
return true
}
var tableCacheLabels = pprof.Labels("pebble", "table-cache")
// tableCacheOpts contains the db specific fields
// of a table cache. This is stored in the tableCacheContainer
// along with the table cache.
// NB: It is important to make sure that the fields in this
// struct are read-only. Since the fields here are shared
// by every single tableCacheShard, if non read-only fields
// are updated, we could have unnecessary evictions of those
// fields, and the surrounding fields from the CPU caches.
type tableCacheOpts struct {
// iterCount keeps track of how many iterators are open. It is used to keep
// track of leaked iterators on a per-db level.
iterCount *atomic.Int32
loggerAndTracer LoggerAndTracer
cacheID uint64
objProvider objstorage.Provider
opts sstable.ReaderOptions
filterMetrics *sstable.FilterMetricsTracker
sstStatsCollector *sstable.CategoryStatsCollector
}
// tableCacheContainer contains the table cache and
// fields which are unique to the DB.
type tableCacheContainer struct {
tableCache *TableCache
// dbOpts contains fields relevant to the table cache
// which are unique to each DB.
dbOpts tableCacheOpts
}
// newTableCacheContainer will panic if the underlying cache in the table cache
// doesn't match Options.Cache.
func newTableCacheContainer(
tc *TableCache,
cacheID uint64,
objProvider objstorage.Provider,
opts *Options,
size int,
sstStatsCollector *sstable.CategoryStatsCollector,
) *tableCacheContainer {
// We will release a ref to table cache acquired here when tableCacheContainer.close is called.
if tc != nil {
if tc.cache != opts.Cache {
panic("pebble: underlying cache for the table cache and db are different")
}
tc.Ref()
} else {
// NewTableCache should create a ref to tc which the container should
// drop whenever it is closed.
tc = NewTableCache(opts.Cache, opts.Experimental.TableCacheShards, size)
}
t := &tableCacheContainer{}
t.tableCache = tc
t.dbOpts.loggerAndTracer = opts.LoggerAndTracer
t.dbOpts.cacheID = cacheID
t.dbOpts.objProvider = objProvider
t.dbOpts.opts = opts.MakeReaderOptions()
t.dbOpts.filterMetrics = &sstable.FilterMetricsTracker{}
t.dbOpts.iterCount = new(atomic.Int32)
t.dbOpts.sstStatsCollector = sstStatsCollector
return t
}
// Before calling close, make sure that there will be no further need
// to access any of the files associated with the store.
func (c *tableCacheContainer) close() error {
// We want to do some cleanup work here. Check for leaked iterators
// by the DB using this container. Note that we'll still perform cleanup
// below in the case that there are leaked iterators.
var err error
if v := c.dbOpts.iterCount.Load(); v > 0 {
err = errors.Errorf("leaked iterators: %d", errors.Safe(v))
}
// Release nodes here.
for _, shard := range c.tableCache.shards {
if shard != nil {
shard.removeDB(&c.dbOpts)
}
}
return firstError(err, c.tableCache.Unref())
}
func (c *tableCacheContainer) newIters(
ctx context.Context,
file *manifest.FileMetadata,
opts *IterOptions,
internalOpts internalIterOpts,
) (internalIterator, keyspan.FragmentIterator, error) {
return c.tableCache.getShard(file.FileBacking.DiskFileNum).newIters(ctx, file, opts, internalOpts, &c.dbOpts)
}
func (c *tableCacheContainer) newRangeKeyIter(
file *manifest.FileMetadata, opts keyspan.SpanIterOptions,
) (keyspan.FragmentIterator, error) {
return c.tableCache.getShard(file.FileBacking.DiskFileNum).newRangeKeyIter(file, opts, &c.dbOpts)
}
// getTableProperties returns the properties associated with the backing physical
// table if the input metadata belongs to a virtual sstable.
func (c *tableCacheContainer) getTableProperties(file *fileMetadata) (*sstable.Properties, error) {
return c.tableCache.getShard(file.FileBacking.DiskFileNum).getTableProperties(file, &c.dbOpts)
}
func (c *tableCacheContainer) evict(fileNum base.DiskFileNum) {
c.tableCache.getShard(fileNum).evict(fileNum, &c.dbOpts, false)
}
func (c *tableCacheContainer) metrics() (CacheMetrics, FilterMetrics) {
var m CacheMetrics
for i := range c.tableCache.shards {
s := c.tableCache.shards[i]
s.mu.RLock()
m.Count += int64(len(s.mu.nodes))
s.mu.RUnlock()
m.Hits += s.hits.Load()
m.Misses += s.misses.Load()
}
m.Size = m.Count * int64(unsafe.Sizeof(sstable.Reader{}))
f := c.dbOpts.filterMetrics.Load()
return m, f
}
func (c *tableCacheContainer) estimateSize(
meta *fileMetadata, lower, upper []byte,
) (size uint64, err error) {
if meta.Virtual {
err = c.withVirtualReader(
meta.VirtualMeta(),
func(r sstable.VirtualReader) (err error) {
size, err = r.EstimateDiskUsage(lower, upper)
return err
},
)
} else {
err = c.withReader(
meta.PhysicalMeta(),
func(r *sstable.Reader) (err error) {
size, err = r.EstimateDiskUsage(lower, upper)
return err
},
)
}
if err != nil {
return 0, err
}
return size, nil
}
// createCommonReader creates a Reader for this file. isForeign, if true for
// virtual sstables, is passed into the vSSTable reader so its iterators can
// collapse obsolete points accordingly.
func createCommonReader(
v *tableCacheValue, file *fileMetadata, isForeign bool,
) sstable.CommonReader {
// TODO(bananabrick): We suffer an allocation if file is a virtual sstable.
var cr sstable.CommonReader = v.reader
if file.Virtual {
virtualReader := sstable.MakeVirtualReader(
v.reader, file.VirtualMeta(), isForeign,
)
cr = &virtualReader
}
return cr
}
func (c *tableCacheContainer) withCommonReader(
meta *fileMetadata, fn func(sstable.CommonReader) error,
) error {
s := c.tableCache.getShard(meta.FileBacking.DiskFileNum)
v := s.findNode(meta, &c.dbOpts)
defer s.unrefValue(v)
if v.err != nil {
return v.err
}
provider := c.dbOpts.objProvider
objMeta, err := provider.Lookup(fileTypeTable, meta.FileBacking.DiskFileNum)
if err != nil {
return err
}
return fn(createCommonReader(v, meta, provider.IsSharedForeign(objMeta)))
}
func (c *tableCacheContainer) withReader(meta physicalMeta, fn func(*sstable.Reader) error) error {
s := c.tableCache.getShard(meta.FileBacking.DiskFileNum)
v := s.findNode(meta.FileMetadata, &c.dbOpts)
defer s.unrefValue(v)
if v.err != nil {
return v.err
}
return fn(v.reader)
}
// withVirtualReader fetches a VirtualReader associated with a virtual sstable.
func (c *tableCacheContainer) withVirtualReader(
meta virtualMeta, fn func(sstable.VirtualReader) error,
) error {
s := c.tableCache.getShard(meta.FileBacking.DiskFileNum)
v := s.findNode(meta.FileMetadata, &c.dbOpts)
defer s.unrefValue(v)
if v.err != nil {
return v.err
}
provider := c.dbOpts.objProvider
objMeta, err := provider.Lookup(fileTypeTable, meta.FileBacking.DiskFileNum)
if err != nil {
return err
}
return fn(sstable.MakeVirtualReader(v.reader, meta, provider.IsSharedForeign(objMeta)))
}
func (c *tableCacheContainer) iterCount() int64 {
return int64(c.dbOpts.iterCount.Load())
}
// TableCache is a shareable cache for open sstables.
type TableCache struct {
refs atomic.Int64
cache *Cache
shards []*tableCacheShard
}
// Ref adds a reference to the table cache. Once tableCache.init returns,
// the table cache only remains valid if there is at least one reference
// to it.
func (c *TableCache) Ref() {
v := c.refs.Add(1)
// We don't want the reference count to ever go from 0 -> 1,
// cause a reference count of 0 implies that we've closed the cache.
if v <= 1 {
panic(fmt.Sprintf("pebble: inconsistent reference count: %d", v))
}
}
// Unref removes a reference to the table cache.
func (c *TableCache) Unref() error {
v := c.refs.Add(-1)
switch {
case v < 0:
panic(fmt.Sprintf("pebble: inconsistent reference count: %d", v))
case v == 0:
var err error
for i := range c.shards {
// The cache shard is not allocated yet, nothing to close
if c.shards[i] == nil {
continue
}
err = firstError(err, c.shards[i].Close())
}
// Unref the cache which we create a reference to when the tableCache
// is first instantiated.
c.cache.Unref()
return err
}
return nil
}
// NewTableCache will create a reference to the table cache. It is the callers responsibility
// to call tableCache.Unref if they will no longer hold a reference to the table cache.
func NewTableCache(cache *Cache, numShards int, size int) *TableCache {
if size == 0 {
panic("pebble: cannot create a table cache of size 0")
} else if numShards == 0 {
panic("pebble: cannot create a table cache with 0 shards")
}
c := &TableCache{}
c.cache = cache
c.cache.Ref()
c.shards = make([]*tableCacheShard, numShards)
for i := range c.shards {
c.shards[i] = &tableCacheShard{}
c.shards[i].init(size / len(c.shards))
}
// Hold a ref to the cache here.
c.refs.Store(1)
return c
}
func (c *TableCache) getShard(fileNum base.DiskFileNum) *tableCacheShard {
return c.shards[uint64(fileNum.FileNum())%uint64(len(c.shards))]
}
type tableCacheKey struct {
cacheID uint64
fileNum base.DiskFileNum
}
type tableCacheShard struct {
hits atomic.Int64
misses atomic.Int64
iterCount atomic.Int32
size int
mu struct {
sync.RWMutex
nodes map[tableCacheKey]*tableCacheNode
// The iters map is only created and populated in race builds.
iters map[io.Closer][]byte
handHot *tableCacheNode
handCold *tableCacheNode
handTest *tableCacheNode
coldTarget int
sizeHot int
sizeCold int
sizeTest int
}
releasing sync.WaitGroup
releasingCh chan *tableCacheValue
releaseLoopExit sync.WaitGroup
}
func (c *tableCacheShard) init(size int) {
c.size = size
c.mu.nodes = make(map[tableCacheKey]*tableCacheNode)
c.mu.coldTarget = size
c.releasingCh = make(chan *tableCacheValue, 100)
c.releaseLoopExit.Add(1)
go c.releaseLoop()
if invariants.RaceEnabled {
c.mu.iters = make(map[io.Closer][]byte)
}
}
func (c *tableCacheShard) releaseLoop() {
pprof.Do(context.Background(), tableCacheLabels, func(context.Context) {
defer c.releaseLoopExit.Done()
for v := range c.releasingCh {
v.release(c)
}
})
}
// checkAndIntersectFilters checks the specific table and block property filters
// for intersection with any available table and block-level properties. Returns
// true for ok if this table should be read by this iterator.
func (c *tableCacheShard) checkAndIntersectFilters(
v *tableCacheValue,
tableFilter func(userProps map[string]string) bool,
blockPropertyFilters []BlockPropertyFilter,
boundLimitedFilter sstable.BoundLimitedBlockPropertyFilter,
) (ok bool, filterer *sstable.BlockPropertiesFilterer, err error) {
if tableFilter != nil &&
!tableFilter(v.reader.Properties.UserProperties) {
return false, nil, nil
}
if boundLimitedFilter != nil || len(blockPropertyFilters) > 0 {
filterer, err = sstable.IntersectsTable(
blockPropertyFilters,
boundLimitedFilter,
v.reader.Properties.UserProperties,
)
// NB: IntersectsTable will return a nil filterer if the table-level
// properties indicate there's no intersection with the provided filters.
if filterer == nil || err != nil {
return false, nil, err
}
}
return true, filterer, nil
}
func (c *tableCacheShard) newIters(
ctx context.Context,
file *manifest.FileMetadata,
opts *IterOptions,
internalOpts internalIterOpts,
dbOpts *tableCacheOpts,
) (internalIterator, keyspan.FragmentIterator, error) {
// TODO(sumeer): constructing the Reader should also use a plumbed context,
// since parts of the sstable are read during the construction. The Reader
// should not remember that context since the Reader can be long-lived.
// Calling findNode gives us the responsibility of decrementing v's
// refCount. If opening the underlying table resulted in error, then we
// decrement this straight away. Otherwise, we pass that responsibility to
// the sstable iterator, which decrements when it is closed.
v := c.findNode(file, dbOpts)
if v.err != nil {
defer c.unrefValue(v)
return nil, nil, v.err
}
hideObsoletePoints := false
var pointKeyFilters []BlockPropertyFilter
if opts != nil {
// This code is appending (at most one filter) in-place to
// opts.PointKeyFilters even though the slice is shared for iterators in
// the same iterator tree. This is acceptable since all the following
// properties are true:
// - The iterator tree is single threaded, so the shared backing for the
// slice is being mutated in a single threaded manner.
// - Each shallow copy of the slice has its own notion of length.
// - The appended element is always the obsoleteKeyBlockPropertyFilter
// struct, which is stateless, so overwriting that struct when creating
// one sstable iterator is harmless to other sstable iterators that are
// relying on that struct.
//
// An alternative would be to have different slices for different sstable
// iterators, but that requires more work to avoid allocations.
//
// TODO(bilal): for compaction reads of foreign sstables, we do hide
// obsolete points (see sstable.Reader.newCompactionIter) but we don't
// apply the obsolete block property filter. We could optimize this by
// applying the filter.
hideObsoletePoints, pointKeyFilters =
v.reader.TryAddBlockPropertyFilterForHideObsoletePoints(
opts.snapshotForHideObsoletePoints, file.LargestSeqNum, opts.PointKeyFilters)
}
ok := true
var filterer *sstable.BlockPropertiesFilterer
var err error
if opts != nil {
ok, filterer, err = c.checkAndIntersectFilters(v, opts.TableFilter,
pointKeyFilters, internalOpts.boundLimitedFilter)
}
if err != nil {
c.unrefValue(v)
return nil, nil, err
}
provider := dbOpts.objProvider
// Check if this file is a foreign file.
objMeta, err := provider.Lookup(fileTypeTable, file.FileBacking.DiskFileNum)
if err != nil {
return nil, nil, err
}
// Note: This suffers an allocation for virtual sstables.
cr := createCommonReader(v, file, provider.IsSharedForeign(objMeta))
// NB: range-del iterator does not maintain a reference to the table, nor
// does it need to read from it after creation.
rangeDelIter, err := cr.NewRawRangeDelIter()
if err != nil {
c.unrefValue(v)
return nil, nil, err
}
// Assert expected bounds in tests.
if invariants.Enabled && rangeDelIter != nil {
cmp := base.DefaultComparer.Compare
if dbOpts.opts.Comparer != nil {
cmp = dbOpts.opts.Comparer.Compare
}
// TODO(radu): we should be using AssertBounds, but it currently fails in
// some cases (#3167).
rangeDelIter = keyspan.AssertUserKeyBounds(
rangeDelIter, file.SmallestPointKey.UserKey, file.LargestPointKey.UserKey, cmp,
)
}
if !ok {
c.unrefValue(v)
// Return an empty iterator. This iterator has no mutable state, so
// using a singleton is fine.
// NB: We still return the potentially non-empty rangeDelIter. This
// ensures the iterator observes the file's range deletions even if the
// block property filters exclude all the file's point keys. The range
// deletions may still delete keys lower in the LSM in files that DO
// match the active filters.
//
// The point iterator returned must implement the filteredIter
// interface, so that the level iterator surfaces file boundaries when
// range deletions are present.
return filteredAll, rangeDelIter, err
}
var iter sstable.Iterator
useFilter := true
if opts != nil {
useFilter = manifest.LevelToInt(opts.level) != 6 || opts.UseL6Filters
ctx = objiotracing.WithLevel(ctx, manifest.LevelToInt(opts.level))
}
tableFormat, err := v.reader.TableFormat()
if err != nil {
return nil, nil, err
}
var rp sstable.ReaderProvider
if tableFormat >= sstable.TableFormatPebblev3 && v.reader.Properties.NumValueBlocks > 0 {
rp = &tableCacheShardReaderProvider{c: c, file: file, dbOpts: dbOpts}
}
if provider.IsSharedForeign(objMeta) {
if tableFormat < sstable.TableFormatPebblev4 {
return nil, nil, errors.New("pebble: shared foreign sstable has a lower table format than expected")
}
hideObsoletePoints = true
}
var categoryAndQoS sstable.CategoryAndQoS
if opts != nil {
categoryAndQoS = opts.CategoryAndQoS
}
if internalOpts.bytesIterated != nil {
iter, err = cr.NewCompactionIter(
internalOpts.bytesIterated, categoryAndQoS, dbOpts.sstStatsCollector, rp,
internalOpts.bufferPool)
} else {
iter, err = cr.NewIterWithBlockPropertyFiltersAndContextEtc(
ctx, opts.GetLowerBound(), opts.GetUpperBound(), filterer, hideObsoletePoints, useFilter,
internalOpts.stats, categoryAndQoS, dbOpts.sstStatsCollector, rp)
}
if err != nil {
if rangeDelIter != nil {
_ = rangeDelIter.Close()
}
c.unrefValue(v)
return nil, nil, err
}
// NB: v.closeHook takes responsibility for calling unrefValue(v) here. Take
// care to avoid introducing an allocation here by adding a closure.
iter.SetCloseHook(v.closeHook)
c.iterCount.Add(1)
dbOpts.iterCount.Add(1)
if invariants.RaceEnabled {
c.mu.Lock()
c.mu.iters[iter] = debug.Stack()
c.mu.Unlock()
}
return iter, rangeDelIter, nil
}
func (c *tableCacheShard) newRangeKeyIter(
file *manifest.FileMetadata, opts keyspan.SpanIterOptions, dbOpts *tableCacheOpts,
) (keyspan.FragmentIterator, error) {
// Calling findNode gives us the responsibility of decrementing v's
// refCount. If opening the underlying table resulted in error, then we
// decrement this straight away. Otherwise, we pass that responsibility to
// the sstable iterator, which decrements when it is closed.
v := c.findNode(file, dbOpts)
if v.err != nil {
defer c.unrefValue(v)
return nil, v.err
}
ok := true
var err error
// Don't filter a table's range keys if the file contains RANGEKEYDELs.
// The RANGEKEYDELs may delete range keys in other levels. Skipping the
// file's range key blocks may surface deleted range keys below. This is
// done here, rather than deferring to the block-property collector in order
// to maintain parity with point keys and the treatment of RANGEDELs.
if v.reader.Properties.NumRangeKeyDels == 0 {
ok, _, err = c.checkAndIntersectFilters(v, nil, opts.RangeKeyFilters, nil)
}
if err != nil {
c.unrefValue(v)
return nil, err
}
if !ok {
c.unrefValue(v)
// Return the empty iterator. This iterator has no mutable state, so
// using a singleton is fine.
return emptyKeyspanIter, err
}
var iter keyspan.FragmentIterator
if file.Virtual {
provider := dbOpts.objProvider
var objMeta objstorage.ObjectMetadata
objMeta, err = provider.Lookup(fileTypeTable, file.FileBacking.DiskFileNum)
if err == nil {
virtualReader := sstable.MakeVirtualReader(
v.reader, file.VirtualMeta(), provider.IsSharedForeign(objMeta),
)
iter, err = virtualReader.NewRawRangeKeyIter()
}
} else {
iter, err = v.reader.NewRawRangeKeyIter()
}
// iter is a block iter that holds the entire value of the block in memory.
// No need to hold onto a ref of the cache value.
c.unrefValue(v)
if err != nil {
return nil, err
}
if iter == nil {
// NewRawRangeKeyIter can return nil even if there's no error. However,
// the keyspan.LevelIter expects a non-nil iterator if err is nil.
return emptyKeyspanIter, nil
}
return iter, nil
}
type tableCacheShardReaderProvider struct {
c *tableCacheShard
file *manifest.FileMetadata
dbOpts *tableCacheOpts
v *tableCacheValue
}
var _ sstable.ReaderProvider = &tableCacheShardReaderProvider{}
// GetReader implements sstable.ReaderProvider. Note that it is not the
// responsibility of tableCacheShardReaderProvider to ensure that the file
// continues to exist. The ReaderProvider is used in iterators where the
// top-level iterator is pinning the read state and preventing the files from
// being deleted.
//
// The caller must call tableCacheShardReaderProvider.Close.
//
// Note that currently the Reader returned here is only used to read value
// blocks. This reader shouldn't be used for other purposes like reading keys
// outside of virtual sstable bounds.
//
// TODO(bananabrick): We could return a wrapper over the Reader to ensure
// that the reader isn't used for other purposes.
func (rp *tableCacheShardReaderProvider) GetReader() (*sstable.Reader, error) {
// Calling findNode gives us the responsibility of decrementing v's
// refCount.
v := rp.c.findNode(rp.file, rp.dbOpts)
if v.err != nil {
defer rp.c.unrefValue(v)
return nil, v.err
}
rp.v = v
return v.reader, nil
}
// Close implements sstable.ReaderProvider.
func (rp *tableCacheShardReaderProvider) Close() {
rp.c.unrefValue(rp.v)
rp.v = nil
}
// getTableProperties return sst table properties for target file
func (c *tableCacheShard) getTableProperties(
file *fileMetadata, dbOpts *tableCacheOpts,
) (*sstable.Properties, error) {
// Calling findNode gives us the responsibility of decrementing v's refCount here
v := c.findNode(file, dbOpts)
defer c.unrefValue(v)
if v.err != nil {
return nil, v.err
}
return &v.reader.Properties, nil
}
// releaseNode releases a node from the tableCacheShard.
//
// c.mu must be held when calling this.
func (c *tableCacheShard) releaseNode(n *tableCacheNode) {
c.unlinkNode(n)
c.clearNode(n)
}
// unlinkNode removes a node from the tableCacheShard, leaving the shard
// reference in place.
//
// c.mu must be held when calling this.
func (c *tableCacheShard) unlinkNode(n *tableCacheNode) {
key := tableCacheKey{n.cacheID, n.fileNum}
delete(c.mu.nodes, key)
switch n.ptype {
case tableCacheNodeHot:
c.mu.sizeHot--
case tableCacheNodeCold:
c.mu.sizeCold--
case tableCacheNodeTest:
c.mu.sizeTest--
}
if n == c.mu.handHot {
c.mu.handHot = c.mu.handHot.prev()
}
if n == c.mu.handCold {
c.mu.handCold = c.mu.handCold.prev()
}
if n == c.mu.handTest {
c.mu.handTest = c.mu.handTest.prev()
}
if n.unlink() == n {
// This was the last entry in the cache.
c.mu.handHot = nil
c.mu.handCold = nil
c.mu.handTest = nil
}
n.links.prev = nil
n.links.next = nil
}
func (c *tableCacheShard) clearNode(n *tableCacheNode) {
if v := n.value; v != nil {
n.value = nil
c.unrefValue(v)
}
}
// unrefValue decrements the reference count for the specified value, releasing
// it if the reference count fell to 0. Note that the value has a reference if
// it is present in tableCacheShard.mu.nodes, so a reference count of 0 means
// the node has already been removed from that map.
func (c *tableCacheShard) unrefValue(v *tableCacheValue) {
if v.refCount.Add(-1) == 0 {
c.releasing.Add(1)
c.releasingCh <- v
}
}
// findNode returns the node for the table with the given file number, creating
// that node if it didn't already exist. The caller is responsible for
// decrementing the returned node's refCount.
func (c *tableCacheShard) findNode(meta *fileMetadata, dbOpts *tableCacheOpts) *tableCacheValue {
v := c.findNodeInternal(meta, dbOpts)
// Loading a file before its global sequence number is known (eg,
// during ingest before entering the commit pipeline) can pollute
// the cache with incorrect state. In invariant builds, verify
// that the global sequence number of the returned reader matches.
if invariants.Enabled {
if v.reader != nil && meta.LargestSeqNum == meta.SmallestSeqNum &&
v.reader.Properties.GlobalSeqNum != meta.SmallestSeqNum {
panic(errors.AssertionFailedf("file %s loaded from table cache with the wrong global sequence number %d",
meta, v.reader.Properties.GlobalSeqNum))
}
}
return v
}
func (c *tableCacheShard) findNodeInternal(
meta *fileMetadata, dbOpts *tableCacheOpts,
) *tableCacheValue {
if refs := meta.Refs(); refs <= 0 {
panic(errors.AssertionFailedf("attempting to load file %s with refs=%d from table cache",
meta, refs))
}
// Fast-path for a hit in the cache.
c.mu.RLock()
key := tableCacheKey{dbOpts.cacheID, meta.FileBacking.DiskFileNum}
if n := c.mu.nodes[key]; n != nil && n.value != nil {
// Fast-path hit.
//
// The caller is responsible for decrementing the refCount.
v := n.value
v.refCount.Add(1)
c.mu.RUnlock()
n.referenced.Store(true)
c.hits.Add(1)
<-v.loaded
return v
}
c.mu.RUnlock()
c.mu.Lock()
n := c.mu.nodes[key]
switch {
case n == nil:
// Slow-path miss of a non-existent node.
n = &tableCacheNode{
fileNum: meta.FileBacking.DiskFileNum,
ptype: tableCacheNodeCold,
}
c.addNode(n, dbOpts)
c.mu.sizeCold++
case n.value != nil:
// Slow-path hit of a hot or cold node.
//
// The caller is responsible for decrementing the refCount.
v := n.value
v.refCount.Add(1)
n.referenced.Store(true)
c.hits.Add(1)
c.mu.Unlock()
<-v.loaded
return v
default:
// Slow-path miss of a test node.
c.unlinkNode(n)
c.mu.coldTarget++
if c.mu.coldTarget > c.size {
c.mu.coldTarget = c.size
}
n.referenced.Store(false)
n.ptype = tableCacheNodeHot
c.addNode(n, dbOpts)
c.mu.sizeHot++
}
c.misses.Add(1)
v := &tableCacheValue{
loaded: make(chan struct{}),
}
v.refCount.Store(2)
// Cache the closure invoked when an iterator is closed. This avoids an
// allocation on every call to newIters.
v.closeHook = func(i sstable.Iterator) error {
if invariants.RaceEnabled {
c.mu.Lock()
delete(c.mu.iters, i)
c.mu.Unlock()
}
c.unrefValue(v)
c.iterCount.Add(-1)
dbOpts.iterCount.Add(-1)
return nil
}
n.value = v
c.mu.Unlock()
// Note adding to the cache lists must complete before we begin loading the
// table as a failure during load will result in the node being unlinked.
pprof.Do(context.Background(), tableCacheLabels, func(context.Context) {
v.load(
loadInfo{
backingFileNum: meta.FileBacking.DiskFileNum,
smallestSeqNum: meta.SmallestSeqNum,
largestSeqNum: meta.LargestSeqNum,
}, c, dbOpts)
})
return v
}
func (c *tableCacheShard) addNode(n *tableCacheNode, dbOpts *tableCacheOpts) {
c.evictNodes()
n.cacheID = dbOpts.cacheID
key := tableCacheKey{n.cacheID, n.fileNum}
c.mu.nodes[key] = n
n.links.next = n
n.links.prev = n
if c.mu.handHot == nil {
// First element.
c.mu.handHot = n
c.mu.handCold = n
c.mu.handTest = n
} else {
c.mu.handHot.link(n)
}
if c.mu.handCold == c.mu.handHot {
c.mu.handCold = c.mu.handCold.prev()
}
}
func (c *tableCacheShard) evictNodes() {
for c.size <= c.mu.sizeHot+c.mu.sizeCold && c.mu.handCold != nil {
c.runHandCold()
}
}
func (c *tableCacheShard) runHandCold() {
n := c.mu.handCold
if n.ptype == tableCacheNodeCold {
if n.referenced.Load() {
n.referenced.Store(false)
n.ptype = tableCacheNodeHot
c.mu.sizeCold--
c.mu.sizeHot++
} else {
c.clearNode(n)
n.ptype = tableCacheNodeTest
c.mu.sizeCold--
c.mu.sizeTest++
for c.size < c.mu.sizeTest && c.mu.handTest != nil {
c.runHandTest()
}
}
}
c.mu.handCold = c.mu.handCold.next()
for c.size-c.mu.coldTarget <= c.mu.sizeHot && c.mu.handHot != nil {
c.runHandHot()
}
}
func (c *tableCacheShard) runHandHot() {
if c.mu.handHot == c.mu.handTest && c.mu.handTest != nil {
c.runHandTest()
if c.mu.handHot == nil {
return
}
}
n := c.mu.handHot
if n.ptype == tableCacheNodeHot {
if n.referenced.Load() {
n.referenced.Store(false)
} else {
n.ptype = tableCacheNodeCold
c.mu.sizeHot--
c.mu.sizeCold++
}
}
c.mu.handHot = c.mu.handHot.next()
}
func (c *tableCacheShard) runHandTest() {
if c.mu.sizeCold > 0 && c.mu.handTest == c.mu.handCold && c.mu.handCold != nil {
c.runHandCold()
if c.mu.handTest == nil {
return
}
}
n := c.mu.handTest
if n.ptype == tableCacheNodeTest {
c.mu.coldTarget--
if c.mu.coldTarget < 0 {
c.mu.coldTarget = 0
}
c.unlinkNode(n)
c.clearNode(n)
}
c.mu.handTest = c.mu.handTest.next()
}
func (c *tableCacheShard) evict(fileNum base.DiskFileNum, dbOpts *tableCacheOpts, allowLeak bool) {
c.mu.Lock()
key := tableCacheKey{dbOpts.cacheID, fileNum}
n := c.mu.nodes[key]
var v *tableCacheValue
if n != nil {
// NB: This is equivalent to tableCacheShard.releaseNode(), but we perform
// the tableCacheNode.release() call synchronously below to ensure the
// sstable file descriptor is closed before returning. Note that
// tableCacheShard.releasing needs to be incremented while holding
// tableCacheShard.mu in order to avoid a race with Close()
c.unlinkNode(n)