Source file src/sync/pool.go
1 // Copyright 2013 The Go Authors. All rights reserved. 2 // Use of this source code is governed by a BSD-style 3 // license that can be found in the LICENSE file. 4 5 package sync 6 7 import ( 8 "internal/race" 9 "runtime" 10 "sync/atomic" 11 "unsafe" 12 ) 13 14 // A Pool is a set of temporary objects that may be individually saved and 15 // retrieved. 16 // 17 // Any item stored in the Pool may be removed automatically at any time without 18 // notification. If the Pool holds the only reference when this happens, the 19 // item might be deallocated. 20 // 21 // A Pool is safe for use by multiple goroutines simultaneously. 22 // 23 // Pool's purpose is to cache allocated but unused items for later reuse, 24 // relieving pressure on the garbage collector. That is, it makes it easy to 25 // build efficient, thread-safe free lists. However, it is not suitable for all 26 // free lists. 27 // 28 // An appropriate use of a Pool is to manage a group of temporary items 29 // silently shared among and potentially reused by concurrent independent 30 // clients of a package. Pool provides a way to amortize allocation overhead 31 // across many clients. 32 // 33 // An example of good use of a Pool is in the fmt package, which maintains a 34 // dynamically-sized store of temporary output buffers. The store scales under 35 // load (when many goroutines are actively printing) and shrinks when 36 // quiescent. 37 // 38 // On the other hand, a free list maintained as part of a short-lived object is 39 // not a suitable use for a Pool, since the overhead does not amortize well in 40 // that scenario. It is more efficient to have such objects implement their own 41 // free list. 42 // 43 // A Pool must not be copied after first use. 44 type Pool struct { 45 noCopy noCopy 46 47 local unsafe.Pointer // local fixed-size per-P pool, actual type is [P]poolLocal 48 localSize uintptr // size of the local array 49 50 victim unsafe.Pointer // local from previous cycle 51 victimSize uintptr // size of victims array 52 53 // New optionally specifies a function to generate 54 // a value when Get would otherwise return nil. 55 // It may not be changed concurrently with calls to Get. 56 New func() any 57 } 58 59 // Local per-P Pool appendix. 60 type poolLocalInternal struct { 61 private any // Can be used only by the respective P. 62 shared poolChain // Local P can pushHead/popHead; any P can popTail. 63 } 64 65 type poolLocal struct { 66 poolLocalInternal 67 68 // Prevents false sharing on widespread platforms with 69 // 128 mod (cache line size) = 0 . 70 pad [128 - unsafe.Sizeof(poolLocalInternal{})%128]byte 71 } 72 73 // from runtime 74 func fastrandn(n uint32) uint32 75 76 var poolRaceHash [128]uint64 77 78 // poolRaceAddr returns an address to use as the synchronization point 79 // for race detector logic. We don't use the actual pointer stored in x 80 // directly, for fear of conflicting with other synchronization on that address. 81 // Instead, we hash the pointer to get an index into poolRaceHash. 82 // See discussion on golang.org/cl/31589. 83 func poolRaceAddr(x any) unsafe.Pointer { 84 ptr := uintptr((*[2]unsafe.Pointer)(unsafe.Pointer(&x))[1]) 85 h := uint32((uint64(uint32(ptr)) * 0x85ebca6b) >> 16) 86 return unsafe.Pointer(&poolRaceHash[h%uint32(len(poolRaceHash))]) 87 } 88 89 // Put adds x to the pool. 90 func (p *Pool) Put(x any) { 91 if x == nil { 92 return 93 } 94 if race.Enabled { 95 if fastrandn(4) == 0 { 96 // Randomly drop x on floor. 97 return 98 } 99 race.ReleaseMerge(poolRaceAddr(x)) 100 race.Disable() 101 } 102 l, _ := p.pin() 103 if l.private == nil { 104 l.private = x 105 x = nil 106 } 107 if x != nil { 108 l.shared.pushHead(x) 109 } 110 runtime_procUnpin() 111 if race.Enabled { 112 race.Enable() 113 } 114 } 115 116 // Get selects an arbitrary item from the Pool, removes it from the 117 // Pool, and returns it to the caller. 118 // Get may choose to ignore the pool and treat it as empty. 119 // Callers should not assume any relation between values passed to Put and 120 // the values returned by Get. 121 // 122 // If Get would otherwise return nil and p.New is non-nil, Get returns 123 // the result of calling p.New. 124 func (p *Pool) Get() any { 125 if race.Enabled { 126 race.Disable() 127 } 128 l, pid := p.pin() 129 x := l.private 130 l.private = nil 131 if x == nil { 132 // Try to pop the head of the local shard. We prefer 133 // the head over the tail for temporal locality of 134 // reuse. 135 x, _ = l.shared.popHead() 136 if x == nil { 137 x = p.getSlow(pid) 138 } 139 } 140 runtime_procUnpin() 141 if race.Enabled { 142 race.Enable() 143 if x != nil { 144 race.Acquire(poolRaceAddr(x)) 145 } 146 } 147 if x == nil && p.New != nil { 148 x = p.New() 149 } 150 return x 151 } 152 153 func (p *Pool) getSlow(pid int) any { 154 // See the comment in pin regarding ordering of the loads. 155 size := runtime_LoadAcquintptr(&p.localSize) // load-acquire 156 locals := p.local // load-consume 157 // Try to steal one element from other procs. 158 for i := 0; i < int(size); i++ { 159 l := indexLocal(locals, (pid+i+1)%int(size)) 160 if x, _ := l.shared.popTail(); x != nil { 161 return x 162 } 163 } 164 165 // Try the victim cache. We do this after attempting to steal 166 // from all primary caches because we want objects in the 167 // victim cache to age out if at all possible. 168 size = atomic.LoadUintptr(&p.victimSize) 169 if uintptr(pid) >= size { 170 return nil 171 } 172 locals = p.victim 173 l := indexLocal(locals, pid) 174 if x := l.private; x != nil { 175 l.private = nil 176 return x 177 } 178 for i := 0; i < int(size); i++ { 179 l := indexLocal(locals, (pid+i)%int(size)) 180 if x, _ := l.shared.popTail(); x != nil { 181 return x 182 } 183 } 184 185 // Mark the victim cache as empty for future gets don't bother 186 // with it. 187 atomic.StoreUintptr(&p.victimSize, 0) 188 189 return nil 190 } 191 192 // pin pins the current goroutine to P, disables preemption and 193 // returns poolLocal pool for the P and the P's id. 194 // Caller must call runtime_procUnpin() when done with the pool. 195 func (p *Pool) pin() (*poolLocal, int) { 196 pid := runtime_procPin() 197 // In pinSlow we store to local and then to localSize, here we load in opposite order. 198 // Since we've disabled preemption, GC cannot happen in between. 199 // Thus here we must observe local at least as large localSize. 200 // We can observe a newer/larger local, it is fine (we must observe its zero-initialized-ness). 201 s := runtime_LoadAcquintptr(&p.localSize) // load-acquire 202 l := p.local // load-consume 203 if uintptr(pid) < s { 204 return indexLocal(l, pid), pid 205 } 206 return p.pinSlow() 207 } 208 209 func (p *Pool) pinSlow() (*poolLocal, int) { 210 // Retry under the mutex. 211 // Can not lock the mutex while pinned. 212 runtime_procUnpin() 213 allPoolsMu.Lock() 214 defer allPoolsMu.Unlock() 215 pid := runtime_procPin() 216 // poolCleanup won't be called while we are pinned. 217 s := p.localSize 218 l := p.local 219 if uintptr(pid) < s { 220 return indexLocal(l, pid), pid 221 } 222 if p.local == nil { 223 allPools = append(allPools, p) 224 } 225 // If GOMAXPROCS changes between GCs, we re-allocate the array and lose the old one. 226 size := runtime.GOMAXPROCS(0) 227 local := make([]poolLocal, size) 228 atomic.StorePointer(&p.local, unsafe.Pointer(&local[0])) // store-release 229 runtime_StoreReluintptr(&p.localSize, uintptr(size)) // store-release 230 return &local[pid], pid 231 } 232 233 func poolCleanup() { 234 // This function is called with the world stopped, at the beginning of a garbage collection. 235 // It must not allocate and probably should not call any runtime functions. 236 237 // Because the world is stopped, no pool user can be in a 238 // pinned section (in effect, this has all Ps pinned). 239 240 // Drop victim caches from all pools. 241 for _, p := range oldPools { 242 p.victim = nil 243 p.victimSize = 0 244 } 245 246 // Move primary cache to victim cache. 247 for _, p := range allPools { 248 p.victim = p.local 249 p.victimSize = p.localSize 250 p.local = nil 251 p.localSize = 0 252 } 253 254 // The pools with non-empty primary caches now have non-empty 255 // victim caches and no pools have primary caches. 256 oldPools, allPools = allPools, nil 257 } 258 259 var ( 260 allPoolsMu Mutex 261 262 // allPools is the set of pools that have non-empty primary 263 // caches. Protected by either 1) allPoolsMu and pinning or 2) 264 // STW. 265 allPools []*Pool 266 267 // oldPools is the set of pools that may have non-empty victim 268 // caches. Protected by STW. 269 oldPools []*Pool 270 ) 271 272 func init() { 273 runtime_registerPoolCleanup(poolCleanup) 274 } 275 276 func indexLocal(l unsafe.Pointer, i int) *poolLocal { 277 lp := unsafe.Pointer(uintptr(l) + uintptr(i)*unsafe.Sizeof(poolLocal{})) 278 return (*poolLocal)(lp) 279 } 280 281 // Implemented in runtime. 282 func runtime_registerPoolCleanup(cleanup func()) 283 func runtime_procPin() int 284 func runtime_procUnpin() 285 286 // The below are implemented in runtime/internal/atomic and the 287 // compiler also knows to intrinsify the symbol we linkname into this 288 // package. 289 290 //go:linkname runtime_LoadAcquintptr runtime/internal/atomic.LoadAcquintptr 291 func runtime_LoadAcquintptr(ptr *uintptr) uintptr 292 293 //go:linkname runtime_StoreReluintptr runtime/internal/atomic.StoreReluintptr 294 func runtime_StoreReluintptr(ptr *uintptr, val uintptr) uintptr 295