mirror of
https://github.com/autc04/Retro68.git
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437 lines
14 KiB
Go
437 lines
14 KiB
Go
// Copyright 2009 The Go Authors. All rights reserved.
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// Use of this source code is governed by a BSD-style
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// license that can be found in the LICENSE file.
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// Garbage collector: sweeping
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package runtime
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import (
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"runtime/internal/atomic"
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"unsafe"
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)
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var sweep sweepdata
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// State of background sweep.
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type sweepdata struct {
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lock mutex
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g *g
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parked bool
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started bool
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nbgsweep uint32
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npausesweep uint32
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}
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// finishsweep_m ensures that all spans are swept.
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//
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// The world must be stopped. This ensures there are no sweeps in
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// progress.
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//
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//go:nowritebarrier
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func finishsweep_m() {
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// Sweeping must be complete before marking commences, so
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// sweep any unswept spans. If this is a concurrent GC, there
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// shouldn't be any spans left to sweep, so this should finish
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// instantly. If GC was forced before the concurrent sweep
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// finished, there may be spans to sweep.
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for sweepone() != ^uintptr(0) {
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sweep.npausesweep++
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}
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nextMarkBitArenaEpoch()
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}
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func bgsweep(c chan int) {
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setSystemGoroutine()
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sweep.g = getg()
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lock(&sweep.lock)
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sweep.parked = true
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c <- 1
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goparkunlock(&sweep.lock, "GC sweep wait", traceEvGoBlock, 1)
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for {
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for gosweepone() != ^uintptr(0) {
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sweep.nbgsweep++
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Gosched()
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}
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for freeSomeWbufs(true) {
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Gosched()
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}
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lock(&sweep.lock)
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if !gosweepdone() {
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// This can happen if a GC runs between
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// gosweepone returning ^0 above
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// and the lock being acquired.
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unlock(&sweep.lock)
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continue
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}
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sweep.parked = true
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goparkunlock(&sweep.lock, "GC sweep wait", traceEvGoBlock, 1)
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}
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}
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// sweeps one span
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// returns number of pages returned to heap, or ^uintptr(0) if there is nothing to sweep
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//go:nowritebarrier
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func sweepone() uintptr {
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_g_ := getg()
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sweepRatio := mheap_.sweepPagesPerByte // For debugging
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// increment locks to ensure that the goroutine is not preempted
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// in the middle of sweep thus leaving the span in an inconsistent state for next GC
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_g_.m.locks++
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if atomic.Load(&mheap_.sweepdone) != 0 {
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_g_.m.locks--
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return ^uintptr(0)
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}
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atomic.Xadd(&mheap_.sweepers, +1)
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npages := ^uintptr(0)
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sg := mheap_.sweepgen
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for {
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s := mheap_.sweepSpans[1-sg/2%2].pop()
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if s == nil {
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atomic.Store(&mheap_.sweepdone, 1)
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break
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}
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if s.state != mSpanInUse {
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// This can happen if direct sweeping already
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// swept this span, but in that case the sweep
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// generation should always be up-to-date.
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if s.sweepgen != sg {
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print("runtime: bad span s.state=", s.state, " s.sweepgen=", s.sweepgen, " sweepgen=", sg, "\n")
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throw("non in-use span in unswept list")
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}
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continue
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}
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if s.sweepgen != sg-2 || !atomic.Cas(&s.sweepgen, sg-2, sg-1) {
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continue
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}
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npages = s.npages
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if !s.sweep(false) {
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// Span is still in-use, so this returned no
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// pages to the heap and the span needs to
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// move to the swept in-use list.
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npages = 0
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}
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break
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}
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// Decrement the number of active sweepers and if this is the
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// last one print trace information.
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if atomic.Xadd(&mheap_.sweepers, -1) == 0 && atomic.Load(&mheap_.sweepdone) != 0 {
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if debug.gcpacertrace > 0 {
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print("pacer: sweep done at heap size ", memstats.heap_live>>20, "MB; allocated ", (memstats.heap_live-mheap_.sweepHeapLiveBasis)>>20, "MB during sweep; swept ", mheap_.pagesSwept, " pages at ", sweepRatio, " pages/byte\n")
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}
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}
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_g_.m.locks--
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return npages
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}
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//go:nowritebarrier
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func gosweepone() uintptr {
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var ret uintptr
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systemstack(func() {
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ret = sweepone()
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})
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return ret
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}
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//go:nowritebarrier
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func gosweepdone() bool {
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return mheap_.sweepdone != 0
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}
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// Returns only when span s has been swept.
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//go:nowritebarrier
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func (s *mspan) ensureSwept() {
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// Caller must disable preemption.
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// Otherwise when this function returns the span can become unswept again
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// (if GC is triggered on another goroutine).
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_g_ := getg()
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if _g_.m.locks == 0 && _g_.m.mallocing == 0 && _g_ != _g_.m.g0 {
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throw("MSpan_EnsureSwept: m is not locked")
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}
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sg := mheap_.sweepgen
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if atomic.Load(&s.sweepgen) == sg {
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return
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}
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// The caller must be sure that the span is a MSpanInUse span.
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if atomic.Cas(&s.sweepgen, sg-2, sg-1) {
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s.sweep(false)
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return
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}
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// unfortunate condition, and we don't have efficient means to wait
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for atomic.Load(&s.sweepgen) != sg {
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osyield()
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}
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}
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// Sweep frees or collects finalizers for blocks not marked in the mark phase.
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// It clears the mark bits in preparation for the next GC round.
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// Returns true if the span was returned to heap.
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// If preserve=true, don't return it to heap nor relink in MCentral lists;
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// caller takes care of it.
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//TODO go:nowritebarrier
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func (s *mspan) sweep(preserve bool) bool {
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// It's critical that we enter this function with preemption disabled,
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// GC must not start while we are in the middle of this function.
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_g_ := getg()
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if _g_.m.locks == 0 && _g_.m.mallocing == 0 && _g_ != _g_.m.g0 {
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throw("MSpan_Sweep: m is not locked")
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}
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sweepgen := mheap_.sweepgen
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if s.state != mSpanInUse || s.sweepgen != sweepgen-1 {
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print("MSpan_Sweep: state=", s.state, " sweepgen=", s.sweepgen, " mheap.sweepgen=", sweepgen, "\n")
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throw("MSpan_Sweep: bad span state")
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}
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if trace.enabled {
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traceGCSweepSpan(s.npages * _PageSize)
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}
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atomic.Xadd64(&mheap_.pagesSwept, int64(s.npages))
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spc := s.spanclass
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size := s.elemsize
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res := false
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c := _g_.m.mcache
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freeToHeap := false
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// The allocBits indicate which unmarked objects don't need to be
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// processed since they were free at the end of the last GC cycle
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// and were not allocated since then.
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// If the allocBits index is >= s.freeindex and the bit
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// is not marked then the object remains unallocated
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// since the last GC.
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// This situation is analogous to being on a freelist.
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// Unlink & free special records for any objects we're about to free.
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// Two complications here:
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// 1. An object can have both finalizer and profile special records.
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// In such case we need to queue finalizer for execution,
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// mark the object as live and preserve the profile special.
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// 2. A tiny object can have several finalizers setup for different offsets.
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// If such object is not marked, we need to queue all finalizers at once.
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// Both 1 and 2 are possible at the same time.
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specialp := &s.specials
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special := *specialp
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for special != nil {
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// A finalizer can be set for an inner byte of an object, find object beginning.
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objIndex := uintptr(special.offset) / size
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p := s.base() + objIndex*size
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mbits := s.markBitsForIndex(objIndex)
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if !mbits.isMarked() {
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// This object is not marked and has at least one special record.
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// Pass 1: see if it has at least one finalizer.
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hasFin := false
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endOffset := p - s.base() + size
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for tmp := special; tmp != nil && uintptr(tmp.offset) < endOffset; tmp = tmp.next {
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if tmp.kind == _KindSpecialFinalizer {
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// Stop freeing of object if it has a finalizer.
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mbits.setMarkedNonAtomic()
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hasFin = true
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break
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}
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}
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// Pass 2: queue all finalizers _or_ handle profile record.
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for special != nil && uintptr(special.offset) < endOffset {
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// Find the exact byte for which the special was setup
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// (as opposed to object beginning).
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p := s.base() + uintptr(special.offset)
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if special.kind == _KindSpecialFinalizer || !hasFin {
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// Splice out special record.
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y := special
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special = special.next
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*specialp = special
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freespecial(y, unsafe.Pointer(p), size)
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} else {
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// This is profile record, but the object has finalizers (so kept alive).
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// Keep special record.
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specialp = &special.next
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special = *specialp
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}
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}
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} else {
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// object is still live: keep special record
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specialp = &special.next
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special = *specialp
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}
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}
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if debug.allocfreetrace != 0 || raceenabled || msanenabled {
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// Find all newly freed objects. This doesn't have to
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// efficient; allocfreetrace has massive overhead.
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mbits := s.markBitsForBase()
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abits := s.allocBitsForIndex(0)
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for i := uintptr(0); i < s.nelems; i++ {
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if !mbits.isMarked() && (abits.index < s.freeindex || abits.isMarked()) {
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x := s.base() + i*s.elemsize
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if debug.allocfreetrace != 0 {
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tracefree(unsafe.Pointer(x), size)
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}
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if raceenabled {
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racefree(unsafe.Pointer(x), size)
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}
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if msanenabled {
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msanfree(unsafe.Pointer(x), size)
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}
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}
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mbits.advance()
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abits.advance()
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}
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}
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// Count the number of free objects in this span.
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nalloc := uint16(s.countAlloc())
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if spc.sizeclass() == 0 && nalloc == 0 {
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s.needzero = 1
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freeToHeap = true
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}
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nfreed := s.allocCount - nalloc
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// This test is not reliable with gccgo, because of
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// conservative stack scanning. The test boils down to
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// checking that no new bits have been set in gcmarkBits since
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// the span was added to the sweep count. New bits are set by
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// greyobject. Seeing a new bit means that a live pointer has
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// appeared that was not found during the mark phase. That can
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// not happen when pointers are followed strictly. However,
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// with conservative checking, it is possible for a pointer
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// that will never be used to appear live and to cause a mark
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// to be added. That is unfortunate in that it causes this
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// check to be inaccurate, and it will keep an object live
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// unnecessarily, but provided the pointer is not really live
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// it is not otherwise a problem. So we disable the test for gccgo.
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if false && nalloc > s.allocCount {
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print("runtime: nelems=", s.nelems, " nalloc=", nalloc, " previous allocCount=", s.allocCount, " nfreed=", nfreed, "\n")
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throw("sweep increased allocation count")
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}
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s.allocCount = nalloc
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wasempty := s.nextFreeIndex() == s.nelems
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s.freeindex = 0 // reset allocation index to start of span.
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if trace.enabled {
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getg().m.p.ptr().traceReclaimed += uintptr(nfreed) * s.elemsize
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}
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// gcmarkBits becomes the allocBits.
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// get a fresh cleared gcmarkBits in preparation for next GC
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s.allocBits = s.gcmarkBits
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s.gcmarkBits = newMarkBits(s.nelems)
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// Initialize alloc bits cache.
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s.refillAllocCache(0)
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// We need to set s.sweepgen = h.sweepgen only when all blocks are swept,
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// because of the potential for a concurrent free/SetFinalizer.
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// But we need to set it before we make the span available for allocation
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// (return it to heap or mcentral), because allocation code assumes that a
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// span is already swept if available for allocation.
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if freeToHeap || nfreed == 0 {
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// The span must be in our exclusive ownership until we update sweepgen,
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// check for potential races.
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if s.state != mSpanInUse || s.sweepgen != sweepgen-1 {
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print("MSpan_Sweep: state=", s.state, " sweepgen=", s.sweepgen, " mheap.sweepgen=", sweepgen, "\n")
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throw("MSpan_Sweep: bad span state after sweep")
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}
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// Serialization point.
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// At this point the mark bits are cleared and allocation ready
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// to go so release the span.
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atomic.Store(&s.sweepgen, sweepgen)
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}
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if nfreed > 0 && spc.sizeclass() != 0 {
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c.local_nsmallfree[spc.sizeclass()] += uintptr(nfreed)
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res = mheap_.central[spc].mcentral.freeSpan(s, preserve, wasempty)
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// MCentral_FreeSpan updates sweepgen
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} else if freeToHeap {
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// Free large span to heap
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// NOTE(rsc,dvyukov): The original implementation of efence
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// in CL 22060046 used SysFree instead of SysFault, so that
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// the operating system would eventually give the memory
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// back to us again, so that an efence program could run
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// longer without running out of memory. Unfortunately,
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// calling SysFree here without any kind of adjustment of the
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// heap data structures means that when the memory does
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// come back to us, we have the wrong metadata for it, either in
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// the MSpan structures or in the garbage collection bitmap.
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// Using SysFault here means that the program will run out of
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// memory fairly quickly in efence mode, but at least it won't
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// have mysterious crashes due to confused memory reuse.
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// It should be possible to switch back to SysFree if we also
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// implement and then call some kind of MHeap_DeleteSpan.
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if debug.efence > 0 {
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s.limit = 0 // prevent mlookup from finding this span
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sysFault(unsafe.Pointer(s.base()), size)
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} else {
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mheap_.freeSpan(s, 1)
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}
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c.local_nlargefree++
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c.local_largefree += size
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res = true
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}
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if !res {
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// The span has been swept and is still in-use, so put
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// it on the swept in-use list.
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mheap_.sweepSpans[sweepgen/2%2].push(s)
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}
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return res
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}
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// deductSweepCredit deducts sweep credit for allocating a span of
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// size spanBytes. This must be performed *before* the span is
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// allocated to ensure the system has enough credit. If necessary, it
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// performs sweeping to prevent going in to debt. If the caller will
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// also sweep pages (e.g., for a large allocation), it can pass a
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// non-zero callerSweepPages to leave that many pages unswept.
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//
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// deductSweepCredit makes a worst-case assumption that all spanBytes
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// bytes of the ultimately allocated span will be available for object
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// allocation.
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//
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// deductSweepCredit is the core of the "proportional sweep" system.
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// It uses statistics gathered by the garbage collector to perform
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// enough sweeping so that all pages are swept during the concurrent
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// sweep phase between GC cycles.
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//
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// mheap_ must NOT be locked.
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func deductSweepCredit(spanBytes uintptr, callerSweepPages uintptr) {
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if mheap_.sweepPagesPerByte == 0 {
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// Proportional sweep is done or disabled.
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return
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}
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if trace.enabled {
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traceGCSweepStart()
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}
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retry:
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sweptBasis := atomic.Load64(&mheap_.pagesSweptBasis)
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// Fix debt if necessary.
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newHeapLive := uintptr(atomic.Load64(&memstats.heap_live)-mheap_.sweepHeapLiveBasis) + spanBytes
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pagesTarget := int64(mheap_.sweepPagesPerByte*float64(newHeapLive)) - int64(callerSweepPages)
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for pagesTarget > int64(atomic.Load64(&mheap_.pagesSwept)-sweptBasis) {
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if gosweepone() == ^uintptr(0) {
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mheap_.sweepPagesPerByte = 0
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break
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}
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if atomic.Load64(&mheap_.pagesSweptBasis) != sweptBasis {
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// Sweep pacing changed. Recompute debt.
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goto retry
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}
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}
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if trace.enabled {
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traceGCSweepDone()
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}
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}
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