src/runtime/mcache.go - go - Git at Google

 // Copyright 2009 The Go 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 runtime

 import (
 	"runtime/internal/atomic"
 	"unsafe"
 )

 // Per-thread (in Go, per-P) cache for small objects.
 // No locking needed because it is per-thread (per-P).
 //
 // mcaches are allocated from non-GC'd memory, so any heap pointers
 // must be specially handled.
 //
 //go:notinheap
 type mcache struct {
 	// The following members are accessed on every malloc,
 	// so they are grouped here for better caching.
 	next_sample uintptr // trigger heap sample after allocating this many bytes
 	local_scan  uintptr // bytes of scannable heap allocated

 	// Allocator cache for tiny objects w/o pointers.
 	// See "Tiny allocator" comment in malloc.go.

 	// tiny points to the beginning of the current tiny block, or
 	// nil if there is no current tiny block.
 	//
 	// tiny is a heap pointer. Since mcache is in non-GC'd memory,
 	// we handle it by clearing it in releaseAll during mark
 	// termination.
 	tiny             uintptr
 	tinyoffset       uintptr
 	local_tinyallocs uintptr // number of tiny allocs not counted in other stats

 	// The rest is not accessed on every malloc.

 	alloc [numSpanClasses]*mspan // spans to allocate from, indexed by spanClass

 	stackcache [_NumStackOrders]stackfreelist

 	// Local allocator stats, flushed during GC.
 	local_largefree  uintptr                  // bytes freed for large objects (>maxsmallsize)
 	local_nlargefree uintptr                  // number of frees for large objects (>maxsmallsize)
 	local_nsmallfree [_NumSizeClasses]uintptr // number of frees for small objects (<=maxsmallsize)

 	// flushGen indicates the sweepgen during which this mcache
 	// was last flushed. If flushGen != mheap_.sweepgen, the spans
 	// in this mcache are stale and need to the flushed so they
 	// can be swept. This is done in acquirep.
 	flushGen uint32
 }

 // A gclink is a node in a linked list of blocks, like mlink,
 // but it is opaque to the garbage collector.
 // The GC does not trace the pointers during collection,
 // and the compiler does not emit write barriers for assignments
 // of gclinkptr values. Code should store references to gclinks
 // as gclinkptr, not as *gclink.
 type gclink struct {
 	next gclinkptr
 }

 // A gclinkptr is a pointer to a gclink, but it is opaque
 // to the garbage collector.
 type gclinkptr uintptr

 // ptr returns the *gclink form of p.
 // The result should be used for accessing fields, not stored
 // in other data structures.
 func (p gclinkptr) ptr() *gclink {
 	return (*gclink)(unsafe.Pointer(p))
 }

 type stackfreelist struct {
 	list gclinkptr // linked list of free stacks
 	size uintptr   // total size of stacks in list
 }

 // dummy mspan that contains no free objects.
 var emptymspan mspan

 func allocmcache() *mcache {
 	var c *mcache
 	systemstack(func() {
 		lock(&mheap_.lock)
 		c = (*mcache)(mheap_.cachealloc.alloc())
 		c.flushGen = mheap_.sweepgen
 		unlock(&mheap_.lock)
 	})
 	for i := range c.alloc {
 		c.alloc[i] = &emptymspan
 	}
 	c.next_sample = nextSample()
 	return c
 }

 func freemcache(c *mcache) {
 	systemstack(func() {
 		c.releaseAll()
 		stackcache_clear(c)

 		// NOTE(rsc,rlh): If gcworkbuffree comes back, we need to coordinate
 		// with the stealing of gcworkbufs during garbage collection to avoid
 		// a race where the workbuf is double-freed.
 		// gcworkbuffree(c.gcworkbuf)

 		lock(&mheap_.lock)
 		purgecachedstats(c)
 		mheap_.cachealloc.free(unsafe.Pointer(c))
 		unlock(&mheap_.lock)
 	})
 }

 // refill acquires a new span of span class spc for c. This span will
 // have at least one free object. The current span in c must be full.
 //
 // Must run in a non-preemptible context since otherwise the owner of
 // c could change.
 func (c *mcache) refill(spc spanClass) {
 	// Return the current cached span to the central lists.
 	s := c.alloc[spc]

 	if uintptr(s.allocCount) != s.nelems {
 		throw("refill of span with free space remaining")
 	}
 	if s != &emptymspan {
 		// Mark this span as no longer cached.
 		if s.sweepgen != mheap_.sweepgen+3 {
 			throw("bad sweepgen in refill")
 		}
 		if go115NewMCentralImpl {
 			mheap_.central[spc].mcentral.uncacheSpan(s)
 		} else {
 			atomic.Store(&s.sweepgen, mheap_.sweepgen)
 		}
 	}

 	// Get a new cached span from the central lists.
 	s = mheap_.central[spc].mcentral.cacheSpan()
 	if s == nil {
 		throw("out of memory")
 	}

 	if uintptr(s.allocCount) == s.nelems {
 		throw("span has no free space")
 	}

 	// Indicate that this span is cached and prevent asynchronous
 	// sweeping in the next sweep phase.
 	s.sweepgen = mheap_.sweepgen + 3

 	c.alloc[spc] = s
 }

 func (c *mcache) releaseAll() {
 	for i := range c.alloc {
 		s := c.alloc[i]
 		if s != &emptymspan {
 			mheap_.central[i].mcentral.uncacheSpan(s)
 			c.alloc[i] = &emptymspan
 		}
 	}
 	// Clear tinyalloc pool.
 	c.tiny = 0
 	c.tinyoffset = 0
 }

 // prepareForSweep flushes c if the system has entered a new sweep phase
 // since c was populated. This must happen between the sweep phase
 // starting and the first allocation from c.
 func (c *mcache) prepareForSweep() {
 	// Alternatively, instead of making sure we do this on every P
 	// between starting the world and allocating on that P, we
 	// could leave allocate-black on, allow allocation to continue
 	// as usual, use a ragged barrier at the beginning of sweep to
 	// ensure all cached spans are swept, and then disable
 	// allocate-black. However, with this approach it's difficult
 	// to avoid spilling mark bits into the *next* GC cycle.
 	sg := mheap_.sweepgen
 	if c.flushGen == sg {
 		return
 	} else if c.flushGen != sg-2 {
 		println("bad flushGen", c.flushGen, "in prepareForSweep; sweepgen", sg)
 		throw("bad flushGen")
 	}
 	c.releaseAll()
 	stackcache_clear(c)
 	atomic.Store(&c.flushGen, mheap_.sweepgen) // Synchronizes with gcStart
 }
	// Copyright 2009 The Go 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 runtime

	import (
	"runtime/internal/atomic"
	"unsafe"
	)

	// Per-thread (in Go, per-P) cache for small objects.
	// No locking needed because it is per-thread (per-P).
	//
	// mcaches are allocated from non-GC'd memory, so any heap pointers
	// must be specially handled.
	//
	//go:notinheap
	type mcache struct {
	// The following members are accessed on every malloc,
	// so they are grouped here for better caching.
	next_sample uintptr // trigger heap sample after allocating this many bytes
	local_scan uintptr // bytes of scannable heap allocated

	// Allocator cache for tiny objects w/o pointers.
	// See "Tiny allocator" comment in malloc.go.

	// tiny points to the beginning of the current tiny block, or
	// nil if there is no current tiny block.
	//
	// tiny is a heap pointer. Since mcache is in non-GC'd memory,
	// we handle it by clearing it in releaseAll during mark
	// termination.
	tiny uintptr
	tinyoffset uintptr
	local_tinyallocs uintptr // number of tiny allocs not counted in other stats

	// The rest is not accessed on every malloc.

	alloc [numSpanClasses]*mspan // spans to allocate from, indexed by spanClass

	stackcache [_NumStackOrders]stackfreelist

	// Local allocator stats, flushed during GC.
	local_largefree uintptr // bytes freed for large objects (>maxsmallsize)
	local_nlargefree uintptr // number of frees for large objects (>maxsmallsize)
	local_nsmallfree [_NumSizeClasses]uintptr // number of frees for small objects (<=maxsmallsize)

	// flushGen indicates the sweepgen during which this mcache
	// was last flushed. If flushGen != mheap_.sweepgen, the spans
	// in this mcache are stale and need to the flushed so they
	// can be swept. This is done in acquirep.
	flushGen uint32
	}

	// A gclink is a node in a linked list of blocks, like mlink,
	// but it is opaque to the garbage collector.
	// The GC does not trace the pointers during collection,
	// and the compiler does not emit write barriers for assignments
	// of gclinkptr values. Code should store references to gclinks
	// as gclinkptr, not as *gclink.
	type gclink struct {
	next gclinkptr
	}

	// A gclinkptr is a pointer to a gclink, but it is opaque
	// to the garbage collector.
	type gclinkptr uintptr

	// ptr returns the *gclink form of p.
	// The result should be used for accessing fields, not stored
	// in other data structures.
	func (p gclinkptr) ptr() *gclink {
	return (*gclink)(unsafe.Pointer(p))
	}

	type stackfreelist struct {
	list gclinkptr // linked list of free stacks
	size uintptr // total size of stacks in list
	}

	// dummy mspan that contains no free objects.
	var emptymspan mspan

	func allocmcache() *mcache {
	var c *mcache
	systemstack(func() {
	lock(&mheap_.lock)
	c = (*mcache)(mheap_.cachealloc.alloc())
	c.flushGen = mheap_.sweepgen
	unlock(&mheap_.lock)
	})
	for i := range c.alloc {
	c.alloc[i] = &emptymspan
	}
	c.next_sample = nextSample()
	return c
	}

	func freemcache(c *mcache) {
	systemstack(func() {
	c.releaseAll()
	stackcache_clear(c)

	// NOTE(rsc,rlh): If gcworkbuffree comes back, we need to coordinate
	// with the stealing of gcworkbufs during garbage collection to avoid
	// a race where the workbuf is double-freed.
	// gcworkbuffree(c.gcworkbuf)

	lock(&mheap_.lock)
	purgecachedstats(c)
	mheap_.cachealloc.free(unsafe.Pointer(c))
	unlock(&mheap_.lock)
	})
	}

	// refill acquires a new span of span class spc for c. This span will
	// have at least one free object. The current span in c must be full.
	//
	// Must run in a non-preemptible context since otherwise the owner of
	// c could change.
	func (c *mcache) refill(spc spanClass) {
	// Return the current cached span to the central lists.
	s := c.alloc[spc]

	if uintptr(s.allocCount) != s.nelems {
	throw("refill of span with free space remaining")
	}
	if s != &emptymspan {
	// Mark this span as no longer cached.
	if s.sweepgen != mheap_.sweepgen+3 {
	throw("bad sweepgen in refill")
	}
	if go115NewMCentralImpl {
	mheap_.central[spc].mcentral.uncacheSpan(s)
	} else {
	atomic.Store(&s.sweepgen, mheap_.sweepgen)
	}
	}

	// Get a new cached span from the central lists.
	s = mheap_.central[spc].mcentral.cacheSpan()
	if s == nil {
	throw("out of memory")
	}

	if uintptr(s.allocCount) == s.nelems {
	throw("span has no free space")
	}

	// Indicate that this span is cached and prevent asynchronous
	// sweeping in the next sweep phase.
	s.sweepgen = mheap_.sweepgen + 3

	c.alloc[spc] = s
	}

	func (c *mcache) releaseAll() {
	for i := range c.alloc {
	s := c.alloc[i]
	if s != &emptymspan {
	mheap_.central[i].mcentral.uncacheSpan(s)
	c.alloc[i] = &emptymspan
	}
	}
	// Clear tinyalloc pool.
	c.tiny = 0
	c.tinyoffset = 0
	}

	// prepareForSweep flushes c if the system has entered a new sweep phase
	// since c was populated. This must happen between the sweep phase
	// starting and the first allocation from c.
	func (c *mcache) prepareForSweep() {
	// Alternatively, instead of making sure we do this on every P
	// between starting the world and allocating on that P, we
	// could leave allocate-black on, allow allocation to continue
	// as usual, use a ragged barrier at the beginning of sweep to
	// ensure all cached spans are swept, and then disable
	// allocate-black. However, with this approach it's difficult
	// to avoid spilling mark bits into the next GC cycle.
	sg := mheap_.sweepgen
	if c.flushGen == sg {
	return
	} else if c.flushGen != sg-2 {
	println("bad flushGen", c.flushGen, "in prepareForSweep; sweepgen", sg)
	throw("bad flushGen")
	}
	c.releaseAll()
	stackcache_clear(c)
	atomic.Store(&c.flushGen, mheap_.sweepgen) // Synchronizes with gcStart
	}