// 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. // Page heap. // // See malloc.go for overview. package runtime import ( "runtime/internal/atomic" "runtime/internal/sys" "unsafe" ) // Main malloc heap. // The heap itself is the "free[]" and "large" arrays, // but all the other global data is here too. type mheap struct { lock mutex free [_MaxMHeapList]mSpanList // free lists of given length freelarge mSpanList // free lists length >= _MaxMHeapList busy [_MaxMHeapList]mSpanList // busy lists of large objects of given length busylarge mSpanList // busy lists of large objects length >= _MaxMHeapList allspans **mspan // all spans out there gcspans **mspan // copy of allspans referenced by gc marker or sweeper nspan uint32 sweepgen uint32 // sweep generation, see comment in mspan sweepdone uint32 // all spans are swept // span lookup spans **mspan spans_mapped uintptr // Proportional sweep pagesInUse uint64 // pages of spans in stats _MSpanInUse; R/W with mheap.lock spanBytesAlloc uint64 // bytes of spans allocated this cycle; updated atomically pagesSwept uint64 // pages swept this cycle; updated atomically sweepPagesPerByte float64 // proportional sweep ratio; written with lock, read without // TODO(austin): pagesInUse should be a uintptr, but the 386 // compiler can't 8-byte align fields. // Malloc stats. largefree uint64 // bytes freed for large objects (>maxsmallsize) nlargefree uint64 // number of frees for large objects (>maxsmallsize) nsmallfree [_NumSizeClasses]uint64 // number of frees for small objects (<=maxsmallsize) // range of addresses we might see in the heap bitmap uintptr bitmap_mapped uintptr arena_start uintptr arena_used uintptr // always mHeap_Map{Bits,Spans} before updating arena_end uintptr arena_reserved bool // central free lists for small size classes. // the padding makes sure that the MCentrals are // spaced CacheLineSize bytes apart, so that each MCentral.lock // gets its own cache line. central [_NumSizeClasses]struct { mcentral mcentral pad [sys.CacheLineSize]byte } spanalloc fixalloc // allocator for span* cachealloc fixalloc // allocator for mcache* specialfinalizeralloc fixalloc // allocator for specialfinalizer* specialprofilealloc fixalloc // allocator for specialprofile* speciallock mutex // lock for special record allocators. } var mheap_ mheap // An MSpan is a run of pages. // // When a MSpan is in the heap free list, state == MSpanFree // and heapmap(s->start) == span, heapmap(s->start+s->npages-1) == span. // // When a MSpan is allocated, state == MSpanInUse or MSpanStack // and heapmap(i) == span for all s->start <= i < s->start+s->npages. // Every MSpan is in one doubly-linked list, // either one of the MHeap's free lists or one of the // MCentral's span lists. // An MSpan representing actual memory has state _MSpanInUse, // _MSpanStack, or _MSpanFree. Transitions between these states are // constrained as follows: // // * A span may transition from free to in-use or stack during any GC // phase. // // * During sweeping (gcphase == _GCoff), a span may transition from // in-use to free (as a result of sweeping) or stack to free (as a // result of stacks being freed). // // * During GC (gcphase != _GCoff), a span *must not* transition from // stack or in-use to free. Because concurrent GC may read a pointer // and then look up its span, the span state must be monotonic. const ( _MSpanInUse = iota // allocated for garbage collected heap _MSpanStack // allocated for use by stack allocator _MSpanFree _MSpanDead ) // mSpanList heads a linked list of spans. // // Linked list structure is based on BSD's "tail queue" data structure. type mSpanList struct { first *mspan // first span in list, or nil if none last **mspan // last span's next field, or first if none } type mspan struct { next *mspan // next span in list, or nil if none prev **mspan // previous span's next field, or list head's first field if none list *mSpanList // For debugging. TODO: Remove. start pageID // starting page number npages uintptr // number of pages in span freelist gclinkptr // list of free objects // sweep generation: // if sweepgen == h->sweepgen - 2, the span needs sweeping // if sweepgen == h->sweepgen - 1, the span is currently being swept // if sweepgen == h->sweepgen, the span is swept and ready to use // h->sweepgen is incremented by 2 after every GC sweepgen uint32 divMul uint32 // for divide by elemsize - divMagic.mul ref uint16 // capacity - number of objects in freelist sizeclass uint8 // size class incache bool // being used by an mcache state uint8 // mspaninuse etc needzero uint8 // needs to be zeroed before allocation divShift uint8 // for divide by elemsize - divMagic.shift divShift2 uint8 // for divide by elemsize - divMagic.shift2 elemsize uintptr // computed from sizeclass or from npages unusedsince int64 // first time spotted by gc in mspanfree state npreleased uintptr // number of pages released to the os limit uintptr // end of data in span speciallock mutex // guards specials list specials *special // linked list of special records sorted by offset. baseMask uintptr // if non-0, elemsize is a power of 2, & this will get object allocation base } func (s *mspan) base() uintptr { return uintptr(s.start << _PageShift) } func (s *mspan) layout() (size, n, total uintptr) { total = s.npages << _PageShift size = s.elemsize if size > 0 { n = total / size } return } var h_allspans []*mspan // TODO: make this h.allspans once mheap can be defined in Go // h_spans is a lookup table to map virtual address page IDs to *mspan. // For allocated spans, their pages map to the span itself. // For free spans, only the lowest and highest pages map to the span itself. Internal // pages map to an arbitrary span. // For pages that have never been allocated, h_spans entries are nil. var h_spans []*mspan // TODO: make this h.spans once mheap can be defined in Go func recordspan(vh unsafe.Pointer, p unsafe.Pointer) { h := (*mheap)(vh) s := (*mspan)(p) if len(h_allspans) >= cap(h_allspans) { n := 64 * 1024 / sys.PtrSize if n < cap(h_allspans)*3/2 { n = cap(h_allspans) * 3 / 2 } var new []*mspan sp := (*slice)(unsafe.Pointer(&new)) sp.array = sysAlloc(uintptr(n)*sys.PtrSize, &memstats.other_sys) if sp.array == nil { throw("runtime: cannot allocate memory") } sp.len = len(h_allspans) sp.cap = n if len(h_allspans) > 0 { copy(new, h_allspans) // Don't free the old array if it's referenced by sweep. // See the comment in mgc.go. if h.allspans != mheap_.gcspans { sysFree(unsafe.Pointer(h.allspans), uintptr(cap(h_allspans))*sys.PtrSize, &memstats.other_sys) } } h_allspans = new h.allspans = (**mspan)(unsafe.Pointer(sp.array)) } h_allspans = append(h_allspans, s) h.nspan = uint32(len(h_allspans)) } // inheap reports whether b is a pointer into a (potentially dead) heap object. // It returns false for pointers into stack spans. // Non-preemptible because it is used by write barriers. //go:nowritebarrier //go:nosplit func inheap(b uintptr) bool { if b == 0 || b < mheap_.arena_start || b >= mheap_.arena_used { return false } // Not a beginning of a block, consult span table to find the block beginning. k := b >> _PageShift x := k x -= mheap_.arena_start >> _PageShift s := h_spans[x] if s == nil || pageID(k) < s.start || b >= s.limit || s.state != mSpanInUse { return false } return true } // TODO: spanOf and spanOfUnchecked are open-coded in a lot of places. // Use the functions instead. // spanOf returns the span of p. If p does not point into the heap or // no span contains p, spanOf returns nil. func spanOf(p uintptr) *mspan { if p == 0 || p < mheap_.arena_start || p >= mheap_.arena_used { return nil } return spanOfUnchecked(p) } // spanOfUnchecked is equivalent to spanOf, but the caller must ensure // that p points into the heap (that is, mheap_.arena_start <= p < // mheap_.arena_used). func spanOfUnchecked(p uintptr) *mspan { return h_spans[(p-mheap_.arena_start)>>_PageShift] } func mlookup(v uintptr, base *uintptr, size *uintptr, sp **mspan) int32 { _g_ := getg() _g_.m.mcache.local_nlookup++ if sys.PtrSize == 4 && _g_.m.mcache.local_nlookup >= 1<<30 { // purge cache stats to prevent overflow lock(&mheap_.lock) purgecachedstats(_g_.m.mcache) unlock(&mheap_.lock) } s := mheap_.lookupMaybe(unsafe.Pointer(v)) if sp != nil { *sp = s } if s == nil { if base != nil { *base = 0 } if size != nil { *size = 0 } return 0 } p := uintptr(s.start) << _PageShift if s.sizeclass == 0 { // Large object. if base != nil { *base = p } if size != nil { *size = s.npages << _PageShift } return 1 } n := s.elemsize if base != nil { i := (uintptr(v) - uintptr(p)) / n *base = p + i*n } if size != nil { *size = n } return 1 } // Initialize the heap. func (h *mheap) init(spans_size uintptr) { h.spanalloc.init(unsafe.Sizeof(mspan{}), recordspan, unsafe.Pointer(h), &memstats.mspan_sys) h.cachealloc.init(unsafe.Sizeof(mcache{}), nil, nil, &memstats.mcache_sys) h.specialfinalizeralloc.init(unsafe.Sizeof(specialfinalizer{}), nil, nil, &memstats.other_sys) h.specialprofilealloc.init(unsafe.Sizeof(specialprofile{}), nil, nil, &memstats.other_sys) // h->mapcache needs no init for i := range h.free { h.free[i].init() h.busy[i].init() } h.freelarge.init() h.busylarge.init() for i := range h.central { h.central[i].mcentral.init(int32(i)) } sp := (*slice)(unsafe.Pointer(&h_spans)) sp.array = unsafe.Pointer(h.spans) sp.len = int(spans_size / sys.PtrSize) sp.cap = int(spans_size / sys.PtrSize) } // mHeap_MapSpans makes sure that the spans are mapped // up to the new value of arena_used. // // It must be called with the expected new value of arena_used, // *before* h.arena_used has been updated. // Waiting to update arena_used until after the memory has been mapped // avoids faults when other threads try access the bitmap immediately // after observing the change to arena_used. func (h *mheap) mapSpans(arena_used uintptr) { // Map spans array, PageSize at a time. n := arena_used n -= h.arena_start n = n / _PageSize * sys.PtrSize n = round(n, sys.PhysPageSize) if h.spans_mapped >= n { return } sysMap(add(unsafe.Pointer(h.spans), h.spans_mapped), n-h.spans_mapped, h.arena_reserved, &memstats.other_sys) h.spans_mapped = n } // Sweeps spans in list until reclaims at least npages into heap. // Returns the actual number of pages reclaimed. func (h *mheap) reclaimList(list *mSpanList, npages uintptr) uintptr { n := uintptr(0) sg := mheap_.sweepgen retry: for s := list.first; s != nil; s = s.next { if s.sweepgen == sg-2 && atomic.Cas(&s.sweepgen, sg-2, sg-1) { list.remove(s) // swept spans are at the end of the list list.insertBack(s) unlock(&h.lock) snpages := s.npages if s.sweep(false) { n += snpages } lock(&h.lock) if n >= npages { return n } // the span could have been moved elsewhere goto retry } if s.sweepgen == sg-1 { // the span is being sweept by background sweeper, skip continue } // already swept empty span, // all subsequent ones must also be either swept or in process of sweeping break } return n } // Sweeps and reclaims at least npage pages into heap. // Called before allocating npage pages. func (h *mheap) reclaim(npage uintptr) { // First try to sweep busy spans with large objects of size >= npage, // this has good chances of reclaiming the necessary space. for i := int(npage); i < len(h.busy); i++ { if h.reclaimList(&h.busy[i], npage) != 0 { return // Bingo! } } // Then -- even larger objects. if h.reclaimList(&h.busylarge, npage) != 0 { return // Bingo! } // Now try smaller objects. // One such object is not enough, so we need to reclaim several of them. reclaimed := uintptr(0) for i := 0; i < int(npage) && i < len(h.busy); i++ { reclaimed += h.reclaimList(&h.busy[i], npage-reclaimed) if reclaimed >= npage { return } } // Now sweep everything that is not yet swept. unlock(&h.lock) for { n := sweepone() if n == ^uintptr(0) { // all spans are swept break } reclaimed += n if reclaimed >= npage { break } } lock(&h.lock) } // Allocate a new span of npage pages from the heap for GC'd memory // and record its size class in the HeapMap and HeapMapCache. func (h *mheap) alloc_m(npage uintptr, sizeclass int32, large bool) *mspan { _g_ := getg() if _g_ != _g_.m.g0 { throw("_mheap_alloc not on g0 stack") } lock(&h.lock) // To prevent excessive heap growth, before allocating n pages // we need to sweep and reclaim at least n pages. if h.sweepdone == 0 { // TODO(austin): This tends to sweep a large number of // spans in order to find a few completely free spans // (for example, in the garbage benchmark, this sweeps // ~30x the number of pages its trying to allocate). // If GC kept a bit for whether there were any marks // in a span, we could release these free spans // at the end of GC and eliminate this entirely. h.reclaim(npage) } // transfer stats from cache to global memstats.heap_scan += uint64(_g_.m.mcache.local_scan) _g_.m.mcache.local_scan = 0 memstats.tinyallocs += uint64(_g_.m.mcache.local_tinyallocs) _g_.m.mcache.local_tinyallocs = 0 s := h.allocSpanLocked(npage) if s != nil { // Record span info, because gc needs to be // able to map interior pointer to containing span. atomic.Store(&s.sweepgen, h.sweepgen) s.state = _MSpanInUse s.freelist = 0 s.ref = 0 s.sizeclass = uint8(sizeclass) if sizeclass == 0 { s.elemsize = s.npages << _PageShift s.divShift = 0 s.divMul = 0 s.divShift2 = 0 s.baseMask = 0 } else { s.elemsize = uintptr(class_to_size[sizeclass]) m := &class_to_divmagic[sizeclass] s.divShift = m.shift s.divMul = m.mul s.divShift2 = m.shift2 s.baseMask = m.baseMask } // update stats, sweep lists h.pagesInUse += uint64(npage) if large { memstats.heap_objects++ atomic.Xadd64(&memstats.heap_live, int64(npage<<_PageShift)) // Swept spans are at the end of lists. if s.npages < uintptr(len(h.free)) { h.busy[s.npages].insertBack(s) } else { h.busylarge.insertBack(s) } } } // heap_scan and heap_live were updated. if gcBlackenEnabled != 0 { gcController.revise() } if trace.enabled { traceHeapAlloc() } // h_spans is accessed concurrently without synchronization // from other threads. Hence, there must be a store/store // barrier here to ensure the writes to h_spans above happen // before the caller can publish a pointer p to an object // allocated from s. As soon as this happens, the garbage // collector running on another processor could read p and // look up s in h_spans. The unlock acts as the barrier to // order these writes. On the read side, the data dependency // between p and the index in h_spans orders the reads. unlock(&h.lock) return s } func (h *mheap) alloc(npage uintptr, sizeclass int32, large bool, needzero bool) *mspan { // Don't do any operations that lock the heap on the G stack. // It might trigger stack growth, and the stack growth code needs // to be able to allocate heap. var s *mspan systemstack(func() { s = h.alloc_m(npage, sizeclass, large) }) if s != nil { if needzero && s.needzero != 0 { memclr(unsafe.Pointer(s.start<<_PageShift), s.npages<<_PageShift) } s.needzero = 0 } return s } func (h *mheap) allocStack(npage uintptr) *mspan { _g_ := getg() if _g_ != _g_.m.g0 { throw("mheap_allocstack not on g0 stack") } lock(&h.lock) s := h.allocSpanLocked(npage) if s != nil { s.state = _MSpanStack s.freelist = 0 s.ref = 0 memstats.stacks_inuse += uint64(s.npages << _PageShift) } // This unlock acts as a release barrier. See mHeap_Alloc_m. unlock(&h.lock) return s } // Allocates a span of the given size. h must be locked. // The returned span has been removed from the // free list, but its state is still MSpanFree. func (h *mheap) allocSpanLocked(npage uintptr) *mspan { var list *mSpanList var s *mspan // Try in fixed-size lists up to max. for i := int(npage); i < len(h.free); i++ { list = &h.free[i] if !list.isEmpty() { s = list.first goto HaveSpan } } // Best fit in list of large spans. list = &h.freelarge s = h.allocLarge(npage) if s == nil { if !h.grow(npage) { return nil } s = h.allocLarge(npage) if s == nil { return nil } } HaveSpan: // Mark span in use. if s.state != _MSpanFree { throw("MHeap_AllocLocked - MSpan not free") } if s.npages < npage { throw("MHeap_AllocLocked - bad npages") } list.remove(s) if s.inList() { throw("still in list") } if s.npreleased > 0 { sysUsed(unsafe.Pointer(s.start<<_PageShift), s.npages<<_PageShift) memstats.heap_released -= uint64(s.npreleased << _PageShift) s.npreleased = 0 } if s.npages > npage { // Trim extra and put it back in the heap. t := (*mspan)(h.spanalloc.alloc()) t.init(s.start+pageID(npage), s.npages-npage) s.npages = npage p := uintptr(t.start) p -= (h.arena_start >> _PageShift) if p > 0 { h_spans[p-1] = s } h_spans[p] = t h_spans[p+t.npages-1] = t t.needzero = s.needzero s.state = _MSpanStack // prevent coalescing with s t.state = _MSpanStack h.freeSpanLocked(t, false, false, s.unusedsince) s.state = _MSpanFree } s.unusedsince = 0 p := uintptr(s.start) p -= (h.arena_start >> _PageShift) for n := uintptr(0); n < npage; n++ { h_spans[p+n] = s } memstats.heap_inuse += uint64(npage << _PageShift) memstats.heap_idle -= uint64(npage << _PageShift) //println("spanalloc", hex(s.start<<_PageShift)) if s.inList() { throw("still in list") } return s } // Allocate a span of exactly npage pages from the list of large spans. func (h *mheap) allocLarge(npage uintptr) *mspan { return bestFit(&h.freelarge, npage, nil) } // Search list for smallest span with >= npage pages. // If there are multiple smallest spans, take the one // with the earliest starting address. func bestFit(list *mSpanList, npage uintptr, best *mspan) *mspan { for s := list.first; s != nil; s = s.next { if s.npages < npage { continue } if best == nil || s.npages < best.npages || (s.npages == best.npages && s.start < best.start) { best = s } } return best } // Try to add at least npage pages of memory to the heap, // returning whether it worked. // // h must be locked. func (h *mheap) grow(npage uintptr) bool { // Ask for a big chunk, to reduce the number of mappings // the operating system needs to track; also amortizes // the overhead of an operating system mapping. // Allocate a multiple of 64kB. npage = round(npage, (64<<10)/_PageSize) ask := npage << _PageShift if ask < _HeapAllocChunk { ask = _HeapAllocChunk } v := h.sysAlloc(ask) if v == nil { if ask > npage<<_PageShift { ask = npage << _PageShift v = h.sysAlloc(ask) } if v == nil { print("runtime: out of memory: cannot allocate ", ask, "-byte block (", memstats.heap_sys, " in use)\n") return false } } // Create a fake "in use" span and free it, so that the // right coalescing happens. s := (*mspan)(h.spanalloc.alloc()) s.init(pageID(uintptr(v)>>_PageShift), ask>>_PageShift) p := uintptr(s.start) p -= (h.arena_start >> _PageShift) for i := p; i < p+s.npages; i++ { h_spans[i] = s } atomic.Store(&s.sweepgen, h.sweepgen) s.state = _MSpanInUse h.pagesInUse += uint64(s.npages) h.freeSpanLocked(s, false, true, 0) return true } // Look up the span at the given address. // Address is guaranteed to be in map // and is guaranteed to be start or end of span. func (h *mheap) lookup(v unsafe.Pointer) *mspan { p := uintptr(v) p -= h.arena_start return h_spans[p>>_PageShift] } // Look up the span at the given address. // Address is *not* guaranteed to be in map // and may be anywhere in the span. // Map entries for the middle of a span are only // valid for allocated spans. Free spans may have // other garbage in their middles, so we have to // check for that. func (h *mheap) lookupMaybe(v unsafe.Pointer) *mspan { if uintptr(v) < h.arena_start || uintptr(v) >= h.arena_used { return nil } p := uintptr(v) >> _PageShift q := p q -= h.arena_start >> _PageShift s := h_spans[q] if s == nil || p < uintptr(s.start) || uintptr(v) >= uintptr(unsafe.Pointer(s.limit)) || s.state != _MSpanInUse { return nil } return s } // Free the span back into the heap. func (h *mheap) freeSpan(s *mspan, acct int32) { systemstack(func() { mp := getg().m lock(&h.lock) memstats.heap_scan += uint64(mp.mcache.local_scan) mp.mcache.local_scan = 0 memstats.tinyallocs += uint64(mp.mcache.local_tinyallocs) mp.mcache.local_tinyallocs = 0 if acct != 0 { memstats.heap_objects-- } if gcBlackenEnabled != 0 { // heap_scan changed. gcController.revise() } h.freeSpanLocked(s, true, true, 0) unlock(&h.lock) }) } func (h *mheap) freeStack(s *mspan) { _g_ := getg() if _g_ != _g_.m.g0 { throw("mheap_freestack not on g0 stack") } s.needzero = 1 lock(&h.lock) memstats.stacks_inuse -= uint64(s.npages << _PageShift) h.freeSpanLocked(s, true, true, 0) unlock(&h.lock) } // s must be on a busy list (h.busy or h.busylarge) or unlinked. func (h *mheap) freeSpanLocked(s *mspan, acctinuse, acctidle bool, unusedsince int64) { switch s.state { case _MSpanStack: if s.ref != 0 { throw("MHeap_FreeSpanLocked - invalid stack free") } case _MSpanInUse: if s.ref != 0 || s.sweepgen != h.sweepgen { print("MHeap_FreeSpanLocked - span ", s, " ptr ", hex(s.start<<_PageShift), " ref ", s.ref, " sweepgen ", s.sweepgen, "/", h.sweepgen, "\n") throw("MHeap_FreeSpanLocked - invalid free") } h.pagesInUse -= uint64(s.npages) default: throw("MHeap_FreeSpanLocked - invalid span state") } if acctinuse { memstats.heap_inuse -= uint64(s.npages << _PageShift) } if acctidle { memstats.heap_idle += uint64(s.npages << _PageShift) } s.state = _MSpanFree if s.inList() { h.busyList(s.npages).remove(s) } // Stamp newly unused spans. The scavenger will use that // info to potentially give back some pages to the OS. s.unusedsince = unusedsince if unusedsince == 0 { s.unusedsince = nanotime() } s.npreleased = 0 // Coalesce with earlier, later spans. p := uintptr(s.start) p -= h.arena_start >> _PageShift if p > 0 { t := h_spans[p-1] if t != nil && t.state == _MSpanFree { s.start = t.start s.npages += t.npages s.npreleased = t.npreleased // absorb released pages s.needzero |= t.needzero p -= t.npages h_spans[p] = s h.freeList(t.npages).remove(t) t.state = _MSpanDead h.spanalloc.free(unsafe.Pointer(t)) } } if (p+s.npages)*sys.PtrSize < h.spans_mapped { t := h_spans[p+s.npages] if t != nil && t.state == _MSpanFree { s.npages += t.npages s.npreleased += t.npreleased s.needzero |= t.needzero h_spans[p+s.npages-1] = s h.freeList(t.npages).remove(t) t.state = _MSpanDead h.spanalloc.free(unsafe.Pointer(t)) } } // Insert s into appropriate list. h.freeList(s.npages).insert(s) } func (h *mheap) freeList(npages uintptr) *mSpanList { if npages < uintptr(len(h.free)) { return &h.free[npages] } return &h.freelarge } func (h *mheap) busyList(npages uintptr) *mSpanList { if npages < uintptr(len(h.free)) { return &h.busy[npages] } return &h.busylarge } func scavengelist(list *mSpanList, now, limit uint64) uintptr { if sys.PhysPageSize > _PageSize { // golang.org/issue/9993 // If the physical page size of the machine is larger than // our logical heap page size the kernel may round up the // amount to be freed to its page size and corrupt the heap // pages surrounding the unused block. return 0 } if list.isEmpty() { return 0 } var sumreleased uintptr for s := list.first; s != nil; s = s.next { if (now-uint64(s.unusedsince)) > limit && s.npreleased != s.npages { released := (s.npages - s.npreleased) << _PageShift memstats.heap_released += uint64(released) sumreleased += released s.npreleased = s.npages sysUnused(unsafe.Pointer(s.start<<_PageShift), s.npages<<_PageShift) } } return sumreleased } func (h *mheap) scavenge(k int32, now, limit uint64) { lock(&h.lock) var sumreleased uintptr for i := 0; i < len(h.free); i++ { sumreleased += scavengelist(&h.free[i], now, limit) } sumreleased += scavengelist(&h.freelarge, now, limit) unlock(&h.lock) if debug.gctrace > 0 { if sumreleased > 0 { print("scvg", k, ": ", sumreleased>>20, " MB released\n") } // TODO(dvyukov): these stats are incorrect as we don't subtract stack usage from heap. // But we can't call ReadMemStats on g0 holding locks. print("scvg", k, ": inuse: ", memstats.heap_inuse>>20, ", idle: ", memstats.heap_idle>>20, ", sys: ", memstats.heap_sys>>20, ", released: ", memstats.heap_released>>20, ", consumed: ", (memstats.heap_sys-memstats.heap_released)>>20, " (MB)\n") } } //go:linkname runtime_debug_freeOSMemory runtime/debug.freeOSMemory func runtime_debug_freeOSMemory() { gcStart(gcForceBlockMode, false) systemstack(func() { mheap_.scavenge(-1, ^uint64(0), 0) }) } // Initialize a new span with the given start and npages. func (span *mspan) init(start pageID, npages uintptr) { span.next = nil span.prev = nil span.list = nil span.start = start span.npages = npages span.freelist = 0 span.ref = 0 span.sizeclass = 0 span.incache = false span.elemsize = 0 span.state = _MSpanDead span.unusedsince = 0 span.npreleased = 0 span.speciallock.key = 0 span.specials = nil span.needzero = 0 } func (span *mspan) inList() bool { return span.prev != nil } // Initialize an empty doubly-linked list. func (list *mSpanList) init() { list.first = nil list.last = &list.first } func (list *mSpanList) remove(span *mspan) { if span.prev == nil || span.list != list { println("failed MSpanList_Remove", span, span.prev, span.list, list) throw("MSpanList_Remove") } if span.next != nil { span.next.prev = span.prev } else { // TODO: After we remove the span.list != list check above, // we could at least still check list.last == &span.next here. list.last = span.prev } *span.prev = span.next span.next = nil span.prev = nil span.list = nil } func (list *mSpanList) isEmpty() bool { return list.first == nil } func (list *mSpanList) insert(span *mspan) { if span.next != nil || span.prev != nil || span.list != nil { println("failed MSpanList_Insert", span, span.next, span.prev, span.list) throw("MSpanList_Insert") } span.next = list.first if list.first != nil { list.first.prev = &span.next } else { list.last = &span.next } list.first = span span.prev = &list.first span.list = list } func (list *mSpanList) insertBack(span *mspan) { if span.next != nil || span.prev != nil || span.list != nil { println("failed MSpanList_InsertBack", span, span.next, span.prev, span.list) throw("MSpanList_InsertBack") } span.next = nil span.prev = list.last *list.last = span list.last = &span.next span.list = list } const ( _KindSpecialFinalizer = 1 _KindSpecialProfile = 2 // Note: The finalizer special must be first because if we're freeing // an object, a finalizer special will cause the freeing operation // to abort, and we want to keep the other special records around // if that happens. ) type special struct { next *special // linked list in span offset uint16 // span offset of object kind byte // kind of special } // Adds the special record s to the list of special records for // the object p. All fields of s should be filled in except for // offset & next, which this routine will fill in. // Returns true if the special was successfully added, false otherwise. // (The add will fail only if a record with the same p and s->kind // already exists.) func addspecial(p unsafe.Pointer, s *special) bool { span := mheap_.lookupMaybe(p) if span == nil { throw("addspecial on invalid pointer") } // Ensure that the span is swept. // Sweeping accesses the specials list w/o locks, so we have // to synchronize with it. And it's just much safer. mp := acquirem() span.ensureSwept() offset := uintptr(p) - uintptr(span.start<<_PageShift) kind := s.kind lock(&span.speciallock) // Find splice point, check for existing record. t := &span.specials for { x := *t if x == nil { break } if offset == uintptr(x.offset) && kind == x.kind { unlock(&span.speciallock) releasem(mp) return false // already exists } if offset < uintptr(x.offset) || (offset == uintptr(x.offset) && kind < x.kind) { break } t = &x.next } // Splice in record, fill in offset. s.offset = uint16(offset) s.next = *t *t = s unlock(&span.speciallock) releasem(mp) return true } // Removes the Special record of the given kind for the object p. // Returns the record if the record existed, nil otherwise. // The caller must FixAlloc_Free the result. func removespecial(p unsafe.Pointer, kind uint8) *special { span := mheap_.lookupMaybe(p) if span == nil { throw("removespecial on invalid pointer") } // Ensure that the span is swept. // Sweeping accesses the specials list w/o locks, so we have // to synchronize with it. And it's just much safer. mp := acquirem() span.ensureSwept() offset := uintptr(p) - uintptr(span.start<<_PageShift) lock(&span.speciallock) t := &span.specials for { s := *t if s == nil { break } // This function is used for finalizers only, so we don't check for // "interior" specials (p must be exactly equal to s->offset). if offset == uintptr(s.offset) && kind == s.kind { *t = s.next unlock(&span.speciallock) releasem(mp) return s } t = &s.next } unlock(&span.speciallock) releasem(mp) return nil } // The described object has a finalizer set for it. type specialfinalizer struct { special special fn *funcval nret uintptr fint *_type ot *ptrtype } // Adds a finalizer to the object p. Returns true if it succeeded. func addfinalizer(p unsafe.Pointer, f *funcval, nret uintptr, fint *_type, ot *ptrtype) bool { lock(&mheap_.speciallock) s := (*specialfinalizer)(mheap_.specialfinalizeralloc.alloc()) unlock(&mheap_.speciallock) s.special.kind = _KindSpecialFinalizer s.fn = f s.nret = nret s.fint = fint s.ot = ot if addspecial(p, &s.special) { // This is responsible for maintaining the same // GC-related invariants as markrootSpans in any // situation where it's possible that markrootSpans // has already run but mark termination hasn't yet. if gcphase != _GCoff { _, base, _ := findObject(p) mp := acquirem() gcw := &mp.p.ptr().gcw // Mark everything reachable from the object // so it's retained for the finalizer. scanobject(uintptr(base), gcw) // Mark the finalizer itself, since the // special isn't part of the GC'd heap. scanblock(uintptr(unsafe.Pointer(&s.fn)), sys.PtrSize, &oneptrmask[0], gcw) if gcBlackenPromptly { gcw.dispose() } releasem(mp) } return true } // There was an old finalizer lock(&mheap_.speciallock) mheap_.specialfinalizeralloc.free(unsafe.Pointer(s)) unlock(&mheap_.speciallock) return false } // Removes the finalizer (if any) from the object p. func removefinalizer(p unsafe.Pointer) { s := (*specialfinalizer)(unsafe.Pointer(removespecial(p, _KindSpecialFinalizer))) if s == nil { return // there wasn't a finalizer to remove } lock(&mheap_.speciallock) mheap_.specialfinalizeralloc.free(unsafe.Pointer(s)) unlock(&mheap_.speciallock) } // The described object is being heap profiled. type specialprofile struct { special special b *bucket } // Set the heap profile bucket associated with addr to b. func setprofilebucket(p unsafe.Pointer, b *bucket) { lock(&mheap_.speciallock) s := (*specialprofile)(mheap_.specialprofilealloc.alloc()) unlock(&mheap_.speciallock) s.special.kind = _KindSpecialProfile s.b = b if !addspecial(p, &s.special) { throw("setprofilebucket: profile already set") } } // Do whatever cleanup needs to be done to deallocate s. It has // already been unlinked from the MSpan specials list. func freespecial(s *special, p unsafe.Pointer, size uintptr) { switch s.kind { case _KindSpecialFinalizer: sf := (*specialfinalizer)(unsafe.Pointer(s)) queuefinalizer(p, sf.fn, sf.nret, sf.fint, sf.ot) lock(&mheap_.speciallock) mheap_.specialfinalizeralloc.free(unsafe.Pointer(sf)) unlock(&mheap_.speciallock) case _KindSpecialProfile: sp := (*specialprofile)(unsafe.Pointer(s)) mProf_Free(sp.b, size) lock(&mheap_.speciallock) mheap_.specialprofilealloc.free(unsafe.Pointer(sp)) unlock(&mheap_.speciallock) default: throw("bad special kind") panic("not reached") } }