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683 lines
24 KiB
C++
683 lines
24 KiB
C++
// -*- Mode: C++; c-basic-offset: 2; indent-tabs-mode: nil -*-
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// Copyright (c) 2008, Google Inc.
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// All rights reserved.
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//
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// Redistribution and use in source and binary forms, with or without
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// modification, are permitted provided that the following conditions are
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// met:
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//
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// * Redistributions of source code must retain the above copyright
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// notice, this list of conditions and the following disclaimer.
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// * Redistributions in binary form must reproduce the above
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// copyright notice, this list of conditions and the following disclaimer
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// in the documentation and/or other materials provided with the
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// distribution.
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// * Neither the name of Google Inc. nor the names of its
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// contributors may be used to endorse or promote products derived from
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// this software without specific prior written permission.
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//
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// THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
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// "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
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// LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR
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// A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT
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// OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
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// SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT
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// LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
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// DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
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// THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
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// (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
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// OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
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// ---
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// Author: Sanjay Ghemawat <opensource@google.com>
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#include "config.h"
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#ifdef HAVE_INTTYPES_H
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#include <inttypes.h> // for PRIuPTR
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#endif
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#include <errno.h> // for ENOMEM, errno
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#include <gperftools/malloc_extension.h> // for MallocRange, etc
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#include "base/basictypes.h"
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#include "base/commandlineflags.h"
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#include "internal_logging.h" // for ASSERT, TCMalloc_Printer, etc
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#include "page_heap_allocator.h" // for PageHeapAllocator
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#include "static_vars.h" // for Static
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#include "system-alloc.h" // for TCMalloc_SystemAlloc, etc
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DEFINE_double(tcmalloc_release_rate,
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EnvToDouble("TCMALLOC_RELEASE_RATE", 1.0),
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"Rate at which we release unused memory to the system. "
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"Zero means we never release memory back to the system. "
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"Increase this flag to return memory faster; decrease it "
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"to return memory slower. Reasonable rates are in the "
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"range [0,10]");
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DEFINE_int64(tcmalloc_heap_limit_mb,
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EnvToInt("TCMALLOC_HEAP_LIMIT_MB", 0),
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"Limit total size of the process heap to the "
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"specified number of MiB. "
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"When we approach the limit the memory is released "
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"to the system more aggressively (more minor page faults). "
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"Zero means to allocate as long as system allows.");
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namespace tcmalloc {
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PageHeap::PageHeap()
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: pagemap_(MetaDataAlloc),
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pagemap_cache_(0),
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scavenge_counter_(0),
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// Start scavenging at kMaxPages list
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release_index_(kMaxPages),
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aggressive_decommit_(false) {
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COMPILE_ASSERT(kNumClasses <= (1 << PageMapCache::kValuebits), valuebits);
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DLL_Init(&large_.normal);
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DLL_Init(&large_.returned);
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for (int i = 0; i < kMaxPages; i++) {
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DLL_Init(&free_[i].normal);
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DLL_Init(&free_[i].returned);
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}
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}
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Span* PageHeap::SearchFreeAndLargeLists(Length n) {
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ASSERT(Check());
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ASSERT(n > 0);
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// Find first size >= n that has a non-empty list
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for (Length s = n; s < kMaxPages; s++) {
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Span* ll = &free_[s].normal;
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// If we're lucky, ll is non-empty, meaning it has a suitable span.
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if (!DLL_IsEmpty(ll)) {
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ASSERT(ll->next->location == Span::ON_NORMAL_FREELIST);
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return Carve(ll->next, n);
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}
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// Alternatively, maybe there's a usable returned span.
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ll = &free_[s].returned;
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if (!DLL_IsEmpty(ll)) {
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// We did not call EnsureLimit before, to avoid releasing the span
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// that will be taken immediately back.
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// Calling EnsureLimit here is not very expensive, as it fails only if
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// there is no more normal spans (and it fails efficiently)
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// or SystemRelease does not work (there is probably no returned spans).
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if (EnsureLimit(n)) {
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// ll may have became empty due to coalescing
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if (!DLL_IsEmpty(ll)) {
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ASSERT(ll->next->location == Span::ON_RETURNED_FREELIST);
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return Carve(ll->next, n);
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}
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}
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}
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}
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// No luck in free lists, our last chance is in a larger class.
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return AllocLarge(n); // May be NULL
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}
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static const size_t kForcedCoalesceInterval = 128*1024*1024;
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Span* PageHeap::New(Length n) {
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ASSERT(Check());
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ASSERT(n > 0);
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Span* result = SearchFreeAndLargeLists(n);
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if (result != NULL)
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return result;
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if (stats_.free_bytes != 0 && stats_.unmapped_bytes != 0
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&& stats_.free_bytes + stats_.unmapped_bytes >= stats_.system_bytes / 4
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&& (stats_.system_bytes / kForcedCoalesceInterval
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!= (stats_.system_bytes + (n << kPageShift)) / kForcedCoalesceInterval)) {
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// We're about to grow heap, but there are lots of free pages.
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// tcmalloc's design decision to keep unmapped and free spans
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// separately and never coalesce them means that sometimes there
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// can be free pages span of sufficient size, but it consists of
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// "segments" of different type so page heap search cannot find
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// it. In order to prevent growing heap and wasting memory in such
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// case we're going to unmap all free pages. So that all free
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// spans are maximally coalesced.
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//
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// We're also limiting 'rate' of going into this path to be at
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// most once per 128 megs of heap growth. Otherwise programs that
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// grow heap frequently (and that means by small amount) could be
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// penalized with higher count of minor page faults.
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//
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// See also large_heap_fragmentation_unittest.cc and
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// https://code.google.com/p/gperftools/issues/detail?id=368
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ReleaseAtLeastNPages(static_cast<Length>(0x7fffffff));
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// then try again. If we are forced to grow heap because of large
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// spans fragmentation and not because of problem described above,
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// then at the very least we've just unmapped free but
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// insufficiently big large spans back to OS. So in case of really
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// unlucky memory fragmentation we'll be consuming virtual address
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// space, but not real memory
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result = SearchFreeAndLargeLists(n);
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if (result != NULL) return result;
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}
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// Grow the heap and try again.
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if (!GrowHeap(n)) {
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ASSERT(stats_.unmapped_bytes+ stats_.committed_bytes==stats_.system_bytes);
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ASSERT(Check());
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// underlying SysAllocator likely set ENOMEM but we can get here
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// due to EnsureLimit so we set it here too.
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//
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// Setting errno to ENOMEM here allows us to avoid dealing with it
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// in fast-path.
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errno = ENOMEM;
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return NULL;
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}
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return SearchFreeAndLargeLists(n);
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}
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Span* PageHeap::AllocLarge(Length n) {
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// find the best span (closest to n in size).
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// The following loops implements address-ordered best-fit.
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Span *best = NULL;
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// Search through normal list
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for (Span* span = large_.normal.next;
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span != &large_.normal;
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span = span->next) {
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if (span->length >= n) {
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if ((best == NULL)
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|| (span->length < best->length)
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|| ((span->length == best->length) && (span->start < best->start))) {
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best = span;
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ASSERT(best->location == Span::ON_NORMAL_FREELIST);
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}
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}
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}
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Span *bestNormal = best;
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// Search through released list in case it has a better fit
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for (Span* span = large_.returned.next;
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span != &large_.returned;
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span = span->next) {
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if (span->length >= n) {
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if ((best == NULL)
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|| (span->length < best->length)
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|| ((span->length == best->length) && (span->start < best->start))) {
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best = span;
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ASSERT(best->location == Span::ON_RETURNED_FREELIST);
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}
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}
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}
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if (best == bestNormal) {
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return best == NULL ? NULL : Carve(best, n);
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}
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// best comes from returned list.
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if (EnsureLimit(n, false)) {
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return Carve(best, n);
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}
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if (EnsureLimit(n, true)) {
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// best could have been destroyed by coalescing.
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// bestNormal is not a best-fit, and it could be destroyed as well.
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// We retry, the limit is already ensured:
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return AllocLarge(n);
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}
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// If bestNormal existed, EnsureLimit would succeeded:
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ASSERT(bestNormal == NULL);
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// We are not allowed to take best from returned list.
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return NULL;
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}
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Span* PageHeap::Split(Span* span, Length n) {
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ASSERT(0 < n);
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ASSERT(n < span->length);
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ASSERT(span->location == Span::IN_USE);
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ASSERT(span->sizeclass == 0);
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Event(span, 'T', n);
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const int extra = span->length - n;
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Span* leftover = NewSpan(span->start + n, extra);
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ASSERT(leftover->location == Span::IN_USE);
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Event(leftover, 'U', extra);
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RecordSpan(leftover);
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pagemap_.set(span->start + n - 1, span); // Update map from pageid to span
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span->length = n;
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return leftover;
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}
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void PageHeap::CommitSpan(Span* span) {
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TCMalloc_SystemCommit(reinterpret_cast<void*>(span->start << kPageShift),
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static_cast<size_t>(span->length << kPageShift));
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stats_.committed_bytes += span->length << kPageShift;
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}
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bool PageHeap::DecommitSpan(Span* span) {
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bool rv = TCMalloc_SystemRelease(reinterpret_cast<void*>(span->start << kPageShift),
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static_cast<size_t>(span->length << kPageShift));
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if (rv) {
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stats_.committed_bytes -= span->length << kPageShift;
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}
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return rv;
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}
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Span* PageHeap::Carve(Span* span, Length n) {
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ASSERT(n > 0);
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ASSERT(span->location != Span::IN_USE);
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const int old_location = span->location;
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RemoveFromFreeList(span);
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span->location = Span::IN_USE;
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Event(span, 'A', n);
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const int extra = span->length - n;
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ASSERT(extra >= 0);
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if (extra > 0) {
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Span* leftover = NewSpan(span->start + n, extra);
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leftover->location = old_location;
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Event(leftover, 'S', extra);
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RecordSpan(leftover);
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// The previous span of |leftover| was just splitted -- no need to
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// coalesce them. The next span of |leftover| was not previously coalesced
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// with |span|, i.e. is NULL or has got location other than |old_location|.
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#ifndef NDEBUG
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const PageID p = leftover->start;
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const Length len = leftover->length;
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Span* next = GetDescriptor(p+len);
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ASSERT (next == NULL ||
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next->location == Span::IN_USE ||
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next->location != leftover->location);
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#endif
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PrependToFreeList(leftover); // Skip coalescing - no candidates possible
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span->length = n;
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pagemap_.set(span->start + n - 1, span);
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}
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ASSERT(Check());
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if (old_location == Span::ON_RETURNED_FREELIST) {
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// We need to recommit this address space.
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CommitSpan(span);
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}
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ASSERT(span->location == Span::IN_USE);
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ASSERT(span->length == n);
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ASSERT(stats_.unmapped_bytes+ stats_.committed_bytes==stats_.system_bytes);
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return span;
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}
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void PageHeap::Delete(Span* span) {
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ASSERT(Check());
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ASSERT(span->location == Span::IN_USE);
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ASSERT(span->length > 0);
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ASSERT(GetDescriptor(span->start) == span);
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ASSERT(GetDescriptor(span->start + span->length - 1) == span);
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const Length n = span->length;
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span->sizeclass = 0;
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span->sample = 0;
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span->location = Span::ON_NORMAL_FREELIST;
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Event(span, 'D', span->length);
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MergeIntoFreeList(span); // Coalesces if possible
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IncrementalScavenge(n);
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ASSERT(stats_.unmapped_bytes+ stats_.committed_bytes==stats_.system_bytes);
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ASSERT(Check());
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}
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bool PageHeap::MayMergeSpans(Span *span, Span *other) {
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if (aggressive_decommit_) {
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return other->location != Span::IN_USE;
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}
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return span->location == other->location;
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}
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void PageHeap::MergeIntoFreeList(Span* span) {
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ASSERT(span->location != Span::IN_USE);
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// Coalesce -- we guarantee that "p" != 0, so no bounds checking
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// necessary. We do not bother resetting the stale pagemap
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// entries for the pieces we are merging together because we only
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// care about the pagemap entries for the boundaries.
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//
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// Note: depending on aggressive_decommit_ mode we allow only
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// similar spans to be coalesced.
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//
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// The following applies if aggressive_decommit_ is enabled:
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//
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// Note that the adjacent spans we merge into "span" may come out of a
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// "normal" (committed) list, and cleanly merge with our IN_USE span, which
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// is implicitly committed. If the adjacents spans are on the "returned"
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// (decommitted) list, then we must get both spans into the same state before
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// or after we coalesce them. The current code always decomits. This is
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// achieved by blindly decommitting the entire coalesced region, which may
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// include any combination of committed and decommitted spans, at the end of
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// the method.
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// TODO(jar): "Always decommit" causes some extra calls to commit when we are
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// called in GrowHeap() during an allocation :-/. We need to eval the cost of
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// that oscillation, and possibly do something to reduce it.
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// TODO(jar): We need a better strategy for deciding to commit, or decommit,
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// based on memory usage and free heap sizes.
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uint64_t temp_committed = 0;
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const PageID p = span->start;
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const Length n = span->length;
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Span* prev = GetDescriptor(p-1);
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if (prev != NULL && MayMergeSpans(span, prev)) {
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// Merge preceding span into this span
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ASSERT(prev->start + prev->length == p);
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const Length len = prev->length;
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if (aggressive_decommit_ && prev->location == Span::ON_RETURNED_FREELIST) {
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// We're about to put the merge span into the returned freelist and call
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// DecommitSpan() on it, which will mark the entire span including this
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// one as released and decrease stats_.committed_bytes by the size of the
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// merged span. To make the math work out we temporarily increase the
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// stats_.committed_bytes amount.
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temp_committed = prev->length << kPageShift;
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}
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RemoveFromFreeList(prev);
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DeleteSpan(prev);
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span->start -= len;
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span->length += len;
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pagemap_.set(span->start, span);
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Event(span, 'L', len);
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}
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Span* next = GetDescriptor(p+n);
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if (next != NULL && MayMergeSpans(span, next)) {
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// Merge next span into this span
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ASSERT(next->start == p+n);
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const Length len = next->length;
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if (aggressive_decommit_ && next->location == Span::ON_RETURNED_FREELIST) {
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// See the comment below 'if (prev->location ...' for explanation.
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temp_committed += next->length << kPageShift;
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}
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RemoveFromFreeList(next);
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DeleteSpan(next);
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span->length += len;
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pagemap_.set(span->start + span->length - 1, span);
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Event(span, 'R', len);
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}
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if (aggressive_decommit_) {
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if (DecommitSpan(span)) {
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span->location = Span::ON_RETURNED_FREELIST;
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stats_.committed_bytes += temp_committed;
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} else {
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ASSERT(temp_committed == 0);
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}
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}
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PrependToFreeList(span);
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}
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void PageHeap::PrependToFreeList(Span* span) {
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ASSERT(span->location != Span::IN_USE);
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SpanList* list = (span->length < kMaxPages) ? &free_[span->length] : &large_;
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if (span->location == Span::ON_NORMAL_FREELIST) {
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stats_.free_bytes += (span->length << kPageShift);
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DLL_Prepend(&list->normal, span);
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} else {
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stats_.unmapped_bytes += (span->length << kPageShift);
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DLL_Prepend(&list->returned, span);
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}
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}
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void PageHeap::RemoveFromFreeList(Span* span) {
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ASSERT(span->location != Span::IN_USE);
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if (span->location == Span::ON_NORMAL_FREELIST) {
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stats_.free_bytes -= (span->length << kPageShift);
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} else {
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stats_.unmapped_bytes -= (span->length << kPageShift);
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}
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DLL_Remove(span);
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}
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void PageHeap::IncrementalScavenge(Length n) {
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// Fast path; not yet time to release memory
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scavenge_counter_ -= n;
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if (scavenge_counter_ >= 0) return; // Not yet time to scavenge
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const double rate = FLAGS_tcmalloc_release_rate;
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if (rate <= 1e-6) {
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// Tiny release rate means that releasing is disabled.
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scavenge_counter_ = kDefaultReleaseDelay;
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return;
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}
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Length released_pages = ReleaseAtLeastNPages(1);
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if (released_pages == 0) {
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// Nothing to scavenge, delay for a while.
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scavenge_counter_ = kDefaultReleaseDelay;
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} else {
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// Compute how long to wait until we return memory.
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// FLAGS_tcmalloc_release_rate==1 means wait for 1000 pages
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// after releasing one page.
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const double mult = 1000.0 / rate;
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double wait = mult * static_cast<double>(released_pages);
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if (wait > kMaxReleaseDelay) {
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// Avoid overflow and bound to reasonable range.
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wait = kMaxReleaseDelay;
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}
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scavenge_counter_ = static_cast<int64_t>(wait);
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}
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}
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Length PageHeap::ReleaseLastNormalSpan(SpanList* slist) {
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Span* s = slist->normal.prev;
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ASSERT(s->location == Span::ON_NORMAL_FREELIST);
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if (DecommitSpan(s)) {
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RemoveFromFreeList(s);
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const Length n = s->length;
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s->location = Span::ON_RETURNED_FREELIST;
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MergeIntoFreeList(s); // Coalesces if possible.
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return n;
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}
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return 0;
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}
|
|
|
|
Length PageHeap::ReleaseAtLeastNPages(Length num_pages) {
|
|
Length released_pages = 0;
|
|
|
|
// Round robin through the lists of free spans, releasing the last
|
|
// span in each list. Stop after releasing at least num_pages
|
|
// or when there is nothing more to release.
|
|
while (released_pages < num_pages && stats_.free_bytes > 0) {
|
|
for (int i = 0; i < kMaxPages+1 && released_pages < num_pages;
|
|
i++, release_index_++) {
|
|
if (release_index_ > kMaxPages) release_index_ = 0;
|
|
SpanList* slist = (release_index_ == kMaxPages) ?
|
|
&large_ : &free_[release_index_];
|
|
if (!DLL_IsEmpty(&slist->normal)) {
|
|
Length released_len = ReleaseLastNormalSpan(slist);
|
|
// Some systems do not support release
|
|
if (released_len == 0) return released_pages;
|
|
released_pages += released_len;
|
|
}
|
|
}
|
|
}
|
|
return released_pages;
|
|
}
|
|
|
|
bool PageHeap::EnsureLimit(Length n, bool withRelease)
|
|
{
|
|
Length limit = (FLAGS_tcmalloc_heap_limit_mb*1024*1024) >> kPageShift;
|
|
if (limit == 0) return true; //there is no limit
|
|
|
|
// We do not use stats_.system_bytes because it does not take
|
|
// MetaDataAllocs into account.
|
|
Length takenPages = TCMalloc_SystemTaken >> kPageShift;
|
|
//XXX takenPages may be slightly bigger than limit for two reasons:
|
|
//* MetaDataAllocs ignore the limit (it is not easy to handle
|
|
// out of memory there)
|
|
//* sys_alloc may round allocation up to huge page size,
|
|
// although smaller limit was ensured
|
|
|
|
ASSERT(takenPages >= stats_.unmapped_bytes >> kPageShift);
|
|
takenPages -= stats_.unmapped_bytes >> kPageShift;
|
|
|
|
if (takenPages + n > limit && withRelease) {
|
|
takenPages -= ReleaseAtLeastNPages(takenPages + n - limit);
|
|
}
|
|
|
|
return takenPages + n <= limit;
|
|
}
|
|
|
|
void PageHeap::RegisterSizeClass(Span* span, size_t sc) {
|
|
// Associate span object with all interior pages as well
|
|
ASSERT(span->location == Span::IN_USE);
|
|
ASSERT(GetDescriptor(span->start) == span);
|
|
ASSERT(GetDescriptor(span->start+span->length-1) == span);
|
|
Event(span, 'C', sc);
|
|
span->sizeclass = sc;
|
|
for (Length i = 1; i < span->length-1; i++) {
|
|
pagemap_.set(span->start+i, span);
|
|
}
|
|
}
|
|
|
|
void PageHeap::GetSmallSpanStats(SmallSpanStats* result) {
|
|
for (int s = 0; s < kMaxPages; s++) {
|
|
result->normal_length[s] = DLL_Length(&free_[s].normal);
|
|
result->returned_length[s] = DLL_Length(&free_[s].returned);
|
|
}
|
|
}
|
|
|
|
void PageHeap::GetLargeSpanStats(LargeSpanStats* result) {
|
|
result->spans = 0;
|
|
result->normal_pages = 0;
|
|
result->returned_pages = 0;
|
|
for (Span* s = large_.normal.next; s != &large_.normal; s = s->next) {
|
|
result->normal_pages += s->length;;
|
|
result->spans++;
|
|
}
|
|
for (Span* s = large_.returned.next; s != &large_.returned; s = s->next) {
|
|
result->returned_pages += s->length;
|
|
result->spans++;
|
|
}
|
|
}
|
|
|
|
bool PageHeap::GetNextRange(PageID start, base::MallocRange* r) {
|
|
Span* span = reinterpret_cast<Span*>(pagemap_.Next(start));
|
|
if (span == NULL) {
|
|
return false;
|
|
}
|
|
r->address = span->start << kPageShift;
|
|
r->length = span->length << kPageShift;
|
|
r->fraction = 0;
|
|
switch (span->location) {
|
|
case Span::IN_USE:
|
|
r->type = base::MallocRange::INUSE;
|
|
r->fraction = 1;
|
|
if (span->sizeclass > 0) {
|
|
// Only some of the objects in this span may be in use.
|
|
const size_t osize = Static::sizemap()->class_to_size(span->sizeclass);
|
|
r->fraction = (1.0 * osize * span->refcount) / r->length;
|
|
}
|
|
break;
|
|
case Span::ON_NORMAL_FREELIST:
|
|
r->type = base::MallocRange::FREE;
|
|
break;
|
|
case Span::ON_RETURNED_FREELIST:
|
|
r->type = base::MallocRange::UNMAPPED;
|
|
break;
|
|
default:
|
|
r->type = base::MallocRange::UNKNOWN;
|
|
break;
|
|
}
|
|
return true;
|
|
}
|
|
|
|
static void RecordGrowth(size_t growth) {
|
|
StackTrace* t = Static::stacktrace_allocator()->New();
|
|
t->depth = GetStackTrace(t->stack, kMaxStackDepth-1, 3);
|
|
t->size = growth;
|
|
t->stack[kMaxStackDepth-1] = reinterpret_cast<void*>(Static::growth_stacks());
|
|
Static::set_growth_stacks(t);
|
|
}
|
|
|
|
bool PageHeap::GrowHeap(Length n) {
|
|
ASSERT(kMaxPages >= kMinSystemAlloc);
|
|
if (n > kMaxValidPages) return false;
|
|
Length ask = (n>kMinSystemAlloc) ? n : static_cast<Length>(kMinSystemAlloc);
|
|
size_t actual_size;
|
|
void* ptr = NULL;
|
|
if (EnsureLimit(ask)) {
|
|
ptr = TCMalloc_SystemAlloc(ask << kPageShift, &actual_size, kPageSize);
|
|
}
|
|
if (ptr == NULL) {
|
|
if (n < ask) {
|
|
// Try growing just "n" pages
|
|
ask = n;
|
|
if (EnsureLimit(ask)) {
|
|
ptr = TCMalloc_SystemAlloc(ask << kPageShift, &actual_size, kPageSize);
|
|
}
|
|
}
|
|
if (ptr == NULL) return false;
|
|
}
|
|
ask = actual_size >> kPageShift;
|
|
RecordGrowth(ask << kPageShift);
|
|
|
|
uint64_t old_system_bytes = stats_.system_bytes;
|
|
stats_.system_bytes += (ask << kPageShift);
|
|
stats_.committed_bytes += (ask << kPageShift);
|
|
const PageID p = reinterpret_cast<uintptr_t>(ptr) >> kPageShift;
|
|
ASSERT(p > 0);
|
|
|
|
// If we have already a lot of pages allocated, just pre allocate a bunch of
|
|
// memory for the page map. This prevents fragmentation by pagemap metadata
|
|
// when a program keeps allocating and freeing large blocks.
|
|
|
|
if (old_system_bytes < kPageMapBigAllocationThreshold
|
|
&& stats_.system_bytes >= kPageMapBigAllocationThreshold) {
|
|
pagemap_.PreallocateMoreMemory();
|
|
}
|
|
|
|
// Make sure pagemap_ has entries for all of the new pages.
|
|
// Plus ensure one before and one after so coalescing code
|
|
// does not need bounds-checking.
|
|
if (pagemap_.Ensure(p-1, ask+2)) {
|
|
// Pretend the new area is allocated and then Delete() it to cause
|
|
// any necessary coalescing to occur.
|
|
Span* span = NewSpan(p, ask);
|
|
RecordSpan(span);
|
|
Delete(span);
|
|
ASSERT(stats_.unmapped_bytes+ stats_.committed_bytes==stats_.system_bytes);
|
|
ASSERT(Check());
|
|
return true;
|
|
} else {
|
|
// We could not allocate memory within "pagemap_"
|
|
// TODO: Once we can return memory to the system, return the new span
|
|
return false;
|
|
}
|
|
}
|
|
|
|
bool PageHeap::Check() {
|
|
ASSERT(free_[0].normal.next == &free_[0].normal);
|
|
ASSERT(free_[0].returned.next == &free_[0].returned);
|
|
return true;
|
|
}
|
|
|
|
bool PageHeap::CheckExpensive() {
|
|
bool result = Check();
|
|
CheckList(&large_.normal, kMaxPages, 1000000000, Span::ON_NORMAL_FREELIST);
|
|
CheckList(&large_.returned, kMaxPages, 1000000000, Span::ON_RETURNED_FREELIST);
|
|
for (Length s = 1; s < kMaxPages; s++) {
|
|
CheckList(&free_[s].normal, s, s, Span::ON_NORMAL_FREELIST);
|
|
CheckList(&free_[s].returned, s, s, Span::ON_RETURNED_FREELIST);
|
|
}
|
|
return result;
|
|
}
|
|
|
|
bool PageHeap::CheckList(Span* list, Length min_pages, Length max_pages,
|
|
int freelist) {
|
|
for (Span* s = list->next; s != list; s = s->next) {
|
|
CHECK_CONDITION(s->location == freelist); // NORMAL or RETURNED
|
|
CHECK_CONDITION(s->length >= min_pages);
|
|
CHECK_CONDITION(s->length <= max_pages);
|
|
CHECK_CONDITION(GetDescriptor(s->start) == s);
|
|
CHECK_CONDITION(GetDescriptor(s->start+s->length-1) == s);
|
|
}
|
|
return true;
|
|
}
|
|
|
|
} // namespace tcmalloc
|