third_party/tcmalloc/vendor/src/page_heap.h - chromium/src - Git at Google

 // -*- Mode: C++; c-basic-offset: 2; indent-tabs-mode: nil -*-
 // Copyright (c) 2008, Google Inc.
 // All rights reserved.
 //
 // Redistribution and use in source and binary forms, with or without
 // modification, are permitted provided that the following conditions are
 // met:
 //
 //     * Redistributions of source code must retain the above copyright
 // notice, this list of conditions and the following disclaimer.
 //     * Redistributions in binary form must reproduce the above
 // copyright notice, this list of conditions and the following disclaimer
 // in the documentation and/or other materials provided with the
 // distribution.
 //     * Neither the name of Google Inc. nor the names of its
 // contributors may be used to endorse or promote products derived from
 // this software without specific prior written permission.
 //
 // THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
 // "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
 // LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR
 // A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT
 // OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
 // SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT
 // LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
 // DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
 // THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
 // (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
 // OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.

 // ---
 // Author: Sanjay Ghemawat <opensource@google.com>

 #ifndef TCMALLOC_PAGE_HEAP_H_
 #define TCMALLOC_PAGE_HEAP_H_

 #include <config.h>
 #include <stddef.h>                     // for size_t
 #ifdef HAVE_STDINT_H
 #include <stdint.h>                     // for uint64_t, int64_t, uint16_t
 #endif
 #include <gperftools/malloc_extension.h>
 #include "base/basictypes.h"
 #include "common.h"
 #include "packed-cache-inl.h"
 #include "pagemap.h"
 #include "span.h"

 // We need to dllexport PageHeap just for the unittest.  MSVC complains
 // that we don't dllexport the PageHeap members, but we don't need to
 // test those, so I just suppress this warning.
 #ifdef _MSC_VER
 #pragma warning(push)
 #pragma warning(disable:4251)
 #endif

 // This #ifdef should almost never be set.  Set NO_TCMALLOC_SAMPLES if
 // you're porting to a system where you really can't get a stacktrace.
 // Because we control the definition of GetStackTrace, all clients of
 // GetStackTrace should #include us rather than stacktrace.h.
 #ifdef NO_TCMALLOC_SAMPLES
   // We use #define so code compiles even if you #include stacktrace.h somehow.
 # define GetStackTrace(stack, depth, skip)  (0)
 #else
 # include <gperftools/stacktrace.h>
 #endif

 namespace base {
 struct MallocRange;
 }

 namespace tcmalloc {

 // -------------------------------------------------------------------------
 // Map from page-id to per-page data
 // -------------------------------------------------------------------------

 // We use PageMap2<> for 32-bit and PageMap3<> for 64-bit machines.
 // We also use a simple one-level cache for hot PageID-to-sizeclass mappings,
 // because sometimes the sizeclass is all the information we need.

 // Selector class -- general selector uses 3-level map
 template <int BITS> class MapSelector {
  public:
   typedef TCMalloc_PageMap3<BITS-kPageShift> Type;
 };

 #ifndef TCMALLOC_SMALL_BUT_SLOW
 // x86-64 and arm64 are using 48 bits of address space. So we can use
 // just two level map, but since initial ram consumption of this mode
 // is a bit on the higher side, we opt-out of it in
 // TCMALLOC_SMALL_BUT_SLOW mode.
 template <> class MapSelector<48> {
  public:
   typedef TCMalloc_PageMap2<48-kPageShift> Type;
 };

 #endif // TCMALLOC_SMALL_BUT_SLOW

 // A two-level map for 32-bit machines
 template <> class MapSelector<32> {
  public:
   typedef TCMalloc_PageMap2<32-kPageShift> Type;
 };

 // -------------------------------------------------------------------------
 // Page-level allocator
 //  * Eager coalescing
 //
 // Heap for page-level allocation.  We allow allocating and freeing a
 // contiguous runs of pages (called a "span").
 // -------------------------------------------------------------------------

 class PERFTOOLS_DLL_DECL PageHeap {
  public:
   PageHeap();

   // Allocate a run of "n" pages.  Returns zero if out of memory.
   // Caller should not pass "n == 0" -- instead, n should have
   // been rounded up already.
   Span* New(Length n);

   // Delete the span "[p, p+n-1]".
   // REQUIRES: span was returned by earlier call to New() and
   //           has not yet been deleted.
   void Delete(Span* span);

   // Mark an allocated span as being used for small objects of the
   // specified size-class.
   // REQUIRES: span was returned by an earlier call to New()
   //           and has not yet been deleted.
   void RegisterSizeClass(Span* span, uint32 sc);

   // Split an allocated span into two spans: one of length "n" pages
   // followed by another span of length "span->length - n" pages.
   // Modifies "*span" to point to the first span of length "n" pages.
   // Returns a pointer to the second span.
   //
   // REQUIRES: "0 < n < span->length"
   // REQUIRES: span->location == IN_USE
   // REQUIRES: span->sizeclass == 0
   Span* Split(Span* span, Length n);

   // Return the descriptor for the specified page.  Returns NULL if
   // this PageID was not allocated previously.
   inline ATTRIBUTE_ALWAYS_INLINE
   Span* GetDescriptor(PageID p) const {
     return reinterpret_cast<Span*>(pagemap_.get(p));
   }

   // If this page heap is managing a range with starting page # >= start,
   // store info about the range in *r and return true.  Else return false.
   bool GetNextRange(PageID start, base::MallocRange* r);

   // Page heap statistics
   struct Stats {
     Stats() : system_bytes(0), free_bytes(0), unmapped_bytes(0), committed_bytes(0),
         scavenge_count(0), commit_count(0), total_commit_bytes(0),
         decommit_count(0), total_decommit_bytes(0),
         reserve_count(0), total_reserve_bytes(0) {}
     uint64_t system_bytes;    // Total bytes allocated from system
     uint64_t free_bytes;      // Total bytes on normal freelists
     uint64_t unmapped_bytes;  // Total bytes on returned freelists
     uint64_t committed_bytes;  // Bytes committed, always <= system_bytes_.

     uint64_t scavenge_count;   // Number of times scavagened flush pages

     uint64_t commit_count;          // Number of virtual memory commits
     uint64_t total_commit_bytes;    // Bytes committed in lifetime of process
     uint64_t decommit_count;        // Number of virtual memory decommits
     uint64_t total_decommit_bytes;  // Bytes decommitted in lifetime of process

     uint64_t reserve_count;         // Number of virtual memory reserves
     uint64_t total_reserve_bytes;   // Bytes reserved in lifetime of process
   };
   inline Stats stats() const { return stats_; }

   struct SmallSpanStats {
     // For each free list of small spans, the length (in spans) of the
     // normal and returned free lists for that size.
     //
     // NOTE: index 'i' accounts the number of spans of length 'i + 1'.
     int64 normal_length[kMaxPages];
     int64 returned_length[kMaxPages];
   };
   void GetSmallSpanStats(SmallSpanStats* result);

   // Stats for free large spans (i.e., spans with more than kMaxPages pages).
   struct LargeSpanStats {
     int64 spans;           // Number of such spans
     int64 normal_pages;    // Combined page length of normal large spans
     int64 returned_pages;  // Combined page length of unmapped spans
   };
   void GetLargeSpanStats(LargeSpanStats* result);

   bool Check();
   // Like Check() but does some more comprehensive checking.
   bool CheckExpensive();
   bool CheckList(Span* list, Length min_pages, Length max_pages,
                  int freelist);  // ON_NORMAL_FREELIST or ON_RETURNED_FREELIST
   bool CheckSet(SpanSet *s, Length min_pages, int freelist);

   // Try to release at least num_pages for reuse by the OS.  Returns
   // the actual number of pages released, which may be less than
   // num_pages if there weren't enough pages to release. The result
   // may also be larger than num_pages since page_heap might decide to
   // release one large range instead of fragmenting it into two
   // smaller released and unreleased ranges.
   Length ReleaseAtLeastNPages(Length num_pages);

   // Reads and writes to pagemap_cache_ do not require locking.
   bool TryGetSizeClass(PageID p, uint32* out) const {
     return pagemap_cache_.TryGet(p, out);
   }
   void SetCachedSizeClass(PageID p, uint32 cl) {
     ASSERT(cl != 0);
     pagemap_cache_.Put(p, cl);
   }
   void InvalidateCachedSizeClass(PageID p) { pagemap_cache_.Invalidate(p); }
   uint32 GetSizeClassOrZero(PageID p) const {
     uint32 cached_value;
     if (!TryGetSizeClass(p, &cached_value)) {
       cached_value = 0;
     }
     return cached_value;
   }

   bool GetAggressiveDecommit(void) {return aggressive_decommit_;}
   void SetAggressiveDecommit(bool aggressive_decommit) {
     aggressive_decommit_ = aggressive_decommit;
   }

  private:
   // Allocates a big block of memory for the pagemap once we reach more than
   // 128MB
   static const size_t kPageMapBigAllocationThreshold = 128 << 20;

   // Minimum number of pages to fetch from system at a time.  Must be
   // significantly bigger than kBlockSize to amortize system-call
   // overhead, and also to reduce external fragementation.  Also, we
   // should keep this value big because various incarnations of Linux
   // have small limits on the number of mmap() regions per
   // address-space.
   // REQUIRED: kMinSystemAlloc <= kMaxPages;
   static const int kMinSystemAlloc = kMaxPages;

   // Never delay scavenging for more than the following number of
   // deallocated pages.  With 4K pages, this comes to 4GB of
   // deallocation.
   static const int kMaxReleaseDelay = 1 << 20;

   // If there is nothing to release, wait for so many pages before
   // scavenging again.  With 4K pages, this comes to 1GB of memory.
   static const int kDefaultReleaseDelay = 1 << 18;

   // Pick the appropriate map and cache types based on pointer size
   typedef MapSelector<kAddressBits>::Type PageMap;
   typedef PackedCache<kAddressBits - kPageShift> PageMapCache;
   mutable PageMapCache pagemap_cache_;
   PageMap pagemap_;

   // We segregate spans of a given size into two circular linked
   // lists: one for normal spans, and one for spans whose memory
   // has been returned to the system.
   struct SpanList {
     Span        normal;
     Span        returned;
   };

   // Sets of spans with length > kMaxPages.
   //
   // Rather than using a linked list, we use sets here for efficient
   // best-fit search.
   SpanSet large_normal_;
   SpanSet large_returned_;

   // Array mapping from span length to a doubly linked list of free spans
   //
   // NOTE: index 'i' stores spans of length 'i + 1'.
   SpanList free_[kMaxPages];

   // Statistics on system, free, and unmapped bytes
   Stats stats_;

   Span* SearchFreeAndLargeLists(Length n);

   bool GrowHeap(Length n);

   // REQUIRES: span->length >= n
   // REQUIRES: span->location != IN_USE
   // Remove span from its free list, and move any leftover part of
   // span into appropriate free lists.  Also update "span" to have
   // length exactly "n" and mark it as non-free so it can be returned
   // to the client.  After all that, decrease free_pages_ by n and
   // return span.
   Span* Carve(Span* span, Length n);

   void RecordSpan(Span* span) {
     pagemap_.set(span->start, span);
     if (span->length > 1) {
       pagemap_.set(span->start + span->length - 1, span);
     }
   }

   // Allocate a large span of length == n.  If successful, returns a
   // span of exactly the specified length.  Else, returns NULL.
   Span* AllocLarge(Length n);

   // Coalesce span with neighboring spans if possible, prepend to
   // appropriate free list, and adjust stats.
   void MergeIntoFreeList(Span* span);

   // Commit the span.
   void CommitSpan(Span* span);

   // Decommit the span.
   bool DecommitSpan(Span* span);

   // Prepends span to appropriate free list, and adjusts stats.
   void PrependToFreeList(Span* span);

   // Removes span from its free list, and adjust stats.
   void RemoveFromFreeList(Span* span);

   // Incrementally release some memory to the system.
   // IncrementalScavenge(n) is called whenever n pages are freed.
   void IncrementalScavenge(Length n);

   // Attempts to decommit 's' and move it to the returned freelist.
   //
   // Returns the length of the Span or zero if release failed.
   //
   // REQUIRES: 's' must be on the NORMAL freelist.
   Length ReleaseSpan(Span *s);

   // Checks if we are allowed to take more memory from the system.
   // If limit is reached and allowRelease is true, tries to release
   // some unused spans.
   bool EnsureLimit(Length n, bool allowRelease = true);

   Span* CheckAndHandlePreMerge(Span *span, Span *other);

   // Number of pages to deallocate before doing more scavenging
   int64_t scavenge_counter_;

   // Index of last free list where we released memory to the OS.
   int release_index_;

   bool aggressive_decommit_;
 };

 }  // namespace tcmalloc

 #ifdef _MSC_VER
 #pragma warning(pop)
 #endif

 #endif  // TCMALLOC_PAGE_HEAP_H_
	// -- Mode: C++; c-basic-offset: 2; indent-tabs-mode: nil --
	// Copyright (c) 2008, Google Inc.
	// All rights reserved.
	//
	// Redistribution and use in source and binary forms, with or without
	// modification, are permitted provided that the following conditions are
	// met:
	//
	// * Redistributions of source code must retain the above copyright
	// notice, this list of conditions and the following disclaimer.
	// * Redistributions in binary form must reproduce the above
	// copyright notice, this list of conditions and the following disclaimer
	// in the documentation and/or other materials provided with the
	// distribution.
	// * Neither the name of Google Inc. nor the names of its
	// contributors may be used to endorse or promote products derived from
	// this software without specific prior written permission.
	//
	// THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
	// "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
	// LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR
	// A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT
	// OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
	// SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT
	// LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
	// DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
	// THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
	// (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
	// OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.

	// ---
	// Author: Sanjay Ghemawat <opensource@google.com>

	#ifndef TCMALLOC_PAGE_HEAP_H_
	#define TCMALLOC_PAGE_HEAP_H_

	#include <config.h>
	#include <stddef.h> // for size_t
	#ifdef HAVE_STDINT_H
	#include <stdint.h> // for uint64_t, int64_t, uint16_t
	#endif
	#include <gperftools/malloc_extension.h>
	#include "base/basictypes.h"
	#include "common.h"
	#include "packed-cache-inl.h"
	#include "pagemap.h"
	#include "span.h"

	// We need to dllexport PageHeap just for the unittest. MSVC complains
	// that we don't dllexport the PageHeap members, but we don't need to
	// test those, so I just suppress this warning.
	#ifdef _MSC_VER
	#pragma warning(push)
	#pragma warning(disable:4251)
	#endif

	// This #ifdef should almost never be set. Set NO_TCMALLOC_SAMPLES if
	// you're porting to a system where you really can't get a stacktrace.
	// Because we control the definition of GetStackTrace, all clients of
	// GetStackTrace should #include us rather than stacktrace.h.
	#ifdef NO_TCMALLOC_SAMPLES
	// We use #define so code compiles even if you #include stacktrace.h somehow.
	# define GetStackTrace(stack, depth, skip) (0)
	#else
	# include <gperftools/stacktrace.h>
	#endif

	namespace base {
	struct MallocRange;
	}

	namespace tcmalloc {

	// -------------------------------------------------------------------------
	// Map from page-id to per-page data
	// -------------------------------------------------------------------------

	// We use PageMap2<> for 32-bit and PageMap3<> for 64-bit machines.
	// We also use a simple one-level cache for hot PageID-to-sizeclass mappings,
	// because sometimes the sizeclass is all the information we need.

	// Selector class -- general selector uses 3-level map
	template <int BITS> class MapSelector {
	public:
	typedef TCMalloc_PageMap3<BITS-kPageShift> Type;
	};

	#ifndef TCMALLOC_SMALL_BUT_SLOW
	// x86-64 and arm64 are using 48 bits of address space. So we can use
	// just two level map, but since initial ram consumption of this mode
	// is a bit on the higher side, we opt-out of it in
	// TCMALLOC_SMALL_BUT_SLOW mode.
	template <> class MapSelector<48> {
	public:
	typedef TCMalloc_PageMap2<48-kPageShift> Type;
	};

	#endif // TCMALLOC_SMALL_BUT_SLOW

	// A two-level map for 32-bit machines
	template <> class MapSelector<32> {
	public:
	typedef TCMalloc_PageMap2<32-kPageShift> Type;
	};

	// -------------------------------------------------------------------------
	// Page-level allocator
	// * Eager coalescing
	//
	// Heap for page-level allocation. We allow allocating and freeing a
	// contiguous runs of pages (called a "span").
	// -------------------------------------------------------------------------

	class PERFTOOLS_DLL_DECL PageHeap {
	public:
	PageHeap();

	// Allocate a run of "n" pages. Returns zero if out of memory.
	// Caller should not pass "n == 0" -- instead, n should have
	// been rounded up already.
	Span* New(Length n);

	// Delete the span "[p, p+n-1]".
	// REQUIRES: span was returned by earlier call to New() and
	// has not yet been deleted.
	void Delete(Span* span);

	// Mark an allocated span as being used for small objects of the
	// specified size-class.
	// REQUIRES: span was returned by an earlier call to New()
	// and has not yet been deleted.
	void RegisterSizeClass(Span* span, uint32 sc);

	// Split an allocated span into two spans: one of length "n" pages
	// followed by another span of length "span->length - n" pages.
	// Modifies "*span" to point to the first span of length "n" pages.
	// Returns a pointer to the second span.
	//
	// REQUIRES: "0 < n < span->length"
	// REQUIRES: span->location == IN_USE
	// REQUIRES: span->sizeclass == 0
	Span* Split(Span* span, Length n);

	// Return the descriptor for the specified page. Returns NULL if
	// this PageID was not allocated previously.
	inline ATTRIBUTE_ALWAYS_INLINE
	Span* GetDescriptor(PageID p) const {
	return reinterpret_cast<Span*>(pagemap_.get(p));
	}

	// If this page heap is managing a range with starting page # >= start,
	// store info about the range in *r and return true. Else return false.
	bool GetNextRange(PageID start, base::MallocRange* r);

	// Page heap statistics
	struct Stats {
	Stats() : system_bytes(0), free_bytes(0), unmapped_bytes(0), committed_bytes(0),
	scavenge_count(0), commit_count(0), total_commit_bytes(0),
	decommit_count(0), total_decommit_bytes(0),
	reserve_count(0), total_reserve_bytes(0) {}
	uint64_t system_bytes; // Total bytes allocated from system
	uint64_t free_bytes; // Total bytes on normal freelists
	uint64_t unmapped_bytes; // Total bytes on returned freelists
	uint64_t committed_bytes; // Bytes committed, always <= system_bytes_.

	uint64_t scavenge_count; // Number of times scavagened flush pages

	uint64_t commit_count; // Number of virtual memory commits
	uint64_t total_commit_bytes; // Bytes committed in lifetime of process
	uint64_t decommit_count; // Number of virtual memory decommits
	uint64_t total_decommit_bytes; // Bytes decommitted in lifetime of process

	uint64_t reserve_count; // Number of virtual memory reserves
	uint64_t total_reserve_bytes; // Bytes reserved in lifetime of process
	};
	inline Stats stats() const { return stats_; }

	struct SmallSpanStats {
	// For each free list of small spans, the length (in spans) of the
	// normal and returned free lists for that size.
	//
	// NOTE: index 'i' accounts the number of spans of length 'i + 1'.
	int64 normal_length[kMaxPages];
	int64 returned_length[kMaxPages];
	};
	void GetSmallSpanStats(SmallSpanStats* result);

	// Stats for free large spans (i.e., spans with more than kMaxPages pages).
	struct LargeSpanStats {
	int64 spans; // Number of such spans
	int64 normal_pages; // Combined page length of normal large spans
	int64 returned_pages; // Combined page length of unmapped spans
	};
	void GetLargeSpanStats(LargeSpanStats* result);

	bool Check();
	// Like Check() but does some more comprehensive checking.
	bool CheckExpensive();
	bool CheckList(Span* list, Length min_pages, Length max_pages,
	int freelist); // ON_NORMAL_FREELIST or ON_RETURNED_FREELIST
	bool CheckSet(SpanSet *s, Length min_pages, int freelist);

	// Try to release at least num_pages for reuse by the OS. Returns
	// the actual number of pages released, which may be less than
	// num_pages if there weren't enough pages to release. The result
	// may also be larger than num_pages since page_heap might decide to
	// release one large range instead of fragmenting it into two
	// smaller released and unreleased ranges.
	Length ReleaseAtLeastNPages(Length num_pages);

	// Reads and writes to pagemap_cache_ do not require locking.
	bool TryGetSizeClass(PageID p, uint32* out) const {
	return pagemap_cache_.TryGet(p, out);
	}
	void SetCachedSizeClass(PageID p, uint32 cl) {
	ASSERT(cl != 0);
	pagemap_cache_.Put(p, cl);
	}
	void InvalidateCachedSizeClass(PageID p) { pagemap_cache_.Invalidate(p); }
	uint32 GetSizeClassOrZero(PageID p) const {
	uint32 cached_value;
	if (!TryGetSizeClass(p, &cached_value)) {
	cached_value = 0;
	}
	return cached_value;
	}

	bool GetAggressiveDecommit(void) {return aggressive_decommit_;}
	void SetAggressiveDecommit(bool aggressive_decommit) {
	aggressive_decommit_ = aggressive_decommit;
	}

	private:
	// Allocates a big block of memory for the pagemap once we reach more than
	// 128MB
	static const size_t kPageMapBigAllocationThreshold = 128 << 20;

	// Minimum number of pages to fetch from system at a time. Must be
	// significantly bigger than kBlockSize to amortize system-call
	// overhead, and also to reduce external fragementation. Also, we
	// should keep this value big because various incarnations of Linux
	// have small limits on the number of mmap() regions per
	// address-space.
	// REQUIRED: kMinSystemAlloc <= kMaxPages;
	static const int kMinSystemAlloc = kMaxPages;

	// Never delay scavenging for more than the following number of
	// deallocated pages. With 4K pages, this comes to 4GB of
	// deallocation.
	static const int kMaxReleaseDelay = 1 << 20;

	// If there is nothing to release, wait for so many pages before
	// scavenging again. With 4K pages, this comes to 1GB of memory.
	static const int kDefaultReleaseDelay = 1 << 18;

	// Pick the appropriate map and cache types based on pointer size
	typedef MapSelector<kAddressBits>::Type PageMap;
	typedef PackedCache<kAddressBits - kPageShift> PageMapCache;
	mutable PageMapCache pagemap_cache_;
	PageMap pagemap_;

	// We segregate spans of a given size into two circular linked
	// lists: one for normal spans, and one for spans whose memory
	// has been returned to the system.
	struct SpanList {
	Span normal;
	Span returned;
	};

	// Sets of spans with length > kMaxPages.
	//
	// Rather than using a linked list, we use sets here for efficient
	// best-fit search.
	SpanSet large_normal_;
	SpanSet large_returned_;

	// Array mapping from span length to a doubly linked list of free spans
	//
	// NOTE: index 'i' stores spans of length 'i + 1'.
	SpanList free_[kMaxPages];

	// Statistics on system, free, and unmapped bytes
	Stats stats_;

	Span* SearchFreeAndLargeLists(Length n);

	bool GrowHeap(Length n);

	// REQUIRES: span->length >= n
	// REQUIRES: span->location != IN_USE
	// Remove span from its free list, and move any leftover part of
	// span into appropriate free lists. Also update "span" to have
	// length exactly "n" and mark it as non-free so it can be returned
	// to the client. After all that, decrease free_pages_ by n and
	// return span.
	Span* Carve(Span* span, Length n);

	void RecordSpan(Span* span) {
	pagemap_.set(span->start, span);
	if (span->length > 1) {
	pagemap_.set(span->start + span->length - 1, span);
	}
	}

	// Allocate a large span of length == n. If successful, returns a
	// span of exactly the specified length. Else, returns NULL.
	Span* AllocLarge(Length n);

	// Coalesce span with neighboring spans if possible, prepend to
	// appropriate free list, and adjust stats.
	void MergeIntoFreeList(Span* span);

	// Commit the span.
	void CommitSpan(Span* span);

	// Decommit the span.
	bool DecommitSpan(Span* span);

	// Prepends span to appropriate free list, and adjusts stats.
	void PrependToFreeList(Span* span);

	// Removes span from its free list, and adjust stats.
	void RemoveFromFreeList(Span* span);

	// Incrementally release some memory to the system.
	// IncrementalScavenge(n) is called whenever n pages are freed.
	void IncrementalScavenge(Length n);

	// Attempts to decommit 's' and move it to the returned freelist.
	//
	// Returns the length of the Span or zero if release failed.
	//
	// REQUIRES: 's' must be on the NORMAL freelist.
	Length ReleaseSpan(Span *s);

	// Checks if we are allowed to take more memory from the system.
	// If limit is reached and allowRelease is true, tries to release
	// some unused spans.
	bool EnsureLimit(Length n, bool allowRelease = true);

	Span* CheckAndHandlePreMerge(Span span, Span other);

	// Number of pages to deallocate before doing more scavenging
	int64_t scavenge_counter_;

	// Index of last free list where we released memory to the OS.
	int release_index_;

	bool aggressive_decommit_;
	};

	} // namespace tcmalloc

	#ifdef _MSC_VER
	#pragma warning(pop)
	#endif

	#endif // TCMALLOC_PAGE_HEAP_H_