src/base/allocator/partition_allocator/partition_alloc_constants.h - cobalt - Git at Google

 // Copyright (c) 2018 The Chromium Authors. All rights reserved.
 // Use of this source code is governed by a BSD-style license that can be
 // found in the LICENSE file.

 #ifndef BASE_ALLOCATOR_PARTITION_ALLOCATOR_PARTITION_ALLOC_CONSTANTS_H_
 #define BASE_ALLOCATOR_PARTITION_ALLOCATOR_PARTITION_ALLOC_CONSTANTS_H_

 #include <limits.h>

 #include "base/allocator/partition_allocator/page_allocator_constants.h"
 #include "base/logging.h"
 #include "starboard/types.h"

 namespace base {

 // Allocation granularity of sizeof(void*) bytes.
 static const size_t kAllocationGranularity = sizeof(void*);
 static const size_t kAllocationGranularityMask = kAllocationGranularity - 1;
 static const size_t kBucketShift = (kAllocationGranularity == 8) ? 3 : 2;

 // Underlying partition storage pages are a power-of-two size. It is typical
 // for a partition page to be based on multiple system pages. Most references to
 // "page" refer to partition pages.
 // We also have the concept of "super pages" -- these are the underlying system
 // allocations we make. Super pages contain multiple partition pages inside them
 // and include space for a small amount of metadata per partition page.
 // Inside super pages, we store "slot spans". A slot span is a continguous range
 // of one or more partition pages that stores allocations of the same size.
 // Slot span sizes are adjusted depending on the allocation size, to make sure
 // the packing does not lead to unused (wasted) space at the end of the last
 // system page of the span. For our current max slot span size of 64k and other
 // constant values, we pack _all_ PartitionRootGeneric::Alloc() sizes perfectly
 // up against the end of a system page.
 #if defined(_MIPS_ARCH_LOONGSON)
 static const size_t kPartitionPageShift = 16;  // 64KB
 #else
 static const size_t kPartitionPageShift = 14;  // 16KB
 #endif
 static const size_t kPartitionPageSize = 1 << kPartitionPageShift;
 static const size_t kPartitionPageOffsetMask = kPartitionPageSize - 1;
 static const size_t kPartitionPageBaseMask = ~kPartitionPageOffsetMask;
 static const size_t kMaxPartitionPagesPerSlotSpan = 4;

 // To avoid fragmentation via never-used freelist entries, we hand out partition
 // freelist sections gradually, in units of the dominant system page size.
 // What we're actually doing is avoiding filling the full partition page (16 KB)
 // with freelist pointers right away. Writing freelist pointers will fault and
 // dirty a private page, which is very wasteful if we never actually store
 // objects there.
 static const size_t kNumSystemPagesPerPartitionPage =
     kPartitionPageSize / kSystemPageSize;
 static const size_t kMaxSystemPagesPerSlotSpan =
     kNumSystemPagesPerPartitionPage * kMaxPartitionPagesPerSlotSpan;

 // We reserve virtual address space in 2MB chunks (aligned to 2MB as well).
 // These chunks are called "super pages". We do this so that we can store
 // metadata in the first few pages of each 2MB aligned section. This leads to
 // a very fast free(). We specifically choose 2MB because this virtual address
 // block represents a full but single PTE allocation on ARM, ia32 and x64.
 //
 // The layout of the super page is as follows. The sizes below are the same
 // for 32 bit and 64 bit.
 //
 //   | Guard page (4KB)    |
 //   | Metadata page (4KB) |
 //   | Guard pages (8KB)   |
 //   | Slot span           |
 //   | Slot span           |
 //   | ...                 |
 //   | Slot span           |
 //   | Guard page (4KB)    |
 //
 //   - Each slot span is a contiguous range of one or more PartitionPages.
 //   - The metadata page has the following format. Note that the PartitionPage
 //     that is not at the head of a slot span is "unused". In other words,
 //     the metadata for the slot span is stored only in the first PartitionPage
 //     of the slot span. Metadata accesses to other PartitionPages are
 //     redirected to the first PartitionPage.
 //
 //     | SuperPageExtentEntry (32B)                 |
 //     | PartitionPage of slot span 1 (32B, used)   |
 //     | PartitionPage of slot span 1 (32B, unused) |
 //     | PartitionPage of slot span 1 (32B, unused) |
 //     | PartitionPage of slot span 2 (32B, used)   |
 //     | PartitionPage of slot span 3 (32B, used)   |
 //     | ...                                        |
 //     | PartitionPage of slot span N (32B, unused) |
 //
 // A direct mapped page has a similar layout to fake it looking like a super
 // page:
 //
 //     | Guard page (4KB)     |
 //     | Metadata page (4KB)  |
 //     | Guard pages (8KB)    |
 //     | Direct mapped object |
 //     | Guard page (4KB)     |
 //
 //    - The metadata page has the following layout:
 //
 //     | SuperPageExtentEntry (32B)    |
 //     | PartitionPage (32B)           |
 //     | PartitionBucket (32B)         |
 //     | PartitionDirectMapExtent (8B) |
 static const size_t kSuperPageShift = 21;  // 2MB
 static const size_t kSuperPageSize = 1 << kSuperPageShift;
 static const size_t kSuperPageOffsetMask = kSuperPageSize - 1;
 static const size_t kSuperPageBaseMask = ~kSuperPageOffsetMask;
 static const size_t kNumPartitionPagesPerSuperPage =
     kSuperPageSize / kPartitionPageSize;

 // The following kGeneric* constants apply to the generic variants of the API.
 // The "order" of an allocation is closely related to the power-of-two size of
 // the allocation. More precisely, the order is the bit index of the
 // most-significant-bit in the allocation size, where the bit numbers starts
 // at index 1 for the least-significant-bit.
 // In terms of allocation sizes, order 0 covers 0, order 1 covers 1, order 2
 // covers 2->3, order 3 covers 4->7, order 4 covers 8->15.
 static const size_t kGenericMinBucketedOrder = 4;  // 8 bytes.
 static const size_t kGenericMaxBucketedOrder =
     20;  // Largest bucketed order is 1<<(20-1) (storing 512KB -> almost 1MB)
 static const size_t kGenericNumBucketedOrders =
     (kGenericMaxBucketedOrder - kGenericMinBucketedOrder) + 1;
 // Eight buckets per order (for the higher orders), e.g. order 8 is 128, 144,
 // 160, ..., 240:
 static const size_t kGenericNumBucketsPerOrderBits = 3;
 static const size_t kGenericNumBucketsPerOrder =
     1 << kGenericNumBucketsPerOrderBits;
 static const size_t kGenericNumBuckets =
     kGenericNumBucketedOrders * kGenericNumBucketsPerOrder;
 static const size_t kGenericSmallestBucket = 1
                                              << (kGenericMinBucketedOrder - 1);
 static const size_t kGenericMaxBucketSpacing =
     1 << ((kGenericMaxBucketedOrder - 1) - kGenericNumBucketsPerOrderBits);
 static const size_t kGenericMaxBucketed =
     (1 << (kGenericMaxBucketedOrder - 1)) +
     ((kGenericNumBucketsPerOrder - 1) * kGenericMaxBucketSpacing);
 static const size_t kGenericMinDirectMappedDownsize =
     kGenericMaxBucketed +
     1;  // Limit when downsizing a direct mapping using realloc().
 static const size_t kGenericMaxDirectMapped =
     (1UL << 31) + kPageAllocationGranularity;  // 2 GB plus one more page.
 static const size_t kBitsPerSizeT = sizeof(void*) * CHAR_BIT;

 // Constant for the memory reclaim logic.
 static const size_t kMaxFreeableSpans = 16;

 // If the total size in bytes of allocated but not committed pages exceeds this
 // value (probably it is a "out of virtual address space" crash),
 // a special crash stack trace is generated at |PartitionOutOfMemory|.
 // This is to distinguish "out of virtual address space" from
 // "out of physical memory" in crash reports.
 static const size_t kReasonableSizeOfUnusedPages = 1024 * 1024 * 1024;  // 1GB

 // These two byte values match tcmalloc.
 static const unsigned char kUninitializedByte = 0xAB;
 static const unsigned char kFreedByte = 0xCD;

 // Flags for PartitionAllocGenericFlags.
 enum PartitionAllocFlags {
   PartitionAllocReturnNull = 1 << 0,
   PartitionAllocZeroFill = 1 << 1,

   PartitionAllocLastFlag = PartitionAllocZeroFill
 };

 }  // namespace base

 #endif  // BASE_ALLOCATOR_PARTITION_ALLOCATOR_PARTITION_ALLOC_CONSTANTS_H_
	// Copyright (c) 2018 The Chromium Authors. All rights reserved.
	// Use of this source code is governed by a BSD-style license that can be
	// found in the LICENSE file.

	#ifndef BASE_ALLOCATOR_PARTITION_ALLOCATOR_PARTITION_ALLOC_CONSTANTS_H_
	#define BASE_ALLOCATOR_PARTITION_ALLOCATOR_PARTITION_ALLOC_CONSTANTS_H_

	#include <limits.h>

	#include "base/allocator/partition_allocator/page_allocator_constants.h"
	#include "base/logging.h"
	#include "starboard/types.h"

	namespace base {

	// Allocation granularity of sizeof(void*) bytes.
	static const size_t kAllocationGranularity = sizeof(void*);
	static const size_t kAllocationGranularityMask = kAllocationGranularity - 1;
	static const size_t kBucketShift = (kAllocationGranularity == 8) ? 3 : 2;

	// Underlying partition storage pages are a power-of-two size. It is typical
	// for a partition page to be based on multiple system pages. Most references to
	// "page" refer to partition pages.
	// We also have the concept of "super pages" -- these are the underlying system
	// allocations we make. Super pages contain multiple partition pages inside them
	// and include space for a small amount of metadata per partition page.
	// Inside super pages, we store "slot spans". A slot span is a continguous range
	// of one or more partition pages that stores allocations of the same size.
	// Slot span sizes are adjusted depending on the allocation size, to make sure
	// the packing does not lead to unused (wasted) space at the end of the last
	// system page of the span. For our current max slot span size of 64k and other
	// constant values, we pack _all_ PartitionRootGeneric::Alloc() sizes perfectly
	// up against the end of a system page.
	#if defined(_MIPS_ARCH_LOONGSON)
	static const size_t kPartitionPageShift = 16; // 64KB
	#else
	static const size_t kPartitionPageShift = 14; // 16KB
	#endif
	static const size_t kPartitionPageSize = 1 << kPartitionPageShift;
	static const size_t kPartitionPageOffsetMask = kPartitionPageSize - 1;
	static const size_t kPartitionPageBaseMask = ~kPartitionPageOffsetMask;
	static const size_t kMaxPartitionPagesPerSlotSpan = 4;

	// To avoid fragmentation via never-used freelist entries, we hand out partition
	// freelist sections gradually, in units of the dominant system page size.
	// What we're actually doing is avoiding filling the full partition page (16 KB)
	// with freelist pointers right away. Writing freelist pointers will fault and
	// dirty a private page, which is very wasteful if we never actually store
	// objects there.
	static const size_t kNumSystemPagesPerPartitionPage =
	kPartitionPageSize / kSystemPageSize;
	static const size_t kMaxSystemPagesPerSlotSpan =
	kNumSystemPagesPerPartitionPage * kMaxPartitionPagesPerSlotSpan;

	// We reserve virtual address space in 2MB chunks (aligned to 2MB as well).
	// These chunks are called "super pages". We do this so that we can store
	// metadata in the first few pages of each 2MB aligned section. This leads to
	// a very fast free(). We specifically choose 2MB because this virtual address
	// block represents a full but single PTE allocation on ARM, ia32 and x64.
	//
	// The layout of the super page is as follows. The sizes below are the same
	// for 32 bit and 64 bit.
	//
	// \| Guard page (4KB) \|
	// \| Metadata page (4KB) \|
	// \| Guard pages (8KB) \|
	// \| Slot span \|
	// \| Slot span \|
	// \| ... \|
	// \| Slot span \|
	// \| Guard page (4KB) \|
	//
	// - Each slot span is a contiguous range of one or more PartitionPages.
	// - The metadata page has the following format. Note that the PartitionPage
	// that is not at the head of a slot span is "unused". In other words,
	// the metadata for the slot span is stored only in the first PartitionPage
	// of the slot span. Metadata accesses to other PartitionPages are
	// redirected to the first PartitionPage.
	//
	// \| SuperPageExtentEntry (32B) \|
	// \| PartitionPage of slot span 1 (32B, used) \|
	// \| PartitionPage of slot span 1 (32B, unused) \|
	// \| PartitionPage of slot span 1 (32B, unused) \|
	// \| PartitionPage of slot span 2 (32B, used) \|
	// \| PartitionPage of slot span 3 (32B, used) \|
	// \| ... \|
	// \| PartitionPage of slot span N (32B, unused) \|
	//
	// A direct mapped page has a similar layout to fake it looking like a super
	// page:
	//
	// \| Guard page (4KB) \|
	// \| Metadata page (4KB) \|
	// \| Guard pages (8KB) \|
	// \| Direct mapped object \|
	// \| Guard page (4KB) \|
	//
	// - The metadata page has the following layout:
	//
	// \| SuperPageExtentEntry (32B) \|
	// \| PartitionPage (32B) \|
	// \| PartitionBucket (32B) \|
	// \| PartitionDirectMapExtent (8B) \|
	static const size_t kSuperPageShift = 21; // 2MB
	static const size_t kSuperPageSize = 1 << kSuperPageShift;
	static const size_t kSuperPageOffsetMask = kSuperPageSize - 1;
	static const size_t kSuperPageBaseMask = ~kSuperPageOffsetMask;
	static const size_t kNumPartitionPagesPerSuperPage =
	kSuperPageSize / kPartitionPageSize;

	// The following kGeneric* constants apply to the generic variants of the API.
	// The "order" of an allocation is closely related to the power-of-two size of
	// the allocation. More precisely, the order is the bit index of the
	// most-significant-bit in the allocation size, where the bit numbers starts
	// at index 1 for the least-significant-bit.
	// In terms of allocation sizes, order 0 covers 0, order 1 covers 1, order 2
	// covers 2->3, order 3 covers 4->7, order 4 covers 8->15.
	static const size_t kGenericMinBucketedOrder = 4; // 8 bytes.
	static const size_t kGenericMaxBucketedOrder =
	20; // Largest bucketed order is 1<<(20-1) (storing 512KB -> almost 1MB)
	static const size_t kGenericNumBucketedOrders =
	(kGenericMaxBucketedOrder - kGenericMinBucketedOrder) + 1;
	// Eight buckets per order (for the higher orders), e.g. order 8 is 128, 144,
	// 160, ..., 240:
	static const size_t kGenericNumBucketsPerOrderBits = 3;
	static const size_t kGenericNumBucketsPerOrder =
	1 << kGenericNumBucketsPerOrderBits;
	static const size_t kGenericNumBuckets =
	kGenericNumBucketedOrders * kGenericNumBucketsPerOrder;
	static const size_t kGenericSmallestBucket = 1
	<< (kGenericMinBucketedOrder - 1);
	static const size_t kGenericMaxBucketSpacing =
	1 << ((kGenericMaxBucketedOrder - 1) - kGenericNumBucketsPerOrderBits);
	static const size_t kGenericMaxBucketed =
	(1 << (kGenericMaxBucketedOrder - 1)) +
	((kGenericNumBucketsPerOrder - 1) * kGenericMaxBucketSpacing);
	static const size_t kGenericMinDirectMappedDownsize =
	kGenericMaxBucketed +
	1; // Limit when downsizing a direct mapping using realloc().
	static const size_t kGenericMaxDirectMapped =
	(1UL << 31) + kPageAllocationGranularity; // 2 GB plus one more page.
	static const size_t kBitsPerSizeT = sizeof(void) CHAR_BIT;

	// Constant for the memory reclaim logic.
	static const size_t kMaxFreeableSpans = 16;

	// If the total size in bytes of allocated but not committed pages exceeds this
	// value (probably it is a "out of virtual address space" crash),
	// a special crash stack trace is generated at \|PartitionOutOfMemory\|.
	// This is to distinguish "out of virtual address space" from
	// "out of physical memory" in crash reports.
	static const size_t kReasonableSizeOfUnusedPages = 1024 * 1024 * 1024; // 1GB

	// These two byte values match tcmalloc.
	static const unsigned char kUninitializedByte = 0xAB;
	static const unsigned char kFreedByte = 0xCD;

	// Flags for PartitionAllocGenericFlags.
	enum PartitionAllocFlags {
	PartitionAllocReturnNull = 1 << 0,
	PartitionAllocZeroFill = 1 << 1,

	PartitionAllocLastFlag = PartitionAllocZeroFill
	};

	} // namespace base

	#endif // BASE_ALLOCATOR_PARTITION_ALLOCATOR_PARTITION_ALLOC_CONSTANTS_H_