third_party/skia/src/core/SkArenaAlloc.cpp - cobalt - Git at Google

 /*
  * Copyright 2016 Google Inc.
  *
  * Use of this source code is governed by a BSD-style license that can be
  * found in the LICENSE file.
  */

 #include "src/core/SkArenaAlloc.h"
 #include <algorithm>
 #include <new>

 static char* end_chain(char*) { return nullptr; }

 static uint32_t first_allocated_block(uint32_t blockSize, uint32_t firstHeapAllocation) {
     return firstHeapAllocation > 0 ? firstHeapAllocation :
            blockSize           > 0 ? blockSize           : 1024;
 }

 SkArenaAlloc::SkArenaAlloc(char* block, size_t size, size_t firstHeapAllocation)
     : fDtorCursor {block}
     , fCursor     {block}
     , fEnd        {block + ToU32(size)}
     , fFirstBlock {block}
     , fFirstSize  {ToU32(size)}
     , fFirstHeapAllocationSize  {first_allocated_block(ToU32(size), ToU32(firstHeapAllocation))}
 {
     if (size < sizeof(Footer)) {
         fEnd = fCursor = fDtorCursor = nullptr;
     }

     if (fCursor != nullptr) {
         this->installFooter(end_chain, 0);
     }
 }

 SkArenaAlloc::~SkArenaAlloc() {
     RunDtorsOnBlock(fDtorCursor);
 }

 void SkArenaAlloc::reset() {
     this->~SkArenaAlloc();
     new (this) SkArenaAlloc{fFirstBlock, fFirstSize, fFirstHeapAllocationSize};
 }

 void SkArenaAlloc::installFooter(FooterAction* action, uint32_t padding) {
     assert(padding < 64);
     int64_t actionInt = (int64_t)(intptr_t)action;

     // The top 14 bits should be either all 0s or all 1s. Check this.
     assert((actionInt << 6) >> 6 == actionInt);
     Footer encodedFooter = (actionInt << 6) | padding;
     memmove(fCursor, &encodedFooter, sizeof(Footer));
     fCursor += sizeof(Footer);
     fDtorCursor = fCursor;
 }

 void SkArenaAlloc::installPtrFooter(FooterAction* action, char* ptr, uint32_t padding) {
     memmove(fCursor, &ptr, sizeof(char*));
     fCursor += sizeof(char*);
     this->installFooter(action, padding);
 }

 char* SkArenaAlloc::SkipPod(char* footerEnd) {
     char* objEnd = footerEnd - (sizeof(Footer) + sizeof(int32_t));
     int32_t skip;
     memmove(&skip, objEnd, sizeof(int32_t));
     return objEnd - skip;
 }

 void SkArenaAlloc::RunDtorsOnBlock(char* footerEnd) {
     while (footerEnd != nullptr) {
         Footer footer;
         memcpy(&footer, footerEnd - sizeof(Footer), sizeof(Footer));

         FooterAction* action = (FooterAction*)(footer >> 6);
         ptrdiff_t padding = footer & 63;

         footerEnd = action(footerEnd) - padding;
     }
 }

 char* SkArenaAlloc::NextBlock(char* footerEnd) {
     char* objEnd = footerEnd - (sizeof(Footer) + sizeof(char*));
     char* next;
     memmove(&next, objEnd, sizeof(char*));
     RunDtorsOnBlock(next);
     delete [] objEnd;
     return nullptr;
 }

 void SkArenaAlloc::installUint32Footer(FooterAction* action, uint32_t value, uint32_t padding) {
     memmove(fCursor, &value, sizeof(uint32_t));
     fCursor += sizeof(uint32_t);
     this->installFooter(action, padding);
 }

 void SkArenaAlloc::ensureSpace(uint32_t size, uint32_t alignment) {
     constexpr uint32_t headerSize = sizeof(Footer) + sizeof(ptrdiff_t);
     // The chrome c++ library we use does not define std::max_align_t.
     // This must be conservative to add the right amount of extra memory to handle the alignment
     // padding.
     constexpr uint32_t alignof_max_align_t = 8;
     constexpr uint32_t maxSize = std::numeric_limits<uint32_t>::max();
     constexpr uint32_t overhead = headerSize + sizeof(Footer);
     AssertRelease(size <= maxSize - overhead);
     uint32_t objSizeAndOverhead = size + overhead;
     if (alignment > alignof_max_align_t) {
         uint32_t alignmentOverhead = alignment - 1;
         AssertRelease(objSizeAndOverhead <= maxSize - alignmentOverhead);
         objSizeAndOverhead += alignmentOverhead;
     }

     uint32_t minAllocationSize;
     if (fFirstHeapAllocationSize <= maxSize / fFib0) {
         minAllocationSize = fFirstHeapAllocationSize * fFib0;
         fFib0 += fFib1;
         std::swap(fFib0, fFib1);
     } else {
         minAllocationSize = maxSize;
     }
     uint32_t allocationSize = std::max(objSizeAndOverhead, minAllocationSize);

     // Round up to a nice size. If > 32K align to 4K boundary else up to max_align_t. The > 32K
     // heuristic is from the JEMalloc behavior.
     {
         uint32_t mask = allocationSize > (1 << 15) ? (1 << 12) - 1 : 16 - 1;
         AssertRelease(allocationSize <= maxSize - mask);
         allocationSize = (allocationSize + mask) & ~mask;
     }

     char* newBlock = new char[allocationSize];

     auto previousDtor = fDtorCursor;
     fCursor = newBlock;
     fDtorCursor = newBlock;
     fEnd = fCursor + allocationSize;
     this->installPtrFooter(NextBlock, previousDtor, 0);
 }

 char* SkArenaAlloc::allocObjectWithFooter(uint32_t sizeIncludingFooter, uint32_t alignment) {
     uintptr_t mask = alignment - 1;

 restart:
     uint32_t skipOverhead = 0;
     bool needsSkipFooter = fCursor != fDtorCursor;
     if (needsSkipFooter) {
         skipOverhead = sizeof(Footer) + sizeof(uint32_t);
     }
     char* objStart = (char*)((uintptr_t)(fCursor + skipOverhead + mask) & ~mask);
     uint32_t totalSize = sizeIncludingFooter + skipOverhead;

     if ((ptrdiff_t)totalSize > fEnd - objStart) {
         this->ensureSpace(totalSize, alignment);
         goto restart;
     }

     AssertRelease((ptrdiff_t)totalSize <= fEnd - objStart);

     // Install a skip footer if needed, thus terminating a run of POD data. The calling code is
     // responsible for installing the footer after the object.
     if (needsSkipFooter) {
         this->installUint32Footer(SkipPod, ToU32(fCursor - fDtorCursor), 0);
     }

     return objStart;
 }
	/*
	* Copyright 2016 Google Inc.
	*
	* Use of this source code is governed by a BSD-style license that can be
	* found in the LICENSE file.
	*/

	#include "src/core/SkArenaAlloc.h"
	#include <algorithm>
	#include <new>

	static char* end_chain(char*) { return nullptr; }

	static uint32_t first_allocated_block(uint32_t blockSize, uint32_t firstHeapAllocation) {
	return firstHeapAllocation > 0 ? firstHeapAllocation :
	blockSize > 0 ? blockSize : 1024;
	}

	SkArenaAlloc::SkArenaAlloc(char* block, size_t size, size_t firstHeapAllocation)
	: fDtorCursor {block}
	, fCursor {block}
	, fEnd {block + ToU32(size)}
	, fFirstBlock {block}
	, fFirstSize {ToU32(size)}
	, fFirstHeapAllocationSize {first_allocated_block(ToU32(size), ToU32(firstHeapAllocation))}
	{
	if (size < sizeof(Footer)) {
	fEnd = fCursor = fDtorCursor = nullptr;
	}

	if (fCursor != nullptr) {
	this->installFooter(end_chain, 0);
	}
	}

	SkArenaAlloc::~SkArenaAlloc() {
	RunDtorsOnBlock(fDtorCursor);
	}

	void SkArenaAlloc::reset() {
	this->~SkArenaAlloc();
	new (this) SkArenaAlloc{fFirstBlock, fFirstSize, fFirstHeapAllocationSize};
	}

	void SkArenaAlloc::installFooter(FooterAction* action, uint32_t padding) {
	assert(padding < 64);
	int64_t actionInt = (int64_t)(intptr_t)action;

	// The top 14 bits should be either all 0s or all 1s. Check this.
	assert((actionInt << 6) >> 6 == actionInt);
	Footer encodedFooter = (actionInt << 6) \| padding;
	memmove(fCursor, &encodedFooter, sizeof(Footer));
	fCursor += sizeof(Footer);
	fDtorCursor = fCursor;
	}

	void SkArenaAlloc::installPtrFooter(FooterAction* action, char* ptr, uint32_t padding) {
	memmove(fCursor, &ptr, sizeof(char*));
	fCursor += sizeof(char*);
	this->installFooter(action, padding);
	}

	char* SkArenaAlloc::SkipPod(char* footerEnd) {
	char* objEnd = footerEnd - (sizeof(Footer) + sizeof(int32_t));
	int32_t skip;
	memmove(&skip, objEnd, sizeof(int32_t));
	return objEnd - skip;
	}

	void SkArenaAlloc::RunDtorsOnBlock(char* footerEnd) {
	while (footerEnd != nullptr) {
	Footer footer;
	memcpy(&footer, footerEnd - sizeof(Footer), sizeof(Footer));

	FooterAction* action = (FooterAction*)(footer >> 6);
	ptrdiff_t padding = footer & 63;

	footerEnd = action(footerEnd) - padding;
	}
	}

	char* SkArenaAlloc::NextBlock(char* footerEnd) {
	char* objEnd = footerEnd - (sizeof(Footer) + sizeof(char*));
	char* next;
	memmove(&next, objEnd, sizeof(char*));
	RunDtorsOnBlock(next);
	delete [] objEnd;
	return nullptr;
	}

	void SkArenaAlloc::installUint32Footer(FooterAction* action, uint32_t value, uint32_t padding) {
	memmove(fCursor, &value, sizeof(uint32_t));
	fCursor += sizeof(uint32_t);
	this->installFooter(action, padding);
	}

	void SkArenaAlloc::ensureSpace(uint32_t size, uint32_t alignment) {
	constexpr uint32_t headerSize = sizeof(Footer) + sizeof(ptrdiff_t);
	// The chrome c++ library we use does not define std::max_align_t.
	// This must be conservative to add the right amount of extra memory to handle the alignment
	// padding.
	constexpr uint32_t alignof_max_align_t = 8;
	constexpr uint32_t maxSize = std::numeric_limits<uint32_t>::max();
	constexpr uint32_t overhead = headerSize + sizeof(Footer);
	AssertRelease(size <= maxSize - overhead);
	uint32_t objSizeAndOverhead = size + overhead;
	if (alignment > alignof_max_align_t) {
	uint32_t alignmentOverhead = alignment - 1;
	AssertRelease(objSizeAndOverhead <= maxSize - alignmentOverhead);
	objSizeAndOverhead += alignmentOverhead;
	}

	uint32_t minAllocationSize;
	if (fFirstHeapAllocationSize <= maxSize / fFib0) {
	minAllocationSize = fFirstHeapAllocationSize * fFib0;
	fFib0 += fFib1;
	std::swap(fFib0, fFib1);
	} else {
	minAllocationSize = maxSize;
	}
	uint32_t allocationSize = std::max(objSizeAndOverhead, minAllocationSize);

	// Round up to a nice size. If > 32K align to 4K boundary else up to max_align_t. The > 32K
	// heuristic is from the JEMalloc behavior.
	{
	uint32_t mask = allocationSize > (1 << 15) ? (1 << 12) - 1 : 16 - 1;
	AssertRelease(allocationSize <= maxSize - mask);
	allocationSize = (allocationSize + mask) & ~mask;
	}

	char* newBlock = new char[allocationSize];

	auto previousDtor = fDtorCursor;
	fCursor = newBlock;
	fDtorCursor = newBlock;
	fEnd = fCursor + allocationSize;
	this->installPtrFooter(NextBlock, previousDtor, 0);
	}

	char* SkArenaAlloc::allocObjectWithFooter(uint32_t sizeIncludingFooter, uint32_t alignment) {
	uintptr_t mask = alignment - 1;

	restart:
	uint32_t skipOverhead = 0;
	bool needsSkipFooter = fCursor != fDtorCursor;
	if (needsSkipFooter) {
	skipOverhead = sizeof(Footer) + sizeof(uint32_t);
	}
	char* objStart = (char*)((uintptr_t)(fCursor + skipOverhead + mask) & ~mask);
	uint32_t totalSize = sizeIncludingFooter + skipOverhead;

	if ((ptrdiff_t)totalSize > fEnd - objStart) {
	this->ensureSpace(totalSize, alignment);
	goto restart;
	}

	AssertRelease((ptrdiff_t)totalSize <= fEnd - objStart);

	// Install a skip footer if needed, thus terminating a run of POD data. The calling code is
	// responsible for installing the footer after the object.
	if (needsSkipFooter) {
	this->installUint32Footer(SkipPod, ToU32(fCursor - fDtorCursor), 0);
	}

	return objStart;
	}