util/arena.cc - platform/external/regex-re2 - Git at Google

 // Copyright 2000 The RE2 Authors.  All Rights Reserved.
 // Use of this source code is governed by a BSD-style
 // license that can be found in the LICENSE file.

 #include "util/util.h"

 namespace re2 {

 // ----------------------------------------------------------------------
 // UnsafeArena::UnsafeArena()
 // UnsafeArena::~UnsafeArena()
 //    Destroying the arena automatically calls Reset()
 // ----------------------------------------------------------------------


 UnsafeArena::UnsafeArena(const size_t block_size)
   : block_size_(block_size),
     freestart_(NULL),                   // set for real in Reset()
     last_alloc_(NULL),
     remaining_(0),
     blocks_alloced_(1),
     overflow_blocks_(NULL) {
   assert(block_size > kDefaultAlignment);

   first_blocks_[0].mem = reinterpret_cast<char*>(malloc(block_size_));
   first_blocks_[0].size = block_size_;

   Reset();
 }

 UnsafeArena::~UnsafeArena() {
   FreeBlocks();
   assert(overflow_blocks_ == NULL);    // FreeBlocks() should do that
   // The first X blocks stay allocated always by default.  Delete them now.
   for (int i = 0; i < blocks_alloced_; i++)
     free(first_blocks_[i].mem);
 }

 // ----------------------------------------------------------------------
 // UnsafeArena::Reset()
 //    Clears all the memory an arena is using.
 // ----------------------------------------------------------------------

 void UnsafeArena::Reset() {
   FreeBlocks();
   freestart_ = first_blocks_[0].mem;
   remaining_ = first_blocks_[0].size;
   last_alloc_ = NULL;

   // We do not know for sure whether or not the first block is aligned,
   // so we fix that right now.
   const int overage = reinterpret_cast<uintptr_t>(freestart_) &
                       (kDefaultAlignment-1);
   if (overage > 0) {
     const int waste = kDefaultAlignment - overage;
     freestart_ += waste;
     remaining_ -= waste;
   }
   freestart_when_empty_ = freestart_;
   assert(!(reinterpret_cast<uintptr_t>(freestart_)&(kDefaultAlignment-1)));
 }

 // -------------------------------------------------------------
 // UnsafeArena::AllocNewBlock()
 //    Adds and returns an AllocatedBlock.
 //    The returned AllocatedBlock* is valid until the next call
 //    to AllocNewBlock or Reset.  (i.e. anything that might
 //    affect overflow_blocks_).
 // -------------------------------------------------------------

 UnsafeArena::AllocatedBlock* UnsafeArena::AllocNewBlock(const size_t block_size) {
   AllocatedBlock *block;
   // Find the next block.
   if ( blocks_alloced_ < arraysize(first_blocks_) ) {
     // Use one of the pre-allocated blocks
     block = &first_blocks_[blocks_alloced_++];
   } else {                   // oops, out of space, move to the vector
     if (overflow_blocks_ == NULL) overflow_blocks_ = new vector<AllocatedBlock>;
     // Adds another block to the vector.
     overflow_blocks_->resize(overflow_blocks_->size()+1);
     // block points to the last block of the vector.
     block = &overflow_blocks_->back();
   }

   block->mem = reinterpret_cast<char*>(malloc(block_size));
   block->size = block_size;

   return block;
 }

 // ----------------------------------------------------------------------
 // UnsafeArena::GetMemoryFallback()
 //    We take memory out of our pool, aligned on the byte boundary
 //    requested.  If we don't have space in our current pool, we
 //    allocate a new block (wasting the remaining space in the
 //    current block) and give you that.  If your memory needs are
 //    too big for a single block, we make a special your-memory-only
 //    allocation -- this is equivalent to not using the arena at all.
 // ----------------------------------------------------------------------

 void* UnsafeArena::GetMemoryFallback(const size_t size, const int align) {
   if (size == 0)
     return NULL;             // stl/stl_alloc.h says this is okay

   assert(align > 0 && 0 == (align & (align - 1)));  // must be power of 2

   // If the object is more than a quarter of the block size, allocate
   // it separately to avoid wasting too much space in leftover bytes
   if (block_size_ == 0 || size > block_size_/4) {
     // then it gets its own block in the arena
     assert(align <= kDefaultAlignment);   // because that's what new gives us
     // This block stays separate from the rest of the world; in particular
     // we don't update last_alloc_ so you can't reclaim space on this block.
     return AllocNewBlock(size)->mem;
   }

   const int overage =
     (reinterpret_cast<uintptr_t>(freestart_) & (align-1));
   if (overage) {
     const int waste = align - overage;
     freestart_ += waste;
     if (waste < remaining_) {
       remaining_ -= waste;
     } else {
       remaining_ = 0;
     }
   }
   if (size > remaining_) {
     AllocatedBlock *block = AllocNewBlock(block_size_);
     freestart_ = block->mem;
     remaining_ = block->size;
   }
   remaining_ -= size;
   last_alloc_ = freestart_;
   freestart_ += size;
   assert((reinterpret_cast<uintptr_t>(last_alloc_) & (align-1)) == 0);
   return reinterpret_cast<void*>(last_alloc_);
 }

 // ----------------------------------------------------------------------
 // UnsafeArena::FreeBlocks()
 //    Unlike GetMemory(), which does actual work, ReturnMemory() is a
 //    no-op: we don't "free" memory until Reset() is called.  We do
 //    update some stats, though.  Note we do no checking that the
 //    pointer you pass in was actually allocated by us, or that it
 //    was allocated for the size you say, so be careful here!
 //       FreeBlocks() does the work for Reset(), actually freeing all
 //    memory allocated in one fell swoop.
 // ----------------------------------------------------------------------

 void UnsafeArena::FreeBlocks() {
   for ( int i = 1; i < blocks_alloced_; ++i ) {  // keep first block alloced
     free(first_blocks_[i].mem);
     first_blocks_[i].mem = NULL;
     first_blocks_[i].size = 0;
   }
   blocks_alloced_ = 1;
   if (overflow_blocks_ != NULL) {
     vector<AllocatedBlock>::iterator it;
     for (it = overflow_blocks_->begin(); it != overflow_blocks_->end(); ++it) {
       free(it->mem);
     }
     delete overflow_blocks_;             // These should be used very rarely
     overflow_blocks_ = NULL;
   }
 }

 }  // namespace re2
	// Copyright 2000 The RE2 Authors. All Rights Reserved.
	// Use of this source code is governed by a BSD-style
	// license that can be found in the LICENSE file.

	#include "util/util.h"

	namespace re2 {

	// ----------------------------------------------------------------------
	// UnsafeArena::UnsafeArena()
	// UnsafeArena::~UnsafeArena()
	// Destroying the arena automatically calls Reset()
	// ----------------------------------------------------------------------


	UnsafeArena::UnsafeArena(const size_t block_size)
	: block_size_(block_size),
	freestart_(NULL), // set for real in Reset()
	last_alloc_(NULL),
	remaining_(0),
	blocks_alloced_(1),
	overflow_blocks_(NULL) {
	assert(block_size > kDefaultAlignment);

	first_blocks_[0].mem = reinterpret_cast<char*>(malloc(block_size_));
	first_blocks_[0].size = block_size_;

	Reset();
	}

	UnsafeArena::~UnsafeArena() {
	FreeBlocks();
	assert(overflow_blocks_ == NULL); // FreeBlocks() should do that
	// The first X blocks stay allocated always by default. Delete them now.
	for (int i = 0; i < blocks_alloced_; i++)
	free(first_blocks_[i].mem);
	}

	// ----------------------------------------------------------------------
	// UnsafeArena::Reset()
	// Clears all the memory an arena is using.
	// ----------------------------------------------------------------------

	void UnsafeArena::Reset() {
	FreeBlocks();
	freestart_ = first_blocks_[0].mem;
	remaining_ = first_blocks_[0].size;
	last_alloc_ = NULL;

	// We do not know for sure whether or not the first block is aligned,
	// so we fix that right now.
	const int overage = reinterpret_cast<uintptr_t>(freestart_) &
	(kDefaultAlignment-1);
	if (overage > 0) {
	const int waste = kDefaultAlignment - overage;
	freestart_ += waste;
	remaining_ -= waste;
	}
	freestart_when_empty_ = freestart_;
	assert(!(reinterpret_cast<uintptr_t>(freestart_)&(kDefaultAlignment-1)));
	}

	// -------------------------------------------------------------
	// UnsafeArena::AllocNewBlock()
	// Adds and returns an AllocatedBlock.
	// The returned AllocatedBlock* is valid until the next call
	// to AllocNewBlock or Reset. (i.e. anything that might
	// affect overflow_blocks_).
	// -------------------------------------------------------------

	UnsafeArena::AllocatedBlock* UnsafeArena::AllocNewBlock(const size_t block_size) {
	AllocatedBlock *block;
	// Find the next block.
	if ( blocks_alloced_ < arraysize(first_blocks_) ) {
	// Use one of the pre-allocated blocks
	block = &first_blocks_[blocks_alloced_++];
	} else { // oops, out of space, move to the vector
	if (overflow_blocks_ == NULL) overflow_blocks_ = new vector<AllocatedBlock>;
	// Adds another block to the vector.
	overflow_blocks_->resize(overflow_blocks_->size()+1);
	// block points to the last block of the vector.
	block = &overflow_blocks_->back();
	}

	block->mem = reinterpret_cast<char*>(malloc(block_size));
	block->size = block_size;

	return block;
	}

	// ----------------------------------------------------------------------
	// UnsafeArena::GetMemoryFallback()
	// We take memory out of our pool, aligned on the byte boundary
	// requested. If we don't have space in our current pool, we
	// allocate a new block (wasting the remaining space in the
	// current block) and give you that. If your memory needs are
	// too big for a single block, we make a special your-memory-only
	// allocation -- this is equivalent to not using the arena at all.
	// ----------------------------------------------------------------------

	void* UnsafeArena::GetMemoryFallback(const size_t size, const int align) {
	if (size == 0)
	return NULL; // stl/stl_alloc.h says this is okay

	assert(align > 0 && 0 == (align & (align - 1))); // must be power of 2

	// If the object is more than a quarter of the block size, allocate
	// it separately to avoid wasting too much space in leftover bytes
	if (block_size_ == 0 \|\| size > block_size_/4) {
	// then it gets its own block in the arena
	assert(align <= kDefaultAlignment); // because that's what new gives us
	// This block stays separate from the rest of the world; in particular
	// we don't update last_alloc_ so you can't reclaim space on this block.
	return AllocNewBlock(size)->mem;
	}

	const int overage =
	(reinterpret_cast<uintptr_t>(freestart_) & (align-1));
	if (overage) {
	const int waste = align - overage;
	freestart_ += waste;
	if (waste < remaining_) {
	remaining_ -= waste;
	} else {
	remaining_ = 0;
	}
	}
	if (size > remaining_) {
	AllocatedBlock *block = AllocNewBlock(block_size_);
	freestart_ = block->mem;
	remaining_ = block->size;
	}
	remaining_ -= size;
	last_alloc_ = freestart_;
	freestart_ += size;
	assert((reinterpret_cast<uintptr_t>(last_alloc_) & (align-1)) == 0);
	return reinterpret_cast<void*>(last_alloc_);
	}

	// ----------------------------------------------------------------------
	// UnsafeArena::FreeBlocks()
	// Unlike GetMemory(), which does actual work, ReturnMemory() is a
	// no-op: we don't "free" memory until Reset() is called. We do
	// update some stats, though. Note we do no checking that the
	// pointer you pass in was actually allocated by us, or that it
	// was allocated for the size you say, so be careful here!
	// FreeBlocks() does the work for Reset(), actually freeing all
	// memory allocated in one fell swoop.
	// ----------------------------------------------------------------------

	void UnsafeArena::FreeBlocks() {
	for ( int i = 1; i < blocks_alloced_; ++i ) { // keep first block alloced
	free(first_blocks_[i].mem);
	first_blocks_[i].mem = NULL;
	first_blocks_[i].size = 0;
	}
	blocks_alloced_ = 1;
	if (overflow_blocks_ != NULL) {
	vector<AllocatedBlock>::iterator it;
	for (it = overflow_blocks_->begin(); it != overflow_blocks_->end(); ++it) {
	free(it->mem);
	}
	delete overflow_blocks_; // These should be used very rarely
	overflow_blocks_ = NULL;
	}
	}

	} // namespace re2