// Copyright (c) 2018 PaddlePaddle Authors. All Rights Reserved. // // Licensed under the Apache License, Version 2.0 (the "License"); // you may not use this file except in compliance with the License. // You may obtain a copy of the License at // // http://www.apache.org/licenses/LICENSE-2.0 // // Unless required by applicable law or agreed to in writing, software // distributed under the License is distributed on an "AS IS" BASIS, // WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. // See the License for the specific language governing permissions and // limitations under the License. #include "paddle/fluid/memory/allocation/best_fit_allocator.h" #include #include #include #include namespace paddle { namespace memory { namespace allocation { static int HighestBitPos(size_t N) { if (UNLIKELY(N == 0)) { return 0; } else { #ifdef __GNUCC__ return sizeof(unsigned int) * 8 - __builtin_clz(N); #else return static_cast(std::log2(N) + 1); #endif } } BestFitAllocator::BestFitAllocator(Allocation* allocation) : allocation_(allocation) { details::Chunk chunk; chunk.size_ = allocation_->size(); chunk.offset_ = 0; chunk.is_free = true; chunks_.emplace_back(chunk); free_chunks_[HighestBitPos(chunk.size_)].insert( {chunk.size_, chunks_.begin()}); } size_t BestFitAllocator::FreeSize() const { size_t acc = 0; for (auto& array_item : free_chunks_) { for (auto& pair : array_item) { acc += pair.second->size_; } } return acc; } BestFitAllocator::ListIt BestFitAllocator::SplitChunk(size_t request_size, size_t free_chunk_offset, MapIt bin_iterator) { auto to_split_it = bin_iterator->second; free_chunks_[free_chunk_offset].erase(bin_iterator); PADDLE_ENFORCE(to_split_it->is_free); PADDLE_ENFORCE_GE(to_split_it->size_, request_size); auto remaining_size = to_split_it->size_ - request_size; details::Chunk to_use; details::Chunk remaining; to_use.size_ = request_size; to_use.is_free = false; remaining.size_ = remaining_size; remaining.is_free = true; // calc offsets to_use.offset_ = to_split_it->offset_; remaining.offset_ = to_use.offset_ + to_use.size_; // insert to chunk list auto to_use_it = chunks_.insert(to_split_it, to_use); if (remaining.size_ != 0) { auto bit_size = static_cast(HighestBitPos(remaining.size_)); free_chunks_[bit_size].insert( {remaining.size_, chunks_.insert(to_split_it, remaining)}); } chunks_.erase(to_split_it); return to_use_it; } void BestFitAllocator::InsertFreeNode(const ListIt& it) { auto pos = static_cast(HighestBitPos(it->size_)); auto& free_map = free_chunks_[pos]; free_map.insert({it->size_, it}); } void BestFitAllocator::EraseFreeNode(const ListIt& it) { size_t pos = static_cast(HighestBitPos(it->size_)); auto& free_map = free_chunks_[pos]; auto map_it = free_map.find(it->size_); while (map_it->second != it && map_it != free_map.end()) { ++map_it; } PADDLE_ENFORCE(map_it != free_map.end()); free_map.erase(map_it); } size_t BestFitAllocator::NumFreeChunks() const { size_t num = 0; for (auto& array_item : free_chunks_) { num += array_item.size(); } return num; } void BestFitAllocator::Free(Allocation* allocation) { auto* bf_allocation = dynamic_cast(allocation); auto chunk_it = bf_allocation->ChunkIterator(); PADDLE_ENFORCE(!chunk_it->is_free); chunk_it->is_free = true; if (chunk_it != chunks_.begin()) { auto prev_it = chunk_it; --prev_it; if (prev_it->is_free) { // Merge Left. EraseFreeNode(prev_it); prev_it->size_ += chunk_it->size_; chunks_.erase(chunk_it); chunk_it = prev_it; } } auto next_it = chunk_it; ++next_it; if (next_it != chunks_.end() && next_it->is_free) { EraseFreeNode(next_it); chunk_it->size_ += next_it->size_; chunks_.erase(next_it); } InsertFreeNode(chunk_it); delete allocation; } Allocation* BestFitAllocator::AllocateImpl(size_t size, Allocator::Attr attr) { auto highest_set_bit = static_cast(HighestBitPos(size)); MapIt map_it; for (; highest_set_bit < free_chunks_.size(); ++highest_set_bit) { map_it = free_chunks_[highest_set_bit].lower_bound(size); if (map_it != free_chunks_[highest_set_bit].end()) { break; } } if (UNLIKELY(highest_set_bit == free_chunks_.size())) { throw BadAlloc(string::Sprintf( "Cannot allocate %d, All fragments size is %d", size, FreeSize())); } auto chunk_it = SplitChunk(size, highest_set_bit, map_it); return new BestFitAllocation(this, chunk_it); } BestFitAllocation::BestFitAllocation( paddle::memory::allocation::BestFitAllocator* allocator, typename details::ChunkList::iterator chunk_it) : Allocation(reinterpret_cast( reinterpret_cast(allocator->BasePtr()) + chunk_it->offset_), chunk_it->size_, allocator->Place()), chunk_it_(chunk_it) {} } // namespace allocation } // namespace memory } // namespace paddle