// Copyright (c) 2006-2008 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. #include "net/disk_cache/block_files.h" #include "base/file_util.h" #include "base/histogram.h" #include "base/string_util.h" #include "base/time.h" #include "net/disk_cache/file_lock.h" using base::Time; namespace { const wchar_t* kBlockName = L"data_"; // This array is used to perform a fast lookup of the nibble bit pattern to the // type of entry that can be stored there (number of consecutive blocks). const char s_types[16] = {4, 3, 2, 2, 1, 1, 1, 1, 0, 0, 0, 0, 0, 0, 0, 0}; // Returns the type of block (number of consecutive blocks that can be stored) // for a given nibble of the bitmap. inline int GetMapBlockType(uint8 value) { value &= 0xf; return s_types[value]; } void FixAllocationCounters(disk_cache::BlockFileHeader* header); // Creates a new entry on the allocation map, updating the apropriate counters. // target is the type of block to use (number of empty blocks), and size is the // actual number of blocks to use. bool CreateMapBlock(int target, int size, disk_cache::BlockFileHeader* header, int* index) { if (target <= 0 || target > disk_cache::kMaxNumBlocks || size <= 0 || size > disk_cache::kMaxNumBlocks) { NOTREACHED(); return false; } Time start = Time::Now(); // We are going to process the map on 32-block chunks (32 bits), and on every // chunk, iterate through the 8 nibbles where the new block can be located. int current = header->hints[target - 1]; for (int i = 0; i < header->max_entries / 32; i++, current++) { if (current == header->max_entries / 32) current = 0; uint32 map_block = header->allocation_map[current]; for (int j = 0; j < 8; j++, map_block >>= 4) { if (GetMapBlockType(map_block) != target) continue; disk_cache::FileLock lock(header); int index_offset = j * 4 + 4 - target; *index = current * 32 + index_offset; uint32 to_add = ((1 << size) - 1) << index_offset; header->allocation_map[current] |= to_add; header->hints[target - 1] = current; header->empty[target - 1]--; DCHECK(header->empty[target - 1] >= 0); header->num_entries++; if (target != size) { header->empty[target - size - 1]++; } HISTOGRAM_TIMES(L"DiskCache.CreateBlock", Time::Now() - start); return true; } } // It is possible to have an undetected corruption (for example when the OS // crashes), fix it here. LOG(ERROR) << "Failing CreateMapBlock"; FixAllocationCounters(header); return false; } // Deletes the block pointed by index from allocation_map, and updates the // relevant counters on the header. void DeleteMapBlock(int index, int size, disk_cache::BlockFileHeader* header) { if (size < 0 || size > disk_cache::kMaxNumBlocks) { NOTREACHED(); return; } Time start = Time::Now(); int byte_index = index / 8; uint8* byte_map = reinterpret_cast(header->allocation_map); uint8 map_block = byte_map[byte_index]; if (index % 8 >= 4) map_block >>= 4; // See what type of block will be availabe after we delete this one. int bits_at_end = 4 - size - index % 4; uint8 end_mask = (0xf << (4 - bits_at_end)) & 0xf; bool update_counters = (map_block & end_mask) == 0; uint8 new_value = map_block & ~(((1 << size) - 1) << (index % 4)); int new_type = GetMapBlockType(new_value); disk_cache::FileLock lock(header); DCHECK((((1 << size) - 1) << (index % 8)) < 0x100); uint8 to_clear = ((1 << size) - 1) << (index % 8); DCHECK((byte_map[byte_index] & to_clear) == to_clear); byte_map[byte_index] &= ~to_clear; if (update_counters) { if (bits_at_end) header->empty[bits_at_end - 1]--; header->empty[new_type - 1]++; DCHECK(header->empty[bits_at_end - 1] >= 0); } header->num_entries--; DCHECK(header->num_entries >= 0); HISTOGRAM_TIMES(L"DiskCache.DeleteBlock", Time::Now() - start); } // Restores the "empty counters" and allocation hints. void FixAllocationCounters(disk_cache::BlockFileHeader* header) { for (int i = 0; i < disk_cache::kMaxNumBlocks; i++) { header->hints[i] = 0; header->empty[i] = 0; } for (int i = 0; i < header->max_entries / 32; i++) { uint32 map_block = header->allocation_map[i]; for (int j = 0; j < 8; j++, map_block >>= 4) { int type = GetMapBlockType(map_block); if (type) header->empty[type -1]++; } } } bool NeedToGrowBlockFile(const disk_cache::BlockFileHeader* header, int block_count) { for (int i = block_count; i <= disk_cache::kMaxNumBlocks; i++) { if (header->empty[i - 1]) return false; } return true; } } // namespace namespace disk_cache { BlockFiles::~BlockFiles() { if (zero_buffer_) delete[] zero_buffer_; CloseFiles(); } bool BlockFiles::Init(bool create_files) { DCHECK(!init_); if (init_) return false; block_files_.resize(kFirstAdditionlBlockFile); for (int i = 0; i < kFirstAdditionlBlockFile; i++) { if (create_files) if (!CreateBlockFile(i, static_cast(i + 1), true)) return false; if (!OpenBlockFile(i)) return false; } init_ = true; return true; } void BlockFiles::CloseFiles() { init_ = false; for (unsigned int i = 0; i < block_files_.size(); i++) { if (block_files_[i]) { block_files_[i]->Release(); block_files_[i] = NULL; } } block_files_.clear(); } std::wstring BlockFiles::Name(int index) { // The file format allows for 256 files. DCHECK(index < 256 || index >= 0); std::wstring name(path_); std::wstring tmp = StringPrintf(L"%ls%d", kBlockName, index); file_util::AppendToPath(&name, tmp); return name; } bool BlockFiles::CreateBlockFile(int index, FileType file_type, bool force) { std::wstring name = Name(index); int flags = force ? base::PLATFORM_FILE_CREATE_ALWAYS : base::PLATFORM_FILE_CREATE; flags |= base::PLATFORM_FILE_WRITE | base::PLATFORM_FILE_EXCLUSIVE_WRITE; scoped_refptr file(new File( base::CreatePlatformFile(name.c_str(), flags, NULL))); if (!file->IsValid()) return false; BlockFileHeader header; header.entry_size = Addr::BlockSizeForFileType(file_type); header.this_file = static_cast(index); DCHECK(index <= kint16max && index >= 0); return file->Write(&header, sizeof(header), 0); } bool BlockFiles::OpenBlockFile(int index) { if (block_files_.size() - 1 < static_cast(index)) { DCHECK(index > 0); int to_add = index - static_cast(block_files_.size()) + 1; block_files_.resize(block_files_.size() + to_add); } std::wstring name = Name(index); MappedFile* file = new MappedFile(); file->AddRef(); if (!file->Init(name, kBlockHeaderSize)) { NOTREACHED(); LOG(ERROR) << "Failed to open " << name; file->Release(); return false; } block_files_[index] = file; BlockFileHeader* header = reinterpret_cast(file->buffer()); if (kBlockMagic != header->magic || kCurrentVersion != header->version) { LOG(ERROR) << "Invalid file version or magic"; return false; } if (header->updating) { // Last instance was not properly shutdown. if (!FixBlockFileHeader(file)) return false; } return true; } MappedFile* BlockFiles::GetFile(Addr address) { CHECK(block_files_.size() >= 4); int file_index = address.FileNumber(); if (static_cast(file_index) >= block_files_.size() || !block_files_[file_index]) { // We need to open the file if (!OpenBlockFile(file_index)) return NULL; } DCHECK(block_files_.size() >= static_cast(file_index)); return block_files_[file_index]; } bool BlockFiles::GrowBlockFile(MappedFile* file, BlockFileHeader* header) { if (kMaxBlocks == header->max_entries) return false; DCHECK(!header->empty[3]); int new_size = header->max_entries + 1024; if (new_size > kMaxBlocks) new_size = kMaxBlocks; int new_size_bytes = new_size * header->entry_size + sizeof(*header); FileLock lock(header); if (!file->SetLength(new_size_bytes)) { // Most likely we are trying to truncate the file, so the header is wrong. if (header->updating < 10 && !FixBlockFileHeader(file)) { // If we can't fix the file increase the lock guard so we'll pick it on // the next start and replace it. header->updating = 100; return false; } return (header->max_entries >= new_size); } header->empty[3] = (new_size - header->max_entries) / 4; // 4 blocks entries header->max_entries = new_size; return true; } MappedFile* BlockFiles::FileForNewBlock(FileType block_type, int block_count) { COMPILE_ASSERT(RANKINGS == 1, invalid_fily_type); MappedFile* file = block_files_[block_type - 1]; BlockFileHeader* header = reinterpret_cast(file->buffer()); Time start = Time::Now(); while (NeedToGrowBlockFile(header, block_count)) { if (kMaxBlocks == header->max_entries) { file = NextFile(file); if (!file) return NULL; header = reinterpret_cast(file->buffer()); continue; } if (!GrowBlockFile(file, header)) return NULL; break; } HISTOGRAM_TIMES(L"DiskCache.GetFileForNewBlock", Time::Now() - start); return file; } MappedFile* BlockFiles::NextFile(const MappedFile* file) { BlockFileHeader* header = reinterpret_cast(file->buffer()); int new_file = header->next_file; if (!new_file) { // RANKINGS is not reported as a type for small entries, but we may be // extending the rankings block file. FileType type = Addr::RequiredFileType(header->entry_size); if (header->entry_size == Addr::BlockSizeForFileType(RANKINGS)) type = RANKINGS; new_file = CreateNextBlockFile(type); if (!new_file) return NULL; FileLock lock(header); header->next_file = new_file; } // Only the block_file argument is relevant for what we want. Addr address(BLOCK_256, 1, new_file, 0); return GetFile(address); } int BlockFiles::CreateNextBlockFile(FileType block_type) { for (int i = kFirstAdditionlBlockFile; i <= kMaxBlockFile; i++) { if (CreateBlockFile(i, block_type, false)) return i; } return 0; } bool BlockFiles::CreateBlock(FileType block_type, int block_count, Addr* block_address) { if (block_type < RANKINGS || block_type > BLOCK_4K || block_count < 1 || block_count > 4) return false; if (!init_) return false; MappedFile* file = FileForNewBlock(block_type, block_count); if (!file) return false; BlockFileHeader* header = reinterpret_cast(file->buffer()); int target_size = 0; for (int i = block_count; i <= 4; i++) { if (header->empty[i - 1]) { target_size = i; break; } } DCHECK(target_size); int index; if (!CreateMapBlock(target_size, block_count, header, &index)) return false; Addr address(block_type, block_count, header->this_file, index); block_address->set_value(address.value()); return true; } void BlockFiles::DeleteBlock(Addr address, bool deep) { if (!address.is_initialized() || address.is_separate_file()) return; if (!zero_buffer_) { zero_buffer_ = new char[Addr::BlockSizeForFileType(BLOCK_4K) * 4]; memset(zero_buffer_, 0, Addr::BlockSizeForFileType(BLOCK_4K) * 4); } MappedFile* file = GetFile(address); if (!file) return; size_t size = address.BlockSize() * address.num_blocks(); size_t offset = address.start_block() * address.BlockSize() + kBlockHeaderSize; if (deep) file->Write(zero_buffer_, size, offset); BlockFileHeader* header = reinterpret_cast(file->buffer()); DeleteMapBlock(address.start_block(), address.num_blocks(), header); } bool BlockFiles::FixBlockFileHeader(MappedFile* file) { BlockFileHeader* header = reinterpret_cast(file->buffer()); int file_size = static_cast(file->GetLength()); if (file_size < static_cast(sizeof(*header))) return false; // file_size > 2GB is also an error. int expected = header->entry_size * header->max_entries + sizeof(*header); if (file_size != expected) { int max_expected = header->entry_size * kMaxBlocks + sizeof(*header); if (file_size < expected || header->empty[3] || file_size > max_expected) { NOTREACHED(); LOG(ERROR) << "Unexpected file size"; return false; } // We were in the middle of growing the file. int num_entries = (file_size - sizeof(*header)) / header->entry_size; header->max_entries = num_entries; } FixAllocationCounters(header); header->updating = 0; return true; } } // namespace disk_cache