src/net/disk_cache/blockfile/block_files.cc - cobalt - Git at Google

 // Copyright (c) 2012 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/blockfile/block_files.h"

 #include <limits>

 #include "base/atomicops.h"
 #include "base/files/file_path.h"
 #include "base/metrics/histogram_macros.h"
 #include "base/strings/string_util.h"
 #include "base/strings/stringprintf.h"
 #include "base/threading/thread_checker.h"
 #include "base/time/time.h"
 #include "net/disk_cache/blockfile/file_lock.h"
 #include "net/disk_cache/blockfile/stress_support.h"
 #include "net/disk_cache/blockfile/trace.h"
 #include "net/disk_cache/cache_util.h"
 #include "starboard/memory.h"

 using base::TimeTicks;

 namespace {

 const char kBlockName[] = "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(uint32_t value) {
   value &= 0xf;
   return s_types[value];
 }

 }  // namespace

 namespace disk_cache {

 BlockHeader::BlockHeader() : header_(NULL) {
 }

 BlockHeader::BlockHeader(BlockFileHeader* header) : header_(header) {
 }

 BlockHeader::BlockHeader(MappedFile* file)
     : header_(reinterpret_cast<BlockFileHeader*>(file->buffer())) {
 }

 BlockHeader::BlockHeader(const BlockHeader& other) = default;

 BlockHeader::~BlockHeader() = default;

 bool BlockHeader::CreateMapBlock(int size, int* index) {
   DCHECK(size > 0 && size <= kMaxNumBlocks);
   int target = 0;
   for (int i = size; i <= kMaxNumBlocks; i++) {
     if (header_->empty[i - 1]) {
       target = i;
       break;
     }
   }

   if (!target) {
     STRESS_NOTREACHED();
     return false;
   }

   TimeTicks start = TimeTicks::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_t 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;
       STRESS_DCHECK(*index / 4 == (*index + size - 1) / 4);
       uint32_t to_add = ((1 << size) - 1) << index_offset;
       header_->num_entries++;

       // Note that there is no race in the normal sense here, but if we enforce
       // the order of memory accesses between num_entries and allocation_map, we
       // can assert that even if we crash here, num_entries will never be less
       // than the actual number of used blocks.
       base::subtle::MemoryBarrier();
       header_->allocation_map[current] |= to_add;

       header_->hints[target - 1] = current;
       header_->empty[target - 1]--;
       STRESS_DCHECK(header_->empty[target - 1] >= 0);
       if (target != size) {
         header_->empty[target - size - 1]++;
       }
       LOCAL_HISTOGRAM_TIMES("DiskCache.CreateBlock", TimeTicks::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();
   return false;
 }

 void BlockHeader::DeleteMapBlock(int index, int size) {
   if (size < 0 || size > kMaxNumBlocks) {
     NOTREACHED();
     return;
   }
   TimeTicks start = TimeTicks::Now();
   int byte_index = index / 8;
   uint8_t* byte_map = reinterpret_cast<uint8_t*>(header_->allocation_map);
   uint8_t map_block = byte_map[byte_index];

   if (index % 8 >= 4)
     map_block >>= 4;

   // See what type of block will be available after we delete this one.
   int bits_at_end = 4 - size - index % 4;
   uint8_t end_mask = (0xf << (4 - bits_at_end)) & 0xf;
   bool update_counters = (map_block & end_mask) == 0;
   uint8_t new_value = map_block & ~(((1 << size) - 1) << (index % 4));
   int new_type = GetMapBlockType(new_value);

   disk_cache::FileLock lock(header_);
   STRESS_DCHECK((((1 << size) - 1) << (index % 8)) < 0x100);
   uint8_t to_clear = ((1 << size) - 1) << (index % 8);
   STRESS_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]++;
     STRESS_DCHECK(header_->empty[bits_at_end - 1] >= 0);
   }
   base::subtle::MemoryBarrier();
   header_->num_entries--;
   STRESS_DCHECK(header_->num_entries >= 0);
   LOCAL_HISTOGRAM_TIMES("DiskCache.DeleteBlock", TimeTicks::Now() - start);
 }

 // Note that this is a simplified version of DeleteMapBlock().
 bool BlockHeader::UsedMapBlock(int index, int size) {
   if (size < 0 || size > kMaxNumBlocks)
     return false;

   int byte_index = index / 8;
   uint8_t* byte_map = reinterpret_cast<uint8_t*>(header_->allocation_map);
   uint8_t map_block = byte_map[byte_index];

   if (index % 8 >= 4)
     map_block >>= 4;

   STRESS_DCHECK((((1 << size) - 1) << (index % 8)) < 0x100);
   uint8_t to_clear = ((1 << size) - 1) << (index % 8);
   return ((byte_map[byte_index] & to_clear) == to_clear);
 }

 void BlockHeader::FixAllocationCounters() {
   for (int i = 0; i < kMaxNumBlocks; i++) {
     header_->hints[i] = 0;
     header_->empty[i] = 0;
   }

   for (int i = 0; i < header_->max_entries / 32; i++) {
     uint32_t 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 BlockHeader::NeedToGrowBlockFile(int block_count) const {
   bool have_space = false;
   int empty_blocks = 0;
   for (int i = 0; i < kMaxNumBlocks; i++) {
     empty_blocks += header_->empty[i] * (i + 1);
     if (i >= block_count - 1 && header_->empty[i])
       have_space = true;
   }

   if (header_->next_file && (empty_blocks < kMaxBlocks / 10)) {
     // This file is almost full but we already created another one, don't use
     // this file yet so that it is easier to find empty blocks when we start
     // using this file again.
     return true;
   }
   return !have_space;
 }

 bool BlockHeader::CanAllocate(int block_count) const {
   DCHECK_GT(block_count, 0);
   for (int i = block_count - 1; i < kMaxNumBlocks; i++) {
     if (header_->empty[i])
       return true;
   }

   return false;
 }

 int BlockHeader::EmptyBlocks() const {
   int empty_blocks = 0;
   for (int i = 0; i < kMaxNumBlocks; i++) {
     empty_blocks += header_->empty[i] * (i + 1);
     if (header_->empty[i] < 0)
       return 0;
   }
   return empty_blocks;
 }

 int BlockHeader::MinimumAllocations() const {
   return header_->empty[kMaxNumBlocks - 1];
 }

 int BlockHeader::Capacity() const {
   return header_->max_entries;
 }

 bool BlockHeader::ValidateCounters() const {
   if (header_->max_entries < 0 || header_->max_entries > kMaxBlocks ||
       header_->num_entries < 0)
     return false;

   int empty_blocks = EmptyBlocks();
   if (empty_blocks + header_->num_entries > header_->max_entries)
     return false;

   return true;
 }

 int BlockHeader::FileId() const {
   return header_->this_file;
 }

 int BlockHeader::NextFileId() const {
   return header_->next_file;
 }

 int BlockHeader::Size() const {
   return static_cast<int>(sizeof(*header_));
 }

 BlockFileHeader* BlockHeader::Header() {
   return header_;
 }

 // ------------------------------------------------------------------------

 BlockFiles::BlockFiles(const base::FilePath& path)
     : init_(false), zero_buffer_(NULL), path_(path) {
 }

 BlockFiles::~BlockFiles() {
   if (zero_buffer_)
     delete[] zero_buffer_;
   CloseFiles();
 }

 bool BlockFiles::Init(bool create_files) {
   DCHECK(!init_);
   if (init_)
     return false;

   thread_checker_.reset(new base::ThreadChecker);

   block_files_.resize(kFirstAdditionalBlockFile);
   for (int16_t i = 0; i < kFirstAdditionalBlockFile; i++) {
     if (create_files)
       if (!CreateBlockFile(i, static_cast<FileType>(i + 1), true))
         return false;

     if (!OpenBlockFile(i))
       return false;

     // Walk this chain of files removing empty ones.
     if (!RemoveEmptyFile(static_cast<FileType>(i + 1)))
       return false;
   }

   init_ = true;
   return true;
 }

 MappedFile* BlockFiles::GetFile(Addr address) {
   DCHECK(thread_checker_->CalledOnValidThread());
   DCHECK_GE(block_files_.size(),
             static_cast<size_t>(kFirstAdditionalBlockFile));
   DCHECK(address.is_block_file() || !address.is_initialized());
   if (!address.is_initialized())
     return NULL;

   int file_index = address.FileNumber();
   if (static_cast<unsigned int>(file_index) >= block_files_.size() ||
       !block_files_[file_index]) {
     // We need to open the file
     if (!OpenBlockFile(file_index))
       return NULL;
   }
   DCHECK_GE(block_files_.size(), static_cast<unsigned int>(file_index));
   return block_files_[file_index].get();
 }

 bool BlockFiles::CreateBlock(FileType block_type, int block_count,
                              Addr* block_address) {
   DCHECK(thread_checker_->CalledOnValidThread());
   DCHECK_NE(block_type, EXTERNAL);
   DCHECK_NE(block_type, BLOCK_FILES);
   DCHECK_NE(block_type, BLOCK_ENTRIES);
   DCHECK_NE(block_type, BLOCK_EVICTED);
   if (block_count < 1 || block_count > kMaxNumBlocks)
     return false;

   if (!init_)
     return false;

   MappedFile* file = FileForNewBlock(block_type, block_count);
   if (!file)
     return false;

   ScopedFlush flush(file);
   BlockHeader file_header(file);

   int index;
   if (!file_header.CreateMapBlock(block_count, &index))
     return false;

   Addr address(block_type, block_count, file_header.FileId(), index);
   block_address->set_value(address.value());
   Trace("CreateBlock 0x%x", address.value());
   return true;
 }

 void BlockFiles::DeleteBlock(Addr address, bool deep) {
   DCHECK(thread_checker_->CalledOnValidThread());
   if (!address.is_initialized() || address.is_separate_file())
     return;

   if (!zero_buffer_) {
     zero_buffer_ = new char[Addr::BlockSizeForFileType(BLOCK_4K) * 4];
     SbMemorySet(zero_buffer_, 0, Addr::BlockSizeForFileType(BLOCK_4K) * 4);
   }
   MappedFile* file = GetFile(address);
   if (!file)
     return;

   Trace("DeleteBlock 0x%x", address.value());

   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);

   BlockHeader file_header(file);
   file_header.DeleteMapBlock(address.start_block(), address.num_blocks());
   file->Flush();

   if (!file_header.Header()->num_entries) {
     // This file is now empty. Let's try to delete it.
     FileType type = Addr::RequiredFileType(file_header.Header()->entry_size);
     if (Addr::BlockSizeForFileType(RANKINGS) ==
         file_header.Header()->entry_size) {
       type = RANKINGS;
     }
     RemoveEmptyFile(type);  // Ignore failures.
   }
 }

 void BlockFiles::CloseFiles() {
   if (init_) {
     DCHECK(thread_checker_->CalledOnValidThread());
   }
   init_ = false;
   block_files_.clear();
 }

 void BlockFiles::ReportStats() {
   DCHECK(thread_checker_->CalledOnValidThread());
   int used_blocks[kFirstAdditionalBlockFile];
   int load[kFirstAdditionalBlockFile];
   for (int i = 0; i < kFirstAdditionalBlockFile; i++) {
     GetFileStats(i, &used_blocks[i], &load[i]);
   }
   UMA_HISTOGRAM_COUNTS_1M("DiskCache.Blocks_0", used_blocks[0]);
   UMA_HISTOGRAM_COUNTS_1M("DiskCache.Blocks_1", used_blocks[1]);
   UMA_HISTOGRAM_COUNTS_1M("DiskCache.Blocks_2", used_blocks[2]);
   UMA_HISTOGRAM_COUNTS_1M("DiskCache.Blocks_3", used_blocks[3]);

   UMA_HISTOGRAM_ENUMERATION("DiskCache.BlockLoad_0", load[0], 101);
   UMA_HISTOGRAM_ENUMERATION("DiskCache.BlockLoad_1", load[1], 101);
   UMA_HISTOGRAM_ENUMERATION("DiskCache.BlockLoad_2", load[2], 101);
   UMA_HISTOGRAM_ENUMERATION("DiskCache.BlockLoad_3", load[3], 101);
 }

 bool BlockFiles::IsValid(Addr address) {
 #ifdef NDEBUG
   return true;
 #else
   if (!address.is_initialized() || address.is_separate_file())
     return false;

   MappedFile* file = GetFile(address);
   if (!file)
     return false;

   BlockHeader header(file);
   bool rv = header.UsedMapBlock(address.start_block(), address.num_blocks());
   DCHECK(rv);

   static bool read_contents = false;
   if (read_contents) {
     std::unique_ptr<char[]> buffer;
     buffer.reset(new char[Addr::BlockSizeForFileType(BLOCK_4K) * 4]);
     size_t size = address.BlockSize() * address.num_blocks();
     size_t offset = address.start_block() * address.BlockSize() +
                     kBlockHeaderSize;
     bool ok = file->Read(buffer.get(), size, offset);
     DCHECK(ok);
   }

   return rv;
 #endif
 }

 bool BlockFiles::CreateBlockFile(int index, FileType file_type, bool force) {
   base::FilePath name = Name(index);
   int flags = force ? base::File::FLAG_CREATE_ALWAYS : base::File::FLAG_CREATE;
   flags |= base::File::FLAG_WRITE | base::File::FLAG_EXCLUSIVE_WRITE;

   scoped_refptr<File> file(new File(base::File(name, flags)));
   if (!file->IsValid())
     return false;

   BlockFileHeader header;
   SbMemorySet(&header, 0, sizeof(header));
   header.magic = kBlockMagic;
   header.version = kBlockVersion2;
   header.entry_size = Addr::BlockSizeForFileType(file_type);
   header.this_file = static_cast<int16_t>(index);
   DCHECK(index <= std::numeric_limits<int16_t>::max() && index >= 0);

   return file->Write(&header, sizeof(header), 0);
 }

 bool BlockFiles::OpenBlockFile(int index) {
   if (block_files_.size() - 1 < static_cast<unsigned int>(index)) {
     DCHECK(index > 0);
     int to_add = index - static_cast<int>(block_files_.size()) + 1;
     block_files_.resize(block_files_.size() + to_add);
   }

   base::FilePath name = Name(index);
   scoped_refptr<MappedFile> file(new MappedFile());

   if (!file->Init(name, kBlockHeaderSize)) {
     LOG(ERROR) << "Failed to open " << name.value();
     return false;
   }

   size_t file_len = file->GetLength();
   if (file_len < static_cast<size_t>(kBlockHeaderSize)) {
     LOG(ERROR) << "File too small " << name.value();
     return false;
   }

   BlockHeader file_header(file.get());
   BlockFileHeader* header = file_header.Header();
   if (kBlockMagic != header->magic || kBlockVersion2 != header->version) {
     LOG(ERROR) << "Invalid file version or magic " << name.value();
     return false;
   }

   if (header->updating || !file_header.ValidateCounters()) {
     // Last instance was not properly shutdown, or counters are out of sync.
     if (!FixBlockFileHeader(file.get())) {
       LOG(ERROR) << "Unable to fix block file " << name.value();
       return false;
     }
   }

   if (static_cast<int>(file_len) <
       header->max_entries * header->entry_size + kBlockHeaderSize) {
     LOG(ERROR) << "File too small " << name.value();
     return false;
   }

   if (index == 0) {
     // Load the links file into memory.
     if (!file->Preload())
       return false;
   }

   ScopedFlush flush(file.get());
   DCHECK(!block_files_[index]);
   block_files_[index] = std::move(file);
   return true;
 }

 bool BlockFiles::GrowBlockFile(MappedFile* file, BlockFileHeader* header) {
   if (kMaxBlocks == header->max_entries)
     return false;

   ScopedFlush flush(file);
   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);

   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);
   }

   FileLock lock(header);
   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) {
   static_assert(RANKINGS == 1, "invalid file type");
   MappedFile* file = block_files_[block_type - 1].get();
   BlockHeader file_header(file);

   TimeTicks start = TimeTicks::Now();
   while (file_header.NeedToGrowBlockFile(block_count)) {
     if (kMaxBlocks == file_header.Header()->max_entries) {
       file = NextFile(file);
       if (!file)
         return NULL;
       file_header = BlockHeader(file);
       continue;
     }

     if (!GrowBlockFile(file, file_header.Header()))
       return NULL;
     break;
   }
   LOCAL_HISTOGRAM_TIMES("DiskCache.GetFileForNewBlock",
                         TimeTicks::Now() - start);
   return file;
 }

 MappedFile* BlockFiles::NextFile(MappedFile* file) {
   ScopedFlush flush(file);
   BlockFileHeader* header = reinterpret_cast<BlockFileHeader*>(file->buffer());
   int16_t 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);
 }

 int16_t BlockFiles::CreateNextBlockFile(FileType block_type) {
   for (int16_t i = kFirstAdditionalBlockFile; i <= kMaxBlockFile; i++) {
     if (CreateBlockFile(i, block_type, false))
       return i;
   }
   return 0;
 }

 // We walk the list of files for this particular block type, deleting the ones
 // that are empty.
 bool BlockFiles::RemoveEmptyFile(FileType block_type) {
   MappedFile* file = block_files_[block_type - 1].get();
   BlockFileHeader* header = reinterpret_cast<BlockFileHeader*>(file->buffer());

   while (header->next_file) {
     // Only the block_file argument is relevant for what we want.
     Addr address(BLOCK_256, 1, header->next_file, 0);
     MappedFile* next_file = GetFile(address);
     if (!next_file)
       return false;

     BlockFileHeader* next_header =
         reinterpret_cast<BlockFileHeader*>(next_file->buffer());
     if (!next_header->num_entries) {
       DCHECK_EQ(next_header->entry_size, header->entry_size);
       // Delete next_file and remove it from the chain.
       int file_index = header->next_file;
       header->next_file = next_header->next_file;
       DCHECK(block_files_.size() >= static_cast<unsigned int>(file_index));
       file->Flush();

       // We get a new handle to the file and release the old one so that the
       // file gets unmmaped... so we can delete it.
       base::FilePath name = Name(file_index);
       scoped_refptr<File> this_file(new File(false));
       this_file->Init(name);
       block_files_[file_index] = NULL;

       int failure = DeleteCacheFile(name) ? 0 : 1;
       UMA_HISTOGRAM_COUNTS_1M("DiskCache.DeleteFailed2", failure);
       if (failure)
         LOG(ERROR) << "Failed to delete " << name.value() << " from the cache.";
       continue;
     }

     header = next_header;
     file = next_file;
   }
   return true;
 }

 // Note that we expect to be called outside of a FileLock... however, we cannot
 // DCHECK on header->updating because we may be fixing a crash.
 bool BlockFiles::FixBlockFileHeader(MappedFile* file) {
   ScopedFlush flush(file);
   BlockHeader file_header(file);
   int file_size = static_cast<int>(file->GetLength());
   if (file_size < file_header.Size())
     return false;  // file_size > 2GB is also an error.

   const int kMinHeaderBlockSize = 36;
   const int kMaxHeaderBlockSize = 4096;
   BlockFileHeader* header = file_header.Header();
   if (header->entry_size < kMinHeaderBlockSize ||
       header->entry_size > kMaxHeaderBlockSize || header->num_entries < 0)
     return false;

   // Make sure that we survive crashes.
   header->updating = 1;
   int expected = header->entry_size * header->max_entries + file_header.Size();
   if (file_size != expected) {
     int max_expected = header->entry_size * kMaxBlocks + file_header.Size();
     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 - file_header.Size()) / header->entry_size;
     header->max_entries = num_entries;
   }

   file_header.FixAllocationCounters();
   int empty_blocks = file_header.EmptyBlocks();
   if (empty_blocks + header->num_entries > header->max_entries)
     header->num_entries = header->max_entries - empty_blocks;

   if (!file_header.ValidateCounters())
     return false;

   header->updating = 0;
   return true;
 }

 // We are interested in the total number of blocks used by this file type, and
 // the max number of blocks that we can store (reported as the percentage of
 // used blocks). In order to find out the number of used blocks, we have to
 // substract the empty blocks from the total blocks for each file in the chain.
 void BlockFiles::GetFileStats(int index, int* used_count, int* load) {
   int max_blocks = 0;
   *used_count = 0;
   *load = 0;
   for (;;) {
     if (!block_files_[index] && !OpenBlockFile(index))
       return;

     BlockFileHeader* header =
         reinterpret_cast<BlockFileHeader*>(block_files_[index]->buffer());

     max_blocks += header->max_entries;
     int used = header->max_entries;
     for (int i = 0; i < kMaxNumBlocks; i++) {
       used -= header->empty[i] * (i + 1);
       DCHECK_GE(used, 0);
     }
     *used_count += used;

     if (!header->next_file)
       break;
     index = header->next_file;
   }
   if (max_blocks)
     *load = *used_count * 100 / max_blocks;
 }

 base::FilePath BlockFiles::Name(int index) {
   // The file format allows for 256 files.
   DCHECK(index < 256 && index >= 0);
   std::string tmp = base::StringPrintf("%s%d", kBlockName, index);
   return path_.AppendASCII(tmp);
 }

 }  // namespace disk_cache
	// Copyright (c) 2012 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/blockfile/block_files.h"

	#include <limits>

	#include "base/atomicops.h"
	#include "base/files/file_path.h"
	#include "base/metrics/histogram_macros.h"
	#include "base/strings/string_util.h"
	#include "base/strings/stringprintf.h"
	#include "base/threading/thread_checker.h"
	#include "base/time/time.h"
	#include "net/disk_cache/blockfile/file_lock.h"
	#include "net/disk_cache/blockfile/stress_support.h"
	#include "net/disk_cache/blockfile/trace.h"
	#include "net/disk_cache/cache_util.h"
	#include "starboard/memory.h"

	using base::TimeTicks;

	namespace {

	const char kBlockName[] = "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(uint32_t value) {
	value &= 0xf;
	return s_types[value];
	}

	} // namespace

	namespace disk_cache {

	BlockHeader::BlockHeader() : header_(NULL) {
	}

	BlockHeader::BlockHeader(BlockFileHeader* header) : header_(header) {
	}

	BlockHeader::BlockHeader(MappedFile* file)
	: header_(reinterpret_cast<BlockFileHeader*>(file->buffer())) {
	}

	BlockHeader::BlockHeader(const BlockHeader& other) = default;

	BlockHeader::~BlockHeader() = default;

	bool BlockHeader::CreateMapBlock(int size, int* index) {
	DCHECK(size > 0 && size <= kMaxNumBlocks);
	int target = 0;
	for (int i = size; i <= kMaxNumBlocks; i++) {
	if (header_->empty[i - 1]) {
	target = i;
	break;
	}
	}

	if (!target) {
	STRESS_NOTREACHED();
	return false;
	}

	TimeTicks start = TimeTicks::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_t 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;
	STRESS_DCHECK(index / 4 == (index + size - 1) / 4);
	uint32_t to_add = ((1 << size) - 1) << index_offset;
	header_->num_entries++;

	// Note that there is no race in the normal sense here, but if we enforce
	// the order of memory accesses between num_entries and allocation_map, we
	// can assert that even if we crash here, num_entries will never be less
	// than the actual number of used blocks.
	base::subtle::MemoryBarrier();
	header_->allocation_map[current] \|= to_add;

	header_->hints[target - 1] = current;
	header_->empty[target - 1]--;
	STRESS_DCHECK(header_->empty[target - 1] >= 0);
	if (target != size) {
	header_->empty[target - size - 1]++;
	}
	LOCAL_HISTOGRAM_TIMES("DiskCache.CreateBlock", TimeTicks::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();
	return false;
	}

	void BlockHeader::DeleteMapBlock(int index, int size) {
	if (size < 0 \|\| size > kMaxNumBlocks) {
	NOTREACHED();
	return;
	}
	TimeTicks start = TimeTicks::Now();
	int byte_index = index / 8;
	uint8_t* byte_map = reinterpret_cast<uint8_t*>(header_->allocation_map);
	uint8_t map_block = byte_map[byte_index];

	if (index % 8 >= 4)
	map_block >>= 4;

	// See what type of block will be available after we delete this one.
	int bits_at_end = 4 - size - index % 4;
	uint8_t end_mask = (0xf << (4 - bits_at_end)) & 0xf;
	bool update_counters = (map_block & end_mask) == 0;
	uint8_t new_value = map_block & ~(((1 << size) - 1) << (index % 4));
	int new_type = GetMapBlockType(new_value);

	disk_cache::FileLock lock(header_);
	STRESS_DCHECK((((1 << size) - 1) << (index % 8)) < 0x100);
	uint8_t to_clear = ((1 << size) - 1) << (index % 8);
	STRESS_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]++;
	STRESS_DCHECK(header_->empty[bits_at_end - 1] >= 0);
	}
	base::subtle::MemoryBarrier();
	header_->num_entries--;
	STRESS_DCHECK(header_->num_entries >= 0);
	LOCAL_HISTOGRAM_TIMES("DiskCache.DeleteBlock", TimeTicks::Now() - start);
	}

	// Note that this is a simplified version of DeleteMapBlock().
	bool BlockHeader::UsedMapBlock(int index, int size) {
	if (size < 0 \|\| size > kMaxNumBlocks)
	return false;

	int byte_index = index / 8;
	uint8_t* byte_map = reinterpret_cast<uint8_t*>(header_->allocation_map);
	uint8_t map_block = byte_map[byte_index];

	if (index % 8 >= 4)
	map_block >>= 4;

	STRESS_DCHECK((((1 << size) - 1) << (index % 8)) < 0x100);
	uint8_t to_clear = ((1 << size) - 1) << (index % 8);
	return ((byte_map[byte_index] & to_clear) == to_clear);
	}

	void BlockHeader::FixAllocationCounters() {
	for (int i = 0; i < kMaxNumBlocks; i++) {
	header_->hints[i] = 0;
	header_->empty[i] = 0;
	}

	for (int i = 0; i < header_->max_entries / 32; i++) {
	uint32_t 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 BlockHeader::NeedToGrowBlockFile(int block_count) const {
	bool have_space = false;
	int empty_blocks = 0;
	for (int i = 0; i < kMaxNumBlocks; i++) {
	empty_blocks += header_->empty[i] * (i + 1);
	if (i >= block_count - 1 && header_->empty[i])
	have_space = true;
	}

	if (header_->next_file && (empty_blocks < kMaxBlocks / 10)) {
	// This file is almost full but we already created another one, don't use
	// this file yet so that it is easier to find empty blocks when we start
	// using this file again.
	return true;
	}
	return !have_space;
	}

	bool BlockHeader::CanAllocate(int block_count) const {
	DCHECK_GT(block_count, 0);
	for (int i = block_count - 1; i < kMaxNumBlocks; i++) {
	if (header_->empty[i])
	return true;
	}

	return false;
	}

	int BlockHeader::EmptyBlocks() const {
	int empty_blocks = 0;
	for (int i = 0; i < kMaxNumBlocks; i++) {
	empty_blocks += header_->empty[i] * (i + 1);
	if (header_->empty[i] < 0)
	return 0;
	}
	return empty_blocks;
	}

	int BlockHeader::MinimumAllocations() const {
	return header_->empty[kMaxNumBlocks - 1];
	}

	int BlockHeader::Capacity() const {
	return header_->max_entries;
	}

	bool BlockHeader::ValidateCounters() const {
	if (header_->max_entries < 0 \|\| header_->max_entries > kMaxBlocks \|\|
	header_->num_entries < 0)
	return false;

	int empty_blocks = EmptyBlocks();
	if (empty_blocks + header_->num_entries > header_->max_entries)
	return false;

	return true;
	}

	int BlockHeader::FileId() const {
	return header_->this_file;
	}

	int BlockHeader::NextFileId() const {
	return header_->next_file;
	}

	int BlockHeader::Size() const {
	return static_cast<int>(sizeof(*header_));
	}

	BlockFileHeader* BlockHeader::Header() {
	return header_;
	}

	// ------------------------------------------------------------------------

	BlockFiles::BlockFiles(const base::FilePath& path)
	: init_(false), zero_buffer_(NULL), path_(path) {
	}

	BlockFiles::~BlockFiles() {
	if (zero_buffer_)
	delete[] zero_buffer_;
	CloseFiles();
	}

	bool BlockFiles::Init(bool create_files) {
	DCHECK(!init_);
	if (init_)
	return false;

	thread_checker_.reset(new base::ThreadChecker);

	block_files_.resize(kFirstAdditionalBlockFile);
	for (int16_t i = 0; i < kFirstAdditionalBlockFile; i++) {
	if (create_files)
	if (!CreateBlockFile(i, static_cast<FileType>(i + 1), true))
	return false;

	if (!OpenBlockFile(i))
	return false;

	// Walk this chain of files removing empty ones.
	if (!RemoveEmptyFile(static_cast<FileType>(i + 1)))
	return false;
	}

	init_ = true;
	return true;
	}

	MappedFile* BlockFiles::GetFile(Addr address) {
	DCHECK(thread_checker_->CalledOnValidThread());
	DCHECK_GE(block_files_.size(),
	static_cast<size_t>(kFirstAdditionalBlockFile));
	DCHECK(address.is_block_file() \|\| !address.is_initialized());
	if (!address.is_initialized())
	return NULL;

	int file_index = address.FileNumber();
	if (static_cast<unsigned int>(file_index) >= block_files_.size() \|\|
	!block_files_[file_index]) {
	// We need to open the file
	if (!OpenBlockFile(file_index))
	return NULL;
	}
	DCHECK_GE(block_files_.size(), static_cast<unsigned int>(file_index));
	return block_files_[file_index].get();
	}

	bool BlockFiles::CreateBlock(FileType block_type, int block_count,
	Addr* block_address) {
	DCHECK(thread_checker_->CalledOnValidThread());
	DCHECK_NE(block_type, EXTERNAL);
	DCHECK_NE(block_type, BLOCK_FILES);
	DCHECK_NE(block_type, BLOCK_ENTRIES);
	DCHECK_NE(block_type, BLOCK_EVICTED);
	if (block_count < 1 \|\| block_count > kMaxNumBlocks)
	return false;

	if (!init_)
	return false;

	MappedFile* file = FileForNewBlock(block_type, block_count);
	if (!file)
	return false;

	ScopedFlush flush(file);
	BlockHeader file_header(file);

	int index;
	if (!file_header.CreateMapBlock(block_count, &index))
	return false;

	Addr address(block_type, block_count, file_header.FileId(), index);
	block_address->set_value(address.value());
	Trace("CreateBlock 0x%x", address.value());
	return true;
	}

	void BlockFiles::DeleteBlock(Addr address, bool deep) {
	DCHECK(thread_checker_->CalledOnValidThread());
	if (!address.is_initialized() \|\| address.is_separate_file())
	return;

	if (!zero_buffer_) {
	zero_buffer_ = new char[Addr::BlockSizeForFileType(BLOCK_4K) * 4];
	SbMemorySet(zero_buffer_, 0, Addr::BlockSizeForFileType(BLOCK_4K) * 4);
	}
	MappedFile* file = GetFile(address);
	if (!file)
	return;

	Trace("DeleteBlock 0x%x", address.value());

	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);

	BlockHeader file_header(file);
	file_header.DeleteMapBlock(address.start_block(), address.num_blocks());
	file->Flush();

	if (!file_header.Header()->num_entries) {
	// This file is now empty. Let's try to delete it.
	FileType type = Addr::RequiredFileType(file_header.Header()->entry_size);
	if (Addr::BlockSizeForFileType(RANKINGS) ==
	file_header.Header()->entry_size) {
	type = RANKINGS;
	}
	RemoveEmptyFile(type); // Ignore failures.
	}
	}

	void BlockFiles::CloseFiles() {
	if (init_) {
	DCHECK(thread_checker_->CalledOnValidThread());
	}
	init_ = false;
	block_files_.clear();
	}

	void BlockFiles::ReportStats() {
	DCHECK(thread_checker_->CalledOnValidThread());
	int used_blocks[kFirstAdditionalBlockFile];
	int load[kFirstAdditionalBlockFile];
	for (int i = 0; i < kFirstAdditionalBlockFile; i++) {
	GetFileStats(i, &used_blocks[i], &load[i]);
	}
	UMA_HISTOGRAM_COUNTS_1M("DiskCache.Blocks_0", used_blocks[0]);
	UMA_HISTOGRAM_COUNTS_1M("DiskCache.Blocks_1", used_blocks[1]);
	UMA_HISTOGRAM_COUNTS_1M("DiskCache.Blocks_2", used_blocks[2]);
	UMA_HISTOGRAM_COUNTS_1M("DiskCache.Blocks_3", used_blocks[3]);

	UMA_HISTOGRAM_ENUMERATION("DiskCache.BlockLoad_0", load[0], 101);
	UMA_HISTOGRAM_ENUMERATION("DiskCache.BlockLoad_1", load[1], 101);
	UMA_HISTOGRAM_ENUMERATION("DiskCache.BlockLoad_2", load[2], 101);
	UMA_HISTOGRAM_ENUMERATION("DiskCache.BlockLoad_3", load[3], 101);
	}

	bool BlockFiles::IsValid(Addr address) {
	#ifdef NDEBUG
	return true;
	#else
	if (!address.is_initialized() \|\| address.is_separate_file())
	return false;

	MappedFile* file = GetFile(address);
	if (!file)
	return false;

	BlockHeader header(file);
	bool rv = header.UsedMapBlock(address.start_block(), address.num_blocks());
	DCHECK(rv);

	static bool read_contents = false;
	if (read_contents) {
	std::unique_ptr<char[]> buffer;
	buffer.reset(new char[Addr::BlockSizeForFileType(BLOCK_4K) * 4]);
	size_t size = address.BlockSize() * address.num_blocks();
	size_t offset = address.start_block() * address.BlockSize() +
	kBlockHeaderSize;
	bool ok = file->Read(buffer.get(), size, offset);
	DCHECK(ok);
	}

	return rv;
	#endif
	}

	bool BlockFiles::CreateBlockFile(int index, FileType file_type, bool force) {
	base::FilePath name = Name(index);
	int flags = force ? base::File::FLAG_CREATE_ALWAYS : base::File::FLAG_CREATE;
	flags \|= base::File::FLAG_WRITE \| base::File::FLAG_EXCLUSIVE_WRITE;

	scoped_refptr<File> file(new File(base::File(name, flags)));
	if (!file->IsValid())
	return false;

	BlockFileHeader header;
	SbMemorySet(&header, 0, sizeof(header));
	header.magic = kBlockMagic;
	header.version = kBlockVersion2;
	header.entry_size = Addr::BlockSizeForFileType(file_type);
	header.this_file = static_cast<int16_t>(index);
	DCHECK(index <= std::numeric_limits<int16_t>::max() && index >= 0);

	return file->Write(&header, sizeof(header), 0);
	}

	bool BlockFiles::OpenBlockFile(int index) {
	if (block_files_.size() - 1 < static_cast<unsigned int>(index)) {
	DCHECK(index > 0);
	int to_add = index - static_cast<int>(block_files_.size()) + 1;
	block_files_.resize(block_files_.size() + to_add);
	}

	base::FilePath name = Name(index);
	scoped_refptr<MappedFile> file(new MappedFile());

	if (!file->Init(name, kBlockHeaderSize)) {
	LOG(ERROR) << "Failed to open " << name.value();
	return false;
	}

	size_t file_len = file->GetLength();
	if (file_len < static_cast<size_t>(kBlockHeaderSize)) {
	LOG(ERROR) << "File too small " << name.value();
	return false;
	}

	BlockHeader file_header(file.get());
	BlockFileHeader* header = file_header.Header();
	if (kBlockMagic != header->magic \|\| kBlockVersion2 != header->version) {
	LOG(ERROR) << "Invalid file version or magic " << name.value();
	return false;
	}

	if (header->updating \|\| !file_header.ValidateCounters()) {
	// Last instance was not properly shutdown, or counters are out of sync.
	if (!FixBlockFileHeader(file.get())) {
	LOG(ERROR) << "Unable to fix block file " << name.value();
	return false;
	}
	}

	if (static_cast<int>(file_len) <
	header->max_entries * header->entry_size + kBlockHeaderSize) {
	LOG(ERROR) << "File too small " << name.value();
	return false;
	}

	if (index == 0) {
	// Load the links file into memory.
	if (!file->Preload())
	return false;
	}

	ScopedFlush flush(file.get());
	DCHECK(!block_files_[index]);
	block_files_[index] = std::move(file);
	return true;
	}

	bool BlockFiles::GrowBlockFile(MappedFile* file, BlockFileHeader* header) {
	if (kMaxBlocks == header->max_entries)
	return false;

	ScopedFlush flush(file);
	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);

	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);
	}

	FileLock lock(header);
	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) {
	static_assert(RANKINGS == 1, "invalid file type");
	MappedFile* file = block_files_[block_type - 1].get();
	BlockHeader file_header(file);

	TimeTicks start = TimeTicks::Now();
	while (file_header.NeedToGrowBlockFile(block_count)) {
	if (kMaxBlocks == file_header.Header()->max_entries) {
	file = NextFile(file);
	if (!file)
	return NULL;
	file_header = BlockHeader(file);
	continue;
	}

	if (!GrowBlockFile(file, file_header.Header()))
	return NULL;
	break;
	}
	LOCAL_HISTOGRAM_TIMES("DiskCache.GetFileForNewBlock",
	TimeTicks::Now() - start);
	return file;
	}

	MappedFile* BlockFiles::NextFile(MappedFile* file) {
	ScopedFlush flush(file);
	BlockFileHeader* header = reinterpret_cast<BlockFileHeader*>(file->buffer());
	int16_t 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);
	}

	int16_t BlockFiles::CreateNextBlockFile(FileType block_type) {
	for (int16_t i = kFirstAdditionalBlockFile; i <= kMaxBlockFile; i++) {
	if (CreateBlockFile(i, block_type, false))
	return i;
	}
	return 0;
	}

	// We walk the list of files for this particular block type, deleting the ones
	// that are empty.
	bool BlockFiles::RemoveEmptyFile(FileType block_type) {
	MappedFile* file = block_files_[block_type - 1].get();
	BlockFileHeader* header = reinterpret_cast<BlockFileHeader*>(file->buffer());

	while (header->next_file) {
	// Only the block_file argument is relevant for what we want.
	Addr address(BLOCK_256, 1, header->next_file, 0);
	MappedFile* next_file = GetFile(address);
	if (!next_file)
	return false;

	BlockFileHeader* next_header =
	reinterpret_cast<BlockFileHeader*>(next_file->buffer());
	if (!next_header->num_entries) {
	DCHECK_EQ(next_header->entry_size, header->entry_size);
	// Delete next_file and remove it from the chain.
	int file_index = header->next_file;
	header->next_file = next_header->next_file;
	DCHECK(block_files_.size() >= static_cast<unsigned int>(file_index));
	file->Flush();

	// We get a new handle to the file and release the old one so that the
	// file gets unmmaped... so we can delete it.
	base::FilePath name = Name(file_index);
	scoped_refptr<File> this_file(new File(false));
	this_file->Init(name);
	block_files_[file_index] = NULL;

	int failure = DeleteCacheFile(name) ? 0 : 1;
	UMA_HISTOGRAM_COUNTS_1M("DiskCache.DeleteFailed2", failure);
	if (failure)
	LOG(ERROR) << "Failed to delete " << name.value() << " from the cache.";
	continue;
	}

	header = next_header;
	file = next_file;
	}
	return true;
	}

	// Note that we expect to be called outside of a FileLock... however, we cannot
	// DCHECK on header->updating because we may be fixing a crash.
	bool BlockFiles::FixBlockFileHeader(MappedFile* file) {
	ScopedFlush flush(file);
	BlockHeader file_header(file);
	int file_size = static_cast<int>(file->GetLength());
	if (file_size < file_header.Size())
	return false; // file_size > 2GB is also an error.

	const int kMinHeaderBlockSize = 36;
	const int kMaxHeaderBlockSize = 4096;
	BlockFileHeader* header = file_header.Header();
	if (header->entry_size < kMinHeaderBlockSize \|\|
	header->entry_size > kMaxHeaderBlockSize \|\| header->num_entries < 0)
	return false;

	// Make sure that we survive crashes.
	header->updating = 1;
	int expected = header->entry_size * header->max_entries + file_header.Size();
	if (file_size != expected) {
	int max_expected = header->entry_size * kMaxBlocks + file_header.Size();
	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 - file_header.Size()) / header->entry_size;
	header->max_entries = num_entries;
	}

	file_header.FixAllocationCounters();
	int empty_blocks = file_header.EmptyBlocks();
	if (empty_blocks + header->num_entries > header->max_entries)
	header->num_entries = header->max_entries - empty_blocks;

	if (!file_header.ValidateCounters())
	return false;

	header->updating = 0;
	return true;
	}

	// We are interested in the total number of blocks used by this file type, and
	// the max number of blocks that we can store (reported as the percentage of
	// used blocks). In order to find out the number of used blocks, we have to
	// substract the empty blocks from the total blocks for each file in the chain.
	void BlockFiles::GetFileStats(int index, int* used_count, int* load) {
	int max_blocks = 0;
	*used_count = 0;
	*load = 0;
	for (;;) {
	if (!block_files_[index] && !OpenBlockFile(index))
	return;

	BlockFileHeader* header =
	reinterpret_cast<BlockFileHeader*>(block_files_[index]->buffer());

	max_blocks += header->max_entries;
	int used = header->max_entries;
	for (int i = 0; i < kMaxNumBlocks; i++) {
	used -= header->empty[i] * (i + 1);
	DCHECK_GE(used, 0);
	}
	*used_count += used;

	if (!header->next_file)
	break;
	index = header->next_file;
	}
	if (max_blocks)
	load = used_count * 100 / max_blocks;
	}

	base::FilePath BlockFiles::Name(int index) {
	// The file format allows for 256 files.
	DCHECK(index < 256 && index >= 0);
	std::string tmp = base::StringPrintf("%s%d", kBlockName, index);
	return path_.AppendASCII(tmp);
	}

	} // namespace disk_cache