src/cobalt/media/blink/multibuffer.cc - cobalt - Git at Google

 // Copyright 2015 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 "cobalt/media/blink/multibuffer.h"

 #include <utility>

 #include "base/bind.h"
 #include "base/location.h"

 namespace cobalt {
 namespace media {

 // Prune 80 blocks per 30 seconds.
 // This means a full cache will go away in ~5 minutes.
 enum {
   kBlockPruneInterval = 30,
   kBlocksPrunedPerInterval = 80,
 };

 // Returns the block ID closest to (but less or equal than) |pos| from |index|.
 template <class T>
 static MultiBuffer::BlockId ClosestPreviousEntry(
     const std::map<MultiBuffer::BlockId, T>& index, MultiBuffer::BlockId pos) {
   auto i = index.upper_bound(pos);
   DCHECK(i == index.end() || i->first > pos);
   if (i == index.begin()) {
     return std::numeric_limits<MultiBufferBlockId>::min();
   }
   --i;
   DCHECK_LE(i->first, pos);
   return i->first;
 }

 // Returns the block ID closest to (but greter than or equal to) |pos|
 // from |index|.
 template <class T>
 static MultiBuffer::BlockId ClosestNextEntry(
     const std::map<MultiBuffer::BlockId, T>& index, MultiBuffer::BlockId pos) {
   auto i = index.lower_bound(pos);
   if (i == index.end()) {
     return std::numeric_limits<MultiBufferBlockId>::max();
   }
   DCHECK_GE(i->first, pos);
   return i->first;
 }

 //
 // MultiBuffer::GlobalLRU
 //
 MultiBuffer::GlobalLRU::GlobalLRU(
     const scoped_refptr<base::SingleThreadTaskRunner>& task_runner)
     : max_size_(0),
       data_size_(0),
       background_pruning_pending_(false),
       task_runner_(task_runner) {}

 MultiBuffer::GlobalLRU::~GlobalLRU() {
   // By the time we're freed, all blocks should have been removed,
   // and our sums should be zero.
   DCHECK(lru_.Empty());
   DCHECK_EQ(max_size_, 0);
   DCHECK_EQ(data_size_, 0);
 }

 void MultiBuffer::GlobalLRU::Use(MultiBuffer* multibuffer,
                                  MultiBufferBlockId block_id) {
   GlobalBlockId id(multibuffer, block_id);
   lru_.Use(id);
   SchedulePrune();
 }

 void MultiBuffer::GlobalLRU::Insert(MultiBuffer* multibuffer,
                                     MultiBufferBlockId block_id) {
   GlobalBlockId id(multibuffer, block_id);
   lru_.Insert(id);
   SchedulePrune();
 }

 void MultiBuffer::GlobalLRU::Remove(MultiBuffer* multibuffer,
                                     MultiBufferBlockId block_id) {
   GlobalBlockId id(multibuffer, block_id);
   lru_.Remove(id);
 }

 bool MultiBuffer::GlobalLRU::Contains(MultiBuffer* multibuffer,
                                       MultiBufferBlockId block_id) {
   GlobalBlockId id(multibuffer, block_id);
   return lru_.Contains(id);
 }

 void MultiBuffer::GlobalLRU::IncrementDataSize(int64_t blocks) {
   data_size_ += blocks;
   DCHECK_GE(data_size_, 0);
   SchedulePrune();
 }

 void MultiBuffer::GlobalLRU::IncrementMaxSize(int64_t blocks) {
   max_size_ += blocks;
   DCHECK_GE(max_size_, 0);
   SchedulePrune();
 }

 bool MultiBuffer::GlobalLRU::Pruneable() const {
   return data_size_ > max_size_ && !lru_.Empty();
 }

 void MultiBuffer::GlobalLRU::SchedulePrune() {
   if (Pruneable() && !background_pruning_pending_) {
     task_runner_->PostDelayedTask(
         FROM_HERE, base::Bind(&MultiBuffer::GlobalLRU::PruneTask, this),
         base::TimeDelta::FromSeconds(kBlockPruneInterval));
     background_pruning_pending_ = true;
   }
 }

 void MultiBuffer::GlobalLRU::PruneTask() {
   background_pruning_pending_ = false;
   Prune(kBlocksPrunedPerInterval);
   SchedulePrune();
 }

 void MultiBuffer::GlobalLRU::Prune(int64_t max_to_free) {
   // We group the blocks by multibuffer so that we can free as many blocks as
   // possible in one call. This reduces the number of callbacks to clients
   // when their available ranges change.
   std::map<MultiBuffer*, std::vector<MultiBufferBlockId>> to_free;
   int64_t freed = 0;
   while (data_size_ - freed > max_size_ && !lru_.Empty() &&
          freed < max_to_free) {
     GlobalBlockId block_id = lru_.Pop();
     to_free[block_id.first].push_back(block_id.second);
     freed++;
   }
   for (const auto& to_free_pair : to_free) {
     to_free_pair.first->ReleaseBlocks(to_free_pair.second);
   }
 }

 int64_t MultiBuffer::GlobalLRU::Size() const { return lru_.Size(); }

 //
 // MultiBuffer
 //
 MultiBuffer::MultiBuffer(int32_t block_size_shift,
                          const scoped_refptr<GlobalLRU>& global_lru)
     : max_size_(0), block_size_shift_(block_size_shift), lru_(global_lru) {}

 MultiBuffer::~MultiBuffer() {
   CHECK(pinned_.empty());
   DCHECK_EQ(max_size_, 0);
   // Remove all blocks from the LRU.
   for (const auto& i : data_) {
     lru_->Remove(this, i.first);
   }
   lru_->IncrementDataSize(-static_cast<int64_t>(data_.size()));
   lru_->IncrementMaxSize(-max_size_);
 }

 void MultiBuffer::AddReader(const BlockId& pos, Reader* reader) {
   std::set<Reader*>* set_of_readers = &readers_[pos];
   bool already_waited_for = !set_of_readers->empty();
   set_of_readers->insert(reader);

   if (already_waited_for || Contains(pos)) {
     return;
   }

   // We may need to create a new data provider to service this request.
   // Look for an existing data provider first.
   DataProvider* provider = NULL;
   BlockId closest_writer = ClosestPreviousEntry(writer_index_, pos);

   if (closest_writer > pos - kMaxWaitForWriterOffset) {
     auto i = present_.find(pos);
     BlockId closest_block;
     if (i.value()) {
       // Shouldn't happen, we already tested that Contains(pos) is true.
       NOTREACHED();
       closest_block = pos;
     } else if (i == present_.begin()) {
       closest_block = -1;
     } else {
       closest_block = i.interval_begin() - 1;
     }

     // Make sure that there are no present blocks between the writer and
     // the requested position, as that will cause the writer to quit.
     if (closest_writer > closest_block) {
       provider = writer_index_[closest_writer].get();
       DCHECK(provider);
     }
   }
   if (!provider) {
     DCHECK(writer_index_.find(pos) == writer_index_.end());
     writer_index_[pos] = CreateWriter(pos);
     provider = writer_index_[pos].get();
   }
   provider->SetDeferred(false);
 }

 void MultiBuffer::RemoveReader(const BlockId& pos, Reader* reader) {
   auto i = readers_.find(pos);
   if (i == readers_.end()) return;
   i->second.erase(reader);
   if (i->second.empty()) {
     readers_.erase(i);
   }
 }

 void MultiBuffer::CleanupWriters(const BlockId& pos) {
   BlockId p2 = pos + kMaxWaitForReaderOffset;
   BlockId closest_writer = ClosestPreviousEntry(writer_index_, p2);
   while (closest_writer > pos - kMaxWaitForWriterOffset) {
     DCHECK(writer_index_[closest_writer]);
     OnDataProviderEvent(writer_index_[closest_writer].get());
     closest_writer = ClosestPreviousEntry(writer_index_, closest_writer - 1);
   }
 }

 bool MultiBuffer::Contains(const BlockId& pos) const {
   DCHECK(present_[pos] == 0 || present_[pos] == 1)
       << " pos = " << pos << " present_[pos] " << present_[pos];
   DCHECK_EQ(present_[pos], data_.find(pos) != data_.end() ? 1 : 0);
   return !!present_[pos];
 }

 MultiBufferBlockId MultiBuffer::FindNextUnavailable(const BlockId& pos) const {
   auto i = present_.find(pos);
   if (i.value()) return i.interval_end();
   return pos;
 }

 void MultiBuffer::NotifyAvailableRange(
     const Interval<MultiBufferBlockId>& observer_range,
     const Interval<MultiBufferBlockId>& new_range) {
   std::set<Reader*> tmp;
   for (auto i = readers_.lower_bound(observer_range.begin);
        i != readers_.end() && i->first < observer_range.end; ++i) {
     tmp.insert(i->second.begin(), i->second.end());
   }
   for (Reader* reader : tmp) {
     reader->NotifyAvailableRange(new_range);
   }
 }

 void MultiBuffer::ReleaseBlocks(const std::vector<MultiBufferBlockId>& blocks) {
   IntervalMap<BlockId, int32_t> freed;
   for (MultiBufferBlockId to_free : blocks) {
     DCHECK(data_[to_free]);
     DCHECK_EQ(pinned_[to_free], 0);
     DCHECK_EQ(present_[to_free], 1);
     data_.erase(to_free);
     freed.IncrementInterval(to_free, to_free + 1, 1);
     present_.IncrementInterval(to_free, to_free + 1, -1);
   }
   lru_->IncrementDataSize(-static_cast<int64_t>(blocks.size()));

   for (const auto& freed_range : freed) {
     if (freed_range.second) {
       // Technically, there shouldn't be any observers in this range
       // as all observers really should be pinning the range where it's
       // actually observing.
       NotifyAvailableRange(
           freed_range.first,
           // Empty range.
           Interval<BlockId>(freed_range.first.begin, freed_range.first.begin));

       auto i = present_.find(freed_range.first.begin);
       DCHECK_EQ(i.value(), 0);
       DCHECK_LE(i.interval_begin(), freed_range.first.begin);
       DCHECK_LE(freed_range.first.end, i.interval_end());

       if (i.interval_begin() == freed_range.first.begin) {
         // Notify the previous range that it contains fewer blocks.
         auto j = i;
         --j;
         DCHECK_EQ(j.value(), 1);
         NotifyAvailableRange(j.interval(), j.interval());
       }
       if (i.interval_end() == freed_range.first.end) {
         // Notify the following range that it contains fewer blocks.
         auto j = i;
         ++j;
         DCHECK_EQ(j.value(), 1);
         NotifyAvailableRange(j.interval(), j.interval());
       }
     }
   }
   if (data_.empty()) OnEmpty();
 }

 void MultiBuffer::OnEmpty() {}

 void MultiBuffer::AddProvider(std::unique_ptr<DataProvider> provider) {
   // If there is already a provider in the same location, we delete it.
   DCHECK(!provider->Available());
   BlockId pos = provider->Tell();
   writer_index_[pos] = std::move(provider);
 }

 std::unique_ptr<MultiBuffer::DataProvider> MultiBuffer::RemoveProvider(
     DataProvider* provider) {
   BlockId pos = provider->Tell();
   auto iter = writer_index_.find(pos);
   DCHECK(iter != writer_index_.end());
   DCHECK_EQ(iter->second.get(), provider);
   std::unique_ptr<DataProvider> ret = std::move(iter->second);
   writer_index_.erase(iter);
   return ret;
 }

 MultiBuffer::ProviderState MultiBuffer::SuggestProviderState(
     const BlockId& pos) const {
   MultiBufferBlockId next_reader_pos = ClosestNextEntry(readers_, pos);
   if (next_reader_pos != std::numeric_limits<MultiBufferBlockId>::max() &&
       (next_reader_pos - pos <= kMaxWaitForWriterOffset || !RangeSupported())) {
     // Check if there is another writer between us and the next reader.
     MultiBufferBlockId next_writer_pos =
         ClosestNextEntry(writer_index_, pos + 1);
     if (next_writer_pos > next_reader_pos) {
       return ProviderStateLoad;
     }
   }

   MultiBufferBlockId previous_reader_pos =
       ClosestPreviousEntry(readers_, pos - 1);
   if (previous_reader_pos != std::numeric_limits<MultiBufferBlockId>::min() &&
       (pos - previous_reader_pos <= kMaxWaitForReaderOffset ||
        !RangeSupported())) {
     MultiBufferBlockId previous_writer_pos =
         ClosestPreviousEntry(writer_index_, pos - 1);
     if (previous_writer_pos < previous_reader_pos) {
       return ProviderStateDefer;
     }
   }

   return ProviderStateDead;
 }

 bool MultiBuffer::ProviderCollision(const BlockId& id) const {
   // If there is a writer at the same location, it is always a collision.
   if (writer_index_.find(id) != writer_index_.end()) return true;

   // Data already exists at providers current position,
   // if the URL supports ranges, we can kill the data provider.
   if (RangeSupported() && Contains(id)) return true;

   return false;
 }

 void MultiBuffer::Prune(size_t max_to_free) { lru_->Prune(max_to_free); }

 void MultiBuffer::OnDataProviderEvent(DataProvider* provider_tmp) {
   std::unique_ptr<DataProvider> provider(RemoveProvider(provider_tmp));
   BlockId start_pos = provider->Tell();
   BlockId pos = start_pos;
   bool eof = false;
   int64_t blocks_before = data_.size();

   while (!ProviderCollision(pos) && !eof) {
     if (!provider->Available()) {
       AddProvider(std::move(provider));
       break;
     }
     DCHECK_GE(pos, 0);
     scoped_refptr<DataBuffer> data = provider->Read();
     data_[pos] = data;
     eof = data->end_of_stream();
     if (!pinned_[pos]) lru_->Use(this, pos);
     ++pos;
   }
   int64_t blocks_after = data_.size();
   int64_t blocks_added = blocks_after - blocks_before;

   if (pos > start_pos) {
     present_.SetInterval(start_pos, pos, 1);
     Interval<BlockId> expanded_range = present_.find(start_pos).interval();
     NotifyAvailableRange(expanded_range, expanded_range);
     lru_->IncrementDataSize(blocks_added);
     Prune(blocks_added * kMaxFreesPerAdd + 1);
   } else {
     // Make sure to give progress reports even when there
     // aren't any new blocks yet.
     NotifyAvailableRange(Interval<BlockId>(start_pos, start_pos + 1),
                          Interval<BlockId>(start_pos, start_pos));
   }

   // Check that it's still there before we try to delete it.
   // In case of EOF or a collision, we might not have called AddProvider above.
   // Even if we did call AddProvider, calling NotifyAvailableRange can cause
   // readers to seek or self-destruct and clean up any associated writers.
   auto i = writer_index_.find(pos);
   if (i != writer_index_.end() && i->second.get() == provider_tmp) {
     switch (SuggestProviderState(pos)) {
       case ProviderStateLoad:
         // Not sure we actually need to do this
         provider_tmp->SetDeferred(false);
         break;
       case ProviderStateDefer:
         provider_tmp->SetDeferred(true);
         break;
       case ProviderStateDead:
         RemoveProvider(provider_tmp);
         break;
     }
   }
 }

 void MultiBuffer::MergeFrom(MultiBuffer* other) {
   // Import data and update LRU.
   size_t data_size = data_.size();
   for (const auto& data : other->data_) {
     if (data_.insert(std::make_pair(data.first, data.second)).second) {
       if (!pinned_[data.first]) {
         lru_->Insert(this, data.first);
       }
     }
   }
   lru_->IncrementDataSize(static_cast<int64_t>(data_.size() - data_size));
   // Update present_
   for (const auto& r : other->present_) {
     if (r.second) {
       present_.SetInterval(r.first.begin, r.first.end, 1);
     }
   }
   // Notify existing readers.
   auto last = present_.begin();
   for (const auto& r : other->present_) {
     if (r.second) {
       auto i = present_.find(r.first.begin);
       if (i != last) {
         NotifyAvailableRange(i.interval(), i.interval());
         last = i;
       }
     }
   }
 }

 void MultiBuffer::PinRange(const BlockId& from, const BlockId& to,
                            int32_t how_much) {
   DCHECK_NE(how_much, 0);
   DVLOG(3) << "PINRANGE [" << from << " - " << to << ") += " << how_much;
   pinned_.IncrementInterval(from, to, how_much);
   Interval<BlockId> modified_range(from, to);

   // Iterate over all the modified ranges and check if any of them have
   // transitioned in or out of the unlocked state. If so, we iterate over
   // all buffers in that range and add/remove them from the LRU as approperiate.
   // We iterate *backwards* through the ranges, with the idea that data in a
   // continous range should be freed from the end first.

   if (data_.empty()) return;

   auto range = pinned_.find(to - 1);
   while (1) {
     DCHECK_GE(range.value(), 0);
     if (range.value() == 0 || range.value() == how_much) {
       bool pin = range.value() == how_much;
       Interval<BlockId> transition_range =
           modified_range.Intersect(range.interval());
       if (transition_range.Empty()) break;

       // For each range that has transitioned to/from a pinned state,
       // we iterate over the corresponding ranges in |present_| to find
       // the blocks that are actually in the multibuffer.
       for (auto present_block_range = present_.find(transition_range.end - 1);
            present_block_range != present_.begin(); --present_block_range) {
         if (!present_block_range.value()) continue;
         Interval<BlockId> present_transitioned_range =
             transition_range.Intersect(present_block_range.interval());
         if (present_transitioned_range.Empty()) break;
         for (BlockId block = present_transitioned_range.end - 1;
              block >= present_transitioned_range.begin; --block) {
           DCHECK_GE(block, 0);
           DCHECK(data_.find(block) != data_.end());
           if (pin) {
             DCHECK(pinned_[block]);
             lru_->Remove(this, block);
           } else {
             DCHECK(!pinned_[block]);
             lru_->Insert(this, block);
           }
         }
       }
     }
     if (range == pinned_.begin()) break;
     --range;
   }
 }

 void MultiBuffer::PinRanges(const IntervalMap<BlockId, int32_t>& ranges) {
   for (const auto& r : ranges) {
     if (r.second != 0) {
       PinRange(r.first.begin, r.first.end, r.second);
     }
   }
 }

 void MultiBuffer::IncrementMaxSize(int32_t size) {
   max_size_ += size;
   lru_->IncrementMaxSize(size);
   DCHECK_GE(max_size_, 0);
   // Pruning only happens when blocks are added.
 }

 int64_t MultiBuffer::UncommittedBytesAt(const MultiBuffer::BlockId& block) {
   auto i = writer_index_.find(block);
   if (writer_index_.end() == i) return 0;
   return i->second->AvailableBytes();
 }

 }  // namespace media
 }  // namespace cobalt
	// Copyright 2015 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 "cobalt/media/blink/multibuffer.h"

	#include <utility>

	#include "base/bind.h"
	#include "base/location.h"

	namespace cobalt {
	namespace media {

	// Prune 80 blocks per 30 seconds.
	// This means a full cache will go away in ~5 minutes.
	enum {
	kBlockPruneInterval = 30,
	kBlocksPrunedPerInterval = 80,
	};

	// Returns the block ID closest to (but less or equal than) \|pos\| from \|index\|.
	template <class T>
	static MultiBuffer::BlockId ClosestPreviousEntry(
	const std::map<MultiBuffer::BlockId, T>& index, MultiBuffer::BlockId pos) {
	auto i = index.upper_bound(pos);
	DCHECK(i == index.end() \|\| i->first > pos);
	if (i == index.begin()) {
	return std::numeric_limits<MultiBufferBlockId>::min();
	}
	--i;
	DCHECK_LE(i->first, pos);
	return i->first;
	}

	// Returns the block ID closest to (but greter than or equal to) \|pos\|
	// from \|index\|.
	template <class T>
	static MultiBuffer::BlockId ClosestNextEntry(
	const std::map<MultiBuffer::BlockId, T>& index, MultiBuffer::BlockId pos) {
	auto i = index.lower_bound(pos);
	if (i == index.end()) {
	return std::numeric_limits<MultiBufferBlockId>::max();
	}
	DCHECK_GE(i->first, pos);
	return i->first;
	}

	//
	// MultiBuffer::GlobalLRU
	//
	MultiBuffer::GlobalLRU::GlobalLRU(
	const scoped_refptr<base::SingleThreadTaskRunner>& task_runner)
	: max_size_(0),
	data_size_(0),
	background_pruning_pending_(false),
	task_runner_(task_runner) {}

	MultiBuffer::GlobalLRU::~GlobalLRU() {
	// By the time we're freed, all blocks should have been removed,
	// and our sums should be zero.
	DCHECK(lru_.Empty());
	DCHECK_EQ(max_size_, 0);
	DCHECK_EQ(data_size_, 0);
	}

	void MultiBuffer::GlobalLRU::Use(MultiBuffer* multibuffer,
	MultiBufferBlockId block_id) {
	GlobalBlockId id(multibuffer, block_id);
	lru_.Use(id);
	SchedulePrune();
	}

	void MultiBuffer::GlobalLRU::Insert(MultiBuffer* multibuffer,
	MultiBufferBlockId block_id) {
	GlobalBlockId id(multibuffer, block_id);
	lru_.Insert(id);
	SchedulePrune();
	}

	void MultiBuffer::GlobalLRU::Remove(MultiBuffer* multibuffer,
	MultiBufferBlockId block_id) {
	GlobalBlockId id(multibuffer, block_id);
	lru_.Remove(id);
	}

	bool MultiBuffer::GlobalLRU::Contains(MultiBuffer* multibuffer,
	MultiBufferBlockId block_id) {
	GlobalBlockId id(multibuffer, block_id);
	return lru_.Contains(id);
	}

	void MultiBuffer::GlobalLRU::IncrementDataSize(int64_t blocks) {
	data_size_ += blocks;
	DCHECK_GE(data_size_, 0);
	SchedulePrune();
	}

	void MultiBuffer::GlobalLRU::IncrementMaxSize(int64_t blocks) {
	max_size_ += blocks;
	DCHECK_GE(max_size_, 0);
	SchedulePrune();
	}

	bool MultiBuffer::GlobalLRU::Pruneable() const {
	return data_size_ > max_size_ && !lru_.Empty();
	}

	void MultiBuffer::GlobalLRU::SchedulePrune() {
	if (Pruneable() && !background_pruning_pending_) {
	task_runner_->PostDelayedTask(
	FROM_HERE, base::Bind(&MultiBuffer::GlobalLRU::PruneTask, this),
	base::TimeDelta::FromSeconds(kBlockPruneInterval));
	background_pruning_pending_ = true;
	}
	}

	void MultiBuffer::GlobalLRU::PruneTask() {
	background_pruning_pending_ = false;
	Prune(kBlocksPrunedPerInterval);
	SchedulePrune();
	}

	void MultiBuffer::GlobalLRU::Prune(int64_t max_to_free) {
	// We group the blocks by multibuffer so that we can free as many blocks as
	// possible in one call. This reduces the number of callbacks to clients
	// when their available ranges change.
	std::map<MultiBuffer*, std::vector<MultiBufferBlockId>> to_free;
	int64_t freed = 0;
	while (data_size_ - freed > max_size_ && !lru_.Empty() &&
	freed < max_to_free) {
	GlobalBlockId block_id = lru_.Pop();
	to_free[block_id.first].push_back(block_id.second);
	freed++;
	}
	for (const auto& to_free_pair : to_free) {
	to_free_pair.first->ReleaseBlocks(to_free_pair.second);
	}
	}

	int64_t MultiBuffer::GlobalLRU::Size() const { return lru_.Size(); }

	//
	// MultiBuffer
	//
	MultiBuffer::MultiBuffer(int32_t block_size_shift,
	const scoped_refptr<GlobalLRU>& global_lru)
	: max_size_(0), block_size_shift_(block_size_shift), lru_(global_lru) {}

	MultiBuffer::~MultiBuffer() {
	CHECK(pinned_.empty());
	DCHECK_EQ(max_size_, 0);
	// Remove all blocks from the LRU.
	for (const auto& i : data_) {
	lru_->Remove(this, i.first);
	}
	lru_->IncrementDataSize(-static_cast<int64_t>(data_.size()));
	lru_->IncrementMaxSize(-max_size_);
	}

	void MultiBuffer::AddReader(const BlockId& pos, Reader* reader) {
	std::set<Reader> set_of_readers = &readers_[pos];
	bool already_waited_for = !set_of_readers->empty();
	set_of_readers->insert(reader);

	if (already_waited_for \|\| Contains(pos)) {
	return;
	}

	// We may need to create a new data provider to service this request.
	// Look for an existing data provider first.
	DataProvider* provider = NULL;
	BlockId closest_writer = ClosestPreviousEntry(writer_index_, pos);

	if (closest_writer > pos - kMaxWaitForWriterOffset) {
	auto i = present_.find(pos);
	BlockId closest_block;
	if (i.value()) {
	// Shouldn't happen, we already tested that Contains(pos) is true.
	NOTREACHED();
	closest_block = pos;
	} else if (i == present_.begin()) {
	closest_block = -1;
	} else {
	closest_block = i.interval_begin() - 1;
	}

	// Make sure that there are no present blocks between the writer and
	// the requested position, as that will cause the writer to quit.
	if (closest_writer > closest_block) {
	provider = writer_index_[closest_writer].get();
	DCHECK(provider);
	}
	}
	if (!provider) {
	DCHECK(writer_index_.find(pos) == writer_index_.end());
	writer_index_[pos] = CreateWriter(pos);
	provider = writer_index_[pos].get();
	}
	provider->SetDeferred(false);
	}

	void MultiBuffer::RemoveReader(const BlockId& pos, Reader* reader) {
	auto i = readers_.find(pos);
	if (i == readers_.end()) return;
	i->second.erase(reader);
	if (i->second.empty()) {
	readers_.erase(i);
	}
	}

	void MultiBuffer::CleanupWriters(const BlockId& pos) {
	BlockId p2 = pos + kMaxWaitForReaderOffset;
	BlockId closest_writer = ClosestPreviousEntry(writer_index_, p2);
	while (closest_writer > pos - kMaxWaitForWriterOffset) {
	DCHECK(writer_index_[closest_writer]);
	OnDataProviderEvent(writer_index_[closest_writer].get());
	closest_writer = ClosestPreviousEntry(writer_index_, closest_writer - 1);
	}
	}

	bool MultiBuffer::Contains(const BlockId& pos) const {
	DCHECK(present_[pos] == 0 \|\| present_[pos] == 1)
	<< " pos = " << pos << " present_[pos] " << present_[pos];
	DCHECK_EQ(present_[pos], data_.find(pos) != data_.end() ? 1 : 0);
	return !!present_[pos];
	}

	MultiBufferBlockId MultiBuffer::FindNextUnavailable(const BlockId& pos) const {
	auto i = present_.find(pos);
	if (i.value()) return i.interval_end();
	return pos;
	}

	void MultiBuffer::NotifyAvailableRange(
	const Interval<MultiBufferBlockId>& observer_range,
	const Interval<MultiBufferBlockId>& new_range) {
	std::set<Reader*> tmp;
	for (auto i = readers_.lower_bound(observer_range.begin);
	i != readers_.end() && i->first < observer_range.end; ++i) {
	tmp.insert(i->second.begin(), i->second.end());
	}
	for (Reader* reader : tmp) {
	reader->NotifyAvailableRange(new_range);
	}
	}

	void MultiBuffer::ReleaseBlocks(const std::vector<MultiBufferBlockId>& blocks) {
	IntervalMap<BlockId, int32_t> freed;
	for (MultiBufferBlockId to_free : blocks) {
	DCHECK(data_[to_free]);
	DCHECK_EQ(pinned_[to_free], 0);
	DCHECK_EQ(present_[to_free], 1);
	data_.erase(to_free);
	freed.IncrementInterval(to_free, to_free + 1, 1);
	present_.IncrementInterval(to_free, to_free + 1, -1);
	}
	lru_->IncrementDataSize(-static_cast<int64_t>(blocks.size()));

	for (const auto& freed_range : freed) {
	if (freed_range.second) {
	// Technically, there shouldn't be any observers in this range
	// as all observers really should be pinning the range where it's
	// actually observing.
	NotifyAvailableRange(
	freed_range.first,
	// Empty range.
	Interval<BlockId>(freed_range.first.begin, freed_range.first.begin));

	auto i = present_.find(freed_range.first.begin);
	DCHECK_EQ(i.value(), 0);
	DCHECK_LE(i.interval_begin(), freed_range.first.begin);
	DCHECK_LE(freed_range.first.end, i.interval_end());

	if (i.interval_begin() == freed_range.first.begin) {
	// Notify the previous range that it contains fewer blocks.
	auto j = i;
	--j;
	DCHECK_EQ(j.value(), 1);
	NotifyAvailableRange(j.interval(), j.interval());
	}
	if (i.interval_end() == freed_range.first.end) {
	// Notify the following range that it contains fewer blocks.
	auto j = i;
	++j;
	DCHECK_EQ(j.value(), 1);
	NotifyAvailableRange(j.interval(), j.interval());
	}
	}
	}
	if (data_.empty()) OnEmpty();
	}

	void MultiBuffer::OnEmpty() {}

	void MultiBuffer::AddProvider(std::unique_ptr<DataProvider> provider) {
	// If there is already a provider in the same location, we delete it.
	DCHECK(!provider->Available());
	BlockId pos = provider->Tell();
	writer_index_[pos] = std::move(provider);
	}

	std::unique_ptr<MultiBuffer::DataProvider> MultiBuffer::RemoveProvider(
	DataProvider* provider) {
	BlockId pos = provider->Tell();
	auto iter = writer_index_.find(pos);
	DCHECK(iter != writer_index_.end());
	DCHECK_EQ(iter->second.get(), provider);
	std::unique_ptr<DataProvider> ret = std::move(iter->second);
	writer_index_.erase(iter);
	return ret;
	}

	MultiBuffer::ProviderState MultiBuffer::SuggestProviderState(
	const BlockId& pos) const {
	MultiBufferBlockId next_reader_pos = ClosestNextEntry(readers_, pos);
	if (next_reader_pos != std::numeric_limits<MultiBufferBlockId>::max() &&
	(next_reader_pos - pos <= kMaxWaitForWriterOffset \|\| !RangeSupported())) {
	// Check if there is another writer between us and the next reader.
	MultiBufferBlockId next_writer_pos =
	ClosestNextEntry(writer_index_, pos + 1);
	if (next_writer_pos > next_reader_pos) {
	return ProviderStateLoad;
	}
	}

	MultiBufferBlockId previous_reader_pos =
	ClosestPreviousEntry(readers_, pos - 1);
	if (previous_reader_pos != std::numeric_limits<MultiBufferBlockId>::min() &&
	(pos - previous_reader_pos <= kMaxWaitForReaderOffset \|\|
	!RangeSupported())) {
	MultiBufferBlockId previous_writer_pos =
	ClosestPreviousEntry(writer_index_, pos - 1);
	if (previous_writer_pos < previous_reader_pos) {
	return ProviderStateDefer;
	}
	}

	return ProviderStateDead;
	}

	bool MultiBuffer::ProviderCollision(const BlockId& id) const {
	// If there is a writer at the same location, it is always a collision.
	if (writer_index_.find(id) != writer_index_.end()) return true;

	// Data already exists at providers current position,
	// if the URL supports ranges, we can kill the data provider.
	if (RangeSupported() && Contains(id)) return true;

	return false;
	}

	void MultiBuffer::Prune(size_t max_to_free) { lru_->Prune(max_to_free); }

	void MultiBuffer::OnDataProviderEvent(DataProvider* provider_tmp) {
	std::unique_ptr<DataProvider> provider(RemoveProvider(provider_tmp));
	BlockId start_pos = provider->Tell();
	BlockId pos = start_pos;
	bool eof = false;
	int64_t blocks_before = data_.size();

	while (!ProviderCollision(pos) && !eof) {
	if (!provider->Available()) {
	AddProvider(std::move(provider));
	break;
	}
	DCHECK_GE(pos, 0);
	scoped_refptr<DataBuffer> data = provider->Read();
	data_[pos] = data;
	eof = data->end_of_stream();
	if (!pinned_[pos]) lru_->Use(this, pos);
	++pos;
	}
	int64_t blocks_after = data_.size();
	int64_t blocks_added = blocks_after - blocks_before;

	if (pos > start_pos) {
	present_.SetInterval(start_pos, pos, 1);
	Interval<BlockId> expanded_range = present_.find(start_pos).interval();
	NotifyAvailableRange(expanded_range, expanded_range);
	lru_->IncrementDataSize(blocks_added);
	Prune(blocks_added * kMaxFreesPerAdd + 1);
	} else {
	// Make sure to give progress reports even when there
	// aren't any new blocks yet.
	NotifyAvailableRange(Interval<BlockId>(start_pos, start_pos + 1),
	Interval<BlockId>(start_pos, start_pos));
	}

	// Check that it's still there before we try to delete it.
	// In case of EOF or a collision, we might not have called AddProvider above.
	// Even if we did call AddProvider, calling NotifyAvailableRange can cause
	// readers to seek or self-destruct and clean up any associated writers.
	auto i = writer_index_.find(pos);
	if (i != writer_index_.end() && i->second.get() == provider_tmp) {
	switch (SuggestProviderState(pos)) {
	case ProviderStateLoad:
	// Not sure we actually need to do this
	provider_tmp->SetDeferred(false);
	break;
	case ProviderStateDefer:
	provider_tmp->SetDeferred(true);
	break;
	case ProviderStateDead:
	RemoveProvider(provider_tmp);
	break;
	}
	}
	}

	void MultiBuffer::MergeFrom(MultiBuffer* other) {
	// Import data and update LRU.
	size_t data_size = data_.size();
	for (const auto& data : other->data_) {
	if (data_.insert(std::make_pair(data.first, data.second)).second) {
	if (!pinned_[data.first]) {
	lru_->Insert(this, data.first);
	}
	}
	}
	lru_->IncrementDataSize(static_cast<int64_t>(data_.size() - data_size));
	// Update present_
	for (const auto& r : other->present_) {
	if (r.second) {
	present_.SetInterval(r.first.begin, r.first.end, 1);
	}
	}
	// Notify existing readers.
	auto last = present_.begin();
	for (const auto& r : other->present_) {
	if (r.second) {
	auto i = present_.find(r.first.begin);
	if (i != last) {
	NotifyAvailableRange(i.interval(), i.interval());
	last = i;
	}
	}
	}
	}

	void MultiBuffer::PinRange(const BlockId& from, const BlockId& to,
	int32_t how_much) {
	DCHECK_NE(how_much, 0);
	DVLOG(3) << "PINRANGE [" << from << " - " << to << ") += " << how_much;
	pinned_.IncrementInterval(from, to, how_much);
	Interval<BlockId> modified_range(from, to);

	// Iterate over all the modified ranges and check if any of them have
	// transitioned in or out of the unlocked state. If so, we iterate over
	// all buffers in that range and add/remove them from the LRU as approperiate.
	// We iterate backwards through the ranges, with the idea that data in a
	// continous range should be freed from the end first.

	if (data_.empty()) return;

	auto range = pinned_.find(to - 1);
	while (1) {
	DCHECK_GE(range.value(), 0);
	if (range.value() == 0 \|\| range.value() == how_much) {
	bool pin = range.value() == how_much;
	Interval<BlockId> transition_range =
	modified_range.Intersect(range.interval());
	if (transition_range.Empty()) break;

	// For each range that has transitioned to/from a pinned state,
	// we iterate over the corresponding ranges in \|present_\| to find
	// the blocks that are actually in the multibuffer.
	for (auto present_block_range = present_.find(transition_range.end - 1);
	present_block_range != present_.begin(); --present_block_range) {
	if (!present_block_range.value()) continue;
	Interval<BlockId> present_transitioned_range =
	transition_range.Intersect(present_block_range.interval());
	if (present_transitioned_range.Empty()) break;
	for (BlockId block = present_transitioned_range.end - 1;
	block >= present_transitioned_range.begin; --block) {
	DCHECK_GE(block, 0);
	DCHECK(data_.find(block) != data_.end());
	if (pin) {
	DCHECK(pinned_[block]);
	lru_->Remove(this, block);
	} else {
	DCHECK(!pinned_[block]);
	lru_->Insert(this, block);
	}
	}
	}
	}
	if (range == pinned_.begin()) break;
	--range;
	}
	}

	void MultiBuffer::PinRanges(const IntervalMap<BlockId, int32_t>& ranges) {
	for (const auto& r : ranges) {
	if (r.second != 0) {
	PinRange(r.first.begin, r.first.end, r.second);
	}
	}
	}

	void MultiBuffer::IncrementMaxSize(int32_t size) {
	max_size_ += size;
	lru_->IncrementMaxSize(size);
	DCHECK_GE(max_size_, 0);
	// Pruning only happens when blocks are added.
	}

	int64_t MultiBuffer::UncommittedBytesAt(const MultiBuffer::BlockId& block) {
	auto i = writer_index_.find(block);
	if (writer_index_.end() == i) return 0;
	return i->second->AvailableBytes();
	}

	} // namespace media
	} // namespace cobalt