gpu/command_buffer/client/transfer_buffer.h - chromium/src.git - 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.

 #ifndef GPU_COMMAND_BUFFER_CLIENT_TRANSFER_BUFFER_H_
 #define GPU_COMMAND_BUFFER_CLIENT_TRANSFER_BUFFER_H_

 #include <stddef.h>
 #include <stdint.h>

 #include <memory>

 #include "base/compiler_specific.h"
 #include "base/containers/circular_deque.h"
 #include "base/macros.h"
 #include "base/unguessable_token.h"
 #include "gpu/command_buffer/client/ring_buffer.h"
 #include "gpu/command_buffer/common/buffer.h"
 #include "gpu/gpu_export.h"

 namespace gpu {

 class CommandBufferHelper;
 template <typename>
 class ScopedResultPtr;

 // Interface for managing the transfer buffer.
 class GPU_EXPORT TransferBufferInterface {
  public:
   TransferBufferInterface() = default;
   virtual ~TransferBufferInterface() = default;

   // Returns 128-bit GUID of the shared memory's region when the back end is
   // base::UnsafeSharedMemoryRegion. Otherwise, this returns an empty GUID.
   virtual base::UnguessableToken shared_memory_guid() const = 0;

   virtual bool Initialize(unsigned int buffer_size,
                           unsigned int result_size,
                           unsigned int min_buffer_size,
                           unsigned int max_buffer_size,
                           unsigned int alignment) = 0;

   virtual int GetShmId() = 0;

   virtual void Free() = 0;

   virtual bool HaveBuffer() const = 0;

   // Allocates up to size bytes.
   virtual void* AllocUpTo(unsigned int size, unsigned int* size_allocated) = 0;

   // Allocates size bytes.
   // Note: Alloc will fail if it can not return size bytes.
   virtual void* Alloc(unsigned int size) = 0;

   virtual RingBuffer::Offset GetOffset(void* pointer) const = 0;

   virtual void DiscardBlock(void* p) = 0;

   virtual void FreePendingToken(void* p, unsigned int token) = 0;

   virtual unsigned int GetSize() const = 0;

   virtual unsigned int GetFreeSize() const = 0;

   virtual unsigned int GetFragmentedFreeSize() const = 0;

   virtual void ShrinkLastBlock(unsigned int new_size) = 0;

  protected:
   template <typename>
   friend class ScopedResultPtr;
   // Use ScopedResultPtr instead of calling these directly. The acquire/release
   // semantics allow TransferBuffer to detect if there is an outstanding result
   // pointer when the buffer is resized, which would otherwise cause a
   // use-after-free bug.
   virtual void* AcquireResultBuffer() = 0;
   virtual void ReleaseResultBuffer() = 0;
   virtual int GetResultOffset() = 0;
 };

 // Class that manages the transfer buffer.
 class GPU_EXPORT TransferBuffer : public TransferBufferInterface {
  public:
   TransferBuffer(CommandBufferHelper* helper);
   ~TransferBuffer() override;

   // Overridden from TransferBufferInterface.
   base::UnguessableToken shared_memory_guid() const override;
   bool Initialize(unsigned int default_buffer_size,
                   unsigned int result_size,
                   unsigned int min_buffer_size,
                   unsigned int max_buffer_size,
                   unsigned int alignment) override;
   int GetShmId() override;
   void* AcquireResultBuffer() override;
   void ReleaseResultBuffer() override;
   int GetResultOffset() override;
   void Free() override;
   bool HaveBuffer() const override;
   void* AllocUpTo(unsigned int size, unsigned int* size_allocated) override;
   void* Alloc(unsigned int size) override;
   RingBuffer::Offset GetOffset(void* pointer) const override;
   void DiscardBlock(void* p) override;
   void FreePendingToken(void* p, unsigned int token) override;
   unsigned int GetSize() const override;
   unsigned int GetFreeSize() const override;
   unsigned int GetFragmentedFreeSize() const override;
   void ShrinkLastBlock(unsigned int new_size) override;

   // These are for testing.
   unsigned int GetCurrentMaxAllocationWithoutRealloc() const;
   unsigned int GetMaxAllocation() const;

   // We will attempt to shrink the ring buffer once the number of bytes
   // allocated reaches this threshold times the high water mark.
   static const int kShrinkThreshold = 120;

  private:
   // Tries to reallocate the ring buffer if it's not large enough for size.
   void ReallocateRingBuffer(unsigned int size, bool shrink = false);

   void AllocateRingBuffer(unsigned int size);

   void ShrinkOrExpandRingBufferIfNecessary(unsigned int size);

   // Returns the number of bytes that are still in use in ring buffers that we
   // previously freed.
   unsigned int GetPreviousRingBufferUsedBytes();

   CommandBufferHelper* helper_;
   std::unique_ptr<RingBuffer> ring_buffer_;
   base::circular_deque<std::unique_ptr<RingBuffer>> previous_ring_buffers_;

   // size reserved for results
   unsigned int result_size_;

   // default size. Size we want when starting or re-allocating
   unsigned int default_buffer_size_;

   // min size we'll consider successful
   unsigned int min_buffer_size_;

   // max size we'll let the buffer grow
   unsigned int max_buffer_size_;

   // Size of the currently allocated ring buffer.
   unsigned int last_allocated_size_ = 0;

   // The size to shrink the ring buffer to next time shrinking happens.
   unsigned int high_water_mark_ = 0;

   // alignment for allocations
   unsigned int alignment_;

   // Number of bytes since we last attempted to shrink the ring buffer.
   unsigned int bytes_since_last_shrink_ = 0;

   // the current buffer.
   scoped_refptr<gpu::Buffer> buffer_;

   // id of buffer. -1 = no buffer
   int32_t buffer_id_;

   // address of result area
   void* result_buffer_;

   // offset to result area
   uint32_t result_shm_offset_;

   // false if we failed to allocate min_buffer_size
   bool usable_;

   // While a ScopedResultPtr exists, we can't resize the transfer buffer. Only
   // one ScopedResultPtr should exist at a time. This tracks whether one exists.
   bool outstanding_result_pointer_ = false;
 };

 // A class that will manage the lifetime of a transferbuffer allocation.
 class GPU_EXPORT ScopedTransferBufferPtr {
  public:
   ScopedTransferBufferPtr(unsigned int size,
                           CommandBufferHelper* helper,
                           TransferBufferInterface* transfer_buffer)
       : buffer_(nullptr),
         size_(0),
         helper_(helper),
         transfer_buffer_(transfer_buffer) {
     Reset(size);
   }

   // Constructs an empty and invalid allocation that should be Reset() later.
   ScopedTransferBufferPtr(CommandBufferHelper* helper,
                           TransferBufferInterface* transfer_buffer)
       : buffer_(nullptr),
         size_(0),
         helper_(helper),
         transfer_buffer_(transfer_buffer) {}

   ~ScopedTransferBufferPtr() {
     Release();
   }

   ScopedTransferBufferPtr(ScopedTransferBufferPtr&& other);

   bool valid() const { return buffer_ != nullptr; }

   unsigned int size() const {
     return size_;
   }

   int shm_id() const {
     return transfer_buffer_->GetShmId();
   }

   RingBuffer::Offset offset() const {
     return transfer_buffer_->GetOffset(buffer_);
   }

   void* address() const {
     return buffer_;
   }

   // Returns true if |memory| lies inside this buffer.
   bool BelongsToBuffer(char* memory) const;

   void Release();

   void Discard();

   void Reset(unsigned int new_size);

   // Shrinks this transfer buffer to a given size.
   void Shrink(unsigned int new_size);

  private:
   void* buffer_;
   unsigned int size_;
   CommandBufferHelper* helper_;
   TransferBufferInterface* transfer_buffer_;
   DISALLOW_COPY_AND_ASSIGN(ScopedTransferBufferPtr);
 };

 template <typename T>
 class ScopedTransferBufferArray : public ScopedTransferBufferPtr {
  public:
   ScopedTransferBufferArray(
       unsigned int num_elements,
       CommandBufferHelper* helper, TransferBufferInterface* transfer_buffer)
       : ScopedTransferBufferPtr(
           num_elements * sizeof(T), helper, transfer_buffer) {
   }

   T* elements() {
     return static_cast<T*>(address());
   }

   unsigned int num_elements() const {
     return size() / sizeof(T);
   }
 };

 // ScopedResultPtr is a move-only smart pointer that calls AcquireResultBuffer
 // and ReleaseResultBuffer for you.
 template <typename T>
 class ScopedResultPtr {
  public:
   explicit ScopedResultPtr(TransferBufferInterface* tb)
       : result_(static_cast<T*>(tb->AcquireResultBuffer())),
         transfer_buffer_(tb) {}
   ~ScopedResultPtr() {
     if (transfer_buffer_)
       transfer_buffer_->ReleaseResultBuffer();
   }

   int offset() const { return transfer_buffer_->GetResultOffset(); }

   // Make this a move-only class like unique_ptr.
   DISALLOW_COPY_AND_ASSIGN(ScopedResultPtr);
   ScopedResultPtr(ScopedResultPtr<T>&& other) { *this = std::move(other); }
   ScopedResultPtr& operator=(ScopedResultPtr<T>&& other) {
     this->result_ = other.result_;
     this->transfer_buffer_ = other.transfer_buffer_;
     other.result_ = nullptr;
     other.transfer_buffer_ = nullptr;
     return *this;
   };

   // Dereferencing behaviors
   T& operator*() const { return *result_; }
   T* operator->() const { return result_; }
   explicit operator bool() { return result_; }

  private:
   T* result_;
   TransferBufferInterface* transfer_buffer_;
 };

 }  // namespace gpu

 #endif  // GPU_COMMAND_BUFFER_CLIENT_TRANSFER_BUFFER_H_
	// 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.

	#ifndef GPU_COMMAND_BUFFER_CLIENT_TRANSFER_BUFFER_H_
	#define GPU_COMMAND_BUFFER_CLIENT_TRANSFER_BUFFER_H_

	#include <stddef.h>
	#include <stdint.h>

	#include <memory>

	#include "base/compiler_specific.h"
	#include "base/containers/circular_deque.h"
	#include "base/macros.h"
	#include "base/unguessable_token.h"
	#include "gpu/command_buffer/client/ring_buffer.h"
	#include "gpu/command_buffer/common/buffer.h"
	#include "gpu/gpu_export.h"

	namespace gpu {

	class CommandBufferHelper;
	template <typename>
	class ScopedResultPtr;

	// Interface for managing the transfer buffer.
	class GPU_EXPORT TransferBufferInterface {
	public:
	TransferBufferInterface() = default;
	virtual ~TransferBufferInterface() = default;

	// Returns 128-bit GUID of the shared memory's region when the back end is
	// base::UnsafeSharedMemoryRegion. Otherwise, this returns an empty GUID.
	virtual base::UnguessableToken shared_memory_guid() const = 0;

	virtual bool Initialize(unsigned int buffer_size,
	unsigned int result_size,
	unsigned int min_buffer_size,
	unsigned int max_buffer_size,
	unsigned int alignment) = 0;

	virtual int GetShmId() = 0;

	virtual void Free() = 0;

	virtual bool HaveBuffer() const = 0;

	// Allocates up to size bytes.
	virtual void* AllocUpTo(unsigned int size, unsigned int* size_allocated) = 0;

	// Allocates size bytes.
	// Note: Alloc will fail if it can not return size bytes.
	virtual void* Alloc(unsigned int size) = 0;

	virtual RingBuffer::Offset GetOffset(void* pointer) const = 0;

	virtual void DiscardBlock(void* p) = 0;

	virtual void FreePendingToken(void* p, unsigned int token) = 0;

	virtual unsigned int GetSize() const = 0;

	virtual unsigned int GetFreeSize() const = 0;

	virtual unsigned int GetFragmentedFreeSize() const = 0;

	virtual void ShrinkLastBlock(unsigned int new_size) = 0;

	protected:
	template <typename>
	friend class ScopedResultPtr;
	// Use ScopedResultPtr instead of calling these directly. The acquire/release
	// semantics allow TransferBuffer to detect if there is an outstanding result
	// pointer when the buffer is resized, which would otherwise cause a
	// use-after-free bug.
	virtual void* AcquireResultBuffer() = 0;
	virtual void ReleaseResultBuffer() = 0;
	virtual int GetResultOffset() = 0;
	};

	// Class that manages the transfer buffer.
	class GPU_EXPORT TransferBuffer : public TransferBufferInterface {
	public:
	TransferBuffer(CommandBufferHelper* helper);
	~TransferBuffer() override;

	// Overridden from TransferBufferInterface.
	base::UnguessableToken shared_memory_guid() const override;
	bool Initialize(unsigned int default_buffer_size,
	unsigned int result_size,
	unsigned int min_buffer_size,
	unsigned int max_buffer_size,
	unsigned int alignment) override;
	int GetShmId() override;
	void* AcquireResultBuffer() override;
	void ReleaseResultBuffer() override;
	int GetResultOffset() override;
	void Free() override;
	bool HaveBuffer() const override;
	void* AllocUpTo(unsigned int size, unsigned int* size_allocated) override;
	void* Alloc(unsigned int size) override;
	RingBuffer::Offset GetOffset(void* pointer) const override;
	void DiscardBlock(void* p) override;
	void FreePendingToken(void* p, unsigned int token) override;
	unsigned int GetSize() const override;
	unsigned int GetFreeSize() const override;
	unsigned int GetFragmentedFreeSize() const override;
	void ShrinkLastBlock(unsigned int new_size) override;

	// These are for testing.
	unsigned int GetCurrentMaxAllocationWithoutRealloc() const;
	unsigned int GetMaxAllocation() const;

	// We will attempt to shrink the ring buffer once the number of bytes
	// allocated reaches this threshold times the high water mark.
	static const int kShrinkThreshold = 120;

	private:
	// Tries to reallocate the ring buffer if it's not large enough for size.
	void ReallocateRingBuffer(unsigned int size, bool shrink = false);

	void AllocateRingBuffer(unsigned int size);

	void ShrinkOrExpandRingBufferIfNecessary(unsigned int size);

	// Returns the number of bytes that are still in use in ring buffers that we
	// previously freed.
	unsigned int GetPreviousRingBufferUsedBytes();

	CommandBufferHelper* helper_;
	std::unique_ptr<RingBuffer> ring_buffer_;
	base::circular_deque<std::unique_ptr<RingBuffer>> previous_ring_buffers_;

	// size reserved for results
	unsigned int result_size_;

	// default size. Size we want when starting or re-allocating
	unsigned int default_buffer_size_;

	// min size we'll consider successful
	unsigned int min_buffer_size_;

	// max size we'll let the buffer grow
	unsigned int max_buffer_size_;

	// Size of the currently allocated ring buffer.
	unsigned int last_allocated_size_ = 0;

	// The size to shrink the ring buffer to next time shrinking happens.
	unsigned int high_water_mark_ = 0;

	// alignment for allocations
	unsigned int alignment_;

	// Number of bytes since we last attempted to shrink the ring buffer.
	unsigned int bytes_since_last_shrink_ = 0;

	// the current buffer.
	scoped_refptr<gpu::Buffer> buffer_;

	// id of buffer. -1 = no buffer
	int32_t buffer_id_;

	// address of result area
	void* result_buffer_;

	// offset to result area
	uint32_t result_shm_offset_;

	// false if we failed to allocate min_buffer_size
	bool usable_;

	// While a ScopedResultPtr exists, we can't resize the transfer buffer. Only
	// one ScopedResultPtr should exist at a time. This tracks whether one exists.
	bool outstanding_result_pointer_ = false;
	};

	// A class that will manage the lifetime of a transferbuffer allocation.
	class GPU_EXPORT ScopedTransferBufferPtr {
	public:
	ScopedTransferBufferPtr(unsigned int size,
	CommandBufferHelper* helper,
	TransferBufferInterface* transfer_buffer)
	: buffer_(nullptr),
	size_(0),
	helper_(helper),
	transfer_buffer_(transfer_buffer) {
	Reset(size);
	}

	// Constructs an empty and invalid allocation that should be Reset() later.
	ScopedTransferBufferPtr(CommandBufferHelper* helper,
	TransferBufferInterface* transfer_buffer)
	: buffer_(nullptr),
	size_(0),
	helper_(helper),
	transfer_buffer_(transfer_buffer) {}

	~ScopedTransferBufferPtr() {
	Release();
	}

	ScopedTransferBufferPtr(ScopedTransferBufferPtr&& other);

	bool valid() const { return buffer_ != nullptr; }

	unsigned int size() const {
	return size_;
	}

	int shm_id() const {
	return transfer_buffer_->GetShmId();
	}

	RingBuffer::Offset offset() const {
	return transfer_buffer_->GetOffset(buffer_);
	}

	void* address() const {
	return buffer_;
	}

	// Returns true if \|memory\| lies inside this buffer.
	bool BelongsToBuffer(char* memory) const;

	void Release();

	void Discard();

	void Reset(unsigned int new_size);

	// Shrinks this transfer buffer to a given size.
	void Shrink(unsigned int new_size);

	private:
	void* buffer_;
	unsigned int size_;
	CommandBufferHelper* helper_;
	TransferBufferInterface* transfer_buffer_;
	DISALLOW_COPY_AND_ASSIGN(ScopedTransferBufferPtr);
	};

	template <typename T>
	class ScopedTransferBufferArray : public ScopedTransferBufferPtr {
	public:
	ScopedTransferBufferArray(
	unsigned int num_elements,
	CommandBufferHelper* helper, TransferBufferInterface* transfer_buffer)
	: ScopedTransferBufferPtr(
	num_elements * sizeof(T), helper, transfer_buffer) {
	}

	T* elements() {
	return static_cast<T*>(address());
	}

	unsigned int num_elements() const {
	return size() / sizeof(T);
	}
	};

	// ScopedResultPtr is a move-only smart pointer that calls AcquireResultBuffer
	// and ReleaseResultBuffer for you.
	template <typename T>
	class ScopedResultPtr {
	public:
	explicit ScopedResultPtr(TransferBufferInterface* tb)
	: result_(static_cast<T*>(tb->AcquireResultBuffer())),
	transfer_buffer_(tb) {}
	~ScopedResultPtr() {
	if (transfer_buffer_)
	transfer_buffer_->ReleaseResultBuffer();
	}

	int offset() const { return transfer_buffer_->GetResultOffset(); }

	// Make this a move-only class like unique_ptr.
	DISALLOW_COPY_AND_ASSIGN(ScopedResultPtr);
	ScopedResultPtr(ScopedResultPtr<T>&& other) { *this = std::move(other); }
	ScopedResultPtr& operator=(ScopedResultPtr<T>&& other) {
	this->result_ = other.result_;
	this->transfer_buffer_ = other.transfer_buffer_;
	other.result_ = nullptr;
	other.transfer_buffer_ = nullptr;
	return *this;
	};

	// Dereferencing behaviors
	T& operator() const { return result_; }
	T* operator->() const { return result_; }
	explicit operator bool() { return result_; }

	private:
	T* result_;
	TransferBufferInterface* transfer_buffer_;
	};

	} // namespace gpu

	#endif // GPU_COMMAND_BUFFER_CLIENT_TRANSFER_BUFFER_H_