include/core/SkRWBuffer.h - skia - Git at Google

 /*
  * Copyright 2015 Google Inc.
  *
  * Use of this source code is governed by a BSD-style license that can be
  * found in the LICENSE file.
  */

 #ifndef SkRWBuffer_DEFINED
 #define SkRWBuffer_DEFINED

 #include "SkRefCnt.h"

 struct SkBufferBlock;
 struct SkBufferHead;
 class SkRWBuffer;
 class SkStreamAsset;

 /**
  *  Contains a read-only, thread-sharable block of memory. To access the memory, the caller must
  *  instantiate a local iterator, as the memory is stored in 1 or more contiguous blocks.
  */
 class SK_API SkROBuffer : public SkRefCnt {
 public:
     /**
      *  Return the logical length of the data owned/shared by this buffer. It may be stored in
      *  multiple contiguous blocks, accessible via the iterator.
      */
     size_t size() const { return fAvailable; }

     class SK_API Iter {
     public:
         Iter(const SkROBuffer*);
         Iter(const sk_sp<SkROBuffer>&);

         void reset(const SkROBuffer*);

         /**
          *  Return the current continuous block of memory, or nullptr if the iterator is exhausted
          */
         const void* data() const;

         /**
          *  Returns the number of bytes in the current continguous block of memory, or 0 if the
          *  iterator is exhausted.
          */
         size_t size() const;

         /**
          *  Advance to the next contiguous block of memory, returning true if there is another
          *  block, or false if the iterator is exhausted.
          */
         bool next();

     private:
         const SkBufferBlock* fBlock;
         size_t               fRemaining;
         const SkROBuffer*    fBuffer;
     };

 private:
     SkROBuffer(const SkBufferHead* head, size_t available, const SkBufferBlock* fTail);
     virtual ~SkROBuffer();

     const SkBufferHead*     fHead;
     const size_t            fAvailable;
     const SkBufferBlock*    fTail;

     friend class SkRWBuffer;
 };

 /**
  *  Accumulates bytes of memory that are "appended" to it, growing internal storage as needed.
  *  The growth is done such that at any time in the writer's thread, an RBuffer or StreamAsset
  *  can be snapped off (and safely passed to another thread). The RBuffer/StreamAsset snapshot
  *  can see the previously stored bytes, but will be unaware of any future writes.
  */
 class SK_API SkRWBuffer {
 public:
     SkRWBuffer(size_t initialCapacity = 0);
     ~SkRWBuffer();

     size_t size() const { return fTotalUsed; }

     /**
      *  Append |length| bytes from |buffer|.
      *
      *  If the caller knows in advance how much more data they are going to append, they can
      *  pass a |reserve| hint (representing the number of upcoming bytes *in addition* to the
      *  current append), to minimize the number of internal allocations.
      */
     void append(const void* buffer, size_t length, size_t reserve = 0);

     sk_sp<SkROBuffer> makeROBufferSnapshot() const {
         return sk_sp<SkROBuffer>(new SkROBuffer(fHead, fTotalUsed, fTail));
     }

     std::unique_ptr<SkStreamAsset> makeStreamSnapshot() const;

 #ifdef SK_DEBUG
     void validate() const;
 #else
     void validate() const {}
 #endif

 private:
     SkBufferHead*   fHead;
     SkBufferBlock*  fTail;
     size_t          fTotalUsed;
 };

 #endif
	/*
	* Copyright 2015 Google Inc.
	*
	* Use of this source code is governed by a BSD-style license that can be
	* found in the LICENSE file.
	*/

	#ifndef SkRWBuffer_DEFINED
	#define SkRWBuffer_DEFINED

	#include "SkRefCnt.h"

	struct SkBufferBlock;
	struct SkBufferHead;
	class SkRWBuffer;
	class SkStreamAsset;

	/**
	* Contains a read-only, thread-sharable block of memory. To access the memory, the caller must
	* instantiate a local iterator, as the memory is stored in 1 or more contiguous blocks.
	*/
	class SK_API SkROBuffer : public SkRefCnt {
	public:
	/**
	* Return the logical length of the data owned/shared by this buffer. It may be stored in
	* multiple contiguous blocks, accessible via the iterator.
	*/
	size_t size() const { return fAvailable; }

	class SK_API Iter {
	public:
	Iter(const SkROBuffer*);
	Iter(const sk_sp<SkROBuffer>&);

	void reset(const SkROBuffer*);

	/**
	* Return the current continuous block of memory, or nullptr if the iterator is exhausted
	*/
	const void* data() const;

	/**
	* Returns the number of bytes in the current continguous block of memory, or 0 if the
	* iterator is exhausted.
	*/
	size_t size() const;

	/**
	* Advance to the next contiguous block of memory, returning true if there is another
	* block, or false if the iterator is exhausted.
	*/
	bool next();

	private:
	const SkBufferBlock* fBlock;
	size_t fRemaining;
	const SkROBuffer* fBuffer;
	};

	private:
	SkROBuffer(const SkBufferHead* head, size_t available, const SkBufferBlock* fTail);
	virtual ~SkROBuffer();

	const SkBufferHead* fHead;
	const size_t fAvailable;
	const SkBufferBlock* fTail;

	friend class SkRWBuffer;
	};

	/**
	* Accumulates bytes of memory that are "appended" to it, growing internal storage as needed.
	* The growth is done such that at any time in the writer's thread, an RBuffer or StreamAsset
	* can be snapped off (and safely passed to another thread). The RBuffer/StreamAsset snapshot
	* can see the previously stored bytes, but will be unaware of any future writes.
	*/
	class SK_API SkRWBuffer {
	public:
	SkRWBuffer(size_t initialCapacity = 0);
	~SkRWBuffer();

	size_t size() const { return fTotalUsed; }

	/**
	* Append \|length\| bytes from \|buffer\|.
	*
	* If the caller knows in advance how much more data they are going to append, they can
	* pass a \|reserve\| hint (representing the number of upcoming bytes in addition to the
	* current append), to minimize the number of internal allocations.
	*/
	void append(const void* buffer, size_t length, size_t reserve = 0);

	sk_sp<SkROBuffer> makeROBufferSnapshot() const {
	return sk_sp<SkROBuffer>(new SkROBuffer(fHead, fTotalUsed, fTail));
	}

	std::unique_ptr<SkStreamAsset> makeStreamSnapshot() const;

	#ifdef SK_DEBUG
	void validate() const;
	#else
	void validate() const {}
	#endif

	private:
	SkBufferHead* fHead;
	SkBufferBlock* fTail;
	size_t fTotalUsed;
	};

	#endif