src/gpu/GrGpuCommandBuffer.h - skia - Git at Google

 /*
 * Copyright 2016 Google Inc.
 *
 * Use of this source code is governed by a BSD-style license that can be
 * found in the LICENSE file.
 */

 #ifndef GrGpuCommandBuffer_DEFINED
 #define GrGpuCommandBuffer_DEFINED

 #include "GrColor.h"
 #include "ops/GrDrawOp.h"

 class GrOpFlushState;
 class GrFixedClip;
 class GrGpu;
 class GrMesh;
 class GrPipeline;
 class GrPrimitiveProcessor;
 class GrRenderTarget;
 struct SkIRect;
 struct SkRect;

 /**
  * The GrGpuCommandBuffer is a series of commands (draws, clears, and discards), which all target
  * the same render target. It is possible that these commands execute immediately (GL), or get
  * buffered up for later execution (Vulkan). GrOps will execute their draw commands into a
  * GrGpuCommandBuffer.
  *
  * Ideally we'd know the GrRenderTarget, or at least its properties when the GrGpuCommandBuffer, is
  * created. We also then wouldn't include it in the GrPipeline or as a parameter to the clear and
  * discard methods. The logical place for that will be in GrRenderTargetOpList post-MDB. For now
  * the render target is redundantly passed to each operation, though it will always be the same
  * render target for a given command buffer even pre-MDB.
  */
 class GrGpuCommandBuffer {
 public:
     enum class LoadOp {
         kLoad,
         kClear,
         kDiscard,
     };

     enum class StoreOp {
         kStore,
         kDiscard,
     };

     struct LoadAndStoreInfo {
         LoadOp  fLoadOp;
         StoreOp fStoreOp;
         GrColor fClearColor;
     };

     GrGpuCommandBuffer() {}
     virtual ~GrGpuCommandBuffer() {}

     // Signals the end of recording to the command buffer and that it can now be submitted.
     virtual void end() = 0;

     // Sends the command buffer off to the GPU object to execute the commands built up in the
     // buffer. The gpu object is allowed to defer execution of the commands until it is flushed.
     void submit();

     // We pass in an array of meshCount GrMesh to the draw. The backend should loop over each
     // GrMesh object and emit a draw for it. Each draw will use the same GrPipeline and
     // GrPrimitiveProcessor. This may fail if the draw would exceed any resource limits (e.g.
     // number of vertex attributes is too large).
     bool draw(const GrPipeline&,
               const GrPrimitiveProcessor&,
               const GrMesh*,
               int meshCount,
               const SkRect& bounds);

     // Performs an upload of vertex data in the middle of a set of a set of draws
     virtual void inlineUpload(GrOpFlushState* state, GrDrawOp::DeferredUploadFn& upload) = 0;

     /**
      * Clear the passed in render target. Ignores the draw state and clip.
      */
     void clear(GrRenderTarget*, const GrFixedClip&, GrColor);

     void clearStencilClip(GrRenderTarget*, const GrFixedClip&, bool insideStencilMask);

     /**
      * Discards the contents render target. nullptr indicates that the current render target should
      * be discarded.
      */
     // TODO: This should be removed in the future to favor using the load and store ops for discard
     virtual void discard(GrRenderTarget*) = 0;

 private:
     virtual GrGpu* gpu() = 0;
     virtual GrRenderTarget* renderTarget() = 0;

     virtual void onSubmit() = 0;

     // overridden by backend-specific derived class to perform the draw call.
     virtual void onDraw(const GrPipeline&,
                         const GrPrimitiveProcessor&,
                         const GrMesh*,
                         int meshCount,
                         const SkRect& bounds) = 0;

     // overridden by backend-specific derived class to perform the clear.
     virtual void onClear(GrRenderTarget*, const GrFixedClip&, GrColor) = 0;

     virtual void onClearStencilClip(GrRenderTarget*, const GrFixedClip&,
                                     bool insideStencilMask) = 0;

 };

 #endif
	/*
	* Copyright 2016 Google Inc.
	*
	* Use of this source code is governed by a BSD-style license that can be
	* found in the LICENSE file.
	*/

	#ifndef GrGpuCommandBuffer_DEFINED
	#define GrGpuCommandBuffer_DEFINED

	#include "GrColor.h"
	#include "ops/GrDrawOp.h"

	class GrOpFlushState;
	class GrFixedClip;
	class GrGpu;
	class GrMesh;
	class GrPipeline;
	class GrPrimitiveProcessor;
	class GrRenderTarget;
	struct SkIRect;
	struct SkRect;

	/**
	* The GrGpuCommandBuffer is a series of commands (draws, clears, and discards), which all target
	* the same render target. It is possible that these commands execute immediately (GL), or get
	* buffered up for later execution (Vulkan). GrOps will execute their draw commands into a
	* GrGpuCommandBuffer.
	*
	* Ideally we'd know the GrRenderTarget, or at least its properties when the GrGpuCommandBuffer, is
	* created. We also then wouldn't include it in the GrPipeline or as a parameter to the clear and
	* discard methods. The logical place for that will be in GrRenderTargetOpList post-MDB. For now
	* the render target is redundantly passed to each operation, though it will always be the same
	* render target for a given command buffer even pre-MDB.
	*/
	class GrGpuCommandBuffer {
	public:
	enum class LoadOp {
	kLoad,
	kClear,
	kDiscard,
	};

	enum class StoreOp {
	kStore,
	kDiscard,
	};

	struct LoadAndStoreInfo {
	LoadOp fLoadOp;
	StoreOp fStoreOp;
	GrColor fClearColor;
	};

	GrGpuCommandBuffer() {}
	virtual ~GrGpuCommandBuffer() {}

	// Signals the end of recording to the command buffer and that it can now be submitted.
	virtual void end() = 0;

	// Sends the command buffer off to the GPU object to execute the commands built up in the
	// buffer. The gpu object is allowed to defer execution of the commands until it is flushed.
	void submit();

	// We pass in an array of meshCount GrMesh to the draw. The backend should loop over each
	// GrMesh object and emit a draw for it. Each draw will use the same GrPipeline and
	// GrPrimitiveProcessor. This may fail if the draw would exceed any resource limits (e.g.
	// number of vertex attributes is too large).
	bool draw(const GrPipeline&,
	const GrPrimitiveProcessor&,
	const GrMesh*,
	int meshCount,
	const SkRect& bounds);

	// Performs an upload of vertex data in the middle of a set of a set of draws
	virtual void inlineUpload(GrOpFlushState* state, GrDrawOp::DeferredUploadFn& upload) = 0;

	/**
	* Clear the passed in render target. Ignores the draw state and clip.
	*/
	void clear(GrRenderTarget*, const GrFixedClip&, GrColor);

	void clearStencilClip(GrRenderTarget*, const GrFixedClip&, bool insideStencilMask);

	/**
	* Discards the contents render target. nullptr indicates that the current render target should
	* be discarded.
	*/
	// TODO: This should be removed in the future to favor using the load and store ops for discard
	virtual void discard(GrRenderTarget*) = 0;

	private:
	virtual GrGpu* gpu() = 0;
	virtual GrRenderTarget* renderTarget() = 0;

	virtual void onSubmit() = 0;

	// overridden by backend-specific derived class to perform the draw call.
	virtual void onDraw(const GrPipeline&,
	const GrPrimitiveProcessor&,
	const GrMesh*,
	int meshCount,
	const SkRect& bounds) = 0;

	// overridden by backend-specific derived class to perform the clear.
	virtual void onClear(GrRenderTarget*, const GrFixedClip&, GrColor) = 0;

	virtual void onClearStencilClip(GrRenderTarget*, const GrFixedClip&,
	bool insideStencilMask) = 0;

	};

	#endif