src/gpu/GrBatchFlushState.h - platform/external/skqp - Gitiles

 /*
  * 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 GrBatchBuffer_DEFINED
 #define GrBatchBuffer_DEFINED

 #include "GrBufferAllocPool.h"
 #include "GrGpu.h"
 #include "batches/GrMeshDrawOp.h"

 class GrGpuCommandBuffer;
 class GrResourceProvider;

 /** Tracks the state across all the GrBatches in a GrOpList flush. */
 class GrBatchFlushState {
 public:
     GrBatchFlushState(GrGpu*, GrResourceProvider*);

     ~GrBatchFlushState() { this->reset(); }

     /** Inserts an upload to be executed after all batches in the flush prepared their draws
         but before the draws are executed to the backend 3D API. */
     void addASAPUpload(GrDrawOp::DeferredUploadFn&& upload) {
         fAsapUploads.emplace_back(std::move(upload));
     }

     const GrCaps& caps() const { return *fGpu->caps(); }
     GrResourceProvider* resourceProvider() const { return fResourceProvider; }

     /** Has the token been flushed to the backend 3D API. */
     bool hasDrawBeenFlushed(GrDrawOpUploadToken token) const {
         return token.fSequenceNumber <= fLastFlushedToken.fSequenceNumber;
     }

     /** Issue a token to an operation that is being enqueued. */
     GrDrawOpUploadToken issueDrawToken() {
         return GrDrawOpUploadToken(++fLastIssuedToken.fSequenceNumber);
     }

     /** Call every time a draw that was issued a token is flushed */
     void flushToken() { ++fLastFlushedToken.fSequenceNumber; }

     /** Gets the next draw token that will be issued. */
     GrDrawOpUploadToken nextDrawToken() const {
         return GrDrawOpUploadToken(fLastIssuedToken.fSequenceNumber + 1);
     }

     /** The last token flushed to all the way to the backend API. */
     GrDrawOpUploadToken nextTokenToFlush() const {
         return GrDrawOpUploadToken(fLastFlushedToken.fSequenceNumber + 1);
     }

     void* makeVertexSpace(size_t vertexSize, int vertexCount,
                           const GrBuffer** buffer, int* startVertex);
     uint16_t* makeIndexSpace(int indexCount, const GrBuffer** buffer, int* startIndex);

     /** This is called after each batch has a chance to prepare its draws and before the draws
         are issued. */
     void preIssueDraws() {
         fVertexPool.unmap();
         fIndexPool.unmap();
         int uploadCount = fAsapUploads.count();

         for (int i = 0; i < uploadCount; i++) {
             this->doUpload(fAsapUploads[i]);
         }
         fAsapUploads.reset();
     }

     void doUpload(GrDrawOp::DeferredUploadFn& upload) {
         GrDrawOp::WritePixelsFn wp = [this] (GrSurface* surface,
                 int left, int top, int width, int height,
                 GrPixelConfig config, const void* buffer,
                 size_t rowBytes) -> bool {
             return this->fGpu->writePixels(surface, left, top, width, height, config, buffer,
                                            rowBytes);
         };
         upload(wp);
     }

     void putBackIndices(size_t indices) { fIndexPool.putBack(indices * sizeof(uint16_t)); }

     void putBackVertexSpace(size_t sizeInBytes) { fVertexPool.putBack(sizeInBytes); }

     GrGpuCommandBuffer* commandBuffer() { return fCommandBuffer; }
     void setCommandBuffer(GrGpuCommandBuffer* buffer) { fCommandBuffer = buffer; }

     GrGpu* gpu() { return fGpu; }

     void reset() {
         fVertexPool.reset();
         fIndexPool.reset();
     }

 private:

     GrGpu*                                      fGpu;

     GrResourceProvider*                         fResourceProvider;

     GrGpuCommandBuffer*                         fCommandBuffer;

     GrVertexBufferAllocPool                     fVertexPool;
     GrIndexBufferAllocPool                      fIndexPool;

     SkSTArray<4, GrDrawOp::DeferredUploadFn>    fAsapUploads;

     GrDrawOpUploadToken                         fLastIssuedToken;

     GrDrawOpUploadToken                         fLastFlushedToken;
 };

 /**
  * A word about uploads and tokens: Batches should usually schedule their uploads to occur at the
  * begining of a frame whenever possible. These are called ASAP uploads. Of course, this requires
  * that there are no draws that have yet to be flushed that rely on the old texture contents. In
  * that case the ASAP upload would happen prior to the previous draw causing the draw to read the
  * new (wrong) texture data. In that case they should schedule an inline upload.
  *
  * Batches, in conjunction with helpers such as GrBatchAtlas, can use the token system to know
  * what the most recent draw was that referenced a resource (or portion of a resource). Each draw
  * is assigned a token. A resource (or portion) can be tagged with the most recent draw's
  * token. The target provides a facility for testing whether the draw corresponding to the token
  * has been flushed. If it has not been flushed then the batch must perform an inline upload
  * instead. When scheduling an inline upload the batch provides the token of the draw that the
  * upload must occur before. The upload will then occur between the draw that requires the new
  * data but after the token that requires the old data.
  *
  * TODO: Currently the token/upload interface is spread over GrDrawOp, GrMeshDrawOp,
  * GrDrawOp::Target, and GrMeshDrawOp::Target. However, the interface at the GrDrawOp level is not
  * complete and isn't useful. We should push it down to GrMeshDrawOp until it is required at the
  * GrDrawOp level.
  */

 /**
  * GrDrawOp instances use this object to allocate space for their geometry and to issue the draws
  * that render their batch.
  */
 class GrDrawOp::Target {
 public:
     Target(GrBatchFlushState* state, GrDrawOp* batch) : fState(state), fBatch(batch) {}

     /** Returns the token of the draw that this upload will occur before. */
     GrDrawOpUploadToken addInlineUpload(DeferredUploadFn&& upload) {
         fBatch->fInlineUploads.emplace_back(std::move(upload), fState->nextDrawToken());
         return fBatch->fInlineUploads.back().fUploadBeforeToken;
     }

     /** Returns the token of the draw that this upload will occur before. Since ASAP uploads
         are done first during a flush, this will be the first token since the most recent
         flush. */
     GrDrawOpUploadToken addAsapUpload(DeferredUploadFn&& upload) {
         fState->addASAPUpload(std::move(upload));
         return fState->nextTokenToFlush();
     }

     bool hasDrawBeenFlushed(GrDrawOpUploadToken token) const {
         return fState->hasDrawBeenFlushed(token);
     }

     /** Gets the next draw token that will be issued by this target. This can be used by a batch
         to record that the next draw it issues will use a resource (e.g. texture) while preparing
         that draw. */
     GrDrawOpUploadToken nextDrawToken() const { return fState->nextDrawToken(); }

     const GrCaps& caps() const { return fState->caps(); }

     GrResourceProvider* resourceProvider() const { return fState->resourceProvider(); }

 protected:
     GrDrawOp* batch() { return fBatch; }
     GrBatchFlushState* state() { return fState; }

 private:
     GrBatchFlushState*  fState;
     GrDrawOp*           fBatch;
 };

 /** Extension of GrDrawOp::Target for use by GrMeshDrawOp. Adds the ability to create vertex
     draws. */
 class GrMeshDrawOp::Target : public GrDrawOp::Target {
 public:
     Target(GrBatchFlushState* state, GrMeshDrawOp* batch) : INHERITED(state, batch) {}

     void draw(const GrGeometryProcessor* gp, const GrMesh& mesh);

     void* makeVertexSpace(size_t vertexSize, int vertexCount,
                           const GrBuffer** buffer, int* startVertex) {
         return this->state()->makeVertexSpace(vertexSize, vertexCount, buffer, startVertex);
     }

     uint16_t* makeIndexSpace(int indexCount, const GrBuffer** buffer, int* startIndex) {
         return this->state()->makeIndexSpace(indexCount, buffer, startIndex);
     }

     /** Helpers for batches which over-allocate and then return data to the pool. */
     void putBackIndices(int indices) { this->state()->putBackIndices(indices); }
     void putBackVertices(int vertices, size_t vertexStride) {
         this->state()->putBackVertexSpace(vertices * vertexStride);
     }

 private:
     GrMeshDrawOp* vertexBatch() { return static_cast<GrMeshDrawOp*>(this->batch()); }
     typedef GrDrawOp::Target INHERITED;
 };

 #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 GrBatchBuffer_DEFINED
	#define GrBatchBuffer_DEFINED

	#include "GrBufferAllocPool.h"
	#include "GrGpu.h"
	#include "batches/GrMeshDrawOp.h"

	class GrGpuCommandBuffer;
	class GrResourceProvider;

	/** Tracks the state across all the GrBatches in a GrOpList flush. */
	class GrBatchFlushState {
	public:
	GrBatchFlushState(GrGpu, GrResourceProvider);

	~GrBatchFlushState() { this->reset(); }

	/** Inserts an upload to be executed after all batches in the flush prepared their draws
	but before the draws are executed to the backend 3D API. */
	void addASAPUpload(GrDrawOp::DeferredUploadFn&& upload) {
	fAsapUploads.emplace_back(std::move(upload));
	}

	const GrCaps& caps() const { return *fGpu->caps(); }
	GrResourceProvider* resourceProvider() const { return fResourceProvider; }

	/** Has the token been flushed to the backend 3D API. */
	bool hasDrawBeenFlushed(GrDrawOpUploadToken token) const {
	return token.fSequenceNumber <= fLastFlushedToken.fSequenceNumber;
	}

	/** Issue a token to an operation that is being enqueued. */
	GrDrawOpUploadToken issueDrawToken() {
	return GrDrawOpUploadToken(++fLastIssuedToken.fSequenceNumber);
	}

	/** Call every time a draw that was issued a token is flushed */
	void flushToken() { ++fLastFlushedToken.fSequenceNumber; }

	/** Gets the next draw token that will be issued. */
	GrDrawOpUploadToken nextDrawToken() const {
	return GrDrawOpUploadToken(fLastIssuedToken.fSequenceNumber + 1);
	}

	/** The last token flushed to all the way to the backend API. */
	GrDrawOpUploadToken nextTokenToFlush() const {
	return GrDrawOpUploadToken(fLastFlushedToken.fSequenceNumber + 1);
	}

	void* makeVertexSpace(size_t vertexSize, int vertexCount,
	const GrBuffer** buffer, int* startVertex);
	uint16_t* makeIndexSpace(int indexCount, const GrBuffer** buffer, int* startIndex);

	/** This is called after each batch has a chance to prepare its draws and before the draws
	are issued. */
	void preIssueDraws() {
	fVertexPool.unmap();
	fIndexPool.unmap();
	int uploadCount = fAsapUploads.count();

	for (int i = 0; i < uploadCount; i++) {
	this->doUpload(fAsapUploads[i]);
	}
	fAsapUploads.reset();
	}

	void doUpload(GrDrawOp::DeferredUploadFn& upload) {
	GrDrawOp::WritePixelsFn wp = [this] (GrSurface* surface,
	int left, int top, int width, int height,
	GrPixelConfig config, const void* buffer,
	size_t rowBytes) -> bool {
	return this->fGpu->writePixels(surface, left, top, width, height, config, buffer,
	rowBytes);
	};
	upload(wp);
	}

	void putBackIndices(size_t indices) { fIndexPool.putBack(indices * sizeof(uint16_t)); }

	void putBackVertexSpace(size_t sizeInBytes) { fVertexPool.putBack(sizeInBytes); }

	GrGpuCommandBuffer* commandBuffer() { return fCommandBuffer; }
	void setCommandBuffer(GrGpuCommandBuffer* buffer) { fCommandBuffer = buffer; }

	GrGpu* gpu() { return fGpu; }

	void reset() {
	fVertexPool.reset();
	fIndexPool.reset();
	}

	private:

	GrGpu* fGpu;

	GrResourceProvider* fResourceProvider;

	GrGpuCommandBuffer* fCommandBuffer;

	GrVertexBufferAllocPool fVertexPool;
	GrIndexBufferAllocPool fIndexPool;

	SkSTArray<4, GrDrawOp::DeferredUploadFn> fAsapUploads;

	GrDrawOpUploadToken fLastIssuedToken;

	GrDrawOpUploadToken fLastFlushedToken;
	};

	/**
	* A word about uploads and tokens: Batches should usually schedule their uploads to occur at the
	* begining of a frame whenever possible. These are called ASAP uploads. Of course, this requires
	* that there are no draws that have yet to be flushed that rely on the old texture contents. In
	* that case the ASAP upload would happen prior to the previous draw causing the draw to read the
	* new (wrong) texture data. In that case they should schedule an inline upload.
	*
	* Batches, in conjunction with helpers such as GrBatchAtlas, can use the token system to know
	* what the most recent draw was that referenced a resource (or portion of a resource). Each draw
	* is assigned a token. A resource (or portion) can be tagged with the most recent draw's
	* token. The target provides a facility for testing whether the draw corresponding to the token
	* has been flushed. If it has not been flushed then the batch must perform an inline upload
	* instead. When scheduling an inline upload the batch provides the token of the draw that the
	* upload must occur before. The upload will then occur between the draw that requires the new
	* data but after the token that requires the old data.
	*
	* TODO: Currently the token/upload interface is spread over GrDrawOp, GrMeshDrawOp,
	* GrDrawOp::Target, and GrMeshDrawOp::Target. However, the interface at the GrDrawOp level is not
	* complete and isn't useful. We should push it down to GrMeshDrawOp until it is required at the
	* GrDrawOp level.
	*/

	/**
	* GrDrawOp instances use this object to allocate space for their geometry and to issue the draws
	* that render their batch.
	*/
	class GrDrawOp::Target {
	public:
	Target(GrBatchFlushState* state, GrDrawOp* batch) : fState(state), fBatch(batch) {}

	/** Returns the token of the draw that this upload will occur before. */
	GrDrawOpUploadToken addInlineUpload(DeferredUploadFn&& upload) {
	fBatch->fInlineUploads.emplace_back(std::move(upload), fState->nextDrawToken());
	return fBatch->fInlineUploads.back().fUploadBeforeToken;
	}

	/** Returns the token of the draw that this upload will occur before. Since ASAP uploads
	are done first during a flush, this will be the first token since the most recent
	flush. */
	GrDrawOpUploadToken addAsapUpload(DeferredUploadFn&& upload) {
	fState->addASAPUpload(std::move(upload));
	return fState->nextTokenToFlush();
	}

	bool hasDrawBeenFlushed(GrDrawOpUploadToken token) const {
	return fState->hasDrawBeenFlushed(token);
	}

	/** Gets the next draw token that will be issued by this target. This can be used by a batch
	to record that the next draw it issues will use a resource (e.g. texture) while preparing
	that draw. */
	GrDrawOpUploadToken nextDrawToken() const { return fState->nextDrawToken(); }

	const GrCaps& caps() const { return fState->caps(); }

	GrResourceProvider* resourceProvider() const { return fState->resourceProvider(); }

	protected:
	GrDrawOp* batch() { return fBatch; }
	GrBatchFlushState* state() { return fState; }

	private:
	GrBatchFlushState* fState;
	GrDrawOp* fBatch;
	};

	/** Extension of GrDrawOp::Target for use by GrMeshDrawOp. Adds the ability to create vertex
	draws. */
	class GrMeshDrawOp::Target : public GrDrawOp::Target {
	public:
	Target(GrBatchFlushState* state, GrMeshDrawOp* batch) : INHERITED(state, batch) {}

	void draw(const GrGeometryProcessor* gp, const GrMesh& mesh);

	void* makeVertexSpace(size_t vertexSize, int vertexCount,
	const GrBuffer** buffer, int* startVertex) {
	return this->state()->makeVertexSpace(vertexSize, vertexCount, buffer, startVertex);
	}

	uint16_t* makeIndexSpace(int indexCount, const GrBuffer** buffer, int* startIndex) {
	return this->state()->makeIndexSpace(indexCount, buffer, startIndex);
	}

	/** Helpers for batches which over-allocate and then return data to the pool. */
	void putBackIndices(int indices) { this->state()->putBackIndices(indices); }
	void putBackVertices(int vertices, size_t vertexStride) {
	this->state()->putBackVertexSpace(vertices * vertexStride);
	}

	private:
	GrMeshDrawOp* vertexBatch() { return static_cast<GrMeshDrawOp*>(this->batch()); }
	typedef GrDrawOp::Target INHERITED;
	};

	#endif