/* * Copyright 2010 Google Inc. * * Use of this source code is governed by a BSD-style license that can be * found in the LICENSE file. */ #ifndef GrContext_DEFINED #define GrContext_DEFINED #include "GrConfig.h" #include "GrPaint.h" #include "GrAARectRenderer.h" #include "GrClipData.h" // not strictly needed but requires WK change in LayerTextureUpdaterCanvas to // remove. #include "GrRenderTarget.h" #include "SkClipStack.h" class GrAutoScratchTexture; class GrCacheKey; class GrDrawState; class GrDrawTarget; class GrFontCache; class GrGpu; class GrIndexBuffer; class GrIndexBufferAllocPool; class GrInOrderDrawBuffer; class GrPathRenderer; class GrPathRendererChain; class GrResourceEntry; class GrResourceCache; class GrStencilBuffer; class GrVertexBuffer; class GrVertexBufferAllocPool; class GrSoftwarePathRenderer; class GR_API GrContext : public GrRefCnt { public: SK_DECLARE_INST_COUNT(GrContext) /** * Creates a GrContext from within a 3D context. */ static GrContext* Create(GrEngine engine, GrPlatform3DContext context3D); /** * Returns the number of GrContext instances for the current thread. */ static int GetThreadInstanceCount(); virtual ~GrContext(); /** * The GrContext normally assumes that no outsider is setting state * within the underlying 3D API's context/device/whatever. This call informs * the context that the state was modified and it should resend. Shouldn't * be called frequently for good performance. */ void resetContext(); /** * Callback function to allow classes to cleanup on GrContext destruction. * The 'info' field is filled in with the 'info' passed to addCleanUp. */ typedef void (*PFCleanUpFunc)(const GrContext* context, void* info); /** * Add a function to be called from within GrContext's destructor. * This gives classes a chance to free resources held on a per context basis. * The 'info' parameter will be stored and passed to the callback function. */ void addCleanUp(PFCleanUpFunc cleanUp, void* info) { CleanUpData* entry = fCleanUpData.push(); entry->fFunc = cleanUp; entry->fInfo = info; } /** * Abandons all gpu resources, assumes 3D API state is unknown. Call this * if you have lost the associated GPU context, and thus internal texture, * buffer, etc. references/IDs are now invalid. Should be called even when * GrContext is no longer going to be used for two reasons: * 1) ~GrContext will not try to free the objects in the 3D API. * 2) If you've created GrResources that outlive the GrContext they will * be marked as invalid (GrResource::isValid()) and won't attempt to * free their underlying resource in the 3D API. * Content drawn since the last GrContext::flush() may be lost. */ void contextLost(); /** * Similar to contextLost, but makes no attempt to reset state. * Use this method when GrContext destruction is pending, but * the graphics context is destroyed first. */ void contextDestroyed(); /** * Frees gpu created by the context. Can be called to reduce GPU memory * pressure. */ void freeGpuResources(); /** * Returns the number of bytes of GPU memory hosted by the texture cache. */ size_t getGpuTextureCacheBytes() const; /////////////////////////////////////////////////////////////////////////// // Textures /** * Create a new entry, based on the specified key and texture, and return * a "locked" texture. Must call be balanced with an unlockTexture() call. * * @param params The tex params used to draw a texture may help determine * the cache entry used. (e.g. different versions may exist * for different wrap modes on GPUs with limited NPOT * texture support). NULL implies clamp wrap modes. * @param desc Description of the texture properties. * @param cacheData Cache-specific properties (e.g., texture gen ID) * @param srcData Pointer to the pixel values. * @param rowBytes The number of bytes between rows of the texture. Zero * implies tightly packed rows. */ GrTexture* createTexture(const GrTextureParams* params, const GrTextureDesc& desc, const GrCacheData& cacheData, void* srcData, size_t rowBytes); /** * Look for a texture that matches 'key' in the cache. If not found, * return NULL. */ GrTexture* findTexture(const GrCacheKey& key); /** * Search for an entry based on key and dimensions. If found, * return it. The return value will be NULL if not found. * * @param desc Description of the texture properties. * @param cacheData Cache-specific properties (e.g., texture gen ID) * @param params The tex params used to draw a texture may help determine * the cache entry used. (e.g. different versions may exist * for different wrap modes on GPUs with limited NPOT * texture support). NULL implies clamp wrap modes. */ GrTexture* findTexture(const GrTextureDesc& desc, const GrCacheData& cacheData, const GrTextureParams* params); /** * Determines whether a texture is in the cache. If the texture is found it * will not be locked or returned. This call does not affect the priority of * the texture for deletion. */ bool isTextureInCache(const GrTextureDesc& desc, const GrCacheData& cacheData, const GrTextureParams* params) const; /** * Enum that determines how closely a returned scratch texture must match * a provided GrTextureDesc. */ enum ScratchTexMatch { /** * Finds a texture that exactly matches the descriptor. */ kExact_ScratchTexMatch, /** * Finds a texture that approximately matches the descriptor. Will be * at least as large in width and height as desc specifies. If desc * specifies that texture is a render target then result will be a * render target. If desc specifies a render target and doesn't set the * no stencil flag then result will have a stencil. Format and aa level * will always match. */ kApprox_ScratchTexMatch }; /** * Returns a texture matching the desc. It's contents are unknown. Subsequent * requests with the same descriptor are not guaranteed to return the same * texture. The same texture is guaranteed not be returned again until it is * unlocked. Call must be balanced with an unlockTexture() call. * * Textures created by createAndLockTexture() hide the complications of * tiling non-power-of-two textures on APIs that don't support this (e.g. * unextended GLES2). Tiling a npot texture created by lockScratchTexture on * such an API will create gaps in the tiling pattern. This includes clamp * mode. (This may be addressed in a future update.) */ GrTexture* lockScratchTexture(const GrTextureDesc& desc, ScratchTexMatch match); /** * When done with an entry, call unlockTexture(entry) on it, which returns * it to the cache, where it may be purged. */ void unlockScratchTexture(GrTexture* texture); /** * This method should be called whenever a GrTexture is unreffed or * switched from exclusive to non-exclusive. This * gives the resource cache a chance to discard unneeded textures. * Note: this entry point will be removed once totally ref-driven * cache maintenance is implemented */ void purgeCache(); /** * Creates a texture that is outside the cache. Does not count against * cache's budget. */ GrTexture* createUncachedTexture(const GrTextureDesc& desc, void* srcData, size_t rowBytes); /** * Returns true if the specified use of an indexed texture is supported. * Support may depend upon whether the texture params indicate that the * texture will be tiled. Passing NULL for the texture params indicates * clamp mode. */ bool supportsIndex8PixelConfig(const GrTextureParams*, int width, int height) const; /** * Return the current texture cache limits. * * @param maxTextures If non-null, returns maximum number of textures that * can be held in the cache. * @param maxTextureBytes If non-null, returns maximum number of bytes of * texture memory that can be held in the cache. */ void getTextureCacheLimits(int* maxTextures, size_t* maxTextureBytes) const; /** * Specify the texture cache limits. If the current cache exceeds either * of these, it will be purged (LRU) to keep the cache within these limits. * * @param maxTextures The maximum number of textures that can be held in * the cache. * @param maxTextureBytes The maximum number of bytes of texture memory * that can be held in the cache. */ void setTextureCacheLimits(int maxTextures, size_t maxTextureBytes); /** * Return the max width or height of a texture supported by the current gpu */ int getMaxTextureSize() const; /** * Return the max width or height of a render target supported by the * current gpu */ int getMaxRenderTargetSize() const; /////////////////////////////////////////////////////////////////////////// // Render targets /** * Sets the render target. * @param target the render target to set. (should not be NULL.) */ void setRenderTarget(GrRenderTarget* target); /** * Gets the current render target. * @return the currently bound render target. Should never be NULL. */ const GrRenderTarget* getRenderTarget() const; GrRenderTarget* getRenderTarget(); GrAARectRenderer* getAARectRenderer() { return fAARectRenderer; } /** * Can the provided configuration act as a color render target? */ bool isConfigRenderable(GrPixelConfig config) const; /////////////////////////////////////////////////////////////////////////// // Platform Surfaces /** * Wraps an existing texture with a GrTexture object. * * OpenGL: if the object is a texture Gr may change its GL texture params * when it is drawn. * * @param desc description of the object to create. * * @return GrTexture object or NULL on failure. */ GrTexture* createPlatformTexture(const GrPlatformTextureDesc& desc); /** * Wraps an existing render target with a GrRenderTarget object. It is * similar to createPlatformTexture but can be used to draw into surfaces * that are not also textures (e.g. FBO 0 in OpenGL, or an MSAA buffer that * the client will resolve to a texture). * * @param desc description of the object to create. * * @return GrTexture object or NULL on failure. */ GrRenderTarget* createPlatformRenderTarget( const GrPlatformRenderTargetDesc& desc); /////////////////////////////////////////////////////////////////////////// // Matrix state /** * Gets the current transformation matrix. * @return the current matrix. */ const GrMatrix& getMatrix() const; /** * Sets the transformation matrix. * @param m the matrix to set. */ void setMatrix(const GrMatrix& m); /** * Concats the current matrix. The passed matrix is applied before the * current matrix. * @param m the matrix to concat. */ void concatMatrix(const GrMatrix& m) const; /////////////////////////////////////////////////////////////////////////// // Clip state /** * Gets the current clip. * @return the current clip. */ const GrClipData* getClip() const; /** * Sets the clip. * @param clipData the clip to set. */ void setClip(const GrClipData* clipData); /////////////////////////////////////////////////////////////////////////// // Draws /** * Clear the entire or rect of the render target, ignoring any clips. * @param rect the rect to clear or the whole thing if rect is NULL. * @param color the color to clear to. * @param target if non-NULL, the render target to clear otherwise clear * the current render target */ void clear(const GrIRect* rect, GrColor color, GrRenderTarget* target = NULL); /** * Draw everywhere (respecting the clip) with the paint. */ void drawPaint(const GrPaint& paint); /** * Draw the rect using a paint. * @param paint describes how to color pixels. * @param strokeWidth If strokeWidth < 0, then the rect is filled, else * the rect is mitered stroked based on strokeWidth. If * strokeWidth == 0, then the stroke is always a single * pixel thick. * @param matrix Optional matrix applied to the rect. Applied before * context's matrix or the paint's matrix. * The rects coords are used to access the paint (through texture matrix) */ void drawRect(const GrPaint& paint, const GrRect&, GrScalar strokeWidth = -1, const GrMatrix* matrix = NULL); /** * Maps a rect of paint coordinates onto the a rect of destination * coordinates. Each rect can optionally be transformed. The srcRect * is stretched over the dstRect. The dstRect is transformed by the * context's matrix and the srcRect is transformed by the paint's matrix. * Additional optional matrices can be provided by parameters. * * @param paint describes how to color pixels. * @param dstRect the destination rect to draw. * @param srcRect rect of paint coordinates to be mapped onto dstRect * @param dstMatrix Optional matrix to transform dstRect. Applied before * context's matrix. * @param srcMatrix Optional matrix to transform srcRect Applied before * paint's matrix. */ void drawRectToRect(const GrPaint& paint, const GrRect& dstRect, const GrRect& srcRect, const GrMatrix* dstMatrix = NULL, const GrMatrix* srcMatrix = NULL); /** * Draws a path. * * @param paint describes how to color pixels. * @param path the path to draw * @param fill the path filling rule to use. * @param translate optional additional translation applied to the * path. */ void drawPath(const GrPaint& paint, const SkPath& path, GrPathFill fill, const GrPoint* translate = NULL); /** * Draws vertices with a paint. * * @param paint describes how to color pixels. * @param primitiveType primitives type to draw. * @param vertexCount number of vertices. * @param positions array of vertex positions, required. * @param texCoords optional array of texture coordinates used * to access the paint. * @param colors optional array of per-vertex colors, supercedes * the paint's color field. * @param indices optional array of indices. If NULL vertices * are drawn non-indexed. * @param indexCount if indices is non-null then this is the * number of indices. */ void drawVertices(const GrPaint& paint, GrPrimitiveType primitiveType, int vertexCount, const GrPoint positions[], const GrPoint texs[], const GrColor colors[], const uint16_t indices[], int indexCount); /** * Draws an oval. * * @param paint describes how to color pixels. * @param rect the bounding rect of the oval. * @param strokeWidth if strokeWidth < 0, then the oval is filled, else * the rect is stroked based on strokeWidth. If * strokeWidth == 0, then the stroke is always a single * pixel thick. */ void drawOval(const GrPaint& paint, const GrRect& rect, SkScalar strokeWidth); /////////////////////////////////////////////////////////////////////////// // Misc. /** * Flags that affect flush() behavior. */ enum FlushBits { /** * A client may want Gr to bind a GrRenderTarget in the 3D API so that * it can be rendered to directly. However, Gr lazily sets state. Simply * calling setRenderTarget() followed by flush() without flags may not * bind the render target. This flag forces the context to bind the last * set render target in the 3D API. */ kForceCurrentRenderTarget_FlushBit = 0x1, /** * A client may reach a point where it has partially rendered a frame * through a GrContext that it knows the user will never see. This flag * causes the flush to skip submission of deferred content to the 3D API * during the flush. */ kDiscard_FlushBit = 0x2, }; /** * Call to ensure all drawing to the context has been issued to the * underlying 3D API. * @param flagsBitfield flags that control the flushing behavior. See * FlushBits. */ void flush(int flagsBitfield = 0); /** * These flags can be used with the read/write pixels functions below. */ enum PixelOpsFlags { /** The GrContext will not be flushed. This means that the read or write may occur before previous draws have executed. */ kDontFlush_PixelOpsFlag = 0x1, /** The src for write or dst read is unpremultiplied. This is only respected if both the config src and dst configs are an RGBA/BGRA 8888 format. */ kUnpremul_PixelOpsFlag = 0x2, }; /** * Reads a rectangle of pixels from a render target. * @param target the render target to read from. NULL means the current render target. * @param left left edge of the rectangle to read (inclusive) * @param top top edge of the rectangle to read (inclusive) * @param width width of rectangle to read in pixels. * @param height height of rectangle to read in pixels. * @param config the pixel config of the destination buffer * @param buffer memory to read the rectangle into. * @param rowBytes number of bytes bewtween consecutive rows. Zero means rows are tightly * packed. * @param pixelOpsFlags see PixelOpsFlags enum above. * * @return true if the read succeeded, false if not. The read can fail because of an unsupported * pixel config or because no render target is currently set and NULL was passed for * target. */ bool readRenderTargetPixels(GrRenderTarget* target, int left, int top, int width, int height, GrPixelConfig config, void* buffer, size_t rowBytes = 0, uint32_t pixelOpsFlags = 0); /** * Copy the src pixels [buffer, rowbytes, pixelconfig] into a render target at the specified * rectangle. * @param target the render target to write into. NULL means the current render target. * @param left left edge of the rectangle to write (inclusive) * @param top top edge of the rectangle to write (inclusive) * @param width width of rectangle to write in pixels. * @param height height of rectangle to write in pixels. * @param config the pixel config of the source buffer * @param buffer memory to read the rectangle from. * @param rowBytes number of bytes bewtween consecutive rows. Zero means rows are tightly * packed. * @param pixelOpsFlags see PixelOpsFlags enum above. */ void writeRenderTargetPixels(GrRenderTarget* target, int left, int top, int width, int height, GrPixelConfig config, const void* buffer, size_t rowBytes = 0, uint32_t pixelOpsFlags = 0); /** * Reads a rectangle of pixels from a texture. * @param texture the texture to read from. * @param left left edge of the rectangle to read (inclusive) * @param top top edge of the rectangle to read (inclusive) * @param width width of rectangle to read in pixels. * @param height height of rectangle to read in pixels. * @param config the pixel config of the destination buffer * @param buffer memory to read the rectangle into. * @param rowBytes number of bytes bewtween consecutive rows. Zero means rows are tightly * packed. * @param pixelOpsFlags see PixelOpsFlags enum above. * * @return true if the read succeeded, false if not. The read can fail because of an unsupported * pixel config. */ bool readTexturePixels(GrTexture* texture, int left, int top, int width, int height, GrPixelConfig config, void* buffer, size_t rowBytes = 0, uint32_t pixelOpsFlags = 0); /** * Writes a rectangle of pixels to a texture. * @param texture the render target to read from. * @param left left edge of the rectangle to write (inclusive) * @param top top edge of the rectangle to write (inclusive) * @param width width of rectangle to write in pixels. * @param height height of rectangle to write in pixels. * @param config the pixel config of the source buffer * @param buffer memory to read pixels from * @param rowBytes number of bytes bewtween consecutive rows. Zero * means rows are tightly packed. * @param pixelOpsFlags see PixelOpsFlags enum above. */ void writeTexturePixels(GrTexture* texture, int left, int top, int width, int height, GrPixelConfig config, const void* buffer, size_t rowBytes, uint32_t pixelOpsFlags = 0); /** * Copies all texels from one texture to another. * @param src the texture to copy from. * @param dst the render target to copy to. */ void copyTexture(GrTexture* src, GrRenderTarget* dst); /** * Resolves a render target that has MSAA. The intermediate MSAA buffer is * downsampled to the associated GrTexture (accessible via * GrRenderTarget::asTexture()). Any pending draws to the render target will * be executed before the resolve. * * This is only necessary when a client wants to access the object directly * using the underlying graphics API. GrContext will detect when it must * perform a resolve to a GrTexture used as the source of a draw or before * reading pixels back from a GrTexture or GrRenderTarget. */ void resolveRenderTarget(GrRenderTarget* target); /** * Applies a 2D Gaussian blur to a given texture. * @param srcTexture The source texture to be blurred. * @param canClobberSrc If true, srcTexture may be overwritten, and * may be returned as the result. * @param rect The destination rectangle. * @param sigmaX The blur's standard deviation in X. * @param sigmaY The blur's standard deviation in Y. * @return the blurred texture, which may be srcTexture ref'ed, or a * new texture. It is the caller's responsibility to unref this texture. */ GrTexture* gaussianBlur(GrTexture* srcTexture, bool canClobberSrc, const SkRect& rect, float sigmaX, float sigmaY); /** * Zooms a subset of the texture to a larger size with a nice edge. * The inner rectangle is a simple scaling of the texture by a factor of * |zoom|. The outer |inset| pixels transition from the background texture * to the zoomed coordinate system at a rate of * (distance_to_edge / inset) ^2, producing a rounded lens effect. * @param srcTexture The source texture to be zoomed. * @param dstRect The destination rectangle. * @param srcRect The source rectangle. Must be smaller than * dstRect * @param inset Number of pixels to blend along the edges. * @return the zoomed texture, which is dstTexture. */ GrTexture* zoom(GrTexture* srcTexture, const SkRect& dstRect, const SkRect& srcRect, float inset); /////////////////////////////////////////////////////////////////////////// // Helpers class AutoRenderTarget : public ::GrNoncopyable { public: AutoRenderTarget(GrContext* context, GrRenderTarget* target) { fPrevTarget = context->getRenderTarget(); GrSafeRef(fPrevTarget); context->setRenderTarget(target); fContext = context; } AutoRenderTarget(GrContext* context) { fPrevTarget = context->getRenderTarget(); GrSafeRef(fPrevTarget); fContext = context; } ~AutoRenderTarget() { if (NULL != fContext) { fContext->setRenderTarget(fPrevTarget); } GrSafeUnref(fPrevTarget); } private: GrContext* fContext; GrRenderTarget* fPrevTarget; }; /** * Save/restore the view-matrix in the context. */ class AutoMatrix : GrNoncopyable { public: enum InitialMatrix { kPreserve_InitialMatrix, kIdentity_InitialMatrix, }; AutoMatrix() : fContext(NULL) {} AutoMatrix(GrContext* ctx, InitialMatrix initialState) : fContext(ctx) { fMatrix = ctx->getMatrix(); switch (initialState) { case kPreserve_InitialMatrix: break; case kIdentity_InitialMatrix: ctx->setMatrix(GrMatrix::I()); break; default: GrCrash("Unexpected initial matrix state"); } } AutoMatrix(GrContext* ctx, const GrMatrix& matrix) : fContext(ctx) { fMatrix = ctx->getMatrix(); ctx->setMatrix(matrix); } void set(GrContext* ctx) { if (NULL != fContext) { fContext->setMatrix(fMatrix); } fMatrix = ctx->getMatrix(); fContext = ctx; } void set(GrContext* ctx, const GrMatrix& matrix) { if (NULL != fContext) { fContext->setMatrix(fMatrix); } fMatrix = ctx->getMatrix(); ctx->setMatrix(matrix); fContext = ctx; } ~AutoMatrix() { if (NULL != fContext) { fContext->setMatrix(fMatrix); } } private: GrContext* fContext; GrMatrix fMatrix; }; class AutoClip : GrNoncopyable { public: // This enum exists to require a caller of the constructor to acknowledge that the clip will // initially be wide open. It also could be extended if there are other desirable initial // clip states. enum InitialClip { kWideOpen_InitialClip, }; AutoClip(GrContext* context, InitialClip initialState) : fContext(context) { GrAssert(kWideOpen_InitialClip == initialState); fNewClipData.fClipStack = &fNewClipStack; fOldClip = context->getClip(); context->setClip(&fNewClipData); } AutoClip(GrContext* context, const GrRect& newClipRect) : fContext(context) , fNewClipStack(newClipRect) { fNewClipData.fClipStack = &fNewClipStack; fOldClip = fContext->getClip(); fContext->setClip(&fNewClipData); } ~AutoClip() { if (NULL != fContext) { fContext->setClip(fOldClip); } } private: GrContext* fContext; const GrClipData* fOldClip; SkClipStack fNewClipStack; GrClipData fNewClipData; }; class AutoWideOpenIdentityDraw { public: AutoWideOpenIdentityDraw(GrContext* ctx, GrRenderTarget* rt) : fAutoClip(ctx, AutoClip::kWideOpen_InitialClip) , fAutoRT(ctx, rt) , fAutoMatrix(ctx, AutoMatrix::kIdentity_InitialMatrix) { } private: AutoClip fAutoClip; AutoRenderTarget fAutoRT; AutoMatrix fAutoMatrix; }; /////////////////////////////////////////////////////////////////////////// // Functions intended for internal use only. GrGpu* getGpu() { return fGpu; } const GrGpu* getGpu() const { return fGpu; } GrFontCache* getFontCache() { return fFontCache; } GrDrawTarget* getTextTarget(const GrPaint& paint); const GrIndexBuffer* getQuadIndexBuffer() const; /** * Stencil buffers add themselves to the cache using * addStencilBuffer. findStencilBuffer is called to check the * cache for a SB that matches an RT's criteria. */ void addStencilBuffer(GrStencilBuffer* sb); GrStencilBuffer* findStencilBuffer(int width, int height, int sampleCnt); GrPathRenderer* getPathRenderer(const SkPath& path, GrPathFill fill, const GrDrawTarget* target, bool antiAlias, bool allowSW); #if GR_CACHE_STATS void printCacheStats() const; #endif private: // Used to indicate whether a draw should be performed immediately or queued in fDrawBuffer. enum BufferedDraw { kYes_BufferedDraw, kNo_BufferedDraw, }; BufferedDraw fLastDrawWasBuffered; GrGpu* fGpu; GrDrawState* fDrawState; GrResourceCache* fTextureCache; GrFontCache* fFontCache; GrPathRendererChain* fPathRendererChain; GrSoftwarePathRenderer* fSoftwarePathRenderer; GrVertexBufferAllocPool* fDrawBufferVBAllocPool; GrIndexBufferAllocPool* fDrawBufferIBAllocPool; GrInOrderDrawBuffer* fDrawBuffer; GrAARectRenderer* fAARectRenderer; bool fDidTestPMConversions; int fPMToUPMConversion; int fUPMToPMConversion; struct CleanUpData { PFCleanUpFunc fFunc; void* fInfo; }; SkTDArray fCleanUpData; GrContext(GrGpu* gpu); void setupDrawBuffer(); void flushDrawBuffer(); void setPaint(const GrPaint& paint); /// Sets the paint and returns the target to draw into. The paint can be NULL in which case the /// draw state is left unmodified. GrDrawTarget* prepareToDraw(const GrPaint*, BufferedDraw); void internalDrawPath(const GrPaint& paint, const SkPath& path, GrPathFill fill, const GrPoint* translate); GrTexture* createResizedTexture(const GrTextureDesc& desc, const GrCacheData& cacheData, void* srcData, size_t rowBytes, bool needsFiltering); // Needed so GrTexture's returnToCache helper function can call // addExistingTextureToCache friend class GrTexture; // Add an existing texture to the texture cache. This is intended solely // for use with textures released from an GrAutoScratchTexture. void addExistingTextureToCache(GrTexture* texture); GrCustomStage* createPMToUPMEffect(GrTexture* texture, bool swapRAndB); GrCustomStage* createUPMToPMEffect(GrTexture* texture, bool swapRAndB); typedef GrRefCnt INHERITED; }; /** * Gets and locks a scratch texture from a descriptor using * either exact or approximate criteria. Unlocks texture in * the destructor. */ class GrAutoScratchTexture : ::GrNoncopyable { public: GrAutoScratchTexture() : fContext(NULL) , fTexture(NULL) { } GrAutoScratchTexture(GrContext* context, const GrTextureDesc& desc, GrContext::ScratchTexMatch match = GrContext::kApprox_ScratchTexMatch) : fContext(NULL) , fTexture(NULL) { this->set(context, desc, match); } ~GrAutoScratchTexture() { this->reset(); } void reset() { if (NULL != fContext && NULL != fTexture) { fContext->unlockScratchTexture(fTexture); fTexture = NULL; } } /* * When detaching a texture we do not unlock it in the texture cache but * we do set the returnToCache flag. In this way the texture remains * "locked" in the texture cache until it is freed and recycled in * GrTexture::internal_dispose. In reality, the texture has been removed * from the cache (because this is in AutoScratchTexture) and by not * calling unlockTexture we simply don't re-add it. It will be reattached * in GrTexture::internal_dispose. * * Note that the caller is assumed to accept and manage the ref to the * returned texture. */ GrTexture* detach() { GrTexture* temp = fTexture; // Conceptually the texture's cache entry loses its ref to the // texture while the caller of this method gets a ref. GrAssert(NULL != temp->getCacheEntry()); fTexture = NULL; temp->setFlag((GrTextureFlags) GrTexture::kReturnToCache_FlagBit); return temp; } GrTexture* set(GrContext* context, const GrTextureDesc& desc, GrContext::ScratchTexMatch match = GrContext::kApprox_ScratchTexMatch) { this->reset(); fContext = context; if (NULL != fContext) { fTexture = fContext->lockScratchTexture(desc, match); if (NULL == fTexture) { fContext = NULL; } return fTexture; } else { return NULL; } } GrTexture* texture() { return fTexture; } private: GrContext* fContext; GrTexture* fTexture; }; #endif