src/utils/SkCanvasStateUtils.cpp - platform/external/skqp - Gitiles

 /*
  * Copyright 2013 Google Inc.
  *
  * Use of this source code is governed by a BSD-style license that can be
  * found in the LICENSE file.
  */

 #include "SkCanvasStateUtils.h"

 #include "SkCanvas.h"
 #include "SkCanvasStack.h"
 #include "SkDevice.h"
 #include "SkRasterClip.h"
 #include "SkWriter32.h"

 /*
  * WARNING: The structs below are part of a stable ABI and as such we explicitly
  * use unambigious primitives (e.g. int32_t instead of an enum).
  *
  * ANY CHANGES TO THE STRUCTS BELOW THAT IMPACT THE ABI SHOULD RESULT IN A NEW
  * NEW SUBCLASS OF SkCanvasState. SUCH CHANGES SHOULD ONLY BE MADE IF ABSOLUTELY
  * NECESSARY!
  *
  * In order to test changes, run the CanvasState tests. gyp/canvas_state_lib.gyp
  * describes how to create a library to pass to the CanvasState tests. The tests
  * should succeed when building the library with your changes and passing that to
  * the tests running in the unchanged Skia.
  */
 enum RasterConfigs {
   kUnknown_RasterConfig   = 0,
   kRGB_565_RasterConfig   = 1,
   kARGB_8888_RasterConfig = 2
 };
 typedef int32_t RasterConfig;

 enum CanvasBackends {
     kUnknown_CanvasBackend = 0,
     kRaster_CanvasBackend  = 1,
     kGPU_CanvasBackend     = 2,
     kPDF_CanvasBackend     = 3
 };
 typedef int32_t CanvasBackend;

 struct ClipRect {
     int32_t left, top, right, bottom;
 };

 struct SkMCState {
     float matrix[9];
     // NOTE: this only works for non-antialiased clips
     int32_t clipRectCount;
     ClipRect* clipRects;
 };

 // NOTE: If you add more members, create a new subclass of SkCanvasState with a
 // new CanvasState::version.
 struct SkCanvasLayerState {
     CanvasBackend type;
     int32_t x, y;
     int32_t width;
     int32_t height;

     SkMCState mcState;

     union {
         struct {
             RasterConfig config; // pixel format: a value from RasterConfigs.
             uint64_t rowBytes;   // Number of bytes from start of one line to next.
             void* pixels;        // The pixels, all (height * rowBytes) of them.
         } raster;
         struct {
             int32_t textureID;
         } gpu;
     };
 };

 class SkCanvasState {
 public:
     SkCanvasState(int32_t version, SkCanvas* canvas) {
         SkASSERT(canvas);
         this->version = version;
         width = canvas->getBaseLayerSize().width();
         height = canvas->getBaseLayerSize().height();

     }

     /**
      * The version this struct was built with.  This field must always appear
      * first in the struct so that when the versions don't match (and the
      * remaining contents and size are potentially different) we can still
      * compare the version numbers.
      */
     int32_t version;
     int32_t width;
     int32_t height;
     int32_t alignmentPadding;
 };

 class SkCanvasState_v1 : public SkCanvasState {
 public:
     static const int32_t kVersion = 1;

     SkCanvasState_v1(SkCanvas* canvas)
     : INHERITED(kVersion, canvas)
     {
         layerCount = 0;
         layers = nullptr;
         mcState.clipRectCount = 0;
         mcState.clipRects = nullptr;
         originalCanvas = SkRef(canvas);
     }

     ~SkCanvasState_v1() {
         // loop through the layers and free the data allocated to the clipRects
         for (int i = 0; i < layerCount; ++i) {
             sk_free(layers[i].mcState.clipRects);
         }

         sk_free(mcState.clipRects);
         sk_free(layers);

         // it is now safe to free the canvas since there should be no remaining
         // references to the content that is referenced by this canvas (e.g. pixels)
         originalCanvas->unref();
     }

     SkMCState mcState;

     int32_t layerCount;
     SkCanvasLayerState* layers;
 private:
     SkCanvas* originalCanvas;
     typedef SkCanvasState INHERITED;
 };

 ////////////////////////////////////////////////////////////////////////////////

 class ClipValidator : public SkCanvas::ClipVisitor {
 public:
     ClipValidator() : fFailed(false) {}
     bool failed() { return fFailed; }

     // ClipVisitor
     void clipRect(const SkRect& rect, SkCanvas::ClipOp op, bool antialias) override {
         fFailed |= antialias;
     }

     void clipRRect(const SkRRect& rrect, SkCanvas::ClipOp op, bool antialias) override {
         fFailed |= antialias;
     }

     void clipPath(const SkPath&, SkCanvas::ClipOp, bool antialias) override {
         fFailed |= antialias;
     }

 private:
     bool fFailed;
 };

 static void setup_MC_state(SkMCState* state, const SkMatrix& matrix, const SkRegion& clip) {
     // initialize the struct
     state->clipRectCount = 0;

     // capture the matrix
     for (int i = 0; i < 9; i++) {
         state->matrix[i] = matrix.get(i);
     }

     /*
      * capture the clip
      *
      * storage is allocated on the stack for the first 4 rects. This value was
      * chosen somewhat arbitrarily, but does allow us to represent simple clips
      * and some more common complex clips (e.g. a clipRect with a sub-rect
      * clipped out of its interior) without needing to malloc any additional memory.
      */
     SkSWriter32<4*sizeof(ClipRect)> clipWriter;

     if (!clip.isEmpty()) {
         // only returns the b/w clip so aa clips fail
         SkRegion::Iterator clip_iterator(clip);
         for (; !clip_iterator.done(); clip_iterator.next()) {
             // this assumes the SkIRect is stored in l,t,r,b ordering which
             // matches the ordering of our ClipRect struct
             clipWriter.writeIRect(clip_iterator.rect());
             state->clipRectCount++;
         }
     }

     // allocate memory for the clip then and copy them to the struct
     state->clipRects = (ClipRect*) sk_malloc_throw(clipWriter.bytesWritten());
     clipWriter.flatten(state->clipRects);
 }


 SkCanvasState* SkCanvasStateUtils::CaptureCanvasState(SkCanvas* canvas) {
     SkASSERT(canvas);

     // Check the clip can be decomposed into rectangles (i.e. no soft clips).
     ClipValidator validator;
     canvas->replayClips(&validator);
     if (validator.failed()) {
         return nullptr;
     }

     SkAutoTDelete<SkCanvasState_v1> canvasState(new SkCanvasState_v1(canvas));

     // decompose the total matrix and clip
     setup_MC_state(&canvasState->mcState, canvas->getTotalMatrix(),
                    canvas->internal_private_getTotalClip());

     /*
      * decompose the layers
      *
      * storage is allocated on the stack for the first 3 layers. It is common in
      * some view systems (e.g. Android) that a few non-clipped layers are present
      * and we will not need to malloc any additional memory in those cases.
      */
     SkSWriter32<3*sizeof(SkCanvasLayerState)> layerWriter;
     int layerCount = 0;
     for (SkCanvas::LayerIter layer(canvas); !layer.done(); layer.next()) {

         // we currently only work for bitmap backed devices
         SkPixmap pmap;
         if (!layer.device()->accessPixels(&pmap) || 0 == pmap.width() || 0 == pmap.height()) {
             return nullptr;
         }

         SkCanvasLayerState* layerState =
                 (SkCanvasLayerState*) layerWriter.reserve(sizeof(SkCanvasLayerState));
         layerState->type = kRaster_CanvasBackend;
         layerState->x = layer.x();
         layerState->y = layer.y();
         layerState->width = pmap.width();
         layerState->height = pmap.height();

         switch (pmap.colorType()) {
             case kN32_SkColorType:
                 layerState->raster.config = kARGB_8888_RasterConfig;
                 break;
             case kRGB_565_SkColorType:
                 layerState->raster.config = kRGB_565_RasterConfig;
                 break;
             default:
                 return nullptr;
         }
         layerState->raster.rowBytes = pmap.rowBytes();
         layerState->raster.pixels = pmap.writable_addr();

         setup_MC_state(&layerState->mcState, layer.matrix(), layer.clip().bwRgn());
         layerCount++;
     }

     // allocate memory for the layers and then and copy them to the struct
     SkASSERT(layerWriter.bytesWritten() == layerCount * sizeof(SkCanvasLayerState));
     canvasState->layerCount = layerCount;
     canvasState->layers = (SkCanvasLayerState*) sk_malloc_throw(layerWriter.bytesWritten());
     layerWriter.flatten(canvasState->layers);

     return canvasState.release();
 }

 ////////////////////////////////////////////////////////////////////////////////

 static void setup_canvas_from_MC_state(const SkMCState& state, SkCanvas* canvas) {
     // reconstruct the matrix
     SkMatrix matrix;
     for (int i = 0; i < 9; i++) {
         matrix.set(i, state.matrix[i]);
     }

     // reconstruct the clip
     SkRegion clip;
     for (int i = 0; i < state.clipRectCount; ++i) {
         clip.op(SkIRect::MakeLTRB(state.clipRects[i].left,
                                   state.clipRects[i].top,
                                   state.clipRects[i].right,
                                   state.clipRects[i].bottom),
                 SkRegion::kUnion_Op);
     }

     canvas->setMatrix(matrix);
     canvas->clipRegion(clip, SkCanvas::kReplace_Op);
 }

 static SkCanvas* create_canvas_from_canvas_layer(const SkCanvasLayerState& layerState) {
     SkASSERT(kRaster_CanvasBackend == layerState.type);

     SkBitmap bitmap;
     SkColorType colorType =
         layerState.raster.config == kARGB_8888_RasterConfig ? kN32_SkColorType :
         layerState.raster.config == kRGB_565_RasterConfig ? kRGB_565_SkColorType :
         kUnknown_SkColorType;

     if (colorType == kUnknown_SkColorType) {
         return nullptr;
     }

     bitmap.installPixels(SkImageInfo::Make(layerState.width, layerState.height,
                                            colorType, kPremul_SkAlphaType),
                          layerState.raster.pixels, (size_t) layerState.raster.rowBytes);

     SkASSERT(!bitmap.empty());
     SkASSERT(!bitmap.isNull());

     SkAutoTUnref<SkCanvas> canvas(new SkCanvas(bitmap));

     // setup the matrix and clip
     setup_canvas_from_MC_state(layerState.mcState, canvas.get());

     return canvas.release();
 }

 SkCanvas* SkCanvasStateUtils::CreateFromCanvasState(const SkCanvasState* state) {
     SkASSERT(state);
     // Currently there is only one possible version.
     SkASSERT(SkCanvasState_v1::kVersion == state->version);

     const SkCanvasState_v1* state_v1 = static_cast<const SkCanvasState_v1*>(state);

     if (state_v1->layerCount < 1) {
         return nullptr;
     }

     SkAutoTUnref<SkCanvasStack> canvas(new SkCanvasStack(state->width, state->height));

     // setup the matrix and clip on the n-way canvas
     setup_canvas_from_MC_state(state_v1->mcState, canvas);

     // Iterate over the layers and add them to the n-way canvas
     for (int i = state_v1->layerCount - 1; i >= 0; --i) {
         SkAutoTUnref<SkCanvas> canvasLayer(create_canvas_from_canvas_layer(state_v1->layers[i]));
         if (!canvasLayer.get()) {
             return nullptr;
         }
         canvas->pushCanvas(canvasLayer.get(), SkIPoint::Make(state_v1->layers[i].x,
                                                              state_v1->layers[i].y));
     }

     return canvas.release();
 }

 ////////////////////////////////////////////////////////////////////////////////

 void SkCanvasStateUtils::ReleaseCanvasState(SkCanvasState* state) {
     SkASSERT(!state || SkCanvasState_v1::kVersion == state->version);
     // Upcast to the correct version of SkCanvasState. This avoids having a virtual destructor on
     // SkCanvasState. That would be strange since SkCanvasState has no other virtual functions, and
     // instead uses the field "version" to determine how to behave.
     delete static_cast<SkCanvasState_v1*>(state);
 }
	/*
	* Copyright 2013 Google Inc.
	*
	* Use of this source code is governed by a BSD-style license that can be
	* found in the LICENSE file.
	*/

	#include "SkCanvasStateUtils.h"

	#include "SkCanvas.h"
	#include "SkCanvasStack.h"
	#include "SkDevice.h"
	#include "SkRasterClip.h"
	#include "SkWriter32.h"

	/*
	* WARNING: The structs below are part of a stable ABI and as such we explicitly
	* use unambigious primitives (e.g. int32_t instead of an enum).
	*
	* ANY CHANGES TO THE STRUCTS BELOW THAT IMPACT THE ABI SHOULD RESULT IN A NEW
	* NEW SUBCLASS OF SkCanvasState. SUCH CHANGES SHOULD ONLY BE MADE IF ABSOLUTELY
	* NECESSARY!
	*
	* In order to test changes, run the CanvasState tests. gyp/canvas_state_lib.gyp
	* describes how to create a library to pass to the CanvasState tests. The tests
	* should succeed when building the library with your changes and passing that to
	* the tests running in the unchanged Skia.
	*/
	enum RasterConfigs {
	kUnknown_RasterConfig = 0,
	kRGB_565_RasterConfig = 1,
	kARGB_8888_RasterConfig = 2
	};
	typedef int32_t RasterConfig;

	enum CanvasBackends {
	kUnknown_CanvasBackend = 0,
	kRaster_CanvasBackend = 1,
	kGPU_CanvasBackend = 2,
	kPDF_CanvasBackend = 3
	};
	typedef int32_t CanvasBackend;

	struct ClipRect {
	int32_t left, top, right, bottom;
	};

	struct SkMCState {
	float matrix[9];
	// NOTE: this only works for non-antialiased clips
	int32_t clipRectCount;
	ClipRect* clipRects;
	};

	// NOTE: If you add more members, create a new subclass of SkCanvasState with a
	// new CanvasState::version.
	struct SkCanvasLayerState {
	CanvasBackend type;
	int32_t x, y;
	int32_t width;
	int32_t height;

	SkMCState mcState;

	union {
	struct {
	RasterConfig config; // pixel format: a value from RasterConfigs.
	uint64_t rowBytes; // Number of bytes from start of one line to next.
	void* pixels; // The pixels, all (height * rowBytes) of them.
	} raster;
	struct {
	int32_t textureID;
	} gpu;
	};
	};

	class SkCanvasState {
	public:
	SkCanvasState(int32_t version, SkCanvas* canvas) {
	SkASSERT(canvas);
	this->version = version;
	width = canvas->getBaseLayerSize().width();
	height = canvas->getBaseLayerSize().height();

	}

	/**
	* The version this struct was built with. This field must always appear
	* first in the struct so that when the versions don't match (and the
	* remaining contents and size are potentially different) we can still
	* compare the version numbers.
	*/
	int32_t version;
	int32_t width;
	int32_t height;
	int32_t alignmentPadding;
	};

	class SkCanvasState_v1 : public SkCanvasState {
	public:
	static const int32_t kVersion = 1;

	SkCanvasState_v1(SkCanvas* canvas)
	: INHERITED(kVersion, canvas)
	{
	layerCount = 0;
	layers = nullptr;
	mcState.clipRectCount = 0;
	mcState.clipRects = nullptr;
	originalCanvas = SkRef(canvas);
	}

	~SkCanvasState_v1() {
	// loop through the layers and free the data allocated to the clipRects
	for (int i = 0; i < layerCount; ++i) {
	sk_free(layers[i].mcState.clipRects);
	}

	sk_free(mcState.clipRects);
	sk_free(layers);

	// it is now safe to free the canvas since there should be no remaining
	// references to the content that is referenced by this canvas (e.g. pixels)
	originalCanvas->unref();
	}

	SkMCState mcState;

	int32_t layerCount;
	SkCanvasLayerState* layers;
	private:
	SkCanvas* originalCanvas;
	typedef SkCanvasState INHERITED;
	};

	////////////////////////////////////////////////////////////////////////////////

	class ClipValidator : public SkCanvas::ClipVisitor {
	public:
	ClipValidator() : fFailed(false) {}
	bool failed() { return fFailed; }

	// ClipVisitor
	void clipRect(const SkRect& rect, SkCanvas::ClipOp op, bool antialias) override {
	fFailed \|= antialias;
	}

	void clipRRect(const SkRRect& rrect, SkCanvas::ClipOp op, bool antialias) override {
	fFailed \|= antialias;
	}

	void clipPath(const SkPath&, SkCanvas::ClipOp, bool antialias) override {
	fFailed \|= antialias;
	}

	private:
	bool fFailed;
	};

	static void setup_MC_state(SkMCState* state, const SkMatrix& matrix, const SkRegion& clip) {
	// initialize the struct
	state->clipRectCount = 0;

	// capture the matrix
	for (int i = 0; i < 9; i++) {
	state->matrix[i] = matrix.get(i);
	}

	/*
	* capture the clip
	*
	* storage is allocated on the stack for the first 4 rects. This value was
	* chosen somewhat arbitrarily, but does allow us to represent simple clips
	* and some more common complex clips (e.g. a clipRect with a sub-rect
	* clipped out of its interior) without needing to malloc any additional memory.
	*/
	SkSWriter32<4*sizeof(ClipRect)> clipWriter;

	if (!clip.isEmpty()) {
	// only returns the b/w clip so aa clips fail
	SkRegion::Iterator clip_iterator(clip);
	for (; !clip_iterator.done(); clip_iterator.next()) {
	// this assumes the SkIRect is stored in l,t,r,b ordering which
	// matches the ordering of our ClipRect struct
	clipWriter.writeIRect(clip_iterator.rect());
	state->clipRectCount++;
	}
	}

	// allocate memory for the clip then and copy them to the struct
	state->clipRects = (ClipRect*) sk_malloc_throw(clipWriter.bytesWritten());
	clipWriter.flatten(state->clipRects);
	}



	SkCanvasState* SkCanvasStateUtils::CaptureCanvasState(SkCanvas* canvas) {
	SkASSERT(canvas);

	// Check the clip can be decomposed into rectangles (i.e. no soft clips).
	ClipValidator validator;
	canvas->replayClips(&validator);
	if (validator.failed()) {
	return nullptr;
	}

	SkAutoTDelete<SkCanvasState_v1> canvasState(new SkCanvasState_v1(canvas));

	// decompose the total matrix and clip
	setup_MC_state(&canvasState->mcState, canvas->getTotalMatrix(),
	canvas->internal_private_getTotalClip());

	/*
	* decompose the layers
	*
	* storage is allocated on the stack for the first 3 layers. It is common in
	* some view systems (e.g. Android) that a few non-clipped layers are present
	* and we will not need to malloc any additional memory in those cases.
	*/
	SkSWriter32<3*sizeof(SkCanvasLayerState)> layerWriter;
	int layerCount = 0;
	for (SkCanvas::LayerIter layer(canvas); !layer.done(); layer.next()) {

	// we currently only work for bitmap backed devices
	SkPixmap pmap;
	if (!layer.device()->accessPixels(&pmap) \|\| 0 == pmap.width() \|\| 0 == pmap.height()) {
	return nullptr;
	}

	SkCanvasLayerState* layerState =
	(SkCanvasLayerState*) layerWriter.reserve(sizeof(SkCanvasLayerState));
	layerState->type = kRaster_CanvasBackend;
	layerState->x = layer.x();
	layerState->y = layer.y();
	layerState->width = pmap.width();
	layerState->height = pmap.height();

	switch (pmap.colorType()) {
	case kN32_SkColorType:
	layerState->raster.config = kARGB_8888_RasterConfig;
	break;
	case kRGB_565_SkColorType:
	layerState->raster.config = kRGB_565_RasterConfig;
	break;
	default:
	return nullptr;
	}
	layerState->raster.rowBytes = pmap.rowBytes();
	layerState->raster.pixels = pmap.writable_addr();

	setup_MC_state(&layerState->mcState, layer.matrix(), layer.clip().bwRgn());
	layerCount++;
	}

	// allocate memory for the layers and then and copy them to the struct
	SkASSERT(layerWriter.bytesWritten() == layerCount * sizeof(SkCanvasLayerState));
	canvasState->layerCount = layerCount;
	canvasState->layers = (SkCanvasLayerState*) sk_malloc_throw(layerWriter.bytesWritten());
	layerWriter.flatten(canvasState->layers);

	return canvasState.release();
	}

	////////////////////////////////////////////////////////////////////////////////

	static void setup_canvas_from_MC_state(const SkMCState& state, SkCanvas* canvas) {
	// reconstruct the matrix
	SkMatrix matrix;
	for (int i = 0; i < 9; i++) {
	matrix.set(i, state.matrix[i]);
	}

	// reconstruct the clip
	SkRegion clip;
	for (int i = 0; i < state.clipRectCount; ++i) {
	clip.op(SkIRect::MakeLTRB(state.clipRects[i].left,
	state.clipRects[i].top,
	state.clipRects[i].right,
	state.clipRects[i].bottom),
	SkRegion::kUnion_Op);
	}

	canvas->setMatrix(matrix);
	canvas->clipRegion(clip, SkCanvas::kReplace_Op);
	}

	static SkCanvas* create_canvas_from_canvas_layer(const SkCanvasLayerState& layerState) {
	SkASSERT(kRaster_CanvasBackend == layerState.type);

	SkBitmap bitmap;
	SkColorType colorType =
	layerState.raster.config == kARGB_8888_RasterConfig ? kN32_SkColorType :
	layerState.raster.config == kRGB_565_RasterConfig ? kRGB_565_SkColorType :
	kUnknown_SkColorType;

	if (colorType == kUnknown_SkColorType) {
	return nullptr;
	}

	bitmap.installPixels(SkImageInfo::Make(layerState.width, layerState.height,
	colorType, kPremul_SkAlphaType),
	layerState.raster.pixels, (size_t) layerState.raster.rowBytes);

	SkASSERT(!bitmap.empty());
	SkASSERT(!bitmap.isNull());

	SkAutoTUnref<SkCanvas> canvas(new SkCanvas(bitmap));

	// setup the matrix and clip
	setup_canvas_from_MC_state(layerState.mcState, canvas.get());

	return canvas.release();
	}

	SkCanvas* SkCanvasStateUtils::CreateFromCanvasState(const SkCanvasState* state) {
	SkASSERT(state);
	// Currently there is only one possible version.
	SkASSERT(SkCanvasState_v1::kVersion == state->version);

	const SkCanvasState_v1* state_v1 = static_cast<const SkCanvasState_v1*>(state);

	if (state_v1->layerCount < 1) {
	return nullptr;
	}

	SkAutoTUnref<SkCanvasStack> canvas(new SkCanvasStack(state->width, state->height));

	// setup the matrix and clip on the n-way canvas
	setup_canvas_from_MC_state(state_v1->mcState, canvas);

	// Iterate over the layers and add them to the n-way canvas
	for (int i = state_v1->layerCount - 1; i >= 0; --i) {
	SkAutoTUnref<SkCanvas> canvasLayer(create_canvas_from_canvas_layer(state_v1->layers[i]));
	if (!canvasLayer.get()) {
	return nullptr;
	}
	canvas->pushCanvas(canvasLayer.get(), SkIPoint::Make(state_v1->layers[i].x,
	state_v1->layers[i].y));
	}

	return canvas.release();
	}

	////////////////////////////////////////////////////////////////////////////////

	void SkCanvasStateUtils::ReleaseCanvasState(SkCanvasState* state) {
	SkASSERT(!state \|\| SkCanvasState_v1::kVersion == state->version);
	// Upcast to the correct version of SkCanvasState. This avoids having a virtual destructor on
	// SkCanvasState. That would be strange since SkCanvasState has no other virtual functions, and
	// instead uses the field "version" to determine how to behave.
	delete static_cast<SkCanvasState_v1*>(state);
	}