src/compute/sk/SkSurface_Compute.cpp - 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.
  */

 //
 //
 //

 #include "SkSurface_Compute.h"
 #include "SkDevice_Compute.h"
 #include "SkImage_Compute.h"

 //
 //
 //

 #if SK_SUPPORT_GPU_COMPUTE

 //
 // C++
 //

 #include "gl/GrGLGpu.h"
 #include "SkSurface_Gpu.h"

 //
 //
 //

 SkSurface_Compute::SkSurface_Compute(sk_sp<SkContext_Compute> compute,
                                      int const width, int const height)
   : INHERITED(width,height,nullptr),
     compute(compute)
 {
   //
   // resize interop
   //
   // skc_interop_size_set(compute->interop,width,height,NULL); TODO skc.h
 }

 SkSurface_Compute::~SkSurface_Compute()
 {
   ;
 }

 //
 //
 //

 SkCanvas*
 SkSurface_Compute::onNewCanvas()
 {
   uint32_t w = 0,h = 0;

   // skc_interop_size_get(compute->interop,&w,&h); TODO skc.h

   SkDevice_Compute * const device_compute = new SkDevice_Compute(compute,w,h);
   SkCanvas         * const canvas         = new SkCanvas(device_compute,SkCanvas::kConservativeRasterClip_InitFlag);

   //
   // destroy device upon surface destruction
   //
   device = sk_sp<SkBaseDevice>(device_compute);

   //
   // move origin from upper left to lower left
   //
   SkMatrix matrix;

   matrix.setScaleTranslate(1.0f,-1.0f,0.0f,(SkScalar)h);

   canvas->setMatrix(matrix);

   return canvas;
 }

 //
 //
 //

 sk_sp<SkSurface>
 SkSurface_Compute::onNewSurface(const SkImageInfo& info)
 {
   return sk_make_sp<SkSurface_Compute>(compute,info.width(),info.height());
 }

 //
 //
 //

 sk_sp<SkImage>
 SkSurface_Compute::onNewImageSnapshot()
 {
   uint32_t w,h;

   // skc_interop_size_get(compute->interop,&w,&h); TODO skc.h

   GrGLuint snap;

   // skc_interop_snap_create(compute->interop, TODO skc.h
 		// 	  skc_surface_interop_surface_get(compute->surface),
 		// 	  &snap);

   return sk_make_sp<SkImage_Compute>(compute,snap,w,h);
 }

 //
 //
 //

 void
 SkSurface_Compute::onCopyOnWrite(ContentChangeMode mode)
 {
   ;
 }

 //
 //
 //

 #if 0

 sk_sp<SkSurface>
 SkSurface_Compute::MakeComputeBackedSurface(SkWindow                       * const window,
                                             const SkWindow::AttachmentInfo &       attachmentInfo,
                                             GrGLInterface const            * const grInterface,
                                             GrContext                      * const grContext,
                                             sk_sp<SkContext_Compute>               compute)
 {
   GrBackendRenderTargetDesc desc;

   desc.fWidth  = SkScalarRoundToInt(window->width());
   desc.fHeight = SkScalarRoundToInt(window->height());

   if (0 == desc.fWidth || 0 == desc.fHeight) {
     return nullptr;
   }

   // TODO: Query the actual framebuffer for sRGB capable. However, to
   // preserve old (fake-linear) behavior, we don't do this. Instead, rely
   // on the flag (currently driven via 'C' mode in SampleApp).
   //
   // Also, we may not have real sRGB support (ANGLE, in particular), so check for
   // that, and fall back to L32:
   //
   // ... and, if we're using a 10-bit/channel FB0, it doesn't do sRGB conversion on write,
   // so pretend that it's non-sRGB 8888:
   desc.fConfig =
     grContext->caps()->srgbSupport() &&
     SkImageInfoIsGammaCorrect(window->info()) &&
     (attachmentInfo.fColorBits != 30)
     ? kSkiaGamma8888_GrPixelConfig : kSkia8888_GrPixelConfig;

   desc.fOrigin      = kBottomLeft_GrSurfaceOrigin;
   desc.fSampleCnt   = 0; //  attachmentInfo.fSampleCount;
   desc.fStencilBits = 0; //  attachmentInfo.fStencilBits;

   GrGLint buffer;

   GR_GL_GetIntegerv(grInterface,GR_GL_FRAMEBUFFER_BINDING,&buffer);
   desc.fRenderTargetHandle = buffer;

   sk_sp<SkColorSpace> colorSpace =
     grContext->caps()->srgbSupport() && SkImageInfoIsGammaCorrect(window->info())
     ? SkColorSpace::NewNamed(SkColorSpace::kSRGB_Named) : nullptr;

   //
   //
   //

   if (!grContext) {
     return nullptr;
   }

   if (!SkSurface_Gpu::Valid(grContext,desc.fConfig,colorSpace.get())) {
     return nullptr;
   }

   return sk_make_sp<SkSurface_Compute>(compute,desc.fWidth,desc.fHeight);
 }

 #endif

 //
 //
 //

 #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.
	*/

	//
	//
	//

	#include "SkSurface_Compute.h"
	#include "SkDevice_Compute.h"
	#include "SkImage_Compute.h"

	//
	//
	//

	#if SK_SUPPORT_GPU_COMPUTE

	//
	// C++
	//

	#include "gl/GrGLGpu.h"
	#include "SkSurface_Gpu.h"

	//
	//
	//

	SkSurface_Compute::SkSurface_Compute(sk_sp<SkContext_Compute> compute,
	int const width, int const height)
	: INHERITED(width,height,nullptr),
	compute(compute)
	{
	//
	// resize interop
	//
	// skc_interop_size_set(compute->interop,width,height,NULL); TODO skc.h
	}

	SkSurface_Compute::~SkSurface_Compute()
	{
	;
	}

	//
	//
	//

	SkCanvas*
	SkSurface_Compute::onNewCanvas()
	{
	uint32_t w = 0,h = 0;

	// skc_interop_size_get(compute->interop,&w,&h); TODO skc.h

	SkDevice_Compute * const device_compute = new SkDevice_Compute(compute,w,h);
	SkCanvas * const canvas = new SkCanvas(device_compute,SkCanvas::kConservativeRasterClip_InitFlag);

	//
	// destroy device upon surface destruction
	//
	device = sk_sp<SkBaseDevice>(device_compute);

	//
	// move origin from upper left to lower left
	//
	SkMatrix matrix;

	matrix.setScaleTranslate(1.0f,-1.0f,0.0f,(SkScalar)h);

	canvas->setMatrix(matrix);

	return canvas;
	}

	//
	//
	//

	sk_sp<SkSurface>
	SkSurface_Compute::onNewSurface(const SkImageInfo& info)
	{
	return sk_make_sp<SkSurface_Compute>(compute,info.width(),info.height());
	}

	//
	//
	//

	sk_sp<SkImage>
	SkSurface_Compute::onNewImageSnapshot()
	{
	uint32_t w,h;

	// skc_interop_size_get(compute->interop,&w,&h); TODO skc.h

	GrGLuint snap;

	// skc_interop_snap_create(compute->interop, TODO skc.h
	// skc_surface_interop_surface_get(compute->surface),
	// &snap);

	return sk_make_sp<SkImage_Compute>(compute,snap,w,h);
	}

	//
	//
	//

	void
	SkSurface_Compute::onCopyOnWrite(ContentChangeMode mode)
	{
	;
	}

	//
	//
	//

	#if 0

	sk_sp<SkSurface>
	SkSurface_Compute::MakeComputeBackedSurface(SkWindow * const window,
	const SkWindow::AttachmentInfo & attachmentInfo,
	GrGLInterface const * const grInterface,
	GrContext * const grContext,
	sk_sp<SkContext_Compute> compute)
	{
	GrBackendRenderTargetDesc desc;

	desc.fWidth = SkScalarRoundToInt(window->width());
	desc.fHeight = SkScalarRoundToInt(window->height());

	if (0 == desc.fWidth \|\| 0 == desc.fHeight) {
	return nullptr;
	}

	// TODO: Query the actual framebuffer for sRGB capable. However, to
	// preserve old (fake-linear) behavior, we don't do this. Instead, rely
	// on the flag (currently driven via 'C' mode in SampleApp).
	//
	// Also, we may not have real sRGB support (ANGLE, in particular), so check for
	// that, and fall back to L32:
	//
	// ... and, if we're using a 10-bit/channel FB0, it doesn't do sRGB conversion on write,
	// so pretend that it's non-sRGB 8888:
	desc.fConfig =
	grContext->caps()->srgbSupport() &&
	SkImageInfoIsGammaCorrect(window->info()) &&
	(attachmentInfo.fColorBits != 30)
	? kSkiaGamma8888_GrPixelConfig : kSkia8888_GrPixelConfig;

	desc.fOrigin = kBottomLeft_GrSurfaceOrigin;
	desc.fSampleCnt = 0; // attachmentInfo.fSampleCount;
	desc.fStencilBits = 0; // attachmentInfo.fStencilBits;

	GrGLint buffer;

	GR_GL_GetIntegerv(grInterface,GR_GL_FRAMEBUFFER_BINDING,&buffer);
	desc.fRenderTargetHandle = buffer;

	sk_sp<SkColorSpace> colorSpace =
	grContext->caps()->srgbSupport() && SkImageInfoIsGammaCorrect(window->info())
	? SkColorSpace::NewNamed(SkColorSpace::kSRGB_Named) : nullptr;

	//
	//
	//

	if (!grContext) {
	return nullptr;
	}

	if (!SkSurface_Gpu::Valid(grContext,desc.fConfig,colorSpace.get())) {
	return nullptr;
	}

	return sk_make_sp<SkSurface_Compute>(compute,desc.fWidth,desc.fHeight);
	}

	#endif

	//
	//
	//

	#endif