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/*
* Copyright 2013 Google Inc.
*
* Use of this source code is governed by a BSD-style license that can be
* found in the LICENSE file.
*/
#ifndef GrCaps_DEFINED
#define GrCaps_DEFINED
#include "GrTypes.h"
#include "GrTypesPriv.h"
#include "GrBlend.h"
#include "GrShaderVar.h"
#include "SkRefCnt.h"
#include "SkString.h"
struct GrContextOptions;
class GrShaderCaps : public SkRefCnt {
public:
/** Info about shader variable precision within a given shader stage. That is, this info
is relevant to a float (or vecNf) variable declared with a GrSLPrecision
in a given GrShaderType. The info here is hoisted from the OpenGL spec. */
struct PrecisionInfo {
PrecisionInfo() {
fLogRangeLow = 0;
fLogRangeHigh = 0;
fBits = 0;
}
/** Is this precision level allowed in the shader stage? */
bool supported() const { return 0 != fBits; }
bool operator==(const PrecisionInfo& that) const {
return fLogRangeLow == that.fLogRangeLow && fLogRangeHigh == that.fLogRangeHigh &&
fBits == that.fBits;
}
bool operator!=(const PrecisionInfo& that) const { return !(*this == that); }
/** floor(log2(|min_value|)) */
int fLogRangeLow;
/** floor(log2(|max_value|)) */
int fLogRangeHigh;
/** Number of bits of precision. As defined in OpenGL (with names modified to reflect this
struct) :
"""
If the smallest representable value greater than 1 is 1 + e, then fBits will
contain floor(log2(e)), and every value in the range [2^fLogRangeLow,
2^fLogRangeHigh] can be represented to at least one part in 2^fBits.
"""
*/
int fBits;
};
GrShaderCaps();
virtual SkString dump() const;
bool shaderDerivativeSupport() const { return fShaderDerivativeSupport; }
bool geometryShaderSupport() const { return fGeometryShaderSupport; }
bool pathRenderingSupport() const { return fPathRenderingSupport; }
bool dstReadInShaderSupport() const { return fDstReadInShaderSupport; }
bool dualSourceBlendingSupport() const { return fDualSourceBlendingSupport; }
bool mixedSamplesSupport() const { return fMixedSamplesSupport; }
bool programmableSampleLocationsSupport() const { return fProgrammableSampleLocationsSupport; }
/**
* Get the precision info for a variable of type kFloat_GrSLType, kVec2f_GrSLType, etc in a
* given shader type. If the shader type is not supported or the precision level is not
* supported in that shader type then the returned struct will report false when supported() is
* called.
*/
const PrecisionInfo& getFloatShaderPrecisionInfo(GrShaderType shaderType,
GrSLPrecision precision) const {
return fFloatPrecisions[shaderType][precision];
};
/**
* Is there any difference between the float shader variable precision types? If this is true
* then unless the shader type is not supported, any call to getFloatShaderPrecisionInfo() would
* report the same info for all precisions in all shader types.
*/
bool floatPrecisionVaries() const { return fShaderPrecisionVaries; }
protected:
/** Subclasses must call this after initialization in order to apply caps overrides requested by
the client. Note that overrides will only reduce the caps never expand them. */
void applyOptionsOverrides(const GrContextOptions& options);
bool fShaderDerivativeSupport : 1;
bool fGeometryShaderSupport : 1;
bool fPathRenderingSupport : 1;
bool fDstReadInShaderSupport : 1;
bool fDualSourceBlendingSupport : 1;
bool fMixedSamplesSupport : 1;
bool fProgrammableSampleLocationsSupport : 1;
bool fShaderPrecisionVaries;
PrecisionInfo fFloatPrecisions[kGrShaderTypeCount][kGrSLPrecisionCount];
private:
typedef SkRefCnt INHERITED;
};
/**
* Represents the capabilities of a GrContext.
*/
class GrCaps : public SkRefCnt {
public:
GrCaps(const GrContextOptions&);
virtual SkString dump() const;
GrShaderCaps* shaderCaps() const { return fShaderCaps; }
bool npotTextureTileSupport() const { return fNPOTTextureTileSupport; }
/** To avoid as-yet-unnecessary complexity we don't allow any partial support of MIP Maps (e.g.
only for POT textures) */
bool mipMapSupport() const { return fMipMapSupport; }
bool twoSidedStencilSupport() const { return fTwoSidedStencilSupport; }
bool stencilWrapOpsSupport() const { return fStencilWrapOpsSupport; }
bool discardRenderTargetSupport() const { return fDiscardRenderTargetSupport; }
#if GR_FORCE_GPU_TRACE_DEBUGGING
bool gpuTracingSupport() const { return true; }
#else
bool gpuTracingSupport() const { return fGpuTracingSupport; }
#endif
bool compressedTexSubImageSupport() const { return fCompressedTexSubImageSupport; }
bool oversizedStencilSupport() const { return fOversizedStencilSupport; }
bool textureBarrierSupport() const { return fTextureBarrierSupport; }
bool useDrawInsteadOfClear() const { return fUseDrawInsteadOfClear; }
bool useDrawInsteadOfPartialRenderTargetWrite() const {
return fUseDrawInsteadOfPartialRenderTargetWrite;
}
bool preferVRAMUseOverFlushes() const { return fPreferVRAMUseOverFlushes; }
/**
* Indicates the capabilities of the fixed function blend unit.
*/
enum BlendEquationSupport {
kBasic_BlendEquationSupport, //<! Support to select the operator that
// combines src and dst terms.
kAdvanced_BlendEquationSupport, //<! Additional fixed function support for specific
// SVG/PDF blend modes. Requires blend barriers.
kAdvancedCoherent_BlendEquationSupport, //<! Advanced blend equation support that does not
// require blend barriers, and permits overlap.
kLast_BlendEquationSupport = kAdvancedCoherent_BlendEquationSupport
};
BlendEquationSupport blendEquationSupport() const { return fBlendEquationSupport; }
bool advancedBlendEquationSupport() const {
return fBlendEquationSupport >= kAdvanced_BlendEquationSupport;
}
bool advancedCoherentBlendEquationSupport() const {
return kAdvancedCoherent_BlendEquationSupport == fBlendEquationSupport;
}
bool canUseAdvancedBlendEquation(GrBlendEquation equation) const {
SkASSERT(GrBlendEquationIsAdvanced(equation));
return SkToBool(fAdvBlendEqBlacklist & (1 << equation));
}
/**
* Indicates whether GPU->CPU memory mapping for GPU resources such as vertex buffers and
* textures allows partial mappings or full mappings.
*/
enum MapFlags {
kNone_MapFlags = 0x0, //<! Cannot map the resource.
kCanMap_MapFlag = 0x1, //<! The resource can be mapped. Must be set for any of
// the other flags to have meaning.k
kSubset_MapFlag = 0x2, //<! The resource can be partially mapped.
};
uint32_t mapBufferFlags() const { return fMapBufferFlags; }
// Scratch textures not being reused means that those scratch textures
// that we upload to (i.e., don't have a render target) will not be
// recycled in the texture cache. This is to prevent ghosting by drivers
// (in particular for deferred architectures).
bool reuseScratchTextures() const { return fReuseScratchTextures; }
bool reuseScratchBuffers() const { return fReuseScratchBuffers; }
int maxRenderTargetSize() const { return fMaxRenderTargetSize; }
int maxTextureSize() const { return fMaxTextureSize; }
/** 0 unless GPU has problems with small textures */
int minTextureSize() const { return fMinTextureSize; }
// Will be 0 if MSAA is not supported
int maxSampleCount() const { return fMaxSampleCount; }
bool isConfigRenderable(GrPixelConfig config, bool withMSAA) const {
SkASSERT(kGrPixelConfigCnt > config);
return fConfigRenderSupport[config][withMSAA];
}
bool isConfigTexturable(GrPixelConfig config) const {
SkASSERT(kGrPixelConfigCnt > config);
return fConfigTextureSupport[config];
}
bool suppressPrints() const { return fSupressPrints; }
bool drawPathMasksToCompressedTexturesSupport() const {
return fDrawPathMasksToCompressedTextureSupport;
}
size_t geometryBufferMapThreshold() const {
SkASSERT(fGeometryBufferMapThreshold >= 0);
return fGeometryBufferMapThreshold;
}
bool supportsInstancedDraws() const {
return fSupportsInstancedDraws;
}
bool fullClearIsFree() const { return fFullClearIsFree; }
/** True in environments that will issue errors if memory uploaded to buffers
is not initialized (even if not read by draw calls). */
bool mustClearUploadedBufferData() const { return fMustClearUploadedBufferData; }
protected:
/** Subclasses must call this at the end of their constructors in order to apply caps
overrides requested by the client. Note that overrides will only reduce the caps never
expand them. */
void applyOptionsOverrides(const GrContextOptions& options);
SkAutoTUnref<GrShaderCaps> fShaderCaps;
bool fNPOTTextureTileSupport : 1;
bool fMipMapSupport : 1;
bool fTwoSidedStencilSupport : 1;
bool fStencilWrapOpsSupport : 1;
bool fDiscardRenderTargetSupport : 1;
bool fReuseScratchTextures : 1;
bool fReuseScratchBuffers : 1;
bool fGpuTracingSupport : 1;
bool fCompressedTexSubImageSupport : 1;
bool fOversizedStencilSupport : 1;
bool fTextureBarrierSupport : 1;
bool fSupportsInstancedDraws : 1;
bool fFullClearIsFree : 1;
bool fMustClearUploadedBufferData : 1;
// Driver workaround
bool fUseDrawInsteadOfClear : 1;
bool fUseDrawInsteadOfPartialRenderTargetWrite : 1;
// ANGLE workaround
bool fPreferVRAMUseOverFlushes : 1;
BlendEquationSupport fBlendEquationSupport;
uint32_t fAdvBlendEqBlacklist;
GR_STATIC_ASSERT(kLast_GrBlendEquation < 32);
uint32_t fMapBufferFlags;
int fGeometryBufferMapThreshold;
int fMaxRenderTargetSize;
int fMaxTextureSize;
int fMinTextureSize;
int fMaxSampleCount;
// The first entry for each config is without msaa and the second is with.
bool fConfigRenderSupport[kGrPixelConfigCnt][2];
bool fConfigTextureSupport[kGrPixelConfigCnt];
private:
bool fSupressPrints : 1;
bool fDrawPathMasksToCompressedTextureSupport : 1;
typedef SkRefCnt INHERITED;
};
#endif