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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 GrPrimitiveProcessor_DEFINED
#define GrPrimitiveProcessor_DEFINED
#include "src/gpu/GrColor.h"
#include "src/gpu/GrNonAtomicRef.h"
#include "src/gpu/GrProcessor.h"
#include "src/gpu/GrShaderVar.h"
class GrCoordTransform;
/*
* The GrPrimitiveProcessor represents some kind of geometric primitive. This includes the shape
* of the primitive and the inherent color of the primitive. The GrPrimitiveProcessor is
* responsible for providing a color and coverage input into the Ganesh rendering pipeline. Through
* optimization, Ganesh may decide a different color, no color, and / or no coverage are required
* from the GrPrimitiveProcessor, so the GrPrimitiveProcessor must be able to support this
* functionality.
*
* There are two feedback loops between the GrFragmentProcessors, the GrXferProcessor, and the
* GrPrimitiveProcessor. These loops run on the CPU and to determine known properties of the final
* color and coverage inputs to the GrXferProcessor in order to perform optimizations that preserve
* correctness. The GrDrawOp seeds these loops with initial color and coverage, in its
* getProcessorAnalysisInputs implementation. These seed values are processed by the
* subsequent
* stages of the rendering pipeline and the output is then fed back into the GrDrawOp in
* the applyPipelineOptimizations call, where the op can use the information to inform decisions
* about GrPrimitiveProcessor creation.
*/
class GrGLSLPrimitiveProcessor;
/**
* GrPrimitiveProcessor defines an interface which all subclasses must implement. All
* GrPrimitiveProcessors must proivide seed color and coverage for the Ganesh color / coverage
* pipelines, and they must provide some notion of equality
*
* TODO: This class does not really need to be ref counted. Instances should be allocated using
* GrOpFlushState's arena and destroyed when the arena is torn down.
*/
class GrPrimitiveProcessor : public GrProcessor, public GrNonAtomicRef<GrPrimitiveProcessor> {
public:
class TextureSampler;
/** Describes a vertex or instance attribute. */
class Attribute {
public:
constexpr Attribute() = default;
constexpr Attribute(const char* name,
GrVertexAttribType cpuType,
GrSLType gpuType)
: fName(name), fCPUType(cpuType), fGPUType(gpuType) {}
constexpr Attribute(const Attribute&) = default;
Attribute& operator=(const Attribute&) = default;
constexpr bool isInitialized() const { return SkToBool(fName); }
constexpr const char* name() const { return fName; }
constexpr GrVertexAttribType cpuType() const { return fCPUType; }
constexpr GrSLType gpuType() const { return fGPUType; }
inline constexpr size_t size() const;
constexpr size_t sizeAlign4() const { return SkAlign4(this->size()); }
GrShaderVar asShaderVar() const {
return {fName, fGPUType, GrShaderVar::kIn_TypeModifier};
}
private:
const char* fName = nullptr;
GrVertexAttribType fCPUType = kFloat_GrVertexAttribType;
GrSLType fGPUType = kFloat_GrSLType;
};
class Iter {
public:
Iter() : fCurr(nullptr), fRemaining(0) {}
Iter(const Iter& iter) : fCurr(iter.fCurr), fRemaining(iter.fRemaining) {}
Iter& operator= (const Iter& iter) {
fCurr = iter.fCurr;
fRemaining = iter.fRemaining;
return *this;
}
Iter(const Attribute* attrs, int count) : fCurr(attrs), fRemaining(count) {
this->skipUninitialized();
}
bool operator!=(const Iter& that) const { return fCurr != that.fCurr; }
const Attribute& operator*() const { return *fCurr; }
void operator++() {
if (fRemaining) {
fRemaining--;
fCurr++;
this->skipUninitialized();
}
}
private:
void skipUninitialized() {
if (!fRemaining) {
fCurr = nullptr;
} else {
while (!fCurr->isInitialized()) {
++fCurr;
}
}
}
const Attribute* fCurr;
int fRemaining;
};
class AttributeSet {
public:
Iter begin() const { return Iter(fAttributes, fCount); }
Iter end() const { return Iter(); }
private:
friend class GrPrimitiveProcessor;
void init(const Attribute* attrs, int count) {
fAttributes = attrs;
fRawCount = count;
fCount = 0;
fStride = 0;
for (int i = 0; i < count; ++i) {
if (attrs[i].isInitialized()) {
fCount++;
fStride += attrs[i].sizeAlign4();
}
}
}
const Attribute* fAttributes = nullptr;
int fRawCount = 0;
int fCount = 0;
size_t fStride = 0;
};
GrPrimitiveProcessor(ClassID);
int numTextureSamplers() const { return fTextureSamplerCnt; }
const TextureSampler& textureSampler(int index) const;
int numVertexAttributes() const { return fVertexAttributes.fCount; }
const AttributeSet& vertexAttributes() const { return fVertexAttributes; }
int numInstanceAttributes() const { return fInstanceAttributes.fCount; }
const AttributeSet& instanceAttributes() const { return fInstanceAttributes; }
bool hasVertexAttributes() const { return SkToBool(fVertexAttributes.fCount); }
bool hasInstanceAttributes() const { return SkToBool(fInstanceAttributes.fCount); }
/**
* A common practice is to populate the the vertex/instance's memory using an implicit array of
* structs. In this case, it is best to assert that:
* stride == sizeof(struct)
*/
size_t vertexStride() const { return fVertexAttributes.fStride; }
size_t instanceStride() const { return fInstanceAttributes.fStride; }
// Only the GrGeometryProcessor subclass actually has a geo shader or vertex attributes, but
// we put these calls on the base class to prevent having to cast
virtual bool willUseGeoShader() const = 0;
/**
* Computes a transformKey from an array of coord transforms. Will only look at the first
* <numCoords> transforms in the array.
*
* TODO: A better name for this function would be "compute" instead of "get".
*/
uint32_t getTransformKey(const SkTArray<GrCoordTransform*, true>& coords,
int numCoords) const;
/**
* Sets a unique key on the GrProcessorKeyBuilder that is directly associated with this geometry
* processor's GL backend implementation.
*
* TODO: A better name for this function would be "compute" instead of "get".
*/
virtual void getGLSLProcessorKey(const GrShaderCaps&, GrProcessorKeyBuilder*) const = 0;
void getAttributeKey(GrProcessorKeyBuilder* b) const {
// Ensure that our CPU and GPU type fields fit together in a 32-bit value, and we never
// collide with the "uninitialized" value.
static_assert(kGrVertexAttribTypeCount < (1 << 8), "");
static_assert(kGrSLTypeCount < (1 << 8), "");
auto add_attributes = [=](const Attribute* attrs, int attrCount) {
for (int i = 0; i < attrCount; ++i) {
b->add32(attrs[i].isInitialized() ? (attrs[i].cpuType() << 16) | attrs[i].gpuType()
: ~0);
}
};
add_attributes(fVertexAttributes.fAttributes, fVertexAttributes.fRawCount);
add_attributes(fInstanceAttributes.fAttributes, fInstanceAttributes.fRawCount);
}
/** Returns a new instance of the appropriate *GL* implementation class
for the given GrProcessor; caller is responsible for deleting
the object. */
virtual GrGLSLPrimitiveProcessor* createGLSLInstance(const GrShaderCaps&) const = 0;
virtual bool isPathRendering() const { return false; }
protected:
void setVertexAttributes(const Attribute* attrs, int attrCount) {
fVertexAttributes.init(attrs, attrCount);
}
void setInstanceAttributes(const Attribute* attrs, int attrCount) {
SkASSERT(attrCount >= 0);
fInstanceAttributes.init(attrs, attrCount);
}
void setTextureSamplerCnt(int cnt) {
SkASSERT(cnt >= 0);
fTextureSamplerCnt = cnt;
}
/**
* Helper for implementing onTextureSampler(). E.g.:
* return IthTexureSampler(i, fMyFirstSampler, fMySecondSampler, fMyThirdSampler);
*/
template <typename... Args>
static const TextureSampler& IthTextureSampler(int i, const TextureSampler& samp0,
const Args&... samps) {
return (0 == i) ? samp0 : IthTextureSampler(i - 1, samps...);
}
inline static const TextureSampler& IthTextureSampler(int i);
private:
virtual const TextureSampler& onTextureSampler(int) const { return IthTextureSampler(0); }
AttributeSet fVertexAttributes;
AttributeSet fInstanceAttributes;
int fTextureSamplerCnt = 0;
typedef GrProcessor INHERITED;
};
//////////////////////////////////////////////////////////////////////////////
/**
* Used to capture the properties of the GrTextureProxies required/expected by a primitiveProcessor
* along with an associated GrSamplerState. The actual proxies used are stored in either the
* fixed or dynamic state arrays. TextureSamplers don't perform any coord manipulation to account
* for texture origin.
*/
class GrPrimitiveProcessor::TextureSampler {
public:
TextureSampler() = default;
TextureSampler(GrTextureType, const GrSamplerState&, const GrSwizzle&,
uint32_t extraSamplerKey = 0);
TextureSampler(const TextureSampler&) = delete;
TextureSampler& operator=(const TextureSampler&) = delete;
void reset(GrTextureType, const GrSamplerState&, const GrSwizzle&,
uint32_t extraSamplerKey = 0);
GrTextureType textureType() const { return fTextureType; }
const GrSamplerState& samplerState() const { return fSamplerState; }
const GrSwizzle& swizzle() const { return fSwizzle; }
uint32_t extraSamplerKey() const { return fExtraSamplerKey; }
bool isInitialized() const { return fIsInitialized; }
private:
GrSamplerState fSamplerState;
GrSwizzle fSwizzle;
GrTextureType fTextureType = GrTextureType::k2D;
uint32_t fExtraSamplerKey = 0;
bool fIsInitialized = false;
};
const GrPrimitiveProcessor::TextureSampler& GrPrimitiveProcessor::IthTextureSampler(int i) {
SK_ABORT("Illegal texture sampler index");
static const TextureSampler kBogus;
return kBogus;
}
//////////////////////////////////////////////////////////////////////////////
/**
* Returns the size of the attrib type in bytes.
* This was moved from include/private/GrTypesPriv.h in service of Skia dependents that build
* with C++11.
*/
static constexpr inline size_t GrVertexAttribTypeSize(GrVertexAttribType type) {
switch (type) {
case kFloat_GrVertexAttribType:
return sizeof(float);
case kFloat2_GrVertexAttribType:
return 2 * sizeof(float);
case kFloat3_GrVertexAttribType:
return 3 * sizeof(float);
case kFloat4_GrVertexAttribType:
return 4 * sizeof(float);
case kHalf_GrVertexAttribType:
return sizeof(uint16_t);
case kHalf2_GrVertexAttribType:
return 2 * sizeof(uint16_t);
case kHalf3_GrVertexAttribType:
return 3 * sizeof(uint16_t);
case kHalf4_GrVertexAttribType:
return 4 * sizeof(uint16_t);
case kInt2_GrVertexAttribType:
return 2 * sizeof(int32_t);
case kInt3_GrVertexAttribType:
return 3 * sizeof(int32_t);
case kInt4_GrVertexAttribType:
return 4 * sizeof(int32_t);
case kByte_GrVertexAttribType:
return 1 * sizeof(char);
case kByte2_GrVertexAttribType:
return 2 * sizeof(char);
case kByte3_GrVertexAttribType:
return 3 * sizeof(char);
case kByte4_GrVertexAttribType:
return 4 * sizeof(char);
case kUByte_GrVertexAttribType:
return 1 * sizeof(char);
case kUByte2_GrVertexAttribType:
return 2 * sizeof(char);
case kUByte3_GrVertexAttribType:
return 3 * sizeof(char);
case kUByte4_GrVertexAttribType:
return 4 * sizeof(char);
case kUByte_norm_GrVertexAttribType:
return 1 * sizeof(char);
case kUByte4_norm_GrVertexAttribType:
return 4 * sizeof(char);
case kShort2_GrVertexAttribType:
return 2 * sizeof(int16_t);
case kShort4_GrVertexAttribType:
return 4 * sizeof(int16_t);
case kUShort2_GrVertexAttribType: // fall through
case kUShort2_norm_GrVertexAttribType:
return 2 * sizeof(uint16_t);
case kInt_GrVertexAttribType:
return sizeof(int32_t);
case kUint_GrVertexAttribType:
return sizeof(uint32_t);
case kUShort_norm_GrVertexAttribType:
return sizeof(uint16_t);
case kUShort4_norm_GrVertexAttribType:
return 4 * sizeof(uint16_t);
}
// GCC fails because SK_ABORT evaluates to non constexpr. clang and cl.exe think this is
// unreachable and don't complain.
#if defined(__clang__) || !defined(__GNUC__)
SK_ABORT("Unsupported type conversion");
#endif
return 0;
}
constexpr size_t GrPrimitiveProcessor::Attribute::size() const {
return GrVertexAttribTypeSize(fCPUType);
}
#endif