const char* bgColor = inputColor;
const char* fgColor = "fgColor";
code->appendf("\t\tvec4 %s = ", fgColor);
- builder->appendTextureLookup(code, samplerName);
- code->append(";\n");
+ builder->emitTextureLookup(samplerName);
+ code->appendf(";\n");
code->appendf("\t\t%s.a = 1.0 - (1.0 - %s.a) * (1.0 - %s.b);\n", outputColor, bgColor, fgColor);
switch (fMode) {
case SkBlendImageFilter::kNormal_Mode:
SkString texCoords;
texCoords.appendf("coord + vec2(%d, %d) * %s", dx, dy, imgInc);
code->appendf("\t\tm[%d] = ", index++);
- builder->appendTextureLookup(code, samplerName, texCoords.c_str());
+ builder->emitTextureLookup(samplerName, texCoords.c_str());
code->appendf(".a;\n");
}
}
SkString arg;
arg.appendf("%s * m[4]", surfScale);
fLight->emitSurfaceToLight(builder, code, arg.c_str());
- code->append(";\n");
+ code->appendf(";\n");
code->appendf("\t\t%s = %s(%s(m, %s), surfaceToLight, ",
outputColor, lightFunc.c_str(), interiorNormalName.c_str(), surfScale);
fLight->emitLightColor(builder, "surfaceToLight");
- code->append(");\n");
- GrGLSLMulVarBy4f(code, 2, outputColor, inputColor);
+ code->appendf(")%s;\n", builder->fModulate.c_str());
}
GrGLProgramStage::StageKey GrGLLightingEffect::GenKey(const GrCustomStage& s,
code->appendf("\t\tvec2 mix_coord = mix(coord, zoom_coord, weight);\n");
code->appendf("\t\tvec4 output_color = ");
- state->appendTextureLookup(code, samplerName, "mix_coord");
- code->append(";\n");
+ state->emitTextureLookup(samplerName, "mix_coord");
+ code->appendf(";\n");
code->appendf("\t\t%s = output_color;", outputColor);
- GrGLSLMulVarBy4f(code, 2, outputColor, inputColor);
}
void GrGLMagnifierEffect::setData(const GrGLUniformManager& uman,
const char* func;
switch (fType) {
case GrMorphologyEffect::kErode_MorphologyType:
- code->appendf("\t\t%s = vec4(1, 1, 1, 1);\n", outputColor);
+ code->appendf("\t\tvec4 value = vec4(1, 1, 1, 1);\n");
func = "min";
break;
case GrMorphologyEffect::kDilate_MorphologyType:
- code->appendf("\t\t%s = vec4(0, 0, 0, 0);\n", outputColor);
+ code->appendf("\t\tvec4 value = vec4(0, 0, 0, 0);\n");
func = "max";
break;
default:
code->appendf("\t\tvec2 coord = %s - %d.0 * %s;\n",
builder->defaultTexCoordsName(), fRadius, imgInc);
code->appendf("\t\tfor (int i = 0; i < %d; i++) {\n", this->width());
- code->appendf("\t\t\t%s = %s(%s, ", outputColor, func, outputColor);
- builder->appendTextureLookup(&builder->fFSCode, samplerName, "coord");
+ code->appendf("\t\t\tvalue = %s(value, ", func);
+ builder->emitTextureLookup(samplerName, "coord");
code->appendf(");\n");
code->appendf("\t\t\tcoord += %s;\n", imgInc);
code->appendf("\t\t}\n");
- GrGLSLMulVarBy4f(code, 2, outputColor, inputColor);
+ code->appendf("\t\t%s = value%s;\n", outputColor, builder->fModulate.c_str());
}
GrGLProgramStage::StageKey GrGLMorphologyEffect::GenKey(const GrCustomStage& s,
}
void GrGLGradientStage::emitColorLookup(GrGLShaderBuilder* builder,
- const char* gradientTValue,
+ const char* tName,
const char* outputColor,
- const char* inputColor,
const char* samplerName) {
- SkString* code = &builder->fFSCode;
- code->appendf("\tvec2 coord = vec2(%s, %s);\n",
- gradientTValue,
- builder->getUniformVariable(fFSYUni).c_str());
- GrGLSLMulVarBy4f(code, 1, outputColor, inputColor);
- code->appendf("\t%s = ", outputColor);
- builder->appendTextureLookupAndModulate(code, inputColor, samplerName, "coord");
- code->append(";\n");
+ builder->fFSCode.appendf("\tvec2 coord = vec2(%s, %s);\n",
+ tName,
+ builder->getUniformVariable(fFSYUni).c_str());
+ builder->emitTextureLookupAndModulate(outputColor, samplerName, "coord");
}
/////////////////////////////////////////////////////////////////////
// emit code that gets a fragment's color from an expression for t; for now
// this always uses the texture, but for simpler cases we'll be able to lerp
- void emitColorLookup(GrGLShaderBuilder* builder,
- const char* gradientTValue,
- const char* outputColor,
- const char* inputColor,
- const char* samplerName);
+ void emitColorLookup(GrGLShaderBuilder* builder, const char* t,
+ const char* outputColor, const char* samplerName);
private:
const char* samplerName) {
SkString t;
t.printf("%s.x", builder->defaultTexCoordsName());
- this->emitColorLookup(builder, t.c_str(), outputColor, inputColor, samplerName);
+ this->emitColorLookup(builder, t.c_str(), outputColor, samplerName);
}
/////////////////////////////////////////////////////////////////////
const char* samplerName) {
SkString t;
t.printf("length(%s.xy)", builder->defaultTexCoordsName());
- this->emitColorLookup(builder, t.c_str(), outputColor, inputColor, samplerName);
+ this->emitColorLookup(builder, t.c_str(), outputColor, samplerName);
}
/////////////////////////////////////////////////////////////////////
SkString t;
t.printf("atan(- %s.y, - %s.x) * 0.1591549430918 + 0.5",
builder->defaultTexCoordsName(), builder->defaultTexCoordsName());
- this->emitColorLookup(builder, t.c_str(), outputColor, inputColor, samplerName);
+ this->emitColorLookup(builder, t.c_str(), outputColor, samplerName);
}
/////////////////////////////////////////////////////////////////////
p5.c_str(), p3.c_str());
code->appendf("\t\t");
- this->emitColorLookup(builder, tName.c_str(), outputColor, inputColor, samplerName);
+ this->emitColorLookup(builder, tName.c_str(), outputColor, samplerName);
// otherwise, if r(t) for the larger root was <= 0, try the other root
code->appendf("\t\t} else {\n");
tName.c_str(), p5.c_str(), p3.c_str());
code->appendf("\t\t\t");
- this->emitColorLookup(builder, tName.c_str(), outputColor, inputColor, samplerName);
+ this->emitColorLookup(builder, tName.c_str(), outputColor, samplerName);
// end if (r(t) > 0) for smaller root
code->appendf("\t\t\t}\n");
code->appendf("\tif (%s * %s + %s > 0.0) {\n", tName.c_str(),
p5.c_str(), p3.c_str());
code->appendf("\t");
- this->emitColorLookup(builder, tName.c_str(), outputColor, inputColor, samplerName);
+ this->emitColorLookup(builder, tName.c_str(), outputColor, samplerName);
code->appendf("\t}\n");
}
}
t.printf("-%s / %s", cName.c_str(), bVar.c_str());
}
- this->emitColorLookup(builder, t.c_str(), outputColor, inputColor, samplerName);
+ this->emitColorLookup(builder, t.c_str(), outputColor, samplerName);
}
void GrGLRadial2Gradient::setData(const GrGLUniformManager& uman,
const char* outputColor,
const char* inputColor,
const char* samplerName) SK_OVERRIDE {
- builder->fFSCode.appendf("\t\t%s = ", outputColor);
- builder->appendTextureLookup(&builder->fFSCode, samplerName);
- builder->fFSCode.appendf("%s;\n", builder->fSwizzle.c_str());
+ builder->fFSCode.append("\tvec4 tempColor;\n");
+ builder->emitTextureLookupAndModulate("tempColor", samplerName);
if (GrConfigConversionEffect::kNone_PMConversion == fPMConversion) {
GrAssert(fSwapRedAndBlue);
- builder->fFSCode.appendf("\t%s = %s.bgra;\n", outputColor, outputColor);
+ builder->fFSCode.appendf("\t%s = tempColor.bgra;\n", outputColor);
} else {
const char* swiz = fSwapRedAndBlue ? "bgr" : "rgb";
switch (fPMConversion) {
case GrConfigConversionEffect::kMulByAlpha_RoundUp_PMConversion:
builder->fFSCode.appendf(
- "\t\t%s = vec4(ceil(%s.%s * %s.a * 255.0) / 255.0, %s.a);\n",
- outputColor, outputColor, swiz, outputColor, outputColor);
+ "\t%s = vec4(ceil(tempColor.%s*tempColor.a*255.0)/255.0, tempColor.a);\n",
+ outputColor, swiz);
break;
case GrConfigConversionEffect::kMulByAlpha_RoundDown_PMConversion:
builder->fFSCode.appendf(
- "\t\t%s = vec4(floor(%s.%s * %s.a * 255.0) / 255.0, %s.a);\n",
- outputColor, outputColor, swiz, outputColor, outputColor);
+ "\t%s = vec4(floor(tempColor.%s*tempColor.a*255.0)/255.0, tempColor.a);\n",
+ outputColor, swiz);
break;
case GrConfigConversionEffect::kDivByAlpha_RoundUp_PMConversion:
- builder->fFSCode.appendf("\t\t%s = %s.a <= 0.0 ? vec4(0,0,0,0) : vec4(ceil(%s.%s / %s.a * 255.0) / 255.0, %s.a);\n",
- outputColor, outputColor, outputColor, swiz, outputColor, outputColor);
+ builder->fFSCode.appendf("\t%s = tempColor.a <= 0.0 ? vec4(0,0,0,0) : vec4(ceil(tempColor.%s / tempColor.a * 255.0)/255.0, tempColor.a);\n",
+ outputColor, swiz);
break;
case GrConfigConversionEffect::kDivByAlpha_RoundDown_PMConversion:
- builder->fFSCode.appendf("\t\t%s = %s.a <= 0.0 ? vec4(0,0,0,0) : vec4(floor(%s.%s / %s.a * 255.0) / 255.0, %s.a);\n",
- outputColor, outputColor, outputColor, swiz, outputColor, outputColor);
+ builder->fFSCode.appendf("\t%s = tempColor.a <= 0.0 ? vec4(0,0,0,0) : vec4(floor(tempColor.%s / tempColor.a * 255.0)/255.0, tempColor.a);\n",
+ outputColor, swiz);
break;
default:
GrCrash("Unknown conversion op.");
break;
}
}
- GrGLSLMulVarBy4f(&builder->fFSCode, 2, outputColor, inputColor);
}
static inline StageKey GenKey(const GrCustomStage& s, const GrGLCaps&) {
index.appendS32(i);
kernel.appendArrayAccess(index.c_str(), &kernelIndex);
code->appendf("\t\t%s += ", outputColor);
- builder->appendTextureLookup(&builder->fFSCode, samplerName, "coord");
+ builder->emitTextureLookup(samplerName, "coord");
code->appendf(" * %s;\n", kernelIndex.c_str());
code->appendf("\t\tcoord += %s;\n", imgInc);
}
- GrGLSLMulVarBy4f(&builder->fFSCode, 2, outputColor, inputColor);
+
+ if (builder->fModulate.size()) {
+ code->appendf("\t\t%s = %s%s;\n", outputColor, outputColor,
+ builder->fModulate.c_str());
+ }
}
void GrGLConvolutionEffect::setData(const GrGLUniformManager& uman,
const char* outputColor,
const char* inputColor,
const char* samplerName) SK_OVERRIDE {
- builder->fFSCode.appendf("\t%s = ", outputColor);
- builder->appendTextureLookupAndModulate(&builder->fFSCode, inputColor, samplerName);
- builder->fFSCode.append(";\n");
+ builder->emitTextureLookupAndModulate(outputColor, samplerName);
}
static inline StageKey GenKey(const GrCustomStage&, const GrGLCaps&) { return 0; }
builder->getUniformCStr(fNameUni),
builder->getUniformCStr(fNameUni));
- builder->fFSCode.appendf("\t%s = ", outputColor);
- builder->appendTextureLookupAndModulate(&builder->fFSCode, inputColor, samplerName, "clampCoord");
- builder->fFSCode.append(";\n");
+ builder->emitTextureLookupAndModulate(outputColor, samplerName, "clampCoord");
}
void GrGLTextureDomainEffect::setData(const GrGLUniformManager& uman,
builder->fVSCode.appendf("\t}\n");
builder->computeSwizzle(desc.fInConfigFlags);
+ builder->computeModulate(fsInColor);
// Enclose custom code in a block to avoid namespace conflicts
builder->fFSCode.appendf("\t{ // stage %d %s \n",
outAppend->append(GrGLSLZerosVecf(4));
return kZeros_GrSLConstantVec;
} else {
- // both inputs are ones vectors
outAppend->append(GrGLSLOnesVecf(4));
return kOnes_GrSLConstantVec;
}
}
}
-namespace {
-void append_tabs(SkString* outAppend, int tabCnt) {
- static const char kTabs[] = "\t\t\t\t\t\t\t\t";
- while (tabCnt) {
- int cnt = GrMin((int)GR_ARRAY_COUNT(kTabs), tabCnt);
- outAppend->append(kTabs, cnt);
- tabCnt -= cnt;
- }
-}
-}
-
-GrSLConstantVec GrGLSLMulVarBy4f(SkString* outAppend,
- int tabCnt,
- const char* vec4VarName,
- const char* mulFactor,
- GrSLConstantVec mulFactorDefault) {
- bool haveFactor = NULL != mulFactor && '\0' != *mulFactor;
-
- GrAssert(NULL != outAppend);
- GrAssert(NULL != vec4VarName);
- GrAssert(kNone_GrSLConstantVec != mulFactorDefault || haveFactor);
-
- if (!haveFactor) {
- if (kOnes_GrSLConstantVec == mulFactorDefault) {
- return kNone_GrSLConstantVec;
- } else {
- GrAssert(kZeros_GrSLConstantVec == mulFactorDefault);
- append_tabs(outAppend, tabCnt);
- outAppend->appendf("%s = vec4(0, 0, 0, 0);\n", vec4VarName);
- return kZeros_GrSLConstantVec;
- }
- }
- append_tabs(outAppend, tabCnt);
- outAppend->appendf("%s *= %s;\n", vec4VarName, mulFactor);
- return kNone_GrSLConstantVec;
-}
-
GrSLConstantVec GrGLSLAdd4f(SkString* outAppend,
const char* in0,
const char* in1,
GrSLConstantVec default0 = kOnes_GrSLConstantVec,
GrSLConstantVec default1 = kOnes_GrSLConstantVec);
-/**
- * Does an inplace mul, *=, of vec4VarName by mulFactor. If mulFactorDefault is not kNone then
- * mulFactor may be either "" or NULL. In this case either nothing will be appened (kOnes) or an
- * assignment of vec(0,0,0,0) will be appended (kZeros). The assignment is prepended by tabCnt tabs.
- * A semicolon and newline are added after the assignment. (TODO: Remove tabCnt when we auto-insert
- * tabs to custom stage-generated lines.) If a zeros vec is assigned then the return value is
- * kZeros, otherwise kNone.
- */
-GrSLConstantVec GrGLSLMulVarBy4f(SkString* outAppend,
- int tabCnt,
- const char* vec4VarName,
- const char* mulFactor,
- GrSLConstantVec mulFactorDefault = kOnes_GrSLConstantVec);
/**
* Produces a string that is the result of adding two inputs. The inputs must be vec4 or float.
}
}
+void GrGLShaderBuilder::computeModulate(const char* fsInColor) {
+ if (NULL != fsInColor) {
+ fModulate.printf(" * %s", fsInColor);
+ } else {
+ fModulate.reset();
+ }
+}
+
void GrGLShaderBuilder::setupTextureAccess(const char* varyingFSName, GrSLType varyingType) {
// FIXME: We don't know how the custom stage will manipulate the coords. So we give up on using
// projective texturing and always give the stage 2D coords. This will be fixed when custom
}
}
-void GrGLShaderBuilder::appendTextureLookup(SkString* out,
- const char* samplerName,
- const char* coordName,
- GrSLType varyingType) const {
+void GrGLShaderBuilder::emitTextureLookup(const char* samplerName,
+ const char* coordName,
+ GrSLType varyingType) {
if (NULL == coordName) {
coordName = fDefaultTexCoordsName.c_str();
varyingType = kVec2f_GrSLType;
}
- out->appendf("%s(%s, %s)", sample_function_name(varyingType), samplerName, coordName);
+ fFSCode.appendf("%s(%s, %s)", sample_function_name(varyingType), samplerName, coordName);
}
-void GrGLShaderBuilder::appendTextureLookupAndModulate(SkString* out,
- const char* modulation,
- const char* samplerName,
- const char* coordName,
- GrSLType varyingType) const {
- GrAssert(NULL != out);
- SkString lookup;
- this->appendTextureLookup(&lookup, samplerName, coordName, varyingType);
- GrGLSLModulate4f(out, modulation, lookup.c_str());
- out->append(fSwizzle.c_str());
+void GrGLShaderBuilder::emitTextureLookupAndModulate(const char* outColor,
+ const char* samplerName,
+ const char* coordName,
+ GrSLType varyingType) {
+ fFSCode.appendf("\t%s = ", outColor);
+ this->emitTextureLookup(samplerName, coordName, varyingType);
+ fFSCode.appendf("%s%s;\n", fSwizzle.c_str(), fModulate.c_str());
}
void GrGLShaderBuilder::emitCustomTextureLookup(const GrTextureAccess& textureAccess,
GrGLShaderBuilder(const GrGLContextInfo&, GrGLUniformManager&);
void computeSwizzle(uint32_t configFlags);
+ void computeModulate(const char* fsInColor);
/** Determines whether we should use texture2D() or texture2Dproj(), and if an explicit divide
is required for the sample coordinates, creates the new variable and emits the code to
/** texture2D(samplerName, coordName), with projection if necessary; if coordName is not
specified, uses fSampleCoords. coordType must either be Vec2f or Vec3f. The latter is
interpreted as projective texture coords. */
- void appendTextureLookup(SkString* out,
- const char* samplerName,
- const char* coordName = NULL,
- GrSLType coordType = kVec2f_GrSLType) const;
-
- /** appends a texture lookup, with swizzle as necessary. If coordName is NULL then it as if
- defaultTexCoordsName() was passed. coordType must be either kVec2f or kVec3f. If modulateVar
- is not NULL or "" then the texture lookup will be modulated by it. modulation must refer to
- be expression that evaluates to a float or vec4. */
- void appendTextureLookupAndModulate(SkString* out,
- const char* modulation,
- const char* samplerName,
- const char* coordName = NULL,
- GrSLType varyingType = kVec2f_GrSLType) const;
+ void emitTextureLookup(const char* samplerName,
+ const char* coordName = NULL,
+ GrSLType coordType = kVec2f_GrSLType);
+
+ /** sets outColor to results of texture lookup, with swizzle, and/or modulate as necessary. If
+ coordName is NULL then it as if defaultTexCoordsName() was passed. coordType must be either
+ kVec2f or kVec3f. */
+ void emitTextureLookupAndModulate(const char* outColor,
+ const char* samplerName,
+ const char* coordName = NULL,
+ GrSLType coordType = kVec2f_GrSLType);
/** Gets the name of the default texture coords which are always kVec2f */
const char* defaultTexCoordsName() const { return fDefaultTexCoordsName.c_str(); }
//@{
SkString fSwizzle;
+ SkString fModulate;
//@}
projects / platform / upstream / libSkiaSharp.git / commitdiff