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skia / skia / 38efb0d355c1a4d834cb73d63e9ad87ac78dd942 / . / src / sksl / SkSLCPPCodeGenerator.cpp
blob: 7b35ca8f90cbb3e3f51053d2de65c87a79b1536a [file] [log] [blame]
/*
* 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 "SkSLCPPCodeGenerator.h"
#include "SkSLCompiler.h"
#include "SkSLHCodeGenerator.h"
namespace SkSL {
static bool needs_uniform_var(const Variable& var) {
return (var.fModifiers.fFlags & Modifiers::kUniform_Flag) &&
var.fType.kind() != Type::kSampler_Kind;
}
CPPCodeGenerator::CPPCodeGenerator(const Context* context, const Program* program,
ErrorReporter* errors, String name, OutputStream* out)
: INHERITED(context, program, errors, out)
, fName(std::move(name))
, fFullName(String::printf("Gr%s", fName.c_str()))
, fSectionAndParameterHelper(*program, *errors) {
fLineEnding = "\\n";
}
void CPPCodeGenerator::writef(const char* s, va_list va) {
static constexpr int BUFFER_SIZE = 1024;
va_list copy;
va_copy(copy, va);
char buffer[BUFFER_SIZE];
int length = vsnprintf(buffer, BUFFER_SIZE, s, va);
if (length < BUFFER_SIZE) {
fOut->write(buffer, length);
} else {
std::unique_ptr<char[]> heap(new char[length + 1]);
vsprintf(heap.get(), s, copy);
fOut->write(heap.get(), length);
}
}
void CPPCodeGenerator::writef(const char* s, ...) {
va_list va;
va_start(va, s);
this->writef(s, va);
va_end(va);
}
void CPPCodeGenerator::writeHeader() {
}
bool CPPCodeGenerator::usesPrecisionModifiers() const {
return false;
}
String CPPCodeGenerator::getTypeName(const Type& type) {
return type.name();
}
void CPPCodeGenerator::writeBinaryExpression(const BinaryExpression& b,
Precedence parentPrecedence) {
if (b.fOperator == Token::PERCENT) {
// need to use "%%" instead of "%" b/c the code will be inside of a printf
Precedence precedence = GetBinaryPrecedence(b.fOperator);
if (precedence >= parentPrecedence) {
this->write("(");
}
this->writeExpression(*b.fLeft, precedence);
this->write(" %% ");
this->writeExpression(*b.fRight, precedence);
if (precedence >= parentPrecedence) {
this->write(")");
}
} else {
INHERITED::writeBinaryExpression(b, parentPrecedence);
}
}
void CPPCodeGenerator::writeIndexExpression(const IndexExpression& i) {
const Expression& base = *i.fBase;
if (base.fKind == Expression::kVariableReference_Kind) {
int builtin = ((VariableReference&) base).fVariable.fModifiers.fLayout.fBuiltin;
if (SK_TRANSFORMEDCOORDS2D_BUILTIN == builtin) {
this->write("%s");
if (i.fIndex->fKind != Expression::kIntLiteral_Kind) {
fErrors.error(i.fIndex->fOffset,
"index into sk_TransformedCoords2D must be an integer literal");
return;
}
int64_t index = ((IntLiteral&) *i.fIndex).fValue;
String name = "sk_TransformedCoords2D_" + to_string(index);
fFormatArgs.push_back(name + ".c_str()");
if (fWrittenTransformedCoords.find(index) == fWrittenTransformedCoords.end()) {
fExtraEmitCodeCode += " SkString " + name +
" = fragBuilder->ensureCoords2D(args.fTransformedCoords[" +
to_string(index) + "]);\n";
fWrittenTransformedCoords.insert(index);
}
return;
} else if (SK_TEXTURESAMPLERS_BUILTIN == builtin) {
this->write("%s");
if (i.fIndex->fKind != Expression::kIntLiteral_Kind) {
fErrors.error(i.fIndex->fOffset,
"index into sk_TextureSamplers must be an integer literal");
return;
}
int64_t index = ((IntLiteral&) *i.fIndex).fValue;
fFormatArgs.push_back(" fragBuilder->getProgramBuilder()->samplerVariable("
"args.fTexSamplers[" + to_string(index) + "]).c_str()");
return;
}
}
INHERITED::writeIndexExpression(i);
}
static String default_value(const Type& type) {
if (type.fName == "bool") {
return "false";
}
switch (type.kind()) {
case Type::kScalar_Kind: return "0";
case Type::kVector_Kind: return type.name() + "(0)";
case Type::kMatrix_Kind: return type.name() + "(1)";
default: ABORT("unsupported default_value type\n");
}
}
static String default_value(const Variable& var) {
if (var.fModifiers.fLayout.fCType == "GrColor4f") {
return "GrColor4f::kIllegalConstructor";
}
return default_value(var.fType);
}
static bool is_private(const Variable& var) {
return !(var.fModifiers.fFlags & Modifiers::kUniform_Flag) &&
!(var.fModifiers.fFlags & Modifiers::kIn_Flag) &&
var.fStorage == Variable::kGlobal_Storage &&
var.fModifiers.fLayout.fBuiltin == -1;
}
void CPPCodeGenerator::writeRuntimeValue(const Type& type, const Layout& layout,
const String& cppCode) {
if (type.isFloat()) {
this->write("%f");
fFormatArgs.push_back(cppCode);
} else if (type == *fContext.fInt_Type) {
this->write("%d");
fFormatArgs.push_back(cppCode);
} else if (type == *fContext.fBool_Type) {
this->write("%s");
fFormatArgs.push_back("(" + cppCode + " ? \"true\" : \"false\")");
} else if (type == *fContext.fFloat2_Type || type == *fContext.fHalf2_Type) {
this->write(type.name() + "(%f, %f)");
fFormatArgs.push_back(cppCode + ".fX");
fFormatArgs.push_back(cppCode + ".fY");
} else if (type == *fContext.fFloat4_Type || type == *fContext.fHalf4_Type) {
this->write(type.name() + "(%f, %f, %f, %f)");
if (layout.fCType == "SkPMColor") {
fFormatArgs.push_back("SkGetPackedR32(" + cppCode + ") / 255.0");
fFormatArgs.push_back("SkGetPackedG32(" + cppCode + ") / 255.0");
fFormatArgs.push_back("SkGetPackedB32(" + cppCode + ") / 255.0");
fFormatArgs.push_back("SkGetPackedA32(" + cppCode + ") / 255.0");
} else if (layout.fCType == "GrColor4f") {
fFormatArgs.push_back(cppCode + ".fRGBA[0]");
fFormatArgs.push_back(cppCode + ".fRGBA[1]");
fFormatArgs.push_back(cppCode + ".fRGBA[2]");
fFormatArgs.push_back(cppCode + ".fRGBA[3]");
} else {
fFormatArgs.push_back(cppCode + ".left()");
fFormatArgs.push_back(cppCode + ".top()");
fFormatArgs.push_back(cppCode + ".right()");
fFormatArgs.push_back(cppCode + ".bottom()");
}
} else if (type.kind() == Type::kEnum_Kind) {
this->write("%d");
fFormatArgs.push_back("(int) " + cppCode);
} else if (type == *fContext.fInt4_Type || type == *fContext.fShort4_Type) {
this->write(type.name() + "(%d, %d, %d, %d)");
fFormatArgs.push_back(cppCode + ".left()");
fFormatArgs.push_back(cppCode + ".top()");
fFormatArgs.push_back(cppCode + ".right()");
fFormatArgs.push_back(cppCode + ".bottom()");
} else {
printf("unsupported runtime value type '%s'\n", String(type.fName).c_str());
ASSERT(false);
}
}
void CPPCodeGenerator::writeVarInitializer(const Variable& var, const Expression& value) {
if (is_private(var)) {
this->writeRuntimeValue(var.fType, var.fModifiers.fLayout, var.fName);
} else {
this->writeExpression(value, kTopLevel_Precedence);
}
}
String CPPCodeGenerator::getSamplerHandle(const Variable& var) {
int samplerCount = 0;
for (const auto param : fSectionAndParameterHelper.getParameters()) {
if (&var == param) {
return "args.fTexSamplers[" + to_string(samplerCount) + "]";
}
if (param->fType.kind() == Type::kSampler_Kind) {
++samplerCount;
}
}
ABORT("should have found sampler in parameters\n");
}
void CPPCodeGenerator::writeIntLiteral(const IntLiteral& i) {
this->write(to_string((int32_t) i.fValue));
}
void CPPCodeGenerator::writeSwizzle(const Swizzle& swizzle) {
if (fCPPMode) {
ASSERT(swizzle.fComponents.size() == 1); // no support for multiple swizzle components yet
this->writeExpression(*swizzle.fBase, kPostfix_Precedence);
switch (swizzle.fComponents[0]) {
case 0: this->write(".left()"); break;
case 1: this->write(".top()"); break;
case 2: this->write(".right()"); break;
case 3: this->write(".bottom()"); break;
}
} else {
INHERITED::writeSwizzle(swizzle);
}
}
void CPPCodeGenerator::writeVariableReference(const VariableReference& ref) {
if (fCPPMode) {
this->write(ref.fVariable.fName);
return;
}
switch (ref.fVariable.fModifiers.fLayout.fBuiltin) {
case SK_INCOLOR_BUILTIN:
this->write("%s");
fFormatArgs.push_back(String("args.fInputColor ? args.fInputColor : \"half4(1)\""));
break;
case SK_OUTCOLOR_BUILTIN:
this->write("%s");
fFormatArgs.push_back(String("args.fOutputColor"));
break;
default:
if (ref.fVariable.fType.kind() == Type::kSampler_Kind) {
this->write("%s");
fFormatArgs.push_back("fragBuilder->getProgramBuilder()->samplerVariable(" +
this->getSamplerHandle(ref.fVariable) + ").c_str()");
return;
}
if (ref.fVariable.fModifiers.fFlags & Modifiers::kUniform_Flag) {
this->write("%s");
String name = ref.fVariable.fName;
String var = String::printf("args.fUniformHandler->getUniformCStr(%sVar)",
HCodeGenerator::FieldName(name.c_str()).c_str());
String code;
if (ref.fVariable.fModifiers.fLayout.fWhen.size()) {
code = String::printf("%sVar.isValid() ? %s : \"%s\"",
HCodeGenerator::FieldName(name.c_str()).c_str(),
var.c_str(),
default_value(ref.fVariable.fType).c_str());
} else {
code = var;
}
fFormatArgs.push_back(code);
} else if (SectionAndParameterHelper::IsParameter(ref.fVariable)) {
String name(ref.fVariable.fName);
this->writeRuntimeValue(ref.fVariable.fType, ref.fVariable.fModifiers.fLayout,
String::printf("_outer.%s()", name.c_str()).c_str());
} else {
this->write(ref.fVariable.fName);
}
}
}
void CPPCodeGenerator::writeIfStatement(const IfStatement& s) {
if (s.fIsStatic) {
this->write("@");
}
INHERITED::writeIfStatement(s);
}
void CPPCodeGenerator::writeSwitchStatement(const SwitchStatement& s) {
if (s.fIsStatic) {
this->write("@");
}
INHERITED::writeSwitchStatement(s);
}
void CPPCodeGenerator::writeFunctionCall(const FunctionCall& c) {
if (c.fFunction.fBuiltin && c.fFunction.fName == "process") {
ASSERT(c.fArguments.size() == 1);
ASSERT(Expression::kVariableReference_Kind == c.fArguments[0]->fKind);
int index = 0;
bool found = false;
for (const auto& p : fProgram.fElements) {
if (ProgramElement::kVar_Kind == p->fKind) {
const VarDeclarations* decls = (const VarDeclarations*) p.get();
for (const auto& raw : decls->fVars) {
VarDeclaration& decl = (VarDeclaration&) *raw;
if (decl.fVar == &((VariableReference&) *c.fArguments[0]).fVariable) {
found = true;
} else if (decl.fVar->fType == *fContext.fFragmentProcessor_Type) {
++index;
}
}
}
if (found) {
break;
}
}
ASSERT(found);
String childName = "_child" + to_string(index);
fExtraEmitCodeCode += " SkString " + childName + "(\"" + childName + "\");\n" +
" this->emitChild(" + to_string(index) + ", &" + childName +
", args);\n";
this->write("%s");
fFormatArgs.push_back(childName + ".c_str()");
return;
}
INHERITED::writeFunctionCall(c);
if (c.fFunction.fBuiltin && c.fFunction.fName == "texture") {
this->write(".%s");
ASSERT(c.fArguments.size() >= 1);
ASSERT(c.fArguments[0]->fKind == Expression::kVariableReference_Kind);
String sampler = this->getSamplerHandle(((VariableReference&) *c.fArguments[0]).fVariable);
fFormatArgs.push_back("fragBuilder->getProgramBuilder()->samplerSwizzle(" + sampler +
").c_str()");
}
}
void CPPCodeGenerator::writeFunction(const FunctionDefinition& f) {
if (f.fDeclaration.fName == "main") {
fFunctionHeader = "";
OutputStream* oldOut = fOut;
StringStream buffer;
fOut = &buffer;
for (const auto& s : ((Block&) *f.fBody).fStatements) {
this->writeStatement(*s);
this->writeLine();
}
fOut = oldOut;
this->write(fFunctionHeader);
this->write(buffer.str());
} else {
INHERITED::writeFunction(f);
}
}
void CPPCodeGenerator::writeSetting(const Setting& s) {
static constexpr const char* kPrefix = "sk_Args.";
if (!strncmp(s.fName.c_str(), kPrefix, strlen(kPrefix))) {
const char* name = s.fName.c_str() + strlen(kPrefix);
this->writeRuntimeValue(s.fType, Layout(), HCodeGenerator::FieldName(name).c_str());
} else {
this->write(s.fName.c_str());
}
}
bool CPPCodeGenerator::writeSection(const char* name, const char* prefix) {
const Section* s = fSectionAndParameterHelper.getSection(name);
if (s) {
this->writef("%s%s", prefix, s->fText.c_str());
return true;
}
return false;
}
void CPPCodeGenerator::writeProgramElement(const ProgramElement& p) {
if (p.fKind == ProgramElement::kSection_Kind) {
return;
}
if (p.fKind == ProgramElement::kVar_Kind) {
const VarDeclarations& decls = (const VarDeclarations&) p;
if (!decls.fVars.size()) {
return;
}
const Variable& var = *((VarDeclaration&) *decls.fVars[0]).fVar;
if (var.fModifiers.fFlags & (Modifiers::kIn_Flag | Modifiers::kUniform_Flag) ||
-1 != var.fModifiers.fLayout.fBuiltin) {
return;
}
}
INHERITED::writeProgramElement(p);
}
void CPPCodeGenerator::addUniform(const Variable& var) {
if (!needs_uniform_var(var)) {
return;
}
const char* precision;
if (var.fModifiers.fFlags & Modifiers::kHighp_Flag) {
precision = "kHigh_GrSLPrecision";
} else if (var.fModifiers.fFlags & Modifiers::kMediump_Flag) {
precision = "kMedium_GrSLPrecision";
} else if (var.fModifiers.fFlags & Modifiers::kLowp_Flag) {
precision = "kLow_GrSLPrecision";
} else {
precision = "kDefault_GrSLPrecision";
}
const char* type;
if (var.fType == *fContext.fFloat_Type) {
type = "kFloat_GrSLType";
} else if (var.fType == *fContext.fHalf_Type) {
type = "kHalf_GrSLType";
} else if (var.fType == *fContext.fFloat2_Type) {
type = "kFloat2_GrSLType";
} else if (var.fType == *fContext.fHalf2_Type) {
type = "kHalf2_GrSLType";
} else if (var.fType == *fContext.fFloat4_Type) {
type = "kFloat4_GrSLType";
} else if (var.fType == *fContext.fHalf4_Type) {
type = "kHalf4_GrSLType";
} else if (var.fType == *fContext.fFloat4x4_Type) {
type = "kFloat4x4_GrSLType";
} else if (var.fType == *fContext.fHalf4x4_Type) {
type = "kHalf4x4_GrSLType";
} else {
ABORT("unsupported uniform type: %s %s;\n", String(var.fType.fName).c_str(),
String(var.fName).c_str());
}
if (var.fModifiers.fLayout.fWhen.size()) {
this->writef(" if (%s) {\n ", var.fModifiers.fLayout.fWhen.c_str());
}
String name(var.fName);
this->writef(" %sVar = args.fUniformHandler->addUniform(kFragment_GrShaderFlag, %s, "
"%s, \"%s\");\n", HCodeGenerator::FieldName(name.c_str()).c_str(), type, precision,
name.c_str());
if (var.fModifiers.fLayout.fWhen.size()) {
this->write(" }\n");
}
}
void CPPCodeGenerator::writePrivateVars() {
for (const auto& p : fProgram.fElements) {
if (ProgramElement::kVar_Kind == p->fKind) {
const VarDeclarations* decls = (const VarDeclarations*) p.get();
for (const auto& raw : decls->fVars) {
VarDeclaration& decl = (VarDeclaration&) *raw;
if (is_private(*decl.fVar)) {
if (decl.fVar->fType == *fContext.fFragmentProcessor_Type) {
fErrors.error(decl.fOffset,
"fragmentProcessor variables must be declared 'in'");
return;
}
this->writef("%s %s = %s;\n",
HCodeGenerator::FieldType(fContext, decl.fVar->fType,
decl.fVar->fModifiers.fLayout).c_str(),
String(decl.fVar->fName).c_str(),
default_value(*decl.fVar).c_str());
}
}
}
}
}
void CPPCodeGenerator::writePrivateVarValues() {
for (const auto& p : fProgram.fElements) {
if (ProgramElement::kVar_Kind == p->fKind) {
const VarDeclarations* decls = (const VarDeclarations*) p.get();
for (const auto& raw : decls->fVars) {
VarDeclaration& decl = (VarDeclaration&) *raw;
if (is_private(*decl.fVar) && decl.fValue) {
this->writef("%s = ", String(decl.fVar->fName).c_str());
fCPPMode = true;
this->writeExpression(*decl.fValue, kAssignment_Precedence);
fCPPMode = false;
this->write(";\n");
}
}
}
}
}
static bool is_accessible(const Variable& var) {
return Type::kSampler_Kind != var.fType.kind() &&
Type::kOther_Kind != var.fType.kind();
}
void CPPCodeGenerator::writeCodeAppend(const String& code) {
// codeAppendf can only handle appending 1024 bytes at a time, so we need to break the string
// into chunks. Unfortunately we can't tell exactly how long the string is going to end up,
// because printf escape sequences get replaced by strings of unknown length, but keeping the
// format string below 512 bytes is probably safe.
static constexpr size_t maxChunkSize = 512;
size_t start = 0;
size_t index = 0;
size_t argStart = 0;
size_t argCount;
while (index < code.size()) {
argCount = 0;
this->write(" fragBuilder->codeAppendf(\"");
while (index < code.size() && index < start + maxChunkSize) {
if ('%' == code[index]) {
if (index == start + maxChunkSize - 1 || index == code.size() - 1) {
break;
}
if (code[index + 1] != '%') {
++argCount;
}
} else if ('\\' == code[index] && index == start + maxChunkSize - 1) {
// avoid splitting an escape sequence that happens to fall across a chunk boundary
break;
}
++index;
}
fOut->write(code.c_str() + start, index - start);
this->write("\"");
for (size_t i = argStart; i < argStart + argCount; ++i) {
this->writef(", %s", fFormatArgs[i].c_str());
}
this->write(");\n");
argStart += argCount;
start = index;
}
}
bool CPPCodeGenerator::writeEmitCode(std::vector<const Variable*>& uniforms) {
this->write(" void emitCode(EmitArgs& args) override {\n"
" GrGLSLFPFragmentBuilder* fragBuilder = args.fFragBuilder;\n");
this->writef(" const %s& _outer = args.fFp.cast<%s>();\n"
" (void) _outer;\n",
fFullName.c_str(), fFullName.c_str());
for (const auto& p : fProgram.fElements) {
if (ProgramElement::kVar_Kind == p->fKind) {
const VarDeclarations* decls = (const VarDeclarations*) p.get();
for (const auto& raw : decls->fVars) {
VarDeclaration& decl = (VarDeclaration&) *raw;
String nameString(decl.fVar->fName);
const char* name = nameString.c_str();
if (SectionAndParameterHelper::IsParameter(*decl.fVar) &&
is_accessible(*decl.fVar)) {
this->writef(" auto %s = _outer.%s();\n"
" (void) %s;\n",
name, name, name);
}
}
}
}
this->writePrivateVarValues();
for (const auto u : uniforms) {
this->addUniform(*u);
}
this->writeSection(EMIT_CODE_SECTION);
OutputStream* old = fOut;
StringStream mainBuffer;
fOut = &mainBuffer;
bool result = INHERITED::generateCode();
fOut = old;
this->writef("%s", fExtraEmitCodeCode.c_str());
this->writeCodeAppend(mainBuffer.str());
this->write(" }\n");
return result;
}
void CPPCodeGenerator::writeSetData(std::vector<const Variable*>& uniforms) {
const char* fullName = fFullName.c_str();
const Section* section = fSectionAndParameterHelper.getSection(SET_DATA_SECTION);
const char* pdman = section ? section->fArgument.c_str() : "pdman";
this->writef(" void onSetData(const GrGLSLProgramDataManager& %s, "
"const GrFragmentProcessor& _proc) override {\n",
pdman);
bool wroteProcessor = false;
for (const auto u : uniforms) {
if (u->fModifiers.fFlags & Modifiers::kIn_Flag) {
if (!wroteProcessor) {
this->writef(" const %s& _outer = _proc.cast<%s>();\n", fullName, fullName);
wroteProcessor = true;
this->writef(" {\n");
}
String nameString(u->fName);
const char* name = nameString.c_str();
if (u->fType == *fContext.fFloat4_Type || u->fType == *fContext.fHalf4_Type) {
this->writef(" const SkRect %sValue = _outer.%s();\n"
" %s.set4fv(%sVar, 1, (float*) &%sValue);\n",
name, name, pdman, HCodeGenerator::FieldName(name).c_str(), name);
} else if (u->fType == *fContext.fFloat4x4_Type ||
u->fType == *fContext.fHalf4x4_Type) {
this->writef(" float %sValue[16];\n"
" _outer.%s().asColMajorf(%sValue);\n"
" %s.setMatrix4f(%sVar, %sValue);\n",
name, name, name, pdman, HCodeGenerator::FieldName(name).c_str(),
name);
} else if (u->fType == *fContext.fFragmentProcessor_Type) {
// do nothing
} else {
this->writef(" %s.set1f(%sVar, _outer.%s());\n",
pdman, HCodeGenerator::FieldName(name).c_str(), name);
}
}
}
if (wroteProcessor) {
this->writef(" }\n");
}
if (section) {
int samplerIndex = 0;
for (const auto& p : fProgram.fElements) {
if (ProgramElement::kVar_Kind == p->fKind) {
const VarDeclarations* decls = (const VarDeclarations*) p.get();
for (const auto& raw : decls->fVars) {
VarDeclaration& decl = (VarDeclaration&) *raw;
String nameString(decl.fVar->fName);
const char* name = nameString.c_str();
if (decl.fVar->fType.kind() == Type::kSampler_Kind) {
this->writef(" GrSurfaceProxy& %sProxy = "
"*_outer.textureSampler(%d).proxy();\n",
name, samplerIndex);
this->writef(" GrTexture& %s = *%sProxy.priv().peekTexture();\n",
name, name);
this->writef(" (void) %s;\n", name);
++samplerIndex;
} else if (needs_uniform_var(*decl.fVar)) {
this->writef(" UniformHandle& %s = %sVar;\n"
" (void) %s;\n",
name, HCodeGenerator::FieldName(name).c_str(), name);
} else if (SectionAndParameterHelper::IsParameter(*decl.fVar) &&
decl.fVar->fType != *fContext.fFragmentProcessor_Type) {
if (!wroteProcessor) {
this->writef(" const %s& _outer = _proc.cast<%s>();\n", fullName,
fullName);
wroteProcessor = true;
}
this->writef(" auto %s = _outer.%s();\n"
" (void) %s;\n",
name, name, name);
}
}
}
}
this->writeSection(SET_DATA_SECTION);
}
this->write(" }\n");
}
void CPPCodeGenerator::writeClone() {
if (!this->writeSection(CLONE_SECTION)) {
if (fSectionAndParameterHelper.getSection(FIELDS_SECTION)) {
fErrors.error(0, "fragment processors with custom @fields must also have a custom"
"@clone");
}
this->writef("%s::%s(const %s& src)\n"
": INHERITED(k%s_ClassID, src.optimizationFlags())", fFullName.c_str(),
fFullName.c_str(), fFullName.c_str(), fFullName.c_str());
for (const auto& param : fSectionAndParameterHelper.getParameters()) {
if (param->fType == *fContext.fFragmentProcessor_Type) {
continue;
}
String fieldName = HCodeGenerator::FieldName(String(param->fName).c_str());
this->writef("\n, %s(src.%s)",
fieldName.c_str(),
fieldName.c_str());
}
for (const Section* s : fSectionAndParameterHelper.getSections(COORD_TRANSFORM_SECTION)) {
String fieldName = HCodeGenerator::FieldName(s->fArgument.c_str());
this->writef("\n, %sCoordTransform(src.%sCoordTransform)", fieldName.c_str(),
fieldName.c_str());
}
this->writef(" {\n");
int childCount = 0;
for (const auto& param : fSectionAndParameterHelper.getParameters()) {
if (param->fType.kind() == Type::kSampler_Kind) {
this->writef(" this->addTextureSampler(&%s);\n",
HCodeGenerator::FieldName(String(param->fName).c_str()).c_str());
} else if (param->fType == *fContext.fFragmentProcessor_Type) {
this->writef(" this->registerChildProcessor(src.childProcessor(%d).clone());"
"\n", childCount++);
}
}
for (const Section* s : fSectionAndParameterHelper.getSections(COORD_TRANSFORM_SECTION)) {
String field = HCodeGenerator::FieldName(s->fArgument.c_str());
this->writef(" this->addCoordTransform(&%sCoordTransform);\n", field.c_str());
}
this->write("}\n");
this->writef("std::unique_ptr<GrFragmentProcessor> %s::clone() const {\n",
fFullName.c_str());
this->writef(" return std::unique_ptr<GrFragmentProcessor>(new %s(*this));\n",
fFullName.c_str());
this->write("}\n");
}
}
void CPPCodeGenerator::writeTest() {
const Section* test = fSectionAndParameterHelper.getSection(TEST_CODE_SECTION);
if (test) {
this->writef(
"GR_DEFINE_FRAGMENT_PROCESSOR_TEST(%s);\n"
"#if GR_TEST_UTILS\n"
"std::unique_ptr<GrFragmentProcessor> %s::TestCreate(GrProcessorTestData* %s) {\n",
fFullName.c_str(),
fFullName.c_str(),
test->fArgument.c_str());
this->writeSection(TEST_CODE_SECTION);
this->write("}\n"
"#endif\n");
}
}
void CPPCodeGenerator::writeGetKey() {
this->writef("void %s::onGetGLSLProcessorKey(const GrShaderCaps& caps, "
"GrProcessorKeyBuilder* b) const {\n",
fFullName.c_str());
for (const auto& param : fSectionAndParameterHelper.getParameters()) {
String nameString(param->fName);
const char* name = nameString.c_str();
if (param->fModifiers.fLayout.fKey != Layout::kNo_Key &&
(param->fModifiers.fFlags & Modifiers::kUniform_Flag)) {
fErrors.error(param->fOffset,
"layout(key) may not be specified on uniforms");
}
switch (param->fModifiers.fLayout.fKey) {
case Layout::kKey_Key:
if (param->fType == *fContext.fFloat4x4_Type) {
ABORT("no automatic key handling for float4x4\n");
} else if (param->fType == *fContext.fFloat2_Type) {
this->writef(" b->add32(%s.fX);\n",
HCodeGenerator::FieldName(name).c_str());
this->writef(" b->add32(%s.fY);\n",
HCodeGenerator::FieldName(name).c_str());
} else if (param->fType == *fContext.fFloat4_Type) {
this->writef(" b->add32(%s.x());\n",
HCodeGenerator::FieldName(name).c_str());
this->writef(" b->add32(%s.y());\n",
HCodeGenerator::FieldName(name).c_str());
this->writef(" b->add32(%s.width());\n",
HCodeGenerator::FieldName(name).c_str());
this->writef(" b->add32(%s.height());\n",
HCodeGenerator::FieldName(name).c_str());
} else {
this->writef(" b->add32((int32_t) %s);\n",
HCodeGenerator::FieldName(name).c_str());
}
break;
case Layout::kIdentity_Key:
if (param->fType.kind() != Type::kMatrix_Kind) {
fErrors.error(param->fOffset,
"layout(key=identity) requires matrix type");
}
this->writef(" b->add32(%s.isIdentity() ? 1 : 0);\n",
HCodeGenerator::FieldName(name).c_str());
break;
case Layout::kNo_Key:
break;
}
}
this->write("}\n");
}
bool CPPCodeGenerator::generateCode() {
std::vector<const Variable*> uniforms;
for (const auto& p : fProgram.fElements) {
if (ProgramElement::kVar_Kind == p->fKind) {
const VarDeclarations* decls = (const VarDeclarations*) p.get();
for (const auto& raw : decls->fVars) {
VarDeclaration& decl = (VarDeclaration&) *raw;
if ((decl.fVar->fModifiers.fFlags & Modifiers::kUniform_Flag) &&
decl.fVar->fType.kind() != Type::kSampler_Kind) {
uniforms.push_back(decl.fVar);
}
}
}
}
const char* baseName = fName.c_str();
const char* fullName = fFullName.c_str();
this->writef("%s\n", HCodeGenerator::GetHeader(fProgram, fErrors).c_str());
this->writef(kFragmentProcessorHeader, fullName);
this->writef("#include \"%s.h\"\n"
"#if SK_SUPPORT_GPU\n", fullName);
this->writeSection(CPP_SECTION);
this->writef("#include \"glsl/GrGLSLFragmentProcessor.h\"\n"
"#include \"glsl/GrGLSLFragmentShaderBuilder.h\"\n"
"#include \"glsl/GrGLSLProgramBuilder.h\"\n"
"#include \"GrTexture.h\"\n"
"#include \"SkSLCPP.h\"\n"
"#include \"SkSLUtil.h\"\n"
"class GrGLSL%s : public GrGLSLFragmentProcessor {\n"
"public:\n"
" GrGLSL%s() {}\n",
baseName, baseName);
bool result = this->writeEmitCode(uniforms);
this->write("private:\n");
this->writeSetData(uniforms);
this->writePrivateVars();
for (const auto& u : uniforms) {
if (needs_uniform_var(*u) && !(u->fModifiers.fFlags & Modifiers::kIn_Flag)) {
this->writef(" UniformHandle %sVar;\n",
HCodeGenerator::FieldName(String(u->fName).c_str()).c_str());
}
}
for (const auto& param : fSectionAndParameterHelper.getParameters()) {
if (needs_uniform_var(*param)) {
this->writef(" UniformHandle %sVar;\n",
HCodeGenerator::FieldName(String(param->fName).c_str()).c_str());
}
}
this->writef("};\n"
"GrGLSLFragmentProcessor* %s::onCreateGLSLInstance() const {\n"
" return new GrGLSL%s();\n"
"}\n",
fullName, baseName);
this->writeGetKey();
this->writef("bool %s::onIsEqual(const GrFragmentProcessor& other) const {\n"
" const %s& that = other.cast<%s>();\n"
" (void) that;\n",
fullName, fullName, fullName);
for (const auto& param : fSectionAndParameterHelper.getParameters()) {
if (param->fType == *fContext.fFragmentProcessor_Type) {
continue;
}
String nameString(param->fName);
const char* name = nameString.c_str();
this->writef(" if (%s != that.%s) return false;\n",
HCodeGenerator::FieldName(name).c_str(),
HCodeGenerator::FieldName(name).c_str());
}
this->write(" return true;\n"
"}\n");
this->writeClone();
this->writeTest();
this->writeSection(CPP_END_SECTION);
this->write("#endif\n");
result &= 0 == fErrors.errorCount();
return result;
}
} // namespace