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android / platform / frameworks / compile / slang / android-8.0.0_r31 / . / slang_rs_reflection_cpp.cpp
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/*
* Copyright 2013, The Android Open Source Project
*
* Licensed under the Apache License, Version 2.0 (the "License");
* you may not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* http://www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS,
* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
#include <sys/stat.h>
#include <stdio.h>
#include <stdlib.h>
#include <iostream>
#include <cstdarg>
#include <cctype>
#include <algorithm>
#include <sstream>
#include <string>
#include "os_sep.h"
#include "slang_rs_context.h"
#include "slang_rs_export_var.h"
#include "slang_rs_export_foreach.h"
#include "slang_rs_export_func.h"
#include "slang_rs_reflect_utils.h"
#include "slang_version.h"
#include "slang_rs_reflection_cpp.h"
using namespace std;
namespace slang {
const char kRsTypeItemClassName[] = "Item";
const char kRsElemPrefix[] = "__rs_elem_";
// The name of the Allocation type that is reflected in C++
const char kAllocationSp[] = "android::RSC::sp<android::RSC::Allocation>";
static const char *GetMatrixTypeName(const RSExportMatrixType *EMT) {
static const char *MatrixTypeCNameMap[] = {
"rs_matrix2x2", "rs_matrix3x3", "rs_matrix4x4",
};
unsigned Dim = EMT->getDim();
if ((Dim - 2) < (sizeof(MatrixTypeCNameMap) / sizeof(const char *)))
return MatrixTypeCNameMap[EMT->getDim() - 2];
slangAssert(false && "GetMatrixTypeName : Unsupported matrix dimension");
return nullptr;
}
static std::string GetTypeName(const RSExportType *ET, bool PreIdentifier = true) {
if((!PreIdentifier) && (ET->getClass() != RSExportType::ExportClassConstantArray)) {
slangAssert(false && "Non-array type post identifier?");
return "";
}
switch (ET->getClass()) {
case RSExportType::ExportClassPrimitive: {
const RSExportPrimitiveType *EPT =
static_cast<const RSExportPrimitiveType *>(ET);
if (EPT->isRSObjectType()) {
return std::string("android::RSC::sp<const android::RSC::") +
RSExportPrimitiveType::getRSReflectionType(EPT)->c_name + ">";
} else {
return RSExportPrimitiveType::getRSReflectionType(EPT)->c_name;
}
}
case RSExportType::ExportClassPointer: {
const RSExportType *PointeeType =
static_cast<const RSExportPointerType *>(ET)->getPointeeType();
if (PointeeType->getClass() != RSExportType::ExportClassRecord)
return kAllocationSp;
else
return PointeeType->getElementName();
}
case RSExportType::ExportClassVector: {
const RSExportVectorType *EVT = static_cast<const RSExportVectorType *>(ET);
std::stringstream VecName;
VecName << EVT->getRSReflectionType(EVT)->rs_c_vector_prefix
<< EVT->getNumElement();
return VecName.str();
}
case RSExportType::ExportClassMatrix: {
return GetMatrixTypeName(static_cast<const RSExportMatrixType *>(ET));
}
case RSExportType::ExportClassConstantArray: {
const RSExportConstantArrayType *CAT =
static_cast<const RSExportConstantArrayType *>(ET);
if (PreIdentifier) {
std::string ElementTypeName = GetTypeName(CAT->getElementType());
return ElementTypeName;
}
else {
std::stringstream ArraySpec;
ArraySpec << "[" << CAT->getNumElement() << "]";
return ArraySpec.str();
}
}
case RSExportType::ExportClassRecord: {
// TODO: Fix for C structs!
return ET->getElementName() + "." + kRsTypeItemClassName;
}
default: { slangAssert(false && "Unknown class of type"); }
}
return "";
}
RSReflectionCpp::RSReflectionCpp(const RSContext *Context,
const string &OutputDirectory,
const string &RSSourceFileName,
const string &BitCodeFileName)
: mRSContext(Context), mRSSourceFilePath(RSSourceFileName),
mBitCodeFilePath(BitCodeFileName), mOutputDirectory(OutputDirectory),
mNextExportVarSlot(0), mNextExportFuncSlot(0), mNextExportForEachSlot(0) {
mCleanedRSFileName = RootNameFromRSFileName(mRSSourceFilePath);
mClassName = "ScriptC_" + mCleanedRSFileName;
}
RSReflectionCpp::~RSReflectionCpp() {}
bool RSReflectionCpp::reflect() {
writeHeaderFile();
writeImplementationFile();
return true;
}
#define RS_TYPE_CLASS_NAME_PREFIX "ScriptField_"
bool RSReflectionCpp::writeHeaderFile() {
// Create the file and write the license note.
if (!mOut.startFile(mOutputDirectory, mClassName + ".h", mRSSourceFilePath,
mRSContext->getLicenseNote(), false,
mRSContext->getVerbose())) {
return false;
}
mOut.indent() << "#include \"RenderScript.h\"\n\n";
// Add NOLINT to suppress clang-tidy warnings of "using namespace".
// Keep "using namespace" to compile existing code.
mOut.indent() << "using namespace android::RSC; // NOLINT\n\n";
mOut.comment("This class encapsulates access to the exported elements of the script. "
"Typically, you would instantiate this class once, call the set_* methods "
"for each of the exported global variables you want to change, then call "
"one of the forEach_ methods to invoke a kernel.");
mOut.indent() << "class " << mClassName << " : public android::RSC::ScriptC";
mOut.startBlock();
mOut.decreaseIndent();
mOut.indent() << "private:\n";
mOut.increaseIndent();
genFieldsToStoreExportVariableValues();
genTypeInstancesUsedInForEach();
genFieldsForAllocationTypeVerification();
mOut.decreaseIndent();
mOut.indent() << "public:\n";
mOut.increaseIndent();
// Generate the constructor and destructor declarations.
mOut.indent() << mClassName << "(android::RSC::sp<android::RSC::RS> rs);\n";
mOut.indent() << "virtual ~" << mClassName << "();\n\n";
genExportVariablesGetterAndSetter();
genForEachDeclarations();
genExportFunctionDeclarations();
mOut.endBlock(true);
mOut.closeFile();
return true;
}
void RSReflectionCpp::genTypeInstancesUsedInForEach() {
for (auto I = mRSContext->export_foreach_begin(),
E = mRSContext->export_foreach_end();
I != E; I++) {
const RSExportForEach *EF = *I;
const RSExportType *OET = EF->getOutType();
if (OET) {
genTypeInstanceFromPointer(OET);
}
const RSExportForEach::InTypeVec &InTypes = EF->getInTypes();
for (RSExportForEach::InTypeIter BI = InTypes.begin(),
EI = InTypes.end(); BI != EI; BI++) {
genTypeInstanceFromPointer(*BI);
}
}
}
void RSReflectionCpp::genFieldsForAllocationTypeVerification() {
bool CommentAdded = false;
for (std::set<std::string>::iterator I = mTypesToCheck.begin(),
E = mTypesToCheck.end();
I != E; I++) {
if (!CommentAdded) {
mOut.comment("The following elements are used to verify the types of "
"allocations passed to kernels.");
CommentAdded = true;
}
mOut.indent() << "android::RSC::sp<const android::RSC::Element> "
<< kRsElemPrefix << *I << ";\n";
}
}
void RSReflectionCpp::genFieldsToStoreExportVariableValues() {
bool CommentAdded = false;
for (RSContext::const_export_var_iterator I = mRSContext->export_vars_begin(),
E = mRSContext->export_vars_end();
I != E; I++) {
const RSExportVar *ev = *I;
if (ev->isConst()) {
continue;
}
if (!CommentAdded) {
mOut.comment("For each non-const variable exported by the script, we "
"have an equivalent field. This field contains the last "
"value this variable was set to using the set_ method. "
"This may not be current value of the variable in the "
"script, as the script is free to modify its internal "
"variable without changing this field. If the script "
"initializes the exported variable, the constructor will "
"initialize this field to the same value.");
CommentAdded = true;
}
mOut.indent() << GetTypeName(ev->getType()) << " " RS_EXPORT_VAR_PREFIX
<< ev->getName() << ";\n";
}
}
void RSReflectionCpp::genForEachDeclarations() {
bool CommentAdded = false;
for (RSContext::const_export_foreach_iterator
I = mRSContext->export_foreach_begin(),
E = mRSContext->export_foreach_end();
I != E; I++) {
const RSExportForEach *ForEach = *I;
if (ForEach->isDummyRoot()) {
mOut.indent() << "// No forEach_root(...)\n";
continue;
}
if (!CommentAdded) {
mOut.comment("For each kernel of the script corresponds one method. "
"That method queues the kernel for execution. The kernel "
"may not have completed nor even started by the time this "
"function returns. Calls that extract the data out of the "
"output allocation will wait for the kernels to complete.");
CommentAdded = true;
}
std::string FunctionStart = "void forEach_" + ForEach->getName() + "(";
mOut.indent() << FunctionStart;
ArgumentList Arguments;
const RSExportForEach::InVec &Ins = ForEach->getIns();
for (RSExportForEach::InIter BI = Ins.begin(), EI = Ins.end();
BI != EI; BI++) {
Arguments.push_back(Argument(kAllocationSp, (*BI)->getName()));
}
if (ForEach->hasOut() || ForEach->hasReturn()) {
Arguments.push_back(Argument(kAllocationSp, "aout"));
}
const RSExportRecordType *ERT = ForEach->getParamPacketType();
if (ERT) {
for (RSExportForEach::const_param_iterator i = ForEach->params_begin(),
e = ForEach->params_end();
i != e; i++) {
RSReflectionTypeData rtd;
(*i)->getType()->convertToRTD(&rtd);
Arguments.push_back(Argument(rtd.type->c_name, (*i)->getName()));
}
}
genArguments(Arguments, FunctionStart.length());
mOut << ");\n";
}
}
void RSReflectionCpp::genExportFunctionDeclarations() {
for (RSContext::const_export_func_iterator
I = mRSContext->export_funcs_begin(),
E = mRSContext->export_funcs_end();
I != E; I++) {
const RSExportFunc *ef = *I;
makeFunctionSignature(false, ef);
}
}
// forEach_* implementation
void RSReflectionCpp::genExportForEachBodies() {
uint32_t slot = 0;
for (auto I = mRSContext->export_foreach_begin(),
E = mRSContext->export_foreach_end();
I != E; I++, slot++) {
const RSExportForEach *ef = *I;
if (ef->isDummyRoot()) {
mOut.indent() << "// No forEach_root(...)\n";
continue;
}
ArgumentList Arguments;
std::string FunctionStart =
"void " + mClassName + "::forEach_" + ef->getName() + "(";
mOut.indent() << FunctionStart;
if (ef->hasIns()) {
// FIXME: Add support for kernels with multiple inputs.
slangAssert(ef->getIns().size() == 1);
Arguments.push_back(Argument(kAllocationSp, "ain"));
}
if (ef->hasOut() || ef->hasReturn()) {
Arguments.push_back(Argument(kAllocationSp, "aout"));
}
const RSExportRecordType *ERT = ef->getParamPacketType();
if (ERT) {
for (RSExportForEach::const_param_iterator i = ef->params_begin(),
e = ef->params_end();
i != e; i++) {
RSReflectionTypeData rtd;
(*i)->getType()->convertToRTD(&rtd);
Arguments.push_back(Argument(rtd.type->c_name, (*i)->getName()));
}
}
genArguments(Arguments, FunctionStart.length());
mOut << ")";
mOut.startBlock();
const RSExportType *OET = ef->getOutType();
const RSExportForEach::InTypeVec &InTypes = ef->getInTypes();
if (ef->hasIns()) {
// FIXME: Add support for kernels with multiple inputs.
slangAssert(ef->getIns().size() == 1);
genTypeCheck(InTypes[0], "ain");
}
if (OET) {
genTypeCheck(OET, "aout");
}
// TODO Add the appropriate dimension checking code, as seen in
// slang_rs_reflection.cpp.
std::string FieldPackerName = ef->getName() + "_fp";
if (ERT) {
if (genCreateFieldPacker(ERT, FieldPackerName.c_str())) {
genPackVarOfType(ERT, nullptr, FieldPackerName.c_str());
}
}
mOut.indent() << "forEach(" << slot << ", ";
if (ef->hasIns()) {
// FIXME: Add support for kernels with multiple inputs.
slangAssert(ef->getIns().size() == 1);
mOut << "ain, ";
} else {
mOut << "NULL, ";
}
if (ef->hasOut() || ef->hasReturn()) {
mOut << "aout, ";
} else {
mOut << "NULL, ";
}
// FIXME (no support for usrData with C++ kernels)
mOut << "NULL, 0);\n";
mOut.endBlock();
}
}
// invoke_* implementation
void RSReflectionCpp::genExportFunctionBodies() {
uint32_t slot = 0;
// Reflect export function
for (auto I = mRSContext->export_funcs_begin(),
E = mRSContext->export_funcs_end();
I != E; I++) {
const RSExportFunc *ef = *I;
makeFunctionSignature(true, ef);
mOut.startBlock();
const RSExportRecordType *params = ef->getParamPacketType();
size_t param_len = 0;
if (params) {
param_len = params->getAllocSize();
if (genCreateFieldPacker(params, "__fp")) {
genPackVarOfType(params, nullptr, "__fp");
}
}
mOut.indent() << "invoke(" << slot;
if (params) {
mOut << ", __fp.getData(), " << param_len << ");\n";
} else {
mOut << ", NULL, 0);\n";
}
mOut.endBlock();
slot++;
}
}
bool RSReflectionCpp::genEncodedBitCode() {
FILE *pfin = fopen(mBitCodeFilePath.c_str(), "rb");
if (pfin == nullptr) {
fprintf(stderr, "Error: could not read file %s\n",
mBitCodeFilePath.c_str());
return false;
}
unsigned char buf[16];
int read_length;
mOut.indent() << "static const unsigned char __txt[] =";
mOut.startBlock();
while ((read_length = fread(buf, 1, sizeof(buf), pfin)) > 0) {
mOut.indent();
for (int i = 0; i < read_length; i++) {
char buf2[16];
snprintf(buf2, sizeof(buf2), "0x%02x,", buf[i]);
mOut << buf2;
}
mOut << "\n";
}
mOut.endBlock(true);
mOut << "\n";
return true;
}
bool RSReflectionCpp::writeImplementationFile() {
if (!mOut.startFile(mOutputDirectory, mClassName + ".cpp", mRSSourceFilePath,
mRSContext->getLicenseNote(), false,
mRSContext->getVerbose())) {
return false;
}
// Front matter
mOut.indent() << "#include \"" << mClassName << ".h\"\n\n";
genEncodedBitCode();
mOut.indent() << "\n\n";
// Constructor
const std::string &packageName = mRSContext->getReflectJavaPackageName();
mOut.indent() << mClassName << "::" << mClassName
<< "(android::RSC::sp<android::RSC::RS> rs):\n"
" ScriptC(rs, __txt, sizeof(__txt), \""
<< mCleanedRSFileName << "\", " << mCleanedRSFileName.length()
<< ", \"/data/data/" << packageName << "/app\", sizeof(\""
<< packageName << "\"))";
mOut.startBlock();
for (std::set<std::string>::iterator I = mTypesToCheck.begin(),
E = mTypesToCheck.end();
I != E; I++) {
mOut.indent() << kRsElemPrefix << *I << " = android::RSC::Element::" << *I
<< "(mRS);\n";
}
for (RSContext::const_export_var_iterator I = mRSContext->export_vars_begin(),
E = mRSContext->export_vars_end();
I != E; I++) {
const RSExportVar *EV = *I;
if (!EV->getInit().isUninit()) {
genInitExportVariable(EV->getType(), EV->getName(), EV->getInit());
} else {
genZeroInitExportVariable(EV->getName());
}
}
mOut.endBlock();
// Destructor
mOut.indent() << mClassName << "::~" << mClassName << "()";
mOut.startBlock();
mOut.endBlock();
// Function bodies
genExportForEachBodies();
genExportFunctionBodies();
mOut.closeFile();
return true;
}
void RSReflectionCpp::genExportVariablesGetterAndSetter() {
mOut.comment("Methods to set and get the variables exported by the script. "
"Const variables will not have a setter.\n\n"
"Note that the value returned by the getter may not be the "
"current value of the variable in the script. The getter will "
"return the initial value of the variable (as defined in the "
"script) or the the last value set by using the setter method. "
"The script is free to modify its value independently.");
for (RSContext::const_export_var_iterator I = mRSContext->export_vars_begin(),
E = mRSContext->export_vars_end();
I != E; I++) {
const RSExportVar *EV = *I;
const RSExportType *ET = EV->getType();
switch (ET->getClass()) {
case RSExportType::ExportClassPrimitive: {
genGetterAndSetter(static_cast<const RSExportPrimitiveType *>(ET), EV);
break;
}
case RSExportType::ExportClassPointer: {
// TODO Deprecate this.
genPointerTypeExportVariable(EV);
break;
}
case RSExportType::ExportClassVector: {
genGetterAndSetter(static_cast<const RSExportVectorType *>(ET), EV);
break;
}
case RSExportType::ExportClassMatrix: {
genMatrixTypeExportVariable(EV);
break;
}
case RSExportType::ExportClassConstantArray: {
genGetterAndSetter(static_cast<const RSExportConstantArrayType *>(ET),
EV);
break;
}
case RSExportType::ExportClassRecord: {
genGetterAndSetter(static_cast<const RSExportRecordType *>(ET), EV);
break;
}
default: { slangAssert(false && "Unknown class of type"); }
}
}
}
void RSReflectionCpp::genGetterAndSetter(const RSExportPrimitiveType *EPT,
const RSExportVar *EV) {
RSReflectionTypeData rtd;
EPT->convertToRTD(&rtd);
std::string TypeName = GetTypeName(EPT);
if (!EV->isConst()) {
mOut.indent() << "void set_" << EV->getName() << "(" << TypeName << " v)";
mOut.startBlock();
mOut.indent() << "setVar(" << getNextExportVarSlot() << ", ";
if (EPT->isRSObjectType()) {
mOut << "v";
} else {
mOut << "&v, sizeof(v)";
}
mOut << ");\n";
mOut.indent() << RS_EXPORT_VAR_PREFIX << EV->getName() << " = v;\n";
mOut.endBlock();
}
mOut.indent() << TypeName << " get_" << EV->getName() << "() const";
mOut.startBlock();
if (EV->isConst()) {
const clang::APValue &val = EV->getInit();
bool isBool = !strcmp(TypeName.c_str(), "bool");
mOut.indent() << "return ";
genInitValue(val, isBool);
mOut << ";\n";
} else {
mOut.indent() << "return " << RS_EXPORT_VAR_PREFIX << EV->getName()
<< ";\n";
}
mOut.endBlock();
}
void RSReflectionCpp::genPointerTypeExportVariable(const RSExportVar *EV) {
const RSExportType *ET = EV->getType();
slangAssert((ET->getClass() == RSExportType::ExportClassPointer) &&
"Variable should be type of pointer here");
std::string TypeName = GetTypeName(ET);
const std::string &VarName = EV->getName();
RSReflectionTypeData rtd;
EV->getType()->convertToRTD(&rtd);
uint32_t slot = getNextExportVarSlot();
if (!EV->isConst()) {
mOut.indent() << "void bind_" << VarName << "(" << TypeName << " v)";
mOut.startBlock();
mOut.indent() << "bindAllocation(v, " << slot << ");\n";
mOut.indent() << RS_EXPORT_VAR_PREFIX << VarName << " = v;\n";
mOut.endBlock();
}
mOut.indent() << TypeName << " get_" << VarName << "() const";
mOut.startBlock();
if (EV->isConst()) {
const clang::APValue &val = EV->getInit();
bool isBool = !strcmp(TypeName.c_str(), "bool");
mOut.indent() << "return ";
genInitValue(val, isBool);
mOut << ";\n";
} else {
mOut.indent() << "return " << RS_EXPORT_VAR_PREFIX << VarName << ";\n";
}
mOut.endBlock();
}
void RSReflectionCpp::genGetterAndSetter(const RSExportVectorType *EVT,
const RSExportVar *EV) {
slangAssert(EVT != nullptr);
RSReflectionTypeData rtd;
EVT->convertToRTD(&rtd);
if (!EV->isConst()) {
mOut.indent() << "void set_" << EV->getName() << "("
<< rtd.type->rs_c_vector_prefix << EVT->getNumElement()
<< " v)";
mOut.startBlock();
mOut.indent() << "setVar(" << getNextExportVarSlot()
<< ", &v, sizeof(v));\n";
mOut.indent() << RS_EXPORT_VAR_PREFIX << EV->getName() << " = v;\n";
mOut.endBlock();
}
mOut.indent() << rtd.type->rs_c_vector_prefix << EVT->getNumElement()
<< " get_" << EV->getName() << "() const";
mOut.startBlock();
if (EV->isConst()) {
const clang::APValue &val = EV->getInit();
mOut.indent() << "return ";
genInitValue(val, false);
mOut << ";\n";
} else {
mOut.indent() << "return " << RS_EXPORT_VAR_PREFIX << EV->getName()
<< ";\n";
}
mOut.endBlock();
}
void RSReflectionCpp::genMatrixTypeExportVariable(const RSExportVar *EV) {
uint32_t slot = getNextExportVarSlot();
stringstream tmp;
tmp << slot;
const RSExportType *ET = EV->getType();
if (ET->getName() == "rs_matrix4x4") {
mOut.indent() << "void set_" << EV->getName() << "(float v[16])";
mOut.startBlock();
mOut.indent() << "setVar(" << tmp.str() << ", v, sizeof(float)*16);\n";
mOut.endBlock();
} else if (ET->getName() == "rs_matrix3x3") {
mOut.indent() << "void set_" << EV->getName() << "(float v[9])";
mOut.startBlock();
mOut.indent() << "setVar(" << tmp.str() << ", v, sizeof(float)*9);";
mOut.endBlock();
} else if (ET->getName() == "rs_matrix2x2") {
mOut.indent() << "void set_" << EV->getName() << "(float v[4])";
mOut.startBlock();
mOut.indent() << "setVar(" << tmp.str() << ", v, sizeof(float)*4);";
mOut.endBlock();
} else {
mOut.indent() << "#error: TODO: " << ET->getName();
slangAssert(false);
}
}
void RSReflectionCpp::genGetterAndSetter(const RSExportConstantArrayType *AT,
const RSExportVar *EV) {
std::stringstream ArraySpec;
const RSExportType *ET = EV->getType();
const RSExportConstantArrayType *CAT =
static_cast<const RSExportConstantArrayType *>(ET);
uint32_t slot = getNextExportVarSlot();
stringstream tmp;
tmp << slot;
ArraySpec << CAT->getNumElement();
mOut.indent() << "void set_" << EV->getName() << "(" << GetTypeName(EV->getType()) << " v "
<< GetTypeName(EV->getType(), false) << ")";
mOut.startBlock();
mOut.indent() << "setVar(" << tmp.str() << ", v, sizeof(" << GetTypeName(EV->getType()) + ") *"
<< ArraySpec.str() << ");";
mOut.endBlock();
}
void RSReflectionCpp::genGetterAndSetter(const RSExportRecordType *ERT,
const RSExportVar *EV) {
slangAssert(false);
}
void RSReflectionCpp::makeFunctionSignature(bool isDefinition,
const RSExportFunc *ef) {
mOut.indent() << "void ";
if (isDefinition) {
mOut << mClassName << "::";
}
mOut << "invoke_" << ef->getName() << "(";
if (ef->getParamPacketType()) {
bool FirstArg = true;
for (RSExportFunc::const_param_iterator i = ef->params_begin(),
e = ef->params_end();
i != e; i++) {
if (!FirstArg) {
mOut << ", ";
} else {
FirstArg = false;
}
mOut << GetTypeName((*i)->getType()) << " " << (*i)->getName();
}
}
if (isDefinition) {
mOut << ")";
} else {
mOut << ");\n";
}
}
void RSReflectionCpp::genArguments(const ArgumentList &Arguments, int Offset) {
bool FirstArg = true;
for (ArgumentList::const_iterator I = Arguments.begin(), E = Arguments.end();
I != E; I++) {
if (!FirstArg) {
mOut << ",\n";
mOut.indent() << string(Offset, ' ');
} else {
FirstArg = false;
}
mOut << I->Type << " " << I->Name;
if (!I->DefaultValue.empty()) {
mOut << " = " << I->DefaultValue;
}
}
}
bool RSReflectionCpp::genCreateFieldPacker(const RSExportType *ET,
const char *FieldPackerName) {
size_t AllocSize = ET->getAllocSize();
if (AllocSize > 0) {
mOut.indent() << "android::RSC::FieldPacker " << FieldPackerName << "("
<< AllocSize << ");\n";
return true;
}
return false;
}
void RSReflectionCpp::genPackVarOfType(const RSExportType *ET,
const char *VarName,
const char *FieldPackerName) {
switch (ET->getClass()) {
case RSExportType::ExportClassPrimitive:
case RSExportType::ExportClassVector:
case RSExportType::ExportClassPointer:
case RSExportType::ExportClassMatrix: {
mOut.indent() << FieldPackerName << ".add(" << VarName << ");\n";
break;
}
case RSExportType::ExportClassConstantArray: {
/*const RSExportConstantArrayType *ECAT =
static_cast<const RSExportConstantArrayType *>(ET);
// TODO(zonr): more elegant way. Currently, we obtain the unique index
// variable (this method involves recursive call which means
// we may have more than one level loop, therefore we can't
// always use the same index variable name here) name given
// in the for-loop from counting the '.' in @VarName.
unsigned Level = 0;
size_t LastDotPos = 0;
std::string ElementVarName(VarName);
while (LastDotPos != std::string::npos) {
LastDotPos = ElementVarName.find_first_of('.', LastDotPos + 1);
Level++;
}
std::string IndexVarName("ct");
IndexVarName.append(llvm::utostr(Level));
C.indent() << "for (int " << IndexVarName << " = 0; " <<
IndexVarName << " < " << ECAT->getSize() << "; " <<
IndexVarName << "++)";
C.startBlock();
ElementVarName.append("[" + IndexVarName + "]");
genPackVarOfType(C, ECAT->getElementType(), ElementVarName.c_str(),
FieldPackerName);
C.endBlock();*/
break;
}
case RSExportType::ExportClassRecord: {
const RSExportRecordType *ERT = static_cast<const RSExportRecordType *>(ET);
// Relative pos from now on in field packer
unsigned Pos = 0;
for (RSExportRecordType::const_field_iterator I = ERT->fields_begin(),
E = ERT->fields_end();
I != E; I++) {
const RSExportRecordType::Field *F = *I;
std::string FieldName;
size_t FieldOffset = F->getOffsetInParent();
const RSExportType *T = F->getType();
size_t FieldStoreSize = T->getStoreSize();
size_t FieldAllocSize = T->getAllocSize();
if (VarName != nullptr)
FieldName = VarName + ("." + F->getName());
else
FieldName = F->getName();
if (FieldOffset > Pos) {
mOut.indent() << FieldPackerName << ".skip(" << (FieldOffset - Pos)
<< ");\n";
}
genPackVarOfType(F->getType(), FieldName.c_str(), FieldPackerName);
// There is padding in the field type
if (FieldAllocSize > FieldStoreSize) {
mOut.indent() << FieldPackerName << ".skip("
<< (FieldAllocSize - FieldStoreSize) << ");\n";
}
Pos = FieldOffset + FieldAllocSize;
}
// There maybe some padding after the struct
if (ERT->getAllocSize() > Pos) {
mOut.indent() << FieldPackerName << ".skip(" << ERT->getAllocSize() - Pos
<< ");\n";
}
break;
}
default: { slangAssert(false && "Unknown class of type"); }
}
}
void RSReflectionCpp::genTypeCheck(const RSExportType *ET,
const char *VarName) {
mOut.indent() << "// Type check for " << VarName << "\n";
if (ET->getClass() == RSExportType::ExportClassPointer) {
const RSExportPointerType *EPT =
static_cast<const RSExportPointerType *>(ET);
ET = EPT->getPointeeType();
}
std::string TypeName;
switch (ET->getClass()) {
case RSExportType::ExportClassPrimitive:
case RSExportType::ExportClassVector:
case RSExportType::ExportClassRecord: {
TypeName = ET->getElementName();
break;
}
default:
break;
}
if (!TypeName.empty()) {
mOut.indent() << "if (!" << VarName
<< "->getType()->getElement()->isCompatible("
<< kRsElemPrefix << TypeName << "))";
mOut.startBlock();
mOut.indent() << "mRS->throwError(RS_ERROR_RUNTIME_ERROR, "
"\"Incompatible type\");\n";
mOut.indent() << "return;\n";
mOut.endBlock();
}
}
void RSReflectionCpp::genTypeInstanceFromPointer(const RSExportType *ET) {
if (ET->getClass() == RSExportType::ExportClassPointer) {
// For pointer parameters to original forEach kernels.
const RSExportPointerType *EPT =
static_cast<const RSExportPointerType *>(ET);
genTypeInstance(EPT->getPointeeType());
} else {
// For handling pass-by-value kernel parameters.
genTypeInstance(ET);
}
}
void RSReflectionCpp::genTypeInstance(const RSExportType *ET) {
switch (ET->getClass()) {
case RSExportType::ExportClassPrimitive:
case RSExportType::ExportClassVector:
case RSExportType::ExportClassConstantArray:
case RSExportType::ExportClassRecord: {
std::string TypeName = ET->getElementName();
mTypesToCheck.insert(TypeName);
break;
}
default:
break;
}
}
void RSReflectionCpp::genInitExportVariable(const RSExportType *ET,
const std::string &VarName,
const clang::APValue &Val) {
slangAssert(!Val.isUninit() && "Not a valid initializer");
switch (ET->getClass()) {
case RSExportType::ExportClassPrimitive: {
const RSExportPrimitiveType *EPT =
static_cast<const RSExportPrimitiveType *>(ET);
if (EPT->getType() == DataTypeBoolean) {
genInitBoolExportVariable(VarName, Val);
} else {
genInitPrimitiveExportVariable(VarName, Val);
}
break;
}
case RSExportType::ExportClassPointer: {
if (!Val.isInt() || Val.getInt().getSExtValue() != 0)
std::cerr << "Initializer which is non-NULL to pointer type variable "
"will be ignored" << std::endl;
break;
}
case RSExportType::ExportClassVector: {
const RSExportVectorType *EVT = static_cast<const RSExportVectorType *>(ET);
switch (Val.getKind()) {
case clang::APValue::Int:
case clang::APValue::Float: {
for (unsigned i = 0; i < EVT->getNumElement(); i++) {
std::string Name = VarName + "." + getVectorAccessor(i);
genInitPrimitiveExportVariable(Name, Val);
}
break;
}
case clang::APValue::Vector: {
unsigned NumElements = std::min(
static_cast<unsigned>(EVT->getNumElement()), Val.getVectorLength());
for (unsigned i = 0; i < NumElements; i++) {
const clang::APValue &ElementVal = Val.getVectorElt(i);
std::string Name = VarName + "." + getVectorAccessor(i);
genInitPrimitiveExportVariable(Name, ElementVal);
}
break;
}
case clang::APValue::MemberPointer:
case clang::APValue::Uninitialized:
case clang::APValue::ComplexInt:
case clang::APValue::ComplexFloat:
case clang::APValue::LValue:
case clang::APValue::Array:
case clang::APValue::Struct:
case clang::APValue::Union:
case clang::APValue::AddrLabelDiff: {
slangAssert(false && "Unexpected type of value of initializer.");
}
}
break;
}
case RSExportType::ExportClassMatrix:
case RSExportType::ExportClassConstantArray:
case RSExportType::ExportClassRecord: {
slangAssert(false && "Unsupported initializer for record/matrix/constant "
"array type variable currently");
break;
}
default: { slangAssert(false && "Unknown class of type"); }
}
}
const char *RSReflectionCpp::getVectorAccessor(unsigned Index) {
static const char *VectorAccessorMap[] = {/* 0 */ "x",
/* 1 */ "y",
/* 2 */ "z",
/* 3 */ "w",
};
slangAssert((Index < (sizeof(VectorAccessorMap) / sizeof(const char *))) &&
"Out-of-bound index to access vector member");
return VectorAccessorMap[Index];
}
void RSReflectionCpp::genZeroInitExportVariable(const std::string &VarName) {
mOut.indent() << "memset(&" << RS_EXPORT_VAR_PREFIX << VarName
<< ", 0, sizeof(" << RS_EXPORT_VAR_PREFIX << VarName << "));\n";
}
void
RSReflectionCpp::genInitPrimitiveExportVariable(const std::string &VarName,
const clang::APValue &Val) {
slangAssert(!Val.isUninit() && "Not a valid initializer");
mOut.indent() << RS_EXPORT_VAR_PREFIX << VarName << " = ";
genInitValue(Val);
mOut << ";\n";
}
void RSReflectionCpp::genInitValue(const clang::APValue &Val, bool asBool) {
switch (Val.getKind()) {
case clang::APValue::Int: {
const llvm::APInt &api = Val.getInt();
if (asBool) {
mOut << ((api.getSExtValue() == 0) ? "false" : "true");
} else {
// TODO: Handle unsigned correctly for C++
mOut << api.getSExtValue();
if (api.getBitWidth() > 32) {
mOut << "L";
}
}
break;
}
case clang::APValue::Float: {
const llvm::APFloat &apf = Val.getFloat();
llvm::SmallString<30> s;
apf.toString(s);
mOut << s.c_str();
if (&apf.getSemantics() == &llvm::APFloat::IEEEsingle) {
if (s.count('.') == 0) {
mOut << ".f";
} else {
mOut << "f";
}
}
break;
}
case clang::APValue::ComplexInt:
case clang::APValue::ComplexFloat:
case clang::APValue::LValue:
case clang::APValue::Vector: {
slangAssert(false && "Primitive type cannot have such kind of initializer");
break;
}
default: { slangAssert(false && "Unknown kind of initializer"); }
}
}
void RSReflectionCpp::genInitBoolExportVariable(const std::string &VarName,
const clang::APValue &Val) {
slangAssert(!Val.isUninit() && "Not a valid initializer");
slangAssert((Val.getKind() == clang::APValue::Int) &&
"Bool type has wrong initial APValue");
mOut.indent() << RS_EXPORT_VAR_PREFIX << VarName << " = "
<< ((Val.getInt().getSExtValue() == 0) ? "false" : "true")
<< ";";
}
} // namespace slang