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android / platform / frameworks / compile / slang / 59e3736 / . / slang_rs_export_type.cpp
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/*
* Copyright 2010-2012, 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 "slang_rs_export_type.h"
#include <list>
#include <vector>
#include "clang/AST/RecordLayout.h"
#include "llvm/ADT/StringExtras.h"
#include "llvm/DerivedTypes.h"
#include "llvm/Target/TargetData.h"
#include "llvm/Type.h"
#include "slang_assert.h"
#include "slang_rs_context.h"
#include "slang_rs_export_element.h"
#include "slang_rs_type_spec.h"
#include "slang_version.h"
#define CHECK_PARENT_EQUALITY(ParentClass, E) \
if (!ParentClass::equals(E)) \
return false;
namespace slang {
namespace {
static RSReflectionType gReflectionTypes[] = {
{"FLOAT_16", "F16", 16, "half", "half", "Half", "Half", false},
{"FLOAT_32", "F32", 32, "float", "float", "Float", "Float", false},
{"FLOAT_64", "F64", 64, "double", "double", "Double", "Double",false},
{"SIGNED_8", "I8", 8, "int8_t", "byte", "Byte", "Byte", false},
{"SIGNED_16", "I16", 16, "int16_t", "short", "Short", "Short", false},
{"SIGNED_32", "I32", 32, "int32_t", "int", "Int", "Int", false},
{"SIGNED_64", "I64", 64, "int64_t", "long", "Long", "Long", false},
{"UNSIGNED_8", "U8", 8, "uint8_t", "short", "UByte", "Short", true},
{"UNSIGNED_16", "U16", 16, "uint16_t", "int", "UShort", "Int", true},
{"UNSIGNED_32", "U32", 32, "uint32_t", "long", "UInt", "Long", true},
{"UNSIGNED_64", "U64", 64, "uint64_t", "long", "ULong", "Long", false},
{"BOOLEAN", "BOOLEAN", 8, "bool", "boolean", NULL, NULL, false},
{"UNSIGNED_5_6_5", NULL, 16, NULL, NULL, NULL, NULL, false},
{"UNSIGNED_5_5_5_1", NULL, 16, NULL, NULL, NULL, NULL, false},
{"UNSIGNED_4_4_4_4", NULL, 16, NULL, NULL, NULL, NULL, false},
{"MATRIX_2X2", NULL, 4*32, "rsMatrix_2x2", "Matrix2f", NULL, NULL, false},
{"MATRIX_3X3", NULL, 9*32, "rsMatrix_3x3", "Matrix3f", NULL, NULL, false},
{"MATRIX_4X4", NULL, 16*32, "rsMatrix_4x4", "Matrix4f", NULL, NULL, false},
{"RS_ELEMENT", "ELEMENT", 32, "Element", "Element", NULL, NULL, false},
{"RS_TYPE", "TYPE", 32, "Type", "Type", NULL, NULL, false},
{"RS_ALLOCATION", "ALLOCATION", 32, "Allocation", "Allocation", NULL, NULL, false},
{"RS_SAMPLER", "SAMPLER", 32, "Sampler", "Sampler", NULL, NULL, false},
{"RS_SCRIPT", "SCRIPT", 32, "Script", "Script", NULL, NULL, false},
{"RS_MESH", "MESH", 32, "Mesh", "Mesh", NULL, NULL, false},
{"RS_PATH", "PATH", 32, "Path", "Path", NULL, NULL, false},
{"RS_PROGRAM_FRAGMENT", "PROGRAM_FRAGMENT", 32, "ProgramFragment", "ProgramFragment", NULL, NULL, false},
{"RS_PROGRAM_VERTEX", "PROGRAM_VERTEX", 32, "ProgramVertex", "ProgramVertex", NULL, NULL, false},
{"RS_PROGRAM_RASTER", "PROGRAM_RASTER", 32, "ProgramRaster", "ProgramRaster", NULL, NULL, false},
{"RS_PROGRAM_STORE", "PROGRAM_STORE", 32, "ProgramStore", "ProgramStore", NULL, NULL, false},
{"RS_FONT", "FONT", 32, "Font", "Font", NULL, NULL, false}
};
static const clang::Type *TypeExportableHelper(
const clang::Type *T,
llvm::SmallPtrSet<const clang::Type*, 8>& SPS,
clang::DiagnosticsEngine *DiagEngine,
const clang::VarDecl *VD,
const clang::RecordDecl *TopLevelRecord);
static void ReportTypeError(clang::DiagnosticsEngine *DiagEngine,
const clang::VarDecl *VD,
const clang::RecordDecl *TopLevelRecord,
const char *Message,
unsigned int TargetAPI = 0) {
if (!DiagEngine) {
return;
}
const clang::SourceManager &SM = DiagEngine->getSourceManager();
// Attempt to use the type declaration first (if we have one).
// Fall back to the variable definition, if we are looking at something
// like an array declaration that can't be exported.
if (TopLevelRecord) {
DiagEngine->Report(
clang::FullSourceLoc(TopLevelRecord->getLocation(), SM),
DiagEngine->getCustomDiagID(clang::DiagnosticsEngine::Error, Message))
<< TopLevelRecord->getName() << TargetAPI;
} else if (VD) {
DiagEngine->Report(
clang::FullSourceLoc(VD->getLocation(), SM),
DiagEngine->getCustomDiagID(clang::DiagnosticsEngine::Error, Message))
<< VD->getName() << TargetAPI;
} else {
slangAssert(false && "Variables should be validated before exporting");
}
}
static const clang::Type *ConstantArrayTypeExportableHelper(
const clang::ConstantArrayType *CAT,
llvm::SmallPtrSet<const clang::Type*, 8>& SPS,
clang::DiagnosticsEngine *DiagEngine,
const clang::VarDecl *VD,
const clang::RecordDecl *TopLevelRecord) {
// Check element type
const clang::Type *ElementType = GET_CONSTANT_ARRAY_ELEMENT_TYPE(CAT);
if (ElementType->isArrayType()) {
ReportTypeError(DiagEngine, VD, TopLevelRecord,
"multidimensional arrays cannot be exported: '%0'");
return NULL;
} else if (ElementType->isExtVectorType()) {
const clang::ExtVectorType *EVT =
static_cast<const clang::ExtVectorType*>(ElementType);
unsigned numElements = EVT->getNumElements();
const clang::Type *BaseElementType = GET_EXT_VECTOR_ELEMENT_TYPE(EVT);
if (!RSExportPrimitiveType::IsPrimitiveType(BaseElementType)) {
ReportTypeError(DiagEngine, VD, TopLevelRecord,
"vectors of non-primitive types cannot be exported: '%0'");
return NULL;
}
if (numElements == 3 && CAT->getSize() != 1) {
ReportTypeError(DiagEngine, VD, TopLevelRecord,
"arrays of width 3 vector types cannot be exported: '%0'");
return NULL;
}
}
if (TypeExportableHelper(ElementType, SPS, DiagEngine, VD,
TopLevelRecord) == NULL) {
return NULL;
} else {
return CAT;
}
}
static const clang::Type *TypeExportableHelper(
clang::Type const *T,
llvm::SmallPtrSet<clang::Type const *, 8> &SPS,
clang::DiagnosticsEngine *DiagEngine,
clang::VarDecl const *VD,
clang::RecordDecl const *TopLevelRecord) {
// Normalize first
if ((T = GET_CANONICAL_TYPE(T)) == NULL)
return NULL;
if (SPS.count(T))
return T;
switch (T->getTypeClass()) {
case clang::Type::Builtin: {
const clang::BuiltinType *BT =
UNSAFE_CAST_TYPE(const clang::BuiltinType, T);
switch (BT->getKind()) {
#define ENUM_SUPPORT_BUILTIN_TYPE(builtin_type, type, cname) \
case builtin_type:
#include "RSClangBuiltinEnums.inc"
return T;
default: {
return NULL;
}
}
}
case clang::Type::Record: {
if (RSExportPrimitiveType::GetRSSpecificType(T) !=
RSExportPrimitiveType::DataTypeUnknown) {
return T; // RS object type, no further checks are needed
}
// Check internal struct
if (T->isUnionType()) {
ReportTypeError(DiagEngine, VD, T->getAsUnionType()->getDecl(),
"unions cannot be exported: '%0'");
return NULL;
} else if (!T->isStructureType()) {
slangAssert(false && "Unknown type cannot be exported");
return NULL;
}
clang::RecordDecl *RD = T->getAsStructureType()->getDecl();
if (RD != NULL) {
RD = RD->getDefinition();
if (RD == NULL) {
ReportTypeError(DiagEngine, NULL, T->getAsStructureType()->getDecl(),
"struct is not defined in this module");
return NULL;
}
}
if (!TopLevelRecord) {
TopLevelRecord = RD;
}
if (RD->getName().empty()) {
ReportTypeError(DiagEngine, NULL, RD,
"anonymous structures cannot be exported");
return NULL;
}
// Fast check
if (RD->hasFlexibleArrayMember() || RD->hasObjectMember())
return NULL;
// Insert myself into checking set
SPS.insert(T);
// Check all element
for (clang::RecordDecl::field_iterator FI = RD->field_begin(),
FE = RD->field_end();
FI != FE;
FI++) {
const clang::FieldDecl *FD = *FI;
const clang::Type *FT = RSExportType::GetTypeOfDecl(FD);
FT = GET_CANONICAL_TYPE(FT);
if (!TypeExportableHelper(FT, SPS, DiagEngine, VD, TopLevelRecord)) {
return NULL;
}
// We don't support bit fields yet
//
// TODO(zonr/srhines): allow bit fields of size 8, 16, 32
if (FD->isBitField()) {
if (DiagEngine) {
DiagEngine->Report(
clang::FullSourceLoc(FD->getLocation(),
DiagEngine->getSourceManager()),
DiagEngine->getCustomDiagID(
clang::DiagnosticsEngine::Error,
"bit fields are not able to be exported: '%0.%1'"))
<< RD->getName()
<< FD->getName();
}
return NULL;
}
}
return T;
}
case clang::Type::Pointer: {
if (TopLevelRecord) {
ReportTypeError(DiagEngine, VD, TopLevelRecord,
"structures containing pointers cannot be exported: '%0'");
return NULL;
}
const clang::PointerType *PT =
UNSAFE_CAST_TYPE(const clang::PointerType, T);
const clang::Type *PointeeType = GET_POINTEE_TYPE(PT);
if (PointeeType->getTypeClass() == clang::Type::Pointer) {
ReportTypeError(DiagEngine, VD, TopLevelRecord,
"multiple levels of pointers cannot be exported: '%0'");
return NULL;
}
// We don't support pointer with array-type pointee or unsupported pointee
// type
if (PointeeType->isArrayType() ||
(TypeExportableHelper(PointeeType, SPS, DiagEngine, VD,
TopLevelRecord) == NULL))
return NULL;
else
return T;
}
case clang::Type::ExtVector: {
const clang::ExtVectorType *EVT =
UNSAFE_CAST_TYPE(const clang::ExtVectorType, T);
// Only vector with size 2, 3 and 4 are supported.
if (EVT->getNumElements() < 2 || EVT->getNumElements() > 4)
return NULL;
// Check base element type
const clang::Type *ElementType = GET_EXT_VECTOR_ELEMENT_TYPE(EVT);
if ((ElementType->getTypeClass() != clang::Type::Builtin) ||
(TypeExportableHelper(ElementType, SPS, DiagEngine, VD,
TopLevelRecord) == NULL))
return NULL;
else
return T;
}
case clang::Type::ConstantArray: {
const clang::ConstantArrayType *CAT =
UNSAFE_CAST_TYPE(const clang::ConstantArrayType, T);
return ConstantArrayTypeExportableHelper(CAT, SPS, DiagEngine, VD,
TopLevelRecord);
}
default: {
return NULL;
}
}
}
// Return the type that can be used to create RSExportType, will always return
// the canonical type
// If the Type T is not exportable, this function returns NULL. DiagEngine is
// used to generate proper Clang diagnostic messages when a
// non-exportable type is detected. TopLevelRecord is used to capture the
// highest struct (in the case of a nested hierarchy) for detecting other
// types that cannot be exported (mostly pointers within a struct).
static const clang::Type *TypeExportable(const clang::Type *T,
clang::DiagnosticsEngine *DiagEngine,
const clang::VarDecl *VD) {
llvm::SmallPtrSet<const clang::Type*, 8> SPS =
llvm::SmallPtrSet<const clang::Type*, 8>();
return TypeExportableHelper(T, SPS, DiagEngine, VD, NULL);
}
static bool ValidateRSObjectInVarDecl(clang::VarDecl *VD,
bool InCompositeType,
unsigned int TargetAPI) {
if (TargetAPI < SLANG_JB_TARGET_API) {
// Only if we are already in a composite type (like an array or structure).
if (InCompositeType) {
// Only if we are actually exported (i.e. non-static).
if (VD->getLinkage() == clang::ExternalLinkage) {
// Only if we are not a pointer to an object.
const clang::Type *T = GET_CANONICAL_TYPE(VD->getType().getTypePtr());
if (T->getTypeClass() != clang::Type::Pointer) {
clang::ASTContext &C = VD->getASTContext();
ReportTypeError(&C.getDiagnostics(), VD, NULL,
"arrays/structures containing RS object types "
"cannot be exported in target API < %1: '%0'",
SLANG_JB_TARGET_API);
return false;
}
}
}
}
return true;
}
// Helper function for ValidateVarDecl(). We do a recursive descent on the
// type hierarchy to ensure that we can properly export/handle the
// declaration.
// \return true if the variable declaration is valid,
// false if it is invalid (along with proper diagnostics).
//
// VD - top-level variable declaration that we are validating.
// T - sub-type of VD's type that we are validating.
// SPS - set of types we have already seen/validated.
// InCompositeType - true if we are within an outer composite type.
// UnionDecl - set if we are in a sub-type of a union.
// TargetAPI - target SDK API level.
static bool ValidateVarDeclHelper(
clang::VarDecl *VD,
const clang::Type *&T,
llvm::SmallPtrSet<const clang::Type*, 8>& SPS,
bool InCompositeType,
clang::RecordDecl *UnionDecl,
unsigned int TargetAPI) {
if ((T = GET_CANONICAL_TYPE(T)) == NULL)
return true;
if (SPS.count(T))
return true;
switch (T->getTypeClass()) {
case clang::Type::Record: {
if (RSExportPrimitiveType::IsRSObjectType(T)) {
if (!ValidateRSObjectInVarDecl(VD, InCompositeType, TargetAPI)) {
return false;
}
}
if (RSExportPrimitiveType::GetRSSpecificType(T) !=
RSExportPrimitiveType::DataTypeUnknown) {
if (!UnionDecl) {
return true;
} else if (RSExportPrimitiveType::IsRSObjectType(T)) {
clang::ASTContext &C = VD->getASTContext();
ReportTypeError(&C.getDiagnostics(), VD, UnionDecl,
"unions containing RS object types are not allowed");
return false;
}
}
clang::RecordDecl *RD = NULL;
// Check internal struct
if (T->isUnionType()) {
RD = T->getAsUnionType()->getDecl();
UnionDecl = RD;
} else if (T->isStructureType()) {
RD = T->getAsStructureType()->getDecl();
} else {
slangAssert(false && "Unknown type cannot be exported");
return false;
}
if (RD != NULL) {
RD = RD->getDefinition();
if (RD == NULL) {
// FIXME
return true;
}
}
// Fast check
if (RD->hasFlexibleArrayMember() || RD->hasObjectMember())
return false;
// Insert myself into checking set
SPS.insert(T);
// Check all elements
for (clang::RecordDecl::field_iterator FI = RD->field_begin(),
FE = RD->field_end();
FI != FE;
FI++) {
const clang::FieldDecl *FD = *FI;
const clang::Type *FT = RSExportType::GetTypeOfDecl(FD);
FT = GET_CANONICAL_TYPE(FT);
if (!ValidateVarDeclHelper(VD, FT, SPS, true, UnionDecl, TargetAPI)) {
return false;
}
}
return true;
}
case clang::Type::Builtin: {
break;
}
case clang::Type::Pointer: {
const clang::PointerType *PT =
UNSAFE_CAST_TYPE(const clang::PointerType, T);
const clang::Type *PointeeType = GET_POINTEE_TYPE(PT);
return ValidateVarDeclHelper(VD, PointeeType, SPS, InCompositeType,
UnionDecl, TargetAPI);
}
case clang::Type::ExtVector: {
const clang::ExtVectorType *EVT =
UNSAFE_CAST_TYPE(const clang::ExtVectorType, T);
const clang::Type *ElementType = GET_EXT_VECTOR_ELEMENT_TYPE(EVT);
return ValidateVarDeclHelper(VD, ElementType, SPS, true, UnionDecl,
TargetAPI);
}
case clang::Type::ConstantArray: {
const clang::ConstantArrayType *CAT =
UNSAFE_CAST_TYPE(const clang::ConstantArrayType, T);
const clang::Type *ElementType = GET_CONSTANT_ARRAY_ELEMENT_TYPE(CAT);
return ValidateVarDeclHelper(VD, ElementType, SPS, true, UnionDecl,
TargetAPI);
}
default: {
break;
}
}
return true;
}
} // namespace
/****************************** RSExportType ******************************/
bool RSExportType::NormalizeType(const clang::Type *&T,
llvm::StringRef &TypeName,
clang::DiagnosticsEngine *DiagEngine,
const clang::VarDecl *VD) {
if ((T = TypeExportable(T, DiagEngine, VD)) == NULL) {
return false;
}
// Get type name
TypeName = RSExportType::GetTypeName(T);
if (TypeName.empty()) {
if (DiagEngine) {
if (VD) {
DiagEngine->Report(
clang::FullSourceLoc(VD->getLocation(),
DiagEngine->getSourceManager()),
DiagEngine->getCustomDiagID(clang::DiagnosticsEngine::Error,
"anonymous types cannot be exported"));
} else {
DiagEngine->Report(
DiagEngine->getCustomDiagID(clang::DiagnosticsEngine::Error,
"anonymous types cannot be exported"));
}
}
return false;
}
return true;
}
bool RSExportType::ValidateVarDecl(clang::VarDecl *VD, unsigned int TargetAPI) {
const clang::Type *T = VD->getType().getTypePtr();
llvm::SmallPtrSet<const clang::Type*, 8> SPS =
llvm::SmallPtrSet<const clang::Type*, 8>();
return ValidateVarDeclHelper(VD, T, SPS, false, NULL, TargetAPI);
}
const clang::Type
*RSExportType::GetTypeOfDecl(const clang::DeclaratorDecl *DD) {
if (DD) {
clang::QualType T;
if (DD->getTypeSourceInfo())
T = DD->getTypeSourceInfo()->getType();
else
T = DD->getType();
if (T.isNull())
return NULL;
else
return T.getTypePtr();
}
return NULL;
}
llvm::StringRef RSExportType::GetTypeName(const clang::Type* T) {
T = GET_CANONICAL_TYPE(T);
if (T == NULL)
return llvm::StringRef();
switch (T->getTypeClass()) {
case clang::Type::Builtin: {
const clang::BuiltinType *BT =
UNSAFE_CAST_TYPE(const clang::BuiltinType, T);
switch (BT->getKind()) {
#define ENUM_SUPPORT_BUILTIN_TYPE(builtin_type, type, cname) \
case builtin_type: \
return cname; \
break;
#include "RSClangBuiltinEnums.inc"
default: {
slangAssert(false && "Unknown data type of the builtin");
break;
}
}
break;
}
case clang::Type::Record: {
clang::RecordDecl *RD;
if (T->isStructureType()) {
RD = T->getAsStructureType()->getDecl();
} else {
break;
}
llvm::StringRef Name = RD->getName();
if (Name.empty()) {
if (RD->getTypedefNameForAnonDecl() != NULL) {
Name = RD->getTypedefNameForAnonDecl()->getName();
}
if (Name.empty()) {
// Try to find a name from redeclaration (i.e. typedef)
for (clang::TagDecl::redecl_iterator RI = RD->redecls_begin(),
RE = RD->redecls_end();
RI != RE;
RI++) {
slangAssert(*RI != NULL && "cannot be NULL object");
Name = (*RI)->getName();
if (!Name.empty())
break;
}
}
}
return Name;
}
case clang::Type::Pointer: {
// "*" plus pointee name
const clang::Type *PT = GET_POINTEE_TYPE(T);
llvm::StringRef PointeeName;
if (NormalizeType(PT, PointeeName, NULL, NULL)) {
char *Name = new char[ 1 /* * */ + PointeeName.size() + 1 ];
Name[0] = '*';
memcpy(Name + 1, PointeeName.data(), PointeeName.size());
Name[PointeeName.size() + 1] = '\0';
return Name;
}
break;
}
case clang::Type::ExtVector: {
const clang::ExtVectorType *EVT =
UNSAFE_CAST_TYPE(const clang::ExtVectorType, T);
return RSExportVectorType::GetTypeName(EVT);
break;
}
case clang::Type::ConstantArray : {
// Construct name for a constant array is too complicated.
return DUMMY_TYPE_NAME_FOR_RS_CONSTANT_ARRAY_TYPE;
}
default: {
break;
}
}
return llvm::StringRef();
}
RSExportType *RSExportType::Create(RSContext *Context,
const clang::Type *T,
const llvm::StringRef &TypeName) {
// Lookup the context to see whether the type was processed before.
// Newly created RSExportType will insert into context
// in RSExportType::RSExportType()
RSContext::export_type_iterator ETI = Context->findExportType(TypeName);
if (ETI != Context->export_types_end())
return ETI->second;
RSExportType *ET = NULL;
switch (T->getTypeClass()) {
case clang::Type::Record: {
RSExportPrimitiveType::DataType dt =
RSExportPrimitiveType::GetRSSpecificType(TypeName);
switch (dt) {
case RSExportPrimitiveType::DataTypeUnknown: {
// User-defined types
ET = RSExportRecordType::Create(Context,
T->getAsStructureType(),
TypeName);
break;
}
case RSExportPrimitiveType::DataTypeRSMatrix2x2: {
// 2 x 2 Matrix type
ET = RSExportMatrixType::Create(Context,
T->getAsStructureType(),
TypeName,
2);
break;
}
case RSExportPrimitiveType::DataTypeRSMatrix3x3: {
// 3 x 3 Matrix type
ET = RSExportMatrixType::Create(Context,
T->getAsStructureType(),
TypeName,
3);
break;
}
case RSExportPrimitiveType::DataTypeRSMatrix4x4: {
// 4 x 4 Matrix type
ET = RSExportMatrixType::Create(Context,
T->getAsStructureType(),
TypeName,
4);
break;
}
default: {
// Others are primitive types
ET = RSExportPrimitiveType::Create(Context, T, TypeName);
break;
}
}
break;
}
case clang::Type::Builtin: {
ET = RSExportPrimitiveType::Create(Context, T, TypeName);
break;
}
case clang::Type::Pointer: {
ET = RSExportPointerType::Create(Context,
UNSAFE_CAST_TYPE(const clang::PointerType, T), TypeName);
// FIXME: free the name (allocated in RSExportType::GetTypeName)
delete [] TypeName.data();
break;
}
case clang::Type::ExtVector: {
ET = RSExportVectorType::Create(Context,
UNSAFE_CAST_TYPE(const clang::ExtVectorType, T), TypeName);
break;
}
case clang::Type::ConstantArray: {
ET = RSExportConstantArrayType::Create(
Context,
UNSAFE_CAST_TYPE(const clang::ConstantArrayType, T));
break;
}
default: {
clang::DiagnosticsEngine *DiagEngine = Context->getDiagnostics();
DiagEngine->Report(
DiagEngine->getCustomDiagID(clang::DiagnosticsEngine::Error,
"unknown type cannot be exported: '%0'"))
<< T->getTypeClassName();
break;
}
}
return ET;
}
RSExportType *RSExportType::Create(RSContext *Context, const clang::Type *T) {
llvm::StringRef TypeName;
if (NormalizeType(T, TypeName, Context->getDiagnostics(), NULL)) {
return Create(Context, T, TypeName);
} else {
return NULL;
}
}
RSExportType *RSExportType::CreateFromDecl(RSContext *Context,
const clang::VarDecl *VD) {
return RSExportType::Create(Context, GetTypeOfDecl(VD));
}
size_t RSExportType::GetTypeStoreSize(const RSExportType *ET) {
return ET->getRSContext()->getTargetData()->getTypeStoreSize(
ET->getLLVMType());
}
size_t RSExportType::GetTypeAllocSize(const RSExportType *ET) {
if (ET->getClass() == RSExportType::ExportClassRecord)
return static_cast<const RSExportRecordType*>(ET)->getAllocSize();
else
return ET->getRSContext()->getTargetData()->getTypeAllocSize(
ET->getLLVMType());
}
RSExportType::RSExportType(RSContext *Context,
ExportClass Class,
const llvm::StringRef &Name)
: RSExportable(Context, RSExportable::EX_TYPE),
mClass(Class),
// Make a copy on Name since memory stored @Name is either allocated in
// ASTContext or allocated in GetTypeName which will be destroyed later.
mName(Name.data(), Name.size()),
mLLVMType(NULL),
mSpecType(NULL) {
// Don't cache the type whose name start with '<'. Those type failed to
// get their name since constructing their name in GetTypeName() requiring
// complicated work.
if (!Name.startswith(DUMMY_RS_TYPE_NAME_PREFIX))
// TODO(zonr): Need to check whether the insertion is successful or not.
Context->insertExportType(llvm::StringRef(Name), this);
return;
}
bool RSExportType::keep() {
if (!RSExportable::keep())
return false;
// Invalidate converted LLVM type.
mLLVMType = NULL;
return true;
}
bool RSExportType::equals(const RSExportable *E) const {
CHECK_PARENT_EQUALITY(RSExportable, E);
return (static_cast<const RSExportType*>(E)->getClass() == getClass());
}
RSExportType::~RSExportType() {
delete mSpecType;
}
/************************** RSExportPrimitiveType **************************/
llvm::ManagedStatic<RSExportPrimitiveType::RSSpecificTypeMapTy>
RSExportPrimitiveType::RSSpecificTypeMap;
llvm::Type *RSExportPrimitiveType::RSObjectLLVMType = NULL;
bool RSExportPrimitiveType::IsPrimitiveType(const clang::Type *T) {
if ((T != NULL) && (T->getTypeClass() == clang::Type::Builtin))
return true;
else
return false;
}
RSExportPrimitiveType::DataType
RSExportPrimitiveType::GetRSSpecificType(const llvm::StringRef &TypeName) {
if (TypeName.empty())
return DataTypeUnknown;
if (RSSpecificTypeMap->empty()) {
#define ENUM_RS_MATRIX_TYPE(type, cname, dim) \
RSSpecificTypeMap->GetOrCreateValue(cname, DataType ## type);
#include "RSMatrixTypeEnums.inc"
#define ENUM_RS_OBJECT_TYPE(type, cname) \
RSSpecificTypeMap->GetOrCreateValue(cname, DataType ## type);
#include "RSObjectTypeEnums.inc"
}
RSSpecificTypeMapTy::const_iterator I = RSSpecificTypeMap->find(TypeName);
if (I == RSSpecificTypeMap->end())
return DataTypeUnknown;
else
return I->getValue();
}
RSExportPrimitiveType::DataType
RSExportPrimitiveType::GetRSSpecificType(const clang::Type *T) {
T = GET_CANONICAL_TYPE(T);
if ((T == NULL) || (T->getTypeClass() != clang::Type::Record))
return DataTypeUnknown;
return GetRSSpecificType( RSExportType::GetTypeName(T) );
}
bool RSExportPrimitiveType::IsRSMatrixType(DataType DT) {
return ((DT >= FirstRSMatrixType) && (DT <= LastRSMatrixType));
}
bool RSExportPrimitiveType::IsRSObjectType(DataType DT) {
return ((DT >= FirstRSObjectType) && (DT <= LastRSObjectType));
}
bool RSExportPrimitiveType::IsStructureTypeWithRSObject(const clang::Type *T) {
bool RSObjectTypeSeen = false;
while (T && T->isArrayType()) {
T = T->getArrayElementTypeNoTypeQual();
}
const clang::RecordType *RT = T->getAsStructureType();
if (!RT) {
return false;
}
const clang::RecordDecl *RD = RT->getDecl();
RD = RD->getDefinition();
for (clang::RecordDecl::field_iterator FI = RD->field_begin(),
FE = RD->field_end();
FI != FE;
FI++) {
// We just look through all field declarations to see if we find a
// declaration for an RS object type (or an array of one).
const clang::FieldDecl *FD = *FI;
const clang::Type *FT = RSExportType::GetTypeOfDecl(FD);
while (FT && FT->isArrayType()) {
FT = FT->getArrayElementTypeNoTypeQual();
}
RSExportPrimitiveType::DataType DT = GetRSSpecificType(FT);
if (IsRSObjectType(DT)) {
// RS object types definitely need to be zero-initialized
RSObjectTypeSeen = true;
} else {
switch (DT) {
case RSExportPrimitiveType::DataTypeRSMatrix2x2:
case RSExportPrimitiveType::DataTypeRSMatrix3x3:
case RSExportPrimitiveType::DataTypeRSMatrix4x4:
// Matrix types should get zero-initialized as well
RSObjectTypeSeen = true;
break;
default:
// Ignore all other primitive types
break;
}
while (FT && FT->isArrayType()) {
FT = FT->getArrayElementTypeNoTypeQual();
}
if (FT->isStructureType()) {
// Recursively handle structs of structs (even though these can't
// be exported, it is possible for a user to have them internally).
RSObjectTypeSeen |= IsStructureTypeWithRSObject(FT);
}
}
}
return RSObjectTypeSeen;
}
const size_t RSExportPrimitiveType::SizeOfDataTypeInBits[] = {
#define ENUM_RS_DATA_TYPE(type, cname, bits) \
bits,
#include "RSDataTypeEnums.inc"
0 // DataTypeMax
};
size_t RSExportPrimitiveType::GetSizeInBits(const RSExportPrimitiveType *EPT) {
slangAssert(((EPT->getType() > DataTypeUnknown) &&
(EPT->getType() < DataTypeMax)) &&
"RSExportPrimitiveType::GetSizeInBits : unknown data type");
return SizeOfDataTypeInBits[ static_cast<int>(EPT->getType()) ];
}
RSExportPrimitiveType::DataType
RSExportPrimitiveType::GetDataType(RSContext *Context, const clang::Type *T) {
if (T == NULL)
return DataTypeUnknown;
switch (T->getTypeClass()) {
case clang::Type::Builtin: {
const clang::BuiltinType *BT =
UNSAFE_CAST_TYPE(const clang::BuiltinType, T);
switch (BT->getKind()) {
#define ENUM_SUPPORT_BUILTIN_TYPE(builtin_type, type, cname) \
case builtin_type: { \
return DataType ## type; \
}
#include "RSClangBuiltinEnums.inc"
// The size of type WChar depend on platform so we abandon the support
// to them.
default: {
clang::DiagnosticsEngine *DiagEngine = Context->getDiagnostics();
DiagEngine->Report(
DiagEngine->getCustomDiagID(
clang::DiagnosticsEngine::Error,
"built-in type cannot be exported: '%0'"))
<< T->getTypeClassName();
break;
}
}
break;
}
case clang::Type::Record: {
// must be RS object type
return RSExportPrimitiveType::GetRSSpecificType(T);
}
default: {
clang::DiagnosticsEngine *DiagEngine = Context->getDiagnostics();
DiagEngine->Report(
DiagEngine->getCustomDiagID(clang::DiagnosticsEngine::Error,
"primitive type cannot be exported: '%0'"))
<< T->getTypeClassName();
break;
}
}
return DataTypeUnknown;
}
RSExportPrimitiveType
*RSExportPrimitiveType::Create(RSContext *Context,
const clang::Type *T,
const llvm::StringRef &TypeName,
bool Normalized) {
DataType DT = GetDataType(Context, T);
if ((DT == DataTypeUnknown) || TypeName.empty())
return NULL;
else
return new RSExportPrimitiveType(Context, ExportClassPrimitive, TypeName,
DT, Normalized);
}
RSExportPrimitiveType *RSExportPrimitiveType::Create(RSContext *Context,
const clang::Type *T) {
llvm::StringRef TypeName;
if (RSExportType::NormalizeType(T, TypeName, Context->getDiagnostics(), NULL)
&& IsPrimitiveType(T)) {
return Create(Context, T, TypeName);
} else {
return NULL;
}
}
llvm::Type *RSExportPrimitiveType::convertToLLVMType() const {
llvm::LLVMContext &C = getRSContext()->getLLVMContext();
if (isRSObjectType()) {
// struct {
// int *p;
// } __attribute__((packed, aligned(pointer_size)))
//
// which is
//
// <{ [1 x i32] }> in LLVM
//
if (RSObjectLLVMType == NULL) {
std::vector<llvm::Type *> Elements;
Elements.push_back(llvm::ArrayType::get(llvm::Type::getInt32Ty(C), 1));
RSObjectLLVMType = llvm::StructType::get(C, Elements, true);
}
return RSObjectLLVMType;
}
switch (mType) {
case DataTypeFloat32: {
return llvm::Type::getFloatTy(C);
break;
}
case DataTypeFloat64: {
return llvm::Type::getDoubleTy(C);
break;
}
case DataTypeBoolean: {
return llvm::Type::getInt1Ty(C);
break;
}
case DataTypeSigned8:
case DataTypeUnsigned8: {
return llvm::Type::getInt8Ty(C);
break;
}
case DataTypeSigned16:
case DataTypeUnsigned16:
case DataTypeUnsigned565:
case DataTypeUnsigned5551:
case DataTypeUnsigned4444: {
return llvm::Type::getInt16Ty(C);
break;
}
case DataTypeSigned32:
case DataTypeUnsigned32: {
return llvm::Type::getInt32Ty(C);
break;
}
case DataTypeSigned64:
case DataTypeUnsigned64: {
return llvm::Type::getInt64Ty(C);
break;
}
default: {
slangAssert(false && "Unknown data type");
}
}
return NULL;
}
union RSType *RSExportPrimitiveType::convertToSpecType() const {
llvm::OwningPtr<union RSType> ST(new union RSType);
RS_TYPE_SET_CLASS(ST, RS_TC_Primitive);
// enum RSExportPrimitiveType::DataType is synced with enum RSDataType in
// slang_rs_type_spec.h
RS_PRIMITIVE_TYPE_SET_DATA_TYPE(ST, getType());
return ST.take();
}
bool RSExportPrimitiveType::equals(const RSExportable *E) const {
CHECK_PARENT_EQUALITY(RSExportType, E);
return (static_cast<const RSExportPrimitiveType*>(E)->getType() == getType());
}
RSReflectionType *RSExportPrimitiveType::getRSReflectionType(DataType DT) {
if (DT > DataTypeUnknown && DT < DataTypeMax) {
return &gReflectionTypes[DT];
} else {
return NULL;
}
}
/**************************** RSExportPointerType ****************************/
RSExportPointerType
*RSExportPointerType::Create(RSContext *Context,
const clang::PointerType *PT,
const llvm::StringRef &TypeName) {
const clang::Type *PointeeType = GET_POINTEE_TYPE(PT);
const RSExportType *PointeeET;
if (PointeeType->getTypeClass() != clang::Type::Pointer) {
PointeeET = RSExportType::Create(Context, PointeeType);
} else {
// Double or higher dimension of pointer, export as int*
PointeeET = RSExportPrimitiveType::Create(Context,
Context->getASTContext().IntTy.getTypePtr());
}
if (PointeeET == NULL) {
// Error diagnostic is emitted for corresponding pointee type
return NULL;
}
return new RSExportPointerType(Context, TypeName, PointeeET);
}
llvm::Type *RSExportPointerType::convertToLLVMType() const {
llvm::Type *PointeeType = mPointeeType->getLLVMType();
return llvm::PointerType::getUnqual(PointeeType);
}
union RSType *RSExportPointerType::convertToSpecType() const {
llvm::OwningPtr<union RSType> ST(new union RSType);
RS_TYPE_SET_CLASS(ST, RS_TC_Pointer);
RS_POINTER_TYPE_SET_POINTEE_TYPE(ST, getPointeeType()->getSpecType());
if (RS_POINTER_TYPE_GET_POINTEE_TYPE(ST) != NULL)
return ST.take();
else
return NULL;
}
bool RSExportPointerType::keep() {
if (!RSExportType::keep())
return false;
const_cast<RSExportType*>(mPointeeType)->keep();
return true;
}
bool RSExportPointerType::equals(const RSExportable *E) const {
CHECK_PARENT_EQUALITY(RSExportType, E);
return (static_cast<const RSExportPointerType*>(E)
->getPointeeType()->equals(getPointeeType()));
}
/***************************** RSExportVectorType *****************************/
llvm::StringRef
RSExportVectorType::GetTypeName(const clang::ExtVectorType *EVT) {
const clang::Type *ElementType = GET_EXT_VECTOR_ELEMENT_TYPE(EVT);
if ((ElementType->getTypeClass() != clang::Type::Builtin))
return llvm::StringRef();
const clang::BuiltinType *BT = UNSAFE_CAST_TYPE(const clang::BuiltinType,
ElementType);
if ((EVT->getNumElements() < 1) ||
(EVT->getNumElements() > 4))
return llvm::StringRef();
switch (BT->getKind()) {
// Compiler is smart enough to optimize following *big if branches* since
// they all become "constant comparison" after macro expansion
#define ENUM_SUPPORT_BUILTIN_TYPE(builtin_type, type, cname) \
case builtin_type: { \
const char *Name[] = { cname"2", cname"3", cname"4" }; \
return Name[EVT->getNumElements() - 2]; \
break; \
}
#include "RSClangBuiltinEnums.inc"
default: {
return llvm::StringRef();
}
}
}
RSExportVectorType *RSExportVectorType::Create(RSContext *Context,
const clang::ExtVectorType *EVT,
const llvm::StringRef &TypeName,
bool Normalized) {
slangAssert(EVT != NULL && EVT->getTypeClass() == clang::Type::ExtVector);
const clang::Type *ElementType = GET_EXT_VECTOR_ELEMENT_TYPE(EVT);
RSExportPrimitiveType::DataType DT =
RSExportPrimitiveType::GetDataType(Context, ElementType);
if (DT != RSExportPrimitiveType::DataTypeUnknown)
return new RSExportVectorType(Context,
TypeName,
DT,
Normalized,
EVT->getNumElements());
else
return NULL;
}
llvm::Type *RSExportVectorType::convertToLLVMType() const {
llvm::Type *ElementType = RSExportPrimitiveType::convertToLLVMType();
return llvm::VectorType::get(ElementType, getNumElement());
}
union RSType *RSExportVectorType::convertToSpecType() const {
llvm::OwningPtr<union RSType> ST(new union RSType);
RS_TYPE_SET_CLASS(ST, RS_TC_Vector);
RS_VECTOR_TYPE_SET_ELEMENT_TYPE(ST, getType());
RS_VECTOR_TYPE_SET_VECTOR_SIZE(ST, getNumElement());
return ST.take();
}
bool RSExportVectorType::equals(const RSExportable *E) const {
CHECK_PARENT_EQUALITY(RSExportPrimitiveType, E);
return (static_cast<const RSExportVectorType*>(E)->getNumElement()
== getNumElement());
}
/***************************** RSExportMatrixType *****************************/
RSExportMatrixType *RSExportMatrixType::Create(RSContext *Context,
const clang::RecordType *RT,
const llvm::StringRef &TypeName,
unsigned Dim) {
slangAssert((RT != NULL) && (RT->getTypeClass() == clang::Type::Record));
slangAssert((Dim > 1) && "Invalid dimension of matrix");
// Check whether the struct rs_matrix is in our expected form (but assume it's
// correct if we're not sure whether it's correct or not)
const clang::RecordDecl* RD = RT->getDecl();
RD = RD->getDefinition();
if (RD != NULL) {
clang::DiagnosticsEngine *DiagEngine = Context->getDiagnostics();
const clang::SourceManager *SM = Context->getSourceManager();
// Find definition, perform further examination
if (RD->field_empty()) {
DiagEngine->Report(
clang::FullSourceLoc(RD->getLocation(), *SM),
DiagEngine->getCustomDiagID(
clang::DiagnosticsEngine::Error,
"invalid matrix struct: must have 1 field for saving values: '%0'"))
<< RD->getName();
return NULL;
}
clang::RecordDecl::field_iterator FIT = RD->field_begin();
const clang::FieldDecl *FD = *FIT;
const clang::Type *FT = RSExportType::GetTypeOfDecl(FD);
if ((FT == NULL) || (FT->getTypeClass() != clang::Type::ConstantArray)) {
DiagEngine->Report(
clang::FullSourceLoc(RD->getLocation(), *SM),
DiagEngine->getCustomDiagID(clang::DiagnosticsEngine::Error,
"invalid matrix struct: first field should"
" be an array with constant size: '%0'"))
<< RD->getName();
return NULL;
}
const clang::ConstantArrayType *CAT =
static_cast<const clang::ConstantArrayType *>(FT);
const clang::Type *ElementType = GET_CONSTANT_ARRAY_ELEMENT_TYPE(CAT);
if ((ElementType == NULL) ||
(ElementType->getTypeClass() != clang::Type::Builtin) ||
(static_cast<const clang::BuiltinType *>(ElementType)->getKind() !=
clang::BuiltinType::Float)) {
DiagEngine->Report(
clang::FullSourceLoc(RD->getLocation(), *SM),
DiagEngine->getCustomDiagID(clang::DiagnosticsEngine::Error,
"invalid matrix struct: first field "
"should be a float array: '%0'"))
<< RD->getName();
return NULL;
}
if (CAT->getSize() != Dim * Dim) {
DiagEngine->Report(
clang::FullSourceLoc(RD->getLocation(), *SM),
DiagEngine->getCustomDiagID(clang::DiagnosticsEngine::Error,
"invalid matrix struct: first field "
"should be an array with size %0: '%1'"))
<< (Dim * Dim) << (RD->getName());
return NULL;
}
FIT++;
if (FIT != RD->field_end()) {
DiagEngine->Report(
clang::FullSourceLoc(RD->getLocation(), *SM),
DiagEngine->getCustomDiagID(clang::DiagnosticsEngine::Error,
"invalid matrix struct: must have "
"exactly 1 field: '%0'"))
<< RD->getName();
return NULL;
}
}
return new RSExportMatrixType(Context, TypeName, Dim);
}
llvm::Type *RSExportMatrixType::convertToLLVMType() const {
// Construct LLVM type:
// struct {
// float X[mDim * mDim];
// }
llvm::LLVMContext &C = getRSContext()->getLLVMContext();
llvm::ArrayType *X = llvm::ArrayType::get(llvm::Type::getFloatTy(C),
mDim * mDim);
return llvm::StructType::get(C, X, false);
}
union RSType *RSExportMatrixType::convertToSpecType() const {
llvm::OwningPtr<union RSType> ST(new union RSType);
RS_TYPE_SET_CLASS(ST, RS_TC_Matrix);
switch (getDim()) {
case 2: RS_MATRIX_TYPE_SET_DATA_TYPE(ST, RS_DT_RSMatrix2x2); break;
case 3: RS_MATRIX_TYPE_SET_DATA_TYPE(ST, RS_DT_RSMatrix3x3); break;
case 4: RS_MATRIX_TYPE_SET_DATA_TYPE(ST, RS_DT_RSMatrix4x4); break;
default: slangAssert(false && "Matrix type with unsupported dimension.");
}
return ST.take();
}
bool RSExportMatrixType::equals(const RSExportable *E) const {
CHECK_PARENT_EQUALITY(RSExportType, E);
return (static_cast<const RSExportMatrixType*>(E)->getDim() == getDim());
}
/************************* RSExportConstantArrayType *************************/
RSExportConstantArrayType
*RSExportConstantArrayType::Create(RSContext *Context,
const clang::ConstantArrayType *CAT) {
slangAssert(CAT != NULL && CAT->getTypeClass() == clang::Type::ConstantArray);
slangAssert((CAT->getSize().getActiveBits() < 32) && "array too large");
unsigned Size = static_cast<unsigned>(CAT->getSize().getZExtValue());
slangAssert((Size > 0) && "Constant array should have size greater than 0");
const clang::Type *ElementType = GET_CONSTANT_ARRAY_ELEMENT_TYPE(CAT);
RSExportType *ElementET = RSExportType::Create(Context, ElementType);
if (ElementET == NULL) {
return NULL;
}
return new RSExportConstantArrayType(Context,
ElementET,
Size);
}
llvm::Type *RSExportConstantArrayType::convertToLLVMType() const {
return llvm::ArrayType::get(mElementType->getLLVMType(), getSize());
}
union RSType *RSExportConstantArrayType::convertToSpecType() const {
llvm::OwningPtr<union RSType> ST(new union RSType);
RS_TYPE_SET_CLASS(ST, RS_TC_ConstantArray);
RS_CONSTANT_ARRAY_TYPE_SET_ELEMENT_TYPE(
ST, getElementType()->getSpecType());
RS_CONSTANT_ARRAY_TYPE_SET_ELEMENT_SIZE(ST, getSize());
if (RS_CONSTANT_ARRAY_TYPE_GET_ELEMENT_TYPE(ST) != NULL)
return ST.take();
else
return NULL;
}
bool RSExportConstantArrayType::keep() {
if (!RSExportType::keep())
return false;
const_cast<RSExportType*>(mElementType)->keep();
return true;
}
bool RSExportConstantArrayType::equals(const RSExportable *E) const {
CHECK_PARENT_EQUALITY(RSExportType, E);
const RSExportConstantArrayType *RHS =
static_cast<const RSExportConstantArrayType*>(E);
return ((getSize() == RHS->getSize()) &&
(getElementType()->equals(RHS->getElementType())));
}
/**************************** RSExportRecordType ****************************/
RSExportRecordType *RSExportRecordType::Create(RSContext *Context,
const clang::RecordType *RT,
const llvm::StringRef &TypeName,
bool mIsArtificial) {
slangAssert(RT != NULL && RT->getTypeClass() == clang::Type::Record);
const clang::RecordDecl *RD = RT->getDecl();
slangAssert(RD->isStruct());
RD = RD->getDefinition();
if (RD == NULL) {
slangAssert(false && "struct is not defined in this module");
return NULL;
}
// Struct layout construct by clang. We rely on this for obtaining the
// alloc size of a struct and offset of every field in that struct.
const clang::ASTRecordLayout *RL =
&Context->getASTContext().getASTRecordLayout(RD);
slangAssert((RL != NULL) &&
"Failed to retrieve the struct layout from Clang.");
RSExportRecordType *ERT =
new RSExportRecordType(Context,
TypeName,
RD->hasAttr<clang::PackedAttr>(),
mIsArtificial,
RL->getSize().getQuantity());
unsigned int Index = 0;
for (clang::RecordDecl::field_iterator FI = RD->field_begin(),
FE = RD->field_end();
FI != FE;
FI++, Index++) {
clang::DiagnosticsEngine *DiagEngine = Context->getDiagnostics();
// FIXME: All fields should be primitive type
slangAssert((*FI)->getKind() == clang::Decl::Field);
clang::FieldDecl *FD = *FI;
if (FD->isBitField()) {
return NULL;
}
// Type
RSExportType *ET = RSExportElement::CreateFromDecl(Context, FD);
if (ET != NULL) {
ERT->mFields.push_back(
new Field(ET, FD->getName(), ERT,
static_cast<size_t>(RL->getFieldOffset(Index) >> 3)));
} else {
DiagEngine->Report(
clang::FullSourceLoc(RD->getLocation(), DiagEngine->getSourceManager()),
DiagEngine->getCustomDiagID(clang::DiagnosticsEngine::Error,
"field type cannot be exported: '%0.%1'"))
<< RD->getName() << FD->getName();
return NULL;
}
}
return ERT;
}
llvm::Type *RSExportRecordType::convertToLLVMType() const {
// Create an opaque type since struct may reference itself recursively.
// TODO(sliao): LLVM took out the OpaqueType. Any other to migrate to?
std::vector<llvm::Type*> FieldTypes;
for (const_field_iterator FI = fields_begin(), FE = fields_end();
FI != FE;
FI++) {
const Field *F = *FI;
const RSExportType *FET = F->getType();
FieldTypes.push_back(FET->getLLVMType());
}
llvm::StructType *ST = llvm::StructType::get(getRSContext()->getLLVMContext(),
FieldTypes,
mIsPacked);
if (ST != NULL) {
return ST;
} else {
return NULL;
}
}
union RSType *RSExportRecordType::convertToSpecType() const {
unsigned NumFields = getFields().size();
unsigned AllocSize = sizeof(union RSType) +
sizeof(struct RSRecordField) * NumFields;
llvm::OwningPtr<union RSType> ST(
reinterpret_cast<union RSType*>(operator new(AllocSize)));
::memset(ST.get(), 0, AllocSize);
RS_TYPE_SET_CLASS(ST, RS_TC_Record);
RS_RECORD_TYPE_SET_NAME(ST, getName().c_str());
RS_RECORD_TYPE_SET_NUM_FIELDS(ST, NumFields);
setSpecTypeTemporarily(ST.get());
unsigned FieldIdx = 0;
for (const_field_iterator FI = fields_begin(), FE = fields_end();
FI != FE;
FI++, FieldIdx++) {
const Field *F = *FI;
RS_RECORD_TYPE_SET_FIELD_NAME(ST, FieldIdx, F->getName().c_str());
RS_RECORD_TYPE_SET_FIELD_TYPE(ST, FieldIdx, F->getType()->getSpecType());
}
// TODO(slang): Check whether all fields were created normally.
return ST.take();
}
bool RSExportRecordType::keep() {
if (!RSExportType::keep())
return false;
for (std::list<const Field*>::iterator I = mFields.begin(),
E = mFields.end();
I != E;
I++) {
const_cast<RSExportType*>((*I)->getType())->keep();
}
return true;
}
bool RSExportRecordType::equals(const RSExportable *E) const {
CHECK_PARENT_EQUALITY(RSExportType, E);
const RSExportRecordType *ERT = static_cast<const RSExportRecordType*>(E);
if (ERT->getFields().size() != getFields().size())
return false;
const_field_iterator AI = fields_begin(), BI = ERT->fields_begin();
for (unsigned i = 0, e = getFields().size(); i != e; i++) {
if (!(*AI)->getType()->equals((*BI)->getType()))
return false;
AI++;
BI++;
}
return true;
}
void RSExportType::convertToRTD(RSReflectionTypeData *rtd) const {
memset(rtd, 0, sizeof(*rtd));
rtd->vecSize = 1;
switch(getClass()) {
case RSExportType::ExportClassPrimitive: {
const RSExportPrimitiveType *EPT = static_cast<const RSExportPrimitiveType*>(this);
rtd->type = RSExportPrimitiveType::getRSReflectionType(EPT);
return;
}
case RSExportType::ExportClassPointer: {
const RSExportPointerType *EPT = static_cast<const RSExportPointerType*>(this);
const RSExportType *PointeeType = EPT->getPointeeType();
PointeeType->convertToRTD(rtd);
rtd->isPointer = true;
return;
}
case RSExportType::ExportClassVector: {
const RSExportVectorType *EVT = static_cast<const RSExportVectorType*>(this);
rtd->type = EVT->getRSReflectionType(EVT);
rtd->vecSize = EVT->getNumElement();
return;
}
case RSExportType::ExportClassMatrix: {
const RSExportMatrixType *EMT = static_cast<const RSExportMatrixType*>(this);
unsigned Dim = EMT->getDim();
slangAssert((Dim >= 2) && (Dim <= 4));
rtd->type = &gReflectionTypes[15 + Dim-2];
return;
}
case RSExportType::ExportClassConstantArray: {
const RSExportConstantArrayType* CAT =
static_cast<const RSExportConstantArrayType*>(this);
CAT->getElementType()->convertToRTD(rtd);
rtd->arraySize = CAT->getSize();
return;
}
case RSExportType::ExportClassRecord: {
slangAssert(!"RSExportType::ExportClassRecord not implemented");
return;// RS_TYPE_CLASS_NAME_PREFIX + ET->getName() + ".Item";
}
default: {
slangAssert(false && "Unknown class of type");
}
}
}
} // namespace slang