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android / platform / development / 47809766797d371ea31b3f5672edd3257a326c8c / . / vndk / tools / header-checker / src / dumper / abi_wrappers.cpp
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// Copyright (C) 2016 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 "dumper/abi_wrappers.h"
#include "repr/ir_reader.h"
#include "utils/header_abi_util.h"
#include <clang/AST/QualTypeNames.h>
#include <regex>
#include <string>
#include <assert.h>
#include <limits.h>
#include <stdlib.h>
namespace header_checker {
namespace dumper {
//------------------------------------------------------------------------------
// Helper Function
//------------------------------------------------------------------------------
static repr::AccessSpecifierIR AccessClangToIR(
const clang::AccessSpecifier sp) {
switch (sp) {
case clang::AS_private: {
return repr::AccessSpecifierIR::PrivateAccess;
}
case clang::AS_protected: {
return repr::AccessSpecifierIR::ProtectedAccess;
}
default: {
return repr::AccessSpecifierIR::PublicAccess;
}
}
}
//------------------------------------------------------------------------------
// ABI Wrapper
//------------------------------------------------------------------------------
ABIWrapper::ABIWrapper(
clang::MangleContext *mangle_contextp,
clang::ASTContext *ast_contextp,
const clang::CompilerInstance *cip,
repr::ModuleIR *module,
ASTCaches *ast_caches)
: cip_(cip),
mangle_contextp_(mangle_contextp),
ast_contextp_(ast_contextp),
module_(module),
ast_caches_(ast_caches) {}
std::string ABIWrapper::GetDeclSourceFile(const clang::Decl *decl,
const clang::CompilerInstance *cip) {
clang::SourceManager &sm = cip->getSourceManager();
clang::SourceLocation location = decl->getLocation();
// We need to use the expansion location to identify whether we should recurse
// into the AST Node or not. For eg: macros specifying LinkageSpecDecl can
// have their spelling location defined somewhere outside a source / header
// file belonging to a library. This should not allow the AST node to be
// skipped. Its expansion location will still be the source-file / header
// belonging to the library.
clang::SourceLocation expansion_location = sm.getExpansionLoc(location);
llvm::StringRef file_name = sm.getFilename(expansion_location);
return utils::RealPath(file_name.str());
}
std::string ABIWrapper::GetCachedDeclSourceFile(
const clang::Decl *decl, const clang::CompilerInstance *cip) {
assert(decl != nullptr);
auto result = ast_caches_->decl_to_source_file_cache_.find(decl);
if (result == ast_caches_->decl_to_source_file_cache_.end()) {
return GetDeclSourceFile(decl, cip);
}
return result->second;
}
std::string ABIWrapper::GetMangledNameDecl(
const clang::NamedDecl *decl, clang::MangleContext *mangle_contextp) {
if (!mangle_contextp->shouldMangleDeclName(decl)) {
clang::IdentifierInfo *identifier = decl->getIdentifier();
return identifier ? identifier->getName() : "";
}
std::string mangled_name;
llvm::raw_string_ostream ostream(mangled_name);
mangle_contextp->mangleName(decl, ostream);
ostream.flush();
return mangled_name;
}
bool ABIWrapper::SetupTemplateArguments(const clang::TemplateArgumentList *tl,
repr::TemplatedArtifactIR *ta,
const std::string &source_file) {
repr::TemplateInfoIR template_info;
for (int i = 0; i < tl->size(); i++) {
const clang::TemplateArgument &arg = (*tl)[i];
// TODO: More comprehensive checking needed.
if (arg.getKind() != clang::TemplateArgument::Type) {
continue;
}
clang::QualType type = arg.getAsType();
template_info.AddTemplateElement(
repr::TemplateElementIR(GetTypeUniqueId(type)));
if (!CreateBasicNamedAndTypedDecl(type, source_file)) {
llvm::errs() << "Setting up template arguments failed\n";
return false;
}
}
ta->SetTemplateInfo(std::move(template_info));
return true;
}
bool ABIWrapper::SetupFunctionParameter(
repr::CFunctionLikeIR *functionp, const clang::QualType qual_type,
bool has_default_arg, const std::string &source_file, bool is_this_ptr) {
if (!CreateBasicNamedAndTypedDecl(qual_type, source_file)) {
llvm::errs() << "Setting up function parameter failed\n";
return false;
}
functionp->AddParameter(repr::ParamIR(
GetTypeUniqueId(qual_type), has_default_arg, is_this_ptr));
return true;
}
static const clang::RecordDecl *GetAnonymousRecord(clang::QualType type) {
const clang::Type *type_ptr = type.getTypePtr();
assert(type_ptr != nullptr);
if (!type_ptr->isRecordType()) {
return nullptr;
}
const clang::TagDecl *tag_decl = type_ptr->getAsTagDecl();
if (!tag_decl) {
return nullptr;
}
const clang::RecordDecl *record_decl =
llvm::dyn_cast<clang::RecordDecl>(tag_decl);
if (record_decl != nullptr &&
(!record_decl->hasNameForLinkage() ||
record_decl->isAnonymousStructOrUnion())) {
return record_decl;
}
return nullptr;
}
static const clang::EnumDecl *GetAnonymousEnum(
const clang::QualType qual_type) {
const clang::Type *type_ptr = qual_type.getTypePtr();
assert(type_ptr != nullptr);
const clang::TagDecl *tag_decl = type_ptr->getAsTagDecl();
if (!tag_decl) {
return nullptr;
}
const clang::EnumDecl *enum_decl = llvm::dyn_cast<clang::EnumDecl>(tag_decl);
if (!enum_decl || enum_decl->hasNameForLinkage()) {
return nullptr;
}
return enum_decl;
}
static bool IsReferencingType(clang::QualType qual_type) {
const clang::QualType canonical_type = qual_type.getCanonicalType();
const clang::Type *base_type = canonical_type.getTypePtr();
bool is_ptr = base_type->isPointerType();
bool is_reference = base_type->isReferenceType();
bool is_array = base_type->isArrayType();
return is_array || is_ptr || is_reference || qual_type.hasLocalQualifiers();
}
// Get type 'referenced' by qual_type. Referenced type implies, in order:
// 1) Strip off all qualifiers if qual_type has CVR qualifiers.
// 2) Strip off a pointer level if qual_type is a pointer.
// 3) Strip off the reference if qual_type is a reference.
// Note: qual_type is expected to be a canonical type.
static clang::QualType GetReferencedType(const clang::QualType qual_type) {
const clang::Type *type_ptr = qual_type.getTypePtr();
if (qual_type.hasLocalQualifiers()) {
return qual_type.getLocalUnqualifiedType();
}
if (type_ptr->isPointerType()) {
return type_ptr->getPointeeType();
}
if (type_ptr->isArrayType()) {
return
type_ptr->getArrayElementTypeNoTypeQual()->getCanonicalTypeInternal();
}
return qual_type.getNonReferenceType();
}
bool ABIWrapper::CreateAnonymousRecord(const clang::RecordDecl *record_decl) {
RecordDeclWrapper record_decl_wrapper(mangle_contextp_, ast_contextp_, cip_,
record_decl, module_, ast_caches_);
return record_decl_wrapper.GetRecordDecl();
}
bool ABIWrapper::CreateExtendedType(clang::QualType qual_type,
repr::TypeIR *typep) {
const clang::QualType canonical_type = qual_type.getCanonicalType();
// The source file is going to be set later anyway.
return CreateBasicNamedAndTypedDecl(canonical_type, typep, "");
}
// A mangled anonymous enum name ends with $_<number> or Ut<number>_ where the
// number may be inconsistent between translation units. This function replaces
// the name with $ followed by the lexicographically smallest field name.
static std::string GetAnonymousEnumUniqueId(llvm::StringRef mangled_name,
const clang::EnumDecl *enum_decl) {
// Get the type name from the mangled name.
const std::string mangled_name_str = mangled_name;
std::smatch match_result;
std::string old_suffix;
std::string nested_name_suffix;
if (std::regex_search(mangled_name_str, match_result,
std::regex(R"((\$_\d+)(E?)$)"))) {
const std::ssub_match &old_name = match_result[1];
old_suffix = std::to_string(old_name.length()) + match_result[0].str();
nested_name_suffix = match_result[2].str();
if (!mangled_name.endswith(old_suffix)) {
llvm::errs() << "Unexpected length of anonymous enum type name: "
<< mangled_name << "\n";
::exit(1);
}
} else if (std::regex_search(mangled_name_str, match_result,
std::regex(R"(Ut\d*_(E?)$)"))) {
old_suffix = match_result[0].str();
nested_name_suffix = match_result[1].str();
} else {
llvm::errs() << "Cannot parse anonymous enum name: " << mangled_name
<< "\n";
::exit(1);
}
// Find the smallest enumerator name.
std::string smallest_enum_name;
for (auto enum_it : enum_decl->enumerators()) {
std::string enum_name = enum_it->getNameAsString();
if (smallest_enum_name.empty() || smallest_enum_name > enum_name) {
smallest_enum_name = enum_name;
}
}
smallest_enum_name = "$" + smallest_enum_name;
std::string new_suffix = std::to_string(smallest_enum_name.length()) +
smallest_enum_name + nested_name_suffix;
return mangled_name.drop_back(old_suffix.length()).str() + new_suffix;
}
std::string ABIWrapper::GetTypeUniqueId(clang::QualType qual_type) {
const clang::Type *canonical_type = qual_type.getCanonicalType().getTypePtr();
assert(canonical_type != nullptr);
llvm::SmallString<256> uid;
llvm::raw_svector_ostream out(uid);
mangle_contextp_->mangleCXXRTTI(qual_type, out);
if (const clang::EnumDecl *enum_decl = GetAnonymousEnum(qual_type)) {
return GetAnonymousEnumUniqueId(uid.str(), enum_decl);
}
return uid.str();
}
// CreateBasicNamedAndTypedDecl creates a BasicNamedAndTypedDecl which will
// include all the generic information of a basic type. Other methods will
// create more specific information, e.g. RecordDecl, EnumDecl.
bool ABIWrapper::CreateBasicNamedAndTypedDecl(
clang::QualType canonical_type, repr::TypeIR *typep,
const std::string &source_file) {
// Cannot determine the size and alignment for template parameter dependent
// types as well as incomplete types.
const clang::Type *base_type = canonical_type.getTypePtr();
assert(base_type != nullptr);
clang::Type::TypeClass type_class = base_type->getTypeClass();
// Set the size and alignment of the type.
// Temporary hack: Skip the auto types, incomplete types and dependent types.
if (type_class != clang::Type::Auto && !base_type->isIncompleteType() &&
!base_type->isDependentType()) {
std::pair<clang::CharUnits, clang::CharUnits> size_and_alignment =
ast_contextp_->getTypeInfoInChars(canonical_type);
typep->SetSize(size_and_alignment.first.getQuantity());
typep->SetAlignment(size_and_alignment.second.getQuantity());
}
std::string human_name = QualTypeToString(canonical_type);
std::string mangled_name = GetTypeUniqueId(canonical_type);
typep->SetName(human_name);
typep->SetLinkerSetKey(mangled_name);
// This type has a reference type if its a pointer / reference OR it has CVR
// qualifiers.
clang::QualType referenced_type = GetReferencedType(canonical_type);
typep->SetReferencedType(GetTypeUniqueId(referenced_type));
typep->SetSelfType(mangled_name);
// Create the type for referenced type.
return CreateBasicNamedAndTypedDecl(referenced_type, source_file);
}
// This overload takes in a qualtype and adds its information to the abi-dump on
// its own.
bool ABIWrapper::CreateBasicNamedAndTypedDecl(clang::QualType qual_type,
const std::string &source_file) {
const clang::QualType canonical_type = qual_type.getCanonicalType();
const clang::Type *base_type = canonical_type.getTypePtr();
bool is_builtin = base_type->isBuiltinType();
bool should_continue_with_recursive_type_creation =
IsReferencingType(canonical_type) || is_builtin ||
base_type->isFunctionType() ||
(GetAnonymousRecord(canonical_type) != nullptr);
if (!should_continue_with_recursive_type_creation ||
!ast_caches_->converted_qual_types_.insert(qual_type).second) {
return true;
}
// Do something similar to what is being done right now. Create an object
// extending Type and return a pointer to that and pass it to CreateBasic...
// CreateBasic...(qualtype, Type *) fills in size, alignemnt etc.
auto type_and_status = SetTypeKind(canonical_type, source_file);
std::unique_ptr<repr::TypeIR> typep = std::move(type_and_status.typep_);
if (!base_type->isVoidType() && type_and_status.should_create_type_ &&
!typep) {
llvm::errs() << "nullptr with valid type while creating basic type\n";
return false;
}
if (!type_and_status.should_create_type_) {
return true;
}
return (CreateBasicNamedAndTypedDecl(
canonical_type, typep.get(), source_file) &&
module_->AddLinkableMessage(*typep));
}
// This method returns a TypeAndCreationStatus object. This object contains a
// type and information to tell the clients of this method whether the caller
// should continue creating the type.
TypeAndCreationStatus ABIWrapper::SetTypeKind(
const clang::QualType canonical_type, const std::string &source_file) {
if (canonical_type.hasLocalQualifiers()) {
auto qual_type_ir =
std::make_unique<repr::QualifiedTypeIR>();
qual_type_ir->SetConstness(canonical_type.isConstQualified());
qual_type_ir->SetRestrictedness(canonical_type.isRestrictQualified());
qual_type_ir->SetVolatility(canonical_type.isVolatileQualified());
qual_type_ir->SetSourceFile(source_file);
return TypeAndCreationStatus(std::move(qual_type_ir));
}
const clang::Type *type_ptr = canonical_type.getTypePtr();
if (type_ptr->isPointerType()) {
auto pointer_type_ir = std::make_unique<repr::PointerTypeIR>();
pointer_type_ir->SetSourceFile(source_file);
return TypeAndCreationStatus(std::move(pointer_type_ir));
}
if (type_ptr->isLValueReferenceType()) {
auto lvalue_reference_type_ir =
std::make_unique<repr::LvalueReferenceTypeIR>();
lvalue_reference_type_ir->SetSourceFile(source_file);
return TypeAndCreationStatus(std::move(lvalue_reference_type_ir));
}
if (type_ptr->isRValueReferenceType()) {
auto rvalue_reference_type_ir =
std::make_unique<repr::RvalueReferenceTypeIR>();
rvalue_reference_type_ir->SetSourceFile(source_file);
return TypeAndCreationStatus(std::move(rvalue_reference_type_ir));
}
if (type_ptr->isArrayType()) {
auto array_type_ir = std::make_unique<repr::ArrayTypeIR>();
array_type_ir->SetSourceFile(source_file);
return TypeAndCreationStatus(std::move(array_type_ir));
}
if (type_ptr->isEnumeralType()) {
return TypeAndCreationStatus(std::make_unique<repr::EnumTypeIR>());
}
if (type_ptr->isBuiltinType()) {
auto builtin_type_ir = std::make_unique<repr::BuiltinTypeIR>();
builtin_type_ir->SetSignedness(type_ptr->isUnsignedIntegerType());
builtin_type_ir->SetIntegralType(type_ptr->isIntegralType(*ast_contextp_));
return TypeAndCreationStatus(std::move(builtin_type_ir));
}
if (auto &&func_type_ptr =
llvm::dyn_cast<const clang::FunctionType>(type_ptr)) {
FunctionTypeWrapper function_type_wrapper(mangle_contextp_, ast_contextp_,
cip_, func_type_ptr, module_,
ast_caches_, source_file);
if (!function_type_wrapper.GetFunctionType()) {
llvm::errs() << "FunctionType could not be created\n";
::exit(1);
}
}
if (type_ptr->isRecordType()) {
// If this record is anonymous, create it.
const clang::RecordDecl *anon_record = GetAnonymousRecord(canonical_type);
// Avoid constructing RecordDeclWrapper with invalid record, which results
// in segmentation fault.
if (anon_record && !anon_record->isInvalidDecl() &&
!CreateAnonymousRecord(anon_record)) {
llvm::errs() << "Anonymous record could not be created\n";
::exit(1);
}
}
return TypeAndCreationStatus(nullptr, false);
}
std::string ABIWrapper::QualTypeToString(const clang::QualType &sweet_qt) {
const clang::QualType salty_qt = sweet_qt.getCanonicalType();
// clang::TypeName::getFullyQualifiedName removes the part of the type related
// to it being a template parameter. Don't use it for dependent types.
if (salty_qt.getTypePtr()->isDependentType()) {
return salty_qt.getAsString();
}
return clang::TypeName::getFullyQualifiedName(
salty_qt, *ast_contextp_, ast_contextp_->getPrintingPolicy());
}
//------------------------------------------------------------------------------
// Function Type Wrapper
//------------------------------------------------------------------------------
FunctionTypeWrapper::FunctionTypeWrapper(
clang::MangleContext *mangle_contextp, clang::ASTContext *ast_contextp,
const clang::CompilerInstance *compiler_instance_p,
const clang::FunctionType *function_type, repr::ModuleIR *module,
ASTCaches *ast_caches, const std::string &source_file)
: ABIWrapper(mangle_contextp, ast_contextp, compiler_instance_p, module,
ast_caches),
function_type_(function_type),
source_file_(source_file) {}
bool FunctionTypeWrapper::SetupFunctionType(
repr::FunctionTypeIR *function_type_ir) {
// Add ReturnType
function_type_ir->SetReturnType(
GetTypeUniqueId(function_type_->getReturnType()));
function_type_ir->SetSourceFile(source_file_);
const clang::FunctionProtoType *function_pt =
llvm::dyn_cast<clang::FunctionProtoType>(function_type_);
if (!function_pt) {
return true;
}
for (unsigned i = 0, e = function_pt->getNumParams(); i != e; ++i) {
clang::QualType param_type = function_pt->getParamType(i);
if (!SetupFunctionParameter(function_type_ir, param_type, false,
source_file_)) {
return false;
}
}
return true;
}
bool FunctionTypeWrapper::GetFunctionType() {
auto abi_decl = std::make_unique<repr::FunctionTypeIR>();
clang::QualType canonical_type = function_type_->getCanonicalTypeInternal();
if (!CreateBasicNamedAndTypedDecl(canonical_type, abi_decl.get(), "")) {
llvm::errs() << "Couldn't create (function type) extended type\n";
return false;
}
return SetupFunctionType(abi_decl.get()) &&
module_->AddLinkableMessage(*abi_decl);
}
//------------------------------------------------------------------------------
// Function Decl Wrapper
//------------------------------------------------------------------------------
FunctionDeclWrapper::FunctionDeclWrapper(
clang::MangleContext *mangle_contextp,
clang::ASTContext *ast_contextp,
const clang::CompilerInstance *compiler_instance_p,
const clang::FunctionDecl *decl,
repr::ModuleIR *module,
ASTCaches *ast_caches)
: ABIWrapper(mangle_contextp, ast_contextp, compiler_instance_p, module,
ast_caches),
function_decl_(decl) {}
bool FunctionDeclWrapper::SetupThisParameter(repr::FunctionIR *functionp,
const std::string &source_file) {
const clang::CXXMethodDecl *cxx_method_decl =
llvm::dyn_cast<clang::CXXMethodDecl>(function_decl_);
// No this pointer for static methods.
if (!cxx_method_decl || cxx_method_decl->isStatic()) {
return true;
}
clang::QualType this_type = cxx_method_decl->getThisType();
return SetupFunctionParameter(functionp, this_type, false, source_file, true);
}
bool FunctionDeclWrapper::SetupFunctionParameters(
repr::FunctionIR *functionp,
const std::string &source_file) {
clang::FunctionDecl::param_const_iterator param_it =
function_decl_->param_begin();
// If this is a CXXMethodDecl, we need to add the "this" pointer.
if (!SetupThisParameter(functionp, source_file)) {
llvm::errs() << "Setting up 'this' parameter failed\n";
return false;
}
while (param_it != function_decl_->param_end()) {
// The linker set key is blank since that shows up in the mangled name.
bool has_default_arg = (*param_it)->hasDefaultArg();
clang::QualType param_qt = (*param_it)->getType();
if (!SetupFunctionParameter(functionp, param_qt, has_default_arg,
source_file)) {
return false;
}
param_it++;
}
return true;
}
bool FunctionDeclWrapper::SetupFunction(repr::FunctionIR *functionp,
const std::string &source_file) {
// Go through all the parameters in the method and add them to the fields.
// Also get the fully qualfied name.
// TODO: Change this to get the complete function signature
functionp->SetName(function_decl_->getQualifiedNameAsString());
functionp->SetSourceFile(source_file);
clang::QualType return_type = function_decl_->getReturnType();
functionp->SetReturnType(GetTypeUniqueId(return_type));
functionp->SetAccess(AccessClangToIR(function_decl_->getAccess()));
return CreateBasicNamedAndTypedDecl(return_type, source_file) &&
SetupFunctionParameters(functionp, source_file) &&
SetupTemplateInfo(functionp, source_file);
}
bool FunctionDeclWrapper::SetupTemplateInfo(repr::FunctionIR *functionp,
const std::string &source_file) {
switch (function_decl_->getTemplatedKind()) {
case clang::FunctionDecl::TK_FunctionTemplateSpecialization: {
const clang::TemplateArgumentList *arg_list =
function_decl_->getTemplateSpecializationArgs();
if (arg_list && !SetupTemplateArguments(arg_list, functionp,
source_file)) {
return false;
}
break;
}
default: {
break;
}
}
return true;
}
std::unique_ptr<repr::FunctionIR> FunctionDeclWrapper::GetFunctionDecl() {
auto abi_decl = std::make_unique<repr::FunctionIR>();
std::string source_file = GetCachedDeclSourceFile(function_decl_, cip_);
if (!SetupFunction(abi_decl.get(), source_file)) {
return nullptr;
}
return abi_decl;
}
//------------------------------------------------------------------------------
// Record Decl Wrapper
//------------------------------------------------------------------------------
RecordDeclWrapper::RecordDeclWrapper(
clang::MangleContext *mangle_contextp,
clang::ASTContext *ast_contextp,
const clang::CompilerInstance *compiler_instance_p,
const clang::RecordDecl *decl, repr::ModuleIR *module,
ASTCaches *ast_caches)
: ABIWrapper(mangle_contextp, ast_contextp, compiler_instance_p, module,
ast_caches),
record_decl_(decl) {}
bool RecordDeclWrapper::SetupRecordFields(repr::RecordTypeIR *recordp,
const std::string &source_file) {
clang::RecordDecl::field_iterator field = record_decl_->field_begin();
uint32_t field_index = 0;
const clang::ASTRecordLayout &record_layout =
ast_contextp_->getASTRecordLayout(record_decl_);
while (field != record_decl_->field_end()) {
clang::QualType field_type = field->getType();
if (!CreateBasicNamedAndTypedDecl(field_type, source_file)) {
llvm::errs() << "Creation of Type failed\n";
return false;
}
std::string field_name = field->getName();
uint64_t field_offset = record_layout.getFieldOffset(field_index);
recordp->AddRecordField(repr::RecordFieldIR(
field_name, GetTypeUniqueId(field_type), field_offset,
AccessClangToIR(field->getAccess())));
field++;
field_index++;
}
return true;
}
bool RecordDeclWrapper::SetupCXXBases(
repr::RecordTypeIR *cxxp, const clang::CXXRecordDecl *cxx_record_decl) {
if (!cxx_record_decl || !cxxp) {
return false;
}
clang::CXXRecordDecl::base_class_const_iterator base_class =
cxx_record_decl->bases_begin();
while (base_class != cxx_record_decl->bases_end()) {
bool is_virtual = base_class->isVirtual();
repr::AccessSpecifierIR access =
AccessClangToIR(base_class->getAccessSpecifier());
cxxp->AddCXXBaseSpecifier(repr::CXXBaseSpecifierIR(
GetTypeUniqueId(base_class->getType()), is_virtual, access));
base_class++;
}
return true;
}
typedef std::map<uint64_t, clang::ThunkInfo> ThunkMap;
bool RecordDeclWrapper::SetupRecordVTable(
repr::RecordTypeIR *record_declp,
const clang::CXXRecordDecl *cxx_record_decl) {
if (!cxx_record_decl || !record_declp) {
return false;
}
clang::VTableContextBase *base_vtable_contextp =
ast_contextp_->getVTableContext();
const clang::Type *typep = cxx_record_decl->getTypeForDecl();
if (!base_vtable_contextp || !typep) {
return false;
}
// Skip Microsoft ABI.
clang::ItaniumVTableContext *itanium_vtable_contextp =
llvm::dyn_cast<clang::ItaniumVTableContext>(base_vtable_contextp);
if (!itanium_vtable_contextp || !cxx_record_decl->isPolymorphic() ||
typep->isDependentType() || typep->isIncompleteType()) {
return true;
}
const clang::VTableLayout &vtable_layout =
itanium_vtable_contextp->getVTableLayout(cxx_record_decl);
llvm::ArrayRef<clang::VTableLayout::VTableThunkTy> thunks =
vtable_layout.vtable_thunks();
ThunkMap thunk_map(thunks.begin(), thunks.end());
repr::VTableLayoutIR vtable_ir_layout;
uint64_t index = 0;
for (auto vtable_component : vtable_layout.vtable_components()) {
clang::ThunkInfo thunk_info;
ThunkMap::iterator it = thunk_map.find(index);
if (it != thunk_map.end()) {
thunk_info = it->second;
}
repr::VTableComponentIR added_component =
SetupRecordVTableComponent(vtable_component, thunk_info);
vtable_ir_layout.AddVTableComponent(std::move(added_component));
index++;
}
record_declp->SetVTableLayout(std::move(vtable_ir_layout));
return true;
}
repr::VTableComponentIR RecordDeclWrapper::SetupRecordVTableComponent(
const clang::VTableComponent &vtable_component,
const clang::ThunkInfo &thunk_info) {
repr::VTableComponentIR::Kind kind =
repr::VTableComponentIR::Kind::RTTI;
std::string mangled_component_name = "";
llvm::raw_string_ostream ostream(mangled_component_name);
int64_t value = 0;
clang::VTableComponent::Kind clang_component_kind =
vtable_component.getKind();
bool is_pure = false;
switch (clang_component_kind) {
case clang::VTableComponent::CK_VCallOffset:
kind = repr::VTableComponentIR::Kind::VCallOffset;
value = vtable_component.getVCallOffset().getQuantity();
break;
case clang::VTableComponent::CK_VBaseOffset:
kind = repr::VTableComponentIR::Kind::VBaseOffset;
value = vtable_component.getVBaseOffset().getQuantity();
break;
case clang::VTableComponent::CK_OffsetToTop:
kind = repr::VTableComponentIR::Kind::OffsetToTop;
value = vtable_component.getOffsetToTop().getQuantity();
break;
case clang::VTableComponent::CK_RTTI:
{
kind = repr::VTableComponentIR::Kind::RTTI;
const clang::CXXRecordDecl *rtti_decl =
vtable_component.getRTTIDecl();
assert(rtti_decl != nullptr);
mangled_component_name = GetMangledRTTI(rtti_decl);
}
break;
case clang::VTableComponent::CK_FunctionPointer:
case clang::VTableComponent::CK_CompleteDtorPointer:
case clang::VTableComponent::CK_DeletingDtorPointer:
case clang::VTableComponent::CK_UnusedFunctionPointer:
{
const clang::CXXMethodDecl *method_decl =
vtable_component.getFunctionDecl();
assert(method_decl != nullptr);
is_pure = method_decl->isPure();
switch (clang_component_kind) {
case clang::VTableComponent::CK_FunctionPointer:
kind = repr::VTableComponentIR::Kind::FunctionPointer;
if (thunk_info.isEmpty()) {
mangle_contextp_->mangleName(method_decl, ostream);
} else {
mangle_contextp_->mangleThunk(method_decl, thunk_info, ostream);
}
ostream.flush();
break;
case clang::VTableComponent::CK_CompleteDtorPointer:
case clang::VTableComponent::CK_DeletingDtorPointer:
{
clang::CXXDtorType dtor_type;
if (clang_component_kind ==
clang::VTableComponent::CK_CompleteDtorPointer) {
dtor_type = clang::CXXDtorType::Dtor_Complete;
kind = repr::VTableComponentIR::Kind::CompleteDtorPointer;
} else {
dtor_type = clang::CXXDtorType::Dtor_Deleting;
kind = repr::VTableComponentIR::Kind::DeletingDtorPointer;
}
if (thunk_info.isEmpty()) {
mangle_contextp_->mangleCXXDtor(
vtable_component.getDestructorDecl(), dtor_type, ostream);
} else {
mangle_contextp_->mangleCXXDtorThunk(
vtable_component.getDestructorDecl(), dtor_type,
thunk_info.This, ostream);
}
ostream.flush();
}
break;
case clang::VTableComponent::CK_UnusedFunctionPointer:
kind = repr::VTableComponentIR::Kind::UnusedFunctionPointer;
break;
default:
break;
}
}
break;
default:
break;
}
return repr::VTableComponentIR(mangled_component_name, kind, value,
is_pure);
}
bool RecordDeclWrapper::SetupTemplateInfo(
repr::RecordTypeIR *record_declp,
const clang::CXXRecordDecl *cxx_record_decl,
const std::string &source_file) {
assert(cxx_record_decl != nullptr);
const clang::ClassTemplateSpecializationDecl *specialization_decl =
clang::dyn_cast<clang::ClassTemplateSpecializationDecl>(cxx_record_decl);
if (specialization_decl) {
const clang::TemplateArgumentList *arg_list =
&specialization_decl->getTemplateArgs();
if (arg_list &&
!SetupTemplateArguments(arg_list, record_declp, source_file)) {
return false;
}
}
return true;
}
bool RecordDeclWrapper::SetupRecordInfo(repr::RecordTypeIR *record_declp,
const std::string &source_file) {
if (!record_declp) {
return false;
}
if (record_decl_->isStruct()) {
record_declp->SetRecordKind(
repr::RecordTypeIR::RecordKind::struct_kind);
} else if (record_decl_->isClass()) {
record_declp->SetRecordKind(
repr::RecordTypeIR::RecordKind::class_kind);
} else {
record_declp->SetRecordKind(
repr::RecordTypeIR::RecordKind::union_kind);
}
const clang::Type *basic_type = nullptr;
if (!(basic_type = record_decl_->getTypeForDecl())) {
return false;
}
clang::QualType qual_type = basic_type->getCanonicalTypeInternal();
if (!CreateExtendedType(qual_type, record_declp)) {
return false;
}
record_declp->SetSourceFile(source_file);
if (!record_decl_->hasNameForLinkage() ||
record_decl_->isAnonymousStructOrUnion()) {
record_declp->SetAnonymity(true);
}
record_declp->SetAccess(AccessClangToIR(record_decl_->getAccess()));
return SetupRecordFields(record_declp, source_file) &&
SetupCXXRecordInfo(record_declp, source_file);
}
bool RecordDeclWrapper::SetupCXXRecordInfo(repr::RecordTypeIR *record_declp,
const std::string &source_file) {
const clang::CXXRecordDecl *cxx_record_decl =
clang::dyn_cast<clang::CXXRecordDecl>(record_decl_);
if (!cxx_record_decl) {
return true;
}
return SetupTemplateInfo(record_declp, cxx_record_decl, source_file) &&
SetupCXXBases(record_declp, cxx_record_decl) &&
SetupRecordVTable(record_declp, cxx_record_decl);
}
// TODO: Can we use clang's ODR hash to do faster ODR checking?
bool RecordDeclWrapper::GetRecordDecl() {
auto abi_decl = std::make_unique<repr::RecordTypeIR>();
std::string source_file = GetCachedDeclSourceFile(record_decl_, cip_);
if (!SetupRecordInfo(abi_decl.get(), source_file)) {
llvm::errs() << "Setting up CXX Bases / Template Info failed\n";
return false;
}
if ((abi_decl->GetReferencedType() == "") ||
(abi_decl->GetSelfType() == "")) {
// The only way to have an empty referenced / self type is when the type was
// cached, don't add the record.
return true;
}
return module_->AddLinkableMessage(*abi_decl);
}
std::string RecordDeclWrapper::GetMangledRTTI(
const clang::CXXRecordDecl *cxx_record_decl) {
clang::QualType qual_type =
cxx_record_decl->getTypeForDecl()->getCanonicalTypeInternal();
llvm::SmallString<256> uid;
llvm::raw_svector_ostream out(uid);
mangle_contextp_->mangleCXXRTTI(qual_type, out);
return uid.str();
}
//------------------------------------------------------------------------------
// Enum Decl Wrapper
//------------------------------------------------------------------------------
EnumDeclWrapper::EnumDeclWrapper(
clang::MangleContext *mangle_contextp,
clang::ASTContext *ast_contextp,
const clang::CompilerInstance *compiler_instance_p,
const clang::EnumDecl *decl, repr::ModuleIR *module,
ASTCaches *ast_caches)
: ABIWrapper(mangle_contextp, ast_contextp, compiler_instance_p, module,
ast_caches),
enum_decl_(decl) {}
bool EnumDeclWrapper::SetupEnumFields(repr::EnumTypeIR *enump) {
if (!enump) {
return false;
}
clang::EnumDecl::enumerator_iterator enum_it = enum_decl_->enumerator_begin();
while (enum_it != enum_decl_->enumerator_end()) {
std::string name = enum_it->getQualifiedNameAsString();
uint64_t field_value = enum_it->getInitVal().getExtValue();
enump->AddEnumField(repr::EnumFieldIR(name, field_value));
enum_it++;
}
return true;
}
bool EnumDeclWrapper::SetupEnum(repr::EnumTypeIR *enum_type,
const std::string &source_file) {
clang::QualType enum_qual_type =
enum_decl_->getTypeForDecl()->getCanonicalTypeInternal();
if (!CreateExtendedType(enum_qual_type, enum_type)) {
return false;
}
enum_type->SetSourceFile(source_file);
enum_type->SetUnderlyingType(GetTypeUniqueId(enum_decl_->getIntegerType()));
enum_type->SetAccess(AccessClangToIR(enum_decl_->getAccess()));
return SetupEnumFields(enum_type) &&
CreateBasicNamedAndTypedDecl(enum_decl_->getIntegerType(), "");
}
bool EnumDeclWrapper::GetEnumDecl() {
auto abi_decl = std::make_unique<repr::EnumTypeIR>();
std::string source_file = GetCachedDeclSourceFile(enum_decl_, cip_);
if (!SetupEnum(abi_decl.get(), source_file)) {
llvm::errs() << "Setting up Enum failed\n";
return false;
}
return module_->AddLinkableMessage(*abi_decl);
}
//------------------------------------------------------------------------------
// Global Decl Wrapper
//------------------------------------------------------------------------------
GlobalVarDeclWrapper::GlobalVarDeclWrapper(
clang::MangleContext *mangle_contextp,
clang::ASTContext *ast_contextp,
const clang::CompilerInstance *compiler_instance_p,
const clang::VarDecl *decl, repr::ModuleIR *module,
ASTCaches *ast_caches)
: ABIWrapper(mangle_contextp, ast_contextp, compiler_instance_p, module,
ast_caches),
global_var_decl_(decl) {}
bool GlobalVarDeclWrapper::SetupGlobalVar(repr::GlobalVarIR *global_varp,
const std::string &source_file) {
// Temporary fix: clang segfaults on trying to mangle global variable which
// is a dependent sized array type.
std::string mangled_name =
GetMangledNameDecl(global_var_decl_, mangle_contextp_);
if (!CreateBasicNamedAndTypedDecl(global_var_decl_->getType(), source_file)) {
return false;
}
global_varp->SetSourceFile(source_file);
global_varp->SetName(global_var_decl_->getQualifiedNameAsString());
global_varp->SetLinkerSetKey(mangled_name);
global_varp->SetAccess(AccessClangToIR(global_var_decl_->getAccess()));
global_varp->SetReferencedType(GetTypeUniqueId(global_var_decl_->getType()));
return true;
}
bool GlobalVarDeclWrapper::GetGlobalVarDecl() {
auto abi_decl = std::make_unique<repr::GlobalVarIR>();
std::string source_file = GetCachedDeclSourceFile(global_var_decl_, cip_);
return SetupGlobalVar(abi_decl.get(), source_file) &&
module_->AddLinkableMessage(*abi_decl);
}
} // dumper
} // header_checker