lib/CodeGen/CodeGenTypes.cpp

5f016e2cb5d11daeb237544de1c5d59f20fe1a6eReid Spencer//===--- CodeGenTypes.cpp - Type translation for LLVM CodeGen -------------===//
5f016e2cb5d11daeb237544de1c5d59f20fe1a6eReid Spencer//
5f016e2cb5d11daeb237544de1c5d59f20fe1a6eReid Spencer//                     The LLVM Compiler Infrastructure
5f016e2cb5d11daeb237544de1c5d59f20fe1a6eReid Spencer//
0bc735ffcfb223c0186419547abaa5c84482663eChris Lattner// This file is distributed under the University of Illinois Open Source
0bc735ffcfb223c0186419547abaa5c84482663eChris Lattner// License. See LICENSE.TXT for details.
5f016e2cb5d11daeb237544de1c5d59f20fe1a6eReid Spencer//
5f016e2cb5d11daeb237544de1c5d59f20fe1a6eReid Spencer//===----------------------------------------------------------------------===//
5f016e2cb5d11daeb237544de1c5d59f20fe1a6eReid Spencer//
1eb4433ac451dc16f4133a88af2d002ac26c58efMike Stump// This is the code that handles AST -> LLVM type lowering.
5f016e2cb5d11daeb237544de1c5d59f20fe1a6eReid Spencer//
5f016e2cb5d11daeb237544de1c5d59f20fe1a6eReid Spencer//===----------------------------------------------------------------------===//
5f016e2cb5d11daeb237544de1c5d59f20fe1a6eReid Spencer
5f016e2cb5d11daeb237544de1c5d59f20fe1a6eReid Spencer#include "CodeGenTypes.h"
de7fb8413b13651fd85b7125d08b3c9ac2816d9dDaniel Dunbar#include "clang/AST/ASTContext.h"
c4a1dea2dc56bd1357ec91b829a0b9e68229a13eDaniel Dunbar#include "clang/AST/DeclObjC.h"
742cd1b7bb86b52b23b335d47abbd842dac0e1bfFariborz Jahanian#include "clang/AST/DeclCXX.h"
de7fb8413b13651fd85b7125d08b3c9ac2816d9dDaniel Dunbar#include "clang/AST/Expr.h"
19cc4abea06a9b49e0e16a50d335c064cd723572Anders Carlsson#include "clang/AST/RecordLayout.h"
5f016e2cb5d11daeb237544de1c5d59f20fe1a6eReid Spencer#include "llvm/DerivedTypes.h"
4e533287e6a9adac78c9ac370612581aad9b8c5eAnders Carlsson#include "llvm/Module.h"
d9e9ede6b1703849da739629904dad197306e527Devang Patel#include "llvm/Target/TargetData.h"
5f016e2cb5d11daeb237544de1c5d59f20fe1a6eReid Spencer
45c25ba11cbf8c9a461def5b03f6ee9481e06769Daniel Dunbar#include "CGCall.h"
45372a6fdcd2b0840704569478db456822e02baeAnders Carlsson#include "CGRecordLayoutBuilder.h"
45c25ba11cbf8c9a461def5b03f6ee9481e06769Daniel Dunbar
5f016e2cb5d11daeb237544de1c5d59f20fe1a6eReid Spencerusing namespace clang;
5f016e2cb5d11daeb237544de1c5d59f20fe1a6eReid Spencerusing namespace CodeGen;
5f016e2cb5d11daeb237544de1c5d59f20fe1a6eReid Spencer
7a4718e813e5e99d478567a482217c7eef8572c5Devang PatelCodeGenTypes::CodeGenTypes(ASTContext &Ctx, llvm::Module& M,
7a4718e813e5e99d478567a482217c7eef8572c5Devang Patel                           const llvm::TargetData &TD)
6b1da0ea19c12346192f5ea4d70872c13bfcc82aDaniel Dunbar  : Context(Ctx), Target(Ctx.Target), TheModule(M), TheTargetData(TD),
6b1da0ea19c12346192f5ea4d70872c13bfcc82aDaniel Dunbar    TheABIInfo(0) {
d2d2a11a91d7ddf468bfb70f66362d24806ed601Chris Lattner}
5f016e2cb5d11daeb237544de1c5d59f20fe1a6eReid Spencer
b84a06e68ffd71da22e3c75b6e4bbdba37816413Devang PatelCodeGenTypes::~CodeGenTypes() {
1eb4433ac451dc16f4133a88af2d002ac26c58efMike Stump  for (llvm::DenseMap<const Type *, CGRecordLayout *>::iterator
1eb4433ac451dc16f4133a88af2d002ac26c58efMike Stump         I = CGRecordLayouts.begin(), E = CGRecordLayouts.end();
b84a06e68ffd71da22e3c75b6e4bbdba37816413Devang Patel      I != E; ++I)
b84a06e68ffd71da22e3c75b6e4bbdba37816413Devang Patel    delete I->second;
f8f1893c2860e119f8719b49e2a97fee71f87733Eli Friedman  {
f8f1893c2860e119f8719b49e2a97fee71f87733Eli Friedman    llvm::FoldingSet<CGFunctionInfo>::iterator
f8f1893c2860e119f8719b49e2a97fee71f87733Eli Friedman         I = FunctionInfos.begin(), E = FunctionInfos.end();
f8f1893c2860e119f8719b49e2a97fee71f87733Eli Friedman    while (I != E)
f8f1893c2860e119f8719b49e2a97fee71f87733Eli Friedman      delete &*I++;
f8f1893c2860e119f8719b49e2a97fee71f87733Eli Friedman  }
f8f1893c2860e119f8719b49e2a97fee71f87733Eli Friedman  delete TheABIInfo;
b84a06e68ffd71da22e3c75b6e4bbdba37816413Devang Patel}
b84a06e68ffd71da22e3c75b6e4bbdba37816413Devang Patel
5f016e2cb5d11daeb237544de1c5d59f20fe1a6eReid Spencer/// ConvertType - Convert the specified type to its LLVM form.
5f016e2cb5d11daeb237544de1c5d59f20fe1a6eReid Spencerconst llvm::Type *CodeGenTypes::ConvertType(QualType T) {
fce71b8ea53b6eb9c1630da24659289bc848f837Chris Lattner  llvm::PATypeHolder Result = ConvertTypeRecursive(T);
fce71b8ea53b6eb9c1630da24659289bc848f837Chris Lattner
fce71b8ea53b6eb9c1630da24659289bc848f837Chris Lattner  // Any pointers that were converted defered evaluation of their pointee type,
fce71b8ea53b6eb9c1630da24659289bc848f837Chris Lattner  // creating an opaque type instead.  This is in order to avoid problems with
fce71b8ea53b6eb9c1630da24659289bc848f837Chris Lattner  // circular types.  Loop through all these defered pointees, if any, and
fce71b8ea53b6eb9c1630da24659289bc848f837Chris Lattner  // resolve them now.
fce71b8ea53b6eb9c1630da24659289bc848f837Chris Lattner  while (!PointersToResolve.empty()) {
6aeae7fa9cfaacba3a4077d62c01c2531d88a63eDaniel Dunbar    std::pair<QualType, llvm::OpaqueType*> P =
fce71b8ea53b6eb9c1630da24659289bc848f837Chris Lattner      PointersToResolve.back();
fce71b8ea53b6eb9c1630da24659289bc848f837Chris Lattner    PointersToResolve.pop_back();
fce71b8ea53b6eb9c1630da24659289bc848f837Chris Lattner    // We can handle bare pointers here because we know that the only pointers
fce71b8ea53b6eb9c1630da24659289bc848f837Chris Lattner    // to the Opaque type are P.second and from other types.  Refining the
fce71b8ea53b6eb9c1630da24659289bc848f837Chris Lattner    // opqaue type away will invalidate P.second, but we don't mind :).
57a84fb51de4f3de50debcf12dd194af8c6aaa58Eli Friedman    const llvm::Type *NT = ConvertTypeForMemRecursive(P.first);
fce71b8ea53b6eb9c1630da24659289bc848f837Chris Lattner    P.second->refineAbstractTypeTo(NT);
fce71b8ea53b6eb9c1630da24659289bc848f837Chris Lattner  }
fce71b8ea53b6eb9c1630da24659289bc848f837Chris Lattner
fce71b8ea53b6eb9c1630da24659289bc848f837Chris Lattner  return Result;
fce71b8ea53b6eb9c1630da24659289bc848f837Chris Lattner}
fce71b8ea53b6eb9c1630da24659289bc848f837Chris Lattner
fce71b8ea53b6eb9c1630da24659289bc848f837Chris Lattnerconst llvm::Type *CodeGenTypes::ConvertTypeRecursive(QualType T) {
09dc6660487fc2f4a4bb2032e30123d3e0da7230Chris Lattner  T = Context.getCanonicalType(T);
1eb4433ac451dc16f4133a88af2d002ac26c58efMike Stump
30ec9972be5a5af1f7a2277360dfa3aa1540b4faDevang Patel  // See if type is already cached.
0ffe89ab1e4890899e0e11a6f68223567a69b38aDevang Patel  llvm::DenseMap<Type *, llvm::PATypeHolder>::iterator
9619662a1d42e2008b865d3459c0677e149dad1bChris Lattner    I = TypeCache.find(T.getTypePtr());
3c40085b373d8e6e4523812e06f73a0cb9d5142cDevang Patel  // If type is found in map and this is not a definition for a opaque
fae6e2994a51d8ec1e61b6eb68765247c83b1ccfChris Lattner  // place holder type then use it. Otherwise, convert type T.
4581fff8af09a156a9dcc4de62587385c5da9574Chris Lattner  if (I != TypeCache.end())
47c87b4b160d45285b24b1b7f4e3cbaaed3dc464Devang Patel    return I->second.get();
30ec9972be5a5af1f7a2277360dfa3aa1540b4faDevang Patel
30ec9972be5a5af1f7a2277360dfa3aa1540b4faDevang Patel  const llvm::Type *ResultType = ConvertNewType(T);
1eb4433ac451dc16f4133a88af2d002ac26c58efMike Stump  TypeCache.insert(std::make_pair(T.getTypePtr(),
4581fff8af09a156a9dcc4de62587385c5da9574Chris Lattner                                  llvm::PATypeHolder(ResultType)));
30ec9972be5a5af1f7a2277360dfa3aa1540b4faDevang Patel  return ResultType;
30ec9972be5a5af1f7a2277360dfa3aa1540b4faDevang Patel}
30ec9972be5a5af1f7a2277360dfa3aa1540b4faDevang Patel
57a84fb51de4f3de50debcf12dd194af8c6aaa58Eli Friedmanconst llvm::Type *CodeGenTypes::ConvertTypeForMemRecursive(QualType T) {
57a84fb51de4f3de50debcf12dd194af8c6aaa58Eli Friedman  const llvm::Type *ResultType = ConvertTypeRecursive(T);
0032b2781b4deb131f8c9b7968f2030bf2489cddOwen Anderson  if (ResultType == llvm::Type::getInt1Ty(getLLVMContext()))
0032b2781b4deb131f8c9b7968f2030bf2489cddOwen Anderson    return llvm::IntegerType::get(getLLVMContext(),
0032b2781b4deb131f8c9b7968f2030bf2489cddOwen Anderson                                  (unsigned)Context.getTypeSize(T));
57a84fb51de4f3de50debcf12dd194af8c6aaa58Eli Friedman  return ResultType;
57a84fb51de4f3de50debcf12dd194af8c6aaa58Eli Friedman}
57a84fb51de4f3de50debcf12dd194af8c6aaa58Eli Friedman
4581fff8af09a156a9dcc4de62587385c5da9574Chris Lattner/// ConvertTypeForMem - Convert type T into a llvm::Type.  This differs from
4581fff8af09a156a9dcc4de62587385c5da9574Chris Lattner/// ConvertType in that it is used to convert to the memory representation for
4581fff8af09a156a9dcc4de62587385c5da9574Chris Lattner/// a type.  For example, the scalar representation for _Bool is i1, but the
4581fff8af09a156a9dcc4de62587385c5da9574Chris Lattner/// memory representation is usually i8 or i32, depending on the target.
19009e6fe7e0f51d2e49f4c94928a048c11c5281Chris Lattnerconst llvm::Type *CodeGenTypes::ConvertTypeForMem(QualType T) {
19009e6fe7e0f51d2e49f4c94928a048c11c5281Chris Lattner  const llvm::Type *R = ConvertType(T);
1eb4433ac451dc16f4133a88af2d002ac26c58efMike Stump
19009e6fe7e0f51d2e49f4c94928a048c11c5281Chris Lattner  // If this is a non-bool type, don't map it.
0032b2781b4deb131f8c9b7968f2030bf2489cddOwen Anderson  if (R != llvm::Type::getInt1Ty(getLLVMContext()))
19009e6fe7e0f51d2e49f4c94928a048c11c5281Chris Lattner    return R;
1eb4433ac451dc16f4133a88af2d002ac26c58efMike Stump
19009e6fe7e0f51d2e49f4c94928a048c11c5281Chris Lattner  // Otherwise, return an integer of the target-specified size.
0032b2781b4deb131f8c9b7968f2030bf2489cddOwen Anderson  return llvm::IntegerType::get(getLLVMContext(),
0032b2781b4deb131f8c9b7968f2030bf2489cddOwen Anderson                                (unsigned)Context.getTypeSize(T));
1eb4433ac451dc16f4133a88af2d002ac26c58efMike Stump
19009e6fe7e0f51d2e49f4c94928a048c11c5281Chris Lattner}
19009e6fe7e0f51d2e49f4c94928a048c11c5281Chris Lattner
b3b6b9b27ab8bdb2a435a5a92ce62e74e3399377Eli Friedman// Code to verify a given function type is complete, i.e. the return type
b3b6b9b27ab8bdb2a435a5a92ce62e74e3399377Eli Friedman// and all of the argument types are complete.
b3b6b9b27ab8bdb2a435a5a92ce62e74e3399377Eli Friedmanstatic const TagType *VerifyFuncTypeComplete(const Type* T) {
b3b6b9b27ab8bdb2a435a5a92ce62e74e3399377Eli Friedman  const FunctionType *FT = cast<FunctionType>(T);
6217b80b7a1379b74cced1c076338262c3c980b3Ted Kremenek  if (const TagType* TT = FT->getResultType()->getAs<TagType>())
b3b6b9b27ab8bdb2a435a5a92ce62e74e3399377Eli Friedman    if (!TT->getDecl()->isDefinition())
b3b6b9b27ab8bdb2a435a5a92ce62e74e3399377Eli Friedman      return TT;
b3b6b9b27ab8bdb2a435a5a92ce62e74e3399377Eli Friedman  if (const FunctionProtoType *FPT = dyn_cast<FunctionProtoType>(T))
b3b6b9b27ab8bdb2a435a5a92ce62e74e3399377Eli Friedman    for (unsigned i = 0; i < FPT->getNumArgs(); i++)
6217b80b7a1379b74cced1c076338262c3c980b3Ted Kremenek      if (const TagType* TT = FPT->getArgType(i)->getAs<TagType>())
b3b6b9b27ab8bdb2a435a5a92ce62e74e3399377Eli Friedman        if (!TT->getDecl()->isDefinition())
b3b6b9b27ab8bdb2a435a5a92ce62e74e3399377Eli Friedman          return TT;
b3b6b9b27ab8bdb2a435a5a92ce62e74e3399377Eli Friedman  return 0;
b3b6b9b27ab8bdb2a435a5a92ce62e74e3399377Eli Friedman}
b3b6b9b27ab8bdb2a435a5a92ce62e74e3399377Eli Friedman
c5b8806cda286cf41866176ef98011fdaa68da01Chris Lattner/// UpdateCompletedType - When we find the full definition for a TagDecl,
c5b8806cda286cf41866176ef98011fdaa68da01Chris Lattner/// replace the 'opaque' type we previously made for it if applicable.
c5b8806cda286cf41866176ef98011fdaa68da01Chris Lattnervoid CodeGenTypes::UpdateCompletedType(const TagDecl *TD) {
e607ed068334bacb8d7b093996b4671c6ca79e25Mike Stump  const Type *Key = Context.getTagDeclType(TD).getTypePtr();
1eb4433ac451dc16f4133a88af2d002ac26c58efMike Stump  llvm::DenseMap<const Type*, llvm::PATypeHolder>::iterator TDTI =
efb6d0dc3eafbcf4f8cd053138bd1abed1dda8d4Daniel Dunbar    TagDeclTypes.find(Key);
6ef58e36bbbfa232fe8b50309361e841985abfc6Chris Lattner  if (TDTI == TagDeclTypes.end()) return;
1eb4433ac451dc16f4133a88af2d002ac26c58efMike Stump
6ef58e36bbbfa232fe8b50309361e841985abfc6Chris Lattner  // Remember the opaque LLVM type for this tagdecl.
d86e6bc7ab4388a578daf46e7c76be9122a25072Chris Lattner  llvm::PATypeHolder OpaqueHolder = TDTI->second;
d86e6bc7ab4388a578daf46e7c76be9122a25072Chris Lattner  assert(isa<llvm::OpaqueType>(OpaqueHolder.get()) &&
6ef58e36bbbfa232fe8b50309361e841985abfc6Chris Lattner         "Updating compilation of an already non-opaque type?");
1eb4433ac451dc16f4133a88af2d002ac26c58efMike Stump
d86e6bc7ab4388a578daf46e7c76be9122a25072Chris Lattner  // Remove it from TagDeclTypes so that it will be regenerated.
d86e6bc7ab4388a578daf46e7c76be9122a25072Chris Lattner  TagDeclTypes.erase(TDTI);
d86e6bc7ab4388a578daf46e7c76be9122a25072Chris Lattner
8fb1dd005f4cb530bca11d622362d39727294420Chris Lattner  // Generate the new type.
8fb1dd005f4cb530bca11d622362d39727294420Chris Lattner  const llvm::Type *NT = ConvertTagDeclType(TD);
d86e6bc7ab4388a578daf46e7c76be9122a25072Chris Lattner
8fb1dd005f4cb530bca11d622362d39727294420Chris Lattner  // Refine the old opaque type to its new definition.
8fb1dd005f4cb530bca11d622362d39727294420Chris Lattner  cast<llvm::OpaqueType>(OpaqueHolder.get())->refineAbstractTypeTo(NT);
b3b6b9b27ab8bdb2a435a5a92ce62e74e3399377Eli Friedman
b3b6b9b27ab8bdb2a435a5a92ce62e74e3399377Eli Friedman  // Since we just completed a tag type, check to see if any function types
b3b6b9b27ab8bdb2a435a5a92ce62e74e3399377Eli Friedman  // were completed along with the tag type.
b3b6b9b27ab8bdb2a435a5a92ce62e74e3399377Eli Friedman  // FIXME: This is very inefficient; if we track which function types depend
b3b6b9b27ab8bdb2a435a5a92ce62e74e3399377Eli Friedman  // on which tag types, though, it should be reasonably efficient.
b3b6b9b27ab8bdb2a435a5a92ce62e74e3399377Eli Friedman  llvm::DenseMap<const Type*, llvm::PATypeHolder>::iterator i;
b3b6b9b27ab8bdb2a435a5a92ce62e74e3399377Eli Friedman  for (i = FunctionTypes.begin(); i != FunctionTypes.end(); ++i) {
b3b6b9b27ab8bdb2a435a5a92ce62e74e3399377Eli Friedman    if (const TagType* TT = VerifyFuncTypeComplete(i->first)) {
b3b6b9b27ab8bdb2a435a5a92ce62e74e3399377Eli Friedman      // This function type still depends on an incomplete tag type; make sure
b3b6b9b27ab8bdb2a435a5a92ce62e74e3399377Eli Friedman      // that tag type has an associated opaque type.
b3b6b9b27ab8bdb2a435a5a92ce62e74e3399377Eli Friedman      ConvertTagDeclType(TT->getDecl());
b3b6b9b27ab8bdb2a435a5a92ce62e74e3399377Eli Friedman    } else {
b3b6b9b27ab8bdb2a435a5a92ce62e74e3399377Eli Friedman      // This function no longer depends on an incomplete tag type; create the
b3b6b9b27ab8bdb2a435a5a92ce62e74e3399377Eli Friedman      // function type, and refine the opaque type to the new function type.
b3b6b9b27ab8bdb2a435a5a92ce62e74e3399377Eli Friedman      llvm::PATypeHolder OpaqueHolder = i->second;
b3b6b9b27ab8bdb2a435a5a92ce62e74e3399377Eli Friedman      const llvm::Type *NFT = ConvertNewType(QualType(i->first, 0));
b3b6b9b27ab8bdb2a435a5a92ce62e74e3399377Eli Friedman      cast<llvm::OpaqueType>(OpaqueHolder.get())->refineAbstractTypeTo(NFT);
b3b6b9b27ab8bdb2a435a5a92ce62e74e3399377Eli Friedman      FunctionTypes.erase(i);
b3b6b9b27ab8bdb2a435a5a92ce62e74e3399377Eli Friedman    }
b3b6b9b27ab8bdb2a435a5a92ce62e74e3399377Eli Friedman  }
d86e6bc7ab4388a578daf46e7c76be9122a25072Chris Lattner}
d86e6bc7ab4388a578daf46e7c76be9122a25072Chris Lattner
1eb4433ac451dc16f4133a88af2d002ac26c58efMike Stumpstatic const llvm::Type* getTypeForFormat(llvm::LLVMContext &VMContext,
0032b2781b4deb131f8c9b7968f2030bf2489cddOwen Anderson                                          const llvm::fltSemantics &format) {
b7cfe88e88cb4f46308de89cf3f0c81bfe624128Chris Lattner  if (&format == &llvm::APFloat::IEEEsingle)
0032b2781b4deb131f8c9b7968f2030bf2489cddOwen Anderson    return llvm::Type::getFloatTy(VMContext);
b7cfe88e88cb4f46308de89cf3f0c81bfe624128Chris Lattner  if (&format == &llvm::APFloat::IEEEdouble)
0032b2781b4deb131f8c9b7968f2030bf2489cddOwen Anderson    return llvm::Type::getDoubleTy(VMContext);
b7cfe88e88cb4f46308de89cf3f0c81bfe624128Chris Lattner  if (&format == &llvm::APFloat::IEEEquad)
0032b2781b4deb131f8c9b7968f2030bf2489cddOwen Anderson    return llvm::Type::getFP128Ty(VMContext);
b7cfe88e88cb4f46308de89cf3f0c81bfe624128Chris Lattner  if (&format == &llvm::APFloat::PPCDoubleDouble)
0032b2781b4deb131f8c9b7968f2030bf2489cddOwen Anderson    return llvm::Type::getPPC_FP128Ty(VMContext);
b7cfe88e88cb4f46308de89cf3f0c81bfe624128Chris Lattner  if (&format == &llvm::APFloat::x87DoubleExtended)
0032b2781b4deb131f8c9b7968f2030bf2489cddOwen Anderson    return llvm::Type::getX86_FP80Ty(VMContext);
b7cfe88e88cb4f46308de89cf3f0c81bfe624128Chris Lattner  assert(0 && "Unknown float format!");
f6a943e047f541619a2202f9e43b20b3d7c0a96dEli Friedman  return 0;
f6a943e047f541619a2202f9e43b20b3d7c0a96dEli Friedman}
f6a943e047f541619a2202f9e43b20b3d7c0a96dEli Friedman
30ec9972be5a5af1f7a2277360dfa3aa1540b4faDevang Patelconst llvm::Type *CodeGenTypes::ConvertNewType(QualType T) {
e27ec8ad56dbf1efb2de004b90fbbb86f740e3f1John McCall  const clang::Type &Ty = *Context.getCanonicalType(T).getTypePtr();
1eb4433ac451dc16f4133a88af2d002ac26c58efMike Stump
5f016e2cb5d11daeb237544de1c5d59f20fe1a6eReid Spencer  switch (Ty.getTypeClass()) {
72564e73277e29f6db3305d1f27ba408abb7ed88Douglas Gregor#define TYPE(Class, Base)
72564e73277e29f6db3305d1f27ba408abb7ed88Douglas Gregor#define ABSTRACT_TYPE(Class, Base)
72564e73277e29f6db3305d1f27ba408abb7ed88Douglas Gregor#define NON_CANONICAL_TYPE(Class, Base) case Type::Class:
72564e73277e29f6db3305d1f27ba408abb7ed88Douglas Gregor#define DEPENDENT_TYPE(Class, Base) case Type::Class:
72564e73277e29f6db3305d1f27ba408abb7ed88Douglas Gregor#include "clang/AST/TypeNodes.def"
72564e73277e29f6db3305d1f27ba408abb7ed88Douglas Gregor    assert(false && "Non-canonical or dependent types aren't possible.");
72564e73277e29f6db3305d1f27ba408abb7ed88Douglas Gregor    break;
72564e73277e29f6db3305d1f27ba408abb7ed88Douglas Gregor
5f016e2cb5d11daeb237544de1c5d59f20fe1a6eReid Spencer  case Type::Builtin: {
5f016e2cb5d11daeb237544de1c5d59f20fe1a6eReid Spencer    switch (cast<BuiltinType>(Ty).getKind()) {
afef76e43a30380b3c612a674738f2f574c8f166Argyrios Kyrtzidis    default: assert(0 && "Unknown builtin type!");
5f016e2cb5d11daeb237544de1c5d59f20fe1a6eReid Spencer    case BuiltinType::Void:
de2e22d33afec98324a66a358dfe0951b3c7259aSteve Naroff    case BuiltinType::ObjCId:
de2e22d33afec98324a66a358dfe0951b3c7259aSteve Naroff    case BuiltinType::ObjCClass:
13dcd00615de5c4279d97bdf63cd5f0a14fd9dccFariborz Jahanian    case BuiltinType::ObjCSel:
5f016e2cb5d11daeb237544de1c5d59f20fe1a6eReid Spencer      // LLVM void type can only be used as the result of a function call.  Just
5f016e2cb5d11daeb237544de1c5d59f20fe1a6eReid Spencer      // map to the same as char.
0032b2781b4deb131f8c9b7968f2030bf2489cddOwen Anderson      return llvm::IntegerType::get(getLLVMContext(), 8);
5f016e2cb5d11daeb237544de1c5d59f20fe1a6eReid Spencer
5f016e2cb5d11daeb237544de1c5d59f20fe1a6eReid Spencer    case BuiltinType::Bool:
19009e6fe7e0f51d2e49f4c94928a048c11c5281Chris Lattner      // Note that we always return bool as i1 for use as a scalar type.
0032b2781b4deb131f8c9b7968f2030bf2489cddOwen Anderson      return llvm::Type::getInt1Ty(getLLVMContext());
1eb4433ac451dc16f4133a88af2d002ac26c58efMike Stump
d2d2a11a91d7ddf468bfb70f66362d24806ed601Chris Lattner    case BuiltinType::Char_S:
d2d2a11a91d7ddf468bfb70f66362d24806ed601Chris Lattner    case BuiltinType::Char_U:
d2d2a11a91d7ddf468bfb70f66362d24806ed601Chris Lattner    case BuiltinType::SChar:
d2d2a11a91d7ddf468bfb70f66362d24806ed601Chris Lattner    case BuiltinType::UChar:
5f016e2cb5d11daeb237544de1c5d59f20fe1a6eReid Spencer    case BuiltinType::Short:
5f016e2cb5d11daeb237544de1c5d59f20fe1a6eReid Spencer    case BuiltinType::UShort:
5f016e2cb5d11daeb237544de1c5d59f20fe1a6eReid Spencer    case BuiltinType::Int:
5f016e2cb5d11daeb237544de1c5d59f20fe1a6eReid Spencer    case BuiltinType::UInt:
5f016e2cb5d11daeb237544de1c5d59f20fe1a6eReid Spencer    case BuiltinType::Long:
5f016e2cb5d11daeb237544de1c5d59f20fe1a6eReid Spencer    case BuiltinType::ULong:
5f016e2cb5d11daeb237544de1c5d59f20fe1a6eReid Spencer    case BuiltinType::LongLong:
5f016e2cb5d11daeb237544de1c5d59f20fe1a6eReid Spencer    case BuiltinType::ULongLong:
afef76e43a30380b3c612a674738f2f574c8f166Argyrios Kyrtzidis    case BuiltinType::WChar:
f5c209d23b20ada4a9b6235db50317239cbf6ae1Alisdair Meredith    case BuiltinType::Char16:
f5c209d23b20ada4a9b6235db50317239cbf6ae1Alisdair Meredith    case BuiltinType::Char32:
0032b2781b4deb131f8c9b7968f2030bf2489cddOwen Anderson      return llvm::IntegerType::get(getLLVMContext(),
98be4943e8dc4f3905629a7102668960873cf863Chris Lattner        static_cast<unsigned>(Context.getTypeSize(T)));
1eb4433ac451dc16f4133a88af2d002ac26c58efMike Stump
f6a943e047f541619a2202f9e43b20b3d7c0a96dEli Friedman    case BuiltinType::Float:
c8b1227fa8c17d9881815e40c04e19334be536f8Nate Begeman    case BuiltinType::Double:
5f016e2cb5d11daeb237544de1c5d59f20fe1a6eReid Spencer    case BuiltinType::LongDouble:
1eb4433ac451dc16f4133a88af2d002ac26c58efMike Stump      return getTypeForFormat(getLLVMContext(),
0032b2781b4deb131f8c9b7968f2030bf2489cddOwen Anderson                              Context.getFloatTypeSemantics(T));
1eb4433ac451dc16f4133a88af2d002ac26c58efMike Stump
c1eb14a66fdd955aff3f957a5843295f27952bddAnders Carlsson    case BuiltinType::NullPtr: {
c1eb14a66fdd955aff3f957a5843295f27952bddAnders Carlsson      // Model std::nullptr_t as i8*
c1eb14a66fdd955aff3f957a5843295f27952bddAnders Carlsson      const llvm::Type *Ty = llvm::IntegerType::get(getLLVMContext(), 8);
c1eb14a66fdd955aff3f957a5843295f27952bddAnders Carlsson      return llvm::PointerType::getUnqual(Ty);
c1eb14a66fdd955aff3f957a5843295f27952bddAnders Carlsson    }
c1eb14a66fdd955aff3f957a5843295f27952bddAnders Carlsson
2df9ced9fd1e8c7d7b38443db07e0e811de22571Chris Lattner    case BuiltinType::UInt128:
2df9ced9fd1e8c7d7b38443db07e0e811de22571Chris Lattner    case BuiltinType::Int128:
0032b2781b4deb131f8c9b7968f2030bf2489cddOwen Anderson      return llvm::IntegerType::get(getLLVMContext(), 128);
5f016e2cb5d11daeb237544de1c5d59f20fe1a6eReid Spencer    }
5f016e2cb5d11daeb237544de1c5d59f20fe1a6eReid Spencer    break;
5f016e2cb5d11daeb237544de1c5d59f20fe1a6eReid Spencer  }
f98aba35e6c3da5aae61843fc01334939e4e12ecEli Friedman  case Type::FixedWidthInt:
1eb4433ac451dc16f4133a88af2d002ac26c58efMike Stump    return llvm::IntegerType::get(getLLVMContext(),
0032b2781b4deb131f8c9b7968f2030bf2489cddOwen Anderson                                  cast<FixedWidthIntType>(T)->getWidth());
5f016e2cb5d11daeb237544de1c5d59f20fe1a6eReid Spencer  case Type::Complex: {
1eb4433ac451dc16f4133a88af2d002ac26c58efMike Stump    const llvm::Type *EltTy =
fce71b8ea53b6eb9c1630da24659289bc848f837Chris Lattner      ConvertTypeRecursive(cast<ComplexType>(Ty).getElementType());
47a434ff3d49e7906eda88e8e8242e4297725b32Owen Anderson    return llvm::StructType::get(TheModule.getContext(), EltTy, EltTy, NULL);
5f016e2cb5d11daeb237544de1c5d59f20fe1a6eReid Spencer  }
7c80bd64032e610c0dbd74fc0ef6ea334447f2fdSebastian Redl  case Type::LValueReference:
7c80bd64032e610c0dbd74fc0ef6ea334447f2fdSebastian Redl  case Type::RValueReference: {
6aeae7fa9cfaacba3a4077d62c01c2531d88a63eDaniel Dunbar    const ReferenceType &RTy = cast<ReferenceType>(Ty);
6aeae7fa9cfaacba3a4077d62c01c2531d88a63eDaniel Dunbar    QualType ETy = RTy.getPointeeType();
8c8f69ec1477424e11faef6b235505584d61e522Owen Anderson    llvm::OpaqueType *PointeeType = llvm::OpaqueType::get(getLLVMContext());
6aeae7fa9cfaacba3a4077d62c01c2531d88a63eDaniel Dunbar    PointersToResolve.push_back(std::make_pair(ETy, PointeeType));
6aeae7fa9cfaacba3a4077d62c01c2531d88a63eDaniel Dunbar    return llvm::PointerType::get(PointeeType, ETy.getAddressSpace());
6aeae7fa9cfaacba3a4077d62c01c2531d88a63eDaniel Dunbar  }
5f016e2cb5d11daeb237544de1c5d59f20fe1a6eReid Spencer  case Type::Pointer: {
6aeae7fa9cfaacba3a4077d62c01c2531d88a63eDaniel Dunbar    const PointerType &PTy = cast<PointerType>(Ty);
fce71b8ea53b6eb9c1630da24659289bc848f837Chris Lattner    QualType ETy = PTy.getPointeeType();
8c8f69ec1477424e11faef6b235505584d61e522Owen Anderson    llvm::OpaqueType *PointeeType = llvm::OpaqueType::get(getLLVMContext());
6aeae7fa9cfaacba3a4077d62c01c2531d88a63eDaniel Dunbar    PointersToResolve.push_back(std::make_pair(ETy, PointeeType));
fce71b8ea53b6eb9c1630da24659289bc848f837Chris Lattner    return llvm::PointerType::get(PointeeType, ETy.getAddressSpace());
5f016e2cb5d11daeb237544de1c5d59f20fe1a6eReid Spencer  }
1eb4433ac451dc16f4133a88af2d002ac26c58efMike Stump
fb22d96692c5240fb8d611290dbf7eeed3759c73Steve Naroff  case Type::VariableArray: {
fb22d96692c5240fb8d611290dbf7eeed3759c73Steve Naroff    const VariableArrayType &A = cast<VariableArrayType>(Ty);
0953e767ff7817f97b3ab20896b229891eeff45bJohn McCall    assert(A.getIndexTypeCVRQualifiers() == 0 &&
5f016e2cb5d11daeb237544de1c5d59f20fe1a6eReid Spencer           "FIXME: We only handle trivial array types so far!");
c5773c4b8ce1ed6ed5c7112c9020c954a47dce96Eli Friedman    // VLAs resolve to the innermost element type; this matches
c5773c4b8ce1ed6ed5c7112c9020c954a47dce96Eli Friedman    // the return of alloca, and there isn't any obviously better choice.
57a84fb51de4f3de50debcf12dd194af8c6aaa58Eli Friedman    return ConvertTypeForMemRecursive(A.getElementType());
c5773c4b8ce1ed6ed5c7112c9020c954a47dce96Eli Friedman  }
c5773c4b8ce1ed6ed5c7112c9020c954a47dce96Eli Friedman  case Type::IncompleteArray: {
c5773c4b8ce1ed6ed5c7112c9020c954a47dce96Eli Friedman    const IncompleteArrayType &A = cast<IncompleteArrayType>(Ty);
0953e767ff7817f97b3ab20896b229891eeff45bJohn McCall    assert(A.getIndexTypeCVRQualifiers() == 0 &&
c5773c4b8ce1ed6ed5c7112c9020c954a47dce96Eli Friedman           "FIXME: We only handle trivial array types so far!");
c5773c4b8ce1ed6ed5c7112c9020c954a47dce96Eli Friedman    // int X[] -> [0 x int]
57a84fb51de4f3de50debcf12dd194af8c6aaa58Eli Friedman    return llvm::ArrayType::get(ConvertTypeForMemRecursive(A.getElementType()), 0);
5f016e2cb5d11daeb237544de1c5d59f20fe1a6eReid Spencer  }
fb22d96692c5240fb8d611290dbf7eeed3759c73Steve Naroff  case Type::ConstantArray: {
fb22d96692c5240fb8d611290dbf7eeed3759c73Steve Naroff    const ConstantArrayType &A = cast<ConstantArrayType>(Ty);
57a84fb51de4f3de50debcf12dd194af8c6aaa58Eli Friedman    const llvm::Type *EltTy = ConvertTypeForMemRecursive(A.getElementType());
fb22d96692c5240fb8d611290dbf7eeed3759c73Steve Naroff    return llvm::ArrayType::get(EltTy, A.getSize().getZExtValue());
fb22d96692c5240fb8d611290dbf7eeed3759c73Steve Naroff  }
213541a68a3e137d11d2cefb612c6cdb410d7e8eNate Begeman  case Type::ExtVector:
5f016e2cb5d11daeb237544de1c5d59f20fe1a6eReid Spencer  case Type::Vector: {
5f016e2cb5d11daeb237544de1c5d59f20fe1a6eReid Spencer    const VectorType &VT = cast<VectorType>(Ty);
fce71b8ea53b6eb9c1630da24659289bc848f837Chris Lattner    return llvm::VectorType::get(ConvertTypeRecursive(VT.getElementType()),
5f016e2cb5d11daeb237544de1c5d59f20fe1a6eReid Spencer                                 VT.getNumElements());
5f016e2cb5d11daeb237544de1c5d59f20fe1a6eReid Spencer  }
5f016e2cb5d11daeb237544de1c5d59f20fe1a6eReid Spencer  case Type::FunctionNoProto:
bb36d331f439f49859efcfb4435c61762fbba6f9Daniel Dunbar  case Type::FunctionProto: {
b3b6b9b27ab8bdb2a435a5a92ce62e74e3399377Eli Friedman    // First, check whether we can build the full function type.
b3b6b9b27ab8bdb2a435a5a92ce62e74e3399377Eli Friedman    if (const TagType* TT = VerifyFuncTypeComplete(&Ty)) {
b3b6b9b27ab8bdb2a435a5a92ce62e74e3399377Eli Friedman      // This function's type depends on an incomplete tag type; make sure
b3b6b9b27ab8bdb2a435a5a92ce62e74e3399377Eli Friedman      // we have an opaque type corresponding to the tag type.
b3b6b9b27ab8bdb2a435a5a92ce62e74e3399377Eli Friedman      ConvertTagDeclType(TT->getDecl());
b3b6b9b27ab8bdb2a435a5a92ce62e74e3399377Eli Friedman      // Create an opaque type for this function type, save it, and return it.
8c8f69ec1477424e11faef6b235505584d61e522Owen Anderson      llvm::Type *ResultType = llvm::OpaqueType::get(getLLVMContext());
b3b6b9b27ab8bdb2a435a5a92ce62e74e3399377Eli Friedman      FunctionTypes.insert(std::make_pair(&Ty, ResultType));
b3b6b9b27ab8bdb2a435a5a92ce62e74e3399377Eli Friedman      return ResultType;
b3b6b9b27ab8bdb2a435a5a92ce62e74e3399377Eli Friedman    }
b3b6b9b27ab8bdb2a435a5a92ce62e74e3399377Eli Friedman    // The function type can be built; call the appropriate routines to
b3b6b9b27ab8bdb2a435a5a92ce62e74e3399377Eli Friedman    // build it.
9a1a9c41cf7e2735f059bb0c1d85f3207f637b22Chris Lattner    if (const FunctionProtoType *FPT = dyn_cast<FunctionProtoType>(&Ty))
b3b6b9b27ab8bdb2a435a5a92ce62e74e3399377Eli Friedman      return GetFunctionType(getFunctionInfo(FPT), FPT->isVariadic());
9a1a9c41cf7e2735f059bb0c1d85f3207f637b22Chris Lattner
9a1a9c41cf7e2735f059bb0c1d85f3207f637b22Chris Lattner    const FunctionNoProtoType *FNPT = cast<FunctionNoProtoType>(&Ty);
9a1a9c41cf7e2735f059bb0c1d85f3207f637b22Chris Lattner    return GetFunctionType(getFunctionInfo(FNPT), true);
bb36d331f439f49859efcfb4435c61762fbba6f9Daniel Dunbar  }
1eb4433ac451dc16f4133a88af2d002ac26c58efMike Stump
391d77a26382dddf25da73e29fc1fa5aaaea4c6fChris Lattner  case Type::ObjCInterface: {
412f59b23fc502b199b9ca96c72ef5d5ad21d62bDaniel Dunbar    // Objective-C interfaces are always opaque (outside of the
412f59b23fc502b199b9ca96c72ef5d5ad21d62bDaniel Dunbar    // runtime, which can do whatever it likes); we never refine
412f59b23fc502b199b9ca96c72ef5d5ad21d62bDaniel Dunbar    // these.
412f59b23fc502b199b9ca96c72ef5d5ad21d62bDaniel Dunbar    const llvm::Type *&T = InterfaceTypes[cast<ObjCInterfaceType>(&Ty)];
412f59b23fc502b199b9ca96c72ef5d5ad21d62bDaniel Dunbar    if (!T)
8c8f69ec1477424e11faef6b235505584d61e522Owen Anderson        T = llvm::OpaqueType::get(getLLVMContext());
412f59b23fc502b199b9ca96c72ef5d5ad21d62bDaniel Dunbar    return T;
391d77a26382dddf25da73e29fc1fa5aaaea4c6fChris Lattner  }
1eb4433ac451dc16f4133a88af2d002ac26c58efMike Stump
14108da7f7fc059772711e4ffee1322a27b152a7Steve Naroff  case Type::ObjCObjectPointer: {
28e478010eb4d789da85c6378dbfa9d66b95830bDaniel Dunbar    // Protocol qualifications do not influence the LLVM type, we just return a
28e478010eb4d789da85c6378dbfa9d66b95830bDaniel Dunbar    // pointer to the underlying interface type. We don't need to worry about
28e478010eb4d789da85c6378dbfa9d66b95830bDaniel Dunbar    // recursive conversion.
1eb4433ac451dc16f4133a88af2d002ac26c58efMike Stump    const llvm::Type *T =
28e478010eb4d789da85c6378dbfa9d66b95830bDaniel Dunbar      ConvertTypeRecursive(cast<ObjCObjectPointerType>(Ty).getPointeeType());
28e478010eb4d789da85c6378dbfa9d66b95830bDaniel Dunbar    return llvm::PointerType::getUnqual(T);
14108da7f7fc059772711e4ffee1322a27b152a7Steve Naroff  }
28e478010eb4d789da85c6378dbfa9d66b95830bDaniel Dunbar
72564e73277e29f6db3305d1f27ba408abb7ed88Douglas Gregor  case Type::Record:
72564e73277e29f6db3305d1f27ba408abb7ed88Douglas Gregor  case Type::Enum: {
de0efb3b6eac36bdeae0e60f753a974cc4118a31Chris Lattner    const TagDecl *TD = cast<TagType>(Ty).getDecl();
8fb1dd005f4cb530bca11d622362d39727294420Chris Lattner    const llvm::Type *Res = ConvertTagDeclType(TD);
1eb4433ac451dc16f4133a88af2d002ac26c58efMike Stump
de0efb3b6eac36bdeae0e60f753a974cc4118a31Chris Lattner    std::string TypeName(TD->getKindName());
de0efb3b6eac36bdeae0e60f753a974cc4118a31Chris Lattner    TypeName += '.';
1eb4433ac451dc16f4133a88af2d002ac26c58efMike Stump
de0efb3b6eac36bdeae0e60f753a974cc4118a31Chris Lattner    // Name the codegen type after the typedef name
de0efb3b6eac36bdeae0e60f753a974cc4118a31Chris Lattner    // if there is no tag type name available
de0efb3b6eac36bdeae0e60f753a974cc4118a31Chris Lattner    if (TD->getIdentifier())
6b7fc1344d440b2378d7a1825046c60617cadae2Anders Carlsson      // FIXME: We should not have to check for a null decl context here.
6b7fc1344d440b2378d7a1825046c60617cadae2Anders Carlsson      // Right now we do it because the implicit Obj-C decls don't have one.
6b7fc1344d440b2378d7a1825046c60617cadae2Anders Carlsson      TypeName += TD->getDeclContext() ? TD->getQualifiedNameAsString() :
6b7fc1344d440b2378d7a1825046c60617cadae2Anders Carlsson        TD->getNameAsString();
de0efb3b6eac36bdeae0e60f753a974cc4118a31Chris Lattner    else if (const TypedefType *TdT = dyn_cast<TypedefType>(T))
6b7fc1344d440b2378d7a1825046c60617cadae2Anders Carlsson      // FIXME: We should not have to check for a null decl context here.
6b7fc1344d440b2378d7a1825046c60617cadae2Anders Carlsson      // Right now we do it because the implicit Obj-C decls don't have one.
6b7fc1344d440b2378d7a1825046c60617cadae2Anders Carlsson      TypeName += TdT->getDecl()->getDeclContext() ?
6b7fc1344d440b2378d7a1825046c60617cadae2Anders Carlsson        TdT->getDecl()->getQualifiedNameAsString() :
6b7fc1344d440b2378d7a1825046c60617cadae2Anders Carlsson        TdT->getDecl()->getNameAsString();
de0efb3b6eac36bdeae0e60f753a974cc4118a31Chris Lattner    else
de0efb3b6eac36bdeae0e60f753a974cc4118a31Chris Lattner      TypeName += "anon";
1eb4433ac451dc16f4133a88af2d002ac26c58efMike Stump
1eb4433ac451dc16f4133a88af2d002ac26c58efMike Stump    TheModule.addTypeName(TypeName, Res);
de0efb3b6eac36bdeae0e60f753a974cc4118a31Chris Lattner    return Res;
de0efb3b6eac36bdeae0e60f753a974cc4118a31Chris Lattner  }
9048891ff983d0681c116c6e8f1073aa31bdd6e8Daniel Dunbar
9048891ff983d0681c116c6e8f1073aa31bdd6e8Daniel Dunbar  case Type::BlockPointer: {
4e174f1b1e95faacc21da2eac70f7853807f3ea3Daniel Dunbar    const QualType FTy = cast<BlockPointerType>(Ty).getPointeeType();
8c8f69ec1477424e11faef6b235505584d61e522Owen Anderson    llvm::OpaqueType *PointeeType = llvm::OpaqueType::get(getLLVMContext());
209bb438042ef7652b2b046e43d4ffb5a00d9725Fariborz Jahanian    PointersToResolve.push_back(std::make_pair(FTy, PointeeType));
209bb438042ef7652b2b046e43d4ffb5a00d9725Fariborz Jahanian    return llvm::PointerType::get(PointeeType, FTy.getAddressSpace());
9048891ff983d0681c116c6e8f1073aa31bdd6e8Daniel Dunbar  }
424c51d3d4bea87291919b75e73ca59386702ad5Sebastian Redl
0e650017acdbbeb0c590e77bbea88c200ea1caefAnders Carlsson  case Type::MemberPointer: {
0e650017acdbbeb0c590e77bbea88c200ea1caefAnders Carlsson    // FIXME: This is ABI dependent. We use the Itanium C++ ABI.
0e650017acdbbeb0c590e77bbea88c200ea1caefAnders Carlsson    // http://www.codesourcery.com/public/cxx-abi/abi.html#member-pointers
0e650017acdbbeb0c590e77bbea88c200ea1caefAnders Carlsson    // If we ever want to support other ABIs this needs to be abstracted.
0e650017acdbbeb0c590e77bbea88c200ea1caefAnders Carlsson
0e650017acdbbeb0c590e77bbea88c200ea1caefAnders Carlsson    QualType ETy = cast<MemberPointerType>(Ty).getPointeeType();
4a2251bb06a03166e34b509ca840b36f816c4081Eli Friedman    const llvm::Type *PtrDiffTy =
4a2251bb06a03166e34b509ca840b36f816c4081Eli Friedman        ConvertTypeRecursive(Context.getPointerDiffType());
0e650017acdbbeb0c590e77bbea88c200ea1caefAnders Carlsson    if (ETy->isFunctionType()) {
4a2251bb06a03166e34b509ca840b36f816c4081Eli Friedman      return llvm::StructType::get(TheModule.getContext(), PtrDiffTy, PtrDiffTy,
0e650017acdbbeb0c590e77bbea88c200ea1caefAnders Carlsson                                   NULL);
0e650017acdbbeb0c590e77bbea88c200ea1caefAnders Carlsson    } else
4a2251bb06a03166e34b509ca840b36f816c4081Eli Friedman      return PtrDiffTy;
0e650017acdbbeb0c590e77bbea88c200ea1caefAnders Carlsson  }
7532dc66648cfe7432c9fe66dec5225f0ab301c6Douglas Gregor
7532dc66648cfe7432c9fe66dec5225f0ab301c6Douglas Gregor  case Type::TemplateSpecialization:
7532dc66648cfe7432c9fe66dec5225f0ab301c6Douglas Gregor    assert(false && "Dependent types can't get here");
5f016e2cb5d11daeb237544de1c5d59f20fe1a6eReid Spencer  }
1eb4433ac451dc16f4133a88af2d002ac26c58efMike Stump
5f016e2cb5d11daeb237544de1c5d59f20fe1a6eReid Spencer  // FIXME: implement.
8c8f69ec1477424e11faef6b235505584d61e522Owen Anderson  return llvm::OpaqueType::get(getLLVMContext());
5f016e2cb5d11daeb237544de1c5d59f20fe1a6eReid Spencer}
5f016e2cb5d11daeb237544de1c5d59f20fe1a6eReid Spencer
fc3b8e9c1381d5e6ec361591d649c56a870ff971Chris Lattner/// ConvertTagDeclType - Lay out a tagged decl type like struct or union or
fc3b8e9c1381d5e6ec361591d649c56a870ff971Chris Lattner/// enum.
8fb1dd005f4cb530bca11d622362d39727294420Chris Lattnerconst llvm::Type *CodeGenTypes::ConvertTagDeclType(const TagDecl *TD) {
cad86653942d4e33c2674ea40e77d7fe59990130Fariborz Jahanian
cad86653942d4e33c2674ea40e77d7fe59990130Fariborz Jahanian  // FIXME. This may have to move to a better place.
cad86653942d4e33c2674ea40e77d7fe59990130Fariborz Jahanian  if (const CXXRecordDecl *RD = dyn_cast<CXXRecordDecl>(TD)) {
cad86653942d4e33c2674ea40e77d7fe59990130Fariborz Jahanian    for (CXXRecordDecl::base_class_const_iterator i = RD->bases_begin(),
cad86653942d4e33c2674ea40e77d7fe59990130Fariborz Jahanian         e = RD->bases_end(); i != e; ++i) {
cad86653942d4e33c2674ea40e77d7fe59990130Fariborz Jahanian      if (!i->isVirtual()) {
cad86653942d4e33c2674ea40e77d7fe59990130Fariborz Jahanian        const CXXRecordDecl *Base =
6217b80b7a1379b74cced1c076338262c3c980b3Ted Kremenek          cast<CXXRecordDecl>(i->getType()->getAs<RecordType>()->getDecl());
cad86653942d4e33c2674ea40e77d7fe59990130Fariborz Jahanian        ConvertTagDeclType(Base);
cad86653942d4e33c2674ea40e77d7fe59990130Fariborz Jahanian      }
cad86653942d4e33c2674ea40e77d7fe59990130Fariborz Jahanian    }
cad86653942d4e33c2674ea40e77d7fe59990130Fariborz Jahanian  }
1eb4433ac451dc16f4133a88af2d002ac26c58efMike Stump
efb6d0dc3eafbcf4f8cd053138bd1abed1dda8d4Daniel Dunbar  // TagDecl's are not necessarily unique, instead use the (clang)
efb6d0dc3eafbcf4f8cd053138bd1abed1dda8d4Daniel Dunbar  // type connected to the decl.
1eb4433ac451dc16f4133a88af2d002ac26c58efMike Stump  const Type *Key =
e607ed068334bacb8d7b093996b4671c6ca79e25Mike Stump    Context.getTagDeclType(TD).getTypePtr();
1eb4433ac451dc16f4133a88af2d002ac26c58efMike Stump  llvm::DenseMap<const Type*, llvm::PATypeHolder>::iterator TDTI =
efb6d0dc3eafbcf4f8cd053138bd1abed1dda8d4Daniel Dunbar    TagDeclTypes.find(Key);
1eb4433ac451dc16f4133a88af2d002ac26c58efMike Stump
5de00fcf7c923a14bb79bdbaabb2faeb5633d85aChris Lattner  // If we've already compiled this tag type, use the previous definition.
5de00fcf7c923a14bb79bdbaabb2faeb5633d85aChris Lattner  if (TDTI != TagDeclTypes.end())
fc3b8e9c1381d5e6ec361591d649c56a870ff971Chris Lattner    return TDTI->second;
1eb4433ac451dc16f4133a88af2d002ac26c58efMike Stump
5de00fcf7c923a14bb79bdbaabb2faeb5633d85aChris Lattner  // If this is still a forward definition, just define an opaque type to use
5de00fcf7c923a14bb79bdbaabb2faeb5633d85aChris Lattner  // for this tagged decl.
fc3b8e9c1381d5e6ec361591d649c56a870ff971Chris Lattner  if (!TD->isDefinition()) {
8c8f69ec1477424e11faef6b235505584d61e522Owen Anderson    llvm::Type *ResultType = llvm::OpaqueType::get(getLLVMContext());
efb6d0dc3eafbcf4f8cd053138bd1abed1dda8d4Daniel Dunbar    TagDeclTypes.insert(std::make_pair(Key, ResultType));
5de00fcf7c923a14bb79bdbaabb2faeb5633d85aChris Lattner    return ResultType;
5de00fcf7c923a14bb79bdbaabb2faeb5633d85aChris Lattner  }
1eb4433ac451dc16f4133a88af2d002ac26c58efMike Stump
5de00fcf7c923a14bb79bdbaabb2faeb5633d85aChris Lattner  // Okay, this is a definition of a type.  Compile the implementation now.
1eb4433ac451dc16f4133a88af2d002ac26c58efMike Stump
39ba4aeca296b1c9f04bde7d9d3cbbf129f1abd3Argyrios Kyrtzidis  if (TD->isEnum()) {
fc3b8e9c1381d5e6ec361591d649c56a870ff971Chris Lattner    // Don't bother storing enums in TagDeclTypes.
fce71b8ea53b6eb9c1630da24659289bc848f837Chris Lattner    return ConvertTypeRecursive(cast<EnumDecl>(TD)->getIntegerType());
5de00fcf7c923a14bb79bdbaabb2faeb5633d85aChris Lattner  }
1eb4433ac451dc16f4133a88af2d002ac26c58efMike Stump
5de00fcf7c923a14bb79bdbaabb2faeb5633d85aChris Lattner  // This decl could well be recursive.  In this case, insert an opaque
5de00fcf7c923a14bb79bdbaabb2faeb5633d85aChris Lattner  // definition of this type, which the recursive uses will get.  We will then
5de00fcf7c923a14bb79bdbaabb2faeb5633d85aChris Lattner  // refine this opaque version later.
5de00fcf7c923a14bb79bdbaabb2faeb5633d85aChris Lattner
5de00fcf7c923a14bb79bdbaabb2faeb5633d85aChris Lattner  // Create new OpaqueType now for later use in case this is a recursive
5de00fcf7c923a14bb79bdbaabb2faeb5633d85aChris Lattner  // type.  This will later be refined to the actual type.
8c8f69ec1477424e11faef6b235505584d61e522Owen Anderson  llvm::PATypeHolder ResultHolder = llvm::OpaqueType::get(getLLVMContext());
efb6d0dc3eafbcf4f8cd053138bd1abed1dda8d4Daniel Dunbar  TagDeclTypes.insert(std::make_pair(Key, ResultHolder));
1eb4433ac451dc16f4133a88af2d002ac26c58efMike Stump
5de00fcf7c923a14bb79bdbaabb2faeb5633d85aChris Lattner  const llvm::Type *ResultType;
5de00fcf7c923a14bb79bdbaabb2faeb5633d85aChris Lattner  const RecordDecl *RD = cast<const RecordDecl>(TD);
ae287239879386b9abf6da50a67bbb7fe81897f1Daniel Dunbar
696798febaf1f69020cdf7474b91e71736c5aa69Anders Carlsson  // Layout fields.
1eb4433ac451dc16f4133a88af2d002ac26c58efMike Stump  CGRecordLayout *Layout =
696798febaf1f69020cdf7474b91e71736c5aa69Anders Carlsson    CGRecordLayoutBuilder::ComputeLayout(*this, RD);
1eb4433ac451dc16f4133a88af2d002ac26c58efMike Stump
696798febaf1f69020cdf7474b91e71736c5aa69Anders Carlsson  CGRecordLayouts[Key] = Layout;
696798febaf1f69020cdf7474b91e71736c5aa69Anders Carlsson  ResultType = Layout->getLLVMType();
1eb4433ac451dc16f4133a88af2d002ac26c58efMike Stump
5de00fcf7c923a14bb79bdbaabb2faeb5633d85aChris Lattner  // Refine our Opaque type to ResultType.  This can invalidate ResultType, so
5de00fcf7c923a14bb79bdbaabb2faeb5633d85aChris Lattner  // make sure to read the result out of the holder.
5de00fcf7c923a14bb79bdbaabb2faeb5633d85aChris Lattner  cast<llvm::OpaqueType>(ResultHolder.get())
5de00fcf7c923a14bb79bdbaabb2faeb5633d85aChris Lattner    ->refineAbstractTypeTo(ResultType);
1eb4433ac451dc16f4133a88af2d002ac26c58efMike Stump
5de00fcf7c923a14bb79bdbaabb2faeb5633d85aChris Lattner  return ResultHolder.get();
1eb4433ac451dc16f4133a88af2d002ac26c58efMike Stump}
fc3b8e9c1381d5e6ec361591d649c56a870ff971Chris Lattner
b84a06e68ffd71da22e3c75b6e4bbdba37816413Devang Patel/// getLLVMFieldNo - Return llvm::StructType element number
b84a06e68ffd71da22e3c75b6e4bbdba37816413Devang Patel/// that corresponds to the field FD.
b84a06e68ffd71da22e3c75b6e4bbdba37816413Devang Patelunsigned CodeGenTypes::getLLVMFieldNo(const FieldDecl *FD) {
8330ceeebb3bfac31116b387b90ff2ce3cef85e4Anders Carlsson  assert(!FD->isBitField() && "Don't use getLLVMFieldNo on bit fields!");
1eb4433ac451dc16f4133a88af2d002ac26c58efMike Stump
ce5605ecf76d8cde6372138f830bb144d174ced9Chris Lattner  llvm::DenseMap<const FieldDecl*, unsigned>::iterator I = FieldInfo.find(FD);
21fdf416723e8c475812a0324a1f9fafc949c25fHartmut Kaiser  assert (I != FieldInfo.end()  && "Unable to find field info");
391d77a26382dddf25da73e29fc1fa5aaaea4c6fChris Lattner  return I->second;
391d77a26382dddf25da73e29fc1fa5aaaea4c6fChris Lattner}
391d77a26382dddf25da73e29fc1fa5aaaea4c6fChris Lattner
c4c429a1a5947ba9be64d3070741d98362872265Devang Patel/// addFieldInfo - Assign field number to field FD.
2c46ce8de96787aa8e040690a80896f1148c29b0Lauro Ramos Venanciovoid CodeGenTypes::addFieldInfo(const FieldDecl *FD, unsigned No) {
2c46ce8de96787aa8e040690a80896f1148c29b0Lauro Ramos Venancio  FieldInfo[FD] = No;
2c46ce8de96787aa8e040690a80896f1148c29b0Lauro Ramos Venancio}
2c46ce8de96787aa8e040690a80896f1148c29b0Lauro Ramos Venancio
2c46ce8de96787aa8e040690a80896f1148c29b0Lauro Ramos Venancio/// getBitFieldInfo - Return the BitFieldInfo  that corresponds to the field FD.
2c46ce8de96787aa8e040690a80896f1148c29b0Lauro Ramos VenancioCodeGenTypes::BitFieldInfo CodeGenTypes::getBitFieldInfo(const FieldDecl *FD) {
2c46ce8de96787aa8e040690a80896f1148c29b0Lauro Ramos Venancio  llvm::DenseMap<const FieldDecl *, BitFieldInfo>::iterator
2c46ce8de96787aa8e040690a80896f1148c29b0Lauro Ramos Venancio    I = BitFields.find(FD);
2c46ce8de96787aa8e040690a80896f1148c29b0Lauro Ramos Venancio  assert (I != BitFields.end()  && "Unable to find bitfield info");
2c46ce8de96787aa8e040690a80896f1148c29b0Lauro Ramos Venancio  return I->second;
2c46ce8de96787aa8e040690a80896f1148c29b0Lauro Ramos Venancio}
2c46ce8de96787aa8e040690a80896f1148c29b0Lauro Ramos Venancio
2c46ce8de96787aa8e040690a80896f1148c29b0Lauro Ramos Venancio/// addBitFieldInfo - Assign a start bit and a size to field FD.
8330ceeebb3bfac31116b387b90ff2ce3cef85e4Anders Carlssonvoid CodeGenTypes::addBitFieldInfo(const FieldDecl *FD, unsigned FieldNo,
8330ceeebb3bfac31116b387b90ff2ce3cef85e4Anders Carlsson                                   unsigned Start, unsigned Size) {
8330ceeebb3bfac31116b387b90ff2ce3cef85e4Anders Carlsson  BitFields.insert(std::make_pair(FD, BitFieldInfo(FieldNo, Start, Size)));
b84a06e68ffd71da22e3c75b6e4bbdba37816413Devang Patel}
b84a06e68ffd71da22e3c75b6e4bbdba37816413Devang Patel
88a981b47c7face1b1fdaa9074256245107b9ca9Devang Patel/// getCGRecordLayout - Return record layout info for the given llvm::Type.
ad3e7118c40711faf5f51f08d599dbd525d3408aAnders Carlssonconst CGRecordLayout &
af31913e48c96fddb45a0fd33f25617546502cbbChris LattnerCodeGenTypes::getCGRecordLayout(const TagDecl *TD) const {
1eb4433ac451dc16f4133a88af2d002ac26c58efMike Stump  const Type *Key =
e607ed068334bacb8d7b093996b4671c6ca79e25Mike Stump    Context.getTagDeclType(TD).getTypePtr();
3958b502404b4bd67f26fee398cb347abe89e6a8Jeffrey Yasskin  llvm::DenseMap<const Type*, CGRecordLayout *>::const_iterator I
efb6d0dc3eafbcf4f8cd053138bd1abed1dda8d4Daniel Dunbar    = CGRecordLayouts.find(Key);
1eb4433ac451dc16f4133a88af2d002ac26c58efMike Stump  assert (I != CGRecordLayouts.end()
b84a06e68ffd71da22e3c75b6e4bbdba37816413Devang Patel          && "Unable to find record layout information for type");
ad3e7118c40711faf5f51f08d599dbd525d3408aAnders Carlsson  return *I->second;
b84a06e68ffd71da22e3c75b6e4bbdba37816413Devang Patel}