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llvm-project/clang/lib/Frontend/InitPreprocessor.cpp
Erich Keane 0a6b5b653e PTH-- Remove feature entirely- 
When debugging a boost build with a modified
version of Clang, I discovered that the PTH implementation
stores TokenKind in 8 bits. However, we currently have 368
TokenKinds.

The result is that the value gets truncated and the wrong token
gets picked up when including PTH files. It seems that this will
go wrong every time someone uses a token that uses the 9th bit.

Upon asking on IRC, it was brought up that this was a highly
experimental features that was considered a failure. I discovered
via googling that BoostBuild (mostly Boost.Math) is the only user of
this
feature, using the CC1 flag directly. I believe that this can be
transferred over to normal PCH with minimal effort:
https://github.com/boostorg/build/issues/367

Based on advice on IRC and research showing that this is a nearly
completely unused feature, this patch removes it entirely.

Note: I considered leaving the build-flags in place and making them
emit an error/warning, however since I've basically identified and
warned the only user, it seemed better to just remove them.

Differential Revision: https://reviews.llvm.org/D54547

Change-Id: If32744275ef1f585357bd6c1c813d96973c4d8d9
llvm-svn: 348266
2018-12-04 14:34:09 +00:00

1176 lines
49 KiB
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//===--- InitPreprocessor.cpp - PP initialization code. ---------*- C++ -*-===//
//
// The LLVM Compiler Infrastructure
//
// This file is distributed under the University of Illinois Open Source
// License. See LICENSE.TXT for details.
//
//===----------------------------------------------------------------------===//
//
// This file implements the clang::InitializePreprocessor function.
//
//===----------------------------------------------------------------------===//
#include "clang/Basic/FileManager.h"
#include "clang/Basic/MacroBuilder.h"
#include "clang/Basic/SourceManager.h"
#include "clang/Basic/SyncScope.h"
#include "clang/Basic/TargetInfo.h"
#include "clang/Basic/Version.h"
#include "clang/Frontend/FrontendDiagnostic.h"
#include "clang/Frontend/FrontendOptions.h"
#include "clang/Frontend/Utils.h"
#include "clang/Lex/HeaderSearch.h"
#include "clang/Lex/Preprocessor.h"
#include "clang/Lex/PreprocessorOptions.h"
#include "clang/Serialization/ASTReader.h"
#include "llvm/ADT/APFloat.h"
using namespace clang;
static bool MacroBodyEndsInBackslash(StringRef MacroBody) {
while (!MacroBody.empty() && isWhitespace(MacroBody.back()))
MacroBody = MacroBody.drop_back();
return !MacroBody.empty() && MacroBody.back() == '\\';
}
// Append a #define line to Buf for Macro. Macro should be of the form XXX,
// in which case we emit "#define XXX 1" or "XXX=Y z W" in which case we emit
// "#define XXX Y z W". To get a #define with no value, use "XXX=".
static void DefineBuiltinMacro(MacroBuilder &Builder, StringRef Macro,
DiagnosticsEngine &Diags) {
std::pair<StringRef, StringRef> MacroPair = Macro.split('=');
StringRef MacroName = MacroPair.first;
StringRef MacroBody = MacroPair.second;
if (MacroName.size() != Macro.size()) {
// Per GCC -D semantics, the macro ends at \n if it exists.
StringRef::size_type End = MacroBody.find_first_of("\n\r");
if (End != StringRef::npos)
Diags.Report(diag::warn_fe_macro_contains_embedded_newline)
<< MacroName;
MacroBody = MacroBody.substr(0, End);
// We handle macro bodies which end in a backslash by appending an extra
// backslash+newline. This makes sure we don't accidentally treat the
// backslash as a line continuation marker.
if (MacroBodyEndsInBackslash(MacroBody))
Builder.defineMacro(MacroName, Twine(MacroBody) + "\\\n");
else
Builder.defineMacro(MacroName, MacroBody);
} else {
// Push "macroname 1".
Builder.defineMacro(Macro);
}
}
/// AddImplicitInclude - Add an implicit \#include of the specified file to the
/// predefines buffer.
/// As these includes are generated by -include arguments the header search
/// logic is going to search relatively to the current working directory.
static void AddImplicitInclude(MacroBuilder &Builder, StringRef File) {
Builder.append(Twine("#include \"") + File + "\"");
}
static void AddImplicitIncludeMacros(MacroBuilder &Builder, StringRef File) {
Builder.append(Twine("#__include_macros \"") + File + "\"");
// Marker token to stop the __include_macros fetch loop.
Builder.append("##"); // ##?
}
/// Add an implicit \#include using the original file used to generate
/// a PCH file.
static void AddImplicitIncludePCH(MacroBuilder &Builder, Preprocessor &PP,
const PCHContainerReader &PCHContainerRdr,
StringRef ImplicitIncludePCH) {
std::string OriginalFile =
ASTReader::getOriginalSourceFile(ImplicitIncludePCH, PP.getFileManager(),
PCHContainerRdr, PP.getDiagnostics());
if (OriginalFile.empty())
return;
AddImplicitInclude(Builder, OriginalFile);
}
/// PickFP - This is used to pick a value based on the FP semantics of the
/// specified FP model.
template <typename T>
static T PickFP(const llvm::fltSemantics *Sem, T IEEEHalfVal, T IEEESingleVal,
T IEEEDoubleVal, T X87DoubleExtendedVal, T PPCDoubleDoubleVal,
T IEEEQuadVal) {
if (Sem == (const llvm::fltSemantics*)&llvm::APFloat::IEEEhalf())
return IEEEHalfVal;
if (Sem == (const llvm::fltSemantics*)&llvm::APFloat::IEEEsingle())
return IEEESingleVal;
if (Sem == (const llvm::fltSemantics*)&llvm::APFloat::IEEEdouble())
return IEEEDoubleVal;
if (Sem == (const llvm::fltSemantics*)&llvm::APFloat::x87DoubleExtended())
return X87DoubleExtendedVal;
if (Sem == (const llvm::fltSemantics*)&llvm::APFloat::PPCDoubleDouble())
return PPCDoubleDoubleVal;
assert(Sem == (const llvm::fltSemantics*)&llvm::APFloat::IEEEquad());
return IEEEQuadVal;
}
static void DefineFloatMacros(MacroBuilder &Builder, StringRef Prefix,
const llvm::fltSemantics *Sem, StringRef Ext) {
const char *DenormMin, *Epsilon, *Max, *Min;
DenormMin = PickFP(Sem, "5.9604644775390625e-8", "1.40129846e-45",
"4.9406564584124654e-324", "3.64519953188247460253e-4951",
"4.94065645841246544176568792868221e-324",
"6.47517511943802511092443895822764655e-4966");
int Digits = PickFP(Sem, 3, 6, 15, 18, 31, 33);
int DecimalDigits = PickFP(Sem, 5, 9, 17, 21, 33, 36);
Epsilon = PickFP(Sem, "9.765625e-4", "1.19209290e-7",
"2.2204460492503131e-16", "1.08420217248550443401e-19",
"4.94065645841246544176568792868221e-324",
"1.92592994438723585305597794258492732e-34");
int MantissaDigits = PickFP(Sem, 11, 24, 53, 64, 106, 113);
int Min10Exp = PickFP(Sem, -13, -37, -307, -4931, -291, -4931);
int Max10Exp = PickFP(Sem, 4, 38, 308, 4932, 308, 4932);
int MinExp = PickFP(Sem, -14, -125, -1021, -16381, -968, -16381);
int MaxExp = PickFP(Sem, 15, 128, 1024, 16384, 1024, 16384);
Min = PickFP(Sem, "6.103515625e-5", "1.17549435e-38", "2.2250738585072014e-308",
"3.36210314311209350626e-4932",
"2.00416836000897277799610805135016e-292",
"3.36210314311209350626267781732175260e-4932");
Max = PickFP(Sem, "6.5504e+4", "3.40282347e+38", "1.7976931348623157e+308",
"1.18973149535723176502e+4932",
"1.79769313486231580793728971405301e+308",
"1.18973149535723176508575932662800702e+4932");
SmallString<32> DefPrefix;
DefPrefix = "__";
DefPrefix += Prefix;
DefPrefix += "_";
Builder.defineMacro(DefPrefix + "DENORM_MIN__", Twine(DenormMin)+Ext);
Builder.defineMacro(DefPrefix + "HAS_DENORM__");
Builder.defineMacro(DefPrefix + "DIG__", Twine(Digits));
Builder.defineMacro(DefPrefix + "DECIMAL_DIG__", Twine(DecimalDigits));
Builder.defineMacro(DefPrefix + "EPSILON__", Twine(Epsilon)+Ext);
Builder.defineMacro(DefPrefix + "HAS_INFINITY__");
Builder.defineMacro(DefPrefix + "HAS_QUIET_NAN__");
Builder.defineMacro(DefPrefix + "MANT_DIG__", Twine(MantissaDigits));
Builder.defineMacro(DefPrefix + "MAX_10_EXP__", Twine(Max10Exp));
Builder.defineMacro(DefPrefix + "MAX_EXP__", Twine(MaxExp));
Builder.defineMacro(DefPrefix + "MAX__", Twine(Max)+Ext);
Builder.defineMacro(DefPrefix + "MIN_10_EXP__","("+Twine(Min10Exp)+")");
Builder.defineMacro(DefPrefix + "MIN_EXP__", "("+Twine(MinExp)+")");
Builder.defineMacro(DefPrefix + "MIN__", Twine(Min)+Ext);
}
/// DefineTypeSize - Emit a macro to the predefines buffer that declares a macro
/// named MacroName with the max value for a type with width 'TypeWidth' a
/// signedness of 'isSigned' and with a value suffix of 'ValSuffix' (e.g. LL).
static void DefineTypeSize(const Twine &MacroName, unsigned TypeWidth,
StringRef ValSuffix, bool isSigned,
MacroBuilder &Builder) {
llvm::APInt MaxVal = isSigned ? llvm::APInt::getSignedMaxValue(TypeWidth)
: llvm::APInt::getMaxValue(TypeWidth);
Builder.defineMacro(MacroName, MaxVal.toString(10, isSigned) + ValSuffix);
}
/// DefineTypeSize - An overloaded helper that uses TargetInfo to determine
/// the width, suffix, and signedness of the given type
static void DefineTypeSize(const Twine &MacroName, TargetInfo::IntType Ty,
const TargetInfo &TI, MacroBuilder &Builder) {
DefineTypeSize(MacroName, TI.getTypeWidth(Ty), TI.getTypeConstantSuffix(Ty),
TI.isTypeSigned(Ty), Builder);
}
static void DefineFmt(const Twine &Prefix, TargetInfo::IntType Ty,
const TargetInfo &TI, MacroBuilder &Builder) {
bool IsSigned = TI.isTypeSigned(Ty);
StringRef FmtModifier = TI.getTypeFormatModifier(Ty);
for (const char *Fmt = IsSigned ? "di" : "ouxX"; *Fmt; ++Fmt) {
Builder.defineMacro(Prefix + "_FMT" + Twine(*Fmt) + "__",
Twine("\"") + FmtModifier + Twine(*Fmt) + "\"");
}
}
static void DefineType(const Twine &MacroName, TargetInfo::IntType Ty,
MacroBuilder &Builder) {
Builder.defineMacro(MacroName, TargetInfo::getTypeName(Ty));
}
static void DefineTypeWidth(StringRef MacroName, TargetInfo::IntType Ty,
const TargetInfo &TI, MacroBuilder &Builder) {
Builder.defineMacro(MacroName, Twine(TI.getTypeWidth(Ty)));
}
static void DefineTypeSizeof(StringRef MacroName, unsigned BitWidth,
const TargetInfo &TI, MacroBuilder &Builder) {
Builder.defineMacro(MacroName,
Twine(BitWidth / TI.getCharWidth()));
}
static void DefineExactWidthIntType(TargetInfo::IntType Ty,
const TargetInfo &TI,
MacroBuilder &Builder) {
int TypeWidth = TI.getTypeWidth(Ty);
bool IsSigned = TI.isTypeSigned(Ty);
// Use the target specified int64 type, when appropriate, so that [u]int64_t
// ends up being defined in terms of the correct type.
if (TypeWidth == 64)
Ty = IsSigned ? TI.getInt64Type() : TI.getUInt64Type();
const char *Prefix = IsSigned ? "__INT" : "__UINT";
DefineType(Prefix + Twine(TypeWidth) + "_TYPE__", Ty, Builder);
DefineFmt(Prefix + Twine(TypeWidth), Ty, TI, Builder);
StringRef ConstSuffix(TI.getTypeConstantSuffix(Ty));
Builder.defineMacro(Prefix + Twine(TypeWidth) + "_C_SUFFIX__", ConstSuffix);
}
static void DefineExactWidthIntTypeSize(TargetInfo::IntType Ty,
const TargetInfo &TI,
MacroBuilder &Builder) {
int TypeWidth = TI.getTypeWidth(Ty);
bool IsSigned = TI.isTypeSigned(Ty);
// Use the target specified int64 type, when appropriate, so that [u]int64_t
// ends up being defined in terms of the correct type.
if (TypeWidth == 64)
Ty = IsSigned ? TI.getInt64Type() : TI.getUInt64Type();
const char *Prefix = IsSigned ? "__INT" : "__UINT";
DefineTypeSize(Prefix + Twine(TypeWidth) + "_MAX__", Ty, TI, Builder);
}
static void DefineLeastWidthIntType(unsigned TypeWidth, bool IsSigned,
const TargetInfo &TI,
MacroBuilder &Builder) {
TargetInfo::IntType Ty = TI.getLeastIntTypeByWidth(TypeWidth, IsSigned);
if (Ty == TargetInfo::NoInt)
return;
const char *Prefix = IsSigned ? "__INT_LEAST" : "__UINT_LEAST";
DefineType(Prefix + Twine(TypeWidth) + "_TYPE__", Ty, Builder);
DefineTypeSize(Prefix + Twine(TypeWidth) + "_MAX__", Ty, TI, Builder);
DefineFmt(Prefix + Twine(TypeWidth), Ty, TI, Builder);
}
static void DefineFastIntType(unsigned TypeWidth, bool IsSigned,
const TargetInfo &TI, MacroBuilder &Builder) {
// stdint.h currently defines the fast int types as equivalent to the least
// types.
TargetInfo::IntType Ty = TI.getLeastIntTypeByWidth(TypeWidth, IsSigned);
if (Ty == TargetInfo::NoInt)
return;
const char *Prefix = IsSigned ? "__INT_FAST" : "__UINT_FAST";
DefineType(Prefix + Twine(TypeWidth) + "_TYPE__", Ty, Builder);
DefineTypeSize(Prefix + Twine(TypeWidth) + "_MAX__", Ty, TI, Builder);
DefineFmt(Prefix + Twine(TypeWidth), Ty, TI, Builder);
}
/// Get the value the ATOMIC_*_LOCK_FREE macro should have for a type with
/// the specified properties.
static const char *getLockFreeValue(unsigned TypeWidth, unsigned TypeAlign,
unsigned InlineWidth) {
// Fully-aligned, power-of-2 sizes no larger than the inline
// width will be inlined as lock-free operations.
if (TypeWidth == TypeAlign && (TypeWidth & (TypeWidth - 1)) == 0 &&
TypeWidth <= InlineWidth)
return "2"; // "always lock free"
// We cannot be certain what operations the lib calls might be
// able to implement as lock-free on future processors.
return "1"; // "sometimes lock free"
}
/// Add definitions required for a smooth interaction between
/// Objective-C++ automated reference counting and libstdc++ (4.2).
static void AddObjCXXARCLibstdcxxDefines(const LangOptions &LangOpts,
MacroBuilder &Builder) {
Builder.defineMacro("_GLIBCXX_PREDEFINED_OBJC_ARC_IS_SCALAR");
std::string Result;
{
// Provide specializations for the __is_scalar type trait so that
// lifetime-qualified objects are not considered "scalar" types, which
// libstdc++ uses as an indicator of the presence of trivial copy, assign,
// default-construct, and destruct semantics (none of which hold for
// lifetime-qualified objects in ARC).
llvm::raw_string_ostream Out(Result);
Out << "namespace std {\n"
<< "\n"
<< "struct __true_type;\n"
<< "struct __false_type;\n"
<< "\n";
Out << "template<typename _Tp> struct __is_scalar;\n"
<< "\n";
if (LangOpts.ObjCAutoRefCount) {
Out << "template<typename _Tp>\n"
<< "struct __is_scalar<__attribute__((objc_ownership(strong))) _Tp> {\n"
<< " enum { __value = 0 };\n"
<< " typedef __false_type __type;\n"
<< "};\n"
<< "\n";
}
if (LangOpts.ObjCWeak) {
Out << "template<typename _Tp>\n"
<< "struct __is_scalar<__attribute__((objc_ownership(weak))) _Tp> {\n"
<< " enum { __value = 0 };\n"
<< " typedef __false_type __type;\n"
<< "};\n"
<< "\n";
}
if (LangOpts.ObjCAutoRefCount) {
Out << "template<typename _Tp>\n"
<< "struct __is_scalar<__attribute__((objc_ownership(autoreleasing)))"
<< " _Tp> {\n"
<< " enum { __value = 0 };\n"
<< " typedef __false_type __type;\n"
<< "};\n"
<< "\n";
}
Out << "}\n";
}
Builder.append(Result);
}
static void InitializeStandardPredefinedMacros(const TargetInfo &TI,
const LangOptions &LangOpts,
const FrontendOptions &FEOpts,
MacroBuilder &Builder) {
if (!LangOpts.MSVCCompat && !LangOpts.TraditionalCPP)
Builder.defineMacro("__STDC__");
if (LangOpts.Freestanding)
Builder.defineMacro("__STDC_HOSTED__", "0");
else
Builder.defineMacro("__STDC_HOSTED__");
if (!LangOpts.CPlusPlus) {
if (LangOpts.C17)
Builder.defineMacro("__STDC_VERSION__", "201710L");
else if (LangOpts.C11)
Builder.defineMacro("__STDC_VERSION__", "201112L");
else if (LangOpts.C99)
Builder.defineMacro("__STDC_VERSION__", "199901L");
else if (!LangOpts.GNUMode && LangOpts.Digraphs)
Builder.defineMacro("__STDC_VERSION__", "199409L");
} else {
// FIXME: Use correct value for C++20.
if (LangOpts.CPlusPlus2a)
Builder.defineMacro("__cplusplus", "201707L");
// C++17 [cpp.predefined]p1:
// The name __cplusplus is defined to the value 201703L when compiling a
// C++ translation unit.
else if (LangOpts.CPlusPlus17)
Builder.defineMacro("__cplusplus", "201703L");
// C++1y [cpp.predefined]p1:
// The name __cplusplus is defined to the value 201402L when compiling a
// C++ translation unit.
else if (LangOpts.CPlusPlus14)
Builder.defineMacro("__cplusplus", "201402L");
// C++11 [cpp.predefined]p1:
// The name __cplusplus is defined to the value 201103L when compiling a
// C++ translation unit.
else if (LangOpts.CPlusPlus11)
Builder.defineMacro("__cplusplus", "201103L");
// C++03 [cpp.predefined]p1:
// The name __cplusplus is defined to the value 199711L when compiling a
// C++ translation unit.
else
Builder.defineMacro("__cplusplus", "199711L");
// C++1z [cpp.predefined]p1:
// An integer literal of type std::size_t whose value is the alignment
// guaranteed by a call to operator new(std::size_t)
//
// We provide this in all language modes, since it seems generally useful.
Builder.defineMacro("__STDCPP_DEFAULT_NEW_ALIGNMENT__",
Twine(TI.getNewAlign() / TI.getCharWidth()) +
TI.getTypeConstantSuffix(TI.getSizeType()));
}
// In C11 these are environment macros. In C++11 they are only defined
// as part of <cuchar>. To prevent breakage when mixing C and C++
// code, define these macros unconditionally. We can define them
// unconditionally, as Clang always uses UTF-16 and UTF-32 for 16-bit
// and 32-bit character literals.
Builder.defineMacro("__STDC_UTF_16__", "1");
Builder.defineMacro("__STDC_UTF_32__", "1");
if (LangOpts.ObjC)
Builder.defineMacro("__OBJC__");
// OpenCL v1.0/1.1 s6.9, v1.2/2.0 s6.10: Preprocessor Directives and Macros.
if (LangOpts.OpenCL) {
if (LangOpts.CPlusPlus) {
if (LangOpts.OpenCLCPlusPlusVersion == 100)
Builder.defineMacro("__OPENCL_CPP_VERSION__", "100");
else
llvm_unreachable("Unsupported OpenCL C++ version");
Builder.defineMacro("__CL_CPP_VERSION_1_0__", "100");
} else {
// OpenCL v1.0 and v1.1 do not have a predefined macro to indicate the
// language standard with which the program is compiled. __OPENCL_VERSION__
// is for the OpenCL version supported by the OpenCL device, which is not
// necessarily the language standard with which the program is compiled.
// A shared OpenCL header file requires a macro to indicate the language
// standard. As a workaround, __OPENCL_C_VERSION__ is defined for
// OpenCL v1.0 and v1.1.
switch (LangOpts.OpenCLVersion) {
case 100:
Builder.defineMacro("__OPENCL_C_VERSION__", "100");
break;
case 110:
Builder.defineMacro("__OPENCL_C_VERSION__", "110");
break;
case 120:
Builder.defineMacro("__OPENCL_C_VERSION__", "120");
break;
case 200:
Builder.defineMacro("__OPENCL_C_VERSION__", "200");
break;
default:
llvm_unreachable("Unsupported OpenCL version");
}
Builder.defineMacro("CL_VERSION_1_0", "100");
Builder.defineMacro("CL_VERSION_1_1", "110");
Builder.defineMacro("CL_VERSION_1_2", "120");
Builder.defineMacro("CL_VERSION_2_0", "200");
if (TI.isLittleEndian())
Builder.defineMacro("__ENDIAN_LITTLE__");
if (LangOpts.FastRelaxedMath)
Builder.defineMacro("__FAST_RELAXED_MATH__");
}
}
// Not "standard" per se, but available even with the -undef flag.
if (LangOpts.AsmPreprocessor)
Builder.defineMacro("__ASSEMBLER__");
if (LangOpts.CUDA && !LangOpts.HIP)
Builder.defineMacro("__CUDA__");
if (LangOpts.HIP) {
Builder.defineMacro("__HIP__");
Builder.defineMacro("__HIPCC__");
if (LangOpts.CUDAIsDevice)
Builder.defineMacro("__HIP_DEVICE_COMPILE__");
}
}
/// Initialize the predefined C++ language feature test macros defined in
/// ISO/IEC JTC1/SC22/WG21 (C++) SD-6: "SG10 Feature Test Recommendations".
static void InitializeCPlusPlusFeatureTestMacros(const LangOptions &LangOpts,
MacroBuilder &Builder) {
// C++98 features.
if (LangOpts.RTTI)
Builder.defineMacro("__cpp_rtti", "199711L");
if (LangOpts.CXXExceptions)
Builder.defineMacro("__cpp_exceptions", "199711L");
// C++11 features.
if (LangOpts.CPlusPlus11) {
Builder.defineMacro("__cpp_unicode_characters", "200704L");
Builder.defineMacro("__cpp_raw_strings", "200710L");
Builder.defineMacro("__cpp_unicode_literals", "200710L");
Builder.defineMacro("__cpp_user_defined_literals", "200809L");
Builder.defineMacro("__cpp_lambdas", "200907L");
Builder.defineMacro("__cpp_constexpr",
LangOpts.CPlusPlus17 ? "201603L" :
LangOpts.CPlusPlus14 ? "201304L" : "200704");
Builder.defineMacro("__cpp_range_based_for",
LangOpts.CPlusPlus17 ? "201603L" : "200907");
Builder.defineMacro("__cpp_static_assert",
LangOpts.CPlusPlus17 ? "201411L" : "200410");
Builder.defineMacro("__cpp_decltype", "200707L");
Builder.defineMacro("__cpp_attributes", "200809L");
Builder.defineMacro("__cpp_rvalue_references", "200610L");
Builder.defineMacro("__cpp_variadic_templates", "200704L");
Builder.defineMacro("__cpp_initializer_lists", "200806L");
Builder.defineMacro("__cpp_delegating_constructors", "200604L");
Builder.defineMacro("__cpp_nsdmi", "200809L");
Builder.defineMacro("__cpp_inheriting_constructors", "201511L");
Builder.defineMacro("__cpp_ref_qualifiers", "200710L");
Builder.defineMacro("__cpp_alias_templates", "200704L");
}
if (LangOpts.ThreadsafeStatics)
Builder.defineMacro("__cpp_threadsafe_static_init", "200806L");
// C++14 features.
if (LangOpts.CPlusPlus14) {
Builder.defineMacro("__cpp_binary_literals", "201304L");
Builder.defineMacro("__cpp_digit_separators", "201309L");
Builder.defineMacro("__cpp_init_captures", "201304L");
Builder.defineMacro("__cpp_generic_lambdas", "201304L");
Builder.defineMacro("__cpp_decltype_auto", "201304L");
Builder.defineMacro("__cpp_return_type_deduction", "201304L");
Builder.defineMacro("__cpp_aggregate_nsdmi", "201304L");
Builder.defineMacro("__cpp_variable_templates", "201304L");
}
if (LangOpts.SizedDeallocation)
Builder.defineMacro("__cpp_sized_deallocation", "201309L");
// C++17 features.
if (LangOpts.CPlusPlus17) {
Builder.defineMacro("__cpp_hex_float", "201603L");
Builder.defineMacro("__cpp_inline_variables", "201606L");
Builder.defineMacro("__cpp_noexcept_function_type", "201510L");
Builder.defineMacro("__cpp_capture_star_this", "201603L");
Builder.defineMacro("__cpp_if_constexpr", "201606L");
Builder.defineMacro("__cpp_deduction_guides", "201703L");
Builder.defineMacro("__cpp_template_auto", "201606L"); // (old name)
Builder.defineMacro("__cpp_namespace_attributes", "201411L");
Builder.defineMacro("__cpp_enumerator_attributes", "201411L");
Builder.defineMacro("__cpp_nested_namespace_definitions", "201411L");
Builder.defineMacro("__cpp_variadic_using", "201611L");
Builder.defineMacro("__cpp_aggregate_bases", "201603L");
Builder.defineMacro("__cpp_structured_bindings", "201606L");
Builder.defineMacro("__cpp_nontype_template_args", "201411L");
Builder.defineMacro("__cpp_fold_expressions", "201603L");
Builder.defineMacro("__cpp_guaranteed_copy_elision", "201606L");
Builder.defineMacro("__cpp_nontype_template_parameter_auto", "201606L");
}
if (LangOpts.AlignedAllocation && !LangOpts.AlignedAllocationUnavailable)
Builder.defineMacro("__cpp_aligned_new", "201606L");
if (LangOpts.RelaxedTemplateTemplateArgs)
Builder.defineMacro("__cpp_template_template_args", "201611L");
// C++20 features.
if (LangOpts.Char8)
Builder.defineMacro("__cpp_char8_t", "201811L");
// TS features.
if (LangOpts.ConceptsTS)
Builder.defineMacro("__cpp_experimental_concepts", "1L");
if (LangOpts.CoroutinesTS)
Builder.defineMacro("__cpp_coroutines", "201703L");
}
static void InitializePredefinedMacros(const TargetInfo &TI,
const LangOptions &LangOpts,
const FrontendOptions &FEOpts,
MacroBuilder &Builder) {
// Compiler version introspection macros.
Builder.defineMacro("__llvm__"); // LLVM Backend
Builder.defineMacro("__clang__"); // Clang Frontend
#define TOSTR2(X) #X
#define TOSTR(X) TOSTR2(X)
Builder.defineMacro("__clang_major__", TOSTR(CLANG_VERSION_MAJOR));
Builder.defineMacro("__clang_minor__", TOSTR(CLANG_VERSION_MINOR));
Builder.defineMacro("__clang_patchlevel__", TOSTR(CLANG_VERSION_PATCHLEVEL));
#undef TOSTR
#undef TOSTR2
Builder.defineMacro("__clang_version__",
"\"" CLANG_VERSION_STRING " "
+ getClangFullRepositoryVersion() + "\"");
if (!LangOpts.MSVCCompat) {
// Currently claim to be compatible with GCC 4.2.1-5621, but only if we're
// not compiling for MSVC compatibility
Builder.defineMacro("__GNUC_MINOR__", "2");
Builder.defineMacro("__GNUC_PATCHLEVEL__", "1");
Builder.defineMacro("__GNUC__", "4");
Builder.defineMacro("__GXX_ABI_VERSION", "1002");
}
// Define macros for the C11 / C++11 memory orderings
Builder.defineMacro("__ATOMIC_RELAXED", "0");
Builder.defineMacro("__ATOMIC_CONSUME", "1");
Builder.defineMacro("__ATOMIC_ACQUIRE", "2");
Builder.defineMacro("__ATOMIC_RELEASE", "3");
Builder.defineMacro("__ATOMIC_ACQ_REL", "4");
Builder.defineMacro("__ATOMIC_SEQ_CST", "5");
// Define macros for the OpenCL memory scope.
// The values should match AtomicScopeOpenCLModel::ID enum.
static_assert(
static_cast<unsigned>(AtomicScopeOpenCLModel::WorkGroup) == 1 &&
static_cast<unsigned>(AtomicScopeOpenCLModel::Device) == 2 &&
static_cast<unsigned>(AtomicScopeOpenCLModel::AllSVMDevices) == 3 &&
static_cast<unsigned>(AtomicScopeOpenCLModel::SubGroup) == 4,
"Invalid OpenCL memory scope enum definition");
Builder.defineMacro("__OPENCL_MEMORY_SCOPE_WORK_ITEM", "0");
Builder.defineMacro("__OPENCL_MEMORY_SCOPE_WORK_GROUP", "1");
Builder.defineMacro("__OPENCL_MEMORY_SCOPE_DEVICE", "2");
Builder.defineMacro("__OPENCL_MEMORY_SCOPE_ALL_SVM_DEVICES", "3");
Builder.defineMacro("__OPENCL_MEMORY_SCOPE_SUB_GROUP", "4");
// Support for #pragma redefine_extname (Sun compatibility)
Builder.defineMacro("__PRAGMA_REDEFINE_EXTNAME", "1");
// As sad as it is, enough software depends on the __VERSION__ for version
// checks that it is necessary to report 4.2.1 (the base GCC version we claim
// compatibility with) first.
Builder.defineMacro("__VERSION__", "\"4.2.1 Compatible " +
Twine(getClangFullCPPVersion()) + "\"");
// Initialize language-specific preprocessor defines.
// Standard conforming mode?
if (!LangOpts.GNUMode && !LangOpts.MSVCCompat)
Builder.defineMacro("__STRICT_ANSI__");
if (!LangOpts.MSVCCompat && LangOpts.CPlusPlus11)
Builder.defineMacro("__GXX_EXPERIMENTAL_CXX0X__");
if (LangOpts.ObjC) {
if (LangOpts.ObjCRuntime.isNonFragile()) {
Builder.defineMacro("__OBJC2__");
if (LangOpts.ObjCExceptions)
Builder.defineMacro("OBJC_ZEROCOST_EXCEPTIONS");
}
if (LangOpts.getGC() != LangOptions::NonGC)
Builder.defineMacro("__OBJC_GC__");
if (LangOpts.ObjCRuntime.isNeXTFamily())
Builder.defineMacro("__NEXT_RUNTIME__");
if (LangOpts.ObjCRuntime.getKind() == ObjCRuntime::GNUstep) {
auto version = LangOpts.ObjCRuntime.getVersion();
std::string versionString = "1";
// Don't rely on the tuple argument, because we can be asked to target
// later ABIs than we actually support, so clamp these values to those
// currently supported
if (version >= VersionTuple(2, 0))
Builder.defineMacro("__OBJC_GNUSTEP_RUNTIME_ABI__", "20");
else
Builder.defineMacro("__OBJC_GNUSTEP_RUNTIME_ABI__",
"1" + Twine(std::min(8U, version.getMinor().getValueOr(0))));
}
if (LangOpts.ObjCRuntime.getKind() == ObjCRuntime::ObjFW) {
VersionTuple tuple = LangOpts.ObjCRuntime.getVersion();
unsigned minor = 0;
if (tuple.getMinor().hasValue())
minor = tuple.getMinor().getValue();
unsigned subminor = 0;
if (tuple.getSubminor().hasValue())
subminor = tuple.getSubminor().getValue();
Builder.defineMacro("__OBJFW_RUNTIME_ABI__",
Twine(tuple.getMajor() * 10000 + minor * 100 +
subminor));
}
Builder.defineMacro("IBOutlet", "__attribute__((iboutlet))");
Builder.defineMacro("IBOutletCollection(ClassName)",
"__attribute__((iboutletcollection(ClassName)))");
Builder.defineMacro("IBAction", "void)__attribute__((ibaction)");
Builder.defineMacro("IBInspectable", "");
Builder.defineMacro("IB_DESIGNABLE", "");
}
// Define a macro that describes the Objective-C boolean type even for C
// and C++ since BOOL can be used from non Objective-C code.
Builder.defineMacro("__OBJC_BOOL_IS_BOOL",
Twine(TI.useSignedCharForObjCBool() ? "0" : "1"));
if (LangOpts.CPlusPlus)
InitializeCPlusPlusFeatureTestMacros(LangOpts, Builder);
// darwin_constant_cfstrings controls this. This is also dependent
// on other things like the runtime I believe. This is set even for C code.
if (!LangOpts.NoConstantCFStrings)
Builder.defineMacro("__CONSTANT_CFSTRINGS__");
if (LangOpts.ObjC)
Builder.defineMacro("OBJC_NEW_PROPERTIES");
if (LangOpts.PascalStrings)
Builder.defineMacro("__PASCAL_STRINGS__");
if (LangOpts.Blocks) {
Builder.defineMacro("__block", "__attribute__((__blocks__(byref)))");
Builder.defineMacro("__BLOCKS__");
}
if (!LangOpts.MSVCCompat && LangOpts.Exceptions)
Builder.defineMacro("__EXCEPTIONS");
if (!LangOpts.MSVCCompat && LangOpts.RTTI)
Builder.defineMacro("__GXX_RTTI");
if (LangOpts.SjLjExceptions)
Builder.defineMacro("__USING_SJLJ_EXCEPTIONS__");
else if (LangOpts.SEHExceptions)
Builder.defineMacro("__SEH__");
else if (LangOpts.DWARFExceptions &&
(TI.getTriple().isThumb() || TI.getTriple().isARM()))
Builder.defineMacro("__ARM_DWARF_EH__");
if (LangOpts.Deprecated)
Builder.defineMacro("__DEPRECATED");
if (!LangOpts.MSVCCompat && LangOpts.CPlusPlus) {
Builder.defineMacro("__GNUG__", "4");
Builder.defineMacro("__GXX_WEAK__");
Builder.defineMacro("__private_extern__", "extern");
}
if (LangOpts.MicrosoftExt) {
if (LangOpts.WChar) {
// wchar_t supported as a keyword.
Builder.defineMacro("_WCHAR_T_DEFINED");
Builder.defineMacro("_NATIVE_WCHAR_T_DEFINED");
}
}
if (LangOpts.Optimize)
Builder.defineMacro("__OPTIMIZE__");
if (LangOpts.OptimizeSize)
Builder.defineMacro("__OPTIMIZE_SIZE__");
if (LangOpts.FastMath)
Builder.defineMacro("__FAST_MATH__");
// Initialize target-specific preprocessor defines.
// __BYTE_ORDER__ was added in GCC 4.6. It's analogous
// to the macro __BYTE_ORDER (no trailing underscores)
// from glibc's <endian.h> header.
// We don't support the PDP-11 as a target, but include
// the define so it can still be compared against.
Builder.defineMacro("__ORDER_LITTLE_ENDIAN__", "1234");
Builder.defineMacro("__ORDER_BIG_ENDIAN__", "4321");
Builder.defineMacro("__ORDER_PDP_ENDIAN__", "3412");
if (TI.isBigEndian()) {
Builder.defineMacro("__BYTE_ORDER__", "__ORDER_BIG_ENDIAN__");
Builder.defineMacro("__BIG_ENDIAN__");
} else {
Builder.defineMacro("__BYTE_ORDER__", "__ORDER_LITTLE_ENDIAN__");
Builder.defineMacro("__LITTLE_ENDIAN__");
}
if (TI.getPointerWidth(0) == 64 && TI.getLongWidth() == 64
&& TI.getIntWidth() == 32) {
Builder.defineMacro("_LP64");
Builder.defineMacro("__LP64__");
}
if (TI.getPointerWidth(0) == 32 && TI.getLongWidth() == 32
&& TI.getIntWidth() == 32) {
Builder.defineMacro("_ILP32");
Builder.defineMacro("__ILP32__");
}
// Define type sizing macros based on the target properties.
assert(TI.getCharWidth() == 8 && "Only support 8-bit char so far");
Builder.defineMacro("__CHAR_BIT__", Twine(TI.getCharWidth()));
DefineTypeSize("__SCHAR_MAX__", TargetInfo::SignedChar, TI, Builder);
DefineTypeSize("__SHRT_MAX__", TargetInfo::SignedShort, TI, Builder);
DefineTypeSize("__INT_MAX__", TargetInfo::SignedInt, TI, Builder);
DefineTypeSize("__LONG_MAX__", TargetInfo::SignedLong, TI, Builder);
DefineTypeSize("__LONG_LONG_MAX__", TargetInfo::SignedLongLong, TI, Builder);
DefineTypeSize("__WCHAR_MAX__", TI.getWCharType(), TI, Builder);
DefineTypeSize("__WINT_MAX__", TI.getWIntType(), TI, Builder);
DefineTypeSize("__INTMAX_MAX__", TI.getIntMaxType(), TI, Builder);
DefineTypeSize("__SIZE_MAX__", TI.getSizeType(), TI, Builder);
DefineTypeSize("__UINTMAX_MAX__", TI.getUIntMaxType(), TI, Builder);
DefineTypeSize("__PTRDIFF_MAX__", TI.getPtrDiffType(0), TI, Builder);
DefineTypeSize("__INTPTR_MAX__", TI.getIntPtrType(), TI, Builder);
DefineTypeSize("__UINTPTR_MAX__", TI.getUIntPtrType(), TI, Builder);
DefineTypeSizeof("__SIZEOF_DOUBLE__", TI.getDoubleWidth(), TI, Builder);
DefineTypeSizeof("__SIZEOF_FLOAT__", TI.getFloatWidth(), TI, Builder);
DefineTypeSizeof("__SIZEOF_INT__", TI.getIntWidth(), TI, Builder);
DefineTypeSizeof("__SIZEOF_LONG__", TI.getLongWidth(), TI, Builder);
DefineTypeSizeof("__SIZEOF_LONG_DOUBLE__",TI.getLongDoubleWidth(),TI,Builder);
DefineTypeSizeof("__SIZEOF_LONG_LONG__", TI.getLongLongWidth(), TI, Builder);
DefineTypeSizeof("__SIZEOF_POINTER__", TI.getPointerWidth(0), TI, Builder);
DefineTypeSizeof("__SIZEOF_SHORT__", TI.getShortWidth(), TI, Builder);
DefineTypeSizeof("__SIZEOF_PTRDIFF_T__",
TI.getTypeWidth(TI.getPtrDiffType(0)), TI, Builder);
DefineTypeSizeof("__SIZEOF_SIZE_T__",
TI.getTypeWidth(TI.getSizeType()), TI, Builder);
DefineTypeSizeof("__SIZEOF_WCHAR_T__",
TI.getTypeWidth(TI.getWCharType()), TI, Builder);
DefineTypeSizeof("__SIZEOF_WINT_T__",
TI.getTypeWidth(TI.getWIntType()), TI, Builder);
if (TI.hasInt128Type())
DefineTypeSizeof("__SIZEOF_INT128__", 128, TI, Builder);
DefineType("__INTMAX_TYPE__", TI.getIntMaxType(), Builder);
DefineFmt("__INTMAX", TI.getIntMaxType(), TI, Builder);
Builder.defineMacro("__INTMAX_C_SUFFIX__",
TI.getTypeConstantSuffix(TI.getIntMaxType()));
DefineType("__UINTMAX_TYPE__", TI.getUIntMaxType(), Builder);
DefineFmt("__UINTMAX", TI.getUIntMaxType(), TI, Builder);
Builder.defineMacro("__UINTMAX_C_SUFFIX__",
TI.getTypeConstantSuffix(TI.getUIntMaxType()));
DefineTypeWidth("__INTMAX_WIDTH__", TI.getIntMaxType(), TI, Builder);
DefineType("__PTRDIFF_TYPE__", TI.getPtrDiffType(0), Builder);
DefineFmt("__PTRDIFF", TI.getPtrDiffType(0), TI, Builder);
DefineTypeWidth("__PTRDIFF_WIDTH__", TI.getPtrDiffType(0), TI, Builder);
DefineType("__INTPTR_TYPE__", TI.getIntPtrType(), Builder);
DefineFmt("__INTPTR", TI.getIntPtrType(), TI, Builder);
DefineTypeWidth("__INTPTR_WIDTH__", TI.getIntPtrType(), TI, Builder);
DefineType("__SIZE_TYPE__", TI.getSizeType(), Builder);
DefineFmt("__SIZE", TI.getSizeType(), TI, Builder);
DefineTypeWidth("__SIZE_WIDTH__", TI.getSizeType(), TI, Builder);
DefineType("__WCHAR_TYPE__", TI.getWCharType(), Builder);
DefineTypeWidth("__WCHAR_WIDTH__", TI.getWCharType(), TI, Builder);
DefineType("__WINT_TYPE__", TI.getWIntType(), Builder);
DefineTypeWidth("__WINT_WIDTH__", TI.getWIntType(), TI, Builder);
DefineTypeWidth("__SIG_ATOMIC_WIDTH__", TI.getSigAtomicType(), TI, Builder);
DefineTypeSize("__SIG_ATOMIC_MAX__", TI.getSigAtomicType(), TI, Builder);
DefineType("__CHAR16_TYPE__", TI.getChar16Type(), Builder);
DefineType("__CHAR32_TYPE__", TI.getChar32Type(), Builder);
DefineTypeWidth("__UINTMAX_WIDTH__", TI.getUIntMaxType(), TI, Builder);
DefineType("__UINTPTR_TYPE__", TI.getUIntPtrType(), Builder);
DefineFmt("__UINTPTR", TI.getUIntPtrType(), TI, Builder);
DefineTypeWidth("__UINTPTR_WIDTH__", TI.getUIntPtrType(), TI, Builder);
DefineFloatMacros(Builder, "FLT16", &TI.getHalfFormat(), "F16");
DefineFloatMacros(Builder, "FLT", &TI.getFloatFormat(), "F");
DefineFloatMacros(Builder, "DBL", &TI.getDoubleFormat(), "");
DefineFloatMacros(Builder, "LDBL", &TI.getLongDoubleFormat(), "L");
// Define a __POINTER_WIDTH__ macro for stdint.h.
Builder.defineMacro("__POINTER_WIDTH__",
Twine((int)TI.getPointerWidth(0)));
// Define __BIGGEST_ALIGNMENT__ to be compatible with gcc.
Builder.defineMacro("__BIGGEST_ALIGNMENT__",
Twine(TI.getSuitableAlign() / TI.getCharWidth()) );
if (!LangOpts.CharIsSigned)
Builder.defineMacro("__CHAR_UNSIGNED__");
if (!TargetInfo::isTypeSigned(TI.getWCharType()))
Builder.defineMacro("__WCHAR_UNSIGNED__");
if (!TargetInfo::isTypeSigned(TI.getWIntType()))
Builder.defineMacro("__WINT_UNSIGNED__");
// Define exact-width integer types for stdint.h
DefineExactWidthIntType(TargetInfo::SignedChar, TI, Builder);
if (TI.getShortWidth() > TI.getCharWidth())
DefineExactWidthIntType(TargetInfo::SignedShort, TI, Builder);
if (TI.getIntWidth() > TI.getShortWidth())
DefineExactWidthIntType(TargetInfo::SignedInt, TI, Builder);
if (TI.getLongWidth() > TI.getIntWidth())
DefineExactWidthIntType(TargetInfo::SignedLong, TI, Builder);
if (TI.getLongLongWidth() > TI.getLongWidth())
DefineExactWidthIntType(TargetInfo::SignedLongLong, TI, Builder);
DefineExactWidthIntType(TargetInfo::UnsignedChar, TI, Builder);
DefineExactWidthIntTypeSize(TargetInfo::UnsignedChar, TI, Builder);
DefineExactWidthIntTypeSize(TargetInfo::SignedChar, TI, Builder);
if (TI.getShortWidth() > TI.getCharWidth()) {
DefineExactWidthIntType(TargetInfo::UnsignedShort, TI, Builder);
DefineExactWidthIntTypeSize(TargetInfo::UnsignedShort, TI, Builder);
DefineExactWidthIntTypeSize(TargetInfo::SignedShort, TI, Builder);
}
if (TI.getIntWidth() > TI.getShortWidth()) {
DefineExactWidthIntType(TargetInfo::UnsignedInt, TI, Builder);
DefineExactWidthIntTypeSize(TargetInfo::UnsignedInt, TI, Builder);
DefineExactWidthIntTypeSize(TargetInfo::SignedInt, TI, Builder);
}
if (TI.getLongWidth() > TI.getIntWidth()) {
DefineExactWidthIntType(TargetInfo::UnsignedLong, TI, Builder);
DefineExactWidthIntTypeSize(TargetInfo::UnsignedLong, TI, Builder);
DefineExactWidthIntTypeSize(TargetInfo::SignedLong, TI, Builder);
}
if (TI.getLongLongWidth() > TI.getLongWidth()) {
DefineExactWidthIntType(TargetInfo::UnsignedLongLong, TI, Builder);
DefineExactWidthIntTypeSize(TargetInfo::UnsignedLongLong, TI, Builder);
DefineExactWidthIntTypeSize(TargetInfo::SignedLongLong, TI, Builder);
}
DefineLeastWidthIntType(8, true, TI, Builder);
DefineLeastWidthIntType(8, false, TI, Builder);
DefineLeastWidthIntType(16, true, TI, Builder);
DefineLeastWidthIntType(16, false, TI, Builder);
DefineLeastWidthIntType(32, true, TI, Builder);
DefineLeastWidthIntType(32, false, TI, Builder);
DefineLeastWidthIntType(64, true, TI, Builder);
DefineLeastWidthIntType(64, false, TI, Builder);
DefineFastIntType(8, true, TI, Builder);
DefineFastIntType(8, false, TI, Builder);
DefineFastIntType(16, true, TI, Builder);
DefineFastIntType(16, false, TI, Builder);
DefineFastIntType(32, true, TI, Builder);
DefineFastIntType(32, false, TI, Builder);
DefineFastIntType(64, true, TI, Builder);
DefineFastIntType(64, false, TI, Builder);
char UserLabelPrefix[2] = {TI.getDataLayout().getGlobalPrefix(), 0};
Builder.defineMacro("__USER_LABEL_PREFIX__", UserLabelPrefix);
if (LangOpts.FastMath || LangOpts.FiniteMathOnly)
Builder.defineMacro("__FINITE_MATH_ONLY__", "1");
else
Builder.defineMacro("__FINITE_MATH_ONLY__", "0");
if (!LangOpts.MSVCCompat) {
if (LangOpts.GNUInline || LangOpts.CPlusPlus)
Builder.defineMacro("__GNUC_GNU_INLINE__");
else
Builder.defineMacro("__GNUC_STDC_INLINE__");
// The value written by __atomic_test_and_set.
// FIXME: This is target-dependent.
Builder.defineMacro("__GCC_ATOMIC_TEST_AND_SET_TRUEVAL", "1");
}
auto addLockFreeMacros = [&](const llvm::Twine &Prefix) {
// Used by libc++ and libstdc++ to implement ATOMIC_<foo>_LOCK_FREE.
unsigned InlineWidthBits = TI.getMaxAtomicInlineWidth();
#define DEFINE_LOCK_FREE_MACRO(TYPE, Type) \
Builder.defineMacro(Prefix + #TYPE "_LOCK_FREE", \
getLockFreeValue(TI.get##Type##Width(), \
TI.get##Type##Align(), \
InlineWidthBits));
DEFINE_LOCK_FREE_MACRO(BOOL, Bool);
DEFINE_LOCK_FREE_MACRO(CHAR, Char);
if (LangOpts.Char8)
DEFINE_LOCK_FREE_MACRO(CHAR8_T, Char); // Treat char8_t like char.
DEFINE_LOCK_FREE_MACRO(CHAR16_T, Char16);
DEFINE_LOCK_FREE_MACRO(CHAR32_T, Char32);
DEFINE_LOCK_FREE_MACRO(WCHAR_T, WChar);
DEFINE_LOCK_FREE_MACRO(SHORT, Short);
DEFINE_LOCK_FREE_MACRO(INT, Int);
DEFINE_LOCK_FREE_MACRO(LONG, Long);
DEFINE_LOCK_FREE_MACRO(LLONG, LongLong);
Builder.defineMacro(Prefix + "POINTER_LOCK_FREE",
getLockFreeValue(TI.getPointerWidth(0),
TI.getPointerAlign(0),
InlineWidthBits));
#undef DEFINE_LOCK_FREE_MACRO
};
addLockFreeMacros("__CLANG_ATOMIC_");
if (!LangOpts.MSVCCompat)
addLockFreeMacros("__GCC_ATOMIC_");
if (LangOpts.NoInlineDefine)
Builder.defineMacro("__NO_INLINE__");
if (unsigned PICLevel = LangOpts.PICLevel) {
Builder.defineMacro("__PIC__", Twine(PICLevel));
Builder.defineMacro("__pic__", Twine(PICLevel));
if (LangOpts.PIE) {
Builder.defineMacro("__PIE__", Twine(PICLevel));
Builder.defineMacro("__pie__", Twine(PICLevel));
}
}
// Macros to control C99 numerics and <float.h>
Builder.defineMacro("__FLT_EVAL_METHOD__", Twine(TI.getFloatEvalMethod()));
Builder.defineMacro("__FLT_RADIX__", "2");
Builder.defineMacro("__DECIMAL_DIG__", "__LDBL_DECIMAL_DIG__");
if (LangOpts.getStackProtector() == LangOptions::SSPOn)
Builder.defineMacro("__SSP__");
else if (LangOpts.getStackProtector() == LangOptions::SSPStrong)
Builder.defineMacro("__SSP_STRONG__", "2");
else if (LangOpts.getStackProtector() == LangOptions::SSPReq)
Builder.defineMacro("__SSP_ALL__", "3");
// Define a macro that exists only when using the static analyzer.
if (FEOpts.ProgramAction == frontend::RunAnalysis)
Builder.defineMacro("__clang_analyzer__");
if (LangOpts.FastRelaxedMath)
Builder.defineMacro("__FAST_RELAXED_MATH__");
if (FEOpts.ProgramAction == frontend::RewriteObjC ||
LangOpts.getGC() != LangOptions::NonGC) {
Builder.defineMacro("__weak", "__attribute__((objc_gc(weak)))");
Builder.defineMacro("__strong", "__attribute__((objc_gc(strong)))");
Builder.defineMacro("__autoreleasing", "");
Builder.defineMacro("__unsafe_unretained", "");
} else if (LangOpts.ObjC) {
Builder.defineMacro("__weak", "__attribute__((objc_ownership(weak)))");
Builder.defineMacro("__strong", "__attribute__((objc_ownership(strong)))");
Builder.defineMacro("__autoreleasing",
"__attribute__((objc_ownership(autoreleasing)))");
Builder.defineMacro("__unsafe_unretained",
"__attribute__((objc_ownership(none)))");
}
// On Darwin, there are __double_underscored variants of the type
// nullability qualifiers.
if (TI.getTriple().isOSDarwin()) {
Builder.defineMacro("__nonnull", "_Nonnull");
Builder.defineMacro("__null_unspecified", "_Null_unspecified");
Builder.defineMacro("__nullable", "_Nullable");
}
// Add a macro to differentiate between regular iOS/tvOS/watchOS targets and
// the corresponding simulator targets.
if (TI.getTriple().isOSDarwin() && TI.getTriple().isSimulatorEnvironment())
Builder.defineMacro("__APPLE_EMBEDDED_SIMULATOR__", "1");
// OpenMP definition
// OpenMP 2.2:
// In implementations that support a preprocessor, the _OPENMP
// macro name is defined to have the decimal value yyyymm where
// yyyy and mm are the year and the month designations of the
// version of the OpenMP API that the implementation support.
if (!LangOpts.OpenMPSimd) {
switch (LangOpts.OpenMP) {
case 0:
break;
case 40:
Builder.defineMacro("_OPENMP", "201307");
break;
case 45:
Builder.defineMacro("_OPENMP", "201511");
break;
default:
// Default version is OpenMP 3.1
Builder.defineMacro("_OPENMP", "201107");
break;
}
}
// CUDA device path compilaton
if (LangOpts.CUDAIsDevice && !LangOpts.HIP) {
// The CUDA_ARCH value is set for the GPU target specified in the NVPTX
// backend's target defines.
Builder.defineMacro("__CUDA_ARCH__");
}
// We need to communicate this to our CUDA header wrapper, which in turn
// informs the proper CUDA headers of this choice.
if (LangOpts.CUDADeviceApproxTranscendentals || LangOpts.FastMath) {
Builder.defineMacro("__CLANG_CUDA_APPROX_TRANSCENDENTALS__");
}
// OpenCL definitions.
if (LangOpts.OpenCL) {
#define OPENCLEXT(Ext) \
if (TI.getSupportedOpenCLOpts().isSupported(#Ext, \
LangOpts.OpenCLVersion)) \
Builder.defineMacro(#Ext);
#include "clang/Basic/OpenCLExtensions.def"
auto Arch = TI.getTriple().getArch();
if (Arch == llvm::Triple::spir || Arch == llvm::Triple::spir64)
Builder.defineMacro("__IMAGE_SUPPORT__");
}
if (TI.hasInt128Type() && LangOpts.CPlusPlus && LangOpts.GNUMode) {
// For each extended integer type, g++ defines a macro mapping the
// index of the type (0 in this case) in some list of extended types
// to the type.
Builder.defineMacro("__GLIBCXX_TYPE_INT_N_0", "__int128");
Builder.defineMacro("__GLIBCXX_BITSIZE_INT_N_0", "128");
}
// Get other target #defines.
TI.getTargetDefines(LangOpts, Builder);
}
/// InitializePreprocessor - Initialize the preprocessor getting it and the
/// environment ready to process a single file. This returns true on error.
///
void clang::InitializePreprocessor(
Preprocessor &PP, const PreprocessorOptions &InitOpts,
const PCHContainerReader &PCHContainerRdr,
const FrontendOptions &FEOpts) {
const LangOptions &LangOpts = PP.getLangOpts();
std::string PredefineBuffer;
PredefineBuffer.reserve(4080);
llvm::raw_string_ostream Predefines(PredefineBuffer);
MacroBuilder Builder(Predefines);
// Emit line markers for various builtin sections of the file. We don't do
// this in asm preprocessor mode, because "# 4" is not a line marker directive
// in this mode.
if (!PP.getLangOpts().AsmPreprocessor)
Builder.append("# 1 \"<built-in>\" 3");
// Install things like __POWERPC__, __GNUC__, etc into the macro table.
if (InitOpts.UsePredefines) {
// FIXME: This will create multiple definitions for most of the predefined
// macros. This is not the right way to handle this.
if ((LangOpts.CUDA || LangOpts.OpenMPIsDevice) && PP.getAuxTargetInfo())
InitializePredefinedMacros(*PP.getAuxTargetInfo(), LangOpts, FEOpts,
Builder);
InitializePredefinedMacros(PP.getTargetInfo(), LangOpts, FEOpts, Builder);
// Install definitions to make Objective-C++ ARC work well with various
// C++ Standard Library implementations.
if (LangOpts.ObjC && LangOpts.CPlusPlus &&
(LangOpts.ObjCAutoRefCount || LangOpts.ObjCWeak)) {
switch (InitOpts.ObjCXXARCStandardLibrary) {
case ARCXX_nolib:
case ARCXX_libcxx:
break;
case ARCXX_libstdcxx:
AddObjCXXARCLibstdcxxDefines(LangOpts, Builder);
break;
}
}
}
// Even with predefines off, some macros are still predefined.
// These should all be defined in the preprocessor according to the
// current language configuration.
InitializeStandardPredefinedMacros(PP.getTargetInfo(), PP.getLangOpts(),
FEOpts, Builder);
// Add on the predefines from the driver. Wrap in a #line directive to report
// that they come from the command line.
if (!PP.getLangOpts().AsmPreprocessor)
Builder.append("# 1 \"<command line>\" 1");
// Process #define's and #undef's in the order they are given.
for (unsigned i = 0, e = InitOpts.Macros.size(); i != e; ++i) {
if (InitOpts.Macros[i].second) // isUndef
Builder.undefineMacro(InitOpts.Macros[i].first);
else
DefineBuiltinMacro(Builder, InitOpts.Macros[i].first,
PP.getDiagnostics());
}
// Exit the command line and go back to <built-in> (2 is LC_LEAVE).
if (!PP.getLangOpts().AsmPreprocessor)
Builder.append("# 1 \"<built-in>\" 2");
// If -imacros are specified, include them now. These are processed before
// any -include directives.
for (unsigned i = 0, e = InitOpts.MacroIncludes.size(); i != e; ++i)
AddImplicitIncludeMacros(Builder, InitOpts.MacroIncludes[i]);
// Process -include-pch/-include-pth directives.
if (!InitOpts.ImplicitPCHInclude.empty())
AddImplicitIncludePCH(Builder, PP, PCHContainerRdr,
InitOpts.ImplicitPCHInclude);
// Process -include directives.
for (unsigned i = 0, e = InitOpts.Includes.size(); i != e; ++i) {
const std::string &Path = InitOpts.Includes[i];
AddImplicitInclude(Builder, Path);
}
// Instruct the preprocessor to skip the preamble.
PP.setSkipMainFilePreamble(InitOpts.PrecompiledPreambleBytes.first,
InitOpts.PrecompiledPreambleBytes.second);
// Copy PredefinedBuffer into the Preprocessor.
PP.setPredefines(Predefines.str());
}
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