llvm-6502/include/llvm/Target/TargetOptions.h
Rafael Espindola e0a2541eb7 Add r228980 back.
Add support for having multiple sections with the same name and comdat.

Using this in combination with -ffunction-sections allows LLVM to output a .o
file with mulitple sections named .text. This saves space by avoiding long
unique names of the form .text.<C++ mangled name>.

git-svn-id: https://llvm.org/svn/llvm-project/llvm/trunk@229541 91177308-0d34-0410-b5e6-96231b3b80d8
2015-02-17 20:48:01 +00:00

311 lines
12 KiB
C++

//===-- llvm/Target/TargetOptions.h - Target Options ------------*- C++ -*-===//
//
// The LLVM Compiler Infrastructure
//
// This file is distributed under the University of Illinois Open Source
// License. See LICENSE.TXT for details.
//
//===----------------------------------------------------------------------===//
//
// This file defines command line option flags that are shared across various
// targets.
//
//===----------------------------------------------------------------------===//
#ifndef LLVM_TARGET_TARGETOPTIONS_H
#define LLVM_TARGET_TARGETOPTIONS_H
#include "llvm/MC/MCTargetOptions.h"
#include <string>
namespace llvm {
class MachineFunction;
class StringRef;
// Possible float ABI settings. Used with FloatABIType in TargetOptions.h.
namespace FloatABI {
enum ABIType {
Default, // Target-specific (either soft or hard depending on triple,etc).
Soft, // Soft float.
Hard // Hard float.
};
}
namespace FPOpFusion {
enum FPOpFusionMode {
Fast, // Enable fusion of FP ops wherever it's profitable.
Standard, // Only allow fusion of 'blessed' ops (currently just fmuladd).
Strict // Never fuse FP-ops.
};
}
namespace JumpTable {
enum JumpTableType {
Single, // Use a single table for all indirect jumptable calls.
Arity, // Use one table per number of function parameters.
Simplified, // Use one table per function type, with types projected
// into 4 types: pointer to non-function, struct,
// primitive, and function pointer.
Full // Use one table per unique function type
};
}
namespace ThreadModel {
enum Model {
POSIX, // POSIX Threads
Single // Single Threaded Environment
};
}
enum class CFIntegrity {
Sub, // Use subtraction-based checks.
Ror, // Use rotation-based checks.
Add // Use addition-based checks. This depends on having
// sufficient alignment in the code and is usually not
// feasible.
};
class TargetOptions {
public:
TargetOptions()
: PrintMachineCode(false), NoFramePointerElim(false),
LessPreciseFPMADOption(false), UnsafeFPMath(false),
NoInfsFPMath(false), NoNaNsFPMath(false),
HonorSignDependentRoundingFPMathOption(false), UseSoftFloat(false),
NoZerosInBSS(false), JITEmitDebugInfo(false),
JITEmitDebugInfoToDisk(false), GuaranteedTailCallOpt(false),
DisableTailCalls(false), StackAlignmentOverride(0),
EnableFastISel(false), PositionIndependentExecutable(false),
UseInitArray(false), DisableIntegratedAS(false),
CompressDebugSections(false), FunctionSections(false),
DataSections(false), UniqueSectionNames(true), TrapUnreachable(false),
TrapFuncName(), FloatABIType(FloatABI::Default),
AllowFPOpFusion(FPOpFusion::Standard), JTType(JumpTable::Single),
FCFI(false), ThreadModel(ThreadModel::POSIX),
CFIType(CFIntegrity::Sub), CFIEnforcing(false), CFIFuncName() {}
/// PrintMachineCode - This flag is enabled when the -print-machineinstrs
/// option is specified on the command line, and should enable debugging
/// output from the code generator.
unsigned PrintMachineCode : 1;
/// NoFramePointerElim - This flag is enabled when the -disable-fp-elim is
/// specified on the command line. If the target supports the frame pointer
/// elimination optimization, this option should disable it.
unsigned NoFramePointerElim : 1;
/// DisableFramePointerElim - This returns true if frame pointer elimination
/// optimization should be disabled for the given machine function.
bool DisableFramePointerElim(const MachineFunction &MF) const;
/// LessPreciseFPMAD - This flag is enabled when the
/// -enable-fp-mad is specified on the command line. When this flag is off
/// (the default), the code generator is not allowed to generate mad
/// (multiply add) if the result is "less precise" than doing those
/// operations individually.
unsigned LessPreciseFPMADOption : 1;
bool LessPreciseFPMAD() const;
/// UnsafeFPMath - This flag is enabled when the
/// -enable-unsafe-fp-math flag is specified on the command line. When
/// this flag is off (the default), the code generator is not allowed to
/// produce results that are "less precise" than IEEE allows. This includes
/// use of X86 instructions like FSIN and FCOS instead of libcalls.
/// UnsafeFPMath implies LessPreciseFPMAD.
unsigned UnsafeFPMath : 1;
/// NoInfsFPMath - This flag is enabled when the
/// -enable-no-infs-fp-math flag is specified on the command line. When
/// this flag is off (the default), the code generator is not allowed to
/// assume the FP arithmetic arguments and results are never +-Infs.
unsigned NoInfsFPMath : 1;
/// NoNaNsFPMath - This flag is enabled when the
/// -enable-no-nans-fp-math flag is specified on the command line. When
/// this flag is off (the default), the code generator is not allowed to
/// assume the FP arithmetic arguments and results are never NaNs.
unsigned NoNaNsFPMath : 1;
/// HonorSignDependentRoundingFPMath - This returns true when the
/// -enable-sign-dependent-rounding-fp-math is specified. If this returns
/// false (the default), the code generator is allowed to assume that the
/// rounding behavior is the default (round-to-zero for all floating point
/// to integer conversions, and round-to-nearest for all other arithmetic
/// truncations). If this is enabled (set to true), the code generator must
/// assume that the rounding mode may dynamically change.
unsigned HonorSignDependentRoundingFPMathOption : 1;
bool HonorSignDependentRoundingFPMath() const;
/// UseSoftFloat - This flag is enabled when the -soft-float flag is
/// specified on the command line. When this flag is on, the code generator
/// will generate libcalls to the software floating point library instead of
/// target FP instructions.
unsigned UseSoftFloat : 1;
/// NoZerosInBSS - By default some codegens place zero-initialized data to
/// .bss section. This flag disables such behaviour (necessary, e.g. for
/// crt*.o compiling).
unsigned NoZerosInBSS : 1;
/// JITEmitDebugInfo - This flag indicates that the JIT should try to emit
/// debug information and notify a debugger about it.
unsigned JITEmitDebugInfo : 1;
/// JITEmitDebugInfoToDisk - This flag indicates that the JIT should write
/// the object files generated by the JITEmitDebugInfo flag to disk. This
/// flag is hidden and is only for debugging the debug info.
unsigned JITEmitDebugInfoToDisk : 1;
/// GuaranteedTailCallOpt - This flag is enabled when -tailcallopt is
/// specified on the commandline. When the flag is on, participating targets
/// will perform tail call optimization on all calls which use the fastcc
/// calling convention and which satisfy certain target-independent
/// criteria (being at the end of a function, having the same return type
/// as their parent function, etc.), using an alternate ABI if necessary.
unsigned GuaranteedTailCallOpt : 1;
/// DisableTailCalls - This flag controls whether we will use tail calls.
/// Disabling them may be useful to maintain a correct call stack.
unsigned DisableTailCalls : 1;
/// StackAlignmentOverride - Override default stack alignment for target.
unsigned StackAlignmentOverride;
/// EnableFastISel - This flag enables fast-path instruction selection
/// which trades away generated code quality in favor of reducing
/// compile time.
unsigned EnableFastISel : 1;
/// PositionIndependentExecutable - This flag indicates whether the code
/// will eventually be linked into a single executable, despite the PIC
/// relocation model being in use. It's value is undefined (and irrelevant)
/// if the relocation model is anything other than PIC.
unsigned PositionIndependentExecutable : 1;
/// UseInitArray - Use .init_array instead of .ctors for static
/// constructors.
unsigned UseInitArray : 1;
/// Disable the integrated assembler.
unsigned DisableIntegratedAS : 1;
/// Compress DWARF debug sections.
unsigned CompressDebugSections : 1;
/// Emit functions into separate sections.
unsigned FunctionSections : 1;
/// Emit data into separate sections.
unsigned DataSections : 1;
unsigned UniqueSectionNames : 1;
/// Emit target-specific trap instruction for 'unreachable' IR instructions.
unsigned TrapUnreachable : 1;
/// getTrapFunctionName - If this returns a non-empty string, this means
/// isel should lower Intrinsic::trap to a call to the specified function
/// name instead of an ISD::TRAP node.
std::string TrapFuncName;
StringRef getTrapFunctionName() const;
/// FloatABIType - This setting is set by -float-abi=xxx option is specfied
/// on the command line. This setting may either be Default, Soft, or Hard.
/// Default selects the target's default behavior. Soft selects the ABI for
/// UseSoftFloat, but does not indicate that FP hardware may not be used.
/// Such a combination is unfortunately popular (e.g. arm-apple-darwin).
/// Hard presumes that the normal FP ABI is used.
FloatABI::ABIType FloatABIType;
/// AllowFPOpFusion - This flag is set by the -fuse-fp-ops=xxx option.
/// This controls the creation of fused FP ops that store intermediate
/// results in higher precision than IEEE allows (E.g. FMAs).
///
/// Fast mode - allows formation of fused FP ops whenever they're
/// profitable.
/// Standard mode - allow fusion only for 'blessed' FP ops. At present the
/// only blessed op is the fmuladd intrinsic. In the future more blessed ops
/// may be added.
/// Strict mode - allow fusion only if/when it can be proven that the excess
/// precision won't effect the result.
///
/// Note: This option only controls formation of fused ops by the
/// optimizers. Fused operations that are explicitly specified (e.g. FMA
/// via the llvm.fma.* intrinsic) will always be honored, regardless of
/// the value of this option.
FPOpFusion::FPOpFusionMode AllowFPOpFusion;
/// JTType - This flag specifies the type of jump-instruction table to
/// create for functions that have the jumptable attribute.
JumpTable::JumpTableType JTType;
/// FCFI - This flags controls whether or not forward-edge control-flow
/// integrity is applied.
bool FCFI;
/// ThreadModel - This flag specifies the type of threading model to assume
/// for things like atomics
ThreadModel::Model ThreadModel;
/// CFIType - This flag specifies the type of control-flow integrity check
/// to add as a preamble to indirect calls.
CFIntegrity CFIType;
/// CFIEnforcing - This flags controls whether or not CFI violations cause
/// the program to halt.
bool CFIEnforcing;
/// getCFIFuncName - If this returns a non-empty string, then this is the
/// name of the function that will be called for each CFI violation in
/// non-enforcing mode.
std::string CFIFuncName;
StringRef getCFIFuncName() const;
/// Machine level options.
MCTargetOptions MCOptions;
};
// Comparison operators:
inline bool operator==(const TargetOptions &LHS,
const TargetOptions &RHS) {
#define ARE_EQUAL(X) LHS.X == RHS.X
return
ARE_EQUAL(UnsafeFPMath) &&
ARE_EQUAL(NoInfsFPMath) &&
ARE_EQUAL(NoNaNsFPMath) &&
ARE_EQUAL(HonorSignDependentRoundingFPMathOption) &&
ARE_EQUAL(UseSoftFloat) &&
ARE_EQUAL(NoZerosInBSS) &&
ARE_EQUAL(JITEmitDebugInfo) &&
ARE_EQUAL(JITEmitDebugInfoToDisk) &&
ARE_EQUAL(GuaranteedTailCallOpt) &&
ARE_EQUAL(DisableTailCalls) &&
ARE_EQUAL(StackAlignmentOverride) &&
ARE_EQUAL(EnableFastISel) &&
ARE_EQUAL(PositionIndependentExecutable) &&
ARE_EQUAL(UseInitArray) &&
ARE_EQUAL(TrapUnreachable) &&
ARE_EQUAL(TrapFuncName) &&
ARE_EQUAL(FloatABIType) &&
ARE_EQUAL(AllowFPOpFusion) &&
ARE_EQUAL(JTType) &&
ARE_EQUAL(FCFI) &&
ARE_EQUAL(ThreadModel) &&
ARE_EQUAL(CFIType) &&
ARE_EQUAL(CFIEnforcing) &&
ARE_EQUAL(CFIFuncName) &&
ARE_EQUAL(MCOptions);
#undef ARE_EQUAL
}
inline bool operator!=(const TargetOptions &LHS,
const TargetOptions &RHS) {
return !(LHS == RHS);
}
} // End llvm namespace
#endif