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llvm-mirror/utils/TableGen/CodeGenIntrinsics.h
Vedant Kumar d61070716c Mark @llvm.trap cold
A call to @llvm.trap can be expected to be cold (i.e. unlikely to be
reached in a normal program execution).

Outlining paths which unconditionally trap is an important memory
saving. As the hot/cold splitting pass (imho) should not treat all
noreturn calls as cold, explicitly mark @llvm.trap cold so that it can
be outlined.

Split out of https://reviews.llvm.org/D54244.

Differential Revision: https://reviews.llvm.org/D54329

llvm-svn: 346885
2018-11-14 19:53:41 +00:00

174 lines
5.7 KiB
C++

//===- CodeGenIntrinsic.h - Intrinsic Class Wrapper ------------*- 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 a wrapper class for the 'Intrinsic' TableGen class.
//
//===----------------------------------------------------------------------===//
#ifndef LLVM_UTILS_TABLEGEN_CODEGENINTRINSICS_H
#define LLVM_UTILS_TABLEGEN_CODEGENINTRINSICS_H
#include "SDNodeProperties.h"
#include "llvm/Support/MachineValueType.h"
#include <string>
#include <vector>
namespace llvm {
class Record;
class RecordKeeper;
class CodeGenTarget;
struct CodeGenIntrinsic {
Record *TheDef; // The actual record defining this intrinsic.
std::string Name; // The name of the LLVM function "llvm.bswap.i32"
std::string EnumName; // The name of the enum "bswap_i32"
std::string GCCBuiltinName; // Name of the corresponding GCC builtin, or "".
std::string MSBuiltinName; // Name of the corresponding MS builtin, or "".
std::string TargetPrefix; // Target prefix, e.g. "ppc" for t-s intrinsics.
/// This structure holds the return values and parameter values of an
/// intrinsic. If the number of return values is > 1, then the intrinsic
/// implicitly returns a first-class aggregate. The numbering of the types
/// starts at 0 with the first return value and continues from there through
/// the parameter list. This is useful for "matching" types.
struct IntrinsicSignature {
/// The MVT::SimpleValueType for each return type. Note that this list is
/// only populated when in the context of a target .td file. When building
/// Intrinsics.td, this isn't available, because we don't know the target
/// pointer size.
std::vector<MVT::SimpleValueType> RetVTs;
/// The records for each return type.
std::vector<Record *> RetTypeDefs;
/// The MVT::SimpleValueType for each parameter type. Note that this list is
/// only populated when in the context of a target .td file. When building
/// Intrinsics.td, this isn't available, because we don't know the target
/// pointer size.
std::vector<MVT::SimpleValueType> ParamVTs;
/// The records for each parameter type.
std::vector<Record *> ParamTypeDefs;
};
IntrinsicSignature IS;
/// Bit flags describing the type (ref/mod) and location of memory
/// accesses that may be performed by the intrinsics. Analogous to
/// \c FunctionModRefBehaviour.
enum ModRefBits {
/// The intrinsic may access memory that is otherwise inaccessible via
/// LLVM IR.
MR_InaccessibleMem = 1,
/// The intrinsic may access memory through pointer arguments.
/// LLVM IR.
MR_ArgMem = 2,
/// The intrinsic may access memory anywhere, i.e. it is not restricted
/// to access through pointer arguments.
MR_Anywhere = 4 | MR_ArgMem | MR_InaccessibleMem,
/// The intrinsic may read memory.
MR_Ref = 8,
/// The intrinsic may write memory.
MR_Mod = 16,
/// The intrinsic may both read and write memory.
MR_ModRef = MR_Ref | MR_Mod,
};
/// Memory mod/ref behavior of this intrinsic, corresponding to intrinsic
/// properties (IntrReadMem, IntrArgMemOnly, etc.).
enum ModRefBehavior {
NoMem = 0,
ReadArgMem = MR_Ref | MR_ArgMem,
ReadInaccessibleMem = MR_Ref | MR_InaccessibleMem,
ReadInaccessibleMemOrArgMem = MR_Ref | MR_ArgMem | MR_InaccessibleMem,
ReadMem = MR_Ref | MR_Anywhere,
WriteArgMem = MR_Mod | MR_ArgMem,
WriteInaccessibleMem = MR_Mod | MR_InaccessibleMem,
WriteInaccessibleMemOrArgMem = MR_Mod | MR_ArgMem | MR_InaccessibleMem,
WriteMem = MR_Mod | MR_Anywhere,
ReadWriteArgMem = MR_ModRef | MR_ArgMem,
ReadWriteInaccessibleMem = MR_ModRef | MR_InaccessibleMem,
ReadWriteInaccessibleMemOrArgMem = MR_ModRef | MR_ArgMem |
MR_InaccessibleMem,
ReadWriteMem = MR_ModRef | MR_Anywhere,
};
ModRefBehavior ModRef;
/// SDPatternOperator Properties applied to the intrinsic.
unsigned Properties;
/// This is set to true if the intrinsic is overloaded by its argument
/// types.
bool isOverloaded;
/// True if the intrinsic is commutative.
bool isCommutative;
/// True if the intrinsic can throw.
bool canThrow;
/// True if the intrinsic is marked as noduplicate.
bool isNoDuplicate;
/// True if the intrinsic is no-return.
bool isNoReturn;
/// True if the intrinsic is cold.
bool isCold;
/// True if the intrinsic is marked as convergent.
bool isConvergent;
/// True if the intrinsic has side effects that aren't captured by any
/// of the other flags.
bool hasSideEffects;
// True if the intrinsic is marked as speculatable.
bool isSpeculatable;
enum ArgAttribute { NoCapture, Returned, ReadOnly, WriteOnly, ReadNone };
std::vector<std::pair<unsigned, ArgAttribute>> ArgumentAttributes;
bool hasProperty(enum SDNP Prop) const {
return Properties & (1 << Prop);
}
CodeGenIntrinsic(Record *R);
};
class CodeGenIntrinsicTable {
std::vector<CodeGenIntrinsic> Intrinsics;
public:
struct TargetSet {
std::string Name;
size_t Offset;
size_t Count;
};
std::vector<TargetSet> Targets;
explicit CodeGenIntrinsicTable(const RecordKeeper &RC, bool TargetOnly);
CodeGenIntrinsicTable() = default;
bool empty() const { return Intrinsics.empty(); }
size_t size() const { return Intrinsics.size(); }
CodeGenIntrinsic &operator[](size_t Pos) { return Intrinsics[Pos]; }
const CodeGenIntrinsic &operator[](size_t Pos) const {
return Intrinsics[Pos];
}
};
}
#endif