clang-r445002/include/llvm/CodeGen/TargetCallingConv.h - platform/prebuilts/clang/host/darwin-x86 - Git at Google

 //===-- llvm/CodeGen/TargetCallingConv.h - Calling Convention ---*- C++ -*-===//
 //
 // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
 // See https://llvm.org/LICENSE.txt for license information.
 // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
 //
 //===----------------------------------------------------------------------===//
 //
 // This file defines types for working with calling-convention information.
 //
 //===----------------------------------------------------------------------===//

 #ifndef LLVM_CODEGEN_TARGETCALLINGCONV_H
 #define LLVM_CODEGEN_TARGETCALLINGCONV_H

 #include "llvm/CodeGen/ValueTypes.h"
 #include "llvm/Support/Alignment.h"
 #include "llvm/Support/MachineValueType.h"
 #include "llvm/Support/MathExtras.h"
 #include <cassert>
 #include <climits>
 #include <cstdint>

 namespace llvm {
 namespace ISD {

   struct ArgFlagsTy {
   private:
     unsigned IsZExt : 1;     ///< Zero extended
     unsigned IsSExt : 1;     ///< Sign extended
     unsigned IsInReg : 1;    ///< Passed in register
     unsigned IsSRet : 1;     ///< Hidden struct-ret ptr
     unsigned IsByVal : 1;    ///< Struct passed by value
     unsigned IsByRef : 1;    ///< Passed in memory
     unsigned IsNest : 1;     ///< Nested fn static chain
     unsigned IsReturned : 1; ///< Always returned
     unsigned IsSplit : 1;
     unsigned IsInAlloca : 1;   ///< Passed with inalloca
     unsigned IsPreallocated : 1; ///< ByVal without the copy
     unsigned IsSplitEnd : 1;   ///< Last part of a split
     unsigned IsSwiftSelf : 1;  ///< Swift self parameter
     unsigned IsSwiftAsync : 1;  ///< Swift async context parameter
     unsigned IsSwiftError : 1; ///< Swift error parameter
     unsigned IsCFGuardTarget : 1; ///< Control Flow Guard target
     unsigned IsHva : 1;        ///< HVA field for
     unsigned IsHvaStart : 1;   ///< HVA structure start
     unsigned IsSecArgPass : 1; ///< Second argument
     unsigned MemAlign : 4;     ///< Log 2 of alignment when arg is passed in memory
                                ///< (including byval/byref)
     unsigned OrigAlign : 5;    ///< Log 2 of original alignment
     unsigned IsInConsecutiveRegsLast : 1;
     unsigned IsInConsecutiveRegs : 1;
     unsigned IsCopyElisionCandidate : 1; ///< Argument copy elision candidate
     unsigned IsPointer : 1;

     unsigned ByValOrByRefSize; ///< Byval or byref struct size

     unsigned PointerAddrSpace; ///< Address space of pointer argument

   public:
     ArgFlagsTy()
         : IsZExt(0), IsSExt(0), IsInReg(0), IsSRet(0), IsByVal(0), IsByRef(0),
           IsNest(0), IsReturned(0), IsSplit(0), IsInAlloca(0),
           IsPreallocated(0), IsSplitEnd(0), IsSwiftSelf(0), IsSwiftAsync(0),
           IsSwiftError(0), IsCFGuardTarget(0), IsHva(0), IsHvaStart(0),
           IsSecArgPass(0), MemAlign(0), OrigAlign(0),
           IsInConsecutiveRegsLast(0), IsInConsecutiveRegs(0),
           IsCopyElisionCandidate(0), IsPointer(0), ByValOrByRefSize(0),
           PointerAddrSpace(0) {
       static_assert(sizeof(*this) == 3 * sizeof(unsigned), "flags are too big");
     }

     bool isZExt() const { return IsZExt; }
     void setZExt() { IsZExt = 1; }

     bool isSExt() const { return IsSExt; }
     void setSExt() { IsSExt = 1; }

     bool isInReg() const { return IsInReg; }
     void setInReg() { IsInReg = 1; }

     bool isSRet() const { return IsSRet; }
     void setSRet() { IsSRet = 1; }

     bool isByVal() const { return IsByVal; }
     void setByVal() { IsByVal = 1; }

     bool isByRef() const { return IsByRef; }
     void setByRef() { IsByRef = 1; }

     bool isInAlloca() const { return IsInAlloca; }
     void setInAlloca() { IsInAlloca = 1; }

     bool isPreallocated() const { return IsPreallocated; }
     void setPreallocated() { IsPreallocated = 1; }

     bool isSwiftSelf() const { return IsSwiftSelf; }
     void setSwiftSelf() { IsSwiftSelf = 1; }

     bool isSwiftAsync() const { return IsSwiftAsync; }
     void setSwiftAsync() { IsSwiftAsync = 1; }

     bool isSwiftError() const { return IsSwiftError; }
     void setSwiftError() { IsSwiftError = 1; }

     bool isCFGuardTarget() const { return IsCFGuardTarget; }
     void setCFGuardTarget() { IsCFGuardTarget = 1; }

     bool isHva() const { return IsHva; }
     void setHva() { IsHva = 1; }

     bool isHvaStart() const { return IsHvaStart; }
     void setHvaStart() { IsHvaStart = 1; }

     bool isSecArgPass() const { return IsSecArgPass; }
     void setSecArgPass() { IsSecArgPass = 1; }

     bool isNest() const { return IsNest; }
     void setNest() { IsNest = 1; }

     bool isReturned() const { return IsReturned; }
     void setReturned(bool V = true) { IsReturned = V; }

     bool isInConsecutiveRegs()  const { return IsInConsecutiveRegs; }
     void setInConsecutiveRegs(bool Flag = true) { IsInConsecutiveRegs = Flag; }

     bool isInConsecutiveRegsLast() const { return IsInConsecutiveRegsLast; }
     void setInConsecutiveRegsLast(bool Flag = true) {
       IsInConsecutiveRegsLast = Flag;
     }

     bool isSplit()   const { return IsSplit; }
     void setSplit()  { IsSplit = 1; }

     bool isSplitEnd()   const { return IsSplitEnd; }
     void setSplitEnd()  { IsSplitEnd = 1; }

     bool isCopyElisionCandidate()  const { return IsCopyElisionCandidate; }
     void setCopyElisionCandidate() { IsCopyElisionCandidate = 1; }

     bool isPointer()  const { return IsPointer; }
     void setPointer() { IsPointer = 1; }

     Align getNonZeroMemAlign() const {
       return decodeMaybeAlign(MemAlign).valueOrOne();
     }

     void setMemAlign(Align A) {
       MemAlign = encode(A);
       assert(getNonZeroMemAlign() == A && "bitfield overflow");
     }

     Align getNonZeroByValAlign() const {
       assert(isByVal());
       MaybeAlign A = decodeMaybeAlign(MemAlign);
       assert(A && "ByValAlign must be defined");
       return *A;
     }

     Align getNonZeroOrigAlign() const {
       return decodeMaybeAlign(OrigAlign).valueOrOne();
     }

     void setOrigAlign(Align A) {
       OrigAlign = encode(A);
       assert(getNonZeroOrigAlign() == A && "bitfield overflow");
     }

     unsigned getByValSize() const {
       assert(isByVal() && !isByRef());
       return ByValOrByRefSize;
     }
     void setByValSize(unsigned S) {
       assert(isByVal() && !isByRef());
       ByValOrByRefSize = S;
     }

     unsigned getByRefSize() const {
       assert(!isByVal() && isByRef());
       return ByValOrByRefSize;
     }
     void setByRefSize(unsigned S) {
       assert(!isByVal() && isByRef());
       ByValOrByRefSize = S;
     }

     unsigned getPointerAddrSpace() const { return PointerAddrSpace; }
     void setPointerAddrSpace(unsigned AS) { PointerAddrSpace = AS; }
 };

   /// InputArg - This struct carries flags and type information about a
   /// single incoming (formal) argument or incoming (from the perspective
   /// of the caller) return value virtual register.
   ///
   struct InputArg {
     ArgFlagsTy Flags;
     MVT VT = MVT::Other;
     EVT ArgVT;
     bool Used = false;

     /// Index original Function's argument.
     unsigned OrigArgIndex;
     /// Sentinel value for implicit machine-level input arguments.
     static const unsigned NoArgIndex = UINT_MAX;

     /// Offset in bytes of current input value relative to the beginning of
     /// original argument. E.g. if argument was splitted into four 32 bit
     /// registers, we got 4 InputArgs with PartOffsets 0, 4, 8 and 12.
     unsigned PartOffset;

     InputArg() = default;
     InputArg(ArgFlagsTy flags, EVT vt, EVT argvt, bool used,
              unsigned origIdx, unsigned partOffs)
       : Flags(flags), Used(used), OrigArgIndex(origIdx), PartOffset(partOffs) {
       VT = vt.getSimpleVT();
       ArgVT = argvt;
     }

     bool isOrigArg() const {
       return OrigArgIndex != NoArgIndex;
     }

     unsigned getOrigArgIndex() const {
       assert(OrigArgIndex != NoArgIndex && "Implicit machine-level argument");
       return OrigArgIndex;
     }
   };

   /// OutputArg - This struct carries flags and a value for a
   /// single outgoing (actual) argument or outgoing (from the perspective
   /// of the caller) return value virtual register.
   ///
   struct OutputArg {
     ArgFlagsTy Flags;
     MVT VT;
     EVT ArgVT;

     /// IsFixed - Is this a "fixed" value, ie not passed through a vararg "...".
     bool IsFixed = false;

     /// Index original Function's argument.
     unsigned OrigArgIndex;

     /// Offset in bytes of current output value relative to the beginning of
     /// original argument. E.g. if argument was splitted into four 32 bit
     /// registers, we got 4 OutputArgs with PartOffsets 0, 4, 8 and 12.
     unsigned PartOffset;

     OutputArg() = default;
     OutputArg(ArgFlagsTy flags, MVT vt, EVT argvt, bool isfixed,
               unsigned origIdx, unsigned partOffs)
         : Flags(flags), IsFixed(isfixed), OrigArgIndex(origIdx),
           PartOffset(partOffs) {
       VT = vt;
       ArgVT = argvt;
     }
   };

 } // end namespace ISD
 } // end namespace llvm

 #endif // LLVM_CODEGEN_TARGETCALLINGCONV_H
	//===-- llvm/CodeGen/TargetCallingConv.h - Calling Convention ---- C++ --===//
	//
	// Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
	// See https://llvm.org/LICENSE.txt for license information.
	// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
	//
	//===----------------------------------------------------------------------===//
	//
	// This file defines types for working with calling-convention information.
	//
	//===----------------------------------------------------------------------===//

	#ifndef LLVM_CODEGEN_TARGETCALLINGCONV_H
	#define LLVM_CODEGEN_TARGETCALLINGCONV_H

	#include "llvm/CodeGen/ValueTypes.h"
	#include "llvm/Support/Alignment.h"
	#include "llvm/Support/MachineValueType.h"
	#include "llvm/Support/MathExtras.h"
	#include <cassert>
	#include <climits>
	#include <cstdint>

	namespace llvm {
	namespace ISD {

	struct ArgFlagsTy {
	private:
	unsigned IsZExt : 1; ///< Zero extended
	unsigned IsSExt : 1; ///< Sign extended
	unsigned IsInReg : 1; ///< Passed in register
	unsigned IsSRet : 1; ///< Hidden struct-ret ptr
	unsigned IsByVal : 1; ///< Struct passed by value
	unsigned IsByRef : 1; ///< Passed in memory
	unsigned IsNest : 1; ///< Nested fn static chain
	unsigned IsReturned : 1; ///< Always returned
	unsigned IsSplit : 1;
	unsigned IsInAlloca : 1; ///< Passed with inalloca
	unsigned IsPreallocated : 1; ///< ByVal without the copy
	unsigned IsSplitEnd : 1; ///< Last part of a split
	unsigned IsSwiftSelf : 1; ///< Swift self parameter
	unsigned IsSwiftAsync : 1; ///< Swift async context parameter
	unsigned IsSwiftError : 1; ///< Swift error parameter
	unsigned IsCFGuardTarget : 1; ///< Control Flow Guard target
	unsigned IsHva : 1; ///< HVA field for
	unsigned IsHvaStart : 1; ///< HVA structure start
	unsigned IsSecArgPass : 1; ///< Second argument
	unsigned MemAlign : 4; ///< Log 2 of alignment when arg is passed in memory
	///< (including byval/byref)
	unsigned OrigAlign : 5; ///< Log 2 of original alignment
	unsigned IsInConsecutiveRegsLast : 1;
	unsigned IsInConsecutiveRegs : 1;
	unsigned IsCopyElisionCandidate : 1; ///< Argument copy elision candidate
	unsigned IsPointer : 1;

	unsigned ByValOrByRefSize; ///< Byval or byref struct size

	unsigned PointerAddrSpace; ///< Address space of pointer argument

	public:
	ArgFlagsTy()
	: IsZExt(0), IsSExt(0), IsInReg(0), IsSRet(0), IsByVal(0), IsByRef(0),
	IsNest(0), IsReturned(0), IsSplit(0), IsInAlloca(0),
	IsPreallocated(0), IsSplitEnd(0), IsSwiftSelf(0), IsSwiftAsync(0),
	IsSwiftError(0), IsCFGuardTarget(0), IsHva(0), IsHvaStart(0),
	IsSecArgPass(0), MemAlign(0), OrigAlign(0),
	IsInConsecutiveRegsLast(0), IsInConsecutiveRegs(0),
	IsCopyElisionCandidate(0), IsPointer(0), ByValOrByRefSize(0),
	PointerAddrSpace(0) {
	static_assert(sizeof(this) == 3 sizeof(unsigned), "flags are too big");
	}

	bool isZExt() const { return IsZExt; }
	void setZExt() { IsZExt = 1; }

	bool isSExt() const { return IsSExt; }
	void setSExt() { IsSExt = 1; }

	bool isInReg() const { return IsInReg; }
	void setInReg() { IsInReg = 1; }

	bool isSRet() const { return IsSRet; }
	void setSRet() { IsSRet = 1; }

	bool isByVal() const { return IsByVal; }
	void setByVal() { IsByVal = 1; }

	bool isByRef() const { return IsByRef; }
	void setByRef() { IsByRef = 1; }

	bool isInAlloca() const { return IsInAlloca; }
	void setInAlloca() { IsInAlloca = 1; }

	bool isPreallocated() const { return IsPreallocated; }
	void setPreallocated() { IsPreallocated = 1; }

	bool isSwiftSelf() const { return IsSwiftSelf; }
	void setSwiftSelf() { IsSwiftSelf = 1; }

	bool isSwiftAsync() const { return IsSwiftAsync; }
	void setSwiftAsync() { IsSwiftAsync = 1; }

	bool isSwiftError() const { return IsSwiftError; }
	void setSwiftError() { IsSwiftError = 1; }

	bool isCFGuardTarget() const { return IsCFGuardTarget; }
	void setCFGuardTarget() { IsCFGuardTarget = 1; }

	bool isHva() const { return IsHva; }
	void setHva() { IsHva = 1; }

	bool isHvaStart() const { return IsHvaStart; }
	void setHvaStart() { IsHvaStart = 1; }

	bool isSecArgPass() const { return IsSecArgPass; }
	void setSecArgPass() { IsSecArgPass = 1; }

	bool isNest() const { return IsNest; }
	void setNest() { IsNest = 1; }

	bool isReturned() const { return IsReturned; }
	void setReturned(bool V = true) { IsReturned = V; }

	bool isInConsecutiveRegs() const { return IsInConsecutiveRegs; }
	void setInConsecutiveRegs(bool Flag = true) { IsInConsecutiveRegs = Flag; }

	bool isInConsecutiveRegsLast() const { return IsInConsecutiveRegsLast; }
	void setInConsecutiveRegsLast(bool Flag = true) {
	IsInConsecutiveRegsLast = Flag;
	}

	bool isSplit() const { return IsSplit; }
	void setSplit() { IsSplit = 1; }

	bool isSplitEnd() const { return IsSplitEnd; }
	void setSplitEnd() { IsSplitEnd = 1; }

	bool isCopyElisionCandidate() const { return IsCopyElisionCandidate; }
	void setCopyElisionCandidate() { IsCopyElisionCandidate = 1; }

	bool isPointer() const { return IsPointer; }
	void setPointer() { IsPointer = 1; }

	Align getNonZeroMemAlign() const {
	return decodeMaybeAlign(MemAlign).valueOrOne();
	}

	void setMemAlign(Align A) {
	MemAlign = encode(A);
	assert(getNonZeroMemAlign() == A && "bitfield overflow");
	}

	Align getNonZeroByValAlign() const {
	assert(isByVal());
	MaybeAlign A = decodeMaybeAlign(MemAlign);
	assert(A && "ByValAlign must be defined");
	return *A;
	}

	Align getNonZeroOrigAlign() const {
	return decodeMaybeAlign(OrigAlign).valueOrOne();
	}

	void setOrigAlign(Align A) {
	OrigAlign = encode(A);
	assert(getNonZeroOrigAlign() == A && "bitfield overflow");
	}

	unsigned getByValSize() const {
	assert(isByVal() && !isByRef());
	return ByValOrByRefSize;
	}
	void setByValSize(unsigned S) {
	assert(isByVal() && !isByRef());
	ByValOrByRefSize = S;
	}

	unsigned getByRefSize() const {
	assert(!isByVal() && isByRef());
	return ByValOrByRefSize;
	}
	void setByRefSize(unsigned S) {
	assert(!isByVal() && isByRef());
	ByValOrByRefSize = S;
	}

	unsigned getPointerAddrSpace() const { return PointerAddrSpace; }
	void setPointerAddrSpace(unsigned AS) { PointerAddrSpace = AS; }
	};

	/// InputArg - This struct carries flags and type information about a
	/// single incoming (formal) argument or incoming (from the perspective
	/// of the caller) return value virtual register.
	///
	struct InputArg {
	ArgFlagsTy Flags;
	MVT VT = MVT::Other;
	EVT ArgVT;
	bool Used = false;

	/// Index original Function's argument.
	unsigned OrigArgIndex;
	/// Sentinel value for implicit machine-level input arguments.
	static const unsigned NoArgIndex = UINT_MAX;

	/// Offset in bytes of current input value relative to the beginning of
	/// original argument. E.g. if argument was splitted into four 32 bit
	/// registers, we got 4 InputArgs with PartOffsets 0, 4, 8 and 12.
	unsigned PartOffset;

	InputArg() = default;
	InputArg(ArgFlagsTy flags, EVT vt, EVT argvt, bool used,
	unsigned origIdx, unsigned partOffs)
	: Flags(flags), Used(used), OrigArgIndex(origIdx), PartOffset(partOffs) {
	VT = vt.getSimpleVT();
	ArgVT = argvt;
	}

	bool isOrigArg() const {
	return OrigArgIndex != NoArgIndex;
	}

	unsigned getOrigArgIndex() const {
	assert(OrigArgIndex != NoArgIndex && "Implicit machine-level argument");
	return OrigArgIndex;
	}
	};

	/// OutputArg - This struct carries flags and a value for a
	/// single outgoing (actual) argument or outgoing (from the perspective
	/// of the caller) return value virtual register.
	///
	struct OutputArg {
	ArgFlagsTy Flags;
	MVT VT;
	EVT ArgVT;

	/// IsFixed - Is this a "fixed" value, ie not passed through a vararg "...".
	bool IsFixed = false;

	/// Index original Function's argument.
	unsigned OrigArgIndex;

	/// Offset in bytes of current output value relative to the beginning of
	/// original argument. E.g. if argument was splitted into four 32 bit
	/// registers, we got 4 OutputArgs with PartOffsets 0, 4, 8 and 12.
	unsigned PartOffset;

	OutputArg() = default;
	OutputArg(ArgFlagsTy flags, MVT vt, EVT argvt, bool isfixed,
	unsigned origIdx, unsigned partOffs)
	: Flags(flags), IsFixed(isfixed), OrigArgIndex(origIdx),
	PartOffset(partOffs) {
	VT = vt;
	ArgVT = argvt;
	}
	};

	} // end namespace ISD
	} // end namespace llvm

	#endif // LLVM_CODEGEN_TARGETCALLINGCONV_H