clang-r353983c/include/llvm/Target/TargetCallingConv.td - platform/prebuilts/clang/host/darwin-x86 - Git at Google

 //===- TargetCallingConv.td - Target Calling Conventions ---*- tablegen -*-===//
 //
 // 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 the target-independent interfaces with which targets
 // describe their calling conventions.
 //
 //===----------------------------------------------------------------------===//

 class CCAction;
 class CallingConv;

 /// CCCustom - Calls a custom arg handling function.
 class CCCustom<string fn> : CCAction {
   string FuncName = fn;
 }

 /// CCPredicateAction - Instances of this class check some predicate, then
 /// delegate to another action if the predicate is true.
 class CCPredicateAction<CCAction A> : CCAction {
   CCAction SubAction = A;
 }

 /// CCIfType - If the current argument is one of the specified types, apply
 /// Action A.
 class CCIfType<list<ValueType> vts, CCAction A> : CCPredicateAction<A> {
   list<ValueType> VTs = vts;
 }

 /// CCIf - If the predicate matches, apply A.
 class CCIf<string predicate, CCAction A> : CCPredicateAction<A> {
   string Predicate = predicate;
 }

 /// CCIfByVal - If the current argument has ByVal parameter attribute, apply
 /// Action A.
 class CCIfByVal<CCAction A> : CCIf<"ArgFlags.isByVal()", A> {
 }

 /// CCIfSwiftSelf - If the current argument has swiftself parameter attribute,
 /// apply Action A.
 class CCIfSwiftSelf<CCAction A> : CCIf<"ArgFlags.isSwiftSelf()", A> {
 }

 /// CCIfSwiftError - If the current argument has swifterror parameter attribute,
 /// apply Action A.
 class CCIfSwiftError<CCAction A> : CCIf<"ArgFlags.isSwiftError()", A> {
 }

 /// CCIfConsecutiveRegs - If the current argument has InConsecutiveRegs
 /// parameter attribute, apply Action A.
 class CCIfConsecutiveRegs<CCAction A> : CCIf<"ArgFlags.isInConsecutiveRegs()", A> {
 }

 /// CCIfCC - Match if the current calling convention is 'CC'.
 class CCIfCC<string CC, CCAction A>
   : CCIf<!strconcat("State.getCallingConv() == ", CC), A> {}

 /// CCIfInReg - If this argument is marked with the 'inreg' attribute, apply
 /// the specified action.
 class CCIfInReg<CCAction A> : CCIf<"ArgFlags.isInReg()", A> {}

 /// CCIfNest - If this argument is marked with the 'nest' attribute, apply
 /// the specified action.
 class CCIfNest<CCAction A> : CCIf<"ArgFlags.isNest()", A> {}

 /// CCIfSplit - If this argument is marked with the 'split' attribute, apply
 /// the specified action.
 class CCIfSplit<CCAction A> : CCIf<"ArgFlags.isSplit()", A> {}

 /// CCIfSRet - If this argument is marked with the 'sret' attribute, apply
 /// the specified action.
 class CCIfSRet<CCAction A> : CCIf<"ArgFlags.isSRet()", A> {}

 /// CCIfVarArg - If the current function is vararg - apply the action
 class CCIfVarArg<CCAction A> : CCIf<"State.isVarArg()", A> {}

 /// CCIfNotVarArg - If the current function is not vararg - apply the action
 class CCIfNotVarArg<CCAction A> : CCIf<"!State.isVarArg()", A> {}

 /// CCAssignToReg - This action matches if there is a register in the specified
 /// list that is still available.  If so, it assigns the value to the first
 /// available register and succeeds.
 class CCAssignToReg<list<Register> regList> : CCAction {
   list<Register> RegList = regList;
 }

 /// CCAssignToRegWithShadow - Same as CCAssignToReg, but with list of registers
 /// which became shadowed, when some register is used.
 class CCAssignToRegWithShadow<list<Register> regList,
                               list<Register> shadowList> : CCAction {
   list<Register> RegList = regList;
   list<Register> ShadowRegList = shadowList;
 }

 /// CCAssignToStack - This action always matches: it assigns the value to a
 /// stack slot of the specified size and alignment on the stack.  If size is
 /// zero then the ABI size is used; if align is zero then the ABI alignment
 /// is used - these may depend on the target or subtarget.
 class CCAssignToStack<int size, int align> : CCAction {
   int Size = size;
   int Align = align;
 }

 /// CCAssignToStackWithShadow - Same as CCAssignToStack, but with a list of
 /// registers to be shadowed. Note that, unlike CCAssignToRegWithShadow, this
 /// shadows ALL of the registers in shadowList.
 class CCAssignToStackWithShadow<int size,
                                 int align,
                                 list<Register> shadowList> : CCAction {
   int Size = size;
   int Align = align;
   list<Register> ShadowRegList = shadowList;
 }

 /// CCPassByVal - This action always matches: it assigns the value to a stack
 /// slot to implement ByVal aggregate parameter passing. Size and alignment
 /// specify the minimum size and alignment for the stack slot.
 class CCPassByVal<int size, int align> : CCAction {
   int Size = size;
   int Align = align;
 }

 /// CCPromoteToType - If applied, this promotes the specified current value to
 /// the specified type.
 class CCPromoteToType<ValueType destTy> : CCAction {
   ValueType DestTy = destTy;
 }

 /// CCPromoteToUpperBitsInType - If applied, this promotes the specified current
 /// value to the specified type and shifts the value into the upper bits.
 class CCPromoteToUpperBitsInType<ValueType destTy> : CCAction {
   ValueType DestTy = destTy;
 }

 /// CCBitConvertToType - If applied, this bitconverts the specified current
 /// value to the specified type.
 class CCBitConvertToType<ValueType destTy> : CCAction {
   ValueType DestTy = destTy;
 }

 /// CCPassIndirect - If applied, this stores the value to stack and passes the pointer
 /// as normal argument.
 class CCPassIndirect<ValueType destTy> : CCAction {
   ValueType DestTy = destTy;
 }

 /// CCDelegateTo - This action invokes the specified sub-calling-convention.  It
 /// is successful if the specified CC matches.
 class CCDelegateTo<CallingConv cc> : CCAction {
   CallingConv CC = cc;
 }

 /// CallingConv - An instance of this is used to define each calling convention
 /// that the target supports.
 class CallingConv<list<CCAction> actions> {
   list<CCAction> Actions = actions;

   /// If true, this calling convention will be emitted as externally visible in
   /// the llvm namespaces instead of as a static function.
   bit Entry = 0;

   bit Custom = 0;
 }

 /// CustomCallingConv - An instance of this is used to declare calling
 /// conventions that are implemented using a custom function of the same name.
 class CustomCallingConv : CallingConv<[]> {
   let Custom = 1;
 }

 /// CalleeSavedRegs - A list of callee saved registers for a given calling
 /// convention.  The order of registers is used by PrologEpilogInsertion when
 /// allocation stack slots for saved registers.
 ///
 /// For each CalleeSavedRegs def, TableGen will emit a FOO_SaveList array for
 /// returning from getCalleeSavedRegs(), and a FOO_RegMask bit mask suitable for
 /// returning from getCallPreservedMask().
 class CalleeSavedRegs<dag saves> {
   dag SaveList = saves;

   // Registers that are also preserved across function calls, but should not be
   // included in the generated FOO_SaveList array. These registers will be
   // included in the FOO_RegMask bit mask. This can be used for registers that
   // are saved automatically, like the SPARC register windows.
   dag OtherPreserved;
 }
	//===- TargetCallingConv.td - Target Calling Conventions ---- tablegen --===//
	//
	// 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 the target-independent interfaces with which targets
	// describe their calling conventions.
	//
	//===----------------------------------------------------------------------===//

	class CCAction;
	class CallingConv;

	/// CCCustom - Calls a custom arg handling function.
	class CCCustom<string fn> : CCAction {
	string FuncName = fn;
	}

	/// CCPredicateAction - Instances of this class check some predicate, then
	/// delegate to another action if the predicate is true.
	class CCPredicateAction<CCAction A> : CCAction {
	CCAction SubAction = A;
	}

	/// CCIfType - If the current argument is one of the specified types, apply
	/// Action A.
	class CCIfType<list<ValueType> vts, CCAction A> : CCPredicateAction<A> {
	list<ValueType> VTs = vts;
	}

	/// CCIf - If the predicate matches, apply A.
	class CCIf<string predicate, CCAction A> : CCPredicateAction<A> {
	string Predicate = predicate;
	}

	/// CCIfByVal - If the current argument has ByVal parameter attribute, apply
	/// Action A.
	class CCIfByVal<CCAction A> : CCIf<"ArgFlags.isByVal()", A> {
	}

	/// CCIfSwiftSelf - If the current argument has swiftself parameter attribute,
	/// apply Action A.
	class CCIfSwiftSelf<CCAction A> : CCIf<"ArgFlags.isSwiftSelf()", A> {
	}

	/// CCIfSwiftError - If the current argument has swifterror parameter attribute,
	/// apply Action A.
	class CCIfSwiftError<CCAction A> : CCIf<"ArgFlags.isSwiftError()", A> {
	}

	/// CCIfConsecutiveRegs - If the current argument has InConsecutiveRegs
	/// parameter attribute, apply Action A.
	class CCIfConsecutiveRegs<CCAction A> : CCIf<"ArgFlags.isInConsecutiveRegs()", A> {
	}

	/// CCIfCC - Match if the current calling convention is 'CC'.
	class CCIfCC<string CC, CCAction A>
	: CCIf<!strconcat("State.getCallingConv() == ", CC), A> {}

	/// CCIfInReg - If this argument is marked with the 'inreg' attribute, apply
	/// the specified action.
	class CCIfInReg<CCAction A> : CCIf<"ArgFlags.isInReg()", A> {}

	/// CCIfNest - If this argument is marked with the 'nest' attribute, apply
	/// the specified action.
	class CCIfNest<CCAction A> : CCIf<"ArgFlags.isNest()", A> {}

	/// CCIfSplit - If this argument is marked with the 'split' attribute, apply
	/// the specified action.
	class CCIfSplit<CCAction A> : CCIf<"ArgFlags.isSplit()", A> {}

	/// CCIfSRet - If this argument is marked with the 'sret' attribute, apply
	/// the specified action.
	class CCIfSRet<CCAction A> : CCIf<"ArgFlags.isSRet()", A> {}

	/// CCIfVarArg - If the current function is vararg - apply the action
	class CCIfVarArg<CCAction A> : CCIf<"State.isVarArg()", A> {}

	/// CCIfNotVarArg - If the current function is not vararg - apply the action
	class CCIfNotVarArg<CCAction A> : CCIf<"!State.isVarArg()", A> {}

	/// CCAssignToReg - This action matches if there is a register in the specified
	/// list that is still available. If so, it assigns the value to the first
	/// available register and succeeds.
	class CCAssignToReg<list<Register> regList> : CCAction {
	list<Register> RegList = regList;
	}

	/// CCAssignToRegWithShadow - Same as CCAssignToReg, but with list of registers
	/// which became shadowed, when some register is used.
	class CCAssignToRegWithShadow<list<Register> regList,
	list<Register> shadowList> : CCAction {
	list<Register> RegList = regList;
	list<Register> ShadowRegList = shadowList;
	}

	/// CCAssignToStack - This action always matches: it assigns the value to a
	/// stack slot of the specified size and alignment on the stack. If size is
	/// zero then the ABI size is used; if align is zero then the ABI alignment
	/// is used - these may depend on the target or subtarget.
	class CCAssignToStack<int size, int align> : CCAction {
	int Size = size;
	int Align = align;
	}

	/// CCAssignToStackWithShadow - Same as CCAssignToStack, but with a list of
	/// registers to be shadowed. Note that, unlike CCAssignToRegWithShadow, this
	/// shadows ALL of the registers in shadowList.
	class CCAssignToStackWithShadow<int size,
	int align,
	list<Register> shadowList> : CCAction {
	int Size = size;
	int Align = align;
	list<Register> ShadowRegList = shadowList;
	}

	/// CCPassByVal - This action always matches: it assigns the value to a stack
	/// slot to implement ByVal aggregate parameter passing. Size and alignment
	/// specify the minimum size and alignment for the stack slot.
	class CCPassByVal<int size, int align> : CCAction {
	int Size = size;
	int Align = align;
	}

	/// CCPromoteToType - If applied, this promotes the specified current value to
	/// the specified type.
	class CCPromoteToType<ValueType destTy> : CCAction {
	ValueType DestTy = destTy;
	}

	/// CCPromoteToUpperBitsInType - If applied, this promotes the specified current
	/// value to the specified type and shifts the value into the upper bits.
	class CCPromoteToUpperBitsInType<ValueType destTy> : CCAction {
	ValueType DestTy = destTy;
	}

	/// CCBitConvertToType - If applied, this bitconverts the specified current
	/// value to the specified type.
	class CCBitConvertToType<ValueType destTy> : CCAction {
	ValueType DestTy = destTy;
	}

	/// CCPassIndirect - If applied, this stores the value to stack and passes the pointer
	/// as normal argument.
	class CCPassIndirect<ValueType destTy> : CCAction {
	ValueType DestTy = destTy;
	}

	/// CCDelegateTo - This action invokes the specified sub-calling-convention. It
	/// is successful if the specified CC matches.
	class CCDelegateTo<CallingConv cc> : CCAction {
	CallingConv CC = cc;
	}

	/// CallingConv - An instance of this is used to define each calling convention
	/// that the target supports.
	class CallingConv<list<CCAction> actions> {
	list<CCAction> Actions = actions;

	/// If true, this calling convention will be emitted as externally visible in
	/// the llvm namespaces instead of as a static function.
	bit Entry = 0;

	bit Custom = 0;
	}

	/// CustomCallingConv - An instance of this is used to declare calling
	/// conventions that are implemented using a custom function of the same name.
	class CustomCallingConv : CallingConv<[]> {
	let Custom = 1;
	}

	/// CalleeSavedRegs - A list of callee saved registers for a given calling
	/// convention. The order of registers is used by PrologEpilogInsertion when
	/// allocation stack slots for saved registers.
	///
	/// For each CalleeSavedRegs def, TableGen will emit a FOO_SaveList array for
	/// returning from getCalleeSavedRegs(), and a FOO_RegMask bit mask suitable for
	/// returning from getCallPreservedMask().
	class CalleeSavedRegs<dag saves> {
	dag SaveList = saves;

	// Registers that are also preserved across function calls, but should not be
	// included in the generated FOO_SaveList array. These registers will be
	// included in the FOO_RegMask bit mask. This can be used for registers that
	// are saved automatically, like the SPARC register windows.
	dag OtherPreserved;
	}