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

 //===- TargetGlobalISel.td - Common code for GlobalISel ----*- 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 used to support
 // SelectionDAG instruction selection patterns (specified in
 // TargetSelectionDAG.td) when generating GlobalISel instruction selectors.
 //
 // This is intended as a compatibility layer, to enable reuse of target
 // descriptions written for SelectionDAG without requiring explicit GlobalISel
 // support.  It will eventually supersede SelectionDAG patterns.
 //
 //===----------------------------------------------------------------------===//

 // Declare that a generic Instruction is 'equivalent' to an SDNode, that is,
 // SelectionDAG patterns involving the SDNode can be transformed to match the
 // Instruction instead.
 class GINodeEquiv<Instruction i, SDNode node> {
   Instruction I = i;
   SDNode Node = node;

   // SelectionDAG has separate nodes for atomic and non-atomic memory operations
   // (ISD::LOAD, ISD::ATOMIC_LOAD, ISD::STORE, ISD::ATOMIC_STORE) but GlobalISel
   // stores this information in the MachineMemoryOperand.
   bit CheckMMOIsNonAtomic = 0;

   // SelectionDAG has one node for all loads and uses predicates to
   // differentiate them. GlobalISel on the other hand uses separate opcodes.
   // When this is true, the resulting opcode is G_LOAD/G_SEXTLOAD/G_ZEXTLOAD
   // depending on the predicates on the node.
   Instruction IfSignExtend = ?;
   Instruction IfZeroExtend = ?;
 }

 // These are defined in the same order as the G_* instructions.
 def : GINodeEquiv<G_ANYEXT, anyext>;
 def : GINodeEquiv<G_SEXT, sext>;
 def : GINodeEquiv<G_ZEXT, zext>;
 def : GINodeEquiv<G_TRUNC, trunc>;
 def : GINodeEquiv<G_BITCAST, bitconvert>;
 // G_INTTOPTR - SelectionDAG has no equivalent.
 // G_PTRTOINT - SelectionDAG has no equivalent.
 def : GINodeEquiv<G_CONSTANT, imm>;
 def : GINodeEquiv<G_FCONSTANT, fpimm>;
 def : GINodeEquiv<G_ADD, add>;
 def : GINodeEquiv<G_SUB, sub>;
 def : GINodeEquiv<G_MUL, mul>;
 def : GINodeEquiv<G_SDIV, sdiv>;
 def : GINodeEquiv<G_UDIV, udiv>;
 def : GINodeEquiv<G_SREM, srem>;
 def : GINodeEquiv<G_UREM, urem>;
 def : GINodeEquiv<G_AND, and>;
 def : GINodeEquiv<G_OR, or>;
 def : GINodeEquiv<G_XOR, xor>;
 def : GINodeEquiv<G_SHL, shl>;
 def : GINodeEquiv<G_LSHR, srl>;
 def : GINodeEquiv<G_ASHR, sra>;
 def : GINodeEquiv<G_SELECT, select>;
 def : GINodeEquiv<G_FNEG, fneg>;
 def : GINodeEquiv<G_FPEXT, fpextend>;
 def : GINodeEquiv<G_FPTRUNC, fpround>;
 def : GINodeEquiv<G_FPTOSI, fp_to_sint>;
 def : GINodeEquiv<G_FPTOUI, fp_to_uint>;
 def : GINodeEquiv<G_SITOFP, sint_to_fp>;
 def : GINodeEquiv<G_UITOFP, uint_to_fp>;
 def : GINodeEquiv<G_FADD, fadd>;
 def : GINodeEquiv<G_FSUB, fsub>;
 def : GINodeEquiv<G_FMA, fma>;
 def : GINodeEquiv<G_FMUL, fmul>;
 def : GINodeEquiv<G_FDIV, fdiv>;
 def : GINodeEquiv<G_FREM, frem>;
 def : GINodeEquiv<G_FPOW, fpow>;
 def : GINodeEquiv<G_FEXP2, fexp2>;
 def : GINodeEquiv<G_FLOG2, flog2>;
 def : GINodeEquiv<G_INTRINSIC, intrinsic_wo_chain>;
 // ISD::INTRINSIC_VOID can also be handled with G_INTRINSIC_W_SIDE_EFFECTS.
 def : GINodeEquiv<G_INTRINSIC_W_SIDE_EFFECTS, intrinsic_void>;
 def : GINodeEquiv<G_INTRINSIC_W_SIDE_EFFECTS, intrinsic_w_chain>;
 def : GINodeEquiv<G_BR, br>;
 def : GINodeEquiv<G_BSWAP, bswap>;
 def : GINodeEquiv<G_CTLZ, ctlz>;
 def : GINodeEquiv<G_CTTZ, cttz>;
 def : GINodeEquiv<G_CTLZ_ZERO_UNDEF, ctlz_zero_undef>;
 def : GINodeEquiv<G_CTTZ_ZERO_UNDEF, cttz_zero_undef>;
 def : GINodeEquiv<G_CTPOP, ctpop>;
 def : GINodeEquiv<G_EXTRACT_VECTOR_ELT, vector_extract>;
 def : GINodeEquiv<G_FCEIL, fceil>;
 def : GINodeEquiv<G_FCOS, fcos>;
 def : GINodeEquiv<G_FSIN, fsin>;
 def : GINodeEquiv<G_FABS, fabs>;
 def : GINodeEquiv<G_FSQRT, fsqrt>;
 def : GINodeEquiv<G_FFLOOR, ffloor>;

 // Broadly speaking G_LOAD is equivalent to ISD::LOAD but there are some
 // complications that tablegen must take care of. For example, Predicates such
 // as isSignExtLoad require that this is not a perfect 1:1 mapping since a
 // sign-extending load is (G_SEXTLOAD x) in GlobalISel. Additionally,
 // G_LOAD handles both atomic and non-atomic loads where as SelectionDAG had
 // separate nodes for them. This GINodeEquiv maps the non-atomic loads to
 // G_LOAD with a non-atomic MachineMemOperand.
 def : GINodeEquiv<G_LOAD, ld> {
   let CheckMMOIsNonAtomic = 1;
   let IfSignExtend = G_SEXTLOAD;
   let IfZeroExtend = G_ZEXTLOAD;
 }
 // Broadly speaking G_STORE is equivalent to ISD::STORE but there are some
 // complications that tablegen must take care of. For example, predicates such
 // as isTruncStore require that this is not a perfect 1:1 mapping since a
 // truncating store is (G_STORE (G_TRUNCATE x)) in GlobalISel. Additionally,
 // G_STORE handles both atomic and non-atomic stores where as SelectionDAG had
 // separate nodes for them. This GINodeEquiv maps the non-atomic stores to
 // G_STORE with a non-atomic MachineMemOperand.
 def : GINodeEquiv<G_STORE, st> { let CheckMMOIsNonAtomic = 1; }

 def : GINodeEquiv<G_ATOMIC_CMPXCHG, atomic_cmp_swap>;
 def : GINodeEquiv<G_ATOMICRMW_XCHG, atomic_swap>;
 def : GINodeEquiv<G_ATOMICRMW_ADD, atomic_load_add>;
 def : GINodeEquiv<G_ATOMICRMW_SUB, atomic_load_sub>;
 def : GINodeEquiv<G_ATOMICRMW_AND, atomic_load_and>;
 def : GINodeEquiv<G_ATOMICRMW_NAND, atomic_load_nand>;
 def : GINodeEquiv<G_ATOMICRMW_OR, atomic_load_or>;
 def : GINodeEquiv<G_ATOMICRMW_XOR, atomic_load_xor>;
 def : GINodeEquiv<G_ATOMICRMW_MIN, atomic_load_min>;
 def : GINodeEquiv<G_ATOMICRMW_MAX, atomic_load_max>;
 def : GINodeEquiv<G_ATOMICRMW_UMIN, atomic_load_umin>;
 def : GINodeEquiv<G_ATOMICRMW_UMAX, atomic_load_umax>;

 // Specifies the GlobalISel equivalents for SelectionDAG's ComplexPattern.
 // Should be used on defs that subclass GIComplexOperandMatcher<>.
 class GIComplexPatternEquiv<ComplexPattern seldag> {
   ComplexPattern SelDAGEquivalent = seldag;
 }

 // Specifies the GlobalISel equivalents for SelectionDAG's SDNodeXForm.
 // Should be used on defs that subclass GICustomOperandRenderer<>.
 class GISDNodeXFormEquiv<SDNodeXForm seldag> {
   SDNodeXForm SelDAGEquivalent = seldag;
 }
	//===- TargetGlobalISel.td - Common code for GlobalISel ----- 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 used to support
	// SelectionDAG instruction selection patterns (specified in
	// TargetSelectionDAG.td) when generating GlobalISel instruction selectors.
	//
	// This is intended as a compatibility layer, to enable reuse of target
	// descriptions written for SelectionDAG without requiring explicit GlobalISel
	// support. It will eventually supersede SelectionDAG patterns.
	//
	//===----------------------------------------------------------------------===//

	// Declare that a generic Instruction is 'equivalent' to an SDNode, that is,
	// SelectionDAG patterns involving the SDNode can be transformed to match the
	// Instruction instead.
	class GINodeEquiv<Instruction i, SDNode node> {
	Instruction I = i;
	SDNode Node = node;

	// SelectionDAG has separate nodes for atomic and non-atomic memory operations
	// (ISD::LOAD, ISD::ATOMIC_LOAD, ISD::STORE, ISD::ATOMIC_STORE) but GlobalISel
	// stores this information in the MachineMemoryOperand.
	bit CheckMMOIsNonAtomic = 0;

	// SelectionDAG has one node for all loads and uses predicates to
	// differentiate them. GlobalISel on the other hand uses separate opcodes.
	// When this is true, the resulting opcode is G_LOAD/G_SEXTLOAD/G_ZEXTLOAD
	// depending on the predicates on the node.
	Instruction IfSignExtend = ?;
	Instruction IfZeroExtend = ?;
	}

	// These are defined in the same order as the G_* instructions.
	def : GINodeEquiv<G_ANYEXT, anyext>;
	def : GINodeEquiv<G_SEXT, sext>;
	def : GINodeEquiv<G_ZEXT, zext>;
	def : GINodeEquiv<G_TRUNC, trunc>;
	def : GINodeEquiv<G_BITCAST, bitconvert>;
	// G_INTTOPTR - SelectionDAG has no equivalent.
	// G_PTRTOINT - SelectionDAG has no equivalent.
	def : GINodeEquiv<G_CONSTANT, imm>;
	def : GINodeEquiv<G_FCONSTANT, fpimm>;
	def : GINodeEquiv<G_ADD, add>;
	def : GINodeEquiv<G_SUB, sub>;
	def : GINodeEquiv<G_MUL, mul>;
	def : GINodeEquiv<G_SDIV, sdiv>;
	def : GINodeEquiv<G_UDIV, udiv>;
	def : GINodeEquiv<G_SREM, srem>;
	def : GINodeEquiv<G_UREM, urem>;
	def : GINodeEquiv<G_AND, and>;
	def : GINodeEquiv<G_OR, or>;
	def : GINodeEquiv<G_XOR, xor>;
	def : GINodeEquiv<G_SHL, shl>;
	def : GINodeEquiv<G_LSHR, srl>;
	def : GINodeEquiv<G_ASHR, sra>;
	def : GINodeEquiv<G_SELECT, select>;
	def : GINodeEquiv<G_FNEG, fneg>;
	def : GINodeEquiv<G_FPEXT, fpextend>;
	def : GINodeEquiv<G_FPTRUNC, fpround>;
	def : GINodeEquiv<G_FPTOSI, fp_to_sint>;
	def : GINodeEquiv<G_FPTOUI, fp_to_uint>;
	def : GINodeEquiv<G_SITOFP, sint_to_fp>;
	def : GINodeEquiv<G_UITOFP, uint_to_fp>;
	def : GINodeEquiv<G_FADD, fadd>;
	def : GINodeEquiv<G_FSUB, fsub>;
	def : GINodeEquiv<G_FMA, fma>;
	def : GINodeEquiv<G_FMUL, fmul>;
	def : GINodeEquiv<G_FDIV, fdiv>;
	def : GINodeEquiv<G_FREM, frem>;
	def : GINodeEquiv<G_FPOW, fpow>;
	def : GINodeEquiv<G_FEXP2, fexp2>;
	def : GINodeEquiv<G_FLOG2, flog2>;
	def : GINodeEquiv<G_INTRINSIC, intrinsic_wo_chain>;
	// ISD::INTRINSIC_VOID can also be handled with G_INTRINSIC_W_SIDE_EFFECTS.
	def : GINodeEquiv<G_INTRINSIC_W_SIDE_EFFECTS, intrinsic_void>;
	def : GINodeEquiv<G_INTRINSIC_W_SIDE_EFFECTS, intrinsic_w_chain>;
	def : GINodeEquiv<G_BR, br>;
	def : GINodeEquiv<G_BSWAP, bswap>;
	def : GINodeEquiv<G_CTLZ, ctlz>;
	def : GINodeEquiv<G_CTTZ, cttz>;
	def : GINodeEquiv<G_CTLZ_ZERO_UNDEF, ctlz_zero_undef>;
	def : GINodeEquiv<G_CTTZ_ZERO_UNDEF, cttz_zero_undef>;
	def : GINodeEquiv<G_CTPOP, ctpop>;
	def : GINodeEquiv<G_EXTRACT_VECTOR_ELT, vector_extract>;
	def : GINodeEquiv<G_FCEIL, fceil>;
	def : GINodeEquiv<G_FCOS, fcos>;
	def : GINodeEquiv<G_FSIN, fsin>;
	def : GINodeEquiv<G_FABS, fabs>;
	def : GINodeEquiv<G_FSQRT, fsqrt>;
	def : GINodeEquiv<G_FFLOOR, ffloor>;

	// Broadly speaking G_LOAD is equivalent to ISD::LOAD but there are some
	// complications that tablegen must take care of. For example, Predicates such
	// as isSignExtLoad require that this is not a perfect 1:1 mapping since a
	// sign-extending load is (G_SEXTLOAD x) in GlobalISel. Additionally,
	// G_LOAD handles both atomic and non-atomic loads where as SelectionDAG had
	// separate nodes for them. This GINodeEquiv maps the non-atomic loads to
	// G_LOAD with a non-atomic MachineMemOperand.
	def : GINodeEquiv<G_LOAD, ld> {
	let CheckMMOIsNonAtomic = 1;
	let IfSignExtend = G_SEXTLOAD;
	let IfZeroExtend = G_ZEXTLOAD;
	}
	// Broadly speaking G_STORE is equivalent to ISD::STORE but there are some
	// complications that tablegen must take care of. For example, predicates such
	// as isTruncStore require that this is not a perfect 1:1 mapping since a
	// truncating store is (G_STORE (G_TRUNCATE x)) in GlobalISel. Additionally,
	// G_STORE handles both atomic and non-atomic stores where as SelectionDAG had
	// separate nodes for them. This GINodeEquiv maps the non-atomic stores to
	// G_STORE with a non-atomic MachineMemOperand.
	def : GINodeEquiv<G_STORE, st> { let CheckMMOIsNonAtomic = 1; }

	def : GINodeEquiv<G_ATOMIC_CMPXCHG, atomic_cmp_swap>;
	def : GINodeEquiv<G_ATOMICRMW_XCHG, atomic_swap>;
	def : GINodeEquiv<G_ATOMICRMW_ADD, atomic_load_add>;
	def : GINodeEquiv<G_ATOMICRMW_SUB, atomic_load_sub>;
	def : GINodeEquiv<G_ATOMICRMW_AND, atomic_load_and>;
	def : GINodeEquiv<G_ATOMICRMW_NAND, atomic_load_nand>;
	def : GINodeEquiv<G_ATOMICRMW_OR, atomic_load_or>;
	def : GINodeEquiv<G_ATOMICRMW_XOR, atomic_load_xor>;
	def : GINodeEquiv<G_ATOMICRMW_MIN, atomic_load_min>;
	def : GINodeEquiv<G_ATOMICRMW_MAX, atomic_load_max>;
	def : GINodeEquiv<G_ATOMICRMW_UMIN, atomic_load_umin>;
	def : GINodeEquiv<G_ATOMICRMW_UMAX, atomic_load_umax>;

	// Specifies the GlobalISel equivalents for SelectionDAG's ComplexPattern.
	// Should be used on defs that subclass GIComplexOperandMatcher<>.
	class GIComplexPatternEquiv<ComplexPattern seldag> {
	ComplexPattern SelDAGEquivalent = seldag;
	}

	// Specifies the GlobalISel equivalents for SelectionDAG's SDNodeXForm.
	// Should be used on defs that subclass GICustomOperandRenderer<>.
	class GISDNodeXFormEquiv<SDNodeXForm seldag> {
	SDNodeXForm SelDAGEquivalent = seldag;
	}