test/TableGen/GlobalISelEmitter-multiple-output.td - llvm-project/llvm - Git at Google

 // RUN: llvm-tblgen -gen-global-isel -optimize-match-table=false -warn-on-skipped-patterns -I %p/../../include -I %p/Common %s -o - < %s | FileCheck %s

 include "llvm/Target/Target.td"
 include "GlobalISelEmitterCommon.td"

 // Test the generation of patterns with multiple output operands and makes sure that
 // we are able to create a new instruction if necessary, or just simply change the
 // opcode if the input and output operands of the generic instruction are the same
 // as the target-specific instruction

 // Verify that patterns with multiple outputs are translated

 // Test where only the opcode is mutated during ISel

 let Constraints = "$ptr_out = $addr" in
 def LDPost : I<(outs GPR32:$val, GPR32:$ptr_out), (ins GPR32:$addr, GPR32:$off), []>;
 def SDTLoadPost : SDTypeProfile<2, 2, [
   SDTCisInt<0>, SDTCisSameAs<1,2>, SDTCisPtrTy<2>, SDTCisInt<3>,
 ]>;
 def loadpost : SDNode<"MyTgt::LOADPOST", SDTLoadPost, [
   SDNPHasChain, SDNPMayLoad, SDNPMemOperand
 ]>;
 def G_POST_LOAD : MyTargetGenericInstruction{
   let OutOperandList = (outs type0:$val, type1:$ptr_out);
   let InOperandList = (ins type1:$ptr, type2:$off);
 }
 def : GINodeEquiv<G_POST_LOAD, loadpost>;
 def : Pat<(loadpost (p0 GPR32:$addr), (i32 GPR32:$off)),
   (LDPost GPR32:$addr, GPR32:$off)
 >;

 // CHECK:      GIM_CheckOpcode, /*MI*/0, MyTarget::G_POST_LOAD,
 // CHECK-NEXT: // MIs[0] val
 // CHECK-NEXT: GIM_CheckType, /*MI*/0, /*Op*/0, /*Type*/GILLT_s32,
 // CHECK-NEXT: GIM_CheckRegBankForClass, /*MI*/0, /*Op*/0, /*RC*/MyTarget::GPR32RegClassID,
 // CHECK-NEXT: // MIs[0] ptr_out
 // CHECK-NEXT: GIM_CheckType, /*MI*/0, /*Op*/1, /*Type*/GILLT_p0s32,
 // CHECK-NEXT: GIM_CheckRegBankForClass, /*MI*/0, /*Op*/1, /*RC*/MyTarget::GPR32RegClassID,
 // CHECK-NEXT: // MIs[0] addr
 // CHECK-NEXT: GIM_CheckType, /*MI*/0, /*Op*/2, /*Type*/GILLT_p0s32,
 // CHECK-NEXT: GIM_CheckRegBankForClass, /*MI*/0, /*Op*/2, /*RC*/MyTarget::GPR32RegClassID,
 // CHECK-NEXT: // MIs[0] off
 // CHECK-NEXT: GIM_CheckType, /*MI*/0, /*Op*/3, /*Type*/GILLT_s32,
 // CHECK-NEXT: GIM_CheckRegBankForClass, /*MI*/0, /*Op*/3, /*RC*/MyTarget::GPR32RegClassID,
 // CHECK-NEXT: // (loadpost:{ *:[i32] }:{ *:[i32] } GPR32:{ *:[i32] }:$addr, GPR32:{ *:[i32] }:$off)  =>  (LDPost:{ *:[i32] }:{ *:[i32] } GPR32:{ *:[i32] }:$addr, GPR32:{ *:[i32] }:$off)
 // CHECK-NEXT: GIR_MutateOpcode, /*InsnID*/0, /*RecycleInsnID*/0, /*Opcode*/MyTarget::LDPost,
 // CHECK-NEXT: GIR_ConstrainSelectedInstOperands, /*InsnID*/0,

 // Test where a whole new MIR instruction is created during ISel

 def TWO_INS : I<(outs GPR32:$out1, GPR32:$out2), (ins GPR32:$in1, GPR32:$in2), []>;

 def SDTTwoIn : SDTypeProfile<2, 2, [
   SDTCisInt<0>, SDTCisInt<1>, SDTCisInt<2>, SDTCisInt<3>
 ]>;
 def two_in : SDNode<"MyTgt::TWO_IN", SDTTwoIn, []>;
 def G_TWO_IN : MyTargetGenericInstruction{
   let OutOperandList = (outs type0:$out1, type0:$out2);
   let InOperandList = (ins type0:$in1, type0:$in2);
 }
 def : GINodeEquiv<G_TWO_IN, two_in>;

 // Swap the input operands for an easy way to force the creation of a new instruction
 def : Pat<(two_in GPR32:$i1, GPR32:$i2), (TWO_INS GPR32:$i2, GPR32:$i1)>;

 // CHECK:      GIM_CheckOpcode, /*MI*/0, MyTarget::G_TWO_IN,
 // CHECK-NEXT: // MIs[0] out1
 // CHECK-NEXT: GIM_CheckType, /*MI*/0, /*Op*/0, /*Type*/GILLT_s32,
 // CHECK-NEXT: GIM_CheckRegBankForClass, /*MI*/0, /*Op*/0, /*RC*/MyTarget::GPR32RegClassID,
 // CHECK-NEXT: // MIs[0] out2
 // CHECK-NEXT: GIM_CheckType, /*MI*/0, /*Op*/1, /*Type*/GILLT_s32,
 // CHECK-NEXT: GIM_CheckRegBankForClass, /*MI*/0, /*Op*/1, /*RC*/MyTarget::GPR32RegClassID,
 // CHECK-NEXT: // MIs[0] i1
 // CHECK-NEXT: GIM_CheckType, /*MI*/0, /*Op*/2, /*Type*/GILLT_s32,
 // CHECK-NEXT: GIM_CheckRegBankForClass, /*MI*/0, /*Op*/2, /*RC*/MyTarget::GPR32RegClassID,
 // CHECK-NEXT: // MIs[0] i2
 // CHECK-NEXT: GIM_CheckType, /*MI*/0, /*Op*/3, /*Type*/GILLT_s32,
 // CHECK-NEXT: GIM_CheckRegBankForClass, /*MI*/0, /*Op*/3, /*RC*/MyTarget::GPR32RegClassID,
 // CHECK-NEXT: // (two_in:{ *:[i32] }:{ *:[i32] } GPR32:{ *:[i32] }:$i1, GPR32:{ *:[i32] }:$i2)  =>  (TWO_INS:{ *:[i32] }:{ *:[i32] } GPR32:{ *:[i32] }:$i2, GPR32:{ *:[i32] }:$i1)
 // CHECK-NEXT: GIR_BuildMI, /*InsnID*/0, /*Opcode*/MyTarget::TWO_INS,
 // CHECK-NEXT: GIR_Copy, /*NewInsnID*/0, /*OldInsnID*/0, /*OpIdx*/0, // out1
 // CHECK-NEXT: GIR_Copy, /*NewInsnID*/0, /*OldInsnID*/0, /*OpIdx*/1, // out2
 // CHECK-NEXT: GIR_Copy, /*NewInsnID*/0, /*OldInsnID*/0, /*OpIdx*/3, // i2
 // CHECK-NEXT: GIR_Copy, /*NewInsnID*/0, /*OldInsnID*/0, /*OpIdx*/2, // i1
 // CHECK-NEXT: GIR_EraseFromParent, /*InsnID*/0,
 // CHECK-NEXT: GIR_ConstrainSelectedInstOperands, /*InsnID*/0,
	// RUN: llvm-tblgen -gen-global-isel -optimize-match-table=false -warn-on-skipped-patterns -I %p/../../include -I %p/Common %s -o - < %s \| FileCheck %s

	include "llvm/Target/Target.td"
	include "GlobalISelEmitterCommon.td"

	// Test the generation of patterns with multiple output operands and makes sure that
	// we are able to create a new instruction if necessary, or just simply change the
	// opcode if the input and output operands of the generic instruction are the same
	// as the target-specific instruction

	// Verify that patterns with multiple outputs are translated

	// Test where only the opcode is mutated during ISel

	let Constraints = "$ptr_out = $addr" in
	def LDPost : I<(outs GPR32:$val, GPR32:$ptr_out), (ins GPR32:$addr, GPR32:$off), []>;
	def SDTLoadPost : SDTypeProfile<2, 2, [
	SDTCisInt<0>, SDTCisSameAs<1,2>, SDTCisPtrTy<2>, SDTCisInt<3>,
	]>;
	def loadpost : SDNode<"MyTgt::LOADPOST", SDTLoadPost, [
	SDNPHasChain, SDNPMayLoad, SDNPMemOperand
	]>;
	def G_POST_LOAD : MyTargetGenericInstruction{
	let OutOperandList = (outs type0:$val, type1:$ptr_out);
	let InOperandList = (ins type1:$ptr, type2:$off);
	}
	def : GINodeEquiv<G_POST_LOAD, loadpost>;
	def : Pat<(loadpost (p0 GPR32:$addr), (i32 GPR32:$off)),
	(LDPost GPR32:$addr, GPR32:$off)
	>;

	// CHECK: GIM_CheckOpcode, /MI/0, MyTarget::G_POST_LOAD,
	// CHECK-NEXT: // MIs[0] val
	// CHECK-NEXT: GIM_CheckType, /MI/0, /Op/0, /Type/GILLT_s32,
	// CHECK-NEXT: GIM_CheckRegBankForClass, /MI/0, /Op/0, /RC/MyTarget::GPR32RegClassID,
	// CHECK-NEXT: // MIs[0] ptr_out
	// CHECK-NEXT: GIM_CheckType, /MI/0, /Op/1, /Type/GILLT_p0s32,
	// CHECK-NEXT: GIM_CheckRegBankForClass, /MI/0, /Op/1, /RC/MyTarget::GPR32RegClassID,
	// CHECK-NEXT: // MIs[0] addr
	// CHECK-NEXT: GIM_CheckType, /MI/0, /Op/2, /Type/GILLT_p0s32,
	// CHECK-NEXT: GIM_CheckRegBankForClass, /MI/0, /Op/2, /RC/MyTarget::GPR32RegClassID,
	// CHECK-NEXT: // MIs[0] off
	// CHECK-NEXT: GIM_CheckType, /MI/0, /Op/3, /Type/GILLT_s32,
	// CHECK-NEXT: GIM_CheckRegBankForClass, /MI/0, /Op/3, /RC/MyTarget::GPR32RegClassID,
	// CHECK-NEXT: // (loadpost:{ :[i32] }:{ :[i32] } GPR32:{ :[i32] }:$addr, GPR32:{ :[i32] }:$off) => (LDPost:{ :[i32] }:{ :[i32] } GPR32:{ :[i32] }:$addr, GPR32:{ :[i32] }:$off)
	// CHECK-NEXT: GIR_MutateOpcode, /InsnID/0, /RecycleInsnID/0, /Opcode/MyTarget::LDPost,
	// CHECK-NEXT: GIR_ConstrainSelectedInstOperands, /InsnID/0,

	// Test where a whole new MIR instruction is created during ISel

	def TWO_INS : I<(outs GPR32:$out1, GPR32:$out2), (ins GPR32:$in1, GPR32:$in2), []>;

	def SDTTwoIn : SDTypeProfile<2, 2, [
	SDTCisInt<0>, SDTCisInt<1>, SDTCisInt<2>, SDTCisInt<3>
	]>;
	def two_in : SDNode<"MyTgt::TWO_IN", SDTTwoIn, []>;
	def G_TWO_IN : MyTargetGenericInstruction{
	let OutOperandList = (outs type0:$out1, type0:$out2);
	let InOperandList = (ins type0:$in1, type0:$in2);
	}
	def : GINodeEquiv<G_TWO_IN, two_in>;

	// Swap the input operands for an easy way to force the creation of a new instruction
	def : Pat<(two_in GPR32:$i1, GPR32:$i2), (TWO_INS GPR32:$i2, GPR32:$i1)>;

	// CHECK: GIM_CheckOpcode, /MI/0, MyTarget::G_TWO_IN,
	// CHECK-NEXT: // MIs[0] out1
	// CHECK-NEXT: GIM_CheckType, /MI/0, /Op/0, /Type/GILLT_s32,
	// CHECK-NEXT: GIM_CheckRegBankForClass, /MI/0, /Op/0, /RC/MyTarget::GPR32RegClassID,
	// CHECK-NEXT: // MIs[0] out2
	// CHECK-NEXT: GIM_CheckType, /MI/0, /Op/1, /Type/GILLT_s32,
	// CHECK-NEXT: GIM_CheckRegBankForClass, /MI/0, /Op/1, /RC/MyTarget::GPR32RegClassID,
	// CHECK-NEXT: // MIs[0] i1
	// CHECK-NEXT: GIM_CheckType, /MI/0, /Op/2, /Type/GILLT_s32,
	// CHECK-NEXT: GIM_CheckRegBankForClass, /MI/0, /Op/2, /RC/MyTarget::GPR32RegClassID,
	// CHECK-NEXT: // MIs[0] i2
	// CHECK-NEXT: GIM_CheckType, /MI/0, /Op/3, /Type/GILLT_s32,
	// CHECK-NEXT: GIM_CheckRegBankForClass, /MI/0, /Op/3, /RC/MyTarget::GPR32RegClassID,
	// CHECK-NEXT: // (two_in:{ :[i32] }:{ :[i32] } GPR32:{ :[i32] }:$i1, GPR32:{ :[i32] }:$i2) => (TWO_INS:{ :[i32] }:{ :[i32] } GPR32:{ :[i32] }:$i2, GPR32:{ :[i32] }:$i1)
	// CHECK-NEXT: GIR_BuildMI, /InsnID/0, /Opcode/MyTarget::TWO_INS,
	// CHECK-NEXT: GIR_Copy, /NewInsnID/0, /OldInsnID/0, /OpIdx/0, // out1
	// CHECK-NEXT: GIR_Copy, /NewInsnID/0, /OldInsnID/0, /OpIdx/1, // out2
	// CHECK-NEXT: GIR_Copy, /NewInsnID/0, /OldInsnID/0, /OpIdx/3, // i2
	// CHECK-NEXT: GIR_Copy, /NewInsnID/0, /OldInsnID/0, /OpIdx/2, // i1
	// CHECK-NEXT: GIR_EraseFromParent, /InsnID/0,
	// CHECK-NEXT: GIR_ConstrainSelectedInstOperands, /InsnID/0,