test/TableGen/GlobalISelEmitterCustomPredicate.td - llvm-project/llvm - Git at Google

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

 // Verify that all MI predicates are enumerated.
 //
 // CHECK: // PatFrag predicates.
 // CHECK-NEXT: enum {
 // CHECK-NEXT:   GICXXPred_MI_Predicate_and_or_pat = GICXXPred_Invalid + 1,
 // CHECK-NEXT:   GICXXPred_MI_Predicate_mul_pat,
 // CHECK-NEXT:   GICXXPred_MI_Predicate_or_oneuse,
 // CHECK-NEXT:   GICXXPred_MI_Predicate_patfrags_test_pat,
 // CHECK-NEXT:   GICXXPred_MI_Predicate_sub3_pat,
 // CHECK-NEXT: };

 // Verify that we emit cases for all MI predicates.
 //
 // CHECK: bool MyTargetInstructionSelector::testMIPredicate_MI(
 // CHECK:    case GICXXPred_MI_Predicate_and_or_pat: {
 // CHECK:      return doesComplexCheck(MI);
 // CHECK:    case GICXXPred_MI_Predicate_mul_pat: {
 // CHECK:      return doesComplexCheck(MI);
 // CHECK:    case GICXXPred_MI_Predicate_or_oneuse: {
 // CHECK:      return MRI.hasOneNonDBGUse(MI.getOperand(0).getReg());
 // CHECK:    case GICXXPred_MI_Predicate_patfrags_test_pat: {
 // CHECK:      return doesComplexCheck(MI);
 // CHECK:    case GICXXPred_MI_Predicate_sub3_pat: {
 // CHECK:      return doesComplexCheck(MI);

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

 // Boilerplate code for setting up some registers with subregs.
 class MyReg<string n, list<Register> subregs = []>
   : Register<n> {
   let SubRegs = subregs;
 }

 class MyClass<int size, list<ValueType> types, dag registers>
   : RegisterClass<"Test", types, size, registers> {
   let Size = size;
 }

 def sub0 : SubRegIndex<16>;
 def sub1 : SubRegIndex<16, 16>;
 def S0 : MyReg<"s0">;
 def S1 : MyReg<"s1">;
 def SRegs : MyClass<16, [i16], (sequence "S%u", 0, 1)>;

 let SubRegIndices = [sub0, sub1] in {
 def D0 : MyReg<"d0", [S0, S1]>;
 }

 def DRegs : MyClass<32, [i32], (sequence "D%u", 0, 0)>;
 def DOP : RegisterOperand<DRegs>;
 def AND_OR : I<(outs DRegs:$dst), (ins DOP:$src0, DOP:$src1, DOP:$src2), []>;
 def MUL_OR : I<(outs DRegs:$dst), (ins DOP:$src0, DOP:$src1, DOP:$src2), []>;

 def or_oneuse : PatFrag<
   (ops node:$x, node:$y),
   (or node:$x, node:$y), [{ return foo(); }]> {
   let GISelPredicateCode = [{
     return MRI.hasOneNonDBGUse(MI.getOperand(0).getReg());
   }];
 }


 // FIXME: GISelPredicateCode ignored if DAG predicate not set.
 def and_or_pat : PatFrag<
   (ops node:$x, node:$y, node:$z),
   (and (or node:$x, node:$y), node:$z), [{ return foo(); }]> {
   let GISelPredicateCode = [{
     return doesComplexCheck(MI);
   }];
   let PredicateCodeUsesOperands = 1;
 }

 // CHECK:      GIM_Try, /*On fail goto*//*Label 0*/ GIMT_Encode4(110), // Rule ID 7 //
 // CHECK-NEXT:   GIM_CheckNumOperands, /*MI*/0, /*Expected*/3,
 // CHECK-NEXT:   GIM_CheckOpcode, /*MI*/0, GIMT_Encode2(TargetOpcode::G_AND),
 // CHECK-NEXT:   // MIs[0] DstI[dst]
 // CHECK-NEXT:   GIM_CheckType, /*MI*/0, /*Op*/0, /*Type*/GILLT_s32,
 // CHECK-NEXT:   GIM_CheckRegBankForClass, /*MI*/0, /*Op*/0, /*RC*/GIMT_Encode2(Test::DRegsRegClassID),
 // CHECK-NEXT:   // MIs[0] src2
 // CHECK-NEXT:   GIM_CheckType, /*MI*/0, /*Op*/1, /*Type*/GILLT_s32,
 // CHECK-NEXT:   GIM_RecordNamedOperand, /*MI*/0, /*Op*/1, /*StoreIdx*/2, // Name : pred:3:z
 // CHECK-NEXT:   GIM_CheckRegBankForClass, /*MI*/0, /*Op*/1, /*RC*/GIMT_Encode2(Test::DRegsRegClassID),
 // CHECK-NEXT:   // MIs[0] Operand 2
 // CHECK-NEXT:   GIM_CheckType, /*MI*/0, /*Op*/2, /*Type*/GILLT_s32,
 // CHECK-NEXT:   GIM_RecordInsn, /*DefineMI*/1, /*MI*/0, /*OpIdx*/2, // MIs[1]
 // CHECK-NEXT:   GIM_CheckNumOperands, /*MI*/1, /*Expected*/3,
 // CHECK-NEXT:   GIM_CheckOpcode, /*MI*/1, GIMT_Encode2(TargetOpcode::G_OR),
 // CHECK-NEXT:   // MIs[1] Operand 0
 // CHECK-NEXT:   GIM_CheckType, /*MI*/1, /*Op*/0, /*Type*/GILLT_s32,
 // CHECK-NEXT:   // MIs[1] src0
 // CHECK-NEXT:   GIM_CheckType, /*MI*/1, /*Op*/1, /*Type*/GILLT_s32,
 // CHECK-NEXT:   GIM_RecordNamedOperand, /*MI*/1, /*Op*/1, /*StoreIdx*/0, // Name : pred:3:x
 // CHECK-NEXT:   GIM_CheckRegBankForClass, /*MI*/1, /*Op*/1, /*RC*/GIMT_Encode2(Test::DRegsRegClassID),
 // CHECK-NEXT:   // MIs[1] src1
 // CHECK-NEXT:   GIM_CheckType, /*MI*/1, /*Op*/2, /*Type*/GILLT_s32,
 // CHECK-NEXT:   GIM_RecordNamedOperand, /*MI*/1, /*Op*/2, /*StoreIdx*/1, // Name : pred:3:y
 // CHECK-NEXT:   GIM_CheckRegBankForClass, /*MI*/1, /*Op*/2, /*RC*/GIMT_Encode2(Test::DRegsRegClassID),
 // CHECK-NEXT:   GIM_CheckCxxInsnPredicate, /*MI*/0, /*FnId*/GIMT_Encode2(GICXXPred_MI_Predicate_and_or_pat),
 // CHECK-NEXT:   GIM_CheckIsSafeToFold, /*InsnID*/1,
 // CHECK-NEXT:   // (and:{ *:[i32] } DOP:{ *:[i32] }:$src2:$pred:3:z, (or:{ *:[i32] } DOP:{ *:[i32] }:$src0:$pred:3:x, DOP:{ *:[i32] }:$src1:$pred:3:y))<<P:3:Predicate_and_or_pat>>  =>  (AND_OR:{ *:[i32] } DOP:{ *:[i32] }:$src0, DOP:{ *:[i32] }:$src1, DOP:{ *:[i32] }:$src2)
 // CHECK-NEXT:   GIR_BuildMI, /*InsnID*/0, /*Opcode*/GIMT_Encode2(MyTarget::AND_OR),

 // CHECK:      GIM_Try, /*On fail goto*//*Label 1*/ GIMT_Encode4(220), // Rule ID 3 //
 // CHECK-NEXT:   GIM_CheckNumOperands, /*MI*/0, /*Expected*/3,
 // CHECK-NEXT:   GIM_CheckOpcode, /*MI*/0, GIMT_Encode2(TargetOpcode::G_AND),
 // CHECK-NEXT:   // MIs[0] DstI[dst]
 // CHECK-NEXT:   GIM_CheckType, /*MI*/0, /*Op*/0, /*Type*/GILLT_s32,
 // CHECK-NEXT:   GIM_CheckRegBankForClass, /*MI*/0, /*Op*/0, /*RC*/GIMT_Encode2(Test::DRegsRegClassID),
 // CHECK-NEXT:   // MIs[0] Operand 1
 // CHECK-NEXT:   GIM_CheckType, /*MI*/0, /*Op*/1, /*Type*/GILLT_s32,
 // CHECK-NEXT:   GIM_RecordInsn, /*DefineMI*/1, /*MI*/0, /*OpIdx*/1, // MIs[1]
 // CHECK-NEXT:   GIM_CheckNumOperands, /*MI*/1, /*Expected*/3,
 // CHECK-NEXT:   GIM_CheckOpcode, /*MI*/1, GIMT_Encode2(TargetOpcode::G_OR),
 // CHECK-NEXT:   // MIs[1] Operand 0
 // CHECK-NEXT:   GIM_CheckType, /*MI*/1, /*Op*/0, /*Type*/GILLT_s32,
 // CHECK-NEXT:   // MIs[1] src0
 // CHECK-NEXT:   GIM_CheckType, /*MI*/1, /*Op*/1, /*Type*/GILLT_s32,
 // CHECK-NEXT:   GIM_RecordNamedOperand, /*MI*/1, /*Op*/1, /*StoreIdx*/0, // Name : pred:3:x
 // CHECK-NEXT:   GIM_CheckRegBankForClass, /*MI*/1, /*Op*/1, /*RC*/GIMT_Encode2(Test::DRegsRegClassID),
 // CHECK-NEXT:   // MIs[1] src1
 // CHECK-NEXT:   GIM_CheckType, /*MI*/1, /*Op*/2, /*Type*/GILLT_s32,
 // CHECK-NEXT:   GIM_RecordNamedOperand, /*MI*/1, /*Op*/2, /*StoreIdx*/1, // Name : pred:3:y
 // CHECK-NEXT:   GIM_CheckRegBankForClass, /*MI*/1, /*Op*/2, /*RC*/GIMT_Encode2(Test::DRegsRegClassID),
 // CHECK-NEXT:   // MIs[0] src2
 // CHECK-NEXT:   GIM_CheckType, /*MI*/0, /*Op*/2, /*Type*/GILLT_s32,
 // CHECK-NEXT:   GIM_RecordNamedOperand, /*MI*/0, /*Op*/2, /*StoreIdx*/2, // Name : pred:3:z
 // CHECK-NEXT:   GIM_CheckRegBankForClass, /*MI*/0, /*Op*/2, /*RC*/GIMT_Encode2(Test::DRegsRegClassID),
 // CHECK-NEXT:   GIM_CheckCxxInsnPredicate, /*MI*/0, /*FnId*/GIMT_Encode2(GICXXPred_MI_Predicate_and_or_pat),
 // CHECK-NEXT:   GIM_CheckIsSafeToFold, /*InsnID*/1,
 // CHECK-NEXT:   // (and:{ *:[i32] } (or:{ *:[i32] } DOP:{ *:[i32] }:$src0:$pred:3:x, DOP:{ *:[i32] }:$src1:$pred:3:y), DOP:{ *:[i32] }:$src2:$pred:3:z)<<P:3:Predicate_and_or_pat>>  =>  (AND_OR:{ *:[i32] } DOP:{ *:[i32] }:$src0, DOP:{ *:[i32] }:$src1, DOP:{ *:[i32] }:$src2)
 // CHECK-NEXT:   GIR_BuildMI, /*InsnID*/0, /*Opcode*/GIMT_Encode2(MyTarget::AND_OR),

 // Test commutative, standalone pattern.
 def : Pat<
   (i32 (and_or_pat DOP:$src0, DOP:$src1, DOP:$src2)),
   (AND_OR DOP:$src0, DOP:$src1, DOP:$src2)
 >;

 def mul_pat : PatFrag<
   (ops node:$x, node:$y),
   (mul node:$x, node:$y), [{ return foo(); }]> {
   let GISelPredicateCode = [{
     return doesComplexCheck(MI);
   }];
   let PredicateCodeUsesOperands = 1;
 }

 // CHECK:      GIM_Try, /*On fail goto*//*Label 2*/ GIMT_Encode4(326), // Rule ID 4 //
 // CHECK-NEXT:   GIM_CheckNumOperands, /*MI*/0, /*Expected*/3,
 // CHECK-NEXT:   GIM_CheckOpcode, /*MI*/0, GIMT_Encode2(TargetOpcode::G_MUL),
 // CHECK-NEXT:   // MIs[0] DstI[dst]
 // CHECK-NEXT:   GIM_CheckType, /*MI*/0, /*Op*/0, /*Type*/GILLT_s32,
 // CHECK-NEXT:   GIM_CheckRegBankForClass, /*MI*/0, /*Op*/0, /*RC*/GIMT_Encode2(Test::DRegsRegClassID),
 // CHECK-NEXT:   // MIs[0] Operand 1
 // CHECK-NEXT:   GIM_CheckType, /*MI*/0, /*Op*/1, /*Type*/GILLT_s32,
 // CHECK-NEXT:   GIM_RecordNamedOperand, /*MI*/0, /*Op*/1, /*StoreIdx*/0, // Name : pred:4:x
 // CHECK-NEXT:   GIM_RecordInsn, /*DefineMI*/1, /*MI*/0, /*OpIdx*/1, // MIs[1]
 // CHECK-NEXT:   GIM_CheckNumOperands, /*MI*/1, /*Expected*/3,
 // CHECK-NEXT:   GIM_CheckOpcode, /*MI*/1, GIMT_Encode2(TargetOpcode::G_OR),
 // CHECK-NEXT:   // MIs[1] Operand 0
 // CHECK-NEXT:   GIM_CheckType, /*MI*/1, /*Op*/0, /*Type*/GILLT_s32,
 // CHECK-NEXT:   // MIs[1] src0
 // CHECK-NEXT:   GIM_CheckType, /*MI*/1, /*Op*/1, /*Type*/GILLT_s32,
 // CHECK-NEXT:   GIM_CheckRegBankForClass, /*MI*/1, /*Op*/1, /*RC*/GIMT_Encode2(Test::DRegsRegClassID),
 // CHECK-NEXT:   // MIs[1] src1
 // CHECK-NEXT:   GIM_CheckType, /*MI*/1, /*Op*/2, /*Type*/GILLT_s32,
 // CHECK-NEXT:   GIM_CheckRegBankForClass, /*MI*/1, /*Op*/2, /*RC*/GIMT_Encode2(Test::DRegsRegClassID),
 // CHECK-NEXT:   // MIs[0] src2
 // CHECK-NEXT:   GIM_CheckType, /*MI*/0, /*Op*/2, /*Type*/GILLT_s32,
 // CHECK-NEXT:   GIM_RecordNamedOperand, /*MI*/0, /*Op*/2, /*StoreIdx*/1, // Name : pred:4:y
 // CHECK-NEXT:   GIM_CheckRegBankForClass, /*MI*/0, /*Op*/2, /*RC*/GIMT_Encode2(Test::DRegsRegClassID),
 // CHECK-NEXT:   GIM_CheckCxxInsnPredicate, /*MI*/0, /*FnId*/GIMT_Encode2(GICXXPred_MI_Predicate_mul_pat),
 // CHECK-NEXT:   GIM_CheckIsSafeToFold, /*InsnID*/1,
 // CHECK-NEXT:   // (mul:{ *:[i32] } (or:{ *:[i32] } DOP:{ *:[i32] }:$src0, DOP:{ *:[i32] }:$src1):$pred:4:x, DOP:{ *:[i32] }:$src2:$pred:4:y)<<P:4:Predicate_mul_pat>>  =>  (MUL_OR:{ *:[i32] } DOP:{ *:[i32] }:$src0, DOP:{ *:[i32] }:$src1, DOP:{ *:[i32] }:$src2)
 // CHECK-NEXT:   GIR_BuildMI, /*InsnID*/0, /*Opcode*/GIMT_Encode2(MyTarget::MUL_OR),

 // CHECK:      GIM_Try, /*On fail goto*//*Label 3*/ GIMT_Encode4(432), // Rule ID 8 //
 // CHECK-NEXT:   GIM_CheckNumOperands, /*MI*/0, /*Expected*/3,
 // CHECK-NEXT:   GIM_CheckOpcode, /*MI*/0, GIMT_Encode2(TargetOpcode::G_MUL),
 // CHECK-NEXT:   // MIs[0] DstI[dst]
 // CHECK-NEXT:   GIM_CheckType, /*MI*/0, /*Op*/0, /*Type*/GILLT_s32,
 // CHECK-NEXT:   GIM_CheckRegBankForClass, /*MI*/0, /*Op*/0, /*RC*/GIMT_Encode2(Test::DRegsRegClassID),
 // CHECK-NEXT:   // MIs[0] src2
 // CHECK-NEXT:   GIM_CheckType, /*MI*/0, /*Op*/1, /*Type*/GILLT_s32,
 // CHECK-NEXT:   GIM_RecordNamedOperand, /*MI*/0, /*Op*/1, /*StoreIdx*/1, // Name : pred:4:y
 // CHECK-NEXT:   GIM_CheckRegBankForClass, /*MI*/0, /*Op*/1, /*RC*/GIMT_Encode2(Test::DRegsRegClassID),
 // CHECK-NEXT:   // MIs[0] Operand 2
 // CHECK-NEXT:   GIM_CheckType, /*MI*/0, /*Op*/2, /*Type*/GILLT_s32,
 // CHECK-NEXT:   GIM_RecordNamedOperand, /*MI*/0, /*Op*/2, /*StoreIdx*/0, // Name : pred:4:x
 // CHECK-NEXT:   GIM_RecordInsn, /*DefineMI*/1, /*MI*/0, /*OpIdx*/2, // MIs[1]
 // CHECK-NEXT:   GIM_CheckNumOperands, /*MI*/1, /*Expected*/3,
 // CHECK-NEXT:   GIM_CheckOpcode, /*MI*/1, GIMT_Encode2(TargetOpcode::G_OR),
 // CHECK-NEXT:   // MIs[1] Operand 0
 // CHECK-NEXT:   GIM_CheckType, /*MI*/1, /*Op*/0, /*Type*/GILLT_s32,
 // CHECK-NEXT:   // MIs[1] src0
 // CHECK-NEXT:   GIM_CheckType, /*MI*/1, /*Op*/1, /*Type*/GILLT_s32,
 // CHECK-NEXT:   GIM_CheckRegBankForClass, /*MI*/1, /*Op*/1, /*RC*/GIMT_Encode2(Test::DRegsRegClassID),
 // CHECK-NEXT:   // MIs[1] src1
 // CHECK-NEXT:   GIM_CheckType, /*MI*/1, /*Op*/2, /*Type*/GILLT_s32,
 // CHECK-NEXT:   GIM_CheckRegBankForClass, /*MI*/1, /*Op*/2, /*RC*/GIMT_Encode2(Test::DRegsRegClassID),
 // CHECK-NEXT:   GIM_CheckCxxInsnPredicate, /*MI*/0, /*FnId*/GIMT_Encode2(GICXXPred_MI_Predicate_mul_pat),
 // CHECK-NEXT:   GIM_CheckIsSafeToFold, /*InsnID*/1,
 // CHECK-NEXT:   // (mul:{ *:[i32] } DOP:{ *:[i32] }:$src2:$pred:4:y, (or:{ *:[i32] } DOP:{ *:[i32] }:$src0, DOP:{ *:[i32] }:$src1):$pred:4:x)<<P:4:Predicate_mul_pat>>  =>  (MUL_OR:{ *:[i32] } DOP:{ *:[i32] }:$src0, DOP:{ *:[i32] }:$src1, DOP:{ *:[i32] }:$src2)
 // CHECK-NEXT:   GIR_BuildMI, /*InsnID*/0, /*Opcode*/GIMT_Encode2(MyTarget::MUL_OR),

 // Test commutative patterns where named operands in the source pattern are not
 // directly bound to PatFrag's operands.
 def : Pat<
   (i32 (mul_pat (or DOP:$src0, DOP:$src1), DOP:$src2)),
   (MUL_OR DOP:$src0, DOP:$src1, DOP:$src2)
 >;

 def sub3_pat : PatFrag<
   (ops node:$x, node:$y, node:$z),
   (sub (sub node:$x, node:$y), node:$z), [{ return foo(); }]> {
   let GISelPredicateCode = [{
     return doesComplexCheck(MI);
   }];

   let PredicateCodeUsesOperands = 1;
 }

 // CHECK:      GIM_Try, /*On fail goto*//*Label 4*/ GIMT_Encode4(527), // Rule ID 0 //
 // CHECK-NEXT:   GIM_CheckNumOperands, /*MI*/0, /*Expected*/3,
 // CHECK-NEXT:   GIM_CheckOpcode, /*MI*/0, GIMT_Encode2(TargetOpcode::G_SUB),
 // CHECK-NEXT:   // MIs[0] DstI[dst]
 // CHECK-NEXT:   GIM_CheckType, /*MI*/0, /*Op*/0, /*Type*/GILLT_s32,
 // CHECK-NEXT:   GIM_CheckRegBankForClass, /*MI*/0, /*Op*/0, /*RC*/GIMT_Encode2(Test::DRegsRegClassID),
 // CHECK-NEXT:   // MIs[0] Operand 1
 // CHECK-NEXT:   GIM_CheckType, /*MI*/0, /*Op*/1, /*Type*/GILLT_s32,
 // CHECK-NEXT:   GIM_RecordInsn, /*DefineMI*/1, /*MI*/0, /*OpIdx*/1, // MIs[1]
 // CHECK-NEXT:   GIM_CheckNumOperands, /*MI*/1, /*Expected*/3,
 // CHECK-NEXT:   GIM_CheckOpcode, /*MI*/1, GIMT_Encode2(TargetOpcode::G_SUB),
 // CHECK-NEXT:   // MIs[1] Operand 0
 // CHECK-NEXT:   GIM_CheckType, /*MI*/1, /*Op*/0, /*Type*/GILLT_s32,
 // CHECK-NEXT:   // MIs[1] src0
 // CHECK-NEXT:   GIM_CheckType, /*MI*/1, /*Op*/1, /*Type*/GILLT_s32,
 // CHECK-NEXT:   GIM_RecordNamedOperand, /*MI*/1, /*Op*/1, /*StoreIdx*/0, // Name : pred:1:x
 // CHECK-NEXT:   // MIs[1] src1
 // CHECK-NEXT:   GIM_CheckType, /*MI*/1, /*Op*/2, /*Type*/GILLT_s32,
 // CHECK-NEXT:   GIM_RecordNamedOperand, /*MI*/1, /*Op*/2, /*StoreIdx*/1, // Name : pred:1:y
 // CHECK-NEXT:   // MIs[0] src2
 // CHECK-NEXT:   GIM_CheckType, /*MI*/0, /*Op*/2, /*Type*/GILLT_s32,
 // CHECK-NEXT:   GIM_RecordNamedOperand, /*MI*/0, /*Op*/2, /*StoreIdx*/2, // Name : pred:1:z
 // CHECK-NEXT:   GIM_CheckCxxInsnPredicate, /*MI*/0, /*FnId*/GIMT_Encode2(GICXXPred_MI_Predicate_sub3_pat),
 // CHECK-NEXT:   GIM_CheckIsSafeToFold, /*InsnID*/1,
 // CHECK-NEXT:   // (sub:{ *:[i32] } (sub:{ *:[i32] } i32:{ *:[i32] }:$src0:$pred:1:x, i32:{ *:[i32] }:$src1:$pred:1:y), i32:{ *:[i32] }:$src2:$pred:1:z)<<P:1:Predicate_sub3_pat>>  =>  (SUB3:{ *:[i32] } i32:{ *:[i32] }:$src0, i32:{ *:[i32] }:$src1, i32:{ *:[i32] }:$src2)
 // CHECK-NEXT:   GIR_BuildMI, /*InsnID*/0, /*Opcode*/GIMT_Encode2(MyTarget::SUB3)

 // Test a non-commutative pattern.
 def SUB3 : I<(outs DRegs:$dst),
   (ins DOP:$src0, DOP:$src1, DOP:$src2),
   [(set DRegs:$dst, (sub3_pat i32:$src0, i32:$src1, i32:$src2))]
 >;


 def patfrags_test_pat : PatFrags<
   (ops node:$x, node:$y, node:$z),
   [ (xor (add node:$x, node:$y), node:$z),
     (xor (sub node:$x, node:$y), node:$z)
   ], [{ return foo(); }]> {
   let GISelPredicateCode = [{
     return doesComplexCheck(MI);
   }];

   let PredicateCodeUsesOperands = 1;
 }

 // CHECK: GIM_Try, /*On fail goto*//*Label 5*/ GIMT_Encode4(622), // Rule ID 1 //
 // CHECK: // (xor:{ *:[i32] } (add:{ *:[i32] } i32:{ *:[i32] }:$src0:$pred:2:x, i32:{ *:[i32] }:$src1:$pred:2:y), i32:{ *:[i32] }:$src2:$pred:2:z)<<P:2:Predicate_patfrags_test_pat>>  =>  (PATFRAGS:{ *:[i32] } i32:{ *:[i32] }:$src0, i32:{ *:[i32] }:$src1, i32:{ *:[i32] }:$src2)

 // CHECK: GIM_Try, /*On fail goto*//*Label 6*/ GIMT_Encode4(717), // Rule ID 2 //
 // CHECK: // (xor:{ *:[i32] } (sub:{ *:[i32] } i32:{ *:[i32] }:$src0:$pred:2:x, i32:{ *:[i32] }:$src1:$pred:2:y), i32:{ *:[i32] }:$src2:$pred:2:z)<<P:2:Predicate_patfrags_test_pat>>  =>  (PATFRAGS:{ *:[i32] } i32:{ *:[i32] }:$src0, i32:{ *:[i32] }:$src1, i32:{ *:[i32] }:$src2)

 // CHECK: GIM_Try, /*On fail goto*//*Label 7*/ GIMT_Encode4(812), // Rule ID 5 //
 // CHECK: // (xor:{ *:[i32] } i32:{ *:[i32] }:$src2:$pred:2:z, (add:{ *:[i32] } i32:{ *:[i32] }:$src0:$pred:2:x, i32:{ *:[i32] }:$src1:$pred:2:y))<<P:2:Predicate_patfrags_test_pat>>  =>  (PATFRAGS:{ *:[i32] } i32:{ *:[i32] }:$src0, i32:{ *:[i32] }:$src1, i32:{ *:[i32] }:$src2)

 // CHECK: GIM_Try, /*On fail goto*//*Label 8*/ GIMT_Encode4(907), // Rule ID 6 //
 // CHECK: // (xor:{ *:[i32] } i32:{ *:[i32] }:$src2:$pred:2:z, (sub:{ *:[i32] } i32:{ *:[i32] }:$src0:$pred:2:x, i32:{ *:[i32] }:$src1:$pred:2:y))<<P:2:Predicate_patfrags_test_pat>>  =>  (PATFRAGS:{ *:[i32] } i32:{ *:[i32] }:$src0, i32:{ *:[i32] }:$src1, i32:{ *:[i32] }:$src2)


 // Test a commutative pattern using multiple patterns using PatFrags.
 def PATFRAGS : I<(outs DRegs:$dst),
   (ins DOP:$src0, DOP:$src1, DOP:$src2),
   [(set DRegs:$dst, (patfrags_test_pat i32:$src0, i32:$src1, i32:$src2))]
 >;
	// RUN: llvm-tblgen %s -gen-global-isel -optimize-match-table=false -I %p/../../include -I %p/Common -o - \| FileCheck %s

	// Verify that all MI predicates are enumerated.
	//
	// CHECK: // PatFrag predicates.
	// CHECK-NEXT: enum {
	// CHECK-NEXT: GICXXPred_MI_Predicate_and_or_pat = GICXXPred_Invalid + 1,
	// CHECK-NEXT: GICXXPred_MI_Predicate_mul_pat,
	// CHECK-NEXT: GICXXPred_MI_Predicate_or_oneuse,
	// CHECK-NEXT: GICXXPred_MI_Predicate_patfrags_test_pat,
	// CHECK-NEXT: GICXXPred_MI_Predicate_sub3_pat,
	// CHECK-NEXT: };

	// Verify that we emit cases for all MI predicates.
	//
	// CHECK: bool MyTargetInstructionSelector::testMIPredicate_MI(
	// CHECK: case GICXXPred_MI_Predicate_and_or_pat: {
	// CHECK: return doesComplexCheck(MI);
	// CHECK: case GICXXPred_MI_Predicate_mul_pat: {
	// CHECK: return doesComplexCheck(MI);
	// CHECK: case GICXXPred_MI_Predicate_or_oneuse: {
	// CHECK: return MRI.hasOneNonDBGUse(MI.getOperand(0).getReg());
	// CHECK: case GICXXPred_MI_Predicate_patfrags_test_pat: {
	// CHECK: return doesComplexCheck(MI);
	// CHECK: case GICXXPred_MI_Predicate_sub3_pat: {
	// CHECK: return doesComplexCheck(MI);

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

	// Boilerplate code for setting up some registers with subregs.
	class MyReg<string n, list<Register> subregs = []>
	: Register<n> {
	let SubRegs = subregs;
	}

	class MyClass<int size, list<ValueType> types, dag registers>
	: RegisterClass<"Test", types, size, registers> {
	let Size = size;
	}

	def sub0 : SubRegIndex<16>;
	def sub1 : SubRegIndex<16, 16>;
	def S0 : MyReg<"s0">;
	def S1 : MyReg<"s1">;
	def SRegs : MyClass<16, [i16], (sequence "S%u", 0, 1)>;

	let SubRegIndices = [sub0, sub1] in {
	def D0 : MyReg<"d0", [S0, S1]>;
	}

	def DRegs : MyClass<32, [i32], (sequence "D%u", 0, 0)>;
	def DOP : RegisterOperand<DRegs>;
	def AND_OR : I<(outs DRegs:$dst), (ins DOP:$src0, DOP:$src1, DOP:$src2), []>;
	def MUL_OR : I<(outs DRegs:$dst), (ins DOP:$src0, DOP:$src1, DOP:$src2), []>;

	def or_oneuse : PatFrag<
	(ops node:$x, node:$y),
	(or node:$x, node:$y), [{ return foo(); }]> {
	let GISelPredicateCode = [{
	return MRI.hasOneNonDBGUse(MI.getOperand(0).getReg());
	}];
	}


	// FIXME: GISelPredicateCode ignored if DAG predicate not set.
	def and_or_pat : PatFrag<
	(ops node:$x, node:$y, node:$z),
	(and (or node:$x, node:$y), node:$z), [{ return foo(); }]> {
	let GISelPredicateCode = [{
	return doesComplexCheck(MI);
	}];
	let PredicateCodeUsesOperands = 1;
	}

	// CHECK: GIM_Try, /On fail goto//Label 0/ GIMT_Encode4(110), // Rule ID 7 //
	// CHECK-NEXT: GIM_CheckNumOperands, /MI/0, /Expected/3,
	// CHECK-NEXT: GIM_CheckOpcode, /MI/0, GIMT_Encode2(TargetOpcode::G_AND),
	// CHECK-NEXT: // MIs[0] DstI[dst]
	// CHECK-NEXT: GIM_CheckType, /MI/0, /Op/0, /Type/GILLT_s32,
	// CHECK-NEXT: GIM_CheckRegBankForClass, /MI/0, /Op/0, /RC/GIMT_Encode2(Test::DRegsRegClassID),
	// CHECK-NEXT: // MIs[0] src2
	// CHECK-NEXT: GIM_CheckType, /MI/0, /Op/1, /Type/GILLT_s32,
	// CHECK-NEXT: GIM_RecordNamedOperand, /MI/0, /Op/1, /StoreIdx/2, // Name : pred:3:z
	// CHECK-NEXT: GIM_CheckRegBankForClass, /MI/0, /Op/1, /RC/GIMT_Encode2(Test::DRegsRegClassID),
	// CHECK-NEXT: // MIs[0] Operand 2
	// CHECK-NEXT: GIM_CheckType, /MI/0, /Op/2, /Type/GILLT_s32,
	// CHECK-NEXT: GIM_RecordInsn, /DefineMI/1, /MI/0, /OpIdx/2, // MIs[1]
	// CHECK-NEXT: GIM_CheckNumOperands, /MI/1, /Expected/3,
	// CHECK-NEXT: GIM_CheckOpcode, /MI/1, GIMT_Encode2(TargetOpcode::G_OR),
	// CHECK-NEXT: // MIs[1] Operand 0
	// CHECK-NEXT: GIM_CheckType, /MI/1, /Op/0, /Type/GILLT_s32,
	// CHECK-NEXT: // MIs[1] src0
	// CHECK-NEXT: GIM_CheckType, /MI/1, /Op/1, /Type/GILLT_s32,
	// CHECK-NEXT: GIM_RecordNamedOperand, /MI/1, /Op/1, /StoreIdx/0, // Name : pred:3:x
	// CHECK-NEXT: GIM_CheckRegBankForClass, /MI/1, /Op/1, /RC/GIMT_Encode2(Test::DRegsRegClassID),
	// CHECK-NEXT: // MIs[1] src1
	// CHECK-NEXT: GIM_CheckType, /MI/1, /Op/2, /Type/GILLT_s32,
	// CHECK-NEXT: GIM_RecordNamedOperand, /MI/1, /Op/2, /StoreIdx/1, // Name : pred:3:y
	// CHECK-NEXT: GIM_CheckRegBankForClass, /MI/1, /Op/2, /RC/GIMT_Encode2(Test::DRegsRegClassID),
	// CHECK-NEXT: GIM_CheckCxxInsnPredicate, /MI/0, /FnId/GIMT_Encode2(GICXXPred_MI_Predicate_and_or_pat),
	// CHECK-NEXT: GIM_CheckIsSafeToFold, /InsnID/1,
	// CHECK-NEXT: // (and:{ :[i32] } DOP:{ :[i32] }:$src2:$pred:3:z, (or:{ :[i32] } DOP:{ :[i32] }:$src0:$pred:3:x, DOP:{ :[i32] }:$src1:$pred:3:y))<<P:3:Predicate_and_or_pat>> => (AND_OR:{ :[i32] } DOP:{ :[i32] }:$src0, DOP:{ :[i32] }:$src1, DOP:{ *:[i32] }:$src2)
	// CHECK-NEXT: GIR_BuildMI, /InsnID/0, /Opcode/GIMT_Encode2(MyTarget::AND_OR),

	// CHECK: GIM_Try, /On fail goto//Label 1/ GIMT_Encode4(220), // Rule ID 3 //
	// CHECK-NEXT: GIM_CheckNumOperands, /MI/0, /Expected/3,
	// CHECK-NEXT: GIM_CheckOpcode, /MI/0, GIMT_Encode2(TargetOpcode::G_AND),
	// CHECK-NEXT: // MIs[0] DstI[dst]
	// CHECK-NEXT: GIM_CheckType, /MI/0, /Op/0, /Type/GILLT_s32,
	// CHECK-NEXT: GIM_CheckRegBankForClass, /MI/0, /Op/0, /RC/GIMT_Encode2(Test::DRegsRegClassID),
	// CHECK-NEXT: // MIs[0] Operand 1
	// CHECK-NEXT: GIM_CheckType, /MI/0, /Op/1, /Type/GILLT_s32,
	// CHECK-NEXT: GIM_RecordInsn, /DefineMI/1, /MI/0, /OpIdx/1, // MIs[1]
	// CHECK-NEXT: GIM_CheckNumOperands, /MI/1, /Expected/3,
	// CHECK-NEXT: GIM_CheckOpcode, /MI/1, GIMT_Encode2(TargetOpcode::G_OR),
	// CHECK-NEXT: // MIs[1] Operand 0
	// CHECK-NEXT: GIM_CheckType, /MI/1, /Op/0, /Type/GILLT_s32,
	// CHECK-NEXT: // MIs[1] src0
	// CHECK-NEXT: GIM_CheckType, /MI/1, /Op/1, /Type/GILLT_s32,
	// CHECK-NEXT: GIM_RecordNamedOperand, /MI/1, /Op/1, /StoreIdx/0, // Name : pred:3:x
	// CHECK-NEXT: GIM_CheckRegBankForClass, /MI/1, /Op/1, /RC/GIMT_Encode2(Test::DRegsRegClassID),
	// CHECK-NEXT: // MIs[1] src1
	// CHECK-NEXT: GIM_CheckType, /MI/1, /Op/2, /Type/GILLT_s32,
	// CHECK-NEXT: GIM_RecordNamedOperand, /MI/1, /Op/2, /StoreIdx/1, // Name : pred:3:y
	// CHECK-NEXT: GIM_CheckRegBankForClass, /MI/1, /Op/2, /RC/GIMT_Encode2(Test::DRegsRegClassID),
	// CHECK-NEXT: // MIs[0] src2
	// CHECK-NEXT: GIM_CheckType, /MI/0, /Op/2, /Type/GILLT_s32,
	// CHECK-NEXT: GIM_RecordNamedOperand, /MI/0, /Op/2, /StoreIdx/2, // Name : pred:3:z
	// CHECK-NEXT: GIM_CheckRegBankForClass, /MI/0, /Op/2, /RC/GIMT_Encode2(Test::DRegsRegClassID),
	// CHECK-NEXT: GIM_CheckCxxInsnPredicate, /MI/0, /FnId/GIMT_Encode2(GICXXPred_MI_Predicate_and_or_pat),
	// CHECK-NEXT: GIM_CheckIsSafeToFold, /InsnID/1,
	// CHECK-NEXT: // (and:{ :[i32] } (or:{ :[i32] } DOP:{ :[i32] }:$src0:$pred:3:x, DOP:{ :[i32] }:$src1:$pred:3:y), DOP:{ :[i32] }:$src2:$pred:3:z)<<P:3:Predicate_and_or_pat>> => (AND_OR:{ :[i32] } DOP:{ :[i32] }:$src0, DOP:{ :[i32] }:$src1, DOP:{ *:[i32] }:$src2)
	// CHECK-NEXT: GIR_BuildMI, /InsnID/0, /Opcode/GIMT_Encode2(MyTarget::AND_OR),

	// Test commutative, standalone pattern.
	def : Pat<
	(i32 (and_or_pat DOP:$src0, DOP:$src1, DOP:$src2)),
	(AND_OR DOP:$src0, DOP:$src1, DOP:$src2)
	>;

	def mul_pat : PatFrag<
	(ops node:$x, node:$y),
	(mul node:$x, node:$y), [{ return foo(); }]> {
	let GISelPredicateCode = [{
	return doesComplexCheck(MI);
	}];
	let PredicateCodeUsesOperands = 1;
	}

	// CHECK: GIM_Try, /On fail goto//Label 2/ GIMT_Encode4(326), // Rule ID 4 //
	// CHECK-NEXT: GIM_CheckNumOperands, /MI/0, /Expected/3,
	// CHECK-NEXT: GIM_CheckOpcode, /MI/0, GIMT_Encode2(TargetOpcode::G_MUL),
	// CHECK-NEXT: // MIs[0] DstI[dst]
	// CHECK-NEXT: GIM_CheckType, /MI/0, /Op/0, /Type/GILLT_s32,
	// CHECK-NEXT: GIM_CheckRegBankForClass, /MI/0, /Op/0, /RC/GIMT_Encode2(Test::DRegsRegClassID),
	// CHECK-NEXT: // MIs[0] Operand 1
	// CHECK-NEXT: GIM_CheckType, /MI/0, /Op/1, /Type/GILLT_s32,
	// CHECK-NEXT: GIM_RecordNamedOperand, /MI/0, /Op/1, /StoreIdx/0, // Name : pred:4:x
	// CHECK-NEXT: GIM_RecordInsn, /DefineMI/1, /MI/0, /OpIdx/1, // MIs[1]
	// CHECK-NEXT: GIM_CheckNumOperands, /MI/1, /Expected/3,
	// CHECK-NEXT: GIM_CheckOpcode, /MI/1, GIMT_Encode2(TargetOpcode::G_OR),
	// CHECK-NEXT: // MIs[1] Operand 0
	// CHECK-NEXT: GIM_CheckType, /MI/1, /Op/0, /Type/GILLT_s32,
	// CHECK-NEXT: // MIs[1] src0
	// CHECK-NEXT: GIM_CheckType, /MI/1, /Op/1, /Type/GILLT_s32,
	// CHECK-NEXT: GIM_CheckRegBankForClass, /MI/1, /Op/1, /RC/GIMT_Encode2(Test::DRegsRegClassID),
	// CHECK-NEXT: // MIs[1] src1
	// CHECK-NEXT: GIM_CheckType, /MI/1, /Op/2, /Type/GILLT_s32,
	// CHECK-NEXT: GIM_CheckRegBankForClass, /MI/1, /Op/2, /RC/GIMT_Encode2(Test::DRegsRegClassID),
	// CHECK-NEXT: // MIs[0] src2
	// CHECK-NEXT: GIM_CheckType, /MI/0, /Op/2, /Type/GILLT_s32,
	// CHECK-NEXT: GIM_RecordNamedOperand, /MI/0, /Op/2, /StoreIdx/1, // Name : pred:4:y
	// CHECK-NEXT: GIM_CheckRegBankForClass, /MI/0, /Op/2, /RC/GIMT_Encode2(Test::DRegsRegClassID),
	// CHECK-NEXT: GIM_CheckCxxInsnPredicate, /MI/0, /FnId/GIMT_Encode2(GICXXPred_MI_Predicate_mul_pat),
	// CHECK-NEXT: GIM_CheckIsSafeToFold, /InsnID/1,
	// CHECK-NEXT: // (mul:{ :[i32] } (or:{ :[i32] } DOP:{ :[i32] }:$src0, DOP:{ :[i32] }:$src1):$pred:4:x, DOP:{ :[i32] }:$src2:$pred:4:y)<<P:4:Predicate_mul_pat>> => (MUL_OR:{ :[i32] } DOP:{ :[i32] }:$src0, DOP:{ :[i32] }:$src1, DOP:{ *:[i32] }:$src2)
	// CHECK-NEXT: GIR_BuildMI, /InsnID/0, /Opcode/GIMT_Encode2(MyTarget::MUL_OR),

	// CHECK: GIM_Try, /On fail goto//Label 3/ GIMT_Encode4(432), // Rule ID 8 //
	// CHECK-NEXT: GIM_CheckNumOperands, /MI/0, /Expected/3,
	// CHECK-NEXT: GIM_CheckOpcode, /MI/0, GIMT_Encode2(TargetOpcode::G_MUL),
	// CHECK-NEXT: // MIs[0] DstI[dst]
	// CHECK-NEXT: GIM_CheckType, /MI/0, /Op/0, /Type/GILLT_s32,
	// CHECK-NEXT: GIM_CheckRegBankForClass, /MI/0, /Op/0, /RC/GIMT_Encode2(Test::DRegsRegClassID),
	// CHECK-NEXT: // MIs[0] src2
	// CHECK-NEXT: GIM_CheckType, /MI/0, /Op/1, /Type/GILLT_s32,
	// CHECK-NEXT: GIM_RecordNamedOperand, /MI/0, /Op/1, /StoreIdx/1, // Name : pred:4:y
	// CHECK-NEXT: GIM_CheckRegBankForClass, /MI/0, /Op/1, /RC/GIMT_Encode2(Test::DRegsRegClassID),
	// CHECK-NEXT: // MIs[0] Operand 2
	// CHECK-NEXT: GIM_CheckType, /MI/0, /Op/2, /Type/GILLT_s32,
	// CHECK-NEXT: GIM_RecordNamedOperand, /MI/0, /Op/2, /StoreIdx/0, // Name : pred:4:x
	// CHECK-NEXT: GIM_RecordInsn, /DefineMI/1, /MI/0, /OpIdx/2, // MIs[1]
	// CHECK-NEXT: GIM_CheckNumOperands, /MI/1, /Expected/3,
	// CHECK-NEXT: GIM_CheckOpcode, /MI/1, GIMT_Encode2(TargetOpcode::G_OR),
	// CHECK-NEXT: // MIs[1] Operand 0
	// CHECK-NEXT: GIM_CheckType, /MI/1, /Op/0, /Type/GILLT_s32,
	// CHECK-NEXT: // MIs[1] src0
	// CHECK-NEXT: GIM_CheckType, /MI/1, /Op/1, /Type/GILLT_s32,
	// CHECK-NEXT: GIM_CheckRegBankForClass, /MI/1, /Op/1, /RC/GIMT_Encode2(Test::DRegsRegClassID),
	// CHECK-NEXT: // MIs[1] src1
	// CHECK-NEXT: GIM_CheckType, /MI/1, /Op/2, /Type/GILLT_s32,
	// CHECK-NEXT: GIM_CheckRegBankForClass, /MI/1, /Op/2, /RC/GIMT_Encode2(Test::DRegsRegClassID),
	// CHECK-NEXT: GIM_CheckCxxInsnPredicate, /MI/0, /FnId/GIMT_Encode2(GICXXPred_MI_Predicate_mul_pat),
	// CHECK-NEXT: GIM_CheckIsSafeToFold, /InsnID/1,
	// CHECK-NEXT: // (mul:{ :[i32] } DOP:{ :[i32] }:$src2:$pred:4:y, (or:{ :[i32] } DOP:{ :[i32] }:$src0, DOP:{ :[i32] }:$src1):$pred:4:x)<<P:4:Predicate_mul_pat>> => (MUL_OR:{ :[i32] } DOP:{ :[i32] }:$src0, DOP:{ :[i32] }:$src1, DOP:{ *:[i32] }:$src2)
	// CHECK-NEXT: GIR_BuildMI, /InsnID/0, /Opcode/GIMT_Encode2(MyTarget::MUL_OR),

	// Test commutative patterns where named operands in the source pattern are not
	// directly bound to PatFrag's operands.
	def : Pat<
	(i32 (mul_pat (or DOP:$src0, DOP:$src1), DOP:$src2)),
	(MUL_OR DOP:$src0, DOP:$src1, DOP:$src2)
	>;

	def sub3_pat : PatFrag<
	(ops node:$x, node:$y, node:$z),
	(sub (sub node:$x, node:$y), node:$z), [{ return foo(); }]> {
	let GISelPredicateCode = [{
	return doesComplexCheck(MI);
	}];

	let PredicateCodeUsesOperands = 1;
	}

	// CHECK: GIM_Try, /On fail goto//Label 4/ GIMT_Encode4(527), // Rule ID 0 //
	// CHECK-NEXT: GIM_CheckNumOperands, /MI/0, /Expected/3,
	// CHECK-NEXT: GIM_CheckOpcode, /MI/0, GIMT_Encode2(TargetOpcode::G_SUB),
	// CHECK-NEXT: // MIs[0] DstI[dst]
	// CHECK-NEXT: GIM_CheckType, /MI/0, /Op/0, /Type/GILLT_s32,
	// CHECK-NEXT: GIM_CheckRegBankForClass, /MI/0, /Op/0, /RC/GIMT_Encode2(Test::DRegsRegClassID),
	// CHECK-NEXT: // MIs[0] Operand 1
	// CHECK-NEXT: GIM_CheckType, /MI/0, /Op/1, /Type/GILLT_s32,
	// CHECK-NEXT: GIM_RecordInsn, /DefineMI/1, /MI/0, /OpIdx/1, // MIs[1]
	// CHECK-NEXT: GIM_CheckNumOperands, /MI/1, /Expected/3,
	// CHECK-NEXT: GIM_CheckOpcode, /MI/1, GIMT_Encode2(TargetOpcode::G_SUB),
	// CHECK-NEXT: // MIs[1] Operand 0
	// CHECK-NEXT: GIM_CheckType, /MI/1, /Op/0, /Type/GILLT_s32,
	// CHECK-NEXT: // MIs[1] src0
	// CHECK-NEXT: GIM_CheckType, /MI/1, /Op/1, /Type/GILLT_s32,
	// CHECK-NEXT: GIM_RecordNamedOperand, /MI/1, /Op/1, /StoreIdx/0, // Name : pred:1:x
	// CHECK-NEXT: // MIs[1] src1
	// CHECK-NEXT: GIM_CheckType, /MI/1, /Op/2, /Type/GILLT_s32,
	// CHECK-NEXT: GIM_RecordNamedOperand, /MI/1, /Op/2, /StoreIdx/1, // Name : pred:1:y
	// CHECK-NEXT: // MIs[0] src2
	// CHECK-NEXT: GIM_CheckType, /MI/0, /Op/2, /Type/GILLT_s32,
	// CHECK-NEXT: GIM_RecordNamedOperand, /MI/0, /Op/2, /StoreIdx/2, // Name : pred:1:z
	// CHECK-NEXT: GIM_CheckCxxInsnPredicate, /MI/0, /FnId/GIMT_Encode2(GICXXPred_MI_Predicate_sub3_pat),
	// CHECK-NEXT: GIM_CheckIsSafeToFold, /InsnID/1,
	// CHECK-NEXT: // (sub:{ :[i32] } (sub:{ :[i32] } i32:{ :[i32] }:$src0:$pred:1:x, i32:{ :[i32] }:$src1:$pred:1:y), i32:{ :[i32] }:$src2:$pred:1:z)<<P:1:Predicate_sub3_pat>> => (SUB3:{ :[i32] } i32:{ :[i32] }:$src0, i32:{ :[i32] }:$src1, i32:{ *:[i32] }:$src2)
	// CHECK-NEXT: GIR_BuildMI, /InsnID/0, /Opcode/GIMT_Encode2(MyTarget::SUB3)

	// Test a non-commutative pattern.
	def SUB3 : I<(outs DRegs:$dst),
	(ins DOP:$src0, DOP:$src1, DOP:$src2),
	[(set DRegs:$dst, (sub3_pat i32:$src0, i32:$src1, i32:$src2))]
	>;


	def patfrags_test_pat : PatFrags<
	(ops node:$x, node:$y, node:$z),
	[ (xor (add node:$x, node:$y), node:$z),
	(xor (sub node:$x, node:$y), node:$z)
	], [{ return foo(); }]> {
	let GISelPredicateCode = [{
	return doesComplexCheck(MI);
	}];

	let PredicateCodeUsesOperands = 1;
	}

	// CHECK: GIM_Try, /On fail goto//Label 5/ GIMT_Encode4(622), // Rule ID 1 //
	// CHECK: // (xor:{ :[i32] } (add:{ :[i32] } i32:{ :[i32] }:$src0:$pred:2:x, i32:{ :[i32] }:$src1:$pred:2:y), i32:{ :[i32] }:$src2:$pred:2:z)<<P:2:Predicate_patfrags_test_pat>> => (PATFRAGS:{ :[i32] } i32:{ :[i32] }:$src0, i32:{ :[i32] }:$src1, i32:{ *:[i32] }:$src2)

	// CHECK: GIM_Try, /On fail goto//Label 6/ GIMT_Encode4(717), // Rule ID 2 //
	// CHECK: // (xor:{ :[i32] } (sub:{ :[i32] } i32:{ :[i32] }:$src0:$pred:2:x, i32:{ :[i32] }:$src1:$pred:2:y), i32:{ :[i32] }:$src2:$pred:2:z)<<P:2:Predicate_patfrags_test_pat>> => (PATFRAGS:{ :[i32] } i32:{ :[i32] }:$src0, i32:{ :[i32] }:$src1, i32:{ *:[i32] }:$src2)

	// CHECK: GIM_Try, /On fail goto//Label 7/ GIMT_Encode4(812), // Rule ID 5 //
	// CHECK: // (xor:{ :[i32] } i32:{ :[i32] }:$src2:$pred:2:z, (add:{ :[i32] } i32:{ :[i32] }:$src0:$pred:2:x, i32:{ :[i32] }:$src1:$pred:2:y))<<P:2:Predicate_patfrags_test_pat>> => (PATFRAGS:{ :[i32] } i32:{ :[i32] }:$src0, i32:{ :[i32] }:$src1, i32:{ *:[i32] }:$src2)

	// CHECK: GIM_Try, /On fail goto//Label 8/ GIMT_Encode4(907), // Rule ID 6 //
	// CHECK: // (xor:{ :[i32] } i32:{ :[i32] }:$src2:$pred:2:z, (sub:{ :[i32] } i32:{ :[i32] }:$src0:$pred:2:x, i32:{ :[i32] }:$src1:$pred:2:y))<<P:2:Predicate_patfrags_test_pat>> => (PATFRAGS:{ :[i32] } i32:{ :[i32] }:$src0, i32:{ :[i32] }:$src1, i32:{ *:[i32] }:$src2)


	// Test a commutative pattern using multiple patterns using PatFrags.
	def PATFRAGS : I<(outs DRegs:$dst),
	(ins DOP:$src0, DOP:$src1, DOP:$src2),
	[(set DRegs:$dst, (patfrags_test_pat i32:$src0, i32:$src1, i32:$src2))]
	>;