[CIR] Backport AbstractConditionalOperator for ComplexType

clang/lib/CIR/CodeGen/CIRGenExprComplex.cpp

@@ -310,8 +310,24 @@ class ComplexExprEmitter : public StmtVisitor<ComplexExprEmitter, mlir::Value> {
   }
 
   mlir::Value
-  VisitAbstractConditionalOperator(const AbstractConditionalOperator *CO) {
-    llvm_unreachable("NYI");
+  VisitAbstractConditionalOperator(const AbstractConditionalOperator *E) {
+    mlir::Value condValue = Visit(E->getCond());
+    mlir::Location loc = CGF.getLoc(E->getSourceRange());
+
+    return Builder
+        .create<cir::TernaryOp>(
+            loc, condValue,
+            /*thenBuilder=*/
+            [&](mlir::OpBuilder &b, mlir::Location loc) {
+              mlir::Value trueValue = Visit(E->getTrueExpr());
+              b.create<cir::YieldOp>(loc, trueValue);
+            },
+            /*elseBuilder=*/
+            [&](mlir::OpBuilder &b, mlir::Location loc) {
+              mlir::Value falseValue = Visit(E->getFalseExpr());
+              b.create<cir::YieldOp>(loc, falseValue);
+            })
+        .getResult();
   }
 
   mlir::Value VisitChooseExpr(ChooseExpr *CE) {

clang/test/CIR/CodeGen/complex.cpp

@@ -14,3 +14,38 @@ void complex_functional_cast() {
 
 // LLVM: %[[INIT:.*]] = alloca { i32, i32 }, i64 1, align 4
 // LLVM: store { i32, i32 } zeroinitializer, ptr %[[INIT]], align 4
+
+void complex_abstract_condition(bool cond, int _Complex a, int _Complex b) {
+  int _Complex c = cond ? a : b;
+}
+
+// CIR: %[[COND:.*]] = cir.alloca !cir.bool, !cir.ptr<!cir.bool>, ["cond", init]
+// CIR: %[[COMPLEX_A:.*]] = cir.alloca !cir.complex<!s32i>, !cir.ptr<!cir.complex<!s32i>>, ["a", init]
+// CIR: %[[COMPLEX_B:.*]] = cir.alloca !cir.complex<!s32i>, !cir.ptr<!cir.complex<!s32i>>, ["b", init]
+// CIR: %[[RESULT:.*]] = cir.alloca !cir.complex<!s32i>, !cir.ptr<!cir.complex<!s32i>>, ["c", init]
+// CIR: %[[TMP_COND:.*]] = cir.load{{.*}} %[[COND]] : !cir.ptr<!cir.bool>, !cir.bool
+// CIR: %[[RESULT_VAL:.*]] = cir.ternary(%[[TMP_COND]], true {
+// CIR:   %[[TMP_A:.*]] = cir.load{{.*}} %[[COMPLEX_A]] : !cir.ptr<!cir.complex<!s32i>>, !cir.complex<!s32i>
+// CIR:   cir.yield %[[TMP_A]] : !cir.complex<!s32i>
+// CIR: }, false {
+// CIR:   %[[TMP_B:.*]] = cir.load{{.*}} %[[COMPLEX_B]] : !cir.ptr<!cir.complex<!s32i>>, !cir.complex<!s32i>
+// CIR:   cir.yield %[[TMP_B]] : !cir.complex<!s32i>
+// CIR: }) : (!cir.bool) -> !cir.complex<!s32i>
+// CIR: cir.store{{.*}} %[[RESULT_VAL]], %[[RESULT]] : !cir.complex<!s32i>, !cir.ptr<!cir.complex<!s32i>>
+
+// LLVM: %[[COND:.*]] = alloca i8, i64 1, align 1
+// LLVM: %[[COMPLEX_A:.*]] = alloca { i32, i32 }, i64 1, align 4
+// LLVM: %[[COMPLEX_B:.*]] = alloca { i32, i32 }, i64 1, align 4
+// LLVM: %[[RESULT:.*]] = alloca { i32, i32 }, i64 1, align 4
+// LLVM: %[[TMP_COND:.*]] = load i8, ptr %[[COND]], align 1
+// LLVM: %[[COND_VAL:.*]] = trunc i8 %[[TMP_COND]] to i1
+// LLVM: br i1 %[[COND_VAL]], label %[[TRUE_BB:.*]], label %[[FALSE_BB:.*]]
+// LLVM: [[TRUE_BB]]:
+// LLVM:  %[[TMP_A:.*]] = load { i32, i32 }, ptr %[[COMPLEX_A]], align 4
+// LLVM:  br label %[[END_BB:.*]]
+// LLVM: [[FALSE_BB]]:
+// LLVM:  %[[TMP_B:.*]] = load { i32, i32 }, ptr %[[COMPLEX_B]], align 4
+// LLVM:  br label %[[END_BB]]
+// LLVM: [[END_BB]]:
+// LLVM: %[[RESULT_VAL:.*]] = phi { i32, i32 } [ %[[TMP_B]], %[[FALSE_BB]] ], [ %[[TMP_A]], %[[TRUE_BB]] ]
+// LLVM: store { i32, i32 } %[[RESULT_VAL]], ptr %[[RESULT]], align 4