[flang] Fix hlfir.as_expr codegen for polymorphic entities

flang/lib/Optimizer/HLFIR/Transforms/BufferizeHLFIR.cpp

@@ -159,6 +159,22 @@ createArrayTemp(mlir::Location loc, fir::FirOpBuilder &builder,
   return {hlfir::Entity{declareOp.getBase()}, trueVal};
 }
 
+/// Copy \p source into a new temporary and package the temporary into a
+/// <temp,cleanup> tuple. The temporary may be heap or stack allocated.
+static mlir::Value copyInTempAndPackage(mlir::Location loc,
+                                        fir::FirOpBuilder &builder,
+                                        hlfir::Entity source) {
+  auto [temp, cleanup] = hlfir::createTempFromMold(loc, builder, source);
+  builder.create<hlfir::AssignOp>(loc, source, temp, temp.isAllocatable(),
+                                  /*keep_lhs_length_if_realloc=*/false,
+                                  /*temporary_lhs=*/true);
+  // Dereference allocatable temporary directly to simplify processing
+  // of its uses.
+  if (temp.isAllocatable())
+    temp = hlfir::derefPointersAndAllocatables(loc, builder, temp);
+  return packageBufferizedExpr(loc, builder, temp, cleanup);
+}
+
 struct AsExprOpConversion : public mlir::OpConversionPattern<hlfir::AsExprOp> {
   using mlir::OpConversionPattern<hlfir::AsExprOp>::OpConversionPattern;
   explicit AsExprOpConversion(mlir::MLIRContext *ctx)
@@ -178,12 +194,7 @@ struct AsExprOpConversion : public mlir::OpConversionPattern<hlfir::AsExprOp> {
     }
     // Otherwise, create a copy in a new buffer.
     hlfir::Entity source = hlfir::Entity{adaptor.getVar()};
-    auto [temp, cleanup] = hlfir::createTempFromMold(loc, builder, source);
-    builder.create<hlfir::AssignOp>(loc, source, temp, temp.isAllocatable(),
-                                    /*keep_lhs_length_if_realloc=*/false,
-                                    /*temporary_lhs=*/true);
-    mlir::Value bufferizedExpr =
-        packageBufferizedExpr(loc, builder, temp, cleanup);
+    mlir::Value bufferizedExpr = copyInTempAndPackage(loc, builder, source);
     rewriter.replaceOp(asExpr, bufferizedExpr);
     return mlir::success();
   }
@@ -542,12 +553,7 @@ struct AssociateOpConversion
     // non-trivial value with more than one use. We will have to make a copy and
     // use that
     hlfir::Entity source = hlfir::Entity{bufferizedExpr};
-    auto [temp, cleanup] = hlfir::createTempFromMold(loc, builder, source);
-    builder.create<hlfir::AssignOp>(loc, source, temp, temp.isAllocatable(),
-                                    /*keep_lhs_length_if_realloc=*/false,
-                                    /*temporary_lhs=*/true);
-    mlir::Value bufferTuple =
-        packageBufferizedExpr(loc, builder, temp, cleanup);
+    mlir::Value bufferTuple = copyInTempAndPackage(loc, builder, source);
     bufferizedExpr = getBufferizedExprStorage(bufferTuple);
     replaceWith(bufferizedExpr, hlfir::Entity{bufferizedExpr}.getFirBase(),
                 getBufferizedExprMustFreeFlag(bufferTuple));

flang/test/HLFIR/as_expr-codegen-polymorphic.fir

@@ -0,0 +1,38 @@
+// Test hlfir.as_expr codegen for polymorphic expressions.
+
+// RUN: fir-opt %s -bufferize-hlfir | FileCheck %s
+
+!t = !fir.type<t{i:i32}>
+func.func @as_expr_class(%arg0 : !fir.class<!t>, %arg1: !fir.ref<!t>) {
+    %0 = hlfir.as_expr %arg0 : (!fir.class<!t>) -> !hlfir.expr<!t?>
+    hlfir.assign %0 to %arg1 : !hlfir.expr<!t?>, !fir.ref<!t>
+   return
+}
+// CHECK-LABEL:   func.func @as_expr_class(
+// CHECK:           %[[VAL_5:.*]] = arith.constant true
+// CHECK:           %[[VAL_6:.*]]:2 = hlfir.declare %{{.*}} {fortran_attrs = #fir.var_attrs<allocatable>, uniq_name = ".tmp"} : (!fir.ref<!fir.class<!fir.heap<!fir.type<t{i:i32}>>>>) -> (!fir.ref<!fir.class<!fir.heap<!fir.type<t{i:i32}>>>>, !fir.ref<!fir.class<!fir.heap<!fir.type<t{i:i32}>>>>)
+// ... copy ...
+// CHECK:           %[[VAL_11:.*]] = fir.load %[[VAL_6]]#0 : !fir.ref<!fir.class<!fir.heap<!fir.type<t{i:i32}>>>>
+// CHECK:           %[[VAL_12:.*]] = fir.undefined tuple<!fir.class<!fir.heap<!fir.type<t{i:i32}>>>, i1>
+// CHECK:           %[[VAL_13:.*]] = fir.insert_value %[[VAL_12]], %[[VAL_5]], [1 : index] : (tuple<!fir.class<!fir.heap<!fir.type<t{i:i32}>>>, i1>, i1) -> tuple<!fir.class<!fir.heap<!fir.type<t{i:i32}>>>, i1>
+// CHECK:           %[[VAL_14:.*]] = fir.insert_value %[[VAL_13]], %[[VAL_11]], [0 : index] : (tuple<!fir.class<!fir.heap<!fir.type<t{i:i32}>>>, i1>, !fir.class<!fir.heap<!fir.type<t{i:i32}>>>) -> tuple<!fir.class<!fir.heap<!fir.type<t{i:i32}>>>, i1>
+// CHECK:           hlfir.assign %[[VAL_11]] to %{{.*}} : !fir.class<!fir.heap<!fir.type<t{i:i32}>>>, !fir.ref<!fir.type<t{i:i32}>>
+
+
+func.func @as_expr_class_2(%arg0 : !fir.class<!fir.array<?x!t>>) {
+    %0 = hlfir.as_expr %arg0 : (!fir.class<!fir.array<?x!t>>) -> !hlfir.expr<?x!t?>
+    %c1 = arith.constant 1 : index
+    %1 = hlfir.apply %0, %c1 : (!hlfir.expr<?x!t?>, index) -> !hlfir.expr<!t?>
+   return
+}
+// CHECK-LABEL:   func.func @as_expr_class_2(
+// CHECK:           %[[VAL_9:.*]] = arith.constant true
+// CHECK:           %[[VAL_10:.*]]:2 = hlfir.declare %{{.*}} {fortran_attrs = #fir.var_attrs<allocatable>, uniq_name = ".tmp"} : (!fir.ref<!fir.class<!fir.heap<!fir.array<?x!fir.type<t{i:i32}>>>>>) -> (!fir.ref<!fir.class<!fir.heap<!fir.array<?x!fir.type<t{i:i32}>>>>>, !fir.ref<!fir.class<!fir.heap<!fir.array<?x!fir.type<t{i:i32}>>>>>)
+// CHECK:           %[[VAL_11:.*]] = arith.constant 1 : i32
+// ... copy ...
+// CHECK:           %[[VAL_15:.*]] = fir.load %[[VAL_10]]#0 : !fir.ref<!fir.class<!fir.heap<!fir.array<?x!fir.type<t{i:i32}>>>>>
+// CHECK:           %[[VAL_16:.*]] = fir.undefined tuple<!fir.class<!fir.heap<!fir.array<?x!fir.type<t{i:i32}>>>>, i1>
+// CHECK:           %[[VAL_17:.*]] = fir.insert_value %[[VAL_16]], %[[VAL_9]], [1 : index] : (tuple<!fir.class<!fir.heap<!fir.array<?x!fir.type<t{i:i32}>>>>, i1>, i1) -> tuple<!fir.class<!fir.heap<!fir.array<?x!fir.type<t{i:i32}>>>>, i1>
+// CHECK:           %[[VAL_18:.*]] = fir.insert_value %[[VAL_17]], %[[VAL_15]], [0 : index] : (tuple<!fir.class<!fir.heap<!fir.array<?x!fir.type<t{i:i32}>>>>, i1>, !fir.class<!fir.heap<!fir.array<?x!fir.type<t{i:i32}>>>>) -> tuple<!fir.class<!fir.heap<!fir.array<?x!fir.type<t{i:i32}>>>>, i1>
+// CHECK:           %[[VAL_19:.*]] = arith.constant 1 : index
+// CHECK:           %[[VAL_20:.*]] = hlfir.designate %[[VAL_15]] (%[[VAL_19]])  : (!fir.class<!fir.heap<!fir.array<?x!fir.type<t{i:i32}>>>>, index) -> !fir.class<!fir.type<t{i:i32}>>

flang/test/HLFIR/bufferize-poly-expr.fir

@@ -26,12 +26,12 @@ func.func @test_poly_expr_without_associate() {
 // CHECK:           %[[VAL_11:.*]] = fir.convert %[[VAL_4]]#1 : (!fir.class<!fir.heap<!fir.type<_QFtestTt{c:i32}>>>) -> !fir.box<none>
 // CHECK:           %[[VAL_12:.*]] = fir.call @_FortranAAllocatableApplyMold(%[[VAL_10]], %[[VAL_11]], %[[VAL_9]]) : (!fir.ref<!fir.box<none>>, !fir.box<none>, i32) -> none
 // CHECK:           hlfir.assign %[[VAL_4]]#0 to %[[VAL_8]]#0 realloc temporary_lhs : !fir.class<!fir.heap<!fir.type<_QFtestTt{c:i32}>>>, !fir.ref<!fir.class<!fir.heap<!fir.type<_QFtestTt{c:i32}>>>>
-// CHECK:           %[[VAL_13:.*]] = fir.undefined tuple<!fir.ref<!fir.class<!fir.heap<!fir.type<_QFtestTt{c:i32}>>>>, i1>
-// CHECK:           %[[VAL_14:.*]] = fir.insert_value %[[VAL_13]], %[[VAL_7]], [1 : index] : (tuple<!fir.ref<!fir.class<!fir.heap<!fir.type<_QFtestTt{c:i32}>>>>, i1>, i1) -> tuple<!fir.ref<!fir.class<!fir.heap<!fir.type<_QFtestTt{c:i32}>>>>, i1>
-// CHECK:           %[[VAL_15:.*]] = fir.insert_value %[[VAL_14]], %[[VAL_8]]#0, [0 : index] : (tuple<!fir.ref<!fir.class<!fir.heap<!fir.type<_QFtestTt{c:i32}>>>>, i1>, !fir.ref<!fir.class<!fir.heap<!fir.type<_QFtestTt{c:i32}>>>>) -> tuple<!fir.ref<!fir.class<!fir.heap<!fir.type<_QFtestTt{c:i32}>>>>, i1>
-// CHECK:           hlfir.assign %[[VAL_8]]#0 to %[[VAL_2]]#0 realloc : !fir.ref<!fir.class<!fir.heap<!fir.type<_QFtestTt{c:i32}>>>>, !fir.ref<!fir.class<!fir.heap<!fir.type<_QFtestTt{c:i32}>>>>
-// CHECK:           %[[VAL_16:.*]] = fir.load %[[VAL_8]]#0 : !fir.ref<!fir.class<!fir.heap<!fir.type<_QFtestTt{c:i32}>>>>
-// CHECK:           %[[VAL_17:.*]] = fir.box_addr %[[VAL_16]] : (!fir.class<!fir.heap<!fir.type<_QFtestTt{c:i32}>>>) -> !fir.heap<!fir.type<_QFtestTt{c:i32}>>
+// CHECK:           %[[VAL_8B:.*]] = fir.load %[[VAL_8]]#0
+// CHECK:           %[[VAL_13:.*]] = fir.undefined tuple<!fir.class<!fir.heap<!fir.type<_QFtestTt{c:i32}>>>, i1>
+// CHECK:           %[[VAL_14:.*]] = fir.insert_value %[[VAL_13]], %[[VAL_7]], [1 : index] : (tuple<!fir.class<!fir.heap<!fir.type<_QFtestTt{c:i32}>>>, i1>, i1) -> tuple<!fir.class<!fir.heap<!fir.type<_QFtestTt{c:i32}>>>, i1>
+// CHECK:           %[[VAL_15:.*]] = fir.insert_value %[[VAL_14]], %[[VAL_8B]], [0 : index] : (tuple<!fir.class<!fir.heap<!fir.type<_QFtestTt{c:i32}>>>, i1>, !fir.class<!fir.heap<!fir.type<_QFtestTt{c:i32}>>>) -> tuple<!fir.class<!fir.heap<!fir.type<_QFtestTt{c:i32}>>>, i1>
+// CHECK:           hlfir.assign %[[VAL_8B]] to %[[VAL_2]]#0 realloc : !fir.class<!fir.heap<!fir.type<_QFtestTt{c:i32}>>>, !fir.ref<!fir.class<!fir.heap<!fir.type<_QFtestTt{c:i32}>>>>
+// CHECK:           %[[VAL_17:.*]] = fir.box_addr %[[VAL_8B]] : (!fir.class<!fir.heap<!fir.type<_QFtestTt{c:i32}>>>) -> !fir.heap<!fir.type<_QFtestTt{c:i32}>>
 // CHECK:           fir.freemem %[[VAL_17]] : !fir.heap<!fir.type<_QFtestTt{c:i32}>>
 // CHECK:           return
 // CHECK:         }
@@ -81,25 +81,24 @@ func.func @test_poly_expr_with_associate(%arg1: !fir.class<!fir.array<3x!fir.typ
 // CHECK:           %[[VAL_17:.*]] = fir.convert %[[VAL_5]] : (!fir.class<!fir.heap<!fir.array<?x!fir.type<_QMtest_typeTt1{i:i32}>>>>) -> !fir.box<none>
 // CHECK:           %[[VAL_18:.*]] = fir.call @_FortranAAllocatableApplyMold(%[[VAL_16]], %[[VAL_17]], %[[VAL_15]]) : (!fir.ref<!fir.box<none>>, !fir.box<none>, i32) -> none
 // CHECK:           hlfir.assign %[[VAL_5]] to %[[VAL_14]]#0 realloc temporary_lhs : !fir.class<!fir.heap<!fir.array<?x!fir.type<_QMtest_typeTt1{i:i32}>>>>, !fir.ref<!fir.class<!fir.heap<!fir.array<?x!fir.type<_QMtest_typeTt1{i:i32}>>>>>
-// CHECK:           %[[VAL_19:.*]] = fir.undefined tuple<!fir.ref<!fir.class<!fir.heap<!fir.array<?x!fir.type<_QMtest_typeTt1{i:i32}>>>>>, i1>
-// CHECK:           %[[VAL_20:.*]] = fir.insert_value %[[VAL_19]], %[[VAL_13]], [1 : index] : (tuple<!fir.ref<!fir.class<!fir.heap<!fir.array<?x!fir.type<_QMtest_typeTt1{i:i32}>>>>>, i1>, i1) -> tuple<!fir.ref<!fir.class<!fir.heap<!fir.array<?x!fir.type<_QMtest_typeTt1{i:i32}>>>>>, i1>
-// CHECK:           %[[VAL_21:.*]] = fir.insert_value %[[VAL_20]], %[[VAL_14]]#0, [0 : index] : (tuple<!fir.ref<!fir.class<!fir.heap<!fir.array<?x!fir.type<_QMtest_typeTt1{i:i32}>>>>>, i1>, !fir.ref<!fir.class<!fir.heap<!fir.array<?x!fir.type<_QMtest_typeTt1{i:i32}>>>>>) -> tuple<!fir.ref<!fir.class<!fir.heap<!fir.array<?x!fir.type<_QMtest_typeTt1{i:i32}>>>>>, i1>
+// CHECK:           %[[VAL_14B:.*]] = fir.load %[[VAL_14]]#0
+// CHECK:           %[[VAL_19:.*]] = fir.undefined tuple<!fir.class<!fir.heap<!fir.array<?x!fir.type<_QMtest_typeTt1{i:i32}>>>>, i1>
+// CHECK:           %[[VAL_20:.*]] = fir.insert_value %[[VAL_19]], %[[VAL_13]], [1 : index] : (tuple<!fir.class<!fir.heap<!fir.array<?x!fir.type<_QMtest_typeTt1{i:i32}>>>>, i1>, i1) -> tuple<!fir.class<!fir.heap<!fir.array<?x!fir.type<_QMtest_typeTt1{i:i32}>>>>, i1>
+// CHECK:           %[[VAL_21:.*]] = fir.insert_value %[[VAL_20]], %[[VAL_14B]], [0 : index] : (tuple<!fir.class<!fir.heap<!fir.array<?x!fir.type<_QMtest_typeTt1{i:i32}>>>>, i1>, !fir.class<!fir.heap<!fir.array<?x!fir.type<_QMtest_typeTt1{i:i32}>>>>) -> tuple<!fir.class<!fir.heap<!fir.array<?x!fir.type<_QMtest_typeTt1{i:i32}>>>>, i1>
 // CHECK:           %[[VAL_22:.*]] = arith.constant 0 : index
 // CHECK:           %[[VAL_23:.*]]:3 = fir.box_dims %[[VAL_5]], %[[VAL_22]] : (!fir.class<!fir.heap<!fir.array<?x!fir.type<_QMtest_typeTt1{i:i32}>>>>, index) -> (index, index, index)
 // CHECK:           %[[VAL_24:.*]] = fir.shape %[[VAL_23]]#1 : (index) -> !fir.shape<1>
-// CHECK:           %[[VAL_25:.*]] = fir.load %[[VAL_14]]#0 : !fir.ref<!fir.class<!fir.heap<!fir.array<?x!fir.type<_QMtest_typeTt1{i:i32}>>>>>
-// CHECK:           %[[VAL_26:.*]] = fir.load %[[VAL_14]]#1 : !fir.ref<!fir.class<!fir.heap<!fir.array<?x!fir.type<_QMtest_typeTt1{i:i32}>>>>>
 // CHECK:           %[[VAL_27:.*]] = fir.convert %[[VAL_2]] : (!fir.ref<!fir.class<!fir.heap<!fir.array<?x!fir.type<_QMtest_typeTt1{i:i32}>>>>>) -> !fir.box<none>
 // CHECK:           %[[VAL_28:.*]] = fir.call @_FortranADestroy(%[[VAL_27]]) fastmath<contract> : (!fir.box<none>) -> none
 // CHECK:           %[[VAL_29:.*]] = arith.constant 3 : index
 // CHECK:           %[[VAL_30:.*]] = fir.shape %[[VAL_29]] : (index) -> !fir.shape<1>
 // CHECK:           %[[VAL_31:.*]] = arith.constant 1 : index
 // CHECK:           fir.do_loop %[[VAL_32:.*]] = %[[VAL_31]] to %[[VAL_29]] step %[[VAL_31]] {
 // CHECK:             %[[VAL_33:.*]] = hlfir.designate %[[VAL_3]]#0 (%[[VAL_32]])  : (!fir.class<!fir.array<3x!fir.type<_QMtest_typeTt1{i:i32}>>>, index) -> !fir.class<!fir.type<_QMtest_typeTt1{i:i32}>>
-// CHECK:             %[[VAL_34:.*]] = hlfir.designate %[[VAL_25]] (%[[VAL_32]])  : (!fir.class<!fir.heap<!fir.array<?x!fir.type<_QMtest_typeTt1{i:i32}>>>>, index) -> !fir.class<!fir.type<_QMtest_typeTt1{i:i32}>>
+// CHECK:             %[[VAL_34:.*]] = hlfir.designate %[[VAL_14B]] (%[[VAL_32]])  : (!fir.class<!fir.heap<!fir.array<?x!fir.type<_QMtest_typeTt1{i:i32}>>>>, index) -> !fir.class<!fir.type<_QMtest_typeTt1{i:i32}>>
 // CHECK:             fir.dispatch "assign"(%[[VAL_33]] : !fir.class<!fir.type<_QMtest_typeTt1{i:i32}>>) (%[[VAL_33]], %[[VAL_34]] : !fir.class<!fir.type<_QMtest_typeTt1{i:i32}>>, !fir.class<!fir.type<_QMtest_typeTt1{i:i32}>>) {pass_arg_pos = 0 : i32}
 // CHECK:           }
-// CHECK:           %[[VAL_35:.*]] = fir.box_addr %[[VAL_26]] : (!fir.class<!fir.heap<!fir.array<?x!fir.type<_QMtest_typeTt1{i:i32}>>>>) -> !fir.heap<!fir.array<?x!fir.type<_QMtest_typeTt1{i:i32}>>>
+// CHECK:           %[[VAL_35:.*]] = fir.box_addr %[[VAL_14B]] : (!fir.class<!fir.heap<!fir.array<?x!fir.type<_QMtest_typeTt1{i:i32}>>>>) -> !fir.heap<!fir.array<?x!fir.type<_QMtest_typeTt1{i:i32}>>>
 // CHECK:           fir.freemem %[[VAL_35]] : !fir.heap<!fir.array<?x!fir.type<_QMtest_typeTt1{i:i32}>>>
 // CHECK:           return
 // CHECK:         }