// RUN: fir-opt --inline-elementals %s | FileCheck %s // check inlining one elemental into another // a = b * c + d func.func @inline_to_elemental(%arg0: !fir.box> {fir.bindc_name = "a"}, %arg1: !fir.box> {fir.bindc_name = "b"}, %arg2: !fir.box> {fir.bindc_name = "c"}, %arg3: !fir.box> {fir.bindc_name = "d"}) { %0:2 = hlfir.declare %arg0 {uniq_name = "a"} : (!fir.box>) -> (!fir.box>, !fir.box>) %1:2 = hlfir.declare %arg1 {uniq_name = "b"} : (!fir.box>) -> (!fir.box>, !fir.box>) %2:2 = hlfir.declare %arg2 {uniq_name = "c"} : (!fir.box>) -> (!fir.box>, !fir.box>) %3:2 = hlfir.declare %arg3 {uniq_name = "d"} : (!fir.box>) -> (!fir.box>, !fir.box>) %c0 = arith.constant 0 : index %4:3 = fir.box_dims %1#0, %c0 : (!fir.box>, index) -> (index, index, index) %5 = fir.shape %4#1 : (index) -> !fir.shape<1> %6 = hlfir.elemental %5 unordered : (!fir.shape<1>) -> !hlfir.expr { ^bb0(%arg4: index): %8 = hlfir.designate %1#0 (%arg4) : (!fir.box>, index) -> !fir.ref %9 = hlfir.designate %2#0 (%arg4) : (!fir.box>, index) -> !fir.ref %10 = fir.load %8 : !fir.ref %11 = fir.load %9 : !fir.ref %12 = arith.muli %10, %11 : i32 hlfir.yield_element %12 : i32 } %7 = hlfir.elemental %5 : (!fir.shape<1>) -> !hlfir.expr { ^bb0(%arg4: index): %8 = hlfir.apply %6, %arg4 : (!hlfir.expr, index) -> i32 %9 = hlfir.designate %3#0 (%arg4) : (!fir.box>, index) -> !fir.ref %10 = fir.load %9 : !fir.ref %11 = arith.addi %8, %10 : i32 hlfir.yield_element %11 : i32 } hlfir.assign %7 to %0#0 : !hlfir.expr, !fir.box> hlfir.destroy %7 : !hlfir.expr hlfir.destroy %6 : !hlfir.expr return } // CHECK-LABEL: func.func @inline_to_elemental // CHECK-SAME: %[[A_ARG:.*]]: !fir.box> {fir.bindc_name = "a"} // CHECK-SAME: %[[B_ARG:.*]]: !fir.box> {fir.bindc_name = "b"} // CHECK-SAME: %[[C_ARG:.*]]: !fir.box> {fir.bindc_name = "c"} // CHECK-SAME: %[[D_ARG:.*]]: !fir.box> {fir.bindc_name = "d"} // CHECK-NEXT: %[[C0:.*]] = arith.constant 0 : index // CHECK-DAG: %[[A:.*]]:2 = hlfir.declare %[[A_ARG]] // CHECK-DAG: %[[B:.*]]:2 = hlfir.declare %[[B_ARG]] // CHECK-DAG: %[[C:.*]]:2 = hlfir.declare %[[C_ARG]] // CHECK-DAG: %[[D:.*]]:2 = hlfir.declare %[[D_ARG]] // CHECK-NEXT: %[[B_DIM0:.*]]:3 = fir.box_dims %[[B]]#0, %[[C0]] // CHECK-NEXT: %[[B_SHAPE:.*]] = fir.shape %[[B_DIM0]]#1 // CHECK-NEXT: %[[EXPR:.*]] = hlfir.elemental %[[B_SHAPE]] // CHECK-NEXT: ^bb0(%[[I:.*]]: index): // inline the first elemental: // CHECK-NEXT: %[[B_I_REF:.*]] = hlfir.designate %[[B]]#0 (%[[I]]) // CHECK-NEXT: %[[C_I_REF:.*]] = hlfir.designate %[[C]]#0 (%[[I]]) // CHECK-NEXT: %[[B_I:.*]] = fir.load %[[B_I_REF]] // CHECK-NEXT: %[[C_I:.*]] = fir.load %[[C_I_REF]] // CHECK-NEXT: %[[MUL:.*]] = arith.muli %[[B_I]], %[[C_I]] // second elemental: // CHECK-NEXT: %[[D_I_REF:.*]] = hlfir.designate %[[D]]#0 (%[[I]]) // CHECK-NEXT: %[[D_I:.*]] = fir.load %[[D_I_REF]] // CHECK-NEXT: %[[ADD:.*]] = arith.addi %[[MUL]], %[[D_I]] // CHECK-NEXT: hlfir.yield_element %[[ADD]] // CHECK-NEXT: } // CHECK-NEXT: hlfir.assign %[[EXPR]] to %[[A]]#0 // CHECK-NEXT: hlfir.destroy %[[EXPR]] // CHECK-NEXT: return // CHECK-NEXT: } // check inlining into a do_loop func.func @inline_to_loop(%arg0: !fir.box> {fir.bindc_name = "a"}, %arg1: !fir.box> {fir.bindc_name = "b"}, %arg2: !fir.box> {fir.bindc_name = "c"}, %arg3: !fir.box> {fir.bindc_name = "d"}) { %0:2 = hlfir.declare %arg0 {uniq_name = "a"} : (!fir.box>) -> (!fir.box>, !fir.box>) %1:2 = hlfir.declare %arg1 {uniq_name = "b"} : (!fir.box>) -> (!fir.box>, !fir.box>) %2:2 = hlfir.declare %arg2 {uniq_name = "c"} : (!fir.box>) -> (!fir.box>, !fir.box>) %3:2 = hlfir.declare %arg3 {uniq_name = "d"} : (!fir.box>) -> (!fir.box>, !fir.box>) %c0 = arith.constant 0 : index %4:3 = fir.box_dims %1#0, %c0 : (!fir.box>, index) -> (index, index, index) %5 = fir.shape %4#1 : (index) -> !fir.shape<1> %6 = hlfir.elemental %5 unordered : (!fir.shape<1>) -> !hlfir.expr { ^bb0(%arg4: index): %8 = hlfir.designate %1#0 (%arg4) : (!fir.box>, index) -> !fir.ref %9 = hlfir.designate %2#0 (%arg4) : (!fir.box>, index) -> !fir.ref %10 = fir.load %8 : !fir.ref %11 = fir.load %9 : !fir.ref %12 = arith.muli %10, %11 : i32 hlfir.yield_element %12 : i32 } %array = fir.array_load %0#0 : (!fir.box>) -> !fir.array %c1 = arith.constant 1 : index %max = arith.subi %4#1, %c1 : index %7 = fir.do_loop %arg4 = %c0 to %max step %c1 unordered iter_args(%arg5 = %array) -> (!fir.array) { %8 = hlfir.apply %6, %arg4 : (!hlfir.expr, index) -> i32 %9 = hlfir.designate %3#0 (%arg4) : (!fir.box>, index) -> !fir.ref %10 = fir.load %9 : !fir.ref %11 = arith.addi %8, %10 : i32 %12 = fir.array_update %arg5, %11, %arg4 : (!fir.array, i32, index) -> !fir.array fir.result %12 : !fir.array } fir.array_merge_store %array, %7 to %arg0 : !fir.array, !fir.array, !fir.box> hlfir.destroy %6 : !hlfir.expr return } // CHECK-LABEL: func.func @inline_to_loop // CHECK-SAME: %[[A_ARG:.*]]: !fir.box> {fir.bindc_name = "a"} // CHECK-SAME: %[[B_ARG:.*]]: !fir.box> {fir.bindc_name = "b"} // CHECK-SAME: %[[C_ARG:.*]]: !fir.box> {fir.bindc_name = "c"} // CHECK-SAME: %[[D_ARG:.*]]: !fir.box> {fir.bindc_name = "d"} // CHECK-DAG: %[[C1:.*]] = arith.constant 1 : index // CHECK-DAG: %[[C0:.*]] = arith.constant 0 : index // CHECK-DAG: %[[A:.*]]:2 = hlfir.declare %[[A_ARG]] // CHECK-DAG: %[[B:.*]]:2 = hlfir.declare %[[B_ARG]] // CHECK-DAG: %[[C:.*]]:2 = hlfir.declare %[[C_ARG]] // CHECK-DAG: %[[D:.*]]:2 = hlfir.declare %[[D_ARG]] // CHECK-NEXT: %[[B_DIM0:.*]]:3 = fir.box_dims %[[B]]#0, %[[C0]] // CHECK-NEXT: %[[ARRAY:.*]] = fir.array_load %[[A]]#0 // CHECK-NEXT: %[[MAX:.*]] = arith.subi %[[B_DIM0]]#1, %[[C1]] // CHECK-NEXT: %[[LOOP:.*]] = fir.do_loop %[[I:.*]] = %[[C0]] to %[[MAX]] step %[[C1]] unordered iter_args(%[[LOOP_ARRAY:.*]] = %[[ARRAY]]) // inline the elemental: // CHECK-NEXT: %[[B_I_REF:.*]] = hlfir.designate %[[B]]#0 (%[[I]]) // CHECK-NEXT: %[[C_I_REF:.*]] = hlfir.designate %[[C]]#0 (%[[I]]) // CHECK-NEXT: %[[B_I:.*]] = fir.load %[[B_I_REF]] // CHECK-NEXT: %[[C_I:.*]] = fir.load %[[C_I_REF]] // CHECK-NEXT: %[[MUL:.*]] = arith.muli %[[B_I]], %[[C_I]] // loop body: // CHECK-NEXT: %[[D_I_REF:.*]] = hlfir.designate %[[D]]#0 (%[[I]]) // CHECK-NEXT: %[[D_I:.*]] = fir.load %[[D_I_REF]] // CHECK-NEXT: %[[ADD:.*]] = arith.addi %[[MUL]], %[[D_I]] // CHECK-NEXT: %[[ARRAY_UPD:.*]] = fir.array_update %[[LOOP_ARRAY]], %[[ADD]], %[[I]] // CHECK-NEXT: fir.result %[[ARRAY_UPD]] // CHECK-NEXT: } // CHECK-NEXT: fir.array_merge_store %[[ARRAY]], %[[LOOP]] to %[[A_ARG]] // CHECK-NEXT: return // CHECK-NEXT: } // inlining into a single hlfir.apply // a = (b * c)[1] func.func @inline_to_apply(%arg0: !fir.ref {fir.bindc_name = "a"}, %arg1: !fir.box> {fir.bindc_name = "b"}, %arg2: !fir.box> {fir.bindc_name = "c"}) { %0:2 = hlfir.declare %arg0 {uniq_name = "a"} : (!fir.ref) -> (!fir.ref, !fir.ref) %1:2 = hlfir.declare %arg1 {uniq_name = "b"} : (!fir.box>) -> (!fir.box>, !fir.box>) %2:2 = hlfir.declare %arg2 {uniq_name = "c"} : (!fir.box>) -> (!fir.box>, !fir.box>) %c0 = arith.constant 0 : index %4:3 = fir.box_dims %1#0, %c0 : (!fir.box>, index) -> (index, index, index) %5 = fir.shape %4#1 : (index) -> !fir.shape<1> %6 = hlfir.elemental %5 unordered : (!fir.shape<1>) -> !hlfir.expr { ^bb0(%arg4: index): %8 = hlfir.designate %1#0 (%arg4) : (!fir.box>, index) -> !fir.ref %9 = hlfir.designate %2#0 (%arg4) : (!fir.box>, index) -> !fir.ref %10 = fir.load %8 : !fir.ref %11 = fir.load %9 : !fir.ref %12 = arith.muli %10, %11 : i32 hlfir.yield_element %12 : i32 } %c1 = arith.constant 1 : index %res = hlfir.apply %6, %c1 : (!hlfir.expr, index) -> i32 fir.store %res to %0#0 : !fir.ref hlfir.destroy %6 : !hlfir.expr return } // CHECK-LABEL: func.func @inline_to_apply // CHECK-SAME: %[[A_ARG:.*]]: !fir.ref {fir.bindc_name = "a"} // CHECK-SAME: %[[B_ARG:.*]]: !fir.box> {fir.bindc_name = "b"} // CHECK-SAME: %[[C_ARG:.*]]: !fir.box> {fir.bindc_name = "c"} // CHECK-DAG: %[[C1:.*]] = arith.constant 1 : index // CHECK-DAG: %[[A:.*]]:2 = hlfir.declare %[[A_ARG]] // CHECK-DAG: %[[B:.*]]:2 = hlfir.declare %[[B_ARG]] // CHECK-DAG: %[[C:.*]]:2 = hlfir.declare %[[C_ARG]] // inline the elemental: // CHECK-NEXT: %[[B_1_REF:.*]] = hlfir.designate %[[B]]#0 (%[[C1]]) // CHECK-NEXT: %[[C_1_REF:.*]] = hlfir.designate %[[C]]#0 (%[[C1]]) // CHECK-NEXT: %[[B_1:.*]] = fir.load %[[B_1_REF]] // CHECK-NEXT: %[[C_1:.*]] = fir.load %[[C_1_REF]] // CHECK-NEXT: %[[MUL:.*]] = arith.muli %[[B_1]], %[[C_1]] // store: // CHECK-NEXT: fir.store %[[MUL]] to %0#0 : !fir.ref // CHECK-NEXT: return // CHECK-NEXT: } // Check long chains of elementals // subroutine reproducer(a) // real, dimension(:) :: a // a = sqrt(a * (a - 1)) // end subroutine func.func @_QPreproducer(%arg0: !fir.box> {fir.bindc_name = "a"}) { %0:2 = hlfir.declare %arg0 {uniq_name = "_QFreproducerEa"} : (!fir.box>) -> (!fir.box>, !fir.box>) %cst = arith.constant 1.000000e+00 : f32 %c0 = arith.constant 0 : index %1:3 = fir.box_dims %0#0, %c0 : (!fir.box>, index) -> (index, index, index) %2 = fir.shape %1#1 : (index) -> !fir.shape<1> %3 = hlfir.elemental %2 unordered : (!fir.shape<1>) -> !hlfir.expr { ^bb0(%arg1: index): %9 = hlfir.designate %0#0 (%arg1) : (!fir.box>, index) -> !fir.ref %10 = fir.load %9 : !fir.ref %11 = arith.subf %10, %cst fastmath : f32 hlfir.yield_element %11 : f32 } %4 = hlfir.elemental %2 unordered : (!fir.shape<1>) -> !hlfir.expr { ^bb0(%arg1: index): %9 = hlfir.apply %3, %arg1 : (!hlfir.expr, index) -> f32 %10 = hlfir.no_reassoc %9 : f32 hlfir.yield_element %10 : f32 } %c0_0 = arith.constant 0 : index %5:3 = fir.box_dims %0#0, %c0_0 : (!fir.box>, index) -> (index, index, index) %6 = fir.shape %5#1 : (index) -> !fir.shape<1> %7 = hlfir.elemental %6 unordered : (!fir.shape<1>) -> !hlfir.expr { ^bb0(%arg1: index): %9 = hlfir.designate %0#0 (%arg1) : (!fir.box>, index) -> !fir.ref %10 = hlfir.apply %4, %arg1 : (!hlfir.expr, index) -> f32 %11 = fir.load %9 : !fir.ref %12 = arith.mulf %11, %10 fastmath : f32 hlfir.yield_element %12 : f32 } %8 = hlfir.elemental %6 : (!fir.shape<1>) -> !hlfir.expr { ^bb0(%arg1: index): %9 = hlfir.apply %7, %arg1 : (!hlfir.expr, index) -> f32 %10 = math.sqrt %9 fastmath : f32 hlfir.yield_element %10 : f32 } hlfir.assign %8 to %0#0 : !hlfir.expr, !fir.box> hlfir.destroy %8 : !hlfir.expr hlfir.destroy %7 : !hlfir.expr hlfir.destroy %4 : !hlfir.expr hlfir.destroy %3 : !hlfir.expr return } // CHECK-LABEL: func.func @_QPreproducer // CHECK-SAME: %[[A_ARG:.*]]: !fir.box> {fir.bindc_name = "a"} // CHECK-DAG: %[[CST:.*]] = arith.constant 1.0000 // CHECK-DAG: %[[C0:.*]] = arith.constant 0 // CHECK-DAG: %[[A_VAR:.*]]:2 = hlfir.declare %[[A_ARG]] // CHECK-NEXT: %[[A_DIMS_0:.*]]:3 = fir.box_dims %[[A_VAR]]#0, %[[C0]] // CHECK-NEXT: %[[SHAPE_0:.*]] = fir.shape %[[A_DIMS_0]]#1 // all in one elemental: // CHECK-NEXT: %[[EXPR:.*]] = hlfir.elemental %[[SHAPE_0]] // CHECK-NEXT: ^bb0(%[[I:.*]]: index): // CHECK-NEXT: %[[A_I0:.*]] = hlfir.designate %[[A_VAR]]#0 (%[[I]]) // CHECK-NEXT: %[[A_I1:.*]] = hlfir.designate %[[A_VAR]]#0 (%[[I]]) // CHECK-NEXT: %[[A_I1_VAL:.*]] = fir.load %[[A_I1]] // CHECK-NEXT: %[[SUB:.*]] = arith.subf %[[A_I1_VAL]], %[[CST]] // CHECK-NEXT: %[[SUB0:.*]] = hlfir.no_reassoc %[[SUB]] : f32 // CHECK-NEXT: %[[A_I0_VAL:.*]] = fir.load %[[A_I0]] // CHECK-NEXT: %[[MUL:.*]] = arith.mulf %[[A_I0_VAL]], %[[SUB0]] // CHECK-NEXT: %[[SQRT:.*]] = math.sqrt %[[MUL]] // CHECK-NEXT: hlfir.yield_element %[[SQRT]] // CHECK-NEXT: } // CHECK-NEXT: hlfir.assign %[[EXPR]] to %[[A_VAR]]#0 // CHECK-NEXT: hlfir.destroy %[[EXPR]] // CHECK-NEXT: return // CHECK-NEXT: } // Check that the ordered elemental is not inlined into another: // a = b + c + d func.func @noinline_ordered(%arg0: !fir.box> {fir.bindc_name = "a"}, %arg1: !fir.box> {fir.bindc_name = "b"}, %arg2: !fir.box> {fir.bindc_name = "c"}, %arg3: !fir.box> {fir.bindc_name = "d"}) { %0:2 = hlfir.declare %arg0 {uniq_name = "a"} : (!fir.box>) -> (!fir.box>, !fir.box>) %1:2 = hlfir.declare %arg1 {uniq_name = "b"} : (!fir.box>) -> (!fir.box>, !fir.box>) %2:2 = hlfir.declare %arg2 {uniq_name = "c"} : (!fir.box>) -> (!fir.box>, !fir.box>) %3:2 = hlfir.declare %arg3 {uniq_name = "d"} : (!fir.box>) -> (!fir.box>, !fir.box>) %c0 = arith.constant 0 : index %4:3 = fir.box_dims %1#0, %c0 : (!fir.box>, index) -> (index, index, index) %5 = fir.shape %4#1 : (index) -> !fir.shape<1> %6 = hlfir.elemental %5 : (!fir.shape<1>) -> !hlfir.expr { ^bb0(%arg4: index): %8 = hlfir.designate %1#0 (%arg4) : (!fir.box>, index) -> !fir.ref %9 = hlfir.designate %2#0 (%arg4) : (!fir.box>, index) -> !fir.ref %10 = fir.load %8 : !fir.ref %11 = fir.load %9 : !fir.ref %12 = arith.muli %10, %11 : i32 hlfir.yield_element %12 : i32 } %7 = hlfir.elemental %5 unordered : (!fir.shape<1>) -> !hlfir.expr { ^bb0(%arg4: index): %8 = hlfir.apply %6, %arg4 : (!hlfir.expr, index) -> i32 %9 = hlfir.designate %3#0 (%arg4) : (!fir.box>, index) -> !fir.ref %10 = fir.load %9 : !fir.ref %11 = arith.addi %8, %10 : i32 hlfir.yield_element %11 : i32 } hlfir.assign %7 to %0#0 : !hlfir.expr, !fir.box> hlfir.destroy %7 : !hlfir.expr hlfir.destroy %6 : !hlfir.expr return } // CHECK-LABEL: func.func @noinline_ordered( // CHECK-SAME: %[[VAL_0:.*]]: !fir.box> {fir.bindc_name = "a"}, // CHECK-SAME: %[[VAL_1:.*]]: !fir.box> {fir.bindc_name = "b"}, // CHECK-SAME: %[[VAL_2:.*]]: !fir.box> {fir.bindc_name = "c"}, // CHECK-SAME: %[[VAL_3:.*]]: !fir.box> {fir.bindc_name = "d"}) { // CHECK: %[[VAL_4:.*]] = arith.constant 0 : index // CHECK: %[[VAL_5:.*]]:2 = hlfir.declare %[[VAL_0]] {uniq_name = "a"} : (!fir.box>) -> (!fir.box>, !fir.box>) // CHECK: %[[VAL_6:.*]]:2 = hlfir.declare %[[VAL_1]] {uniq_name = "b"} : (!fir.box>) -> (!fir.box>, !fir.box>) // CHECK: %[[VAL_7:.*]]:2 = hlfir.declare %[[VAL_2]] {uniq_name = "c"} : (!fir.box>) -> (!fir.box>, !fir.box>) // CHECK: %[[VAL_8:.*]]:2 = hlfir.declare %[[VAL_3]] {uniq_name = "d"} : (!fir.box>) -> (!fir.box>, !fir.box>) // CHECK: %[[VAL_9:.*]]:3 = fir.box_dims %[[VAL_6]]#0, %[[VAL_4]] : (!fir.box>, index) -> (index, index, index) // CHECK: %[[VAL_10:.*]] = fir.shape %[[VAL_9]]#1 : (index) -> !fir.shape<1> // CHECK: %[[VAL_11:.*]] = hlfir.elemental %[[VAL_10]] : (!fir.shape<1>) -> !hlfir.expr { // CHECK: ^bb0(%[[VAL_12:.*]]: index): // CHECK: %[[VAL_13:.*]] = hlfir.designate %[[VAL_6]]#0 (%[[VAL_12]]) : (!fir.box>, index) -> !fir.ref // CHECK: %[[VAL_14:.*]] = hlfir.designate %[[VAL_7]]#0 (%[[VAL_12]]) : (!fir.box>, index) -> !fir.ref // CHECK: %[[VAL_15:.*]] = fir.load %[[VAL_13]] : !fir.ref // CHECK: %[[VAL_16:.*]] = fir.load %[[VAL_14]] : !fir.ref // CHECK: %[[VAL_17:.*]] = arith.muli %[[VAL_15]], %[[VAL_16]] : i32 // CHECK: hlfir.yield_element %[[VAL_17]] : i32 // CHECK: } // CHECK: %[[VAL_18:.*]] = hlfir.elemental %[[VAL_10]] unordered : (!fir.shape<1>) -> !hlfir.expr { // CHECK: ^bb0(%[[VAL_19:.*]]: index): // CHECK: %[[VAL_20:.*]] = hlfir.apply %[[VAL_21:.*]], %[[VAL_19]] : (!hlfir.expr, index) -> i32 // CHECK: %[[VAL_22:.*]] = hlfir.designate %[[VAL_8]]#0 (%[[VAL_19]]) : (!fir.box>, index) -> !fir.ref // CHECK: %[[VAL_23:.*]] = fir.load %[[VAL_22]] : !fir.ref // CHECK: %[[VAL_24:.*]] = arith.addi %[[VAL_20]], %[[VAL_23]] : i32 // CHECK: hlfir.yield_element %[[VAL_24]] : i32 // CHECK: } // CHECK: hlfir.assign %[[VAL_25:.*]] to %[[VAL_5]]#0 : !hlfir.expr, !fir.box> // CHECK: hlfir.destroy %[[VAL_25]] : !hlfir.expr // CHECK: hlfir.destroy %[[VAL_26:.*]] : !hlfir.expr // CHECK: return // CHECK: } // Check that the elemental is not inlined, because its array result // must be finalized. // FIXME: the inlining is actually blocked by the type check // between the yield_element and apply. When this is fixed, // the test should keep passing. func.func @noinline_due_to_finalization(%arg0: !fir.box>> {fir.bindc_name = "x"}) { %c0 = arith.constant 0 : index %0 = fir.alloca !fir.type<_QMtypesTt1{x:f32}> {bindc_name = ".result"} %1:2 = hlfir.declare %arg0 {uniq_name = "_QFtest1Ex"} : (!fir.box>>) -> (!fir.box>>, !fir.box>>) %2:3 = fir.box_dims %1#0, %c0 : (!fir.box>>, index) -> (index, index, index) %3 = fir.shape %2#1 : (index) -> !fir.shape<1> %4 = hlfir.elemental %3 unordered : (!fir.shape<1>) -> !hlfir.expr> { ^bb0(%arg1: index): %6 = hlfir.designate %1#0 (%arg1) : (!fir.box>>, index) -> !fir.ref> %7 = fir.call @_QPelem1(%6) fastmath : (!fir.ref>) -> !fir.type<_QMtypesTt1{x:f32}> fir.save_result %7 to %0 : !fir.type<_QMtypesTt1{x:f32}>, !fir.ref> %8:2 = hlfir.declare %0 {uniq_name = ".tmp.func_result"} : (!fir.ref>) -> (!fir.ref>, !fir.ref>) hlfir.yield_element %8#0 : !fir.ref> } %5 = hlfir.elemental %3 unordered : (!fir.shape<1>) -> !hlfir.expr> { ^bb0(%arg1: index): %6 = hlfir.apply %4, %arg1 : (!hlfir.expr>, index) -> !hlfir.expr> %7 = hlfir.no_reassoc %6 : !hlfir.expr> hlfir.yield_element %7 : !hlfir.expr> } hlfir.assign %5 to %1#0 : !hlfir.expr>, !fir.box>> hlfir.destroy %5 : !hlfir.expr> hlfir.destroy %4 finalize : !hlfir.expr> return } // CHECK-LABEL: func.func @noinline_due_to_finalization( // CHECK: %[[VAL_6:.*]] = hlfir.elemental %{{.*}} unordered : (!fir.shape<1>) -> !hlfir.expr> { // CHECK: %[[VAL_11:.*]] = hlfir.elemental %{{.*}} unordered : (!fir.shape<1>) -> !hlfir.expr> { // CHECK: %[[VAL_13:.*]] = hlfir.apply %[[VAL_6]], %{{.*}} : (!hlfir.expr>, index) -> !hlfir.expr> // CHECK: hlfir.destroy %[[VAL_11]] : !hlfir.expr> // CHECK: hlfir.destroy %[[VAL_6]] finalize : !hlfir.expr>