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Differential D144380

[MLIR][OpenMP] Add conversion support from FIR to LLVM Dialect for OMP Target Data with region
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Authored by TIFitis on Feb 20 2023, 4:21 AM.

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Reviewers
kiranchandramohan
raghavendhra
domada
clementval
agozillon
skatrak
ftynse
jdoerfert
dcaballe
Commits
rGaf694df712f2: [MLIR][OpenMP] Add conversion support from FIR to LLVM Dialect for OMP Target…
Summary

This enables conversion of OpenMP Target Data op with region from FIR Dialect to LLVM IR Dialect.

Diff Detail

Event Timeline

TIFitis created this revision.Feb 20 2023, 4:21 AM
Herald added a reviewer: ftynse. · View Herald TranscriptFeb 20 2023, 4:21 AM
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TIFitis requested review of this revision.Feb 20 2023, 4:21 AM
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Harbormaster completed remote builds in B214727: Diff 498796.Feb 20 2023, 4:23 AM
TIFitis added a comment.Feb 20 2023, 4:31 AM

When trying to lower the following Fortran code to FIR and then LLVMIR I am getting an error in fir-opt which I'm not quite sure how to fix. Any hints/inputs would be greatly appreciated.

Fortran Code:

subroutine openmp_target_data
    integer :: a(1024), i
    !$omp target data map(tofrom: a)
        do i = 1, 1024
            a(i) = i
        end do
    !$omp end target data
end subroutine openmp_target_data

FIR: flang-new -fc1 -emit-fir -fopenmp test.f90 -o test.fir

func.func @_QPopenmp_target_data() {
  %0 = fir.alloca !fir.array<1024xi32> {bindc_name = "a", uniq_name = "_QFopenmp_target_dataEa"}
  %1 = fir.alloca i32 {bindc_name = "i", uniq_name = "_QFopenmp_target_dataEi"}
  omp.target_data   map((tofrom -> %0 : !fir.ref<!fir.array<1024xi32>>)) {
    %c1_i32 = arith.constant 1 : i32
    %2 = fir.convert %c1_i32 : (i32) -> index
    %c1024_i32 = arith.constant 1024 : i32
    %3 = fir.convert %c1024_i32 : (i32) -> index
    %c1 = arith.constant 1 : index
    %4 = fir.convert %2 : (index) -> i32
    %5:2 = fir.do_loop %arg0 = %2 to %3 step %c1 iter_args(%arg1 = %4) -> (index, i32) {
      fir.store %arg1 to %1 : !fir.ref<i32>
      %6 = fir.load %1 : !fir.ref<i32>
      %7 = fir.load %1 : !fir.ref<i32>
      %8 = fir.convert %7 : (i32) -> i64
      %c1_i64 = arith.constant 1 : i64
      %9 = arith.subi %8, %c1_i64 : i64
      %10 = fir.coordinate_of %0, %9 : (!fir.ref<!fir.array<1024xi32>>, i64) -> !fir.ref<i32>
      fir.store %6 to %10 : !fir.ref<i32>
      %11 = arith.addi %arg0, %c1 : index
      %12 = fir.convert %c1 : (index) -> i32
      %13 = fir.load %1 : !fir.ref<i32>
      %14 = arith.addi %13, %12 : i32
      fir.result %11, %14 : index, i32
    }
    fir.store %5#1 to %1 : !fir.ref<i32>
    omp.terminator
  }
  return
}

LLVMIR: fir-opt --fir-to-llvm-ir="target=aarch64-unknown-linux-gnu" test.fir -o test.mlir

test.fir:12:14: error: failed to legalize operation 'fir.do_loop'
      %5:2 = fir.do_loop %arg0 = %2 to %3 step %c1 iter_args(%arg1 = %4) -> (index, i32) {
             ^
test.fir:12:14: note: see current operation: 
%18:2 = "fir.do_loop"(%9, %13, %15, %17) ({
^bb0(%arg0: index, %arg1: i32):
  "fir.store"(%arg1, %5) : (i32, !fir.ref<i32>) -> ()
  %19 = "fir.load"(%5) : (!fir.ref<i32>) -> i32
  %20 = "fir.load"(%5) : (!fir.ref<i32>) -> i32
  %21 = "fir.convert"(%20) : (i32) -> i64
  %22 = "arith.constant"() {value = 1 : i64} : () -> i64
  %23 = "arith.subi"(%21, %22) : (i64, i64) -> i64
  %24 = "fir.coordinate_of"(%2, %23) {baseType = !fir.ref<!fir.array<1024xi32>>} : (!fir.ref<!fir.array<1024xi32>>, i64) -> !fir.ref<i32>
  "fir.store"(%19, %24) : (i32, !fir.ref<i32>) -> ()
  %25 = "arith.addi"(%arg0, %15) : (index, index) -> index
  %26 = "fir.convert"(%15) : (index) -> i32
  %27 = "fir.load"(%5) : (!fir.ref<i32>) -> i32
  %28 = "arith.addi"(%27, %26) : (i32, i32) -> i32
  "fir.result"(%25, %28) : (index, i32) -> ()
}) {finalValue} : (index, index, index, i32) -> (index, i32)

Thanks,
Akash

kiranchandramohan added a comment.Feb 20 2023, 10:19 AM
In D144380#4138622, @TIFitis wrote:

When trying to lower the following Fortran code to FIR and then LLVMIR I am getting an error in fir-opt which I'm not quite sure how to fix. Any hints/inputs would be greatly appreciated.

Fortran Code:

subroutine openmp_target_data
    integer :: a(1024), i
    !$omp target data map(tofrom: a)
        do i = 1, 1024
            a(i) = i
        end do
    !$omp end target data
end subroutine openmp_target_data

FIR: flang-new -fc1 -emit-fir -fopenmp test.f90 -o test.fir

func.func @_QPopenmp_target_data() {
  %0 = fir.alloca !fir.array<1024xi32> {bindc_name = "a", uniq_name = "_QFopenmp_target_dataEa"}
  %1 = fir.alloca i32 {bindc_name = "i", uniq_name = "_QFopenmp_target_dataEi"}
  omp.target_data   map((tofrom -> %0 : !fir.ref<!fir.array<1024xi32>>)) {
    %c1_i32 = arith.constant 1 : i32
    %2 = fir.convert %c1_i32 : (i32) -> index
    %c1024_i32 = arith.constant 1024 : i32
    %3 = fir.convert %c1024_i32 : (i32) -> index
    %c1 = arith.constant 1 : index
    %4 = fir.convert %2 : (index) -> i32
    %5:2 = fir.do_loop %arg0 = %2 to %3 step %c1 iter_args(%arg1 = %4) -> (index, i32) {
      fir.store %arg1 to %1 : !fir.ref<i32>
      %6 = fir.load %1 : !fir.ref<i32>
      %7 = fir.load %1 : !fir.ref<i32>
      %8 = fir.convert %7 : (i32) -> i64
      %c1_i64 = arith.constant 1 : i64
      %9 = arith.subi %8, %c1_i64 : i64
      %10 = fir.coordinate_of %0, %9 : (!fir.ref<!fir.array<1024xi32>>, i64) -> !fir.ref<i32>
      fir.store %6 to %10 : !fir.ref<i32>
      %11 = arith.addi %arg0, %c1 : index
      %12 = fir.convert %c1 : (index) -> i32
      %13 = fir.load %1 : !fir.ref<i32>
      %14 = arith.addi %13, %12 : i32
      fir.result %11, %14 : index, i32
    }
    fir.store %5#1 to %1 : !fir.ref<i32>
    omp.terminator
  }
  return
}

LLVMIR: fir-opt --fir-to-llvm-ir="target=aarch64-unknown-linux-gnu" test.fir -o test.mlir

test.fir:12:14: error: failed to legalize operation 'fir.do_loop'
      %5:2 = fir.do_loop %arg0 = %2 to %3 step %c1 iter_args(%arg1 = %4) -> (index, i32) {
             ^
test.fir:12:14: note: see current operation: 
%18:2 = "fir.do_loop"(%9, %13, %15, %17) ({
^bb0(%arg0: index, %arg1: i32):
  "fir.store"(%arg1, %5) : (i32, !fir.ref<i32>) -> ()
  %19 = "fir.load"(%5) : (!fir.ref<i32>) -> i32
  %20 = "fir.load"(%5) : (!fir.ref<i32>) -> i32
  %21 = "fir.convert"(%20) : (i32) -> i64
  %22 = "arith.constant"() {value = 1 : i64} : () -> i64
  %23 = "arith.subi"(%21, %22) : (i64, i64) -> i64
  %24 = "fir.coordinate_of"(%2, %23) {baseType = !fir.ref<!fir.array<1024xi32>>} : (!fir.ref<!fir.array<1024xi32>>, i64) -> !fir.ref<i32>
  "fir.store"(%19, %24) : (i32, !fir.ref<i32>) -> ()
  %25 = "arith.addi"(%arg0, %15) : (index, index) -> index
  %26 = "fir.convert"(%15) : (index) -> i32
  %27 = "fir.load"(%5) : (!fir.ref<i32>) -> i32
  %28 = "arith.addi"(%27, %26) : (i32, i32) -> i32
  "fir.result"(%25, %28) : (index, i32) -> ()
}) {finalValue} : (index, index, index, i32) -> (index, i32)

Thanks,
Akash

FIR to LLVM IR conversion happens as a sequence of passes. All FIR operations cannot be converted to LLVM using the fir-to-llvm-ir Conversion pass. We have to run other passes before it. In this specific case only cfg-conversion need to be run.

fir-opt --cfg-conversion --fir-to-llvm-ir="target=aarch64-unknown-linux-gnu" test.fir -o test.mlir
TIFitis updated this revision to Diff 499155.Feb 21 2023, 6:51 AM

Added tests.

Herald added a project: Restricted Project. · View Herald TranscriptFeb 21 2023, 6:51 AM
Harbormaster completed remote builds in B215008: Diff 499155.Feb 21 2023, 6:52 AM
TIFitis updated this revision to Diff 499156.Feb 21 2023, 6:54 AM

Updated check regex in test.

Harbormaster completed remote builds in B215009: Diff 499156.Feb 21 2023, 6:54 AM
TIFitis updated this revision to Diff 499558.Feb 22 2023, 9:35 AM

Rebased

kiranchandramohan added inline comments.Feb 22 2023, 9:41 AM
mlir/lib/Conversion/OpenMPToLLVM/OpenMPToLLVM.cpp
178–187

Wouldn't this Operation require a region conversion as well?

TIFitis marked an inline comment as done.Feb 22 2023, 10:51 AM
TIFitis added inline comments.
mlir/lib/Conversion/OpenMPToLLVM/OpenMPToLLVM.cpp
178–187

Yes, its present in line 189.

Harbormaster completed remote builds in B215297: Diff 499558.Feb 22 2023, 12:19 PM
kiranchandramohan accepted this revision.Feb 22 2023, 3:22 PM
This revision is now accepted and ready to land.Feb 22 2023, 3:22 PM
TIFitis edited the summary of this revision. (Show Details)Feb 23 2023, 9:00 AM
Closed by commit rGaf694df712f2: [MLIR][OpenMP] Add conversion support from FIR to LLVM Dialect for OMP Target… (authored by TIFitis). · Explain WhyFeb 23 2023, 9:01 AM
This revision was automatically updated to reflect the committed changes.
TIFitis marked an inline comment as done.
TIFitis added a commit: rGaf694df712f2: [MLIR][OpenMP] Add conversion support from FIR to LLVM Dialect for OMP Target….

Revision Contents

PathSize
flang/
test/
Fir/
81 lines
mlir/
lib/
Conversion/
OpenMPToLLVM/
55 lines
test/
Conversion/
OpenMPToLLVM/
20 lines

Diff 499883

flang/test/Fir/convert-to-llvm-openmp-and-fir.fir

Show First 20 LinesShow All 66 Lines▼ Show 20 Lines
// CHECK: llvm.store %[[N]], %[[X_REF]] : !llvm.ptr<i32> // CHECK: llvm.store %[[N]], %[[X_REF]] : !llvm.ptr<i32>
// CHECK: omp.terminator // CHECK: omp.terminator
// CHECK: } // CHECK: }
// CHECK: omp.terminator // CHECK: omp.terminator
// CHECK: } // CHECK: }
// CHECK: llvm.return // CHECK: llvm.return
// CHECK: } // CHECK: }
// ----- // -----
func.func @_QPsb(%arr: !fir.box<!fir.array<?xi32>> {fir.bindc_name = "arr"}) { func.func @_QPsb(%arr: !fir.box<!fir.array<?xi32>> {fir.bindc_name = "arr"}) {
%0 = fir.alloca i32 {bindc_name = "i", uniq_name = "_QFsbEi"} %0 = fir.alloca i32 {bindc_name = "i", uniq_name = "_QFsbEi"}
omp.parallel { omp.parallel {
%c1 = arith.constant 1 : i32 %c1 = arith.constant 1 : i32
%c50 = arith.constant 50 : i32 %c50 = arith.constant 50 : i32
omp.wsloop for (%indx) : i32 = (%c1) to (%c50) inclusive step (%c1) { omp.wsloop for (%indx) : i32 = (%c1) to (%c50) inclusive step (%c1) {
▲ Show 20 LinesShow All 129 Lines▼ Show 20 Lines
// CHECK: llvm.store %[[I1]], %[[ARR_I_REF]] : !llvm.ptr<i32> // CHECK: llvm.store %[[I1]], %[[ARR_I_REF]] : !llvm.ptr<i32>
// CHECK: omp.yield // CHECK: omp.yield
// CHECK: } // CHECK: }
// CHECK: omp.terminator // CHECK: omp.terminator
// CHECK: } // CHECK: }
// CHECK: llvm.return // CHECK: llvm.return
// CHECK: } // CHECK: }
// -----
func.func @_QPomp_target_data() { func.func @_QPomp_target_data() {
%0 = fir.alloca !fir.array<1024xi32> {bindc_name = "a", uniq_name = "_QFomp_target_dataEa"} %0 = fir.alloca !fir.array<1024xi32> {bindc_name = "a", uniq_name = "_QFomp_target_dataEa"}
%1 = fir.alloca !fir.array<1024xi32> {bindc_name = "b", uniq_name = "_QFomp_target_dataEb"} %1 = fir.alloca !fir.array<1024xi32> {bindc_name = "b", uniq_name = "_QFomp_target_dataEb"}
%2 = fir.alloca !fir.array<1024xi32> {bindc_name = "c", uniq_name = "_QFomp_target_dataEc"} %2 = fir.alloca !fir.array<1024xi32> {bindc_name = "c", uniq_name = "_QFomp_target_dataEc"}
%3 = fir.alloca !fir.array<1024xi32> {bindc_name = "d", uniq_name = "_QFomp_target_dataEd"} %3 = fir.alloca !fir.array<1024xi32> {bindc_name = "d", uniq_name = "_QFomp_target_dataEd"}
omp.target_enter_data map((to -> %0 : !fir.ref<!fir.array<1024xi32>>), (to -> %1 : !fir.ref<!fir.array<1024xi32>>), (always, alloc -> %2 : !fir.ref<!fir.array<1024xi32>>)) omp.target_enter_data map((to -> %0 : !fir.ref<!fir.array<1024xi32>>), (to -> %1 : !fir.ref<!fir.array<1024xi32>>), (always, alloc -> %2 : !fir.ref<!fir.array<1024xi32>>))
omp.target_exit_data map((from -> %0 : !fir.ref<!fir.array<1024xi32>>), (from -> %1 : !fir.ref<!fir.array<1024xi32>>), (release -> %2 : !fir.ref<!fir.array<1024xi32>>), (always, delete -> %3 : !fir.ref<!fir.array<1024xi32>>)) omp.target_exit_data map((from -> %0 : !fir.ref<!fir.array<1024xi32>>), (from -> %1 : !fir.ref<!fir.array<1024xi32>>), (release -> %2 : !fir.ref<!fir.array<1024xi32>>), (always, delete -> %3 : !fir.ref<!fir.array<1024xi32>>))
return return
} }
// CHECK-LABEL: llvm.func @_QPomp_target_data() { // CHECK-LABEL: llvm.func @_QPomp_target_data() {
// CHECK: %[[VAL_0:.*]] = llvm.mlir.constant(1 : i64) : i64 // CHECK: %[[VAL_0:.*]] = llvm.mlir.constant(1 : i64) : i64
// CHECK: %[[VAL_1:.*]] = llvm.alloca %[[VAL_0]] x !llvm.array<1024 x i32> {bindc_name = "a", in_type = !fir.array<1024xi32>, operand_segment_sizes = array<i32: 0, 0>, uniq_name = "_QFomp_target_dataEa"} : (i64) -> !llvm.ptr<array<1024 x i32>> // CHECK: %[[VAL_1:.*]] = llvm.alloca %[[VAL_0]] x !llvm.array<1024 x i32> {bindc_name = "a", in_type = !fir.array<1024xi32>, operand_segment_sizes = array<i32: 0, 0>, uniq_name = "_QFomp_target_dataEa"} : (i64) -> !llvm.ptr<array<1024 x i32>>
// CHECK: %[[VAL_2:.*]] = llvm.mlir.constant(1 : i64) : i64 // CHECK: %[[VAL_2:.*]] = llvm.mlir.constant(1 : i64) : i64
// CHECK: %[[VAL_3:.*]] = llvm.alloca %[[VAL_2]] x !llvm.array<1024 x i32> {bindc_name = "b", in_type = !fir.array<1024xi32>, operand_segment_sizes = array<i32: 0, 0>, uniq_name = "_QFomp_target_dataEb"} : (i64) -> !llvm.ptr<array<1024 x i32>> // CHECK: %[[VAL_3:.*]] = llvm.alloca %[[VAL_2]] x !llvm.array<1024 x i32> {bindc_name = "b", in_type = !fir.array<1024xi32>, operand_segment_sizes = array<i32: 0, 0>, uniq_name = "_QFomp_target_dataEb"} : (i64) -> !llvm.ptr<array<1024 x i32>>
// CHECK: %[[VAL_4:.*]] = llvm.mlir.constant(1 : i64) : i64 // CHECK: %[[VAL_4:.*]] = llvm.mlir.constant(1 : i64) : i64
// CHECK: %[[VAL_5:.*]] = llvm.alloca %[[VAL_4]] x !llvm.array<1024 x i32> {bindc_name = "c", in_type = !fir.array<1024xi32>, operand_segment_sizes = array<i32: 0, 0>, uniq_name = "_QFomp_target_dataEc"} : (i64) -> !llvm.ptr<array<1024 x i32>> // CHECK: %[[VAL_5:.*]] = llvm.alloca %[[VAL_4]] x !llvm.array<1024 x i32> {bindc_name = "c", in_type = !fir.array<1024xi32>, operand_segment_sizes = array<i32: 0, 0>, uniq_name = "_QFomp_target_dataEc"} : (i64) -> !llvm.ptr<array<1024 x i32>>
// CHECK: %[[VAL_6:.*]] = llvm.mlir.constant(1 : i64) : i64 // CHECK: %[[VAL_6:.*]] = llvm.mlir.constant(1 : i64) : i64
// CHECK: %[[VAL_7:.*]] = llvm.alloca %[[VAL_6]] x !llvm.array<1024 x i32> {bindc_name = "d", in_type = !fir.array<1024xi32>, operand_segment_sizes = array<i32: 0, 0>, uniq_name = "_QFomp_target_dataEd"} : (i64) -> !llvm.ptr<array<1024 x i32>> // CHECK: %[[VAL_7:.*]] = llvm.alloca %[[VAL_6]] x !llvm.array<1024 x i32> {bindc_name = "d", in_type = !fir.array<1024xi32>, operand_segment_sizes = array<i32: 0, 0>, uniq_name = "_QFomp_target_dataEd"} : (i64) -> !llvm.ptr<array<1024 x i32>>
// CHECK: omp.target_enter_data map((to -> %[[VAL_1]] : !llvm.ptr<array<1024 x i32>>), (to -> %[[VAL_3]] : !llvm.ptr<array<1024 x i32>>), (always, alloc -> %[[VAL_5]] : !llvm.ptr<array<1024 x i32>>)) // CHECK: omp.target_enter_data map((to -> %[[VAL_1]] : !llvm.ptr<array<1024 x i32>>), (to -> %[[VAL_3]] : !llvm.ptr<array<1024 x i32>>), (always, alloc -> %[[VAL_5]] : !llvm.ptr<array<1024 x i32>>))
// CHECK: omp.target_exit_data map((from -> %[[VAL_1]] : !llvm.ptr<array<1024 x i32>>), (from -> %[[VAL_3]] : !llvm.ptr<array<1024 x i32>>), (release -> %[[VAL_5]] : !llvm.ptr<array<1024 x i32>>), (always, delete -> %[[VAL_7]] : !llvm.ptr<array<1024 x i32>>)) // CHECK: omp.target_exit_data map((from -> %[[VAL_1]] : !llvm.ptr<array<1024 x i32>>), (from -> %[[VAL_3]] : !llvm.ptr<array<1024 x i32>>), (release -> %[[VAL_5]] : !llvm.ptr<array<1024 x i32>>), (always, delete -> %[[VAL_7]] : !llvm.ptr<array<1024 x i32>>))
// CHECK: llvm.return // CHECK: llvm.return
// CHECK: } // CHECK: }
// -----
func.func @_QPopenmp_target_data_region() {
%0 = fir.alloca !fir.array<1024xi32> {bindc_name = "a", uniq_name = "_QFopenmp_target_data_regionEa"}
%1 = fir.alloca i32 {bindc_name = "i", uniq_name = "_QFopenmp_target_data_regionEi"}
omp.target_data map((tofrom -> %0 : !fir.ref<!fir.array<1024xi32>>)) {
%c1_i32 = arith.constant 1 : i32
%2 = fir.convert %c1_i32 : (i32) -> index
%c1024_i32 = arith.constant 1024 : i32
%3 = fir.convert %c1024_i32 : (i32) -> index
%c1 = arith.constant 1 : index
%4 = fir.convert %2 : (index) -> i32
%5:2 = fir.do_loop %arg0 = %2 to %3 step %c1 iter_args(%arg1 = %4) -> (index, i32) {
fir.store %arg1 to %1 : !fir.ref<i32>
%6 = fir.load %1 : !fir.ref<i32>
%7 = fir.load %1 : !fir.ref<i32>
%8 = fir.convert %7 : (i32) -> i64
%c1_i64 = arith.constant 1 : i64
%9 = arith.subi %8, %c1_i64 : i64
%10 = fir.coordinate_of %0, %9 : (!fir.ref<!fir.array<1024xi32>>, i64) -> !fir.ref<i32>
fir.store %6 to %10 : !fir.ref<i32>
%11 = arith.addi %arg0, %c1 : index
%12 = fir.convert %c1 : (index) -> i32
%13 = fir.load %1 : !fir.ref<i32>
%14 = arith.addi %13, %12 : i32
fir.result %11, %14 : index, i32
}
fir.store %5#1 to %1 : !fir.ref<i32>
omp.terminator
}
return
}
// CHECK-LABEL: llvm.func @_QPopenmp_target_data_region() {
// CHECK: %[[VAL_0:.*]] = llvm.mlir.constant(1 : i64) : i64
// CHECK: %[[VAL_1:.*]] = llvm.alloca %[[VAL_0]] x !llvm.array<1024 x i32> {bindc_name = "a", in_type = !fir.array<1024xi32>, operand_segment_sizes = array<i32: 0, 0>, uniq_name = "_QFopenmp_target_data_regionEa"} : (i64) -> !llvm.ptr<array<1024 x i32>>
// CHECK: %[[VAL_2:.*]] = llvm.mlir.constant(1 : i64) : i64
// CHECK: %[[VAL_3:.*]] = llvm.alloca %[[VAL_2]] x i32 {bindc_name = "i", in_type = i32, operand_segment_sizes = array<i32: 0, 0>, uniq_name = "_QFopenmp_target_data_regionEi"} : (i64) -> !llvm.ptr<i32>
// CHECK: omp.target_data map((tofrom -> %[[VAL_1]] : !llvm.ptr<array<1024 x i32>>)) {
// CHECK: %[[VAL_4:.*]] = llvm.mlir.constant(1 : i32) : i32
// CHECK: %[[VAL_5:.*]] = llvm.sext %[[VAL_4]] : i32 to i64
// CHECK: %[[VAL_6:.*]] = llvm.mlir.constant(1024 : i32) : i32
// CHECK: %[[VAL_7:.*]] = llvm.sext %[[VAL_6]] : i32 to i64
// CHECK: %[[VAL_8:.*]] = llvm.mlir.constant(1 : index) : i64
// CHECK: %[[VAL_9:.*]] = llvm.trunc %[[VAL_5]] : i64 to i32
// CHECK: %[[VAL_10:.*]] = llvm.sub %[[VAL_7]], %[[VAL_5]] : i64
// CHECK: %[[VAL_11:.*]] = llvm.add %[[VAL_10]], %[[VAL_8]] : i64
// CHECK: llvm.br ^bb1(%[[VAL_5]], %[[VAL_9]], %[[VAL_11]] : i64, i32, i64)
// CHECK: ^bb1(%[[VAL_12:.*]]: i64, %[[VAL_13:.*]]: i32, %[[VAL_14:.*]]: i64):
// CHECK: %[[VAL_15:.*]] = llvm.mlir.constant(0 : index) : i64
// CHECK: %[[VAL_16:.*]] = llvm.icmp "sgt" %[[VAL_14]], %[[VAL_15]] : i64
// CHECK: llvm.cond_br %[[VAL_16]], ^bb2, ^bb3
// CHECK: ^bb2:
// CHECK: llvm.store %[[VAL_13]], %[[VAL_3]] : !llvm.ptr<i32>
// CHECK: %[[VAL_17:.*]] = llvm.load %[[VAL_3]] : !llvm.ptr<i32>
// CHECK: %[[VAL_18:.*]] = llvm.load %[[VAL_3]] : !llvm.ptr<i32>
// CHECK: %[[VAL_19:.*]] = llvm.sext %[[VAL_18]] : i32 to i64
// CHECK: %[[VAL_20:.*]] = llvm.mlir.constant(1 : i64) : i64
// CHECK: %[[VAL_21:.*]] = llvm.sub %[[VAL_19]], %[[VAL_20]] : i64
// CHECK: %[[VAL_22:.*]] = llvm.getelementptr %[[VAL_1]][0, %[[VAL_21]]] : (!llvm.ptr<array<1024 x i32>>, i64) -> !llvm.ptr<i32>
// CHECK: llvm.store %[[VAL_17]], %[[VAL_22]] : !llvm.ptr<i32>
// CHECK: %[[VAL_23:.*]] = llvm.add %[[VAL_12]], %[[VAL_8]] : i64
// CHECK: %[[VAL_24:.*]] = llvm.trunc %[[VAL_8]] : i64 to i32
// CHECK: %[[VAL_25:.*]] = llvm.load %[[VAL_3]] : !llvm.ptr<i32>
// CHECK: %[[VAL_26:.*]] = llvm.add %[[VAL_25]], %[[VAL_24]] : i32
// CHECK: %[[VAL_27:.*]] = llvm.add %[[VAL_12]], %[[VAL_8]] : i64
// CHECK: %[[VAL_28:.*]] = llvm.mlir.constant(1 : index) : i64
// CHECK: %[[VAL_29:.*]] = llvm.sub %[[VAL_14]], %[[VAL_28]] : i64
// CHECK: llvm.br ^bb1(%[[VAL_27]], %[[VAL_26]], %[[VAL_29]] : i64, i32, i64)
// CHECK: ^bb3:
// CHECK: llvm.store %[[VAL_13]], %[[VAL_3]] : !llvm.ptr<i32>
// CHECK: omp.terminator
// CHECK: }
// CHECK: llvm.return
// CHECK: }
// -----
func.func @_QPsimdloop_with_nested_loop() { func.func @_QPsimdloop_with_nested_loop() {
%0 = fir.alloca i32 {adapt.valuebyref} %0 = fir.alloca i32 {adapt.valuebyref}
%1 = fir.alloca !fir.array<10xi32> {bindc_name = "a", uniq_name = "_QFsimdloop_with_nested_loopEa"} %1 = fir.alloca !fir.array<10xi32> {bindc_name = "a", uniq_name = "_QFsimdloop_with_nested_loopEa"}
%2 = fir.alloca i32 {bindc_name = "i", uniq_name = "_QFsimdloop_with_nested_loopEi"} %2 = fir.alloca i32 {bindc_name = "i", uniq_name = "_QFsimdloop_with_nested_loopEi"}
%3 = fir.alloca i32 {bindc_name = "j", uniq_name = "_QFsimdloop_with_nested_loopEj"} %3 = fir.alloca i32 {bindc_name = "j", uniq_name = "_QFsimdloop_with_nested_loopEj"}
%c1_i32 = arith.constant 1 : i32 %c1_i32 = arith.constant 1 : i32
%c10_i32 = arith.constant 10 : i32 %c10_i32 = arith.constant 10 : i32
%c1_i32_0 = arith.constant 1 : i32 %c1_i32_0 = arith.constant 1 : i32
▲ Show 20 LinesShow All 156 LinesShow Last 20 Lines

mlir/lib/Conversion/OpenMPToLLVM/OpenMPToLLVM.cpp

Show First 20 LinesShow All 145 Lines▼ Show 20 Lines rewriter.replaceOpWithNewOp<Op>(curOp, TypeRange(), adaptor.getOperands(),
curOp.getOperation()->getAttrs()); curOp.getOperation()->getAttrs());
return success(); return success();
} }
}; };
} // namespace } // namespace
void mlir::configureOpenMPToLLVMConversionLegality( void mlir::configureOpenMPToLLVMConversionLegality(
ConversionTarget &target, LLVMTypeConverter &typeConverter) { ConversionTarget &target, LLVMTypeConverter &typeConverter) {
target.addDynamicallyLegalOp<mlir::omp::AtomicUpdateOp, mlir::omp::CriticalOp, target.addDynamicallyLegalOp<
mlir::omp::ParallelOp, mlir::omp::WsLoopOp, mlir::omp::AtomicUpdateOp, mlir::omp::CriticalOp, mlir::omp::DataOp,
mlir::omp::SimdLoopOp, mlir::omp::MasterOp, mlir::omp::ParallelOp, mlir::omp::WsLoopOp, mlir::omp::SimdLoopOp,
mlir::omp::SectionOp, mlir::omp::SectionsOp, mlir::omp::MasterOp, mlir::omp::SectionOp, mlir::omp::SectionsOp,
mlir::omp::SingleOp, mlir::omp::TaskOp>( mlir::omp::SingleOp, mlir::omp::TaskOp>([&](Operation *op) {
[&](Operation *op) {
return typeConverter.isLegal(&op->getRegion(0)) && return typeConverter.isLegal(&op->getRegion(0)) &&
typeConverter.isLegal(op->getOperandTypes()) && typeConverter.isLegal(op->getOperandTypes()) &&
typeConverter.isLegal(op->getResultTypes()); typeConverter.isLegal(op->getResultTypes());
}); });
target.addDynamicallyLegalOp<mlir::omp::AtomicReadOp, target
mlir::omp::AtomicWriteOp, mlir::omp::FlushOp, .addDynamicallyLegalOp<mlir::omp::AtomicReadOp, mlir::omp::AtomicWriteOp,
mlir::omp::ThreadprivateOp, mlir::omp::DataOp, mlir::omp::FlushOp, mlir::omp::ThreadprivateOp,
mlir::omp::EnterDataOp, mlir::omp::ExitDataOp>( mlir::omp::EnterDataOp, mlir::omp::ExitDataOp>(
[&](Operation *op) { [&](Operation *op) {
return typeConverter.isLegal(op->getOperandTypes()) && return typeConverter.isLegal(op->getOperandTypes()) &&
typeConverter.isLegal(op->getResultTypes()); typeConverter.isLegal(op->getResultTypes());
}); });
target.addDynamicallyLegalOp<mlir::omp::ReductionOp>([&](Operation *op) { target.addDynamicallyLegalOp<mlir::omp::ReductionOp>([&](Operation *op) {
return typeConverter.isLegal(op->getOperandTypes()); return typeConverter.isLegal(op->getOperandTypes());
}); });
} }
void mlir::populateOpenMPToLLVMConversionPatterns(LLVMTypeConverter &converter, void mlir::populateOpenMPToLLVMConversionPatterns(LLVMTypeConverter &converter,
RewritePatternSet &patterns) { RewritePatternSet &patterns) {
patterns.add< patterns.add<
ReductionOpConversion, RegionOpConversion<omp::CriticalOp>, LegalizeDataOpForLLVMTranslation<omp::DataOp>,
RegionOpConversion<omp::MasterOp>, ReductionOpConversion, LegalizeDataOpForLLVMTranslation<omp::EnterDataOp>,
RegionOpConversion<omp::MasterOp>, RegionOpConversion<omp::ParallelOp>, LegalizeDataOpForLLVMTranslation<omp::ExitDataOp>, ReductionOpConversion,
RegionOpConversion<omp::WsLoopOp>, RegionOpConversion<omp::SectionsOp>, RegionOpConversion<omp::CriticalOp>, RegionOpConversion<omp::MasterOp>,
RegionOpConversion<omp::SectionOp>, RegionOpConversion<omp::SimdLoopOp>, ReductionOpConversion, RegionOpConversion<omp::MasterOp>,
RegionOpConversion<omp::SingleOp>, RegionOpConversion<omp::TaskOp>, RegionOpConversion<omp::ParallelOp>, RegionOpConversion<omp::WsLoopOp>,
RegionOpConversion<omp::SectionsOp>, RegionOpConversion<omp::SectionOp>,
RegionOpConversion<omp::SimdLoopOp>, RegionOpConversion<omp::SingleOp>,
RegionOpConversion<omp::TaskOp>, RegionOpConversion<omp::DataOp>,
kiranchandramohanUnsubmitted
Done
ReplyInline Actions

Wouldn't this Operation require a region conversion as well?

kiranchandramohan: Wouldn't this Operation require a region conversion as well?
TIFitisAuthorUnsubmitted
Done
ReplyInline Actions

Yes, its present in line 189.

TIFitis: Yes, its present in line 189.
RegionLessOpWithVarOperandsConversion<omp::AtomicReadOp>, RegionLessOpWithVarOperandsConversion<omp::AtomicReadOp>,
RegionLessOpWithVarOperandsConversion<omp::AtomicWriteOp>, RegionLessOpWithVarOperandsConversion<omp::AtomicWriteOp>,
RegionOpWithVarOperandsConversion<omp::AtomicUpdateOp>, RegionOpWithVarOperandsConversion<omp::AtomicUpdateOp>,
RegionLessOpWithVarOperandsConversion<omp::FlushOp>, RegionLessOpWithVarOperandsConversion<omp::FlushOp>,
RegionLessOpWithVarOperandsConversion<omp::ThreadprivateOp>, RegionLessOpWithVarOperandsConversion<omp::ThreadprivateOp>>(converter);
LegalizeDataOpForLLVMTranslation<omp::DataOp>,
LegalizeDataOpForLLVMTranslation<omp::EnterDataOp>,
LegalizeDataOpForLLVMTranslation<omp::ExitDataOp>>(converter);
} }
namespace { namespace {
struct ConvertOpenMPToLLVMPass struct ConvertOpenMPToLLVMPass
: public impl::ConvertOpenMPToLLVMPassBase<ConvertOpenMPToLLVMPass> { : public impl::ConvertOpenMPToLLVMPassBase<ConvertOpenMPToLLVMPass> {
using Base::Base; using Base::Base;
void runOnOperation() override; void runOnOperation() override;
Show All 22 Lines

mlir/test/Conversion/OpenMPToLLVM/convert-to-llvmir.mlir

Show First 20 LinesShow All 199 Lines▼ Show 20 Lines
llvm.func @_QPomp_target_data(%a : !llvm.ptr<i32>, %b : !llvm.ptr<i32>, %c : !llvm.ptr<i32>, %d : !llvm.ptr<i32>) { llvm.func @_QPomp_target_data(%a : !llvm.ptr<i32>, %b : !llvm.ptr<i32>, %c : !llvm.ptr<i32>, %d : !llvm.ptr<i32>) {
omp.target_enter_data map((to -> %a : !llvm.ptr<i32>), (to -> %b : !llvm.ptr<i32>), (always, alloc -> %c : !llvm.ptr<i32>)) omp.target_enter_data map((to -> %a : !llvm.ptr<i32>), (to -> %b : !llvm.ptr<i32>), (always, alloc -> %c : !llvm.ptr<i32>))
omp.target_exit_data map((from -> %a : !llvm.ptr<i32>), (from -> %b : !llvm.ptr<i32>), (release -> %c : !llvm.ptr<i32>), (always, delete -> %d : !llvm.ptr<i32>)) omp.target_exit_data map((from -> %a : !llvm.ptr<i32>), (from -> %b : !llvm.ptr<i32>), (release -> %c : !llvm.ptr<i32>), (always, delete -> %d : !llvm.ptr<i32>))
llvm.return llvm.return
} }
// ----- // -----
// CHECK-LABEL: @_QPomp_target_data_region
// CHECK: (%[[ARG0:.*]]: !llvm.ptr<array<1024 x i32>>, %[[ARG1:.*]]: !llvm.ptr<i32>) {
// CHECK: omp.target_data map((tofrom -> %[[ARG0]] : !llvm.ptr<array<1024 x i32>>)) {
// CHECK: %[[VAL_1:.*]] = llvm.mlir.constant(10 : i32) : i32
// CHECK: llvm.store %[[VAL_1]], %[[ARG1]] : !llvm.ptr<i32>
// CHECK: omp.terminator
// CHECK: }
// CHECK: llvm.return
llvm.func @_QPomp_target_data_region(%a : !llvm.ptr<array<1024 x i32>>, %i : !llvm.ptr<i32>) {
omp.target_data map((tofrom -> %a : !llvm.ptr<array<1024 x i32>>)) {
%1 = llvm.mlir.constant(10 : i32) : i32
llvm.store %1, %i : !llvm.ptr<i32>
omp.terminator
}
llvm.return
}
// -----
// CHECK-LABEL: @_QPsb // CHECK-LABEL: @_QPsb
// CHECK: omp.sections // CHECK: omp.sections
// CHECK: omp.section // CHECK: omp.section
// CHECK: llvm.br // CHECK: llvm.br
// CHECK: llvm.icmp // CHECK: llvm.icmp
// CHECK: llvm.cond_br // CHECK: llvm.cond_br
// CHECK: llvm.br // CHECK: llvm.br
// CHECK: omp.terminator // CHECK: omp.terminator
Show All 23 Lines