River Riddle 3655069234 [mlir] Move the Builtin FuncOp to the Func dialect
This commit moves FuncOp out of the builtin dialect, and into the Func
dialect. This move has been planned in some capacity from the moment
we made FuncOp an operation (years ago). This commit handles the
functional aspects of the move, but various aspects are left untouched
to ease migration: func::FuncOp is re-exported into mlir to reduce
the actual API churn, the assembly format still accepts the unqualified
`func`. These temporary measures will remain for a little while to
simplify migration before being removed.

Differential Revision: https://reviews.llvm.org/D121266
2022-03-16 17:07:03 -07:00

79 lines
3.2 KiB
MLIR

// RUN: mlir-opt %s -pass-pipeline="async-to-async-runtime,func.func(async-runtime-ref-counting,async-runtime-ref-counting-opt),convert-async-to-llvm,func.func(convert-arith-to-llvm),convert-vector-to-llvm,convert-memref-to-llvm,convert-func-to-llvm,reconcile-unrealized-casts" \
// RUN: | mlir-cpu-runner \
// RUN: -e main -entry-point-result=void -O0 \
// RUN: -shared-libs=%linalg_test_lib_dir/libmlir_c_runner_utils%shlibext \
// RUN: -shared-libs=%linalg_test_lib_dir/libmlir_runner_utils%shlibext \
// RUN: -shared-libs=%linalg_test_lib_dir/libmlir_async_runtime%shlibext \
// RUN: | FileCheck %s --dump-input=always
func @main() {
// ------------------------------------------------------------------------ //
// Blocking async.await outside of the async.execute.
// ------------------------------------------------------------------------ //
%token, %result = async.execute -> !async.value<f32> {
%0 = arith.constant 123.456 : f32
async.yield %0 : f32
}
%1 = async.await %result : !async.value<f32>
// CHECK: 123.456
vector.print %1 : f32
// ------------------------------------------------------------------------ //
// Non-blocking async.await inside the async.execute
// ------------------------------------------------------------------------ //
%token0, %result0 = async.execute -> !async.value<f32> {
%token1, %result2 = async.execute -> !async.value<f32> {
%2 = arith.constant 456.789 : f32
async.yield %2 : f32
}
%3 = async.await %result2 : !async.value<f32>
async.yield %3 : f32
}
%4 = async.await %result0 : !async.value<f32>
// CHECK: 456.789
vector.print %4 : f32
// ------------------------------------------------------------------------ //
// Memref allocated inside async.execute region.
// ------------------------------------------------------------------------ //
%token2, %result2 = async.execute[%token0] -> !async.value<memref<f32>> {
%5 = memref.alloc() : memref<f32>
%c0 = arith.constant 0.25 : f32
memref.store %c0, %5[]: memref<f32>
async.yield %5 : memref<f32>
}
%6 = async.await %result2 : !async.value<memref<f32>>
%7 = memref.cast %6 : memref<f32> to memref<*xf32>
// CHECK: Unranked Memref
// CHECK-SAME: rank = 0 offset = 0 sizes = [] strides = []
// CHECK-NEXT: [0.25]
call @print_memref_f32(%7): (memref<*xf32>) -> ()
// ------------------------------------------------------------------------ //
// Memref passed as async.execute operand.
// ------------------------------------------------------------------------ //
%token3 = async.execute(%result2 as %unwrapped : !async.value<memref<f32>>) {
%8 = memref.load %unwrapped[]: memref<f32>
%9 = arith.addf %8, %8 : f32
memref.store %9, %unwrapped[]: memref<f32>
async.yield
}
async.await %token3 : !async.token
// CHECK: Unranked Memref
// CHECK-SAME: rank = 0 offset = 0 sizes = [] strides = []
// CHECK-NEXT: [0.5]
call @print_memref_f32(%7): (memref<*xf32>) -> ()
memref.dealloc %6 : memref<f32>
return
}
func private @print_memref_f32(memref<*xf32>)
attributes { llvm.emit_c_interface }