mlir/test/mlir-opt/async.mlir - external/github.com/llvm/llvm-project.git - Git at Google

 // Check if mlir marks the corresponding function with required coroutine attribute.
 //
 // RUN:   mlir-opt %s -async-to-async-runtime                                  \
 // RUN:               -async-runtime-ref-counting                              \
 // RUN:               -async-runtime-ref-counting-opt                          \
 // RUN:               -convert-async-to-llvm                                   \
 // RUN:               -convert-linalg-to-loops                                 \
 // RUN:               -convert-scf-to-cf                                       \
 // RUN:               -convert-linalg-to-llvm                                  \
 // RUN:               -convert-memref-to-llvm                                  \
 // RUN:               -convert-arith-to-llvm                                   \
 // RUN:               -convert-std-to-llvm                                     \
 // RUN:               -reconcile-unrealized-casts                              \
 // RUN: | FileCheck %s

 // CHECK: llvm.func @async_execute_fn{{.*}}attributes{{.*}}"coroutine.presplit", "0"
 // CHECK: llvm.func @async_execute_fn_0{{.*}}attributes{{.*}}"coroutine.presplit", "0"
 // CHECK: llvm.func @async_execute_fn_1{{.*}}attributes{{.*}}"coroutine.presplit", "0"

 func @main() {
   %i0 = arith.constant 0 : index
   %i1 = arith.constant 1 : index
   %i2 = arith.constant 2 : index
   %i3 = arith.constant 3 : index

   %c0 = arith.constant 0.0 : f32
   %c1 = arith.constant 1.0 : f32
   %c2 = arith.constant 2.0 : f32
   %c3 = arith.constant 3.0 : f32
   %c4 = arith.constant 4.0 : f32

   %A = memref.alloc() : memref<4xf32>
   linalg.fill(%c0, %A) : f32, memref<4xf32>

   %U = memref.cast %A :  memref<4xf32> to memref<*xf32>
   call @print_memref_f32(%U): (memref<*xf32>) -> ()

   memref.store %c1, %A[%i0]: memref<4xf32>
   call @mlirAsyncRuntimePrintCurrentThreadId(): () -> ()
   call @print_memref_f32(%U): (memref<*xf32>) -> ()

   %outer = async.execute {
     memref.store %c2, %A[%i1]: memref<4xf32>
     call @mlirAsyncRuntimePrintCurrentThreadId(): () -> ()
     call @print_memref_f32(%U): (memref<*xf32>) -> ()

     // No op async region to create a token for testing async dependency.
     %noop = async.execute {
       call @mlirAsyncRuntimePrintCurrentThreadId(): () -> ()
       async.yield
     }

     %inner = async.execute [%noop] {
       memref.store %c3, %A[%i2]: memref<4xf32>
       call @mlirAsyncRuntimePrintCurrentThreadId(): () -> ()
       call @print_memref_f32(%U): (memref<*xf32>) -> ()

       async.yield
     }
     async.await %inner : !async.token

     memref.store %c4, %A[%i3]: memref<4xf32>
     call @mlirAsyncRuntimePrintCurrentThreadId(): () -> ()
     call @print_memref_f32(%U): (memref<*xf32>) -> ()

     async.yield
   }
   async.await %outer : !async.token

   call @mlirAsyncRuntimePrintCurrentThreadId(): () -> ()
   call @print_memref_f32(%U): (memref<*xf32>) -> ()

   memref.dealloc %A : memref<4xf32>

   return
 }

 func private @mlirAsyncRuntimePrintCurrentThreadId() -> ()

 func private @print_memref_f32(memref<*xf32>) attributes { llvm.emit_c_interface }
	// Check if mlir marks the corresponding function with required coroutine attribute.
	//
	// RUN: mlir-opt %s -async-to-async-runtime \
	// RUN: -async-runtime-ref-counting \
	// RUN: -async-runtime-ref-counting-opt \
	// RUN: -convert-async-to-llvm \
	// RUN: -convert-linalg-to-loops \
	// RUN: -convert-scf-to-cf \
	// RUN: -convert-linalg-to-llvm \
	// RUN: -convert-memref-to-llvm \
	// RUN: -convert-arith-to-llvm \
	// RUN: -convert-std-to-llvm \
	// RUN: -reconcile-unrealized-casts \
	// RUN: \| FileCheck %s

	// CHECK: llvm.func @async_execute_fn{{.}}attributes{{.}}"coroutine.presplit", "0"
	// CHECK: llvm.func @async_execute_fn_0{{.}}attributes{{.}}"coroutine.presplit", "0"
	// CHECK: llvm.func @async_execute_fn_1{{.}}attributes{{.}}"coroutine.presplit", "0"

	func @main() {
	%i0 = arith.constant 0 : index
	%i1 = arith.constant 1 : index
	%i2 = arith.constant 2 : index
	%i3 = arith.constant 3 : index

	%c0 = arith.constant 0.0 : f32
	%c1 = arith.constant 1.0 : f32
	%c2 = arith.constant 2.0 : f32
	%c3 = arith.constant 3.0 : f32
	%c4 = arith.constant 4.0 : f32

	%A = memref.alloc() : memref<4xf32>
	linalg.fill(%c0, %A) : f32, memref<4xf32>

	%U = memref.cast %A : memref<4xf32> to memref<*xf32>
	call @print_memref_f32(%U): (memref<*xf32>) -> ()

	memref.store %c1, %A[%i0]: memref<4xf32>
	call @mlirAsyncRuntimePrintCurrentThreadId(): () -> ()
	call @print_memref_f32(%U): (memref<*xf32>) -> ()

	%outer = async.execute {
	memref.store %c2, %A[%i1]: memref<4xf32>
	call @mlirAsyncRuntimePrintCurrentThreadId(): () -> ()
	call @print_memref_f32(%U): (memref<*xf32>) -> ()

	// No op async region to create a token for testing async dependency.
	%noop = async.execute {
	call @mlirAsyncRuntimePrintCurrentThreadId(): () -> ()
	async.yield
	}

	%inner = async.execute [%noop] {
	memref.store %c3, %A[%i2]: memref<4xf32>
	call @mlirAsyncRuntimePrintCurrentThreadId(): () -> ()
	call @print_memref_f32(%U): (memref<*xf32>) -> ()

	async.yield
	}
	async.await %inner : !async.token

	memref.store %c4, %A[%i3]: memref<4xf32>
	call @mlirAsyncRuntimePrintCurrentThreadId(): () -> ()
	call @print_memref_f32(%U): (memref<*xf32>) -> ()

	async.yield
	}
	async.await %outer : !async.token

	call @mlirAsyncRuntimePrintCurrentThreadId(): () -> ()
	call @print_memref_f32(%U): (memref<*xf32>) -> ()

	memref.dealloc %A : memref<4xf32>

	return
	}

	func private @mlirAsyncRuntimePrintCurrentThreadId() -> ()

	func private @print_memref_f32(memref<*xf32>) attributes { llvm.emit_c_interface }