// RUN: mlir-opt --allow-unregistered-dialect -verify-diagnostics -ownership-based-buffer-deallocation=private-function-dynamic-ownership=false \
// RUN: --buffer-deallocation-simplification -split-input-file %s | FileCheck %s
// RUN: mlir-opt --allow-unregistered-dialect -verify-diagnostics -ownership-based-buffer-deallocation=private-function-dynamic-ownership=true \
// RUN: --buffer-deallocation-simplification -split-input-file %s | FileCheck %s --check-prefix=CHECK-DYNAMIC
// RUN: mlir-opt %s -buffer-deallocation-pipeline --split-input-file > /dev/null
// RUN: mlir-opt %s -buffer-deallocation-pipeline=private-function-dynamic-ownership --split-input-file > /dev/null
// Test Case: Existing AllocOp with no users.
// BufferDeallocation expected behavior: It should insert a DeallocOp right
// before ReturnOp.
func.func private @emptyUsesValue(%arg0: memref<4xf32>) {
%0 = memref.alloc() : memref<4xf32>
"test.read_buffer"(%0) : (memref<4xf32>) -> ()
return
}
// CHECK-LABEL: func private @emptyUsesValue(
// CHECK: [[ALLOC:%.*]] = memref.alloc()
// CHECK: bufferization.dealloc ([[ALLOC]] :
// CHECK-SAME: if (%true{{[0-9_]*}})
// CHECK-NOT: retain
// CHECK-NEXT: return
// CHECK-DYNAMIC-LABEL: func private @emptyUsesValue(
// CHECK-DYNAMIC-SAME: [[ARG0:%.+]]: memref<4xf32>)
// CHECK-DYNAMIC: [[ALLOC:%.*]] = memref.alloc()
// CHECK-DYNAMIC-NEXT: "test.read_buffer"
// CHECK-DYNAMIC-NEXT: bufferization.dealloc ([[ALLOC]] :{{.*}}) if (%true{{[0-9_]*}})
// CHECK-DYNAMIC-NOT: retain
// CHECK-DYNAMIC-NEXT: return
// -----
func.func @emptyUsesValue(%arg0: memref<4xf32>) {
%0 = memref.alloc() : memref<4xf32>
"test.read_buffer"(%0) : (memref<4xf32>) -> ()
return
}
// CHECK-LABEL: func @emptyUsesValue(
// CHECK-DYNAMIC-LABEL: func @emptyUsesValue(
// CHECK-DYNAMIC: [[ALLOC:%.*]] = memref.alloc()
// CHECK-DYNAMIC: bufferization.dealloc ([[ALLOC]] :{{.*}}) if (%true{{[0-9_]*}})
// CHECK-DYNAMIC-NOT: retain
// CHECK-DYNAMIC-NEXT: return
// -----
// Test Case: Dead operations in a single block.
// BufferDeallocation expected behavior: It only inserts the two missing
// DeallocOps after the last BufferBasedOp.
func.func private @redundantOperations(%arg0: memref<2xf32>) {
%0 = memref.alloc() : memref<2xf32>
test.buffer_based in(%arg0: memref<2xf32>) out(%0: memref<2xf32>)
%1 = memref.alloc() : memref<2xf32>
test.buffer_based in(%0: memref<2xf32>) out(%1: memref<2xf32>)
return
}
// CHECK-LABEL: func private @redundantOperations
// CHECK: (%[[ARG0:.*]]: {{.*}})
// CHECK: %[[FIRST_ALLOC:.*]] = memref.alloc()
// CHECK-NEXT: test.buffer_based
// CHECK: %[[SECOND_ALLOC:.*]] = memref.alloc()
// CHECK-NEXT: test.buffer_based
// CHECK-NEXT: bufferization.dealloc (%[[FIRST_ALLOC]] : {{.*}}) if (%true{{[0-9_]*}})
// CHECK-NEXT: bufferization.dealloc (%[[SECOND_ALLOC]] : {{.*}}) if (%true{{[0-9_]*}})
// CHECK-NEXT: return
// CHECK-DYNAMIC-LABEL: func private @redundantOperations
// CHECK-DYNAMIC: (%[[ARG0:.*]]: memref{{.*}})
// CHECK-DYNAMIC: %[[FIRST_ALLOC:.*]] = memref.alloc()
// CHECK-DYNAMIC-NEXT: test.buffer_based
// CHECK-DYNAMIC: %[[SECOND_ALLOC:.*]] = memref.alloc()
// CHECK-DYNAMIC-NEXT: test.buffer_based
// CHECK-DYNAMIC-NEXT: bufferization.dealloc (%[[FIRST_ALLOC]] : {{.*}}) if (%true{{[0-9_]*}})
// CHECK-DYNAMIC-NEXT: bufferization.dealloc (%[[SECOND_ALLOC]] : {{.*}}) if (%true{{[0-9_]*}})
// CHECK-DYNAMIC-NEXT: return
// -----
// Test Case: buffer deallocation escaping
// BufferDeallocation expected behavior: It must not dealloc %arg1 and %x
// since they are operands of return operation and should escape from
// deallocating. It should dealloc %y after CopyOp.
func.func private @memref_in_function_results(
%arg0: memref<5xf32>,
%arg1: memref<10xf32>,
%arg2: memref<5xf32>) -> (memref<10xf32>, memref<15xf32>) {
%x = memref.alloc() : memref<15xf32>
%y = memref.alloc() : memref<5xf32>
test.buffer_based in(%arg0: memref<5xf32>) out(%y: memref<5xf32>)
test.copy(%y, %arg2) : (memref<5xf32>, memref<5xf32>)
return %arg1, %x : memref<10xf32>, memref<15xf32>
}
// CHECK-LABEL: func private @memref_in_function_results
// CHECK: (%[[ARG0:.*]]: memref<5xf32>, %[[ARG1:.*]]: memref<10xf32>,
// CHECK-SAME: %[[RESULT:.*]]: memref<5xf32>)
// CHECK: %[[X:.*]] = memref.alloc()
// CHECK: %[[Y:.*]] = memref.alloc()
// CHECK: test.copy
// CHECK-NEXT: %[[V0:.+]] = scf.if %false
// CHECK-NEXT: scf.yield %[[ARG1]]
// CHECK-NEXT: } else {
// CHECK-NEXT: %[[CLONE:.+]] = bufferization.clone %[[ARG1]]
// CHECK-NEXT: scf.yield %[[CLONE]]
// CHECK-NEXT: }
// CHECK: bufferization.dealloc (%[[Y]] : {{.*}}) if (%true{{[0-9_]*}})
// CHECK-NOT: retain
// CHECK: return %[[V0]], %[[X]]
// CHECK-DYNAMIC-LABEL: func private @memref_in_function_results
// CHECK-DYNAMIC: (%[[ARG0:.*]]: memref<5xf32>, %[[ARG1:.*]]: memref<10xf32>,
// CHECK-DYNAMIC-SAME: %[[RESULT:.*]]: memref<5xf32>)
// CHECK-DYNAMIC: %[[X:.*]] = memref.alloc()
// CHECK-DYNAMIC: %[[Y:.*]] = memref.alloc()
// CHECK-DYNAMIC: test.copy
// CHECK-DYNAMIC: bufferization.dealloc (%[[Y]] : {{.*}}) if (%true{{[0-9_]*}})
// CHECK-DYNAMIC-NOT: retain
// CHECK-DYNAMIC: return %[[ARG1]], %[[X]], %false, %true
// -----
// CHECK-DYNAMIC-LABEL: func private @private_callee(
// CHECK-DYNAMIC-SAME: %[[arg0:.*]]: memref<f32>) -> (memref<f32>, i1)
// CHECK-DYNAMIC: %[[true:.*]] = arith.constant true
// CHECK-DYNAMIC: %[[alloc:.*]] = memref.alloc() : memref<f32>
// CHECK-DYNAMIC-NOT: bufferization.dealloc
// CHECK-DYNAMIC: return %[[alloc]], %[[true]]
func.func private @private_callee(%arg0: memref<f32>) -> memref<f32> {
%alloc = memref.alloc() : memref<f32>
return %alloc : memref<f32>
}
// CHECK-DYNAMIC: func @caller() -> f32
// CHECK-DYNAMIC: %[[true:.*]] = arith.constant true
// CHECK-DYNAMIC: %[[alloc:.*]] = memref.alloc() : memref<f32>
// CHECK-DYNAMIC: %[[call:.*]]:2 = call @private_callee(%[[alloc]])
// CHECK-DYNAMIC: memref.load
// CHECK-DYNAMIC: %[[base:.*]], %[[offset:.*]] = memref.extract_strided_metadata %[[call]]#0
// CHECK-DYNAMIC: bufferization.dealloc (%[[alloc]], %[[base]] : {{.*}}) if (%[[true]], %[[call]]#1)
// CHECK-DYNAMIC-NOT: retain
func.func @caller() -> (f32) {
%alloc = memref.alloc() : memref<f32>
%ret = call @private_callee(%alloc) : (memref<f32>) -> memref<f32>
%val = memref.load %ret[] : memref<f32>
return %val : f32
}