llvm-project/mlir/test/AffineOps/invalid.mlir

171 lines
4.0 KiB
MLIR

// RUN: mlir-opt %s -split-input-file -verify-diagnostics
// -----
func @affine_apply_operand_non_index(%arg0 : i32) {
// Custom parser automatically assigns all arguments the `index` so we must
// use the generic syntax here to exercise the verifier.
// expected-error@+1 {{operands must be of type 'index'}}
%0 = "affine.apply"(%arg0) {map = affine_map<(d0) -> (d0)>} : (i32) -> (index)
return
}
// -----
func @affine_apply_resul_non_index(%arg0 : index) {
// Custom parser automatically assigns `index` as the result type so we must
// use the generic syntax here to exercise the verifier.
// expected-error@+1 {{result must be of type 'index'}}
%0 = "affine.apply"(%arg0) {map = affine_map<(d0) -> (d0)>} : (index) -> (i32)
return
}
// -----
#map = affine_map<(d0)[s0] -> (d0 + s0)>
func @affine_for_lower_bound_invalid_dim(%arg : index) {
affine.for %n0 = 0 to 7 {
%dim = addi %arg, %arg : index
// expected-error@+1 {{operand cannot be used as a dimension id}}
affine.for %n1 = 0 to #map(%dim)[%arg] {
}
}
return
}
// -----
#map = affine_map<(d0)[s0] -> (d0 + s0)>
func @affine_for_upper_bound_invalid_dim(%arg : index) {
affine.for %n0 = 0 to 7 {
%dim = addi %arg, %arg : index
// expected-error@+1 {{operand cannot be used as a dimension id}}
affine.for %n1 = #map(%dim)[%arg] to 7 {
}
}
return
}
// -----
func @affine_load_invalid_dim(%M : memref<10xi32>) {
"unknown"() ({
^bb0(%arg: index):
affine.load %M[%arg] : memref<10xi32>
// expected-error@-1 {{index must be a dimension or symbol identifier}}
br ^bb1
^bb1:
br ^bb1
}) : () -> ()
return
}
// -----
#map0 = affine_map<(d0)[s0] -> (d0 + s0)>
func @affine_for_lower_bound_invalid_sym() {
affine.for %i0 = 0 to 7 {
// expected-error@+1 {{operand cannot be used as a symbol}}
affine.for %n0 = #map0(%i0)[%i0] to 7 {
}
}
return
}
// -----
#map0 = affine_map<(d0)[s0] -> (d0 + s0)>
func @affine_for_upper_bound_invalid_sym() {
affine.for %i0 = 0 to 7 {
// expected-error@+1 {{operand cannot be used as a symbol}}
affine.for %n0 = 0 to #map0(%i0)[%i0] {
}
}
return
}
// -----
#set0 = affine_set<(i)[N] : (i >= 0, N - i >= 0)>
func @affine_if_invalid_dim(%arg : index) {
affine.for %n0 = 0 to 7 {
%dim = addi %arg, %arg : index
// expected-error@+1 {{operand cannot be used as a dimension id}}
affine.if #set0(%dim)[%n0] {}
}
return
}
// -----
#set0 = affine_set<(i)[N] : (i >= 0, N - i >= 0)>
func @affine_if_invalid_sym() {
affine.for %i0 = 0 to 7 {
// expected-error@+1 {{operand cannot be used as a symbol}}
affine.if #set0(%i0)[%i0] {}
}
return
}
// -----
#set0 = affine_set<(i)[N] : (i >= 0, N - i >= 0)>
func @affine_if_invalid_dimop_dim(%arg0: index, %arg1: index, %arg2: index, %arg3: index) {
affine.for %n0 = 0 to 7 {
%0 = alloc(%arg0, %arg1, %arg2, %arg3) : memref<?x?x?x?xf32>
%dim = dim %0, 0 : memref<?x?x?x?xf32>
// expected-error@+1 {{operand cannot be used as a dimension id}}
affine.if #set0(%dim)[%n0] {}
}
return
}
// -----
func @affine_store_missing_l_square(%C: memref<4096x4096xf32>) {
%9 = constant 0.0 : f32
// expected-error@+1 {{expected '['}}
affine.store %9, %C : memref<4096x4096xf32>
return
}
// -----
// CHECK-LABEL: @affine_min
func @affine_min(%arg0 : index, %arg1 : index, %arg2 : index) {
// expected-error@+1 {{operand count and affine map dimension and symbol count must match}}
%0 = affine.min affine_map<(d0) -> (d0)> (%arg0, %arg1)
return
}
// -----
// CHECK-LABEL: @affine_min
func @affine_min(%arg0 : index, %arg1 : index, %arg2 : index) {
// expected-error@+1 {{operand count and affine map dimension and symbol count must match}}
%0 = affine.min affine_map<()[s0] -> (s0)> (%arg0, %arg1)
return
}
// -----
// CHECK-LABEL: @affine_min
func @affine_min(%arg0 : index, %arg1 : index, %arg2 : index) {
// expected-error@+1 {{operand count and affine map dimension and symbol count must match}}
%0 = affine.min affine_map<(d0) -> (d0)> ()
return
}