// RUN: mlir-opt -allow-unregistered-dialect -split-input-file %s -verify-diagnostics func @dma_start_not_enough_operands() { // expected-error@+1 {{expected at least 4 operands}} "memref.dma_start"() : () -> () } // ----- func @dma_no_src_memref(%m : f32, %tag : f32, %c0 : index) { // expected-error@+1 {{expected source to be of memref type}} memref.dma_start %m[%c0], %m[%c0], %c0, %tag[%c0] : f32, f32, f32 } // ----- func @dma_start_not_enough_operands_for_src( %src: memref<2x2x2xf32>, %idx: index) { // expected-error@+1 {{expected at least 7 operands}} "memref.dma_start"(%src, %idx, %idx, %idx) : (memref<2x2x2xf32>, index, index, index) -> () } // ----- func @dma_start_src_index_wrong_type( %src: memref<2x2xf32>, %idx: index, %dst: memref<2xf32,1>, %tag: memref, %flt: f32) { // expected-error@+1 {{expected source indices to be of index type}} "memref.dma_start"(%src, %idx, %flt, %dst, %idx, %tag, %idx) : (memref<2x2xf32>, index, f32, memref<2xf32,1>, index, memref, index) -> () } // ----- func @dma_no_dst_memref(%m : f32, %tag : f32, %c0 : index) { %mref = memref.alloc() : memref<8 x f32> // expected-error@+1 {{expected destination to be of memref type}} memref.dma_start %mref[%c0], %m[%c0], %c0, %tag[%c0] : memref<8 x f32>, f32, f32 } // ----- func @dma_start_not_enough_operands_for_dst( %src: memref<2x2xf32>, %idx: index, %dst: memref<2xf32,1>, %tag: memref) { // expected-error@+1 {{expected at least 7 operands}} "memref.dma_start"(%src, %idx, %idx, %dst, %idx, %idx) : (memref<2x2xf32>, index, index, memref<2xf32,1>, index, index) -> () } // ----- func @dma_start_dst_index_wrong_type( %src: memref<2x2xf32>, %idx: index, %dst: memref<2xf32,1>, %tag: memref, %flt: f32) { // expected-error@+1 {{expected destination indices to be of index type}} "memref.dma_start"(%src, %idx, %idx, %dst, %flt, %tag, %idx) : (memref<2x2xf32>, index, index, memref<2xf32,1>, f32, memref, index) -> () } // ----- func @dma_start_dst_index_wrong_type( %src: memref<2x2xf32>, %idx: index, %dst: memref<2xf32,1>, %tag: memref, %flt: f32) { // expected-error@+1 {{expected num elements to be of index type}} "memref.dma_start"(%src, %idx, %idx, %dst, %idx, %flt, %tag) : (memref<2x2xf32>, index, index, memref<2xf32,1>, index, f32, memref) -> () } // ----- func @dma_no_tag_memref(%tag : f32, %c0 : index) { %mref = memref.alloc() : memref<8 x f32> // expected-error@+1 {{expected tag to be of memref type}} memref.dma_start %mref[%c0], %mref[%c0], %c0, %tag[%c0] : memref<8 x f32>, memref<8 x f32>, f32 } // ----- func @dma_start_not_enough_operands_for_tag( %src: memref<2x2xf32>, %idx: index, %dst: memref<2xf32,1>, %tag: memref<2xi32,2>) { // expected-error@+1 {{expected at least 8 operands}} "memref.dma_start"(%src, %idx, %idx, %dst, %idx, %idx, %tag) : (memref<2x2xf32>, index, index, memref<2xf32,1>, index, index, memref<2xi32,2>) -> () } // ----- func @dma_start_dst_index_wrong_type( %src: memref<2x2xf32>, %idx: index, %dst: memref<2xf32,1>, %tag: memref<2xi32,2>, %flt: f32) { // expected-error@+1 {{expected tag indices to be of index type}} "memref.dma_start"(%src, %idx, %idx, %dst, %idx, %idx, %tag, %flt) : (memref<2x2xf32>, index, index, memref<2xf32,1>, index, index, memref<2xi32,2>, f32) -> () } // ----- func @dma_start_too_many_operands( %src: memref<2x2xf32>, %idx: index, %dst: memref<2xf32,1>, %tag: memref) { // expected-error@+1 {{incorrect number of operands}} "memref.dma_start"(%src, %idx, %idx, %dst, %idx, %idx, %tag, %idx, %idx, %idx) : (memref<2x2xf32>, index, index, memref<2xf32,1>, index, index, memref, index, index, index) -> () } // ----- func @dma_start_wrong_stride_type( %src: memref<2x2xf32>, %idx: index, %dst: memref<2xf32,1>, %tag: memref, %flt: f32) { // expected-error@+1 {{expected stride and num elements per stride to be of type index}} "memref.dma_start"(%src, %idx, %idx, %dst, %idx, %idx, %tag, %idx, %flt) : (memref<2x2xf32>, index, index, memref<2xf32,1>, index, index, memref, index, f32) -> () } // ----- func @dma_wait_wrong_index_type(%tag : memref<2x2xi32>, %idx: index, %flt: index) { // expected-error@+1 {{expected tagIndices to have the same number of elements as the tagMemRef rank, expected 2, but got 1}} "memref.dma_wait"(%tag, %flt, %idx) : (memref<2x2xi32>, index, index) -> () return } // ----- func @transpose_not_permutation(%v : memref(off + M * i + j)>>) { // expected-error @+1 {{expected a permutation map}} memref.transpose %v (i, j) -> (i, i) : memref(off + M * i + j)>> to memref(off + M * i + j)>> } // ----- func @transpose_bad_rank(%v : memref(off + M * i + j)>>) { // expected-error @+1 {{expected a permutation map of same rank as the input}} memref.transpose %v (i) -> (i) : memref(off + M * i + j)>> to memref(off + M * i + j)>> } // ----- func @transpose_wrong_type(%v : memref(off + M * i + j)>>) { // expected-error @+1 {{output type 'memref (d0 * s1 + s0 + d1)>>' does not match transposed input type 'memref (d0 * s1 + s0 + d1)>>'}} memref.transpose %v (i, j) -> (j, i) : memref(off + M * i + j)>> to memref(off + M * i + j)>> } // ----- func @memref_reinterpret_cast_too_many_offsets(%in: memref) { // expected-error @+1 {{expected 1 offset values}} %out = memref.reinterpret_cast %in to offset: [0, 0], sizes: [10, 10], strides: [10, 1] : memref to memref<10x10xf32, offset: 0, strides: [10, 1]> return } // ----- func @memref_reinterpret_cast_incompatible_element_types(%in: memref<*xf32>) { // expected-error @+1 {{different element types specified}} %out = memref.reinterpret_cast %in to offset: [0], sizes: [10], strides: [1] : memref<*xf32> to memref<10xi32, offset: 0, strides: [1]> return } // ----- func @memref_reinterpret_cast_incompatible_memory_space(%in: memref<*xf32>) { // expected-error @+1 {{different memory spaces specified}} %out = memref.reinterpret_cast %in to offset: [0], sizes: [10], strides: [1] : memref<*xf32> to memref<10xi32, offset: 0, strides: [1], 2> return } // ----- func @memref_reinterpret_cast_offset_mismatch(%in: memref) { // expected-error @+1 {{expected result type with offset = 2 instead of 1}} %out = memref.reinterpret_cast %in to offset: [1], sizes: [10], strides: [1] : memref to memref<10xf32, offset: 2, strides: [1]> return } // ----- func @memref_reinterpret_cast_size_mismatch(%in: memref<*xf32>) { // expected-error @+1 {{expected result type with size = 10 instead of 1 in dim = 0}} %out = memref.reinterpret_cast %in to offset: [0], sizes: [10], strides: [1] : memref<*xf32> to memref<1xf32, offset: 0, strides: [1]> return } // ----- func @memref_reinterpret_cast_offset_mismatch(%in: memref) { // expected-error @+1 {{expected result type with stride = 2 instead of 1 in dim = 0}} %out = memref.reinterpret_cast %in to offset: [2], sizes: [10], strides: [2] : memref to memref<10xf32, offset: 2, strides: [1]> return } // ----- func @memref_reinterpret_cast_no_map_but_offset(%in: memref) { // expected-error @+1 {{expected result type with offset = 0 instead of 2}} %out = memref.reinterpret_cast %in to offset: [2], sizes: [10], strides: [1] : memref to memref<10xf32> return } // ----- func @memref_reinterpret_cast_no_map_but_stride(%in: memref) { // expected-error @+1 {{expected result type with stride = 10 instead of 1 in dim = 0}} %out = memref.reinterpret_cast %in to offset: [0], sizes: [10], strides: [10] : memref to memref<10xf32> return } // ----- func @memref_reinterpret_cast_no_map_but_strides(%in: memref) { // expected-error @+1 {{expected result type with stride = 42 instead of 10 in dim = 0}} %out = memref.reinterpret_cast %in to offset: [0], sizes: [9, 10], strides: [42, 1] : memref to memref<9x10xf32> return } // ----- func @memref_reinterpret_cast_non_strided_layout(%in: memref) { // expected-error @+1 {{expected result type to have strided layout but found 'memref<9x10xf32, affine_map<(d0, d1) -> (d0)>>}} %out = memref.reinterpret_cast %in to offset: [0], sizes: [9, 10], strides: [42, 1] : memref to memref<9x10xf32, affine_map<(d0, d1) -> (d0)>> return } // ----- func @memref_reshape_element_type_mismatch( %buf: memref<*xf32>, %shape: memref<1xi32>) { // expected-error @+1 {{element types of source and destination memref types should be the same}} memref.reshape %buf(%shape) : (memref<*xf32>, memref<1xi32>) -> memref } // ----- func @memref_reshape_dst_ranked_shape_unranked( %buf: memref<*xf32>, %shape: memref) { // expected-error @+1 {{cannot use shape operand with dynamic length to reshape to statically-ranked memref type}} memref.reshape %buf(%shape) : (memref<*xf32>, memref) -> memref } // ----- func @memref_reshape_dst_shape_rank_mismatch( %buf: memref<*xf32>, %shape: memref<1xi32>) { // expected-error @+1 {{length of shape operand differs from the result's memref rank}} memref.reshape %buf(%shape) : (memref<*xf32>, memref<1xi32>) -> memref } // ----- func @memref_reshape_src_affine_map_is_not_identity( %buf: memref<4x4xf32, offset: 0, strides: [3, 2]>, %shape: memref<1xi32>) { // expected-error @+1 {{source memref type should have identity affine map}} memref.reshape %buf(%shape) : (memref<4x4xf32, offset: 0, strides: [3, 2]>, memref<1xi32>) -> memref<8xf32> } // ----- func @memref_reshape_result_affine_map_is_not_identity( %buf: memref<4x4xf32>, %shape: memref<1xi32>) { // expected-error @+1 {{result memref type should have identity affine map}} memref.reshape %buf(%shape) : (memref<4x4xf32>, memref<1xi32>) -> memref<8xf32, offset: 0, strides: [2]> } // ----- // expected-error @+1 {{type should be static shaped memref}} memref.global @foo : i32 // ----- // expected-error @+1 {{type should be static shaped memref}} memref.global @foo : i32 = 5 // ----- // expected-error @+1 {{type should be static shaped memref}} memref.global @foo : memref<*xf32> // ----- // expected-error @+1 {{type should be static shaped memref}} memref.global @foo : memref // ----- // expected-error @+1 {{initial value should be a unit or elements attribute}} memref.global @foo : memref<2x2xf32> = "foo" // ----- // expected-error @+1 {{inferred shape of elements literal ([2]) does not match type ([2, 2])}} memref.global @foo : memref<2x2xf32> = dense<[0.0, 1.0]> // ----- // expected-error @+1 {{expected valid '@'-identifier for symbol name}} memref.global "private" "public" @foo : memref<2x2xf32> = "foo" // ----- // expected-error @+1 {{expected valid '@'-identifier for symbol name}} memref.global constant external @foo : memref<2x2xf32> = "foo" // ----- // constant qualifier must be after visibility. // expected-error @+1 {{expected valid '@'-identifier for symbol name}} memref.global constant "private" @foo : memref<2x2xf32> = "foo" // ----- // expected-error @+1 {{op visibility expected to be one of ["public", "private", "nested"], but got "priate"}} memref.global "priate" constant @memref5 : memref<2xf32> = uninitialized // ----- func @nonexistent_global_memref() { // expected-error @+1 {{'gv' does not reference a valid global memref}} %0 = memref.get_global @gv : memref<3xf32> return } // ----- func @foo() func @nonexistent_global_memref() { // expected-error @+1 {{'foo' does not reference a valid global memref}} %0 = memref.get_global @foo : memref<3xf32> return } // ----- memref.global @gv : memref<3xi32> func @mismatched_types() { // expected-error @+1 {{result type 'memref<3xf32>' does not match type 'memref<3xi32>' of the global memref @gv}} %0 = memref.get_global @gv : memref<3xf32> return } // ----- // expected-error @+1 {{alignment attribute value 63 is not a power of 2}} memref.global "private" @gv : memref<4xf32> = dense<1.0> { alignment = 63 } // ----- func @copy_different_shape(%arg0: memref<2xf32>, %arg1: memref<3xf32>) { // expected-error @+1 {{op requires the same shape for all operands}} memref.copy %arg0, %arg1 : memref<2xf32> to memref<3xf32> return } // ----- func @copy_different_eltype(%arg0: memref<2xf32>, %arg1: memref<2xf16>) { // expected-error @+1 {{op requires the same element type for all operands}} memref.copy %arg0, %arg1 : memref<2xf32> to memref<2xf16> return } // ----- func @expand_shape(%arg0: memref) { // expected-error @+1 {{invalid number of reassociation groups: found 1, expected 0}} %0 = memref.expand_shape %arg0 [[0]] : memref into memref return } // ----- func @expand_shape(%arg0: memref) { // expected-error @+1 {{rank 0 memrefs can only be extended/collapsed with/from ones}} %0 = memref.expand_shape %arg0 [] : memref into memref<1x2xf32> return } // ----- func @collapse_shape_to_higher_rank(%arg0: memref) { // expected-error @+1 {{op reassociation index 0 is out of bounds}} %0 = memref.collapse_shape %arg0 [[0]] : memref into memref<1xf32> } // ----- func @expand_shape_to_smaller_rank(%arg0: memref<1xf32>) { // expected-error @+1 {{op reassociation index 0 is out of bounds}} %0 = memref.expand_shape %arg0 [[0]] : memref<1xf32> into memref } // ----- func @expand_shape_invalid_result_layout( %arg0: memref<30x20xf32, offset : 100, strides : [4000, 2]>) { // expected-error @+1 {{expected expanded type to be 'memref<2x15x20xf32, affine_map<(d0, d1, d2) -> (d0 * 60000 + d1 * 4000 + d2 * 2 + 100)>>' but found 'memref<2x15x20xf32, affine_map<(d0, d1, d2) -> (d0 * 5000 + d1 * 4000 + d2 * 2 + 100)>>'}} %0 = memref.expand_shape %arg0 [[0, 1], [2]] : memref<30x20xf32, offset : 100, strides : [4000, 2]> into memref<2x15x20xf32, offset : 100, strides : [5000, 4000, 2]> } // ----- func @collapse_shape_mismatch_indices_num(%arg0: memref) { // expected-error @+1 {{invalid number of reassociation groups: found 1, expected 2}} %0 = memref.collapse_shape %arg0 [[0, 1]] : memref into memref } // ----- func @collapse_shape_invalid_reassociation(%arg0: memref) { // expected-error @+1 {{reassociation indices must be contiguous}} %0 = memref.collapse_shape %arg0 [[0, 1], [1, 2]] : memref into memref } // ----- func @collapse_shape_reshaping_non_contiguous( %arg0: memref<3x4x5xf32, offset: 0, strides: [270, 50, 10]>) { // expected-error @+1 {{invalid source layout map or collapsing non-contiguous dims}} %0 = memref.collapse_shape %arg0 [[0, 1], [2]] : memref<3x4x5xf32, offset: 0, strides: [270, 50, 10]> into memref<12x5xf32, offset: 0, strides: [50, 1]> return } // ----- func @collapse_shape_wrong_collapsed_type(%arg0: memref) { // expected-error @+1 {{expected collapsed type to be 'memref' but found 'memref (d0 * s0 + d1)>>'}} %0 = memref.collapse_shape %arg0 [[0, 1], [2]] : memref into memref (d0 * s0 + d1)>> } // ----- func @expand_shape_illegal_dynamic_memref (%arg0: memref) -> memref { // expected-error @+1 {{at most one dimension in a reassociation group may be dynamic}} %0 = memref.expand_shape %arg0 [[0], [1], [2, 3, 4]] : memref into memref return %0 : memref } // ----- func @expand_shape_illegal_static_memref (%arg0: memref<2x3x20xf32>) -> memref<2x3x2x4x5xf32> { // expected-error @+1 {{collapsed dim size (20) must equal reassociation group size (40)}} %0 = memref.expand_shape %arg0 [[0], [1], [2, 3, 4]] : memref<2x3x20xf32> into memref<2x3x2x4x5xf32> return %0 : memref<2x3x2x4x5xf32> } // ----- func @collapse_shape_illegal_static_memref (%arg0: memref<2x3x2x4x5xf32>) -> memref<2x3x20xf32> { // expected-error @+1 {{collapsed dim size (20) must equal reassociation group size (40)}} %0 = memref.collapse_shape %arg0 [[0], [1], [2, 3, 4]] : memref<2x3x2x4x5xf32> into memref<2x3x20xf32> return %0 : memref<2x3x20xf32> } // ----- func @expand_shape_illegal_mixed_memref(%arg0 : memref) -> memref { // expected-error @+1 {{collapsed dim (1) must be dynamic if and only if reassociation group is dynamic}} %0 = memref.expand_shape %arg0 [[0, 1], [2]] : memref into memref return %0 : memref } // ----- func @expand_shape_illegal_mixed_memref_2(%arg0 : memref) -> memref { // expected-error @+1 {{collapsed dim (1) must be dynamic if and only if reassociation group is dynamic}} %0 = memref.expand_shape %arg0 [[0], [1, 2]] : memref into memref return %0 : memref } // ----- func @expand_shape_unsupported_src_layout( %arg0 : memref<20x2x10x5xf32, offset: 0, strides: [100, 10, 50, 1]>) -> memref<20x2x2x5x5xf32, offset : 0, strides : [100, 10, 250, 50, 1]> { // expected-error @+1 {{invalid source layout map}} %0 = memref.expand_shape %arg0 [[0], [1], [2, 3], [4]] : memref<20x2x10x5xf32, offset: 0, strides: [100, 10, 50, 1]> into memref<20x2x2x5x5xf32, offset : 0, strides : [100, 10, 250, 50, 1]> return %0 : memref<20x2x2x5x5xf32, offset : 0, strides : [100, 10, 250, 50, 1]> } // ----- func @expand_shape_invalid_static_dim_size(%arg0 : memref) -> memref { // expected-error @+1 {{collapsed dim size (21) must equal reassociation group size (20)}} %0 = memref.expand_shape %arg0 [[0], [1, 2]] : memref into memref return %0 : memref } // ----- func @collapse_shape_illegal_mixed_memref(%arg0 : memref) -> memref { // expected-error @+1 {{collapsed dim (1) must be dynamic if and only if reassociation group is dynamic}} %0 = memref.collapse_shape %arg0 [[0, 1], [2]] : memref into memref return %0 : memref } // ----- func @collapse_shape_illegal_mixed_memref_2(%arg0 : memref) -> memref { // expected-error @+1 {{collapsed dim (1) must be dynamic if and only if reassociation group is dynamic}} %0 = memref.collapse_shape %arg0 [[0], [1, 2]] : memref into memref return %0 : memref } // ----- func @invalid_view(%arg0 : index, %arg1 : index, %arg2 : index) { %0 = memref.alloc() : memref<2048xi8> // expected-error@+1 {{expected SSA operand}} %1 = memref.view %0[][%arg0, %arg1] : memref<2048xi8> to memref return } // ----- func @invalid_view(%arg0 : index, %arg1 : index, %arg2 : index) { %0 = memref.alloc() : memref<2048xi8, affine_map<(d0) -> (d0 floordiv 8, d0 mod 8)>> // expected-error@+1 {{unsupported map for base memref type}} %1 = memref.view %0[%arg2][%arg0, %arg1] : memref<2048xi8, affine_map<(d0) -> (d0 floordiv 8, d0 mod 8)>> to memref (d0 * 4 + d1 + s0)>> return } // ----- func @invalid_view(%arg0 : index, %arg1 : index, %arg2 : index) { %0 = memref.alloc() : memref<2048xi8> // expected-error@+1 {{unsupported map for result memref type}} %1 = memref.view %0[%arg2][%arg0, %arg1] : memref<2048xi8> to memref (d0, d1, s0)>> return } // ----- func @invalid_view(%arg0 : index, %arg1 : index, %arg2 : index) { %0 = memref.alloc() : memref<2048xi8, 2> // expected-error@+1 {{different memory spaces}} %1 = memref.view %0[%arg2][%arg0, %arg1] : memref<2048xi8, 2> to memref return } // ----- func @invalid_view(%arg0 : index, %arg1 : index, %arg2 : index) { %0 = memref.alloc() : memref<2048xi8> // expected-error@+1 {{incorrect number of size operands for type}} %1 = memref.view %0[%arg2][%arg0] : memref<2048xi8> to memref return } // ----- func @invalid_subview(%arg0 : index, %arg1 : index, %arg2 : index) { %0 = memref.alloc() : memref<8x16x4xf32> // expected-error@+1 {{expected mixed offsets rank to match mixed sizes rank (2 vs 3) so the rank of the result type is well-formed}} %1 = memref.subview %0[0, 0][2, 2, 2][1, 1, 1] : memref<8x16x4xf32> to memref<8x16x4xf32> return } // ----- func @invalid_subview(%arg0 : index, %arg1 : index, %arg2 : index) { %0 = memref.alloc() : memref<8x16x4xf32> // expected-error@+1 {{expected mixed sizes rank to match mixed strides rank (3 vs 2) so the rank of the result type is well-formed}} %1 = memref.subview %0[0, 0, 0][2, 2, 2][1, 1] : memref<8x16x4xf32> to memref<8x16x4xf32> return } // ----- func @invalid_subview(%arg0 : index, %arg1 : index, %arg2 : index) { %0 = memref.alloc() : memref<8x16x4xf32> // expected-error@+1 {{expected mixed sizes rank to match mixed strides rank (3 vs 2) so the rank of the result type is well-formed}} %1 = memref.reinterpret_cast %0 to offset: [0], sizes: [2, 2, 2], strides:[1, 1] : memref<8x16x4xf32> to memref<8x16x4xf32> return } // ----- func @invalid_subview(%arg0 : index, %arg1 : index, %arg2 : index) { %0 = memref.alloc() : memref<8x16x4xf32, offset: 0, strides: [64, 4, 1], 2> // expected-error@+1 {{different memory spaces}} %1 = memref.subview %0[0, 0, 0][%arg2, %arg2, %arg2][1, 1, 1] : memref<8x16x4xf32, offset: 0, strides: [64, 4, 1], 2> to memref<8x?x4xf32, affine_map<(d0, d1, d2)[s0] -> (d0 * s0 + d1 * 4 + d2)>> return } // ----- func @invalid_subview(%arg0 : index, %arg1 : index, %arg2 : index) { %0 = memref.alloc() : memref<8x16x4xf32, affine_map<(d0, d1, d2) -> (d0 + d1, d1 + d2, d2)>> // expected-error@+1 {{is not strided}} %1 = memref.subview %0[0, 0, 0][%arg2, %arg2, %arg2][1, 1, 1] : memref<8x16x4xf32, affine_map<(d0, d1, d2) -> (d0 + d1, d1 + d2, d2)>> to memref<8x?x4xf32, offset: 0, strides: [?, 4, 1]> return } // ----- func @invalid_subview(%arg0 : index, %arg1 : index, %arg2 : index) { %0 = memref.alloc() : memref<8x16x4xf32> // expected-error@+1 {{expected 3 offset values}} %1 = memref.subview %0[%arg0, %arg1, 0, 0][%arg2, 0, 0, 0][1, 1, 1, 1] : memref<8x16x4xf32> to memref<8x?x4xf32, offset: 0, strides:[?, ?, 4]> return } // ----- func @invalid_subview(%arg0 : index, %arg1 : index, %arg2 : index) { %0 = memref.alloc() : memref<8x16x4xf32> // expected-error@+1 {{expected result element type to be 'f32'}} %1 = memref.subview %0[0, 0, 0][8, 16, 4][1, 1, 1] : memref<8x16x4xf32> to memref<8x16x4xi32> return } // ----- func @invalid_subview(%arg0 : index, %arg1 : index, %arg2 : index) { %0 = memref.alloc() : memref<8x16x4xf32> // expected-error@+1 {{expected result rank to be smaller or equal to the source rank.}} %1 = memref.subview %0[0, 0, 0][8, 16, 4][1, 1, 1] : memref<8x16x4xf32> to memref<8x16x4x3xi32> return } // ----- func @invalid_rank_reducing_subview(%arg0 : index, %arg1 : index, %arg2 : index) { %0 = memref.alloc() : memref<8x16x4xf32> // expected-error@+1 {{expected result type to be 'memref<8x16x4xf32, affine_map<(d0, d1, d2) -> (d0 * 64 + d1 * 4 + d2)>>' or a rank-reduced version. (mismatch of result sizes)}} %1 = memref.subview %0[0, 0, 0][8, 16, 4][1, 1, 1] : memref<8x16x4xf32> to memref<16x4xf32> return } // ----- func @invalid_rank_reducing_subview(%arg0 : index, %arg1 : index, %arg2 : index) { %0 = memref.alloc() : memref<8x16x4xf32> // expected-error@+1 {{expected result type to be 'memref<8x16x4xf32, affine_map<(d0, d1, d2) -> (d0 * 64 + d1 * 4 + d2 + 8)>>' or a rank-reduced version. (mismatch of result sizes)}} %1 = memref.subview %0[0, 2, 0][8, 16, 4][1, 1, 1] : memref<8x16x4xf32> to memref<16x4xf32> return } // ----- func @invalid_rank_reducing_subview(%arg0 : memref, %arg1 : index, %arg2 : index) { // expected-error@+1 {{expected result type to be 'memref (d0 * s1 + s0 + d1)>>' or a rank-reduced version. (mismatch of result layout)}} %0 = memref.subview %arg0[0, %arg1][%arg2, 1][1, 1] : memref to memref return } // ----- #map0 = affine_map<(d0, d1)[s0] -> (d0 * 16 + d1)> func @subview_bad_offset_1(%arg0: memref<16x16xf32>) { %c0 = arith.constant 0 : index %c8 = arith.constant 8 : index // expected-error @+1 {{expected result type to be 'memref<8x8xf32, affine_map<(d0, d1)[s0] -> (d0 * 16 + s0 + d1)>>' or a rank-reduced version}} %s2 = memref.subview %arg0[%c8, %c8][8, 8][1, 1] : memref<16x16xf32> to memref<8x8xf32, #map0> return } // ----- #map0 = affine_map<(d0, d1)[s0] -> (d0 * 16 + d1 + 136)> func @subview_bad_offset_2(%arg0: memref<16x16xf32>) { %c0 = arith.constant 0 : index %c8 = arith.constant 8 : index // expected-error @+1 {{expected result type to be 'memref<8x8xf32, affine_map<(d0, d1)[s0] -> (d0 * 16 + s0 + d1)>>' or a rank-reduced version}} %s2 = memref.subview %arg0[%c8, 8][8, 8][1, 1] : memref<16x16xf32> to memref<8x8xf32, #map0> return } // ----- #map0 = affine_map<(d0, d1)[s0] -> (d0 * 16 + d1 + s0 * 437)> func @subview_bad_offset_3(%arg0: memref<16x16xf32>) { %c0 = arith.constant 0 : index %c8 = arith.constant 8 : index // expected-error @+1 {{expected result type to be 'memref<8x8xf32, affine_map<(d0, d1)[s0] -> (d0 * 16 + s0 + d1)>>' or a rank-reduced version}} %s2 = memref.subview %arg0[%c8, 8][8, 8][1, 1] : memref<16x16xf32> to memref<8x8xf32, #map0> return } // ----- func @invalid_memref_cast(%arg0 : memref<12x4x16xf32, offset:0, strides:[64, 16, 1]>) { // expected-error@+1{{operand type 'memref<12x4x16xf32, affine_map<(d0, d1, d2) -> (d0 * 64 + d1 * 16 + d2)>>' and result type 'memref<12x4x16xf32, affine_map<(d0, d1, d2) -> (d0 * 128 + d1 * 32 + d2 * 2)>>' are cast incompatible}} %0 = memref.cast %arg0 : memref<12x4x16xf32, offset:0, strides:[64, 16, 1]> to memref<12x4x16xf32, offset:0, strides:[128, 32, 2]> return } // ----- func @invalid_memref_cast(%arg0 : memref<12x4x16xf32, offset:0, strides:[64, 16, 1]>) { // expected-error@+1{{operand type 'memref<12x4x16xf32, affine_map<(d0, d1, d2) -> (d0 * 64 + d1 * 16 + d2)>>' and result type 'memref<12x4x16xf32, affine_map<(d0, d1, d2) -> (d0 * 64 + d1 * 16 + d2 + 16)>>' are cast incompatible}} %0 = memref.cast %arg0 : memref<12x4x16xf32, offset:0, strides:[64, 16, 1]> to memref<12x4x16xf32, offset:16, strides:[64, 16, 1]> return } // ----- // incompatible element types func @invalid_memref_cast() { %0 = memref.alloc() : memref<2x5xf32, 0> // expected-error@+1 {{operand type 'memref<2x5xf32>' and result type 'memref<*xi32>' are cast incompatible}} %1 = memref.cast %0 : memref<2x5xf32, 0> to memref<*xi32> return } // ----- func @invalid_prefetch_rw(%i : index) { %0 = memref.alloc() : memref<10xf32> // expected-error@+1 {{rw specifier has to be 'read' or 'write'}} memref.prefetch %0[%i], rw, locality<0>, data : memref<10xf32> return } // ----- func @invalid_prefetch_cache_type(%i : index) { %0 = memref.alloc() : memref<10xf32> // expected-error@+1 {{cache type has to be 'data' or 'instr'}} memref.prefetch %0[%i], read, locality<0>, false : memref<10xf32> return } // ----- func @invalid_prefetch_locality_hint(%i : index) { %0 = memref.alloc() : memref<10xf32> // expected-error@+1 {{32-bit signless integer attribute whose minimum value is 0 whose maximum value is 3}} memref.prefetch %0[%i], read, locality<5>, data : memref<10xf32> return } // ----- // incompatible memory space func @invalid_memref_cast() { %0 = memref.alloc() : memref<2x5xf32, 0> // expected-error@+1 {{operand type 'memref<2x5xf32>' and result type 'memref<*xf32, 1>' are cast incompatible}} %1 = memref.cast %0 : memref<2x5xf32, 0> to memref<*xf32, 1> return } // ----- // unranked to unranked func @invalid_memref_cast() { %0 = memref.alloc() : memref<2x5xf32, 0> %1 = memref.cast %0 : memref<2x5xf32, 0> to memref<*xf32, 0> // expected-error@+1 {{operand type 'memref<*xf32>' and result type 'memref<*xf32>' are cast incompatible}} %2 = memref.cast %1 : memref<*xf32, 0> to memref<*xf32, 0> return } // ----- // alignment is not power of 2. func @assume_alignment(%0: memref<4x4xf16>) { // expected-error@+1 {{alignment must be power of 2}} memref.assume_alignment %0, 12 : memref<4x4xf16> return } // ----- // 0 alignment value. func @assume_alignment(%0: memref<4x4xf16>) { // expected-error@+1 {{attribute 'alignment' failed to satisfy constraint: 32-bit signless integer attribute whose value is positive}} memref.assume_alignment %0, 0 : memref<4x4xf16> return } // ----- "alloca_without_scoped_alloc_parent"() ({ memref.alloca() : memref<1xf32> // expected-error@-1 {{requires an ancestor op with AutomaticAllocationScope trait}} return }) : () -> () // ----- func @bad_alloc_wrong_dynamic_dim_count() { ^bb0: %0 = arith.constant 7 : index // Test alloc with wrong number of dynamic dimensions. // expected-error@+1 {{dimension operand count does not equal memref dynamic dimension count}} %1 = memref.alloc(%0)[%0] : memref<2x4xf32, affine_map<(d0, d1)[s0] -> ((d0 + s0), d1)>, 1> return } // ----- func @bad_alloc_wrong_symbol_count() { ^bb0: %0 = arith.constant 7 : index // Test alloc with wrong number of symbols // expected-error@+1 {{symbol operand count does not equal memref symbol count}} %1 = memref.alloc(%0) : memref<2x?xf32, affine_map<(d0, d1)[s0] -> ((d0 + s0), d1)>, 1> return } // ----- func @test_store_zero_results() { ^bb0: %0 = memref.alloc() : memref<1024x64xf32, affine_map<(d0, d1) -> (d0, d1)>, 1> %1 = arith.constant 0 : index %2 = arith.constant 1 : index %3 = memref.load %0[%1, %2] : memref<1024x64xf32, affine_map<(d0, d1) -> (d0, d1)>, 1> // Test that store returns zero results. %4 = memref.store %3, %0[%1, %2] : memref<1024x64xf32, affine_map<(d0, d1) -> (d0, d1)>, 1> // expected-error {{cannot name an operation with no results}} return } // ----- func @test_store_zero_results2(%x: i32, %p: memref) { "memref.store"(%x,%p) : (i32, memref) -> i32 // expected-error {{'memref.store' op requires zero results}} return } // ----- func @test_alloc_memref_map_rank_mismatch() { ^bb0: // expected-error@+1 {{memref layout mismatch between rank and affine map: 2 != 1}} %0 = memref.alloc() : memref<1024x64xf32, affine_map<(d0) -> (d0)>, 1> return } // ----- func @rank(%0: f32) { // expected-error@+1 {{'memref.rank' op operand #0 must be unranked.memref of any type values or memref of any type values}} "memref.rank"(%0): (f32)->index return } // ----- #map = affine_map<(d0, d1, d2)[s0, s1, s2, s3] -> (s0 + d0 * s1 + d1 * s2 + d2 * s3)> func @illegal_num_offsets(%arg0 : memref, %arg1 : index, %arg2 : index) { // expected-error@+1 {{expected 3 offset values}} %0 = memref.subview %arg0[0, 0] [%arg1, %arg2] [1, 1] : memref to memref } // ----- func @atomic_rmw_idxs_rank_mismatch(%I: memref<16x10xf32>, %i : index, %val : f32) { // expected-error@+1 {{expects the number of subscripts to be equal to memref rank}} %x = memref.atomic_rmw addf %val, %I[%i] : (f32, memref<16x10xf32>) -> f32 return } // ----- func @atomic_rmw_expects_float(%I: memref<16x10xi32>, %i : index, %val : i32) { // expected-error@+1 {{expects a floating-point type}} %x = memref.atomic_rmw addf %val, %I[%i, %i] : (i32, memref<16x10xi32>) -> i32 return } // ----- func @atomic_rmw_expects_int(%I: memref<16x10xf32>, %i : index, %val : f32) { // expected-error@+1 {{expects an integer type}} %x = memref.atomic_rmw addi %val, %I[%i, %i] : (f32, memref<16x10xf32>) -> f32 return } // ----- func @generic_atomic_rmw_wrong_arg_num(%I: memref<10xf32>, %i : index) { // expected-error@+1 {{expected single number of entry block arguments}} %x = memref.generic_atomic_rmw %I[%i] : memref<10xf32> { ^bb0(%arg0 : f32, %arg1 : f32): %c1 = arith.constant 1.0 : f32 memref.atomic_yield %c1 : f32 } return } // ----- func @generic_atomic_rmw_wrong_arg_type(%I: memref<10xf32>, %i : index) { // expected-error@+1 {{expected block argument of the same type result type}} %x = memref.generic_atomic_rmw %I[%i] : memref<10xf32> { ^bb0(%old_value : i32): %c1 = arith.constant 1.0 : f32 memref.atomic_yield %c1 : f32 } return } // ----- func @generic_atomic_rmw_result_type_mismatch(%I: memref<10xf32>, %i : index) { // expected-error@+1 {{failed to verify that result type matches element type of memref}} %0 = "memref.generic_atomic_rmw"(%I, %i) ({ ^bb0(%old_value: f32): %c1 = arith.constant 1.0 : f32 memref.atomic_yield %c1 : f32 }) : (memref<10xf32>, index) -> i32 return } // ----- func @generic_atomic_rmw_has_side_effects(%I: memref<10xf32>, %i : index) { // expected-error@+4 {{should contain only operations with no side effects}} %x = memref.generic_atomic_rmw %I[%i] : memref<10xf32> { ^bb0(%old_value : f32): %c1 = arith.constant 1.0 : f32 %buf = memref.alloc() : memref<2048xf32> memref.atomic_yield %c1 : f32 } } // ----- func @atomic_yield_type_mismatch(%I: memref<10xf32>, %i : index) { // expected-error@+4 {{op types mismatch between yield op: 'i32' and its parent: 'f32'}} %x = memref.generic_atomic_rmw %I[%i] : memref<10xf32> { ^bb0(%old_value : f32): %c1 = arith.constant 1 : i32 memref.atomic_yield %c1 : i32 } return }