[Mlir-commits] [mlir] [mlir][vector] Update tests for collapse 2/n (nfc) (PR #94604)
Andrzej WarzyĆski
llvmlistbot at llvm.org
Sun Jun 9 10:03:43 PDT 2024
https://github.com/banach-space updated https://github.com/llvm/llvm-project/pull/94604
>From 48c614fb8ece5a45b998c9b4206aeb80ec5d2d8b Mon Sep 17 00:00:00 2001
From: Andrzej Warzynski <andrzej.warzynski at arm.com>
Date: Wed, 5 Jun 2024 16:39:15 +0100
Subject: [PATCH 1/3] [mlir][vector] Update tests for collapse 1/n (nfc)
The main goal of this PR (and subsequent PRs), is to add more tests with
scalable vectors to:
* vector-transfer-collapse-inner-most-dims.mlir
There's quite a few cases to consider, hence this is split into multiple
PRs. In this PR, the very first test is complemented with all the possible
combinations:
* scalable (rather than fixed) unit trailing dim,
* dynamic (rather than static) trailing dim in the source memref.
Also,
* @leading_scalable_dimension_transfer_read and
@trailing_scalable_one_dim_transfer_read,
are replaced with:
* @contiguous_inner_most_scalable_inner_dim and
@negative_scalable_unit_dim,
respectively, and added to the list above (i.e. alongside other
variations for the very first test).
In addition:
* "_view" is removed from function names (it's not clear to me what it
was meant to signify)
* extra comments are added to separate tests for vector.transfer_read
and vector.transfer_write
NOTE: This PR is limited to tests for `vector.transfer_read`.
---
...tor-transfer-collapse-inner-most-dims.mlir | 91 ++++++++++++-------
1 file changed, 59 insertions(+), 32 deletions(-)
diff --git a/mlir/test/Dialect/Vector/vector-transfer-collapse-inner-most-dims.mlir b/mlir/test/Dialect/Vector/vector-transfer-collapse-inner-most-dims.mlir
index b4cb640108bae..0123709004bd6 100644
--- a/mlir/test/Dialect/Vector/vector-transfer-collapse-inner-most-dims.mlir
+++ b/mlir/test/Dialect/Vector/vector-transfer-collapse-inner-most-dims.mlir
@@ -1,12 +1,17 @@
// RUN: mlir-opt %s -test-vector-transfer-collapse-inner-most-dims -split-input-file | FileCheck %s
-func.func @contiguous_inner_most_view(%in: memref<1x1x8x1xf32, strided<[3072, 8, 1, 1], offset: ?>>) -> vector<1x8x1xf32>{
+//-----------------------------------------------------------------------------
+// 1. vector.transfer_read
+//-----------------------------------------------------------------------------
+
+func.func @contiguous_inner_most(%in: memref<1x1x8x1xf32, strided<[3072, 8, 1, 1], offset: ?>>) -> vector<1x8x1xf32>{
%c0 = arith.constant 0 : index
%cst = arith.constant 0.0 : f32
%0 = vector.transfer_read %in[%c0, %c0, %c0, %c0], %cst {in_bounds = [true, true, true]} : memref<1x1x8x1xf32, strided<[3072, 8, 1, 1], offset: ?>>, vector<1x8x1xf32>
return %0 : vector<1x8x1xf32>
}
-// CHECK: func @contiguous_inner_most_view(%[[SRC:.+]]: memref<1x1x8x1xf32, strided<[3072, 8, 1, 1], offset: ?>>
+
+// CHECK: func @contiguous_inner_most(%[[SRC:.+]]: memref<1x1x8x1xf32, strided<[3072, 8, 1, 1], offset: ?>>
// CHECK: %[[SRC_0:.+]] = memref.subview %[[SRC]]
// CHECK-SAME: memref<1x1x8x1xf32, strided<[3072, 8, 1, 1], offset: ?>> to memref<1x1x8xf32, strided<[3072, 8, 1], offset: ?>>
// CHECK: %[[VEC:.+]] = vector.transfer_read %[[SRC_0]]
@@ -14,15 +19,61 @@ func.func @contiguous_inner_most_view(%in: memref<1x1x8x1xf32, strided<[3072, 8,
// CHECK: %[[RESULT:.+]] = vector.shape_cast %[[VEC]]
// CHECK: return %[[RESULT]]
+// Same as the top example within this split, but with the inner vector
+// dim scalable. Note that this example only makes sense when "8 = [8]" (i.e.
+// vscale = 1). This is assumed (implicitly) via the `in_bounds` attribute.
+
+func.func @contiguous_inner_most_scalable_inner_dim(%in: memref<1x1x8x1xf32, strided<[3072, 8, 1, 1], offset: ?>>) -> vector<1x[8]x1xf32>{
+ %c0 = arith.constant 0 : index
+ %cst = arith.constant 0.0 : f32
+ %0 = vector.transfer_read %in[%c0, %c0, %c0, %c0], %cst {in_bounds = [true, true, true]} : memref<1x1x8x1xf32, strided<[3072, 8, 1, 1], offset: ?>>, vector<1x[8]x1xf32>
+ return %0 : vector<1x[8]x1xf32>
+}
+
+// CHECK: func @contiguous_inner_most_scalable_inner_dim(%[[SRC:.+]]: memref<1x1x8x1xf32, strided<[3072, 8, 1, 1], offset: ?>>
+// CHECK: %[[SRC_0:.+]] = memref.subview %[[SRC]]
+// CHECK-SAME: memref<1x1x8x1xf32, strided<[3072, 8, 1, 1], offset: ?>> to memref<1x1x8xf32, strided<[3072, 8, 1], offset: ?>>
+// CHECK: %[[VEC:.+]] = vector.transfer_read %[[SRC_0]]
+// CHECK-SAME: memref<1x1x8xf32, strided<[3072, 8, 1], offset: ?>>, vector<1x[8]xf32>
+// CHECK: %[[RESULT:.+]] = vector.shape_cast %[[VEC]]
+// CHECK: return %[[RESULT]]
+
+// Same as the top example within this split, but the trailing unit dim was
+// replaced with a dyn dim - not supported
+
+func.func @non_unit_trailing_dim(%in: memref<1x1x8x?xf32, strided<[3072, 8, 1, 1], offset: ?>>) -> vector<1x8x1xf32>{
+ %c0 = arith.constant 0 : index
+ %cst = arith.constant 0.0 : f32
+ %0 = vector.transfer_read %in[%c0, %c0, %c0, %c0], %cst {in_bounds = [true, true, true]} : memref<1x1x8x?xf32, strided<[3072, 8, 1, 1], offset: ?>>, vector<1x8x1xf32>
+ return %0 : vector<1x8x1xf32>
+}
+
+// CHECK-LABEL: func @non_unit_trailing_dim
+// CHECK-NOT: memref.subview
+// CHECK-NOT: vector.shape_cast
+
+// Same as the top example within this split, but with a scalable unit dim in
+// the output vector - not supported
+
+func.func @negative_scalable_unit_dim(%in: memref<1x1x8x1xf32, strided<[3072, 8, 1, 1], offset: ?>>) -> vector<1x8x[1]xf32>{
+ %c0 = arith.constant 0 : index
+ %cst = arith.constant 0.0 : f32
+ %0 = vector.transfer_read %in[%c0, %c0, %c0, %c0], %cst {in_bounds = [true, true, true]} : memref<1x1x8x1xf32, strided<[3072, 8, 1, 1], offset: ?>>, vector<1x8x[1]xf32>
+ return %0 : vector<1x8x[1]xf32>
+}
+// CHECK-LABEL: func @scalable_unit_dim
+// CHECK-NOT: memref.subview
+// CHECK-NOT: vector.shape_cast
+
// -----
-func.func @contiguous_outer_dyn_inner_most_view(%a: index, %b: index, %memref: memref<?x?x8x1xf32>) -> vector<8x1xf32> {
+func.func @contiguous_outer_dyn_inner_most(%a: index, %b: index, %memref: memref<?x?x8x1xf32>) -> vector<8x1xf32> {
%c0 = arith.constant 0 : index
%pad = arith.constant 0.0 : f32
%v = vector.transfer_read %memref[%a, %b, %c0, %c0], %pad {in_bounds = [true, true]} : memref<?x?x8x1xf32>, vector<8x1xf32>
return %v : vector<8x1xf32>
}
-// CHECK: func.func @contiguous_outer_dyn_inner_most_view(
+// CHECK: func.func @contiguous_outer_dyn_inner_most(
// CHECK-SAME: %[[IDX0:[a-zA-Z0-9]+]]
// CHECK-SAME: %[[IDX1:[a-zA-Z0-9]+]]
// CHECK-SAME: %[[SRC:[a-zA-Z0-9]+]]
@@ -103,6 +154,10 @@ func.func @contiguous_inner_most_dim_out_of_bounds_2d(%arg0: memref<1x1xf32>) ->
// -----
+//-----------------------------------------------------------------------------
+// 2. vector.transfer_write
+//-----------------------------------------------------------------------------
+
func.func @drop_two_inner_most_dim_for_transfer_write(%arg0: memref<1x512x16x1x1xf32>, %arg1: vector<1x16x16x1x1xf32>, %arg2: index) {
%c0 = arith.constant 0 : index
vector.transfer_write %arg1, %arg0[%c0, %arg2, %c0, %c0, %c0]
@@ -177,21 +232,6 @@ func.func @non_unit_strides(%arg0: memref<512x16x1xf32, strided<[8192, 16, 4], o
// -----
-func.func @leading_scalable_dimension_transfer_read(%dest : memref<24x1xf32>) -> vector<[4]x1xf32> {
- %c0 = arith.constant 0 : index
- %pad = arith.constant 0.0 : f32
- %0 = vector.transfer_read %dest[%c0, %c0], %pad {in_bounds = [true, true]} : memref<24x1xf32>, vector<[4]x1xf32>
- return %0 : vector<[4]x1xf32>
-}
-// CHECK: func.func @leading_scalable_dimension_transfer_read
-// CHECK-SAME: %[[DEST:[a-zA-Z0-9]+]]
-// CHECK: %[[SUBVIEW:.+]] = memref.subview %[[DEST]][0, 0] [24, 1] [1, 1] : memref<24x1xf32> to memref<24xf32, strided<[1]>>
-// CHECK: %[[READ:.+]] = vector.transfer_read %[[SUBVIEW]]{{.*}} {in_bounds = [true]} : memref<24xf32, strided<[1]>>, vector<[4]xf32>
-// CHECK: %[[CAST:.+]] = vector.shape_cast %[[READ]] : vector<[4]xf32> to vector<[4]x1xf32>
-// CHECK: return %[[CAST]]
-
-// -----
-
// Negative test: [1] (scalable 1) is _not_ a unit dimension.
func.func @trailing_scalable_one_dim_transfer_read(%dest : memref<24x1xf32>) -> vector<4x[1]xf32> {
%c0 = arith.constant 0 : index
@@ -217,16 +257,3 @@ func.func @leading_scalable_dimension_transfer_write(%dest : memref<24x1xf32>, %
// CHECK: %[[SUBVIEW:.+]] = memref.subview %[[DEST]][0, 0] [24, 1] [1, 1] : memref<24x1xf32> to memref<24xf32, strided<[1]>>
// CHECK: %[[CAST:.+]] = vector.shape_cast %[[VEC]] : vector<[4]x1xf32> to vector<[4]xf32>
// CHECK: vector.transfer_write %[[CAST]], %[[SUBVIEW]]{{.*}} {in_bounds = [true]} : vector<[4]xf32>, memref<24xf32, strided<[1]>>
-
-// -----
-
-// Negative test: [1] (scalable 1) is _not_ a unit dimension.
-func.func @trailing_scalable_one_dim_transfer_write(%dest : memref<24x1xf32>, %vec: vector<4x[1]xf32>, %index: index) {
- %c0 = arith.constant 0 : index
- vector.transfer_write %vec, %dest[%index, %c0] {in_bounds = [true, true]} : vector<4x[1]xf32>, memref<24x1xf32>
- return
-}
-// CHECK: func.func @trailing_scalable_one_dim_transfer_write
-// CHECK-NOT: vector.shape_cast
-// CHECK: vector.transfer_write {{.*}} : vector<4x[1]xf32>, memref<24x1xf32>
-// CHECK-NOT: vector.shape_cast
>From e9731a0a4ec6e26148c47895ed64a097e7090b3c Mon Sep 17 00:00:00 2001
From: Andrzej Warzynski <andrzej.warzynski at arm.com>
Date: Thu, 6 Jun 2024 18:07:09 +0100
Subject: [PATCH 2/3] fixup! [mlir][vector] Update tests for collapse 1/n (nfc)
Fix failing test
---
.../vector-transfer-collapse-inner-most-dims.mlir | 15 ++++++++++++++-
1 file changed, 14 insertions(+), 1 deletion(-)
diff --git a/mlir/test/Dialect/Vector/vector-transfer-collapse-inner-most-dims.mlir b/mlir/test/Dialect/Vector/vector-transfer-collapse-inner-most-dims.mlir
index 0123709004bd6..9b23681dba6a8 100644
--- a/mlir/test/Dialect/Vector/vector-transfer-collapse-inner-most-dims.mlir
+++ b/mlir/test/Dialect/Vector/vector-transfer-collapse-inner-most-dims.mlir
@@ -61,7 +61,7 @@ func.func @negative_scalable_unit_dim(%in: memref<1x1x8x1xf32, strided<[3072, 8,
%0 = vector.transfer_read %in[%c0, %c0, %c0, %c0], %cst {in_bounds = [true, true, true]} : memref<1x1x8x1xf32, strided<[3072, 8, 1, 1], offset: ?>>, vector<1x8x[1]xf32>
return %0 : vector<1x8x[1]xf32>
}
-// CHECK-LABEL: func @scalable_unit_dim
+// CHECK-LABEL: func @negative_scalable_unit_dim
// CHECK-NOT: memref.subview
// CHECK-NOT: vector.shape_cast
@@ -257,3 +257,16 @@ func.func @leading_scalable_dimension_transfer_write(%dest : memref<24x1xf32>, %
// CHECK: %[[SUBVIEW:.+]] = memref.subview %[[DEST]][0, 0] [24, 1] [1, 1] : memref<24x1xf32> to memref<24xf32, strided<[1]>>
// CHECK: %[[CAST:.+]] = vector.shape_cast %[[VEC]] : vector<[4]x1xf32> to vector<[4]xf32>
// CHECK: vector.transfer_write %[[CAST]], %[[SUBVIEW]]{{.*}} {in_bounds = [true]} : vector<[4]xf32>, memref<24xf32, strided<[1]>>
+
+// -----
+
+// Negative test: [1] (scalable 1) is _not_ a unit dimension.
+func.func @trailing_scalable_one_dim_transfer_write(%dest : memref<24x1xf32>, %vec: vector<4x[1]xf32>, %index: index) {
+ %c0 = arith.constant 0 : index
+ vector.transfer_write %vec, %dest[%index, %c0] {in_bounds = [true, true]} : vector<4x[1]xf32>, memref<24x1xf32>
+ return
+}
+// CHECK: func.func @trailing_scalable_one_dim_transfer_write
+// CHECK-NOT: vector.shape_cast
+// CHECK: vector.transfer_write {{.*}} : vector<4x[1]xf32>, memref<24x1xf32>
+// CHECK-NOT: vector.shape_cast
>From f246e3a18d978f78f88f79c1fea1bac4b79103c8 Mon Sep 17 00:00:00 2001
From: Andrzej Warzynski <andrzej.warzynski at arm.com>
Date: Thu, 6 Jun 2024 11:21:45 +0100
Subject: [PATCH 3/3] [mlir][vector] Update tests for collapse 2/n (nfc)
The main goal of this PR (and subsequent PRs), is to add more tests with
scalable vectors to:
* vector-transfer-collapse-inner-most-dims.mlir
Changes in this PR:
1. Renamed `@contiguous_inner_most_dim_bounds` as
`@contiguous_inner_most_dim_with_subview`. This test was introduced
to make sure that the `in_bounds` attribute is correctly preserved,
but that's already verified by some earlier tests. The updated name
highlights the differentiating factor of this test when compared to
the other tests _currently_ present in the file, i.e. the presence of
`memref.subview` in the input IR.
2. Renamed `@contiguous_inner_most_dim_out_of_bounds_2d` as
`@negative_non_unit_inner_vec_dim`. While this test does contain an
out-of-bounds access, the actual reason for the tested pattern to
fail is the fact that the inner dim in the output vector is not "1".
A complimentary test was added to verify that the pattern also fails
when the source memref has non-unit trailing dim
(`@negative_non_unit_inner_memref_dim`).
3. Renamed `@contiguous_inner_most_dim` as
`@contiguous_inner_most_dim_non_zero_idxs` - this test verifies that
the pattern works in the presence of non-zero idxs.
4. Added more tests for scalable vectors - this should cover all cases
for `vector.transfer_read`.
NOTE: This PR is limited to tests for `vector.transfer_read`.
Follow-up for: #94490
---
...tor-transfer-collapse-inner-most-dims.mlir | 136 +++++++++++++-----
1 file changed, 104 insertions(+), 32 deletions(-)
diff --git a/mlir/test/Dialect/Vector/vector-transfer-collapse-inner-most-dims.mlir b/mlir/test/Dialect/Vector/vector-transfer-collapse-inner-most-dims.mlir
index 9b23681dba6a8..a50c01898c62e 100644
--- a/mlir/test/Dialect/Vector/vector-transfer-collapse-inner-most-dims.mlir
+++ b/mlir/test/Dialect/Vector/vector-transfer-collapse-inner-most-dims.mlir
@@ -53,7 +53,7 @@ func.func @non_unit_trailing_dim(%in: memref<1x1x8x?xf32, strided<[3072, 8, 1, 1
// CHECK-NOT: vector.shape_cast
// Same as the top example within this split, but with a scalable unit dim in
-// the output vector - not supported
+// the output vector - not supported (scalable 1 is _not_ a unit dimension).
func.func @negative_scalable_unit_dim(%in: memref<1x1x8x1xf32, strided<[3072, 8, 1, 1], offset: ?>>) -> vector<1x8x[1]xf32>{
%c0 = arith.constant 0 : index
@@ -67,13 +67,13 @@ func.func @negative_scalable_unit_dim(%in: memref<1x1x8x1xf32, strided<[3072, 8,
// -----
-func.func @contiguous_outer_dyn_inner_most(%a: index, %b: index, %memref: memref<?x?x8x1xf32>) -> vector<8x1xf32> {
+func.func @contiguous_inner_most_dynamic_outer(%a: index, %b: index, %memref: memref<?x?x8x1xf32>) -> vector<8x1xf32> {
%c0 = arith.constant 0 : index
%pad = arith.constant 0.0 : f32
%v = vector.transfer_read %memref[%a, %b, %c0, %c0], %pad {in_bounds = [true, true]} : memref<?x?x8x1xf32>, vector<8x1xf32>
return %v : vector<8x1xf32>
}
-// CHECK: func.func @contiguous_outer_dyn_inner_most(
+// CHECK: func.func @contiguous_inner_most_dynamic_outer
// CHECK-SAME: %[[IDX0:[a-zA-Z0-9]+]]
// CHECK-SAME: %[[IDX1:[a-zA-Z0-9]+]]
// CHECK-SAME: %[[SRC:[a-zA-Z0-9]+]]
@@ -89,68 +89,154 @@ func.func @contiguous_outer_dyn_inner_most(%a: index, %b: index, %memref: memref
// CHECK: %[[RESULT:.+]] = vector.shape_cast %[[VEC]]
// CHECK: return %[[RESULT]]
+// Same as the top example within this split, but with the outer vector
+// dim scalable. Note that this example only makes sense when "8 = [8]" (i.e.
+// vscale = 1). This is assumed (implicitly) via the `in_bounds` attribute.
+
+func.func @contiguous_inner_most_outer_dim_dyn_scalable_inner_dim(%a: index, %b: index, %memref: memref<?x?x8x1xf32>) -> vector<[8]x1xf32> {
+ %c0 = arith.constant 0 : index
+ %pad = arith.constant 0.0 : f32
+ %v = vector.transfer_read %memref[%a, %b, %c0, %c0], %pad {in_bounds = [true, true]} : memref<?x?x8x1xf32>, vector<[8]x1xf32>
+ return %v : vector<[8]x1xf32>
+}
+// CHECK-LABEL: func @contiguous_inner_most_outer_dim_dyn_scalable_inner_dim
+// CHECK-SAME: %[[IDX0:[a-zA-Z0-9]+]]
+// CHECK-SAME: %[[IDX1:[a-zA-Z0-9]+]]
+// CHECK-SAME: %[[SRC:[a-zA-Z0-9]+]]
+// CHECK: %[[VIEW:.+]] = memref.subview %[[SRC]]{{.*}} memref<?x?x8x1xf32> to memref<?x?x8xf32, strided<[?, 8, 1], offset: ?>>
+// CHECK: %[[VEC_READ:.+]] = vector.transfer_read %[[VIEW]]
+// CHECK-SAME: {in_bounds = [true]}
+// CHECK-SAME: memref<?x?x8xf32, strided<[?, 8, 1], offset: ?>>, vector<[8]xf32>
+// CHECK: vector.shape_cast %[[VEC_READ]]
+
// -----
-func.func @contiguous_inner_most_dim(%A: memref<16x1xf32>, %i:index, %j:index) -> (vector<8x1xf32>) {
+func.func @contiguous_inner_most_dim_non_zero_idxs(%A: memref<16x1xf32>, %i:index, %j:index) -> (vector<8x1xf32>) {
%c0 = arith.constant 0 : index
%f0 = arith.constant 0.0 : f32
%1 = vector.transfer_read %A[%i, %j], %f0 : memref<16x1xf32>, vector<8x1xf32>
return %1 : vector<8x1xf32>
}
-// CHECK: func @contiguous_inner_most_dim(%[[SRC:.+]]: memref<16x1xf32>, %[[I:.+]]: index, %[[J:.+]]: index) -> vector<8x1xf32>
+// CHECK: func @contiguous_inner_most_dim_non_zero_idxs(%[[SRC:.+]]: memref<16x1xf32>, %[[I:.+]]: index, %[[J:.+]]: index) -> vector<8x1xf32>
// CHECK: %[[SRC_0:.+]] = memref.subview %[[SRC]]
// CHECK-SAME: memref<16x1xf32> to memref<16xf32, strided<[1]>>
// CHECK: %[[V:.+]] = vector.transfer_read %[[SRC_0]]
-// CHECK: %[[RESULT]] = vector.shape_cast %[[V]] : vector<8xf32> to vector<8x1xf32>
+// CHECK: %[[RESULT:.+]] = vector.shape_cast %[[V]] : vector<8xf32> to vector<8x1xf32>
// CHECK: return %[[RESULT]]
+// Same as the top example within this split, but with the outer vector
+// dim scalable. Note that this example only makes sense when "8 = [8]" (i.e.
+// vscale = 1). This is assumed (implicitly) via the `in_bounds` attribute.
+
+func.func @contiguous_inner_most_dim_non_zero_idxs_scalable_inner_dim(%A: memref<16x1xf32>, %i:index, %j:index) -> (vector<[8]x1xf32>) {
+ %c0 = arith.constant 0 : index
+ %f0 = arith.constant 0.0 : f32
+ %1 = vector.transfer_read %A[%i, %j], %f0 : memref<16x1xf32>, vector<[8]x1xf32>
+ return %1 : vector<[8]x1xf32>
+}
+// CHECK-LABEL: func @contiguous_inner_most_dim_non_zero_idxs_scalable_inner_dim(
+// CHECK-SAME: %[[SRC:.+]]: memref<16x1xf32>, %[[I:.+]]: index, %[[J:.+]]: index) -> vector<[8]x1xf32>
+// CHECK: %[[SRC_0:.+]] = memref.subview %[[SRC]]
+// CHECK-SAME: memref<16x1xf32> to memref<16xf32, strided<[1]>>
+// CHECK: %[[V:.+]] = vector.transfer_read %[[SRC_0]]
+// CHECK: %[[RESULT:.+]] = vector.shape_cast %[[V]] : vector<[8]xf32> to vector<[8]x1xf32>
+// CHECK: return %[[RESULT]]
+
// -----
-func.func @contiguous_inner_most_dim_bounds(%A: memref<1000x1xf32>, %i:index, %ii:index) -> (vector<4x1xf32>) {
+func.func @contiguous_inner_most_dim_with_subview(%A: memref<1000x1xf32>, %i:index, %ii:index) -> (vector<4x1xf32>) {
%c0 = arith.constant 0 : index
%cst = arith.constant 0.0 : f32
%0 = memref.subview %A[%i, 0] [40, 1] [1, 1] : memref<1000x1xf32> to memref<40x1xf32, strided<[1, 1], offset: ?>>
%1 = vector.transfer_read %0[%ii, %c0], %cst {in_bounds = [true, true]} : memref<40x1xf32, strided<[1, 1], offset: ?>>, vector<4x1xf32>
return %1 : vector<4x1xf32>
}
-// CHECK: func @contiguous_inner_most_dim_bounds(%[[SRC:.+]]: memref<1000x1xf32>, %[[II:.+]]: index, %[[J:.+]]: index) -> vector<4x1xf32>
+// CHECK: func @contiguous_inner_most_dim_with_subview(%[[SRC:.+]]: memref<1000x1xf32>, %[[II:.+]]: index, %[[J:.+]]: index) -> vector<4x1xf32>
// CHECK: %[[SRC_0:.+]] = memref.subview %[[SRC]]
// CHECK: %[[SRC_1:.+]] = memref.subview %[[SRC_0]]
// CHECK: %[[V:.+]] = vector.transfer_read %[[SRC_1]]
// CHECK-SAME: {in_bounds = [true]}
// CHECK-SAME: vector<4xf32>
+// Same as the top example within this split, but with the outer vector
+// dim scalable. Note that this example only makes sense when "4 = [4]" (i.e.
+// vscale = 1). This is assumed (implicitly) via the `in_bounds` attribute.
+
+func.func @contiguous_inner_most_dim_with_subview_scalable_inner_dim(%A: memref<1000x1xf32>, %i:index, %ii:index) -> (vector<[4]x1xf32>) {
+ %c0 = arith.constant 0 : index
+ %cst = arith.constant 0.0 : f32
+ %0 = memref.subview %A[%i, 0] [40, 1] [1, 1] : memref<1000x1xf32> to memref<40x1xf32, strided<[1, 1], offset: ?>>
+ %1 = vector.transfer_read %0[%ii, %c0], %cst {in_bounds = [true, true]} : memref<40x1xf32, strided<[1, 1], offset: ?>>, vector<[4]x1xf32>
+ return %1 : vector<[4]x1xf32>
+}
+// CHECK-LABEL: func @contiguous_inner_most_dim_with_subview_scalable_inner_dim
+// CHECK-SAME: %[[SRC:.+]]: memref<1000x1xf32>
+// CHECK: %[[SRC_0:.+]] = memref.subview %[[SRC]]
+// CHECK: %[[V:.+]] = vector.transfer_read %[[SRC_0]]
+// CHECK-SAME: {in_bounds = [true]}
+// CHECK-SAME: vector<[4]xf32>
+
// -----
-func.func @contiguous_inner_most_dim_bounds_2d(%A: memref<1000x1x1xf32>, %i:index, %ii:index) -> (vector<4x1x1xf32>) {
+func.func @contiguous_inner_most_dim_with_subview_2d(%A: memref<1000x1x1xf32>, %i:index, %ii:index) -> (vector<4x1x1xf32>) {
%c0 = arith.constant 0 : index
%cst = arith.constant 0.0 : f32
%0 = memref.subview %A[%i, 0, 0] [40, 1, 1] [1, 1, 1] : memref<1000x1x1xf32> to memref<40x1x1xf32, strided<[1, 1, 1], offset: ?>>
%1 = vector.transfer_read %0[%ii, %c0, %c0], %cst {in_bounds = [true, true, true]} : memref<40x1x1xf32, strided<[1, 1, 1], offset: ?>>, vector<4x1x1xf32>
return %1 : vector<4x1x1xf32>
}
-// CHECK: func @contiguous_inner_most_dim_bounds_2d(%[[SRC:.+]]: memref<1000x1x1xf32>, %[[II:.+]]: index, %[[J:.+]]: index) -> vector<4x1x1xf32>
+// CHECK: func @contiguous_inner_most_dim_with_subview_2d(%[[SRC:.+]]: memref<1000x1x1xf32>, %[[II:.+]]: index, %[[J:.+]]: index) -> vector<4x1x1xf32>
// CHECK: %[[SRC_0:.+]] = memref.subview %[[SRC]]
// CHECK: %[[SRC_1:.+]] = memref.subview %[[SRC_0]]
// CHECK: %[[V:.+]] = vector.transfer_read %[[SRC_1]]
// CHECK-SAME: {in_bounds = [true]}
// CHECK-SAME: vector<4xf32>
+// Same as the top example within this split, but with the outer vector
+// dim scalable. Note that this example only makes sense when "4 = [4]" (i.e.
+// vscale = 1). This is assumed (implicitly) via the `in_bounds` attribute.
+
+func.func @contiguous_inner_most_dim_with_subview_2d_scalable_inner_dim(%A: memref<1000x1x1xf32>, %i:index, %ii:index) -> (vector<[4]x1x1xf32>) {
+ %c0 = arith.constant 0 : index
+ %cst = arith.constant 0.0 : f32
+ %0 = memref.subview %A[%i, 0, 0] [40, 1, 1] [1, 1, 1] : memref<1000x1x1xf32> to memref<40x1x1xf32, strided<[1, 1, 1], offset: ?>>
+ %1 = vector.transfer_read %0[%ii, %c0, %c0], %cst {in_bounds = [true, true, true]} : memref<40x1x1xf32, strided<[1, 1, 1], offset: ?>>, vector<[4]x1x1xf32>
+ return %1 : vector<[4]x1x1xf32>
+}
+// CHECK-LABEL: func @contiguous_inner_most_dim_with_subview_2d_scalable_inner_dim(
+// CHECK-SAME: %[[SRC:.+]]: memref<1000x1x1xf32>, %[[II:.+]]: index, %[[J:.+]]: index) -> vector<[4]x1x1xf32>
+// CHECK: %[[SRC_0:.+]] = memref.subview %[[SRC]]
+// CHECK: %[[SRC_1:.+]] = memref.subview %[[SRC_0]]
+// CHECK: %[[V:.+]] = vector.transfer_read %[[SRC_1]]
+// CHECK-SAME: {in_bounds = [true]}
+// CHECK-SAME: vector<[4]xf32>
+// CHECK: vector.shape_cast %[[V]]
+
// -----
-func.func @contiguous_inner_most_dim_out_of_bounds_2d(%arg0: memref<1x1xf32>) -> vector<4x8xf32> {
+// NOTE: This is an out-of-bounds access.
+
+func.func @negative_non_unit_inner_vec_dim(%arg0: memref<4x1xf32>) -> vector<4x8xf32> {
%c0 = arith.constant 0 : index
%cst = arith.constant 0.000000e+00 : f32
- %0 = vector.transfer_read %arg0[%c0, %c0], %cst : memref<1x1xf32>, vector<4x8xf32>
+ %0 = vector.transfer_read %arg0[%c0, %c0], %cst : memref<4x1xf32>, vector<4x8xf32>
return %0 : vector<4x8xf32>
}
-// The inner most unit dim can not be dropped. In this context, we do not
-// generate rank-reduced memref.subview ops.
-// CHECK: func.func @contiguous_inner_most_dim_out_of_bounds_2d
-// CHECK-SAME: %[[SRC:[a-zA-Z0-9]+]]
+// CHECK: func.func @negative_non_unit_inner_vec_dim
+// CHECK-NOT: memref.subview
+// CHECK: vector.transfer_read
+
+// -----
+
+func.func @negative_non_unit_inner_memref_dim(%arg0: memref<4x8xf32>) -> vector<4x1xf32> {
+ %c0 = arith.constant 0 : index
+ %cst = arith.constant 0.000000e+00 : f32
+ %0 = vector.transfer_read %arg0[%c0, %c0], %cst : memref<4x8xf32>, vector<4x1xf32>
+ return %0 : vector<4x1xf32>
+}
+// CHECK: func.func @negative_non_unit_inner_memref_dim
// CHECK-NOT: memref.subview
-// CHECK: %[[READ:.+]] = vector.transfer_read %[[SRC]]
-// CHECK: return %[[READ]] : vector<4x8xf32>
+// CHECK: vector.transfer_read
// -----
@@ -232,20 +318,6 @@ func.func @non_unit_strides(%arg0: memref<512x16x1xf32, strided<[8192, 16, 4], o
// -----
-// Negative test: [1] (scalable 1) is _not_ a unit dimension.
-func.func @trailing_scalable_one_dim_transfer_read(%dest : memref<24x1xf32>) -> vector<4x[1]xf32> {
- %c0 = arith.constant 0 : index
- %pad = arith.constant 0.0 : f32
- %0 = vector.transfer_read %dest[%c0, %c0], %pad {in_bounds = [true, true]} : memref<24x1xf32>, vector<4x[1]xf32>
- return %0 : vector<4x[1]xf32>
-}
-// CHECK: func.func @trailing_scalable_one_dim_transfer_read
-// CHECK-NOT: vector.shape_cast
-// CHECK: vector.transfer_read {{.*}} : memref<24x1xf32>, vector<4x[1]xf32>
-// CHECK-NOT: vector.shape_cast
-
-// -----
-
func.func @leading_scalable_dimension_transfer_write(%dest : memref<24x1xf32>, %vec: vector<[4]x1xf32>) {
%c0 = arith.constant 0 : index
vector.transfer_write %vec, %dest[%c0, %c0] {in_bounds = [true, true]} : vector<[4]x1xf32>, memref<24x1xf32>
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