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// RUN: mlir-opt -allow-unregistered-dialect -split-input-file %s | FileCheck %s
// RUN: mlir-opt -allow-unregistered-dialect %s -mlir-print-op-generic | FileCheck -check-prefix=GENERIC %s
// Check that the attributes for the affine operations are round-tripped.
// Check that `affine.yield` is visible in the generic form.
// CHECK-LABEL: @empty
func @empty() {
// CHECK: affine.for
// CHECK-NEXT: } {some_attr = true}
//
// GENERIC: "affine.for"()
// GENERIC-NEXT: ^bb0(%{{.*}}: index):
// GENERIC-NEXT: "affine.yield"() : () -> ()
// GENERIC-NEXT: })
affine.for %i = 0 to 10 {
} {some_attr = true}
// CHECK: affine.if
// CHECK-NEXT: } {some_attr = true}
//
// GENERIC: "affine.if"()
// GENERIC-NEXT: "affine.yield"() : () -> ()
// GENERIC-NEXT: }, {
// GENERIC-NEXT: })
affine.if affine_set<() : ()> () {
} {some_attr = true}
// CHECK: } else {
// CHECK: } {some_attr = true}
//
// GENERIC: "affine.if"()
// GENERIC-NEXT: "affine.yield"() : () -> ()
// GENERIC-NEXT: }, {
// GENERIC-NEXT: "foo"() : () -> ()
// GENERIC-NEXT: "affine.yield"() : () -> ()
// GENERIC-NEXT: })
affine.if affine_set<() : ()> () {
} else {
"foo"() : () -> ()
} {some_attr = true}
return
}
// Check that an explicit affine.yield is not printed in custom format.
// Check that no extra terminator is introduced.
// CHECK-LABEL: @affine.yield
func @affine.yield() {
// CHECK: affine.for
// CHECK-NEXT: }
//
// GENERIC: "affine.for"() ( {
// GENERIC-NEXT: ^bb0(%{{.*}}: index): // no predecessors
// GENERIC-NEXT: "affine.yield"() : () -> ()
// GENERIC-NEXT: }) {lower_bound = #map0, step = 1 : index, upper_bound = #map1} : () -> ()
affine.for %i = 0 to 10 {
"affine.yield"() : () -> ()
}
return
}
// -----
// CHECK-DAG: #[[$MAP0:map[0-9]+]] = affine_map<(d0)[s0] -> (1000, d0 + 512, s0)>
// CHECK-DAG: #[[$MAP1:map[0-9]+]] = affine_map<(d0, d1)[s0] -> (d0 - d1, s0 + 512)>
// CHECK-DAG: #[[$MAP2:map[0-9]+]] = affine_map<()[s0, s1] -> (s0 - s1, 11)>
// CHECK-DAG: #[[$MAP3:map[0-9]+]] = affine_map<() -> (77, 78, 79)>
// CHECK-LABEL: @affine_min
func @affine_min(%arg0 : index, %arg1 : index, %arg2 : index) {
// CHECK: affine.min #[[$MAP0]](%arg0)[%arg1]
%0 = affine.min affine_map<(d0)[s0] -> (1000, d0 + 512, s0)> (%arg0)[%arg1]
// CHECK: affine.min #[[$MAP1]](%arg0, %arg1)[%arg2]
%1 = affine.min affine_map<(d0, d1)[s0] -> (d0 - d1, s0 + 512)> (%arg0, %arg1)[%arg2]
// CHECK: affine.min #[[$MAP2]]()[%arg1, %arg2]
%2 = affine.min affine_map<()[s0, s1] -> (s0 - s1, 11)> ()[%arg1, %arg2]
// CHECK: affine.min #[[$MAP3]]()
%3 = affine.min affine_map<()[] -> (77, 78, 79)> ()[]
return
}
// CHECK-LABEL: @affine_max
func @affine_max(%arg0 : index, %arg1 : index, %arg2 : index) {
// CHECK: affine.max #[[$MAP0]](%arg0)[%arg1]
%0 = affine.max affine_map<(d0)[s0] -> (1000, d0 + 512, s0)> (%arg0)[%arg1]
// CHECK: affine.max #[[$MAP1]](%arg0, %arg1)[%arg2]
%1 = affine.max affine_map<(d0, d1)[s0] -> (d0 - d1, s0 + 512)> (%arg0, %arg1)[%arg2]
// CHECK: affine.max #[[$MAP2]]()[%arg1, %arg2]
%2 = affine.max affine_map<()[s0, s1] -> (s0 - s1, 11)> ()[%arg1, %arg2]
// CHECK: affine.max #[[$MAP3]]()
%3 = affine.max affine_map<()[] -> (77, 78, 79)> ()[]
return
}
// -----
func @valid_symbols(%arg0: index, %arg1: index, %arg2: index) {
%c1 = constant 1 : index
%c0 = constant 0 : index
%0 = alloc(%arg0, %arg1) : memref<?x?xf32>
affine.for %arg3 = 0 to %arg2 step 768 {
%13 = dim %0, %c1 : memref<?x?xf32>
affine.for %arg4 = 0 to %13 step 264 {
%18 = dim %0, %c0 : memref<?x?xf32>
%20 = std.subview %0[%c0, %c0][%18,%arg4][%c1,%c1] : memref<?x?xf32>
to memref<?x?xf32, offset : ?, strides : [?, ?]>
%24 = dim %20, %c0 : memref<?x?xf32, offset : ?, strides : [?, ?]>
affine.for %arg5 = 0 to %24 step 768 {
"foo"() : () -> ()
}
}
}
return
}
// -----
// Test symbol constraints for ops with AffineScope trait.
// CHECK-LABEL: func @valid_symbol_affine_scope
func @valid_symbol_affine_scope(%n : index, %A : memref<?xf32>) {
test.affine_scope {
%c1 = constant 1 : index
%l = subi %n, %c1 : index
// %l, %n are valid symbols since test.affine_scope defines a new affine
// scope.
affine.for %i = %l to %n {
%m = subi %l, %i : index
test.affine_scope {
// %m and %n are valid symbols.
affine.for %j = %m to %n {
%v = affine.load %A[%n - 1] : memref<?xf32>
affine.store %v, %A[%n - 1] : memref<?xf32>
}
"terminate"() : () -> ()
}
}
"terminate"() : () -> ()
}
return
}
// -----
// Test the fact that module op always provides an affine scope.
%idx = "test.foo"() : () -> (index)
"test.func"() ({
^bb0(%A : memref<?xf32>):
affine.load %A[%idx] : memref<?xf32>
"terminate"() : () -> ()
}) : () -> ()
// -----
// CHECK-LABEL: func @parallel
// CHECK-SAME: (%[[A:.*]]: memref<100x100xf32>, %[[N:.*]]: index)
func @parallel(%A : memref<100x100xf32>, %N : index) {
// CHECK: affine.parallel (%[[I0:.*]], %[[J0:.*]]) = (0, 0) to (symbol(%[[N]]), 100) step (10, 10)
affine.parallel (%i0, %j0) = (0, 0) to (symbol(%N), 100) step (10, 10) {
// CHECK: affine.parallel (%{{.*}}, %{{.*}}) = (%[[I0]], %[[J0]]) to (%[[I0]] + 10, %[[J0]] + 10) reduce ("minf", "maxf") -> (f32, f32)
%0:2 = affine.parallel (%i1, %j1) = (%i0, %j0) to (%i0 + 10, %j0 + 10) reduce ("minf", "maxf") -> (f32, f32) {
%2 = affine.load %A[%i0 + %i0, %j0 + %j1] : memref<100x100xf32>
affine.yield %2, %2 : f32, f32
}
}
return
}
// -----
// CHECK-LABEL: func @affine_if
func @affine_if() -> f32 {
// CHECK: %[[ZERO:.*]] = constant {{.*}} : f32
%zero = constant 0.0 : f32
// CHECK: %[[OUT:.*]] = affine.if {{.*}}() -> f32 {
%0 = affine.if affine_set<() : ()> () -> f32 {
// CHECK: affine.yield %[[ZERO]] : f32
affine.yield %zero : f32
} else {
// CHECK: affine.yield %[[ZERO]] : f32
affine.yield %zero : f32
}
// CHECK: return %[[OUT]] : f32
return %0 : f32
}
// -----
// Test affine.for with yield values.
#set = affine_set<(d0): (d0 - 10 >= 0)>
// CHECK-LABEL: func @yield_loop
func @yield_loop(%buffer: memref<1024xf32>) -> f32 {
%sum_init_0 = constant 0.0 : f32
%res = affine.for %i = 0 to 10 step 2 iter_args(%sum_iter = %sum_init_0) -> f32 {
%t = affine.load %buffer[%i] : memref<1024xf32>
%sum_next = affine.if #set(%i) -> (f32) {
%new_sum = addf %sum_iter, %t : f32
affine.yield %new_sum : f32
} else {
affine.yield %sum_iter : f32
}
affine.yield %sum_next : f32
}
return %res : f32
}
// CHECK: %[[const_0:.*]] = constant 0.000000e+00 : f32
// CHECK-NEXT: %[[output:.*]] = affine.for %{{.*}} = 0 to 10 step 2 iter_args(%{{.*}} = %[[const_0]]) -> (f32) {
// CHECK: affine.if #set(%{{.*}}) -> f32 {
// CHECK: affine.yield %{{.*}} : f32
// CHECK-NEXT: } else {
// CHECK-NEXT: affine.yield %{{.*}} : f32
// CHECK-NEXT: }
// CHECK-NEXT: affine.yield %{{.*}} : f32
// CHECK-NEXT: }
// CHECK-NEXT: return %[[output]] : f32
// CHECK-LABEL: func @affine_for_multiple_yield
func @affine_for_multiple_yield(%buffer: memref<1024xf32>) -> (f32, f32) {
%init_0 = constant 0.0 : f32
%res1, %res2 = affine.for %i = 0 to 10 step 2 iter_args(%iter_arg1 = %init_0, %iter_arg2 = %init_0) -> (f32, f32) {
%t = affine.load %buffer[%i] : memref<1024xf32>
%ret1 = addf %t, %iter_arg1 : f32
%ret2 = addf %t, %iter_arg2 : f32
affine.yield %ret1, %ret2 : f32, f32
}
return %res1, %res2 : f32, f32
}
// CHECK: %[[const_0:.*]] = constant 0.000000e+00 : f32
// CHECK-NEXT: %[[output:[0-9]+]]:2 = affine.for %{{.*}} = 0 to 10 step 2 iter_args(%[[iter_arg1:.*]] = %[[const_0]], %[[iter_arg2:.*]] = %[[const_0]]) -> (f32, f32) {
// CHECK: %[[res1:.*]] = addf %{{.*}}, %[[iter_arg1]] : f32
// CHECK-NEXT: %[[res2:.*]] = addf %{{.*}}, %[[iter_arg2]] : f32
// CHECK-NEXT: affine.yield %[[res1]], %[[res2]] : f32, f32
// CHECK-NEXT: }