// RUN: mlir-opt -test-constant-fold -split-input-file %s | FileCheck %s
// CHECK-LABEL: func @affine_apply
func.func @affine_apply(%variable : index) -> (index, index, index) {
%c177 = arith.constant 177 : index
%c211 = arith.constant 211 : index
%N = arith.constant 1075 : index
// CHECK:[[C1159:%.+]] = arith.constant 1159 : index
// CHECK:[[C1152:%.+]] = arith.constant 1152 : index
%x0 = affine.apply affine_map<(d0, d1)[S0] -> ( (d0 + 128 * S0) floordiv 128 + d1 mod 128)>
(%c177, %c211)[%N]
%x1 = affine.apply affine_map<(d0, d1)[S0] -> (128 * (S0 ceildiv 128))>
(%c177, %c211)[%N]
// CHECK:[[C42:%.+]] = arith.constant 42 : index
%y = affine.apply affine_map<(d0) -> (42)> (%variable)
// CHECK: return [[C1159]], [[C1152]], [[C42]]
return %x0, %x1, %y : index, index, index
}
// -----
// CHECK: #[[map:.*]] = affine_map<(d0, d1) -> (42, d1)
func.func @affine_min(%variable: index) -> (index, index) {
// CHECK: %[[C42:.*]] = arith.constant 42
%c42 = arith.constant 42 : index
%c44 = arith.constant 44 : index
// Partial folding will use a different map.
// CHECK: %[[r:.*]] = affine.min #[[map]](%[[C42]], %{{.*}})
%0 = affine.min affine_map<(d0, d1) -> (d0, d1)>(%c42, %variable)
// Full folding will remove the operation entirely.
// CHECK-NOT: affine.min
%1 = affine.min affine_map<(d0, d1) -> (d0, d1)>(%c42, %c44)
// CHECK: return %[[r]], %[[C42]]
return %0, %1 : index, index
}
// -----
// CHECK: #[[map:.*]] = affine_map<(d0, d1) -> (42, d1)
func.func @affine_min(%variable: index) -> (index, index) {
// CHECK: %[[C42:.*]] = arith.constant 42
%c42 = arith.constant 42 : index
// CHECK: %[[C44:.*]] = arith.constant 44
%c44 = arith.constant 44 : index
// Partial folding will use a different map.
// CHECK: %[[r:.*]] = affine.max #[[map]](%[[C42]], %{{.*}})
%0 = affine.max affine_map<(d0, d1) -> (d0, d1)>(%c42, %variable)
// Full folding will remove the operation entirely.
// CHECK-NOT: affine.max
%1 = affine.max affine_map<(d0, d1) -> (d0, d1)>(%c42, %c44)
// CHECK: return %[[r]], %[[C44]]
return %0, %1 : index, index
}
// -----
func.func @affine_apply_poison_division_zero() {
// This is just for mlir::context to load ub dialect
%ub = ub.poison : index
%c16 = arith.constant 16 : index
%0 = affine.apply affine_map<(d0)[s0] -> (d0 mod (s0 - s0))>(%c16)[%c16]
%1 = affine.apply affine_map<(d0)[s0] -> (d0 floordiv (s0 - s0))>(%c16)[%c16]
%2 = affine.apply affine_map<(d0)[s0] -> (d0 ceildiv (s0 - s0))>(%c16)[%c16]
%alloc = memref.alloc(%0, %1, %2) : memref<?x?x?xi1>
%3 = affine.load %alloc[%0, %1, %2] : memref<?x?x?xi1>
affine.store %3, %alloc[%0, %1, %2] : memref<?x?x?xi1>
return
}
// CHECK-NOT: affine.apply
// CHECK: %[[poison:.*]] = ub.poison : index
// CHECK-NEXT: %[[alloc:.*]] = memref.alloc(%[[poison]], %[[poison]], %[[poison]])
// CHECK-NEXT: %[[load:.*]] = affine.load %[[alloc]][%[[poison]], %[[poison]], %[[poison]]] : memref<?x?x?xi1>
// CHECK-NEXT: affine.store %[[load]], %alloc[%[[poison]], %[[poison]], %[[poison]]] : memref<?x?x?xi1>
// -----
// Check that this doesn't crash because the ub dialect is automatically loaded
func.func @affine_apply_poison_division_zero_2() -> index {
%c16 = arith.constant 16 : index
%0 = affine.apply affine_map<(d0)[s0] -> (d0 mod (s0 - s0))>(%c16)[%c16]
return %0 : index
}
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