// RUN: mlir-opt %s -split-input-file -affine-data-copy-generate="generate-dma=false fast-mem-space=0 skip-non-unit-stride-loops" | FileCheck %s // Small buffer size to trigger fine copies. // RUN: mlir-opt %s -split-input-file -affine-data-copy-generate="generate-dma=false fast-mem-space=0 fast-mem-capacity=1" | FileCheck --check-prefix=CHECK-SMALL %s // Test affine data copy with a memref filter. We use a test pass that invokes // affine data copy utility on the input loop nest. // '-test-affine-data-copy-memref-filter' passes the first memref found in an // affine.load op in the innermost loop as a filter. // RUN: mlir-opt %s -split-input-file -test-affine-data-copy='memref-filter' | FileCheck %s --check-prefix=FILTER // RUN: mlir-opt %s -split-input-file -test-affine-data-copy='for-memref-region' | FileCheck %s --check-prefix=MEMREF_REGION // -copy-skip-non-stride-loops forces the copies to be placed right inside the // tile space loops, avoiding the sensitivity of copy placement depth to memory // footprint -- so that one could write a definite test case and not have to // update it each time something related to the cost functions change. #id = affine_map<(d0) -> (d0)> #ub = affine_map<(d0) -> (d0 + 128)> // Map used to index the buffer while computing. // CHECK-DAG: [[$MAP_IDENTITY:map[0-9]+]] = affine_map<(d0) -> (d0)> // CHECK-DAG: [[$MAP_PLUS_128:map[0-9]+]] = affine_map<(d0) -> (d0 + 128)> // CHECK-LABEL: func @matmul // FILTER-LABEL: func @matmul func @matmul(%A: memref<4096x4096xf32>, %B: memref<4096x4096xf32>, %C: memref<4096x4096xf32>) -> memref<4096x4096xf32> { affine.for %i = 0 to 4096 step 128 { affine.for %j = 0 to 4096 step 128 { affine.for %k = 0 to 4096 step 128 { affine.for %ii = #id(%i) to #ub(%i) { affine.for %jj = #id(%j) to #ub(%j) { affine.for %kk = #id(%k) to #ub(%k) { %5 = affine.load %A[%ii, %kk] : memref<4096x4096xf32> %6 = affine.load %B[%kk, %jj] : memref<4096x4096xf32> %7 = affine.load %C[%ii, %jj] : memref<4096x4096xf32> %8 = mulf %5, %6 : f32 %9 = addf %7, %8 : f32 affine.store %9, %C[%ii, %jj] : memref<4096x4096xf32> } } } } } } return %C : memref<4096x4096xf32> } // Buffers of size 128x128 get created here for all three matrices. // CHECK: affine.for %[[I:.*]] = 0 to 4096 step 128 { // CHECK: affine.for %[[J:.*]] = 0 to 4096 step 128 { // CHECK: [[BUFC:%[0-9]+]] = alloc() : memref<128x128xf32> // The result matrix's copy gets hoisted out. // Result matrix copy-in. // CHECK: affine.for %[[II:.*]] = #[[$MAP_IDENTITY]](%{{.*}}) to #[[$MAP_PLUS_128]](%{{.*}}) { // CHECK: affine.for %[[JJ:.*]] = #[[$MAP_IDENTITY]](%{{.*}}) to #[[$MAP_PLUS_128]](%{{.*}}) { // CHECK: affine.load %{{.*}}[%{{.*}}, %{{.*}}] : memref<4096x4096xf32> // CHECK: affine.store %{{.*}}, [[BUFC]][-%[[I]] + %[[II]], -%[[J]] + %[[JJ]]] : memref<128x128xf32> // CHECK: } // CHECK: } // LHS matrix copy-in. // CHECK: affine.for %[[K:.*]] = 0 to 4096 step 128 { // CHECK: [[BUFA:%[0-9]+]] = alloc() : memref<128x128xf32> // CHECK: affine.for %[[II:.*]] = #[[$MAP_IDENTITY]](%{{.*}}) to #[[$MAP_PLUS_128]](%{{.*}}) { // CHECK: affine.for %[[KK:.*]] = #[[$MAP_IDENTITY]](%{{.*}}) to #[[$MAP_PLUS_128]](%{{.*}}) { // CHECK: affine.load %{{.*}}[%{{.*}}, %{{.*}}] : memref<4096x4096xf32> // CHECK: affine.store %{{.*}}, [[BUFA]][-%[[I]] + %[[II]], -%[[K]] + %[[KK]]] : memref<128x128xf32> // CHECK: } // CHECK: } // RHS matrix copy-in. // CHECK: [[BUFB:%[0-9]+]] = alloc() : memref<128x128xf32> // CHECK: affine.for %[[KK:.*]] = #[[$MAP_IDENTITY]](%{{.*}}) to #[[$MAP_PLUS_128]](%{{.*}}) { // CHECK: affine.for %[[JJ:.*]] = #[[$MAP_IDENTITY]](%{{.*}}) to #[[$MAP_PLUS_128]](%{{.*}}) { // CHECK: affine.load %{{.*}}[%{{.*}}, %{{.*}}] : memref<4096x4096xf32> // CHECK: affine.store %{{.*}}, [[BUFB]][-%[[K]] + %[[KK]], -%[[J]] + %[[JJ]]] : memref<128x128xf32> // CHECK: } // CHECK: } // Computation on the fast buffers. // CHECK: affine.for %{{.*}} = #[[$MAP_IDENTITY]](%{{.*}}) to #[[$MAP_PLUS_128]](%{{.*}}) { // CHECK: affine.for %{{.*}} = #[[$MAP_IDENTITY]](%{{.*}}) to #[[$MAP_PLUS_128]](%{{.*}}) { // CHECK: affine.for %{{.*}} = #[[$MAP_IDENTITY]](%{{.*}}) to #[[$MAP_PLUS_128]](%{{.*}}) { // CHECK: affine.load [[BUFA]][-%{{.*}} + %{{.*}}, -%{{.*}} + %{{.*}}] : memref<128x128xf32> // CHECK: affine.load [[BUFB]][-%{{.*}} + %{{.*}}, -%{{.*}} + %{{.*}}] : memref<128x128xf32> // CHECK: affine.load [[BUFC]][-%{{.*}} + %{{.*}}, -%{{.*}} + %{{.*}}] : memref<128x128xf32> // CHECK: mulf %{{.*}}, %{{.*}} : f32 // CHECK: addf %{{.*}}, %{{.*}} : f32 // CHECK: affine.store %{{.*}}, [[BUFC]][-%{{.*}} + %{{.*}}, -%{{.*}} + %{{.*}}] : memref<128x128xf32> // CHECK: } // CHECK: } // CHECK: } // CHECK: dealloc [[BUFB]] : memref<128x128xf32> // CHECK: dealloc [[BUFA]] : memref<128x128xf32> // CHECK: } // Result matrix copy out. // CHECK: affine.for %{{.*}} = #[[$MAP_IDENTITY]](%{{.*}}) to #[[$MAP_PLUS_128]](%{{.*}}) { // CHECK: affine.for %{{.*}} = #[[$MAP_IDENTITY]](%{{.*}}) to #[[$MAP_PLUS_128]](%{{.*}}) { // CHECK: affine.load [[BUFC]][-%{{.*}} + %{{.*}}, -%{{.*}} + %{{.*}}] : memref<128x128xf32> // CHECK: store %{{.*}}, %{{.*}}[%{{.*}}, %{{.*}}] : memref<4096x4096xf32> // CHECK: } // CHECK: } // CHECK: dealloc [[BUFC]] : memref<128x128xf32> // CHECK: } // CHECK: } // Check that only one memref is copied when memref filter is used. // FILTER: affine.for %{{.*}} = 0 to 4096 step 128 { // FILTER: alloc() : memref<128x4096xf32> // FILTER-NOT: alloc() // FILTER: affine.for // FILTER: affine.for %{{.*}} = 0 to 4096 { // FILTER: affine.for %{{.*}} = 0 to 4096 step 128 { // FILTER-NEXT: affine.for %{{.*}} = 0 to 4096 step 128 { // FILTER-NEXT: affine.for %{{.*}} = #map{{.*}}(%{{.*}}) to #map{{.*}}(%{{.*}}) { // FILTER-NEXT: affine.for %{{.*}} = #map{{.*}}(%{{.*}}) to #map{{.*}}(%{{.*}}) { // FILTER-NEXT: affine.for %{{.*}} = #map{{.*}}(%{{.*}}) to #map{{.*}}(%{{.*}}) { // FILTER: dealloc %{{.*}} : memref<128x4096xf32> // FILTER-NOT: dealloc %{{.*}} : memref<128x4096xf32> // ----- // // This test case will lead to single element buffers. These are eventually // expected to be turned into registers via alloca and mem2reg. // // CHECK-SMALL-LABEL: func @single_elt_buffers // FILTER-LABEL: func @single_elt_buffers // MEMREF_REGION-LABEL: func @single_elt_buffers func @single_elt_buffers(%arg0: memref<1024x1024xf32>, %arg1: memref<1024x1024xf32>, %arg2: memref<1024x1024xf32>) -> memref<1024x1024xf32> { affine.for %i = 0 to 1024 { affine.for %j = 0 to 1024 { affine.for %k = 0 to 1024 { %6 = affine.load %arg1[%k, %j] : memref<1024x1024xf32> %7 = affine.load %arg2[%i, %j] : memref<1024x1024xf32> %9 = addf %6, %7 : f32 affine.store %9, %arg2[%i, %j] : memref<1024x1024xf32> } } } return %arg2 : memref<1024x1024xf32> } // CHECK-SMALL: affine.for %arg{{.*}} = 0 to 1024 { // CHECK-SMALL: affine.for %arg{{.*}} = 0 to 1024 { // CHECK-SMALL: alloc() : memref<1x1xf32> // CHECK-SMALL: affine.load %arg{{.*}}[%{{.*}}, %{{.*}}] : memref<1024x1024xf32> // CHECK-SMALL: affine.store %{{.*}}, %{{.*}}[0, 0] : memref<1x1xf32> // CHECK-SMALL: affine.for %arg{{.*}} = 0 to 1024 { // CHECK-SMALL: alloc() : memref<1x1xf32> // CHECK-SMALL: affine.load %arg{{.*}}[%{{.*}}, %{{.*}}] : memref<1024x1024xf32> // CHECK-SMALL: affine.store %{{.*}}, %{{.*}}[0, 0] : memref<1x1xf32> // CHECK-SMALL: affine.load %{{.*}}[0, 0] : memref<1x1xf32> // CHECK-SMALL: affine.load %{{.*}}[0, 0] : memref<1x1xf32> // CHECK-SMALL: addf %{{.*}}, %{{.*}} : f32 // CHECK-SMALL: affine.store %{{.*}}, %{{.*}}[0, 0] : memref<1x1xf32> // CHECK-SMALL: dealloc %{{.*}} : memref<1x1xf32> // CHECK-SMALL: } // CHECK-SMALL: affine.load %{{.*}}[0, 0] : memref<1x1xf32> // CHECK-SMALL: affine.store %{{.*}}, %arg{{.*}}[%{{.*}}, %{{.*}}] : memref<1024x1024xf32> // CHECK-SMALL: dealloc %{{.*}} : memref<1x1xf32> // CHECK-SMALL: } // CHECK-SMALL: } // CHECK-SMALL: return // Check that only one memref is copied when memref filter is used. // FILTER: alloc() : memref<1024x1024xf32> // FILTER-NOT: alloc() // FILTER: affine.for %{{.*}} = 0 to 1024 { // FILTER: affine.for %{{.*}} = 0 to 1024 { // FILTER: affine.for %{{.*}} = 0 to 1024 { // FILTER-NEXT: affine.for %{{.*}} = 0 to 1024 { // FILTER-NEXT: affine.for %{{.*}} = 0 to 1024 { // FILTER: dealloc %{{.*}} : memref<1024x1024xf32> // FILTER-NOT: dealloc // FILTER: return // CHeck that only one memref is copied, because for-memref-region is enabled // (and the first ever encountered load is analyzed). // MEMREF_REGION: alloc() : memref<1024x1024xf32> // MEMREF_REGION-NOT: alloc() // MEMREF_REGION: affine.for %{{.*}} = 0 to 1024 { // MEMREF_REGION: affine.for %{{.*}} = 0 to 1024 { // MEMREF_REGION: } // MEMREF_REGION: } // MEMREF_REGION-NEXT: affine.for %{{.*}} = 0 to 1024 { // MEMREF_REGION-NEXT: affine.for %{{.*}} = 0 to 1024 { // MEMREF_REGION-NEXT: affine.for %{{.*}} = 0 to 1024 { // MEMREF_REGION: dealloc %{{.*}} : memref<1024x1024xf32> // MEMREF_REGION-NOT: dealloc // MEMREF_REGION-NEXT: return // ----- // This pattern typically appears with tiling with tile sizes that don't divide // the loop trip counts. #map_ub = affine_map<(d0) -> (4096, d0 + 100)> // CHECK-DAG: [[$MAP_IDENTITY:map[0-9]+]] = affine_map<(d0) -> (d0)> // CHECK-DAG: [[$MAP_MIN_UB1:map[0-9]+]] = affine_map<(d0) -> (d0 + 100, 4096)> // CHECK-DAG: [[$MAP_MIN_UB2:map[0-9]+]] = affine_map<(d0) -> (4096, d0 + 100)> // CHECK-LABEL: func @min_upper_bound func @min_upper_bound(%A: memref<4096xf32>) -> memref<4096xf32> { affine.for %i = 0 to 4096 step 100 { affine.for %ii = affine_map<(d0) -> (d0)>(%i) to min #map_ub(%i) { %5 = affine.load %A[%ii] : memref<4096xf32> %6 = mulf %5, %5 : f32 affine.store %6, %A[%ii] : memref<4096xf32> } } return %A : memref<4096xf32> } // CHECK: affine.for %[[IV1:.*]] = 0 to 4096 step 100 // CHECK: %[[BUF:.*]] = alloc() : memref<100xf32> // CHECK-NEXT: affine.for %[[IV2:.*]] = #[[$MAP_IDENTITY]](%[[IV1]]) to min #[[$MAP_MIN_UB1]](%[[IV1]]) { // CHECK-NEXT: affine.load %{{.*}}[%[[IV2]]] : memref<4096xf32> // CHECK-NEXT: affine.store %{{.*}}, %[[BUF]][-%[[IV1]] + %[[IV2]]] : memref<100xf32> // CHECK-NEXT: } // CHECK-NEXT: affine.for %[[IV2:.*]] = #[[$MAP_IDENTITY]](%[[IV1]]) to min #[[$MAP_MIN_UB2]](%[[IV1]]) { // CHECK-NEXT: affine.load %[[BUF]][-%[[IV1]] + %[[IV2]]] : memref<100xf32> // CHECK-NEXT: mulf // CHECK-NEXT: affine.store %{{.*}}, %[[BUF]][-%[[IV1]] + %[[IV2]]] : memref<100xf32> // CHECK-NEXT: } // CHECK: affine.for %[[IV2:.*]] = #[[$MAP_IDENTITY]](%[[IV1]]) to min #[[$MAP_MIN_UB1]](%[[IV1]]) { // CHECK-NEXT: affine.load %[[BUF]][-%[[IV1]] + %[[IV2]]] : memref<100xf32> // CHECK-NEXT: affine.store %{{.*}}, %{{.*}}[%[[IV2]]] : memref<4096xf32> // CHECK-NEXT: } // CHECK-NEXT: dealloc %[[BUF]] : memref<100xf32> // CHECK-NEXT: } // ----- // Lower bound is a max; upper bound is a min. This pattern typically appears // with multi-level tiling when the tile sizes used don't divide loop trip // counts. #lb = affine_map<()[s0, s1] -> (s0 * 512, s1 * 6)> #ub = affine_map<()[s0, s1] -> (s0 * 512 + 512, s1 * 6 + 6)> // CHECK-DAG: #[[$LB:.*]] = affine_map<()[s0, s1] -> (s0 * 512, s1 * 6)> // CHECK-DAG: #[[$UB:.*]] = affine_map<()[s0, s1] -> (s0 * 512 + 512, s1 * 6 + 6)> // CHECK-LABEL: max_lower_bound(%{{.*}}: memref<2048x516xf64>, // CHECK-SAME: [[i:arg[0-9]+]] // CHECK-SAME: [[j:arg[0-9]+]] func @max_lower_bound(%M: memref<2048x516xf64>, %i : index, %j : index) { affine.for %ii = 0 to 2048 { affine.for %jj = max #lb()[%i, %j] to min #ub()[%i, %j] { affine.load %M[%ii, %jj] : memref<2048x516xf64> } } return } // CHECK: %[[BUF:.*]] = alloc() : memref<2048x6xf64> // CHECK-NEXT: affine.for %[[ii:.*]] = 0 to 2048 { // CHECK-NEXT: affine.for %[[jj:.*]] = max #[[$LB]]()[%[[i]], %[[j]]] to min #[[$UB]]()[%[[i]], %[[j]]] { // CHECK-NEXT: affine.load %{{.*}}[%[[ii]], %[[jj]]] : memref<2048x516xf64> // CHECK-NEXT: affine.store %{{.*}}, %[[BUF]][%[[ii]], %[[jj]] - symbol(%[[j]]) * 6] : memref<2048x6xf64> // CHECK-NEXT: } // CHECK-NEXT: } // CHECK-NEXT: affine.for %[[ii_:.*]] = 0 to 2048 { // CHECK-NEXT: affine.for %[[jj_:.*]] = max #[[$LB]]()[%{{.*}}, %{{.*}}] to min #[[$UB]]()[%{{.*}}, %{{.*}}] { // CHECK-NEXT: affine.load %[[BUF]][%[[ii_]], %[[jj_]] - symbol(%[[j]]) * 6] : memref<2048x6xf64> // CHECK-NEXT: } // CHECK-NEXT: } // CHECK-NEXT: dealloc %[[BUF]] : memref<2048x6xf64>