# RUN: %PYTHON %s | FileCheck %s # This is just a smoke test that the dialect is functional. from mlir.ir import * from mlir.dialects import nvvm from mlir.dialects import llvm from mlir.dialects import func import mlir.extras.types as T from mlir.dialects import arith def constructAndPrintInModule(f): print("\nTEST:", f.__name__) with Context(), Location.unknown(): module = Module.create() with InsertionPoint(module.body): f() print(module) return f # CHECK-LABEL: testSmoke @constructAndPrintInModule def testSmoke(): i64 = IntegerType.get_signless(64) mat64f32_t = Type.parse( "!llvm.struct<(f32, f32, f32, f32, f32, f32, f32, f32, f32, f32, f32, f32, f32, f32, f32, f32)>" ) shape_attr = Attribute.parse("#nvvm.shape") # CHECK-LABEL: func @wgmma_f32_f16_f16(%arg0: i64, %arg1: i64) @func.FuncOp.from_py_func(i64, i64) def wgmma_f32_f16_f16(desc_a, desc_b): # CHECK: nvvm.cp.async.wait.group 5 nvvm.CpAsyncWaitGroupOp(5) # CHECK: %0 = llvm.mlir.undef : [[MAT_T:.*]] result = llvm.UndefOp(mat64f32_t) # CHECK: %1 = nvvm.wgmma.mma_async %arg0, %arg1, %0, , D[, ], A[, , ], B[, , ] : [[MAT_T]] -> [[MAT_T]] result1 = nvvm.WgmmaMmaAsyncOp( results_=mat64f32_t, inouts=result, descriptorA=desc_a, descriptorB=desc_b, shape=shape_attr, typeA=nvvm.WGMMATypes.f16, typeB=nvvm.WGMMATypes.f16, typeD=nvvm.WGMMATypes.f32, scaleD=nvvm.WGMMAScaleOut.zero, scaleA=nvvm.WGMMAScaleIn.neg, scaleB=nvvm.WGMMAScaleIn.neg, layoutA=nvvm.MMALayout.col, layoutB=nvvm.MMALayout.col, ) # CHECK-LABEL: TEST: test_inline_ptx # CHECK-LABEL: func.func @my_inline_ptx( # CHECK-SAME: %[[arg0:[a-zA-Z0-9_]+]]: f32, %[[arg1:[a-zA-Z0-9_]+]]: f32, %[[arg2:[a-zA-Z0-9_]+]]: i32, %[[arg3:[a-zA-Z0-9_]+]]: i32) # CHECK: %[[S0:.+]]:2 = nvvm.inline_ptx # CHECK-SAME: ro(%[[arg0]], %[[arg1]] : f32, f32) rw(%[[arg2]], %[[arg3]] : i32, i32) -> f32, f32 # CHECK: %[[S1:.+]] = arith.addf %[[arg0]], %[[arg1]] : f32 # CHECK: %[[S2:.+]] = arith.addi %[[arg2]], %[[arg3]] : i32 # CHECK: %[[S3:.+]] = arith.addf %[[S0]]#0, %[[S0]]#1 : f32 @constructAndPrintInModule def test_inline_ptx(): i32 = T.i32() f32 = T.f32() @func.FuncOp.from_py_func(f32, f32, i32, i32) def my_inline_ptx(a, b, c, d): ptx = r""" { .reg .pred p; setp.ge.s32 p, {$r0}, {$r1}; selp.s32 {$r0}, {$r0}, {$r1}, p; selp.s32 {$r1}, {$r0}, {$r1}, p; selp.s32 {$rw0}, {$r0}, {$r1}, p; selp.s32 {$rw1}, {$r0}, {$r1}, p; } """ wo0, wo1 = nvvm.inline_ptx( read_only_args=[a, b], read_write_args=[c, d], write_only_args=[f32, f32], ptx_code=ptx, ) arith.addf(a, b) arith.addi(c, d) arith.addf(wo0, wo1)