# RUN: %PYTHON %s | FileCheck %s from mlir.ir import * from mlir.dialects import arith from mlir.dialects import func from mlir.dialects import scf from mlir.dialects import builtin 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: TEST: testSimpleLoop @constructAndPrintInModule def testSimpleLoop(): index_type = IndexType.get() @builtin.FuncOp.from_py_func(index_type, index_type, index_type) def simple_loop(lb, ub, step): loop = scf.ForOp(lb, ub, step, [lb, lb]) with InsertionPoint(loop.body): scf.YieldOp(loop.inner_iter_args) return # CHECK: func @simple_loop(%[[ARG0:.*]]: index, %[[ARG1:.*]]: index, %[[ARG2:.*]]: index) # CHECK: scf.for %{{.*}} = %[[ARG0]] to %[[ARG1]] step %[[ARG2]] # CHECK: iter_args(%[[I1:.*]] = %[[ARG0]], %[[I2:.*]] = %[[ARG0]]) # CHECK: scf.yield %[[I1]], %[[I2]] # CHECK-LABEL: TEST: testInductionVar @constructAndPrintInModule def testInductionVar(): index_type = IndexType.get() @builtin.FuncOp.from_py_func(index_type, index_type, index_type) def induction_var(lb, ub, step): loop = scf.ForOp(lb, ub, step, [lb]) with InsertionPoint(loop.body): scf.YieldOp([loop.induction_variable]) return # CHECK: func @induction_var(%[[ARG0:.*]]: index, %[[ARG1:.*]]: index, %[[ARG2:.*]]: index) # CHECK: scf.for %[[IV:.*]] = %[[ARG0]] to %[[ARG1]] step %[[ARG2]] # CHECK: scf.yield %[[IV]] @constructAndPrintInModule def testOpsAsArguments(): index_type = IndexType.get() callee = builtin.FuncOp( "callee", ([], [index_type, index_type]), visibility="private") f = builtin.FuncOp("ops_as_arguments", ([], [])) with InsertionPoint(f.add_entry_block()): lb = arith.ConstantOp.create_index(0) ub = arith.ConstantOp.create_index(42) step = arith.ConstantOp.create_index(2) iter_args = func.CallOp(callee, []) loop = scf.ForOp(lb, ub, step, iter_args) with InsertionPoint(loop.body): scf.YieldOp(loop.inner_iter_args) func.ReturnOp([]) # CHECK-LABEL: TEST: testOpsAsArguments # CHECK: func private @callee() -> (index, index) # CHECK: func @ops_as_arguments() { # CHECK: %[[LB:.*]] = arith.constant 0 # CHECK: %[[UB:.*]] = arith.constant 42 # CHECK: %[[STEP:.*]] = arith.constant 2 # CHECK: %[[ARGS:.*]]:2 = call @callee() # CHECK: scf.for %arg0 = %c0 to %c42 step %c2 # CHECK: iter_args(%{{.*}} = %[[ARGS]]#0, %{{.*}} = %[[ARGS]]#1) # CHECK: scf.yield %{{.*}}, %{{.*}} # CHECK: return @constructAndPrintInModule def testIfWithoutElse(): bool = IntegerType.get_signless(1) i32 = IntegerType.get_signless(32) @builtin.FuncOp.from_py_func(bool) def simple_if(cond): if_op = scf.IfOp(cond) with InsertionPoint(if_op.then_block): one = arith.ConstantOp(i32, 1) add = arith.AddIOp(one, one) scf.YieldOp([]) return # CHECK: func @simple_if(%[[ARG0:.*]]: i1) # CHECK: scf.if %[[ARG0:.*]] # CHECK: %[[ONE:.*]] = arith.constant 1 # CHECK: %[[ADD:.*]] = arith.addi %[[ONE]], %[[ONE]] # CHECK: return @constructAndPrintInModule def testIfWithElse(): bool = IntegerType.get_signless(1) i32 = IntegerType.get_signless(32) @builtin.FuncOp.from_py_func(bool) def simple_if_else(cond): if_op = scf.IfOp(cond, [i32, i32], hasElse=True) with InsertionPoint(if_op.then_block): x_true = arith.ConstantOp(i32, 0) y_true = arith.ConstantOp(i32, 1) scf.YieldOp([x_true, y_true]) with InsertionPoint(if_op.else_block): x_false = arith.ConstantOp(i32, 2) y_false = arith.ConstantOp(i32, 3) scf.YieldOp([x_false, y_false]) add = arith.AddIOp(if_op.results[0], if_op.results[1]) return # CHECK: func @simple_if_else(%[[ARG0:.*]]: i1) # CHECK: %[[RET:.*]]:2 = scf.if %[[ARG0:.*]] # CHECK: %[[ZERO:.*]] = arith.constant 0 # CHECK: %[[ONE:.*]] = arith.constant 1 # CHECK: scf.yield %[[ZERO]], %[[ONE]] # CHECK: } else { # CHECK: %[[TWO:.*]] = arith.constant 2 # CHECK: %[[THREE:.*]] = arith.constant 3 # CHECK: scf.yield %[[TWO]], %[[THREE]] # CHECK: arith.addi %[[RET]]#0, %[[RET]]#1 # CHECK: return