# Owner(s): ["module: functorch"] import contextlib import functools import unittest import torch import torch.utils._pytree as pytree from functorch.experimental import control_flow from functorch.experimental.control_flow import cond from torch._dynamo.testing import normalize_gm from torch._higher_order_ops.associative_scan import ( _fake_associative_scan, associative_scan, ) from torch._higher_order_ops.map import _fake_map from torch._higher_order_ops.scan import _fake_scan, scan from torch._higher_order_ops.schema import HopSchemaGenerator from torch._higher_order_ops.while_loop import while_loop from torch._subclasses.functional_tensor import ( CppFunctionalizeAPI, FunctionalTensor, FunctionalTensorMode, PythonFunctionalizeAPI, ) from torch.fx.experimental.proxy_tensor import make_fx from torch.testing._internal.common_cuda import SM70OrLater from torch.testing._internal.common_quantization import skipIfNoDynamoSupport from torch.testing._internal.common_utils import ( decorateIf, instantiate_parametrized_tests, IS_WINDOWS, parametrize, requires_cuda, run_tests, skipIfCrossRef, skipIfRocm, skipIfTorchDynamo, TEST_WITH_CROSSREF, TEST_WITH_TORCHDYNAMO, TestCase, ) # TODO: pull these helpers from AOTAutograd later def to_fun(t): if isinstance(t, torch.Tensor): return FunctionalTensor.to_functional(t) return t def from_fun(t): if not isinstance(t, FunctionalTensor): # quick sanity assert if isinstance(t, torch.Tensor): assert not torch._is_functional_tensor(t) return t torch._sync(t) return torch._from_functional_tensor(t.elem) def to_fun_old(t): if isinstance(t, torch.Tensor) and not torch._is_functional_tensor(t): out = torch._to_functional_tensor(t) torch._mirror_autograd_meta_to(t, out) return out return t def from_fun_old(t): # quick sanity assert if isinstance(t, torch.Tensor): assert torch._is_functional_tensor(t) torch._sync(t) return torch._from_functional_tensor(t) return t def _fake_while_loop(cond_fn, body_fn, operands): while cond_fn(*operands): operands = body_fn(*operands) return operands def compile_mode_helper(fct, compile_mode): if compile_mode == "compile": return torch.compile(fct, fullgraph=True, dynamic=False) elif compile_mode == "compile_dynamic_shape": return torch.compile(fct, fullgraph=True, dynamic=True) elif compile_mode == "eager": return torch.compile(fct, fullgraph=True, backend="eager") else: return fct ALIAS_FN = [ lambda x: x, lambda x: x.view(-1), lambda x: x.reshape(-1), lambda x: x.squeeze(0), lambda x: x.unsqueeze(0), lambda x: x.transpose(0, 1), lambda x: x.flatten(), lambda x: x.expand(1, *x.size()), ] def get_scan_combine_fn(name, associative=True, parameters=None): def add(x: torch.Tensor, y: torch.Tensor): return x + y def adds(x: torch.Tensor, y: torch.Tensor): return x + x, y + y def mul(x: torch.Tensor, y: torch.Tensor): return x * y def div(x: torch.Tensor, y: torch.Tensor): return x / y def s5_operator(x: torch.Tensor, y: torch.Tensor): A_i, Bu_i = x A_j, Bu_j = y return A_j * A_i, A_j * Bu_i + Bu_j def different_input_size_operator(x: torch.Tensor, y: torch.Tensor): x_o, dA_o, dB_o, C_o, y_o = x x_n, dA_n, dB_n, C_n, y_n = y x_new = x_n + x_o y_new = torch.einsum("bdn,bn->bd", x_new, C_n) return x_new, dA_n + 0.0, dB_n + 0.0, C_n + 0.0, y_new def tuple_fct(x, y): return (x[0] + y[0], x[1] * y[1]) def complex_pointwise(x, y): return { "i": x["i"] * y["i"], "j": ( [x["j"][0][0] * y["j"][0][0]], [{"o": x["j"][1][0]["o"] + y["j"][1][0]["o"]}], ), } def non_pointwise(x: torch.Tensor, y: torch.Tensor): W = torch.diag(torch.ones(2, device=x.device)) return x @ W + y @ W def RNN(x: torch.Tensor, y: torch.Tensor): c_new = y @ parameters[0] + parameters[1] h_new = torch.tanh(c_new + x @ parameters[2] + parameters[3]) return h_new, h_new.clone() def fct_c1_no_grad(x: torch.Tensor, y: torch.Tensor): h_new = torch.tanh(x[0] + x[1] + y) c2 = x[1] + y with torch.no_grad(): c1 = x[0] + y return (c1, c2), h_new if name == "add": fct = add elif name == "adds": fct = adds elif name == "mul": fct = mul elif name == "div": fct = div elif name == "s5_operator": fct = s5_operator elif name == "different_input_size_operator": fct = different_input_size_operator elif name == "tuple_fct": fct = tuple_fct elif name == "complex_pointwise": fct = complex_pointwise elif name == "non_pointwise": fct = non_pointwise elif name == "RNN": fct = RNN elif name == "fct_c1_no_grad": fct = fct_c1_no_grad else: raise ValueError("Combine_fn name unknown!") if not associative: return lambda x, y: (fct(x, y), fct(x, y)) else: return fct def _while_loop_tests(): def simple(x): def cond_fn(x): return x.sum() < 10 def body_fn(x): return (x + 1,) return while_loop(cond_fn, body_fn, (x,)) def simple_with_mutation(x): def cond_fn(x): y = x.clone().add_(1).add_(-1) return y.sum() < 10 def body_fn(x): y = x.clone().add_(1).add_(-1) return (y + 1,) return while_loop(cond_fn, body_fn, (x,)) def nested(out_iter, it, y): def cond_fn(out_iter, it, y): return it.sum() < 10 def body_fn(out_iter, it, y): return (out_iter.clone(), it + y, y + 1) def outer_cond_fn(out_iter, it, y): return out_iter.sum() < 2 def outer_body_fn(out_iter, it, y): out_iter, it, y = while_loop(cond_fn, body_fn, (out_iter, it, y)) return (out_iter + 1, it, y) return while_loop(outer_cond_fn, outer_body_fn, (out_iter, it, y)) class Nested(torch.nn.Module): def forward(self, ci, cj, a, b): def cond_fn(i1, j1, x1, y1): return i1 > 0 def body_fn(i1, j1, x1, y1): def cond_fn_nested(i2, j2, x2, y2): return j2 > 0 def body_fn_nested(i2, j2, x2, y2): return i2.clone(), j2 - 1, x2 + 3.14, y2 - 2.71 i1, j1, x1, y1 = while_loop( cond_fn_nested, body_fn_nested, [i1, j1, x1, y1] ) return i1 - 1, j1.clone(), x1 * 2, y1 / 2 return while_loop(cond_fn, body_fn, (ci, cj, a, b)) class SimpleWithLinear(torch.nn.Module): def __init__(self) -> None: super().__init__() self.linear = torch.nn.Linear(2, 2) self.dec = torch.nn.Buffer(torch.tensor(1)) def forward(self, iter, x): def cond_fn(it, x): return it - self.dec > 0 def body_fn(it, x): return it - 1, self.linear(x) return while_loop(cond_fn, body_fn, (iter, x)) class SimpleWithPytreeCarry(torch.nn.Module): def forward(self, it, pytree_input): def cond_fn(it, pytree_input): return it > 0 def body_fn(it, pytree_input): x = pytree_input[0][0] y = pytree_input[1]["x"] z = pytree_input[1]["y"] new_x = y.sin() new_y = z.cos() new_z = x + 1 return it - 1, ([new_x], {"x": new_y, "y": new_z}) return while_loop(cond_fn, body_fn, (it, pytree_input)) class NestedWithLinear(torch.nn.Module): def __init__(self) -> None: super().__init__() self.mod = SimpleWithLinear() self.outer_linear = torch.nn.Linear(2, 2) self.dec = torch.nn.Buffer(torch.tensor(1)) def forward(self, iter, x): def cond_fn(it, x): return it - self.dec > 0 def body_fn(it, x): return it - 1, self.outer_linear(self.mod(it, x)[1]) return while_loop(cond_fn, body_fn, (iter, x)) class PytreeIntCarry(torch.nn.Module): def forward(self, x): a = x.shape[0] b = x.shape[1] def cond_fn(shapes, const_int_dict, x): a, b = shapes c1, c2, c3 = const_int_dict["int_carry"] return c1 * c2 * c3 < a * b def body_fn(shapes, const_int_dict, x): a, b = shapes c1, c2, c3 = const_int_dict["int_carry"] return ( [a + 1, b + 1], {"int_carry": (c1 + 1, c2 + 1, c3 + 1)}, x + 1, ) carry = ([a, b], {"int_carry": (2, 2, 3)}, x.sin()) out_shapes, out_it, out_x = while_loop(cond_fn, body_fn, carry) out_inc = pytree.tree_map(lambda x: x + 1, out_it) out_add = pytree.tree_map(lambda x: x + out_x, out_it) return (out_shapes, out_inc, out_add, out_x) class IntCarry(torch.nn.Module): def forward(self, x): def cond_fn(it, x): return it < x.shape[0] def body_fn(it, x): x_clone = x.clone() # Need these checks to select from x torch._check(it >= 0) torch._check(it < x.shape[0]) x_clone.select(0, it).copy_(x_clone.select(0, it) + it) return it + 1, x_clone # We invoke the hop directly to avoid triggering dyanmo tracing out_it, out_x = torch.ops.higher_order.while_loop( cond_fn, body_fn, (0, x), tuple() ) # We need torch._check to use it in torch.ones call torch._check(out_it > 0) return ( out_it + 1, out_it + out_x, out_it < x.shape[0], torch.ones(out_it * 2), ) class ConstAndSymIntOutput(torch.nn.Module): def forward(self, t): a = t.shape[0] b = t.shape[1] def cond_fn(a, b, c1, c2, c3, c0, u0, x): return c1 * c2 * c3 < a * b def body_fn(a, b, c1, c2, c3, c0, u0, x): return b, c1, c2, c3, a, 0, u0 + 1, x + 1 carry = (a, b, 1, 1, 1, a + 1, t.sum().to(torch.int64).item(), t.sin()) out_it = torch.ops.higher_order.while_loop(cond_fn, body_fn, carry, tuple()) out_inc = pytree.tree_map(lambda x: x + 1, out_it) out_add = pytree.tree_map(lambda x: x + t, out_it) return out_inc, out_add nested2 = Nested() simple_with_linear = SimpleWithLinear() simple_with_pytree_carry = SimpleWithPytreeCarry() nested_with_linear = NestedWithLinear() int_carry = IntCarry() pytree_int_carry = PytreeIntCarry() const_and_symint_output = ConstAndSymIntOutput() x = torch.zeros(1) y = torch.zeros(1) z = torch.zeros(1) return { "simple": (simple, (x,)), "nested": (nested, (x, y, z)), "nested2": ( nested2, (torch.tensor(2), torch.tensor(2), torch.ones(2, 2), torch.ones(2, 2)), ), "simple_with_mutation": (simple_with_mutation, (x,)), "simple_with_linear": ( simple_with_linear, (torch.tensor(3), torch.randn(2, 2)), ), "nested_with_linear": ( nested_with_linear, (torch.tensor(3), torch.randn(2, 2)), ), "simple_with_pytree_carry": ( simple_with_pytree_carry, ( torch.tensor(3), ([torch.randn(3, 3)], {"x": torch.randn(3, 3), "y": torch.randn(3, 3)}), ), ), "int_carry": (int_carry, (torch.randn(2, 3, requires_grad=True),)), "pytree_int_carry": ( pytree_int_carry, (torch.randn(2, 3, requires_grad=True),), ), "const_and_symint_output": ( const_and_symint_output, (torch.randn(2, 3, requires_grad=True),), ), } WHILE_LOOP_TESTS = _while_loop_tests() def collect_meta_for_filtered_nodes( gm: torch.fx.GraphModule, node_names, meta_field_name ): ret = [] for mod in gm.modules(): for node in mod.graph.nodes: if node.name in node_names: for field_name in meta_field_name: ret.append(node.meta.get(field_name)) return ret def reduce_func(*operands): acc = 0 for operand in operands: acc += operand return acc class ReduceObj: def __call__(self, *operands): return reduce_func(*operands) class ReduceMod(torch.nn.Module): def _reduce(self, *operands): return reduce_func(*operands) def forward(self, *operands): return self._reduce(*operands) @unittest.skipIf(IS_WINDOWS, "Windows not supported for this test") @skipIfNoDynamoSupport class TestControlFlow(TestCase): def setUp(self): torch._dynamo.reset() super().setUp() def check_autograd(self, result, result_exp, params): params_flatten = pytree.tree_leaves(params) result_flatten = pytree.tree_leaves(result) result_exp_flatten = pytree.tree_leaves(result_exp) grad_exp_init = [torch.ones_like(el) for el in result_exp_flatten] expected_grads = torch.autograd.grad( result_exp_flatten, params_flatten, grad_exp_init ) grad_init = [torch.ones_like(el) for el in result_flatten] grads = torch.autograd.grad(result_flatten, params_flatten, grad_init) self.assertEqual(grads, expected_grads, atol=6e-05, rtol=6e-06) def test_cond_no_trace(self): def true_fn(x): return x.sin() def false_fn(x): return x.cos() x = torch.randn(4) result = cond(False, true_fn, false_fn, [x]) self.assertEqual(result, torch.cos(x)) @unittest.skipIf(not torch.cuda.is_available(), "Test requires CUDA.") def test_cond_gpu(self): def true_fn(x): return x.sin() def false_fn(x): return x.cos() x = torch.randn(4, device="cuda") pred = torch.tensor(False, device="cuda") result = cond(pred, true_fn, false_fn, [x]) self.assertEqual(result, torch.cos(x)) def test_cond_autograd_simple(self): def true_fn(x): return x.sin() def false_fn(x): return x.cos() for pred, fn in zip( [torch.tensor(False), torch.tensor(True)], [false_fn, true_fn] ): x = torch.randn(4, requires_grad=True) result = cond(pred, true_fn, false_fn, (x,)) self.assertEqual(result, fn(x)) grad_out = torch.ones_like(result) grads = torch.autograd.grad(result, (x,), grad_out) expected_grads = torch.autograd.grad(fn(x), (x,), grad_out) self.assertEqual(expected_grads, grads) def f(pred, x): result = cond(pred, true_fn, false_fn, (x,)) grad_out = torch.ones_like(result) return torch.autograd.grad(result, (x,), grad_out) gm = make_fx(f)(pred, x) self.assertExpectedInline( gm.code.strip(), """\ def forward(self, pred_1, x_1): true_graph_0 = self.true_graph_0 false_graph_0 = self.false_graph_0 cond = torch.ops.higher_order.cond(pred_1, true_graph_0, false_graph_0, (x_1,)); true_graph_0 = false_graph_0 = None getitem = cond[0]; cond = None ones_like = torch.ops.aten.ones_like.default(getitem, pin_memory = False); getitem = None true_graph_1 = self.true_graph_1 false_graph_1 = self.false_graph_1 cond_1 = torch.ops.higher_order.cond(pred_1, true_graph_1, false_graph_1, (x_1, ones_like)); pred_1 = true_graph_1 = false_graph_1 = x_1 = ones_like = None getitem_1 = cond_1[0]; cond_1 = None return (getitem_1,)""", # noqa: B950 ) def test_cond_autograd_complex(self): def true_fn(x): return torch.abs((x**2).sin()) def false_fn(x): return (x + 42).cos() for pred, fn in zip( [torch.tensor(False), torch.tensor(True)], [false_fn, true_fn] ): x = torch.randn(4, requires_grad=True) result = cond(pred, true_fn, false_fn, (x,)) self.assertEqual(result, fn(x)) grad_out = torch.ones_like(result) grads = torch.autograd.grad(result, (x,), grad_out) expected_grads = torch.autograd.grad(fn(x), (x,), grad_out) self.assertEqual(expected_grads, grads) def f(pred, x): result = cond(pred, true_fn, false_fn, (x,)) grad_out = torch.ones_like(result) return torch.autograd.grad(result, (x,), grad_out) gm = make_fx(f)(pred, x) self.assertExpectedInline( gm.code.strip(), """\ def forward(self, pred_1, x_1): true_graph_0 = self.true_graph_0 false_graph_0 = self.false_graph_0 cond = torch.ops.higher_order.cond(pred_1, true_graph_0, false_graph_0, (x_1,)); true_graph_0 = false_graph_0 = None getitem = cond[0]; cond = None ones_like = torch.ops.aten.ones_like.default(getitem, pin_memory = False); getitem = None true_graph_1 = self.true_graph_1 false_graph_1 = self.false_graph_1 cond_1 = torch.ops.higher_order.cond(pred_1, true_graph_1, false_graph_1, (x_1, ones_like)); pred_1 = true_graph_1 = false_graph_1 = x_1 = ones_like = None getitem_1 = cond_1[0]; cond_1 = None return (getitem_1,)""", # noqa: B950 ) @skipIfTorchDynamo("Skip due to graph break when run with dynamo") def test_cond_autograd_nested(self): class Nested(torch.nn.Module): def forward(self, p0, p1, p2, a, b, c): def true_fn(x0, y0, z0): def true_true_fn(x1, y1, z1): return (x1 - y1 * z1) * 3.14 def true_false_fn(x1, y1, z1): def true_false_true_fn(x2, y2, z2): return (x2 * y2 * z2) / 2.71 def true_false_false_fn(x2, y2, z2): return (x2 + y2 + z2) * 1.23 return torch.cond( p2, true_false_true_fn, true_false_false_fn, [x1, y1, z1] ) return torch.cond(p1, true_true_fn, true_false_fn, [x0, y0, z0]) def false_fn(x0, y0, z0): def false_true_fn(x1, y1, z1): def false_true_true_fn(x2, y2, z2): return (x2 - y2 - z2) + 1.23 def false_true_false_fn(x2, y2, z2): return (x2 / y2 / z2) - 3.14 return torch.cond( p2, false_true_true_fn, false_true_false_fn, [x1, y1, z1] ) def false_false_fn(x1, y1, z1): return (x1 - y1 * z1) / 2.71 return torch.cond(p1, false_true_fn, false_false_fn, [x0, y0, z0]) return torch.cond(p0, true_fn, false_fn, [a, b, c]) nn_module = Nested() def true_fn(x): return nn_module( torch.tensor(False), torch.tensor(True), torch.tensor(False), x, x, x ) def false_fn(x): return nn_module( torch.tensor(True), torch.tensor(False), torch.tensor(True), x, x, x ) x = torch.randn(4, requires_grad=True) for pred, fn in zip( [torch.tensor(False), torch.tensor(True)], [false_fn, true_fn] ): result = cond(pred, true_fn, false_fn, (x,)) self.assertEqual(result, fn(x)) grad_out = torch.ones_like(result) grads = torch.autograd.grad(result, (x,), grad_out) expected_grads = torch.autograd.grad(fn(x), (x,), grad_out) self.assertEqual(expected_grads, grads) @skipIfTorchDynamo("Skip due to graph break when run with dynamo") def test_cond_autograd_mixed_require_grad(self): def true_fn(x, y, z): return x * y * z def false_fn(x, y, z): return x + y + z x = torch.randn(4, requires_grad=True) y = torch.randn(4, requires_grad=False) for pred, fn in zip( [torch.tensor(False), torch.tensor(True)], [false_fn, true_fn] ): result = cond(pred, true_fn, false_fn, (x, y, x)) self.assertEqual(result, fn(x, y, x)) grad_out = torch.ones_like(result) grads = torch.autograd.grad(result, (x,), grad_out) expected_grads = torch.autograd.grad(fn(x, y, x), (x,), grad_out) self.assertEqual(expected_grads, grads) def f(pred, x, y, z): result = cond(pred, true_fn, false_fn, (x, y, z)) grad_out = torch.ones_like(result) return torch.autograd.grad(result, (x,), grad_out) gm = make_fx(f)(pred, x, y, x) self.assertExpectedInline( gm.code.strip(), """\ def forward(self, pred_1, x_1, y_1, z_1): true_graph_0 = self.true_graph_0 false_graph_0 = self.false_graph_0 cond = torch.ops.higher_order.cond(pred_1, true_graph_0, false_graph_0, (z_1, y_1)); true_graph_0 = false_graph_0 = None getitem = cond[0]; cond = None ones_like = torch.ops.aten.ones_like.default(getitem, pin_memory = False); getitem = None true_graph_1 = self.true_graph_1 false_graph_1 = self.false_graph_1 cond_1 = torch.ops.higher_order.cond(pred_1, true_graph_1, false_graph_1, (z_1, y_1, ones_like)); pred_1 = true_graph_1 = false_graph_1 = z_1 = y_1 = ones_like = None getitem_1 = cond_1[0] getitem_2 = cond_1[1]; cond_1 = getitem_2 = None return (getitem_1,)""", # noqa: B950 ) @skipIfTorchDynamo("Skip due to graph break when run with dynamo") def test_cond_autograd_grad_through_cond(self): nn_module = torch.nn.Linear(4, 4) def true_fn(x): return nn_module(x) def false_fn(X): return x * nn_module(x) x = torch.randn(4, requires_grad=True) for pred, fn in zip( [torch.tensor(False), torch.tensor(True)], [false_fn, true_fn] ): result = cond(pred, true_fn, false_fn, (x,)) self.assertEqual(result, fn(x)) grad_out = torch.ones_like(result) grads = torch.autograd.grad(result, (nn_module.weight,), grad_out) expected_grads = torch.autograd.grad( fn( x, ), (nn_module.weight,), grad_out, ) self.assertEqual(expected_grads, grads) def f(pred, x): result = cond(pred, true_fn, false_fn, (x,)) grad_out = torch.ones_like(result) return torch.autograd.grad(result, (nn_module.weight,), grad_out) # need to set _allow_non_fake_inputs = True because model parameters don't # get fakified. gm = make_fx(f, tracing_mode="symbolic", _allow_non_fake_inputs=True)(pred, x) self.assertExpectedInline( gm.code.strip(), """\ def forward(self, pred_1, x_1): sym_size_int = torch.ops.aten.sym_size.int(x_1, 0) true_graph_0 = self.true_graph_0 false_graph_0 = self.false_graph_0 _param_constant0 = self._param_constant0 _param_constant1 = self._param_constant1 _tensor_constant0 = self._tensor_constant0 cond = torch.ops.higher_order.cond(pred_1, true_graph_0, false_graph_0, (_param_constant0, _param_constant1, x_1, sym_size_int, _tensor_constant0)); true_graph_0 = false_graph_0 = _param_constant0 = _param_constant1 = _tensor_constant0 = None getitem = cond[0]; cond = None ones_like = torch.ops.aten.ones_like.default(getitem, pin_memory = False); getitem = None true_graph_1 = self.true_graph_1 false_graph_1 = self.false_graph_1 _param_constant0_1 = self._param_constant0 _param_constant1_1 = self._param_constant1 _tensor_constant0_1 = self._tensor_constant0 cond_1 = torch.ops.higher_order.cond(pred_1, true_graph_1, false_graph_1, (_param_constant0_1, _param_constant1_1, x_1, sym_size_int, _tensor_constant0_1, ones_like)); pred_1 = true_graph_1 = false_graph_1 = _param_constant0_1 = _param_constant1_1 = x_1 = sym_size_int = _tensor_constant0_1 = ones_like = None getitem_1 = cond_1[0]; getitem_1 = None getitem_2 = cond_1[1] getitem_3 = cond_1[2]; getitem_3 = None getitem_4 = cond_1[3]; getitem_4 = None getitem_5 = cond_1[4]; cond_1 = getitem_5 = None return (getitem_2,)""", # noqa: B950 ) def test_cond_in_forloop(self): def for_loop_fake(x): for i in range(3): x = x * x + 1 return x def for_loop_test(x): for i in range(3): pred = i < 3 def true_fn(x): return x * x + 1 def false_fn(x): return x x = cond(pred, true_fn, false_fn, (x,)) return x x = torch.ones(4, requires_grad=True) x_new = for_loop_test(x) x_exp = for_loop_fake(x) self.assertEqual(x_new, x_exp) grad_out = torch.ones_like(x_new) grads = torch.autograd.grad(x_new, (x,), grad_out) expected_grads = torch.autograd.grad(x_exp, (x,), grad_out) self.assertEqual(expected_grads, grads) def f(x): x_new = for_loop_test(x) grad_out = torch.ones_like(x_new) return torch.autograd.grad(x_new, (x,), grad_out) gm = make_fx(f, tracing_mode="symbolic")(x) self.assertExpectedInline( gm.code.strip(), """\ def forward(self, x_1): mul = torch.ops.aten.mul.Tensor(x_1, x_1) add = torch.ops.aten.add.Tensor(mul, 1); mul = None mul_1 = torch.ops.aten.mul.Tensor(add, add) add_1 = torch.ops.aten.add.Tensor(mul_1, 1); mul_1 = None mul_2 = torch.ops.aten.mul.Tensor(add_1, add_1) add_2 = torch.ops.aten.add.Tensor(mul_2, 1); mul_2 = None ones_like = torch.ops.aten.ones_like.default(add_2, pin_memory = False); add_2 = None mul_3 = torch.ops.aten.mul.Tensor(ones_like, add_1) mul_4 = torch.ops.aten.mul.Tensor(ones_like, add_1); ones_like = add_1 = None add_3 = torch.ops.aten.add.Tensor(mul_4, mul_3); mul_4 = mul_3 = None mul_5 = torch.ops.aten.mul.Tensor(add_3, add) mul_6 = torch.ops.aten.mul.Tensor(add_3, add); add_3 = add = None add_4 = torch.ops.aten.add.Tensor(mul_6, mul_5); mul_6 = mul_5 = None mul_7 = torch.ops.aten.mul.Tensor(add_4, x_1) mul_8 = torch.ops.aten.mul.Tensor(add_4, x_1); add_4 = x_1 = None add_5 = torch.ops.aten.add.Tensor(mul_8, mul_7); mul_8 = mul_7 = None return (add_5,)""", # noqa: B950 ) @skipIfTorchDynamo("Skip due to graph break when run with dynamo") def test_cond_autograd_pytree_not_all_inputs_used(self): def true_fn(x): return x["t"][0] + x["t"][1]["b"] def false_fn(x): return x["t"][0] * (x["t"][2][0] / x["t"][1]["b"]) a = torch.randn(4, requires_grad=True) b = torch.randn(4, requires_grad=True) c = torch.randn(4, requires_grad=True) for pred, fn in zip( [torch.tensor(False), torch.tensor(True)], [false_fn, true_fn] ): result = cond(pred, true_fn, false_fn, ({"t": [a, {"b": b}, (c,)]},)) self.assertEqual(result, fn({"t": [a, {"b": b}, (c,)]})) grad_out = torch.ones_like(result) if pred: with self.assertRaisesRegex(Exception, r"."): grads = torch.autograd.grad(result, (a, b, c), grad_out) expected_grads = torch.autograd.grad( fn({"t": [a, {"b": b}, (c,)]}), (a, b, c), grad_out ) self.assertEqual(expected_grads, grads) def f(pred, a, b, c): result = cond(pred, true_fn, false_fn, ({"t": [a, {"b": b}, (c,)]},)) grad_out = torch.ones_like(result) return torch.autograd.grad(result, (a, b), grad_out) gm = make_fx(f, tracing_mode="symbolic", _allow_non_fake_inputs=True)( pred, a, b, c ) self.assertExpectedInline( gm.code.strip(), """\ def forward(self, pred_1, a_1, b_1, c_1): sym_size_int = torch.ops.aten.sym_size.int(a_1, 0) sym_size_int_1 = torch.ops.aten.sym_size.int(b_1, 0) sym_size_int_2 = torch.ops.aten.sym_size.int(c_1, 0) true_graph_0 = self.true_graph_0 false_graph_0 = self.false_graph_0 cond = torch.ops.higher_order.cond(pred_1, true_graph_0, false_graph_0, (a_1, b_1, sym_size_int, sym_size_int_1, c_1, sym_size_int_2)); true_graph_0 = false_graph_0 = None getitem = cond[0]; cond = None ones_like = torch.ops.aten.ones_like.default(getitem, pin_memory = False); getitem = None true_graph_1 = self.true_graph_1 false_graph_1 = self.false_graph_1 cond_1 = torch.ops.higher_order.cond(pred_1, true_graph_1, false_graph_1, (a_1, b_1, sym_size_int, sym_size_int_1, c_1, sym_size_int_2, ones_like)); pred_1 = true_graph_1 = false_graph_1 = a_1 = b_1 = sym_size_int = sym_size_int_1 = c_1 = sym_size_int_2 = ones_like = None getitem_1 = cond_1[0] getitem_2 = cond_1[1] getitem_3 = cond_1[2]; getitem_3 = None getitem_4 = cond_1[3]; getitem_4 = None getitem_5 = cond_1[4]; getitem_5 = None getitem_6 = cond_1[5]; cond_1 = getitem_6 = None return (getitem_1, getitem_2)""", # noqa: B950 ) # Forward self.assertExpectedInline( gm.true_graph_0.code.strip(), """\ def forward(self, arg0_1, arg1_1, arg2_1, arg3_1, arg4_1, arg5_1): add = torch.ops.aten.add.Tensor(arg0_1, arg1_1); arg0_1 = arg1_1 = None return (add,)""", ) # Backward self.assertExpectedInline( gm.true_graph_1.code.strip(), """\ def forward(self, arg0_1, arg1_1, arg2_1, arg3_1, arg4_1, arg5_1, arg6_1): add = torch.ops.aten.add.Tensor(arg0_1, arg1_1); arg0_1 = arg1_1 = add = None clone = torch.ops.aten.clone.default(arg6_1) clone_1 = torch.ops.aten.clone.default(arg6_1); arg6_1 = None zeros_like = torch.ops.aten.zeros_like.default(arg4_1, pin_memory = False); arg4_1 = None return [clone, clone_1, None, None, zeros_like, None]""", ) def test_cond_autograd_pytree_input(self): def true_fn(x): return x["t"][0] + x["t"][1]["b"] * x["t"][2][0] def false_fn(x): return x["t"][0] * (x["t"][2][0] / x["t"][1]["b"]) a = torch.randn(4, requires_grad=True) b = torch.randn(4, requires_grad=True) c = torch.randn(4, requires_grad=True) for pred, fn in zip( [torch.tensor(False), torch.tensor(True)], [false_fn, true_fn] ): result = cond(pred, true_fn, false_fn, ({"t": [a, {"b": b}, (c,)]},)) self.assertEqual(result, fn({"t": [a, {"b": b}, (c,)]})) grad_out = torch.ones_like(result) grads = torch.autograd.grad(result, (a, b), grad_out) expected_grads = torch.autograd.grad( fn({"t": [a, {"b": b}, (c,)]}), (a, b), grad_out ) self.assertEqual(expected_grads, grads) def f(pred): result = cond(pred, true_fn, false_fn, ({"t": [a, {"b": b}, (c,)]},)) grad_out = torch.ones_like(result) return torch.autograd.grad(result, (a, b), grad_out) # need to set _allow_non_fake_inputs = True because model parameters don't # get fakified. gm = make_fx(f, tracing_mode="symbolic", _allow_non_fake_inputs=True)(pred) self.assertExpectedInline( gm.code.strip(), """\ def forward(self, pred_1): true_graph_0 = self.true_graph_0 false_graph_0 = self.false_graph_0 _tensor_constant0 = self._tensor_constant0 _tensor_constant1 = self._tensor_constant1 _tensor_constant2 = self._tensor_constant2 cond = torch.ops.higher_order.cond(pred_1, true_graph_0, false_graph_0, (_tensor_constant0, _tensor_constant1, _tensor_constant2)); true_graph_0 = false_graph_0 = _tensor_constant0 = _tensor_constant1 = _tensor_constant2 = None getitem = cond[0]; cond = None ones_like = torch.ops.aten.ones_like.default(getitem, pin_memory = False); getitem = None true_graph_1 = self.true_graph_1 false_graph_1 = self.false_graph_1 _tensor_constant0_1 = self._tensor_constant0 _tensor_constant1_1 = self._tensor_constant1 _tensor_constant2_1 = self._tensor_constant2 cond_1 = torch.ops.higher_order.cond(pred_1, true_graph_1, false_graph_1, (_tensor_constant0_1, _tensor_constant1_1, _tensor_constant2_1, ones_like)); pred_1 = true_graph_1 = false_graph_1 = _tensor_constant0_1 = _tensor_constant1_1 = _tensor_constant2_1 = ones_like = None getitem_1 = cond_1[0] getitem_2 = cond_1[1] getitem_3 = cond_1[2]; cond_1 = getitem_3 = None return (getitem_1, getitem_2)""", # noqa: B950 ) def test_cond_autograd_different_pytree_output(self): def true_fn(x): return x["t"][0], {"r": x["t"][2][0] / x["t"][1]["b"]}, [x["t"][2][0]] def false_fn(x): return {"res": [x["t"][0] * x["t"][1]["b"], x["t"][2][0]]} a = torch.randn(4, requires_grad=True) b = torch.randn(4, requires_grad=True) c = torch.randn(4, requires_grad=True) for pred, fn in zip( [torch.tensor(False), torch.tensor(True)], [false_fn, true_fn] ): with self.assertRaisesRegex( torch._dynamo.exc.UncapturedHigherOrderOpError, "Cond doesn't work unless it is captured completely with torch.compile", ): cond(pred, true_fn, false_fn, ({"t": [a, {"b": b}, (c,)]},)) @skipIfTorchDynamo("Skip due to graph break when run with dynamo") def test_cond_autograd_same_pytree_output(self): def true_fn(x): return {"res": [x["t"][0].clone(), (x["t"][2][0].clone(),)]} def false_fn(x): return {"res": [x["t"][1]["b"].clone(), (x["t"][2][0].clone(),)]} a = torch.randn(4, requires_grad=True) b = torch.randn(4, requires_grad=True) c = torch.randn(4, requires_grad=True) for pred, fn in zip( [torch.tensor(False), torch.tensor(True)], [false_fn, true_fn] ): result = cond(pred, true_fn, false_fn, ({"t": [a, {"b": b}, (c,)]},)) result_exp = fn({"t": [a, {"b": b}, (c,)]}) self.assertEqual(result, result_exp) result_flat, _ = pytree.tree_flatten(result) result_exp_flat, _ = pytree.tree_flatten(result_exp) grad_out = [torch.ones_like(g) for g in result_flat] expected_grads = torch.autograd.grad(result_exp_flat, (c,), grad_out) grads = torch.autograd.grad(result_flat, (c,), grad_out) self.assertEqual(expected_grads, grads) def f(pred): result = cond(pred, true_fn, false_fn, ({"t": [a, {"b": b}, (c,)]},)) return result gm = make_fx(f, tracing_mode="real", _allow_non_fake_inputs=True)(pred) self.assertExpectedInline( gm.code.strip(), """\ def forward(self, pred_1): true_graph_0 = self.true_graph_0 false_graph_0 = self.false_graph_0 _tensor_constant0 = self._tensor_constant0 _tensor_constant1 = self._tensor_constant1 _tensor_constant2 = self._tensor_constant2 cond = torch.ops.higher_order.cond(pred_1, true_graph_0, false_graph_0, (_tensor_constant0, _tensor_constant1, _tensor_constant2)); pred_1 = true_graph_0 = false_graph_0 = _tensor_constant0 = _tensor_constant1 = _tensor_constant2 = None getitem = cond[0] getitem_1 = cond[1]; cond = None return {'res': [getitem, (getitem_1,)]}""", # noqa: B950 ) @skipIfTorchDynamo("Skip due to graph break when run with dynamo") def test_cond_autograd_torch_nn_module(self): nn_module_true = torch.nn.Linear(4, 4) def true_fn(x): return nn_module_true(torch.abs((x**2).sin())) nn_module_false = torch.nn.GRUCell(4, 4) def false_fn(x): return nn_module_false((x + 42).cos()) for pred, fn in zip( [torch.tensor(False), torch.tensor(True)], [false_fn, true_fn] ): x = torch.randn(4, requires_grad=True) result = cond(pred, true_fn, false_fn, (x,)) self.assertEqual(result, fn(x)) grad_out = torch.ones_like(result) grads = torch.autograd.grad(result, (x,), grad_out) expected_grads = torch.autograd.grad(fn(x), (x,), grad_out) self.assertEqual(expected_grads, grads) def f(pred, x): result = cond(pred, true_fn, false_fn, (x,)) grad_out = torch.ones_like(result) return torch.autograd.grad(result, (x,), grad_out) gm = make_fx(f)(pred, x) self.assertExpectedInline( gm.code.strip(), """\ def forward(self, pred_1, x_1): true_graph_0 = self.true_graph_0 false_graph_0 = self.false_graph_0 _param_constant0 = self._param_constant0 _param_constant1 = self._param_constant1 _param_constant2 = self._param_constant2 _param_constant3 = self._param_constant3 _param_constant4 = self._param_constant4 _param_constant5 = self._param_constant5 cond = torch.ops.higher_order.cond(pred_1, true_graph_0, false_graph_0, (x_1, _param_constant0, _param_constant1, _param_constant2, _param_constant3, _param_constant4, _param_constant5)); true_graph_0 = false_graph_0 = _param_constant0 = _param_constant1 = _param_constant2 = _param_constant3 = _param_constant4 = _param_constant5 = None getitem = cond[0]; cond = None ones_like = torch.ops.aten.ones_like.default(getitem, pin_memory = False); getitem = None true_graph_1 = self.true_graph_1 false_graph_1 = self.false_graph_1 _param_constant0_1 = self._param_constant0 _param_constant1_1 = self._param_constant1 _param_constant2_1 = self._param_constant2 _param_constant3_1 = self._param_constant3 _param_constant4_1 = self._param_constant4 _param_constant5_1 = self._param_constant5 cond_1 = torch.ops.higher_order.cond(pred_1, true_graph_1, false_graph_1, (x_1, _param_constant0_1, _param_constant1_1, _param_constant2_1, _param_constant3_1, _param_constant4_1, _param_constant5_1, ones_like)); pred_1 = true_graph_1 = false_graph_1 = x_1 = _param_constant0_1 = _param_constant1_1 = _param_constant2_1 = _param_constant3_1 = _param_constant4_1 = _param_constant5_1 = ones_like = None getitem_1 = cond_1[0] getitem_2 = cond_1[1]; getitem_2 = None getitem_3 = cond_1[2]; getitem_3 = None getitem_4 = cond_1[3]; getitem_4 = None getitem_5 = cond_1[4]; getitem_5 = None getitem_6 = cond_1[5]; getitem_6 = None getitem_7 = cond_1[6]; cond_1 = getitem_7 = None return (getitem_1,)""", # noqa: B950 ) def test_cond_autograd_user_nn_module(self): class User_nn_module(torch.nn.Module): def __init__(self) -> None: super().__init__() def forward(self, input): return input * input nn_module_true = User_nn_module() def true_fn(x): return nn_module_true(torch.abs((x**2).sin())) nn_module_false = torch.nn.ReLU(inplace=False) def false_fn(x): return nn_module_false((x + 42).cos()) for pred, fn in zip( [torch.tensor(False), torch.tensor(True)], [false_fn, true_fn] ): x = torch.randn(4, requires_grad=True) result = cond(pred, true_fn, false_fn, (x,)) self.assertEqual(result, fn(x)) grad_out = torch.ones_like(result) grads = torch.autograd.grad(result, (x,), grad_out) expected_grads = torch.autograd.grad(fn(x), (x,), grad_out) self.assertEqual(expected_grads, grads) def f(pred, x): result = cond(pred, true_fn, false_fn, (x,)) grad_out = torch.ones_like(result) return torch.autograd.grad(result, (x,), grad_out) gm = make_fx(f)(pred, x) self.assertExpectedInline( gm.code.strip(), """\ def forward(self, pred_1, x_1): true_graph_0 = self.true_graph_0 false_graph_0 = self.false_graph_0 cond = torch.ops.higher_order.cond(pred_1, true_graph_0, false_graph_0, (x_1,)); true_graph_0 = false_graph_0 = None getitem = cond[0]; cond = None ones_like = torch.ops.aten.ones_like.default(getitem, pin_memory = False); getitem = None true_graph_1 = self.true_graph_1 false_graph_1 = self.false_graph_1 cond_1 = torch.ops.higher_order.cond(pred_1, true_graph_1, false_graph_1, (x_1, ones_like)); pred_1 = true_graph_1 = false_graph_1 = x_1 = ones_like = None getitem_1 = cond_1[0]; cond_1 = None return (getitem_1,)""", # noqa: B950 ) def test_cond_autograd_inner_fn(self): def true_fn(x): return torch.abs((x**2).sin()) def false_fn(x): def inner_fn(x): return x**2 return torch.abs(inner_fn(x).sin()) x = torch.randn(4, requires_grad=True) pred = torch.tensor(False) fn = false_fn result_false = cond(pred, true_fn, false_fn, (x,)) self.assertEqual(result_false, fn(x)) grad_out = torch.ones_like(result_false) grads_false = torch.autograd.grad(result_false, (x,), grad_out) expected_grads = torch.autograd.grad(fn(x), (x,), grad_out) self.assertEqual(expected_grads, grads_false) pred = torch.tensor(True) fn = true_fn result_true = cond(pred, true_fn, false_fn, (x,)) self.assertEqual(result_true, fn(x)) self.assertEqual(result_false, result_true) grad_out = torch.ones_like(result_true) grads_true = torch.autograd.grad(result_true, (x,), grad_out) expected_grads = torch.autograd.grad(fn(x), (x,), grad_out) self.assertEqual(expected_grads, grads_true) self.assertEqual(grads_false, grads_true) def f(pred, x): result = cond(pred, true_fn, false_fn, (x,)) grad_out = torch.ones_like(result) return torch.autograd.grad(result, (x,), grad_out) gm = make_fx(f)(pred, x) self.assertExpectedInline( gm.code.strip(), """\ def forward(self, pred_1, x_1): true_graph_0 = self.true_graph_0 false_graph_0 = self.false_graph_0 cond = torch.ops.higher_order.cond(pred_1, true_graph_0, false_graph_0, (x_1,)); true_graph_0 = false_graph_0 = None getitem = cond[0]; cond = None ones_like = torch.ops.aten.ones_like.default(getitem, pin_memory = False); getitem = None true_graph_1 = self.true_graph_1 false_graph_1 = self.false_graph_1 cond_1 = torch.ops.higher_order.cond(pred_1, true_graph_1, false_graph_1, (x_1, ones_like)); pred_1 = true_graph_1 = false_graph_1 = x_1 = ones_like = None getitem_1 = cond_1[0]; cond_1 = None return (getitem_1,)""", # noqa: B950 ) def test_cond_autograd_inner_tensor(self): def true_fn(x): return torch.abs((x**2).sin()) def false_fn(x): y = torch.ones(4, requires_grad=False) * 42 return (x * y).cos() for pred, fn in zip( [torch.tensor(False), torch.tensor(True)], [false_fn, true_fn] ): x = torch.randn(4, requires_grad=True) result = cond(pred, true_fn, false_fn, (x,)) self.assertEqual(result, fn(x)) grad_out = torch.ones_like(result) grads = torch.autograd.grad(result, (x,), grad_out) expected_grads = torch.autograd.grad(fn(x), (x,), grad_out) self.assertEqual(expected_grads, grads) def f(pred, x): result = cond(pred, true_fn, false_fn, (x,)) grad_out = torch.ones_like(result) return torch.autograd.grad(result, (x,), grad_out) gm = make_fx(f)(pred, x) self.assertExpectedInline( gm.code.strip(), """\ def forward(self, pred_1, x_1): true_graph_0 = self.true_graph_0 false_graph_0 = self.false_graph_0 cond = torch.ops.higher_order.cond(pred_1, true_graph_0, false_graph_0, (x_1,)); true_graph_0 = false_graph_0 = None getitem = cond[0]; cond = None ones_like = torch.ops.aten.ones_like.default(getitem, pin_memory = False); getitem = None true_graph_1 = self.true_graph_1 false_graph_1 = self.false_graph_1 cond_1 = torch.ops.higher_order.cond(pred_1, true_graph_1, false_graph_1, (x_1, ones_like)); pred_1 = true_graph_1 = false_graph_1 = x_1 = ones_like = None getitem_1 = cond_1[0]; cond_1 = None return (getitem_1,)""", # noqa: B950 ) @unittest.skipIf(not torch.cuda.is_available(), "Test requires CUDA.") def test_cond_autograd_gpu(self): def true_fn(x): return x.sin() def false_fn(x): return x.cos() for pred, fn in zip( [torch.tensor(False, device="cuda"), torch.tensor(True, device="cuda")], [false_fn, true_fn], ): x = torch.randn(4, requires_grad=True, device="cuda") result = cond(pred, true_fn, false_fn, (x,)) self.assertEqual(result, fn(x)) grad_out = torch.ones_like(result) grads = torch.autograd.grad(result, (x,), grad_out) expected_grads = torch.autograd.grad(fn(x), (x,), grad_out) self.assertEqual(expected_grads, grads) def _test_cond_autograd(self, cond_fct, pred_fn, true_fn, false_fn, operands): from torch.fx.passes.shape_prop import _extract_tensor_metadata, TensorMetadata # This is a helper function that extracts the metadata from the tensor and # sets the requries_grad flag to false. This is needed as we compare the # metadata of the operands and the gradients def _extract_tensor_metadata_except_requires_grad(arg): metadata = _extract_tensor_metadata(arg) metadata = TensorMetadata( metadata.shape, metadata.dtype, False, metadata.stride, metadata.memory_format, metadata.is_quantized, metadata.qparams, ) return metadata # Comparison of FWD path cond_outputs = cond_fct(pred_fn(*operands), true_fn, false_fn, operands) operands_forced_grad = [o.clone().detach() for o in operands] for o in operands_forced_grad: o.requires_grad = True cond_outputs_exp = ( true_fn(*operands_forced_grad) if pred_fn(*operands_forced_grad) else false_fn(*operands_forced_grad) ) self.assertEqual(cond_outputs, cond_outputs_exp) # Comparison of BWD path cond_inputs = [o for o in operands if o.requires_grad] cond_inputs_exp = [o for o in operands_forced_grad if o.requires_grad] # Check if at least some operators require grads if len(cond_inputs) > 0: grad_inputs = torch.autograd.grad( cond_outputs, cond_inputs, allow_unused=True, retain_graph=True ) grad_inputs_exp = torch.autograd.grad( cond_outputs_exp, cond_inputs_exp, allow_unused=True, materialize_grads=True, ) grad_exp_masked = [ g for g, o in zip(grad_inputs_exp, operands) if o.requires_grad ] self.assertEqual(grad_exp_masked, grad_inputs) # Extraction and comparison of Metadata of operands and gradients operands_metadata = [ _extract_tensor_metadata_except_requires_grad(o) for o in cond_inputs ] grad_metadata = [ _extract_tensor_metadata_except_requires_grad(o) for o in grad_inputs ] self.assertTrue( all(op == g for op, g in zip(operands_metadata, grad_metadata)) ) return cond_outputs, cond_inputs # TODO: The compile_mode = `compile_dynamic_shape` raises the Error # torch._inductor.exc.LoweringException: NotImplementedError: get_size() is not # implemented by ! @skipIfTorchDynamo("don't test compile on compile") @unittest.skipIf(not SM70OrLater, "triton") @unittest.skipIf(not torch.cuda.is_available(), "Test requires CUDA.") @parametrize("compile_mode", ["compile_dynamic_shape"]) @parametrize("scalar", [False]) @unittest.expectedFailure def test_cond_autograd_zeros_unused_branch_complex_compile_fail( self, compile_mode, scalar ): device = torch.device("cuda") cond_fct = compile_mode_helper(torch.cond, compile_mode) autograd = [False, True, True, True, True] if scalar: # These operands work x = torch.randn((), device=device, requires_grad=bool(autograd[0])) w1 = torch.randn((), device=device, requires_grad=bool(autograd[1])) b1 = torch.randn((), device=device, requires_grad=bool(autograd[2])) w2 = torch.randn((), device=device, requires_grad=bool(autograd[3])) b2 = torch.randn((), device=device, requires_grad=bool(autograd[4])) else: # These operands do not work x = torch.randn(4, 5, device=device, requires_grad=bool(autograd[0])) w1 = torch.randn(2, 4, device=device, requires_grad=bool(autograd[1])) b1 = torch.randn(2, 1, device=device, requires_grad=bool(autograd[2])) w2 = torch.randn(2, 4, device=device, requires_grad=bool(autograd[3])) b2 = torch.randn(1, 5, device=device, requires_grad=bool(autograd[4])) operands = [x, w1, b1, w2, b2] def true_fn(x, w1, b1, w2, b2): if scalar: # This works return ((w1 * x + b1),) else: # This does not work return ((w1 @ x + b1).sum(),) def false_fn(x, w1, b1, w2, b2): if scalar: # This works return ((w2 * x + b2),) else: # This does not work return ((w2 @ x + b2).sum(),) def pred_fn(x, w1, b1, w2, b2): return x.mean() > 0 cond_outputs, cond_inputs = self._test_cond_autograd( cond_fct, pred_fn, true_fn, false_fn, operands ) @unittest.skipIf(not torch.cuda.is_available(), "Test requires CUDA.") def test_map_gpu(self): def f(x, y): return x + y xs = torch.ones(3, 2, 2, device="cuda") y = torch.ones(2, device="cuda") res = control_flow.map(f, xs, y) expected = _fake_map(f, xs, y) self.assertEqual(expected, res) @unittest.skipIf(not torch.cuda.is_available(), "Test requires CUDA.") def test_while_loop_gpu(self): def cond_fn(x): return x.sum() < 10 def body_fn(x): return (x + 1,) x = torch.zeros(1, device="cuda") res = while_loop(cond_fn, body_fn, (x,)) expected = _fake_while_loop(cond_fn, body_fn, (x,)) self.assertEqual(expected, res) def test_map_illegal_inputs(self): def f(x, y): return x[0] + x[1] + y with self.assertRaisesRegex( RuntimeError, r"Mapped xs can only consist of tensors\. Got xs \[3, tensor\(\[1\., 1\.\]\)\]\.", ): _ = control_flow.map(f, (3, torch.ones(2)), torch.ones(2)) with self.assertRaisesRegex( RuntimeError, r"Leading dimensions of mapped xs cannot be 0\." ): _ = control_flow.map( f, (torch.ones(0, 1, 2), torch.ones(0, 1, 2)), torch.ones(2) ) with self.assertRaisesRegex( RuntimeError, r"Leading dimensions of mapped xs must be consistent\. " r"Got shapes \[torch\.Size\(\[3, 4, 5\]\), torch\.Size\(\[4, 4, 5\]\)\]\.", ): _ = control_flow.map( f, (torch.ones(3, 4, 5), torch.ones(4, 4, 5)), torch.ones(5) ) @torch._dynamo.config.patch(capture_scalar_outputs=True) def test_map_illegal_outputs(self): def f(x, y): return x.item() def f1(x, y): return y.size() def f2(x, y): return None x = torch.ones([3]) y = torch.ones([1, 2, 3]) with self.assertRaisesRegex( RuntimeError, "map doesn't work unless it is captured completely" ): control_flow.map(f, x, y) with self.assertRaisesRegex( # Should be # torch._dynamo.exc.UncapturedHigherOrderOpError, # "Expected all leaves to be of torch.Tensor type.*", torch._dynamo.exc.UncapturedHigherOrderOpError, "map doesn't work unless it is captured completely with torch.compile.*", ): control_flow.map(f1, x, y) # return None is OK control_flow.map(f2, x, y) def test_map_list_in_out(self): def f(x, y): return [[x[0][0] + y]] xs = [[torch.ones(3, 2, 2)]] y = torch.ones(2) res = control_flow.map(f, xs, y) expected = _fake_map(f, xs, y) self.assertEqual(len(res), 1) self.assertEqual(len(res[0]), 1) self.assertEqual(expected, res) def test_map_dict_in_out(self): def f(x, y): return {"c": x["a"]["b"] + y} xs = {"a": {"b": torch.ones(3, 2, 2)}} y = torch.ones(2) res = control_flow.map(f, xs, y) expected = _fake_map(f, xs, y) self.assertEqual(len(res), 1) self.assertTrue("c" in res) self.assertEqual(expected, res) def test_map_autograd_simple(self): def f(x, y): return x.sin().cos() * y.cos().sin() xs = torch.ones(3, 2, 2, requires_grad=True) y = torch.ones(2, requires_grad=True) res = control_flow.map(f, xs, y) expected_res = _fake_map(f, xs, y) grad_out = torch.ones_like(res) grads = torch.autograd.grad(res, (xs, y), grad_out) expected_grads = torch.autograd.grad(expected_res, (xs, y), grad_out) self.assertEqual(expected_res, res) self.assertEqual(expected_grads, grads) def test_map_autograd_simple_partial_grad(self): def f(x, y): return x.sin().cos() * y.cos().sin() xs = torch.ones(3, 2, 2, requires_grad=True) # Disable the gradient computation for y y = torch.ones(2, requires_grad=False) res = control_flow.map(f, xs, y) expected_res = _fake_map(f, xs, y) grad_out = torch.ones_like(res) grads = torch.autograd.grad(res, (xs,), grad_out) expected_grads = torch.autograd.grad(expected_res, (xs,), grad_out) self.assertEqual(expected_res, res) self.assertEqual(expected_grads, grads) def test_map_autograd_no_grad_output(self): def f(x, y): return x[0].sin().cos() + y, y.cos().sin() xs = [torch.ones(3, 2, 2, requires_grad=True), torch.ones(3, 3)] # Disable the gradient computation for y y = torch.ones(2, requires_grad=False) res = control_flow.map(f, xs, y) expected_res = _fake_map(f, xs, y) grad_out = torch.ones_like(res[0]) grads = torch.autograd.grad(res[0], (xs[0],), grad_out) expected_grads = torch.autograd.grad(expected_res[0], (xs[0],), grad_out) self.assertEqual(expected_res, res) self.assertEqual(expected_grads, grads) def test_map_autograd_nested_list(self): import torch.utils._pytree as pytree def f(x, y): a, b = x c, d = a return [[b.sin() * c.cos()], d.sin() * y.cos()] def fwbw(map_op, f, x, y): z = map_op(f, x, y) flat_x = pytree.tree_leaves(x) flat_z = pytree.tree_leaves(z) grads = torch.autograd.grad( flat_z, flat_x, [torch.ones_like(z) for z in flat_z] ) return z, grads x = [ [ torch.randn(3, 2, 2, requires_grad=True), torch.randn(3, 2, 1, requires_grad=True), ], torch.ones(3, 1, 2, requires_grad=True), ] y = torch.ones(1, requires_grad=True) true_outs = fwbw(control_flow.map, f, x, y) fake_outs = fwbw(_fake_map, f, x, y) self.assertEqual(true_outs, fake_outs) def test_map_autograd_higher_order(self): from torch.autograd.functional import hessian as hes, jacobian as jac def f(x, y): return x.sin().cos() + y def wrapper_jac(x, y): return control_flow.map(f, x, y) def wrapper_jac_fake(x, y): return _fake_map(f, x, y) def wrapper_hes(x, y): return control_flow.map(f, x, y).sum() def wrapper_hes_fake(x, y): return _fake_map(f, x, y).sum() for g_fct, (wrap, wrap_fake) in [ (jac, [wrapper_jac, wrapper_jac_fake]), (hes, [wrapper_hes, wrapper_hes_fake]), ]: xs = torch.ones(3, 2, 2, requires_grad=True) # Disable the gradient computation for y y = torch.ones(2, requires_grad=False) res = control_flow.map(f, xs, y) expected_res = _fake_map(f, xs, y) self.assertEqual(expected_res, res) expected_grads = g_fct(wrap_fake, (xs, y)) grads = g_fct(wrap, (xs, y)) self.assertEqual(expected_res, res) self.assertEqual(expected_grads, grads) def test_scan_y_less_ndim_then_dim(self): def combine_fn(carry, x): return carry @ x, (carry @ x).sum() init = torch.randn(4, 3) xs = torch.randn(3, 3, 2) dim = 2 out = scan(combine_fn, init, xs, dim=dim) exp_out = _fake_scan(combine_fn, init, xs, dim=dim) self.assertEqual(out, exp_out) # TODO: provide an implementation for all compile modes and re-enable all test @skipIfTorchDynamo("don't test compile on compile") @requires_cuda @parametrize("reverse", [False, True]) @parametrize("compile_mode", ["none", "eager"]) @parametrize("device", [torch.device("cpu"), torch.device("cuda")]) @parametrize("autograd", [False, True]) def test_scan_compile(self, reverse, compile_mode, device, autograd): def add2(x: torch.Tensor, y: torch.Tensor): return x * y, x + y x = torch.randn(3, 10, 2, device=device, requires_grad=autograd) scan_fct = compile_mode_helper(scan, compile_mode) for op, op_pt, init in [ ( get_scan_combine_fn("add", False), torch.cumsum, torch.zeros(10, 2, device=device, requires_grad=autograd), ), ( get_scan_combine_fn("mul", False), torch.cumprod, torch.ones(10, 2, device=device, requires_grad=autograd), ), ]: result = scan_fct(op, init, x, dim=0, reverse=reverse) result_exp = _fake_scan(op, init=init, xs=x, dim=0, reverse=reverse) self.assertEqual(result, result_exp) if not reverse: result_exp_PT = op_pt(x, 0) self.assertEqual(result[1], result_exp_PT) if autograd: self.check_autograd(result, result_exp, (init, x)) # Jax Examples x = torch.arange(0, 4, device=device, dtype=torch.int64) init = torch.zeros(1, device=device, dtype=torch.int64) cumsum1 = scan_fct( get_scan_combine_fn("add", False), init, x, dim=0, reverse=reverse, ) cumsum_exp = _fake_scan( get_scan_combine_fn("add", False), init=init, xs=x, dim=0, reverse=reverse, ) if not reverse: self.assertEqual( cumsum1[1], torch.tensor([[0.0], [1.0], [3.0], [6.0]], dtype=torch.int64), ) self.assertEqual(cumsum1[0], torch.tensor([6.0], dtype=torch.int64)) else: self.assertEqual( cumsum1[1], torch.tensor([[6.0], [6.0], [5.0], [3.0]], dtype=torch.int64), ) self.assertEqual(cumsum1[0], torch.tensor([6.0], dtype=torch.int64)) self.assertEqual(cumsum1, cumsum_exp) # Different carry computation as output computation x = torch.arange(1, 5, device=device, dtype=torch.int64) init = torch.ones(1, device=device, dtype=torch.int64) result = scan_fct(add2, init, x, dim=0, reverse=reverse) result_exp = _fake_scan(add2, init=init, xs=x, dim=0, reverse=reverse) if not reverse: self.assertEqual( result[1], torch.tensor([[2.0], [3.0], [5.0], [10.0]], dtype=torch.int64), ) self.assertEqual(result[0], torch.tensor([24.0], dtype=torch.int64)) else: self.assertEqual( result[1], torch.tensor([[25.0], [14.0], [7.0], [5.0]], dtype=torch.int64), ) self.assertEqual(result[0], torch.tensor([24.0], dtype=torch.int64)) self.assertEqual(result, result_exp) # Non associative operation x = torch.arange( 0, 5, device=device, dtype=torch.float32, requires_grad=autograd ) init = torch.ones(1, device=device, dtype=torch.float32, requires_grad=autograd) result = scan_fct( get_scan_combine_fn("div", False), init, x, dim=0, reverse=reverse, ) result_exp = _fake_scan( get_scan_combine_fn("div", False), init=init, xs=x, dim=0, reverse=reverse, ) self.assertEqual(result, result_exp) if autograd: self.check_autograd(result, result_exp, (init, x)) # TODO: provide an implementation for all compile modes and re-enable all test @skipIfTorchDynamo("don't test compile on compile") @requires_cuda @parametrize("reverse", [False, True]) @parametrize("compile_mode", ["none", "eager"]) @parametrize("device", [torch.device("cpu"), torch.device("cuda")]) @parametrize( "dtype", [ torch.float16, torch.float32, torch.int32, torch.int64, torch.complex64, ], ) def test_scan_dtype(self, reverse, compile_mode, device, dtype): scan_fct = compile_mode_helper(scan, compile_mode) # Check all outputs and carries on the correct device and with torch.float32 x = torch.randn(3, 10, 2, device=device).to(dtype=dtype) op, init = ( get_scan_combine_fn("adds"), torch.zeros(10, 2, device=device, dtype=dtype), ) result = scan_fct(op, init, x, dim=0, reverse=reverse) result_exp = _fake_scan(op, init=init, xs=x, dim=0, reverse=reverse) self.assertEqual(result, result_exp) self.assertEqual( [[r.device.type for r in res] for res in result], [[device.type for _ in res] for res in result], ) self.assertEqual( [[r.dtype for r in res] for res in result], [[dtype for _ in res] for res in result], ) # Check all outputs and carries on the correct device and # carry.dtype torch.float32 and output.dtype torch.float16 x = torch.randn(3, 10, 2, device=device).to(dtype=dtype) op, init = ( get_scan_combine_fn("adds"), torch.zeros(10, 2, device=device, dtype=torch.float32), ) result = scan_fct(op, init, x, dim=0, reverse=reverse) result_exp = _fake_scan(op, init=init, xs=x, dim=0, reverse=reverse) self.assertEqual(result, result_exp) self.assertEqual( [[r.dtype for r in res] for res in result], [ [torch.float32 for _ in range(len(result[0]))], [dtype for _ in range(len(result[1]))], ], ) # Check all outputs and carries on the correct device and # carry.dtype torch.int64 and output.dtype torch.float32 x = torch.randn(3, 10, 2, device=device) op, init = ( get_scan_combine_fn("adds"), torch.zeros(10, 2, device=device, dtype=dtype), ) result = scan_fct(op, init, x, dim=0, reverse=reverse) result_exp = _fake_scan(op, init=init, xs=x, dim=0, reverse=reverse) self.assertEqual(result, result_exp) self.assertEqual( [[r.dtype for r in res] for res in result], [ [dtype for _ in range(len(result[0]))], [torch.float32 for _ in range(len(result[1]))], ], ) @unittest.skipIf(not SM70OrLater, "triton") @requires_cuda @parametrize("reverse", [False, True]) @parametrize("compile_mode", ["none", "eager"]) @parametrize("device", [torch.device("cpu"), torch.device("cuda")]) @parametrize("autograd", [False, True]) def test_scan_dim(self, reverse, compile_mode, device, autograd): import random scan_fct = compile_mode_helper(scan, compile_mode) num_dims = [random.randint(2, 5) for _ in range(5)] for num_dim in num_dims: shapes = [random.randint(1, 10) for _ in range(num_dim)] rnd_scan_dim = random.randint(0, num_dim - 1) x = torch.randn(*shapes, device=device, requires_grad=autograd) init_shapes = shapes[:rnd_scan_dim] + shapes[rnd_scan_dim + 1 :] for op, op_pt, init in [ ( get_scan_combine_fn("add", False), torch.cumsum, torch.zeros(*init_shapes, device=device, requires_grad=autograd), ), ( get_scan_combine_fn("mul", False), torch.cumprod, torch.ones(*init_shapes, device=device, requires_grad=autograd), ), ]: result = scan_fct(op, init, x, dim=rnd_scan_dim, reverse=reverse) result_exp = _fake_scan( op, init=init, xs=x, dim=rnd_scan_dim, reverse=reverse ) self.assertEqual(result, result_exp) if not reverse: result_exp_PT = op_pt(x, rnd_scan_dim) res_list = list(result) res_list[1] = res_list[1].movedim(0, rnd_scan_dim) self.assertEqual(res_list[1], result_exp_PT) if autograd: self.check_autograd(result, result_exp, (init, x)) @unittest.skipIf(not SM70OrLater, "triton") @requires_cuda @parametrize("reverse", [False, True]) @parametrize("compile_mode", ["none", "eager"]) @parametrize("device", [torch.device("cpu"), torch.device("cuda")]) @parametrize("autograd", [False, True]) def test_scan_binary_operator(self, reverse, compile_mode, device, autograd): state_dim = 20 timesteps = 10 scan_fct = compile_mode_helper(scan, compile_mode) projected_inputs = torch.randn( timesteps, state_dim, requires_grad=autograd, device=device ) A = torch.randn(state_dim, requires_grad=autograd, device=device) elements = (A.repeat((timesteps, 1)), projected_inputs) init = tuple( [ torch.ones_like( torch._ops.ops.aten.slice(elements[0], 0, 0, 1, 1), requires_grad=autograd, ) ] + [ torch.zeros_like( torch._ops.ops.aten.slice(projected_inputs, 0, 0, 1, 1), requires_grad=autograd, ) ] ) result = scan_fct( get_scan_combine_fn("s5_operator", False), init, elements, dim=0, reverse=reverse, ) expected_result = _fake_scan( get_scan_combine_fn("s5_operator", False), init=init, xs=elements, dim=0, reverse=reverse, ) self.assertEqual(result, expected_result) if autograd: init_flatten, _ = pytree.tree_flatten(init) elements_flatten, _ = pytree.tree_flatten(elements) result_flatten, _ = pytree.tree_flatten(result) result_exp_flatten, _ = pytree.tree_flatten(expected_result) grad_out = [torch.ones_like(el) for el in result_exp_flatten] expected_grads = torch.autograd.grad( result_exp_flatten, (*init_flatten, *elements_flatten), grad_out ) grads = torch.autograd.grad( result_flatten, (*init_flatten, *elements_flatten), grad_out ) self.assertEqual(grads, expected_grads) @skipIfRocm(msg="Unsupported on ROCM yet") @unittest.skipIf(not SM70OrLater, "triton") @requires_cuda @parametrize("reverse", [False, True]) @parametrize("compile_mode", ["none", "eager"]) @parametrize("device", [torch.device("cpu"), torch.device("cuda")]) @parametrize("autograd", [False, True]) def test_scan_tuple(self, reverse, compile_mode, device, autograd): x = torch.randn(3, 2, 2, device=device, requires_grad=autograd) y = torch.randn(3, 2, 2, device=device, requires_grad=autograd) inp = (x, y) init = tuple(torch._ops.ops.aten.slice(e, 0, 0, 1, 1) for e in inp) scan_fct = compile_mode_helper(scan, compile_mode) result_same = scan_fct( get_scan_combine_fn("tuple_fct", False), init, inp, dim=0, reverse=reverse, ) expected_result = _fake_scan( get_scan_combine_fn("tuple_fct", False), init=init, xs=inp, dim=0, reverse=reverse, ) self.assertEqual(result_same, expected_result) if autograd: self.check_autograd(result_same, expected_result, (init, inp)) def fct_different_output_tuple(x, y): return ((x[0] + y[0], x[1] * y[1]), (x[1] * y[1])) inp = (x, y) init = tuple(torch._ops.ops.aten.slice(e, 0, 0, 1, 1) for e in inp) result_diff = scan( fct_different_output_tuple, init, inp, dim=0, reverse=reverse ) expected_result = _fake_scan( fct_different_output_tuple, init=init, xs=inp, dim=0, reverse=reverse ) self.assertEqual(result_diff, expected_result) self.assertEqual(result_diff[1], result_same[1][1]) if autograd: self.check_autograd(result_diff, expected_result, (init, inp)) def test_scan_wrong_pytree(self): # Init and input have same pytree def fct_wrong_pytree(x, y): return ( { "i": x["i"] * y["j"][0][0], "k": torch.tensor(0.0), "j": ( [x["j"][1][0]["o"].clone()], [{"o": torch.sin(x["i"])}], ), }, { "i": x["i"] * y["j"][0][0], "k": torch.tensor(0.0), "j": ([x["j"][1][0]["o"].clone()], [{"o": torch.sin(x["i"])}]), }, ) x = torch.randn(3, 2, 2) y = torch.randn(3, 2, 2) z = torch.randn(3, 2, 2) inp = {"i": x, "j": ([y], [{"o": z}])} inp_flat, inp_spec = pytree.tree_flatten(inp) init_flat = [torch._ops.ops.aten.slice(e, 0, 0, 1, 1) for e in inp_flat] init = pytree.tree_unflatten(init_flat, inp_spec) with self.assertRaisesRegex( # Should be # torch._dynamo.exc.UncapturedHigherOrderOpError, # r"The tree structure of the inits and the carries are not identical.*", torch._dynamo.exc.UncapturedHigherOrderOpError, "Expected init and carry to have same number of outputs but got lhs.*", ): scan(fct_wrong_pytree, init, inp, dim=0) def test_scan_float_output(self): # Init and input have same pytree def fct_float_output(x, y): return 0.0, x + y x = torch.randn(3, 2, 2) init = torch._ops.ops.aten.slice(x, 0, 0, 1, 1) with self.assertRaisesRegex( # Should be: # torch._dynamo.exc.Unsupported, # "HigherOrderOperator body's output must consist of tensors or ints only" torch._dynamo.exc.UncapturedHigherOrderOpError, "scan must be captured completely.*", ): scan(fct_float_output, init, x, dim=0) @requires_cuda @parametrize("reverse", [False, True]) @parametrize("compile_mode", ["none", "eager"]) @parametrize("device", [torch.device("cpu"), torch.device("cuda")]) @parametrize("autograd", [False, True]) def test_scan_complex_pytree(self, reverse, compile_mode, device, autograd): # Init and input have same pytree scan_fct = compile_mode_helper(scan, compile_mode) x = torch.randn(3, 2, 2, device=device, requires_grad=autograd) y = torch.randn(3, 2, 2, device=device, requires_grad=autograd) z = torch.randn(3, 2, 2, device=device, requires_grad=autograd) inp = {"i": x, "j": ([y], [{"o": z}])} inp_flat, inp_spec = pytree.tree_flatten(inp) init_flat = [torch._ops.ops.aten.slice(e, 0, 0, 1, 1) for e in inp_flat] init = pytree.tree_unflatten(init_flat, inp_spec) result = scan_fct( get_scan_combine_fn("complex_pointwise", False), init, inp, dim=0, reverse=reverse, ) expected_result = _fake_scan( get_scan_combine_fn("complex_pointwise", False), init=init, xs=inp, dim=0, reverse=reverse, ) self.assertEqual(result, expected_result) if autograd: self.check_autograd(result, expected_result, (init, inp)) # TODO: Does not work because of the usage of vmap witin associative_scan # The paT206899919 rameterization is commented out for the moment and the test is marked with expected fail # Fails with: AssertionError: scan is not an OpOverload @skipIfRocm(msg="Unsupported on ROCM yet") @unittest.skipIf(not SM70OrLater, "triton") @requires_cuda @unittest.expectedFailure def test_scan_associative_scan(self): combine_mode = "generic" compile_mode_scan = "compile" compile_mode_associative_scan = "none" reverse = True reverse_associative_scan = True device = torch.device("cuda") scan_fct = compile_mode_helper(scan, compile_mode_scan) associative_scan_fct = compile_mode_helper( associative_scan, compile_mode_associative_scan ) init = torch.randn(10, 5, device=device) inp = torch.randn(3, 10, 5, device=device) def body(x, y): val = associative_scan_fct( get_scan_combine_fn("add", True), y, 0, reverse=reverse_associative_scan, combine_mode=combine_mode, ) return x + y, x + val result = scan_fct(body, init, inp, dim=0, reverse=reverse) expected_result = _fake_scan( body, init, inp, 0, reverse=reverse, ) self.assertEqual(result, expected_result) # TODO: provide an implementation for all compile modes and re-enable all test @skipIfTorchDynamo("don't test compile on compile") @requires_cuda @parametrize("compile_mode", ["none", "eager"]) @parametrize("reverse", [False, True]) @parametrize("device", [torch.device("cpu"), torch.device("cuda")]) @parametrize("autograd", [False, True]) def test_scan_downstream_scan_matmul(self, compile_mode, reverse, device, autograd): inp = torch.randn(3, 10, 2, device=device, requires_grad=autograd) init = torch.randn(3, 2, device=device, requires_grad=autograd) for ind in range(2): # Chain with matmul def chain_fct(inp): W = torch.ones(2, 5, device=device) o = scan( get_scan_combine_fn("add", False), init, inp, dim=1, reverse=reverse, ) return o[ind] @ W fct_cmp = compile_mode_helper(chain_fct, compile_mode) expected_result = _fake_scan( get_scan_combine_fn("add", False), init=init, xs=inp, dim=1, reverse=reverse, )[ind] @ torch.ones(2, 5, device=device) result = fct_cmp(inp) self.assertEqual(result, expected_result) if autograd: self.check_autograd(result, expected_result, (init, inp)) # TODO: provide an implementation for all compile modes and re-enable all test @skipIfTorchDynamo("don't test compile on compile") @requires_cuda @parametrize("compile_mode", ["none", "eager"]) @parametrize("reverse", [False, True]) @parametrize("device", [torch.device("cpu"), torch.device("cuda")]) @parametrize("autograd", [False, True]) def test_scan_downstream_scan_scan_dim( self, compile_mode, reverse, device, autograd ): inp = torch.randn(3, 10, 2, device=device, requires_grad=autograd) init = torch.randn(3, 2, device=device, requires_grad=autograd) # Chain with scan on different dim init2 = torch.randn(1, 10, 2, device=device, requires_grad=autograd) def chain_fct_different_dim(inp): o1 = scan( get_scan_combine_fn("add", False), init, inp, dim=1, reverse=reverse, ) o1 = pytree.tree_map(lambda t: t.movedim(0, 1), o1) o2 = scan( get_scan_combine_fn("add", False), init2, o1[1], dim=0, reverse=reverse, ) return o2 fct_cmp = compile_mode_helper(chain_fct_different_dim, compile_mode) xs = _fake_scan( get_scan_combine_fn("add", False), init=init, xs=inp, dim=1, reverse=reverse, )[1] xs = pytree.tree_map(lambda t: t.movedim(0, 1), xs) expected_result = _fake_scan( get_scan_combine_fn("add", False), init=init2, xs=xs, dim=0, reverse=reverse, ) result = fct_cmp(inp) self.assertEqual(result, expected_result) if autograd: self.check_autograd(result, expected_result, (init, init2, inp)) @unittest.skipIf(not SM70OrLater, "triton") @requires_cuda @parametrize("reverse", [False, True]) @parametrize("compile_mode", ["none", "eager"]) @parametrize("device", [torch.device("cpu"), torch.device("cuda")]) @parametrize("autograd", [False, True]) def test_scan_non_pointwise(self, reverse, compile_mode, device, autograd): scan_fct = compile_mode_helper(scan, compile_mode) x = torch.randn(3, 10, 2, device=device, requires_grad=autograd) init = torch.randn(10, 2, device=device, requires_grad=autograd) expected_result = _fake_scan( get_scan_combine_fn("non_pointwise", False), init=init, xs=x, dim=0, reverse=reverse, ) result = scan_fct( get_scan_combine_fn("non_pointwise", False), init, x, dim=0, reverse=reverse, ) self.assertEqual(result, expected_result) if autograd: self.check_autograd(result, expected_result, (init, x)) @requires_cuda @parametrize("reverse", [False, True]) @parametrize("device", [torch.device("cpu"), torch.device("cuda")]) def test_scan_compile_cnt(self, reverse, device): dim = 1 from torch._dynamo.testing import CompileCounter # Tests rely on automatic_dynamic = True with torch._dynamo.config.patch(automatic_dynamic_shapes=True): cnt = CompileCounter() x = torch.randn(3, 2, 5, device=device) init = torch.randn(3, 5, device=device) # First compilation step torch.compile(scan, backend=cnt)( get_scan_combine_fn("add", False), init, x, dim=dim, reverse=reverse, ) self.assertEqual(cnt.frame_count, 1) x = torch.randn(3, 20, 5, device=device) init = torch.randn(3, 5, device=device) # Recompilation due to first different size torch.compile(scan, backend=cnt)( get_scan_combine_fn("add", False), init, x, dim=dim, reverse=reverse, ) self.assertEqual(cnt.frame_count, 2) x = torch.randn(3, 40, 5, device=device) init = torch.randn(3, 5, device=device) # No recompilation, because of dynamic shape torch.compile(scan, backend=cnt)( get_scan_combine_fn("add", False), init, x, dim=dim, reverse=reverse, ) self.assertEqual(cnt.frame_count, 2) x = torch.randn(3, 40, 5, device=device) init = torch.randn(3, 40, device=device) # Recompilation because of dim change torch.compile(scan, backend=cnt)( get_scan_combine_fn("add", False), init, x, dim=2, reverse=reverse, ) self.assertEqual(cnt.frame_count, 3) x = torch.randn(3, 40, 20, device=device) init = torch.randn(3, 40, device=device) # Recompilation due to first different size on new dim torch.compile(scan, backend=cnt)( get_scan_combine_fn("add", False), init, x, dim=2, reverse=reverse, ) self.assertEqual(cnt.frame_count, 4) x = torch.randn(3, 40, 40, device=device) init = torch.randn(3, 40, device=device) # No recompilation, because of dynamic shape on new dim torch.compile(scan, backend=cnt)( get_scan_combine_fn("add", False), init, x, dim=2, reverse=reverse, ) self.assertEqual(cnt.frame_count, 4) x = torch.randn(3, 60, 40, device=device) init = torch.randn(3, 40, device=device) # Recompilation because of dim change torch.compile(scan, backend=cnt)( get_scan_combine_fn("add", False), init, x, dim=1, reverse=reverse, ) self.assertEqual(cnt.frame_count, 5) x = torch.randn(3, 60, 40, device=device) init = torch.randn(3, 40, device=device) # Recompilation because of reverse change torch.compile(scan, backend=cnt)( get_scan_combine_fn("add", False), init, x, dim=1, reverse=not reverse, ) self.assertEqual(cnt.frame_count, 6) x = torch.randn(3, 60, 40, device=device) init = torch.randn(3, 40, device=device) # No recompilation, as nothing changed torch.compile(scan, backend=cnt)( get_scan_combine_fn("add", False), init, x, dim=1, reverse=not reverse, ) self.assertEqual(cnt.frame_count, 6) x = torch.randn(3, 120, 80, device=device) init = torch.randn(3, 80, device=device) # No recompilation, final test torch.compile(scan, backend=cnt)( get_scan_combine_fn("add", False), init, x, dim=1, reverse=reverse, ) self.assertEqual(cnt.frame_count, 6) @skipIfTorchDynamo("don't test compile on compile") def test_scan_init_scanned_0(self): # Only init and no input x = torch.randn(3, 1, 2, device=torch.device("cpu")) init = torch.randn(3, 2, device=torch.device("cpu")) dim = 1 # Scan dimension is 0 init = torch._ops.ops.aten.slice(x, dim, 0, 1, 1) inp = torch._ops.ops.aten.slice(x, dim, 1, None, 1) with self.assertRaisesRegex( RuntimeError, "All xs leaves must at least have.*", ): scan( get_scan_combine_fn("add", False), init, inp, dim=dim, ) @skipIfTorchDynamo("don't test compile on compile") def test_scan_init_non_tensor(self): x = torch.randn(3, 1, 2, device=torch.device("cpu")) dim = 1 # Init is a float and not a tensor init = 1.0 with self.assertRaisesRegex(RuntimeError, "All init leaves must be a Tensor.*"): scan(get_scan_combine_fn("add", False), init, x, dim=dim, reverse=False) @skipIfTorchDynamo("don't test compile on compile") def test_scan_init_wrong_shape(self): scan_fct = compile_mode_helper(scan, "none") # Only init and no input x = torch.randn(3, 1, 2) dim = 1 # Init wrong shape (Other dim different) init = torch.randn(1, 2) with self.assertRaisesRegex( torch._dynamo.exc.UncapturedHigherOrderOpError, "Expected init and carry to have same metadata.*", ): scan_fct( get_scan_combine_fn("add", False), init, x, dim=dim, ) @skipIfTorchDynamo("don't test compile on compile") def test_scan_init_wrong_pytree_init_longer_carry(self): def init_longer_carry(x: torch.Tensor, y: torch.Tensor): return x[0] + 1.0, y + 1.0 scan_fct = compile_mode_helper(scan, "none") # Only init and no input x = torch.randn(3, 1, 2) dim = 1 # Init wrong pytree init = ( torch._ops.ops.aten.slice(x, dim, 0, 1, 1), torch._ops.ops.aten.slice(x, dim, 0, 1, 1), ) with self.assertRaisesRegex( torch._dynamo.exc.UncapturedHigherOrderOpError, "Expected init and carry to have same number of outputs but got lhs.*", ): scan_fct(init_longer_carry, init, x, dim=dim) @skipIfTorchDynamo("don't test compile on compile") def test_scan_init_wrong_pytree_init_shorter_carry(self): def init_shorter_carry(x: torch.Tensor, y: torch.Tensor): return (x + 1, x + 2), x + 3 scan_fct = compile_mode_helper(scan, "none") # Only init and no input x = torch.randn(3, 1, 2) dim = 1 # Init wrong pytree init = torch._ops.ops.aten.slice(x, dim, 0, 1, 1) with self.assertRaisesRegex( # Should be # torch._dynamo.exc.Unsupported, # The tree structure of the inits and the carries are not identical! torch._dynamo.exc.UncapturedHigherOrderOpError, "Expected init and carry to have same number of outputs but got lhs.*", ): scan_fct(init_shorter_carry, init, x, dim=dim) @skipIfTorchDynamo("don't test compile on compile") def test_scan_init_wrong_pytree_carry_shape(self): def wrong_carry_shape(x: torch.Tensor, y: torch.Tensor): return x[0, :], x + 3 scan_fct = compile_mode_helper(scan, "none") # Only init and no input x = torch.randn(3, 1, 2) dim = 1 # Init wrong pytree init = torch._ops.ops.aten.slice(x, dim, 0, 1, 1) with self.assertRaisesRegex( # Should be # torch._dynamo.exc.Unsupported, # "Encountered aliasing during higher order op tracing for HOP.*" torch._dynamo.exc.UncapturedHigherOrderOpError, "scan must be captured completely with torch.compile.*", ): scan_fct(wrong_carry_shape, init, x, dim=dim) @skipIfTorchDynamo("don't test compile on compile") def test_scan_one_return(self): def no_carry(x: torch.Tensor, y: torch.Tensor): return x + 3 scan_fct = compile_mode_helper(scan, "none") # Only init and no input x = torch.randn(3, 1, 2) dim = 1 # Init wrong pytree init = torch._ops.ops.aten.slice(x, dim, 0, 1, 1) with self.assertRaisesRegex( # Should be # torch._dynamo.exc.Unsupported, # combine_fn needs to produce two pytrees, one for the carries and one for the outputs. torch._dynamo.exc.UncapturedHigherOrderOpError, "scan must be captured completely with.*", ): scan_fct(no_carry, init, x, dim=dim) @skipIfTorchDynamo("don't test compile on compile") @requires_cuda @parametrize("reverse", [False, True]) @parametrize("compile_mode", ["none", "eager"]) @parametrize("device", [torch.device("cpu"), torch.device("cuda")]) @parametrize("autograd", [False, True]) def test_scan_init(self, reverse, compile_mode, device, autograd): scan_fct = compile_mode_helper(scan, compile_mode) # Only init and no input x = torch.randn(3, 1, 2, device=device, requires_grad=autograd) dim = 1 op, op_pt = (get_scan_combine_fn("add", False), torch.cumsum) # Only init given init = torch._ops.ops.aten.slice(x, dim, 0, 1, 1) result = scan_fct(op, init, [], dim=dim, reverse=reverse) result_exp = _fake_scan(op, init=init, xs=[], dim=dim, reverse=reverse) result_init = scan_fct(op, init, [], dim=dim, reverse=reverse) self.assertEqual(result, result_exp) self.assertEqual(result_init, result_exp) self.assertEqual(result_init[0], init) if autograd: self.check_autograd(result, result_exp, (init,)) x = torch.randn(3, 5, 2, device=device, requires_grad=autograd) dim = 0 op, op_pt = (get_scan_combine_fn("add", False), torch.cumsum) inp = torch._ops.ops.aten.slice(x, dim, 1, None, 1) # Init tensor scalar init = torch.ones(1, device=device, requires_grad=autograd) def add_scalar_carry(x: torch.Tensor, y: torch.Tensor): return x + 1.0, x + y result_init = scan_fct(add_scalar_carry, init, inp, dim=dim, reverse=reverse) result_exp = _fake_scan( add_scalar_carry, init=init, xs=inp, dim=dim, reverse=reverse ) self.assertEqual(result_init, result_exp) self.assertEqual(result_init[0], torch.tensor([3.0], device=device)) if autograd: self.check_autograd(result_init, result_exp, (init, inp)) # Init tensor entirely different shape than inp init = torch.randn(7, 8, device=device, requires_grad=autograd) def add_scalar_carry2(x: torch.Tensor, y: torch.Tensor): return x + 1.0, x[: y.shape[0], : y.shape[1]] + y result_init = scan_fct(add_scalar_carry2, init, inp, dim=dim, reverse=reverse) result_exp = _fake_scan( add_scalar_carry2, init=init, xs=inp, dim=dim, reverse=reverse ) self.assertEqual(result_init, result_exp) # Init with two timestep on dim axis. Should work as y has always 1 on dim axis and # hence automatic broadcasting should work # I.e., the input shape is 2x5x2, but the carry at each iteration is 2x5x2, # thus the output of each iteration is 2x5x2, which results in the total output # to be 4x5x2 init = torch._ops.ops.aten.slice(x, dim, 0, 2, 1) result_init = scan_fct(op, init, inp, dim=dim, reverse=reverse) result_exp = _fake_scan(op, init=init, xs=inp, dim=dim, reverse=reverse) self.assertEqual(result_init, result_exp) self.assertEqual(result_init[0].shape, torch.Size([2, 5, 2])) if autograd: self.check_autograd(result_init, result_exp, (init, inp)) init = torch.tile(init, (1, 2, 1)) def add_scalar_carry_sliced_out(x: torch.Tensor, y: torch.Tensor): return x + 1.0, x[:, :1, :] + y result_init = scan_fct( add_scalar_carry_sliced_out, init, inp, dim=dim, reverse=reverse ) result_exp = _fake_scan( add_scalar_carry_sliced_out, init=init, xs=inp, dim=dim, reverse=reverse ) self.assertEqual(result_init, result_exp) self.assertEqual(result_init[0].shape, torch.Size([2, 10, 2])) self.assertEqual(result_init[1].shape, torch.Size([2, 2, 5, 2])) if autograd: self.check_autograd(result_init, result_exp, (init, inp)) # Correct case op, op_pt = (get_scan_combine_fn("add", False), torch.cumsum) x = torch.randn(3, 2, 2, device=device, requires_grad=autograd) init = torch.zeros(3, 2, device=device, requires_grad=autograd) dim = 2 result = scan_fct(op, init, x, dim=dim, reverse=reverse) result_exp = _fake_scan(op, init=init, xs=x, dim=dim, reverse=reverse) self.assertEqual(result, result_exp) if not reverse: result_exp_PT = op_pt(x, dim) result = list(result) result[1] = pytree.tree_map(lambda t: torch.movedim(t, 0, dim), result[1]) self.assertEqual(result[1], result_exp_PT) if autograd: self.check_autograd(result, result_exp, (init, x)) @requires_cuda @parametrize("reverse", [False, True]) @parametrize("device", [torch.device("cpu"), torch.device("cuda")]) def test_scan_init_wrong_pytree_complex(self, reverse, device): x = torch.randn(3, 2, 2, device=device) y = torch.randn(3, 2, 2, device=device) z = torch.randn(3, 2, 2, device=device) # Wrong pytree fed to the function init = { "i": torch._ops.ops.aten.slice(x, 0, 0, 1, 1), "j": ( {"a": torch._ops.ops.aten.slice(x, 0, 0, 1, 1)}, [torch._ops.ops.aten.slice(y, 0, 0, 1, 1)], [{"o": torch._ops.ops.aten.slice(z, 0, 0, 1, 1)}], ), } inp = { "i": torch._ops.ops.aten.slice(x, 0, 0, None, 1), "j": ( [torch._ops.ops.aten.slice(y, 0, 0, None, 1)], [{"o": torch._ops.ops.aten.slice(z, 0, 0, None, 1)}], ), } with self.assertRaisesRegex( Exception, ".*", ): scan( get_scan_combine_fn("complex_pointwise", False), init, inp, dim=0, reverse=reverse, ) @unittest.skipIf(not SM70OrLater, "triton") @requires_cuda @parametrize("reverse", [False, True]) @parametrize("compile_mode", ["none", "eager"]) @parametrize("device", [torch.device("cpu"), torch.device("cuda")]) @parametrize("autograd", [False, True]) def test_scan_init_pytree_complex(self, reverse, compile_mode, device, autograd): def fct_pointwise_different_output(x, y): return ( { "i": x["i"] * y["i"], "j": ( [x["j"][0][0] * y["j"][0][0]], [{"o": x["j"][1][0]["o"] + y["j"][1][0]["o"]}], ), }, ( y["i"] * 2, { "o": x["i"] * y["i"], "j": ( [x["j"][0][0] * y["j"][0][0]], [{"o": x["j"][1][0]["o"] + y["j"][1][0]["o"]}], ), }, ), ) def fct_pointwise_different_carry(x, y): return ( { "i": x["i"] * y["i"], "j": ( x["i"] * 2, [x["j"][1][0] * y["j"][0][0]], [{"o": x["j"][2][0]["o"] + y["j"][1][0]["o"]}], ), }, ( y["i"] * 2, { "o": x["i"] * y["i"] + x["j"][0][0], "j": ( [x["j"][1][0] * y["j"][0][0]], [{"o": x["j"][2][0]["o"] + y["j"][1][0]["o"]}], ), }, ), ) scan_fct = compile_mode_helper(scan, compile_mode) x = torch.randn(3, 2, 2, device=device, requires_grad=autograd) y = torch.randn(3, 2, 2, device=device, requires_grad=autograd) z = torch.randn(3, 2, 2, device=device, requires_grad=autograd) if reverse: init_start, init_end = -1, None inp_start, inp_end = 0, -1 else: init_start, init_end = 0, 1 inp_start, inp_end = 1, None # Regular case init = { "i": torch._ops.ops.aten.slice(x, 0, init_start, init_end, 1), "j": ( [torch._ops.ops.aten.slice(y, 0, init_start, init_end, 1)], [{"o": torch._ops.ops.aten.slice(z, 0, init_start, init_end, 1)}], ), } inp = { "i": torch._ops.ops.aten.slice(x, 0, inp_start, inp_end, 1), "j": ( [torch._ops.ops.aten.slice(y, 0, inp_start, inp_end, 1)], [{"o": torch._ops.ops.aten.slice(z, 0, inp_start, inp_end, 1)}], ), } result = scan_fct( get_scan_combine_fn("complex_pointwise", False), init, inp, dim=0, reverse=reverse, ) expected_result = _fake_scan( get_scan_combine_fn("complex_pointwise", False), init, inp, dim=0, reverse=reverse, ) self.assertEqual(result, expected_result) if autograd: init_flat = pytree.tree_leaves(init) inp_flat = pytree.tree_leaves(inp) self.check_autograd(result, expected_result, (*init_flat, *inp_flat)) # Pytree of output is different result = scan_fct( fct_pointwise_different_output, init, inp, dim=0, reverse=reverse ) expected_result = _fake_scan( fct_pointwise_different_output, init=init, xs=inp, dim=0, reverse=reverse ) self.assertEqual(result, expected_result) # Pytree of carry is different init = { "i": torch._ops.ops.aten.slice(x, 0, init_start, init_end, 1), "j": ( torch._ops.ops.aten.slice(x, 0, init_start, init_end, 1), [torch._ops.ops.aten.slice(y, 0, init_start, init_end, 1)], [{"o": torch._ops.ops.aten.slice(z, 0, init_start, init_end, 1)}], ), } inp = { "i": torch._ops.ops.aten.slice(x, 0, inp_start, inp_end, 1), "j": ( [torch._ops.ops.aten.slice(y, 0, inp_start, inp_end, 1)], [{"o": torch._ops.ops.aten.slice(z, 0, inp_start, inp_end, 1)}], ), } result = scan_fct( fct_pointwise_different_carry, init, inp, dim=0, reverse=reverse ) expected_result = _fake_scan( fct_pointwise_different_carry, init=init, xs=inp, dim=0, reverse=reverse ) self.assertEqual(result, expected_result) if autograd: init_flat = pytree.tree_leaves(init) inp_flat = pytree.tree_leaves(inp) self.check_autograd(result, expected_result, (*init_flat, *inp_flat)) @skipIfTorchDynamo("don't test compile on compile") @skipIfNoDynamoSupport @skipIfCrossRef # Arg order changes with crossref def test_scan_pytree_output(self): from torch._dynamo.testing import EagerAndRecordGraphs x = torch.randn(3, 10, 2, device=torch.device("cpu")) init = torch.randn(1, 10, 2, device=torch.device("cpu")) def f(fct, init, xs): return scan(fct, init, xs, dim=0, reverse=True) def combine_fn(init, x): a, b = (init[0] + x, init[1] - x) return (a, b), a - b # Check graph backend = EagerAndRecordGraphs() torch.compile(f, backend=backend)(combine_fn, (init, init.clone()), x) gm = backend.graphs[0] self.assertExpectedInline( normalize_gm(gm.print_readable(print_output=False)), """\ class GraphModule(torch.nn.Module): def forward(self, L_init_0_: "f32[1, 10, 2]", L_init_1_: "f32[1, 10, 2]", L_xs_: "f32[3, 10, 2]"): l_init_0_ = L_init_0_ l_init_1_ = L_init_1_ l_xs_ = L_xs_ elem: "f32[3, 10, 2]" = torch.movedim(l_xs_, 0, 0); l_xs_ = None flip: "f32[3, 10, 2]" = torch.flip(elem, [0]); elem = None scan_combine_fn_0 = self.scan_combine_fn_0 scan = torch.ops.higher_order.scan(scan_combine_fn_0, [l_init_0_, l_init_1_], [flip], []); scan_combine_fn_0 = l_init_0_ = l_init_1_ = flip = None getitem: "f32[1, 10, 2]" = scan[0] getitem_1: "f32[1, 10, 2]" = scan[1] out: "f32[3, 1, 10, 2]" = scan[2]; scan = None out_1: "f32[3, 1, 10, 2]" = out.flip([0]); out = None return (getitem, getitem_1, out_1) class scan_combine_fn_0(torch.nn.Module): def forward(self, child: "f32[1, 10, 2]", child_1: "f32[1, 10, 2]", child_2: "f32[10, 2]"): a: "f32[1, 10, 2]" = child + child_2; child = None b: "f32[1, 10, 2]" = child_1 - child_2; child_1 = child_2 = None child_3: "f32[1, 10, 2]" = a - b return [a, b, child_3] """, # noqa: B950 ) @skipIfTorchDynamo("Graph is not captured by backend if test with dynamo") @unittest.skipIf(not SM70OrLater, "triton") @requires_cuda @parametrize("compile_mode", ["none", "eager"]) @parametrize("autograd", [False, True]) def test_scan_closure_RNN(self, compile_mode, autograd): dim = 1 device = torch.device("cpu") scan_fct = compile_mode_helper(scan, compile_mode) rnn = torch.nn.RNN( input_size=5, hidden_size=7, batch_first=True, ) rnn = rnn.to(device=device) x = torch.randn(3, 10, 5, device=device, requires_grad=autograd) h = torch.randn(3, 7, device=device, requires_grad=autograd) W_ih = rnn.weight_ih_l0.T.clone() b_ih = rnn.bias_ih_l0.clone() W_hh = rnn.weight_hh_l0.T.clone() b_hh = rnn.bias_hh_l0.clone() if not autograd: W_ih = W_ih.detach() b_ih = b_ih.detach() W_hh = W_hh.detach() b_hh = b_hh.detach() expected_result = rnn(x, torch.unsqueeze(h, 0)) expected_result_out = expected_result[0] expected_result_state = expected_result[1][0, :] result = scan_fct( get_scan_combine_fn("RNN", True, parameters=[W_ih, b_ih, W_hh, b_hh]), h, x, dim=dim, reverse=False, ) result_cmp = [result[0], torch.movedim(result[1], 0, dim)] self.assertEqual(result_cmp[0], expected_result_state) self.assertEqual(result_cmp[1], expected_result_out) if autograd: result_flat = pytree.tree_leaves(result) result_exp_flat = [expected_result_state, expected_result_out] grad_out_expected = [torch.ones_like(r) for r in result_exp_flat] expected_grads = torch.autograd.grad( result_exp_flat, ( h, x, rnn.weight_ih_l0, rnn.bias_ih_l0, rnn.weight_hh_l0, rnn.bias_hh_l0, ), grad_out_expected, ) expected_add_input_grads = list(expected_grads[2:]) expected_grads = expected_grads[:2] grad_out = [torch.ones_like(r) for r in result] grads = torch.autograd.grad( result_flat, (h, x, W_ih, b_ih, W_hh, b_hh), grad_out ) add_input_grads = list(grads[2:]) add_input_grads[0] = add_input_grads[0].T add_input_grads[2] = add_input_grads[2].T grads = grads[:2] self.assertEqual(grads, expected_grads) self.assertEqual(add_input_grads, expected_add_input_grads) @unittest.skipIf(not SM70OrLater, "triton") @requires_cuda @parametrize("reverse", [False, True]) @parametrize("compile_mode", ["none", "eager"]) @parametrize( "partial_grad", ["xs", "init", "additional_inputs", "complex", "random"] ) @parametrize("device", [torch.device("cpu"), torch.device("cuda")]) def test_scan_closure_RNN_partial_autograd( self, reverse, compile_mode, partial_grad, device ): dim = 1 scan_fct = compile_mode_helper(scan, compile_mode) # The first two booleans are the xs # The second two are the inits # The last four are the additional_inputs autograds = [] if partial_grad == "xs": # xs tests autograds.append([True, False, True, True, True, True, True, True]) autograds.append([False, False, True, True, True, True, True, True]) elif partial_grad == "init": # init tests autograds.append([True, True, False, True, True, True, True, True]) autograds.append([True, True, False, False, True, True, True, True]) elif partial_grad == "additional_inputs": # additional input tests autograds.append([True, True, True, True, False, True, False, True]) autograds.append([True, True, True, True, False, False, False, False]) elif partial_grad == "complex": # complex cases autograds.append([True, False, False, False, False, False, False, True]) autograds.append([False, False, True, True, False, False, False, True]) elif partial_grad == "random": # random tests import random for _ in range(5): autograds.append([bool(random.randint(0, 1)) for _ in range(8)]) for autograd in autograds: x = torch.randn(3, 10, 5, device=device, requires_grad=autograd[0]) x1 = torch.randn(3, 10, 5, device=device, requires_grad=autograd[1]) h = torch.randn(3, 7, device=device, requires_grad=autograd[2]) h_1 = torch.randn(3, 7, device=device, requires_grad=autograd[3]) W_ih = torch.randn(5, 7, device=device, requires_grad=autograd[4]) b_ih = torch.randn(7, device=device, requires_grad=autograd[5]) W_hh = torch.randn(7, 7, device=device, requires_grad=autograd[6]) b_hh = torch.randn(7, device=device, requires_grad=autograd[7]) params = [ p for p, a in zip([x, x1, h, h_1, W_ih, b_ih, W_hh, b_hh], autograd) if a ] def RNN(x: torch.Tensor, y: torch.Tensor): c_new_0 = x[0] + 1 c_new_1 = x[1] + 1 h_new = ( torch.tanh(c_new_1 + x[0] @ W_hh + b_hh) + y[0] @ W_ih + y[1] @ W_ih + b_ih + x[1] ) return (c_new_0, c_new_1), h_new inits = (h, h_1) result = scan_fct(RNN, inits, (x, x1), dim=dim, reverse=reverse) result_exp = _fake_scan(RNN, (h, h_1), (x, x1), dim=dim, reverse=reverse) self.assertEqual(result, result_exp) if autograd: result_flat = pytree.tree_leaves(result) result_exp_flat = pytree.tree_leaves(result_exp) exp_grad_mask = [ True if r.requires_grad else False for r in result_exp_flat ] self.check_autograd( [r for r, m in zip(result_flat, exp_grad_mask) if m], [r for r, m in zip(result_exp_flat, exp_grad_mask) if m], params, ) @unittest.skipIf(not SM70OrLater, "triton") @requires_cuda @parametrize("reverse", [False, True]) @parametrize("compile_mode", ["none", "eager"]) @parametrize("device", [torch.device("cpu"), torch.device("cuda")]) @parametrize("autograd", [False, True]) def test_scan_closure_combine_fn_with_no_grad_init_carries_unequal_grad( self, reverse, compile_mode, device, autograd ): dim = 1 scan_fct = compile_mode_helper(scan, compile_mode) x = torch.randn(3, 10, 7, device=device, requires_grad=autograd) h1 = torch.randn(3, 7, device=device, requires_grad=autograd) h2 = torch.randn(3, 7, device=device, requires_grad=autograd) result = scan_fct( get_scan_combine_fn("fct_c1_no_grad", True), (h1, h2), x, dim=dim, reverse=reverse, ) result_exp = _fake_scan( get_scan_combine_fn("fct_c1_no_grad", True), (h1, h2), x, dim=dim, reverse=reverse, ) self.assertEqual(result, result_exp) if autograd: # TODO: Ideally we should be able to select the results that require gradients like this # [leaf for leaf in pytree.tree_leaves(result) if leaf.requires_grad == True] # However, for the scan operator this does not work, as all outputs always have # grad_fn= res_req_grad_flat = pytree.tree_leaves(result)[1:] res_exp_req_grad_flat = pytree.tree_leaves(result_exp)[1:] self.check_autograd(res_req_grad_flat, res_exp_req_grad_flat, (x, h2)) @unittest.skipIf(not SM70OrLater, "triton") @requires_cuda @parametrize("reverse", [False, True]) @parametrize("compile_mode", ["none", "eager"]) @parametrize("device", [torch.device("cpu"), torch.device("cuda")]) @parametrize("autograd", [False, True]) def test_scan_closure_combine_fn_with_no_grad_init_carries_equal_grad( self, reverse, compile_mode, device, autograd ): dim = 1 scan_fct = compile_mode_helper(scan, compile_mode) x = torch.randn(3, 10, 7, device=device, requires_grad=autograd) h1 = torch.randn(3, 7, device=device, requires_grad=False) h2 = torch.randn(3, 7, device=device, requires_grad=autograd) result = scan_fct( get_scan_combine_fn("fct_c1_no_grad", True), (h1, h2), x, dim=dim, reverse=reverse, ) result_exp = _fake_scan( get_scan_combine_fn("fct_c1_no_grad", True), (h1, h2), x, dim=dim, reverse=reverse, ) self.assertEqual(result, result_exp) if autograd: # TODO: Ideally we should be able to select the results that require gradients like this # [leaf for leaf in pytree.tree_leaves(result) if leaf.requires_grad == True] # However, for the scan operator this does not work, as all outputs always have # grad_fn= res_req_grad_flat = pytree.tree_leaves(result)[1:] res_exp_req_grad_flat = pytree.tree_leaves(result_exp)[1:] self.check_autograd(res_req_grad_flat, res_exp_req_grad_flat, (x, h2)) @unittest.skipIf(not SM70OrLater, "triton") @requires_cuda @parametrize("reverse", [False, True]) @parametrize("compile_mode", ["none", "eager"]) @parametrize("device", [torch.device("cpu"), torch.device("cuda")]) @parametrize("autograd", [False, True]) def test_scan_closure_combine_fn_with_no_grad_for_out( self, reverse, compile_mode, device, autograd ): dim = 1 scan_fct = compile_mode_helper(scan, compile_mode) x = torch.randn(3, 10, 7, device=device, requires_grad=autograd) h1 = torch.randn(3, 7, device=device, requires_grad=autograd) h2 = torch.randn(3, 7, device=device, requires_grad=autograd) def fct_ys_no_grad(x: torch.Tensor, y: torch.Tensor): c1 = x[0] + y c2 = x[1] + y with torch.no_grad(): h_new = torch.tanh(x[0] + x[1] + y) return (c1, c2), h_new result = scan_fct(fct_ys_no_grad, (h1, h2), x, dim=dim, reverse=reverse) result_exp = _fake_scan(fct_ys_no_grad, (h1, h2), x, dim=dim, reverse=reverse) self.assertEqual(result, result_exp) if autograd: self.check_autograd(result[0], result_exp[0], (x, h1, h2)) @unittest.skipIf(not SM70OrLater, "triton") @requires_cuda @parametrize("reverse", [False, True]) @parametrize("compile_mode", ["none", "eager"]) @parametrize("device", [torch.device("cpu"), torch.device("cuda")]) @parametrize("autograd", [False, True]) def test_scan_closure_combine_fn_with_no_grad_additional_inputs_partial( self, reverse, compile_mode, device, autograd ): dim = 1 scan_fct = compile_mode_helper(scan, compile_mode) x = torch.randn(3, 10, 7, device=device, requires_grad=autograd) h = torch.randn(3, 7, device=device, requires_grad=autograd) W_ih = torch.randn(7, 7, device=device, requires_grad=autograd) b_ih = torch.randn(7, device=device, requires_grad=autograd) W_hh = torch.randn(7, 7, device=device, requires_grad=autograd) b_hh = torch.randn(7, device=device, requires_grad=autograd) def fct_no_grad_bhh_Whh(x: torch.Tensor, y: torch.Tensor): c_new = y @ W_ih + b_ih + x h_new = c_new + 1 with torch.no_grad(): h_new_no_grad = torch.tanh(x @ W_hh + b_hh) h_new2 = h_new + h_new_no_grad return c_new, h_new2 result = scan_fct(fct_no_grad_bhh_Whh, h, x, dim=dim, reverse=reverse) result_exp = _fake_scan(fct_no_grad_bhh_Whh, h, x, dim=dim, reverse=reverse) self.assertEqual(result, result_exp) if autograd: self.check_autograd(result[1], result_exp[1], (h, x, W_ih, b_ih)) @unittest.skipIf(not SM70OrLater, "triton") @requires_cuda @parametrize("reverse", [False, True]) @parametrize("compile_mode", ["none", "eager"]) @parametrize("device", [torch.device("cpu"), torch.device("cuda")]) @parametrize("autograd", [False, True]) def test_scan_closure_combine_fn_with_no_grad_additional_inputs_all( self, reverse, compile_mode, device, autograd ): dim = 1 scan_fct = compile_mode_helper(scan, compile_mode) x = torch.randn(3, 10, 7, device=device, requires_grad=autograd) h = torch.randn(3, 7, device=device, requires_grad=autograd) W_ih = torch.randn(7, 7, device=device, requires_grad=autograd) b_ih = torch.randn(7, device=device, requires_grad=autograd) W_hh = torch.randn(7, 7, device=device, requires_grad=autograd) b_hh = torch.randn(7, device=device, requires_grad=autograd) def fct_no_grad_bih_Wih_bhh_Whh(x: torch.Tensor, y: torch.Tensor): c_new = x + y h_new = c_new + x with torch.no_grad(): c_new_no_grad = y @ W_ih + b_ih h_new_no_grad = torch.tanh(x @ W_hh + b_hh) c_new2 = c_new + c_new_no_grad h_new2 = h_new + h_new_no_grad return c_new2, h_new2 result = scan_fct(fct_no_grad_bih_Wih_bhh_Whh, h, x, dim=dim, reverse=reverse) result_exp = _fake_scan( fct_no_grad_bih_Wih_bhh_Whh, h, x, dim=dim, reverse=reverse ) self.assertEqual(result, result_exp) if autograd: self.check_autograd(result[1], result_exp[1], (h, x)) @unittest.skipIf(not SM70OrLater, "triton") @requires_cuda @parametrize("reverse", [False, True]) @parametrize("compile_mode", ["none", "eager"]) @parametrize("device", [torch.device("cpu"), torch.device("cuda")]) @parametrize("autograd", [False, True]) def test_scan_closure_combine_fn_carries_ys_same_grad( self, reverse, compile_mode, device, autograd ): dim = 1 scan_fct = compile_mode_helper(scan, compile_mode) x = torch.randn(3, 10, 7, device=device, requires_grad=autograd) h = torch.randn(3, 7, device=device, requires_grad=autograd) W_ih = torch.randn(7, 7, device=device, requires_grad=autograd) b_ih = torch.randn(7, device=device, requires_grad=autograd) W_hh = torch.randn(7, 7, device=device, requires_grad=autograd) b_hh = torch.randn(7, device=device, requires_grad=autograd) def fct_no_grad_bih_Wih_bhh_Whh(x: torch.Tensor, y: torch.Tensor): c_new = x + y h_new = c_new + 1 with torch.no_grad(): c_new_no_grad = y @ W_ih + b_ih h_new_no_grad = torch.tanh(x @ W_hh + b_hh) c_new2 = c_new + c_new_no_grad h_new2 = h_new + h_new_no_grad return c_new2, h_new2 result = scan_fct(fct_no_grad_bih_Wih_bhh_Whh, h, x, dim=dim, reverse=reverse) result_exp = _fake_scan( fct_no_grad_bih_Wih_bhh_Whh, h, x, dim=dim, reverse=reverse ) self.assertEqual(result, result_exp) if autograd: self.check_autograd(result[1], result_exp[1], (h, x)) @unittest.skipIf(not SM70OrLater, "triton") @requires_cuda @parametrize("reverse", [False, True]) @parametrize("compile_mode", ["none", "eager"]) @parametrize("device", [torch.device("cpu"), torch.device("cuda")]) @parametrize("autograd", [False, True]) def test_scan_closure_nested(self, reverse, compile_mode, device, autograd): scan_fct = compile_mode_helper(scan, compile_mode) # Simple non-nested case x = torch.randn(3, 20, 5, device=device, requires_grad=autograd) h = torch.randn(3, 7, device=device, requires_grad=autograd) W = torch.randn(5, 7, device=device, requires_grad=autograd) b = torch.randn(7, device=device, requires_grad=autograd) def f1(x: torch.Tensor, y: torch.Tensor): c_new = y @ W + b h_new = torch.tanh(c_new + x) return c_new, h_new result = scan_fct(f1, h, x, dim=1, reverse=reverse) result_exp = _fake_scan(f1, h, x, dim=1, reverse=reverse) self.assertEqual(result, result_exp) if autograd: self.check_autograd(result, result_exp, (h, x, W, b)) # Nested case def chain_fct(fct, f_1, f_2, xs, h_1, h_2): o1 = fct( f_1, h_1, xs, dim=1, reverse=reverse, ) o2 = fct( f_2, h_2, o1[1], dim=0, reverse=reverse, ) return o2 x1 = torch.ones(3, 20, 5, device=device, requires_grad=autograd) h1 = torch.zeros(3, 7, device=device, requires_grad=autograd) h2 = torch.zeros(3, 3, device=device, requires_grad=autograd) W_1 = torch.randn(5, 7, device=device, requires_grad=autograd) b_1 = torch.randn(7, device=device, requires_grad=autograd) W_2 = torch.randn(7, 3, device=device, requires_grad=autograd) b_2 = torch.randn(3, device=device, requires_grad=autograd) def f1(x: torch.Tensor, y: torch.Tensor): c_new = y @ W_1 + b_1 h_new = torch.tanh(c_new + x) return c_new, h_new def f2(x: torch.Tensor, y: torch.Tensor): c_new = y @ W_2 + b_2 h_new = torch.tanh(c_new + x) return c_new, h_new result1 = chain_fct(scan_fct, f1, f2, x1, h1, h2) expected_result = chain_fct(_fake_scan, f1, f2, x1, h1, h2) self.assertEqual(result1, expected_result) if autograd: self.check_autograd(result1, expected_result, (h1, h2, x1, W_1, b_1)) # Complex case x1 = torch.randn(3, 20, 3, device=device, requires_grad=autograd) h1 = torch.randn(3, 3, device=device, requires_grad=autograd) h2 = torch.randn(3, 3, device=device, requires_grad=autograd) W_1 = torch.randn(3, 3, device=device, requires_grad=autograd) b_1 = torch.randn(3, device=device, requires_grad=autograd) W_2 = torch.randn(3, 3, device=device, requires_grad=autograd) b_2 = torch.randn(3, device=device, requires_grad=autograd) def f1(x: torch.Tensor, y: torch.Tensor): c_new = y @ W_1 + b_1 h_new = torch.tanh(c_new + x) return c_new, h_new def f2(x: torch.Tensor, y: torch.Tensor): c_new = y @ W_2 + b_2 * b_1 + y @ W_1 h_new = torch.tanh(c_new + x) return c_new, h_new result1 = chain_fct(scan_fct, f1, f2, x1, h1, h2) expected_result = chain_fct(_fake_scan, f1, f2, x1, h1, h2) self.assertEqual(result1, expected_result) if autograd: self.check_autograd( result1, expected_result, (h1, h2, x1, W_1, b_1, W_2, b_2) ) @skipIfNoDynamoSupport def test_scan_simple_graph_wrong_dtype(self): def add_wrong_dtype(x: torch.Tensor, y: torch.Tensor): return torch.ones_like(x + y, dtype=torch.int64), x + y x = torch.randn(3, 10, 2, device=torch.device("cpu")) init = torch.randn(1, 10, 2, device=torch.device("cpu")) def f(fct, init, xs): return scan(fct, init, xs, dim=0, reverse=True) # Wrong dtype with self.assertRaisesRegex( torch._dynamo.exc.UncapturedHigherOrderOpError, "Expected init and carry to have same metadata.*", ): f(add_wrong_dtype, init, x) @skipIfNoDynamoSupport @skipIfCrossRef # Arg order changes with crossref def test_scan_simple_graph(self): from torch._dynamo.testing import EagerAndRecordGraphs x = torch.randn(3, 10, 2, device=torch.device("cpu")) init = torch.randn(1, 10, 2, device=torch.device("cpu")) def f(fct, init, xs): return scan(fct, init, xs, dim=0, reverse=True) # Correct case gm = make_fx(f, tracing_mode="symbolic")( get_scan_combine_fn("add", False), init, x ) self.assertExpectedInline( gm.code.strip(), """\ def forward(self, fct_1, init_1, xs_1): permute = torch.ops.aten.permute.default(xs_1, [0, 1, 2]) flip = torch.ops.aten.flip.default(permute, [0]); permute = None sym_size_int_1 = torch.ops.aten.sym_size.int(init_1, 1) sym_size_int_2 = torch.ops.aten.sym_size.int(init_1, 2) sym_size_int_3 = torch.ops.aten.sym_size.int(xs_1, 1) sym_size_int_4 = torch.ops.aten.sym_size.int(xs_1, 2); xs_1 = None scan_combine_graph_0 = self.scan_combine_graph_0 scan = torch.ops.higher_order.scan(scan_combine_graph_0, [init_1], [flip], (sym_size_int_1, sym_size_int_2, sym_size_int_3, sym_size_int_4)); scan_combine_graph_0 = init_1 = flip = sym_size_int_1 = sym_size_int_2 = sym_size_int_3 = sym_size_int_4 = None getitem = scan[0] getitem_1 = scan[1]; scan = None flip_1 = torch.ops.aten.flip.default(getitem_1, [0]); getitem_1 = None return (getitem, flip_1)""", # noqa: B950 ) # Check graph backend = EagerAndRecordGraphs() torch.compile(f, backend=backend)(get_scan_combine_fn("add", False), init, x) gm = backend.graphs[0] self.assertExpectedInline( gm.code.strip(), """\ def forward(self, L_init_ : torch.Tensor, L_xs_ : torch.Tensor): l_init_ = L_init_ l_xs_ = L_xs_ elem = torch.movedim(l_xs_, 0, 0); l_xs_ = None flip = torch.flip(elem, [0]); elem = None scan_combine_fn_0 = self.scan_combine_fn_0 scan = torch.ops.higher_order.scan(scan_combine_fn_0, [l_init_], [flip], []); scan_combine_fn_0 = l_init_ = flip = None carry = scan[0] out = scan[1]; scan = None out_1 = out.flip([0]); out = None return (carry, out_1)""", # noqa: B950 ) @requires_cuda def test_scan_input_mutation(self): device = torch.device("cuda") def fct_input_mutation(x, y): x.add_(1) return x + y, x + y + 2 x = torch.randn(3, 2, 2, device=device) init = torch.randn(2, 2, device=device) with self.assertRaisesRegex( # Should be # torch._dynamo.exc.Unsupported, # "Encountered aliasing during higher order op tracing for HOP.*" torch._dynamo.exc.UncapturedHigherOrderOpError, "scan must be captured completely with torch.compile.*", ): scan(fct_input_mutation, init, x, dim=0) @requires_cuda def test_scan_input_carry_alias(self): device = torch.device("cuda") def fct_input_output_alias(x, y): return (x[0], x[1] + y[1]), (x[1] + y[1] + 1, x[1] + y[1] + 2) x = torch.randn(3, 2, 2, device=device) y = torch.randn(3, 2, 2, device=device) inp = (x, y) init = (torch.randn(2, 2, device=device), torch.randn(2, 2, device=device)) with self.assertRaisesRegex( # Should be # torch._dynamo.exc.Unsupported, # "Encountered aliasing during higher order op tracing for HOP.*" torch._dynamo.exc.UncapturedHigherOrderOpError, "scan must be captured completely with torch.compile.*", ): scan(fct_input_output_alias, init, inp, dim=0) @requires_cuda def test_scan_input_output_alias(self): device = torch.device("cuda") def fct_input_output_alias(x, y): return (x[0] + 1, x[1] + y[1]), (x[1], x[1] + y[1] + 2) x = torch.randn(3, 2, 2, device=device) y = torch.randn(3, 2, 2, device=device) inp = (x, y) init = (torch.randn(2, 2, device=device), torch.randn(2, 2, device=device)) with self.assertRaisesRegex( # Should be # torch._dynamo.exc.Unsupported, # "Encountered aliasing during higher order op tracing for HOP.*" torch._dynamo.exc.UncapturedHigherOrderOpError, "scan must be captured completely with torch.compile.*", ): scan(fct_input_output_alias, init, inp, dim=0) @unittest.skipIf(not SM70OrLater, "triton") @requires_cuda def test_scan_carry_carry_alias(self): device = torch.device("cuda") def fct_carry_carry_alias(x, y): c = x[0] + y[1] return (c, c), (x[0] + y[1], x[0] + y[1] + 1) x = torch.randn(3, 2, 2, device=device) y = torch.randn(3, 2, 2, device=device) inp = (x, y) init = (torch.randn(2, 2, device=device), torch.randn(2, 2, device=device)) with self.assertRaisesRegex( # Should be # torch._dynamo.exc.Unsupported, # "Encountered aliasing during higher order op tracing for HOP.*" torch._dynamo.exc.UncapturedHigherOrderOpError, "scan must be captured completely with torch.compile.*", ): scan(fct_carry_carry_alias, init, inp, dim=0) @unittest.skipIf(not SM70OrLater, "triton") @requires_cuda def test_scan_carry_output_alias(self): device = torch.device("cuda") def fct_carry_output_alias(x, y): c = x[0] + y[1] return (x[0] + y[1], c), (c, x[0] + y[1] + 1) x = torch.randn(3, 2, 2, device=device) y = torch.randn(3, 2, 2, device=device) inp = (x, y) init = (torch.randn(2, 2, device=device), torch.randn(2, 2, device=device)) with self.assertRaisesRegex( # Should be # torch._dynamo.exc.Unsupported, # "Encountered aliasing during higher order op tracing for HOP.*" torch._dynamo.exc.UncapturedHigherOrderOpError, "scan must be captured completely with torch.compile.*", ): scan(fct_carry_output_alias, init, inp, dim=0) class AssociativeScanModels: @staticmethod def get_scan_fct(compile_mode, combine_mode): # Compile the associative_scan according to the provided compile_mode if compile_mode != "fake": assoc_scan_comp = compile_mode_helper(associative_scan, compile_mode) def scan_fct(combine_fn, xs, dim, reverse): return assoc_scan_comp(combine_fn, xs, dim, reverse, combine_mode) else: scan_fct = _fake_associative_scan return scan_fct class CombineFn(torch.nn.Module): def __init__(self, combine_fn, dim, reverse, combine_mode, compile_mode): super().__init__() self.scan_fct = AssociativeScanModels.get_scan_fct( compile_mode, combine_mode ) self.combine_fn = combine_fn self.dim = dim self.reverse = reverse def forward(self, inputs): results = self.scan_fct(self.combine_fn, inputs, self.dim, self.reverse) return results class Simple(torch.nn.Module): def __init__(self, dim, reverse, combine_mode, compile_mode): super().__init__() kwargs = { "dim": dim, "reverse": reverse, "combine_mode": combine_mode, "compile_mode": compile_mode, } self.combine_fns = [ AssociativeScanModels.CombineFn( get_scan_combine_fn("add", True), **kwargs ), AssociativeScanModels.CombineFn( get_scan_combine_fn("mul", True), **kwargs ), ] def forward(self, inputs): results = [] for combine_fn in self.combine_fns: results.append(combine_fn(inputs)) return results class ChainFn(torch.nn.Module): def __init__(self, combine_fn, dim, reverse, combine_mode, compile_mode): super().__init__() chain_len = len(combine_fn) kwargs = { "combine_fn": combine_fn, "dim": dim, "reverse": reverse, "combine_mode": combine_mode, } # Prepare the kwargs as a list. self.nested_tuple = [] for ind in range(chain_len): kwargs_el = {} for key, val in kwargs.items(): # Check if val is a list and if it has the same length as combine_fn # If so, then use the individual elements. # If not, duplicate the first element. if type(val) == list and len(val) == chain_len: kwargs_el[key] = val[ind] else: kwargs_el[key] = val scan_fct = AssociativeScanModels.get_scan_fct( compile_mode, kwargs_el["combine_mode"] ) combine_fn = kwargs_el["combine_fn"] del kwargs_el["combine_fn"] del kwargs_el["combine_mode"] self.nested_tuple.append((combine_fn, scan_fct, kwargs_el)) def forward(self, inputs): results = inputs for combine_fn, scan_fct, kwargs in self.nested_tuple: results = combine_fn(scan_fct, results, **kwargs) return results class NestedFn(torch.nn.Module): def forward(self, scan_fct, inputs, **kwargs): combine_fn = kwargs["combine_fn"] # Remove combine_fn from kwargs del kwargs["combine_fn"] results = scan_fct(combine_fn, inputs, **kwargs) return results @unittest.skipIf(IS_WINDOWS, "Windows not supported for this test") @skipIfNoDynamoSupport class AssociativeScanTests(TestCase): def setUp(self): torch._dynamo.reset() super().setUp() def _run_test(self, model, model_fake, inputs): result = model(inputs) result_exp = model_fake(inputs) self.assertEqual(result, result_exp) # Return the result of the functions under test for further investigations return result def _prepare_fake_kwargs(self, original_kwargs): kwargs_fake = original_kwargs.copy() kwargs_fake["compile_mode"] = "fake" return kwargs_fake @unittest.skipIf(not SM70OrLater, "triton") @requires_cuda @parametrize("reverse", [False, True]) @parametrize("compile_mode", ["none", "eager", "compile", "compile_dynamic_shape"]) @parametrize("combine_mode", ["pointwise", "generic"]) @parametrize("device", [torch.device("cpu"), torch.device("cuda")]) # Skipping the combination of combine_mode=pointwise and device=cpu # as the current implementation of pointwise does only support CUDA device # Skipping the combination of combine_mode=pointwise and compile_mode=compile_dynamic_shape # as the current implementation does not support lifted arguments @decorateIf( unittest.skip, lambda params: ( params["combine_mode"] == "pointwise" and ( params["device"] == torch.device("cpu") or params["compile_mode"] == "compile_dynamic_shape" or torch.version.hip ) ), ) def test_associative_scan_compile( self, combine_mode, reverse, compile_mode, device ): x = torch.randn(3, 10, 2, device=device) kwargs = { "dim": 0, "reverse": reverse, "compile_mode": compile_mode, "combine_mode": combine_mode, } kwargs_fake = self._prepare_fake_kwargs(kwargs) results = self._run_test( model=AssociativeScanModels.Simple(**kwargs), model_fake=AssociativeScanModels.Simple(**kwargs_fake), inputs=x, ) if not reverse: results_torch = [] for op_pt in [torch.cumsum, torch.cumprod]: results_torch.append(op_pt(x, 0)) self.assertEqual(results, results_torch) # Jax Examples x = torch.arange(0, 4, device=device) kwargs = { "dim": 0, "reverse": reverse, "compile_mode": compile_mode, "combine_fn": get_scan_combine_fn("add", True), "combine_mode": combine_mode, } kwargs_fake = self._prepare_fake_kwargs(kwargs) result = self._run_test( model=AssociativeScanModels.CombineFn(**kwargs), model_fake=AssociativeScanModels.CombineFn(**kwargs_fake), inputs=x, ) if not reverse: results_torch = torch.tensor([0.0, 1.0, 3.0, 6.0], dtype=torch.int64) else: results_torch = torch.tensor([6.0, 6.0, 5.0, 3.0], dtype=torch.int64) self.assertEqual(result, results_torch) @unittest.skipIf(not SM70OrLater, "triton") @requires_cuda @parametrize("reverse", [False, True]) @parametrize("compile_mode", ["none", "eager", "compile", "compile_dynamic_shape"]) @parametrize("combine_mode", ["pointwise", "generic"]) @parametrize("device", [torch.device("cpu"), torch.device("cuda")]) # Skipping the combination of combine_mode=pointwise and device=cpu # as the current implementation of pointwise does only support CUDA device # Skipping the combination of combine_mode=pointwise and compile_mode=compile_dynamic_shape # as the current implementation does not support lifted arguments @decorateIf( unittest.skip, lambda params: ( params["combine_mode"] == "pointwise" and ( params["device"] == torch.device("cpu") or params["compile_mode"] == "compile_dynamic_shape" or torch.version.hip ) ), ) def test_associative_scan_dim(self, combine_mode, compile_mode, reverse, device): import random random.seed(1234) num_dims = [random.randint(2, 5) for _ in range(4)] for num_dim in num_dims: # To avoid triggering automatic dynamic shape torch._dynamo.reset() shapes = [random.randint(1, 9) for _ in range(num_dim)] rnd_scan_dim = random.randint(0, num_dim - 1) x = torch.randn(*shapes, device=device) kwargs = { "dim": rnd_scan_dim, "reverse": reverse, "compile_mode": compile_mode, "combine_mode": combine_mode, } kwargs_fake = self._prepare_fake_kwargs(kwargs) results = self._run_test( model=AssociativeScanModels.Simple(**kwargs), model_fake=AssociativeScanModels.Simple(**kwargs_fake), inputs=x, ) if not reverse: results_torch = [] for op_pt in [torch.cumsum, torch.cumprod]: results_torch.append(op_pt(x, 0)) self.assertEqual(results, results_torch) @unittest.skipIf(not SM70OrLater, "triton") @requires_cuda @unittest.expectedFailure def test_associative_scan_dim_shape_failure(self, compile_mode, combine_mode): num_dims = [2] for num_dim in num_dims: shapes = [9 for _ in range(num_dim)] rnd_scan_dim = 0 x = torch.randn(*shapes, device=torch.device("cuda")) kwargs = { "dim": rnd_scan_dim, "reverse": True, "compile_mode": "compile", "combine_mode": "generic", } kwargs_fake = self._prepare_fake_kwargs(kwargs) self._run_test( model=AssociativeScanModels.Simple(**kwargs), model_fake=AssociativeScanModels.Simple(**kwargs_fake), inputs=x, ) @skipIfRocm(msg="Unsupported on ROCM yet") @unittest.skipIf(not SM70OrLater, "triton") @requires_cuda @parametrize("compile_mode", ["none", "eager", "compile", "compile_dynamic_shape"]) @parametrize("combine_mode", ["pointwise", "generic"]) @parametrize("reverse", [False, True]) @parametrize("device", [torch.device("cpu"), torch.device("cuda")]) # Skipping the combination of combine_mode=pointwise and device=cpu # as the current implementation of pointwise does only support CUDA device # Skipping the combination of combine_mode=pointwise and compile_mode=compile_dynamic_shape # as the current implementation does not support lifted arguments @decorateIf( unittest.skip, lambda params: ( params["combine_mode"] == "pointwise" and ( params["device"] == torch.device("cpu") or params["compile_mode"] == "compile_dynamic_shape" or torch.version.hip ) ), ) def test_associative_scan_tuple(self, compile_mode, combine_mode, reverse, device): x = torch.randn(3, 2, 2, device=device) y = torch.randn(3, 2, 2, device=device) inp = (x, y) kwargs = { "dim": 0, "reverse": reverse, "compile_mode": compile_mode, "combine_fn": get_scan_combine_fn("tuple_fct", True), "combine_mode": combine_mode, } kwargs_fake = self._prepare_fake_kwargs(kwargs) self._run_test( model=AssociativeScanModels.CombineFn(**kwargs), model_fake=AssociativeScanModels.CombineFn(**kwargs_fake), inputs=inp, ) @unittest.skipIf(not SM70OrLater, "triton") @requires_cuda @parametrize("compile_mode", ["none", "eager", "compile", "compile_dynamic_shape"]) @parametrize("combine_mode", ["pointwise", "generic"]) @parametrize("reverse", [False, True]) @parametrize("device", [torch.device("cpu"), torch.device("cuda")]) def test_associative_scan_expand_in_combine_fn( self, compile_mode, combine_mode, reverse, device ): x = torch.randn(3, 2, 2, device=device) def combine_fn(x, y): return x * torch.sum(y, -1).expand(x.shape) kwargs = { "dim": 0, "reverse": reverse, "compile_mode": compile_mode, "combine_fn": combine_fn, "combine_mode": "generic", } kwargs_fake = self._prepare_fake_kwargs(kwargs) self._run_test( model=AssociativeScanModels.CombineFn(**kwargs), model_fake=AssociativeScanModels.CombineFn(**kwargs_fake), inputs=x, ) @unittest.skipIf(not SM70OrLater, "triton") @requires_cuda @parametrize("compile_mode", ["none", "eager", "compile", "compile_dynamic_shape"]) @parametrize("reverse", [False, True]) @parametrize("device", [torch.device("cpu"), torch.device("cuda")]) def test_associative_scan_non_contiguous_tensor( self, compile_mode, reverse, device ): x = torch.arange(30, device=device).view(10, 3).t() assert not x.is_contiguous() kwargs = { "dim": 0, "reverse": reverse, "compile_mode": compile_mode, "combine_fn": get_scan_combine_fn("add", True), "combine_mode": "generic", } kwargs_fake = self._prepare_fake_kwargs(kwargs) self._run_test( model=AssociativeScanModels.CombineFn(**kwargs), model_fake=AssociativeScanModels.CombineFn(**kwargs_fake), inputs=x, ) @unittest.skipIf(not SM70OrLater, "triton") @requires_cuda @parametrize("compile_mode", ["none", "eager", "compile", "compile_dynamic_shape"]) @parametrize("combine_mode", ["pointwise", "generic"]) @parametrize("reverse", [False, True]) @parametrize("device", [torch.device("cpu"), torch.device("cuda")]) # Skipping the combination of combine_mode=pointwise and device=cpu # as the current implementation of pointwise does only support CUDA device # Skipping the combination of combine_mode=pointwise and compile_mode=compile_dynamic_shape # as the current implementation does not support lifted arguments @decorateIf( unittest.skip, lambda params: ( params["combine_mode"] == "pointwise" and ( params["device"] == torch.device("cpu") or params["compile_mode"] == "compile_dynamic_shape" or torch.version.hip ) ), ) def test_associative_scan_complex_pytree( self, compile_mode, combine_mode, reverse, device ): x = torch.randn(3, 2, 2, device=device) y = torch.randn(3, 2, 2, device=device) z = torch.randn(3, 2, 2, device=device) inp = {"i": x, "j": ([y], [{"o": z}])} kwargs = { "dim": 0, "reverse": reverse, "compile_mode": compile_mode, "combine_fn": get_scan_combine_fn("complex_pointwise", True), "combine_mode": combine_mode, } kwargs_fake = self._prepare_fake_kwargs(kwargs) self._run_test( model=AssociativeScanModels.CombineFn(**kwargs), model_fake=AssociativeScanModels.CombineFn(**kwargs_fake), inputs=inp, ) @skipIfTorchDynamo("don't test compile on compile") @skipIfNoDynamoSupport @skipIfCrossRef # Arg order changes with crossref def test_associative_scan_pytree_output(self): from torch._dynamo.testing import EagerAndRecordGraphs x = ( ( torch.randn(3, 10, 2, device=torch.device("cpu")), (torch.randn(3, 10, 2, device=torch.device("cpu")),), ), torch.randn(3, 10, 2, device=torch.device("cpu")), ) def f(fct, xs): return associative_scan( fct, xs, dim=0, reverse=True, combine_mode="generic" ) def combine_fn(x: torch.Tensor, y: torch.Tensor): a, b = (x[0][0] + y[1], x[0][1][0] - y[1]) return (a, (b,)), a - b # Check graph backend = EagerAndRecordGraphs() torch.compile(f, backend=backend)(combine_fn, x) gm = backend.graphs[0] self.assertExpectedInline( normalize_gm(gm.print_readable(print_output=False)), """\ class GraphModule(torch.nn.Module): def forward(self, L_xs_0_0_: "f32[3, 10, 2]", L_xs_0_1_0_: "f32[3, 10, 2]", L_xs_1_: "f32[3, 10, 2]"): l_xs_0_0_ = L_xs_0_0_ l_xs_0_1_0_ = L_xs_0_1_0_ l_xs_1_ = L_xs_1_ elem: "f32[3, 10, 2]" = torch.movedim(l_xs_0_0_, 0, 0); l_xs_0_0_ = None elem_1: "f32[3, 10, 2]" = torch.movedim(l_xs_0_1_0_, 0, 0); l_xs_0_1_0_ = None elem_2: "f32[3, 10, 2]" = torch.movedim(l_xs_1_, 0, 0); l_xs_1_ = None elem_3: "f32[3, 10, 2]" = torch.flip(elem, [0]); elem = None elem_4: "f32[3, 10, 2]" = torch.flip(elem_1, [0]); elem_1 = None elem_5: "f32[3, 10, 2]" = torch.flip(elem_2, [0]); elem_2 = None child: "f32[1, 10, 2]" = torch.ops.aten.slice(elem_3, 0, 0, -1, 2) child_1: "f32[1, 10, 2]" = torch.ops.aten.slice(elem_4, 0, 0, -1, 2) child_2: "f32[1, 10, 2]" = torch.ops.aten.slice(elem_5, 0, 0, -1, 2) child_3: "f32[1, 10, 2]" = torch.ops.aten.slice(elem_3, 0, 1, None, 2) child_4: "f32[1, 10, 2]" = torch.ops.aten.slice(elem_4, 0, 1, None, 2) child_5: "f32[1, 10, 2]" = torch.ops.aten.slice(elem_5, 0, 1, None, 2) lazy_load_decompositions = torch._functorch.vmap.lazy_load_decompositions(); lazy_load_decompositions = None _vmap_increment_nesting = torch._C._functorch._vmap_increment_nesting(1, 'error'); _vmap_increment_nesting = None _add_batch_dim: "f32[10, 2]" = torch._C._functorch._add_batch_dim(child, 0, 1); child = None _add_batch_dim_1: "f32[10, 2]" = torch._C._functorch._add_batch_dim(child_1, 0, 1); child_1 = None _add_batch_dim_2: "f32[10, 2]" = torch._C._functorch._add_batch_dim(child_2, 0, 1); child_2 = _add_batch_dim_2 = None _add_batch_dim_3: "f32[10, 2]" = torch._C._functorch._add_batch_dim(child_3, 0, 1); child_3 = _add_batch_dim_3 = None _add_batch_dim_4: "f32[10, 2]" = torch._C._functorch._add_batch_dim(child_4, 0, 1); child_4 = _add_batch_dim_4 = None _add_batch_dim_5: "f32[10, 2]" = torch._C._functorch._add_batch_dim(child_5, 0, 1); child_5 = None a: "f32[10, 2]" = _add_batch_dim + _add_batch_dim_5; _add_batch_dim = None b: "f32[10, 2]" = _add_batch_dim_1 - _add_batch_dim_5; _add_batch_dim_1 = _add_batch_dim_5 = None child_6: "f32[10, 2]" = a - b child_7: "f32[1, 10, 2]" = torch._C._functorch._remove_batch_dim(a, 1, 1, 0); a = None child_8: "f32[1, 10, 2]" = torch._C._functorch._remove_batch_dim(b, 1, 1, 0); b = None child_9: "f32[1, 10, 2]" = torch._C._functorch._remove_batch_dim(child_6, 1, 1, 0); child_6 = None _vmap_decrement_nesting = torch._C._functorch._vmap_decrement_nesting(); _vmap_decrement_nesting = None child_10: "f32[1, 10, 2]" = torch.ops.aten.slice(elem_3, 0, 2, None, 2) child_11: "f32[1, 10, 2]" = torch.ops.aten.slice(elem_4, 0, 2, None, 2) child_12: "f32[1, 10, 2]" = torch.ops.aten.slice(elem_5, 0, 2, None, 2) lazy_load_decompositions_1 = torch._functorch.vmap.lazy_load_decompositions(); lazy_load_decompositions_1 = None _vmap_increment_nesting_1 = torch._C._functorch._vmap_increment_nesting(1, 'error'); _vmap_increment_nesting_1 = None _add_batch_dim_6: "f32[10, 2]" = torch._C._functorch._add_batch_dim(child_7, 0, 1) _add_batch_dim_7: "f32[10, 2]" = torch._C._functorch._add_batch_dim(child_8, 0, 1) _add_batch_dim_8: "f32[10, 2]" = torch._C._functorch._add_batch_dim(child_9, 0, 1); _add_batch_dim_8 = None _add_batch_dim_9: "f32[10, 2]" = torch._C._functorch._add_batch_dim(child_10, 0, 1); child_10 = _add_batch_dim_9 = None _add_batch_dim_10: "f32[10, 2]" = torch._C._functorch._add_batch_dim(child_11, 0, 1); child_11 = _add_batch_dim_10 = None _add_batch_dim_11: "f32[10, 2]" = torch._C._functorch._add_batch_dim(child_12, 0, 1); child_12 = None a_1: "f32[10, 2]" = _add_batch_dim_6 + _add_batch_dim_11; _add_batch_dim_6 = None b_1: "f32[10, 2]" = _add_batch_dim_7 - _add_batch_dim_11; _add_batch_dim_7 = _add_batch_dim_11 = None child_13: "f32[10, 2]" = a_1 - b_1 child_14: "f32[1, 10, 2]" = torch._C._functorch._remove_batch_dim(a_1, 1, 1, 0); a_1 = None child_15: "f32[1, 10, 2]" = torch._C._functorch._remove_batch_dim(b_1, 1, 1, 0); b_1 = None child_16: "f32[1, 10, 2]" = torch._C._functorch._remove_batch_dim(child_13, 1, 1, 0); child_13 = None _vmap_decrement_nesting_1 = torch._C._functorch._vmap_decrement_nesting(); _vmap_decrement_nesting_1 = None slice_10: "f32[1, 10, 2]" = torch.ops.aten.slice(elem_3, 0, 0, 1); elem_3 = None cat: "f32[2, 10, 2]" = torch.cat([slice_10, child_14], dim = 0); slice_10 = child_14 = None slice_11: "f32[1, 10, 2]" = torch.ops.aten.slice(elem_4, 0, 0, 1); elem_4 = None cat_1: "f32[2, 10, 2]" = torch.cat([slice_11, child_15], dim = 0); slice_11 = child_15 = None slice_12: "f32[1, 10, 2]" = torch.ops.aten.slice(elem_5, 0, 0, 1); elem_5 = None cat_2: "f32[2, 10, 2]" = torch.cat([slice_12, child_16], dim = 0); slice_12 = child_16 = None b_2: "f32[2, 10, 2]" = torch._C._nn.pad(child_7, [0, 0, 0, 0, 0, 1], 'constant', None); child_7 = None stacked: "f32[2, 2, 10, 2]" = torch.stack([cat, b_2], dim = 1); cat = b_2 = None interleaved: "f32[4, 10, 2]" = torch.flatten(stacked, start_dim = 0, end_dim = 1); stacked = None interleaved_1: "f32[3, 10, 2]" = torch.ops.aten.slice(interleaved, 0, 0, 3); interleaved = None b_3: "f32[2, 10, 2]" = torch._C._nn.pad(child_8, [0, 0, 0, 0, 0, 1], 'constant', None); child_8 = None stacked_1: "f32[2, 2, 10, 2]" = torch.stack([cat_1, b_3], dim = 1); cat_1 = b_3 = None interleaved_2: "f32[4, 10, 2]" = torch.flatten(stacked_1, start_dim = 0, end_dim = 1); stacked_1 = None interleaved_3: "f32[3, 10, 2]" = torch.ops.aten.slice(interleaved_2, 0, 0, 3); interleaved_2 = None b_4: "f32[2, 10, 2]" = torch._C._nn.pad(child_9, [0, 0, 0, 0, 0, 1], 'constant', None); child_9 = None stacked_2: "f32[2, 2, 10, 2]" = torch.stack([cat_2, b_4], dim = 1); cat_2 = b_4 = None interleaved_4: "f32[4, 10, 2]" = torch.flatten(stacked_2, start_dim = 0, end_dim = 1); stacked_2 = None interleaved_5: "f32[3, 10, 2]" = torch.ops.aten.slice(interleaved_4, 0, 0, 3); interleaved_4 = None child_17: "f32[3, 10, 2]" = interleaved_1.flip([0]); interleaved_1 = None child_18: "f32[3, 10, 2]" = interleaved_3.flip([0]); interleaved_3 = None child_19: "f32[3, 10, 2]" = interleaved_5.flip([0]); interleaved_5 = None movedim_3: "f32[3, 10, 2]" = torch.movedim(child_17, 0, 0); child_17 = None movedim_4: "f32[3, 10, 2]" = torch.movedim(child_18, 0, 0); child_18 = None movedim_5: "f32[3, 10, 2]" = torch.movedim(child_19, 0, 0); child_19 = None return (movedim_3, movedim_4, movedim_5) """, # noqa: B950 ) @unittest.skipIf(not SM70OrLater, "triton") @requires_cuda @parametrize("combine_mode", ["pointwise", "generic"]) @parametrize("compile_mode", ["none", "eager", "compile", "compile_dynamic_shape"]) @parametrize("reverse", [False, True]) @parametrize("device", [torch.device("cpu"), torch.device("cuda")]) # Skipping the combination of combine_mode=pointwise and device=cpu # as the current implementation of pointwise does only support CUDA device # Skipping the combination of combine_mode=pointwise and compile_mode=compile_dynamic_shape # as the current implementation does not support lifted arguments @decorateIf( unittest.skip, lambda params: ( params["combine_mode"] == "pointwise" and ( params["device"] == torch.device("cpu") or params["compile_mode"] == "compile_dynamic_shape" or torch.version.hip ) ), ) def test_associative_scan_downstream_scan_matmul( self, combine_mode, compile_mode, reverse, device ): def first_chain_fct(scan_fct, inp, **kwargs): o = scan_fct(get_scan_combine_fn("add", True), inp, **kwargs) return o def second_chain_fct(scan_fct, inp, **kwargs): W = torch.ones(2, 5, device=device) return inp @ W inp = torch.randn(3, 10, 2, device=device) kwargs = { "dim": 1, "reverse": reverse, "compile_mode": compile_mode, "combine_fn": [first_chain_fct, second_chain_fct], "combine_mode": combine_mode, } kwargs_fake = self._prepare_fake_kwargs(kwargs) self._run_test( model=AssociativeScanModels.ChainFn(**kwargs), model_fake=AssociativeScanModels.ChainFn(**kwargs_fake), inputs=inp, ) @unittest.skipIf(not SM70OrLater, "triton") @requires_cuda @parametrize("combine_mode", ["pointwise", "generic"]) @parametrize("compile_mode", ["none", "eager", "compile", "compile_dynamic_shape"]) @parametrize("reverse", [False, True]) @parametrize("device", [torch.device("cpu"), torch.device("cuda")]) # Skipping the combination of combine_mode=pointwise and device=cpu # as the current implementation of pointwise does only support CUDA device # Skipping the combination of combine_mode=pointwise and compile_mode=compile_dynamic_shape # as the current implementation does not support lifted arguments @decorateIf( unittest.skip, lambda params: ( params["combine_mode"] == "pointwise" and ( params["device"] == torch.device("cpu") or params["compile_mode"] == "compile_dynamic_shape" or torch.version.hip ) ), ) def test_associative_scan_downstream_scan_scan( self, combine_mode, compile_mode, reverse, device ): def first_chain_fct(scan_fct, inp, **kwargs): o1 = scan_fct(get_scan_combine_fn("add", True), inp, **kwargs) return o1 def second_chain_fct(scan_fct, inp, **kwargs): o2 = scan_fct(get_scan_combine_fn("add", True), inp, **kwargs) return o2 inp = torch.randn(3, 10, 2, device=device) kwargs = { "dim": 1, "reverse": reverse, "compile_mode": compile_mode, "combine_fn": [first_chain_fct, second_chain_fct], "combine_mode": combine_mode, } kwargs_fake = self._prepare_fake_kwargs(kwargs) self._run_test( model=AssociativeScanModels.ChainFn(**kwargs), model_fake=AssociativeScanModels.ChainFn(**kwargs_fake), inputs=inp, ) @unittest.skipIf(not SM70OrLater, "triton") @requires_cuda @parametrize("combine_mode", ["pointwise", "generic"]) @parametrize("compile_mode", ["none", "eager", "compile", "compile_dynamic_shape"]) @parametrize("reverse_first", [False, True]) @parametrize("same_direction", [False, True]) @parametrize("device", [torch.device("cpu"), torch.device("cuda")]) # Skipping the combination of combine_mode=pointwise and device=cpu # as the current implementation of pointwise does only support CUDA device # Skipping the combination of combine_mode=pointwise and compile_mode=compile_dynamic_shape # as the current implementation does not support lifted arguments @decorateIf( unittest.skip, lambda params: ( params["combine_mode"] == "pointwise" and ( params["device"] == torch.device("cpu") or params["compile_mode"] == "compile_dynamic_shape" or torch.version.hip ) ), ) def test_associative_scan_downstream_scan_scan_different_dim( self, combine_mode, compile_mode, reverse_first, same_direction, device ): reverse_second = reverse_first if same_direction else not reverse_first def first_chain_fct(scan_fct, inp, **kwargs): o1 = scan_fct(get_scan_combine_fn("add", True), inp, **kwargs) return o1 def second_chain_fct(scan_fct, inp, **kwargs): o2 = scan_fct(get_scan_combine_fn("add", True), inp, **kwargs) return o2 inp = torch.randn(3, 10, 2, device=device) kwargs = { "dim": [1, 0], "reverse": [reverse_first, reverse_second], "compile_mode": compile_mode, "combine_fn": [first_chain_fct, second_chain_fct], "combine_mode": [combine_mode, combine_mode], } kwargs_fake = self._prepare_fake_kwargs(kwargs) self._run_test( model=AssociativeScanModels.ChainFn(**kwargs), model_fake=AssociativeScanModels.ChainFn(**kwargs_fake), inputs=inp, ) # TODO: Does not work because of the usage of vmap witin associative_scan # TODO: Re-enable additional parameters again once this issues has been resolved @unittest.skipIf(not SM70OrLater, "triton") @requires_cuda @unittest.expectedFailure def test_associative_scan_nested(self): combine_mode = "pointwise" compile_mode = "eager" reverse_first = False same_direction = False device = torch.device("cuda") reverse_second = reverse_first if same_direction else not reverse_first def first_nested_fct(x, y): y_new = associative_scan( second_nested_fct, y, 0, reverse=reverse_second, combine_mode=combine_mode, ) return x + y_new def first_nested_fct_fake(x, y): y_new = _fake_associative_scan( second_nested_fct, y, 0, reverse=reverse_second ) return x + y_new def second_nested_fct(x, y): return x * y inp = torch.randn(3, 10, 2, device=device) kwargs = { "dim": 0, "reverse": reverse_first, "compile_mode": compile_mode, "combine_fn": first_nested_fct, "combine_mode": combine_mode, } kwargs_fake = self._prepare_fake_kwargs(kwargs) kwargs_fake["combine_fn"] = first_nested_fct_fake self._run_test( model=AssociativeScanModels.NestedFn(**kwargs), model_fake=AssociativeScanModels.NestedFn(**kwargs_fake), inputs=inp, ) @unittest.skipIf(not SM70OrLater, "triton") @requires_cuda @parametrize("compile_mode", ["none", "eager", "compile", "compile_dynamic_shape"]) @parametrize("loop_type", ["for"]) @parametrize("reverse", [False, True]) @parametrize("device", [torch.device("cpu"), torch.device("cuda")]) def test_associative_scan_loop_in_combine_fn( self, compile_mode, loop_type, reverse, device ): def combine_fn(x, y): cnt = torch.zeros_like(y[0, :]) if loop_type == "while": def cond_fn(ind, loop_val): return (loop_val < 5)[0] def body_fn(ind, loop_val): return ind + 1, loop_val + torch.abs(ind) new_ind, cnt = torch.while_loop( cond_fn=cond_fn, body_fn=body_fn, carried_inputs=( torch.zeros(1, dtype=torch.int32, device=cnt.device), cnt, ), ) else: for ind in range(10): cnt += torch.abs(y[ind]) return x * cnt inp = torch.randn(3, 10, 1, device=device) * 2 kwargs = { "dim": 0, "reverse": reverse, "compile_mode": compile_mode, "combine_fn": combine_fn, "combine_mode": "generic", } kwargs_fake = self._prepare_fake_kwargs(kwargs) self._run_test( model=AssociativeScanModels.CombineFn(**kwargs), model_fake=AssociativeScanModels.CombineFn(**kwargs_fake), inputs=inp, ) # TODO: Does not work because of the usage of vmap witin associative_scan # TODO: Re-enable additional parameters again once this issues has been resolved @unittest.skipIf(not SM70OrLater, "triton") @requires_cuda @unittest.expectedFailure def test_associative_scan_loop_in_combine_fn_failure(self): compile_mode = "none" loop_type = "while" reverse = False device = torch.device("cuda") def combine_fn(x, y): _cnt = torch.zeros_like(y[0, :]) if loop_type == "while": def cond_fn(ind, loop_val): return (loop_val < 5)[0] def body_fn(ind, loop_val): return ind + 1, loop_val + torch.abs(ind) inp = torch.randn(3, 10, 1, device=device) * 2 kwargs = { "dim": 0, "reverse": reverse, "compile_mode": compile_mode, "combine_fn": combine_fn, "combine_mode": "generic", } kwargs_fake = self._prepare_fake_kwargs(kwargs) self._run_test( model=AssociativeScanModels.CombineFn(**kwargs), model_fake=AssociativeScanModels.CombineFn(**kwargs_fake), inputs=inp, ) @unittest.skipIf(not SM70OrLater, "triton") @requires_cuda @parametrize("compile_mode", ["none", "eager", "compile", "compile_dynamic_shape"]) @parametrize("reverse", [False, True]) @parametrize("device", [torch.device("cpu"), torch.device("cuda")]) # Skipping the combination of compile_mode=compile_dynamic_shape # as the current implementation does not support lifted arguments @decorateIf( unittest.skip, lambda params: ( params["device"] == torch.device("cpu") or params["compile_mode"] == "compile_dynamic_shape" or torch.version.hip ), ) def test_associative_scan_cond_in_combine_fn(self, compile_mode, reverse, device): def combine_fn(x, y): val = cond(torch.sum(y) > 0.0, lambda y: y.clone(), lambda y: 1.0 - y, (y,)) return x * val inp = torch.randn(3, 10, 1, device=device) kwargs = { "dim": 0, "reverse": reverse, "compile_mode": compile_mode, "combine_fn": combine_fn, "combine_mode": "generic", } kwargs_fake = self._prepare_fake_kwargs(kwargs) self._run_test( model=AssociativeScanModels.CombineFn(**kwargs), model_fake=AssociativeScanModels.CombineFn(**kwargs_fake), inputs=inp, ) # TODO: Does not work because of the usage of vmap witin associative_scan # TODO: Re-enable additional parameters again once this issues has been resolved @unittest.skipIf(not SM70OrLater, "triton") @requires_cuda @unittest.expectedFailure def test_associative_scan_map_in_combine_fn(self): compile_mode = "none" reverse = False device = torch.device("cuda") def combine_fn(x, y): def body(x, y): return x + y y_init = y[0] y_new = control_flow.map(body, y, y_init) return x * y_new inp = torch.randn(3, 10, 1, device=device) kwargs = { "dim": 0, "reverse": reverse, "compile_mode": compile_mode, "combine_fn": combine_fn, "combine_mode": "generic", } kwargs_fake = self._prepare_fake_kwargs(kwargs) self._run_test( model=AssociativeScanModels.CombineFn(**kwargs), model_fake=AssociativeScanModels.CombineFn(**kwargs_fake), inputs=inp, ) @unittest.skipIf(not SM70OrLater, "triton") @requires_cuda @parametrize("compile_mode", ["none", "eager", "compile", "compile_dynamic_shape"]) @parametrize("reverse", [False, True]) @parametrize("device", [torch.device("cpu"), torch.device("cuda")]) def test_associative_scan_vmap_in_combine_fn(self, compile_mode, reverse, device): def combine_fn(x, y): def body(x): return x**2 mapped_body = torch.vmap(body, 0, 0) y_new = mapped_body(y) return x + y_new inp = torch.randn(3, 10, 2, device=device) kwargs = { "dim": 0, "reverse": reverse, "compile_mode": compile_mode, "combine_fn": combine_fn, "combine_mode": "generic", } kwargs_fake = self._prepare_fake_kwargs(kwargs) self._run_test( model=AssociativeScanModels.CombineFn(**kwargs), model_fake=AssociativeScanModels.CombineFn(**kwargs_fake), inputs=inp, ) @unittest.skipIf(not SM70OrLater, "triton") @requires_cuda @parametrize("reverse", [False, True]) @parametrize("compile_mode", ["none", "eager", "compile", "compile_dynamic_shape"]) @parametrize("device", [torch.device("cpu"), torch.device("cuda")]) # Skipping the combination of associative_scan and device=cpu # as the current implementation of pointwise does only support CUDA device @decorateIf( unittest.skip, lambda params: (params["device"] == torch.device("cpu")), ) def test_associative_scan_non_pointwise_generic( self, reverse, compile_mode, device ): x = torch.randn(3, 10, 2, device=device) kwargs = { "dim": 0, "reverse": reverse, "compile_mode": compile_mode, "combine_fn": get_scan_combine_fn("non_pointwise", True), "combine_mode": "generic", } kwargs_fake = self._prepare_fake_kwargs(kwargs) self._run_test( model=AssociativeScanModels.CombineFn(**kwargs), model_fake=AssociativeScanModels.CombineFn(**kwargs_fake), inputs=x, ) @skipIfRocm(msg="Unsupported on ROCM yet") @unittest.skipIf(not SM70OrLater, "triton") @requires_cuda @parametrize("compile_mode", ["none", "eager", "compile", "compile_dynamic_shape"]) @parametrize("combine_mode", ["pointwise", "generic"]) @parametrize("reverse", [False, True]) @parametrize("device", [torch.device("cpu"), torch.device("cuda")]) # Skipping the combination of combine_mode=pointwise and device=cpu # as the current implementation of pointwise does only support CUDA device # Skipping the combination of combine_mode=pointwise and compile_mode=compile_dynamic_shape # as the current implementation does not support lifted arguments @decorateIf( unittest.skip, lambda params: ( params["combine_mode"] == "pointwise" and ( params["device"] == torch.device("cpu") or params["compile_mode"] == "compile_dynamic_shape" or torch.version.hip ) ), ) def test_associative_scan_binary_operator( self, compile_mode, combine_mode, reverse, device ): state_dim = 20 timesteps = 10 projected_inputs = torch.randn( timesteps, state_dim, requires_grad=True, device=device ) A = torch.randn(state_dim, requires_grad=True, device=device) elements = (A.repeat((timesteps, 1)), projected_inputs) kwargs = { "dim": 0, "reverse": reverse, "compile_mode": compile_mode, "combine_fn": get_scan_combine_fn("s5_operator", True), "combine_mode": combine_mode, } kwargs_fake = self._prepare_fake_kwargs(kwargs) self._run_test( model=AssociativeScanModels.CombineFn(**kwargs), model_fake=AssociativeScanModels.CombineFn(**kwargs_fake), inputs=elements, ) @skipIfRocm(msg="Unsupported on ROCM yet") @unittest.skipIf(not SM70OrLater, "triton") @requires_cuda @parametrize("compile_mode", ["none", "eager", "compile", "compile_dynamic_shape"]) @parametrize("reverse", [False, True]) @parametrize("device", [torch.device("cpu"), torch.device("cuda")]) def test_associative_scan_different_input_size(self, compile_mode, reverse, device): batch = 5 hidden_dim = 3 length = 10 dstate = 7 deltaA = torch.randn( (batch, hidden_dim, length, dstate), requires_grad=True, device=device ) deltaB_u = torch.randn( (batch, hidden_dim, length, dstate), requires_grad=True, device=device ) C = torch.randn((batch, dstate, length), requires_grad=True, device=device) x = torch.randn( (batch, hidden_dim, length, dstate), requires_grad=True, device=device ) y = torch.randn((batch, hidden_dim, length), requires_grad=True, device=device) elements = (x, deltaA, deltaB_u, C, y) kwargs = { "dim": 2, "reverse": reverse, "compile_mode": compile_mode, "combine_fn": get_scan_combine_fn("different_input_size_operator", True), "combine_mode": "generic", } kwargs_fake = self._prepare_fake_kwargs(kwargs) self._run_test( model=AssociativeScanModels.CombineFn(**kwargs), model_fake=AssociativeScanModels.CombineFn(**kwargs_fake), inputs=elements, ) @unittest.skipIf(not SM70OrLater, "triton") @requires_cuda def test_associative_scan_different_input_size_wrong_dim(self): batch = 5 hidden_dim = 3 length = 10 dstate = 7 deltaA = torch.randn( (batch, hidden_dim, length, dstate), device=torch.device("cuda") ) deltaB_u = torch.randn( (batch, hidden_dim, length, dstate), device=torch.device("cuda") ) C = torch.randn((batch, dstate, length), device=torch.device("cuda")) x = torch.randn( (batch, hidden_dim, length, dstate), device=torch.device("cuda") ) y = torch.randn( (batch, hidden_dim, length, dstate), device=torch.device("cuda") ) elements = (x, deltaA, deltaB_u, C, y) with self.assertRaisesRegex( ValueError, "All xs leaves must at least have.*", ): associative_scan( get_scan_combine_fn("different_input_size_operator", True), elements, 3, combine_mode="pointwise", ) @unittest.skipIf(not SM70OrLater, "triton") @unittest.skipIf(not torch.cuda.is_available(), "Test requires CUDA.") @parametrize("compile_mode", ["none", "eager", "compile", "compile_dynamic_shape"]) @parametrize("combine_mode", ["pointwise", "generic"]) @parametrize("reverse", [False, True]) @parametrize("device", [torch.device("cpu"), torch.device("cuda")]) # Skipping the combine_mode=pointwise # as the current implementation of associative_scan lowering # does not support lifted arguments @decorateIf( unittest.skip, lambda params: (params["combine_mode"] == "pointwise"), ) def test_associative_scan_freevars_simple( self, compile_mode, combine_mode, reverse, device ): H = torch.rand(2, device=device) def fct_freevars1(x: torch.Tensor, y: torch.Tensor): return x * H + y * 2 def fct_freevars2(x: torch.Tensor, y: torch.Tensor): return x * H + y * H H1 = torch.rand(1, device=device) H2 = torch.rand(1, device=device) def fct_freevars3(x: torch.Tensor, y: torch.Tensor): return x * H1 + y * H2 inp = torch.randn(3, 2, 2, device=device) for fct, param in [ (fct_freevars1, (H,)), (fct_freevars2, (H,)), (fct_freevars3, (H1, H2)), ]: kwargs = { "dim": 0, "reverse": reverse, "compile_mode": compile_mode, "combine_fn": fct, "combine_mode": combine_mode, } kwargs_fake = self._prepare_fake_kwargs(kwargs) self._run_test( model=AssociativeScanModels.CombineFn(**kwargs), model_fake=AssociativeScanModels.CombineFn(**kwargs_fake), inputs=inp, ) @unittest.skipIf(not SM70OrLater, "triton") @unittest.skipIf(not torch.cuda.is_available(), "Test requires CUDA.") @parametrize("compile_mode", ["none", "eager", "compile", "compile_dynamic_shape"]) @parametrize("combine_mode", ["pointwise", "generic"]) @parametrize("reverse", [False, True]) @parametrize("device", [torch.device("cpu"), torch.device("cuda")]) # Skipping the combine_mode=pointwise # as the current implementation of associative_scan lowering # does not support lifted arguments @decorateIf( unittest.skip, lambda params: (params["combine_mode"] == "pointwise"), ) def test_associative_scan_freevars_nested( self, compile_mode, combine_mode, reverse, device ): H1 = torch.rand(4, 5, device=device) H2 = torch.rand(4, 1, device=device) def fct_nested_outside(x: torch.Tensor, y: torch.Tensor): def inner(xi): return xi * H2 ret = inner(y) return x + ret * H1 def fct_nested_outside_fake(x: torch.Tensor, y: torch.Tensor): def inner(xi): return xi * H2 ret = inner(y) return x + ret * H1 H1_i = torch.rand(4, 5, device=device) # TODO: Using random tensors in the `combine_fn` triggers the vmap randomness error: # RuntimeError: vmap: called random operation while in randomness error mode. # Please either use the 'same' or 'different' randomness flags on vmap or perform the randomness operation out of vmap def fct_nested_inside(x: torch.Tensor, y: torch.Tensor): # H2_i = torch.rand(4, 1, device=device) H2_i = torch.ones(4, 1, device=device) * 42 def inner(xi): return xi * H2_i ret = inner(y) return x + ret * H1 def fct_nested_inside_fake(x: torch.Tensor, y: torch.Tensor): # H2_i = torch.rand(4, 1, device=device) H2_i = torch.ones(4, 1, device=device) * 42 def inner(xi): return xi * H2_i ret = inner(y) return x + ret * H1 inp = torch.randn(3, 4, 5, device=device) for fct, fct_fake, param in [ (fct_nested_outside, fct_nested_outside_fake, (H1, H2)), (fct_nested_inside, fct_nested_inside_fake, (H1_i,)), ]: kwargs = { "dim": 0, "reverse": reverse, "compile_mode": compile_mode, "combine_fn": fct, "combine_mode": combine_mode, } kwargs_fake = self._prepare_fake_kwargs(kwargs) kwargs_fake["combine_fn"] = fct_fake self._run_test( model=AssociativeScanModels.CombineFn(**kwargs), model_fake=AssociativeScanModels.CombineFn(**kwargs_fake), inputs=inp, ) @unittest.skipIf(not SM70OrLater, "triton") @unittest.skipIf(not torch.cuda.is_available(), "Test requires CUDA.") @parametrize("compile_mode", ["none", "eager", "compile", "compile_dynamic_shape"]) @parametrize("combine_mode", ["pointwise", "generic"]) @parametrize("reverse", [False, True]) @parametrize("device", [torch.device("cpu"), torch.device("cuda")]) # Skipping the combine_mode=pointwise # as the current implementation of associative_scan lowering # does not support lifted arguments @decorateIf( unittest.skip, lambda params: (params["combine_mode"] == "pointwise"), ) def test_associative_scan_freevars_fct( self, compile_mode, combine_mode, reverse, device ): def additional_fct_no_add_inp(x, y): return x * y def fct_nested_outside(x: torch.Tensor, y: torch.Tensor): ret = additional_fct_no_add_inp(y, y) return x + ret inp = torch.randn(3, 4, 5, device=device) kwargs = { "dim": 0, "reverse": reverse, "compile_mode": compile_mode, "combine_fn": fct_nested_outside, "combine_mode": combine_mode, } kwargs_fake = self._prepare_fake_kwargs(kwargs) self._run_test( model=AssociativeScanModels.CombineFn(**kwargs), model_fake=AssociativeScanModels.CombineFn(**kwargs_fake), inputs=inp, ) @unittest.skipIf(not SM70OrLater, "triton") @unittest.skipIf(not torch.cuda.is_available(), "Test requires CUDA.") @parametrize("compile_mode", ["none", "eager", "compile", "compile_dynamic_shape"]) @parametrize("reverse", [False, True]) @parametrize("device", [torch.device("cpu"), torch.device("cuda")]) def test_associative_scan_freevars_fct_generic(self, compile_mode, reverse, device): def additional_fct_no_add_inp(x, y): return x * y def fct_nested_outside(x: torch.Tensor, y: torch.Tensor): ret = associative_scan( additional_fct_no_add_inp, y, 1, combine_mode="generic" ) return x + ret def fct_nested_outside_fake(x: torch.Tensor, y: torch.Tensor): ret = _fake_associative_scan(additional_fct_no_add_inp, y, 1) return x + ret inp = torch.randn(3, 4, 5, device=device) kwargs = { "dim": 0, "reverse": reverse, "compile_mode": compile_mode, "combine_fn": fct_nested_outside, "combine_mode": "generic", } kwargs_fake = self._prepare_fake_kwargs(kwargs) kwargs_fake["combine_fn"] = fct_nested_outside_fake self._run_test( model=AssociativeScanModels.CombineFn(**kwargs), model_fake=AssociativeScanModels.CombineFn(**kwargs_fake), inputs=inp, ) @unittest.skipIf(not SM70OrLater, "triton") @unittest.skipIf(not torch.cuda.is_available(), "Test requires CUDA.") @parametrize("compile_mode", ["none", "eager", "compile", "compile_dynamic_shape"]) @parametrize("combine_mode", ["pointwise", "generic"]) @parametrize("reverse", [False, True]) @parametrize("device", [torch.device("cpu"), torch.device("cuda")]) # Skipping the combine_mode=pointwise # as the current implementation of associative_scan lowering # does not support lifted arguments @decorateIf( unittest.skip, lambda params: (params["combine_mode"] == "pointwise"), ) def test_associative_scan_freevars_shape_check( self, compile_mode, combine_mode, reverse, device ): H = torch.eye(2, device=device, requires_grad=True) def fct_freevars(x: torch.Tensor, y: torch.Tensor): return x @ H + y inp = torch.randn(2, 2, 3, device=device, requires_grad=True) kwargs = { "dim": 2, "reverse": reverse, "compile_mode": compile_mode, "combine_fn": fct_freevars, "combine_mode": combine_mode, } kwargs_fake = self._prepare_fake_kwargs(kwargs) self._run_test( model=AssociativeScanModels.CombineFn(**kwargs), model_fake=AssociativeScanModels.CombineFn(**kwargs_fake), inputs=inp, ) @unittest.skipIf(not SM70OrLater, "triton") @unittest.skipIf(not torch.cuda.is_available(), "Test requires CUDA.") @parametrize("compile_mode", ["none", "eager", "compile", "compile_dynamic_shape"]) @parametrize("reverse", [False, True]) @parametrize("device", [torch.device("cpu"), torch.device("cuda")]) @parametrize("combine_mode", ["pointwise", "generic"]) # Skipping the combine_mode=pointwise # as the current implementation of associative_scan lowering # does not support lifted arguments @decorateIf( unittest.skip, lambda params: (params["combine_mode"] == "pointwise"), ) def test_associative_scan_freevars_pytree( self, compile_mode, combine_mode, reverse, device ): xf = torch.randn(2, 2, device=device, requires_grad=True) yf = torch.randn(2, 2, device=device, requires_grad=True) zf = torch.randn(2, 2, device=device, requires_grad=True) inpf = {"i": xf, "j": ([yf], [{"o": zf}])} def fct_pointwise(x, y): return { "i": (x["i"] * y["i"]) + inpf["i"], "j": ( [(x["j"][0][0] * y["j"][0][0]) + inpf["j"][0][0]], [ { "o": (x["j"][1][0]["o"] + y["j"][1][0]["o"]) + inpf["j"][1][0]["o"] } ], ), } x = torch.randn(3, 2, 2, device=device, requires_grad=True) y = torch.randn(3, 2, 2, device=device, requires_grad=True) z = torch.randn(3, 2, 2, device=device, requires_grad=True) inp = {"i": x, "j": ([y], [{"o": z}])} kwargs = { "dim": 0, "reverse": reverse, "compile_mode": compile_mode, "combine_fn": fct_pointwise, "combine_mode": combine_mode, } kwargs_fake = self._prepare_fake_kwargs(kwargs) self._run_test( model=AssociativeScanModels.CombineFn(**kwargs), model_fake=AssociativeScanModels.CombineFn(**kwargs_fake), inputs=inp, ) @unittest.skipIf(not SM70OrLater, "triton") def test_associative_scan_sparse_tensor(self): x = torch.tensor( [[[0.0, 0], [1.0, 2.0]], [[0.0, 0], [3.0, 4.0]], [[0.0, 0], [5.0, 6.0]]] ).to_sparse() with self.assertRaisesRegex( ValueError, "xs leaves must dense Tensors.*", ): associative_scan( get_scan_combine_fn("add", True), x, 0, combine_mode="generic" ) @unittest.skipIf(not SM70OrLater, "triton") @requires_cuda def test_associative_scan_combine_fn_wrong_meta_in_combine_fn(self): device = torch.device("cuda") B, N, C, H, W = 3, 3, 2, 3, 3 x = torch.randn(B, N, C, H, W, device=device) def fct_wrong_dtype(x, y): return (x + y).to(torch.int64) def fct_wrong_device(x, y): return (x + y).to( torch.device("cpu") if device.type == "cuda" else torch.device("cuda") ) def fct_wrong_stride(x, y): return (x + y).to(memory_format=torch.channels_last) for fct in [fct_wrong_dtype, fct_wrong_device, fct_wrong_stride]: with self.assertRaisesRegex( torch._dynamo.exc.UncapturedHigherOrderOpError, "Expected initial_xs and combine_fn_output to have same metadata.*", ): associative_scan(fct, x, 0) @unittest.skipIf(not SM70OrLater, "triton") def test_associative_scan_wrong_pytree(self): def fct_wrong_pytree(x, y): return { "i": x["i"] * y["j"][0][0], "k": torch.tensor(0.0), "j": ([x["j"][1][0]["o"]], [{"o": torch.sin(x["i"])}]), } x = torch.randn(3, 2, 2) y = torch.randn(3, 2, 2) z = torch.randn(3, 2, 2) inp = {"i": x, "j": ([y], [{"o": z}])} with self.assertRaisesRegex( AssertionError, "Combin_fn received wrong number of arguments.*", ): associative_scan(fct_wrong_pytree, inp, 0, combine_mode="generic") @unittest.skipIf(not SM70OrLater, "triton") @requires_cuda def test_associative_scan_non_pointwise(self): device = torch.device("cuda") x = torch.randn(3, 10, 2, device=device) with self.assertRaisesRegex( # Should be: RuntimeError, r"For combine_mode='pointwise', the combine_fn needs to be pointwise", ): associative_scan( get_scan_combine_fn("non_pointwise", True), x, 0, combine_mode="pointwise", ) @requires_cuda def test_associative_scan_input_mutation(self): device = torch.device("cuda") def fct_input_mutation(x, y): x.add_(1) return x + y x = torch.randn(3, 2, 2, device=device) with self.assertRaisesRegex( # Should be # torch._dynamo.exc.Unsupported, # "Encountered aliasing during higher order op tracing for HOP.*" torch._dynamo.exc.UncapturedHigherOrderOpError, "associative_scan must be captured completely with torch.compile.*", ): associative_scan(fct_input_mutation, x, 0) @requires_cuda def test_associative_scan_input_output_alias(self): device = torch.device("cuda") def fct_input_output_alias(x, y): return x[0], x[1] + y[1] x = torch.randn(3, 2, 2, device=device) y = torch.randn(3, 2, 2, device=device) inp = (x, y) with self.assertRaisesRegex( # Should be # torch._dynamo.exc.Unsupported, # "Encountered aliasing during higher order op tracing for HOP.*" torch._dynamo.exc.UncapturedHigherOrderOpError, "associative_scan must be captured completely with torch.compile.*", ): associative_scan(fct_input_output_alias, inp, 0) @unittest.skipIf(not SM70OrLater, "triton") @requires_cuda def test_associative_scan_output_output_alias(self): device = torch.device("cuda") def fct_output_output_alias(x, y): c = x[0] + y[1] return c, c x = torch.randn(3, 2, 2, device=device) y = torch.randn(3, 2, 2, device=device) inp = (x, y) with self.assertRaisesRegex( # Should be # torch._dynamo.exc.Unsupported, # "Encountered aliasing during higher order op tracing for HOP.*" torch._dynamo.exc.UncapturedHigherOrderOpError, "associative_scan must be captured completely with torch.compile.*", ): associative_scan(fct_output_output_alias, inp, 0) @unittest.skipIf(IS_WINDOWS, "Windows not supported for this test") @skipIfNoDynamoSupport class TestControlFlowTraced(TestCase): def setUp(self): torch._dynamo.reset() super().setUp() def _check_tracing(self, fn, args, allow_non_fake_inputs=False): graphs = {} eager_res = fn(*args) for tracing_mode in ["symbolic", "real", "fake"]: graph = make_fx( fn, tracing_mode=tracing_mode, _allow_non_fake_inputs=allow_non_fake_inputs, )(*args) graphs[tracing_mode] = graph self.assertEqual(graph(*args), eager_res) return graphs def _check_compile(self, fn, args, *, dynamic=False, backend="eager"): eager_res = fn(*args) compiled_fn = torch.compile(fn, backend=backend, dynamic=dynamic) self.assertEqual(compiled_fn(*args), eager_res) def _check_export(self, fn, args, *, strict=False, dynamic_shapes=None): eg_out = fn(*args) ep = torch.export.export(fn, args, strict=strict, dynamic_shapes=dynamic_shapes) ep_out = ep.module()(*args) self.assertEqual(eg_out, ep_out) return ep def test_cond_traced_not_nested(self): def true_fn(x): return x.sin() def false_fn(x): return x.cos() def f(x, y): return cond(y, true_fn, false_fn, [x]) x = torch.randn(4) graph = make_fx(f)(x, torch.tensor(False)) result_true = graph.forward(x, torch.tensor(True)) result_false = graph.forward(x, torch.tensor(False)) self.assertFalse(torch.allclose(result_true, result_false)) self.assertEqual(result_true, torch.sin(x)) self.assertEqual(result_false, torch.cos(x)) graph = make_fx(f, tracing_mode="symbolic")(x, torch.tensor(False)) self.assertEqual(graph(x, torch.tensor(True)), f(x, torch.tensor(True))) @skipIfTorchDynamo("Graph is not captured by backend if test with dynamo") @skipIfCrossRef # Arg order changes with crossref def test_cond_simple_with_linear_compile_check_graph(self): from torch._dynamo.testing import EagerAndRecordGraphs def true_fn(x): return x.sin() def false_fn(x): return x.cos() x = torch.randn(4, requires_grad=True) def f(pred, x): result = cond(pred, true_fn, false_fn, (x,)) grad_out = torch.ones_like(result) return torch.autograd.grad(result, (x,), grad_out) backend = EagerAndRecordGraphs() torch.compile(f, backend=backend)(torch.tensor(False), x) self.assertEqual(len(backend.graphs), 2) gm = backend.graphs[0] self.assertExpectedInline( gm.code.strip(), """\ def forward(self, L_pred_ : torch.Tensor, L_x_ : torch.Tensor): l_pred_ = L_pred_ l_x_ = L_x_ cond_true_0 = self.cond_true_0 cond_false_0 = self.cond_false_0 cond = torch.ops.higher_order.cond(l_pred_, cond_true_0, cond_false_0, (l_x_,)); l_pred_ = cond_true_0 = cond_false_0 = l_x_ = None result = cond[0]; cond = None grad_out = torch.ones_like(result) return (result, grad_out)""", # noqa: B950 ) self.assertExpectedInline( normalize_gm(backend.graphs[1].print_readable(print_output=False)), """\ class GraphModule(torch.nn.Module): def forward(self, L_ctx_saved_tensors_0_: "f32[4]", L_ctx_pred: "b8[]", L_args_1_: "f32[4]"): l_ctx_saved_tensors_0_ = L_ctx_saved_tensors_0_ l_ctx_pred = L_ctx_pred l_args_1_ = L_args_1_ cond_true_0 = self.cond_true_0 cond_false_0 = self.cond_false_0 cond = torch.ops.higher_order.cond(l_ctx_pred, cond_true_0, cond_false_0, (l_args_1_, l_ctx_saved_tensors_0_)); l_ctx_pred = cond_true_0 = cond_false_0 = l_args_1_ = l_ctx_saved_tensors_0_ = None getitem: "f32[4]" = cond[0]; cond = None return (getitem,) class cond_true_0(torch.nn.Module): def forward(self, l_args_1_, l_ctx_saved_tensors_0_): l_args_1__1 = l_args_1_ l_ctx_saved_tensors_0__1 = l_ctx_saved_tensors_0_ sin: "f32[4]" = torch.ops.aten.sin.default(l_ctx_saved_tensors_0__1); sin = None cos: "f32[4]" = torch.ops.aten.cos.default(l_ctx_saved_tensors_0__1); l_ctx_saved_tensors_0__1 = None mul: "f32[4]" = torch.ops.aten.mul.Tensor(l_args_1__1, cos); l_args_1__1 = cos = None return (mul,) class cond_false_0(torch.nn.Module): def forward(self, l_args_1_, l_ctx_saved_tensors_0_): l_args_1__1 = l_args_1_ l_ctx_saved_tensors_0__1 = l_ctx_saved_tensors_0_ cos: "f32[4]" = torch.ops.aten.cos.default(l_ctx_saved_tensors_0__1); cos = None sin: "f32[4]" = torch.ops.aten.sin.default(l_ctx_saved_tensors_0__1); l_ctx_saved_tensors_0__1 = None neg: "f32[4]" = torch.ops.aten.neg.default(sin); sin = None mul: "f32[4]" = torch.ops.aten.mul.Tensor(l_args_1__1, neg); l_args_1__1 = neg = None return (mul,) """, # noqa: B950 ) def test_while_loop_op_mismatch_in_meta(self): class Mod(torch.nn.Module): def forward(self, c, a, b): def cond_fn(c, a, b): return c > 0 def body_fn(c, a, b): return c - 1, a.nonzero(), b.nonzero() return torch.ops.higher_order.while_loop( cond_fn, body_fn, (c, a, b), tuple(), ) with self.assertRaisesRegex( torch._dynamo.exc.UncapturedHigherOrderOpError, "Expected carried_inputs and body_output to have same metadata but found", ): make_fx(Mod(), tracing_mode="fake")( torch.tensor( 0, ), torch.randn(2, 3), torch.randn(2, 3), ) def test_while_loop_nested_traced(self): fn, inp = WHILE_LOOP_TESTS["nested"] graphs = self._check_tracing(fn, inp) self.assertExpectedInline( graphs["symbolic"].code.strip("\n"), """\ def forward(self, out_iter_1, it_1, y_1): while_loop_cond_graph_0 = self.while_loop_cond_graph_0 while_loop_body_graph_0 = self.while_loop_body_graph_0 while_loop = torch.ops.higher_order.while_loop(while_loop_cond_graph_0, while_loop_body_graph_0, (out_iter_1, it_1, y_1), ()); while_loop_cond_graph_0 = while_loop_body_graph_0 = out_iter_1 = it_1 = y_1 = None getitem = while_loop[0] getitem_1 = while_loop[1] getitem_2 = while_loop[2]; while_loop = None return (getitem, getitem_1, getitem_2) """, # noqa: B950 ) self.assertExpectedInline( graphs["symbolic"].while_loop_cond_graph_0.code.strip("\n"), """\ def forward(self, arg0_1, arg1_1, arg2_1): sum_1 = torch.ops.aten.sum.default(arg0_1); arg0_1 = None lt = torch.ops.aten.lt.Scalar(sum_1, 2); sum_1 = None return lt """, ) self.assertExpectedInline( graphs["symbolic"].while_loop_body_graph_0.code.strip("\n"), """\ def forward(self, arg0_1, arg1_1, arg2_1): while_loop_cond_graph_0 = self.while_loop_cond_graph_0 while_loop_body_graph_0 = self.while_loop_body_graph_0 while_loop = torch.ops.higher_order.while_loop(while_loop_cond_graph_0, while_loop_body_graph_0, (arg0_1, arg1_1, arg2_1), ()); while_loop_cond_graph_0 = while_loop_body_graph_0 = arg0_1 = arg1_1 = arg2_1 = None getitem = while_loop[0] getitem_1 = while_loop[1] getitem_2 = while_loop[2]; while_loop = None add = torch.ops.aten.add.Tensor(getitem, 1); getitem = None return (add, getitem_1, getitem_2) """, # noqa: B950 ) def test_while_loop_pytree_carry(self): fn, inp = WHILE_LOOP_TESTS["simple_with_pytree_carry"] from torch._dynamo.testing import EagerAndRecordGraphs backend = EagerAndRecordGraphs() expected_res = fn(*inp) compiled_res = torch.compile(fn, backend=backend)(*inp) self.assertEqual(expected_res, compiled_res) # When test with torch dynamo, the graph is not captured because # it's traced together with the code before torch.compile if not TEST_WITH_TORCHDYNAMO: self.assertEqual(len(backend.graphs), 1) self.assertExpectedInline( backend.graphs[0].code.strip(), """\ def forward(self, L_it_ : torch.Tensor, L_pytree_input_0_0_ : torch.Tensor, L_pytree_input_1_x_ : torch.Tensor, L_pytree_input_1_y_ : torch.Tensor): l_it_ = L_it_ l_pytree_input_0_0_ = L_pytree_input_0_0_ l_pytree_input_1_x_ = L_pytree_input_1_x_ l_pytree_input_1_y_ = L_pytree_input_1_y_ cond_fn_0 = self.cond_fn_0 body_fn_0 = self.body_fn_0 while_loop = torch.ops.higher_order.while_loop(cond_fn_0, body_fn_0, (l_it_, l_pytree_input_0_0_, l_pytree_input_1_x_, l_pytree_input_1_y_), ()); cond_fn_0 = body_fn_0 = l_it_ = l_pytree_input_0_0_ = l_pytree_input_1_x_ = l_pytree_input_1_y_ = None getitem = while_loop[0] getitem_1 = while_loop[1] value = while_loop[2] value_1 = while_loop[3]; while_loop = None return (getitem, getitem_1, value, value_1)""", # noqa: B950 ) def _wrap_with_functionalize(self, fn, func_type): mode = None if func_type == "cpp": fn = CppFunctionalizeAPI().functionalize(fn) elif func_type == "python": fn = PythonFunctionalizeAPI().functionalize(fn) mode = FunctionalTensorMode() elif func_type == "functorch": fn = torch.func.functionalize(fn) else: assert func_type == "no" return fn, mode @parametrize("func_type", ["no", "cpp", "python", "functorch"]) def test_while_loop_simple_functionalize_check_graph(self, func_type): fn, inp = WHILE_LOOP_TESTS["simple_with_mutation"] fn, mode = self._wrap_with_functionalize(fn, func_type) mode = mode if mode is not None else contextlib.nullcontext() with mode: graphs = self._check_tracing(fn, inp) if func_type == "no": self.assertExpectedInline( graphs["symbolic"].code.strip("\n"), """\ def forward(self, x_1): while_loop_cond_graph_0 = self.while_loop_cond_graph_0 while_loop_body_graph_0 = self.while_loop_body_graph_0 while_loop = torch.ops.higher_order.while_loop(while_loop_cond_graph_0, while_loop_body_graph_0, (x_1,), ()); while_loop_cond_graph_0 = while_loop_body_graph_0 = x_1 = None getitem = while_loop[0]; while_loop = None return (getitem,) """, # noqa: B950 ) self.assertExpectedInline( graphs["symbolic"].while_loop_cond_graph_0.code.strip("\n"), """\ def forward(self, arg0_1): clone = torch.ops.aten.clone.default(arg0_1); arg0_1 = None add_ = torch.ops.aten.add_.Tensor(clone, 1); clone = None add__1 = torch.ops.aten.add_.Tensor(add_, -1); add_ = None sum_1 = torch.ops.aten.sum.default(add__1); add__1 = None lt = torch.ops.aten.lt.Scalar(sum_1, 10); sum_1 = None return lt """, ) self.assertExpectedInline( graphs["symbolic"].while_loop_body_graph_0.code.strip("\n"), """\ def forward(self, arg0_1): clone = torch.ops.aten.clone.default(arg0_1); arg0_1 = None add_ = torch.ops.aten.add_.Tensor(clone, 1); clone = None add__1 = torch.ops.aten.add_.Tensor(add_, -1); add_ = None add = torch.ops.aten.add.Tensor(add__1, 1); add__1 = None return (add,) """, ) elif func_type == "python": self.assertExpectedInline( graphs["symbolic"].code.strip("\n"), """\ def forward(self, arg0_1): while_loop_cond_graph_0 = self.while_loop_cond_graph_0 while_loop_body_graph_0 = self.while_loop_body_graph_0 while_loop = torch.ops.higher_order.while_loop(while_loop_cond_graph_0, while_loop_body_graph_0, (arg0_1,), ()); while_loop_cond_graph_0 = while_loop_body_graph_0 = arg0_1 = None getitem = while_loop[0]; while_loop = None return (getitem,) """, # noqa: B950 ) self.assertExpectedInline( graphs["symbolic"].while_loop_cond_graph_0.code.strip("\n"), """\ def forward(self, arg0_1): clone = torch.ops.aten.clone.default(arg0_1); arg0_1 = None add = torch.ops.aten.add.Tensor(clone, 1); clone = None add_1 = torch.ops.aten.add.Tensor(add, -1); add = None sum_1 = torch.ops.aten.sum.default(add_1); add_1 = None lt = torch.ops.aten.lt.Scalar(sum_1, 10); sum_1 = None return lt """, ) self.assertExpectedInline( graphs["symbolic"].while_loop_body_graph_0.code.strip("\n"), """\ def forward(self, arg0_1): clone = torch.ops.aten.clone.default(arg0_1); arg0_1 = None add = torch.ops.aten.add.Tensor(clone, 1); clone = None add_1 = torch.ops.aten.add.Tensor(add, -1); add = None add_2 = torch.ops.aten.add.Tensor(add_1, 1); add_1 = None return (add_2,) """, ) else: self.assertExpectedInline( graphs["symbolic"].code.strip("\n"), """\ def forward(self, x_1): while_loop_cond_graph_0 = self.while_loop_cond_graph_0 while_loop_body_graph_0 = self.while_loop_body_graph_0 while_loop = torch.ops.higher_order.while_loop(while_loop_cond_graph_0, while_loop_body_graph_0, (x_1,), ()); while_loop_cond_graph_0 = while_loop_body_graph_0 = x_1 = None getitem = while_loop[0]; while_loop = None return (getitem,) """, # noqa: B950 ) self.assertExpectedInline( graphs["symbolic"].while_loop_cond_graph_0.code.strip("\n"), """\ def forward(self, arg0_1): clone = torch.ops.aten.clone.default(arg0_1); arg0_1 = None add = torch.ops.aten.add.Tensor(clone, 1); clone = None add_1 = torch.ops.aten.add.Tensor(add, -1); add = None sum_1 = torch.ops.aten.sum.default(add_1); add_1 = None lt = torch.ops.aten.lt.Scalar(sum_1, 10); sum_1 = None return lt """, ) self.assertExpectedInline( graphs["symbolic"].while_loop_body_graph_0.code.strip("\n"), """\ def forward(self, arg0_1): clone = torch.ops.aten.clone.default(arg0_1); arg0_1 = None add = torch.ops.aten.add.Tensor(clone, 1); clone = None add_1 = torch.ops.aten.add.Tensor(add, -1); add = None add_2 = torch.ops.aten.add.Tensor(add_1, 1); add_1 = None return (add_2,) """, ) @parametrize("func_type", ["no", "cpp", "python", "functorch"]) # - "simple_with_linear" and "nested_with_linear" doesn't work becaue parameters and buffers # are not inputs so they're not wrapped by functionalization and tracing. # # - make_fx tracing mode "real" fails for "int_carry", "pytree_int_carry" and "const_and_symint_output" # because tensors are real but we unspecialize the ints with unbacked symints causing # data dependent errors. # Since this is not the common use path, we skip them for now. @parametrize( "while_loop_test", set(WHILE_LOOP_TESTS.keys()) - { "simple_with_linear", "nested_with_linear", "int_carry", "pytree_int_carry", "const_and_symint_output", }, ) def test_while_loop_functionalize(self, func_type, while_loop_test): fn, inp = WHILE_LOOP_TESTS[while_loop_test] fn, mode = self._wrap_with_functionalize(fn, func_type) mode = mode if mode is not None else contextlib.nullcontext() with mode: self._check_tracing(fn, inp) # - make_fx tracing mode "real" fails for "int_carry", "pytree_int_carry" and "const_and_symint_output" # because tensors are real but we unspecialize the ints with unbacked symints causing # data dependent errors. # Since this is not the common use path, we skip them for now. @parametrize( "while_loop_test", set(WHILE_LOOP_TESTS.keys()) - {"int_carry", "pytree_int_carry", "const_and_symint_output"}, ) def test_while_loop_tracing(self, while_loop_test): fn, inp = WHILE_LOOP_TESTS[while_loop_test] allow_non_fake_inputs = ( False if while_loop_test not in ("simple_with_linear", "nested_with_linear") else True ) self._check_tracing(fn, inp, allow_non_fake_inputs) @parametrize("backend", ["eager", "aot_eager"]) @parametrize("while_loop_test", list(WHILE_LOOP_TESTS.keys())) def test_while_loop_compile(self, backend, while_loop_test): fn, inp = WHILE_LOOP_TESTS[while_loop_test] self._check_compile(fn, inp, backend=backend) @skipIfTorchDynamo("Graph is not captured by backend if test with dynamo") @skipIfCrossRef # Arg order changes with cross ref def test_while_loop_simple_with_linear_compile_check_graph(self): fn, inp = WHILE_LOOP_TESTS["simple_with_linear"] from torch._dynamo.testing import EagerAndRecordGraphs backend = EagerAndRecordGraphs() torch.compile(fn, backend=backend)(*inp) self.assertEqual(len(backend.graphs), 1) gm = backend.graphs[0] if torch._dynamo.config.inline_inbuilt_nn_modules: self.assertExpectedInline( gm.code.strip(), """\ def forward(self, L_iter_ : torch.Tensor, L_x_ : torch.Tensor, L_self_buffers_dec_ : torch.Tensor, L_self_modules_linear_parameters_weight_ : torch.nn.parameter.Parameter, L_self_modules_linear_parameters_bias_ : torch.nn.parameter.Parameter): l_iter_ = L_iter_ l_x_ = L_x_ l_self_buffers_dec_ = L_self_buffers_dec_ l_self_modules_linear_parameters_weight_ = L_self_modules_linear_parameters_weight_ l_self_modules_linear_parameters_bias_ = L_self_modules_linear_parameters_bias_ cond_fn_0 = self.cond_fn_0 body_fn_0 = self.body_fn_0 while_loop = torch.ops.higher_order.while_loop(cond_fn_0, body_fn_0, (l_iter_, l_x_), (l_self_buffers_dec_, l_self_modules_linear_parameters_bias_, l_self_modules_linear_parameters_weight_)); cond_fn_0 = body_fn_0 = l_iter_ = l_x_ = l_self_buffers_dec_ = l_self_modules_linear_parameters_bias_ = l_self_modules_linear_parameters_weight_ = None getitem = while_loop[0] getitem_1 = while_loop[1]; while_loop = None return (getitem, getitem_1)""", # noqa: B950 ) self.assertExpectedInline( gm.cond_fn_0.code.strip(), """\ def forward(self, l_iter_ : torch.Tensor, l_x_ : torch.Tensor, l_self_buffers_dec__cond_fn, l_self_modules_linear_parameters_bias__body_fn, l_self_modules_linear_parameters_weight__body_fn): sub = l_iter_ - l_self_buffers_dec__cond_fn; l_iter_ = l_self_buffers_dec__cond_fn = None gt = sub > 0; sub = None return gt""", # noqa: B950 ) self.assertExpectedInline( gm.body_fn_0.code.strip(), """\ def forward(self, l_iter_ : torch.Tensor, l_x_ : torch.Tensor, l_self_buffers_dec__cond_fn, l_self_modules_linear_parameters_bias__body_fn, l_self_modules_linear_parameters_weight__body_fn): child = l_iter_ - 1; l_iter_ = None child_1 = torch._C._nn.linear(l_x_, l_self_modules_linear_parameters_weight__body_fn, l_self_modules_linear_parameters_bias__body_fn); l_x_ = l_self_modules_linear_parameters_weight__body_fn = l_self_modules_linear_parameters_bias__body_fn = None return (child, child_1)""", # noqa: B950 ) else: self.assertExpectedInline( gm.code.strip(), """\ def forward(self, L_iter_ : torch.Tensor, L_x_ : torch.Tensor): l_iter_ = L_iter_ l_x_ = L_x_ l__self___dec = self.L__self___dec l__self___linear_weight = self.L__self___linear_weight l__self___linear_bias = self.L__self___linear_bias cond_fn_0 = self.cond_fn_0 body_fn_0 = self.body_fn_0 while_loop = torch.ops.higher_order.while_loop(cond_fn_0, body_fn_0, (l_iter_, l_x_), (l__self___dec, l__self___linear_bias, l__self___linear_weight)); cond_fn_0 = body_fn_0 = l_iter_ = l_x_ = l__self___dec = l__self___linear_bias = l__self___linear_weight = None getitem = while_loop[0] getitem_1 = while_loop[1]; while_loop = None return (getitem, getitem_1)""", # noqa: B950 ) self.assertExpectedInline( gm.cond_fn_0.code.strip(), """\ def forward(self, l_iter_, l_x_, l__self___dec_cond_fn, l__self___linear_bias_body_fn, l__self___linear_weight_body_fn): sub = l_iter_ - l__self___dec_cond_fn; l_iter_ = l__self___dec_cond_fn = None gt = sub > 0; sub = None return gt""", # noqa: B950 ) self.assertExpectedInline( gm.body_fn_0.code.strip(), """\ def forward(self, l_iter_, l_x_, l__self___dec_cond_fn, l__self___linear_bias_body_fn, l__self___linear_weight_body_fn): child = l_iter_ - 1; l_iter_ = None child_1 = torch._C._nn.linear(l_x_, l__self___linear_weight_body_fn, l__self___linear_bias_body_fn); l_x_ = l__self___linear_weight_body_fn = l__self___linear_bias_body_fn = None return (child, child_1)""", # noqa: B950 ) def test_while_loop_nested2_traced(self): fn, inp = WHILE_LOOP_TESTS["nested2"] graphs = self._check_tracing(fn, inp) gm = graphs["symbolic"] outer_body = gm.while_loop_body_graph_0 inner_body = outer_body.while_loop_body_graph_0 inner_cond = outer_body.while_loop_cond_graph_0 self.assertExpectedInline( gm.code.strip("\n"), """\ def forward(self, arg0_1, arg1_1, arg2_1, arg3_1): sym_size_int = torch.ops.aten.sym_size.int(arg3_1, 1) sym_size_int_1 = torch.ops.aten.sym_size.int(arg2_1, 1) sym_size_int_2 = torch.ops.aten.sym_size.int(arg2_1, 0) sym_size_int_3 = torch.ops.aten.sym_size.int(arg3_1, 0) while_loop_cond_graph_0 = self.while_loop_cond_graph_0 while_loop_body_graph_0 = self.while_loop_body_graph_0 while_loop = torch.ops.higher_order.while_loop(while_loop_cond_graph_0, while_loop_body_graph_0, (arg0_1, arg1_1, arg2_1, arg3_1), (sym_size_int, sym_size_int_1, sym_size_int_2, sym_size_int_3)); while_loop_cond_graph_0 = while_loop_body_graph_0 = arg0_1 = arg1_1 = arg2_1 = arg3_1 = sym_size_int = sym_size_int_1 = sym_size_int_2 = sym_size_int_3 = None getitem = while_loop[0] getitem_1 = while_loop[1] getitem_2 = while_loop[2] getitem_3 = while_loop[3]; while_loop = None return (getitem, getitem_1, getitem_2, getitem_3) """, # noqa: B950 ) self.assertExpectedInline( outer_body.code.strip("\n"), """\ def forward(self, arg0_1, arg1_1, arg2_1, arg3_1, arg4_1, arg5_1, arg6_1, arg7_1): while_loop_cond_graph_0 = self.while_loop_cond_graph_0 while_loop_body_graph_0 = self.while_loop_body_graph_0 while_loop = torch.ops.higher_order.while_loop(while_loop_cond_graph_0, while_loop_body_graph_0, (arg0_1, arg1_1, arg2_1, arg3_1), (arg7_1, arg7_1, arg7_1, arg7_1)); while_loop_cond_graph_0 = while_loop_body_graph_0 = arg0_1 = arg1_1 = arg2_1 = arg3_1 = arg7_1 = None getitem = while_loop[0] getitem_1 = while_loop[1] getitem_2 = while_loop[2] getitem_3 = while_loop[3]; while_loop = None sub = torch.ops.aten.sub.Tensor(getitem, 1); getitem = None clone = torch.ops.aten.clone.default(getitem_1); getitem_1 = None mul = torch.ops.aten.mul.Tensor(getitem_2, 2); getitem_2 = None div = torch.ops.aten.div.Tensor(getitem_3, 2); getitem_3 = None return (sub, clone, mul, div) """, # noqa: B950 ) self.assertExpectedInline( outer_body.code.strip("\n"), """\ def forward(self, arg0_1, arg1_1, arg2_1, arg3_1, arg4_1, arg5_1, arg6_1, arg7_1): while_loop_cond_graph_0 = self.while_loop_cond_graph_0 while_loop_body_graph_0 = self.while_loop_body_graph_0 while_loop = torch.ops.higher_order.while_loop(while_loop_cond_graph_0, while_loop_body_graph_0, (arg0_1, arg1_1, arg2_1, arg3_1), (arg7_1, arg7_1, arg7_1, arg7_1)); while_loop_cond_graph_0 = while_loop_body_graph_0 = arg0_1 = arg1_1 = arg2_1 = arg3_1 = arg7_1 = None getitem = while_loop[0] getitem_1 = while_loop[1] getitem_2 = while_loop[2] getitem_3 = while_loop[3]; while_loop = None sub = torch.ops.aten.sub.Tensor(getitem, 1); getitem = None clone = torch.ops.aten.clone.default(getitem_1); getitem_1 = None mul = torch.ops.aten.mul.Tensor(getitem_2, 2); getitem_2 = None div = torch.ops.aten.div.Tensor(getitem_3, 2); getitem_3 = None return (sub, clone, mul, div) """, # noqa: B950 ) self.assertExpectedInline( inner_body.code.strip("\n"), """\ def forward(self, arg0_1, arg1_1, arg2_1, arg3_1, arg4_1, arg5_1, arg6_1, arg7_1): clone = torch.ops.aten.clone.default(arg0_1); arg0_1 = None sub = torch.ops.aten.sub.Tensor(arg1_1, 1); arg1_1 = None add = torch.ops.aten.add.Tensor(arg2_1, 3.14); arg2_1 = None sub_1 = torch.ops.aten.sub.Tensor(arg3_1, 2.71); arg3_1 = None return (clone, sub, add, sub_1) """, ) self.assertExpectedInline( inner_cond.code.strip("\n"), """\ def forward(self, arg0_1, arg1_1, arg2_1, arg3_1, arg4_1, arg5_1, arg6_1, arg7_1): gt = torch.ops.aten.gt.Scalar(arg1_1, 0); arg1_1 = None return gt """, ) def test_cond_nested_traced(self): def true_nested(y): return y * y def false_nested(y): return y + y def true_fn(x, pred2): z = cond(pred2, true_nested, false_nested, [x]) return x + z def false_fn(x, _): return x.cos() def f(x, pred, pred2): return cond(pred, true_fn, false_fn, [x, pred2]) x = torch.randn(4) graph = make_fx(f)(x, torch.tensor(False), torch.tensor(False)) result_true_true = graph.forward( x, torch.tensor(True), torch.tensor(True) ) # True + True -> x * x result_true_false = graph.forward( x, torch.tensor(True), torch.tensor(False) ) # True + True -> x + x result_false_true = graph.forward( x, torch.tensor(False), torch.tensor(True) ) # False + either -> cos result_false_false = graph.forward( x, torch.tensor(False), torch.tensor(False) ) # False + either -> cos self.assertNotEqual(result_true_true, result_true_false) self.assertFalse(torch.allclose(result_false_true, result_true_true)) self.assertEqual(result_false_true, result_false_false) self.assertEqual(result_true_true, (x * x) + x) self.assertEqual(result_true_false, x + x + x) self.assertEqual(result_false_true, torch.cos(x)) graph = make_fx(f, tracing_mode="symbolic")( x, torch.tensor(False), torch.tensor(False) ) self.assertEqual( graph(x, torch.tensor(True), torch.tensor(True)), f(x, torch.tensor(True), torch.tensor(True)), ) def test_cond_functionalized(self): def true_fn(x): y = x.sin() y.add_(4) return x.sin().max() + y.sum() def false_fn(x): return x.cos().min() def f(x): pred = x.shape[0] == 1 return cond(pred, true_fn, false_fn, [x]) example_inputs = (torch.ones(4, 5),) functional_f = torch.func.functionalize(f) self.assertEqual(functional_f(*example_inputs), f(*example_inputs)) graph_module = make_fx(torch.func.functionalize(f), tracing_mode="symbolic")( *example_inputs ) self.assertEqual(graph_module(*example_inputs), f(*example_inputs)) all_ops_in_true_branch = [] for node in graph_module.true_graph_0.graph.nodes: if node.op == "call_function": all_ops_in_true_branch.append(node.target) self.assertFalse(any(op._schema.is_mutable for op in all_ops_in_true_branch)) self.assertEqual(graph_module(*example_inputs), f(*example_inputs)) def test_cond_accepts_torch_function_as_inputs(self): a = torch.randn(3, 4) b = torch.randn(3, 4) def f(a, b): return cond(a.sum() > 0, torch.add, torch.mul, (a, b)) gm = self._check_tracing(f, (a, b))["symbolic"] self.assertExpectedInline( gm.code.strip(), """\ def forward(self, a_1, b_1): sum_1 = torch.ops.aten.sum.default(a_1) gt = torch.ops.aten.gt.Scalar(sum_1, 0); sum_1 = None sym_size_int = torch.ops.aten.sym_size.int(a_1, 1) sym_size_int_1 = torch.ops.aten.sym_size.int(b_1, 0) sym_size_int_2 = torch.ops.aten.sym_size.int(b_1, 1) sym_size_int_3 = torch.ops.aten.sym_size.int(a_1, 0) true_graph_0 = self.true_graph_0 false_graph_0 = self.false_graph_0 cond = torch.ops.higher_order.cond(gt, true_graph_0, false_graph_0, (a_1, b_1, sym_size_int, sym_size_int_1, sym_size_int_2, sym_size_int_3)); gt = true_graph_0 = false_graph_0 = a_1 = b_1 = sym_size_int = sym_size_int_1 = sym_size_int_2 = sym_size_int_3 = None getitem = cond[0]; cond = None return getitem""", # noqa: B950 ) self.assertExpectedInline( gm.true_graph_0.code.strip(), """\ def forward(self, arg0_1, arg1_1, arg2_1, arg3_1, arg4_1, arg5_1): add = torch.ops.aten.add.Tensor(arg0_1, arg1_1); arg0_1 = arg1_1 = None return (add,)""", ) self.assertExpectedInline( gm.false_graph_0.code.strip(), """\ def forward(self, arg0_1, arg1_1, arg2_1, arg3_1, arg4_1, arg5_1): mul = torch.ops.aten.mul.Tensor(arg0_1, arg1_1); arg0_1 = arg1_1 = None return (mul,)""", ) def test_cond_retrace_functionalized(self): def true_fn(x): return x.sin() def false_fn(x): return x.cos() def f(x): return cond(x.all(), true_fn, false_fn, (x,)) inp = torch.ones(1, 2) gm_non_functional = make_fx(f, tracing_mode="real")(inp) gm_functional = make_fx( torch.func.functionalize(gm_non_functional), tracing_mode="real" )(inp) self.assertEqual(gm_functional(torch.zeros(1, 2)), f(torch.zeros(1, 2))) def test_cond_subgraph_same_shape_env_as_parent(self): def true_fn(x): return x.sin() + 10 def false_fn(x): return x.cos() - 20 def f(x, pred): y = cond(pred, true_fn, false_fn, [x]) z = torch.add(y, y) return z symbolic_traced_graph = self._check_tracing( f, (torch.ones(4), torch.Tensor([True])) )["symbolic"] graph_shape_env = symbolic_traced_graph.shape_env def _node_shape_env_iter(gm): for node in symbolic_traced_graph.graph.nodes: if node.op == "call_function": val = node.meta.get("val") if isinstance(val, tuple): for v in val: yield v.fake_mode.shape_env elif isinstance(val, torch.SymInt): yield val.node.shape_env else: yield val.fake_mode.shape_env for shape_env in _node_shape_env_iter(symbolic_traced_graph): self.assertTrue(shape_env is graph_shape_env) for shape_env in _node_shape_env_iter(symbolic_traced_graph.true_graph_0): self.assertTrue(shape_env is graph_shape_env) for shape_env in _node_shape_env_iter(symbolic_traced_graph.false_graph_0): self.assertTrue(shape_env is graph_shape_env) def test_cond_functionalized_nested(self): def true_true_fn(x): y = x.cos() y.add_(4) return x.sin().max() + y.sin().max() def true_false_fn(x): return x.cos().min() def true_fn(x): pred = x.shape[0] == 1 return cond(pred, true_true_fn, true_false_fn, [x]) def false_fn(x): return x.sum() def f(x): pred = x.shape[0] == 1 return cond(pred, true_fn, false_fn, [x]) example_inputs = (torch.ones(4, 5),) functional_f = torch.func.functionalize(f) self.assertEqual(functional_f(*example_inputs), f(*example_inputs)) graph_module = make_fx(torch.func.functionalize(f), tracing_mode="symbolic")( *example_inputs ) self.assertEqual(graph_module(*example_inputs), f(*example_inputs)) gm_true_true_branch = graph_module.true_graph_0.true_graph_0 self.assertEqual(graph_module(*example_inputs), f(*example_inputs)) all_ops = [] for node in gm_true_true_branch.graph.nodes: if node.op == "call_function": all_ops.append(node.target) self.assertFalse(any(op._schema.is_mutable for op in all_ops)) def test_cond_functionalized_data_dependent_pred(self): def true_fn(x): return x.sin().sum() def false_fn(x): return x.cos().sum() def f(x): pred = x.nonzero().shape[0] == 1 return cond(pred, true_fn, false_fn, [x]) example_inputs = (torch.ones(4, 5),) functional_f = torch.func.functionalize(f) self.assertEqual(functional_f(*example_inputs), f(*example_inputs)) graph_module = make_fx(torch.func.functionalize(f))(*example_inputs) self.assertEqual(graph_module(*example_inputs), f(*example_inputs)) def test_cond_functionalized_input_mutation_on_true_branch(self): def true_fn(x): view_x = x.view(x.shape) view_x.add_(1) return view_x.sin().sum() def false_fn(x): return x.cos().sum() def f(x): pred = x.shape[0] == 4 return cond(pred, true_fn, false_fn, [x]) example_inputs = (torch.ones(4, 5),) # torch.cond inlines into one of the branches because the predicate # is a constant. gm = make_fx(torch.func.functionalize(f))(*example_inputs) self.assertExpectedInline( gm.code.strip(), """\ def forward(self, x_1): view = torch.ops.aten.view.default(x_1, [4, 5]) add = torch.ops.aten.add.Tensor(view, 1); view = None view_1 = torch.ops.aten.view.default(add, [4, 5]); add = None view_2 = torch.ops.aten.view.default(view_1, [4, 5]) sin = torch.ops.aten.sin.default(view_2); view_2 = None sum_1 = torch.ops.aten.sum.default(sin); sin = None copy_ = torch.ops.aten.copy_.default(x_1, view_1); x_1 = view_1 = copy_ = None return sum_1""", ) # torch.cond triggers the check of the branches because the predicate # is a SymBool. with self.assertRaisesRegex( torch._dynamo.exc.TorchRuntimeError, "cond_true might be modifying the input!", ): make_fx(torch.func.functionalize(f), tracing_mode="symbolic")( *example_inputs ) def test_cond_functionalized_input_mutation_on_false_branch(self): def true_fn(x): return x.sin().sum() def false_fn(x): view_x = x.view(x.shape) view_x.add_(1) return view_x.cos().sum() def f(x): pred = x.shape[0] == 4 return cond(pred, true_fn, false_fn, [x]) example_inputs = (torch.ones(5, 5),) gm = make_fx(torch.func.functionalize(f))(*example_inputs) # torch.cond inlines into one of the branches because the predicate # is a constant. self.assertExpectedInline( gm.code.strip(), """\ def forward(self, x_1): view = torch.ops.aten.view.default(x_1, [5, 5]) add = torch.ops.aten.add.Tensor(view, 1); view = None view_1 = torch.ops.aten.view.default(add, [5, 5]); add = None view_2 = torch.ops.aten.view.default(view_1, [5, 5]) cos = torch.ops.aten.cos.default(view_2); view_2 = None sum_1 = torch.ops.aten.sum.default(cos); cos = None copy_ = torch.ops.aten.copy_.default(x_1, view_1); x_1 = view_1 = copy_ = None return sum_1""", ) # torch.cond triggers the check of the branches because the predicate # is a SymBool. with self.assertRaisesRegex( torch._dynamo.exc.TorchRuntimeError, "cond_false might be modifying the input!", ): make_fx(torch.func.functionalize(f), tracing_mode="symbolic")( *example_inputs ) def test_cond_functionalized_output_alias_input(self): def true_fn(x): return x.clone() def false_fn(x): view_x = x.view(x.shape) return view_x def f(x): pred = x.shape[0] == 4 return cond(pred, true_fn, false_fn, [x]) example_inputs = (torch.ones(5, 5),) gm = make_fx(torch.func.functionalize(f))(*example_inputs) # torch.cond inlines into one of the branches because the predicate # is a constant. self.assertExpectedInline( gm.code.strip(), """\ def forward(self, x_1): view = torch.ops.aten.view.default(x_1, [5, 5]); x_1 = None return view""", ) # torch.cond triggers the check of the branches because the predicate # is a SymBool. with self.assertRaisesRegex( # Should be # torch._dynamo.exc.Unsupported, # "Encountered aliasing during higher order op tracing for HOP.*" torch._dynamo.exc.UncapturedHigherOrderOpError, "Cond doesn't work unless it is captured completely with torch.compile.*", ): make_fx(torch.func.functionalize(f), tracing_mode="symbolic")( *example_inputs ) def test_cond_functionalized_nested_input_mutation(self): def true_true_fn(x): x.add_(4) return x.sin().max() def true_false_fn(x): return x.cos().min() def true_fn(x): pred = x.shape[0] == 1 return cond(pred, true_true_fn, true_false_fn, [x]) def false_fn(x): return x.sum() def f(x): pred = x.shape[0] == 1 return cond(pred, true_fn, false_fn, [x]) example_inputs = (torch.ones(4, 5),) with self.assertRaisesRegex( torch._dynamo.exc.TorchRuntimeError, "cond_true might be modifying the input!", ): make_fx(torch.func.functionalize(f), tracing_mode="symbolic")( *example_inputs ) def test_cond_functionalized_nested_input_mutation_with_aot_func(self): def true_true_fn(x): x.add_(4) return x.sin().max() def true_false_fn(x): return x.cos().min() def true_fn(x): pred = x.shape[0] == 1 return cond(pred, true_true_fn, true_false_fn, [x]) def false_fn(x): return x.sum() def f(x): pred = x.shape[0] == 1 return cond(pred, true_fn, false_fn, [x]) example_input = torch.ones(4, 5) try: example_input_func = to_fun_old(example_input) torch._enable_functionalization(reapply_views=False) f(example_input_func) with self.assertRaisesRegex( # Should be # torch._dynamo.exc.Unsupported, # "Encountered aliasing during higher order op tracing for HOP.*" torch._dynamo.exc.UncapturedHigherOrderOpError, "Cond doesn't work unless it is captured completely with torch.compile.*", ): make_fx(f, tracing_mode="symbolic")(example_input_func) finally: torch._disable_functionalization() def f_wrapper(func): @functools.wraps(func) def wrapper(*args, **kwargs): torch._enable_functionalization(reapply_views=False) try: return func(*args, **kwargs) finally: torch._disable_functionalization() return wrapper with self.assertRaisesRegex( # Should be # torch._dynamo.exc.Unsupported, # "Encountered aliasing during higher order op tracing for HOP.*" torch._dynamo.exc.UncapturedHigherOrderOpError, "Cond doesn't work unless it is captured completely with torch.compile.*", ): make_fx(f_wrapper(f), tracing_mode="symbolic")(example_input_func) def test_cond_functionalized_input_aliasing_with_aot_func(self): def true_fn(x): return x def false_fn(x): view_x = x.view(x.shape) return view_x def f(x): pred = x.sum() > 0 return cond(pred, true_fn, false_fn, [x]) example_input = torch.ones(5, 5) try: example_input_func = to_fun_old(example_input) torch._enable_functionalization(reapply_views=False) with self.assertRaisesRegex( # Should be # torch._dynamo.exc.Unsupported, # "Encountered aliasing during higher order op tracing for HOP.*" torch._dynamo.exc.UncapturedHigherOrderOpError, "Cond doesn't work unless it is captured completely with torch.compile.*", ): f(example_input_func) finally: torch._disable_functionalization() def f_wrapper(func): @functools.wraps(func) def wrapper(*args, **kwargs): torch._enable_functionalization(reapply_views=False) try: func_args = pytree.tree_map( lambda x: torch._to_functional_tensor(x) if isinstance(x, torch.Tensor) else x, args, ) func_kwargs = pytree.tree_map( lambda x: torch._to_functional_tensor(x) if isinstance(x, torch.Tensor) else x, kwargs, ) return func(*func_args, **func_kwargs) finally: torch._disable_functionalization() return wrapper with self.assertRaisesRegex( # Should be # torch._dynamo.exc.Unsupported, # "Encountered aliasing during higher order op tracing for HOP.*" torch._dynamo.exc.UncapturedHigherOrderOpError, "Cond doesn't work unless it is captured completely with torch.compile.*", ): make_fx(f_wrapper(f), tracing_mode="symbolic")(example_input) def test_cond_functionalized_aot_func_check_functional(self): def true_fn(x): return x.cos() def false_fn(x): y = x.sin() y.add_(5) return y def f(x): pred = x.shape[0] == 4 return cond(pred, true_fn, false_fn, [x]) example_input = torch.ones(5, 5) def f_wrapper(func): @functools.wraps(func) def wrapper(*args, **kwargs): torch._enable_functionalization(reapply_views=False) try: func_args = pytree.tree_map( lambda x: to_fun_old(x) if isinstance(x, torch.Tensor) else x, args, ) func_kwargs = pytree.tree_map( lambda x: to_fun_old(x) if isinstance(x, torch.Tensor) else x, kwargs, ) return pytree.tree_map( from_fun_old, func(*func_args, **func_kwargs) ) finally: torch._disable_functionalization() return wrapper result_gm = make_fx(f_wrapper(f), tracing_mode="symbolic")(example_input) for node in result_gm.true_graph_0.graph.nodes: if node.op == "call_function": self.assertTrue(not node.target._schema.is_mutable) for node in result_gm.false_graph_0.graph.nodes: if node.op == "call_function": self.assertTrue(not node.target._schema.is_mutable) self.assertEqual(result_gm(torch.ones(5, 5)), f(torch.ones(5, 5))) def test_cond_nested_traced_other_inputs(self): def true_nested(y): return y * y def false_nested(y): return y + y def true_fn(k, pred2): z = cond(pred2, true_nested, false_nested, [k]) return torch.add(torch.tensor([0.25, 0.25]), z) def false_fn(k, _): return k.cos() def f(k, pred, pred2): return cond(pred, true_fn, false_fn, [k, pred2]) x = torch.tensor([0.5, 0.5]) graph = make_fx(f)(x, torch.tensor(False), torch.tensor(False)) a = torch.tensor([1.0, 1.0]) result_true_true = graph.forward(a, torch.tensor(True), torch.tensor(True)) self.assertEqual(result_true_true, (a * a) + torch.tensor([0.25, 0.25])) b = torch.tensor([2.0, 2.0]) result_true_true = graph.forward(b, torch.tensor(True), torch.tensor(True)) self.assertEqual(result_true_true, (b * b) + torch.tensor([0.25, 0.25])) def test_cond_nested_traced_multi(self): def true_a(y): return y * y def false_a(y): return y + y def true_b(y, z): return y + z def false_b(y, z): return y * z def f(x, pred, pred2): a_out = cond(pred, true_a, false_a, [x]) b_out = cond(pred2, true_b, false_b, [x, x]) return a_out + b_out x = torch.randn(4) graph = make_fx(f)(x, torch.tensor(False), torch.tensor(False)) self.assertExpectedInline( graph.code.strip(), """\ def forward(self, x_1, pred_1, pred2_1): true_graph_0 = self.true_graph_0 false_graph_0 = self.false_graph_0 cond = torch.ops.higher_order.cond(pred_1, true_graph_0, false_graph_0, (x_1,)); pred_1 = true_graph_0 = false_graph_0 = None getitem = cond[0]; cond = None true_graph_1 = self.true_graph_1 false_graph_1 = self.false_graph_1 cond_1 = torch.ops.higher_order.cond(pred2_1, true_graph_1, false_graph_1, (x_1,)); pred2_1 = true_graph_1 = false_graph_1 = x_1 = None getitem_1 = cond_1[0]; cond_1 = None add = torch.ops.aten.add.Tensor(getitem, getitem_1); getitem = getitem_1 = None return add""", # noqa: B950 ) self.assertExpectedInline( graph.true_graph_0.code.strip(), """\ def forward(self, arg0_1): mul = torch.ops.aten.mul.Tensor(arg0_1, arg0_1); arg0_1 = None return (mul,)""", ) def test_raise_error_on_mismatch_type_size(self): def true_fn(x): return x.sin() def false_fn(x): return (x, x) def f(x, y): return cond(y, true_fn, false_fn, [x]) x = torch.randn(4) with self.assertRaisesRegex( # Should be # torch._dynamo.exc.Unsupported, # "Encountered aliasing during higher order op tracing for HOP.*" torch._dynamo.exc.UncapturedHigherOrderOpError, "Cond doesn't work unless it is captured completely with torch.compile.*", ): make_fx(f)(x, torch.tensor(False)) def test_raise_error_on_mismatch_tensor_size(self): def true_fn(x): return x.sin() def false_fn(x): return torch.zeros([10, 10]) def f(x, y): return cond(y, true_fn, false_fn, [x]) x = torch.randn(4) with self.assertRaisesRegex( torch._dynamo.exc.TorchRuntimeError, "When merging two branches' output in torch.cond", ): make_fx(f)(x, torch.tensor(False)) def test_cond_traced_not_nested_fake_tensor(self): def true_fn(x): return x.sin() def false_fn(x): return x.cos() def f(x, y): return cond(y, true_fn, false_fn, [x]) x = torch.randn(4) graph = make_fx(f, tracing_mode="fake")(x, torch.tensor(False)) result_true = graph.forward(x, torch.tensor(True)) result_false = graph.forward(x, torch.tensor(False)) self.assertFalse(torch.allclose(result_true, result_false)) self.assertEqual(result_true, torch.sin(x)) self.assertEqual(result_false, torch.cos(x)) def test_cond_nested_traced_fake_tensor(self): def true_nested(y): return y * y def false_nested(y): return y + y def true_fn(x, pred2): z = cond(pred2, true_nested, false_nested, [x]) return x + z def false_fn(x, _): return x.cos() def f(x, pred, pred2): return cond(pred, true_fn, false_fn, [x, pred2]) x = torch.randn(4) graph = make_fx(f, tracing_mode="fake")( x, torch.tensor(False), torch.tensor(False) ) result_true_true = graph.forward( x, torch.tensor(True), torch.tensor(True) ) # True + True -> x * x result_true_false = graph.forward( x, torch.tensor(True), torch.tensor(False) ) # True + True -> x + x result_false_true = graph.forward( x, torch.tensor(False), torch.tensor(True) ) # False + either -> cos result_false_false = graph.forward( x, torch.tensor(False), torch.tensor(False) ) # False + either -> cos self.assertNotEqual(result_true_true, result_true_false) self.assertFalse(torch.allclose(result_false_true, result_true_true)) self.assertEqual(result_false_true, result_false_false) self.assertEqual(result_true_true, (x * x) + x) self.assertEqual(result_true_false, x + x + x) self.assertEqual(result_false_true, torch.cos(x)) def test_cond_nested_traced_other_inputs_fake_tensor(self): def true_nested(y): return y * y def false_nested(y): return y + y def true_fn(k, pred2): z = cond(pred2, true_nested, false_nested, [k]) return torch.add(torch.tensor([0.25, 0.25]), z) def false_fn(k, _): return k.cos() def f(k, pred, pred2): return cond(pred, true_fn, false_fn, [k, pred2]) x = torch.tensor([0.5, 0.5]) graph = make_fx(f, tracing_mode="fake")( x, torch.tensor(False), torch.tensor(False) ) a = torch.tensor([1.0, 1.0]) result_true_true = graph.forward(a, torch.tensor(True), torch.tensor(True)) self.assertEqual(result_true_true, (a * a) + torch.tensor([0.25, 0.25])) b = torch.tensor([2.0, 2.0]) result_true_true = graph.forward(b, torch.tensor(True), torch.tensor(True)) self.assertEqual(result_true_true, (b * b) + torch.tensor([0.25, 0.25])) def test_cond_nested_traced_multi_fake_tensor(self): def true_a(y): return y * y def false_a(y): return y + y def true_b(y, z): return y + z def false_b(y, z): return y * z def f(x, pred, pred2): a_out = cond(pred, true_a, false_a, [x]) b_out = cond(pred2, true_b, false_b, [x, x]) return a_out + b_out x = torch.randn(4) graph = make_fx(f, tracing_mode="fake")( x, torch.tensor(False), torch.tensor(False) ) self.assertExpectedInline( graph.code.strip(), """\ def forward(self, x_1, pred_1, pred2_1): true_graph_0 = self.true_graph_0 false_graph_0 = self.false_graph_0 cond = torch.ops.higher_order.cond(pred_1, true_graph_0, false_graph_0, (x_1,)); pred_1 = true_graph_0 = false_graph_0 = None getitem = cond[0]; cond = None true_graph_1 = self.true_graph_1 false_graph_1 = self.false_graph_1 cond_1 = torch.ops.higher_order.cond(pred2_1, true_graph_1, false_graph_1, (x_1,)); pred2_1 = true_graph_1 = false_graph_1 = x_1 = None getitem_1 = cond_1[0]; cond_1 = None add = torch.ops.aten.add.Tensor(getitem, getitem_1); getitem = getitem_1 = None return add""", # noqa: B950 ) self.assertExpectedInline( graph.true_graph_0.code.strip(), """\ def forward(self, arg0_1): mul = torch.ops.aten.mul.Tensor(arg0_1, arg0_1); arg0_1 = None return (mul,)""", ) def test_raise_error_on_mismatch_type_size_fake_tensor(self): def true_fn(x): return x.sin() def false_fn(x): return (x, x) def f(x, y): return cond(y, true_fn, false_fn, [x]) x = torch.randn(4) with self.assertRaisesRegex( # Should be # torch._dynamo.exc.Unsupported, # "Encountered aliasing during higher order op tracing for HOP.*" torch._dynamo.exc.UncapturedHigherOrderOpError, "Cond doesn't work unless it is captured completely with torch.compile.*", ): make_fx(f, tracing_mode="fake")(x, torch.tensor(False)) def test_raise_error_on_mismatch_tensor_size_fake_tensor(self): def true_fn(x): return x.sin() def false_fn(x): return torch.zeros([10, 10]) def f(x, y): return cond(y, true_fn, false_fn, [x]) x = torch.randn(4) with self.assertRaisesRegex( torch._dynamo.exc.TorchRuntimeError, "When merging two branches' output in torch.cond", ): make_fx(f, tracing_mode="fake")(x, torch.tensor(False)) def check_map_count(self, gm, op_count): i = 0 for m in gm.modules(): for node in m.graph.nodes: if ( node.op == "call_function" and node.target == torch.ops.higher_order.map_impl ): i += 1 self.assertEqual(i, op_count) def test_tracing_map_real(self): def f(x, y): return x + y def g(xs, y): return control_flow.map(f, xs, y) gm = make_fx(g, tracing_mode="real")(torch.ones(3, 2, 2), torch.ones(2)) x = torch.randn(3, 2, 2) y = torch.randn(2) res = gm(x, y) self.assertEqual(res, g(x, y)) self.check_map_count(gm, 1) def test_tracing_map_symbolic_simple(self): def f(x, y): return x + y def g(xs, y): return control_flow.map(f, xs, y) gm = make_fx(g, tracing_mode="symbolic")(torch.ones(3, 2, 4), torch.ones(4)) x = torch.randn(3, 2, 2) y = torch.randn(2) res = gm(x, y) self.assertEqual(res, g(x, y)) self.check_map_count(gm, 1) def test_tracing_map_symbolic_list(self): def f(x, y): return [x[0][0] + y, x[1] * y] def g(xs, y, z): out = control_flow.map(f, xs, y) return out[0] + z, out[1] * z example_x = [[torch.ones(3, 4, 5)], torch.ones(3, 4, 5)] gm = make_fx(g, tracing_mode="symbolic")( example_x, torch.ones(5), torch.ones(5) ) x = [[torch.randn(4, 5, 6)], torch.ones(4, 5, 6)] y = torch.randn(6) z = torch.ones(6) res = gm(x, y, z) self.assertEqual(res, g(x, y, z)) self.check_map_count(gm, 1) def test_tracing_map_symbolic_dict(self): def f(x, y): return {"d": x["b"]["a"] + y, "e": x["c"] * y} def g(xs, y, z): out = control_flow.map(f, xs, y) return {"f": out["d"] + z, "g": out["e"] * z} example_x = {"b": {"a": torch.ones(3, 4, 5)}, "c": torch.ones(3, 4, 5)} gm = make_fx(g, tracing_mode="symbolic")( example_x, torch.ones(5), torch.ones(5) ) x = {"b": {"a": torch.randn(4, 5, 6)}, "c": torch.ones(4, 5, 6)} y = torch.randn(6) z = torch.ones(6) res = gm(x, y, z) self.assertEqual(res, g(x, y, z)) self.check_map_count(gm, 1) def test_tracing_map_autograd_symbolic_simple(self): def f(x, y): return x + y def g(xs, y): out = control_flow.map(f, xs, y) return torch.autograd.grad(out, (xs, y), torch.ones_like(out)) gm = make_fx(g, tracing_mode="symbolic")( torch.ones(3, 4, 5, requires_grad=True), torch.ones(5, requires_grad=True) ) x = torch.randn(4, 5, 6, requires_grad=True) y = torch.randn(6, requires_grad=True) res = gm(x, y) self.assertEqual(res, g(x, y)) self.check_map_count(gm, 2) def test_tracing_map_autograd_symbolic_list(self): import torch.utils._pytree as pytree def f(x, y): return [x[0].cos() + y.sin(), x[1].sin() * y.cos()] def g(xs, y): out = control_flow.map(f, xs, y) flat_out = pytree.tree_leaves(out) flat_inp = pytree.tree_leaves((xs, y)) requires_grad_inp = [inp for inp in flat_inp if inp.requires_grad] return torch.autograd.grad( flat_out, requires_grad_inp, [torch.ones_like(out) for out in flat_out] ) gm = make_fx(g, tracing_mode="symbolic")( [torch.ones(3, 4, 5), torch.ones(3, 4, 5, requires_grad=True)], torch.ones(5, requires_grad=True), ) x = [torch.randn(4, 5, 6), torch.ones(4, 5, 6, requires_grad=True)] y = torch.randn(6, requires_grad=True) res = gm(x, y) self.assertEqual(res, g(x, y)) self.check_map_count(gm, 2) def test_tracing_map_autograd_symbolic_dict(self): def f(x, y): return [x["a"] + y, x["b"] * y] def g(xs, y): out = control_flow.map(f, xs, y) flat_out = pytree.tree_leaves(out) flat_inp = pytree.tree_leaves((xs, y)) requires_grad_inp = [inp for inp in flat_inp if inp.requires_grad] return torch.autograd.grad( flat_out, requires_grad_inp, [torch.ones_like(out) for out in flat_out] ) traced_x = { "a": torch.ones(3, 4, 5, requires_grad=True), "b": torch.ones(3, 4, 5, requires_grad=True), } gm = make_fx(g, tracing_mode="symbolic")( traced_x, torch.ones(5, requires_grad=True) ) x = { "a": torch.randn(4, 5, 6, requires_grad=True), "b": torch.ones(4, 5, 6, requires_grad=True), } y = torch.randn(6, requires_grad=True) res = gm(x, y) self.assertEqual(res, g(x, y)) self.check_map_count(gm, 2) def test_tracing_map_autograd_aot_functionalized(self): def inner(x, y): z = x - 1 z.add_(1) return z * y def f(xs, y): res = control_flow.map(inner, xs, y) grads = torch.autograd.grad(res, (xs, y), torch.ones_like(res)) return grads def f_wrapper(func): @functools.wraps(func) def wrapper(*args, **kwargs): torch._enable_functionalization(reapply_views=False) try: return pytree.tree_map(from_fun_old, func(*args, **kwargs)) finally: torch._disable_functionalization() return wrapper example_inputs = ( torch.ones(3, 2, 4, requires_grad=True), torch.ones(2, 4, requires_grad=True), ) gm = make_fx(f, tracing_mode="symbolic")(*example_inputs) fgm = make_fx(f_wrapper(f), tracing_mode="symbolic")(*example_inputs) xs = torch.ones(3, 4, 5, requires_grad=True) y = torch.ones(4, 5, requires_grad=True) self.assertEqual(gm(xs, y), f(xs, y)) def count_mutable(gm): c = 0 for node in gm.graph.nodes: if node.op == "call_function": if node.target == torch.ops.higher_order.map_impl: c += count_mutable(getattr(gm, str(node.args[0]))) elif schema := getattr(node.target, "_schema", None): c += int(schema.is_mutable) return c self.assertEqual(count_mutable(fgm), 0) # One for forward, one for recomputation logic in backward self.assertEqual(count_mutable(gm), 2) def test_map_functionalized(self): def map_fn(x, y): z = x + y z.add_(4) return z def f(xs, y): return control_flow.map(map_fn, xs, y) example_inputs = (torch.ones(3, 2, 4), torch.ones(4)) functional_f = torch.func.functionalize(f) self.assertEqual(functional_f(*example_inputs), f(*example_inputs)) gm = make_fx(torch.func.functionalize(f))(*example_inputs) self.assertEqual(gm(*example_inputs), f(*example_inputs)) gm = make_fx(torch.func.functionalize(f), tracing_mode="symbolic")( *example_inputs ) self.assertEqual(gm(*example_inputs), f(*example_inputs)) for node in gm.body_graph_0.graph.nodes: if node.op == "call_function": self.assertTrue(not node.target._schema.is_mutable) self.check_map_count(gm, 1) def test_map_functionalized_aot_func(self): def map_fn(x, y): z = x + y z.add_(4) return z def f(xs, y): return control_flow.map(map_fn, xs, y) def f_wrapper(func): @functools.wraps(func) def wrapper(*args, **kwargs): torch._enable_functionalization(reapply_views=False) try: return pytree.tree_map(from_fun_old, func(*args, **kwargs)) finally: torch._disable_functionalization() return wrapper example_inputs = (torch.ones(3, 2, 4), torch.ones(4)) gm = make_fx(f_wrapper(f))(*example_inputs) for node in gm.body_graph_0.graph.nodes: if node.op == "call_function": self.assertTrue(not node.target._schema.is_mutable) self.assertEqual(gm(*example_inputs), f(*example_inputs)) def test_map_functionalized_arg_mutation(self): def map_fn(x, y): y.add_(4) return x + y def f(xs, y): return control_flow.map(map_fn, xs, y) example_inputs = (torch.ones(3, 2, 4), torch.ones(4)) functional_f = torch.func.functionalize(f) with self.assertRaisesRegex( torch._dynamo.exc.TorchRuntimeError, "map might be modifying the input!", ): functional_f(*example_inputs) def test_map_functionalized_elem_mutation(self): def map_fn(x, y): x.add_(4) return x + y def f(xs, y): return control_flow.map(map_fn, xs, y) example_inputs = (torch.ones(3, 2, 4), torch.ones(4)) functional_f = torch.func.functionalize(f) with self.assertRaisesRegex( torch._dynamo.exc.TorchRuntimeError, "map might be modifying the input!" ): functional_f(*example_inputs) def test_cond_autograd_backward(self): def true_fn(x): return x.cos() def false_fn(x): return x.sin() def f(x, y): return control_flow.cond(x.shape[0] > 4, true_fn, false_fn, [y]) example_inputs = ( torch.ones(3, 2, 4, requires_grad=True), torch.ones(4, requires_grad=True), ) f(*example_inputs).sum().backward() # Ensure no error is thrown when not running backward res = f(*example_inputs) # Ensure no error is thrown when not running backward res_compiled = torch.compile(f)(*example_inputs) self.assertEqual(res, res_compiled) def test_map_functionalized_elem_alias(self): def map_fn(x): x.view(x.shape) return x def f(xs): return control_flow.map(map_fn, xs) example_inputs = (torch.ones(3, 2, 4),) functional_f = torch.func.functionalize(f) with self.assertRaisesRegex( # Should be # torch._dynamo.exc.Unsupported, # "Encountered aliasing during higher order op tracing.*" torch._dynamo.exc.UncapturedHigherOrderOpError, "map doesn't work unless it is captured completely with torch.compile.*", ): functional_f(*example_inputs) def test_nested_map_cond_real(self): def true_fn(x, y): return x * y def false_fn(x, y): return x + y def f(x, pred, y): return cond(pred, true_fn, false_fn, [x, y]) def g(pred, xs, y): return control_flow.map(f, xs, pred, y) gm = make_fx(g, tracing_mode="real")( torch.tensor(True), torch.ones(3, 2, 4), torch.ones(4) ) pred = torch.tensor(False) x = torch.randn(3, 2, 4) y = torch.randn(4) res = gm(pred, x, y) self.assertEqual(res, g(pred, x, y)) self.check_map_count(gm, 1) def test_nested_map_cond_symbolic(self): def true_fn(x, y): return x * y def false_fn(x, y): return x + y def f(x, pred, y): return cond(pred, true_fn, false_fn, [x, y]) def g(pred, xs, y): return control_flow.map(f, xs, pred, y) gm = make_fx(g, tracing_mode="symbolic")( torch.tensor(True), torch.ones(3, 2, 4), torch.ones(4) ) pred = torch.tensor(False) x = torch.randn(3, 2, 2) y = torch.randn(2) res = gm(pred, x, y) self.assertEqual(res, g(pred, x, y)) self.check_map_count(gm, 1) def test_nested_cond_map_cond_symbolic(self): def true_fn(x, y): return x * y def false_fn(x, y): return x + y def f(x, pred, y): return cond(pred, true_fn, false_fn, [x, y]) def g(pred, xs, y): return control_flow.map(f, xs, pred, y) def main_true_fn(pred, xs, y): return g(pred, xs, y) * 2 def main_false_fn(pred, xs, y): return g(pred, xs, y) + 1 def main(p, pred, xs, y): return cond(p, main_true_fn, main_false_fn, [pred, xs, y]) gm = make_fx(main, tracing_mode="symbolic")( torch.tensor(True), torch.tensor(True), torch.ones(3, 2, 4), torch.ones(4) ) p = torch.tensor(False) pred = torch.tensor(False) xs = torch.randn(3, 2, 2) y = torch.randn(2) res = gm(p, pred, xs, y) self.assertEqual(res, main(p, pred, xs, y)) self.check_map_count(gm, 2) def test_cond_with_sym_pred(self): def true_fn(x): return x + x def false_fn(x): return x * x def foo(x): return cond(x.shape[0] == 4, true_fn, false_fn, [x]) gm = make_fx(foo, tracing_mode="symbolic")(torch.ones(3, 2, 1)) # The symbols in make_fx's shape_env should not be specialized. self.assertEqual(len(gm.shape_env.guards), 0) self.assertExpectedInline( gm.code.strip(), """\ def forward(self, x_1): sym_size_int = torch.ops.aten.sym_size.int(x_1, 0) eq = sym_size_int == 4 sym_size_int_1 = torch.ops.aten.sym_size.int(x_1, 1) true_graph_0 = self.true_graph_0 false_graph_0 = self.false_graph_0 cond = torch.ops.higher_order.cond(eq, true_graph_0, false_graph_0, (x_1, sym_size_int_1, sym_size_int)); eq = true_graph_0 = false_graph_0 = x_1 = sym_size_int_1 = sym_size_int = None getitem = cond[0]; cond = None return getitem""", # noqa: B950 ) # We expect the traced graph module to work even if input size changes. x = torch.ones(4, 3, 2) self.assertEqual(gm(x), true_fn(x)) self.assertEqual(foo(x), true_fn(x)) def test_cond_with_unbacked_sym_pred(self): def foo(x): def true_fn(x): return x + x def false_fn(x): return x * x az = x.nonzero() return cond(az.shape[0] > 3, true_fn, false_fn, (x,)) gm = make_fx(foo, tracing_mode="symbolic")(torch.randn(7)) self.assertExpectedInline( gm.code.strip(), """\ def forward(self, x_1): nonzero = torch.ops.aten.nonzero.default(x_1) sym_size_int = torch.ops.aten.sym_size.int(nonzero, 0); nonzero = None gt = sym_size_int > 3; sym_size_int = None sym_size_int_1 = torch.ops.aten.sym_size.int(x_1, 0) true_graph_0 = self.true_graph_0 false_graph_0 = self.false_graph_0 cond = torch.ops.higher_order.cond(gt, true_graph_0, false_graph_0, (x_1, sym_size_int_1)); gt = true_graph_0 = false_graph_0 = x_1 = sym_size_int_1 = None getitem = cond[0]; cond = None return getitem""", # noqa: B950 ) def _check_closure_correctly_lifted(self, f, *, args, exp_res, exp_arg_num): assert isinstance(args, (tuple, list)) self.assertEqual(f(*args), exp_res) gm = make_fx(f)(*args) self.assertEqual(gm(*args), exp_res) def cnt_placeholder(gm): return len([node for node in gm.graph.nodes if node.op == "placeholder"]) placeholder_cnts = [cnt_placeholder(mod) for mod in gm.children()] self.assertTrue(all(cnt == exp_arg_num for cnt in placeholder_cnts)) def _check_closure_correctly_lifted_with_mutation( self, f, closures_to_be_mutated, *, args, exp_arg_num ): exp_res = f(*args) self._check_closure_correctly_lifted( f, args=args, exp_res=exp_res, exp_arg_num=exp_arg_num ) for closure in closures_to_be_mutated: closure.add(-1) new_exp_res = f(*args) self._check_closure_correctly_lifted( f, args=args, exp_res=new_exp_res, exp_arg_num=exp_arg_num ) def test_cond_with_tensor_closure(self): a = torch.ones(2, 3) b = torch.ones(2, 3) + 1 def true_fn(x): return x + a def false_fn(x): return x + b def foo(x): return cond(x.shape[0] == 4, true_fn, false_fn, [x]) # expected branches takes [x, a, b] as input inp = torch.randn(2, 3) self._check_closure_correctly_lifted_with_mutation( foo, (a, b), args=(inp,), exp_arg_num=3 ) def test_cond_with_tensor_closure_graph_module(self): a = torch.ones(2, 3) b = torch.ones(2, 3) + 1 def true_fn(x): return x + a def false_fn(x): return x + b def foo(x): return cond(x.shape[0] == 4, true_fn, false_fn, [x]) # expected branches takes [x, a, b] as input inp = torch.randn(2, 3) gm = make_fx(foo, tracing_mode="symbolic", _allow_non_fake_inputs=True)(inp) self.assertExpectedInline( gm.code.strip(), """\ def forward(self, x_1): sym_size_int = torch.ops.aten.sym_size.int(x_1, 0) eq = sym_size_int == 4 sym_size_int_1 = torch.ops.aten.sym_size.int(x_1, 1) true_graph_0 = self.true_graph_0 false_graph_0 = self.false_graph_0 _tensor_constant0 = self._tensor_constant0 _tensor_constant1 = self._tensor_constant1 cond = torch.ops.higher_order.cond(eq, true_graph_0, false_graph_0, (x_1, _tensor_constant0, sym_size_int_1, sym_size_int, _tensor_constant1)); eq = true_graph_0 = false_graph_0 = x_1 = _tensor_constant0 = sym_size_int_1 = sym_size_int = _tensor_constant1 = None getitem = cond[0]; cond = None return getitem""", # noqa: B950 ) self.assertExpectedInline( gm.true_graph_0.code.strip(), """\ def forward(self, arg0_1, arg1_1, arg2_1, arg3_1, arg4_1): add = torch.ops.aten.add.Tensor(arg0_1, arg1_1); arg0_1 = arg1_1 = None return (add,)""", ) def test_cond_with_module_param_closure(self): class Mod(torch.nn.Module): def __init__(self) -> None: super().__init__() self.register_parameter( "param", torch.nn.Parameter(torch.ones(2, 3), requires_grad=False) ) self.buffer = torch.nn.Buffer(torch.ones(2, 3) + 1) my_mode = Mod() def true_fn(x): return x + my_mode.param def false_fn(x): return x + my_mode.buffer def foo(x): return cond(x.shape[0] == 4, true_fn, false_fn, [x]) inp = torch.ones(2, 3) # expected both branches takes (x, param, buffer) self._check_closure_correctly_lifted_with_mutation( foo, (my_mode.param, my_mode.buffer), args=(inp,), exp_arg_num=3 ) def test_cond_with_module_python_scalar_closure(self): def foo(x): a = torch.ones(1, 1) b = 1 def true_fn(x): return x + a def false_fn(x): return x + b return cond(x.shape[0] == 4, true_fn, false_fn, [x]) inp = torch.ones(2, 3) res = inp + 1 # python scalar b is not lifted as input, so both branches take (x, a) self._check_closure_correctly_lifted( foo, args=(inp,), exp_res=res, exp_arg_num=2 ) def test_cond_nested_with_closure(self): a = torch.ones(1, 1) b = torch.ones(1, 1) + 1 def inner_true_fn(x): return x + a def inner_false_fn(x): return x + b def foo(x): def true_fn(x): return cond(x.shape[0] == 2, inner_true_fn, inner_false_fn, [x]) def false_fn(x): return cond(x.shape[0] > 4, inner_true_fn, inner_false_fn, [x]) return cond(x.shape[0] == 4, true_fn, false_fn, [x]) inp = torch.ones(2, 3) # For top-level cond, it take 3 arguments (x, a, b). Dynamo should # realize that the nonlocal variables are same for the true and false # branches, so it should de-dupe them. # For second-level conds, it takes (x, a, b) self._check_closure_correctly_lifted_with_mutation( foo, (a, b), args=(inp,), exp_arg_num=3 ) def test_cond_nested_with_closure_graph_module(self): a = torch.ones(1, 1) b = torch.ones(1, 1) + 1 def inner_true_fn(x): return x + a def inner_false_fn(x): return x + b def foo(x): def true_fn(x): return cond(x.shape[0] == 2, inner_true_fn, inner_false_fn, [x]) def false_fn(x): return cond(x.shape[0] > 4, inner_true_fn, inner_false_fn, [x]) return cond(x.shape[0] == 4, true_fn, false_fn, [x]) def test_map_unfunc_boolean_tensor_for_nested_map_cond(self): def map_fn(pred, x): def fn(x, pred): return control_flow.cond(pred, lambda x: x * 2, lambda x: x / 2, (x,)) return control_flow.map(fn, x, pred) def f_wrapper(func): @functools.wraps(func) def wrapper(*args, **kwargs): torch._enable_functionalization(reapply_views=False) try: func_args = pytree.tree_map( lambda x: to_fun_old(x) if isinstance(x, torch.Tensor) else x, args, ) func_kwargs = pytree.tree_map( lambda x: to_fun_old(x) if isinstance(x, torch.Tensor) else x, kwargs, ) return pytree.tree_map( from_fun_old, func(*func_args, **func_kwargs) ) finally: torch._disable_functionalization() return wrapper gm = make_fx(f_wrapper(map_fn))( torch.tensor(True), torch.ones([2, 3], requires_grad=False) ) self.assertExpectedInline( gm.code.strip(), """\ def forward(self, pred_1, x_1): unbind = torch.ops.aten.unbind.int(x_1) getitem = unbind[0]; getitem = None getitem_1 = unbind[1]; unbind = getitem_1 = None body_graph_0 = self.body_graph_0 map_impl = torch.ops.higher_order.map_impl(body_graph_0, [x_1], [pred_1]); body_graph_0 = x_1 = pred_1 = None getitem_2 = map_impl[0]; map_impl = None return getitem_2""", ) self.assertExpectedInline( gm.body_graph_0.code.strip(), """\ def forward(self, arg0_1, arg1_1): true_graph_0 = self.true_graph_0 false_graph_0 = self.false_graph_0 cond = torch.ops.higher_order.cond(arg1_1, true_graph_0, false_graph_0, (arg0_1,)); arg1_1 = true_graph_0 = false_graph_0 = arg0_1 = None getitem = cond[0]; cond = None return (getitem,)""", # noqa: B950 ) @skipIfCrossRef # Arg order changes with crossref def test_cond_make_fx_preserve_stack_trace_for_nodes_in_subgraph(self): def true_fn(x): return x + x.cos() def false_fn(x): return x * x.sin() def foo(x): return cond(x.shape[0] == 4, true_fn, false_fn, (x,)) inp = torch.randn([4, 3]) gm, _ = torch._dynamo.export(foo)(inp) def run_with_interpreter(*args): with torch.fx.traceback.preserve_node_meta(): return torch.fx.Interpreter(gm).run(*args) new_gm = make_fx(run_with_interpreter)(inp) checked_ops = {"add", "mul", "sin", "cos"} checked_meta = ["source_fn_stack", "stack_trace"] all_source_fns = collect_meta_for_filtered_nodes(gm, checked_ops, checked_meta) new_source_fns = collect_meta_for_filtered_nodes( new_gm, checked_ops, checked_meta ) self.assertEqual(all_source_fns, new_source_fns) @unittest.skipIf( TEST_WITH_TORCHDYNAMO, "triggers cache limit for foo and changes unique_graphs count.", ) def test_cond_no_dynamo_cache_limit(self): torch._dynamo.reset() counters = torch._dynamo.utils.counters counters.clear() def foo(x, true_fn, false_fn): return cond(x.sum() < 0, true_fn, false_fn, (x,)) inp = torch.ones(3, 4) exp_out = inp.sin() iter_n = torch._dynamo.config.recompile_limit + 1 # Need functions that cause recompilations def get_dummy_fns(str): def dummy_cos(x): return x.cos() + len(str) - len(str) def dummy_sin(x): return x.sin() + len(str) - len(str) return dummy_cos, dummy_sin for i in range(iter_n): # we fail guards each iter because `str(i)` is different self.assertEqual(foo(inp, *get_dummy_fns(str(i))), exp_out) # each iteration captures a cond and a getitem from the tuple output self.assertEqual(counters["stats"]["calls_captured"], iter_n * 2) self.assertEqual(counters["stats"]["unique_graphs"], iter_n) def test_cond_with_consecutive_make_fx_symbolic(self): def true_fn(x): return x - x.cos() def false_fn(x): return x + x.sin() def foo(x): return cond(x.shape[0] == 4, true_fn, false_fn, [x]) inps = (torch.ones(3, 4), torch.ones(3, 5), torch.ones(5, 4), torch.ones(5, 3)) for inp in inps: gm = make_fx(foo, tracing_mode="symbolic")(torch.ones(3, 4)) self.assertExpectedInline( gm.code.strip(), """\ def forward(self, x_1): sym_size_int = torch.ops.aten.sym_size.int(x_1, 0) eq = sym_size_int == 4 sym_size_int_1 = torch.ops.aten.sym_size.int(x_1, 1) true_graph_0 = self.true_graph_0 false_graph_0 = self.false_graph_0 cond = torch.ops.higher_order.cond(eq, true_graph_0, false_graph_0, (x_1, sym_size_int_1, sym_size_int)); eq = true_graph_0 = false_graph_0 = x_1 = sym_size_int_1 = sym_size_int = None getitem = cond[0]; cond = None return getitem""", # noqa: B950 ) self.assertExpectedInline( gm.true_graph_0.code.strip(), """\ def forward(self, arg0_1, arg1_1, arg2_1): cos = torch.ops.aten.cos.default(arg0_1) sub = torch.ops.aten.sub.Tensor(arg0_1, cos); arg0_1 = cos = None return (sub,)""", ) self.assertExpectedInline( gm.false_graph_0.code.strip(), """\ def forward(self, arg0_1, arg1_1, arg2_1): sin = torch.ops.aten.sin.default(arg0_1) add = torch.ops.aten.add.Tensor(arg0_1, sin); arg0_1 = sin = None return (add,)""", ) def _create_test_fns_for_cond( self, pred, inner_most_fn, operands, closure_list, nested_level ): if nested_level == 0: if len(closure_list) > 0: def true_fn(*operands): return inner_most_fn(*operands) + inner_most_fn(*closure_list) def false_fn(*operands): return inner_most_fn(*operands) - inner_most_fn(*closure_list) else: def true_fn(*operands): return inner_most_fn(*operands) def false_fn(*operands): return inner_most_fn(*operands) def fn(*operands): if len(operands) == 0 and len(closure_list) == 0: return torch.zeros(1) return cond(pred, true_fn, false_fn, operands) return operands, fn else: args, inner_fn = self._create_test_fns_for_cond( pred <= 0, inner_most_fn, operands, closure_list, nested_level - 1 ) def true_fn(*operands): return inner_most_fn(*operands) + inner_fn(*args) def false_fn(*operands): return inner_most_fn(*operands) - inner_fn(*args) def fn(*operands): if len(operands) == 0 and len(closure_list) == 0: return torch.ones(1) return cond(pred, true_fn, false_fn, operands) return operands, fn def _init_predicate(self, pred_type): if pred_type == "bool": return True elif pred_type == "intTensor": return torch.tensor(1) elif pred_type == "floatTensor": return torch.tensor(1.0) elif pred_type == "boolTensor": return torch.tensor(False) else: raise NotImplementedError def _init_fn(self, inner_fn_type): if inner_fn_type == "function": return reduce_func elif inner_fn_type == "module": return ReduceMod() elif inner_fn_type == "object": return ReduceObj() else: raise NotImplementedError @parametrize("predType", ["bool", "intTensor", "floatTensor", "boolTensor"]) @parametrize("innerFnType", ["function", "module", "object"]) @parametrize("nOperands", [0, 1]) @parametrize("nClosure", [0, 1]) @parametrize("nesting", [0, 2]) def test_cond_tracing_with_valid_inputs( self, predType, innerFnType, nOperands, nClosure, nesting ): pred = self._init_predicate(predType) inner_fn = self._init_fn(innerFnType) operands = [torch.ones(2, 3) + i for i in range(nOperands)] closure = [torch.ones(2, 3) - i for i in range(nClosure)] args, fn = self._create_test_fns_for_cond( pred, inner_fn, operands, closure, nesting ) eager_res = fn(*args) for tracing_mode in ["symbolic", "fake", "real"]: # set _allow_non_fake_inputs = True to allow fake prop through closures with self.subTest(tracing_mode=tracing_mode): gm = make_fx( fn, tracing_mode=tracing_mode, _allow_non_fake_inputs=True )(*args) self.assertEqual(gm(*args), eager_res) @parametrize("predType", ["boolTensor"]) @parametrize("innerFnType", ["function", "module", "object"]) @parametrize("nOperands", [1, 2]) @parametrize("nClosure", [0, 1]) @parametrize("nesting", [0]) def test_cond_vmap(self, predType, innerFnType, nOperands, nClosure, nesting): pred = self._init_predicate(predType) inner_fn = self._init_fn(innerFnType) operands = [torch.ones(2, 3) + i for i in range(nOperands)] closure = [torch.ones(2, 3) - i for i in range(nClosure)] args, fn = self._create_test_fns_for_cond( pred, inner_fn, operands, closure, nesting ) eager_res = fn(*args) out = torch.vmap(fn)(*args) if nClosure == 0: self.assertEqual(eager_res, out) else: self.assertEqual(eager_res, out[0]) self.assertEqual(eager_res, out[1]) def test_cond_vmap_simple(self): def fn(x): return torch.cond( pred=torch.tensor([True]), true_fn=lambda x: x + 100, false_fn=lambda x: x.clone(), operands=(x,), ) a = torch.arange(15).reshape((3, 5)) res = torch.vmap(fn, in_dims=(0,))(a) self.assertEqual(res.shape, (3, 5)) self.assertEqual(res, a + 100) def test_cond_vmap_multiple_inputs(self): def fn(x, y): return torch.cond( pred=x.sum() < y.sum(), true_fn=lambda x, y: x + 100, false_fn=lambda x, y: y.clone(), operands=(x, y), ) a = torch.arange(15).reshape(3, 5) b = torch.ones_like(a) + 3 res = torch.vmap(fn, in_dims=(0, 0))(a, b) expected = torch.tensor( [[100, 101, 102, 103, 104], [4, 4, 4, 4, 4], [4, 4, 4, 4, 4]] ) self.assertEqual(res.shape, (3, 5)) self.assertEqual(expected, res) def test_cond_vmap_single_input_with_closure(self): a = torch.ones((3, 5)) + 3 c = torch.arange(5) def fn(x): return torch.cond( pred=torch.tensor([True]), true_fn=lambda x: x + c, false_fn=lambda x: x - c, operands=(x,), ) res = torch.vmap(fn, in_dims=(0,))( a, ) with unittest.mock.patch("torch._dynamo.config.error_on_recompile", True): res = torch.vmap(fn, in_dims=(0,))( a, ) self.assertEqual(a + c, res) def test_cond_vmap_multiple_args_with_closure(self): a = torch.ones((3, 5), dtype=torch.int64) + 3 b = torch.arange(15).reshape(3, 5) c = torch.arange(5) def fn(x, y): return torch.cond( pred=torch.tensor([False]), true_fn=lambda x, y: x + c, false_fn=lambda x, y: y - c, operands=(x, y), ) res = torch.vmap(fn)(a, b) self.assertEqual(b - c, res) @parametrize("nClosure", [0, 1]) def test_cond_vmap_multiple_outputs(self, nClosure): if nClosure: c = torch.ones(5, dtype=torch.int64) + 5 def fn(x): return torch.cond( pred=torch.tensor([True]), true_fn=lambda x: (x + c, x - c), false_fn=lambda x: (x.clone(), x.clone()), operands=(x,), ) else: def fn(x): return torch.cond( pred=torch.tensor([True]), true_fn=lambda x: (x + 1, x - 1), false_fn=lambda x: (x.clone(), x.clone()), operands=(x,), ) a = torch.arange(15).reshape(3, 5) res = torch.vmap(fn)( a, ) self.assertEqual(len(res), 2) if nClosure: self.assertEqual(res, (a + c, a - c)) else: self.assertEqual(res, (a + 1, a - 1)) @parametrize("boolcond", [True, False]) def test_vmap_vmap(self, boolcond): def fn(x): return torch.cond( pred=torch.tensor([True]) if not boolcond else True, true_fn=lambda x: x + 1, false_fn=lambda x: x - 1, operands=(x,), ) def wrapper(x): return torch.vmap(fn)(x) a = torch.ones((3, 4, 5)) res = torch.vmap(wrapper)(a) self.assertEqual(res, a + 1) def test_cond_trace_set__and_mutate_input(self): def f(a, tmp): a_view = a.view(-1) with torch.no_grad(): a.set_(tmp) a_view.mul_(2) return a + tmp inp = torch.ones(3, 3, requires_grad=True) tmp = torch.ones(3, 3, requires_grad=True) # graph break: torch._dynamo.exc.Unsupported: call_function DelayGraphBreakVariable() [TensorVariable()] {} # due to set_ with self.assertRaisesRegex( torch._dynamo.exc.UncapturedHigherOrderOpError, "Cond doesn't work unless it is captured completely with torch.compile", ): torch.cond(inp.sum() > 0, f, f, (inp, tmp)) @skipIfCrossRef # Arg order changes with crossref def test_cond_trace_set__and_mutate_intermediate(self): def f(a, tmp): a = a.clone() a_view = a.view(-1) tmp = tmp.clone() with torch.no_grad(): a.set_(tmp) a_view.mul_(2) return a + tmp inp = torch.ones(3, 3, requires_grad=True) tmp = torch.ones(3, 3, requires_grad=True) class Mod(torch.nn.Module): def forward(self, inp: torch.Tensor, tmp: torch.Tensor) -> torch.Tensor: return torch.cond(inp.sum() > 0, f, f, (inp, tmp)) with self.assertRaisesRegex( RuntimeError, "cannot mutate tensors with frozen storage" ): out = torch.compile(Mod(), backend="aot_eager")(inp, tmp) with self.assertRaisesRegex( RuntimeError, "cannot mutate tensors with frozen storage" ): out = torch.compile(Mod(), backend="inductor")(inp, tmp) from torch._dynamo.testing import EagerAndRecordGraphs backend = EagerAndRecordGraphs() out = torch.compile(Mod(), backend=backend)(inp, tmp) self.assertExpectedInline( backend.graphs[0].cond_true_0.code.strip("\n"), """\ def forward(self, l_inp_, l_tmp_): l_inp__1 = l_inp_ l_tmp__1 = l_tmp_ a = l_inp__1.clone(); l_inp__1 = None a_view = a.view(-1) tmp = l_tmp__1.clone(); l_tmp__1 = None _set_grad_enabled = torch._C._set_grad_enabled(False); _set_grad_enabled = None set_ = a.set_(tmp); set_ = None mul_ = a_view.mul_(2); a_view = mul_ = None _set_grad_enabled_1 = torch._C._set_grad_enabled(True); _set_grad_enabled_1 = None add = a + tmp; a = tmp = None return (add,) """, ) self.assertEqual(out, f(inp, tmp)) @parametrize("requires_grad", [True, False]) def test_cond_symint_operands(self, requires_grad): from torch._dynamo.testing import EagerAndRecordGraphs backend = EagerAndRecordGraphs() class Mod(torch.nn.Module): def __init__(self): super().__init__() self.num = 3 def forward(self, a, b): return torch.cond( pred=torch.tensor([True]), true_fn=lambda a, b: a + b + self.num, false_fn=lambda a, b: a - b - self.num, operands=(a, b), ) a = torch.ones(3, 3, requires_grad=requires_grad) b = torch.ones(3, 3, requires_grad=requires_grad) out = torch.compile(Mod(), backend=backend, dynamic=True)(a, b) self.assertEqual(out, Mod()(a, b)) self.assertEqual(len(backend.graphs), 1) self.assertExpectedInline( backend.graphs[0].code.strip(), """\ def forward(self, s97 : torch.SymInt, L_a_ : torch.Tensor, L_b_ : torch.Tensor): l_a_ = L_a_ l_b_ = L_b_ tensor = torch.tensor([True]) cond_true_0 = self.cond_true_0 cond_false_0 = self.cond_false_0 cond = torch.ops.higher_order.cond(tensor, cond_true_0, cond_false_0, (l_a_, l_b_, s97)); tensor = cond_true_0 = cond_false_0 = l_a_ = l_b_ = s97 = None getitem = cond[0]; cond = None return (getitem,)""", # noqa: B950 ) def test_two_hops_not_sharing_code_obj(self): pred, args = torch.tensor(True), (torch.ones(3, 3),) def fn1(x): return x + 1 def fn2(x): return x - 1 from torch._dynamo.testing import CompileCounter # Tests rely on automatic_dynamic = True with torch._dynamo.config.patch(automatic_dynamic_shapes=True): cnt = CompileCounter() torch.compile(torch.cond, backend=cnt)(pred, fn1, fn2, args) self.assertEqual(cnt.frame_count, 1) args = (torch.randn(3, 3),) # No recompilation torch.compile(torch.cond, backend=cnt)(pred, fn1, fn2, args) self.assertEqual(cnt.frame_count, 1) def cond_fn(x): return x.sum() > 0 args = (torch.randn(4, 4),) torch.compile(torch.while_loop, backend=cnt)(cond_fn, fn2, args) # recompilation self.assertEqual(cnt.frame_count, 2) args = (torch.randn(4, 4),) torch.compile(torch.while_loop, backend=cnt)(cond_fn, fn2, args) self.assertEqual(cnt.frame_count, 2) # With recompilation due to automatic dynamic # This also proves that while_loop doesn't share code obj with cond torch.compile(torch.cond, backend=cnt)(pred, fn1, fn2, (torch.randn(4, 4),)) self.assertEqual(cnt.frame_count, 3) def test_hop_raises_if_not_overriding_call(self): class WrongHop(torch._ops.HigherOrderOperator): pass with self.assertRaisesRegex(TypeError, "WrongHop"): WrongHop("wrong_hop") def test_scan_functionalized(self): def f(init, xs): return scan(get_scan_combine_fn("add", False), init, xs, dim=1) example_inputs = torch.ones(5, 7, 4) example_init = torch.ones(5, 4) functional_f = torch.func.functionalize(f) self.assertEqual( functional_f(example_init, example_inputs), f(example_init, example_inputs) ) def test_scan_functionalized_elem_mutation(self): def add1(x, y): x.add_(4) return x + y, x + y def f(init, xs): return scan(add1, init, xs, dim=1) example_inputs = torch.ones(5, 7, 4) example_init = torch.ones(5, 4) functional_f = torch.func.functionalize(f) with self.assertRaisesRegex( # TODO: Fix this so that the HOPs show similar errors for functionalization # This is the Exception with PYTORCH_TEST_WITH_DYNAMO=0 # RuntimeError, # "torch.scan might be modifying the input!", # This is the Exception with PYTORCH_TEST_WITH_DYNAMO=1 # torch._dynamo.exc.TorchDynamoException, # "Unexpected exception when running generated GraphModule.*" Exception, ".*", ): functional_f(example_init, example_inputs) def add2(x, y): y.add_(4) return x + y, x + y def f(init, xs): return scan(add2, init, xs, dim=1) functional_f = torch.func.functionalize(f) with self.assertRaisesRegex( # TODO: Fix this so that the HOPs show similar errors for functionalization # Should be # This is the Exception with PYTORCH_TEST_WITH_DYNAMO=0 # RuntimeError, # "torch.scan might be modifying the input!", # This is the Exception with PYTORCH_TEST_WITH_DYNAMO=1 # torch._dynamo.exc.TorchDynamoException, # "Unexpected exception when running generated GraphModule.*" Exception, ".*", ): functional_f(example_init, example_inputs) def test_scan_functionalized_elem_alias(self): def add(x, y): return x, x def f(init, xs): return scan(add, init, xs, dim=1) example_inputs = torch.ones(5, 7, 4) example_init = torch.ones(5, 4) functional_f = torch.func.functionalize(f) with self.assertRaisesRegex( # TODO: Fix this so that the HOPs show similar errors for functionalization # Should be # This is the Exception with PYTORCH_TEST_WITH_DYNAMO=0 # torch._dynamo.exc.Unsupported, # "Encountered aliasing during higher order op tracing for HOP.*" # This is the Exception with PYTORCH_TEST_WITH_DYNAMO=1 # torch._dynamo.exc.UncapturedHigherOrderOpError, # "scan must be captured completely with torch.compile.*", Exception, ".*", ): functional_f(example_init, example_inputs) @skipIfTorchDynamo("Graph is not captured by backend if test with dynamo") def test_scan_pytree_closure(self): from torch._dynamo.testing import EagerAndRecordGraphs param_buffer = ({"param": torch.randn(3, 3)}, (torch.randn(3),)) def add(carry, x): ret = (carry @ param_buffer[0]["param"]) @ x + param_buffer[1][0] return ret, ret.sum() def f(init, xs): return scan(add, init, xs) init = torch.randn(4, 3) xs = torch.randn(3, 3, 3) backend = EagerAndRecordGraphs() eager_out = f(init, xs) compiled_out = torch.compile(f, backend=backend)(init, xs) exp_out = _fake_scan(add, init, xs) self.assertEqual(len(backend.graphs), 1) if TEST_WITH_CROSSREF: self.assertExpectedInline( backend.graphs[0].code.strip(), """\ def forward(self, L_init_ : torch.Tensor, L_xs_ : torch.Tensor, L_add_closure_0_cell_contents_0_param_ : torch.Tensor, L_add_closure_0_cell_contents_1_0_ : torch.Tensor): l_init_ = L_init_ l_xs_ = L_xs_ l_add_closure_0_cell_contents_0_param_ = L_add_closure_0_cell_contents_0_param_ l_add_closure_0_cell_contents_1_0_ = L_add_closure_0_cell_contents_1_0_ r = torch.movedim(l_xs_, 0, 0); l_xs_ = None scan_combine_fn_0 = self.scan_combine_fn_0 scan = torch.ops.higher_order.scan(scan_combine_fn_0, [l_init_], [r], [l_add_closure_0_cell_contents_0_param_, l_add_closure_0_cell_contents_1_0_]); scan_combine_fn_0 = l_init_ = r = l_add_closure_0_cell_contents_0_param_ = l_add_closure_0_cell_contents_1_0_ = None carry = scan[0] out = scan[1]; scan = None return (carry, out)""", # noqa: B950 ) else: self.assertExpectedInline( backend.graphs[0].code.strip(), """\ def forward(self, L_init_ : torch.Tensor, L_xs_ : torch.Tensor, L_add_closure_0_cell_contents_0_param_ : torch.Tensor, L_add_closure_0_cell_contents_1_0_ : torch.Tensor): l_init_ = L_init_ l_xs_ = L_xs_ l_add_closure_0_cell_contents_0_param_ = L_add_closure_0_cell_contents_0_param_ l_add_closure_0_cell_contents_1_0_ = L_add_closure_0_cell_contents_1_0_ movedim = torch.movedim(l_xs_, 0, 0); l_xs_ = None scan_combine_fn_0 = self.scan_combine_fn_0 scan = torch.ops.higher_order.scan(scan_combine_fn_0, [l_init_], [movedim], [l_add_closure_0_cell_contents_0_param_, l_add_closure_0_cell_contents_1_0_]); scan_combine_fn_0 = l_init_ = movedim = l_add_closure_0_cell_contents_0_param_ = l_add_closure_0_cell_contents_1_0_ = None carry = scan[0] out = scan[1]; scan = None return (carry, out)""", # noqa: B950 ) self.assertEqual(eager_out, exp_out) self.assertEqual(compiled_out, exp_out) @skipIfTorchDynamo("Skip because we're testing export") # TODO: we cannot turn on strict=True yet because torch._check for out_it > 0 is # removed from the graph in dynamo and in non-strict export's graph capturing # step, we re-run the traced graph module to get graph captured result. # Since torch._check is removed from graph, we end up getting a data-dependent # error when we call torch.ones(out_it * 2). @parametrize("strict", [False]) @parametrize("dynamic", [True, False]) def test_while_loop_op_int_carry_export(self, strict, dynamic): m, args = WHILE_LOOP_TESTS["int_carry"] dynamic_shapes = {"x": {0: torch.export.Dim("dim_x")}} if dynamic else None ep = self._check_export(m, args, strict=strict, dynamic_shapes=dynamic_shapes) if not strict and dynamic: self.assertExpectedInline( normalize_gm(ep.module().print_readable(print_output=False)), """\ class GraphModule(torch.nn.Module): def forward(self, x): x: "f32[s77, 3]"; x, = fx_pytree.tree_flatten_spec(([x], {}), self._in_spec) sym_size_int_1: "Sym(s77)" = torch.ops.aten.sym_size.int(x, 0) while_loop_cond_graph_0 = self.while_loop_cond_graph_0 while_loop_body_graph_0 = self.while_loop_body_graph_0 while_loop = torch.ops.higher_order.while_loop(while_loop_cond_graph_0, while_loop_body_graph_0, (0, x), ()); while_loop_cond_graph_0 = while_loop_body_graph_0 = x = None getitem_2: "Sym(u1)" = while_loop[0] ge: "Sym(u1 >= 1)" = getitem_2 >= 1 _assert_scalar_default = torch.ops.aten._assert_scalar.default(ge, "Runtime assertion failed for expression u1 >= 1 on node 'ge'"); ge = _assert_scalar_default = None gt_1: "Sym(u1 > 0)" = getitem_2 > 0 _assert_scalar_default_1 = torch.ops.aten._assert_scalar.default(gt_1, "Runtime assertion failed for expression 0 < u1 on node 'gt_1'"); gt_1 = _assert_scalar_default_1 = None getitem_1: "f32[s77, 3]" = while_loop[1]; while_loop = None add: "Sym(u1 + 1)" = getitem_2 + 1 add_1: "f32[s77, 3]" = torch.ops.aten.add.Tensor(getitem_1, getitem_2); getitem_1 = None lt: "Sym(u1 < s77)" = getitem_2 < sym_size_int_1; sym_size_int_1 = None mul: "Sym(2*u1)" = getitem_2 * 2; getitem_2 = None ones: "f32[2*u1]" = torch.ops.aten.ones.default([mul], device = device(type='cpu'), pin_memory = False); mul = None return pytree.tree_unflatten((add, add_1, lt, ones), self._out_spec) class while_loop_cond_graph_0(torch.nn.Module): def forward(self, it_1: "Sym(u0)", x_1: "f32[s77, 3]"): sym_size_int: "Sym(s77)" = torch.ops.aten.sym_size.int(x_1, 0); x_1 = None lt: "Sym(u0 < s77)" = it_1 < sym_size_int; it_1 = sym_size_int = None return lt class while_loop_body_graph_0(torch.nn.Module): def forward(self, it_1: "Sym(u0)", x_1: "f32[s77, 3]"): clone: "f32[s77, 3]" = torch.ops.aten.clone.default(x_1); x_1 = None select: "f32[3]" = torch.ops.aten.select.int(clone, 0, it_1) select_1: "f32[3]" = torch.ops.aten.select.int(clone, 0, it_1) add: "f32[3]" = torch.ops.aten.add.Tensor(select_1, it_1); select_1 = None copy_: "f32[3]" = torch.ops.aten.copy_.default(select, add); select = add = copy_ = None add_1: "Sym(u0 + 1)" = it_1 + 1; it_1 = None return (add_1, clone) """, # noqa: B950 ) @skipIfTorchDynamo("Graph is not captured correctly when test with dynamo") @parametrize("dynamic", [True, False]) @parametrize("backend", ["eager", "aot_eager"]) def test_while_loop_op_int_carry_compile(self, dynamic, backend): from torch._dynamo.testing import EagerAndRecordGraphs m, args = WHILE_LOOP_TESTS["int_carry"] if backend == "eager": backend = EagerAndRecordGraphs() self._check_compile(m, args, dynamic=dynamic, backend=backend) if ( isinstance(backend, EagerAndRecordGraphs) and dynamic and not TEST_WITH_CROSSREF ): self.assertEqual(len(backend.graphs), 1) self.assertExpectedInline( normalize_gm(backend.graphs[0].print_readable(print_output=False)), """\ class GraphModule(torch.nn.Module): def forward(self, s77: "Sym(s77)", s27: "Sym(s27)", L_x_: "f32[s77, s27]"): l_x_ = L_x_ cond_fn_0 = self.cond_fn_0 body_fn_0 = self.body_fn_0 while_loop = torch.ops.higher_order.while_loop(cond_fn_0, body_fn_0, (0, l_x_), (s27, s77)); cond_fn_0 = body_fn_0 = l_x_ = s27 = None getitem_4: "Sym(u1)" = while_loop[0] ge: "Sym(u1 >= 1)" = getitem_4 >= 1 _assert_scalar_default = torch.ops.aten._assert_scalar.default(ge, "Runtime assertion failed for expression u1 >= 1 on node 'ge'"); ge = _assert_scalar_default = None gt_1: "Sym(u1 > 0)" = getitem_4 > 0 _assert_scalar_default_1 = torch.ops.aten._assert_scalar.default(gt_1, "Runtime assertion failed for expression 0 < u1 on node 'gt_1'"); gt_1 = _assert_scalar_default_1 = None out_x: "f32[s77, s27]" = while_loop[1]; while_loop = None gt: "Sym(u1 > 0)" = getitem_4 > 0 _check = torch._check(gt); gt = _check = None add: "Sym(u1 + 1)" = getitem_4 + 1 add_1: "f32[s77, s27]" = getitem_4 + out_x; out_x = None lt: "Sym(u1 < s77)" = getitem_4 < s77; s77 = None mul: "Sym(2*u1)" = getitem_4 * 2; getitem_4 = None ones: "f32[2*u1]" = torch.ones(mul); mul = None return (add, add_1, lt, ones) class cond_fn_0(torch.nn.Module): def forward(self, unbacked_symint: "Sym(u0)", l_x_: "f32[s77, s27]", s27, s77): s27_1 = s27 s77_1 = s77 size = l_x_.size(); l_x_ = None getitem: "Sym(s77)" = size[0] getitem_1: "Sym(s27)" = size[1]; size = getitem_1 = None lt: "Sym(u0 < s77)" = unbacked_symint < getitem; unbacked_symint = getitem = None return lt class body_fn_0(torch.nn.Module): def forward(self, unbacked_symint: "Sym(u0)", l_x_: "f32[s77, s27]", s27, s77): s27_1 = s27 s77_1 = s77 x_clone: "f32[s77, s27]" = l_x_.clone() ge: "Sym(u0 >= 0)" = unbacked_symint >= 0 _check = torch._check(ge); ge = _check = None size = l_x_.size(); l_x_ = None getitem: "Sym(s77)" = size[0] getitem_1: "Sym(s27)" = size[1]; size = getitem_1 = None lt: "Sym(u0 < s77)" = unbacked_symint < getitem; getitem = None _check_1 = torch._check(lt); lt = _check_1 = None select: "f32[s27]" = x_clone.select(0, unbacked_symint) select_1: "f32[s27]" = x_clone.select(0, unbacked_symint) add: "f32[s27]" = select_1 + unbacked_symint; select_1 = None copy_: "f32[s27]" = select.copy_(add); select = add = copy_ = None add_1: "Sym(u0 + 1)" = unbacked_symint + 1; unbacked_symint = None return (add_1, x_clone) """, # noqa: B950 ) @skipIfTorchDynamo("Skip because we're testing export") @parametrize("strict", [True, False]) @parametrize("dynamic", [True, False]) @torch._dynamo.config.patch(capture_scalar_outputs=True) def test_while_loop_op_constant_and_symint_output_export(self, strict, dynamic): m, args = WHILE_LOOP_TESTS["const_and_symint_output"] dynamic_shapes = {"t": {0: torch.export.Dim("dim_t")}} if dynamic else None ep = self._check_export(m, args, strict=strict, dynamic_shapes=dynamic_shapes) # strict or dynamic gives a slightly different graph if not strict and not dynamic: self.assertExpectedInline( normalize_gm(ep.module().print_readable(print_output=False)), """\ class GraphModule(torch.nn.Module): def forward(self, t): t: "f32[2, 3]"; t, = fx_pytree.tree_flatten_spec(([t], {}), self._in_spec) sum_1: "f32[]" = torch.ops.aten.sum.default(t) _assert_tensor_metadata_default = torch.ops.aten._assert_tensor_metadata.default(sum_1, dtype = torch.float32, device = device(type='cpu'), layout = torch.strided); _assert_tensor_metadata_default = None to: "i64[]" = torch.ops.aten.to.dtype(sum_1, torch.int64); sum_1 = None item: "Sym(u0)" = torch.ops.aten.item.default(to); to = None sin: "f32[2, 3]" = torch.ops.aten.sin.default(t) while_loop_cond_graph_0 = self.while_loop_cond_graph_0 while_loop_body_graph_0 = self.while_loop_body_graph_0 while_loop = torch.ops.higher_order.while_loop(while_loop_cond_graph_0, while_loop_body_graph_0, (2, 3, 1, 1, 1, 3, item, sin), ()); while_loop_cond_graph_0 = while_loop_body_graph_0 = item = sin = None getitem_8: "Sym(u8)" = while_loop[0] getitem_9: "Sym(u9)" = while_loop[1] getitem_10: "Sym(u10)" = while_loop[2] getitem_11: "Sym(u11)" = while_loop[3] getitem_12: "Sym(u12)" = while_loop[4] getitem_13: "Sym(u13)" = while_loop[5] getitem_14: "Sym(u14)" = while_loop[6] getitem_7: "f32[2, 3]" = while_loop[7]; while_loop = None add: "Sym(u8 + 1)" = getitem_8 + 1 add_1: "Sym(u9 + 1)" = getitem_9 + 1 add_2: "Sym(u10 + 1)" = getitem_10 + 1 add_3: "Sym(u11 + 1)" = getitem_11 + 1 add_4: "Sym(u12 + 1)" = getitem_12 + 1 add_5: "Sym(u13 + 1)" = getitem_13 + 1 add_6: "Sym(u14 + 1)" = getitem_14 + 1 add_7: "f32[2, 3]" = torch.ops.aten.add.Tensor(getitem_7, 1) add_8: "f32[2, 3]" = torch.ops.aten.add.Tensor(t, getitem_8); getitem_8 = None add_9: "f32[2, 3]" = torch.ops.aten.add.Tensor(t, getitem_9); getitem_9 = None add_10: "f32[2, 3]" = torch.ops.aten.add.Tensor(t, getitem_10); getitem_10 = None add_11: "f32[2, 3]" = torch.ops.aten.add.Tensor(t, getitem_11); getitem_11 = None add_12: "f32[2, 3]" = torch.ops.aten.add.Tensor(t, getitem_12); getitem_12 = None add_13: "f32[2, 3]" = torch.ops.aten.add.Tensor(t, getitem_13); getitem_13 = None add_14: "f32[2, 3]" = torch.ops.aten.add.Tensor(t, getitem_14); getitem_14 = None add_15: "f32[2, 3]" = torch.ops.aten.add.Tensor(getitem_7, t); getitem_7 = t = None return pytree.tree_unflatten((add, add_1, add_2, add_3, add_4, add_5, add_6, add_7, add_8, add_9, add_10, add_11, add_12, add_13, add_14, add_15), self._out_spec) class while_loop_cond_graph_0(torch.nn.Module): def forward(self, a_1: "Sym(u1)", b_1: "Sym(u2)", c1_1: "Sym(u3)", c2_1: "Sym(u4)", c3_1: "Sym(u5)", c0_1: "Sym(u6)", u0_1: "Sym(u7)", x_1: "f32[2, 3]"): mul: "Sym(u3*u4)" = c1_1 * c2_1; c1_1 = c2_1 = None mul_1: "Sym(u3*u4*u5)" = mul * c3_1; mul = c3_1 = None mul_2: "Sym(u1*u2)" = a_1 * b_1; a_1 = b_1 = None lt: "Sym(u3*u4*u5 < u1*u2)" = mul_1 < mul_2; mul_1 = mul_2 = None return lt class while_loop_body_graph_0(torch.nn.Module): def forward(self, a_1: "Sym(u1)", b_1: "Sym(u2)", c1_1: "Sym(u3)", c2_1: "Sym(u4)", c3_1: "Sym(u5)", c0_1: "Sym(u6)", u0_1: "Sym(u7)", x_1: "f32[2, 3]"): add: "Sym(u7 + 1)" = u0_1 + 1; u0_1 = None add_1: "f32[2, 3]" = torch.ops.aten.add.Tensor(x_1, 1); x_1 = None return (b_1, c1_1, c2_1, c3_1, a_1, 0, add, add_1) """, # noqa: B950 ) @skipIfTorchDynamo("Graph is not captured correctly when test with dynamo") @parametrize("dynamic", [True, False]) @parametrize("backend", ["eager", "aot_eager"]) @torch._dynamo.config.patch(capture_scalar_outputs=True) def test_while_loop_op_constant_and_symint_output_compile(self, dynamic, backend): from torch._dynamo.testing import EagerAndRecordGraphs m, args = WHILE_LOOP_TESTS["const_and_symint_output"] if backend == "eager": backend = EagerAndRecordGraphs() self._check_compile(m, args, dynamic=dynamic, backend=backend) if ( isinstance(backend, EagerAndRecordGraphs) # cross ref or dynamic gives a slightly different graph and not dynamic and not TEST_WITH_CROSSREF ): self.assertEqual(len(backend.graphs), 1) self.assertExpectedInline( normalize_gm(backend.graphs[0].print_readable(print_output=False)), """\ class GraphModule(torch.nn.Module): def forward(self, L_t_: "f32[2, 3]"): l_t_ = L_t_ sum_1: "f32[]" = l_t_.sum() to: "i64[]" = sum_1.to(torch.int64); sum_1 = None item: "Sym(u0)" = to.item(); to = None child: "f32[2, 3]" = l_t_.sin() cond_fn_0 = self.cond_fn_0 body_fn_0 = self.body_fn_0 while_loop = torch.ops.higher_order.while_loop(cond_fn_0, body_fn_0, (2, 3, 1, 1, 1, 3, item, child), ()); cond_fn_0 = body_fn_0 = item = child = None getitem_8: "Sym(u8)" = while_loop[0] getitem_9: "Sym(u9)" = while_loop[1] getitem_10: "Sym(u10)" = while_loop[2] getitem_11: "Sym(u11)" = while_loop[3] getitem_12: "Sym(u12)" = while_loop[4] getitem_13: "Sym(u13)" = while_loop[5] getitem_14: "Sym(u14)" = while_loop[6] child_1: "f32[2, 3]" = while_loop[7]; while_loop = None add: "Sym(u8 + 1)" = getitem_8 + 1 add_1: "Sym(u9 + 1)" = getitem_9 + 1 add_2: "Sym(u10 + 1)" = getitem_10 + 1 add_3: "Sym(u11 + 1)" = getitem_11 + 1 add_4: "Sym(u12 + 1)" = getitem_12 + 1 add_5: "Sym(u13 + 1)" = getitem_13 + 1 add_6: "Sym(u14 + 1)" = getitem_14 + 1 add_7: "f32[2, 3]" = child_1 + 1 add_8: "f32[2, 3]" = getitem_8 + l_t_; getitem_8 = None add_9: "f32[2, 3]" = getitem_9 + l_t_; getitem_9 = None add_10: "f32[2, 3]" = getitem_10 + l_t_; getitem_10 = None add_11: "f32[2, 3]" = getitem_11 + l_t_; getitem_11 = None add_12: "f32[2, 3]" = getitem_12 + l_t_; getitem_12 = None add_13: "f32[2, 3]" = getitem_13 + l_t_; getitem_13 = None add_14: "f32[2, 3]" = getitem_14 + l_t_; getitem_14 = None add_15: "f32[2, 3]" = child_1 + l_t_; child_1 = l_t_ = None return (add, add_1, add_2, add_3, add_4, add_5, add_6, add_7, add_8, add_9, add_10, add_11, add_12, add_13, add_14, add_15) class cond_fn_0(torch.nn.Module): def forward(self, unbacked_symint: "Sym(u1)", unbacked_symint_0: "Sym(u2)", unbacked_symint_1: "Sym(u3)", unbacked_symint_2: "Sym(u4)", unbacked_symint_3: "Sym(u5)", unbacked_symint_4: "Sym(u6)", unbacked_symint_5: "Sym(u7)", child: "f32[2, 3]"): mul: "Sym(u3*u4)" = unbacked_symint_1 * unbacked_symint_2; unbacked_symint_1 = unbacked_symint_2 = None mul_1: "Sym(u3*u4*u5)" = mul * unbacked_symint_3; mul = unbacked_symint_3 = None mul_2: "Sym(u1*u2)" = unbacked_symint * unbacked_symint_0; unbacked_symint = unbacked_symint_0 = None lt: "Sym(u3*u4*u5 < u1*u2)" = mul_1 < mul_2; mul_1 = mul_2 = None return lt class body_fn_0(torch.nn.Module): def forward(self, unbacked_symint: "Sym(u1)", unbacked_symint_0: "Sym(u2)", unbacked_symint_1: "Sym(u3)", unbacked_symint_2: "Sym(u4)", unbacked_symint_3: "Sym(u5)", unbacked_symint_4: "Sym(u6)", unbacked_symint_5: "Sym(u7)", child: "f32[2, 3]"): add: "Sym(u7 + 1)" = unbacked_symint_5 + 1; unbacked_symint_5 = None child_1: "f32[2, 3]" = child + 1; child = None return (unbacked_symint_0, unbacked_symint_1, unbacked_symint_2, unbacked_symint_3, unbacked_symint, 0, add, child_1) """, # noqa: B950 ) @skipIfTorchDynamo("Skip because we're testing export") @parametrize("strict", [True, False]) @parametrize("dynamic", [True, False]) def test_while_loop_op_pytree_int_carry_export(self, strict, dynamic): m, args = WHILE_LOOP_TESTS["pytree_int_carry"] dynamic_shapes = {"x": {0: torch.export.Dim("dim_x")}} if dynamic else None ep = self._check_export(m, args, strict=strict, dynamic_shapes=dynamic_shapes) if strict and dynamic: self.assertExpectedInline( normalize_gm(ep.module().print_readable(print_output=False)), """\ class GraphModule(torch.nn.Module): def forward(self, x): x: "f32[s77, 3]"; x, = fx_pytree.tree_flatten_spec(([x], {}), self._in_spec) sym_size_int_1: "Sym(s77)" = torch.ops.aten.sym_size.int(x, 0) sin: "f32[s77, 3]" = torch.ops.aten.sin.default(x); x = None while_loop_cond_graph_0 = self.while_loop_cond_graph_0 while_loop_body_graph_0 = self.while_loop_body_graph_0 while_loop = torch.ops.higher_order.while_loop(while_loop_cond_graph_0, while_loop_body_graph_0, (sym_size_int_1, 3, 2, 2, 3, sin), ()); while_loop_cond_graph_0 = while_loop_body_graph_0 = sym_size_int_1 = sin = None getitem_6: "Sym(u5)" = while_loop[0] getitem_7: "Sym(u6)" = while_loop[1] getitem_8: "Sym(u7)" = while_loop[2] getitem_9: "Sym(u8)" = while_loop[3] getitem_10: "Sym(u9)" = while_loop[4] getitem_5: "f32[s77, 3]" = while_loop[5]; while_loop = None add: "Sym(u7 + 1)" = getitem_8 + 1 add_1: "Sym(u8 + 1)" = getitem_9 + 1 add_2: "Sym(u9 + 1)" = getitem_10 + 1 add_3: "f32[s77, 3]" = torch.ops.aten.add.Tensor(getitem_5, getitem_8); getitem_8 = None add_4: "f32[s77, 3]" = torch.ops.aten.add.Tensor(getitem_5, getitem_9); getitem_9 = None add_5: "f32[s77, 3]" = torch.ops.aten.add.Tensor(getitem_5, getitem_10); getitem_10 = None return pytree.tree_unflatten((getitem_6, getitem_7, add, add_1, add_2, add_3, add_4, add_5, getitem_5), self._out_spec) class while_loop_cond_graph_0(torch.nn.Module): def forward(self, arg0_1: "Sym(u15)", arg1_1: "Sym(u16)", arg2_1: "Sym(u17)", arg3_1: "Sym(u18)", arg4_1: "Sym(u19)", arg5_1: "f32[s77, 3]"): mul: "Sym(u17*u18)" = arg2_1 * arg3_1; arg2_1 = arg3_1 = None mul_1: "Sym(u17*u18*u19)" = mul * arg4_1; mul = arg4_1 = None mul_2: "Sym(u15*u16)" = arg0_1 * arg1_1; arg0_1 = arg1_1 = None lt: "Sym(u17*u18*u19 < u15*u16)" = mul_1 < mul_2; mul_1 = mul_2 = None return lt class while_loop_body_graph_0(torch.nn.Module): def forward(self, arg0_1: "Sym(u15)", arg1_1: "Sym(u16)", arg2_1: "Sym(u17)", arg3_1: "Sym(u18)", arg4_1: "Sym(u19)", arg5_1: "f32[s77, 3]"): add: "Sym(u15 + 1)" = arg0_1 + 1; arg0_1 = None add_1: "Sym(u16 + 1)" = arg1_1 + 1; arg1_1 = None add_2: "Sym(u17 + 1)" = arg2_1 + 1; arg2_1 = None add_3: "Sym(u18 + 1)" = arg3_1 + 1; arg3_1 = None add_4: "Sym(u19 + 1)" = arg4_1 + 1; arg4_1 = None add_5: "f32[s77, 3]" = torch.ops.aten.add.Tensor(arg5_1, 1); arg5_1 = None return (add, add_1, add_2, add_3, add_4, add_5) """, # noqa: B950 ) @skipIfTorchDynamo("Graph is not captured correctly when test with dynamo") @parametrize("dynamic", [True, False]) @parametrize("backend", ["eager", "aot_eager"]) @torch._dynamo.config.patch(capture_scalar_outputs=True) def test_while_loop_op_pytree_int_carry_compile(self, dynamic, backend): from torch._dynamo.testing import EagerAndRecordGraphs m, args = WHILE_LOOP_TESTS["pytree_int_carry"] if backend == "eager": backend = EagerAndRecordGraphs() self._check_compile(m, args, dynamic=dynamic, backend=backend) if ( isinstance(backend, EagerAndRecordGraphs) and dynamic and not TEST_WITH_CROSSREF ): self.assertEqual(len(backend.graphs), 1) self.assertExpectedInline( normalize_gm(backend.graphs[0].print_readable(print_output=False)), """\ class GraphModule(torch.nn.Module): def forward(self, s77: "Sym(s77)", s27: "Sym(s27)", L_x_: "f32[s77, s27]"): l_x_ = L_x_ child: "f32[s77, s27]" = l_x_.sin(); l_x_ = None cond_fn_0 = self.cond_fn_0 body_fn_0 = self.body_fn_0 while_loop = torch.ops.higher_order.while_loop(cond_fn_0, body_fn_0, (s77, s27, 2, 2, 3, child), (s27, s77)); cond_fn_0 = body_fn_0 = s77 = s27 = child = None getitem_10: "Sym(u5)" = while_loop[0] getitem_11: "Sym(u6)" = while_loop[1] getitem_12: "Sym(u7)" = while_loop[2] getitem_13: "Sym(u8)" = while_loop[3] getitem_14: "Sym(u9)" = while_loop[4] out_x: "f32[s77, s27]" = while_loop[5]; while_loop = None add: "Sym(u7 + 1)" = getitem_12 + 1 add_1: "Sym(u8 + 1)" = getitem_13 + 1 add_2: "Sym(u9 + 1)" = getitem_14 + 1 add_3: "f32[s77, s27]" = getitem_12 + out_x; getitem_12 = None add_4: "f32[s77, s27]" = getitem_13 + out_x; getitem_13 = None add_5: "f32[s77, s27]" = getitem_14 + out_x; getitem_14 = None return (getitem_10, getitem_11, add, add_1, add_2, add_3, add_4, add_5, out_x) class cond_fn_0(torch.nn.Module): def forward(self, unbacked_symint: "Sym(u0)", unbacked_symint_0: "Sym(u1)", unbacked_symint_1: "Sym(u2)", unbacked_symint_2: "Sym(u3)", unbacked_symint_3: "Sym(u4)", child: "f32[s77, s27]", s27, s77): s27_1 = s27 s77_1 = s77 mul: "Sym(u2*u3)" = unbacked_symint_1 * unbacked_symint_2; unbacked_symint_1 = unbacked_symint_2 = None mul_1: "Sym(u2*u3*u4)" = mul * unbacked_symint_3; mul = unbacked_symint_3 = None mul_2: "Sym(u0*u1)" = unbacked_symint * unbacked_symint_0; unbacked_symint = unbacked_symint_0 = None lt: "Sym(u2*u3*u4 < u0*u1)" = mul_1 < mul_2; mul_1 = mul_2 = None return lt class body_fn_0(torch.nn.Module): def forward(self, unbacked_symint: "Sym(u0)", unbacked_symint_0: "Sym(u1)", unbacked_symint_1: "Sym(u2)", unbacked_symint_2: "Sym(u3)", unbacked_symint_3: "Sym(u4)", child: "f32[s77, s27]", s27, s77): s27_1 = s27 s77_1 = s77 add: "Sym(u0 + 1)" = unbacked_symint + 1; unbacked_symint = None add_1: "Sym(u1 + 1)" = unbacked_symint_0 + 1; unbacked_symint_0 = None add_2: "Sym(u2 + 1)" = unbacked_symint_1 + 1; unbacked_symint_1 = None add_3: "Sym(u3 + 1)" = unbacked_symint_2 + 1; unbacked_symint_2 = None add_4: "Sym(u4 + 1)" = unbacked_symint_3 + 1; unbacked_symint_3 = None child_1: "f32[s77, s27]" = child + 1; child = None return (add, add_1, add_2, add_3, add_4, child_1) """, # noqa: B950 ) def test_input_output_alias(self): def fn(f, *args): return torch.cond(args[0].sum() > 0, f, f, args) x = torch.randn(2, 2) for f in ALIAS_FN: with self.assertRaisesRegex( # Should be # torch._dynamo.exc.Unsupported, # "Encountered aliasing during higher order op tracing for HOP.*" torch._dynamo.exc.UncapturedHigherOrderOpError, "Cond doesn't work unless it is captured completely with torch.compile.*", ): torch.compile(fn)(f, x) def test_input_input_alias(self): def fn(view_f, arg): def f(arg1, arg2): return arg1.cos(), arg2.sin() return torch.cond(arg.sum() > 0, f, f, (arg, view_f(arg))) x = torch.randn(2, 2) # ALIAS_FN[0] is an identical function, cond optimizes the duplication # as a result of auto lifting. for view_f in ALIAS_FN[1:]: with self.assertRaisesRegex( # Should be # torch._dynamo.exc.Unsupported, # "Encountered aliasing during higher order op tracing for HOP.*" torch._dynamo.exc.UncapturedHigherOrderOpError, "Cond doesn't work unless it is captured completely with torch.compile.*", ): torch.compile(fn)(view_f, x) @parametrize("inference_mode", [True, False]) def test_input_mutation(self, inference_mode): def fn(view_f, *args): def mutate_f(x): v = view_f(x) v.add_(1) return v.sin() return torch.cond(args[0].sum() > 0, mutate_f, mutate_f, args) x = torch.randn(2, 2) for f in ALIAS_FN: with self.assertRaisesRegex( # Should be # torch._dynamo.exc.Unsupported, # "Encountered aliasing during higher order op tracing for HOP.*" torch._dynamo.exc.UncapturedHigherOrderOpError, "Cond doesn't work unless it is captured completely with torch.compile.*", ): torch.compile(fn)(f, x) with self.assertRaisesRegex( # Should be # torch._dynamo.exc.Unsupported, # "Encountered aliasing during higher order op tracing for HOP.*" torch._dynamo.exc.UncapturedHigherOrderOpError, "Cond doesn't work unless it is captured completely with torch.compile.*", ): with torch.inference_mode(inference_mode): torch.compile(fn)(f, x) @skipIfTorchDynamo("Graph is not captured correctly when test with dynamo") def test_while_loop_unbacked_bindings(self): from torch._dynamo.testing import EagerAndRecordGraphs m, args = WHILE_LOOP_TESTS["pytree_int_carry"] backend = EagerAndRecordGraphs() self._check_compile(m, args, dynamic=True, backend=backend) self.assertEqual(len(backend.graphs), 1) while_loop_nodes = backend.graphs[0].graph.find_nodes( op="call_function", target=torch.ops.higher_order.while_loop ) self.assertEqual(len(while_loop_nodes), 1) self.assertEqual(len(while_loop_nodes[0].meta.get("unbacked_bindings")), 5) # Return the .module() graph str result of non-strict export def _check_export_ret_graph_str(self, fn, args, dynamic_shapes=None) -> str: strict_ep = torch.export.export( fn, args, dynamic_shapes=dynamic_shapes, strict=True ) non_strict_ep = torch.export.export( fn, args, dynamic_shapes=dynamic_shapes, strict=False ) eager_res = fn(*args) self.assertEqual(strict_ep.module()(*args), eager_res) self.assertEqual(non_strict_ep.module()(*args), eager_res) return normalize_gm(non_strict_ep.module().print_readable(print_output=False)) @skipIfTorchDynamo("Skip because dynamo cannot trace torch.export.") @torch._dynamo.config.patch(capture_scalar_outputs=True) def test_cond_eager_run_with_item(self): class M(torch.nn.Module): def forward(self, a, b1, b2, c): def true_fn(x): return x * b1.item() def false_fn(x): return x * b2.item() r = torch.cond(a, true_fn, false_fn, (c,)) return r * 2 x = torch.randn(10, requires_grad=True) args = ( torch.tensor(True), torch.tensor([3]), torch.tensor([4]), x, ) model = M() torch.export.export(model, args, strict=True) graph_str = self._check_export_ret_graph_str(model, args, None) self.assertExpectedInline( graph_str, """\ class GraphModule(torch.nn.Module): def forward(self, a, b1, b2, c): a: "b8[]"; b1: "i64[1]"; b2: "i64[1]"; c: "f32[10]"; a, b1, b2, c, = fx_pytree.tree_flatten_spec(([a, b1, b2, c], {}), self._in_spec) true_graph_0 = self.true_graph_0 false_graph_0 = self.false_graph_0 cond = torch.ops.higher_order.cond(a, true_graph_0, false_graph_0, (c, b1, b2)); a = true_graph_0 = false_graph_0 = c = b1 = b2 = None getitem: "f32[10]" = cond[0]; cond = None mul: "f32[10]" = torch.ops.aten.mul.Tensor(getitem, 2); getitem = None return pytree.tree_unflatten((mul,), self._out_spec) class true_graph_0(torch.nn.Module): def forward(self, c: "f32[10]", b1: "i64[1]", b2: "i64[1]"): item: "Sym(u0)" = torch.ops.aten.item.default(b1); b1 = None mul: "f32[10]" = torch.ops.aten.mul.Tensor(c, item); c = item = None return (mul,) class false_graph_0(torch.nn.Module): def forward(self, c: "f32[10]", b1: "i64[1]", b2: "i64[1]"): item: "Sym(u1)" = torch.ops.aten.item.default(b2); b2 = None mul: "f32[10]" = torch.ops.aten.mul.Tensor(c, item); c = item = None return (mul,) """, # noqa: B950 ) @skipIfTorchDynamo("Skip because dynamo cannot trace torch.export.") def test_cond_symint_closure(self): from torch.export import Dim class M(torch.nn.Module): def forward(self, x, y, z): a = y.shape[0] b = z.shape[0] def true_fn(x): return x + a def false_fn(x): return x + b * z # When exporting with non-strict: a and b are symints, # so torch.compile need to wrap and trace symint inputs. return torch.cond(x.shape[0] > 5, true_fn, false_fn, (x,)) args = (torch.ones(3, 3), torch.ones(5), torch.ones(3, 3)) model = M() dynamic_shapes = {"x": {0: Dim("d")}, "y": {0: Dim("d1")}, "z": {0: Dim("d")}} non_strict_graph_str = self._check_export_ret_graph_str( model, args, dynamic_shapes ) self.assertExpectedInline( non_strict_graph_str, """\ class GraphModule(torch.nn.Module): def forward(self, x, y, z): x: "f32[s68, 3]"; y: "f32[s17]"; z: "f32[s68, 3]"; x, y, z, = fx_pytree.tree_flatten_spec(([x, y, z], {}), self._in_spec) sym_size_int_4: "Sym(s17)" = torch.ops.aten.sym_size.int(y, 0); y = None sym_size_int_5: "Sym(s68)" = torch.ops.aten.sym_size.int(z, 0) gt: "Sym(s68 > 5)" = sym_size_int_5 > 5 true_graph_0 = self.true_graph_0 false_graph_0 = self.false_graph_0 cond = torch.ops.higher_order.cond(gt, true_graph_0, false_graph_0, (x, sym_size_int_4, sym_size_int_5, z)); gt = true_graph_0 = false_graph_0 = x = sym_size_int_4 = sym_size_int_5 = z = None getitem: "f32[s68, 3]" = cond[0]; cond = None return pytree.tree_unflatten((getitem,), self._out_spec) class true_graph_0(torch.nn.Module): def forward(self, x: "f32[s68, 3]", sym_size_int_4: "Sym(s17)", sym_size_int_5: "Sym(s68)", z: "f32[s68, 3]"): add: "f32[s68, 3]" = torch.ops.aten.add.Tensor(x, sym_size_int_4); x = sym_size_int_4 = None return (add,) class false_graph_0(torch.nn.Module): def forward(self, x: "f32[s68, 3]", sym_size_int_4: "Sym(s17)", sym_size_int_5: "Sym(s68)", z: "f32[s68, 3]"): mul: "f32[s68, 3]" = torch.ops.aten.mul.Tensor(z, sym_size_int_5); z = sym_size_int_5 = None add: "f32[s68, 3]" = torch.ops.aten.add.Tensor(x, mul); x = mul = None return (add,) """, # noqa: B950 ) # unbacked symint inputs are created during non-strict export, # which causes a graph break @unittest.expectedFailure def test_cond_unbacked_symint_closure(self): from torch.export import Dim class M(torch.nn.Module): def forward(self, x, y, z): a = y.shape[0] b = z.shape[0] # c is an unbacked symint in non-strict export c = y.sum().item() def true_fn(x): return x + a + c def false_fn(x): return x + b * z * c # When exporting with non-strict: a and b are symints, # so torch.compile need to wrap and trace symint inputs. return torch.cond(x.shape[0] > 5, true_fn, false_fn, (x,)) args = (torch.ones(3, 3), torch.ones(5, dtype=torch.int32), torch.ones(3, 3)) model = M() dynamic_shapes = {"x": {0: Dim("d")}, "y": {0: Dim("d1")}, "z": {0: Dim("d")}} _ = self._check_export_ret_graph_str(model, args, dynamic_shapes) @skipIfTorchDynamo( "Skip because _merge_output is not intended for dynamo to compile" ) def test_merge_output(self): from torch._higher_order_ops.cond import _merge_output from torch._subclasses.fake_tensor import FakeTensorMode from torch.fx.experimental.symbolic_shapes import ShapeEnv # The shapes and strides are from raondomly generated pairs of tensors then swapaxes valid_test_cases = [ # [(size1, stride1), (size2, stride2), (expected_stride, expected_size)] [((3,), (1,)), ((4,), (1,)), ("(u0,)", "(1,)")], [((1, 3), (3, 1)), ((3, 2), (2, 1)), ("(u0, u1)", "(u1, 1)")], [((2, 1), (1, 1)), ((7, 3), (3, 1)), ("(u0, u1)", "(u1, 1)")], [((5, 5), (1, 5)), ((4, 5), (1, 4)), ("(u0, 5)", "(1, u0)")], [ ((7, 3, 1), (1, 7, 1)), ((4, 3, 3), (3, 12, 1)), ("(u0, 3, u1)", "(u1, u0*u1, 1)"), ], [ ((5, 7, 4), (7, 1, 35)), ((7, 4, 4), (4, 1, 28)), ("(u0, u1, 4)", "(u1, 1, u0*u1)"), ], [ ((1, 6, 3, 2), (36, 1, 6, 18)), ((4, 2, 2, 6), (24, 1, 2, 4)), ("(u0, u1, u2, u3)", "(u1*u2*u3, 1, u1, u1*u2)"), ], [ ((6, 1, 6, 3), (18, 1, 1, 6)), ((2, 1, 3, 4), (12, 1, 1, 3)), ("(u0, 1, u1, u2)", "(u1*u2, 1, 1, u1)"), ], [ ((3, 1, 2, 4, 1), (8, 8, 4, 1, 1)), ((2, 4, 1, 4, 1), (16, 4, 4, 1, 1)), ("(u0, u1, u2, 4, 1)", "(4*u1*u2, 4*u2, 4, 1, 1)"), ], ] def _inner(case): fake_mode = FakeTensorMode(shape_env=ShapeEnv()) (size1, stride1), (size2, stride2), (merged_size, merged_stride) = case with fake_mode: t1 = torch.empty_strided(size1, stride1) t2 = torch.empty_strided(size2, stride2) out = _merge_output(t1, t2, fake_mode) self.assertEqual(str(tuple(out.size())), merged_size) self.assertEqual(str(tuple(out.stride())), merged_stride) for case in valid_test_cases: _inner(case) # The shapes and strides are from raondomly generated pairs of tensors then swapaxes invalid_test_cases = [ # [(size1, stride1), (size2, stride2)] [((1,), (1,)), ((1,), (0,))], [ ((1, 3), (1, 1)), ((5, 6), (6, 1)), ], # t1 is not contiguous, t2 is contiguous [ ((2, 1), (1, 1)), ((7, 3), (1, 3)), ], # t1 is contiguous, t2 is not contiguous [ ((5, 4), (4, 1)), ((5, 5), (1, 5)), ], # t1 is contiguous, t2 is not contiguous [((7, 3, 1), (1, 7, 1)), ((4, 3, 3), (9, 1, 3))], # layout is different [((5, 7, 4), (7, 1, 35)), ((7, 4, 4), (4, 28, 1))], # layout is different [ ((1, 6, 3, 2), (36, 1, 6, 18)), ((4, 1, 1, 6), (1, 4, 4, 4)), ], # layout is different [ ((6, 1, 6, 3), (18, 1, 1, 6)), ((1, 1, 1, 1), (1, 1, 1, 1)), ], # layout is different [ ((6, 1, 1, 6, 3), (3, 18, 18, 18, 1)), ((5, 1, 2, 1, 1), (2, 10, 1, 10, 1)), ], # layout is different ] for case in invalid_test_cases: with self.assertRaisesRegex(Exception, r"."): _inner(case) @parametrize("dynamic", [True, False]) @parametrize("backend", ["eager", "aot_eager"]) def test_cond_mismatched_branch_output(self, dynamic, backend): from torch._dynamo.testing import EagerAndRecordGraphs class M(torch.nn.Module): def forward(self, x, y, z): a = y.shape[0] b = z.shape[0] def true_fn(x): # clone the outputs so branches have the same storage_offset return (x + a)[2:].clone() def false_fn(x): # clone the outputs so branches have the same storage_offset return (x + b * z)[:2].clone() ret = torch.cond(x.sum() > 0, true_fn, false_fn, (x,)) return y.sum() - ret m = M() x, y, z = torch.randn(5, 4), torch.randn(5, 4), torch.randn(5, 4) out = m(x, y, z) if not (backend == "eager" and dynamic and not TEST_WITH_CROSSREF): compiled_out = torch.compile( m, backend=backend, dynamic=dynamic, fullgraph=True )(x, y, z) self.assertEqual(compiled_out, out) else: bk = EagerAndRecordGraphs() compiled_out = torch.compile( m, backend=bk, dynamic=dynamic, fullgraph=True )(x, y, z) self.assertEqual(compiled_out, out) self.assertExpectedInline( normalize_gm(bk.graphs[0].print_readable(print_output=False)), """\ class GraphModule(torch.nn.Module): def forward(self, s17: "Sym(s17)", s94: "Sym(s94)", L_y_: "f32[s17, s94]", L_z_: "f32[s17, s94]", L_x_: "f32[s17, s94]"): l_y_ = L_y_ l_z_ = L_z_ l_x_ = L_x_ sum_1: "f32[]" = l_x_.sum() gt: "b8[]" = sum_1 > 0; sum_1 = None cond_true_0 = self.cond_true_0 cond_false_0 = self.cond_false_0 cond = torch.ops.higher_order.cond(gt, cond_true_0, cond_false_0, (l_x_, s94, s17, s17, l_z_)); gt = cond_true_0 = cond_false_0 = l_x_ = s94 = s17 = l_z_ = None getitem_5: "f32[u0, s94]" = cond[0] sym_size_int: "Sym(u0)" = torch.ops.aten.sym_size.int(getitem_5, 0); getitem_5 = None _check_is_size = torch._check_is_size(sym_size_int); _check_is_size = None ge: "Sym(u0 >= 0)" = sym_size_int >= 0; sym_size_int = None _assert_scalar_default = torch.ops.aten._assert_scalar.default(ge, "Runtime assertion failed for expression u0 >= 0 on node 'ge'"); ge = _assert_scalar_default = None ret: "f32[u0, s94]" = cond[0]; cond = None sum_2: "f32[]" = l_y_.sum(); l_y_ = None sub: "f32[u0, s94]" = sum_2 - ret; sum_2 = ret = None return (sub,) class cond_true_0(torch.nn.Module): def forward(self, l_x_, s94, s17_true_branch, getitem_2_false_branch, l_z__false_branch): l_x__1 = l_x_ s94_1 = s94 add: "f32[s17, s94]" = l_x__1 + s17_true_branch; l_x__1 = s17_true_branch = None getitem: "f32[s17 - 2, s94]" = add[slice(2, None, None)]; add = None clone: "f32[s17 - 2, s94]" = getitem.clone(); getitem = None return (clone,) class cond_false_0(torch.nn.Module): def forward(self, l_x_, s94, s17_true_branch, getitem_2_false_branch, l_z__false_branch): l_x__1 = l_x_ s94_1 = s94 mul: "f32[s17, s94]" = getitem_2_false_branch * l_z__false_branch; getitem_2_false_branch = l_z__false_branch = None add: "f32[s17, s94]" = l_x__1 + mul; l_x__1 = mul = None getitem: "f32[2, s94]" = add[slice(None, 2, None)]; add = None clone: "f32[2, s94]" = getitem.clone(); getitem = None return (clone,) """, # noqa: B950 ) @parametrize("dynamic", [True, False]) @parametrize("backend", ["eager", "aot_eager"]) def test_cond_mismatched_branch_strided_output(self, dynamic, backend): class M(torch.nn.Module): def forward(self, x, y): def true_fn(x, y): return ( (x.swapaxes(-1, 0) + 1) .unsqueeze(1) .expand(-1, 5, -1, -1, -1, -1, -1), torch.empty_strided((3, 3), (0, 1)), ) def false_fn(x, y): return ( (y.swapaxes(-1, 0) + 1) .unsqueeze(1) .expand(-1, 4, -1, -1, -1, -1, -1), torch.empty_strided((4, 5), (0, 1)), ) ret = torch.cond(x.sum() > 0, true_fn, false_fn, (x, y)) return y.sum() + ret[0] m = M() x, y = torch.randn(1, 6, 1, 5, 4, 3), torch.randn(1, 4, 5, 1, 3, 8) out = m(x, y) compiled_out = torch.compile( m, backend=backend, dynamic=dynamic, fullgraph=True )(x, y) self.assertEqual(compiled_out, out) _hop_schema_test_schema_types = [ "bool", "int", "float", "str", "Tensor", "SymInt", "SymBool", "GraphModule", "ScriptObj", ] @skipIfTorchDynamo("We don't expect users to torch.compile hop schema generation.") @unittest.skipIf(IS_WINDOWS, "Windows not supported for this test") class TestHopSchema(TestCase): def _get_example_val(self, ty: str): from torch.fx.experimental.sym_node import SymNode from torch.fx.experimental.symbolic_shapes import ShapeEnv def create_symtype(cls, pytype, shape_env, val): from torch._dynamo.source import ConstantSource symbol = shape_env.create_symbol( val, source=ConstantSource( f"__testing_hop_schema{len(shape_env.var_to_val)}" ), ) return cls(SymNode(symbol, shape_env, pytype, hint=val)) if ty == "bool": return True elif ty == "int": return 1 elif ty == "float": return 1.0 elif ty == "str": return "foo" elif ty == "Tensor": return torch.tensor(1) elif ty == "SymInt": shape_env = ShapeEnv() return create_symtype(torch.SymInt, int, shape_env, 1) elif ty == "SymBool": shape_env = ShapeEnv() return create_symtype(torch.SymBool, bool, shape_env, True) elif ty == "GraphModule": def f(x): return x.sin() return make_fx(f)(torch.ones(1)) elif ty == "ScriptObj": from torch.testing._internal.torchbind_impls import ( init_torchbind_implementations, ) init_torchbind_implementations() foo = torch.classes._TorchScriptTesting._Foo(3, 4) return foo else: raise NotImplementedError(ty) @parametrize("schema_type", _hop_schema_test_schema_types) def test_type_gen(self, schema_type): from torchgen.gen_schema_utils import TypeGen example_val = self._get_example_val(schema_type) ty = TypeGen.from_example(example_val) # Test the generated type can be parsed self.assertEqual(ty.parse(str(ty)), ty) @parametrize("schema_type", _hop_schema_test_schema_types) def test_list_gen(self, schema_type): from torchgen.gen_schema_utils import TypeGen example_val = self._get_example_val(schema_type) li1 = [example_val] ty1 = TypeGen.from_example(li1) ty2 = TypeGen.from_example(li1) self.assertEqual(ty1.parse(str(ty1)), ty1) self.assertEqual(ty2.parse(str(ty2)), ty2) def test_function_schema_gen(self): from torchgen.gen_schema_utils import FunctionSchemaGen inps = [ (schema_type + "_v", self._get_example_val(schema_type)) for schema_type in _hop_schema_test_schema_types ] schema1 = FunctionSchemaGen.from_example("test_op1", inps, torch.ones(1)) schema2 = FunctionSchemaGen.from_example( "test_op2", inps, [ torch.ones(1), ], ) schema3 = FunctionSchemaGen.from_example( "test_op3", inps, [torch.ones(1), torch.ones(1)] ) self.assertExpectedInline( str(schema1), """test_op1(bool bool_v, int int_v, float float_v, str str_v, Tensor Tensor_v, SymInt SymInt_v, SymBool SymBool_v, GraphModule GraphModule_v, __torch__.torch.classes._Foo ScriptObj_v) -> Tensor""", # noqa: B950 ) self.assertExpectedInline( str(schema2), """test_op2(bool bool_v, int int_v, float float_v, str str_v, Tensor Tensor_v, SymInt SymInt_v, SymBool SymBool_v, GraphModule GraphModule_v, __torch__.torch.classes._Foo ScriptObj_v) -> Tensor""", # noqa: B950 ) self.assertExpectedInline( str(schema3), """test_op3(bool bool_v, int int_v, float float_v, str str_v, Tensor Tensor_v, SymInt SymInt_v, SymBool SymBool_v, GraphModule GraphModule_v, __torch__.torch.classes._Foo ScriptObj_v) -> (Tensor, Tensor)""", # noqa: B950, ) self.assertEqual(schema1.parse(str(schema1)), schema1) self.assertEqual(schema2.parse(str(schema2)), schema2) self.assertEqual(schema3.parse(str(schema3)), schema3) def test_while_loop_schema_gen(self): fn, inp = WHILE_LOOP_TESTS["simple_with_linear"] graph = make_fx(fn)(*inp).graph while_loop_node = next( node for node in graph.nodes if node.op == "call_function" and node.target is torch.ops.higher_order.while_loop ) schema = torch._library.utils.hop_schema_from_fx_node(while_loop_node) self.assertExpectedInline( str(schema), """while_loop(GraphModule cond_fn, GraphModule body_fn, Tensor[2] carried_inputs, Tensor[3] additional_inputs) -> Tensor[2]""", # noqa: B950 ) self.assertEqual(schema.parse(str(schema)), schema) def test_schema_tree_spec(self): schema_gen = HopSchemaGenerator(torch.ops.higher_order.cond) args = (torch.randn(3, 4), torch.randn(2, 3)) with self.assertRaisesRegex( RuntimeError, "Please only add flattened inputs to the hop schema" ): schema_gen.add_arg("tuple_args", args) for i, arg in enumerate(args): schema_gen.add_arg(f"tuple_args{i}", arg) schema_gen.add_schema_tree_spec(pytree.tree_flatten(args)[1]) flat_schema = schema_gen.gen_schema() self.assertExpectedInline( str(flat_schema), """cond(Tensor tuple_args0, Tensor tuple_args1) -> ()""" ) instantiate_parametrized_tests(TestHopSchema) instantiate_parametrized_tests(TestControlFlowTraced) instantiate_parametrized_tests(TestControlFlow) instantiate_parametrized_tests(AssociativeScanTests) if __name__ == "__main__": run_tests()