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test_autograd.py
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test_autograd.py
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# Owner(s): ["module: autograd"]
import contextlib
import gc
import io
import math
import os
import random
import sys
import tempfile
import threading
import time
import unittest
import uuid
import warnings
import operator
import subprocess
from copy import deepcopy
from collections import OrderedDict
from itertools import product
from operator import mul
from functools import reduce, partial
import torch
from torch import nn
from torch import inf, nan
from torch.autograd.function import once_differentiable
from torch.autograd.profiler import (profile, record_function, emit_nvtx, emit_itt)
from torch.autograd.profiler_util import (_format_time, EventList, FunctionEvent, FunctionEventAvg)
from torch.utils.checkpoint import checkpoint, checkpoint_sequential
from torch.testing import make_tensor
from torch.testing._internal.common_cuda import TEST_CUDA
from torch.testing._internal.common_utils import (
TestCase, run_tests, skipIfNoLapack, slowTest, IS_WINDOWS, IS_MACOS,
disable_gc, gradcheck, gradgradcheck, parametrize,
instantiate_parametrized_tests, skipIfMps, set_warn_always_context)
from torch.autograd import Variable, Function, detect_anomaly, kineto_available, _calculate_shape
from torch.autograd.function import InplaceFunction
import torch.autograd.forward_ad as fwAD
from torch.autograd.graph import GradientEdge
import torch.autograd._functions
from torch.testing._internal.common_methods_invocations import mask_not_all_zeros
from torch.testing._internal.common_device_type import (instantiate_device_type_tests,
onlyCPU, onlyCUDA, dtypes, dtypesIfCUDA,
deviceCountAtLeast, skipMeta, dtypesIfMPS)
from torch.testing._internal.common_dtype import floating_types_and
from torch.utils._mode_utils import no_dispatch
from torch.utils._python_dispatch import TorchDispatchMode
import weakref
import collections
import pickle
def graph_desc(fn):
if fn is None:
return 'None'
result = type(fn).__name__ + '('
next_functions = fn.next_functions
for next_fn, _ in next_functions:
result += graph_desc(next_fn)
result += ', '
if next_functions:
result = result[:-2]
return result + ')'
class TestAutograd(TestCase):
def test_copy_slices_graph_task_updates(self):
def f1(x, y):
out = x.clone().view(-1)
out += y
return out
def f2(x, y):
out = x.clone().view(-1)
b = out * 2
out += y
return out + b
x = torch.rand(2, requires_grad=True)
y = torch.rand(2, requires_grad=True)
y_safe = torch._C._functions.DelayedError("Boom!", 1)(y)
for f in [f1, f2]:
# Ensure that the error Node works
out = f(x, y_safe)
with self.assertRaisesRegex(RuntimeError, "Boom!"):
out.sum().backward()
out = f(x, y_safe)
with self.assertRaisesRegex(RuntimeError, "Boom!"):
torch.autograd.grad(out.sum(), y)
# Ensure that if we don't ask for y, it doesn't crash
out = f(x, y_safe)
torch.autograd.grad(out.sum(), x)
out = f(x, y_safe)
torch.autograd.grad(out.sum(), y_safe)
out = f(x, y_safe)
torch.autograd.grad(out.sum(), (x, y_safe))
# Ensure that we don't run extra view Node
def f3(x, y):
out = x.clone().view(-1)
def hook(*args):
# This should never be called!
self.assertTrue(False)
out.register_hook(hook)
b = out + y
out += y
return out + b, b
out, b = f3(x, y_safe)
torch.autograd.grad(out.sum(), (b, y_safe))
def test_grad_mode_class_decoration(self):
# Decorating class is deprecated and should not be used
with self.assertWarnsRegex(UserWarning, "Decorating classes is deprecated"):
@torch.no_grad()
class Foo:
def __init__(self):
assert not torch.is_grad_enabled()
def foo(self):
# Not applied to methods
assert torch.is_grad_enabled()
# Show that we can actually construct the class
foo = Foo()
foo.foo()
# Decorating functions or methods is fine though
with warnings.catch_warnings(record=True) as w:
@torch.no_grad()
def foo():
assert not torch.is_grad_enabled()
foo()
class Foo2:
@torch.no_grad()
def __init__(self):
assert not torch.is_grad_enabled()
@torch.no_grad()
def foo(self):
assert not torch.is_grad_enabled()
foo2 = Foo2()
foo2.foo()
self.assertEqual(len(w), 0)
def test_tensor_grad_warnings(self):
dummy = torch.empty(1)
with warnings.catch_warnings(record=True) as w:
# Accessing .grad on leaf
dummy.requires_grad_()
foo = dummy.grad
self.assertEqual(len(w), 0)
# Accessing .grad on non-leaf
dummy = dummy.clone()
foo = dummy.grad
self.assertEqual(len(w), 1)
# Accessing .grad on non-leaf that retains gradients
dummy.retain_grad()
foo = dummy.grad
self.assertEqual(len(w), 1)
def _function_test(self, cls):
x = torch.randn(5, 5, requires_grad=True)
y = torch.randn(5, 5, requires_grad=True)
result = cls.apply(x, 2, y)
go = torch.ones((), requires_grad=True)
result.sum().backward(go, create_graph=True)
self.assertEqual(x.grad, y + torch.ones(5, 5))
self.assertEqual(y.grad, x + torch.ones(5, 5) * 2)
self.assertIsNotNone(x.grad.grad_fn)
self.assertIsNotNone(y.grad.grad_fn)
return x, y
def test_function(self):
class MyFunction(Function):
@staticmethod
def forward(ctx, tensor1, pyscalar, tensor2):
ctx.pyscalar = pyscalar
ctx.save_for_backward(tensor1, tensor2)
return tensor1 + pyscalar * tensor2 + tensor1 * tensor2
@staticmethod
def backward(ctx, grad_output):
var1, var2 = ctx.saved_tensors
# NOTE: self is the test case here
self.assertIsInstance(var1, torch.Tensor)
self.assertIsInstance(var2, torch.Tensor)
self.assertIsInstance(grad_output, torch.Tensor)
return (grad_output + grad_output * var2, None,
grad_output * ctx.pyscalar + grad_output * var1)
x, y = self._function_test(MyFunction)
x_grad_desc = graph_desc(x.grad.grad_fn)
y_grad_desc = graph_desc(y.grad.grad_fn)
self.assertExpected(x_grad_desc, "x_grad_desc")
self.assertExpected(y_grad_desc, "y_grad_desc")
def test_once_differentiable(self):
class MyFunction(Function):
@staticmethod
def forward(ctx, tensor1, pyscalar, tensor2):
ctx.pyscalar = pyscalar
ctx.save_for_backward(tensor1, tensor2)
return tensor1 + pyscalar * tensor2 + tensor1 * tensor2
@staticmethod
@once_differentiable
def backward(ctx, grad_output):
self.assertFalse(torch.is_grad_enabled())
t1, t2 = ctx.saved_tensors
return (grad_output + grad_output * t2, None,
grad_output * ctx.pyscalar + grad_output * t1)
x, y = self._function_test(MyFunction)
self.assertEqual(graph_desc(x.grad.grad_fn),
'CopyBackwards(None, Error(AccumulateGrad(), None, AccumulateGrad()))')
self.assertEqual(graph_desc(y.grad.grad_fn),
'CopyBackwards(None, Error(AccumulateGrad(), None, AccumulateGrad()))')
def test_function_returns_input(self):
class MyFunction(Function):
@staticmethod
def forward(ctx, x):
return x
@staticmethod
def backward(ctx, grad):
return grad * 2
for shape in [(1,), ()]:
v = torch.ones(shape, requires_grad=True)
MyFunction.apply(v).backward()
self.assertEqual(v.grad, torch.full(shape, 2.))
with torch.no_grad():
v.grad.zero_()
MyFunction.apply(v.clone()).backward()
self.assertEqual(v.grad, torch.full(shape, 2.))
def test_function_returns_undefined_tensor(self):
class MyFunction(Function):
@staticmethod
def forward(ctx, x):
return x * 2
@staticmethod
def backward(ctx, grad):
return None
# Test that undefined tensors returned from custom backward function
# are propagated as undefined and not tensor full of zeroes
x = torch.ones(1, requires_grad=True)
MyFunction.apply(x).backward()
self.assertIsNone(x.grad)
MyFunction.apply(x ** 2).backward()
self.assertIsNone(x.grad)
MyFunction.apply(x).sum().backward()
self.assertIsNone(x.grad)
self.assertIsNone(torch.autograd.grad(MyFunction.apply(x), x, allow_unused=True)[0])
def test_materialize_grads(self):
class MyFunction(Function):
@staticmethod
def forward(ctx, x):
return x
@staticmethod
def backward(ctx, grad):
self.assertEqual(grad, torch.zeros(1))
return grad
x = torch.ones(1, requires_grad=True)
torch._C._functions.UndefinedGrad()(MyFunction.apply(x)).backward()
def test_dont_materialize_grads(self):
class MyFunction(Function):
@staticmethod
def forward(ctx, x):
ctx.set_materialize_grads(False)
return x
@staticmethod
def backward(ctx, grad):
self.assertIsNone(grad)
return grad
x = torch.ones(1, requires_grad=True)
torch._C._functions.UndefinedGrad()(MyFunction.apply(x)).backward()
def test_set_materialize_non_diff_grads(self):
class Func(torch.autograd.Function):
@staticmethod
def forward(ctx, x):
out0 = x.clone()
out1 = x.clone()
ctx.mark_non_differentiable(out1)
ctx._materialize_non_diff_grads = False
return out0, out1
@staticmethod
def backward(ctx, g0, g1):
self.assertIsNone(g1)
return g0
a = torch.tensor(1., requires_grad=True)
out = Func.apply(a)[0]
out.backward()
def test_legacy_function_deprecation_exception(self):
# Trigger exception
class MyFunction(Function):
def forward(self, x):
return x
def backward(self, grad_output):
return grad_output
# Check exception occurs
with self.assertRaisesRegex(
RuntimeError,
'Legacy autograd function with non-static forward method is deprecated'):
MyFunction()(torch.randn(3, 4))
class SimulateBackwardError(Function):
@staticmethod
def forward(ctx, input):
return input.clone()
@staticmethod
@once_differentiable
def backward(ctx, input):
raise Exception("Simulate error on backward pass")
def test_custom_function_exception(self):
t1 = torch.rand((3, 3), requires_grad=True)
t2 = torch.rand((3, 3), requires_grad=True)
tmp = (t1 + t2) * (t1 + t2)
t3 = TestAutograd.SimulateBackwardError.apply(tmp)
with self.assertRaisesRegex(Exception, "Simulate error on backward pass"):
t3.sum().backward()
def test_custom_function_non_tensor_inputs_outputs(self):
class MyFunction(Function):
@staticmethod
def forward(ctx, t1, t2, scale, t3):
t4 = t1 + t2 * t3
t5 = t1 * t2 + t3
t4 *= scale
t5 *= scale
# Save scale
ctx.scale = scale
ctx.save_for_backward(t1, t2, t3)
return scale, t4, None, True, t5, "bar", t1
@staticmethod
@once_differentiable
def backward(ctx, *grads):
# Verify grads
self.assertEqual(7, len(grads))
self.assertIsNone(grads[0])
self.assertIsNone(grads[2])
self.assertIsNone(grads[3])
self.assertIsNone(grads[5])
scale = ctx.scale
var1, var2, var3 = ctx.saved_tensors
return (
grads[1] * scale + grads[4] * var2 * scale + grads[6],
grads[1] * var3 * scale + grads[4] * var1 * scale,
None,
grads[1] * var2 * scale + grads[4] * scale,
)
t1 = torch.rand(10, dtype=torch.double, requires_grad=True)
t2 = torch.rand(10, dtype=torch.double, requires_grad=True)
t3 = torch.rand(10, dtype=torch.double)
scale = random.randint(0, 10)
res = MyFunction.apply(t1, t2, scale, t3)
self.assertEqual(scale, res[0])
self.assertEqual((t1 + t2 * t3) * scale, res[1])
self.assertEqual(None, res[2])
self.assertEqual(True, res[3])
self.assertEqual((t1 * t2 + t3) * scale, res[4])
self.assertEqual("bar", res[5])
self.assertEqual(t1, res[6])
# Validate running backward.
torch.autograd.backward([res[1].sum(), res[4].sum(), res[6].sum()])
self.assertIsNotNone(t1.grad)
self.assertIsNotNone(t2.grad)
self.assertIsNone(t3.grad)
# Test gradcheck
def foo(t1, t2, t3):
res = MyFunction.apply(t1, t2, scale, t3)
return res[1], res[4], res[6]
gradcheck(foo, (t1, t2, t3))
def test_custom_function_no_tensors(self):
class MyFunction(Function):
@staticmethod
def forward(ctx, t1, t2, scale, t3):
t4 = t1 + t2 * t3
t5 = t1 * t2 + t3
t4 *= scale
t5 *= scale
return scale, t4, None, True, t5, "bar", t1
@staticmethod
@once_differentiable
def backward(ctx, *args):
return (args[0], args[1], None, args[2])
t1 = random.random()
t2 = random.random()
t3 = random.random()
scale = random.randint(0, 10)
res = MyFunction.apply(t1, t2, scale, t3)
self.assertEqual(scale, res[0])
self.assertEqual((t1 + t2 * t3) * scale, res[1])
self.assertEqual(None, res[2])
self.assertEqual(True, res[3])
self.assertEqual((t1 * t2 + t3) * scale, res[4])
self.assertEqual("bar", res[5])
self.assertEqual(t1, res[6])
def test_invalid_gradients(self):
class MyFunction(Function):
@staticmethod
def forward(ctx, x):
return x * 2
@staticmethod
def backward(ctx, grad_output):
return torch.randn(10, dtype=torch.float)
with self.assertRaisesRegex(RuntimeError, 'expected shape'):
input = torch.randn(5, 5, dtype=torch.float, requires_grad=True)
MyFunction.apply(input).sum().backward()
def test_unrelated_inputs(self):
# test to ensure grad(grad)check runs successfully even if there is an
# unrelated (but differentiable) inputs
def my_function(x, y):
return x * x
x = torch.rand(10, dtype=torch.double, requires_grad=True)
y = torch.rand(10, dtype=torch.double, requires_grad=True)
gradcheck(my_function, (x, y))
gradgradcheck(my_function, (x, y))
def test_not_implemented_grad(self):
a = torch.rand(2, requires_grad=True)
# if grad for nextafter ends up being implemented, this should be changed
y = torch.nextafter(a, a).sum()
with self.assertRaisesRegex(
NotImplementedError,
'the derivative for .* is not implemented'):
y.backward()
def test_not_implemented_fwad(self):
x = torch.randn(3)
v = torch.rand(3)
with fwAD.dual_level():
dual_x = fwAD.make_dual(x, v)
err_msg = r"Trying to use forward AD with .* that does not support it"
hint_msg = "Running forward AD for an OP that does not implement it should raise a NotImplementedError"
with self.assertRaisesRegex(NotImplementedError, err_msg, msg=hint_msg):
# if forward AD ends up being implemented for torch.igamma, choose a different op
torch.igamma(dual_x, dual_x)
def test_will_engine_execute_node(self):
counter = [0]
class MyFunction(Function):
@staticmethod
def forward(ctx, x):
return x * 2
@staticmethod
def backward(ctx, gO):
return gO * 2
def get_grad_fn(t):
if t.requires_grad and t.grad_fn is None:
return t.clone().grad_fn.next_functions[0][0]
else:
return t.grad_fn
a = torch.randn(2, 3, 4, requires_grad=True)
a2 = torch.randn(2, 3, 4, requires_grad=True)
b = a * a2
b2 = b.cos()
c = MyFunction.apply(b)
should_execute = list(map(get_grad_fn, (a, b, c)))
should_not_execute = list(map(get_grad_fn, (a2, b2)))
def fn(x):
counter[0] += 1
for g in should_execute:
self.assertTrue(torch._C._will_engine_execute_node(g))
for g in should_not_execute:
self.assertFalse(torch._C._will_engine_execute_node(g))
b.register_hook(fn)
c.register_hook(fn)
# .backward(inputs=) is OK
out = c.sum()
torch.autograd.backward(out, inputs=(a, b), retain_graph=True)
self.assertEqual(counter[0], 2)
# .backward() is OK
should_execute = list(map(get_grad_fn, (a, a2, b, c)))
should_not_execute = list(map(get_grad_fn, (b2,)))
torch.autograd.backward(out, retain_graph=True)
# .grad is NOT OK when leaf is passed (this is the current state, subject to change)
with self.assertRaisesRegex(RuntimeError, "are currently running autograd.grad()"):
torch.autograd.grad(out, (a,))
# .grad is OK when non-leaf is passed
a = torch.randn(1, 2, 3, requires_grad=True) * 2
b = a * 2
def fn(x):
# Check a non-leaf
counter[0] += 1
self.assertTrue(torch._C._will_engine_execute_node(b.grad_fn))
b.register_hook(fn)
counter[0] = 0
torch.autograd.grad(b.sum(), (a,))
self.assertEqual(counter[0], 1)
# Verify other errors are raised
with self.assertRaisesRegex(RuntimeError, "during the backward pass"):
torch._C._will_engine_execute_node(out.grad_fn)
with self.assertRaisesRegex(RuntimeError, "expects an grad_fn"):
torch._C._will_engine_execute_node(out)
def test_custom_function_vmap_defaults(self):
class MySquare(Function):
@staticmethod
def forward(x):
return x ** 2
@staticmethod
def setup_context(ctx, inputs, output):
x, = inputs
ctx.save_for_backward(x)
@staticmethod
def backward(ctx, gO):
x, = ctx.saved_tensors
return gO * 2 * x
self.assertFalse(MySquare.generate_vmap_rule)
self.assertTrue(hasattr(MySquare, 'vmap'))
def test_custom_function_setup_context_simple(self):
class MySquare(Function):
@staticmethod
def forward(x):
return x ** 2
@staticmethod
def setup_context(ctx, inputs, output):
x, = inputs
ctx.save_for_backward(x)
@staticmethod
def backward(ctx, gO):
x, = ctx.saved_tensors
return gO * 2 * x
x = torch.randn([], requires_grad=True)
y = MySquare.apply(x)
gx, = torch.autograd.grad(y, x)
self.assertEqual(gx, 2 * x)
def test_custom_function_setup_context_multi_output(self):
# Multiple outputs with some non-Tensor outputs.
class MySquare(Function):
@staticmethod
def forward(x):
two_x = x.item() * 2
return x ** 2, two_x
@staticmethod
def setup_context(ctx, inputs, output):
x, = inputs
_, two_x = output
ctx.two_x = two_x
@staticmethod
@once_differentiable
def backward(ctx, gO, _):
return gO * ctx.two_x
x = torch.randn([], requires_grad=True)
y, _ = MySquare.apply(x)
gx, = torch.autograd.grad(y, x)
self.assertEqual(gx, 2 * x)
def test_custom_function_setup_context_multi_input(self):
class MyReshape(Function):
@staticmethod
def forward(x, shape, scale_forward, scale_backward):
return x.reshape(shape) * scale_forward
@staticmethod
def setup_context(ctx, inputs, output):
x, shape, scale_forward, scale_backward = inputs
ctx.scale_backward = scale_backward
ctx.x_shape = x.shape
@staticmethod
def backward(ctx, gO):
return gO.reshape(ctx.x_shape) * ctx.scale_backward, None, None, None
class MyReshapeRef(Function):
@staticmethod
def forward(ctx, x, shape, scale_forward, scale_backward):
ctx.scale_backward = scale_backward
ctx.x_shape = x.shape
return x.reshape(shape) * scale_forward
@staticmethod
def backward(ctx, gO):
return gO.reshape(ctx.x_shape) * ctx.scale_backward, None, None, None
def test(x, shape, scale_forward, scale_backward):
y = MyReshape.apply(x, shape, scale_forward, scale_backward).sum()
gx, = torch.autograd.grad(y, x)
y_expected = MyReshapeRef.apply(x, shape, scale_forward, scale_backward).sum()
gx_expected, = torch.autograd.grad(y_expected, x)
self.assertEqual(y_expected, y)
self.assertEqual(gx_expected, gx)
test(torch.randn(24, requires_grad=True), (3, 8), 7, 11)
test(torch.randn(2, 3, 4, requires_grad=True), (6, 4), -1, 2)
def test_accumulate_grad(self):
grad_output = torch.ones(5, 5)
def compute_grad(create_graph):
x = torch.randn(5, 5, requires_grad=True)
y = x + 2
y.backward(grad_output, retain_graph=True)
x_grad = x.grad
x_grad_clone = x.grad.clone()
y.backward(grad_output, create_graph=create_graph)
return x_grad, x_grad_clone
# Accumulate in-place when create_graph is False
x_grad, x_grad_clone = compute_grad(create_graph=False)
self.assertEqual(x_grad, x_grad_clone * 2)
# Accumulate out-of-place when create_graph is False
x_grad, x_grad_clone = compute_grad(create_graph=True)
self.assertEqual(x_grad, x_grad_clone)
def test_accumulate_grad_tensor_reference(self):
def _test_grad_tensor(params_grad_tensor, backward_grad_tensor, should_preserve_reference, create_graph):
params = torch.tensor([1.5, 1.5]).requires_grad_()
params.grad = params_grad_tensor
grad_saved = params.grad
params.backward(backward_grad_tensor, create_graph=create_graph)
self.assertEqual(id(grad_saved) == id(params.grad), should_preserve_reference)
for create_graph in (False, True):
# Accumulate dense gradient to sparse gradient will change the `params.grad` reference
_test_grad_tensor(
torch.sparse_coo_tensor(torch.tensor([[1, 1]]).long(), torch.tensor([1., 1.])),
torch.tensor([1.5, 1.5]),
False, # never accumulates in-place
create_graph)
# Accumulate dense gradient to dense gradient will preserve the `params.grad` reference,
# but only if create_graph=False.
_test_grad_tensor(
torch.tensor([1.5, 1.5]),
torch.tensor([1.5, 1.5]),
not create_graph,
create_graph)
# Accumulate sparse gradient to sparse gradient will preserve the `params.grad` reference,
# but only if create_graph=False.
_test_grad_tensor(
torch.sparse_coo_tensor(torch.tensor([[1, 1]]).long(), torch.tensor([1., 1.])),
torch.sparse_coo_tensor(torch.tensor([[1, 1]]).long(), torch.tensor([1., 1.])),
not create_graph,
create_graph)
def test_accumulate_grad_with_zero_numel_grad(self):
a = torch.rand(4, 0, requires_grad=True)
b = torch.rand(4, 1, requires_grad=True)
c = a + b
assert c.shape == (4, 0)
c.sum().backward()
self.assertEqual(b.grad, torch.zeros(4, 1))
self.assertEqual(a.grad, torch.zeros(4, 0))
def test_hessian_vector(self):
x = torch.randn(2, 2, requires_grad=True)
y = torch.randn(2, 2, requires_grad=True)
z = x ** 2 + y * x + y ** 2
z.backward(torch.ones(2, 2), create_graph=True)
with torch.no_grad():
x_grad = 2 * x + y
y_grad = x + 2 * y
self.assertEqual(x.grad, x_grad)
self.assertEqual(y.grad, y_grad)
grad_sum = 2 * x.grad + y.grad
grad_sum.backward(torch.ones(2, 2))
x_hv = torch.ones(2, 2) * 5
y_hv = torch.ones(2, 2) * 4
self.assertEqual(x.grad, x_grad + x_hv)
self.assertEqual(y.grad, y_grad + y_hv)
def test_grad(self):
x = torch.randn(2, 2, requires_grad=True)
y = torch.randn(2, 2, requires_grad=True)
z = x ** 2 + y * x + y ** 2
z.backward(torch.ones(2, 2), create_graph=True)
x_grad = 2 * x + y
y_grad = x + 2 * y
self.assertEqual(x.grad, x_grad)
self.assertEqual(y.grad, y_grad)
grad_sum = 2 * x.grad + y.grad
x_hv = torch.autograd.grad(
outputs=[grad_sum], grad_outputs=[torch.ones(2, 2)],
inputs=[x], create_graph=True)
expected_x_hv = torch.ones(2, 2) * 5
expected_y_hv = torch.ones(2, 2) * 4
self.assertEqual(x_hv[0], expected_x_hv)
self.assertEqual(x.grad, x_grad)
self.assertEqual(y.grad, y_grad)
# Test that grad_outputs and outputs have the same shape
grad_out = torch.ones(2)
try:
torch.autograd.grad(
outputs=[grad_sum], grad_outputs=[grad_out],
inputs=[x], create_graph=True)
self.assertFail()
except RuntimeError as error:
self.assertEqual(str(error), "Mismatch in shape: grad_output[0] has a shape of "
+ str(grad_out.shape) + " and output[0] has a shape of "
+ str(grad_sum.shape) + ".")
def test_grad_to_node(self):
def check_matches(out, inp):
ref = torch.autograd.grad(out.sum(), inp)
edge = torch.autograd.graph.get_gradient_edge(inp)
new = torch.autograd.grad(out.sum(), edge)
self.assertEqual(ref, new)
# We need to ensure that our main types of Node work (regular cpp Nodes,
# AccumulateGrad Nodes and custom Function)
x = torch.rand(2, requires_grad=True)
out = x.clone()
check_matches(out, x)
x = x.clone()
out = x.clone()
check_matches(out, x)
x = torch.autograd._functions.Resize.apply(x, (2,))
out = x.clone()
check_matches(out, x)
x = torch.var_mean(x)[1]
out = x.clone()
check_matches(out, x)
def test_grad_to_node_set(self):
x = torch.rand(2, requires_grad=True)
x_edge = torch.autograd.graph.get_gradient_edge(x)
out = x.clone()
with torch.no_grad():
x.set_(torch.rand_like(x))
with self.assertRaisesRegex(RuntimeError, "to not have been used in the graph"):
torch.autograd.grad(out.sum(), x)
# Works
torch.autograd.grad(out.sum(), x_edge)
def test_grad_to_node_inplace(self):
x = torch.rand(2, requires_grad=True).clone()
x_edge = torch.autograd.graph.get_gradient_edge(x)
x *= 2
g_old, g_new = torch.autograd.grad(x.sum(), (x_edge, x))
self.assertEqual(g_old, 2 * torch.ones_like(x))
self.assertEqual(g_new, torch.ones_like(x))
def test_grad_to_node_multi(self):
x = torch.rand(2, requires_grad=True).clone()
y = torch.rand(2, requires_grad=True).clone()
out = x + y
ref = torch.autograd.grad(out.sum(), (x, y))
inp_edges = (GradientEdge(x.grad_fn, x.output_nr), GradientEdge(y.grad_fn, y.output_nr))
new = torch.autograd.grad(out.sum(), inp_edges)
self.assertEqual(ref, new)
def test_grad_to_node_materialize(self):
x = torch.rand(2, requires_grad=True).clone()
edge_x = GradientEdge(x.grad_fn, x.output_nr)
y = torch.rand(2, requires_grad=True).clone()
edge_y = GradientEdge(y.grad_fn, y.output_nr)
out = x.clone()
# Works
torch.autograd.grad(out.sum(), (edge_x, y), allow_unused=True, materialize_grads=True)
torch.autograd.grad(out.sum(), (x, y), allow_unused=True, materialize_grads=True)
torch.autograd.grad(out.sum(), (x, edge_y), allow_unused=True)
with self.assertRaisesRegex(RuntimeError, "materialize_grads cannot be used when the given input is a GradientEdge"):
torch.autograd.grad(out.sum(), (x, edge_y), allow_unused=True, materialize_grads=True)
def test_backward_to_node(self):
x = torch.rand(2, requires_grad=True).clone()
edge_x = GradientEdge(x.grad_fn, x.output_nr)
y = torch.rand(2, requires_grad=True).clone()
edge_y = GradientEdge(y.grad_fn, y.output_nr)
out = x.clone()
# All should work in this case
torch.autograd.backward(out.sum(), inputs=(edge_x, y))
torch.autograd.backward(out.sum(), inputs=(x, y))
torch.autograd.backward(out.sum(), inputs=(x, edge_y))
torch.autograd.backward(out.sum(), inputs=(edge_x, edge_y))
def test_grad_nonleaf(self):
x_init = torch.randn(2, 2, requires_grad=True)
x = x_init
y = torch.randn(2, 2, requires_grad=True)
grad_output = torch.ones(2, 2)
def fn(x):
return x ** 2 + y * x + y ** 2
for _ in range(5):
grad_x, = torch.autograd.grad(
fn(x), x, grad_outputs=grad_output, create_graph=True)
grad_x_expected = 2 * x + y
self.assertIsNone(y.grad)
self.assertIsNone(x.grad)
self.assertEqual(grad_x, grad_x_expected)
x = x + 0.05 * grad_x
val_init = fn(x_init).sum()
val_final = fn(x).sum()
self.assertGreater(val_final, val_init)
x.backward(grad_output)
self.assertIsNotNone(y.grad)
self.assertIsNotNone(x_init.grad)
def test_grad_nonleaf_many_outputs(self):
# This checks an edge case for function callbacks
# We want to capture two grads of a function, but can only
# register a single callback.
x = torch.randn(4, 2, requires_grad=True)
a, b = x.chunk(2)
def hook(*grads):
hook_called[0] = True
hook_called = [False]
x.register_hook(hook)
go = torch.randn(2, 2)
grad_a, grad_b = torch.autograd.grad(
(a + 2 * b), [a, b], grad_outputs=go, create_graph=True)
self.assertEqual(grad_a, go)
self.assertEqual(grad_b, go * 2)
self.assertFalse(hook_called[0])
self.assertIsNone(x.grad)
def test_grad_nonleaf_register_hook(self):
# This checks an edge case for register_hook.
# We want to capture grad of a nonleaf tensor,
# but avoid segfault during backward of other nonleaf tensors
x = torch.randn(5, requires_grad=True)
x_list = x.unbind()
x0 = x_list[0]
hook_results = [None]
def hook(grad):
hook_results[0] = grad
x0.register_hook(hook)
x_list[0].backward()
self.assertEqual(hook_results[0], torch.tensor(1.))
expected_grad = torch.tensor([1., 0, 0, 0, 0])
self.assertEqual(x.grad, expected_grad)
self.assertIsNone(x_list[0].grad)
for i in range(1, 5, 1):
x_list[i].backward()
self.assertEqual(hook_results[0], None)
expected_grad[i] = 1.0
self.assertEqual(x.grad, expected_grad)
self.assertIsNone(x_list[i].grad)
def test_grad_materialize_grads(self):
x = torch.tensor(0.5, requires_grad=True)
a = torch.tensor(1.0, requires_grad=True)
y = x * a
dydx = torch.autograd.grad(y, x, create_graph=True)
d2ydx2_none = torch.autograd.grad(dydx, x, create_graph=True, allow_unused=True)
d2ydx2 = torch.autograd.grad(dydx, x, create_graph=True, allow_unused=True, materialize_grads=True)
# `allow_unused` set to True implicitly
d3ydx3 = torch.autograd.grad(d2ydx2, x, materialize_grads=True)
self.assertIsNone(d2ydx2_none[0])
self.assertEqual(d2ydx2[0].item(), 0)
self.assertEqual(d3ydx3[0].item(), 0)
with self.assertRaisesRegex(ValueError, "Expected allow_unused to be True or not passed when"):
torch.autograd.grad(y, x, allow_unused=False, materialize_grads=True)
def test_post_accumulate_grad_hook_on_non_leaf(self):
def hook(tensor):
tensor.sub_(1.)
leaf = torch.rand(3, requires_grad=True)
non_leaf = 2. * leaf
with self.assertRaisesRegex(
RuntimeError,
"post accumulate grad hooks cannot be registered on non-leaf tensors"):
non_leaf.register_post_accumulate_grad_hook(hook)
def test_post_accumulate_grad_hook_multiple_hooks(self):
def hook1(tensor):
tensor.sub_(tensor.grad)