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rocm_jax/tests/api_test.py
Roy Frostig ef9b2fe4a1 custom vmap: support closure and staged constants 
The `custom_vmap` primitive stages out its wrapped function at call
time. It might extract closed-over or otherwise constant values
("consts") in doing so. To handle these, we can reduce back to the
empty closure setting: convert the consts to formal arguments, both in
the target function and in the custom vmap rule, and ignore them in
the latter.

We only need to play this trick once, on initial entry. After that, we
can resume in assuming an empty closure.
2022-11-22 17:44:08 -08:00

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# Copyright 2018 The JAX Authors.
#
# Licensed under the Apache License, Version 2.0 (the "License");
# you may not use this file except in compliance with the License.
# You may obtain a copy of the License at
#
# https://www.apache.org/licenses/LICENSE-2.0
#
# Unless required by applicable law or agreed to in writing, software
# distributed under the License is distributed on an "AS IS" BASIS,
# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
# See the License for the specific language governing permissions and
# limitations under the License.
import collections
import collections.abc
from contextlib import contextmanager
import copy
import enum
from functools import partial
import inspect
import operator
import platform
import re
import subprocess
import sys
import types
from typing import Callable, List, Optional
import unittest
import warnings
import weakref
import functools
import itertools as it
import operator as op
from absl import logging
from absl.testing import absltest, parameterized
import numpy as np
import concurrent.futures
import jax
import jax.numpy as jnp
from jax import float0, jit, grad, device_put, jacfwd, jacrev, hessian
from jax import core, lax
from jax import custom_batching
from jax._src import api, dtypes, dispatch, lib
from jax.core import Primitive
from jax.errors import UnexpectedTracerError
from jax.interpreters import ad
from jax.interpreters import mlir
from jax.interpreters import xla
from jax.interpreters import pxla
from jax.interpreters import batching
from jax.interpreters import partial_eval as pe
from jax.interpreters.pxla import PartitionSpec as P
from jax._src import array, sharding
from jax.experimental import pjit
from jax.experimental import maps
from jax._src import config as jax_config
from jax._src import custom_derivatives
from jax._src import device_array
from jax._src import prng
from jax._src.lib import mlir_api_version
from jax._src.lib import xla_client
from jax._src.lib import xla_extension_version
from jax._src import test_util as jtu
from jax import tree_util
from jax import linear_util as lu
import jax._src.util as jax_util
from jax._src.ad_checkpoint import saved_residuals
from jax.ad_checkpoint import checkpoint as new_checkpoint, checkpoint_name
from jax.config import config
config.parse_flags_with_absl()
FLAGS = config.FLAGS
python_version = (sys.version_info[0], sys.version_info[1])
numpy_version = tuple(map(int, np.__version__.split('.')[:3]))
def _check_instance(self, x):
if config.jax_array:
self.assertIsInstance(x, array.ArrayImpl)
else:
self.assertIsInstance(x, device_array.DeviceArray)
class CPPJitTest(jtu.BufferDonationTestCase):
"""Shared tests between the Python and the C++ jax,jit implementations.
Because the Python implementation supports more features, we need to have the
Python tests that extend the C++ tests (and not the other way around).
"""
@property
def use_cpp_jit(self) -> bool:
return True
@property
def jit(self):
return functools.partial(api._jit, self.use_cpp_jit)
def test_jit_repr(self):
def my_function():
return
jitted = jit(my_function)
self.assertEqual(repr(jitted), f"<CompiledFunction of {repr(my_function)}>")
def test_jit_repr_errors(self):
class Callable:
def __call__(self): pass
def __repr__(self):
raise ValueError("invalid repr")
# repr succeeds when underlying function repr fails.
jitted = jit(Callable())
self.assertEqual(repr(jitted), "<CompiledFunction>")
# repr succeeds when object is malformed.
del jitted.__wrapped__
self.assertEqual(repr(jitted), "<CompiledFunction>")
def test_jit_of_noncallable(self):
self.assertRaisesRegex(TypeError, "Expected a callable value.*",
lambda: self.jit(3))
def test_jit_of_generator(self):
def gen(x):
yield x
self.assertRaisesRegex(TypeError,
"Expected a function, got a generator function.*",
lambda: self.jit(gen))
@parameterized.parameters([
# Integer support
(1, 2, 3, 4, 5),
# Numpy array support
(
np.asarray(1, np.int32),
np.asarray(2, np.int32),
np.asarray(3, np.int32),
np.asarray(4, np.int32),
np.asarray(5, np.int32),
),
])
def test_jit_static_args(self, one, two, three, four, five):
side = []
def f(x, y, z, flag=False, flag2=False):
del flag2 # unused
assert flag
side.append(None)
return 100 * x + 10 * y + z
f1 = self.jit(f, static_argnums=(3, 4))
assert f1(one, two, three, True, False) == 123
assert len(side) == 1
assert f1(one, two, three, True, False) == 123
assert len(side) == 1 # Obvious cache hit.
assert f1(two, one, three, True, False) == 213
assert len(side) == 1 # Should cache hit because same signature.
assert f1(two, one, three, True, True) == 213
assert len(side) == 2
side[:] = []
f2 = self.jit(f, static_argnums=(0, 2, 3, 4))
assert f2(1, 2, 3, True, False) == 123
assert len(side) == 1
assert f2(1, 3, 3, True, False) == 133
assert len(side) == 1
assert f2(2, 2, 3, True, False) == 223
assert len(side) == 2
assert f2(2, 4, 3, True, False) == 243
assert len(side) == 2
assert f2(2, 4, 3, True, True) == 243
assert len(side) == 3
assert f2(2, 5, 3, True, True) == 253
assert len(side) == 3
def test_static_args_equality(self):
class A():
def __hash__(self):
return 1
def __eq__(self, other):
return isinstance(other, A)
side = []
def f(x, static_arg):
del static_arg
side.append(None)
return x * 100
f1 = self.jit(f, static_argnums=(1,))
self.assertEqual(f1(1, A()), 100)
self.assertLen(side, 1)
self.assertEqual(f1(1, A()), 100)
self.assertLen(side, 1)
if self.use_cpp_jit:
f1_cpp = getattr(f1, "_cpp_jitted_f", f1)
self.assertEqual(f1_cpp._cache_size(), 1)
@parameterized.parameters([
(1, 2, 3),
(
np.asarray(1, np.int32),
np.asarray(2, np.int32),
np.asarray(3, np.int32),
),
])
def test_jit_kwargs(self, one, two, three):
side = []
# For the CPP jit, we need to clear the cache to prevent cache hits between
# parameterized tests.
if hasattr(self.jit, "cache_clear"):
self.jit.cache_clear()
def f(x, y, z):
side.append(None)
return 100 * x + 10 * y + z.astype(y.dtype)
f = self.jit(f)
assert f(one, two, three) == 123
assert len(side) == 1
assert f(one, two, three) == 123
assert len(side) == 1
assert f(one, two, z=three) == 123
assert len(side) == 2 # actually recompiles from kwarg
assert f(one, two, z=three) == 123
assert len(side) == 2 # but should still cache
f(one, two, z=np.zeros(3)) # doesn't crash
if config.x64_enabled:
# In the above call, three is of a new type (int64), thus it should
# trigger a new compilation.
assert len(side) == 3
def test_jit_device(self):
device = jax.devices()[-1]
x = self.jit(lambda x: x, device=device)(3.)
_check_instance(self, x)
self.assertEqual(x.device(), device)
@jtu.skip_on_devices("cpu")
def test_jit_default_device(self):
if jax.device_count() == 1:
raise unittest.SkipTest("Test requires multiple devices")
system_default_device = jnp.add(1, 1).device()
test_device = jax.devices()[-1]
self.assertNotEqual(system_default_device, test_device)
f = jax.jit(lambda x: x + 1)
self.assertEqual(f(1).device(), system_default_device)
with jax.default_device(test_device):
self.assertEqual(jnp.add(1, 1).device(), test_device)
self.assertEqual(f(1).device(), test_device)
self.assertEqual(jnp.add(1, 1).device(), system_default_device)
self.assertEqual(f(1).device(), system_default_device)
with jax.default_device(test_device):
# Explicit `device` or `backend` argument to jit overrides default_device
self.assertEqual(
jax.jit(f, device=system_default_device)(1).device(),
system_default_device)
out = jax.jit(f, backend="cpu")(1)
if config.jax_array:
self.assertIsInstance(out.sharding, sharding.SingleDeviceSharding)
self.assertEqual(out._arrays[0].platform(), "cpu")
else:
self.assertEqual(out.platform(), "cpu")
# Sticky input device overrides default_device
sticky = jax.device_put(1, system_default_device)
self.assertEqual(jnp.add(sticky, 1).device(), system_default_device)
self.assertEqual(f(sticky).device(), system_default_device)
# Test nested default_devices
with jax.default_device(system_default_device):
self.assertEqual(f(1).device(), system_default_device)
self.assertEqual(f(1).device(), test_device)
# Test a few more non-default_device calls for good luck
self.assertEqual(jnp.add(1, 1).device(), system_default_device)
self.assertEqual(f(sticky).device(), system_default_device)
self.assertEqual(f(1).device(), system_default_device)
# TODO(skye): make this work!
def test_jit_default_platform(self):
with self.assertRaisesWithLiteralMatch(
ValueError, "jax.default_device must be passed a Device object "
"(e.g. `jax.devices('cpu')[0]`), got: 'cpu'"):
with jax.default_device("cpu"):
jax.jit(lambda x: x + 1)(1)
def test_complex_support(self):
self.assertEqual(self.jit(lambda x: x + 1)(1 + 1j), 2 + 1j)
@parameterized.parameters("static_argnums", "donate_argnums")
def test_jit_argnums_overflow_error(self, argnum_type: str):
def f(a, b, c):
...
# TODO(phawkins): reenable this test after Python 3.7 support is dropped.
# def g(a, /, b, *, c):
# ...
def h(a, *args):
...
def i():
...
# Simplest cases
self.jit(f, **{argnum_type: (0, 1)})
# self.jit(g, **{argnum_type: (0, 1)})
self.jit(f, **{argnum_type: (0, 1, -3)})
# Out of bounds without *args
# with self.assertRaises(ValueError):
with self.assertWarns(SyntaxWarning):
self.jit(f, **{argnum_type: (0, 1, 3)})
# with self.assertRaises(ValueError):
with self.assertWarns(SyntaxWarning):
self.jit(f, **{argnum_type: (0, 1, -4)})
# # with self.assertRaises(ValueError):
# with self.assertWarns(SyntaxWarning):
# self.jit(g, **{argnum_type: (0, 1, 3)})
# # with self.assertRaises(ValueError):
# with self.assertWarns(SyntaxWarning):
# self.jit(g, **{argnum_type: (0, 1, -3)})
# Out of bounds with *args
self.jit(h, **{argnum_type: (0, 999)})
self.jit(h, **{argnum_type: (0, -999)})
# No positional arguments
self.jit(i, static_argnums=())
self.jit(i)
def test_jit_argnames_validation(self):
def f(a, b, c):
...
def g(a, b, **kwargs):
...
# TODO(phawkins): reenable this test after Python 3.7 support is dropped.
# def h(a, /, b, c, *args, **kwargs):
# ...
# Simplest case
self.jit(f, static_argnames=("b", "c"))
# Undefined arg without **kwargs
# with self.assertRaises(ValueError):
with self.assertWarns(SyntaxWarning):
self.jit(f, static_argnames=("b", "c", "not_defined"))
# Undefined arg with **kwargs
self.jit(g, static_argnames=("a", "b", "not_defined"))
# TODO(phawkins): reenable this test after Python 3.7 support is dropped.
# self.jit(h, static_argnames=("b", "c"))
# self.jit(h, static_argnames=("b", "c", "not_defined"))
#
# # Positional only
# # with self.assertRaises(ValueError):
# with self.assertWarns(SyntaxWarning):
# self.jit(h, static_argnames=("a", "c"))
# # Var positional
# # with self.assertRaises(ValueError):
# with self.assertWarns(SyntaxWarning):
# self.jit(h, static_argnames=("args", "c"))
def test_jit_with_many_args_works(self):
@self.jit
def f(args_list):
return sum(args_list)
self.assertEqual(f(list(range(500))), sum(range(500)))
# Jit and Donate arguments
def test_jit_donate_argnums_warning_raised(self):
x = jnp.array([1.0, 2.0], jnp.float32)
y = jnp.array([1, 2], jnp.int32)
f = self.jit(lambda x, y: x.sum() + jnp.float32(y.sum()), donate_argnums=(0, 1))
with warnings.catch_warnings(record=True) as w:
warnings.simplefilter("always")
f(x, y)
self.assertLen(w, 1)
self.assertTrue(issubclass(w[-1].category, UserWarning))
self.assertIn(
"Some donated buffers were not usable:",
str(w[-1].message))
def test_jit_donate_argnums_invalidates_input(self):
if jtu.device_under_test() == "cpu" and xla_extension_version < 102:
raise unittest.SkipTest("CPU buffer donation requires jaxlib > 0.3.22")
# We can't just use `lambda x: x` because JAX simplifies this away to an
# empty XLA computation.
move = self.jit(lambda x: x + x - x, donate_argnums=0)
x = jnp.ones([])
y = move(x)
self.assertDeleted(x)
self.assertEqual(y, 1.)
def test_jit_donate_argnums_static_argnums(self):
if jtu.device_under_test() == "cpu" and xla_extension_version < 102:
raise unittest.SkipTest("CPU buffer donation requires jaxlib > 0.3.22")
jit_fun = self.jit(
lambda a, b, c, d: ((a + b + c), (a + b + d)),
static_argnums=(0, 1),
donate_argnums=(2, 3))
c = jax.device_put(jnp.array([2., 2.]))
d = jax.device_put(jnp.array([1., 1., 1., 1.]))
e, f = jit_fun(1, 2, c, d)
np.testing.assert_allclose(e, jnp.array([5., 5.]))
np.testing.assert_allclose(f, jnp.array([4., 4., 4., 4.]))
self.assertDeleted(c)
self.assertDeleted(d)
def test_jit_donate_argnums_weak_type(self):
if jtu.device_under_test() == "cpu" and xla_extension_version < 102:
raise unittest.SkipTest("CPU buffer donation requires jaxlib > 0.3.22")
# input has weak-type, output does not have weak-type
move = self.jit(lambda x: x.astype(int), donate_argnums=0)
x = jnp.broadcast_to(2, (3,))
move(x)
self.assertDeleted(x)
def test_jnp_array_copy(self):
if jtu.device_under_test() == "cpu" and xla_extension_version < 102:
raise unittest.SkipTest("CPU buffer donation requires jaxlib > 0.3.22")
# https://github.com/google/jax/issues/3412
@partial(self.jit, donate_argnums=(0,))
def _test(array):
return array.at[0].set(77)
x = jnp.asarray([0, 1])
x_copy = jnp.array(x, copy=True)
with warnings.catch_warnings():
warnings.simplefilter("ignore")
_test(x) # donation
# Gives: RuntimeError: Invalid argument: CopyToHostAsync() called on invalid buffer.
print(x_copy) # doesn't crash
def test_jit_global_cache(self):
def f(x):
assert python_should_be_executing
return x
python_should_be_executing = True
self.jit(f)(2)
python_should_be_executing = False
self.jit(f)(3)
def test_jit_cache_clear(self):
@self.jit
def f(x, y): return x + y
client = jax.devices()[0].client
num_live_initial = len(client.live_executables())
f(1, 2).block_until_ready()
num_live = len(client.live_executables())
self.assertEqual(num_live_initial + 1, num_live)
f.clear_cache()
num_live = len(client.live_executables())
self.assertEqual(num_live_initial, num_live)
def test_jit_shallow_copy(self):
def f(x):
return copy.copy(x)
self.jit(f)(1)
def test_jit_deep_copy(self):
def f(x):
return copy.deepcopy(x)
self.jit(f)(1)
def test_disable_jit(self):
effects = []
@self.jit
def f(x):
effects.append(1)
return x
with api.disable_jit():
f(2)
f(2)
assert len(effects) == 2
f(2)
f(2)
assert len(effects) == 3
def test_static_argnum_on_method(self):
class A:
@functools.partial(self.jit, static_argnums=(0,))
def my_func_jit(self, x):
return x+2
A().my_func_jit(3)
def test_static_argnum_on_static_method_is_not_supported(self):
with self.assertRaisesRegex(TypeError, "Expected a callable value"):
class A:
@functools.partial(self.jit, static_argnums=(0,))
@classmethod
def my_classmethod_jit(cls, x):
return x+2
def test_staticmethod_is_not_supported(self):
with self.assertRaisesRegex(TypeError,
"staticmethod arguments are not supported"):
class A:
@functools.partial(self.jit)
@staticmethod
def my_staticmethod_jit(x):
return x + 2
def test_concurrent_jit(self):
@self.jit
def f(x):
return x + x - 3.
xs = [self.rng().randn(i) for i in range(10)]
with concurrent.futures.ThreadPoolExecutor() as executor:
futures = [executor.submit(partial(f, x)) for x in xs]
ys = [f.result() for f in futures]
for x, y in zip(xs, ys):
self.assertAllClose(x * 2 - 3., y)
def test_trivial_computations(self):
x = jnp.array([1, 2, 3])
y = self.jit(lambda x: x)(x)
self.assertEqual(x.unsafe_buffer_pointer(), y.unsafe_buffer_pointer())
z1, z2 = self.jit(lambda x: (x, x))(x)
self.assertEqual(z1.unsafe_buffer_pointer(), z2.unsafe_buffer_pointer())
x1, x2 = jnp.array([1, 2]), jnp.array([2, 3])
z1, z2, z3 = self.jit(lambda x, y: (y, 1, x))(x1, x2)
self.assertEqual(z1.unsafe_buffer_pointer(), x2.unsafe_buffer_pointer())
self.assertEqual(z3.unsafe_buffer_pointer(), x1.unsafe_buffer_pointer())
self.assertEqual(z2, 1)
def test_trivial_computations_with_tokens(self):
@self.jit
def noop(arr, token):
return arr, token
arr = jnp.ones(10)
token = jax.lax.create_token()
self.assertEqual(token, noop(arr, token)[1])
def test_jit_bad_input(self):
def f(x):
return x
self.assertRaisesRegex(
TypeError, ".* 'foo' of type <.*'str'> is not a valid JAX type",
lambda: self.jit(f)("foo"))
# Jax type objects aren't valid data arguments.
self.assertRaisesRegex(
TypeError,
".* '.*int32.*' of type <.*_ScalarMeta.*> is not a valid JAX type",
lambda: self.jit(f)(jnp.int32))
def test_jit_on_all_devices(self):
# Verifies we can run the same computation on every device present, even
# if they are, for example, different models of GPU.
data = self.rng().rand(1000).astype(np.float32)
f = self.jit(jnp.negative)
for device in jax.local_devices():
x = device_put(data, device=device)
np.testing.assert_array_equal(-data, f(x))
def test_jit_nested_donate_ignored(self):
jit_fun = self.jit(lambda x: self.jit(lambda y: y**2, donate_argnums=0)(x))
a = jax.device_put(jnp.array(1))
# NOTE(mattjj): stopped raising error here and instead just ignored
# with self.assertRaisesRegex(ValueError, "nested.*not supported"):
# jit_fun(a)
jit_fun(a) # doesn't crash
def test_jit_reference_dropping(self):
x = jnp.ones(10)
f = (lambda x: lambda: x)(x) # reference to x in f's closure
g = self.jit(f)
x = weakref.ref(x) # no more strong ref to x in this scope
assert x() is not None # x is still around
f() # f runs
g() # g runs
g() # g runs a second time
del f # delete the raw callable
assert x() is not None # x is still around
g() # g still runs
del g # no more references to x
assert x() is None # x is gone
def test_jit_of_nonweakreferenceable_function(self):
class CallableWithSlots:
__slots__ = []
def __call__(self, x):
return x + 1
c = CallableWithSlots()
with self.assertRaisesRegex(TypeError, "cannot create weak reference.*"):
weakref.ref(c)
# Building a jit object does not crash.
f = self.jit(c)
with self.assertRaisesRegex(TypeError, "cannot create weak reference.*"):
# Calling the jit object will fail, but not because of the C++ JIT. The
# Python-level jit cache requires weak reference support.
f(3)
def test_jit_raises_on_first_invocation_on_non_hashable_static_argnum(self):
if self.jit != api._python_jit:
raise unittest.SkipTest("this test only applies to _python_jit")
f = lambda x, y: x + 3
jitted_f = self.jit(f, static_argnums=(1,))
msg = ("Non-hashable static arguments are not supported, as this can lead "
"to unexpected cache-misses. Static argument (index 1) of type "
"<class 'numpy.ndarray'> for function <lambda> is non-hashable.")
with self.assertRaisesRegex(ValueError, re.escape(msg)):
jitted_f(1, np.asarray(1))
def test_cpp_jit_raises_on_non_hashable_static_argnum(self):
if not self.use_cpp_jit:
raise unittest.SkipTest("this test only applies to _cpp_jit")
f = lambda x, y: x + 3
jitted_f = self.jit(f, static_argnums=[1])
jitted_f(1, 1)
msg = ("Non-hashable static arguments are not supported. An error occurred "
".*while trying to hash an object of type "
"<class 'numpy\\.ndarray'>, 1. The error was:\nTypeError: "
"unhashable type: 'numpy\\.ndarray'")
with self.assertRaisesRegex(ValueError, msg):
jitted_f(1, np.asarray(1))
class HashableWithoutEq:
def __hash__(self):
return 1
def __eq__(self, other):
raise NotImplementedError(
"A Python error is as is, without stack trace")
with self.assertRaisesRegex(
ValueError,
re.escape("static arguments should be comparable using __eq__")):
jitted_f(1, HashableWithoutEq())
# __eq__ would only be called if we might have a cache hit. Call the
# function a second time with exactly the same arguments to make sure that
# we could.
jitted_f(1, HashableWithoutEq())
def test_cpp_jit_raises_other_exceptions_when_hashing_fails(self):
class A:
def __hash__(self):
raise ValueError
f = jax.jit(lambda x: x + 1, static_argnums=(0,))
a = A()
with self.assertRaisesRegex(ValueError, '^$'): # no extra message
f(a)
def test_cpp_jitted_function_returns_PyBuffer(self):
if not self.use_cpp_jit:
raise unittest.SkipTest("this test only applies to _cpp_jit")
jitted_f = self.jit(lambda a: a + 1)
jitted_f(1)
if config.jax_array:
out = jitted_f(2)
self.assertIsInstance(out.sharding, sharding.SingleDeviceSharding)
self.assertIsInstance(out._arrays[0], device_array.Buffer)
else:
self.assertIsInstance(jitted_f(2), device_array.Buffer)
@jtu.skip_on_devices("cpu")
def test_explicit_backend(self):
f = lambda x: x + 1
jitted_f = jit(f, backend=jtu.device_under_test())
jitted_f_cpu = jit(f, backend="cpu")
result = jitted_f(1.)
result_cpu = jitted_f_cpu(1.)
if config.jax_array:
buf = result._arrays[0]
buf_cpu = result_cpu._arrays[0]
else:
buf = result.device_buffer
buf_cpu = result_cpu.device_buffer
self.assertEqual(buf.platform(), jtu.device_under_test())
self.assertEqual(buf_cpu.platform(), "cpu")
@jtu.skip_on_devices("cpu")
def test_device_to_device_copy_between_backends(self):
# b/186624243
f = lambda x: x + 1
jitted_f = jit(f, backend=jtu.device_under_test())
jitted_f_cpu = jit(f, backend="cpu")
x = np.arange(30).reshape(1, 10, 3)
result = jitted_f(x)
result_cpu = jitted_f_cpu(result)
result_2 = jitted_f(result_cpu)
result_cpu_2 = jitted_f_cpu(result_2)
self.assertAllClose(result_2, x + 3)
self.assertAllClose(result_cpu_2, x + 4)
@jtu.skip_on_devices("cpu")
def test_mismatched_nested_backends(self):
@partial(jit, backend=jtu.device_under_test())
def f(x):
return jit(lambda x: x + 1, backend="cpu")(x)
with self.assertRaisesRegex(
ValueError,
"Outer-jit backend specification .* must match explicit inner-jit "
"backend specification cpu."):
f(1.)
def test_omnistaging(self):
# See https://github.com/google/jax/issues/5206
# TODO(frostig): remove `wrap` once we always enable_custom_prng
def wrap(arr):
arr = np.array(arr, dtype=np.uint32)
if config.jax_enable_custom_prng:
return prng.random_wrap(arr, impl=jax.random.default_prng_impl())
else:
return arr
key_list = [None]
def init():
key, subkey = jax.random.split(key_list[0])
key_list[0] = key
return jax.random.normal(subkey, ())
key_list[0] = wrap([2384771982, 3928867769])
init()
self.jit(init)()
self.assertIsInstance(key_list[0], core.Tracer)
del key_list[0]
def test_jit_wrapped_attributes(self):
def f(x: int) -> int:
"""docstring of f."""
return x + 1
f.some_value = 4
jf = self.jit(f)
for attr in ["doc", "name", "module", "qualname", "annotations"]:
self.assertEqual(
{attr: getattr(f, f"__{attr}__")},
{attr: getattr(jf, f"__{attr}__")})
self.assertEqual(f.some_value, jf.some_value)
def test_jit_python_builtin(self):
x = jnp.array([1, 2])
expected = x + 1
jit_add = self.jit(operator.add, static_argnums=(1,))
actual = jit_add(x, 1)
self.assertArraysEqual(expected, actual)
def test__infer_argnums_and_argnames(self):
def f(x, y=1):
pass
sig = inspect.signature(f)
argnums, argnames = api._infer_argnums_and_argnames(
sig, argnums=None, argnames=None)
assert argnums == ()
assert argnames == ()
argnums, argnames = api._infer_argnums_and_argnames(
sig, argnums=0, argnames=None)
assert argnums == (0,)
assert argnames == ('x',)
argnums, argnames = api._infer_argnums_and_argnames(
sig, argnums=None, argnames='y')
assert argnums == (1,)
assert argnames == ('y',)
argnums, argnames = api._infer_argnums_and_argnames(
sig, argnums=0, argnames='y') # no validation
assert argnums == (0,)
assert argnames == ('y',)
def g(x, y, *args):
pass
sig = inspect.signature(g)
argnums, argnames = api._infer_argnums_and_argnames(
sig, argnums=(1, 2), argnames=None)
assert argnums == (1, 2)
assert argnames == ('y',)
def h(x, y, **kwargs):
pass
sig = inspect.signature(h)
argnums, argnames = api._infer_argnums_and_argnames(
sig, argnums=None, argnames=('foo', 'bar'))
assert argnums == ()
assert argnames == ('foo', 'bar')
def test_jit_with_static_argnames(self):
def f(x):
assert x == 'foo'
return 1
f_nums = self.jit(f, static_argnums=0)
assert f_nums('foo') == 1
assert f_nums(x='foo') == 1
f_names = self.jit(f, static_argnames='x')
assert f_names('foo') == 1
assert f_names(x='foo') == 1
def test_new_static_argnum_on_keyword_arguments(self):
f = self.jit(lambda x: x, static_argnums=0)
y = f(x=4)
assert y == 4
def test_new_static_argnum_with_default_arguments(self):
f = self.jit(lambda x=4: x, static_argnums=0)
y = f()
assert y == 4
def test_jit_with_mismatched_static_argnames(self):
x_is_tracer, y_is_tracer = False, False
def f(x, y):
assert isinstance(x, core.Tracer) == x_is_tracer
assert isinstance(y, core.Tracer) == y_is_tracer
return 1
# If both static_argnums and static_argnames are provided, they are allowed
# to disagree and `jit` will respect the user's choices.
f_nums = self.jit(f, static_argnums=1, static_argnames=())
x_is_tracer, y_is_tracer = True, False
assert f_nums(2, 'foo') == 1
x_is_tracer, y_is_tracer = True, True
assert f_nums(1, y=2) == 1
f_names = self.jit(f, static_argnums=(), static_argnames='y')
x_is_tracer, y_is_tracer = True, True
assert f_names(2, 3) == 1
x_is_tracer, y_is_tracer = True, False
assert f_names(1, y='foo') == 1
f_mixed = self.jit(f, static_argnums=(1,), static_argnames='x')
x_is_tracer, y_is_tracer = True, False
assert f_mixed(2, 'foo') == 1
x_is_tracer, y_is_tracer = True, True
assert f_mixed(1, y=3) == 1
x_is_tracer, y_is_tracer = False, True
assert f_mixed(x='foo', y=3) == 1
# TODO(zhangqiaorjc): Test pruning constants after DCE pass prunes primitive
# applications.
@parameterized.parameters(2, 3, 4)
def test_jit_with_pruned_args(self, num_args):
def f(*args):
used = np.array(2)
return args[1] + used
f_pruned = self.jit(f)
args = range(num_args)
with jtu.count_device_put() as count:
np.testing.assert_allclose(f_pruned(*args), 3)
self.assertEqual(count[0], 1)
def testBuffersAreFreedPromptly(self):
# Regression test for a bug where garbage collection was delayed too long
# for NumPy buffers that are aliased zero-copy by the runtime.
@self.jit
def f(x):
return x + 1
refs = []
x = np.ones((10000,), np.float32)
for step in range(1000):
x = f(x)
refs.append(weakref.ref(x))
x = np.asarray(x)
# We expect most of the input buffers to have been garbage
# collected in parallel with the execution. We can't call
# block_until_ready() here because it would force a garbage collection.
live_refs = len([ref for ref in refs if ref() is not None])
self.assertLessEqual(live_refs, 100)
def test_jit_lower_compile(self):
def f(x):
return jnp.sqrt(x ** 2) + 1.
f_jit = self.jit(f)
lowered = f_jit.lower(1.)
compiled = lowered.compile()
self.assertAllClose(compiled(1.), 2.)
self.assertEqual(lowered.in_avals, compiled.in_avals)
expected_dtype = np.float64 if config.x64_enabled else np.float32
for obj in [lowered, compiled]:
self.assertEqual(
obj.in_avals,
((jax.ShapedArray([], expected_dtype, weak_type=True),), {}))
self.assertEqual(obj.in_tree, jax.tree_util.tree_flatten(((0,), {}))[1])
def test_jit_lower_duck_typing(self):
f_jit = self.jit(lambda x: 2 * x)
f_low = f_jit.lower(jax.ShapeDtypeStruct((), 'float32')) # doesn't crash
f_exe = f_low.compile()
self.assertAllClose(f_exe(jnp.float32(1.)), jnp.float32(2.))
def test_jit_lower_compile_in_tree_mismatch(self):
def f(x):
return jnp.sqrt(x ** 2) + 1.
f_jit = self.jit(f)
f_low = f_jit.lower(1.)
f_exe = f_low.compile()
self.assertRaisesRegex(
TypeError, "function compiled for .*, called with .*",
lambda: f_exe([1.]))
def test_jit_lower_compile_trivial(self):
def f(x): return x
out = self.jit(f).lower(1.).compile()(4.)
self.assertAllClose(out, 4.)
def test_jit_lower_compile_sharding_computation(self):
if not config.jax_array:
self.skipTest('with_sharding_constraint only works with the Array path '
'in jit.')
s = sharding.SingleDeviceSharding(jax.devices()[0])
def f(x): return pjit.with_sharding_constraint(x, s)
out = self.jit(f).lower(1.).compile()(4.)
self.assertAllClose(out, 4.)
def test_jit_lower_compile_trivial_in_tree_mismatch(self):
def f(x): return x
f_exe = self.jit(f).lower(1.).compile()
self.assertRaisesRegex(
TypeError, "function compiled for .*, called with .*",
lambda: f_exe([4.]))
def test_jit_lower_compile_arg_type_mismatch(self):
def f(x):
return jnp.sqrt(x ** 2) + 1.
x = jnp.array(1, dtype=int)
x_f32 = x.astype(jnp.float32)
x_i32 = x.astype(jnp.int32)
f_exe = self.jit(f).lower(x_f32).compile()
self.assertRaisesRegex(
TypeError,
"Computation was compiled for different input types and called with "
"different types. One of the mismatches is:\n"
"Compiled with:\n.*float32.*\n"
"called with:\n.*int32.*",
lambda: f_exe(x_i32))
def test_jit_lower_compile_multi_arg(self):
def f(*args):
x, *_ = args
return jnp.sqrt(x ** 2) + 1.
f_exe = self.jit(f).lower(1., 1.).compile()
self.assertAllClose(f_exe(1., 1.), 2.)
def test_jit_lower_compile_trivial_multi_arg(self):
def f(*args):
x, *_ = args
return x
f_exe = self.jit(f).lower(1., 1.).compile()
self.assertAllClose(f_exe(1., 1.), 1.)
def test_jit_lower_donate_argnums_available(self):
if jtu.device_under_test() == "cpu" and xla_extension_version < 102:
raise unittest.SkipTest("CPU buffer donation requires jaxlib > 0.3.22")
def f(*args):
x, *_ = args
return x + 4.
f_low = self.jit(f, donate_argnums=(0,)).lower(1., 1.)
f_com = f_low.compile()
f_low.donate_argnums == f_com.donate_argnums == (0,)
def test_jit_lower_compile_vmap(self):
f = self.jit(lambda x: x + 4).lower(1.).compile()
def err():
return jax.vmap(lambda x: f(x) + 2)(jnp.ones(3))
self.assertRaisesRegex(
TypeError,
"Cannot apply JAX transformations to a function lowered and compiled "
"for a particular signature. Detected .*BatchTracer",
err)
def test_jit_lower_as_text(self):
f = self.jit(lambda x: x + 4).lower(1.)
self.assertIsInstance(f.as_text(), str)
self.assertIsInstance(f.as_text(dialect='hlo'), str)
self.assertIsInstance(f.as_text(dialect='mhlo'), str)
if mlir_api_version >= 37:
self.assertIsInstance(f.as_text(dialect="stablehlo"), str)
def test_jit_lower_compiler_ir(self):
f = self.jit(lambda x: x + 4).lower(1.)
self.assertIsNotNone(f.compiler_ir())
self.assertIsNotNone(f.compiler_ir(dialect='hlo'))
self.assertIsNotNone(f.compiler_ir(dialect='mhlo'))
if mlir_api_version >= 37:
self.assertIsNotNone(f.compiler_ir(dialect="stablehlo"))
def test_jit_lower_trivial_compiler_ir(self):
f = self.jit(lambda x: x).lower(1.)
self.assertIsNotNone(f.compiler_ir())
self.assertIsNotNone(f.compiler_ir(dialect='hlo'))
self.assertIsNotNone(f.compiler_ir(dialect='mhlo'))
if mlir_api_version >= 37:
self.assertIsNotNone(f.compiler_ir(dialect="stablehlo"))
def test_jit_lower_no_prunning(self):
compiled = self.jit(lambda x, y: x + y).lower(1., 2.).compile()
self.assertEqual(compiled._executable._kept_var_idx, {0, 1})
self.assertLen(compiled._executable.in_avals, 2)
compiled = self.jit(lambda x, y: x).lower(1., 2.).compile()
self.assertEqual(compiled._executable._kept_var_idx, {0})
self.assertLen(compiled._executable.in_avals, 1)
compiled = self.jit(lambda x, y: x, keep_unused=True).lower(
1., 2.).compile()
self.assertEqual(compiled._executable._kept_var_idx, {0, 1})
self.assertLen(compiled._executable.in_avals, 2)
# Also works with jax.jit
jitted_f = self.jit(lambda x, y: x, keep_unused=True)
with jtu.count_device_put() as count:
_ = jitted_f(1, 2)
self.assertEqual(count[0], 1)
@jtu.ignore_warning(category=DeprecationWarning)
def test_jit_lower_compile_compiler_ir(self):
# TODO(frostig): remove (deprecated)
f = self.jit(lambda x: x + 4).lower(1.).compile()
self.assertIsNotNone(f.compiler_ir())
@jtu.ignore_warning(category=DeprecationWarning)
def test_jit_lower_trivial_compile_compiler_ir(self):
# TODO(frostig): remove (deprecated)
f = self.jit(lambda x: x).lower(1.).compile()
self.assertIsNotNone(f.compiler_ir())
def test_jit_lower_compile_as_text(self):
f = self.jit(lambda x: x).lower(1.).compile()
g = self.jit(lambda x: x + 4).lower(1.).compile()
self.assertIsInstance(f.as_text(), (str, type(None)))
self.assertIsInstance(g.as_text(), (str, type(None)))
def test_jit_lower_compile_cost_analysis(self):
f = self.jit(lambda x: x).lower(1.).compile()
g = self.jit(lambda x: x + 4).lower(1.).compile()
f.cost_analysis() # doesn't raise
g.cost_analysis() # doesn't raise
def test_jit_lower_compile_memory_analysis(self):
f = self.jit(lambda x: x).lower(1.).compile()
g = self.jit(lambda x: x + 4).lower(1.).compile()
f.memory_analysis() # doesn't raise
g.memory_analysis() # doesn't raise
def test_jit_lower_compile_executable(self):
f = self.jit(lambda x: x).lower(1.).compile()
g = self.jit(lambda x: x + 4).lower(1.).compile()
self.assertIsNotNone(f.runtime_executable())
self.assertIsNotNone(g.runtime_executable())
def test_jit_enum_as_dict_keys_fails(self):
class E(enum.Enum):
A = 0
B = 1
@self.jit
def f(d) -> float:
return d[E.A]
with self.assertRaisesRegex(TypeError, "'<' not supported.*"):
f({E.A: 1.0, E.B: 2.0})
def test_jit_static_argnums_requires_type_equality(self):
# See: https://github.com/google/jax/pull/9311
@partial(self.jit, static_argnums=(0,))
def f(k):
assert python_should_be_executing
return k
# Values of 'x' that compare as equal but have different types do not lead
# to cache hits.
for x in [1, True, 1.0]:
python_should_be_executing = True
self.assertEqual(x, f(x))
python_should_be_executing = False
self.assertEqual(x, f(x))
@unittest.skipIf(xla_extension_version < 99, "C++ jax.Array is not available")
def test_hitting_cpp_path(self):
if not self.use_cpp_jit:
raise unittest.SkipTest("this test only applies to _cpp_jit")
jit_impl = dispatch._xla_call_impl_lazy
count = 0
def jit_impl_and_count(*args, **kwargs):
nonlocal count
count += 1
return jit_impl(*args, **kwargs)
f = self.jit(lambda x: x + 1)
try:
dispatch._xla_call_impl_lazy = jit_impl_and_count
f(0)
self.assertEqual(count, 1)
f(0)
self.assertEqual(count, 1)
f(1)
self.assertEqual(count, 1)
f(2)
self.assertEqual(count, 1)
finally:
dispatch._xla_call_impl_lazy = jit_impl
def test_caches_depend_on_axis_env(self):
# https://github.com/google/jax/issues/9187
f = lambda: lax.psum(1, "i")
g = jax.jit(f)
expected = jax.vmap(f, axis_name="i", axis_size=2, out_axes=None)()
ans = jax.vmap(g, axis_name="i", axis_size=2, out_axes=None)()
self.assertEqual(ans, expected)
# This second call to g could erroneously get a cache hit.
expected = jax.vmap(f, axis_name="i", axis_size=3, out_axes=None)()
ans = jax.vmap(g, axis_name="i", axis_size=3, out_axes=None)()
self.assertEqual(ans, expected)
def test_caches_dont_depend_on_unnamed_axis_env(self):
# https://github.com/google/jax/issues/9187
f = jax.jit(lambda: jnp.sin(1))
expected = f()
with jtu.count_jit_and_pmap_compiles() as count: # noqa: F841
ans = jax.vmap(f, axis_size=2, out_axes=None)()
self.assertEqual(count[0], 0) # no compiles
self.assertArraysAllClose(ans, expected, check_dtypes=True)
@unittest.skipIf(xla_extension_version < 99, "C++ jax.Array is not available")
def test_cache_key_defaults(self):
# https://github.com/google/jax/discussions/11875
if not self.use_cpp_jit:
raise unittest.SkipTest("this test only applies to _cpp_jit")
f = self.jit(lambda x: (x ** 2).sum())
self.assertEqual(f._cache_size(), 0)
x = jnp.arange(5.0)
for _ in range(3):
_ = f(x)
self.assertEqual(f._cache_size(), 1)
class PythonJitTest(CPPJitTest):
@property
def use_cpp_jit(self) -> bool:
return False
class APITest(jtu.JaxTestCase):
@parameterized.named_parameters(
('array', True),
('no_array', False)
)
def test_grad_item(self, array_enabled):
with jax_config.jax_array(array_enabled):
def f(x):
if x.astype(bool).item():
return x ** 2
else:
return x
out = jax.grad(f)(2.0)
self.assertEqual(out, 4)
@parameterized.named_parameters(
('array', True),
('no_array', False)
)
def test_jit_item(self, array_enabled):
with jax_config.jax_array(array_enabled):
def f(x):
return x.item()
x = jnp.array(1.0)
self.assertEqual(f(x), x)
with self.assertRaisesRegex(core.ConcretizationTypeError, "Abstract tracer value"):
jax.jit(f)(x)
@parameterized.named_parameters(
('grad', jax.grad),
('jacfwd', jax.jacfwd),
('jacref', jax.jacrev),
)
def test_grad_wrap(self, transform):
# Ensures that transforms wrap transformed functions with the correct signature.
@partial(jit, static_argnames=['flag'])
@transform
def my_function(x, flag):
return x if flag else jnp.zeros_like(x)
self.assertEqual(my_function(1.0, False), 0.0)
self.assertEqual(my_function(1.0, True), 1.0)
def test_grad_bad_input(self):
def f(x):
return x
self.assertRaisesRegex(
TypeError, ".* 'foo' of type <.*'str'> is not a valid JAX type",
lambda: grad(f)("foo"))
def test_grad_argnums(self):
def f(x, y, z, flag=False):
assert flag
return 1.0 * x + 2.0 * y + 3.0 * z
assert grad(f)(1.0, 1.0, 1.0, flag=True) == 1.0
assert grad(f, argnums=1)(1.0, 1.0, 1.0, flag=True) == 2.0
assert grad(f, argnums=(2, 0))(1.0, 1.0, 1.0, flag=True) == (3.0, 1.0)
def test_value_and_grad_argnums(self):
def f(x, y, z, flag=False):
assert flag
return 1.0 * x + 2.0 * y + 3.0 * z
y = f(1.0, 1.0, 1.0, flag=True)
assert api.value_and_grad(f)(1.0, 1.0, 1.0, flag=True) == (y, 1.0)
assert api.value_and_grad(f, argnums=1)(1.0, 1.0, 1.0, flag=True) == (y, 2.0)
assert api.value_and_grad(f, argnums=(2, 0))(1.0, 1.0, 1.0, flag=True) == (y, (3.0, 1.0))
def test_grad_of_jit(self):
side = []
@jit
def f(x):
side.append(None)
return x * x
assert grad(f)(1.0) == 2.0
assert len(side) == 1
assert grad(f)(2.0) == 4.0
assert len(side) == 1
def test_jit_of_grad(self):
side = []
@jit
def f(x):
side.append(None)
return x * x
g = jit(grad(f))
assert g(1.0) == 2.0
assert len(side) == 1
assert g(2.0) == 4.0
assert len(side) == 1
@parameterized.named_parameters(
{"testcase_name": f"_{transform.__name__}", "transform": transform}
for transform in [grad, jacfwd, jacrev])
def test_ad_weak_types(self, transform):
out = transform(lambda x: x)(1.0)
self.assertTrue(dtypes.is_weakly_typed(out))
def test_bad_input(self):
def f(x):
return x
self.assertRaisesRegex(
TypeError, ".* 'foo' of type <.*'str'> is not a valid JAX type",
lambda: grad(f)("foo"))
self.assertRaisesRegex(
TypeError, ".* 'foo' of type <.*'str'> is not a valid JAX type",
lambda: jit(f)("foo"))
def test_grad_tuple_output(self):
jtu.check_raises(lambda: grad(lambda x: (x,x))(1.0), TypeError,
"Gradient only defined for scalar-output functions. ")
def test_grad_unit_output(self):
jtu.check_raises(lambda: grad(lambda x: ())(np.zeros(3)), TypeError,
"Gradient only defined for scalar-output functions. ")
def test_grad_nonscalar_output(self):
jtu.check_raises(lambda: grad(lambda x: x)(np.zeros(3)), TypeError,
"Gradient only defined for scalar-output functions. ")
def test_unwrapped_numpy(self):
def f(x):
return np.exp(x)
with self.assertRaisesRegex(Exception, "The numpy.ndarray conversion .*"):
grad(f)(np.zeros(3))
def test_binop_mismatch(self):
def f(x, y):
return x + y
jtu.check_raises(
lambda: f(jnp.zeros(3), jnp.zeros(4)),
TypeError,
"add got incompatible shapes for broadcasting: (3,), (4,).")
jtu.check_raises(
lambda: grad(f)(np.zeros(3), np.zeros(4)),
TypeError,
"add got incompatible shapes for broadcasting: (3,), (4,).")
def test_dot_mismatch(self):
def f(x, y):
return jnp.dot(x, y)
self.assertRaisesRegex(
TypeError, "Incompatible shapes for dot: got \\(3L?,\\) and \\(4L?,\\).",
lambda: grad(f)(np.zeros(3), np.zeros(4)))
def test_abstract_error_message(self):
for castfun in [float, complex, int]:
def f(x):
return castfun(x)
self.assertRaisesRegex(
TypeError,
f"[Tt]ry using `x.astype\\({castfun.__name__}\\)`",
lambda: jit(f)(1.0))
def test_switch_value_jit(self):
def f(x):
y = x > 0
if y:
return x
else:
return -x
assert grad(f)(1.0) == 1.0
assert grad(f)(-1.0) == -1.0
with self.assertRaisesRegex(core.ConcretizationTypeError,
"Abstract tracer value"):
jit(f)(1)
def test_list_index_err(self):
L = [1, 2, 3]
def f(n):
return L[n]
assert jit(f, static_argnums=(0,))(0) == L[0]
self.assertRaisesRegex(
TypeError,
r"The __index__\(\) method was called on the JAX Tracer object.*",
lambda: jit(f)(0))
def test_range_err(self):
def f(x, n):
for i in range(n):
x = x + i
return x
assert jit(f, static_argnums=(1,))(0, 5) == 10
self.assertRaisesRegex(
TypeError,
r"The __index__\(\) method was called on the JAX Tracer object.*",
lambda: jit(f)(0, 5))
def test_cast_int(self):
f = lambda x: int(x)
self.assertRaisesRegex(
TypeError,
"('(?:JaxprTracer|DynamicJaxprTracer)' object cannot be interpreted as an integer"
"|Abstract tracer value encountered where concrete value is expected.*)", lambda: jit(f)(0))
def test_casts(self):
for castfun in [hex, oct]:
f = lambda x: castfun(x)
self.assertRaisesRegex(
TypeError,
r"The __index__\(\) method was called on the JAX Tracer object.*", lambda: jit(f)(0))
def test_unimplemented_interpreter_rules(self):
foo_p = Primitive('foo')
def foo(x):
return foo_p.bind(x)
jtu.check_raises(lambda: foo(1.0), NotImplementedError,
"Evaluation rule for 'foo' not implemented")
jtu.check_raises(lambda: jit(foo)(1.0), NotImplementedError,
"Abstract evaluation for 'foo' not implemented")
jtu.check_raises(lambda: grad(foo)(1.0), NotImplementedError,
"Differentiation rule for 'foo' not implemented")
foo_p.def_abstract_eval(lambda x: x)
jtu.check_raises_regexp(lambda: jit(foo)(1.0), NotImplementedError,
".* rule for primitive 'foo' not found.*")
foo_p.def_impl(lambda x: x)
ad.defjvp(foo_p, lambda g, x: foo(g))
jtu.check_raises(lambda: grad(foo)(1.0), NotImplementedError,
"Transpose rule (for reverse-mode differentiation) for 'foo' not implemented")
def test_is_subclass(self):
self.assertTrue(issubclass(device_array.DeviceArray, jnp.ndarray))
self.assertTrue(issubclass(device_array.Buffer, jnp.ndarray))
self.assertTrue(issubclass(pxla.ShardedDeviceArray, jnp.ndarray))
self.assertTrue(issubclass(pxla._ShardedDeviceArray, jnp.ndarray))
self.assertFalse(issubclass(np.ndarray, jnp.ndarray))
self.assertFalse(issubclass(device_array.DeviceArray, np.ndarray))
self.assertFalse(issubclass(device_array.Buffer, np.ndarray))
self.assertFalse(issubclass(pxla.ShardedDeviceArray, np.ndarray))
self.assertFalse(issubclass(pxla._ShardedDeviceArray, np.ndarray))
def test_is_instance(self):
def f(x):
self.assertIsInstance(x, jnp.ndarray)
self.assertNotIsInstance(x, np.ndarray)
return x + 2
jit(f)(3)
jax.vmap(f)(np.arange(3))
def test_device_put_and_get(self):
x = np.arange(12.).reshape((3, 4)).astype("float32")
dx = api.device_put(x)
_check_instance(self, dx)
self.assertIsInstance(dx, jnp.ndarray)
self.assertNotIsInstance(dx, np.ndarray)
x2 = api.device_get(dx)
self.assertNotIsInstance(x2, jnp.ndarray)
self.assertIsInstance(x2, np.ndarray)
assert np.all(x == x2)
y = [x, (2 * x, 3 * x)]
dy = api.device_put(y)
y2 = api.device_get(dy)
self.assertIsInstance(y2, list)
self.assertIsInstance(y2[0], np.ndarray)
assert np.all(y2[0] == x)
self.assertIsInstance(y2[1], tuple)
self.assertIsInstance(y2[1][0], np.ndarray)
assert np.all(y2[1][0] == 2 * x)
self.assertIsInstance(y2[1][1], np.ndarray)
assert np.all(y2[1][1] == 3 * x)
@jax_config.jax_array(True)
def test_device_put_sharding(self):
mesh = maps.Mesh(jax.devices(), ('x',))
s = sharding.NamedSharding(mesh, P('x'))
x = jnp.arange(len(jax.devices()))
y = jax.device_put(x, s)
self.assertEqual(y.sharding, s)
self.assertArraysAllClose(y, x)
# this might hit a special fast path
z = jax.device_put(y, s)
self.assertEqual(z.sharding, s)
self.assertArraysAllClose(z, x)
self.assertIs(z, y) # no copy
w = jax.device_put(z)
self.assertIs(w, z)
u = jax.device_put(y, jax.devices()[0])
self.assertArraysAllClose(u, y)
self.assertEqual(u.device(), jax.devices()[0])
@jax_config.jax_array(True)
def test_device_put_sharding_tree(self):
if jax.device_count() < 2:
raise unittest.SkipTest("Test requires >= 2 devices")
mesh = maps.Mesh(np.array(jax.devices()[:2]).reshape((2, 1)), ("x", "y"))
s1 = sharding.NamedSharding(mesh, P("x"))
s2 = sharding.NamedSharding(mesh, P("y"))
s3 = sharding.NamedSharding(mesh, P("x", "y"))
x = jnp.arange(2)
y = jnp.arange(2) + 10
z = (jnp.arange(2) + 100).reshape((2, 1))
out = jax.device_put((x, (y, z)), device=(s1, (s2, s3)))
self.assertEqual(out[0].sharding, s1)
self.assertEqual(out[1][0].sharding, s2)
self.assertEqual(out[1][1].sharding, s3)
self.assertArraysAllClose(out[0], x)
self.assertArraysAllClose(out[1][0], y)
self.assertArraysAllClose(out[1][1], z)
@jax_config.jax_array(True)
def test_device_put_sharding_tree_prefix(self):
if jax.device_count() < 2:
raise unittest.SkipTest("Test requires >= 2 devices")
mesh = maps.Mesh(np.array(jax.devices()[:2]).reshape((2, 1)), ("x", "y"))
s1 = sharding.NamedSharding(mesh, P("x"))
s2 = sharding.NamedSharding(mesh, P("y"))
x = jnp.arange(2)
y = jnp.arange(2) + 10
z = jnp.arange(2) + 100
out = jax.device_put((x, (y, z)), device=(s1, s2))
self.assertEqual(out[0].sharding, s1)
self.assertEqual(out[1][0].sharding, s2)
self.assertEqual(out[1][1].sharding, s2)
self.assertArraysAllClose(out[0], x)
self.assertArraysAllClose(out[1][0], y)
self.assertArraysAllClose(out[1][1], z)
@jax_config.jax_array(True)
def test_device_put_sharding_mismatched_tree_same_leaf_count(self):
if jax.device_count() < 2:
raise unittest.SkipTest("Test requires >= 2 devices")
mesh = maps.Mesh(np.array(jax.devices()[:2]).reshape((2, 1)), ("x", "y"))
s1 = sharding.NamedSharding(mesh, P("x"))
s2 = sharding.NamedSharding(mesh, P("y"))
x = jnp.arange(2)
y = jnp.arange(2) + 10
z = jnp.arange(2) + 100
with self.assertRaisesRegex(
ValueError,
"device_put device specification must be a tree prefix of the "
r"corresponding value, got specification \(\(NamedSharding\(.*\), "
r"NamedSharding\(.*\)\), NamedSharding\(.*\)\) for value tree "
r"PyTreeDef\(\(\*, \(\*, \*\)\)\)."
):
jax.device_put((x, (y, z)), device=((s1, s2), s2))
@jax_config.jax_array(True)
def test_device_put_sharding_mismatched_tree_different_leaf_count(self):
if jax.device_count() < 2:
raise unittest.SkipTest("Test requires >= 2 devices")
mesh = maps.Mesh(np.array(jax.devices()[:2]).reshape((2, 1)), ("x", "y"))
s1 = sharding.NamedSharding(mesh, P("x"))
s2 = sharding.NamedSharding(mesh, P("y"))
x = jnp.arange(2)
y = jnp.arange(2) + 10
z = jnp.arange(2) + 100
with self.assertRaisesRegex(
ValueError,
"device_put device specification must be a tree prefix of the "
r"corresponding value, got specification \(NamedSharding\(.*\), "
r"NamedSharding\(.*\)\) for value tree PyTreeDef\(\(\*, \*, \*\)\)."
):
jax.device_put((x, y, z), device=(s1, s2))
def test_device_get_scalar(self):
x = np.arange(12.).reshape((3, 4)).astype("float32")
x = api.device_put(x)
_check_instance(self, x)
self.assertIsInstance(x.sharding, jax.sharding.SingleDeviceSharding)
for s in x.addressable_shards:
self.assertArraysEqual(s.data, x)
self.assertEqual(s.replica_id, 0)
self.assertEqual(s.index, (slice(None), slice(None)))
y = [x, 2]
y2 = api.device_get(y)
self.assertIsInstance(y2, list)
self.assertIsInstance(y2[0], np.ndarray)
assert np.all(y2[0] == x)
self.assertIsInstance(y2[1], int)
self.assertEqual(y2[1], 2)
@parameterized.parameters([(3,)], [(2, 0)])
def test_device_put_across_devices(self, shape):
if len(api.local_devices()) < 2:
raise unittest.SkipTest("this test requires multiple devices")
d1, d2 = api.local_devices()[:2]
data = self.rng().randn(*shape).astype(np.float32)
x = api.device_put(data, device=d1)
if config.jax_array:
self.assertEqual(x.device(), d1)
else:
self.assertEqual(x.device_buffer.device(), d1)
y = api.device_put(x, device=d2)
if config.jax_array:
self.assertEqual(y.device(), d2)
else:
self.assertEqual(y.device_buffer.device(), d2)
np.testing.assert_array_equal(data, np.array(y))
# Make sure these don't crash
api.device_put(x)
api.device_put(y)
@jtu.skip_on_devices("cpu")
def test_device_put_across_platforms(self):
default_device = jax.devices()[0]
cpu_device = jax.devices("cpu")[0]
np_arr = np.array([1,2,3])
scalar = 1
device_arr = jnp.array([1,2,3])
if config.jax_array:
assert device_arr.device() is default_device
else:
assert device_arr.device_buffer.device() is default_device
for val in [np_arr, device_arr, scalar]:
x = api.device_put(val, device=cpu_device)
if config.jax_array:
self.assertEqual(x.device(), cpu_device)
else:
self.assertEqual(x.device_buffer.device(), cpu_device)
@jtu.skip_on_devices("tpu")
def test_jacobian(self):
R = self.rng().randn
A = R(4, 3)
x = R(3)
f = lambda x: jnp.dot(A, x)
assert np.allclose(jacfwd(f)(x), A)
assert np.allclose(jacrev(f)(x), A)
f = lambda x: jnp.tanh(jnp.dot(A, x))
assert np.allclose(jacfwd(f)(x), jacrev(f)(x))
@jtu.skip_on_devices("tpu")
def test_hessian(self):
R = self.rng().randn
A = R(4, 4)
x = R(4)
f = lambda x: jnp.dot(x, jnp.dot(A, x))
assert np.allclose(hessian(f)(x), A + A.T)
@jtu.skip_on_devices("tpu")
def test_hessian_holomorphic(self):
R = self.rng().randn
A = R(4, 4)
x = R(4).astype('complex64') * (1 + 2j)
f = lambda x: jnp.dot(x, jnp.dot(A.astype(x.dtype), x))
assert np.allclose(hessian(f, holomorphic=True)(x), A + A.T)
@jtu.skip_on_devices("tpu")
def test_hessian_aux(self):
R = self.rng().randn
A = R(4, 4)
x = R(4)
f = lambda x: (jnp.dot(x, jnp.dot(A, x)), x)
h, aux = hessian(f, has_aux=True)(x)
assert np.allclose(h, A + A.T)
assert np.allclose(aux, x)
def test_std_basis(self):
basis = api._std_basis(jnp.zeros(3))
assert getattr(basis, "shape", None) == (3, 3)
assert np.allclose(basis, np.eye(3))
basis = api._std_basis(jnp.zeros((3, 3)))
assert getattr(basis, "shape", None) == (9, 3, 3)
assert np.allclose(basis, np.eye(9).reshape(9, 3, 3))
basis = api._std_basis([0., (jnp.zeros(3), jnp.zeros((3, 4)))])
assert isinstance(basis, list) and len(basis) == 2
assert getattr(basis[0], "shape", None) == (16,)
assert isinstance(basis[1], tuple) and len(basis[1]) == 2
assert getattr(basis[1][0], "shape", None) == (16, 3)
assert getattr(basis[1][1], "shape", None) == (16, 3, 4)
@jtu.skip_on_devices("tpu")
def test_jacobian_on_pytrees(self):
for jacfun in [jacfwd, jacrev]:
ans = jacfun(lambda x, y: (x, y))(0., 1.)
expected = (1., 0.)
self.assertAllClose(ans, expected, check_dtypes=False)
ans = jacfun(lambda x, y: (x, y), 1)(0., 1.)
expected = (0., 1.)
self.assertAllClose(ans, expected, check_dtypes=False)
ans = jacfun(lambda x, y: (x, y), (0, 1))(0., 1.)
expected = ((1., 0.),
(0., 1.),)
self.assertAllClose(ans, expected, check_dtypes=False)
ans = jacfun(lambda x: x[:2])((1., 2., 3.))
expected = ((1., 0., 0.),
(0., 1., 0.))
self.assertAllClose(ans, expected, check_dtypes=False)
R = self.rng().randn
x = jnp.array(R(2))
y = jnp.array(R(3))
ans = jacfun(lambda x, y: {'x': x, 'xy': jnp.outer(x, y)})(x, y)
expected = {'x': np.eye(2),
'xy': np.kron(np.eye(2), y[:, None]).reshape(2, 3, 2)}
self.assertAllClose(ans, expected, check_dtypes=False)
@jtu.skip_on_devices("tpu")
def test_hessian_on_pytrees(self):
ans = hessian(lambda x: jnp.array(x)**2)((1., 2.))
expected = ((np.array([2., 0.]), np.array([0., 0.])),
(np.array([0., 0.]), np.array([0., 2.])))
self.assertAllClose(ans, expected, check_dtypes=False)
@jtu.skip_on_devices("tpu")
def test_issue1372(self):
def quad(x):
return jnp.dot(x, x)
def f(x, u):
return quad(x) + quad(u)
x, u = jnp.ones(5), jnp.ones(2)
rev = jacrev
fwd = jacfwd
# Diagonal entries
self.assertEqual(rev(rev(f, 0), 0)(x, u).shape, (5, 5))
self.assertEqual(rev(fwd(f, 0), 0)(x, u).shape, (5, 5))
self.assertEqual(fwd(rev(f, 0), 0)(x, u).shape, (5, 5))
self.assertEqual(fwd(fwd(f, 0), 0)(x, u).shape, (5, 5))
self.assertEqual(rev(rev(f, 1), 1)(x, u).shape, (2, 2))
self.assertEqual(rev(fwd(f, 1), 1)(x, u).shape, (2, 2))
self.assertEqual(fwd(rev(f, 1), 1)(x, u).shape, (2, 2))
self.assertEqual(fwd(fwd(f, 1), 1)(x, u).shape, (2, 2))
# Off-diagonal entries by reverse-mode on the outside
self.assertEqual(rev(rev(f, 1), 0)(x, u).shape, (2, 5))
self.assertEqual(rev(fwd(f, 1), 0)(x, u).shape, (2, 5))
self.assertEqual(rev(rev(f, 0), 1)(x, u).shape, (5, 2))
self.assertEqual(rev(fwd(f, 0), 1)(x, u).shape, (5, 2))
# Off-diagonal entries by forward-mode on the outside
self.assertEqual(fwd(rev(f, 1), 0)(x, u).shape, (2, 5))
self.assertEqual(fwd(fwd(f, 1), 0)(x, u).shape, (2, 5))
self.assertEqual(fwd(rev(f, 0), 1)(x, u).shape, (5, 2))
self.assertEqual(fwd(fwd(f, 0), 1)(x, u).shape, (5, 2))
def test_large_device_constant(self):
ans = jit(lambda x: 2 * x)(jnp.ones(int(2e6))) # doesn't crash
self.assertAllClose(ans, np.ones(int(2e6)) * 2., check_dtypes=False)
def test_grad_and_aux_basic(self):
g, aux = grad(lambda x: (x**3, [x**2]), has_aux=True)(3.)
self.assertAllClose(g, grad(lambda x: x**3)(3.))
self.assertAllClose(aux, [9.], check_dtypes=False)
def test_grad_and_aux_error(self):
with self.assertRaisesRegex(TypeError, "two-element tuple"):
grad(lambda x: (1, 2, 3), has_aux=True)(1.)
with self.assertRaisesRegex(TypeError, "two-element tuple"):
grad(lambda x: x, has_aux=True)(1.)
with self.assertRaisesRegex(TypeError, "two-element tuple"):
grad(lambda x: (x,), has_aux=True)(1.)
def test_grad_and_aux_nested(self):
def f(x):
g, aux = grad(lambda x: (x**3, [x**3]), has_aux=True)(x)
return aux[0]
f2 = lambda x: x**3
self.assertEqual(grad(f)(4.), grad(f2)(4.))
self.assertEqual(jit(grad(f))(4.), grad(f2)(4.))
self.assertEqual(jit(grad(jit(f)))(4.), grad(f2)(4.))
def f(x):
g, aux = grad(lambda x: (x**3, [x**3]), has_aux=True)(x)
return aux[0] * jnp.sin(x)
f2 = lambda x: x**3 * jnp.sin(x)
self.assertEqual(grad(f)(4.), grad(f2)(4.))
self.assertEqual(jit(grad(f))(4.), grad(f2)(4.))
self.assertEqual(jit(grad(jit(f)))(4.), grad(f2)(4.))
def test_grad_and_aux_constant(self):
g, aux = grad(lambda x: (x**3, [4.]), has_aux=True)(4.)
self.assertEqual(g, grad(lambda x: x**3)(4.))
self.assertEqual(aux, [4.])
g, aux = grad(lambda x: (x**3, [x**2, 4.]), has_aux=True)(4.)
self.assertEqual(g, grad(lambda x: x**3)(4.))
self.assertEqual(aux, [4.**2, 4.])
def test_grad_and_aux_no_tracers(self):
# see https://github.com/google/jax/issues/1950
def f(x):
aux = dict(identity=x, p1=x+1)
return x ** 2, aux
_, aux = jax.grad(f, has_aux=True)(3.)
self.assertIsInstance(aux, dict)
for val in aux.values():
self.assertNotIsInstance(val, core.Tracer)
def test_jacfwd_and_aux_basic(self):
jac, aux = jacfwd(lambda x: (x**3, [x**2]), has_aux=True)(3.)
self.assertAllClose(jac, jacfwd(lambda x: x**3)(3.))
self.assertAllClose(aux, [9.], check_dtypes=False)
def test_jacrev_and_aux_basic(self):
jac, aux = jacrev(lambda x: (x**3, [x**2]), has_aux=True)(3.)
self.assertAllClose(jac, jacrev(lambda x: x**3)(3.))
self.assertAllClose(aux, [9.], check_dtypes=False)
def test_jacfwd_and_aux_nested(self):
def f(x):
jac, aux = jacfwd(lambda x: (x**3, [x**3]), has_aux=True)(x)
return aux[0]
f2 = lambda x: x**3
self.assertEqual(jacfwd(f)(4.), jacfwd(f2)(4.))
self.assertEqual(jit(jacfwd(f))(4.), jacfwd(f2)(4.))
self.assertEqual(jit(jacfwd(jit(f)))(4.), jacfwd(f2)(4.))
def f(x):
jac, aux = jacfwd(lambda x: (x**3, [x**3]), has_aux=True)(x)
return aux[0] * jnp.sin(x)
f2 = lambda x: x**3 * jnp.sin(x)
self.assertEqual(jacfwd(f)(4.), jacfwd(f2)(4.))
self.assertEqual(jit(jacfwd(f))(4.), jacfwd(f2)(4.))
self.assertEqual(jit(jacfwd(jit(f)))(4.), jacfwd(f2)(4.))
def test_jacrev_and_aux_nested(self):
def f(x):
jac, aux = jacrev(lambda x: (x**3, [x**3]), has_aux=True)(x)
return aux[0]
f2 = lambda x: x**3
self.assertEqual(jacrev(f)(4.), jacrev(f2)(4.))
self.assertEqual(jit(jacrev(f))(4.), jacrev(f2)(4.))
self.assertEqual(jit(jacrev(jit(f)))(4.), jacrev(f2)(4.))
def f(x):
jac, aux = jacrev(lambda x: (x**3, [x**3]), has_aux=True)(x)
return aux[0] * jnp.sin(x)
f2 = lambda x: x**3 * jnp.sin(x)
self.assertEqual(jacrev(f)(4.), jacrev(f2)(4.))
self.assertEqual(jit(jacrev(f))(4.), jacrev(f2)(4.))
self.assertEqual(jit(jacrev(jit(f)))(4.), jacrev(f2)(4.))
def test_jvp_and_aux_basic(self):
fun = lambda x: (x**3, [x**2])
primals, tangents, aux = api.jvp(fun, (3.,), (4.,), has_aux=True)
expected_primals, expected_tangents = api.jvp(lambda x: x**3, (3.,), (4.,))
self.assertAllClose(primals, expected_primals, check_dtypes=True)
self.assertAllClose(tangents, expected_tangents, check_dtypes=True)
self.assertEqual(aux, [3.**2])
def test_jvp_mismatched_arguments(self):
self.assertRaisesRegex(
TypeError,
("primal and tangent arguments to jax.jvp must have the same tree "
"structure"),
lambda: api.jvp(lambda x, y: x * y, (np.float32(2),), ()))
# If primals and tangents must both be tuples or both lists
self.assertRaisesRegex(
TypeError,
("primal and tangent arguments to jax.jvp must have the same tree "
"structure"),
lambda: api.jvp(lambda x, y: x * y, (np.float32(2),), [np.float32(2)]))
self.assertRaisesRegex(
TypeError,
"primal and tangent arguments to jax.jvp do not match.",
lambda: api.jvp(lambda x: -x, (np.float16(2),), (np.float32(4),)))
# If primals and tangents are not of the same shape then raise error
fun = lambda x: x+1
with self.assertRaisesRegex(
ValueError, "jvp called with different primal and tangent shapes"):
api.jvp(fun, (jnp.array([1.,2.,3.]),), (jnp.array([1.,2.,3.,4.]),))
with self.assertRaisesRegex(
ValueError, "jvp called with different primal and tangent shapes"):
api.jvp(fun, (jnp.float32(10.),), (jnp.array([1.,2.,3.], dtype=jnp.float32),))
with self.assertRaisesRegex(
ValueError, "jvp called with different primal and tangent shapes"):
api.jvp(fun, (jnp.array([1.,2.,3.], dtype=jnp.float32),), (jnp.float32(20.),))
with self.assertRaisesRegex(
ValueError, "jvp called with different primal and tangent shapes"):
api.jvp(fun, (jnp.array([1.,2.,3.]),), (20.,))
def test_jvp_non_tuple_arguments(self):
def f(x, y): return x + y
self.assertRaisesRegex(
TypeError,
"primal and tangent arguments to jax.jvp must be tuples or lists; found float and tuple.",
lambda: api.jvp(f, 0., (1.,)))
self.assertRaisesRegex(
TypeError,
"primal and tangent arguments to jax.jvp must be tuples or lists; found tuple and ndarray.",
lambda: api.jvp(f, (0.,), np.array([1., 2.])))
def test_vjp_mismatched_arguments(self):
_, pullback = api.vjp(lambda x, y: x * y, np.float32(3), np.float32(4))
self.assertRaisesRegex(
TypeError,
"Tree structure of cotangent input.*does not match",
lambda: pullback((np.float32(7), np.float32(100))))
self.assertRaisesRegex(
TypeError,
"Type of cotangent input to vjp pullback.*is not the expected tangent type",
lambda: pullback(np.float16(42)))
def test_vjp_bad_cotangent_shape(self):
x = np.ones((2, 5), dtype=np.float32)
y = np.ones((5, 3), dtype=np.float32)
def f_jax(x, y):
return jnp.matmul(x, y)
res, pullback = jax.vjp(f_jax, x, y)
with self.assertRaisesRegex(
ValueError,
"Shape of cotangent input to vjp pullback function .* must be the same as the shape of corresponding primal input .*"):
pullback(np.ones((2, 4), dtype=np.float32))
def test_jvp_jit_cached(self):
"""Bug in caching in presence of JVP and JIT."""
def func(x):
def inner(y):
return y * x
# Must have two calls to the inner jit (the second one hits the cache)
res1 = api.jit(inner)(4.)
res2 = api.jit(inner)(5.)
return res1 + res2
self.assertAllClose((45., 9.), api.jvp(func, (5.,), (1.,)))
def test_linear_transpose_abstract(self):
x = types.SimpleNamespace(shape=(3,), dtype=np.dtype(np.float32))
y = jnp.arange(3, dtype=np.float32)
transpose_fun = api.linear_transpose(lambda x: 2 * x, x)
z, = transpose_fun(y)
self.assertArraysEqual(2 * y, z, check_dtypes=True)
def test_linear_transpose_integer(self):
f = lambda x: 2 * x
transpose = api.linear_transpose(f, 1)
actual, = transpose(3)
expected = 6
self.assertEqual(actual, expected)
def test_linear_transpose_error(self):
with self.assertRaisesRegex(
TypeError, "linear_transpose only supports"):
api.linear_transpose(lambda x: 2. * x, 1)
transpose_fun = api.linear_transpose(lambda x: [x, x], 1.0)
with self.assertRaisesRegex(TypeError, "cotangent tree does not match"):
transpose_fun(1.0)
transpose_fun = api.linear_transpose(lambda x: jnp.stack([x, x]), 1.0)
with self.assertRaisesRegex(TypeError, "cotangent type does not match"):
transpose_fun(1.0)
transpose_fun = api.linear_transpose(lambda x: 1j * x, 1.0)
with self.assertRaisesRegex(TypeError, "cotangent type does not match"):
transpose_fun(1.0)
transpose_fun = api.linear_transpose(lambda x: x, 1.0)
with self.assertRaisesRegex(TypeError, "cotangent type does not match"):
transpose_fun(1j)
def test_linear_transpose_complex(self):
f = lambda x: (1 + 2j) * x
transpose = api.linear_transpose(f, 1j)
actual, = transpose(3 + 4j)
expected = -5 + 10j
self.assertEqual(actual, expected)
def test_linear_transpose_zeros(self):
f = lambda x: x[0]
transpose = api.linear_transpose(f, [1., 2.])
actual, = transpose(3.)
expected = [3., 0.]
self.assertEqual(actual, expected)
def test_complex_grad_raises_error(self):
self.assertRaises(TypeError, lambda: grad(lambda x: jnp.sin(x))(1 + 2j))
def test_holomorphic_grad(self):
out = grad(lambda x: jnp.sin(x), holomorphic=True)(1 + 2j)
expected = 2.0327230070196656 - 3.0518977991518j
self.assertAllClose(out, expected, check_dtypes=False)
def test_nonholomorphic_grad(self):
zs = 0.5j * np.arange(5) + np.arange(5)
def f(z):
return jnp.sum(jnp.cos(jnp.abs(z)))
ans = grad(f)(zs)
expected = np.array([ 0. + 0.j,
-0.80430663 + 0.40215331j,
-0.70368982 + 0.35184491j,
0.1886467 - 0.09432335j,
0.86873727 - 0.43436864j])
self.assertAllClose(ans, expected, check_dtypes=False,
atol=jtu.default_gradient_tolerance,
rtol=jtu.default_gradient_tolerance)
def test_complex_output_jacrev_raises_error(self):
self.assertRaises(TypeError, lambda: jacrev(lambda x: jnp.sin(x))(1 + 2j))
def test_nonholomorphic_jacrev(self):
# code based on https://github.com/google/jax/issues/603
zs = 0.5j * np.arange(5) + np.arange(5)
def f(z):
return jnp.cos(jnp.linalg.norm(2 * z))
ans = jacrev(f)(zs)
expected = grad(f)(zs)
self.assertAllClose(ans, expected)
@jax.numpy_dtype_promotion('standard') # Test explicitly exercises implicit dtype promotion.
def test_heterogeneous_jacfwd(self):
# See https://github.com/google/jax/issues/7157
# See https://github.com/google/jax/issues/7780
x = np.array([2.0], dtype=np.float16)
y = np.array([3.0], dtype=np.float32)
a = (x, y)
def f(tup):
jtu._check_dtypes_match(tup, a)
x, y = tup
return x, y, x + y
actual = jacfwd(f)(a)
desired = ((np.array(1., dtype=np.float16), np.array(0., dtype=np.float16)),
(np.array(0., dtype=np.float32), np.array(1., dtype=np.float32)),
(np.array(1., dtype=np.float32), np.array(1., dtype=np.float32)))
jtu._check_dtypes_match(actual, desired)
jtu.check_eq(actual, desired)
@jax.numpy_dtype_promotion('standard') # Test explicitly exercises implicit dtype promotion.
def test_heterogeneous_jacrev(self):
# See https://github.com/google/jax/issues/7157
# See https://github.com/google/jax/issues/7780
x = np.array([2.0], dtype=np.float16)
y = np.array([3.0], dtype=np.float32)
a = (x, y)
def f(tup):
jtu._check_dtypes_match(tup, a)
x, y = tup
return x, y, x + y
actual = jacrev(f)(a)
desired = ((np.array(1., dtype=np.float16), np.array(0., dtype=np.float32)),
(np.array(0., dtype=np.float16), np.array(1., dtype=np.float32)),
(np.array(1., dtype=np.float16), np.array(1., dtype=np.float32)))
jtu._check_dtypes_match(actual, desired)
jtu.check_eq(actual, desired)
def test_heterogeneous_grad(self):
# See https://github.com/google/jax/issues/7157
x = np.array(1.0+1j)
y = np.array(2.0)
a = (x, y)
def f(tup):
jtu._check_dtypes_match(tup, a)
x, y = tup
return jnp.square(jnp.abs(x)) + y
actual = grad(f)(a)
desired = (np.array(2 - 2j), np.array(1.))
jtu._check_dtypes_match(actual, desired)
jtu.check_eq(actual, desired)
def test_complex_input_jacfwd_raises_error(self):
self.assertRaises(TypeError, lambda: jacfwd(lambda x: jnp.sin(x))(1 + 2j))
def test_legacy_devicearray_repr(self):
dx = device_put(3.)
str(dx.item()) # doesn't crash
def test_devicearray_repr(self):
x = device_put(jnp.zeros(3))
_check_instance(self, x)
repr(x) # doesn't crash
x = device_put(jnp.full(3, 1 + 1j))
_check_instance(self, x)
repr(x) # doesn't crash
def test_devicearray_delete(self):
x = device_put(1.)
x.delete()
if config.jax_array:
msg = "Array has been deleted."
else:
msg = "DeviceArray has been deleted."
self.assertRaisesRegex(RuntimeError, msg, lambda: repr(x))
def test_devicearray_block_until_ready(self):
x = device_put(1.)
y = x.block_until_ready()
# Tests mostly that block_until_ready() does not produce an error.
self.assertTrue(y is x)
def test_block_until_ready_function(self):
# Just tests that we don't error...
pytree = (device_put(1.), np.ones(3))
pytree = jax.block_until_ready(pytree)
self.assertAllClose(pytree[0], jnp.array(1.), check_dtypes=False)
self.assertAllClose(pytree[1], np.ones(3), check_dtypes=False)
def test_devicearray_weakref_friendly(self):
x = device_put(1.)
y = weakref.ref(x)
self.assertEqual(y(), 1.)
del x
self.assertIsNone(y())
def test_namedtuple_transparency(self):
# See https://github.com/google/jax/issues/446
Point = collections.namedtuple("Point", ["x", "y"])
def f(pt):
return jnp.sqrt(pt.x ** 2 + pt.y ** 2)
pt = Point(1., 2.)
f(pt) # doesn't crash
g = api.grad(f)(pt)
self.assertIsInstance(g, Point)
f_jit = api.jit(f)
self.assertAllClose(f(pt), f_jit(pt), check_dtypes=False)
def test_namedtuple_subclass_transparency(self):
# See https://github.com/google/jax/issues/806
Point = collections.namedtuple("Point", ["x", "y"])
class ZeroPoint(Point):
def is_zero(self):
return (self.x == 0) and (self.y == 0)
pt = ZeroPoint(0., 0.)
def f(pt):
return 0. if pt.is_zero() else jnp.sqrt(pt.x ** 2 + pt.y ** 2)
f(pt) # doesn't crash
_ = api.grad(f)(pt)
self.assertIsInstance(pt, ZeroPoint)
@parameterized.parameters(1, 2, 3)
def test_shape_dtype_struct(self, i):
s = api.ShapeDtypeStruct(shape=(i, 2, 3), dtype=jnp.float32)
self.assertEqual(s.shape, (i, 2, 3))
self.assertEqual(s.dtype, jnp.float32)
self.assertEqual(s.ndim, 3)
self.assertEqual(s.size, i * 2 * 3)
self.assertLen(s, i)
for f in (str, repr):
self.assertEqual(
f(s), f"ShapeDtypeStruct(shape=({i}, 2, 3), dtype=float32)")
def test_shape_dtype_struct_scalar(self):
s = api.ShapeDtypeStruct(shape=(), dtype=jnp.float32)
self.assertEmpty(s.shape)
self.assertEqual(s.size, 1)
self.assertEqual(s.ndim, 0)
with self.assertRaisesRegex(TypeError, "len[(][)] of unsized object"):
_ = len(s)
def test_shape_dtype_struct_hash(self):
s1 = api.ShapeDtypeStruct(shape=(2, 3), dtype=jnp.float32)
s2 = api.ShapeDtypeStruct(shape=(2, 3), dtype=jnp.float32)
s3 = api.ShapeDtypeStruct(shape=(2, 4), dtype=jnp.float32)
self.assertEqual(hash(s1), hash(s2))
self.assertNotEqual(hash(s1), hash(s3))
def test_eval_shape(self):
def fun(x, y):
return jnp.tanh(jnp.dot(x, y) + 3.)
x = jnp.ones((2, 3))
y = jnp.ones((3, 4))
out_shape = api.eval_shape(fun, x, y)
self.assertEqual(out_shape.shape, (2, 4))
def test_eval_shape_constants(self):
def fun():
x = jnp.ones((2, 3))
y = jnp.ones((3, 4))
return jnp.tanh(jnp.dot(x, y) + 3.)
out_shape = api.eval_shape(fun)
self.assertEqual(out_shape.shape, (2, 4))
def test_eval_shape_tuple_unpacking(self):
def fun(x, y):
a, b = x
return a + b + y
x = (jnp.ones(2), jnp.ones(2))
y = 3.
out_shape = api.eval_shape(fun, x, y)
self.assertEqual(out_shape.shape, (2,))
def test_eval_shape_tuple_itemgetting(self):
def fun(x, y):
return x[0] + x[1] + y
x = (jnp.ones(2), jnp.ones(2))
y = 3.
out_shape = api.eval_shape(fun, x, y)
self.assertEqual(out_shape.shape, (2,))
def test_eval_shape_output_dict(self):
def fun(x, y):
return {'hi': x[0] + x[1] + y}
x = (jnp.ones(2), jnp.ones(2))
y = 3.
out_shape = api.eval_shape(fun, x, y)
out_shape = tree_util.tree_map(np.shape, out_shape)
self.assertEqual(out_shape, {'hi': (2,)})
def test_eval_shape_shape_error(self):
def fun(x, y):
return jnp.tanh(jnp.dot(x, y) + 3.)
x = jnp.ones((3, 3))
y = jnp.ones((4, 4))
self.assertRaises(TypeError, lambda: api.eval_shape(fun, x, y))
def test_eval_shape_duck_typing(self):
def fun(A, b, x):
return jnp.dot(A, x) + b
class MyArgArray:
def __init__(self, shape, dtype):
self.shape = shape
self.dtype = np.dtype(dtype)
A = MyArgArray((3, 4), jnp.float32)
b = MyArgArray((1, 5), jnp.float32)
x = MyArgArray((4, 5), jnp.float32)
out_shape = api.eval_shape(fun, A, b, x)
self.assertEqual(out_shape.shape, (3, 5))
def test_eval_shape_duck_typing2(self):
# https://github.com/google/jax/issues/5683
class EasyDict(dict):
def __init__(self, *args, **kwargs):
super().__init__(*args, **kwargs)
self.__dict__ = self
x = EasyDict(shape=(3,), dtype=np.dtype('float32'))
out_shape = api.eval_shape(lambda x: x, x) # doesn't crash
self.assertEqual(out_shape.shape, (3,))
def test_eval_shape_names(self):
def fun(x, y):
return lax.psum(x, 'i') + y
class MyArgArray:
def __init__(self, shape, dtype, named_shape):
self.shape = shape
self.dtype = jnp.dtype(dtype)
self.named_shape = named_shape
x = MyArgArray((3, 2), jnp.float32, {'i': 10})
y = MyArgArray((3, 2), jnp.float32, {'j': 5})
with core.extend_axis_env('i', 10, None):
with core.extend_axis_env('j', 5, None):
out_shape = api.eval_shape(fun, x, y)
self.assertEqual(out_shape.named_shape, {'j': 5})
def test_issue_871(self):
T = jnp.array([[1., 2.], [3., 4.], [5., 6.]])
x = jnp.array([1, 2, 3])
msg = ("linearized function called on tangent values inconsistent with "
"the original primal values")
y, f_jvp = api.linearize(jnp.sum, x)
with self.assertRaisesRegex(ValueError, msg):
f_jvp(T)
y, f_jvp = api.linearize(api.jit(jnp.sum), x)
with self.assertRaisesRegex(ValueError, msg):
f_jvp(T)
def test_grad_of_int_errors(self):
# Errors without allow_int=True
dfn = grad(lambda x: x ** 2)
self.assertRaisesRegex(
TypeError,
(r"grad requires real- or complex-valued inputs \(input dtype that is a "
r"sub-dtype of np.inexact\), but got int.*."),
lambda: dfn(3))
@unittest.skipIf(numpy_version == (1, 21, 0),
"https://github.com/numpy/numpy/issues/19305")
def test_jvp_of_int_identity(self):
primals = (1,)
tangents = (np.zeros(shape=(), dtype=float0),)
_, out = api.jvp(lambda x: x, primals, tangents)
self.assertEqual(out, np.zeros(shape=(), dtype=float0))
@unittest.skipIf(numpy_version == (1, 21, 0),
"https://github.com/numpy/numpy/issues/19305")
def test_jvp_of_int_add(self):
primals = (2,)
tangents = (np.zeros(shape=(), dtype=float0),)
_, out_tangent = api.jvp(lambda x: x+1, primals, tangents)
self.assertEqual(out_tangent, np.zeros(shape=(), dtype=float0))
@unittest.skipIf(numpy_version == (1, 21, 0),
"https://github.com/numpy/numpy/issues/19305")
def test_jit_jvp_of_int(self):
primals = (2,)
tangents = (np.zeros(shape=(), dtype=float0),)
_, out_tangent = api.jvp(jax.jit(lambda x: x+1), primals, tangents)
self.assertEqual(out_tangent, np.zeros(shape=(), dtype=float0))
@unittest.skipIf(numpy_version == (1, 21, 0),
"https://github.com/numpy/numpy/issues/19305")
def test_vjp_of_int_index(self):
primal, fn_vjp = api.vjp(lambda x, i: x[i], np.ones(2)*2, 1)
tangent_x, tangent_i = fn_vjp(1.)
self.assertEqual(primal, 2.)
self.assertAllClose(tangent_x, jnp.array([0., 1.]))
self.assertEqual(tangent_i, np.zeros(shape=(), dtype=float0))
@unittest.skipIf(numpy_version == (1, 21, 0),
"https://github.com/numpy/numpy/issues/19305")
def test_vjp_of_int_shapes(self):
out, fn_vjp = api.vjp(lambda x: lax.reshape(x, (2, 2)), np.ones((4, 1),
dtype=int))
tangent, = fn_vjp(out)
self.assertArraysEqual(tangent, np.zeros(shape=(4, 1), dtype=float0))
@unittest.skipIf(numpy_version == (1, 21, 0),
"https://github.com/numpy/numpy/issues/19305")
def test_jit_vjp_of_int(self):
primal, fn_vjp = api.vjp(lambda x, y: x+y, 2, 1)
tangent_x, tangent_i = jax.jit(fn_vjp)(1)
self.assertEqual(primal, 3)
self.assertEqual(tangent_x, np.zeros(shape=(), dtype=float0))
self.assertEqual(tangent_i, np.zeros(shape=(), dtype=float0))
@unittest.skipIf(numpy_version == (1, 21, 0),
"https://github.com/numpy/numpy/issues/19305")
def test_vjp_of_int_fulllike(self):
# Regression test for tangent and cotangent mismatch in convert_element_type
# transpose rule wrt a ConstVar
f = lax.full_like
out, vjp = api.vjp(f, np.zeros((2, 2)), 1)
self.assertAllClose(out, jnp.ones((2, 2)))
tangent_x, tangent_y = vjp(out)
self.assertAllClose(tangent_x, jnp.zeros((2, 2)))
self.assertEqual(tangent_y, np.zeros(shape=(), dtype=float0))
@unittest.skipIf(numpy_version == (1, 21, 0),
"https://github.com/numpy/numpy/issues/19305")
def test_grad_of_int(self):
# Need real-valued output, but testing integer input.
out = api.grad(lambda x: x+0., allow_int=True)(1)
self.assertEqual(out, np.zeros(shape=(), dtype=float0))
@unittest.skipIf(numpy_version == (1, 21, 0),
"https://github.com/numpy/numpy/issues/19305")
def test_grad_of_bool(self):
def cond(pred):
return lax.cond(pred, lambda _: 1., lambda _: 2., 1.)
value, grd = api.value_and_grad(cond, allow_int=True)(True)
self.assertEqual(value, 1.)
self.assertEqual(grd, np.zeros(shape=(), dtype=float0))
@unittest.skipIf(numpy_version == (1, 21, 0),
"https://github.com/numpy/numpy/issues/19305")
def test_grad_of_int_index(self):
grad_x, grad_i = api.grad(lambda x, i: x[i], argnums=(0, 1),
allow_int=True)(np.ones(2), 1)
self.assertAllClose(grad_x, jnp.array([0., 1.]))
self.assertEqual(grad_i, np.zeros(shape=(), dtype=float0))
@unittest.skipIf(numpy_version == (1, 21, 0),
"https://github.com/numpy/numpy/issues/19305")
def test_jit_grad_of_int(self):
grad_f = api.grad(lambda x, i: x[i], argnums=(0, 1), allow_int=True)
grad_x, grad_i = jax.jit(grad_f)(np.ones(2), 1)
self.assertAllClose(grad_x, jnp.array([0., 1.]))
self.assertEqual(grad_i, np.zeros(shape=(), dtype=float0))
@unittest.skipIf(numpy_version == (1, 21, 0),
"https://github.com/numpy/numpy/issues/19305")
def test_float0_reshape(self):
# dtype-agnostic operations are supported
float0_array = jax.grad(lambda x: jnp.sum(x+0.),
allow_int=True)(np.ones((2, 4), dtype=int))
self.assertArraysEqual(float0_array.reshape((4, 2)),
np.zeros((4, 2), dtype=float0))
self.assertArraysEqual(float0_array.transpose(),
np.zeros((4, 2), dtype=float0))
def test_float0_error(self):
# float0 is incompatible with other dtypes
float0_array = jax.grad(lambda x: x+0., allow_int=True)(1)
error_text = "float0s do not support any operations by design"
with self.assertRaisesRegex(TypeError, error_text):
# dispatch via DeviceArray
_ = float0_array + jnp.zeros(())
with self.assertRaisesRegex(TypeError, error_text):
# dispatch via lax
_ = lax.add(float0_array, jnp.zeros(()))
def test_grad_complex_result_errors(self):
dfn = grad(lambda x: x ** 2 + 1j)
self.assertRaisesRegex(
TypeError,
(r"grad requires real-valued outputs \(output dtype that is a "
r"sub-dtype of np.floating\), but got complex.*"),
lambda: dfn(3.))
def test_holomorphic_grad_of_float_errors(self):
dfn = grad(lambda x: x ** 2, holomorphic=True)
self.assertRaisesRegex(
TypeError,
(r"grad with holomorphic=True requires inputs with complex dtype, "
r"but got float.*"),
lambda: dfn(3.))
def test_holomorphic_jacrev_of_float_errors(self):
dfn = jacrev(lambda x: x ** 2, holomorphic=True)
self.assertRaisesRegex(
TypeError,
(r"jacrev with holomorphic=True requires inputs with complex dtype, "
r"but got float.*"),
lambda: dfn(3.))
def test_holomorphic_jacfwd_of_float_errors(self):
dfn = jacfwd(lambda x: x ** 2, holomorphic=True)
self.assertRaisesRegex(
TypeError,
(r"jacfwd with holomorphic=True requires inputs with complex dtype, "
r"but got float.*"),
lambda: dfn(3.))
def test_jacfwd_of_complex_errors(self):
dfn = jacfwd(lambda x: x ** 2)
self.assertRaisesRegex(
TypeError,
(r"jacfwd requires real-valued inputs \(input dtype that is a "
r"sub-dtype of np.floating\), but got complex.*"),
lambda: dfn(3. + 1j))
def test_xla_computation(self):
# these tests basically check the examples in the xla_computation docstring
def e(x):
return jnp.sin(jnp.cos(x))
c = api.xla_computation(e)(2.)
self.assertIn('cosine', c.as_hlo_text())
self.assertIn('sine', c.as_hlo_text())
def f(x):
return x - lax.psum(x, 'i')
axis_env = [('i', 4)]
c = api.xla_computation(f, axis_env=axis_env)(2)
self.assertIn('all-reduce', c.as_hlo_text())
self.assertIn('replica_groups={{0,1,2,3}}', c.as_hlo_text())
def g(x):
rowsum = lax.psum(x, 'i')
colsum = lax.psum(x, 'j')
allsum = lax.psum(x, ('i', 'j'))
return rowsum, colsum, allsum
axis_env = [('i', 4), ('j', 2)]
c = api.xla_computation(g, axis_env=axis_env)(5.)
self.assertIn('all-reduce', c.as_hlo_text())
self.assertIn('replica_groups={{0,2,4,6},{1,3,5,7}}', c.as_hlo_text())
self.assertIn('replica_groups={{0,1},{2,3},{4,5},{6,7}}', c.as_hlo_text())
self.assertIn('replica_groups={{0,1,2,3,4,5,6,7}}', c.as_hlo_text())
def h(x):
rowsum = lax.psum(x, 'i', axis_index_groups=[[0, 1], [2, 3]])
colsum = lax.psum(x, 'j')
return rowsum, colsum
axis_env = [('i', 4), ('j', 2)]
c = api.xla_computation(h, axis_env=axis_env)(5.)
self.assertIn('all-reduce', c.as_hlo_text())
self.assertIn('replica_groups={{0,2},{4,6},{1,3},{5,7}}', c.as_hlo_text())
self.assertIn('replica_groups={{0,1},{2,3},{4,5},{6,7}}', c.as_hlo_text())
def test_xla_computation_args(self):
def foo(x, y, z):
return x + y + z
c = api.xla_computation(foo)(1., 2., 3.)
self.assertEqual(len(c.program_shape().parameter_shapes()), 3)
c = api.xla_computation(foo, tuple_args=True)(1., 2., 3.)
param_shapes = c.program_shape().parameter_shapes()
self.assertEqual(len(param_shapes), 1)
self.assertEqual(param_shapes[0].xla_element_type(),
xla_client.PrimitiveType.TUPLE)
def test_xla_computation_duck_typing(self):
def foo(x, y, z):
return x + y + z
x = jax.ShapeDtypeStruct((), np.float32)
y = jax.ShapeDtypeStruct((), np.float32)
z = jax.ShapeDtypeStruct((), np.float32)
c = api.xla_computation(foo)(x, y, z)
self.assertEqual(len(c.program_shape().parameter_shapes()), 3)
c = api.xla_computation(foo, tuple_args=True)(1., 2., 3.)
param_shapes = c.program_shape().parameter_shapes()
self.assertEqual(len(param_shapes), 1)
self.assertEqual(param_shapes[0].xla_element_type(),
xla_client.PrimitiveType.TUPLE)
def test_compiler_ir(self):
# TODO(phawkins): merge these tests with the `xla_computation` tests.
def e(x):
return jnp.sin(jnp.cos(x))
hlo = api.jit(e).lower(2.).compiler_ir(dialect="hlo").as_hlo_text()
self.assertIn(' cosine', hlo)
self.assertIn(' sine', hlo)
mhlo = str(api.jit(e).lower(2.).compiler_ir(dialect="mhlo"))
self.assertIn('mhlo.cosine', mhlo)
self.assertIn('mhlo.sine', mhlo)
if mlir_api_version >= 37:
stablehlo = str(api.jit(e).lower(2.).compiler_ir(dialect="stablehlo"))
self.assertIn("stablehlo.cosine", stablehlo)
self.assertIn("stablehlo.sine", stablehlo)
def test_staging_out_multi_replica(self):
def f(x):
return api.pmap(jnp.mean)(x)
xla_comp = api.xla_computation(f)
xla_comp(jnp.arange(8)).as_hlo_text() # doesn't crash
def test_xla_computation_instantiate_constant_outputs(self):
def f():
return jnp.zeros((3, 4))
xla_comp = api.xla_computation(f)()
out_shape, = xla_comp.program_shape().result_shape().tuple_shapes()
self.assertEqual(out_shape.dimensions(), (3, 4))
def test_xla_computation_static_argnums(self):
def f(x, y):
return x + y
xla_comp = api.xla_computation(f, static_argnums=(1,))(2, 3)
hlo_text = xla_comp.as_hlo_text()
self.assertIn("constant(3)", hlo_text)
# The static arguments should be removed from the function being compiled,
# thus the function should have only a single argument.
self.assertIn("parameter(0)", hlo_text)
self.assertNotIn("parameter(1)", hlo_text)
def test_xla_computation_return_shape(self):
_, shape_tree = api.xla_computation(lambda x: (x + 1, jnp.zeros(2, jnp.float32)),
return_shape=True)(np.int32(1))
expected = (api.ShapeDtypeStruct(shape=(), dtype=jnp.int32),
api.ShapeDtypeStruct(shape=(2,), dtype=jnp.float32))
self.assertEqual(shape_tree, expected)
def test_xla_computation_partitioned(self):
def f(x, y):
return jnp.dot(x, y) + 1
x = jax.ShapeDtypeStruct((8, 8), np.float32)
y = jax.ShapeDtypeStruct((8, 16), np.float32)
xla_comp = api.xla_computation(f, in_parts=(P(2, 2), None),
out_parts=P(4, 1))(x, y)
hlo_text = xla_comp.as_hlo_text()
self.assertIn('sharding={devices=[2,2]0,1,2,3}', hlo_text)
self.assertIn('sharding={replicated}', hlo_text)
self.assertIn('sharding={{devices=[4,1]0,1,2,3}}', hlo_text)
def test_xla_computation_replicated_and_partitioned(self):
def f(x, y):
return jnp.dot(x, y), lax.psum(x, 'i')
x = jax.ShapeDtypeStruct((8, 8), np.float32)
y = jax.ShapeDtypeStruct((8, 16), np.float32)
axis_env = [('i', 4)]
xla_comp = api.xla_computation(f, axis_env=axis_env,
in_parts=(P(2, 2), None),
out_parts=(P(4, 1), None))(x, y)
hlo_text = xla_comp.as_hlo_text()
self.assertIn('all-reduce', hlo_text)
self.assertIn('replica_groups={{0,1,2,3}}', hlo_text)
self.assertIn('sharding={devices=[2,2]0,1,2,3}', hlo_text)
self.assertIn('sharding={replicated}', hlo_text)
self.assertIn('sharding={{devices=[4,1]0,1,2,3}, {replicated}}', hlo_text)
def test_xla_computation_psum_constant(self):
f = lambda: jax.lax.psum(1, "i")
api.xla_computation(f, axis_env=[("i", 2)])() # doesn't crash
@jtu.ignore_warning(message="Some donated buffers were not usable")
def test_xla_computation_donate_argnums(self):
if jtu.device_under_test() == "cpu" and xla_extension_version < 102:
raise unittest.SkipTest("CPU buffer donation requires jaxlib > 0.3.22")
api.xla_computation(lambda x: None, donate_argnums=(0,))(3) # doesn't crash
def test_xla_computation_lower_fun_axis_env(self):
axis_name = 'i'
def fn(x):
y = lax.all_gather(
x, axis_name=axis_name)
return y * lax.axis_index(axis_name).astype(jnp.float32)
input_x = jnp.ones((5,6,4), dtype=jnp.float32)
axis_env = [(axis_name, api.local_device_count())]
_ = api.xla_computation(fn, axis_env=axis_env, backend='cpu')(input_x)
def test_xla_computation_axis_env(self):
def fn(x):
z = x * jax.lax.axis_index('i').astype(jnp.float32)
def inner_fn(carry, a):
return carry + a, ()
return jax.lax.scan(inner_fn, jnp.zeros_like(z[0]), z)
x = jnp.ones((5, 6, 4), dtype=jnp.float32)
_ = jax.xla_computation(fn, axis_env=(('i', 8),), backend='cpu')(x)
def test_concurrent_device_get_and_put(self):
def f(x):
for _ in range(100):
y = jax.device_put(x)
x = jax.device_get(y)
return x
xs = [self.rng().randn(i) for i in range(10)]
with concurrent.futures.ThreadPoolExecutor() as executor:
futures = [executor.submit(partial(f, x)) for x in xs]
ys = [f.result() for f in futures]
for x, y in zip(xs, ys):
self.assertAllClose(x, y)
def test_dtype_from_builtin_types(self):
for dtype in [bool, int, float, complex]:
with warnings.catch_warnings(record=True) as caught_warnings:
x = jnp.array(0, dtype=dtype)
self.assertEmpty(caught_warnings)
assert x.dtype == dtypes.canonicalize_dtype(dtype)
def test_dtype_warning(self):
# cf. issue #1230
if config.x64_enabled:
raise unittest.SkipTest("test only applies when x64 is disabled")
def check_warning(warn, nowarn):
with warnings.catch_warnings(record=True) as w:
warnings.simplefilter("always")
nowarn() # get rid of extra startup warning
prev_len = len(w)
nowarn()
assert len(w) == prev_len
warn()
assert len(w) > 0
msg = str(w[-1].message)
expected_prefix = "Explicitly requested dtype "
self.assertEqual(expected_prefix, msg[:len(expected_prefix)])
prev_len = len(w)
nowarn()
assert len(w) == prev_len
check_warning(lambda: jnp.array([1, 2, 3], dtype="float64"),
lambda: jnp.array([1, 2, 3], dtype="float32"))
check_warning(lambda: jnp.array([1, 2, 3], dtype="float64"),
lambda: jnp.array([1, 2, 3], dtype=float))
check_warning(lambda: jnp.ones(3, dtype=np.float64),
lambda: jnp.ones(3))
check_warning(lambda: jnp.ones(3, dtype=np.float64),
lambda: jnp.ones(3, dtype=float))
check_warning(lambda: jnp.ones_like(3, dtype=np.int64),
lambda: jnp.ones_like(3, dtype=np.int32))
check_warning(lambda: jnp.zeros(3, dtype="int64"),
lambda: jnp.zeros(3, dtype="int32"))
check_warning(lambda: jnp.zeros_like(3, dtype="float64"),
lambda: jnp.zeros_like(3, dtype="float32"))
check_warning(lambda: jnp.full((2, 3), 1, dtype="int64"),
lambda: jnp.full((2, 3), 1))
check_warning(lambda: jnp.ones(3).astype("float64"),
lambda: jnp.ones(3).astype("float32"))
check_warning(lambda: jnp.eye(3, dtype=np.float64),
lambda: jnp.eye(3))
check_warning(lambda: jnp.arange(3, dtype=np.float64),
lambda: jnp.arange(3, dtype=np.float32))
check_warning(lambda: jnp.linspace(0, 3, dtype=np.float64),
lambda: jnp.linspace(0, 3, dtype=np.float32))
check_warning(lambda: jnp.tri(2, dtype="float64"),
lambda: jnp.tri(2, dtype="float32"))
check_warning(lambda: jnp.arange(1).astype("float64"),
lambda: jnp.arange(1).astype(float))
check_warning(lambda: jnp.arange(1.0).astype("int64"),
lambda: jnp.arange(1.0).astype(int))
def test_error_for_invalid_dtype(self):
with self.assertRaisesRegex(TypeError, ".*not a valid JAX array type.*"):
lax.add(jnp.array(7), np.array("hello"))
def test_vmap_preserves_docstr(self):
def superfun(a):
"""Does things with stuff."""
pass
self.assertRegex(api.vmap(superfun).__doc__, "\n".join([
"Vectorized version of superfun.*",
"",
"Original documentation:",
"",
superfun.__doc__,
]))
def test_vmap_in_axes_list(self):
# https://github.com/google/jax/issues/2367
dictionary = {'a': 5., 'b': jnp.ones(2)}
x = jnp.zeros(3)
y = jnp.arange(3.)
def f(dct, x, y):
return dct['a'] + dct['b'] + x + y
out1 = api.vmap(f, (None, 0, 0))(dictionary, x, y)
out2 = api.vmap(f, [None, 0, 0])(dictionary, x, y)
self.assertAllClose(out1, out2)
def test_vmap_in_axes_tree_prefix_error(self):
# https://github.com/google/jax/issues/795
value_tree = jnp.ones(3)
self.assertRaisesRegex(
ValueError,
"vmap in_axes specification must be a tree prefix of the corresponding "
r"value, got specification \(0, 0\) for value tree "
+ re.escape(f"{tree_util.tree_structure((value_tree,))}."),
lambda: api.vmap(lambda x: x, in_axes=(0, 0))(value_tree)
)
def test_vmap_in_axes_leaf_types(self):
with self.assertRaisesRegex(
TypeError, r"vmap in_axes must be an int, None, or .*"):
api.vmap(lambda x: x, in_axes=(jnp.array([1., 2.]),))(jnp.array([1., 2.]))
def test_vmap_out_axes_leaf_types(self):
with self.assertRaisesRegex(
TypeError, r"vmap out_axes must be an int, None, or .*"):
api.vmap(lambda x: x, out_axes=(jnp.array([1., 2.]),))(jnp.array([1., 2.]))
def test_vmap_unbatched_object_passthrough_issue_183(self):
# https://github.com/google/jax/issues/183
fun = lambda f, x: f(x)
vfun = api.vmap(fun, (None, 0))
ans = vfun(lambda x: x + 1, jnp.arange(3))
self.assertAllClose(ans, np.arange(1, 4), check_dtypes=False)
def test_vmap_mismatched_keyword(self):
# https://github.com/google/jax/issues/10193
@jax.vmap
def f(x, y):
return x + y
with self.assertRaisesRegex(
ValueError,
"vmap got inconsistent sizes for array axes to be mapped:\n"
r" \* one axis had size 1: axis 0 of argument x of type int32\[1\];"
"\n"
r" \* one axis had size 2: axis 0 of argument y of type int32\[2\]"):
f(jnp.array([1], 'int32'), y=jnp.array([1, 2], 'int32'))
def test_vmap_mismatched_axis_sizes_error_message_issue_705(self):
# https://github.com/google/jax/issues/705
def h(a, b):
return jnp.sum(a) + jnp.sum(b)
X = self.rng().randn(10, 4).astype('float32')
U = self.rng().randn(10, 2).astype('float32')
with self.assertRaisesRegex(
ValueError,
"vmap got inconsistent sizes for array axes to be mapped:\n"
r" \* one axis had size 10: axis 0 of argument a of type float32\[10,4\];""\n"
r" \* one axis had size 2: axis 1 of argument b of type float32\[10,2\]"):
api.vmap(h, in_axes=(0, 1))(X, U)
with self.assertRaisesRegex(
ValueError,
"vmap got inconsistent sizes for array axes to be mapped:\n"
r" \* most axes \(2 of them\) had size 10, e.g. axis 0 of argument x "
r"of type float32\[10,4\];" "\n"
r" \* one axis had size 2: axis 1 of argument y of type float32\[10,2\]"):
api.vmap(lambda x, y, z: None, in_axes=(0, 1, 0))(X, U, X)
with self.assertRaisesRegex(
ValueError,
"vmap got inconsistent sizes for array axes to be mapped:\n"
r" \* most axes \(2 of them\) had size 2, e.g. axis 1 of argument b\[0\] "
r"of type float32\[10,2\];" "\n"
r" \* one axis had size 10: axis 0 of argument a of type float32\[10,4\]"):
api.vmap(h, in_axes=(0, 1))(X, [U, U])
error = (r"vmap was requested to map its argument along axis 0, which "
r"implies that its rank should be at least 1, but is only 0 "
r"\(its shape is \(\)\)")
with self.assertRaisesRegex(ValueError, error):
# The mapped inputs cannot be scalars
api.vmap(lambda x: x)(1.)
with self.assertRaisesRegex(
ValueError, "vmap must have at least one non-None value in in_axes"):
# If the output is mapped, there must be a non-None in_axes
api.vmap(lambda x: x, in_axes=None)(jnp.array([1., 2.]))
error = (r"vmap was requested to map its argument along axis 1, which "
r"implies that its rank should be at least 2, but is only 1 "
r"\(its shape is \(2,\)\)")
with self.assertRaisesRegex(ValueError, error):
api.vmap(lambda x: x, in_axes=1)(jnp.array([1., 2.]))
# Error is: TypeError: only integer scalar arrays can be converted to a scalar index
with self.assertRaisesRegex(
ValueError,
"vmap out_axes specification must be a tree prefix of the "
"corresponding value.*"):
api.vmap(lambda x: x, in_axes=0, out_axes=(2, 3))(jnp.array([1., 2.]))
with self.assertRaisesRegex(
ValueError,
r"vmap has mapped output \(axis_name=foo\) but out_axes is None"):
# If the output is mapped (user-named axis), then there must be some
# out_axes specified.
api.vmap(lambda x: x, out_axes=None, axis_name="foo")(jnp.array([1., 2.]))
with self.assertRaisesRegex(
ValueError,
"vmap has mapped output but out_axes is None"):
# If the output is mapped (unnamed axis), then there must be some out_axes
# specified.
api.vmap(lambda x: x, out_axes=None)(jnp.array([1., 2.]))
def test_vmap_structured_in_axes(self):
A, B, C, D = 2, 3, 4, 5
K = 6 # batch size
x = np.ones((K, A, B)) # batch axis in different locations
y = np.ones((B, K, C))
z = np.ones((C, D, K))
def foo(tree_arg):
x, (y, z) = tree_arg
return jnp.dot(x, jnp.dot(y, z))
tree = (x, (y, z))
vfoo = api.vmap(foo, in_axes=((0, (1, 2)),))
self.assertEqual(vfoo(tree).shape, (6, 2, 5))
Point = collections.namedtuple("Point", ["x", "y"])
tree = (x, Point(y, z))
vfoo = api.vmap(foo, in_axes=((0, Point(1, 2)),))
self.assertEqual(vfoo(tree).shape, (6, 2, 5))
def foo(tree_arg):
x, dct = tree_arg
y, z = dct['a'], dct['b']
return jnp.dot(x, jnp.dot(y, z))
tree = (x, {'a': y, 'b': z})
vfoo = api.vmap(foo, in_axes=((0, {'a': 1, 'b': 2}),))
self.assertEqual(vfoo(tree).shape, (6, 2, 5))
tree = (x, collections.OrderedDict([('a', y), ('b', z)]))
vfoo = api.vmap(
foo, in_axes=((0, collections.OrderedDict([('a', 1), ('b', 2)])),))
self.assertEqual(vfoo(tree).shape, (6, 2, 5))
def test_vmap_in_axes_bool_error(self):
# https://github.com/google/jax/issues/6372
with self.assertRaisesRegex(TypeError, "must be an int"):
api.vmap(lambda x: x, in_axes=False)(jnp.zeros(3))
def test_pmap_in_axes_bool_error(self):
# https://github.com/google/jax/issues/6372
with self.assertRaisesRegex(TypeError, "must be an int"):
api.pmap(lambda x: x, in_axes=False)(jnp.zeros(1))
def test_vmap_empty_arguments(self):
with self.assertRaisesRegex(
ValueError,
"vmap wrapped function must be passed at least one argument "
r"containing an array, got empty \*args=\(\{\},\) and \*\*kwargs=\{\}"):
api.vmap(lambda x: x)({})
def test_pmap_empty_arguments(self):
with self.assertRaisesRegex(
ValueError,
"pmap wrapped function must be passed at least one argument "
r"containing an array, got empty \*args=\(\{\},\) and \*\*kwargs=\{\}"):
api.pmap(lambda x: x)({})
def test_pmap_global_cache(self):
def f(x, y):
return x, y
x = np.ones((1, 1, 1))
# All defaults
with jtu.assert_num_jit_and_pmap_compilations(1):
for _ in range(2):
api.pmap(f)(x, x)
# With axis name
with jtu.assert_num_jit_and_pmap_compilations(1):
for _ in range(2):
api.pmap(f, 'i')(x, x)
# With in_axes and out_axes
for x_in, y_in, x_out, y_out in it.product(*((0, 1, 2) for _ in range(4))):
with jtu.assert_num_jit_and_pmap_compilations(1):
for _ in range(2):
api.pmap(f, 'i', in_axes=(x_in, y_in), out_axes=(x_out, y_out))(x, x)
# Forward-mode AD on the outside
with jtu.assert_num_jit_and_pmap_compilations(1):
for _ in range(2):
api.jvp(api.pmap(f), (x, x), (x, x))
# Reverse-mode AD on the outside. One compilation for forward, one for backward.
with jtu.assert_num_jit_and_pmap_compilations(2):
for _ in range(2):
api.vjp(api.pmap(f), x, x)[1]((x, x))
def test_device_array_repr(self):
rep = jnp.ones(()) + 1.
if config.jax_array:
msg = 'Array'
else:
msg = 'DeviceArray'
self.assertStartsWith(repr(rep), msg)
def test_device_array_hash(self):
rep = jnp.ones((1,)) + 1.
_check_instance(self, rep)
self.assertNotIsInstance(rep, collections.abc.Hashable)
with self.assertRaisesRegex(TypeError, 'unhashable type'):
hash(rep)
def test_grad_without_enough_args_error_message(self):
# https://github.com/google/jax/issues/1696
def f(x, y): return x + y
df = api.grad(f, argnums=0)
self.assertRaisesRegex(
TypeError,
"differentiating with respect to argnums=0 requires at least 1 "
"positional arguments to be passed by the caller, but got only 0 "
"positional arguments.",
lambda: partial(df, x=0.)(y=1.))
def test_jit_compilation_time_logging(self):
@api.jit
def f(x):
return x * 2
# make sure some initial warnings & cached operations already happen.
f(jnp.ones(2))
prev_level = logging.get_verbosity()
try:
logging.set_verbosity('DEBUG')
with self.assertLogs(level=logging.DEBUG) as l:
f(2.)
finally:
logging.set_verbosity(prev_level)
self.assertGreaterEqual(len(l.output), 3) # 3 lines
self.assertTrue(any('Finished tracing' in line for line in l.output))
self.assertTrue(any('Compiling f' in line for line in l.output))
self.assertTrue(any('Finished XLA compilation' in line for line in l.output))
def test_grad_of_jit_compilation_caching(self):
if not hasattr(self, "assertLogs"):
raise unittest.SkipTest("test requires assertLogs (python 3)")
# make sure some initial warnings & cached operations already happen.
api.grad(api.jit(lambda x: x))(1.0)
@api.jit
def f(x):
return jnp.sin(x)
prev_level = logging.get_verbosity()
try:
logging.set_verbosity('DEBUG')
with self.assertLogs(level=logging.DEBUG) as l:
ans1 = api.grad(f)(2.)
ans2 = api.grad(f)(3.)
finally:
logging.set_verbosity(prev_level)
self.assertGreaterEqual(len(l.output), 2 * 3) # one for fwd, one for bwd, 3 lines each
self.assertAllClose(ans1, np.cos(2.), check_dtypes=False)
self.assertAllClose(ans2, np.cos(3.), check_dtypes=False)
def test_grad_of_jit_compilation_caching2(self):
# Like the above test, but instead of logging use our compile counters.
# make sure some initial convert element type operations are pre-cached.
api.grad(api.jit(lambda x: x))(1.0)
@api.jit
def f(x):
return jnp.sin(x)
with jtu.count_jit_and_pmap_compiles() as count: # noqa: F841
_ = jax.grad(f)(3.)
self.assertEqual(count[0], 2) # one for fwd, one for bwd
with jtu.count_jit_and_pmap_compiles() as count: # noqa: F841
_ = jax.grad(f)(3.)
_ = jax.grad(f)(4.)
self.assertEqual(count[0], 0) # cache hits on both fwd and bwd
def test_grad_does_not_unflatten_tree_with_none(self):
# https://github.com/google/jax/issues/7546
class CustomNode(list):
pass
def unflatten(unused_aux_data, children):
self.assertIsNotNone(children[0])
return CustomNode(children)
tree_util.register_pytree_node(CustomNode, lambda x: (x, None), unflatten)
grad(lambda x: x[0])(CustomNode([0.]))
def test_trivial_computations(self):
x = jnp.array([1, 2, 3])
y = api.jit(lambda x: x)(x)
self.assertEqual(x.unsafe_buffer_pointer(), y.unsafe_buffer_pointer())
z1, z2 = api.jit(lambda x: (x, x))(x)
self.assertEqual(z1.unsafe_buffer_pointer(), z2.unsafe_buffer_pointer())
x1, x2 = jnp.array([1, 2]), jnp.array([2, 3])
z1, z2, z3 = api.jit(lambda x, y: (y, 1, x))(x1, x2)
self.assertEqual(z1.unsafe_buffer_pointer(), x2.unsafe_buffer_pointer())
self.assertEqual(z3.unsafe_buffer_pointer(), x1.unsafe_buffer_pointer())
self.assertEqual(z2, 1)
def test_nested_jit_hoisting(self):
@api.jit
def f(x, y):
z = 2 * x
return y + z, 3
@api.jit
def g(x):
return f(2, x)
mlir_jaxpr_subcomp = mlir.jaxpr_subcomp
jaxprs = []
def mlir_jaxpr_subcomp_and_collect(c, jaxpr, *args, **kwargs):
jaxprs.append(jaxpr)
return mlir_jaxpr_subcomp(c, jaxpr, *args, **kwargs)
try:
mlir.jaxpr_subcomp = mlir_jaxpr_subcomp_and_collect
ans = g(3)
finally:
mlir.jaxpr_subcomp = mlir_jaxpr_subcomp
self.assertEqual(ans, (7, 3))
self.assertLen(jaxprs, 2)
outer_jaxpr, inner_jaxpr = jaxprs
self.assertLen(outer_jaxpr.eqns, 1)
self.assertEqual(outer_jaxpr.eqns[0].primitive.name, 'xla_call')
subjaxpr_1 = outer_jaxpr.eqns[0].params["call_jaxpr"]
self.assertEqual(str(subjaxpr_1), str(inner_jaxpr))
self.assertLen(inner_jaxpr.eqns, 2)
self.assertEqual(inner_jaxpr.eqns[-2].primitive.name, 'mul')
self.assertEqual(inner_jaxpr.eqns[-1].primitive.name, 'add')
def test_primitive_compilation_cache(self):
with jtu.count_primitive_compiles() as count:
lax.add(1, 2)
lax.add(2, 3)
self.assertEqual(count[0], 1)
def test_arange_jit(self):
# see https://github.com/google/jax/issues/553
def fun(x):
r = jnp.arange(x.shape[0])[x]
return r
jit(fun)(jnp.array([0, 1, 2], dtype=jnp.int32)) # doesn't crash
def helper_save_tracer(self, x):
self._saved_tracer = x
return x
def test_escaped_tracers_different_top_level_traces(self):
api.jit(self.helper_save_tracer)(0.)
with self.assertRaisesRegex(
UnexpectedTracerError, "Encountered an unexpected tracer"):
api.jit(lambda x: self._saved_tracer)(0.)
def test_escaped_tracers_cant_lift_sublevels(self):
api.jit(self.helper_save_tracer)(0.)
with self.assertRaisesRegex(
UnexpectedTracerError,
re.compile(
"Encountered an unexpected tracer",
re.DOTALL)):
api.jit(lambda x: x)(self._saved_tracer)
def test_escaped_tracers_tracer_from_higher_level(self):
api.grad(self.helper_save_tracer)(0.)
with self.assertRaisesRegex(
UnexpectedTracerError,
re.compile(
"Encountered an unexpected tracer.*Tracer from a higher level",
re.DOTALL)):
api.grad(lambda x: x)(self._saved_tracer)
def test_escaped_tracers_incompatible_sublevel(self):
def func1(x):
api.jit(self.helper_save_tracer)(0.)
# Use the tracer
return x + self._saved_tracer
with self.assertRaisesRegex(
UnexpectedTracerError,
re.compile("Encountered an unexpected tracer",
re.DOTALL)):
api.jit(func1)(2.)
def test_escaped_tracers_cant_lift(self):
def func1(x):
api.grad(self.helper_save_tracer)(0.)
return x + self._saved_tracer
with self.assertRaisesRegex(
UnexpectedTracerError,
re.compile("Encountered an unexpected tracer.*Can't lift",
re.DOTALL)):
api.grad(func1)(2.)
def test_escaped_tracers_not_among_input_tracers(self):
def func1(x):
api.grad(self.helper_save_tracer)(x)
# Use the tracer
return x + self._saved_tracer
with self.assertRaisesRegex(
UnexpectedTracerError,
re.compile(
"Encountered an unexpected tracer.*Tracer not in input tracers",
re.DOTALL)):
api.jit(func1)(2.)
def test_escaped_tracer_omnistaging(self):
count = 1
@jit
def f():
nonlocal count
count = jnp.add(count, 1)
f() # leaked a tracer! but currently undetected
def f(x, c):
jnp.add(count, 1)
return None, None
@jit
def g():
lax.scan(f, None, None, length=2)
with self.assertRaisesRegex(UnexpectedTracerError,
"was created on line"):
g()
def test_escaped_tracer_omnistaging_top_trace(self):
count = 1
def f(_, __):
nonlocal count
count = jnp.add(count, 1)
return None, None
lax.scan(f, None, None, length=2) # leaked a tracer! (of level 1!)
with self.assertRaisesRegex(UnexpectedTracerError,
"was created on line"):
# The following call will try and raise the ones array to the count tracer
# level, which is no longer live.
jax.jit(jnp.add)(jnp.ones(()), count)
def test_escaped_tracer_transform_name(self):
with self.assertRaisesRegex(UnexpectedTracerError,
"for jit"):
jax.jit(self.helper_save_tracer)(1)
_ = self._saved_tracer+1
with self.assertRaisesRegex(UnexpectedTracerError,
"for pmap"):
jax.pmap(self.helper_save_tracer)(jnp.ones((1, 2)))
_ = self._saved_tracer+1
with self.assertRaisesRegex(UnexpectedTracerError,
"for eval_shape"):
jax.eval_shape(self.helper_save_tracer, 1)
_ = self._saved_tracer+1
def test_escaped_tracer_shape_dtype(self):
with self.assertRaisesRegex(core.UnexpectedTracerError, r"int32\[4,3\]"):
jax.jit(self.helper_save_tracer)(jnp.ones((4, 3), dtype=jnp.int32))
_ = self._saved_tracer+1
def test_pmap_static_kwarg_error_message(self):
# https://github.com/google/jax/issues/3007
def f(a, b):
return a + b
g = jax.pmap(f, static_broadcasted_argnums=(1,))
msg = (r"pmapped function has static_broadcasted_argnums=\(1,\) but was "
r"called with only 1 positional argument. All static broadcasted "
r"arguments must be passed positionally.")
with self.assertRaisesRegex(ValueError, msg):
g(jnp.ones((1, 1)), b=1)
def test_vmap_unmapped_last(self):
@partial(jax.vmap, out_axes=-1)
def f(x):
return np.zeros((2,))
f(np.zeros((5,)))
# TODO(jakevdp): re-enable this if possible.
@unittest.skipIf(True, "broken by convert_element_type change.")
def test_xla_constant_dedup(self):
y = np.array([7, 14], dtype=np.float32)
def f(x):
return x + y + y
x = np.array([1, 2], dtype=np.float32)
hlo_lines = jax.xla_computation(f)(x).as_hlo_text().split('\n')
hlo_lines = {s.strip() for s in hlo_lines}
self.assertIn('constant.1 = f32[2]{0} constant({7, 14})', hlo_lines)
self.assertNotIn('constant.2 = f32[2]{0} constant({7, 14})', hlo_lines)
def test_eval_context(self):
@jit
def f():
with core.eval_context():
assert jnp.add(1, 1) == 2
f() # doesn't crash
def test_concrete_error_because_arg_unary(self):
@jax.jit
def f(x):
if x > 0:
return x
else:
return 0
msg = r"on the value of the argument 'x'"
with self.assertRaisesRegex(core.ConcretizationTypeError, msg):
f(1)
def test_concrete_error_because_arg_binary(self):
@jax.jit
def f(x, y):
if x > y:
return x
else:
return y
msg = r"on the values of the arguments 'x' and 'y'"
with self.assertRaisesRegex(core.ConcretizationTypeError, msg):
f(1, 2)
def test_concrete_error_because_arg_ternary(self):
@jax.jit
def f(x, y, z):
if x > z:
return x
else:
return y
msg = r"on the values of the arguments 'x' and 'z'"
with self.assertRaisesRegex(core.ConcretizationTypeError, msg):
f(1, 2, 3)
with self.assertRaisesRegex(core.ConcretizationTypeError, msg):
f(1, 2, z=3)
with self.assertRaisesRegex(core.ConcretizationTypeError, msg):
f(1, y=2, z=3)
def test_concrete_error_because_arg_varargs(self):
@jax.jit
def f(*args):
x, y, z = args
if x > z:
return x
else:
return y
msg = r"on the values of the argument 'args'"
with self.assertRaisesRegex(core.ConcretizationTypeError, msg):
f(1, 2, 3)
def test_concrete_error_because_arg_kwargs(self):
@jax.jit
def f(**kwargs):
x, y, z = kwargs['x'], kwargs['y'], kwargs['z']
if x > z:
return x
else:
return y
msg = r"on the values of the argument 'kwargs'"
with self.assertRaisesRegex(core.ConcretizationTypeError, msg):
f(x=1, y=2, z=3)
def test_concrete_error_because_arg_pytree(self):
@jax.jit
def f(xy, z):
x, y = xy
if x > 0:
return x
else:
return y
msg = r"on the value of the argument 'xy'"
with self.assertRaisesRegex(core.ConcretizationTypeError, msg):
f((1, 2), z=3)
def test_concrete_error_because_const(self):
@jax.jit
def f():
assert jnp.add(1, 1) > 0
msg = "on these lines"
with self.assertRaisesRegex(core.ConcretizationTypeError, msg):
f()
def test_concrete_error_because_const_2(self):
@jax.jit
def f():
result = sum(jnp.add(1, 1) for _ in range(6))
assert result > 0
msg = "Additional originating lines are not shown."
with self.assertRaisesRegex(core.ConcretizationTypeError, msg):
f()
def test_concrete_error_with_nested_call(self):
@jax.jit
def f(x, y):
if y:
return x
@jax.jit
def g(x):
return f(x, True)
msg = r"on the value of the argument 'y'"
with self.assertRaisesRegex(core.ConcretizationTypeError, msg):
g(1)
def test_xla_computation_zeros_doesnt_device_put(self):
with jtu.count_device_put() as count:
api.xla_computation(lambda: jnp.zeros(3))()
self.assertEqual(count[0], 0)
def test_join_concrete_arrays_with_omnistaging(self):
# https://github.com/google/jax/issues/4622
x = jnp.array([1., 2., 3.])
y = jnp.array([1., 2., 4.])
@jit
def f():
core.lattice_join(core.ConcreteArray(x.dtype, x),
core.ConcreteArray(y.dtype, y))
f() # doesn't crash
def test_linearize_aval_error(self):
# https://github.com/google/jax/issues/4622
f = lambda x: x
# these should not error
_, f_jvp = api.linearize(f, 1.)
f_jvp(1.)
_, f_jvp = api.linearize(f, np.ones(2, np.int32))
f_jvp(np.zeros(2, float0))
# these should error
_, f_jvp = api.linearize(f, 1.)
with self.assertRaisesRegex(ValueError, "tangent values inconsistent"):
f_jvp(1)
_, f_jvp = api.linearize(f, np.ones(2, np.int32))
with self.assertRaisesRegex(ValueError, "tangent values inconsistent"):
f_jvp(np.ones(2, np.int32))
def test_grad_of_token_consuming_primitive(self):
# https://github.com/google/jax/issues/5463
tokentest_p = core.Primitive("tokentest")
tokentest_p.def_impl(partial(xla.apply_primitive, tokentest_p))
tokentest_p.def_abstract_eval(lambda x, y: x)
mlir.register_lowering(tokentest_p, lambda ctx, x, y: [x])
ad.defjvp(tokentest_p, (lambda g, x, token: x), None)
token = jax.lax.create_token(123)
arr = jnp.ones((3, 2))
res, vjp_fun = jax.vjp(lambda x: tokentest_p.bind(x, token), arr)
# Should not crash.
vjp_fun(arr)
def test_jit_returning_token(self):
x = jax.jit(jax.lax.create_token)(1.0)
self.assertIsInstance(x, jax.core.Token)
def test_jit_capturing_token(self):
tok = jax.core.token
_, y = jax.jit(lambda x: (x + 2, tok))(7)
self.assertIsInstance(y, jax.core.Token)
def test_leak_checker_catches_a_jit_leak(self):
with jax.checking_leaks():
lst = []
@jit
def f(x):
lst.append(x)
return x
with self.assertRaisesRegex(Exception, r"Leaked"):
f(3)
def test_leak_checker_catches_a_pmap_leak(self):
with jax.checking_leaks():
lst = []
@api.pmap
def f(x):
lst.append(x)
return x
with self.assertRaisesRegex(Exception, r"Leaked"):
f(np.ones(1))
def test_leak_checker_catches_a_grad_leak(self):
with jax.checking_leaks():
lst = []
def f(x):
lst.append(x)
return x
with self.assertRaisesRegex(Exception, r"Leaked trace"):
api.grad(f)(3.)
def test_leak_checker_avoids_false_positives(self):
with jax.checking_leaks():
api.vmap(lambda x: x)(np.arange(3.)) # doesn't crash
@jit
def f(x):
return x
f(3) # doesn't crash
api.vmap(f)(np.arange(3)) # doesn't crash
api.grad(f)(3.) # doesn't crash
@api.pmap
def f(x):
return x
f(np.ones(1)) # doesn't crash
api.vmap(f)(np.ones((1, 1))) # doesn't crash
def test_leak_checker_catches_a_scan_leak(self):
with jax.checking_leaks():
lst = []
to_scan = lambda c, x: (lst.append(c) or jnp.sin(c), None)
with self.assertRaisesRegex(Exception, r"Leaked trace"):
lax.scan(to_scan, 1., np.arange(3.))
def test_leak_checker_avoids_false_positives_scan(self):
with jax.checking_leaks():
to_scan = lambda c, x: (jnp.sin(c), None)
lax.scan(to_scan, 1., np.arange(3.)) # doesn't crash
def test_leak_checker_avoids_false_positives_scan_jvp(self):
with jax.checking_leaks():
to_scan = lambda c, x: (c, None)
def f(x):
lax.scan(to_scan, x, None, length=1)
api.jvp(f, (3.,), (1.,)) # doesn't crash
def test_leak_checker_avoids_false_positives_scan_vmap(self):
with jax.checking_leaks():
to_scan = lambda c, _: (1., None)
@api.vmap
def f(x):
lax.scan(to_scan, x, None, length=1)
f(np.arange(5.)) # doesn't crash
def test_leak_checker_avoids_false_positives_scan_vmap_2(self):
with jax.checking_leaks():
to_scan = lambda c, _: (c, None)
@api.vmap
def f(x):
lax.scan(to_scan, x, None, length=1)
f(np.arange(5.)) # doesn't crash
def test_leak_checker_catches_a_sublevel_leak(self):
with jax.checking_leaks():
@jit
def f(x):
lst = []
@jit
def g(x):
lst.append(x)
return x
x = g(x)
return x
with self.assertRaisesRegex(Exception, r"Leaked sublevel"):
f(3)
def test_leak_checker_avoids_false_positive_custom_jvp(self):
# see https://github.com/google/jax/issues/5636
with jax.checking_leaks():
@api.custom_jvp
def t(y):
return y
def t_jvp(p, t):
pass
t.defjvp(t_jvp)
@jit
def s(y):
return t(y)
s(3) # doesn't crash
def test_leak_checker_internal_error(self):
def apply_fn(inp):
fn = jax.checkpoint(lambda x: jax.nn.relu(1.0 * x))
return jax.vjp(fn, inp)
with jax.check_tracer_leaks():
jax.jit(apply_fn)(1.0) # don't crash
def test_leak_checker_reference_chain(self):
class A:
def __init__(self, dct):
self.dct = dct
a = A({})
x = jnp.arange(3)
def sketch(x):
def foo():
return x
a.dct['hi'] = [foo]
return x
# TODO(mattjj): full test msg below fails (harmlessly) on CI, investigate
msg = (
r"This BatchTracer with object id [0-9]+ was created on line:\n"
r" .*\n"
r"<BatchTracer [0-9]+> is referred to by"
)
# msg = (
# r"This BatchTracer with object id [0-9]+ was created on line:\n"
# r" .*\n"
# r"<BatchTracer [0-9]+> is referred to by <function [0-9]+> \(foo\) "
# r"closed-over variable x\n"
# r"<function [0-9]+> is referred to by <list [0-9]+>\[0\]\n"
# r"<list [0-9]+> is referred to by <dict [0-9]+>\['hi'\]\n"
# r"<dict [0-9]+> is referred to by <A [0-9]+>\.dct\n"
# )
with jax.check_tracer_leaks():
with self.assertRaisesRegex(Exception, msg):
jax.vmap(sketch)(x)
def test_default_backend(self):
first_local_device = api.local_devices()[0]
self.assertEqual(first_local_device.platform, api.default_backend())
@jtu.skip_on_devices("cpu")
def test_default_device(self):
system_default_device = jnp.zeros(2).device()
test_device = jax.devices("cpu")[-1]
# Sanity check creating array using system default device
self.assertEqual(jnp.ones(1).device(), system_default_device)
# Create array with default_device set
with jax.default_device(test_device):
# Hits cached primitive path
self.assertEqual(jnp.ones(1).device(), test_device)
# Uncached
self.assertEqual(jnp.zeros((1, 2)).device(), test_device)
# Test that we can reset to system default device
self.assertEqual(jnp.ones(1).device(), system_default_device)
def test_dunder_jax_array(self):
# https://github.com/google/jax/pull/4725
class AlexArray:
def __init__(self, jax_val):
self.jax_val = jax_val
def __jax_array__(self):
return self.jax_val
dtype = property(lambda self: self.jax_val.dtype)
shape = property(lambda self: self.jax_val.shape)
x = AlexArray(jnp.array([1., 2., 3.]))
y = jnp.sin(x)
self.assertAllClose(y, jnp.sin(jnp.array([1., 2., 3.])))
y = api.grad(api.jit(lambda x: jnp.sin(x).sum()))(x)
self.assertAllClose(y, jnp.cos(jnp.array([1., 2., 3.])))
x = AlexArray(jnp.array([[1., 2., 3.]]))
y = api.pmap(jnp.sin)(x)
self.assertAllClose(y, jnp.sin(jnp.array([[1., 2., 3.]])))
x = jnp.array(1)
a = AlexArray(x)
for f in [jnp.isscalar, jnp.size, jnp.shape, jnp.dtype]:
self.assertEqual(f(x), f(a))
x = AlexArray(jnp.array(1))
a1 = jnp.array(x)
self.assertAllClose(1, a1)
a2 = jnp.array(((x, x), [x, x]))
self.assertAllClose(np.array(((1, 1), (1, 1))), a2)
def test_constant_handler_mro(self):
# https://github.com/google/jax/issues/6129
class Foo(enum.IntEnum):
bar = 1
@api.pmap
def f(_):
return Foo.bar
ans = f(jnp.arange(1)) # doesn't crash
expected = jnp.arange(1) + 1
self.assertAllClose(ans, expected)
@parameterized.named_parameters([
{"testcase_name": f"{dtype.__name__}", "dtype": dtype}
for dtype in jtu.dtypes.all])
def test_constant_handlers(self, dtype):
# https://github.com/google/jax/issues/9380
@jax.jit
def f():
return jnp.exp(dtype(0))
f() # doesn't error
def test_large_python_ints(self):
with self.assertRaises(OverflowError):
jnp.multiply(2 ** 100, 3.)
out = lax.convert_element_type(2 ** 100, jnp.float32) # doesn't crash
self.assertArraysEqual(out, np.float32(2 ** 100))
def test_dot_precision_context_manager(self):
x = jnp.zeros((2, 2))
with jax.default_matmul_precision(None):
jnp.dot(x, x) # doesn't crash
jaxpr = jax.make_jaxpr(jnp.dot)(x, x)
self.assertIn('precision=None', str(jaxpr))
with jax.default_matmul_precision("bfloat16"):
x @ x # doesn't crash
jaxpr = jax.make_jaxpr(op.matmul)(x, x)
self.assertIn('Precision.DEFAULT', str(jaxpr))
with jax.default_matmul_precision("tensorfloat32"):
jnp.dot(x, x) # doesn't crash
jaxpr = jax.make_jaxpr(jnp.dot)(x, x)
self.assertIn('Precision.HIGH', str(jaxpr))
with jax.default_matmul_precision("float32"):
jnp.dot(x, x) # doesn't crash
jaxpr = jax.make_jaxpr(jnp.dot)(x, x)
self.assertIn('Precision.HIGHEST', str(jaxpr))
dot = partial(jnp.dot, precision=lax.Precision.HIGHEST)
with jax.default_matmul_precision("tensorfloat32"):
dot(x, x) # doesn't crash
jaxpr = jax.make_jaxpr(dot)(x, x)
self.assertIn('Precision.HIGHEST', str(jaxpr))
def test_dot_precision_flag(self):
x = jnp.zeros((2, 2))
prev_val = config._read("jax_default_matmul_precision")
try:
config.FLAGS.jax_default_matmul_precision = "tensorfloat32"
jnp.dot(x, x) # doesn't crash
jaxpr = jax.make_jaxpr(jnp.dot)(x, x)
finally:
config.FLAGS.jax_default_matmul_precision = prev_val
self.assertIn('Precision.HIGH', str(jaxpr))
self.assertEqual(prev_val, config._read("jax_default_matmul_precision"))
prev_val = config._read("jax_default_matmul_precision")
try:
config.update('jax_default_matmul_precision','tensorfloat32')
jnp.dot(x, x) # doesn't crash
jaxpr = jax.make_jaxpr(jnp.dot)(x, x)
finally:
config.update('jax_default_matmul_precision', prev_val)
self.assertIn('Precision.HIGH', str(jaxpr))
self.assertEqual(prev_val, config._read("jax_default_matmul_precision"))
def test_dot_precision_forces_retrace(self):
num_traces = 0
def g(x):
nonlocal num_traces
num_traces += 1
return jnp.dot(x, x)
def f_cond(x):
return lax.cond(True, g, g, x)
@jax.jit
def f_jit(x):
nonlocal num_traces
num_traces += 1
return jnp.dot(x, x)
for f in [f_jit, f_cond]:
# Use _read() to read the flag value rather than threadlocal value.
precision = config._read('jax_default_matmul_precision')
try:
num_traces = 0
x = jnp.zeros((2, 2))
f(x)
self.assertEqual(num_traces, 1)
f(x)
self.assertEqual(num_traces, 1)
with jax.default_matmul_precision("tensorfloat32"):
f(x)
self.assertEqual(num_traces, 2)
FLAGS.jax_default_matmul_precision = "float32"
f(x)
self.assertGreaterEqual(num_traces, 2)
nt = num_traces
f(x)
self.assertEqual(num_traces, nt + 1)
f(x)
self.assertEqual(num_traces, nt + 1)
finally:
FLAGS.jax_default_matmul_precision = precision
def test_backward_pass_ref_dropping(self):
refs = []
@api.custom_vjp
def f(x):
return x
def f_fwd(x):
return x, None
def f_rev(_, g):
assert len(refs) != 2 or refs[0]() is None
zero = np.zeros(())
refs.append(weakref.ref(zero))
return (zero,)
f.defvjp(f_fwd, f_rev)
api.grad(lambda x: f(f(f(x))))(1.)
def test_jit_inline(self):
@partial(api.jit, inline=False)
def f(x):
return x * 2
jaxpr = api.make_jaxpr(f)(3)
self.assertIn('xla_call', str(jaxpr))
@partial(api.jit, inline=True)
def f(x):
return x * 2
jaxpr = api.make_jaxpr(f)(3)
self.assertNotIn('xla_call', str(jaxpr))
# Repro for https://github.com/google/jax/issues/7229.
def test_compute_with_large_transfer(self):
def f(x, delta):
return x + jnp.asarray(delta, x.dtype)
# A large and potentially unaligned array to trigger non-zero-copy and
# async device array copy.
xs = self.rng().uniform(0., 1., size=(10, 131, 111, 3)).astype(np.float32)
for x in xs:
delta = self.rng().uniform(-0.5, 0.5, size=())
jitted_f = api.jit(f)
np.testing.assert_allclose(jitted_f(x, delta), f(x, delta))
def test_vjp_fun_jit(self):
# test that the function returned by vjp can be returned
# from and passed to jitted functions
f = lambda x: 2. * x
@partial(jit, static_argnums=0)
def linearize_vjp(f, x):
_, vjp_fun = api.vjp(f, x)
return vjp_fun
linearized = linearize_vjp(f, 1.)
actual = jit(lambda f, x: f(x))(linearized, 3.)
expected = (6.,)
self.assertEqual(actual, expected)
def test_linearize_fun_jit(self):
# test that the function returned by linearize can be returned
# from and passed to jitted functions
f = lambda x: 2. * x
@partial(jit, static_argnums=0)
def linearize(f, x):
_, jvp_fun = api.linearize(f, x)
return jvp_fun
linearized = linearize(f, 1.)
actual = jit(lambda f, x: f(x))(linearized, 3.)
expected = 6.
self.assertEqual(actual, expected)
def test_linear_transpose_fun_jit(self):
# test that the function returned by linear_transpose can be returned
# from and passed to jitted functions
f = lambda x: 2. * x
@partial(jit, static_argnums=0)
def transpose(f, x):
return api.linear_transpose(f, x)
transposed = transpose(f, 1.)
actual = jit(lambda f, x: f(x))(transposed, 3.)
expected = (6.,)
self.assertEqual(actual, expected)
def test_leaked_tracer_issue_7613(self):
# from https://github.com/google/jax/issues/7613
import numpy.random as npr
def sigmoid(x):
return 1. / (1. + jnp.exp(-x))
x = jnp.ones((1, 50))
A = jnp.array(npr.randn(50, 50))
@jax.jit
def loss(A, x):
h = jax.nn.sigmoid(A * x)
return jnp.sum((h - x)**2)
with jax.checking_leaks():
_ = jax.grad(loss)(A, x) # doesn't crash
def test_vmap_caching(self):
# https://github.com/google/jax/issues/7621
f = lambda x: jnp.square(x).mean()
jf = jax.jit(f)
x = jax.random.uniform(jax.random.PRNGKey(0), shape=(8, 4))
with jtu.count_jit_and_pmap_compiles() as count: # noqa: F841
for _ in range(5):
jax.hessian(jf)(x).block_until_ready()
n = count[0]
# The exact number of compilations may vary depending on the number of
# jit decorators in the function above, but it should not grow after an
# initial warmup phase.
for _ in range(5):
jax.hessian(jf)(x).block_until_ready()
self.assertEqual(count[0], n)
def test_jnp_array_doesnt_device_put(self):
with jtu.count_device_put() as count:
api.make_jaxpr(lambda: jnp.array(3))()
self.assertEqual(count[0], 0)
def test_rank_promotion_forces_retrace(self):
num_traces = 0
def g(x):
nonlocal num_traces
num_traces += 1
return x + x
def f_cond(x):
return lax.cond(True, g, g, x)
@jax.jit
def f_jit(x):
nonlocal num_traces
num_traces += 1
return x + x
for f in [f_jit, f_cond]:
# Use _read() to read the flag value rather than threadlocal value.
allow_promotion = config._read('jax_numpy_rank_promotion')
try:
FLAGS.jax_numpy_rank_promotion = "allow"
num_traces = 0
@jax.jit
def f(x):
nonlocal num_traces
num_traces += 1
return x + x
x = jnp.zeros((2, 2))
f(x)
self.assertEqual(num_traces, 1)
f(x)
self.assertEqual(num_traces, 1)
with jax.numpy_rank_promotion("warn"):
f(x)
self.assertEqual(num_traces, 2)
FLAGS.jax_numpy_rank_promotion = "raise"
f(x)
self.assertGreaterEqual(num_traces, 2)
nt = num_traces
f(x)
self.assertEqual(num_traces, nt + 1)
f(x)
self.assertEqual(num_traces, nt + 1)
finally:
FLAGS.jax_numpy_rank_promotion = allow_promotion
def test_grad_negative_argnums(self):
def f(x, y):
return x.sum() * y.sum()
x = jax.random.normal(jax.random.PRNGKey(0), (16, 16))
y = jax.random.normal(jax.random.PRNGKey(1), (16, 16))
g = jax.grad(f, argnums=-1)
g(x, y) # doesn't crash
def test_jit_negative_static_argnums(self):
g = jax.jit(lambda x, y: x * y, static_argnums=-1)
g(1, 2) # doesn't crash
def test_fastpath_cache_confusion(self):
# https://github.com/google/jax/issues/12542
@jax.jit
def a(x):
return ()
@jax.jit
def b(x):
return a(x)
@jax.jit
def g(x):
return x, x
@jax.jit
def h(x):
return g(x)
jaxpr = jax.make_jaxpr(h)(7)
jax.core.eval_jaxpr(jaxpr.jaxpr, jaxpr.consts, 7)
b(8) # don't crash
def test_fastpath_cache_confusion2(self):
@jax.jit
def a(): # note nullary function, still staged out though
return ()
@jax.jit
def b(x):
return a()
@jax.jit
def g(x):
return x, x
@jax.jit
def h(x):
return g(x)
jaxpr = jax.make_jaxpr(h)(7)
jax.core.eval_jaxpr(jaxpr.jaxpr, jaxpr.consts, 7)
b(8) # don't crash
def test_vjp_multiple_arguments_error_message(self):
# https://github.com/google/jax/issues/13099
def foo(x):
return (x, x)
_, f_vjp = jax.vjp(foo, 1.0)
with self.assertRaisesRegex(TypeError, "applied to foo"):
f_vjp(1.0, 1.0)
@jtu.with_config(jax_experimental_subjaxpr_lowering_cache=True)
class SubcallTraceCacheTest(jtu.JaxTestCase):
def test_subcall_trace_caching(self):
should_be_tracing_f = False
@api.jit
def f(x):
self.assertTrue(should_be_tracing_f)
return x**2
@api.jit
def g(x):
nonlocal should_be_tracing_f
self.assertTrue(should_be_tracing_g)
should_be_tracing_f = True
y = f(x)
should_be_tracing_f = False
z = f(x + 1)
return y + z
should_be_tracing_g = True
out = g(2)
self.assertEqual(out, 13)
should_be_tracing_g = False
out = g(3)
self.assertEqual(out, 25)
def test_subcall_jaxpr_id(self):
@api.jit
def f(x):
return x**2
def g(x):
y = f(x)
z = f(x + 1)
return y + z
jaxpr = api.make_jaxpr(g)(2)
self.assertIn("call_jaxpr", jaxpr.eqns[0].params)
self.assertIn("call_jaxpr", jaxpr.eqns[2].params)
subjaxpr1 = jaxpr.eqns[0].params["call_jaxpr"]
subjaxpr2 = jaxpr.eqns[2].params["call_jaxpr"]
self.assertIs(subjaxpr1, subjaxpr2)
class RematTest(jtu.JaxTestCase):
@parameterized.named_parameters(
{"testcase_name": f"{suffix}", "remat": remat}
for suffix, remat in [
('', api.remat),
('_policy', partial(api.remat, policy=lambda *_, **__: False)),
('_new', partial(new_checkpoint, policy=lambda *_, **__: False)),
])
def test_remat_basic(self, remat):
@remat
def g(x):
return lax.sin(lax.sin(x)), 3.
def f(x):
x, _ = g(x)
return x
ans = f(2.)
expected = np.sin(np.sin(2.))
self.assertAllClose(ans, expected, check_dtypes=False)
ans, f_lin = api.linearize(f, 2.)
expected = np.sin(np.sin(2.))
self.assertAllClose(ans, expected, check_dtypes=False)
ans = f_lin(3.)
expected = np.cos(np.sin(2.)) * np.cos(2.) * 3.
self.assertAllClose(ans, expected, check_dtypes=False)
sin_calls = []
cos_calls = []
sin_impl = lax.sin_p.impl
cos_impl = lax.cos_p.impl
try:
lax.sin_p.def_impl(lambda x: sin_calls.append(1) or sin_impl(x))
lax.cos_p.def_impl(lambda x: cos_calls.append(1) or cos_impl(x))
f_lin(3.)
finally:
lax.sin_p.def_impl(sin_impl)
lax.cos_p.def_impl(cos_impl)
self.assertEqual(len(sin_calls), 1)
self.assertEqual(len(cos_calls), 2)
@parameterized.named_parameters(
{"testcase_name": f"{suffix}", "remat": remat}
for suffix, remat in [
('', api.remat),
('_policy', partial(api.remat, policy=lambda *_, **__: False)),
('_new', partial(new_checkpoint, policy=lambda *_, **__: False)),
])
def test_remat_freevars(self, remat):
def f1(x):
y = 2 * jnp.sin(x)
z = jnp.cos(x) * jnp.sin(y)
return z
def f2(x):
y = 2 * jnp.sin(x)
z = remat(lambda x: jnp.cos(x) * jnp.sin(y))(x)
return z
ans, f_lin = api.linearize(f2, 2.)
expected, f_lin_expected = api.linearize(f1, 2.)
self.assertAllClose(ans, expected, check_dtypes=False)
ans = f_lin(3.)
expected = f_lin_expected(3.)
self.assertAllClose(ans, expected, check_dtypes=False)
def test_remat_concrete_error(self):
@api.remat # no static_argnums or concrete
def g(x):
if x > 0:
return lax.sin(x)
else:
return lax.cos(x)
with self.assertRaisesRegex(core.ConcretizationTypeError, "static_argnums"):
g(3.)
@partial(api.remat, static_argnums=(0,)) # using static_argnums but...
def g(x):
if x > 0: # jnp operations still get staged!
return lax.sin(x)
else:
return lax.cos(x)
with self.assertRaisesRegex(core.ConcretizationTypeError, "static_argnums"):
g(jnp.array(3.))
# But don't raise an error mentioning static_argnums here:
@api.remat
def g(x):
jax.jit(lambda: 0 if jnp.add(1, 1) else 0)()
return lax.sin(x)
try:
g(jnp.array(3.))
except core.ConcretizationTypeError as e:
msg = str(e)
self.assertNotIn('static_argnums', msg)
def test_remat_grad_python_control_flow_static_argnums(self):
@partial(api.remat, static_argnums=(0,))
def g(x):
with jax.ensure_compile_time_eval():
x_pos = x > 0
if x_pos:
return lax.sin(x), 3.
else:
return lax.cos(x), 4.
def f(x):
x, _ = g(x)
return x
ans = f(2.)
expected = np.sin(2.)
self.assertAllClose(ans, expected, check_dtypes=False)
ans = api.grad(f)(2.)
expected = np.cos(2.)
self.assertAllClose(ans, expected, check_dtypes=False)
def test_remat_grad_python_control_flow_unhashable_static_argnums(self):
@partial(api.remat, static_argnums=(0,))
def g(x):
x = x.val
with jax.ensure_compile_time_eval():
x_pos = x > 0
if x_pos:
return lax.sin(x), 3.
else:
return lax.cos(x), 4.
def f(x):
x, _ = g(x)
return x
class A:
def __init__(self, val):
self.val = val
def __hash__(self):
raise TypeError
ans = f(A(2.))
expected = np.sin(2.)
self.assertAllClose(ans, expected, check_dtypes=False)
ans = api.grad(lambda x: f(A(x)))(2.)
expected = np.cos(2.)
self.assertAllClose(ans, expected, check_dtypes=False)
def test_remat_retracing(self):
# This is *not* a very important behavior; remat doesn't need to provide
# caching guarantees with the same importance as jit. But even so, in the
# interest of not redoing tracing work (and thus make jax.remat more
# feasible to use in eager mode), this test checks that we don't re-trace
# the remat-decorated function.
count = 0
@api.remat
def g(x):
nonlocal count
count += 1
return lax.sin(x), 3.
def f(x):
x, _ = g(x)
return x
for _ in range(10):
y = f(2.)
y.block_until_ready()
self.assertEqual(count, 1)
def test_remat_static_agnums_retracing(self):
# This is *not* a super important behavior; remat doesn't need to provide
# caching guarantees with the same importance as jit. But even so, in the
# interest of not redoing tracing work (and thus make jax.remat more
# feasible to use in eager mode), this test checks that we don't re-trace
# the remat-decorated function *even with static_argnums*. See also the
# above test, which doesn't check for static_argnums.
count = 0
@partial(api.remat, static_argnums=(0,))
def g(x):
nonlocal count
count += 1
with jax.ensure_compile_time_eval():
x_pos = x > 0
if x_pos:
return lax.sin(x), 3.
else:
return lax.cos(x), 4.
def f(x):
x, _ = g(x)
return x
for _ in range(10):
y = f(2.)
y.block_until_ready()
self.assertEqual(count, 1)
@parameterized.named_parameters(
{"testcase_name": f"{suffix}", "remat": remat}
for suffix, remat in [
('', api.remat),
('_policy', partial(api.remat, policy=lambda *_, **__: False)),
('_new', partial(new_checkpoint, policy=lambda *_, **__: False)),
])
def test_remat_jit(self, remat):
@remat
def g(x):
return lax.sin(lax.sin(x))
def f_(x):
return g(x)
f = api.jit(f_)
ans = f(2.)
expected = np.sin(np.sin(2.))
self.assertAllClose(ans, expected, check_dtypes=False)
ans = api.grad(f)(2.)
expected = np.cos(np.sin(2.)) * np.cos(2.)
self.assertAllClose(ans, expected, check_dtypes=False)
ans = api.jit(api.grad(f_))(2.)
expected = np.cos(np.sin(2.)) * np.cos(2.)
self.assertAllClose(ans, expected, check_dtypes=False)
@parameterized.named_parameters(
{"testcase_name": f"{suffix}", "remat": remat}
for suffix, remat in [
('', api.remat),
('_policy', partial(api.remat, policy=lambda *_, **__: False)),
('_new', partial(new_checkpoint, policy=lambda *_, **__: False)),
])
def test_remat_vmap(self, remat):
@remat
def g(x):
return lax.sin(lax.sin(x))
x = np.arange(3.)
ans = api.vmap(g)(x)
expected = np.sin(np.sin(x))
self.assertAllClose(ans, expected, check_dtypes=False)
ans = api.jacfwd(g)(x)
expected = np.diag(np.cos(np.sin(x)) * np.cos(x))
self.assertAllClose(ans, expected, check_dtypes=False)
ans = api.jacrev(g)(x)
expected = np.diag(np.cos(np.sin(x)) * np.cos(x))
self.assertAllClose(ans, expected, check_dtypes=False)
# Make sure that introducing constants in vmap works.
constant_introducing_p = core.Primitive('introduce_constant')
constant_introducing_p.def_abstract_eval(core.raise_to_shaped)
def _constant_introducing_batcher(xs, ds):
(x,), (d,) = xs, ds
return (x + np.arange(x.size, dtype=x.dtype).reshape(x.shape)), d
batching.primitive_batchers[constant_introducing_p] = _constant_introducing_batcher
api.vmap(remat(constant_introducing_p.bind))(jnp.ones(20))
@parameterized.named_parameters(
{"testcase_name": f"{suffix}", "remat": remat}
for suffix, remat in [
('', api.remat),
('_policy', partial(api.remat, policy=lambda *_, **__: False)),
('_new', partial(new_checkpoint, policy=lambda *_, **__: False)),
])
def test_remat_vmap_not_leading_dim(self, remat):
@remat
def g(x):
return lax.sin(lax.sin(x))
x = np.arange(3 * 5.).reshape(3, 5)
ans = api.vmap(g, 1, 0)(x)
expected = np.sin(np.sin(x)).T
self.assertAllClose(ans, expected, check_dtypes=False)
@parameterized.named_parameters(
{"testcase_name": f"{suffix}", "remat": remat}
for suffix, remat in [
('', api.remat),
('_policy', partial(api.remat, policy=lambda *_, **__: False)),
('_new', partial(new_checkpoint, policy=lambda *_, **__: False)),
])
def test_remat_higher_order_autodiff(self, remat):
def f(x):
return lax.cos(lax.sin(x))
g = remat(f)
ans = api.grad(api.grad(g))(3.)
expected = api.grad(api.grad(f))(3.)
self.assertAllClose(ans, expected, check_dtypes=False)
@parameterized.named_parameters(
{"testcase_name": f"{suffix}", "remat": remat}
for suffix, remat in [
('', api.remat),
('_new', new_checkpoint),
])
def test_remat_scan(self, remat):
to_scan = lambda c, x: (jnp.sin(c), None)
def f_noremat(x):
y, _ = lax.scan(to_scan, x, np.arange(3.))
return y
def f_yesremat(x):
y, _ = lax.scan(remat(to_scan), x, np.arange(3.))
return y
ans = f_yesremat(4.)
expected = f_noremat(4.)
self.assertAllClose(ans, expected, check_dtypes=False)
ans = api.grad(f_yesremat)(4.)
expected = api.grad(f_noremat)(4.)
self.assertAllClose(ans, expected, check_dtypes=False)
jaxpr = api.make_jaxpr(api.linearize(f_yesremat, 4.)[1])(1.)
scan_eqn, = jaxpr.jaxpr.eqns
self.assertIn(' cos ', str(scan_eqn.params['jaxpr']))
jaxpr = api.make_jaxpr(api.vjp(f_yesremat, 4.)[1])(1.)
scan_eqn, = jaxpr.jaxpr.eqns
self.assertIn(' cos ', str(scan_eqn.params['jaxpr']))
@parameterized.named_parameters(
{"testcase_name": f"{suffix}", "remat": remat}
for suffix, remat in [
('', api.remat),
('_policy', partial(api.remat, policy=lambda *_, **__: False)),
('_new', partial(new_checkpoint, policy=lambda *_, **__: False)),
])
def test_remat_no_redundant_flops(self, remat):
# see https://github.com/google/jax/pull/1749#issuecomment-558267584
@api.jit
def g(x):
return f(2., x)
@remat
def f(x, y):
return jnp.sin(x) * y
# We swap out sin_p's impl rule to count how many times it's invoked
called = []
sin_impl = lax.sin_p.impl
try:
lax.sin_p.def_impl(lambda x: called.append(1) or sin_impl(x))
api.grad(g)(3.)
finally:
lax.sin_p.def_impl(sin_impl)
num_calls = len(called)
self.assertLessEqual(num_calls, 1)
@parameterized.named_parameters(
{"testcase_name": f"{suffix}", "remat": remat}
for suffix, remat in [
('', api.remat),
('_policy', partial(api.remat, policy=lambda *_, **__: False)),
('_new', partial(new_checkpoint, policy=lambda *_, **__: False)),
])
def test_remat_binomial_checkpointing(self, remat):
def binom_checkpoint(funs):
if len(funs) == 1:
return funs[0]
else:
f1 = binom_checkpoint(funs[:len(funs)//2])
f2 = binom_checkpoint(funs[len(funs)//2:])
return remat(lambda x: f1(f2(x)))
f1 = binom_checkpoint([jnp.sin, jnp.sin, jnp.sin, jnp.sin])
f2 = lambda x: jnp.sin(jnp.sin(jnp.sin(jnp.sin(x))))
x = 4.
self.assertAllClose(f1(x), f2(x), check_dtypes=False)
self.assertAllClose(api.grad(f1)(x), api.grad(f2)(x), check_dtypes=False)
@parameterized.named_parameters(
{"testcase_name": f"{suffix}", "remat": remat}
for suffix, remat in [
('', api.remat),
('_new', new_checkpoint),
])
def test_remat_symbolic_zeros(self, remat):
# code from https://github.com/google/jax/issues/1907
key = jax.random.PRNGKey(0)
key, split = jax.random.split(key)
n = 5
def func(D0):
def shift(R, dR, **unused_kwargs):
return R + dR
def apply_fn(R):
return D0 * R
Rinit = jax.random.uniform(split, (n,3), minval=0.0, maxval=5.0,
dtype=jnp.float32)
def move(R,i):
F = apply_fn(R)
return shift(R, 0.001 * F), jnp.array([0.])
move = remat(move)
R, temp = lax.scan(move, Rinit, jnp.arange(2))
return R[0, 0]
api.grad(func)(5.0) # doesn't crash
@parameterized.named_parameters(
{"testcase_name": f"{suffix}", "remat": remat}
for suffix, remat in [
('', api.remat),
('_policy', partial(api.remat, policy=lambda *_, **__: False)),
('_new', partial(new_checkpoint, policy=lambda *_, **__: False)),
])
def test_remat_jit2(self, remat):
@api.jit
def f(x):
y = 2 * x
@remat
def g():
return y
return g()
self.assertAllClose(f(3), 6, check_dtypes=False)
@parameterized.named_parameters(
{"testcase_name": f"{suffix}", "remat": remat}
for suffix, remat in [
('', api.remat),
('_new', new_checkpoint),
])
def test_remat_nontrivial_env(self, remat):
# simplified from https://github.com/google/jax/issues/2030
@remat
def foo(state, dt=0.5, c=1):
u, u_t = state
u_tt = c**2 * u
u_t = u_t + u_tt * dt
return (u, u_t)
@partial(api.jit, static_argnums=(1,))
def _multi_step(state, count, dt, c):
f = lambda s, _: (foo(s, dt, c), _)
return lax.scan(f, state, None, count)
def multi_step(state, count, dt=1/jnp.sqrt(2), c=1):
return _multi_step(state, count, dt, c)
def loss(u0, target, steps, dt=1/jnp.sqrt(2), c=1):
init = (u0, jnp.zeros_like(u0))
(uf, _), _ = multi_step(init, steps, dt, c)
return ((uf - target) ** 2).mean()
target = jnp.zeros((128, 128))
u0 = jnp.ones_like(target)
loss(u0, target, 10) # doesn't crash
@parameterized.named_parameters(
{"testcase_name": f"{suffix}", "remat": remat}
for suffix, remat in [
('', api.remat),
('_policy', partial(api.remat, policy=lambda *_, **__: False)),
('_new', partial(new_checkpoint, policy=lambda *_, **__: False)),
])
def test_remat_jit3(self, remat):
# https://github.com/google/jax/issues/2180
def f(w, x):
a = jnp.dot(x, w)
b = jnp.einsum("btd,bTd->btT", a, a)
c = jnp.einsum("btT,btd->btd", b, a)
return jnp.sum(c)
w = jnp.ones([1, 1])
x = jnp.ones([1, 1, 1])
f = remat(f)
api.grad(f)(w, x) # doesn't crash
@api.jit
def mul(a, b):
return a * b
def f(w, x):
a = mul(w, x)
b = mul(a, a)
return b
w = 1.
x = 1.
f = remat(f)
api.grad(f)(w, x) # doesn't crash
@parameterized.named_parameters(
{"testcase_name": f"{suffix}", "remat": remat}
for suffix, remat in [
('', api.remat),
('_new', new_checkpoint),
])
def test_remat_scan2(self, remat):
# https://github.com/google/jax/issues/1963
def scan_bug(x0):
f = lambda x, _: (x + 1, None)
def scanned_f(x, _):
return lax.scan(f, x, xs=None, length=1)[0], None
x, _ = remat(scanned_f)(x0, None)
return x
jax.grad(scan_bug)(1.0) # doesn't crash
def test_remat_jit_static_argnum_omnistaging(self):
# https://github.com/google/jax/issues/2833
# NOTE(mattjj): after #3370, this test doesn't actually call remat...
def named_call(f):
def named_f(*args):
f_ = lu.wrap_init(lambda: (f(*args),))
out, = core.call_p.bind(f_)
return out
return named_f
def f(a_bool, y):
if a_bool:
return y + 1
else:
return y
api.jit(named_call(f), static_argnums=0)(True, 1) # no crash
@parameterized.named_parameters(
{"testcase_name": f"{suffix}", "remat": remat}
for suffix, remat in [
('', api.remat),
('_policy', partial(api.remat, policy=lambda *_, **__: False)),
('_new', partial(new_checkpoint, policy=lambda *_, **__: False)),
])
def test_remat_eval_counter(self, remat):
# https://github.com/google/jax/issues/2737
add_one_p = Primitive('add_one')
add_one = add_one_p.bind
num_evals = 0
@contextmanager
def assertEvals(n):
start = num_evals
yield
assert num_evals - start == n
def add_one_impl(x):
nonlocal num_evals
num_evals += 1
return x + 1
add_one_p.def_impl(add_one_impl)
def add_one_jvp(pin, tin):
pout = add_one(pin[0])
return pout, pout * tin[0]
ad.primitive_jvps[add_one_p] = add_one_jvp
add_one_p.def_abstract_eval(lambda x: x)
v = np.zeros((1,))
f = remat(add_one)
g = remat(lambda x: add_one(f(x)))
# 2 calls needed to evaluate g
with assertEvals(2):
_, vjp = jax.vjp(g, v)
# 2 calls made while transposing g, 1 call made while transposing f
with assertEvals(3):
vjp(v)
@jax_util.curry
def call(f, *args):
return jax.core.call(
jax.linear_util.wrap_init(lambda *args: [f(*args)]),
*args, name='foo')[0]
f = call(add_one)
g = remat(lambda x: add_one(f(x)))
# 2 calls needed to evaluate g
with assertEvals(2):
_, vjp = jax.vjp(g, v)
# 2 calls made while transposing g, no reevaluation for transposition of f
with assertEvals(2):
vjp(v)
@parameterized.named_parameters(
{"testcase_name": f"{suffix}", "remat": remat}
for suffix, remat in [
('', api.remat),
('_policy', partial(api.remat, policy=lambda *_, **__: False)),
('_new', partial(new_checkpoint, policy=lambda *_, **__: False)),
])
def test_escaped_tracer_remat(self, remat):
# b/169779185
def f():
seq = [jnp.zeros([])]
def g():
seq[0] += 1 # this is line 7 btw
return seq[0]
remat(g)()
remat(lambda: g())() # lambda defeats caching
with self.assertRaisesRegex(UnexpectedTracerError, "global state"):
api.jit(f)()
@parameterized.named_parameters(
{"testcase_name": f"{suffix}", "remat": remat}
for suffix, remat in [
('', api.remat),
('_policy', partial(api.remat, policy=lambda *_, **__: False)),
('_new', partial(new_checkpoint, policy=lambda *_, **__: False)),
])
def test_no_cse_widget_on_primals(self, remat):
@remat
def g(x):
return lax.sin(lax.sin(x)), 3.
def f(x):
x, _ = g(x)
return x
c = api.xla_computation(f)(2.)
self.assertNotIn('while', c.as_hlo_text())
self.assertNotIn('conditional', c.as_hlo_text())
self.assertNotIn('opt-barrier', c.as_hlo_text())
c = api.xla_computation(grad(f))(2.)
text = c.as_hlo_text()
self.assertTrue('while' in text or 'conditional' in text
or 'opt-barrier' in text)
@parameterized.named_parameters(
{"testcase_name": f"{suffix}", "remat": remat}
for suffix, remat in [
('', api.remat),
('_new', new_checkpoint),
])
def test_no_cse_widget_with_prevent_cse_false(self, remat):
@partial(remat, prevent_cse=False)
def g(x):
return lax.sin(lax.sin(x)), 3.
def f(x):
x, _ = g(x)
return x
c = api.xla_computation(f)(2.)
self.assertNotIn('while', c.as_hlo_text())
self.assertNotIn('conditional', c.as_hlo_text())
c = api.xla_computation(grad(f))(2.)
self.assertNotIn('while', c.as_hlo_text())
self.assertNotIn('conditional', c.as_hlo_text())
@parameterized.named_parameters(
{"testcase_name": f"_{policy_name}_{remat_name}", "remat": remat,
"policy": policy, "in_jaxpr2": in_jaxpr2, "not_in_jaxpr2": not_in_jaxpr2}
for remat_name, remat in [
('old_remat', api.remat),
('new_remat', new_checkpoint),
]
for policy_name, policy, in_jaxpr2, not_in_jaxpr2 in [
('save_anything', lambda *_, **__: True, [], [' sin ', ' cos ']),
('save_nothing', lambda *_, **__: False, [' sin ', ' cos '], []),
('save_sin', lambda p, *_, **__: str(p) == 'sin', [' cos '], [' sin ']),
])
def test_remat_custom_policy(self, remat, policy, in_jaxpr2, not_in_jaxpr2):
for square in [lambda x: x * x, api.jit(lambda x: x * x)]:
f = remat(lambda x: jnp.sin(square(jnp.sin(x))), policy=policy)
y, f_lin = api.linearize(f, 1.)
ydot = f_lin(2.)
jaxpr_text = str(f_lin.func.args[0])
for substr in in_jaxpr2:
self.assertIn(substr, jaxpr_text)
for substr in not_in_jaxpr2:
self.assertNotIn(substr, jaxpr_text)
y_expected, ydot_expected = api.jvp(lambda x: jnp.sin(square(jnp.sin(x))),
[1.], [2.])
self.assertAllClose(y, y_expected)
self.assertAllClose(ydot, ydot_expected)
jtu.check_grads(f, (3.,), order=2, modes=['fwd', 'rev'])
@parameterized.named_parameters(
{"testcase_name": f"_{remat_name}", "remat": remat}
for remat_name, remat in [
('old_remat', api.remat),
('new_remat', new_checkpoint),
])
def test_remat_custom_policy_save_cos(self, remat):
save_cos = lambda prim, *_, **__: str(prim) == 'cos'
f = remat(lambda x: jnp.sin(jnp.sin(x)), # different function
policy=save_cos)
_, f_lin = api.linearize(f, 1.)
jaxpr_text = str(f_lin.func.args[0])
self.assertNotIn(' sin ', jaxpr_text)
self.assertNotIn(' cos ', jaxpr_text)
jtu.check_grads(f, (3.,), order=2, modes=['fwd', 'rev'])
@parameterized.named_parameters(
{"testcase_name": f"_{remat_name}", "remat": remat}
for remat_name, remat in [
('old_remat', api.remat),
('new_remat', new_checkpoint),
])
def test_remat_checkpoint_dots(self, remat):
@partial(remat, policy=jax.checkpoint_policies.checkpoint_dots)
def f(x):
x = jnp.dot(x, x, precision=lax.Precision.HIGHEST)
x = jnp.sin(x)
x = jnp.dot(x, x, precision=lax.Precision.HIGHEST)
x = jnp.sin(x)
x = jnp.dot(x, x, precision=lax.Precision.HIGHEST)
x = jnp.sin(x)
return x
_, f_lin = api.linearize(f, jnp.ones((2, 2)))
jaxpr_text = str(f_lin.func.args[0])
self.assertEqual(jaxpr_text.count(' sin '), 2)
self.assertEqual(jaxpr_text.count(' dot_'), 6)
jtu.check_grads(f, (jnp.ones((2, 2)),), order=2, modes=['fwd', 'rev'])
@parameterized.named_parameters(
{"testcase_name": f"_{remat_name}", "remat": remat}
for remat_name, remat in [
('old_remat', api.remat),
('new_remat', new_checkpoint),
])
def test_remat_checkpoint_dots_with_no_batch_dims(self, remat):
@partial(remat, policy=jax.checkpoint_policies.checkpoint_dots_with_no_batch_dims)
def f(x):
x = jnp.einsum('ij,jk->ik', x, x, precision=lax.Precision.HIGHEST)
x = jnp.sin(x)
x = jnp.einsum('ij,jk->ik', x, x, precision=lax.Precision.HIGHEST)
x = jnp.sin(x)
x = jnp.einsum('ij,jk->ik', x, x, precision=lax.Precision.HIGHEST)
x = jnp.sin(x)
return x
_, f_lin = api.linearize(f, jnp.ones((2, 2)))
jaxpr_text = str(f_lin.func.args[0])
self.assertEqual(jaxpr_text.count(' sin '), 2)
self.assertEqual(jaxpr_text.count(' dot_general'), 6)
jtu.check_grads(f, (jnp.ones((2, 2)),), order=2, modes=['fwd', 'rev'])
@parameterized.named_parameters(
{"testcase_name": f"_{remat_name}", "remat": remat}
for remat_name, remat in [
('old_remat', api.remat),
('new_remat', new_checkpoint),
])
def test_remat_checkpoint_dots_with_no_batch_dims2(self, remat):
@partial(remat, policy=jax.checkpoint_policies.checkpoint_dots_with_no_batch_dims)
def f(x):
x = jnp.einsum('nij,njk->nik', x, x, precision=lax.Precision.HIGHEST)
x = jnp.sin(x)
x = jnp.einsum('nij,njk->nik', x, x, precision=lax.Precision.HIGHEST)
x = jnp.sin(x)
x = jnp.einsum('nij,njk->nik', x, x, precision=lax.Precision.HIGHEST)
x = jnp.sin(x)
return x
_, f_lin = api.linearize(f, jnp.ones((3, 2, 2)))
jaxpr_text = str(f_lin.func.args[0])
self.assertEqual(jaxpr_text.count(' sin '), 2)
self.assertEqual(jaxpr_text.count(' dot_general'), 9)
jtu.check_grads(f, (jnp.ones((3, 2, 2)),), order=2, modes=['fwd', 'rev'])
@parameterized.named_parameters(
{"testcase_name": f"_{remat_name}", "remat": remat}
for remat_name, remat in [
('old_remat', api.remat),
('new_remat', new_checkpoint),
])
def test_remat_checkpoint_dots_jit(self, remat):
@api.jit
@partial(remat, policy=jax.checkpoint_policies.checkpoint_dots)
def f(x):
x = jnp.dot(x, x, precision=lax.Precision.HIGHEST)
x = jnp.sin(x * 1e-3)
x = jnp.dot(x, x, precision=lax.Precision.HIGHEST)
x = jnp.sin(x * 1e-3)
x = jnp.dot(x, x, precision=lax.Precision.HIGHEST)
x = jnp.sin(x * 1e-3)
return x
_, f_lin = api.linearize(f, jnp.ones((2, 2)))
jaxpr_text = str(f_lin.func.args[0])
self.assertEqual(jaxpr_text.count(' sin '), 2)
self.assertEqual(jaxpr_text.count(' dot_'), 6)
jtu.check_grads(f, (jnp.ones((2, 2)),), order=2, modes=['fwd', 'rev'])
def test_remat_checkpoint_dots_inside_scan(self):
x = jnp.ones((5,))
def f(W):
@partial(api.remat, policy=jax.checkpoint_policies.checkpoint_dots)
def f(x):
x = jnp.sin(jnp.dot(x, W, precision=lax.Precision.HIGHEST))
x = jnp.sin(jnp.dot(x, W, precision=lax.Precision.HIGHEST))
x = jnp.sin(jnp.dot(x, W, precision=lax.Precision.HIGHEST))
return x
def body(x, _): return f(x), None
return lax.scan(body, x, None, length=2)[0]
_, f_vjp = api.vjp(f, jnp.ones((5, 5)))
jaxpr_text = str(f_vjp.args[0].func.args[1])
# Two sine calls in the backward pass because while we don't save sines
# within the (rematted) body function, we can save the scan carry, which
# effectively saves one sine. Three cosines for the Jacobian coefficients.
self.assertEqual(jaxpr_text.count(' sin '), 2)
self.assertEqual(jaxpr_text.count(' cos '), 3)
# Six calls to dot_general in the backward pass because we save the primal
# matmuls and only compure the backward pass ones (two for each primal one).
self.assertEqual(jaxpr_text.count(' dot_'), 6)
jtu.check_grads(api.jit(f), (jnp.ones((5, 5)),), order=2,
modes=['fwd', 'rev'])
def test_remat_custom_jvp_policy(self):
@api.custom_jvp
def sin(x):
return jnp.sin(x)
def sin_jvp(primals, tangents):
x, = primals
g, = tangents
return sin(x), jnp.cos(x) * g
sin.defjvp(sin_jvp)
@partial(api.remat, policy=jax.checkpoint_policies.checkpoint_dots)
def f(x):
x = jnp.dot(x, x, precision=lax.Precision.HIGHEST)
x = sin(x * 1e-3)
x = jnp.dot(x, x, precision=lax.Precision.HIGHEST)
x = sin(x * 1e-3)
x = jnp.dot(x, x, precision=lax.Precision.HIGHEST)
x = sin(x * 1e-3)
return x
jtu.check_grads(f, (3.,), order=2, modes=['fwd', 'rev'])
def g(x):
return lax.scan(lambda x, _: (f(x), None), x, None, length=2)[0]
jtu.check_grads(g, (3.,), order=2, modes=['fwd', 'rev'])
def test_remat_custom_vjp_policy(self):
@api.custom_vjp
def sin(x):
return jnp.sin(x)
def sin_fwd(x):
return sin(x), x
def sin_bwd(x, y_bar):
return (jnp.cos(x) * y_bar,)
sin.defvjp(sin_fwd, sin_bwd)
@partial(api.remat, policy=jax.checkpoint_policies.checkpoint_dots)
def f(x):
@partial(api.named_call, name="dot")
def dot2(y, z):
return jnp.dot(x, jnp.dot(y, z, precision=lax.Precision.HIGHEST),
precision=lax.Precision.HIGHEST)
x = dot2(x, x)
x = sin(x * 1e-3)
x = dot2(x, x)
x = sin(x * 1e-3)
x = dot2(x, x)
x = sin(x * 1e-3)
return x
jtu.check_grads(f, (3.,), order=2, modes=['rev'])
def g(x):
return lax.scan(lambda x, _: (f(x), None), x, None, length=2)[0]
jtu.check_grads(g, (3.,), order=2, modes=['rev'])
@parameterized.named_parameters(
{"testcase_name": f"_{remat_name}", "remat": remat}
for remat_name, remat in [
('old_remat', api.remat),
('new_remat', new_checkpoint),
])
def test_remat_dropvar_policy(self, remat):
def f(x):
return x, x
@partial(remat, policy=jax.checkpoint_policies.checkpoint_dots)
def g(x):
x = api.grad(lambda x: f(x)[0])(x)
return x
api.grad(g)(3.)
def test_remat_custom_jvp_linear_policy(self):
@api.custom_jvp
def sum(x):
return jnp.sum(x, axis=0)
@sum.defjvp
def sum_jvp(primals, tangents):
(x,), (xdot,) = primals, tangents
return sum(x), sum(xdot)
@partial(api.remat, policy=jax.checkpoint_policies.checkpoint_dots)
def f(x):
return sum(x)
jtu.check_grads(f, (jnp.ones(3),), order=2, modes=['fwd', 'rev'])
def g(x):
return lax.scan(lambda _, x: (None, f(x)), None, x)[1]
jtu.check_grads(g, (jnp.ones((2, 3)),), order=2, modes=['fwd', 'rev'])
def test_constants_not_hoisted(self):
# The old implementation of remat worked by data dependence, and so
# (potentially large) constants would not be rematerialized and could be
# wastefully instantiated. This test checks that the newer remat
# implementation avoids that. See https://github.com/google/jax/pull/8191.
# no residuals from constants created inside jnp.einsum
@partial(new_checkpoint, policy=lambda *_, **__: False)
def f(x):
return jnp.einsum('ii->i', x)
res_avals = saved_residuals(f, jnp.ones((2, 2)))
self.assertLen(res_avals, 0)
# no residuals from jnp.zeros
@partial(new_checkpoint, policy=lambda *_, **__: False)
def f(x):
return jnp.zeros_like(x) * x
res_avals = saved_residuals(f, jnp.ones((2, 2)))
self.assertLen(res_avals, 0)
# no residuals from jnp.zeros, but input must be saved
@partial(new_checkpoint, policy=lambda *_, **__: False)
def f(x):
return jnp.zeros_like(x) * jnp.sin(x)
res_avals = saved_residuals(f, jnp.ones((2, 2)))
self.assertLen(res_avals, 1)
def test_name_denylist(self):
def f(x):
y = checkpoint_name(jnp.multiply(2., 2.), 'y')
z = checkpoint_name(jnp.multiply(2., 2.), 'z')
w = checkpoint_name(jnp.multiply(2., 2.), 'w')
u = jnp.multiply(2., 2.)
return (((x * y) * z) * w) * u
policy = jax.checkpoint_policies.save_any_names_but_these('y', 'z', 'w')
res = saved_residuals(new_checkpoint(f, policy=policy), 1.)
self.assertLen(res, 0) # can't save anything
policy = jax.checkpoint_policies.save_any_names_but_these('z', 'w')
res = saved_residuals(new_checkpoint(f, policy=policy), 1.)
self.assertLen(res, 1) # can save only y
policy = jax.checkpoint_policies.save_any_names_but_these('w')
res = saved_residuals(new_checkpoint(f, policy=policy), 1.)
self.assertLen(res, 2) # can save y and z
policy = jax.checkpoint_policies.save_any_names_but_these()
res = saved_residuals(new_checkpoint(f, policy=policy), 1.)
self.assertLen(res, 3) # can save y, z, and w
def test_name_allowlist(self):
def f(x):
y = checkpoint_name(jnp.multiply(2., 2.), 'y')
z = checkpoint_name(jnp.multiply(2., 2.), 'z')
w = checkpoint_name(jnp.multiply(2., 2.), 'w')
u = jnp.multiply(2., 2.)
return (((x * y) * z) * w) * u
policy = jax.checkpoint_policies.save_only_these_names('y', 'z', 'w')
res = saved_residuals(new_checkpoint(f, policy=policy), 1.)
self.assertLen(res, 3) # can save y, z, and w
policy = jax.checkpoint_policies.save_only_these_names('z', 'w')
res = saved_residuals(new_checkpoint(f, policy=policy), 1.)
self.assertLen(res, 2) # can save z and w
policy = jax.checkpoint_policies.save_only_these_names('w')
res = saved_residuals(new_checkpoint(f, policy=policy), 1.)
self.assertLen(res, 1) # can save w
policy = jax.checkpoint_policies.save_only_these_names()
res = saved_residuals(new_checkpoint(f, policy=policy), 1.)
self.assertLen(res, 0) # can't save anything!
def test_saved_residuals_utility(self):
def f(x, y):
x1, x2 = x
z = checkpoint_name(jnp.sin(3.), 'z')
return z * ((x1 * x2) * y) * np.array([3.])
res = saved_residuals(f, (2., 3.), y=4.)
self.assertLen(res, 6)
self.assertEqual(res[0][0].shape, (1,))
self.assertEqual(res[0][1], "from a constant")
self.assertEqual(res[1][0].shape, ())
self.assertEqual(res[1][1], "from the argument 'x'")
self.assertEqual(res[2][0].shape, ())
self.assertEqual(res[2][1], "from the argument 'x'")
self.assertEqual(res[3][0].shape, ())
self.assertEqual(res[3][1], "from the argument 'y'")
self.assertEqual(res[4][0].shape, ())
self.assertStartsWith(res[4][1], "named 'z'")
self.assertEqual(res[5][0].shape, ())
@parameterized.named_parameters(
{"testcase_name": f"{suffix}", "remat": remat}
for suffix, remat in [
('', api.remat),
('_policy', partial(api.remat, policy=lambda *_, **__: False)),
('_new', partial(new_checkpoint, policy=lambda *_, **__: False)),
])
def test_checkpoint_dropvars(self, remat):
@remat
def f(x):
_, x = api.jit(lambda: (x, x))()
return x
_ = api.grad(f)(3.) # doesn't crash
def test_dce_keeps_eqns_with_used_outputs_but_no_used_inputs(self):
@new_checkpoint
def f(x):
c = jax.jit(lambda: 3.)()
return c * x
_ = jax.grad(f)(3.) # doesn't crash
def test_linearize_caching(self):
# https://github.com/google/jax/issues/9661
identity = jax.checkpoint(jax.jit(lambda x: 2 * x))
_, f_lin = jax.linearize(identity, 1.)
with jtu.count_jit_and_pmap_compiles() as count: # noqa: F841
for _ in range(20):
f_lin(1.).block_until_ready()
self.assertEqual(count[0], 1) # cached after first execution
def test_vjp_caching(self):
# https://github.com/google/jax/issues/9661
identity = jax.checkpoint(jax.jit(lambda x: 2 * x))
_, f_vjp = jax.vjp(identity, 1.)
with jtu.count_jit_and_pmap_compiles() as count: # noqa: F841
for _ in range(20):
f_vjp(1.)[0].block_until_ready()
self.assertEqual(count[0], 1) # fwd execute_trivial, backward_pass on bwd
def test_vjp_caching_static_argnums(self):
identity = jax.remat(lambda x, y: jax.jit(lambda x: 2 * x if y else x)(x),
static_argnums=(1,))
_, f_vjp = jax.vjp(identity, 1., True)
with jtu.count_jit_and_pmap_compiles() as count: # noqa: F841
for _ in range(20):
f_vjp(1.)[0].block_until_ready()
self.assertEqual(count[0], 1) # fwd execute_trivial, backward_pass on bwd
def test_fwd_caching(self):
# see above test also
identity = jax.checkpoint(jax.jit(lambda x: 2 * x))
with jtu.count_jit_and_pmap_compiles() as count: # noqa: F841
for _ in range(20):
y, _ = jax.vjp(identity, 1.)
y.block_until_ready()
self.assertEqual(count[0], 1)
def test_fwd_caching_static_argnums(self):
# see above test also
identity = jax.checkpoint(jax.jit(lambda x: 2 * x), static_argnums=(0,))
with jtu.count_jit_and_pmap_compiles() as count: # noqa: F841
for _ in range(20):
y = identity(1.)
y.block_until_ready()
self.assertEqual(count[0], 1)
@parameterized.named_parameters(
{"testcase_name": f"{suffix}", "remat": remat}
for suffix, remat in [
('', api.remat),
('_new', new_checkpoint),
])
def test_remat_of_scan(self, remat):
to_scan = lambda c, _: (jnp.sin(c), jnp.sin(c))
f = lambda x: lax.scan(to_scan, x, None, length=3)
jtu.check_grads(remat(f), (3.,), order=2, modes=['rev'])
jaxpr = api.make_jaxpr(api.linearize(remat(f), 4.)[1])(1.)
self.assertIn(' sin ', str(jaxpr))
self.assertIn(' cos ', str(jaxpr))
@parameterized.named_parameters(
{"testcase_name": f"{suffix}", "remat": remat}
for suffix, remat in [
('', api.remat),
('_new', new_checkpoint),
])
def test_const_in_jvp_scan(self, remat):
@api.custom_jvp
def f(x):
return x * np.arange(3.)
@f.defjvp
def f_jvp(primals, tangents):
(x,), (xdot,) = primals, tangents
return f(x), xdot * np.arange(3.)
@remat
def g(x):
def body(c, _):
return f(c), None
y, _ = jax.lax.scan(body, x, None, length=1)
return y.sum()
jax.grad(g)(jnp.arange(3.)) # doesn't crash
def test_remat_checkpoint_dots_outside_scan(self):
# see also above test test_remat_checkpoint_dots_inside_scan
x = jnp.ones((5,))
@partial(new_checkpoint, policy=jax.checkpoint_policies.checkpoint_dots)
def f(W):
def f(x):
x = jnp.sin(jnp.dot(x, W, precision=lax.Precision.HIGHEST))
x = jnp.sin(jnp.dot(x, W, precision=lax.Precision.HIGHEST))
x = jnp.sin(jnp.dot(x, W, precision=lax.Precision.HIGHEST))
return x
def body(x, _): return f(x), None
return lax.scan(body, x, None, length=2)[0]
_, f_vjp = api.vjp(f, jnp.ones((5, 5)))
jaxpr = f_vjp.args[0].func.args[1]
jaxpr_text = str(jaxpr)
self.assertEqual(jaxpr_text.count(' sin '), 3)
self.assertEqual(jaxpr_text.count(' cos '), 3)
# Six calls to dot_general in the backward pass because we save the primal
# matmuls and only compure the backward pass ones (two for each primal one).
self.assertEqual(jaxpr_text.count(' dot_'), 6)
jtu.check_grads(api.jit(f), (jnp.ones((5, 5)),), order=2,
modes=['fwd', 'rev'])
def test_remat_of_scan_policy(self):
save_cos = lambda prim, *_, **__: str(prim) == 'cos'
to_scan = lambda c, _: (jnp.sin(c), jnp.sin(c))
f = new_checkpoint(lambda x: lax.scan(to_scan, x, None, length=3),
policy=save_cos)
jtu.check_grads(f, (3.,), order=2, modes=['rev'])
jaxpr = api.make_jaxpr(api.linearize(f, 4.)[1])(1.)
jaxpr_text = str(jaxpr)
self.assertEqual(jaxpr_text.count(' sin '), 0)
self.assertEqual(jaxpr_text.count(' cos '), 0)
def test_remat_of_scan_funky_custom_jvp(self):
def scan_apply(f, x):
y, _ = lax.scan(lambda x, _: (f(x), None), x, None, length=1)
return y
@api.custom_jvp
def sin(x):
return jnp.sin(x)
def sin_jvp(primals, tangents):
x, = primals
xdot, = tangents
y, c = jax.jit(lambda: (jnp.sin(x), jnp.cos(x)))()
ydot = c * xdot
return y, ydot
sin.defjvp(sin_jvp)
save_cos = lambda prim, *_, **__: str(prim) == 'cos'
f = new_checkpoint(partial(scan_apply, sin), policy=save_cos)
jtu.check_grads(f, (3.,), order=2, modes=['rev'])
jaxpr = api.make_jaxpr(api.linearize(f, 4.)[1])(1.)
jaxpr_text = str(jaxpr)
self.assertEqual(jaxpr_text.count(' sin '), 0)
self.assertEqual(jaxpr_text.count(' cos '), 0)
save_sin = lambda prim, *_, **__: str(prim) == 'sin'
f = new_checkpoint(partial(scan_apply, sin), policy=save_sin)
jtu.check_grads(f, (3.,), order=2, modes=['rev'])
jaxpr = api.make_jaxpr(api.linearize(f, 4.)[1])(1.)
jaxpr_text = str(jaxpr)
self.assertEqual(jaxpr_text.count(' sin '), 0)
self.assertEqual(jaxpr_text.count(' cos '), 1)
f = new_checkpoint(partial(scan_apply, sin),
policy=jax.checkpoint_policies.everything_saveable)
jtu.check_grads(f, (3.,), order=2, modes=['rev'])
jaxpr = api.make_jaxpr(api.linearize(f, 4.)[1])(1.)
jaxpr_text = str(jaxpr)
self.assertEqual(jaxpr_text.count(' sin '), 0)
self.assertEqual(jaxpr_text.count(' cos '), 0)
f = new_checkpoint(partial(scan_apply, sin),
policy=jax.checkpoint_policies.nothing_saveable)
jtu.check_grads(f, (3.,), order=2, modes=['rev'])
jaxpr = api.make_jaxpr(api.linearize(f, 4.)[1])(1.)
jaxpr_text = str(jaxpr)
self.assertEqual(jaxpr_text.count(' sin '), 1) # +1 b/c dce fixed point
self.assertEqual(jaxpr_text.count(' cos '), 1)
f = new_checkpoint(lambda x: scan_apply(sin, scan_apply(sin, x)),
policy=jax.checkpoint_policies.nothing_saveable)
jtu.check_grads(f, (3.,), order=2, modes=['rev'])
jaxpr = api.make_jaxpr(api.linearize(f, 4.)[1])(1.)
jaxpr_text = str(jaxpr)
self.assertEqual(jaxpr_text.count(' sin '), 2) # +1 b/c dce fixed point
self.assertEqual(jaxpr_text.count(' cos '), 2)
def test_remat_of_scan_funky_custom_jvp2(self):
# Like the above test but instead of using jit inside custom_jvp, use scan.
def scan_apply(f, x):
y, _ = lax.scan(lambda x, _: (f(x), None), x, None, length=1)
return y
@api.custom_jvp
def sin(x):
return jnp.sin(x)
def sin_jvp(primals, tangents):
x, = primals
xdot, = tangents
y, c = scan_apply(lambda xs: (jnp.sin(xs[0]), jnp.cos(xs[1])), (x, x))
ydot = c * xdot
return y, ydot
sin.defjvp(sin_jvp)
save_cos = lambda prim, *_, **__: str(prim) == 'cos'
f = new_checkpoint(partial(scan_apply, sin), policy=save_cos)
jtu.check_grads(f, (3.,), order=2, modes=['rev'])
jaxpr = api.make_jaxpr(api.linearize(f, 4.)[1])(1.)
jaxpr_text = str(jaxpr)
self.assertEqual(jaxpr_text.count(' sin '), 1) # +1 b/c dce fixed point
self.assertEqual(jaxpr_text.count(' cos '), 0)
save_sin = lambda prim, *_, **__: str(prim) == 'sin'
f = new_checkpoint(partial(scan_apply, sin), policy=save_sin)
jtu.check_grads(f, (3.,), order=2, modes=['rev'])
jaxpr = api.make_jaxpr(api.linearize(f, 4.)[1])(1.)
jaxpr_text = str(jaxpr)
self.assertEqual(jaxpr_text.count(' sin '), 0)
self.assertEqual(jaxpr_text.count(' cos '), 1)
f = new_checkpoint(partial(scan_apply, sin),
policy=jax.checkpoint_policies.everything_saveable)
jtu.check_grads(f, (3.,), order=2, modes=['rev'])
jaxpr = api.make_jaxpr(api.linearize(f, 4.)[1])(1.)
jaxpr_text = str(jaxpr)
self.assertEqual(jaxpr_text.count(' sin '), 0)
self.assertEqual(jaxpr_text.count(' cos '), 0)
f = new_checkpoint(partial(scan_apply, sin),
policy=jax.checkpoint_policies.nothing_saveable)
jtu.check_grads(f, (3.,), order=2, modes=['rev'])
jaxpr = api.make_jaxpr(api.linearize(f, 4.)[1])(1.)
jaxpr_text = str(jaxpr)
self.assertEqual(jaxpr_text.count(' sin '), 1) # +1 b/c dce fixed point
self.assertEqual(jaxpr_text.count(' cos '), 1)
f = new_checkpoint(lambda x: scan_apply(sin, scan_apply(sin, x)),
policy=jax.checkpoint_policies.nothing_saveable)
jtu.check_grads(f, (3.,), order=2, modes=['rev'])
jaxpr = api.make_jaxpr(api.linearize(f, 4.)[1])(1.)
jaxpr_text = str(jaxpr)
self.assertEqual(jaxpr_text.count(' sin '), 2) # +1 b/c dce fixed point
self.assertEqual(jaxpr_text.count(' cos '), 2)
@parameterized.named_parameters(
{"testcase_name": f"{suffix}", "remat": remat}
for suffix, remat in [
('', api.remat),
('_new', new_checkpoint),
])
def test_remat_of_cond(self, remat):
true_fn = lambda c: (jnp.sin(c), jnp.sin(c))
false_fn = lambda c: (jnp.sin(c), jnp.sin(c))
f = lambda x: lax.cond(x > 0., true_fn, false_fn, x)
jtu.check_grads(remat(f), (3.,), order=2, modes=['rev'])
jaxpr = api.make_jaxpr(api.linearize(remat(f), 4.)[1])(1.)
self.assertNotIn(' sin ', str(jaxpr))
self.assertIn(' cos ', str(jaxpr))
true_fn = lambda c: jnp.sin(jnp.sin(c))
false_fn = lambda c: c
f = lambda x: lax.cond(x > 0., true_fn, false_fn, x)
jtu.check_grads(remat(f), (3.,), order=2, modes=['rev'])
jaxpr = api.make_jaxpr(api.linearize(remat(f), 4.)[1])(1.)
self.assertIn(' sin ', str(jaxpr))
self.assertIn(' cos ', str(jaxpr))
@parameterized.named_parameters(
{"testcase_name": f"{suffix}", "remat": remat}
for suffix, remat in [
('', api.remat),
('_new', new_checkpoint),
])
def test_const_in_jvp_cond(self, remat):
@api.custom_jvp
def f(x):
return x * np.arange(3.)
@f.defjvp
def f_jvp(primals, tangents):
(x,), (xdot,) = primals, tangents
return f(x), xdot * np.arange(3.)
@remat
def g(x):
y = jax.lax.cond(x.sum() > 0, f, lambda x: x, x)
return y.sum()
jax.grad(g)(jnp.arange(3.)) # doesn't crash
def test_remat_checkpoint_dots_inside_cond(self):
x = jnp.ones((5,))
def f(W):
@partial(api.remat, policy=jax.checkpoint_policies.checkpoint_dots)
def f(x):
x = jnp.sin(jnp.dot(x, W, precision=lax.Precision.HIGHEST))
x = jnp.sin(jnp.dot(x, W, precision=lax.Precision.HIGHEST))
x = jnp.sin(jnp.dot(x, W, precision=lax.Precision.HIGHEST))
return x
return lax.cond(x.sum() > 0, f, lambda x: x, x)
_, f_vjp = api.vjp(f, jnp.ones((5, 5)))
jaxpr_text = str(f_vjp.args[0].func.args[1])
self.assertEqual(jaxpr_text.count(' sin '), 2)
self.assertEqual(jaxpr_text.count(' cos '), 3)
# Five calls to dot_general in the backward pass because we have two for
# each forward-pass dot, except for the first which only has one (as we are
# differentiating with respect to only W and not x).
self.assertEqual(jaxpr_text.count(' dot_'), 5)
jtu.check_grads(api.jit(f), (jnp.ones((5, 5)),), order=2,
modes=['fwd', 'rev'])
def test_remat_checkpoint_dots_outside_cond(self):
# see also above test test_remat_checkpoint_dots_inside_cond
# The behavior between the two tests is essentially identical, whereas for
# scan different things are saved based on this difference in remat
# placement (because of the carry).
x = jnp.ones((5,))
@partial(new_checkpoint, policy=jax.checkpoint_policies.checkpoint_dots)
def f(W):
def f(x):
x = jnp.sin(jnp.dot(x, W, precision=lax.Precision.HIGHEST))
x = jnp.sin(jnp.dot(x, W, precision=lax.Precision.HIGHEST))
x = jnp.sin(jnp.dot(x, W, precision=lax.Precision.HIGHEST))
return x
return lax.cond(x.sum() > 0, f, lambda x: x, x)
_, f_vjp = api.vjp(f, jnp.ones((5, 5)))
jaxpr = f_vjp.args[0].func.args[1]
jaxpr_text = str(jaxpr)
self.assertEqual(jaxpr_text.count(' sin '), 2)
self.assertEqual(jaxpr_text.count(' cos '), 3)
self.assertEqual(jaxpr_text.count(' dot_'), 5)
jtu.check_grads(api.jit(f), (jnp.ones((5, 5)),), order=2,
modes=['fwd', 'rev'])
def test_remat_of_cond_policy(self):
save_cos = lambda prim, *_, **__: str(prim) == 'cos'
f = new_checkpoint(lambda x: lax.cond(x > 0, jnp.sin, lambda x: x, x),
policy=save_cos)
jtu.check_grads(f, (3.,), order=2, modes=['rev'])
jaxpr = api.make_jaxpr(api.linearize(f, 4.)[1])(1.)
jaxpr_text = str(jaxpr)
self.assertEqual(jaxpr_text.count(' sin '), 0)
self.assertEqual(jaxpr_text.count(' cos '), 0)
def test_remat_of_cond_funky_custom_jvp(self):
def cond_apply(f, x):
return lax.cond(x.sum() > -jnp.inf, f, lambda x: x, x)
@api.custom_jvp
def sin(x):
return jnp.sin(x)
def sin_jvp(primals, tangents):
x, = primals
xdot, = tangents
y, c = jax.jit(lambda: (jnp.sin(x), jnp.cos(x)))()
ydot = c * xdot
return y, ydot
sin.defjvp(sin_jvp)
save_cos = lambda prim, *_, **__: str(prim) == 'cos'
f = new_checkpoint(partial(cond_apply, sin), policy=save_cos)
jtu.check_grads(f, (3.,), order=2, modes=['rev'])
jaxpr = api.make_jaxpr(api.linearize(f, 4.)[1])(1.)
jaxpr_text = str(jaxpr)
self.assertEqual(jaxpr_text.count(' sin '), 0)
self.assertEqual(jaxpr_text.count(' cos '), 0)
save_sin = lambda prim, *_, **__: str(prim) == 'sin'
f = new_checkpoint(partial(cond_apply, sin), policy=save_sin)
jtu.check_grads(f, (3.,), order=2, modes=['rev'])
jaxpr = api.make_jaxpr(api.linearize(f, 4.)[1])(1.)
jaxpr_text = str(jaxpr)
self.assertEqual(jaxpr_text.count(' sin '), 0)
self.assertEqual(jaxpr_text.count(' cos '), 1)
f = new_checkpoint(partial(cond_apply, sin),
policy=jax.checkpoint_policies.everything_saveable)
jtu.check_grads(f, (3.,), order=2, modes=['rev'])
jaxpr = api.make_jaxpr(api.linearize(f, 4.)[1])(1.)
jaxpr_text = str(jaxpr)
self.assertEqual(jaxpr_text.count(' sin '), 0)
self.assertEqual(jaxpr_text.count(' cos '), 0)
f = new_checkpoint(partial(cond_apply, sin),
policy=jax.checkpoint_policies.nothing_saveable)
jtu.check_grads(f, (3.,), order=2, modes=['rev'])
jaxpr = api.make_jaxpr(api.linearize(f, 4.)[1])(1.)
jaxpr_text = str(jaxpr)
self.assertEqual(jaxpr_text.count(' sin '), 0)
self.assertEqual(jaxpr_text.count(' cos '), 1)
f = new_checkpoint(lambda x: cond_apply(sin, cond_apply(sin, x)),
policy=jax.checkpoint_policies.nothing_saveable)
jtu.check_grads(f, (3.,), order=2, modes=['rev'])
jaxpr = api.make_jaxpr(api.linearize(f, 4.)[1])(1.)
jaxpr_text = str(jaxpr)
self.assertEqual(jaxpr_text.count(' sin '), 1)
self.assertEqual(jaxpr_text.count(' cos '), 2)
def test_remat_of_cond_funky_custom_jvp2(self):
# Like the above test but instead of using jit inside custom_jvp, use cond.
def cond_apply(f, x):
return lax.cond(True, f, lambda x: x, x)
@api.custom_jvp
def sin(x):
return jnp.sin(x)
def sin_jvp(primals, tangents):
x, = primals
xdot, = tangents
y, c = cond_apply(lambda xs: (jnp.sin(xs[0]), jnp.cos(xs[1])), (x, x))
ydot = c * xdot
return y, ydot
sin.defjvp(sin_jvp)
save_cos = lambda prim, *_, **__: str(prim) == 'cos'
f = new_checkpoint(partial(cond_apply, sin), policy=save_cos)
jtu.check_grads(f, (3.,), order=2, modes=['rev'])
jaxpr = api.make_jaxpr(api.linearize(f, 4.)[1])(1.)
jaxpr_text = str(jaxpr)
self.assertEqual(jaxpr_text.count(' sin '), 0)
self.assertEqual(jaxpr_text.count(' cos '), 0)
save_sin = lambda prim, *_, **__: str(prim) == 'sin'
f = new_checkpoint(partial(cond_apply, sin), policy=save_sin)
jtu.check_grads(f, (3.,), order=2, modes=['rev'])
jaxpr = api.make_jaxpr(api.linearize(f, 4.)[1])(1.)
jaxpr_text = str(jaxpr)
self.assertEqual(jaxpr_text.count(' sin '), 0)
self.assertEqual(jaxpr_text.count(' cos '), 1)
f = new_checkpoint(partial(cond_apply, sin),
policy=jax.checkpoint_policies.everything_saveable)
jtu.check_grads(f, (3.,), order=2, modes=['rev'])
jaxpr = api.make_jaxpr(api.linearize(f, 4.)[1])(1.)
jaxpr_text = str(jaxpr)
self.assertEqual(jaxpr_text.count(' sin '), 0)
self.assertEqual(jaxpr_text.count(' cos '), 0)
f = new_checkpoint(partial(cond_apply, sin),
policy=jax.checkpoint_policies.nothing_saveable)
jtu.check_grads(f, (3.,), order=2, modes=['rev'])
jaxpr = api.make_jaxpr(api.linearize(f, 4.)[1])(1.)
jaxpr_text = str(jaxpr)
self.assertEqual(jaxpr_text.count(' sin '), 0)
self.assertEqual(jaxpr_text.count(' cos '), 1)
f = new_checkpoint(lambda x: cond_apply(sin, cond_apply(sin, x)),
policy=jax.checkpoint_policies.nothing_saveable)
jtu.check_grads(f, (3.,), order=2, modes=['rev'])
jaxpr = api.make_jaxpr(api.linearize(f, 4.)[1])(1.)
jaxpr_text = str(jaxpr)
self.assertEqual(jaxpr_text.count(' sin '), 1)
self.assertEqual(jaxpr_text.count(' cos '), 2)
@parameterized.named_parameters(
{"testcase_name": f"{suffix}", "remat": remat}
for suffix, remat in [
('', api.remat),
('_new', new_checkpoint),
])
def test_remat_of_while_loop(self, remat):
def cond_fn(carry):
i, _ = carry
return i < 3
def body_fn(carry):
i, x = carry
return i + 1, jnp.sin(x)
def f(x):
_, y = lax.while_loop(cond_fn, body_fn, (0, x))
return y
_, f_lin = jax.linearize(remat(f), 3.)
y_dot = f_lin(1.0)
expected = jax.grad(lambda x: jnp.sin(jnp.sin(jnp.sin(x))))(3.)
self.assertArraysAllClose(y_dot, expected, check_dtypes=False)
jaxpr = api.make_jaxpr(jax.linearize(remat(f), 4.)[1])(1.)
self.assertIn(' sin ', str(jaxpr))
self.assertIn(' cos ', str(jaxpr))
def test_remat_of_while_loop_policy(self):
def cond_fn(carry):
i, _ = carry
return i < 3
def body_fn(carry):
i, x = carry
return i + 1, jnp.sin(x)
def f(x):
_, y = lax.while_loop(cond_fn, body_fn, (0, x))
return y
# even with a policy, we can't save residuals (w/o dynamic shapes)!
save_cos = lambda prim, *_, **__: str(prim) == 'cos'
g = new_checkpoint(f, policy=save_cos)
jaxpr = api.make_jaxpr(jax.linearize(g, 4.)[1])(1.)
self.assertIn(' sin ', str(jaxpr))
self.assertIn(' cos ', str(jaxpr))
class JaxprTest(jtu.JaxTestCase):
def test_scalar_literals(self):
jaxpr = api.make_jaxpr(lambda x: x + 2)(42)
self.assertLen(jaxpr.jaxpr.constvars, 0)
def test_abstract_inputs(self):
jaxpr = api.make_jaxpr(lambda x: x + 2.)(
types.SimpleNamespace(shape=(), dtype=np.dtype(np.float32)))
self.assertEqual(jaxpr.in_avals[0].shape, ())
self.assertEqual(jaxpr.in_avals[0].dtype, np.float32)
def test_const(self):
def fun(x):
return (x, 1., np.zeros(1, dtype=jnp.float32))
expected = "{ lambda a:f32[1]; b:f32[]. let in (b, 1.0, a) }"
jaxpr = api.make_jaxpr(fun)(jnp.float32(0.))
self.assertMultiLineStrippedEqual(expected, str(jaxpr))
def test_cond(self):
def f(x):
return lax.cond(x >= 0.,
x + 1.,
lambda xt: xt + x,
x + 2.,
lambda xf: xf - x)
expected = """{ lambda ; a:f32[]. let
b:bool[] = ge a 0.0
c:f32[] = add a 1.0
d:f32[] = add a 2.0
e:i32[] = convert_element_type[new_dtype=int32 weak_type=False] b
f:f32[] = cond[
branches=(
{ lambda ; g_:f32[] h:f32[] i:f32[] j:f32[]. let
k:f32[] = sub j h
in (k,) }
{ lambda ; l:f32[] m_:f32[] n:f32[] o:f32[]. let
p:f32[] = add n l
in (p,) }
)
linear=(False, False, False, False)
] e a a c d
in (f,) }"""
jaxpr = api.make_jaxpr(f)(jnp.float32(3.))
self.assertMultiLineStrippedEqual(expected, str(jaxpr))
def test_make_jaxpr_static_argnums(self):
def f(x, y):
return x + y
jaxpr = api.make_jaxpr(f, static_argnums=(1,))(2, 3)
self.assertIn('3', str(jaxpr))
def test_make_jaxpr_return_shape(self):
_, shape_tree = api.make_jaxpr(lambda x: (x + 1, jnp.zeros(2, jnp.float32)),
return_shape=True)(jnp.int32(1))
expected = (api.ShapeDtypeStruct(shape=(), dtype=jnp.int32),
api.ShapeDtypeStruct(shape=(2,), dtype=jnp.float32))
self.assertEqual(shape_tree, expected)
def test_make_jaxpr_axis_env(self):
def f(x):
return x - lax.psum(x, 'i')
jaxpr = api.make_jaxpr(f, axis_env=[('i', 4)])(2)
self.assertIn('psum', str(jaxpr))
def test_make_jaxpr_named(self):
def f(x):
return x - lax.psum(x, 'i')
x = api.ShapeDtypeStruct(
shape=(2, 3), dtype=jnp.dtype(jnp.float32), named_shape={'i': 10})
jaxpr = api.make_jaxpr(f, axis_env=[('i', 10)])(x)
named_shapes = [v.aval.named_shape for v in jaxpr.jaxpr.eqns[1].invars]
self.assertEqual(named_shapes, [{'i': 10}, {}])
@parameterized.parameters(True, False)
def test_vjp_reduce_axes_jaxpr(self, gy_batched):
def f(w, x):
return jnp.sin(jnp.dot(x, w))
w = api.ShapeDtypeStruct(
shape=(3, 4), dtype=jnp.float32, named_shape={})
x = api.ShapeDtypeStruct(
shape=(3,), dtype=jnp.float32, named_shape={'batch': 2})
gy = api.ShapeDtypeStruct(
shape=(4,), dtype=jnp.float32,
named_shape={'batch': 2} if gy_batched else {})
# per-example
jaxpr, shapes = api.make_jaxpr(
lambda w, x, gy: api.vjp(f, w, x)[1](gy), axis_env=[('batch', 2)],
return_shape=True)(w, x, gy)
expected = (api.ShapeDtypeStruct(
shape=(3, 4), dtype=jnp.float32, named_shape={'batch': 2}), x)
self.assertEqual(shapes, expected)
self.assertNotIn('psum', str(jaxpr))
# reduced
jaxpr, shapes = api.make_jaxpr(
lambda w, x, gy: api.vjp(f, w, x, reduce_axes=('batch',))[1](gy),
axis_env=[('batch', 2)],
return_shape=True)(w, x, gy)
expected = (w, x)
self.assertEqual(shapes, expected)
self.assertIn('psum', str(jaxpr))
def test_weak_type_jit_invariance(self):
y = jnp.broadcast_to(3., (3,))
self.assertTrue(y.aval.weak_type)
def f():
return lax.convert_element_type(y, 'float32')
self.assertEqual(f().aval.weak_type, api.jit(f)().aval.weak_type)
def test_elide_trivial_convert_element_types(self):
# since we apply convert_element_type to a numpy.ndarray, the primitive is
# still bound and thus would appear in the jaxpr if we didn't clean it up
if config.x64_enabled:
x = np.arange(3, dtype='float64')
else:
x = np.arange(3, dtype='float32')
cet = partial(lax.convert_element_type, new_dtype=x.dtype)
jaxpr = api.make_jaxpr(lambda: cet(cet(cet(x))))()
self.assertLen(jaxpr.eqns, 0)
def test_elide_trivial_broadcasts(self):
# since we apply broadcast to a numpy.ndarray, the primitive is still bound
# and thus would appear in the jaxpr if we didn't clean it up
jaxpr = api.make_jaxpr(lambda: lax.broadcast(np.float32(3), ()))()
self.assertLen(jaxpr.jaxpr.eqns, 0)
def test_convert_element_type_literal_constant_folding(self):
# this convert_elemnt_type is nontrivial, but because it's on a scalar we
# constant-fold it
cet = partial(lax.convert_element_type, new_dtype='float16')
jaxpr = api.make_jaxpr(lambda: cet(3.))()
self.assertLen(jaxpr.eqns, 0)
class DCETest(jtu.JaxTestCase):
def assert_dce_result(self, jaxpr: core.Jaxpr, used_outputs: List[bool],
expected_used_inputs: List[bool],
expected_num_eqns: Optional[int] = None,
check_diff: bool = True):
jaxpr_dce, used_inputs = pe.dce_jaxpr(jaxpr, used_outputs)
core.check_jaxpr(jaxpr_dce)
self.assertEqual(used_inputs, expected_used_inputs)
if expected_num_eqns is not None:
all_jaxprs = it.chain([jaxpr_dce], core.subjaxprs(jaxpr_dce))
num_eqns = sum(len(subjaxpr.eqns) for subjaxpr in all_jaxprs)
self.assertEqual(num_eqns, expected_num_eqns, msg=str(jaxpr_dce))
rand_ = jtu.rand_small(np.random.RandomState(0))
rand = lambda v: rand_(v.aval.shape, v.aval.dtype)
consts = [rand(v) for v in jaxpr.constvars]
inputs = [rand(v) for v in jaxpr.invars ]
inputs_dce = [x for x, used in zip(inputs, used_inputs) if used]
full_outs = core.eval_jaxpr(jaxpr , consts, *inputs)
expected_outs_dce = [y for y, used in zip(full_outs, used_outputs) if used]
outs = core.eval_jaxpr(jaxpr_dce, consts, *inputs_dce)
self.assertAllClose(outs, expected_outs_dce)
if check_diff and expected_num_eqns != 0:
f = lambda *args: core.eval_jaxpr(jaxpr_dce, consts, *args)
jtu.check_grads(f, inputs_dce, order=2, modes=['rev'])
def test_dce_jaxpr_scan_nontrivial_fixedpoint_carry(self):
# The idea is that each element of the output carry tuple depends on the
# corresponding carried input as well as the one to the left. The extensive
# inputs and outputs aren't used here; just the carry depending on itself.
def f(lst):
def body(c, _):
return [c[0]] + [c1 + c2 for c1, c2 in zip(c[:-1], c[1:])], None
out, _ = jax.lax.scan(body, lst, None, length=len(lst))
return out
jaxpr = api.make_jaxpr(f)([1., 2., 3., 4.]).jaxpr
self.assertLen(jaxpr.eqns, 1)
self.assertLen(jaxpr.eqns[0].params['jaxpr'].jaxpr.eqns, 3)
# If we use all but the last element, all but the first input is used, and
# only one eqn is pruned.
self.assert_dce_result(
jaxpr, used_outputs=[True, True, True, False],
expected_used_inputs=[True, True, True, False],
expected_num_eqns=1 + 2) # one outer scan eqn, two adds in the body
# Same as above if we just pull on the third element.
self.assert_dce_result(
jaxpr, used_outputs=[False, False, True, False],
expected_used_inputs=[True, True, True, False],
expected_num_eqns=1 + 2) # one outer scan eqn, two adds in the body
# If we use all but the last two elements, the last two inputs are not used,
# and two eqns can be pruned.
self.assert_dce_result(
jaxpr, used_outputs=[True, True, False, False],
expected_used_inputs=[True, True, False, False],
expected_num_eqns=1 + 1) # one outer scan eqn, one add in body
# If we only use the last element, no eqns can be pruned.
self.assert_dce_result(
jaxpr, used_outputs=[False, False, False, True],
expected_used_inputs=[True, True, True, True],
expected_num_eqns=1 + 3) # one outer scan eqn, three adds in body
def test_dce_jaxpr_scan_nontrivial_fixedpoint_carry_2(self):
# This is much like the above test, except with a more interesting
# dependence structure among the carry elements. Also add a const and
# extensive input.
hidden_sequence = [1, 2, 3, 5, 8]
def f(lst):
def body(c, _):
_ = jnp.sin(np.array([3., 1., 4.]))
sub_c = [c[i] for i in hidden_sequence]
sub_c = [sub_c[0]] + [c1 * c2 for c1, c2 in zip(sub_c[:-1], sub_c[1:])]
new_c = list(c)
for i, elt in zip(hidden_sequence, sub_c):
new_c[i] = elt
return new_c, None
out, _ = jax.lax.scan(body, lst, np.arange(len(lst), dtype='float32'))
return out
jaxpr = api.make_jaxpr(f)([1., 2., 3., 4., 5., 6., 7., 8., 9., 10.]).jaxpr
self.assertLen(jaxpr.eqns, 1)
self.assertLen(jaxpr.eqns[0].params['jaxpr'].jaxpr.eqns, 5)
# If we use the value at index 8 only, all the hidden sequence must be kept
# and no eqns can be pruned.
used_outputs = [False] * 10
used_outputs[8] = True
expected_used_inputs = [False] * 10
for i in hidden_sequence:
expected_used_inputs[i] = True
self.assert_dce_result(
jaxpr, used_outputs=used_outputs,
expected_used_inputs=expected_used_inputs,
expected_num_eqns=1 + 4)
# If we use the value at any indices not in the hidden sequence, none of the
# hidden sequence must be kept and we can prune all body eqns.
used_outputs = [False] * 10
expected_used_inputs = [False] * 10
used_outputs[9] = expected_used_inputs[9] = True
self.assert_dce_result(
jaxpr, used_outputs=used_outputs,
expected_used_inputs=expected_used_inputs,
expected_num_eqns=1) # 1 b/c scan doesn't have fwding rule
used_outputs[7] = expected_used_inputs[7] = True
used_outputs[6] = expected_used_inputs[6] = True
self.assert_dce_result(
jaxpr, used_outputs=used_outputs,
expected_used_inputs=expected_used_inputs,
expected_num_eqns=1)
# If we use the value at index 3 only, some of the hidden sequence must be
# kept but the rest pruned.
used_outputs = [False] * 10
used_outputs[3] = True
expected_used_inputs = [False] * 10
expected_used_inputs[1] = expected_used_inputs[2] = \
expected_used_inputs[3] = True
self.assert_dce_result(
jaxpr, used_outputs=used_outputs,
expected_used_inputs=expected_used_inputs,
expected_num_eqns=1 + 2)
def test_dce_jaxpr_scan_nontrivial_fixedpoint_extensive_output(self):
# Here we test how using the extensive output affects the carry.
def f(lst):
def body(c, _):
return [c[-1], *c[:-1]], c[-1]
_, ys = jax.lax.scan(body, lst, None, length=len(lst))
return ys
jaxpr = api.make_jaxpr(f)([1., 2., 3., 4.]).jaxpr
self.assertLen(jaxpr.eqns, 1)
# If we only use the extensive output, all carry elements are needed, and we
# need to keep the scan itself.
self.assert_dce_result(
jaxpr, used_outputs=[True],
expected_used_inputs=[True, True, True, True],
expected_num_eqns=1)
# If we don't use the extensive output, no carry elements are needed, and we
# don't need to keep the scan.
self.assert_dce_result(
jaxpr, used_outputs=[False],
expected_used_inputs=[False, False, False, False],
expected_num_eqns=0)
def test_dce_jaxpr_scan_extensive_input(self):
# Here we test an extensive input affecting the carry.
def cumprod(xs):
def body(c, x):
return c * x, c
c, ys = jax.lax.scan(body, jnp.float32(1.), xs)
return c, ys
jaxpr = api.make_jaxpr(cumprod)(jnp.arange(1., 5., dtype='float32')).jaxpr
# If we only use the carry output or extensive output, we need the input.
self.assert_dce_result(
jaxpr, used_outputs=[True, False],
expected_used_inputs=[True],
expected_num_eqns=2)
self.assert_dce_result(
jaxpr, used_outputs=[False, True],
expected_used_inputs=[True],
expected_num_eqns=2)
# If we don't use either output, the scan is eliminated.
self.assert_dce_result(
jaxpr, used_outputs=[False, False],
expected_used_inputs=[False],
expected_num_eqns=0)
def test_dce_jaxpr_scan_overpruning(self):
# This is a regression test for a specific issue.
@api.remat
def scanned_f(c, x):
out = jnp.tanh(c * x)
return out, out
def f(xs):
return lax.scan(scanned_f, jnp.array(1., 'float32'), xs)
xs = jnp.arange(10., dtype='float32')
jaxpr = api.make_jaxpr(lambda xs: api.linearize(f, xs)[1])(xs).jaxpr
jaxpr, used_inputs = pe.dce_jaxpr(jaxpr, [True] * len(jaxpr.outvars))
self.assertLen(jaxpr.eqns, 1)
self.assertLen(jaxpr.eqns[-1].params['jaxpr'].jaxpr.eqns, 2)
def test_dce_jaxpr_scan_const_in_jvp(self):
# The main point of this test is to check for a crash.
@api.custom_jvp
def f(x):
return x * np.arange(3.)
@f.defjvp
def f_jvp(primals, tangents):
(x,), (xdot,) = primals, tangents
return f(x), xdot * np.arange(3.)
def g(x):
def body(c, _):
return f(c), None
y, _ = jax.lax.scan(body, x, None, length=1)
return y
jaxpr = api.make_jaxpr(lambda x, xdot: api.jvp(g, (x,), (xdot,))
)(np.arange(3.), np.arange(3.)).jaxpr
self.assert_dce_result(
jaxpr, used_outputs=[True, True],
expected_used_inputs=[True, True])
self.assert_dce_result(
jaxpr, used_outputs=[True, False],
expected_used_inputs=[True, False])
def test_dce_jaxpr_scan_results(self):
# This doesn't test whether DCE is doing nontrivial work; instead it tests
# whether the result after applying DCE computes different values. If
# dce_jaxpr were an identity function, it'd pass this test!
def f(cs, xs):
def body(c, x):
return (c[0], c[0] + c[1], jnp.arange(3.)), x
cs, xs = jax.lax.scan(body, cs, xs)
return cs[::2], xs[::2]
cs = 1., 2., jnp.arange(3.)
xs = jnp.arange(3.), jnp.arange(3.) + 5
jaxpr_ = jax.make_jaxpr(f)(cs, xs)
jaxpr, consts = jaxpr_.jaxpr, jaxpr_.consts
jaxpr_pruned, used_inputs = pe.dce_jaxpr(jaxpr, [True] * len(jaxpr.outvars))
args = (*cs, *xs)
result1 = core.eval_jaxpr(jaxpr , consts, *cs, *xs)
pruned_args = [x for x, used in zip(args, used_inputs) if used]
result2 = core.eval_jaxpr(jaxpr_pruned, consts, *pruned_args)
self.assertAllClose(result1, result2)
def test_dce_jaxpr_cond_trivial(self):
x = jnp.array(1., dtype='float32')
# start with 7 eqns, use both outputs so nothing can be pruned
def f(x1, x2):
return lax.cond(x1 > 0,
lambda x1, x2: (jnp.sin(x1), jnp.sin(x2)),
lambda x1, x2: (jnp.sin(x1), jnp.sin(x2)),
x1, x2)
jaxpr = jax.make_jaxpr(f)(x, x).jaxpr
self.assert_dce_result(jaxpr, [True, True], [True, True], 7)
# use neither output so everything can be pruned
self.assert_dce_result(jaxpr, [False, False], [False, False], 0)
def test_dce_jaxpr_cond_nontrivial(self):
x = jnp.array(1., dtype='float32')
# start with 7 eqns, dont use an output so an eqn can be trimmed on each
# side and x2 _can_ be pruned
def f(x1, x2):
return lax.cond(x1 > 0,
lambda x1, x2: (jnp.sin(x1), jnp.sin(x2)),
lambda x1, x2: (jnp.sin(x1), jnp.sin(x1)),
x1, x2)
jaxpr = jax.make_jaxpr(f)(x, x).jaxpr
self.assert_dce_result(jaxpr, [True, False], [True, False], 5)
# start with 7 eqns, dont use an output so an eqn can be trimmed on each
# side, but x2 _can't_ be pruned b/c of a swap
def f(x1, x2):
return lax.cond(x1 > 0,
lambda x1, x2: (jnp.sin(x1), jnp.sin(x2)),
lambda x1, x2: (jnp.sin(x2), jnp.sin(x1)),
x1, x2)
jaxpr = jax.make_jaxpr(f)(x, x).jaxpr
self.assert_dce_result(jaxpr, [True, False], [True, True], 5)
# start with 7 eqns, only use x1 on one side and x2 on the other, so we
# can't prune any inputs or eqns
def f(x1, x2):
return lax.cond(x1 > 0,
lambda x1, x2: (jnp.sin(x1), jnp.sin(x1)),
lambda x1, x2: (jnp.sin(x2), jnp.sin(x2)),
x1, x2)
jaxpr = jax.make_jaxpr(f)(x, x).jaxpr
self.assert_dce_result(jaxpr, [True, True], [True, True], 7)
# use only one output, so we can prune eqns but not inputs
self.assert_dce_result(jaxpr, [True, False], [True, True], 5)
class CustomJVPTest(jtu.JaxTestCase):
def test_basic(self):
@api.custom_jvp
def f(x):
return jnp.sin(x)
def f_jvp(primals, tangents):
x, = primals
g, = tangents
return f(x), 2 * jnp.cos(x) * g
f.defjvp(f_jvp)
x = 3.
self.assertAllClose(f(x), jnp.sin(x))
self.assertAllClose(api.jvp(f, (x,), (1.,)),
(jnp.sin(x), 2 * jnp.cos(x)))
self.assertAllClose(api.grad(f)(x), 2 * jnp.cos(x))
def test_invariance(self):
@api.custom_jvp
def f(x):
return jnp.cos(2 * x) / 2.
def f_jvp(primals, tangents):
x, = primals
g, = tangents
return (f(x), 3 * g)
f.defjvp(f_jvp)
def f2(x):
y, _ = api.jvp(f, (x,), (x,))
return y
def f3(x):
y, _ = api.jvp(f2, (x,), (x,))
return y
x = 1.
self.assertAllClose(api.jvp(f, (x,), (x,)),
api.jvp(f2, (x,), (x,)),
check_dtypes=False)
self.assertAllClose(api.jvp(f, (x,), (x,)),
api.jvp(f3, (x,), (x,)),
check_dtypes=False)
def test_python_control_flow(self):
@api.custom_jvp
def f(x):
if x > 0:
return jnp.sin(x)
else:
return jnp.cos(x)
def f_jvp(primals, tangents):
x, = primals
g, = tangents
if x > 0:
return f(x), 2 * g
else:
return f(x), 3 * g
f.defjvp(f_jvp)
x = 2.
self.assertAllClose(f(x), jnp.sin(x))
self.assertAllClose(f(-x), jnp.cos(-x))
self.assertAllClose(api.jvp(f, (x,), (1.,)),
(jnp.sin(x), 2.),
check_dtypes=False)
self.assertAllClose(api.jvp(f, (-x,), (1.,)),
(jnp.cos(-x), 3.),
check_dtypes=False)
self.assertAllClose(api.grad(f)(x), 2., check_dtypes=False)
self.assertAllClose(api.grad(f)(-x), 3., check_dtypes=False)
def test_vmap(self):
@api.custom_jvp
def f(x):
assert jnp.ndim(x) == 0
return jnp.sin(x)
def f_jvp(primals, tangents):
x, = primals
g, = tangents
assert jnp.ndim(x) == jnp.ndim(g) == 0
return f(x), 2 * jnp.cos(x) * g
f.defjvp(f_jvp)
x = jnp.arange(3.)
xx = jnp.arange(6.).reshape(2, 3)
# vmap of f
self.assertAllClose(api.vmap(f)(x), jnp.sin(x))
self.assertAllClose(api.vmap(api.vmap(f))(xx), jnp.sin(xx))
# vmap of jvp of f
self.assertAllClose(api.vmap(lambda x: api.jvp(f, (x,), (x,)))(x),
(jnp.sin(x), 2 * jnp.cos(x) * x))
self.assertAllClose(api.vmap(api.vmap(lambda x: api.jvp(f, (x,), (x,))))(xx),
(jnp.sin(xx), 2 * jnp.cos(xx) * xx))
# jvp of vmap of f
self.assertAllClose(api.jvp(api.vmap(f), (x,), (x,)),
(jnp.sin(x), 2 * jnp.cos(x) * x))
self.assertAllClose(api.jvp(api.vmap(api.vmap(f)), (xx,), (xx,)),
(jnp.sin(xx), 2 * jnp.cos(xx) * xx))
# vmap of jvp of vmap of f
self.assertAllClose(api.vmap(lambda x: api.jvp(api.vmap(f), (x,), (x,)))(xx),
(jnp.sin(xx), 2 * jnp.cos(xx) * xx))
def test_jit(self):
@api.custom_jvp
def f(x):
return jnp.sin(x)
def f_jvp(primals, tangents):
x, = primals
g, = tangents
return f(x), 2 * jnp.cos(x) * g
f.defjvp(f_jvp)
x = 3.
# jit
self.assertAllClose(api.jit(f)(x), jnp.sin(x))
self.assertAllClose(api.jit(api.jit(f))(x), jnp.sin(x))
# jit of jvp
self.assertAllClose(api.jit(lambda x: api.jvp(f, (x,), (x,)))(x),
(jnp.sin(x), 2 * jnp.cos(x) * x),
check_dtypes=False)
# jvp of jit
self.assertAllClose(api.jvp(api.jit(f), (x,), (x,)),
(jnp.sin(x), 2 * jnp.cos(x) * x),
check_dtypes=False)
def test_pytrees(self):
@api.custom_jvp
def f(x):
return {'b': jnp.sin(x['a'])}
def f_jvp(primals, tangents):
x, = primals
g, = tangents
return f(x), {'b': 2 * jnp.cos(x['a']) * g['a']}
f.defjvp(f_jvp)
x = {'a': 3.}
self.assertAllClose(f(x)['b'], jnp.sin(x['a']))
self.assertAllClose(api.jvp(f, (x,), (x,)),
({'b': jnp.sin(x['a'])},
{'b': 2 * jnp.cos(x['a']) * x['a']}),
check_dtypes=False)
def test_kwargs(self):
# from https://github.com/google/jax/issues/1938
@api.custom_jvp
def my_fun(x, y, c=1.):
return c * (x + y)
def my_jvp(primals, tangents):
x, y, c = primals
t_x, t_y, t_c = tangents
return my_fun(x, y, c), t_c
my_fun.defjvp(my_jvp)
f = lambda x, y: jnp.square(my_fun(x, y, c=2.)).sum()
f(10., 5.) # doesn't crash
api.jvp(f, (10., 5.), (1., 1.)) # doesn't crash
def test_initial_style(self):
@api.custom_jvp
def f(x):
return 3 * x
def f_jvp(primals, tangents):
x, = primals
g, = tangents
return f(x), 2 * g
f.defjvp(f_jvp)
def foo(x):
out, _ = lax.scan(lambda c, _: (f(c), None), x, None, length=1)
return out
ans = api.grad(foo)(3.)
expected = 2.
self.assertAllClose(ans, expected, check_dtypes=False)
ans = api.grad(api.jit(foo))(3.)
expected = 2.
self.assertAllClose(ans, expected, check_dtypes=False)
ans = api.jit(api.grad(foo))(3.)
expected = 2.
self.assertAllClose(ans, expected, check_dtypes=False)
ans = api.grad(api.grad(foo))(3.)
expected = 0.
self.assertAllClose(ans, expected, check_dtypes=False)
ans = api.grad(api.grad(api.jit(foo)))(3.)
expected = 0.
self.assertAllClose(ans, expected, check_dtypes=False)
ans = api.grad(api.jit(api.grad(foo)))(3.)
expected = 0.
self.assertAllClose(ans, expected, check_dtypes=False)
ans = api.jit(api.grad(api.grad(foo)))(3.)
expected = 0.
self.assertAllClose(ans, expected, check_dtypes=False)
def test_initial_style_vmap(self):
@api.custom_jvp
def f(x):
assert jnp.ndim(x) == 0
return 3 * x
def f_jvp(primals, tangents):
x, = primals
g, = tangents
return f(x), 2 * g
f.defjvp(f_jvp)
def foo(x):
out, _ = lax.scan(lambda c, _: (f(c), None), x, None, length=1)
return out
ans = api.vmap(foo)(jnp.ones(3))
expected = 3. * jnp.ones(3)
self.assertAllClose(ans, expected, check_dtypes=False)
ans = api.vmap(api.jit(foo))(jnp.ones(3))
expected = 3. * jnp.ones(3)
self.assertAllClose(ans, expected, check_dtypes=False)
ans = api.jit(api.vmap(foo))(jnp.ones(3))
expected = 3. * jnp.ones(3)
self.assertAllClose(ans, expected, check_dtypes=False)
ans = api.grad(lambda x: api.vmap(foo)(x).sum())(jnp.ones(3))
expected = 2. * jnp.ones(3)
self.assertAllClose(ans, expected, check_dtypes=False)
ans = api.grad(lambda x: api.vmap(api.jit(foo))(x).sum())(jnp.ones(3))
expected = 2. * jnp.ones(3)
self.assertAllClose(ans, expected, check_dtypes=False)
ans = api.grad(lambda x: api.jit(api.vmap(foo))(x).sum())(jnp.ones(3))
expected = 2. * jnp.ones(3)
self.assertAllClose(ans, expected, check_dtypes=False)
ans = api.grad(api.jit(lambda x: api.vmap(foo)(x).sum()))(jnp.ones(3))
expected = 2. * jnp.ones(3)
self.assertAllClose(ans, expected, check_dtypes=False)
ans = api.jit(api.grad(lambda x: api.vmap(foo)(x).sum()))(jnp.ones(3))
expected = 2. * jnp.ones(3)
self.assertAllClose(ans, expected, check_dtypes=False)
def test_initial_style_vmap_with_collective(self):
@api.custom_jvp
def f(x):
return lax.psum(x, 'foo')
@f.defjvp
def f_jvp(xs, ts):
x, = xs
t, = ts
return lax.psum(x, 'foo'), t
def g(x):
jaxpr = api.make_jaxpr(f)(x)
return core.eval_jaxpr(jaxpr.jaxpr, [], x)[0]
v = api.vmap(lambda _, x: g(x), axis_name='foo', in_axes=(0, None),
out_axes=None)(jnp.arange(4.), 2.)
self.assertAllClose(v, 8.)
def test_closed_over_tracers_error_message(self):
def f(x):
@api.custom_jvp
def g(y):
return x + y
def g_jvp(primals, tangents):
return g(x), 2 * primals[0]
g.defjvp(g_jvp)
return g(1.)
self.assertRaises(ad.CustomJVPException, lambda: api.jvp(f, (3.,), (1.,)))
self.assertRaises(ad.CustomJVPException, lambda: api.grad(f)(3.))
def test_nondiff_arg(self):
@partial(api.custom_jvp, nondiff_argnums=(0,))
def app(f, x):
return f(x)
def app_jvp(f, primals, tangents):
(x,), (t,) = primals, tangents
return app(f, x), 3 * t
app.defjvp(app_jvp)
ans = app(lambda x: 2 * x, 1)
expected = 2
self.assertAllClose(ans, expected, check_dtypes=False)
ans = api.jvp(lambda x: app(lambda y: 2 * y, x), (1.,), (1.,))
expected = (2., 3.)
self.assertAllClose(ans, expected, check_dtypes=False)
def test_nondiff_arg_jit_tracer(self):
@partial(api.custom_jvp, nondiff_argnums=(0,))
def f(x, y):
return x * y
def f_jvp(x, primals, tangents):
(y,), (t_y,) = primals, tangents
return f(x, y), 5 * t_y
f.defjvp(f_jvp)
@jit
def g(x, y):
return f(x, y)
ans = api.jvp(lambda y: g(2., y), (3.,), (1.,))
expected = (6., 5.)
self.assertAllClose(ans, expected, check_dtypes=False)
def test_nondiff_arg_hiding_jvp_tracer(self):
def f(x):
@partial(api.custom_jvp, nondiff_argnums=(0,))
def g(h, x):
return h(x)
@g.defjvp
def g_jvp(h, primals, tangents):
x, = primals
t, = tangents
return g(h, x), 2. * t
h = lambda y: x + y # capture x
return g(h, x)
with self.assertRaisesRegex(ad.CustomJVPException, "Detected differentiation"):
api.jvp(f, (2.,), (1.,))
def test_vmap_axes(self):
raise unittest.SkipTest("TODO") # TODO(mattjj): write test
def test_pmap(self):
raise unittest.SkipTest("TODO") # TODO(mattjj): write test
def test_missing_jvp_rule_error_message(self):
@api.custom_jvp
def foo(x):
return x ** 2
self.assertRaisesRegex(
AttributeError,
r"No JVP defined for custom_jvp function foo using defjvp.",
lambda: foo(2))
self.assertRaisesRegex(
AttributeError,
r"No JVP defined for custom_jvp function foo using defjvp.",
lambda: api.jvp(foo, (2.,), (1.,)))
self.assertRaisesRegex(
AttributeError,
r"No JVP defined for custom_jvp function foo using defjvp.",
lambda: api.grad(foo)(2.))
def test_jvp_rule_inconsistent_pytree_structures_error_message(self):
@api.custom_jvp
def f(x):
return (x**2,)
@f.defjvp
def foo_jvp(primals, tangents):
x, = primals
t, = tangents
return f(x), [2 * x * t, x]
f(2.) # doesn't crash
self.assertRaisesRegex(
TypeError,
re.escape(
"Custom JVP rule foo_jvp for function f "
"must produce primal and tangent outputs "
"with equal container (pytree) structures, but got "
"{} and {} respectively.".format(
tree_util.tree_structure((1,)),
tree_util.tree_structure([1, 2]))
),
lambda: api.jvp(f, (2.,), (1.,)))
def test_primal_tangent_aval_disagreement_error_message(self):
@api.custom_jvp
def f(x):
return x ** 2
@f.defjvp
def foo_jvp(primals, tangents):
x, = primals
t, = tangents
return f(x), jnp.reshape(t, (1,))
f(2.) # doesn't crash
self.assertRaisesRegex(
TypeError,
re.escape(
"Custom JVP rule must produce primal and tangent outputs "
"with equal shapes and dtypes, but got float32[] and float32[1] "
"respectively."),
lambda: api.jvp(f, (jnp.float32(2.),), (jnp.float32(1.),)))
def test_jvp_rule_doesnt_return_pair_error_message(self):
# https://github.com/google/jax/issues/2516
@api.custom_jvp
def f(x):
return x ** 2
@f.defjvp
def foo_jvp(primals, tangents):
x, = primals
t, = tangents
return t
f(2.) # doesn't crash
self.assertRaisesRegex(
TypeError,
re.escape(
"Custom JVP rule foo_jvp for function f "
"must produce a pair (list or tuple of length two) "
"representing primal and tangent outputs, but got 1.0"),
lambda: api.jvp(f, (2.,), (1.,)))
def test_jvp_rule_primal_out_type_doesnt_match_primal_error_message(self):
# https://github.com/lucidrains/flash-attention-jax/issues/7
def scan_apply(f, x):
y, _ = jax.lax.scan(lambda x, _: (f(x), None), x, None, length=1)
return y
@jax.custom_jvp
def f(x):
return x
@f.defjvp
def f_jvp(primals, tangents):
(x,), (xdot,) = primals, tangents
return (x, x), (xdot, xdot)
x = jnp.float32(1.)
self.assertRaisesRegex(
TypeError,
re.escape(
"Custom JVP rule f_jvp for function f must produce a pair "
"(list or tuple of length two) where the first element represents "
"the primal output (equal in value to the output of the "
"custom_jvp-decorated function f, and in particular of the "
"same container/pytree structure), but instead the JVP rule "
"output's first element had container/pytree structure:\n"
" (float32[], float32[])\n"
"while the custom_jvp-decorated function f had output "
"container/pytree structure:\n"
" float32[]."
),
lambda: jax.jvp(lambda x: scan_apply(f, x), (x,), (x,)))
@f.defjvp
def f_jvp2(primals, tangents):
(x,), (xdot,) = primals, tangents
return jnp.zeros((3, *x.shape), x.dtype), xdot
self.assertRaisesRegex(
TypeError,
re.escape(
"Custom JVP rule f_jvp2 for function f must produce a pair "
"(list or tuple of length two) where the first element represents "
"the primal output (equal in value to the output of the "
"custom_jvp-decorated function f, and in particular "
"with leaves of the same shape/dtype), but instead the JVP rule "
"output's first element had shapes/dtypes of:\n"
" float32[3]\n"
"while the custom_jvp-decorated function f had output shapes/dtypes"
" of:\n"
" float32[]"
),
lambda: jax.jvp(lambda x: scan_apply(f, x), (x,), (x,)))
def test_multiple_rule_invocations(self):
@jax.custom_jvp
def expit(x):
return 1 / (1 + lax.exp(-x))
@expit.defjvp
def _expit_jvp(primals, tangents):
(x,), (t,) = primals, tangents
ans = expit(x)
t_out = t * ans * (1 - ans)
return ans, t_out
def scanned_fun(c, _):
return [expit(c[0])] + [c[i-1] + c[i] for i in range(1, len(c))], None
def foo(x):
c, _ = lax.scan(scanned_fun, [x, 0., 0., 0., 0.], None, length=10)
return c[-1]
# just make sure these don't crash
foo(3.)
grad(foo)(3.)
grad(lambda x: jax.vmap(foo)(x).sum())(jnp.arange(3.))
def test_hard_stuff(self):
arr = jnp.ones((5, 2, 2))
api.jit(jax.vmap(jnp.linalg.det))(arr) # doesn't crash
def test_hard_stuff2(self):
@jax.custom_jvp
def f(x):
return lax.tie_in(x, np.zeros(x.shape, x.dtype))
@f.defjvp
def f_jvp(primals, tangents):
x, = primals
t, = tangents
return f(x), t
# don't crash
jax.jit(jax.vmap(f))(jnp.arange(3.))
jax.jit(jax.vmap(jax.grad(f)))(jnp.arange(3.))
jax.jit(jax.grad(lambda x: jax.vmap(f)(x).sum()))(jnp.arange(3.))
jax.grad(lambda x: jax.vmap(f)(x).sum())(jnp.arange(3.))
jax.jvp(jax.vmap(f), (jnp.arange(3.),), (jnp.ones(3),))
def test_hard_stuff3(self):
@jax.custom_jvp
def relu(x):
return jnp.maximum(x, 0)
@relu.defjvp
def _relu_jvp(primals, tangents):
x, = primals
t, = tangents
return relu(x), lax.select(x > 0, t, lax.full_like(t, 0))
def scanned_fun(c, _):
return [relu(c[0])] + [c[i-1] + c[i] for i in range(1, len(c))], None
def f(x):
c, _ = lax.scan(scanned_fun, [x, 0., 0., 0., 0.], None, length=10)
return c[-1]
# don't crash
jax.jit(jax.vmap(f))(jnp.arange(3.))
jax.jit(jax.vmap(jax.grad(f)))(jnp.arange(3.))
jax.jit(jax.grad(lambda x: jax.vmap(f)(x).sum()))(jnp.arange(3.))
jax.grad(lambda x: jax.vmap(f)(x).sum())(jnp.arange(3.))
jax.jvp(jax.jit(jax.vmap(f)), (jnp.arange(3.),), (jnp.ones(3),))
def test_eval_shape(self):
@jax.custom_jvp
def expit(x):
return 1 / (1 + lax.exp(-x))
@expit.defjvp
def _expit_jvp(primals, tangents):
(x,), (t,) = primals, tangents
ans = expit(x)
t_out = t * ans * (1 - ans)
return ans, t_out
# don't crash
api.eval_shape(expit, jnp.ones((2, 3)))
api.eval_shape(api.grad(lambda x: expit(x).sum()), jnp.ones((2, 3)))
def test_jaxpr_zeros(self):
# from https://github.com/google/jax/issues/2657
@api.custom_jvp
def f(A, b):
return A @ b
def f_jvp(primals, tangents):
A, b = primals
dA, db = tangents
z = f(A, b)
dz = A @ db + dA @ b
return z, dz
f.defjvp(f_jvp)
def experiment(theta):
def step(q, _):
z = f(jnp.eye(3), jnp.ones(3) * theta)
q += z[0]
return q, q
q = 0.
q, _ = lax.scan(step, q, None, 4)
return q
grad(experiment)(1.) # doesn't crash
def test_linear_in_scan(self):
@api.custom_jvp
def f(x):
return -x
@f.defjvp
def f_jvp(primals, tangents):
x, = primals
x_dot, = tangents
return f(x), f(x_dot)
def foo(x):
out, _ = lax.scan(lambda c, _: (f(c), None), x, None, length=1)
return out
ans = api.grad(foo)(3.)
expected = -1.
self.assertAllClose(ans, expected, check_dtypes=False)
def test_custom_jvps_first_rule_is_none(self):
# https://github.com/google/jax/issues/3389
@api.custom_jvp
def f(x, y):
return x ** 2 * y
f.defjvps(None, lambda x_dot, primal_out, x, y: 2 * x * y * x_dot)
ans = grad(f, 1)(2., 3.) # doesn't crash
expected = 12.
self.assertAllClose(ans, expected, check_dtypes=False)
def test_concurrent_initial_style(self):
# https://github.com/google/jax/issues/3843
def unroll(param, sequence):
def scan_f(prev_state, inputs):
return prev_state, jax.nn.sigmoid(param * inputs)
return jnp.sum(jax.lax.scan(scan_f, None, sequence)[1])
def run():
return jax.grad(unroll)(jnp.array(1.0), jnp.array([1.0]))
expected = run()
# we just don't want this to crash
n_workers = 2
with concurrent.futures.ThreadPoolExecutor(max_workers=n_workers) as e:
futures = []
for _ in range(n_workers):
futures.append(e.submit(run))
results = [f.result() for f in futures]
for ans in results:
self.assertAllClose(ans, expected)
def test_nondiff_argnums_vmap_tracer(self):
# https://github.com/google/jax/issues/3964
@partial(jax.custom_jvp, nondiff_argnums=(0, 2))
def sample(shape, param, seed):
return jax.random.uniform(key=seed, shape=shape, minval=param)
@sample.defjvp
def sample_jvp(shape, seed, primals, tangents):
param, = primals
dparam, = tangents
dparam = jnp.broadcast_to(dparam, shape)
samples = sample(shape, param, seed)
return samples, samples * dparam # dummy jvp for proof of concept
# check these don't crash
jax.vmap(lambda seed: sample((2,3), 1., seed))(
jax.random.split(jax.random.PRNGKey(1), 10))
jax.jvp(lambda x: sample((2, 3), x, jax.random.PRNGKey(1)),
(1.,), (1.,))
def test_fun_with_nested_calls_2(self):
def call(f, *args):
f = api.custom_jvp(f)
f.defjvp(lambda primals, tangents: (f(*primals), sum(tangents)))
return f(*args)
def fun_with_nested_calls_2(x):
def bar(y):
def baz(w):
q = call(lambda x: y, x)
q = q + call(lambda: y)
q = q + call(lambda y: w + y, y)
q = call(lambda w: call(jnp.sin, x) * y, 1.0) + q
return q
return api.jit(baz)(x)
return call(bar, x)
# test these don't crash
self.assertAllClose(api.jit(fun_with_nested_calls_2)(3.),
fun_with_nested_calls_2(3.))
api.vmap(fun_with_nested_calls_2)(jnp.arange(3.))
def test_closure_with_vmap(self):
# https://github.com/google/jax/issues/3822
alpha = np.float32(2.)
def sample(seed):
@api.custom_jvp
def f(alpha):
return jax.random.gamma(seed, alpha, shape=[])
@f.defjvp
def f_jvp(primal, tangent):
alpha = primal
dalpha = tangent
sample = f(alpha)
partial_alpha = lax.random_gamma_grad(alpha, sample)
return sample, partial_alpha * dalpha
return f(alpha)
api.vmap(sample)(jax.random.split(jax.random.PRNGKey(1), 3)) # don't crash
def test_closure_with_vmap2(self):
# https://github.com/google/jax/issues/8783
def h(z):
def f(x):
@jax.custom_jvp
def g(y):
return x * y
# NOTE: rule closes over vmap tracer
@g.defjvp
def g_jvp(primals, tangents):
(y,), (ydot,) = primals, tangents
return x * y, x * ydot
return g(z) # NOTE: no vmapped arg
return jax.vmap(f)(jnp.arange(3., dtype='float32'))
primals, tangents = jax.jvp(h, (jnp.float32(1.),), (jnp.float32(2.),))
self.assertAllClose(primals , jnp.arange(3., dtype='float32'))
self.assertAllClose(tangents, 2 * jnp.arange(3., dtype='float32'))
@unittest.skipIf(numpy_version == (1, 21, 0),
"https://github.com/numpy/numpy/issues/19305")
def test_float0(self):
@api.custom_jvp
def f(x, y):
return x, y
def f_jvp(primals, _):
# we need a defined (non-float0) tangent to trigger the rule
return primals, (2., 1)
f.defjvp(f_jvp)
primals = (2., 3)
tangents = (np.ones(()), np.zeros((), float0),)
expected_tangents = (2., np.zeros((), float0))
self.assertArraysEqual(api.jvp(f, primals, tangents),
(primals, expected_tangents))
@unittest.skipIf(numpy_version == (1, 21, 0),
"https://github.com/numpy/numpy/issues/19305")
def test_float0_initial_style(self):
@api.custom_jvp
def f(x, y):
return x, y
def f_jvp(primals, _):
x, y = primals
return (x, y), (2., 1)
f.defjvp(f_jvp)
def foo(x, y):
out, _ = lax.scan(lambda c, _: (f(*c), None), (x, y), None, length=1)
return out
primals = (2., 3)
tangents = (np.ones(()), np.zeros((), float0),)
expected_tangents = (2., np.zeros((), float0))
self.assertArraysEqual(api.jvp(foo, primals, tangents),
(primals, expected_tangents))
def test_remat(self):
@api.custom_jvp
def f(x):
return jnp.sin(x)
def f_jvp(primals, tangents):
x, = primals
g, = tangents
return f(x), 2 * jnp.cos(x) * g
f.defjvp(f_jvp)
@api.remat
def g(x):
return f(f(x))
ans = g(2.)
expected = np.sin(np.sin(2.))
self.assertAllClose(ans, expected, check_dtypes=False)
ans = api.grad(g)(2.)
expected = 4. * api.grad(lambda x: jnp.sin(jnp.sin(x)))(2.)
self.assertAllClose(ans, expected, check_dtypes=False)
def test_remat_higher_order(self):
@api.custom_jvp
def f(x):
return jnp.sin(x)
def f_jvp(primals, tangents):
x, = primals
g, = tangents
return f(x), 2 * jnp.cos(x) * g
f.defjvp(f_jvp)
def g(x):
return f(f(x))
ans = api.grad(api.grad(new_checkpoint(g)))(2.)
expected = api.grad(api.grad(g))(2.)
self.assertAllClose(ans, expected, check_dtypes=False)
ans = api.grad(new_checkpoint(api.grad(g)))(2.)
expected = api.grad(api.grad(g))(2.)
self.assertAllClose(ans, expected, check_dtypes=False)
ans = api.grad(api.grad(api.grad(new_checkpoint(g))))(2.)
expected = api.grad(api.grad(api.grad(g)))(2.)
self.assertAllClose(ans, expected, check_dtypes=False)
def test_initial_style_vmap_2(self):
# This is like test_initial_style_vmap except the primal function closes
# over an array constant.
y = jnp.array([1., 2., 3.])
@api.custom_jvp
def f(x):
assert jnp.ndim(x) == 0
return 3 * x * jnp.sum(y)
def f_jvp(primals, tangents):
x, = primals
g, = tangents
return f(x), 2 * g
f.defjvp(f_jvp)
def foo(x):
out, _ = lax.scan(lambda c, _: (f(c), None), x, None, length=1)
return out
ans = api.grad(lambda x: api.vmap(foo)(x).sum())(jnp.ones(3))
expected = 2. * jnp.ones(3)
self.assertAllClose(ans, expected, check_dtypes=False)
ans = api.grad(lambda x: api.vmap(api.jit(foo))(x).sum())(jnp.ones(3))
expected = 2. * jnp.ones(3)
self.assertAllClose(ans, expected, check_dtypes=False)
ans = api.grad(lambda x: api.jit(api.vmap(foo))(x).sum())(jnp.ones(3))
expected = 2. * jnp.ones(3)
self.assertAllClose(ans, expected, check_dtypes=False)
ans = api.grad(api.jit(lambda x: api.vmap(foo)(x).sum()))(jnp.ones(3))
expected = 2. * jnp.ones(3)
self.assertAllClose(ans, expected, check_dtypes=False)
ans = api.jit(api.grad(lambda x: api.vmap(foo)(x).sum()))(jnp.ones(3))
expected = 2. * jnp.ones(3)
self.assertAllClose(ans, expected, check_dtypes=False)
def test_custom_jvp_vmap_broadcasting_interaction(self):
# https://github.com/google/jax/issues/6452
def f2(y, z):
v1 = z
v2 = jnp.sum(y) + z
return jnp.logaddexp(v1, v2)
def f1(y, z):
v = api.vmap(lambda _y: f2(_y, z))(y)
return jnp.sum(v)
y = jnp.ones((3, 2))
f = lambda z: f1(y, z)
z = 0.1
val, g = api.value_and_grad(f)(z)
self.assertEqual(val.shape, ())
self.assertEqual(g.shape, ())
def test_custom_jvp_vmap_broadcasting_interaction_2(self):
# https://github.com/google/jax/issues/5849
@api.custom_jvp
def transform(box, R):
if jnp.isscalar(box) or box.size == 1:
return R * box
elif box.ndim == 2:
return jnp.einsum('ij,j->i', box, R)
raise ValueError()
@transform.defjvp
def transform_jvp(primals, tangents):
box, R = primals
dbox, dR = tangents
return (transform(box, R), dR + transform(dbox, R))
def periodic_general(box):
def displacement_fn(Ra, Rb, **kwargs):
_box = kwargs.get('box', box)
return transform(_box, Ra - Rb)
return displacement_fn
N = 250
scalar_box = 1.0
displacement = periodic_general(scalar_box)
key = jax.random.PRNGKey(0)
R = jax.random.uniform(key, (N, 2))
def energy_fn(box):
d = partial(displacement, box=box)
d = api.vmap(api.vmap(d, (None, 0)), (0, None))
return jnp.sum(d(R, R) ** 2)
self.assertEqual(grad(energy_fn)(scalar_box).shape, ())
def test_custom_jvp_implicit_broadcasting(self):
# https://github.com/google/jax/issues/6357
if config.x64_enabled:
raise unittest.SkipTest("test only applies when x64 is disabled")
@jax.custom_jvp
def projection_unit_simplex(x: jnp.ndarray) -> jnp.ndarray:
"""Projection onto the unit simplex."""
s = 1.0
n_features = x.shape[0]
u = jnp.sort(x)[::-1]
cssv = jnp.cumsum(u) - s
ind = jnp.arange(n_features, dtype=x.dtype) + 1
cond = u - cssv / ind > 0
idx = jnp.count_nonzero(cond)
threshold = cssv[idx - 1] / idx.astype(x.dtype)
return jax.nn.relu(x - threshold)
@projection_unit_simplex.defjvp
def projection_unit_simplex_jvp(primals, tangents):
x, = primals
x_dot, = tangents
primal_out = projection_unit_simplex(x)
supp = (primal_out > 0).astype(x_dot.dtype)
card = jnp.count_nonzero(supp).astype(x_dot.dtype)
tangent_out = supp * x_dot - (jnp.dot(supp, x_dot) / card) * supp
return primal_out, tangent_out
rng = self.rng()
x = rng.rand(5).astype(np.float32)
J_rev = jax.jacrev(projection_unit_simplex)(x)
J_fwd = jax.jacfwd(projection_unit_simplex)(x)
p = projection_unit_simplex(x)
support = (p > 0).astype(jnp.float32)
cardinality = jnp.count_nonzero(support).astype(support.dtype)
J_true = jnp.diag(support) - jnp.outer(support, support) / cardinality
self.assertAllClose(J_true, J_fwd)
self.assertAllClose(J_true, J_rev)
proj = jax.vmap(projection_unit_simplex)
def fun(X):
return jnp.sum(proj(X) ** 2)
rng = self.rng()
X = rng.rand(4, 5).astype(np.float32)
U = rng.rand(4, 5)
U /= np.sqrt(np.sum(U ** 2))
U = U.astype(np.float32)
eps = 1e-3
dir_deriv_num = (fun(X + eps * U) - fun(X - eps * U)) / (2 * eps)
dir_deriv = jnp.vdot(jax.grad(fun)(X), U)
self.assertAllClose(dir_deriv, dir_deriv_num, atol=1e-3)
def test_vmap_inside_defjvp(self):
# https://github.com/google/jax/issues/3201
seed = 47
key = jax.random.PRNGKey(seed)
mat = jax.random.normal(key, (2, 3))
@jax.custom_jvp
def f(mat, aux):
num_rows, num_cols = mat.shape
return jnp.ones((num_rows, 1)) / num_cols
@f.defjvp
def f_jvp(primals, tangents):
mat, aux = primals
vec, _ = tangents
output = f(*primals)
num_rows, num_cols = mat.shape
size = num_rows * num_cols
# -----
bd_mat = mat.reshape(1, 1, num_rows, num_cols)
bd_mat = jnp.tile(bd_mat, reps=(num_rows, num_cols))
bd_mat = bd_mat.reshape(size, num_rows, num_cols)
# -----
rowsum = jnp.sum(mat, axis=1, keepdims=True)
colsum = jnp.sum(mat, axis=0, keepdims=True)
bd_rowsum = jnp.tile(rowsum, reps=(1, num_rows))
bd_colsum = jnp.tile(colsum, reps=(num_cols, 1))
# -----
bd_vec = vec.reshape(size, 1)
# -----
def operate(mx, val):
buf = 0
for i in range(2):
buf = buf + jnp.matmul(mx, bd_colsum) / jnp.power(aux, i)
buf = jnp.matmul(bd_rowsum, buf)
return buf * val[None, :]
# -----
# Vertorizing will raise shape error
bd_buf = jax.vmap(operate, in_axes=(0, 0), out_axes=0)(bd_mat, bd_vec)
# -----
bd_buf = bd_buf / aux
jvp = jnp.sum(bd_buf, axis=0)
jvp = jnp.mean(jvp, axis=1, keepdims=True)
# -----
# JVP ends successfully, but still raise an error
return (output, jvp)
jax.grad(lambda mat, aux: jnp.sum(f(mat, aux)))(mat, 0.5) # doesn't crash
def test_custom_jvp_unbroadcasting(self):
# https://github.com/google/jax/issues/3056
a = jnp.array([1., 1.])
@jax.custom_jvp
def f(x):
return a * x
@f.defjvp
def f_jvp(primals, tangents):
x, = primals
dx, = tangents
return a * x, a * dx
shape = grad(lambda x: jnp.sum(f(x)))(jnp.array(1.)).shape
self.assertEqual(shape, ())
def test_maybe_perturbed_internal_helper_function(self):
# This is a unit test for an internal API. We include it so as not to
# regress https://github.com/google/jax/issues/9567. For an explanation of
# this helper function, see https://github.com/google/jax/issues/6415.
def f(x):
def g(y, _):
z = y * x
self.assertTrue(custom_derivatives._maybe_perturbed(z))
return y, None
g(1, None)
return lax.scan(g, 1, xs=None, length=1)[0]
jax.jvp(f, (1.0,), (1.0,)) # assertions inside f
def test_maybe_perturbed_int_regression(self):
# see https://github.com/google/jax/discussions/9951
@jax.jit
def f():
x = jnp.array(1)
_, aux_args = custom_derivatives.closure_convert(lambda: x)
self.assertEmpty(aux_args)
f()
def test_sinc_constant_function_batching(self):
# https://github.com/google/jax/pull/10756
batch_data = jnp.arange(15.).reshape(5, 3)
@jax.vmap
def f(x):
return jax.lax.map(jnp.sinc, x)
g = lambda param: f(param * batch_data).sum()
@jax.vmap
def f_ref(x):
return jnp.stack([jnp.sinc(x_) for x_ in x])
g_ref = lambda param: f_ref(param * batch_data).sum()
grad = jax.grad(g )(0.1) # doesn't crash
grad_ref = jax.grad(g_ref)(0.1)
self.assertAllClose(grad, grad_ref, check_dtypes=False)
class CustomVJPTest(jtu.JaxTestCase):
def test_basic(self):
@api.custom_vjp
def f(x):
return jnp.sin(x)
def f_fwd(x):
return f(x), jnp.cos(x)
def f_rev(cos_x, g):
return (2 * cos_x * g,)
f.defvjp(f_fwd, f_rev)
x = 3.
self.assertAllClose(f(x), jnp.sin(x))
self.assertAllClose(api.grad(f)(x), 2 * jnp.cos(x))
self.assertAllClose(api.value_and_grad(f)(x),
(jnp.sin(x), 2 * jnp.cos(x)))
def test_invariance(self):
@api.custom_vjp
def f(x):
return jnp.cos(2 * x) / 2.
def f_fwd(x):
return (f(x), x)
def f_rev(x, g):
return (g * 3,)
f.defvjp(f_fwd, f_rev)
def f2(x):
y, _ = api.value_and_grad(f)(x)
return y
def f3(x):
y, _ = api.value_and_grad(f2)(x)
return y
x = 1.
self.assertAllClose(f(x), f2(x), check_dtypes=False)
self.assertAllClose(f(x), f3(x), check_dtypes=False)
self.assertAllClose(api.grad(f)(x), api.grad(f2)(x),
check_dtypes=False)
self.assertAllClose(api.grad(f)(x), api.grad(f3)(x),
check_dtypes=False)
def test_python_control_flow(self):
@api.custom_vjp
def f(x):
if x > 0:
return jnp.sin(x)
else:
return jnp.cos(x)
def f_fwd(x):
if x > 0:
return f(x), x
else:
return f(x), x
def f_rev(x, g):
if x > 0:
return (2 * g,)
else:
return (3 * g,)
f.defvjp(f_fwd, f_rev)
x = 2.
self.assertAllClose(f(x), jnp.sin(x))
self.assertAllClose(f(-x), jnp.cos(-x))
self.assertAllClose(api.value_and_grad(f)(x), (jnp.sin(x), 2.),
check_dtypes=False)
self.assertAllClose(api.value_and_grad(f)(-x), (jnp.cos(-x), 3.),
check_dtypes=False)
def test_vmap(self):
@api.custom_vjp
def f(x):
assert jnp.ndim(x) == 0
return jnp.sin(x)
def f_fwd(x):
assert jnp.ndim(x) == 0
return f(x), jnp.cos(x)
def f_rev(cos_x, g):
return (2 * cos_x * g,)
f.defvjp(f_fwd, f_rev)
x = jnp.arange(3.)
xx = jnp.arange(6.).reshape(2, 3)
# vmap of f
self.assertAllClose(api.vmap(f)(x), jnp.sin(x))
self.assertAllClose(api.vmap(api.vmap(f))(xx), jnp.sin(xx))
# vmap of grad of f
self.assertAllClose(api.vmap(api.grad(f))(x), 2 * jnp.cos(x))
self.assertAllClose(api.vmap(api.value_and_grad(f))(x),
(jnp.sin(x), 2 * jnp.cos(x)))
self.assertAllClose(api.vmap(api.vmap(api.grad(f)))(xx), 2 * jnp.cos(xx))
self.assertAllClose(api.vmap(api.vmap(api.value_and_grad(f)))(xx),
(jnp.sin(xx), 2 * jnp.cos(xx)))
# grad of vmap of f
self.assertAllClose(api.grad(lambda x: api.vmap(f)(x).sum())(x),
2 * jnp.cos(x))
self.assertAllClose(api.grad(lambda x: api.vmap(api.vmap(f))(x).sum())(xx),
2 * jnp.cos(xx))
# vmap of grad of vmap of f
self.assertAllClose(api.vmap(api.grad(lambda x: api.vmap(f)(x).sum()))(xx),
2 * jnp.cos(xx))
def test_jit(self):
@api.custom_vjp
def f(x):
return jnp.sin(x)
def f_fwd(x):
return f(x), jnp.cos(x)
def f_rev(cos_x, g):
return (2 * cos_x * g,)
f.defvjp(f_fwd, f_rev)
x = 3.
# jit
self.assertAllClose(api.jit(f)(x), jnp.sin(x))
self.assertAllClose(api.jit(api.jit(f))(x), jnp.sin(x))
# jit of grad
self.assertAllClose(api.jit(api.grad(f))(x), 2 * jnp.cos(x),
check_dtypes=False)
# grad of jit
self.assertAllClose(api.grad(api.jit(f))(x), 2 * jnp.cos(x),
check_dtypes=False)
def test_pytrees(self):
@api.custom_vjp
def f(x):
return {'b': jnp.sin(x['a'])}
def f_fwd(x):
return f(x), {'r': jnp.cos(x['a'])}
def f_bwd(res, g):
cos_x = res['r']
return ({'a': 2 * cos_x * g['b']},)
f.defvjp(f_fwd, f_bwd)
x = {'a': 3.}
self.assertAllClose(f(x)['b'], jnp.sin(x['a']))
self.assertAllClose(api.grad(lambda x: f(x)['b'])(x),
{'a': 2 * jnp.cos(x['a'])})
def test_jvp_error(self):
@api.custom_vjp
def f(x):
return jnp.sin(x)
def f_fwd(x):
return f(x), jnp.cos(x)
def f_rev(cos_x, g):
return (2 * cos_x * g,)
f.defvjp(f_fwd, f_rev)
self.assertRaisesRegex(
TypeError,
r"can't apply forward-mode autodiff \(jvp\) to a custom_vjp function.",
lambda: api.jvp(f, (3.,), (1.,)))
self.assertRaisesRegex(
TypeError,
r"can't apply forward-mode autodiff \(jvp\) to a custom_vjp function.",
lambda: api.jvp(api.vmap(f), (jnp.arange(3.),), (jnp.ones(3),)))
self.assertRaisesRegex(
TypeError,
r"can't apply forward-mode autodiff \(jvp\) to a custom_vjp function.",
lambda: api.jvp(jit(f), (3.,), (1.,)))
def test_kwargs(self):
# from https://github.com/google/jax/issues/1938
@api.custom_vjp
def my_fun(x, y, c=1.):
return c * (x + y)
my_fun.defvjp(lambda x, y, c=1.: (my_fun(c, y, c), None),
lambda _, g: (g, g, g))
f = lambda x, y: jnp.square(my_fun(x, y, c=2.)).sum()
f(10., 5.) # doesn't crash
api.grad(f)(10., 5.) # doesn't crash
def test_initial_style(self):
@api.custom_vjp
def f(x):
return jnp.sin(x)
def f_fwd(x):
return f(x), jnp.cos(x)
def f_rev(cos_x, g):
return (2 * cos_x * g,)
f.defvjp(f_fwd, f_rev)
def foo(x):
out, _ = lax.scan(lambda c, _: (f(c), None), x, None, length=1)
return out
ans = api.grad(foo)(3.)
expected = 2. * jnp.cos(3.)
self.assertAllClose(ans, expected, check_dtypes=False)
ans = api.grad(api.grad(foo))(3.)
expected = -2. * jnp.sin(3.)
self.assertAllClose(ans, expected)
def test_initial_style_vmap(self):
@api.custom_vjp
def f(x):
assert jnp.ndim(x) == 0
return 3 * x
def f_fwd(x):
return f(x), jnp.cos(x)
def f_rev(cos_x, g):
return (2 * cos_x * g,)
f.defvjp(f_fwd, f_rev)
def foo(x):
out, _ = lax.scan(lambda c, _: (f(c), None), x, None, length=1)
return out
ans = api.vmap(foo)(jnp.arange(3.))
expected = 3. * jnp.arange(3.)
self.assertAllClose(ans, expected, check_dtypes=False)
ans = api.grad(lambda x: api.vmap(foo)(x).sum())(jnp.arange(3.))
expected = 2. * jnp.cos(jnp.arange(3.))
self.assertAllClose(ans, expected, check_dtypes=False)
def test_nondiff_arg(self):
@partial(api.custom_vjp, nondiff_argnums=(0,))
def app(f, x):
return f(x)
def app_fwd(f, x):
return app(f, x), jnp.cos(x)
def app_rev(f, cos_x, g):
return (cos_x * g,)
app.defvjp(app_fwd, app_rev)
ans = app(lambda x: 2 * x, 1)
expected = 2
self.assertAllClose(ans, expected, check_dtypes=False)
ans = api.value_and_grad(lambda x: app(lambda y: 2 * y, x))(1.)
expected = (2., jnp.cos(1.))
self.assertAllClose(ans, expected, check_dtypes=False)
def test_closed_over_tracer(self):
# This test is similar to test_nondiff_arg_tracer except it uses lexical
# closure rather than the nondiff_argnums mechanism. We decided to disallow
# tracers in nondiff_argnums to greatly simplify bookkeeping while still
# supporting the cases for which it is necessary.
def outer(x):
@api.custom_vjp
def f(y):
return x * y
def f_fwd(y):
return f(y), jnp.cos(y)
def f_rev(cos_y, g):
return (cos_y * g,)
f.defvjp(f_fwd, f_rev)
return f
@jit
def g(x, y):
return outer(x)(y)
ans = g(2, 3.)
expected = 6.
self.assertAllClose(ans, expected, check_dtypes=False)
ans = api.grad(g, 1)(2., 3.)
expected = jnp.cos(3.)
self.assertAllClose(ans, expected, check_dtypes=False)
def test_closed_over_tracer2(self):
def outer(x):
@api.custom_vjp
def f(y):
return x * y
def f_fwd(y):
return f(y), jnp.cos(y)
def f_rev(cos_y, g):
return (cos_y * g,)
f.defvjp(f_fwd, f_rev)
return f
@api.vmap
def g(x):
return outer(x)(3.)
ans = g(np.arange(3.))
expected = np.arange(3.) * 3
self.assertAllClose(ans, expected, check_dtypes=False)
def test_closed_over_tracer3(self):
def outer(x):
@api.custom_vjp
def f(y):
return x * y
def f_fwd(y):
return f(y), (x, jnp.cos(y))
def f_rev(res, g):
x, cos_y = res
return (cos_y * g * x,)
f.defvjp(f_fwd, f_rev)
return api.grad(f)
@api.vmap
def g(x):
return outer(x)(3.)
ans = g(np.arange(3.))
expected = np.cos(3.) * np.arange(3.)
self.assertAllClose(ans, expected, check_dtypes=False)
def test_nondiff_arg_tracer_error(self):
# This is similar to the old (now skipped) test_nondiff_arg_tracer, except
# we're testing for the error message that that usage pattern now raises.
@partial(api.custom_vjp, nondiff_argnums=(0,))
def f(x, y):
return x * y
def f_fwd(x, y):
return f(x, y), jnp.cos(y)
def f_rev(x, cos_y, g):
return (cos_y * g,)
f.defvjp(f_fwd, f_rev)
@jit
def g(x, y):
return f(x, y)
with self.assertRaisesRegex(UnexpectedTracerError, "custom_vjp"):
_ = g(2, 3.)
with self.assertRaisesRegex(UnexpectedTracerError, "custom_vjp"):
_ = api.grad(g, 1)(2., 3.)
def test_vmap_axes(self):
raise unittest.SkipTest("TODO") # TODO(mattjj): write test
def test_pmap(self):
raise unittest.SkipTest("TODO") # TODO(mattjj): write test
def test_missing_vjp_rule_error(self):
@api.custom_vjp
def foo(x):
return x ** 2
self.assertRaisesRegex(
AttributeError,
r"No VJP defined for custom_vjp function foo using defvjp.",
lambda: foo(2))
self.assertRaisesRegex(
AttributeError,
r"No VJP defined for custom_vjp function foo using defvjp.",
lambda: api.grad(foo)(2.))
def test_vjp_rule_inconsistent_pytree_structures_error(self):
@api.custom_vjp
def f(x):
return x
def foo_fwd(x):
return x, None
def foo_bwd(_, g):
return (g, g)
f.defvjp(foo_fwd, foo_bwd)
f(2) # doesn't crash
self.assertRaisesRegex(
TypeError,
re.escape(
"Custom VJP rule must produce an output with the same container "
"(pytree) structure as the args tuple of the primal function, "
"and in particular must produce a tuple of length equal to the "
"number of arguments to the primal function, but got VJP output "
"structure {} for primal input structure {}.".format(
tree_util.tree_structure((1, 1)),
tree_util.tree_structure((1,)))
),
lambda: api.grad(f)(2.))
def test_vjp_bwd_returns_non_tuple_error(self):
@api.custom_vjp
def f(x):
return x
def foo_fwd(x):
return x, None
def foo_bwd(_, g):
return 2. * g # Should be a tuple
f.defvjp(foo_fwd, foo_bwd)
with self.assertRaisesRegex(TypeError, "Custom VJP rule .* must produce a tuple"):
api.grad(f)(3.)
def test_fwd_rule_primal_out_type_doesnt_match_primal_error_message(self):
# https://github.com/lucidrains/flash-attention-jax/issues/7
def scan_apply(f, x):
y, _ = jax.lax.scan(lambda x, _: (f(x), None), x, None, length=1)
return y
@jax.custom_vjp
def f(x):
return x
def f_fwd(x):
return (x, x), None
def f_bwd(_, y_bar):
return (y_bar,)
f.defvjp(f_fwd, f_bwd)
self.assertRaisesRegex(
TypeError,
re.escape(
"Custom VJP fwd rule f_fwd for function f must produce a pair "
"(list or tuple of length two) where the first element represents "
"the primal output (equal to the output of the "
"custom_vjp-decorated function f) and the second element "
"represents residuals (i.e. values stored from the forward "
"pass for use on the backward pass), but instead the fwd rule "
"output's first element had container/pytree structure:\n"
" (float32[], float32[])\n"
"while the custom_vjp-decorated function f had output "
"container/pytree structure:\n"
" float32[]."
),
lambda: jax.grad(lambda x: scan_apply(f, x))(jnp.float32(1.)))
def f_fwd2(x):
return jnp.zeros((3, *x.shape), x.dtype), None
def f_bwd2(_, y_bar):
return (y_bar,)
f.defvjp(f_fwd2, f_bwd2)
self.assertRaisesRegex(
TypeError,
re.escape(
"Custom VJP fwd rule f_fwd2 for function f must produce a pair "
"(list or tuple of length two) where the first element represents "
"the primal output (equal to the output of the "
"custom_vjp-decorated function f) and the second element "
"represents residuals (i.e. values stored from the forward "
"pass for use on the backward pass), but instead the fwd rule "
"output's first element had shapes/dtypes of:\n"
" float32[3]\n"
"while the custom_vjp-decorated function f had output "
"shapes/dtypes of:\n"
" float32[]"
),
lambda: jax.grad(lambda x: scan_apply(f, x))(jnp.float32(1.)))
def test_issue2511(self):
arr = jnp.ones((5, 2, 2))
foo = lambda x: api.vmap(jnp.linalg.det, (0,))(x)
api.jit(foo)(arr) # doesn't crash
def test_lowering_out_of_traces(self):
# https://github.com/google/jax/issues/2578
class F(collections.namedtuple("F", ["a"])):
def __call__(self, x):
return jax.nn.relu(self.a) * x
@jax.jit
def g(f, x):
return f(x)
jax.grad(g, argnums=(1,))(F(2.0), 0.) # doesn't crash
def test_clip_gradient(self):
# https://github.com/google/jax/issues/2784
@api.custom_vjp
def _clip_gradient(lo, hi, x):
return x # identity function when not differentiating
def clip_gradient_fwd(lo, hi, x):
return x, (lo, hi,)
def clip_gradient_bwd(res, g):
lo, hi = res
return (None, None, jnp.clip(g, lo, hi),)
_clip_gradient.defvjp(clip_gradient_fwd, clip_gradient_bwd)
def clip_gradient(x):
lo = -0.1
hi = x + 0.1
return _clip_gradient(lo, hi, x)
g = jax.grad(clip_gradient)(0.1) # doesn't crash
self.assertAllClose(g, jnp.array(0.2))
def test_nestable_vjp(self):
# Verify that https://github.com/google/jax/issues/3667 is resolved.
def f(x):
return x ** 2
@api.custom_vjp
def g(x):
return f(x)
def g_fwd(x):
y, f_vjp = api.vjp(f, x)
return y, f_vjp
def g_bwd(f_vjp, y_bar):
return f_vjp(y_bar)
g.defvjp(g_fwd, g_bwd)
# Check that VJP can be nested in simple situations. For this to pass,
# vjp has to return a PyTree.
_, g_vjp = api.vjp(g, 1.0)
y, = g_vjp(1.0)
self.assertAllClose(y, jnp.array(2.0))
# Check that VJP can be nested in complex situations. For this to pass,
# vjp can't treat the closed-over tracer x as a static argument.
@jit
def z(x):
_, g_vjp = api.vjp(g, x)
return g_vjp
y, = z(1.0)(3.0)
self.assertAllClose(y, jnp.array(6.0))
def test_initial_style_vmap_2(self):
# https://github.com/google/jax/issues/4173
x = jnp.ones((10, 3))
# Create the custom function
@api.custom_vjp
def custom_fun(x):
return x.sum()
def forward(x):
return x.sum(), (jnp.ones_like(x),)
def backward(res, g):
return g * res[0],
custom_fun.defvjp(forward, backward)
def train_fun(x):
def summed_fun(x):
return api.vmap(custom_fun)(x).sum()
return api.grad(summed_fun)(x)
def scan_body(carry, inputs):
x = carry
return carry, train_fun(x)
scan_range = jnp.arange(4)
lax.scan(scan_body, x, scan_range) # don't crash
def test_initial_style_vmap_3(self):
# This is like test_initial_style_vmap except the primal function closes
# over an array constant.
y = jnp.array([1., 2., 3.])
@api.custom_vjp
def f(x):
assert jnp.ndim(x) == 0
return 3 * x * jnp.sum(y)
def f_fwd(x):
return f(x), jnp.cos(x)
def f_rev(cos_x, g):
return (2 * cos_x * g,)
f.defvjp(f_fwd, f_rev)
def foo(x):
out, _ = lax.scan(lambda c, _: (f(c), None), x, None, length=1)
return out
ans = api.vmap(foo)(jnp.arange(3.))
expected = 3. * jnp.arange(3.) * 6
self.assertAllClose(ans, expected, check_dtypes=False)
ans = api.grad(lambda x: api.vmap(foo)(x).sum())(jnp.arange(3.))
expected = 2. * jnp.cos(jnp.arange(3.))
self.assertAllClose(ans, expected, check_dtypes=False)
def test_initial_style_vmap_with_collective(self):
@api.custom_vjp
def f(x):
return lax.psum(x, 'foo')
def f_fwd(x):
return lax.psum(x, 'foo'), None
def f_bwd(res, dx):
return dx
f.defvjp(f_fwd, f_bwd)
def g(x):
jaxpr = api.make_jaxpr(f)(x)
return core.eval_jaxpr(jaxpr.jaxpr, [], x)[0]
out = api.vmap(lambda _, x: g(x), axis_name='foo', in_axes=(0, None),
out_axes=None)(jnp.arange(4.), 2.)
self.assertAllClose(out, 8.)
def test_bwd_closes_over_tracer(self):
def f(y):
@jax.custom_vjp
def f(x):
return 2. * jnp.sin(x)
def fwd(x):
return f(x), ()
def bwd(_, g):
return (2. * jnp.cos(y) * g,) # capture!
f.defvjp(fwd, bwd)
return jax.grad(f)(1.)
ans = jax.jit(f)(2.)
self.assertAllClose(ans, 2. * jnp.cos(2.))
ans = jax.vmap(f)(jnp.arange(3.))
self.assertAllClose(ans, 2. * jnp.cos(jnp.arange(3.)))
ans = jax.jit(jax.vmap(f))(jnp.arange(3.))
self.assertAllClose(ans, 2. * jnp.cos(jnp.arange(3.)))
ans = jax.vmap(jax.jit(f))(jnp.arange(3.))
self.assertAllClose(ans, 2. * jnp.cos(jnp.arange(3.)))
ans = jax.grad(f)(4.)
self.assertAllClose(ans, -2. * jnp.sin(4.))
def test_fwd_closes_over_tracer(self):
def f(y):
@jax.custom_vjp
def f(x):
return 2. * jnp.sin(x)
def fwd(x):
return f(x), y
def bwd(y, g):
return (2. * jnp.cos(y) * g,) # capture!
f.defvjp(fwd, bwd)
return jax.grad(f)(1.)
ans = jax.jit(f)(2.)
self.assertAllClose(ans, 2. * jnp.cos(2.))
ans = jax.vmap(f)(jnp.arange(3.))
self.assertAllClose(ans, 2. * jnp.cos(jnp.arange(3.)))
ans = jax.jit(jax.vmap(f))(jnp.arange(3.))
self.assertAllClose(ans, 2. * jnp.cos(jnp.arange(3.)))
ans = jax.vmap(jax.jit(f))(jnp.arange(3.))
self.assertAllClose(ans, 2. * jnp.cos(jnp.arange(3.)))
ans = jax.grad(f)(4.)
self.assertAllClose(ans, -2. * jnp.sin(4.))
@unittest.skipIf(numpy_version == (1, 21, 0),
"https://github.com/numpy/numpy/issues/19305")
def test_float0(self):
@api.custom_vjp
def f(x, _):
return x
def f_fwd(x, _):
# we need a defined (non-float0) tangent to trigger the rule
return x, (2., 1)
def f_rev(*_):
return (2., 1)
f.defvjp(f_fwd, f_rev)
x = 2.
y = 3
self.assertEqual(api.grad(f, allow_int=True, argnums=(0, 1))(x, y),
(2., np.zeros(shape=(), dtype=float0)))
@unittest.skipIf(numpy_version == (1, 21, 0),
"https://github.com/numpy/numpy/issues/19305")
def test_float0_initial_style(self):
@api.custom_vjp
def f(x):
return x
def f_fwd(x):
return x, (2., x)
def f_rev(*_):
return ((2., 1),)
f.defvjp(f_fwd, f_rev)
def foo(x, y):
out, _ = lax.scan(lambda c, _: (f(c), None), (x, y), None, length=1)
return out[0]
x = 2.
y = 3
self.assertEqual(api.grad(foo, allow_int=True, argnums=(0, 1))(x, y),
(2., np.zeros(shape=(), dtype=float0)))
def test_remat(self):
@api.custom_vjp
def f(x):
return jnp.sin(x)
def f_fwd(x):
return f(x), jnp.cos(x)
def f_rev(cos_x, g):
return (2 * cos_x * g,)
f.defvjp(f_fwd, f_rev)
@api.remat
def g(x):
return f(f(x))
ans = g(2.)
expected = np.sin(np.sin(2.))
self.assertAllClose(ans, expected, check_dtypes=False)
ans = api.grad(g)(2.)
expected = 4. * api.grad(lambda x: jnp.sin(jnp.sin(x)))(2.)
self.assertAllClose(ans, expected, check_dtypes=False)
def test_remat_higher_order(self):
@api.custom_vjp
def f(x):
return jnp.sin(x)
def f_fwd(x):
return f(x), jnp.cos(x)
def f_rev(cos_x, g):
return (2 * cos_x * g,)
f.defvjp(f_fwd, f_rev)
def g(x):
return f(f(x))
ans = api.grad(api.grad(api.remat(g)))(2.)
expected = api.grad(api.grad(g))(2.)
self.assertAllClose(ans, expected, check_dtypes=False)
ans = api.grad(api.remat(api.grad(g)))(2.)
expected = api.grad(api.grad(g))(2.)
self.assertAllClose(ans, expected, check_dtypes=False)
ans = api.grad(api.grad(api.grad(api.remat(g))))(2.)
expected = api.grad(api.grad(api.grad(g)))(2.)
self.assertAllClose(ans, expected, check_dtypes=False)
def test_bwd_nones(self):
@api.custom_vjp
def f(x, y):
return x * jnp.sin(y)
def f_fwd(x, y):
return f(x, y), jnp.cos(y)
def f_rev(cos, g):
return (None, 2 * cos * g)
f.defvjp(f_fwd, f_rev)
ans = api.grad(lambda x: f(x, x))(3.)
expected = 2 * jnp.cos(3.)
self.assertAllClose(ans, expected, check_dtypes=False)
def test_bwd_nones_vmap(self):
@api.custom_vjp
def f(x, y):
return x * jnp.sin(y)
def f_fwd(x, y):
return f(x, y), jnp.cos(y)
def f_rev(cos, g):
return (None, 2 * cos * g)
f.defvjp(f_fwd, f_rev)
ans = api.grad(lambda x: api.vmap(f)(x, x).sum())(jnp.arange(3.))
expected = 2 * jnp.cos(jnp.arange(3.))
self.assertAllClose(ans, expected, check_dtypes=False)
def test_bwd_nones_pytree(self):
@api.custom_vjp
def f(xs, y):
x1, x2 = xs
return x1 * x2 * jnp.sin(y)
def f_fwd(xs, y):
return f(xs, y), jnp.cos(y)
def f_rev(cos, g):
return (None, 2 * cos * g)
f.defvjp(f_fwd, f_rev)
ans = api.grad(lambda x: f((x, x), x))(3.)
expected = 2 * jnp.cos(3.)
self.assertAllClose(ans, expected, check_dtypes=False)
def test_custom_vjp_closure_4521(self):
# https://github.com/google/jax/issues/4521
@api.custom_vjp
def g(x, y):
return None
def g_fwd(x, y):
return None, y
def g_bwd(residuals, z_bar):
assert False
g.defvjp(g_fwd, g_bwd)
def f(xs, y):
v_g = api.vmap(g, in_axes=(0, None), out_axes=None)
v_g(xs, y)
def scan_body(xs, _):
y = jnp.zeros(1)
_, vjp_f = api.vjp(f, xs, y)
vjp_f(None)
return xs, None
lax.scan(scan_body, jnp.ones(5), None, 100) # doesn't crash
def test_float0_bwd_none(self):
@api.custom_vjp
def f(i, x):
return jnp.sin(x)
def f_fwd(i, x):
return f(i, x), jnp.cos(x)
def f_rev(cos_x, g):
return (None, 2 * cos_x * g)
f.defvjp(f_fwd, f_rev)
ans = api.grad(f, 1)(jnp.array([1, 2]), 3.) # doesn't crash
expected = 2 * jnp.cos(3.)
self.assertAllClose(ans, expected, check_dtypes=False)
def test_custom_gradient(self):
@api.custom_gradient
def f(x):
return x ** 2, lambda g: (g * x,)
self.assertAllClose(f(3.), 9., check_dtypes=False)
self.assertAllClose(api.grad(f)(3.), 3., check_dtypes=False)
self.assertAllClose(api.grad(api.grad(f))(3.), 1., check_dtypes=False)
def test_custom_gradient_2(self):
@api.custom_gradient
def f(x, y):
return x * y, lambda g: (y, x)
self.assertAllClose(f(3., 4.), 12., check_dtypes=False)
self.assertAllClose(api.grad(f, argnums=(0, 1))(3., 4.), (4., 3.),
check_dtypes=False)
def test_custom_gradient_3(self):
@api.custom_gradient
def f(x):
vjp = lambda g: (jnp.cos(x) * jnp.array([3., 4., 5.]),)
return jnp.sum(jnp.sin(x)), vjp
self.assertAllClose(f(jnp.arange(3)), jnp.sum(jnp.sin(jnp.arange(3.))),
check_dtypes=False)
self.assertAllClose(
api.grad(f)(jnp.arange(3.)),
api.grad(lambda x: jnp.sum(jnp.sin(x)))(jnp.arange(3.)) * jnp.array([3., 4., 5.]),
check_dtypes=False)
def test_custom_gradient_can_return_singleton_value_in_vjp(self):
@api.custom_gradient
def f(x):
return x ** 2, lambda g: g * x
self.assertAllClose(f(3.), 9., check_dtypes=False)
self.assertAllClose(api.grad(f)(3.), 3., check_dtypes=False)
self.assertAllClose(api.grad(api.grad(f))(3.), 1., check_dtypes=False)
def test_closure_convert(self):
def cos_after(fn, x):
converted_fn, aux_args = api.closure_convert(fn, x)
self.assertLessEqual(len(aux_args), 1)
return _cos_after(converted_fn, x, *aux_args)
@partial(api.custom_vjp, nondiff_argnums=(0,))
def _cos_after(fn, x, *args):
return jnp.cos(fn(x, *args))
def fwd(fn, x, *args):
y = _cos_after(fn, x, *args)
return y, (x, args)
def rev(fn, res, g):
x, args = res
x_bar = 17. * x
args_bars = [42. * a for a in args]
return (x_bar, *args_bars)
_cos_after.defvjp(fwd, rev)
def dist(c, x):
return jnp.sum((x - c) ** 2.)
def solve(c, x):
def closure(x):
return dist(c, x)
return cos_after(closure, x)
c, x = 2. * jnp.ones(2), jnp.ones(2)
expected = jnp.cos(dist(c, x))
self.assertAllClose(solve(c, x), expected, check_dtypes=False)
g_c, g_x = api.grad(solve, argnums=(0, 1))(c, x)
self.assertAllClose(g_c, 42. * c, check_dtypes=False)
self.assertAllClose(g_x, 17. * x, check_dtypes=False)
def test_closure_convert_mixed_consts(self):
# Like test_closure_convert, but close over values that
# participate in AD as well as values that do not.
# See https://github.com/google/jax/issues/6415
def cos_after(fn, x):
converted_fn, aux_args = api.closure_convert(fn, x)
self.assertLessEqual(len(aux_args), 1)
return _cos_after(converted_fn, x, *aux_args)
@partial(api.custom_vjp, nondiff_argnums=(0,))
def _cos_after(fn, x, *args):
return jnp.cos(fn(x, *args))
def fwd(fn, x, *args):
y = _cos_after(fn, x, *args)
return y, (x, args)
def rev(fn, res, g):
x, args = res
x_bar = 17. * x
args_bars = [42. * a for a in args]
return (x_bar, *args_bars)
_cos_after.defvjp(fwd, rev)
def dist(c, s, x):
return jnp.sum(s * (x - c) ** 2.)
def solve(c, s, x):
def closure(x):
return dist(c, s, x)
return cos_after(closure, x)
c, s, x = 2. * jnp.ones(2), 3. * jnp.ones(2), jnp.ones(2)
expected = jnp.cos(dist(c, s, x))
self.assertAllClose(solve(c, s, x), expected, check_dtypes=False)
g_c, g_x = api.grad(solve, argnums=(0, 2))(c, s, x)
self.assertAllClose(g_c, 42. * c, check_dtypes=False)
self.assertAllClose(g_x, 17. * x, check_dtypes=False)
def test_float0_cotangents_automatically_handled(self):
@jax.custom_vjp
def f(x, y):
return x
def f_fwd(x, y):
return x, None
def f_bwd(_, zbar):
return (0., 1)
f.defvjp(f_fwd, f_bwd)
jax.jit(lambda x: jax.vjp(f, 0., x)[1](1.))(1) # doesn't crash
def test_custom_vjp_scan_batching_edge_case(self):
# https://github.com/google/jax/issues/5832
@jax.custom_vjp
def mul(x, coeff): return x * coeff
def mul_fwd(x, coeff): return mul(x, coeff), (x, coeff)
def mul_bwd(res, g):
x, coeff = res
g_x = g * coeff
g_coeff = (x * g).sum()
return g_x, g_coeff
mul.defvjp(mul_fwd, mul_bwd)
def scan_over_mul(x, coeff):
def f_(x, t):
return mul(x, coeff), None
y, _ = jax.lax.scan(f_, x, jnp.arange(3))
return y
key = jax.random.PRNGKey(0)
key1, key2 = jax.random.split(key, 2)
x_batch = jax.random.normal(key1, (3, 2))
covector_batch = jax.random.normal(key2, (3, 2))
coeff = jnp.array(1.)
batched_scan_over_mul = jax.vmap(scan_over_mul, in_axes=(0, None), out_axes=0)
res, vjp_fun = jax.vjp(batched_scan_over_mul, x_batch, coeff)
vjp_fun(covector_batch) # doesn't crash
jtu.check_grads(batched_scan_over_mul, (x_batch, coeff), order=2,
modes=['rev'])
def test_closure_with_vmap2(self):
# https://github.com/google/jax/issues/8783
def h(z):
def f(x):
@jax.custom_vjp
def g(y):
return x * y
def g_fwd(y):
return x * y, (x, x * y, y)
def g_rev(res, w_bar):
x, *_ = res
return (x * w_bar,)
g.defvjp(g_fwd, g_rev)
return g(z)
return jax.vmap(f)(jnp.arange(3., dtype='float32')).sum()
jtu.check_grads(h, (jnp.float32(3.14),), order=1, modes=['rev'])
def test_pytrees_not_required_to_contain_nones(self):
class A(list):
pass
def unflatten(_, children):
assert children[0] is not None
return A(children)
tree_util.register_pytree_node(A, lambda x: (x, None), unflatten)
@jax.custom_vjp
def f(x):
return x[0]
def f_fwd(x):
return x[0], None
def f_bwd(_, g):
return A([g]),
f.defvjp(f_fwd, f_bwd)
jax.grad(f)(A([1.])) # doesn't crash
def transpose_unary(f, x_example):
def transposed(y):
x, = api.linear_transpose(f, x_example)(y)
return x
return transposed
# This class wraps api.custom_transpose in order to pass in a
# particular tree of output type on each call. Otherwise it forwards
# all attribute access.
class _custom_transpose:
def __init__(self, out_types, fun):
self.out_types = out_types
self.fun = api.custom_transpose(fun)
def __getattr__(self, name):
return getattr(self.fun, name)
def __call__(self, *args):
return self.fun(self.out_types, *args)
# This function is meant to be used as a decorator that delegates to
# custom_transpose but makes it easy to specify output argument types
# by example. If used directly a decorator (i.e. not invoked with
# example arguments), assumes a scalar-valued function.
#
# TODO(frostig): remove this (and its uses) once custom_transpose offers
# an option of inferring output types.
def custom_transpose(example_out):
if isinstance(example_out, Callable):
out_type = core.get_aval(0.).at_least_vspace()
return _custom_transpose(out_type, example_out)
return partial(
_custom_transpose,
tree_util.tree_map(
lambda x: core.get_aval(x).at_least_vspace(), example_out))
class CustomTransposeTest(jtu.JaxTestCase):
def test_linear_call(self):
def f(x, y):
def fn(r, x): return x / r
def tp(r, t): return t / r
return x + api.linear_call(fn, tp, y, x)
def f_ref(x, y):
return x + x / y
x = jnp.ones(2) * 6.
y = jnp.ones(2) * 3.
self.assertAllClose(f(x, y), f_ref(x, y))
f1 = lambda x: f(x, y)
f1_ref = lambda x: f_ref(x, y)
self.assertAllClose(transpose_unary(f1, x)(x),
transpose_unary(f1_ref, x)(x))
def test_linear_call_incorrect_transpose(self):
def f(x, y):
def fn(r, x): return x / r
def tp(r, t): return t / (2. * r) # nb: not the true transpose
return x + api.linear_call(fn, tp, y, x)
def f_ref(x, y):
return x + x / y
x = jnp.ones(2) * 6.
y = jnp.ones(2) * 3.
self.assertAllClose(f(x, y), f_ref(x, y))
f1 = lambda x: f(x, y)
f1_ref = lambda x: f_ref(x, 2. * y) # nb: double the reference divisor
self.assertAllClose(transpose_unary(f1, x)(x),
transpose_unary(f1_ref, x)(x))
def test_linear_call_transpose_transpose_transpose(self):
def fn(r, x): return x / r
def tp(r, t): return t / (2. * r) # nb: untrue transpose
def f_(x, y):
return x + api.linear_call(fn, tp, y, x)
x = jnp.ones(2) * 6.
y = jnp.ones(2) * 3.
f = lambda x: f_(x, y)
ft = transpose_unary(f, x)
ftt = transpose_unary(ft, x)
fttt = transpose_unary(ftt, x)
self.assertAllClose(ft(x), x + tp(y, x))
self.assertAllClose(f(x), ftt(x))
self.assertAllClose(ft(x), fttt(x))
def test_linear_call_scalar_to_vector(self):
def f(c, x):
def fn(_, x):
return [x, x]
def tp(_, t):
t1, t2 = t
return t1 + t2
return api.linear_call(fn, tp, (), c * x)
def f_ref(c, x):
return [c * x, c * x]
c, x = 2., 3.
t = [4., 5.]
self.assertAllClose(f(c, x), f_ref(c, x))
self.assertAllClose(transpose_unary(partial(f, c), x)(t),
transpose_unary(partial(f_ref, c), x)(t))
def test_linear_call_nested(self):
# identity function with an untrue transpose of 0
def id_(x):
def f(_, x): return x
def t(_, t): return 0.
return api.linear_call(f, t, (), x)
# identity function with an untrue transpose of 7, and where both
# forward and transpose have custom transpositions that should
# never end up invoked.
def f(x):
def f_(_, x): return id_(x)
def t_(_, t): return id_(7.)
return api.linear_call(f_, t_, (), x)
x = 5.
id_t = transpose_unary(id_, x)
id_tt = transpose_unary(id_t, x)
ft = transpose_unary(f, x)
ftt = transpose_unary(ft, x)
fttt = transpose_unary(ftt, x)
self.assertAllClose(id_(x), x)
self.assertAllClose(id_t(x), 0.)
self.assertAllClose(id_tt(x), x)
self.assertAllClose(f(x), x)
self.assertAllClose(ft(x), 7.)
self.assertAllClose(ftt(x), x)
self.assertAllClose(fttt(x), 7.)
def test_linear_call_jit(self):
def f(x, y):
def fn(r, x): return x / r
def tp(r, t): return t / r
return x + api.linear_call(fn, tp, y, x)
x = jnp.ones(2) * 6.
y = jnp.ones(2) * 3.
self.assertAllClose(f(x, y), jax.jit(f)(x, y))
f1 = lambda x: f(x, y)
self.assertAllClose(transpose_unary(f1, x)(x),
jax.jit(transpose_unary(f1, x))(x))
def test_basic(self):
def f(x, y):
@custom_transpose(jnp.ones(2))
def fn(r, x): return x / r
@fn.def_transpose
def tp(r, t): return t / r
return x + fn(y, x)
def f_ref(x, y):
return x + x / y
x = jnp.ones(2) * 6.
y = jnp.ones(2) * 3.
self.assertAllClose(f(x, y), f_ref(x, y))
f1 = lambda x: f(x, y)
f1_ref = lambda x: f_ref(x, y)
self.assertAllClose(transpose_unary(f1, x)(x),
transpose_unary(f1_ref, x)(x))
def test_incorrect_transpose(self):
def f(x, y):
@custom_transpose(jnp.ones(2))
def fn(r, x): return x / r
@fn.def_transpose
def tp(r, t): return t / (2. * r) # nb: not the true transpose
return x + fn(y, x)
def f_ref(x, y):
return x + x / y
x = jnp.ones(2) * 6.
y = jnp.ones(2) * 3.
self.assertAllClose(f(x, y), f_ref(x, y))
f1 = lambda x: f(x, y)
f1_ref = lambda x: f_ref(x, 2. * y) # nb: double the reference divisor
self.assertAllClose(transpose_unary(f1, x)(x),
transpose_unary(f1_ref, x)(x))
def test_transpose_transpose_transpose(self):
@custom_transpose(jnp.ones(2))
def fn(r, x): return x / r
@custom_transpose(jnp.ones(2))
def tp(r, t): return t / (2. * r) # nb: untrue transpose
fn.def_transpose(tp)
tp.def_transpose(fn)
def f_(x, y):
return x + fn(y, x)
x = jnp.ones(2) * 6.
y = jnp.ones(2) * 3.
f = lambda x: f_(x, y)
ft = transpose_unary(f, x)
ftt = transpose_unary(ft, x)
fttt = transpose_unary(ftt, x)
self.assertAllClose(ft(x), x + tp(y, x))
self.assertAllClose(f(x), ftt(x))
self.assertAllClose(ft(x), fttt(x))
def test_scalar_to_vector(self):
def f(c, x):
@custom_transpose([0., 0.])
def fn(_, x):
return [x, x]
@fn.def_transpose
def tp(_, t):
t1, t2 = t
return t1 + t2
return fn((), c * x)
def f_ref(c, x):
return [c * x, c * x]
c, x = 2., 3.
t = [4., 5.]
self.assertAllClose(f(c, x), f_ref(c, x))
self.assertAllClose(transpose_unary(partial(f, c), x)(t),
transpose_unary(partial(f_ref, c), x)(t))
def test_nested(self):
# identity function with an untrue transpose of 0
def id_(x):
f = custom_transpose(lambda _, x: x)
t = custom_transpose(lambda _, t: 0.)
f.def_transpose(t)
t.def_transpose(f)
return f((), x)
# identity function with an untrue transpose of 7, and where both
# forward and transpose have custom transpositions that should
# never end up invoked.
def f(x):
f_ = custom_transpose(lambda _, x: id_(x))
t_ = custom_transpose(lambda _, t: id_(7.))
f_.def_transpose(t_)
t_.def_transpose(f_)
return f_((), x)
x = 5.
id_t = transpose_unary(id_, x)
id_tt = transpose_unary(id_t, x)
ft = transpose_unary(f, x)
ftt = transpose_unary(ft, x)
fttt = transpose_unary(ftt, x)
self.assertAllClose(id_(x), x)
self.assertAllClose(id_t(x), 0.)
self.assertAllClose(id_tt(x), x)
self.assertAllClose(f(x), x)
self.assertAllClose(ft(x), 7.)
self.assertAllClose(ftt(x), x)
self.assertAllClose(fttt(x), 7.)
def test_one_degree(self):
T = lambda f: transpose_unary(f, 0.)
@custom_transpose
def f(_, z): return 2. * z
@f.def_transpose
def ft(_, z): return 3. * z
f = partial(f, ())
self.assertAllClose(2., f(1.))
self.assertAllClose(3., T(f)(1.))
self.assertAllClose(3., T(T(f))(1.))
self.assertAllClose(3., T(T(T(f)))(1.))
self.assertAllClose(3., T(T(T(T(f))))(1.)) # ...
def test_two_degrees(self):
T = lambda f: transpose_unary(f, 0.)
@custom_transpose
def f(_, z): return 2. * z
@f.def_transpose
@custom_transpose
def ft(_, z): return 3. * z
@ft.def_transpose
def ftt(_, z): return 7. * z
f = partial(f, ())
self.assertAllClose(2., f(1.))
self.assertAllClose(3., T(f)(1.))
self.assertAllClose(7., T(T(f))(1.))
self.assertAllClose(7., T(T(T(f)))(1.))
self.assertAllClose(7., T(T(T(T(f))))(1.)) # ...
def test_symmetric(self):
T = lambda f: transpose_unary(f, 0.)
@custom_transpose
def f(_, z): return 2. * z
@custom_transpose
def g(_, z): return 3. * z
f.def_transpose(g)
g.def_transpose(f)
f = partial(f, ())
self.assertAllClose(2., f(1.))
self.assertAllClose(3., T(f)(1.))
self.assertAllClose(2., T(T(f))(1.))
self.assertAllClose(3., T(T(T(f)))(1.))
self.assertAllClose(2., T(T(T(T(f))))(1.)) # ...
def test_recursive(self):
T = lambda f: transpose_unary(f, 0.)
@custom_transpose
def f(c, z): return c * z
@f.def_transpose
def ft(c, z): return f(c + 1., z)
g = partial(f, 1.)
self.assertAllClose(1., g(1.))
self.assertAllClose(2., T(g)(1.))
self.assertAllClose(3., T(T(g))(1.))
self.assertAllClose(4., T(T(T(g)))(1.))
self.assertAllClose(5., T(T(T(T(g))))(1.)) # ...
def test_jvp_lin(self):
def f(x, y):
@custom_transpose(jnp.ones(2))
def fn(r, x): return x / r
@fn.def_transpose
def tp(r, t): return t / r
return x + fn(y, x)
def f_ref(x, y): return x + x / y
x, y, tx = 6., 3., 1.
g = lambda x: f(x, y)
g_ref = lambda x: f_ref(x, y)
self.assertAllClose(api.jvp(g, [x], [tx]), api.jvp(g_ref, [x], [tx]))
def test_jvp_res(self):
raise unittest.SkipTest('unimplemented') # TODO(frostig)
def f(x, y):
@custom_transpose(jnp.ones(2))
def fn(r, x): return x / r
@fn.def_transpose
def tp(r, t): return t / r
return x + fn(y, x)
def f_ref(x, y): return x + x / y
x, y, ty = 6., 3., 1.
g = lambda y: f(x, y)
g_ref = lambda y: f_ref(x, y)
self.assertAllClose(api.jvp(g, [y], [ty]), api.jvp(g_ref, [y], [ty]))
def test_jvp_both(self):
raise unittest.SkipTest('unimplemented') # TODO(frostig)
def f(x, y):
@custom_transpose(jnp.ones(2))
def fn(r, x): return x / r
@fn.def_transpose
def tp(r, t): return t / r
return x + fn(y, x)
def f_ref(x, y): return x + x / y
x, y, tx, ty = 6., 3., 1., 1.
self.assertAllClose(api.jvp(f, [x, y], [tx, ty]),
api.jvp(f_ref, [x, y], [tx, ty]))
def test_make_jaxpr(self):
def f(x, y):
@custom_transpose(jnp.ones(2))
def fn(r, x): return x / r
@fn.def_transpose
def tp(r, t): return 2 * t / r
return x + fn(y, x)
x = jnp.ones(2) * 6.
y = jnp.ones(2) * 3.
f_ = lambda x: f(x, y)
f_t = transpose_unary(f_, x)
jaxpr = api.make_jaxpr(f_)(x)
self.assertIn('custom_transpose_call', str(jaxpr))
jaxpr_t = api.make_jaxpr(f_t)(x)
self.assertNotIn('custom_transpose_call', str(jaxpr_t))
def test_jit(self):
def f(x, y):
@custom_transpose(jnp.ones(2))
def fn(r, x): return x / r
@fn.def_transpose
def tp(r, t): return 2 * t / r
return x + fn(y, x)
x = jnp.ones(2) * 6.
y = jnp.ones(2) * 3.
self.assertAllClose(f(x, y), jax.jit(f)(x, y))
f_ = lambda x: f(x, y)
f_t = transpose_unary(f_, x)
g_ = jax.jit(f_)
g_t = transpose_unary(g_, x)
self.assertAllClose(f_(x), jax.jit(f_)(x))
self.assertAllClose(f_t(x), jax.jit(f_t)(x))
self.assertAllClose(f_(x), g_(x))
self.assertAllClose(f_t(x), g_t(x))
def test_jit_recursive(self):
def f(x, y):
@custom_transpose(jnp.ones(2))
def fn(r, x): return x / r
@fn.def_transpose
def tp(r, t): return 2 * fn(r, t)
return x + fn(y, x)
x = jnp.ones(2) * 6.
y = jnp.ones(2) * 3.
self.assertAllClose(f(x, y), jax.jit(f)(x, y))
f_ = lambda x: f(x, y)
f_t = transpose_unary(f_, x)
g_ = jax.jit(f_)
g_t = transpose_unary(g_, x)
self.assertAllClose(f_(x), jax.jit(f_)(x))
self.assertAllClose(f_t(x), jax.jit(f_t)(x))
self.assertAllClose(f_(x), g_(x))
self.assertAllClose(f_t(x), g_t(x))
def test_cond(self):
def f(x, y):
@custom_transpose(jnp.ones(2))
def fn(r, x): return x / r
@fn.def_transpose
def tp(r, t): return 2 * t / r
return x + fn(y, x)
def cond_wrap(f):
return lambda i, x: lax.cond(i > 0, f, lambda x: x, x,
linear=(True,))
i = 7.
x = jnp.ones(2) * 6.
y = jnp.ones(2) * 3.
f_ = lambda x: f(x, y)
f_t = transpose_unary(f_, x)
g_ = partial(cond_wrap(f_), i)
g_t = transpose_unary(g_, x)
self.assertAllClose(f_(x), g_(x))
self.assertAllClose(f_t(x), g_t(x))
def test_cond_recursive(self):
def f(x, y):
@custom_transpose(jnp.ones(2))
def fn(r, x): return x / r
@fn.def_transpose
def tp(r, t): return 2 * fn(r, t)
return x + fn(y, x)
def cond_wrap(f):
return lambda i, x: lax.cond(i > 0, f, lambda x: x, x,
linear=(True,))
i = 7.
x = jnp.ones(2) * 6.
y = jnp.ones(2) * 3.
f_ = lambda x: f(x, y)
f_t = transpose_unary(f_, x)
g_ = partial(cond_wrap(f_), i)
g_t = transpose_unary(g_, x)
self.assertAllClose(f_(x), g_(x))
self.assertAllClose(f_t(x), g_t(x))
class CustomVmapTest(jtu.JaxTestCase):
def test_basic(self):
@api.custom_vmap
def f(x): return jnp.sin(x)
@f.def_vmap
def rule(axis_size, in_batched, xs):
xs_batched, = in_batched
self.assertEqual(xs_batched, True)
self.assertEqual(axis_size, xs.shape[0])
return jnp.cos(xs), xs_batched
x, xs = jnp.array(1.), jnp.arange(3)
y = f(x)
self.assertAllClose(y, jnp.sin(x))
ys = api.vmap(f)(xs)
self.assertAllClose(ys, jnp.cos(xs))
def test_closure(self):
z = jnp.array([2., 1., 3.])
@api.custom_vmap
def f(x): return z + jnp.sin(x)
@f.def_vmap
def rule(axis_size, in_batched, *args):
self.assertEqual(len(in_batched), 1)
self.assertEqual(len(args), 1)
xs, = args
xs_batched, = in_batched
self.assertEqual(xs_batched, True)
self.assertEqual(axis_size, xs.shape[0])
return z + jnp.cos(xs), xs_batched
x, xs = jnp.array(1.), jnp.arange(3)
y = f(x)
self.assertAllClose(y, z + jnp.sin(x))
ys = api.vmap(f)(xs)
self.assertAllClose(ys, z + jnp.cos(xs))
def test_rule_multi_output(self):
@api.custom_vmap
def f(x): return jnp.sin(x), jnp.cos(x)
@f.def_vmap
def rule(axis_size, in_batched, xs):
return (jnp.cos(xs), jnp.sin(xs)), tuple(in_batched * 2)
x, xs = jnp.array(1.), jnp.arange(3)
y1, y2 = f(x)
self.assertAllClose(y1, jnp.sin(x))
self.assertAllClose(y2, jnp.cos(x))
ys1, ys2 = api.vmap(f)(xs)
self.assertAllClose(ys1, jnp.cos(xs))
self.assertAllClose(ys2, jnp.sin(xs))
def test_nary(self):
@api.custom_vmap
def f(x, y): return jnp.sin(x) + y ** 2.
@f.def_vmap
def rule(axis_size, in_batched, xs, ys):
self.assertEqual(in_batched, [True, True])
self.assertEqual(axis_size, 3)
self.assertEqual(axis_size, xs.shape[0])
self.assertEqual(axis_size, ys.shape[0])
return jnp.cos(xs) + ys ** 2., True
xs, ys = jnp.arange(3.0), jnp.arange(3.0)
zs = api.vmap(f)(xs, ys)
self.assertAllClose(zs, jnp.cos(xs) + ys ** 2.)
def test_nary_mixed_batching(self):
@api.custom_vmap
def vector_dot(u, v):
self.assertEqual(u.ndim, 1)
self.assertEqual(v.ndim, 1)
return u @ v
size = 4
vlen = 3
in_batched_log = []
@vector_dot.def_vmap
def vector_dot_vmap_rule(axis_size, in_batched, u, v):
in_batched_log.append(in_batched)
self.assertEqual(axis_size, size)
u_batched, v_batched = in_batched
if u_batched:
self.assertEqual(u.ndim, 2)
self.assertEqual(u.shape[0], size)
else:
self.assertEqual(u.ndim, 1)
self.assertEqual(u.shape[0], vlen)
if v_batched:
self.assertEqual(v.ndim, 2)
self.assertEqual(v.shape[0], size)
else:
self.assertEqual(v.ndim, 1)
self.assertEqual(v.shape[0], vlen)
if u_batched and v_batched:
out = jnp.sum(u * v, axis=1)
else:
out = u @ v if u_batched else v @ u
return out, u_batched or v_batched
f = vector_dot
v = lambda *shape: jnp.ones(shape)
y = api.vmap(f, in_axes=(0, None))(v(4, 3), v(3))
self.assertAllClose(y, v(4, 3) @ v(3))
y = api.vmap(f, in_axes=(1, None))(v(3, 4), v(3))
self.assertAllClose(y, v(3, 4).T @ v(3))
y = api.vmap(f, in_axes=(None, 0))(v(3), v(4, 3))
self.assertAllClose(y, v(3) @ v(4, 3).T)
y = api.vmap(f, in_axes=(0, 0))(v(4, 3), v(4, 3))
self.assertAllClose(y, jnp.sum(v(4, 3) * v(4, 3), axis=1))
self.assertEqual(in_batched_log[0], [True, False])
self.assertEqual(in_batched_log[1], [True, False])
self.assertEqual(in_batched_log[2], [False, True])
self.assertEqual(in_batched_log[3], [True, True])
def test_rule_input_signature(self):
@api.custom_vmap
def f(x): return jnp.sin(x)
rule_args = []
@f.def_vmap
def rule(axis_size, in_batched, xs):
rule_args.append((axis_size, in_batched))
return jnp.cos(xs), in_batched[0]
xs = jnp.arange(3)
_ = api.vmap(f)(xs)
(axis_size, in_batched), = rule_args
self.assertIs(type(axis_size), int)
self.assertIs(type(in_batched), list)
self.assertEqual(len(in_batched), 1)
def test_rule_output_vs_batching_output_mismatch(self):
@api.custom_vmap
def f(x): return jnp.sin(x)
@f.def_vmap
def test_rule_abc(axis_size, in_batched, xs):
return [jnp.sin(xs), jnp.cos(xs)], in_batched
xs = jnp.arange(3)
self.assertRaisesRegex(
ValueError,
'structure of output value and output batching specification '
r'returned by custom vmap rule \(test_rule_abc\) do not match.*',
lambda: api.vmap(f)(xs))
def test_rule_vs_call_output_mismatch(self):
@api.custom_vmap
def f(x): return jnp.sin(x)
@f.def_vmap
def test_rule_abc2(axis_size, in_batched, xs):
return [jnp.sin(xs)], in_batched
xs = jnp.arange(3)
self.assertRaisesRegex(
ValueError,
r'structure of output returned by custom vmap rule \(test_rule_abc2\) '
r'does not match that of original custom-vmapped function.*',
lambda: api.vmap(f)(xs))
def test_jvp_basic(self):
@api.custom_vmap
def f(x): return jnp.sin(x)
@f.def_vmap
def rule(axis_size, in_batched, xs):
self.assertEqual(axis_size, 3)
self.assertEqual(in_batched, [True])
return jnp.cos(xs), in_batched[0]
f_jvp = lambda x, tx: api.jvp(f, [x], [tx])
x, tx = jnp.array(1.), jnp.array(2.)
xs, txs = jnp.arange(3.), jnp.arange(3.) * 2.
y, ty = f_jvp(x, tx)
self.assertAllClose(y, jnp.sin(x))
self.assertAllClose(ty, jnp.cos(x) * tx)
ys, tys = api.vmap(f_jvp)(xs, txs)
self.assertAllClose(ys, jnp.cos(xs))
self.assertAllClose(tys, -jnp.sin(xs) * txs)
ys, tys = api.jvp(api.vmap(f), [xs], [txs])
self.assertAllClose(ys, jnp.cos(xs))
self.assertAllClose(tys, -jnp.sin(xs) * txs)
def test_jvp_closure(self):
z = jnp.array([2., 1., 3.])
def bcast(x): return z + x - z
@api.custom_vmap
def f(x): return z + jnp.sin(x)
@f.def_vmap
def rule(axis_size, in_batched, xs):
self.assertEqual(axis_size, 3)
self.assertEqual(in_batched, [True])
return z + jnp.cos(xs), in_batched[0]
f_jvp = lambda x, tx: api.jvp(f, [x], [tx])
x, tx = jnp.array(1.), jnp.array(2.)
xs, txs = jnp.arange(3.), jnp.arange(3.) * 2.
y, ty = f_jvp(x, tx)
self.assertAllClose(y, z + jnp.sin(x))
self.assertAllClose(ty, bcast(jnp.cos(x)) * tx)
ys, tys = api.vmap(f_jvp)(xs, txs)
self.assertAllClose(ys, z + jnp.cos(xs))
self.assertAllClose(tys, bcast(-jnp.sin(xs)) * txs)
ys, tys = api.jvp(api.vmap(f), [xs], [txs])
self.assertAllClose(ys, z + jnp.cos(xs))
self.assertAllClose(tys, bcast(-jnp.sin(xs)) * txs)
def test_jvp_nary(self):
@api.custom_vmap
def f(x, y): return jnp.sin(x) + y
@f.def_vmap
def rule(axis_size, in_batched, xs, ys):
self.assertEqual(axis_size, 3)
self.assertEqual(in_batched, [True, True])
return jnp.cos(xs) + ys, True
f_jvp = lambda x, y, tx, ty: api.jvp(f, [x, y], [tx, ty])
x, y, tx, ty = jnp.arange(4.)
xs, ys, txs, tys = 4. + jnp.arange(3. * 4).reshape((4, 3))
zs, tzs = api.vmap(f_jvp)(xs, ys, txs, tys)
self.assertAllClose(zs, jnp.cos(xs) + ys)
self.assertAllClose(tzs, -jnp.sin(xs) * txs + tys)
zs, tzs = api.jvp(api.vmap(f), [xs, ys], [txs, tys])
self.assertAllClose(zs, jnp.cos(xs) + ys)
self.assertAllClose(tzs, -jnp.sin(xs) * txs + tys)
def test_jvp_extra_batched_tangents(self):
@api.custom_vmap
def f(x): return jnp.sin(x)
@f.def_vmap
def rule(axis_size, in_batched, xs):
self.assertEqual(axis_size, 3)
self.assertEqual(in_batched, [False])
return jnp.cos(xs), in_batched[0]
f_jvp = lambda x, tx: api.jvp(f, [x], [tx])
x, txs = jnp.array(1.), 2. + jnp.arange(3.)
y, tys = api.vmap(f_jvp, in_axes=(None, 0), out_axes=(None, 0))(x, txs)
self.assertAllClose(y, jnp.cos(x))
self.assertAllClose(tys, -jnp.sin(x) * txs)
def test_jacfwd(self):
# jacfwd is another way to exercise extra-batched tangents
@api.custom_vmap
def f(x): return jnp.sin(x)
@f.def_vmap
def rule(axis_size, in_batched, xs):
self.assertEqual(axis_size, 3)
self.assertEqual(in_batched, [False])
return jnp.cos(xs), in_batched[0]
x = jnp.arange(3.) + .72
j = api.jacfwd(f)(x)
self.assertAllClose(j, -jnp.diag(jnp.sin(x)))
def test_jvp_extra_batched_primals(self):
@api.custom_vmap
def f(x): return jnp.sin(x)
@f.def_vmap
def rule(axis_size, in_batched, xs):
self.assertEqual(axis_size, 3)
self.assertEqual(in_batched, [False])
return jnp.cos(xs), in_batched[0]
f_jvp = lambda x, tx: api.jvp(f, [x], [tx])
xs, tx = jnp.arange(3.), jnp.array(4.)
ys, tys = api.vmap(f_jvp, in_axes=(0, None))(xs, tx)
self.assertAllClose(ys, jnp.cos(xs))
self.assertAllClose(tys, -jnp.sin(xs) * tx)
def test_jvp_extra_batched_primals_with_linear_vmap_rule(self):
# When a function is linear, its Jacobian is constant. JAX's JVP
# of linear functions takes advantage of this: when mapping over a
# batch of primals relative to a fixed (i.e. symbolically
# replicated) tangent, output tangents remain replicated as well
# (i.e. JAX will not broadcast them). This is true in general, and
# this test checks that vmapped JVPs continue to behave this way
# when custom_vmap is involved and the custom vmap rule is linear.
@api.custom_vmap
def f_linear(x): return 7. * x
@f_linear.def_vmap
def linear_rule(axis_size, in_batched, xs):
return 11. * xs, in_batched[0]
@api.custom_vmap
def f_nonlinear(x): return jnp.sin(x)
@f_nonlinear.def_vmap
def nonlinear_rule(axis_size, in_batched, xs):
return jnp.cos(xs), in_batched[0]
f_lin_jvp = lambda x, tx: api.jvp(f_linear, [x], [tx])
f_non_jvp = lambda x, tx: api.jvp(f_nonlinear, [x], [tx])
xs, tx = jnp.arange(3.), jnp.array(4.)
# doesn't err
_ = api.vmap(f_lin_jvp, in_axes=(0, None), out_axes=(0, None))(xs, tx)
# does err
self.assertRaisesRegex(
ValueError, 'vmap has mapped output but out_axes is None',
lambda: api.vmap(
f_non_jvp, in_axes=(0, None), out_axes=(0, None))(xs, tx))
def test_jvp_dataflow_violation(self):
# The jvp-of-custom-vmap machinery should not assume the standard
# dataflow constraint on the JVP of the custom vmap rule (primal
# outputs independent of tangent inputs). Both jvp and vmap are
# "forward" transformations under which, at present, we don't
# enforce the JVP dependence diagram. Because output primals can
# depend on input tangents, extra-batched input tangents can
# create batched output primals, as this test checks.
@api.custom_jvp
def cos_with_invalid_dataflow_jvp(x): return jnp.cos(x)
@cos_with_invalid_dataflow_jvp.defjvp
def invalid_dataflow_jvp(x, tx):
[x], [tx] = x, tx
return jnp.cos(x * tx), tx
@api.custom_vmap
def f(x): return jnp.sin(x)
@f.def_vmap
def rule(axis_size, in_batched, xs):
return cos_with_invalid_dataflow_jvp(xs), in_batched[0]
f_jvp = lambda x, tx: api.jvp(f, [x], [tx])
x, txs = jnp.array(1.), 2. + jnp.arange(3.)
# doesn't err
ys, tys = api.vmap(f_jvp, in_axes=(None, 0))(x, txs)
self.assertAllClose(ys, jnp.cos(x * txs))
self.assertAllClose(tys, txs)
# does err
self.assertRaisesRegex(
ValueError, 'vmap has mapped output but out_axes is None',
lambda: api.vmap(
f_jvp, in_axes=(None, 0), out_axes=(None, 0))(x, txs))
def test_tree(self):
tree_sin = partial(tree_util.tree_map, jnp.sin)
tree_cos = partial(tree_util.tree_map, jnp.cos)
x, xs = jnp.array(1.), jnp.arange(3)
x = (x, [x + 1, x + 2], [x + 3], x + 4)
xs = (xs, [xs + 1, xs + 2], [xs + 3], xs + 4)
in_batched_ref = tree_util.tree_map(lambda _: True, x)
@api.custom_vmap
def f(xs): return tree_sin(xs)
@f.def_vmap
def rule(axis_size, in_batched, xs):
self.assertEqual(in_batched, [in_batched_ref])
sz, = {z.shape[0] for z in tree_util.tree_leaves(xs)}
self.assertEqual(axis_size, sz)
return tree_cos(xs), in_batched[0]
y = f(x)
self.assertAllClose(y, tree_sin(x))
ys = api.vmap(f)(xs)
self.assertAllClose(ys, tree_cos(xs))
def test_tree_with_nones(self):
tree_sin = partial(tree_util.tree_map, jnp.sin)
tree_cos = partial(tree_util.tree_map, jnp.cos)
x, xs = jnp.array(1.), jnp.arange(3)
x = (x, [x + 1, None], [x + 3], None)
xs = (xs, [xs + 1, None], [xs + 3], None)
in_batched_ref = tree_util.tree_map(lambda _: True, x)
@api.custom_vmap
def f(xs): return tree_sin(xs)
@f.def_vmap
def rule(axis_size, in_batched, xs):
self.assertEqual(in_batched, [in_batched_ref])
sz, = {z.shape[0] for z in tree_util.tree_leaves(xs)}
self.assertEqual(axis_size, sz)
return tree_cos(xs), in_batched[0]
y = f(x)
self.assertAllClose(y, tree_sin(x))
ys = api.vmap(f)(xs)
self.assertAllClose(ys, tree_cos(xs))
def test_jit(self):
@api.custom_vmap
def f(x): return jnp.sin(x)
@f.def_vmap
def rule(axis_size, in_batched, xs):
self.assertEqual(in_batched, [True])
self.assertEqual(axis_size, xs.shape[0])
return jnp.cos(xs), in_batched[0]
x, xs = jnp.array(1.), jnp.arange(3)
self.assertAllClose(f(x), jit(f)(x))
self.assertAllClose(jit(api.vmap(f))(xs), api.vmap(f)(xs))
self.assertAllClose(api.vmap(jit(f))(xs), api.vmap(f)(xs))
def test_sequential_vmap_basic(self):
@custom_batching.sequential_vmap
def f(x):
return x + 1.
def vmap_ref(xs):
return lax.map(f, xs)
xs = jnp.arange(3.)
jaxpr = api.make_jaxpr(api.vmap(f))(xs)
jaxpr_ref = api.make_jaxpr(vmap_ref)(xs)
self.assertEqual(str(jaxpr), str(jaxpr_ref))
def test_sequential_vmap_nary_same_batching(self):
@custom_batching.sequential_vmap
def f(x, y):
return x + y
def vmap_ref(xs, ys):
return lax.map(lambda args: f(*args), (xs, ys))
xs, ys = jnp.arange(3.), 4. + jnp.arange(3.)
jaxpr = api.make_jaxpr(api.vmap(f))(xs, ys)
jaxpr_ref = api.make_jaxpr(vmap_ref)(xs, ys)
self.assertEqual(str(jaxpr), str(jaxpr_ref))
def test_sequential_vmap_nary_mixed_batching(self):
@custom_batching.sequential_vmap
def f(x, y):
return x + y
def vmap_ref(xs, y):
return lax.map(lambda x: f(x, y), xs)
xs, y = jnp.arange(3.), 4.
jaxpr = api.make_jaxpr(api.vmap(f, in_axes=(0, None)))(xs, y)
jaxpr_ref = api.make_jaxpr(vmap_ref)(xs, y)
self.assertEqual(str(jaxpr), str(jaxpr_ref))
class CustomApiTest(jtu.JaxTestCase):
"""Test interactions among the custom_{vmap,jvp,vjp,transpose,*} APIs"""
def test_method_forwarding(self):
@api.custom_vmap
@api.custom_jvp
@api.custom_transpose
def f(x): return 2. * x
# none of these err:
@f.def_vmap
def f_batch(sz, b, xs): return 2. * xs
@f.defjvp
def f_jvp(x, tx): return 2. * x, 2. * tx
@f.def_transpose
def f_transpose(x): return 2. * x
def test_def_method_forwarding_all_permutations(self):
for wraps in it.permutations([
api.custom_jvp, api.custom_transpose, api.custom_vmap]):
f = lambda x: x + 1.
for wrap in wraps:
f = wrap(f)
for methods in it.permutations(['defjvp', 'def_vmap', 'def_transpose']):
for method in methods:
self.assertIsInstance(getattr(f, method), Callable)
for decorators in it.permutations([
api.custom_vjp, api.custom_transpose, api.custom_vmap]):
f = lambda x: x + 1.
for decorator in decorators:
f = decorator(f)
for methods in it.permutations(['defvjp', 'def_vmap', 'def_transpose']):
for method in methods:
self.assertIsInstance(getattr(f, method), Callable)
class BufferDonationTest(jtu.BufferDonationTestCase):
def test_pmap_donate_argnums_invalidates_input(self):
if jtu.device_under_test() == "cpu" and xla_extension_version < 102:
raise unittest.SkipTest("CPU buffer donation requires jaxlib > 0.3.22")
move = api.pmap(lambda x: x + x - x, donate_argnums=0)
n = jax.local_device_count()
x = api.pmap(lambda x: x)(jnp.ones([n]))
y = move(x)
self.assertDeleted(x)
np.testing.assert_allclose(y, [1.] * n)
def test_pmap_nested_donate_ignored(self):
pmap_fun = jit(lambda x: api.pmap(lambda y: y ** 2, donate_argnums=0)(x))
a = api.pmap(lambda x: x)(jnp.array([1]))
# NOTE(mattjj): stopped raising error here and instead just ignored
# with self.assertRaisesRegex(ValueError, "nested.*not supported"):
# pmap_fun(a)
pmap_fun(a) # doesn't crash
class NamedCallTest(jtu.JaxTestCase):
def test_default_name(self):
@api.named_call
def my_test_function(x):
return x**2
@jax.jit
def f(x):
return my_test_function(x)
c = jax.xla_computation(f)(2)
print_opts = xla_client._xla.HloPrintOptions.short_parsable()
print_opts.print_metadata = True
hlo_text = c.as_hlo_module().to_string(print_opts)
self.assertIn("my_test_function", hlo_text)
def test_non_jaxtype_arg(self):
# For the test to fail without the invalid JaxType filter we need to pass
# in a valid JaxType that forces the invalid Jaxtype to be raised to an
# abstract value.
def f(not_a_jaxtype, a_jaxtype):
# then Jax needs to try and evaluate the abstractified non-JaxType
if not_a_jaxtype:
return a_jaxtype
return 0
f = api.named_call(f, name="test")
out = jax.jit(f, static_argnums=(0,))("not a Jaxtype", 1)
self.assertEqual(out, 1)
@parameterized.parameters(jax.jit, jax.grad, jax.vmap, jax.remat)
def test_jax_transforms(self, transform):
f = jnp.sum
x = jnp.array([1.])
unnamed_out = transform(f)(x)
named_out = transform(api.named_call(f, name="test"))(x)
self.assertEqual(unnamed_out, named_out)
def test_static_argnums(self):
f = api.named_call(lambda x, y: y if x else None, name="test")
f = jax.jit(f, static_argnums=(0,))
out = f(True, 5)
self.assertEqual(out, 5)
def test_partial_eval(self):
f = api.named_call(lambda x, y: y if x else None, name="test")
f = jax.jit(functools.partial(f, True))
out = f(5)
self.assertEqual(out, 5)
@jtu.sample_product(
[dict(func=func, jit=jit)
for func in ['identity', 'asarray', 'device_put']
for jit in jtu.JIT_IMPLEMENTATION
if not (jit._name == "noop" and func == 'identity')
],
)
def test_integer_overflow(self, jit, func):
funcdict = {
'identity': lambda x: x,
'asarray': jnp.asarray,
'device_put': api.device_put,
}
f = jit(funcdict[func])
int_dtype = dtypes.canonicalize_dtype(jnp.int_)
int_max = np.iinfo(int_dtype).max
int_min = np.iinfo(int_dtype).min
self.assertEqual(f(int_max).dtype, int_dtype)
self.assertEqual(f(int_min).dtype, int_dtype)
self.assertRaises(OverflowError, f, int_max + 1)
self.assertRaises(OverflowError, f, int_min - 1)
class BackendsTest(jtu.JaxTestCase):
@unittest.skipIf(not sys.executable, "test requires sys.executable")
@unittest.skipIf(platform.system() == "Darwin",
"Warning doesn't apply on Mac")
@jtu.skip_on_devices("gpu", "tpu")
def test_cpu_warning_suppression(self):
warning_expected = (
"import jax; "
"jax.numpy.arange(10)")
warning_not_expected = (
"import jax; "
"jax.config.update('jax_platform_name', 'cpu'); "
"jax.numpy.arange(10)")
result = subprocess.run([sys.executable, '-c', warning_expected],
check=True, capture_output=True)
assert "No GPU/TPU found" in result.stderr.decode()
result = subprocess.run([sys.executable, '-c', warning_not_expected],
check=True, capture_output=True)
assert "No GPU/TPU found" not in result.stderr.decode()
class CleanupTest(jtu.JaxTestCase):
def test_call_wrapped_second_phase_cleanup(self):
try:
jax.vmap(lambda x: x, out_axes=None)(jnp.arange(3))
except:
assert core.trace_state_clean() # this is the hard one
assert core.trace_state_clean()
class EnvironmentInfoTest(jtu.JaxTestCase):
@parameterized.parameters([True, False])
def test_print_environment_info(self, return_string):
with jtu.capture_stdout() as stdout:
result = jax.print_environment_info(return_string=return_string)
if return_string:
self.assertEmpty(stdout())
else:
self.assertIsNone(result)
result = stdout()
assert f"jax: {jax.__version__}" in result
assert f"jaxlib: {lib.version_str}" in result
assert f"numpy: {np.__version__}" in result
if __name__ == '__main__':
absltest.main(testLoader=jtu.JaxTestLoader())
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