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paddlepaddle--paddle/test/distribution/test_distribution_exponential_static.py
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2026-07-13 12:40:42 +08:00

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# Copyright (c) 2023 PaddlePaddle Authors. All Rights Reserved.
#
# 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
#
# http://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 unittest
import numpy as np
import parameterize
import scipy.stats
from distribution import config
import paddle
from paddle.distribution import exponential
np.random.seed(2023)
paddle.seed(2023)
paddle.enable_static()
@parameterize.place(config.DEVICES)
@parameterize.parameterize_cls(
(parameterize.TEST_CASE_NAME, 'rate'),
[
(
'one-dim',
parameterize.xrand(
(4,),
dtype='float32',
min=np.finfo(dtype='float32').tiny,
),
),
(
'multi-dim',
parameterize.xrand(
(10, 12),
dtype='float32',
min=np.finfo(dtype='float32').tiny,
),
),
],
)
class TestExponential(unittest.TestCase):
def setUp(self):
self.program = paddle.static.Program()
self.executor = paddle.static.Executor(self.place)
with paddle.static.program_guard(self.program):
self.scale = 1 / self.rate
rate = paddle.static.data('rate', self.rate.shape, self.rate.dtype)
self._paddle_expon = exponential.Exponential(rate)
self.feeds = {'rate': self.rate}
def test_mean(self):
with paddle.static.program_guard(self.program):
[mean] = self.executor.run(
self.program,
feed=self.feeds,
fetch_list=[self._paddle_expon.mean],
)
np.testing.assert_allclose(
mean,
scipy.stats.expon.mean(scale=self.scale),
rtol=config.RTOL.get(str(self.rate.dtype)),
atol=config.ATOL.get(str(self.rate.dtype)),
)
def test_variance(self):
with paddle.static.program_guard(self.program):
[variance] = self.executor.run(
self.program,
feed=self.feeds,
fetch_list=[self._paddle_expon.variance],
)
np.testing.assert_allclose(
variance,
scipy.stats.expon.var(scale=self.scale),
rtol=config.RTOL.get(str(self.rate.dtype)),
atol=config.ATOL.get(str(self.rate.dtype)),
)
def test_entropy(self):
with paddle.static.program_guard(self.program):
[entropy] = self.executor.run(
self.program,
feed=self.feeds,
fetch_list=[self._paddle_expon.entropy()],
)
np.testing.assert_allclose(
entropy,
scipy.stats.expon.entropy(scale=self.scale),
rtol=config.RTOL.get(str(self.rate.dtype)),
atol=config.ATOL.get(str(self.rate.dtype)),
)
def test_prob(self):
with paddle.static.program_guard(self.program):
value = paddle.static.data(
'value',
self._paddle_expon.rate.shape,
self._paddle_expon.rate.dtype,
)
prob = self._paddle_expon.prob(value)
random_number = np.random.rand(
*self._paddle_expon.rate.shape
).astype(self.rate.dtype)
feeds = dict(self.feeds, value=random_number)
[prob] = self.executor.run(
self.program, feed=feeds, fetch_list=[prob]
)
np.testing.assert_allclose(
prob,
scipy.stats.expon.pdf(random_number, scale=self.scale),
rtol=config.RTOL.get(str(self.rate.dtype)),
atol=config.ATOL.get(str(self.rate.dtype)),
)
def test_log_prob(self):
with paddle.static.program_guard(self.program):
value = paddle.static.data(
'value',
self._paddle_expon.rate.shape,
self._paddle_expon.rate.dtype,
)
log_prob = self._paddle_expon.log_prob(value)
random_number = np.random.rand(
*self._paddle_expon.rate.shape
).astype(self.rate.dtype)
feeds = dict(self.feeds, value=random_number)
[log_prob] = self.executor.run(
self.program, feed=feeds, fetch_list=[log_prob]
)
np.testing.assert_allclose(
log_prob,
scipy.stats.expon.logpdf(random_number, scale=self.scale),
rtol=config.RTOL.get(str(self.rate.dtype)),
atol=config.ATOL.get(str(self.rate.dtype)),
)
def test_cdf(self):
with paddle.static.program_guard(self.program):
value = paddle.static.data(
'value',
self._paddle_expon.rate.shape,
self._paddle_expon.rate.dtype,
)
cdf = self._paddle_expon.cdf(value)
random_number = np.random.rand(
*self._paddle_expon.rate.shape
).astype(self.rate.dtype)
feeds = dict(self.feeds, value=random_number)
[cdf] = self.executor.run(
self.program, feed=feeds, fetch_list=[cdf]
)
np.testing.assert_allclose(
cdf,
scipy.stats.expon.cdf(random_number, scale=self.scale),
rtol=config.RTOL.get(str(self.rate.dtype)),
atol=config.ATOL.get(str(self.rate.dtype)),
)
def test_icdf(self):
with paddle.static.program_guard(self.program):
value = paddle.static.data(
'value',
self._paddle_expon.rate.shape,
self._paddle_expon.rate.dtype,
)
icdf = self._paddle_expon.icdf(value)
random_number = np.random.rand(
*self._paddle_expon.rate.shape
).astype(self.rate.dtype)
feeds = dict(self.feeds, value=random_number)
[icdf] = self.executor.run(
self.program, feed=feeds, fetch_list=[icdf]
)
np.testing.assert_allclose(
icdf,
scipy.stats.expon.ppf(random_number, scale=self.scale),
rtol=config.RTOL.get(str(self.rate.dtype)),
atol=config.ATOL.get(str(self.rate.dtype)),
)
@parameterize.place(config.DEVICES)
@parameterize.parameterize_cls(
(parameterize.TEST_CASE_NAME, 'rate'),
[
(
'one-dim',
parameterize.xrand(
(2,),
dtype='float32',
min=np.finfo(dtype='float32').tiny,
),
),
(
'multi-dim',
parameterize.xrand(
(2, 3),
dtype='float32',
min=np.finfo(dtype='float32').tiny,
),
),
],
)
class TestExponentialSample(unittest.TestCase):
def setUp(self):
self.program = paddle.static.Program()
self.executor = paddle.static.Executor(self.place)
with paddle.static.program_guard(self.program):
self.scale = 1 / self.rate
rate = paddle.static.data('rate', self.rate.shape, self.rate.dtype)
self._paddle_expon = exponential.Exponential(rate)
self.feeds = {'rate': self.rate}
def test_sample_shape(self):
cases = [
{
'input': (),
'expect': tuple(np.squeeze(self.rate).shape),
},
{
'input': (4, 2),
'expect': (4, 2, *np.squeeze(self.rate).shape),
},
]
for case in cases:
with paddle.static.program_guard(self.program):
[data] = self.executor.run(
self.program,
feed=self.feeds,
fetch_list=self._paddle_expon.sample(case.get('input')),
)
self.assertTrue(data.shape == case.get('expect'))
def test_rsample_shape(self):
cases = [
{
'input': (),
'expect': tuple(np.squeeze(self.rate).shape),
},
{
'input': (3, 2),
'expect': (3, 2, *np.squeeze(self.rate).shape),
},
]
for case in cases:
with paddle.static.program_guard(self.program):
[data] = self.executor.run(
self.program,
feed=self.feeds,
fetch_list=self._paddle_expon.rsample(case.get('input')),
)
self.assertTrue(data.shape == case.get('expect'))
def test_sample(self):
sample_shape = (20000,)
with paddle.static.program_guard(self.program):
[data] = self.executor.run(
self.program,
feed=self.feeds,
fetch_list=self._paddle_expon.sample(sample_shape),
)
except_shape = sample_shape + np.squeeze(self.rate).shape
self.assertTrue(data.shape == except_shape)
np.testing.assert_allclose(
data.mean(axis=0),
scipy.stats.expon.mean(scale=self.scale),
rtol=0.1,
atol=config.ATOL.get(str(self.rate.dtype)),
)
np.testing.assert_allclose(
data.var(axis=0),
scipy.stats.expon.var(scale=self.scale),
rtol=0.1,
atol=config.ATOL.get(str(self.rate.dtype)),
)
def test_rsample(self):
sample_shape = (20000,)
with paddle.static.program_guard(self.program):
[data] = self.executor.run(
self.program,
feed=self.feeds,
fetch_list=self._paddle_expon.rsample(sample_shape),
)
except_shape = sample_shape + np.squeeze(self.rate).shape
self.assertTrue(data.shape == except_shape)
np.testing.assert_allclose(
data.mean(axis=0),
scipy.stats.expon.mean(scale=self.scale),
rtol=0.1,
atol=config.ATOL.get(str(self.rate.dtype)),
)
np.testing.assert_allclose(
data.var(axis=0),
scipy.stats.expon.var(scale=self.scale),
rtol=0.1,
atol=config.ATOL.get(str(self.rate.dtype)),
)
@parameterize.place(config.DEVICES)
@parameterize.parameterize_cls(
(parameterize.TEST_CASE_NAME, 'rate'),
[
('0-dim', 0.4),
],
)
class TestExponentialSampleKS(unittest.TestCase):
def setUp(self):
self.program = paddle.static.Program()
self.executor = paddle.static.Executor(self.place)
with paddle.static.program_guard(self.program):
self.scale = 1 / self.rate
rate = paddle.static.data('rate', (), 'float')
self._paddle_expon = exponential.Exponential(rate)
self.feeds = {'rate': self.rate}
def test_sample(self):
sample_shape = (10000,)
with paddle.static.program_guard(self.program):
[samples] = self.executor.run(
self.program,
feed=self.feeds,
fetch_list=self._paddle_expon.sample(sample_shape),
)
self.assertTrue(self._kstest(samples))
def test_rsample(self):
sample_shape = (10000,)
with paddle.static.program_guard(self.program):
[samples] = self.executor.run(
self.program,
feed=self.feeds,
fetch_list=self._paddle_expon.rsample(sample_shape),
)
self.assertTrue(self._kstest(samples))
def _kstest(self, samples):
# Uses the Kolmogorov-Smirnov test for goodness of fit.
ks, _ = scipy.stats.kstest(
samples, scipy.stats.expon(scale=self.scale).cdf
)
return ks < 0.02
@parameterize.place(config.DEVICES)
@parameterize.parameterize_cls(
(parameterize.TEST_CASE_NAME, 'rate1', 'rate2'),
[
(
'one-dim',
parameterize.xrand(
(2,),
dtype='float32',
min=np.finfo(dtype='float32').tiny,
),
parameterize.xrand(
(2,),
dtype='float32',
min=np.finfo(dtype='float32').tiny,
),
),
(
'multi-dim',
parameterize.xrand(
(2, 3),
dtype='float32',
min=np.finfo(dtype='float32').tiny,
),
parameterize.xrand(
(2, 3),
dtype='float32',
min=np.finfo(dtype='float32').tiny,
),
),
],
)
class TestExponentialKL(unittest.TestCase):
def setUp(self):
self.program1 = paddle.static.Program()
self.program2 = paddle.static.Program()
self.executor = paddle.static.Executor(self.place)
with paddle.static.program_guard(self.program1, self.program2):
rate1 = paddle.static.data(
'rate1', self.rate1.shape, self.rate1.dtype
)
rate2 = paddle.static.data(
'rate2', self.rate2.shape, self.rate2.dtype
)
self._expon1 = exponential.Exponential(rate1)
self._expon2 = exponential.Exponential(rate2)
self.feeds = {
'rate1': self.rate1,
'rate2': self.rate2,
}
def test_kl_divergence(self):
with paddle.static.program_guard(self.program1, self.program2):
self.executor.run(self.program2)
[kl] = self.executor.run(
self.program1,
feed=self.feeds,
fetch_list=[self._expon1.kl_divergence(self._expon2)],
)
np.testing.assert_allclose(
kl,
self._kl(),
rtol=config.RTOL.get(str(self.rate1.dtype)),
atol=config.ATOL.get(str(self.rate1.dtype)),
)
def test_kl1_error(self):
self.assertRaises(
TypeError,
self._expon1.kl_divergence,
paddle.distribution.beta.Beta,
)
def _kl(self):
rate_ratio = self.rate2 / self.rate1
t1 = -np.log(rate_ratio)
return t1 + rate_ratio - 1
if __name__ == '__main__':
unittest.main()