Files
ray/rllib/models/tests/test_distributions.py
T
428516056a [RLlib] SAC Torch (incl. Atari learning) (#7984)
* Policy-classes cleanup and torch/tf unification.
- Make Policy abstract.
- Add `action_dist` to call to `extra_action_out_fn` (necessary for PPO torch).
- Move some methods and vars to base Policy
  (from TFPolicy): num_state_tensors, ACTION_PROB, ACTION_LOGP and some more.

* Fix `clip_action` import from Policy (should probably be moved into utils altogether).

* - Move `is_recurrent()` and `num_state_tensors()` into TFPolicy (from DynamicTFPolicy).
- Add config to all Policy c'tor calls (as 3rd arg after obs and action spaces).

* Add `config` to c'tor call to TFPolicy.

* Add missing `config` to c'tor call to TFPolicy in marvil_policy.py.

* Fix test_rollout_worker.py::MockPolicy and BadPolicy classes (Policy base class is now abstract).

* Fix LINT errors in Policy classes.

* Implement StatefulPolicy abstract methods in test cases: test_multi_agent_env.py.

* policy.py LINT errors.

* Create a simple TestPolicy to sub-class from when testing Policies (reduces code in some test cases).

* policy.py
- Remove abstractmethod from `apply_gradients` and `compute_gradients` (these are not required iff `learn_on_batch` implemented).
- Fix docstring of `num_state_tensors`.

* Make QMIX torch Policy a child of TorchPolicy (instead of Policy).

* QMixPolicy add empty implementations of abstract Policy methods.

* Store Policy's config in self.config in base Policy c'tor.

* - Make only compute_actions in base Policy's an abstractmethod and provide pass
implementation to all other methods if not defined.
- Fix state_batches=None (most Policies don't have internal states).

* Cartpole tf learning.

* Cartpole tf AND torch learning (in ~ same ts).

* Cartpole tf AND torch learning (in ~ same ts). 2

* Cartpole tf (torch syntax-broken) learning (in ~ same ts). 3

* Cartpole tf AND torch learning (in ~ same ts). 4

* Cartpole tf AND torch learning (in ~ same ts). 5

* Cartpole tf AND torch learning (in ~ same ts). 6

* Cartpole tf AND torch learning (in ~ same ts). Pendulum tf learning.

* WIP.

* WIP.

* SAC torch learning Pendulum.

* WIP.

* SAC torch and tf learning Pendulum and Cartpole after cleanup.

* WIP.

* LINT.

* LINT.

* SAC: Move policy.target_model to policy.device as well.

* Fixes and cleanup.

* Fix data-format of tf keras Conv2d layers (broken for some tf-versions which have data_format="channels_first" as default).

* Fixes and LINT.

* Fixes and LINT.

* Fix and LINT.

* WIP.

* Test fixes and LINT.

* Fixes and LINT.

Co-authored-by: Sven Mika <sven@Svens-MacBook-Pro.local>
2020-04-15 13:25:16 +02:00

266 lines
11 KiB
Python

import numpy as np
from gym.spaces import Box
from scipy.stats import norm, beta
import unittest
from ray.rllib.models.tf.tf_action_dist import Categorical, MultiCategorical, \
SquashedGaussian, GumbelSoftmax
from ray.rllib.models.torch.torch_action_dist import TorchMultiCategorical, \
TorchSquashedGaussian, TorchBeta
from ray.rllib.utils import try_import_tf, try_import_torch
from ray.rllib.utils.numpy import MIN_LOG_NN_OUTPUT, MAX_LOG_NN_OUTPUT, \
softmax, SMALL_NUMBER
from ray.rllib.utils.test_utils import check, framework_iterator
tf = try_import_tf()
torch, _ = try_import_torch()
class TestDistributions(unittest.TestCase):
"""Tests ActionDistribution classes."""
def test_categorical(self):
"""Tests the Categorical ActionDistribution (tf only)."""
num_samples = 100000
logits = tf.placeholder(tf.float32, shape=(None, 10))
z = 8 * (np.random.rand(10) - 0.5)
data = np.tile(z, (num_samples, 1))
c = Categorical(logits, {}) # dummy config dict
sample_op = c.sample()
sess = tf.Session()
sess.run(tf.global_variables_initializer())
samples = sess.run(sample_op, feed_dict={logits: data})
counts = np.zeros(10)
for sample in samples:
counts[sample] += 1.0
probs = np.exp(z) / np.sum(np.exp(z))
self.assertTrue(np.sum(np.abs(probs - counts / num_samples)) <= 0.01)
def test_multi_categorical(self):
batch_size = 100
num_categories = 3
num_sub_distributions = 5
# Create 5 categorical distributions of 3 categories each.
inputs_space = Box(
-1.0,
2.0,
shape=(batch_size, num_sub_distributions * num_categories))
values_space = Box(
0,
num_categories - 1,
shape=(num_sub_distributions, batch_size),
dtype=np.int32)
inputs = inputs_space.sample()
input_lengths = [num_categories] * num_sub_distributions
inputs_split = np.split(inputs, num_sub_distributions, axis=1)
for fw in framework_iterator():
# Create the correct distribution object.
cls = MultiCategorical if fw != "torch" else TorchMultiCategorical
multi_categorical = cls(inputs, None, input_lengths)
# Batch of size=3 and deterministic (True).
expected = np.transpose(np.argmax(inputs_split, axis=-1))
# Sample, expect always max value
# (max likelihood for deterministic draw).
out = multi_categorical.deterministic_sample()
check(out, expected)
# Batch of size=3 and non-deterministic -> expect roughly the mean.
out = multi_categorical.sample()
check(
tf.reduce_mean(out)
if fw != "torch" else torch.mean(out.float()),
1.0,
decimals=0)
# Test log-likelihood outputs.
probs = softmax(inputs_split)
values = values_space.sample()
out = multi_categorical.logp(values if fw != "torch" else [
torch.Tensor(values[i]) for i in range(num_sub_distributions)
]) # v in np.stack(values, 1)])
expected = []
for i in range(batch_size):
expected.append(
np.sum(
np.log(
np.array([
probs[j][i][values[j][i]]
for j in range(num_sub_distributions)
]))))
check(out, expected, decimals=4)
# Test entropy outputs.
out = multi_categorical.entropy()
expected_entropy = -np.sum(np.sum(probs * np.log(probs), 0), -1)
check(out, expected_entropy)
def test_squashed_gaussian(self):
"""Tests the SquashedGaussian ActionDistribution for all frameworks."""
input_space = Box(-2.0, 2.0, shape=(200, 10))
low, high = -2.0, 1.0
for fw, sess in framework_iterator(session=True):
cls = SquashedGaussian if fw != "torch" else TorchSquashedGaussian
# Batch of size=n and deterministic.
inputs = input_space.sample()
means, _ = np.split(inputs, 2, axis=-1)
squashed_distribution = cls(inputs, {}, low=low, high=high)
expected = ((np.tanh(means) + 1.0) / 2.0) * (high - low) + low
# Sample n times, expect always mean value (deterministic draw).
out = squashed_distribution.deterministic_sample()
check(out, expected)
# Batch of size=n and non-deterministic -> expect roughly the mean.
inputs = input_space.sample()
means, log_stds = np.split(inputs, 2, axis=-1)
squashed_distribution = cls(inputs, {}, low=low, high=high)
expected = ((np.tanh(means) + 1.0) / 2.0) * (high - low) + low
values = squashed_distribution.sample()
if sess:
values = sess.run(values)
else:
values = values.numpy()
self.assertTrue(np.max(values) < high)
self.assertTrue(np.min(values) > low)
check(np.mean(values), expected.mean(), decimals=1)
# Test log-likelihood outputs.
sampled_action_logp = squashed_distribution.logp(
values if fw != "torch" else torch.Tensor(values))
if sess:
sampled_action_logp = sess.run(sampled_action_logp)
else:
sampled_action_logp = sampled_action_logp.numpy()
# Convert to parameters for distr.
stds = np.exp(
np.clip(log_stds, MIN_LOG_NN_OUTPUT, MAX_LOG_NN_OUTPUT))
# Unsquash values, then get log-llh from regular gaussian.
# atanh_in = np.clip((values - low) / (high - low) * 2.0 - 1.0,
# -1.0 + SMALL_NUMBER, 1.0 - SMALL_NUMBER)
atanh_in = (values - low) / (high - low) * 2.0 - 1.0
unsquashed_values = np.arctanh(atanh_in)
log_prob_unsquashed = np.sum(
np.log(
norm.pdf(unsquashed_values, means, stds) + SMALL_NUMBER),
-1)
log_prob = log_prob_unsquashed - \
np.sum(np.log(1 - np.tanh(unsquashed_values) ** 2),
axis=-1)
check(np.sum(sampled_action_logp), np.sum(log_prob), rtol=0.05)
# NN output.
means = np.array([[0.1, 0.2, 0.3, 0.4, 50.0],
[-0.1, -0.2, -0.3, -0.4, -1.0]])
log_stds = np.array([[0.8, -0.2, 0.3, -1.0, 2.0],
[0.7, -0.3, 0.4, -0.9, 2.0]])
squashed_distribution = cls(
inputs=np.concatenate([means, log_stds], axis=-1),
model={},
low=low,
high=high)
# Convert to parameters for distr.
stds = np.exp(log_stds)
# Values to get log-likelihoods for.
values = np.array([[0.9, 0.2, 0.4, -0.1, -1.05],
[-0.9, -0.2, 0.4, -0.1, -1.05]])
# Unsquash values, then get log-llh from regular gaussian.
unsquashed_values = np.arctanh((values - low) /
(high - low) * 2.0 - 1.0)
log_prob_unsquashed = \
np.sum(np.log(norm.pdf(unsquashed_values, means, stds)), -1)
log_prob = log_prob_unsquashed - \
np.sum(np.log(1 - np.tanh(unsquashed_values) ** 2),
axis=-1)
outs = squashed_distribution.logp(values if fw != "torch" else
torch.Tensor(values))
if sess:
outs = sess.run(outs)
check(outs, log_prob, decimals=4)
def test_beta(self):
input_space = Box(-2.0, 1.0, shape=(200, 10))
low, high = -1.0, 2.0
plain_beta_value_space = Box(0.0, 1.0, shape=(200, 5))
for fw, sess in framework_iterator(frameworks="torch", session=True):
cls = TorchBeta
inputs = input_space.sample()
beta_distribution = cls(inputs, {}, low=low, high=high)
inputs = beta_distribution.inputs
alpha, beta_ = np.split(inputs.numpy(), 2, axis=-1)
# Mean for a Beta distribution: 1 / [1 + (beta/alpha)]
expected = (1.0 / (1.0 + beta_ / alpha)) * (high - low) + low
# Sample n times, expect always mean value (deterministic draw).
out = beta_distribution.deterministic_sample()
check(out, expected, rtol=0.01)
# Batch of size=n and non-deterministic -> expect roughly the mean.
values = beta_distribution.sample()
if sess:
values = sess.run(values)
else:
values = values.numpy()
self.assertTrue(np.max(values) <= high)
self.assertTrue(np.min(values) >= low)
check(np.mean(values), expected.mean(), decimals=1)
# Test log-likelihood outputs (against scipy).
inputs = input_space.sample()
beta_distribution = cls(inputs, {}, low=low, high=high)
inputs = beta_distribution.inputs
alpha, beta_ = np.split(inputs.numpy(), 2, axis=-1)
values = plain_beta_value_space.sample()
values_scaled = values * (high - low) + low
out = beta_distribution.logp(torch.Tensor(values_scaled))
check(
out,
np.sum(np.log(beta.pdf(values, alpha, beta_)), -1),
rtol=0.001)
# TODO(sven): Test entropy outputs (against scipy).
def test_gumbel_softmax(self):
"""Tests the GumbelSoftmax ActionDistribution (tf-eager only)."""
for fw, sess in framework_iterator(
frameworks=["tf", "eager"], session=True):
batch_size = 1000
num_categories = 5
input_space = Box(-1.0, 1.0, shape=(batch_size, num_categories))
# Batch of size=n and deterministic.
inputs = input_space.sample()
gumbel_softmax = GumbelSoftmax(inputs, {}, temperature=1.0)
expected = softmax(inputs)
# Sample n times, expect always mean value (deterministic draw).
out = gumbel_softmax.deterministic_sample()
check(out, expected)
# Batch of size=n and non-deterministic -> expect roughly that
# the max-likelihood (argmax) ints are output (most of the time).
inputs = input_space.sample()
gumbel_softmax = GumbelSoftmax(inputs, {}, temperature=1.0)
expected_mean = np.mean(np.argmax(inputs, -1)).astype(np.float32)
outs = gumbel_softmax.sample()
if sess:
outs = sess.run(outs)
check(np.mean(np.argmax(outs, -1)), expected_mean, rtol=0.08)
if __name__ == "__main__":
import pytest
import sys
sys.exit(pytest.main(["-v", __file__]))