Implementing New Environments¶
In this section, we will walk through an example of implementing a point robot environment using our framework.
Each environment should implement at least the following methods / properties defined
in the file garage/envs/base.py
:
class Env:
def step(self, action):
"""
Run one timestep of the environment's dynamics. When end of episode
is reached, reset() should be called to reset the environment's internal state.
Input
-----
action : an action provided by the environment
Outputs
-------
(observation, reward, done, info)
observation : agent's observation of the current environment
reward [Float] : amount of reward due to the previous action
done : a boolean, indicating whether the episode has ended
info : a dictionary containing other diagnostic information from the previous action
"""
raise NotImplementedError
def reset(self):
"""
Resets the state of the environment, returning an initial observation.
Outputs
-------
observation : the initial observation of the space. (Initial reward is assumed to be 0.)
"""
raise NotImplementedError
@property
def action_space(self):
"""
Returns a Space object
"""
raise NotImplementedError
@property
def observation_space(self):
"""
Returns a Space object
"""
raise NotImplementedError
We will implement a simple environment with 2D observations and 2D actions. The goal is to control a point robot in 2D to move it to the origin. We receive position of a point robot in the 2D plane \((x, y) \in \mathbb{R}^2\). The action is its velocity \((\dot x, \dot y) \in \mathbb{R}^2\) constrained so that \(|\dot x| \leq 0.1\) and \(|\dot y| \leq 0.1\). We encourage the robot to move to the origin by defining its reward as the negative distance to the origin: \(r(x, y) = - \sqrt{x^2 + y^2}\).
We start by creating a new file for the environment. We assume that it is placed under
examples/point_env.py
. First, let’s declare a class inheriting from
the base environment and add some imports:
import akro
import numpy as np
from garage.envs.base import Env
from garage.envs.base import Step
class PointEnv(Env):
# ...
For each environment, we will need to specify the set of valid observations and the set of valid actions. This is done by implementing the following property methods:
class PointEnv(Env):
# ...
@property
def observation_space(self):
return akro.Box(low=-np.inf, high=np.inf, shape=(2,))
@property
def action_space(self):
return akro.Box(low=-0.1, high=0.1, shape=(2,))
The Box
space means that the observations and actions are 2D vectors
with continuous values. The observations can have arbitrary values, while the
actions should have magnitude at most 0.1.
Now onto the interesting part, where we actually implement the dynamics for the
MDP. This is done through two methods, reset
and
step
. The reset
method randomly initializes the state
of the environment according to some initial state distribution. To keep things
simple, we will just sample the coordinates from a uniform distribution. The
method should also return the initial observation. In our case, it will be the
same as its state.
class PointEnv(Env):
# ...
def reset(self):
self._state = np.random.uniform(-1, 1, size=(2,))
observation = np.copy(self._state)
return observation
The step
method takes an action and advances the state of the
environment. It should return a Step
object (which is a wrapper around
namedtuple
), containing the observation for the next time step, the reward,
a flag indicating whether the episode is terminated after taking the step, and optional
extra keyword arguments (whose values should be vectors only) for diagnostic purposes.
The procedure that interfaces with the environment is responsible for calling
reset
after seeing that the episode is terminated.
class PointEnv(Env):
# ...
def step(self, action):
self._state = self._state + action
x, y = self._state
reward = - (x**2 + y**2) ** 0.5
done = abs(x) < 0.01 and abs(y) < 0.01
next_observation = np.copy(self._state)
return Step(observation=next_observation, reward=reward, done=done)
Finally, we can implement some plotting to visualize what the MDP is doing. For simplicity, let’s just print the current state of the MDP on the terminal:
class PointEnv(Env):
# ...
def render(self):
print 'current state:', self._state
And we’re done! We can now simulate the environment using the following diagnostic script:
python scripts/sim_env.py garage.envs.point_env --mode random
It simulates an episode of the environment with random actions, sampled from a uniform distribution within the defined action bounds.
You could also train a neural network policy to solve the task, which is probably an overkill. To do so, create a new script with the following content (we will use stub mode):
from garage.envs import PointEnv
from garage.envs import normalize
from garage.np.baselines import LinearFeatureBaseline
from garage.tf.algos.trpo import TRPO
from garage.tf.policies.gaussian_mlp_policy import GaussianMLPPolicy
env = normalize(PointEnv())
policy = GaussianMLPPolicy(
env_spec=env.spec,
)
baseline = LinearFeatureBaseline(env_spec=env.spec)
algo = TRPO(
env=env,
policy=policy,
baseline=baseline,
)
algo.train()
Assume that the file is examples/tf/trpo_point.py
. You can then run the script:
python examples/tf/trpo_point.py