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wrappers.py
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wrappers.py
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import math
import operator
from functools import reduce
import numpy as np
import gym
from gym import error, spaces, utils
from .minigrid import OBJECT_TO_IDX, COLOR_TO_IDX, STATE_TO_IDX
class ReseedWrapper(gym.core.Wrapper):
"""
Wrapper to always regenerate an environment with the same set of seeds.
This can be used to force an environment to always keep the same
configuration when reset.
"""
def __init__(self, env, seeds=[0], seed_idx=0):
self.seeds = list(seeds)
self.seed_idx = seed_idx
super().__init__(env)
def reset(self, **kwargs):
seed = self.seeds[self.seed_idx]
self.seed_idx = (self.seed_idx + 1) % len(self.seeds)
self.env.seed(seed)
return self.env.reset(**kwargs)
def step(self, action):
obs, reward, done, info = self.env.step(action)
return obs, reward, done, info
class ActionBonus(gym.core.Wrapper):
"""
Wrapper which adds an exploration bonus.
This is a reward to encourage exploration of less
visited (state,action) pairs.
"""
def __init__(self, env):
super().__init__(env)
self.counts = {}
def step(self, action):
obs, reward, done, info = self.env.step(action)
env = self.unwrapped
tup = (tuple(env.agent_pos), env.agent_dir, action)
# Get the count for this (s,a) pair
pre_count = 0
if tup in self.counts:
pre_count = self.counts[tup]
# Update the count for this (s,a) pair
new_count = pre_count + 1
self.counts[tup] = new_count
bonus = 1 / math.sqrt(new_count)
reward += bonus
return obs, reward, done, info
def reset(self, **kwargs):
return self.env.reset(**kwargs)
class StateBonus(gym.core.Wrapper):
"""
Adds an exploration bonus based on which positions
are visited on the grid.
"""
def __init__(self, env):
super().__init__(env)
self.counts = {}
def step(self, action):
obs, reward, done, info = self.env.step(action)
# Tuple based on which we index the counts
# We use the position after an update
env = self.unwrapped
tup = (tuple(env.agent_pos))
# Get the count for this key
pre_count = 0
if tup in self.counts:
pre_count = self.counts[tup]
# Update the count for this key
new_count = pre_count + 1
self.counts[tup] = new_count
bonus = 1 / math.sqrt(new_count)
reward += bonus
return obs, reward, done, info
def reset(self, **kwargs):
return self.env.reset(**kwargs)
class ImgObsWrapper(gym.core.ObservationWrapper):
"""
Use the image as the only observation output, no language/mission.
"""
def __init__(self, env):
super().__init__(env)
self.observation_space = env.observation_space.spaces['image']
def observation(self, obs):
return obs['image']
class OneHotPartialObsWrapper(gym.core.ObservationWrapper):
"""
Wrapper to get a one-hot encoding of a partially observable
agent view as observation.
"""
def __init__(self, env, tile_size=8):
super().__init__(env)
self.tile_size = tile_size
obs_shape = env.observation_space['image'].shape
# Number of bits per cell
num_bits = len(OBJECT_TO_IDX) + len(COLOR_TO_IDX) + len(STATE_TO_IDX)
self.observation_space.spaces["image"] = spaces.Box(
low=0,
high=255,
shape=(obs_shape[0], obs_shape[1], num_bits),
dtype='uint8'
)
def observation(self, obs):
img = obs['image']
out = np.zeros(self.observation_space.spaces['image'].shape, dtype='uint8')
for i in range(img.shape[0]):
for j in range(img.shape[1]):
type = img[i, j, 0]
color = img[i, j, 1]
state = img[i, j, 2]
out[i, j, type] = 1
out[i, j, len(OBJECT_TO_IDX) + color] = 1
out[i, j, len(OBJECT_TO_IDX) + len(COLOR_TO_IDX) + state] = 1
return {
'mission': obs['mission'],
'image': out
}
class RGBImgObsWrapper(gym.core.ObservationWrapper):
"""
Wrapper to use fully observable RGB image as the only observation output,
no language/mission. This can be used to have the agent to solve the
gridworld in pixel space.
"""
def __init__(self, env, tile_size=8):
super().__init__(env)
self.tile_size = tile_size
self.observation_space.spaces['image'] = spaces.Box(
low=0,
high=255,
shape=(self.env.width * tile_size, self.env.height * tile_size, 3),
dtype='uint8'
)
def observation(self, obs):
env = self.unwrapped
rgb_img = env.render(
mode='rgb_array',
highlight=False,
tile_size=self.tile_size
)
return {
'mission': obs['mission'],
'image': rgb_img
}
class RGBImgPartialObsWrapper(gym.core.ObservationWrapper):
"""
Wrapper to use partially observable RGB image as the only observation output
This can be used to have the agent to solve the gridworld in pixel space.
"""
def __init__(self, env, tile_size=8):
super().__init__(env)
self.tile_size = tile_size
obs_shape = env.observation_space.spaces['image'].shape
self.observation_space.spaces['image'] = spaces.Box(
low=0,
high=255,
shape=(obs_shape[0] * tile_size, obs_shape[1] * tile_size, 3),
dtype='uint8'
)
def observation(self, obs):
env = self.unwrapped
rgb_img_partial = env.get_obs_render(
obs['image'],
tile_size=self.tile_size
)
return {
'mission': obs['mission'],
'image': rgb_img_partial
}
class FullyObsWrapper(gym.core.ObservationWrapper):
"""
Fully observable gridworld using a compact grid encoding
"""
def __init__(self, env):
super().__init__(env)
self.observation_space.spaces["image"] = spaces.Box(
low=0,
high=255,
shape=(self.env.width, self.env.height, 3), # number of cells
dtype='uint8'
)
def observation(self, obs):
env = self.unwrapped
full_grid = env.grid.encode()
full_grid[env.agent_pos[0]][env.agent_pos[1]] = np.array([
OBJECT_TO_IDX['agent'],
COLOR_TO_IDX['red'],
env.agent_dir
])
return {
'mission': obs['mission'],
'image': full_grid
}
class FlatObsWrapper(gym.core.ObservationWrapper):
"""
Encode mission strings using a one-hot scheme,
and combine these with observed images into one flat array
"""
def __init__(self, env, maxStrLen=96):
super().__init__(env)
self.maxStrLen = maxStrLen
self.numCharCodes = 27
imgSpace = env.observation_space.spaces['image']
imgSize = reduce(operator.mul, imgSpace.shape, 1)
self.observation_space = spaces.Box(
low=0,
high=255,
shape=(imgSize + self.numCharCodes * self.maxStrLen,),
dtype='uint8'
)
self.cachedStr = None
self.cachedArray = None
def observation(self, obs):
image = obs['image']
mission = obs['mission']
# Cache the last-encoded mission string
if mission != self.cachedStr:
assert len(mission) <= self.maxStrLen, 'mission string too long ({} chars)'.format(len(mission))
mission = mission.lower()
strArray = np.zeros(shape=(self.maxStrLen, self.numCharCodes), dtype='float32')
for idx, ch in enumerate(mission):
if ch >= 'a' and ch <= 'z':
chNo = ord(ch) - ord('a')
elif ch == ' ':
chNo = ord('z') - ord('a') + 1
assert chNo < self.numCharCodes, '%s : %d' % (ch, chNo)
strArray[idx, chNo] = 1
self.cachedStr = mission
self.cachedArray = strArray
obs = np.concatenate((image.flatten(), self.cachedArray.flatten()))
return obs
class ViewSizeWrapper(gym.core.Wrapper):
"""
Wrapper to customize the agent field of view size.
This cannot be used with fully observable wrappers.
"""
def __init__(self, env, agent_view_size=7):
super().__init__(env)
assert agent_view_size % 2 == 1
assert agent_view_size >= 3
# Override default view size
env.unwrapped.agent_view_size = agent_view_size
# Compute observation space with specified view size
observation_space = gym.spaces.Box(
low=0,
high=255,
shape=(agent_view_size, agent_view_size, 3),
dtype='uint8'
)
# Override the environment's observation space
self.observation_space = spaces.Dict({
'image': observation_space
})
def reset(self, **kwargs):
return self.env.reset(**kwargs)
def step(self, action):
return self.env.step(action)
from .minigrid import Goal
class DirectionObsWrapper(gym.core.ObservationWrapper):
"""
Provides the slope/angular direction to the goal with the observations as modeled by (y2 - y2 )/( x2 - x1)
type = {slope , angle}
"""
def __init__(self, env,type='slope'):
super().__init__(env)
self.goal_position = None
self.type = type
def reset(self):
obs = self.env.reset()
if not self.goal_position:
self.goal_position = [x for x,y in enumerate(self.grid.grid) if isinstance(y,(Goal) ) ]
if len(self.goal_position) >= 1: # in case there are multiple goals , needs to be handled for other env types
self.goal_position = (int(self.goal_position[0]/self.height) , self.goal_position[0]%self.width)
return obs
def observation(self, obs):
slope = np.divide( self.goal_position[1] - self.agent_pos[1] , self.goal_position[0] - self.agent_pos[0])
obs['goal_direction'] = np.arctan( slope ) if self.type == 'angle' else slope
return obs