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graphicsDisplay.py
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graphicsDisplay.py
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# graphicsDisplay.py
# ------------------
# Licensing Information: You are free to use or extend these projects for
# educational purposes provided that (1) you do not distribute or publish
# solutions, (2) you retain this notice, and (3) you provide clear
# attribution to UC Berkeley, including a link to http://ai.berkeley.edu.
#
# Attribution Information: The Pacman AI projects were developed at UC Berkeley.
# The core projects and autograders were primarily created by John DeNero
# ([email protected]) and Dan Klein ([email protected]).
# Student side autograding was added by Brad Miller, Nick Hay, and
# Pieter Abbeel ([email protected]).
from graphicsUtils import *
import math
import time
from game import Directions
###########################
# GRAPHICS DISPLAY CODE #
###########################
# Most code by Dan Klein and John Denero written or rewritten for cs188, UC Berkeley.
# Some code from a Pacman implementation by LiveWires, and used / modified
# with permission.
DEFAULT_GRID_SIZE = 30.0
INFO_PANE_HEIGHT = 35
BACKGROUND_COLOR = formatColor(0, 0, 0)
WALL_COLOR = formatColor(0.0 / 255.0, 51.0 / 255.0, 255.0 / 255.0)
INFO_PANE_COLOR = formatColor(.4, .4, 0)
SCORE_COLOR = formatColor(.9, .9, .9)
PACMAN_OUTLINE_WIDTH = 2
PACMAN_CAPTURE_OUTLINE_WIDTH = 4
GHOST_COLORS = []
GHOST_COLORS.append(formatColor(.9, 0, 0)) # Red
GHOST_COLORS.append(formatColor(0, .3, .9)) # Blue
GHOST_COLORS.append(formatColor(.98, .41, .07)) # Orange
GHOST_COLORS.append(formatColor(.1, .75, .7)) # Green
GHOST_COLORS.append(formatColor(1.0, 0.6, 0.0)) # Yellow
GHOST_COLORS.append(formatColor(.4, 0.13, 0.91)) # Purple
TEAM_COLORS = GHOST_COLORS[:2]
GHOST_SHAPE = [
(0, 0.3),
(0.25, 0.75),
(0.5, 0.3),
(0.75, 0.75),
(0.75, -0.5),
(0.5, -0.75),
(-0.5, -0.75),
(-0.75, -0.5),
(-0.75, 0.75),
(-0.5, 0.3),
(-0.25, 0.75)
]
GHOST_SIZE = 0.65
SCARED_COLOR = formatColor(1, 1, 1)
GHOST_VEC_COLORS = list(map(colorToVector, GHOST_COLORS))
PACMAN_COLOR = formatColor(255.0 / 255.0, 255.0 / 255.0, 61.0 / 255)
PACMAN_SCALE = 0.5
#pacman_speed = 0.25
# Food
FOOD_COLOR = formatColor(1, 1, 1)
FOOD_SIZE = 0.1
# Laser
LASER_COLOR = formatColor(1, 0, 0)
LASER_SIZE = 0.02
# Capsule graphics
CAPSULE_COLOR = formatColor(1, 1, 1)
CAPSULE_SIZE = 0.25
# Drawing walls
WALL_RADIUS = 0.15
class InfoPane:
def __init__(self, layout, gridSize):
self.gridSize = gridSize
self.width = (layout.width) * gridSize
self.base = (layout.height + 1) * gridSize
self.height = INFO_PANE_HEIGHT
self.fontSize = 24
self.textColor = PACMAN_COLOR
self.drawPane()
def toScreen(self, pos, y=None):
"""
Translates a point relative from the bottom left of the info pane.
"""
if y == None:
x, y = pos
else:
x = pos
x = self.gridSize + x # Margin
y = self.base + y
return x, y
def drawPane(self):
self.scoreText = text(self.toScreen(
0, 0), self.textColor, "SCORE: 0", "Times", self.fontSize, "bold")
def initializeGhostDistances(self, distances):
self.ghostDistanceText = []
size = 20
if self.width < 240:
size = 12
if self.width < 160:
size = 10
for i, d in enumerate(distances):
t = text(self.toScreen(self.width / 2 + self.width / 8 * i,
0), GHOST_COLORS[i + 1], d, "Times", size, "bold")
self.ghostDistanceText.append(t)
def updateScore(self, score):
changeText(self.scoreText, "SCORE: % 4d" % score)
def setTeam(self, isBlue):
text = "RED TEAM"
if isBlue:
text = "BLUE TEAM"
self.teamText = text(self.toScreen(
300, 0), self.textColor, text, "Times", self.fontSize, "bold")
def updateGhostDistances(self, distances):
if len(distances) == 0:
return
if 'ghostDistanceText' not in dir(self):
self.initializeGhostDistances(distances)
else:
for i, d in enumerate(distances):
changeText(self.ghostDistanceText[i], d)
def drawGhost(self):
pass
def drawPacman(self):
pass
def drawWarning(self):
pass
def clearIcon(self):
pass
def updateMessage(self, message):
pass
def clearMessage(self):
pass
class PacmanGraphics:
def __init__(self, zoom=1.0, frameTime=0.0, capture=False):
self.have_window = 0
self.currentGhostImages = {}
self.pacmanImage = None
self.zoom = zoom
self.gridSize = DEFAULT_GRID_SIZE * zoom
self.capture = capture
self.frameTime = frameTime
def checkNullDisplay(self):
return False
def initialize(self, state, isBlue=False):
self.isBlue = isBlue
self.startGraphics(state)
# self.drawDistributions(state)
self.distributionImages = None # Initialized lazily
self.drawStaticObjects(state)
self.drawAgentObjects(state)
# Information
self.previousState = state
def startGraphics(self, state):
self.layout = state.layout
layout = self.layout
self.width = layout.width
self.height = layout.height
self.make_window(self.width, self.height)
self.infoPane = InfoPane(layout, self.gridSize)
self.currentState = layout
def drawDistributions(self, state):
walls = state.layout.walls
dist = []
for x in range(walls.width):
distx = []
dist.append(distx)
for y in range(walls.height):
(screen_x, screen_y) = self.to_screen((x, y))
block = square((screen_x, screen_y),
0.5 * self.gridSize,
color=BACKGROUND_COLOR,
filled=1, behind=2)
distx.append(block)
self.distributionImages = dist
def drawStaticObjects(self, state):
layout = self.layout
self.drawWalls(layout.walls)
self.food = self.drawFood(layout.food)
self.capsules = self.drawCapsules(layout.capsules)
refresh()
def drawAgentObjects(self, state):
self.agentImages = [] # (agentState, image)
for index, agent in enumerate(state.agentStates):
if agent.isPacman:
image = self.drawPacman(agent, index)
self.agentImages.append((agent, image))
else:
image = self.drawGhost(agent, index)
self.agentImages.append((agent, image))
refresh()
def swapImages(self, agentIndex, newState):
"""
Changes an image from a ghost to a pacman or vis versa (for capture)
"""
prevState, prevImage = self.agentImages[agentIndex]
for item in prevImage:
remove_from_screen(item)
if newState.isPacman:
image = self.drawPacman(newState, agentIndex)
self.agentImages[agentIndex] = (newState, image)
else:
image = self.drawGhost(newState, agentIndex)
self.agentImages[agentIndex] = (newState, image)
refresh()
def update(self, newState):
agentIndex = newState._agentMoved
agentState = newState.agentStates[agentIndex]
if self.agentImages[agentIndex][0].isPacman != agentState.isPacman:
self.swapImages(agentIndex, agentState)
prevState, prevImage = self.agentImages[agentIndex]
if agentState.isPacman:
self.animatePacman(agentState, prevState, prevImage)
else:
self.moveGhost(agentState, agentIndex, prevState, prevImage)
self.agentImages[agentIndex] = (agentState, prevImage)
if newState._foodEaten != None:
self.removeFood(newState._foodEaten, self.food)
if newState._capsuleEaten != None:
self.removeCapsule(newState._capsuleEaten, self.capsules)
self.infoPane.updateScore(newState.score)
if 'ghostDistances' in dir(newState):
self.infoPane.updateGhostDistances(newState.ghostDistances)
def make_window(self, width, height):
grid_width = (width - 1) * self.gridSize
grid_height = (height - 1) * self.gridSize
screen_width = 2 * self.gridSize + grid_width
screen_height = 2 * self.gridSize + grid_height + INFO_PANE_HEIGHT
begin_graphics(screen_width,
screen_height,
BACKGROUND_COLOR,
"CS188 Pacman")
def drawPacman(self, pacman, index):
position = self.getPosition(pacman)
screen_point = self.to_screen(position)
endpoints = self.getEndpoints(self.getDirection(pacman))
width = PACMAN_OUTLINE_WIDTH
outlineColor = PACMAN_COLOR
fillColor = PACMAN_COLOR
if self.capture:
outlineColor = TEAM_COLORS[index % 2]
fillColor = GHOST_COLORS[index]
width = PACMAN_CAPTURE_OUTLINE_WIDTH
return [circle(screen_point, PACMAN_SCALE * self.gridSize,
fillColor=fillColor, outlineColor=outlineColor,
endpoints=endpoints,
width=width)]
def getEndpoints(self, direction, position=(0, 0)):
x, y = position
pos = x - int(x) + y - int(y)
width = 30 + 80 * math.sin(math.pi * pos)
delta = width / 2
if (direction == 'West'):
endpoints = (180 + delta, 180 - delta)
elif (direction == 'North'):
endpoints = (90 + delta, 90 - delta)
elif (direction == 'South'):
endpoints = (270 + delta, 270 - delta)
else:
endpoints = (0 + delta, 0 - delta)
return endpoints
def movePacman(self, position, direction, image):
screenPosition = self.to_screen(position)
endpoints = self.getEndpoints(direction, position)
r = PACMAN_SCALE * self.gridSize
moveCircle(image[0], screenPosition, r, endpoints)
refresh()
def animatePacman(self, pacman, prevPacman, image):
if self.frameTime < 0:
print('Press any key to step forward, "q" to play')
keys = wait_for_keys()
if 'q' in keys:
self.frameTime = 0.1
if self.frameTime > 0.01 or self.frameTime < 0:
start = time.time()
fx, fy = self.getPosition(prevPacman)
px, py = self.getPosition(pacman)
frames = 4.0
for i in range(1, int(frames) + 1):
pos = px * i / frames + fx * \
(frames - i) / frames, py * i / \
frames + fy * (frames - i) / frames
self.movePacman(pos, self.getDirection(pacman), image)
refresh()
sleep(abs(self.frameTime) / frames)
else:
self.movePacman(self.getPosition(pacman),
self.getDirection(pacman), image)
refresh()
def getGhostColor(self, ghost, ghostIndex):
if ghost.scaredTimer > 0:
return SCARED_COLOR
else:
return GHOST_COLORS[ghostIndex]
def drawGhost(self, ghost, agentIndex):
pos = self.getPosition(ghost)
dir = self.getDirection(ghost)
(screen_x, screen_y) = (self.to_screen(pos))
coords = []
for (x, y) in GHOST_SHAPE:
coords.append((x * self.gridSize * GHOST_SIZE + screen_x,
y * self.gridSize * GHOST_SIZE + screen_y))
colour = self.getGhostColor(ghost, agentIndex)
body = polygon(coords, colour, filled=1)
WHITE = formatColor(1.0, 1.0, 1.0)
BLACK = formatColor(0.0, 0.0, 0.0)
dx = 0
dy = 0
if dir == 'North':
dy = -0.2
if dir == 'South':
dy = 0.2
if dir == 'East':
dx = 0.2
if dir == 'West':
dx = -0.2
leftEye = circle((screen_x + self.gridSize * GHOST_SIZE * (-0.3 + dx / 1.5), screen_y -
self.gridSize * GHOST_SIZE * (0.3 - dy / 1.5)), self.gridSize * GHOST_SIZE * 0.2, WHITE, WHITE)
rightEye = circle((screen_x + self.gridSize * GHOST_SIZE * (0.3 + dx / 1.5), screen_y -
self.gridSize * GHOST_SIZE * (0.3 - dy / 1.5)), self.gridSize * GHOST_SIZE * 0.2, WHITE, WHITE)
leftPupil = circle((screen_x + self.gridSize * GHOST_SIZE * (-0.3 + dx), screen_y -
self.gridSize * GHOST_SIZE * (0.3 - dy)), self.gridSize * GHOST_SIZE * 0.08, BLACK, BLACK)
rightPupil = circle((screen_x + self.gridSize * GHOST_SIZE * (0.3 + dx), screen_y -
self.gridSize * GHOST_SIZE * (0.3 - dy)), self.gridSize * GHOST_SIZE * 0.08, BLACK, BLACK)
ghostImageParts = []
ghostImageParts.append(body)
ghostImageParts.append(leftEye)
ghostImageParts.append(rightEye)
ghostImageParts.append(leftPupil)
ghostImageParts.append(rightPupil)
return ghostImageParts
def moveEyes(self, pos, dir, eyes):
(screen_x, screen_y) = (self.to_screen(pos))
dx = 0
dy = 0
if dir == 'North':
dy = -0.2
if dir == 'South':
dy = 0.2
if dir == 'East':
dx = 0.2
if dir == 'West':
dx = -0.2
moveCircle(eyes[0], (screen_x + self.gridSize * GHOST_SIZE * (-0.3 + dx / 1.5), screen_y -
self.gridSize * GHOST_SIZE * (0.3 - dy / 1.5)), self.gridSize * GHOST_SIZE * 0.2)
moveCircle(eyes[1], (screen_x + self.gridSize * GHOST_SIZE * (0.3 + dx / 1.5), screen_y -
self.gridSize * GHOST_SIZE * (0.3 - dy / 1.5)), self.gridSize * GHOST_SIZE * 0.2)
moveCircle(eyes[2], (screen_x + self.gridSize * GHOST_SIZE * (-0.3 + dx), screen_y -
self.gridSize * GHOST_SIZE * (0.3 - dy)), self.gridSize * GHOST_SIZE * 0.08)
moveCircle(eyes[3], (screen_x + self.gridSize * GHOST_SIZE * (0.3 + dx), screen_y -
self.gridSize * GHOST_SIZE * (0.3 - dy)), self.gridSize * GHOST_SIZE * 0.08)
def moveGhost(self, ghost, ghostIndex, prevGhost, ghostImageParts):
old_x, old_y = self.to_screen(self.getPosition(prevGhost))
new_x, new_y = self.to_screen(self.getPosition(ghost))
delta = new_x - old_x, new_y - old_y
for ghostImagePart in ghostImageParts:
move_by(ghostImagePart, delta)
refresh()
if ghost.scaredTimer > 0:
color = SCARED_COLOR
else:
color = GHOST_COLORS[ghostIndex]
edit(ghostImageParts[0], ('fill', color), ('outline', color))
self.moveEyes(self.getPosition(ghost),
self.getDirection(ghost), ghostImageParts[-4:])
refresh()
def getPosition(self, agentState):
if agentState.configuration == None:
return (-1000, -1000)
return agentState.getPosition()
def getDirection(self, agentState):
if agentState.configuration == None:
return Directions.STOP
return agentState.configuration.getDirection()
def finish(self):
end_graphics()
def to_screen(self, point):
(x, y) = point
#y = self.height - y
x = (x + 1) * self.gridSize
y = (self.height - y) * self.gridSize
return (x, y)
# Fixes some TK issue with off-center circles
def to_screen2(self, point):
(x, y) = point
#y = self.height - y
x = (x + 1) * self.gridSize
y = (self.height - y) * self.gridSize
return (x, y)
def drawWalls(self, wallMatrix):
wallColor = WALL_COLOR
for xNum, x in enumerate(wallMatrix):
if self.capture and (xNum * 2) < wallMatrix.width:
wallColor = TEAM_COLORS[0]
if self.capture and (xNum * 2) >= wallMatrix.width:
wallColor = TEAM_COLORS[1]
for yNum, cell in enumerate(x):
if cell: # There's a wall here
pos = (xNum, yNum)
screen = self.to_screen(pos)
screen2 = self.to_screen2(pos)
# draw each quadrant of the square based on adjacent walls
wIsWall = self.isWall(xNum - 1, yNum, wallMatrix)
eIsWall = self.isWall(xNum + 1, yNum, wallMatrix)
nIsWall = self.isWall(xNum, yNum + 1, wallMatrix)
sIsWall = self.isWall(xNum, yNum - 1, wallMatrix)
nwIsWall = self.isWall(xNum - 1, yNum + 1, wallMatrix)
swIsWall = self.isWall(xNum - 1, yNum - 1, wallMatrix)
neIsWall = self.isWall(xNum + 1, yNum + 1, wallMatrix)
seIsWall = self.isWall(xNum + 1, yNum - 1, wallMatrix)
# NE quadrant
if (not nIsWall) and (not eIsWall):
# inner circle
circle(screen2, WALL_RADIUS * self.gridSize,
wallColor, wallColor, (0, 91), 'arc')
if (nIsWall) and (not eIsWall):
# vertical line
line(add(screen, (self.gridSize * WALL_RADIUS, 0)), add(screen,
(self.gridSize * WALL_RADIUS, self.gridSize * (-0.5) - 1)), wallColor)
if (not nIsWall) and (eIsWall):
# horizontal line
line(add(screen, (0, self.gridSize * (-1) * WALL_RADIUS)), add(screen,
(self.gridSize * 0.5 + 1, self.gridSize * (-1) * WALL_RADIUS)), wallColor)
if (nIsWall) and (eIsWall) and (not neIsWall):
# outer circle
circle(add(screen2, (self.gridSize * 2 * WALL_RADIUS, self.gridSize * (-2) * WALL_RADIUS)),
WALL_RADIUS * self.gridSize - 1, wallColor, wallColor, (180, 271), 'arc')
line(add(screen, (self.gridSize * 2 * WALL_RADIUS - 1, self.gridSize * (-1) * WALL_RADIUS)),
add(screen, (self.gridSize * 0.5 + 1, self.gridSize * (-1) * WALL_RADIUS)), wallColor)
line(add(screen, (self.gridSize * WALL_RADIUS, self.gridSize * (-2) * WALL_RADIUS + 1)),
add(screen, (self.gridSize * WALL_RADIUS, self.gridSize * (-0.5))), wallColor)
# NW quadrant
if (not nIsWall) and (not wIsWall):
# inner circle
circle(screen2, WALL_RADIUS * self.gridSize,
wallColor, wallColor, (90, 181), 'arc')
if (nIsWall) and (not wIsWall):
# vertical line
line(add(screen, (self.gridSize * (-1) * WALL_RADIUS, 0)), add(screen,
(self.gridSize * (-1) * WALL_RADIUS, self.gridSize * (-0.5) - 1)), wallColor)
if (not nIsWall) and (wIsWall):
# horizontal line
line(add(screen, (0, self.gridSize * (-1) * WALL_RADIUS)), add(screen,
(self.gridSize * (-0.5) - 1, self.gridSize * (-1) * WALL_RADIUS)), wallColor)
if (nIsWall) and (wIsWall) and (not nwIsWall):
# outer circle
circle(add(screen2, (self.gridSize * (-2) * WALL_RADIUS, self.gridSize * (-2) * WALL_RADIUS)),
WALL_RADIUS * self.gridSize - 1, wallColor, wallColor, (270, 361), 'arc')
line(add(screen, (self.gridSize * (-2) * WALL_RADIUS + 1, self.gridSize * (-1) * WALL_RADIUS)),
add(screen, (self.gridSize * (-0.5), self.gridSize * (-1) * WALL_RADIUS)), wallColor)
line(add(screen, (self.gridSize * (-1) * WALL_RADIUS, self.gridSize * (-2) * WALL_RADIUS + 1)),
add(screen, (self.gridSize * (-1) * WALL_RADIUS, self.gridSize * (-0.5))), wallColor)
# SE quadrant
if (not sIsWall) and (not eIsWall):
# inner circle
circle(screen2, WALL_RADIUS * self.gridSize,
wallColor, wallColor, (270, 361), 'arc')
if (sIsWall) and (not eIsWall):
# vertical line
line(add(screen, (self.gridSize * WALL_RADIUS, 0)), add(screen,
(self.gridSize * WALL_RADIUS, self.gridSize * (0.5) + 1)), wallColor)
if (not sIsWall) and (eIsWall):
# horizontal line
line(add(screen, (0, self.gridSize * (1) * WALL_RADIUS)), add(screen,
(self.gridSize * 0.5 + 1, self.gridSize * (1) * WALL_RADIUS)), wallColor)
if (sIsWall) and (eIsWall) and (not seIsWall):
# outer circle
circle(add(screen2, (self.gridSize * 2 * WALL_RADIUS, self.gridSize * (2) * WALL_RADIUS)),
WALL_RADIUS * self.gridSize - 1, wallColor, wallColor, (90, 181), 'arc')
line(add(screen, (self.gridSize * 2 * WALL_RADIUS - 1, self.gridSize * (1) * WALL_RADIUS)),
add(screen, (self.gridSize * 0.5, self.gridSize * (1) * WALL_RADIUS)), wallColor)
line(add(screen, (self.gridSize * WALL_RADIUS, self.gridSize * (2) * WALL_RADIUS - 1)),
add(screen, (self.gridSize * WALL_RADIUS, self.gridSize * (0.5))), wallColor)
# SW quadrant
if (not sIsWall) and (not wIsWall):
# inner circle
circle(screen2, WALL_RADIUS * self.gridSize,
wallColor, wallColor, (180, 271), 'arc')
if (sIsWall) and (not wIsWall):
# vertical line
line(add(screen, (self.gridSize * (-1) * WALL_RADIUS, 0)), add(screen,
(self.gridSize * (-1) * WALL_RADIUS, self.gridSize * (0.5) + 1)), wallColor)
if (not sIsWall) and (wIsWall):
# horizontal line
line(add(screen, (0, self.gridSize * (1) * WALL_RADIUS)), add(screen,
(self.gridSize * (-0.5) - 1, self.gridSize * (1) * WALL_RADIUS)), wallColor)
if (sIsWall) and (wIsWall) and (not swIsWall):
# outer circle
circle(add(screen2, (self.gridSize * (-2) * WALL_RADIUS, self.gridSize * (2) * WALL_RADIUS)),
WALL_RADIUS * self.gridSize - 1, wallColor, wallColor, (0, 91), 'arc')
line(add(screen, (self.gridSize * (-2) * WALL_RADIUS + 1, self.gridSize * (1) * WALL_RADIUS)),
add(screen, (self.gridSize * (-0.5), self.gridSize * (1) * WALL_RADIUS)), wallColor)
line(add(screen, (self.gridSize * (-1) * WALL_RADIUS, self.gridSize * (2) * WALL_RADIUS - 1)),
add(screen, (self.gridSize * (-1) * WALL_RADIUS, self.gridSize * (0.5))), wallColor)
def isWall(self, x, y, walls):
if x < 0 or y < 0:
return False
if x >= walls.width or y >= walls.height:
return False
return walls[x][y]
def drawFood(self, foodMatrix):
foodImages = []
color = FOOD_COLOR
for xNum, x in enumerate(foodMatrix):
if self.capture and (xNum * 2) <= foodMatrix.width:
color = TEAM_COLORS[0]
if self.capture and (xNum * 2) > foodMatrix.width:
color = TEAM_COLORS[1]
imageRow = []
foodImages.append(imageRow)
for yNum, cell in enumerate(x):
if cell: # There's food here
screen = self.to_screen((xNum, yNum))
dot = circle(screen,
FOOD_SIZE * self.gridSize,
outlineColor=color, fillColor=color,
width=1)
imageRow.append(dot)
else:
imageRow.append(None)
return foodImages
def drawCapsules(self, capsules):
capsuleImages = {}
for capsule in capsules:
(screen_x, screen_y) = self.to_screen(capsule)
dot = circle((screen_x, screen_y),
CAPSULE_SIZE * self.gridSize,
outlineColor=CAPSULE_COLOR,
fillColor=CAPSULE_COLOR,
width=1)
capsuleImages[capsule] = dot
return capsuleImages
def removeFood(self, cell, foodImages):
x, y = cell
remove_from_screen(foodImages[x][y])
def removeCapsule(self, cell, capsuleImages):
x, y = cell
remove_from_screen(capsuleImages[(x, y)])
def drawExpandedCells(self, cells):
"""
Draws an overlay of expanded grid positions for search agents
"""
n = float(len(cells))
baseColor = [1.0, 0.0, 0.0]
self.clearExpandedCells()
self.expandedCells = []
for k, cell in enumerate(cells):
screenPos = self.to_screen(cell)
cellColor = formatColor(
*[(n - k) * c * .5 / n + .25 for c in baseColor])
block = square(screenPos,
0.5 * self.gridSize,
color=cellColor,
filled=1, behind=2)
self.expandedCells.append(block)
if self.frameTime < 0:
refresh()
def clearExpandedCells(self):
if 'expandedCells' in dir(self) and len(self.expandedCells) > 0:
for cell in self.expandedCells:
remove_from_screen(cell)
def updateDistributions(self, distributions):
"Draws an agent's belief distributions"
# copy all distributions so we don't change their state
distributions = [x.copy() for x in distributions]
if self.distributionImages == None:
self.drawDistributions(self.previousState)
for x in range(len(self.distributionImages)):
for y in range(len(self.distributionImages[0])):
image = self.distributionImages[x][y]
weights = [dist[(x, y)] for dist in distributions]
if sum(weights) != 0:
pass
# Fog of war
color = [0.0, 0.0, 0.0]
colors = GHOST_VEC_COLORS[1:] # With Pacman
if self.capture:
colors = GHOST_VEC_COLORS
for weight, gcolor in zip(weights, colors):
color = [min(1.0, c + 0.95 * g * weight ** .3)
for c, g in zip(color, gcolor)]
changeColor(image, formatColor(*color))
refresh()
class FirstPersonPacmanGraphics(PacmanGraphics):
def __init__(self, zoom=1.0, showGhosts=True, capture=False, frameTime=0):
PacmanGraphics.__init__(self, zoom, frameTime=frameTime)
self.showGhosts = showGhosts
self.capture = capture
def initialize(self, state, isBlue=False):
self.isBlue = isBlue
PacmanGraphics.startGraphics(self, state)
# Initialize distribution images
walls = state.layout.walls
dist = []
self.layout = state.layout
# Draw the rest
self.distributionImages = None # initialize lazily
self.drawStaticObjects(state)
self.drawAgentObjects(state)
# Information
self.previousState = state
def lookAhead(self, config, state):
if config.getDirection() == 'Stop':
return
else:
pass
# Draw relevant ghosts
allGhosts = state.getGhostStates()
visibleGhosts = state.getVisibleGhosts()
for i, ghost in enumerate(allGhosts):
if ghost in visibleGhosts:
self.drawGhost(ghost, i)
else:
self.currentGhostImages[i] = None
def getGhostColor(self, ghost, ghostIndex):
return GHOST_COLORS[ghostIndex]
def getPosition(self, ghostState):
if not self.showGhosts and not ghostState.isPacman and ghostState.getPosition()[1] > 1:
return (-1000, -1000)
else:
return PacmanGraphics.getPosition(self, ghostState)
def add(x, y):
return (x[0] + y[0], x[1] + y[1])
# Saving graphical output
# -----------------------
# Note: to make an animated gif from this postscript output, try the command:
# convert -delay 7 -loop 1 -compress lzw -layers optimize frame* out.gif
# convert is part of imagemagick (freeware)
SAVE_POSTSCRIPT = False
POSTSCRIPT_OUTPUT_DIR = 'frames'
FRAME_NUMBER = 0
import os
def saveFrame():
"Saves the current graphical output as a postscript file"
global SAVE_POSTSCRIPT, FRAME_NUMBER, POSTSCRIPT_OUTPUT_DIR
if not SAVE_POSTSCRIPT:
return
if not os.path.exists(POSTSCRIPT_OUTPUT_DIR):
os.mkdir(POSTSCRIPT_OUTPUT_DIR)
name = os.path.join(POSTSCRIPT_OUTPUT_DIR, 'frame_%08d.ps' % FRAME_NUMBER)
FRAME_NUMBER += 1
writePostscript(name) # writes the current canvas