self.types = types # List of possible types the piece can be (should just be two)
self.current_type = "unknown" # Current type
self.choice = -1 # Index of the current type in self.types (-1 = unknown type)
- self.types_revealed = [True, False] # Whether the types are known (by default the first type is always known at game start)
-
- #
+
self.last_state = None
+
self.move_pattern = None
-
+ self.coverage = None
+ self.possible_moves = None
def init_from_copy(self, c):
self.types = c.types[:]
self.current_type = c.current_type
self.choice = c.choice
- self.types_revealed = c.types_revealed[:]
-
+
self.last_state = None
self.move_pattern = None
# Make a string for the piece (used for debug)
def __str__(self):
- return str(self.current_type) + " " + str(self.types) + " at " + str(self.x) + ","+str(self.y)
+ return str(self.colour) + " " + str(self.current_type) + " " + str(self.types) + " at " + str(self.x) + ","+str(self.y)
# Draw the piece in a pygame surface
def draw(self, window, grid_sz = [80,80], style="quantum"):
# Draw the two possible types underneath the current_type image
for i in range(len(self.types)):
- if self.types_revealed[i] == True:
+ if always_reveal_states == True or self.types[i][0] != '?':
img = small_images[self.colour][self.types[i]]
else:
img = small_images[self.colour]["unknown"] # If the type hasn't been revealed, show a placeholder
# Collapses the wave function!
def select(self):
- if self.current_type == "unknown":
+ if self.current_type == "unknown" or not self.choice in [0,1]:
self.choice = random.randint(0,1)
+ if self.types[self.choice][0] == '?':
+ self.types[self.choice] = self.types[self.choice][1:]
self.current_type = self.types[self.choice]
- self.types_revealed[self.choice] = True
return self.choice
# Uncollapses (?) the wave function!
def deselect(self):
#print "Deselect called"
if (self.x + self.y) % 2 != 0:
- if (self.types[0] != self.types[1]) or (self.types_revealed[0] == False or self.types_revealed[1] == False):
+ if (self.types[0] != self.types[1]) or (self.types[0][0] == '?' or self.types[1][0] == '?'):
self.current_type = "unknown"
self.choice = -1
else:
# --- piece.py --- #
[w,h] = [8,8] # Width and height of board(s)
+always_reveal_states = False
+
# Class to represent a quantum chess board
class Board():
# Initialise; if master=True then the secondary piece types are assigned
self.grid = [[None] * w for _ in range(h)] # 2D List (you can get arrays in python, somehow, but they scare me)
self.unrevealed_types = {"white" : piece_types.copy(), "black" : piece_types.copy()}
self.king = {"white" : None, "black" : None} # We need to keep track of the king, because he is important
+ self.max_moves = None
+ self.moves = 0
+ self.move_stack = []
for c in ["black", "white"]:
del self.unrevealed_types[c]["unknown"]
+ if style == "empty":
+ return
+
# Add all the pieces with known primary types
for i in range(0, 2):
c.append(Piece(s, 1, y, ["knight"]))
c.append(Piece(s, 2, y, ["bishop"]))
k = Piece(s, 3, y, ["king", "king"]) # There can only be one ruler!
- k.types_revealed[1] = True
k.current_type = "king"
self.king[s] = k
c.append(k)
types_left[choice] -= 1
if types_left[choice] <= 0:
del types_left[choice]
- piece.types.append(choice)
+ piece.types.append('?' + choice)
elif style == "classical":
piece.types.append(piece.types[0])
piece.current_type = piece.types[0]
- piece.types_revealed[1] = True
piece.choice = 0
def clone(self):
for i in range(len(mypieces)):
newpieces[i].init_from_copy(mypieces[i])
+
+ # Reset the board from a string
+ def reset_board(self, s):
+ self.pieces = {"white" : [], "black" : []}
+ self.king = {"white" : None, "black" : None}
+ self.grid = [[None] * w for _ in range(h)]
+ for x in range(w):
+ for y in range(h):
+ self.grid[x][y] = None
+
+ for line in s.split("\n"):
+ if line == "":
+ continue
+ if line[0] == "#":
+ continue
+
+ tokens = line.split(" ")
+ [x, y] = map(int, tokens[len(tokens)-1].split(","))
+ current_type = tokens[1]
+ types = map(lambda e : e.strip(" '[],"), line.split('[')[1].split(']')[0].split(','))
+
+ target = Piece(tokens[0], x, y, types)
+ target.current_type = current_type
+
+ try:
+ target.choice = types.index(current_type)
+ except:
+ target.choice = -1
+
+ self.pieces[tokens[0]].append(target)
+ if target.current_type == "king":
+ self.king[tokens[0]] = target
+
+ self.grid[x][y] = target
def display_grid(self, window = None, grid_sz = [80,80]):
del self.unrevealed_types[piece.colour][state]
piece.types[type_index] = state
- piece.types_revealed[type_index] = True
piece.current_type = state
if len(self.possible_moves(piece)) <= 0:
piece.deselect() # Piece can't move; deselect it
+
+ # Piece needs to recalculate moves
+ piece.possible_moves = None
# Update the board when a piece has been moved
def update_move(self, x, y, x2, y2):
+
piece = self.grid[x][y]
+ #print "Moving " + str(x) + "," + str(y) + " to " + str(x2) + "," + str(y2) + "; possible_moves are " + str(self.possible_moves(piece))
+
+ if not [x2,y2] in self.possible_moves(piece):
+ raise Exception("ILLEGAL move")
+
self.grid[x][y] = None
taken = self.grid[x2][y2]
if taken != None:
piece.current_type = "queen"
piece.deselect() # Uncollapse (?) the wavefunction!
- self.verify()
+ self.moves += 1
+
+ # All other pieces need to recalculate moves
+ for p in self.pieces["white"] + self.pieces["black"]:
+ p.possible_moves = None
+
+ #self.verify()
# Update the board from a string
# Guesses what to do based on the format of the string
if prob > 0:
result.update({p : prob})
- self.verify()
+ #self.verify()
return result
for i in range(len(p.types)):
t = p.types[i]
prob = 0.5
- if t == "unknown" or p.types_revealed[i] == False:
+ if t == "unknown" or p.types[i][0] == '?':
total_types = 0
for t2 in self.unrevealed_types[p.colour].keys():
total_types += self.unrevealed_types[p.colour][t2]
for point in self.possible_moves(p, reject_allied):
result[point[0]][point[1]] += prob
- self.verify()
+ #self.verify()
p.current_type = "unknown"
return result
if t == state:
result += prob
continue
- if t == "unknown" or p.types_revealed[i] == False:
+ if t == "unknown" or p.types[i][0] == '?':
total_prob = 0
for t2 in self.unrevealed_types[p.colour].keys():
total_prob += self.unrevealed_types[p.colour][t2]
# This is probably inefficient, but I looked at some sample chess games and they seem to actually do things this way
# reject_allied indicates whether squares occupied by allied pieces will be removed
# (set to false to check for defense)
- def possible_moves(self, p, reject_allied = True):
- result = []
+ def possible_moves(self, p, reject_allied = True, state=None):
if p == None:
+ raise Exception("SANITY: No piece")
+
+
+
+ if state != None and state != p.current_type:
+ old_type = p.current_type
+ p.current_type = state
+ result = self.possible_moves(p, reject_allied, state=None)
+ p.current_type = old_type
return result
+
+ if p.possible_moves != None:
+ return p.possible_moves
+
+
+ result = []
+
if p.current_type == "unknown":
if g != None and (g.colour == p.colour and reject_allied == True):
result.remove(point) # Remove allied pieces
- self.verify()
+ #self.verify()
+
+ p.possible_moves = result
return result
return p
+ # Returns "white", "black" or "DRAW" if the game should end
+ def end_condition(self):
+ if self.king["white"] == None:
+ if self.king["black"] == None:
+ return "DRAW" # This shouldn't happen
+ return "black"
+ elif self.king["black"] == None:
+ return "white"
+ elif len(self.pieces["white"]) == 1 and len(self.pieces["black"]) == 1:
+ return "DRAW"
+ elif self.max_moves != None and self.moves > self.max_moves:
+ return "DRAW"
+ return None
# I typed the full statement about 30 times before writing this function...
def on_board(self, x, y):
return (x >= 0 and x < w) and (y >= 0 and y < h)
+
+ # Pushes a move temporarily
+ def push_move(self, piece, x, y):
+ target = self.grid[x][y]
+ self.move_stack.append([piece, target, piece.x, piece.y, x, y])
+ [piece.x, piece.y] = [x, y]
+ self.grid[x][y] = piece
+ self.grid[piece.x][piece.y] = None
+
+ for p in self.pieces["white"] + self.pieces["black"]:
+ p.possible_moves = None
+
+ # Restore move
+ def pop_move(self):
+ #print str(self.move_stack)
+ [piece, target, x1, y1, x2, y2] = self.move_stack[len(self.move_stack)-1]
+ self.move_stack = self.move_stack[:-1]
+ piece.x = x1
+ piece.y = y1
+ self.grid[x1][y1] = piece
+ if target != None:
+ target.x = x2
+ target.y = y2
+ self.grid[x2][y2] = target
+
+ for p in self.pieces["white"] + self.pieces["black"]:
+ p.possible_moves = None
+
# --- board.py --- #
import subprocess
import select
self.name = name
self.colour = colour
+ def update(self, result):
+ pass
+
+ def reset_board(self, s):
+ pass
+
# Player that runs from another process
-class AgentPlayer(Player):
+class ExternalAgent(Player):
def __init__(self, name, colour):
Player.__init__(self, name, colour)
- self.p = subprocess.Popen(name, stdin=subprocess.PIPE, stdout=subprocess.PIPE,stderr=subprocess.PIPE)
+ self.p = subprocess.Popen(name,bufsize=0,stdin=subprocess.PIPE, stdout=subprocess.PIPE, shell=True,universal_newlines=True)
self.send_message(colour)
else:
ready = [self.p.stdin]
if self.p.stdin in ready:
- #print "Writing to p.stdin"
+ #sys.stderr.write("Writing \'" + s + "\' to " + str(self.p) + "\n")
try:
self.p.stdin.write(s + "\n")
except:
raise Exception("UNRESPONSIVE")
else:
- raise Exception("UNRESPONSIVE")
+ raise Exception("TIMEOUT")
def get_response(self):
if agent_timeout > 0.0:
else:
ready = [self.p.stdout]
if self.p.stdout in ready:
- #print "Reading from p.stdout"
+ #sys.stderr.write("Reading from " + str(self.p) + " 's stdout...\n")
try:
- return self.p.stdout.readline().strip("\r\n")
+ result = self.p.stdout.readline().strip("\r\n")
+ #sys.stderr.write("Read \'" + result + "\' from " + str(self.p) + "\n")
+ return result
except: # Exception, e:
raise Exception("UNRESPONSIVE")
else:
- raise Exception("UNRESPONSIVE")
+ raise Exception("TIMEOUT")
def select(self):
raise Exception("GIBBERISH \"" + str(line) + "\"")
return result
+ def reset_board(self, s):
+ self.send_message("BOARD")
+ for line in s.split("\n"):
+ self.send_message(line.strip(" \r\n"))
+ self.send_message("END BOARD")
+
def quit(self, final_result):
try:
self.send_message("QUIT " + final_result)
sys.stdout.write(result + "\n")
-# Player that makes random moves
-class AgentRandom(Player):
+# Default internal player (makes random moves)
+class InternalAgent(Player):
def __init__(self, name, colour):
Player.__init__(self, name, colour)
self.choice = None
self.board = Board(style = "agent")
+
+
+ def update(self, result):
+
+ self.board.update(result)
+ self.board.verify()
+
+ def reset_board(self, s):
+ self.board.reset_board(s)
+
+ def quit(self, final_result):
+ pass
+
+class AgentRandom(InternalAgent):
+ def __init__(self, name, colour):
+ InternalAgent.__init__(self, name, colour)
+
def select(self):
while True:
self.choice = self.board.pieces[self.colour][random.randint(0, len(self.board.pieces[self.colour])-1)]
move = moves[random.randint(0, len(moves)-1)]
return move
- def update(self, result):
- #sys.stderr.write(sys.argv[0] + " : Update board for AgentRandom\n")
- self.board.update(result)
- self.board.verify()
- def quit(self, final_result):
- pass
+# Terrible, terrible hacks
+
+def run_agent(agent):
+ #sys.stderr.write(sys.argv[0] + " : Running agent " + str(agent) + "\n")
+ while True:
+ line = sys.stdin.readline().strip(" \r\n")
+ if line == "SELECTION?":
+ #sys.stderr.write(sys.argv[0] + " : Make selection\n")
+ [x,y] = agent.select() # Gets your agent's selection
+ #sys.stderr.write(sys.argv[0] + " : Selection was " + str(agent.choice) + "\n")
+ sys.stdout.write(str(x) + " " + str(y) + "\n")
+ elif line == "MOVE?":
+ #sys.stderr.write(sys.argv[0] + " : Make move\n")
+ [x,y] = agent.get_move() # Gets your agent's move
+ sys.stdout.write(str(x) + " " + str(y) + "\n")
+ elif line.split(" ")[0] == "QUIT":
+ #sys.stderr.write(sys.argv[0] + " : Quitting\n")
+ agent.quit(" ".join(line.split(" ")[1:])) # Quits the game
+ break
+ elif line.split(" ")[0] == "BOARD":
+ s = ""
+ line = sys.stdin.readline().strip(" \r\n")
+ while line != "END BOARD":
+ s += line + "\n"
+ line = sys.stdin.readline().strip(" \r\n")
+ agent.board.reset_board(s)
+
+ else:
+ agent.update(line) # Updates agent.board
+ return 0
+# Sort of works?
+
+class ExternalWrapper(ExternalAgent):
+ def __init__(self, agent):
+ run = "python -u -c \"import sys;import os;from qchess import *;agent = " + agent.__class__.__name__ + "('" + agent.name + "','"+agent.colour+"');sys.stdin.readline();sys.exit(run_agent(agent))\""
+ # str(run)
+ ExternalAgent.__init__(self, run, agent.colour)
+
+
+
# --- player.py --- #
+# A sample agent
+
+
+class AgentBishop(AgentRandom): # Inherits from AgentRandom (in qchess)
+ def __init__(self, name, colour):
+ InternalAgent.__init__(self, name, colour)
+ self.value = {"pawn" : 1, "bishop" : 3, "knight" : 3, "rook" : 5, "queen" : 9, "king" : 100, "unknown" : 4}
+
+ self.aggression = 2.0 # Multiplier for scoring due to aggressive actions
+ self.defence = 1.0 # Multiplier for scoring due to defensive actions
+
+ self.depth = 0 # Current depth
+ self.max_depth = 2 # Recurse this many times (for some reason, makes more mistakes when this is increased???)
+ self.recurse_for = -1 # Recurse for the best few moves each times (less than 0 = all moves)
+
+ for p in self.board.pieces["white"] + self.board.pieces["black"]:
+ p.last_moves = None
+ p.selected_moves = None
+
+
+
+ def get_value(self, piece):
+ if piece == None:
+ return 0.0
+ return float(self.value[piece.types[0]] + self.value[piece.types[1]]) / 2.0
+
+ # Score possible moves for the piece
+
+ def prioritise_moves(self, piece):
+
+ #sys.stderr.write(sys.argv[0] + " : " + str(self) + " prioritise called for " + str(piece) + "\n")
+
+
+
+ grid = self.board.probability_grid(piece)
+ #sys.stderr.write("\t Probability grid " + str(grid) + "\n")
+ moves = []
+ for x in range(w):
+ for y in range(h):
+ if grid[x][y] < 0.3: # Throw out moves with < 30% probability
+ #sys.stderr.write("\tReject " + str(x) + "," + str(y) + " (" + str(grid[x][y]) + ")\n")
+ continue
+
+ target = self.board.grid[x][y]
+
+
+
+
+ # Get total probability that the move is protected
+ self.board.push_move(piece, x, y)
+
+
+
+ defenders = self.board.coverage(x, y, piece.colour, reject_allied = False)
+ d_prob = 0.0
+ for d in defenders.keys():
+ d_prob += defenders[d]
+ if len(defenders.keys()) > 0:
+ d_prob /= float(len(defenders.keys()))
+
+ if (d_prob > 1.0):
+ d_prob = 1.0
+
+ # Get total probability that the move is threatened
+ attackers = self.board.coverage(x, y, opponent(piece.colour), reject_allied = False)
+ a_prob = 0.0
+ for a in attackers.keys():
+ a_prob += attackers[a]
+ if len(attackers.keys()) > 0:
+ a_prob /= float(len(attackers.keys()))
+
+ if (a_prob > 1.0):
+ a_prob = 1.0
+
+ self.board.pop_move()
+
+
+
+ # Score of the move
+ value = self.aggression * (1.0 + d_prob) * self.get_value(target) - self.defence * (1.0 - d_prob) * a_prob * self.get_value(piece)
+
+ # Adjust score based on movement of piece out of danger
+ attackers = self.board.coverage(piece.x, piece.y, opponent(piece.colour))
+ s_prob = 0.0
+ for a in attackers.keys():
+ s_prob += attackers[a]
+ if len(attackers.keys()) > 0:
+ s_prob /= float(len(attackers.keys()))
+
+ if (s_prob > 1.0):
+ s_prob = 1.0
+ value += self.defence * s_prob * self.get_value(piece)
+
+ # Adjust score based on probability that the move is actually possible
+ moves.append([[x, y], grid[x][y] * value])
+
+ moves.sort(key = lambda e : e[1], reverse = True)
+ #sys.stderr.write(sys.argv[0] + ": Moves for " + str(piece) + " are " + str(moves) + "\n")
+
+ piece.last_moves = moves
+ piece.selected_moves = None
+
+
+
+
+ return moves
+
+ def select_best(self, colour):
+
+ self.depth += 1
+ all_moves = {}
+ for p in self.board.pieces[colour]:
+ self.choice = p # Temporarily pick that piece
+ m = self.prioritise_moves(p)
+ if len(m) > 0:
+ all_moves.update({p : m[0]})
+
+ if len(all_moves.items()) <= 0:
+ return None
+
+
+ opts = all_moves.items()
+ opts.sort(key = lambda e : e[1][1], reverse = True)
+
+ if self.depth >= self.max_depth:
+ self.depth -= 1
+ return list(opts[0])
+
+ if self.recurse_for >= 0:
+ opts = opts[0:self.recurse_for]
+ #sys.stderr.write(sys.argv[0] + " : Before recurse, options are " + str(opts) + "\n")
+
+ # Take the best few moves, and recurse
+ for choice in opts[0:self.recurse_for]:
+ [xx,yy] = [choice[0].x, choice[0].y] # Remember position
+ [nx,ny] = choice[1][0] # Target
+ [choice[0].x, choice[0].y] = [nx, ny] # Set position
+ target = self.board.grid[nx][ny] # Remember piece in spot
+ self.board.grid[xx][yy] = None # Remove piece
+ self.board.grid[nx][ny] = choice[0] # Replace with moving piece
+
+ # Recurse
+ best_enemy_move = self.select_best(opponent(choice[0].colour))
+ choice[1][1] -= best_enemy_move[1][1] / float(self.depth + 1.0)
+
+ [choice[0].x, choice[0].y] = [xx, yy] # Restore position
+ self.board.grid[nx][ny] = target # Restore taken piece
+ self.board.grid[xx][yy] = choice[0] # Restore moved piece
+
+
+
+ opts.sort(key = lambda e : e[1][1], reverse = True)
+ #sys.stderr.write(sys.argv[0] + " : After recurse, options are " + str(opts) + "\n")
+
+ self.depth -= 1
+ return list(opts[0])
+
+
+
+ # Returns [x,y] of selected piece
+ def select(self):
+ #sys.stderr.write("Getting choice...")
+ self.choice = self.select_best(self.colour)[0]
+
+ #sys.stderr.write(" Done " + str(self.choice)+"\n")
+ return [self.choice.x, self.choice.y]
+
+ # Returns [x,y] of square to move selected piece into
+ def get_move(self):
+ #sys.stderr.write("Choice is " + str(self.choice) + "\n")
+ self.choice.selected_moves = self.choice.last_moves
+ moves = self.prioritise_moves(self.choice)
+ if len(moves) > 0:
+ return moves[0][0]
+ else:
+ return AgentRandom.get_move(self)
+
+# --- agent_bishop.py --- #
import multiprocessing
# Hacky alternative to using select for timing out players
# WARNING: Do not wrap around HumanPlayer or things breakify
+# WARNING: Do not use in general or things breakify
class Sleeper(multiprocessing.Process):
def __init__(self, timeout):
elif not s.is_alive():
w.terminate()
s.join()
- raise Exception("UNRESPONSIVE")
+ raise Exception("TIMEOUT")
def stopped(self):
return self._stop.isSet()
# --- thread_util.py --- #
+log_files = []
+import datetime
+import urllib2
+
+class LogFile():
+ def __init__(self, log):
+
+ self.log = log
+ self.logged = []
+ self.log.write("# Log starts " + str(datetime.datetime.now()) + "\n")
+
+ def write(self, s):
+ now = datetime.datetime.now()
+ self.log.write(str(now) + " : " + s + "\n")
+ self.logged.append((now, s))
+
+ def setup(self, board, players):
+
+ for p in players:
+ self.log.write("# " + p.colour + " : " + p.name + "\n")
+
+ self.log.write("# Initial board\n")
+ for x in range(0, w):
+ for y in range(0, h):
+ if board.grid[x][y] != None:
+ self.log.write(str(board.grid[x][y]) + "\n")
+
+ self.log.write("# Start game\n")
+
+ def close(self):
+ self.log.write("# EOF\n")
+ if self.log != sys.stdout:
+ self.log.close()
+
+class ShortLog(LogFile):
+ def __init__(self, file_name):
+ if file_name == "":
+ self.log = sys.stdout
+ else:
+ self.log = open(file_name, "w", 0)
+ LogFile.__init__(self, self.log)
+ self.file_name = file_name
+ self.phase = 0
+
+ def write(self, s):
+ now = datetime.datetime.now()
+ self.logged.append((now, s))
+
+ if self.phase == 0:
+ if self.log != sys.stdout:
+ self.log.close()
+ self.log = open(self.file_name, "w", 0)
+ self.log.write("# Short log updated " + str(datetime.datetime.now()) + "\n")
+ LogFile.setup(self, game.board, game.players)
+
+ elif self.phase == 1:
+ for message in self.logged[len(self.logged)-2:]:
+ self.log.write(str(message[0]) + " : " + message[1] + "\n")
+
+ self.phase = (self.phase + 1) % 2
+
+ def close(self):
+ if self.phase == 1:
+ ending = self.logged[len(self.logged)-1]
+ self.log.write(str(ending[0]) + " : " + ending[1] + "\n")
+ self.log.write("# EOF\n")
+ if self.log != sys.stdout:
+ self.log.close()
+
+
+class HeadRequest(urllib2.Request):
+ def get_method(self):
+ return "HEAD"
+
+class HttpGetter(StoppableThread):
+ def __init__(self, address):
+ StoppableThread.__init__(self)
+ self.address = address
+ self.log = urllib2.urlopen(address)
+ self.lines = []
+ self.lock = threading.RLock() #lock for access of self.state
+ self.cond = threading.Condition() # conditional
+
+ def run(self):
+ while not self.stopped():
+ line = self.log.readline()
+ if line == "":
+ date_mod = datetime.datetime.strptime(self.log.headers['last-modified'], "%a, %d %b %Y %H:%M:%S GMT")
+ self.log.close()
+
+ next_log = urllib2.urlopen(HeadRequest(self.address))
+ date_new = datetime.datetime.strptime(next_log.headers['last-modified'], "%a, %d %b %Y %H:%M:%S GMT")
+ while date_new <= date_mod and not self.stopped():
+ next_log = urllib2.urlopen(HeadRequest(self.address))
+ date_new = datetime.datetime.strptime(next_log.headers['last-modified'], "%a, %d %b %Y %H:%M:%S GMT")
+ if self.stopped():
+ break
+
+ self.log = urllib2.urlopen(self.address)
+ line = self.log.readline()
+
+ self.cond.acquire()
+ self.lines.append(line)
+ self.cond.notifyAll()
+ self.cond.release()
+
+ #sys.stderr.write(" HttpGetter got \'" + str(line) + "\'\n")
+
+ self.log.close()
+
+
+
+
+
+class HttpReplay():
+ def __init__(self, address):
+ self.getter = HttpGetter(address)
+ self.getter.start()
+
+ def readline(self):
+ self.getter.cond.acquire()
+ while len(self.getter.lines) == 0:
+ self.getter.cond.wait()
+
+ result = self.getter.lines[0]
+ self.getter.lines = self.getter.lines[1:]
+ self.getter.cond.release()
+
+ return result
+
+
+ def close(self):
+ self.getter.stop()
+
+class FileReplay():
+ def __init__(self, filename):
+ self.f = open(filename, "r", 0)
+ self.filename = filename
+ self.mod = os.path.getmtime(filename)
+ self.count = 0
+
+ def readline(self):
+ line = self.f.readline()
+
+ while line == "":
+ mod2 = os.path.getmtime(self.filename)
+ if mod2 > self.mod:
+ #sys.stderr.write("File changed!\n")
+ self.mod = mod2
+ self.f.close()
+ self.f = open(self.filename, "r", 0)
+
+ new_line = self.f.readline()
+
+ if " ".join(new_line.split(" ")[0:3]) != "# Short log":
+ for i in range(self.count):
+ new_line = self.f.readline()
+ #sys.stderr.write("Read back " + str(i) + ": " + str(new_line) + "\n")
+ new_line = self.f.readline()
+ else:
+ self.count = 0
+
+ line = new_line
+
+ self.count += 1
+ return line
+
+ def close(self):
+ self.f.close()
+
+
+def log(s):
+ for l in log_files:
+ l.write(s)
+
+
+def log_init(board, players):
+ for l in log_files:
+ l.setup(board, players)
+
+# --- log.py --- #
+
+
+
+
# A thread that runs the game
class GameThread(StoppableThread):
self.lock = threading.RLock() #lock for access of self.state
self.cond = threading.Condition() # conditional for some reason, I forgot
self.final_result = ""
+
+
# Run the game (run in new thread with start(), run in current thread with run())
def run(self):
p2.update(result) # Inform players of what happened
+ log(result)
target = self.board.grid[x][y]
if isinstance(graphics, GraphicsThread):
if self.stopped():
break
- result = self.board.update_move(x, y, x2, y2)
+ result = str(x) + " " + str(y) + " -> " + str(x2) + " " + str(y2)
+ log(result)
+
+ self.board.update_move(x, y, x2, y2)
+
for p2 in self.players:
- p2.update(str(x) + " " + str(y) + " -> " + str(x2) + " " + str(y2)) # Inform players of what happened
+ p2.update(result) # Inform players of what happened
+
+
if isinstance(graphics, GraphicsThread):
with graphics.lock:
# with self.lock:
# self.final_result = self.state["turn"].colour + " " + e.message
- if self.board.king["black"] == None:
- if self.board.king["white"] == None:
- with self.lock:
- self.final_result = self.state["turn"].colour + " DRAW"
- else:
- with self.lock:
- self.final_result = "white"
- self.stop()
- elif self.board.king["white"] == None:
+ end = self.board.end_condition()
+ if end != None:
with self.lock:
- self.final_result = "black"
+ if end == "DRAW":
+ self.final_result = self.state["turn"].colour + " " + end
+ else:
+ self.final_result = end
self.stop()
-
-
+
if self.stopped():
break
for p2 in self.players:
p2.quit(self.final_result)
- graphics.stop()
+ log(self.final_result)
+
+ if isinstance(graphics, GraphicsThread):
+ graphics.stop()
+# A thread that replays a log file
+class ReplayThread(GameThread):
+ def __init__(self, players, src, end=False,max_moves=None):
+ self.board = Board(style="empty")
+ self.board.max_moves = max_moves
+ GameThread.__init__(self, self.board, players)
+ self.src = src
+ self.end = end
+
+ self.reset_board(self.src.readline())
+
+ def reset_board(self, line):
+ agent_str = ""
+ self_str = ""
+ while line != "# Start game" and line != "# EOF":
+
+ while line == "":
+ line = self.src.readline().strip(" \r\n")
+ continue
+
+ if line[0] == '#':
+ line = self.src.readline().strip(" \r\n")
+ continue
+
+ self_str += line + "\n"
+
+ if self.players[0].name == "dummy" and self.players[1].name == "dummy":
+ line = self.src.readline().strip(" \r\n")
+ continue
+
+ tokens = line.split(" ")
+ types = map(lambda e : e.strip("[] ,'"), tokens[2:4])
+ for i in range(len(types)):
+ if types[i][0] == "?":
+ types[i] = "unknown"
+
+ agent_str += tokens[0] + " " + tokens[1] + " " + str(types) + " ".join(tokens[4:]) + "\n"
+ line = self.src.readline().strip(" \r\n")
+
+ for p in self.players:
+ p.reset_board(agent_str)
+
+
+ self.board.reset_board(self_str)
+
+
+ def run(self):
+ move_count = 0
+ last_line = ""
+ line = self.src.readline().strip(" \r\n")
+ while line != "# EOF":
+
+
+ if self.stopped():
+ break
+
+ if len(line) <= 0:
+ continue
+
+
+ if line[0] == '#':
+ last_line = line
+ line = self.src.readline().strip(" \r\n")
+ continue
+
+ tokens = line.split(" ")
+ if tokens[0] == "white" or tokens[0] == "black":
+ self.reset_board(line)
+ last_line = line
+ line = self.src.readline().strip(" \r\n")
+ continue
+
+ move = line.split(":")
+ move = move[len(move)-1].strip(" \r\n")
+ tokens = move.split(" ")
+
+
+ try:
+ [x,y] = map(int, tokens[0:2])
+ except:
+ last_line = line
+ self.stop()
+ break
+
+ log(move)
+
+ target = self.board.grid[x][y]
+ with self.lock:
+ if target.colour == "white":
+ self.state["turn"] = self.players[0]
+ else:
+ self.state["turn"] = self.players[1]
+
+ move_piece = (tokens[2] == "->")
+ if move_piece:
+ [x2,y2] = map(int, tokens[len(tokens)-2:])
+
+ if isinstance(graphics, GraphicsThread):
+ with graphics.lock:
+ graphics.state["select"] = target
+
+ if not move_piece:
+ self.board.update_select(x, y, int(tokens[2]), tokens[len(tokens)-1])
+ if isinstance(graphics, GraphicsThread):
+ with graphics.lock:
+ if target.current_type != "unknown":
+ graphics.state["moves"] = self.board.possible_moves(target)
+ else:
+ graphics.state["moves"] = None
+ time.sleep(turn_delay)
+ else:
+ self.board.update_move(x, y, x2, y2)
+ if isinstance(graphics, GraphicsThread):
+ with graphics.lock:
+ graphics.state["moves"] = [[x2,y2]]
+ time.sleep(turn_delay)
+ with graphics.lock:
+ graphics.state["select"] = None
+ graphics.state["moves"] = None
+ graphics.state["dest"] = None
+
+
+
+
+
+ for p in self.players:
+ p.update(move)
+
+ last_line = line
+ line = self.src.readline().strip(" \r\n")
+
+
+ end = self.board.end_condition()
+ if end != None:
+ self.final_result = end
+ self.stop()
+ break
+
+
+
+
+
+
+
+
+
+
+
+
+
+ if self.end and isinstance(graphics, GraphicsThread):
+ #graphics.stop()
+ pass # Let the user stop the display
+ elif not self.end and self.board.end_condition() == None:
+ global game
+ # Work out the last move
+
+ t = last_line.split(" ")
+ if t[len(t)-2] == "black":
+ self.players.reverse()
+ elif t[len(t)-2] == "white":
+ pass
+ elif self.state["turn"] != None and self.state["turn"].colour == "white":
+ self.players.reverse()
+
+
+ game = GameThread(self.board, self.players)
+ game.run()
+ else:
+ pass
+
+
+
def opponent(colour):
if colour == "white":
return "black"
else:
return "white"
# --- game.py --- #
-import pygame
+try:
+ import pygame
+except:
+ pass
import os
# Dictionary that stores the unicode character representations of the different pieces
images[c].update({p : pygame.image.load(os.path.join(image_dir, c + "_" + p + ".png"))})
small_images[c].update({p : pygame.image.load(os.path.join(image_dir, c + "_" + p + "_small.png"))})
# --- images.py --- #
-import pygame
-
-
-
-
-
-
+graphics_enabled = True
+try:
+ import pygame
+except:
+ graphics_enabled = False
+
#print "Test font"
pygame.font.Font(os.path.join(os.path.curdir, "data", "DejaVuSans.ttf"), 32).render("Hello", True,(0,0,0))
- #create_images(grid_sz)
+ #load_images()
create_images(grid_sz)
"""
if choice == 0:
players.append(HumanPlayer("human", colour))
elif choice == 1:
- if True:
- import Tkinter
- from tkFileDialog import askopenfilename
- root = Tkinter.Tk() # Need a root to make Tkinter behave
- root.withdraw() # Some sort of magic incantation
- path = askopenfilename(parent=root, initialdir="../agents",title=
-'Choose an agent.')
- if path == "":
- return self.SelectPlayers()
- players.append(make_player(path, colour))
+ import inspect
+ internal_agents = inspect.getmembers(sys.modules[__name__], inspect.isclass)
+ internal_agents = [x for x in internal_agents if issubclass(x[1], InternalAgent)]
+ internal_agents.remove(('InternalAgent', InternalAgent))
+ if len(internal_agents) > 0:
+ choice2 = self.SelectButton(["internal", "external"], prompt="Type of agent")
else:
- print "Exception was " + str(e.message)
- p = None
- while p == None:
- self.board.display_grid(self.window, self.grid_sz)
- pygame.display.flip()
- path = self.getstr(prompt = "Enter path:")
- if path == None:
- return None
+ choice2 = 1
+ if choice2 == 0:
+ agent = internal_agents[self.SelectButton(map(lambda e : e[0], internal_agents), prompt="Choose internal agent")]
+ players.append(agent[1](agent[0], colour))
+ elif choice2 == 1:
+ try:
+ import Tkinter
+ from tkFileDialog import askopenfilename
+ root = Tkinter.Tk() # Need a root to make Tkinter behave
+ root.withdraw() # Some sort of magic incantation
+ path = askopenfilename(parent=root, initialdir="../agents",title=
+'Choose an agent.')
if path == "":
return self.SelectPlayers()
-
- try:
- p = make_player(path, colour)
- except:
+ players.append(make_player(path, colour))
+ except:
+
+ p = None
+ while p == None:
self.board.display_grid(self.window, self.grid_sz)
pygame.display.flip()
- self.message("Invalid path!")
- time.sleep(1)
- p = None
- players.append(p)
+ path = self.getstr(prompt = "Enter path:")
+ if path == None:
+ return None
+
+ if path == "":
+ return self.SelectPlayers()
+
+ try:
+ p = make_player(path, colour)
+ except:
+ self.board.display_grid(self.window, self.grid_sz)
+ pygame.display.flip()
+ self.message("Invalid path!")
+ time.sleep(1)
+ p = None
+ players.append(p)
elif choice == 2:
address = ""
while address == "":
if len(s) > 1:
address = s[1]
return NetworkReceiver(colour, address)
+ if s[0] == "internal":
+
+ import inspect
+ internal_agents = inspect.getmembers(sys.modules[__name__], inspect.isclass)
+ internal_agents = [x for x in internal_agents if issubclass(x[1], InternalAgent)]
+ internal_agents.remove(('InternalAgent', InternalAgent))
+
+ if len(s) != 2:
+ sys.stderr.write(sys.argv[0] + " : '@internal' should be followed by ':' and an agent name\n")
+ sys.stderr.write(sys.argv[0] + " : Choices are: " + str(map(lambda e : e[0], internal_agents)) + "\n")
+ return None
+
+ for a in internal_agents:
+ if s[1] == a[0]:
+ return a[1](name, colour)
+
+ sys.stderr.write(sys.argv[0] + " : Can't find an internal agent matching \"" + s[1] + "\"\n")
+ sys.stderr.write(sys.argv[0] + " : Choices are: " + str(map(lambda e : e[0], internal_agents)) + "\n")
+ return None
+
else:
- return AgentPlayer(name, colour)
+ return ExternalAgent(name, colour)
global turn_delay
global agent_timeout
- global log_file
+ global log_files
global src_file
+ global graphics_enabled
+ global always_reveal_states
-
-
+ max_moves = None
+ src_file = None
style = "quantum"
colour = "white"
- graphics_enabled = True
+
+ # Get the important warnings out of the way
+ if platform.system() == "Windows":
+ sys.stderr.write(sys.argv[0] + " : Warning - You are using " + platform.system() + "\n")
+ if platform.release() == "Vista":
+ sys.stderr.write(sys.argv[0] + " : God help you.\n")
+
players = []
i = 0
i += 1
arg = argv[i]
if arg[0] != '-':
- players.append(make_player(arg, colour))
+ p = make_player(arg, colour)
+ if not isinstance(p, Player):
+ sys.stderr.write(sys.argv[0] + " : Fatal error creating " + colour + " player\n")
+ return 100
+ players.append(p)
if colour == "white":
colour = "black"
elif colour == "black":
style = "classical"
elif arg[1] == '-' and arg[2:] == "quantum":
style = "quantum"
+ elif arg[1] == '-' and arg[2:] == "reveal":
+ always_reveal_states = True
elif (arg[1] == '-' and arg[2:] == "graphics"):
- graphics_enabled = not graphics_enabled
+ graphics_enabled = True
+ elif (arg[1] == '-' and arg[2:] == "no-graphics"):
+ graphics_enabled = False
elif (arg[1] == '-' and arg[2:].split("=")[0] == "file"):
# Load game from file
if len(arg[2:].split("=")) == 1:
- src_file = sys.stdout
+ src_file = sys.stdin
else:
- src_file = arg[2:].split("=")[1]
+ f = arg[2:].split("=")[1]
+ if f[0:7] == "http://":
+ src_file = HttpReplay(f)
+ else:
+ src_file = FileReplay(f.split(":")[0])
+
+ if len(f.split(":")) == 2:
+ max_moves = int(f.split(":")[1])
+
elif (arg[1] == '-' and arg[2:].split("=")[0] == "log"):
# Log file
if len(arg[2:].split("=")) == 1:
- log_file = sys.stdout
+ log_files.append(LogFile(sys.stdout))
else:
- log_file = arg[2:].split("=")[1]
+ f = arg[2:].split("=")[1]
+ if f[0] == '@':
+ log_files.append(ShortLog(f[1:]))
+ else:
+ log_files.append(LogFile(open(f, "w", 0)))
elif (arg[1] == '-' and arg[2:].split("=")[0] == "delay"):
# Delay
if len(arg[2:].split("=")) == 1:
# Create the board
- board = Board(style)
+
+ # Construct a GameThread! Make it global! Damn the consequences!
+
+ if src_file != None:
+ # Hack to stop ReplayThread from exiting
+ #if len(players) == 0:
+ # players = [HumanPlayer("dummy", "white"), HumanPlayer("dummy", "black")]
+
+ # Normally the ReplayThread exits if there are no players
+ # TODO: Decide which behaviour to use, and fix it
+ end = (len(players) == 0)
+ if end:
+ players = [Player("dummy", "white"), Player("dummy", "black")]
+ elif len(players) != 2:
+ sys.stderr.write(sys.argv[0] + " : Usage " + sys.argv[0] + " white black\n")
+ if graphics_enabled:
+ sys.stderr.write(sys.argv[0] + " : (You won't get a GUI, because --file was used, and the author is lazy)\n")
+ return 44
+ game = ReplayThread(players, src_file, end=end, max_moves=max_moves)
+ else:
+ board = Board(style)
+ board.max_moves = max_moves
+ game = GameThread(board, players)
+
+
# Initialise GUI
if graphics_enabled == True:
try:
- graphics = GraphicsThread(board, grid_sz = [64,64]) # Construct a GraphicsThread!
+ graphics = GraphicsThread(game.board, grid_sz = [64,64]) # Construct a GraphicsThread!
except Exception,e:
graphics = None
# If using windows, select won't work; use horrible TimeoutPlayer hack
- if agent_timeout > 0 and platform.system() == "Windows":
- sys.stderr.write(sys.argv[0] + " : Warning - You are using Windows\n")
- sys.stderr.write(sys.argv[0] + " : - Timeouts will be implemented with a terrible hack.\n")
+ if agent_timeout > 0:
+ if platform.system() == "Windows":
+ for i in range(len(players)):
+ if isinstance(players[i], ExternalAgent) or isinstance(players[i], InternalAgent):
+ players[i] = TimeoutPlayer(players[i], agent_timeout)
- for i in range(len(players)):
- if isinstance(players[i], AgentPlayer):
- players[i] = TimeoutPlayer(players[i], agent_timeout)
+ else:
+ warned = False
+ # InternalAgents get wrapped to an ExternalAgent when there is a timeout
+ # This is not confusing at all.
+ for i in range(len(players)):
+ if isinstance(players[i], InternalAgent):
+ players[i] = ExternalWrapper(players[i])
- # Could potentially wrap TimeoutPlayer around internal classes...
- # But that would suck
-
- # Construct a GameThread! Make it global! Damn the consequences!
- game = GameThread(board, players)
+ log_init(game.board, players)
+
if graphics != None:
game.start() # This runs in a new thread
graphics.run()
- game.join()
- return game.error + graphics.error
+ if game.is_alive():
+ game.join()
+
+
+ error = game.error + graphics.error
else:
game.run()
- return game.error
+ error = game.error
+
+
+ for l in log_files:
+ l.close()
+
+ if src_file != None and src_file != sys.stdin:
+ src_file.close()
+
+ sys.stdout.write(game.final_result + "\n")
+
+ return error
# This is how python does a main() function...
if __name__ == "__main__":
- sys.exit(main(sys.argv))
+ try:
+ sys.exit(main(sys.argv))
+ except KeyboardInterrupt:
+ sys.stderr.write(sys.argv[0] + " : Got KeyboardInterrupt. Stopping everything\n")
+ if isinstance(graphics, StoppableThread):
+ graphics.stop()
+ graphics.run() # Will clean up graphics because it is stopped, not run it (a bit dodgy)
+
+ if isinstance(game, StoppableThread):
+ game.stop()
+ if game.is_alive():
+ game.join()
+
+ sys.exit(102)
+
# --- main.py --- #
-# EOF - created from make on Mon Jan 28 22:52:28 WST 2013
+# EOF - created from make on Thu Feb 28 18:12:37 WST 2013