/usr/bin/make-pysol-freecell-board is in freecell-solver-bin 3.26.0-1.
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#
# make_pysol_freecell_board.py - Program to generate the boards of
# PySol for input into Freecell Solver.
#
# Usage: make_pysol_freecell_board.py [board number] | fc-solve
#
# Or on non-UNIXes:
#
# python make_pysol_freecell_board.py [board number] | fc-solve
#
# This program is platform independant and will generate the same results
# on all architectures and operating systems.
#
# Based on the code by Markus Franz Xaver Johannes Oberhumer.
# Modified by Shlomi Fish, 2000
#
# Since much of the code here is ripped from the actual PySol code, this
# program is distributed under the GNU General Public License.
#
#
#
## vim:ts=4:et:nowrap
##
##---------------------------------------------------------------------------##
##
## PySol -- a Python Solitaire game
##
## Copyright (C) 2000 Markus Franz Xaver Johannes Oberhumer
## Copyright (C) 1999 Markus Franz Xaver Johannes Oberhumer
## Copyright (C) 1998 Markus Franz Xaver Johannes Oberhumer
##
## This program is free software; you can redistribute it and/or modify
## it under the terms of the GNU General Public License as published by
## the Free Software Foundation; either version 2 of the License, or
## (at your option) any later version.
##
## This program is distributed in the hope that it will be useful,
## but WITHOUT ANY WARRANTY; without even the implied warranty of
## MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
## GNU General Public License for more details.
##
## You should have received a copy of the GNU General Public License
## along with this program; see the file COPYING.
## If not, write to the Free Software Foundation, Inc.,
## 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA.
##
## Markus F.X.J. Oberhumer
## <markus.oberhumer@jk.uni-linz.ac.at>
## http://wildsau.idv.uni-linz.ac.at/mfx/pysol.html
##
##---------------------------------------------------------------------------##
# imports
import sys, os, re, string, time, types
import random
# PySol imports
# /***********************************************************************
# // Abstract PySol Random number generator.
# //
# // We use a seed of type long in the range [0, MAX_SEED].
# ************************************************************************/
class PysolRandom:
MAX_SEED = 0L
ORIGIN_UNKNOWN = 0
ORIGIN_RANDOM = 1
ORIGIN_PREVIEW = 2 # random from preview
ORIGIN_SELECTED = 3 # manually entered
ORIGIN_NEXT_GAME = 4 # "Next game number"
DEALS_PYSOL = 0
DEALS_PYSOLFC = 1
DEALS_MS = 2
def __init__(self, seed=None):
if seed is None:
seed = self._getRandomSeed()
self.initial_seed = self.setSeed(seed)
self.origin = self.ORIGIN_UNKNOWN
def __str__(self):
return self.str(self.initial_seed)
def reset(self):
self.seed = self.initial_seed
def getSeed(self):
return self.seed
def setSeed(self, seed):
seed = self._convertSeed(seed)
if type(seed) is not types.LongType:
raise TypeError, "seeds must be longs"
if not (0L <= seed <= self.MAX_SEED):
raise ValueError, "seed out of range"
self.seed = seed
return seed
def copy(self):
random = PysolRandom(0L)
random.__class__ = self.__class__
random.__dict__.update(self.__dict__)
return random
#
# implementation
#
def choice(self, seq):
return seq[int(self.random() * len(seq))]
# Get a random integer in the range [a, b] including both end points.
def randint(self, a, b):
return a + int(self.random() * (b+1-a))
#
# subclass responsibility
#
# Get the next random number in the range [0.0, 1.0).
def random(self):
raise SubclassResponsibility
#
# subclass overrideable
#
def _convertSeed(self, seed):
return long(seed)
def increaseSeed(self, seed):
if seed < self.MAX_SEED:
return seed + 1L
return 0L
def _getRandomSeed(self):
t = long(time.time() * 256.0)
t = (t ^ (t >> 24)) % (self.MAX_SEED + 1L)
return t
#
# shuffle
# see: Knuth, Vol. 2, Chapter 3.4.2, Algorithm P
# see: FAQ of sci.crypt: "How do I shuffle cards ?"
#
def shuffle(self, seq):
n = len(seq) - 1
while n > 0:
j = self.randint(0, n)
seq[n], seq[j] = seq[j], seq[n]
n = n - 1
# /***********************************************************************
# // Linear Congruential random generator
# //
# // Knuth, Donald.E., "The Art of Computer Programming,", Vol 2,
# // Seminumerical Algorithms, Third Edition, Addison-Wesley, 1998,
# // p. 106 (line 26) & p. 108
# ************************************************************************/
class LCRandom64(PysolRandom):
MAX_SEED = 0xffffffffffffffffL # 64 bits
def str(self, seed):
s = repr(long(seed))[:-1]
s = "0"*(20-len(s)) + s
return s
def random(self):
self.seed = (self.seed*6364136223846793005L + 1L) & self.MAX_SEED
return ((self.seed >> 21) & 0x7fffffffL) / 2147483648.0
# /***********************************************************************
# // Linear Congruential random generator
# // In PySol this is only used for 0 <= seed <= 32000.
# ************************************************************************/
class LCRandom31(PysolRandom):
MAX_SEED = 0x7fffffffL # 31 bits
def str(self, seed):
return "%05d" % int(seed)
def random(self):
self.seed = (self.seed*214013L + 2531011L) & self.MAX_SEED
return (self.seed >> 16) / 32768.0
def randint(self, a, b):
self.seed = (self.seed*214013L + 2531011L) & self.MAX_SEED
return a + (int(self.seed >> 16) % (b+1-a))
# ************************************************************************
# * Mersenne Twister random number generator
# * uses standart python module `random'
# ************************************************************************
class BasicRandom:
#MAX_SEED = 0L
#MAX_SEED = 0xffffffffffffffffL # 64 bits
MAX_SEED = 100000000000000000000L # 20 digits
ORIGIN_UNKNOWN = 0
ORIGIN_RANDOM = 1
ORIGIN_PREVIEW = 2 # random from preview
ORIGIN_SELECTED = 3 # manually entered
ORIGIN_NEXT_GAME = 4 # "Next game number"
def __str__(self):
return self.str(self.initial_seed)
def str(self, seed):
return '%020d' % seed
def reset(self):
raise SubclassResponsibility
def copy(self):
random = self.__class__(0L)
random.__dict__.update(self.__dict__)
return random
def increaseSeed(self, seed):
if seed < self.MAX_SEED:
return seed + 1L
return 0L
def _getRandomSeed(self):
t = long(time.time() * 256.0)
t = (t ^ (t >> 24)) % (self.MAX_SEED + 1L)
return t
class MTRandom(BasicRandom, random.Random):
def setSeed(self, seed):
random.Random.__init__(self, seed)
self.initial_seed = seed
self.initial_state = self.getstate()
self.origin = self.ORIGIN_UNKNOWN
def reset(self):
self.setstate(self.initial_state)
class Card:
ACE = 1
KING = 13
def __init__(self, id, rank, suit, print_ts):
self.id = id
self.rank = rank
self.suit = suit
self.flipped = False
self.print_ts = print_ts
self.empty = False
def is_king(self):
return self.rank == self.KING
def is_ace(self):
return self.rank == self.ACE
def rank_s(self):
s = "0A23456789TJQK"[self.rank]
if (not self.print_ts) and s == "T":
s = "10"
return s
def suit_s(self):
return "CSHD"[self.suit];
def to_s(self):
if self.empty:
return "-"
ret = ""
ret = ret + self.rank_s()
ret = ret + self.suit_s()
if self.flipped:
ret = "<" + ret + ">"
return ret
def found_s(self):
return self.suit_s() + "-" + self.rank_s()
def flip(self, flipped=True):
new_card = Card(self.id, self.rank, self.suit, self.print_ts)
new_card.flipped = flipped
return new_card
def is_empty(self):
return self.empty
class Columns:
def __init__(self, num):
self.num = num
cols = []
for i in range(num):
cols.append([])
self.cols = cols
def add(self, idx, card):
self.cols[idx].append(card)
def rev(self):
self.cols.reverse()
def output(self):
for column in self.cols:
print column_to_string(column)
class Board:
def __init__(self, num_columns, with_freecells=False,
with_talon=False, with_foundations=False):
self.with_freecells = with_freecells
self.with_talon = with_talon
self.with_foundations = with_foundations
self.columns = Columns(num_columns)
if (self.with_freecells):
self.freecells = []
if (self.with_talon):
self.talon = []
if (self.with_foundations):
self.foundations = map(lambda s:empty_card(),range(4))
def reverse_cols(self):
return self.columns.rev()
def add(self, idx, card):
return self.columns.add(idx, card)
def print_freecells(self):
print "FC: " + column_to_string(self.freecells)
def print_talon(self):
print "Talon: " + column_to_string(self.talon)
def print_foundations(self):
cells = []
for f in [2,0,3,1]:
if not self.foundations[f].is_empty():
cells.append(self.foundations[f].found_s())
if len(cells):
print "Foundations:" + ("".join(map(lambda s: " "+s, cells)))
def output(self):
if (self.with_talon):
self.print_talon()
if (self.with_foundations):
self.print_foundations()
if (self.with_freecells):
self.print_freecells()
self.columns.output()
def add_freecell(self, card):
if not self.with_freecells:
raise AttributeError("Layout does not have freecells!")
self.freecells.append(card)
def add_talon(self, card):
if not self.with_talon:
raise AttributeError("Layout does not have a talon!")
self.talon.append(card)
def put_into_founds(self, card):
if not self.with_foundations:
raise AttributeError("Layout does not have foundations!")
if ((self.foundations[card.suit].rank+1) == card.rank):
self.foundations[card.suit] = card
return True
else:
return False
self.talon.append(card)
def empty_card():
ret = Card(0,0,0,1)
ret.empty = True
return ret
def createCards(num_decks, print_ts):
cards = []
for deck in range(num_decks):
id = 0
for suit in range(4):
for rank in range(13):
cards.append(Card(id, rank+1, suit, print_ts))
id = id + 1
return cards
def column_to_list_of_strings(col):
return map( lambda c: c.to_s(), col)
def column_to_string(col):
return " ".join(column_to_list_of_strings(col))
def flip_card(card_str, flip):
if flip:
return "<" + card_str + ">"
else:
return card_str
def shuffle(orig_cards, game_num, which_deals):
if ((game_num <= 32000) or which_deals == PysolRandom.DEALS_MS):
r = LCRandom31()
r.setSeed(game_num)
fcards = []
if (len(orig_cards) == 52):
for i in range(13):
for j in (0, 39, 26, 13):
fcards.append(orig_cards[i + j])
orig_cards = fcards
r.shuffle(orig_cards)
else:
r = 0
if (which_deals == PysolRandom.DEALS_PYSOLFC):
r = MTRandom()
else:
r = LCRandom64()
r.setSeed(game_num)
r.shuffle(orig_cards)
return orig_cards
class Game:
REVERSE_MAP = \
{
"freecell":
[ "freecell", "forecell", "bakers_game",
"ko_bakers_game", "kings_only_bakers_game", "relaxed_freecell",
"eight_off" ],
"der_katz":
[ "der_katz", "der_katzenschwantz", "die_schlange"],
"seahaven":
[ "seahaven_towers", "seahaven", "relaxed_seahaven", "relaxed_seahaven_towers" ],
"bakers_dozen" : None,
"gypsy" : None,
"klondike" : [ "klondike", "klondike_by_threes", "casino_klondike", "small_harp", "thumb_and_pouch", "vegas_klondike", "whitehead" ],
"simple_simon" : None,
"yukon" : None,
"beleaguered_castle" : [ "beleaguered_castle", "streets_and_alleys", "citadel" ],
"fan" : None,
"black_hole" : None,
"all_in_a_row" : None,
}
def __init__(self, game_id, game_num, which_deals, print_ts):
mymap = {}
for k in self.REVERSE_MAP.keys():
if self.REVERSE_MAP[k] is None:
mymap[k] = k
else:
for alias in self.REVERSE_MAP[k]:
mymap[alias] = k
self.games_map = mymap
self.game_id = game_id
self.game_num = game_num
self.print_ts = print_ts
self.which_deals = which_deals
def print_layout(self):
game_class = self.lookup()
if not game_class:
raise ValueError("Unknown game type " + self.game_id + "\n")
self.deal()
getattr(self, game_class)()
self.board.output()
def lookup(self):
return self.games_map[self.game_id];
def is_two_decks(self):
return self.game_id in ("der_katz", "der_katzenschwantz", "die_schlange", "gypsy")
def get_num_decks(self):
if self.is_two_decks():
return 2
else:
return 1
def deal(self):
orig_cards = createCards(self.get_num_decks(), self.print_ts)
orig_cards = shuffle(orig_cards, self.game_num, self.which_deals)
cards = orig_cards
cards.reverse()
self.cards = cards
self.card_idx = 0
return True
def __iter__(self):
return self
def no_more_cards(self):
return self.card_idx >= len(self.cards)
def next(self):
if self.no_more_cards():
raise StopIteration
c = self.cards[self.card_idx]
self.card_idx = self.card_idx + 1
return c
def new_cards(self, cards):
self.cards = cards
self.card_idx = 0
def add(self, idx, card):
return self.board.add(idx, card)
def add_freecell(self, card):
return self.board.add_freecell(card)
def cyclical_deal(game, num_cards, num_cols, flipped=False):
for i in range(num_cards):
game.add(i%num_cols, game.next().flip(flipped=flipped))
return i
def add_all_to_talon(game):
for card in game:
game.board.add_talon(card)
### These are the games variants:
### Each one is a callback.
def der_katz(game):
if (game.game_id == "die_schlange"):
print "Foundations: H-A S-A D-A C-A H-A S-A D-A C-A"
game.board = Board(9)
col_idx = 0
for card in game:
if card.is_king():
col_idx = col_idx + 1
if not ((game.game_id == "die_schlange") and (card.rank == 1)):
game.add(col_idx, card)
def freecell(game):
is_fc = (game.game_id in ('forecell', 'eight_off'))
game.board = Board(8, with_freecells=is_fc)
if is_fc:
game.cyclical_deal(48, 8)
for card in game:
game.add_freecell(card)
if game.game_id == "eight_off":
game.add_freecell(empty_card())
else:
game.cyclical_deal(52, 8)
def seahaven(game):
game.board = Board(10, with_freecells=True)
game.add_freecell(empty_card())
game.cyclical_deal(50, 10)
for card in game:
game.add_freecell(card)
def bakers_dozen(game):
i, n = 0, 13
kings = []
cards = game.cards
cards.reverse()
for c in cards:
if c.is_king():
kings.append(i)
i = i + 1
for i in kings:
j = i % n
while j < i:
if not cards[j].is_king():
cards[i], cards[j] = cards[j], cards[i]
break
j = j + n
game.new_cards(cards)
game.board = Board(13)
game.cyclical_deal(52, 13)
def gypsy(game):
num_cols = 8
game.board = Board(num_cols, with_talon=True)
game.cyclical_deal(num_cols*2, num_cols, flipped=True)
game.cyclical_deal(num_cols, num_cols, flipped=False)
game.add_all_to_talon()
def klondike(game):
num_cols = 7
game.board = Board(num_cols, with_talon=True)
for r in range(1,num_cols):
for s in range(num_cols-r):
game.add(s, game.next().flip())
game.cyclical_deal(num_cols, num_cols)
game.add_all_to_talon()
if not (game.game_id == "small_harp"):
game.board.reverse_cols()
def simple_simon(game):
game.board = Board(10)
num_cards = 9
while num_cards >= 3:
for s in range(num_cards):
game.add(s, game.next())
num_cards = num_cards - 1
for s in range(10):
game.add(s, game.next())
def fan(game):
game.board = Board(18)
game.cyclical_deal(52-1, 17)
game.add(17, game.next())
def _shuffleHookMoveSorter(self, cards, func, ncards):
# note that we reverse the cards, so that smaller sort_orders
# will be nearer to the top of the Talon
sitems, i = [], len(cards)
for c in cards[:]:
select, sort_order = func(c)
if select:
cards.remove(c)
sitems.append((sort_order, i, c))
if len(sitems) >= ncards:
break
i = i - 1
sitems.sort()
sitems.reverse()
scards = map(lambda item: item[2], sitems)
return cards, scards
def _shuffleHookMoveToBottom(self, cards, func, ncards=999999):
# move cards to bottom of the Talon (i.e. last cards to be dealt)
cards, scards = self._shuffleHookMoveSorter(cards, func, ncards)
ret = scards + cards
return ret
def _shuffleHookMoveToTop(self, cards, func, ncards=999999):
# move cards to top of the Talon (i.e. last cards to be dealt)
cards, scards = self._shuffleHookMoveSorter(cards, func, ncards)
return cards + scards
def black_hole(game):
game.board = Board(17)
# move Ace to bottom of the Talon (i.e. last cards to be dealt)
game.cards = game._shuffleHookMoveToBottom(game.cards, lambda c: (c.id == 13, c.suit), 1)
game.next()
game.cyclical_deal(52-1, 17)
print "Foundations: AS"
def all_in_a_row(game):
game.board = Board(13)
# move Ace to bottom of the Talon (i.e. last cards to be dealt)
game.cards = game._shuffleHookMoveToTop(game.cards, lambda c: (c.id == 13, c.suit), 1)
game.cyclical_deal(52, 13)
print "Foundations: -"
def beleaguered_castle(game):
aces_up = game.game_id in ("beleaguered_castle", "citadel")
game.board = Board(8, with_foundations=True)
if aces_up:
new_cards = []
for c in game:
if c.is_ace():
game.board.put_into_founds(c)
else:
new_cards.append(c)
game.new_cards(new_cards)
for i in range(6):
for s in range(8):
c = game.next()
if (game.game_id == "citadel") and game.board.put_into_founds(c):
# Already dealt with this card
True
else:
game.add(s, c)
if game.no_more_cards():
break
if (game.game_id == "streets_and_alleys"):
game.cyclical_deal(4, 4)
def yukon(game):
num_cols = 7
game.board = Board(num_cols)
for i in range(1, num_cols):
for j in range(i, num_cols):
game.add(j, game.next().flip())
for i in range(4):
for j in range(1,num_cols):
game.add(j, game.next())
game.cyclical_deal(num_cols, num_cols)
def shlomif_main(args):
print_ts = 0
which_deals = PysolRandom.DEALS_PYSOL
while args[1][0] == '-':
if (args[1] == "-t"):
print_ts = 1
args.pop(0)
elif ((args[1] == "--pysolfc") or (args[1] == "-F")):
which_deals = PysolRandom.DEALS_PYSOLFC
args.pop(0)
elif ((args[1] == "--ms") or (args[1] == "-M")):
which_deals = PysolRandom.DEALS_MS
args.pop(0)
else:
raise ValueError("Unknown flag " + args[1] + "!")
game_num = long(args[1])
if (len(args) >= 3):
which_game = args[2]
else:
which_game = "freecell"
game = Game(which_game, game_num, which_deals, print_ts)
game.print_layout();
if __name__ == "__main__":
sys.exit(shlomif_main(sys.argv))
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