#!/usr/bin/env python
# -*- mode: python; coding: utf-8; -*-
# ---------------------------------------------------------------------------##
#
# Copyright (C) 1998-2003 Markus Franz Xaver Johannes Oberhumer
# Copyright (C) 2003 Mt. Hood Playing Card Co.
# Copyright (C) 2005-2009 Skomoroh
#
# 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 3 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. If not, see <http://www.gnu.org/licenses/>.
#
# ---------------------------------------------------------------------------##
from pysollib.game import Game
from pysollib.gamedb import GI, GameInfo, registerGame
from pysollib.hint import DefaultHint
from pysollib.layout import Layout
from pysollib.stack import \
AbstractFoundationStack, \
BasicRowStack, \
DealRowRedealTalonStack, \
InitialDealTalonStack, \
OpenStack, \
ReserveStack, \
SS_FoundationStack, \
StackWrapper, \
TalonStack
from pysollib.util import ANY_RANK, ANY_SUIT, KING, NO_RANK, UNLIMITED_REDEALS
# ************************************************************************
# *
# ************************************************************************
class MonteCarlo_Hint(DefaultHint):
# FIXME: demo is not too clever in this game
pass
# ************************************************************************
# * Monte Carlo
# * Monte Carlo (2 decks)
# ************************************************************************
class MonteCarlo_Talon(TalonStack):
def canDealCards(self):
free = 0
for r in self.game.s.rows:
if not r.cards:
free = 1
elif free:
return True
return free and len(self.cards)
def dealCards(self, sound=False):
self.game.updateStackMove(self.game.s.talon, 2 | 16) # for undo
n = self.game.fillEmptyStacks()
self.game.updateStackMove(self.game.s.talon, 1 | 16) # for redo
return n
class MonteCarlo_RowStack(BasicRowStack):
def acceptsCards(self, from_stack, cards):
if not OpenStack.acceptsCards(self, from_stack, cards):
return False
# check the rank
if self.cards[-1].rank != cards[0].rank:
return False
# now look if the stacks are neighbours
return self.game.isNeighbour(from_stack, self)
def moveMove(self, ncards, to_stack, frames=-1, shadow=-1):
assert ncards == 1 and to_stack in self.game.s.rows
if to_stack.cards:
self._dropPairMove(ncards, to_stack, frames=-1, shadow=shadow)
else:
BasicRowStack.moveMove(
self, ncards, to_stack, frames=frames, shadow=shadow)
def _dropPairMove(self, n, other_stack, frames=-1, shadow=-1):
game = self.game
old_state = game.enterState(game.S_FILL)
f = game.s.foundations[0]
game.updateStackMove(game.s.talon, 2 | 16) # for undo
if not game.demo:
game.playSample("droppair", priority=200)
game.moveMove(n, self, f, frames=frames, shadow=shadow)
game.moveMove(n, other_stack, f, frames=frames, shadow=shadow)
self.fillStack()
other_stack.fillStack()
if self.game.FILL_STACKS_AFTER_DROP:
game.fillEmptyStacks()
game.updateStackMove(game.s.talon, 1 | 16) # for redo
game.leaveState(old_state)
class MonteCarlo(Game):
Talon_Class = MonteCarlo_Talon
Foundation_Class = StackWrapper(
AbstractFoundationStack, max_accept=0)
RowStack_Class = MonteCarlo_RowStack
Hint_Class = MonteCarlo_Hint
FILL_STACKS_AFTER_DROP = False
#
# game layout
#
def createGame(self, rows=5, cols=5):
# create layout
l, s = Layout(self), self.s
# set window
self.setSize(l.XM + (cols+1.5)*l.XS, l.YM + rows*l.YS)
# create stacks
for i in range(rows):
for j in range(cols):
x, y = l.XM + j*l.XS, l.YM + i*l.YS
s.rows.append(self.RowStack_Class(x, y, self,
max_accept=1, max_cards=2,
dir=0, base_rank=NO_RANK))
x, y = self.width - l.XS, l.YM
s.foundations.append(self.Foundation_Class(x, y, self, suit=ANY_SUIT,
max_move=0, base_rank=ANY_RANK,
max_cards=self.gameinfo.ncards))
l.createText(s.foundations[0], "s")
y += 2*l.YS
s.talon = self.Talon_Class(x, y, self, max_rounds=1)
l.createText(s.talon, "s", text_format="%D")
# define stack-groups
l.defaultStackGroups()
#
# game overrides
#
def startGame(self):
self._startAndDealRow()
def getAutoStacks(self, event=None):
return ((), (), self.sg.dropstacks)
def shallHighlightMatch(self, stack1, card1, stack2, card2):
return card1.rank == card2.rank
#
# game extras
#
def isNeighbour(self, stack1, stack2):
if not (0 <= stack1.id <= 24 and 0 <= stack2.id <= 24):
return False
column = stack2.id % 5
diff = stack1.id - stack2.id
if column == 0:
return diff in (-5, -4, 1, 5, 6)
elif column == 4:
return diff in (-6, -5, -1, 4, 5)
else:
return diff in (-6, -5, -4, -1, 1, 4, 5, 6)
def fillEmptyStacks(self):
free, n = 0, 0
self.startDealSample()
for r in self.s.rows:
assert len(r.cards) <= 1
if not r.cards:
free += 1
elif free > 0:
to_stack = self.allstacks[r.id - free]
self.moveMove(1, r, to_stack, frames=4, shadow=0)
if free > 0:
for r in self.s.rows:
if not r.cards:
if not self.s.talon.cards:
break
self.flipMove(self.s.talon)
self.moveMove(1, self.s.talon, r)
n += 1
self.stopSamples()
return n + free
class MonteCarlo2Decks(MonteCarlo):
pass
# ************************************************************************
# * Weddings
# ************************************************************************
class Weddings_Talon(MonteCarlo_Talon):
def canDealCards(self):
free = 0
for r in self.game.s.rows:
if not r.cards:
free = 1
else:
k = r.id
while k >= 5 and not self.game.allstacks[k - 5].cards:
k = k - 5
if k != r.id:
return True
return free and len(self.cards)
class Weddings(MonteCarlo):
Talon_Class = Weddings_Talon
def fillEmptyStacks(self):
free, n = 0, 0
self.startDealSample()
for r in self.s.rows:
assert len(r.cards) <= 1
if not r.cards:
free = free + 1
else:
k = r.id
while k >= 5 and not self.allstacks[k - 5].cards:
k = k - 5
if k != r.id:
to_stack = self.allstacks[k]
self.moveMove(1, r, to_stack, frames=4, shadow=0)
if free > 0:
for r in self.s.rows:
if not r.cards:
if not self.s.talon.cards:
break
self.flipMove(self.s.talon)
self.moveMove(1, self.s.talon, r)
n = n + 1
self.stopSamples()
return n
# ************************************************************************
# * Simple Carlo (Monte Carlo for Children, stacks do not
# * have to be neighbours)
# ************************************************************************
class SimpleCarlo(MonteCarlo):
FILL_STACKS_AFTER_DROP = True
def getAutoStacks(self, event=None):
return ((), (), ())
def isNeighbour(self, stack1, stack2):
return 0 <= stack1.id <= 24 and 0 <= stack2.id <= 24
# ************************************************************************
# * Simple Pairs
# ************************************************************************
class SimplePairs(MonteCarlo):
def createGame(self):
# create layout
l, s = Layout(self), self.s
# set window
self.setSize(l.XM + 6*l.XS, l.YM + 4*l.YS)
# create stacks
for i in range(3):
for j in range(3):
x, y = l.XM + (2*j+3)*l.XS//2, l.YM + (2*i+1)*l.YS//2
s.rows.append(self.RowStack_Class(x, y, self,
max_accept=1, max_cards=2,
dir=0, base_rank=NO_RANK))
x, y = l.XM, l.YM + 3*l.YS//2
s.talon = TalonStack(x, y, self, max_rounds=1)
l.createText(s.talon, "s")
x = x + 5*l.XS
s.foundations.append(self.Foundation_Class(x, y, self, suit=ANY_SUIT,
max_move=0, max_cards=52, base_rank=ANY_RANK))
l.createText(s.foundations[0], "s")
# define stack-groups
l.defaultStackGroups()
def fillStack(self, stack):
if stack in self.s.rows:
if len(stack.cards) == 0 and len(self.s.talon.cards) > 0:
self.flipMove(self.s.talon)
self.moveMove(1, self.s.talon, stack)
def isNeighbour(self, stack1, stack2):
return 0 <= stack1.id <= 15 and 0 <= stack2.id <= 15
# ************************************************************************
# * Neighbour
# ************************************************************************
class Neighbour_Foundation(AbstractFoundationStack):
def acceptsCards(self, from_stack, cards):
if not AbstractFoundationStack.acceptsCards(self, from_stack, cards):
return False
# We accept any King. Pairs will get delivered by _dropPairMove.
return cards[0].rank == KING
class Neighbour_RowStack(MonteCarlo_RowStack):
def acceptsCards(self, from_stack, cards):
if not OpenStack.acceptsCards(self, from_stack, cards):
return False
# check the rank
if self.cards[-1].rank + cards[0].rank != 11:
return False
# now look if the stacks are neighbours
return self.game.isNeighbour(from_stack, self)
def clickHandler(self, event):
if self._dropKingClickHandler(event):
return 1
return MonteCarlo_RowStack.clickHandler(self, event)
def moveMove(self, ncards, to_stack, frames=-1, shadow=-1):
assert ncards == 1
if self.cards[-1].rank == KING:
assert to_stack in self.game.s.foundations
BasicRowStack.moveMove(
self, ncards, to_stack, frames=frames, shadow=shadow)
else:
MonteCarlo_RowStack.moveMove(
self, ncards, to_stack, frames=frames, shadow=shadow)
def _dropKingClickHandler(self, event):
if not self.cards:
return 0
c = self.cards[-1]
if c.face_up and c.rank == KING and not self.basicIsBlocked():
self.game.playSample("autodrop", priority=20)
self.playMoveMove(1, self.game.s.foundations[0], sound=False)
return 1
return 0
def fillStack(self):
if not self.cards and self.game.s.talon.canDealCards():
old_state = self.game.enterState(self.game.S_FILL)
self.game.s.talon.dealCards()
self.game.leaveState(old_state)
class Neighbour(MonteCarlo):
Foundation_Class = Neighbour_Foundation
RowStack_Class = Neighbour_RowStack
FILL_STACKS_AFTER_DROP = True
def getAutoStacks(self, event=None):
return ((), self.sg.dropstacks, ())
def shallHighlightMatch(self, stack1, card1, stack2, card2):
return card1.rank + card2.rank == 11
# ************************************************************************
# * Fourteen
# ************************************************************************
class Fourteen_RowStack(MonteCarlo_RowStack):
def acceptsCards(self, from_stack, cards):
if not OpenStack.acceptsCards(self, from_stack, cards):
return False
# check the rank
return self.cards[-1].rank + cards[0].rank == 12
class Fourteen(Game):
Foundation_Class = StackWrapper(AbstractFoundationStack, max_accept=0)
RowStack_Class = Fourteen_RowStack
FILL_STACKS_AFTER_DROP = False
#
# game layout
#
def createGame(self):
# create layout
l, s = Layout(self), self.s
# set window
self.setSize(l.XM + 7*l.XS, l.YM + 5*l.YS)
# create stacks
for i in (0, 2.5):
for j in range(6):
x, y = l.XM + j*l.XS, l.YM + i*l.YS
s.rows.append(self.RowStack_Class(x, y, self,
max_move=1, max_accept=1,
dir=0, base_rank=NO_RANK))
x, y = l.XM + 6*l.XS, l.YM
s.foundations.append(self.Foundation_Class(x, y, self, suit=ANY_SUIT,
max_move=0, max_cards=52, base_rank=ANY_RANK))
l.createText(s.foundations[0], "s")
x, y = self.width - l.XS, self.height - l.YS
s.talon = InitialDealTalonStack(x, y, self)
# define stack-groups
l.defaultStackGroups()
#
# game overrides
#
def startGame(self):
self._startDealNumRows(3)
self.s.talon.dealRow()
self.s.talon.dealRow(rows=self.s.rows[:4])
def getAutoStacks(self, event=None):
return ((), (), self.sg.dropstacks)
def shallHighlightMatch(self, stack1, card1, stack2, card2):
return card1.rank + card2.rank == 12
# ************************************************************************
# * Nestor
# * Double Nestor
# ************************************************************************
class Nestor_RowStack(MonteCarlo_RowStack):
def acceptsCards(self, from_stack, cards):
if not OpenStack.acceptsCards(self, from_stack, cards):
return False
# check the rank
return self.cards[-1].rank == cards[0].rank
class Nestor(Game):
Foundation_Class = StackWrapper(AbstractFoundationStack, max_accept=0)
RowStack_Class = Nestor_RowStack
FILL_STACKS_AFTER_DROP = False
COLS = 8
COLCARDS = 6
#
# game layout
#
def createGame(self):
# create layout
l, s = Layout(self), self.s
# set window
self.setSize(l.XM + self.COLS * l.XS,
l.YM + 2 * l.YS + (self.COLCARDS + 6) * l.YOFFSET)
# create stacks
x, y = l.XM, l.YM
for i in range(self.COLS):
s.rows.append(self.RowStack_Class(x, y, self,
max_move=1, max_accept=1,
dir=0, base_rank=NO_RANK))
x += l.XS
x, y = l.XM + ((self.COLS / 2) - 2) * l.XS, self.height-l.YS
for i in range(4):
s.rows.append(self.RowStack_Class(x, y, self,
max_move=1, max_accept=1,
dir=0, base_rank=NO_RANK))
x += l.XS
x, y = self.width-l.XS, self.height-l.YS
s.foundations.append(self.Foundation_Class(x, y, self, suit=ANY_SUIT,
max_move=0, max_cards=(52 * self.gameinfo.decks),
base_rank=ANY_RANK))
l.createText(s.foundations[0], "n")
x, y = l.XM, self.height - l.YS
s.talon = InitialDealTalonStack(x, y, self)
# define stack-groups
l.defaultStackGroups()
#
# game overrides
#
def _checkRow(self, cards):
for i in range(len(cards)):
for j in range(i):
if cards[i].rank == cards[j].rank:
return j
return -1
def _shuffleHook(self, cards):
# no row will have two cards of the same rank
for i in range(self.COLS):
for t in range(1000): # just in case
j = self._checkRow(cards[i * self.COLCARDS:(i + 1)
* self.COLCARDS])
if j < 0:
break
j += i * self.COLCARDS
k = self.random.choice(list(range((i+1) * self.COLCARDS,
(52 * self.gameinfo.decks))))
cards[j], cards[k] = cards[k], cards[j]
cards.reverse()
return cards
def startGame(self):
for r in self.s.rows[:self.COLS]:
for j in range(self.COLCARDS):
self.s.talon.dealRow(rows=[r], frames=0)
self.startDealSample()
self.s.talon.dealRow(rows=self.s.rows[self.COLS:])
def getAutoStacks(self, event=None):
return ((), (), self.sg.dropstacks)
def shallHighlightMatch(self, stack1, card1, stack2, card2):
return card1.rank == card2.rank
class DoubleNestor(Nestor):
COLS = 10
COLCARDS = 10
# ************************************************************************
# * Vertical
# ************************************************************************
class Vertical(Nestor):
def createGame(self):
# create layout
l, s = Layout(self), self.s
# set window
self.setSize(l.XM+9*l.XS, l.YM+2*l.YS+12*l.YOFFSET)
# create stacks
x, y = l.XM, l.YM
for i in range(7):
s.rows.append(self.RowStack_Class(x, y, self,
max_move=1, max_accept=1,
dir=0, base_rank=NO_RANK))
x += l.XS
x, y = l.XM, self.height-l.YS
for i in range(9):
s.rows.append(self.RowStack_Class(x, y, self,
max_move=1, max_accept=1,
dir=0, base_rank=NO_RANK))
x += l.XS
x, y = self.width-l.XS, l.YM
s.foundations.append(self.Foundation_Class(x, y, self, suit=ANY_SUIT,
max_move=0, max_cards=52, base_rank=ANY_RANK))
l.createText(s.foundations[0], "s")
x -= l.XS
s.talon = InitialDealTalonStack(x, y, self)
# define stack-groups
l.defaultStackGroups()
def startGame(self):
self.s.talon.dealRow(frames=0)
for i in range(4):
self.s.talon.dealRow(rows=self.s.rows[:7], frames=0)
self.startDealSample()
self.s.talon.dealRow(rows=self.s.rows[:7])
self.s.talon.dealRow(rows=[self.s.rows[3]])
# ************************************************************************
# * The Wish
# ************************************************************************
class TheWish(Game):
FILL_STACKS_AFTER_DROP = False
def createGame(self):
# create layout
l, s = Layout(self), self.s
# set window
self.setSize(l.XM+6*l.XS, 2*l.YM+2*l.YS+6*l.YOFFSET)
# create stacks
for i in range(2):
for j in range(4):
x, y = l.XM + j*l.XS, l.YM+i*(l.YM+l.YS+3*l.YOFFSET)
s.rows.append(Nestor_RowStack(x, y, self,
max_move=1, max_accept=1,
dir=0, base_rank=NO_RANK))
x, y = self.width - l.XS, l.YM
s.talon = InitialDealTalonStack(x, y, self)
x, y = self.width - l.XS, self.height - l.YS
s.foundations.append(
AbstractFoundationStack(
x, y, self, suit=ANY_SUIT,
max_move=0, max_cards=32, max_accept=0, base_rank=ANY_RANK))
l.createText(s.foundations[0], "n")
# define stack-groups
l.defaultStackGroups()
#
# game overrides
#
def startGame(self):
for i in range(3):
self.s.talon.dealRow(flip=0, frames=0)
self._startAndDealRow()
def fillStack(self, stack):
if stack.cards:
self.flipMove(stack)
def getAutoStacks(self, event=None):
return ((), (), self.sg.dropstacks)
def shallHighlightMatch(self, stack1, card1, stack2, card2):
return card1.rank == card2.rank
class TheWishOpen(TheWish):
def fillStack(self, stack):
pass
def startGame(self):
self._startDealNumRowsAndDealSingleRow(3)
# ************************************************************************
# * Der letzte Monarch (The last Monarch)
# ************************************************************************
class DerLetzteMonarch_Foundation(SS_FoundationStack):
def acceptsCards(self, from_stack, cards):
if cards is None:
# special hack for _getDropStack() below
return SS_FoundationStack.acceptsCards(
self, from_stack, from_stack.cards)
#
if not SS_FoundationStack.acceptsCards(self, from_stack, cards):
return False
# We only accept cards from a Reserve. Other cards will get
# delivered by _handlePairMove.
return from_stack in self.game.s.reserves
class DerLetzteMonarch_RowStack(ReserveStack):
def canDropCards(self, stacks):
return (None, 0)
def acceptsCards(self, from_stack, cards):
if not ReserveStack.acceptsCards(self, from_stack, cards):
return False
# must be neighbours
if not self.game.isNeighbour(from_stack, self):
return False
# must be able to move our card to the foundations or reserves
return self._getDropStack() is not None
def _getDropStack(self):
if len(self.cards) != 1:
return None
for s in self.game.s.foundations:
if s.acceptsCards(self, None): # special hack
return s
for s in self.game.s.reserves:
if not s.cards:
return s
return None
def moveMove(self, ncards, to_stack, frames=-1, shadow=-1):
assert ncards == 1 and to_stack in self.game.s.rows
assert len(to_stack.cards) == 1
self._handlePairMove(ncards, to_stack, frames=-1, shadow=0)
self.fillStack()
def _handlePairMove(self, n, other_stack, frames=-1, shadow=-1):
game = self.game
old_state = game.enterState(game.S_FILL)
s = other_stack._getDropStack()
assert s is not None
game.moveMove(n, other_stack, s, frames=frames, shadow=shadow)
game.moveMove(n, self, other_stack, frames=0)
game.leaveState(old_state)
class DerLetzteMonarch_ReserveStack(ReserveStack):
def clickHandler(self, event):
return self.doubleclickHandler(event)
class DerLetzteMonarch(Game):
Talon_Class = InitialDealTalonStack
#
# game layout
#
def createGame(self, texts=False):
# create layout
l, s = Layout(self, card_x_space=4), self.s
# set window
decks = self.gameinfo.decks
if decks == 1:
w = l.XM + 13*l.XS
dx = 0
else:
w = l.XM + 15*l.XS
dx = l.XS
h = l.YM + 5*l.YS
self.setSize(w, h)
# create stacks
for i in range(4):
for j in range(13):
x, y, = dx + l.XM + j*l.XS, l.YM + (i+1)*l.YS
s.rows.append(
DerLetzteMonarch_RowStack(
x, y, self, max_accept=1, max_cards=2))
for i in range(4):
x, y, = l.XM + (i+2)*l.XS, l.YM
s.reserves.append(
DerLetzteMonarch_ReserveStack(
x, y, self, max_accept=0))
for i in range(4*decks):
x, y, = l.XM + (i+7)*l.XS, l.YM
s.foundations.append(DerLetzteMonarch_Foundation(x, y, self,
suit=i % 4, max_move=0))
s.talon = self.Talon_Class(l.XM, l.YM, self)
if texts:
l.createText(s.talon, 'ne')
# define stack-groups (non default)
self.sg.talonstacks = [s.talon]
self.sg.openstacks = s.foundations + s.rows
self.sg.dropstacks = s.rows + s.reserves
self.sg.reservestacks = s.reserves
#
# game overrides
#
def startGame(self):
self.s.talon.dealRow(rows=self.s.rows[:39], frames=0)
self.startDealSample()
self.s.talon.dealRow(rows=self.s.rows[39:])
def isGameWon(self):
c = 0
for s in self.s.foundations:
c = c + len(s.cards)
return c == self.gameinfo.ncards-1
def getAutoStacks(self, event=None):
return ((), self.s.reserves, ())
def getDemoInfoText(self):
return "Der letzte\nMonarch"
#
# game extras
#
def isNeighbour(self, stack1, stack2):
if not (0 <= stack1.id <= 51 and 0 <= stack2.id <= 51):
return False
column = stack2.id % 13
diff = stack1.id - stack2.id
if column == 0:
return diff in (-13, 1, 13)
elif column == 12:
return diff in (-13, -1, 13)
else:
return diff in (-13, -1, 1, 13)
class TheLastMonarchII(DerLetzteMonarch):
Talon_Class = TalonStack
def createGame(self):
DerLetzteMonarch.createGame(self, texts=True)
def fillStack(self, stack):
if stack in self.s.rows and not stack.cards:
if self.s.talon.cards:
old_state = self.enterState(self.S_FILL)
self.s.talon.flipMove()
self.s.talon.moveMove(1, stack)
self.leaveState(old_state)
# ************************************************************************
# * Doublets
# ************************************************************************
class DoubletsII(Game):
FILL_STACKS_AFTER_DROP = False # for Nestor_RowStack
def createGame(self):
l, s = Layout(self), self.s
self.setSize(l.XM+12*l.XS, l.YM+3*l.YS+3*l.YOFFSET)
x, y = l.XM, l.YM
for i in range(12):
s.rows.append(Nestor_RowStack(x, y, self,
max_move=1, max_accept=1,
dir=0, base_rank=NO_RANK))
x += l.XS
x, y = l.XM, self.height-l.YS
s.talon = TalonStack(x, y, self)
l.createText(s.talon, 'n')
x, y = self.width-l.XS, self.height-l.YS
s.foundations.append(AbstractFoundationStack(x, y, self, suit=ANY_SUIT,
max_move=0, max_cards=52,
base_rank=ANY_RANK, max_accept=0))
l.createText(s.foundations[0], "n")
l.defaultStackGroups()
def startGame(self):
for i in range(3):
self.s.talon.dealRow(frames=0, flip=0)
self._startAndDealRow()
def fillStack(self, stack):
if stack in self.s.rows:
if stack.cards:
stack.flipMove(animation=True)
else:
if self.s.talon.cards:
old_state = self.enterState(self.S_FILL)
self.s.talon.flipMove()
self.s.talon.moveMove(1, stack)
self.leaveState(old_state)
# ************************************************************************
# * Right and Left
# ************************************************************************
class RightAndLeft_Talon(DealRowRedealTalonStack):
def _redeal(self, rows=None, reverse=False, frames=0):
return DealRowRedealTalonStack._redeal(self, rows=rows,
reverse=reverse, frames=3)
class RightAndLeft(Game):
FILL_STACKS_AFTER_DROP = False
def createGame(self):
# create layout
l, s = Layout(self), self.s
# set window
self.setSize(l.XM+5*l.XS, l.YM+3*l.YS)
# create stacks
x, y = l.XM+l.XS, l.YM+2*l.YS
s.talon = RightAndLeft_Talon(x, y, self, max_rounds=UNLIMITED_REDEALS)
l.createText(s.talon, 'se')
x, y = l.XM+0.5*l.XS, l.YM
for i in range(2):
stack = Nestor_RowStack(x, y, self, max_move=1, max_accept=1,
dir=0, base_rank=NO_RANK)
stack.CARD_YOFFSET = 0
l.createText(stack, 's')
s.rows.append(stack)
x += l.XS
x += 1.5*l.XS
s.foundations.append(AbstractFoundationStack(x, y, self, suit=ANY_SUIT,
max_move=0, max_cards=104,
max_accept=0, base_rank=ANY_RANK))
l.createText(s.foundations[0], 's')
# define stack-groups
l.defaultStackGroups()
def startGame(self):
self._startAndDealRow()
# register the game
registerGame(GameInfo(89, MonteCarlo, "Monte Carlo",
GI.GT_PAIRING_TYPE, 1, 0, GI.SL_MOSTLY_LUCK,
altnames=("Quilt",)))
registerGame(GameInfo(216, MonteCarlo2Decks, "Monte Carlo (2 decks)",
GI.GT_PAIRING_TYPE, 2, 0, GI.SL_MOSTLY_LUCK))
registerGame(GameInfo(212, Weddings, "Weddings",
GI.GT_PAIRING_TYPE, 1, 0, GI.SL_MOSTLY_LUCK))
registerGame(GameInfo(90, SimpleCarlo, "Simple Carlo",
GI.GT_PAIRING_TYPE, 1, 0, GI.SL_MOSTLY_LUCK))
registerGame(GameInfo(91, SimplePairs, "Simple Pairs",
GI.GT_PAIRING_TYPE, 1, 0, GI.SL_LUCK,
altnames=("Jamestown",)))
registerGame(GameInfo(92, Neighbour, "Neighbour",
GI.GT_PAIRING_TYPE, 1, 0, GI.SL_MOSTLY_LUCK))
registerGame(GameInfo(96, Fourteen, "Fourteen",
GI.GT_PAIRING_TYPE | GI.GT_OPEN, 1, 0,
GI.SL_MOSTLY_LUCK))
registerGame(GameInfo(235, Nestor, "Nestor",
GI.GT_PAIRING_TYPE | GI.GT_OPEN, 1, 0,
GI.SL_MOSTLY_LUCK))
registerGame(GameInfo(152, DerLetzteMonarch, "The Last Monarch",
GI.GT_1DECK_TYPE | GI.GT_OPEN, 1, 0, GI.SL_MOSTLY_SKILL,
altnames=("Der letzte Monarch",)))
registerGame(GameInfo(328, TheWish, "The Wish",
GI.GT_PAIRING_TYPE, 1, 0, GI.SL_MOSTLY_LUCK,
ranks=(0, 6, 7, 8, 9, 10, 11, 12)))
registerGame(GameInfo(329, TheWishOpen, "The Wish (open)",
GI.GT_PAIRING_TYPE | GI.GT_OPEN | GI.GT_ORIGINAL, 1, 0,
GI.SL_MOSTLY_SKILL,
ranks=(0, 6, 7, 8, 9, 10, 11, 12)))
registerGame(GameInfo(368, Vertical, "Vertical",
GI.GT_PAIRING_TYPE | GI.GT_OPEN, 1, 0,
GI.SL_MOSTLY_LUCK))
registerGame(GameInfo(649, DoubletsII, "Doublets II",
GI.GT_PAIRING_TYPE, 1, 0, GI.SL_MOSTLY_LUCK))
registerGame(GameInfo(663, TheLastMonarchII, "The Last Monarch II",
GI.GT_2DECK_TYPE | GI.GT_ORIGINAL, 2, 0,
GI.SL_MOSTLY_SKILL))
registerGame(GameInfo(727, RightAndLeft, "Right and Left",
GI.GT_PAIRING_TYPE, 2, -1, GI.SL_LUCK))
registerGame(GameInfo(801, DoubleNestor, "Double Nestor",
GI.GT_PAIRING_TYPE | GI.GT_OPEN, 2, 0,
GI.SL_MOSTLY_LUCK))