Mercurial > traipse_dev
view orpg/dieroller/die.py @ 63:c160f26ecf65 ornery-dev
Traipse Dev 'OpenRPG' {090817-00}
Traipse is a distribution of OpenRPG that is designed to be easy to setup and go. Traipse also makes it easy for developers to work on code without fear of sacrifice. 'Ornery-Orc' continues the trend of 'Grumpy' and adds fixes to the code. 'Ornery-Orc''s main goal is to offer more advanced features and enhance the productivity of the user.
Update Summary:
Minor fixes to plugins. Hidden Die Roll no longer prints out data to the terminal. Bug fix in Simple Init; if the Auto Advance check was off and members were added, buttons would remain disabled. Added new CSS classes to Simple Init posts. Fix to Chat Log so log parses CSS classes correctly. Added Text Color button from Core; background color defaults to your settings. Fix to Alias Lib so panes have a minimum size.
author | sirebral |
---|---|
date | Mon, 17 Aug 2009 00:56:02 -0500 |
parents | 4385a7d0efd1 |
children | 449a8900f9ac |
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#!/usr/bin/env python # Copyright (C) 2000-2001 The OpenRPG Project # # openrpg-dev@lists.sourceforge.net # # 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; if not, write to the Free Software # Foundation, Inc., 675 Mass Ave, Cambridge, MA 02139, USA. # -- # # File: die.py # Author: Andrew Bennett # Maintainer: # Version: # $Id: die.py,v 1.13 2007/03/13 17:53:42 digitalxero Exp $ # # Description: This class is used to make working with dice easier # __version__ = "$Id: die.py,v 1.13 2007/03/13 17:53:42 digitalxero Exp $" import random import UserList import copy #import string class die_base(UserList.UserList): def __init__(self,source = []): if isinstance(source, (int, float, basestring)): s = [] s.append(di(source)) else: s = source UserList.UserList.__init__(self,s) def sum(self): s = 0 for a in self.data: s += int(a) return s def __lshift__(self,other): if type(other) == type(3) or type(other) == type(3.0): o = other elif hasattr(other,"sum"): o = other.sum() else: return None result = [] for die in self: if die < o: result.append(die) return self.__class__(result) def __rshift__(self,other): if type(other) == type(3) or type(other) == type(3.0): o = other elif hasattr(other,"sum"): o = other.sum() else: return None result = [] for die in self: if die > o: result.append(die) return self.__class__(result) def __rlshift__(self,other): return self.__rshift__(other) def __rrshift__(self,other): return self.__lshift__(other) def __str__(self): if len(self.data) > 0: myStr = "[" + str(self.data[0]) for a in self.data[1:]: myStr += "," myStr += str(a) myStr += "] = (" + str(self.sum()) + ")" else: myStr = "[] = (0)" return myStr def __lt__(self,other): if type(other) == type(3) or type(other) == type(3.0): return (self.sum() < other) elif hasattr(other,"sum"): return (self.sum() < other.sum()) else: return UserList.UserList.__lt__(self,other) def __le__(self,other): if type(other) == type(3) or type(other) == type(3.0): return (self.sum() <= other) elif hasattr(other,"sum"): return (self.sum() <= other.sum()) else: return UserList.UserList.__le__(self,other) def __eq__(self,other): if type(other) == type(3) or type(other) == type(3.0): return (self.sum() == other) elif hasattr(other,"sum"): return (self.sum() == other.sum()) else: return UserList.UserList.__eq__(self,other) def __ne__(self,other): if type(other) == type(3) or type(other) == type(3.0): return (self.sum() != other) elif hasattr(other,"sum"): return (self.sum() != other.sum()) else: return UserList.UserList.__ne__(self,other) def __gt__(self,other): if type(other) == type(3) or type(other) == type(3.0): return (self.sum() > other) elif hasattr(other,"sum"): return (self.sum() > other.sum()) else: return UserList.UserList.__gt__(self,other) def __ge__(self,other): if type(other) == type(3) or type(other) == type(3.0): return (self.sum() >= other) elif hasattr(other,"sum"): return (self.sum() >= other.sum()) else: return UserList.UserList.__ge__(self,other) def __cmp__(self,other): # this function included for backwards compatibility # As of 2.1, lists implement the "rich comparison" # methods overloaded above. if type(other) == type(3) or type(other) == type(3.0): return cmp(self.sum(), other) elif hasattr(other,"sum"): return cmp(self.sum(), other.sum()) else: return UserList.UserList.__cmp__(self,other) def __rcmp__(self,other): return self.__cmp__(other) def __add__(self,other): mycopy = copy.deepcopy(self) if type(other) == type(3) or type(other) == type(3.0): #if other < 0: # return self.__sub__(-other) #other = [di(other,other)] other = [static_di(other)] #return self.sum() + other elif type(other) == type("test"): return self mycopy.extend(other) #result = UserList.UserList.__add__(mycopy,other) return mycopy def __iadd__(self,other): return self.__add__(other) def __radd__(self,other): mycopy = copy.deepcopy(self) if type(other) == type(3) or type(other) == type(3.0): new_die = di(0) new_die.set_value(other) other = new_die mycopy.insert(0,other) return mycopy def __int__(self): return self.sum() def __sub__(self,other): mycopy = copy.deepcopy(self) if type(other) == type(3) or type(other) == type(3.0): neg_die = static_di(-other) #neg_die.set_value(-other) other = [neg_die] #return self.sum() - other else: other = -other mycopy.extend(other) return mycopy def __rsub__(self,other): mycopy = -copy.deepcopy(self) #print type(other) if type(other) == type(3) or type(other) == type(3.0): new_die = di(0) new_die.set_value(other) other = new_die mycopy.insert(0,other) return mycopy def __isub__(self,other): return self.__sub__(other) def __mul__(self,other): if type(other) == type(3) or type(other) == type(3.0): return self.sum() * other elif hasattr(other,"sum"): return other.sum() * self.sum() else: return UserList.UserList.__mul__(self,other) def __rmul__(self,other): return self.__mul__(other) def __div__(self,other): if type(other) == type(3) or type(other) == type(3.0): return float(self.sum()) / other elif hasattr(other,"sum"): return float(self.sum()) / other.sum() else: return UserList.UserList.__div__(self,other) def __rdiv__(self,other): if type(other) == type(3) or type(other) == type(3.0): return other / float(self.sum()) elif hasattr(other,"sum"): return other.sum() / float(self.sum()) else: return UserList.UserList.__rdiv__(self,other) def __mod__(self,other): if type(other) == type(3) or type(other) == type(3.0): return self.sum()%other elif hasattr(other,"sum"): return self.sum() % other.sum() else: return UserList.UserList.__mod__(self,other) def __rmod__(self,other): if type(other) == type(3) or type(other) == type(3.0): return other % self.sum() elif hasattr(other,"sum"): return other.sum() % self.sum() else: return UserList.UserList.__rmod__(self,other) def __neg__(self): for i in range(len(self.data)): self.data[i] = -self.data[i] return self def __pos__(self): for i in range(len(self.data)): self.data[i] = +self.data[i] return self def __abs__(self): for i in range(len(self.data)): self.data[i] = abs(self.data[i]) return self #return abs(self.sum()) def __pow__(self,other): if type(other) == type(3) or type(other) == type(3.0): return self.sum() ** other elif hasattr(other,"sum"): return self.sum() ** other.sum() else: return UserList.UserList.__pow__(self,other) def __rpow__(self,other): # We're overloading exponentiation of ints to create "other" number of dice if other >= 1: result = self.__class__(self[0].sides) for t in range(other-1): result+=self.__class__(self[0].sides) else: result = None return result ### di class to handle actual dice class di: def __init__(self,sides,min=1): self.sides = sides self.history = None self.value = None self.target = None self.roll(min) def __str__(self): if len(self.history) > 1: return str(self.history) else: return str(self.value) def __neg__(self): self.value = -self.value for i in range(len(self.history)): self.history[i] = -self.history[i] return self def __pos__(self): self.value = +self.value for i in range(len(self.history)): self.history[i] = +self.history[i] return self def __abs__(self): self.value = abs(self.value) for i in range(len(self.history)): self.history[i] = abs(self.history[i]) return self def __repr__(self): if len(self.history) > 1: return str(self.history) else: return str(self.value) def __int__(self): return self.value def __lt__(self,other): if type(other) == type(3) or type(other) == type(3.0): return self.value < other elif hasattr(other,"value"): return self.value < other.value else: return self < other def __le__(self,other): if type(other) == type(3) or type(other) == type(3.0): return self.value <= other elif hasattr(other,"value"): return self.value <= other.value else: return self <= other def __eq__(self,other): if type(other) == type(3) or type(other) == type(3.0): return self.value == other elif hasattr(other,"value"): return self.value == other.value else: return self == other def __ne__(self,other): if type(other) == type(3) or type(other) == type(3.0): return self.value != other elif hasattr(other,"value"): return self.value != other.value else: return self != other def __gt__(self,other): if type(other) == type(3) or type(other) == type(3.0): return self.value > other elif hasattr(other,"value"): return self.value > other.value else: return self > other def __ge__(self,other): if type(other) == type(3) or type(other) == type(3.0): return self.value >= other elif hasattr(other,"value"): return self.value >= other.value else: return self >= other def __cmp__(self,other): # this function included for backwards compatibility # As of 2.1, lists implement the "rich comparison" # methods overloaded above. if type(other) == type(3) or type(other) == type(3.0): return cmp(self.value, other) elif hasattr(other,"value"): return cmp(self.value, other.value) else: return cmp(self,other) def roll(self,min=1): if isinstance(self.sides, basestring) and self.sides.lower() == 'f': self.value = random.randint(-1, 1) else: #self.value = random.randint(min, self.sides) self.value = int(random.uniform(min, self.sides+1)) self.history = [] self.history.append(self.value) def extraroll(self): if isinstance(self.sides, basestring) and self.sides.lower() == 'f': result = random.randint(-1, 1) else: #result = random.randint(1, self.sides) result = int(random.uniform(1,self.sides+1)) self.value += result self.history.append(result) def lastroll(self): return self.history[len(self.history)-1] def set_value(self,value): self.value = value self.history = [] self.history.append(self.value) def modify(self,mod): self.value += mod self.history.append(mod) def gethistory(self): return self.history[:] class static_di(di): def __init__(self,value): di.__init__(self,value,value) self.set_value(value) class std(die_base): def __init__(self,source=[]): die_base.__init__(self,source) # Examples of adding member functions through inheritance. def ascending(self): result = self[:] result.sort() return result def descending(self): result = self[:] result.sort() result.reverse() return result def takeHighest(self,num_dice): return self.descending()[:num_dice] def takeLowest(self,num_dice): return self.ascending()[:num_dice] def extra(self,num): for i in range(len(self.data)): if self.data[i].lastroll() >= num: self.data[i].extraroll() return self def open(self,num): if num <= 1: self done = 1 for i in range(len(self.data)): if self.data[i].lastroll() >= num: self.data[i].extraroll() done = 0 if done: return self else: return self.open(num) def minroll(self,min): for i in range(len(self.data)): if self.data[i].lastroll() < min: self.data[i].roll(min) return self def each(self,mod): mod = int(mod) for i in range(len(self.data)): self.data[i].modify(mod) return self def vs(self, target): for dn in self.data: dn.target = target return self ## If we are testing against a saving throw, we check for ## greater than or equal to against the target value and ## we only return the number of successful saves. A negative ## value will never be generated. def sum(self): retValue = 0 for dn in self.data: setValue = reduce( lambda x, y : int(x)+int(y), dn.history ) if dn.target: if setValue >= dn.target: retValue += 1 else: retValue += setValue return retValue