lafrite
/
Mapytex
1
0
Fork 0
Code Issues Pull Requests Releases Wiki Activity

remove tabs

This commit is contained in:
Lafrite 2013-08-08 01:12:11 +02:00
parent 08f493ae79
commit 80bdd86297
4 changed files with 414 additions and 413 deletions
Show Stats Download Patch File Download Diff File Expand all files Collapse all files

34
arithmetic.py
View File

@ -3,26 +3,26 @@
def gcd(a, b):
"""Compute gcd(a,b)
"""Compute gcd(a,b)
:param a: first number
:param b: second number
:returns: the gcd
:param a: first number
:param b: second number
:returns: the gcd
"""
if a > b:
c = a % b
else:
c = b % a
"""
if a > b:
c = a % b
else:
c = b % a
if c == 0:
return min(a,b)
elif a == 1:
return b
elif b == 1:
return a
else:
return gcd(min(a,b), c)
if c == 0:
return min(a,b)
elif a == 1:
return b
elif b == 1:
return a
else:
return gcd(min(a,b), c)
# -----------------------------

444
calculus.py
View File

@ -7,315 +7,315 @@ from generic import Stack
def infixToPostfix(infixExp):
"""Transform an infix expression into postfix expression
"""Transform an infix expression into postfix expression
:param infixExp: an infix expression (caracters must be separate by a space)
:returns: the corresponding postfix expression
:param infixExp: an infix expression (caracters must be separate by a space)
:returns: the corresponding postfix expression
:Example:
:Example:
>>> infixToPostfix("1 + 2")
'1 2 +'
>>> infixToPostfix("1 + 2")
'1 2 +'
>>> infixToPostfix("1 * 2 + 3")
'1 2 * 3 +'
>>> infixToPostfix("1 * 2 + 3")
'1 2 * 3 +'
"""
priority = {"*" : 3, "/": 3, "+": 2, "-":2, "(": 1}
opStack = Stack()
postfixList = []
"""
priority = {"*" : 3, "/": 3, "+": 2, "-":2, "(": 1}
opStack = Stack()
postfixList = []
tokenList = infixExp.split(" ")
tokenList = infixExp.split(" ")
for token in tokenList:
if token == "(":
opStack.push(token)
elif token == ")":
topToken = opStack.pop()
while topToken != "(":
postfixList.append(topToken)
topToken = opStack.pop()
elif token in "+-*/":
while (not opStack.isEmpty()) and (priority[opStack.peek()] >= priority[token]):
postfixList.append(opStack.pop())
opStack.push(token)
else:
postfixList.append(token)
for token in tokenList:
if token == "(":
opStack.push(token)
elif token == ")":
topToken = opStack.pop()
while topToken != "(":
postfixList.append(topToken)
topToken = opStack.pop()
elif token in "+-*/":
while (not opStack.isEmpty()) and (priority[opStack.peek()] >= priority[token]):
postfixList.append(opStack.pop())
opStack.push(token)
else:
postfixList.append(token)
while not opStack.isEmpty():
postfixList.append(opStack.pop())
while not opStack.isEmpty():
postfixList.append(opStack.pop())
return " ".join(postfixList)
return " ".join(postfixList)
def computePostfix(postfixExp):
"""Compute a postfix expression
"""Compute a postfix expression
:param postfixExp: a postfix expression
:returns: the result of the expression
:param postfixExp: a postfix expression
:returns: the result of the expression
"""
print(postfixToInfix(postfixExp))
# where to save numbers or
operandeStack = Stack()
"""
print(postfixToInfix(postfixExp))
# where to save numbers or
operandeStack = Stack()
tokenList = postfixExp.split(" ")
tokenList = postfixExp.split(" ")
for (i,token) in enumerate(tokenList):
if token in "+-*/":
op2 = operandeStack.pop()
op1 = operandeStack.pop()
res = doMath(token, op1, op2)
operandeStack.push(res)
for (i,token) in enumerate(tokenList):
if token in "+-*/":
op2 = operandeStack.pop()
op1 = operandeStack.pop()
res = doMath(token, op1, op2)
operandeStack.push(res)
#print("Operation: {op1} {op} {op2}".format(op1 = op1, op = token, op2 = op2))
#print(operandeStack)
#print(tokenList[i+1:])
newPostfix = " ".join(operandeStack + tokenList[i+1:])
print(postfixToInfix(newPostfix))
#print("Operation: {op1} {op} {op2}".format(op1 = op1, op = token, op2 = op2))
#print(operandeStack)
#print(tokenList[i+1:])
newPostfix = " ".join(operandeStack + tokenList[i+1:])
print(postfixToInfix(newPostfix))
else:
operandeStack.push(token)
else:
operandeStack.push(token)
return operandeStack.pop()
return operandeStack.pop()
def computePostfixBis(postfixExp):
"""Compute a postfix expression like a good student
"""Compute a postfix expression like a good student
:param postfixExp: a postfix expression
:returns: the result of the expression
:param postfixExp: a postfix expression
:returns: the result of the expression
"""
print(postfixToInfix(postfixExp))
# where to save numbers or
operandeStack = Stack()
"""
print(postfixToInfix(postfixExp))
# where to save numbers or
operandeStack = Stack()
tokenList = postfixExp.split(" ")
tokenList = postfixExp.split(" ")
# On fait le calcul jusqu'à n'avoir plus qu'un élément
while len(tokenList) > 1:
tmpTokenList = []
# on va chercher les motifs du genre A B + pour les calculer
while len(tokenList) > 2:
if isNumber(tokenList[0]) and isNumber(tokenList[1]) and tokenList[2] in "+-*/":
# S'il y a une opération à faire
op1 = tokenList[0]
op2 = tokenList[1]
token = tokenList[2]
res = doMath(token, op1, op2)
# On fait le calcul jusqu'à n'avoir plus qu'un élément
while len(tokenList) > 1:
tmpTokenList = []
# on va chercher les motifs du genre A B + pour les calculer
while len(tokenList) > 2:
if isNumber(tokenList[0]) and isNumber(tokenList[1]) and tokenList[2] in "+-*/":
# S'il y a une opération à faire
op1 = tokenList[0]
op2 = tokenList[1]
token = tokenList[2]
res = doMath(token, op1, op2)
tmpTokenList.append(res)
tmpTokenList.append(res)
# Comme on vient de faire le calcul, on peut détruire aussi les deux prochains termes
del tokenList[0:3]
else:
tmpTokenList.append(tokenList[0])
# Comme on vient de faire le calcul, on peut détruire aussi les deux prochains termes
del tokenList[0:3]
else:
tmpTokenList.append(tokenList[0])
del tokenList[0]
tmpTokenList += tokenList
del tokenList[0]
tmpTokenList += tokenList
tokenList = tmpTokenList.copy()
print(postfixToInfix(" ".join(tokenList)))
tokenList = tmpTokenList.copy()
print(postfixToInfix(" ".join(tokenList)))
return tokenList[0]
return tokenList[0]
def isNumber(exp):
"""Check if the expression can be a number
"""Check if the expression can be a number
:param exp: an expression
:returns: True if the expression can be a number and false otherwise
:param exp: an expression
:returns: True if the expression can be a number and false otherwise
"""
tokenList = exp.split(" ")
if len(tokenList) != 1:
# si l'expression est trop longue pour être un chiffre
return 0
return exp.isdigit() or (exp[0] == "-" and exp[1:].isdigit())
"""
tokenList = exp.split(" ")
if len(tokenList) != 1:
# si l'expression est trop longue pour être un chiffre
return 0
return exp.isdigit() or (exp[0] == "-" and exp[1:].isdigit())
def doMath(op, op1, op2):
"""Compute "op1 op op2"
"""Compute "op1 op op2"
:param op: operator
:param op1: first operande
:param op2: second operande
:returns: string representing the result
:param op: operator
:param op1: first operande
:param op2: second operande
:returns: string representing the result
"""
return str(eval(op1 + op + op2))
"""
return str(eval(op1 + op + op2))
def postfixToInfix(postfixExp):
"""Transforme postfix expression into infix expression
"""Transforme postfix expression into infix expression
:param postfixExp: a postfix expression
:returns: the corresponding infix expression
:param postfixExp: a postfix expression
:returns: the corresponding infix expression
"""
operandeStack = Stack()
"""
operandeStack = Stack()
tokenList = postfixExp.split(" ")
tokenList = postfixExp.split(" ")
for (i,token) in enumerate(tokenList):
if token in "+-*/":
op2 = operandeStack.pop()
if needPar(op2, token, "after"):
op2 = "( " + op2 + " )"
op1 = operandeStack.pop()
if needPar(op1, token, "before"):
op1 = "( " + op1 + " )"
res = "{op1} {op} {op2}".format(op1 = op1, op = token, op2 = op2)
for (i,token) in enumerate(tokenList):
if token in "+-*/":
op2 = operandeStack.pop()
if needPar(op2, token, "after"):
op2 = "( " + op2 + " )"
op1 = operandeStack.pop()
if needPar(op1, token, "before"):
op1 = "( " + op1 + " )"
res = "{op1} {op} {op2}".format(op1 = op1, op = token, op2 = op2)
operandeStack.push(res)
operandeStack.push(res)
else:
operandeStack.push(token)
else:
operandeStack.push(token)
return operandeStack.pop()
return operandeStack.pop()
def needPar(operande, operator, posi = "after"):
"""Says whether or not the operande needs parenthesis
"""Says whether or not the operande needs parenthesis
:param operande: the operande
:param operator: the operator
:param posi: "after"(default) if the operande will be after the operator, "before" othewise
:returns: bollean
"""
priority = {"*" : 3, "/": 3, "+": 2, "-":2}
:param operande: the operande
:param operator: the operator
:param posi: "after"(default) if the operande will be after the operator, "before" othewise
:returns: bollean
"""
priority = {"*" : 3, "/": 3, "+": 2, "-":2}
if isNumber(operande) and "-" in operande:
return 1
elif not isNumber(operande):
# Si c'est une grande expression ou un chiffre négatif
stand_alone = get_main_op(operande)
# Si la priorité de l'operande est plus faible que celle de l'opérateur
minor_priority = priority[get_main_op(operande)] < priority[operator]
# Si l'opérateur est -/ pour after ou juste / pour before
special = (operator in "-/" and posi == "after") or (operator in "/" and posi == "before")
if isNumber(operande) and "-" in operande:
return 1
elif not isNumber(operande):
# Si c'est une grande expression ou un chiffre négatif
stand_alone = get_main_op(operande)
# Si la priorité de l'operande est plus faible que celle de l'opérateur
minor_priority = priority[get_main_op(operande)] < priority[operator]
# Si l'opérateur est -/ pour after ou juste / pour before
special = (operator in "-/" and posi == "after") or (operator in "/" and posi == "before")
return stand_alone and (minor_priority or special)
else:
return 0
return stand_alone and (minor_priority or special)
else:
return 0
def get_main_op(exp):
"""Getting the main operation of the expression
"""Getting the main operation of the expression
:param exp: the expression
:returns: the main operation (+, -, * or /) or 0 if the expression is only one element
:param exp: the expression
:returns: the main operation (+, -, * or /) or 0 if the expression is only one element
"""
"""
priority = {"*" : 3, "/": 3, "+": 2, "-":2}
priority = {"*" : 3, "/": 3, "+": 2, "-":2}
parStack = Stack()
tokenList = exp.split(" ")
parStack = Stack()
tokenList = exp.split(" ")
if len(tokenList) == 1:
# Si l'expression n'est qu'un élément
return 0
if len(tokenList) == 1:
# Si l'expression n'est qu'un élément
return 0
main_op = []
main_op = []
for token in tokenList:
if token == "(":
parStack.push(token)
elif token == ")":
parStack.pop()
elif token in "+-*/" and parStack.isEmpty():
main_op.append(token)
for token in tokenList:
if token == "(":
parStack.push(token)
elif token == ")":
parStack.pop()
elif token in "+-*/" and parStack.isEmpty():
main_op.append(token)
return min(main_op, key = lambda s: priority[s])
return min(main_op, key = lambda s: priority[s])
def expand_list(list_list):
"""Expand list of list
"""Expand list of list
:param list: the list to expande
:returns: list of expanded lists
:param list: the list to expande
:returns: list of expanded lists
:Example:
:Example:
>>> expand_list([1,2,[3,4],5,[6,7,8]])
[[1, 2, 3, 5, 6], [1, 2, 4, 5, 7], [1, 2, 4, 5, 8]]
>>> expand_list([1,2,[3,4],5,[6,7,8]])
[[1, 2, 3, 5, 6], [1, 2, 4, 5, 7], [1, 2, 4, 5, 8]]
"""
list_in_list = [i for i in list_list if type(i) == list].copy()
nbr_ans_list = max([len(i) for i in list_in_list])
"""
list_in_list = [i for i in list_list if type(i) == list].copy()
nbr_ans_list = max([len(i) for i in list_in_list])
ans = [list_list.copy() for i in range(nbr_ans_list)]
for (i,l) in enumerate(ans):
for (j,e) in enumerate(l):
if type(e) == list:
ans[i][j] = e[min(i,len(e)-1)]
ans = [list_list.copy() for i in range(nbr_ans_list)]
for (i,l) in enumerate(ans):
for (j,e) in enumerate(l):
if type(e) == list:
ans[i][j] = e[min(i,len(e)-1)]
return ans
return ans
def debug_var(name, var):
"""print the name of the variable and the value
"""print the name of the variable and the value
:param name: the name of the variable
:param var: the variable we want information
"""
print(name, ": ", var)
:param name: the name of the variable
:param var: the variable we want information
"""
print(name, ": ", var)
def test(exp):
"""Make various test on an expression
"""Make various test on an expression
"""
print("-------------")
print("Expression ",exp)
postfix = infixToPostfix(exp)
#print("Postfix " , postfix)
#print(computePostfix(postfix))
#print("Bis")
print(computePostfixBis(postfix))
#print(postfixToInfix(postfix))
#print(get_main_op(exp))
"""
print("-------------")
print("Expression ",exp)
postfix = infixToPostfix(exp)
#print("Postfix " , postfix)
#print(computePostfix(postfix))
#print("Bis")
print(computePostfixBis(postfix))
#print(postfixToInfix(postfix))
#print(get_main_op(exp))
if __name__ == '__main__':
#exp = "1 + 3 * 5"
#test(exp)
#exp = "1 + 3 * 5"
#test(exp)
#exp = "2 * 3 * 3 * 5"
#test(exp)
#exp = "2 * 3 * 3 * 5"
#test(exp)
#exp = "2 * 3 + 3 * 5"
#test(exp)
#exp = "2 * 3 + 3 * 5"
#test(exp)
#exp = "2 * ( 3 + 4 ) + 3 * 5"
#test(exp)
#
#exp = "2 * ( 3 + 4 ) + ( 3 - 4 ) * 5"
#test(exp)
#
#exp = "2 * ( 2 - ( 3 + 4 ) ) + ( 3 - 4 ) * 5"
#test(exp)
#
#exp = "2 * ( 2 - ( 3 + 4 ) ) + 5 * ( 3 - 4 )"
#test(exp)
#
#exp = "2 + 5 * ( 3 - 4 )"
#test(exp)
#
#exp = "( 2 + 5 ) * ( 3 - 4 )"
#test(exp)
#
#exp = "( 2 + 5 ) * ( 3 * 4 )"
#test(exp)
#
#exp = "( 2 + 5 ) / ( 3 * 4 )"
#test(exp)
#exp = "2 * ( 3 + 4 ) + 3 * 5"
#test(exp)
#
#exp = "2 * ( 3 + 4 ) + ( 3 - 4 ) * 5"
#test(exp)
#
#exp = "2 * ( 2 - ( 3 + 4 ) ) + ( 3 - 4 ) * 5"
#test(exp)
#
#exp = "2 * ( 2 - ( 3 + 4 ) ) + 5 * ( 3 - 4 )"
#test(exp)
#
#exp = "2 + 5 * ( 3 - 4 )"
#test(exp)
#
#exp = "( 2 + 5 ) * ( 3 - 4 )"
#test(exp)
#
#exp = "( 2 + 5 ) * ( 3 * 4 )"
#test(exp)
#
#exp = "( 2 + 5 ) / ( 3 * 4 )"
#test(exp)
#print(expand_list([1,2,['a','b','c'], 3, ['d','e']]))
## Ce denier pose un soucis. Pour le faire marcher il faudrai implémenter le calcul avec les fractions
#exp = "( 2 + 5 ) / 3 * 4"
#test(exp)
import doctest
doctest.testmod()
#print(expand_list([1,2,['a','b','c'], 3, ['d','e']]))
## Ce denier pose un soucis. Pour le faire marcher il faudrai implémenter le calcul avec les fractions
#exp = "( 2 + 5 ) / 3 * 4"
#test(exp)
import doctest
doctest.testmod()
# -----------------------------

275
fraction.py
View File

@ -5,184 +5,185 @@ from calculus import isNumber
from arithmetic import gcd
class Fraction(object):
"""Fractions!"""
"""Fractions!"""
def __init__(self, num, denom = 1):
"""To initiate a fraction we need a numerator and a denominator
def __init__(self, num, denom = 1):
"""To initiate a fraction we need a numerator and a denominator
:param num: the numerator
:param denom: the denominator
:param num: the numerator
:param denom: the denominator
"""
self._num = num
self._denom = denom
"""
self._num = num
self._denom = denom
def simplify(self):
"""Simplify the fraction
def simplify(self):
"""Simplify the fraction
:returns: steps to simplify the fraction or the fraction if there is nothing to do
"""
steps = [str(self)]
:returns: steps to simplify the fraction or the fraction if there is nothing to do
"""
steps = [str(self)]
if self._denom < 0:
self._num = - self._num
self._denom = - self._denom
steps += [str(self)]
if self._denom < 0:
self._num = - self._num
self._denom = - self._denom
steps += [str(self)]
gcd_ = gcd(abs(self._num), abs(self._denom))
if self._num == self._denom:
self._num = 1
self._denom = 1
steps += [str(self)]
elif gcd_ != 1:
gcd_ = gcd(abs(self._num), abs(self._denom))
if self._num == self._denom:
self._num = 1
self._denom = 1
steps += [str(self)]
self._num, self._denom = self._num // gcd_ , self._denom // gcd_
steps += ["( {reste1} * {gcd} ) / ( {reste2} * {gcd} )".format(reste1 = self._num, reste2 = self._denom, gcd = gcd_)]
steps += [str(self)]
return steps
elif gcd_ != 1:
self._num, self._denom = self._num // gcd_ , self._denom // gcd_
steps += ["( {reste1} * {gcd} ) / ( {reste2} * {gcd} )".format(reste1 = self._num, reste2 = self._denom, gcd = gcd_)]
steps += [str(self)]
def __str__(self):
if self._denom == 1:
return str(self._num)
else:
return str(self._num) + " / " + str(self._denom)
def __add__(self, other):
if type(other) == Fraction:
#cool
number = other
else:
number = Fraction(other)
return steps
steps = ["{frac1} + {frac2}".format(frac1 = self, frac2 = number)]
def __str__(self):
if self._denom == 1:
return str(self._num)
else:
return str(self._num) + " / " + str(self._denom)
def __add__(self, other):
if type(other) == Fraction:
#cool
number = other
else:
number = Fraction(other)
if self._denom == number._denom:
com_denom = self._denom
num1 = self._num
num2 = number._num
steps = ["{frac1} + {frac2}".format(frac1 = self, frac2 = number)]
else:
gcd_denom = gcd(self._denom, number._denom)
coef1 = number._denom // gcd_denom
coef2 = self._denom // gcd_denom
if self._denom == number._denom:
com_denom = self._denom
num1 = self._num
num2 = number._num
steps += ["( {num1} * {coef1} ) / ( {den1} * {coef1} ) + ( {num2} * {coef2} ) / ( {den2} * {coef2} )".format(num1 = self._num, den1 = self._denom, coef1 = coef1, num2 = number._num, den2 = number._denom, coef2 = coef2)]
else:
gcd_denom = gcd(self._denom, number._denom)
coef1 = number._denom // gcd_denom
coef2 = self._denom // gcd_denom
com_denom = self._denom * coef1
num1 = self._num * coef1
num2 = number._num * coef2
steps += ["( {num1} * {coef1} ) / ( {den1} * {coef1} ) + ( {num2} * {coef2} ) / ( {den2} * {coef2} )".format(num1 = self._num, den1 = self._denom, coef1 = coef1, num2 = number._num, den2 = number._denom, coef2 = coef2)]
steps += ["( {num1} + {num2} ) / {denom}".format(num1 = num1, num2 = num2, denom = com_denom)]
com_denom = self._denom * coef1
num1 = self._num * coef1
num2 = number._num * coef2
num = num1 + num2
steps += ["( {num1} + {num2} ) / {denom}".format(num1 = num1, num2 = num2, denom = com_denom)]
ans_frac = Fraction(num, com_denom)
steps += ans_frac.simplify()
num = num1 + num2
return steps
ans_frac = Fraction(num, com_denom)
steps += ans_frac.simplify()
def __sub__(self, other):
if type(other) == Fraction:
#cool
number = other
else:
number = Fraction(other)
return steps
steps = ["{frac1} - {frac2}".format(frac1 = self, frac2 = number)]
def __sub__(self, other):
if type(other) == Fraction:
#cool
number = other
else:
number = Fraction(other)
if self._denom == number._denom:
com_denom = self._denom
num1 = self._num
num2 = number._num
steps = ["{frac1} - {frac2}".format(frac1 = self, frac2 = number)]
else:
gcd_denom = gcd(self._denom, number._denom)
coef1 = number._denom // gcd_denom
coef2 = self._denom // gcd_denom
if self._denom == number._denom:
com_denom = self._denom
num1 = self._num
num2 = number._num
steps += ["( {num1} * {coef1} ) / ( {den1} * {coef1} ) - ( {num2} * {coef2} ) / ( {den2} * {coef2} )".format(num1 = self._num, den1 = self._denom, coef1 = coef1, num2 = number._num, den2 = number._denom, coef2 = coef2)]
else:
gcd_denom = gcd(self._denom, number._denom)
coef1 = number._denom // gcd_denom
coef2 = self._denom // gcd_denom
com_denom = self._denom * coef1
num1 = self._num * coef1
num2 = number._num * coef2
steps += ["( {num1} * {coef1} ) / ( {den1} * {coef1} ) - ( {num2} * {coef2} ) / ( {den2} * {coef2} )".format(num1 = self._num, den1 = self._denom, coef1 = coef1, num2 = number._num, den2 = number._denom, coef2 = coef2)]
steps += ["( {num1} - {num2} ) / {denom}".format(num1 = num1, num2 = num2, denom = com_denom)]
com_denom = self._denom * coef1
num1 = self._num * coef1
num2 = number._num * coef2
num = num1 - num2
steps += ["( {num1} - {num2} ) / {denom}".format(num1 = num1, num2 = num2, denom = com_denom)]
ans_frac = Fraction(num, com_denom)
steps += ans_frac.simplify()
num = num1 - num2
return steps
def __mul__(self, other):
if type(other) == Fraction:
#cool
number = other
else:
number = Fraction(other)
ans_frac = Fraction(num, com_denom)
steps += ans_frac.simplify()
steps = ["( {frac1} ) * ( {frac2} )".format(frac1 = self, frac2 = number)]
steps += ["( {num1} * {num2} ) / ( {denom1} * {denom2} )".format(num1 = self._num, num2 = number._num, denom1 = self._denom, denom2 = number._denom)]
return steps
def __mul__(self, other):
if type(other) == Fraction:
#cool
number = other
else:
number = Fraction(other)
num = self._num * number._num
denom = self._denom * number._denom
steps = ["( {frac1} ) * ( {frac2} )".format(frac1 = self, frac2 = number)]
steps += ["( {num1} * {num2} ) / ( {denom1} * {denom2} )".format(num1 = self._num, num2 = number._num, denom1 = self._denom, denom2 = number._denom)]
ans_frac = Fraction(num, denom)
steps += ans_frac.simplify()
num = self._num * number._num
denom = self._denom * number._denom
return steps
ans_frac = Fraction(num, denom)
steps += ans_frac.simplify()
def __truediv__(self, other):
if type(other) == Fraction:
#cool
number = other
else:
number = Fraction(other)
return steps
steps = ["( {frac1} ) / ( {frac2} )".format(frac1 = self, frac2 = number)]
number = Fraction(number._denom, number._num)
steps += self * number
def __truediv__(self, other):
if type(other) == Fraction:
#cool
number = other
else:
number = Fraction(other)
return steps
steps = ["( {frac1} ) / ( {frac2} )".format(frac1 = self, frac2 = number)]
number = Fraction(number._denom, number._num)
steps += self * number
return steps
if __name__ == '__main__':
f = Fraction(34, 12)
g = Fraction(1,5)
h = Fraction(-1,5)
t = Fraction(-4,5)
print("---------")
for i in (f - 1):
print(i)
print("---------")
for i in (f + 1):
print(i)
print("---------")
for i in (f + g):
print(i)
print("---------")
for i in (f - g):
print(i)
print("---------")
for i in (f * g):
print(i)
print("---------")
for i in (h + t):
print(i)
print("---------")
for i in (h - t):
print(i)
print("---------")
for i in (h * t):
print(i)
print("---------")
for i in (h / t):
print(i)
f = Fraction(34, 12)
g = Fraction(1,5)
h = Fraction(-1,5)
t = Fraction(-4,5)
print("---------")
for i in (f - 1):
print(i)
print("---------")
for i in (f + 1):
print(i)
print("---------")
for i in (f + g):
print(i)
print("---------")
for i in (f - g):
print(i)
print("---------")
for i in (f * g):
print(i)
print("---------")
for i in (h + t):
print(i)
print("---------")
for i in (h - t):
print(i)
print("---------")
for i in (h * t):
print(i)
print("---------")
for i in (h / t):
print(i)
#print(f.simplify())
#print(f.simplify())
# -----------------------------
# Reglages pour 'vim'

74
generic.py
View File

@ -3,59 +3,59 @@
class Stack(object):
"""Docstring for Stack """
"""Docstring for Stack """
def __init__(self):
"""@todo: to be defined1 """
self.items = []
def __init__(self):
"""@todo: to be defined1 """
self.items = []
def pushFromList(self, list):
"""Push the list in the stack
def pushFromList(self, list):
"""Push the list in the stack
:param list: a list
"""
for i in list[::-1]:
self.push(i)
:param list: a list
"""
for i in list[::-1]:
self.push(i)
def isEmpty(self):
""" Says if the stack is empty
:returns: @todo
def isEmpty(self):
""" Says if the stack is empty
:returns: @todo
"""
return self.items == []
"""
return self.items == []
def push(self, item):
"""Push an item in the stack
def push(self, item):
"""Push an item in the stack
:param item: @todo
:returns: @todo
:param item: @todo
:returns: @todo
"""
self.items.append(item)
"""
self.items.append(item)
def pop(self):
"""Getting the last item and remove it
:returns: last item
def pop(self):
"""Getting the last item and remove it
:returns: last item
"""
return self.items.pop()
"""
return self.items.pop()
def peek(self, posi = 0):
"""Getting the last item
def peek(self, posi = 0):
"""Getting the last item
:param posi: which item to peek 0 (last) 1 (the onebefore the last)...
:returns: the item
:returns: the item
"""
return self.items[-1 - posi]
"""
return self.items[-1 - posi]
def __len__(self):
return len(self.items)
def __len__(self):
return len(self.items)
def __str__(self):
return str(self.items) + " -> "
def __str__(self):
return str(self.items) + " -> "
def __add__(self, addList):
return self.items + addList
def __add__(self, addList):
return self.items + addList
# -----------------------------
# Reglages pour 'vim'