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Mapytex/pymath/expression.py

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#!/usr/bin/env python
# encoding: utf-8
#debuging
#from debug.tools import report
from .generic import Stack, flatten_list, expand_list, isNumber, isOperator, isNumerand
from .str2tokens import str2tokens
from .operator import op
from .explicable import Explicable
from .random_expression import RdExpression
__all__ = ['Expression']
class Fake_int(int, Explicable):
isNumber = True
def __init__(self, val):
super(Fake_int, self).__init__(val)
self._val = val
self.postfix_tokens = [self]
self.steps = []
def simplify(self):
return Fake_int(self._val)
class Expression(Explicable):
"""A calculus expression. Today it can andle only expression with numbers later it will be able to manipulate unknown"""
@classmethod
def random(self, form="", conditions=[], val_min = -10, val_max=10):
"""Create a random expression from form and with conditions
:param form: the form of the expression (/!\ variables need to be in brackets {})
:param conditions: condition on variables (/!\ variables need to be in brackets {})
:param val_min: min value for generate variables
:param val_max: max value for generate variables
"""
random_generator = RdExpression(form, conditions)
return Expression(random_generator(val_min, val_max))
@classmethod
def tmp_render(cls, render = lambda _,x:Expression(x)):
""" Same ad tmp_render for Renderable but default render is Expression
>>> exp = Expression("2*3/5")
>>> print(exp)
2 \\times \\frac{ 3 }{ 5 }
>>> for i in exp.simplify().explain():
... print(i)
2 \\times \\frac{ 3 }{ 5 }
\\frac{ 3 }{ 5 } \\times 2
\\frac{ 3 \\times 2 }{ 5 }
\\frac{ 6 }{ 5 }
>>> with Expression.tmp_render():
... for i in exp.simplify().explain():
... i
< <class 'pymath.expression.Expression'> [2, 3, 5, '/', '*'] >
< <class 'pymath.expression.Expression'> [2, < Fraction 3 / 5>, '*'] >
< <class 'pymath.expression.Expression'> [3, 5, '/', 2, '*'] >
< <class 'pymath.expression.Expression'> [3, 2, '*', 5, '/'] >
< <class 'pymath.expression.Expression'> [6, 5, '/'] >
>>> from .render import txt
>>> with Expression.tmp_render(txt):
... for i in exp.simplify().explain():
... print(i)
2 * 3 / 5
3 / 5 * 2
( 3 * 2 ) / 5
6 / 5
>>> for i in exp.simplify().explain():
... print(i)
2 \\times \\frac{ 3 }{ 5 }
\\frac{ 3 }{ 5 } \\times 2
\\frac{ 3 \\times 2 }{ 5 }
\\frac{ 6 }{ 5 }
"""
return super(Expression, cls).tmp_render(render)
def __new__(cls, exp):
"""Create Expression objects
:param exp: the expression. It can be a string or a list of postfix tokens.
"""
expression = object.__new__(cls)
if type(exp) == str:
expression.postfix_tokens = str2tokens(exp)
elif type(exp) == list:
# Ici on ne peut convertir les "+" en opérateur que s'ils sont d'arité 2.
exp_mod_op = [op.get_op(i) if op.can_be_operator(i) else i for i in exp]
expression.postfix_tokens = flatten_list([tok.postfix_tokens if Expression.isExpression(tok) else tok for tok in exp_mod_op])
elif type(exp) == Expression:
return exp
elif isNumerand(exp):
expression.postfix_tokens = [exp]
else:
raise ValueError("Can't build Expression with {} object".format(type(exp)))
if len(expression.postfix_tokens) == 1:
token = expression.postfix_tokens[0]
if type(token) == Fake_int or type(token) == int:
return Fake_int(token)
elif hasattr(token, 'simplify') and hasattr(token, 'explain'):
ans = expression.postfix_tokens[0]
return ans
elif type(token) == str:
# TODO: Pourquoi ne pas créer directement un polynom ici? |jeu. févr. 26 18:59:24 CET 2015
# On crée un faux str en ajoutant la méthode simplify et simplified et la caractérisique isNumber
simplify = lambda x:[x]
is_polynom = True
methods_attr = {'simplify':simplify, '_isPolynom': is_polynom, 'postfix_tokens': [token]}
fake_token = type('fake_str', (str,Explicable, ), methods_attr)(token)
return fake_token
else:
raise ValueError("Unknow token type in Expression: {}".format(type(token)))
else:
expression._isExpression = 1
return expression
def __str__(self):
"""
Overload str
If you want to changer render use Expression.set_render(...) or use tmp_render context manager.
"""
return self.STR_RENDER(self.postfix_tokens)
def __repr__(self):
return " ".join(["<", str(self.__class__) , str(self.postfix_tokens), ">"])
def simplify(self):
""" Compute entirely the expression and return the result with .steps attribute """
self.compute_exp()
self.simplified = self.child.simplify()
self.simplified.steps = self.child.steps + self.simplified.steps
return self.simplified
def compute_exp(self):
""" Create self.child with and stock steps in it """
ini_step = Expression(self.postfix_tokens)
tokenList = self.postfix_tokens.copy()
tmpTokenList = []
while len(tokenList) > 2:
# on va chercher les motifs du genre A B +, quand l'operateur est d'arité 2, pour les calculer
if isNumerand(tokenList[0]) and isNumerand(tokenList[1]) \
and isOperator(tokenList[2]) and tokenList[2].arity == 2 :
# S'il y a une opération à faire
op1 = tokenList[0]
op2 = tokenList[1]
operator = tokenList[2]
res = operator(op1, op2)
tmpTokenList.append(res)
# Comme on vient de faire le calcul, on peut détruire aussi les deux prochains termes
del tokenList[0:3]
# Et les motifs du gens A -, quand l'operateur est d'arité 1
elif isNumerand(tokenList[0]) \
and isOperator(tokenList[1]) and tokenList[1].arity == 1:
# S'il y a une opération à faire
op1 = tokenList[0]
operator = tokenList[1]
res = operator(op1)
tmpTokenList.append(res)
# Comme on vient de faire le calcul, on peut détruire aussi les deux prochains termes
del tokenList[0:2]
else:
tmpTokenList.append(tokenList[0])
del tokenList[0]
if len(tokenList) == 2 and isNumerand(tokenList[0]) \
and isOperator(tokenList[1]) and tokenList[1].arity == 1:
# S'il reste deux éléments dont un operation d'arité 1
op1 = tokenList[0]
operator = tokenList[1]
res = operator(op1)
tmpTokenList.append(res)
# Comme on vient de faire le calcul, on peut détruire aussi les deux prochains termes
del tokenList[0:2]
tmpTokenList += tokenList
self.child = Expression(tmpTokenList)
steps = self.develop_steps(tmpTokenList)
if self.child.postfix_tokens == ini_step.postfix_tokens:
self.child.steps = steps
else:
self.child.steps = [ini_step] + steps
def develop_steps(self, tokenList):
""" From a list of tokens, it develops steps of each tokens """
# TODO: Attention les étapes sont dans le mauvais sens |lun. avril 20 10:06:03 CEST 2015
tmp_steps = []
with Expression.tmp_render():
for t in tokenList:
if hasattr(t, "explain"):
tmp_steps.append([i for i in t.explain()])
else:
tmp_steps.append([t])
if max([len(i) for i in tmp_steps]) == 1:
# Cas où rien n'a dû être expliqué.
return []
else:
tmp_steps = expand_list(tmp_steps)[:-1]
steps = [Expression(s) for s in tmp_steps]
return steps
@classmethod
def isExpression(self, other):
try:
other._isExpression
except AttributeError:
return 0
return 1
# -----------
# Expression act as container from self.postfix_tokens
def __getitem__(self, index):
return self.postfix_tokens[index]
def __setitem__(self, index, value):
self.postfix_tokens[index] = value
# -----------
# Some math manipulations
def operate(self, other, operator):
if type(other) == Expression:
return Expression(self.postfix_tokens + other.postfix_tokens + [operator])
elif type(other) == list:
return Expression(self.postfix_tokens + other + [operator])
else:
return Expression(self.postfix_tokens + [other] + [operator])
def roperate(self, other, operator):
if type(other) == Expression:
return Expression(other.postfix_tokens + self.postfix_tokens + [operator])
elif type(other) == list:
return Expression(other + self.postfix_tokens + [operator])
else:
return Expression([other] + self.postfix_tokens + [operator])
def __add__(self, other):
""" Overload +
>>> a = Expression("1+2")
>>> print(a.postfix_tokens)
[1, 2, '+']
>>> b = Expression("3+4")
>>> print(b.postfix_tokens)
[3, 4, '+']
>>> c = a + b
>>> print(c.postfix_tokens)
[1, 2, '+', 3, 4, '+', '+']
"""
return self.operate(other, op.add)
def __radd__(self, other):
return self.roperate(other, op.add)
def __sub__(self, other):
""" Overload -
>>> a = Expression("1+2")
>>> print(a.postfix_tokens)
[1, 2, '+']
>>> b = Expression("3+4")
>>> print(b.postfix_tokens)
[3, 4, '+']
>>> c = a - b
>>> print(c.postfix_tokens)
[1, 2, '+', 3, 4, '+', '-']
"""
return self.operate(other, op.sub)
def __rsub__(self, other):
return self.roperate(other, op.sub)
def __mul__(self, other):
""" Overload *
>>> a = Expression("1+2")
>>> print(a.postfix_tokens)
[1, 2, '+']
>>> b = Expression("3+4")
>>> print(b.postfix_tokens)
[3, 4, '+']
>>> c = a * b
>>> print(c.postfix_tokens)
[1, 2, '+', 3, 4, '+', '*']
"""
return self.operate(other, op.mul)
def __rmul__(self, other):
return self.roperate(other, op.mul)
def __truediv__(self, other):
""" Overload /
>>> a = Expression("1+2")
>>> print(a.postfix_tokens)
[1, 2, '+']
>>> b = Expression("3+4")
>>> print(b.postfix_tokens)
[3, 4, '+']
>>> c = a / b
>>> print(c.postfix_tokens)
[1, 2, '+', 3, 4, '+', '/']
>>>
"""
return self.operate(other, op.div)
def __rtruediv__(self, other):
return self.roperate(other, op.div)
def __pow__(self, other):
return self.operate(other, op.pw)
def __xor__(self, other):
return self.operate(other, op.pw)
def __neg__(self):
return Expression(self.postfix_tokens + [op.sub1])
def untest(exp):
a = Expression(exp)
b = a.simplify()
for i in b.explain():
#print(type(i))
print(i)
#print(type(a.simplified()), ":", a.simplified())
print("\n")
if __name__ == '__main__':
print('\n')
A = Expression("( -8 x + 8 ) ( -8 - ( -6 x ) )")
Ar = A.simplify()
for i in Ar.explain():
print(i)
#print("------------")
#for i in Ar.explain():
# print(i)
#print(type(Ar))
#print('\n-----------')
#A = Expression("-6 / 3 + 10 / -5")
#Ar = A.simplify()
#for i in Ar.explain():
# print(i)
#print('\n-----------')
#A = Expression("1/3 + 4/6")
#Ar = A.simplify()
#for i in Ar.explain():
# print(i)
#import doctest
#doctest.testmod()
# -----------------------------
# Reglages pour 'vim'
# vim:set autoindent expandtab tabstop=4 shiftwidth=4:
# cursor: 16 del
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