Ejemplo n.º 1
0
 def update_equalitiy_classes(self, element, another_element):
     m1, m2 = self.to_class[to_string(element)], self.to_class[to_string(another_element)], 
     if m1 != m2:
         m = min(m1, m2)
         M = max(m1, m2)
         for element in self.equality_classes[M]:
             self.to_class[to_string(element)] = m
         self.equality_classes[m] += self.equality_classes[M]
         self.equality_classes[M] = []
         self.equality_classes[m] = sorted(self.equality_classes[m], key = lambda x: (len(x), str(x)))
Ejemplo n.º 2
0
    def _simplify(self, element):      
        
        if to_string(element) in self.to_class.keys():
            self.visited.append(element)
            return self._getClass(element)[0]
        
        if len(element) <= self.nb_terms_in_simplest_form:
            self.visited.append(element)
            self.create_new_class(element)
            return element
           
        transformed_element = copy.copy(element)

        for i in range(len(transformed_element), -1, -1):        
            for j in range (0, len(transformed_element) - i):
                sequence = transformed_element[j : j + i + 1]
                if to_string(sequence) not in self.to_class.keys():
                    continue
        
                for replacement in self._getClass(sequence):                    
                
                    transformed_element = element[:j] + replacement + element[j + i + 1:]
                    if transformed_element in self.visited:
                        print transformed_element, " visited"
                        continue
                    else:
                        self.visited.append(transformed_element)
                        
                    simplified_transformed_element = self._simplify(transformed_element)
                    if simplified_transformed_element in self.visited:
                        continue
                    else:
                        self.visited.append(transformed_element)
                
                    if simplified_transformed_element in self.to_class.keys():
                        self.join_class(element, simplified_transformed_element)
                        return self._getClass(simplified_transformed_element)[0]
        
        if transformed_element != 
                        
        return element
    
    def simplify(self, element):
        """
            Find the simplest form of an element. For example, for the group of 1 generator x1 and 1 relation x1^5=0, x1^4 will return x1^-1
            This works with element in string form.
        """
        #if len(self.all_elements) > 0:
        #    return self._elementToElementString(self._strongSimplify(self.elementStringToElement(element)))
        self.visited = []
        return self._elementToElementString(self._simplify(self.elementStringToElement(element)))
    
    def _multiply(self, element1, element2):
        """
            Multiply to 2 elements of the group in list form. E.g, for the group of 1 generator x1 and 1 relation x1^5=0, multiplying [1,1,1] and [1,1] returns [].
            This works with elements in list form.
        """
        self.visited = []
        element1 = self._simplify(element1)
        self.visited = []
        element2 = self._simplify(element2)
        self.visited = []
        return self._simplify(element1 + element2)
    
    def multiply(self, element1, element2):
        """
            Multiply to 2 elements of the group in list form. E.g, for the group of 1 generator x1 and 1 relation x1^5=0, multiplying x1^3 and x1^2 returns e.
            This works with elements in string form.
        """
        element1 = self.simplify(element1)
        self.visited = []
        element2 = self.simplify(element2)
        self.visited = []
        return self.simplify(self.elementStringToElement(element1) + self.elementStringToElement(element2))
        
    def _power(self, element, exponent):
        """
            Return element to a power in group. For example, for the group of 1 generator x1 and 1 relation x1^5=0, _power(1,4) returns [3].
            This works with elements in list form.
        """
        if self.order > 0:
            exponent = exponent % self.order
        if exponent == 0:
            return []
        return self._simplify( self._multiply (self._power(element, exponent - 1), element ) )
    
    def power(self, element, exponent):
        """
            Return element to a power in group. For example, for the group of 1 generator x1 and 1 relation x1^5=0, power('x1',4) returns x1^-1.
            This works with elements in list form.
        """
        return self._elementToElementString(self._exponential(self.elementStringToElement(element), exponent))

    def _isNeutral(self, element):
        """
            Check if an element (in list form) is neutral.
        """
        self.visited = []
        return self._simplify(element) == []
    
    def isNeutral(self, element):
        """
            Check if an element (in string form) is neutral.
        """
        return self._isNeutral(self.elementStringToElement(element))
        
    def _inverse(self, element):
        """
            Return the inverse of an element (in list form).
        """
        return [self._index_of_inverse(i) for i in reversed(element)]      
        
    def _areEqual(self, element1, element2):
        """
            Return the inverse of an element (in string form).
        """
        return self._isNeutral(element1 + self._inverse(element2))
            
    def _order(self, element):
        """
            Return the order of an element (in list form) in the group
        """
        if self.order > 0:
            for i in range(1, self.order + 1):
                if self._isNeutral(self._power(element, i)):
                    return i
        return "Unknown" 

    def order(self, element):
        """
            Return the order of an element (in string form) in the group
        """
        return self._order(self.elementStringToElement(element))           
    
    def _shortenSequence(self, sequence):
        """
            Sequence is the list form of an element
        """
        ordered_generalized_relations = sorted(self.generalized_relations, key = lambda x: len(x))
        transformed_sequence = sequence
        for relation in ordered_generalized_relations:
            #relation is sth like [0,1,2,2]
            if len(sequence) > len(relation)/2  and position_of_list_in_list(sequence, relation) >= 0:
                transformed_sequence = self._shortenSequenceInSpecifiedRelation(sequence, relation)
                break
        return transformed_sequence
    
    def _shortenSequenceWithAlgo2(self, sequence):
        """
            Sequence is the list form of an element
        """
        ordered_generalized_relations = sorted(self.generalized_relations, key = lambda x: len(x))
        transformed_sequence = sequence
        for relation in ordered_generalized_relations:
            #relation is sth like [0,1,2,2]
            if 2 * len(sequence) >= len(relation) and position_of_list_in_list(sequence, relation) >= 0:
                transformed_sequence = self._shortenSequenceInSpecifiedRelation(sequence, relation)
                break
        return transformed_sequence


    def _shortenSequenceInSpecifiedRelation(self, sequence, relation):
        """
            Sequence is the list form of an element
        """
        position = position_of_list_in_list(sequence, relation)
        remaining = remaining_of_list_after_removing(sequence, relation, position)
        transformed_sequence = self._inverse(remaining[0]) + self._inverse(remaining[1])
        return transformed_sequence
    
    def elementStringToElement(self, element_string):
        for variable in self.retrieveVariablesFromElement(element_string):
            element_string = element_string.replace(variable, self.generators[variable])
        element_list = element_string.split(MULTIPLICATION_SIGN)
        element = []
        for term in element_list:
            #term is sth like x0^3, 1
            if term.find(NEUTRAL_ELEMENT) >= 0:
                pass
            elif EXPONENT_SIGN in term:
                base, exponent = int(term.split(EXPONENT_SIGN)[0].replace(VARIABLE, "")), int(term.split(EXPONENT_SIGN)[1])
                if exponent > 0:
                    element += [base] * exponent
                else:
                    element += [self._index_of_inverse(base)] * (-exponent)
            else:
                element.append(int(term.replace(VARIABLE, "")))
        return element
    
    def _relationToExpression(self, relation):
        expression = ""
        for pair in relation:
            expression += "%s%s%d%s" % (self.reversed_generators[VARIABLE + str(pair[0])], EXPONENT_SIGN, pair[1], MULTIPLICATION_SIGN)
        expression += END_OF_EQUATION
        expression = expression.replace(MULTIPLICATION_SIGN + END_OF_EQUATION, END_OF_EQUATION)
        return expression
    
    def _elementToElementString(self, element):
        element_string = ""
        pairs = []
        if len(element) > 0:
            if element[0] <= self.nb_generators:
                pairs.append([element[0], 1])
            else:
                pairs.append([self._index_of_inverse(element[0]), -1])
        for i in range(1, len(element)):
            if (element[i] == element[i-1] or element[i]==self._index_of_inverse(element[i-1])) and element[i] <= self.nb_generators:
                pairs[-1][1] += 1
            elif (element[i] == element[i-1] or element[i]==self._index_of_inverse(element[i-1])) and element[i] > self.nb_generators:
                pairs[-1][1] -= 1
            elif element[i] <= self.nb_generators:
                pairs.append([element[i], 1])
            elif element[i] > self.nb_generators:
                pairs.append([self._index_of_inverse(element[i]), -1])

        for pair in pairs:
            if pair[1] != 0:
                element_string += "%s%s%d%s" % ( self.reversed_generators[VARIABLE + str(pair[0])], EXPONENT_SIGN, pair[1], MULTIPLICATION_SIGN)
        if len(element_string) > 0 and element_string[-1] == MULTIPLICATION_SIGN:
            element_string = element_string[:-1]
        element_string = element_string.replace("%s1" % EXPONENT_SIGN, "")
        if element_string == "":
            element_string = NEUTRAL_ELEMENT
        return element_string

    def retrieveVariablesFromExpression(self, expression):
        regex = re.compile('[^a-zA-Z]')
        simplified_expression = regex.sub('', expression)
        variables = set(list(simplified_expression))
        index = len(self.generators)
        for character in sorted(list(variables)):
            if character != "e":
                if character not in self.generators.keys():
                    self.generators[character] = "x" + str(index)
                    expression = expression.replace(character, "$" + str(index))
                    index += 1
                else:
                    expression = expression.replace(character, self.generators[character].replace("x", "$"))
                    
        expression = expression.replace("$", "x")
        return expression
    
    def retrieveVariablesFromElement(self, element):
        regex = re.compile('[^a-zA-Z]')
        simplified_element = regex.sub('', element)
        variables = set(list(simplified_element))
        return sorted(list(variables))
    
    def _listElementsOfLength(self, length):
        all_classes = []
        if length==0:
            all_classes.append([])
            return all_classes
        for element in self._listElementsOfLength(length-1):
            for index in range (1, 2*self.nb_generators + 1):
                new_element = element + [index]
                if self.commutative:
                    new_element = self._sortElementInCommutativeGroup(new_element)
                    if len(new_element) == length and new_element not in all_classes:
                        all_classes.append(self._sortElementInCommutativeGroup(new_element))
                elif len(self._simplify(new_element)) == length and new_element not in all_classes:
                    all_classes.append(new_element)
        return all_classes
    
    def _listAllElements(self):
        all_classes = []
        for length in range(self.nb_terms_in_simplest_form + 1):
            all_classes += self._listElementsOfLength(length)
        
        distinct_classes = []
        for some_class in all_classes:
            is_new = True
            for another_class in distinct_classes:
                try:
                    if self._areEqual(some_class, another_class):
                        is_new = False
                        break
                except:
                    print "Unable to multiply"
                    pass
            if is_new:
                distinct_classes.append(some_class)
        
        return distinct_classes

    def _checkCommutative(self):
        if self.commutative:
            return True
        for generator in range(1, self.nb_generators + 1):
            for another_generator in range(1, self.nb_generators + 1):
                if not self._areEqual([generator, another_generator], [another_generator, generator]):
                    return False
        return True
    
    def _sortElementInCommutativeGroup(self, element):
        if not self.commutative:
            return element
        preres = [0] * (self.nb_generators + 1)
        for term in element:
            #term is sth like 1 or 2 or 3
            if term <= self.nb_generators:
                preres[term] += 1
            else:
                preres[self._index_of_inverse(term)] -= 1
        res = []
        for generator in range(1, self.nb_generators + 1):
            if preres[generator] > 0:
                res += [generator] * preres[generator]
            elif preres[generator] < 0:
                res += [self._index_of_inverse(generator)] * (-preres[generator])
        return res
    
    def _createMultiplicationTable(self):
        multi_tab = []
        for idx1 in range(self.order):
            row = []
            for idx2 in range(self.order):
                if self.commutative:
                    row += [self._simplify(self._sortElementInCommutativeGroup(self._multiply(self.all_elements[idx1], self.all_elements[idx2])))]
                else:
                    row += [self._simplify(self._multiply(self.all_elements[idx1], self.all_elements[idx2]))]
            multi_tab += [row]
        return multi_tab
    
    def createMultiplicationTable(self):
        multi_tab = self._createMultiplicationTable()
        multi_string_tab = [[self._elementToElementString(element) for element in row] for row in multi_tab]
        return multi_string_tab
Ejemplo n.º 3
0
 def _getClass(self, element):
     return self.equality_classes[self.to_class[to_string(element)]]
Ejemplo n.º 4
0
 def join_class(self, element, another_element):
     self.to_class[to_string(element)] = self.to_class[to_string(another_element)]
     self.equality_classes[self.to_class[to_string(another_element)]].append(element)
     self.equality_classes[self.to_class[to_string(another_element)]] = sorted(self.equality_classes[self.to_class[to_string(another_element)]], key = lambda x: (len(x), str(x)))
Ejemplo n.º 5
0
 def create_new_class(self, element):
      self.to_class[to_string(element)] = len(self.equality_classes)
      self.equality_classes.append([element])       
Ejemplo n.º 6
0
    def _generalizeRelations(self):
        for i in range(1, self.nb_generators + 1):
            # Firstly, find all relations of the form x * inverse(x) = e
            self.generalized_relations.append([i, self._index_of_inverse(i)])
            self.generalized_relations.append([self._index_of_inverse(i), i]) 
        
        #Now, generate all relations that is a permutation of relations in self.relations, for example [1,2,3] will be [1,2,3], [2,3,1] and [3,1,2]
        #We call them relation of type 1
        
        relations_type_1 = []
        for relation in self.relations:
            # Here relation is sth like ([(1,1), (2,-1), (3,1)])                       
            reformulated_relation = []
            for term in relation:
                #term is sth like (1,1)
                base, exponent = term[0], term[1]
                if exponent > 0:
                    reformulated_relation += [base] * exponent
                else:
                    reformulated_relation += [self._index_of_inverse(base)] * (-exponent)
                #After this step, our example become [1,5,3]
            
            n = len(reformulated_relation)
            for permutator in range(n):
                permutated_relation = [reformulated_relation[(permutator + i) % n] for i in range(n)]
                if permutated_relation not in relations_type_1:
                    relations_type_1.append(permutated_relation)
            #After this step, relations_type_1 contains [1,5,3], [5,3,1], [3,1,5]
            
            #We also express the inverse form of the relation. E.g, [1,5,3] becomes [6,2,4]
            #Do the same, we get more elements of relations_type_1: [6,2,4], [2,4,6], [4,6,2]
            reformulated_relation = []
            for term in reversed(relation):
                #term is sth like (0,1)
                base, exponent = term[0], term[1]
                if exponent > 0:
                    reformulated_relation += [self._index_of_inverse(base)] * exponent
                else:
                    reformulated_relation += [base] * (-exponent)
            
            n = len(reformulated_relation)
            for permutator in range(n):
                permutated_relation = [reformulated_relation[(permutator + i) % n] for i in range(n)]
                if permutated_relation not in relations_type_1:
                    relations_type_1.append(permutated_relation)          
        
        #We want to define relations of type 2, which is formed by mean of: find another form of some sequence form a relation, then replace it in another relation
        #For example, if x1*x1=e, we have [1,1]=[] or equivalently, [1]=[4], hence in [1,5,3], we can substitute [1] in this relation and it becomes [4,5,3]
        
        relations_type_2 = relations_type_1
        
        relations_type_1 = sorted(relations_type_1, key = lambda x: len(x))
        
        for relation in relations_type_1:
            #print "-----Current relation-------", relation
            relation_sublists = sublists(relation)
            for sequence in relation_sublists:
                #print "---Current sequence---", sequence
                for other_relation in relations_type_1:
                    #print "Working with", other_relation
                    positions = all_discrete_positions_of_list_in_list(sequence, other_relation)
                    #print "Positions", positions
                    if len(positions) > 1:
                        for subset in all_subsets(positions):
                            if len(subset) > 0:
                                #print "Subset", subset
                                for position in subset:
                                    new_relation = other_relation[:position] + self._shortenSequenceInSpecifiedRelation(sequence, relation) + other_relation[position + len(sequence):]
                                    #print "Use %s in position %d in %s, %s becomes %s"% (sequence, position, relation, other_relation, new_relation)
                                    #print "New relation", new_relation                        
                                    if new_relation not in relations_type_2 and new_relation not in self.generalized_relations:
                                        relations_type_2.append(new_relation)
       
        self.generalized_relations += relations_type_2   

        relations_type_3 = []
        for relation in self.relations:
            if len(relation) == 1 and relation[0][1] == 2:
                x = relation[0][0]
                y = self._index_of_inverse(x)
                for another_relation in self.generalized_relations:
                    new_another_relation = copy.copy(another_relation)
                    for idx in range(len(another_relation)):
                        if another_relation[idx] == x:
                            new_another_relation[idx] = y
                        if another_relation[idx] == y:
                            new_another_relation[idx] = x
                    if new_another_relation not in self.generalized_relations and new_another_relation not in relations_type_3:
                        relations_type_3.append(new_another_relation)
        self.generalized_relations += relations_type_3        
        
        self.to_class[to_string([])] = 0
        self.equality_classes.append([])
        self.equality_classes[0].append([])
    
        for reformulated_relation in self.generalized_relations:      
            for i in range(len(reformulated_relation), -1, -1):
                for j in range (0, len(reformulated_relation) - i):                
                    sequence = reformulated_relation[j : j + i + 1]
                    
                    remaining = remaining_of_list_after_removing(sequence, reformulated_relation, j)
                    transformed_sequence = self._inverse(remaining[0]) + self._inverse(remaining[1])
                    if to_string(sequence) not in self.to_class.keys():
                        if to_string(transformed_sequence) not in self.to_class.keys():
                            self.create_new_class(transformed_sequence)
                        if sequence != transformed_sequence:
                            self.join_class(sequence, transformed_sequence)
                    else:
                        if to_string(transformed_sequence) not in self.to_class.keys():
                            self.join_class(transformed_sequence, sequence)
                        else:
                            self.update_equalitiy_classes(transformed_sequence, sequence)
        
        print self.equality_classes