Exemplo n.º 1
0
 def choose_flee_action(self, game_state):
   #
   q = Queue()
   q.push((game_state, []))
   visited = []
   i = 0
   while not q.is_empty():
     i = i+1
     state, route = q.pop()
     if self.nearest_ghost_distance(state) <= 1 and state != game_state:
       continue
     elif state.get_agent_position(self.index) in visited:
       continue
     elif self.in_home_territory(state,state.get_agent_position(self.index),0):
       if len(route) == 0:
         return Directions.STOP
       else:
         return route[0]
     visited = visited + [state.get_agent_position(self.index)]
     actions = state.get_legal_actions(self.index)
     rev = Directions.REVERSE[state.get_agent_state(self.index).configuration.direction]
     if rev in actions and len(actions) > 1 and i!=1:
       actions.remove(rev)
     for action in actions:
       q.push((self.get_successor(state,action),route+[action]))
   return random.choice(game_state.get_legal_actions(self.index))
Exemplo n.º 2
0
 def get_all_clourse(self):
     queue = Queue()
     all_clourse = self.all_clourse
     queue.enqueue(
         self.get_clourse([
             Item(self.expression[0].leftside, self.expression[0].rightside,
                  0, "#")
         ]))
     i = 0
     while not queue.is_empty():
         current = queue.dequeue()
         all_clourse.append(current)
         current_index = len(all_clourse) - 1
         self.map_of_clourses[current_index] = {}
         for x in sorted(list(self.terminators | self.variable)):
             next = self.Go(current, x)
             if next != set(
             ) and next not in self.all_clourse and not queue.In(
                     next):  #next不为空,并且不在队列中,也不在all_clourse中
                 queue.enqueue(next)
                 i += 1
             if next in self.all_clourse:
                 self.map_of_clourses[current_index][
                     x] = self.all_clourse.index(next)
             elif queue.In(next):
                 self.map_of_clourses[current_index][x] = len(
                     self.all_clourse) + queue.index(next)
Exemplo n.º 3
0
 def bfs(self, starting_vertex, destination_vertex):
     """
     Return a list containing the shortest path from
     starting_vertex to destination_vertex in
     breath-first order.
     """
     # create an empty queue and enqueue a list containing the starting vertex
     queue = Queue()
     queue.enqueue([starting_vertex])
     # create a set to store the visited vertices
     visited = set()
     # while the queue is not empty
     while not queue.is_empty():
         # dequeue to the path
         path = queue.dequeue()
         # set a vertex to the last item in the path
         vertex = path[-1]
         # if that vertex has not been visited
         if vertex not in visited:
             # if vertex is equal to destination value
             if vertex == destination_vertex:
                 # return path
                 return path
             # mark vertex as visited
             visited.add(vertex)
             # loop over next vertex in the set of vertices for the current vertex
             for next_vertex in self.vertices[vertex]:
                 # set a new path equal to a new list of the path
                 new_path = list(path)
                 # append next vertex to new path
                 new_path.append(next_vertex)
                 # enqueue the new path
                 queue.enqueue(new_path)
     # return None if it breaks out of the while loop
     return None
Exemplo n.º 4
0
def earliest_ancestor(ancestors, starting_node):
    '''
    Build the graph
    '''
    # instantiate a new graph object
    graph = Graph()
    # loop over all pairs in ancestors
    for pair in ancestors:
        # add pair[0] and pair[1] to the graph
        graph.add_vertex(pair[0])
        graph.add_vertex(pair[1])
        # build the edges in reverse
        graph.add_edge(pair[1], pair[0])
    '''
    BFS with paths to find the earliest known ancestor
    '''
    # create a queue
    queue = Queue()
    # enqueue starting node inside a list
    queue.enqueue([starting_node])
    # set a max path length to 1
    max_path_length = 1
    # set initial earliest ancestor
    earliest_ancestor = -1
    # while the queue is not empty
    while not queue.is_empty():
        # dequeue to the path
        path = queue.dequeue()
        # set a vertex to the last item in the path
        vertex = path[-1]
        # if path is longer or equal and the value is smaller, or if the path is longer
        if (len(path) >= max_path_length and
                vertex < earliest_ancestor) or (len(path) > max_path_length):
            # set the earliest ancestor to the vertex
            earliest_ancestor = vertex
            # set the max path length to the len of the path
            max_path_length = len(path)
        # loop over next vertex in the set of vertices for the current vertex
        for next_vertex in graph.vertices[vertex]:
            # set a new path equal to a new list of the path
            path_copy = list(path)
            # append next vertex to new path
            path_copy.append(next_vertex)
            # enqueue the new path
            queue.enqueue(path_copy)
    # return earliest ancestor
    return earliest_ancestor
Exemplo n.º 5
0
 def show_symbol_table(self):
     table = self.init_table
     q = Queue()
     q.enqueue(table)
     i = 0
     while not q.is_empty():
         table = q.dequeue()
         print("符号表" + str(i), table.offset, table.father_table)
         i += 1
         for item in table.table:
             if item.type == "fuction" or item.type == "record":
                 q.enqueue(item.redundant_point)
             if item.type == "array":
                 item.show_item("\t")
                 item.redundant_point.show_vector()
             else:
                 item.show_item()
Exemplo n.º 6
0
 def bft(self, starting_vertex):
     """
     Print each vertex in breadth-first order
     beginning from starting_vertex.
     """
     # create an empty queue and enqueue the starting vertex
     queue = Queue()
     queue.enqueue(starting_vertex)
     # create a set to store the visited vertices
     visited = set()
     # while the queue is not empty
     while not queue.is_empty():
         # Dequeue the first vertex
         v = queue.dequeue()
         # if that vertex has not been visited
         if v not in visited:
             # mark it as visited and print for traversal visualization
             visited.add(v)
             print(v)
             # then enqueue all of its direct neighbour(s)
             for next_vertex in self.vertices[v]:
                 queue.enqueue(next_vertex)
Exemplo n.º 7
0
class semantic_action():
    def __init__(self,attribute_stack,init_table):
        self.offset_stack = Stack()
        self.table_stack = Stack()
        self.offset_stack.push(0)
        self.table_stack.push(init_table)
        self.attribute_stack = attribute_stack
        self.temp_count = 0
        self.code_list = []
        self.next_quad = 0
        self.param_queue = Queue()
        self.legal_type = {"float":3,"int":2,"char":1}
        self.action_array = [self.semantic_action_0,self.semantic_action_1,self.semantic_action_2,self.semantic_action_3,self.semantic_action_4,self.semantic_action_5
        ,self.semantic_action_6,self.semantic_action_7,self.semantic_action_8,self.semantic_action_9,self.semantic_action_10
        ,self.semantic_action_11,self.semantic_action_12,self.semantic_action_13,self.semantic_action_14,self.semantic_action_15,
        self.semantic_action_16,self.semantic_action_17,self.semantic_action_18,self.semantic_action_19,self.semantic_action_20,
        self.semantic_action_21,self.semantic_action_22,self.semantic_action_23,self.semantic_action_24,self.semantic_action_25,
        self.semantic_action_26,self.semantic_action_27,self.semantic_action_28,self.semantic_action_29,self.semantic_action_30,
        self.semantic_action_31,self.semantic_action_32,self.semantic_action_33,self.semantic_action_34,self.semantic_action_35,
        self.semantic_action_36,self.semantic_action_37,self.semantic_action_38,self.semantic_action_39,self.semantic_action_40,
        self.semantic_action_41,self.semantic_action_42,self.semantic_action_43,self.semantic_action_44,self.semantic_action_45,
        self.semantic_action_46,self.semantic_action_47,self.semantic_action_48,self.semantic_action_49,self.semantic_action_50,
        self.semantic_action_51,self.semantic_action_52,self.semantic_action_53,self.semantic_action_54,self.semantic_action_55,
        self.semantic_action_56,self.semantic_action_57,self.semantic_action_58,self.semantic_action_59,self.semantic_action_60,
        self.semantic_action_61,self.semantic_action_62,self.semantic_action_63,self.semantic_action_64,self.semantic_action_65,
        self.semantic_action_66,self.semantic_action_67,self.semantic_action_68]
    def do_action(self,index):
        a = self.action_array[index]()
        #print(self.table_stack.array)
        #print("do semantic analysis "+str(index))
        return a
    def new_temp(self):
        result = "$"+str(self.temp_count)
        self.temp_count += 1
        return result
    def gencode(self,op,first,second,result):
        self.code_list.append(code(op,first,second,result))
        self.next_quad += 1
    #{addwidth(top(tblptr),top(offset));
    #在外层过程符号表中加入当前过程
    #pop(tblptr);pop(offset)}
    #D::=def X id M1 ( Param ) { W' Z }
    def semantic_action_5(self):
        Param = self.attribute_stack.get_top(6)
        offset = self.offset_stack.get_top()
        t = self.table_stack.get_top()
        t.set_offset(offset)
        name = self.attribute_stack.get_top(9)["addr"]
        X = self.attribute_stack.get_top(10)
        Z = self.attribute_stack.get_top(2)
        if t.duplicate_check(name):#重复定义,程序报错
            raise MyException(name+"重复定义")
        if X["type"] != Z["type"]:
            raise MyException("返回类型不匹配")
        t.return_type = X["type"]
        if t.father_table.duplicate_check(name):
            raise MyException("函数重复定义")
        t.father_table.add(symbol_item(name,"fuction",None,t))
        t.param_num = Param["param_num"]
        self.table_stack.pop(1)
        self.offset_stack.pop(1)
        return {}
    #Z::=return E ;
    #{if 需要返回结果 then gencode(‘:=’, E.addr, -, F);
    #gencode(‘ret’, -, -, -)}
    def semantic_action_6(self):
        Z_attribute = {}
        E = self.attribute_stack.get_top(2)
        Z_attribute["type"] = E["type"]
        self.gencode("=",E["addr"],None,"F")
        self.gencode("ret",None,None,None)
        return Z_attribute
    #M1::=ε
    def semantic_action_7(self):
        t = symbol_table(self.table_stack.get_top())
        self.table_stack.push(t)
        self.offset_stack.push(0)
        return {}
    #S::=T id ;
    def semantic_action_10(self):
        t = self.table_stack.get_top()
        id_name = self.attribute_stack.get_top(2)["addr"]
        T_type = self.attribute_stack.get_top(3)["type"]
        T_width = self.attribute_stack.get_top(3)["width"]
        offset = self.offset_stack.get_top()

        if t.duplicate_check(id_name):
            raise MyException(id_name+"重复定义")
        else:
            if "array_dope_vector" in self.attribute_stack.get_top(3):#数组或者正常变量
                redundant_point = self.attribute_stack.get_top(3)["array_dope_vector"]
                if redundant_point != None:
                    redundant_point.address = offset
            else:#结构体
                redundant_point = self.attribute_stack.get_top(3)["table"]
            t.add(symbol_item(id_name,T_type,offset,redundant_point))
        self.offset_stack.pop(1)
        self.offset_stack.push(offset+T_width)
        return {}
    #Param::=T id
    def semantic_action_11(self):
        Param_attribute = {}
        t = self.table_stack.get_top()
        id_name = self.attribute_stack.get_top(1)["addr"]
        T_type = self.attribute_stack.get_top(2)["type"]
        T_width = self.attribute_stack.get_top(2)["width"]
        offset = self.offset_stack.get_top()
        if t.duplicate_check(id_name):#重复定义了
            raise MyException(id_name+"重复定义")
        else:#没有重复定义
            if "array_dope_vector" in self.attribute_stack.get_top(2):#数组或者正常变量
                redundant_point = self.attribute_stack.get_top(2)["array_dope_vector"]
                if redundant_point != None:
                    redundant_point.address = offset
            else:#结构体
                redundant_point = self.attribute_stack.get_top(2)["table"]
            t.add(symbol_item(id_name,T_type,offset,redundant_point))
        self.offset_stack.pop(1)
        self.offset_stack.push(offset+T_width)
        Param_attribute["param_num"] = 1
        return Param_attribute
    #Param::=Param , T id
    def semantic_action_12(self):
        Param_attribute = {}
        Param = self.attribute_stack.get_top(4)
        t = self.table_stack.get_top()
        id_name = self.attribute_stack.get_top(1)["addr"]
        T_type = self.attribute_stack.get_top(2)["type"]
        T_width = self.attribute_stack.get_top(2)["width"]
        offset = self.offset_stack.get_top()
        if t.duplicate_check(id_name):
            raise MyException(id_name+"重复定义")
        else:
            if "array_dope_vector" in self.attribute_stack.get_top(2):#数组或者正常变量
                redundant_point = self.attribute_stack.get_top(2)["array_dope_vector"]
                if redundant_point != None:
                    redundant_point.address = offset
            else:#结构体
                redundant_point = self.attribute_stack.get_top(2)["table"]
            t.add(symbol_item(id_name,T_type,offset,redundant_point))
        self.offset_stack.pop(1)
        self.offset_stack.push(offset+T_width)
        Param_attribute["param_num"] = Param["param_num"]+1
        return Param_attribute
    #{T.type := integer; T.width := 4}
    #X::=int
    def semantic_action_16(self):
        X_attribute = {"type":"int","width":4}
        return X_attribute
    #X::=float
    #{T.type :=real; T.width :=8}
    def semantic_action_17(self):
        X_attribute = {"type":"float","width":8}
        return X_attribute
    #X::=boolean
    def semantic_action_18(self):
        X_attribute = {"type":"boolean","width":1}
        return X_attribute
    #X::=char
    def semantic_action_19(self):
        X_attribute = {"type":"char","width":1}
        return X_attribute
    #C::=ε
    def semantic_action_21(self):
        C_attribute = {"array_dope_vector":None}
        return C_attribute
    #C::=C [ CI ]
    def semantic_action_20(self):
        right_C_attribute = self.attribute_stack.get_top(4)
        left_C_attribute = {}
        limit = self.attribute_stack.get_top(2)["value"]
        if right_C_attribute["array_dope_vector"] == None:
            left_C_attribute["array_dope_vector"] = array_dope_vector(1,(limit,),None,None)
        else:
            pre_vector = right_C_attribute["array_dope_vector"]
            left_C_attribute["array_dope_vector"] = array_dope_vector(pre_vector.dimension+1,pre_vector.limits+(limit,),None,None)
        return left_C_attribute
    #T::=X C 生成类型
    #{T.type := array(num.val, T1.type);T.width := num.val×X.width}数组
    #{T.type := X.type ;T.width := X.width}正常变量
    #给符号表准备类型和redunant_point的信息
    def semantic_action_13(self):
        T_attribute = {}
        vector = self.attribute_stack.get_top(1)["array_dope_vector"]
        X_attribute = self.attribute_stack.get_top(2)
        #正常变量
        if vector == None:
            T_attribute["type"] = X_attribute["type"]
            T_attribute["width"] = X_attribute["width"]
            T_attribute["array_dope_vector"] = None
        else:#数组
            T_attribute["type"] = "array"
            total = vector.limits[0]
            for i in range(1,vector.dimension):
                total *= vector.limits[i]
            vector.type = X_attribute["type"]
            T_attribute["width"] = total * X_attribute["width"]
            T_attribute["array_dope_vector"] = vector
        return T_attribute
    #T → record M2 D end {T.type := record(top(tblptr));
    #T.width := top(offset);
    #pop(tblptr); pop(offset)}
    #T::=struct { M2 Param } 
    def semantic_action_14(self):
        T_attribute = {}
        T_attribute["type"] = "struct"
        T_attribute["width"] = self.offset_stack.get_top(1)
        T_attribute["table"] = self.table_stack.get_top(1)
        self.table_stack.get_top(1).set_offset(self.offset_stack.get_top(1))
        self.offset_stack.pop(1)
        self.table_stack.pop(1)
        return T_attribute

    #M2::=ε{t:= mktable(previous); push(t, tblptr); push(0, offset)}
    def semantic_action_15(self):
        t = symbol_table(self.table_stack.get_top(1))
        self.table_stack.push(t)
        self.offset_stack.push(0)
        return {}
    #{if Left.offset=null then  /*Left是简单变量id*/
    #gencode(Left.addr ':=' E.addr);
    #else
    #gencode(Left.addr '[' Left.offset '] ' ':=' E.addr)} /*Left是数组元素*/
    #S::=Left = E ;
    def semantic_action_24(self):
        left_offset = self.attribute_stack.get_top(4)["offset"]
        left_addr = self.attribute_stack.get_top(4)["addr"]
        E_addr = self.attribute_stack.get_top(2)["addr"]
        Left = self.attribute_stack.get_top(4)
        E = self.attribute_stack.get_top(2)
        if self.attribute_stack.get_top(4)["type"]=="struct":
            raise MyException("赋值语句类型错误")
        if not (Left["type"]=="boolean" and E["type"]=="boolean" or 
                Left["type"] in self.legal_type and E["type"] in self.legal_type):
                raise MyException("赋值类型不匹配")
        #类型转换
        left_type_prioity = self.legal_type[Left["type"]]
        E_type_prioity = self.legal_type[E["type"]]
        #如果Left的类型比E宽
        if left_type_prioity>E_type_prioity:
            temp = self.widen(E["addr"],E["type"],Left["type"])
            E["addr"] = temp
        elif left_type_prioity<E_type_prioity:
            raise MyException("赋值语句不能向宽类型转换")
        if left_offset == None:
            self.gencode("=",str(E_addr),None,str(left_addr))
        else:
            self.gencode("=",str(E_addr),None,str(left_addr)+"["+str(left_offset)+"]")
        return {}
    #S::=Left = B ;
    def semantic_action_25(self):
        left = self.attribute_stack.get_top(4)
        B = self.attribute_stack.get_top(2)
        if left["type"]!="boolean":
            raise MyException("赋值语句类型错误")
        if left["offset"] == None:
            result = str(left["addr"])
        else:
            result= str(left["addr"])+"["+str(left["offset"])+"]"
        self.back_patch(B["truelist"],self.next_quad)
        self.back_patch(B["falselist"],self.next_quad+2)
        self.gencode("=","true",None,result)
        self.gencode("goto",None,None,self.next_quad+2)
        self.gencode("=","false",None,result)
        return {}
    #Left::=id
    #{Left.addr:=id.addr; Left.offset:=null}
    #id只能是结构体类型或者一般数据类型,其他的报错。如果正确向上传递类型信息,如果是结构体,那么要传递符号表信息
    def semantic_action_26(self):
        left_attribute = {}
        t = self.table_stack.get_top(1)
        id_addr = self.attribute_stack.get_top(1)["addr"]
        item = t.search(id_addr)
        if item==None:
            raise MyException(id_addr+"未定义") 
        if item.type=="fuction" or item.type == "array":
            raise MyException(id_addr+"类型不匹配")
        left_attribute["type"] = item.type
        left_attribute["addr"] = id_addr
        left_attribute["offset"] = None
        left_attribute["table"] = item.redundant_point
        return left_attribute
    def width(self,array_type):
        if array_type == "int":
            return "4"
        elif array_type == "float":
            return "8"
        elif array_type == "char" or array_type == "boolean":
            return "1"
    #Left::=L
    #{ Left.addr:=newtemp;        /*Left是数组元素,因此存放基址和位移*/
    #Left.offset:=newtemp;
    #gencode(Left.addr ':=' c(L.array));
    #gencode(Left.offset ':=' L.addr '*' width(L.array))}
    #L的类型必须是基本类型,而不是array
    def semantic_action_27(self):
        left_attribute = {}
        left_attribute["addr"] = self.new_temp()
        left_attribute["offset"] = self.new_temp()
        l_array = self.attribute_stack.get_top(1)["array"]
        l_addr = self.attribute_stack.get_top(1)["addr"]
        L = self.attribute_stack.get_top(1)
        if L["type"]=="array":
            raise MyException("数组索引过少")
        left_attribute["type"] = L["type"]
        self.gencode("=",str(l_array.address),None,left_attribute["addr"])
        self.gencode("*",l_addr,self.width(l_array.type),left_attribute["offset"])
        return left_attribute
    #Left::=Left1 . id
    #最终推到出的形式为struct.struct.struct.id或者struct.struct.struct.L
    #右部 left 有 addr 和 offset addr存的是结构体的复合名字 offset存的是数组的偏移量
    #Left.addr:=id.name+Left1.addr        /*Left是数组元素,因此存放基址和位移*/
    #Left.offset:=Left1.addr
    #Left的类型只能是结构体,其他的报错。id的类型是结构体或者是一般类型否则报错,但是id不可能为函数,因为定义语句不允许
    # ,如果是结构体要传递符号表信息
    def semantic_action_28(self):
        left_attribute = {}
        id_name = self.attribute_stack.get_top(1)["addr"]
        Left1 = self.attribute_stack.get_top(3)
        t = Left1["table"]
        item = t.search(id_name)
        if item == None:
            raise MyException(id_name+"未定义")
        if Left1["type"] != "struct":
            raise MyException("不能对非结构体进行.操作")
        if item.type == "struct":
            left_attribute["table"] = item.redundant_point
        left_attribute["type"] = item.type
        left_attribute["addr"] = id_name +"."+self.attribute_stack.get_top(3)["addr"]
        left_attribute["offset"] = self.attribute_stack.get_top(3)["offset"]
        return left_attribute
    #L::=id [ E ]
    #{L.array:=id.addr; L.addr:= E.addr; L.ndim:=1}
    #array用来存内情向量表
    #数组id的addr为内情向量
    def semantic_action_29(self):
        L_attribute = {}
        t = self.table_stack.get_top(1)
        id_name = self.attribute_stack.get_top(4)["addr"]
        item = t.search(id_name)
        E = self.attribute_stack.get_top(2)
        if item == None:
            raise MyException(id_name+"未定义")
        if item.type != "array":
            raise MyException(id_name+"非数组变量不能有索引") 
        if E["type"] != "int":
            raise MyException("数组索引只能用整数")
        L_attribute["array"] = self.table_stack.get_top(1).search(id_name).redundant_point
        L_attribute["addr"] = self.attribute_stack.get_top(2)["addr"]
        L_attribute["ndim"] = 0
        if len(L_attribute["array"].limits) == 1:
            L_attribute["type"] = L_attribute["array"].type
        else:
            L_attribute["type"] = "array"
        return L_attribute
    #{t:=newtemp;
    # m:= L1.ndim+1;
    #gencode(t ':=' L1.addr '*' limit(L1.array, m)); /*计算em-1×nm */
    #gencode(t ':=' t '+' E.addr);                    /* 计算+ im  */
    #L.array:= L1.array;
    #L.addr:=t;
    #L.ndim:=m}
    #L::=L1 [ E ]
    def semantic_action_30(self):
        L_attribute = {}
        t = self.new_temp()
        m = self.attribute_stack.get_top(4)["ndim"]+1
        L1 = self.attribute_stack.get_top(4)
        E = self.attribute_stack.get_top(2)
        if L1["type"]!="array":
                raise MyException("数组索引过多")
        self.gencode("*",L1["addr"],L1["array"].limits[m],t)
        self.gencode("+",t,E["addr"],t)
        L_attribute["array"] = L1["array"]
        L_attribute["addr"] = t
        L_attribute["ndim"] = m
        if m==len(L1["array"].limits)-1:
            L_attribute["type"] = L1["array"].type
        else:
            L_attribute["type"] = "array"
        return L_attribute
    #E::=E1 + Y
    #{E.addr:=newtemp;gencode(E.addr ':='E1.addr'+'Y.addr)}
    def semantic_action_31(self):
        E_attribute = {}
        E_attribute["addr"] = self.new_temp()
        E1 = self.attribute_stack.get_top(3)
        Y = self.attribute_stack.get_top(1)
        if Y["type"] not in self.legal_type:
            raise MyException("算数类型不对")
        if E1["type"] not in self.legal_type:
            raise MyException("算数类型不对")
        E_attribute["type"] = self.max_type(E1["type"],Y["type"])
        a1 = self.widen(E1["addr"],E1["type"],E_attribute["type"])
        a2 = self.widen(Y["addr"],Y["type"],E_attribute["type"])
        self.gencode("+",a1,a2,E_attribute["addr"])
        return E_attribute
    #E::=E1 - Y
    #{E.addr:=newtemp;gencode(E.addr ':='E1.addr'-'Y.addr)}
    def semantic_action_32(self):
        E_attribute = {}
        E_attribute["addr"] = self.new_temp()
        E1 = self.attribute_stack.get_top(3)
        Y = self.attribute_stack.get_top(1)
        if E1["type"] not in self.legal_type:
            raise MyException("算数类型不对")
        if Y["type"] not in self.legal_type:
            raise MyException("算数类型不对")
        E_attribute["type"] = self.max_type(E1["type"],Y["type"])
        a1 = self.widen(E1["addr"],E1["type"],E_attribute["type"])
        a2 = self.widen(Y["addr"],Y["type"],E_attribute["type"])
        self.gencode("-",a1,a2,E_attribute["addr"])
        return E_attribute
    #E::=Y
    #{E.addr:=Y.addr}
    def semantic_action_33(self):
        E_attribute = {}
        E_attribute["addr"] = self.attribute_stack.get_top(1)["addr"]
        E_attribute["type"] = self.attribute_stack.get_top(1)["type"]
        return E_attribute
    #Y::=Y1 * F
    #{Y.addr:=newtemp;gencode(Y.addr ':='Y1.addr'*'F.addr)}
    def semantic_action_34(self):
        Y_attribute = {}
        Y_attribute["addr"] = self.new_temp()
        Y1 = self.attribute_stack.get_top(3)
        F = self.attribute_stack.get_top(1)
        if F["type"] not in self.legal_type:
            raise MyException("算数类型不对")
        if Y1["type"] not in self.legal_type:
            raise MyException("算数类型不对")
        Y_attribute["type"] = self.max_type(Y1["type"],F["type"])
        a1 = self.widen(Y1["addr"],Y1["type"],Y_attribute["type"])
        a2 = self.widen(F["addr"],F["type"],Y_attribute["type"])
        self.gencode("*",a1,a2,Y_attribute["addr"])
        return Y_attribute
    #Y::=Y1 / F
    #{Y.addr:=newtemp;gencode(Y.addr ':='Y1.addr'/'F.addr)} 
    def semantic_action_35(self):
        Y_attribute = {}
        Y_attribute["addr"] = self.new_temp()
        Y1 = self.attribute_stack.get_top(3)
        F = self.attribute_stack.get_top(1)
        if F["type"] not in self.legal_type:
            raise MyException("算数类型不对")
        if Y1["type"] not in self.legal_type:
            raise MyException("算数类型不对")
        Y_attribute["type"] = self.max_type(Y1["type"],F["type"])
        a1 = self.widen(Y1["addr"],Y1["type"],Y_attribute["type"])
        a2 = self.widen(F["addr"],F["type"],Y_attribute["type"])
        self.gencode("/",a1,a2,Y_attribute["addr"])
        return Y_attribute
    #Y::=F
    #{Y.addr:=F.addr}
    def semantic_action_36(self):
        Y_attribute = {}
        Y_attribute["addr"] = self.attribute_stack.get_top(1)["addr"]
        Y_attribute["type"] = self.attribute_stack.get_top(1)["type"]
        return Y_attribute
    #F::=( M )
    #{F.addr:=M.addr}
    def semantic_action_37(self):
        F_attribute = {}
        F_attribute["addr"] = self.attribute_stack.get_top(2)["addr"]
        F_attribute["type"] = self.attribute_stack.get_top(2)["type"]
        return F_attribute
    #F::=M
    #F.addr:=M.addr
    def semantic_action_38(self):
        F_attribute = {}
        F_attribute["addr"] = self.attribute_stack.get_top(1)["addr"]
        F_attribute["type"] = self.attribute_stack.get_top(1)["type"]
        return F_attribute
    #{if Left.offset=null then /*Left是简单id*/
    #M.addr:= Left.addr
    #else begin           /*Left是数组元素*/
    #M.addr:=newtemp;
    #gencode(M.addr ':=' Left.addr ' [' Left.offset ']')
    #end}
    #M::=Left
    #Left只能是一般类型,不能是结构体。Left一定不是数组类型Left::=L的时候已经检查了
    def semantic_action_39(self):
        M_attribute = {}
        Left = self.attribute_stack.get_top(1)
        if Left["type"] not in {"char","int","float","boolean"}:
            raise MyException("类型错误")
        if Left["offset"] == None:
            M_attribute["addr"] = Left["addr"]
        else:
            M_attribute["addr"] = self.new_temp()
            self.gencode("=",Left["addr"] + "[" + Left["offset"] + "]",None,M_attribute["addr"])
        M_attribute["type"] = Left["type"]
        return M_attribute
    #M::=CI
    #M.addr:=newtemp;
    #gencode(M.addr ':=' CI)
    def semantic_action_40(self):
        M_attribute = {}
        M_attribute["addr"] = self.new_temp()
        M_attribute["type"] = "int"
        CI = self.attribute_stack.get_top(1)
        self.gencode("=",str(CI["value"]),None,M_attribute["addr"])
        return M_attribute
    #M::=CF
    #M.addr:=newtemp;
    #gencode(M.addr ':=' CF)
    def semantic_action_41(self):
        M_attribute = {}
        M_attribute["addr"] = self.new_temp()
        M_attribute["type"] = "float"
        CF = self.attribute_stack.get_top(1)
        self.gencode("=",str(CF["value"]),None,M_attribute["addr"])
        return M_attribute
    #M::=CC
    #M.addr:=newtemp;
    #gencode(M.addr ':=' CC)
    def semantic_action_42(self):
        M_attribute = {}
        M_attribute["addr"] = self.new_temp()
        M_attribute["type"] = "char"
        CC = self.attribute_stack.get_top(1)
        self.gencode("=",str(CC["value"]),None,M_attribute["addr"])
        return M_attribute
    def back_patch(self,code_index_list,quad):
        for index in code_index_list:
            self.code_list[index].result = quad
    def merge(self,list1,list2):
        return list1+list2
    def makelist(self,quad):
        return [quad]
    #{backpatch(B.truelist, M3.quad);
    #S.nextlist := merge(B.falselist, W'.nextlist)}
    #S::= if B { M3 W' }
    def semantic_action_43(self):
        S_attribute = {}
        B = self.attribute_stack.get_top(5)
        M3 = self.attribute_stack.get_top(3)
        W_ = self.attribute_stack.get_top(2)
        self.back_patch(B["truelist"],M3["quad"])
        S_attribute["nextlist"] = self.merge(B["falselist"],W_["nextlist"])
        return S_attribute
    #{backpatch(B.truelist, M31.quad);
    #backpatch(B.falselist, M32.quad);
    #S.nextlist := merge(W'1.nextlist, merge(M4.nextlist, W'2.nextlist))}
    #S::= if B { M31 W'1 } M4 else { M32 W'2 }
    def semantic_action_44(self):
        S_attribute = {}
        B = self.attribute_stack.get_top(11)
        M31 = self.attribute_stack.get_top(9)
        M32 = self.attribute_stack.get_top(3)
        W_1 = self.attribute_stack.get_top(8)
        W_2 = self.attribute_stack.get_top(2)
        M4 = self.attribute_stack.get_top(6)
        self.back_patch(B["truelist"],M31["quad"])
        self.back_patch(B["falselist"],M32["quad"])
        S_attribute["nextlist"] = self.merge(W_1["nextlist"],self.merge(M4["nextlist"],W_2["nextlist"]))
        return S_attribute
    #{backpatch(W'.nextlist, M31.quad); 
    #backpatch(B.truelist,M32.quad);
    #S.nextlist:=B.falselist; 
    #gencode('goto'M31.quad)}
    #S::= while M31 B do { M32 W' }
    def semantic_action_45(self):
        S_attribute = {}
        W_ = self.attribute_stack.get_top(2)
        M32 = self.attribute_stack.get_top(3)
        B = self.attribute_stack.get_top(6)
        M31 = self.attribute_stack.get_top(7)
        self.back_patch(W_["nextlist"],M31["quad"])
        self.back_patch(B["truelist"],M32["quad"])
        S_attribute["nextlist"] = B["falselist"]
        self.gencode("goto",None,None,M31["quad"])
        return S_attribute
    #{M.quad := nextquad}
    #M3::=ε
    def semantic_action_46(self):
        M3_attirbute = {}
        M3_attirbute["quad"] = self.next_quad
        return M3_attirbute
    #{M4.nextlist := makelist(nextquad); gencode('goto –')}
    #M4::=ε
    def semantic_action_47(self):
        M4_attribute = {}
        M4_attribute["nextlist"] = self.makelist(self.next_quad)
        self.gencode("goto",None,None,None)
        return M4_attribute
    #{ backpatch(B1.falselist, M3.quad);
	#B.truelist := merge(B1.truelist, G.truelist);
	#B.falselist := G.falselist}
    #B::=B1 || M3 G
    def semantic_action_48(self):
        B_attribute = {}
        B1 = self.attribute_stack.get_top(4)
        M3 = self.attribute_stack.get_top(2)
        G = self.attribute_stack.get_top(1)
        self.back_patch(B1["falselist"],M3["quad"])
        B_attribute["truelist"] = self.merge(B1["truelist"],G["truelist"])
        B_attribute["falselist"] = G["falselist"]
        return B_attribute
    #B.truelist = G.truelist
    #B.falselist = G.falselist
    #B::=G
    def semantic_action_49(self):
        B_attribute = {}
        G = self.attribute_stack.get_top(1)
        B_attribute["truelist"] = G["truelist"]
        B_attribute["falselist"] = G["falselist"]
        return B_attribute
    #{backpatch(G1.truelist, M3.quad);
	#G.truelist := H.truelist;
	#G.falselist := merge(G1.falselist, H.falselist)}
    #G::=G1 && M3 H
    def semantic_action_50(self):
        G_attribute = {}
        G1 = self.attribute_stack.get_top(4)
        M3 = self.attribute_stack.get_top(2)
        H = self.attribute_stack.get_top(1)
        self.back_patch(G1["truelist"],M3["quad"])
        G_attribute["truelist"] = H["truelist"]
        G_attribute["falselist"] = self.merge(G1["falselist"],H["falselist"])
        return G_attribute
    #G.truelist = H.truelist
    #G.falselist = H.falselist
    #G::=H
    def semantic_action_51(self):
        G_attribute = {}
        H = self.attribute_stack.get_top(1)
        G_attribute["truelist"] = H["truelist"]
        G_attribute["falselist"] = H["falselist"]
        return G_attribute
    #H.truelist := H1.falselist; H.falselist := H1.truelist
    #H::=! H1
    def semantic_action_52(self):
        H_attribute = {}
        H1 = self.attribute_stack.get_top(1)
        H_attribute["truelist"] = H1["falselist"]
        H_attribute["falselist"] = H1["truelist"]
        return H_attribute
    #H.truelist = I.truelist
    #H.falselist = I.falselist
    #H::=I
    def semantic_action_53(self):
        H_attribute = {}
        I = self.attribute_stack.get_top(1)
        H_attribute["truelist"] = I["truelist"]
        H_attribute["falselist"] = I["falselist"]
        return H_attribute
    #{I.truelist :=makelist(nextquad);
    #I.falselist := makelist(nextquad+1);
	#gencode('if' E1.addr R.op E2.addr 'goto –');
	#gencode('goto –')}
    #I::=E1 R E2
    def semantic_action_54(self):
        I_attribute = {}
        E2 = self.attribute_stack.get_top(1)
        R = self.attribute_stack.get_top(2)
        E1 = self.attribute_stack.get_top(3)
        I_attribute["truelist"] = self.makelist(self.next_quad)
        I_attribute["falselist"] = self.makelist(self.next_quad+1)
        self.gencode("goto"+R["op"],E1["addr"],E2["addr"],None)
        self.gencode("goto",None,None,None)
        return I_attribute
    #I.truelist := B.truelist;
    #I.falselist := B.falselist
    #I::=( B )
    def semantic_action_55(self):
        I_attribute = {}
        B = self.attribute_stack.get_top(2)
        I_attribute["truelist"] = B["truelist"]
        I_attribute["falselist"] = B["falselist"]
        return I_attribute
    #I::=true
    #I.truelist := makelist(nextquad);
    #gencode('goto –')
    def semantic_action_56(self):
        I_attribute = {}
        I_attribute["truelist"] = self.makelist(self.next_quad)
        I_attribute["falselist"] = []
        self.gencode("goto",None,None,None)
        return I_attribute
    #I.falselist := makelist(nextquad);
    # gencode('goto –')
    #I::=false
    def semantic_action_57(self):
        I_attribute = {}
        I_attribute["falselist"] = self.makelist(self.next_quad)
        I_attribute["truelist"] = []
        self.gencode("goto",None,None,None)
        return I_attribute
    #R.op = "<"
    #R::=<
    def semantic_action_58(self):
        R_attribute = {"op":"<"}
        return R_attribute
    #R.op = "<="
    #R::=< =
    def semantic_action_59(self):
        R_attribute = {"op":"<="}
        return R_attribute
    #R.op = "=="
    #R::== =
    def semantic_action_60(self):
        R_attribute = {"op":"=="}
        return R_attribute
    #R.op = "! ="
    #R::=! =
    def semantic_action_61(self):
        R_attribute = {"op":"!="}
        return R_attribute
    #R.op = ">"
    #R::=>
    def semantic_action_62(self):
        R_attribute = {"op":">"}
        return R_attribute
    #R.op = ">="
    #R::=> =
    def semantic_action_63(self):
        R_attribute = {"op":">="}
        return R_attribute
    #{backpatch(W'1.nextlist, M3.quad); 
    #W'.nextlist = S.nextlist if S has nextlist
    #or W'.nextlist = []
    #W'::=W'1 M3 S 
    def semantic_action_9(self):
        W__attribute = {}
        W_1 = self.attribute_stack.get_top(3)
        M3 = self.attribute_stack.get_top(2)
        S = self.attribute_stack.get_top(1)
        self.back_patch(W_1["nextlist"],M3["quad"])
        if "nextlist" in S:
            W__attribute["nextlist"] = S["nextlist"]
        else:
            W__attribute["nextlist"] = []
        return W__attribute
    #W'.nextlist = S.nextlist if S has nextlist
    #or W'.nextlist = []
    #W'::=S
    def semantic_action_8(self):
        W__attribute = {}
        S = self.attribute_stack.get_top(1)
        if "nextlist" in S:
            W__attribute["nextlist"] = S["nextlist"]
        else:
            W__attribute["nextlist"] = []
        return W__attribute
    #P.nextlist = S.nextlist if S has nextlist
    #or P.nextlist = []
    #P::=S
    def semantic_action_4(self):
        P_attribute = {}
        S = self.attribute_stack.get_top(1)
        if "nextlist" in S:
            P_attribute["nextlist"] = S["nextlist"]
        else:
            P_attribute["nextlist"] = []
        return P_attribute
    #P.nextlist = []
    #P::=D
    def semantic_action_3(self):
        P_attribute = {}
        P_attribute["nextlist"] = []
        return P_attribute
    #P'::=P
    #P'.nextlist = P.nextlist
    def semantic_action_2(self):
        P__attribute = {}
        P = self.attribute_stack.get_top(1)
        P__attribute["nextlist"] = P["nextlist"]
        return P__attribute
    #P'::=P'1 M3 P
    #{backpatch(P'1.nextlist, M3.quad); 
    #P'.nextlist = P.nextlist
    def semantic_action_1(self):
        P__attribute = {}
        P = self.attribute_stack.get_top(1)
        M3 = self.attribute_stack.get_top(2)
        P_1 = self.attribute_stack.get_top(3)
        self.back_patch(P_1["nextlist"],M3["quad"])
        P__attribute["nextlist"] = P["nextlist"]
        return P__attribute
    #start::=P'
    def semantic_action_0(self):
        return {}
    # {n :=0; 
    #repeat
    #n:=n+1;
    #从queue的队首取出一个实参地址p;
	#gencode('param', -, -, p);
    #until queue为空;
	#gencode('call', id.addr, n, -)}
    #S::=Left = call id ( Elist ) ;
    #要检查参数数目和类型
    def semantic_action_64(self):
        t = self.table_stack.get_top(1)
        id = self.attribute_stack.get_top(5)
        Elist = self.attribute_stack.get_top(3)
        Left = self.attribute_stack.get_top(8)
        item = t.search(id["addr"])
        n=0
        if item==None:
            raise MyException(id["addr"]+"未定义")
        table = item.redundant_point
        if item.type!="fuction":
            raise MyException("不能对非函数变量进行函数调用")
        if table.param_num != len(Elist["type_array"]):
            raise MyException("参数个数不正确")
        for i in range(table.param_num):
            if table.table[i].type != Elist["type_array"][i]:
                raise MyException("第"+str(i+1)+"个参数类型不正确")
        if not (Left["type"]=="boolean" and table.return_type=="boolean" or 
                Left["type"] in self.legal_type and table.return_type in self.legal_type):
                raise MyException("赋值类型不匹配")
        #类型转换
        left_type_prioity = self.legal_type[Left["type"]]
        E_type_prioity = self.legal_type[table.return_type]
        #如果Left的类型比E宽
        if left_type_prioity>E_type_prioity:
            temp = self.widen(table.return_type,table.return_type,Left["type"])
            table.return_type = temp
        elif left_type_prioity<E_type_prioity:
            raise MyException("赋值语句不能向宽类型转换")
        while not self.param_queue.is_empty():
            p = self.param_queue.dequeue()
            self.gencode("param",None,None,p)
            n+=1
        self.gencode("call",id["addr"],n,None)
        self.gencode("=","F",None,Left["addr"])
        return {}
    #Elist::=Elist , E
    #{将E.addr添加到queue的队尾}
    def semantic_action_65(self):
        Elist_attribute = {}
        E = self.attribute_stack.get_top(1)
        Elist = self.attribute_stack.get_top(3)
        self.param_queue.enqueue(E["addr"])
        Elist_attribute["type_array"] = Elist["type_array"] + [E["type"]]
        return Elist_attribute
    #Elist::=E
    #初始化queue,然后将E.addr加入到queue的队尾。
    #记录E的类型,用于对比实参和形参类型
    def semantic_action_66(self):
        Elist_attribute = {}
        self.param_queue = Queue()
        E = self.attribute_stack.get_top(1)
        self.param_queue.enqueue(E["addr"])
        Elist_attribute["type_array"] = [E["type"]]
        return Elist_attribute
    #List::=id
    def semantic_action_68(self):
        self.param_queue = Queue()
        id = self.attribute_stack.get_top(1)
        t = self.table_stack.get_top(1)
        if t.search(id["addr"])==None:
            raise MyException(id["addr"]+"未定义") 
        self.param_queue.enqueue(id["addr"])

        return {}
    #List::=List , id
    ##{将id.addr添加到queue的队尾}
    def semantic_action_67(self):
        id = self.attribute_stack.get_top(1)
        t = self.table_stack.get_top(1)
        if t.search(id["addr"])==None:
            raise MyException(id["addr"]+"未定义") 
        self.param_queue.enqueue(id["addr"])
        return {}
    #{n:=0;
    #repeat 
    #move(Queue, in);
    #gencode(‘param’, -, -, in);
    #n:=n+1;
    #until Queue为空;
    #gencode(‘call’, ‘SYSOUT’, n, -)}
    #S::=print ( Elist ) ;
    def semantic_action_22(self):
        n = 0
        while not self.param_queue.is_empty():
            p = self.param_queue.dequeue()
            self.gencode("param",None,None,p)
            n = n+1
        self.gencode("call","SYSOUT",n,None)
        return {}
    #{n:=0;
    #repeat 
    #move(Queue, in);
    #gencode(‘par’, ‘in’, -, -);
    #n:=n+1;
    #until Queue为空;
    #gencode(‘call’, ‘SYSIN’, n, -);}
    #S::=input ( List ) ;
    def semantic_action_23(self):
        n = 0
        while not self.param_queue.is_empty():
            p = self.param_queue.dequeue()
            self.gencode("param",None,None,p)
            n = n+1
        self.gencode("call","SYSIN",n,None)
        return {}
    def max_type(self,type1,type2):
        legal_type = self.legal_type
        if type1 not in legal_type or type2 not in legal_type:
            raise MyException("算数运算类型不正确")
        type1_prioity = legal_type[type1]
        type2_prioity = legal_type[type2]
        if type1_prioity>type2_prioity:
            return type1
        else:
            return type2
    def widen(self,addr,init_type,wide_type):
        init_type_prioity = self.legal_type[init_type]
        wide_type_prioity = self.legal_type[wide_type]
        if init_type_prioity==wide_type_prioity:
            return addr
        elif init_type_prioity<wide_type_prioity:
            temp = self.new_temp()
            self.gencode(init_type+"to"+wide_type,addr,None,temp)
            return temp
Exemplo n.º 8
0
class User:
    """
    User class serves as an abstraction for users. Users are only allowed to
    shop at only one store. User instances are treated as regular users.
    """
    ##### Part 4.1 #####
    user_counter = 0
    def __init__(self, name, store):
        """
        Constructor for User instances. Each instance is initialized with the
        user's username and the store they shop at. Instance attributes are:
        name, store, balance, their user ID, purchase history, and shopping
        cart.
        """
        # YOUR CODE GOES HERE #
        self.name = name
        self.store = store
        self.balance = 0
        self.id = User.user_counter
        User.user_counter += 1
        self.purchase_history = Stack()
        self.cart = Queue()
        self.store.add_user(self)

    def __str__(self):
        """
        Return the string representation as:
        "standard user: {name} - {balance}$"
        """
        # YOUR CODE GOES HERE #
        return "standard user: {} - {}$".format(self.name, self.balance)

    def __repr__(self):
        """
        Return the string representation as:
        "USER<{id}>"
        """
        # YOUR CODE GOES HERE #
        return "USER<{}>".format(self.id)

    def set_name(self, new_name):
        """
        Replaces a user's old name to new_name
        """
        # YOUR CODE GOES HERE #
        self.name = new_name

    def get_name(self):
        """
        Returns the user's current name
        """
        # YOUR CODE GOES HERE #
        return self.name

    def set_balance(self, amount):
        """
        Set the user's current balance to the given amount
        """
        # YOUR CODE GOES HERE #
        self.balance = amount

    def get_balance(self):
        """
        Returns the user's current balance
        """
        # YOUR CODE GOES HERE #
        return self.balance

    def add_balance(self, amount):
        """
        Add the given amount to the current balance
        """
        # YOUR CODE GOES HERE #
        self.balance += amount

    def last_purchase(self):
        """
        Return the user's most recent purchase
        """
        # YOUR CODE GOES HERE #
        return self.purchase_history.peek()

    def view_history(self):
        """
        Print the user's entire purchase history
        """
        # YOUR CODE GOES HERE #
        print(self.purchase_history)

    def view_cart(self):
        """
        Print all items in the user's cart
        """
        # YOUR CODE GOES HERE #
        print(self.cart)

    def clear_cart(self):
        """
        Remove all items from the user's cart
        """
        # YOUR CODE GOES HERE #
        self.cart = Queue()

    ##### Part 5.2 #####
    def add_cart(self, product_id):
        """
        Add the product with the given product id to the user's cart
        """
        # YOUR CODE GOES HERE #
        item = self.store.get_product(product_id)
        if item == None:
            pass
        else:
            self.cart.enqueue(item)

    def checkout(self):
        """
        Purchase all items in the user's cart and return a list of all
        purchased products.

        As soon as a product cannot be purchased, purchasing is stopped.
        Anything that was purchased successfully is returned in a list.
        """
        # YOUR CODE GOES HERE #
        purchases = []
        while not(self.cart.is_empty()):
            product = self.cart.peek()
            purchase = self.store.order(self.id, product.id)
            if purchase:
                self.cart.dequeue()
                purchases.append(purchase.product)
                self.purchase_history.push(purchase)
            else:
                break
        return purchases

    ##### Part 5.3 #####
    def undo_purchase(self):
        """
        Undo the user's most recent purchase.

        If there is no shopping history, print "USER: no purchase history" and
        do nothing else.
        Else, attempt to undo the purchase. If the store allows the request,
        remove that purchase from the user's purchase history.
        """
        # YOUR CODE GOES HERE #
        if self.purchase_history.is_empty():
            print("USER: no purchase history")
        else:
            last_purchase = self.purchase_history.peek()
            user = last_purchase.user
            user_id = user.id
            product = last_purchase.product
            request = self.store.undo_order(user_id, product)

            if request:
                user.purchase_history.pop()