def test_queue(self): test_queue = Queue() for i in range(0, 5): test_queue.push(i) counter = 0 while test_queue.is_empty() is not True: self.assertTrue(test_queue.peek() == counter) test_queue.pop() counter += 1 self.assertTrue(test_queue.is_empty())
def shunting_yard(self, elements: Queue): """Does the shunting yard algorithm to produce something that is ready for rpn""" operator_stack = Stack() while not elements.is_empty(): element = elements.pop() if isinstance(element, numbers.Number): self.output_queue.push(element) elif isinstance(element, Function) or element == "(": operator_stack.push(element) elif element == ")": while operator_stack.peek() != "(": self.output_queue.push(operator_stack.pop()) # Pop ( if operator_stack.peek() == "(": operator_stack.pop() if not operator_stack.is_empty() and isinstance(operator_stack.peek(), Function): self.output_queue.push(operator_stack.pop()) elif isinstance(element, Operator): intermediate_storage = Stack() while ((not operator_stack.is_empty()) and (not operator_stack.peek() == "(") and operator_stack.peek().strength < element.strength): intermediate_storage.push(operator_stack.pop()) while not intermediate_storage.is_empty(): operator_stack.push(intermediate_storage.pop()) operator_stack.push(element) while not operator_stack.is_empty(): self.output_queue.push(operator_stack.pop())
def test_queue(self): """Test Queue class""" queue = Queue() for num in self.test_list: queue.push(num) index = 0 while not queue.is_empty(): num = queue.pop() self.assertEqual(num, self.test_list[index]) index += 1
class Dispatcher: """A dispatcher fulfills requests from riders and drivers for a ride-sharing service. When a rider requests a driver, the dispatcher assigns a driver to the rider. If no driver is available, the rider is placed on a waiting list for the next available driver. A rider that has not yet been picked up by a driver may cancel their request. When a driver requests a rider, the dispatcher assigns a rider from the waiting list to the driver. If there is no rider on the waiting list the dispatcher does nothing. Once a driver requests a rider, the driver is registered with the dispatcher, and will be used to fulfill future rider requests. """ def __init__(self): """Initialize a Dispatcher. @type self: Dispatcher @type _waitlist: Queue of Rider @type _fleet: PriorityQueue of Driver @rtype: None """ self._waitlist = Queue() self._fleet = [] def request_driver(self, rider): """Return a driver for the rider, or None if no driver is available. Add the rider to the waiting list if there is no available driver. @type self: Dispatcher @type rider: Rider @rtype: Driver | None >>> d = Dispatcher() >>> d1 = Driver('a', Location(9,0), 1) >>> d2 = Driver('b', Location(0,0), 1) >>> d._fleet = [d1, d2] >>> r1 = Rider('a', Location(0,0), Location(1,0), 3) >>> print(d.request_driver(r1)) a """ fastest_driver = self._fleet[0] for driver in self._fleet: if not driver.is_idle: self._waitlist.add(rider) return None else: for i in range(len(self._fleet) - 1): for j in range(len(self._fleet) - 1): if self._fleet[i].get_travel_time(rider.origin) \ < self._fleet[j].get_travel_time(rider.origin): fastest_driver = self._fleet[i] else: fastest_driver = self._fleet[j] return fastest_driver def request_rider(self, driver): """Return a rider for the driver, or None if no rider is available. If this is a new driver, register the driver for future rider requests. @type self: Dispatcher @type driver: Driver @rtype: Rider | None >>> d = Dispatcher() >>> r1 = Rider('a', Location(0,0), Location(1,0), 3) >>> d._waitlist = Queue() >>> d._waitlist.add(r1) >>> d1 = Driver('a', Location(0,0), 1) >>> d2 = Driver('b', Location(0,0), 1) >>> d._fleet = [d1] >>> print(d.request_rider(d2)) a >>> print(d._fleet) """ if driver not in self._fleet: self._fleet.append(driver) # If waitlist is not empty, assign a rider if not self._waitlist.is_empty(): return self._waitlist.remove() else: return None def cancel_ride(self, rider): """Cancel the ride for rider and change their status to CANCELLED. @type self: Dispatcher @type rider: Rider @rtype: None """ rider._status = CANCELLED self._waitlist.remove(rider)
class Dispatcher: """A dispatcher fulfills requests from riders and drivers. When a rider requests a driver, the dispatcher assigns a driver to the rider. If no driver is available, the rider is placed on a waiting list for the next available driver. A rider that has not yet been picked up by a driver may cancel their request. When a driver requests a rider, the dispatcher assigns a rider from the waiting list to the driver. If there is no rider on the waiting list the dispatcher does nothing. Once a driver requests a rider, the driver is registered with the dispatcher, and will be used to fulfill future rider requests. """ def __init__(self): """Initialize a Dispatcher. @type self: Dispatcher @type waiting_riders @type availalbe_drivers @rtype: None """ self._available_drivers = [] self._waiting_riders = Queue() def __str__(self): """Return a string representation. @type self: Dispatcher @rtype: str """ return "Dispatcher:\n waiting_riders {0}, \n availalbe_drivers {1}"\ .format(self._waiting_riders, self._available_drivers) def request_driver(self, rider): """Return a driver for the rider, or None if no driver is available. Add the rider to the waiting list if there is no available driver. If there are available drivers, return the one that can reach the driver fastest @type self: Dispatcher @type rider: Rider @rtype: Driver | None """ if len(self._available_drivers) == 0: self._waiting_riders.add(rider) return None DriverTimes = [] for driver in self._available_drivers: if driver.is_idle: DriverTimes.append(driver.get_travel_time(rider.origin)) shortestTime = min(DriverTimes) for driver in self._available_drivers: if driver.get_travel_time(rider.origin) == shortestTime: return driver def request_rider(self, driver): """Return a rider for the driver, or None if no rider is available. If this is a new driver, register the driver for future rider requests. Return None if no riders are available, otherwise return the longest waiting rider. @type self: Dispatcher @type driver: Driver @rtype: Rider | None """ if not driver in self._available_drivers: self._available_drivers.append(driver) if self._waiting_riders.is_empty(): return None # The longest waiting rider if the first element of self.waiting_riders return self._waiting_riders.remove() def cancel_ride(self, rider): """Cancel the ride for rider. @type self: Dispatcher @type rider: Rider @rtype: None >>> John = Dispatcher() >>> Bobby = Rider('Bobby', Location(1,2), Location(3,4), 10) >>> John._waiting_riders.items = [Bobby] >>> John.cancel_ride(Bobby) >>> print(John._waiting_riders.items) [] """ if rider in self._waiting_riders.items: self._waiting_riders.items.remove(rider)
class calculator: def __init__(self): self.functions = { 'EXP': Function(numpy.exp), 'LOG': Function(numpy.log), 'SIN': Function(numpy.sin), 'COS': Function(numpy.cos), 'SQRT': Function(numpy.sqrt), 'SQUARE': Function(numpy.square) } self.operators = { 'PLUSS': Operator(numpy.add, 0), 'GANGE': Operator(numpy.multiply, 1), 'DELE': Operator(numpy.divide, 1), 'MINUS': Operator(numpy.subtract, 0) } self.output_queue = Queue() def RPN(self): stack = Stack() while not self.output_queue.is_empty(): ele = self.output_queue.pop() if isinstance(ele, float): stack.push(ele) elif ele in self.functions.keys(): ele2 = stack.pop() stack.push(self.functions[ele].execute(ele2)) elif ele in self.operators.keys(): ele2 = stack.pop() ele3 = stack.pop() stack.push(self.operators[ele].execute(ele3, ele2)) return stack.pop() def shunting_yard(self, string_regn): op_strong = "GANGE,DELE" op_stack = Stack() for ele in string_regn: if ele.isdigit() or ele[0] == '-': self.output_queue.push(float(ele)) elif ele in self.functions.keys() or ele == "(": op_stack.push(ele) elif ele == ")": num = op_stack.pop() while num != "(": self.output_queue.push(num) num = op_stack.pop() if ele in self.operators.keys(): peek = op_stack.peek() if peek: if peek in op_strong: self.output_queue.push(op_stack.pop()) op_stack.push(ele) # print(op_stack.items) # print(self.output_queue.items) while not op_stack.is_empty(): self.output_queue.push(op_stack.pop()) # print(self.output_queue.items) return self.RPN() def string_parser(self, text): text.replace(" ", "") regex = '[-A-Z/(*/)*a-z0-9]+' #regex = '[-A-Za-z0-9]+' list1 = re.findall(regex, text) list3 = re.findall('[/(*/)*]+', text) list2 = [] count_par = 0 for i in list1: if '(' in i: num = i.count('(') self.split_par(i, list2, '(', num, list3, count_par) count_par += 1 elif ')' in i: num = i.count(')') self.split_par(i, list2, ')', num, list3, count_par) count_par += 1 else: list2.append(i) # print(list2) return self.shunting_yard(list2) def split_par2(self, i, list2, par, num): start_par = i.split(par) count = 0 for ele in start_par: if ele != "": print(ele) list2.append(ele) for j in range(num): list2.append(par) count += 2 if count > len(start_par) + 1 + num: list2.pop(-1) return list2 def split_par(self, i, list2, par, num, list3, count_par): start_par = i.split(par) count = 0 for ele in start_par: if ele != "": list2.append(ele) for i in range(len(list3[count_par])): list2.append(par) count += 2 if count > len(start_par) + 1 + num: list2.pop(-1) return list2
class Calc: """Calcualtor for evaluation different expressions""" def __init__(self): self.functions = { 'EXP': Function(np.exp), 'LOG': Function(np.log), 'SIN': Function(np.sin), 'COS': Function(np.cos), 'SQRT': Function(np.sqrt) } self.operators = { 'PLUS': Operator(np.add, 0), 'ADD': Operator(np.add, 0), 'TIMES': Operator(np.multiply, 1), 'MULTIPLY': Operator(np.multiply, 1), 'DIVIDE': Operator(np.divide, 1), 'MINUS': Operator(np.subtract, 0), 'SUBTRACT': Operator(np.subtract, 0) } self.output_queue = Queue() def calculate_expression(self, text): """Takes an expression in human readable form and calculates the answer""" text = self.parse_text(text) self.shunting_yard(text) answer = self.rpn() return answer def parse_text(self, text): """Parses human readable text into something that is ready to be sorted by shunting_yard""" text = text.replace(" ", "").upper() index = 0 shunting_yard_ready = Queue() while index < len(text): text = text[index:] # Check for number match = re.search("^[-0123456789.]+", text) if match is not None: shunting_yard_ready.push(float(match.group(0))) index = match.end(0) continue # Check for function match = re.search("|".join(["^" + func for func in self.functions.keys()]), text) if match is not None: shunting_yard_ready.push(self.functions[match.group(0)]) index = match.end(0) continue # Check for operator match = re.search("|".join(["^" + op for op in self.operators.keys()]), text) if match is not None: shunting_yard_ready.push(self.operators[match.group(0)]) index = match.end(0) continue # Check for paranthases match = re.search("^[()]", text) if match is not None: shunting_yard_ready.push(match.group(0)) index = match.end(0) continue return shunting_yard_ready def shunting_yard(self, elements: Queue): """Does the shunting yard algorithm to produce something that is ready for rpn""" operator_stack = Stack() while not elements.is_empty(): element = elements.pop() if isinstance(element, numbers.Number): self.output_queue.push(element) elif isinstance(element, Function) or element == "(": operator_stack.push(element) elif element == ")": while operator_stack.peek() != "(": self.output_queue.push(operator_stack.pop()) # Pop ( if operator_stack.peek() == "(": operator_stack.pop() if not operator_stack.is_empty() and isinstance(operator_stack.peek(), Function): self.output_queue.push(operator_stack.pop()) elif isinstance(element, Operator): intermediate_storage = Stack() while ((not operator_stack.is_empty()) and (not operator_stack.peek() == "(") and operator_stack.peek().strength < element.strength): intermediate_storage.push(operator_stack.pop()) while not intermediate_storage.is_empty(): operator_stack.push(intermediate_storage.pop()) operator_stack.push(element) while not operator_stack.is_empty(): self.output_queue.push(operator_stack.pop()) def rpn(self): """Evaluates self.output_queue in RPN""" intermediate_storage = Stack() while not self.output_queue.is_empty(): item = self.output_queue.pop() if isinstance(item, numbers.Number): intermediate_storage.push(item) elif isinstance(item, Function): result = item.execute(intermediate_storage.pop()) intermediate_storage.push(result) elif isinstance(item, Operator): operand1 = intermediate_storage.pop() operand2 = intermediate_storage.pop() result = item.execute(operand2, operand1) intermediate_storage.push(result) return intermediate_storage.pop()