版权声明:本文为博主原创文章,未经博主允许不得转载。 https://blog.csdn.net/weixin_42787086/article/details/84564978
- 总等待时间 VS 总顾客人数:来的顾客人多,每个人都会产生等待时间,总等待时间自然也会多,不会随着ATM数量的增加而减少(ATM空闲情况除外)
- 总服务人数 VS 总顾客人数:ATM增多,能同时服务的顾客人数自然更多,所以这是一个效率概念,是会有明显提升的
- 需要创建2个队列用于存储新来的顾客,但总等待时间,总服务人数,总拒绝人数都不需要单独计算。但两台ATM的当前处理时间需要单独创建,因为需要分别计算两个队列的dequeue()
- 需要新增 重载operator<,用于判断将新顾客放在哪个队列
// queue.h -- interface for a queue
#ifndef QUEUE_H_
#define QUEUE_H_
// This queue will contain Customer items
class Customer
{
private:
long arrive; // arrival time for customer
int processtime; // processing time for customer
public:
Customer() : arrive(0), processtime (0) {}
void set(long when);
long when() const
{
return arrive;
}
int ptime() const
{
return processtime;
}
};
typedef Customer Item;
class Queue
{
private:
// class scope definitions
// Node is a nested structure definition local to this class
struct Node
{
Item item;
struct Node * next;
};
enum {Q_SIZE = 10};
// private class members
Node * front; // pointer to front of Queue
Node * rear; // pointer to rear of Queue
int items; // current number of items in Queue
const int qsize; // maximum number of items in Queue
// preemptive definitions to prevent public copying
Queue(const Queue & q) : qsize(0) { }
Queue & operator=(const Queue & q)
{
return *this;
}
public:
Queue(int qs = Q_SIZE); // create queue with a qs limit
~Queue();
bool isempty() const;
bool isfull() const;
int queuecount() const;
bool enqueue(const Item &item); // add item to end
bool dequeue(Item &item); // remove item from front
// Newly Added: help distribute new customer to which queue
bool operator<(Queue& obj);
};
#endif
// queue.cpp -- Queue and Customer methods
#include"queue.h"
#include <cstdlib> // (or stdlib.h) for rand()
// Queue methods
Queue::Queue(int qs) : qsize(qs)
{
front = rear = NULL; // or nullptr
items = 0;
}
Queue::~Queue()
{
Node * temp;
while (front != NULL) // while queue is not yet empty
{
temp = front; // save address of front item
front = front->next;// reset pointer to next item
delete temp; // delete former front
}
}
bool Queue::isempty() const
{
return items == 0;
}
bool Queue::isfull() const
{
return items == qsize;
}
int Queue::queuecount() const
{
return items;
}
// Add item to queue
bool Queue::enqueue(const Item & item)
{
if (isfull())
return false;
Node * add = new Node; // create node
// on failure, new throws std::bad_alloc exception
add->item = item; // set node pointers
add->next = NULL; // or nullptr;
items++;
if (front == NULL) // if queue is empty,
front = add; // place item at front
else
rear->next = add; // else place at rear
rear = add; // have rear point to new node
return true;
}
// Place front item into item variable and remove from queue
bool Queue::dequeue(Item & item)
{
if (front == NULL)
return false;
item = front->item; // set item to first item in queue
items--;
Node * temp = front; // save location of first item
front = front->next; // reset front to next item
delete temp; // delete former first item
if (items == 0)
rear = NULL;
return true;
}
bool Queue::operator<(Queue& obj)
{
return items < obj.items;
}
// customer method
// when is the time at which the customer arrives
// the arrival time is set to when and the processing
// time set to a random value in the range 1 - 3
void Customer::set(long when)
{
processtime = std::rand() % 3 + 1;
arrive = when;
}
// bank.cpp -- using the Queue interface
// compile with queue.cpp
#include <iostream>
#include <cstdlib> // for rand() and srand()
#include <ctime> // for time()
#include "queue.h"
const int MIN_PER_HR = 60;
bool newcustomer(double x); // is there a new customer?
int main()
{
using std::cin;
using std::cout;
using std::endl;
using std::ios_base;
// setting things up
std::srand(std::time(0)); // random initializing of rand()
cout << "Case Study: Bank of Heather Automatic Teller\n";
cout << "Enter maximum size of queue: ";
int qs;
cin >> qs;
cout << "Enter the number of simulation hours: ";
int hours; // hours of simulation
cin >> hours;
// simulation will run 1 cycle per minute
long cyclelimit = MIN_PER_HR * hours; // # of cycles
// clear input queue
while (cin.get() != '\n')
continue;
char ch;
cout << "Enter q to quit, others to continue.\n";
cin.get(ch);
while (ch != 'q')
{
// create 2 lines
Queue line1(qs); // line queue holds up to qs people
Queue line2(qs);
cout << "Enter the average number of customers per hour: ";// for 2 lines
double perhour; // average # of arrival per hour
cin >> perhour;
double min_per_cust; // average time between arrivals
min_per_cust = MIN_PER_HR / perhour;
Item temp; // new customer data,OR, temp object for dequeue()
long turnaways = 0; // turned away by full queue
long customers = 0; // joined the queue
long served = 0; // served during the simulation
long sum_line = 0; // cumulative line length
int wait_time1 = 0; // time until autoteller is free
int wait_time2 = 0;
long line_wait = 0; // cumulative time in line
// running the simulation
for (int cycle = 0; cycle < cyclelimit; cycle++)
{
if (newcustomer(min_per_cust)) // have newcomer
{
if (line1.isfull()&&line2.isfull())
turnaways++;
else
{
customers++;
temp.set(cycle); // cycle = time of arrival
// Newly Added: decide which queue to put new customer into
if (line1 < line2)
line1.enqueue(temp); // add newcomer to line
else
line2.enqueue(temp);
}
}
if (wait_time1 <= 0 && !line1.isempty())
{
line1.dequeue(temp); // attend next customer
wait_time1 = temp.ptime(); // for wait_time minutes
line_wait += cycle - temp.when();
served++;
}
if (wait_time1 > 0)
wait_time1--;
sum_line += line1.queuecount();
// Newly Added:same situation for line2
if (wait_time2 <= 0 && !line2.isempty())
{
line2.dequeue(temp); // attend next customer
wait_time2 = temp.ptime(); // for wait_time minutes
line_wait += cycle - temp.when();
served++;
}
if (wait_time2 > 0)
wait_time2--;
sum_line += line2.queuecount();
}
// reporting results
if (customers > 0)
{
cout << "customers accepted: " << customers << endl;
cout << " customers served: " << served << endl;
cout << " turnaways: " << turnaways << endl;
cout << "average queue size: ";
cout.precision(2);
cout.setf(ios_base::fixed, ios_base::floatfield);
cout << (double)sum_line / cyclelimit << endl;
cout << " average wait time: "
<< (double)line_wait / served << " minutes\n";
}
else
cout << "No customers!\n";
cout << "Done!\n";
// clear input queue
while (cin.get() != '\n')
continue;
cout << "Enter q to quit\n";
cin.get(ch);
}
cin.get();
return 0;
}
// x = average time, in minutes, between customers
// return value is true if customer shows up this minute
bool newcustomer(double x)
{
return (std::rand() * x / RAND_MAX < 1);
}