If your queue is based on an array, then for efficiency's sake, I would recommend creating a bounded or "circular" queue, where the max-size of the queue is fixed, and you basically have a head and tail pointer that point to the "first" and "last" positions in the queue's array, and when the tail-pointer (or an index value) moves to a position "past" the end of the array, it actually moves back to the beginning of the array. An unbounded queue based on an array would be horribly inefficient, as you would need to keep reallocating memory each time you fill up the max-size of the array, and/or attempt to re-shuffle elements down the array when you remove the first element of the queue.
Using integral-type array indexes for head
and tail
rather than actual pointer types, along with a counter for determining the overall number of items in your queue, your enqueue and dequeue functions could look as simple as:
template<typename T>
bool queue<T>::enqueue(const T& item)
{
if (count == array_size)
return false;
array[tail] = item;
tail = (tail + 1) % array_size;
count++;
return true;
}
template<typename T>
bool queue<T>::dequeue(T& item)
{
if (!count)
return false;
item = array[head];
head = (head + 1) % array_size;
count--;
return true;
}
You can extend this concept to whatever other functions you'd like, i.e., if you'd rather have a separate functions like the STL uses for accessing the head of the queue and actually "removing" an element from the queue.
std
version as you've demonstrated. If this is homework, just remember that a queue is first in, first out.