Queues (also known as output-restricted deques) are mutable ordered collections that can contain any Scheme object. Each queue contains a list that contains the elements of the queue, and maintains pointers to the first and last pairs of the list. It's cheap to add or remove elements from the front of the list or to add elements to the back, but not to remove elements from the back. Queues are disjoint from other types of Scheme objects.
The API provided here is closely analogous to the R7RS-small API for lists. Other list procedures can be applied to queues using queue->list, list->queue, and list-queue!. It subsumes the Chicken and SLIB APIs.
Except as noted, all procedures are O(n), where n is the length of the queue.
(make-queue k [ fill ])
Returns a newly allocated queue of k elements whose value is fill. If fill is omitted, an implementation-dependent value is chosen.
(queue element ...)
Returns a newly allocated queue containing the elements.
(queue-copy queue)
Returns a newly allocated queue containing the elements of queue.
(queue? obj)
Returns #t if obj is a queue, and #f otherwise. This operation is O(1).
(queue-empty? queue)
Returns #t if obj is a queue with no elements, and #f otherwise. This operation is O(1).
(queue-first queue element)
Returns the first element of the queue. This operation is O(1).
(queue-lastqueue element)
Returns the last element of the queue. This operation is O(1).
(queue-ref ''queue k'')`
Returns the kth element of queue. This operation is O(k).
(queue-add-first! queue element)
Adds element to the beginning of queue. Returns an unspecified value. This operation is O(1).
(queue-add-last! queue element)
Adds element to the end of queue. Returns an unspecified value. This operation is O(1).
(queue-remove-first! queue)
Removes the first element of the queue and returns it. This operation is O(1).
(queue-remove-last! queue)
Removes the last element of the queue and returns it. This operation is O(n), because the list does not have backward links.
(queue-set! queue k value)
Sets the kth element of queue to value. This operation is O(k).
(queue-length queue)
Returns the number of elements in queue.
(queue-appendqueue ...)
Returns a queue which contains all the elements in all the queues in the order in which they appear in the call.
(queue-reverse queue)
Returns a newly allocated queue with the same elements as in queue but in reverse order.
(queue-member? queue element; [ predicate ])
Returns #t if element is a member of queue (in the sense of predicate, which defaults to equal?) and #f otherwise.
(queue-map proc queue)
Applies proc to each element of queue in order and returns a newly allocated queue containing the results.
(queue-map! proc queue)
Applies proc to each element of queue in order and modifies queue to contain the results.
(queue-for-each proc queue)
Applies proc to each element of queue in order, discarding the returned values. Returns an unspecified value.
(queue->list queue)
Returns the list that contains the members of queue in order. It is an error to mutate the cdrs of such a list, as it shares storage with the queue. This operation is O(1).
(list->queue list)
Returns a newly allocated queue containing the elements of list in order. It is an error to mutate the cdrs of list after calling this procedure, as it shares storage with the queue. This operation is O(1).
To apply a non-destructive list procedure to a queue and return a new queue, use (list->queue (proc (queue->list queue))).
(list->queue! queue list)
Replaces the list associated with queue with list, effectively discarding all the elements of queue in favor of those in list. It is an error to mutate the cdrs of list after calling this procedure, as it shares storage with the queue. Returns an unspecified value. This operation is O(1).
To apply a destructive list procedure to a queue, use (list->queue! (proc (queue->list queue))).
R5RS implementations do not have make-list, list-copy, list-set!, or map!, which therefore would need to be packaged with the sample implementation. All but list-set! are available in SRFI 1, but it's trivial to provide local implementations of them.