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fifo_queue.go
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fifo_queue.go
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package goconcurrentqueue
import (
"context"
"fmt"
"sync"
"time"
)
const (
WaitForNextElementChanCapacity = 1000
dequeueOrWaitForNextElementInvokeGapTime = 10
)
// FIFO (First In First Out) concurrent queue
type FIFO struct {
slice []interface{}
rwmutex sync.RWMutex
lockRWmutex sync.RWMutex
isLocked bool
// queue for watchers that will wait for next elements (if queue is empty at DequeueOrWaitForNextElement execution )
waitForNextElementChan chan chan interface{}
// queue to unlock consumers that were locked when queue was empty (during DequeueOrWaitForNextElement execution)
unlockDequeueOrWaitForNextElementChan chan struct{}
}
// NewFIFO returns a new FIFO concurrent queue
func NewFIFO() *FIFO {
ret := &FIFO{}
ret.initialize()
return ret
}
func (st *FIFO) initialize() {
st.slice = make([]interface{}, 0)
st.waitForNextElementChan = make(chan chan interface{}, WaitForNextElementChanCapacity)
st.unlockDequeueOrWaitForNextElementChan = make(chan struct{}, WaitForNextElementChanCapacity)
}
// Enqueue enqueues an element. Returns error if queue is locked.
func (st *FIFO) Enqueue(value interface{}) error {
if st.isLocked {
return NewQueueError(QueueErrorCodeLockedQueue, "The queue is locked")
}
// let consumers (DequeueOrWaitForNextElement) know there is a new element
select {
case st.unlockDequeueOrWaitForNextElementChan <- struct{}{}:
default:
// message could not be sent
}
// check if there is a listener waiting for the next element (this element)
select {
case listener := <-st.waitForNextElementChan:
// send the element through the listener's channel instead of enqueue it
select {
case listener <- value:
default:
// enqueue if listener is not ready
// lock the object to enqueue the element into the slice
st.rwmutex.Lock()
// enqueue the element
st.slice = append(st.slice, value)
defer st.rwmutex.Unlock()
}
default:
// lock the object to enqueue the element into the slice
st.rwmutex.Lock()
// enqueue the element
st.slice = append(st.slice, value)
defer st.rwmutex.Unlock()
}
return nil
}
// Dequeue dequeues an element. Returns error if queue is locked or empty.
func (st *FIFO) Dequeue() (interface{}, error) {
if st.isLocked {
return nil, NewQueueError(QueueErrorCodeLockedQueue, "The queue is locked")
}
st.rwmutex.Lock()
defer st.rwmutex.Unlock()
len := len(st.slice)
if len == 0 {
return nil, NewQueueError(QueueErrorCodeEmptyQueue, "empty queue")
}
elementToReturn := st.slice[0]
st.slice = st.slice[1:]
return elementToReturn, nil
}
// DequeueOrWaitForNextElement dequeues an element (if exist) or waits until the next element gets enqueued and returns it.
// Multiple calls to DequeueOrWaitForNextElement() would enqueue multiple "listeners" for future enqueued elements.
func (st *FIFO) DequeueOrWaitForNextElement() (interface{}, error) {
return st.DequeueOrWaitForNextElementContext(context.Background())
}
// DequeueOrWaitForNextElementContext dequeues an element (if exist) or waits until the next element gets enqueued and returns it.
// Multiple calls to DequeueOrWaitForNextElementContext() would enqueue multiple "listeners" for future enqueued elements.
// When the passed context expires this function exits and returns the context' error
func (st *FIFO) DequeueOrWaitForNextElementContext(ctx context.Context) (interface{}, error) {
for {
if st.isLocked {
return nil, NewQueueError(QueueErrorCodeLockedQueue, "The queue is locked")
}
// get the slice's len
st.rwmutex.Lock()
length := len(st.slice)
st.rwmutex.Unlock()
if length == 0 {
// channel to wait for next enqueued element
waitChan := make(chan interface{})
select {
// enqueue a watcher into the watchForNextElementChannel to wait for the next element
case st.waitForNextElementChan <- waitChan:
// n
for {
// re-checks every i milliseconds (top: 10 times) ... the following verifies if an item was enqueued
// around the same time DequeueOrWaitForNextElementContext was invoked, meaning the waitChan wasn't yet sent over
// st.waitForNextElementChan
for i := 0; i < dequeueOrWaitForNextElementInvokeGapTime; i++ {
select {
case <-ctx.Done():
return nil, ctx.Err()
case dequeuedItem := <-waitChan:
return dequeuedItem, nil
case <-time.After(time.Millisecond * time.Duration(i)):
if dequeuedItem, err := st.Dequeue(); err == nil {
return dequeuedItem, nil
}
}
}
// return the next enqueued element, if any
select {
// new enqueued element, no need to keep waiting
case <-st.unlockDequeueOrWaitForNextElementChan:
// check if we got a new element just after we got <-st.unlockDequeueOrWaitForNextElementChan
select {
case item := <-waitChan:
return item, nil
default:
}
// go back to: for loop
continue
case item := <-waitChan:
return item, nil
case <-ctx.Done():
return nil, ctx.Err()
}
// n
}
default:
// too many watchers (waitForNextElementChanCapacity) enqueued waiting for next elements
return nil, NewQueueError(QueueErrorCodeEmptyQueue, "empty queue and can't wait for next element because there are too many DequeueOrWaitForNextElement() waiting")
}
}
st.rwmutex.Lock()
// verify that at least 1 item resides on the queue
if len(st.slice) == 0 {
st.rwmutex.Unlock()
continue
}
elementToReturn := st.slice[0]
st.slice = st.slice[1:]
st.rwmutex.Unlock()
return elementToReturn, nil
}
}
// Get returns an element's value and keeps the element at the queue
func (st *FIFO) Get(index int) (interface{}, error) {
if st.isLocked {
return nil, NewQueueError(QueueErrorCodeLockedQueue, "The queue is locked")
}
st.rwmutex.RLock()
defer st.rwmutex.RUnlock()
if len(st.slice) <= index {
return nil, NewQueueError(QueueErrorCodeIndexOutOfBounds, fmt.Sprintf("index out of bounds: %v", index))
}
return st.slice[index], nil
}
// Remove removes an element from the queue
func (st *FIFO) Remove(index int) error {
if st.isLocked {
return NewQueueError(QueueErrorCodeLockedQueue, "The queue is locked")
}
st.rwmutex.Lock()
defer st.rwmutex.Unlock()
if len(st.slice) <= index {
return NewQueueError(QueueErrorCodeIndexOutOfBounds, fmt.Sprintf("index out of bounds: %v", index))
}
// remove the element
st.slice = append(st.slice[:index], st.slice[index+1:]...)
return nil
}
// GetLen returns the number of enqueued elements
func (st *FIFO) GetLen() int {
st.rwmutex.RLock()
defer st.rwmutex.RUnlock()
return len(st.slice)
}
// GetCap returns the queue's capacity
func (st *FIFO) GetCap() int {
st.rwmutex.RLock()
defer st.rwmutex.RUnlock()
return cap(st.slice)
}
// Lock // Locks the queue. No enqueue/dequeue operations will be allowed after this point.
func (st *FIFO) Lock() {
st.lockRWmutex.Lock()
defer st.lockRWmutex.Unlock()
st.isLocked = true
}
// Unlock unlocks the queue
func (st *FIFO) Unlock() {
st.lockRWmutex.Lock()
defer st.lockRWmutex.Unlock()
st.isLocked = false
}
// IsLocked returns true whether the queue is locked
func (st *FIFO) IsLocked() bool {
st.lockRWmutex.RLock()
defer st.lockRWmutex.RUnlock()
return st.isLocked
}