A lightweight linked list type queue implementation, meant for microcontrollers. Written as a C++ template class.
Creates a queue up to <maximum_number_of_items> items:
ArduinoQueue<T> intQueue(maximum_number_of_items);
Creates a queue up to <maximum_size_in_bytes> bytes:
ArduinoQueue<T> intQueue(0, maximum_size_in_bytes);
Creates a queue up to <maximum_number_of_items> items or <maximum_size_in_bytes> bytes, whatever comes first:
ArduinoQueue<T> intQueue(maximum_number_of_items, maximum_size_in_bytes);
Include the header file on your code:
#include <ArduinoQueue.h>
Then create the queue according to your needs, examples:
ArduinoQueue<int> intQueue(20);
ArduinoQueue<int> intQueue(20, 10);
struct car {
char brand[10];
char model[10];
int nr_doors;
};
ArduinoQueue<car> myCarsQueue(50);
Finally use the following functions:
intQueue.enqueue(1); // Adds number 1 to the queue
intQueue.enqueue(123); // Adds number 123 to the queue
int number = intQueue.dequeue(); // Will return number 1 and remove it from the queue
int number = intQueue.getHead(); // Will return number 123 but leave it still in the queue
int number = intQueue.dequeue(); // Will return number 123 and remove it from the queue
You can use also the following functions to get more queue properties:
bool state = intQueue.isEmpty(); // Returns true if the queue is empty, false otherwise
bool state = intQueue.isFull(); // Returns true if the queue is full, false otherwise
unsigned int n = intQueue.itemCount(); // Returns the number of items currently on the queue
unsigned int n = intQueue.itemSize(); // Returns the size of the item being stored (bytes)
unsigned int n = intQueue.maxQueueSize(); // Returns the maximum possible size of the queue (items)*
unsigned int n = intQueue.maxMemorySize(); // Returns the maximum possible size of the queue (bytes)*
This library is not thread safe. Mutexes are often hardware specific on the way they are optimized to operate. So for the sake of performance and portability, it is left out.
The memory for the queue nodes are dynamically allocated. Note that while the Queue class cleans up the nodes in memory after destructor or dequeue is called, it keeps a copy of the item being queued. So for example if you are queuing pointers, you will need to keep track of the memory behind them.
CPU: Intel i7-6500U
RAM: DDR4L
Benchmark result (1000 samples):
Enqueued 1000000 ints in average 0.018749799 seconds
Dequeued 1000000 ints in average 0.016496857 seconds
Allocated 15.2588 MB (16 bytes per item)