Ring Buffers

A ring buffer is a circular buffer, whose contents are stored in first-in-first-out order. Two content data modes are supported:

  • Data item mode: Multiple 32-bit word data items with metadata can be enqueued and dequeued from the ring buffer in chunks of up to 1020 bytes. Each data item also has two associated metadata values: a type identifier and a 16-bit integer value, both of which are application-specific.

  • Byte mode: raw bytes can be enqueued and dequeued.

Concepts

Any number of ring buffers can be defined (limited only by available RAM). Each ring buffer is referenced by its memory address.

A ring buffer has the following key properties:

  • A data buffer of 32-bit words or bytes. The data buffer contains the data items or raw bytes that have been added to the ring buffer but not yet removed.

  • A data buffer size, measured in 32-bit words or bytes. This governs the maximum amount of data (including metadata values) the ring buffer can hold.

A ring buffer must be initialized before it can be used. This sets its data buffer to empty.

Data item mode

A data item mode ring buffer instance is declared using RING_BUF_ITEM_DECLARE_POW2() or RING_BUF_ITEM_DECLARE_SIZE() and accessed using ring_buf_item_put() and ring_buf_item_get().

A ring buffer data item is an array of 32-bit words from 0 to 1020 bytes in length. When a data item is enqueued (ring_buf_item_put()) its contents are copied to the data buffer, along with its associated metadata values (which occupy one additional 32-bit word). If the ring buffer has insufficient space to hold the new data item the enqueue operation fails.

A data items is dequeued (ring_buf_item_get()) from a ring buffer by removing the oldest enqueued item. The contents of the dequeued data item, as well as its two metadata values, are copied to areas supplied by the retriever. If the ring buffer is empty, or if the data array supplied by the retriever is not large enough to hold the data item’s data, the dequeue operation fails.

Byte mode

A byte mode ring buffer instance is declared using RING_BUF_ITEM_DECLARE_SIZE() and accessed using: ring_buf_put_claim(), ring_buf_put_finish(), ring_buf_get_claim(), ring_buf_get_finish(), ring_buf_put() and ring_buf_get().

Data can be copied into the ring buffer (see ring_buf_put()) or ring buffer memory can be used directly by the user. In the latter case, the operation is split into three stages:

  1. allocating the buffer (ring_buf_put_claim()) when user requests the destination location where data can be written.

  2. writing the data by the user (e.g. buffer written by DMA).

  3. indicating the amount of data written to the provided buffer (ring_buf_put_finish()). The amount can be less than or equal to the allocated amount.

Data can be retrieved from a ring buffer through copying (see ring_buf_get()) or accessed directly by address. In the latter case, the operation is split into three stages:

  1. retrieving source location with valid data written to a ring buffer (see ring_buf_get_claim()).

  2. processing data

  3. freeing processed data (see ring_buf_get_finish()). The amount freed can be less than or equal or to the retrieved amount.

Concurrency

The ring buffer APIs do not provide any concurrency control. Depending on usage (particularly with respect to number of concurrent readers/writers) applications may need to protect the ring buffer with mutexes and/or use semaphores to notify consumers that there is data to read.

For the trivial case of one producer and one consumer, concurrency shouldn’t be needed.

Internal Operation

If the size of the data buffer is a power of two, the ring buffer uses efficient masking operations instead of expensive modulo operations when enqueuing and dequeuing data items. This option is applicable only for data item mode.

Implementation

Defining a Ring Buffer

A ring buffer is defined using a variable of type ring_buf. It must then be initialized by calling ring_buf_init().

The following code defines and initializes an empty data item mode ring buffer (which is part of a larger data structure). The ring buffer’s data buffer is capable of holding 64 words of data and metadata information.

#define MY_RING_BUF_SIZE 64

struct my_struct {
    struct ring_buf rb;
    uint32_t buffer[MY_RING_BUF_SIZE];
    ...
};
struct my_struct ms;

void init_my_struct {
    ring_buf_init(&ms.rb, sizeof(ms.buffer), ms.buffer);
    ...
}

Alternatively, a ring buffer can be defined and initialized at compile time using one of two macros at file scope. Each macro defines both the ring buffer itself and its data buffer.

The following code defines a ring buffer with a power-of-two sized data buffer, which can be accessed using efficient masking operations.

/* Buffer with 2^8 (or 256) words */
RING_BUF_ITEM_DECLARE_POW2(my_ring_buf, 8);

The following code defines an application-specific sized byte mode ring buffer enqueued and dequeued as raw bytes:

#define MY_RING_BUF_WORDS 93
RING_BUF_ITEM_DECLARE_SIZE(my_ring_buf, MY_RING_BUF_WORDS);

The following code defines a ring buffer with an arbitrary-sized data buffer, which can be accessed using less efficient modulo operations. Ring buffer is intended to be used for raw bytes.

#define MY_RING_BUF_BYTES 93
RING_BUF_DECLARE_SIZE(my_ring_buf, MY_RING_BUF_BYTES);

Enqueuing Data

A data item is added to a ring buffer by calling ring_buf_item_put().

uint32_t data[MY_DATA_WORDS];
int ret;

ret = ring_buf_item_put(&ring_buf, TYPE_FOO, 0, data, SIZE32_OF(data));
if (ret == -EMSGSIZE) {
    /* not enough room for the data item */
    ...
}

If the data item requires only the type or application-specific integer value (i.e. it has no data array), a size of 0 and data pointer of NULL can be specified.

int ret;

ret = ring_buf_item_put(&ring_buf, TYPE_BAR, 17, NULL, 0);
if (ret == -EMSGSIZE) {
    /* not enough room for the data item */
    ...
}

Bytes are copied to a byte mode ring buffer by calling ring_buf_put().

uint8_t my_data[MY_RING_BUF_BYTES];
uint32_t ret;

ret = ring_buf_put(&ring_buf, my_data, SIZE_OF(my_data));
if (ret != SIZE_OF(my_data)) {
    /* not enough room, partial copy. */
    ...
}

Data can be added to a byte mode ring buffer by directly accessing the ring buffer’s memory. For example:

uint32_t size;
uint32_t rx_size;
uint8_t *data;
int err;

/* Allocate buffer within a ring buffer memory. */
size = ring_buf_put_claim(&ring_buf, &data, MY_RING_BUF_BYTES);

/* Work directly on a ring buffer memory. */
rx_size = uart_rx(data, size);

/* Indicate amount of valid data. rx_size can be equal or less than size. */
err = ring_buf_put_finish(&ring_buf, rx_size);
if (err != 0) {
    /* No space to put requested amount of data to ring buffer. */
    ...
}

Retrieving Data

A data item is removed from a ring buffer by calling ring_buf_item_get().

uint32_t my_data[MY_DATA_WORDS];
uint16_t my_type;
uint8_t  my_value;
uint8_t  my_size;
int ret;

my_size = SIZE32_OF(my_data);
ret = ring_buf_item_get(&ring_buf, &my_type, &my_value, my_data, &my_size);
if (ret == -EMSGSIZE) {
    printk("Buffer is too small, need %d uint32_t\n", my_size);
} else if (ret == -EAGAIN) {
    printk("Ring buffer is empty\n");
} else {
    printk("Got item of type %u value &u of size %u dwords\n",
           my_type, my_value, my_size);
    ...
}

Data bytes are copied out from a byte mode ring buffer by calling ring_buf_get(). For example:

uint8_t my_data[MY_DATA_BYTES];
size_t  ret;

ret = ring_buf_get(&ring_buf, my_data, sizeof(my_data));
if (ret != sizeof(my_size)) {
    /* Less bytes copied. */
} else {
    /* Requested amount of bytes retrieved. */
    ...
}

Data can be retrieved from a byte mode ring buffer by direct operations on the ring buffer’s memory. For example:

uint32_t size;
uint32_t proc_size;
uint8_t *data;
int err;

/* Get buffer within a ring buffer memory. */
size = ring_buf_get_claim(&ring_buf, &data, MY_RING_BUF_BYTES);

/* Work directly on a ring buffer memory. */
proc_size = process(data, size);

/* Indicate amount of data that can be freed. proc_size can be equal or less
 * than size.
 */
err = ring_buf_get_finish(&ring_buf, proc_size);
if (err != 0) {
    /* proc_size exceeds amount of valid data in a ring buffer. */
    ...
}

Configuration Options

Related configuration options:

API Reference

The following ring buffer APIs are provided by include/ring_buffer.h:

group ring_buffer_apis

Defines

RING_BUF_ITEM_DECLARE_POW2(name, pow)

Statically define and initialize a high performance ring buffer.

This macro establishes a ring buffer whose size must be a power of 2; that is, the ring buffer contains 2^pow 32-bit words, where pow is the specified ring buffer size exponent. A high performance ring buffer doesn’t require the use of modulo arithmetic operations to maintain itself.

The ring buffer can be accessed outside the module where it is defined using:

extern struct ring_buf <name>; 

Parameters
  • name: Name of the ring buffer.

  • pow: Ring buffer size exponent.

RING_BUF_ITEM_DECLARE_SIZE(name, size32)

Statically define and initialize a standard ring buffer.

This macro establishes a ring buffer of an arbitrary size. A standard ring buffer uses modulo arithmetic operations to maintain itself.

The ring buffer can be accessed outside the module where it is defined using:

extern struct ring_buf <name>; 

Parameters
  • name: Name of the ring buffer.

  • size32: Size of ring buffer (in 32-bit words).

RING_BUF_DECLARE(name, size8)

Statically define and initialize a ring buffer for byte data.

This macro establishes a ring buffer of an arbitrary size.

The ring buffer can be accessed outside the module where it is defined using:

extern struct ring_buf <name>; 

Parameters
  • name: Name of the ring buffer.

  • size8: Size of ring buffer (in bytes).

Functions

static inline void ring_buf_init(struct ring_buf *buf, uint32_t size, void *data)

Initialize a ring buffer.

This routine initializes a ring buffer, prior to its first use. It is only used for ring buffers not defined using RING_BUF_DECLARE, RING_BUF_ITEM_DECLARE_POW2 or RING_BUF_ITEM_DECLARE_SIZE.

Setting size to a power of 2 establishes a high performance ring buffer that doesn’t require the use of modulo arithmetic operations to maintain itself.

Parameters
  • buf: Address of ring buffer.

  • size: Ring buffer size (in 32-bit words or bytes).

  • data: Ring buffer data area (uint32_t data[size] or uint8_t data[size] for bytes mode).

static inline int ring_buf_is_empty(struct ring_buf *buf)

Determine if a ring buffer is empty.

Return

1 if the ring buffer is empty, or 0 if not.

Parameters
  • buf: Address of ring buffer.

static inline void ring_buf_reset(struct ring_buf *buf)

Reset ring buffer state.

Parameters
  • buf: Address of ring buffer.

static inline uint32_t ring_buf_space_get(struct ring_buf *buf)

Determine free space in a ring buffer.

Return

Ring buffer free space (in 32-bit words or bytes).

Parameters
  • buf: Address of ring buffer.

static inline uint32_t ring_buf_capacity_get(struct ring_buf *buf)

Return ring buffer capacity.

Return

Ring buffer capacity (in 32-bit words or bytes).

Parameters
  • buf: Address of ring buffer.

int ring_buf_item_put(struct ring_buf *buf, uint16_t type, uint8_t value, uint32_t *data, uint8_t size32)

Write a data item to a ring buffer.

This routine writes a data item to ring buffer buf. The data item is an array of 32-bit words (from zero to 1020 bytes in length), coupled with a 16-bit type identifier and an 8-bit integer value.

Warning

Use cases involving multiple writers to the ring buffer must prevent concurrent write operations, either by preventing all writers from being preempted or by using a mutex to govern writes to the ring buffer.

Parameters
  • buf: Address of ring buffer.

  • type: Data item’s type identifier (application specific).

  • value: Data item’s integer value (application specific).

  • data: Address of data item.

  • size32: Data item size (number of 32-bit words).

Return Value
  • 0: Data item was written.

  • -EMSGSIZE: Ring buffer has insufficient free space.

int ring_buf_item_get(struct ring_buf *buf, uint16_t *type, uint8_t *value, uint32_t *data, uint8_t *size32)

Read a data item from a ring buffer.

This routine reads a data item from ring buffer buf. The data item is an array of 32-bit words (up to 1020 bytes in length), coupled with a 16-bit type identifier and an 8-bit integer value.

Warning

Use cases involving multiple reads of the ring buffer must prevent concurrent read operations, either by preventing all readers from being preempted or by using a mutex to govern reads to the ring buffer.

Parameters
  • buf: Address of ring buffer.

  • type: Area to store the data item’s type identifier.

  • value: Area to store the data item’s integer value.

  • data: Area to store the data item.

  • size32: Size of the data item storage area (number of 32-bit chunks).

Return Value
  • 0: Data item was fetched; size32 now contains the number of 32-bit words read into data area data.

  • -EAGAIN: Ring buffer is empty.

  • -EMSGSIZE: Data area data is too small; size32 now contains the number of 32-bit words needed.

uint32_t ring_buf_put_claim(struct ring_buf *buf, uint8_t **data, uint32_t size)

Allocate buffer for writing data to a ring buffer.

With this routine, memory copying can be reduced since internal ring buffer can be used directly by the user. Once data is written to allocated area number of bytes written can be confirmed (see ring_buf_put_finish).

Warning

Use cases involving multiple writers to the ring buffer must prevent concurrent write operations, either by preventing all writers from being preempted or by using a mutex to govern writes to the ring buffer.

Warning

Ring buffer instance should not mix byte access and item access (calls prefixed with ring_buf_item_).

Return

Size of allocated buffer which can be smaller than requested if there is not enough free space or buffer wraps.

Parameters
  • [in] buf: Address of ring buffer.

  • [out] data: Pointer to the address. It is set to a location within ring buffer.

  • [in] size: Requested allocation size (in bytes).

int ring_buf_put_finish(struct ring_buf *buf, uint32_t size)

Indicate number of bytes written to allocated buffers.

Warning

Use cases involving multiple writers to the ring buffer must prevent concurrent write operations, either by preventing all writers from being preempted or by using a mutex to govern writes to the ring buffer.

Warning

Ring buffer instance should not mix byte access and item access (calls prefixed with ring_buf_item_).

Parameters
  • buf: Address of ring buffer.

  • size: Number of valid bytes in the allocated buffers.

Return Value
  • 0: Successful operation.

  • -EINVAL: Provided size exceeds free space in the ring buffer.

uint32_t ring_buf_put(struct ring_buf *buf, const uint8_t *data, uint32_t size)

Write (copy) data to a ring buffer.

This routine writes data to a ring buffer buf.

Warning

Use cases involving multiple writers to the ring buffer must prevent concurrent write operations, either by preventing all writers from being preempted or by using a mutex to govern writes to the ring buffer.

Warning

Ring buffer instance should not mix byte access and item access (calls prefixed with ring_buf_item_).

Parameters
  • buf: Address of ring buffer.

  • data: Address of data.

  • size: Data size (in bytes).

Return Value
  • Number: of bytes written.

uint32_t ring_buf_get_claim(struct ring_buf *buf, uint8_t **data, uint32_t size)

Get address of a valid data in a ring buffer.

With this routine, memory copying can be reduced since internal ring buffer can be used directly by the user. Once data is processed it can be freed using ring_buf_get_finish.

Warning

Use cases involving multiple reads of the ring buffer must prevent concurrent read operations, either by preventing all readers from being preempted or by using a mutex to govern reads to the ring buffer.

Warning

Ring buffer instance should not mix byte access and item access (calls prefixed with ring_buf_item_).

Return

Number of valid bytes in the provided buffer which can be smaller than requested if there is not enough free space or buffer wraps.

Parameters
  • [in] buf: Address of ring buffer.

  • [out] data: Pointer to the address. It is set to a location within ring buffer.

  • [in] size: Requested size (in bytes).

int ring_buf_get_finish(struct ring_buf *buf, uint32_t size)

Indicate number of bytes read from claimed buffer.

Warning

Use cases involving multiple reads of the ring buffer must prevent concurrent read operations, either by preventing all readers from being preempted or by using a mutex to govern reads to the ring buffer.

Warning

Ring buffer instance should not mix byte access and item mode (calls prefixed with ring_buf_item_).

Parameters
  • buf: Address of ring buffer.

  • size: Number of bytes that can be freed.

Return Value
  • 0: Successful operation.

  • -EINVAL: Provided size exceeds valid bytes in the ring buffer.

uint32_t ring_buf_get(struct ring_buf *buf, uint8_t *data, uint32_t size)

Read data from a ring buffer.

This routine reads data from a ring buffer buf.

Warning

Use cases involving multiple reads of the ring buffer must prevent concurrent read operations, either by preventing all readers from being preempted or by using a mutex to govern reads to the ring buffer.

Warning

Ring buffer instance should not mix byte access and item mode (calls prefixed with ring_buf_item_).

Parameters
  • buf: Address of ring buffer.

  • data: Address of the output buffer.

  • size: Data size (in bytes).

Return Value
  • Number: of bytes written to the output buffer.