include/i2s.h - third_party/github/zephyrproject-rtos/zephyr - Git at Google

 /*
  * Copyright (c) 2017 Piotr Mienkowski
  *
  * SPDX-License-Identifier: Apache-2.0
  */

 /**
  * @file
  * @brief Public APIs for the I2S (Inter-IC Sound) bus drivers.
  */

 #ifndef ZEPHYR_INCLUDE_I2S_H_
 #define ZEPHYR_INCLUDE_I2S_H_

 /**
  * @defgroup i2s_interface I2S Interface
  * @ingroup io_interfaces
  * @brief I2S (Inter-IC Sound) Interface
  *
  * The I2S API provides support for the standard I2S interface standard as well
  * as common non-standard extensions such as PCM Short/Long Frame Sync,
  * Left/Right Justified Data Format.
  * @{
  */

 #include <zephyr/types.h>
 #include <device.h>

 #ifdef __cplusplus
 extern "C" {
 #endif

 /*
  * The following #defines are used to configure the I2S controller.
  */


 typedef u8_t i2s_fmt_t;

 /** Data Format bit field position. */
 #define I2S_FMT_DATA_FORMAT_SHIFT           0
 /** Data Format bit field mask. */
 #define I2S_FMT_DATA_FORMAT_MASK            (0x7 << I2S_FMT_DATA_FORMAT_SHIFT)

 /** @brief Standard I2S Data Format.
  *
  * Serial data is transmitted in two's complement with the MSB first. Both
  * Word Select (WS) and Serial Data (SD) signals are sampled on the rising edge
  * of the clock signal (SCK). The MSB is always sent one clock period after the
  * WS changes. Left channel data are sent first indicated by WS = 0, followed
  * by right channel data indicated by WS = 1.
  *
  *        -. .-. .-. .-. .-. .-. .-. .-. .-. .-. .-. .-. .-. .-. .-. .-. .-. .-.
  *     SCK '-' '-' '-' '-' '-' '-' '-' '-' '-' '-' '-' '-' '-' '-' '-' '-' '-' '
  *        -.                               .-------------------------------.
  *     WS  '-------------------------------'                               '----
  *        -.---.---.---.---.---.---.---.---.---.---.---.---.---.---.---.---.---.
  *     SD  |   |MSB|   |...|   |LSB| x |...| x |MSB|   |...|   |LSB| x |...| x |
  *        -'---'---'---'---'---'---'---'---'---'---'---'---'---'---'---'---'---'
  *             | Left channel                  | Right channel                 |
  */
 #define I2S_FMT_DATA_FORMAT_I2S             (0 << I2S_FMT_DATA_FORMAT_SHIFT)

 /** @brief PCM Short Frame Sync Data Format.
  *
  * Serial data is transmitted in two's complement with the MSB first. Both
  * Word Select (WS) and Serial Data (SD) signals are sampled on the falling edge
  * of the clock signal (SCK). The falling edge of the frame sync signal (WS)
  * indicates the start of the PCM word. The frame sync is one clock cycle long.
  * An arbitrary number of data words can be sent in one frame.
  *
  *          .-. .-. .-. .-. .-. .-. .-. .-. .-. .-. .-. .-. .-. .-. .-. .-. .-.
  *     SCK -' '-' '-' '-' '-' '-' '-' '-' '-' '-' '-' '-' '-' '-' '-' '-' '-' '-
  *          .---.                                                       .---.
  *     WS  -'   '-                                                     -'   '-
  *         -.---.---.---.---.---.---.---.---.---.---.---.---.---.---.---.---.---
  *     SD   |   |MSB|   |...|   |LSB|MSB|   |...|   |LSB|MSB|   |...|   |LSB|
  *         -'---'---'---'---'---'---'---'---'---'---'---'---'---'---'---'---'---
  *              | Word 1            | Word 2            | Word 3  |  Word n |
  */
 #define I2S_FMT_DATA_FORMAT_PCM_SHORT       (1 << I2S_FMT_DATA_FORMAT_SHIFT)

 /** @brief PCM Long Frame Sync Data Format.
  *
  * Serial data is transmitted in two's complement with the MSB first. Both
  * Word Select (WS) and Serial Data (SD) signals are sampled on the falling edge
  * of the clock signal (SCK). The rising edge of the frame sync signal (WS)
  * indicates the start of the PCM word. The frame sync has an arbitrary length,
  * however it has to fall before the start of the next frame. An arbitrary
  * number of data words can be sent in one frame.
  *
  *          .-. .-. .-. .-. .-. .-. .-. .-. .-. .-. .-. .-. .-. .-. .-. .-. .-.
  *     SCK -' '-' '-' '-' '-' '-' '-' '-' '-' '-' '-' '-' '-' '-' '-' '-' '-' '-
  *              .--- ---.    ---.        ---.                               .---
  *     WS      -'       '-      '-          '-                             -'
  *         -.---.---.---.---.---.---.---.---.---.---.---.---.---.---.---.---.---
  *     SD   |   |MSB|   |...|   |LSB|MSB|   |...|   |LSB|MSB|   |...|   |LSB|
  *         -'---'---'---'---'---'---'---'---'---'---'---'---'---'---'---'---'---
  *              | Word 1            | Word 2            | Word 3  |  Word n |
  */
 #define I2S_FMT_DATA_FORMAT_PCM_LONG        (2 << I2S_FMT_DATA_FORMAT_SHIFT)

 /**
  * @brief Left Justified Data Format.
  *
  * Serial data is transmitted in two's complement with the MSB first. Both
  * Word Select (WS) and Serial Data (SD) signals are sampled on the rising edge
  * of the clock signal (SCK). The bits within the data word are left justified
  * such that the MSB is always sent in the clock period following the WS
  * transition. Left channel data are sent first indicated by WS = 1, followed
  * by right channel data indicated by WS = 0.
  *
  *          .-. .-. .-. .-. .-. .-. .-. .-. .-. .-. .-. .-. .-. .-. .-. .-. .-.
  *     SCK -' '-' '-' '-' '-' '-' '-' '-' '-' '-' '-' '-' '-' '-' '-' '-' '-' '-
  *            .-------------------------------.                               .-
  *     WS  ---'                               '-------------------------------'
  *         ---.---.---.---.---.---.---.---.---.---.---.---.---.---.---.---.---.-
  *     SD     |MSB|   |...|   |LSB| x |...| x |MSB|   |...|   |LSB| x |...| x |
  *         ---'---'---'---'---'---'---'---'---'---'---'---'---'---'---'---'---'-
  *            | Left channel                  | Right channel                 |
  */
 #define I2S_FMT_DATA_FORMAT_LEFT_JUSTIFIED  (3 << I2S_FMT_DATA_FORMAT_SHIFT)

 /**
  * @brief Right Justified Data Format.
  *
  * Serial data is transmitted in two's complement with the MSB first. Both
  * Word Select (WS) and Serial Data (SD) signals are sampled on the rising edge
  * of the clock signal (SCK). The bits within the data word are right justified
  * such that the LSB is always sent in the clock period preceding the WS
  * transition. Left channel data are sent first indicated by WS = 1, followed
  * by right channel data indicated by WS = 0.
  *
  *          .-. .-. .-. .-. .-. .-. .-. .-. .-. .-. .-. .-. .-. .-. .-. .-. .-.
  *     SCK -' '-' '-' '-' '-' '-' '-' '-' '-' '-' '-' '-' '-' '-' '-' '-' '-' '-
  *            .-------------------------------.                               .-
  *     WS  ---'                               '-------------------------------'
  *         ---.---.---.---.---.---.---.---.---.---.---.---.---.---.---.---.---.-
  *     SD     | x |...| x |MSB|   |...|   |LSB| x |...| x |MSB|   |...|   |LSB|
  *         ---'---'---'---'---'---'---'---'---'---'---'---'---'---'---'---'---'-
  *            | Left channel                  | Right channel                 |
  */
 #define I2S_FMT_DATA_FORMAT_RIGHT_JUSTIFIED (4 << I2S_FMT_DATA_FORMAT_SHIFT)

 /** Send MSB first */
 #define I2S_FMT_DATA_ORDER_MSB              (0 << 3)
 /** Send LSB first */
 #define I2S_FMT_DATA_ORDER_LSB              BIT(3)
 /** Invert bit ordering, send LSB first */
 #define I2S_FMT_DATA_ORDER_INV              I2S_FMT_DATA_ORDER_LSB

 /** Data Format bit field position. */
 #define I2S_FMT_CLK_FORMAT_SHIFT           4
 /** Data Format bit field mask. */
 #define I2S_FMT_CLK_FORMAT_MASK            (0x3 << I2S_FMT_CLK_FORMAT_SHIFT)

 /** Invert bit clock */
 #define I2S_FMT_BIT_CLK_INV                 BIT(4)
 /** Invert frame clock */
 #define I2S_FMT_FRAME_CLK_INV               BIT(5)

 /** NF represents "Normal Frame" whereas IF represents "Inverted Frame"
  *  NB represents "Normal Bit Clk" whereas IB represents "Inverted Bit clk"
  */
 #define I2S_FMT_CLK_NF_NB		(0 << I2S_FMT_CLK_FORMAT_SHIFT)
 #define I2S_FMT_CLK_NF_IB		(1 << I2S_FMT_CLK_FORMAT_SHIFT)
 #define I2S_FMT_CLK_IF_NB		(2 << I2S_FMT_CLK_FORMAT_SHIFT)
 #define I2S_FMT_CLK_IF_IB		(3 << I2S_FMT_CLK_FORMAT_SHIFT)

 typedef u8_t i2s_opt_t;

 /** Run bit clock continuously */
 #define I2S_OPT_BIT_CLK_CONT                (0 << 0)
 /** Run bit clock when sending data only */
 #define I2S_OPT_BIT_CLK_GATED               BIT(0)
 /** I2S driver is bit clock master */
 #define I2S_OPT_BIT_CLK_MASTER              (0 << 1)
 /** I2S driver is bit clock slave */
 #define I2S_OPT_BIT_CLK_SLAVE               BIT(1)
 /** I2S driver is frame clock master */
 #define I2S_OPT_FRAME_CLK_MASTER            (0 << 2)
 /** I2S driver is frame clock slave */
 #define I2S_OPT_FRAME_CLK_SLAVE             BIT(2)

 /** @brief Loop back mode.
  *
  * In loop back mode RX input will be connected internally to TX output.
  * This is used primarily for testing.
  */
 #define I2S_OPT_LOOPBACK                    BIT(7)

 /** @brief Ping pong mode
  *
  * In ping pong mode TX output will keep alternating between a ping buffer
  * and a pong buffer. This is normally used in audio streams when one buffer
  * is being populated while the other is being played (DMAed) and vice versa.
  * So, in this mode, 2 sets of buffers fixed in size are used. Static Arrays
  * are used to achieve this and hence they are never freed.
  */
 #define I2S_OPT_PINGPONG                    BIT(6)

 /**
  * @brief I2C Direction
  */
 enum i2s_dir {
 	/** Receive data */
 	I2S_DIR_RX,
 	/** Transmit data */
 	I2S_DIR_TX,
 };

 /** Interface state */
 enum i2s_state {
 	/** @brief The interface is not ready.
 	 *
 	 * The interface was initialized but is not yet ready to receive /
 	 * transmit data. Call i2s_configure() to configure interface and change
 	 * its state to READY.
 	 */
 	I2S_STATE_NOT_READY,
 	/** The interface is ready to receive / transmit data. */
 	I2S_STATE_READY,
 	/** The interface is receiving / transmitting data. */
 	I2S_STATE_RUNNING,
 	/** The interface is draining its transmit queue. */
 	I2S_STATE_STOPPING,
 	/** TX buffer underrun or RX buffer overrun has occurred. */
 	I2S_STATE_ERROR,
 };

 /** Trigger command */
 enum i2s_trigger_cmd {
 	/** @brief Start the transmission / reception of data.
 	 *
 	 * If I2S_DIR_TX is set some data has to be queued for transmission by
 	 * the i2s_write() function. This trigger can be used in READY state
 	 * only and changes the interface state to RUNNING.
 	 */
 	I2S_TRIGGER_START,
 	/** @brief Stop the transmission / reception of data.
 	 *
 	 * Stop the transmission / reception of data at the end of the current
 	 * memory block. This trigger can be used in RUNNING state only and at
 	 * first changes the interface state to STOPPING. When the current TX /
 	 * RX block is transmitted / received the state is changed to READY.
 	 * Subsequent START trigger will resume transmission / reception where
 	 * it stopped.
 	 */
 	I2S_TRIGGER_STOP,
 	/** @brief Empty the transmit queue.
 	 *
 	 * Send all data in the transmit queue and stop the transmission.
 	 * If the trigger is applied to the RX queue it has the same effect as
 	 * I2S_TRIGGER_STOP. This trigger can be used in RUNNING state only and
 	 * at first changes the interface state to STOPPING. When all TX blocks
 	 * are transmitted the state is changed to READY.
 	 */
 	I2S_TRIGGER_DRAIN,
 	/** @brief Discard the transmit / receive queue.
 	 *
 	 * Stop the transmission / reception immediately and discard the
 	 * contents of the respective queue. This trigger can be used in any
 	 * state other than NOT_READY and changes the interface state to READY.
 	 */
 	I2S_TRIGGER_DROP,
 	/** @brief Prepare the queues after underrun/overrun error has occurred.
 	 *
 	 * This trigger can be used in ERROR state only and changes the
 	 * interface state to READY.
 	 */
 	I2S_TRIGGER_PREPARE,
 };

 /** @struct i2s_config
  * @brief Interface configuration options.
  *
  * Memory slab pointed to by the mem_slab field has to be defined and
  * initialized by the user. For I2S driver to function correctly number of
  * memory blocks in a slab has to be at least 2 per queue. Size of the memory
  * block should be multiple of frame_size where frame_size = (channels *
  * word_size_bytes). As an example 16 bit word will occupy 2 bytes, 24 or 32
  * bit word will occupy 4 bytes.
  *
  * Please check Zephyr Kernel Primer for more information on memory slabs.
  *
  * @remark When I2S data format is selected parameter channels is ignored,
  * number of words in a frame is always 2.
  *
  * @param word_size Number of bits representing one data word.
  * @param channels Number of words per frame.
  * @param format Data stream format as defined by I2S_FMT_* constants.
  * @param options Configuration options as defined by I2S_OPT_* constants.
  * @param frame_clk_freq Frame clock (WS) frequency, this is sampling rate.
  * @param mem_slab memory slab to store RX/TX data.
  * @param block_size Size of one RX/TX memory block (buffer) in bytes.
  * @param timeout Read/Write timeout. Number of milliseconds to wait in case TX
  *        queue is full, RX queue is empty or one of the special values
  *        K_NO_WAIT, K_FOREVER.
  */
 struct i2s_config {
 	u8_t word_size;
 	u8_t channels;
 	i2s_fmt_t format;
 	i2s_opt_t options;
 	u32_t frame_clk_freq;
 	struct k_mem_slab *mem_slab;
 	size_t block_size;
 	s32_t timeout;
 };

 /**
  * @cond INTERNAL_HIDDEN
  *
  * For internal use only, skip these in public documentation.
  */
 struct i2s_driver_api {
 	int (*configure)(struct device *dev, enum i2s_dir dir,
 			 struct i2s_config *cfg);
 	struct i2s_config *(*config_get)(struct device *dev,
 					 enum i2s_dir dir);
 	int (*read)(struct device *dev, void **mem_block, size_t *size);
 	int (*write)(struct device *dev, void *mem_block, size_t size);
 	int (*trigger)(struct device *dev, enum i2s_dir dir,
 		       enum i2s_trigger_cmd cmd);
 };
 /**
  * @endcond
  */

 /**
  * @brief Configure operation of a host I2S controller.
  *
  * The dir parameter specifies if Transmit (TX) or Receive (RX) direction
  * will be configured by data provided via cfg parameter.
  *
  * The function can be called in NOT_READY or READY state only. If executed
  * successfully the function will change the interface state to READY.
  *
  * If the function is called with the parameter cfg->frame_clk_freq set to 0
  * the interface state will be changed to NOT_READY.
  *
  * @param dev Pointer to the device structure for the driver instance.
  * @param dir Stream direction: RX or TX as defined by I2S_DIR_*
  * @param cfg Pointer to the structure containing configuration parameters.
  *
  * @retval 0 If successful.
  * @retval -EINVAL Invalid argument.
  */
 __syscall int i2s_configure(struct device *dev, enum i2s_dir dir,
 			    struct i2s_config *cfg);

 static inline int z_impl_i2s_configure(struct device *dev, enum i2s_dir dir,
 				      struct i2s_config *cfg)
 {
 	const struct i2s_driver_api *api = dev->driver_api;

 	return api->configure(dev, dir, cfg);
 }

 /**
  * @brief Fetch configuration information of a host I2S controller
  *
  * @param dev Pointer to the device structure for the driver instance
  * @param dir Stream direction: RX or TX as defined by I2S_DIR_*
  * @retval Pointer to the structure containing configuration parameters,
  *         or NULL if un-configured
  */
 static inline struct i2s_config *i2s_config_get(struct device *dev,
 						enum i2s_dir dir)
 {
 	const struct i2s_driver_api *api = dev->driver_api;

 	return api->config_get(dev, dir);
 }

 /**
  * @brief Read data from the RX queue.
  *
  * Data received by the I2S interface is stored in the RX queue consisting of
  * memory blocks preallocated by this function from rx_mem_slab (as defined by
  * i2s_configure). Ownership of the RX memory block is passed on to the user
  * application which has to release it.
  *
  * The data is read in chunks equal to the size of the memory block. If the
  * interface is in READY state the number of bytes read can be smaller.
  *
  * If there is no data in the RX queue the function will block waiting for
  * the next RX memory block to fill in. This operation can timeout as defined
  * by i2s_configure. If the timeout value is set to K_NO_WAIT the function
  * is non-blocking.
  *
  * Reading from the RX queue is possible in any state other than NOT_READY.
  * If the interface is in the ERROR state it is still possible to read all the
  * valid data stored in RX queue. Afterwards the function will return -EIO
  * error.
  *
  * @param dev Pointer to the device structure for the driver instance.
  * @param mem_block Pointer to the RX memory block containing received data.
  * @param size Pointer to the variable storing the number of bytes read.
  *
  * @retval 0 If successful.
  * @retval -EIO The interface is in NOT_READY or ERROR state and there are no
  *         more data blocks in the RX queue.
  * @retval -EBUSY Returned without waiting.
  * @retval -EAGAIN Waiting period timed out.
  */
 static inline int i2s_read(struct device *dev, void **mem_block,
 				 size_t *size)
 {
 	const struct i2s_driver_api *api = dev->driver_api;

 	return api->read(dev, mem_block, size);
 }

 /**
  * @brief Read data from the RX queue into a provided buffer
  *
  * Data received by the I2S interface is stored in the RX queue consisting of
  * memory blocks preallocated by this function from rx_mem_slab (as defined by
  * i2s_configure). Calling this function removes one block from the queue
  * which is copied into the provided buffer and then freed.
  *
  * The provided buffer must be large enough to contain a full memory block
  * of data, which is parameterized for the channel via i2s_configure().
  *
  * This function is otherwise equivalent to i2s_read().
  *
  * @param dev Pointer to the device structure for the driver instance.
  * @param buf Destination buffer for read data, which must be at least the
  *            as large as the configured memory block size for the RX channel.
  * @param size Pointer to the variable storing the number of bytes read.
  *
  * @retval 0 If successful.
  * @retval -EIO The interface is in NOT_READY or ERROR state and there are no
  *         more data blocks in the RX queue.
  * @retval -EBUSY Returned without waiting.
  * @retval -EAGAIN Waiting period timed out.
  */
 __syscall int i2s_buf_read(struct device *dev, void *buf, size_t *size);

 /**
  * @brief Write data to the TX queue.
  *
  * Data to be sent by the I2S interface is stored first in the TX queue. TX
  * queue consists of memory blocks preallocated by the user from tx_mem_slab
  * (as defined by i2s_configure). This function takes ownership of the memory
  * block and will release it when all data are transmitted.
  *
  * If there are no free slots in the TX queue the function will block waiting
  * for the next TX memory block to be send and removed from the queue. This
  * operation can timeout as defined by i2s_configure. If the timeout value is
  * set to K_NO_WAIT the function is non-blocking.
  *
  * Writing to the TX queue is only possible if the interface is in READY or
  * RUNNING state.
  *
  * @param dev Pointer to the device structure for the driver instance.
  * @param mem_block Pointer to the TX memory block containing data to be sent.
  * @param size Number of bytes to write. This value has to be equal or smaller
  *        than the size of the memory block.
  *
  * @retval 0 If successful.
  * @retval -EIO The interface is not in READY or RUNNING state.
  * @retval -EBUSY Returned without waiting.
  * @retval -EAGAIN Waiting period timed out.
  */
 static inline int i2s_write(struct device *dev, void *mem_block, size_t size)
 {
 	const struct i2s_driver_api *api = dev->driver_api;

 	return api->write(dev, mem_block, size);
 }

 /**
  * @brief Write data to the TX queue from a provided buffer
  *
  * This function acquires a memory block from the I2S channel TX queue
  * and copies the provided data buffer into it. It is otherwise equivalent
  * to i2s_write().
  *
  * @param dev Pointer to the device structure for the driver instance.
  * @param buf Pointer to a buffer containing the data to transmit.
  * @param size Number of bytes to write. This value has to be equal or smaller
  *        than the size of the channel's TX memory block configuration.
  *
  * @retval 0 If successful.
  * @retval -EIO The interface is not in READY or RUNNING state.
  * @retval -EBUSY Returned without waiting.
  * @retval -EAGAIN Waiting period timed out.
  * @retval -ENOMEM No memory in TX slab queue.
  * @retval -EINVAL Size parameter larger than TX queue memory block.
  */
 __syscall int i2s_buf_write(struct device *dev, void *buf, size_t size);

 /**
  * @brief Send a trigger command.
  *
  * @param dev Pointer to the device structure for the driver instance.
  * @param dir Stream direction: RX or TX.
  * @param cmd Trigger command.
  *
  * @retval 0 If successful.
  * @retval -EINVAL Invalid argument.
  * @retval -EIO The trigger cannot be executed in the current state or a DMA
  *         channel cannot be allocated.
  * @retval -ENOMEM RX/TX memory block not available.
  */
 __syscall int i2s_trigger(struct device *dev, enum i2s_dir dir,
 			  enum i2s_trigger_cmd cmd);

 static inline int z_impl_i2s_trigger(struct device *dev, enum i2s_dir dir,
 				    enum i2s_trigger_cmd cmd)
 {
 	const struct i2s_driver_api *api = dev->driver_api;

 	return api->trigger(dev, dir, cmd);
 }

 #include <syscalls/i2s.h>

 #ifdef __cplusplus
 }
 #endif

 /**
  * @}
  */

 #endif /* ZEPHYR_INCLUDE_I2S_H_ */
	/*
	* Copyright (c) 2017 Piotr Mienkowski
	*
	* SPDX-License-Identifier: Apache-2.0
	*/

	/**
	* @file
	* @brief Public APIs for the I2S (Inter-IC Sound) bus drivers.
	*/

	#ifndef ZEPHYR_INCLUDE_I2S_H_
	#define ZEPHYR_INCLUDE_I2S_H_

	/**
	* @defgroup i2s_interface I2S Interface
	* @ingroup io_interfaces
	* @brief I2S (Inter-IC Sound) Interface
	*
	* The I2S API provides support for the standard I2S interface standard as well
	* as common non-standard extensions such as PCM Short/Long Frame Sync,
	* Left/Right Justified Data Format.
	* @{
	*/

	#include <zephyr/types.h>
	#include <device.h>

	#ifdef __cplusplus
	extern "C" {
	#endif

	/*
	* The following #defines are used to configure the I2S controller.
	*/


	typedef u8_t i2s_fmt_t;

	/** Data Format bit field position. */
	#define I2S_FMT_DATA_FORMAT_SHIFT 0
	/** Data Format bit field mask. */
	#define I2S_FMT_DATA_FORMAT_MASK (0x7 << I2S_FMT_DATA_FORMAT_SHIFT)

	/** @brief Standard I2S Data Format.
	*
	* Serial data is transmitted in two's complement with the MSB first. Both
	* Word Select (WS) and Serial Data (SD) signals are sampled on the rising edge
	* of the clock signal (SCK). The MSB is always sent one clock period after the
	* WS changes. Left channel data are sent first indicated by WS = 0, followed
	* by right channel data indicated by WS = 1.
	*
	* -. .-. .-. .-. .-. .-. .-. .-. .-. .-. .-. .-. .-. .-. .-. .-. .-. .-.
	* SCK '-' '-' '-' '-' '-' '-' '-' '-' '-' '-' '-' '-' '-' '-' '-' '-' '-' '
	* -. .-------------------------------.
	* WS '-------------------------------' '----
	* -.---.---.---.---.---.---.---.---.---.---.---.---.---.---.---.---.---.
	* SD \| \|MSB\| \|...\| \|LSB\| x \|...\| x \|MSB\| \|...\| \|LSB\| x \|...\| x \|
	* -'---'---'---'---'---'---'---'---'---'---'---'---'---'---'---'---'---'
	* \| Left channel \| Right channel \|
	*/
	#define I2S_FMT_DATA_FORMAT_I2S (0 << I2S_FMT_DATA_FORMAT_SHIFT)

	/** @brief PCM Short Frame Sync Data Format.
	*
	* Serial data is transmitted in two's complement with the MSB first. Both
	* Word Select (WS) and Serial Data (SD) signals are sampled on the falling edge
	* of the clock signal (SCK). The falling edge of the frame sync signal (WS)
	* indicates the start of the PCM word. The frame sync is one clock cycle long.
	* An arbitrary number of data words can be sent in one frame.
	*
	* .-. .-. .-. .-. .-. .-. .-. .-. .-. .-. .-. .-. .-. .-. .-. .-. .-.
	* SCK -' '-' '-' '-' '-' '-' '-' '-' '-' '-' '-' '-' '-' '-' '-' '-' '-' '-
	* .---. .---.
	* WS -' '- -' '-
	* -.---.---.---.---.---.---.---.---.---.---.---.---.---.---.---.---.---
	* SD \| \|MSB\| \|...\| \|LSB\|MSB\| \|...\| \|LSB\|MSB\| \|...\| \|LSB\|
	* -'---'---'---'---'---'---'---'---'---'---'---'---'---'---'---'---'---
	* \| Word 1 \| Word 2 \| Word 3 \| Word n \|
	*/
	#define I2S_FMT_DATA_FORMAT_PCM_SHORT (1 << I2S_FMT_DATA_FORMAT_SHIFT)

	/** @brief PCM Long Frame Sync Data Format.
	*
	* Serial data is transmitted in two's complement with the MSB first. Both
	* Word Select (WS) and Serial Data (SD) signals are sampled on the falling edge
	* of the clock signal (SCK). The rising edge of the frame sync signal (WS)
	* indicates the start of the PCM word. The frame sync has an arbitrary length,
	* however it has to fall before the start of the next frame. An arbitrary
	* number of data words can be sent in one frame.
	*
	* .-. .-. .-. .-. .-. .-. .-. .-. .-. .-. .-. .-. .-. .-. .-. .-. .-.
	* SCK -' '-' '-' '-' '-' '-' '-' '-' '-' '-' '-' '-' '-' '-' '-' '-' '-' '-
	* .--- ---. ---. ---. .---
	* WS -' '- '- '- -'
	* -.---.---.---.---.---.---.---.---.---.---.---.---.---.---.---.---.---
	* SD \| \|MSB\| \|...\| \|LSB\|MSB\| \|...\| \|LSB\|MSB\| \|...\| \|LSB\|
	* -'---'---'---'---'---'---'---'---'---'---'---'---'---'---'---'---'---
	* \| Word 1 \| Word 2 \| Word 3 \| Word n \|
	*/
	#define I2S_FMT_DATA_FORMAT_PCM_LONG (2 << I2S_FMT_DATA_FORMAT_SHIFT)

	/**
	* @brief Left Justified Data Format.
	*
	* Serial data is transmitted in two's complement with the MSB first. Both
	* Word Select (WS) and Serial Data (SD) signals are sampled on the rising edge
	* of the clock signal (SCK). The bits within the data word are left justified
	* such that the MSB is always sent in the clock period following the WS
	* transition. Left channel data are sent first indicated by WS = 1, followed
	* by right channel data indicated by WS = 0.
	*
	* .-. .-. .-. .-. .-. .-. .-. .-. .-. .-. .-. .-. .-. .-. .-. .-. .-.
	* SCK -' '-' '-' '-' '-' '-' '-' '-' '-' '-' '-' '-' '-' '-' '-' '-' '-' '-
	* .-------------------------------. .-
	* WS ---' '-------------------------------'
	* ---.---.---.---.---.---.---.---.---.---.---.---.---.---.---.---.---.-
	* SD \|MSB\| \|...\| \|LSB\| x \|...\| x \|MSB\| \|...\| \|LSB\| x \|...\| x \|
	* ---'---'---'---'---'---'---'---'---'---'---'---'---'---'---'---'---'-
	* \| Left channel \| Right channel \|
	*/
	#define I2S_FMT_DATA_FORMAT_LEFT_JUSTIFIED (3 << I2S_FMT_DATA_FORMAT_SHIFT)

	/**
	* @brief Right Justified Data Format.
	*
	* Serial data is transmitted in two's complement with the MSB first. Both
	* Word Select (WS) and Serial Data (SD) signals are sampled on the rising edge
	* of the clock signal (SCK). The bits within the data word are right justified
	* such that the LSB is always sent in the clock period preceding the WS
	* transition. Left channel data are sent first indicated by WS = 1, followed
	* by right channel data indicated by WS = 0.
	*
	* .-. .-. .-. .-. .-. .-. .-. .-. .-. .-. .-. .-. .-. .-. .-. .-. .-.
	* SCK -' '-' '-' '-' '-' '-' '-' '-' '-' '-' '-' '-' '-' '-' '-' '-' '-' '-
	* .-------------------------------. .-
	* WS ---' '-------------------------------'
	* ---.---.---.---.---.---.---.---.---.---.---.---.---.---.---.---.---.-
	* SD \| x \|...\| x \|MSB\| \|...\| \|LSB\| x \|...\| x \|MSB\| \|...\| \|LSB\|
	* ---'---'---'---'---'---'---'---'---'---'---'---'---'---'---'---'---'-
	* \| Left channel \| Right channel \|
	*/
	#define I2S_FMT_DATA_FORMAT_RIGHT_JUSTIFIED (4 << I2S_FMT_DATA_FORMAT_SHIFT)

	/** Send MSB first */
	#define I2S_FMT_DATA_ORDER_MSB (0 << 3)
	/** Send LSB first */
	#define I2S_FMT_DATA_ORDER_LSB BIT(3)
	/** Invert bit ordering, send LSB first */
	#define I2S_FMT_DATA_ORDER_INV I2S_FMT_DATA_ORDER_LSB

	/** Data Format bit field position. */
	#define I2S_FMT_CLK_FORMAT_SHIFT 4
	/** Data Format bit field mask. */
	#define I2S_FMT_CLK_FORMAT_MASK (0x3 << I2S_FMT_CLK_FORMAT_SHIFT)

	/** Invert bit clock */
	#define I2S_FMT_BIT_CLK_INV BIT(4)
	/** Invert frame clock */
	#define I2S_FMT_FRAME_CLK_INV BIT(5)

	/** NF represents "Normal Frame" whereas IF represents "Inverted Frame"
	* NB represents "Normal Bit Clk" whereas IB represents "Inverted Bit clk"
	*/
	#define I2S_FMT_CLK_NF_NB (0 << I2S_FMT_CLK_FORMAT_SHIFT)
	#define I2S_FMT_CLK_NF_IB (1 << I2S_FMT_CLK_FORMAT_SHIFT)
	#define I2S_FMT_CLK_IF_NB (2 << I2S_FMT_CLK_FORMAT_SHIFT)
	#define I2S_FMT_CLK_IF_IB (3 << I2S_FMT_CLK_FORMAT_SHIFT)

	typedef u8_t i2s_opt_t;

	/** Run bit clock continuously */
	#define I2S_OPT_BIT_CLK_CONT (0 << 0)
	/** Run bit clock when sending data only */
	#define I2S_OPT_BIT_CLK_GATED BIT(0)
	/** I2S driver is bit clock master */
	#define I2S_OPT_BIT_CLK_MASTER (0 << 1)
	/** I2S driver is bit clock slave */
	#define I2S_OPT_BIT_CLK_SLAVE BIT(1)
	/** I2S driver is frame clock master */
	#define I2S_OPT_FRAME_CLK_MASTER (0 << 2)
	/** I2S driver is frame clock slave */
	#define I2S_OPT_FRAME_CLK_SLAVE BIT(2)

	/** @brief Loop back mode.
	*
	* In loop back mode RX input will be connected internally to TX output.
	* This is used primarily for testing.
	*/
	#define I2S_OPT_LOOPBACK BIT(7)

	/** @brief Ping pong mode
	*
	* In ping pong mode TX output will keep alternating between a ping buffer
	* and a pong buffer. This is normally used in audio streams when one buffer
	* is being populated while the other is being played (DMAed) and vice versa.
	* So, in this mode, 2 sets of buffers fixed in size are used. Static Arrays
	* are used to achieve this and hence they are never freed.
	*/
	#define I2S_OPT_PINGPONG BIT(6)

	/**
	* @brief I2C Direction
	*/
	enum i2s_dir {
	/** Receive data */
	I2S_DIR_RX,
	/** Transmit data */
	I2S_DIR_TX,
	};

	/** Interface state */
	enum i2s_state {
	/** @brief The interface is not ready.
	*
	* The interface was initialized but is not yet ready to receive /
	* transmit data. Call i2s_configure() to configure interface and change
	* its state to READY.
	*/
	I2S_STATE_NOT_READY,
	/** The interface is ready to receive / transmit data. */
	I2S_STATE_READY,
	/** The interface is receiving / transmitting data. */
	I2S_STATE_RUNNING,
	/** The interface is draining its transmit queue. */
	I2S_STATE_STOPPING,
	/** TX buffer underrun or RX buffer overrun has occurred. */
	I2S_STATE_ERROR,
	};

	/** Trigger command */
	enum i2s_trigger_cmd {
	/** @brief Start the transmission / reception of data.
	*
	* If I2S_DIR_TX is set some data has to be queued for transmission by
	* the i2s_write() function. This trigger can be used in READY state
	* only and changes the interface state to RUNNING.
	*/
	I2S_TRIGGER_START,
	/** @brief Stop the transmission / reception of data.
	*
	* Stop the transmission / reception of data at the end of the current
	* memory block. This trigger can be used in RUNNING state only and at
	* first changes the interface state to STOPPING. When the current TX /
	* RX block is transmitted / received the state is changed to READY.
	* Subsequent START trigger will resume transmission / reception where
	* it stopped.
	*/
	I2S_TRIGGER_STOP,
	/** @brief Empty the transmit queue.
	*
	* Send all data in the transmit queue and stop the transmission.
	* If the trigger is applied to the RX queue it has the same effect as
	* I2S_TRIGGER_STOP. This trigger can be used in RUNNING state only and
	* at first changes the interface state to STOPPING. When all TX blocks
	* are transmitted the state is changed to READY.
	*/
	I2S_TRIGGER_DRAIN,
	/** @brief Discard the transmit / receive queue.
	*
	* Stop the transmission / reception immediately and discard the
	* contents of the respective queue. This trigger can be used in any
	* state other than NOT_READY and changes the interface state to READY.
	*/
	I2S_TRIGGER_DROP,
	/** @brief Prepare the queues after underrun/overrun error has occurred.
	*
	* This trigger can be used in ERROR state only and changes the
	* interface state to READY.
	*/
	I2S_TRIGGER_PREPARE,
	};

	/** @struct i2s_config
	* @brief Interface configuration options.
	*
	* Memory slab pointed to by the mem_slab field has to be defined and
	* initialized by the user. For I2S driver to function correctly number of
	* memory blocks in a slab has to be at least 2 per queue. Size of the memory
	* block should be multiple of frame_size where frame_size = (channels *
	* word_size_bytes). As an example 16 bit word will occupy 2 bytes, 24 or 32
	* bit word will occupy 4 bytes.
	*
	* Please check Zephyr Kernel Primer for more information on memory slabs.
	*
	* @remark When I2S data format is selected parameter channels is ignored,
	* number of words in a frame is always 2.
	*
	* @param word_size Number of bits representing one data word.
	* @param channels Number of words per frame.
	* @param format Data stream format as defined by I2S_FMT_* constants.
	* @param options Configuration options as defined by I2S_OPT_* constants.
	* @param frame_clk_freq Frame clock (WS) frequency, this is sampling rate.
	* @param mem_slab memory slab to store RX/TX data.
	* @param block_size Size of one RX/TX memory block (buffer) in bytes.
	* @param timeout Read/Write timeout. Number of milliseconds to wait in case TX
	* queue is full, RX queue is empty or one of the special values
	* K_NO_WAIT, K_FOREVER.
	*/
	struct i2s_config {
	u8_t word_size;
	u8_t channels;
	i2s_fmt_t format;
	i2s_opt_t options;
	u32_t frame_clk_freq;
	struct k_mem_slab *mem_slab;
	size_t block_size;
	s32_t timeout;
	};

	/**
	* @cond INTERNAL_HIDDEN
	*
	* For internal use only, skip these in public documentation.
	*/
	struct i2s_driver_api {
	int (configure)(struct device dev, enum i2s_dir dir,
	struct i2s_config *cfg);
	struct i2s_config (config_get)(struct device *dev,
	enum i2s_dir dir);
	int (read)(struct device dev, void *mem_block, size_t size);
	int (write)(struct device dev, void *mem_block, size_t size);
	int (trigger)(struct device dev, enum i2s_dir dir,
	enum i2s_trigger_cmd cmd);
	};
	/**
	* @endcond
	*/

	/**
	* @brief Configure operation of a host I2S controller.
	*
	* The dir parameter specifies if Transmit (TX) or Receive (RX) direction
	* will be configured by data provided via cfg parameter.
	*
	* The function can be called in NOT_READY or READY state only. If executed
	* successfully the function will change the interface state to READY.
	*
	* If the function is called with the parameter cfg->frame_clk_freq set to 0
	* the interface state will be changed to NOT_READY.
	*
	* @param dev Pointer to the device structure for the driver instance.
	* @param dir Stream direction: RX or TX as defined by I2S_DIR_*
	* @param cfg Pointer to the structure containing configuration parameters.
	*
	* @retval 0 If successful.
	* @retval -EINVAL Invalid argument.
	*/
	__syscall int i2s_configure(struct device *dev, enum i2s_dir dir,
	struct i2s_config *cfg);

	static inline int z_impl_i2s_configure(struct device *dev, enum i2s_dir dir,
	struct i2s_config *cfg)
	{
	const struct i2s_driver_api *api = dev->driver_api;

	return api->configure(dev, dir, cfg);
	}

	/**
	* @brief Fetch configuration information of a host I2S controller
	*
	* @param dev Pointer to the device structure for the driver instance
	* @param dir Stream direction: RX or TX as defined by I2S_DIR_*
	* @retval Pointer to the structure containing configuration parameters,
	* or NULL if un-configured
	*/
	static inline struct i2s_config i2s_config_get(struct device dev,
	enum i2s_dir dir)
	{
	const struct i2s_driver_api *api = dev->driver_api;

	return api->config_get(dev, dir);
	}

	/**
	* @brief Read data from the RX queue.
	*
	* Data received by the I2S interface is stored in the RX queue consisting of
	* memory blocks preallocated by this function from rx_mem_slab (as defined by
	* i2s_configure). Ownership of the RX memory block is passed on to the user
	* application which has to release it.
	*
	* The data is read in chunks equal to the size of the memory block. If the
	* interface is in READY state the number of bytes read can be smaller.
	*
	* If there is no data in the RX queue the function will block waiting for
	* the next RX memory block to fill in. This operation can timeout as defined
	* by i2s_configure. If the timeout value is set to K_NO_WAIT the function
	* is non-blocking.
	*
	* Reading from the RX queue is possible in any state other than NOT_READY.
	* If the interface is in the ERROR state it is still possible to read all the
	* valid data stored in RX queue. Afterwards the function will return -EIO
	* error.
	*
	* @param dev Pointer to the device structure for the driver instance.
	* @param mem_block Pointer to the RX memory block containing received data.
	* @param size Pointer to the variable storing the number of bytes read.
	*
	* @retval 0 If successful.
	* @retval -EIO The interface is in NOT_READY or ERROR state and there are no
	* more data blocks in the RX queue.
	* @retval -EBUSY Returned without waiting.
	* @retval -EAGAIN Waiting period timed out.
	*/
	static inline int i2s_read(struct device dev, void *mem_block,
	size_t *size)
	{
	const struct i2s_driver_api *api = dev->driver_api;

	return api->read(dev, mem_block, size);
	}

	/**
	* @brief Read data from the RX queue into a provided buffer
	*
	* Data received by the I2S interface is stored in the RX queue consisting of
	* memory blocks preallocated by this function from rx_mem_slab (as defined by
	* i2s_configure). Calling this function removes one block from the queue
	* which is copied into the provided buffer and then freed.
	*
	* The provided buffer must be large enough to contain a full memory block
	* of data, which is parameterized for the channel via i2s_configure().
	*
	* This function is otherwise equivalent to i2s_read().
	*
	* @param dev Pointer to the device structure for the driver instance.
	* @param buf Destination buffer for read data, which must be at least the
	* as large as the configured memory block size for the RX channel.
	* @param size Pointer to the variable storing the number of bytes read.
	*
	* @retval 0 If successful.
	* @retval -EIO The interface is in NOT_READY or ERROR state and there are no
	* more data blocks in the RX queue.
	* @retval -EBUSY Returned without waiting.
	* @retval -EAGAIN Waiting period timed out.
	*/
	__syscall int i2s_buf_read(struct device dev, void buf, size_t *size);

	/**
	* @brief Write data to the TX queue.
	*
	* Data to be sent by the I2S interface is stored first in the TX queue. TX
	* queue consists of memory blocks preallocated by the user from tx_mem_slab
	* (as defined by i2s_configure). This function takes ownership of the memory
	* block and will release it when all data are transmitted.
	*
	* If there are no free slots in the TX queue the function will block waiting
	* for the next TX memory block to be send and removed from the queue. This
	* operation can timeout as defined by i2s_configure. If the timeout value is
	* set to K_NO_WAIT the function is non-blocking.
	*
	* Writing to the TX queue is only possible if the interface is in READY or
	* RUNNING state.
	*
	* @param dev Pointer to the device structure for the driver instance.
	* @param mem_block Pointer to the TX memory block containing data to be sent.
	* @param size Number of bytes to write. This value has to be equal or smaller
	* than the size of the memory block.
	*
	* @retval 0 If successful.
	* @retval -EIO The interface is not in READY or RUNNING state.
	* @retval -EBUSY Returned without waiting.
	* @retval -EAGAIN Waiting period timed out.
	*/
	static inline int i2s_write(struct device dev, void mem_block, size_t size)
	{
	const struct i2s_driver_api *api = dev->driver_api;

	return api->write(dev, mem_block, size);
	}

	/**
	* @brief Write data to the TX queue from a provided buffer
	*
	* This function acquires a memory block from the I2S channel TX queue
	* and copies the provided data buffer into it. It is otherwise equivalent
	* to i2s_write().
	*
	* @param dev Pointer to the device structure for the driver instance.
	* @param buf Pointer to a buffer containing the data to transmit.
	* @param size Number of bytes to write. This value has to be equal or smaller
	* than the size of the channel's TX memory block configuration.
	*
	* @retval 0 If successful.
	* @retval -EIO The interface is not in READY or RUNNING state.
	* @retval -EBUSY Returned without waiting.
	* @retval -EAGAIN Waiting period timed out.
	* @retval -ENOMEM No memory in TX slab queue.
	* @retval -EINVAL Size parameter larger than TX queue memory block.
	*/
	__syscall int i2s_buf_write(struct device dev, void buf, size_t size);

	/**
	* @brief Send a trigger command.
	*
	* @param dev Pointer to the device structure for the driver instance.
	* @param dir Stream direction: RX or TX.
	* @param cmd Trigger command.
	*
	* @retval 0 If successful.
	* @retval -EINVAL Invalid argument.
	* @retval -EIO The trigger cannot be executed in the current state or a DMA
	* channel cannot be allocated.
	* @retval -ENOMEM RX/TX memory block not available.
	*/
	__syscall int i2s_trigger(struct device *dev, enum i2s_dir dir,
	enum i2s_trigger_cmd cmd);

	static inline int z_impl_i2s_trigger(struct device *dev, enum i2s_dir dir,
	enum i2s_trigger_cmd cmd)
	{
	const struct i2s_driver_api *api = dev->driver_api;

	return api->trigger(dev, dir, cmd);
	}

	#include <syscalls/i2s.h>

	#ifdef __cplusplus
	}
	#endif

	/**
	* @}
	*/

	#endif /* ZEPHYR_INCLUDE_I2S_H_ */