src/rp2_common/hardware_i2c/include/hardware/i2c.h - third_party/github/raspberrypi/pico-sdk - Git at Google

 /*
  * Copyright (c) 2020 Raspberry Pi (Trading) Ltd.
  *
  * SPDX-License-Identifier: BSD-3-Clause
  */

 #ifndef _HARDWARE_I2C_H
 #define _HARDWARE_I2C_H

 #include "pico.h"
 #include "pico/time.h"
 #include "hardware/structs/i2c.h"

 // PICO_CONFIG: PARAM_ASSERTIONS_ENABLED_I2C, Enable/disable assertions in the I2C module, type=bool, default=0, group=hardware_i2c
 #ifndef PARAM_ASSERTIONS_ENABLED_I2C
 #define PARAM_ASSERTIONS_ENABLED_I2C 0
 #endif

 #ifdef __cplusplus
 extern "C" {
 #endif

 /** \file hardware/i2c.h
  *  \defgroup hardware_i2c hardware_i2c
  *
  * I2C Controller API
  *
  * The I2C bus is a two-wire serial interface, consisting of a serial data line SDA and a serial clock SCL. These wires carry
  * information between the devices connected to the bus. Each device is recognized by a unique address and can operate as
  * either a “transmitter” or “receiver”, depending on the function of the device. Devices can also be considered as masters or
  * slaves when performing data transfers. A master is a device that initiates a data transfer on the bus and generates the
  * clock signals to permit that transfer. At that time, any device addressed is considered a slave.
  *
  * This API allows the controller to be set up as a master or a slave using the \ref i2c_set_slave_mode function.
  *
  * The external pins of each controller are connected to GPIO pins as defined in the GPIO muxing table in the datasheet. The muxing options
  * give some IO flexibility, but each controller external pin should be connected to only one GPIO.
  *
  * Note that the controller does NOT support High speed mode or Ultra-fast speed mode, the fastest operation being fast mode plus
  * at up to 1000Kb/s.
  *
  * See the datasheet for more information on the I2C controller and its usage.
  *
  * \subsection i2c_example Example
  * \addtogroup hardware_i2c
  * \include bus_scan.c
  */

 typedef struct i2c_inst i2c_inst_t;

 /** The I2C identifiers for use in I2C functions.
  *
  * e.g. i2c_init(i2c0, 48000)
  *
  *  \ingroup hardware_i2c
  * @{
  */
 extern i2c_inst_t i2c0_inst;
 extern i2c_inst_t i2c1_inst;

 #define i2c0 (&i2c0_inst) ///< Identifier for I2C HW Block 0
 #define i2c1 (&i2c1_inst) ///< Identifier for I2C HW Block 1

 /** @} */

 // ----------------------------------------------------------------------------
 // Setup

 /*! \brief   Initialise the I2C HW block
  *  \ingroup hardware_i2c
  *
  * Put the I2C hardware into a known state, and enable it. Must be called
  * before other functions. By default, the I2C is configured to operate as a
  * master.
  *
  * The I2C bus frequency is set as close as possible to requested, and
  * the return actual rate set is returned
  *
  * \param i2c Either \ref i2c0 or \ref i2c1
  * \param baudrate Baudrate in Hz (e.g. 100kHz is 100000)
  * \return Actual set baudrate
  */
 uint i2c_init(i2c_inst_t *i2c, uint baudrate);

 /*! \brief   Disable the I2C HW block
  *  \ingroup hardware_i2c
  *
  * \param i2c Either \ref i2c0 or \ref i2c1
  *
  * Disable the I2C again if it is no longer used. Must be reinitialised before
  * being used again.
  */
 void i2c_deinit(i2c_inst_t *i2c);

 /*! \brief  Set I2C baudrate
  *  \ingroup hardware_i2c
  *
  * Set I2C bus frequency as close as possible to requested, and return actual
  * rate set.
  * Baudrate may not be as exactly requested due to clocking limitations.
  *
  * \param i2c Either \ref i2c0 or \ref i2c1
  * \param baudrate Baudrate in Hz (e.g. 100kHz is 100000)
  * \return Actual set baudrate
  */
 uint i2c_set_baudrate(i2c_inst_t *i2c, uint baudrate);

 /*! \brief  Set I2C port to slave mode
  *  \ingroup hardware_i2c
  *
  * \param i2c Either \ref i2c0 or \ref i2c1
  * \param slave true to use slave mode, false to use master mode
  * \param addr If \p slave is true, set the slave address to this value
  */
 void i2c_set_slave_mode(i2c_inst_t *i2c, bool slave, uint8_t addr);

 // ----------------------------------------------------------------------------
 // Generic input/output

 struct i2c_inst {
     i2c_hw_t *hw;
     bool restart_on_next;
 };

 /*! \brief Convert I2c instance to hardware instance number
  *  \ingroup hardware_i2c
  *
  * \param i2c I2C instance
  * \return Number of UART, 0 or 1.
  */
 static inline uint i2c_hw_index(i2c_inst_t *i2c) {
     invalid_params_if(I2C, i2c != i2c0 && i2c != i2c1);
     return i2c == i2c1 ? 1 : 0;
 }

 static inline i2c_hw_t *i2c_get_hw(i2c_inst_t *i2c) {
     i2c_hw_index(i2c); // check it is a hw i2c
     return i2c->hw;
 }

 /*! \brief Attempt to write specified number of bytes to address, blocking until the specified absolute time is reached.
  *  \ingroup hardware_i2c
  *
  * \param i2c Either \ref i2c0 or \ref i2c1
  * \param addr Address of device to write to
  * \param src Pointer to data to send
  * \param len Length of data in bytes to send
  * \param nostop  If true, master retains control of the bus at the end of the transfer (no Stop is issued),
  *           and the next transfer will begin with a Restart rather than a Start.
  * \param until The absolute time that the block will wait until the entire transaction is complete. Note, an individual timeout of
  *           this value divided by the length of data is applied for each byte transfer, so if the first or subsequent
  *           bytes fails to transfer within that sub timeout, the function will return with an error.
  *
  * \return Number of bytes written, or PICO_ERROR_GENERIC if address not acknowledged, no device present, or PICO_ERROR_TIMEOUT if a timeout occurred.
  */
 int i2c_write_blocking_until(i2c_inst_t *i2c, uint8_t addr, const uint8_t *src, size_t len, bool nostop, absolute_time_t until);

 /*! \brief  Attempt to read specified number of bytes from address, blocking until the specified absolute time is reached.
  *  \ingroup hardware_i2c
  *
  * \param i2c Either \ref i2c0 or \ref i2c1
  * \param addr Address of device to read from
  * \param dst Pointer to buffer to receive data
  * \param len Length of data in bytes to receive
  * \param nostop  If true, master retains control of the bus at the end of the transfer (no Stop is issued),
  *           and the next transfer will begin with a Restart rather than a Start.
  * \param until The absolute time that the block will wait until the entire transaction is complete.
  * \return Number of bytes read, or PICO_ERROR_GENERIC if address not acknowledged, no device present, or PICO_ERROR_TIMEOUT if a timeout occurred.
  */
 int i2c_read_blocking_until(i2c_inst_t *i2c, uint8_t addr, uint8_t *dst, size_t len, bool nostop, absolute_time_t until);

 /*! \brief Attempt to write specified number of bytes to address, with timeout
  *  \ingroup hardware_i2c
  *
  * \param i2c Either \ref i2c0 or \ref i2c1
  * \param addr Address of device to write to
  * \param src Pointer to data to send
  * \param len Length of data in bytes to send
  * \param nostop  If true, master retains control of the bus at the end of the transfer (no Stop is issued),
  *           and the next transfer will begin with a Restart rather than a Start.
  * \param timeout_us The time that the function will wait for the entire transaction to complete. Note, an individual timeout of
  *           this value divided by the length of data is applied for each byte transfer, so if the first or subsequent
  *           bytes fails to transfer within that sub timeout, the function will return with an error.
  *
  * \return Number of bytes written, or PICO_ERROR_GENERIC if address not acknowledged, no device present, or PICO_ERROR_TIMEOUT if a timeout occurred.
  */
 static inline int i2c_write_timeout_us(i2c_inst_t *i2c, uint8_t addr, const uint8_t *src, size_t len, bool nostop, uint timeout_us) {
     absolute_time_t t = make_timeout_time_us(timeout_us);
     return i2c_write_blocking_until(i2c, addr, src, len, nostop, t);
 }

 int i2c_write_timeout_per_char_us(i2c_inst_t *i2c, uint8_t addr, const uint8_t *src, size_t len, bool nostop, uint timeout_per_char_us);

 /*! \brief  Attempt to read specified number of bytes from address, with timeout
  *  \ingroup hardware_i2c
  *
  * \param i2c Either \ref i2c0 or \ref i2c1
  * \param addr Address of device to read from
  * \param dst Pointer to buffer to receive data
  * \param len Length of data in bytes to receive
  * \param nostop  If true, master retains control of the bus at the end of the transfer (no Stop is issued),
  *           and the next transfer will begin with a Restart rather than a Start.
  * \param timeout_us The time that the function will wait for the entire transaction to complete
  * \return Number of bytes read, or PICO_ERROR_GENERIC if address not acknowledged, no device present, or PICO_ERROR_TIMEOUT if a timeout occurred.
  */
 static inline int i2c_read_timeout_us(i2c_inst_t *i2c, uint8_t addr, uint8_t *dst, size_t len, bool nostop, uint timeout_us) {
     absolute_time_t t = make_timeout_time_us(timeout_us);
     return i2c_read_blocking_until(i2c, addr, dst, len, nostop, t);
 }

 int i2c_read_timeout_per_char_us(i2c_inst_t *i2c, uint8_t addr, uint8_t *dst, size_t len, bool nostop, uint timeout_per_char_us);

 /*! \brief Attempt to write specified number of bytes to address, blocking
  *  \ingroup hardware_i2c
  *
  * \param i2c Either \ref i2c0 or \ref i2c1
  * \param addr Address of device to write to
  * \param src Pointer to data to send
  * \param len Length of data in bytes to send
  * \param nostop  If true, master retains control of the bus at the end of the transfer (no Stop is issued),
  *           and the next transfer will begin with a Restart rather than a Start.
  * \return Number of bytes written, or PICO_ERROR_GENERIC if address not acknowledged, no device present.
  */
 int i2c_write_blocking(i2c_inst_t *i2c, uint8_t addr, const uint8_t *src, size_t len, bool nostop);

 /*! \brief  Attempt to read specified number of bytes from address, blocking
  *  \ingroup hardware_i2c
  *
  * \param i2c Either \ref i2c0 or \ref i2c1
  * \param addr Address of device to read from
  * \param dst Pointer to buffer to receive data
  * \param len Length of data in bytes to receive
  * \param nostop  If true, master retains control of the bus at the end of the transfer (no Stop is issued),
  *           and the next transfer will begin with a Restart rather than a Start.
  * \return Number of bytes read, or PICO_ERROR_GENERIC if address not acknowledged, no device present.
  */
 int i2c_read_blocking(i2c_inst_t *i2c, uint8_t addr, uint8_t *dst, size_t len, bool nostop);


 /*! \brief Determine non-blocking write space available
  *  \ingroup hardware_i2c
  *
  * \param i2c Either \ref i2c0 or \ref i2c1
  * \return 0 if no space is available in the I2C to write more data. If return is nonzero, at
  * least that many bytes can be written without blocking.
  */
 static inline size_t i2c_get_write_available(i2c_inst_t *i2c) {
     const size_t IC_TX_BUFFER_DEPTH = 32;
     return IC_TX_BUFFER_DEPTH - i2c_get_hw(i2c)->txflr;
 }

 /*! \brief Determine number of bytes received
  *  \ingroup hardware_i2c
  *
  * \param i2c Either \ref i2c0 or \ref i2c1
  * \return 0 if no data available, if return is nonzero at
  * least that many bytes can be read without blocking.
  */
 static inline size_t i2c_get_read_available(i2c_inst_t *i2c) {
     return i2c_get_hw(i2c)->rxflr;
 }

 /*! \brief Write direct to TX FIFO
  *  \ingroup hardware_i2c
  *
  * \param i2c Either \ref i2c0 or \ref i2c1
  * \param src Data to send
  * \param len Number of bytes to send
  *
  * Writes directly to the to I2C TX FIFO which us mainly useful for
  * slave-mode operation.
  */
 static inline void i2c_write_raw_blocking(i2c_inst_t *i2c, const uint8_t *src, size_t len) {
     for (size_t i = 0; i < len; ++i) {
         // TODO NACK or STOP on end?
         while (!i2c_get_write_available(i2c))
             tight_loop_contents();
         i2c_get_hw(i2c)->data_cmd = *src++;
     }
 }

 /*! \brief Write direct to TX FIFO
  *  \ingroup hardware_i2c
  *
  * \param i2c Either \ref i2c0 or \ref i2c1
  * \param dst Buffer to accept data
  * \param len Number of bytes to send
  *
  * Reads directly from the I2C RX FIFO which us mainly useful for
  * slave-mode operation.
  */
 static inline void i2c_read_raw_blocking(i2c_inst_t *i2c, uint8_t *dst, size_t len) {
     for (size_t i = 0; i < len; ++i) {
         while (!i2c_get_read_available(i2c))
             tight_loop_contents();
         *dst++ = i2c_get_hw(i2c)->data_cmd;
     }
 }

 #ifdef __cplusplus
 }
 #endif

 #endif
	/*
	* Copyright (c) 2020 Raspberry Pi (Trading) Ltd.
	*
	* SPDX-License-Identifier: BSD-3-Clause
	*/

	#ifndef _HARDWARE_I2C_H
	#define _HARDWARE_I2C_H

	#include "pico.h"
	#include "pico/time.h"
	#include "hardware/structs/i2c.h"

	// PICO_CONFIG: PARAM_ASSERTIONS_ENABLED_I2C, Enable/disable assertions in the I2C module, type=bool, default=0, group=hardware_i2c
	#ifndef PARAM_ASSERTIONS_ENABLED_I2C
	#define PARAM_ASSERTIONS_ENABLED_I2C 0
	#endif

	#ifdef __cplusplus
	extern "C" {
	#endif

	/** \file hardware/i2c.h
	* \defgroup hardware_i2c hardware_i2c
	*
	* I2C Controller API
	*
	* The I2C bus is a two-wire serial interface, consisting of a serial data line SDA and a serial clock SCL. These wires carry
	* information between the devices connected to the bus. Each device is recognized by a unique address and can operate as
	* either a “transmitter” or “receiver”, depending on the function of the device. Devices can also be considered as masters or
	* slaves when performing data transfers. A master is a device that initiates a data transfer on the bus and generates the
	* clock signals to permit that transfer. At that time, any device addressed is considered a slave.
	*
	* This API allows the controller to be set up as a master or a slave using the \ref i2c_set_slave_mode function.
	*
	* The external pins of each controller are connected to GPIO pins as defined in the GPIO muxing table in the datasheet. The muxing options
	* give some IO flexibility, but each controller external pin should be connected to only one GPIO.
	*
	* Note that the controller does NOT support High speed mode or Ultra-fast speed mode, the fastest operation being fast mode plus
	* at up to 1000Kb/s.
	*
	* See the datasheet for more information on the I2C controller and its usage.
	*
	* \subsection i2c_example Example
	* \addtogroup hardware_i2c
	* \include bus_scan.c
	*/

	typedef struct i2c_inst i2c_inst_t;

	/** The I2C identifiers for use in I2C functions.
	*
	* e.g. i2c_init(i2c0, 48000)
	*
	* \ingroup hardware_i2c
	* @{
	*/
	extern i2c_inst_t i2c0_inst;
	extern i2c_inst_t i2c1_inst;

	#define i2c0 (&i2c0_inst) ///< Identifier for I2C HW Block 0
	#define i2c1 (&i2c1_inst) ///< Identifier for I2C HW Block 1

	/** @} */

	// ----------------------------------------------------------------------------
	// Setup

	/*! \brief Initialise the I2C HW block
	* \ingroup hardware_i2c
	*
	* Put the I2C hardware into a known state, and enable it. Must be called
	* before other functions. By default, the I2C is configured to operate as a
	* master.
	*
	* The I2C bus frequency is set as close as possible to requested, and
	* the return actual rate set is returned
	*
	* \param i2c Either \ref i2c0 or \ref i2c1
	* \param baudrate Baudrate in Hz (e.g. 100kHz is 100000)
	* \return Actual set baudrate
	*/
	uint i2c_init(i2c_inst_t *i2c, uint baudrate);

	/*! \brief Disable the I2C HW block
	* \ingroup hardware_i2c
	*
	* \param i2c Either \ref i2c0 or \ref i2c1
	*
	* Disable the I2C again if it is no longer used. Must be reinitialised before
	* being used again.
	*/
	void i2c_deinit(i2c_inst_t *i2c);

	/*! \brief Set I2C baudrate
	* \ingroup hardware_i2c
	*
	* Set I2C bus frequency as close as possible to requested, and return actual
	* rate set.
	* Baudrate may not be as exactly requested due to clocking limitations.
	*
	* \param i2c Either \ref i2c0 or \ref i2c1
	* \param baudrate Baudrate in Hz (e.g. 100kHz is 100000)
	* \return Actual set baudrate
	*/
	uint i2c_set_baudrate(i2c_inst_t *i2c, uint baudrate);

	/*! \brief Set I2C port to slave mode
	* \ingroup hardware_i2c
	*
	* \param i2c Either \ref i2c0 or \ref i2c1
	* \param slave true to use slave mode, false to use master mode
	* \param addr If \p slave is true, set the slave address to this value
	*/
	void i2c_set_slave_mode(i2c_inst_t *i2c, bool slave, uint8_t addr);

	// ----------------------------------------------------------------------------
	// Generic input/output

	struct i2c_inst {
	i2c_hw_t *hw;
	bool restart_on_next;
	};

	/*! \brief Convert I2c instance to hardware instance number
	* \ingroup hardware_i2c
	*
	* \param i2c I2C instance
	* \return Number of UART, 0 or 1.
	*/
	static inline uint i2c_hw_index(i2c_inst_t *i2c) {
	invalid_params_if(I2C, i2c != i2c0 && i2c != i2c1);
	return i2c == i2c1 ? 1 : 0;
	}

	static inline i2c_hw_t i2c_get_hw(i2c_inst_t i2c) {
	i2c_hw_index(i2c); // check it is a hw i2c
	return i2c->hw;
	}

	/*! \brief Attempt to write specified number of bytes to address, blocking until the specified absolute time is reached.
	* \ingroup hardware_i2c
	*
	* \param i2c Either \ref i2c0 or \ref i2c1
	* \param addr Address of device to write to
	* \param src Pointer to data to send
	* \param len Length of data in bytes to send
	* \param nostop If true, master retains control of the bus at the end of the transfer (no Stop is issued),
	* and the next transfer will begin with a Restart rather than a Start.
	* \param until The absolute time that the block will wait until the entire transaction is complete. Note, an individual timeout of
	* this value divided by the length of data is applied for each byte transfer, so if the first or subsequent
	* bytes fails to transfer within that sub timeout, the function will return with an error.
	*
	* \return Number of bytes written, or PICO_ERROR_GENERIC if address not acknowledged, no device present, or PICO_ERROR_TIMEOUT if a timeout occurred.
	*/
	int i2c_write_blocking_until(i2c_inst_t i2c, uint8_t addr, const uint8_t src, size_t len, bool nostop, absolute_time_t until);

	/*! \brief Attempt to read specified number of bytes from address, blocking until the specified absolute time is reached.
	* \ingroup hardware_i2c
	*
	* \param i2c Either \ref i2c0 or \ref i2c1
	* \param addr Address of device to read from
	* \param dst Pointer to buffer to receive data
	* \param len Length of data in bytes to receive
	* \param nostop If true, master retains control of the bus at the end of the transfer (no Stop is issued),
	* and the next transfer will begin with a Restart rather than a Start.
	* \param until The absolute time that the block will wait until the entire transaction is complete.
	* \return Number of bytes read, or PICO_ERROR_GENERIC if address not acknowledged, no device present, or PICO_ERROR_TIMEOUT if a timeout occurred.
	*/
	int i2c_read_blocking_until(i2c_inst_t i2c, uint8_t addr, uint8_t dst, size_t len, bool nostop, absolute_time_t until);

	/*! \brief Attempt to write specified number of bytes to address, with timeout
	* \ingroup hardware_i2c
	*
	* \param i2c Either \ref i2c0 or \ref i2c1
	* \param addr Address of device to write to
	* \param src Pointer to data to send
	* \param len Length of data in bytes to send
	* \param nostop If true, master retains control of the bus at the end of the transfer (no Stop is issued),
	* and the next transfer will begin with a Restart rather than a Start.
	* \param timeout_us The time that the function will wait for the entire transaction to complete. Note, an individual timeout of
	* this value divided by the length of data is applied for each byte transfer, so if the first or subsequent
	* bytes fails to transfer within that sub timeout, the function will return with an error.
	*
	* \return Number of bytes written, or PICO_ERROR_GENERIC if address not acknowledged, no device present, or PICO_ERROR_TIMEOUT if a timeout occurred.
	*/
	static inline int i2c_write_timeout_us(i2c_inst_t i2c, uint8_t addr, const uint8_t src, size_t len, bool nostop, uint timeout_us) {
	absolute_time_t t = make_timeout_time_us(timeout_us);
	return i2c_write_blocking_until(i2c, addr, src, len, nostop, t);
	}

	int i2c_write_timeout_per_char_us(i2c_inst_t i2c, uint8_t addr, const uint8_t src, size_t len, bool nostop, uint timeout_per_char_us);

	/*! \brief Attempt to read specified number of bytes from address, with timeout
	* \ingroup hardware_i2c
	*
	* \param i2c Either \ref i2c0 or \ref i2c1
	* \param addr Address of device to read from
	* \param dst Pointer to buffer to receive data
	* \param len Length of data in bytes to receive
	* \param nostop If true, master retains control of the bus at the end of the transfer (no Stop is issued),
	* and the next transfer will begin with a Restart rather than a Start.
	* \param timeout_us The time that the function will wait for the entire transaction to complete
	* \return Number of bytes read, or PICO_ERROR_GENERIC if address not acknowledged, no device present, or PICO_ERROR_TIMEOUT if a timeout occurred.
	*/
	static inline int i2c_read_timeout_us(i2c_inst_t i2c, uint8_t addr, uint8_t dst, size_t len, bool nostop, uint timeout_us) {
	absolute_time_t t = make_timeout_time_us(timeout_us);
	return i2c_read_blocking_until(i2c, addr, dst, len, nostop, t);
	}

	int i2c_read_timeout_per_char_us(i2c_inst_t i2c, uint8_t addr, uint8_t dst, size_t len, bool nostop, uint timeout_per_char_us);

	/*! \brief Attempt to write specified number of bytes to address, blocking
	* \ingroup hardware_i2c
	*
	* \param i2c Either \ref i2c0 or \ref i2c1
	* \param addr Address of device to write to
	* \param src Pointer to data to send
	* \param len Length of data in bytes to send
	* \param nostop If true, master retains control of the bus at the end of the transfer (no Stop is issued),
	* and the next transfer will begin with a Restart rather than a Start.
	* \return Number of bytes written, or PICO_ERROR_GENERIC if address not acknowledged, no device present.
	*/
	int i2c_write_blocking(i2c_inst_t i2c, uint8_t addr, const uint8_t src, size_t len, bool nostop);

	/*! \brief Attempt to read specified number of bytes from address, blocking
	* \ingroup hardware_i2c
	*
	* \param i2c Either \ref i2c0 or \ref i2c1
	* \param addr Address of device to read from
	* \param dst Pointer to buffer to receive data
	* \param len Length of data in bytes to receive
	* \param nostop If true, master retains control of the bus at the end of the transfer (no Stop is issued),
	* and the next transfer will begin with a Restart rather than a Start.
	* \return Number of bytes read, or PICO_ERROR_GENERIC if address not acknowledged, no device present.
	*/
	int i2c_read_blocking(i2c_inst_t i2c, uint8_t addr, uint8_t dst, size_t len, bool nostop);


	/*! \brief Determine non-blocking write space available
	* \ingroup hardware_i2c
	*
	* \param i2c Either \ref i2c0 or \ref i2c1
	* \return 0 if no space is available in the I2C to write more data. If return is nonzero, at
	* least that many bytes can be written without blocking.
	*/
	static inline size_t i2c_get_write_available(i2c_inst_t *i2c) {
	const size_t IC_TX_BUFFER_DEPTH = 32;
	return IC_TX_BUFFER_DEPTH - i2c_get_hw(i2c)->txflr;
	}

	/*! \brief Determine number of bytes received
	* \ingroup hardware_i2c
	*
	* \param i2c Either \ref i2c0 or \ref i2c1
	* \return 0 if no data available, if return is nonzero at
	* least that many bytes can be read without blocking.
	*/
	static inline size_t i2c_get_read_available(i2c_inst_t *i2c) {
	return i2c_get_hw(i2c)->rxflr;
	}

	/*! \brief Write direct to TX FIFO
	* \ingroup hardware_i2c
	*
	* \param i2c Either \ref i2c0 or \ref i2c1
	* \param src Data to send
	* \param len Number of bytes to send
	*
	* Writes directly to the to I2C TX FIFO which us mainly useful for
	* slave-mode operation.
	*/
	static inline void i2c_write_raw_blocking(i2c_inst_t i2c, const uint8_t src, size_t len) {
	for (size_t i = 0; i < len; ++i) {
	// TODO NACK or STOP on end?
	while (!i2c_get_write_available(i2c))
	tight_loop_contents();
	i2c_get_hw(i2c)->data_cmd = *src++;
	}
	}

	/*! \brief Write direct to TX FIFO
	* \ingroup hardware_i2c
	*
	* \param i2c Either \ref i2c0 or \ref i2c1
	* \param dst Buffer to accept data
	* \param len Number of bytes to send
	*
	* Reads directly from the I2C RX FIFO which us mainly useful for
	* slave-mode operation.
	*/
	static inline void i2c_read_raw_blocking(i2c_inst_t i2c, uint8_t dst, size_t len) {
	for (size_t i = 0; i < len; ++i) {
	while (!i2c_get_read_available(i2c))
	tight_loop_contents();
	*dst++ = i2c_get_hw(i2c)->data_cmd;
	}
	}

	#ifdef __cplusplus
	}
	#endif

	#endif