src/rp2_common/hardware_spi/include/hardware/spi.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_SPI_H
 #define _HARDWARE_SPI_H

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

 // PICO_CONFIG: PARAM_ASSERTIONS_ENABLED_SPI, Enable/disable assertions in the SPI module, type=bool, default=0, group=hardware_spi
 #ifndef PARAM_ASSERTIONS_ENABLED_SPI
 #define PARAM_ASSERTIONS_ENABLED_SPI 0
 #endif

 #ifdef __cplusplus
 extern "C" {
 #endif

 /** \file hardware/spi.h
  *  \defgroup hardware_spi hardware_spi
  *
  * Hardware SPI API
  *
  * RP2040 has 2 identical instances of the Serial Peripheral Interface (SPI) controller.
  *
  * The PrimeCell SSP is a master or slave interface for synchronous serial communication with peripheral devices that have
  * Motorola SPI, National Semiconductor Microwire, or Texas Instruments synchronous serial interfaces.
  *
  * Controller can be defined as master or slave using the \ref spi_set_slave function.
  *
  * Each controller can be connected to a number of GPIO pins, see the datasheet GPIO function selection table for more information.
  */

 /**
  * Opaque type representing an SPI instance.
  */
 typedef struct spi_inst spi_inst_t;

 /** Identifier for the first (SPI 0) hardware SPI instance (for use in SPI functions).
  *
  * e.g. spi_init(spi0, 48000)
  *
  *  \ingroup hardware_spi
  */
 #define spi0 ((spi_inst_t * const)spi0_hw)

 /** Identifier for the second (SPI 1) hardware SPI instance (for use in SPI functions).
  *
  * e.g. spi_init(spi1, 48000)
  *
  *  \ingroup hardware_spi
  */
 #define spi1 ((spi_inst_t * const)spi1_hw)

 typedef enum {
     SPI_CPHA_0 = 0,
     SPI_CPHA_1 = 1
 } spi_cpha_t;

 typedef enum {
     SPI_CPOL_0 = 0,
     SPI_CPOL_1 = 1
 } spi_cpol_t;

 typedef enum {
     SPI_LSB_FIRST = 0,
     SPI_MSB_FIRST = 1
 } spi_order_t;

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

 /*! \brief Initialise SPI instances
  *  \ingroup hardware_spi
  * Puts the SPI into a known state, and enable it. Must be called before other
  * functions.
  *
  * \param spi SPI instance specifier, either \ref spi0 or \ref spi1
  * \param baudrate Baudrate required in Hz
  *
  * \note There is no guarantee that the baudrate requested will be possible, the nearest will be chosen,
  * and this function does not return any indication of this. You can use the \ref spi_set_baudrate function
  * which will return the actual baudrate selected if this is important.
  */
 void spi_init(spi_inst_t *spi, uint baudrate);

 /*! \brief Deinitialise SPI instances
  *  \ingroup hardware_spi
  * Puts the SPI into a disabled state. Init will need to be called to reenable the device
  * functions.
  *
  * \param spi SPI instance specifier, either \ref spi0 or \ref spi1
  */
 void spi_deinit(spi_inst_t *spi);

 /*! \brief Set SPI baudrate
  *  \ingroup hardware_spi
  *
  * Set SPI frequency as close as possible to baudrate, and return the actual
  * achieved rate.
  *
  * \param spi SPI instance specifier, either \ref spi0 or \ref spi1
  * \param baudrate Baudrate required in Hz, should be capable of a bitrate of at least 2Mbps, or higher, depending on system clock settings.
  * \return The actual baudrate set
  */
 uint spi_set_baudrate(spi_inst_t *spi, uint baudrate);

 /*! \brief Convert I2c instance to hardware instance number
  *  \ingroup hardware_spi
  *
  * \param spi SPI instance
  * \return Number of SPI, 0 or 1.
  */
 static inline uint spi_get_index(spi_inst_t *spi) {
     invalid_params_if(SPI, spi != spi0 && spi != spi1);
     return spi == spi1 ? 1 : 0;
 }

 static inline spi_hw_t *spi_get_hw(spi_inst_t *spi) {
     spi_get_index(spi); // check it is a hw spi
     return (spi_hw_t *)spi;
 }

 /*! \brief Configure SPI
  *  \ingroup hardware_spi
  *
  * Configure how the SPI serialises and deserialises data on the wire
  *
  * \param spi SPI instance specifier, either \ref spi0 or \ref spi1
  * \param data_bits Number of data bits per transfer. Valid values 4..16.
  * \param cpol SSPCLKOUT polarity, applicable to Motorola SPI frame format only.
  * \param cpha SSPCLKOUT phase, applicable to Motorola SPI frame format only
  * \param order Must be SPI_MSB_FIRST, no other values supported on the PL022
  */
 static inline void spi_set_format(spi_inst_t *spi, uint data_bits, spi_cpol_t cpol, spi_cpha_t cpha, spi_order_t order) {
     invalid_params_if(SPI, data_bits < 4 || data_bits > 16);
     // LSB-first not supported on PL022:
     invalid_params_if(SPI, order != SPI_MSB_FIRST);
     invalid_params_if(SPI, cpol != SPI_CPOL_0 && cpol != SPI_CPOL_1);
     invalid_params_if(SPI, cpha != SPI_CPHA_0 && cpha != SPI_CPHA_1);
     hw_write_masked(&spi_get_hw(spi)->cr0,
         (data_bits - 1) << SPI_SSPCR0_DSS_LSB |
         cpol << SPI_SSPCR0_SPO_LSB |
         cpha << SPI_SSPCR0_SPH_LSB,
         SPI_SSPCR0_DSS_BITS |
         SPI_SSPCR0_SPO_BITS |
         SPI_SSPCR0_SPH_BITS);
 }

 /*! \brief Set SPI master/slave
  *  \ingroup hardware_spi
  *
  * Configure the SPI for master- or slave-mode operation. By default,
  * spi_init() sets master-mode.
  *
  * \param spi SPI instance specifier, either \ref spi0 or \ref spi1
  * \param slave true to set SPI device as a slave device, false for master.
  */
 static inline void spi_set_slave(spi_inst_t *spi, bool slave) {
     if (slave)
         hw_set_bits(&spi_get_hw(spi)->cr1, SPI_SSPCR1_MS_BITS);
     else
         hw_clear_bits(&spi_get_hw(spi)->cr1, SPI_SSPCR1_MS_BITS);
 }

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

 /*! \brief Check whether a write can be done on SPI device
  *  \ingroup hardware_spi
  *
  * \param spi SPI instance specifier, either \ref spi0 or \ref spi1
  * \return 0 if no space is available to write. Non-zero if a write is possible
  *
  * \note Although the controllers each have a 8 deep TX FIFO, the current HW implementation can only return 0 or 1
  * rather than the space available.
  */
 static inline size_t spi_is_writable(spi_inst_t *spi) {
     // PL022 doesn't expose levels directly, so return values are only 0 or 1
     return (spi_get_hw(spi)->sr & SPI_SSPSR_TNF_BITS) >> SPI_SSPSR_TNF_LSB;
 }

 /*! \brief Check whether a read can be done on SPI device
  *  \ingroup hardware_spi
  *
  * \param spi SPI instance specifier, either \ref spi0 or \ref spi1
  * \return Non-zero if a read is possible i.e. data is present
  *
  * \note Although the controllers each have a 8 deep RX FIFO, the current HW implementation can only return 0 or 1
  * rather than the data available.
  */
 static inline size_t spi_is_readable(spi_inst_t *spi) {
     return (spi_get_hw(spi)->sr & SPI_SSPSR_RNE_BITS) >> SPI_SSPSR_RNE_LSB;
 }

 /*! \brief Write/Read to/from an SPI device
  *  \ingroup hardware_spi
  *
  * Write \p len bytes from \p src to SPI. Simultaneously read \p len bytes from SPI to \p dst.
  * Blocks until all data is transferred. No timeout, as SPI hardware always transfers at a known data rate.
  *
  * \param spi SPI instance specifier, either \ref spi0 or \ref spi1
  * \param src Buffer of data to write
  * \param dst Buffer for read data
  * \param len Length of BOTH buffers
  * \return Number of bytes written/read
 */
 int spi_write_read_blocking(spi_inst_t *spi, const uint8_t *src, uint8_t *dst, size_t len);

 /*! \brief Write to an SPI device, blocking
  *  \ingroup hardware_spi
  *
  * Write \p len bytes from \p src to SPI, and discard any data received back
  * Blocks until all data is transferred. No timeout, as SPI hardware always transfers at a known data rate.
  *
  * \param spi SPI instance specifier, either \ref spi0 or \ref spi1
  * \param src Buffer of data to write
  * \param len Length of \p src
  * \return Number of bytes written/read
  */
 int spi_write_blocking(spi_inst_t *spi, const uint8_t *src, size_t len);

 /*! \brief Read from an SPI device
  *  \ingroup hardware_spi
  *
  * Read \p len bytes from SPI to \p dst.
  * Blocks until all data is transferred. No timeout, as SPI hardware always transfers at a known data rate.
  * \p repeated_tx_data is output repeatedly on TX as data is read in from RX.
  * Generally this can be 0, but some devices require a specific value here,
  * e.g. SD cards expect 0xff
  *
  * \param spi SPI instance specifier, either \ref spi0 or \ref spi1
  * \param repeated_tx_data Buffer of data to write
  * \param dst Buffer for read data
  * \param len Length of buffer \p dst
  * \return Number of bytes written/read
  */
 int spi_read_blocking(spi_inst_t *spi, uint8_t repeated_tx_data, uint8_t *dst, size_t len);

 // ----------------------------------------------------------------------------
 // SPI-specific operations and aliases

 // FIXME need some instance-private data for select() and deselect() if we are going that route

 /*! \brief Write/Read half words to/from an SPI device
  *  \ingroup hardware_spi
  *
  * Write \p len halfwords from \p src to SPI. Simultaneously read \p len halfwords from SPI to \p dst.
  * Blocks until all data is transferred. No timeout, as SPI hardware always transfers at a known data rate.
  *
  * \param spi SPI instance specifier, either \ref spi0 or \ref spi1
  * \param src Buffer of data to write
  * \param dst Buffer for read data
  * \param len Length of BOTH buffers in halfwords
  * \return Number of bytes written/read
 */
 int spi_write16_read16_blocking(spi_inst_t *spi, const uint16_t *src, uint16_t *dst, size_t len);

 /*! \brief Write to an SPI device
  *  \ingroup hardware_spi
  *
  * Write \p len halfwords from \p src to SPI. Discard any data received back.
  * Blocks until all data is transferred. No timeout, as SPI hardware always transfers at a known data rate.
  *
  * \param spi SPI instance specifier, either \ref spi0 or \ref spi1
  * \param src Buffer of data to write
  * \param len Length of buffers
  * \return Number of bytes written/read
 */
 int spi_write16_blocking(spi_inst_t *spi, const uint16_t *src, size_t len);

 /*! \brief Read from an SPI device
  *  \ingroup hardware_spi
  *
  * Read \p len halfwords from SPI to \p dst.
  * Blocks until all data is transferred. No timeout, as SPI hardware always transfers at a known data rate.
  * \p repeated_tx_data is output repeatedly on TX as data is read in from RX.
  * Generally this can be 0, but some devices require a specific value here,
  * e.g. SD cards expect 0xff
  *
  * \param spi SPI instance specifier, either \ref spi0 or \ref spi1
  * \param repeated_tx_data Buffer of data to write
  * \param dst Buffer for read data
  * \param len Length of buffer \p dst  in halfwords
  * \return Number of bytes written/read
  */
 int spi_read16_blocking(spi_inst_t *spi, uint16_t repeated_tx_data, uint16_t *dst, size_t len);

 #ifdef __cplusplus
 }
 #endif

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

	#ifndef _HARDWARE_SPI_H
	#define _HARDWARE_SPI_H

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

	// PICO_CONFIG: PARAM_ASSERTIONS_ENABLED_SPI, Enable/disable assertions in the SPI module, type=bool, default=0, group=hardware_spi
	#ifndef PARAM_ASSERTIONS_ENABLED_SPI
	#define PARAM_ASSERTIONS_ENABLED_SPI 0
	#endif

	#ifdef __cplusplus
	extern "C" {
	#endif

	/** \file hardware/spi.h
	* \defgroup hardware_spi hardware_spi
	*
	* Hardware SPI API
	*
	* RP2040 has 2 identical instances of the Serial Peripheral Interface (SPI) controller.
	*
	* The PrimeCell SSP is a master or slave interface for synchronous serial communication with peripheral devices that have
	* Motorola SPI, National Semiconductor Microwire, or Texas Instruments synchronous serial interfaces.
	*
	* Controller can be defined as master or slave using the \ref spi_set_slave function.
	*
	* Each controller can be connected to a number of GPIO pins, see the datasheet GPIO function selection table for more information.
	*/

	/**
	* Opaque type representing an SPI instance.
	*/
	typedef struct spi_inst spi_inst_t;

	/** Identifier for the first (SPI 0) hardware SPI instance (for use in SPI functions).
	*
	* e.g. spi_init(spi0, 48000)
	*
	* \ingroup hardware_spi
	*/
	#define spi0 ((spi_inst_t * const)spi0_hw)

	/** Identifier for the second (SPI 1) hardware SPI instance (for use in SPI functions).
	*
	* e.g. spi_init(spi1, 48000)
	*
	* \ingroup hardware_spi
	*/
	#define spi1 ((spi_inst_t * const)spi1_hw)

	typedef enum {
	SPI_CPHA_0 = 0,
	SPI_CPHA_1 = 1
	} spi_cpha_t;

	typedef enum {
	SPI_CPOL_0 = 0,
	SPI_CPOL_1 = 1
	} spi_cpol_t;

	typedef enum {
	SPI_LSB_FIRST = 0,
	SPI_MSB_FIRST = 1
	} spi_order_t;

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

	/*! \brief Initialise SPI instances
	* \ingroup hardware_spi
	* Puts the SPI into a known state, and enable it. Must be called before other
	* functions.
	*
	* \param spi SPI instance specifier, either \ref spi0 or \ref spi1
	* \param baudrate Baudrate required in Hz
	*
	* \note There is no guarantee that the baudrate requested will be possible, the nearest will be chosen,
	* and this function does not return any indication of this. You can use the \ref spi_set_baudrate function
	* which will return the actual baudrate selected if this is important.
	*/
	void spi_init(spi_inst_t *spi, uint baudrate);

	/*! \brief Deinitialise SPI instances
	* \ingroup hardware_spi
	* Puts the SPI into a disabled state. Init will need to be called to reenable the device
	* functions.
	*
	* \param spi SPI instance specifier, either \ref spi0 or \ref spi1
	*/
	void spi_deinit(spi_inst_t *spi);

	/*! \brief Set SPI baudrate
	* \ingroup hardware_spi
	*
	* Set SPI frequency as close as possible to baudrate, and return the actual
	* achieved rate.
	*
	* \param spi SPI instance specifier, either \ref spi0 or \ref spi1
	* \param baudrate Baudrate required in Hz, should be capable of a bitrate of at least 2Mbps, or higher, depending on system clock settings.
	* \return The actual baudrate set
	*/
	uint spi_set_baudrate(spi_inst_t *spi, uint baudrate);

	/*! \brief Convert I2c instance to hardware instance number
	* \ingroup hardware_spi
	*
	* \param spi SPI instance
	* \return Number of SPI, 0 or 1.
	*/
	static inline uint spi_get_index(spi_inst_t *spi) {
	invalid_params_if(SPI, spi != spi0 && spi != spi1);
	return spi == spi1 ? 1 : 0;
	}

	static inline spi_hw_t spi_get_hw(spi_inst_t spi) {
	spi_get_index(spi); // check it is a hw spi
	return (spi_hw_t *)spi;
	}

	/*! \brief Configure SPI
	* \ingroup hardware_spi
	*
	* Configure how the SPI serialises and deserialises data on the wire
	*
	* \param spi SPI instance specifier, either \ref spi0 or \ref spi1
	* \param data_bits Number of data bits per transfer. Valid values 4..16.
	* \param cpol SSPCLKOUT polarity, applicable to Motorola SPI frame format only.
	* \param cpha SSPCLKOUT phase, applicable to Motorola SPI frame format only
	* \param order Must be SPI_MSB_FIRST, no other values supported on the PL022
	*/
	static inline void spi_set_format(spi_inst_t *spi, uint data_bits, spi_cpol_t cpol, spi_cpha_t cpha, spi_order_t order) {
	invalid_params_if(SPI, data_bits < 4 \|\| data_bits > 16);
	// LSB-first not supported on PL022:
	invalid_params_if(SPI, order != SPI_MSB_FIRST);
	invalid_params_if(SPI, cpol != SPI_CPOL_0 && cpol != SPI_CPOL_1);
	invalid_params_if(SPI, cpha != SPI_CPHA_0 && cpha != SPI_CPHA_1);
	hw_write_masked(&spi_get_hw(spi)->cr0,
	(data_bits - 1) << SPI_SSPCR0_DSS_LSB \|
	cpol << SPI_SSPCR0_SPO_LSB \|
	cpha << SPI_SSPCR0_SPH_LSB,
	SPI_SSPCR0_DSS_BITS \|
	SPI_SSPCR0_SPO_BITS \|
	SPI_SSPCR0_SPH_BITS);
	}

	/*! \brief Set SPI master/slave
	* \ingroup hardware_spi
	*
	* Configure the SPI for master- or slave-mode operation. By default,
	* spi_init() sets master-mode.
	*
	* \param spi SPI instance specifier, either \ref spi0 or \ref spi1
	* \param slave true to set SPI device as a slave device, false for master.
	*/
	static inline void spi_set_slave(spi_inst_t *spi, bool slave) {
	if (slave)
	hw_set_bits(&spi_get_hw(spi)->cr1, SPI_SSPCR1_MS_BITS);
	else
	hw_clear_bits(&spi_get_hw(spi)->cr1, SPI_SSPCR1_MS_BITS);
	}

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

	/*! \brief Check whether a write can be done on SPI device
	* \ingroup hardware_spi
	*
	* \param spi SPI instance specifier, either \ref spi0 or \ref spi1
	* \return 0 if no space is available to write. Non-zero if a write is possible
	*
	* \note Although the controllers each have a 8 deep TX FIFO, the current HW implementation can only return 0 or 1
	* rather than the space available.
	*/
	static inline size_t spi_is_writable(spi_inst_t *spi) {
	// PL022 doesn't expose levels directly, so return values are only 0 or 1
	return (spi_get_hw(spi)->sr & SPI_SSPSR_TNF_BITS) >> SPI_SSPSR_TNF_LSB;
	}

	/*! \brief Check whether a read can be done on SPI device
	* \ingroup hardware_spi
	*
	* \param spi SPI instance specifier, either \ref spi0 or \ref spi1
	* \return Non-zero if a read is possible i.e. data is present
	*
	* \note Although the controllers each have a 8 deep RX FIFO, the current HW implementation can only return 0 or 1
	* rather than the data available.
	*/
	static inline size_t spi_is_readable(spi_inst_t *spi) {
	return (spi_get_hw(spi)->sr & SPI_SSPSR_RNE_BITS) >> SPI_SSPSR_RNE_LSB;
	}

	/*! \brief Write/Read to/from an SPI device
	* \ingroup hardware_spi
	*
	* Write \p len bytes from \p src to SPI. Simultaneously read \p len bytes from SPI to \p dst.
	* Blocks until all data is transferred. No timeout, as SPI hardware always transfers at a known data rate.
	*
	* \param spi SPI instance specifier, either \ref spi0 or \ref spi1
	* \param src Buffer of data to write
	* \param dst Buffer for read data
	* \param len Length of BOTH buffers
	* \return Number of bytes written/read
	*/
	int spi_write_read_blocking(spi_inst_t spi, const uint8_t src, uint8_t *dst, size_t len);

	/*! \brief Write to an SPI device, blocking
	* \ingroup hardware_spi
	*
	* Write \p len bytes from \p src to SPI, and discard any data received back
	* Blocks until all data is transferred. No timeout, as SPI hardware always transfers at a known data rate.
	*
	* \param spi SPI instance specifier, either \ref spi0 or \ref spi1
	* \param src Buffer of data to write
	* \param len Length of \p src
	* \return Number of bytes written/read
	*/
	int spi_write_blocking(spi_inst_t spi, const uint8_t src, size_t len);

	/*! \brief Read from an SPI device
	* \ingroup hardware_spi
	*
	* Read \p len bytes from SPI to \p dst.
	* Blocks until all data is transferred. No timeout, as SPI hardware always transfers at a known data rate.
	* \p repeated_tx_data is output repeatedly on TX as data is read in from RX.
	* Generally this can be 0, but some devices require a specific value here,
	* e.g. SD cards expect 0xff
	*
	* \param spi SPI instance specifier, either \ref spi0 or \ref spi1
	* \param repeated_tx_data Buffer of data to write
	* \param dst Buffer for read data
	* \param len Length of buffer \p dst
	* \return Number of bytes written/read
	*/
	int spi_read_blocking(spi_inst_t spi, uint8_t repeated_tx_data, uint8_t dst, size_t len);

	// ----------------------------------------------------------------------------
	// SPI-specific operations and aliases

	// FIXME need some instance-private data for select() and deselect() if we are going that route

	/*! \brief Write/Read half words to/from an SPI device
	* \ingroup hardware_spi
	*
	* Write \p len halfwords from \p src to SPI. Simultaneously read \p len halfwords from SPI to \p dst.
	* Blocks until all data is transferred. No timeout, as SPI hardware always transfers at a known data rate.
	*
	* \param spi SPI instance specifier, either \ref spi0 or \ref spi1
	* \param src Buffer of data to write
	* \param dst Buffer for read data
	* \param len Length of BOTH buffers in halfwords
	* \return Number of bytes written/read
	*/
	int spi_write16_read16_blocking(spi_inst_t spi, const uint16_t src, uint16_t *dst, size_t len);

	/*! \brief Write to an SPI device
	* \ingroup hardware_spi
	*
	* Write \p len halfwords from \p src to SPI. Discard any data received back.
	* Blocks until all data is transferred. No timeout, as SPI hardware always transfers at a known data rate.
	*
	* \param spi SPI instance specifier, either \ref spi0 or \ref spi1
	* \param src Buffer of data to write
	* \param len Length of buffers
	* \return Number of bytes written/read
	*/
	int spi_write16_blocking(spi_inst_t spi, const uint16_t src, size_t len);

	/*! \brief Read from an SPI device
	* \ingroup hardware_spi
	*
	* Read \p len halfwords from SPI to \p dst.
	* Blocks until all data is transferred. No timeout, as SPI hardware always transfers at a known data rate.
	* \p repeated_tx_data is output repeatedly on TX as data is read in from RX.
	* Generally this can be 0, but some devices require a specific value here,
	* e.g. SD cards expect 0xff
	*
	* \param spi SPI instance specifier, either \ref spi0 or \ref spi1
	* \param repeated_tx_data Buffer of data to write
	* \param dst Buffer for read data
	* \param len Length of buffer \p dst in halfwords
	* \return Number of bytes written/read
	*/
	int spi_read16_blocking(spi_inst_t spi, uint16_t repeated_tx_data, uint16_t dst, size_t len);

	#ifdef __cplusplus
	}
	#endif

	#endif