/** * \file Hardware SPI master driver * * Part of esp-open-rtos * * \copyright Ruslan V. Uss, 2016 * BSD Licensed as described in the file LICENSE */ #ifndef _ESP_SPI_H_ #define _ESP_SPI_H_ #include #include #include "esp/spi_regs.h" #include "esp/clocks.h" /** * Macro for use with spi_init and spi_set_frequency_div. * SPI frequency = 80000000 / divider / count * dvider must be in 1..8192 and count in 1..64 */ #define SPI_GET_FREQ_DIV(divider, count) (((count) << 16) | ((divider) & 0xffff)) /** * Predefinded SPI frequency dividers */ #define SPI_FREQ_DIV_125K SPI_GET_FREQ_DIV(64, 10) ///< 125kHz #define SPI_FREQ_DIV_250K SPI_GET_FREQ_DIV(32, 10) ///< 250kHz #define SPI_FREQ_DIV_500K SPI_GET_FREQ_DIV(16, 10) ///< 500kHz #define SPI_FREQ_DIV_1M SPI_GET_FREQ_DIV(8, 10) ///< 1MHz #define SPI_FREQ_DIV_2M SPI_GET_FREQ_DIV(4, 10) ///< 2MHz #define SPI_FREQ_DIV_4M SPI_GET_FREQ_DIV(2, 10) ///< 4MHz #define SPI_FREQ_DIV_8M SPI_GET_FREQ_DIV(5, 2) ///< 8MHz #define SPI_FREQ_DIV_10M SPI_GET_FREQ_DIV(4, 2) ///< 10MHz #define SPI_FREQ_DIV_20M SPI_GET_FREQ_DIV(2, 2) ///< 20MHz #define SPI_FREQ_DIV_40M SPI_GET_FREQ_DIV(1, 2) ///< 40MHz #define SPI_FREQ_DIV_80M SPI_GET_FREQ_DIV(1, 1) ///< 80MHz /* * Possible Data Structure of SPI Transaction * * [COMMAND]+[ADDRESS]+[DataOUT]+[DUMMYBITS]+[DataIN] * * [COMMAND]+[ADDRESS]+[DUMMYBITS]+[DataOUT] * */ #ifdef __cplusplus extern "C" { #endif typedef enum _spi_mode_t { SPI_MODE0 = 0, ///< CPOL = 0, CPHA = 0 SPI_MODE1, ///< CPOL = 0, CPHA = 1 SPI_MODE2, ///< CPOL = 1, CPHA = 0 SPI_MODE3 ///< CPOL = 1, CPHA = 1 } spi_mode_t; typedef enum _spi_endianness_t { SPI_LITTLE_ENDIAN = 0, SPI_BIG_ENDIAN } spi_endianness_t; typedef enum _spi_word_size_t { SPI_8BIT = 1, ///< 1 byte SPI_16BIT = 2, ///< 2 bytes SPI_32BIT = 4 ///< 4 bytes } spi_word_size_t; /** * SPI bus settings */ typedef struct { spi_mode_t mode; ///< Bus mode uint32_t freq_divider; ///< Bus frequency as a divider. See spi_init() bool msb; ///< MSB first if true spi_endianness_t endianness; ///< Bus byte order bool minimal_pins; ///< Minimal set of pins if true. Spee spi_init() } spi_settings_t; /** * \brief Initalize SPI bus * Initalize specified SPI bus and setup appropriate pins: * Bus 0: * - MISO = GPIO 7 * - MOSI = GPIO 8 * - SCK = GPIO 6 * - CS0 = GPIO 11 (if minimal_pins is false) * - HD = GPIO 9 (if minimal_pins is false) * - WP = GPIO 10 (if minimal_pins is false) * Bus 1: * - MISO = GPIO 12 * - MOSI = GPIO 13 * - SCK = GPIO 14 * - CS0 = GPIO 15 (if minimal_pins is false) * Note that system flash memory is on the bus 0! * \param bus Bus ID: 0 - system, 1 - user * \param mode Bus mode * \param freq_divider SPI bus frequency divider, use SPI_GET_FREQ_DIV() or predefined value * \param msb Bit order, MSB first if true * \param endianness Byte order * \param minimal_pins If true use the minimal set of pins: MISO, MOSI and SCK. * \return false when error */ bool spi_init(uint8_t bus, spi_mode_t mode, uint32_t freq_divider, bool msb, spi_endianness_t endianness, bool minimal_pins); /** * \brief Initalize SPI bus * spi_init() wrapper. * Example: * * const spi_settings_t my_settings = { * .mode = SPI_MODE0, * .freq_divider = SPI_FREQ_DIV_4M, * .msb = true, * .endianness = SPI_LITTLE_ENDIAN, * .minimal_pins = true * } * .... * spi_settings_t old; * spi_get_settings(1, &old); // save current settings * //spi_init(1, SPI_MODE0, SPI_FREQ_DIV_4M, true, SPI_LITTLE_ENDIAN, true); // use own settings * // or * spi_set_settings(1, &my_settings); * // some work with spi here * .... * spi_set_settings(1, &old); // restore saved settings * * \param s Pointer to the settings structure * \return false when error */ static inline bool spi_set_settings(uint8_t bus, const spi_settings_t *s) { return spi_init(bus, s->mode, s->freq_divider, s->msb, s->endianness, s->minimal_pins); } /** * \brief Get current settings of the SPI bus * See spi_set_settings(). * \param bus Bus ID: 0 - system, 1 - user * \param s Pointer to the structure that receives SPI bus settings */ void spi_get_settings(uint8_t bus, spi_settings_t *s); /** * \brief Set SPI bus mode * \param bus Bus ID: 0 - system, 1 - user * \param mode Bus mode */ void spi_set_mode(uint8_t bus, spi_mode_t mode); /** * \brief Get mode of the SPI bus * \param bus Bus ID: 0 - system, 1 - user * \return Bus mode */ spi_mode_t spi_get_mode(uint8_t bus); /** * \brief Set SPI bus frequency * Examples: * * spi_set_frequency_div(1, SPI_FREQ_DIV_8M); // 8 MHz, predefined value * ... * spi_set_frequency_div(1, SPI_GET_FREQ_DIV(8, 10)); // divider = 8, count = 10, * // frequency = 80000000 Hz / 8 / 10 = 1000000 Hz * * \param bus Bus ID: 0 - system, 1 - user * \param divider Predivider of the system bus frequency (80MHz) in the 2 low * bytes and period pulses count in the third byte. Please note that * divider must be be in range 1..8192 and count in range 2..64. Use the * macro SPI_GET_FREQ_DIV(divider, count) to get the correct parameter value. */ void spi_set_frequency_div(uint8_t bus, uint32_t divider); /** * \brief Get SPI bus frequency as a divider * Example: * * uint32_t old_freq = spi_get_frequency_div(1); * spi_set_frequency_div(1, SPI_FREQ_DIV_8M); * ... * spi_set_frequency_div(1, old_freq); * * \param bus Bus ID: 0 - system, 1 - user * \return SPI frequency, as divider. */ inline uint32_t spi_get_frequency_div(uint8_t bus) { return (FIELD2VAL(SPI_CLOCK_DIV_PRE, SPI(bus).CLOCK) + 1) | (FIELD2VAL(SPI_CLOCK_COUNT_NUM, SPI(bus).CLOCK) + 1); } /** * \brief Get SPI bus frequency in Hz * \param bus Bus ID: 0 - system, 1 - user * \return SPI frequency, Hz */ inline uint32_t spi_get_frequency_hz(uint8_t bus) { return APB_CLK_FREQ / (FIELD2VAL(SPI_CLOCK_DIV_PRE, SPI(bus).CLOCK) + 1) / (FIELD2VAL(SPI_CLOCK_COUNT_NUM, SPI(bus).CLOCK) + 1); } /** * \brief Set SPI bus bit order * \param bus Bus ID: 0 - system, 1 - user * \param msb Bit order, MSB first if true */ void spi_set_msb(uint8_t bus, bool msb); /** * \brief Get SPI bus bit order * \param bus Bus ID: 0 - system, 1 - user * \return msb Bit order, MSB first if true */ inline bool spi_get_msb(uint8_t bus) { return !(SPI(bus).CTRL0 & (SPI_CTRL0_WR_BIT_ORDER | SPI_CTRL0_RD_BIT_ORDER)); } /** * \brief Set SPI bus byte order * \param bus Bus ID: 0 - system, 1 - user * \param endianness Byte order */ void spi_set_endianness(uint8_t bus, spi_endianness_t endianness); /** * \brief Get SPI bus byte order * \param bus Bus ID: 0 - system, 1 - user * \return endianness Byte order */ inline spi_endianness_t spi_get_endianness(uint8_t bus) { return SPI(bus).USER0 & (SPI_USER0_WR_BYTE_ORDER | SPI_USER0_RD_BYTE_ORDER) ? SPI_BIG_ENDIAN : SPI_LITTLE_ENDIAN; } /** * \brief Transfer 8 bits over SPI * \param bus Bus ID: 0 - system, 1 - user * \param data Byte to send * \return Received byte */ uint8_t spi_transfer_8(uint8_t bus, uint8_t data); /** * \brief Transfer 16 bits over SPI * \param bus Bus ID: 0 - system, 1 - user * \param data Word to send * \return Received word */ uint16_t spi_transfer_16(uint8_t bus, uint16_t data); /** * \brief Transfer 32 bits over SPI * \param bus Bus ID: 0 - system, 1 - user * \param data dword to send * \return Received dword */ uint32_t spi_transfer_32(uint8_t bus, uint32_t data); /** * \brief Transfer buffer of words over SPI * Please note that the buffer size is in words, not in bytes! * Example: * * const uint16_t out_buf[] = { 0xa0b0, 0xa1b1, 0xa2b2, 0xa3b3 }; * uint16_t in_buf[sizeof(out_buf)]; * spi_init(1, SPI_MODE1, SPI_FREQ_DIV_4M, true, SPI_BIG_ENDIAN, true); * spi_transfer(1, out_buf, in_buf, sizeof(out_buf), SPI_16BIT); // len = 4 words * 2 bytes = 8 bytes * * \param bus Bus ID: 0 - system, 1 - user * \param out_data Data to send. * \param in_data Receive buffer. If NULL, received data will be lost. * \param len Buffer size in words * \param word_size Size of the word * \return Transmitted/received words count */ size_t spi_transfer(uint8_t bus, const void *out_data, void *in_data, size_t len, spi_word_size_t word_size); /** * \brief Add permanent command bits when transfert data over SPI * Example: * * spi_set_command(1, 1, 0x01); // Set one command bit to 1 * for (uint8_t i = 0; i < x; i++ ) { * spi_transfer_8(1, 0x55); // Send 1 bit command + 8 bits data x times * } * spi_clear_command(1); // Clear command * spi_transfer_8(1, 0x55); // Send 8 bits data * * \param bus Bus ID: 0 - system, 1 - user * \param bits Number of bits (max: 16). * \param data Command to send for each transfert. */ static inline void spi_set_command(uint8_t bus, uint8_t bits, uint16_t data) { if (!bits) return; SPI(bus).USER0 |= SPI_USER0_COMMAND; //enable COMMAND function in SPI module uint16_t command = data << (16 - bits); //align command data to high bits command = ((command >> 8) & 0xff) | ((command << 8) & 0xff00); //swap byte order SPI(bus).USER2 = SET_FIELD(SPI(bus).USER2, SPI_USER2_COMMAND_BITLEN, --bits); SPI(bus).USER2 = SET_FIELD(SPI(bus).USER2, SPI_USER2_COMMAND_VALUE, command); } /** * \brief Add permanent address bits when transfert data over SPI * Example: * * spi_set_address(1,8,0x45); // Set one address byte to 0x45 * for (uint8_t i = 0 ; i < x ; i++ ) { * spi_transfer_16(1,0xC584); // Send 16 bits address + 16 bits data x times * } * spi_clear_address(1); // Clear command * spi_transfer_16(1,0x55); // Send 16 bits data * * \param bus Bus ID: 0 - system, 1 - user * \param bits Number of bits (max: 32). * \param data Address to send for each transfert. */ static inline void spi_set_address(uint8_t bus, uint8_t bits, uint32_t data) { if (!bits) return; SPI(bus).USER0 |= SPI_USER0_ADDR; //enable ADDRess function in SPI module SPI(bus).ADDR = data << (32 - bits); //align address data to high bits SPI(bus).USER1 = SET_FIELD(SPI(bus).USER1, SPI_USER1_ADDR_BITLEN, --bits); } /** * \brief Add permanent dummy bits when transfert data over SPI * Example: * * spi_set_dummy_bits(1, 4, false); // Set 4 dummy bit before Dout * for (uint8_t i = 0; i < x; i++ ) { * spi_transfer_16(1, 0xC584); // Send 4 bits dummy + 16 bits Dout x times * } * spi_set_dummy_bits(1, 4, true); // Set 4 dummy bit between Dout and Din * spi_transfer_8(1, 0x55); // Send 8 bits Dout + 4 bits dummy + 8 bits Din * * \param bus Bus ID: 0 - system, 1 - user * \param bits Number of bits * \param pos Position of dummy bit, between Dout and Din if true. */ static inline void spi_set_dummy_bits(uint8_t bus, uint8_t bits, bool pos) { if (!bits) return; if (pos) SPI(bus).USER0 |= SPI_USER0_MISO; // Dummy bit will be between Dout and Din data if set SPI(bus).USER0 |= SPI_USER0_DUMMY; //enable dummy bits SPI(bus).USER1 = SET_FIELD(SPI(bus).USER1, SPI_USER1_DUMMY_CYCLELEN, --bits); } /** * \brief Clear adress Bits * \param bus Bus ID: 0 - system, 1 - user */ static inline void spi_clear_address(uint8_t bus) { SPI(bus).USER0 &= ~(SPI_USER0_ADDR); } /** * \brief Clear command Bits * \param bus Bus ID: 0 - system, 1 - user */ static inline void spi_clear_command(uint8_t bus) { SPI(bus).USER0 &= ~(SPI_USER0_COMMAND); } /** * \brief Clear dummy Bits * \param bus Bus ID: 0 - system, 1 - user */ static inline void spi_clear_dummy(uint8_t bus) { SPI(bus).USER0 &= ~(SPI_USER0_DUMMY | SPI_USER0_MISO); } /** * \brief Send many 8 bits template over SPI * \param bus Bus ID: 0 - system, 1 - user * \param data Byte template (8 bits) * \param repeats Copy byte number */ void spi_repeat_send_8(uint8_t bus, uint8_t data, int32_t repeats); /** * \brief Send many 16 bits template over SPI * \param bus Bus ID: 0 - system, 1 - user * \param data Word template (16 bits) * \param repeats Copy word number */ void spi_repeat_send_16(uint8_t bus, uint16_t data, int32_t repeats); /** * \brief Send many 32 bits template over SPI * \param bus Bus ID: 0 - system, 1 - user * \param data Dualword template (32 bits) * \param repeats Copy dword number */ void spi_repeat_send_32(uint8_t bus, uint32_t data, int32_t repeats); /** * \brief Repeatedly send byte over SPI and receive data * \param bus Bus ID: 0 - system, 1 - user * \param out_byte Byte to send * \param in_data Receive buffer * \param len Buffer size in words * \param word_size Size of the word */ void spi_read(uint8_t bus, uint8_t out_byte, void *in_data, size_t len, spi_word_size_t word_size); #ifdef __cplusplus } #endif #endif /* _ESP_SPI_H_ */