/* * Copyright (c) 2015 Intel Corporation * * SPDX-License-Identifier: Apache-2.0 */ /** * @file * @brief Public legacy API for SPI drivers and applications */ #ifndef __SPI_LEGACY_H__ #define __SPI_LEGACY_H__ /** * @brief SPI Legacy interface * @defgroup spi_interface_legacy SPI Interface * @ingroup io_interfaces * @{ */ #include #include #include #ifdef __cplusplus extern "C" { #endif /** * @brief SPI Polarity & Phase Modes */ #define SPI_MODE_CPOL 0x1 #define SPI_MODE_CPHA 0x2 #define SPI_MODE_LOOP 0x4 #define SPI_MODE_MASK (0x7) #define SPI_MODE(_in_) ((_in_) & SPI_MODE_MASK) /** * @brief SPI Transfer modes (host controller dependent) */ #define SPI_TRANSFER_MSB (0 << 3) #define SPI_TRANSFER_LSB (1 << 3) #define SPI_TRANSFER_MASK (0x8) #define SPI_WORD_SIZE_MASK (0xFF << 4) #define SPI_WORD_SIZE_GET(_in_) (((_in_) & SPI_WORD_SIZE_MASK) >> 4) #define SPI_WORD(_in_) ((_in_) << 4) /** * @brief SPI configuration structure. * * config is a bit field with the following parts: * mode [ 0 : 2 ] - Polarity, phase and loop mode. * transfer_mode [ 3 ] - LSB or MSB first transfer mode. * word_size [ 4 : 11 ] - Size of a data frame in bits. * RESERVED [ 12 : 31 ] - Undefined or device-specific usage. * * max_sys_freq is the clock divider supported by the the host * spi controller. */ struct spi_config { u32_t config; u32_t max_sys_freq; }; /** * @typedef spi_api_configure * @brief Callback API upon configuring the const controller * See spi_configure() for argument description */ typedef int (*spi_api_configure)(struct device *dev, struct spi_config *config); /** * @typedef spi_api_slave_select * @brief Callback API upon selecting a slave * See spi_slave_select() for argument description */ typedef int (*spi_api_slave_select)(struct device *dev, u32_t slave); /** * @typedef spi_api_io * @brief Callback API for I/O * See spi_read() and spi_write() for argument descriptions */ typedef int (*spi_api_io)(struct device *dev, const void *tx_buf, u32_t tx_buf_len, void *rx_buf, u32_t rx_buf_len); struct spi_driver_api { spi_api_configure configure; spi_api_slave_select slave_select; spi_api_io transceive; }; /** * @brief Configure a host controller for operating against slaves. * @param dev Pointer to the device structure for the driver instance. * @param config Pointer to the configuration provided by the application. * * @retval 0 If successful. * @retval Negative errno code if failure. */ static inline int spi_configure(struct device *dev, struct spi_config *config) { const struct spi_driver_api *api = dev->driver_api; return api->configure(dev, config); } /** * @brief Select a slave to deal with. * * This routine is meaningful only if the controller supports per-slave * addressing: One SS line per-slave. If not, this routine has no effect * and daisy-chaining should be considered to deal with multiple slaves * on the same line. * * @param dev Pointer to the device structure for the driver instance * @param slave An integer identifying the slave. It starts from 1 which * corresponds to cs0. * * @retval 0 If successful. * @retval Negative errno code if failure. */ static inline int spi_slave_select(struct device *dev, u32_t slave) { const struct spi_driver_api *api = dev->driver_api; if (!api->slave_select) { return 0; } return api->slave_select(dev, slave); } /** * @brief Read the specified amount of data from the SPI driver. * @param dev Pointer to the device structure for the driver instance. * @param buf Memory buffer where data will be transferred. * @param len Size of the memory buffer available for writing. * * @retval 0 If successful. * @retval Negative errno code if failure. */ static inline int spi_read(struct device *dev, void *buf, u32_t len) { const struct spi_driver_api *api = dev->driver_api; return api->transceive(dev, NULL, 0, buf, len); } /** * @brief Write the specified amount of data from the SPI driver. * @param dev Pointer to the device structure for the driver instance. * @param buf Memory buffer from where data is transferred. * @param len Size of the memory buffer available for reading. * * @retval 0 If successful. * @retval Negative errno code if failure. */ static inline int spi_write(struct device *dev, const void *buf, u32_t len) { const struct spi_driver_api *api = dev->driver_api; return api->transceive(dev, buf, len, NULL, 0); } /** * @brief Read and write the specified amount of data from the SPI driver. * * This routine is meant for full-duplex transmission. * Only equal length is supported(tx_buf_len must be equal to rx_buf_len). * * @param dev Pointer to the device structure for the driver instance. * @param tx_buf Memory buffer where data originates * @param tx_buf_len Size of the memory buffer available for reading. * @param rx_buf Memory buffer where data is transferred. * @param rx_buf_len Size of the memory buffer available for writing. * * @retval 0 If successful. * @retval Negative errno code if failure. */ static inline int spi_transceive(struct device *dev, const void *tx_buf, u32_t tx_buf_len, void *rx_buf, u32_t rx_buf_len) { const struct spi_driver_api *api = dev->driver_api; return api->transceive(dev, tx_buf, tx_buf_len, rx_buf, rx_buf_len); } #ifdef __cplusplus } #endif /** * @} */ #endif /* __SPI_LEGACY_H__ */