/* SPDX-License-Identifier: GPL-2.0-or-later */ /* * Common library for ADIS16XXX devices * * Copyright 2012 Analog Devices Inc. * Author: Lars-Peter Clausen */ #ifndef __IIO_ADIS_H__ #define __IIO_ADIS_H__ #include #include #include #define ADIS_WRITE_REG(reg) ((0x80 | (reg))) #define ADIS_READ_REG(reg) ((reg) & 0x7f) #define ADIS_PAGE_SIZE 0x80 #define ADIS_REG_PAGE_ID 0x00 struct adis; struct adis_burst; /** * struct adis_timeouts - ADIS chip variant timeouts * @reset_ms - Wait time after rst pin goes inactive * @sw_reset_ms - Wait time after sw reset command * @self_test_ms - Wait time after self test command */ struct adis_timeout { u16 reset_ms; u16 sw_reset_ms; u16 self_test_ms; }; /** * struct adis_data - ADIS chip variant specific data * @read_delay: SPI delay for read operations in us * @write_delay: SPI delay for write operations in us * @cs_change_delay: SPI delay between CS changes in us * @glob_cmd_reg: Register address of the GLOB_CMD register * @msc_ctrl_reg: Register address of the MSC_CTRL register * @diag_stat_reg: Register address of the DIAG_STAT register * @prod_id_reg: Register address of the PROD_ID register * @prod_id: Product ID code that should be expected when reading @prod_id_reg * @self_test_mask: Bitmask of supported self-test operations * @self_test_reg: Register address to request self test command * @self_test_no_autoclear: True if device's self-test needs clear of ctrl reg * @status_error_msgs: Array of error messgaes * @status_error_mask: Bitmask of errors supported by the device * @timeouts: Chip specific delays * @enable_irq: Hook for ADIS devices that have a special IRQ enable/disable * @has_paging: True if ADIS device has paged registers */ struct adis_data { unsigned int read_delay; unsigned int write_delay; unsigned int cs_change_delay; unsigned int glob_cmd_reg; unsigned int msc_ctrl_reg; unsigned int diag_stat_reg; unsigned int prod_id_reg; unsigned int prod_id; unsigned int self_test_mask; unsigned int self_test_reg; bool self_test_no_autoclear; const struct adis_timeout *timeouts; const char * const *status_error_msgs; unsigned int status_error_mask; int (*enable_irq)(struct adis *adis, bool enable); bool has_paging; }; /** * struct adis - ADIS device instance data * @spi: Reference to SPI device which owns this ADIS IIO device * @trig: IIO trigger object data * @data: ADIS chip variant specific data * @burst: ADIS burst transfer information * @burst_extra_len: Burst extra length. Should only be used by devices that can * dynamically change their burst mode length. * @state_lock: Lock used by the device to protect state * @msg: SPI message object * @xfer: SPI transfer objects to be used for a @msg * @current_page: Some ADIS devices have registers, this selects current page * @irq_flag: IRQ handling flags as passed to request_irq() * @buffer: Data buffer for information read from the device * @tx: DMA safe TX buffer for SPI transfers * @rx: DMA safe RX buffer for SPI transfers */ struct adis { struct spi_device *spi; struct iio_trigger *trig; const struct adis_data *data; struct adis_burst *burst; unsigned int burst_extra_len; /** * The state_lock is meant to be used during operations that require * a sequence of SPI R/W in order to protect the SPI transfer * information (fields 'xfer', 'msg' & 'current_page') between * potential concurrent accesses. * This lock is used by all "adis_{functions}" that have to read/write * registers. These functions also have unlocked variants * (see "__adis_{functions}"), which don't hold this lock. * This allows users of the ADIS library to group SPI R/W into * the drivers, but they also must manage this lock themselves. */ struct mutex state_lock; struct spi_message msg; struct spi_transfer *xfer; unsigned int current_page; unsigned long irq_flag; void *buffer; uint8_t tx[10] ____cacheline_aligned; uint8_t rx[4]; }; int adis_init(struct adis *adis, struct iio_dev *indio_dev, struct spi_device *spi, const struct adis_data *data); int __adis_reset(struct adis *adis); /** * adis_reset() - Reset the device * @adis: The adis device * * Returns 0 on success, a negative error code otherwise */ static inline int adis_reset(struct adis *adis) { int ret; mutex_lock(&adis->state_lock); ret = __adis_reset(adis); mutex_unlock(&adis->state_lock); return ret; } int __adis_write_reg(struct adis *adis, unsigned int reg, unsigned int val, unsigned int size); int __adis_read_reg(struct adis *adis, unsigned int reg, unsigned int *val, unsigned int size); /** * __adis_write_reg_8() - Write single byte to a register (unlocked) * @adis: The adis device * @reg: The address of the register to be written * @value: The value to write */ static inline int __adis_write_reg_8(struct adis *adis, unsigned int reg, uint8_t val) { return __adis_write_reg(adis, reg, val, 1); } /** * __adis_write_reg_16() - Write 2 bytes to a pair of registers (unlocked) * @adis: The adis device * @reg: The address of the lower of the two registers * @value: Value to be written */ static inline int __adis_write_reg_16(struct adis *adis, unsigned int reg, uint16_t val) { return __adis_write_reg(adis, reg, val, 2); } /** * __adis_write_reg_32() - write 4 bytes to four registers (unlocked) * @adis: The adis device * @reg: The address of the lower of the four register * @value: Value to be written */ static inline int __adis_write_reg_32(struct adis *adis, unsigned int reg, uint32_t val) { return __adis_write_reg(adis, reg, val, 4); } /** * __adis_read_reg_16() - read 2 bytes from a 16-bit register (unlocked) * @adis: The adis device * @reg: The address of the lower of the two registers * @val: The value read back from the device */ static inline int __adis_read_reg_16(struct adis *adis, unsigned int reg, uint16_t *val) { unsigned int tmp; int ret; ret = __adis_read_reg(adis, reg, &tmp, 2); if (ret == 0) *val = tmp; return ret; } /** * __adis_read_reg_32() - read 4 bytes from a 32-bit register (unlocked) * @adis: The adis device * @reg: The address of the lower of the two registers * @val: The value read back from the device */ static inline int __adis_read_reg_32(struct adis *adis, unsigned int reg, uint32_t *val) { unsigned int tmp; int ret; ret = __adis_read_reg(adis, reg, &tmp, 4); if (ret == 0) *val = tmp; return ret; } /** * adis_write_reg() - write N bytes to register * @adis: The adis device * @reg: The address of the lower of the two registers * @value: The value to write to device (up to 4 bytes) * @size: The size of the @value (in bytes) */ static inline int adis_write_reg(struct adis *adis, unsigned int reg, unsigned int val, unsigned int size) { int ret; mutex_lock(&adis->state_lock); ret = __adis_write_reg(adis, reg, val, size); mutex_unlock(&adis->state_lock); return ret; } /** * adis_read_reg() - read N bytes from register * @adis: The adis device * @reg: The address of the lower of the two registers * @val: The value read back from the device * @size: The size of the @val buffer */ static int adis_read_reg(struct adis *adis, unsigned int reg, unsigned int *val, unsigned int size) { int ret; mutex_lock(&adis->state_lock); ret = __adis_read_reg(adis, reg, val, size); mutex_unlock(&adis->state_lock); return ret; } /** * adis_write_reg_8() - Write single byte to a register * @adis: The adis device * @reg: The address of the register to be written * @value: The value to write */ static inline int adis_write_reg_8(struct adis *adis, unsigned int reg, uint8_t val) { return adis_write_reg(adis, reg, val, 1); } /** * adis_write_reg_16() - Write 2 bytes to a pair of registers * @adis: The adis device * @reg: The address of the lower of the two registers * @value: Value to be written */ static inline int adis_write_reg_16(struct adis *adis, unsigned int reg, uint16_t val) { return adis_write_reg(adis, reg, val, 2); } /** * adis_write_reg_32() - write 4 bytes to four registers * @adis: The adis device * @reg: The address of the lower of the four register * @value: Value to be written */ static inline int adis_write_reg_32(struct adis *adis, unsigned int reg, uint32_t val) { return adis_write_reg(adis, reg, val, 4); } /** * adis_read_reg_16() - read 2 bytes from a 16-bit register * @adis: The adis device * @reg: The address of the lower of the two registers * @val: The value read back from the device */ static inline int adis_read_reg_16(struct adis *adis, unsigned int reg, uint16_t *val) { unsigned int tmp; int ret; ret = adis_read_reg(adis, reg, &tmp, 2); if (ret == 0) *val = tmp; return ret; } /** * adis_read_reg_32() - read 4 bytes from a 32-bit register * @adis: The adis device * @reg: The address of the lower of the two registers * @val: The value read back from the device */ static inline int adis_read_reg_32(struct adis *adis, unsigned int reg, uint32_t *val) { unsigned int tmp; int ret; ret = adis_read_reg(adis, reg, &tmp, 4); if (ret == 0) *val = tmp; return ret; } int __adis_update_bits_base(struct adis *adis, unsigned int reg, const u32 mask, const u32 val, u8 size); /** * adis_update_bits_base() - ADIS Update bits function - Locked version * @adis: The adis device * @reg: The address of the lower of the two registers * @mask: Bitmask to change * @val: Value to be written * @size: Size of the register to update * * Updates the desired bits of @reg in accordance with @mask and @val. */ static inline int adis_update_bits_base(struct adis *adis, unsigned int reg, const u32 mask, const u32 val, u8 size) { int ret; mutex_lock(&adis->state_lock); ret = __adis_update_bits_base(adis, reg, mask, val, size); mutex_unlock(&adis->state_lock); return ret; } /** * adis_update_bits() - Wrapper macro for adis_update_bits_base - Locked version * @adis: The adis device * @reg: The address of the lower of the two registers * @mask: Bitmask to change * @val: Value to be written * * This macro evaluates the sizeof of @val at compile time and calls * adis_update_bits_base() accordingly. Be aware that using MACROS/DEFINES for * @val can lead to undesired behavior if the register to update is 16bit. */ #define adis_update_bits(adis, reg, mask, val) ({ \ BUILD_BUG_ON(sizeof(val) == 1 || sizeof(val) == 8); \ __builtin_choose_expr(sizeof(val) == 4, \ adis_update_bits_base(adis, reg, mask, val, 4), \ adis_update_bits_base(adis, reg, mask, val, 2)); \ }) /** * adis_update_bits() - Wrapper macro for adis_update_bits_base * @adis: The adis device * @reg: The address of the lower of the two registers * @mask: Bitmask to change * @val: Value to be written * * This macro evaluates the sizeof of @val at compile time and calls * adis_update_bits_base() accordingly. Be aware that using MACROS/DEFINES for * @val can lead to undesired behavior if the register to update is 16bit. */ #define __adis_update_bits(adis, reg, mask, val) ({ \ BUILD_BUG_ON(sizeof(val) == 1 || sizeof(val) == 8); \ __builtin_choose_expr(sizeof(val) == 4, \ __adis_update_bits_base(adis, reg, mask, val, 4), \ __adis_update_bits_base(adis, reg, mask, val, 2)); \ }) int adis_enable_irq(struct adis *adis, bool enable); int __adis_check_status(struct adis *adis); int __adis_initial_startup(struct adis *adis); static inline int adis_check_status(struct adis *adis) { int ret; mutex_lock(&adis->state_lock); ret = __adis_check_status(adis); mutex_unlock(&adis->state_lock); return ret; } /* locked version of __adis_initial_startup() */ static inline int adis_initial_startup(struct adis *adis) { int ret; mutex_lock(&adis->state_lock); ret = __adis_initial_startup(adis); mutex_unlock(&adis->state_lock); return ret; } int adis_single_conversion(struct iio_dev *indio_dev, const struct iio_chan_spec *chan, unsigned int error_mask, int *val); #define ADIS_VOLTAGE_CHAN(addr, si, chan, name, info_all, bits) { \ .type = IIO_VOLTAGE, \ .indexed = 1, \ .channel = (chan), \ .extend_name = name, \ .info_mask_separate = BIT(IIO_CHAN_INFO_RAW) | \ BIT(IIO_CHAN_INFO_SCALE), \ .info_mask_shared_by_all = info_all, \ .address = (addr), \ .scan_index = (si), \ .scan_type = { \ .sign = 'u', \ .realbits = (bits), \ .storagebits = 16, \ .endianness = IIO_BE, \ }, \ } #define ADIS_SUPPLY_CHAN(addr, si, info_all, bits) \ ADIS_VOLTAGE_CHAN(addr, si, 0, "supply", info_all, bits) #define ADIS_AUX_ADC_CHAN(addr, si, info_all, bits) \ ADIS_VOLTAGE_CHAN(addr, si, 1, NULL, info_all, bits) #define ADIS_TEMP_CHAN(addr, si, info_all, bits) { \ .type = IIO_TEMP, \ .indexed = 1, \ .channel = 0, \ .info_mask_separate = BIT(IIO_CHAN_INFO_RAW) | \ BIT(IIO_CHAN_INFO_SCALE) | \ BIT(IIO_CHAN_INFO_OFFSET), \ .info_mask_shared_by_all = info_all, \ .address = (addr), \ .scan_index = (si), \ .scan_type = { \ .sign = 'u', \ .realbits = (bits), \ .storagebits = 16, \ .endianness = IIO_BE, \ }, \ } #define ADIS_MOD_CHAN(_type, mod, addr, si, info_sep, info_all, bits) { \ .type = (_type), \ .modified = 1, \ .channel2 = IIO_MOD_ ## mod, \ .info_mask_separate = BIT(IIO_CHAN_INFO_RAW) | \ info_sep, \ .info_mask_shared_by_type = BIT(IIO_CHAN_INFO_SCALE), \ .info_mask_shared_by_all = info_all, \ .address = (addr), \ .scan_index = (si), \ .scan_type = { \ .sign = 's', \ .realbits = (bits), \ .storagebits = 16, \ .endianness = IIO_BE, \ }, \ } #define ADIS_ACCEL_CHAN(mod, addr, si, info_sep, info_all, bits) \ ADIS_MOD_CHAN(IIO_ACCEL, mod, addr, si, info_sep, info_all, bits) #define ADIS_GYRO_CHAN(mod, addr, si, info_sep, info_all, bits) \ ADIS_MOD_CHAN(IIO_ANGL_VEL, mod, addr, si, info_sep, info_all, bits) #define ADIS_INCLI_CHAN(mod, addr, si, info_sep, info_all, bits) \ ADIS_MOD_CHAN(IIO_INCLI, mod, addr, si, info_sep, info_all, bits) #define ADIS_ROT_CHAN(mod, addr, si, info_sep, info_all, bits) \ ADIS_MOD_CHAN(IIO_ROT, mod, addr, si, info_sep, info_all, bits) #ifdef CONFIG_IIO_ADIS_LIB_BUFFER /** * struct adis_burst - ADIS data for burst transfers * @en burst mode enabled * @reg_cmd register command that triggers burst * @extra_len extra length to account in the SPI RX buffer * @burst_max_len holds the maximum burst size when the device supports * more than one burst mode with different sizes */ struct adis_burst { bool en; unsigned int reg_cmd; const u32 extra_len; const u32 burst_max_len; }; int devm_adis_setup_buffer_and_trigger(struct adis *adis, struct iio_dev *indio_dev, irq_handler_t trigger_handler); int adis_setup_buffer_and_trigger(struct adis *adis, struct iio_dev *indio_dev, irqreturn_t (*trigger_handler)(int, void *)); void adis_cleanup_buffer_and_trigger(struct adis *adis, struct iio_dev *indio_dev); int devm_adis_probe_trigger(struct adis *adis, struct iio_dev *indio_dev); int adis_probe_trigger(struct adis *adis, struct iio_dev *indio_dev); void adis_remove_trigger(struct adis *adis); int adis_update_scan_mode(struct iio_dev *indio_dev, const unsigned long *scan_mask); #else /* CONFIG_IIO_BUFFER */ static inline int devm_adis_setup_buffer_and_trigger(struct adis *adis, struct iio_dev *indio_dev, irq_handler_t trigger_handler) { return 0; } static inline int adis_setup_buffer_and_trigger(struct adis *adis, struct iio_dev *indio_dev, irqreturn_t (*trigger_handler)(int, void *)) { return 0; } static inline void adis_cleanup_buffer_and_trigger(struct adis *adis, struct iio_dev *indio_dev) { } static inline int devm_adis_probe_trigger(struct adis *adis, struct iio_dev *indio_dev) { return 0; } static inline int adis_probe_trigger(struct adis *adis, struct iio_dev *indio_dev) { return 0; } static inline void adis_remove_trigger(struct adis *adis) { } #define adis_update_scan_mode NULL #endif /* CONFIG_IIO_BUFFER */ #ifdef CONFIG_DEBUG_FS int adis_debugfs_reg_access(struct iio_dev *indio_dev, unsigned int reg, unsigned int writeval, unsigned int *readval); #else #define adis_debugfs_reg_access NULL #endif #endif