#ifndef RTEMS_LIBI2C_H #define RTEMS_LIBI2C_H /*$Id$*/ #include #include #ifdef __cplusplus extern "C" { #endif /* Simple I2C driver API */ /* Initialize the libary - may fail if no semaphore or no driver slot is available */ int rtems_libi2c_initialize (); /* Bus Driver API * * Bus drivers provide access to low-level i2c functions * such as 'send start', 'send address', 'get bytes' etc. */ /* first field must be a pointer to ops; driver * may add its own fields after this. * the struct that is registered with the library * is not copied; a pointer will we passed * to the callback functions (ops). */ typedef struct rtems_libi2c_bus_t_ { struct rtems_libi2c_bus_ops_ *ops; int size; /* size of whole structure */ } rtems_libi2c_bus_t; /* Access functions a low level driver must provide; * * All of these, except read_bytes and write_bytes * return RTEMS_SUCCESSFUL on success and an error status * otherwise. The read and write ops return the number * of chars read/written or -(status code) on error. */ typedef struct rtems_libi2c_bus_ops_ { /* Initialize the bus; might be called again to reset the bus driver */ rtems_status_code (*init) (rtems_libi2c_bus_t * bushdl); /* Send start condition */ rtems_status_code (*send_start) (rtems_libi2c_bus_t * bushdl); /* Send stop condition */ rtems_status_code (*send_stop) (rtems_libi2c_bus_t * bushdl); /* initiate transfer from (rw!=0) or to a device */ rtems_status_code (*send_addr) (rtems_libi2c_bus_t * bushdl, unsigned32 addr, int rw); /* read a number of bytes */ int (*read_bytes) (rtems_libi2c_bus_t * bushdl, unsigned char *bytes, int nbytes); /* write a number of bytes */ int (*write_bytes) (rtems_libi2c_bus_t * bushdl, unsigned char *bytes, int nbytes); } rtems_libi2c_bus_ops_t; /* * Register a lowlevel driver * * TODO: better description * * This allocates a major number identifying *this* driver * (i.e., libi2c) and the minor number encodes a bus# and a i2c address. * * The name will be registered in the filesystem (parent * directories must exist). It may be NULL in which case * the library will pick a default. * * RETURNS: bus # (>=0) or -1 on error (errno set). */ int rtems_libi2c_register_bus (char *name, rtems_libi2c_bus_t * bus); extern rtems_device_major_number rtems_libi2c_major; #define RTEMS_LIBI2C_MAKE_MINOR(busno, i2caddr) \ ((((busno)&((1<<3)-1))<<10) | ((i2caddr)&((1<<10)-1))) /* After the library is initialized, a major number is available. * As soon as a low-level bus driver is registered (above routine * returns a 'busno'), a device node can be created in the filesystem * with a major/minor number pair of * * rtems_libi2c_major / RTEMS_LIBI2C_MAKE_MINOR(busno, i2caddr) * * and a 'raw' hi-level driver is then attached to this device * node. * This 'raw' driver has very simple semantics: * * 'open' sends a start condition * 'read'/'write' address the device identified by the i2c bus# and address * encoded in the minor number and read or write, respectively * a stream of bytes from or to the device. Every time the * direction is changed, a 're-start' condition followed by * an 'address' cycle is generated on the i2c bus. * 'close' sends a stop condition. * * Hence, using the 'raw' driver, e.g., 100 bytes at offset 0x200 can be * read from an EEPROM by the following pseudo-code: * * mknod("/dev/i2c-54", mode, MKDEV(rtems_libi2c_major, RTEMS_LIBI2C_MAKE_MINOR(0,0x54))) * * int fd; * char off[2]={0x02,0x00}; * * fd = open("/dev/i2c-54",O_RDWR); * write(fd,off,2); * read(fd,buf,100); * close(fd); * */ /* Higher Level Driver API * * Higher level drivers know how to deal with specific i2c * devices (independent of the bus interface chip) and provide * an abstraction, i.e., the usual read/write/ioctl access. * * Using the above example, such a high level driver could * prevent the user from issuing potentially destructive write * operations (the aforementioned EEPROM interprets any 3rd * and following byte written to the device as data, i.e., the * contents could easily be changed!). * The correct 'read-pointer offset' programming could be * implemented in 'open' and 'ioctl' of a high-level driver and * the user would then only have to perform harmless read * operations, e.g., * * fd = open("/dev/i2c.eeprom",O_RDONLY) / * opens and sets EEPROM read pointer * / * ioctl(fd, IOCTL_SEEK, 0x200) / * repositions the read pointer * / * read(fd, buf, 100) * close(fd) * */ /* struct provided at driver registration. The driver may store * private data behind the mandatory first fields but the size * must be set to the size of the entire struct, e.g., * * struct driver_pvt { * rtems_libi2c_drv_t pub; * struct { ... } pvt; * } my_driver = { * { ops: my_ops, * size: sizeof(my_driver) * }, * { ...}; * }; * * A pointer to this struct is passed to the callback ops. */ typedef struct rtems_libi2c_drv_t_ { rtems_driver_address_table *ops; /* the driver ops */ int size; /* size of whole structure (including appended private data) */ } rtems_libi2c_drv_t; /* * The high level driver must be registered with a particular * bus number and i2c address. * * The registration procedure also creates a filesystem node, * i.e., the returned minor number is not really needed. * * If the 'name' argument is NULL, no filesystem node is * created (but this can be done 'manually' using rtems_libi2c_major * and the return value of this routine). * * RETURNS minor number (FYI) or -1 on failure */ int rtems_libi2c_register_drv (char *name, rtems_libi2c_drv_t * drvtbl, unsigned bus, unsigned i2caddr); /* Operations available to high level drivers */ /* NOTES: The bus a device is attached to is LOCKED from the first send_start * until send_stop is executed! * * Bus tenure MUST NOT span multiple system calls - otherwise, a single * thread could get into the protected sections (or would deadlock if the * mutex was not nestable). * E.g., consider what happens if 'open' sends a 'start' and 'close' * sends a 'stop' (i.e., the bus mutex would be locked in 'open' and * released in 'close'. A single thread could try to open two devices * on the same bus and would either deadlock or nest into the bus mutex * and potentially mess up the i2c messages. * * The correct way is to *always* relinquish the i2c bus (i.e., send 'stop' * from any driver routine prior to returning control to the caller. * Consult the implementation of the generic driver routines (open, close, ...) * below or the examples in i2c-2b-eeprom.c and i2c-2b-ds1621.c * * Drivers just pass the minor number on to these routines... */ rtems_status_code rtems_libi2c_send_start (rtems_device_minor_number minor); rtems_status_code rtems_libi2c_send_stop (rtems_device_minor_number minor); rtems_status_code rtems_libi2c_send_addr (rtems_device_minor_number minor, int rw); /* the read/write routines return the number of bytes transferred * or -(status_code) on error. */ int rtems_libi2c_read_bytes (rtems_device_minor_number minor, unsigned char *bytes, int nbytes); int rtems_libi2c_write_bytes (rtems_device_minor_number minor, unsigned char *bytes, int nbytes); /* Send start, send address and read bytes */ int rtems_libi2c_start_read_bytes (unsigned32 minor, unsigned char *bytes, int nbytes); /* Send start, send address and write bytes */ int rtems_libi2c_start_write_bytes (unsigned32 minor, unsigned char *bytes, int nbytes); #ifdef __cplusplus } #endif #endif