*
* The function eb8245_request_io() is used to reserve the io-memory. If your
* hardware uses a dedicated memory range as hardware control registers you
- * will have to add the code to reserve this memory as well.
+ * will have to add the code to reserve this memory as well.
* %IO_RANGE is the io-memory range that gets reserved, please adjust according
* your hardware. Example: #define IO_RANGE 0x100 for i82527 chips or
* #define IO_RANGE 0x20 for sja1000 chips in basic CAN mode.
int eb8245_request_io(struct candevice_t *candev)
{
can_ioptr_t remap_addr;
-
+
if (!can_request_mem_region(candev->io_addr,IO_RANGE,DEVICE_NAME " - eb8245")) {
CANMSG("Unable to request IO-memory: 0x%lx\n",candev->io_addr);
return -ENODEV;
CANMSG("Unable to access I/O memory at: 0x%lx\n", candev->io_addr);
can_release_mem_region(candev->io_addr,IO_RANGE);
return -ENODEV;
-
+
}
can_base_addr_fixup(candev, remap_addr);
DEBUGMSG("Registered IO-memory: 0x%lx - 0x%lx\n", candev->io_addr, candev->io_addr + IO_RANGE - 1);
* eb8245_reset - hardware reset routine
* @candev: Pointer to candevice/board structure
*
- * The function eb8245_reset() is used to give a hardware reset. This is
- * rather hardware specific so I haven't included example code. Don't forget to
+ * The function eb8245_reset() is used to give a hardware reset. This is
+ * rather hardware specific so I haven't included example code. Don't forget to
* check the reset status of the chip before returning.
* Return Value: The function returns zero on success or %-ENODEV on failure
* File: src/eb8245.c
int i;
struct canchip_t *chip=candev->chip[0];
unsigned cdr;
-
+
eb8245_write_register(sjaMOD_RM, chip->chip_base_addr+SJAMOD);
udelay(1000);
-
+
cdr=eb8245_read_register(chip->chip_base_addr+SJACDR);
eb8245_write_register(cdr|sjaCDR_PELICAN, chip->chip_base_addr+SJACDR);
eb8245_write_register(cdr|sjaCDR_PELICAN, chip->chip_base_addr+SJACDR);
eb8245_write_register(0, chip->chip_base_addr+SJAIER);
-
+
return 0;
}
* Return Value: The function always returns zero
* File: src/eb8245.c
*/
-int eb8245_init_hw_data(struct candevice_t *candev)
+int eb8245_init_hw_data(struct candevice_t *candev)
{
candev->res_addr=RESET_ADDR;
candev->nr_82527_chips=0;
* The entry @int_clk_reg holds hardware specific options for the Clock Out
* register. Options defined in the %i82527.h file:
* %iCLK_CD0, %iCLK_CD1, %iCLK_CD2, %iCLK_CD3, %iCLK_SL0, %iCLK_SL1.
- * The entry @int_bus_reg holds hardware specific options for the Bus
+ * The entry @int_bus_reg holds hardware specific options for the Bus
* Configuration register. Options defined in the %i82527.h file:
* %iBUS_DR0, %iBUS_DR1, %iBUS_DT1, %iBUS_POL, %iBUS_CBY.
* The entry @int_cpu_reg holds hardware specific options for the cpu interface
* CAN chip. In case of the sja1000 there's only one message object but on the
* i82527 chip there are 15.
* The code below is for a i82527 chip and initializes the object base addresses
- * The entry @obj_base_addr represents the first memory address of the message
+ * The entry @obj_base_addr represents the first memory address of the message
* object. In case of the sja1000 @obj_base_addr is taken the same as the chips
* base address.
* Unless the hardware uses a segmented memory map, flags can be set zero.
* eb8245_program_irq - program interrupts
* @candev: Pointer to candevice/board structure
*
- * The function eb8245_program_irq() is used for hardware that uses
+ * The function eb8245_program_irq() is used for hardware that uses
* programmable interrupts. If your hardware doesn't use programmable interrupts
- * you should not set the @candevices_t->flags entry to %CANDEV_PROGRAMMABLE_IRQ and
- * leave this function unedited. Again this function is hardware specific so
+ * you should not set the @candevices_t->flags entry to %CANDEV_PROGRAMMABLE_IRQ and
+ * leave this function unedited. Again this function is hardware specific so
* there's no example code.
* Return value: The function returns zero on success or %-ENODEV on failure
* File: src/eb8245.c
projects / lincan.git / blobdiff