* Rewritten for new CAN queues by Pavel Pisa - OCERA team member
* email:pisa@cmp.felk.cvut.cz
* This software is released under the GPL-License.
* Rewritten for new CAN queues by Pavel Pisa - OCERA team member
* email:pisa@cmp.felk.cvut.cz
* This software is released under the GPL-License.
-#include <linux/autoconf.h>
-
-#include <linux/ioport.h>
-#include <linux/delay.h>
-#include <asm/errno.h>
-#include <asm/io.h>
-
+#include "../include/can.h"
+#include "../include/can_sysdep.h"
#include "../include/main.h"
#include "../include/pc-i03.h"
#include "../include/sja1000.h"
#include "../include/main.h"
#include "../include/pc-i03.h"
#include "../include/sja1000.h"
- * pci03_request_io: - reserve io memory
- * @io_addr: The reserved memory starts at @io_addr, wich is the module
- * parameter @io.
+ * pci03_request_io: - reserve io or memory range for can board
+ * @candev: pointer to candevice/board which asks for io. Field @io_addr
+ * of @candev is used in most cases to define start of the range
*
* The function pci03_request_io() is used to reserve the io-memory. If your
* hardware uses a dedicated memory range as hardware control registers you
*
* The function pci03_request_io() is used to reserve the io-memory. If your
* hardware uses a dedicated memory range as hardware control registers you
- * pci03_release_io - free reserved io-memory
- * @io_addr: Start of the memory range to be released.
+ * pci03_elease_io - free reserved io memory range
+ * @candev: pointer to candevice/board which releases io
*
* The function pci03_release_io() is used to free reserved io-memory.
* In case you have reserved more io memory, don't forget to free it here.
*
* The function pci03_release_io() is used to free reserved io-memory.
* In case you have reserved more io memory, don't forget to free it here.
*
* The function pci03_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 pci03_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 pci03_init_hw_data() is used to initialize the hardware
* structure containing information about the installed CAN-board.
* %RESET_ADDR represents the io-address of the hardware reset register.
* %NR_82527 represents the number of intel 82527 chips on the board.
* %NR_SJA1000 represents the number of philips sja1000 chips on the board.
*
* The function pci03_init_hw_data() is used to initialize the hardware
* structure containing information about the installed CAN-board.
* %RESET_ADDR represents the io-address of the hardware reset register.
* %NR_82527 represents the number of intel 82527 chips on the board.
* %NR_SJA1000 represents the number of philips sja1000 chips on the board.
* @chipnr: Number of the CAN chip on the hardware card
*
* The function pci03_init_chip_data() is used to initialize the hardware
* @chipnr: Number of the CAN chip on the hardware card
*
* The function pci03_init_chip_data() is used to initialize the hardware
* The @clock entry holds the chip clock value in Hz.
* The entry @sja_cdr_reg holds hardware specific options for the Clock Divider
* register. Options defined in the %sja1000.h file:
* The @clock entry holds the chip clock value in Hz.
* The entry @sja_cdr_reg holds hardware specific options for the Clock Divider
* register. Options defined in the %sja1000.h file:
- * %CDR_CLKOUT_MASK, %CDR_CLK_OFF, %CDR_RXINPEN, %CDR_CBP, %CDR_PELICAN
+ * %sjaCDR_CLKOUT_MASK, %sjaCDR_CLK_OFF, %sjaCDR_RXINPEN, %sjaCDR_CBP, %sjaCDR_PELICAN
* The entry @sja_ocr_reg holds hardware specific options for the Output Control
* register. Options defined in the %sja1000.h file:
* The entry @sja_ocr_reg holds hardware specific options for the Output Control
* register. Options defined in the %sja1000.h file:
- * %OCR_MODE_BIPHASE, %OCR_MODE_TEST, %OCR_MODE_NORMAL, %OCR_MODE_CLOCK,
- * %OCR_TX0_LH, %OCR_TX1_ZZ.
+ * %sjaOCR_MODE_BIPHASE, %sjaOCR_MODE_TEST, %sjaOCR_MODE_NORMAL, %sjaOCR_MODE_CLOCK,
+ * %sjaOCR_TX0_LH, %sjaOCR_TX1_ZZ.
* 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_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.
- candev->chip[chipnr]->sja_cdr_reg = CDR_CBP | CDR_CLK_OFF;
- candev->chip[chipnr]->sja_ocr_reg = OCR_MODE_NORMAL |
- OCR_TX0_HL | OCR_TX1_LZ;
+ candev->chip[chipnr]->sja_cdr_reg = sjaCDR_CBP | sjaCDR_CLK_OFF;
+ candev->chip[chipnr]->sja_ocr_reg = sjaOCR_MODE_NORMAL |
+ sjaOCR_TX0_HL | sjaOCR_TX1_LZ;
* @objnr: Number of the message buffer
*
* The function pci03_init_obj_data() is used to initialize the hardware
* @objnr: Number of the message buffer
*
* The function pci03_init_obj_data() is used to initialize the hardware
*
* The function pci03_program_irq() is used for hardware that uses
* programmable interrupts. If your hardware doesn't use programmable interrupts
*
* The function pci03_program_irq() is used for hardware that uses
* programmable interrupts. If your hardware doesn't use programmable interrupts
* 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
* 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