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/* $Id: sbus.h,v 1.15 1998/05/22 14:33:36 jj Exp $
 * sbus.h:  Defines for the Sun SBus.
 *
 * Copyright (C) 1995 David S. Miller (davem@caip.rutgers.edu)
 */

#ifndef _SPARC_SBUS_H
#define _SPARC_SBUS_H

#include <asm/oplib.h>
#include <asm/iommu.h>

/* We scan which devices are on the SBus using the PROM node device
 * tree.  SBus devices are described in two different ways.  You can
 * either get an absolute address at which to access the device, or
 * you can get a SBus 'slot' number and an offset within that slot.
 */

/* The base address at which to calculate device OBIO addresses. */
#define SUN_SBUS_BVADDR        0xf8000000
#define SBUS_OFF_MASK          0x01ffffff

/* These routines are used to calculate device address from slot
 * numbers + offsets, and vice versa.
 */

extern __inline__ unsigned long sbus_devaddr(int slotnum, unsigned long offset)
{
  return (unsigned long) (SUN_SBUS_BVADDR+((slotnum)<<25)+(offset));
}

extern __inline__ int sbus_dev_slot(unsigned long dev_addr)
{
  return (int) (((dev_addr)-SUN_SBUS_BVADDR)>>25);
}

extern __inline__ unsigned long sbus_dev_offset(unsigned long dev_addr)
{
  return (unsigned long) (((dev_addr)-SUN_SBUS_BVADDR)&SBUS_OFF_MASK);
}

struct linux_sbus;

/* Linux SBUS device tables */
struct linux_sbus_device {
  struct linux_sbus_device *next;      /* next device on this SBus or null */
  struct linux_sbus_device *child;     /* For ledma and espdma on sun4m */
  struct linux_sbus *my_bus;           /* Back ptr to sbus */
  int prom_node;                       /* PROM device tree node for this device */
  char prom_name[32];                  /* PROM device name */

  struct linux_prom_registers reg_addrs[PROMREG_MAX];
  int num_registers, ranges_applied;

  unsigned int irqs[4];
  int num_irqs;

  unsigned long sbus_addr;             /* Absolute base address for device. */
  unsigned long sbus_vaddrs[PROMVADDR_MAX];
  unsigned long num_vaddrs;
  unsigned long offset;                /* Offset given by PROM */
  int slot;
};

/* This struct describes the SBus(s) found on this machine. */
struct linux_sbus {
	struct linux_sbus *next;             /* next SBus, if more than one SBus */
	struct linux_sbus_device *devices;   /* Link to devices on this SBus */
	struct iommu_struct *iommu;          /* IOMMU for this sbus if applicable */
	int prom_node;                       /* PROM device tree node for this SBus */
	char prom_name[16];                  /* Usually "sbus" or "sbi" */
	int clock_freq;
	struct linux_prom_ranges sbus_ranges[PROMREG_MAX];
	int num_sbus_ranges;
	int devid;
	int board;
};

extern struct linux_sbus *SBus_chain;

extern __inline__ int
sbus_is_slave(struct linux_sbus_device *dev)
{
	/* Have to write this for sun4c's */
	return 0;
}

/* Device probing routines could find these handy */
#define for_each_sbus(bus) \
        for((bus) = SBus_chain; (bus); (bus)=(bus)->next)

#define for_each_sbusdev(device, bus) \
        for((device) = (bus)->devices; (device); (device)=(device)->next)
        
#define for_all_sbusdev(device, bus) \
	for((bus) = SBus_chain, (device) = (bus)->devices; (bus); (device)=((device)->next ? (device)->next : ((bus) = (bus)->next, (bus) ? (bus)->devices : 0)))

/* Apply promlib probed SBUS ranges to registers. */
extern void prom_apply_sbus_ranges(struct linux_sbus *sbus, 
				   struct linux_prom_registers *sbusregs,
				   int nregs, struct linux_sbus_device *sdev);

#endif /* !(_SPARC_SBUS_H) */