phyus
/
linux-vybrid_public


			
				
					
						
						
							123456789101112131415161718192021222324252627282930313233343536373839404142434445464748495051525354555657585960616263646566676869707172737475767778798081828384858687888990919293949596979899100101102103104105106107108109110111112113114115116117118119120121122123124125126127128129130131132133134135136137138139140141142143144145146147148149150151152153154155156157158159160161162163164165166167168169170171172173174175176177178179180181182183184185186187188189190191192193194195196197198199200201202203204205206207208209210211212213214215216217218219220221222223224225226227228229230231232233234235236237238239240241
							/* $Id: pbm.h,v 1.27 2001/08/12 13:18:23 davem Exp $
 * pbm.h: UltraSparc PCI controller software state.
 *
 * Copyright (C) 1997, 1998, 1999 David S. Miller (davem@redhat.com)
 */

#ifndef __SPARC64_PBM_H
#define __SPARC64_PBM_H

#include <linux/types.h>
#include <linux/pci.h>
#include <linux/ioport.h>
#include <linux/spinlock.h>

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

/* The abstraction used here is that there are PCI controllers,
 * each with one (Sabre) or two (PSYCHO/SCHIZO) PCI bus modules
 * underneath.  Each PCI bus module uses an IOMMU (shared by both
 * PBMs of a controller, or per-PBM), and if a streaming buffer
 * is present, each PCI bus module has it's own. (ie. the IOMMU
 * might be shared between PBMs, the STC is never shared)
 * Furthermore, each PCI bus module controls it's own autonomous
 * PCI bus.
 */

struct pci_controller_info;

/* This contains the software state necessary to drive a PCI
 * controller's IOMMU.
 */
struct pci_iommu_arena {
	unsigned long	*map;
	unsigned int	hint;
	unsigned int	limit;
};

struct pci_iommu {
	/* This protects the controller's IOMMU and all
	 * streaming buffers underneath.
	 */
	spinlock_t	lock;

	struct pci_iommu_arena arena;

	/* IOMMU page table, a linear array of ioptes. */
	iopte_t		*page_table;		/* The page table itself. */

	/* Base PCI memory space address where IOMMU mappings
	 * begin.
	 */
	u32		page_table_map_base;

	/* IOMMU Controller Registers */
	unsigned long	iommu_control;		/* IOMMU control register */
	unsigned long	iommu_tsbbase;		/* IOMMU page table base register */
	unsigned long	iommu_flush;		/* IOMMU page flush register */
	unsigned long	iommu_ctxflush;		/* IOMMU context flush register */

	/* This is a register in the PCI controller, which if
	 * read will have no side-effects but will guarantee
	 * completion of all previous writes into IOMMU/STC.
	 */
	unsigned long	write_complete_reg;

	/* In order to deal with some buggy third-party PCI bridges that
	 * do wrong prefetching, we never mark valid mappings as invalid.
	 * Instead we point them at this dummy page.
	 */
	unsigned long	dummy_page;
	unsigned long	dummy_page_pa;

	/* CTX allocation. */
	unsigned long ctx_lowest_free;
	unsigned long ctx_bitmap[IOMMU_NUM_CTXS / (sizeof(unsigned long) * 8)];

	/* Here a PCI controller driver describes the areas of
	 * PCI memory space where DMA to/from physical memory
	 * are addressed.  Drivers interrogate the PCI layer
	 * if their device has addressing limitations.  They
	 * do so via pci_dma_supported, and pass in a mask of
	 * DMA address bits their device can actually drive.
	 *
	 * The test for being usable is:
	 * 	(device_mask & dma_addr_mask) == dma_addr_mask
	 */
	u32 dma_addr_mask;
};

extern void pci_iommu_table_init(struct pci_iommu *iommu, int tsbsize, u32 dma_offset, u32 dma_addr_mask);

/* This describes a PCI bus module's streaming buffer. */
struct pci_strbuf {
	int		strbuf_enabled;		/* Present and using it? */

	/* Streaming Buffer Control Registers */
	unsigned long	strbuf_control;		/* STC control register */
	unsigned long	strbuf_pflush;		/* STC page flush register */
	unsigned long	strbuf_fsync;		/* STC flush synchronization reg */
	unsigned long	strbuf_ctxflush;	/* STC context flush register */
	unsigned long	strbuf_ctxmatch_base;	/* STC context flush match reg */
	unsigned long	strbuf_flushflag_pa;	/* Physical address of flush flag */
	volatile unsigned long *strbuf_flushflag; /* The flush flag itself */

	/* And this is the actual flush flag area.
	 * We allocate extra because the chips require
	 * a 64-byte aligned area.
	 */
	volatile unsigned long	__flushflag_buf[(64 + (64 - 1)) / sizeof(long)];
};

#define PCI_STC_FLUSHFLAG_INIT(STC) \
	(*((STC)->strbuf_flushflag) = 0UL)
#define PCI_STC_FLUSHFLAG_SET(STC) \
	(*((STC)->strbuf_flushflag) != 0UL)

/* There can be quite a few ranges and interrupt maps on a PCI
 * segment.  Thus...
 */
#define PROM_PCIRNG_MAX		64
#define PROM_PCIIMAP_MAX	64

struct pci_pbm_info {
	/* PCI controller we sit under. */
	struct pci_controller_info	*parent;

	/* Physical address base of controller registers. */
	unsigned long			controller_regs;

	/* Physical address base of PBM registers. */
	unsigned long			pbm_regs;

	/* Physical address of DMA sync register, if any.  */
	unsigned long			sync_reg;

	/* Opaque 32-bit system bus Port ID. */
	u32				portid;

	/* Chipset version information. */
	int				chip_type;
#define PBM_CHIP_TYPE_SABRE		1
#define PBM_CHIP_TYPE_PSYCHO		2
#define PBM_CHIP_TYPE_SCHIZO		3
#define PBM_CHIP_TYPE_SCHIZO_PLUS	4
#define PBM_CHIP_TYPE_TOMATILLO		5
	int				chip_version;
	int				chip_revision;

	/* Name used for top-level resources. */
	char				name[64];

	/* OBP specific information. */
	int				prom_node;
	char				prom_name[64];
	struct linux_prom_pci_ranges	pbm_ranges[PROM_PCIRNG_MAX];
	int				num_pbm_ranges;
	struct linux_prom_pci_intmap	pbm_intmap[PROM_PCIIMAP_MAX];
	int				num_pbm_intmap;
	struct linux_prom_pci_intmask	pbm_intmask;
	u64				ino_bitmap;

	/* PBM I/O and Memory space resources. */
	struct resource			io_space;
	struct resource			mem_space;

	/* Base of PCI Config space, can be per-PBM or shared. */
	unsigned long			config_space;

	/* State of 66MHz capabilities on this PBM. */
	int				is_66mhz_capable;
	int				all_devs_66mhz;

	/* This PBM's streaming buffer. */
	struct pci_strbuf		stc;

	/* IOMMU state, potentially shared by both PBM segments. */
	struct pci_iommu		*iommu;

	/* PCI slot mapping. */
	unsigned int			pci_first_slot;

	/* Now things for the actual PCI bus probes. */
	unsigned int			pci_first_busno;
	unsigned int			pci_last_busno;
	struct pci_bus			*pci_bus;
};

struct pci_controller_info {
	/* List of all PCI controllers. */
	struct pci_controller_info	*next;

	/* Each controller gets a unique index, used mostly for
	 * error logging purposes.
	 */
	int				index;

	/* Do the PBMs both exist in the same PCI domain? */
	int				pbms_same_domain;

	/* The PCI bus modules controlled by us. */
	struct pci_pbm_info		pbm_A;
	struct pci_pbm_info		pbm_B;

	/* Operations which are controller specific. */
	void (*scan_bus)(struct pci_controller_info *);
	unsigned int (*irq_build)(struct pci_pbm_info *, struct pci_dev *, unsigned int);
	void (*base_address_update)(struct pci_dev *, int);
	void (*resource_adjust)(struct pci_dev *, struct resource *, struct resource *);

	/* Now things for the actual PCI bus probes. */
	struct pci_ops			*pci_ops;
	unsigned int			pci_first_busno;
	unsigned int			pci_last_busno;

	void				*starfire_cookie;
};

/* PCI devices which are not bridges have this placed in their pci_dev
 * sysdata member.  This makes OBP aware PCI device drivers easier to
 * code.
 */
struct pcidev_cookie {
	struct pci_pbm_info		*pbm;
	char				prom_name[64];
	int				prom_node;
	struct linux_prom_pci_registers	prom_regs[PROMREG_MAX];
	int num_prom_regs;
	struct linux_prom_pci_registers prom_assignments[PROMREG_MAX];
	int num_prom_assignments;
};

/* Currently these are the same across all PCI controllers
 * we support.  Someday they may not be...
 */
#define PCI_IRQ_IGN	0x000007c0	/* Interrupt Group Number */
#define PCI_IRQ_INO	0x0000003f	/* Interrupt Number */

#endif /* !(__SPARC64_PBM_H) */