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/* $Id$
*
* This file is subject to the terms and conditions of the GNU General Public
* License. See the file "COPYING" in the main directory of this archive
* for more details.
*
* Copyright (C) 1992 - 1997, 2000 Silicon Graphics, Inc.
* Copyright (C) 2000 by Colin Ngam
*/
#ifndef _ASM_SN_PCI_BRIDGE_H
#define _ASM_SN_PCI_BRIDGE_H
/*
* bridge.h - header file for bridge chip and bridge portion of xbridge chip
*/
#include <asm/sn/xtalk/xwidget.h>
/* I/O page size */
#if _PAGESZ == 4096
#define IOPFNSHIFT 12 /* 4K per mapped page */
#else
#define IOPFNSHIFT 14 /* 16K per mapped page */
#endif /* _PAGESZ */
#define IOPGSIZE (1 << IOPFNSHIFT)
#define IOPG(x) ((x) >> IOPFNSHIFT)
#define IOPGOFF(x) ((x) & (IOPGSIZE-1))
/* Bridge RAM sizes */
#define BRIDGE_INTERNAL_ATES 128
#define XBRIDGE_INTERNAL_ATES 1024
#define BRIDGE_ATE_RAM_SIZE (BRIDGE_INTERNAL_ATES<<3) /* 1kB ATE */
#define XBRIDGE_ATE_RAM_SIZE (XBRIDGE_INTERNAL_ATES<<3) /* 8kB ATE */
#define BRIDGE_CONFIG_BASE 0x20000 /* start of bridge's */
/* map to each device's */
/* config space */
#define BRIDGE_CONFIG1_BASE 0x28000 /* type 1 device config space */
#define BRIDGE_CONFIG_END 0x30000
#define BRIDGE_CONFIG_SLOT_SIZE 0x1000 /* each map == 4k */
#define BRIDGE_SSRAM_512K 0x00080000 /* 512kB */
#define BRIDGE_SSRAM_128K 0x00020000 /* 128kB */
#define BRIDGE_SSRAM_64K 0x00010000 /* 64kB */
#define BRIDGE_SSRAM_0K 0x00000000 /* 0kB */
/* ========================================================================
* Bridge address map
*/
#if defined(_LANGUAGE_C) || defined(_LANGUAGE_C_PLUS_PLUS)
#ifdef __cplusplus
extern "C" {
#endif
/*
* All accesses to bridge hardware registers must be done
* using 32-bit loads and stores.
*/
typedef uint32_t bridgereg_t;
typedef uint64_t bridge_ate_t;
/* pointers to bridge ATEs
* are always "pointer to volatile"
*/
typedef volatile bridge_ate_t *bridge_ate_p;
/*
* It is generally preferred that hardware registers on the bridge
* are located from C code via this structure.
*
* Generated from Bridge spec dated 04oct95
*/
#ifdef LITTLE_ENDIAN
typedef volatile struct bridge_s {
/* Local Registers 0x000000-0x00FFFF */
/* standard widget configuration 0x000000-0x000057 */
widget_cfg_t b_widget; /* 0x000000 */
/* helper fieldnames for accessing bridge widget */
#define b_wid_id b_widget.w_id
#define b_wid_stat b_widget.w_status
#define b_wid_err_upper b_widget.w_err_upper_addr
#define b_wid_err_lower b_widget.w_err_lower_addr
#define b_wid_control b_widget.w_control
#define b_wid_req_timeout b_widget.w_req_timeout
#define b_wid_int_upper b_widget.w_intdest_upper_addr
#define b_wid_int_lower b_widget.w_intdest_lower_addr
#define b_wid_err_cmdword b_widget.w_err_cmd_word
#define b_wid_llp b_widget.w_llp_cfg
#define b_wid_tflush b_widget.w_tflush
/*
* we access these through synergy unswizzled space, so the address
* gets twiddled (i.e. references to 0x4 actually go to 0x0 and vv.)
* That's why we put the register first and filler second.
*/
/* bridge-specific widget configuration 0x000058-0x00007F */
bridgereg_t b_wid_aux_err; /* 0x00005C */
bridgereg_t _pad_000058;
bridgereg_t b_wid_resp_upper; /* 0x000064 */
bridgereg_t _pad_000060;
bridgereg_t b_wid_resp_lower; /* 0x00006C */
bridgereg_t _pad_000068;
bridgereg_t b_wid_tst_pin_ctrl; /* 0x000074 */
bridgereg_t _pad_000070;
bridgereg_t _pad_000078[2];
/* PMU & Map 0x000080-0x00008F */
bridgereg_t b_dir_map; /* 0x000084 */
bridgereg_t _pad_000080;
bridgereg_t _pad_000088[2];
/* SSRAM 0x000090-0x00009F */
bridgereg_t b_ram_perr_or_map_fault;/* 0x000094 */
bridgereg_t _pad_000090;
#define b_ram_perr b_ram_perr_or_map_fault /* Bridge */
#define b_map_fault b_ram_perr_or_map_fault /* Xbridge */
bridgereg_t _pad_000098[2];
/* Arbitration 0x0000A0-0x0000AF */
bridgereg_t b_arb; /* 0x0000A4 */
bridgereg_t _pad_0000A0;
bridgereg_t _pad_0000A8[2];
/* Number In A Can 0x0000B0-0x0000BF */
bridgereg_t b_nic; /* 0x0000B4 */
bridgereg_t _pad_0000B0;
bridgereg_t _pad_0000B8[2];
/* PCI/GIO 0x0000C0-0x0000FF */
bridgereg_t b_bus_timeout; /* 0x0000C4 */
bridgereg_t _pad_0000C0;
#define b_pci_bus_timeout b_bus_timeout
bridgereg_t b_pci_cfg; /* 0x0000CC */
bridgereg_t _pad_0000C8;
bridgereg_t b_pci_err_upper; /* 0x0000D4 */
bridgereg_t _pad_0000D0;
bridgereg_t b_pci_err_lower; /* 0x0000DC */
bridgereg_t _pad_0000D8;
bridgereg_t _pad_0000E0[8];
#define b_gio_err_lower b_pci_err_lower
#define b_gio_err_upper b_pci_err_upper
/* Interrupt 0x000100-0x0001FF */
bridgereg_t b_int_status; /* 0x000104 */
bridgereg_t _pad_000100;
bridgereg_t b_int_enable; /* 0x00010C */
bridgereg_t _pad_000108;
bridgereg_t b_int_rst_stat; /* 0x000114 */
bridgereg_t _pad_000110;
bridgereg_t b_int_mode; /* 0x00011C */
bridgereg_t _pad_000118;
bridgereg_t b_int_device; /* 0x000124 */
bridgereg_t _pad_000120;
bridgereg_t b_int_host_err; /* 0x00012C */
bridgereg_t _pad_000128;
struct {
bridgereg_t addr; /* 0x0001{34,,,6C} */
bridgereg_t __pad; /* 0x0001{30,,,68} */
} b_int_addr[8]; /* 0x000130 */
bridgereg_t b_err_int_view; /* 0x000174 */
bridgereg_t _pad_000170;
bridgereg_t b_mult_int; /* 0x00017c */
bridgereg_t _pad_000178;
struct {
bridgereg_t intr; /* 0x0001{84,,,BC} */
bridgereg_t __pad; /* 0x0001{80,,,B8} */
} b_force_always[8]; /* 0x000180 */
struct {
bridgereg_t intr; /* 0x0001{C4,,,FC} */
bridgereg_t __pad; /* 0x0001{C0,,,F8} */
} b_force_pin[8]; /* 0x0001C0 */
/* Device 0x000200-0x0003FF */
struct {
bridgereg_t reg; /* 0x0002{04,,,3C} */
bridgereg_t __pad; /* 0x0002{00,,,38} */
} b_device[8]; /* 0x000200 */
struct {
bridgereg_t reg; /* 0x0002{44,,,7C} */
bridgereg_t __pad; /* 0x0002{40,,,78} */
} b_wr_req_buf[8]; /* 0x000240 */
struct {
bridgereg_t reg; /* 0x0002{84,,,8C} */
bridgereg_t __pad; /* 0x0002{80,,,88} */
} b_rrb_map[2]; /* 0x000280 */
#define b_even_resp b_rrb_map[0].reg /* 0x000284 */
#define b_odd_resp b_rrb_map[1].reg /* 0x00028C */
bridgereg_t b_resp_status; /* 0x000294 */
bridgereg_t _pad_000290;
bridgereg_t b_resp_clear; /* 0x00029C */
bridgereg_t _pad_000298;
bridgereg_t _pad_0002A0[24];
/* Xbridge only */
struct {
bridgereg_t upper; /* 0x0003{04,,,F4} */
bridgereg_t __pad1; /* 0x0003{00,,,F0} */
bridgereg_t lower; /* 0x0003{0C,,,FC} */
bridgereg_t __pad2; /* 0x0003{08,,,F8} */
} b_buf_addr_match[16];
/* Performance Monitor Registers (even only) */
struct {
bridgereg_t flush_w_touch; /* 0x000404,,,5C4 */
bridgereg_t __pad1; /* 0x000400,,,5C0 */
bridgereg_t flush_wo_touch; /* 0x00040C,,,5CC */
bridgereg_t __pad2; /* 0x000408,,,5C8 */
bridgereg_t inflight; /* 0x000414,,,5D4 */
bridgereg_t __pad3; /* 0x000410,,,5D0 */
bridgereg_t prefetch; /* 0x00041C,,,5DC */
bridgereg_t __pad4; /* 0x000418,,,5D8 */
bridgereg_t total_pci_retry; /* 0x000424,,,5E4 */
bridgereg_t __pad5; /* 0x000420,,,5E0 */
bridgereg_t max_pci_retry; /* 0x00042C,,,5EC */
bridgereg_t __pad6; /* 0x000428,,,5E8 */
bridgereg_t max_latency; /* 0x000434,,,5F4 */
bridgereg_t __pad7; /* 0x000430,,,5F0 */
bridgereg_t clear_all; /* 0x00043C,,,5FC */
bridgereg_t __pad8; /* 0x000438,,,5F8 */
} b_buf_count[8];
char _pad_000600[0x010000 - 0x000600];
/*
* The Xbridge has 1024 internal ATE's and the Bridge has 128.
* Make enough room for the Xbridge ATE's and depend on runtime
* checks to limit access to bridge ATE's.
*/
/* Internal Address Translation Entry RAM 0x010000-0x011fff */
union {
bridge_ate_t wr; /* write-only */
struct {
bridgereg_t rd; /* read-only */
bridgereg_t _p_pad;
} hi;
} b_int_ate_ram[XBRIDGE_INTERNAL_ATES];
#define b_int_ate_ram_lo(idx) b_int_ate_ram[idx+512].hi.rd
/* the xbridge read path for internal ates starts at 0x12000.
* I don't believe we ever try to read the ates.
*/
/* Internal Address Translation Entry RAM LOW 0x012000-0x013fff */
struct {
bridgereg_t rd;
bridgereg_t _p_pad;
} xb_int_ate_ram_lo[XBRIDGE_INTERNAL_ATES];
char _pad_014000[0x20000 - 0x014000];
/* PCI Device Configuration Spaces 0x020000-0x027FFF */
union { /* make all access sizes available. */
uchar_t c[0x1000 / 1];
uint16_t s[0x1000 / 2];
uint32_t l[0x1000 / 4];
uint64_t d[0x1000 / 8];
union {
uchar_t c[0x100 / 1];
uint16_t s[0x100 / 2];
uint32_t l[0x100 / 4];
uint64_t d[0x100 / 8];
} f[8];
} b_type0_cfg_dev[8]; /* 0x020000 */
/* PCI Type 1 Configuration Space 0x028000-0x028FFF */
union { /* make all access sizes available. */
uchar_t c[0x1000 / 1];
uint16_t s[0x1000 / 2];
uint32_t l[0x1000 / 4];
uint64_t d[0x1000 / 8];
} b_type1_cfg; /* 0x028000-0x029000 */
char _pad_029000[0x007000]; /* 0x029000-0x030000 */
/* PCI Interrupt Acknowledge Cycle 0x030000 */
union {
uchar_t c[8 / 1];
uint16_t s[8 / 2];
uint32_t l[8 / 4];
uint64_t d[8 / 8];
} b_pci_iack; /* 0x030000 */
uchar_t _pad_030007[0x04fff8]; /* 0x030008-0x07FFFF */
/* External Address Translation Entry RAM 0x080000-0x0FFFFF */
bridge_ate_t b_ext_ate_ram[0x10000];
/* Reserved 0x100000-0x1FFFFF */
char _pad_100000[0x200000-0x100000];
/* PCI/GIO Device Spaces 0x200000-0xBFFFFF */
union { /* make all access sizes available. */
uchar_t c[0x100000 / 1];
uint16_t s[0x100000 / 2];
uint32_t l[0x100000 / 4];
uint64_t d[0x100000 / 8];
} b_devio_raw[10]; /* 0x200000 */
/* b_devio macro is a bit strange; it reflects the
* fact that the Bridge ASIC provides 2M for the
* first two DevIO windows and 1M for the other six.
*/
#define b_devio(n) b_devio_raw[((n)<2)?(n*2):(n+2)]
/* External Flash Proms 1,0 0xC00000-0xFFFFFF */
union { /* make all access sizes available. */
uchar_t c[0x400000 / 1]; /* read-only */
uint16_t s[0x400000 / 2]; /* read-write */
uint32_t l[0x400000 / 4]; /* read-only */
uint64_t d[0x400000 / 8]; /* read-only */
} b_external_flash; /* 0xC00000 */
} bridge_t;
#else
/*
* Field formats for Error Command Word and Auxillary Error Command Word
* of bridge.
*/
typedef struct bridge_err_cmdword_s {
union {
uint32_t cmd_word;
struct {
uint32_t didn:4, /* Destination ID */
sidn:4, /* SOurce ID */
pactyp:4, /* Packet type */
tnum:5, /* Trans Number */
coh:1, /* Coh Transacti */
ds:2, /* Data size */
gbr:1, /* GBR enable */
vbpm:1, /* VBPM message */
error:1, /* Error occurred */
barr:1, /* Barrier op */
rsvd:8;
} berr_st;
} berr_un;
} bridge_err_cmdword_t;
typedef volatile struct bridge_s {
/* Local Registers 0x000000-0x00FFFF */
/* standard widget configuration 0x000000-0x000057 */
widget_cfg_t b_widget; /* 0x000000 */
/* helper fieldnames for accessing bridge widget */
#define b_wid_id b_widget.w_id
#define b_wid_stat b_widget.w_status
#define b_wid_err_upper b_widget.w_err_upper_addr
#define b_wid_err_lower b_widget.w_err_lower_addr
#define b_wid_control b_widget.w_control
#define b_wid_req_timeout b_widget.w_req_timeout
#define b_wid_int_upper b_widget.w_intdest_upper_addr
#define b_wid_int_lower b_widget.w_intdest_lower_addr
#define b_wid_err_cmdword b_widget.w_err_cmd_word
#define b_wid_llp b_widget.w_llp_cfg
#define b_wid_tflush b_widget.w_tflush
/* bridge-specific widget configuration 0x000058-0x00007F */
bridgereg_t _pad_000058;
bridgereg_t b_wid_aux_err; /* 0x00005C */
bridgereg_t _pad_000060;
bridgereg_t b_wid_resp_upper; /* 0x000064 */
bridgereg_t _pad_000068;
bridgereg_t b_wid_resp_lower; /* 0x00006C */
bridgereg_t _pad_000070;
bridgereg_t b_wid_tst_pin_ctrl; /* 0x000074 */
bridgereg_t _pad_000078[2];
/* PMU & Map 0x000080-0x00008F */
bridgereg_t _pad_000080;
bridgereg_t b_dir_map; /* 0x000084 */
bridgereg_t _pad_000088[2];
/* SSRAM 0x000090-0x00009F */
bridgereg_t _pad_000090;
bridgereg_t b_ram_perr_or_map_fault;/* 0x000094 */
#define b_ram_perr b_ram_perr_or_map_fault /* Bridge */
#define b_map_fault b_ram_perr_or_map_fault /* Xbridge */
bridgereg_t _pad_000098[2];
/* Arbitration 0x0000A0-0x0000AF */
bridgereg_t _pad_0000A0;
bridgereg_t b_arb; /* 0x0000A4 */
bridgereg_t _pad_0000A8[2];
/* Number In A Can 0x0000B0-0x0000BF */
bridgereg_t _pad_0000B0;
bridgereg_t b_nic; /* 0x0000B4 */
bridgereg_t _pad_0000B8[2];
/* PCI/GIO 0x0000C0-0x0000FF */
bridgereg_t _pad_0000C0;
bridgereg_t b_bus_timeout; /* 0x0000C4 */
#define b_pci_bus_timeout b_bus_timeout
bridgereg_t _pad_0000C8;
bridgereg_t b_pci_cfg; /* 0x0000CC */
bridgereg_t _pad_0000D0;
bridgereg_t b_pci_err_upper; /* 0x0000D4 */
bridgereg_t _pad_0000D8;
bridgereg_t b_pci_err_lower; /* 0x0000DC */
bridgereg_t _pad_0000E0[8];
#define b_gio_err_lower b_pci_err_lower
#define b_gio_err_upper b_pci_err_upper
/* Interrupt 0x000100-0x0001FF */
bridgereg_t _pad_000100;
bridgereg_t b_int_status; /* 0x000104 */
bridgereg_t _pad_000108;
bridgereg_t b_int_enable; /* 0x00010C */
bridgereg_t _pad_000110;
bridgereg_t b_int_rst_stat; /* 0x000114 */
bridgereg_t _pad_000118;
bridgereg_t b_int_mode; /* 0x00011C */
bridgereg_t _pad_000120;
bridgereg_t b_int_device; /* 0x000124 */
bridgereg_t _pad_000128;
bridgereg_t b_int_host_err; /* 0x00012C */
struct {
bridgereg_t __pad; /* 0x0001{30,,,68} */
bridgereg_t addr; /* 0x0001{34,,,6C} */
} b_int_addr[8]; /* 0x000130 */
bridgereg_t _pad_000170;
bridgereg_t b_err_int_view; /* 0x000174 */
bridgereg_t _pad_000178;
bridgereg_t b_mult_int; /* 0x00017c */
struct {
bridgereg_t __pad; /* 0x0001{80,,,B8} */
bridgereg_t intr; /* 0x0001{84,,,BC} */
} b_force_always[8]; /* 0x000180 */
struct {
bridgereg_t __pad; /* 0x0001{C0,,,F8} */
bridgereg_t intr; /* 0x0001{C4,,,FC} */
} b_force_pin[8]; /* 0x0001C0 */
/* Device 0x000200-0x0003FF */
struct {
bridgereg_t __pad; /* 0x0002{00,,,38} */
bridgereg_t reg; /* 0x0002{04,,,3C} */
} b_device[8]; /* 0x000200 */
struct {
bridgereg_t __pad; /* 0x0002{40,,,78} */
bridgereg_t reg; /* 0x0002{44,,,7C} */
} b_wr_req_buf[8]; /* 0x000240 */
struct {
bridgereg_t __pad; /* 0x0002{80,,,88} */
bridgereg_t reg; /* 0x0002{84,,,8C} */
} b_rrb_map[2]; /* 0x000280 */
#define b_even_resp b_rrb_map[0].reg /* 0x000284 */
#define b_odd_resp b_rrb_map[1].reg /* 0x00028C */
bridgereg_t _pad_000290;
bridgereg_t b_resp_status; /* 0x000294 */
bridgereg_t _pad_000298;
bridgereg_t b_resp_clear; /* 0x00029C */
bridgereg_t _pad_0002A0[24];
/* Xbridge only */
struct {
bridgereg_t __pad1; /* 0x0003{00,,,F0} */
bridgereg_t upper; /* 0x0003{04,,,F4} */
bridgereg_t __pad2; /* 0x0003{08,,,F8} */
bridgereg_t lower; /* 0x0003{0C,,,FC} */
} b_buf_addr_match[16];
/* Performance Monitor Registers (even only) */
struct {
bridgereg_t __pad1; /* 0x000400,,,5C0 */
bridgereg_t flush_w_touch; /* 0x000404,,,5C4 */
bridgereg_t __pad2; /* 0x000408,,,5C8 */
bridgereg_t flush_wo_touch; /* 0x00040C,,,5CC */
bridgereg_t __pad3; /* 0x000410,,,5D0 */
bridgereg_t inflight; /* 0x000414,,,5D4 */
bridgereg_t __pad4; /* 0x000418,,,5D8 */
bridgereg_t prefetch; /* 0x00041C,,,5DC */
bridgereg_t __pad5; /* 0x000420,,,5E0 */
bridgereg_t total_pci_retry; /* 0x000424,,,5E4 */
bridgereg_t __pad6; /* 0x000428,,,5E8 */
bridgereg_t max_pci_retry; /* 0x00042C,,,5EC */
bridgereg_t __pad7; /* 0x000430,,,5F0 */
bridgereg_t max_latency; /* 0x000434,,,5F4 */
bridgereg_t __pad8; /* 0x000438,,,5F8 */
bridgereg_t clear_all; /* 0x00043C,,,5FC */
} b_buf_count[8];
char _pad_000600[0x010000 - 0x000600];
/*
* The Xbridge has 1024 internal ATE's and the Bridge has 128.
* Make enough room for the Xbridge ATE's and depend on runtime
* checks to limit access to bridge ATE's.
*/
/* Internal Address Translation Entry RAM 0x010000-0x011fff */
union {
bridge_ate_t wr; /* write-only */
struct {
bridgereg_t _p_pad;
bridgereg_t rd; /* read-only */
} hi;
} b_int_ate_ram[XBRIDGE_INTERNAL_ATES];
#define b_int_ate_ram_lo(idx) b_int_ate_ram[idx+512].hi.rd
/* the xbridge read path for internal ates starts at 0x12000.
* I don't believe we ever try to read the ates.
*/
/* Internal Address Translation Entry RAM LOW 0x012000-0x013fff */
struct {
bridgereg_t _p_pad;
bridgereg_t rd; /* read-only */
} xb_int_ate_ram_lo[XBRIDGE_INTERNAL_ATES];
char _pad_014000[0x20000 - 0x014000];
/* PCI Device Configuration Spaces 0x020000-0x027FFF */
union { /* make all access sizes available. */
uchar_t c[0x1000 / 1];
uint16_t s[0x1000 / 2];
uint32_t l[0x1000 / 4];
uint64_t d[0x1000 / 8];
union {
uchar_t c[0x100 / 1];
uint16_t s[0x100 / 2];
uint32_t l[0x100 / 4];
uint64_t d[0x100 / 8];
} f[8];
} b_type0_cfg_dev[8]; /* 0x020000 */
/* PCI Type 1 Configuration Space 0x028000-0x028FFF */
union { /* make all access sizes available. */
uchar_t c[0x1000 / 1];
uint16_t s[0x1000 / 2];
uint32_t l[0x1000 / 4];
uint64_t d[0x1000 / 8];
} b_type1_cfg; /* 0x028000-0x029000 */
char _pad_029000[0x007000]; /* 0x029000-0x030000 */
/* PCI Interrupt Acknowledge Cycle 0x030000 */
union {
uchar_t c[8 / 1];
uint16_t s[8 / 2];
uint32_t l[8 / 4];
uint64_t d[8 / 8];
} b_pci_iack; /* 0x030000 */
uchar_t _pad_030007[0x04fff8]; /* 0x030008-0x07FFFF */
/* External Address Translation Entry RAM 0x080000-0x0FFFFF */
bridge_ate_t b_ext_ate_ram[0x10000];
/* Reserved 0x100000-0x1FFFFF */
char _pad_100000[0x200000-0x100000];
/* PCI/GIO Device Spaces 0x200000-0xBFFFFF */
union { /* make all access sizes available. */
uchar_t c[0x100000 / 1];
uint16_t s[0x100000 / 2];
uint32_t l[0x100000 / 4];
uint64_t d[0x100000 / 8];
} b_devio_raw[10]; /* 0x200000 */
/* b_devio macro is a bit strange; it reflects the
* fact that the Bridge ASIC provides 2M for the
* first two DevIO windows and 1M for the other six.
*/
#define b_devio(n) b_devio_raw[((n)<2)?(n*2):(n+2)]
/* External Flash Proms 1,0 0xC00000-0xFFFFFF */
union { /* make all access sizes available. */
uchar_t c[0x400000 / 1]; /* read-only */
uint16_t s[0x400000 / 2]; /* read-write */
uint32_t l[0x400000 / 4]; /* read-only */
uint64_t d[0x400000 / 8]; /* read-only */
} b_external_flash; /* 0xC00000 */
} bridge_t;
#endif
#define berr_field berr_un.berr_st
#endif /* LANGUAGE_C */
/*
* The values of these macros can and should be crosschecked
* regularly against the offsets of the like-named fields
* within the "bridge_t" structure above.
*/
/* Byte offset macros for Bridge internal registers */
#define BRIDGE_WID_ID WIDGET_ID
#define BRIDGE_WID_STAT WIDGET_STATUS
#define BRIDGE_WID_ERR_UPPER WIDGET_ERR_UPPER_ADDR
#define BRIDGE_WID_ERR_LOWER WIDGET_ERR_LOWER_ADDR
#define BRIDGE_WID_CONTROL WIDGET_CONTROL
#define BRIDGE_WID_REQ_TIMEOUT WIDGET_REQ_TIMEOUT
#define BRIDGE_WID_INT_UPPER WIDGET_INTDEST_UPPER_ADDR
#define BRIDGE_WID_INT_LOWER WIDGET_INTDEST_LOWER_ADDR
#define BRIDGE_WID_ERR_CMDWORD WIDGET_ERR_CMD_WORD
#define BRIDGE_WID_LLP WIDGET_LLP_CFG
#define BRIDGE_WID_TFLUSH WIDGET_TFLUSH
#define BRIDGE_WID_AUX_ERR 0x00005C /* Aux Error Command Word */
#define BRIDGE_WID_RESP_UPPER 0x000064 /* Response Buf Upper Addr */
#define BRIDGE_WID_RESP_LOWER 0x00006C /* Response Buf Lower Addr */
#define BRIDGE_WID_TST_PIN_CTRL 0x000074 /* Test pin control */
#define BRIDGE_DIR_MAP 0x000084 /* Direct Map reg */
/* Bridge has SSRAM Parity Error and Xbridge has Map Fault here */
#define BRIDGE_RAM_PERR 0x000094 /* SSRAM Parity Error */
#define BRIDGE_MAP_FAULT 0x000094 /* Map Fault */
#define BRIDGE_ARB 0x0000A4 /* Arbitration Priority reg */
#define BRIDGE_NIC 0x0000B4 /* Number In A Can */
#define BRIDGE_BUS_TIMEOUT 0x0000C4 /* Bus Timeout Register */
#define BRIDGE_PCI_BUS_TIMEOUT BRIDGE_BUS_TIMEOUT
#define BRIDGE_PCI_CFG 0x0000CC /* PCI Type 1 Config reg */
#define BRIDGE_PCI_ERR_UPPER 0x0000D4 /* PCI error Upper Addr */
#define BRIDGE_PCI_ERR_LOWER 0x0000DC /* PCI error Lower Addr */
#define BRIDGE_INT_STATUS 0x000104 /* Interrupt Status */
#define BRIDGE_INT_ENABLE 0x00010C /* Interrupt Enables */
#define BRIDGE_INT_RST_STAT 0x000114 /* Reset Intr Status */
#define BRIDGE_INT_MODE 0x00011C /* Interrupt Mode */
#define BRIDGE_INT_DEVICE 0x000124 /* Interrupt Device */
#define BRIDGE_INT_HOST_ERR 0x00012C /* Host Error Field */
#define BRIDGE_INT_ADDR0 0x000134 /* Host Address Reg */
#define BRIDGE_INT_ADDR_OFF 0x000008 /* Host Addr offset (1..7) */
#define BRIDGE_INT_ADDR(x) (BRIDGE_INT_ADDR0+(x)*BRIDGE_INT_ADDR_OFF)
#define BRIDGE_INT_VIEW 0x000174 /* Interrupt view */
#define BRIDGE_MULTIPLE_INT 0x00017c /* Multiple interrupt occurred */
#define BRIDGE_FORCE_ALWAYS0 0x000184 /* Force an interrupt (always)*/
#define BRIDGE_FORCE_ALWAYS_OFF 0x000008 /* Force Always offset */
#define BRIDGE_FORCE_ALWAYS(x) (BRIDGE_FORCE_ALWAYS0+(x)*BRIDGE_FORCE_ALWAYS_OFF)
#define BRIDGE_FORCE_PIN0 0x0001c4 /* Force an interrupt */
#define BRIDGE_FORCE_PIN_OFF 0x000008 /* Force Pin offset */
#define BRIDGE_FORCE_PIN(x) (BRIDGE_FORCE_PIN0+(x)*BRIDGE_FORCE_PIN_OFF)
#define BRIDGE_DEVICE0 0x000204 /* Device 0 */
#define BRIDGE_DEVICE_OFF 0x000008 /* Device offset (1..7) */
#define BRIDGE_DEVICE(x) (BRIDGE_DEVICE0+(x)*BRIDGE_DEVICE_OFF)
#define BRIDGE_WR_REQ_BUF0 0x000244 /* Write Request Buffer 0 */
#define BRIDGE_WR_REQ_BUF_OFF 0x000008 /* Buffer Offset (1..7) */
#define BRIDGE_WR_REQ_BUF(x) (BRIDGE_WR_REQ_BUF0+(x)*BRIDGE_WR_REQ_BUF_OFF)
#define BRIDGE_EVEN_RESP 0x000284 /* Even Device Response Buf */
#define BRIDGE_ODD_RESP 0x00028C /* Odd Device Response Buf */
#define BRIDGE_RESP_STATUS 0x000294 /* Read Response Status reg */
#define BRIDGE_RESP_CLEAR 0x00029C /* Read Response Clear reg */
#define BRIDGE_BUF_ADDR_UPPER0 0x000304
#define BRIDGE_BUF_ADDR_UPPER_OFF 0x000010 /* PCI Buffer Upper Offset */
#define BRIDGE_BUF_ADDR_UPPER(x) (BRIDGE_BUF_ADDR_UPPER0+(x)*BRIDGE_BUF_ADDR_UPPER_OFF)
#define BRIDGE_BUF_ADDR_LOWER0 0x00030c
#define BRIDGE_BUF_ADDR_LOWER_OFF 0x000010 /* PCI Buffer Upper Offset */
#define BRIDGE_BUF_ADDR_LOWER(x) (BRIDGE_BUF_ADDR_LOWER0+(x)*BRIDGE_BUF_ADDR_LOWER_OFF)
/*
* Performance Monitor Registers.
*
* The Performance registers are those registers which are associated with
* monitoring the performance of PCI generated reads to the host environ
* ment. Because of the size of the register file only the even registers
* were instrumented.
*/
#define BRIDGE_BUF_OFF 0x40
#define BRIDGE_BUF_NEXT(base, off) (base+((off)*BRIDGE_BUF_OFF))
/*
* Buffer (x) Flush Count with Data Touch Register.
*
* This counter is incremented each time the corresponding response buffer
* is flushed after at least a single data element in the buffer is used.
* A word write to this address clears the count.
*/
#define BRIDGE_BUF_0_FLUSH_TOUCH 0x000404
#define BRIDGE_BUF_2_FLUSH_TOUCH BRIDGE_BUF_NEXT(BRIDGE_BUF_0_FLUSH_TOUCH, 1)
#define BRIDGE_BUF_4_FLUSH_TOUCH BRIDGE_BUF_NEXT(BRIDGE_BUF_0_FLUSH_TOUCH, 2)
#define BRIDGE_BUF_6_FLUSH_TOUCH BRIDGE_BUF_NEXT(BRIDGE_BUF_0_FLUSH_TOUCH, 3)
#define BRIDGE_BUF_8_FLUSH_TOUCH BRIDGE_BUF_NEXT(BRIDGE_BUF_0_FLUSH_TOUCH, 4)
#define BRIDGE_BUF_10_FLUSH_TOUCH BRIDGE_BUF_NEXT(BRIDGE_BUF_0_FLUSH_TOUCH, 5)
#define BRIDGE_BUF_12_FLUSH_TOUCH BRIDGE_BUF_NEXT(BRIDGE_BUF_0_FLUSH_TOUCH, 6)
#define BRIDGE_BUF_14_FLUSH_TOUCH BRIDGE_BUF_NEXT(BRIDGE_BUF_0_FLUSH_TOUCH, 7)
/*
* Buffer (x) Flush Count w/o Data Touch Register
*
* This counter is incremented each time the corresponding response buffer
* is flushed without any data element in the buffer being used. A word
* write to this address clears the count.
*/
#define BRIDGE_BUF_0_FLUSH_NOTOUCH 0x00040c
#define BRIDGE_BUF_2_FLUSH_NOTOUCH BRIDGE_BUF_NEXT(BRIDGE_BUF_0_FLUSH_NOTOUCH, 1)
#define BRIDGE_BUF_4_FLUSH_NOTOUCH BRIDGE_BUF_NEXT(BRIDGE_BUF_0_FLUSH_NOTOUCH, 2)
#define BRIDGE_BUF_6_FLUSH_NOTOUCH BRIDGE_BUF_NEXT(BRIDGE_BUF_0_FLUSH_NOTOUCH, 3)
#define BRIDGE_BUF_8_FLUSH_NOTOUCH BRIDGE_BUF_NEXT(BRIDGE_BUF_0_FLUSH_NOTOUCH, 4)
#define BRIDGE_BUF_10_FLUSH_NOTOUCH BRIDGE_BUF_NEXT(BRIDGE_BUF_0_FLUSH_NOTOUCH, 5)
#define BRIDGE_BUF_12_FLUSH_NOTOUCH BRIDGE_BUF_NEXT(BRIDGE_BUF_0_FLUSH_NOTOUCH, 6)
#define BRIDGE_BUF_14_FLUSH_NOTOUCH BRIDGE_BUF_NEXT(BRIDGE_BUF_0_FLUSH_NOTOUCH, 7)
/*
* Buffer (x) Request in Flight Count Register
*
* This counter is incremented on each bus clock while the request is in
* flight. A word write to this address clears the count.
*/
#define BRIDGE_BUF_0_INFLIGHT 0x000414
#define BRIDGE_BUF_2_INFLIGHT BRIDGE_BUF_NEXT(BRIDGE_BUF_0_INFLIGHT, 1)
#define BRIDGE_BUF_4_INFLIGHT BRIDGE_BUF_NEXT(BRIDGE_BUF_0_INFLIGHT, 2)
#define BRIDGE_BUF_6_INFLIGHT BRIDGE_BUF_NEXT(BRIDGE_BUF_0_INFLIGHT, 3)
#define BRIDGE_BUF_8_INFLIGHT BRIDGE_BUF_NEXT(BRIDGE_BUF_0_INFLIGHT, 4)
#define BRIDGE_BUF_10_INFLIGHT BRIDGE_BUF_NEXT(BRIDGE_BUF_0_INFLIGHT, 5)
#define BRIDGE_BUF_12_INFLIGHT BRIDGE_BUF_NEXT(BRIDGE_BUF_0_INFLIGHT, 6)
#define BRIDGE_BUF_14_INFLIGHT BRIDGE_BUF_NEXT(BRIDGE_BUF_0_INFLIGHT, 7)
/*
* Buffer (x) Prefetch Request Count Register
*
* This counter is incremented each time the request using this buffer was
* generated from the prefetcher. A word write to this address clears the
* count.
*/
#define BRIDGE_BUF_0_PREFETCH 0x00041C
#define BRIDGE_BUF_2_PREFETCH BRIDGE_BUF_NEXT(BRIDGE_BUF_0_PREFETCH, 1)
#define BRIDGE_BUF_4_PREFETCH BRIDGE_BUF_NEXT(BRIDGE_BUF_0_PREFETCH, 2)
#define BRIDGE_BUF_6_PREFETCH BRIDGE_BUF_NEXT(BRIDGE_BUF_0_PREFETCH, 3)
#define BRIDGE_BUF_8_PREFETCH BRIDGE_BUF_NEXT(BRIDGE_BUF_0_PREFETCH, 4)
#define BRIDGE_BUF_10_PREFETCH BRIDGE_BUF_NEXT(BRIDGE_BUF_0_PREFETCH, 5)
#define BRIDGE_BUF_12_PREFETCH BRIDGE_BUF_NEXT(BRIDGE_BUF_0_PREFETCH, 6)
#define BRIDGE_BUF_14_PREFETCH BRIDGE_BUF_NEXT(BRIDGE_BUF_0_PREFETCH, 7)
/*
* Buffer (x) Total PCI Retry Count Register
*
* This counter is incremented each time a PCI bus retry occurs and the ad
* dress matches the tag for the selected buffer. The buffer must also has
* this request in-flight. A word write to this address clears the count.
*/
#define BRIDGE_BUF_0_PCI_RETRY 0x000424
#define BRIDGE_BUF_2_PCI_RETRY BRIDGE_BUF_NEXT(BRIDGE_BUF_0_PCI_RETRY, 1)
#define BRIDGE_BUF_4_PCI_RETRY BRIDGE_BUF_NEXT(BRIDGE_BUF_0_PCI_RETRY, 2)
#define BRIDGE_BUF_6_PCI_RETRY BRIDGE_BUF_NEXT(BRIDGE_BUF_0_PCI_RETRY, 3)
#define BRIDGE_BUF_8_PCI_RETRY BRIDGE_BUF_NEXT(BRIDGE_BUF_0_PCI_RETRY, 4)
#define BRIDGE_BUF_10_PCI_RETRY BRIDGE_BUF_NEXT(BRIDGE_BUF_0_PCI_RETRY, 5)
#define BRIDGE_BUF_12_PCI_RETRY BRIDGE_BUF_NEXT(BRIDGE_BUF_0_PCI_RETRY, 6)
#define BRIDGE_BUF_14_PCI_RETRY BRIDGE_BUF_NEXT(BRIDGE_BUF_0_PCI_RETRY, 7)
/*
* Buffer (x) Max PCI Retry Count Register
*
* This counter is contains the maximum retry count for a single request
* which was in-flight for this buffer. A word write to this address
* clears the count.
*/
#define BRIDGE_BUF_0_MAX_PCI_RETRY 0x00042C
#define BRIDGE_BUF_2_MAX_PCI_RETRY BRIDGE_BUF_NEXT(BRIDGE_BUF_0_MAX_PCI_RETRY, 1)
#define BRIDGE_BUF_4_MAX_PCI_RETRY BRIDGE_BUF_NEXT(BRIDGE_BUF_0_MAX_PCI_RETRY, 2)
#define BRIDGE_BUF_6_MAX_PCI_RETRY BRIDGE_BUF_NEXT(BRIDGE_BUF_0_MAX_PCI_RETRY, 3)
#define BRIDGE_BUF_8_MAX_PCI_RETRY BRIDGE_BUF_NEXT(BRIDGE_BUF_0_MAX_PCI_RETRY, 4)
#define BRIDGE_BUF_10_MAX_PCI_RETRY BRIDGE_BUF_NEXT(BRIDGE_BUF_0_MAX_PCI_RETRY, 5)
#define BRIDGE_BUF_12_MAX_PCI_RETRY BRIDGE_BUF_NEXT(BRIDGE_BUF_0_MAX_PCI_RETRY, 6)
#define BRIDGE_BUF_14_MAX_PCI_RETRY BRIDGE_BUF_NEXT(BRIDGE_BUF_0_MAX_PCI_RETRY, 7)
/*
* Buffer (x) Max Latency Count Register
*
* This counter is contains the maximum count (in bus clocks) for a single
* request which was in-flight for this buffer. A word write to this
* address clears the count.
*/
#define BRIDGE_BUF_0_MAX_LATENCY 0x000434
#define BRIDGE_BUF_2_MAX_LATENCY BRIDGE_BUF_NEXT(BRIDGE_BUF_0_MAX_LATENCY, 1)
#define BRIDGE_BUF_4_MAX_LATENCY BRIDGE_BUF_NEXT(BRIDGE_BUF_0_MAX_LATENCY, 2)
#define BRIDGE_BUF_6_MAX_LATENCY BRIDGE_BUF_NEXT(BRIDGE_BUF_0_MAX_LATENCY, 3)
#define BRIDGE_BUF_8_MAX_LATENCY BRIDGE_BUF_NEXT(BRIDGE_BUF_0_MAX_LATENCY, 4)
#define BRIDGE_BUF_10_MAX_LATENCY BRIDGE_BUF_NEXT(BRIDGE_BUF_0_MAX_LATENCY, 5)
#define BRIDGE_BUF_12_MAX_LATENCY BRIDGE_BUF_NEXT(BRIDGE_BUF_0_MAX_LATENCY, 6)
#define BRIDGE_BUF_14_MAX_LATENCY BRIDGE_BUF_NEXT(BRIDGE_BUF_0_MAX_LATENCY, 7)
/*
* Buffer (x) Clear All Register
*
* Any access to this register clears all the count values for the (x)
* registers.
*/
#define BRIDGE_BUF_0_CLEAR_ALL 0x00043C
#define BRIDGE_BUF_2_CLEAR_ALL BRIDGE_BUF_NEXT(BRIDGE_BUF_0_CLEAR_ALL, 1)
#define BRIDGE_BUF_4_CLEAR_ALL BRIDGE_BUF_NEXT(BRIDGE_BUF_0_CLEAR_ALL, 2)
#define BRIDGE_BUF_6_CLEAR_ALL BRIDGE_BUF_NEXT(BRIDGE_BUF_0_CLEAR_ALL, 3)
#define BRIDGE_BUF_8_CLEAR_ALL BRIDGE_BUF_NEXT(BRIDGE_BUF_0_CLEAR_ALL, 4)
#define BRIDGE_BUF_10_CLEAR_ALL BRIDGE_BUF_NEXT(BRIDGE_BUF_0_CLEAR_ALL, 5)
#define BRIDGE_BUF_12_CLEAR_ALL BRIDGE_BUF_NEXT(BRIDGE_BUF_0_CLEAR_ALL, 6)
#define BRIDGE_BUF_14_CLEAR_ALL BRIDGE_BUF_NEXT(BRIDGE_BUF_0_CLEAR_ALL, 7)
/* end of Performance Monitor Registers */
/* Byte offset macros for Bridge I/O space */
#define BRIDGE_ATE_RAM 0x00010000 /* Internal Addr Xlat Ram */
#define BRIDGE_TYPE0_CFG_DEV0 0x00020000 /* Type 0 Cfg, Device 0 */
#define BRIDGE_TYPE0_CFG_SLOT_OFF 0x00001000 /* Type 0 Cfg Slot Offset (1..7) */
#define BRIDGE_TYPE0_CFG_FUNC_OFF 0x00000100 /* Type 0 Cfg Func Offset (1..7) */
#define BRIDGE_TYPE0_CFG_DEV(s) (BRIDGE_TYPE0_CFG_DEV0+\
(s)*BRIDGE_TYPE0_CFG_SLOT_OFF)
#define BRIDGE_TYPE0_CFG_DEVF(s,f) (BRIDGE_TYPE0_CFG_DEV0+\
(s)*BRIDGE_TYPE0_CFG_SLOT_OFF+\
(f)*BRIDGE_TYPE0_CFG_FUNC_OFF)
#define BRIDGE_TYPE1_CFG 0x00028000 /* Type 1 Cfg space */
#define BRIDGE_PCI_IACK 0x00030000 /* PCI Interrupt Ack */
#define BRIDGE_EXT_SSRAM 0x00080000 /* Extern SSRAM (ATE) */
/* Byte offset macros for Bridge device IO spaces */
#define BRIDGE_DEV_CNT 8 /* Up to 8 devices per bridge */
#define BRIDGE_DEVIO0 0x00200000 /* Device IO 0 Addr */
#define BRIDGE_DEVIO1 0x00400000 /* Device IO 1 Addr */
#define BRIDGE_DEVIO2 0x00600000 /* Device IO 2 Addr */
#define BRIDGE_DEVIO_OFF 0x00100000 /* Device IO Offset (3..7) */
#define BRIDGE_DEVIO_2MB 0x00200000 /* Device IO Offset (0..1) */
#define BRIDGE_DEVIO_1MB 0x00100000 /* Device IO Offset (2..7) */
#if LANGUAGE_C
#define BRIDGE_DEVIO(x) ((x)<=1 ? BRIDGE_DEVIO0+(x)*BRIDGE_DEVIO_2MB : BRIDGE_DEVIO2+((x)-2)*BRIDGE_DEVIO_1MB)
#endif /* LANGUAGE_C */
#define BRIDGE_EXTERNAL_FLASH 0x00C00000 /* External Flash PROMS */
/* ========================================================================
* Bridge register bit field definitions
*/
/* Widget part number of bridge */
#define BRIDGE_WIDGET_PART_NUM 0xc002
#define XBRIDGE_WIDGET_PART_NUM 0xd002
/* Manufacturer of bridge */
#define BRIDGE_WIDGET_MFGR_NUM 0x036
#define XBRIDGE_WIDGET_MFGR_NUM 0x024
/* Revision numbers for known [X]Bridge revisions */
#define BRIDGE_REV_A 0x1
#define BRIDGE_REV_B 0x2
#define BRIDGE_REV_C 0x3
#define BRIDGE_REV_D 0x4
#define XBRIDGE_REV_A 0x1
#define XBRIDGE_REV_B 0x2
/* Part + Rev numbers allows distinction and acscending sequence */
#define BRIDGE_PART_REV_A (BRIDGE_WIDGET_PART_NUM << 4 | BRIDGE_REV_A)
#define BRIDGE_PART_REV_B (BRIDGE_WIDGET_PART_NUM << 4 | BRIDGE_REV_B)
#define BRIDGE_PART_REV_C (BRIDGE_WIDGET_PART_NUM << 4 | BRIDGE_REV_C)
#define BRIDGE_PART_REV_D (BRIDGE_WIDGET_PART_NUM << 4 | BRIDGE_REV_D)
#define XBRIDGE_PART_REV_A (XBRIDGE_WIDGET_PART_NUM << 4 | XBRIDGE_REV_A)
#define XBRIDGE_PART_REV_B (XBRIDGE_WIDGET_PART_NUM << 4 | XBRIDGE_REV_B)
/* Bridge widget status register bits definition */
#define BRIDGE_STAT_LLP_REC_CNT (0xFFu << 24)
#define BRIDGE_STAT_LLP_TX_CNT (0xFF << 16)
#define BRIDGE_STAT_FLASH_SELECT (0x1 << 6)
#define BRIDGE_STAT_PCI_GIO_N (0x1 << 5)
#define BRIDGE_STAT_PENDING (0x1F << 0)
/* Bridge widget control register bits definition */
#define BRIDGE_CTRL_FLASH_WR_EN (0x1ul << 31)
#define BRIDGE_CTRL_EN_CLK50 (0x1 << 30)
#define BRIDGE_CTRL_EN_CLK40 (0x1 << 29)
#define BRIDGE_CTRL_EN_CLK33 (0x1 << 28)
#define BRIDGE_CTRL_RST(n) ((n) << 24)
#define BRIDGE_CTRL_RST_MASK (BRIDGE_CTRL_RST(0xF))
#define BRIDGE_CTRL_RST_PIN(x) (BRIDGE_CTRL_RST(0x1 << (x)))
#define BRIDGE_CTRL_IO_SWAP (0x1 << 23)
#define BRIDGE_CTRL_MEM_SWAP (0x1 << 22)
#define BRIDGE_CTRL_PAGE_SIZE (0x1 << 21)
#define BRIDGE_CTRL_SS_PAR_BAD (0x1 << 20)
#define BRIDGE_CTRL_SS_PAR_EN (0x1 << 19)
#define BRIDGE_CTRL_SSRAM_SIZE(n) ((n) << 17)
#define BRIDGE_CTRL_SSRAM_SIZE_MASK (BRIDGE_CTRL_SSRAM_SIZE(0x3))
#define BRIDGE_CTRL_SSRAM_512K (BRIDGE_CTRL_SSRAM_SIZE(0x3))
#define BRIDGE_CTRL_SSRAM_128K (BRIDGE_CTRL_SSRAM_SIZE(0x2))
#define BRIDGE_CTRL_SSRAM_64K (BRIDGE_CTRL_SSRAM_SIZE(0x1))
#define BRIDGE_CTRL_SSRAM_1K (BRIDGE_CTRL_SSRAM_SIZE(0x0))
#define BRIDGE_CTRL_F_BAD_PKT (0x1 << 16)
#define BRIDGE_CTRL_LLP_XBAR_CRD(n) ((n) << 12)
#define BRIDGE_CTRL_LLP_XBAR_CRD_MASK (BRIDGE_CTRL_LLP_XBAR_CRD(0xf))
#define BRIDGE_CTRL_CLR_RLLP_CNT (0x1 << 11)
#define BRIDGE_CTRL_CLR_TLLP_CNT (0x1 << 10)
#define BRIDGE_CTRL_SYS_END (0x1 << 9)
#define BRIDGE_CTRL_MAX_TRANS(n) ((n) << 4)
#define BRIDGE_CTRL_MAX_TRANS_MASK (BRIDGE_CTRL_MAX_TRANS(0x1f))
#define BRIDGE_CTRL_WIDGET_ID(n) ((n) << 0)
#define BRIDGE_CTRL_WIDGET_ID_MASK (BRIDGE_CTRL_WIDGET_ID(0xf))
/* Bridge Response buffer Error Upper Register bit fields definition */
#define BRIDGE_RESP_ERRUPPR_DEVNUM_SHFT (20)
#define BRIDGE_RESP_ERRUPPR_DEVNUM_MASK (0x7 << BRIDGE_RESP_ERRUPPR_DEVNUM_SHFT)
#define BRIDGE_RESP_ERRUPPR_BUFNUM_SHFT (16)
#define BRIDGE_RESP_ERRUPPR_BUFNUM_MASK (0xF << BRIDGE_RESP_ERRUPPR_BUFNUM_SHFT)
#define BRIDGE_RESP_ERRRUPPR_BUFMASK (0xFFFF)
#define BRIDGE_RESP_ERRUPPR_BUFNUM(x) \
(((x) & BRIDGE_RESP_ERRUPPR_BUFNUM_MASK) >> \
BRIDGE_RESP_ERRUPPR_BUFNUM_SHFT)
#define BRIDGE_RESP_ERRUPPR_DEVICE(x) \
(((x) & BRIDGE_RESP_ERRUPPR_DEVNUM_MASK) >> \
BRIDGE_RESP_ERRUPPR_DEVNUM_SHFT)
/* Bridge direct mapping register bits definition */
#define BRIDGE_DIRMAP_W_ID_SHFT 20
#define BRIDGE_DIRMAP_W_ID (0xf << BRIDGE_DIRMAP_W_ID_SHFT)
#define BRIDGE_DIRMAP_RMF_64 (0x1 << 18)
#define BRIDGE_DIRMAP_ADD512 (0x1 << 17)
#define BRIDGE_DIRMAP_OFF (0x1ffff << 0)
#define BRIDGE_DIRMAP_OFF_ADDRSHFT (31) /* lsbit of DIRMAP_OFF is xtalk address bit 31 */
/* Bridge Arbitration register bits definition */
#define BRIDGE_ARB_REQ_WAIT_TICK(x) ((x) << 16)
#define BRIDGE_ARB_REQ_WAIT_TICK_MASK BRIDGE_ARB_REQ_WAIT_TICK(0x3)
#define BRIDGE_ARB_REQ_WAIT_EN(x) ((x) << 8)
#define BRIDGE_ARB_REQ_WAIT_EN_MASK BRIDGE_ARB_REQ_WAIT_EN(0xff)
#define BRIDGE_ARB_FREEZE_GNT (1 << 6)
#define BRIDGE_ARB_HPRI_RING_B2 (1 << 5)
#define BRIDGE_ARB_HPRI_RING_B1 (1 << 4)
#define BRIDGE_ARB_HPRI_RING_B0 (1 << 3)
#define BRIDGE_ARB_LPRI_RING_B2 (1 << 2)
#define BRIDGE_ARB_LPRI_RING_B1 (1 << 1)
#define BRIDGE_ARB_LPRI_RING_B0 (1 << 0)
/* Bridge Bus time-out register bits definition */
#define BRIDGE_BUS_PCI_RETRY_HLD(x) ((x) << 16)
#define BRIDGE_BUS_PCI_RETRY_HLD_MASK BRIDGE_BUS_PCI_RETRY_HLD(0x1f)
#define BRIDGE_BUS_GIO_TIMEOUT (1 << 12)
#define BRIDGE_BUS_PCI_RETRY_CNT(x) ((x) << 0)
#define BRIDGE_BUS_PCI_RETRY_MASK BRIDGE_BUS_PCI_RETRY_CNT(0x3ff)
/* Bridge interrupt status register bits definition */
#define BRIDGE_ISR_MULTI_ERR (0x1u << 31) /* bridge only */
#define BRIDGE_ISR_PMU_ESIZE_FAULT (0x1 << 30) /* bridge only */
#define BRIDGE_ISR_PAGE_FAULT (0x1 << 30) /* xbridge only */
#define BRIDGE_ISR_UNEXP_RESP (0x1 << 29)
#define BRIDGE_ISR_BAD_XRESP_PKT (0x1 << 28)
#define BRIDGE_ISR_BAD_XREQ_PKT (0x1 << 27)
#define BRIDGE_ISR_RESP_XTLK_ERR (0x1 << 26)
#define BRIDGE_ISR_REQ_XTLK_ERR (0x1 << 25)
#define BRIDGE_ISR_INVLD_ADDR (0x1 << 24)
#define BRIDGE_ISR_UNSUPPORTED_XOP (0x1 << 23)
#define BRIDGE_ISR_XREQ_FIFO_OFLOW (0x1 << 22)
#define BRIDGE_ISR_LLP_REC_SNERR (0x1 << 21)
#define BRIDGE_ISR_LLP_REC_CBERR (0x1 << 20)
#define BRIDGE_ISR_LLP_RCTY (0x1 << 19)
#define BRIDGE_ISR_LLP_TX_RETRY (0x1 << 18)
#define BRIDGE_ISR_LLP_TCTY (0x1 << 17)
#define BRIDGE_ISR_SSRAM_PERR (0x1 << 16)
#define BRIDGE_ISR_PCI_ABORT (0x1 << 15)
#define BRIDGE_ISR_PCI_PARITY (0x1 << 14)
#define BRIDGE_ISR_PCI_SERR (0x1 << 13)
#define BRIDGE_ISR_PCI_PERR (0x1 << 12)
#define BRIDGE_ISR_PCI_MST_TIMEOUT (0x1 << 11)
#define BRIDGE_ISR_GIO_MST_TIMEOUT BRIDGE_ISR_PCI_MST_TIMEOUT
#define BRIDGE_ISR_PCI_RETRY_CNT (0x1 << 10)
#define BRIDGE_ISR_XREAD_REQ_TIMEOUT (0x1 << 9)
#define BRIDGE_ISR_GIO_B_ENBL_ERR (0x1 << 8)
#define BRIDGE_ISR_INT_MSK (0xff << 0)
#define BRIDGE_ISR_INT(x) (0x1 << (x))
#define BRIDGE_ISR_LINK_ERROR \
(BRIDGE_ISR_LLP_REC_SNERR|BRIDGE_ISR_LLP_REC_CBERR| \
BRIDGE_ISR_LLP_RCTY|BRIDGE_ISR_LLP_TX_RETRY| \
BRIDGE_ISR_LLP_TCTY)
#define BRIDGE_ISR_PCIBUS_PIOERR \
(BRIDGE_ISR_PCI_MST_TIMEOUT|BRIDGE_ISR_PCI_ABORT)
#define BRIDGE_ISR_PCIBUS_ERROR \
(BRIDGE_ISR_PCIBUS_PIOERR|BRIDGE_ISR_PCI_PERR| \
BRIDGE_ISR_PCI_SERR|BRIDGE_ISR_PCI_RETRY_CNT| \
BRIDGE_ISR_PCI_PARITY)
#define BRIDGE_ISR_XTALK_ERROR \
(BRIDGE_ISR_XREAD_REQ_TIMEOUT|BRIDGE_ISR_XREQ_FIFO_OFLOW|\
BRIDGE_ISR_UNSUPPORTED_XOP|BRIDGE_ISR_INVLD_ADDR| \
BRIDGE_ISR_REQ_XTLK_ERR|BRIDGE_ISR_RESP_XTLK_ERR| \
BRIDGE_ISR_BAD_XREQ_PKT|BRIDGE_ISR_BAD_XRESP_PKT| \
BRIDGE_ISR_UNEXP_RESP)
#define BRIDGE_ISR_ERRORS \
(BRIDGE_ISR_LINK_ERROR|BRIDGE_ISR_PCIBUS_ERROR| \
BRIDGE_ISR_XTALK_ERROR|BRIDGE_ISR_SSRAM_PERR| \
BRIDGE_ISR_PMU_ESIZE_FAULT)
/*
* List of Errors which are fatal and kill the sytem
*/
#define BRIDGE_ISR_ERROR_FATAL \
((BRIDGE_ISR_XTALK_ERROR & ~BRIDGE_ISR_XREAD_REQ_TIMEOUT)|\
BRIDGE_ISR_PCI_SERR|BRIDGE_ISR_PCI_PARITY )
#define BRIDGE_ISR_ERROR_DUMP \
(BRIDGE_ISR_PCIBUS_ERROR|BRIDGE_ISR_PMU_ESIZE_FAULT| \
BRIDGE_ISR_XTALK_ERROR|BRIDGE_ISR_SSRAM_PERR)
/* Bridge interrupt enable register bits definition */
#define BRIDGE_IMR_UNEXP_RESP BRIDGE_ISR_UNEXP_RESP
#define BRIDGE_IMR_PMU_ESIZE_FAULT BRIDGE_ISR_PMU_ESIZE_FAULT
#define BRIDGE_IMR_BAD_XRESP_PKT BRIDGE_ISR_BAD_XRESP_PKT
#define BRIDGE_IMR_BAD_XREQ_PKT BRIDGE_ISR_BAD_XREQ_PKT
#define BRIDGE_IMR_RESP_XTLK_ERR BRIDGE_ISR_RESP_XTLK_ERR
#define BRIDGE_IMR_REQ_XTLK_ERR BRIDGE_ISR_REQ_XTLK_ERR
#define BRIDGE_IMR_INVLD_ADDR BRIDGE_ISR_INVLD_ADDR
#define BRIDGE_IMR_UNSUPPORTED_XOP BRIDGE_ISR_UNSUPPORTED_XOP
#define BRIDGE_IMR_XREQ_FIFO_OFLOW BRIDGE_ISR_XREQ_FIFO_OFLOW
#define BRIDGE_IMR_LLP_REC_SNERR BRIDGE_ISR_LLP_REC_SNERR
#define BRIDGE_IMR_LLP_REC_CBERR BRIDGE_ISR_LLP_REC_CBERR
#define BRIDGE_IMR_LLP_RCTY BRIDGE_ISR_LLP_RCTY
#define BRIDGE_IMR_LLP_TX_RETRY BRIDGE_ISR_LLP_TX_RETRY
#define BRIDGE_IMR_LLP_TCTY BRIDGE_ISR_LLP_TCTY
#define BRIDGE_IMR_SSRAM_PERR BRIDGE_ISR_SSRAM_PERR
#define BRIDGE_IMR_PCI_ABORT BRIDGE_ISR_PCI_ABORT
#define BRIDGE_IMR_PCI_PARITY BRIDGE_ISR_PCI_PARITY
#define BRIDGE_IMR_PCI_SERR BRIDGE_ISR_PCI_SERR
#define BRIDGE_IMR_PCI_PERR BRIDGE_ISR_PCI_PERR
#define BRIDGE_IMR_PCI_MST_TIMEOUT BRIDGE_ISR_PCI_MST_TIMEOUT
#define BRIDGE_IMR_GIO_MST_TIMEOUT BRIDGE_ISR_GIO_MST_TIMEOUT
#define BRIDGE_IMR_PCI_RETRY_CNT BRIDGE_ISR_PCI_RETRY_CNT
#define BRIDGE_IMR_XREAD_REQ_TIMEOUT BRIDGE_ISR_XREAD_REQ_TIMEOUT
#define BRIDGE_IMR_GIO_B_ENBL_ERR BRIDGE_ISR_GIO_B_ENBL_ERR
#define BRIDGE_IMR_INT_MSK BRIDGE_ISR_INT_MSK
#define BRIDGE_IMR_INT(x) BRIDGE_ISR_INT(x)
/* Bridge interrupt reset register bits definition */
#define BRIDGE_IRR_MULTI_CLR (0x1 << 6)
#define BRIDGE_IRR_CRP_GRP_CLR (0x1 << 5)
#define BRIDGE_IRR_RESP_BUF_GRP_CLR (0x1 << 4)
#define BRIDGE_IRR_REQ_DSP_GRP_CLR (0x1 << 3)
#define BRIDGE_IRR_LLP_GRP_CLR (0x1 << 2)
#define BRIDGE_IRR_SSRAM_GRP_CLR (0x1 << 1)
#define BRIDGE_IRR_PCI_GRP_CLR (0x1 << 0)
#define BRIDGE_IRR_GIO_GRP_CLR (0x1 << 0)
#define BRIDGE_IRR_ALL_CLR 0x7f
#define BRIDGE_IRR_CRP_GRP (BRIDGE_ISR_UNEXP_RESP | \
BRIDGE_ISR_XREQ_FIFO_OFLOW)
#define BRIDGE_IRR_RESP_BUF_GRP (BRIDGE_ISR_BAD_XRESP_PKT | \
BRIDGE_ISR_RESP_XTLK_ERR | \
BRIDGE_ISR_XREAD_REQ_TIMEOUT)
#define BRIDGE_IRR_REQ_DSP_GRP (BRIDGE_ISR_UNSUPPORTED_XOP | \
BRIDGE_ISR_BAD_XREQ_PKT | \
BRIDGE_ISR_REQ_XTLK_ERR | \
BRIDGE_ISR_INVLD_ADDR)
#define BRIDGE_IRR_LLP_GRP (BRIDGE_ISR_LLP_REC_SNERR | \
BRIDGE_ISR_LLP_REC_CBERR | \
BRIDGE_ISR_LLP_RCTY | \
BRIDGE_ISR_LLP_TX_RETRY | \
BRIDGE_ISR_LLP_TCTY)
#define BRIDGE_IRR_SSRAM_GRP (BRIDGE_ISR_SSRAM_PERR | \
BRIDGE_ISR_PMU_ESIZE_FAULT)
#define BRIDGE_IRR_PCI_GRP (BRIDGE_ISR_PCI_ABORT | \
BRIDGE_ISR_PCI_PARITY | \
BRIDGE_ISR_PCI_SERR | \
BRIDGE_ISR_PCI_PERR | \
BRIDGE_ISR_PCI_MST_TIMEOUT | \
BRIDGE_ISR_PCI_RETRY_CNT)
#define BRIDGE_IRR_GIO_GRP (BRIDGE_ISR_GIO_B_ENBL_ERR | \
BRIDGE_ISR_GIO_MST_TIMEOUT)
/* Bridge INT_DEV register bits definition */
#define BRIDGE_INT_DEV_SHFT(n) ((n)*3)
#define BRIDGE_INT_DEV_MASK(n) (0x7 << BRIDGE_INT_DEV_SHFT(n))
#define BRIDGE_INT_DEV_SET(_dev, _line) (_dev << BRIDGE_INT_DEV_SHFT(_line))
/* Bridge interrupt(x) register bits definition */
#define BRIDGE_INT_ADDR_HOST 0x0003FF00
#define BRIDGE_INT_ADDR_FLD 0x000000FF
#define BRIDGE_TMO_PCI_RETRY_HLD_MASK 0x1f0000
#define BRIDGE_TMO_GIO_TIMEOUT_MASK 0x001000
#define BRIDGE_TMO_PCI_RETRY_CNT_MASK 0x0003ff
#define BRIDGE_TMO_PCI_RETRY_CNT_MAX 0x3ff
#ifdef SN0
/*
* The NASID should be shifted by this amount and stored into the
* interrupt(x) register.
*/
#define BRIDGE_INT_ADDR_NASID_SHFT 8
/*
* The BRIDGE_INT_ADDR_DEST_IO bit should be set to send an interrupt to
* memory.
*/
#define BRIDGE_INT_ADDR_DEST_IO (1 << 17)
#define BRIDGE_INT_ADDR_DEST_MEM 0
#define BRIDGE_INT_ADDR_MASK (1 << 17)
#endif
/* Bridge device(x) register bits definition */
#define BRIDGE_DEV_ERR_LOCK_EN (1ull << 28)
#define BRIDGE_DEV_PAGE_CHK_DIS (1ull << 27)
#define BRIDGE_DEV_FORCE_PCI_PAR (1ull << 26)
#define BRIDGE_DEV_VIRTUAL_EN (1ull << 25)
#define BRIDGE_DEV_PMU_WRGA_EN (1ull << 24)
#define BRIDGE_DEV_DIR_WRGA_EN (1ull << 23)
#define BRIDGE_DEV_DEV_SIZE (1ull << 22)
#define BRIDGE_DEV_RT (1ull << 21)
#define BRIDGE_DEV_SWAP_PMU (1ull << 20)
#define BRIDGE_DEV_SWAP_DIR (1ull << 19)
#define BRIDGE_DEV_PREF (1ull << 18)
#define BRIDGE_DEV_PRECISE (1ull << 17)
#define BRIDGE_DEV_COH (1ull << 16)
#define BRIDGE_DEV_BARRIER (1ull << 15)
#define BRIDGE_DEV_GBR (1ull << 14)
#define BRIDGE_DEV_DEV_SWAP (1ull << 13)
#define BRIDGE_DEV_DEV_IO_MEM (1ull << 12)
#define BRIDGE_DEV_OFF_MASK 0x00000fff
#define BRIDGE_DEV_OFF_ADDR_SHFT 20
#define XBRIDGE_DEV_PMU_BITS BRIDGE_DEV_PMU_WRGA_EN
#define BRIDGE_DEV_PMU_BITS (BRIDGE_DEV_PMU_WRGA_EN | \
BRIDGE_DEV_SWAP_PMU)
#define BRIDGE_DEV_D32_BITS (BRIDGE_DEV_DIR_WRGA_EN | \
BRIDGE_DEV_SWAP_DIR | \
BRIDGE_DEV_PREF | \
BRIDGE_DEV_PRECISE | \
BRIDGE_DEV_COH | \
BRIDGE_DEV_BARRIER)
#define XBRIDGE_DEV_D64_BITS (BRIDGE_DEV_DIR_WRGA_EN | \
BRIDGE_DEV_COH | \
BRIDGE_DEV_BARRIER)
#define BRIDGE_DEV_D64_BITS (BRIDGE_DEV_DIR_WRGA_EN | \
BRIDGE_DEV_SWAP_DIR | \
BRIDGE_DEV_COH | \
BRIDGE_DEV_BARRIER)
/* Bridge Error Upper register bit field definition */
#define BRIDGE_ERRUPPR_DEVMASTER (0x1 << 20) /* Device was master */
#define BRIDGE_ERRUPPR_PCIVDEV (0x1 << 19) /* Virtual Req value */
#define BRIDGE_ERRUPPR_DEVNUM_SHFT (16)
#define BRIDGE_ERRUPPR_DEVNUM_MASK (0x7 << BRIDGE_ERRUPPR_DEVNUM_SHFT)
#define BRIDGE_ERRUPPR_DEVICE(err) (((err) >> BRIDGE_ERRUPPR_DEVNUM_SHFT) & 0x7)
#define BRIDGE_ERRUPPR_ADDRMASK (0xFFFF)
/* Bridge interrupt mode register bits definition */
#define BRIDGE_INTMODE_CLR_PKT_EN(x) (0x1 << (x))
/* this should be written to the xbow's link_control(x) register */
#define BRIDGE_CREDIT 3
/* RRB assignment register */
#define BRIDGE_RRB_EN 0x8 /* after shifting down */
#define BRIDGE_RRB_DEV 0x7 /* after shifting down */
#define BRIDGE_RRB_VDEV 0x4 /* after shifting down */
#define BRIDGE_RRB_PDEV 0x3 /* after shifting down */
/* RRB status register */
#define BRIDGE_RRB_VALID(r) (0x00010000<<(r))
#define BRIDGE_RRB_INUSE(r) (0x00000001<<(r))
/* RRB clear register */
#define BRIDGE_RRB_CLEAR(r) (0x00000001<<(r))
/* xbox system controller declarations */
#define XBOX_BRIDGE_WID 8
#define FLASH_PROM1_BASE 0xE00000 /* To read the xbox sysctlr status */
#define XBOX_RPS_EXISTS 1 << 6 /* RPS bit in status register */
#define XBOX_RPS_FAIL 1 << 4 /* RPS status bit in register */
/* ========================================================================
*/
/*
* Macros for Xtalk to Bridge bus (PCI/GIO) PIO
* refer to section 4.2.1 of Bridge Spec for xtalk to PCI/GIO PIO mappings
*/
/* XTALK addresses that map into Bridge Bus addr space */
#define BRIDGE_PIO32_XTALK_ALIAS_BASE 0x000040000000L
#define BRIDGE_PIO32_XTALK_ALIAS_LIMIT 0x00007FFFFFFFL
#define BRIDGE_PIO64_XTALK_ALIAS_BASE 0x000080000000L
#define BRIDGE_PIO64_XTALK_ALIAS_LIMIT 0x0000BFFFFFFFL
#define BRIDGE_PCIIO_XTALK_ALIAS_BASE 0x000100000000L
#define BRIDGE_PCIIO_XTALK_ALIAS_LIMIT 0x0001FFFFFFFFL
/* Ranges of PCI bus space that can be accessed via PIO from xtalk */
#define BRIDGE_MIN_PIO_ADDR_MEM 0x00000000 /* 1G PCI memory space */
#define BRIDGE_MAX_PIO_ADDR_MEM 0x3fffffff
#define BRIDGE_MIN_PIO_ADDR_IO 0x00000000 /* 4G PCI IO space */
#define BRIDGE_MAX_PIO_ADDR_IO 0xffffffff
/* XTALK addresses that map into PCI addresses */
#define BRIDGE_PCI_MEM32_BASE BRIDGE_PIO32_XTALK_ALIAS_BASE
#define BRIDGE_PCI_MEM32_LIMIT BRIDGE_PIO32_XTALK_ALIAS_LIMIT
#define BRIDGE_PCI_MEM64_BASE BRIDGE_PIO64_XTALK_ALIAS_BASE
#define BRIDGE_PCI_MEM64_LIMIT BRIDGE_PIO64_XTALK_ALIAS_LIMIT
#define BRIDGE_PCI_IO_BASE BRIDGE_PCIIO_XTALK_ALIAS_BASE
#define BRIDGE_PCI_IO_LIMIT BRIDGE_PCIIO_XTALK_ALIAS_LIMIT
/*
* Macros for Bridge bus (PCI/GIO) to Xtalk DMA
*/
/* Bridge Bus DMA addresses */
#define BRIDGE_LOCAL_BASE 0
#define BRIDGE_DMA_MAPPED_BASE 0x40000000
#define BRIDGE_DMA_MAPPED_SIZE 0x40000000 /* 1G Bytes */
#define BRIDGE_DMA_DIRECT_BASE 0x80000000
#define BRIDGE_DMA_DIRECT_SIZE 0x80000000 /* 2G Bytes */
#define PCI32_LOCAL_BASE BRIDGE_LOCAL_BASE
/* PCI addresses of regions decoded by Bridge for DMA */
#define PCI32_MAPPED_BASE BRIDGE_DMA_MAPPED_BASE
#define PCI32_DIRECT_BASE BRIDGE_DMA_DIRECT_BASE
#if LANGUAGE_C
#define IS_PCI32_LOCAL(x) ((uint64_t)(x) < PCI32_MAPPED_BASE)
#define IS_PCI32_MAPPED(x) ((uint64_t)(x) < PCI32_DIRECT_BASE && \
(uint64_t)(x) >= PCI32_MAPPED_BASE)
#define IS_PCI32_DIRECT(x) ((uint64_t)(x) >= PCI32_MAPPED_BASE)
#define IS_PCI64(x) ((uint64_t)(x) >= PCI64_BASE)
#endif /* LANGUAGE_C */
/*
* The GIO address space.
*/
/* Xtalk to GIO PIO */
#define BRIDGE_GIO_MEM32_BASE BRIDGE_PIO32_XTALK_ALIAS_BASE
#define BRIDGE_GIO_MEM32_LIMIT BRIDGE_PIO32_XTALK_ALIAS_LIMIT
#define GIO_LOCAL_BASE BRIDGE_LOCAL_BASE
/* GIO addresses of regions decoded by Bridge for DMA */
#define GIO_MAPPED_BASE BRIDGE_DMA_MAPPED_BASE
#define GIO_DIRECT_BASE BRIDGE_DMA_DIRECT_BASE
#if LANGUAGE_C
#define IS_GIO_LOCAL(x) ((uint64_t)(x) < GIO_MAPPED_BASE)
#define IS_GIO_MAPPED(x) ((uint64_t)(x) < GIO_DIRECT_BASE && \
(uint64_t)(x) >= GIO_MAPPED_BASE)
#define IS_GIO_DIRECT(x) ((uint64_t)(x) >= GIO_MAPPED_BASE)
#endif /* LANGUAGE_C */
/* PCI to xtalk mapping */
/* given a DIR_OFF value and a pci/gio 32 bits direct address, determine
* which xtalk address is accessed
*/
#define BRIDGE_DIRECT_32_SEG_SIZE BRIDGE_DMA_DIRECT_SIZE
#define BRIDGE_DIRECT_32_TO_XTALK(dir_off,adr) \
((dir_off) * BRIDGE_DIRECT_32_SEG_SIZE + \
((adr) & (BRIDGE_DIRECT_32_SEG_SIZE - 1)) + PHYS_RAMBASE)
/* 64-bit address attribute masks */
#define PCI64_ATTR_TARG_MASK 0xf000000000000000
#define PCI64_ATTR_TARG_SHFT 60
#define PCI64_ATTR_PREF (1ull << 59)
#define PCI64_ATTR_PREC (1ull << 58)
#define PCI64_ATTR_VIRTUAL (1ull << 57)
#define PCI64_ATTR_BAR (1ull << 56)
#define PCI64_ATTR_SWAP (1ull << 55)
#define PCI64_ATTR_RMF_MASK 0x00ff000000000000
#define PCI64_ATTR_RMF_SHFT 48
#if LANGUAGE_C
/* Address translation entry for mapped pci32 accesses */
typedef union ate_u {
uint64_t ent;
struct xb_ate_s { /* xbridge */
uint64_t :16;
uint64_t addr:36;
uint64_t targ:4;
uint64_t reserved:2;
uint64_t swap:1;
uint64_t barrier:1;
uint64_t prefetch:1;
uint64_t precise:1;
uint64_t coherent:1;
uint64_t valid:1;
} xb_field;
struct ate_s { /* bridge */
uint64_t rmf:16;
uint64_t addr:36;
uint64_t targ:4;
uint64_t reserved:3;
uint64_t barrier:1;
uint64_t prefetch:1;
uint64_t precise:1;
uint64_t coherent:1;
uint64_t valid:1;
} field;
} ate_t;
#endif /* LANGUAGE_C */
#define ATE_V (1 << 0)
#define ATE_CO (1 << 1)
#define ATE_PREC (1 << 2)
#define ATE_PREF (1 << 3)
#define ATE_BAR (1 << 4)
#define ATE_SWAP (1 << 5)
#define ATE_PFNSHIFT 12
#define ATE_TIDSHIFT 8
#define ATE_RMFSHIFT 48
#define mkate(xaddr, xid, attr) ((xaddr) & 0x0000fffffffff000ULL) | \
((xid)<<ATE_TIDSHIFT) | \
(attr)
/*
* for xbridge, bit 29 of the pci address is the swap bit */
#define ATE_SWAPSHIFT 29
#define ATE_SWAP_ON(x) ((x) |= (1 << ATE_SWAPSHIFT))
#define ATE_SWAP_OFF(x) ((x) &= ~(1 << ATE_SWAPSHIFT))
#define is_xbridge(bridge) \
(XWIDGET_PART_NUM(bridge->b_wid_id) == XBRIDGE_WIDGET_PART_NUM)
#if LANGUAGE_C
/* ========================================================================
*/
#ifdef MACROFIELD_LINE
/*
* This table forms a relation between the byte offset macros normally
* used for ASM coding and the calculated byte offsets of the fields
* in the C structure.
*
* See bridge_check.c and bridge_html.c for further details.
*/
#ifndef MACROFIELD_LINE_BITFIELD
#define MACROFIELD_LINE_BITFIELD(m) /* ignored */
#endif
struct macrofield_s bridge_macrofield[] =
{
MACROFIELD_LINE(BRIDGE_WID_ID, b_wid_id)
MACROFIELD_LINE_BITFIELD(WIDGET_REV_NUM)
MACROFIELD_LINE_BITFIELD(WIDGET_PART_NUM)
MACROFIELD_LINE_BITFIELD(WIDGET_MFG_NUM)
MACROFIELD_LINE(BRIDGE_WID_STAT, b_wid_stat)
MACROFIELD_LINE_BITFIELD(BRIDGE_STAT_LLP_REC_CNT)
MACROFIELD_LINE_BITFIELD(BRIDGE_STAT_LLP_TX_CNT)
MACROFIELD_LINE_BITFIELD(BRIDGE_STAT_FLASH_SELECT)
MACROFIELD_LINE_BITFIELD(BRIDGE_STAT_PCI_GIO_N)
MACROFIELD_LINE_BITFIELD(BRIDGE_STAT_PENDING)
MACROFIELD_LINE(BRIDGE_WID_ERR_UPPER, b_wid_err_upper)
MACROFIELD_LINE(BRIDGE_WID_ERR_LOWER, b_wid_err_lower)
MACROFIELD_LINE(BRIDGE_WID_CONTROL, b_wid_control)
MACROFIELD_LINE_BITFIELD(BRIDGE_CTRL_FLASH_WR_EN)
MACROFIELD_LINE_BITFIELD(BRIDGE_CTRL_EN_CLK50)
MACROFIELD_LINE_BITFIELD(BRIDGE_CTRL_EN_CLK40)
MACROFIELD_LINE_BITFIELD(BRIDGE_CTRL_EN_CLK33)
MACROFIELD_LINE_BITFIELD(BRIDGE_CTRL_RST_MASK)
MACROFIELD_LINE_BITFIELD(BRIDGE_CTRL_IO_SWAP)
MACROFIELD_LINE_BITFIELD(BRIDGE_CTRL_MEM_SWAP)
MACROFIELD_LINE_BITFIELD(BRIDGE_CTRL_PAGE_SIZE)
MACROFIELD_LINE_BITFIELD(BRIDGE_CTRL_SS_PAR_BAD)
MACROFIELD_LINE_BITFIELD(BRIDGE_CTRL_SS_PAR_EN)
MACROFIELD_LINE_BITFIELD(BRIDGE_CTRL_SSRAM_SIZE_MASK)
MACROFIELD_LINE_BITFIELD(BRIDGE_CTRL_F_BAD_PKT)
MACROFIELD_LINE_BITFIELD(BRIDGE_CTRL_LLP_XBAR_CRD_MASK)
MACROFIELD_LINE_BITFIELD(BRIDGE_CTRL_CLR_RLLP_CNT)
MACROFIELD_LINE_BITFIELD(BRIDGE_CTRL_CLR_TLLP_CNT)
MACROFIELD_LINE_BITFIELD(BRIDGE_CTRL_SYS_END)
MACROFIELD_LINE_BITFIELD(BRIDGE_CTRL_MAX_TRANS_MASK)
MACROFIELD_LINE_BITFIELD(BRIDGE_CTRL_WIDGET_ID_MASK)
MACROFIELD_LINE(BRIDGE_WID_REQ_TIMEOUT, b_wid_req_timeout)
MACROFIELD_LINE(BRIDGE_WID_INT_UPPER, b_wid_int_upper)
MACROFIELD_LINE_BITFIELD(WIDGET_INT_VECTOR)
MACROFIELD_LINE_BITFIELD(WIDGET_TARGET_ID)
MACROFIELD_LINE_BITFIELD(WIDGET_UPP_ADDR)
MACROFIELD_LINE(BRIDGE_WID_INT_LOWER, b_wid_int_lower)
MACROFIELD_LINE(BRIDGE_WID_ERR_CMDWORD, b_wid_err_cmdword)
MACROFIELD_LINE_BITFIELD(WIDGET_DIDN)
MACROFIELD_LINE_BITFIELD(WIDGET_SIDN)
MACROFIELD_LINE_BITFIELD(WIDGET_PACTYP)
MACROFIELD_LINE_BITFIELD(WIDGET_TNUM)
MACROFIELD_LINE_BITFIELD(WIDGET_COHERENT)
MACROFIELD_LINE_BITFIELD(WIDGET_DS)
MACROFIELD_LINE_BITFIELD(WIDGET_GBR)
MACROFIELD_LINE_BITFIELD(WIDGET_VBPM)
MACROFIELD_LINE_BITFIELD(WIDGET_ERROR)
MACROFIELD_LINE_BITFIELD(WIDGET_BARRIER)
MACROFIELD_LINE(BRIDGE_WID_LLP, b_wid_llp)
MACROFIELD_LINE_BITFIELD(WIDGET_LLP_MAXRETRY)
MACROFIELD_LINE_BITFIELD(WIDGET_LLP_NULLTIMEOUT)
MACROFIELD_LINE_BITFIELD(WIDGET_LLP_MAXBURST)
MACROFIELD_LINE(BRIDGE_WID_TFLUSH, b_wid_tflush)
MACROFIELD_LINE(BRIDGE_WID_AUX_ERR, b_wid_aux_err)
MACROFIELD_LINE(BRIDGE_WID_RESP_UPPER, b_wid_resp_upper)
MACROFIELD_LINE(BRIDGE_WID_RESP_LOWER, b_wid_resp_lower)
MACROFIELD_LINE(BRIDGE_WID_TST_PIN_CTRL, b_wid_tst_pin_ctrl)
MACROFIELD_LINE(BRIDGE_DIR_MAP, b_dir_map)
MACROFIELD_LINE_BITFIELD(BRIDGE_DIRMAP_W_ID)
MACROFIELD_LINE_BITFIELD(BRIDGE_DIRMAP_RMF_64)
MACROFIELD_LINE_BITFIELD(BRIDGE_DIRMAP_ADD512)
MACROFIELD_LINE_BITFIELD(BRIDGE_DIRMAP_OFF)
MACROFIELD_LINE(BRIDGE_RAM_PERR, b_ram_perr)
MACROFIELD_LINE(BRIDGE_ARB, b_arb)
MACROFIELD_LINE_BITFIELD(BRIDGE_ARB_REQ_WAIT_TICK_MASK)
MACROFIELD_LINE_BITFIELD(BRIDGE_ARB_REQ_WAIT_EN_MASK)
MACROFIELD_LINE_BITFIELD(BRIDGE_ARB_FREEZE_GNT)
MACROFIELD_LINE_BITFIELD(BRIDGE_ARB_HPRI_RING_B2)
MACROFIELD_LINE_BITFIELD(BRIDGE_ARB_HPRI_RING_B1)
MACROFIELD_LINE_BITFIELD(BRIDGE_ARB_HPRI_RING_B0)
MACROFIELD_LINE_BITFIELD(BRIDGE_ARB_LPRI_RING_B2)
MACROFIELD_LINE_BITFIELD(BRIDGE_ARB_LPRI_RING_B1)
MACROFIELD_LINE_BITFIELD(BRIDGE_ARB_LPRI_RING_B0)
MACROFIELD_LINE(BRIDGE_NIC, b_nic)
MACROFIELD_LINE(BRIDGE_PCI_BUS_TIMEOUT, b_pci_bus_timeout)
MACROFIELD_LINE(BRIDGE_PCI_CFG, b_pci_cfg)
MACROFIELD_LINE(BRIDGE_PCI_ERR_UPPER, b_pci_err_upper)
MACROFIELD_LINE(BRIDGE_PCI_ERR_LOWER, b_pci_err_lower)
MACROFIELD_LINE(BRIDGE_INT_STATUS, b_int_status)
MACROFIELD_LINE_BITFIELD(BRIDGE_ISR_MULTI_ERR)
MACROFIELD_LINE_BITFIELD(BRIDGE_ISR_PMU_ESIZE_FAULT)
MACROFIELD_LINE_BITFIELD(BRIDGE_ISR_UNEXP_RESP)
MACROFIELD_LINE_BITFIELD(BRIDGE_ISR_BAD_XRESP_PKT)
MACROFIELD_LINE_BITFIELD(BRIDGE_ISR_BAD_XREQ_PKT)
MACROFIELD_LINE_BITFIELD(BRIDGE_ISR_RESP_XTLK_ERR)
MACROFIELD_LINE_BITFIELD(BRIDGE_ISR_REQ_XTLK_ERR)
MACROFIELD_LINE_BITFIELD(BRIDGE_ISR_INVLD_ADDR)
MACROFIELD_LINE_BITFIELD(BRIDGE_ISR_UNSUPPORTED_XOP)
MACROFIELD_LINE_BITFIELD(BRIDGE_ISR_XREQ_FIFO_OFLOW)
MACROFIELD_LINE_BITFIELD(BRIDGE_ISR_LLP_REC_SNERR)
MACROFIELD_LINE_BITFIELD(BRIDGE_ISR_LLP_REC_CBERR)
MACROFIELD_LINE_BITFIELD(BRIDGE_ISR_LLP_RCTY)
MACROFIELD_LINE_BITFIELD(BRIDGE_ISR_LLP_TX_RETRY)
MACROFIELD_LINE_BITFIELD(BRIDGE_ISR_LLP_TCTY)
MACROFIELD_LINE_BITFIELD(BRIDGE_ISR_SSRAM_PERR)
MACROFIELD_LINE_BITFIELD(BRIDGE_ISR_PCI_ABORT)
MACROFIELD_LINE_BITFIELD(BRIDGE_ISR_PCI_PARITY)
MACROFIELD_LINE_BITFIELD(BRIDGE_ISR_PCI_SERR)
MACROFIELD_LINE_BITFIELD(BRIDGE_ISR_PCI_PERR)
MACROFIELD_LINE_BITFIELD(BRIDGE_ISR_PCI_MST_TIMEOUT)
MACROFIELD_LINE_BITFIELD(BRIDGE_ISR_PCI_RETRY_CNT)
MACROFIELD_LINE_BITFIELD(BRIDGE_ISR_XREAD_REQ_TIMEOUT)
MACROFIELD_LINE_BITFIELD(BRIDGE_ISR_GIO_B_ENBL_ERR)
MACROFIELD_LINE_BITFIELD(BRIDGE_ISR_INT_MSK)
MACROFIELD_LINE(BRIDGE_INT_ENABLE, b_int_enable)
MACROFIELD_LINE_BITFIELD(BRIDGE_IMR_UNEXP_RESP)
MACROFIELD_LINE_BITFIELD(BRIDGE_IMR_PMU_ESIZE_FAULT)
MACROFIELD_LINE_BITFIELD(BRIDGE_IMR_BAD_XRESP_PKT)
MACROFIELD_LINE_BITFIELD(BRIDGE_IMR_BAD_XREQ_PKT)
MACROFIELD_LINE_BITFIELD(BRIDGE_IMR_RESP_XTLK_ERR)
MACROFIELD_LINE_BITFIELD(BRIDGE_IMR_REQ_XTLK_ERR)
MACROFIELD_LINE_BITFIELD(BRIDGE_IMR_INVLD_ADDR)
MACROFIELD_LINE_BITFIELD(BRIDGE_IMR_UNSUPPORTED_XOP)
MACROFIELD_LINE_BITFIELD(BRIDGE_IMR_XREQ_FIFO_OFLOW)
MACROFIELD_LINE_BITFIELD(BRIDGE_IMR_LLP_REC_SNERR)
MACROFIELD_LINE_BITFIELD(BRIDGE_IMR_LLP_REC_CBERR)
MACROFIELD_LINE_BITFIELD(BRIDGE_IMR_LLP_RCTY)
MACROFIELD_LINE_BITFIELD(BRIDGE_IMR_LLP_TX_RETRY)
MACROFIELD_LINE_BITFIELD(BRIDGE_IMR_LLP_TCTY)
MACROFIELD_LINE_BITFIELD(BRIDGE_IMR_SSRAM_PERR)
MACROFIELD_LINE_BITFIELD(BRIDGE_IMR_PCI_ABORT)
MACROFIELD_LINE_BITFIELD(BRIDGE_IMR_PCI_PARITY)
MACROFIELD_LINE_BITFIELD(BRIDGE_IMR_PCI_SERR)
MACROFIELD_LINE_BITFIELD(BRIDGE_IMR_PCI_PERR)
MACROFIELD_LINE_BITFIELD(BRIDGE_IMR_PCI_MST_TIMEOUT)
MACROFIELD_LINE_BITFIELD(BRIDGE_IMR_PCI_RETRY_CNT)
MACROFIELD_LINE_BITFIELD(BRIDGE_IMR_XREAD_REQ_TIMEOUT)
MACROFIELD_LINE_BITFIELD(BRIDGE_IMR_GIO_B_ENBL_ERR)
MACROFIELD_LINE_BITFIELD(BRIDGE_IMR_INT_MSK)
MACROFIELD_LINE(BRIDGE_INT_RST_STAT, b_int_rst_stat)
MACROFIELD_LINE_BITFIELD(BRIDGE_IRR_ALL_CLR)
MACROFIELD_LINE_BITFIELD(BRIDGE_IRR_MULTI_CLR)
MACROFIELD_LINE_BITFIELD(BRIDGE_IRR_CRP_GRP_CLR)
MACROFIELD_LINE_BITFIELD(BRIDGE_IRR_RESP_BUF_GRP_CLR)
MACROFIELD_LINE_BITFIELD(BRIDGE_IRR_REQ_DSP_GRP_CLR)
MACROFIELD_LINE_BITFIELD(BRIDGE_IRR_LLP_GRP_CLR)
MACROFIELD_LINE_BITFIELD(BRIDGE_IRR_SSRAM_GRP_CLR)
MACROFIELD_LINE_BITFIELD(BRIDGE_IRR_PCI_GRP_CLR)
MACROFIELD_LINE(BRIDGE_INT_MODE, b_int_mode)
MACROFIELD_LINE_BITFIELD(BRIDGE_INTMODE_CLR_PKT_EN(7))
MACROFIELD_LINE_BITFIELD(BRIDGE_INTMODE_CLR_PKT_EN(6))
MACROFIELD_LINE_BITFIELD(BRIDGE_INTMODE_CLR_PKT_EN(5))
MACROFIELD_LINE_BITFIELD(BRIDGE_INTMODE_CLR_PKT_EN(4))
MACROFIELD_LINE_BITFIELD(BRIDGE_INTMODE_CLR_PKT_EN(3))
MACROFIELD_LINE_BITFIELD(BRIDGE_INTMODE_CLR_PKT_EN(2))
MACROFIELD_LINE_BITFIELD(BRIDGE_INTMODE_CLR_PKT_EN(1))
MACROFIELD_LINE_BITFIELD(BRIDGE_INTMODE_CLR_PKT_EN(0))
MACROFIELD_LINE(BRIDGE_INT_DEVICE, b_int_device)
MACROFIELD_LINE_BITFIELD(BRIDGE_INT_DEV_MASK(7))
MACROFIELD_LINE_BITFIELD(BRIDGE_INT_DEV_MASK(6))
MACROFIELD_LINE_BITFIELD(BRIDGE_INT_DEV_MASK(5))
MACROFIELD_LINE_BITFIELD(BRIDGE_INT_DEV_MASK(4))
MACROFIELD_LINE_BITFIELD(BRIDGE_INT_DEV_MASK(3))
MACROFIELD_LINE_BITFIELD(BRIDGE_INT_DEV_MASK(2))
MACROFIELD_LINE_BITFIELD(BRIDGE_INT_DEV_MASK(1))
MACROFIELD_LINE_BITFIELD(BRIDGE_INT_DEV_MASK(0))
MACROFIELD_LINE(BRIDGE_INT_HOST_ERR, b_int_host_err)
MACROFIELD_LINE_BITFIELD(BRIDGE_INT_ADDR_HOST)
MACROFIELD_LINE_BITFIELD(BRIDGE_INT_ADDR_FLD)
MACROFIELD_LINE(BRIDGE_INT_ADDR0, b_int_addr[0].addr)
MACROFIELD_LINE(BRIDGE_INT_ADDR(0), b_int_addr[0].addr)
MACROFIELD_LINE(BRIDGE_INT_ADDR(1), b_int_addr[1].addr)
MACROFIELD_LINE(BRIDGE_INT_ADDR(2), b_int_addr[2].addr)
MACROFIELD_LINE(BRIDGE_INT_ADDR(3), b_int_addr[3].addr)
MACROFIELD_LINE(BRIDGE_INT_ADDR(4), b_int_addr[4].addr)
MACROFIELD_LINE(BRIDGE_INT_ADDR(5), b_int_addr[5].addr)
MACROFIELD_LINE(BRIDGE_INT_ADDR(6), b_int_addr[6].addr)
MACROFIELD_LINE(BRIDGE_INT_ADDR(7), b_int_addr[7].addr)
MACROFIELD_LINE(BRIDGE_DEVICE0, b_device[0].reg)
MACROFIELD_LINE_BITFIELD(BRIDGE_DEV_ERR_LOCK_EN)
MACROFIELD_LINE_BITFIELD(BRIDGE_DEV_PAGE_CHK_DIS)
MACROFIELD_LINE_BITFIELD(BRIDGE_DEV_FORCE_PCI_PAR)
MACROFIELD_LINE_BITFIELD(BRIDGE_DEV_VIRTUAL_EN)
MACROFIELD_LINE_BITFIELD(BRIDGE_DEV_PMU_WRGA_EN)
MACROFIELD_LINE_BITFIELD(BRIDGE_DEV_DIR_WRGA_EN)
MACROFIELD_LINE_BITFIELD(BRIDGE_DEV_DEV_SIZE)
MACROFIELD_LINE_BITFIELD(BRIDGE_DEV_RT)
MACROFIELD_LINE_BITFIELD(BRIDGE_DEV_SWAP_PMU)
MACROFIELD_LINE_BITFIELD(BRIDGE_DEV_SWAP_DIR)
MACROFIELD_LINE_BITFIELD(BRIDGE_DEV_PREF)
MACROFIELD_LINE_BITFIELD(BRIDGE_DEV_PRECISE)
MACROFIELD_LINE_BITFIELD(BRIDGE_DEV_COH)
MACROFIELD_LINE_BITFIELD(BRIDGE_DEV_BARRIER)
MACROFIELD_LINE_BITFIELD(BRIDGE_DEV_GBR)
MACROFIELD_LINE_BITFIELD(BRIDGE_DEV_DEV_SWAP)
MACROFIELD_LINE_BITFIELD(BRIDGE_DEV_DEV_IO_MEM)
MACROFIELD_LINE_BITFIELD(BRIDGE_DEV_OFF_MASK)
MACROFIELD_LINE(BRIDGE_DEVICE(0), b_device[0].reg)
MACROFIELD_LINE(BRIDGE_DEVICE(1), b_device[1].reg)
MACROFIELD_LINE(BRIDGE_DEVICE(2), b_device[2].reg)
MACROFIELD_LINE(BRIDGE_DEVICE(3), b_device[3].reg)
MACROFIELD_LINE(BRIDGE_DEVICE(4), b_device[4].reg)
MACROFIELD_LINE(BRIDGE_DEVICE(5), b_device[5].reg)
MACROFIELD_LINE(BRIDGE_DEVICE(6), b_device[6].reg)
MACROFIELD_LINE(BRIDGE_DEVICE(7), b_device[7].reg)
MACROFIELD_LINE(BRIDGE_WR_REQ_BUF0, b_wr_req_buf[0].reg)
MACROFIELD_LINE(BRIDGE_WR_REQ_BUF(0), b_wr_req_buf[0].reg)
MACROFIELD_LINE(BRIDGE_WR_REQ_BUF(1), b_wr_req_buf[1].reg)
MACROFIELD_LINE(BRIDGE_WR_REQ_BUF(2), b_wr_req_buf[2].reg)
MACROFIELD_LINE(BRIDGE_WR_REQ_BUF(3), b_wr_req_buf[3].reg)
MACROFIELD_LINE(BRIDGE_WR_REQ_BUF(4), b_wr_req_buf[4].reg)
MACROFIELD_LINE(BRIDGE_WR_REQ_BUF(5), b_wr_req_buf[5].reg)
MACROFIELD_LINE(BRIDGE_WR_REQ_BUF(6), b_wr_req_buf[6].reg)
MACROFIELD_LINE(BRIDGE_WR_REQ_BUF(7), b_wr_req_buf[7].reg)
MACROFIELD_LINE(BRIDGE_EVEN_RESP, b_even_resp)
MACROFIELD_LINE(BRIDGE_ODD_RESP, b_odd_resp)
MACROFIELD_LINE(BRIDGE_RESP_STATUS, b_resp_status)
MACROFIELD_LINE(BRIDGE_RESP_CLEAR, b_resp_clear)
MACROFIELD_LINE(BRIDGE_ATE_RAM, b_int_ate_ram)
MACROFIELD_LINE(BRIDGE_TYPE0_CFG_DEV0, b_type0_cfg_dev[0])
MACROFIELD_LINE(BRIDGE_TYPE0_CFG_DEV(0), b_type0_cfg_dev[0])
MACROFIELD_LINE(BRIDGE_TYPE0_CFG_DEVF(0,0), b_type0_cfg_dev[0].f[0])
MACROFIELD_LINE(BRIDGE_TYPE0_CFG_DEVF(0,1), b_type0_cfg_dev[0].f[1])
MACROFIELD_LINE(BRIDGE_TYPE0_CFG_DEVF(0,2), b_type0_cfg_dev[0].f[2])
MACROFIELD_LINE(BRIDGE_TYPE0_CFG_DEVF(0,3), b_type0_cfg_dev[0].f[3])
MACROFIELD_LINE(BRIDGE_TYPE0_CFG_DEVF(0,4), b_type0_cfg_dev[0].f[4])
MACROFIELD_LINE(BRIDGE_TYPE0_CFG_DEVF(0,5), b_type0_cfg_dev[0].f[5])
MACROFIELD_LINE(BRIDGE_TYPE0_CFG_DEVF(0,6), b_type0_cfg_dev[0].f[6])
MACROFIELD_LINE(BRIDGE_TYPE0_CFG_DEVF(0,7), b_type0_cfg_dev[0].f[7])
MACROFIELD_LINE(BRIDGE_TYPE0_CFG_DEV(1), b_type0_cfg_dev[1])
MACROFIELD_LINE(BRIDGE_TYPE0_CFG_DEVF(1,0), b_type0_cfg_dev[1].f[0])
MACROFIELD_LINE(BRIDGE_TYPE0_CFG_DEVF(1,1), b_type0_cfg_dev[1].f[1])
MACROFIELD_LINE(BRIDGE_TYPE0_CFG_DEVF(1,2), b_type0_cfg_dev[1].f[2])
MACROFIELD_LINE(BRIDGE_TYPE0_CFG_DEVF(1,3), b_type0_cfg_dev[1].f[3])
MACROFIELD_LINE(BRIDGE_TYPE0_CFG_DEVF(1,4), b_type0_cfg_dev[1].f[4])
MACROFIELD_LINE(BRIDGE_TYPE0_CFG_DEVF(1,5), b_type0_cfg_dev[1].f[5])
MACROFIELD_LINE(BRIDGE_TYPE0_CFG_DEVF(1,6), b_type0_cfg_dev[1].f[6])
MACROFIELD_LINE(BRIDGE_TYPE0_CFG_DEVF(1,7), b_type0_cfg_dev[1].f[7])
MACROFIELD_LINE(BRIDGE_TYPE0_CFG_DEV(2), b_type0_cfg_dev[2])
MACROFIELD_LINE(BRIDGE_TYPE0_CFG_DEVF(2,0), b_type0_cfg_dev[2].f[0])
MACROFIELD_LINE(BRIDGE_TYPE0_CFG_DEVF(2,1), b_type0_cfg_dev[2].f[1])
MACROFIELD_LINE(BRIDGE_TYPE0_CFG_DEVF(2,2), b_type0_cfg_dev[2].f[2])
MACROFIELD_LINE(BRIDGE_TYPE0_CFG_DEVF(2,3), b_type0_cfg_dev[2].f[3])
MACROFIELD_LINE(BRIDGE_TYPE0_CFG_DEVF(2,4), b_type0_cfg_dev[2].f[4])
MACROFIELD_LINE(BRIDGE_TYPE0_CFG_DEVF(2,5), b_type0_cfg_dev[2].f[5])
MACROFIELD_LINE(BRIDGE_TYPE0_CFG_DEVF(2,6), b_type0_cfg_dev[2].f[6])
MACROFIELD_LINE(BRIDGE_TYPE0_CFG_DEVF(2,7), b_type0_cfg_dev[2].f[7])
MACROFIELD_LINE(BRIDGE_TYPE0_CFG_DEV(3), b_type0_cfg_dev[3])
MACROFIELD_LINE(BRIDGE_TYPE0_CFG_DEVF(3,0), b_type0_cfg_dev[3].f[0])
MACROFIELD_LINE(BRIDGE_TYPE0_CFG_DEVF(3,1), b_type0_cfg_dev[3].f[1])
MACROFIELD_LINE(BRIDGE_TYPE0_CFG_DEVF(3,2), b_type0_cfg_dev[3].f[2])
MACROFIELD_LINE(BRIDGE_TYPE0_CFG_DEVF(3,3), b_type0_cfg_dev[3].f[3])
MACROFIELD_LINE(BRIDGE_TYPE0_CFG_DEVF(3,4), b_type0_cfg_dev[3].f[4])
MACROFIELD_LINE(BRIDGE_TYPE0_CFG_DEVF(3,5), b_type0_cfg_dev[3].f[5])
MACROFIELD_LINE(BRIDGE_TYPE0_CFG_DEVF(3,6), b_type0_cfg_dev[3].f[6])
MACROFIELD_LINE(BRIDGE_TYPE0_CFG_DEVF(3,7), b_type0_cfg_dev[3].f[7])
MACROFIELD_LINE(BRIDGE_TYPE0_CFG_DEV(4), b_type0_cfg_dev[4])
MACROFIELD_LINE(BRIDGE_TYPE0_CFG_DEVF(4,0), b_type0_cfg_dev[4].f[0])
MACROFIELD_LINE(BRIDGE_TYPE0_CFG_DEVF(4,1), b_type0_cfg_dev[4].f[1])
MACROFIELD_LINE(BRIDGE_TYPE0_CFG_DEVF(4,2), b_type0_cfg_dev[4].f[2])
MACROFIELD_LINE(BRIDGE_TYPE0_CFG_DEVF(4,3), b_type0_cfg_dev[4].f[3])
MACROFIELD_LINE(BRIDGE_TYPE0_CFG_DEVF(4,4), b_type0_cfg_dev[4].f[4])
MACROFIELD_LINE(BRIDGE_TYPE0_CFG_DEVF(4,5), b_type0_cfg_dev[4].f[5])
MACROFIELD_LINE(BRIDGE_TYPE0_CFG_DEVF(4,6), b_type0_cfg_dev[4].f[6])
MACROFIELD_LINE(BRIDGE_TYPE0_CFG_DEVF(4,7), b_type0_cfg_dev[4].f[7])
MACROFIELD_LINE(BRIDGE_TYPE0_CFG_DEV(5), b_type0_cfg_dev[5])
MACROFIELD_LINE(BRIDGE_TYPE0_CFG_DEVF(5,0), b_type0_cfg_dev[5].f[0])
MACROFIELD_LINE(BRIDGE_TYPE0_CFG_DEVF(5,1), b_type0_cfg_dev[5].f[1])
MACROFIELD_LINE(BRIDGE_TYPE0_CFG_DEVF(5,2), b_type0_cfg_dev[5].f[2])
MACROFIELD_LINE(BRIDGE_TYPE0_CFG_DEVF(5,3), b_type0_cfg_dev[5].f[3])
MACROFIELD_LINE(BRIDGE_TYPE0_CFG_DEVF(5,4), b_type0_cfg_dev[5].f[4])
MACROFIELD_LINE(BRIDGE_TYPE0_CFG_DEVF(5,5), b_type0_cfg_dev[5].f[5])
MACROFIELD_LINE(BRIDGE_TYPE0_CFG_DEVF(5,6), b_type0_cfg_dev[5].f[6])
MACROFIELD_LINE(BRIDGE_TYPE0_CFG_DEVF(5,7), b_type0_cfg_dev[5].f[7])
MACROFIELD_LINE(BRIDGE_TYPE0_CFG_DEV(6), b_type0_cfg_dev[6])
MACROFIELD_LINE(BRIDGE_TYPE0_CFG_DEVF(6,0), b_type0_cfg_dev[6].f[0])
MACROFIELD_LINE(BRIDGE_TYPE0_CFG_DEVF(6,1), b_type0_cfg_dev[6].f[1])
MACROFIELD_LINE(BRIDGE_TYPE0_CFG_DEVF(6,2), b_type0_cfg_dev[6].f[2])
MACROFIELD_LINE(BRIDGE_TYPE0_CFG_DEVF(6,3), b_type0_cfg_dev[6].f[3])
MACROFIELD_LINE(BRIDGE_TYPE0_CFG_DEVF(6,4), b_type0_cfg_dev[6].f[4])
MACROFIELD_LINE(BRIDGE_TYPE0_CFG_DEVF(6,5), b_type0_cfg_dev[6].f[5])
MACROFIELD_LINE(BRIDGE_TYPE0_CFG_DEVF(6,6), b_type0_cfg_dev[6].f[6])
MACROFIELD_LINE(BRIDGE_TYPE0_CFG_DEVF(6,7), b_type0_cfg_dev[6].f[7])
MACROFIELD_LINE(BRIDGE_TYPE0_CFG_DEV(7), b_type0_cfg_dev[7])
MACROFIELD_LINE(BRIDGE_TYPE0_CFG_DEVF(7,0), b_type0_cfg_dev[7].f[0])
MACROFIELD_LINE(BRIDGE_TYPE0_CFG_DEVF(7,1), b_type0_cfg_dev[7].f[1])
MACROFIELD_LINE(BRIDGE_TYPE0_CFG_DEVF(7,2), b_type0_cfg_dev[7].f[2])
MACROFIELD_LINE(BRIDGE_TYPE0_CFG_DEVF(7,3), b_type0_cfg_dev[7].f[3])
MACROFIELD_LINE(BRIDGE_TYPE0_CFG_DEVF(7,4), b_type0_cfg_dev[7].f[4])
MACROFIELD_LINE(BRIDGE_TYPE0_CFG_DEVF(7,5), b_type0_cfg_dev[7].f[5])
MACROFIELD_LINE(BRIDGE_TYPE0_CFG_DEVF(7,6), b_type0_cfg_dev[7].f[6])
MACROFIELD_LINE(BRIDGE_TYPE0_CFG_DEVF(7,7), b_type0_cfg_dev[7].f[7])
MACROFIELD_LINE(BRIDGE_TYPE1_CFG, b_type1_cfg)
MACROFIELD_LINE(BRIDGE_PCI_IACK, b_pci_iack)
MACROFIELD_LINE(BRIDGE_EXT_SSRAM, b_ext_ate_ram)
MACROFIELD_LINE(BRIDGE_DEVIO0, b_devio(0))
MACROFIELD_LINE(BRIDGE_DEVIO(0), b_devio(0))
MACROFIELD_LINE(BRIDGE_DEVIO(1), b_devio(1))
MACROFIELD_LINE(BRIDGE_DEVIO(2), b_devio(2))
MACROFIELD_LINE(BRIDGE_DEVIO(3), b_devio(3))
MACROFIELD_LINE(BRIDGE_DEVIO(4), b_devio(4))
MACROFIELD_LINE(BRIDGE_DEVIO(5), b_devio(5))
MACROFIELD_LINE(BRIDGE_DEVIO(6), b_devio(6))
MACROFIELD_LINE(BRIDGE_DEVIO(7), b_devio(7))
MACROFIELD_LINE(BRIDGE_EXTERNAL_FLASH, b_external_flash)
};
#endif
#ifdef __cplusplus
};
#endif
#endif /* C or C++ */
#endif /* _ASM_SN_PCI_BRIDGE_H */
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