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openwrt-xburst/target/linux/brcm-2.4/files/arch/mips/bcm947xx/sbpci.c
2008-01-06 19:28:07 +00:00

782 lines
19 KiB
C

/*
* Low-Level PCI and SB support for BCM47xx
*
* Copyright 2006, Broadcom Corporation
* All Rights Reserved.
*
* THIS SOFTWARE IS OFFERED "AS IS", AND BROADCOM GRANTS NO WARRANTIES OF ANY
* KIND, EXPRESS OR IMPLIED, BY STATUTE, COMMUNICATION OR OTHERWISE. BROADCOM
* SPECIFICALLY DISCLAIMS ANY IMPLIED WARRANTIES OF MERCHANTABILITY, FITNESS
* FOR A SPECIFIC PURPOSE OR NONINFRINGEMENT CONCERNING THIS SOFTWARE.
*
* $Id: hndpci.c,v 1.1.1.3 2006/04/08 06:13:39 honor Exp $
*/
#include <typedefs.h>
#include <osl.h>
#include <pcicfg.h>
#include <bcmdevs.h>
#include <sbconfig.h>
#include <sbutils.h>
#include <sbpci.h>
#include <bcmendian.h>
#include <bcmnvram.h>
#include <hndcpu.h>
#include <hndmips.h>
#include <hndpci.h>
/* debug/trace */
#ifdef BCMDBG_PCI
#define PCI_MSG(args) printf args
#else
#define PCI_MSG(args)
#endif /* BCMDBG_PCI */
/* Can free sbpci_init() memory after boot */
#ifndef linux
#define __init
#endif /* linux */
/* Emulated configuration space */
typedef struct {
int n;
uint size0;
uint size1;
uint size2;
uint size3;
} sb_bar_cfg_t;
static pci_config_regs sb_config_regs[SB_MAXCORES];
static sb_bar_cfg_t sb_bar_cfg[SB_MAXCORES];
/* Links to emulated and real PCI configuration spaces */
#define MAXFUNCS 2
typedef struct {
pci_config_regs *emu; /* emulated PCI config */
pci_config_regs *pci; /* real PCI config */
sb_bar_cfg_t *bar; /* region sizes */
} sb_pci_cfg_t;
static sb_pci_cfg_t sb_pci_cfg[SB_MAXCORES][MAXFUNCS];
/* Special emulated config space for non-existing device */
static pci_config_regs sb_pci_null = { 0xffff, 0xffff };
/* Banned cores */
static uint16 pci_ban[SB_MAXCORES] = { 0 };
static uint pci_banned = 0;
/* CardBus mode */
static bool cardbus = FALSE;
/* Disable PCI host core */
static bool pci_disabled = FALSE;
/* Host bridge slot #, default to 0 */
static uint8 pci_hbslot = 0;
/* Internal macros */
#define PCI_SLOTAD_MAP 16 /* SLOT<n> mapps to AD<n+16> */
#define PCI_HBSBCFG_REV 8 /* MIN. core rev. required to
* access host bridge PCI cfg space
* from SB
*/
/*
* Functions for accessing external PCI configuration space
*/
/* Assume one-hot slot wiring */
#define PCI_SLOT_MAX 16 /* Max. PCI Slots */
static uint32 config_cmd(sb_t * sbh, uint bus, uint dev, uint func, uint off)
{
uint coreidx;
sbpciregs_t *regs;
uint32 addr = 0;
osl_t *osh;
/* CardBusMode supports only one device */
if (cardbus && dev > 1)
return 0;
osh = sb_osh(sbh);
coreidx = sb_coreidx(sbh);
regs = (sbpciregs_t *) sb_setcore(sbh, SB_PCI, 0);
/* Type 0 transaction */
if (bus == 1) {
/* Skip unwired slots */
if (dev < PCI_SLOT_MAX) {
uint32 win;
/* Slide the PCI window to the appropriate slot */
win =
(SBTOPCI_CFG0 |
((1 << (dev + PCI_SLOTAD_MAP)) & SBTOPCI1_MASK));
W_REG(osh, &regs->sbtopci1, win);
addr = SB_PCI_CFG |
((1 << (dev + PCI_SLOTAD_MAP)) & ~SBTOPCI1_MASK) |
(func << PCICFG_FUN_SHIFT) | (off & ~3);
}
} else {
/* Type 1 transaction */
W_REG(osh, &regs->sbtopci1, SBTOPCI_CFG1);
addr = SB_PCI_CFG |
(bus << PCICFG_BUS_SHIFT) |
(dev << PCICFG_SLOT_SHIFT) |
(func << PCICFG_FUN_SHIFT) | (off & ~3);
}
sb_setcoreidx(sbh, coreidx);
return addr;
}
/*
* Read host bridge PCI config registers from Silicon Backplane (>=rev8).
*
* It returns TRUE to indicate that access to the host bridge's pci config
* from SB is ok, and values in 'addr' and 'val' are valid.
*
* It can only read registers at multiple of 4-bytes. Callers must pick up
* needed bytes from 'val' based on 'off' value. Value in 'addr' reflects
* the register address where value in 'val' is read.
*/
static bool
sb_pcihb_read_config(sb_t * sbh, uint bus, uint dev, uint func, uint off,
uint32 ** addr, uint32 * val)
{
sbpciregs_t *regs;
osl_t *osh;
uint coreidx;
bool ret = FALSE;
/* sanity check */
ASSERT(bus == 1);
ASSERT(dev == pci_hbslot);
ASSERT(func == 0);
osh = sb_osh(sbh);
/* read pci config when core rev >= 8 */
coreidx = sb_coreidx(sbh);
regs = (sbpciregs_t *) sb_setcore(sbh, SB_PCI, 0);
if (regs && sb_corerev(sbh) >= PCI_HBSBCFG_REV) {
*addr = (uint32 *) & regs->pcicfg[func][off >> 2];
*val = R_REG(osh, *addr);
ret = TRUE;
}
sb_setcoreidx(sbh, coreidx);
return ret;
}
int
extpci_read_config(sb_t * sbh, uint bus, uint dev, uint func, uint off,
void *buf, int len)
{
uint32 addr = 0, *reg = NULL, val;
int ret = 0;
/*
* Set value to -1 when:
* flag 'pci_disabled' is true;
* value of 'addr' is zero;
* REG_MAP() fails;
* BUSPROBE() fails;
*/
if (pci_disabled)
val = 0xffffffff;
else if (bus == 1 && dev == pci_hbslot && func == 0 &&
sb_pcihb_read_config(sbh, bus, dev, func, off, &reg, &val)) ;
else if (((addr = config_cmd(sbh, bus, dev, func, off)) == 0) ||
((reg = (uint32 *) REG_MAP(addr, len)) == 0) ||
(BUSPROBE(val, reg) != 0))
val = 0xffffffff;
PCI_MSG(("%s: 0x%x <= 0x%p(0x%x), len %d, off 0x%x, buf 0x%p\n",
__FUNCTION__, val, reg, addr, len, off, buf));
val >>= 8 * (off & 3);
if (len == 4)
*((uint32 *) buf) = val;
else if (len == 2)
*((uint16 *) buf) = (uint16) val;
else if (len == 1)
*((uint8 *) buf) = (uint8) val;
else
ret = -1;
if (reg && addr)
REG_UNMAP(reg);
return ret;
}
int
extpci_write_config(sb_t * sbh, uint bus, uint dev, uint func, uint off,
void *buf, int len)
{
osl_t *osh;
uint32 addr = 0, *reg = NULL, val;
int ret = 0;
osh = sb_osh(sbh);
/*
* Ignore write attempt when:
* flag 'pci_disabled' is true;
* value of 'addr' is zero;
* REG_MAP() fails;
* BUSPROBE() fails;
*/
if (pci_disabled)
return 0;
else if (bus == 1 && dev == pci_hbslot && func == 0 &&
sb_pcihb_read_config(sbh, bus, dev, func, off, &reg, &val)) ;
else if (((addr = config_cmd(sbh, bus, dev, func, off)) == 0) ||
((reg = (uint32 *) REG_MAP(addr, len)) == 0) ||
(BUSPROBE(val, reg) != 0))
goto done;
if (len == 4)
val = *((uint32 *) buf);
else if (len == 2) {
val &= ~(0xffff << (8 * (off & 3)));
val |= *((uint16 *) buf) << (8 * (off & 3));
} else if (len == 1) {
val &= ~(0xff << (8 * (off & 3)));
val |= *((uint8 *) buf) << (8 * (off & 3));
} else {
ret = -1;
goto done;
}
PCI_MSG(("%s: 0x%x => 0x%p\n", __FUNCTION__, val, reg));
W_REG(osh, reg, val);
done:
if (reg && addr)
REG_UNMAP(reg);
return ret;
}
/*
* Must access emulated PCI configuration at these locations even when
* the real PCI config space exists and is accessible.
*
* PCI_CFG_VID (0x00)
* PCI_CFG_DID (0x02)
* PCI_CFG_PROGIF (0x09)
* PCI_CFG_SUBCL (0x0a)
* PCI_CFG_BASECL (0x0b)
* PCI_CFG_HDR (0x0e)
* PCI_CFG_INT (0x3c)
* PCI_CFG_PIN (0x3d)
*/
#define FORCE_EMUCFG(off, len) \
((off == PCI_CFG_VID) || (off == PCI_CFG_DID) || \
(off == PCI_CFG_PROGIF) || \
(off == PCI_CFG_SUBCL) || (off == PCI_CFG_BASECL) || \
(off == PCI_CFG_HDR) || \
(off == PCI_CFG_INT) || (off == PCI_CFG_PIN))
/* Sync the emulation registers and the real PCI config registers. */
static void
sb_pcid_read_config(sb_t * sbh, uint coreidx, sb_pci_cfg_t * cfg,
uint off, uint len)
{
osl_t *osh;
uint oldidx;
ASSERT(cfg);
ASSERT(cfg->emu);
ASSERT(cfg->pci);
/* decide if real PCI config register access is necessary */
if (FORCE_EMUCFG(off, len))
return;
osh = sb_osh(sbh);
/* access to the real pci config space only when the core is up */
oldidx = sb_coreidx(sbh);
sb_setcoreidx(sbh, coreidx);
if (sb_iscoreup(sbh)) {
if (len == 4)
*(uint32 *) ((ulong) cfg->emu + off) =
htol32(R_REG
(osh, (uint32 *) ((ulong) cfg->pci + off)));
else if (len == 2)
*(uint16 *) ((ulong) cfg->emu + off) =
htol16(R_REG
(osh, (uint16 *) ((ulong) cfg->pci + off)));
else if (len == 1)
*(uint8 *) ((ulong) cfg->emu + off) =
R_REG(osh, (uint8 *) ((ulong) cfg->pci + off));
}
sb_setcoreidx(sbh, oldidx);
}
static void
sb_pcid_write_config(sb_t * sbh, uint coreidx, sb_pci_cfg_t * cfg,
uint off, uint len)
{
osl_t *osh;
uint oldidx;
ASSERT(cfg);
ASSERT(cfg->emu);
ASSERT(cfg->pci);
osh = sb_osh(sbh);
/* decide if real PCI config register access is necessary */
if (FORCE_EMUCFG(off, len))
return;
/* access to the real pci config space only when the core is up */
oldidx = sb_coreidx(sbh);
sb_setcoreidx(sbh, coreidx);
if (sb_iscoreup(sbh)) {
if (len == 4)
W_REG(osh, (uint32 *) ((ulong) cfg->pci + off),
ltoh32(*(uint32 *) ((ulong) cfg->emu + off)));
else if (len == 2)
W_REG(osh, (uint16 *) ((ulong) cfg->pci + off),
ltoh16(*(uint16 *) ((ulong) cfg->emu + off)));
else if (len == 1)
W_REG(osh, (uint8 *) ((ulong) cfg->pci + off),
*(uint8 *) ((ulong) cfg->emu + off));
}
sb_setcoreidx(sbh, oldidx);
}
/*
* Functions for accessing translated SB configuration space
*/
static int
sb_read_config(sb_t * sbh, uint bus, uint dev, uint func, uint off, void *buf,
int len)
{
pci_config_regs *cfg;
if (dev >= SB_MAXCORES || func >= MAXFUNCS
|| (off + len) > sizeof(pci_config_regs))
return -1;
cfg = sb_pci_cfg[dev][func].emu;
ASSERT(ISALIGNED(off, len));
ASSERT(ISALIGNED((uintptr) buf, len));
/* use special config space if the device does not exist */
if (!cfg)
cfg = &sb_pci_null;
/* sync emulation with real PCI config if necessary */
else if (sb_pci_cfg[dev][func].pci)
sb_pcid_read_config(sbh, dev, &sb_pci_cfg[dev][func], off, len);
if (len == 4)
*((uint32 *) buf) = ltoh32(*((uint32 *) ((ulong) cfg + off)));
else if (len == 2)
*((uint16 *) buf) = ltoh16(*((uint16 *) ((ulong) cfg + off)));
else if (len == 1)
*((uint8 *) buf) = *((uint8 *) ((ulong) cfg + off));
else
return -1;
return 0;
}
static int
sb_write_config(sb_t * sbh, uint bus, uint dev, uint func, uint off, void *buf,
int len)
{
uint coreidx;
void *regs;
pci_config_regs *cfg;
osl_t *osh;
sb_bar_cfg_t *bar;
if (dev >= SB_MAXCORES || func >= MAXFUNCS
|| (off + len) > sizeof(pci_config_regs))
return -1;
cfg = sb_pci_cfg[dev][func].emu;
if (!cfg)
return -1;
ASSERT(ISALIGNED(off, len));
ASSERT(ISALIGNED((uintptr) buf, len));
osh = sb_osh(sbh);
/* Emulate BAR sizing */
if (off >= OFFSETOF(pci_config_regs, base[0]) &&
off <= OFFSETOF(pci_config_regs, base[3]) &&
len == 4 && *((uint32 *) buf) == ~0) {
coreidx = sb_coreidx(sbh);
if ((regs = sb_setcoreidx(sbh, dev))) {
bar = sb_pci_cfg[dev][func].bar;
/* Highest numbered address match register */
if (off == OFFSETOF(pci_config_regs, base[0]))
cfg->base[0] = ~(bar->size0 - 1);
else if (off == OFFSETOF(pci_config_regs, base[1])
&& bar->n >= 1)
cfg->base[1] = ~(bar->size1 - 1);
else if (off == OFFSETOF(pci_config_regs, base[2])
&& bar->n >= 2)
cfg->base[2] = ~(bar->size2 - 1);
else if (off == OFFSETOF(pci_config_regs, base[3])
&& bar->n >= 3)
cfg->base[3] = ~(bar->size3 - 1);
}
sb_setcoreidx(sbh, coreidx);
} else if (len == 4)
*((uint32 *) ((ulong) cfg + off)) = htol32(*((uint32 *) buf));
else if (len == 2)
*((uint16 *) ((ulong) cfg + off)) = htol16(*((uint16 *) buf));
else if (len == 1)
*((uint8 *) ((ulong) cfg + off)) = *((uint8 *) buf);
else
return -1;
/* sync emulation with real PCI config if necessary */
if (sb_pci_cfg[dev][func].pci)
sb_pcid_write_config(sbh, dev, &sb_pci_cfg[dev][func], off,
len);
return 0;
}
int
sbpci_read_config(sb_t * sbh, uint bus, uint dev, uint func, uint off,
void *buf, int len)
{
if (bus == 0)
return sb_read_config(sbh, bus, dev, func, off, buf, len);
else
return extpci_read_config(sbh, bus, dev, func, off, buf, len);
}
int
sbpci_write_config(sb_t * sbh, uint bus, uint dev, uint func, uint off,
void *buf, int len)
{
if (bus == 0)
return sb_write_config(sbh, bus, dev, func, off, buf, len);
else
return extpci_write_config(sbh, bus, dev, func, off, buf, len);
}
void sbpci_ban(uint16 core)
{
if (pci_banned < ARRAYSIZE(pci_ban))
pci_ban[pci_banned++] = core;
}
/*
* Initiliaze PCI core. Return 0 after a successful initialization.
* Otherwise return -1 to indicate there is no PCI core and return 1
* to indicate PCI core is disabled.
*/
int __init sbpci_init_pci(sb_t * sbh)
{
uint chip, chiprev, chippkg, host;
uint32 boardflags;
sbpciregs_t *pci;
sbconfig_t *sb;
uint32 val;
int ret = 0;
char *hbslot;
osl_t *osh;
chip = sb_chip(sbh);
chiprev = sb_chiprev(sbh);
chippkg = sb_chippkg(sbh);
osh = sb_osh(sbh);
if (!(pci = (sbpciregs_t *) sb_setcore(sbh, SB_PCI, 0))) {
printk("PCI: no core\n");
pci_disabled = TRUE;
return -1;
}
if ((chip == 0x4310) && (chiprev == 0))
pci_disabled = TRUE;
sb = (sbconfig_t *) ((ulong) pci + SBCONFIGOFF);
boardflags = (uint32) getintvar(NULL, "boardflags");
/*
* The 200-pin BCM4712 package does not bond out PCI. Even when
* PCI is bonded out, some boards may leave the pins
* floating.
*/
if (((chip == BCM4712_CHIP_ID) &&
((chippkg == BCM4712SMALL_PKG_ID) ||
(chippkg == BCM4712MID_PKG_ID))) || (boardflags & BFL_NOPCI))
pci_disabled = TRUE;
/* Enable the core */
sb_core_reset(sbh, 0, 0);
/*
* If the PCI core should not be touched (disabled, not bonded
* out, or pins floating), do not even attempt to access core
* registers. Otherwise, try to determine if it is in host
* mode.
*/
if (pci_disabled)
host = 0;
else
host = !BUSPROBE(val, &pci->control);
if (!host) {
ret = 1;
/* Disable PCI interrupts in client mode */
W_REG(osh, &sb->sbintvec, 0);
/* Disable the PCI bridge in client mode */
sbpci_ban(SB_PCI);
sb_core_disable(sbh, 0);
printk("PCI: Disabled\n");
} else {
printk("PCI: Initializing host\n");
/* Disable PCI SBReqeustTimeout for BCM4785 */
if (chip == BCM4785_CHIP_ID) {
AND_REG(osh, &sb->sbimconfiglow, ~0x00000070);
sb_commit(sbh);
}
/* Reset the external PCI bus and enable the clock */
W_REG(osh, &pci->control, 0x5); /* enable the tristate drivers */
W_REG(osh, &pci->control, 0xd); /* enable the PCI clock */
OSL_DELAY(150); /* delay > 100 us */
W_REG(osh, &pci->control, 0xf); /* deassert PCI reset */
/* Use internal arbiter and park REQ/GRNT at external master 0 */
W_REG(osh, &pci->arbcontrol, PCI_INT_ARB);
OSL_DELAY(1); /* delay 1 us */
if (sb_corerev(sbh) >= 8) {
val = getintvar(NULL, "parkid");
ASSERT(val <= PCI_PARKID_LAST);
OR_REG(osh, &pci->arbcontrol, val << PCI_PARKID_SHIFT);
OSL_DELAY(1);
}
/* Enable CardBusMode */
cardbus = getintvar(NULL, "cardbus") == 1;
if (cardbus) {
printk("PCI: Enabling CardBus\n");
/* GPIO 1 resets the CardBus device on bcm94710ap */
sb_gpioout(sbh, 1, 1, GPIO_DRV_PRIORITY);
sb_gpioouten(sbh, 1, 1, GPIO_DRV_PRIORITY);
W_REG(osh, &pci->sprom[0],
R_REG(osh, &pci->sprom[0]) | 0x400);
}
/* 64 MB I/O access window */
W_REG(osh, &pci->sbtopci0, SBTOPCI_IO);
/* 64 MB configuration access window */
W_REG(osh, &pci->sbtopci1, SBTOPCI_CFG0);
/* 1 GB memory access window */
W_REG(osh, &pci->sbtopci2, SBTOPCI_MEM | SB_PCI_DMA);
/* Host bridge slot # nvram overwrite */
if ((hbslot = nvram_get("pcihbslot"))) {
pci_hbslot = simple_strtoul(hbslot, NULL, 0);
ASSERT(pci_hbslot < PCI_MAX_DEVICES);
}
/* Enable PCI bridge BAR0 prefetch and burst */
val = 6;
sbpci_write_config(sbh, 1, pci_hbslot, 0, PCI_CFG_CMD, &val,
sizeof(val));
/* Enable PCI interrupts */
W_REG(osh, &pci->intmask, PCI_INTA);
}
return ret;
}
/*
* Get the PCI region address and size information.
*/
static void __init
sbpci_init_regions(sb_t * sbh, uint func, pci_config_regs * cfg,
sb_bar_cfg_t * bar)
{
osl_t *osh;
uint16 coreid;
void *regs;
sbconfig_t *sb;
uint32 base;
osh = sb_osh(sbh);
coreid = sb_coreid(sbh);
regs = sb_coreregs(sbh);
sb = (sbconfig_t *) ((ulong) regs + SBCONFIGOFF);
switch (coreid) {
case SB_USB20H:
base = htol32(sb_base(R_REG(osh, &sb->sbadmatch0)));
cfg->base[0] = func == 0 ? base : base + 0x800; /* OHCI/EHCI */
cfg->base[1] = 0;
cfg->base[2] = 0;
cfg->base[3] = 0;
cfg->base[4] = 0;
cfg->base[5] = 0;
bar->n = 1;
bar->size0 = func == 0 ? 0x200 : 0x100; /* OHCI/EHCI */
bar->size1 = 0;
bar->size2 = 0;
bar->size3 = 0;
break;
default:
cfg->base[0] = htol32(sb_base(R_REG(osh, &sb->sbadmatch0)));
cfg->base[1] = htol32(sb_base(R_REG(osh, &sb->sbadmatch1)));
cfg->base[2] = htol32(sb_base(R_REG(osh, &sb->sbadmatch2)));
cfg->base[3] = htol32(sb_base(R_REG(osh, &sb->sbadmatch3)));
cfg->base[4] = 0;
cfg->base[5] = 0;
bar->n =
(R_REG(osh, &sb->sbidlow) & SBIDL_AR_MASK) >>
SBIDL_AR_SHIFT;
bar->size0 = sb_size(R_REG(osh, &sb->sbadmatch0));
bar->size1 = sb_size(R_REG(osh, &sb->sbadmatch1));
bar->size2 = sb_size(R_REG(osh, &sb->sbadmatch2));
bar->size3 = sb_size(R_REG(osh, &sb->sbadmatch3));
break;
}
}
/*
* Construct PCI config spaces for SB cores so that they
* can be accessed as if they were PCI devices.
*/
static void __init sbpci_init_cores(sb_t * sbh)
{
uint chiprev, coreidx, i;
sbconfig_t *sb;
pci_config_regs *cfg, *pci;
sb_bar_cfg_t *bar;
void *regs;
osl_t *osh;
uint16 vendor, device;
uint16 coreid;
uint8 class, subclass, progif;
uint dev;
uint8 header;
uint func;
chiprev = sb_chiprev(sbh);
coreidx = sb_coreidx(sbh);
osh = sb_osh(sbh);
/* Scan the SB bus */
bzero(sb_config_regs, sizeof(sb_config_regs));
bzero(sb_bar_cfg, sizeof(sb_bar_cfg));
bzero(sb_pci_cfg, sizeof(sb_pci_cfg));
memset(&sb_pci_null, -1, sizeof(sb_pci_null));
cfg = sb_config_regs;
bar = sb_bar_cfg;
for (dev = 0; dev < SB_MAXCORES; dev++) {
/* Check if the core exists */
if (!(regs = sb_setcoreidx(sbh, dev)))
continue;
sb = (sbconfig_t *) ((ulong) regs + SBCONFIGOFF);
/* Check if this core is banned */
coreid = sb_coreid(sbh);
for (i = 0; i < pci_banned; i++)
if (coreid == pci_ban[i])
break;
if (i < pci_banned)
continue;
for (func = 0; func < MAXFUNCS; ++func) {
/* Make sure we won't go beyond the limit */
if (cfg >= &sb_config_regs[SB_MAXCORES]) {
printk("PCI: too many emulated devices\n");
goto done;
}
/* Convert core id to pci id */
if (sb_corepciid
(sbh, func, &vendor, &device, &class, &subclass,
&progif, &header))
continue;
/*
* Differentiate real PCI config from emulated.
* non zero 'pci' indicate there is a real PCI config space
* for this device.
*/
switch (device) {
case BCM47XX_GIGETH_ID:
pci =
(pci_config_regs *) ((uint32) regs + 0x800);
break;
case BCM47XX_SATAXOR_ID:
pci =
(pci_config_regs *) ((uint32) regs + 0x400);
break;
case BCM47XX_ATA100_ID:
pci =
(pci_config_regs *) ((uint32) regs + 0x800);
break;
default:
pci = NULL;
break;
}
/* Supported translations */
cfg->vendor = htol16(vendor);
cfg->device = htol16(device);
cfg->rev_id = chiprev;
cfg->prog_if = progif;
cfg->sub_class = subclass;
cfg->base_class = class;
cfg->header_type = header;
sbpci_init_regions(sbh, func, cfg, bar);
/* Save core interrupt flag */
cfg->int_pin =
R_REG(osh, &sb->sbtpsflag) & SBTPS_NUM0_MASK;
/* Save core interrupt assignment */
cfg->int_line = sb_irq(sbh);
/* Indicate there is no SROM */
*((uint32 *) & cfg->sprom_control) = 0xffffffff;
/* Point to the PCI config spaces */
sb_pci_cfg[dev][func].emu = cfg;
sb_pci_cfg[dev][func].pci = pci;
sb_pci_cfg[dev][func].bar = bar;
cfg++;
bar++;
}
}
done:
sb_setcoreidx(sbh, coreidx);
}
/*
* Initialize PCI core and construct PCI config spaces for SB cores.
* Must propagate sbpci_init_pci() return value to the caller to let
* them know the PCI core initialization status.
*/
int __init sbpci_init(sb_t * sbh)
{
int status = sbpci_init_pci(sbh);
sbpci_init_cores(sbh);
return status;
}