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xserver/hw/xfree86/os-support/bus/linuxPci.c

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/*
* Copyright 1998 by Concurrent Computer Corporation
*
* Permission to use, copy, modify, distribute, and sell this software
* and its documentation for any purpose is hereby granted without fee,
* provided that the above copyright notice appear in all copies and that
* both that copyright notice and this permission notice appear in
* supporting documentation, and that the name of Concurrent Computer
* Corporation not be used in advertising or publicity pertaining to
* distribution of the software without specific, written prior
* permission. Concurrent Computer Corporation makes no representations
* about the suitability of this software for any purpose. It is
* provided "as is" without express or implied warranty.
*
* CONCURRENT COMPUTER CORPORATION DISCLAIMS ALL WARRANTIES WITH REGARD
* TO THIS SOFTWARE, INCLUDING ALL IMPLIED WARRANTIES OF MERCHANTABILITY
* AND FITNESS, IN NO EVENT SHALL CONCURRENT COMPUTER CORPORATION BE
* LIABLE FOR ANY SPECIAL, INDIRECT OR CONSEQUENTIAL DAMAGES OR ANY
* DAMAGES WHATSOEVER RESULTING FROM LOSS OF USE, DATA OR PROFITS,
* WHETHER IN AN ACTION OF CONTRACT, NEGLIGENCE OR OTHER TORTIOUS ACTION,
* ARISING OUT OF OR IN CONNECTION WITH THE USE OR PERFORMANCE OF THIS
* SOFTWARE.
*
* Copyright 1998 by Metro Link Incorporated
*
* Permission to use, copy, modify, distribute, and sell this software
* and its documentation for any purpose is hereby granted without fee,
* provided that the above copyright notice appear in all copies and that
* both that copyright notice and this permission notice appear in
* supporting documentation, and that the name of Metro Link
* Incorporated not be used in advertising or publicity pertaining to
* distribution of the software without specific, written prior
* permission. Metro Link Incorporated makes no representations
* about the suitability of this software for any purpose. It is
* provided "as is" without express or implied warranty.
*
* METRO LINK INCORPORATED DISCLAIMS ALL WARRANTIES WITH REGARD
* TO THIS SOFTWARE, INCLUDING ALL IMPLIED WARRANTIES OF MERCHANTABILITY
* AND FITNESS, IN NO EVENT SHALL METRO LINK INCORPORATED BE
* LIABLE FOR ANY SPECIAL, INDIRECT OR CONSEQUENTIAL DAMAGES OR ANY
* DAMAGES WHATSOEVER RESULTING FROM LOSS OF USE, DATA OR PROFITS,
* WHETHER IN AN ACTION OF CONTRACT, NEGLIGENCE OR OTHER TORTIOUS ACTION,
* ARISING OUT OF OR IN CONNECTION WITH THE USE OR PERFORMANCE OF THIS
* SOFTWARE.
*/
#ifdef HAVE_XORG_CONFIG_H
#include <xorg-config.h>
#endif
#include <stdio.h>
#include "compiler.h"
#include "xf86.h"
#include "xf86Priv.h"
#include "xf86_OSlib.h"
#include "Pci.h"
/*
* linux platform specific PCI access functions -- using /proc/bus/pci
* needs kernel version 2.2.x
*/
static CARD32 linuxPciCfgRead(PCITAG tag, int off);
static void linuxPciCfgWrite(PCITAG, int off, CARD32 val);
static void linuxPciCfgSetBits(PCITAG tag, int off, CARD32 mask, CARD32 bits);
static ADDRESS linuxTransAddrBusToHost(PCITAG tag, PciAddrType type, ADDRESS addr);
#if defined(__powerpc__)
static ADDRESS linuxPpcBusAddrToHostAddr(PCITAG, PciAddrType, ADDRESS);
static ADDRESS linuxPpcHostAddrToBusAddr(PCITAG, PciAddrType, ADDRESS);
#endif
static CARD8 linuxPciCfgReadByte(PCITAG tag, int off);
static void linuxPciCfgWriteByte(PCITAG tag, int off, CARD8 val);
static CARD16 linuxPciCfgReadWord(PCITAG tag, int off);
static void linuxPciCfgWriteWord(PCITAG tag, int off, CARD16 val);
static int linuxPciHandleBIOS(PCITAG Tag, int basereg, unsigned char *buf, int len);
static pciBusFuncs_t linuxFuncs0 = {
/* pciReadLong */ linuxPciCfgRead,
/* pciWriteLong */ linuxPciCfgWrite,
/* pciSetBitsLong */ linuxPciCfgSetBits,
#if defined(__powerpc__)
/* pciAddrHostToBus */ linuxPpcHostAddrToBusAddr,
/* pciAddrBusToHost */ linuxPpcBusAddrToHostAddr,
#else
/* pciAddrHostToBus */ pciAddrNOOP,
/* linuxTransAddrBusToHost is busted on sparc64 but the PCI rework tree
* makes it all moot, so we kludge it for now */
#if defined(__sparc__)
/* pciAddrBusToHost */ pciAddrNOOP,
#else
/* pciAddrBusToHost */ linuxTransAddrBusToHost,
#endif /* __sparc64__ */
#endif
/* pciControlBridge */ NULL,
/* pciGetBridgeBuses */ NULL,
/* pciGetBridgeResources */ NULL,
/* pciReadByte */ linuxPciCfgReadByte,
/* pciWriteByte */ linuxPciCfgWriteByte,
/* pciReadWord */ linuxPciCfgReadWord,
/* pciWriteWord */ linuxPciCfgWriteWord,
};
static pciBusInfo_t linuxPci0 = {
/* configMech */ PCI_CFG_MECH_OTHER,
/* numDevices */ 32,
/* secondary */ FALSE,
/* primary_bus */ 0,
/* funcs */ &linuxFuncs0,
/* pciBusPriv */ NULL,
/* bridge */ NULL
};
/* from lnx_pci.c. */
extern int lnxPciInit(void);
void
linuxPciInit()
{
struct stat st;
if ((xf86Info.pciFlags == PCIForceNone) ||
(-1 == stat("/proc/bus/pci", &st))) {
/* when using this as default for all linux architectures,
we'll need a fallback for 2.0 kernels here */
return;
}
pciNumBuses = 1;
pciBusInfo[0] = &linuxPci0;
pciFindFirstFP = pciGenFindFirst;
pciFindNextFP = pciGenFindNext;
pciSetOSBIOSPtr(linuxPciHandleBIOS);
xf86MaxPciDevs = lnxPciInit();
}
static int
linuxPciOpenFile(PCITAG tag, Bool write)
{
static int lbus,ldev,lfunc,fd = -1,is_write = 0;
int bus, dev, func;
char file[64];
struct stat ignored;
static int is26 = -1;
bus = PCI_BUS_FROM_TAG(tag);
dev = PCI_DEV_FROM_TAG(tag);
func = PCI_FUNC_FROM_TAG(tag);
if (is26 == -1) {
if (stat("/sys/bus/pci",&ignored) < 0)
is26 = 0;
else
is26 = 1;
}
if (fd == -1 || (write && (!is_write))
|| bus != lbus || dev != ldev || func != lfunc) {
if (fd != -1)
close(fd);
if (is26)
sprintf(file,"/sys/bus/pci/devices/0000:%02x:%02x.%01x/config",
bus, dev, func);
else {
if (bus < 256) {
sprintf(file,"/proc/bus/pci/%02x",bus);
if (stat(file, &ignored) < 0)
sprintf(file, "/proc/bus/pci/0000:%02x/%02x.%1x",
bus, dev, func);
else
sprintf(file, "/proc/bus/pci/%02x/%02x.%1x",
bus, dev, func);
} else {
sprintf(file,"/proc/bus/pci/%04x",bus);
if (stat(file, &ignored) < 0)
sprintf(file, "/proc/bus/pci/0000:%04x/%02x.%1x",
bus, dev, func);
else
sprintf(file, "/proc/bus/pci/%04x/%02x.%1x",
bus, dev, func);
}
}
if (write) {
fd = open(file,O_RDWR);
if (fd != -1) is_write = TRUE;
} else switch (is_write) {
case TRUE:
fd = open(file,O_RDWR);
if (fd > -1)
break;
default:
fd = open(file,O_RDONLY);
is_write = FALSE;
}
lbus = bus;
ldev = dev;
lfunc = func;
}
return fd;
}
static CARD32
linuxPciCfgRead(PCITAG tag, int off)
{
int fd;
CARD32 val = 0xffffffff;
if (-1 != (fd = linuxPciOpenFile(tag,FALSE))) {
lseek(fd,off,SEEK_SET);
read(fd,&val,4);
}
return PCI_CPU(val);
}
static void
linuxPciCfgWrite(PCITAG tag, int off, CARD32 val)
{
int fd;
if (-1 != (fd = linuxPciOpenFile(tag,TRUE))) {
lseek(fd,off,SEEK_SET);
val = PCI_CPU(val);
write(fd,&val,4);
}
}
static void
linuxPciCfgSetBits(PCITAG tag, int off, CARD32 mask, CARD32 bits)
{
int fd;
CARD32 val = 0xffffffff;
if (-1 != (fd = linuxPciOpenFile(tag,TRUE))) {
lseek(fd,off,SEEK_SET);
read(fd,&val,4);
val = PCI_CPU(val);
val = (val & ~mask) | (bits & mask);
val = PCI_CPU(val);
lseek(fd,off,SEEK_SET);
write(fd,&val,4);
}
}
/*
* This function will convert a BAR address into a host address
* suitable for passing into the mmap function of a /proc/bus
* device.
*/
ADDRESS linuxTransAddrBusToHost(PCITAG tag, PciAddrType type, ADDRESS addr)
{
ADDRESS ret = xf86GetOSOffsetFromPCI(tag, PCI_MEM|PCI_IO, addr);
if (ret)
return ret;
/*
* if it is not a BAR address, it must be legacy, (or wrong)
* return it as is..
*/
return addr;
}
#if defined(__powerpc__)
#ifndef __NR_pciconfig_iobase
#define __NR_pciconfig_iobase 200
#endif
static ADDRESS
linuxPpcBusAddrToHostAddr(PCITAG tag, PciAddrType type, ADDRESS addr)
{
if (type == PCI_MEM)
{
ADDRESS membase = syscall(__NR_pciconfig_iobase, 1,
PCI_BUS_FROM_TAG(tag), PCI_DFN_FROM_TAG(tag));
return (addr + membase);
}
else if (type == PCI_IO)
{
ADDRESS iobase = syscall(__NR_pciconfig_iobase, 2,
PCI_BUS_FROM_TAG(tag), PCI_DFN_FROM_TAG(tag));
return (addr + iobase);
}
else return addr;
}
static ADDRESS
linuxPpcHostAddrToBusAddr(PCITAG tag, PciAddrType type, ADDRESS addr)
{
if (type == PCI_MEM)
{
ADDRESS membase = syscall(__NR_pciconfig_iobase, 1,
PCI_BUS_FROM_TAG(tag), PCI_DFN_FROM_TAG(tag));
return (addr - membase);
}
else if (type == PCI_IO)
{
ADDRESS iobase = syscall(__NR_pciconfig_iobase, 2,
PCI_BUS_FROM_TAG(tag), PCI_DFN_FROM_TAG(tag));
return (addr - iobase);
}
else return addr;
}
#endif /* __powerpc__ */
static CARD8
linuxPciCfgReadByte(PCITAG tag, int off)
{
int fd;
CARD8 val = 0xff;
if (-1 != (fd = linuxPciOpenFile(tag,FALSE))) {
lseek(fd,off,SEEK_SET);
read(fd,&val,1);
}
return val;
}
static void
linuxPciCfgWriteByte(PCITAG tag, int off, CARD8 val)
{
int fd;
if (-1 != (fd = linuxPciOpenFile(tag,TRUE))) {
lseek(fd,off,SEEK_SET);
write(fd, &val, 1);
}
}
static CARD16
linuxPciCfgReadWord(PCITAG tag, int off)
{
int fd;
CARD16 val = 0xff;
if (-1 != (fd = linuxPciOpenFile(tag,FALSE))) {
lseek(fd, off, SEEK_SET);
read(fd, &val, 2);
}
return PCI_CPU16(val);
}
static void
linuxPciCfgWriteWord(PCITAG tag, int off, CARD16 val)
{
int fd;
if (-1 != (fd = linuxPciOpenFile(tag,TRUE))) {
lseek(fd, off, SEEK_SET);
val = PCI_CPU16(val);
write(fd, &val, 2);
}
}
#ifndef INCLUDE_XF86_NO_DOMAIN
/*
* Compiling the following simply requires the presence of <linux/pci.c>.
* Actually running this is another matter altogether...
*
* This scheme requires that the kernel allow mmap()'ing of a host bridge's I/O
* and memory spaces through its /proc/bus/pci/BUS/DFN entry. Which one is
* determined by a prior ioctl().
*
* For the sparc64 port, this means 2.4.12 or later. For ppc, this
* functionality is almost, but not quite there yet. Alpha and other kernel
* ports to multi-domain architectures still need to implement this.
*
* This scheme is also predicated on the use of an IOADDRESS compatible type to
* designate I/O addresses. Although IOADDRESS is defined as an unsigned
* integral type, it is actually the virtual address of, i.e. a pointer to, the
* I/O port to access. And so, the inX/outX macros in "compiler.h" need to be
* #define'd appropriately (as is done on SPARC's).
*
* Another requirement to port this scheme to another multi-domain architecture
* is to add the appropriate entries in the pciControllerSizes array below.
*
* TO DO: Address the deleterious reaction some host bridges have to master
* aborts. This is already done for secondary PCI buses, but not yet
* for accesses to primary buses (except for the SPARC port, where
* master aborts are avoided during PCI scans).
*/
#include <linux/pci.h>
#ifndef PCIIOC_BASE /* Ioctls for /proc/bus/pci/X/Y nodes. */
#define PCIIOC_BASE ('P' << 24 | 'C' << 16 | 'I' << 8)
/* Get controller for PCI device. */
#define PCIIOC_CONTROLLER (PCIIOC_BASE | 0x00)
/* Set mmap state to I/O space. */
#define PCIIOC_MMAP_IS_IO (PCIIOC_BASE | 0x01)
/* Set mmap state to MEM space. */
#define PCIIOC_MMAP_IS_MEM (PCIIOC_BASE | 0x02)
/* Enable/disable write-combining. */
#define PCIIOC_WRITE_COMBINE (PCIIOC_BASE | 0x03)
#endif
/* This probably shouldn't be Linux-specific */
static pciConfigPtr
xf86GetPciHostConfigFromTag(PCITAG Tag)
{
int bus = PCI_BUS_FROM_TAG(Tag);
pciBusInfo_t *pBusInfo;
while ((bus < pciNumBuses) && (pBusInfo = pciBusInfo[bus])) {
if (bus == pBusInfo->primary_bus)
return pBusInfo->bridge;
bus = pBusInfo->primary_bus;
}
return NULL; /* Bad data */
}
/*
* This is ugly, but until I can extract this information from the kernel,
* it'll have to do. The default I/O space size is 64K, and 4G for memory.
* Anything else needs to go in this table. (PowerPC folk take note.)
*
* Note that Linux/SPARC userland is 32-bit, so 4G overflows to zero here.
*
* Please keep this table in ascending vendor/device order.
*/
static const struct pciSizes {
unsigned short vendor, device;
unsigned long io_size, mem_size;
} pciControllerSizes[] = {
{
PCI_VENDOR_SUN, PCI_CHIP_PSYCHO,
1U << 16, 1U << 31
},
{
PCI_VENDOR_SUN, PCI_CHIP_SCHIZO,
1U << 24, 1U << 31 /* ??? */
},
{
PCI_VENDOR_SUN, PCI_CHIP_SABRE,
1U << 24, (unsigned long)(1ULL << 32)
},
{
PCI_VENDOR_SUN, PCI_CHIP_HUMMINGBIRD,
1U << 24, (unsigned long)(1ULL << 32)
}
};
#define NUM_SIZES (sizeof(pciControllerSizes) / sizeof(pciControllerSizes[0]))
static const struct pciSizes *
linuxGetSizesStruct(PCITAG Tag)
{
static const struct pciSizes default_size = {
0, 0, 1U << 16, (unsigned long)(1ULL << 32)
};
pciConfigPtr pPCI;
int i;
/* Find host bridge */
if ((pPCI = xf86GetPciHostConfigFromTag(Tag))) {
/* Look up vendor/device */
for (i = 0; i < NUM_SIZES; i++) {
if ((pPCI->pci_vendor == pciControllerSizes[i].vendor)
&& (pPCI->pci_device == pciControllerSizes[i].device)) {
return & pciControllerSizes[i];
}
}
}
/* Default to 64KB I/O and 4GB memory. */
return & default_size;
}
static __inline__ unsigned long
linuxGetIOSize(PCITAG Tag)
{
const struct pciSizes * const sizes = linuxGetSizesStruct(Tag);
return sizes->io_size;
}
static __inline__ void
linuxGetSizes(PCITAG Tag, unsigned long *io_size, unsigned long *mem_size)
{
const struct pciSizes * const sizes = linuxGetSizesStruct(Tag);
*io_size = sizes->io_size;
*mem_size = sizes->mem_size;
}
_X_EXPORT int
xf86GetPciDomain(PCITAG Tag)
{
pciConfigPtr pPCI;
int fd, result;
pPCI = xf86GetPciHostConfigFromTag(Tag);
if (pPCI && (result = PCI_DOM_FROM_BUS(pPCI->busnum)))
return result + 1;
if (!pPCI || pPCI->fakeDevice)
return 1; /* Domain 0 is reserved */
if ((fd = linuxPciOpenFile(pPCI ? pPCI->tag : 0,FALSE)) < 0)
return 0;
if ((result = ioctl(fd, PCIIOC_CONTROLLER, 0)) < 0)
return 0;
return result + 1; /* Domain 0 is reserved */
}
static pointer
linuxMapPci(int ScreenNum, int Flags, PCITAG Tag,
ADDRESS Base, unsigned long Size, int mmap_ioctl)
{
do {
pciConfigPtr pPCI;
unsigned char *result;
ADDRESS realBase, Offset;
int fd, mmapflags, prot;
xf86InitVidMem();
pPCI = xf86GetPciHostConfigFromTag(Tag);
if (((fd = linuxPciOpenFile(pPCI ? pPCI->tag : 0,FALSE)) < 0) ||
(ioctl(fd, mmap_ioctl, 0) < 0))
break;
/* Note: IA-64 doesn't compile this and doesn't need to */
#ifdef __ia64__
# ifndef MAP_WRITECOMBINED
# define MAP_WRITECOMBINED 0x00010000
# endif
# ifndef MAP_NONCACHED
# define MAP_NONCACHED 0x00020000
# endif
if (Flags & VIDMEM_FRAMEBUFFER)
mmapflags = MAP_SHARED | MAP_WRITECOMBINED;
else
mmapflags = MAP_SHARED | MAP_NONCACHED;
#else /* !__ia64__ */
mmapflags = (Flags & VIDMEM_FRAMEBUFFER) / VIDMEM_FRAMEBUFFER;
if (ioctl(fd, PCIIOC_WRITE_COMBINE, mmapflags) < 0)
break;
mmapflags = MAP_SHARED;
#endif /* ?__ia64__ */
/* Align to page boundary */
realBase = Base & ~(getpagesize() - 1);
Offset = Base - realBase;
if (Flags & VIDMEM_READONLY)
prot = PROT_READ;
else
prot = PROT_READ | PROT_WRITE;
result = mmap(NULL, Size + Offset, prot, mmapflags, fd, realBase);
if (!result || ((pointer)result == MAP_FAILED))
return NULL;
xf86MakeNewMapping(ScreenNum, Flags, realBase, Size + Offset, result);
return result + Offset;
} while (0);
if (mmap_ioctl == PCIIOC_MMAP_IS_MEM)
return xf86MapVidMem(ScreenNum, Flags, Base, Size);
return NULL;
}
#define MAX_DOMAINS 257
static pointer DomainMmappedIO[MAX_DOMAINS];
static pointer DomainMmappedMem[MAX_DOMAINS];
static int
linuxOpenLegacy(PCITAG Tag, char *name)
{
#define PREFIX "/sys/class/pci_bus/%04x:%02x/%s"
char *path;
int domain, bus;
pciBusInfo_t *pBusInfo;
pciConfigPtr bridge = NULL;
int fd;
path = xalloc(strlen(PREFIX) + strlen(name));
if (!path)
return -1;
for (;;) {
domain = xf86GetPciDomain(Tag);
bus = PCI_BUS_NO_DOMAIN(PCI_BUS_FROM_TAG(Tag));
/* Domain 0 is reserved -- see xf86GetPciDomain() */
if ((domain <= 0) || (domain >= MAX_DOMAINS))
FatalError("linuxOpenLegacy(): domain out of range\n");
sprintf(path, PREFIX, domain - 1, bus, name);
fd = open(path, O_RDWR);
if (fd >= 0) {
xfree(path);
return fd;
}
pBusInfo = pciBusInfo[bus];
if (!pBusInfo || (bridge == pBusInfo->bridge) ||
!(bridge = pBusInfo->bridge)) {
xfree(path);
return -1;
}
Tag = bridge->tag;
}
xfree(path);
return fd;
}
/*
* xf86MapDomainMemory - memory map PCI domain memory
*
* This routine maps the memory region in the domain specified by Tag and
* returns a pointer to it. The pointer is saved for future use if it's in
* the legacy ISA memory space (memory in a domain between 0 and 1MB).
*/
_X_EXPORT pointer
xf86MapDomainMemory(int ScreenNum, int Flags, PCITAG Tag,
ADDRESS Base, unsigned long Size)
{
int domain = xf86GetPciDomain(Tag);
int fd;
/*
* We use /proc/bus/pci on non-legacy addresses or if the Linux sysfs
* legacy_mem interface is unavailable.
*/
if (Base > 1024*1024)
return linuxMapPci(ScreenNum, Flags, Tag, Base, Size,
PCIIOC_MMAP_IS_MEM);
if ((fd = linuxOpenLegacy(Tag, "legacy_mem")) < 0)
return linuxMapPci(ScreenNum, Flags, Tag, Base, Size,
PCIIOC_MMAP_IS_MEM);
/* If we haven't already mapped this legacy space, try to. */
if (!DomainMmappedMem[domain]) {
DomainMmappedMem[domain] = mmap(NULL, 1024*1024, PROT_READ|PROT_WRITE,
MAP_SHARED, fd, 0);
if (DomainMmappedMem[domain] == MAP_FAILED) {
close(fd);
perror("mmap failure");
FatalError("xf86MapDomainMem(): mmap() failure\n");
}
}
close(fd);
return (pointer)((char *)DomainMmappedMem[domain] + Base);
}
/*
* xf86MapDomainIO - map I/O space in this domain
*
* Each domain has a legacy ISA I/O space. This routine will try to
* map it using the Linux sysfs legacy_io interface. If that fails,
* it'll fall back to using /proc/bus/pci.
*
* If the legacy_io interface *does* exist, the file descriptor (fd below)
* will be saved in the DomainMmappedIO array in the upper bits of the
* pointer. Callers will do I/O with small port numbers (<64k values), so
* the platform I/O code can extract the port number and the fd, lseek to
* the port number in the legacy_io file, and issue the read or write.
*
* This has no means of returning failure, so all errors are fatal
*/
_X_EXPORT IOADDRESS
xf86MapDomainIO(int ScreenNum, int Flags, PCITAG Tag,
IOADDRESS Base, unsigned long Size)
{
int domain = xf86GetPciDomain(Tag);
int fd;
if ((domain <= 0) || (domain >= MAX_DOMAINS))
FatalError("xf86MapDomainIO(): domain out of range\n");
if (DomainMmappedIO[domain])
return (IOADDRESS)DomainMmappedIO[domain] + Base;
/* Permanently map all of I/O space */
if ((fd = linuxOpenLegacy(Tag, "legacy_io")) < 0) {
DomainMmappedIO[domain] = linuxMapPci(ScreenNum, Flags, Tag,
0, linuxGetIOSize(Tag),
PCIIOC_MMAP_IS_IO);
/* ia64 can't mmap legacy IO port space */
if (!DomainMmappedIO[domain])
return Base;
}
else { /* legacy_io file exists, encode fd */
DomainMmappedIO[domain] = (pointer)(fd << 24);
}
return (IOADDRESS)DomainMmappedIO[domain] + Base;
}
/*
* xf86ReadDomainMemory - copy from domain memory into a caller supplied buffer
*/
_X_EXPORT int
xf86ReadDomainMemory(PCITAG Tag, ADDRESS Base, int Len, unsigned char *Buf)
{
unsigned char *ptr, *src;
ADDRESS offset;
unsigned long size;
int len, pagemask = getpagesize() - 1;
unsigned int i, dom, bus, dev, func;
unsigned int fd;
char file[256];
struct stat st;
dom = PCI_DOM_FROM_TAG(Tag);
bus = PCI_BUS_FROM_TAG(Tag);
dev = PCI_DEV_FROM_TAG(Tag);
func = PCI_FUNC_FROM_TAG(Tag);
sprintf(file, "/sys/devices/pci%04x:%02x/%04x:%02x:%02x.%1x/rom",
dom, bus, dom, bus, dev, func);
/*
* If the caller wants the ROM and the sysfs rom interface exists,
* try to use it instead of reading it from /proc/bus/pci.
*/
if (((Base & 0xfffff) == 0xC0000) && (stat(file, &st) == 0)) {
if ((fd = open(file, O_RDWR)))
Base = 0x0;
/* enable the ROM first */
write(fd, "1", 2);
lseek(fd, 0, SEEK_SET);
/* copy the ROM until we hit Len, EOF or read error */
for (i = 0; i < Len && read(fd, Buf, 1) > 0; Buf++, i++)
;
write(fd, "0", 2);
close(fd);
return Len;
}
/* Ensure page boundaries */
offset = Base & ~pagemask;
size = ((Base + Len + pagemask) & ~pagemask) - offset;
ptr = xf86MapDomainMemory(-1, VIDMEM_READONLY, Tag, offset, size);
if (!ptr)
return -1;
/* Using memcpy() here can hang the system */
src = ptr + (Base - offset);
for (len = Len; len-- > 0;)
*Buf++ = *src++;
xf86UnMapVidMem(-1, ptr, size);
return Len;
}
resPtr
xf86BusAccWindowsFromOS(void)
{
pciConfigPtr *ppPCI, pPCI;
resPtr pRes = NULL;
resRange range;
unsigned long io_size, mem_size;
int domain;
if ((ppPCI = xf86scanpci(0))) {
for (; (pPCI = *ppPCI); ppPCI++) {
if ((pPCI->pci_base_class != PCI_CLASS_BRIDGE) ||
(pPCI->pci_sub_class != PCI_SUBCLASS_BRIDGE_HOST))
continue;
domain = xf86GetPciDomain(pPCI->tag);
linuxGetSizes(pPCI->tag, &io_size, &mem_size);
RANGE(range, 0, (ADDRESS)(mem_size - 1),
RANGE_TYPE(ResExcMemBlock, domain));
pRes = xf86AddResToList(pRes, &range, -1);
RANGE(range, 0, (IOADDRESS)(io_size - 1),
RANGE_TYPE(ResExcIoBlock, domain));
pRes = xf86AddResToList(pRes, &range, -1);
if (domain <= 0)
break;
}
}
return pRes;
}
resPtr
xf86PciBusAccWindowsFromOS(void)
{
pciConfigPtr *ppPCI, pPCI;
resPtr pRes = NULL;
resRange range;
unsigned long io_size, mem_size;
int domain;
if ((ppPCI = xf86scanpci(0))) {
for (; (pPCI = *ppPCI); ppPCI++) {
if ((pPCI->pci_base_class != PCI_CLASS_BRIDGE) ||
(pPCI->pci_sub_class != PCI_SUBCLASS_BRIDGE_HOST))
continue;
domain = xf86GetPciDomain(pPCI->tag);
linuxGetSizes(pPCI->tag, &io_size, &mem_size);
RANGE(range, 0, (ADDRESS)(mem_size - 1),
RANGE_TYPE(ResExcMemBlock, domain));
pRes = xf86AddResToList(pRes, &range, -1);
RANGE(range, 0, (IOADDRESS)(io_size - 1),
RANGE_TYPE(ResExcIoBlock, domain));
pRes = xf86AddResToList(pRes, &range, -1);
if (domain <= 0)
break;
}
}
return pRes;
}
resPtr
xf86AccResFromOS(resPtr pRes)
{
pciConfigPtr *ppPCI, pPCI;
resRange range;
unsigned long io_size, mem_size;
int domain;
if ((ppPCI = xf86scanpci(0))) {
for (; (pPCI = *ppPCI); ppPCI++) {
if ((pPCI->pci_base_class != PCI_CLASS_BRIDGE) ||
(pPCI->pci_sub_class != PCI_SUBCLASS_BRIDGE_HOST))
continue;
domain = xf86GetPciDomain(pPCI->tag);
linuxGetSizes(pPCI->tag, &io_size, &mem_size);
/*
* At minimum, the top and bottom resources must be claimed, so
* that resources that are (or appear to be) unallocated can be
* relocated.
*/
RANGE(range, 0x00000000u, 0x0009ffffu,
RANGE_TYPE(ResExcMemBlock, domain));
pRes = xf86AddResToList(pRes, &range, -1);
RANGE(range, 0x000c0000u, 0x000effffu,
RANGE_TYPE(ResExcMemBlock, domain));
pRes = xf86AddResToList(pRes, &range, -1);
RANGE(range, 0x000f0000u, 0x000fffffu,
RANGE_TYPE(ResExcMemBlock, domain));
pRes = xf86AddResToList(pRes, &range, -1);
RANGE(range, (ADDRESS)(mem_size - 1), (ADDRESS)(mem_size - 1),
RANGE_TYPE(ResExcMemBlock, domain));
pRes = xf86AddResToList(pRes, &range, -1);
RANGE(range, 0x00000000u, 0x00000000u,
RANGE_TYPE(ResExcIoBlock, domain));
pRes = xf86AddResToList(pRes, &range, -1);
RANGE(range, (IOADDRESS)(io_size - 1), (IOADDRESS)(io_size - 1),
RANGE_TYPE(ResExcIoBlock, domain));
pRes = xf86AddResToList(pRes, &range, -1);
if (domain <= 0)
break;
}
}
return pRes;
}
#endif /* !INCLUDE_XF86_NO_DOMAIN */
int linuxPciHandleBIOS(PCITAG Tag, int basereg, unsigned char *buf, int len)
{
unsigned int dom, bus, dev, func;
unsigned int fd;
char file[256];
struct stat st;
int ret;
int sofar = 0;
dom = PCI_DOM_FROM_TAG(Tag);
bus = PCI_BUS_FROM_TAG(Tag);
dev = PCI_DEV_FROM_TAG(Tag);
func = PCI_FUNC_FROM_TAG(Tag);
sprintf(file, "/sys/bus/pci/devices/%04x:%02x:%02x.%1x/rom",
dom, bus, dev, func);
if (stat(file, &st) == 0)
{
if ((fd = open(file, O_RDWR)))
basereg = 0x0;
/* enable the ROM first */
write(fd, "1", 2);
lseek(fd, 0, SEEK_SET);
do {
/* copy the ROM until we hit Len, EOF or read error */
ret = read(fd, buf+sofar, len-sofar);
if (ret <= 0)
break;
sofar += ret;
} while (sofar < len);
write(fd, "0", 2);
close(fd);
if (sofar < len)
xf86MsgVerb(X_INFO, 3, "Attempted to read BIOS %dKB from %s: got %dKB\n", len/1024, file, sofar/1024);
return sofar;
}
return 0;
}
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