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xserver/hw/xfree86/int10/helper_exec.c

767 lines
21 KiB
C

/*
* XFree86 int10 module
* execute BIOS int 10h calls in x86 real mode environment
* Copyright 1999 Egbert Eich
*
* Part of this code was inspired by the VBIOS POSTing code in DOSEMU
* developed by the "DOSEMU-Development-Team"
*/
/*
* To debug port accesses define PRINT_PORT to 1.
* Note! You also have to comment out ioperm()
* in xf86EnableIO(). Otherwise we won't trap
* on PIO.
*/
#ifdef HAVE_XORG_CONFIG_H
#include <xorg-config.h>
#endif
#define PRINT_PORT 0
#include <unistd.h>
#include <X11/Xos.h>
#include "xf86.h"
#include "xf86_OSproc.h"
#include "compiler.h"
#define _INT10_PRIVATE
#include "int10Defines.h"
#include "xf86int10.h"
#include "Pci.h"
#ifdef _X86EMU
#include "x86emu/x86emui.h"
#else
#define DEBUG_IO_TRACE() 0
#endif
#include <pciaccess.h>
static int pciCfg1in(uint16_t addr, uint32_t *val);
static int pciCfg1out(uint16_t addr, uint32_t val);
static int pciCfg1inw(uint16_t addr, uint16_t *val);
static int pciCfg1outw(uint16_t addr, uint16_t val);
static int pciCfg1inb(uint16_t addr, uint8_t *val);
static int pciCfg1outb(uint16_t addr, uint8_t val);
#if defined (_PC)
static void SetResetBIOSVars(xf86Int10InfoPtr pInt, Bool set);
#endif
#define REG pInt
int
setup_int(xf86Int10InfoPtr pInt)
{
if (pInt != Int10Current) {
if (!MapCurrentInt10(pInt))
return -1;
Int10Current = pInt;
}
X86_EAX = (uint32_t) pInt->ax;
X86_EBX = (uint32_t) pInt->bx;
X86_ECX = (uint32_t) pInt->cx;
X86_EDX = (uint32_t) pInt->dx;
X86_ESI = (uint32_t) pInt->si;
X86_EDI = (uint32_t) pInt->di;
X86_EBP = (uint32_t) pInt->bp;
X86_ESP = 0x1000;
X86_SS = pInt->stackseg >> 4;
X86_EIP = 0x0600;
X86_CS = 0x0; /* address of 'hlt' */
X86_DS = 0x40; /* standard pc ds */
X86_ES = pInt->es;
X86_FS = 0;
X86_GS = 0;
X86_EFLAGS = X86_IF_MASK | X86_IOPL_MASK;
#if defined (_PC)
if (pInt->Flags & SET_BIOS_SCRATCH)
SetResetBIOSVars(pInt, TRUE);
#endif
OsBlockSignals();
return 0;
}
void
finish_int(xf86Int10InfoPtr pInt, int sig)
{
OsReleaseSignals();
pInt->ax = (uint32_t) X86_EAX;
pInt->bx = (uint32_t) X86_EBX;
pInt->cx = (uint32_t) X86_ECX;
pInt->dx = (uint32_t) X86_EDX;
pInt->si = (uint32_t) X86_ESI;
pInt->di = (uint32_t) X86_EDI;
pInt->es = (uint16_t) X86_ES;
pInt->bp = (uint32_t) X86_EBP;
pInt->flags = (uint32_t) X86_FLAGS;
#if defined (_PC)
if (pInt->Flags & RESTORE_BIOS_SCRATCH)
SetResetBIOSVars(pInt, FALSE);
#endif
}
/* general software interrupt handler */
uint32_t
getIntVect(xf86Int10InfoPtr pInt, int num)
{
return MEM_RW(pInt, num << 2) + (MEM_RW(pInt, (num << 2) + 2) << 4);
}
void
pushw(xf86Int10InfoPtr pInt, uint16_t val)
{
X86_ESP -= 2;
MEM_WW(pInt, ((uint32_t) X86_SS << 4) + X86_SP, val);
}
int
run_bios_int(int num, xf86Int10InfoPtr pInt)
{
uint32_t eflags;
#ifndef _PC
/* check if bios vector is initialized */
if (MEM_RW(pInt, (num << 2) + 2) == (SYS_BIOS >> 4)) { /* SYS_BIOS_SEG ? */
if (num == 21 && X86_AH == 0x4e) {
xf86DrvMsg(pInt->pScrn->scrnIndex, X_NOTICE,
"Failing Find-Matching-File on non-PC"
" (int 21, func 4e)\n");
X86_AX = 2;
SET_FLAG(F_CF);
return 1;
}
else {
xf86DrvMsgVerb(pInt->pScrn->scrnIndex, X_NOT_IMPLEMENTED, 2,
"Ignoring int 0x%02x call\n", num);
if (xf86GetVerbosity() > 3) {
dump_registers(pInt);
stack_trace(pInt);
}
return 1;
}
}
#endif
#ifdef PRINT_INT
ErrorF("calling card BIOS at: ");
#endif
eflags = X86_EFLAGS;
#if 0
eflags = eflags | IF_MASK;
X86_EFLAGS = X86_EFLAGS & ~(VIF_MASK | TF_MASK | IF_MASK | NT_MASK);
#endif
pushw(pInt, eflags);
pushw(pInt, X86_CS);
pushw(pInt, X86_IP);
X86_CS = MEM_RW(pInt, (num << 2) + 2);
X86_IP = MEM_RW(pInt, num << 2);
#ifdef PRINT_INT
ErrorF("0x%x:%lx\n", X86_CS, X86_EIP);
#endif
return 1;
}
/* Debugging stuff */
void
dump_code(xf86Int10InfoPtr pInt)
{
int i;
uint32_t lina = SEG_ADR((uint32_t), X86_CS, IP);
xf86DrvMsgVerb(pInt->pScrn->scrnIndex, X_INFO, 3, "code at 0x%8.8" PRIx32 ":\n",
(unsigned) lina);
for (i = 0; i < 0x10; i++)
xf86ErrorFVerb(3, " %2.2x", MEM_RB(pInt, lina + i));
xf86ErrorFVerb(3, "\n");
for (; i < 0x20; i++)
xf86ErrorFVerb(3, " %2.2x", MEM_RB(pInt, lina + i));
xf86ErrorFVerb(3, "\n");
}
void
dump_registers(xf86Int10InfoPtr pInt)
{
xf86DrvMsgVerb(pInt->pScrn->scrnIndex, X_INFO, 3,
"EAX=0x%8.8lx, EBX=0x%8.8lx, ECX=0x%8.8lx, EDX=0x%8.8lx\n",
(unsigned long) X86_EAX, (unsigned long) X86_EBX,
(unsigned long) X86_ECX, (unsigned long) X86_EDX);
xf86DrvMsgVerb(pInt->pScrn->scrnIndex, X_INFO, 3,
"ESP=0x%8.8lx, EBP=0x%8.8lx, ESI=0x%8.8lx, EDI=0x%8.8lx\n",
(unsigned long) X86_ESP, (unsigned long) X86_EBP,
(unsigned long) X86_ESI, (unsigned long) X86_EDI);
xf86DrvMsgVerb(pInt->pScrn->scrnIndex, X_INFO, 3,
"CS=0x%4.4x, SS=0x%4.4x,"
" DS=0x%4.4x, ES=0x%4.4x, FS=0x%4.4x, GS=0x%4.4x\n",
X86_CS, X86_SS, X86_DS, X86_ES, X86_FS, X86_GS);
xf86DrvMsgVerb(pInt->pScrn->scrnIndex, X_INFO, 3,
"EIP=0x%8.8lx, EFLAGS=0x%8.8lx\n",
(unsigned long) X86_EIP, (unsigned long) X86_EFLAGS);
}
void
stack_trace(xf86Int10InfoPtr pInt)
{
int i = 0;
unsigned long stack = SEG_ADR((uint32_t), X86_SS, SP);
unsigned long tail = (uint32_t) ((X86_SS << 4) + 0x1000);
if (stack >= tail)
return;
xf86MsgVerb(X_INFO, 3, "stack at 0x%8.8lx:\n", stack);
for (; stack < tail; stack++) {
xf86ErrorFVerb(3, " %2.2x", MEM_RB(pInt, stack));
i = (i + 1) % 0x10;
if (!i)
xf86ErrorFVerb(3, "\n");
}
if (i)
xf86ErrorFVerb(3, "\n");
}
int
port_rep_inb(xf86Int10InfoPtr pInt,
uint16_t port, uint32_t base, int d_f, uint32_t count)
{
register int inc = d_f ? -1 : 1;
uint32_t dst = base;
if (PRINT_PORT && DEBUG_IO_TRACE())
ErrorF(" rep_insb(%#x) %" PRIu32 " bytes at %8.8" PRIx32 " %s\n",
port, (unsigned) count, (unsigned) base, d_f ? "up" : "down");
while (count--) {
MEM_WB(pInt, dst, x_inb(port));
dst += inc;
}
return dst - base;
}
int
port_rep_inw(xf86Int10InfoPtr pInt,
uint16_t port, uint32_t base, int d_f, uint32_t count)
{
register int inc = d_f ? -2 : 2;
uint32_t dst = base;
if (PRINT_PORT && DEBUG_IO_TRACE())
ErrorF(" rep_insw(%#x) %" PRIu32 " bytes at %8.8" PRIx32 " %s\n",
port, (unsigned) count, (unsigned) base, d_f ? "up" : "down");
while (count--) {
MEM_WW(pInt, dst, x_inw(port));
dst += inc;
}
return dst - base;
}
int
port_rep_inl(xf86Int10InfoPtr pInt,
uint16_t port, uint32_t base, int d_f, uint32_t count)
{
register int inc = d_f ? -4 : 4;
uint32_t dst = base;
if (PRINT_PORT && DEBUG_IO_TRACE())
ErrorF(" rep_insl(%#x) %" PRIu32 " bytes at %8.8" PRIx32 " %s\n",
port, (unsigned) count, (unsigned) base, d_f ? "up" : "down");
while (count--) {
MEM_WL(pInt, dst, x_inl(port));
dst += inc;
}
return dst - base;
}
int
port_rep_outb(xf86Int10InfoPtr pInt,
uint16_t port, uint32_t base, int d_f, uint32_t count)
{
register int inc = d_f ? -1 : 1;
uint32_t dst = base;
if (PRINT_PORT && DEBUG_IO_TRACE())
ErrorF(" rep_outb(%#x) %" PRIu32 " bytes at %8.8" PRIx32 " %s\n",
port, (unsigned) count, (unsigned) base, d_f ? "up" : "down");
while (count--) {
x_outb(port, MEM_RB(pInt, dst));
dst += inc;
}
return dst - base;
}
int
port_rep_outw(xf86Int10InfoPtr pInt,
uint16_t port, uint32_t base, int d_f, uint32_t count)
{
register int inc = d_f ? -2 : 2;
uint32_t dst = base;
if (PRINT_PORT && DEBUG_IO_TRACE())
ErrorF(" rep_outw(%#x) %" PRIu32 " bytes at %8.8" PRIx32 " %s\n",
port, (unsigned) count, (unsigned) base, d_f ? "up" : "down");
while (count--) {
x_outw(port, MEM_RW(pInt, dst));
dst += inc;
}
return dst - base;
}
int
port_rep_outl(xf86Int10InfoPtr pInt,
uint16_t port, uint32_t base, int d_f, uint32_t count)
{
register int inc = d_f ? -4 : 4;
uint32_t dst = base;
if (PRINT_PORT && DEBUG_IO_TRACE())
ErrorF(" rep_outl(%#x) %" PRIu32 " bytes at %8.8" PRIx32 " %s\n",
port, (unsigned) count, (unsigned) base, d_f ? "up" : "down");
while (count--) {
x_outl(port, MEM_RL(pInt, dst));
dst += inc;
}
return dst - base;
}
uint8_t
x_inb(uint16_t port)
{
uint8_t val;
if (port == 0x40) {
Int10Current->inb40time++;
val = (uint8_t) (Int10Current->inb40time >>
((Int10Current->inb40time & 1) << 3));
if (PRINT_PORT && DEBUG_IO_TRACE())
ErrorF(" inb(%#x) = %2.2x\n", port, val);
#ifdef __NOT_YET__
}
else if (port < 0x0100) { /* Don't interfere with mainboard */
val = 0;
xf86DrvMsgVerb(Int10Current->pScrn->scrnIndex, X_NOT_IMPLEMENTED, 2,
"inb 0x%4.4x\n", port);
if (xf86GetVerbosity() > 3) {
dump_registers(Int10Current);
stack_trace(Int10Current);
}
#endif /* __NOT_YET__ */
}
else if (!pciCfg1inb(port, &val)) {
val = pci_io_read8(Int10Current->io, port);
if (PRINT_PORT && DEBUG_IO_TRACE())
ErrorF(" inb(%#x) = %2.2x\n", port, val);
}
return val;
}
uint16_t
x_inw(uint16_t port)
{
uint16_t val;
if (port == 0x5c) {
struct timeval tv;
/*
* Emulate a PC's timer. Typical resolution is 3.26 usec.
* Approximate this by dividing by 3.
*/
X_GETTIMEOFDAY(&tv);
val = (uint16_t) (tv.tv_usec / 3);
}
else if (!pciCfg1inw(port, &val)) {
val = pci_io_read16(Int10Current->io, port);
if (PRINT_PORT && DEBUG_IO_TRACE())
ErrorF(" inw(%#x) = %4.4x\n", port, val);
}
return val;
}
void
x_outb(uint16_t port, uint8_t val)
{
if ((port == 0x43) && (val == 0)) {
struct timeval tv;
/*
* Emulate a PC's timer 0. Such timers typically have a resolution of
* some .838 usec per tick, but this can only provide 1 usec per tick.
* (Not that this matters much, given inherent emulation delays.) Use
* the bottom bit as a byte select. See inb(0x40) above.
*/
X_GETTIMEOFDAY(&tv);
Int10Current->inb40time = (uint16_t) (tv.tv_usec | 1);
if (PRINT_PORT && DEBUG_IO_TRACE())
ErrorF(" outb(%#x, %2.2x)\n", port, val);
#ifdef __NOT_YET__
}
else if (port < 0x0100) { /* Don't interfere with mainboard */
xf86DrvMsgVerb(Int10Current->pScrn->scrnIndex, X_NOT_IMPLEMENTED, 2,
"outb 0x%4.4x,0x%2.2x\n", port, val);
if (xf86GetVerbosity() > 3) {
dump_registers(Int10Current);
stack_trace(Int10Current);
}
#endif /* __NOT_YET__ */
}
else if (!pciCfg1outb(port, val)) {
if (PRINT_PORT && DEBUG_IO_TRACE())
ErrorF(" outb(%#x, %2.2x)\n", port, val);
pci_io_write8(Int10Current->io, port, val);
}
}
void
x_outw(uint16_t port, uint16_t val)
{
if (!pciCfg1outw(port, val)) {
if (PRINT_PORT && DEBUG_IO_TRACE())
ErrorF(" outw(%#x, %4.4x)\n", port, val);
pci_io_write16(Int10Current->io, port, val);
}
}
uint32_t
x_inl(uint16_t port)
{
uint32_t val;
if (!pciCfg1in(port, &val)) {
val = pci_io_read32(Int10Current->io, port);
if (PRINT_PORT && DEBUG_IO_TRACE())
ErrorF(" inl(%#x) = %8.8" PRIx32 "\n", port, (unsigned) val);
}
return val;
}
void
x_outl(uint16_t port, uint32_t val)
{
if (!pciCfg1out(port, val)) {
if (PRINT_PORT && DEBUG_IO_TRACE())
ErrorF(" outl(%#x, %8.8" PRIx32 ")\n", port, (unsigned) val);
pci_io_write32(Int10Current->io, port, val);
}
}
uint8_t
Mem_rb(uint32_t addr)
{
return (*Int10Current->mem->rb) (Int10Current, addr);
}
uint16_t
Mem_rw(uint32_t addr)
{
return (*Int10Current->mem->rw) (Int10Current, addr);
}
uint32_t
Mem_rl(uint32_t addr)
{
return (*Int10Current->mem->rl) (Int10Current, addr);
}
void
Mem_wb(uint32_t addr, uint8_t val)
{
(*Int10Current->mem->wb) (Int10Current, addr, val);
}
void
Mem_ww(uint32_t addr, uint16_t val)
{
(*Int10Current->mem->ww) (Int10Current, addr, val);
}
void
Mem_wl(uint32_t addr, uint32_t val)
{
(*Int10Current->mem->wl) (Int10Current, addr, val);
}
static uint32_t PciCfg1Addr = 0;
#define PCI_DOM_FROM_TAG(tag) (((tag) >> 24) & (PCI_DOM_MASK))
#define PCI_BUS_FROM_TAG(tag) (((tag) >> 16) & (PCI_DOMBUS_MASK))
#define PCI_DEV_FROM_TAG(tag) (((tag) & 0x0000f800u) >> 11)
#define PCI_FUNC_FROM_TAG(tag) (((tag) & 0x00000700u) >> 8)
#define PCI_OFFSET(x) ((x) & 0x000000ff)
#define PCI_TAG(x) ((x) & 0x7fffff00)
static struct pci_device *
pci_device_for_cfg_address(uint32_t addr)
{
struct pci_device *dev = NULL;
uint32_t tag = PCI_TAG(addr);
struct pci_slot_match slot_match = {
.domain = PCI_DOM_FROM_TAG(tag),
.bus = PCI_BUS_NO_DOMAIN(PCI_BUS_FROM_TAG(tag)),
.dev = PCI_DEV_FROM_TAG(tag),
.func = PCI_FUNC_FROM_TAG(tag),
.match_data = 0
};
struct pci_device_iterator *iter =
pci_slot_match_iterator_create(&slot_match);
if (iter)
dev = pci_device_next(iter);
pci_iterator_destroy(iter);
return dev;
}
static int
pciCfg1in(uint16_t addr, uint32_t *val)
{
if (addr == 0xCF8) {
*val = PciCfg1Addr;
return 1;
}
if (addr == 0xCFC) {
pci_device_cfg_read_u32(pci_device_for_cfg_address(PciCfg1Addr),
(uint32_t *) val, PCI_OFFSET(PciCfg1Addr));
if (PRINT_PORT && DEBUG_IO_TRACE())
ErrorF(" cfg_inl(%#" PRIx32 ") = %8.8" PRIx32 "\n", (unsigned) PciCfg1Addr,
(unsigned) *val);
return 1;
}
return 0;
}
static int
pciCfg1out(uint16_t addr, uint32_t val)
{
if (addr == 0xCF8) {
PciCfg1Addr = val;
return 1;
}
if (addr == 0xCFC) {
if (PRINT_PORT && DEBUG_IO_TRACE())
ErrorF(" cfg_outl(%#" PRIx32 ", %8.8" PRIx32 ")\n", (unsigned) PciCfg1Addr,
(unsigned) val);
pci_device_cfg_write_u32(pci_device_for_cfg_address(PciCfg1Addr), val,
PCI_OFFSET(PciCfg1Addr));
return 1;
}
return 0;
}
static int
pciCfg1inw(uint16_t addr, uint16_t *val)
{
int shift;
if ((addr >= 0xCF8) && (addr <= 0xCFB)) {
shift = (addr - 0xCF8) * 8;
*val = (PciCfg1Addr >> shift) & 0xffff;
return 1;
}
if ((addr >= 0xCFC) && (addr <= 0xCFF)) {
const unsigned offset = addr - 0xCFC;
pci_device_cfg_read_u16(pci_device_for_cfg_address(PciCfg1Addr),
val, PCI_OFFSET(PciCfg1Addr) + offset);
if (PRINT_PORT && DEBUG_IO_TRACE())
ErrorF(" cfg_inw(%#" PRIx32 ") = %4.4x\n", (unsigned) (PciCfg1Addr + offset),
(unsigned) *val);
return 1;
}
return 0;
}
static int
pciCfg1outw(uint16_t addr, uint16_t val)
{
int shift;
if ((addr >= 0xCF8) && (addr <= 0xCFB)) {
shift = (addr - 0xCF8) * 8;
PciCfg1Addr &= ~(0xffff << shift);
PciCfg1Addr |= ((uint32_t) val) << shift;
return 1;
}
if ((addr >= 0xCFC) && (addr <= 0xCFF)) {
const unsigned offset = addr - 0xCFC;
if (PRINT_PORT && DEBUG_IO_TRACE())
ErrorF(" cfg_outw(%#" PRIx32 ", %4.4x)\n", (unsigned) (PciCfg1Addr + offset),
(unsigned) val);
pci_device_cfg_write_u16(pci_device_for_cfg_address(PciCfg1Addr), val,
PCI_OFFSET(PciCfg1Addr) + offset);
return 1;
}
return 0;
}
static int
pciCfg1inb(uint16_t addr, uint8_t *val)
{
int shift;
if ((addr >= 0xCF8) && (addr <= 0xCFB)) {
shift = (addr - 0xCF8) * 8;
*val = (PciCfg1Addr >> shift) & 0xff;
return 1;
}
if ((addr >= 0xCFC) && (addr <= 0xCFF)) {
const unsigned offset = addr - 0xCFC;
pci_device_cfg_read_u8(pci_device_for_cfg_address(PciCfg1Addr),
val, PCI_OFFSET(PciCfg1Addr) + offset);
if (PRINT_PORT && DEBUG_IO_TRACE())
ErrorF(" cfg_inb(%#" PRIx32 ") = %2.2x\n", (unsigned) (PciCfg1Addr + offset),
(unsigned) *val);
return 1;
}
return 0;
}
static int
pciCfg1outb(uint16_t addr, uint8_t val)
{
int shift;
if ((addr >= 0xCF8) && (addr <= 0xCFB)) {
shift = (addr - 0xCF8) * 8;
PciCfg1Addr &= ~(0xff << shift);
PciCfg1Addr |= ((uint32_t) val) << shift;
return 1;
}
if ((addr >= 0xCFC) && (addr <= 0xCFF)) {
const unsigned offset = addr - 0xCFC;
if (PRINT_PORT && DEBUG_IO_TRACE())
ErrorF(" cfg_outb(%#" PRIx32 ", %2.2x)\n", (unsigned) (PciCfg1Addr + offset),
(unsigned) val);
pci_device_cfg_write_u8(pci_device_for_cfg_address(PciCfg1Addr), val,
PCI_OFFSET(PciCfg1Addr) + offset);
return 1;
}
return 0;
}
uint8_t
bios_checksum(const uint8_t *start, int size)
{
uint8_t sum = 0;
while (size-- > 0)
sum += *start++;
return sum;
}
/*
* Lock/Unlock legacy VGA. Some Bioses try to be very clever and make
* an attempt to detect a legacy ISA card. If they find one they might
* act very strange: for example they might configure the card as a
* monochrome card. This might cause some drivers to choke.
* To avoid this we attempt legacy VGA by writing to all known VGA
* disable registers before we call the BIOS initialization and
* restore the original values afterwards. In between we hold our
* breath. To get to a (possibly existing) ISA card need to disable
* our current PCI card.
*/
/*
* This is just for booting: we just want to catch pure
* legacy vga therefore we don't worry about mmio etc.
* This stuff should really go into vgaHW.c. However then
* the driver would have to load the vga-module prior to
* doing int10.
*/
void
LockLegacyVGA(xf86Int10InfoPtr pInt, legacyVGAPtr vga)
{
vga->save_msr = pci_io_read8(pInt->io, 0x03CC);
vga->save_vse = pci_io_read8(pInt->io, 0x03C3);
#ifndef __ia64__
vga->save_46e8 = pci_io_read8(pInt->io, 0x46E8);
#endif
vga->save_pos102 = pci_io_read8(pInt->io, 0x0102);
pci_io_write8(pInt->io, 0x03C2, ~(uint8_t) 0x03 & vga->save_msr);
pci_io_write8(pInt->io, 0x03C3, ~(uint8_t) 0x01 & vga->save_vse);
#ifndef __ia64__
pci_io_write8(pInt->io, 0x46E8, ~(uint8_t) 0x08 & vga->save_46e8);
#endif
pci_io_write8(pInt->io, 0x0102, ~(uint8_t) 0x01 & vga->save_pos102);
}
void
UnlockLegacyVGA(xf86Int10InfoPtr pInt, legacyVGAPtr vga)
{
pci_io_write8(pInt->io, 0x0102, vga->save_pos102);
#ifndef __ia64__
pci_io_write8(pInt->io, 0x46E8, vga->save_46e8);
#endif
pci_io_write8(pInt->io, 0x03C3, vga->save_vse);
pci_io_write8(pInt->io, 0x03C2, vga->save_msr);
}
#if defined (_PC)
static void
SetResetBIOSVars(xf86Int10InfoPtr pInt, Bool set)
{
int pagesize = getpagesize();
unsigned char *base;
int i;
if (pci_device_map_legacy
(pInt->dev, 0, pagesize, PCI_DEV_MAP_FLAG_WRITABLE, (void **) &base))
return; /* eek */
if (set) {
for (i = BIOS_SCRATCH_OFF; i < BIOS_SCRATCH_END; i++)
MEM_WW(pInt, i, *(base + i));
}
else {
for (i = BIOS_SCRATCH_OFF; i < BIOS_SCRATCH_END; i++)
*(base + i) = MEM_RW(pInt, i);
}
pci_device_unmap_legacy(pInt->dev, base, pagesize);
}
void
xf86Int10SaveRestoreBIOSVars(xf86Int10InfoPtr pInt, Bool save)
{
int pagesize = getpagesize();
unsigned char *base;
int i;
if (!xf86IsEntityPrimary(pInt->entityIndex)
|| (!save && !pInt->BIOSScratch))
return;
if (pci_device_map_legacy
(pInt->dev, 0, pagesize, PCI_DEV_MAP_FLAG_WRITABLE, (void **) &base))
return; /* eek */
base += BIOS_SCRATCH_OFF;
if (save) {
if ((pInt->BIOSScratch = xnfalloc(BIOS_SCRATCH_LEN)))
for (i = 0; i < BIOS_SCRATCH_LEN; i++)
*(((char *) pInt->BIOSScratch + i)) = *(base + i);
}
else {
if (pInt->BIOSScratch) {
for (i = 0; i < BIOS_SCRATCH_LEN; i++)
*(base + i) = *(pInt->BIOSScratch + i);
free(pInt->BIOSScratch);
pInt->BIOSScratch = NULL;
}
}
pci_device_unmap_legacy(pInt->dev, base - BIOS_SCRATCH_OFF, pagesize);
}
#endif
xf86Int10InfoPtr
xf86InitInt10(int entityIndex)
{
return xf86ExtendedInitInt10(entityIndex, 0);
}