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xserver/hw/xfree86/int10/generic.c

483 lines
12 KiB
C

/*
* XFree86 int10 module
* execute BIOS int 10h calls in x86 real mode environment
* Copyright 1999 Egbert Eich
*/
#ifdef HAVE_XORG_CONFIG_H
#include <xorg-config.h>
#endif
#include <string.h>
#include <unistd.h>
#include "xf86.h"
#include "xf86_OSproc.h"
#include "compiler.h"
#define _INT10_PRIVATE
#include "xf86int10.h"
#include "int10Defines.h"
#include "Pci.h"
#define ALLOC_ENTRIES(x) ((V_RAM / x) - 1)
#include <string.h> /* needed for memmove */
static __inline__ uint32_t
ldl_u(uint32_t * p)
{
uint32_t ret;
memmove(&ret, p, sizeof(*p));
return ret;
}
static __inline__ uint16_t
ldw_u(uint16_t * p)
{
uint16_t ret;
memmove(&ret, p, sizeof(*p));
return ret;
}
static __inline__ void
stl_u(uint32_t val, uint32_t * p)
{
uint32_t tmp = val;
memmove(p, &tmp, sizeof(*p));
}
static __inline__ void
stw_u(uint16_t val, uint16_t * p)
{
uint16_t tmp = val;
memmove(p, &tmp, sizeof(*p));
}
static uint8_t read_b(xf86Int10InfoPtr pInt, int addr);
static uint16_t read_w(xf86Int10InfoPtr pInt, int addr);
static uint32_t read_l(xf86Int10InfoPtr pInt, int addr);
static void write_b(xf86Int10InfoPtr pInt, int addr, uint8_t val);
static void write_w(xf86Int10InfoPtr pInt, int addr, uint16_t val);
static void write_l(xf86Int10InfoPtr pInt, int addr, uint32_t val);
/*
* the emulator cannot pass a pointer to the current xf86Int10InfoRec
* to the memory access functions therefore store it here.
*/
typedef struct {
int shift;
int entries;
void *base;
void *vRam;
int highMemory;
void *sysMem;
char *alloc;
} genericInt10Priv;
#define INTPriv(x) ((genericInt10Priv*)x->private)
int10MemRec genericMem = {
read_b,
read_w,
read_l,
write_b,
write_w,
write_l
};
static void MapVRam(xf86Int10InfoPtr pInt);
static void UnmapVRam(xf86Int10InfoPtr pInt);
#ifdef _PC
#define GET_HIGH_BASE(x) (((V_BIOS + (x) + getpagesize() - 1)/getpagesize()) \
* getpagesize())
#endif
static void *sysMem = NULL;
static Bool
readIntVec(struct pci_device *dev, unsigned char *buf, int len)
{
void *map;
if (pci_device_map_legacy(dev, 0, len, 0, &map))
return FALSE;
memcpy(buf, map, len);
pci_device_unmap_legacy(dev, map, len);
return TRUE;
}
xf86Int10InfoPtr
xf86ExtendedInitInt10(int entityIndex, int Flags)
{
xf86Int10InfoPtr pInt;
void *base = 0;
void *vbiosMem = 0;
void *options = NULL;
legacyVGARec vga;
ScrnInfoPtr pScrn;
pScrn = xf86FindScreenForEntity(entityIndex);
options = xf86HandleInt10Options(pScrn, entityIndex);
if (int10skip(options)) {
free(options);
return NULL;
}
pInt = (xf86Int10InfoPtr) xnfcalloc(1, sizeof(xf86Int10InfoRec));
pInt->entityIndex = entityIndex;
if (!xf86Int10ExecSetup(pInt))
goto error0;
pInt->mem = &genericMem;
pInt->private = (void *) xnfcalloc(1, sizeof(genericInt10Priv));
INTPriv(pInt)->alloc = (void *) xnfcalloc(1, ALLOC_ENTRIES(getpagesize()));
pInt->pScrn = pScrn;
base = INTPriv(pInt)->base = xnfalloc(SYS_BIOS);
/* FIXME: Shouldn't this be a failure case? Leaving dev as NULL seems like
* FIXME: an error
*/
pInt->dev = xf86GetPciInfoForEntity(entityIndex);
/*
* we need to map video RAM MMIO as some chipsets map mmio
* registers into this range.
*/
MapVRam(pInt);
#ifdef _PC
if (!sysMem)
pci_device_map_legacy(pInt->dev, V_BIOS, BIOS_SIZE + SYS_BIOS - V_BIOS,
PCI_DEV_MAP_FLAG_WRITABLE, &sysMem);
INTPriv(pInt)->sysMem = sysMem;
if (!readIntVec(pInt->dev, base, LOW_PAGE_SIZE)) {
xf86DrvMsg(pScrn->scrnIndex, X_ERROR, "Cannot read int vect\n");
goto error1;
}
/*
* Retrieve everything between V_BIOS and SYS_BIOS as some system BIOSes
* have executable code there.
*/
memset((char *) base + V_BIOS, 0, SYS_BIOS - V_BIOS);
INTPriv(pInt)->highMemory = V_BIOS;
if (xf86IsEntityPrimary(entityIndex) && !(initPrimary(options))) {
if (!xf86int10GetBiosSegment(pInt, (unsigned char *) sysMem - V_BIOS))
goto error1;
set_return_trap(pInt);
pInt->Flags = Flags & (SET_BIOS_SCRATCH | RESTORE_BIOS_SCRATCH);
if (!(pInt->Flags & SET_BIOS_SCRATCH))
pInt->Flags &= ~RESTORE_BIOS_SCRATCH;
xf86Int10SaveRestoreBIOSVars(pInt, TRUE);
}
else {
const BusType location_type = xf86int10GetBiosLocationType(pInt);
int bios_location = V_BIOS;
reset_int_vect(pInt);
set_return_trap(pInt);
switch (location_type) {
case BUS_PCI:{
int err;
struct pci_device *rom_device =
xf86GetPciInfoForEntity(pInt->entityIndex);
vbiosMem = (unsigned char *) base + bios_location;
err = pci_device_read_rom(rom_device, vbiosMem);
if (err) {
xf86DrvMsg(pScrn->scrnIndex, X_ERROR, "Cannot read V_BIOS (3) %s\n",
strerror(err));
goto error1;
}
INTPriv(pInt)->highMemory = GET_HIGH_BASE(rom_device->rom_size);
break;
}
default:
goto error1;
}
pInt->BIOSseg = V_BIOS >> 4;
pInt->num = 0xe6;
LockLegacyVGA(pInt, &vga);
xf86ExecX86int10(pInt);
UnlockLegacyVGA(pInt, &vga);
}
#else
if (!sysMem) {
sysMem = xnfalloc(BIOS_SIZE);
setup_system_bios(sysMem);
}
INTPriv(pInt)->sysMem = sysMem;
setup_int_vect(pInt);
set_return_trap(pInt);
/* Retrieve the entire legacy video BIOS segment. This can be up to
* 128KiB.
*/
vbiosMem = (char *) base + V_BIOS;
memset(vbiosMem, 0, 2 * V_BIOS_SIZE);
if (pci_device_read_rom(pInt->dev, vbiosMem) != 0
|| pInt->dev->rom_size < V_BIOS_SIZE) {
xf86DrvMsg(pScrn->scrnIndex, X_WARNING,
"Unable to retrieve all of segment 0x0C0000.\n");
}
/*
* If this adapter is the primary, use its post-init BIOS (if we can find
* it).
*/
{
int bios_location = V_BIOS;
Bool done = FALSE;
vbiosMem = (unsigned char *) base + bios_location;
if (xf86IsEntityPrimary(entityIndex)) {
if (int10_check_bios(pScrn->scrnIndex, bios_location >> 4, vbiosMem))
done = TRUE;
else
xf86DrvMsg(pScrn->scrnIndex, X_INFO,
"No legacy BIOS found -- trying PCI\n");
}
if (!done) {
int err;
struct pci_device *rom_device =
xf86GetPciInfoForEntity(pInt->entityIndex);
err = pci_device_read_rom(rom_device, vbiosMem);
if (err) {
xf86DrvMsg(pScrn->scrnIndex, X_ERROR, "Cannot read V_BIOS (5) %s\n",
strerror(err));
goto error1;
}
}
}
pInt->BIOSseg = V_BIOS >> 4;
pInt->num = 0xe6;
LockLegacyVGA(pInt, &vga);
xf86ExecX86int10(pInt);
UnlockLegacyVGA(pInt, &vga);
#endif
free(options);
return pInt;
error1:
free(base);
UnmapVRam(pInt);
free(INTPriv(pInt)->alloc);
free(pInt->private);
error0:
free(pInt);
free(options);
return NULL;
}
static void
MapVRam(xf86Int10InfoPtr pInt)
{
int pagesize = getpagesize();
int size = ((VRAM_SIZE + pagesize - 1) / pagesize) * pagesize;
pci_device_map_legacy(pInt->dev, V_RAM, size, PCI_DEV_MAP_FLAG_WRITABLE,
&(INTPriv(pInt)->vRam));
pInt->io = pci_legacy_open_io(pInt->dev, 0, 64 * 1024);
}
static void
UnmapVRam(xf86Int10InfoPtr pInt)
{
int pagesize = getpagesize();
int size = ((VRAM_SIZE + pagesize - 1) / pagesize) * pagesize;
pci_device_unmap_legacy(pInt->dev, INTPriv(pInt)->vRam, size);
pci_device_close_io(pInt->dev, pInt->io);
pInt->io = NULL;
}
Bool
MapCurrentInt10(xf86Int10InfoPtr pInt)
{
/* nothing to do here */
return TRUE;
}
void
xf86FreeInt10(xf86Int10InfoPtr pInt)
{
if (!pInt)
return;
#if defined (_PC)
xf86Int10SaveRestoreBIOSVars(pInt, FALSE);
#endif
if (Int10Current == pInt)
Int10Current = NULL;
free(INTPriv(pInt)->base);
UnmapVRam(pInt);
free(INTPriv(pInt)->alloc);
free(pInt->private);
free(pInt);
}
void *
xf86Int10AllocPages(xf86Int10InfoPtr pInt, int num, int *off)
{
int pagesize = getpagesize();
int num_pages = ALLOC_ENTRIES(pagesize);
int i, j;
for (i = 0; i < (num_pages - num); i++) {
if (INTPriv(pInt)->alloc[i] == 0) {
for (j = i; j < (num + i); j++)
if (INTPriv(pInt)->alloc[j] != 0)
break;
if (j == (num + i))
break;
i += num;
}
}
if (i == (num_pages - num))
return NULL;
for (j = i; j < (i + num); j++)
INTPriv(pInt)->alloc[j] = 1;
*off = (i + 1) * pagesize;
return (char *) INTPriv(pInt)->base + *off;
}
void
xf86Int10FreePages(xf86Int10InfoPtr pInt, void *pbase, int num)
{
int pagesize = getpagesize();
int first =
(((char *) pbase - (char *) INTPriv(pInt)->base) / pagesize) - 1;
int i;
for (i = first; i < (first + num); i++)
INTPriv(pInt)->alloc[i] = 0;
}
#define OFF(addr) ((addr) & 0xffff)
#if defined _PC
#define HIGH_OFFSET (INTPriv(pInt)->highMemory)
#define HIGH_BASE V_BIOS
#else
#define HIGH_OFFSET SYS_BIOS
#define HIGH_BASE SYS_BIOS
#endif
#define SYS(addr) ((addr) >= HIGH_OFFSET)
#define V_ADDR(addr) \
(SYS(addr) ? ((char*)INTPriv(pInt)->sysMem) + (addr - HIGH_BASE) \
: (((char*)(INTPriv(pInt)->base) + addr)))
#define VRAM_ADDR(addr) (addr - V_RAM)
#define VRAM_BASE (INTPriv(pInt)->vRam)
#define VRAM(addr) ((addr >= V_RAM) && (addr < (V_RAM + VRAM_SIZE)))
#define V_ADDR_RB(addr) \
((VRAM(addr)) ? MMIO_IN8((uint8_t*)VRAM_BASE,VRAM_ADDR(addr)) \
: *(uint8_t*) V_ADDR(addr))
#define V_ADDR_RW(addr) \
((VRAM(addr)) ? MMIO_IN16((uint16_t*)VRAM_BASE,VRAM_ADDR(addr)) \
: ldw_u((void *)V_ADDR(addr)))
#define V_ADDR_RL(addr) \
((VRAM(addr)) ? MMIO_IN32((uint32_t*)VRAM_BASE,VRAM_ADDR(addr)) \
: ldl_u((void *)V_ADDR(addr)))
#define V_ADDR_WB(addr,val) \
if(VRAM(addr)) \
MMIO_OUT8((uint8_t*)VRAM_BASE,VRAM_ADDR(addr),val); \
else \
*(uint8_t*) V_ADDR(addr) = val;
#define V_ADDR_WW(addr,val) \
if(VRAM(addr)) \
MMIO_OUT16((uint16_t*)VRAM_BASE,VRAM_ADDR(addr),val); \
else \
stw_u((val),(void *)(V_ADDR(addr)));
#define V_ADDR_WL(addr,val) \
if (VRAM(addr)) \
MMIO_OUT32((uint32_t*)VRAM_BASE,VRAM_ADDR(addr),val); \
else \
stl_u(val,(void *)(V_ADDR(addr)));
static uint8_t
read_b(xf86Int10InfoPtr pInt, int addr)
{
return V_ADDR_RB(addr);
}
static uint16_t
read_w(xf86Int10InfoPtr pInt, int addr)
{
#if X_BYTE_ORDER == X_LITTLE_ENDIAN
if (OFF(addr + 1) > 0)
return V_ADDR_RW(addr);
#endif
return V_ADDR_RB(addr) | (V_ADDR_RB(addr + 1) << 8);
}
static uint32_t
read_l(xf86Int10InfoPtr pInt, int addr)
{
#if X_BYTE_ORDER == X_LITTLE_ENDIAN
if (OFF(addr + 3) > 2)
return V_ADDR_RL(addr);
#endif
return V_ADDR_RB(addr) |
(V_ADDR_RB(addr + 1) << 8) |
(V_ADDR_RB(addr + 2) << 16) | (V_ADDR_RB(addr + 3) << 24);
}
static void
write_b(xf86Int10InfoPtr pInt, int addr, uint8_t val)
{
V_ADDR_WB(addr, val);
}
static void
write_w(xf86Int10InfoPtr pInt, int addr, CARD16 val)
{
#if X_BYTE_ORDER == X_LITTLE_ENDIAN
if (OFF(addr + 1) > 0) {
V_ADDR_WW(addr, val);
}
#endif
V_ADDR_WB(addr, val);
V_ADDR_WB(addr + 1, val >> 8);
}
static void
write_l(xf86Int10InfoPtr pInt, int addr, uint32_t val)
{
#if X_BYTE_ORDER == X_LITTLE_ENDIAN
if (OFF(addr + 3) > 2) {
V_ADDR_WL(addr, val);
}
#endif
V_ADDR_WB(addr, val);
V_ADDR_WB(addr + 1, val >> 8);
V_ADDR_WB(addr + 2, val >> 16);
V_ADDR_WB(addr + 3, val >> 24);
}
void *
xf86int10Addr(xf86Int10InfoPtr pInt, uint32_t addr)
{
return V_ADDR(addr);
}