board/MAI/bios_emulator/x86interface.c - github/trini/u-boot - Gitiles

 #include "x86emu.h"
 #include "glue.h"


 /*
  * This isn't nice, but there are a lot of incompatibilities in the U-Boot and scitech include
  * files that this is the only really workable solution.
  * Might be cleaned out later.
  */

 #ifdef DEBUG
 #undef DEBUG
 #endif

 #undef IO_LOGGING
 #undef MEM_LOGGING

 #ifdef IO_LOGGING
 #define LOGIO(port, format, args...) if (dolog(port)) _printf(format , ## args)
 #else
 #define LOGIO(port, format, args...)
 #endif

 #ifdef MEM_LOGGIN
 #define LOGMEM(format, args...) _printf(format , ## args)
 #else
 #define LOGMEM(format, args...)
 #endif

 #ifdef DEBUG
 #define PRINTF(format, args...) _printf(format , ## args)
 #else
 #define PRINTF(format, argc...)
 #endif

 typedef unsigned char UBYTE;
 typedef unsigned short UWORD;
 typedef unsigned long ULONG;

 typedef char BYTE;
 typedef short WORT;
 typedef long LONG;

 #define EMULATOR_MEM_SIZE       (1024*1024)
 #define EMULATOR_BIOS_OFFSET    0xC0000
 #define EMULATOR_STRAP_OFFSET   0x30000
 #define EMULATOR_STACK_OFFSET   0x20000
 #define EMULATOR_LOGO_OFFSET    0x40000 // If you change this, change the strap code, too
 #define VIDEO_BASE (void *)0xFD0B8000

 extern char *getenv(char *);
 extern int tstc(void);
 extern int getc(void);
 extern unsigned char video_get_attr(void);

 int atoi(char *string)
 {
     int res = 0;
     while (*string>='0' && *string <='9')
     {
 	res *= 10;
 	res += *string-'0';
 	string++;
     }

     return res;
 }

 void cons_gets(char *buffer)
 {
     int i = 0;
     char c = 0;

     buffer[0] = 0;
     if (getenv("x86_runthru")) return; //FIXME:
     while (c != 0x0D && c != 0x0A)
     {
 	while (!tstc());
 	c = getc();
 	if (c>=32 && c < 127)
 	{
 	    buffer[i] = c;
 	    i++;
 	    buffer[i] = 0;
 	    putc(c);
 	}
 	else
 	{
 	    if (c == 0x08)
 	    {
 		if (i>0) i--;
 		buffer[i] = 0;
 	    }
 	}
     }
     buffer[i] = '\n';
     buffer[i+1] = 0;
 }

 char *bios_date = "08/14/02";
 UBYTE model = 0xFC;
 UBYTE submodel = 0x00;

 static inline UBYTE read_byte(volatile UBYTE* from)
 {
     int x;
     asm volatile ("lbz %0,%1\n eieio" : "=r" (x) : "m" (*from));
     return (UBYTE)x;
 }

 static inline void write_byte(volatile UBYTE *to, int x)
 {
     asm volatile ("stb %1,%0\n eieio" : "=m" (*to) : "r" (x));
 }

 static inline UWORD read_word_little(volatile UWORD *from)
 {
     int x;
     asm volatile ("lhbrx %0,0,%1\n eieio" : "=r" (x) : "r" (from), "m" (*from));
     return (UWORD)x;
 }

 static inline UWORD read_word_big(volatile UWORD *from)
 {
     int x;
     asm volatile ("lhz %0,%1\n eieio" : "=r" (x) : "m" (*from));
     return (UWORD)x;
 }

 static inline void write_word_little(volatile UWORD *to, int x)
 {
     asm volatile ("sthbrx %1,0,%2\n eieio" : "=m" (*to) : "r" (x), "r" (to));
 }

 static inline void write_word_big(volatile UWORD *to, int x)
 {
     asm volatile ("sth %1,%0\n eieio" : "=m" (*to) : "r" (x));
 }

 static inline ULONG read_long_little(volatile ULONG *from)
 {
     unsigned long x;
     asm volatile ("lwbrx %0,0,%1\n eieio" : "=r" (x) : "r" (from), "m"(*from));
     return (ULONG)x;
 }

 static inline ULONG read_long_big(volatile ULONG *from)
 {
     unsigned long x;
     asm volatile ("lwz %0,%1\n eieio" : "=r" (x) : "m" (*from));
     return (ULONG)x;
 }

 static inline void write_long_little(volatile ULONG *to, ULONG x)
 {
     asm volatile ("stwbrx %1,0,%2\n eieio" : "=m" (*to) : "r" (x), "r" (to));
 }

 static inline void write_long_big(volatile ULONG *to, ULONG x)
 {
     asm volatile ("stw %1,%0\n eieio" : "=m" (*to) : "r" (x));
 }

 static int log_init = 0;
 static int log_do = 0;
 static int log_low = 0;

 int dolog(int port)
 {
     if (log_init && log_do)
     {
 	if (log_low && port > 0x400) return 0;
 	return 1;
     }

     if (!log_init)
     {
 	log_init = 1;
 	log_do = (getenv("x86_logio") != (char *)0);
 	log_low = (getenv("x86_loglow") != (char *)0);
 	if (log_do)
 	{
 	    if (log_low && port > 0x400) return 0;
 	    return 1;
 	}
     }
     return 0;
 }

 // Converts an emulator address to a physical address.
 // Handles all special cases (bios date, model etc), and might need work
 u32 memaddr(u32 addr)
 {
 //    if (addr >= 0xF0000 && addr < 0xFFFFF) printf("WARNING: Segment F access (0x%x)\n", addr);
 //    printf("MemAddr=%p\n", addr);
     if (addr >= 0xA0000 && addr < 0xC0000)
 	return 0xFD000000 + addr;
     else if (addr >= 0xFFFF5 && addr < 0xFFFFE)
     {
 	return (u32)bios_date+addr-0xFFFF5;
     }
     else if (addr == 0xFFFFE)
 	return (u32)&model;
     else if (addr == 0xFFFFF)
 	return (u32)&submodel;
     else if (addr >= 0x80000000)
     {
 	//printf("Warning: High memory access at 0x%x\n", addr);
 	return addr;
     }
     else
 	return (u32)M.mem_base+addr;
 }

 u8 A1_rdb(u32 addr)
 {
     u8 a = read_byte((UBYTE *)memaddr(addr));
     LOGMEM("rdb: %x -> %x\n", addr, a);
     return a;
 }

 u16 A1_rdw(u32 addr)
 {
     u16 a = read_word_little((UWORD *)memaddr(addr));
     LOGMEM("rdw: %x -> %x\n", addr, a);
     return a;
 }

 u32 A1_rdl(u32 addr)
 {
     u32 a = read_long_little((ULONG *)memaddr(addr));
     LOGMEM("rdl: %x -> %x\n", addr, a);
     return a;
 }

 void A1_wrb(u32 addr, u8 val)
 {
     LOGMEM("wrb: %x <- %x\n", addr, val);
     write_byte((UBYTE *)memaddr(addr), val);
 }

 void A1_wrw(u32 addr, u16 val)
 {
     LOGMEM("wrw: %x <- %x\n", addr, val);
     write_word_little((UWORD *)memaddr(addr), val);
 }

 void A1_wrl(u32 addr, u32 val)
 {
     LOGMEM("wrl: %x <- %x\n", addr, val);
     write_long_little((ULONG *)memaddr(addr), val);
 }

 X86EMU_memFuncs _A1_mem =
 {
     A1_rdb,
     A1_rdw,
     A1_rdl,
     A1_wrb,
     A1_wrw,
     A1_wrl,
 };

 #define ARTICIAS_PCI_CFGADDR  0xfec00cf8
 #define ARTICIAS_PCI_CFGDATA  0xfee00cfc
 #define IOBASE                0xFE000000

 #define in_byte(from) read_byte( (UBYTE *)port_to_mem(from))
 #define in_word(from) read_word_little((UWORD *)port_to_mem(from))
 #define in_long(from) read_long_little((ULONG *)port_to_mem(from))
 #define out_byte(to, val) write_byte((UBYTE *)port_to_mem(to), val)
 #define out_word(to, val) write_word_little((UWORD *)port_to_mem(to), val)
 #define out_long(to, val) write_long_little((ULONG *)port_to_mem(to), val)

 u32 port_to_mem(int port)
 {
     if (port >= 0xCFC && port <= 0xCFF) return 0xFEE00000+port;
     else if (port >= 0xCF8 && port <= 0xCFB) return 0xFEC00000+port;
     else return IOBASE + port;
 }

 u8 A1_inb(int port)
 {
     u8 a;
     //if (port == 0x3BA) return 0;
     a = in_byte(port);
     LOGIO(port, "inb: %Xh -> %d (%Xh)\n", port, a, a);
     return a;
 }

 u16 A1_inw(int port)
 {
     u16 a = in_word(port);
     LOGIO(port, "inw: %Xh -> %d (%Xh)\n", port, a, a);
     return a;
 }

 u32 A1_inl(int port)
 {
     u32 a = in_long(port);
     LOGIO(port, "inl: %Xh -> %d (%Xh)\n", port, a, a);
     return a;
 }

 void A1_outb(int port, u8 val)
 {
     LOGIO(port, "outb: %Xh <- %d (%Xh)\n", port, val, val);
 /*    if (port == 0xCF8) port = 0xCFB;
     else if (port == 0xCF9) port = 0xCFA;
     else if (port == 0xCFA) port = 0xCF9;
     else if (port == 0xCFB) port = 0xCF8;*/
     out_byte(port, val);
 }

 void A1_outw(int port, u16 val)
 {
     LOGIO(port, "outw: %Xh <- %d (%Xh)\n", port, val, val);
     out_word(port, val);
 }

 void A1_outl(int port, u32 val)
 {
     LOGIO(port, "outl: %Xh <- %d (%Xh)\n", port, val, val);
     out_long(port, val);
 }

 X86EMU_pioFuncs _A1_pio =
 {
     A1_inb,
     A1_inw,
     A1_inl,
     A1_outb,
     A1_outw,
     A1_outl,
 };

 static int reloced_ops = 0;

 void reloc_ops(void *reloc_addr)
 {
     extern void (*x86emu_optab[256])(u8);
     extern void (*x86emu_optab2[256])(u8);
     extern void tables_relocate(unsigned int offset);
     int i;
     unsigned long delta;
     if (reloced_ops == 1) return;
     reloced_ops = 1;

     delta = TEXT_BASE - (unsigned long)reloc_addr;

     for (i=0; i<256; i++)
     {
 	x86emu_optab[i] -= delta;
 	x86emu_optab2[i] -= delta;
     }

     _A1_mem.rdb = A1_rdb;
     _A1_mem.rdw = A1_rdw;
     _A1_mem.rdl = A1_rdl;
     _A1_mem.wrb = A1_wrb;
     _A1_mem.wrw = A1_wrw;
     _A1_mem.wrl = A1_wrl;

     _A1_pio.inb = A1_inb;
     _A1_pio.inw = A1_inw;
     _A1_pio.inl = A1_inl;
     _A1_pio.outb = A1_outb;
     _A1_pio.outw = A1_outw;
     _A1_pio.outl = A1_outl;

     tables_relocate(delta);

 }


 #define ANY_KEY(text)				\
     printf(text);				\
     while (!tstc());


 unsigned char more_strap[] = {
         0xb4, 0x0, 0xb0, 0x2, 0xcd, 0x10,
 };
 #define MORE_STRAP_BYTES 6 // Additional bytes of strap code


 unsigned char *done_msg="VGA Initialized\0";

 int execute_bios(pci_dev_t gr_dev, void *reloc_addr)
 {
     extern void bios_init(void);
     extern void remove_init_data(void);
     extern int video_rows(void);
     extern int video_cols(void);
     extern int video_size(int, int);
     u8 *strap;
     unsigned char *logo;
     u8 cfg;
     int i;
     char c;
 #ifdef DEBUG
     char *s;
 #endif
 #ifdef EASTEREGG
     int easteregg_active = 0;
 #endif
     char *pal_reset;
     u8 *fb;
     unsigned char *msg;
     unsigned char current_attr;

     remove_init_data();
     PRINTF("Removed init data from cache, now in RAM\n");

     reloc_ops(reloc_addr);
     PRINTF("Attempting to run emulator on %02x:%02x:%02x\n",
 	   PCI_BUS(gr_dev), PCI_DEV(gr_dev), PCI_FUNC(gr_dev));

     // Enable compatibility hole for emulator access to frame buffer
     PRINTF("Enabling compatibility hole\n");
     enable_compatibility_hole();

     // Allocate memory
     // FIXME: We shouldn't use this much memory really.
     memset(&M, 0, sizeof(X86EMU_sysEnv));
     M.mem_base = malloc(EMULATOR_MEM_SIZE);
     M.mem_size = EMULATOR_MEM_SIZE;

     if (!M.mem_base)
     {
 	PRINTF("Unable to allocate one megabyte for emulator\n");
 	return 0;
     }

     if (attempt_map_rom(gr_dev, M.mem_base + EMULATOR_BIOS_OFFSET) == 0)
     {
 	PRINTF("Error mapping rom. Emulation terminated\n");
 	return 0;
     }

 #ifdef DEBUG
     s = getenv("x86_ask_start");
     if (s)
     {
 	printf("Press 'q' to skip initialization, 'd' for dry init\n'i' for i/o session");
 	while (!tstc());
 	c = getc();
 	if (c == 'q') return 0;
 	if (c == 'd')
 	{
 	    extern void bios_set_mode(int mode);
 	    bios_set_mode(0x03);
 	    return 0;
 	}
 	if (c == 'i') do_inout();
     }


 #endif

 #ifdef EASTEREGG
 /*    if (tstc())
     {
 	if (getc() == 'c')
 	{
 	    easteregg_active = 1;
 	}
     }
 */
     if (getenv("easteregg"))
     {
 	easteregg_active = 1;
     }

     if (easteregg_active)
     {
 	// Yay!
 	setenv("x86_mode", "1");
 	setenv("vga_fg_color", "11");
 	setenv("vga_bg_color", "1");
 	easteregg_active = 1;
     }
 #endif

     strap = (u8*)M.mem_base + EMULATOR_STRAP_OFFSET;

     {
 	char *m = getenv("x86_mode");
 	if (m)
 	{
 	    more_strap[3] = atoi(m);
 	    if (more_strap[3] == 1) video_size(40, 25);
 	    else                    video_size(80, 25);
 	}
     }

     /*
      * Poke the strap routine. This might need a bit of extending
      * if there is a mode switch involved, i.e. we want to int10
      * afterwards to set a different graphics mode, or alternatively
      * there might be a different start address requirement if the
      * ROM doesn't have an x86 image in its first image.
      */

     PRINTF("Poking strap...\n");

     // FAR CALL c000:0003
     *strap++ = 0x9A; *strap++ = 0x03; *strap++ = 0x00;
     *strap++ = 0x00; *strap++ = 0xC0;

 #if 1
     // insert additional strap code
     for (i=0; i < MORE_STRAP_BYTES; i++)
     {
 	*strap++ = more_strap[i];
     }
 #endif
     // HALT
     *strap++ = 0xF4;

     PRINTF("Setting up logo data\n");
     logo = (unsigned char *)M.mem_base + EMULATOR_LOGO_OFFSET;
     for (i=0; i<16; i++)
     {
 	*logo++ = 0xFF;
     }

     /*
      * Setup the init parameters.
      * Per PCI specs, AH must contain the bus and AL
      * must contain the devfn, encoded as (dev<<3)|fn
      */

     // Execution starts here
     M.x86.R_CS = SEG(EMULATOR_STRAP_OFFSET);
     M.x86.R_IP = OFF(EMULATOR_STRAP_OFFSET);

     // Stack at top of ram
     M.x86.R_SS = SEG(EMULATOR_STACK_OFFSET);
     M.x86.R_SP = OFF(EMULATOR_STACK_OFFSET);

     // Input parameters
     M.x86.R_AH = PCI_BUS(gr_dev);
     M.x86.R_AL = (PCI_DEV(gr_dev)<<3) | PCI_FUNC(gr_dev);

     // Set the I/O and memory access functions
     X86EMU_setupMemFuncs(&_A1_mem);
     X86EMU_setupPioFuncs(&_A1_pio);

     // Enable timer 2
     cfg = in_byte(0x61); // Get Misc control
     cfg |= 0x01;         // Enable timer 2
     out_byte(0x61, cfg); // output again

     // Set up the timers
     out_byte(0x43, 0x54);
     out_byte(0x41, 0x18);

     out_byte(0x43, 0x36);
     out_byte(0x40, 0x00);
     out_byte(0x40, 0x00);

     out_byte(0x43, 0xb6);
     out_byte(0x42, 0x31);
     out_byte(0x42, 0x13);

     // Init the "BIOS".
     bios_init();

     // Video Card Reset
     out_byte(0x3D8, 0);
     out_byte(0x3B8, 1);
     (void)in_byte(0x3BA);
     (void)in_byte(0x3DA);
     out_byte(0x3C0, 0);
     out_byte(0x61, 0xFC);

 #ifdef DEBUG
     s = _getenv("x86_singlestep");
     if (s && strcmp(s, "on")==0)
     {
 	PRINTF("Enabling single stepping for debug\n");
 	X86EMU_trace_on();
     }
 #endif

     // Ready set go...
     PRINTF("Running emulator\n");
     X86EMU_exec();
     PRINTF("Done running emulator\n");

 /* FIXME: Remove me */
     pal_reset = getenv("x86_palette_reset");
     if (pal_reset && strcmp(pal_reset, "on") == 0)
     {
 	PRINTF("Palette reset\n");
 	//(void)in_byte(0x3da);
 	//out_byte(0x3c0, 0);

 	out_byte(0x3C8, 0);
 	out_byte(0x3C9, 0);
 	out_byte(0x3C9, 0);
 	out_byte(0x3C9, 0);
 	for (i=0; i<254; i++)
 	{
 	    out_byte(0x3C9, 63);
 	    out_byte(0x3C9, 63);
 	    out_byte(0x3C9, 63);
 	}

 	out_byte(0x3c0, 0x20);
     }
 /* FIXME: remove me */
 #ifdef EASTEREGG
     if (easteregg_active)
     {
 	extern void video_easteregg(void);
 	video_easteregg();
     }
 #endif
 /*
     current_attr = video_get_attr();
     fb = (u8 *)VIDEO_BASE;
     for (i=0; i<video_rows()*video_cols()*2; i+=2)
     {
 	*(fb+i) = ' ';
 	*(fb+i+1) = current_attr;
     }

     fb = (u8 *)VIDEO_BASE + (video_rows())-1*(video_cols()*2);
     for (i=0; i<video_cols(); i++)
     {
 	*(fb + 2*i)     = 32;
 	*(fb + 2*i + 1) = 0x17;
     }

     msg = done_msg;
     while (*msg)
     {
 	*fb = *msg;
 	fb  += 2;
 	msg ++;
     }
 */
 #ifdef DEBUG
     if (getenv("x86_do_inout")) do_inout();
 #endif

     dcache_disable();
     return 1;
 }

 // Clean up the x86 mess
 void shutdown_bios(void)
 {
 //    disable_compatibility_hole();
     // Free the memory associated
     free(M.mem_base);

 }

 int to_int(char *buffer)
 {
     int base = 0;
     int res  = 0;

     if (*buffer == '$')
     {
 	base = 16;
 	buffer++;
     }
     else base = 10;

     for (;;)
     {
 	switch(*buffer)
 	{
 	case '0' ... '9':
 	    res *= base;
 	    res += *buffer - '0';
 	    break;
 	case 'A':
 	case 'a':
 	    res *= base;
 	    res += 10;
 	    break;
 	case 'B':
 	case 'b':
 	    res *= base;
 	    res += 11;
 	    break;
 	case 'C':
 	case 'c':
 	    res *= base;
 	    res += 12;
 	    break;
 	case 'D':
 	case 'd':
 	    res *= base;
 	    res += 13;
 	    break;
 	case 'E':
 	case 'e':
 	    res *= base;
 	    res += 14;
 	    break;
 	case 'F':
 	case 'f':
 	    res *= base;
 	    res += 15;
 	    break;
 	default:
 	    return res;
 	}
 	buffer++;
     }
     return res;
 }

 void one_arg(char *buffer, int *a)
 {
     while (*buffer && *buffer != '\n')
     {
 	if (*buffer == ' ') buffer++;
 	else break;
     }

     *a = to_int(buffer);
 }

 void two_args(char *buffer, int *a, int *b)
 {
     while (*buffer && *buffer != '\n')
     {
 	if (*buffer == ' ') buffer++;
 	else break;
     }

     *a = to_int(buffer);

     while (*buffer && *buffer != '\n')
     {
 	if (*buffer != ' ') buffer++;
 	else break;
     }

     while (*buffer && *buffer != '\n')
     {
 	if (*buffer == ' ') buffer++;
 	else break;
     }

     *b = to_int(buffer);
 }

 void do_inout(void)
 {
     char buffer[256];
     char *arg1, *arg2;
     int a,b;

     printf("In/Out Session\nUse 'i[bwl]' for in, 'o[bwl]' for out and 'q' to quit\n");

     do
     {
 	cons_gets(buffer);
 	printf("\n");

 	*arg1 = buffer;
 	while (*arg1 != ' ' ) arg1++;
 	while (*arg1 == ' ') arg1++;

 	if (buffer[0] == 'i')
 	{
 	    one_arg(buffer+2, &a);
 	    switch (buffer[1])
 	    {
 	    case 'b':
 		printf("in_byte(%xh) = %xh\n", a, A1_inb(a));
 		break;
 	    case 'w':
 		printf("in_word(%xh) = %xh\n", a, A1_inw(a));
 		break;
 	    case 'l':
 		printf("in_dword(%xh) = %xh\n", a, A1_inl(a));
 		break;
 	    default:
 		printf("Invalid length '%c'\n", buffer[1]);
 		break;
 	    }
 	}
 	else if (buffer[0] == 'o')
 	{
 	    two_args(buffer+2, &a, &b);
 	    switch (buffer[1])
 	    {
 	    case 'b':
 		printf("out_byte(%d, %d)\n", a, b);
 		A1_outb(a,b);
 		break;
 	    case 'w':
 		printf("out_word(%d, %d)\n", a, b);
 		A1_outw(a, b);
 		break;
 	    case 'l':
 		printf("out_long(%d, %d)\n", a, b);
 		A1_outl(a, b);
 		break;
 	    default:
 		printf("Invalid length '%c'\n", buffer[1]);
 		break;
 	    }
 	} else if (buffer[0] == 'q') return;
     } while (1);
 }
	#include "x86emu.h"
	#include "glue.h"


	/*
	* This isn't nice, but there are a lot of incompatibilities in the U-Boot and scitech include
	* files that this is the only really workable solution.
	* Might be cleaned out later.
	*/

	#ifdef DEBUG
	#undef DEBUG
	#endif

	#undef IO_LOGGING
	#undef MEM_LOGGING

	#ifdef IO_LOGGING
	#define LOGIO(port, format, args...) if (dolog(port)) _printf(format , ## args)
	#else
	#define LOGIO(port, format, args...)
	#endif

	#ifdef MEM_LOGGIN
	#define LOGMEM(format, args...) _printf(format , ## args)
	#else
	#define LOGMEM(format, args...)
	#endif

	#ifdef DEBUG
	#define PRINTF(format, args...) _printf(format , ## args)
	#else
	#define PRINTF(format, argc...)
	#endif

	typedef unsigned char UBYTE;
	typedef unsigned short UWORD;
	typedef unsigned long ULONG;

	typedef char BYTE;
	typedef short WORT;
	typedef long LONG;

	#define EMULATOR_MEM_SIZE (1024*1024)
	#define EMULATOR_BIOS_OFFSET 0xC0000
	#define EMULATOR_STRAP_OFFSET 0x30000
	#define EMULATOR_STACK_OFFSET 0x20000
	#define EMULATOR_LOGO_OFFSET 0x40000 // If you change this, change the strap code, too
	#define VIDEO_BASE (void *)0xFD0B8000

	extern char getenv(char );
	extern int tstc(void);
	extern int getc(void);
	extern unsigned char video_get_attr(void);

	int atoi(char *string)
	{
	int res = 0;
	while (string>='0' && string <='9')
	{
	res *= 10;
	res += *string-'0';
	string++;
	}

	return res;
	}

	void cons_gets(char *buffer)
	{
	int i = 0;
	char c = 0;

	buffer[0] = 0;
	if (getenv("x86_runthru")) return; //FIXME:
	while (c != 0x0D && c != 0x0A)
	{
	while (!tstc());
	c = getc();
	if (c>=32 && c < 127)
	{
	buffer[i] = c;
	i++;
	buffer[i] = 0;
	putc(c);
	}
	else
	{
	if (c == 0x08)
	{
	if (i>0) i--;
	buffer[i] = 0;
	}
	}
	}
	buffer[i] = '\n';
	buffer[i+1] = 0;
	}

	char *bios_date = "08/14/02";
	UBYTE model = 0xFC;
	UBYTE submodel = 0x00;

	static inline UBYTE read_byte(volatile UBYTE* from)
	{
	int x;
	asm volatile ("lbz %0,%1\n eieio" : "=r" (x) : "m" (*from));
	return (UBYTE)x;
	}

	static inline void write_byte(volatile UBYTE *to, int x)
	{
	asm volatile ("stb %1,%0\n eieio" : "=m" (*to) : "r" (x));
	}

	static inline UWORD read_word_little(volatile UWORD *from)
	{
	int x;
	asm volatile ("lhbrx %0,0,%1\n eieio" : "=r" (x) : "r" (from), "m" (*from));
	return (UWORD)x;
	}

	static inline UWORD read_word_big(volatile UWORD *from)
	{
	int x;
	asm volatile ("lhz %0,%1\n eieio" : "=r" (x) : "m" (*from));
	return (UWORD)x;
	}

	static inline void write_word_little(volatile UWORD *to, int x)
	{
	asm volatile ("sthbrx %1,0,%2\n eieio" : "=m" (*to) : "r" (x), "r" (to));
	}

	static inline void write_word_big(volatile UWORD *to, int x)
	{
	asm volatile ("sth %1,%0\n eieio" : "=m" (*to) : "r" (x));
	}

	static inline ULONG read_long_little(volatile ULONG *from)
	{
	unsigned long x;
	asm volatile ("lwbrx %0,0,%1\n eieio" : "=r" (x) : "r" (from), "m"(*from));
	return (ULONG)x;
	}

	static inline ULONG read_long_big(volatile ULONG *from)
	{
	unsigned long x;
	asm volatile ("lwz %0,%1\n eieio" : "=r" (x) : "m" (*from));
	return (ULONG)x;
	}

	static inline void write_long_little(volatile ULONG *to, ULONG x)
	{
	asm volatile ("stwbrx %1,0,%2\n eieio" : "=m" (*to) : "r" (x), "r" (to));
	}

	static inline void write_long_big(volatile ULONG *to, ULONG x)
	{
	asm volatile ("stw %1,%0\n eieio" : "=m" (*to) : "r" (x));
	}

	static int log_init = 0;
	static int log_do = 0;
	static int log_low = 0;

	int dolog(int port)
	{
	if (log_init && log_do)
	{
	if (log_low && port > 0x400) return 0;
	return 1;
	}

	if (!log_init)
	{
	log_init = 1;
	log_do = (getenv("x86_logio") != (char *)0);
	log_low = (getenv("x86_loglow") != (char *)0);
	if (log_do)
	{
	if (log_low && port > 0x400) return 0;
	return 1;
	}
	}
	return 0;
	}

	// Converts an emulator address to a physical address.
	// Handles all special cases (bios date, model etc), and might need work
	u32 memaddr(u32 addr)
	{
	// if (addr >= 0xF0000 && addr < 0xFFFFF) printf("WARNING: Segment F access (0x%x)\n", addr);
	// printf("MemAddr=%p\n", addr);
	if (addr >= 0xA0000 && addr < 0xC0000)
	return 0xFD000000 + addr;
	else if (addr >= 0xFFFF5 && addr < 0xFFFFE)
	{
	return (u32)bios_date+addr-0xFFFF5;
	}
	else if (addr == 0xFFFFE)
	return (u32)&model;
	else if (addr == 0xFFFFF)
	return (u32)&submodel;
	else if (addr >= 0x80000000)
	{
	//printf("Warning: High memory access at 0x%x\n", addr);
	return addr;
	}
	else
	return (u32)M.mem_base+addr;
	}

	u8 A1_rdb(u32 addr)
	{
	u8 a = read_byte((UBYTE *)memaddr(addr));
	LOGMEM("rdb: %x -> %x\n", addr, a);
	return a;
	}

	u16 A1_rdw(u32 addr)
	{
	u16 a = read_word_little((UWORD *)memaddr(addr));
	LOGMEM("rdw: %x -> %x\n", addr, a);
	return a;
	}

	u32 A1_rdl(u32 addr)
	{
	u32 a = read_long_little((ULONG *)memaddr(addr));
	LOGMEM("rdl: %x -> %x\n", addr, a);
	return a;
	}

	void A1_wrb(u32 addr, u8 val)
	{
	LOGMEM("wrb: %x <- %x\n", addr, val);
	write_byte((UBYTE *)memaddr(addr), val);
	}

	void A1_wrw(u32 addr, u16 val)
	{
	LOGMEM("wrw: %x <- %x\n", addr, val);
	write_word_little((UWORD *)memaddr(addr), val);
	}

	void A1_wrl(u32 addr, u32 val)
	{
	LOGMEM("wrl: %x <- %x\n", addr, val);
	write_long_little((ULONG *)memaddr(addr), val);
	}

	X86EMU_memFuncs _A1_mem =
	{
	A1_rdb,
	A1_rdw,
	A1_rdl,
	A1_wrb,
	A1_wrw,
	A1_wrl,
	};

	#define ARTICIAS_PCI_CFGADDR 0xfec00cf8
	#define ARTICIAS_PCI_CFGDATA 0xfee00cfc
	#define IOBASE 0xFE000000

	#define in_byte(from) read_byte( (UBYTE *)port_to_mem(from))
	#define in_word(from) read_word_little((UWORD *)port_to_mem(from))
	#define in_long(from) read_long_little((ULONG *)port_to_mem(from))
	#define out_byte(to, val) write_byte((UBYTE *)port_to_mem(to), val)
	#define out_word(to, val) write_word_little((UWORD *)port_to_mem(to), val)
	#define out_long(to, val) write_long_little((ULONG *)port_to_mem(to), val)

	u32 port_to_mem(int port)
	{
	if (port >= 0xCFC && port <= 0xCFF) return 0xFEE00000+port;
	else if (port >= 0xCF8 && port <= 0xCFB) return 0xFEC00000+port;
	else return IOBASE + port;
	}

	u8 A1_inb(int port)
	{
	u8 a;
	//if (port == 0x3BA) return 0;
	a = in_byte(port);
	LOGIO(port, "inb: %Xh -> %d (%Xh)\n", port, a, a);
	return a;
	}

	u16 A1_inw(int port)
	{
	u16 a = in_word(port);
	LOGIO(port, "inw: %Xh -> %d (%Xh)\n", port, a, a);
	return a;
	}

	u32 A1_inl(int port)
	{
	u32 a = in_long(port);
	LOGIO(port, "inl: %Xh -> %d (%Xh)\n", port, a, a);
	return a;
	}

	void A1_outb(int port, u8 val)
	{
	LOGIO(port, "outb: %Xh <- %d (%Xh)\n", port, val, val);
	/* if (port == 0xCF8) port = 0xCFB;
	else if (port == 0xCF9) port = 0xCFA;
	else if (port == 0xCFA) port = 0xCF9;
	else if (port == 0xCFB) port = 0xCF8;*/
	out_byte(port, val);
	}

	void A1_outw(int port, u16 val)
	{
	LOGIO(port, "outw: %Xh <- %d (%Xh)\n", port, val, val);
	out_word(port, val);
	}

	void A1_outl(int port, u32 val)
	{
	LOGIO(port, "outl: %Xh <- %d (%Xh)\n", port, val, val);
	out_long(port, val);
	}

	X86EMU_pioFuncs _A1_pio =
	{
	A1_inb,
	A1_inw,
	A1_inl,
	A1_outb,
	A1_outw,
	A1_outl,
	};

	static int reloced_ops = 0;

	void reloc_ops(void *reloc_addr)
	{
	extern void (*x86emu_optab[256])(u8);
	extern void (*x86emu_optab2[256])(u8);
	extern void tables_relocate(unsigned int offset);
	int i;
	unsigned long delta;
	if (reloced_ops == 1) return;
	reloced_ops = 1;

	delta = TEXT_BASE - (unsigned long)reloc_addr;

	for (i=0; i<256; i++)
	{
	x86emu_optab[i] -= delta;
	x86emu_optab2[i] -= delta;
	}

	_A1_mem.rdb = A1_rdb;
	_A1_mem.rdw = A1_rdw;
	_A1_mem.rdl = A1_rdl;
	_A1_mem.wrb = A1_wrb;
	_A1_mem.wrw = A1_wrw;
	_A1_mem.wrl = A1_wrl;

	_A1_pio.inb = A1_inb;
	_A1_pio.inw = A1_inw;
	_A1_pio.inl = A1_inl;
	_A1_pio.outb = A1_outb;
	_A1_pio.outw = A1_outw;
	_A1_pio.outl = A1_outl;

	tables_relocate(delta);

	}


	#define ANY_KEY(text) \
	printf(text); \
	while (!tstc());


	unsigned char more_strap[] = {
	0xb4, 0x0, 0xb0, 0x2, 0xcd, 0x10,
	};
	#define MORE_STRAP_BYTES 6 // Additional bytes of strap code


	unsigned char *done_msg="VGA Initialized\0";

	int execute_bios(pci_dev_t gr_dev, void *reloc_addr)
	{
	extern void bios_init(void);
	extern void remove_init_data(void);
	extern int video_rows(void);
	extern int video_cols(void);
	extern int video_size(int, int);
	u8 *strap;
	unsigned char *logo;
	u8 cfg;
	int i;
	char c;
	#ifdef DEBUG
	char *s;
	#endif
	#ifdef EASTEREGG
	int easteregg_active = 0;
	#endif
	char *pal_reset;
	u8 *fb;
	unsigned char *msg;
	unsigned char current_attr;

	remove_init_data();
	PRINTF("Removed init data from cache, now in RAM\n");

	reloc_ops(reloc_addr);
	PRINTF("Attempting to run emulator on %02x:%02x:%02x\n",
	PCI_BUS(gr_dev), PCI_DEV(gr_dev), PCI_FUNC(gr_dev));

	// Enable compatibility hole for emulator access to frame buffer
	PRINTF("Enabling compatibility hole\n");
	enable_compatibility_hole();

	// Allocate memory
	// FIXME: We shouldn't use this much memory really.
	memset(&M, 0, sizeof(X86EMU_sysEnv));
	M.mem_base = malloc(EMULATOR_MEM_SIZE);
	M.mem_size = EMULATOR_MEM_SIZE;

	if (!M.mem_base)
	{
	PRINTF("Unable to allocate one megabyte for emulator\n");
	return 0;
	}

	if (attempt_map_rom(gr_dev, M.mem_base + EMULATOR_BIOS_OFFSET) == 0)
	{
	PRINTF("Error mapping rom. Emulation terminated\n");
	return 0;
	}

	#ifdef DEBUG
	s = getenv("x86_ask_start");
	if (s)
	{
	printf("Press 'q' to skip initialization, 'd' for dry init\n'i' for i/o session");
	while (!tstc());
	c = getc();
	if (c == 'q') return 0;
	if (c == 'd')
	{
	extern void bios_set_mode(int mode);
	bios_set_mode(0x03);
	return 0;
	}
	if (c == 'i') do_inout();
	}


	#endif

	#ifdef EASTEREGG
	/* if (tstc())
	{
	if (getc() == 'c')
	{
	easteregg_active = 1;
	}
	}
	*/
	if (getenv("easteregg"))
	{
	easteregg_active = 1;
	}

	if (easteregg_active)
	{
	// Yay!
	setenv("x86_mode", "1");
	setenv("vga_fg_color", "11");
	setenv("vga_bg_color", "1");
	easteregg_active = 1;
	}
	#endif

	strap = (u8*)M.mem_base + EMULATOR_STRAP_OFFSET;

	{
	char *m = getenv("x86_mode");
	if (m)
	{
	more_strap[3] = atoi(m);
	if (more_strap[3] == 1) video_size(40, 25);
	else video_size(80, 25);
	}
	}

	/*
	* Poke the strap routine. This might need a bit of extending
	* if there is a mode switch involved, i.e. we want to int10
	* afterwards to set a different graphics mode, or alternatively
	* there might be a different start address requirement if the
	* ROM doesn't have an x86 image in its first image.
	*/

	PRINTF("Poking strap...\n");

	// FAR CALL c000:0003
	strap++ = 0x9A; strap++ = 0x03; *strap++ = 0x00;
	strap++ = 0x00; strap++ = 0xC0;

	#if 1
	// insert additional strap code
	for (i=0; i < MORE_STRAP_BYTES; i++)
	{
	*strap++ = more_strap[i];
	}
	#endif
	// HALT
	*strap++ = 0xF4;

	PRINTF("Setting up logo data\n");
	logo = (unsigned char *)M.mem_base + EMULATOR_LOGO_OFFSET;
	for (i=0; i<16; i++)
	{
	*logo++ = 0xFF;
	}

	/*
	* Setup the init parameters.
	* Per PCI specs, AH must contain the bus and AL
	* must contain the devfn, encoded as (dev<<3)\|fn
	*/

	// Execution starts here
	M.x86.R_CS = SEG(EMULATOR_STRAP_OFFSET);
	M.x86.R_IP = OFF(EMULATOR_STRAP_OFFSET);

	// Stack at top of ram
	M.x86.R_SS = SEG(EMULATOR_STACK_OFFSET);
	M.x86.R_SP = OFF(EMULATOR_STACK_OFFSET);

	// Input parameters
	M.x86.R_AH = PCI_BUS(gr_dev);
	M.x86.R_AL = (PCI_DEV(gr_dev)<<3) \| PCI_FUNC(gr_dev);

	// Set the I/O and memory access functions
	X86EMU_setupMemFuncs(&_A1_mem);
	X86EMU_setupPioFuncs(&_A1_pio);

	// Enable timer 2
	cfg = in_byte(0x61); // Get Misc control
	cfg \|= 0x01; // Enable timer 2
	out_byte(0x61, cfg); // output again

	// Set up the timers
	out_byte(0x43, 0x54);
	out_byte(0x41, 0x18);

	out_byte(0x43, 0x36);
	out_byte(0x40, 0x00);
	out_byte(0x40, 0x00);

	out_byte(0x43, 0xb6);
	out_byte(0x42, 0x31);
	out_byte(0x42, 0x13);

	// Init the "BIOS".
	bios_init();

	// Video Card Reset
	out_byte(0x3D8, 0);
	out_byte(0x3B8, 1);
	(void)in_byte(0x3BA);
	(void)in_byte(0x3DA);
	out_byte(0x3C0, 0);
	out_byte(0x61, 0xFC);

	#ifdef DEBUG
	s = _getenv("x86_singlestep");
	if (s && strcmp(s, "on")==0)
	{
	PRINTF("Enabling single stepping for debug\n");
	X86EMU_trace_on();
	}
	#endif

	// Ready set go...
	PRINTF("Running emulator\n");
	X86EMU_exec();
	PRINTF("Done running emulator\n");

	/* FIXME: Remove me */
	pal_reset = getenv("x86_palette_reset");
	if (pal_reset && strcmp(pal_reset, "on") == 0)
	{
	PRINTF("Palette reset\n");
	//(void)in_byte(0x3da);
	//out_byte(0x3c0, 0);

	out_byte(0x3C8, 0);
	out_byte(0x3C9, 0);
	out_byte(0x3C9, 0);
	out_byte(0x3C9, 0);
	for (i=0; i<254; i++)
	{
	out_byte(0x3C9, 63);
	out_byte(0x3C9, 63);
	out_byte(0x3C9, 63);
	}

	out_byte(0x3c0, 0x20);
	}
	/* FIXME: remove me */
	#ifdef EASTEREGG
	if (easteregg_active)
	{
	extern void video_easteregg(void);
	video_easteregg();
	}
	#endif
	/*
	current_attr = video_get_attr();
	fb = (u8 *)VIDEO_BASE;
	for (i=0; i<video_rows()video_cols()2; i+=2)
	{
	*(fb+i) = ' ';
	*(fb+i+1) = current_attr;
	}

	fb = (u8 )VIDEO_BASE + (video_rows())-1(video_cols()*2);
	for (i=0; i<video_cols(); i++)
	{
	(fb + 2i) = 32;
	(fb + 2i + 1) = 0x17;
	}

	msg = done_msg;
	while (*msg)
	{
	fb = msg;
	fb += 2;
	msg ++;
	}
	*/
	#ifdef DEBUG
	if (getenv("x86_do_inout")) do_inout();
	#endif

	dcache_disable();
	return 1;
	}

	// Clean up the x86 mess
	void shutdown_bios(void)
	{
	// disable_compatibility_hole();
	// Free the memory associated
	free(M.mem_base);

	}

	int to_int(char *buffer)
	{
	int base = 0;
	int res = 0;

	if (*buffer == '$')
	{
	base = 16;
	buffer++;
	}
	else base = 10;

	for (;;)
	{
	switch(*buffer)
	{
	case '0' ... '9':
	res *= base;
	res += *buffer - '0';
	break;
	case 'A':
	case 'a':
	res *= base;
	res += 10;
	break;
	case 'B':
	case 'b':
	res *= base;
	res += 11;
	break;
	case 'C':
	case 'c':
	res *= base;
	res += 12;
	break;
	case 'D':
	case 'd':
	res *= base;
	res += 13;
	break;
	case 'E':
	case 'e':
	res *= base;
	res += 14;
	break;
	case 'F':
	case 'f':
	res *= base;
	res += 15;
	break;
	default:
	return res;
	}
	buffer++;
	}
	return res;
	}

	void one_arg(char buffer, int a)
	{
	while (buffer && buffer != '\n')
	{
	if (*buffer == ' ') buffer++;
	else break;
	}

	*a = to_int(buffer);
	}

	void two_args(char buffer, int a, int *b)
	{
	while (buffer && buffer != '\n')
	{
	if (*buffer == ' ') buffer++;
	else break;
	}

	*a = to_int(buffer);

	while (buffer && buffer != '\n')
	{
	if (*buffer != ' ') buffer++;
	else break;
	}

	while (buffer && buffer != '\n')
	{
	if (*buffer == ' ') buffer++;
	else break;
	}

	*b = to_int(buffer);
	}

	void do_inout(void)
	{
	char buffer[256];
	char arg1, arg2;
	int a,b;

	printf("In/Out Session\nUse 'i[bwl]' for in, 'o[bwl]' for out and 'q' to quit\n");

	do
	{
	cons_gets(buffer);
	printf("\n");

	*arg1 = buffer;
	while (*arg1 != ' ' ) arg1++;
	while (*arg1 == ' ') arg1++;

	if (buffer[0] == 'i')
	{
	one_arg(buffer+2, &a);
	switch (buffer[1])
	{
	case 'b':
	printf("in_byte(%xh) = %xh\n", a, A1_inb(a));
	break;
	case 'w':
	printf("in_word(%xh) = %xh\n", a, A1_inw(a));
	break;
	case 'l':
	printf("in_dword(%xh) = %xh\n", a, A1_inl(a));
	break;
	default:
	printf("Invalid length '%c'\n", buffer[1]);
	break;
	}
	}
	else if (buffer[0] == 'o')
	{
	two_args(buffer+2, &a, &b);
	switch (buffer[1])
	{
	case 'b':
	printf("out_byte(%d, %d)\n", a, b);
	A1_outb(a,b);
	break;
	case 'w':
	printf("out_word(%d, %d)\n", a, b);
	A1_outw(a, b);
	break;
	case 'l':
	printf("out_long(%d, %d)\n", a, b);
	A1_outl(a, b);
	break;
	default:
	printf("Invalid length '%c'\n", buffer[1]);
	break;
	}
	} else if (buffer[0] == 'q') return;
	} while (1);
	}