src/post.c - seabios - Gitiles

 // 32bit code to Power On Self Test (POST) a machine.
 //
 // Copyright (C) 2008  Kevin O'Connor <kevin@koconnor.net>
 // Copyright (C) 2002  MandrakeSoft S.A.
 //
 // This file may be distributed under the terms of the GNU GPLv3 license.

 #include "ioport.h" // PORT_*
 #include "config.h" // CONFIG_*
 #include "cmos.h" // CMOS_*
 #include "util.h" // memset
 #include "biosvar.h" // struct bios_data_area_s
 #include "ata.h" // hard_drive_setup
 #include "disk.h" // floppy_drive_setup
 #include "memmap.h" // add_e820
 #include "pic.h" // pic_setup
 #include "pci.h" // create_pirtable
 #include "acpi.h" // acpi_bios_init
 #include "bregs.h" // struct bregs

 #define bda ((struct bios_data_area_s *)MAKE_FARPTR(SEG_BDA, 0))
 #define ebda ((struct extended_bios_data_area_s *)MAKE_FARPTR(SEG_EBDA, 0))

 static void
 set_irq(int vector, void *loc)
 {
     SET_BDA(ivecs[vector].seg, SEG_BIOS);
     SET_BDA(ivecs[vector].offset, (u32)loc - BUILD_BIOS_ADDR);
 }

 // Symbols defined in romlayout.S
 extern void dummy_iret_handler();
 extern void entry_08();
 extern void entry_09();
 extern void entry_hwirq();
 extern void entry_0e();
 extern void entry_10();
 extern void entry_11();
 extern void entry_12();
 extern void entry_13();
 extern void entry_14();
 extern void entry_15();
 extern void entry_16();
 extern void entry_17();
 extern void entry_18();
 extern void entry_19();
 extern void entry_1a();
 extern void entry_1c();
 extern void entry_40();
 extern void entry_70();
 extern void entry_74();
 extern void entry_75();
 extern void entry_76();

 static void
 init_bda()
 {
     dprintf(3, "init bda\n");
     memset(bda, 0, sizeof(*bda));

     SET_BDA(mem_size_kb, BASE_MEM_IN_K);

     int i;
     for (i=0; i<256; i++)
         set_irq(i, &dummy_iret_handler);

     set_irq(0x08, &entry_08);
     set_irq(0x09, &entry_09);
     //set_irq(0x0a, &entry_hwirq);
     //set_irq(0x0b, &entry_hwirq);
     //set_irq(0x0c, &entry_hwirq);
     //set_irq(0x0d, &entry_hwirq);
     set_irq(0x0e, &entry_0e);
     //set_irq(0x0f, &entry_hwirq);
     set_irq(0x10, &entry_10);
     set_irq(0x11, &entry_11);
     set_irq(0x12, &entry_12);
     set_irq(0x13, &entry_13);
     set_irq(0x14, &entry_14);
     set_irq(0x15, &entry_15);
     set_irq(0x16, &entry_16);
     set_irq(0x17, &entry_17);
     set_irq(0x18, &entry_18);
     set_irq(0x19, &entry_19);
     set_irq(0x1a, &entry_1a);
     set_irq(0x1c, &entry_1c);
     set_irq(0x40, &entry_40);
     set_irq(0x70, &entry_70);
     //set_irq(0x71, &entry_hwirq);
     //set_irq(0x72, &entry_hwirq);
     //set_irq(0x73, &entry_hwirq);
     set_irq(0x74, &entry_74);
     set_irq(0x75, &entry_75);
     set_irq(0x76, &entry_76);
     //set_irq(0x77, &entry_hwirq);

     // set vector 0x79 to zero
     // this is used by 'gardian angel' protection system
     SET_BDA(ivecs[0x79].seg, 0);
     SET_BDA(ivecs[0x79].offset, 0);

     set_irq(0x1E, &diskette_param_table2);
 }

 static void
 init_ebda()
 {
     memset(ebda, 0, sizeof(*ebda));
     ebda->size = EBDA_SIZE;
     SET_BDA(ebda_seg, SEG_EBDA);
     SET_BDA(ivecs[0x41].seg, SEG_EBDA);
     SET_BDA(ivecs[0x41].offset
             , offsetof(struct extended_bios_data_area_s, fdpt[0]));
     SET_BDA(ivecs[0x46].seg, SEG_EBDA);
     SET_BDA(ivecs[0x41].offset
             , offsetof(struct extended_bios_data_area_s, fdpt[1]));
 }

 static void
 ram_probe(void)
 {
     dprintf(3, "Find memory size\n");
     if (CONFIG_COREBOOT) {
         coreboot_fill_map();
     } else {
         // On emulators, get memory size from nvram.
         u32 rs = (inb_cmos(CMOS_MEM_EXTMEM2_LOW)
                   | (inb_cmos(CMOS_MEM_EXTMEM2_HIGH) << 8)) * 65536;
         if (rs)
             rs += 16 * 1024 * 1024;
         else
             rs = ((inb_cmos(CMOS_MEM_EXTMEM_LOW)
                    | (inb_cmos(CMOS_MEM_EXTMEM_HIGH) << 8)) * 1024
                   + 1 * 1024 * 1024);
         SET_EBDA(ram_size, rs);
         add_e820(0, rs, E820_RAM);

         /* reserve 256KB BIOS area at the end of 4 GB */
         add_e820(0xfffc0000, 256*1024, E820_RESERVED);
     }

     // Don't declare any memory between 0xa0000 and 0x100000
     add_e820(0xa0000, 0x50000, E820_HOLE);

     // Mark known areas as reserved.
     add_e820((u32)MAKE_FARPTR(SEG_EBDA, 0), EBDA_SIZE * 1024, E820_RESERVED);
     add_e820(BUILD_BIOS_ADDR, BUILD_BIOS_SIZE, E820_RESERVED);

     dprintf(1, "ram_size=0x%08x\n", GET_EBDA(ram_size));
 }

 static void
 init_bios_tables(void)
 {
     if (CONFIG_COREBOOT)
         // XXX - not supported on coreboot yet.
         return;

     smm_init();

     create_pirtable();

     mptable_init();

     smbios_init();

     acpi_bios_init();
 }

 static void
 init_boot_vectors()
 {
     if (! CONFIG_BOOT)
         return;
     dprintf(3, "init boot device ordering\n");

     // Floppy drive
     struct ipl_entry_s *ip = &ebda->ipl.table[0];
     ip->type = IPL_TYPE_FLOPPY;
     ip++;

     // First HDD
     ip->type = IPL_TYPE_HARDDISK;
     ip++;

     // CDROM
     if (CONFIG_CDROM_BOOT) {
         ip->type = IPL_TYPE_CDROM;
         ip++;
     }

     ebda->ipl.count = ip - ebda->ipl.table;
     ebda->ipl.sequence = 0xffff;
     if (CONFIG_COREBOOT) {
         // XXX - hardcode defaults for coreboot.
         ebda->ipl.bootorder = 0x00000231;
         ebda->ipl.checkfloppysig = 1;
     } else {
         // On emulators, get boot order from nvram.
         ebda->ipl.bootorder = (inb_cmos(CMOS_BIOS_BOOTFLAG2)
                                | ((inb_cmos(CMOS_BIOS_BOOTFLAG1) & 0xf0) << 4));
         if (!(inb_cmos(CMOS_BIOS_BOOTFLAG1) & 1))
             ebda->ipl.checkfloppysig = 1;
     }
 }

 // Execute a given option rom.
 static void
 callrom(u16 seg, u16 offset)
 {
     struct bregs br;
     memset(&br, 0, sizeof(br));
     // XXX - should set br.ax to PCI Bus/DevFn
     br.bx = 0xffff;
     br.dx = 0xffff;
     br.es = SEG_BIOS;
     extern char pnp_string[];
     br.di = (u32)pnp_string - BUILD_BIOS_ADDR;
     br.cs = seg;
     br.ip = offset;
     call16(&br);

     debug_serial_setup();
 }

 // Find and run any "option roms" found in the given address range.
 static void
 rom_scan(u32 start, u32 end)
 {
     if (! CONFIG_OPTIONROMS)
         return;

     u8 *p = (u8*)start;
     for (; p <= (u8*)end; p += 2048) {
         u8 *rom = p;
         if (*(u16*)rom != 0xaa55)
             continue;
         u32 len = rom[2] * 512;
         u8 sum = checksum(rom, len);
         if (sum != 0) {
             dprintf(1, "Found option rom with bad checksum:"
                     " loc=%p len=%d sum=%x\n"
                     , rom, len, sum);
             continue;
         }
         p = (u8*)(((u32)p + len) / 2048 * 2048);
         dprintf(1, "Running option rom at %p\n", rom+3);
         callrom(FARPTR_TO_SEG(rom), FARPTR_TO_OFFSET(rom + 3));

         if (GET_BDA(ebda_seg) != SEG_EBDA)
             BX_PANIC("Option rom at %p attempted to move ebda from %x to %x\n"
                      , rom, SEG_EBDA, GET_BDA(ebda_seg));

         // Look at the ROM's PnP Expansion header.  Properly, we're supposed
         // to init all the ROMs and then go back and build an IPL table of
         // all the bootable devices, but we can get away with one pass.
         if (rom[0x1a] != '$' || rom[0x1b] != 'P'
             || rom[0x1c] != 'n' || rom[0x1d] != 'P')
             continue;
         // 0x1A is also the offset into the expansion header of...
         // the Bootstrap Entry Vector, or zero if there is none.
         u16 entry = *(u16*)&rom[0x1a+0x1a];
         if (!entry)
             continue;
         // Found a device that thinks it can boot the system.  Record
         // its BEV and product name string.

         if (! CONFIG_BOOT)
             continue;

         if (ebda->ipl.count >= ARRAY_SIZE(ebda->ipl.table))
             continue;

         struct ipl_entry_s *ip = &ebda->ipl.table[ebda->ipl.count];
         ip->type = IPL_TYPE_BEV;
         ip->vector = (FARPTR_TO_SEG(rom) << 16) | entry;

         u16 desc = *(u16*)&rom[0x1a+0x10];
         if (desc)
             ip->description = (u32)MAKE_FARPTR(FARPTR_TO_SEG(rom), desc);

         ebda->ipl.count++;
     }
 }

 // Call into vga code to turn on console.
 static void
 vga_setup()
 {
     dprintf(1, "Scan for VGA option rom\n");
     rom_scan(0xc0000, 0xc7800);

     dprintf(1, "Turning on vga console\n");
     struct bregs br;
     memset(&br, 0, sizeof(br));
     br.ax = 0x0003;
     call16_int(0x10, &br);
 }

 // Main setup code.
 static void
 post()
 {
     init_bda();
     init_ebda();

     pic_setup();
     timer_setup();
     kbd_setup();
     lpt_setup();
     serial_setup();
     mouse_setup();
     mathcp_setup();

     memmap_setup();

     ram_probe();

     vga_setup();

     printf("BIOS - begin\n\n");

     pci_bios_setup();

     init_bios_tables();

     memmap_finalize();

     floppy_drive_setup();
     hard_drive_setup();

     init_boot_vectors();

     dprintf(1, "Scan for option roms\n");
     rom_scan(0xc8000, 0xe0000);
 }

 // Clear .bss section for C code.
 static void
 clear_bss()
 {
     dprintf(3, "clearing .bss section\n");
     extern char __bss_start[], __bss_end[];
     memset(__bss_start, 0, __bss_end - __bss_start);
 }

 // Reset DMA controller
 static void
 init_dma()
 {
     // first reset the DMA controllers
     outb(0, PORT_DMA1_MASTER_CLEAR);
     outb(0, PORT_DMA2_MASTER_CLEAR);

     // then initialize the DMA controllers
     outb(0xc0, PORT_DMA2_MODE_REG);
     outb(0x00, PORT_DMA2_MASK_REG);
 }

 // Check if the machine was setup with a special restart vector.
 static void
 check_restart_status()
 {
     // Get and then clear CMOS shutdown status.
     u8 status = inb_cmos(CMOS_RESET_CODE);
     outb_cmos(0, CMOS_RESET_CODE);

     if (status == 0x00 || status == 0x09 || status >= 0x0d)
         // Normal post
         return;

     if (status != 0x05) {
         BX_PANIC("Unimplemented shutdown status: %02x\n", status);
         return;
     }

     // XXX - this is supposed to jump without changing any memory -
     // but the stack has been altered by the time the code gets here.
     eoi_pic2();
     struct bregs br;
     memset(&br, 0, sizeof(br));
     br.cs = GET_BDA(jump_cs_ip) >> 16;
     br.ip = GET_BDA(jump_cs_ip);
     call16(&br);
 }

 // 32-bit entry point.
 void VISIBLE32
 _start()
 {
     init_dma();
     check_restart_status();

     debug_serial_setup();
     dprintf(1, "Start bios\n");

     // Setup for .bss and .data sections
     clear_bss();
     make_bios_writable();

     // Perform main setup code.
     post();

     // Present the user with a bootup menu.
     interactive_bootmenu();

     // Setup bios checksum.
     extern char bios_checksum;
     bios_checksum = -checksum((u8*)BUILD_BIOS_ADDR, BUILD_BIOS_SIZE - 1);

     // Prep for boot process.
     make_bios_readonly();
     clear_bss();

     // Invoke int 19 to start boot process.
     dprintf(3, "Jump to int19\n");
     struct bregs br;
     memset(&br, 0, sizeof(br));
     call16_int(0x19, &br);
 }

 // Ughh - some older gcc compilers have a bug which causes VISIBLE32
 // functions to not be exported as a global variable - force _start
 // to be global here.
 asm(".global _start");
	// 32bit code to Power On Self Test (POST) a machine.
	//
	// Copyright (C) 2008 Kevin O'Connor <kevin@koconnor.net>
	// Copyright (C) 2002 MandrakeSoft S.A.
	//
	// This file may be distributed under the terms of the GNU GPLv3 license.

	#include "ioport.h" // PORT_*
	#include "config.h" // CONFIG_*
	#include "cmos.h" // CMOS_*
	#include "util.h" // memset
	#include "biosvar.h" // struct bios_data_area_s
	#include "ata.h" // hard_drive_setup
	#include "disk.h" // floppy_drive_setup
	#include "memmap.h" // add_e820
	#include "pic.h" // pic_setup
	#include "pci.h" // create_pirtable
	#include "acpi.h" // acpi_bios_init
	#include "bregs.h" // struct bregs

	#define bda ((struct bios_data_area_s *)MAKE_FARPTR(SEG_BDA, 0))
	#define ebda ((struct extended_bios_data_area_s *)MAKE_FARPTR(SEG_EBDA, 0))

	static void
	set_irq(int vector, void *loc)
	{
	SET_BDA(ivecs[vector].seg, SEG_BIOS);
	SET_BDA(ivecs[vector].offset, (u32)loc - BUILD_BIOS_ADDR);
	}

	// Symbols defined in romlayout.S
	extern void dummy_iret_handler();
	extern void entry_08();
	extern void entry_09();
	extern void entry_hwirq();
	extern void entry_0e();
	extern void entry_10();
	extern void entry_11();
	extern void entry_12();
	extern void entry_13();
	extern void entry_14();
	extern void entry_15();
	extern void entry_16();
	extern void entry_17();
	extern void entry_18();
	extern void entry_19();
	extern void entry_1a();
	extern void entry_1c();
	extern void entry_40();
	extern void entry_70();
	extern void entry_74();
	extern void entry_75();
	extern void entry_76();

	static void
	init_bda()
	{
	dprintf(3, "init bda\n");
	memset(bda, 0, sizeof(*bda));

	SET_BDA(mem_size_kb, BASE_MEM_IN_K);

	int i;
	for (i=0; i<256; i++)
	set_irq(i, &dummy_iret_handler);

	set_irq(0x08, &entry_08);
	set_irq(0x09, &entry_09);
	//set_irq(0x0a, &entry_hwirq);
	//set_irq(0x0b, &entry_hwirq);
	//set_irq(0x0c, &entry_hwirq);
	//set_irq(0x0d, &entry_hwirq);
	set_irq(0x0e, &entry_0e);
	//set_irq(0x0f, &entry_hwirq);
	set_irq(0x10, &entry_10);
	set_irq(0x11, &entry_11);
	set_irq(0x12, &entry_12);
	set_irq(0x13, &entry_13);
	set_irq(0x14, &entry_14);
	set_irq(0x15, &entry_15);
	set_irq(0x16, &entry_16);
	set_irq(0x17, &entry_17);
	set_irq(0x18, &entry_18);
	set_irq(0x19, &entry_19);
	set_irq(0x1a, &entry_1a);
	set_irq(0x1c, &entry_1c);
	set_irq(0x40, &entry_40);
	set_irq(0x70, &entry_70);
	//set_irq(0x71, &entry_hwirq);
	//set_irq(0x72, &entry_hwirq);
	//set_irq(0x73, &entry_hwirq);
	set_irq(0x74, &entry_74);
	set_irq(0x75, &entry_75);
	set_irq(0x76, &entry_76);
	//set_irq(0x77, &entry_hwirq);

	// set vector 0x79 to zero
	// this is used by 'gardian angel' protection system
	SET_BDA(ivecs[0x79].seg, 0);
	SET_BDA(ivecs[0x79].offset, 0);

	set_irq(0x1E, &diskette_param_table2);
	}

	static void
	init_ebda()
	{
	memset(ebda, 0, sizeof(*ebda));
	ebda->size = EBDA_SIZE;
	SET_BDA(ebda_seg, SEG_EBDA);
	SET_BDA(ivecs[0x41].seg, SEG_EBDA);
	SET_BDA(ivecs[0x41].offset
	, offsetof(struct extended_bios_data_area_s, fdpt[0]));
	SET_BDA(ivecs[0x46].seg, SEG_EBDA);
	SET_BDA(ivecs[0x41].offset
	, offsetof(struct extended_bios_data_area_s, fdpt[1]));
	}

	static void
	ram_probe(void)
	{
	dprintf(3, "Find memory size\n");
	if (CONFIG_COREBOOT) {
	coreboot_fill_map();
	} else {
	// On emulators, get memory size from nvram.
	u32 rs = (inb_cmos(CMOS_MEM_EXTMEM2_LOW)
	\| (inb_cmos(CMOS_MEM_EXTMEM2_HIGH) << 8)) * 65536;
	if (rs)
	rs += 16 * 1024 * 1024;
	else
	rs = ((inb_cmos(CMOS_MEM_EXTMEM_LOW)
	\| (inb_cmos(CMOS_MEM_EXTMEM_HIGH) << 8)) * 1024
	+ 1 * 1024 * 1024);
	SET_EBDA(ram_size, rs);
	add_e820(0, rs, E820_RAM);

	/* reserve 256KB BIOS area at the end of 4 GB */
	add_e820(0xfffc0000, 256*1024, E820_RESERVED);
	}

	// Don't declare any memory between 0xa0000 and 0x100000
	add_e820(0xa0000, 0x50000, E820_HOLE);

	// Mark known areas as reserved.
	add_e820((u32)MAKE_FARPTR(SEG_EBDA, 0), EBDA_SIZE * 1024, E820_RESERVED);
	add_e820(BUILD_BIOS_ADDR, BUILD_BIOS_SIZE, E820_RESERVED);

	dprintf(1, "ram_size=0x%08x\n", GET_EBDA(ram_size));
	}

	static void
	init_bios_tables(void)
	{
	if (CONFIG_COREBOOT)
	// XXX - not supported on coreboot yet.
	return;

	smm_init();

	create_pirtable();

	mptable_init();

	smbios_init();

	acpi_bios_init();
	}

	static void
	init_boot_vectors()
	{
	if (! CONFIG_BOOT)
	return;
	dprintf(3, "init boot device ordering\n");

	// Floppy drive
	struct ipl_entry_s *ip = &ebda->ipl.table[0];
	ip->type = IPL_TYPE_FLOPPY;
	ip++;

	// First HDD
	ip->type = IPL_TYPE_HARDDISK;
	ip++;

	// CDROM
	if (CONFIG_CDROM_BOOT) {
	ip->type = IPL_TYPE_CDROM;
	ip++;
	}

	ebda->ipl.count = ip - ebda->ipl.table;
	ebda->ipl.sequence = 0xffff;
	if (CONFIG_COREBOOT) {
	// XXX - hardcode defaults for coreboot.
	ebda->ipl.bootorder = 0x00000231;
	ebda->ipl.checkfloppysig = 1;
	} else {
	// On emulators, get boot order from nvram.
	ebda->ipl.bootorder = (inb_cmos(CMOS_BIOS_BOOTFLAG2)
	\| ((inb_cmos(CMOS_BIOS_BOOTFLAG1) & 0xf0) << 4));
	if (!(inb_cmos(CMOS_BIOS_BOOTFLAG1) & 1))
	ebda->ipl.checkfloppysig = 1;
	}
	}

	// Execute a given option rom.
	static void
	callrom(u16 seg, u16 offset)
	{
	struct bregs br;
	memset(&br, 0, sizeof(br));
	// XXX - should set br.ax to PCI Bus/DevFn
	br.bx = 0xffff;
	br.dx = 0xffff;
	br.es = SEG_BIOS;
	extern char pnp_string[];
	br.di = (u32)pnp_string - BUILD_BIOS_ADDR;
	br.cs = seg;
	br.ip = offset;
	call16(&br);

	debug_serial_setup();
	}

	// Find and run any "option roms" found in the given address range.
	static void
	rom_scan(u32 start, u32 end)
	{
	if (! CONFIG_OPTIONROMS)
	return;

	u8 p = (u8)start;
	for (; p <= (u8*)end; p += 2048) {
	u8 *rom = p;
	if ((u16)rom != 0xaa55)
	continue;
	u32 len = rom[2] * 512;
	u8 sum = checksum(rom, len);
	if (sum != 0) {
	dprintf(1, "Found option rom with bad checksum:"
	" loc=%p len=%d sum=%x\n"
	, rom, len, sum);
	continue;
	}
	p = (u8)(((u32)p + len) / 2048 2048);
	dprintf(1, "Running option rom at %p\n", rom+3);
	callrom(FARPTR_TO_SEG(rom), FARPTR_TO_OFFSET(rom + 3));

	if (GET_BDA(ebda_seg) != SEG_EBDA)
	BX_PANIC("Option rom at %p attempted to move ebda from %x to %x\n"
	, rom, SEG_EBDA, GET_BDA(ebda_seg));

	// Look at the ROM's PnP Expansion header. Properly, we're supposed
	// to init all the ROMs and then go back and build an IPL table of
	// all the bootable devices, but we can get away with one pass.
	if (rom[0x1a] != '$' \|\| rom[0x1b] != 'P'
	\|\| rom[0x1c] != 'n' \|\| rom[0x1d] != 'P')
	continue;
	// 0x1A is also the offset into the expansion header of...
	// the Bootstrap Entry Vector, or zero if there is none.
	u16 entry = (u16)&rom[0x1a+0x1a];
	if (!entry)
	continue;
	// Found a device that thinks it can boot the system. Record
	// its BEV and product name string.

	if (! CONFIG_BOOT)
	continue;

	if (ebda->ipl.count >= ARRAY_SIZE(ebda->ipl.table))
	continue;

	struct ipl_entry_s *ip = &ebda->ipl.table[ebda->ipl.count];
	ip->type = IPL_TYPE_BEV;
	ip->vector = (FARPTR_TO_SEG(rom) << 16) \| entry;

	u16 desc = (u16)&rom[0x1a+0x10];
	if (desc)
	ip->description = (u32)MAKE_FARPTR(FARPTR_TO_SEG(rom), desc);

	ebda->ipl.count++;
	}
	}

	// Call into vga code to turn on console.
	static void
	vga_setup()
	{
	dprintf(1, "Scan for VGA option rom\n");
	rom_scan(0xc0000, 0xc7800);

	dprintf(1, "Turning on vga console\n");
	struct bregs br;
	memset(&br, 0, sizeof(br));
	br.ax = 0x0003;
	call16_int(0x10, &br);
	}

	// Main setup code.
	static void
	post()
	{
	init_bda();
	init_ebda();

	pic_setup();
	timer_setup();
	kbd_setup();
	lpt_setup();
	serial_setup();
	mouse_setup();
	mathcp_setup();

	memmap_setup();

	ram_probe();

	vga_setup();

	printf("BIOS - begin\n\n");

	pci_bios_setup();

	init_bios_tables();

	memmap_finalize();

	floppy_drive_setup();
	hard_drive_setup();

	init_boot_vectors();

	dprintf(1, "Scan for option roms\n");
	rom_scan(0xc8000, 0xe0000);
	}

	// Clear .bss section for C code.
	static void
	clear_bss()
	{
	dprintf(3, "clearing .bss section\n");
	extern char __bss_start[], __bss_end[];
	memset(__bss_start, 0, __bss_end - __bss_start);
	}

	// Reset DMA controller
	static void
	init_dma()
	{
	// first reset the DMA controllers
	outb(0, PORT_DMA1_MASTER_CLEAR);
	outb(0, PORT_DMA2_MASTER_CLEAR);

	// then initialize the DMA controllers
	outb(0xc0, PORT_DMA2_MODE_REG);
	outb(0x00, PORT_DMA2_MASK_REG);
	}

	// Check if the machine was setup with a special restart vector.
	static void
	check_restart_status()
	{
	// Get and then clear CMOS shutdown status.
	u8 status = inb_cmos(CMOS_RESET_CODE);
	outb_cmos(0, CMOS_RESET_CODE);

	if (status == 0x00 \|\| status == 0x09 \|\| status >= 0x0d)
	// Normal post
	return;

	if (status != 0x05) {
	BX_PANIC("Unimplemented shutdown status: %02x\n", status);
	return;
	}

	// XXX - this is supposed to jump without changing any memory -
	// but the stack has been altered by the time the code gets here.
	eoi_pic2();
	struct bregs br;
	memset(&br, 0, sizeof(br));
	br.cs = GET_BDA(jump_cs_ip) >> 16;
	br.ip = GET_BDA(jump_cs_ip);
	call16(&br);
	}

	// 32-bit entry point.
	void VISIBLE32
	_start()
	{
	init_dma();
	check_restart_status();

	debug_serial_setup();
	dprintf(1, "Start bios\n");

	// Setup for .bss and .data sections
	clear_bss();
	make_bios_writable();

	// Perform main setup code.
	post();

	// Present the user with a bootup menu.
	interactive_bootmenu();

	// Setup bios checksum.
	extern char bios_checksum;
	bios_checksum = -checksum((u8*)BUILD_BIOS_ADDR, BUILD_BIOS_SIZE - 1);

	// Prep for boot process.
	make_bios_readonly();
	clear_bss();

	// Invoke int 19 to start boot process.
	dprintf(3, "Jump to int19\n");
	struct bregs br;
	memset(&br, 0, sizeof(br));
	call16_int(0x19, &br);
	}

	// Ughh - some older gcc compilers have a bug which causes VISIBLE32
	// functions to not be exported as a global variable - force _start
	// to be global here.
	asm(".global _start");