src/device/oprom/yabel/biosemu.c - mirrors/cros/chromiumos/third_party/coreboot - Git at Google

 /******************************************************************************
  * Copyright (c) 2004, 2008 IBM Corporation
  * Copyright (c) 2008, 2009 Pattrick Hueper <phueper@hueper.net>
  * Copyright (c) 2010 coresystems GmbH
  * All rights reserved.
  * This program and the accompanying materials
  * are made available under the terms of the BSD License
  * which accompanies this distribution, and is available at
  * http://www.opensource.org/licenses/bsd-license.php
  *
  * Contributors:
  *     IBM Corporation - initial implementation
  *****************************************************************************/

 #include <string.h>
 #include <types.h>

 #include "debug.h"

 #include <x86emu/x86emu.h>
 #include <x86emu/regs.h>
 #include "../x86emu/prim_ops.h"

 #include "biosemu.h"
 #include "io.h"
 #include "mem.h"
 #include "interrupt.h"
 #include "device.h"
 #include "pmm.h"

 #include <device/device.h>
 #include "compat/rtas.h"

 static X86EMU_memFuncs my_mem_funcs = {
 	my_rdb, my_rdw, my_rdl,
 	my_wrb, my_wrw, my_wrl
 };

 static X86EMU_pioFuncs my_pio_funcs = {
 	my_inb, my_inw, my_inl,
 	my_outb, my_outw, my_outl
 };

 /* interrupt function override array (see biosemu.h) */
 yabel_handleIntFunc yabel_intFuncArray[256];

 void
 mainboard_interrupt_handlers(int interrupt, yabel_handleIntFunc func)
 {
 	yabel_intFuncArray[interrupt] = func;
 }

 /* main entry into YABEL biosemu, arguments are:
  * *biosmem = pointer to virtual memory
  * biosmem_size = size of the virtual memory
  * *dev = pointer to the device to be initialised
  * rom_addr = address of the OptionROM to be executed, if this is = 0, YABEL
  * 	will look for an ExpansionROM BAR and use the code from there.
  */
 u32
 biosemu(u8 *biosmem, u32 biosmem_size, struct device * dev, unsigned long rom_addr)
 {
 	u8 *rom_image;
 	int i = 0;
 #if CONFIG_X86EMU_DEBUG
 	debug_flags = 0;
 #if CONFIG_X86EMU_DEBUG_JMP
 	debug_flags |= DEBUG_JMP;
 #endif
 #if CONFIG_X86EMU_DEBUG_TRACE
 	debug_flags |= DEBUG_TRACE_X86EMU;
 #endif
 #if CONFIG_X86EMU_DEBUG_PNP
 	debug_flags |= DEBUG_PNP;
 #endif
 #if CONFIG_X86EMU_DEBUG_DISK
 	debug_flags |= DEBUG_DISK;
 #endif
 #if CONFIG_X86EMU_DEBUG_PMM
 	debug_flags |= DEBUG_PMM;
 #endif
 #if CONFIG_X86EMU_DEBUG_VBE
 	debug_flags |= DEBUG_VBE;
 #endif
 #if CONFIG_X86EMU_DEBUG_INT10
 	debug_flags |= DEBUG_PRINT_INT10;
 #endif
 #if CONFIG_X86EMU_DEBUG_INTERRUPTS
 	debug_flags |= DEBUG_INTR;
 #endif
 #if CONFIG_X86EMU_DEBUG_CHECK_VMEM_ACCESS
 	debug_flags |= DEBUG_CHECK_VMEM_ACCESS;
 #endif
 #if CONFIG_X86EMU_DEBUG_MEM
 	debug_flags |= DEBUG_MEM;
 #endif
 #if CONFIG_X86EMU_DEBUG_IO
 	debug_flags |= DEBUG_IO;
 #endif

 #endif
 	if (biosmem_size < MIN_REQUIRED_VMEM_SIZE) {
 		printf("Error: Not enough virtual memory: %x, required: %x!\n",
 		       biosmem_size, MIN_REQUIRED_VMEM_SIZE);
 		return -1;
 	}
 	if (biosemu_dev_init(dev) != 0) {
 		printf("Error initializing device!\n");
 		return -1;
 	}
 	if (biosemu_dev_check_exprom(rom_addr) != 0) {
 		printf("Error: Device Expansion ROM invalid!\n");
 		return -1;
 	}
 	biosemu_add_special_memory(0, 0x500); // IVT + BDA
 	biosemu_add_special_memory(OPTION_ROM_CODE_SEGMENT << 4, 0x10000); // option ROM

 	rom_image = (u8 *) bios_device.img_addr;
 	DEBUG_PRINTF("executing rom_image from %p\n", rom_image);
 	DEBUG_PRINTF("biosmem at %p\n", biosmem);

 	DEBUG_PRINTF("Image Size: %d\n", bios_device.img_size);

 	// in case we jump somewhere unexpected, or execution is finished,
 	// fill the biosmem with hlt instructions (0xf4)
 	// But we have to be careful: If biosmem is 0x00000000 we're running
 	// in the lower 1MB and we must not wipe memory like that.
 	if (biosmem) {
 		DEBUG_PRINTF("Clearing biosmem\n");
 		memset(biosmem, 0xf4, biosmem_size);
 	}

 	X86EMU_setMemBase(biosmem, biosmem_size);

 	DEBUG_PRINTF("membase set: %08x, size: %08x\n", (int) M.mem_base,
 		     (int) M.mem_size);

 	// copy expansion ROM image to segment OPTION_ROM_CODE_SEGMENT
 	// NOTE: this sometimes fails, some bytes are 0x00... so we compare
 	// after copying and do some retries...
 	u8 *mem_img = (u8*)(OPTION_ROM_CODE_SEGMENT << 4);
 	u8 copy_count = 0;
 	u8 cmp_result = 0;
 	do {
 #if 0
 		set_ci();
 		memcpy(mem_img, rom_image, len);
 		clr_ci();
 #else
 		// memcpy fails... try copy byte-by-byte with set/clr_ci
 		u8 c;
 		for (i = 0; i < bios_device.img_size; i++) {
 			set_ci();
 			c = *(rom_image + i);
 			if (c != *(rom_image + i)) {
 				clr_ci();
 				printf("Copy failed at: %x/%x\n", i,
 				       bios_device.img_size);
 				printf("rom_image(%x): %x, mem_img(%x): %x\n",
 				       i, *(rom_image + i), i, *(mem_img + i));
 				break;
 			}
 			clr_ci();
 			my_wrb((u32)mem_img + i, c);
 		}
 #endif
 		copy_count++;
 		set_ci();
 		cmp_result = memcmp(mem_img, rom_image, bios_device.img_size);
 		clr_ci();
 	}
 	while ((copy_count < 5) && (cmp_result != 0));
 	if (cmp_result != 0) {
 		printf
 		    ("\nCopying Expansion ROM Image to Memory failed after %d retries! (%x)\n",
 		     copy_count, cmp_result);
 		dump(rom_image, 0x20);
 		dump(mem_img, 0x20);
 		return 0;
 	}
 	// setup default Interrupt Vectors
 	// some expansion ROMs seem to check for these addresses..
 	// each handler is only an IRET (0xCF) instruction
 	// ROM BIOS Int 10 Handler F000:F065
 	my_wrl(0x10 * 4, 0xf000f065);
 	my_wrb(0x000ff065, 0xcf);
 	// ROM BIOS Int 11 Handler F000:F84D
 	my_wrl(0x11 * 4, 0xf000f84d);
 	my_wrb(0x000ff84d, 0xcf);
 	// ROM BIOS Int 12 Handler F000:F841
 	my_wrl(0x12 * 4, 0xf000f841);
 	my_wrb(0x000ff841, 0xcf);
 	// ROM BIOS Int 13 Handler F000:EC59
 	my_wrl(0x13 * 4, 0xf000ec59);
 	my_wrb(0x000fec59, 0xcf);
 	// ROM BIOS Int 14 Handler F000:E739
 	my_wrl(0x14 * 4, 0xf000e739);
 	my_wrb(0x000fe739, 0xcf);
 	// ROM BIOS Int 15 Handler F000:F859
 	my_wrl(0x15 * 4, 0xf000f859);
 	my_wrb(0x000ff859, 0xcf);
 	// ROM BIOS Int 16 Handler F000:E82E
 	my_wrl(0x16 * 4, 0xf000e82e);
 	my_wrb(0x000fe82e, 0xcf);
 	// ROM BIOS Int 17 Handler F000:EFD2
 	my_wrl(0x17 * 4, 0xf000efd2);
 	my_wrb(0x000fefd2, 0xcf);
 	// ROM BIOS Int 1A Handler F000:FE6E
 	my_wrl(0x1a * 4, 0xf000fe6e);
 	my_wrb(0x000ffe6e, 0xcf);

 	// setup BIOS Data Area (0000:04xx, or 0040:00xx)
 	// we currently 0 this area, meaning "we dont have
 	// any hardware" :-) no serial/parallel ports, floppys, ...
 	memset(biosmem + 0x400, 0x0, 0x100);

 	// at offset 13h in BDA is the memory size in kbytes
 	my_wrw(0x413, biosmem_size / 1024);
 	// at offset 0eh in BDA is the segment of the Extended BIOS Data Area
 	// see setup further down
 	my_wrw(0x40e, INITIAL_EBDA_SEGMENT);
 	// TODO: setup BDA Video Data ( offset 49h-66h)
 	// e.g. to store video mode, cursor position, ...
 	// in int10 (done) handler and VBE Functions

 	// TODO: setup BDA Fixed Disk Data
 	// 74h: Fixed Disk Last Operation Status
 	// 75h: Fixed Disk Number of Disk Drives

 	// TODO: check BDA for further needed data...

 	//setup Extended BIOS Data Area
 	//we currently 0 this area
 	memset(biosmem + (INITIAL_EBDA_SEGMENT << 4), 0, INITIAL_EBDA_SIZE);
 	// at offset 0h in EBDA is the size of the EBDA in KB
 	my_wrw((INITIAL_EBDA_SEGMENT << 4) + 0x0, INITIAL_EBDA_SIZE / 1024);
 	//TODO: check for further needed EBDA data...

 	// setup  original ROM BIOS Area (F000:xxxx)
 	const char *date = "06/11/99";
 	for (i = 0; date[i]; i++)
 		my_wrb(0xffff5 + i, date[i]);
 	// set up eisa ident string
 	const char *ident = "PCI_ISA";
 	for (i = 0; ident[i]; i++)
 		my_wrb(0xfffd9 + i, ident[i]);

 	// write system model id for IBM-AT
 	// according to "Ralf Browns Interrupt List" Int15 AH=C0 Table 515,
 	// model FC is the original AT and also used in all DOSEMU Versions.
 	my_wrb(0xFFFFE, 0xfc);

 	//setup interrupt handler
 	X86EMU_intrFuncs intrFuncs[256];
 	for (i = 0; i < 256; i++)
 		intrFuncs[i] = handleInterrupt;
 	X86EMU_setupIntrFuncs(intrFuncs);
 	X86EMU_setupPioFuncs(&my_pio_funcs);
 	X86EMU_setupMemFuncs(&my_mem_funcs);

 	//setup PMM struct in BIOS_DATA_SEGMENT, offset 0x0
 	u8 pmm_length = pmm_setup(BIOS_DATA_SEGMENT, 0x0);
 	if (pmm_length <= 0) {
 		printf ("\nYABEL: Warning: PMM Area could not be setup. PMM not available (%x)\n",
 		     pmm_length);
 		return 0;
 	} else {
 		CHECK_DBG(DEBUG_PMM) {
 			/* test the PMM */
 			pmm_test();
 			/* and clean it again by calling pmm_setup... */
 			pmm_length = pmm_setup(BIOS_DATA_SEGMENT, 0x0);
 		}
 	}
 	// setup the CPU
 	M.x86.R_AH = bios_device.bus;
 	M.x86.R_AL = bios_device.devfn;
 	M.x86.R_DX = 0x80;
 	M.x86.R_EIP = 3;
 	M.x86.R_CS = OPTION_ROM_CODE_SEGMENT;

 	// Initialize stack and data segment
 	M.x86.R_SS = STACK_SEGMENT;
 	M.x86.R_SP = STACK_START_OFFSET;
 	M.x86.R_DS = DATA_SEGMENT;

 	// push a HLT instruction and a pointer to it onto the stack
 	// any return will pop the pointer and jump to the HLT, thus
 	// exiting (more or less) cleanly
 	push_word(0xf4f4);	// F4=HLT
 	push_word(M.x86.R_SS);
 	push_word(M.x86.R_SP + 2);

 	CHECK_DBG(DEBUG_TRACE_X86EMU) {
 		X86EMU_trace_on();
 #if 0
 	} else {
 		M.x86.debug |= DEBUG_SAVE_IP_CS_F;
 		M.x86.debug |= DEBUG_DECODE_F;
 		M.x86.debug |= DEBUG_DECODE_NOPRINT_F;
 #endif
 	}
 	CHECK_DBG(DEBUG_JMP) {
 		M.x86.debug |= DEBUG_TRACEJMP_F;
 		M.x86.debug |= DEBUG_TRACEJMP_REGS_F;
 		M.x86.debug |= DEBUG_TRACECALL_F;
 		M.x86.debug |= DEBUG_TRACECALL_REGS_F;
 	}

 	DEBUG_PRINTF("Executing Initialization Vector...\n");
 	X86EMU_exec();
 	DEBUG_PRINTF("done\n");

 	/* According to the PNP BIOS Spec, Option ROMs should upon exit, return
 	 * some boot device status in AX (see PNP BIOS Spec Section 3.3
 	 */
 	DEBUG_PRINTF_CS_IP("Option ROM Exit Status: %04x\n", M.x86.R_AX);
 #if CONFIG_X86EMU_DEBUG
 	DEBUG_PRINTF("Exit Status Decode:\n");
 	if (M.x86.R_AX & 0x100) {	// bit 8
 		DEBUG_PRINTF
 		    ("  IPL Device supporting INT 13h Block Device Format:\n");
 		switch (((M.x86.R_AX >> 4) & 0x3)) {	// bits 5:4
 		case 0:
 			DEBUG_PRINTF("    No IPL Device attached\n");
 			break;
 		case 1:
 			DEBUG_PRINTF("    IPL Device status unknown\n");
 			break;
 		case 2:
 			DEBUG_PRINTF("    IPL Device attached\n");
 			break;
 		case 3:
 			DEBUG_PRINTF("    IPL Device status RESERVED!!\n");
 			break;
 		}
 	}
 	if (M.x86.R_AX & 0x80) {	// bit 7
 		DEBUG_PRINTF
 		    ("  Output Device supporting INT 10h Character Output:\n");
 		switch (((M.x86.R_AX >> 4) & 0x3)) {	// bits 5:4
 		case 0:
 			DEBUG_PRINTF("    No Display Device attached\n");
 			break;
 		case 1:
 			DEBUG_PRINTF("    Display Device status unknown\n");
 			break;
 		case 2:
 			DEBUG_PRINTF("    Display Device attached\n");
 			break;
 		case 3:
 			DEBUG_PRINTF("    Display Device status RESERVED!!\n");
 			break;
 		}
 	}
 	if (M.x86.R_AX & 0x40) {	// bit 6
 		DEBUG_PRINTF
 		    ("  Input Device supporting INT 9h Character Input:\n");
 		switch (((M.x86.R_AX >> 4) & 0x3)) {	// bits 5:4
 		case 0:
 			DEBUG_PRINTF("    No Input Device attached\n");
 			break;
 		case 1:
 			DEBUG_PRINTF("    Input Device status unknown\n");
 			break;
 		case 2:
 			DEBUG_PRINTF("    Input Device attached\n");
 			break;
 		case 3:
 			DEBUG_PRINTF("    Input Device status RESERVED!!\n");
 			break;
 		}
 	}
 #endif
 	/* Check whether the stack is "clean" i.e. containing the HLT
 	 * instruction we pushed before executing and pointing to the original
 	 * stack address... indicating that the initialization probably was
 	 * successful
 	 */
 	if ((pop_word() == 0xf4f4) && (M.x86.R_SS == STACK_SEGMENT)
 	    && (M.x86.R_SP == STACK_START_OFFSET)) {
 		DEBUG_PRINTF("Stack is clean, initialization successfull!\n");
 	} else {
 		printf("Stack unclean, initialization probably NOT COMPLETE!\n");
 		DEBUG_PRINTF("SS:SP = %04x:%04x, expected: %04x:%04x\n",
 			     M.x86.R_SS, M.x86.R_SP, STACK_SEGMENT,
 			     STACK_START_OFFSET);
 	}

 	// TODO: according to the BIOS Boot Spec initializations may be ended using INT18h and setting
 	// the status.
 	// We need to implement INT18 accordingly, pseudo code is in specsbbs101.pdf page 30
 	// (also for Int19)
 	return 0;
 }
	/******************************************************************************
	* Copyright (c) 2004, 2008 IBM Corporation
	* Copyright (c) 2008, 2009 Pattrick Hueper <phueper@hueper.net>
	* Copyright (c) 2010 coresystems GmbH
	* All rights reserved.
	* This program and the accompanying materials
	* are made available under the terms of the BSD License
	* which accompanies this distribution, and is available at
	* http://www.opensource.org/licenses/bsd-license.php
	*
	* Contributors:
	* IBM Corporation - initial implementation
	*****************************************************************************/

	#include <string.h>
	#include <types.h>

	#include "debug.h"

	#include <x86emu/x86emu.h>
	#include <x86emu/regs.h>
	#include "../x86emu/prim_ops.h"

	#include "biosemu.h"
	#include "io.h"
	#include "mem.h"
	#include "interrupt.h"
	#include "device.h"
	#include "pmm.h"

	#include <device/device.h>
	#include "compat/rtas.h"

	static X86EMU_memFuncs my_mem_funcs = {
	my_rdb, my_rdw, my_rdl,
	my_wrb, my_wrw, my_wrl
	};

	static X86EMU_pioFuncs my_pio_funcs = {
	my_inb, my_inw, my_inl,
	my_outb, my_outw, my_outl
	};

	/* interrupt function override array (see biosemu.h) */
	yabel_handleIntFunc yabel_intFuncArray[256];

	void
	mainboard_interrupt_handlers(int interrupt, yabel_handleIntFunc func)
	{
	yabel_intFuncArray[interrupt] = func;
	}

	/* main entry into YABEL biosemu, arguments are:
	* *biosmem = pointer to virtual memory
	* biosmem_size = size of the virtual memory
	* *dev = pointer to the device to be initialised
	* rom_addr = address of the OptionROM to be executed, if this is = 0, YABEL
	* will look for an ExpansionROM BAR and use the code from there.
	*/
	u32
	biosemu(u8 biosmem, u32 biosmem_size, struct device dev, unsigned long rom_addr)
	{
	u8 *rom_image;
	int i = 0;
	#if CONFIG_X86EMU_DEBUG
	debug_flags = 0;
	#if CONFIG_X86EMU_DEBUG_JMP
	debug_flags \|= DEBUG_JMP;
	#endif
	#if CONFIG_X86EMU_DEBUG_TRACE
	debug_flags \|= DEBUG_TRACE_X86EMU;
	#endif
	#if CONFIG_X86EMU_DEBUG_PNP
	debug_flags \|= DEBUG_PNP;
	#endif
	#if CONFIG_X86EMU_DEBUG_DISK
	debug_flags \|= DEBUG_DISK;
	#endif
	#if CONFIG_X86EMU_DEBUG_PMM
	debug_flags \|= DEBUG_PMM;
	#endif
	#if CONFIG_X86EMU_DEBUG_VBE
	debug_flags \|= DEBUG_VBE;
	#endif
	#if CONFIG_X86EMU_DEBUG_INT10
	debug_flags \|= DEBUG_PRINT_INT10;
	#endif
	#if CONFIG_X86EMU_DEBUG_INTERRUPTS
	debug_flags \|= DEBUG_INTR;
	#endif
	#if CONFIG_X86EMU_DEBUG_CHECK_VMEM_ACCESS
	debug_flags \|= DEBUG_CHECK_VMEM_ACCESS;
	#endif
	#if CONFIG_X86EMU_DEBUG_MEM
	debug_flags \|= DEBUG_MEM;
	#endif
	#if CONFIG_X86EMU_DEBUG_IO
	debug_flags \|= DEBUG_IO;
	#endif

	#endif
	if (biosmem_size < MIN_REQUIRED_VMEM_SIZE) {
	printf("Error: Not enough virtual memory: %x, required: %x!\n",
	biosmem_size, MIN_REQUIRED_VMEM_SIZE);
	return -1;
	}
	if (biosemu_dev_init(dev) != 0) {
	printf("Error initializing device!\n");
	return -1;
	}
	if (biosemu_dev_check_exprom(rom_addr) != 0) {
	printf("Error: Device Expansion ROM invalid!\n");
	return -1;
	}
	biosemu_add_special_memory(0, 0x500); // IVT + BDA
	biosemu_add_special_memory(OPTION_ROM_CODE_SEGMENT << 4, 0x10000); // option ROM

	rom_image = (u8 *) bios_device.img_addr;
	DEBUG_PRINTF("executing rom_image from %p\n", rom_image);
	DEBUG_PRINTF("biosmem at %p\n", biosmem);

	DEBUG_PRINTF("Image Size: %d\n", bios_device.img_size);

	// in case we jump somewhere unexpected, or execution is finished,
	// fill the biosmem with hlt instructions (0xf4)
	// But we have to be careful: If biosmem is 0x00000000 we're running
	// in the lower 1MB and we must not wipe memory like that.
	if (biosmem) {
	DEBUG_PRINTF("Clearing biosmem\n");
	memset(biosmem, 0xf4, biosmem_size);
	}

	X86EMU_setMemBase(biosmem, biosmem_size);

	DEBUG_PRINTF("membase set: %08x, size: %08x\n", (int) M.mem_base,
	(int) M.mem_size);

	// copy expansion ROM image to segment OPTION_ROM_CODE_SEGMENT
	// NOTE: this sometimes fails, some bytes are 0x00... so we compare
	// after copying and do some retries...
	u8 mem_img = (u8)(OPTION_ROM_CODE_SEGMENT << 4);
	u8 copy_count = 0;
	u8 cmp_result = 0;
	do {
	#if 0
	set_ci();
	memcpy(mem_img, rom_image, len);
	clr_ci();
	#else
	// memcpy fails... try copy byte-by-byte with set/clr_ci
	u8 c;
	for (i = 0; i < bios_device.img_size; i++) {
	set_ci();
	c = *(rom_image + i);
	if (c != *(rom_image + i)) {
	clr_ci();
	printf("Copy failed at: %x/%x\n", i,
	bios_device.img_size);
	printf("rom_image(%x): %x, mem_img(%x): %x\n",
	i, (rom_image + i), i, (mem_img + i));
	break;
	}
	clr_ci();
	my_wrb((u32)mem_img + i, c);
	}
	#endif
	copy_count++;
	set_ci();
	cmp_result = memcmp(mem_img, rom_image, bios_device.img_size);
	clr_ci();
	}
	while ((copy_count < 5) && (cmp_result != 0));
	if (cmp_result != 0) {
	printf
	("\nCopying Expansion ROM Image to Memory failed after %d retries! (%x)\n",
	copy_count, cmp_result);
	dump(rom_image, 0x20);
	dump(mem_img, 0x20);
	return 0;
	}
	// setup default Interrupt Vectors
	// some expansion ROMs seem to check for these addresses..
	// each handler is only an IRET (0xCF) instruction
	// ROM BIOS Int 10 Handler F000:F065
	my_wrl(0x10 * 4, 0xf000f065);
	my_wrb(0x000ff065, 0xcf);
	// ROM BIOS Int 11 Handler F000:F84D
	my_wrl(0x11 * 4, 0xf000f84d);
	my_wrb(0x000ff84d, 0xcf);
	// ROM BIOS Int 12 Handler F000:F841
	my_wrl(0x12 * 4, 0xf000f841);
	my_wrb(0x000ff841, 0xcf);
	// ROM BIOS Int 13 Handler F000:EC59
	my_wrl(0x13 * 4, 0xf000ec59);
	my_wrb(0x000fec59, 0xcf);
	// ROM BIOS Int 14 Handler F000:E739
	my_wrl(0x14 * 4, 0xf000e739);
	my_wrb(0x000fe739, 0xcf);
	// ROM BIOS Int 15 Handler F000:F859
	my_wrl(0x15 * 4, 0xf000f859);
	my_wrb(0x000ff859, 0xcf);
	// ROM BIOS Int 16 Handler F000:E82E
	my_wrl(0x16 * 4, 0xf000e82e);
	my_wrb(0x000fe82e, 0xcf);
	// ROM BIOS Int 17 Handler F000:EFD2
	my_wrl(0x17 * 4, 0xf000efd2);
	my_wrb(0x000fefd2, 0xcf);
	// ROM BIOS Int 1A Handler F000:FE6E
	my_wrl(0x1a * 4, 0xf000fe6e);
	my_wrb(0x000ffe6e, 0xcf);

	// setup BIOS Data Area (0000:04xx, or 0040:00xx)
	// we currently 0 this area, meaning "we dont have
	// any hardware" :-) no serial/parallel ports, floppys, ...
	memset(biosmem + 0x400, 0x0, 0x100);

	// at offset 13h in BDA is the memory size in kbytes
	my_wrw(0x413, biosmem_size / 1024);
	// at offset 0eh in BDA is the segment of the Extended BIOS Data Area
	// see setup further down
	my_wrw(0x40e, INITIAL_EBDA_SEGMENT);
	// TODO: setup BDA Video Data ( offset 49h-66h)
	// e.g. to store video mode, cursor position, ...
	// in int10 (done) handler and VBE Functions

	// TODO: setup BDA Fixed Disk Data
	// 74h: Fixed Disk Last Operation Status
	// 75h: Fixed Disk Number of Disk Drives

	// TODO: check BDA for further needed data...

	//setup Extended BIOS Data Area
	//we currently 0 this area
	memset(biosmem + (INITIAL_EBDA_SEGMENT << 4), 0, INITIAL_EBDA_SIZE);
	// at offset 0h in EBDA is the size of the EBDA in KB
	my_wrw((INITIAL_EBDA_SEGMENT << 4) + 0x0, INITIAL_EBDA_SIZE / 1024);
	//TODO: check for further needed EBDA data...

	// setup original ROM BIOS Area (F000:xxxx)
	const char *date = "06/11/99";
	for (i = 0; date[i]; i++)
	my_wrb(0xffff5 + i, date[i]);
	// set up eisa ident string
	const char *ident = "PCI_ISA";
	for (i = 0; ident[i]; i++)
	my_wrb(0xfffd9 + i, ident[i]);

	// write system model id for IBM-AT
	// according to "Ralf Browns Interrupt List" Int15 AH=C0 Table 515,
	// model FC is the original AT and also used in all DOSEMU Versions.
	my_wrb(0xFFFFE, 0xfc);

	//setup interrupt handler
	X86EMU_intrFuncs intrFuncs[256];
	for (i = 0; i < 256; i++)
	intrFuncs[i] = handleInterrupt;
	X86EMU_setupIntrFuncs(intrFuncs);
	X86EMU_setupPioFuncs(&my_pio_funcs);
	X86EMU_setupMemFuncs(&my_mem_funcs);

	//setup PMM struct in BIOS_DATA_SEGMENT, offset 0x0
	u8 pmm_length = pmm_setup(BIOS_DATA_SEGMENT, 0x0);
	if (pmm_length <= 0) {
	printf ("\nYABEL: Warning: PMM Area could not be setup. PMM not available (%x)\n",
	pmm_length);
	return 0;
	} else {
	CHECK_DBG(DEBUG_PMM) {
	/* test the PMM */
	pmm_test();
	/* and clean it again by calling pmm_setup... */
	pmm_length = pmm_setup(BIOS_DATA_SEGMENT, 0x0);
	}
	}
	// setup the CPU
	M.x86.R_AH = bios_device.bus;
	M.x86.R_AL = bios_device.devfn;
	M.x86.R_DX = 0x80;
	M.x86.R_EIP = 3;
	M.x86.R_CS = OPTION_ROM_CODE_SEGMENT;

	// Initialize stack and data segment
	M.x86.R_SS = STACK_SEGMENT;
	M.x86.R_SP = STACK_START_OFFSET;
	M.x86.R_DS = DATA_SEGMENT;

	// push a HLT instruction and a pointer to it onto the stack
	// any return will pop the pointer and jump to the HLT, thus
	// exiting (more or less) cleanly
	push_word(0xf4f4); // F4=HLT
	push_word(M.x86.R_SS);
	push_word(M.x86.R_SP + 2);

	CHECK_DBG(DEBUG_TRACE_X86EMU) {
	X86EMU_trace_on();
	#if 0
	} else {
	M.x86.debug \|= DEBUG_SAVE_IP_CS_F;
	M.x86.debug \|= DEBUG_DECODE_F;
	M.x86.debug \|= DEBUG_DECODE_NOPRINT_F;
	#endif
	}
	CHECK_DBG(DEBUG_JMP) {
	M.x86.debug \|= DEBUG_TRACEJMP_F;
	M.x86.debug \|= DEBUG_TRACEJMP_REGS_F;
	M.x86.debug \|= DEBUG_TRACECALL_F;
	M.x86.debug \|= DEBUG_TRACECALL_REGS_F;
	}

	DEBUG_PRINTF("Executing Initialization Vector...\n");
	X86EMU_exec();
	DEBUG_PRINTF("done\n");

	/* According to the PNP BIOS Spec, Option ROMs should upon exit, return
	* some boot device status in AX (see PNP BIOS Spec Section 3.3
	*/
	DEBUG_PRINTF_CS_IP("Option ROM Exit Status: %04x\n", M.x86.R_AX);
	#if CONFIG_X86EMU_DEBUG
	DEBUG_PRINTF("Exit Status Decode:\n");
	if (M.x86.R_AX & 0x100) { // bit 8
	DEBUG_PRINTF
	(" IPL Device supporting INT 13h Block Device Format:\n");
	switch (((M.x86.R_AX >> 4) & 0x3)) { // bits 5:4
	case 0:
	DEBUG_PRINTF(" No IPL Device attached\n");
	break;
	case 1:
	DEBUG_PRINTF(" IPL Device status unknown\n");
	break;
	case 2:
	DEBUG_PRINTF(" IPL Device attached\n");
	break;
	case 3:
	DEBUG_PRINTF(" IPL Device status RESERVED!!\n");
	break;
	}
	}
	if (M.x86.R_AX & 0x80) { // bit 7
	DEBUG_PRINTF
	(" Output Device supporting INT 10h Character Output:\n");
	switch (((M.x86.R_AX >> 4) & 0x3)) { // bits 5:4
	case 0:
	DEBUG_PRINTF(" No Display Device attached\n");
	break;
	case 1:
	DEBUG_PRINTF(" Display Device status unknown\n");
	break;
	case 2:
	DEBUG_PRINTF(" Display Device attached\n");
	break;
	case 3:
	DEBUG_PRINTF(" Display Device status RESERVED!!\n");
	break;
	}
	}
	if (M.x86.R_AX & 0x40) { // bit 6
	DEBUG_PRINTF
	(" Input Device supporting INT 9h Character Input:\n");
	switch (((M.x86.R_AX >> 4) & 0x3)) { // bits 5:4
	case 0:
	DEBUG_PRINTF(" No Input Device attached\n");
	break;
	case 1:
	DEBUG_PRINTF(" Input Device status unknown\n");
	break;
	case 2:
	DEBUG_PRINTF(" Input Device attached\n");
	break;
	case 3:
	DEBUG_PRINTF(" Input Device status RESERVED!!\n");
	break;
	}
	}
	#endif
	/* Check whether the stack is "clean" i.e. containing the HLT
	* instruction we pushed before executing and pointing to the original
	* stack address... indicating that the initialization probably was
	* successful
	*/
	if ((pop_word() == 0xf4f4) && (M.x86.R_SS == STACK_SEGMENT)
	&& (M.x86.R_SP == STACK_START_OFFSET)) {
	DEBUG_PRINTF("Stack is clean, initialization successfull!\n");
	} else {
	printf("Stack unclean, initialization probably NOT COMPLETE!\n");
	DEBUG_PRINTF("SS:SP = %04x:%04x, expected: %04x:%04x\n",
	M.x86.R_SS, M.x86.R_SP, STACK_SEGMENT,
	STACK_START_OFFSET);
	}

	// TODO: according to the BIOS Boot Spec initializations may be ended using INT18h and setting
	// the status.
	// We need to implement INT18 accordingly, pseudo code is in specsbbs101.pdf page 30
	// (also for Int19)
	return 0;
	}