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// 8086tiny: a tiny, highly functional, highly portable PC emulator/VM
// Copyright 2013-14, Adrian Cable (adrian.cable@gmail.com) - http://www.megalith.co.uk/8086tiny
//
// Revision 1.25
//
// This work is licensed under the MIT License. See included LICENSE.TXT.
# include <time.h>
//#include <sys/timeb.h>
struct timeb
{
time_t time ; /* Seconds since the epoch */
unsigned short millitm ;
short timezone ;
short dstflag ;
} ;
static int ftime ( struct timeb * tp )
{
unsigned counter = 0 ;
__asm__ volatile ( " int $0x40 " : " =a " ( counter ) : " a " ( 26 ) , " b " ( 9 ) ) ;
tp - > millitm = ( counter % 100 ) * 10 ;
return 0 ;
}
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/*
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# include <memory.h>
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*/
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# ifndef _WIN32
# include <unistd.h>
# include <fcntl.h>
# endif
# ifndef NO_GRAPHICS
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# include <SDL.h>
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# endif
// Emulator system constants
# define IO_PORT_COUNT 0x10000
# define RAM_SIZE 0x10FFF0
# define REGS_BASE 0xF0000
# define VIDEO_RAM_SIZE 0x10000
// Graphics/timer/keyboard update delays (explained later)
# ifndef GRAPHICS_UPDATE_DELAY
# define GRAPHICS_UPDATE_DELAY 36000 //1000 times
# endif
# define KEYBOARD_TIMER_UPDATE_DELAY 2000 //1000 times
// 16-bit register decodes
# define REG_AX 0
# define REG_CX 1
# define REG_DX 2
# define REG_BX 3
# define REG_SP 4
# define REG_BP 5
# define REG_SI 6
# define REG_DI 7
# define REG_ES 8
# define REG_CS 9
# define REG_SS 10
# define REG_DS 11
# define REG_ZERO 12
# define REG_SCRATCH 13
// 8-bit register decodes
# define REG_AL 0
# define REG_AH 1
# define REG_CL 2
# define REG_CH 3
# define REG_DL 4
# define REG_DH 5
# define REG_BL 6
# define REG_BH 7
// FLAGS register decodes
# define FLAG_CF 40
# define FLAG_PF 41
# define FLAG_AF 42
# define FLAG_ZF 43
# define FLAG_SF 44
# define FLAG_TF 45
# define FLAG_IF 46
# define FLAG_DF 47
# define FLAG_OF 48
// Lookup tables in the BIOS binary
# define TABLE_XLAT_OPCODE 8
# define TABLE_XLAT_SUBFUNCTION 9
# define TABLE_STD_FLAGS 10
# define TABLE_PARITY_FLAG 11
# define TABLE_BASE_INST_SIZE 12
# define TABLE_I_W_SIZE 13
# define TABLE_I_MOD_SIZE 14
# define TABLE_COND_JUMP_DECODE_A 15
# define TABLE_COND_JUMP_DECODE_B 16
# define TABLE_COND_JUMP_DECODE_C 17
# define TABLE_COND_JUMP_DECODE_D 18
# define TABLE_FLAGS_BITFIELDS 19
// Bitfields for TABLE_STD_FLAGS values
# define FLAGS_UPDATE_SZP 1
# define FLAGS_UPDATE_AO_ARITH 2
# define FLAGS_UPDATE_OC_LOGIC 4
// Helper macros
// Decode mod, r_m and reg fields in instruction
# define DECODE_RM_REG scratch2_uint = 4 * !i_mod, \
op_to_addr = rm_addr = i_mod < 3 ? SEGREG ( seg_override_en ? seg_override : bios_table_lookup [ scratch2_uint + 3 ] [ i_rm ] , bios_table_lookup [ scratch2_uint ] [ i_rm ] , regs16 [ bios_table_lookup [ scratch2_uint + 1 ] [ i_rm ] ] + bios_table_lookup [ scratch2_uint + 2 ] [ i_rm ] * i_data1 + ) : GET_REG_ADDR ( i_rm ) , \
op_from_addr = GET_REG_ADDR ( i_reg ) , \
i_d & & ( scratch_uint = op_from_addr , op_from_addr = rm_addr , op_to_addr = scratch_uint )
// Return memory-mapped register location (offset into mem array) for register #reg_id
# define GET_REG_ADDR(reg_id) (REGS_BASE + (i_w ? 2 * reg_id : 2 * reg_id + reg_id / 4 & 7))
// Returns number of top bit in operand (i.e. 8 for 8-bit operands, 16 for 16-bit operands)
# define TOP_BIT 8*(i_w + 1)
// Opcode execution unit helpers
# define OPCODE ;break; case
# define OPCODE_CHAIN ; case
// [I]MUL/[I]DIV/DAA/DAS/ADC/SBB helpers
# define MUL_MACRO(op_data_type,out_regs) (set_opcode(0x10), \
out_regs [ i_w + 1 ] = ( op_result = CAST ( op_data_type ) mem [ rm_addr ] * ( op_data_type ) * out_regs ) > > 16 , \
regs16 [ REG_AX ] = op_result , \
set_OF ( set_CF ( op_result - ( op_data_type ) op_result ) ) )
# define DIV_MACRO(out_data_type,in_data_type,out_regs) (scratch_int = CAST(out_data_type)mem[rm_addr]) && !(scratch2_uint = (in_data_type)(scratch_uint = (out_regs[i_w+1] << 16) + regs16[REG_AX]) / scratch_int, scratch2_uint - (out_data_type)scratch2_uint) ? out_regs[i_w+1] = scratch_uint - scratch_int * (*out_regs = scratch2_uint) : pc_interrupt(0)
# define DAA_DAS(op1,op2,mask,min) set_AF((((scratch2_uint = regs8[REG_AL]) & 0x0F) > 9) || regs8[FLAG_AF]) && (op_result = regs8[REG_AL] op1 6, set_CF(regs8[FLAG_CF] || (regs8[REG_AL] op2 scratch2_uint))), \
set_CF ( ( ( ( mask & 1 ? scratch2_uint : regs8 [ REG_AL ] ) & mask ) > min ) | | regs8 [ FLAG_CF ] ) & & ( op_result = regs8 [ REG_AL ] op1 0x60 )
# define ADC_SBB_MACRO(a) OP(a##= regs8[FLAG_CF] +), \
set_CF ( regs8 [ FLAG_CF ] & & ( op_result = = op_dest ) | | ( a op_result < a ( int ) op_dest ) ) , \
set_AF_OF_arith ( )
// Execute arithmetic/logic operations in emulator memory/registers
# define R_M_OP(dest,op,src) (i_w ? op_dest = CAST(unsigned short)dest, op_result = CAST(unsigned short)dest op (op_source = CAST(unsigned short)src) \
: ( op_dest = dest , op_result = dest op ( op_source = CAST ( unsigned char ) src ) ) )
# define MEM_OP(dest,op,src) R_M_OP(mem[dest],op,mem[src])
# define OP(op) MEM_OP(op_to_addr,op,op_from_addr)
// Increment or decrement a register #reg_id (usually SI or DI), depending on direction flag and operand size (given by i_w)
# define INDEX_INC(reg_id) (regs16[reg_id] -= (2 * regs8[FLAG_DF] - 1)*(i_w + 1))
// Helpers for stack operations
# define R_M_PUSH(a) (i_w = 1, R_M_OP(mem[SEGREG(REG_SS, REG_SP, --)], =, a))
# define R_M_POP(a) (i_w = 1, regs16[REG_SP] += 2, R_M_OP(a, =, mem[SEGREG(REG_SS, REG_SP, -2+)]))
// Convert segment:offset to linear address in emulator memory space
# define SEGREG(reg_seg,reg_ofs,op) 16 * regs16[reg_seg] + (unsigned short)(op regs16[reg_ofs])
// Returns sign bit of an 8-bit or 16-bit operand
# define SIGN_OF(a) (1 & (i_w ? CAST(short)a : a) >> (TOP_BIT - 1))
// Reinterpretation cast
# define CAST(a) *(a*)&
// Keyboard driver for console. This may need changing for UNIX/non-UNIX platforms
# ifdef _WIN32
# define KEYBOARD_DRIVER kbhit() && (mem[0x4A6] = getch(), pc_interrupt(7))
# else
//#define KEYBOARD_DRIVER read(0, mem + 0x4A6, 1) && (int8_asap = (mem[0x4A6] == 0x1B), pc_interrupt(7))
# define KEYBOARD_DRIVER kbhit() && (mem[0x4A6] = getch(), pc_interrupt(7))
# endif
// Keyboard driver for SDL
# ifdef NO_GRAPHICS
# define SDL_KEYBOARD_DRIVER KEYBOARD_DRIVER
# else
# define SDL_KEYBOARD_DRIVER sdl_screen ? SDL_PollEvent(&sdl_event) && (sdl_event.type == SDL_KEYDOWN || sdl_event.type == SDL_KEYUP) && (scratch_uint = sdl_event.key.keysym.unicode, scratch2_uint = sdl_event.key.keysym.mod, CAST(short)mem[0x4A6] = 0x400 + 0x800*!!(scratch2_uint & KMOD_ALT) + 0x1000*!!(scratch2_uint & KMOD_SHIFT) + 0x2000*!!(scratch2_uint & KMOD_CTRL) + 0x4000*(sdl_event.type == SDL_KEYUP) + ((!scratch_uint || scratch_uint > 0x7F) ? sdl_event.key.keysym.sym : scratch_uint), pc_interrupt(7)) : (KEYBOARD_DRIVER)
# endif
// Global variable definitions
unsigned char mem [ RAM_SIZE ] , io_ports [ IO_PORT_COUNT ] , * opcode_stream , * regs8 , i_rm , i_w , i_reg , i_mod , i_mod_size , i_d , i_reg4bit , raw_opcode_id , xlat_opcode_id , extra , rep_mode , seg_override_en , rep_override_en , trap_flag , int8_asap , scratch_uchar , io_hi_lo , * vid_mem_base , spkr_en , bios_table_lookup [ 20 ] [ 256 ] ;
unsigned short * regs16 , reg_ip , seg_override , file_index , wave_counter ;
unsigned int op_source , op_dest , rm_addr , op_to_addr , op_from_addr , i_data0 , i_data1 , i_data2 , scratch_uint , scratch2_uint , inst_counter , set_flags_type , GRAPHICS_X , GRAPHICS_Y , pixel_colors [ 16 ] , vmem_ctr ;
int op_result , disk [ 3 ] , scratch_int ;
time_t clock_buf ;
struct timeb ms_clock ;
# ifndef NO_GRAPHICS
SDL_AudioSpec sdl_audio = { 44100 , AUDIO_U8 , 1 , 0 , 128 } ;
SDL_AudioSpec sdl_audio_obt = { 44100 , AUDIO_U8 , 1 , 0 , 128 } ;
SDL_Surface * sdl_screen ;
SDL_Event sdl_event ;
unsigned short vid_addr_lookup [ VIDEO_RAM_SIZE ] , cga_colors [ 4 ] = { 0 /* Black */ , 0x1F1F /* Cyan */ , 0xE3E3 /* Magenta */ , 0xFFFF /* White */ } ;
# endif
// Helper functions
// Set carry flag
char set_CF ( int new_CF )
{
return regs8 [ FLAG_CF ] = ! ! new_CF ;
}
// Set auxiliary flag
char set_AF ( int new_AF )
{
return regs8 [ FLAG_AF ] = ! ! new_AF ;
}
// Set overflow flag
char set_OF ( int new_OF )
{
return regs8 [ FLAG_OF ] = ! ! new_OF ;
}
// Set auxiliary and overflow flag after arithmetic operations
char set_AF_OF_arith ( )
{
set_AF ( ( op_source ^ = op_dest ^ op_result ) & 0x10 ) ;
if ( op_result = = op_dest )
return set_OF ( 0 ) ;
else
return set_OF ( 1 & ( regs8 [ FLAG_CF ] ^ op_source > > ( TOP_BIT - 1 ) ) ) ;
}
// Assemble and return emulated CPU FLAGS register in scratch_uint
void make_flags ( )
{
scratch_uint = 0xF002 ; // 8086 has reserved and unused flags set to 1
for ( int i = 9 ; i - - ; )
scratch_uint + = regs8 [ FLAG_CF + i ] < < bios_table_lookup [ TABLE_FLAGS_BITFIELDS ] [ i ] ;
}
// Set emulated CPU FLAGS register from regs8[FLAG_xx] values
void set_flags ( int new_flags )
{
for ( int i = 9 ; i - - ; )
regs8 [ FLAG_CF + i ] = ! ! ( 1 < < bios_table_lookup [ TABLE_FLAGS_BITFIELDS ] [ i ] & new_flags ) ;
}
// Convert raw opcode to translated opcode index. This condenses a large number of different encodings of similar
// instructions into a much smaller number of distinct functions, which we then execute
void set_opcode ( unsigned char opcode )
{
xlat_opcode_id = bios_table_lookup [ TABLE_XLAT_OPCODE ] [ raw_opcode_id = opcode ] ;
extra = bios_table_lookup [ TABLE_XLAT_SUBFUNCTION ] [ opcode ] ;
i_mod_size = bios_table_lookup [ TABLE_I_MOD_SIZE ] [ opcode ] ;
set_flags_type = bios_table_lookup [ TABLE_STD_FLAGS ] [ opcode ] ;
}
// Execute INT #interrupt_num on the emulated machine
char pc_interrupt ( unsigned char interrupt_num )
{
set_opcode ( 0xCD ) ; // Decode like INT
make_flags ( ) ;
R_M_PUSH ( scratch_uint ) ;
R_M_PUSH ( regs16 [ REG_CS ] ) ;
R_M_PUSH ( reg_ip ) ;
MEM_OP ( REGS_BASE + 2 * REG_CS , = , 4 * interrupt_num + 2 ) ;
R_M_OP ( reg_ip , = , mem [ 4 * interrupt_num ] ) ;
return regs8 [ FLAG_TF ] = regs8 [ FLAG_IF ] = 0 ;
}
// AAA and AAS instructions - which_operation is +1 for AAA, and -1 for AAS
int AAA_AAS ( char which_operation )
{
return ( regs16 [ REG_AX ] + = 262 * which_operation * set_AF ( set_CF ( ( ( regs8 [ REG_AL ] & 0x0F ) > 9 ) | | regs8 [ FLAG_AF ] ) ) , regs8 [ REG_AL ] & = 0x0F ) ;
}
# ifndef NO_GRAPHICS
void audio_callback ( void * data , unsigned char * stream , int len )
{
for ( int i = 0 ; i < len ; i + + )
stream [ i ] = ( spkr_en = = 3 ) & & CAST ( unsigned short ) mem [ 0x4AA ] ? - ( ( 54 * wave_counter + + / CAST ( unsigned short ) mem [ 0x4AA ] ) & 1 ) : sdl_audio . silence ;
spkr_en = io_ports [ 0x61 ] & 3 ;
}
# endif
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# include <conio.h>
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# define kbhit con_kbhit
# define getch con_getch
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// Emulator entry point
int main ( int argc , char * * argv )
{
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con_set_title ( " 8086tiny " ) ;
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//freopen("OUT", "w" ,stdout);
# ifndef NO_GRAPHICS
// Initialise SDL
SDL_Init ( SDL_INIT_AUDIO ) ;
sdl_audio . callback = audio_callback ;
# ifdef _WIN32
sdl_audio . samples = 512 ;
# endif
SDL_OpenAudio ( & sdl_audio , & sdl_audio_obt ) ;
# endif
// regs16 and reg8 point to F000:0, the start of memory-mapped registers. CS is initialised to F000
regs16 = ( unsigned short * ) ( regs8 = mem + REGS_BASE ) ;
regs16 [ REG_CS ] = 0xF000 ;
// Trap flag off
regs8 [ FLAG_TF ] = 0 ;
// Set DL equal to the boot device: 0 for the FD, or 0x80 for the HD. Normally, boot from the FD.
// But, if the HD image file is prefixed with @, then boot from the HD
regs8 [ REG_DL ] = ( ( argc > 3 ) & & ( * argv [ 3 ] = = ' @ ' ) ) ? argv [ 3 ] + + , 0x80 : 0 ;
// Open BIOS (file id disk[2]), floppy disk image (disk[1]), and hard disk image (disk[0]) if specified
for ( file_index = 3 ; file_index ; )
disk [ - - file_index ] = * + + argv ? open ( * argv , 32898 ) : 0 ;
// Set CX:AX equal to the hard disk image size, if present
CAST ( unsigned ) regs16 [ REG_AX ] = * disk ? lseek ( * disk , 0 , 2 ) > > 9 : 0 ;
// Load BIOS image into F000:0100, and set IP to 0100
read ( disk [ 2 ] , regs8 + ( reg_ip = 0x100 ) , 0xFF00 ) ;
// Load instruction decoding helper table
for ( int i = 0 ; i < 20 ; i + + )
for ( int j = 0 ; j < 256 ; j + + )
bios_table_lookup [ i ] [ j ] = regs8 [ regs16 [ 0x81 + i ] + j ] ;
// Instruction execution loop. Terminates if CS:IP = 0:0
for ( ; opcode_stream = mem + 16 * regs16 [ REG_CS ] + reg_ip , opcode_stream ! = mem ; )
{
// Set up variables to prepare for decoding an opcode
set_opcode ( * opcode_stream ) ;
// Extract i_w and i_d fields from instruction
i_w = ( i_reg4bit = raw_opcode_id & 7 ) & 1 ;
i_d = i_reg4bit / 2 & 1 ;
// Extract instruction data fields
i_data0 = CAST ( short ) opcode_stream [ 1 ] ;
i_data1 = CAST ( short ) opcode_stream [ 2 ] ;
i_data2 = CAST ( short ) opcode_stream [ 3 ] ;
// seg_override_en and rep_override_en contain number of instructions to hold segment override and REP prefix respectively
if ( seg_override_en )
seg_override_en - - ;
if ( rep_override_en )
rep_override_en - - ;
// i_mod_size > 0 indicates that opcode uses i_mod/i_rm/i_reg, so decode them
if ( i_mod_size )
{
i_mod = ( i_data0 & 0xFF ) > > 6 ;
i_rm = i_data0 & 7 ;
i_reg = i_data0 / 8 & 7 ;
if ( ( ! i_mod & & i_rm = = 6 ) | | ( i_mod = = 2 ) )
i_data2 = CAST ( short ) opcode_stream [ 4 ] ;
else if ( i_mod ! = 1 )
i_data2 = i_data1 ;
else // If i_mod is 1, operand is (usually) 8 bits rather than 16 bits
i_data1 = ( char ) i_data1 ;
DECODE_RM_REG ;
}
// Instruction execution unit
switch ( xlat_opcode_id )
{
OPCODE_CHAIN 0 : // Conditional jump (JAE, JNAE, etc.)
// i_w is the invert flag, e.g. i_w == 1 means JNAE, whereas i_w == 0 means JAE
scratch_uchar = raw_opcode_id / 2 & 7 ;
reg_ip + = ( char ) i_data0 * ( i_w ^ ( regs8 [ bios_table_lookup [ TABLE_COND_JUMP_DECODE_A ] [ scratch_uchar ] ] | | regs8 [ bios_table_lookup [ TABLE_COND_JUMP_DECODE_B ] [ scratch_uchar ] ] | | regs8 [ bios_table_lookup [ TABLE_COND_JUMP_DECODE_C ] [ scratch_uchar ] ] ^ regs8 [ bios_table_lookup [ TABLE_COND_JUMP_DECODE_D ] [ scratch_uchar ] ] ) )
OPCODE 1 : // MOV reg, imm
i_w = ! ! ( raw_opcode_id & 8 ) ;
R_M_OP ( mem [ GET_REG_ADDR ( i_reg4bit ) ] , = , i_data0 )
OPCODE 3 : // PUSH regs16
R_M_PUSH ( regs16 [ i_reg4bit ] )
OPCODE 4 : // POP regs16
R_M_POP ( regs16 [ i_reg4bit ] )
OPCODE 2 : // INC|DEC regs16
i_w = 1 ;
i_d = 0 ;
i_reg = i_reg4bit ;
DECODE_RM_REG ;
i_reg = extra
OPCODE_CHAIN 5 : // INC|DEC|JMP|CALL|PUSH
if ( i_reg < 2 ) // INC|DEC
MEM_OP ( op_from_addr , + = 1 - 2 * i_reg + , REGS_BASE + 2 * REG_ZERO ) ,
op_source = 1 ,
set_AF_OF_arith ( ) ,
set_OF ( op_dest + 1 - i_reg = = 1 < < ( TOP_BIT - 1 ) ) ,
( xlat_opcode_id = = 5 ) & & ( set_opcode ( 0x10 ) , 0 ) ; // Decode like ADC
else if ( i_reg ! = 6 ) // JMP|CALL
i_reg - 3 | | R_M_PUSH ( regs16 [ REG_CS ] ) , // CALL (far)
i_reg & 2 & & R_M_PUSH ( reg_ip + 2 + i_mod * ( i_mod ! = 3 ) + 2 * ( ! i_mod & & i_rm = = 6 ) ) , // CALL (near or far)
i_reg & 1 & & ( regs16 [ REG_CS ] = CAST ( short ) mem [ op_from_addr + 2 ] ) , // JMP|CALL (far)
R_M_OP ( reg_ip , = , mem [ op_from_addr ] ) ,
set_opcode ( 0x9A ) ; // Decode like CALL
else // PUSH
R_M_PUSH ( mem [ rm_addr ] )
OPCODE 6 : // TEST r/m, imm16 / NOT|NEG|MUL|IMUL|DIV|IDIV reg
op_to_addr = op_from_addr ;
switch ( i_reg )
{
OPCODE_CHAIN 0 : // TEST
set_opcode ( 0x20 ) ; // Decode like AND
reg_ip + = i_w + 1 ;
R_M_OP ( mem [ op_to_addr ] , & , i_data2 )
OPCODE 2 : // NOT
OP ( = ~ )
OPCODE 3 : // NEG
OP ( = - ) ;
op_dest = 0 ;
set_opcode ( 0x28 ) ; // Decode like SUB
set_CF ( op_result > op_dest )
OPCODE 4 : // MUL
i_w ? MUL_MACRO ( unsigned short , regs16 ) : MUL_MACRO ( unsigned char , regs8 )
OPCODE 5 : // IMUL
i_w ? MUL_MACRO ( short , regs16 ) : MUL_MACRO ( char , regs8 )
OPCODE 6 : // DIV
i_w ? DIV_MACRO ( unsigned short , unsigned , regs16 ) : DIV_MACRO ( unsigned char , unsigned short , regs8 )
OPCODE 7 : // IDIV
i_w ? DIV_MACRO ( short , int , regs16 ) : DIV_MACRO ( char , short , regs8 ) ;
}
OPCODE 7 : // ADD|OR|ADC|SBB|AND|SUB|XOR|CMP AL/AX, immed
rm_addr = REGS_BASE ;
i_data2 = i_data0 ;
i_mod = 3 ;
i_reg = extra ;
reg_ip - - ;
OPCODE_CHAIN 8 : // ADD|OR|ADC|SBB|AND|SUB|XOR|CMP reg, immed
op_to_addr = rm_addr ;
regs16 [ REG_SCRATCH ] = ( i_d | = ! i_w ) ? ( char ) i_data2 : i_data2 ;
op_from_addr = REGS_BASE + 2 * REG_SCRATCH ;
reg_ip + = ! i_d + 1 ;
set_opcode ( 0x08 * ( extra = i_reg ) ) ;
OPCODE_CHAIN 9 : // ADD|OR|ADC|SBB|AND|SUB|XOR|CMP|MOV reg, r/m
switch ( extra )
{
OPCODE_CHAIN 0 : // ADD
OP ( + = ) ,
set_CF ( op_result < op_dest )
OPCODE 1 : // OR
OP ( | = )
OPCODE 2 : // ADC
ADC_SBB_MACRO ( + )
OPCODE 3 : // SBB
ADC_SBB_MACRO ( - )
OPCODE 4 : // AND
OP ( & = )
OPCODE 5 : // SUB
OP ( - = ) ,
set_CF ( op_result > op_dest )
OPCODE 6 : // XOR
OP ( ^ = )
OPCODE 7 : // CMP
OP ( - ) ,
set_CF ( op_result > op_dest )
OPCODE 8 : // MOV
OP ( = ) ;
}
OPCODE 10 : // MOV sreg, r/m | POP r/m | LEA reg, r/m
if ( ! i_w ) // MOV
i_w = 1 ,
i_reg + = 8 ,
DECODE_RM_REG ,
OP ( = ) ;
else if ( ! i_d ) // LEA
seg_override_en = 1 ,
seg_override = REG_ZERO ,
DECODE_RM_REG ,
R_M_OP ( mem [ op_from_addr ] , = , rm_addr ) ;
else // POP
R_M_POP ( mem [ rm_addr ] )
OPCODE 11 : // MOV AL/AX, [loc]
i_mod = i_reg = 0 ;
i_rm = 6 ;
i_data1 = i_data0 ;
DECODE_RM_REG ;
MEM_OP ( op_from_addr , = , op_to_addr )
OPCODE 12 : // ROL|ROR|RCL|RCR|SHL|SHR|???|SAR reg/mem, 1/CL/imm (80186)
scratch2_uint = SIGN_OF ( mem [ rm_addr ] ) ,
scratch_uint = extra ? // xxx reg/mem, imm
+ + reg_ip ,
( char ) i_data1
: // xxx reg/mem, CL
i_d
? 31 & regs8 [ REG_CL ]
: // xxx reg/mem, 1
1 ;
if ( scratch_uint )
{
if ( i_reg < 4 ) // Rotate operations
scratch_uint % = i_reg / 2 + TOP_BIT ,
R_M_OP ( scratch2_uint , = , mem [ rm_addr ] ) ;
if ( i_reg & 1 ) // Rotate/shift right operations
R_M_OP ( mem [ rm_addr ] , > > = , scratch_uint ) ;
else // Rotate/shift left operations
R_M_OP ( mem [ rm_addr ] , < < = , scratch_uint ) ;
if ( i_reg > 3 ) // Shift operations
set_opcode ( 0x10 ) ; // Decode like ADC
if ( i_reg > 4 ) // SHR or SAR
set_CF ( op_dest > > ( scratch_uint - 1 ) & 1 ) ;
}
switch ( i_reg )
{
OPCODE_CHAIN 0 : // ROL
R_M_OP ( mem [ rm_addr ] , + = , scratch2_uint > > ( TOP_BIT - scratch_uint ) ) ;
set_OF ( SIGN_OF ( op_result ) ^ set_CF ( op_result & 1 ) )
OPCODE 1 : // ROR
scratch2_uint & = ( 1 < < scratch_uint ) - 1 ,
R_M_OP ( mem [ rm_addr ] , + = , scratch2_uint < < ( TOP_BIT - scratch_uint ) ) ;
set_OF ( SIGN_OF ( op_result * 2 ) ^ set_CF ( SIGN_OF ( op_result ) ) )
OPCODE 2 : // RCL
R_M_OP ( mem [ rm_addr ] , + = ( regs8 [ FLAG_CF ] < < ( scratch_uint - 1 ) ) + , scratch2_uint > > ( 1 + TOP_BIT - scratch_uint ) ) ;
set_OF ( SIGN_OF ( op_result ) ^ set_CF ( scratch2_uint & 1 < < ( TOP_BIT - scratch_uint ) ) )
OPCODE 3 : // RCR
R_M_OP ( mem [ rm_addr ] , + = ( regs8 [ FLAG_CF ] < < ( TOP_BIT - scratch_uint ) ) + , scratch2_uint < < ( 1 + TOP_BIT - scratch_uint ) ) ;
set_CF ( scratch2_uint & 1 < < ( scratch_uint - 1 ) ) ;
set_OF ( SIGN_OF ( op_result ) ^ SIGN_OF ( op_result * 2 ) )
OPCODE 4 : // SHL
set_OF ( SIGN_OF ( op_result ) ^ set_CF ( SIGN_OF ( op_dest < < ( scratch_uint - 1 ) ) ) )
OPCODE 5 : // SHR
set_OF ( SIGN_OF ( op_dest ) )
OPCODE 7 : // SAR
scratch_uint < TOP_BIT | | set_CF ( scratch2_uint ) ;
set_OF ( 0 ) ;
R_M_OP ( mem [ rm_addr ] , + = , scratch2_uint * = ~ ( ( ( 1 < < TOP_BIT ) - 1 ) > > scratch_uint ) ) ;
}
OPCODE 13 : // LOOPxx|JCZX
scratch_uint = ! ! - - regs16 [ REG_CX ] ;
switch ( i_reg4bit )
{
OPCODE_CHAIN 0 : // LOOPNZ
scratch_uint & = ! regs8 [ FLAG_ZF ]
OPCODE 1 : // LOOPZ
scratch_uint & = regs8 [ FLAG_ZF ]
OPCODE 3 : // JCXXZ
scratch_uint = ! + + regs16 [ REG_CX ] ;
}
reg_ip + = scratch_uint * ( char ) i_data0
OPCODE 14 : // JMP | CALL short/near
reg_ip + = 3 - i_d ;
if ( ! i_w )
{
if ( i_d ) // JMP far
reg_ip = 0 ,
regs16 [ REG_CS ] = i_data2 ;
else // CALL
R_M_PUSH ( reg_ip ) ;
}
reg_ip + = i_d & & i_w ? ( char ) i_data0 : i_data0
OPCODE 15 : // TEST reg, r/m
MEM_OP ( op_from_addr , & , op_to_addr )
OPCODE 16 : // XCHG AX, regs16
i_w = 1 ;
op_to_addr = REGS_BASE ;
op_from_addr = GET_REG_ADDR ( i_reg4bit ) ;
OPCODE_CHAIN 24 : // NOP|XCHG reg, r/m
if ( op_to_addr ! = op_from_addr )
OP ( ^ = ) ,
MEM_OP ( op_from_addr , ^ = , op_to_addr ) ,
OP ( ^ = )
OPCODE 17 : // MOVSx (extra=0)|STOSx (extra=1)|LODSx (extra=2)
scratch2_uint = seg_override_en ? seg_override : REG_DS ;
for ( scratch_uint = rep_override_en ? regs16 [ REG_CX ] : 1 ; scratch_uint ; scratch_uint - - )
{
MEM_OP ( extra < 2 ? SEGREG ( REG_ES , REG_DI , ) : REGS_BASE , = , extra & 1 ? REGS_BASE : SEGREG ( scratch2_uint , REG_SI , ) ) ,
extra & 1 | | INDEX_INC ( REG_SI ) ,
extra & 2 | | INDEX_INC ( REG_DI ) ;
}
if ( rep_override_en )
regs16 [ REG_CX ] = 0
OPCODE 18 : // CMPSx (extra=0)|SCASx (extra=1)
scratch2_uint = seg_override_en ? seg_override : REG_DS ;
if ( ( scratch_uint = rep_override_en ? regs16 [ REG_CX ] : 1 ) )
{
for ( ; scratch_uint ; rep_override_en | | scratch_uint - - )
{
MEM_OP ( extra ? REGS_BASE : SEGREG ( scratch2_uint , REG_SI , ) , - , SEGREG ( REG_ES , REG_DI , ) ) ,
extra | | INDEX_INC ( REG_SI ) ,
INDEX_INC ( REG_DI ) , rep_override_en & & ! ( - - regs16 [ REG_CX ] & & ( ! op_result = = rep_mode ) ) & & ( scratch_uint = 0 ) ;
}
set_flags_type = FLAGS_UPDATE_SZP | FLAGS_UPDATE_AO_ARITH ; // Funge to set SZP/AO flags
set_CF ( op_result > op_dest ) ;
}
OPCODE 19 : // RET|RETF|IRET
i_d = i_w ;
R_M_POP ( reg_ip ) ;
if ( extra ) // IRET|RETF|RETF imm16
R_M_POP ( regs16 [ REG_CS ] ) ;
if ( extra & 2 ) // IRET
set_flags ( R_M_POP ( scratch_uint ) ) ;
else if ( ! i_d ) // RET|RETF imm16
regs16 [ REG_SP ] + = i_data0
OPCODE 20 : // MOV r/m, immed
R_M_OP ( mem [ op_from_addr ] , = , i_data2 )
OPCODE 21 : // IN AL/AX, DX/imm8
io_ports [ 0x20 ] = 0 ; // PIC EOI
io_ports [ 0x42 ] = - - io_ports [ 0x40 ] ; // PIT channel 0/2 read placeholder
io_ports [ 0x3DA ] ^ = 9 ; // CGA refresh
scratch_uint = extra ? regs16 [ REG_DX ] : ( unsigned char ) i_data0 ;
scratch_uint = = 0x60 & & ( io_ports [ 0x64 ] = 0 ) ; // Scancode read flag
scratch_uint = = 0x3D5 & & ( io_ports [ 0x3D4 ] > > 1 = = 7 ) & & ( io_ports [ 0x3D5 ] = ( ( mem [ 0x49E ] * 80 + mem [ 0x49D ] + CAST ( short ) mem [ 0x4AD ] ) & ( io_ports [ 0x3D4 ] & 1 ? 0xFF : 0xFF00 ) ) > > ( io_ports [ 0x3D4 ] & 1 ? 0 : 8 ) ) ; // CRT cursor position
R_M_OP ( regs8 [ REG_AL ] , = , io_ports [ scratch_uint ] ) ;
OPCODE 22 : // OUT DX/imm8, AL/AX
scratch_uint = extra ? regs16 [ REG_DX ] : ( unsigned char ) i_data0 ;
R_M_OP ( io_ports [ scratch_uint ] , = , regs8 [ REG_AL ] ) ;
scratch_uint = = 0x61 & & ( io_hi_lo = 0 , spkr_en | = regs8 [ REG_AL ] & 3 ) ; // Speaker control
( scratch_uint = = 0x40 | | scratch_uint = = 0x42 ) & & ( io_ports [ 0x43 ] & 6 ) & & ( mem [ 0x469 + scratch_uint - ( io_hi_lo ^ = 1 ) ] = regs8 [ REG_AL ] ) ; // PIT rate programming
# ifndef NO_GRAPHICS
scratch_uint = = 0x43 & & ( io_hi_lo = 0 , regs8 [ REG_AL ] > > 6 = = 2 ) & & ( SDL_PauseAudio ( ( regs8 [ REG_AL ] & 0xF7 ) ! = 0xB6 ) , 0 ) ; // Speaker enable
# endif
scratch_uint = = 0x3D5 & & ( io_ports [ 0x3D4 ] > > 1 = = 6 ) & & ( mem [ 0x4AD + ! ( io_ports [ 0x3D4 ] & 1 ) ] = regs8 [ REG_AL ] ) ; // CRT video RAM start offset
scratch_uint = = 0x3D5 & & ( io_ports [ 0x3D4 ] > > 1 = = 7 ) & & ( scratch2_uint = ( ( mem [ 0x49E ] * 80 + mem [ 0x49D ] + CAST ( short ) mem [ 0x4AD ] ) & ( io_ports [ 0x3D4 ] & 1 ? 0xFF00 : 0xFF ) ) + ( regs8 [ REG_AL ] < < ( io_ports [ 0x3D4 ] & 1 ? 0 : 8 ) ) - CAST ( short ) mem [ 0x4AD ] , mem [ 0x49D ] = scratch2_uint % 80 , mem [ 0x49E ] = scratch2_uint / 80 ) ; // CRT cursor position
scratch_uint = = 0x3B5 & & io_ports [ 0x3B4 ] = = 1 & & ( GRAPHICS_X = regs8 [ REG_AL ] * 16 ) ; // Hercules resolution reprogramming. Defaults are set in the BIOS
scratch_uint = = 0x3B5 & & io_ports [ 0x3B4 ] = = 6 & & ( GRAPHICS_Y = regs8 [ REG_AL ] * 4 ) ;
OPCODE 23 : // REPxx
rep_override_en = 2 ;
rep_mode = i_w ;
seg_override_en & & seg_override_en + +
OPCODE 25 : // PUSH reg
R_M_PUSH ( regs16 [ extra ] )
OPCODE 26 : // POP reg
R_M_POP ( regs16 [ extra ] )
OPCODE 27 : // xS: segment overrides
seg_override_en = 2 ;
seg_override = extra ;
rep_override_en & & rep_override_en + +
OPCODE 28 : // DAA/DAS
i_w = 0 ;
extra ? DAA_DAS ( - = , > = , 0xFF , 0x99 ) : DAA_DAS ( + = , < , 0xF0 , 0x90 ) // extra = 0 for DAA, 1 for DAS
OPCODE 29 : // AAA/AAS
op_result = AAA_AAS ( extra - 1 )
OPCODE 30 : // CBW
regs8 [ REG_AH ] = - SIGN_OF ( regs8 [ REG_AL ] )
OPCODE 31 : // CWD
regs16 [ REG_DX ] = - SIGN_OF ( regs16 [ REG_AX ] )
OPCODE 32 : // CALL FAR imm16:imm16
R_M_PUSH ( regs16 [ REG_CS ] ) ;
R_M_PUSH ( reg_ip + 5 ) ;
regs16 [ REG_CS ] = i_data2 ;
reg_ip = i_data0
OPCODE 33 : // PUSHF
make_flags ( ) ;
R_M_PUSH ( scratch_uint )
OPCODE 34 : // POPF
set_flags ( R_M_POP ( scratch_uint ) )
OPCODE 35 : // SAHF
make_flags ( ) ;
set_flags ( ( scratch_uint & 0xFF00 ) + regs8 [ REG_AH ] )
OPCODE 36 : // LAHF
make_flags ( ) ,
regs8 [ REG_AH ] = scratch_uint
OPCODE 37 : // LES|LDS reg, r/m
i_w = i_d = 1 ;
DECODE_RM_REG ;
OP ( = ) ;
MEM_OP ( REGS_BASE + extra , = , rm_addr + 2 )
OPCODE 38 : // INT 3
+ + reg_ip ;
pc_interrupt ( 3 )
OPCODE 39 : // INT imm8
reg_ip + = 2 ;
pc_interrupt ( i_data0 )
OPCODE 40 : // INTO
+ + reg_ip ;
regs8 [ FLAG_OF ] & & pc_interrupt ( 4 )
OPCODE 41 : // AAM
if ( i_data0 & = 0xFF )
regs8 [ REG_AH ] = regs8 [ REG_AL ] / i_data0 ,
op_result = regs8 [ REG_AL ] % = i_data0 ;
else // Divide by zero
pc_interrupt ( 0 )
OPCODE 42 : // AAD
i_w = 0 ;
regs16 [ REG_AX ] = op_result = 0xFF & regs8 [ REG_AL ] + i_data0 * regs8 [ REG_AH ]
OPCODE 43 : // SALC
regs8 [ REG_AL ] = - regs8 [ FLAG_CF ]
OPCODE 44 : // XLAT
regs8 [ REG_AL ] = mem [ SEGREG ( seg_override_en ? seg_override : REG_DS , REG_BX , regs8 [ REG_AL ] + ) ]
OPCODE 45 : // CMC
regs8 [ FLAG_CF ] ^ = 1
OPCODE 46 : // CLC|STC|CLI|STI|CLD|STD
regs8 [ extra / 2 ] = extra & 1
OPCODE 47 : // TEST AL/AX, immed
R_M_OP ( regs8 [ REG_AL ] , & , i_data0 )
OPCODE 48 : // Emulator-specific 0F xx opcodes
switch ( ( char ) i_data0 )
{
OPCODE_CHAIN 0 : // PUTCHAR_AL
write ( 1 , regs8 , 1 ) ;
2021-01-05 18:23:43 +01:00
// printf("%c", regs8[0]);
2014-12-01 12:16:20 +01:00
OPCODE 1 : // GET_RTC
time ( & clock_buf ) ;
ftime ( & ms_clock ) ;
memcpy ( mem + SEGREG ( REG_ES , REG_BX , ) , localtime ( & clock_buf ) , sizeof ( struct tm ) ) ;
CAST ( short ) mem [ SEGREG ( REG_ES , REG_BX , 36 + ) ] = ms_clock . millitm ;
OPCODE 2 : // DISK_READ
OPCODE_CHAIN 3 : // DISK_WRITE
regs8 [ REG_AL ] = ~ lseek ( disk [ regs8 [ REG_DL ] ] , CAST ( unsigned ) regs16 [ REG_BP ] < < 9 , 0 )
? ( ( char ) i_data0 = = 3 ? ( int ( * ) ( ) ) write : ( int ( * ) ( ) ) read ) ( disk [ regs8 [ REG_DL ] ] , mem + SEGREG ( REG_ES , REG_BX , ) , regs16 [ REG_AX ] )
: 0 ;
}
}
// Increment instruction pointer by computed instruction length. Tables in the BIOS binary
// help us here.
reg_ip + = ( i_mod * ( i_mod ! = 3 ) + 2 * ( ! i_mod & & i_rm = = 6 ) ) * i_mod_size + bios_table_lookup [ TABLE_BASE_INST_SIZE ] [ raw_opcode_id ] + bios_table_lookup [ TABLE_I_W_SIZE ] [ raw_opcode_id ] * ( i_w + 1 ) ;
// If instruction needs to update SF, ZF and PF, set them as appropriate
if ( set_flags_type & FLAGS_UPDATE_SZP )
{
regs8 [ FLAG_SF ] = SIGN_OF ( op_result ) ;
regs8 [ FLAG_ZF ] = ! op_result ;
regs8 [ FLAG_PF ] = bios_table_lookup [ TABLE_PARITY_FLAG ] [ ( unsigned char ) op_result ] ;
// If instruction is an arithmetic or logic operation, also set AF/OF/CF as appropriate.
if ( set_flags_type & FLAGS_UPDATE_AO_ARITH )
set_AF_OF_arith ( ) ;
if ( set_flags_type & FLAGS_UPDATE_OC_LOGIC )
set_CF ( 0 ) , set_OF ( 0 ) ;
}
// Poll timer/keyboard every KEYBOARD_TIMER_UPDATE_DELAY instructions
if ( ! ( + + inst_counter % KEYBOARD_TIMER_UPDATE_DELAY ) )
int8_asap = 1 ;
# ifndef NO_GRAPHICS
// Update the video graphics display every GRAPHICS_UPDATE_DELAY instructions
if ( ! ( inst_counter % GRAPHICS_UPDATE_DELAY ) )
{
// Video card in graphics mode?
if ( io_ports [ 0x3B8 ] & 2 )
{
// If we don't already have an SDL window open, set it up and compute color and video memory translation tables
if ( ! sdl_screen )
{
for ( int i = 0 ; i < 16 ; i + + )
pixel_colors [ i ] = mem [ 0x4AC ] ? // CGA?
cga_colors [ ( i & 12 ) > > 2 ] + ( cga_colors [ i & 3 ] < < 16 ) // CGA -> RGB332
: 0xFF * ( ( ( i & 1 ) < < 24 ) + ( ( i & 2 ) < < 15 ) + ( ( i & 4 ) < < 6 ) + ( ( i & 8 ) > > 3 ) ) ; // Hercules -> RGB332
for ( int i = 0 ; i < GRAPHICS_X * GRAPHICS_Y / 4 ; i + + )
vid_addr_lookup [ i ] = i / GRAPHICS_X * ( GRAPHICS_X / 8 ) + ( i / 2 ) % ( GRAPHICS_X / 8 ) + 0x2000 * ( mem [ 0x4AC ] ? ( 2 * i / GRAPHICS_X ) % 2 : ( 4 * i / GRAPHICS_X ) % 4 ) ;
SDL_Init ( SDL_INIT_VIDEO ) ;
sdl_screen = SDL_SetVideoMode ( GRAPHICS_X , GRAPHICS_Y , 8 , 0 ) ;
SDL_EnableUNICODE ( 1 ) ;
SDL_EnableKeyRepeat ( 500 , 30 ) ;
}
// Refresh SDL display from emulated graphics card video RAM
vid_mem_base = mem + 0xB0000 + 0x8000 * ( mem [ 0x4AC ] ? 1 : io_ports [ 0x3B8 ] > > 7 ) ; // B800:0 for CGA/Hercules bank 2, B000:0 for Hercules bank 1
for ( int i = 0 ; i < GRAPHICS_X * GRAPHICS_Y / 4 ; i + + )
( ( unsigned * ) sdl_screen - > pixels ) [ i ] = pixel_colors [ 15 & ( vid_mem_base [ vid_addr_lookup [ i ] ] > > 4 * ! ( i & 1 ) ) ] ;
SDL_Flip ( sdl_screen ) ;
}
else if ( sdl_screen ) // Application has gone back to text mode, so close the SDL window
{
SDL_QuitSubSystem ( SDL_INIT_VIDEO ) ;
sdl_screen = 0 ;
}
SDL_PumpEvents ( ) ;
}
# endif
// Application has set trap flag, so fire INT 1
if ( trap_flag )
pc_interrupt ( 1 ) ;
trap_flag = regs8 [ FLAG_TF ] ;
// If a timer tick is pending, interrupts are enabled, and no overrides/REP are active,
// then process the tick and check for new keystrokes
if ( int8_asap & & ! seg_override_en & & ! rep_override_en & & regs8 [ FLAG_IF ] & & ! regs8 [ FLAG_TF ] )
pc_interrupt ( 0xA ) , int8_asap = 0 , SDL_KEYBOARD_DRIVER ;
}
# ifndef NO_GRAPHICS
SDL_Quit ( ) ;
# endif
return 0 ;
}