/* i8088.c: Intel 8086/8088 CPU simulator | |
Copyright (C) 1991 Jim Hudgens | |
The file is part of GDE. | |
GDE is free software; you can redistribute it and/or modify | |
it under the terms of the GNU General Public License as published by | |
the Free Software Foundation; either version 1, or (at your option) | |
any later version. | |
GDE is distributed in the hope that it will be useful, | |
but WITHOUT ANY WARRANTY; without even the implied warranty of | |
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the | |
GNU General Public License for more details. | |
You should have received a copy of the GNU General Public License | |
along with GDE; see the file COPYING. If not, write to | |
the Free Software Foundation, 675 Mass Ave, Cambridge, MA 02139, USA. | |
This software was modified by Bill Beech, Mar 2011, from the software GDE | |
of Jim Hudgens as provided with the SIMH AltairZ80 emulation package. | |
I modified it to allow emulation of Intel iSBC Single Board Computers. | |
Copyright (c) 2011, William A. Beech | |
Permission is hereby granted, free of charge, to any person obtaining a | |
copy of this software and associated documentation files (the "Software"), | |
to deal in the Software without restriction, including without limitation | |
the rights to use, copy, modify, merge, publish, distribute, sublicense, | |
and/or sell copies of the Software, and to permit persons to whom the | |
Software is furnished to do so, subject to the following conditions: | |
The above copyright notice and this permission notice shall be included in | |
all copies or substantial portions of the Software. | |
THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR | |
IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, | |
FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL | |
WILLIAM A. BEECH BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER | |
IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN | |
CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE. | |
Except as contained in this notice, the name of William A. Beech shall not be | |
used in advertising or otherwise to promote the sale, use or other dealings | |
in this Software without prior written authorization from William A. Beech. | |
cpu 8088 CPU | |
17 Mar 11 WAB Original code | |
The register state for the 8088 CPU is: | |
AX<0:15> AH/AL Register Pair | |
BX<0:15> BH/BL Register Pair | |
CX<0:15> CH/CL Register Pair | |
DX<0:15> DH/DL Register Pair | |
SI<0:15> Source Index Register | |
DI<0:15> Destination Index Register | |
BP<0:15> Base Pointer | |
SP<0:15> Stack Pointer | |
CS<0:15> Code Segment Register | |
DS<0:15> Date Segment Register | |
SS<0:15> Stack Segment Register | |
ES<0:15> Extra Segment Register | |
IP<0:15> Program Counter | |
PSW<0:15> Program Status Word - Contains the following flags: | |
AF Auxillary Flag | |
CF Carry Flag | |
OF Overflow Flag | |
SF Sign Flag | |
PF Parity Flag | |
ZF Zero Flag | |
DF Direction Flag | |
IF Interrupt Enable Flag | |
TF Trap Flag | |
in bit positions: | |
15 8 7 0 | |
|--|--|--|--|OF|DF|IF|TF|SF|ZF|--|AF|--|PF|--|CF| | |
The 8088 is an 8-bit CPU, which uses 16-bit offset and segment registers | |
in combination with a dedicated adder to address up to 1MB of memory directly. | |
The offset register is added to the segment register shifted left 4 places | |
to obtain the 20-bit address. | |
The CPU utilizes two separate processing units - the Execution Unit (EU) and | |
the Bus Interface Unit (BIU). The EU executes instructions. The BIU fetches | |
instructions, reads operands and writes results. The two units can operate | |
independently of one another and are able, under most circumstances, to | |
extensively overlap instruction fetch with execution. | |
The BIUs of the 8086 and 8088 are functionally identical, but are implemented | |
differently to match the structure and performance characteristics of their | |
respective buses. | |
The almost 300 instructions come in 1, 2, 3, 4, 5, 6 and 7-byte flavors. | |
This routine is the simulator for the 8088. It is called from the | |
simulator control program to execute instructions in simulated memory, | |
starting at the simulated IP. It runs until 'reason' is set non-zero. | |
General notes: | |
1. Reasons to stop. The simulator can be stopped by: | |
HALT instruction | |
I/O error in I/O simulator | |
Invalid OP code (if ITRAP is set on CPU) | |
2. Interrupts. | |
There are 256 possible levels of interrupt, and in effect they | |
do a hardware CALL instruction to one of 256 possible low | |
memory addresses. | |
3. Non-existent memory. On the 8088, reads to non-existent memory | |
return 0FFh, and writes are ignored. | |
Some algorithms were pulled from the GDE Dos/IP Emulator by Jim Hudgens | |
*/ | |
/* | |
This algorithm was pulled from the GDE Dos/IP Emulator by Jim Hudgens | |
CARRY CHAIN CALCULATION. | |
This represents a somewhat expensive calculation which is | |
apparently required to emulate the setting of the OF and | |
AF flag. The latter is not so important, but the former is. | |
The overflow flag is the XOR of the top two bits of the | |
carry chain for an addition (similar for subtraction). | |
Since we do not want to simulate the addition in a bitwise | |
manner, we try to calculate the carry chain given the | |
two operands and the result. | |
So, given the following table, which represents the | |
addition of two bits, we can derive a formula for | |
the carry chain. | |
a b cin r cout | |
0 0 0 0 0 | |
0 0 1 1 0 | |
0 1 0 1 0 | |
0 1 1 0 1 | |
1 0 0 1 0 | |
1 0 1 0 1 | |
1 1 0 0 1 | |
1 1 1 1 1 | |
Construction of table for cout: | |
ab | |
r \ 00 01 11 10 | |
|------------------ | |
0 | 0 1 1 1 | |
1 | 0 0 1 0 | |
By inspection, one gets: cc = ab + r'(a + b) | |
That represents alot of operations, but NO CHOICE.... | |
BORROW CHAIN CALCULATION. | |
The following table represents the | |
subtraction of two bits, from which we can derive a formula for | |
the borrow chain. | |
a b bin r bout | |
0 0 0 0 0 | |
0 0 1 1 1 | |
0 1 0 1 1 | |
0 1 1 0 1 | |
1 0 0 1 0 | |
1 0 1 0 0 | |
1 1 0 0 0 | |
1 1 1 1 1 | |
Construction of table for cout: | |
ab | |
r \ 00 01 11 10 | |
|------------------ | |
0 | 0 1 0 0 | |
1 | 1 1 1 0 | |
By inspection, one gets: bc = a'b + r(a' + b) | |
Segment register selection and overrides are handled as follows: | |
If there is a segment override, the register number is stored | |
in seg_ovr. If there is no override, seg_ovr is zero. Seg_ovr | |
is set to zero after each instruction except segment override | |
instructions. | |
Get_ea sets the value of seg_reg to the override if present | |
otherwise to the default value for the registers used in the | |
effective address calculation. | |
The get/put_smword/byte routines use the register number in | |
seg_reg to obtain the segment value to calculate the absolute | |
memory address for the operation. | |
*/ | |
#include <stdio.h> | |
#include "multibus_defs.h" | |
#define UNIT_V_OPSTOP (UNIT_V_UF) /* Stop on Invalid OP? */ | |
#define UNIT_OPSTOP (1 << UNIT_V_OPSTOP) | |
#define UNIT_V_8088 (UNIT_V_UF+1) /* 8088 or 8086 */ | |
#define UNIT_8088 (1 << UNIT_V_8088) | |
/* Flag values to set proper positions in PSW */ | |
#define CF 0x0001 | |
#define PF 0x0004 | |
#define AF 0x0010 | |
#define ZF 0x0040 | |
#define SF 0x0080 | |
#define TF 0x0100 | |
#define IF 0x0200 | |
#define DF 0x0400 | |
#define OF 0x0800 | |
/* Macros to handle the flags in the PSW | |
8088 has top 4 bits of the flags set to 1 | |
also, bit#1 is set. This is (not well) documented behavior. */ | |
#define PSW_ALWAYS_ON (0xF002) /* for 8086 */ | |
#define PSW_MSK (CF|PF|AF|ZF|SF|TF|IF|DF|OF) | |
#define TOGGLE_FLAG(FLAG) (PSW ^= FLAG) | |
#define SET_FLAG(FLAG) (PSW |= FLAG) | |
#define CLR_FLAG(FLAG) (PSW &= ~FLAG) | |
#define GET_FLAG(FLAG) (PSW & FLAG) | |
#define CONDITIONAL_SET_FLAG(COND,FLAG) \ | |
if (COND) SET_FLAG(FLAG); else CLR_FLAG(FLAG) | |
/* union of byte and word registers */ | |
union { | |
uint8 b[2]; /* two bytes */ | |
uint16 w; /* one word */ | |
} A, B, C, D; /* storage for AX, BX, CX and DX */ | |
/* macros for byte registers */ | |
#define AH (A.b[1]) | |
#define AL (A.b[0]) | |
#define BH (B.b[1]) | |
#define BL (B.b[0]) | |
#define CH (C.b[1]) | |
#define CL (C.b[0]) | |
#define DH (D.b[1]) | |
#define DL (D.b[0]) | |
/* macros for word registers */ | |
#define AX (A.w) | |
#define BX (B.w) | |
#define CX (C.w) | |
#define DX (D.w) | |
/* macros for handling IP and SP */ | |
#define INC_IP1 (++IP & ADDRMASK20) /* increment IP one byte */ | |
#define INC_IP2 ((IP += 2) & ADDRMASK20) /* increment IP two bytes */ | |
/* storage for the rest of the registers */ | |
int32 DI; /* Source Index Register */ | |
int32 SI; /* Destination Index Register */ | |
int32 BP; /* Base Pointer Register */ | |
int32 SP; /* Stack Pointer Register */ | |
int32 CS; /* Code Segment Register */ | |
int32 DS; /* Data Segment Register */ | |
int32 SS; /* Stack Segment Register */ | |
int32 ES; /* Extra Segment Register */ | |
int32 IP; /* Program Counter */ | |
int32 PSW; /* Program Status Word (Flags) */ | |
int32 saved_PC = 0; /* saved program counter */ | |
int32 int_req = 0; /* Interrupt request */ | |
int32 chip = 0; /* 0 = 8088 chip, 1 = 8086 chip */ | |
#define CHIP_8088 0 /* processor types */ | |
#define CHIP_8086 1 | |
#define CHIP_80188 2 | |
#define CHIP_80186 3 | |
#define CHIP_80286 4 | |
int32 seg_ovr = 0; /* segment override register */ | |
int32 seg_reg = 0; /* segment register to use for EA */ | |
#define SEG_NONE 0 /* segmenr override register values */ | |
#define SEG_CS 8 | |
#define SEG_DS 9 | |
#define SEG_ES 10 | |
#define SEG_SS 11 | |
int32 PCX; /* External view of IP */ | |
/* handle prefix instructions */ | |
uint32 sysmode = 0; /* prefix flags */ | |
#define SYSMODE_SEG_DS_SS 0x01 | |
#define SYSMODE_SEGOVR_CS 0x02 | |
#define SYSMODE_SEGOVR_DS 0x04 | |
#define SYSMODE_SEGOVR_ES 0x08 | |
#define SYSMODE_SEGOVR_SS 0x10 | |
#define SYSMODE_SEGMASK (SYSMODE_SEG_DS_SS | SYSMODE_SEGOVR_CS | \ | |
SYSMODE_SEGOVR_DS | SYSMODE_SEGOVR_ES | SYSMODE_SEGOVR_SS) | |
#define SYSMODE_PREFIX_REPE 0x20 | |
#define SYSMODE_PREFIX_REPNE 0x40 | |
/* function prototypes */ | |
int32 sign_ext(int32 val); | |
int32 fetch_byte(int32 flag); | |
int32 fetch_word(void); | |
int32 parity(int32 val); | |
void i86_intr_raise(uint8 num); | |
uint32 get_rbyte(uint32 reg); | |
uint32 get_rword(uint32 reg); | |
void put_rbyte(uint32 reg, uint32 val); | |
void put_rword(uint32 reg, uint32 val); | |
uint32 get_ea(uint32 mrr); | |
void set_segreg(uint32 reg); | |
void get_mrr_dec(uint32 mrr, uint32 *mod, uint32 *reg, uint32 *rm); | |
/* emulator primitives */ | |
uint8 aad_word(uint16 d); | |
uint16 aam_word(uint8 d); | |
uint8 adc_byte(uint8 d, uint8 s); | |
uint16 adc_word(uint16 d, uint16 s); | |
uint8 add_byte(uint8 d, uint8 s); | |
uint16 add_word(uint16 d, uint16 s); | |
uint8 and_byte(uint8 d, uint8 s); | |
uint16 cmp_word(uint16 d, uint16 s); | |
uint8 cmp_byte(uint8 d, uint8 s); | |
uint16 and_word(uint16 d, uint16 s); | |
uint8 dec_byte(uint8 d); | |
uint16 dec_word(uint16 d); | |
void div_byte(uint8 s); | |
void div_word(uint16 s); | |
void idiv_byte(uint8 s); | |
void idiv_word(uint16 s); | |
void imul_byte(uint8 s); | |
void imul_word(uint16 s); | |
uint8 inc_byte(uint8 d); | |
uint16 inc_word(uint16 d); | |
void mul_byte(uint8 s); | |
void mul_word(uint16 s); | |
uint8 neg_byte(uint8 s); | |
uint16 neg_word(uint16 s); | |
uint8 not_byte(uint8 s); | |
uint16 not_word(uint16 s); | |
uint8 or_byte(uint8 d, uint8 s); | |
uint16 or_word(uint16 d, uint16 s); | |
void push_word(uint16 val); | |
uint16 pop_word(void); | |
uint8 rcl_byte(uint8 d, uint8 s); | |
uint16 rcl_word(uint16 d, uint16 s); | |
uint8 rcr_byte(uint8 d, uint8 s); | |
uint16 rcr_word(uint16 d, uint16 s); | |
uint8 rol_byte(uint8 d, uint8 s); | |
uint16 rol_word(uint16 d, uint16 s); | |
uint8 ror_byte(uint8 d, uint8 s); | |
uint16 ror_word(uint16 d, uint16 s); | |
uint8 shl_byte(uint8 d, uint8 s); | |
uint16 shl_word(uint16 d, uint16 s); | |
uint8 shr_byte(uint8 d, uint8 s); | |
uint16 shr_word(uint16 d, uint16 s); | |
uint8 sar_byte(uint8 d, uint8 s); | |
uint16 sar_word(uint16 d, uint16 s); | |
uint8 sbb_byte(uint8 d, uint8 s); | |
uint16 sbb_word(uint16 d, uint16 s); | |
uint8 sub_byte(uint8 d, uint8 s); | |
uint16 sub_word(uint16 d, uint16 s); | |
void test_byte(uint8 d, uint8 s); | |
void test_word(uint16 d, uint16 s); | |
uint8 xor_byte(uint8 d, uint8 s); | |
uint16 xor_word(uint16 d, uint16 s); | |
int32 get_smbyte(int32 segreg, int32 addr); | |
int32 get_smword(int32 segreg, int32 addr); | |
void put_smbyte(int32 segreg, int32 addr, int32 val); | |
void put_smword(int32 segreg, int32 addr, int32 val); | |
/* simulator routines */ | |
int32 sim_instr(void); | |
t_stat i8088_reset (DEVICE *dptr); | |
t_stat i8088_ex (t_value *vptr, t_addr addr, UNIT *uptr, int32 sw); | |
t_stat i8088_dep (t_value val, t_addr addr, UNIT *uptr, int32 sw); | |
/* external references */ | |
//extern t_stat i8088_reset (DEVICE *dptr); | |
/* Multibus memory read and write absolute address routines */ | |
extern int32 get_mbyte(int32 addr); | |
extern int32 get_mword(int32 addr); | |
extern void put_mbyte(int32 addr, int32 val); | |
extern void put_mword(int32 addr, int32 val); | |
extern int32 sim_int_char; | |
extern int32 sim_brk_types, sim_brk_dflt, sim_brk_summ; /* breakpoint info */ | |
/* This is the I/O configuration table. There are 65536 possible | |
device addresses, if a device is plugged to a port it's routine | |
address is here, 'nulldev' means no device is available | |
*/ | |
struct idev { | |
int32 (*routine)(); | |
}; | |
extern struct idev dev_table[]; | |
/* 8088 CPU data structures | |
i8088_dev CPU device descriptor | |
i8088_unit CPU unit descriptor | |
i8088_reg CPU register list | |
i8088_mod CPU modifiers list | |
*/ | |
UNIT i8088_unit = { UDATA (NULL, 0, 0) }; | |
REG i8088_reg[] = { | |
{ HRDATA (IP, saved_PC, 16) }, /* must be first for sim_PC */ | |
{ HRDATA (AX, AX, 16) }, | |
{ HRDATA (BX, BX, 16) }, | |
{ HRDATA (CX, CX, 16) }, | |
{ HRDATA (DX, DX, 16) }, | |
{ HRDATA (DI, DI, 16) }, | |
{ HRDATA (SI, SI, 16) }, | |
{ HRDATA (BP, BP, 16) }, | |
{ HRDATA (SP, SP, 16) }, | |
{ HRDATA (CS, CS, 16) }, | |
{ HRDATA (DS, DS, 16) }, | |
{ HRDATA (SS, SS, 16) }, | |
{ HRDATA (ES, ES, 16) }, | |
{ HRDATA (PSW, PSW, 16) }, | |
{ HRDATA (WRU, sim_int_char, 8) }, | |
{ NULL } | |
}; | |
MTAB i8088_mod[] = { | |
{ UNIT_8088, UNIT_8088, "8086", "8086", NULL }, | |
{ UNIT_8088, 0, "8088", "8088", NULL }, | |
{ UNIT_OPSTOP, UNIT_OPSTOP, "ITRAP", "ITRAP", NULL }, | |
{ UNIT_OPSTOP, 0, "NOITRAP", "NOITRAP", NULL }, | |
{ 0 } | |
}; | |
DEBTAB i8088_debug[] = { | |
{ "ALL", DEBUG_all }, | |
{ "FLOW", DEBUG_flow }, | |
{ "READ", DEBUG_read }, | |
{ "WRITE", DEBUG_write }, | |
{ "LEV1", DEBUG_level1 }, | |
{ "LEV2", DEBUG_level2 }, | |
{ "REG", DEBUG_reg }, | |
{ "ASM", DEBUG_asm }, | |
{ NULL } | |
}; | |
DEVICE i8088_dev = { | |
"I8088", //name | |
&i8088_unit, //units | |
i8088_reg, //registers | |
i8088_mod, //modifiers | |
1, //numunits | |
16, //aradix | |
20, //awidth | |
1, //aincr | |
16, //dradix | |
8, //dwidth | |
&i8088_ex, //examine | |
&i8088_dep, //deposit | |
&i8088_reset, //reset | |
NULL, //boot | |
NULL, //attach | |
NULL, //detach | |
NULL, //ctxt | |
DEV_DEBUG, //flags | |
0, //dctrl | |
i8088_debug, //debflags | |
NULL, //msize | |
NULL //lname | |
}; | |
uint8 xor_3_tab[] = { 0, 1, 1, 0 }; | |
int32 IP; | |
static const char *opcode[] = { | |
"ADD ", "ADD ", "ADD ", "ADD ", /* 0x00 */ | |
"ADD AL,", "ADD AX,", "PUSH ES", "POP ES", | |
"OR ", "OR ", "OR ", "OR ", | |
"OR AL,", "OR AX,", "PUSH CS", "???", | |
"ADC ", "ADC ", "ADC ", "ADC ", /* 0x10 */ | |
"ADC AL,", "ADC AX,", "PUSH SS", "RPOP SS", | |
"SBB ", "SBB ", "SBB ", "SBB ", | |
"SBB AL,", "SBB AX,", "PUSH DS", "POP DS", | |
"AND ", "AND ", "AND ", "AND ", /* 0x20 */ | |
"AND AL,", "AND AX,", "ES:", "DAA", | |
"SUB ", "SUB ", "SUB ", "SUB ", | |
"SUB AL,", "SUB AX,", "CS:", "DAS", | |
"XOR ", "XOR ", "XOR ", "XOR ", /* 0x30 */ | |
"XOR AL,", "XOR AX,", "SS:", "AAA", | |
"CMP ", "CMP ", "CMP ", "CMP ", | |
"CMP AL,", "CMP AX,", "DS:", "AAS", | |
"INC AX", "INC CX", "INC DX", "INC BX", /* 0x40 */ | |
"INC SP", "INC BP", "INC SI", "INC DI", | |
"DEC AX", "DEC CX", "DEC DX", "DEC BX", | |
"DEC SP", "DEC BP", "DEC SI", "DEC DI", | |
"PUSH AX", "PUSH CX", "PUSH DX", "PUSH BX", /* 0x50 */ | |
"PUSH SP", "PUSH BP", "PUSH SI", "PUSH DI", | |
"POP AX", "POP CX", "POP DX", "POP BX", | |
"POP SP", "POP BP", "POP SI", "POP DI", | |
"???", "???", "???", "???", /* 0x60 */ | |
"???", "???", "???", "???", | |
"PUSH ", "IMUL ", "PUSH ", "IMUL ", | |
"INSB", "INSW", "OUTSB", "OUTSW", | |
"JO ", "JNO ", "JC ", "JNC", /* 0x70 */ | |
"JZ ", "JNZ ", "JNA ", "JA", | |
"JS ", "JNS ", "JP ", "JNP ", | |
"JL ", "JNL ", "JLE ", "JNLE", | |
"???", "???", "???", "???", /* 0x80 */ | |
"TEST ", "TEST ", "XCHG ", "XCHG ", | |
"MOV ", "MOV ", "MOV ", "MOV ", | |
"MOV ", "LEA ", "MOV ", "POP ", | |
"NOP", "XCHG AX,CX", "XCHG AX,DX", "XCHG AX,BX",/* 0x90 */ | |
"XCHG AX,SP", "XCHG AX,BP", "XCHG AX,SI", "XCHG AX,DI", | |
"CBW", "CWD", "CALL ", "WAIT", | |
"PUSHF", "POPF", "SAHF", "LAHF", | |
"MOV AL,", "MOV AX,", "MOV ", "MOV ", /* 0xA0 */ | |
"MOVSB", "MOVSW", "CMPSB", "CMPSW", | |
"TEST AL,", "TEST AX,", "STOSB", "STOSW", | |
"LODSB", "LODSW", "SCASB", "SCASW", | |
"MOV AL,", "MOV CL,", "MOV DL,", "MOV BL,", /* 0xB0 */ | |
"MOV AH,", "MOV CH,", "MOV DH,", "MOV BH,", | |
"MOV AX,", "MOV CX,", "MOV DX,", "MOV BX,", | |
"MOV SP,", "MOV BP,", "MOV SI,", "MOV DI," | |
" ", " ", "RET ", "RET ", /* 0xC0 */ | |
"LES ", "LDS ", "MOV ", "MOV ", | |
"???", "???", "RET ", "RET", | |
"INT 3", "INT ", "INTO", "IRET", | |
" ", " ", " ", " ", /* 0xD0 */ | |
"AAM", "AAD", "???", "XLATB", | |
"ESC ", "ESC ", "ESC ", "ESC ", | |
"ESC ", "ESC ", "ESC ", "ESC ", | |
"LOOPNZ ", "LOOPZ ", "LOOP", "JCXZ", /* 0xE0 */ | |
"IN AL,", "IN AX,", "OUT ", "OUT ", | |
"CALL ", "JMP ", "JMP ", "JMP ", | |
"IN AL,DX", "IN AX,DX", "OUT DX,AL", "OUT DX,AX", | |
"LOCK", "???", "REPNZ", "REPZ", /* 0xF0 */ | |
"HLT", "CMC", " ", " ", | |
"CLC", "STC", "CLI", "STI", | |
"CLD", "STD", "???", "???" | |
}; | |
int32 oplen[256] = { | |
1,3,1,1,1,1,2,1,0,1,1,1,1,1,2,1, | |
0,3,1,1,1,1,2,1,0,1,1,1,1,1,2,1, | |
0,3,3,1,1,1,2,1,0,1,3,1,1,1,2,1, | |
0,3,3,1,1,1,2,1,0,1,3,1,1,1,2,1, | |
1,1,1,1,1,1,1,1,1,1,1,1,1,1,1,1, | |
1,1,1,1,1,1,1,1,1,1,1,1,1,1,1,1, | |
1,1,1,1,1,1,1,1,1,1,1,1,1,1,1,1, | |
1,1,1,1,1,1,1,1,1,1,1,1,1,1,1,1, | |
1,1,1,1,1,1,1,1,1,1,1,1,1,1,1,1, | |
1,1,1,1,1,1,1,1,1,1,1,1,1,1,1,1, | |
1,1,1,1,1,1,1,1,1,1,1,1,1,1,1,1, | |
1,1,1,1,1,1,1,1,1,1,1,1,1,1,1,1, | |
1,1,3,3,3,1,2,1,1,1,3,0,3,3,2,1, | |
1,1,3,2,3,1,2,1,1,0,3,2,3,0,2,1, | |
1,1,3,1,3,1,2,1,1,1,3,1,3,0,2,1, | |
1,1,3,1,3,1,2,1,1,1,3,1,3,0,2,1 | |
}; | |
int32 sim_instr (void) | |
{ | |
extern int32 sim_interval; | |
int32 IR, OP, DAR, reason, hi, lo, carry, i, adr; | |
int32 MRR, REG, EA, MOD, RM, DISP, VAL, DATA, OFF, SEG, INC, VAL1; | |
IP = saved_PC & ADDRMASK16; /* load local IP */ | |
reason = 0; /* clear stop reason */ | |
/* Main instruction fetch/decode loop */ | |
while (reason == 0) { /* loop until halted */ | |
if (i8088_dev.dctrl & DEBUG_asm) | |
sim_printf("\n"); | |
if (i8088_dev.dctrl & DEBUG_reg) { | |
sim_printf("Regs: AX=%04X BX=%04X CX=%04X DX=%04X SP=%04X BP=%04X SI=%04X DI=%04X IP=%04X\n", | |
AX, BX, CX, DX, SP, BP, SI, DI, IP); | |
sim_printf("Segs: CS=%04X DS=%04X ES=%04X SS=%04X ", CS, DS, ES, SS); | |
sim_printf("Flags: %04X\n", PSW); | |
} | |
if (sim_interval <= 0) { /* check clock queue */ | |
if (reason = sim_process_event ()) break; | |
} | |
if (int_req > 0) { /* interrupt? */ | |
/* 8088 interrupts not implemented yet. */ | |
} /* end interrupt */ | |
if (sim_brk_summ && | |
sim_brk_test (IP, SWMASK ('E'))) { /* breakpoint? */ | |
reason = STOP_IBKPT; /* stop simulation */ | |
break; | |
} | |
sim_interval--; /* countdown clock */ | |
PCX = IP; | |
IR = OP = fetch_byte(0); /* fetch instruction */ | |
/* Handle below all operations which refer to registers or | |
register pairs. After that, a large switch statement | |
takes care of all other opcodes */ | |
/* data transfer instructions */ | |
/* arithmetic instructions */ | |
/* bit manipulation instructions */ | |
/* string manipulation instructions */ | |
/* control transfer instructions */ | |
/* processor control instructions */ | |
/* The Big Instruction Decode Switch */ | |
switch (IR) { | |
/* data transfer instructions */ | |
/* arithmetic instructions */ | |
case 0x00: /* ADD byte - REG = REG + (EA) */ | |
MRR = fetch_byte(1); | |
get_mrr_dec(MRR, &MOD, ®, &RM); | |
if (MOD != 0x3) { /* based, indexed, or based indexed addressing */ | |
EA = get_ea(MRR); /* get effective address */ | |
VAL = add_byte(get_rbyte(REG), get_smbyte(seg_reg, EA)); /* do operation */ | |
put_rbyte(REG, VAL); /* store result */ | |
} else { /* RM is second register */ | |
VAL = add_byte(get_rbyte(REG), get_rbyte(RM)); /* do operation */ | |
put_rbyte(REG, VAL); /* store result */ | |
} | |
break; | |
case 0x01: /* ADD word - (EA) = (EA) + REG */ | |
MRR = fetch_byte(1); | |
get_mrr_dec(MRR, &MOD, ®, &RM); | |
if (MOD != 0x3) { /* based, indexed, or based indexed addressing */ | |
EA = get_ea(MRR); /* get effective address */ | |
VAL = add_word(get_rword(REG), get_smword(seg_reg, EA)); /* do operation */ | |
put_smword(seg_reg, EA, VAL); /* store result */ | |
} else { /* RM is second register */ | |
VAL = add_word(get_rword(REG), get_rword(RM)); /* do operation */ | |
put_rword(REG, VAL); /* store result */ | |
} | |
break; | |
case 0x02: /* ADD byte - REG = REG + (EA) */ | |
MRR = fetch_byte(1); | |
get_mrr_dec(MRR, &MOD, ®, &RM); | |
if (MOD != 0x3) { /* based, indexed, or based indexed addressing */ | |
EA = get_ea(MRR); /* get effective address */ | |
VAL = add_byte(get_rbyte(REG), get_smbyte(seg_reg, EA)); /* do operation */ | |
put_rbyte(REG, VAL); /* store result */ | |
} else { /* RM is second register */ | |
VAL = add_byte(get_rbyte(REG), get_rbyte(RM)); /* do operation */ | |
put_rbyte(REG, VAL); /* store result */ | |
} | |
break; | |
case 0x03: /* ADD word - (EA) = (EA) + REG */ | |
MRR = fetch_byte(1); | |
get_mrr_dec(MRR, &MOD, ®, &RM); | |
if (MOD != 0x3) { /* based, indexed, or based indexed addressing */ | |
EA = get_ea(MRR); /* get effective address */ | |
VAL = adc_word(get_rword(REG), get_smword(seg_reg, EA)); /* do operation */ | |
put_smbyte(seg_reg, EA, VAL); /* store result */ | |
} else { /* RM is second register */ | |
VAL = adc_word(get_rword(REG), get_rword(RM)); /* do operation */ | |
put_rbyte(REG, VAL); /* store result */ | |
} | |
break; | |
case 0x04: /* ADD byte - AL = AL + DATA */ | |
DATA = fetch_byte(1); | |
VAL = add_byte(AL, DATA); /* do operation */ | |
AL = VAL; /* store result */ | |
break; | |
case 0x05: /* ADD word - (EA) = (EA) + REG */ | |
DATA = fetch_word(); | |
VAL = add_word(AX, DATA); /* do operation */ | |
AX = VAL; /* store result */ | |
break; | |
case 0x06: /* PUSH ES */ | |
push_word(ES); | |
break; | |
case 0x07: /* POP ES */ | |
ES = pop_word(); | |
break; | |
case 0x08: /* OR byte - REG = REG OR (EA) */ | |
MRR = fetch_byte(1); | |
get_mrr_dec(MRR, &MOD, ®, &RM); | |
if (MOD != 0x3) { /* based, indexed, or based indexed addressing */ | |
EA = get_ea(MRR); /* get effective address */ | |
VAL = or_byte(get_rbyte(REG), get_smbyte(seg_reg, EA)); /* do operation */ | |
put_rbyte(REG, VAL); /* store result */ | |
} else { /* RM is second register */ | |
VAL = or_byte(get_rbyte(REG), get_rbyte(RM)); /* do operation */ | |
put_rbyte(REG, VAL); /* store result */ | |
} | |
break; | |
case 0x09: /* OR word - (EA) = (EA) OR REG */ | |
MRR = fetch_byte(1); | |
get_mrr_dec(MRR, &MOD, ®, &RM); | |
if (MOD != 0x3) { /* based, indexed, or based indexed addressing */ | |
EA = get_ea(MRR); /* get effective address */ | |
VAL = or_word(get_rword(REG), get_smword(seg_reg, EA)); /* do operation */ | |
put_smword(seg_reg, EA, VAL); /* store result */ | |
} else { /* RM is second register */ | |
VAL = or_word(get_rword(REG), get_rword(RM)); /* do operation */ | |
put_rword(REG, VAL); /* store result */ | |
} | |
break; | |
case 0x0A: /* OR byte - REG = REG OR (EA) */ | |
MRR = fetch_byte(1); | |
get_mrr_dec(MRR, &MOD, ®, &RM); | |
if (MOD != 0x3) { /* based, indexed, or based indexed addressing */ | |
EA = get_ea(MRR); /* get effective address */ | |
VAL = or_byte(get_rbyte(REG), get_smbyte(seg_reg, EA)); /* do operation */ | |
put_rbyte(REG, VAL); /* store result */ | |
} else { /* RM is second register */ | |
VAL = or_byte(get_rbyte(REG), get_rbyte(RM)); /* do operation */ | |
put_rbyte(REG, VAL); /* store result */ | |
} | |
break; | |
case 0x0B: /* OR word - (EA) = (EA) OR REG */ | |
MRR = fetch_byte(1); | |
get_mrr_dec(MRR, &MOD, ®, &RM); | |
if (MOD != 0x3) { /* based, indexed, or based indexed addressing */ | |
EA = get_ea(MRR); /* get effective address */ | |
VAL = or_word(get_rword(REG), get_smword(seg_reg, EA)); /* do operation */ | |
put_smbyte(seg_reg, EA, VAL); /* store result */ | |
} else { /* RM is second register */ | |
VAL = or_word(get_rword(REG), get_rword(RM)); /* do operation */ | |
put_rbyte(REG, VAL); /* store result */ | |
} | |
break; | |
case 0x0C: /* OR byte - AL = AL OR DATA */ | |
DATA = fetch_byte(1); | |
VAL = or_byte(AL, DATA); /* do operation */ | |
AL = VAL; /* store result */ | |
break; | |
case 0x0D: /* OR word - (EA) = (EA) OR REG */ | |
DATA = fetch_word(); | |
VAL = or_word(AX, DATA); /* do operation */ | |
AX = VAL; /* store result */ | |
break; | |
case 0x0E: /* PUSH CS */ | |
push_word(CS); | |
break; | |
/* 0x0F - Not implemented on 8086/8088 */ | |
case 0x10: /* ADC byte - REG = REG + (EA) + CF */ | |
MRR = fetch_byte(1); | |
get_mrr_dec(MRR, &MOD, ®, &RM); | |
if (MOD != 0x3) { /* based, indexed, or based indexed addressing */ | |
EA = get_ea(MRR); /* get effective address */ | |
VAL = adc_byte(get_rbyte(REG), get_smbyte(seg_reg, EA)); /* do operation */ | |
put_rbyte(REG, VAL); /* store result */ | |
} else { /* RM is second register */ | |
VAL = adc_byte(get_rbyte(REG), get_rbyte(RM)); /* do operation */ | |
put_rbyte(REG, VAL); /* store result */ | |
} | |
break; | |
case 0x11: /* ADC word - (EA) = (EA) + REG + CF */ | |
MRR = fetch_byte(1); | |
get_mrr_dec(MRR, &MOD, ®, &RM); | |
if (MOD != 0x3) { /* based, indexed, or based indexed addressing */ | |
EA = get_ea(MRR); /* get effective address */ | |
VAL = adc_word(get_rword(REG), get_smword(seg_reg, EA)); /* do operation */ | |
put_smword(seg_reg, EA, VAL); /* store result */ | |
} else { /* RM is second register */ | |
VAL = adc_word(get_rword(REG), get_rword(RM)); /* do operation */ | |
put_rbyte(REG, VAL); /* store result */ | |
} | |
break; | |
case 0x12: /* ADC byte - REG = REG + (EA) + CF */ | |
MRR = fetch_byte(1); | |
get_mrr_dec(MRR, &MOD, ®, &RM); | |
if (MOD != 0x3) { /* based, indexed, or based indexed addressing */ | |
EA = get_ea(MRR); /* get effective address */ | |
VAL = adc_byte(get_rbyte(REG), get_smbyte(seg_reg, EA)); /* do operation */ | |
put_rbyte(REG, VAL); /* store result */ | |
} else { /* RM is second register */ | |
VAL = adc_byte(get_rbyte(REG), get_rbyte(RM)); /* do operation */ | |
put_rbyte(REG, VAL); /* store result */ | |
} | |
break; | |
case 0x13: /* ADC word - (EA) = (EA) + REG + CF */ | |
MRR = fetch_byte(1); | |
get_mrr_dec(MRR, &MOD, ®, &RM); | |
if (MOD != 0x3) { /* based, indexed, or based indexed addressing */ | |
EA = get_ea(MRR); /* get effective address */ | |
VAL = adc_word(get_rword(REG), get_smword(seg_reg, EA)); /* do operation */ | |
put_smbyte(seg_reg, EA, VAL); /* store result */ | |
} else { /* RM is second register */ | |
VAL = adc_word(get_rword(REG), get_rword(RM)); /* do operation */ | |
put_rbyte(REG, VAL); /* store result */ | |
} | |
break; | |
case 0x14: /* ADC byte - AL = AL + DATA + CF */ | |
DATA = fetch_byte(1); | |
VAL = adc_byte(AL, DATA); /* do operation */ | |
AL = VAL; /* store result */ | |
break; | |
case 0x15: /* ADC word - (EA) = (EA) + REG + CF */ | |
DATA = fetch_word(); | |
VAL = adc_word(AX, DATA); /* do operation */ | |
AX = VAL; /* store result */ | |
break; | |
case 0x16: /* PUSH SS */ | |
push_word(SS); | |
break; | |
case 0x17: /* POP SS */ | |
SS = pop_word(); | |
break; | |
case 0x18: /* SBB byte - REG = REG - (EA) - CF */ | |
MRR = fetch_byte(1); | |
get_mrr_dec(MRR, &MOD, ®, &RM); | |
if (MOD != 0x3) { /* based, indexed, or based indexed addressing */ | |
EA = get_ea(MRR); /* get effective address */ | |
VAL = sbb_byte(get_rbyte(REG), get_smbyte(seg_reg, EA)); /* do operation */ | |
put_rbyte(REG, VAL); /* store result */ | |
} else { /* RM is second register */ | |
VAL = sbb_byte(get_rbyte(REG), get_rbyte(RM)); /* do operation */ | |
put_rbyte(REG, VAL); /* store result */ | |
} | |
break; | |
case 0x19: /* SBB word - (EA) = (EA) - REG - CF */ | |
MRR = fetch_byte(1); | |
get_mrr_dec(MRR, &MOD, ®, &RM); | |
if (MOD != 0x3) { /* based, indexed, or based indexed addressing */ | |
EA = get_ea(MRR); /* get effective address */ | |
VAL = sbb_word(get_rword(REG), get_smword(seg_reg, EA)); /* do operation */ | |
put_smword(seg_reg, EA, VAL); /* store result */ | |
} else { /* RM is second register */ | |
VAL = sbb_word(get_rword(REG), get_rword(RM)); /* do operation */ | |
put_rbyte(REG, VAL); /* store result */ | |
} | |
break; | |
case 0x1A: /* SBB byte - REG = REG - (EA) - CF */ | |
MRR = fetch_byte(1); | |
get_mrr_dec(MRR, &MOD, ®, &RM); | |
if (MOD != 0x3) { /* based, indexed, or based indexed addressing */ | |
EA = get_ea(MRR); /* get effective address */ | |
VAL = sbb_byte(get_rbyte(REG), get_smbyte(seg_reg, EA)); /* do operation */ | |
put_rbyte(REG, VAL); /* store result */ | |
} else { /* RM is second register */ | |
VAL = sbb_byte(get_rbyte(REG), get_rbyte(RM)); /* do operation */ | |
put_rbyte(REG, VAL); /* store result */ | |
} | |
break; | |
case 0x1B: /* SBB word - (EA) = (EA) - REG - CF */ | |
MRR = fetch_byte(1); | |
get_mrr_dec(MRR, &MOD, ®, &RM); | |
if (MOD != 0x3) { /* based, indexed, or based indexed addressing */ | |
EA = get_ea(MRR); /* get effective address */ | |
VAL = sbb_word(get_rword(REG), get_smword(seg_reg, EA)); /* do operation */ | |
put_smbyte(seg_reg, EA, VAL); /* store result */ | |
} else { /* RM is second register */ | |
VAL = sbb_word(get_rword(REG), get_rword(RM)); /* do operation */ | |
put_rbyte(REG, VAL); /* store result */ | |
} | |
break; | |
case 0x1C: /* SBB byte - AL = AL - DATA - CF */ | |
DATA = fetch_byte(1); | |
VAL = sbb_byte(AL, DATA); /* do operation */ | |
AL = VAL; /* store result */ | |
break; | |
case 0x1D: /* SBB word - (EA) = (EA) - REG - CF */ | |
DATA = fetch_word(); | |
VAL = sbb_word(AX, DATA); /* do operation */ | |
AX = VAL; /* store result */ | |
break; | |
case 0x1E: /* PUSH DS */ | |
push_word(DS); | |
break; | |
case 0x1F: /* POP DS */ | |
DS = pop_word(); | |
break; | |
case 0x20: /* AND byte - REG = REG AND (EA) */ | |
MRR = fetch_byte(1); | |
get_mrr_dec(MRR, &MOD, ®, &RM); | |
if (MOD != 0x3) { /* based, indexed, or based indexed addressing */ | |
EA = get_ea(MRR); /* get effective address */ | |
VAL = and_byte(get_rbyte(REG), get_smbyte(seg_reg, EA)); /* do operation */ | |
put_rbyte(REG, VAL); /* store result */ | |
} else { /* RM is second register */ | |
VAL = and_byte(get_rbyte(REG), get_rbyte(RM)); /* do operation */ | |
put_rbyte(REG, VAL); /* store result */ | |
} | |
break; | |
case 0x21: /* AND word - (EA) = (EA) AND REG */ | |
MRR = fetch_byte(1); | |
get_mrr_dec(MRR, &MOD, ®, &RM); | |
if (MOD != 0x3) { /* based, indexed, or based indexed addressing */ | |
EA = get_ea(MRR); /* get effective address */ | |
VAL = and_word(get_rword(REG), get_smword(seg_reg, EA)); /* do operation */ | |
put_smword(seg_reg, EA, VAL); /* store result */ | |
} else { /* RM is second register */ | |
VAL = and_word(get_rword(REG), get_rword(RM)); /* do operation */ | |
put_rbyte(REG, VAL); /* store result */ | |
} | |
break; | |
case 0x22: /* AND byte - REG = REG AND (EA) */ | |
MRR = fetch_byte(1); | |
get_mrr_dec(MRR, &MOD, ®, &RM); | |
if (MOD != 0x3) { /* based, indexed, or based indexed addressing */ | |
EA = get_ea(MRR); /* get effective address */ | |
VAL = and_byte(get_rbyte(REG), get_smbyte(seg_reg, EA)); /* do operation */ | |
put_rbyte(REG, VAL); /* store result */ | |
} else { /* RM is second register */ | |
VAL = and_byte(get_rbyte(REG), get_rbyte(RM)); /* do operation */ | |
put_rbyte(REG, VAL); /* store result */ | |
} | |
break; | |
case 0x23: /* AND word - (EA) = (EA) AND REG */ | |
MRR = fetch_byte(1); | |
get_mrr_dec(MRR, &MOD, ®, &RM); | |
if (MOD != 0x3) { /* based, indexed, or based indexed addressing */ | |
EA = get_ea(MRR); /* get effective address */ | |
VAL = and_word(get_rword(REG), get_smword(seg_reg, EA)); /* do operation */ | |
put_smbyte(seg_reg, EA, VAL); /* store result */ | |
} else { /* RM is second register */ | |
VAL = and_word(get_rword(REG), get_rword(RM)); /* do operation */ | |
put_rbyte(REG, VAL); /* store result */ | |
} | |
break; | |
case 0x24: /* AND byte - AL = AL AND DATA */ | |
DATA = fetch_byte(1); | |
VAL = and_byte(AL, DATA); /* do operation */ | |
AL = VAL; /* store result */ | |
break; | |
case 0x25: /* AND word - (EA) = (EA) AND REG */ | |
DATA = fetch_word(); | |
VAL = and_word(AX, DATA); /* do operation */ | |
AX = VAL; /* store result */ | |
break; | |
case 0x26: /* ES: - segment override prefix */ | |
seg_ovr = SEG_ES; | |
sysmode |= SYSMODE_SEGOVR_ES; | |
break; | |
case 0x27: /* DAA */ | |
if (((AL & 0xF) > 9) || GET_FLAG(AF)) { | |
AL += 6; | |
SET_FLAG(AF); | |
} | |
if ((AL > 0x9F) || GET_FLAG(CF)) { | |
AL += 0x60; | |
SET_FLAG(CF); | |
} | |
break; | |
case 0x28: /* SUB byte - REG = REG - (EA) */ | |
MRR = fetch_byte(1); | |
get_mrr_dec(MRR, &MOD, ®, &RM); | |
if (MOD != 0x3) { /* based, indexed, or based indexed addressing */ | |
EA = get_ea(MRR); /* get effective address */ | |
VAL = sub_byte(get_rbyte(REG), get_smbyte(seg_reg, EA)); /* do operation */ | |
put_rbyte(REG, VAL); /* store result */ | |
} else { /* RM is second register */ | |
VAL = sub_byte(get_rbyte(REG), get_rbyte(RM)); /* do operation */ | |
put_rbyte(REG, VAL); /* store result */ | |
} | |
break; | |
case 0x29: /* SUB word - (EA) = (EA) - REG */ | |
MRR = fetch_byte(1); | |
get_mrr_dec(MRR, &MOD, ®, &RM); | |
if (MOD != 0x3) { /* based, indexed, or based indexed addressing */ | |
EA = get_ea(MRR); /* get effective address */ | |
VAL = sub_word(get_rword(REG), get_smword(seg_reg, EA)); /* do operation */ | |
put_smword(seg_reg, EA, VAL); /* store result */ | |
} else { /* RM is second register */ | |
VAL = sub_word(get_rword(REG), get_rword(RM)); /* do operation */ | |
put_rbyte(REG, VAL); /* store result */ | |
} | |
break; | |
case 0x2A: /* SUB byte - REG = REG - (EA) */ | |
MRR = fetch_byte(1); | |
get_mrr_dec(MRR, &MOD, ®, &RM); | |
if (MOD != 0x3) { /* based, indexed, or based indexed addressing */ | |
EA = get_ea(MRR); /* get effective address */ | |
VAL = sub_byte(get_rbyte(REG), get_smbyte(seg_reg, EA)); /* do operation */ | |
put_rbyte(REG, VAL); /* store result */ | |
} else { /* RM is second register */ | |
VAL = sub_byte(get_rbyte(REG), get_rbyte(RM)); /* do operation */ | |
put_rbyte(REG, VAL); /* store result */ | |
} | |
break; | |
case 0x2B: /* SUB word - (EA) = (EA) - REG */ | |
MRR = fetch_byte(1); | |
get_mrr_dec(MRR, &MOD, ®, &RM); | |
if (MOD != 0x3) { /* based, indexed, or based indexed addressing */ | |
EA = get_ea(MRR); /* get effective address */ | |
VAL = sub_word(get_rword(REG), get_smword(seg_reg, EA)); /* do operation */ | |
put_smbyte(seg_reg, EA, VAL); /* store result */ | |
} else { /* RM is second register */ | |
VAL = sub_word(get_rword(REG), get_rword(RM)); /* do operation */ | |
put_rbyte(REG, VAL); /* store result */ | |
} | |
break; | |
case 0x2C: /* SUB byte - AL = AL - DATA */ | |
DATA = fetch_byte(1); | |
VAL = sub_byte(AL, DATA); /* do operation */ | |
AL = VAL; /* store result */ | |
break; | |
case 0x2D: /* SUB word - (EA) = (EA) - REG */ | |
DATA = fetch_word(); | |
VAL = sub_word(AX, DATA); /* do operation */ | |
AX = VAL; /* store result */ | |
break; | |
case 0x2E: /* DS: - segment override prefix */ | |
seg_ovr = SEG_DS; | |
sysmode |= SYSMODE_SEGOVR_DS; | |
break; | |
case 0x2F: /* DAS */ | |
if (((AL & 0xF) > 9) || GET_FLAG(AF)) { | |
AL -= 6; | |
SET_FLAG(AF); | |
} | |
if ((AL > 0x9F) || GET_FLAG(CF)) { | |
AL -= 0x60; | |
SET_FLAG(CF); | |
} | |
break; | |
case 0x30: /* XOR byte - REG = REG XOR (EA) */ | |
MRR = fetch_byte(1); | |
get_mrr_dec(MRR, &MOD, ®, &RM); | |
if (MOD != 0x3) { /* based, indexed, or based indexed addressing */ | |
EA = get_ea(MRR); /* get effective address */ | |
VAL = xor_byte(get_rbyte(REG), get_smbyte(seg_reg, EA)); /* do operation */ | |
put_rbyte(REG, VAL); /* store result */ | |
} else { /* RM is second register */ | |
VAL = xor_byte(get_rbyte(REG), get_rbyte(RM)); /* do operation */ | |
put_rbyte(REG, VAL); /* store result */ | |
} | |
break; | |
case 0x31: /* XOR word - (EA) = (EA) XOR REG */ | |
MRR = fetch_byte(1); | |
get_mrr_dec(MRR, &MOD, ®, &RM); | |
if (MOD != 0x3) { /* based, indexed, or based indexed addressing */ | |
EA = get_ea(MRR); /* get effective address */ | |
VAL = xor_word(get_rword(REG), get_smword(seg_reg, EA)); /* do operation */ | |
put_smword(seg_reg, EA, VAL); /* store result */ | |
} else { /* RM is second register */ | |
VAL = xor_word(get_rword(REG), get_rword(RM)); /* do operation */ | |
put_rbyte(REG, VAL); /* store result */ | |
} | |
break; | |
case 0x32: /* XOR byte - REG = REG XOR (EA) */ | |
MRR = fetch_byte(1); | |
get_mrr_dec(MRR, &MOD, ®, &RM); | |
if (MOD != 0x3) { /* based, indexed, or based indexed addressing */ | |
EA = get_ea(MRR); /* get effective address */ | |
VAL = xor_byte(get_rbyte(REG), get_smbyte(seg_reg, EA)); /* do operation */ | |
put_rbyte(REG, VAL); /* store result */ | |
} else { /* RM is second register */ | |
VAL = xor_byte(get_rbyte(REG), get_rbyte(RM)); /* do operation */ | |
put_rbyte(REG, VAL); /* store result */ | |
} | |
break; | |
case 0x33: /* XOR word - (EA) = (EA) XOR REG */ | |
MRR = fetch_byte(1); | |
get_mrr_dec(MRR, &MOD, ®, &RM); | |
if (MOD != 0x3) { /* based, indexed, or based indexed addressing */ | |
EA = get_ea(MRR); /* get effective address */ | |
VAL = xor_word(get_rword(REG), get_smword(seg_reg, EA)); /* do operation */ | |
put_smbyte(seg_reg, EA, VAL); /* store result */ | |
} else { /* RM is second register */ | |
VAL = xor_word(get_rword(REG), get_rword(RM)); /* do operation */ | |
put_rbyte(REG, VAL); /* store result */ | |
} | |
break; | |
case 0x34: /* XOR byte - AL = AL XOR DATA */ | |
DATA = fetch_byte(1); | |
VAL = xor_byte(AL, DATA); /* do operation */ | |
AL = VAL; /* store result */ | |
break; | |
case 0x35: /* XOR word - (EA) = (EA) XOR REG */ | |
DATA = fetch_word(); | |
VAL = xor_word(AX, DATA); /* do operation */ | |
AX = VAL; /* store result */ | |
break; | |
case 0x36: /* SS: - segment override prefix */ | |
seg_ovr = SEG_SS; | |
sysmode |= SYSMODE_SEGOVR_SS; | |
break; | |
case 0x37: /* AAA */ | |
if (((AL & 0xF) > 9) || GET_FLAG(AF)) { | |
AL += 6; | |
AH++; | |
SET_FLAG(AF); | |
} | |
CONDITIONAL_SET_FLAG(GET_FLAG(AF), CF); | |
AL &= 0xF; | |
break; | |
case 0x38: /* CMP byte - CMP (REG, (EA)) */ | |
MRR = fetch_byte(1); | |
get_mrr_dec(MRR, &MOD, ®, &RM); | |
if (MOD != 0x3) { /* based, indexed, or based indexed addressing */ | |
EA = get_ea(MRR); /* get effective address */ | |
VAL = xor_byte(get_rbyte(REG), get_smbyte(seg_reg, EA)); /* do operation */ | |
put_rbyte(REG, VAL); /* store result */ | |
} else { /* RM is second register */ | |
VAL = xor_byte(get_rbyte(REG), get_rbyte(RM)); /* do operation */ | |
put_rbyte(REG, VAL); /* store result */ | |
} | |
break; | |
case 0x39: /* CMP word - CMP ((EA), REG) */ | |
MRR = fetch_byte(1); | |
get_mrr_dec(MRR, &MOD, ®, &RM); | |
if (MOD != 0x3) { /* based, indexed, or based indexed addressing */ | |
EA = get_ea(MRR); /* get effective address */ | |
VAL = xor_word(get_rword(REG), get_smword(seg_reg, EA)); /* do operation */ | |
put_smword(seg_reg, EA, VAL); /* store result */ | |
} else { /* RM is second register */ | |
VAL = xor_word(get_rword(REG), get_rword(RM)); /* do operation */ | |
put_rbyte(REG, VAL); /* store result */ | |
} | |
break; | |
case 0x3A: /* CMP byte - CMP (REG, (EA)) */ | |
MRR = fetch_byte(1); | |
get_mrr_dec(MRR, &MOD, ®, &RM); | |
if (MOD != 0x3) { /* based, indexed, or based indexed addressing */ | |
EA = get_ea(MRR); /* get effective address */ | |
VAL = xor_byte(get_rbyte(REG), get_smbyte(seg_reg, EA)); /* do operation */ | |
put_rbyte(REG, VAL); /* store result */ | |
} else { /* RM is second register */ | |
VAL = xor_byte(get_rbyte(REG), get_rbyte(RM)); /* do operation */ | |
put_rbyte(REG, VAL); /* store result */ | |
} | |
break; | |
case 0x3B: /* CMP word - CMP ((EA), REG) */ | |
MRR = fetch_byte(1); | |
get_mrr_dec(MRR, &MOD, ®, &RM); | |
if (MOD != 0x3) { /* based, indexed, or based indexed addressing */ | |
EA = get_ea(MRR); /* get effective address */ | |
VAL = xor_word(get_rword(REG), get_smword(seg_reg, EA)); /* do operation */ | |
put_smbyte(seg_reg, EA, VAL); /* store result */ | |
} else { /* RM is second register */ | |
VAL = xor_word(get_rword(REG), get_rword(RM)); /* do operation */ | |
put_rbyte(REG, VAL); /* store result */ | |
} | |
break; | |
case 0x3C: /* CMP byte - CMP (AL, DATA) */ | |
DATA = fetch_byte(1); | |
VAL = xor_byte(AL, DATA); /* do operation */ | |
AL = VAL; /* store result */ | |
break; | |
case 0x3D: /* CMP word - CMP ((EA), REG) */ | |
DATA = fetch_word(); | |
VAL = xor_word(AX, DATA); /* do operation */ | |
AX = VAL; /* store result */ | |
break; | |
case 0x3E: /* DS: - segment override prefix */ | |
seg_ovr = SEG_DS; | |
sysmode |= SYSMODE_SEGOVR_DS; | |
break; | |
case 0x3F: /* AAS */ | |
if (((AL & 0xF) > 9) || GET_FLAG(AF)) { | |
AL -= 6; | |
AH--; | |
SET_FLAG(AF); | |
} | |
CONDITIONAL_SET_FLAG(GET_FLAG(AF), CF); | |
AL &= 0xF; | |
break; | |
case 0x40: /* INC AX */ | |
AX = inc_word(AX); | |
break; | |
case 0x41: /* INC CX */ | |
CX = inc_word(CX); | |
break; | |
case 0x42: /* INC DX */ | |
DX = inc_word(DX); | |
break; | |
case 0x43: /* INC BX */ | |
BX = inc_word(BX); | |
break; | |
case 0x44: /* INC SP */ | |
SP = inc_word(SP); | |
break; | |
case 0x45: /* INC BP */ | |
BP = inc_word(BP); | |
break; | |
case 0x46: /* INC SI */ | |
SI = inc_word(SI); | |
break; | |
case 0x47: /* INC DI */ | |
DI = inc_word(DI); | |
break; | |
case 0x48: /* DEC AX */ | |
AX = dec_word(AX); | |
break; | |
case 0x49: /* DEC CX */ | |
CX = dec_word(CX); | |
break; | |
case 0x4A: /* DEC DX */ | |
DX = dec_word(DX); | |
break; | |
case 0x4B: /* DEC BX */ | |
BX = dec_word(BX); | |
break; | |
case 0x4C: /* DEC SP */ | |
SP = dec_word(SP); | |
break; | |
case 0x4D: /* DEC BP */ | |
BP = dec_word(BP); | |
break; | |
case 0x4E: /* DEC SI */ | |
SI = dec_word(SI); | |
break; | |
case 0x4F: /* DEC DI */ | |
DI = dec_word(DI); | |
break; | |
case 0x50: /* PUSH AX */ | |
push_word(AX); | |
break; | |
case 0x51: /* PUSH CX */ | |
push_word(CX); | |
break; | |
case 0x52: /* PUSH DX */ | |
push_word(DX); | |
break; | |
case 0x53: /* PUSH BX */ | |
push_word(BX); | |
break; | |
case 0x54: /* PUSH SP */ | |
push_word(SP); | |
break; | |
case 0x55: /* PUSH BP */ | |
push_word(BP); | |
break; | |
case 0x56: /* PUSH SI */ | |
push_word(SI); | |
break; | |
case 0x57: /* PUSH DI */ | |
push_word(DI); | |
break; | |
case 0x58: /* POP AX */ | |
AX = pop_word(); | |
break; | |
case 0x59: /* POP CX */ | |
CX = pop_word(); | |
break; | |
case 0x5A: /* POP DX */ | |
DX = pop_word(); | |
break; | |
case 0x5B: /* POP BX */ | |
BX = pop_word(); | |
break; | |
case 0x5C: /* POP SP */ | |
SP = pop_word(); | |
break; | |
case 0x5D: /* POP BP */ | |
BP = pop_word(); | |
break; | |
case 0x5E: /* POP SI */ | |
SI = pop_word(); | |
break; | |
case 0x5F: /* POP DI */ | |
DI = pop_word(); | |
break; | |
/* 0x60 - 0x6F - Not implemented on 8086/8088 */ | |
case 0x70: /* JO short label */ | |
/* jump to byte offset if overflow flag is set */ | |
OFF = sign_ext(fetch_byte(1)); | |
EA = (IP + OFF) & ADDRMASK16; | |
if (GET_FLAG(OF)) | |
IP = EA; | |
break; | |
case 0x71: /* JNO short label */ | |
/* jump to byte offset if overflow flag is clear */ | |
OFF = sign_ext(fetch_byte(1)); | |
EA = (IP + OFF) & ADDRMASK16; | |
if (!GET_FLAG(OF)) | |
IP = EA; | |
break; | |
case 0x72: /* JB/JNAE/JC short label */ | |
/* jump to byte offset if carry flag is set. */ | |
OFF = sign_ext(fetch_byte(1)); | |
EA = (IP + OFF) & ADDRMASK16; | |
if (GET_FLAG(CF)) | |
IP = EA; | |
break; | |
case 0x73: /* JNB/JAE/JNC short label */ | |
/* jump to byte offset if carry flsg is clear */ | |
OFF = sign_ext(fetch_byte(1)); | |
EA = (IP + OFF) & ADDRMASK16; | |
if (!GET_FLAG(CF)) | |
IP = EA; | |
break; | |
case 0x74: /* JE/JZ short label */ | |
/* jump to byte offset if zero flag is set */ | |
OFF = sign_ext(fetch_byte(1)); | |
EA = (IP + OFF) & ADDRMASK16; | |
if (GET_FLAG(ZF)) | |
IP = EA; | |
break; | |
case 0x75: /* JNE/JNZ short label */ | |
/* jump to byte offset if zero flag is clear */ | |
OFF = sign_ext(fetch_byte(1)); | |
EA = (IP + OFF) & ADDRMASK16; | |
if (!GET_FLAG(ZF)) | |
IP = EA; | |
break; | |
case 0x76: /* JBE/JNA short label */ | |
/* jump to byte offset if carry flag is set or if the zero | |
flag is set. */ | |
OFF = sign_ext(fetch_byte(1)); | |
EA = (IP + OFF) & ADDRMASK16; | |
if (GET_FLAG(CF) || GET_FLAG(ZF)) | |
IP = EA; | |
break; | |
case 0x77: /* JNBE/JA short label */ | |
/* jump to byte offset if carry flag is clear and if the zero | |
flag is clear */ | |
OFF = sign_ext(fetch_byte(1)); | |
EA = (IP + OFF) & ADDRMASK16; | |
if (!(GET_FLAG(CF) || GET_FLAG(ZF))) | |
IP = EA; | |
break; | |
case 0x78: /* JS short label */ | |
/* jump to byte offset if sign flag is set */ | |
OFF = sign_ext(fetch_byte(1)); | |
EA = (IP + OFF) & ADDRMASK16; | |
if (GET_FLAG(SF)) | |
IP = EA; | |
break; | |
case 0x79: /* JNS short label */ | |
/* jump to byte offset if sign flag is clear */ | |
OFF = sign_ext(fetch_byte(1)); | |
EA = (IP + OFF) & ADDRMASK16; | |
if (!GET_FLAG(SF)) | |
IP = EA; | |
break; | |
case 0x7A: /* JP/JPE short label */ | |
/* jump to byte offset if parity flag is set (even) */ | |
OFF = sign_ext(fetch_byte(1)); | |
EA = (IP + OFF) & ADDRMASK16; | |
if (GET_FLAG(PF)) | |
IP = EA; | |
break; | |
case 0x7B: /* JNP/JPO short label */ | |
/* jump to byte offset if parity flsg is clear (odd) */ | |
OFF = sign_ext(fetch_byte(1)); | |
EA = (IP + OFF) & ADDRMASK16; | |
if (!GET_FLAG(PF)) | |
IP = EA; | |
break; | |
case 0x7C: /* JL/JNGE short label */ | |
/* jump to byte offset if sign flag not equal to overflow flag. */ | |
OFF = sign_ext(fetch_byte(1)); | |
EA = (IP + OFF) & ADDRMASK16; | |
if ((GET_FLAG(SF) != 0) ^ (GET_FLAG(OF) != 0)) | |
IP = EA; | |
break; | |
case 0x7D: /* JNL/JGE short label */ | |
/* jump to byte offset if sign flag equal to overflow flag. */ | |
OFF = sign_ext(fetch_byte(1)); | |
EA = (IP + OFF) & ADDRMASK16; | |
if ((GET_FLAG(SF) != 0) == (GET_FLAG(OF) != 0)) | |
IP = EA; | |
break; | |
case 0x7E: /* JLE/JNG short label */ | |
/* jump to byte offset if sign flag not equal to overflow flag | |
or the zero flag is set */ | |
OFF = sign_ext(fetch_byte(1)); | |
EA = (IP + OFF) & ADDRMASK16; | |
if (((GET_FLAG(SF) != 0) ^ (GET_FLAG(OF) != 0)) || GET_FLAG(ZF)) | |
IP = EA; | |
break; | |
case 0x7F: /* JNLE/JG short label */ | |
/* jump to byte offset if sign flag equal to overflow flag. | |
and the zero flag is clear*/ | |
OFF = sign_ext(fetch_byte(1)); | |
EA = (IP + OFF) & ADDRMASK16; | |
if (((GET_FLAG(SF) != 0) == (GET_FLAG(OF) != 0)) || !GET_FLAG(ZF)) | |
IP = EA; | |
break; | |
case 0x80: /* byte operands */ | |
MRR = fetch_byte(1); | |
get_mrr_dec(MRR, &MOD, ®, &RM); | |
if (MOD != 0x3) { /* based, indexed, or based indexed addressing */ | |
EA = get_ea(MRR); /* get effective address */ | |
DATA = fetch_byte(1); /* must be done after DISP is collected */ | |
switch(REG) { | |
case 0: | |
VAL = add_byte(get_smbyte(seg_reg, EA), DATA); /* ADD mem8, immed8 */ | |
break; | |
case 1: | |
VAL = or_byte(get_smbyte(seg_reg, EA), DATA); /* OR mem8, immed8 */ | |
break; | |
case 2: | |
VAL = adc_byte(get_smbyte(seg_reg, EA), DATA); /* ADC mem8, immed8 */ | |
break; | |
case 3: | |
VAL = sbb_byte(get_smbyte(seg_reg, EA), DATA); /* SBB mem8, immed8 */ | |
break; | |
case 4: | |
VAL = and_byte(get_smbyte(seg_reg, EA), DATA); /* AND mem8, immed8 */ | |
break; | |
case 5: | |
VAL = sub_byte(get_smbyte(seg_reg, EA), DATA); /* SUB mem8, immed8 */ | |
break; | |
case 6: | |
VAL = xor_byte(get_smbyte(seg_reg, EA), DATA); /* XOR mem8, immed8 */ | |
break; | |
case 7: | |
VAL = cmp_byte(get_smbyte(seg_reg, EA), DATA); /* CMP mem8, immed8 */ | |
break; | |
} | |
put_rbyte(EA, VAL); /* store result */ | |
} else { /* RM is second register */ | |
switch(REG) { | |
case 0: | |
VAL = add_byte(get_rbyte(RM), DATA); /* ADD REG8, immed8 */ | |
break; | |
case 1: | |
VAL = or_byte(get_rbyte(RM), DATA); /* OR REG8, immed8 */ | |
break; | |
case 2: | |
VAL = adc_byte(get_rbyte(RM), DATA); /* ADC REG8, immed8 */ | |
break; | |
case 3: | |
VAL = sbb_byte(get_rbyte(RM), DATA); /* SBB REG8, immed8 */ | |
break; | |
case 4: | |
VAL = and_byte(get_rbyte(RM), DATA); /* AND REG8, immed8 */ | |
break; | |
case 5: | |
VAL = sub_byte(get_rbyte(RM), DATA); /* SUB REG8, immed8 */ | |
break; | |
case 6: | |
VAL = xor_byte(get_rbyte(RM), DATA); /* XOR REG8, immed8 */ | |
break; | |
case 7: | |
VAL = cmp_byte(get_rbyte(RM), DATA); /* CMP REG8, immed8 */ | |
break; | |
} | |
put_rbyte(REG, VAL); /* store result */ | |
} | |
break; | |
case 0x81: /* word operands */ | |
MRR = fetch_byte(1); | |
get_mrr_dec(MRR, &MOD, ®, &RM); | |
if (MOD != 0x3) { /* based, indexed, or based indexed addressing */ | |
EA = get_ea(MRR); /* get effective address */ | |
DATA = fetch_byte(1) << 8; /* must be done after DISP is collected */ | |
DATA |= fetch_byte(1); | |
switch(REG) { | |
case 0: | |
VAL = add_word(get_smword(seg_reg, EA), DATA); /* ADD mem16, immed16 */ | |
break; | |
case 1: | |
VAL = or_word(get_smword(seg_reg, EA), DATA); /* OR mem16, immed16 */ | |
break; | |
case 2: | |
VAL = adc_word(get_smword(seg_reg, EA), DATA); /* ADC mem16, immed16 */ | |
break; | |
case 3: | |
VAL = sbb_word(get_smword(seg_reg, EA), DATA); /* SBB mem16, immed16 */ | |
break; | |
case 4: | |
VAL = and_word(get_smword(seg_reg, EA), DATA); /* AND mem16, immed16 */ | |
break; | |
case 5: | |
VAL = sub_word(get_smword(seg_reg, EA), DATA); /* SUB mem16, immed16 */ | |
break; | |
case 6: | |
VAL = xor_word(get_smword(seg_reg, EA), DATA); /* XOR mem16, immed16 */ | |
break; | |
case 7: | |
VAL = cmp_word(get_smword(seg_reg, EA), DATA); /* CMP mem16, immed16 */ | |
break; | |
} | |
put_rword(EA, VAL); /* store result */ | |
} else { /* RM is second register */ | |
switch(REG) { | |
case 0: | |
VAL = add_word(get_rword(RM), DATA); /* ADD reg16, immed16 */ | |
break; | |
case 1: | |
VAL = or_word(get_rword(RM), DATA); /* OR reg16, immed16 */ | |
break; | |
case 2: | |
VAL = adc_word(get_rword(RM), DATA); /* ADC reg16, immed16 */ | |
break; | |
case 3: | |
VAL = sbb_word(get_rword(RM), DATA); /* SBB reg16, immed16 */ | |
break; | |
case 4: | |
VAL = and_word(get_rword(RM), DATA); /* AND reg16, immed16 */ | |
break; | |
case 5: | |
VAL = sub_word(get_rword(RM), DATA); /* SUB reg16, immed16 */ | |
break; | |
case 6: | |
VAL = xor_word(get_rword(RM), DATA); /* XOR reg16, immed16 */ | |
break; | |
case 7: | |
VAL = cmp_word(get_rword(RM), DATA); /* CMP reg16, immed16 */ | |
break; | |
} | |
put_rword(RM, VAL); /* store result */ | |
} | |
break; | |
case 0x82: /* byte operands */ | |
MRR = fetch_byte(1); | |
get_mrr_dec(MRR, &MOD, ®, &RM); | |
if (MOD != 0x3) { /* based, indexed, or based indexed addressing */ | |
EA = get_ea(MRR); /* get effective address */ | |
DATA = fetch_byte(1); /* must be done after DISP is collected */ | |
switch(REG) { | |
case 0: | |
VAL = add_byte(get_smbyte(seg_reg, EA), DATA); /* ADD mem8, immed8 */ | |
break; | |
case 2: | |
VAL = adc_byte(get_smbyte(seg_reg, EA), DATA); /* ADC mem8, immed8 */ | |
break; | |
case 3: | |
VAL = sbb_byte(get_smbyte(seg_reg, EA), DATA); /* SBB mem8, immed8 */ | |
break; | |
case 5: | |
VAL = sub_byte(get_smbyte(seg_reg, EA), DATA); /* SUB mem8, immed8 */ | |
break; | |
case 7: | |
VAL = cmp_byte(get_smbyte(seg_reg, EA), DATA); /* CMP mem8, immed8 */ | |
break; | |
default: /* bad opcodes */ | |
reason = STOP_OPCODE; | |
IP -= 2; | |
break; | |
} | |
put_rbyte(EA, VAL); /* store result */ | |
} else { /* RM is second register */ | |
switch(REG) { | |
case 0: | |
VAL = add_byte(get_rbyte(RM), DATA); /* ADD reg8, immed8 */ | |
break; | |
case 2: | |
VAL = adc_byte(get_rbyte(RM), DATA); /* ADC reg8, immed8 */ | |
break; | |
case 3: | |
VAL = sbb_byte(get_rbyte(RM), DATA); /* SBB reg8, immed8 */ | |
break; | |
case 5: | |
VAL = sub_byte(get_rbyte(RM), DATA); /* SUB reg8, immed8 */ | |
break; | |
case 7: | |
VAL = cmp_byte(get_rbyte(RM), DATA); /* CMP reg8, immed8 */ | |
break; | |
default: /* bad opcodes */ | |
reason = STOP_OPCODE; | |
IP -= 2; | |
break; | |
} | |
put_rbyte(REG, VAL); /* store result */ | |
} | |
break; | |
case 0x83: /* word operands */ | |
MRR = fetch_byte(1); | |
get_mrr_dec(MRR, &MOD, ®, &RM); | |
if (MOD != 0x3) { /* based, indexed, or based indexed addressing */ | |
EA = get_ea(MRR); /* get effective address */ | |
DATA = fetch_byte(1) << 8; /* must be done after DISP is collected */ | |
if (DATA & 0x80) | |
DATA |= 0xFF00; | |
else | |
DATA &= 0xFF; | |
switch(REG) { | |
case 0: | |
VAL = add_word(get_smword(seg_reg, EA), DATA); /* ADD mem16, immed8-SX */ | |
break; | |
case 2: | |
VAL = adc_word(get_smword(seg_reg, EA), DATA); /* ADC mem16, immed8-SX */ | |
break; | |
case 3: | |
VAL = sbb_word(get_smword(seg_reg, EA), DATA); /* SBB mem16, immed8-SX */ | |
break; | |
case 5: | |
VAL = sub_word(get_smword(seg_reg, EA), DATA); /* SUB mem16, immed8-SX */ | |
break; | |
case 7: | |
VAL = cmp_word(get_smword(seg_reg, EA), DATA); /* CMP mem16, immed8-SX */ | |
break; | |
default: /* bad opcodes */ | |
reason = STOP_OPCODE; | |
IP -= 2; | |
break; | |
} | |
put_rword(EA, VAL); /* store result */ | |
} else { /* RM is second register */ | |
switch(REG) { | |
case 0: | |
VAL = add_word(get_rword(RM), DATA); /* ADD reg16, immed8-SX */ | |
break; | |
case 2: | |
VAL = adc_word(get_rword(RM), DATA); /* ADC reg16, immed8-SX */ | |
break; | |
case 3: | |
VAL = sbb_word(get_rword(RM), DATA); /* SBB reg16, immed8-SX */ | |
break; | |
case 5: | |
VAL = sub_word(get_rword(RM), DATA); /* CUB reg16, immed8-SX */ | |
break; | |
case 7: | |
VAL = cmp_word(get_rword(RM), DATA); /* CMP reg16, immed8-SX */ | |
break; | |
default: /* bad opcodes */ | |
reason = STOP_OPCODE; | |
IP -= 2; | |
break; | |
} | |
put_rword(RM, VAL); /* store result */ | |
} | |
break; | |
case 0x84: | |
MRR = fetch_byte(1); | |
get_mrr_dec(MRR, &MOD, ®, &RM); | |
if (MOD != 0x3) { /* based, indexed, or based indexed addressing */ | |
EA = get_ea(MRR); /* get effective address */ | |
test_byte(get_smbyte(seg_reg, EA),get_rbyte(REG)); /* TEST mem8, reg8 */ | |
} else { | |
test_byte(get_rbyte(REG),get_rbyte(RM)); /* TEST reg8, reg8 */ | |
} | |
break; | |
case 0x85: | |
MRR = fetch_byte(1); | |
get_mrr_dec(MRR, &MOD, ®, &RM); | |
if (MOD != 0x3) { /* based, indexed, or based indexed addressing */ | |
EA = get_ea(MRR); /* get effective address */ | |
test_word(get_smword(seg_reg, EA),get_rword(REG)); /* TEST mem16, reg16 */ | |
} else { | |
test_word(get_rword(REG),get_rword(RM)); /* TEST reg16, reg16 */ | |
} | |
break; | |
case 0x86: | |
MRR = fetch_byte(1); | |
get_mrr_dec(MRR, &MOD, ®, &RM); | |
if (MOD != 0x3) { /* based, indexed, or based indexed addressing */ | |
EA = get_ea(MRR); /* get effective address */ | |
VAL = get_rbyte(REG);/* XCHG mem8, reg8 */ | |
put_rbyte(REG, get_smbyte(seg_reg, EA)); | |
put_smbyte(seg_reg, EA, VAL); | |
} else { | |
VAL = get_rbyte(RM);/* XCHG reg8, reg8 */ | |
put_rbyte(RM, get_rbyte(REG)); | |
put_rbyte(REG, VAL); | |
} | |
break; | |
case 0x87: | |
MRR = fetch_byte(1); | |
get_mrr_dec(MRR, &MOD, ®, &RM); | |
if (MOD != 0x3) { /* based, indexed, or based indexed addressing */ | |
EA = get_ea(MRR); /* get effective address */ | |
VAL = get_rword(REG);/* XCHG mem16, reg16 */ | |
put_rword(REG, get_smword(seg_reg, EA)); | |
put_smword(seg_reg, EA, VAL); | |
} else { | |
VAL = get_rword(RM);/* XCHG reg16, reg16 */ | |
put_rword(RM, get_rword(REG)); | |
put_rword(REG, VAL); | |
} | |
break; | |
case 0x88: | |
MRR = fetch_byte(1); | |
get_mrr_dec(MRR, &MOD, ®, &RM); | |
if (MOD != 0x3) { /* based, indexed, or based indexed addressing */ | |
EA = get_ea(MRR); /* get effective address */ | |
put_smbyte(seg_reg, EA, get_rbyte(REG)); /* MOV mem8, reg8 */ | |
} else | |
put_rbyte(REG, get_rbyte(RM)); /* MOV reg8, reg8 */ | |
break; | |
case 0x89: | |
MRR = fetch_byte(1); | |
get_mrr_dec(MRR, &MOD, ®, &RM); | |
if (MOD != 0x3) { /* based, indexed, or based indexed addressing */ | |
EA = get_ea(MRR); /* get effective address */ | |
put_smword(seg_reg, EA, get_rword(REG)); /* MOV mem16, reg16 */ | |
} else | |
put_rword(REG, get_rword(RM)); /* MOV reg16, reg16 */ | |
break; | |
case 0x8A: | |
MRR = fetch_byte(1); | |
get_mrr_dec(MRR, &MOD, ®, &RM); | |
if (MOD != 0x3) { /* based, indexed, or based indexed addressing */ | |
EA = get_ea(MRR); /* get effective address */ | |
put_rbyte(REG, get_smbyte(seg_reg, EA)); /* MOV reg8, mem8 */ | |
} else | |
put_rbyte(REG, get_rbyte(RM)); /* MOV reg8, reg8 */ | |
break; | |
case 0x8B: | |
MRR = fetch_byte(1); | |
get_mrr_dec(MRR, &MOD, ®, &RM); | |
if (MOD != 0x3) { /* based, indexed, or based indexed addressing */ | |
EA = get_ea(MRR); /* get effective address */ | |
put_rword(REG, get_smword(seg_reg, EA)); /* MOV reg16, mem16 */ | |
} else | |
put_rword(REG, get_rword(RM)); /* MOV reg16, reg16 */ | |
break; | |
case 0x8C: | |
MRR = fetch_byte(1); | |
get_mrr_dec(MRR, &MOD, ®, &RM); | |
if (MOD != 0x3) { /* based, indexed, or based indexed addressing */ | |
EA = get_ea(MRR); /* get effective address */ | |
switch(REG) { | |
case 0: /* MOV mem16, ES */ | |
put_smword(seg_reg, EA, ES); | |
break; | |
case 1: /* MOV mem16, CS */ | |
put_smword(seg_reg, EA, CS); | |
break; | |
case 2: /* MOV mem16, SS */ | |
put_smword(seg_reg, EA, SS); | |
break; | |
case 3: /* MOV mem16, DS */ | |
put_smword(seg_reg, EA, DS); | |
break; | |
default: /* bad opcodes */ | |
reason = STOP_OPCODE; | |
IP -= 2; | |
break; | |
} | |
} else { | |
switch(REG) { | |
case 0: /* MOV reg16, ES */ | |
put_rword(RM, ES); | |
break; | |
case 1: /* MOV reg16, CS */ | |
put_rword(RM, CS); | |
break; | |
case 2: /* MOV reg16, SS */ | |
put_rword(RM, SS); | |
break; | |
case 3: /* MOV reg16, DS */ | |
put_rword(RM, DS); | |
break; | |
default: /* bad opcodes */ | |
reason = STOP_OPCODE; | |
IP -= 2; | |
break; | |
} | |
} | |
break; | |
case 0x8D: | |
MRR = fetch_byte(1); | |
get_mrr_dec(MRR, &MOD, ®, &RM); | |
if (MOD != 0x3) { /* based, indexed, or based indexed addressing */ | |
EA = get_ea(MRR); /* get effective address */ | |
put_rword(REG, EA); /* LEA reg16, mem16 */ | |
} else { | |
reason = STOP_OPCODE; | |
IP -= 2; | |
} | |
break; | |
case 0x8E: | |
MRR = fetch_byte(1); | |
get_mrr_dec(MRR, &MOD, ®, &RM); | |
if (MOD != 0x3) { /* based, indexed, or based indexed addressing */ | |
EA = get_ea(MRR); /* get effective address */ | |
switch(REG) { | |
case 0: /* MOV ES, mem16 */ | |
ES = get_smword(seg_reg, EA); | |
break; | |
case 1: /* MOV CS, mem16 */ | |
CS = get_smword(seg_reg, EA); | |
break; | |
case 2: /* MOV SS, mem16 */ | |
SS = get_smword(seg_reg, EA); | |
break; | |
case 3: /* MOV DS, mem16 */ | |
DS = get_smword(seg_reg, EA); | |
break; | |
default: /* bad opcodes */ | |
reason = STOP_OPCODE; | |
IP -= 2; | |
break; | |
} | |
} else { | |
switch(REG) { | |
case 0: /* MOV ES, reg16 */ | |
ES = get_rword(RM); | |
break; | |
case 1: /* MOV CS, reg16 */ | |
CS = get_rword(RM); | |
break; | |
case 2: /* MOV SS, reg16 */ | |
SS = get_rword(RM); | |
break; | |
case 3: /* MOV DS, reg16 */ | |
DS = get_rword(RM); | |
break; | |
default: /* bad opcodes */ | |
reason = STOP_OPCODE; | |
IP -= 2; | |
break; | |
} | |
} | |
break; | |
case 0x8f: | |
MRR = fetch_byte(1); | |
get_mrr_dec(MRR, &MOD, ®, &RM); | |
if (MOD != 0x3) { /* based, indexed, or based indexed addressing */ | |
EA = get_ea(MRR); /* get effective address */ | |
put_smword(seg_reg, EA, pop_word()); | |
} else { | |
reason = STOP_OPCODE; | |
IP -= 2; | |
} | |
break; | |
case 0x90: /* NOP */ | |
break; | |
case 0x91: /* XCHG AX, CX */ | |
VAL = AX; | |
AX = CX; | |
CX = VAL; | |
break; | |
case 0x92: /* XCHG AX, DX */ | |
VAL = AX; | |
AX = DX; | |
DX = VAL; | |
break; | |
case 0x93: /* XCHG AX, BX */ | |
VAL = AX; | |
AX = BX; | |
BX = VAL; | |
break; | |
case 0x94: /* XCHG AX, SP */ | |
VAL = AX; | |
AX = SP; | |
SP = VAL; | |
break; | |
case 0x95: /* XCHG AX, BP */ | |
VAL = AX; | |
AX = BP; | |
BP = VAL; | |
break; | |
case 0x96: /* XCHG AX, SI */ | |
VAL = AX; | |
AX = SI; | |
SI = VAL; | |
break; | |
case 0x97: /* XCHG AX, DI */ | |
VAL = AX; | |
AX = DI; | |
DI = VAL; | |
break; | |
case 0x98: /* cbw */ | |
if (AL & 0x80) | |
AH = 0xFF; | |
else | |
AH = 0; | |
break; | |
case 0x99: /* cbw */ | |
if (AX & 0x8000) | |
DX = 0xffff; | |
else | |
DX = 0x0; | |
break; | |
case 0x9A: /* CALL FAR proc */ | |
OFF = fetch_word(); /* do operation */ | |
SEG = fetch_word(); | |
push_word(CS); | |
CS = SEG; | |
push_word(IP); | |
IP = OFF; | |
break; | |
case 0x9B: /* WAIT */ | |
break; | |
case 0x9C: /* PUSHF */ | |
VAL = PSW; | |
VAL &= PSW_MSK; | |
VAL |= PSW_ALWAYS_ON; | |
push_word(VAL); | |
break; | |
case 0x9D: /* POPF */ | |
PSW = pop_word(); | |
break; | |
case 0x9E: /* SAHF */ | |
PSW &= 0xFFFFFF00; | |
PSW |= AH; | |
break; | |
case 0x9F: /* LAHF */ | |
AH = PSW & 0xFF; | |
AH |= 0x2; | |
break; | |
case 0xA0: /* MOV AL, mem8 */ | |
OFF = fetch_word(); | |
set_segreg(SEG_DS); /* to allow segment override */ | |
AL = get_smbyte(seg_reg, OFF); | |
break; | |
case 0xA1: /* MOV AX, mem16 */ | |
OFF = fetch_word(); | |
set_segreg(SEG_DS); /* to allow segment override */ | |
AX = get_smword(seg_reg, OFF); | |
break; | |
case 0xA2: /* MOV mem8, AL */ | |
OFF = fetch_word(); | |
set_segreg(SEG_DS); /* to allow segment override */ | |
put_smbyte(seg_reg, OFF, AL); | |
break; | |
case 0xA3: /* MOV mem16, AX */ | |
OFF = fetch_word(); | |
set_segreg(SEG_DS); /* to allow segment override */ | |
put_smword(seg_reg, OFF, AX); | |
break; | |
case 0xA4: /* MOVS dest-str8, src-str8 */ | |
if (GET_FLAG(DF)) /* down */ | |
INC = -1; | |
else | |
INC = 1; | |
while (CX != 0) { | |
VAL = get_smbyte(seg_reg, SI); | |
put_smbyte(ES, DI, VAL); | |
CX--; | |
SI += INC; | |
DI += INC; | |
} | |
break; | |
case 0xA5: /* MOVS dest-str16, src-str16 */ | |
if (GET_FLAG(DF)) /* down */ | |
INC = -2; | |
else | |
INC = 2; | |
while (CX != 0) { | |
VAL = get_smword(seg_reg, SI); | |
put_smword(ES, DI, VAL); | |
CX--; | |
SI += INC; | |
DI += INC; | |
} | |
break; | |
case 0xA6: /* CMPS dest-str8, src-str8 */ | |
if (GET_FLAG(DF)) /* down */ | |
INC = -1; | |
else | |
INC = 1; | |
while (CX != 0) { | |
VAL = get_smbyte(seg_reg, SI); | |
VAL1 = get_smbyte(ES, DI); | |
cmp_byte(VAL, VAL1); | |
CX--; | |
SI += INC; | |
DI += INC; | |
if (GET_FLAG(ZF) == 0) | |
break; | |
} | |
break; | |
case 0xA7: /* CMPS dest-str16, src-str16 */ | |
if (GET_FLAG(DF)) /* down */ | |
INC = -2; | |
else | |
INC = 2; | |
while (CX != 0) { | |
VAL = get_smword(seg_reg, SI); | |
VAL1 = get_smword(ES, DI); | |
cmp_word(VAL, VAL1); | |
CX--; | |
SI += INC; | |
DI += INC; | |
if (GET_FLAG(ZF) == 0) | |
break; | |
} | |
break; | |
case 0xA8: /* TEST AL, immed8 */ | |
VAL = fetch_byte(1); | |
test_byte(AL, VAL); | |
break; | |
case 0xA9: /* TEST AX, immed8 */ | |
VAL = fetch_word(); | |
test_word(AX, VAL); | |
break; | |
case 0xAA: /* STOS dest-str8 */ | |
if (GET_FLAG(DF)) /* down */ | |
INC = -1; | |
else | |
INC = 1; | |
if (sysmode & (SYSMODE_PREFIX_REPE | SYSMODE_PREFIX_REPNE)) { | |
while (CX != 0) { | |
put_smbyte(ES, DI, AL); | |
CX--; | |
DI += INC; | |
} | |
sysmode &= ~(SYSMODE_PREFIX_REPE | SYSMODE_PREFIX_REPNE); | |
} else { | |
put_smbyte(ES, DI, AL); | |
DI += INC; | |
} | |
break; | |
case 0xAB: /* STOS dest-str16 */ | |
if (GET_FLAG(DF)) /* down */ | |
INC = -1; | |
else | |
INC = 1; | |
if (sysmode & (SYSMODE_PREFIX_REPE | SYSMODE_PREFIX_REPNE)) { | |
while (CX != 0) { | |
put_smword(ES, DI, AX); | |
CX--; | |
DI += INC; | |
} | |
sysmode &= ~(SYSMODE_PREFIX_REPE | SYSMODE_PREFIX_REPNE); | |
} else { | |
put_smword(ES, DI, AL); | |
DI += INC; | |
} | |
break; | |
case 0xAC: /* LODS dest-str8 */ | |
if (GET_FLAG(DF)) /* down */ | |
INC = -1; | |
else | |
INC = 1; | |
set_segreg(SEG_DS); /* allow overrides */ | |
if (sysmode & (SYSMODE_PREFIX_REPE | SYSMODE_PREFIX_REPNE)) { | |
while (CX != 0) { | |
AL = get_smbyte(seg_reg, SI); | |
CX--; | |
SI += INC; | |
} | |
sysmode &= ~(SYSMODE_PREFIX_REPE | SYSMODE_PREFIX_REPNE); | |
} else { | |
AL = get_smbyte(seg_reg, SI); | |
SI += INC; | |
} | |
break; | |
case 0xAD: /* LODS dest-str16 */ | |
if (GET_FLAG(DF)) /* down */ | |
INC = -1; | |
else | |
INC = 1; | |
set_segreg(SEG_DS); /* allow overrides */ | |
if (sysmode & (SYSMODE_PREFIX_REPE | SYSMODE_PREFIX_REPNE)) { | |
while (CX != 0) { | |
AX = get_smword(seg_reg, SI); | |
CX--; | |
SI += INC; | |
} | |
sysmode &= ~(SYSMODE_PREFIX_REPE | SYSMODE_PREFIX_REPNE); | |
} else { | |
AX = get_smword(seg_reg, SI); | |
SI += INC; | |
} | |
break; | |
case 0xAE: /* SCAS dest-str8 */ | |
if (GET_FLAG(DF)) /* down */ | |
INC = -1; | |
else | |
INC = 1; | |
if (sysmode & (SYSMODE_PREFIX_REPE | SYSMODE_PREFIX_REPNE)) { | |
while (CX != 0) { | |
VAL = get_smbyte(ES, DI); | |
cmp_byte(AL, VAL); | |
CX--; | |
DI += INC; | |
if (GET_FLAG(ZF) == 0) | |
break; | |
} | |
sysmode &= ~(SYSMODE_PREFIX_REPE | SYSMODE_PREFIX_REPNE); | |
} else { | |
VAL = get_smbyte(ES, DI); | |
cmp_byte(AL, VAL); | |
DI += INC; | |
} | |
break; | |
case 0xAF: /* SCAS dest-str16 */ | |
if (GET_FLAG(DF)) /* down */ | |
INC = -2; | |
else | |
INC = 2; | |
if (sysmode & (SYSMODE_PREFIX_REPE | SYSMODE_PREFIX_REPNE)) { | |
while (CX != 0) { | |
VAL = get_smword(ES, DI); | |
cmp_word(AX, VAL); | |
CX--; | |
DI += INC; | |
if (GET_FLAG(ZF) == 0) | |
break; | |
} | |
sysmode &= ~(SYSMODE_PREFIX_REPE | SYSMODE_PREFIX_REPNE); | |
} else { | |
VAL = get_smword(ES, DI); | |
cmp_byte(AL, VAL); | |
DI += INC; | |
} | |
break; | |
case 0xB0: /* MOV AL,immed8 */ | |
AL = fetch_byte(1); | |
break; | |
case 0xB1: /* MOV CL,immed8 */ | |
CL = fetch_byte(1); | |
break; | |
case 0xB2: /* MOV DL,immed8 */ | |
DL = fetch_byte(1); | |
break; | |
case 0xB3: /* MOV BL,immed8 */ | |
BL = fetch_byte(1); | |
break; | |
case 0xB4: /* MOV AH,immed8 */ | |
AH = fetch_byte(1); | |
break; | |
case 0xB5: /* MOV CH,immed8 */ | |
CH = fetch_byte(1); | |
break; | |
case 0xB6: /* MOV DH,immed8 */ | |
DH = fetch_byte(1); | |
break; | |
case 0xB7: /* MOV BH,immed8 */ | |
BH = fetch_byte(1); | |
break; | |
case 0xB8: /* MOV AX,immed16 */ | |
AX = fetch_word(); | |
break; | |
case 0xB9: /* MOV CX,immed16 */ | |
CX = fetch_word(); | |
break; | |
case 0xBA: /* MOV DX,immed16 */ | |
DX = fetch_word(); | |
break; | |
case 0xBB: /* MOV BX,immed16 */ | |
BX = fetch_word(); | |
break; | |
case 0xBC: /* MOV SP,immed16 */ | |
SP = fetch_word(); | |
break; | |
case 0xBD: /* MOV BP,immed16 */ | |
BP = fetch_word(); | |
break; | |
case 0xBE: /* MOV SI,immed16 */ | |
SI = fetch_word(); | |
break; | |
case 0xBF: /* MOV DI,immed16 */ | |
DI = fetch_word(); | |
break; | |
/* 0xC0 - 0xC1 - Not implemented on 8086/8088 */ | |
case 0xC2: /* RET immed16 (intrasegment) */ | |
OFF = fetch_word(); | |
IP = pop_word(); | |
SP += OFF; | |
break; | |
case 0xC3: /* RET (intrasegment) */ | |
IP = pop_word(); | |
break; | |
case 0xC4: | |
MRR = fetch_byte(1); | |
get_mrr_dec(MRR, &MOD, ®, &RM); | |
if (MOD != 0x3) { /* based, indexed, or based indexed addressing */ | |
EA = get_ea(MRR); /* get effective address */ | |
put_rword(REG, get_smword(seg_reg, EA)); /* LES mem16 */ | |
ES = get_smword(seg_reg, EA + 2); | |
} else { | |
// put_rword(REG, get_rword(RM)); /* LES reg16 */ | |
// ES = get_rword(RM) + 2; | |
/* not defined for 8086 */ | |
reason = STOP_OPCODE; | |
IP -= 2; | |
} | |
break; | |
case 0xC5: | |
MRR = fetch_byte(1); | |
get_mrr_dec(MRR, &MOD, ®, &RM); | |
if (MOD != 0x3) { /* based, indexed, or based indexed addressing */ | |
EA = get_ea(MRR); /* get effective address */ | |
put_rword(REG, get_smword(seg_reg, EA)); /* LDS mem16 */ | |
DS = get_smword(seg_reg, EA + 2); | |
} else { | |
// put_rword(REG, get_rword(RM)); /* LDS reg16 */ | |
// DS = get_rword(RM) + 2; | |
/* not defined for 8086 */ | |
reason = STOP_OPCODE; | |
IP -= 2; | |
} | |
break; | |
case 0xC6: | |
MRR = fetch_byte(1); | |
get_mrr_dec(MRR, &MOD, ®, &RM); | |
if (REG) { /* has to be 0 */ | |
reason = STOP_OPCODE; | |
IP -= 2; | |
} | |
if (MOD != 0x3) { /* based, indexed, or based indexed addressing */ | |
EA = get_ea(MRR); /* get effective address */ | |
DATA = fetch_byte(1); /* has to be after DISP */ | |
put_smbyte(seg_reg, EA, DATA); /* MOV mem8, immed8 */ | |
} else { | |
put_rbyte(RM, DATA); /* MOV reg8, immed8 */ | |
} | |
break; | |
case 0xC7: | |
MRR = fetch_byte(1); | |
get_mrr_dec(MRR, &MOD, ®, &RM); | |
if (REG) { /* has to be 0 */ | |
reason = STOP_OPCODE; | |
IP -= 2; | |
} | |
if (MOD != 0x3) { /* based, indexed, or based indexed addressing */ | |
EA = get_ea(MRR); /* get effective address */ | |
DATA = get_mword(IP); /* has to be after DISP */ | |
put_smword(seg_reg, EA, DATA); /* MOV mem16, immed16 */ | |
} else { | |
put_rword(RM, DATA); /* MOV reg16, immed16 */ | |
} | |
break; | |
/* 0xC8 - 0xC9 - Not implemented on 8086/8088 */ | |
case 0xCA: /* RET immed16 (intersegment) */ | |
OFF = fetch_word(); | |
IP = pop_word(); | |
CS = pop_word(); | |
SP += OFF; | |
break; | |
case 0xCB: /* RET (intersegment) */ | |
IP = pop_word(); | |
CS = pop_word(); | |
break; | |
case 0xCC: /* INT 3 */ | |
push_word(PSW); | |
CLR_FLAG(IF); | |
CLR_FLAG(TF); | |
push_word(CS); | |
push_word(IP); | |
CS = get_mword(14); | |
IP = get_mword(12); | |
break; | |
case 0xCD: /* INT immed8 */ | |
OFF = fetch_byte(1); | |
push_word(PSW); | |
CLR_FLAG(IF); | |
CLR_FLAG(TF); | |
push_word(CS); | |
push_word(IP); | |
CS = get_mword((OFF * 4) + 2); | |
IP = get_mword(OFF * 4); | |
break; | |
case 0xCE: /* INTO */ | |
push_word(PSW); | |
CLR_FLAG(IF); | |
CLR_FLAG(TF); | |
push_word(CS); | |
push_word(IP); | |
CS = get_mword(18); | |
IP = get_mword(16); | |
break; | |
case 0xCF: /* IRET */ | |
IP = pop_word(); | |
CS = pop_word(); | |
PSW = pop_word(); | |
break; | |
case 0xD0: | |
MRR = fetch_byte(1); | |
get_mrr_dec(MRR, &MOD, ®, &RM); | |
if (MOD != 0x3) { /* based, indexed, or based indexed addressing */ | |
EA = get_ea(MRR); /* get effective address */ | |
switch(REG) { | |
case 0: | |
VAL = rol_byte(get_smbyte(seg_reg, EA), 1); /* ROL mem8, 1 */ | |
break; | |
case 1: | |
VAL = ror_byte(get_smbyte(seg_reg, EA), 1); /* ROR mem8, 1 */ | |
break; | |
case 2: | |
VAL = rcl_byte(get_smbyte(seg_reg, EA), 1); /* RCL mem8, 1 */ | |
break; | |
case 3: | |
VAL = rcr_byte(get_smbyte(seg_reg, EA), 1); /* RCR mem8, 1 */ | |
break; | |
case 4: | |
VAL = shl_byte(get_smbyte(seg_reg, EA), 1); /* SAL/SHL mem8, 1 */ | |
break; | |
case 5: | |
VAL = shr_byte(get_smbyte(seg_reg, EA), 1); /* SHR mem8, 1 */ | |
break; | |
case 7: | |
VAL = sar_byte(get_smbyte(seg_reg, EA), 1); /* SAR mem8, 1 */ | |
break; | |
default: /* bad opcodes */ | |
reason = STOP_OPCODE; | |
IP -= 2; | |
break; | |
} | |
put_rbyte(EA, VAL); /* store result */ | |
} else { /* RM is second register */ | |
switch(REG) { | |
case 0: | |
VAL = rol_byte(get_rbyte(RM), 1); /* RCL reg8, 1 */ | |
break; | |
case 1: | |
VAL = ror_byte(get_rbyte(RM), 1); /* ROR reg8, 1 */ | |
break; | |
case 2: | |
VAL = rcl_byte(get_rbyte(RM), 1); /* RCL reg8, 1 */ | |
break; | |
case 3: | |
VAL = rcr_byte(get_rbyte(RM), 1); /* RCR reg8, 1 */ | |
break; | |
case 4: | |
VAL = shl_byte(get_rbyte(RM), 1); /* SHL/SAL reg8, 1*/ | |
break; | |
case 5: | |
VAL = shr_byte(get_rbyte(RM), 1); /* SHR reg8, 1 */ | |
break; | |
case 7: | |
VAL = sar_byte(get_rbyte(RM), 1); /* SAR reg8, 1 */ | |
break; | |
default: /* bad opcodes */ | |
reason = STOP_OPCODE; | |
IP -= 2; | |
break; | |
} | |
put_rbyte(RM, VAL); /* store result */ | |
} | |
break; | |
case 0xD1: | |
MRR = fetch_byte(1); | |
get_mrr_dec(MRR, &MOD, ®, &RM); | |
if (MOD != 0x3) { /* based, indexed, or based indexed addressing */ | |
EA = get_ea(MRR); /* get effective address */ | |
switch(REG) { | |
case 0: | |
VAL = rol_word(get_smword(seg_reg, EA), 1); /* ROL mem16, 1 */ | |
break; | |
case 1: | |
VAL = ror_word(get_smword(seg_reg, EA), 1); /* ROR mem16, 1 */ | |
break; | |
case 2: | |
VAL = rcl_word(get_smword(seg_reg, EA), 1); /* RCL mem16, 1 */ | |
break; | |
case 3: | |
VAL = rcr_word(get_smword(seg_reg, EA), 1); /* RCR mem16, 1 */ | |
break; | |
case 4: | |
VAL = shl_word(get_smword(seg_reg, EA), 1); /* SAL/SHL mem16, 1 */ | |
break; | |
case 5: | |
VAL = shr_word(get_smword(seg_reg, EA), 1); /* SHR mem16, 1 */ | |
break; | |
case 7: | |
VAL = sar_word(get_smword(seg_reg, EA), 1); /* SAR mem16, 1 */ | |
break; | |
default: /* bad opcodes */ | |
reason = STOP_OPCODE; | |
IP -= 2; | |
break; | |
} | |
put_rword(EA, VAL); /* store result */ | |
} else { /* RM is second register */ | |
switch(REG) { | |
case 0: | |
VAL = rol_word(get_rword(RM), 1); /* RCL reg16, 1 */ | |
break; | |
case 1: | |
VAL = ror_word(get_rword(RM), 1); /* ROR reg16, 1 */ | |
break; | |
case 2: | |
VAL = rcl_word(get_rword(RM), 1); /* RCL reg16, 1 */ | |
break; | |
case 3: | |
VAL = rcr_word(get_rword(RM), 1); /* RCR reg16, 1 */ | |
break; | |
case 4: | |
VAL = shl_word(get_rword(RM), 1); /* SHL/SAL reg16, 1 */ | |
break; | |
case 5: | |
VAL = shr_word(get_rword(RM), 1); /* SHR reg16, 1 */ | |
break; | |
case 7: | |
VAL = sar_word(get_rword(RM), 1); /* SAR reg16, 1 */ | |
break; | |
default: /* bad opcodes */ | |
reason = STOP_OPCODE; | |
IP -= 2; | |
break; | |
} | |
put_rbyte(RM, VAL); /* store result */ | |
} | |
break; | |
case 0xD2: | |
MRR = fetch_byte(1); | |
get_mrr_dec(MRR, &MOD, ®, &RM); | |
if (MOD != 0x3) { /* based, indexed, or based indexed addressing */ | |
EA = get_ea(MRR); /* get effective address */ | |
switch(REG) { | |
case 0: | |
VAL = rol_byte(get_smbyte(seg_reg, EA), CL); /* ROL mem8, CL */ | |
break; | |
case 1: | |
VAL = ror_byte(get_smbyte(seg_reg, EA), CL); /* ROR mem8, CL */ | |
break; | |
case 2: | |
VAL = rcl_byte(get_smbyte(seg_reg, EA), CL); /* RCL mem8, CL */ | |
break; | |
case 3: | |
VAL = rcr_byte(get_smbyte(seg_reg, EA), CL); /* RCR mem8, CL */ | |
break; | |
case 4: | |
VAL = shl_byte(get_smbyte(seg_reg, EA), CL); /* SAL/SHL mem8, CL */ | |
break; | |
case 5: | |
VAL = shr_byte(get_smbyte(seg_reg, EA), CL); /* SHR mem8, CL */ | |
break; | |
case 7: | |
VAL = sar_byte(get_smbyte(seg_reg, EA), CL); /* SAR mem8, CL */ | |
break; | |
default: /* bad opcodes */ | |
reason = STOP_OPCODE; | |
IP -= 2; | |
break; | |
} | |
put_rbyte(EA, VAL); /* store result */ | |
} else { /* RM is second register */ | |
switch(REG) { | |
case 0: | |
VAL = rol_byte(get_rbyte(RM), CL); /* RCL reg8, CL */ | |
break; | |
case 1: | |
VAL = ror_byte(get_rbyte(RM), CL); /* ROR reg8, CL */ | |
break; | |
case 2: | |
VAL = rcl_byte(get_rbyte(RM), CL); /* RCL reg8, CL */ | |
break; | |
case 3: | |
VAL = rcr_byte(get_rbyte(RM), CL); /* RCR reg8, CL */ | |
break; | |
case 4: | |
VAL = shl_byte(get_rbyte(RM), CL); /* SHL/SAL reg8, CL*/ | |
break; | |
case 5: | |
VAL = shr_byte(get_rbyte(RM), CL); /* SHR reg8, CL */ | |
break; | |
case 7: | |
VAL = sar_byte(get_rbyte(RM), CL); /* SAR reg8, CL */ | |
break; | |
default: /* bad opcodes */ | |
reason = STOP_OPCODE; | |
IP -= 2; | |
break; | |
} | |
put_rbyte(RM, VAL); /* store result */ | |
} | |
break; | |
case 0xD3: | |
MRR = fetch_byte(1); | |
get_mrr_dec(MRR, &MOD, ®, &RM); | |
if (MOD != 0x3) { /* based, indexed, or based indexed addressing */ | |
EA = get_ea(MRR); /* get effective address */ | |
switch(REG) { | |
case 0: | |
VAL = rol_word(get_smword(seg_reg, EA), CL); /* ROL mem16, CL */ | |
break; | |
case 1: | |
VAL = ror_word(get_smword(seg_reg, EA), CL); /* ROR mem16, CL */ | |
break; | |
case 2: | |
VAL = rcl_word(get_smword(seg_reg, EA), CL); /* RCL mem16, CL */ | |
break; | |
case 3: | |
VAL = rcr_word(get_smword(seg_reg, EA), CL); /* RCR mem16, CL */ | |
break; | |
case 4: | |
VAL = shl_word(get_smword(seg_reg, EA), CL); /* SAL/SHL mem16, CL */ | |
break; | |
case 5: | |
VAL = shr_word(get_smword(seg_reg, EA), CL); /* SHR mem16, CL */ | |
break; | |
case 7: | |
VAL = sar_word(get_smword(seg_reg, EA), CL); /* SAR mem16, CL */ | |
break; | |
default: /* bad opcodes */ | |
reason = STOP_OPCODE; | |
IP -= 2; | |
break; | |
} | |
put_rword(EA, VAL); /* store result */ | |
} else { /* RM is second register */ | |
switch(REG) { | |
case 0: | |
VAL = rol_word(get_rword(RM), CL); /* RCL reg16, CL */ | |
break; | |
case 1: | |
VAL = ror_word(get_rword(RM), CL); /* ROR reg16, CL */ | |
break; | |
case 2: | |
VAL = rcl_word(get_rword(RM), CL); /* RCL reg16, CL */ | |
break; | |
case 3: | |
VAL = rcr_word(get_rword(RM), CL); /* RCR reg16, CL */ | |
break; | |
case 4: | |
VAL = shl_word(get_rword(RM), CL); /* SHL/SAL reg16, CL */ | |
break; | |
case 5: | |
VAL = shr_word(get_rword(RM), CL); /* SHR reg16, CL */ | |
break; | |
case 7: | |
VAL = sar_word(get_rword(RM), CL); /* SAR reg16, CL */ | |
break; | |
default: /* bad opcodes */ | |
reason = STOP_OPCODE; | |
IP -= 2; | |
break; | |
} | |
put_rbyte(RM, VAL); /* store result */ | |
} | |
break; | |
case 0xD4: /* AAM */ | |
VAL = fetch_word(); | |
if (VAL != 10) { | |
reason = STOP_OPCODE; | |
IP -= 2; | |
} | |
/* note the type change here --- returning AL and AH in AX. */ | |
AX = aam_word(AL); | |
break; | |
case 0xD5: /* AAD */ | |
VAL = fetch_word(); | |
if (VAL != 10) { | |
reason = STOP_OPCODE; | |
IP -= 2; | |
} | |
AX = aad_word(AX); | |
break; | |
/* 0xD6 - Not implemented on 8086/8088 */ | |
case 0xD7: /* XLAT */ | |
OFF = BX + (uint8)AL; | |
AL = get_smbyte(SEG_CS, OFF); | |
break; | |
case 0xD8: /* ESC */ | |
case 0xD9: | |
case 0xDA: | |
case 0xDB: | |
case 0xDC: | |
case 0xDD: | |
case 0xDE: | |
case 0xDF: | |
/* for now, do nothing, NOP for 8088 */ | |
break; | |
case 0xE0: /* LOOPNE label */ | |
OFF = fetch_byte(1); | |
OFF += (int16)IP; | |
CX -= 1; | |
if (CX != 0 && !GET_FLAG(ZF)) /* CX != 0 and !ZF */ | |
IP = OFF; | |
break; | |
case 0xE1: /* LOOPE label */ | |
OFF = fetch_byte(1); | |
OFF += (int16)IP; | |
CX -= 1; | |
if (CX != 0 && GET_FLAG(ZF)) /* CX != 0 and ZF */ | |
IP = OFF; | |
break; | |
case 0xE2: /* LOOP label */ | |
OFF = fetch_byte(1); | |
OFF += (int16)IP; | |
CX -= 1; | |
if (CX != 0) /* CX != 0 */ | |
IP = OFF; | |
break; | |
case 0xE3: /* JCXZ label */ | |
OFF = fetch_byte(1); | |
OFF += (int16)IP; | |
if (CX == 0) /* CX != 0 */ | |
IP = OFF; | |
break; | |
case 0xE4: /* IN AL,immed8 */ | |
OFF = fetch_byte(1); | |
AL = dev_table[OFF].routine(0, 0); | |
break; | |
case 0xE5: /* IN AX,immed8 */ | |
OFF = fetch_byte(1); | |
AH = dev_table[OFF].routine(0, 0); | |
AL = dev_table[OFF+1].routine(0, 0); | |
break; | |
case 0xE6: /* OUT AL,immed8 */ | |
OFF = fetch_byte(1); | |
dev_table[OFF].routine(1, AL); | |
break; | |
case 0xE7: /* OUT AX,immed8 */ | |
OFF = fetch_byte(1); | |
dev_table[OFF].routine(1, AH); | |
dev_table[OFF+1].routine(1, AL); | |
break; | |
case 0xE8: /* CALL NEAR proc */ | |
OFF = fetch_word(); | |
push_word(IP); | |
IP = (OFF + IP) & ADDRMASK16; | |
break; | |
case 0xE9: /* JMP NEAR label */ | |
OFF = fetch_word(); | |
IP = (OFF + IP) & ADDRMASK16; | |
break; | |
case 0xEA: /* JMP FAR label */ | |
OFF = fetch_word(); | |
SEG = fetch_word(); | |
CS = SEG; | |
IP = OFF; | |
break; | |
case 0xEB: /* JMP short-label */ | |
OFF = fetch_byte(1); | |
if (OFF & 0x80) /* if negative, sign extend */ | |
OFF |= 0XFF00; | |
IP = (IP + OFF) & ADDRMASK16; | |
break; | |
case 0xEC: /* IN AL,DX */ | |
AL = dev_table[DX].routine(0, 0); | |
break; | |
case 0xED: /* IN AX,DX */ | |
AH = dev_table[DX].routine(0, 0); | |
AL = dev_table[DX+1].routine(0, 0); | |
break; | |
case 0xEE: /* OUT AL,DX */ | |
dev_table[DX].routine(1, AL); | |
break; | |
case 0xEF: /* OUT AX,DX */ | |
dev_table[DX].routine(1, AH); | |
dev_table[DX+1].routine(1, AL); | |
break; | |
case 0xF0: /* LOCK */ | |
/* do nothing for now */ | |
break; | |
/* 0xF1 - Not implemented on 8086/8088 */ | |
case 0xF2: /* REPNE/REPNZ */ | |
sysmode |= SYSMODE_PREFIX_REPNE; | |
break; | |
case 0xF3: /* REP/REPE/REPZ */ | |
sysmode |= SYSMODE_PREFIX_REPE; | |
break; | |
case 0xF4: /* HLT */ | |
reason = STOP_HALT; | |
IP--; | |
break; | |
case 0xF5: /* CMC */ | |
TOGGLE_FLAG(CF); | |
break; | |
case 0xF6: | |
MRR = fetch_byte(1); | |
get_mrr_dec(MRR, &MOD, ®, &RM); | |
if (MOD != 0x3) { /* based, indexed, or based indexed addressing */ | |
EA = get_ea(MRR); /* get effective address */ | |
switch(REG) { | |
case 0: /* TEST mem8, immed8 */ | |
DATA = fetch_byte(1); | |
test_byte(get_smbyte(seg_reg, EA), DATA); | |
break; | |
case 2: /* NOT mem8 */ | |
VAL = not_byte(get_smbyte(seg_reg, EA)); | |
put_smbyte(seg_reg, EA, VAL); /* store result */ | |
break; | |
case 3: /* NEG mem8 */ | |
VAL = neg_byte(get_smbyte(seg_reg, EA)); | |
put_smbyte(seg_reg, EA, VAL); /* store result */ | |
break; | |
case 4: /* MUL mem8 */ | |
mul_byte(get_smbyte(seg_reg, EA)); | |
break; | |
case 5: /* IMUL mem8 */ | |
imul_byte(get_smbyte(seg_reg, EA)); | |
break; | |
case 6: /* DIV mem8 */ | |
div_byte(get_smbyte(seg_reg, EA)); | |
break; | |
case 7: /* IDIV mem8 */ | |
idiv_byte(get_smbyte(seg_reg, EA)); | |
break; | |
default: /* bad opcode */ | |
reason = STOP_OPCODE; | |
IP -= 2; | |
break; | |
} | |
} else { /* RM is second register */ | |
switch(REG) { | |
case 0: /* TEST reg8, immed8 */ | |
DATA = fetch_byte(1); | |
test_byte(get_rbyte(RM), DATA); | |
break; | |
case 2: /* NOT reg8 */ | |
VAL = not_byte(get_rbyte(RM)); | |
put_rbyte(RM, VAL); /* store result */ | |
break; | |
case 3: /* NEG reg8 */ | |
VAL = neg_byte(get_rbyte(RM)); | |
put_rbyte(RM, VAL); /* store result */ | |
break; | |
case 4: /* MUL reg8 */ | |
mul_byte(get_rbyte(RM)); | |
break; | |
case 5: /* IMUL reg8 */ | |
imul_byte(get_rbyte(RM)); | |
break; | |
case 6: /* DIV reg8 */ | |
div_byte(get_rbyte(RM)); | |
break; | |
case 7: /* IDIV reg8 */ | |
idiv_byte(get_rbyte(RM)); | |
break; | |
default: /* bad opcode */ | |
reason = STOP_OPCODE; | |
IP -= 2; | |
break; | |
} | |
put_rbyte(RM, VAL); /* store result */ | |
} | |
break; | |
case 0xF7: | |
MRR = fetch_byte(1); | |
get_mrr_dec(MRR, &MOD, ®, &RM); | |
if (MOD != 0x3) { /* based, indexed, or based indexed addressing */ | |
EA = get_ea(MRR); /* get effective address */ | |
switch(REG) { | |
case 0: /* TEST mem16, immed16 */ | |
DATA = fetch_word(); | |
test_word(get_smword(seg_reg, EA), DATA); | |
break; | |
case 2: /* NOT mem16 */ | |
VAL = not_word(get_smword(seg_reg, EA)); | |
put_smword(seg_reg, EA, VAL); /* store result */ | |
break; | |
case 3: /* NEG mem16 */ | |
VAL = neg_word(get_smword(seg_reg, EA)); | |
put_smword(seg_reg, EA, VAL); /* store result */ | |
break; | |
case 4: /* MUL mem16 */ | |
mul_word(get_smword(seg_reg, EA)); | |
break; | |
case 5: /* IMUL mem16 */ | |
imul_word(get_smword(seg_reg, EA)); | |
break; | |
case 6: /* DIV mem16 */ | |
div_word(get_smword(seg_reg, EA)); | |
break; | |
case 7: /* IDIV mem16 */ | |
idiv_word(get_smword(seg_reg, EA)); | |
break; | |
default: /* bad opcode */ | |
reason = STOP_OPCODE; | |
IP -= 2; | |
break; | |
} | |
} else { /* RM is second register */ | |
switch(REG) { | |
case 0: /* TEST reg16, immed16 */ | |
DATA = fetch_word(); | |
test_word(get_rword(RM), DATA); | |
break; | |
case 2: /* NOT reg16 */ | |
VAL = not_word(get_rword(RM)); | |
put_rword(RM, VAL); /* store result */ | |
break; | |
case 3: /* NEG reg16 */ | |
VAL = neg_word(get_rword(RM)); | |
put_rword(RM, VAL); /* store result */ | |
break; | |
case 4: /* MUL reg16 */ | |
mul_word(get_rword(RM)); | |
break; | |
case 5: /* IMUL reg16 */ | |
imul_word(get_rword(RM)); | |
break; | |
case 6: /* DIV reg16 */ | |
div_word(get_rword(RM)); | |
break; | |
case 7: /* IDIV reg16 */ | |
idiv_word(get_rword(RM)); | |
break; | |
default: /* bad opcode */ | |
reason = STOP_OPCODE; | |
IP -= 2; | |
break; | |
} | |
put_rbyte(RM, VAL); /* store result */ | |
} | |
break; | |
case 0xF8: /* CLC */ | |
CLR_FLAG(CF); | |
break; | |
case 0xF9: /* STC */ | |
SET_FLAG(CF); | |
break; | |
case 0xFA: /* CLI */ | |
CLR_FLAG(IF); | |
break; | |
case 0xFB: /* STI */ | |
SET_FLAG(IF); | |
break; | |
case 0xFC: /* CLD */ | |
CLR_FLAG(DF); | |
break; | |
case 0xFD: /* STD */ | |
SET_FLAG(DF); | |
break; | |
case 0xFE: | |
MRR = fetch_byte(1); | |
get_mrr_dec(MRR, &MOD, ®, &RM); | |
if (MOD != 0x3) { /* based, indexed, or based indexed addressing */ | |
EA = get_ea(MRR); /* get effective address */ | |
switch(REG) { | |
case 0: /* INC mem16 */ | |
VAL = inc_byte(get_smbyte(seg_reg, EA)); /* do operation */ | |
put_smbyte(seg_reg, EA, VAL); /* store result */ | |
break; | |
case 1: /* DEC mem16 */ | |
VAL = dec_byte(get_smbyte(seg_reg, EA)); /* do operation */ | |
put_smbyte(seg_reg, EA, VAL); /* store result */ | |
break; | |
default: /* bad opcodes */ | |
reason = STOP_OPCODE; | |
IP -= 2; | |
break; | |
} | |
} else { /* RM is second register */ | |
switch(REG) { | |
case 0: | |
VAL = inc_byte(get_rbyte(RM)); /* do operation */ | |
put_rbyte(RM, VAL); /* store result */ | |
break; | |
case 1: | |
VAL = dec_byte(get_rbyte(RM)); /* do operation */ | |
put_rbyte(RM, VAL); /* store result */ | |
break; | |
default: /* bad opcodes */ | |
reason = STOP_OPCODE; | |
IP -= 2; | |
break; | |
} | |
put_rbyte(RM, VAL); /* store result */ | |
} | |
break; | |
case 0xFF: | |
MRR = fetch_byte(1); | |
get_mrr_dec(MRR, &MOD, ®, &RM); | |
if (MOD != 0x3) { /* based, indexed, or based indexed addressing */ | |
EA = get_ea(MRR); /* get effective address */ | |
switch(REG) { | |
case 0: /* INC mem16 */ | |
VAL = inc_word(get_smword(seg_reg, EA)); /* do operation */ | |
put_smword(seg_reg, EA, VAL); /* store result */ | |
break; | |
case 1: /* DEC mem16 */ | |
VAL = dec_word(get_smword(seg_reg, EA)); /* do operation */ | |
put_smword(seg_reg, EA, VAL); /* store result */ | |
break; | |
case 2: /* CALL NEAR mem16 */ | |
OFF = get_smword(SEG_CS, EA); /* do operation */ | |
push_word(IP); | |
IP = OFF; | |
break; | |
case 3: /* CALL FAR mem16 */ | |
OFF = get_smword(SEG_CS, EA); /* do operation */ | |
SEG = get_smword(SEG_CS, EA + 2); | |
push_word(CS); | |
CS = SEG; | |
push_word(IP); | |
IP = OFF; | |
break; | |
case 4: /* JMP NEAR mem16 */ | |
OFF = get_smword(SEG_CS, EA); /* do operation */ | |
IP = OFF; | |
break; | |
case 5: /* JMP FAR mem16 */ | |
OFF = get_smword(SEG_CS, EA); /* do operation */ | |
SEG = get_smword(SEG_CS, EA + 2); | |
CS = SEG; | |
IP = OFF; | |
break; | |
case 6: /* PUSH mem16 */ | |
VAL = get_smword(seg_reg, EA); /* do operation */ | |
push_word(VAL); | |
break; | |
case 7: /* bad opcode */ | |
reason = STOP_OPCODE; | |
IP -= 2; | |
break; | |
} | |
} else { /* RM is second register */ | |
switch(REG) { | |
case 2: /* CALL NEAR reg16 */ | |
OFF = get_rword(RM); /* do operation */ | |
push_word(IP); | |
IP = OFF; | |
break; | |
case 4: /* JMP NEAR reg16 */ | |
OFF = get_rword(RM); /* do operation */ | |
IP = OFF; | |
break; | |
default: /* bad opcode */ | |
reason = STOP_OPCODE; | |
IP -= 2; | |
break; | |
} | |
put_rbyte(RM, VAL); /* store result */ | |
} | |
break; | |
default: | |
// if (i8088_unit.flags & UNIT_OPSTOP) { | |
reason = STOP_OPCODE; | |
IP--; | |
// } | |
break; | |
} | |
/* not segment override */ | |
if ((IR == 0x26) || (IR == 0x2E) || (IR == 0x36) || (IR == 0x3E)) { | |
seg_ovr = SEG_NONE; /* clear segment override */ | |
sysmode &= 0x0000001E; /* clear flags */ | |
sysmode |= 0x00000001; | |
} | |
} | |
/* Simulation halted */ | |
saved_PC = IP; | |
return reason; | |
} | |
/* emulation subfunctions */ | |
int32 sign_ext(int32 val) | |
{ | |
int32 res; | |
res = val; | |
if (val & 0x80) | |
res |= 0xFF00; | |
return res; | |
} | |
int32 fetch_byte(int32 flag) | |
{ | |
uint8 val; | |
val = get_smbyte(SEG_CS, IP) & 0xFF; /* fetch byte */ | |
if (i8088_dev.dctrl & DEBUG_asm) { /* display source code */ | |
switch (flag) { | |
case 0: /* opcode fetch */ | |
// sim_printf("%04X:%04X %s", CS, IP, opcode[val]); | |
sim_printf("%04X:%04X %02X", CS, IP, val); | |
break; | |
case 1: /* byte operand fetch */ | |
sim_printf(" %02X", val); | |
break; | |
} | |
} | |
IP = INC_IP1; /* increment IP */ | |
return val; | |
} | |
int32 fetch_word(void) | |
{ | |
uint16 val; | |
val = get_smbyte(SEG_CS, IP) & 0xFF; /* fetch low byte */ | |
val |= get_smbyte(SEG_CS, IP + 1) << 8; /* fetch high byte */ | |
if (i8088_dev.dctrl & DEBUG_asm) | |
// sim_printf("0%04XH", val); | |
sim_printf(" %04X", val); | |
IP = INC_IP2; /* increment IP */ | |
return val; | |
} | |
/* calculate parity on a 8- or 16-bit value */ | |
int32 parity(int32 val) | |
{ | |
int32 bc = 0; | |
if (val & 0x0001) bc++; | |
if (val & 0x0002) bc++; | |
if (val & 0x0004) bc++; | |
if (val & 0x0008) bc++; | |
if (val & 0x0010) bc++; | |
if (val & 0x0020) bc++; | |
if (val & 0x0040) bc++; | |
if (val & 0x0080) bc++; | |
if (val & 0x0100) bc++; | |
if (val & 0x0200) bc++; | |
if (val & 0x0400) bc++; | |
if (val & 0x0800) bc++; | |
if (val & 0x1000) bc++; | |
if (val & 0x2000) bc++; | |
if (val & 0x4000) bc++; | |
if (val & 0x8000) bc++; | |
return bc & 1; | |
} | |
void i86_intr_raise(uint8 num) | |
{ | |
/* do nothing for now */ | |
} | |
/* return byte register */ | |
uint32 get_rbyte(uint32 reg) | |
{ | |
uint32 val; | |
switch(reg) { | |
case 0: val = AL; break; | |
case 1: val = CL; break; | |
case 2: val = DL; break; | |
case 3: val = BL; break; | |
case 4: val = AH; break; | |
case 5: val = CH; break; | |
case 6: val = DH; break; | |
case 7: val = BH; break; | |
} | |
return val; | |
} | |
/* return word register - added segment registers as 8-11 */ | |
uint32 get_rword(uint32 reg) | |
{ | |
uint32 val; | |
switch(reg) { | |
case 0: val = AX; break; | |
case 1: val = CX; break; | |
case 2: val = DX; break; | |
case 3: val = BX; break; | |
case 4: val = SP; break; | |
case 5: val = BP; break; | |
case 6: val = SI; break; | |
case 7: val = DI; break; | |
case 8: val = CS; break; | |
case 9: val = DS; break; | |
case 10: val = ES; break; | |
case 11: val = SS; break; | |
} | |
return val; | |
} | |
/* set byte register */ | |
void put_rbyte(uint32 reg, uint32 val) | |
{ | |
val &= 0xFF; /* force byte */ | |
switch(reg){ | |
case 0: AL = val; break; | |
case 1: CL = val; break; | |
case 2: DL = val; break; | |
case 3: BL = val; break; | |
case 4: AH = val; break; | |
case 5: CH = val; break; | |
case 6: DH = val; break; | |
case 7: BH = val; break; | |
} | |
} | |
/* set word register */ | |
void put_rword(uint32 reg, uint32 val) | |
{ | |
val &= 0xFFFF; /* force word */ | |
switch(reg){ | |
case 0: AX = val; break; | |
case 1: CX = val; break; | |
case 2: DX = val; break; | |
case 3: BX = val; break; | |
case 4: SP = val; break; | |
case 5: BP = val; break; | |
case 6: SI = val; break; | |
case 7: DI = val; break; | |
} | |
} | |
/* set seg_reg as required for EA */ | |
void set_segreg(uint32 reg) | |
{ | |
if (seg_ovr) | |
seg_reg = seg_ovr; | |
else | |
seg_ovr = reg; | |
} | |
/* return effective address from mrr - also set seg_reg */ | |
uint32 get_ea(uint32 mrr) | |
{ | |
uint32 MOD, REG, RM, DISP, EA; | |
get_mrr_dec(mrr, &MOD, ®, &RM); | |
switch(MOD) { | |
case 0: /* DISP = 0 */ | |
DISP = 0; | |
switch(RM) { | |
case 0: | |
EA = BX + SI; | |
set_segreg(SEG_DS); | |
break; | |
case 1: | |
EA = BX + DI; | |
set_segreg(SEG_DS); | |
break; | |
case 2: | |
EA = BP + SI; | |
set_segreg(SEG_SS); | |
break; | |
case 3: | |
EA = BP + DI; | |
set_segreg(SEG_SS); | |
break; | |
case 4: | |
EA = SI; | |
set_segreg(SEG_DS); | |
break; | |
case 5: | |
EA = DI; | |
set_segreg(SEG_ES); | |
break; | |
case 6: | |
DISP = fetch_word(); | |
EA = DISP; | |
set_segreg(SEG_DS); | |
break; | |
case 7: | |
EA = BX; | |
set_segreg(SEG_DS); | |
break; | |
} | |
break; | |
case 1: /* DISP is byte */ | |
DISP = fetch_byte(1); | |
switch(RM) { | |
case 0: | |
EA = BX + SI + DISP; | |
set_segreg(SEG_DS); | |
break; | |
case 1: | |
EA = BX + DI + DISP; | |
set_segreg(SEG_DS); | |
break; | |
case 2: | |
EA = BP + SI + DISP; | |
set_segreg(SEG_SS); | |
break; | |
case 3: | |
EA = BP + DI + DISP; | |
set_segreg(SEG_SS); | |
break; | |
case 4: | |
EA = SI + DISP; | |
set_segreg(SEG_DS); | |
break; | |
case 5: | |
EA = DI + DISP; | |
set_segreg(SEG_ES); | |
break; | |
case 6: | |
EA = BP + DISP; | |
set_segreg(SEG_SS); | |
break; | |
case 7: | |
EA = BX + DISP; | |
set_segreg(SEG_DS); | |
break; | |
} | |
break; | |
case 2: /* DISP is word */ | |
DISP = fetch_word(); | |
switch(RM) { | |
case 0: | |
EA = BX + SI + DISP; | |
set_segreg(SEG_DS); | |
break; | |
case 1: | |
EA = BX + DI + DISP; | |
set_segreg(SEG_DS); | |
break; | |
case 2: | |
EA = BP + SI + DISP; | |
set_segreg(SEG_SS); | |
break; | |
case 3: | |
EA = BP + DI + DISP; | |
set_segreg(SEG_SS); | |
break; | |
case 4: | |
EA = SI + DISP; | |
set_segreg(SEG_DS); | |
break; | |
case 5: | |
EA = DI + DISP; | |
set_segreg(SEG_ES); | |
break; | |
case 6: | |
EA = BP + DISP; | |
set_segreg(SEG_SS); | |
break; | |
case 7: | |
EA = BX + DISP; | |
set_segreg(SEG_SS); | |
break; | |
} | |
break; | |
case 3: /* RM is register field */ | |
break; | |
} | |
if (i8088_dev.dctrl & DEBUG_level1) | |
sim_printf("get_ea: MRR=%02X MOD=%02X REG=%02X R/M=%02X DISP=%04X EA=%04X\n", | |
mrr, MOD, REG, RM, DISP, EA); | |
return EA; | |
} | |
/* return mod, reg and rm field from mrr */ | |
void get_mrr_dec(uint32 mrr, uint32 *mod, uint32 *reg, uint32 *rm) | |
{ | |
*mod = (mrr >> 6) & 0x3; | |
*reg = (mrr >> 3) & 0x7; | |
*rm = mrr & 0x7; | |
} | |
/* | |
Most of the primitive algorithms were pulled from the GDE Dos/IP Emulator by Jim Hudgens | |
*/ | |
/* aad primitive */ | |
uint8 aad_word(uint16 d) | |
{ | |
uint16 VAL; | |
uint8 HI, LOW; | |
HI = (d >> 8) & 0xFF; | |
LOW = d & 0xFF; | |
VAL = LOW + 10 * HI; | |
CONDITIONAL_SET_FLAG(VAL & 0x80, SF); | |
CONDITIONAL_SET_FLAG(VAL == 0, ZF); | |
CONDITIONAL_SET_FLAG(parity(VAL & 0xFF), PF); | |
return (uint8) VAL; | |
} | |
/* aam primitive */ | |
uint16 aam_word(uint8 d) | |
{ | |
uint16 VAL, HI; | |
HI = d / 10; | |
VAL = d % 10; | |
VAL |= (HI << 8); | |
CONDITIONAL_SET_FLAG(VAL & 0x80, SF); | |
CONDITIONAL_SET_FLAG(VAL == 0, ZF); | |
CONDITIONAL_SET_FLAG(parity(VAL & 0xFF), PF); | |
return VAL; | |
} | |
/* add with carry byte primitive */ | |
uint8 adc_byte(uint8 d, uint8 s) | |
{ | |
register uint16 res; | |
register uint16 cc; | |
if (GET_FLAG(CF)) | |
res = 1 + d + s; | |
else | |
res = d + s; | |
/* set the flags based on the result */ | |
CONDITIONAL_SET_FLAG(res & 0x0100, CF); | |
CONDITIONAL_SET_FLAG((res & 0xff) == 0, ZF); | |
CONDITIONAL_SET_FLAG(res & 0x80, SF); | |
CONDITIONAL_SET_FLAG(parity(res & 0xff), PF); | |
/* calculate the carry chain SEE NOTE AT TOP.*/ | |
cc = (s & d) | ((~res) & (s | d)); | |
/* set the flags based on the carry chain */ | |
CONDITIONAL_SET_FLAG(xor_3_tab[(cc >> 6) & 0x3], OF); | |
CONDITIONAL_SET_FLAG(cc & 0x08, AF); | |
return (uint8) res; | |
} | |
/* add with carry word primitive */ | |
uint16 adc_word(uint16 d, uint16 s) | |
{ | |
register uint32 res; | |
register uint32 cc; | |
if (GET_FLAG(CF)) | |
res = 1 + d + s; | |
else | |
res = d + s; | |
/* set the flags based on the result */ | |
CONDITIONAL_SET_FLAG(res & 0x10000, CF); | |
CONDITIONAL_SET_FLAG((res & 0xFFFF) == 0, ZF); | |
CONDITIONAL_SET_FLAG(res & 0x8000, SF); | |
CONDITIONAL_SET_FLAG(parity(res & 0xFF), PF); | |
/* calculate the carry chain SEE NOTE AT TOP.*/ | |
cc = (s & d) | ((~res) & (s | d)); | |
/* set the flags based on the carry chain */ | |
CONDITIONAL_SET_FLAG(xor_3_tab[(cc >> 14) & 0x3], OF); | |
CONDITIONAL_SET_FLAG(cc & 0x08, AF); | |
return res; | |
} | |
/* add byte primitive */ | |
uint8 add_byte(uint8 d, uint8 s) | |
{ | |
register uint16 res; | |
register uint16 cc; | |
res = d + s; | |
/* set the flags based on the result */ | |
CONDITIONAL_SET_FLAG(res & 0x0100, CF); | |
CONDITIONAL_SET_FLAG((res & 0xFF) == 0, ZF); | |
CONDITIONAL_SET_FLAG(res & 0x80, SF); | |
CONDITIONAL_SET_FLAG(parity(res & 0xFF), PF); | |
/* calculate the carry chain SEE NOTE AT TOP.*/ | |
cc = (s & d) | ((~res) & (s | d)); | |
/* set the flags based on the carry chain */ | |
CONDITIONAL_SET_FLAG(xor_3_tab[(cc >> 6) & 0x3], OF); | |
CONDITIONAL_SET_FLAG(cc & 0x08, AF); | |
return (uint8) res; | |
} | |
/* add word primitive */ | |
uint16 add_word(uint16 d, uint16 s) | |
{ | |
register uint32 res; | |
register uint32 cc; | |
res = d + s; | |
/* set the flags based on the result */ | |
CONDITIONAL_SET_FLAG(res & 0x10000, CF); | |
CONDITIONAL_SET_FLAG((res & 0xFFFF) == 0, ZF); | |
CONDITIONAL_SET_FLAG(res & 0x8000, SF); | |
CONDITIONAL_SET_FLAG(parity(res & 0xff), PF); | |
/* calculate the carry chain SEE NOTE AT TOP.*/ | |
cc = (s & d) | ((~res) & (s | d)); | |
/* set the flags based on the carry chain */ | |
CONDITIONAL_SET_FLAG(xor_3_tab[(cc >> 14) & 0x3], OF); | |
CONDITIONAL_SET_FLAG(cc & 0x08, AF); | |
return res; | |
} | |
/* and byte primitive */ | |
uint8 and_byte(uint8 d, uint8 s) | |
{ | |
register uint8 res; | |
res = d & s; | |
/* clear flags */ | |
CLR_FLAG(OF); | |
CLR_FLAG(CF); | |
/* set the flags based on the result */ | |
CONDITIONAL_SET_FLAG(res & 0x80, SF); | |
CONDITIONAL_SET_FLAG(res == 0, ZF); | |
CONDITIONAL_SET_FLAG(parity(res), PF); | |
return res; | |
} | |
/* and word primitive */ | |
uint16 and_word(uint16 d, uint16 s) | |
{ | |
register uint16 res; | |
res = d & s; | |
/* clear flags */ | |
CLR_FLAG(OF); | |
CLR_FLAG(CF); | |
/* set the flags based on the result */ | |
CONDITIONAL_SET_FLAG(res & 0x8000, SF); | |
CONDITIONAL_SET_FLAG(res == 0, ZF); | |
CONDITIONAL_SET_FLAG(parity(res & 0xFF), PF); | |
return res; | |
} | |
/* cmp byte primitive */ | |
uint8 cmp_byte(uint8 d, uint8 s) | |
{ | |
register uint32 res; | |
register uint32 bc; | |
res = d - s; | |
/* clear flags */ | |
CLR_FLAG(CF); | |
/* set the flags based on the result */ | |
CONDITIONAL_SET_FLAG(res & 0x80, SF); | |
CONDITIONAL_SET_FLAG((res & 0xFF)==0, ZF); | |
CONDITIONAL_SET_FLAG(parity(res & 0xFF), PF); | |
/* calculate the borrow chain. See note at top */ | |
bc= (res&(~d|s))|(~d&s); | |
/* set flags based on borrow chain */ | |
CONDITIONAL_SET_FLAG(bc & 0x80, CF); | |
CONDITIONAL_SET_FLAG(xor_3_tab[(bc >> 6) & 0x3], OF); | |
CONDITIONAL_SET_FLAG(bc & 0x8, AF); | |
return d; /* long story why this is needed. Look at opcode | |
0x80 in ops.c, for an idea why this is necessary.*/ | |
} | |
/* cmp word primitive */ | |
uint16 cmp_word(uint16 d, uint16 s) | |
{ | |
register uint32 res; | |
register uint32 bc; | |
res = d - s; | |
/* set the flags based on the result */ | |
CONDITIONAL_SET_FLAG(res & 0x8000, SF); | |
CONDITIONAL_SET_FLAG((res & 0xFFFF) == 0, ZF); | |
CONDITIONAL_SET_FLAG(parity(res & 0xFF), PF); | |
/* calculate the borrow chain. See note at top */ | |
bc = (res & (~d | s)) | (~d &s); | |
/* set flags based on borrow chain */ | |
CONDITIONAL_SET_FLAG(bc & 0x8000, CF); | |
CONDITIONAL_SET_FLAG(xor_3_tab[(bc >> 14) & 0x3], OF); | |
CONDITIONAL_SET_FLAG(bc & 0x8, AF); | |
return d; /* long story why this is needed. Look at opcode | |
0x80 in ops.c, for an idea why this is necessary.*/ | |
} | |
/* dec byte primitive */ | |
uint8 dec_byte(uint8 d) | |
{ | |
register uint32 res; | |
register uint32 bc; | |
res = d - 1; | |
/* set the flags based on the result */ | |
CONDITIONAL_SET_FLAG(res & 0x80, SF); | |
CONDITIONAL_SET_FLAG((res & 0xff)==0, ZF); | |
CONDITIONAL_SET_FLAG(parity(res & 0xff), PF); | |
/* calculate the borrow chain. See note at top */ | |
/* based on sub_byte, uses s=1. */ | |
bc = (res & (~d | 1)) | (~d & 1); | |
/* carry flag unchanged */ | |
/* set flags based on borrow chain */ | |
CONDITIONAL_SET_FLAG(xor_3_tab[(bc >> 6) & 0x3], OF); | |
CONDITIONAL_SET_FLAG(bc & 0x8, AF); | |
return res; | |
} | |
/* dec word primitive */ | |
uint16 dec_word(uint16 d) | |
{ | |
register uint32 res; | |
register uint32 bc; | |
res = d - 1; | |
/* set the flags based on the result */ | |
CONDITIONAL_SET_FLAG(res & 0x8000, SF); | |
CONDITIONAL_SET_FLAG((res & 0xffff) == 0, ZF); | |
CONDITIONAL_SET_FLAG(parity(res & 0xff), PF); | |
/* calculate the borrow chain. See note at top */ | |
/* based on the sub_byte routine, with s==1 */ | |
bc = (res & (~d | 1)) | (~d & 1); | |
/* carry flag unchanged */ | |
/* set flags based on borrow chain */ | |
CONDITIONAL_SET_FLAG(xor_3_tab[(bc >> 14) & 0x3], OF); | |
CONDITIONAL_SET_FLAG(bc & 0x8, AF); | |
return res; | |
} | |
/* div byte primitive */ | |
void div_byte(uint8 s) | |
{ | |
uint32 dvd, dvs, div, mod; | |
dvs = s; | |
dvd = AX; | |
if (s == 0) { | |
i86_intr_raise(0); | |
return; | |
} | |
div = dvd / dvs; | |
mod = dvd % dvs; | |
if (abs(div) > 0xFF) { | |
i86_intr_raise(0); | |
return; | |
} | |
/* Undef --- Can't hurt */ | |
CLR_FLAG(SF); | |
CONDITIONAL_SET_FLAG(div == 0, ZF); | |
AL = (uint8)div; | |
AH = (uint8)mod; | |
} | |
/* div word primitive */ | |
void div_word(uint16 s) | |
{ | |
uint32 dvd, dvs, div, mod; | |
dvd = DX; | |
dvd = (dvd << 16) | AX; | |
dvs = s; | |
if (dvs == 0) { | |
i86_intr_raise(0); | |
return; | |
} | |
div = dvd / dvs; | |
mod = dvd % dvs; | |
if (abs(div) > 0xFFFF) { | |
i86_intr_raise(0); | |
return; | |
} | |
/* Undef --- Can't hurt */ | |
CLR_FLAG(SF); | |
CONDITIONAL_SET_FLAG(div == 0, ZF); | |
AX = div; | |
DX = mod; | |
} | |
/* idiv byte primitive */ | |
void idiv_byte(uint8 s) | |
{ | |
int32 dvd, div, mod; | |
dvd = (int16)AX; | |
if (s == 0) { | |
i86_intr_raise(0); | |
return; | |
} | |
div = dvd / (int8)s; | |
mod = dvd % (int8)s; | |
if (abs(div) > 0x7F) { | |
i86_intr_raise(0); | |
return; | |
} | |
/* Undef --- Can't hurt */ | |
CONDITIONAL_SET_FLAG(div & 0x80, SF); | |
CONDITIONAL_SET_FLAG(div == 0, ZF); | |
AL = (int8)div; | |
AH = (int8)mod; | |
} | |
/* idiv word primitive */ | |
void idiv_word(uint16 s) | |
{ | |
int32 dvd, dvs, div, mod; | |
dvd = DX; | |
dvd = (dvd << 16) | AX; | |
if (s == 0) { | |
i86_intr_raise(0); | |
return; | |
} | |
dvs = (int16)s; | |
div = dvd / dvs; | |
mod = dvd % dvs; | |
if (abs(div) > 0x7FFF) { | |
i86_intr_raise(0); | |
return; | |
} | |
/* Undef --- Can't hurt */ | |
CONDITIONAL_SET_FLAG(div & 0x8000, SF); | |
CONDITIONAL_SET_FLAG(div == 0, ZF); | |
AX = div; | |
DX = mod; | |
} | |
/* imul byte primitive */ | |
void imul_byte(uint8 s) | |
{ | |
int16 res; | |
res = (int8)AL * (int8)s; | |
AX = res; | |
/* Undef --- Can't hurt */ | |
CONDITIONAL_SET_FLAG(res & 0x8000, SF); | |
CONDITIONAL_SET_FLAG(res == 0, ZF); | |
if ( AH == 0 || AH == 0xFF) { | |
CLR_FLAG(CF); | |
CLR_FLAG(OF); | |
} else { | |
SET_FLAG(CF); | |
SET_FLAG(OF); | |
} | |
} | |
/* imul word primitive */ | |
void imul_word(uint16 s) | |
{ | |
int32 res; | |
res = (int16)AX * (int16)s; | |
AX = res & 0xFFFF; | |
DX = (res >> 16) & 0xFFFF; | |
/* Undef --- Can't hurt */ | |
CONDITIONAL_SET_FLAG(res & 0x80000000, SF); | |
CONDITIONAL_SET_FLAG(res == 0, ZF); | |
if (DX == 0 || DX == 0xFFFF) { | |
CLR_FLAG(CF); | |
CLR_FLAG(OF); | |
} else { | |
SET_FLAG(CF); | |
SET_FLAG(OF); | |
} | |
} | |
/* inc byte primitive */ | |
uint8 inc_byte(uint8 d) | |
{ | |
register uint32 res; | |
register uint32 cc; | |
res = d + 1; | |
/* set the flags based on the result */ | |
CONDITIONAL_SET_FLAG((res & 0xFF) == 0, ZF); | |
CONDITIONAL_SET_FLAG(res & 0x80, SF); | |
CONDITIONAL_SET_FLAG(parity(res & 0xFF), PF); | |
/* calculate the carry chain SEE NOTE AT TOP.*/ | |
cc = ((1 & d) | (~res)) & (1 | d); | |
/* set the flags based on the carry chain */ | |
CONDITIONAL_SET_FLAG(xor_3_tab[(cc >> 6) & 0x3], OF); | |
CONDITIONAL_SET_FLAG(cc & 0x8, AF); | |
return res; | |
} | |
/* inc word primitive */ | |
uint16 inc_word(uint16 d) | |
{ | |
register uint32 res; | |
register uint32 cc; | |
res = d + 1; | |
/* set the flags based on the result */ | |
CONDITIONAL_SET_FLAG((res & 0xFFFF) == 0, ZF); | |
CONDITIONAL_SET_FLAG(res & 0x8000, SF); | |
CONDITIONAL_SET_FLAG(parity(res & 0xff), PF); | |
/* calculate the carry chain SEE NOTE AT TOP.*/ | |
cc = (1 & d) | ((~res) & (1 | d)); | |
/* set the flags based on the carry chain */ | |
CONDITIONAL_SET_FLAG(xor_3_tab[(cc >> 14) & 0x3], OF); | |
CONDITIONAL_SET_FLAG(cc & 0x8, AF); | |
return res ; | |
} | |
/* mul byte primitive */ | |
void mul_byte(uint8 s) | |
{ | |
uint16 res; | |
res = AL * s; | |
AX = res; | |
/* Undef --- Can't hurt */ | |
CLR_FLAG(SF); | |
CONDITIONAL_SET_FLAG(res == 0, ZF); | |
if (AH == 0) { | |
CLR_FLAG(CF); | |
CLR_FLAG(OF); | |
} else { | |
SET_FLAG(CF); | |
SET_FLAG(OF); | |
} | |
} | |
/* mul word primitive */ | |
void mul_word(uint16 s) | |
{ | |
uint32 res; | |
res = AX * s; | |
/* Undef --- Can't hurt */ | |
CLR_FLAG(SF); | |
CONDITIONAL_SET_FLAG(res == 0, ZF); | |
AX = res & 0xFFFF; | |
DX = (res >> 16) & 0xFFFF; | |
if (DX == 0) { | |
CLR_FLAG(CF); | |
CLR_FLAG(OF); | |
} else { | |
SET_FLAG(CF); | |
SET_FLAG(OF); | |
} | |
} | |
/* neg byte primitive */ | |
uint8 neg_byte(uint8 s) | |
{ | |
register uint8 res; | |
register uint8 bc; | |
CONDITIONAL_SET_FLAG(s != 0, CF); | |
res = -s; | |
CONDITIONAL_SET_FLAG((res & 0xff) == 0, ZF); | |
CONDITIONAL_SET_FLAG(res & 0x80, SF); | |
CONDITIONAL_SET_FLAG(parity(res), PF); | |
/* calculate the borrow chain --- modified such that d=0. */ | |
bc= res | s; | |
CONDITIONAL_SET_FLAG(xor_3_tab[(bc >> 6) & 0x3], OF); | |
CONDITIONAL_SET_FLAG(bc & 0x8, AF); | |
return res; | |
} | |
/* neg word primitive */ | |
uint16 neg_word(uint16 s) | |
{ | |
register uint16 res; | |
register uint16 bc; | |
CONDITIONAL_SET_FLAG(s != 0, CF); | |
res = -s; | |
CONDITIONAL_SET_FLAG((res & 0xFFFF) == 0, ZF); | |
CONDITIONAL_SET_FLAG(res & 0x8000, SF); | |
CONDITIONAL_SET_FLAG(parity(res & 0xFF), PF); | |
/* calculate the borrow chain --- modified such that d=0 */ | |
bc= res | s; | |
CONDITIONAL_SET_FLAG(xor_3_tab[(bc >> 6) & 0x3], OF); | |
CONDITIONAL_SET_FLAG(bc & 0x8, AF); | |
return res; | |
} | |
/* not byte primitive */ | |
uint8 not_byte(uint8 s) | |
{ | |
return ~s; | |
} | |
/* not word primitive */ | |
uint16 not_word(uint16 s) | |
{ | |
return ~s; | |
} | |
/* or byte primitive */ | |
uint8 or_byte(uint8 d, uint8 s) | |
{ | |
register uint8 res; | |
res = d | s; | |
/* clear flags */ | |
CLR_FLAG(OF); | |
CLR_FLAG(CF); | |
/* set the flags based on the result */ | |
CONDITIONAL_SET_FLAG(res & 0x80, SF); | |
CONDITIONAL_SET_FLAG(res == 0, ZF); | |
CONDITIONAL_SET_FLAG(parity(res), PF); | |
return res; | |
} | |
/* or word primitive */ | |
uint16 or_word(uint16 d, uint16 s) | |
{ | |
register uint16 res; | |
res = d | s; | |
/* clear flags */ | |
CLR_FLAG(OF); | |
CLR_FLAG(CF); | |
/* set the flags based on the result */ | |
CONDITIONAL_SET_FLAG(res & 0x8000, SF); | |
CONDITIONAL_SET_FLAG(res == 0, ZF); | |
CONDITIONAL_SET_FLAG(parity(res & 0xFF), PF); | |
return res; | |
} | |
/* push word primitive */ | |
void push_word(uint16 val) | |
{ | |
SP--; | |
put_smbyte(SS, SP, val >> 8); | |
SP--; | |
put_smbyte(SS, SP, val & 0xFF); | |
} | |
/* pop word primitive */ | |
uint16 pop_word(void) | |
{ | |
register uint16 res; | |
res = get_smbyte(SS, SP); | |
SP++; | |
res |= (get_smbyte(SS, SP) << 8); | |
SP++; | |
return res; | |
} | |
/* rcl byte primitive */ | |
uint8 rcl_byte(uint8 d, uint8 s) | |
{ | |
register uint32 res, cnt, mask, cf; | |
res = d; | |
if ((cnt = s % 9)) | |
{ | |
cf = (d >> (8-cnt)) & 0x1; | |
res = (d << cnt) & 0xFF; | |
mask = (1<<(cnt-1)) - 1; | |
res |= (d >> (9-cnt)) & mask; | |
if (GET_FLAG(CF)) | |
res |= 1 << (cnt-1); | |
CONDITIONAL_SET_FLAG(cf, CF); | |
CONDITIONAL_SET_FLAG(cnt == 1 && xor_3_tab[cf + ((res >> 6) & 0x2)], OF); | |
} | |
return res & 0xFF; | |
} | |
/* rcl word primitive */ | |
uint16 rcl_word(uint16 d, uint16 s) | |
{ | |
register uint32 res, cnt, mask, cf; | |
res = d; | |
if ((cnt = s % 17)) | |
{ | |
cf = (d >> (16-cnt)) & 0x1; | |
res = (d << cnt) & 0xFFFF; | |
mask = (1<<(cnt-1)) - 1; | |
res |= (d >> (17-cnt)) & mask; | |
if (GET_FLAG(CF)) | |
res |= 1 << (cnt-1); | |
CONDITIONAL_SET_FLAG(cf, CF); | |
CONDITIONAL_SET_FLAG(cnt == 1 && xor_3_tab[cf + ((res >> 14) & 0x2)], OF); | |
} | |
return res & 0xFFFF; | |
} | |
/* rcr byte primitive */ | |
uint8 rcr_byte(uint8 d, uint8 s) | |
{ | |
uint8 res, cnt; | |
uint8 mask, cf, ocf = 0; | |
res = d; | |
if ((cnt = s % 9)) { | |
if (cnt == 1) { | |
cf = d & 0x1; | |
ocf = GET_FLAG(CF) != 0; | |
} else | |
cf = (d >> (cnt - 1)) & 0x1; | |
mask = (1 <<( 8 - cnt)) - 1; | |
res = (d >> cnt) & mask; | |
res |= (d << (9-cnt)); | |
if (GET_FLAG(CF)) | |
res |= 1 << (8 - cnt); | |
CONDITIONAL_SET_FLAG(cf, CF); | |
if (cnt == 1) | |
CONDITIONAL_SET_FLAG(xor_3_tab[ocf + ((d >> 6) & 0x2)], OF); | |
} | |
return res; | |
} | |
/* rcr word primitive */ | |
uint16 rcr_word(uint16 d, uint16 s) | |
{ | |
uint16 res, cnt; | |
uint16 mask, cf, ocf = 0; | |
res = d; | |
if ((cnt = s % 17)) { | |
if (cnt == 1) { | |
cf = d & 0x1; | |
ocf = GET_FLAG(CF) != 0; | |
} else | |
cf = (d >> (cnt-1)) & 0x1; | |
mask = (1 <<( 16 - cnt)) - 1; | |
res = (d >> cnt) & mask; | |
res |= (d << (17 - cnt)); | |
if (GET_FLAG(CF)) | |
res |= 1 << (16 - cnt); | |
CONDITIONAL_SET_FLAG(cf, CF); | |
if (cnt == 1) | |
CONDITIONAL_SET_FLAG(xor_3_tab[ocf + ((d >> 14) & 0x2)], OF); | |
} | |
return res; | |
} | |
/* rol byte primitive */ | |
uint8 rol_byte(uint8 d, uint8 s) | |
{ | |
register uint32 res, cnt, mask; | |
res =d; | |
if ((cnt = s % 8)) { | |
res = (d << cnt); | |
mask = (1 << cnt) - 1; | |
res |= (d >> (8-cnt)) & mask; | |
CONDITIONAL_SET_FLAG(res & 0x1, CF); | |
CONDITIONAL_SET_FLAG(cnt == 1 && xor_3_tab[(res & 0x1) + ((res >> 6) & 0x2)], OF); | |
} | |
return res & 0xFF; | |
} | |
/* rol word primitive */ | |
uint16 rol_word(uint16 d, uint16 s) | |
{ | |
register uint32 res, cnt, mask; | |
res = d; | |
if ((cnt = s % 16)) { | |
res = (d << cnt); | |
mask = (1 << cnt) - 1; | |
res |= (d >> (16 - cnt)) & mask; | |
CONDITIONAL_SET_FLAG(res & 0x1, CF); | |
CONDITIONAL_SET_FLAG(cnt == 1 && xor_3_tab[(res & 0x1) + ((res >> 14) & 0x2)], OF); | |
} | |
return res&0xFFFF; | |
} | |
/* ror byte primitive */ | |
uint8 ror_byte(uint8 d, uint8 s) | |
{ | |
register uint32 res, cnt, mask; | |
res = d; | |
if ((cnt = s % 8)) { | |
res = (d << (8-cnt)); | |
mask = (1 << (8-cnt)) - 1; | |
res |= (d >> (cnt)) & mask; | |
CONDITIONAL_SET_FLAG(res & 0x80, CF); | |
CONDITIONAL_SET_FLAG(cnt == 1 && xor_3_tab[(res >> 6) & 0x3], OF); | |
} | |
return res & 0xFF; | |
} | |
/* ror word primitive */ | |
uint16 ror_word(uint16 d, uint16 s) | |
{ | |
register uint32 res, cnt, mask; | |
res = d; | |
if ((cnt = s % 16)) { | |
res = (d << (16-cnt)); | |
mask = (1 << (16-cnt)) - 1; | |
res |= (d >> (cnt)) & mask; | |
CONDITIONAL_SET_FLAG(res & 0x8000, CF); | |
CONDITIONAL_SET_FLAG(cnt == 1 && xor_3_tab[(res >> 14) & 0x3], OF); | |
} | |
return res & 0xFFFF; | |
} | |
/* shl byte primitive */ | |
uint8 shl_byte(uint8 d, uint8 s) | |
{ | |
uint32 cnt, res, cf; | |
if (s < 8) { | |
cnt = s % 8; | |
if (cnt > 0) { | |
res = d << cnt; | |
cf = d & (1 << (8 - cnt)); | |
CONDITIONAL_SET_FLAG(cf, CF); | |
CONDITIONAL_SET_FLAG((res & 0xFF)==0, ZF); | |
CONDITIONAL_SET_FLAG(res & 0x80, SF); | |
CONDITIONAL_SET_FLAG(parity(res & 0xFF), PF); | |
} else | |
res = (uint8) d; | |
if (cnt == 1) | |
CONDITIONAL_SET_FLAG((((res & 0x80) == 0x80) ^ | |
(GET_FLAG( CF) != 0)), OF); | |
else | |
CLR_FLAG(OF); | |
} else { | |
res = 0; | |
CONDITIONAL_SET_FLAG((s == 8) && (d & 1), CF); | |
CLR_FLAG(OF); | |
CLR_FLAG(SF); | |
CLR_FLAG(PF); | |
SET_FLAG(ZF); | |
} | |
return res & 0xFF; | |
} | |
/* shl word primitive */ | |
uint16 shl_word(uint16 d, uint16 s) | |
{ | |
uint32 cnt, res, cf; | |
if (s < 16) { | |
cnt = s % 16; | |
if (cnt > 0) { | |
res = d << cnt; | |
cf = d & (1<<(16-cnt)); | |
CONDITIONAL_SET_FLAG(cf, CF); | |
CONDITIONAL_SET_FLAG((res & 0xFFFF) == 0, ZF); | |
CONDITIONAL_SET_FLAG(res & 0x8000, SF); | |
CONDITIONAL_SET_FLAG(parity(res & 0xFF), PF); | |
} else | |
res = (uint16) d; | |
if (cnt == 1) | |
CONDITIONAL_SET_FLAG((((res & 0x8000) == 0x8000) ^ | |
(GET_FLAG(CF) != 0)), OF); | |
else | |
CLR_FLAG(OF); | |
} else { | |
res = 0; | |
CONDITIONAL_SET_FLAG((s == 16) && (d & 1), CF); | |
CLR_FLAG(OF); | |
SET_FLAG(ZF); | |
CLR_FLAG(SF); | |
CLR_FLAG(PF); | |
} | |
return res & 0xFFFF; | |
} | |
/* shr byte primitive */ | |
uint8 shr_byte(uint8 d, uint8 s) | |
{ | |
uint32 cnt, res, cf, mask; | |
if (s < 8) { | |
cnt = s % 8; | |
if (cnt > 0) { | |
mask = (1 << (8 - cnt)) - 1; | |
cf = d & (1 << (cnt - 1)); | |
res = (d >> cnt) & mask; | |
CONDITIONAL_SET_FLAG(cf, CF); | |
CONDITIONAL_SET_FLAG((res & 0xFF) == 0, ZF); | |
CONDITIONAL_SET_FLAG(res & 0x80, SF); | |
CONDITIONAL_SET_FLAG(parity(res & 0xFF), PF); | |
} else | |
res = (uint8) d; | |
if (cnt == 1) | |
CONDITIONAL_SET_FLAG(xor_3_tab[(res >> 6) & 0x3], OF); | |
else | |
CLR_FLAG(OF); | |
} else { | |
res = 0; | |
CONDITIONAL_SET_FLAG((s == 8) && (d & 0x80), CF); | |
CLR_FLAG(OF); | |
SET_FLAG(ZF); | |
CLR_FLAG(SF); | |
CLR_FLAG(PF); | |
} | |
return res & 0xFF; | |
} | |
/* shr word primitive */ | |
uint16 shr_word(uint16 d, uint16 s) | |
{ | |
uint32 cnt, res, cf, mask; | |
res = d; | |
if (s < 16) { | |
cnt = s % 16; | |
if (cnt > 0) { | |
mask = (1 << (16 - cnt)) - 1; | |
cf = d & (1 << (cnt - 1)); | |
res = (d >> cnt) & mask; | |
CONDITIONAL_SET_FLAG(cf, CF); | |
CONDITIONAL_SET_FLAG((res & 0xFFFF) == 0, ZF); | |
CONDITIONAL_SET_FLAG(res & 0x8000, SF); | |
CONDITIONAL_SET_FLAG(parity(res & 0xFF), PF); | |
} else | |
res = d; | |
if (cnt == 1) | |
CONDITIONAL_SET_FLAG(xor_3_tab[(res >> 14) & 0x3], OF); | |
else | |
CLR_FLAG(OF); | |
} else { | |
res = 0; | |
CONDITIONAL_SET_FLAG((s == 16) && (d & 0x8000), CF); | |
CLR_FLAG(OF); | |
SET_FLAG(ZF); | |
CLR_FLAG(SF); | |
CLR_FLAG(PF); | |
} | |
return res & 0xFFFF; | |
} | |
/* sar byte primitive */ | |
uint8 sar_byte(uint8 d, uint8 s) | |
{ | |
uint32 cnt, res, cf, mask, sf; | |
res = d; | |
sf = d & 0x80; | |
cnt = s % 8; | |
if (cnt > 0 && cnt < 8) { | |
mask = (1 << (8 - cnt)) - 1; | |
cf = d & (1 << (cnt -1 )); | |
res = (d >> cnt) & mask; | |
CONDITIONAL_SET_FLAG(cf, CF); | |
if (sf) | |
res |= ~mask; | |
CONDITIONAL_SET_FLAG((res & 0xFF)==0, ZF); | |
CONDITIONAL_SET_FLAG(parity(res & 0xFF), PF); | |
CONDITIONAL_SET_FLAG(res & 0x80, SF); | |
} else if (cnt >= 8) { | |
if (sf) { | |
res = 0xFF; | |
SET_FLAG(CF); | |
CLR_FLAG(ZF); | |
SET_FLAG(SF); | |
SET_FLAG(PF); | |
} else { | |
res = 0; | |
CLR_FLAG(CF); | |
SET_FLAG(ZF); | |
CLR_FLAG(SF); | |
CLR_FLAG(PF); | |
} | |
} | |
return res & 0xFF; | |
} | |
/* sar word primitive */ | |
uint16 sar_word(uint16 d, uint16 s) | |
{ | |
uint32 cnt, res, cf, mask, sf; | |
sf = d & 0x8000; | |
cnt = s % 16; | |
res = d; | |
if (cnt > 0 && cnt < 16) { | |
mask = (1 << (16 - cnt)) - 1; | |
cf = d & (1 << (cnt - 1)); | |
res = (d >> cnt) & mask; | |
CONDITIONAL_SET_FLAG(cf, CF); | |
if (sf) | |
res |= ~mask; | |
CONDITIONAL_SET_FLAG((res & 0xFFFF) == 0, ZF); | |
CONDITIONAL_SET_FLAG(res & 0x8000, SF); | |
CONDITIONAL_SET_FLAG(parity(res & 0xFF), PF); | |
} else if (cnt >= 16) { | |
if (sf) { | |
res = 0xFFFF; | |
SET_FLAG(CF); | |
CLR_FLAG(ZF); | |
SET_FLAG(SF); | |
SET_FLAG(PF); | |
} else { | |
res = 0; | |
CLR_FLAG(CF); | |
SET_FLAG(ZF); | |
CLR_FLAG(SF); | |
CLR_FLAG(PF); | |
} | |
} | |
return res & 0xFFFF; | |
} | |
/* sbb byte primitive */ | |
uint8 sbb_byte(uint8 d, uint8 s) | |
{ | |
register uint32 res; | |
register uint32 bc; | |
if (GET_FLAG(CF)) | |
res = d - s - 1; | |
else | |
res = d - s; | |
/* set the flags based on the result */ | |
CONDITIONAL_SET_FLAG(res & 0x80, SF); | |
CONDITIONAL_SET_FLAG((res & 0xFF) == 0, ZF); | |
CONDITIONAL_SET_FLAG(parity(res & 0xFF), PF); | |
/* calculate the borrow chain. See note at top */ | |
bc= (res&(~d|s))|(~d&s); | |
/* set flags based on borrow chain */ | |
CONDITIONAL_SET_FLAG(bc & 0x80, CF); | |
CONDITIONAL_SET_FLAG(xor_3_tab[(bc >> 6) & 0x3], OF); | |
CONDITIONAL_SET_FLAG(bc & 0x8, AF); | |
// return res & 0x0FF; | |
return (uint8) res; | |
} | |
/* sbb word primitive */ | |
uint16 sbb_word(uint16 d, uint16 s) | |
{ | |
register uint32 res; | |
register uint32 bc; | |
if (GET_FLAG(CF)) | |
res = d - s - 1; | |
else | |
res = d - s; | |
/* set the flags based on the result */ | |
CONDITIONAL_SET_FLAG(res & 0x8000, SF); | |
CONDITIONAL_SET_FLAG((res & 0xFFFF) == 0, ZF); | |
CONDITIONAL_SET_FLAG(parity(res & 0xFF), PF); | |
/* calculate the borrow chain. See note at top */ | |
bc= (res&(~d|s))|(~d&s); | |
/* set flags based on borrow chain */ | |
CONDITIONAL_SET_FLAG(bc & 0x8000, CF); | |
CONDITIONAL_SET_FLAG(xor_3_tab[(bc >> 14) & 0x3], OF); | |
CONDITIONAL_SET_FLAG(bc & 0x8, AF); | |
// return res & 0xFFFF; | |
return (uint16) res; | |
} | |
/* sub byte primitive */ | |
uint8 sub_byte(uint8 d, uint8 s) | |
{ | |
register uint32 res; | |
register uint32 bc; | |
res = d - s; | |
/* set the flags based on the result */ | |
CONDITIONAL_SET_FLAG(res & 0x80, SF); | |
CONDITIONAL_SET_FLAG((res & 0xFF) == 0, ZF); | |
CONDITIONAL_SET_FLAG(parity(res & 0xFF), PF); | |
/* calculate the borrow chain. See note at top */ | |
bc= (res&(~d|s))|(~d&s); | |
/* set flags based on borrow chain */ | |
CONDITIONAL_SET_FLAG(bc & 0x80, CF); | |
CONDITIONAL_SET_FLAG(xor_3_tab[(bc >> 6) & 0x3], OF); | |
CONDITIONAL_SET_FLAG(bc & 0x8, AF); | |
// return res & 0xff; | |
return (uint8) res; | |
} | |
/* sub word primitive */ | |
uint16 sub_word(uint16 d, uint16 s) | |
{ | |
register uint32 res; | |
register uint32 bc; | |
res = d - s; | |
/* set the flags based on the result */ | |
CONDITIONAL_SET_FLAG(res &0x8000, SF); | |
CONDITIONAL_SET_FLAG((res &0xFFFF) == 0, ZF); | |
CONDITIONAL_SET_FLAG(parity(res & 0xFF), PF); | |
/* calculate the borrow chain. See note at top */ | |
bc= (res&(~d|s))|(~d&s); | |
/* set flags based on borrow chain */ | |
CONDITIONAL_SET_FLAG(bc & 0x8000, CF); | |
CONDITIONAL_SET_FLAG(xor_3_tab[(bc >> 14) & 0x3], OF); | |
CONDITIONAL_SET_FLAG(bc & 0x8, AF); | |
// return res & 0xffff; | |
return (uint16) res; | |
} | |
/* test byte primitive */ | |
void test_byte(uint8 d, uint8 s) | |
{ | |
register uint32 res; | |
res = d & s; | |
CLR_FLAG(OF); | |
CONDITIONAL_SET_FLAG(res & 0x80, SF); | |
CONDITIONAL_SET_FLAG(res == 0, ZF); | |
CONDITIONAL_SET_FLAG(parity(res & 0xFF), PF); | |
/* AF == dont care*/ | |
CLR_FLAG(CF); | |
} | |
/* test word primitive */ | |
void test_word(uint16 d, uint16 s) | |
{ | |
register uint32 res; | |
res = d & s; | |
CLR_FLAG(OF); | |
CONDITIONAL_SET_FLAG(res & 0x8000, SF); | |
CONDITIONAL_SET_FLAG(res == 0, ZF); | |
CONDITIONAL_SET_FLAG(parity(res & 0xff), PF); | |
/* AF == dont care*/ | |
CLR_FLAG(CF); | |
} | |
/* xor byte primitive */ | |
uint8 xor_byte(uint8 d, uint8 s) | |
{ | |
register uint8 res; | |
res = d ^ s; | |
/* clear flags */ | |
CLR_FLAG(OF); | |
CLR_FLAG(CF); | |
/* set the flags based on the result */ | |
CONDITIONAL_SET_FLAG(res & 0x80, SF); | |
CONDITIONAL_SET_FLAG(res == 0, ZF); | |
CONDITIONAL_SET_FLAG(parity(res), PF); | |
return res; | |
} | |
/* xor word primitive */ | |
uint16 xor_word(uint16 d, uint16 s) | |
{ | |
register uint16 res; | |
res = d ^ s; | |
/* clear flags */ | |
CLR_FLAG(OF); | |
CLR_FLAG(CF); | |
/* set the flags based on the result */ | |
CONDITIONAL_SET_FLAG(res & 0x8000, SF); | |
CONDITIONAL_SET_FLAG(res == 0, ZF); | |
CONDITIONAL_SET_FLAG(parity(res & 0xFF), PF); | |
return res; | |
} | |
/* memory routines. These use the segment register (segreg) value and offset | |
(addr) to calculate the proper source or destination memory address */ | |
/* get a byte from memory */ | |
int32 get_smbyte(int32 segreg, int32 addr) | |
{ | |
int32 abs_addr, val; | |
abs_addr = addr + (get_rword(segreg) << 4); | |
val = get_mbyte(abs_addr); | |
// sim_printf("get_smbyte: seg=%04X addr=%04X abs_addr=%08X get_mbyte=%02X\n", | |
// get_rword(segreg), addr, abs_addr, val); | |
return val; | |
} | |
/* get a word from memory using addr and segment register */ | |
int32 get_smword(int32 segreg, int32 addr) | |
{ | |
int32 val; | |
val = get_smbyte(segreg, addr); | |
val |= (get_smbyte(segreg, addr+1) << 8); | |
return val; | |
} | |
/* put a byte to memory using addr and segment register */ | |
void put_smbyte(int32 segreg, int32 addr, int32 val) | |
{ | |
int32 abs_addr; | |
abs_addr = addr + (get_rword(segreg) << 4); | |
put_mbyte(abs_addr, val); | |
} | |
/* put a word to memory using addr and segment register */ | |
void put_smword(int32 segreg, int32 addr, int32 val) | |
{ | |
put_smbyte(segreg, addr, val); | |
put_smbyte(segreg, addr+1, val << 8); | |
} | |
/* Reset routine using addr and segment register */ | |
t_stat i8088_reset (DEVICE *dptr) | |
{ | |
PSW = 0; | |
CS = 0xFFFF; | |
DS = 0; | |
SS = 0; | |
ES = 0; | |
saved_PC = 0; | |
int_req = 0; | |
sim_brk_types = sim_brk_dflt = SWMASK ('E'); | |
sim_printf(" 8088 Reset\n"); | |
return SCPE_OK; | |
} | |
/* Memory examine */ | |
t_stat i8088_ex (t_value *vptr, t_addr addr, UNIT *uptr, int32 sw) | |
{ | |
if (addr >= MAXMEMSIZE20) | |
return SCPE_NXM; | |
if (vptr != NULL) | |
*vptr = get_mbyte(addr); | |
return SCPE_OK; | |
} | |
/* Memory deposit */ | |
t_stat i8088_dep (t_value val, t_addr addr, UNIT *uptr, int32 sw) | |
{ | |
if (addr >= MAXMEMSIZE20) | |
return SCPE_NXM; | |
put_mbyte(addr, val); | |
return SCPE_OK; | |
} | |
/* This is the binary loader. The input file is considered to be | |
a string of literal bytes with no special format. The load | |
starts at the current value of the PC. | |
*/ | |
int32 sim_load (FILE *fileref, char *cptr, char *fnam, int flag) | |
{ | |
int32 i, addr = 0, cnt = 0; | |
if ((*cptr != 0) || (flag != 0)) return SCPE_ARG; | |
addr = saved_PC; | |
while ((i = getc (fileref)) != EOF) { | |
put_mbyte(addr, i); | |
addr++; | |
cnt++; | |
} /* end while */ | |
sim_printf ("%d Bytes loaded.\n", cnt); | |
return (SCPE_OK); | |
} | |
/* Symbolic output | |
Inputs: | |
*of = output stream | |
addr = current PC | |
*val = pointer to values | |
*uptr = pointer to unit | |
sw = switches | |
Outputs: | |
status = error code | |
*/ | |
int32 fprint_sym (FILE *of, int32 addr, uint32 *val, | |
UNIT *uptr, int32 sw) | |
{ | |
int32 cflag, c1, c2, inst, adr; | |
cflag = (uptr == NULL) || (uptr == &i8088_unit); | |
c1 = (val[0] >> 8) & 0177; | |
c2 = val[0] & 0177; | |
if (sw & SWMASK ('A')) { | |
fprintf (of, (c2 < 040)? "<%02X>": "%c", c2); | |
return SCPE_OK; | |
} | |
if (sw & SWMASK ('C')) { | |
fprintf (of, (c1 < 040)? "<%02X>": "%c", c1); | |
fprintf (of, (c2 < 040)? "<%02X>": "%c", c2); | |
return SCPE_OK; | |
} | |
if (!(sw & SWMASK ('M'))) return SCPE_ARG; | |
inst = val[0]; | |
fprintf (of, "%s", opcode[inst]); | |
if (oplen[inst] == 2) { | |
if (strchr(opcode[inst], ' ') != NULL) | |
fprintf (of, ","); | |
else fprintf (of, " "); | |
fprintf (of, "%h", val[1]); | |
} | |
if (oplen[inst] == 3) { | |
adr = val[1] & 0xFF; | |
adr |= (val[2] << 8) & 0xff00; | |
if (strchr(opcode[inst], ' ') != NULL) | |
fprintf (of, ","); | |
else fprintf (of, " "); | |
fprintf (of, "%h", adr); | |
} | |
return -(oplen[inst] - 1); | |
} | |
/* Symbolic input | |
Inputs: | |
*cptr = pointer to input string | |
addr = current PC | |
*uptr = pointer to unit | |
*val = pointer to output values | |
sw = switches | |
Outputs: | |
status = error status | |
*/ | |
int32 parse_sym (char *cptr, int32 addr, UNIT *uptr, uint32 *val, int32 sw) | |
{ | |
int32 cflag, i = 0, j, r, fflag = 1; | |
char gbuf[256]; | |
cflag = (uptr == NULL) || (uptr == &i8088_unit); | |
while (isspace (*cptr)) cptr++; /* absorb spaces */ | |
if ((sw & SWMASK ('A')) || ((*cptr == '\'') && cptr++)) { /* ASCII char? */ | |
if (cptr[0] == 0) return SCPE_ARG; /* must have 1 char */ | |
val[0] = (uint32) cptr[0]; | |
return SCPE_OK; | |
} | |
if ((sw & SWMASK ('C')) || ((*cptr == '"') && cptr++)) { /* ASCII string? */ | |
if (cptr[0] == 0) return SCPE_ARG; /* must have 1 char */ | |
val[0] = ((uint32) cptr[0] << 8) + (uint32) cptr[1]; | |
return SCPE_OK; | |
} | |
/* An instruction: get opcode (all characters until null, comma, | |
or numeric (including spaces). | |
*/ | |
while (1) { | |
if (*cptr == ',' || *cptr == '\0' || | |
isdigit(*cptr)) | |
break; | |
gbuf[i] = toupper(*cptr); | |
cptr++; | |
i++; | |
} | |
/* Allow for RST which has numeric as part of opcode */ | |
if (toupper(gbuf[0]) == 'R' && | |
toupper(gbuf[1]) == 'S' && | |
toupper(gbuf[2]) == 'T') { | |
gbuf[i] = toupper(*cptr); | |
cptr++; | |
i++; | |
} | |
/* Allow for 'MOV' which is only opcode that has comma in it. */ | |
if (toupper(gbuf[0]) == 'M' && | |
toupper(gbuf[1]) == 'O' && | |
toupper(gbuf[2]) == 'V') { | |
gbuf[i] = toupper(*cptr); | |
cptr++; | |
i++; | |
gbuf[i] = toupper(*cptr); | |
cptr++; | |
i++; | |
} | |
/* kill trailing spaces if any */ | |
gbuf[i] = '\0'; | |
for (j = i - 1; gbuf[j] == ' '; j--) { | |
gbuf[j] = '\0'; | |
} | |
/* find opcode in table */ | |
for (j = 0; j < 256; j++) { | |
if (strcmp(gbuf, opcode[j]) == 0) | |
fflag = 0; | |
} | |
if (fflag) /* not found */ | |
return SCPE_ARG; | |
val[0] = j; /* store opcode */ | |
if (oplen[j] < 2) /* if 1-byter we are done */ | |
return SCPE_OK; | |
if (*cptr == ',') cptr++; | |
cptr = get_glyph(cptr, gbuf, 0); /* get address */ | |
sscanf(gbuf, "%o", &r); | |
if (oplen[j] == 2) { | |
val[1] = r & 0xFF; | |
return (-1); | |
} | |
val[1] = r & 0xFF; | |
val[2] = (r >> 8) & 0xFF; | |
return (-2); | |
} |