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/* m6800.c: SWTP 6800 CPU simulator
Copyright (c) 2005-2011, William 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 Motorola M6800 CPU
The register state for the M6800 CPU is:
A<0:7> Accumulator A
B<0:7> Accumulator B
IX<0:15> Index Register
CCR<0:7> Condition Code Register
HF half-carry flag
IF interrupt flag
NF negative flag
ZF zero flag
VF overflow flag
CF carry flag
PC<0:15> program counter
SP<0:15> Stack Pointer
The M6800 is an 8-bit CPU, which uses 16-bit registers to address
up to 64KB of memory.
The 72 basic instructions come in 1, 2, and 3-byte flavors.
This routine is the instruction decode routine for the M6800.
It is called from the CPU board simulator to execute
instructions in simulated memory, starting at the simulated PC.
It runs until 'reason' is set non-zero.
General notes:
1. Reasons to stop. The simulator can be stopped by:
WAI instruction
I/O error in I/O simulator
Invalid OP code (if ITRAP is set on CPU)
Invalid mamory address (if MTRAP is set on CPU)
2. Interrupts.
There are 4 types of interrupt, and in effect they do a
hardware CALL instruction to one of 4 possible high memory addresses.
3. Non-existent memory.
On the SWTP 6800, reads to non-existent memory
return 0FFH, and writes are ignored.
*/
#include <stdio.h>
#include "swtp_defs.h"
#define UNIT_V_OPSTOP (UNIT_V_UF) /* Stop on Invalid OP? */
#define UNIT_OPSTOP (1 << UNIT_V_OPSTOP)
#define UNIT_V_MSTOP (UNIT_V_UF+1) /* Stop on Invalid memory? */
#define UNIT_MSTOP (1 << UNIT_V_MSTOP)
/* Flag values to set proper positions in CCR */
#define HF 0x20
#define IF 0x10
#define NF 0x08
#define ZF 0x04
#define VF 0x02
#define CF 0x01
/* Macros to handle the flags in the CCR */
#define CCR_ALWAYS_ON (0xC0) /* for 6800 */
#define CCR_MSK (HF|IF|NF|ZF|VF|CF)
#define TOGGLE_FLAG(FLAG) (CCR ^= (FLAG))
#define SET_FLAG(FLAG) (CCR |= (FLAG))
#define CLR_FLAG(FLAG) (CCR &= ~(FLAG))
#define GET_FLAG(FLAG) (CCR & (FLAG))
#define COND_SET_FLAG(COND,FLAG) \
if (COND) SET_FLAG(FLAG); else CLR_FLAG(FLAG)
#define COND_SET_FLAG_N(VAR) \
if ((VAR) & 0x80) SET_FLAG(NF); else CLR_FLAG(NF)
#define COND_SET_FLAG_Z(VAR) \
if ((VAR) == 0) SET_FLAG(ZF); else CLR_FLAG(ZF)
#define COND_SET_FLAG_H(VAR) \
if ((VAR) & 0x10) SET_FLAG(HF); else CLR_FLAG(HF)
#define COND_SET_FLAG_C(VAR) \
if ((VAR) & 0x100) SET_FLAG(CF); else CLR_FLAG(CF)
#define COND_SET_FLAG_V(COND) \
if (COND) SET_FLAG(VF); else CLR_FLAG(VF)
/* local global variables */
int32 A = 0; /* Accumulator A */
int32 B = 0; /* Accumulator B */
int32 IX = 0; /* Index register */
int32 SP = 0; /* Stack pointer */
int32 CCR = CCR_ALWAYS_ON | IF; /* Condition Code Register */
int32 saved_PC = 0; /* Program counter */
int32 PC; /* global for the helper routines */
int32 INTE = 0; /* Interrupt Enable */
int32 int_req = 0; /* Interrupt request */
int32 mem_fault = 0; /* memory fault flag */
/* function prototypes */
t_stat m6800_reset (DEVICE *dptr);
void dump_regs(void);
void dump_regs1(void);
int32 fetch_byte(int32 flag);
int32 fetch_word(void);
uint8 pop_byte(void);
uint16 pop_word(void);
void push_byte(uint8 val);
void push_word(uint16 val);
void go_rel(int32 cond);
int32 get_rel_addr(void);
int32 get_dir_val(void);
int32 get_dir_addr(void);
int32 get_indir_val(void);
int32 get_indir_addr(void);
int32 get_ext_val(void);
int32 get_ext_addr(void);
int32 get_flag(int32 flag);
void condevalVa(int32 op1, int32 op2);
void condevalVs(int32 op1, int32 op2);
/* external routines */
extern void CPU_BD_put_mbyte(int32 addr, int32 val);
extern void CPU_BD_put_mword(int32 addr, int32 val);
extern int32 CPU_BD_get_mbyte(int32 addr);
extern int32 CPU_BD_get_mword(int32 addr);
/* CPU data structures
m6800_dev CPU device descriptor
m6800_unit CPU unit descriptor
m6800_reg CPU register list
m6800_mod CPU modifiers list */
UNIT m6800_unit = { UDATA (NULL, 0, 0) };
REG m6800_reg[] = {
{ HRDATA (PC, saved_PC, 16) },
{ HRDATA (A, A, 8) },
{ HRDATA (B, B, 8) },
{ HRDATA (IX, IX, 16) },
{ HRDATA (SP, SP, 16) },
{ HRDATA (CCR, CCR, 8) },
{ FLDATA (INTE, INTE, 16) },
{ ORDATA (WRU, sim_int_char, 8) },
{ NULL } };
MTAB m6800_mod[] = {
{ UNIT_OPSTOP, UNIT_OPSTOP, "ITRAP", "ITRAP", NULL },
{ UNIT_OPSTOP, 0, "NOITRAP", "NOITRAP", NULL },
{ UNIT_MSTOP, UNIT_MSTOP, "MTRAP", "MTRAP", NULL },
{ UNIT_MSTOP, 0, "NOMTRAP", "NOMTRAP", NULL },
{ 0 } };
DEBTAB m6800_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 m6800_dev = {
"CPU", //name
&m6800_unit, //units
m6800_reg, //registers
m6800_mod, //modifiers
1, //numunits
16, //aradix
16, //awidth
1, //aincr
16, //dradix
8, //dwidth
NULL, //examine
NULL, //deposit
&m6800_reset, //reset
NULL, //boot
NULL, //attach
NULL, //detach
NULL, //ctxt
DEV_DEBUG, //flags
0, //dctrl
m6800_debug, //debflags
NULL, //msize
NULL //lname
};
static const char *opcode[] = {
"???", "NOP", "???", "???", //0x00
"???", "???", "TAP", "TPA",
"INX", "DEX", "CLV", "SEV",
"CLC", "SEC", "CLI", "SEI",
"SBA", "CBA", "???", "???", //0x10
"???", "???", "TAB", "TBA",
"???", "DAA", "???", "ABA",
"???", "???", "???", "???",
"BRA", "???", "BHI", "BLS", //0x20
"BCC", "BCS", "BNE", "BEQ",
"BVC", "BVS", "BPL", "BMI",
"BGE", "BLT", "BGT", "BLE",
"TSX", "INS", "PULA", "PULB", //0x30
"DES", "TXS", "PSHA", "PSHB",
"???", "RTS", "???", "RTI",
"???", "???", "WAI", "SWI",
"NEGA", "???", "???", "COMA", //0x40
"LSRA", "???", "RORA", "ASRA",
"ASLA", "ROLA", "DECA", "???",
"INCA", "TSTA", "???", "CLRA",
"NEGB", "???", "???", "COMB", //0x50
"LSRB", "???", "RORB", "ASRB",
"ASLB", "ROLB", "DECB", "???",
"INCB", "TSTB", "???", "CLRB",
"NEG", "???", "???", "COM", //0x60
"LSR", "???", "ROR", "ASR",
"ASL", "ROL", "DEC", "???",
"INC", "TST", "JMP", "CLR",
"NEG", "???", "???", "COM", //0x70
"LSR", "???", "ROR", "ASR",
"ASL", "ROL", "DEC", "???",
"INC", "TST", "JMP", "CLR",
"SUBA", "CMPA", "SBCA", "???", //0x80
"ANDA", "BITA", "LDAA", "???",
"EORA", "ADCA", "ORAA", "ADDA",
"CPX", "BSR", "LDS", "???",
"SUBA", "CMPA", "SBCA", "???", //0x90
"ANDA", "BITA", "LDAA", "STAA",
"EORA", "ADCA", "ORAA", "ADDA",
"CPX", "???", "LDS", "STS",
"SUBA", "CMPA", "SBCA", "???", //0xA0
"ANDA", "BITA", "LDAA", "STAA",
"EORA", "ADCA", "ORAA", "ADDA",
"CPX X", "JSR X", "LDS X", "STS X",
"SUBA", "CMPA", "SBCA", "???", //0xB0
"ANDA", "BITA", "LDAA", "STAA",
"EORA", "ADCA", "ORAA", "ADDA",
"CPX", "JSR", "LDS", "STS",
"SUBB", "CMPB", "SBCB", "???", //0xC0
"ANDB", "BITB", "LDAB", "???",
"EORB", "ADCB", "ORAB", "ADDB",
"???", "???", "LDX", "???",
"SUBB", "CMPB", "SBCB", "???", //0xD0
"ANDB", "BITB", "LDAB", "STAB",
"EORB", "ADCB", "ORAB", "ADDB",
"???", "???", "LDX", "STX",
"SUBB", "CMPB", "SBCB", "???", //0xE0
"ANDB", "BITB", "LDAB", "STAB",
"EORB", "ADCB", "ORAB", "ADDB",
"???", "???", "LDX", "STX",
"SUBB", "CMPB", "SBCB", "???", //0xF0
"ANDB", "BITB", "LDAB", "STAB",
"EORB", "ADCB", "ORAB", "ADDB",
"???", "???", "LDX", "STX",
};
int32 oplen[256] = {
0,1,0,0,0,0,1,1,1,1,1,1,1,1,1,1, //0x00
1,1,0,0,0,0,1,1,0,1,0,1,0,0,0,0,
2,0,2,2,2,2,2,2,2,2,2,2,2,2,2,2,
1,1,1,1,1,1,1,1,0,1,0,1,0,0,1,1,
1,0,0,1,1,0,1,1,1,1,1,0,1,1,0,1, //0x40
1,0,0,1,1,0,1,1,1,1,1,0,1,1,0,1,
2,0,0,2,2,0,2,2,2,2,2,0,2,2,2,2,
3,0,0,3,3,0,3,3,3,3,3,0,3,3,3,3,
2,2,2,0,2,2,2,0,2,2,2,2,3,2,3,0, //0x80
2,2,2,0,2,2,2,2,2,2,2,2,2,0,2,2,
2,2,2,0,2,2,2,2,2,2,2,2,2,2,2,2,
3,3,3,0,3,3,3,3,3,3,3,3,3,3,3,3,
2,2,2,0,2,2,2,0,2,2,2,2,0,0,3,0, //0xC0
2,2,2,0,2,2,2,2,2,2,2,2,0,0,2,2,
2,2,2,0,2,2,2,2,2,2,2,2,0,0,2,2,
3,3,3,0,3,3,3,3,3,3,3,3,0,0,3,3
};
t_stat sim_instr (void)
{
int32 IR, OP, DAR, reason, hi, lo, op1;
PC = saved_PC & ADDRMASK; /* load local PC */
reason = 0;
/* Main instruction fetch/decode loop */
while (reason == 0) { /* loop until halted */
// dump_regs1();
if (sim_interval <= 0) /* check clock queue */
if ((reason = sim_process_event ()))
break;
if (mem_fault) { /* memory fault? */
mem_fault = 0; /* reset fault flag */
reason = STOP_MEMORY;
break;
}
if (int_req > 0) { /* interrupt? */
/* 6800 interrupts not implemented yet. None were used,
on a standard SWTP 6800. All I/O is programmed. */
} /* end interrupt */
if (sim_brk_summ &&
sim_brk_test (PC, SWMASK ('E'))) { /* breakpoint? */
reason = STOP_IBKPT; /* stop simulation */
break;
}
IR = OP = fetch_byte(0); /* fetch instruction */
sim_interval--;
/* The Big Instruction Decode Switch */
switch (IR) {
case 0x01: /* NOP */
break;
case 0x06: /* TAP */
CCR = A;
break;
case 0x07: /* TPA */
A = CCR;
break;
case 0x08: /* INX */
IX = (IX + 1) & ADDRMASK;
COND_SET_FLAG_Z(IX);
break;
case 0x09: /* DEX */
IX = (IX - 1) & ADDRMASK;
COND_SET_FLAG_Z(IX);
break;
case 0x0A: /* CLV */
CLR_FLAG(VF);
break;
case 0x0B: /* SEV */
SET_FLAG(VF);
break;
case 0x0C: /* CLC */
CLR_FLAG(CF);
break;
case 0x0D: /* SEC */
SET_FLAG(CF);
break;
case 0x0E: /* CLI */
CLR_FLAG(IF);
break;
case 0x0F: /* SEI */
SET_FLAG(IF);
break;
case 0x10: /* SBA */
op1 = A;
A = A - B;
COND_SET_FLAG_N(A);
COND_SET_FLAG_Z(A);
COND_SET_FLAG_C(A);
condevalVs(B, op1);
A &= 0xFF;
break;
case 0x11: /* CBA */
lo = A - B;
COND_SET_FLAG_N(lo);
COND_SET_FLAG_Z(lo);
COND_SET_FLAG_C(lo);
condevalVs(B, A);
break;
case 0x16: /* TAB */
B = A;
COND_SET_FLAG_N(B);
COND_SET_FLAG_Z(B);
CLR_FLAG(VF);
break;
case 0x17: /* TBA */
A = B;
COND_SET_FLAG_N(B);
COND_SET_FLAG_Z(B);
CLR_FLAG(VF);
break;
case 0x19: /* DAA */
DAR = A & 0x0F;
op1 = get_flag(CF);
if (DAR > 9 || get_flag(CF)) {
DAR += 6;
A &= 0xF0;
A |= (DAR & 0x0F);
COND_SET_FLAG(DAR & 0x10,CF);
}
DAR = (A >> 4) & 0x0F;
if (DAR > 9 || get_flag(CF)) {
DAR += 6;
if (get_flag(CF))
DAR++;
A &= 0x0F;
A |= (DAR << 4);
}
COND_SET_FLAG(op1,CF);
if ((DAR << 4) & 0x100)
SET_FLAG(CF);
COND_SET_FLAG_N(A);
COND_SET_FLAG_Z(A);
A &= 0xFF;
break;
case 0x1B: /* ABA */
A += B;
COND_SET_FLAG_H(A);
COND_SET_FLAG_N(A);
COND_SET_FLAG_Z(A);
COND_SET_FLAG_C(A);
condevalVa(A, B);
A &= 0xFF;
break;
case 0x20: /* BRA rel */
go_rel(1);
break;
case 0x22: /* BHI rel */
go_rel(!(get_flag(CF) | get_flag(ZF)));
break;
case 0x23: /* BLS rel */
go_rel(get_flag(CF) | get_flag(ZF));
break;
case 0x24: /* BCC rel */
go_rel(!get_flag(CF));
break;
case 0x25: /* BCS rel */
go_rel(get_flag(CF));
break;
case 0x26: /* BNE rel */
go_rel(!get_flag(ZF));
break;
case 0x27: /* BEQ rel */
go_rel(get_flag(ZF));
break;
case 0x28: /* BVC rel */
go_rel(!get_flag(VF));
break;
case 0x29: /* BVS rel */
go_rel(get_flag(VF));
break;
case 0x2A: /* BPL rel */
go_rel(!get_flag(NF));
break;
case 0x2B: /* BMI rel */
go_rel(get_flag(NF));
break;
case 0x2C: /* BGE rel */
go_rel(!(get_flag(NF) ^ get_flag(VF)));
break;
case 0x2D: /* BLT rel */
go_rel(get_flag(NF) ^ get_flag(VF));
break;
case 0x2E: /* BGT rel */
go_rel(!(get_flag(ZF) | (get_flag(NF) ^ get_flag(VF))));
break;
case 0x2F: /* BLE rel */
go_rel(get_flag(ZF) | (get_flag(NF) ^ get_flag(VF)));
break;
case 0x30: /* TSX */
IX = (SP + 1) & ADDRMASK;
break;
case 0x31: /* INS */
SP = (SP + 1) & ADDRMASK;
break;
case 0x32: /* PUL A */
A = pop_byte();
break;
case 0x33: /* PUL B */
B = pop_byte();
break;
case 0x34: /* DES */
SP = (SP - 1) & ADDRMASK;
break;
case 0x35: /* TXS */
SP = (IX - 1) & ADDRMASK;
break;
case 0x36: /* PSH A */
push_byte(A);
break;
case 0x37: /* PSH B */
push_byte(B);
break;
case 0x39: /* RTS */
PC = pop_word();
break;
case 0x3B: /* RTI */
CCR = pop_byte();
B = pop_byte();
A = pop_byte();
IX = pop_word();
PC = pop_word();
break;
case 0x3E: /* WAI */
push_word(PC);
push_word(IX);
push_byte(A);
push_byte(B);
push_byte(CCR);
if (get_flag(IF)) {
reason = STOP_HALT;
continue;
} else {
SET_FLAG(IF);
PC = CPU_BD_get_mword(0xFFFE) & ADDRMASK;
}
break;
case 0x3F: /* SWI */
push_word(PC);
push_word(IX);
push_byte(A);
push_byte(B);
push_byte(CCR);
SET_FLAG(IF);
PC = CPU_BD_get_mword(0xFFFB) & ADDRMASK;
break;
case 0x40: /* NEG A */
A = (0 - A) & 0xFF;
COND_SET_FLAG_V(A & 0x80);
COND_SET_FLAG(A,CF);
COND_SET_FLAG_N(A);
COND_SET_FLAG_Z(A);
break;
case 0x43: /* COM A */
A = ~A & 0xFF;
CLR_FLAG(VF);
SET_FLAG(CF);
COND_SET_FLAG_N(A);
COND_SET_FLAG_Z(A);
break;
case 0x44: /* LSR A */
COND_SET_FLAG(A & 0x01,CF);
A = (A >> 1) & 0xFF;
CLR_FLAG(NF);
COND_SET_FLAG_Z(A);
COND_SET_FLAG_V(get_flag(NF) ^ get_flag(CF));
break;
case 0x46: /* ROR A */
hi = get_flag(CF);
COND_SET_FLAG(A & 0x01,CF);
A = (A >> 1) & 0xFF;
if (hi)
A |= 0x80;
COND_SET_FLAG_N(A);
COND_SET_FLAG_Z(A);
COND_SET_FLAG_V(get_flag(NF) ^ get_flag(CF));
break;
case 0x47: /* ASR A */
COND_SET_FLAG(A & 0x01,CF);
lo = A & 0x80;
A = (A >> 1) & 0xFF;
A |= lo;
COND_SET_FLAG_N(A);
COND_SET_FLAG_Z(A);
COND_SET_FLAG_V(get_flag(NF) ^ get_flag(CF));
break;
case 0x48: /* ASL A */
COND_SET_FLAG(A & 0x80,CF);
A = (A << 1) & 0xFF;
COND_SET_FLAG_N(A);
COND_SET_FLAG_Z(A);
COND_SET_FLAG_V(get_flag(NF) ^ get_flag(CF));
break;
case 0x49: /* ROL A */
hi = get_flag(CF);
COND_SET_FLAG(A & 0x80,CF);
A = (A << 1) & 0xFF;
if (hi)
A |= 0x01;
COND_SET_FLAG_N(A);
COND_SET_FLAG_Z(A);
COND_SET_FLAG_V(get_flag(NF) ^ get_flag(CF));
break;
case 0x4A: /* DEC A */
COND_SET_FLAG_V(A == 0x80);
A = (A - 1) & 0xFF;
COND_SET_FLAG_N(A);
COND_SET_FLAG_Z(A);
break;
case 0x4C: /* INC A */
COND_SET_FLAG_V(A == 0x7F);
A = (A + 1) & 0xFF;
COND_SET_FLAG_N(A);
COND_SET_FLAG_Z(A);
break;
case 0x4D: /* TST A */
lo = (A - 0) & 0xFF;
CLR_FLAG(VF);
CLR_FLAG(CF);
COND_SET_FLAG_N(lo);
COND_SET_FLAG_Z(lo);
break;
case 0x4F: /* CLR A */
A = 0;
CLR_FLAG(NF);
CLR_FLAG(VF);
CLR_FLAG(CF);
SET_FLAG(ZF);
break;
case 0x50: /* NEG B */
B = (0 - B) & 0xFF;
COND_SET_FLAG_V(B & 0x80);
COND_SET_FLAG(B,CF);
COND_SET_FLAG_N(B);
COND_SET_FLAG_Z(B);
break;
case 0x53: /* COM B */
B = ~B;
B &= 0xFF;
CLR_FLAG(VF);
SET_FLAG(CF);
COND_SET_FLAG_N(B);
COND_SET_FLAG_Z(B);
break;
case 0x54: /* LSR B */
COND_SET_FLAG(B & 0x01,CF);
B = (B >> 1) & 0xFF;
CLR_FLAG(NF);
COND_SET_FLAG_Z(B);
COND_SET_FLAG_V(get_flag(NF) ^ get_flag(CF));
break;
case 0x56: /* ROR B */
hi = get_flag(CF);
COND_SET_FLAG(B & 0x01,CF);
B = (B >> 1) & 0xFF;
if (hi)
B |= 0x80;
COND_SET_FLAG_N(B);
COND_SET_FLAG_Z(B);
COND_SET_FLAG_V(get_flag(NF) ^ get_flag(CF));
break;
case 0x57: /* ASR B */
COND_SET_FLAG(B & 0x01,CF);
lo = B & 0x80;
B = (B >> 1) & 0xFF;
B |= lo;
COND_SET_FLAG_N(B);
COND_SET_FLAG_Z(B);
COND_SET_FLAG_V(get_flag(NF) ^ get_flag(CF));
break;
case 0x58: /* ASL B */
COND_SET_FLAG(B & 0x80,CF);
B = (B << 1) & 0xFF;
COND_SET_FLAG_N(B);
COND_SET_FLAG_Z(B);
COND_SET_FLAG_V(get_flag(NF) ^ get_flag(CF));
break;
case 0x59: /* ROL B */
hi = get_flag(CF);
COND_SET_FLAG(B & 0x80,CF);
B = (B << 1) & 0xFF;
if (hi)
B |= 0x01;
COND_SET_FLAG_N(B);
COND_SET_FLAG_Z(B);
COND_SET_FLAG_V(get_flag(NF) ^ get_flag(CF));
break;
case 0x5A: /* DEC B */
COND_SET_FLAG_V(B == 0x80);
B = (B - 1) & 0xFF;
COND_SET_FLAG_N(B);
COND_SET_FLAG_Z(B);
break;
case 0x5C: /* INC B */
COND_SET_FLAG_V(B == 0x7F);
B = (B + 1) & 0xFF;
COND_SET_FLAG_N(B);
COND_SET_FLAG_Z(B);
break;
case 0x5D: /* TST B */
lo = (B - 0) & 0xFF;
CLR_FLAG(VF);
CLR_FLAG(CF);
COND_SET_FLAG_N(lo);
COND_SET_FLAG_Z(lo);
break;
case 0x5F: /* CLR B */
B = 0;
CLR_FLAG(NF);
CLR_FLAG(VF);
CLR_FLAG(CF);
SET_FLAG(ZF);
break;
case 0x60: /* NEG ind */
DAR = get_indir_addr();
lo = (0 - CPU_BD_get_mbyte(DAR)) & 0xFF;
CPU_BD_put_mbyte(DAR, lo);
COND_SET_FLAG_V(lo & 0x80);
COND_SET_FLAG(lo,CF);
COND_SET_FLAG_N(lo);
COND_SET_FLAG_Z(lo);
break;
case 0x63: /* COM ind */
DAR = get_indir_addr();
lo = ~CPU_BD_get_mbyte(DAR);
lo &= 0xFF;
CPU_BD_put_mbyte(DAR, lo);
CLR_FLAG(VF);
SET_FLAG(CF);
COND_SET_FLAG_N(lo);
COND_SET_FLAG_Z(lo);
break;
case 0x64: /* LSR ind */
DAR = get_indir_addr();
lo = CPU_BD_get_mbyte(DAR);
COND_SET_FLAG(lo & 0x01,CF);
lo >>= 1;
CPU_BD_put_mbyte(DAR, lo);
CLR_FLAG(NF);
COND_SET_FLAG_Z(lo);
COND_SET_FLAG_V(get_flag(NF) ^ get_flag(CF));
break;
case 0x66: /* ROR ind */
DAR = get_indir_addr();
lo = CPU_BD_get_mbyte(DAR);
hi = get_flag(CF);
COND_SET_FLAG(lo & 0x01,CF);
lo >>= 1;
if (hi)
lo |= 0x80;
CPU_BD_put_mbyte(DAR, lo);
COND_SET_FLAG_N(lo);
COND_SET_FLAG_Z(lo);
COND_SET_FLAG_V(get_flag(NF) ^ get_flag(CF));
break;
case 0x67: /* ASR ind */
DAR = get_indir_addr();
lo = CPU_BD_get_mbyte(DAR);
COND_SET_FLAG(lo & 0x01,CF);
lo = (lo & 0x80) | (lo >> 1);
CPU_BD_put_mbyte(DAR, lo);
COND_SET_FLAG_N(lo);
COND_SET_FLAG_Z(lo);
COND_SET_FLAG_V(get_flag(NF) ^ get_flag(CF));
break;
case 0x68: /* ASL ind */
DAR = get_indir_addr();
lo = CPU_BD_get_mbyte(DAR);
COND_SET_FLAG(lo & 0x80,CF);
lo <<= 1;
CPU_BD_put_mbyte(DAR, lo);
COND_SET_FLAG_N(lo);
COND_SET_FLAG_Z(lo);
COND_SET_FLAG_V(get_flag(NF) ^ get_flag(CF));
break;
case 0x69: /* ROL ind */
DAR = get_indir_addr();
lo = CPU_BD_get_mbyte(DAR);
hi = get_flag(CF);
COND_SET_FLAG(lo & 0x80,CF);
lo <<= 1;
if (hi)
lo |= 0x01;
CPU_BD_put_mbyte(DAR, lo);
COND_SET_FLAG_N(lo);
COND_SET_FLAG_Z(lo);
COND_SET_FLAG_V(get_flag(NF) ^ get_flag(CF));
break;
case 0x6A: /* DEC ind */
DAR = get_indir_addr();
lo = CPU_BD_get_mbyte(DAR);
COND_SET_FLAG_V(lo == 0x80);
lo = (lo - 1) & 0xFF;
CPU_BD_put_mbyte(DAR, lo);
COND_SET_FLAG_N(lo);
COND_SET_FLAG_Z(lo);
break;
case 0x6C: /* INC ind */
DAR= get_indir_addr();
lo = CPU_BD_get_mbyte(DAR);
COND_SET_FLAG_V(lo == 0x7F);
lo = (lo + 1) & 0xFF;
CPU_BD_put_mbyte(DAR, lo);
COND_SET_FLAG_N(lo);
COND_SET_FLAG_Z(lo);
break;
case 0x6D: /* TST ind */
lo = (get_indir_val() - 0) & 0xFF;
CLR_FLAG(VF);
CLR_FLAG(CF);
COND_SET_FLAG_N(lo);
COND_SET_FLAG_Z(lo);
break;
case 0x6E: /* JMP ind */
PC = get_indir_addr();
break;
case 0x6F: /* CLR ind */
CPU_BD_put_mbyte(get_indir_addr(), 0);
CLR_FLAG(NF);
CLR_FLAG(VF);
CLR_FLAG(CF);
SET_FLAG(ZF);
break;
case 0x70: /* NEG ext */
DAR = get_ext_addr();
lo = (0 - CPU_BD_get_mbyte(DAR)) & 0xFF;
CPU_BD_put_mbyte(DAR, lo);
COND_SET_FLAG_V(lo & 0x80);
CLR_FLAG(CF);
if (lo)
SET_FLAG(CF);
COND_SET_FLAG_N(lo);
COND_SET_FLAG_Z(lo);
break;
case 0x73: /* COM ext */
DAR = get_ext_addr();
lo = ~CPU_BD_get_mbyte(DAR);
lo &= 0xFF;
CPU_BD_put_mbyte(DAR, lo);
CLR_FLAG(VF);
SET_FLAG(CF);
COND_SET_FLAG_N(lo);
COND_SET_FLAG_Z(lo);
break;
case 0x74: /* LSR ext */
DAR = get_ext_addr();
lo = CPU_BD_get_mbyte(DAR);
COND_SET_FLAG(lo & 0x01,CF);
lo >>= 1;
CPU_BD_put_mbyte(DAR, lo);
CLR_FLAG(NF);
COND_SET_FLAG_Z(lo);
COND_SET_FLAG_V(get_flag(NF) ^ get_flag(CF));
break;
case 0x76: /* ROR ext */
DAR = get_ext_addr();
hi = get_flag(CF);
lo = CPU_BD_get_mbyte(DAR);
COND_SET_FLAG(lo & 0x01,CF);
lo >>= 1;
if (hi)
lo |= 0x80;
CPU_BD_put_mbyte(DAR, lo);
COND_SET_FLAG_N(lo);
COND_SET_FLAG_Z(lo);
COND_SET_FLAG_V(get_flag(NF) ^ get_flag(CF));
break;
case 0x77: /* ASR ext */
DAR = get_ext_addr();
lo = CPU_BD_get_mbyte(DAR);
COND_SET_FLAG(lo & 0x01,CF);
hi = lo & 0x80;
lo >>= 1;
lo |= hi;
CPU_BD_put_mbyte(DAR, lo);
COND_SET_FLAG_N(lo);
COND_SET_FLAG_Z(lo);
COND_SET_FLAG_V(get_flag(NF) ^ get_flag(CF));
break;
case 0x78: /* ASL ext */
DAR = get_ext_addr();
lo = CPU_BD_get_mbyte(DAR);
COND_SET_FLAG(lo & 0x80,CF);
lo <<= 1;
CPU_BD_put_mbyte(DAR, lo);
COND_SET_FLAG_N(lo);
COND_SET_FLAG_Z(lo);
COND_SET_FLAG_V(get_flag(NF) ^ get_flag(CF));
break;
case 0x79: /* ROL ext */
DAR = get_ext_addr();
lo = CPU_BD_get_mbyte(DAR);
hi = get_flag(CF);
COND_SET_FLAG(lo & 0x80,CF);
lo <<= 1;
if (hi)
lo |= 0x01;
CPU_BD_put_mbyte(DAR, lo);
COND_SET_FLAG_N(lo);
COND_SET_FLAG_Z(lo);
COND_SET_FLAG_V(get_flag(NF) ^ get_flag(CF));
break;
case 0x7A: /* DEC ext */
DAR = get_ext_addr();
lo = CPU_BD_get_mbyte(DAR);
COND_SET_FLAG_V(lo == 0x80);
lo = (lo - 1) & 0xFF;
CPU_BD_put_mbyte(DAR, lo);
COND_SET_FLAG_N(lo);
COND_SET_FLAG_Z(lo);
break;
case 0x7C: /* INC ext */
DAR = get_ext_addr();
lo = CPU_BD_get_mbyte(DAR);
COND_SET_FLAG_V(lo == 0x7F);
lo = (lo + 1) & 0xFF;
CPU_BD_put_mbyte(DAR, lo);
COND_SET_FLAG_N(lo);
COND_SET_FLAG_Z(lo);
break;
case 0x7D: /* TST ext */
lo = CPU_BD_get_mbyte(get_ext_addr()) - 0;
CLR_FLAG(VF);
CLR_FLAG(CF);
COND_SET_FLAG_N(lo);
lo &= 0xFF;
COND_SET_FLAG_Z(lo);
break;
case 0x7E: /* JMP ext */
PC = get_ext_addr() & ADDRMASK;
break;
case 0x7F: /* CLR ext */
CPU_BD_put_mbyte(get_ext_addr(), 0);
CLR_FLAG(NF);
CLR_FLAG(VF);
CLR_FLAG(CF);
SET_FLAG(ZF);
break;
case 0x80: /* SUB A imm */
op1 = get_dir_addr();
A = A - op1;
COND_SET_FLAG_N(A);
COND_SET_FLAG_C(A);
condevalVs(A, op1);
A &= 0xFF;
COND_SET_FLAG_Z(A);
break;
case 0x81: /* CMP A imm */
op1 = get_dir_addr();
lo = A - op1;
COND_SET_FLAG_N(lo);
COND_SET_FLAG_C(lo);
condevalVs(lo, op1);
lo &= 0xFF;
COND_SET_FLAG_Z(lo);
break;
case 0x82: /* SBC A imm */
op1 = get_dir_addr();
A = A - op1 - get_flag(CF);
COND_SET_FLAG_N(A);
COND_SET_FLAG_C(A);
condevalVs(A, op1);
A &= 0xFF;
COND_SET_FLAG_Z(A);
break;
case 0x84: /* AND A imm */
A = (A & get_dir_addr()) & 0xFF;
CLR_FLAG(VF);
COND_SET_FLAG_N(A);
COND_SET_FLAG_Z(A);
break;
case 0x85: /* BIT A imm */
lo = (A & get_dir_addr()) & 0xFF;
CLR_FLAG(VF);
COND_SET_FLAG_N(lo);
COND_SET_FLAG_Z(lo);
break;
case 0x86: /* LDA A imm */
A = get_dir_addr();
CLR_FLAG(VF);
COND_SET_FLAG_N(A);
COND_SET_FLAG_Z(A);
break;
case 0x88: /* EOR A imm */
A = (A ^ get_dir_addr()) & 0xFF;
CLR_FLAG(VF);
COND_SET_FLAG_N(A);
COND_SET_FLAG_Z(A);
break;
case 0x89: /* ADC A imm */
op1 = get_dir_addr();
A = A + op1 + get_flag(CF);
COND_SET_FLAG_H(A);
COND_SET_FLAG_N(A);
COND_SET_FLAG_C(A);
condevalVa(A, op1);
A &= 0xFF;
COND_SET_FLAG_Z(A);
break;
case 0x8A: /* ORA A imm */
A = (A | get_dir_addr()) & 0xFF;
CLR_FLAG(VF);
COND_SET_FLAG_N(A);
COND_SET_FLAG_Z(A);
break;
case 0x8B: /* ADD A imm */
op1 = get_dir_addr();
A = A + op1;
COND_SET_FLAG_H(A);
COND_SET_FLAG_N(A);
COND_SET_FLAG_C(A);
condevalVa(A, op1);
A &= 0xFF;
COND_SET_FLAG_Z(A);
break;
case 0x8C: /* CPX imm */
op1 = IX - get_ext_addr();
COND_SET_FLAG_Z(op1);
COND_SET_FLAG_N(op1 >> 8);
COND_SET_FLAG_V(op1 & 0x10000);
break;
case 0x8D: /* BSR rel */
lo = get_rel_addr();
push_word(PC);
PC = PC + lo;
PC &= ADDRMASK;
break;
case 0x8E: /* LDS imm */
SP = get_ext_addr();
COND_SET_FLAG_N(SP >> 8);
COND_SET_FLAG_Z(SP);
CLR_FLAG(VF);
break;
case 0x90: /* SUB A dir */
op1 = get_dir_val();
A = A - op1;
COND_SET_FLAG_N(A);
COND_SET_FLAG_C(A);
condevalVs(A, op1);
A &= 0xFF;
COND_SET_FLAG_Z(A);
break;
case 0x91: /* CMP A dir */
op1 = get_dir_val();
lo = A - op1;
COND_SET_FLAG_N(lo);
COND_SET_FLAG_C(lo);
condevalVs(A, op1);
lo &= 0xFF;
COND_SET_FLAG_Z(lo);
break;
case 0x92: /* SBC A dir */
op1 = get_dir_val();
A = A - op1 - get_flag(CF);
COND_SET_FLAG_N(A);
COND_SET_FLAG_C(A);
condevalVs(A, op1);
A &= 0xFF;
COND_SET_FLAG_Z(A);
break;
case 0x94: /* AND A dir */
A = (A & get_dir_val()) & 0xFF;
CLR_FLAG(VF);
COND_SET_FLAG_N(A);
COND_SET_FLAG_Z(A);
break;
case 0x95: /* BIT A dir */
lo = (A & get_dir_val()) & 0xFF;
CLR_FLAG(VF);
COND_SET_FLAG_N(lo);
COND_SET_FLAG_Z(lo);
break;
case 0x96: /* LDA A dir */
A = get_dir_val();
CLR_FLAG(VF);
COND_SET_FLAG_N(A);
COND_SET_FLAG_Z(A);
break;
case 0x97: /* STA A dir */
CPU_BD_put_mbyte(get_dir_addr(), A);
CLR_FLAG(VF);
COND_SET_FLAG_N(A);
COND_SET_FLAG_Z(A);
break;
case 0x98: /* EOR A dir */
A = (A ^ get_dir_val()) & 0xFF;
CLR_FLAG(VF);
COND_SET_FLAG_N(A);
COND_SET_FLAG_Z(A);
break;
case 0x99: /* ADC A dir */
op1 = get_dir_val();
A = A + op1 + get_flag(CF);
COND_SET_FLAG_H(A);
COND_SET_FLAG_N(A);
COND_SET_FLAG_C(A);
condevalVa(A, op1);
A &= 0xFF;
COND_SET_FLAG_Z(A);
break;
case 0x9A: /* ORA A dir */
A = (A | get_dir_val()) & 0xFF;
CLR_FLAG(VF);
COND_SET_FLAG_N(A);
COND_SET_FLAG_Z(A);
break;
case 0x9B: /* ADD A dir */
op1 = get_dir_val();
A = A + op1;
COND_SET_FLAG_H(A);
COND_SET_FLAG_N(A);
COND_SET_FLAG_C(A);
condevalVa(A, op1);
A &= 0xFF;
COND_SET_FLAG_Z(A);
break;
case 0x9C: /* CPX dir */
op1 = IX - CPU_BD_get_mword(get_dir_addr());
COND_SET_FLAG_Z(op1);
COND_SET_FLAG_N(op1 >> 8);
COND_SET_FLAG_V(op1 & 0x10000);
break;
case 0x9E: /* LDS dir */
SP = CPU_BD_get_mword(get_dir_addr());
COND_SET_FLAG_N(SP >> 8);
COND_SET_FLAG_Z(SP);
CLR_FLAG(VF);
break;
case 0x9F: /* STS dir */
CPU_BD_put_mword(get_dir_addr(), SP);
COND_SET_FLAG_N(SP >> 8);
COND_SET_FLAG_Z(SP);
CLR_FLAG(VF);
break;
case 0xA0: /* SUB A ind */
op1 = get_indir_val();
A = A - op1;
COND_SET_FLAG_N(A);
COND_SET_FLAG_C(A);
condevalVs(A, op1);
A &= 0xFF;
COND_SET_FLAG_Z(A);
break;
case 0xA1: /* CMP A ind */
op1 = get_indir_val();
lo = A - op1;
COND_SET_FLAG_N(lo);
COND_SET_FLAG_C(lo);
condevalVs(A, op1);
lo &= 0xFF;
COND_SET_FLAG_Z(lo);
break;
case 0xA2: /* SBC A ind */
op1 = get_indir_val();
A = A - op1 - get_flag(CF);
COND_SET_FLAG_N(A);
COND_SET_FLAG_C(A);
condevalVs(A, op1);
A &= 0xFF;
COND_SET_FLAG_Z(A);
break;
case 0xA4: /* AND A ind */
A = (A & get_indir_val()) & 0xFF;
CLR_FLAG(VF);
COND_SET_FLAG_N(A);
COND_SET_FLAG_Z(A);
break;
case 0xA5: /* BIT A ind */
lo = (A & get_indir_val()) & 0xFF;
CLR_FLAG(VF);
COND_SET_FLAG_N(lo);
COND_SET_FLAG_Z(lo);
break;
case 0xA6: /* LDA A ind */
A = get_indir_val();
CLR_FLAG(VF);
COND_SET_FLAG_N(A);
COND_SET_FLAG_Z(A);
break;
case 0xA7: /* STA A ind */
CPU_BD_put_mbyte(get_indir_addr(), A);
CLR_FLAG(VF);
COND_SET_FLAG_N(A);
COND_SET_FLAG_Z(A);
break;
case 0xA8: /* EOR A ind */
A = (A ^ get_indir_val()) & 0xFF;
CLR_FLAG(VF);
COND_SET_FLAG_N(A);
COND_SET_FLAG_Z(A);
break;
case 0xA9: /* ADC A ind */
op1 = get_indir_val();
A = A + op1 + get_flag(CF);
COND_SET_FLAG_H(A);
COND_SET_FLAG_N(A);
COND_SET_FLAG_C(A);
condevalVa(A, op1);
A &= 0xFF;
COND_SET_FLAG_Z(A);
break;
case 0xAA: /* ORA A ind */
A = (A | get_indir_val()) & 0xFF;
CLR_FLAG(VF);
COND_SET_FLAG_N(A);
COND_SET_FLAG_Z(A);
break;
case 0xAB: /* ADD A ind */
op1 = get_indir_val();
A = A + op1;
COND_SET_FLAG_H(A);
COND_SET_FLAG_N(A);
COND_SET_FLAG_C(A);
condevalVa(A, op1);
A &= 0xFF;
COND_SET_FLAG_Z(A);
break;
case 0xAC: /* CPX ind */
op1 = (IX - get_indir_addr()) & ADDRMASK;
COND_SET_FLAG_Z(op1);
COND_SET_FLAG_N(op1 >> 8);
COND_SET_FLAG_V(op1 & 0x10000);
break;
case 0xAD: /* JSR ind */
DAR = get_indir_addr();
push_word(PC);
PC = DAR;
break;
case 0xAE: /* LDS ind */
SP = CPU_BD_get_mword(get_indir_addr());
COND_SET_FLAG_N(SP >> 8);
COND_SET_FLAG_Z(SP);
CLR_FLAG(VF);
break;
case 0xAF: /* STS ind */
CPU_BD_put_mword(get_indir_addr(), SP);
COND_SET_FLAG_N(SP >> 8);
COND_SET_FLAG_Z(SP);
CLR_FLAG(VF);
break;
case 0xB0: /* SUB A ext */
op1 = get_ext_val();
A = A - op1;
COND_SET_FLAG_N(A);
COND_SET_FLAG_C(A);
condevalVs(A, op1);
A &= 0xFF;
COND_SET_FLAG_Z(A);
break;
case 0xB1: /* CMP A ext */
op1 = get_ext_val();
lo = A - op1;
COND_SET_FLAG_N(lo);
COND_SET_FLAG_C(lo);
condevalVs(A, op1);
lo &= 0xFF;
COND_SET_FLAG_Z(lo);
break;
case 0xB2: /* SBC A ext */
op1 = get_ext_val();
A = A - op1 - get_flag(CF);
COND_SET_FLAG_N(A);
COND_SET_FLAG_C(A);
condevalVs(A, op1);
A &= 0xFF;
COND_SET_FLAG_Z(A);
break;
case 0xB4: /* AND A ext */
A = (A & get_ext_val()) & 0xFF;
CLR_FLAG(VF);
COND_SET_FLAG_N(A);
COND_SET_FLAG_Z(A);
break;
case 0xB5: /* BIT A ext */
lo = (A & get_ext_val()) & 0xFF;
CLR_FLAG(VF);
COND_SET_FLAG_N(lo);
COND_SET_FLAG_Z(lo);
break;
case 0xB6: /* LDA A ext */
A = get_ext_val();
CLR_FLAG(VF);
COND_SET_FLAG_N(A);
COND_SET_FLAG_Z(A);
break;
case 0xB7: /* STA A ext */
CPU_BD_put_mbyte(get_ext_addr(), A);
CLR_FLAG(VF);
COND_SET_FLAG_N(A);
COND_SET_FLAG_Z(A);
break;
case 0xB8: /* EOR A ext */
A = (A ^ get_ext_val()) & 0xFF;
CLR_FLAG(VF);
COND_SET_FLAG_N(A);
COND_SET_FLAG_Z(A);
break;
case 0xB9: /* ADC A ext */
op1 = get_ext_val();
A = A + op1 + get_flag(CF);
COND_SET_FLAG_H(A);
COND_SET_FLAG_N(A);
COND_SET_FLAG_C(A);
condevalVa(A, op1);
A &= 0xFF;
COND_SET_FLAG_Z(A);
break;
case 0xBA: /* ORA A ext */
A = (A | get_ext_val()) & 0xFF;
CLR_FLAG(VF);
COND_SET_FLAG_N(A);
COND_SET_FLAG_Z(A);
break;
case 0xBB: /* ADD A ext */
op1 = get_ext_val();
A = A + op1;
COND_SET_FLAG_H(A);
COND_SET_FLAG_N(A);
COND_SET_FLAG_C(A);
condevalVa(A, op1);
A &= 0xFF;
COND_SET_FLAG_Z(A);
break;
case 0xBC: /* CPX ext */
op1 = (IX - CPU_BD_get_mword(get_ext_addr()));// & ADDRMASK;
COND_SET_FLAG_Z(op1);
COND_SET_FLAG_N(op1 >> 8);
COND_SET_FLAG_V(op1 & 0x10000);
break;
case 0xBD: /* JSR ext */
DAR = get_ext_addr();
push_word(PC);
PC = DAR;
break;
case 0xBE: /* LDS ext */
SP = CPU_BD_get_mword(get_ext_addr());
COND_SET_FLAG_N(SP >> 8);
COND_SET_FLAG_Z(SP);
CLR_FLAG(VF);
break;
case 0xBF: /* STS ext */
CPU_BD_put_mword(get_ext_addr(), SP);
COND_SET_FLAG_N(SP >> 8);
COND_SET_FLAG_Z(SP);
CLR_FLAG(VF);
break;
case 0xC0: /* SUB B imm */
op1 = get_dir_addr();
B = B - op1;
COND_SET_FLAG_N(B);
COND_SET_FLAG_C(B);
condevalVs(B, op1);
B &= 0xFF;
COND_SET_FLAG_Z(B);
break;
case 0xC1: /* CMP B imm */
op1 = get_dir_addr();
lo = B - op1;
COND_SET_FLAG_N(lo);
COND_SET_FLAG_C(lo);
condevalVs(B, op1);
lo &= 0xFF;
COND_SET_FLAG_Z(lo);
break;
case 0xC2: /* SBC B imm */
op1 = get_dir_addr();
B = B - op1 - get_flag(CF);
COND_SET_FLAG_N(B);
COND_SET_FLAG_C(B);
condevalVs(B, op1);
B &= 0xFF;
COND_SET_FLAG_Z(B);
break;
case 0xC4: /* AND B imm */
B = (B & get_dir_addr()) & 0xFF;
CLR_FLAG(VF);
COND_SET_FLAG_N(B);
COND_SET_FLAG_Z(B);
break;
case 0xC5: /* BIT B imm */
lo = (B & get_dir_addr()) & 0xFF;
CLR_FLAG(VF);
COND_SET_FLAG_N(lo);
COND_SET_FLAG_Z(lo);
break;
case 0xC6: /* LDA B imm */
B = get_dir_addr();
CLR_FLAG(VF);
COND_SET_FLAG_N(B);
COND_SET_FLAG_Z(B);
break;
case 0xC8: /* EOR B imm */
B = (B ^ get_dir_addr()) & 0xFF;
CLR_FLAG(VF);
COND_SET_FLAG_N(B);
COND_SET_FLAG_Z(B);
break;
case 0xC9: /* ADC B imm */
op1 = get_dir_addr();
B = B + op1 + get_flag(CF);
COND_SET_FLAG_H(B);
COND_SET_FLAG_N(B);
COND_SET_FLAG_C(B);
condevalVa(B, op1);
B &= 0xFF;
COND_SET_FLAG_Z(B);
break;
case 0xCA: /* ORA B imm */
B = (B | get_dir_addr()) & 0xFF;
CLR_FLAG(VF);
COND_SET_FLAG_N(B);
COND_SET_FLAG_Z(B);
break;
case 0xCB: /* ADD B imm */
op1 = get_dir_addr();
B = B + op1;
COND_SET_FLAG_H(B);
COND_SET_FLAG_N(B);
COND_SET_FLAG_C(B);
condevalVa(B, op1);
B &= 0xFF;
COND_SET_FLAG_Z(B);
break;
case 0xCE: /* LDX imm */
IX = get_ext_addr();
COND_SET_FLAG_N(IX >> 8);
COND_SET_FLAG_Z(IX);
CLR_FLAG(VF);
break;
case 0xD0: /* SUB B dir */
op1 = get_dir_val();
B = B - op1;
COND_SET_FLAG_N(B);
COND_SET_FLAG_C(B);
condevalVs(B, op1);
B &= 0xFF;
COND_SET_FLAG_Z(B);
break;
case 0xD1: /* CMP B dir */
op1 = get_dir_val();
lo = B - op1;
COND_SET_FLAG_N(lo);
COND_SET_FLAG_Z(lo);
COND_SET_FLAG_C(lo);
condevalVs(B, op1);
break;
case 0xD2: /* SBC B dir */
op1 = get_dir_val();
B = B - op1 - get_flag(CF);
COND_SET_FLAG_N(B);
COND_SET_FLAG_C(B);
condevalVs(B, op1);
B &= 0xFF;
COND_SET_FLAG_Z(B);
break;
case 0xD4: /* AND B dir */
B = (B & get_dir_val()) & 0xFF;
CLR_FLAG(VF);
COND_SET_FLAG_N(B);
COND_SET_FLAG_Z(B);
break;
case 0xD5: /* BIT B dir */
lo = (B & get_dir_val()) & 0xFF;
CLR_FLAG(VF);
COND_SET_FLAG_N(lo);
COND_SET_FLAG_Z(lo);
break;
case 0xD6: /* LDA B dir */
B = get_dir_val();
CLR_FLAG(VF);
COND_SET_FLAG_N(B);
COND_SET_FLAG_Z(B);
break;
case 0xD7: /* STA B dir */
CPU_BD_put_mbyte(get_dir_addr(), B);
CLR_FLAG(VF);
COND_SET_FLAG_N(B);
COND_SET_FLAG_Z(B);
break;
case 0xD8: /* EOR B dir */
B = (B ^ get_dir_val()) & 0xFF;
CLR_FLAG(VF);
COND_SET_FLAG_N(B);
COND_SET_FLAG_Z(B);
break;
case 0xD9: /* ADC B dir */
op1 = get_dir_val();
B = B + op1 + get_flag(CF);
COND_SET_FLAG_H(B);
COND_SET_FLAG_N(B);
COND_SET_FLAG_C(B);
condevalVa(B, op1);
B &= 0xFF;
COND_SET_FLAG_Z(B);
break;
case 0xDA: /* ORA B dir */
B = (B | get_dir_val()) & 0xFF;
CLR_FLAG(VF);
COND_SET_FLAG_N(B);
COND_SET_FLAG_Z(B);
break;
case 0xDB: /* ADD B dir */
op1 = get_dir_val();
B = B + op1;
COND_SET_FLAG_H(B);
COND_SET_FLAG_N(B);
COND_SET_FLAG_C(B);
condevalVa(B, op1);
B &= 0xFF;
COND_SET_FLAG_Z(B);
break;
case 0xDE: /* LDX dir */
IX = CPU_BD_get_mword(get_dir_addr());
COND_SET_FLAG_N(IX >> 8);
COND_SET_FLAG_Z(IX);
CLR_FLAG(VF);
break;
case 0xDF: /* STX dir */
CPU_BD_put_mword(get_dir_addr(), IX);
COND_SET_FLAG_N(IX >> 8);
COND_SET_FLAG_Z(IX);
CLR_FLAG(VF);
break;
case 0xE0: /* SUB B ind */
op1 = get_indir_val();
B = B - op1;
COND_SET_FLAG_N(B);
COND_SET_FLAG_C(B);
condevalVs(B, op1);
B &= 0xFF;
COND_SET_FLAG_Z(B);
break;
case 0xE1: /* CMP B ind */
op1 = get_indir_val();
lo = B - op1;
COND_SET_FLAG_N(lo);
COND_SET_FLAG_C(lo);
condevalVs(B, op1);
lo &= 0xFF;
COND_SET_FLAG_Z(lo);
break;
case 0xE2: /* SBC B ind */
op1 = get_indir_val();
B = B - op1 - get_flag(CF);
COND_SET_FLAG_N(B);
COND_SET_FLAG_C(B);
condevalVs(B, op1);
B &= 0xFF;
COND_SET_FLAG_Z(B);
break;
case 0xE4: /* AND B ind */
B = (B & get_indir_val()) & 0xFF;
CLR_FLAG(VF);
COND_SET_FLAG_N(B);
COND_SET_FLAG_Z(B);
break;
case 0xE5: /* BIT B ind */
lo = (B & get_indir_val()) & 0xFF;
CLR_FLAG(VF);
COND_SET_FLAG_N(lo);
COND_SET_FLAG_Z(lo);
break;
case 0xE6: /* LDA B ind */
B = get_indir_val();
CLR_FLAG(VF);
COND_SET_FLAG_N(B);
COND_SET_FLAG_Z(B);
break;
case 0xE7: /* STA B ind */
CPU_BD_put_mbyte(get_indir_addr(), B);
CLR_FLAG(VF);
COND_SET_FLAG_N(B);
COND_SET_FLAG_Z(B);
break;
case 0xE8: /* EOR B ind */
B = (B ^ get_indir_val()) & 0xFF;
CLR_FLAG(VF);
COND_SET_FLAG_N(B);
COND_SET_FLAG_Z(B);
break;
case 0xE9: /* ADC B ind */
op1 = get_indir_val();
B = B + op1 + get_flag(CF);
COND_SET_FLAG_H(B);
COND_SET_FLAG_N(B);
COND_SET_FLAG_C(B);
condevalVa(B, op1);
B &= 0xFF;
COND_SET_FLAG_Z(B);
break;
case 0xEA: /* ORA B ind */
B = (B | get_indir_val()) & 0xFF;
CLR_FLAG(VF);
COND_SET_FLAG_N(B);
COND_SET_FLAG_Z(B);
break;
case 0xEB: /* ADD B ind */
op1 = get_indir_val();
B = B + op1;
COND_SET_FLAG_H(B);
COND_SET_FLAG_N(B);
COND_SET_FLAG_C(B);
condevalVa(B, op1);
B &= 0xFF;
COND_SET_FLAG_Z(B);
break;
case 0xEE: /* LDX ind */
IX = CPU_BD_get_mword(get_indir_addr());
COND_SET_FLAG_N(IX >> 8);
COND_SET_FLAG_Z(IX);
CLR_FLAG(VF);
break;
case 0xEF: /* STX ind */
CPU_BD_put_mword(get_indir_addr(), IX);
COND_SET_FLAG_N(IX >> 8);
COND_SET_FLAG_Z(IX);
CLR_FLAG(VF);
break;
case 0xF0: /* SUB B ext */
op1 = get_ext_val();
B = B - op1;
COND_SET_FLAG_N(B);
COND_SET_FLAG_C(B);
condevalVs(B, op1);
B &= 0xFF;
COND_SET_FLAG_Z(B);
break;
case 0xF1: /* CMP B ext */
op1 = get_ext_val();
lo = B - op1;
COND_SET_FLAG_N(lo);
COND_SET_FLAG_C(lo);
condevalVs(B, op1);
lo &= 0xFF;
COND_SET_FLAG_Z(lo);
break;
case 0xF2: /* SBC B ext */
op1 = get_ext_val();
B = B - op1 - get_flag(CF);
COND_SET_FLAG_N(B);
COND_SET_FLAG_C(B);
condevalVs(B, op1);
B &= 0xFF;
COND_SET_FLAG_Z(B);
break;
case 0xF4: /* AND B ext */
B = (B & get_ext_val()) & 0xFF;
CLR_FLAG(VF);
COND_SET_FLAG_N(B);
COND_SET_FLAG_Z(B);
break;
case 0xF5: /* BIT B ext */
lo = (B & get_ext_val()) & 0xFF;
CLR_FLAG(VF);
COND_SET_FLAG_N(lo);
COND_SET_FLAG_Z(lo);
break;
case 0xF6: /* LDA B ext */
B = get_ext_val();
CLR_FLAG(VF);
COND_SET_FLAG_N(B);
COND_SET_FLAG_Z(B);
break;
case 0xF7: /* STA B ext */
CPU_BD_put_mbyte(get_ext_addr(), B);
CLR_FLAG(VF);
COND_SET_FLAG_N(B);
COND_SET_FLAG_Z(B);
break;
case 0xF8: /* EOR B ext */
B = (B ^ get_ext_val()) & 0xFF;
CLR_FLAG(VF);
COND_SET_FLAG_N(B);
COND_SET_FLAG_Z(B);
break;
case 0xF9: /* ADC B ext */
op1 = get_ext_val();
B = B + op1 + get_flag(CF);
COND_SET_FLAG_H(B);
COND_SET_FLAG_N(B);
COND_SET_FLAG_C(B);
condevalVa(B, op1);
B &= 0xFF;
COND_SET_FLAG_Z(B);
break;
case 0xFA: /* ORA B ext */
B = (B | get_ext_val()) & 0xFF;
CLR_FLAG(VF);
COND_SET_FLAG_N(B);
COND_SET_FLAG_Z(B);
break;
case 0xFB: /* ADD B ext */
op1 = get_ext_val();
B = B + op1;
COND_SET_FLAG_H(B);
COND_SET_FLAG_N(B);
COND_SET_FLAG_C(B);
condevalVa(B, op1);
B &= 0xFF;
COND_SET_FLAG_Z(B);
break;
case 0xFE: /* LDX ext */
IX = CPU_BD_get_mword(get_ext_addr());
COND_SET_FLAG_N(IX >> 8);
COND_SET_FLAG_Z(IX);
CLR_FLAG(VF);
break;
case 0xFF: /* STX ext */
CPU_BD_put_mword(get_ext_addr(), IX);
COND_SET_FLAG_N(IX >> 8);
COND_SET_FLAG_Z(IX);
CLR_FLAG(VF);
break;
default: { /* Unassigned */
if (m6800_unit.flags & UNIT_OPSTOP) {
reason = STOP_OPCODE;
PC--;
}
break;
}
}
}
/* Simulation halted - lets dump all the registers! */
dump_regs();
saved_PC = PC;
return reason;
}
/* dump the working registers */
void dump_regs(void)
{
printf("\r\nPC=%04X SP=%04X IX=%04X ", PC, SP, IX);
printf("A=%02X B=%02X CCR=%02X", A, B, CCR);
}
void dump_regs1(void)
{
printf("PC=%04X SP=%04X IX=%04X ", PC, SP, IX);
printf("A=%02X B=%02X CCR=%02X\n", A, B, CCR);
}
/* fetch an instruction or byte */
int32 fetch_byte(int32 flag)
{
uint8 val;
val = CPU_BD_get_mbyte(PC) & 0xFF; /* fetch byte */
if (m6800_dev.dctrl & DEBUG_asm) { /* display source code */
switch (flag) {
case 0: /* opcode fetch */
printf("\n%04X %s", PC, opcode[val]);
break;
case 1: /* byte operand fetch */
printf("0%02XH", val);
break;
}
}
PC = (PC + 1) & ADDRMASK; /* increment PC */
return val;
}
/* fetch a word */
int32 fetch_word(void)
{
uint16 val;
val = CPU_BD_get_mbyte(PC) << 8; /* fetch high byte */
val |= CPU_BD_get_mbyte(PC + 1) & 0xFF; /* fetch low byte */
if (m6800_dev.dctrl & DEBUG_asm)
printf("0%04XH", val);
PC = (PC + 2) & ADDRMASK; /* increment PC */
return val;
}
/* push a byte to the stack */
void push_byte(uint8 val)
{
CPU_BD_put_mbyte(SP, val & 0xFF);
SP = (SP - 1) & ADDRMASK;
}
/* push a word to the stack */
void push_word(uint16 val)
{
push_byte(val & 0xFF);
push_byte(val >> 8);
}
/* pop a byte from the stack */
uint8 pop_byte(void)
{
register uint8 res;
SP = (SP + 1) & ADDRMASK;
res = CPU_BD_get_mbyte(SP);
return res;
}
/* pop a word from the stack */
uint16 pop_word(void)
{
register uint16 res;
res = pop_byte() << 8;
res |= pop_byte();
return res;
}
/* this routine does the jump to relative offset if the condition is
met. Otherwise, execution continues at the current PC. */
void go_rel(int32 cond)
{
int32 temp;
temp = get_rel_addr();
if (cond)
PC += temp;
PC &= ADDRMASK;
}
/* returns the relative offset sign-extended */
int32 get_rel_addr(void)
{
int32 temp;
temp = fetch_byte(1);
if (temp & 0x80)
temp |= 0xFF00;
return temp & ADDRMASK;
}
/* returns the value at the direct address pointed to by PC */
int32 get_dir_val(void)
{
return CPU_BD_get_mbyte(get_dir_addr());
}
/* returns the direct address pointed to by PC */
int32 get_dir_addr(void)
{
int32 temp;
temp = fetch_byte(1);
return temp & 0xFF;
}
/* returns the value at the indirect address pointed to by PC */
int32 get_indir_val(void)
{
return CPU_BD_get_mbyte(get_indir_addr());
}
/* returns the indirect address pointed to by PC or immediate byte */
int32 get_indir_addr(void)
{
int32 temp;
temp = (fetch_byte(1) + IX) & ADDRMASK;
return temp;
}
/* returns the value at the extended address pointed to by PC */
int32 get_ext_val(void)
{
return CPU_BD_get_mbyte(get_ext_addr());
}
/* returns the extended address pointed to by PC or immediate word */
int32 get_ext_addr(void)
{
int32 temp;
temp = fetch_word();
return temp;
}
/* return 1 for flag set or 0 for flag clear */
int32 get_flag(int32 flg)
{
if (CCR & flg)
return 1;
else
return 0;
}
/* test and set V for addition */
void condevalVa(int32 op1, int32 op2)
{
if (get_flag(CF)) {
COND_SET_FLAG_V(((op1 & 0x80) && (op2 & 0x80)) || (
((op1 & 0x80) == 0) && ((op2 & 0x80) == 0)));
}
}
/* test and set V for subtraction */
void condevalVs(int32 op1, int32 op2)
{
if (get_flag(CF)) {
COND_SET_FLAG_V(((op1 & 0x80) && ((op2 & 0x80) == 0)) ||
(((op1 & 0x80) == 0) && (op2 & 0x80)));
}
}
/* calls from the simulator */
/* Reset routine */
t_stat m6800_reset (DEVICE *dptr)
{
CCR = CCR_ALWAYS_ON | IF;
int_req = 0;
sim_brk_types = sim_brk_dflt = SWMASK ('E');
saved_PC = CPU_BD_get_mword(0xFFFE);
// if (saved_PC == 0xFFFF)
// printf("No EPROM image found - M6800 reset incomplete!\n");
// else
// printf("EPROM vector=%04X\n", saved_PC);
return SCPE_OK;
}
/* This is the dumper/loader. This command uses the -h to signify a
hex dump/load vice a binary one. If no address is given to load, it
takes the address from the hex record or the current PC for binary.
*/
t_stat 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) {
CPU_BD_put_mbyte(addr, i);
addr++;
cnt++;
} // end while
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
for M6800
*/
t_stat fprint_sym (FILE *of, t_addr addr, t_value *val, UNIT *uptr, int32 sw)
{
int32 i, inst, inst1;
if (sw & SWMASK ('D')) { // dump memory
for (i=0; i<16; i++)
fprintf(of, "%02X ", val[i]);
fprintf(of, " ");
for (i=0; i<16; i++)
if (isprint(val[i]))
fprintf(of, "%c", val[i]);
else
fprintf(of, ".");
return -15;
} else if (sw & SWMASK ('M')) { // dump instruction mnemonic
inst = val[0];
if (!oplen[inst]) { // invalid opcode
fprintf(of, "%02X", inst);
return 0;
}
inst1 = inst & 0xF0;
fprintf (of, "%s", opcode[inst]); // mnemonic
if (strlen(opcode[inst]) == 3)
fprintf(of, " ");
if (inst1 == 0x20 || inst == 0x8D) { // rel operand
inst1 = val[1];
if (val[1] & 0x80)
inst1 |= 0xFF00;
fprintf(of, " $%04X", (addr + inst1 + 2) & ADDRMASK);
} else if (inst1 == 0x80 || inst1 == 0xC0) { // imm operand
if ((inst & 0x0F) < 0x0C)
fprintf(of, " #$%02X", val[1]);
else
fprintf(of, " #$%02X%02X", val[1], val[2]);
} else if (inst1 == 0x60 || inst1 == 0xA0 || inst1 == 0xE0) // ind operand
fprintf(of, " %d,X", val[1]);
else if (inst1 == 0x70 || inst1 == 0xb0 || inst1 == 0xF0) // ext operand
fprintf(of, " $%02X%02X", val[1], val[2]);
return (-(oplen[inst] - 1));
} else
return SCPE_ARG;
}
/* 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
*/
t_stat parse_sym (char *cptr, t_addr addr, UNIT *uptr, t_value *val, int32 sw)
{
return (-2);
}
/* end of m6800.c */