raze-gles/libraries/game-music-emu/gme/Sap_Cpu.cpp
Christoph Oelckers 718112a8fe - added external libraries for music format playback and decompression from GZDoom.
Currently none of these is being used, but eventually they will, once more code gets ported over.
So it's better to have them right away and avoid editing the project file too much, only to revert that later.
2019-09-22 08:59:48 +02:00

1004 lines
19 KiB
C++

// Game_Music_Emu https://bitbucket.org/mpyne/game-music-emu/
#include "Sap_Cpu.h"
#include <limits.h>
#include "blargg_endian.h"
//#include "nes_cpu_log.h"
/* Copyright (C) 2003-2006 Shay Green. This module is free software; you
can redistribute it and/or modify it under the terms of the GNU Lesser
General Public License as published by the Free Software Foundation; either
version 2.1 of the License, or (at your option) any later version. This
module 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 Lesser General Public License for more
details. You should have received a copy of the GNU Lesser General Public
License along with this module; if not, write to the Free Software Foundation,
Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA */
#define FLUSH_TIME() (void) (s.time = s_time)
#define CACHE_TIME() (void) (s_time = s.time)
#include "sap_cpu_io.h"
#ifndef CPU_DONE
#define CPU_DONE( cpu, time, result_out ) { result_out = -1; }
#endif
#include "blargg_source.h"
int const st_n = 0x80;
int const st_v = 0x40;
int const st_r = 0x20;
int const st_b = 0x10;
int const st_d = 0x08;
int const st_i = 0x04;
int const st_z = 0x02;
int const st_c = 0x01;
void Sap_Cpu::reset( void* new_mem )
{
check( state == &state_ );
state = &state_;
mem = (uint8_t*) new_mem;
r.status = st_i;
r.sp = 0xFF;
r.pc = 0;
r.a = 0;
r.x = 0;
r.y = 0;
state_.time = 0;
state_.base = 0;
irq_time_ = future_sap_time;
end_time_ = future_sap_time;
blargg_verify_byte_order();
}
#define TIME (s_time + s.base)
#define READ( addr ) CPU_READ( this, (addr), TIME )
#define WRITE( addr, data ) {CPU_WRITE( this, (addr), (data), TIME );}
#define READ_LOW( addr ) (mem [int (addr)])
#define WRITE_LOW( addr, data ) (void) (READ_LOW( addr ) = (data))
#define READ_PROG( addr ) (READ_LOW( addr ))
#define SET_SP( v ) (sp = ((v) + 1) | 0x100)
#define GET_SP() ((sp - 1) & 0xFF)
#define PUSH( v ) ((sp = (sp - 1) | 0x100), WRITE_LOW( sp, v ))
bool Sap_Cpu::run( sap_time_t end_time )
{
bool illegal_encountered = false;
set_end_time( end_time );
state_t s = this->state_;
this->state = &s;
int32_t s_time = s.time;
uint8_t* const mem = this->mem; // cache
// registers
uint16_t pc = r.pc;
uint8_t a = r.a;
uint8_t x = r.x;
uint8_t y = r.y;
uint16_t sp;
SET_SP( r.sp );
// status flags
#define IS_NEG (nz & 0x8080)
#define CALC_STATUS( out ) do {\
out = status & (st_v | st_d | st_i);\
out |= ((nz >> 8) | nz) & st_n;\
out |= c >> 8 & st_c;\
if ( !(nz & 0xFF) ) out |= st_z;\
} while ( 0 )
#define SET_STATUS( in ) do {\
status = in & (st_v | st_d | st_i);\
nz = in << 8;\
c = nz;\
nz |= ~in & st_z;\
} while ( 0 )
uint8_t status;
uint16_t c; // carry set if (c & 0x100) != 0
uint16_t nz; // Z set if (nz & 0xFF) == 0, N set if (nz & 0x8080) != 0
{
uint8_t temp = r.status;
SET_STATUS( temp );
}
goto loop;
dec_clock_loop:
s_time--;
loop:
#ifndef NDEBUG
{
sap_time_t correct = end_time_;
if ( !(status & st_i) && correct > irq_time_ )
correct = irq_time_;
check( s.base == correct );
}
#endif
check( (unsigned) GET_SP() < 0x100 );
check( (unsigned) a < 0x100 );
check( (unsigned) x < 0x100 );
check( (unsigned) y < 0x100 );
uint8_t opcode = mem [pc];
pc++;
uint8_t const* instr = mem + pc;
static uint8_t const clock_table [256] =
{// 0 1 2 3 4 5 6 7 8 9 A B C D E F
0,6,2,8,3,3,5,5,3,2,2,2,4,4,6,6,// 0
3,5,2,8,4,4,6,6,2,4,2,7,4,4,7,7,// 1
6,6,2,8,3,3,5,5,4,2,2,2,4,4,6,6,// 2
3,5,2,8,4,4,6,6,2,4,2,7,4,4,7,7,// 3
6,6,2,8,3,3,5,5,3,2,2,2,3,4,6,6,// 4
3,5,2,8,4,4,6,6,2,4,2,7,4,4,7,7,// 5
6,6,2,8,3,3,5,5,4,2,2,2,5,4,6,6,// 6
3,5,2,8,4,4,6,6,2,4,2,7,4,4,7,7,// 7
2,6,2,6,3,3,3,3,2,2,2,2,4,4,4,4,// 8
3,6,2,6,4,4,4,4,2,5,2,5,5,5,5,5,// 9
2,6,2,6,3,3,3,3,2,2,2,2,4,4,4,4,// A
3,5,2,5,4,4,4,4,2,4,2,4,4,4,4,4,// B
2,6,2,8,3,3,5,5,2,2,2,2,4,4,6,6,// C
3,5,2,8,4,4,6,6,2,4,2,7,4,4,7,7,// D
2,6,2,8,3,3,5,5,2,2,2,2,4,4,6,6,// E
3,5,2,8,4,4,6,6,2,4,2,7,4,4,7,7 // F
}; // 0x00 was 7
uint16_t data;
data = clock_table [opcode];
if ( (s_time += data) >= 0 )
goto possibly_out_of_time;
almost_out_of_time:
data = *instr;
#ifdef NES_CPU_LOG_H
nes_cpu_log( "cpu_log", pc - 1, opcode, instr [0], instr [1] );
#endif
switch ( opcode )
{
possibly_out_of_time:
if ( s_time < (int) data )
goto almost_out_of_time;
s_time -= data;
goto out_of_time;
// Macros
#define GET_MSB() (instr [1])
#define ADD_PAGE() (pc++, data += 0x100 * GET_MSB())
#define GET_ADDR() GET_LE16( instr )
#define NO_PAGE_CROSSING( lsb )
#define HANDLE_PAGE_CROSSING( lsb ) s_time += (lsb) >> 8;
#define INC_DEC_XY( reg, n ) reg = uint8_t (nz = reg + n); goto loop;
#define IND_Y( cross, out ) {\
uint16_t temp = READ_LOW( data ) + y;\
out = temp + 0x100 * READ_LOW( uint8_t (data + 1) );\
cross( temp );\
}
#define IND_X( out ) {\
uint16_t temp = data + x;\
out = 0x100 * READ_LOW( uint8_t (temp + 1) ) + READ_LOW( uint8_t (temp) );\
}
#define ARITH_ADDR_MODES( op )\
case op - 0x04: /* (ind,x) */\
IND_X( data )\
goto ptr##op;\
case op + 0x0C: /* (ind),y */\
IND_Y( HANDLE_PAGE_CROSSING, data )\
goto ptr##op;\
case op + 0x10: /* zp,X */\
data = uint8_t (data + x);\
case op + 0x00: /* zp */\
data = READ_LOW( data );\
goto imm##op;\
case op + 0x14: /* abs,Y */\
data += y;\
goto ind##op;\
case op + 0x18: /* abs,X */\
data += x;\
ind##op:\
HANDLE_PAGE_CROSSING( data );\
case op + 0x08: /* abs */\
ADD_PAGE();\
ptr##op:\
FLUSH_TIME();\
data = READ( data );\
CACHE_TIME();\
case op + 0x04: /* imm */\
imm##op:
// TODO: more efficient way to handle negative branch that wraps PC around
#define BRANCH( cond )\
{\
int16_t offset = (int8_t) data;\
uint16_t extra_clock = (++pc & 0xFF) + offset;\
if ( !(cond) ) goto dec_clock_loop;\
pc += offset;\
s_time += extra_clock >> 8 & 1;\
goto loop;\
}
// Often-Used
case 0xB5: // LDA zp,x
a = nz = READ_LOW( uint8_t (data + x) );
pc++;
goto loop;
case 0xA5: // LDA zp
a = nz = READ_LOW( data );
pc++;
goto loop;
case 0xD0: // BNE
BRANCH( (uint8_t) nz );
case 0x20: { // JSR
uint16_t temp = pc + 1;
pc = GET_ADDR();
WRITE_LOW( 0x100 | (sp - 1), temp >> 8 );
sp = (sp - 2) | 0x100;
WRITE_LOW( sp, temp );
goto loop;
}
case 0x4C: // JMP abs
pc = GET_ADDR();
goto loop;
case 0xE8: // INX
INC_DEC_XY( x, 1 )
case 0x10: // BPL
BRANCH( !IS_NEG )
ARITH_ADDR_MODES( 0xC5 ) // CMP
nz = a - data;
pc++;
c = ~nz;
nz &= 0xFF;
goto loop;
case 0x30: // BMI
BRANCH( IS_NEG )
case 0xF0: // BEQ
BRANCH( !(uint8_t) nz );
case 0x95: // STA zp,x
data = uint8_t (data + x);
case 0x85: // STA zp
pc++;
WRITE_LOW( data, a );
goto loop;
case 0xC8: // INY
INC_DEC_XY( y, 1 )
case 0xA8: // TAY
y = a;
nz = a;
goto loop;
case 0x98: // TYA
a = y;
nz = y;
goto loop;
case 0xAD:{// LDA abs
unsigned addr = GET_ADDR();
pc += 2;
nz = READ( addr );
a = nz;
goto loop;
}
case 0x60: // RTS
pc = 1 + READ_LOW( sp );
pc += 0x100 * READ_LOW( 0x100 | (sp - 0xFF) );
sp = (sp - 0xFE) | 0x100;
goto loop;
{
uint16_t addr;
case 0x99: // STA abs,Y
addr = y + GET_ADDR();
pc += 2;
if ( addr <= 0x7FF )
{
WRITE_LOW( addr, a );
goto loop;
}
goto sta_ptr;
case 0x8D: // STA abs
addr = GET_ADDR();
pc += 2;
if ( addr <= 0x7FF )
{
WRITE_LOW( addr, a );
goto loop;
}
goto sta_ptr;
case 0x9D: // STA abs,X (slightly more common than STA abs)
addr = x + GET_ADDR();
pc += 2;
if ( addr <= 0x7FF )
{
WRITE_LOW( addr, a );
goto loop;
}
sta_ptr:
FLUSH_TIME();
WRITE( addr, a );
CACHE_TIME();
goto loop;
case 0x91: // STA (ind),Y
IND_Y( NO_PAGE_CROSSING, addr )
pc++;
goto sta_ptr;
case 0x81: // STA (ind,X)
IND_X( addr )
pc++;
goto sta_ptr;
}
case 0xA9: // LDA #imm
pc++;
a = data;
nz = data;
goto loop;
// common read instructions
{
uint16_t addr;
case 0xA1: // LDA (ind,X)
IND_X( addr )
pc++;
goto a_nz_read_addr;
case 0xB1:// LDA (ind),Y
addr = READ_LOW( data ) + y;
HANDLE_PAGE_CROSSING( addr );
addr += 0x100 * READ_LOW( (uint8_t) (data + 1) );
pc++;
a = nz = READ_PROG( addr );
if ( (addr ^ 0x8000) <= 0x9FFF )
goto loop;
goto a_nz_read_addr;
case 0xB9: // LDA abs,Y
HANDLE_PAGE_CROSSING( data + y );
addr = GET_ADDR() + y;
pc += 2;
a = nz = READ_PROG( addr );
if ( (addr ^ 0x8000) <= 0x9FFF )
goto loop;
goto a_nz_read_addr;
case 0xBD: // LDA abs,X
HANDLE_PAGE_CROSSING( data + x );
addr = GET_ADDR() + x;
pc += 2;
a = nz = READ_PROG( addr );
if ( (addr ^ 0x8000) <= 0x9FFF )
goto loop;
a_nz_read_addr:
FLUSH_TIME();
a = nz = READ( addr );
CACHE_TIME();
goto loop;
}
// Branch
case 0x50: // BVC
BRANCH( !(status & st_v) )
case 0x70: // BVS
BRANCH( status & st_v )
case 0xB0: // BCS
BRANCH( c & 0x100 )
case 0x90: // BCC
BRANCH( !(c & 0x100) )
// Load/store
case 0x94: // STY zp,x
data = uint8_t (data + x);
case 0x84: // STY zp
pc++;
WRITE_LOW( data, y );
goto loop;
case 0x96: // STX zp,y
data = uint8_t (data + y);
case 0x86: // STX zp
pc++;
WRITE_LOW( data, x );
goto loop;
case 0xB6: // LDX zp,y
data = uint8_t (data + y);
case 0xA6: // LDX zp
data = READ_LOW( data );
case 0xA2: // LDX #imm
pc++;
x = data;
nz = data;
goto loop;
case 0xB4: // LDY zp,x
data = uint8_t (data + x);
case 0xA4: // LDY zp
data = READ_LOW( data );
case 0xA0: // LDY #imm
pc++;
y = data;
nz = data;
goto loop;
case 0xBC: // LDY abs,X
data += x;
HANDLE_PAGE_CROSSING( data );
case 0xAC:{// LDY abs
unsigned addr = data + 0x100 * GET_MSB();
pc += 2;
FLUSH_TIME();
y = nz = READ( addr );
CACHE_TIME();
goto loop;
}
case 0xBE: // LDX abs,y
data += y;
HANDLE_PAGE_CROSSING( data );
case 0xAE:{// LDX abs
unsigned addr = data + 0x100 * GET_MSB();
pc += 2;
FLUSH_TIME();
x = nz = READ( addr );
CACHE_TIME();
goto loop;
}
{
uint8_t temp;
case 0x8C: // STY abs
temp = y;
goto store_abs;
case 0x8E: // STX abs
temp = x;
store_abs:
unsigned addr = GET_ADDR();
pc += 2;
if ( addr <= 0x7FF )
{
WRITE_LOW( addr, temp );
goto loop;
}
FLUSH_TIME();
WRITE( addr, temp );
CACHE_TIME();
goto loop;
}
// Compare
case 0xEC:{// CPX abs
unsigned addr = GET_ADDR();
pc++;
FLUSH_TIME();
data = READ( addr );
CACHE_TIME();
goto cpx_data;
}
case 0xE4: // CPX zp
data = READ_LOW( data );
case 0xE0: // CPX #imm
cpx_data:
nz = x - data;
pc++;
c = ~nz;
nz &= 0xFF;
goto loop;
case 0xCC:{// CPY abs
unsigned addr = GET_ADDR();
pc++;
FLUSH_TIME();
data = READ( addr );
CACHE_TIME();
goto cpy_data;
}
case 0xC4: // CPY zp
data = READ_LOW( data );
case 0xC0: // CPY #imm
cpy_data:
nz = y - data;
pc++;
c = ~nz;
nz &= 0xFF;
goto loop;
// Logical
ARITH_ADDR_MODES( 0x25 ) // AND
nz = (a &= data);
pc++;
goto loop;
ARITH_ADDR_MODES( 0x45 ) // EOR
nz = (a ^= data);
pc++;
goto loop;
ARITH_ADDR_MODES( 0x05 ) // ORA
nz = (a |= data);
pc++;
goto loop;
case 0x2C:{// BIT abs
unsigned addr = GET_ADDR();
pc += 2;
status &= ~st_v;
nz = READ( addr );
status |= nz & st_v;
if ( a & nz )
goto loop;
nz <<= 8; // result must be zero, even if N bit is set
goto loop;
}
case 0x24: // BIT zp
nz = READ_LOW( data );
pc++;
status &= ~st_v;
status |= nz & st_v;
if ( a & nz )
goto loop;
nz <<= 8; // result must be zero, even if N bit is set
goto loop;
// Add/subtract
ARITH_ADDR_MODES( 0xE5 ) // SBC
case 0xEB: // unofficial equivalent
data ^= 0xFF;
goto adc_imm;
ARITH_ADDR_MODES( 0x65 ) // ADC
adc_imm: {
check( !(status & st_d) );
int16_t carry = c >> 8 & 1;
int16_t ov = (a ^ 0x80) + carry + (int8_t) data; // sign-extend
status &= ~st_v;
status |= ov >> 2 & 0x40;
c = nz = a + data + carry;
pc++;
a = (uint8_t) nz;
goto loop;
}
// Shift/rotate
case 0x4A: // LSR A
c = 0;
case 0x6A: // ROR A
nz = c >> 1 & 0x80;
c = a << 8;
nz |= a >> 1;
a = nz;
goto loop;
case 0x0A: // ASL A
nz = a << 1;
c = nz;
a = (uint8_t) nz;
goto loop;
case 0x2A: { // ROL A
nz = a << 1;
int16_t temp = c >> 8 & 1;
c = nz;
nz |= temp;
a = (uint8_t) nz;
goto loop;
}
case 0x5E: // LSR abs,X
data += x;
case 0x4E: // LSR abs
c = 0;
case 0x6E: // ROR abs
ror_abs: {
ADD_PAGE();
FLUSH_TIME();
int temp = READ( data );
nz = (c >> 1 & 0x80) | (temp >> 1);
c = temp << 8;
goto rotate_common;
}
case 0x3E: // ROL abs,X
data += x;
goto rol_abs;
case 0x1E: // ASL abs,X
data += x;
case 0x0E: // ASL abs
c = 0;
case 0x2E: // ROL abs
rol_abs:
ADD_PAGE();
nz = c >> 8 & 1;
FLUSH_TIME();
nz |= (c = READ( data ) << 1);
rotate_common:
pc++;
WRITE( data, (uint8_t) nz );
CACHE_TIME();
goto loop;
case 0x7E: // ROR abs,X
data += x;
goto ror_abs;
case 0x76: // ROR zp,x
data = uint8_t (data + x);
goto ror_zp;
case 0x56: // LSR zp,x
data = uint8_t (data + x);
case 0x46: // LSR zp
c = 0;
case 0x66: // ROR zp
ror_zp: {
int temp = READ_LOW( data );
nz = (c >> 1 & 0x80) | (temp >> 1);
c = temp << 8;
goto write_nz_zp;
}
case 0x36: // ROL zp,x
data = uint8_t (data + x);
goto rol_zp;
case 0x16: // ASL zp,x
data = uint8_t (data + x);
case 0x06: // ASL zp
c = 0;
case 0x26: // ROL zp
rol_zp:
nz = c >> 8 & 1;
nz |= (c = READ_LOW( data ) << 1);
goto write_nz_zp;
// Increment/decrement
case 0xCA: // DEX
INC_DEC_XY( x, -1 )
case 0x88: // DEY
INC_DEC_XY( y, -1 )
case 0xF6: // INC zp,x
data = uint8_t (data + x);
case 0xE6: // INC zp
nz = 1;
goto add_nz_zp;
case 0xD6: // DEC zp,x
data = uint8_t (data + x);
case 0xC6: // DEC zp
nz = (uint16_t) -1;
add_nz_zp:
nz += READ_LOW( data );
write_nz_zp:
pc++;
WRITE_LOW( data, nz );
goto loop;
case 0xFE: // INC abs,x
data = x + GET_ADDR();
goto inc_ptr;
case 0xEE: // INC abs
data = GET_ADDR();
inc_ptr:
nz = 1;
goto inc_common;
case 0xDE: // DEC abs,x
data = x + GET_ADDR();
goto dec_ptr;
case 0xCE: // DEC abs
data = GET_ADDR();
dec_ptr:
nz = (uint16_t) -1;
inc_common:
FLUSH_TIME();
nz += READ( data );
pc += 2;
WRITE( data, (uint8_t) nz );
CACHE_TIME();
goto loop;
// Transfer
case 0xAA: // TAX
x = a;
nz = a;
goto loop;
case 0x8A: // TXA
a = x;
nz = x;
goto loop;
case 0x9A: // TXS
SET_SP( x ); // verified (no flag change)
goto loop;
case 0xBA: // TSX
x = nz = GET_SP();
goto loop;
// Stack
case 0x48: // PHA
PUSH( a ); // verified
goto loop;
case 0x68: // PLA
a = nz = READ_LOW( sp );
sp = (sp - 0xFF) | 0x100;
goto loop;
case 0x40:{// RTI
uint8_t temp = READ_LOW( sp );
pc = READ_LOW( 0x100 | (sp - 0xFF) );
pc |= READ_LOW( 0x100 | (sp - 0xFE) ) * 0x100;
sp = (sp - 0xFD) | 0x100;
data = status;
SET_STATUS( temp );
this->r.status = status; // update externally-visible I flag
if ( (data ^ status) & st_i )
{
sap_time_t new_time = end_time_;
if ( !(status & st_i) && new_time > irq_time_ )
new_time = irq_time_;
blargg_long delta = s.base - new_time;
s.base = new_time;
s_time += delta;
}
goto loop;
}
case 0x28:{// PLP
uint8_t temp = READ_LOW( sp );
sp = (sp - 0xFF) | 0x100;
uint8_t changed = status ^ temp;
SET_STATUS( temp );
if ( !(changed & st_i) )
goto loop; // I flag didn't change
if ( status & st_i )
goto handle_sei;
goto handle_cli;
}
case 0x08: { // PHP
uint8_t temp;
CALC_STATUS( temp );
PUSH( temp | (st_b | st_r) );
goto loop;
}
case 0x6C:{// JMP (ind)
data = GET_ADDR();
pc = READ_PROG( data );
data = (data & 0xFF00) | ((data + 1) & 0xFF);
pc |= 0x100 * READ_PROG( data );
goto loop;
}
case 0x00: // BRK
goto handle_brk;
// Flags
case 0x38: // SEC
c = (uint16_t) ~0;
goto loop;
case 0x18: // CLC
c = 0;
goto loop;
case 0xB8: // CLV
status &= ~st_v;
goto loop;
case 0xD8: // CLD
status &= ~st_d;
goto loop;
case 0xF8: // SED
status |= st_d;
goto loop;
case 0x58: // CLI
if ( !(status & st_i) )
goto loop;
status &= ~st_i;
handle_cli: {
this->r.status = status; // update externally-visible I flag
blargg_long delta = s.base - irq_time_;
if ( delta <= 0 )
{
if ( TIME < irq_time_ )
goto loop;
goto delayed_cli;
}
s.base = irq_time_;
s_time += delta;
if ( s_time < 0 )
goto loop;
if ( delta >= s_time + 1 )
{
// delayed irq until after next instruction
s.base += s_time + 1;
s_time = -1;
irq_time_ = s.base; // TODO: remove, as only to satisfy debug check in loop
goto loop;
}
delayed_cli:
debug_printf( "Delayed CLI not emulated\n" );
goto loop;
}
case 0x78: // SEI
if ( status & st_i )
goto loop;
status |= st_i;
handle_sei: {
this->r.status = status; // update externally-visible I flag
blargg_long delta = s.base - end_time_;
s.base = end_time_;
s_time += delta;
if ( s_time < 0 )
goto loop;
debug_printf( "Delayed SEI not emulated\n" );
goto loop;
}
// Unofficial
// SKW - Skip word
case 0x1C: case 0x3C: case 0x5C: case 0x7C: case 0xDC: case 0xFC:
HANDLE_PAGE_CROSSING( data + x );
case 0x0C:
pc++;
// SKB - Skip byte
case 0x74: case 0x04: case 0x14: case 0x34: case 0x44: case 0x54: case 0x64:
case 0x80: case 0x82: case 0x89: case 0xC2: case 0xD4: case 0xE2: case 0xF4:
pc++;
goto loop;
// NOP
case 0xEA: case 0x1A: case 0x3A: case 0x5A: case 0x7A: case 0xDA: case 0xFA:
goto loop;
// Unimplemented
// halt
//case 0x02: case 0x12: case 0x22: case 0x32: case 0x42: case 0x52:
//case 0x62: case 0x72: case 0x92: case 0xB2: case 0xD2: case 0xF2:
default:
illegal_encountered = true;
pc--;
goto stop;
}
assert( false );
int result_;
handle_brk:
if ( (pc - 1) >= idle_addr )
goto idle_done;
pc++;
result_ = 4;
debug_printf( "BRK executed\n" );
interrupt:
{
s_time += 7;
WRITE_LOW( 0x100 | (sp - 1), pc >> 8 );
WRITE_LOW( 0x100 | (sp - 2), pc );
pc = GET_LE16( &READ_PROG( 0xFFFA ) + result_ );
sp = (sp - 3) | 0x100;
uint8_t temp;
CALC_STATUS( temp );
temp |= st_r;
if ( result_ )
temp |= st_b; // TODO: incorrectly sets B flag for IRQ
WRITE_LOW( sp, temp );
status &= ~st_d;
status |= st_i;
this->r.status = status; // update externally-visible I flag
blargg_long delta = s.base - end_time_;
s.base = end_time_;
s_time += delta;
goto loop;
}
idle_done:
//s_time = 0;
pc--;
goto stop;
out_of_time:
pc--;
FLUSH_TIME();
CPU_DONE( this, TIME, result_ );
CACHE_TIME();
if ( result_ >= 0 )
goto interrupt;
if ( s_time < 0 )
goto loop;
stop:
s.time = s_time;
r.pc = pc;
r.sp = GET_SP();
r.a = a;
r.x = x;
r.y = y;
{
uint8_t temp;
CALC_STATUS( temp );
r.status = temp;
}
this->state_ = s;
this->state = &this->state_;
return illegal_encountered;
}