mirror of
https://github.com/bsnes-emu/bsnes.git
synced 2025-02-24 07:02:27 +01:00
4e2eb23835
byuu says: Changelog: - added Cocoa target: higan can now be compiled for OS X Lion [Cydrak, byuu] - SNES/accuracy profile hires color blending improvements - fixes Marvelous text [AWJ] - fixed a slight bug in SNES/SA-1 VBR support caused by a typo - added support for multi-pass shaders that can load external textures (requires OpenGL 3.2+) - added game library path (used by ananke->Import Game) to Settings->Advanced - system profiles, shaders and cheats database can be stored in "all users" shared folders now (eg /usr/share on Linux) - all configuration files are in BML format now, instead of XML (much easier to read and edit this way) - main window supports drag-and-drop of game folders (but not game files / ZIP archives) - audio buffer clears when entering a modal loop on Windows (prevents audio repetition with DirectSound driver) - a substantial amount of code clean-up (probably the biggest refactoring to date) One highly desired target for this release was to default to the optimal drivers instead of the safest drivers, but because AMD drivers don't seem to like my OpenGL 3.2 driver, I've decided to postpone that. AMD has too big a market share. Hopefully with v093 officially released, we can get some public input on what AMD doesn't like.
227 lines
5.3 KiB
C++
227 lines
5.3 KiB
C++
//SUNSOFT-5B
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struct Sunsoft5B : Board {
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uint4 mmu_port;
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uint4 apu_port;
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uint8 prg_bank[4];
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uint8 chr_bank[8];
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uint2 mirror;
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bool irq_enable;
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bool irq_counter_enable;
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uint16 irq_counter;
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int16 dac[16];
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struct Pulse {
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bool disable;
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uint12 frequency;
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uint4 volume;
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uint16 counter; //12-bit countdown + 4-bit phase
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uint1 duty;
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uint4 output;
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void clock() {
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if(--counter == 0) {
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counter = frequency << 4;
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duty ^= 1;
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}
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output = duty ? volume : (uint4)0;
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if(disable) output = 0;
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}
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void reset() {
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disable = 1;
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frequency = 1;
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volume = 0;
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counter = 0;
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duty = 0;
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output = 0;
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}
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void serialize(serializer& s) {
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s.integer(disable);
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s.integer(frequency);
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s.integer(volume);
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s.integer(counter);
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s.integer(duty);
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s.integer(output);
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}
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} pulse[3];
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void main() {
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while(true) {
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if(scheduler.sync == Scheduler::SynchronizeMode::All) {
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scheduler.exit(Scheduler::ExitReason::SynchronizeEvent);
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}
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if(irq_counter_enable) {
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if(--irq_counter == 0xffff) {
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cpu.set_irq_line(irq_enable);
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}
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}
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pulse[0].clock();
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pulse[1].clock();
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pulse[2].clock();
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int16 output = dac[pulse[0].output] + dac[pulse[1].output] + dac[pulse[2].output];
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apu.set_sample(-output);
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tick();
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}
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}
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uint8 prg_read(unsigned addr) {
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if(addr < 0x6000) return cpu.mdr();
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uint8 bank = 0x3f; //((addr & 0xe000) == 0xe000
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if((addr & 0xe000) == 0x6000) bank = prg_bank[0];
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if((addr & 0xe000) == 0x8000) bank = prg_bank[1];
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if((addr & 0xe000) == 0xa000) bank = prg_bank[2];
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if((addr & 0xe000) == 0xc000) bank = prg_bank[3];
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bool ram_enable = bank & 0x80;
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bool ram_select = bank & 0x40;
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bank &= 0x3f;
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if(ram_select) {
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if(ram_enable == false) return cpu.mdr();
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return prgram.data[addr & 0x1fff];
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}
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addr = (bank << 13) | (addr & 0x1fff);
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return prgrom.read(addr);
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}
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void prg_write(unsigned addr, uint8 data) {
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if((addr & 0xe000) == 0x6000) {
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prgram.data[addr & 0x1fff] = data;
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}
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if(addr == 0x8000) {
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mmu_port = data & 0x0f;
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}
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if(addr == 0xa000) {
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switch(mmu_port) {
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case 0: chr_bank[0] = data; break;
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case 1: chr_bank[1] = data; break;
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case 2: chr_bank[2] = data; break;
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case 3: chr_bank[3] = data; break;
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case 4: chr_bank[4] = data; break;
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case 5: chr_bank[5] = data; break;
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case 6: chr_bank[6] = data; break;
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case 7: chr_bank[7] = data; break;
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case 8: prg_bank[0] = data; break;
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case 9: prg_bank[1] = data; break;
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case 10: prg_bank[2] = data; break;
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case 11: prg_bank[3] = data; break;
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case 12: mirror = data & 3; break;
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case 13:
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irq_enable = data & 0x80;
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irq_counter_enable = data & 0x01;
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if(irq_enable == 0) cpu.set_irq_line(0);
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break;
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case 14: irq_counter = (irq_counter & 0xff00) | (data << 0); break;
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case 15: irq_counter = (irq_counter & 0x00ff) | (data << 8); break;
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}
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}
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if(addr == 0xc000) {
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apu_port = data & 0x0f;
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}
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if(addr == 0xe000) {
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switch(apu_port) {
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case 0: pulse[0].frequency = (pulse[0].frequency & 0xff00) | (data << 0); break;
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case 1: pulse[0].frequency = (pulse[0].frequency & 0x00ff) | (data << 8); break;
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case 2: pulse[1].frequency = (pulse[1].frequency & 0xff00) | (data << 0); break;
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case 3: pulse[1].frequency = (pulse[1].frequency & 0x00ff) | (data << 8); break;
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case 4: pulse[2].frequency = (pulse[2].frequency & 0xff00) | (data << 0); break;
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case 5: pulse[2].frequency = (pulse[2].frequency & 0x00ff) | (data << 8); break;
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case 7:
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pulse[0].disable = data & 0x01;
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pulse[1].disable = data & 0x02;
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pulse[2].disable = data & 0x04;
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break;
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case 8: pulse[0].volume = data & 0x0f; break;
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case 9: pulse[1].volume = data & 0x0f; break;
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case 10: pulse[2].volume = data & 0x0f; break;
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}
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}
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}
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unsigned chr_addr(unsigned addr) {
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uint8 bank = (addr >> 10) & 7;
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return (chr_bank[bank] << 10) | (addr & 0x03ff);
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}
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unsigned ciram_addr(unsigned addr) {
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switch(mirror) {
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case 0: return ((addr & 0x0400) >> 0) | (addr & 0x03ff); //vertical
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case 1: return ((addr & 0x0800) >> 1) | (addr & 0x03ff); //horizontal
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case 2: return 0x0000 | (addr & 0x03ff); //first
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case 3: return 0x0400 | (addr & 0x03ff); //second
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}
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}
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uint8 chr_read(unsigned addr) {
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if(addr & 0x2000) return ppu.ciram_read(ciram_addr(addr));
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return Board::chr_read(chr_addr(addr));
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}
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void chr_write(unsigned addr, uint8 data) {
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if(addr & 0x2000) return ppu.ciram_write(ciram_addr(addr), data);
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return Board::chr_write(chr_addr(addr), data);
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}
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void power() {
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for(signed n = 0; n < 16; n++) {
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double volume = 1.0 / pow(2, 1.0 / 2 * (15 - n));
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dac[n] = volume * 8192.0;
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}
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}
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void reset() {
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mmu_port = 0;
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apu_port = 0;
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for(auto& n : prg_bank) n = 0;
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for(auto& n : chr_bank) n = 0;
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mirror = 0;
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irq_enable = 0;
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irq_counter_enable = 0;
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irq_counter = 0;
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pulse[0].reset();
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pulse[1].reset();
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pulse[2].reset();
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}
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void serialize(serializer& s) {
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Board::serialize(s);
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s.integer(mmu_port);
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s.integer(apu_port);
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s.array(prg_bank);
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s.array(chr_bank);
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s.integer(mirror);
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s.integer(irq_enable);
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s.integer(irq_counter_enable);
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s.integer(irq_counter);
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pulse[0].serialize(s);
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pulse[1].serialize(s);
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pulse[2].serialize(s);
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}
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Sunsoft5B(Markup::Node& document) : Board(document) {
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}
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};
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