auto CPU::timer_step(unsigned clocks) -> void {
  for(unsigned c = 0; c < clocks; c++) {
    for(unsigned n = 0; n < 4; n++) {
      auto& timer = regs.timer[n];

      if(timer.pending) {
        timer.pending = false;
        if(timer.control.enable == 1) {
          timer.period = timer.reload;
        }
        continue;
      }

      if(timer.control.enable == false || timer.control.cascade == true) continue;

      static unsigned mask[] = {0, 63, 255, 1023};
      if((regs.clock & mask[timer.control.frequency]) == 0) {
        timer_increment(n);
      }
    }

    regs.clock++;
  }
}

auto CPU::timer_increment(unsigned n) -> void {
  auto& timer = regs.timer[n];
  if(++timer.period == 0) {
    timer.period = timer.reload;

    if(timer.control.irq) regs.irq.flag.timer[n] = 1;

    if(apu.fifo[0].timer == n) timer_fifo_run(0);
    if(apu.fifo[1].timer == n) timer_fifo_run(1);

    if(n < 3 && regs.timer[n + 1].control.enable && regs.timer[n + 1].control.cascade) {
      timer_increment(n + 1);
    }
  }
}

auto CPU::timer_fifo_run(unsigned n) -> void {
  apu.fifo[n].read();
  if(apu.fifo[n].size > 16) return;

  auto& dma = regs.dma[1 + n];
  if(dma.control.enable && dma.control.timingmode == 3) {
    dma.pending = true;
    dma.control.targetmode = 2;
    dma.control.size = 1;
    dma.run.length = 4;
  }
}