//called once every four clock cycles; //as NMI steps by scanlines (divisible by 4) and IRQ by PPU 4-cycle dots. // //ppu.(vh)counter(n) returns the value of said counters n-clocks before current time; //it is used to emulate hardware communication delay between opcode and interrupt units. auto CPU::pollInterrupts() -> void { //NMI hold if(status.nmi_hold) { status.nmi_hold = false; if(status.nmi_enabled) status.nmi_transition = true; } //NMI test bool nmi_valid = (vcounter(2) >= (!ppu.overscan() ? 225 : 240)); if(!status.nmi_valid && nmi_valid) { //0->1 edge sensitive transition status.nmi_line = true; status.nmi_hold = true; //hold /NMI for four cycles } else if(status.nmi_valid && !nmi_valid) { //1->0 edge sensitive transition status.nmi_line = false; } status.nmi_valid = nmi_valid; //IRQ hold status.irq_hold = false; if(status.irq_line) { if(status.virq_enabled || status.hirq_enabled) status.irq_transition = true; } //IRQ test bool irq_valid = (status.virq_enabled || status.hirq_enabled); if(irq_valid) { if((status.virq_enabled && vcounter(10) != (status.virq_pos)) || (status.hirq_enabled && hcounter(10) != (status.hirq_pos + 1) * 4) || (status.virq_pos && vcounter(6) == 0) //IRQs cannot trigger on last dot of field ) irq_valid = false; } if(!status.irq_valid && irq_valid) { //0->1 edge sensitive transition status.irq_line = true; status.irq_hold = true; //hold /IRQ for four cycles } status.irq_valid = irq_valid; } auto CPU::nmitimenUpdate(uint8 data) -> void { bool nmi_enabled = status.nmi_enabled; bool virq_enabled = status.virq_enabled; bool hirq_enabled = status.hirq_enabled; status.nmi_enabled = data & 0x80; status.virq_enabled = data & 0x20; status.hirq_enabled = data & 0x10; //0->1 edge sensitive transition if(!nmi_enabled && status.nmi_enabled && status.nmi_line) { status.nmi_transition = true; } //?->1 level sensitive transition if(status.virq_enabled && !status.hirq_enabled && status.irq_line) { status.irq_transition = true; } if(!status.virq_enabled && !status.hirq_enabled) { status.irq_line = false; status.irq_transition = false; } status.irq_lock = true; } auto CPU::rdnmi() -> bool { bool result = status.nmi_line; if(!status.nmi_hold) { status.nmi_line = false; } return result; } auto CPU::timeup() -> bool { bool result = status.irq_line; if(!status.irq_hold) { status.irq_line = false; status.irq_transition = false; } return result; } auto CPU::nmiTest() -> bool { if(!status.nmi_transition) return false; status.nmi_transition = false; regs.wai = false; return true; } auto CPU::irqTest() -> bool { if(!status.irq_transition && !regs.irq) return false; status.irq_transition = false; regs.wai = false; return !regs.p.i; }