#include #include #include #include #include #define IRQ_TIMER 0 extern "C" void timer_interrupt_entry(); extern "C" void timer_interrupt_handler(RegisterDump&); asm( ".globl timer_interrupt_entry \n" "timer_interrupt_entry: \n" " pusha\n" " pushw %ds\n" " pushw %es\n" " pushw %fs\n" " pushw %gs\n" " pushw %ss\n" " pushw %ss\n" " pushw %ss\n" " pushw %ss\n" " pushw %ss\n" " popw %ds\n" " popw %es\n" " popw %fs\n" " popw %gs\n" " mov %esp, %eax\n" " call timer_interrupt_handler\n" " popw %gs\n" " popw %gs\n" " popw %fs\n" " popw %es\n" " popw %ds\n" " popa\n" " iret\n"); static u32 s_ticks_this_second; static u32 s_seconds_since_boot; void timer_interrupt_handler(RegisterDump& regs) { IRQHandlerScope scope(IRQ_TIMER); if (++s_ticks_this_second >= TICKS_PER_SECOND) { // FIXME: Synchronize with the RTC somehow to prevent drifting apart. ++s_seconds_since_boot; s_ticks_this_second = 0; } Scheduler::timer_tick(regs); } namespace PIT { u32 ticks_this_second() { return s_ticks_this_second; } u32 seconds_since_boot() { return s_seconds_since_boot; } void initialize() { u16 timer_reload; IO::out8(PIT_CTL, TIMER0_SELECT | WRITE_WORD | MODE_SQUARE_WAVE); timer_reload = (BASE_FREQUENCY / TICKS_PER_SECOND); kprintf("PIT: %u Hz, square wave (%x)\n", TICKS_PER_SECOND, timer_reload); IO::out8(TIMER0_CTL, LSB(timer_reload)); IO::out8(TIMER0_CTL, MSB(timer_reload)); register_interrupt_handler(IRQ_VECTOR_BASE + IRQ_TIMER, timer_interrupt_entry); PIC::enable(IRQ_TIMER); } }