/* $Id$ */ /* @file * Tsunami I/O including PIC, PIT, RTC, DMA */ #include #include #include #include #include "base/trace.hh" #include "cpu/exec_context.hh" #include "dev/console.hh" #include "dev/tlaser_clock.hh" #include "dev/tsunami_io.hh" #include "dev/tsunamireg.h" #include "dev/tsunami.hh" #include "mem/functional_mem/memory_control.hh" #include "sim/builder.hh" #include "dev/tsunami_cchip.hh" using namespace std; #define UNIX_YEAR_OFFSET 52 // Timer Event for Periodic interrupt of RTC TsunamiIO::RTCEvent::RTCEvent(Tsunami* t) : Event(&mainEventQueue), tsunami(t) { DPRINTF(MC146818, "RTC Event Initilizing\n"); schedule(curTick + ticksPerSecond/RTC_RATE); } void TsunamiIO::RTCEvent::process() { DPRINTF(MC146818, "RTC Timer Interrupt\n"); schedule(curTick + ticksPerSecond/RTC_RATE); //Actually interrupt the processor here if (!tsunami->cchip->RTCInterrupting) { tsunami->cchip->misc |= 1 << 7; tsunami->cchip->RTCInterrupting = true; tsunami->intrctrl->post(0, TheISA::INTLEVEL_IRQ2, 0); } } const char * TsunamiIO::RTCEvent::description() { return "tsunami RTC 1024Hz interrupt"; } // Timer Event for PIT Timers TsunamiIO::ClockEvent::ClockEvent() : Event(&mainEventQueue) { DPRINTF(Tsunami, "Clock Event Initilizing\n"); mode = 0; } void TsunamiIO::ClockEvent::process() { DPRINTF(Tsunami, "Timer Interrupt\n"); if (mode == 0) status = 0x20; // set bit that linux is looking for else schedule(curTick + interval); } void TsunamiIO::ClockEvent::Program(int count) { DPRINTF(Tsunami, "Timer set to curTick + %d\n", count); // should be count * (cpufreq/pitfreq) interval = count * ticksPerSecond/1193180UL; schedule(curTick + interval); status = 0; } const char * TsunamiIO::ClockEvent::description() { return "tsunami 8254 Interval timer"; } void TsunamiIO::ClockEvent::ChangeMode(uint8_t md) { mode = md; } uint8_t TsunamiIO::ClockEvent::Status() { return status; } TsunamiIO::TsunamiIO(const string &name, Tsunami *t, time_t init_time, Addr addr, Addr mask, MemoryController *mmu) : MmapDevice(name, addr, mask, mmu), tsunami(t), rtc(t) { timerData = 0; set_time(init_time == 0 ? time(NULL) : init_time); uip = 1; picr = 0; picInterrupting = false; } void TsunamiIO::set_time(time_t t) { gmtime_r(&t, &tm); DPRINTFN("Real-time clock set to %s", asctime(&tm)); } Fault TsunamiIO::read(MemReqPtr req, uint8_t *data) { DPRINTF(Tsunami, "io read va=%#x size=%d IOPorrt=%#x\n", req->vaddr, req->size, req->vaddr & 0xfff); Addr daddr = (req->paddr & addr_mask); // ExecContext *xc = req->xc; // int cpuid = xc->cpu_id; switch(req->size) { case sizeof(uint8_t): switch(daddr) { case TSDEV_TMR_CTL: *(uint8_t*)data = timer2.Status(); return No_Fault; case TSDEV_RTC_DATA: switch(RTCAddress) { case RTC_CONTROL_REGISTERA: *(uint8_t*)data = uip << 7 | 0x26; uip = !uip; return No_Fault; case RTC_CONTROL_REGISTERB: // DM and 24/12 and UIE *(uint8_t*)data = 0x46; return No_Fault; case RTC_CONTROL_REGISTERC: // If we want to support RTC user access in linux // This won't work, but for now it's fine *(uint8_t*)data = 0x00; return No_Fault; case RTC_CONTROL_REGISTERD: panic("RTC Control Register D not implemented"); case RTC_SECOND: *(uint8_t *)data = tm.tm_sec; return No_Fault; case RTC_MINUTE: *(uint8_t *)data = tm.tm_min; return No_Fault; case RTC_HOUR: *(uint8_t *)data = tm.tm_hour; return No_Fault; case RTC_DAY_OF_WEEK: *(uint8_t *)data = tm.tm_wday; return No_Fault; case RTC_DAY_OF_MONTH: *(uint8_t *)data = tm.tm_mday; case RTC_MONTH: *(uint8_t *)data = tm.tm_mon + 1; return No_Fault; case RTC_YEAR: *(uint8_t *)data = tm.tm_year - UNIX_YEAR_OFFSET; return No_Fault; default: panic("Unknown RTC Address\n"); } default: panic("I/O Read - va%#x size %d\n", req->vaddr, req->size); } case sizeof(uint16_t): case sizeof(uint32_t): case sizeof(uint64_t): default: panic("I/O Read - invalid size - va %#x size %d\n", req->vaddr, req->size); } panic("I/O Read - va%#x size %d\n", req->vaddr, req->size); return No_Fault; } Fault TsunamiIO::write(MemReqPtr req, const uint8_t *data) { DPRINTF(Tsunami, "io write - va=%#x size=%d IOPort=%#x\n", req->vaddr, req->size, req->vaddr & 0xfff); Addr daddr = (req->paddr & addr_mask); switch(req->size) { case sizeof(uint8_t): switch(daddr) { case TSDEV_PIC1_MASK: mask1 = *(uint8_t*)data; if ((picr & mask1) && !picInterrupting) { picInterrupting = true; tsunami->cchip->postDRIR(uint64_t(1) << 55); DPRINTF(Tsunami, "posting pic interrupt to cchip\n"); } return No_Fault; case TSDEV_PIC2_MASK: mask2 = *(uint8_t*)data; //PIC2 Not implemented to interrupt return No_Fault; case TSDEV_DMA1_RESET: return No_Fault; case TSDEV_DMA2_RESET: return No_Fault; case TSDEV_DMA1_MODE: mode1 = *(uint8_t*)data; return No_Fault; case TSDEV_DMA2_MODE: mode2 = *(uint8_t*)data; return No_Fault; case TSDEV_DMA1_MASK: case TSDEV_DMA2_MASK: return No_Fault; case TSDEV_TMR_CTL: return No_Fault; case TSDEV_TMR2_CTL: if ((*(uint8_t*)data & 0x30) != 0x30) panic("Only L/M write supported\n"); switch(*(uint8_t*)data >> 6) { case 0: timer0.ChangeMode((*(uint8_t*)data & 0xF) >> 1); break; case 2: timer2.ChangeMode((*(uint8_t*)data & 0xF) >> 1); break; default: panic("Read Back Command not implemented\n"); } return No_Fault; case TSDEV_TMR2_DATA: /* two writes before we actually start the Timer so I set a flag in the timerData */ if(timerData & 0x1000) { timerData &= 0x1000; timerData += *(uint8_t*)data << 8; timer2.Program(timerData); } else { timerData = *(uint8_t*)data; timerData |= 0x1000; } return No_Fault; case TSDEV_TMR0_DATA: /* two writes before we actually start the Timer so I set a flag in the timerData */ if(timerData & 0x1000) { timerData &= 0x1000; timerData += *(uint8_t*)data << 8; timer0.Program(timerData); } else { timerData = *(uint8_t*)data; timerData |= 0x1000; } return No_Fault; case TSDEV_RTC_ADDR: RTCAddress = *(uint8_t*)data; return No_Fault; case TSDEV_RTC_DATA: panic("RTC Write not implmented (rtc.o won't work)\n"); default: panic("I/O Write - va%#x size %d\n", req->vaddr, req->size); } case sizeof(uint16_t): case sizeof(uint32_t): case sizeof(uint64_t): default: panic("I/O Write - invalid size - va %#x size %d\n", req->vaddr, req->size); } return No_Fault; } void TsunamiIO::postPIC(uint8_t bitvector) { //PIC2 Is not implemented, because nothing of interest there picr |= bitvector; if ((picr & mask1) && !picInterrupting) { picInterrupting = true; tsunami->cchip->postDRIR(uint64_t(1) << 55); DPRINTF(Tsunami, "posting pic interrupt to cchip\n"); } } void TsunamiIO::clearPIC(uint8_t bitvector) { //PIC2 Is not implemented, because nothing of interest there picr &= ~bitvector; if (!(picr & mask1)) { picInterrupting = false; tsunami->cchip->clearDRIR(uint64_t(1) << 55); DPRINTF(Tsunami, "clearing pic interrupt to cchip\n"); } } void TsunamiIO::serialize(std::ostream &os) { // code should be written } void TsunamiIO::unserialize(Checkpoint *cp, const std::string §ion) { //code should be written } BEGIN_DECLARE_SIM_OBJECT_PARAMS(TsunamiIO) SimObjectParam tsunami; Param time; SimObjectParam mmu; Param addr; Param mask; END_DECLARE_SIM_OBJECT_PARAMS(TsunamiIO) BEGIN_INIT_SIM_OBJECT_PARAMS(TsunamiIO) INIT_PARAM(tsunami, "Tsunami"), INIT_PARAM_DFLT(time, "System time to use " "(0 for actual time, default is 1/1/06", ULL(1136073600)), INIT_PARAM(mmu, "Memory Controller"), INIT_PARAM(addr, "Device Address"), INIT_PARAM(mask, "Address Mask") END_INIT_SIM_OBJECT_PARAMS(TsunamiIO) CREATE_SIM_OBJECT(TsunamiIO) { return new TsunamiIO(getInstanceName(), tsunami, time, addr, mask, mmu); } REGISTER_SIM_OBJECT("TsunamiIO", TsunamiIO)