/* * Copyright (C) 2002-2007 The DOSBox Team * * This program is free software; you can redistribute it and/or modify * it under the terms of the GNU General Public License as published by * the Free Software Foundation; either version 2 of the License, or * (at your option) any later version. * * This program is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. * * You should have received a copy of the GNU General Public License * along with this program; if not, write to the Free Software * Foundation, Inc., 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA. */ /* $Id: timer.cpp,v 1.44 2007/06/12 20:22:08 c2woody Exp $ */ #include #include "dosbox.h" #include "inout.h" #include "pic.h" #include "mem.h" #include "mixer.h" #include "timer.h" #include "setup.h" static INLINE void BIN2BCD(Bit16u& val) { Bit16u temp=val%10 + (((val/10)%10)<<4)+ (((val/100)%10)<<8) + (((val/1000)%10)<<12); val=temp; } static INLINE void BCD2BIN(Bit16u& val) { Bit16u temp= (val&0x0f) +((val>>4)&0x0f) *10 +((val>>8)&0x0f) *100 +((val>>12)&0x0f) *1000; val=temp; } struct PIT_Block { Bitu cntr; float delay; double start; Bit16u read_latch; Bit16u write_latch; Bit8u mode; Bit8u latch_mode; Bit8u read_state; Bit8u write_state; bool bcd; bool go_read_latch; bool new_mode; bool counterstatus_set; }; static PIT_Block pit[3]; static bool gate2; static Bit8u latched_timerstatus; // the timer status can not be overwritten until it is read or the timer was // reprogrammed. static bool latched_timerstatus_locked; static void PIT0_Event(Bitu /*val*/) { PIC_ActivateIRQ(0); if (pit[0].mode != 0) { pit[0].start += pit[0].delay; double error = pit[0].start - PIC_FullIndex(); PIC_AddEvent(PIT0_Event,(float)(pit[0].delay + error)); } } static bool counter_output(Bitu counter) { PIT_Block * p=&pit[counter]; double index=PIC_FullIndex()-p->start; switch (p->mode) { case 0: if (p->new_mode) return false; if (index>p->delay) return true; else return false; break; case 2: if (p->new_mode) return true; index=fmod(index,(double)p->delay); return index>0; case 3: if (p->new_mode) return true; index=fmod(index,(double)p->delay); return index*2delay; default: LOG(LOG_PIT,LOG_ERROR)("Illegal Mode %d for reading output",p->mode); return true; } } static void status_latch(Bitu counter) { // the timer status can not be overwritten until it is read or the timer was // reprogrammed. if(!latched_timerstatus_locked) { PIT_Block * p=&pit[counter]; latched_timerstatus=0; // Timer Status Word // 0: BCD // 1-3: Timer mode // 4-5: read/load mode // 6: "NULL" - this is 0 if "the counter value is in the counter" ;) // should rarely be 1 (i.e. on exotic modes) // 7: OUT - the logic level on the Timer output pin if(p->bcd)latched_timerstatus|=0x1; latched_timerstatus|=((p->mode&7)<<1); if((p->read_state==0)||(p->read_state==3)) latched_timerstatus|=0x30; else if(p->read_state==1) latched_timerstatus|=0x10; else if(p->read_state==2) latched_timerstatus|=0x20; if(counter_output(counter)) latched_timerstatus|=0x80; if(p->new_mode) latched_timerstatus|=0x40; // The first thing that is being read from this counter now is the // counter status. p->counterstatus_set=true; latched_timerstatus_locked=true; } } static void counter_latch(Bitu counter) { /* Fill the read_latch of the selected counter with current count */ PIT_Block * p=&pit[counter]; p->go_read_latch=false; //If gate2 is disabled don't update the read_latch if(counter == 2 && !gate2) return; double index=PIC_FullIndex()-p->start; switch (p->mode) { case 4: /* Software Triggered Strobe */ case 0: /* Interrupt on Terminal Count */ /* Counter keeps on counting after passing terminal count */ if (index>p->delay) { index-=p->delay; if(p->bcd) { index = fmod(index,(1000.0/PIT_TICK_RATE)*10000.0); p->read_latch = (Bit16u)(9999-index*(PIT_TICK_RATE/1000.0)); } else { index = fmod(index,(1000.0/PIT_TICK_RATE)*(double)0x10000); p->read_latch = (Bit16u)(0xffff-index*(PIT_TICK_RATE/1000.0)); } } else { p->read_latch=(Bit16u)(p->cntr-index*(PIT_TICK_RATE/1000.0)); } break; case 2: /* Rate Generator */ index=fmod(index,(double)p->delay); p->read_latch=(Bit16u)(p->cntr - (index/p->delay)*p->cntr); break; case 3: /* Square Wave Rate Generator */ index=fmod(index,(double)p->delay); index*=2; if (index>p->delay) index-=p->delay; p->read_latch=(Bit16u)(p->cntr - (index/p->delay)*p->cntr); // In mode 3 it never returns odd numbers LSB (if odd number is written 1 will be // subtracted on first clock and then always 2) // fixes "Corncob 3D" p->read_latch&=0xfffe; break; default: LOG(LOG_PIT,LOG_ERROR)("Illegal Mode %d for reading counter %d",p->mode,counter); p->read_latch=0xffff; break; } } static void write_latch(Bitu port,Bitu val,Bitu /*iolen*/) { //LOG(LOG_PIT,LOG_ERROR)("port %X write:%X state:%X",port,val,pit[port-0x40].write_state); Bitu counter=port-0x40; PIT_Block * p=&pit[counter]; if(p->bcd == true) BIN2BCD(p->write_latch); switch (p->write_state) { case 0: p->write_latch = p->write_latch | ((val & 0xff) << 8); p->write_state = 3; break; case 3: p->write_latch = val & 0xff; p->write_state = 0; break; case 1: p->write_latch = val & 0xff; break; case 2: p->write_latch = (val & 0xff) << 8; break; } if (p->bcd==true) BCD2BIN(p->write_latch); if (p->write_state != 0) { if (p->write_latch == 0) { if (p->bcd == false) p->cntr = 0x10000; else p->cntr=9999; } else p->cntr = p->write_latch; p->start=PIC_FullIndex(); p->delay=(1000.0f/((float)PIT_TICK_RATE/(float)p->cntr)); switch (counter) { case 0x00: /* Timer hooked to IRQ 0 */ if (p->new_mode || p->mode == 0 ) { if(p->mode==0) PIC_RemoveEvents(PIT0_Event); // DoWhackaDo demo PIC_AddEvent(PIT0_Event,p->delay); } else LOG(LOG_PIT,LOG_NORMAL)("PIT 0 Timer set without new control word"); LOG(LOG_PIT,LOG_NORMAL)("PIT 0 Timer at %.2f Hz mode %d",1000.0/p->delay,p->mode); break; case 0x02: /* Timer hooked to PC-Speaker */ // LOG(LOG_PIT,"PIT 2 Timer at %.3g Hz mode %d",PIT_TICK_RATE/(double)p->cntr,p->mode); PCSPEAKER_SetCounter(p->cntr,p->mode); break; default: LOG(LOG_PIT,LOG_ERROR)("PIT:Illegal timer selected for writing"); } p->new_mode=false; } } static Bitu read_latch(Bitu port,Bitu /*iolen*/) { //LOG(LOG_PIT,LOG_ERROR)("port read %X",port); Bit32u counter=port-0x40; Bit8u ret=0; if(GCC_UNLIKELY(pit[counter].counterstatus_set)){ pit[counter].counterstatus_set = false; latched_timerstatus_locked = false; ret = latched_timerstatus; } else { if (pit[counter].go_read_latch == true) counter_latch(counter); if( pit[counter].bcd == true) BIN2BCD(pit[counter].read_latch); switch (pit[counter].read_state) { case 0: /* read MSB & return to state 3 */ ret=(pit[counter].read_latch >> 8) & 0xff; pit[counter].read_state = 3; pit[counter].go_read_latch = true; break; case 3: /* read LSB followed by MSB */ ret = pit[counter].read_latch & 0xff; if (pit[counter].mode & 0x80) pit[counter].mode &= 7; else pit[counter].read_state = 0; break; case 1: /* read LSB */ ret = pit[counter].read_latch & 0xff; pit[counter].go_read_latch = true; break; case 2: /* read MSB */ ret = (pit[counter].read_latch >> 8) & 0xff; pit[counter].go_read_latch = true; break; default: E_Exit("Timer.cpp: error in readlatch"); break; } if( pit[counter].bcd == true) BCD2BIN(pit[counter].read_latch); } return ret; } static void write_p43(Bitu /*port*/,Bitu val,Bitu /*iolen*/) { //LOG(LOG_PIT,LOG_ERROR)("port 43 %X",val); Bitu latch=(val >> 6) & 0x03; switch (latch) { case 0: case 1: case 2: if ((val & 0x30) == 0) { /* Counter latch command */ counter_latch(latch); } else { pit[latch].bcd = (val&1)>0; if (val & 1) { if(pit[latch].cntr>=9999) pit[latch].cntr=9999; } // Timer is being reprogrammed, unlock the status if(pit[latch].counterstatus_set) { pit[latch].counterstatus_set=false; latched_timerstatus_locked=false; } pit[latch].read_state = (val >> 4) & 0x03; pit[latch].write_state = (val >> 4) & 0x03; Bit8u mode = (val >> 1) & 0x07; if (mode > 5) mode -= 4; //6,7 become 2 and 3 /* Don't set it directly so counter_output uses the old mode */ /* That's theory. It breaks panic. So set it here again */ if(!pit[latch].mode) pit[latch].mode = mode; /* If the line goes from low to up => generate irq. * ( BUT needs to stay up until acknowlegded by the cpu!!! therefore: ) * If the line goes to low => disable irq. * Mode 0 starts with a low line. (so always disable irq) * Mode 2,3 start with a high line. * counter_output tells if the current counter is high or low * So actually a mode 2 timer enables and disables irq al the time. (not handled) */ if (latch == 0) { PIC_RemoveEvents(PIT0_Event); if (!counter_output(0) && mode) { PIC_ActivateIRQ(0); //Don't raise instantaniously. (Origamo) if(CPU_Cycles < 25) CPU_Cycles = 25; } if(!mode) PIC_DeActivateIRQ(0); } pit[latch].new_mode = true; pit[latch].mode = mode; //Set the correct mode (here) } break; case 3: if ((val & 0x20)==0) { /* Latch multiple pit counters */ if (val & 0x02) counter_latch(0); if (val & 0x04) counter_latch(1); if (val & 0x08) counter_latch(2); } // status and values can be latched simultaneously if ((val & 0x10)==0) { /* Latch status words */ // but only 1 status can be latched simultaneously if (val & 0x02) status_latch(0); else if (val & 0x04) status_latch(1); else if (val & 0x08) status_latch(2); } break; } } void TIMER_SetGate2(bool in) { //No changes if gate doesn't change if(gate2 == in) return; Bit8u & mode=pit[2].mode; switch(mode) { case 0: if(in) pit[2].start = PIC_FullIndex(); else { //Fill readlatch and store it. counter_latch(2); pit[2].cntr = pit[2].read_latch; } break; case 2: case 3: //If gate is enabled restart counting. If disable store the current read_latch if(in) pit[2].start = PIC_FullIndex(); else counter_latch(2); break; case 1: case 4: case 5: LOG(LOG_MISC,LOG_WARN)("unsupported gate 2 mode %x",mode); break; } gate2 = in; //Set it here so the counter_latch above works } class TIMER:public Module_base{ private: IO_ReadHandleObject ReadHandler[4]; IO_WriteHandleObject WriteHandler[4]; public: TIMER(Section* configuration):Module_base(configuration){ WriteHandler[0].Install(0x40,write_latch,IO_MB); // WriteHandler[1].Install(0x41,write_latch,IO_MB); WriteHandler[2].Install(0x42,write_latch,IO_MB); WriteHandler[3].Install(0x43,write_p43,IO_MB); ReadHandler[0].Install(0x40,read_latch,IO_MB); ReadHandler[1].Install(0x41,read_latch,IO_MB); ReadHandler[2].Install(0x42,read_latch,IO_MB); /* Setup Timer 0 */ pit[0].cntr=0x10000; pit[0].write_state = 3; pit[0].read_state = 3; pit[0].read_latch=0; pit[0].write_latch=0; pit[0].mode=3; pit[0].bcd = false; pit[0].go_read_latch = true; pit[0].counterstatus_set = false; pit[1].bcd = false; pit[1].write_state = 1; pit[1].read_state = 1; pit[1].go_read_latch = true; pit[1].cntr = 18; pit[1].mode = 2; pit[1].write_state = 3; pit[1].counterstatus_set = false; pit[2].read_latch=0; /* MadTv1 */ pit[2].write_state = 3; /* Chuck Yeager */ pit[2].read_state = 3; pit[2].mode=3; pit[2].bcd=false; pit[2].cntr=1320; pit[2].go_read_latch=true; pit[2].counterstatus_set = false; pit[0].delay=(1000.0f/((float)PIT_TICK_RATE/(float)pit[0].cntr)); pit[1].delay=(1000.0f/((float)PIT_TICK_RATE/(float)pit[1].cntr)); pit[2].delay=(1000.0f/((float)PIT_TICK_RATE/(float)pit[2].cntr)); latched_timerstatus_locked=false; gate2 = true; PIC_AddEvent(PIT0_Event,pit[0].delay); } ~TIMER(){ PIC_RemoveEvents(PIT0_Event); } }; static TIMER* test; void TIMER_Destroy(Section*){ delete test; } void TIMER_Init(Section* sec) { test = new TIMER(sec); sec->AddDestroyFunction(&TIMER_Destroy); }