///////////////////////////////////////////////////////////////////////// // $Id: pit.cc,v 1.15 2003-07-31 12:04:48 vruppert Exp $ ///////////////////////////////////////////////////////////////////////// // // Copyright (C) 2001 MandrakeSoft S.A. // // MandrakeSoft S.A. // 43, rue d'Aboukir // 75002 Paris - France // http://www.linux-mandrake.com/ // http://www.mandrakesoft.com/ // // This library is free software; you can redistribute it and/or // modify it under the terms of the GNU Lesser General Public // License as published by the Free Software Foundation; either // version 2 of the License, or (at your option) any later version. // // This library 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 // Lesser General Public License for more details. // // You should have received a copy of the GNU Lesser General Public // License along with this library; if not, write to the Free Software // Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA #include "bochs.h" #if (BX_USE_NEW_PIT==0) #define LOG_THIS bx_pit. // NOTES ON THE 8253/8254 PIT MODES // MODE 0: Interrupt on Terminal Count // =================================== // Writing new count action: // loaded upon next CLK pulse. counting doesn't start until GATE=1 // GATE 0..1 transition: // ??? // GATE 1..0 transition: // counter expiration action: // wraps to FFFF // * OUT rises until new count val or new control word for mode 0 written // MODE 1: Programmable Monoflop // ============================= // Writing new count action: // not effective for current process // GATE 0..1 transition: // loads counter // counter expiration action: // wraps to FFFF // NOTES: // OUT rises until new count val or new control word for mode 0 written // MODE 2: Rate Generator // ====================== // Writing new count action: // ??? // GATE 0..1 transition: // loads initial count val and starts counting // counter expiration action: // reloads after count expires // NOTES: // * after control word & initial count val N loaded, PIT starts // counting upon next CLK pulse. // * when counter reaches 1, OUT drops to a low level, for one // CLK cycle. (short peak pulse generated) // * afterwards, the initial count val is automatically reloaded // and the PIT restarts the same counting operation again. // * distance of two OUT pulses is N CLK cycles long. // * GATE=1 enables, GATE=0 disables counter. // * if GATE drops to low level during counting operation and rises // to high level later, PIT loads initial count value at the // rise and starts counting. // * PIT starts counting after last data byte written if GATE=1 // * if the output is low when the gate goes low, the output is // immediately set high. // MODE 3: Square Wave Generator // ============================= // Writing new count action: // ??? // GATE 0..1 transition: // ??? // counter expiration action: // reloads after count expires // NOTES: // * initially OUT at a high level // * drop of GATE to a low level while OUT low, raises OUT to a high level // * a rise from a low to a high level at GATE (trigger pulse), // loads the counter with the initial count value and starts // counting operation // * a new count value supplied during the course of an active // counting operation doesn't affect the current process. // At the end of the current half cycle, the PIT loads the new value // * if the GATE line goes low, count is temporarily halted until GATE // returns high // * if the OUT line is high when GATE goes low, OUT is forced low. // ??? different for odd/even counts // MODE 4: Software Triggered Pulse // ================================ // Writing new count action: // ??? // GATE 0..1 transition: // ??? // counter expiration action: // wraps to FFFF // NOTES: // MODE 5: Hardware Triggered Pulse // ================================ // Writing new count action: // ??? // GATE 0..1 transition: // ??? // counter expiration action: // wraps to FFFF // NOTES: #define BX_PIT_LATCH_MODE_LSB 10 #define BX_PIT_LATCH_MODE_MSB 11 #define BX_PIT_LATCH_MODE_16BIT 12 bx_pit_c bx_pit; #if BX_USE_PIT_SMF #define this (&bx_pit) #endif #ifdef OUT # undef OUT #endif bx_pit_c::bx_pit_c( void ) { put("PIT"); settype(PITLOG); memset(&s, 0, sizeof(s)); /* 8254 PIT (Programmable Interval Timer) */ BX_PIT_THIS s.timer_handle[1] = BX_NULL_TIMER_HANDLE; BX_PIT_THIS s.timer_handle[2] = BX_NULL_TIMER_HANDLE; } bx_pit_c::~bx_pit_c( void ) { } int bx_pit_c::init( void ) { DEV_register_irq(0, "8254 PIT"); DEV_register_ioread_handler(this, read_handler, 0x0040, "8254 PIT", 1); DEV_register_ioread_handler(this, read_handler, 0x0041, "8254 PIT", 1); DEV_register_ioread_handler(this, read_handler, 0x0042, "8254 PIT", 1); DEV_register_ioread_handler(this, read_handler, 0x0043, "8254 PIT", 1); DEV_register_ioread_handler(this, read_handler, 0x0061, "8254 PIT", 1); DEV_register_iowrite_handler(this, write_handler, 0x0040, "8254 PIT", 1); DEV_register_iowrite_handler(this, write_handler, 0x0041, "8254 PIT", 1); DEV_register_iowrite_handler(this, write_handler, 0x0042, "8254 PIT", 1); DEV_register_iowrite_handler(this, write_handler, 0x0043, "8254 PIT", 1); DEV_register_iowrite_handler(this, write_handler, 0x0061, "8254 PIT", 1); BX_PIT_THIS s.speaker_data_on = 0; BX_PIT_THIS s.refresh_clock_div2 = 0; BX_PIT_THIS s.timer[0].mode = 3; /* periodic rate generator */ BX_PIT_THIS s.timer[0].latch_mode = BX_PIT_LATCH_MODE_16BIT; BX_PIT_THIS s.timer[0].input_latch_value = 0; BX_PIT_THIS s.timer[0].input_latch_toggle = 0; BX_PIT_THIS s.timer[0].output_latch_value = 0; BX_PIT_THIS s.timer[0].output_latch_toggle = 0; BX_PIT_THIS s.timer[0].output_latch_full = 0; BX_PIT_THIS s.timer[0].counter_max = 0; /* 0xFFFF + 1 : (1193182 / 65535 = 18.2Hz) */ BX_PIT_THIS s.timer[0].counter = 0; /* 0xFFFF + 1 : (1193182 / 65535 = 18.2Hz) */ BX_PIT_THIS s.timer[0].bcd_mode = 0; /* binary counting mode */ BX_PIT_THIS s.timer[0].GATE = 1; /* GATE tied to + logic */ BX_PIT_THIS s.timer[0].OUT = 1; BX_PIT_THIS s.timer[0].active = 0; BX_PIT_THIS s.timer[1].mode = 3; /* periodic rate generator */ BX_PIT_THIS s.timer[1].latch_mode = BX_PIT_LATCH_MODE_16BIT; BX_PIT_THIS s.timer[1].input_latch_value = 0; BX_PIT_THIS s.timer[1].input_latch_toggle = 0; BX_PIT_THIS s.timer[1].output_latch_value = 0; BX_PIT_THIS s.timer[1].output_latch_toggle = 0; BX_PIT_THIS s.timer[1].output_latch_full = 0; BX_PIT_THIS s.timer[1].counter_max = 0; /* 0xFFFF + 1 : (1193182 / 65535 = 18.2Hz) */ BX_PIT_THIS s.timer[1].counter = 0; /* 0xFFFF + 1 : (1193182 / 65535 = 18.2Hz) */ BX_PIT_THIS s.timer[1].bcd_mode = 0; /* binary counting mode */ BX_PIT_THIS s.timer[1].GATE = 1; /* GATE tied to + logic */ BX_PIT_THIS s.timer[1].OUT = 1; BX_PIT_THIS s.timer[1].active = 0; BX_PIT_THIS s.timer[2].mode = 3; /* periodic rate generator */ BX_PIT_THIS s.timer[2].latch_mode = BX_PIT_LATCH_MODE_16BIT; BX_PIT_THIS s.timer[2].input_latch_value = 0; BX_PIT_THIS s.timer[2].input_latch_toggle = 0; BX_PIT_THIS s.timer[2].output_latch_value = 0; BX_PIT_THIS s.timer[2].output_latch_toggle = 0; BX_PIT_THIS s.timer[2].output_latch_full = 0; BX_PIT_THIS s.timer[2].counter_max = 0; /* 0xFFFF + 1 : (1193182 / 65535 = 18.2Hz) */ BX_PIT_THIS s.timer[2].counter = 0; /* 0xFFFF + 1 : (1193182 / 65535 = 18.2Hz) */ BX_PIT_THIS s.timer[2].bcd_mode = 0; /* binary counting mode */ BX_PIT_THIS s.timer[2].GATE = 0; /* timer2 gate controlled by port 61h bit 0 */ BX_PIT_THIS s.timer[2].OUT = 1; BX_PIT_THIS s.timer[2].active = 0; return(1); } void bx_pit_c::reset(unsigned type) { } // static IO port read callback handler // redirects to non-static class handler to avoid virtual functions Bit32u bx_pit_c::read_handler(void *this_ptr, Bit32u address, unsigned io_len) { #if !BX_USE_PIT_SMF bx_pit_c *class_ptr = (bx_pit_c *) this_ptr; return( class_ptr->read(address, io_len) ); } Bit32u bx_pit_c::read( Bit32u address, unsigned int io_len ) { #else UNUSED(this_ptr); #endif // !BX_USE_PIT_SMF if (bx_dbg.pit) BX_INFO(("pit: io read from port %04x", (unsigned) address)); switch (address) { case 0x40: /* timer 0 - system ticks */ return( read_counter(0) ); break; case 0x42: /* timer 2 read */ return( read_counter(2) ); break; case 0x61: /* AT, port 61h */ BX_PIT_THIS s.refresh_clock_div2 = !BX_PIT_THIS s.refresh_clock_div2; return( (BX_PIT_THIS s.timer[2].OUT<<5) | (BX_PIT_THIS s.refresh_clock_div2<<4) | (BX_PIT_THIS s.speaker_data_on<<1) | (BX_PIT_THIS s.timer[2].GATE) ); break; default: BX_PANIC(("pit: unsupported io read from port %04x", address)); } return(0); /* keep compiler happy */ } // static IO port write callback handler // redirects to non-static class handler to avoid virtual functions void bx_pit_c::write_handler(void *this_ptr, Bit32u address, Bit32u dvalue, unsigned io_len) { #if !BX_USE_PIT_SMF bx_pit_c *class_ptr = (bx_pit_c *) this_ptr; class_ptr->write(address, dvalue, io_len); } void bx_pit_c::write( Bit32u address, Bit32u dvalue, unsigned int io_len ) { #else UNUSED(this_ptr); #endif // !BX_USE_PIT_SMF Bit8u command, mode, bcd_mode; Bit8u value; value = (Bit8u ) dvalue; if (bx_dbg.pit) BX_INFO(("pit: write to port %04x = %02x", (unsigned) address, (unsigned) value)); switch (address) { case 0x40: /* timer 0: write count register */ write_count_reg( value, 0 ); break; case 0x41: /* timer 1: write count register */ write_count_reg( value, 1 ); break; case 0x42: /* timer 2: write count register */ write_count_reg( value, 2 ); break; case 0x43: /* timer 0-2 mode control */ /* |7 6 5 4|3 2 1|0| * |-------|-----|-| * |command|mode |bcd/binary| */ command = value >> 4; mode = (value >> 1) & 0x07; bcd_mode = value & 0x01; #if 0 BX_INFO(("timer 0-2 mode control: comm:%02x mode:%02x bcd_mode:%u", (unsigned) command, (unsigned) mode, (unsigned) bcd_mode)); #endif if ( (mode > 5) || (command > 0x0e) ) BX_PANIC(("pit: outp(43h)=%02xh out of range", (unsigned) value)); if (bcd_mode) BX_PANIC(("pit: outp(43h)=%02xh: bcd mode unhandled", (unsigned) bcd_mode)); switch (command) { case 0x0: /* timer 0: counter latch */ latch( 0 ); break; case 0x1: /* timer 0: LSB mode */ case 0x2: /* timer 0: MSB mode */ BX_PANIC(("pit: outp(43h): command %02xh unhandled", (unsigned) command)); break; case 0x3: /* timer 0: 16-bit mode */ BX_PIT_THIS s.timer[0].mode = mode; BX_PIT_THIS s.timer[0].latch_mode = BX_PIT_LATCH_MODE_16BIT; BX_PIT_THIS s.timer[0].input_latch_value = 0; BX_PIT_THIS s.timer[0].input_latch_toggle = 0; BX_PIT_THIS s.timer[0].bcd_mode = bcd_mode; if ( (mode!=3 && mode!=2 && mode!=0) || bcd_mode!=0 ) BX_PANIC(("pit: outp(43h): comm 3, mode %02x, bcd %02x unhandled", (unsigned) mode, bcd_mode)); break; case 0x4: /* timer 1: counter latch */ latch( 1 ); break; case 0x5: /* timer 1: LSB mode */ case 0x6: /* timer 1: MSB mode */ BX_INFO(("pit: outp(43h): command %02xh unhandled (ignored)", (unsigned) command)); break; case 0x7: /* timer 1: 16-bit mode */ BX_PIT_THIS s.timer[1].mode = mode; BX_PIT_THIS s.timer[1].latch_mode = BX_PIT_LATCH_MODE_16BIT; BX_PIT_THIS s.timer[1].input_latch_value = 0; BX_PIT_THIS s.timer[1].input_latch_toggle = 0; BX_PIT_THIS s.timer[1].bcd_mode = bcd_mode; if ( (mode!=3 && mode!=2 && mode!=0) || bcd_mode!=0 ) BX_PANIC(("pit: outp(43h): comm 7, mode %02x, bcd %02x unhandled", (unsigned) mode, bcd_mode)); break; case 0x8: /* timer 2: counter latch */ latch( 2 ); break; case 0x9: /* timer 2: LSB mode */ case 0xa: /* timer 2: MSB mode */ BX_PANIC(("pit: outp(43h): command %02xh unhandled", (unsigned) command)); break; case 0xb: /* timer 2: 16-bit mode */ BX_PIT_THIS s.timer[2].mode = mode; BX_PIT_THIS s.timer[2].latch_mode = BX_PIT_LATCH_MODE_16BIT; BX_PIT_THIS s.timer[2].input_latch_value = 0; BX_PIT_THIS s.timer[2].input_latch_toggle = 0; BX_PIT_THIS s.timer[2].bcd_mode = bcd_mode; if ( (mode!=3 && mode!=2 && mode!=0) || bcd_mode!=0 ) BX_PANIC(("pit: outp(43h): comm Bh, mode %02x, bcd %02x unhandled", (unsigned) mode, bcd_mode)); break; #if 0 case 0xd: /* general counter latch */ if (value & 0x08) /* select counter 2 */ latch( 2 ); if (value & 0x04) /* select counter 1 */ latch( 1 ); if (value & 0x02) /* select counter 0 */ latch( 0 ); break; case 0xe: /* latch status of timers */ BX_PANIC(("pit: outp(43h): command %02xh unhandled", (unsigned) command); break; #endif case 0x0c: case 0x0d: case 0x0e: case 0x0f: BX_INFO(("pit: ignoring 8254 command %u", (unsigned) command)); break; default: /* 0xc & 0xf */ BX_PANIC(("pit: outp(43h) command %1xh unhandled", (unsigned) command)); break; } break; case 0x61: BX_PIT_THIS s.speaker_data_on = (value >> 1) & 0x01; /*??? only on AT+ */ set_GATE(2, value & 0x01); #if BX_CPU_LEVEL < 2 /* ??? XT: */ bx_kbd_port61h_write(value); #endif break; default: BX_PANIC(("pit: unsupported io write to port %04x = %02x", (unsigned) address, (unsigned) value)); } } void bx_pit_c::write_count_reg( Bit8u value, unsigned timerid ) { bx_bool xfer_complete; switch ( BX_PIT_THIS s.timer[timerid].latch_mode ) { case BX_PIT_LATCH_MODE_16BIT: /* write1=LSB, write2=MSB */ if (BX_PIT_THIS s.timer[timerid].input_latch_toggle==0) { BX_PIT_THIS s.timer[timerid].input_latch_value = value; BX_PIT_THIS s.timer[timerid].input_latch_toggle = 1; xfer_complete = 0; if (bx_dbg.pit) BX_INFO(("pit: BX_PIT_THIS s.timer[timerid] write L = %02x", (unsigned) value)); } else { BX_PIT_THIS s.timer[timerid].input_latch_value |= (value << 8); BX_PIT_THIS s.timer[timerid].input_latch_toggle = 0; xfer_complete = 1; if (bx_dbg.pit) BX_INFO(("pit: BX_PIT_THIS s.timer[timerid] write H = %02x", (unsigned) value)); } break; case BX_PIT_LATCH_MODE_MSB: /* write1=MSB, LSB=0 */ BX_PIT_THIS s.timer[timerid].input_latch_value = (value << 8); xfer_complete = 1; if (bx_dbg.pit) BX_INFO(("pit: BX_PIT_THIS s.timer[timerid] write H = %02x", (unsigned) value)); break; case BX_PIT_LATCH_MODE_LSB: /* write1=LSB, MSB=0 */ BX_PIT_THIS s.timer[timerid].input_latch_value = value; xfer_complete = 1; if (bx_dbg.pit) BX_INFO(("pit: BX_PIT_THIS s.timer[timerid] write L = %02x", (unsigned) value)); break; default: BX_PANIC(("write_count_reg: latch_mode unknown")); xfer_complete = 0; } if (xfer_complete) { BX_PIT_THIS s.timer[timerid].counter_max = BX_PIT_THIS s.timer[timerid].input_latch_value; // reprogramming counter clears latch BX_PIT_THIS s.timer[timerid].output_latch_full = 0; // counter bounds // mode minimum maximum // 0 1 0 // 1 1 0 // 2 2 0 // 3 2 0 // 4 1 0 // 5 1 0 switch (BX_PIT_THIS s.timer[timerid].mode) { case 0: BX_PIT_THIS s.timer[timerid].counter = BX_PIT_THIS s.timer[timerid].counter_max; BX_PIT_THIS s.timer[timerid].active = 1; if (BX_PIT_THIS s.timer[timerid].GATE) { BX_PIT_THIS s.timer[timerid].OUT = 0; // OUT pin starts low start( timerid ); } break; case 1: BX_PANIC(("pit:write_count_reg(%u): mode1 unsupported", timerid)); break; case 2: if ( BX_PIT_THIS s.timer[timerid].counter_max == 1 ) BX_PANIC(("pit:write_count_reg(%u): mode %u counter_max=1", timerid, (unsigned) BX_PIT_THIS s.timer[timerid].mode)); if ( BX_PIT_THIS s.timer[timerid].GATE && !BX_PIT_THIS s.timer[timerid].active ) { // software triggered BX_PIT_THIS s.timer[timerid].counter = BX_PIT_THIS s.timer[timerid].counter_max; BX_PIT_THIS s.timer[timerid].active = 1; BX_PIT_THIS s.timer[timerid].OUT = 1; // initially set high start( timerid ); } break; case 3: if ( BX_PIT_THIS s.timer[timerid].counter_max == 1 ) BX_PANIC(("pit:write_count_reg(%u): mode %u counter_max=1", timerid, (unsigned) BX_PIT_THIS s.timer[timerid].mode)); BX_PIT_THIS s.timer[timerid].counter_max = BX_PIT_THIS s.timer[timerid].counter_max & 0xfffe; if ( BX_PIT_THIS s.timer[timerid].GATE && !BX_PIT_THIS s.timer[timerid].active ) { // software triggered BX_PIT_THIS s.timer[timerid].counter = BX_PIT_THIS s.timer[timerid].counter_max; BX_PIT_THIS s.timer[timerid].active = 1; BX_PIT_THIS s.timer[timerid].OUT = 1; // initially set high start( timerid ); } break; case 4: BX_PANIC(("pit:write_count_reg(%u): mode4 unsupported", timerid)); break; case 5: BX_PANIC(("pit:write_count_reg(%u): mode5 unsupported", timerid)); break; } } } Bit8u bx_pit_c::read_counter( unsigned timerid ) { Bit16u counter_value; Bit8u retval; if (BX_PIT_THIS s.timer[timerid].output_latch_full) { /* latched read */ counter_value = BX_PIT_THIS s.timer[timerid].output_latch_value; } else { /* direct unlatched read */ counter_value = BX_PIT_THIS s.timer[timerid].counter; BX_INFO(("CV=%04x", (unsigned) BX_PIT_THIS s.timer[timerid].counter)); } switch (BX_PIT_THIS s.timer[timerid].latch_mode) { case BX_PIT_LATCH_MODE_LSB: retval = (Bit8u ) counter_value; BX_PIT_THIS s.timer[timerid].output_latch_full = 0; break; case BX_PIT_LATCH_MODE_MSB: retval = (Bit8u ) ( counter_value >> 8 ); BX_PIT_THIS s.timer[timerid].output_latch_full = 0; break; case BX_PIT_LATCH_MODE_16BIT: if (BX_PIT_THIS s.timer[timerid].output_latch_toggle==0) { /* LSB 1st */ retval = (Bit8u ) counter_value; } else { /* MSB 2nd */ retval = (Bit8u ) ( counter_value >> 8 ); } BX_PIT_THIS s.timer[timerid].output_latch_toggle = !BX_PIT_THIS s.timer[timerid].output_latch_toggle; if (BX_PIT_THIS s.timer[timerid].output_latch_toggle == 0) BX_PIT_THIS s.timer[timerid].output_latch_full = 0; break; default: BX_PANIC(("pit: io read from port 40h: unknown latch mode")); retval = 0; /* keep compiler happy */ } return( retval ); } void bx_pit_c::latch( unsigned timerid ) { /* subsequent counter latch commands are ignored until value read out */ if (BX_PIT_THIS s.timer[timerid].output_latch_full) { BX_INFO(("pit: pit(%u) latch: output latch full, ignoring", timerid)); return; } BX_PIT_THIS s.timer[timerid].output_latch_value = BX_PIT_THIS s.timer[timerid].counter; if (bx_dbg.pit) BX_INFO(("pit: latch_value = %u", (unsigned) BX_PIT_THIS s.timer[timerid].output_latch_value)); BX_PIT_THIS s.timer[timerid].output_latch_toggle = 0; BX_PIT_THIS s.timer[timerid].output_latch_full = 1; } void bx_pit_c::set_GATE(unsigned pit_id, unsigned value) { // GATE's for Timer 0 & Timer 1 are tied high. if (pit_id != 2) BX_PANIC(("pit:set_GATE: pit_id != 2")); value = (value > 0); /* if no transition of GATE input line, then nothing to do */ if (value == BX_PIT_THIS s.timer[2].GATE) return; if (value) { /* PIT2: GATE transition from 0 to 1 */ BX_PIT_THIS s.timer[2].GATE = 1; switch ( BX_PIT_THIS s.timer[2].mode ) { case 0: BX_PIT_THIS s.timer[2].counter = BX_PIT_THIS s.timer[2].counter_max; if (BX_PIT_THIS s.timer[2].active) { BX_PIT_THIS s.timer[2].OUT = 0; } start( 2 ); break; case 2: // begin counting, reload counter BX_PIT_THIS s.timer[2].active = 1; BX_PIT_THIS s.timer[2].OUT = 1; BX_PIT_THIS s.timer[2].counter = BX_PIT_THIS s.timer[2].counter_max; start( 2 ); break; case 3: // begin counting, reload counter BX_PIT_THIS s.timer[2].active = 1; BX_PIT_THIS s.timer[2].OUT = 1; BX_PIT_THIS s.timer[2].counter = BX_PIT_THIS s.timer[2].counter_max; start( 2 ); break; case 1: case 4: case 5: default: BX_PANIC(("bx_pit_c::set_GATE: unhandled timer2 mode %u", (unsigned) BX_PIT_THIS s.timer[2].mode)); } } else { // PIT2: GATE transition from 1 to 0, deactivate BX_PIT_THIS s.timer[2].GATE = 0; switch ( BX_PIT_THIS s.timer[2].mode ) { case 0: break; case 2: // 1) stops count, 2) OUT goes immediately high BX_PIT_THIS s.timer[2].active = 0; BX_PIT_THIS s.timer[2].OUT = 1; break; case 3: // 1) stops count, 2) OUT goes immediately high BX_PIT_THIS s.timer[2].active = 0; BX_PIT_THIS s.timer[2].OUT = 1; break; case 1: case 4: case 5: default: BX_PANIC(("bx_pit_c::set_GATE: unhandled timer2 mode %u", (unsigned) BX_PIT_THIS s.timer[2].mode)); } } } void bx_pit_c::start(unsigned timerid) { unsigned long period_hz; if (BX_PIT_THIS s.timer[timerid].counter_max == 0x0000) { period_hz = 1193182 / 65536; } else { period_hz = 1193182 / BX_PIT_THIS s.timer[timerid].counter_max; } BX_INFO(("timer%u period set to %lu hz", timerid, period_hz)); switch (BX_PIT_THIS s.timer[timerid].mode) { case 0: /* single timeout */ break; case 1: /* retriggerable one-shot */ BX_PANIC(("start: mode %u unhandled", (unsigned) BX_PIT_THIS s.timer[timerid].mode)); break; case 2: /* rate generator */ break; case 3: /* square wave mode */ break; case 4: /* software triggered strobe */ BX_PANIC(("start: mode %u unhandled", (unsigned) BX_PIT_THIS s.timer[timerid].mode)); break; case 5: /* hardware retriggerable strobe */ BX_PANIC(("start: mode %u unhandled", (unsigned) BX_PIT_THIS s.timer[timerid].mode)); break; default: BX_PANIC(("start: timer%u has bad mode", (unsigned) BX_PIT_THIS s.timer[timerid].mode)); } } int bx_pit_c::SaveState( class state_file *fd ) { fd->write_check ("8254 start"); fd->write (&BX_PIT_THIS s, sizeof (BX_PIT_THIS s)); fd->write_check ("8254 end"); return(0); } int bx_pit_c::LoadState( class state_file *fd ) { fd->read_check ("8254 start"); fd->read (&BX_PIT_THIS s, sizeof (BX_PIT_THIS s)); fd->read_check ("8254 end"); return(0); } #if 0 void bx_kbd_port61h_write(Bit8u value) { // PcError("KBD_PORT61H_WRITE(): not implemented yet"); UNUSED( value ); } #endif bx_bool bx_pit_c::periodic( Bit32u usec_delta ) { bx_bool prev_timer0_out; prev_timer0_out = BX_PIT_THIS s.timer[0].OUT; for (unsigned i = 0; i < 3; i++) { // is timer enabled and active? if ( BX_PIT_THIS s.timer[i].GATE && BX_PIT_THIS s.timer[i].active ) { switch ( BX_PIT_THIS s.timer[i].mode ) { case 0: // Mode 0: Single Timeout // wraps after count expires if ( BX_PIT_THIS s.timer[i].counter == 0 ) { // counter previously expired, wrap counter BX_PIT_THIS s.timer[i].counter = 0xffff; } else if ( usec_delta >= BX_PIT_THIS s.timer[i].counter ) { // counter expired BX_PIT_THIS s.timer[i].counter = 0; BX_PIT_THIS s.timer[i].OUT = 1; } else { // decrement counter by elapsed useconds BX_PIT_THIS s.timer[i].counter -= (Bit16u ) usec_delta; } break; case 1: // Mode 1: Retriggerable One-Shot // wraps after count expires BX_PANIC(("bx_pit_c::periodic: bad mode: timer[%u], mode %u", i, (unsigned) BX_PIT_THIS s.timer[i].mode)); break; case 2: // Mode 2: Rate Generator // reloads after count expires // OUT is low when counter=1, high otherwise // min count=2, max count=0 if ( BX_PIT_THIS s.timer[i].counter == 0 ) { // max counter val, just wrap BX_PIT_THIS s.timer[i].counter = 0xffff; BX_PIT_THIS s.timer[i].OUT = 1; } else if ( BX_PIT_THIS s.timer[i].counter == 1 ) { // counter previously expired, reload BX_PIT_THIS s.timer[i].counter = BX_PIT_THIS s.timer[i].counter_max; BX_PIT_THIS s.timer[i].OUT = 1; } else if ( (BX_PIT_THIS s.timer[i].counter == 2) || (usec_delta >= (Bit32u(BX_PIT_THIS s.timer[i].counter) - 1)) ) { // in either case, counter will reach 1 BX_PIT_THIS s.timer[i].counter = 1; BX_PIT_THIS s.timer[i].OUT = 0; } else { // decrement counter by elapsed useconds BX_PIT_THIS s.timer[i].counter -= (Bit16u ) usec_delta; } break; case 3: // Mode 3: Square Wave Mode // reloads after count expires // min count=2, max count=0 if ( BX_PIT_THIS s.timer[i].counter == 0 ) { // max count, dec by 2 BX_PIT_THIS s.timer[i].counter = 0xfffe; } else if ( (BX_PIT_THIS s.timer[i].counter <= 2) || ( (usec_delta*2) >= BX_PIT_THIS s.timer[i].counter ) ) { // counter expired, reload BX_PIT_THIS s.timer[i].counter = BX_PIT_THIS s.timer[i].counter_max; BX_PIT_THIS s.timer[i].OUT = !BX_PIT_THIS s.timer[i].OUT; //BX_INFO(("CV: reload t%u to %04x", (unsigned) i, (unsigned) // BX_PIT_THIS s.timer[i].counter)); } else { // decrement counter by elapsed useconds BX_PIT_THIS s.timer[i].counter -= (Bit16u ) ( 2*usec_delta ); //BX_INFO(("CV: dec count to %04x", // (unsigned) BX_PIT_THIS s.timer[i].counter)); } break; case 4: // Mode 4: Software Triggered Strobe // wraps after count expires BX_PANIC(("bx_pit_c::periodic: bad mode: timer[%u], mode %u", i, (unsigned) BX_PIT_THIS s.timer[i].mode)); break; case 5: // Mode 5: Hardware Retriggerable Strobe // wraps after count expires BX_PANIC(("bx_pit_c::periodic: bad mode: timer[%u], mode %u", i, (unsigned) BX_PIT_THIS s.timer[i].mode)); break; default: BX_PANIC(("bx_pit_c::periodic: bad mode: timer[%u], mode %u", i, (unsigned) BX_PIT_THIS s.timer[i].mode)); break; } // switch ( BX_PIT_THIS s.tim... } // if ( BX_PIT_THIS s.timer[i]... } // for (unsigned i... // see if there's a rising edge on timer0's output to trigger an IRQ0. if ( (prev_timer0_out==0) && (BX_PIT_THIS s.timer[0].OUT==1) ) return(1); // request IRQ 0 else return(0); } #endif // #if (BX_USE_NEW_PIT==0)