mirrors/Bochs
1
0
Fork 0
Code Issues Pull Requests Packages Projects Releases Wiki Activity
7dd83e2140
Bochs/bochs/pc_system.cc
Volker Ruppert c7c9cc2430 - DMA register and unregister functions for DMA channels added and macros for 
DMA functions defined. Most of the changes are based on the "bochs sync"
   version of plex86. Here is the list of changes:

  * register/unregister functions for DMA channels added. The DMA controller
    can use the DMA read/write handlers of registered devices directly.
  * "hardwired" code in dma.cc removed
  * all DMA related code in devices.cc and iodev.h removed
  * DMA related code in pc_system.* removed except HRQ handling
  * macros for DMA functions defined in bochs.h
  * floppy and SB16 code modified to use the changes described above
2002-06-16 15:02:28 +00:00

475 lines
11 KiB
C++
Raw Blame History

/////////////////////////////////////////////////////////////////////////
// $Id: pc_system.cc,v 1.18 2002-06-16 15:02:27 vruppert Exp $
/////////////////////////////////////////////////////////////////////////
//
// Copyright (C) 2002 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"
#define LOG_THIS bx_pc_system.
#ifdef WIN32
#ifndef __MINGW32__
// #include <winsock2.h> // +++
#include <winsock.h>
#endif
#endif
#if BX_SHOW_IPS
unsigned long ips_count=0;
#endif
#if defined(PROVIDE_M_IPS)
double m_ips; // Millions of Instructions Per Second
#endif
const Bit64u bx_pc_system_c::COUNTER_INTERVAL = 100000;
// constructor
bx_pc_system_c::bx_pc_system_c(void)
{
this->put("SYS");
num_timers = 0;
// set ticks period and remaining to max Bit32u value
num_cpu_ticks_in_period = num_cpu_ticks_left = (Bit32u) -1;
m_ips = 0.0L;
HRQ = 0;
enable_a20 = 1;
//set_INTR (0);
#if BX_CPU_LEVEL < 2
a20_mask = 0xfffff;
#elif BX_CPU_LEVEL == 2
a20_mask = 0xffffff;
#else /* 386+ */
a20_mask = 0xffffffff;
#endif
counter = 0;
counter_timer_index = register_timer_ticks(this, bx_pc_system_c::counter_timer_handler, COUNTER_INTERVAL, 1, 1);
}
void
bx_pc_system_c::init_ips(Bit32u ips)
{
// parameter 'ips' is the processor speed in Instructions-Per-Second
m_ips = double(ips) / 1000000.0L;
BX_DEBUG(("ips = %u", (unsigned) ips));
}
void
bx_pc_system_c::set_HRQ(Boolean val)
{
HRQ = val;
if (val)
BX_CPU(0)->async_event = 1;
}
#if (BX_NUM_SIMULATORS < 2)
void
bx_pc_system_c::set_INTR(Boolean value)
{
if (bx_dbg.interrupts)
BX_INFO(("pc_system: Setting INTR=%d on bootstrap processor %d", (int)value, BX_BOOTSTRAP_PROCESSOR));
//INTR = value;
int cpu = BX_BOOTSTRAP_PROCESSOR;
BX_CPU(cpu)->set_INTR(value);
}
#endif
//
// Read from the IO memory address space
//
Bit32u
bx_pc_system_c::inp(Bit16u addr, unsigned io_len)
{
Bit32u ret;
ret = bx_devices.inp(addr, io_len);
return( ret );
}
//
// Write to the IO memory address space.
//
void
bx_pc_system_c::outp(Bit16u addr, Bit32u value, unsigned io_len)
{
bx_devices.outp(addr, value, io_len);
}
void
bx_pc_system_c::set_enable_a20(Bit8u value)
{
#if BX_CPU_LEVEL < 2
BX_PANIC(("set_enable_a20() called: 8086 emulation"));
#else
#if BX_SUPPORT_A20
if (value) {
enable_a20 = 1;
#if BX_CPU_LEVEL == 2
a20_mask = 0xffffff; /* 286: enable all 24 address lines */
#else /* 386+ */
a20_mask = 0xffffffff; /* 386: enable all 32 address lines */
#endif
}
else {
enable_a20 = 0;
a20_mask = 0xffefffff; /* mask off A20 address line */
}
BX_DBG_A20_REPORT(value);
BX_DEBUG(("A20: set() = %u", (unsigned) enable_a20));
#else
BX_DEBUG(("set_enable_a20: ignoring: SUPPORT_A20 = 0"));
#endif // #if BX_SUPPORT_A20
#endif
}
Boolean
bx_pc_system_c::get_enable_a20(void)
{
#if BX_SUPPORT_A20
if (bx_dbg.a20)
BX_INFO(("A20: get() = %u", (unsigned) enable_a20));
if (enable_a20) return(1);
else return(0);
#else
BX_INFO(("get_enable_a20: ignoring: SUPPORT_A20 = 0"));
return(1);
#endif // #if BX_SUPPORT_A20
}
int
bx_pc_system_c::ResetSignal( PCS_OP operation )
{
UNUSED( operation );
// Reset the processor.
BX_ERROR(( "# bx_pc_system_c::ResetSignal() called" ));
for (int i=0; i<BX_SMP_PROCESSORS; i++)
BX_CPU(i)->reset(BX_RESET_SOFTWARE);
return(0);
}
Bit8u
bx_pc_system_c::IAC(void)
{
return( bx_devices.pic->IAC() );
}
void
bx_pc_system_c::exit(void)
{
if (bx_devices.hard_drive)
bx_devices.hard_drive->close_harddrive();
BX_INFO(("Last time is %d", bx_cmos.s.timeval));
bx_gui.exit();
}
//
// bochs timer support
//
void
bx_pc_system_c::timer_handler(void)
{
Bit64u min;
unsigned i;
Bit64u delta;
// BX_ERROR(( "Time handler ptime = %d", bx_pc_system.time_ticks() ));
delta = num_cpu_ticks_in_period - num_cpu_ticks_left;
#if BX_TIMER_DEBUG
if (num_cpu_ticks_left != 0)
BX_PANIC(("timer_handler: ticks_left!=0"));
#endif
for (i=0; i < num_timers; i++) {
timer[i].triggered = 0;
if (timer[i].active) {
#if BX_TIMER_DEBUG
if (timer[i].remaining < delta) {
BX_PANIC(("timer_handler: remain < delta"));
}
#endif
timer[i].remaining -= delta;
if (timer[i].remaining == 0) {
timer[i].triggered = 1;
// reset remaining period for triggered timer
timer[i].remaining = timer[i].period;
// if triggered timer is one-shot, deactive
if (timer[i].continuous==0)
timer[i].active = 0;
}
}
}
min = (Bit64u) -1; // max number in Bit64u range
for (i=0; i < num_timers; i++) {
if (timer[i].active && (timer[i].remaining < min))
min = timer[i].remaining;
}
num_cpu_ticks_in_period = num_cpu_ticks_left = min;
for (i=0; i < num_timers; i++) {
// call requested timer function. It may request a different
// timer period or deactivate, all cases handled below
if (timer[i].triggered) {
timer[i].funct(timer[i].this_ptr);
}
}
}
void
bx_pc_system_c::expire_ticks(void)
{
unsigned i;
Bit64u ticks_delta;
ticks_delta = num_cpu_ticks_in_period - num_cpu_ticks_left;
if (ticks_delta == 0) return; // no ticks occurred since
for (i=0; i<num_timers; i++) {
if (timer[i].active) {
#if BX_TIMER_DEBUG
if (timer[i].remaining <= ticks_delta) {
for (unsigned j=0; j<num_timers; j++) {
BX_INFO(("^^^timer[%u]", j));
BX_INFO(("^^^remaining = %u, period = %u",
timer[j].remaining, timer[j].period));
}
BX_PANIC(("expire_ticks: i=%u, remain(%u) <= delta(%u)",
i, timer[i].remaining, (unsigned) ticks_delta));
}
#endif
timer[i].remaining -= ticks_delta; // must be >= 1 here
}
}
// set new period to number of ticks left
num_cpu_ticks_in_period = num_cpu_ticks_left;
}
int
bx_pc_system_c::register_timer( void *this_ptr, void (*funct)(void *),
Bit32u useconds, Boolean continuous, Boolean active)
{
Bit64u instructions;
if (num_timers >= BX_MAX_TIMERS) {
BX_PANIC(("register_timer: too many registered timers."));
}
if (this_ptr == NULL)
BX_PANIC(("register_timer: this_ptr is NULL"));
if (funct == NULL)
BX_PANIC(("register_timer: funct is NULL"));
// account for ticks up to now
expire_ticks();
// convert useconds to number of instructions
instructions = (Bit64u) (double(useconds) * m_ips);
if((useconds!=0) && (instructions==0)) instructions = 1;
return register_timer_ticks(this_ptr, funct, instructions, continuous, active);
}
int
bx_pc_system_c::register_timer_ticks(void* this_ptr, bx_timer_handler_t funct, Bit64u instructions, Boolean continuous, Boolean active)
{
unsigned i;
if (num_timers >= BX_MAX_TIMERS) {
BX_PANIC(("register_timer: too many registered timers."));
}
if (this_ptr == NULL)
BX_PANIC(("register_timer: this_ptr is NULL"));
if (funct == NULL)
BX_PANIC(("register_timer: funct is NULL"));
i = num_timers;
num_timers++;
timer[i].period = instructions;
timer[i].remaining = instructions;
timer[i].active = active;
timer[i].funct = funct;
timer[i].continuous = continuous;
timer[i].this_ptr = this_ptr;
if (active) {
if (num_cpu_ticks_in_period == 0) {
// no active timers
num_cpu_ticks_in_period = instructions;
num_cpu_ticks_left = instructions;
}
else {
if (instructions < num_cpu_ticks_left) {
num_cpu_ticks_in_period = instructions;
num_cpu_ticks_left = instructions;
}
}
}
// return timer id
return(i);
}
void
bx_pc_system_c::counter_timer_handler(void* this_ptr)
{
UNUSED(this_ptr);
bx_pc_system.counter++;
}
#if BX_DEBUGGER
void
bx_pc_system_c::timebp_handler(void* this_ptr)
{
BX_CPU(0)->break_point = BREAK_POINT_TIME;
BX_DEBUG(( "Time breakpoint triggered" ));
if (timebp_queue_size > 1) {
Bit64s new_diff = timebp_queue[1] - bx_pc_system.time_ticks();
bx_pc_system.activate_timer_ticks(timebp_timer, new_diff, 1);
}
timebp_queue_size--;
for (int i = 0; i < timebp_queue_size; i++)
timebp_queue[i] = timebp_queue[i+1];
}
#endif // BX_DEBUGGER
Bit64u
bx_pc_system_c::time_usec() {
return (Bit64u) (((double)(Bit64s)time_ticks()) / m_ips );
}
Bit64u
bx_pc_system_c::time_ticks()
{
return (counter + 1) * COUNTER_INTERVAL
- ticks_remaining(counter_timer_index)
+ ((Bit64u)num_cpu_ticks_in_period - (Bit64u)num_cpu_ticks_left);
}
void
bx_pc_system_c::start_timers(void)
{
}
void
bx_pc_system_c::activate_timer_ticks (unsigned timer_index, Bit64u instructions, Boolean continuous)
{
if (timer_index >= num_timers)
BX_PANIC(("activate_timer(): bad timer index given"));
// set timer continuity to new value (1=continuous, 0=one-shot)
timer[timer_index].continuous = continuous;
timer[timer_index].active = 1;
timer[timer_index].remaining = instructions;
if (num_cpu_ticks_in_period == 0) {
// no active timers
num_cpu_ticks_in_period = instructions;
num_cpu_ticks_left = instructions;
}
else {
if (instructions < num_cpu_ticks_left) {
num_cpu_ticks_in_period = instructions;
num_cpu_ticks_left = instructions;
}
}
}
void
bx_pc_system_c::activate_timer( unsigned timer_index,
Bit32u useconds, Boolean continuous )
{
Bit64u instructions;
if (timer_index >= num_timers)
BX_PANIC(("activate_timer(): bad timer index given"));
// account for ticks up to now
expire_ticks();
// set timer continuity to new value (1=continuous, 0=one-shot)
timer[timer_index].continuous = continuous;
// if useconds = 0, use default stored in period field
// else set new period from useconds
if (useconds==0)
instructions = timer[timer_index].period;
else {
// convert useconds to number of instructions
instructions = (Bit64u) (double(useconds) * m_ips);
if(instructions==0) instructions = 1;
timer[timer_index].period = instructions;
}
timer[timer_index].active = 1;
timer[timer_index].remaining = instructions;
if (num_cpu_ticks_in_period == 0) {
// no active timers
num_cpu_ticks_in_period = instructions;
num_cpu_ticks_left = instructions;
}
else {
if (instructions < num_cpu_ticks_left) {
num_cpu_ticks_in_period = instructions;
num_cpu_ticks_left = instructions;
}
}
}
void
bx_pc_system_c::deactivate_timer( unsigned timer_index )
{
if (timer_index >= num_timers)
BX_PANIC(("deactivate_timer(): bad timer index given"));
timer[timer_index].active = 0;
}
Reference in New Issue View Git Blame Copy Permalink