//-------------------------------------------------
// postload - after loading a save state
//-------------------------------------------------
void postload()
{
// remove all timers and make a private list of permanent ones
simple_list <emu_timer> private_list = new simple_list <emu_timer>();
while (m_timer_list != null)
{
emu_timer timer = m_timer_list;
// temporary timers go away entirely (except our special never-expiring one)
if (timer.m_temporary && !timer.expire().is_never())
{
m_timer_allocator.reclaim(timer.release());
}
// permanent ones get added to our private list
else
{
private_list.append(timer_list_remove(timer));
}
}
{
// now re-insert them; this effectively re-sorts them by time
emu_timer timer;
while ((timer = private_list.detach_head()) != null)
{
timer_list_insert(timer);
}
}
m_suspend_changes_pending = true;
rebuild_execute_list();
// report the timer state after a log
LOG("After resetting/reordering timers:\n");
#if VERBOSE
dump_timers();
#endif
}
// execution
//-------------------------------------------------
// timeslice - execute all devices for a single
// timeslice
//-------------------------------------------------
public void timeslice()
{
bool call_debugger = (machine().debug_flags & DEBUG_FLAG_ENABLED) != 0;
// build the execution list if we don't have one yet
//if (UNEXPECTED(m_execute_list == null))
if (m_execute_list == null)
{
rebuild_execute_list();
}
// if the current quantum has expired, find a new one
while (m_basetime >= m_quantum_list.first().expire())
{
m_quantum_allocator.reclaim(m_quantum_list.detach_head());
}
// loop until we hit the next timer
while (m_basetime < m_timer_list.expire())
{
// by default, assume our target is the end of the next quantum
attotime target = m_basetime + new attotime(0, m_quantum_list.first().actual());
// however, if the next timer is going to fire before then, override
if (m_timer_list.expire() < target)
{
target = m_timer_list.expire();
}
if (machine().video().frame_update_count() % 1000 == 0)
{
//LOG(("------------------\n"));
LOG("device_scheduler.timeslice() - cpu_timeslice: target = {0}, m_timer_list.expire: {1}\n", target.as_string(), m_timer_list.expire().as_string());
}
// do we have pending suspension changes?
if (m_suspend_changes_pending)
{
apply_suspend_changes();
}
// loop over all CPUs
for (device_execute_interface exec = m_execute_list; exec != null; exec = exec.m_nextexec)
{
// only process if this CPU is executing or truly halted (not yielding)
// and if our target is later than the CPU's current time (coarse check)
if ((exec.m_suspend == 0 || exec.m_eatcycles > 0) && target.seconds() >= exec.m_localtime.seconds()) //if (EXPECTED((exec->m_suspend == 0 || exec->m_eatcycles) && target.seconds() >= exec->m_localtime.seconds()))
{
// compute how many attoseconds to execute this CPU
attoseconds_t delta = target.attoseconds() - exec.m_localtime.attoseconds();
if (delta < 0 && target.seconds() > exec.m_localtime.seconds())
{
delta += ATTOSECONDS_PER_SECOND;
}
assert(delta == (target - exec.m_localtime).as_attoseconds());
if (exec.m_attoseconds_per_cycle == 0)
{
exec.m_localtime = target;
}
// if we have enough for at least 1 cycle, do the math
else if (delta >= exec.m_attoseconds_per_cycle)
{
// compute how many cycles we want to execute
int ran = exec.m_cycles_running = (int)divu_64x32((u64)delta >> exec.m_divshift, (u32)exec.m_divisor);
if (machine().video().frame_update_count() % 1000 == 0)
{
LOG("device_scheduler.timeslice() - cpu '{0}': {1} ({2} cycles)\n", exec.device().tag(), delta, exec.m_cycles_running);
}
// if we're not suspended, actually execute
if (exec.m_suspend == 0)
{
g_profiler.start(exec.m_profiler);
// note that this global variable cycles_stolen can be modified
// via the call to cpu_execute
exec.m_cycles_stolen = 0;
m_executing_device = exec;
exec.m_icountptr.i = exec.m_cycles_running; // *exec->m_icountptr = exec->m_cycles_running;
if (!call_debugger)
{
exec.run();
}
else
{
exec.debugger_start_cpu_hook(target);
exec.run();
exec.debugger_stop_cpu_hook();
}
// adjust for any cycles we took back
//throw new emu_unimplemented();
#if false
assert(ran >= *exec->m_icountptr);
#endif
ran -= exec.m_icountptr.i; //ran -= *exec->m_icountptr;
//throw new emu_unimplemented();
#if false
assert(ran >= exec->m_cycles_stolen);
#endif
ran -= exec.m_cycles_stolen;
g_profiler.stop();
}
// account for these cycles
exec.m_totalcycles += (u64)ran;
// update the local time for this CPU
attotime deltatime;
if (ran < exec.m_cycles_per_second)
{
deltatime = new attotime(0, exec.m_attoseconds_per_cycle * ran);
}
else
{
u32 remainder;
s32 secs = (s32)divu_64x32_rem((u64)ran, exec.m_cycles_per_second, out remainder);
deltatime = new attotime(secs, remainder * exec.m_attoseconds_per_cycle);
}
assert(deltatime >= attotime.zero);
exec.m_localtime += deltatime;
if (machine().video().frame_update_count() % 100 == 0)
{
LOG("device_scheduler.timeslice() - {0} ran, {1} total, time = {2}\n", ran, exec.m_totalcycles, exec.m_localtime.as_string());
}
// if the new local CPU time is less than our target, move the target up, but not before the base
if (exec.m_localtime < target)
{
target = std.max(exec.m_localtime, m_basetime);
if (machine().video().frame_update_count() % 1000 == 0)
{
LOG("device_scheduler.timeslice() - (new target)\n");
}
}
}
}
}
m_executing_device = null;
// update the base time
m_basetime = target;
}
// execute timers
execute_timers();
}
