// Block while the queue is empty, then return the head of the queue.
public ServiceRequest Dequeue()
{
while (true)
{
// For now disable interrupts:
bool iflag = Processor.DisableInterrupts();
spinLock.Acquire();
try {
if (tail != null)
{
ServiceRequest req = head;
if (req != tail)
{
head = req.next;
}
else
{
head = null;
tail = null;
}
return(req);
}
}
finally {
spinLock.Release();
// Reenable interrupts
Processor.RestoreInterrupts(iflag);
}
// Wait on event
enqueueEvent.InterruptAwareWaitOne();
}
}
public static void AddBytesSent(long bytes)
{
bool iflag = Processor.DisableInterrupts();
bytesSent += bytes;
Processor.RestoreInterrupts(iflag);
}
public void Enqueue(ServiceRequest req)
{
// For now disable interrupts:
bool iflag = Processor.DisableInterrupts();
spinLock.Acquire();
try {
if (head == null)
{
head = req;
tail = req;
}
else
{
tail.next = req;
tail = req;
}
}
finally {
spinLock.Release();
}
// Signal an event : for now it is possible that it can be spirous one...
enqueueEvent.InterruptAwareSet();
// Reenable interrupts
Processor.RestoreInterrupts(iflag);
}
private static void FinalizeServices()
{
ARM_PROGRESS("Kernel!075");
Tracing.Log(Tracing.Audit, "Shutting down AP processors");
Processor.StopApProcessors();
Tracing.Log(Tracing.Audit, "Shutting down I/O system");
Console.WriteLine("Shutting down I/O system");
IoSystem.Finalize();
Tracing.Log(Tracing.Audit, "Interrupts OFF.");
Processor.DisableInterrupts();
Tracing.Log(Tracing.Audit, "Shutting down scheduler");
Console.WriteLine("Shutting down scheduler");
for (int i = 0; i < Processor.processorTable.Length; i++)
{
Processor p = Processor.processorTable[i];
if (p != null)
{
Console.WriteLine(" cpu {0}: {1} context switches, {2} interrupts", i, p.NumContextSwitches, p.NumInterrupts);
}
}
// Finalize the scheduler
scheduler.Finalize();
// We should turn off interrupts here!
Platform.ReleaseResources();
PEImage.Finalize();
DebugStub.WriteLine("Kernel Exiting [{0}]",
__arglist(bootReturnCode));
}
static internal unsafe void GCSynchronizationInterrupt()
{
// - member barriers and other issues with spinwaiting on a variable
bool en = Processor.DisableInterrupts();
//DebugStub.WriteLine("Processor {0} received GCSynchronizationInterrupt!\n",
//__arglist(Processor.GetCurrentProcessorId()));
ProcessorContext *current = Processor.GetCurrentProcessorContext();
// Write value for this processor stating we ackknowledge the interrupt
current->gcIpiGate = 1;
// Question: Are we at a GC safe point? For all GC's?
//
// Spinwait until the GC processor indicates its done by clearing
// this flag.
//
while (current->gcIpiGate != 0)
{
//
}
Processor.RestoreInterrupts(en);
//DebugStub.WriteLine("Processor {0} done with GCSynchronizationInterrupt!\n",
//__arglist(Processor.GetCurrentProcessorId()));
return;
}
public void SetNextTimerInterrupt(TimeSpan delta)
{
// Make sure that interrupts are disabled
bool iflag = Processor.DisableInterrupts();
TimeSpan start = delta;
if (delta < timer.MinInterruptInterval)
{
delta = timer.MinInterruptInterval;
}
if (delta > timer.MaxInterruptInterval)
{
delta = timer.MaxInterruptInterval;
}
#if false
DebugStub.WriteLine("-- SetNextTimerInterrupt(delta={0}, start={1} [min={2},max={3})",
__arglist(delta.Ticks,
start.Ticks,
timer.MinInterruptInterval.Ticks,
timer.MaxInterruptInterval.Ticks));
#endif
timer.SetNextInterrupt(delta);
// Restore interrupts if necessary
Processor.RestoreInterrupts(iflag);
}
private static void ApServiceLoop()
{
DebugStub.WriteLine("ApServiceThread is initialized and sleeping ...");
MpExecution.MpCall mpCall;
bool iflag;
while (true)
{
abiEvent.WaitOne();
DebugStub.WriteLine
("HSG: ** cpu.{0} receives AbiCall interrupt",
__arglist(Processor.GetCurrentProcessorId()));
// Current design: the boot processor will get all
// unserved abi call. So we don't need to worry
// missing any calls
while (true)
{
iflag = Processor.DisableInterrupts();
mpCall = MpExecution.GetMpCall(Processor.GetCurrentProcessorId());
Processor.RestoreInterrupts(iflag);
// There is no unserved abi call, just break
if (mpCall == null)
{
break;
}
BspAbiStub.ProcessMpCall(Processor.GetCurrentProcessorId(), mpCall);
}
}
}
public static bool DisableInterrupts()
{
if ((ProcessPrivileges.GetCurrentPrivileges().AllowedOperations &
ProcessPrivileges.Operations.DisableInterrupts) != 0)
{
return(Processor.DisableInterrupts());
}
// ISSUE: Assert here until all instances get cleaned up from SIPs
// This assertion should be removed / replaced with something that would
// flag / halt / break only the bogus SIP, not the entire system
VTable.Assert(false, "DisableInterrupts called from unprivileged SIP");
return(false);
}
public static void WaypointDump()
{
bool iflag = Processor.DisableInterrupts();
DebugStub.WriteLine("Interrupts: {0}",
__arglist(Processor.CurrentProcessor.NumInterrupts
- WaypointInterrupt));
DebugStub.WriteLine("WPT Waypoint Sequence THD Diff");
for (int i = 1; i < WaypointNumber; i++)
{
DebugStub.WriteLine("{0,3:d} {1,10:d} {2,10:d} {3,3:d} {4,10:d}",
__arglist(
i,
Waypoints[i],
WaypointSeq[i],
WaypointThd[i].GetHashCode(),
Waypoints[i] - Kernel.Waypoints[i - 1]));
}
Processor.RestoreInterrupts(iflag);
}