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/*
* Copyright 2018 Google, Inc.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions are
* met: redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer;
* redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in the
* documentation and/or other materials provided with the distribution;
* neither the name of the copyright holders nor the names of its
* contributors may be used to endorse or promote products derived from
* this software without specific prior written permission.
*
* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
* "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
* LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR
* A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT
* OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
* SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT
* LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
* DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
* THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
* (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
* OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
*
* Authors: Gabe Black
*/
#ifndef __SYSTEMC_CORE_SCHEDULER_HH__
#define __SYSTEMC_CORE_SCHEDULER_HH__
#include <vector>
#include "base/logging.hh"
#include "sim/eventq.hh"
#include "systemc/core/channel.hh"
#include "systemc/core/list.hh"
#include "systemc/core/process.hh"
class Fiber;
namespace sc_gem5
{
typedef NodeList<Process> ProcessList;
typedef NodeList<Channel> ChannelList;
/*
* The scheduler supports three different mechanisms, the initialization phase,
* delta cycles, and timed notifications.
*
* INITIALIZATION PHASE
*
* The initialization phase has three parts:
* 1. Run requested channel updates.
* 2. Make processes which need to initialize runnable (methods and threads
* which didn't have dont_initialize called on them).
* 3. Process delta notifications.
*
* First, the Kernel SimObject calls the update() method during its startup()
* callback which handles the requested channel updates. The Kernel also
* schedules an event to be run at time 0 with a slightly elevated priority
* so that it happens before any "normal" event.
*
* When that t0 event happens, it calls the schedulers prepareForInit method
* which performs step 2 above. That indirectly causes the scheduler's
* readyEvent to be scheduled with slightly lowered priority, ensuring it
* happens after any "normal" event.
*
* Because delta notifications are scheduled at the standard priority, all
* of those events will happen next, performing step 3 above. Once they finish,
* if the readyEvent was scheduled above, there shouldn't be any higher
* priority events in front of it. When it runs, it will start the first
* evaluate phase of the first delta cycle.
*
* DELTA CYCLE
*
* A delta cycle has three phases within it.
* 1. The evaluate phase where runnable processes are allowed to run.
* 2. The update phase where requested channel updates hapen.
* 3. The delta notification phase where delta notifications happen.
*
* The readyEvent runs the first two steps of the delta cycle. It first goes
* through the list of runnable processes and executes them until the set is
* empty, and then immediately runs the update phase. Since these are all part
* of the same event, there's no chance for other events to intervene and
* break the required order above.
*
* During the update phase above, the spec forbids any action which would make
* a process runnable. That means that once the update phase finishes, the set
* of runnable processes will be empty. There may, however, have been some
* delta notifications/timeouts which will have been scheduled during either
* the evaluate or update phase above. Because those are scheduled at the
* normal priority, they will now happen together until there aren't any
* delta events left.
*
* If any processes became runnable during the delta notification phase, the
* readyEvent will have been scheduled and will have been waiting patiently
* behind the delta notification events. That will now run, effectively
* starting the next delta cycle.
*
* TIMED NOTIFICATION PHASE
*
* If no processes became runnable, the event queue will continue to process
* events until it comes across a timed notification, aka a notification
* scheduled to happen in the future. Like delta notification events, those
* will all happen together since the readyEvent priority is lower,
* potentially marking new processes as ready. Once these events finish, the
* readyEvent may run, starting the next delta cycle.
*
* PAUSE/STOP
*
* To inject a pause from sc_pause which should happen after the current delta
* cycle's delta notification phase, an event is scheduled with a lower than
* normal priority, but higher than the readyEvent. That ensures that any
* delta notifications which are scheduled with normal priority will happen
* first, since those are part of the current delta cycle. Then the pause
* event will happen before the next readyEvent which would start the next
* delta cycle. All of these events are scheduled for the current time, and so
* would happen before any timed notifications went off.
*
* To inject a stop from sc_stop, the delta cycles should stop before even the
* delta notifications have happened, but after the evaluate and update phases.
* For that, a stop event with slightly higher than normal priority will be
* scheduled so that it happens before any of the delta notification events
* which are at normal priority.
*
* MAX RUN TIME
*
* When sc_start is called, it's possible to pass in a maximum time the
* simulation should run to, at which point sc_pause is implicitly called. The
* simulation is supposed to run up to the latest timed notification phase
* which is less than or equal to the maximum time. In other words it should
* run timed notifications at the maximum time, but not the subsequent evaluate
* phase. That's implemented by scheduling an event at the max time with a
* priority which is lower than all the others except the ready event. Timed
* notifications will happen before it fires, but it will override any ready
* event and prevent the evaluate phase from starting.
*/
class Scheduler
{
public:
Scheduler();
const std::string name() const { return "systemc_scheduler"; }
uint64_t numCycles() { return _numCycles; }
Process *current() { return _current; }
// Prepare for initialization.
void prepareForInit();
// Register a process with the scheduler.
void reg(Process *p);
// Tell the scheduler not to initialize a process.
void dontInitialize(Process *p);
// Run the next process, if there is one.
void yield();
// Put a process on the ready list.
void ready(Process *p);
// Schedule an update for a given channel.
void requestUpdate(Channel *c);
// Run the given process immediately, preempting whatever may be running.
void
runNow(Process *p)
{
// If a process is running, schedule it/us to run again.
if (_current)
readyList.pushFirst(_current);
// Schedule p to run first.
readyList.pushFirst(p);
yield();
}
// Set an event queue for scheduling events.
void setEventQueue(EventQueue *_eq) { eq = _eq; }
// Get the current time according to gem5.
Tick getCurTick() { return eq ? eq->getCurTick() : 0; }
// For scheduling delayed/timed notifications/timeouts.
void
schedule(::Event *event, Tick tick)
{
pendingTicks[tick]++;
if (initReady)
eq->schedule(event, tick);
else
eventsToSchedule[event] = tick;
}
// For descheduling delayed/timed notifications/timeouts.
void
deschedule(::Event *event)
{
auto it = pendingTicks.find(event->when());
if (--it->second == 0)
pendingTicks.erase(it);
if (initReady)
eq->deschedule(event);
else
eventsToSchedule.erase(event);
}
// Tell the scheduler than an event fired for bookkeeping purposes.
void
eventHappened()
{
auto it = pendingTicks.begin();
if (--it->second == 0)
pendingTicks.erase(it);
if (starved() && !runToTime)
scheduleStarvationEvent();
}
// Pending activity ignores gem5 activity, much like how a systemc
// simulation wouldn't know about asynchronous external events (socket IO
// for instance) that might happen before time advances in a pure
// systemc simulation. Also the spec lists what specific types of pending
// activity needs to be counted, which obviously doesn't include gem5
// events.
// Return whether there's pending systemc activity at this time.
bool
pendingCurr()
{
if (!readyList.empty() || !updateList.empty())
return true;
return pendingTicks.size() &&
pendingTicks.begin()->first == getCurTick();
}
// Return whether there are pending timed notifications or timeouts.
bool
pendingFuture()
{
switch (pendingTicks.size()) {
case 0: return false;
case 1: return pendingTicks.begin()->first > getCurTick();
default: return true;
}
}
// Return how many ticks there are until the first pending event, if any.
Tick
timeToPending()
{
if (!readyList.empty() || !updateList.empty())
return 0;
else if (pendingTicks.size())
return pendingTicks.begin()->first - getCurTick();
else
return MaxTick - getCurTick();
}
// Run scheduled channel updates.
void update();
void setScMainFiber(Fiber *sc_main) { scMain = sc_main; }
void start(Tick max_tick, bool run_to_time);
void schedulePause();
void scheduleStop(bool finish_delta);
bool paused() { return _paused; }
bool stopped() { return _stopped; }
private:
typedef const EventBase::Priority Priority;
static Priority DefaultPriority = EventBase::Default_Pri;
static Priority StopPriority = DefaultPriority - 1;
static Priority PausePriority = DefaultPriority + 1;
static Priority MaxTickPriority = DefaultPriority + 2;
static Priority ReadyPriority = DefaultPriority + 3;
static Priority StarvationPriority = ReadyPriority;
EventQueue *eq;
std::map<Tick, int> pendingTicks;
void runReady();
EventWrapper<Scheduler, &Scheduler::runReady> readyEvent;
void scheduleReadyEvent();
void pause();
void stop();
EventWrapper<Scheduler, &Scheduler::pause> pauseEvent;
EventWrapper<Scheduler, &Scheduler::stop> stopEvent;
Fiber *scMain;
bool
starved()
{
return (readyList.empty() && updateList.empty() &&
(pendingTicks.empty() ||
pendingTicks.begin()->first > maxTick) &&
initList.empty());
}
EventWrapper<Scheduler, &Scheduler::pause> starvationEvent;
void scheduleStarvationEvent();
bool _started;
bool _paused;
bool _stopped;
Tick maxTick;
EventWrapper<Scheduler, &Scheduler::pause> maxTickEvent;
uint64_t _numCycles;
Process *_current;
bool initReady;
bool runToTime;
ProcessList initList;
ProcessList toFinalize;
ProcessList readyList;
ChannelList updateList;
std::map<::Event *, Tick> eventsToSchedule;
};
extern Scheduler scheduler;
} // namespace sc_gem5
#endif // __SYSTEMC_CORE_SCHEDULER_H__
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