AuroraRuntime/Source/Async/WorkItem.cpp

/***
    Copyright (C) 2021 J Reece Wilson (a/k/a "Reece"). All rights reserved.

    File: WorkItem.cpp
    Date: 2021-6-26
    Author: Reece
***/
#include <Source/RuntimeInternal.hpp>
#include "Async.hpp"
#include "WorkItem.hpp"
#include "AsyncApp.hpp"
#include "AuSchedular.hpp"

#if defined(AURORA_COMPILER_CLANG)
    // warning: enumeration values 'kEnumCount' not handled in switch [-Wswitch
    #pragma clang diagnostic ignored "-Wswitch"
    // Yea, I don't give a shit.
#endif

namespace Aurora::Async
{
    FuncWorker::FuncWorker(IThreadPoolInternal *owner,
                           const WorkerPId_t &worker,
                           AuVoidFunc &&func) :
        WorkItem(owner, worker, {}),
        func(func) 
    {
    }

    WorkItem::WorkItem(IThreadPoolInternal *owner,
                       const WorkerPId_t &worker,
                       const AuSPtr<IWorkItemHandler> &task) :
        worker_(worker), task_(task), owner_(owner),
        finishedEvent_(false, true, true)
    {
        this->uShutdownCookie = owner->uAtomicShutdownCookie;

        if (auto pWorker = this->GetState())
        {
            this->optOtherCookie = pWorker->shutdown.uShutdownFence;
        }
    }

    WorkItem::~WorkItem()
    {
        if (auto pIOWatch = AuExchange(this->pIOWatch, {}))
        {
            pIOWatch->StopWatch();
        }
    }

    AuSPtr<IWorkItem> WorkItem::WaitFor(const AuSPtr<IWorkItem> &workItem)
    {
        bool status {};

        {
            auto dependency = AuReinterpretCast<WorkItem>(workItem);

            AU_LOCK_GUARD(this->lock);
            AU_LOCK_GUARD(dependency->lock);

            if (dependency->HasFailed())
            {
                Fail();
                return AU_SHARED_FROM_THIS;
            }

            if (!AuTryInsert(dependency->waiters_, AuSharedFromThis()))
            {
                Fail();
                return AU_SHARED_FROM_THIS;
            }

            if (!AuTryInsert(this->waitOn_, workItem))
            {
                AuTryRemove(dependency->waiters_, AuSharedFromThis());
                Fail();
                return AU_SHARED_FROM_THIS;
            }
        }
        
        return AU_SHARED_FROM_THIS;
    }

    bool WorkItem::WaitForLocked(const AuList<AuSPtr<IWorkItem>> &workItems)
    {
        for (auto &workItem : workItems)
        {
            if (!workItem)
            {
                SysPushErrorArg();
                return false;
            }

            auto dependency = AuReinterpretCast<WorkItem>(workItem);
            AU_LOCK_GUARD(dependency->lock);

            if (dependency->HasFailed())
            {
                return false;
            }

            if (!AuTryInsert(dependency->waiters_, AuSharedFromThis()))
            {
                return false;
            }

            if (!AuTryInsert(this->waitOn_, workItem))
            {
                AuTryRemove(dependency->waiters_, AuSharedFromThis());
                return false;
            }
        }

        return true;
    }

    AuSPtr<IWorkItem> WorkItem::WaitFor(const AuList<AuSPtr<IWorkItem>> &workItems)
    {
        bool status {};

        {
            AU_LOCK_GUARD(this->lock);
            status = WaitForLocked(workItems);
        }

        if (!status)
        {
            Fail();
        }

        return AU_SHARED_FROM_THIS;
    }
    
    AuSPtr<IWorkItem> WorkItem::Then(const AuSPtr<IWorkItem> &next)
    {
        auto that = AU_SHARED_FROM_THIS;
        if (!next)
        {
            SysPushErrorArg();
            return {};
        }
        next->WaitFor(that);
        next->Dispatch();
        return that;
    }
    
    AuSPtr<IWorkItem> WorkItem::SetSchedTimeNs(AuUInt64 ns)
    {
        this->dispatchTimeNs_  = Time::SteadyClockNS() + ns;
        return AU_SHARED_FROM_THIS;
    }
    
    AuSPtr<IWorkItem> WorkItem::SetSchedTimeAbs(AuUInt32 ms)
    {
        return this->SetSchedTimeNsAbs(AuMSToNS<AuUInt64>(ms));
    }

    AuSPtr<IWorkItem> WorkItem::SetSchedTimeNsAbs(AuUInt64 ns)
    {
        auto uNow = AuTime::CurrentClockNS();
        if (uNow > ns)
        {
            return AU_SHARED_FROM_THIS;
        }

        this->dispatchTimeNs_  =  AuTime::SteadyClockNS() + (ns - uNow);
        return AU_SHARED_FROM_THIS;
    }

    AuSPtr<IWorkItem> WorkItem::SetSchedSteadyTimeNsAbs(AuUInt64 ns)
    {
        this->dispatchTimeNs_  =  ns;
        return AU_SHARED_FROM_THIS;
    }

    AuSPtr<IWorkItem> WorkItem::SetSchedByLoopSource(const AuSPtr<IO::Loop::ILoopSource> &pLoopSource)
    {
        this->pIOWatchLS = pLoopSource;
        return AU_SHARED_FROM_THIS;
    }

    AuSPtr<IWorkItem> WorkItem::SetSchedTime(AuUInt32 ms)
    {
        this->dispatchTimeNs_  = Time::SteadyClockNS() + AuMSToNS<AuUInt64>(ms);
        return AU_SHARED_FROM_THIS;
    }
    
    AuSPtr<IWorkItem> WorkItem::AddDelayTime(AuUInt32 ms)
    {
        this->delayTimeNs_ += AuMSToNS<AuUInt64>(ms);
        return AU_SHARED_FROM_THIS;
    }

    AuSPtr<IWorkItem> WorkItem::AddDelayTimeNs(AuUInt64 ns)
    {
        this->delayTimeNs_ += ns;
        return AU_SHARED_FROM_THIS;
    }

    AuSPtr<IWorkItem> WorkItem::Dispatch()
    {
        DispatchEx(false);
        return AU_SHARED_FROM_THIS;
    }

    void WorkItem::DispatchEx(bool check)
    {
        AU_LOCK_GUARD(this->lock);

        DispatchExLocked(check);
    }

    void WorkItem::DispatchExLocked(bool check)
    {
        if (check)
        {
            if (this->dispatchPending_)
            {
                return;
            }
        }

        if (HasFailed())
        {
            return;
        }

        for (auto itr = waitOn_.begin(); itr != waitOn_.end(); )
        {
            auto &waitable = *itr;

            if (!waitable->HasFinished())
            {
                return;
            }
            
            itr = waitOn_.erase(itr);
        }

        this->dispatchPending_ = true;

        if (this->pIOWatchLS)
        {
            if (!this->pIOWatchLS->IsSignaled())
            {
                if (!Schedule())
                {
                    this->Fail();
                }
                return;
            }
            else
            {
                AuResetMember(this->pIOWatchLS);
            }
        }

        if (Time::SteadyClockNS() < this->dispatchTimeNs_)
        {
            if (!Schedule())
            {
                this->Fail();
            }
            return;
        }
        
        if (auto delay = AuExchange(delayTimeNs_, {}))
        {
            this->dispatchTimeNs_ = delay + Time::SteadyClockNS();
            if (!Schedule())
            {
                this->Fail();
            }
            return;
        }

        SendOff();
    }

    EWorkPrio WorkItem::GetPrio()
    {
        return this->prio_;
    }

    void WorkItem::SetPrio(EWorkPrio prio)
    {
        this->prio_ = prio;
    }

    void WorkItem::CancelAsync()
    {
        AU_TRY_LOCK_GUARD_NAMED(this->lock2, asd);
        this->Fail();
    }

    AuOptional<AuPair<AuUInt32, AuUInt32>> WorkItem::QueryFences()
    {
        return AuPair<AuUInt32, AuUInt32>{ this->uShutdownCookie, this->optOtherCookie.ValueOr(0) };
    }

    bool WorkItem::CheckAlive()
    {
        if (this->owner_ &&
           this->uShutdownCookie != this->owner_->uAtomicShutdownCookie)
        {
            this->Fail();
            return false;
        }

        if (this->optOtherCookie)
        {
            if (auto pWorker = this->GetState())
            {
                if (this->optOtherCookie.value() != pWorker->shutdown.uShutdownFence)
                {
                    this->Fail();
                    return false;
                }
            }
        }

        return true;
    }

    void WorkItem::DispatchTask(IWorkItemHandler::ProcessInfo &info)
    {
        if (!this->CheckAlive())
        {
            return;
        }

        if (this->task_)
        {
            try
            {
                this->task_->DispatchFrame(info);
            }
            catch (...)
            {
                // TODO: runtime config for root level exception caught behaviour
                SysPushErrorCatch();
                this->Fail();
                return;
            }
        }
    }

    AuSPtr<ThreadState> WorkItem::GetState()
    {
        if (this->worker_.HasValue())
        {
            return this->owner_->GetThreadHandle(this->worker_.value());
        }
        else
        {
            return {};
        }
    }

    void WorkItem::RunAsyncLocked2()
    {
        AU_LOCK_GUARD(this->lock2);

        IWorkItemHandler::ProcessInfo info(true);
        info.pool = this->owner_->ToThreadPool();

        DispatchTask(info);
 
        RunAsyncLocked2(info);
    }

    void WorkItem::RunAsync()
    {
        AU_LOCK_GUARD(this->lock2);
        RunAsyncLocked();
    }

    void WorkItem::RunAsyncLocked()
    {
        IWorkItemHandler::ProcessInfo info(true);
        info.pool = this->owner_->ToThreadPool();

        DispatchTask(info);

        AU_LOCK_GUARD(this->lock);
        RunAsyncLocked2(info);
    }

    void WorkItem::RunAsyncLocked2(const IWorkItemHandler::ProcessInfo &info)
    {

        switch (info.type)
        {
        case ETickType::eFinished:
        {

            // do nothing
            break;
        }
        case ETickType::eEnumInvalid:
        {
            SysPanic("Handle Invalid");
            break;
        }
        case ETickType::eSchedule:
        {
            if (info.reschedMs)
            {
                SetSchedTime(info.reschedMs);
            } 
            else if (info.reschedNs)
            {
                SetSchedTimeNs(info.reschedNs);
            }
            else if (info.reschedClockAbsMs)
            {
                SetSchedTimeAbs(info.reschedClockAbsMs);
            }
            else if (info.reschedClockAbsNs)
            {
                SetSchedTimeNsAbs(info.reschedClockAbsNs);
            }
            else if (info.reschedSteadyClockAbsNs)
            {
                SetSchedSteadyTimeNsAbs(info.reschedSteadyClockAbsNs);
            }
            else if (info.pLoopSource)
            {
                SetSchedByLoopSource(info.pLoopSource);
            }

            if (!WaitForLocked(info.waitFor))
            {
                this->Fail();
            }
        }
        [[fallthrough]];
        case ETickType::eRerun:
        {
            DispatchExLocked(false);
            return;
        }
        case ETickType::eFailed:
        {
            this->Fail();
            return;
        }
        }

        this->finished = true;

        if (this->finishedEvent_)
        {
            this->finishedEvent_->Set();
        }

        for (auto &waiter : AuExchange(this->waiters_, {}))
        {
            AuReinterpretCast<WorkItem>(waiter)->DispatchExLocked(true);
        }

        this->waitOn_.clear();

        if (auto pIOWatch = AuExchange(this->pIOWatch, {}))
        {
            pIOWatch->StopWatch();
        }

        AuResetMember(this->pIOWatchLS);
    }

    void WorkItem::Fail()
    {
        failed = true;

        if (auto pIOWatch = AuExchange(this->pIOWatch, {}))
        {
            pIOWatch->StopWatch();
        }

        AuResetMember(this->pIOWatchLS);

        if (auto task_ = AuExchange(this->task_, {}))
        {
            task_->OnFailure();
        }

        for (auto &waiter : this->waiters_)
        {
            AuReinterpretCast<WorkItem>(waiter)->Fail();
        }

        this->waiters_.clear();
        this->waitOn_.clear();
     
        if (this->finishedEvent_)
        {
            this->finishedEvent_->Set();
        }
    }
    
    bool WorkItem::BlockUntilComplete()
    {
        if (!this->worker_)
        {
            this->finishedEvent_->Wait();
            return true;
        }

        struct WaitProxy : Threading::IWaitable
        {
            AuThreadPrimitives::IEvent *pEvent {};
            WaitProxy(AuThreadPrimitives::IEvent *pEvent) :
                pEvent(pEvent)
            {

            }
            bool HasOSHandle(AuMach &mach) override
            {
                return this->pEvent->HasOSHandle(mach);
            }
            bool HasLockImplementation() override
            {
                return this->pEvent->HasLockImplementation();
            }
            void Lock() override
            {
                return this->pEvent->Lock();
            }
            bool LockMS(AuUInt64 qwRelTimeoutInMs) override
            {
                return this->pEvent->LockMS(qwRelTimeoutInMs);
            }
            bool LockNS(AuUInt64 qwRelTimeoutInNs) override
            {
                return this->pEvent->LockNS(qwRelTimeoutInNs);
            }
            bool LockAbsMS(AuUInt64 qwAbsTimeoutInMs) override
            {
                return this->pEvent->LockAbsMS(qwAbsTimeoutInMs);
            }
            bool LockAbsNS(AuUInt64 qwAbsTimeoutInNs) override
            {
                return this->pEvent->LockAbsNS(qwAbsTimeoutInNs);
            }
            bool TryLock() override
            {
                return this->pEvent->TryLock();
            }
            void Unlock() override
            {
                // PATCH: ensure release notifications set the event!
                this->pEvent->Set();
            }
        } waitProxy(this->finishedEvent_.AsPointer());

        return this->owner_->WaitFor(this->worker_.value(),
                                     AuUnsafeRaiiToShared(&waitProxy),
                                     0 /*forever*/);
    }
    
    bool WorkItem::HasFinished()
    {
        return this->finished;
    }

    void WorkItem::Cancel()
    {
        AU_LOCK_GUARD(this->lock2);
        Fail();
    }

    bool WorkItem::HasFailed()
    {
        return this->failed;
    }
    
    bool WorkItem::Schedule()
    {
        if (auto pLoopSource = this->pIOWatchLS)
        {
            if (this->pIOWatch)
            {
                return true;
            }

            auto pState = this->GetState();
            if (!pState)
            {
                return false;
            }

            auto pIOProcessor = pState->singletons.GetIOProcessor(this->worker_.value());
            if (!pIOProcessor)
            {
                return false;
            }

            this->pIOWatch = pIOProcessor->StartSimpleLSWatch(pLoopSource, AuMakeSharedThrow<AuIO::IIOSimpleEventListenerFunctional>([=]()
            {
                this->Dispatch();
            }, [=]()
            {
                this->Dispatch();
            }, [=]()
            {
                this->Dispatch();
            }));

            if (!this->pIOWatch)
            {
                return false;
            }

            return true;
        }
        else
        {
            return Async::Schedule(this->dispatchTimeNs_, this->owner_, this->worker_.value(), AuSharedFromThis());
        }
    }

    void WorkItem::SendOff()
    {
        if (!this->worker_)
        {
            // If we aren't actually calling a task interface, we may as well just dispatch objects waiting on us from here
            RunAsyncLocked2();
        }
        else
        {
            this->owner_->Run(this->worker_.value(), AuSharedFromThis());
        }
    }

    inline auto ToInternal(const AuSPtr<IThreadPool> &pool)
    {
        return AuStaticPointerCast<ThreadPool>(pool);
    }

    void FuncWorker::DispatchTask(IWorkItemHandler::ProcessInfo &info)
    {
        auto func = AuExchange(this->func, {});

        if (!this->CheckAlive())
        {
            return;
        }

        if (func)
        {
            func();
        }
    }

    AUKN_SYM AuSPtr<IWorkItem> NewWorkItem(const WorkerId_t &worker, const AuSPtr<IWorkItemHandler> &task)
    {
        AU_DEBUG_MEMCRUNCH;

        if (!task)
        {
            SysPushErrorArg("WorkItem has null task. Running out of memory?");
            return {};
        }

        auto pWorker = GetCurrentWorkerPId().pool;
        if (!pWorker)
        {
            pWorker = AuUnsafeRaiiToShared(static_cast<IAsyncApp *>(gAsyncApp));
        }

        return AuMakeShared<WorkItem>(ToInternal(pWorker).get(), WorkerPId_t { pWorker , worker }, task);
    }

    AUKN_SYM AuSPtr<IWorkItem> NewWorkFunction(const WorkerPId_t &worker, AuVoidFunc func)
    {
        AU_DEBUG_MEMCRUNCH;

        if (!func)
        {
            SysPushErrorArg("WorkItem has null function");
            return {};
        }

        auto pWorker = worker.pool;
        if (!pWorker)
        {
            pWorker = GetCurrentWorkerPId().pool; 
        }

        if (!pWorker)
        {
            pWorker = AuUnsafeRaiiToShared(static_cast<IAsyncApp *>(gAsyncApp));
        }

        return AuMakeSharedThrow<FuncWorker>(ToInternal(pWorker).get(), worker, AuMove(func));
    }

    AUKN_SYM AuSPtr<IWorkItem> NewWorkItem(const WorkerPId_t &worker, const AuSPtr<IWorkItemHandler> &task)
    {
        AU_DEBUG_MEMCRUNCH;

        if (!task)
        {
            SysPushErrorArg("WorkItem has null task. Running out of memory?");
            return {};
        }

        auto pWorker = worker.pool;
        if (!pWorker)
        {
            pWorker = GetCurrentWorkerPId().pool;
        }

        if (!pWorker)
        {
            pWorker = AuUnsafeRaiiToShared(static_cast<IAsyncApp *>(gAsyncApp));
        }

        return AuMakeSharedThrow<WorkItem>(ToInternal(pWorker).get(), worker, task);
    }

    AUKN_SYM AuSPtr<IWorkItem> NewFence()
    {
        auto pWorker = GetCurrentWorkerPId().pool;
        if (!pWorker)
        {
            pWorker = AuUnsafeRaiiToShared(static_cast<IAsyncApp *>(gAsyncApp));
        }
        return AuMakeShared<WorkItem>((IThreadPoolInternal *)ToInternal(pWorker).get(), WorkerPId_t {}, AuSPtr<IWorkItemHandler>{});
    }
    
    void *WorkItem::GetPrivateData()
    {
        if (!this->task_)
        {
            return nullptr;
        }
 
        return this->task_->GetPrivateData();
    }
}