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#include <library/cpp/grpc/server/grpc_request.h>
#include <library/cpp/testing/unittest/registar.h>
#include <library/cpp/testing/unittest/tests_data.h>
 
#include <util/system/thread.h> 
#include <util/thread/pool.h> 
 
using namespace NGrpc;
 
// Here we emulate stream data producer 
class TOrderedProducer: public TThread {
public: 
    TOrderedProducer(IStreamAdaptor* adaptor, ui64 max, bool withSleep, std::function<void(ui64)>&& consumerOp) 
        : TThread(&ThreadProc, this) 
        , Adaptor_(adaptor) 
        , Max_(max) 
        , WithSleep_(withSleep) 
        , ConsumerOp_(std::move(consumerOp)) 
    {} 
 
    static void* ThreadProc(void* _this) { 
        SetCurrentThreadName("OrderedProducerThread"); 
        static_cast<TOrderedProducer*>(_this)->Exec(); 
        return nullptr; 
    } 
 
    void Exec() { 
        for (ui64 i = 0; i < Max_; i++) { 
            auto cb = [i, this]() mutable { 
                ConsumerOp_(i); 
            }; 
            Adaptor_->Enqueue(std::move(cb), false); 
            if (WithSleep_ && (i % 256 == 0)) { 
                Sleep(TDuration::MilliSeconds(10)); 
            } 
        } 
    } 
 
private: 
    IStreamAdaptor* Adaptor_; 
    const ui64 Max_; 
    const bool WithSleep_; 
    std::function<void(ui64)> ConsumerOp_; 
}; 
 
Y_UNIT_TEST_SUITE(StreamAdaptor) { 
    static void OrderingTest(size_t threads, bool withSleep) { 
 
        auto adaptor = CreateStreamAdaptor(); 
 
        const i64 max = 10000; 
 
        // Here we will emulate grpc stream (NextReply call after writing) 
        std::unique_ptr<IThreadPool> consumerQueue(new TThreadPool(TThreadPool::TParams().SetBlocking(false).SetCatching(false)));
        // And make sure only one request inflight (see UNIT_ASSERT on adding to the queue) 
        consumerQueue->Start(threads, 1); 
 
        // Non atomic!!! Stream adaptor must protect us 
        ui64 curVal = 0; 
 
        // Used just to wait in the main thread 
        TAtomic finished = false; 
        auto consumerOp = [&finished, &curVal, ptr{adaptor.get()}, queue{consumerQueue.get()}](ui64 i) { 
            // Check no reordering inside stream adaptor 
            // and no simultanious consumer Op call 
            UNIT_ASSERT_VALUES_EQUAL(curVal, i); 
            curVal++; 
            // We must set finished flag after last ProcessNext, but we can`t compare curVal and max after ProcessNext 
            // so compare here and set after 
            bool tmp = curVal == max; 
            bool res = queue->AddFunc([ptr, &finished, tmp, &curVal, i]() { 
                // Additional check the value still same 
                // run under tsan makes sure no consumer Op call before we call ProcessNext 
                UNIT_ASSERT_VALUES_EQUAL(curVal, i + 1); 
                ptr->ProcessNext(); 
                // Reordering after ProcessNext is possible, so check tmp and set finished to true 
                if (tmp) 
                    AtomicSet(finished, true); 
            }); 
            UNIT_ASSERT(res); 
        }; 
 
        TOrderedProducer producer(adaptor.get(), max, withSleep, std::move(consumerOp)); 
 
        producer.Start(); 
        producer.Join(); 
 
        while (!AtomicGet(finished)) 
        { 
            Sleep(TDuration::MilliSeconds(100)); 
        } 
 
        consumerQueue->Stop(); 
 
        UNIT_ASSERT_VALUES_EQUAL(curVal, max); 
    } 
 
    Y_UNIT_TEST(OrderingOneThread) { 
        OrderingTest(1, false); 
    } 
 
    Y_UNIT_TEST(OrderingTwoThreads) { 
        OrderingTest(2, false); 
    } 
 
    Y_UNIT_TEST(OrderingManyThreads) { 
        OrderingTest(10, false); 
    } 
 
    Y_UNIT_TEST(OrderingOneThreadWithSleep) { 
        OrderingTest(1, true); 
    } 
 
    Y_UNIT_TEST(OrderingTwoThreadsWithSleep) { 
        OrderingTest(2, true); 
    } 
 
    Y_UNIT_TEST(OrderingManyThreadsWithSleep) { 
        OrderingTest(10, true); 
    } 
}