path: root/src/mongo/dbtests/threadedtests.cpp

// @file threadedtests.cpp - Tests for threaded code
//

/**
 *    Copyright (C) 2008 10gen Inc.
 *
 *    This program is free software: you can redistribute it and/or  modify
 *    it under the terms of the GNU Affero General Public License, version 3,
 *    as published by the Free Software Foundation.
 *
 *    This program is distributed in the hope that it will be useful,
 *    but WITHOUT ANY WARRANTY; without even the implied warranty of
 *    MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
 *    GNU Affero General Public License for more details.
 *
 *    You should have received a copy of the GNU Affero General Public License
 *    along with this program.  If not, see <http://www.gnu.org/licenses/>.
 *
 *    As a special exception, the copyright holders give permission to link the
 *    code of portions of this program with the OpenSSL library under certain
 *    conditions as described in each individual source file and distribute
 *    linked combinations including the program with the OpenSSL library. You
 *    must comply with the GNU Affero General Public License in all respects
 *    for all of the code used other than as permitted herein. If you modify
 *    file(s) with this exception, you may extend this exception to your
 *    version of the file(s), but you are not obligated to do so. If you do not
 *    wish to do so, delete this exception statement from your version. If you
 *    delete this exception statement from all source files in the program,
 *    then also delete it in the license file.
 */

#define MONGO_LOG_DEFAULT_COMPONENT ::mongo::logger::LogComponent::kCommand

#include "mongo/platform/basic.h"

#include <boost/version.hpp>
#include <iostream>

#include "mongo/config.h"
#include "mongo/db/client.h"
#include "mongo/db/concurrency/d_concurrency.h"
#include "mongo/db/concurrency/lock_state.h"
#include "mongo/db/operation_context_impl.h"
#include "mongo/dbtests/dbtests.h"
#include "mongo/platform/atomic_word.h"
#include "mongo/platform/bits.h"
#include "mongo/stdx/functional.h"
#include "mongo/stdx/thread.h"
#include "mongo/util/concurrency/old_thread_pool.h"
#include "mongo/util/concurrency/rwlock.h"
#include "mongo/util/concurrency/synchronization.h"
#include "mongo/util/concurrency/old_thread_pool.h"
#include "mongo/util/concurrency/ticketholder.h"
#include "mongo/util/log.h"
#include "mongo/util/timer.h"

namespace ThreadedTests {

using std::unique_ptr;
using std::cout;
using std::endl;
using std::string;

template <int nthreads_param = 10>
class ThreadedTest {
public:
    virtual void setup() {}                     // optional
    virtual void subthread(int remaining) = 0;  // each thread whatever test work you want done
    virtual void validate() = 0;                // after work is done

    static const int nthreads = nthreads_param;

    void run() {
        setup();
        launch_subthreads(nthreads);
        validate();
    }

    virtual ~ThreadedTest(){};  // not necessary, but makes compilers happy

private:
    void launch_subthreads(int remaining) {
        if (!remaining)
            return;

        stdx::thread athread(stdx::bind(&ThreadedTest::subthread, this, remaining));
        launch_subthreads(remaining - 1);
        athread.join();
    }
};


#ifdef MONGO_PLATFORM_32
// Avoid OOM on Linux-32 by using fewer threads
const int nthr = 45;
#else
const int nthr = 135;
#endif
class MongoMutexTest : public ThreadedTest<nthr> {
#if defined(MONGO_CONFIG_DEBUG_BUILD)
    enum { N = 2000 };
#else
    enum { N = 4000 /*0*/ };
#endif
    ProgressMeter pm;

public:
    MongoMutexTest() : pm(N * nthreads) {}

    void run() {
        Timer t;
        cout << "MongoMutexTest N:" << N << endl;
        ThreadedTest<nthr>::run();
        cout << "MongoMutexTest " << t.millis() << "ms" << endl;
    }

private:
    virtual void subthread(int tnumber) {
        Client::initThread("mongomutextest");

        OperationContextImpl txn;

        sleepmillis(0);
        for (int i = 0; i < N; i++) {
            int x = std::rand();
            bool sometimes = (x % 15 == 0);
            if (i % 7 == 0) {
                Lock::GlobalRead r(txn.lockState());  // nested test
                Lock::GlobalRead r2(txn.lockState());
            } else if (i % 7 == 1) {
                Lock::GlobalRead r(txn.lockState());
                ASSERT(txn.lockState()->isReadLocked());
            } else if (i % 7 == 4 && tnumber == 1 /*only one upgrader legal*/) {
                Lock::GlobalWrite w(txn.lockState());
                ASSERT(txn.lockState()->isW());
                if (i % 7 == 2) {
                    Lock::TempRelease t(txn.lockState());
                }
            } else if (i % 7 == 2) {
                Lock::GlobalWrite w(txn.lockState());
                ASSERT(txn.lockState()->isW());
                if (sometimes) {
                    Lock::TempRelease t(txn.lockState());
                }
            } else if (i % 7 == 3) {
                Lock::GlobalWrite w(txn.lockState());
                { Lock::TempRelease t(txn.lockState()); }
                Lock::GlobalRead r(txn.lockState());
                ASSERT(txn.lockState()->isW());
                if (sometimes) {
                    Lock::TempRelease t(txn.lockState());
                }
            } else if (i % 7 == 5) {
                {
                    ScopedTransaction scopedXact(&txn, MODE_IS);
                    Lock::DBLock r(txn.lockState(), "foo", MODE_S);
                }
                {
                    ScopedTransaction scopedXact(&txn, MODE_IS);
                    Lock::DBLock r(txn.lockState(), "bar", MODE_S);
                }
            } else if (i % 7 == 6) {
                if (i > N / 2) {
                    int q = i % 11;
                    if (q == 0) {
                        ScopedTransaction scopedXact(&txn, MODE_IS);

                        Lock::DBLock r(txn.lockState(), "foo", MODE_S);
                        ASSERT(txn.lockState()->isDbLockedForMode("foo", MODE_S));

                        Lock::DBLock r2(txn.lockState(), "foo", MODE_S);
                        ASSERT(txn.lockState()->isDbLockedForMode("foo", MODE_S));

                        Lock::DBLock r3(txn.lockState(), "local", MODE_S);
                        ASSERT(txn.lockState()->isDbLockedForMode("foo", MODE_S));
                        ASSERT(txn.lockState()->isDbLockedForMode("local", MODE_S));
                    } else if (q == 1) {
                        // test locking local only -- with no preceding lock
                        {
                            ScopedTransaction scopedXact(&txn, MODE_IS);
                            Lock::DBLock x(txn.lockState(), "local", MODE_S);
                        }
                        {
                            ScopedTransaction scopedXact(&txn, MODE_IX);
                            Lock::DBLock x(txn.lockState(), "local", MODE_X);

                            //  No actual writing here, so no WriteUnitOfWork
                            if (sometimes) {
                                Lock::TempRelease t(txn.lockState());
                            }
                        }
                    } else if (q == 1) {
                        {
                            ScopedTransaction scopedXact(&txn, MODE_IS);
                            Lock::DBLock x(txn.lockState(), "admin", MODE_S);
                        }

                        {
                            ScopedTransaction scopedXact(&txn, MODE_IX);
                            Lock::DBLock x(txn.lockState(), "admin", MODE_X);
                        }
                    } else if (q == 3) {
                        ScopedTransaction scopedXact(&txn, MODE_IX);

                        Lock::DBLock x(txn.lockState(), "foo", MODE_X);
                        Lock::DBLock y(txn.lockState(), "admin", MODE_S);
                    } else if (q == 4) {
                        ScopedTransaction scopedXact(&txn, MODE_IS);

                        Lock::DBLock x(txn.lockState(), "foo2", MODE_S);
                        Lock::DBLock y(txn.lockState(), "admin", MODE_S);
                    } else {
                        ScopedTransaction scopedXact(&txn, MODE_IX);

                        Lock::DBLock w(txn.lockState(), "foo", MODE_X);

                        { Lock::TempRelease t(txn.lockState()); }

                        Lock::DBLock r2(txn.lockState(), "foo", MODE_S);
                        Lock::DBLock r3(txn.lockState(), "local", MODE_S);
                    }
                } else {
                    ScopedTransaction scopedXact(&txn, MODE_IS);

                    Lock::DBLock r(txn.lockState(), "foo", MODE_S);
                    Lock::DBLock r2(txn.lockState(), "foo", MODE_S);
                    Lock::DBLock r3(txn.lockState(), "local", MODE_S);
                }
            }
            pm.hit();
        }
    }

    virtual void validate() {
        {
            MMAPV1LockerImpl ls;
            Lock::GlobalWrite w(&ls);
        }
        {
            MMAPV1LockerImpl ls;
            Lock::GlobalRead r(&ls);
        }
    }
};

template <typename _AtomicUInt>
class IsAtomicWordAtomic : public ThreadedTest<> {
    static const int iterations = 1000000;
    typedef typename _AtomicUInt::WordType WordType;
    _AtomicUInt target;

    void subthread(int) {
        for (int i = 0; i < iterations; i++) {
            target.fetchAndAdd(WordType(1));
        }
    }
    void validate() {
        ASSERT_EQUALS(target.load(), unsigned(nthreads * iterations));

        _AtomicUInt u;
        ASSERT_EQUALS(0u, u.load());
        ASSERT_EQUALS(0u, u.fetchAndAdd(WordType(1)));
        ASSERT_EQUALS(2u, u.addAndFetch(WordType(1)));
        ASSERT_EQUALS(2u, u.fetchAndSubtract(WordType(1)));
        ASSERT_EQUALS(0u, u.subtractAndFetch(WordType(1)));
        ASSERT_EQUALS(0u, u.load());

        u.fetchAndAdd(WordType(1));
        ASSERT_GREATER_THAN(u.load(), WordType(0));

        u.fetchAndSubtract(WordType(1));
        ASSERT_NOT_GREATER_THAN(u.load(), WordType(0));
    }
};

class ThreadPoolTest {
    static const unsigned iterations = 10000;
    static const unsigned nThreads = 8;

    AtomicUInt32 counter;
    void increment(unsigned n) {
        for (unsigned i = 0; i < n; i++) {
            counter.fetchAndAdd(1);
        }
    }

public:
    void run() {
        OldThreadPool tp(nThreads);

        for (unsigned i = 0; i < iterations; i++) {
            tp.schedule(&ThreadPoolTest::increment, this, 2);
        }

        tp.join();

        ASSERT_EQUALS(counter.load(), iterations * 2);
    }
};

class RWLockTest1 {
public:
    void run() {
        RWLock lk("eliot");
        { rwlock r(lk, true, 1000); }
    }
};

class RWLockTest2 {
public:
    static void worker1(RWLockRecursiveNongreedy* lk, AtomicUInt32* x) {
        x->fetchAndAdd(1);  // 1
        RWLockRecursiveNongreedy::Exclusive b(*lk);
        x->fetchAndAdd(1);  // 2
    }
    static void worker2(RWLockRecursiveNongreedy* lk, AtomicUInt32* x) {
        RWLockRecursiveNongreedy::Shared c(*lk);
        x->fetchAndAdd(1);
    }
    void run() {
        /**
         * note: this test will deadlock if the code breaks
         */
        RWLockRecursiveNongreedy lk("eliot2", 120 * 1000);
        cout << "RWLock impl: " << lk.implType() << endl;
        unique_ptr<RWLockRecursiveNongreedy::Shared> a(new RWLockRecursiveNongreedy::Shared(lk));
        AtomicUInt32 x1(0);
        cout << "A : " << &x1 << endl;
        stdx::thread t1(stdx::bind(worker1, &lk, &x1));
        while (!x1.load())
            ;
        verify(x1.load() == 1);
        sleepmillis(500);
        verify(x1.load() == 1);
        AtomicUInt32 x2(0);
        stdx::thread t2(stdx::bind(worker2, &lk, &x2));
        t2.join();
        verify(x2.load() == 1);
        a.reset();
        for (int i = 0; i < 2000; i++) {
            if (x1.load() == 2)
                break;
            sleepmillis(1);
        }
        verify(x1.load() == 2);
        t1.join();
    }
};

class RWLockTest3 {
public:
    static void worker2(RWLockRecursiveNongreedy* lk, AtomicUInt32* x) {
        verify(!lk->__lock_try(0));
        RWLockRecursiveNongreedy::Shared c(*lk);
        x->fetchAndAdd(1);
    }

    void run() {
        /**
         * note: this test will deadlock if the code breaks
         */

        RWLockRecursiveNongreedy lk("eliot2", 120 * 1000);

        unique_ptr<RWLockRecursiveNongreedy::Shared> a(new RWLockRecursiveNongreedy::Shared(lk));

        AtomicUInt32 x2(0);

        stdx::thread t2(stdx::bind(worker2, &lk, &x2));
        t2.join();
        verify(x2.load() == 1);

        a.reset();
    }
};

class RWLockTest4 {
public:
#if defined(__linux__) || defined(__APPLE__)
    static void worker1(pthread_rwlock_t* lk, AtomicUInt32* x) {
        x->fetchAndAdd(1);  // 1
        cout << "lock b try" << endl;
        while (1) {
            if (pthread_rwlock_trywrlock(lk) == 0)
                break;
            sleepmillis(10);
        }
        cout << "lock b got" << endl;
        x->fetchAndAdd(1);  // 2
        pthread_rwlock_unlock(lk);
    }

    static void worker2(pthread_rwlock_t* lk, AtomicUInt32* x) {
        cout << "lock c try" << endl;
        pthread_rwlock_rdlock(lk);
        x->fetchAndAdd(1);
        cout << "lock c got" << endl;
        pthread_rwlock_unlock(lk);
    }
#endif
    void run() {
/**
 * note: this test will deadlock if the code breaks
 */

#if defined(__linux__) || defined(__APPLE__)

        // create
        pthread_rwlock_t lk;
        verify(pthread_rwlock_init(&lk, 0) == 0);

        // read lock
        verify(pthread_rwlock_rdlock(&lk) == 0);

        AtomicUInt32 x1(0);
        stdx::thread t1(stdx::bind(worker1, &lk, &x1));
        while (!x1.load())
            ;
        verify(x1.load() == 1);
        sleepmillis(500);
        verify(x1.load() == 1);

        AtomicUInt32 x2(0);

        stdx::thread t2(stdx::bind(worker2, &lk, &x2));
        t2.join();
        verify(x2.load() == 1);

        pthread_rwlock_unlock(&lk);

        for (int i = 0; i < 2000; i++) {
            if (x1.load() == 2)
                break;
            sleepmillis(1);
        }

        verify(x1.load() == 2);
        t1.join();
#endif
    }
};

// we don't use upgrade so that part is not important currently but the other aspects of this test
// are interesting; it would be nice to do analogous tests for SimpleRWLock and QLock
class UpgradableTest : public ThreadedTest<7> {
    RWLock m;

public:
    UpgradableTest() : m("utest") {}

private:
    virtual void validate() {}
    virtual void subthread(int x) {
        Client::initThread("utest");

        /* r = get a read lock
           R = get a read lock and we expect it to be fast
           u = get upgradable
           U = get upgradable and we expect it to be fast
           w = get a write lock
        */
        //                    /-- verify upgrade can be done instantly while in a read lock already
        //                    |  /-- verify upgrade acquisition isn't greedy
        //                    |  | /-- verify writes aren't greedy while in upgradable(or are they?)
        //                    v  v v
        const char* what = " RURuRwR";

        sleepmillis(100 * x);

        int Z = 1;
        LOG(Z) << x << ' ' << what[x] << " request" << endl;
        char ch = what[x];
        switch (ch) {
            case 'w': {
                m.lock();
                LOG(Z) << x << " w got" << endl;
                sleepmillis(100);
                LOG(Z) << x << " w unlock" << endl;
                m.unlock();
            } break;
            case 'u':
            case 'U': {
                Timer t;
                RWLock::Upgradable u(m);
                LOG(Z) << x << ' ' << ch << " got" << endl;
                if (ch == 'U') {
#if defined(NTDDI_VERSION) && defined(NTDDI_WIN7) && (NTDDI_VERSION >= NTDDI_WIN7)
                    // SRW locks are neither fair nor FIFO, as per docs
                    if (t.millis() > 2000) {
#else
                    if (t.millis() > 20) {
#endif
                        DEV {
                            // a debug buildbot might be slow, try to avoid false positives
                            mongo::unittest::log() << "warning lock upgrade was slow " << t.millis()
                                                   << endl;
                        }
                        else {
                            mongo::unittest::log()
                                << "assertion failure: lock upgrade was too slow: " << t.millis()
                                << endl;
                            ASSERT(false);
                        }
                    }
                }
                sleepsecs(1);
                LOG(Z) << x << ' ' << ch << " unlock" << endl;
            } break;
            case 'r':
            case 'R': {
                Timer t;
                m.lock_shared();
                LOG(Z) << x << ' ' << ch << " got " << endl;
                if (what[x] == 'R') {
                    if (t.millis() > 15) {
                        // commented out for less chatter, we aren't using upgradeable anyway right
                        // now:
                        // log() << x << " info: when in upgradable, write locks are still greedy "
                        // "on this platform" << endl;
                    }
                }
                sleepmillis(200);
                LOG(Z) << x << ' ' << ch << " unlock" << endl;
                m.unlock_shared();
            } break;
            default:
                ASSERT(false);
        }
    }
};

void sleepalittle() {
    Timer t;
    while (1) {
        stdx::this_thread::yield();
        if (t.micros() > 8)
            break;
    }
}

int once;

/* This test is to see how long it takes to get a lock after there has been contention -- the OS
   will need to reschedule us. if a spinlock, it will be fast of course, but these aren't spin
   locks. Experimenting with different # of threads would be a good idea.
*/
template <class whichmutex, class scoped>
class Slack : public ThreadedTest<17> {
public:
    Slack() {
        k = 0;
        done = false;
        a = b = 0;
        locks = 0;
    }

private:
    whichmutex m;
    char pad1[128];
    unsigned a, b;
    char pad2[128];
    unsigned locks;
    char pad3[128];
    volatile int k;

    virtual void validate() {
        if (once++ == 0) {
            // <= 1.35 we use a different rwmutex impl so worth noting
            cout << "Boost version : " << BOOST_VERSION << endl;
        }
        cout << typeid(whichmutex).name() << " Slack useful work fraction: " << ((double)a) / b
             << " locks:" << locks << endl;
    }
    void watch() {
        while (1) {
            b++;
            //__sync_synchronize();
            if (k) {
                a++;
            }
            sleepmillis(0);
            if (done)
                break;
        }
    }
    volatile bool done;
    virtual void subthread(int x) {
        if (x == 1) {
            watch();
            return;
        }
        Timer t;
        unsigned lks = 0;
        while (1) {
            scoped lk(m);
            k = 1;
            // not very long, we'd like to simulate about 100K locks per second
            sleepalittle();
            lks++;
            if (done || t.millis() > 1500) {
                locks += lks;
                k = 0;
                break;
            }
            k = 0;
            //__sync_synchronize();
        }
        done = true;
    }
};

class CondSlack : public ThreadedTest<17> {
    Notification n;

public:
    CondSlack() {
        k = 0;
        done = false;
        a = b = 0;
        locks = 0;
    }

private:
    unsigned a, b;
    virtual void validate() {
        cout << "CondSlack useful work fraction: " << ((double)a) / b << " locks:" << locks << endl;
    }
    unsigned locks;
    volatile int k;
    void watch() {
        while (1) {
            b++;
            if (k) {
                a++;
            }
            sleepmillis(0);
            if (done)
                break;
        }
    }
    volatile bool done;
    virtual void subthread(int x) {
        if (x == 1) {
            n.notifyOne();
            watch();
            return;
        }
        Timer t;
        while (1) {
            n.waitToBeNotified();
            verify(k == 0);
            k = 1;
            // not very long, we'd like to simulate about 100K locks per second
            sleepalittle();
            k = 0;
            locks++;
            n.notifyOne();
            if (done || t.millis() > 1500)
                break;
        }
        done = true;
    }
};

const int WriteLocksAreGreedy_ThreadCount = 3;
class WriteLocksAreGreedy : public ThreadedTest<WriteLocksAreGreedy_ThreadCount> {
public:
    WriteLocksAreGreedy() : m("gtest"), _barrier(WriteLocksAreGreedy_ThreadCount) {}

private:
    RWLock m;
    boost::barrier _barrier;
    virtual void validate() {}
    virtual void subthread(int x) {
        _barrier.wait();
        int Z = 0;
        Client::initThread("utest");
        if (x == 1) {
            LOG(Z) << mongo::curTimeMillis64() % 10000 << " 1" << endl;
            rwlock_shared lk(m);
            sleepmillis(400);
            LOG(Z) << mongo::curTimeMillis64() % 10000 << " 1x" << endl;
        }
        if (x == 2) {
            sleepmillis(100);
            LOG(Z) << mongo::curTimeMillis64() % 10000 << " 2" << endl;
            rwlock lk(m, true);
            LOG(Z) << mongo::curTimeMillis64() % 10000 << " 2x" << endl;
        }
        if (x == 3) {
            sleepmillis(200);
            Timer t;
            LOG(Z) << mongo::curTimeMillis64() % 10000 << " 3" << endl;
            rwlock_shared lk(m);
            LOG(Z) << mongo::curTimeMillis64() % 10000 << " 3x" << endl;
            LOG(Z) << t.millis() << endl;
            ASSERT(t.millis() > 50);
        }
    }
};


// Tests waiting on the TicketHolder by running many more threads than can fit into the "hotel", but
// only max _nRooms threads should ever get in at once
class TicketHolderWaits : public ThreadedTest<10> {
    static const int checkIns = 1000;
    static const int rooms = 3;

public:
    TicketHolderWaits() : _hotel(rooms), _tickets(_hotel._nRooms) {}

private:
    class Hotel {
    public:
        Hotel(int nRooms) : _nRooms(nRooms), _checkedIn(0), _maxRooms(0) {}

        void checkIn() {
            stdx::lock_guard<stdx::mutex> lk(_frontDesk);
            _checkedIn++;
            verify(_checkedIn <= _nRooms);
            if (_checkedIn > _maxRooms)
                _maxRooms = _checkedIn;
        }

        void checkOut() {
            stdx::lock_guard<stdx::mutex> lk(_frontDesk);
            _checkedIn--;
            verify(_checkedIn >= 0);
        }

        stdx::mutex _frontDesk;
        int _nRooms;
        int _checkedIn;
        int _maxRooms;
    };

    Hotel _hotel;
    TicketHolder _tickets;

    virtual void subthread(int x) {
        string threadName = (str::stream() << "ticketHolder" << x);
        Client::initThread(threadName.c_str());

        for (int i = 0; i < checkIns; i++) {
            _tickets.waitForTicket();
            TicketHolderReleaser whenDone(&_tickets);

            _hotel.checkIn();

            sleepalittle();
            if (i == checkIns - 1)
                sleepsecs(2);

            _hotel.checkOut();

            if ((i % (checkIns / 10)) == 0)
                mongo::unittest::log() << "checked in " << i << " times..." << endl;
        }
    }

    virtual void validate() {
        // This should always be true, assuming that it takes < 1 sec for the hardware to process a
        // check-out/check-in Time for test is then ~ #threads / _nRooms * 2 seconds
        verify(_hotel._maxRooms == _hotel._nRooms);
    }
};

class All : public Suite {
public:
    All() : Suite("threading") {}

    void setupTests() {
        add<WriteLocksAreGreedy>();

        // Slack is a test to see how long it takes for another thread to pick up
        // and begin work after another relinquishes the lock.  e.g. a spin lock
        // would have very little slack.
        add<Slack<SimpleMutex, stdx::lock_guard<SimpleMutex>>>();
        add<Slack<SimpleRWLock, SimpleRWLock::Exclusive>>();
        add<CondSlack>();

        add<UpgradableTest>();

        add<IsAtomicWordAtomic<AtomicUInt32>>();
        add<IsAtomicWordAtomic<AtomicUInt64>>();
        add<ThreadPoolTest>();

        add<RWLockTest1>();
        add<RWLockTest2>();
        add<RWLockTest3>();
        add<RWLockTest4>();

        add<MongoMutexTest>();
        add<TicketHolderWaits>();
    }
};

SuiteInstance<All> myall;
}