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Sorry for not being a native English speaker :( and such a long question :(

Long in short, I need to write a pool of a class, which stores some values. As calculating these values are CPU intensive, I need to run them in parallel, therefore the pool has to be thread safe.

Also, I have to use dynamic arrays rather than std::vector for the class that storing values, as it seems faster and easier to copy the values either using std::copy or memcpy.

Let's start with the code:

AClassPool.h

#ifndef __Test__AClassPool__
#define __Test__AClassPool__

#include <iostream>
#include <vector>
#include <cassert>

#ifdef _WIN64
#elif _WIN32
#include <Windows.h>
#endif

class AClass {
    bool   * m_Member      = nullptr;
    size_t   m_MemberSize  = 0;
    bool   * m_Member2     = nullptr;
    size_t   m_MemberSize2 = 0;

public:

    void   getMember(bool dst[], const size_t len);

    size_t getMemberSize() { return m_MemberSize; }

    AClass();
    AClass(const bool src[],  const size_t len,
           const bool src2[], const size_t len2);

    AClass & operator= (const AClass & rhs);
    AClass(const AClass & other);
    ~AClass();
};

class AClassPool {
    bool bLock;

    std::vector<AClass> vecAC;

    inline void wait() {
        while (bLock) {
#ifdef _WIN64
#elif _WIN32
            Sleep(1);
#elif __APPLE__
            usleep(1 * 1000);
#endif
        }
    }

    bool compareMember(const bool m1[], const size_t len1,
                       const bool m2[], const size_t len2);

public:

    long lookup(const bool m[],  const size_t len);

    void add(AClass ac);
    void erase(const size_t idx) { wait(); bLock = true; vecAC.erase(vecAC.begin() + idx); bLock = false; }
    void clear() { wait(); bLock = true; vecAC.clear(); bLock = false; }
    size_t size() { return vecAC.size(); }

    AClass & operator[] (const size_t idx);
    AClassPool & operator= (const AClassPool & other);

    AClassPool()  { bLock = false; }
    AClassPool(const AClassPool & other);
    ~AClassPool() { clear(); }
};

#endif /* defined(__Test__AClassPool__) */

AClassPool.cpp

#include "AClassPool.h"

// AClass

AClass::AClass() {
    m_Member      = nullptr;
    m_MemberSize  = 0;
    m_Member2     = nullptr;
    m_MemberSize2 = 0;
}

AClass::AClass(const bool src[],  const size_t len,
               const bool src2[], const size_t len2) {
    m_Member      = new bool[len];
    m_MemberSize  = len;
    std::copy(src, src + len, m_Member);

    m_Member2     = new bool[len2];
    m_MemberSize2 = len2;
    std::copy(src2, src2 + len2, m_Member2);
}

void AClass::getMember(bool dst[], const size_t len) {
    assert(len == m_MemberSize);
    std::copy(m_Member, m_Member + len, dst);
}

AClass & AClass::operator=(const AClass & rhs) {
    if (this != &rhs) {
        if (rhs.m_Member != nullptr) {
            if (m_Member != nullptr) { delete [] m_Member; m_Member = nullptr; }
            m_Member  = new bool[rhs.m_MemberSize];
            std::copy(rhs.m_Member, rhs.m_Member + rhs.m_MemberSize, m_Member);

            if (m_Member2 != nullptr) { delete [] m_Member2; m_Member2 = nullptr; }
            m_Member2 = new bool[rhs.m_MemberSize2];
            std::copy(rhs.m_Member2, rhs.m_Member2 + rhs.m_MemberSize2, m_Member2);
        } else {
            if (m_Member  != nullptr) { delete [] m_Member;  m_Member  = nullptr; }
            if (m_Member2 != nullptr) { delete [] m_Member2; m_Member2 = nullptr; }
        }
        m_MemberSize  = rhs.m_MemberSize;
        m_MemberSize2 = rhs.m_MemberSize2;
    }
    return *this;
}

AClass::AClass(const AClass & other) {
    if (other.m_Member != nullptr) {
        if (m_Member != nullptr) { delete [] m_Member; m_Member = nullptr; }
        m_Member   = new bool[other.m_MemberSize];
        std::copy(other.m_Member, other.m_Member + other.m_MemberSize, m_Member);
    } else {
        if (m_Member != nullptr) { delete [] m_Member; m_Member = nullptr; }
    }
    m_MemberSize  = other.m_MemberSize;

    if (other.m_Member2 != nullptr) {
        if (m_Member2 != nullptr) { delete [] m_Member2; m_Member2 = nullptr; }
        m_Member2   = new bool[other.m_MemberSize2];
        std::copy(other.m_Member2, other.m_Member2 + other.m_MemberSize2, m_Member2);
    } else {
        if (m_Member2 != nullptr) { delete [] m_Member2; m_Member2 = nullptr; }
    }
    m_MemberSize2 = other.m_MemberSize2;
}

AClass::~AClass() {
    if (m_Member  != nullptr) { delete [] m_Member;  m_Member  = nullptr; }
    if (m_Member2 != nullptr) { delete [] m_Member2; m_Member2 = nullptr; }
}

// AClassPool

bool AClassPool::compareMember(const bool m1[], const size_t len1,
                               const bool m2[], const size_t len2) {
    if (len1 != len2) {
        return false;
    } else {
        for (unsigned i = 0; i < len1; ++i) {
            if ( m1[i] != m2[i] ) {
                return false;
            }
        }
    }
    return true;
}

long AClassPool::lookup(const bool m[],  const size_t len) {
    bool *tmp = new bool[len];

    wait(); bLock = true;

    for (unsigned i = 0; i < vecAC.size(); ++i) {
        if (vecAC[i].getMemberSize() == len) {
            vecAC[i].getMember(tmp, len);
            if (compareMember(tmp, len, m, len)) {
                bLock = false;
                delete [] tmp;
                return i;
            }
        }
    }

    bLock = false;
    delete [] tmp;
    return -1;
}

void AClassPool::add(AClass ac) {
    size_t size = ac.getMemberSize();
    bool   *tmp = new bool[size];

    ac.getMember(tmp, size);
    if (lookup(tmp, size) < 0) {
        wait(); bLock = true;
        vecAC.push_back(ac);
        bLock = false;
    }

    delete [] tmp;
}

AClass & AClassPool::operator[] (const size_t idx) {
    assert(idx < vecAC.size());
    return vecAC[idx];
}

AClassPool & AClassPool::operator= (const AClassPool & other) {
    if (this != &other) {
        vecAC = other.vecAC;
    }
    return *this;
}

AClassPool::AClassPool(const AClassPool & other) {
    bLock = false;
    vecAC = other.vecAC;
}

And the main.cpp

#include <iostream>
#include <cassert>

#include "AClassPool.h"

#define ITER 10000

#ifdef __APPLE__
#include <dispatch/dispatch.h>
#endif

using namespace std;

void someFunction(AClassPool *pAcp) {

    bool *b1, *b2;
    b1 = new bool[10]();
    b2 = new bool[10](); b2[5] = 1; // To make b2 different from b1

    AClass *pAc = new AClass[2];
    pAc[0] = *new AClass(b1, 10, b1, 10);
    pAc[1] = *new AClass(b2, 10, b2, 10);

    delete [] b1;
    delete [] b2;

    pAcp->add(pAc[0]);  // Add first member

#ifdef _WIN32
#pragma omp parallel for
    for (int i = 0; i < ITER; ++i) {
#elif __APPLE__
    dispatch_queue_t queue = dispatch_queue_create("i.need.a.queue", DISPATCH_QUEUE_CONCURRENT);
    dispatch_apply(ITER, queue, ^(size_t i) {
#endif
        pAcp->add(pAc[1]);  // Note 1
#ifdef __APPLE__
    });
    dispatch_barrier_sync(queue, ^{});
    dispatch_release(queue);
#elif _WIN32
    }
#endif

    cout << pAcp->size() << flush;
    assert(pAcp->size() == 2);

    delete [] pAc;

//    pAcp->clear();    // Note 2
    pAcp->erase(0);
    pAcp->erase(0);

    return;
}

int main(int argc, const char * argv[]) {
    AClassPool acp;
    AClassPool *pAcp = & acp;

#ifdef _WIN32
#pragma omp parallel for
    for (int i = 0; i < ITER; ++i) {
#elif __APPLE__
    dispatch_queue_t queue = dispatch_queue_create("i.need.a.main.queue", DISPATCH_QUEUE_CONCURRENT);
    dispatch_apply(ITER, queue, ^ (size_t i) {
#endif
        someFunction(pAcp);
#ifdef __APPLE__
    });
    dispatch_barrier_sync(queue, ^ {});
    dispatch_release(queue);
#elif _WIN32
    }
#endif
    return 0;
}

Note 1: Add more member to the pool, actually it supposed to be added only once as in AClassPool::add() will check duplicate.

Note 2: These lines were actually for testing thread safety. I know it will cause assert(pAcp->size() == 2); fail, and it should not cause other problems.

The program runs fine if I comment out GCD/OpenMP parts, i.e., running on single thread, but when the code runs on multiple threads (on latest OS X 10.9.2 13C64, latest Xcode 5.1 5B130a), it gives the following problems:

  1. Sometimes it stops at AClass::~AClass(), giving signal SIGABRT and says:

    malloc: * error for object 0x10000000000: pointer being freed was not allocated * set a breakpoint in malloc_error_break to debug

    I tracked the m_Member and m_Member2, addresses of both are 0x10000000000.

  2. Sometimes it stops at line std::memmove(__result, __first, sizeof(_Tp) * (__last - __first)); in function template<> struct __copy<true, random_access_iterator_tag> in file /usr/include/c++/4.2.1/bits/stl_algobase.h (I am running OS X 10.9). Back trace to my code located in line std::copy(m_Member, m_Member + len, dat); in AClass::getMember().

    Values in std::__copy are:

    __result = (bool *) 0x100603b60

    __last = (const bool *) 0xa

    __first = (const bool *) NULL

    Values in AClass::getMember() are:

    this.m_Member = (bool *) 0x1001068e0

    len = (size_t) 10

    dst = (bool *) 0x100603b60

    I tried memcpy instead std::copy, it gives similar error.

  3. If I comment out pAcp->clear() and pAcp->erase(0) around Note 2, it will not cause any exception, but the memory usage will increase steadily. Xcode's Profiler finds memory leak of m_Member and m_Member2 allocations in AClass::AClass(), but I think these memories will be freed in AClass::~AClass(), aren't they?

  4. On Windows, compile with VS2013, will only fails on assert(pAcp->size() == 2);, but the memory leak seems consistent.

  5. Sorry to be so newbie on dynamic memory / multi-thread, could you please help me by spotting other problems in my code? I found weird of detecting if a pointer is null every time before freeing memory, will some of the checks always true that I don't need to check? I experienced some double free or free unallocated memory earlier, therefore I added so many checks, I still see memory freeing problems like in Problem 1

Many thanks in advance, any help is grateful... I am completely lost now...

share|improve this question
    
I have to use dynamic arrays rather than std::vector for the class that storing values, as it seems faster and easier to copy the values either using std::copy or memcpy Let's see your evidence of vector being slower than what you're trying to achieve using "dynamic arrays". –  PaulMcKenzie Mar 17 at 18:32
    
The c++ standard containers don't provide intrinsic thread safety, you have to protect read/write operations against race conditions yourself. –  πάντα ῥεῖ Mar 17 at 18:36
    
1) Your assignment operator for AClassPool is buggy. You failed to copy the bool block; member. 2) There is no need to check for nullptr when issuing a delete. Deleting a nullptr is perfectly valid. –  PaulMcKenzie Mar 17 at 18:36
    
As to the general design stop using dynamically allocated memory and use vector or another container. Get your program working first, then optimize later. It makes no sense to write all of this assuming (or feeling) that vector is slower, and the code you wrote is failing all over the place due to memory mismanagement. Write a working program first using the safest constructs, and then you profile the code and optimize where necessary. Right now, that same program you posted could be half, if not less in size than that if you used vector. –  PaulMcKenzie Mar 17 at 18:57
    
@PaulMcKenzie: I use another package to calculate these values, which values are stored in its own container and a function called elemvec() returns the array. I suppose using std::copy or memcpy is faster and easier than using vector. Maybe I was wrong... I noticed that I didn't copy bool bLock, and it unlikely caused the problem as there is only one instance in the test. Anyway, thanks for reminding me this :) Any further to help me get the memory management right? Or the multi-thread working (well, most important)? Many thanks! –  Tide Gu Mar 18 at 0:29

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