Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free, no registration required.

I'm trying to parallelize a for loop in c++ with openMP. I have many matrices (of class Matrix) that need to be exponentiated with zheevr. The implementation gives a Data Race.

The parallelized for loop is

/* in main */
#pragma omp parallel for shared(Aexp_omp, A, Z, W) private(j) firstprivate(idt)
for (j=0; j< nMat; ++j) {
    Aexp_omp[j] = EigenMethod(A[j],-idt,&(Z[j]),W[j]);
}

Here, Aexp_omp, A, Z are all arrays of a class Matrix. The exact line seems to be the second call to zheevr in EigenMethod. The code executes properly when the #pragma omp critical is not commented out (but putting pragma omp critical here seems to defeat the purpose of parellelizing this code).

I do not understand where the data race is comming from since, if I remember properly, all variables decleared in a loop are private to the thread?

Any insights as to why this is happening? Have I wrongly decleared the pragma omp parallel for part of the code?

Many thanks for your help.

Edit: Full Code

To provide all the information, here is the full code (It's a little long, my apologies). It compiles on my machines with the makefile

omp_matrix: omp_matrix.cpp
        g++ -fopenmp -lgsl -lgslcblas -llapack -lblas -lm -o omp_matrix omp_matrix.cpp

It gives random behaviour when running due to, I suspect the data race. The code has to files, the one with main (and some extra namesspace) and the Matrix class.

/* omp_matrix.cpp */
#include <iostream>
#include <omp.h>
#include <cstdio>
#include <ctime>
#include <string>
#include <cmath>
#include <vector>
#include <complex>
#include <limits>
#include <cstdlib>

const char Trans[]  = {'N','T','C'};
const char UpLo[]   = {'U','L'};
const char Jobz[]   = {'V','N'};
const char Range[]  = {'A','V','I'};
#ifdef __cplusplus
extern "C" {
#endif

void zgemm_(const char* TransA, const char* TransB, const size_t* M, const size_t* N, const size_t* K, const std::complex<double>* alpha, const std::complex<double>* A, const size_t* lda, const std::complex<double>* B, const size_t* ldb, const std::complex<double>* beta, std::complex<double>* C, size_t* ldc);
int zheevr_(const char* jobz, const char* range, const char* uplo, const size_t* n, std::complex<double>* a, size_t* lda, double* vl, double* vu, size_t* il, size_t* iu, double* abstol, size_t* m, double* w, std::complex<double>* z, size_t* ldz, int* isuppz, std::complex<double>* work, int* lwork, double* rwork, int* lrwork, int* iwork, int* liwork, int* info);

#ifdef __cplusplus
}
#endif

    #include "Matrix.hpp"

namespace MOs {
    //Identity Matrix
    template <class T> 
    inline void Identity(Matrix<T>& I){
    size_t dim = I.GetRows();
    if (dim != I.GetColumns())
            exit(1);
    for(size_t i=0; i<dim; i++)
        for(size_t j=0; j<dim; j++)
                I(i,j) = i == j ? T(1) : T(0);
    return; 
    }

    // The H.O. Annilation operator
    template <class T> 
    inline void Destroy(Matrix<T>& a){
            size_t dim = a.GetRows();
            if (dim != a.GetColumns())
                    exit(1);
            for(size_t i=0; i<dim; i++)
                    for(size_t j=0; j<dim; j++)
                            a(i,j) = j == i+1 ? std::sqrt(T(j)) : T(0); 
            return; 
    }

    //Take the Hermitian conjugate of a complex Matrix
    inline Matrix<std::complex<double> > Dagger(const Matrix<std::complex<double> >& A){
            size_t cols = A.GetColumns(), rows= A.GetRows();
            Matrix<std::complex<double> > temp(cols,rows);
            for (size_t i=0; i < rows; i++)
                    for(size_t j=0; j < cols; j++)
                            temp(j,i) = conj(A(i,j));
            return temp;
    }

    template <class T>
    inline Matrix<T> TensorProduct(const Matrix<T>& A, const Matrix<T>& B){
            size_t rows1 = A.GetRows(), rows2 = B.GetRows(), cols1 = A.GetColumns(), cols2 = B.GetColumns();
            size_t rows_new = rows1*rows2, cols_new = cols1*cols2, n, m;
            Matrix<T> temp(rows_new,cols_new);
            for(size_t i=0; i<rows1; i++)
                    for(size_t j=0; j<cols1; j++)
                            for(size_t p=0; p<rows2; p++)
                                    for(size_t q=0; q<cols2; q++){
                                            n = i*rows2+p;    
                                            m = j*cols2+q; //  0 (0 + 1)  + 1*dimb=2 + (0 + 1 )  (j*dimb+q)         
                                            temp(n,m) = A(i,j)*B(p,q);
                            }
                    return temp;
            }
}

Matrix<std::complex<double> > EigenMethod(const Matrix<std::complex<double> >& Ain,  std::complex<double> x, Matrix<std::complex<double> >* Z=NULL, double *W=NULL );

using namespace std;

int main(int argc, char const *argv[]) {
    // dim is the dimension of the system
    size_t  dimQ    = 2;
    size_t  dim = dimQ*dimQ*dimQ;

    // Define the matrices used to build the matrix to be exponentiated
    Matrix<complex<double> > o(dimQ,dimQ), od(dimQ,dimQ), nq(dimQ,dimQ);
    MOs::Destroy(o);
    od = MOs::Dagger(o); nq=od*o;
    Matrix<complex<double> > IdentQ(dimQ, dimQ), Hd(dim, dim);
    MOs::Identity(IdentQ);
    Hd = 0.170*MOs::TensorProduct(MOs::TensorProduct(od,IdentQ),o) + 0.124* MOs::TensorProduct(MOs::TensorProduct(IdentQ,od),o);

    complex<double> idt = complex<double>(0.0,0.2);                 // time unit multiplied by i

    size_t  nMat    = 2;
    double* c   = new double[nMat];
    c[0] = 0.134;
    c[1] = -0.326;

    // Decalre matrices and allocate memory for them
    Matrix<complex<double> >*   A    = new Matrix<complex<double> >[nMat];
    Matrix<complex<double> >*   Aexp     = new Matrix<complex<double> >[nMat];
    Matrix<complex<double> >*   Aexp_omp = new Matrix<complex<double> >[nMat];
    for (size_t k = 0; k < nMat; ++k)
            A[k] = c[k]*Hd;

    // METHOD 1: Serial. Exponentiate one matrix after another
    double start_s = omp_get_wtime();
    for (size_t k = 0; k < nMat; ++k)
            Aexp[k] = EigenMethod(A[k],-idt);
    double end_s = omp_get_wtime();

    cout << "Aexp[0] = \n" << Aexp[0] << endl;
    cout << "Aexp[1] = \n" << Aexp[1] << endl;

    // METHOD 2: Parallel. Exponentiate all matrices at the same time
    // THIS DOES NOT WORK. Data race condition in EigenMetod?
    Matrix<complex<double> >* Z = new Matrix<complex<double> >[nMat];
    double** W = new double*[nMat];
    for (size_t k = 0; k < nMat; ++k) {
            Z[k].initialize(dim,dim);
            W[k] = new double[dim];
    }

    size_t j;
    double start_p1 = omp_get_wtime( );
    #pragma omp parallel for shared(Aexp_omp,A,Z,W) private(j) firstprivate(idt)
    for (j=0; j< nMat; ++j) {
            Aexp_omp[j] = EigenMethod(A[j],-idt,&(Z[j]),W[j]);
    }
    double end_p1 = omp_get_wtime( );

    cout << "Done" << endl;

    cout << "Aexp_omp[0] = \n" << Aexp_omp[0] << endl;
    cout << "Aexp_omp[1] = \n" << Aexp_omp[1] << endl;

    cout << "Serial time: " << end_s - start_s << ", parallel time method 2: " << end_p1-start_p1 << endl;

    delete [] c;
    delete [] A;
    delete [] Aexp;
    delete [] Aexp_omp;

} /* end of int main */

Matrix<complex<double> > EigenMethod(const Matrix<complex<double> >& A, complex<double> x, Matrix<complex<double> >* Z, double *W){ 

    bool returnZ(Z!=NULL), returnW(W!=NULL);                            // flags to see if the function received valid Z and W adresses

    //if (MOs::IsHermitian(A)==0) UFs::MyError("Routine ExpM::EigenMethod: The input Matrix is not Hermitian.");
    size_t N = A.GetRows(), LDA=A.GetLD(), IL, IU, M, LDZ=N;
    double VL, VU, ABSTOL=numeric_limits<double>::min(); 
    complex<double>*    WORK;
    double*         RWORK;
    int*            IWORK;

    //finding the optimal work sizes
    int LWORK=-1, LRWORK=-1, LIWORK=-1, ok=0;
    WORK    = new std::complex<double>[1];
    RWORK   = new double[1];
    IWORK   = new int[1];

    // ZHEEV computes all eigenvalues and, optionally, eigenvectors of a complex Hermitian Matrix A.
    // Jobz[0] = V i.e. compute eigenvalues and eigen-vectors, Range[0] = A i.e. all eigen values will be found, UpLo[1] = L i.e. lower triangle of matrix is stored
    zheevr_ (&Jobz[0],&Range[0],&UpLo[1],&N,NULL,&LDA,&VL,&VU,&IL,&IU,&ABSTOL,&M,NULL,NULL,&LDZ,NULL,WORK,&LWORK,RWORK,&LRWORK,IWORK,&LIWORK,&ok);

    //Setting the optimal workspace
    LWORK   = (int)real(WORK[0]);
    LRWORK  = (int)RWORK[0];
    LIWORK  = IWORK[0];

    delete [] WORK; 
    delete [] RWORK;
    delete [] IWORK;

    //Running the algorithim 
    if (!returnZ) Z = new Matrix<std::complex<double> >(LDZ,LDZ);
    if (!returnW) W = new double[LDA];

    Matrix<std::complex<double> > temp(A);

    int *ISUPPZ;
    ISUPPZ  = new int[2*N]; 
    WORK    = new std::complex<double>[LWORK];
    RWORK   = new double[LRWORK];
    IWORK   = new int[LIWORK];
    //#pragma omp critical
    //{
    // THIS LINE IS DOING SOMETHING WRONG
    zheevr_ (&Jobz[0],&Range[0],&UpLo[1],&N,temp.GetMat(),&LDA,&VL,&VU,&IL,&IU,&ABSTOL,&M,W,Z->GetMat(),&LDZ,ISUPPZ,WORK,&LWORK,RWORK,&LRWORK,IWORK,&LIWORK,&ok);   
    //}

    if (ok!=0) {
        cerr << "Routine EigenMethod: An error occured in geting the diagonalization of A" << endl;
        exit(1);
    }

    //Getting the Diag*Dagger(Z), this is where the exponentiation is done using the eigenvalues
    for (size_t i=0; i < N; i++)
        for(size_t j=0; j < N; j++)
            temp(i,j) = exp(x*W[i])*conj((*Z)(j,i));

    temp = (*Z)*temp;   

    if(!returnW) delete [] W; 
    if(!returnZ) delete Z; 

    delete [] ISUPPZ;
    delete [] WORK;
    delete [] RWORK;
    delete [] IWORK;

    return temp;
}

Next is class Matrix

#ifndef Matrix_h
#define Matrix_h

enum OutputStyle {Column, List, Array};

template <class T>
class Matrix {  
//friend functions get to use the private varibles of the class as well as have different classes as inputs
template <class S>
friend std::ostream& operator << (std::ostream& output, const Matrix<S>& A){
    for (size_t i=0; i<A.rows_; i++){
        for (size_t j=0; j<A.cols_; j++){
            output << A.mat_[j*A.rows_ +i] << "\t";
        }
        output << std::endl;
    }
    return output;
}

// overloads beta*A
template <class S1, class S2>
friend Matrix<S1> operator*(const S2& beta, const Matrix<S1>& A){
    size_t rows= A.rows_, cols = A.cols_;
    Matrix<S1> temp(rows,cols);
    for (size_t i=0; i < rows; i++)
        for(size_t j=0; j < cols; j++)
            temp(i,j) = beta*A(i,j);
    return temp;
}


friend Matrix<std::complex<double> > operator*(const Matrix<std::complex<double> >& A, const Matrix<std::complex<double> >& B) {
    static Matrix<std::complex<double> > C;
    C.initialize(A.rows_,B.cols_);
    std::complex<double> alpha =1.0, beta =0.0;
    zgemm_(&Trans[0], &Trans[0], &A.rows_, &B.cols_, &A.cols_, &alpha, A.mat_, &A.LD_, B.mat_, &B.LD_, &beta, C.mat_, &C.LD_);
    return C;
}


public:
//Construtors
Matrix() : rows_(0), cols_(0), size_(0), LD_(0), outputstyle_(Array){ mat_=0;}
Matrix(size_t rows, size_t cols) : rows_(rows), cols_(cols), size_(rows*cols), LD_(rows), outputstyle_(Array), mat_(new T [size_]){}

Matrix(const Matrix<T>& rhs) : rows_(rhs.rows_), cols_(rhs.cols_), size_(rhs.size_), LD_(rows_), outputstyle_(rhs.outputstyle_), mat_(new T [size_]) {
for(size_t p = 0; p < size_; p++)
    mat_[p] = rhs.mat_[p];
}

//Initialize an empty Matrix() to Matrix(size_t  rows, size_t cols)
inline void initialize(size_t  rows, size_t cols) {
    if (rows_ != rows || cols_ != cols ) {
        if (mat_ != 0) delete [] (mat_);
        rows_   = rows;
        cols_   = cols;
        size_   = rows_*cols_;
        LD_ = rows;
        mat_    = new T[size_];
    }
}

//Destructor
virtual ~Matrix()   {if (mat_ != 0) delete[] (mat_);}

//Assignment operator
inline Matrix<T>& operator=(const Matrix<T>& rhs){
    if (rows_ != rhs.rows_ || cols_ != rhs.cols_ ) {
        if (mat_ != 0) delete [] (mat_);
        rows_=rhs.rows_;
        cols_=rhs.cols_;
        size_=rows_*cols_;
        LD_=rhs.LD_;
        mat_= new T[size_];
    }
    for (size_t p=0; p < size_; p++)
        mat_[p] = T(rhs.mat_[p]);
    return *this;
}

inline T& operator()(size_t i, size_t j){
    if (i >= rows_ || j >= cols_) exit(1);
    return mat_[j*rows_+i];
}

inline T operator()(size_t i, size_t j) const{
    if (i >= rows_ || j >= cols_) exit(1);
    return mat_[j*rows_+i];
}


//overloading functions. 
inline Matrix<T> operator+(const Matrix<T>& A){
    if(rows_ != A.rows_ || cols_ != A.cols_)
        exit(1);
    Matrix<T> temp(rows_,cols_);
    for (unsigned int p=0; p < size_; p++)      
        temp.mat_[p] = mat_[p] + A.mat_[p];
    return temp;
}

//Member Functions
inline size_t GetColumns() const            { return cols_; }
inline size_t GetRows() const               { return rows_; }
inline size_t GetLD() const             { return LD_;   }
inline size_t size() const              { return size_; }
T* GetMat() const                   { return mat_;  }

protected:
size_t rows_, cols_, size_, LD_;
//rows_ and cols_ are the rows and columns of the Matrix
//size_ = rows*colums dimensions of the vector representation   
//LD is the leading dimeonsion and for Column major order is in general eqaul to rows
enum OutputStyle outputstyle_;

T * mat_;

};
#endif /* Matrix_h */
share|improve this question
1  
why do you allocate arrays of lengths 1? this is always slow and you could just use a automatic variable, i.e. instead of double*RWORK=new double[1]; you could say (if you really need a pointer) double _RWORK, *RWORK=&_RWORK; –  Walter Sep 13 '12 at 16:28
    
If you think the culprit is zheevr_() then you should provide it. –  Walter Sep 13 '12 at 16:29
    
W is not declared (it must be a array of pointers to doublem but I cannot find a declaration). –  Walter Sep 13 '12 at 16:32
    
some of the code might be a less than optimal. Thank you for pointing out areas that can be improved. –  user1668831 Sep 13 '12 at 21:05
    
The original Netlib implementation of ZHEEVR calls 15 different external functions and subroutines. Any of them could be non-reentrant and hence non-threadsafe. –  Hristo Iliev Sep 17 '12 at 9:09

1 Answer 1

you don't really give enough code (nor the actual symptoms) to debug this for you. Without that I can only guess that the implementation of zheerv_() uses global variables (either directly or indirectly).

Apart from the code smells I've mentioned already in my comments, there is an issue with the variable idt: the function EigenMethod() takes it by reference, but you pass a temporary (-idt) -- I'm surprised that compiled. I think you don't really change its value (x) inside EigenMethod(), so you should either take a constant references or (preferrable) just a value.

Btw, no need to declare shared variables in the parallel loop, just say

 #pragma omp parallel for
 for(int j=0; j<nMat ;++j) { /* ... */ }

and all variables declared outside the loop are shared by default and the loop variable should never be declared anything (private appears not to be the correct choice anyway).

share|improve this answer
    
The loop interation variables in parallel for loops are private by default. It doesn't hurt to put them in a private clause unless they are declared inside the control block of the for loop - then they do not exist in the outer scope and hence cannot be listed in any clause. –  Hristo Iliev Sep 17 '12 at 9:05
    
in C++, the loop iteration variables should always be declared within the for() statement (unless they are explicitly used outside, but this is never the case for a openMP parallel for loop). This ensures that their scope is where they are used and avoids simple bugs due to accidental usage outside. –  Walter Sep 17 '12 at 9:47

Your Answer

 
discard

By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.