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Ok, so I'm trying to parallelize some C++ code using OpenMP, but I keep getting this weird error. The compiler finds the library and everything, but it gives me an error in side the library itself. It says:

In function 'void set_num_threads(int)':
error: expected primary-initialization before ',' token

The error occurs in this line:

extern void omp_set_num_threads (int) __GOMP_NOTHROW;

... but it also gives an error for almost every other function the file defines. I figure there's something wrong with my compiler, but I don't know what it could be or how to fix it. Help is greatly appreciated. Thank you.

UPDATE I tried running the code on an online compiler and I got the same error, so I have no idea what's wrong.

Ok, so including a random number generator I got from my professor seems to cause the problem. This is the code for its .h file.

#ifndef _NR3_H_
#define _NR3_H_

//#define _CHECKBOUNDS_ 1
//#define _USESTDVECTOR_ 1
//#define _USENRERRORCLASS_ 1
//#define _TURNONFPES_ 1

// all the system #include's we'll ever need
#include <fstream>
#include <cmath>
#include <complex>
#include <iostream>
#include <iomanip>
#include <vector>
#include <limits>
#include <stdlib.h>
#include <stdio.h>
#include <time.h>
#include <fcntl.h>
#include <string.h>
#include <ctype.h>

using namespace std;

// macro-like inline functions

template<class T>
inline T SQR(const T a) {return a*a;}

template<class T>
inline const T &MAX(const T &a, const T &b)
        {return b > a ? (b) : (a);}

inline float MAX(const double &a, const float &b)
        {return b > a ? (b) : float(a);}

inline float MAX(const float &a, const double &b)
        {return b > a ? float(b) : (a);}

template<class T>
inline const T &MIN(const T &a, const T &b)
        {return b < a ? (b) : (a);}

inline float MIN(const double &a, const float &b)
        {return b < a ? (b) : float(a);}

inline float MIN(const float &a, const double &b)
        {return b < a ? float(b) : (a);}

template<class T>
inline T SIGN(const T &a, const T &b)
    {return b >= 0 ? (a >= 0 ? a : -a) : (a >= 0 ? -a : a);}

inline float SIGN(const float &a, const double &b)
    {return b >= 0 ? (a >= 0 ? a : -a) : (a >= 0 ? -a : a);}

inline float SIGN(const double &a, const float &b)
    {return (float)(b >= 0 ? (a >= 0 ? a : -a) : (a >= 0 ? -a : a));}

template<class T>
inline void SWAP(T &a, T &b)
    {T dum=a; a=b; b=dum;}

// exception handling

#ifndef _USENRERRORCLASS_
#define throw(message) \
{printf("ERROR: %s\n     in file %s at line %d\n", message,__FILE__,__LINE__); throw(1);}
#else
struct NRerror {
    char *message;
    char *file;
    int line;
    NRerror(char *m, char *f, int l) : message(m), file(f), line(l) {}
};
#define throw(message) throw(NRerror(message,__FILE__,__LINE__));
void NRcatch(NRerror err) {
    printf("ERROR: %s\n     in file %s at line %d\n",
        err.message, err.file, err.line);
    exit(1);
}
#endif

// usage example:
//
//  try {
//      somebadroutine();
//  }
//  catch(NRerror s) {NRcatch(s);}
//
// (You can of course substitute any other catch body for NRcatch(s).)


// Vector and Matrix Classes

#ifdef _USESTDVECTOR_
#define NRvector vector
#else

template <class T>
class NRvector {
private:
    int nn; // size of array. upper index is nn-1
    T *v;
public:
    NRvector();
    explicit NRvector(int n);       // Zero-based array
    NRvector(int n, const T &a);    //initialize to constant value
    NRvector(int n, const T *a);    // Initialize to array
    NRvector(const NRvector &rhs);  // Copy constructor
    NRvector & operator=(const NRvector &rhs);  //assignment
    typedef T value_type; // make T available externally
    inline T & operator[](const int i); //i'th element
    inline const T & operator[](const int i) const;
    inline int size() const;
    void resize(int newn); // resize (contents not preserved)
    void assign(int newn, const T &a); // resize and assign a constant value
    ~NRvector();
};

// NRvector definitions

template <class T>
NRvector<T>::NRvector() : nn(0), v(NULL) {}

template <class T>
NRvector<T>::NRvector(int n) : nn(n), v(n>0 ? new T[n] : NULL) {}

template <class T>
NRvector<T>::NRvector(int n, const T& a) : nn(n), v(n>0 ? new T[n] : NULL)
{
    for(int i=0; i<n; i++) v[i] = a;
}

template <class T>
NRvector<T>::NRvector(int n, const T *a) : nn(n), v(n>0 ? new T[n] : NULL)
{
    for(int i=0; i<n; i++) v[i] = *a++;
}

template <class T>
NRvector<T>::NRvector(const NRvector<T> &rhs) : nn(rhs.nn), v(nn>0 ? new T[nn] : NULL)
{
    for(int i=0; i<nn; i++) v[i] = rhs[i];
}

template <class T>
NRvector<T> & NRvector<T>::operator=(const NRvector<T> &rhs)
// postcondition: normal assignment via copying has been performed;
//      if vector and rhs were different sizes, vector
//      has been resized to match the size of rhs
{
    if (this != &rhs)
    {
        if (nn != rhs.nn) {
            if (v != NULL) delete [] (v);
            nn=rhs.nn;
            v= nn>0 ? new T[nn] : NULL;
        }
        for (int i=0; i<nn; i++)
            v[i]=rhs[i];
    }
    return *this;
}

template <class T>
inline T & NRvector<T>::operator[](const int i) //subscripting
{
#ifdef _CHECKBOUNDS_
if (i<0 || i>=nn) {
    throw("NRvector subscript out of bounds");
}
#endif
    return v[i];
}

template <class T>
inline const T & NRvector<T>::operator[](const int i) const //subscripting
{
#ifdef _CHECKBOUNDS_
if (i<0 || i>=nn) {
    throw("NRvector subscript out of bounds");
}
#endif
    return v[i];
}

template <class T>
inline int NRvector<T>::size() const
{
    return nn;
}

template <class T>
void NRvector<T>::resize(int newn)
{
    if (newn != nn) {
        if (v != NULL) delete[] (v);
        nn = newn;
        v = nn > 0 ? new T[nn] : NULL;
    }
}

template <class T>
void NRvector<T>::assign(int newn, const T& a)
{
    if (newn != nn) {
        if (v != NULL) delete[] (v);
        nn = newn;
        v = nn > 0 ? new T[nn] : NULL;
    }
    for (int i=0;i<nn;i++) v[i] = a;
}

template <class T>
NRvector<T>::~NRvector()
{
    if (v != NULL) delete[] (v);
}

// end of NRvector definitions

#endif //ifdef _USESTDVECTOR_

template <class T>
class NRmatrix {
private:
    int nn;
    int mm;
    T **v;
public:
    NRmatrix();
    NRmatrix(int n, int m);         // Zero-based array
    NRmatrix(int n, int m, const T &a); //Initialize to constant
    NRmatrix(int n, int m, const T *a); // Initialize to array
    NRmatrix(const NRmatrix &rhs);      // Copy constructor
    NRmatrix & operator=(const NRmatrix &rhs);  //assignment
    typedef T value_type; // make T available externally
    inline T* operator[](const int i);  //subscripting: pointer to row i
    inline const T* operator[](const int i) const;
    inline int nrows() const;
    inline int ncols() const;
    void resize(int newn, int newm); // resize (contents not preserved)
    void assign(int newn, int newm, const T &a); // resize and assign a constant value
    ~NRmatrix();
};

template <class T>
NRmatrix<T>::NRmatrix() : nn(0), mm(0), v(NULL) {}

template <class T>
NRmatrix<T>::NRmatrix(int n, int m) : nn(n), mm(m), v(n>0 ? new T*[n] : NULL)
{
    int i,nel=m*n;
    if (v) v[0] = nel>0 ? new T[nel] : NULL;
    for (i=1;i<n;i++) v[i] = v[i-1] + m;
}

template <class T>
NRmatrix<T>::NRmatrix(int n, int m, const T &a) : nn(n), mm(m), v(n>0 ? new T*[n] : NULL)
{
    int i,j,nel=m*n;
    if (v) v[0] = nel>0 ? new T[nel] : NULL;
    for (i=1; i< n; i++) v[i] = v[i-1] + m;
    for (i=0; i< n; i++) for (j=0; j<m; j++) v[i][j] = a;
}

template <class T>
NRmatrix<T>::NRmatrix(int n, int m, const T *a) : nn(n), mm(m), v(n>0 ? new T*[n] : NULL)
{
    int i,j,nel=m*n;
    if (v) v[0] = nel>0 ? new T[nel] : NULL;
    for (i=1; i< n; i++) v[i] = v[i-1] + m;
    for (i=0; i< n; i++) for (j=0; j<m; j++) v[i][j] = *a++;
}

template <class T>
NRmatrix<T>::NRmatrix(const NRmatrix &rhs) : nn(rhs.nn), mm(rhs.mm), v(nn>0 ? new T*[nn] : NULL)
{
    int i,j,nel=mm*nn;
    if (v) v[0] = nel>0 ? new T[nel] : NULL;
    for (i=1; i< nn; i++) v[i] = v[i-1] + mm;
    for (i=0; i< nn; i++) for (j=0; j<mm; j++) v[i][j] = rhs[i][j];
}

template <class T>
NRmatrix<T> & NRmatrix<T>::operator=(const NRmatrix<T> &rhs)
// postcondition: normal assignment via copying has been performed;
//      if matrix and rhs were different sizes, matrix
//      has been resized to match the size of rhs
{
    if (this != &rhs) {
        int i,j,nel;
        if (nn != rhs.nn || mm != rhs.mm) {
            if (v != NULL) {
                delete[] (v[0]);
                delete[] (v);
            }
            nn=rhs.nn;
            mm=rhs.mm;
            v = nn>0 ? new T*[nn] : NULL;
            nel = mm*nn;
            if (v) v[0] = nel>0 ? new T[nel] : NULL;
            for (i=1; i< nn; i++) v[i] = v[i-1] + mm;
        }
        for (i=0; i< nn; i++) for (j=0; j<mm; j++) v[i][j] = rhs[i][j];
    }
    return *this;
}

template <class T>
inline T* NRmatrix<T>::operator[](const int i)  //subscripting: pointer to row i
{
#ifdef _CHECKBOUNDS_
if (i<0 || i>=nn) {
    throw("NRmatrix subscript out of bounds");
}
#endif
    return v[i];
}

template <class T>
inline const T* NRmatrix<T>::operator[](const int i) const
{
#ifdef _CHECKBOUNDS_
if (i<0 || i>=nn) {
    throw("NRmatrix subscript out of bounds");
}
#endif
    return v[i];
}

template <class T>
inline int NRmatrix<T>::nrows() const
{
    return nn;
}

template <class T>
inline int NRmatrix<T>::ncols() const
{
    return mm;
}

template <class T>
void NRmatrix<T>::resize(int newn, int newm)
{
    int i,nel;
    if (newn != nn || newm != mm) {
        if (v != NULL) {
            delete[] (v[0]);
            delete[] (v);
        }
        nn = newn;
        mm = newm;
        v = nn>0 ? new T*[nn] : NULL;
        nel = mm*nn;
        if (v) v[0] = nel>0 ? new T[nel] : NULL;
        for (i=1; i< nn; i++) v[i] = v[i-1] + mm;
    }
}

template <class T>
void NRmatrix<T>::assign(int newn, int newm, const T& a)
{
    int i,j,nel;
    if (newn != nn || newm != mm) {
        if (v != NULL) {
            delete[] (v[0]);
            delete[] (v);
        }
        nn = newn;
        mm = newm;
        v = nn>0 ? new T*[nn] : NULL;
        nel = mm*nn;
        if (v) v[0] = nel>0 ? new T[nel] : NULL;
        for (i=1; i< nn; i++) v[i] = v[i-1] + mm;
    }
    for (i=0; i< nn; i++) for (j=0; j<mm; j++) v[i][j] = a;
}

template <class T>
NRmatrix<T>::~NRmatrix()
{
    if (v != NULL) {
        delete[] (v[0]);
        delete[] (v);
    }
}

template <class T>
class NRMat3d {
private:
    int nn;
    int mm;
    int kk;
    T ***v;
public:
    NRMat3d();
    NRMat3d(int n, int m, int k);
    inline T** operator[](const int i); //subscripting: pointer to row i
    inline const T* const * operator[](const int i) const;
    inline int dim1() const;
    inline int dim2() const;
    inline int dim3() const;
    ~NRMat3d();
};

template <class T>
NRMat3d<T>::NRMat3d(): nn(0), mm(0), kk(0), v(NULL) {}

template <class T>
NRMat3d<T>::NRMat3d(int n, int m, int k) : nn(n), mm(m), kk(k), v(new T**[n])
{
    int i,j;
    v[0] = new T*[n*m];
    v[0][0] = new T[n*m*k];
    for(j=1; j<m; j++) v[0][j] = v[0][j-1] + k;
    for(i=1; i<n; i++) {
        v[i] = v[i-1] + m;
        v[i][0] = v[i-1][0] + m*k;
        for(j=1; j<m; j++) v[i][j] = v[i][j-1] + k;
    }
}

template <class T>
inline T** NRMat3d<T>::operator[](const int i) //subscripting: pointer to row i
{
    return v[i];
}

template <class T>
inline const T* const * NRMat3d<T>::operator[](const int i) const
{
    return v[i];
}

template <class T>
inline int NRMat3d<T>::dim1() const
{
    return nn;
}

template <class T>
inline int NRMat3d<T>::dim2() const
{
    return mm;
}

template <class T>
inline int NRMat3d<T>::dim3() const
{
    return kk;
}

template <class T>
NRMat3d<T>::~NRMat3d()
{
    if (v != NULL) {
        delete[] (v[0][0]);
        delete[] (v[0]);
        delete[] (v);
    }
}


// basic type names (redefine if your bit lengths don't match)

typedef int Int; // 32 bit integer
typedef unsigned int Uint;

#ifdef _MSC_VER
typedef __int64 Llong; // 64 bit integer
typedef unsigned __int64 Ullong;
#else
typedef long long int Llong; // 64 bit integer
typedef unsigned long long int Ullong;
#endif

typedef char Char; // 8 bit integer
typedef unsigned char Uchar;

typedef double Doub; // default floating type
typedef long double Ldoub;

typedef complex<double> Complex; // default complex type

typedef bool Bool;

// NaN: uncomment one of the following 3 methods of defining a global NaN
// you can test by verifying that (NaN != NaN) is true

static const Doub NaN = numeric_limits<Doub>::quiet_NaN();

//Uint proto_nan[2]={0xffffffff, 0x7fffffff};
//double NaN = *( double* )proto_nan;

//Doub NaN = sqrt(-1.);

// vector types

typedef const NRvector<Int> VecInt_I;
typedef NRvector<Int> VecInt, VecInt_O, VecInt_IO;

typedef const NRvector<Uint> VecUint_I;
typedef NRvector<Uint> VecUint, VecUint_O, VecUint_IO;

typedef const NRvector<Llong> VecLlong_I;
typedef NRvector<Llong> VecLlong, VecLlong_O, VecLlong_IO;

typedef const NRvector<Ullong> VecUllong_I;
typedef NRvector<Ullong> VecUllong, VecUllong_O, VecUllong_IO;

typedef const NRvector<Char> VecChar_I;
typedef NRvector<Char> VecChar, VecChar_O, VecChar_IO;

typedef const NRvector<Char*> VecCharp_I;
typedef NRvector<Char*> VecCharp, VecCharp_O, VecCharp_IO;

typedef const NRvector<Uchar> VecUchar_I;
typedef NRvector<Uchar> VecUchar, VecUchar_O, VecUchar_IO;

typedef const NRvector<Doub> VecDoub_I;
typedef NRvector<Doub> VecDoub, VecDoub_O, VecDoub_IO;

typedef const NRvector<Doub*> VecDoubp_I;
typedef NRvector<Doub*> VecDoubp, VecDoubp_O, VecDoubp_IO;

typedef const NRvector<Complex> VecComplex_I;
typedef NRvector<Complex> VecComplex, VecComplex_O, VecComplex_IO;

typedef const NRvector<Bool> VecBool_I;
typedef NRvector<Bool> VecBool, VecBool_O, VecBool_IO;

// matrix types

typedef const NRmatrix<Int> MatInt_I;
typedef NRmatrix<Int> MatInt, MatInt_O, MatInt_IO;

typedef const NRmatrix<Uint> MatUint_I;
typedef NRmatrix<Uint> MatUint, MatUint_O, MatUint_IO;

typedef const NRmatrix<Llong> MatLlong_I;
typedef NRmatrix<Llong> MatLlong, MatLlong_O, MatLlong_IO;

typedef const NRmatrix<Ullong> MatUllong_I;
typedef NRmatrix<Ullong> MatUllong, MatUllong_O, MatUllong_IO;

typedef const NRmatrix<Char> MatChar_I;
typedef NRmatrix<Char> MatChar, MatChar_O, MatChar_IO;

typedef const NRmatrix<Uchar> MatUchar_I;
typedef NRmatrix<Uchar> MatUchar, MatUchar_O, MatUchar_IO;

typedef const NRmatrix<Doub> MatDoub_I;
typedef NRmatrix<Doub> MatDoub, MatDoub_O, MatDoub_IO;

typedef const NRmatrix<Bool> MatBool_I;
typedef NRmatrix<Bool> MatBool, MatBool_O, MatBool_IO;

// 3D matrix types

typedef const NRMat3d<Doub> Mat3DDoub_I;
typedef NRMat3d<Doub> Mat3DDoub, Mat3DDoub_O, Mat3DDoub_IO;

// Floating Point Exceptions for Microsoft compilers

#ifdef _TURNONFPES_
#ifdef _MSC_VER
struct turn_on_floating_exceptions {
    turn_on_floating_exceptions() {
        int cw = _controlfp( 0, 0 );
        cw &=~(EM_INVALID | EM_OVERFLOW | EM_ZERODIVIDE );
        _controlfp( cw, MCW_EM );
    }
};
turn_on_floating_exceptions yes_turn_on_floating_exceptions;
#endif /* _MSC_VER */
#endif /* _TURNONFPES */

#endif /* _NR3_H_ */





/*This is the ran.h routine provided by NR page 342.  It creates a uniform random deviate between 0 and 1,
  and it is useful for either 64 or 32 bit machines */
struct Ran
{
  Ullong u, v, w;
  Ran(Ullong j) : v(4101842887655102017LL), w(1)
  {
    u = j ^ v; int64();
    v = u; int64();
    w = v; int64();
  }
  inline Ullong int64()
  {
    u = u * 2862933555777941757LL + 7046029254386353087LL;
    v ^= v >> 17; v ^= v << 31; v ^= v >> 8;
    w = 4294957665U * (w & 0xffffffff) + (w >> 32);
    Ullong x = u ^ (u << 21); x ^= x >> 35; x ^= x << 4;
    return (x+v) ^ w;
  }
  inline Doub doub() {return 5.42101086242752217E-20 * int64(); }
  inline Uint int32() { return (Uint)int64();}
};



struct Normaldev : Ran {
    Doub mu, sig;
    Normaldev(Doub mmu, Doub ssig, Ullong i)
    : Ran(i), mu(mmu), sig (ssig){}
    Doub dev()
    {
        Doub u,v,x,y,q;
        do{
            u = doub();
            v = 1.7156*(doub() - 0.5);
            x = u - 0.449871;
            y = abs(v) + 0.386595;
            q = SQR(x) + y * (0.19600*y - 0.25472*x);
        } while (q > 0.27597 && (q > 0.27846 || SQR(v) > -4.*log(u)*SQR(u)));
        return mu + sig*v/u;
    }
};

Other Update Apparently if I put 'include omp.h' before 'include "nr3.h"' it compiles(I guess because omp compiles before throw is redefined as a macro). Thank you so much for your help everyone.

2
  • Do you have weird macros defined? omp_set_num_threads isn't a macro is it?
    – user541686
    Commented Sep 22, 2013 at 2:34
  • 3
    Can you show us the code around your include statement? It's possible the syntax error occurs before the include. Commented Sep 22, 2013 at 2:38

2 Answers 2

1

What's wrong is the macro "__GOMP_NOTHROW" is undefined.

POSSIBLE WORKAROUND: Add -D__GOMP_NOTHROW to your compile switches. For example, add it to "CFLAGS" at the top of your Makefile, or "define macro" in your IDE.

Here's the definition from one version of omp.h:

#ifdef __cplusplus
extern "C" {
# define __GOMP_NOTHROW throw ()
#else
# define __GOMP_NOTHROW __attribute__((__nothrow__))
#endif
2
  • The error is showing up in the library, though. I know the library is working, and __GOMP_NOTHROW is defined earlier in the file. There's something wrong with how I'm including the library. Commented Sep 22, 2013 at 15:22
  • So your professor gave you some weird "nr3.h" header that redefines "throw" as a macro? Charming ;) Q: Out of curiousity, what compiler/compiler version/platform are you on?
    – paulsm4
    Commented Sep 22, 2013 at 17:12
0

Compile your program with the option (for g++)

-fopenmp

Or the openmp flag compatible with your compiler.

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