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 would like to get some help for a weird problem. For a code got from online about matrix, I can compile and run on g++ but fail to build on VC++ 2008. The build error from vc++ is

------ Build started: Project: Matrix, Configuration: Debug Win32 ------
Compiling...Matrix.cpp

c:\matrix\matrix\matrix.cpp(260) : warning C4996: 'std::inner_product': Function call with parameters that may be unsafe - this call relies on the caller to check that the passed values are correct. To disable this warning, use -D_SCL_SECURE_NO_WARNINGS. See documentation on how to use Visual C++ 'Checked Iterators'

c:\program files (x86)\microsoft visual studio 9.0\vc\include\numeric(103) : see    declaration of 'std::inner_product'
c:\matrix\matrix\matrix.cpp(275) : warning C4996: 'std::inner_product': Function call with parameters that may be unsafe - this call relies on the caller to check that the passed values are correct. To disable this warning, use -D_SCL_SECURE_NO_WARNINGS. See documentation on how to use Visual C++ 'Checked Iterators'

c:\program files (x86)\microsoft visual studio 9.0\vc\include\numeric(103) : see declaration of 'std::inner_product'

c:\matrix\matrix\matrix.cpp(288) : warning C4018: '<' : signed/unsigned mismatch

c:\matrix\matrix\matrix.cpp(290) : warning C4018: '<' : signed/unsigned mismatch

c:\matrix\matrix\matrix.cpp(346) : warning C4018: '<' : signed/unsigned mismatch

c:\program files (x86)\microsoft visual studio 9.0\vc\include\xutility(1598) : error C2665: 'std::_Debug_range2' : none of the 2 overloads could convert all the argument types

c:\program files (x86)\microsoft visual studio 9.0\vc\include\xutility(1577): 
    could be 'void std::_Debug_range2<_InIt>(_InIt,_InIt,const wchar_t *,unsigned 
    int,std::input_iterator_tag)'
    with
    [
        _InIt=Cslice_iter<double>
    ]
    c:\program files (x86)\microsoft visual studio 9.0\vc\include\xutility(1583):      
    or       'void std::_Debug_range2<_InIt>(_RanIt,_RanIt,const wchar_t *,unsigned 
    int,std::random_access_iterator_tag)'
    with
    [
        _InIt=Cslice_iter<double>,
        _RanIt=Cslice_iter<double>
    ]
    while trying to match the argument list '(Cslice_iter<T>, Cslice_iter<T>, const wchar_t *, unsigned int, double)'
    with
    [
        T=double
    ]
    c:\program files (x86)\microsoft visual studio 9.0\vc\include\numeric(63) : see reference to function template instantiation 'void std::_Debug_range<_InIt1>(_InIt,_InIt,const wchar_t *,unsigned int)' being compiled
    with
    [
        _InIt1=Cslice_iter<double>,
        _InIt=Cslice_iter<double>
    ]
    c:\program files (x86)\microsoft visual studio 9.0\vc\include\numeric(106) : see reference to function template instantiation '_Ty std::_Inner_product<Cslice_iter<T>,_InIt2,_Ty,std::_Iter_random_helper<_Cat1,_Cat2>::_Iter_random_cat>(_InIt1,_InIt1,_InIt2,_Ty,_InItCats,std::_Range_checked_iterator_tag)' being compiled
    with
    [
        _Ty=double,
        T=double,
        _InIt2=double *,
        _Cat1=double,
        _Cat2=std::random_access_iterator_tag,
        _InIt1=Cslice_iter<double>,
        _InItCats=std::_Iter_random_helper<double,std::random_access_iterator_tag>::_Iter_random_cat
    ]
    c:\matrix\matrix\matrix.cpp(260) : see reference to function template instantiation 'double std::inner_product<Cslice_iter<T>,_Ty*,double>(_InIt1,_InIt1,_InIt2,_Ty)' being compiled
    with
    [
        T=double,
        _Ty=double,
        _InIt1=Cslice_iter<double>,
        _InIt2=double *
    ]
Build log was saved at "file://c:\Matrix\Matrix\Debug\BuildLog.htm"
Matrix - 1 error(s), 5 warning(s)
========== Build: 0 succeeded, 1 failed, 0 up-to-date, 0 skipped ==========

Any help is really appreciated.

Thanks very much.

// Program to test slices and a simple N*M matrix class



#include<iostream>
#include<valarray>
#include<algorithm>
#include<numeric>   // for inner_product
using namespace std;

// forward declarations to allow friend declarations:
template<class T> class Slice_iter;
template<class T> bool operator==(const Slice_iter<T>&, const Slice_iter<T>&);
template<class T> bool operator!=(const Slice_iter<T>&, const Slice_iter<T>&);
template<class T> bool operator< (const Slice_iter<T>&, const Slice_iter<T>&);

template<class T> class Slice_iter {
valarray<T>* v;
slice s;
size_t curr;    // index of current element

T& ref(size_t i) const { return (*v)[s.start()+i*s.stride()]; }
public:
Slice_iter(valarray<T>* vv, slice ss) :v(vv), s(ss), curr(0) { }

Slice_iter end() const
{
    Slice_iter t = *this;
    t.curr = s.size();  // index of last-plus-one element
    return t;
}

Slice_iter& operator++() { curr++; return *this; }
Slice_iter operator++(int) { Slice_iter t = *this; curr++; return t; }

T& operator[](size_t i) { return ref(i); }      // C style subscript
T& operator()(size_t i) { return ref(i); }      // Fortran-style subscript
T& operator*() { return ref(curr); }            // current element

friend bool operator==<>(const Slice_iter& p, const Slice_iter& q);
friend bool operator!=<>(const Slice_iter& p, const Slice_iter& q);
friend bool operator< <>(const Slice_iter& p, const Slice_iter& q);

};


template<class T>
bool operator==(const Slice_iter<T>& p, const Slice_iter<T>& q)
{
return p.curr==q.curr
    && p.s.stride()==q.s.stride()
    && p.s.start()==q.s.start();
}

template<class T>
bool operator!=(const Slice_iter<T>& p, const Slice_iter<T>& q)
{
return !(p==q);
}

template<class T>
bool operator<(const Slice_iter<T>& p, const Slice_iter<T>& q)
{
return p.curr<q.curr
    && p.s.stride()==q.s.stride()
    && p.s.start()==q.s.start();
}


//-------------------------------------------------------------



// forward declarations to allow friend declarations:
template<class T> class Cslice_iter;
template<class T> bool operator==(const Cslice_iter<T>&, const Cslice_iter<T>&);
template<class T> bool operator!=(const Cslice_iter<T>&, const Cslice_iter<T>&);
template<class T> bool operator< (const Cslice_iter<T>&, const Cslice_iter<T>&);


template<class T> class Cslice_iter
{
valarray<T>* v;
slice s;
size_t curr; // index of current element
const T& ref(size_t i) const { return (*v)[s.start()+i*s.stride()]; }
public:
Cslice_iter(valarray<T>* vv, slice ss): v(vv), s(ss), curr(0){}
//typedef T        iterator_category; //I added these defs, otherwise more compile errors on vc++
//typedef T        value_type;        //after I uncomment these, build only fails at call inner_product     
//typedef T*       iterator;          //and transform calls.
//typedef const T* const_iterator;
//typedef T&       reference;
//typedef const T& const_reference;
//typedef T*       pointer;
//typedef std::size_t    size_type;
typedef std::ptrdiff_t difference_type;

Cslice_iter end() const
{
    Cslice_iter t = *this;
    t.curr = s.size(); // index of one plus last element
    return t;
}
Cslice_iter& operator++() { curr++; return *this; }
Cslice_iter operator++(int) { Cslice_iter t = *this; curr++; return t; }

const T& operator[](size_t i) const { return ref(i); }
const T& operator()(size_t i) const { return ref(i); }
const T& operator*() const { return ref(curr); }

friend bool operator==<>(const Cslice_iter& p, const Cslice_iter& q);
friend bool operator!=<>(const Cslice_iter& p, const Cslice_iter& q);
friend bool operator< <>(const Cslice_iter& p, const Cslice_iter& q);

};

template<class T>
bool operator==(const Cslice_iter<T>& p, const Cslice_iter<T>& q)
{
return p.curr==q.curr
    && p.s.stride()==q.s.stride()
    && p.s.start()==q.s.start();
}

template<class T>
bool operator!=(const Cslice_iter<T>& p, const Cslice_iter<T>& q)
{
return !(p==q);
}

template<class T>
bool operator<(const Cslice_iter<T>& p, const Cslice_iter<T>& q)
{
return p.curr<q.curr
    && p.s.stride()==q.s.stride()
    && p.s.start()==q.s.start();
}


//-------------------------------------------------------------


class Matrix {
valarray<double>* v;    // stores elements by column as described in 22.4.5
size_t d1, d2;  // d1 == number of columns, d2 == number of rows
public:
Matrix(size_t x, size_t y);     // note: no default constructor
Matrix(const Matrix&);
Matrix& operator=(const Matrix&);
~Matrix();

size_t size() const { return d1*d2; }
size_t dim1() const { return d1; }
size_t dim2() const { return d2; }

Slice_iter<double> row(size_t i);
Cslice_iter<double> row(size_t i) const;

Slice_iter<double> column(size_t i);
Cslice_iter<double> column(size_t i) const;

double& operator()(size_t x, size_t y); // Fortran-style subscripts
double operator()(size_t x, size_t y) const;

Slice_iter<double> operator()(size_t i) { return column(i); }
Cslice_iter<double> operator()(size_t i) const { return column(i); }

Slice_iter<double> operator[](size_t i) { return column(i); }// C-style subscript
Cslice_iter<double> operator[](size_t i) const { return column(i); }

Matrix& operator*=(double);

valarray<double>& array() { return *v; }
};


inline Slice_iter<double> Matrix::row(size_t i)
{
return Slice_iter<double>(v,slice(i,d1,d2));
}

inline Cslice_iter<double> Matrix::row(size_t i) const
{
return Cslice_iter<double>(v,slice(i,d1,d2));
}

inline Slice_iter<double> Matrix::column(size_t i)
{
return Slice_iter<double>(v,slice(i*d2,d2,1));
}

inline Cslice_iter<double> Matrix::column(size_t i) const
{
return Cslice_iter<double>(v,slice(i*d2,d2,1));
}

Matrix::Matrix(size_t x, size_t y)
{
// check that x and y are sensible
d1 = x;
d2 = y;
v = new valarray<double>(x*y);
}

Matrix::~Matrix()
{
delete v;
}

double& Matrix::operator()(size_t x, size_t y)
{
return column(x)[y];
}



//-------------------------------------------------------------




double mul(const Cslice_iter<double>& v1, const valarray<double>& v2)
{
double res = 0;
for (size_t i = 0; i<v2.size(); i++) res+= v1[i]*v2[i];
return res;
}


valarray<double> operator*(const Matrix& m, const valarray<double>& v)
{
if (m.dim1()!=v.size()) cerr << "wrong number of elements in m*v\n";

valarray<double> res(m.dim2());
for (size_t i = 0; i<m.dim2(); i++) res[i] = mul(m.row(i),v);
return res;
}


// alternative definition of m*v

//valarray<double> operator*(const Matrix& m, valarray<double>& v)
valarray<double> mul_mv(const Matrix& m, valarray<double>& v)
{
if (m.dim1()!=v.size()) cerr << "wrong number of elements in m*v\n";

valarray<double> res(m.dim2());

for (size_t i = 0; i<m.dim2(); i++) {
    const Cslice_iter<double>& ri = m.row(i);
    res[i] = inner_product(ri,ri.end(),&v[0],double(0));
}
return res;
}



valarray<double> operator*(valarray<double>& v, const Matrix& m)
{
if (v.size()!=m.dim2()) cerr << "wrong number of elements in v*m\n";

valarray<double> res(m.dim1());

for (size_t i = 0; i<m.dim1(); i++) {
    const Cslice_iter<double>& ci = m.column(i);
    res[i] = inner_product(ci,ci.end(),&v[0],double(0));
}
return res;
}

Matrix& Matrix::operator*=(double d)
{
(*v) *= d;
return *this;
}

ostream& operator<<(ostream& os, Matrix& m)
{
for(int y=0; y<m.dim2(); y++)
{
    for(int x=0; x<m.dim1(); x++)
        os<<m[x][y]<<"\t";
    os << "\n";
}
return os;
}


//-------------------------------------------------------------


void f (int x_max, int y_max)   // test layout and basic access
{
cout << "\nf(" << x_max <<"," << y_max << "):\n";

Matrix a(x_max, y_max);

for(int x=0; x<x_max; x++)      // initialize
    for(int y=0; y<y_max; y++)
        a[x][y]=x+y*10;

cout<<"C-style access used to initialize:\n" << a;

for(int x=0; x<x_max; x++)
    for(int y=0; y<y_max; y++)
        a(x,y)=x+y*10;

cout <<"Fortran-style access used to initialize:\n" << a;

cout << "addresses: \n";

for(int x=0; x<x_max; x++)
    for(int y=0; y<y_max; y++)
        cout<<"("<< x<<","<<y<<") at "<<&a[x][y]-&a[0][0]<<"\n";
cout <<"columns :\n";

for(int x=0; x<x_max; x++) {
    cout << "column " << x << ":\n";
    for (Slice_iter<double> c = a.column(x); c!=c.end(); ++c)
        cout << "\t" << *c <<"\n";
}

cout <<"rows :\n";

for(int y=0; y<y_max; y++) {
    cout << "row " << y << ":";
    for(Slice_iter<double> r = a.row(y); r!=r.end(); ++r)
        cout << "\t" << *r ;
    cout <<"\n";
}


}

ostream& operator<<(ostream& os, const valarray<double>& v)
{
for (int i = 0; i<v.size(); ++i) os << '\t' << v[i];
return os;
}

void g(int x_max,int y_max) // check multiplication
{
cout << "\ng(" << x_max <<"," << y_max << "):\n";

Matrix a(x_max,y_max);

for(int x=0; x<x_max; x++)      // initialize
    for(int y=0; y<y_max; y++)
        a[x][y]=x+y*10;

valarray<double> r(2,x_max);
cout << "a*v: " << a*r << endl;
cout << "m*v: " << mul_mv(a,r) << endl;

valarray<double> c(2,y_max);
cout << "v*a: " << c*a << endl;

}

int main()
{
f(3,4);
f(4,3);

g(3,4);
g(4,3);
}


//main for vc++
/*int _tmain(int argc, _TCHAR* argv[])
{
f(3,4);
f(4,3);

g(3,4);
g(4,3);

return 0;
}*/

// the stdafx.h from vc++
// stdafx.h : include file for standard system include files,
// or project specific include files that are used frequently, but
// are changed infrequently
//

/*#pragma once

#include "targetver.h"

#include <stdio.h>
#include <tchar.h>
*/
share|improve this question

1 Answer 1

I believe the library is trying to find out if your iterator is an input_iterator or a random_access_iterator by looking for the nested typedefs a well behaved iterator should contain. Specifically iterator_category.

The standard suggests inheriting from std::iterator to get appropriate definitions.

24.4.2 Basic iterator
The iterator template may be used as a base class to ease the definition of required types for new iterators.

namespace std {

    template<class Category, class T, class Distance = ptrdiff_t,
             class Pointer = T*, class Reference = T&>
    struct iterator {
        typedef T value_type;

        typedef Distance difference_type;

        typedef Pointer pointer;

        typedef Reference reference;

        typedef Category iterator_category;

    };

}

Or you can just add the same set of typedefs to your existing class.

share|improve this answer
    
Hi Bo, Thanks for quick response. Could you provide me info about "add the same set of typedefs to your existing class"? I am not sure which class to add as I added to Cslice_iter and tried to add Slice_iter but with the same error. –  Mark Anderson May 7 '12 at 16:28
    
The typedefs are used by iterator_traits to determine the type of an iterator. If you iterator supports random access, it should contain typedef random_access_iterator_tag iterator_category to indicate that. The errors mention Cslice_iter<double>, so that must be the primary candidate. –  Bo Persson May 7 '12 at 16:51

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.