# Understanding LAPACK calls in C++ with a simple example

I am a beginner with LAPACK and C++/Fortran interfacing. I need to solve linear equations and eigenvalues problems using LAPACK/BLAS on Mac OS-X Lion. OS-X Lion provides optimized BLAS and LAPACK libraries (in /usr/lib) and I am linking these libraries instead of downloading them from netlib.

My program (reproduced below) is compiling and running fine, but it is giving me wrong answers. I have researched in the web and Stackoverflow and the issue may have to deal with how C++ and Fortran store arrays in differing formats (row major vs Column major). However, as you will see in my example, the simple array for my example should look identical in C++ and fortran. Anyway here goes.

Lets say we want to solve the following linear system:

x + y = 2

x - y = 0

The solution is (x,y) = (1,1). Now I tried to solve this using Lapack as follows

``````// LAPACK test code

#include<iostream>
#include<vector>

using namespace std;
extern "C" void dgetrs(char *TRANS, int *N, int *NRHS, double *A,
int *LDA, int *IPIV, double *B, int *LDB, int *INFO );

int main()
{
char trans = 'N';
int dim = 2;
int nrhs = 1;
int LDA = dim;
int LDB = dim;
int info;

vector<double> a, b;

a.push_back(1);
a.push_back(1);
a.push_back(1);
a.push_back(-1);

b.push_back(2);
b.push_back(0);

int ipiv[3];

dgetrs(&trans, &dim, &nrhs, & *a.begin(), &LDA, ipiv, & *b.begin(), &LDB, &info);

std::cout << "solution is:";
std::cout << "[" << b[0] << ", " << b[1] << ", " << "]" << std::endl;
std::cout << "Info = " << info << std::endl;

return(0);
}
``````

This code was compiled as follows:

`g++ -Wall -llapack -lblas lapacktest.cpp`

On running this, however, I get the solution as (-2,2) which is obviously wrong. I have tried all combination of row/column re-arrangement of my matrix `a`. Also observe the matrix representation of `a` should be identical in row and column formats. I think getting this simple example to work will get me started with LAPACK and any help will be appreciated.

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what lapack library are you using and is it 64 bit code? –  Anycorn Apr 11 '12 at 18:57
I am using the /usr/lib/liblapack.dylib and /usr/lib/libblas.dylib that is natively present on Mac OS-X Lion. I have not installed any external LAPACK/BLAS libraries. –  RDK Apr 11 '12 at 18:59
In you example, you are solving a symmetric matrix so whether you have row-major or column-major, you won't see any difference. –  GuyGreer Apr 11 '12 at 19:00

## 3 Answers

You need to factor the matrix (by calling `dgetrf`) before you can solve the system using `dgetrs`. Alternatively, you can use the `dgesv` routine, which does both steps for you.

By the way, you don't need to declare the interfaces yourself, they are in the Accelerate headers:

``````// LAPACK test code

#include <iostream>
#include <vector>
#include <Accelerate/Accelerate.h>

using namespace std;

int main()
{
char trans = 'N';
int dim = 2;
int nrhs = 1;
int LDA = dim;
int LDB = dim;
int info;

vector<double> a, b;

a.push_back(1);
a.push_back(1);
a.push_back(1);
a.push_back(-1);

b.push_back(2);
b.push_back(0);

int ipiv[3];

dgetrf_(&dim, &dim, &*a.begin(), &LDA, ipiv, &info);
dgetrs_(&trans, &dim, &nrhs, & *a.begin(), &LDA, ipiv, & *b.begin(), &LDB, &info);

std::cout << "solution is:";
std::cout << "[" << b[0] << ", " << b[1] << ", " << "]" << std::endl;
std::cout << "Info = " << info << std::endl;

return(0);
}
``````
-
Stephen, thanks so much. This works. By the way, I hope you dont mind answering two follow-up questions: (1) Where can I find documentation of LAPACK which specifies all the dependencies (like using dgetrf before dgetrs). For example, I constructed my original program by looking up the information in the dgetrs() function in Netlib. However, it didnt say that I first had to factor using dgetrf. (2) I am assuming that to use Accelerate framework, I just compile using -framework Accelerate. Is that correct? Thanks once again. –  RDK Apr 11 '12 at 19:15
@RDK: You can either compile with -framework Accelerate or link directly against LAPACK/BLAS as you have been doing (you end up getting the same LAPACK library either way). Looking at `dgetrs` on netlib actually does tell you that you need `dgetrf`: "DGETRS solves a system of linear equations with a general N-by-N matrix A using the LU factorization computed by DGETRF." However, a better reference would be the LAPACK user's guide, which is available in html on netlib, and also in a cheap dead tree form. –  Stephen Canon Apr 11 '12 at 19:23
You are right. It does say so. By bad and apologies. I guess I have to read more carefully in the future. I am going for the cheap dead tree form, as my colleagues will also be interested in a reference at hand. Thanks once again for your patience and responses. –  RDK Apr 11 '12 at 19:31
@RDK: no need to apologize, that text is confusing at best. –  Stephen Canon Apr 11 '12 at 19:34

If you want to use LAPACK from C++ you might want to have a look a FLENS. It defines low- and high-level interfaces to LAPACK but also re-implements some LAPACK functions.

With the low-level FLENS-LAPACK interface you can use your own matrix/vector types (if they have a LAPACK conform memory layout). Your call of `dgetrf` would look like that:

``````info = lapack::getrf(NoTrans, dim, nrhs, a.begin(), LDA, ipiv);
``````

and for `dgetrs`

``````lapack::getrs(NoTrans, dim, nrhs, a.begin(), LDA, ipiv, b.begin(), LDB);
``````

So the low-level FLENS-LAPACK functions are overloaded with respect to the element types. Consequently LAPACK function `sgetrs`, `dgetrs`, `cgetrs`, `zgetrs` are in the low-level interface of FLENS-LAPACK `lapack::getrs`. You also pass parameters by value/reference and not as pointer (e.g. `LDA` instead of `&LDA`).

If you use the FLENS matrix-types you can code it as

``````info = lapack::trf(NoTrans, A, ipiv);
if (info==0) {
lapack::trs(NoTrans, A, ipiv, b);
}
``````

Or you just use the LAPACK driver function `dgesv`

``````lapack::sv(NoTrans, A, ipiv, b);
``````

Here a list of FLENS-LAPACK driver functions.

Disclaimer: Yes, FLENS is my baby! That means I coded about 95% of it and every line of code was worth it.

-
FLENS looks like a great way to interface LAPACK/C++. I will be sure to check this out. –  RDK Oct 4 '12 at 19:44

For those who don't want bother with the Accelerate Framework, I provide the code of Stephen Canon (thanks to him, of course) with nothing but pure library linking

``````// LAPACK test code
//compile with: g++ main.cpp -llapack -lblas -o testprog

#include <iostream>
#include <vector>

using namespace std;

extern "C" void dgetrf_(int* dim1, int* dim2, double* a, int* lda, int* ipiv, int* info);
extern "C" void dgetrs_(char *TRANS, int *N, int *NRHS, double *A, int *LDA, int *IPIV, double *B, int *LDB, int *INFO );

int main()
{
char trans = 'N';
int dim = 2;
int nrhs = 1;
int LDA = dim;
int LDB = dim;
int info;

vector<double> a, b;

a.push_back(1);
a.push_back(1);
a.push_back(1);
a.push_back(-1);

b.push_back(2);
b.push_back(0);

int ipiv[3];

dgetrf_(&dim, &dim, &*a.begin(), &LDA, ipiv, &info);
dgetrs_(&trans, &dim, &nrhs, & *a.begin(), &LDA, ipiv, & *b.begin(), &LDB, &info);

std::cout << "solution is:";
std::cout << "[" << b[0] << ", " << b[1] << ", " << "]" << std::endl;
std::cout << "Info = " << info << std::endl;

return(0);
}
``````

And about the manual, there's a full PDF version available at Intel's website. Here's a sample of their HTML documentation.

http://software.intel.com/sites/products/documentation/hpc/mkl/mklman/GUID-A02DB70F-9704-42A4-9071-D409D783D911.htm

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This code example was very helpful. Helped me recognize that my copy of the LAPACK libraries wasn't linked to my project correctly. –  NoseKnowsAll Feb 21 at 9:00