Hot answers tagged lapack++
This is a least squares solution, because you have more unknowns than equations. If m is indeed equal to 2, that tells me that a simple linear least squares will be sufficient for you. The formulas can be written out in closed form. You don't need a library. If m is in single digits, I'd still say that you can easily solve this using A(transpose)*A*X = ...
uBlas is not optimized unless you use it with optimized BLAS bindings. The following are optimized for multi-threading and SIMD: Intel MKL. FORTRAN library with C interface. Not free but very good. Eigen. True C++ library. Free and open source. Easy to use and good. Atlas. FORTRAN and C. Free and open source. Not Windows friendly, but otherwise good. ...
From a numerical analysis standpoint, you never want to write code that Explicitly inverts a matrix, or Forms the matrix of normal equations (A^T A) for a regression Both of these are more work and less accurate (and likely less stable) than the alternatives that solve the same problem directly. Whenever you see some math showing a matrix inversion, ...
You can use the official C bindings for LAPACK, and then build your C++ wrapper around that. That avoids the issue of having to worry about the Fortran calling conventions, and the C bindings are a bit friendlier for C/C++ programmers than calling the Fortran routines directly. Additionally, you could use one of the C++ matrix libraries that are already ...
If liscencing is not a problem, you might try the gnu scientific library http://www.gnu.org/software/gsl/ It comes with a blas library that you can swap for an optimised library if you need to later (for example the intel, ATLAS, or ACML (AMD chip) library.
One way to calculate the determinant is using the LU decomposition: LaVectorLongInt pivots(A.cols()); LUFactorizeIP(A, pivots); double detA = 1; for (int i = 0; i < A.cols(); ++i) detA *= A(i, i); Warning, A will change, so making a copy is probably advised.
High level interface and low level optimizations are two different things. LAPACK and uBLAS provide high level interface and un-optimized low level implementation. Hardware optimized low level routines (or bindings) should come from somewhere else. Once bindings are provided, LAPACK and uBLAS can use optimized low level routines instead of their own ...
I suspect this routine does a deep-copy of the data: http://lapackpp.sourceforge.net/html/classLaVectorDouble.html#be11700fe7c277501329b2d23f485630 This ref() routine might let you maintain the shared memory: http://lapackpp.sourceforge.net/html/classLaVectorDouble.html#191850a7e8993a977a3a545b87dc7528
Linking goes fine because you tell to the linker where the library is, but execution failed because the loader doesn't know anything about the location of your libraries (you can check that performing ldd yourapp, which shows the library needed by your application). Usually, you can solve that by telling to the loader where the library is through the ...
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