But the functions provided there is limited to the matrix and vector arithmetic, so to do inversion, decompositions etc. we still need to use another library. I am now using the latest dnAnalytics, which is merging into Math.Net project. But Math.Net project has no updates to the public for more than a whole year now, I don't know if they have a plan to continue.
I did the following wrapper, this wrapper uses Matlab-like functions to do simple linear algebra. As I am new to F# and FP, would you please give some advices to improve the wrapper and code? Thanks!
#r @"D:\WORK\tools\dnAnalytics_windows_x86\bin\dnAnalytics.dll" #r @"FSharp.PowerPack.dll" open dnAnalytics.LinearAlgebra open Microsoft.FSharp.Math open dnAnalytics.LinearAlgebra.Decomposition // F# matrix -> ndAnalytics DenseMatrix let mat2dnmat (mat:matrix) = let m = new DenseMatrix(mat.ToArray2D()) m // ndAnalytics DenseMatrix -> F# matrix let dnmat2mat (dnmat:DenseMatrix) = let n = dnmat.Rows let m = dnmat.Columns let mat = Matrix.create n m 0. for i=0 to n-1 do for j=0 to m-1 do mat.[i,j] <- dnmat.Item(i,j) mat // random matrix let randmat n m = let r = new System.Random() let ranlist m = [ for i in 1..m do yield r.NextDouble() ] matrix ([1..n] |> List.map (fun x-> ranlist m)) // is square matrix let issqr (m:matrix) = let n, m = m.Dimensions n = m // is postive definite let ispd m = if not (issqr m) then false else let m1 = mat2dnmat m let qrsolver = dnAnalytics.LinearAlgebra.Decomposition.Cholesky(m1) qrsolver.IsPositiveDefinite() // determinant let det m = let m1 = mat2dnmat m let lusolver = dnAnalytics.LinearAlgebra.Decomposition.LU(m1) lusolver.Determinant () // is full rank let isfull m = let m1 = mat2dnmat m let qrsolver = dnAnalytics.LinearAlgebra.Decomposition.GramSchmidt(m1) qrsolver.IsFullRank() // rank let rank m = let m1 = mat2dnmat m let svdsolver = dnAnalytics.LinearAlgebra.Decomposition.Svd(m1, false) svdsolver.Rank() // inversion by lu let inv m = let m1 = mat2dnmat m let lusolver = dnAnalytics.LinearAlgebra.Decomposition.LU(m1) lusolver.Inverse() // lu let lu m = let m1 = mat2dnmat m let lusolver = dnAnalytics.LinearAlgebra.Decomposition.LU(m1) let l = dnmat2mat (DenseMatrix (lusolver.LowerFactor ())) let u = dnmat2mat (DenseMatrix (lusolver.UpperFactor ())) (l,u) // qr let qr m = let m1 = mat2dnmat m let qrsolver = dnAnalytics.LinearAlgebra.Decomposition.GramSchmidt(m1) let q = dnmat2mat (DenseMatrix (qrsolver.Q())) let r = dnmat2mat (DenseMatrix (qrsolver.R())) (q, r) // svd let svd m = let m1 = mat2dnmat m let svdsolver = dnAnalytics.LinearAlgebra.Decomposition.Svd(m1, true) let u = dnmat2mat (DenseMatrix (svdsolver.U())) let w = dnmat2mat (DenseMatrix (svdsolver.W())) let vt = dnmat2mat (DenseMatrix (svdsolver.VT())) (u, w, vt.Transpose)
and test code
(* todo: read matrix market format ref: http://math.nist.gov/MatrixMarket/formats.html *) let readmat (filename:string) = System.IO.File.ReadAllLines(filename) |> Array.map (fun x-> (x |> String.split [' '] |> List.toArray |> Array.map float)) |> matrix let timeit f str= let watch = new System.Diagnostics.Stopwatch() watch.Start() let res = f() watch.Stop() printfn "%s Needed %f ms" str watch.Elapsed.TotalMilliseconds res let test() = let testlu() = for i=1 to 10 do let a,b = lu (randmat 1000 1000) () () let testsvd() = for i=1 to 10 do let u,w,v = svd (randmat 300 300) () () let testdet() = for i=1 to 10 do let d = det (randmat 650 650) () () timeit testlu "lu" timeit testsvd "svd" timeit testdet "det"
I also compared with matlab
t = cputime; for i=1:10, [l,u] = lu(rand(1000,1000)); end; e = cputime-t t = cputime; for i=1:10, [u,w,vt] = svd(rand(300,300)); end; e = cputime-t t = cputime; for i=1:10, d = det(rand(650,650)); end; e = cputime-t
The timings (Duo Core 2.0GH, 2GB memory, Matlab 2009a)
f#: lu Needed 8875.941700 ms svd Needed 14469.102900 ms det Needed 2820.304600 ms matlab: lu 3.7752 svd 5.7408 det 1.2636