{-# LANGUAGE CPP #-} {-# LANGUAGE FlexibleContexts #-} {-# OPTIONS_GHC -fno-warn-missing-signatures #-} ----------------------------------------------------------------------------- {- | Module : Numeric.LinearAlgebra Copyright : (c) Alberto Ruiz 2006-15 License : BSD3 Maintainer : Alberto Ruiz Stability : provisional -} ----------------------------------------------------------------------------- module Numeric.LinearAlgebra ( -- * Basic types and data manipulation -- | This package works with 2D ('Matrix') and 1D ('Vector') -- arrays of real ('R') or complex ('C') double precision numbers. -- Single precision and machine integers are also supported for -- basic arithmetic and data manipulation. module Numeric.LinearAlgebra.Data, -- * Numeric classes -- | -- The standard numeric classes are defined elementwise (commonly referred to -- as the Hadamard product or the Schur product): -- -- >>> vector [1,2,3] * vector [3,0,-2] -- [3.0,0.0,-6.0] -- it :: Vector R -- -- >>> matrix 3 [1..9] * ident 3 -- (3><3) -- [ 1.0, 0.0, 0.0 -- , 0.0, 5.0, 0.0 -- , 0.0, 0.0, 9.0 ] -- * Autoconformable dimensions -- | -- In most operations, single-element vectors and matrices -- (created from numeric literals or using 'scalar'), and matrices -- with just one row or column, automatically -- expand to match the dimensions of the other operand: -- -- >>> 5 + 2*ident 3 :: Matrix Double -- (3><3) -- [ 7.0, 5.0, 5.0 -- , 5.0, 7.0, 5.0 -- , 5.0, 5.0, 7.0 ] -- -- >>> (4><3) [1..] + row [10,20,30] -- (4><3) -- [ 11.0, 22.0, 33.0 -- , 14.0, 25.0, 36.0 -- , 17.0, 28.0, 39.0 -- , 20.0, 31.0, 42.0 ] -- -- * Products -- ** Dot dot, (<.>), -- ** Matrix-vector (#>), (<#), (!#>), -- ** Matrix-matrix (<>), -- | The matrix product is also implemented in the "Data.Monoid" instance, where -- single-element matrices (created from numeric literals or using 'scalar') -- are used for scaling. -- -- >>> import Data.Monoid as M -- >>> let m = matrix 3 [1..6] -- >>> m M.<> 2 M.<> diagl[0.5,1,0] -- (2><3) -- [ 1.0, 4.0, 0.0 -- , 4.0, 10.0, 0.0 ] -- -- 'mconcat' uses 'optimiseMult' to get the optimal association order. -- ** Other outer, kronecker, cross, scale, add, sumElements, prodElements, -- * Linear systems -- ** General (<\>), linearSolveLS, linearSolveSVD, -- ** Determined linearSolve, luSolve, luPacked, luSolve', luPacked', -- ** Symmetric indefinite ldlSolve, ldlPacked, -- ** Positive definite cholSolve, -- ** Triangular UpLo(..), triSolve, -- ** Tridiagonal triDiagSolve, -- ** Sparse cgSolve, cgSolve', -- * Inverse and pseudoinverse inv, pinv, pinvTol, -- * Determinant and rank rcond, rank, det, invlndet, -- * Norms Normed(..), norm_Frob, norm_nuclear, -- * Nullspace and range orth, nullspace, null1, null1sym, -- * Singular value decomposition svd, thinSVD, compactSVD, compactSVDTol, singularValues, leftSV, rightSV, -- * Eigendecomposition eig, geig, eigSH, eigenvalues, geigenvalues, eigenvaluesSH, geigSH, -- * QR qr, thinQR, rq, thinRQ, qrRaw, qrgr, -- * Cholesky chol, mbChol, -- * LU lu, luFact, -- * Hessenberg hess, -- * Schur schur, -- * Matrix functions expm, sqrtm, matFunc, -- * Correlation and convolution corr, conv, corrMin, corr2, conv2, -- * Random arrays Seed, RandDist(..), randomVector, rand, randn, gaussianSample, uniformSample, -- * Misc meanCov, rowOuters, pairwiseD2, normalize, peps, relativeError, magnit, haussholder, optimiseMult, udot, nullspaceSVD, orthSVD, ranksv, iC, sym, mTm, trustSym, unSym, -- * Auxiliary classes Container, Product, Numeric, LSDiv, Herm, Complexable, RealElement, RealOf, ComplexOf, SingleOf, DoubleOf, IndexOf, Field, Linear(), Additive(), Transposable, LU(..), LDL(..), QR(..), CGState(..), Testable(..) ) where import Numeric.LinearAlgebra.Data import Numeric.Matrix() import Numeric.Vector() import Internal.Matrix import Internal.Container hiding ((<>)) import Internal.Numeric hiding (mul) import Internal.Algorithms hiding (linearSolve,Normed,orth,luPacked',linearSolve',luSolve',ldlPacked') import qualified Internal.Algorithms as A import Internal.Util import Internal.Random import Internal.Sparse((!#>)) import Internal.CG import Internal.Conversion #if MIN_VERSION_base(4,11,0) import Prelude hiding ((<>)) #endif {- | dense matrix product >>> let a = (3><5) [1..] >>> a (3><5) [ 1.0, 2.0, 3.0, 4.0, 5.0 , 6.0, 7.0, 8.0, 9.0, 10.0 , 11.0, 12.0, 13.0, 14.0, 15.0 ] >>> let b = (5><2) [1,3, 0,2, -1,5, 7,7, 6,0] >>> b (5><2) [ 1.0, 3.0 , 0.0, 2.0 , -1.0, 5.0 , 7.0, 7.0 , 6.0, 0.0 ] >>> a <> b (3><2) [ 56.0, 50.0 , 121.0, 135.0 , 186.0, 220.0 ] -} (<>) :: Numeric t => Matrix t -> Matrix t -> Matrix t (<>) = mXm infixr 8 <> {- | Solve a linear system (for square coefficient matrix and several right-hand sides) using the LU decomposition, returning Nothing for a singular system. For underconstrained or overconstrained systems use 'linearSolveLS' or 'linearSolveSVD'. @ a = (2><2) [ 1.0, 2.0 , 3.0, 5.0 ] @ @ b = (2><3) [ 6.0, 1.0, 10.0 , 15.0, 3.0, 26.0 ] @ >>> linearSolve a b Just (2><3) [ -1.4802973661668753e-15, 0.9999999999999997, 1.999999999999997 , 3.000000000000001, 1.6653345369377348e-16, 4.000000000000002 ] >>> let Just x = it >>> disp 5 x 2x3 -0.00000 1.00000 2.00000 3.00000 0.00000 4.00000 >>> a <> x (2><3) [ 6.0, 1.0, 10.0 , 15.0, 3.0, 26.0 ] -} linearSolve m b = A.mbLinearSolve m b -- | return an orthonormal basis of the null space of a matrix. See also 'nullspaceSVD'. nullspace m = nullspaceSVD (Left (1*eps)) m (rightSV m) -- | return an orthonormal basis of the range space of a matrix. See also 'orthSVD'. orth m = orthSVD (Left (1*eps)) m (leftSV m)