789 lines
23 KiB
Ada
789 lines
23 KiB
Ada
------------------------------------------------------------------------------
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-- --
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-- GNAT RUN-TIME COMPONENTS --
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-- --
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-- ADA.NUMERICS.GENERIC_REAL_ARRAYS --
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-- --
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-- B o d y --
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-- --
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-- Copyright (C) 2006-2009, Free Software Foundation, Inc. --
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-- --
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-- GNAT is free software; you can redistribute it and/or modify it under --
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-- terms of the GNU General Public License as published by the Free Soft- --
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-- ware Foundation; either version 3, or (at your option) any later ver- --
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-- sion. GNAT is distributed in the hope that it will be useful, but WITH- --
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-- OUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY --
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-- or FITNESS FOR A PARTICULAR PURPOSE. --
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-- --
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-- As a special exception under Section 7 of GPL version 3, you are granted --
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-- additional permissions described in the GCC Runtime Library Exception, --
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-- version 3.1, as published by the Free Software Foundation. --
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-- --
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-- You should have received a copy of the GNU General Public License and --
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-- a copy of the GCC Runtime Library Exception along with this program; --
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-- see the files COPYING3 and COPYING.RUNTIME respectively. If not, see --
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-- <http://www.gnu.org/licenses/>. --
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-- --
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-- GNAT was originally developed by the GNAT team at New York University. --
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-- Extensive contributions were provided by Ada Core Technologies Inc. --
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-- --
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------------------------------------------------------------------------------
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with System; use System;
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with System.Generic_Real_BLAS;
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with System.Generic_Real_LAPACK;
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with System.Generic_Array_Operations; use System.Generic_Array_Operations;
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package body Ada.Numerics.Generic_Real_Arrays is
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-- Operations involving inner products use BLAS library implementations.
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-- This allows larger matrices and vectors to be computed efficiently,
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-- taking into account memory hierarchy issues and vector instructions
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-- that vary widely between machines.
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-- Operations that are defined in terms of operations on the type Real,
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-- such as addition, subtraction and scaling, are computed in the canonical
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-- way looping over all elements.
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-- Operations for solving linear systems and computing determinant,
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-- eigenvalues, eigensystem and inverse, are implemented using the
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-- LAPACK library.
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package BLAS is
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new Generic_Real_BLAS (Real'Base, Real_Vector, Real_Matrix);
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package LAPACK is
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new Generic_Real_LAPACK (Real'Base, Real_Vector, Real_Matrix);
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use BLAS, LAPACK;
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-- Procedure versions of functions returning unconstrained values.
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-- This allows for inlining the function wrapper.
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procedure Eigenvalues (A : Real_Matrix; Values : out Real_Vector);
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procedure Inverse (A : Real_Matrix; R : out Real_Matrix);
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procedure Solve (A : Real_Matrix; X : Real_Vector; B : out Real_Vector);
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procedure Solve (A : Real_Matrix; X : Real_Matrix; B : out Real_Matrix);
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procedure Transpose is new
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Generic_Array_Operations.Transpose
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(Scalar => Real'Base,
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Matrix => Real_Matrix);
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-- Helper function that raises a Constraint_Error is the argument is
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-- not a square matrix, and otherwise returns its length.
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function Length is new Square_Matrix_Length (Real'Base, Real_Matrix);
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-- Instantiating the following subprograms directly would lead to
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-- name clashes, so use a local package.
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package Instantiations is
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function "+" is new
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Vector_Elementwise_Operation
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(X_Scalar => Real'Base,
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Result_Scalar => Real'Base,
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X_Vector => Real_Vector,
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Result_Vector => Real_Vector,
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Operation => "+");
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function "+" is new
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Matrix_Elementwise_Operation
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(X_Scalar => Real'Base,
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Result_Scalar => Real'Base,
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X_Matrix => Real_Matrix,
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Result_Matrix => Real_Matrix,
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Operation => "+");
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function "+" is new
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Vector_Vector_Elementwise_Operation
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(Left_Scalar => Real'Base,
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Right_Scalar => Real'Base,
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Result_Scalar => Real'Base,
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Left_Vector => Real_Vector,
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Right_Vector => Real_Vector,
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Result_Vector => Real_Vector,
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Operation => "+");
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function "+" is new
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Matrix_Matrix_Elementwise_Operation
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(Left_Scalar => Real'Base,
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Right_Scalar => Real'Base,
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Result_Scalar => Real'Base,
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Left_Matrix => Real_Matrix,
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Right_Matrix => Real_Matrix,
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Result_Matrix => Real_Matrix,
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Operation => "+");
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function "-" is new
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Vector_Elementwise_Operation
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(X_Scalar => Real'Base,
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Result_Scalar => Real'Base,
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X_Vector => Real_Vector,
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Result_Vector => Real_Vector,
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Operation => "-");
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function "-" is new
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Matrix_Elementwise_Operation
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(X_Scalar => Real'Base,
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Result_Scalar => Real'Base,
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X_Matrix => Real_Matrix,
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Result_Matrix => Real_Matrix,
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Operation => "-");
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function "-" is new
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Vector_Vector_Elementwise_Operation
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(Left_Scalar => Real'Base,
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Right_Scalar => Real'Base,
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Result_Scalar => Real'Base,
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Left_Vector => Real_Vector,
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Right_Vector => Real_Vector,
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Result_Vector => Real_Vector,
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Operation => "-");
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function "-" is new
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Matrix_Matrix_Elementwise_Operation
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(Left_Scalar => Real'Base,
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Right_Scalar => Real'Base,
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Result_Scalar => Real'Base,
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Left_Matrix => Real_Matrix,
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Right_Matrix => Real_Matrix,
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Result_Matrix => Real_Matrix,
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Operation => "-");
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function "*" is new
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Scalar_Vector_Elementwise_Operation
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(Left_Scalar => Real'Base,
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Right_Scalar => Real'Base,
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Result_Scalar => Real'Base,
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Right_Vector => Real_Vector,
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Result_Vector => Real_Vector,
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Operation => "*");
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function "*" is new
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Scalar_Matrix_Elementwise_Operation
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(Left_Scalar => Real'Base,
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Right_Scalar => Real'Base,
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Result_Scalar => Real'Base,
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Right_Matrix => Real_Matrix,
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Result_Matrix => Real_Matrix,
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Operation => "*");
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function "*" is new
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Vector_Scalar_Elementwise_Operation
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(Left_Scalar => Real'Base,
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Right_Scalar => Real'Base,
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Result_Scalar => Real'Base,
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Left_Vector => Real_Vector,
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Result_Vector => Real_Vector,
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Operation => "*");
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function "*" is new
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Matrix_Scalar_Elementwise_Operation
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(Left_Scalar => Real'Base,
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Right_Scalar => Real'Base,
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Result_Scalar => Real'Base,
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Left_Matrix => Real_Matrix,
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Result_Matrix => Real_Matrix,
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Operation => "*");
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function "*" is new
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Outer_Product
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(Left_Scalar => Real'Base,
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Right_Scalar => Real'Base,
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Result_Scalar => Real'Base,
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Left_Vector => Real_Vector,
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Right_Vector => Real_Vector,
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Matrix => Real_Matrix);
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function "/" is new
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Vector_Scalar_Elementwise_Operation
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(Left_Scalar => Real'Base,
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Right_Scalar => Real'Base,
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Result_Scalar => Real'Base,
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Left_Vector => Real_Vector,
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Result_Vector => Real_Vector,
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Operation => "/");
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function "/" is new
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Matrix_Scalar_Elementwise_Operation
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(Left_Scalar => Real'Base,
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Right_Scalar => Real'Base,
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Result_Scalar => Real'Base,
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Left_Matrix => Real_Matrix,
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Result_Matrix => Real_Matrix,
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Operation => "/");
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function "abs" is new
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Vector_Elementwise_Operation
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(X_Scalar => Real'Base,
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Result_Scalar => Real'Base,
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X_Vector => Real_Vector,
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Result_Vector => Real_Vector,
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Operation => "abs");
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function "abs" is new
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Matrix_Elementwise_Operation
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(X_Scalar => Real'Base,
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Result_Scalar => Real'Base,
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X_Matrix => Real_Matrix,
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Result_Matrix => Real_Matrix,
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Operation => "abs");
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function Unit_Matrix is new
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Generic_Array_Operations.Unit_Matrix
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(Scalar => Real'Base,
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Matrix => Real_Matrix,
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Zero => 0.0,
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One => 1.0);
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function Unit_Vector is new
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Generic_Array_Operations.Unit_Vector
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(Scalar => Real'Base,
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Vector => Real_Vector,
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Zero => 0.0,
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One => 1.0);
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end Instantiations;
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---------
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-- "+" --
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---------
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function "+" (Right : Real_Vector) return Real_Vector
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renames Instantiations."+";
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function "+" (Right : Real_Matrix) return Real_Matrix
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renames Instantiations."+";
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function "+" (Left, Right : Real_Vector) return Real_Vector
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renames Instantiations."+";
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function "+" (Left, Right : Real_Matrix) return Real_Matrix
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renames Instantiations."+";
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---------
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-- "-" --
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---------
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function "-" (Right : Real_Vector) return Real_Vector
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renames Instantiations."-";
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function "-" (Right : Real_Matrix) return Real_Matrix
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renames Instantiations."-";
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function "-" (Left, Right : Real_Vector) return Real_Vector
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renames Instantiations."-";
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function "-" (Left, Right : Real_Matrix) return Real_Matrix
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renames Instantiations."-";
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---------
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-- "*" --
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---------
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-- Scalar multiplication
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function "*" (Left : Real'Base; Right : Real_Vector) return Real_Vector
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renames Instantiations."*";
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function "*" (Left : Real_Vector; Right : Real'Base) return Real_Vector
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renames Instantiations."*";
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function "*" (Left : Real'Base; Right : Real_Matrix) return Real_Matrix
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renames Instantiations."*";
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function "*" (Left : Real_Matrix; Right : Real'Base) return Real_Matrix
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renames Instantiations."*";
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-- Vector multiplication
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function "*" (Left, Right : Real_Vector) return Real'Base is
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begin
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if Left'Length /= Right'Length then
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raise Constraint_Error with
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"vectors are of different length in inner product";
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end if;
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return dot (Left'Length, X => Left, Y => Right);
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end "*";
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function "*" (Left, Right : Real_Vector) return Real_Matrix
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renames Instantiations."*";
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function "*"
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(Left : Real_Vector;
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Right : Real_Matrix) return Real_Vector
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is
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R : Real_Vector (Right'Range (2));
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begin
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if Left'Length /= Right'Length (1) then
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raise Constraint_Error with
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"incompatible dimensions in vector-matrix multiplication";
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end if;
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gemv (Trans => No_Trans'Access,
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M => Right'Length (2),
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N => Right'Length (1),
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A => Right,
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Ld_A => Right'Length (2),
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X => Left,
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Y => R);
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return R;
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end "*";
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function "*"
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(Left : Real_Matrix;
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Right : Real_Vector) return Real_Vector
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is
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R : Real_Vector (Left'Range (1));
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begin
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if Left'Length (2) /= Right'Length then
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raise Constraint_Error with
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"incompatible dimensions in matrix-vector multiplication";
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end if;
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gemv (Trans => Trans'Access,
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M => Left'Length (2),
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N => Left'Length (1),
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A => Left,
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Ld_A => Left'Length (2),
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X => Right,
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Y => R);
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return R;
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end "*";
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-- Matrix Multiplication
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function "*" (Left, Right : Real_Matrix) return Real_Matrix is
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R : Real_Matrix (Left'Range (1), Right'Range (2));
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begin
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if Left'Length (2) /= Right'Length (1) then
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raise Constraint_Error with
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"incompatible dimensions in matrix-matrix multiplication";
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end if;
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gemm (Trans_A => No_Trans'Access,
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Trans_B => No_Trans'Access,
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M => Right'Length (2),
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N => Left'Length (1),
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K => Right'Length (1),
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A => Right,
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Ld_A => Right'Length (2),
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B => Left,
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Ld_B => Left'Length (2),
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C => R,
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Ld_C => R'Length (2));
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return R;
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end "*";
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---------
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-- "/" --
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---------
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function "/" (Left : Real_Vector; Right : Real'Base) return Real_Vector
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renames Instantiations."/";
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function "/" (Left : Real_Matrix; Right : Real'Base) return Real_Matrix
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renames Instantiations."/";
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-----------
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-- "abs" --
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-----------
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function "abs" (Right : Real_Vector) return Real'Base is
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begin
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return nrm2 (Right'Length, Right);
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end "abs";
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function "abs" (Right : Real_Vector) return Real_Vector
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renames Instantiations."abs";
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function "abs" (Right : Real_Matrix) return Real_Matrix
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renames Instantiations."abs";
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-----------------
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-- Determinant --
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-----------------
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function Determinant (A : Real_Matrix) return Real'Base is
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N : constant Integer := Length (A);
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LU : Real_Matrix (1 .. N, 1 .. N) := A;
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Piv : Integer_Vector (1 .. N);
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Info : aliased Integer := -1;
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Det : Real := 1.0;
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begin
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getrf (M => N,
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N => N,
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A => LU,
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Ld_A => N,
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I_Piv => Piv,
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Info => Info'Access);
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if Info /= 0 then
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raise Constraint_Error with "ill-conditioned matrix";
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end if;
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for J in 1 .. N loop
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if Piv (J) /= J then
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Det := -Det * LU (J, J);
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else
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Det := Det * LU (J, J);
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end if;
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end loop;
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return Det;
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end Determinant;
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-----------------
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-- Eigensystem --
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-----------------
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procedure Eigensystem
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(A : Real_Matrix;
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Values : out Real_Vector;
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Vectors : out Real_Matrix)
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is
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N : constant Natural := Length (A);
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Tau : Real_Vector (1 .. N);
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L_Work : Real_Vector (1 .. 1);
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Info : aliased Integer;
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E : Real_Vector (1 .. N);
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pragma Warnings (Off, E);
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begin
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if Values'Length /= N then
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raise Constraint_Error with "wrong length for output vector";
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end if;
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if N = 0 then
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return;
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end if;
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-- Initialize working matrix and check for symmetric input matrix
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Transpose (A, Vectors);
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if A /= Vectors then
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raise Argument_Error with "matrix not symmetric";
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end if;
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-- Compute size of additional working space
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sytrd (Uplo => Lower'Access,
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N => N,
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A => Vectors,
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Ld_A => N,
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D => Values,
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E => E,
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Tau => Tau,
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Work => L_Work,
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L_Work => -1,
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Info => Info'Access);
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declare
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Work : Real_Vector (1 .. Integer'Max (Integer (L_Work (1)), 2 * N));
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pragma Warnings (Off, Work);
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Comp_Z : aliased constant Character := 'V';
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begin
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-- Reduce matrix to tridiagonal form
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sytrd (Uplo => Lower'Access,
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N => N,
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A => Vectors,
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Ld_A => A'Length (1),
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D => Values,
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E => E,
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Tau => Tau,
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Work => Work,
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L_Work => Work'Length,
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Info => Info'Access);
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if Info /= 0 then
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raise Program_Error;
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end if;
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-- Generate the real orthogonal matrix determined by sytrd
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orgtr (Uplo => Lower'Access,
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N => N,
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A => Vectors,
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Ld_A => N,
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Tau => Tau,
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Work => Work,
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L_Work => Work'Length,
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Info => Info'Access);
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if Info /= 0 then
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raise Program_Error;
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end if;
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-- Compute all eigenvalues and eigenvectors using QR algorithm
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steqr (Comp_Z => Comp_Z'Access,
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N => N,
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D => Values,
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E => E,
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Z => Vectors,
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Ld_Z => N,
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Work => Work,
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Info => Info'Access);
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if Info /= 0 then
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raise Constraint_Error with
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"eigensystem computation failed to converge";
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end if;
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end;
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end Eigensystem;
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|
|
-----------------
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-- Eigenvalues --
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-----------------
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procedure Eigenvalues
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(A : Real_Matrix;
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Values : out Real_Vector)
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|
is
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N : constant Natural := Length (A);
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L_Work : Real_Vector (1 .. 1);
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Info : aliased Integer;
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B : Real_Matrix (1 .. N, 1 .. N);
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Tau : Real_Vector (1 .. N);
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E : Real_Vector (1 .. N);
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pragma Warnings (Off, B);
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pragma Warnings (Off, Tau);
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pragma Warnings (Off, E);
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begin
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if Values'Length /= N then
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raise Constraint_Error with "wrong length for output vector";
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end if;
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if N = 0 then
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return;
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end if;
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|
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-- Initialize working matrix and check for symmetric input matrix
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Transpose (A, B);
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if A /= B then
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raise Argument_Error with "matrix not symmetric";
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end if;
|
|
|
|
-- Find size of work area
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sytrd (Uplo => Lower'Access,
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N => N,
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A => B,
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Ld_A => N,
|
|
D => Values,
|
|
E => E,
|
|
Tau => Tau,
|
|
Work => L_Work,
|
|
L_Work => -1,
|
|
Info => Info'Access);
|
|
|
|
declare
|
|
Work : Real_Vector (1 .. Integer'Min (Integer (L_Work (1)), 4 * N));
|
|
pragma Warnings (Off, Work);
|
|
|
|
begin
|
|
-- Reduce matrix to tridiagonal form
|
|
|
|
sytrd (Uplo => Lower'Access,
|
|
N => N,
|
|
A => B,
|
|
Ld_A => A'Length (1),
|
|
D => Values,
|
|
E => E,
|
|
Tau => Tau,
|
|
Work => Work,
|
|
L_Work => Work'Length,
|
|
Info => Info'Access);
|
|
|
|
if Info /= 0 then
|
|
raise Constraint_Error;
|
|
end if;
|
|
|
|
-- Compute all eigenvalues using QR algorithm
|
|
|
|
sterf (N => N,
|
|
D => Values,
|
|
E => E,
|
|
Info => Info'Access);
|
|
|
|
if Info /= 0 then
|
|
raise Constraint_Error with
|
|
"eigenvalues computation failed to converge";
|
|
end if;
|
|
end;
|
|
end Eigenvalues;
|
|
|
|
function Eigenvalues (A : Real_Matrix) return Real_Vector is
|
|
R : Real_Vector (A'Range (1));
|
|
begin
|
|
Eigenvalues (A, R);
|
|
return R;
|
|
end Eigenvalues;
|
|
|
|
-------------
|
|
-- Inverse --
|
|
-------------
|
|
|
|
procedure Inverse (A : Real_Matrix; R : out Real_Matrix) is
|
|
N : constant Integer := Length (A);
|
|
Piv : Integer_Vector (1 .. N);
|
|
L_Work : Real_Vector (1 .. 1);
|
|
Info : aliased Integer := -1;
|
|
|
|
begin
|
|
-- All computations are done using column-major order, but this works
|
|
-- out fine, because Transpose (Inverse (Transpose (A))) = Inverse (A).
|
|
|
|
R := A;
|
|
|
|
-- Compute LU decomposition
|
|
|
|
getrf (M => N,
|
|
N => N,
|
|
A => R,
|
|
Ld_A => N,
|
|
I_Piv => Piv,
|
|
Info => Info'Access);
|
|
|
|
if Info /= 0 then
|
|
raise Constraint_Error with "inverting singular matrix";
|
|
end if;
|
|
|
|
-- Determine size of work area
|
|
|
|
getri (N => N,
|
|
A => R,
|
|
Ld_A => N,
|
|
I_Piv => Piv,
|
|
Work => L_Work,
|
|
L_Work => -1,
|
|
Info => Info'Access);
|
|
|
|
if Info /= 0 then
|
|
raise Constraint_Error;
|
|
end if;
|
|
|
|
declare
|
|
Work : Real_Vector (1 .. Integer (L_Work (1)));
|
|
pragma Warnings (Off, Work);
|
|
|
|
begin
|
|
-- Compute inverse from LU decomposition
|
|
|
|
getri (N => N,
|
|
A => R,
|
|
Ld_A => N,
|
|
I_Piv => Piv,
|
|
Work => Work,
|
|
L_Work => Work'Length,
|
|
Info => Info'Access);
|
|
|
|
if Info /= 0 then
|
|
raise Constraint_Error with "inverting singular matrix";
|
|
end if;
|
|
|
|
-- ??? Should iterate with gerfs, based on implementation advice
|
|
end;
|
|
end Inverse;
|
|
|
|
function Inverse (A : Real_Matrix) return Real_Matrix is
|
|
R : Real_Matrix (A'Range (2), A'Range (1));
|
|
begin
|
|
Inverse (A, R);
|
|
return R;
|
|
end Inverse;
|
|
|
|
-----------
|
|
-- Solve --
|
|
-----------
|
|
|
|
procedure Solve (A : Real_Matrix; X : Real_Vector; B : out Real_Vector) is
|
|
begin
|
|
if Length (A) /= X'Length then
|
|
raise Constraint_Error with
|
|
"incompatible matrix and vector dimensions";
|
|
end if;
|
|
|
|
-- ??? Should solve directly, is faster and more accurate
|
|
|
|
B := Inverse (A) * X;
|
|
end Solve;
|
|
|
|
procedure Solve (A : Real_Matrix; X : Real_Matrix; B : out Real_Matrix) is
|
|
begin
|
|
if Length (A) /= X'Length (1) then
|
|
raise Constraint_Error with "incompatible matrix dimensions";
|
|
end if;
|
|
|
|
-- ??? Should solve directly, is faster and more accurate
|
|
|
|
B := Inverse (A) * X;
|
|
end Solve;
|
|
|
|
function Solve (A : Real_Matrix; X : Real_Vector) return Real_Vector is
|
|
B : Real_Vector (A'Range (2));
|
|
begin
|
|
Solve (A, X, B);
|
|
return B;
|
|
end Solve;
|
|
|
|
function Solve (A, X : Real_Matrix) return Real_Matrix is
|
|
B : Real_Matrix (A'Range (2), X'Range (2));
|
|
begin
|
|
Solve (A, X, B);
|
|
return B;
|
|
end Solve;
|
|
|
|
---------------
|
|
-- Transpose --
|
|
---------------
|
|
|
|
function Transpose (X : Real_Matrix) return Real_Matrix is
|
|
R : Real_Matrix (X'Range (2), X'Range (1));
|
|
begin
|
|
Transpose (X, R);
|
|
|
|
return R;
|
|
end Transpose;
|
|
|
|
-----------------
|
|
-- Unit_Matrix --
|
|
-----------------
|
|
|
|
function Unit_Matrix
|
|
(Order : Positive;
|
|
First_1 : Integer := 1;
|
|
First_2 : Integer := 1) return Real_Matrix
|
|
renames Instantiations.Unit_Matrix;
|
|
|
|
-----------------
|
|
-- Unit_Vector --
|
|
-----------------
|
|
|
|
function Unit_Vector
|
|
(Index : Integer;
|
|
Order : Positive;
|
|
First : Integer := 1) return Real_Vector
|
|
renames Instantiations.Unit_Vector;
|
|
|
|
end Ada.Numerics.Generic_Real_Arrays;
|