amd2.m
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function [p, Info] = amd2 (A, Control) %#ok
%AMD2 p = amd2 (A), the approximate minimum degree ordering of A
% P = AMD2 (S) returns the approximate minimum degree permutation vector for
% the sparse matrix C = S+S'. The Cholesky factorization of C (P,P), or
% S (P,P), tends to be sparser than that of C or S. AMD tends to be faster
% than SYMMMD and SYMAMD, and tends to return better orderings than SYMMMD.
% S must be square. If S is full, amd(S) is equivalent to amd(sparse(S)).
%
% Note that the built-in AMD routine in MATLAB is identical to AMD2,
% except that AMD in MATLAB allows for a struct input to set the parameters.
%
% Usage: P = amd2 (S) ; % finds the ordering
% [P, Info] = amd2 (S, Control) ; % optional parameters & statistics
% Control = amd2 ; % returns default parameters
% amd2 ; % prints default parameters.
%
% Control (1); If S is n-by-n, then rows/columns with more than
% max (16, (Control (1))* sqrt(n)) entries in S+S' are considered
% "dense", and ignored during ordering. They are placed last in the
% output permutation. The default is 10.0 if Control is not present.
% Control (2): If nonzero, then aggressive absorption is performed.
% This is the default if Control is not present.
% Control (3): If nonzero, print statistics about the ordering.
%
% Info (1): status (0: ok, -1: out of memory, -2: matrix invalid)
% Info (2): n = size (A,1)
% Info (3): nnz (A)
% Info (4): the symmetry of the matrix S (0.0 means purely unsymmetric,
% 1.0 means purely symmetric). Computed as:
% B = tril (S, -1) + triu (S, 1) ; symmetry = nnz (B & B') / nnz (B);
% Info (5): nnz (diag (S))
% Info (6): nnz in S+S', excluding the diagonal (= nnz (B+B'))
% Info (7): number "dense" rows/columns in S+S'
% Info (8): the amount of memory used by AMD, in bytes
% Info (9): the number of memory compactions performed by AMD
%
% The following statistics are slight upper bounds because of the
% approximate degree in AMD. The bounds are looser if "dense" rows/columns
% are ignored during ordering (Info (7) > 0). The statistics are for a
% subsequent factorization of the matrix C (P,P). The LU factorization
% statistics assume no pivoting.
%
% Info (10): the number of nonzeros in L, excluding the diagonal
% Info (11): the number of divide operations for LL', LDL', or LU
% Info (12): the number of multiply-subtract pairs for LL' or LDL'
% Info (13): the number of multiply-subtract pairs for LU
% Info (14): the max # of nonzeros in any column of L (incl. diagonal)
% Info (15:20): unused, reserved for future use
%
% An assembly tree post-ordering is performed, which is typically the same
% as an elimination tree post-ordering. It is not always identical because
% of the approximate degree update used, and because "dense" rows/columns
% do not take part in the post-order. It well-suited for a subsequent
% "chol", however. If you require a precise elimination tree post-ordering,
% then see the example below:
%
% Example:
%
% P = amd2 (S) ;
% C = spones (S) + spones (S') ; % skip this if S already symmetric
% [ignore, Q] = etree (C (P,P)) ;
% P = P (Q) ;
%
% See also AMD, COLMMD, COLAMD, COLPERM, SYMAMD, SYMMMD, SYMRCM.
% --------------------------------------------------------------------------
% Copyright 1994-2007, Tim Davis, University of Florida
% Patrick R. Amestoy, and Iain S. Duff. See ../README.txt for License.
% email: davis at cise.ufl.edu CISE Department, Univ. of Florida.
% web: http://www.cise.ufl.edu/research/sparse/amd
% --------------------------------------------------------------------------
%
% Acknowledgements: This work was supported by the National Science
% Foundation, under grants ASC-9111263, DMS-9223088, and CCR-0203270.
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