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srskelf_hybrid.m
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srskelf_hybrid.m
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function F = srskelf_hybrid(A,x,occ,rank_or_tol,pxyfun,opts)
% SRSKELF_HYBRID Strong recursive skeletonization factorization with
% hybrid admissibility (symmetric positive definite only).
%
% F = SRSKELF_HYBRID(A,X,OCC,RANK_OR_TOL,PXYFUN) produces a
% factorization F of the interaction matrix A on the points X using tree
% occupancy parameter OCC, local precision parameter RANK_OR_TOL, and
% proxy function PXYFUN to capture the far field. This is a function of
% the form
%
% [KPXY,NBR] = PXYFUN(X,SLF,NBR,L,CTR)
%
% that is called for every block, where
%
% - KPXY: interaction matrix against artificial proxy points
% - NBR: block neighbor indices (can be modified)
% - X: input points
% - SLF: block indices
% - L: block size
% - CTR: block center
%
% See the examples for further details.
%
% F = SRSKELF_HYBRID(A,X,OCC,RANK_OR_TOL,PXYFUN,OPTS) also passes
% various options to the algorithm. Valid options include:
%
% - EXT: set the root node extent to [EXT(I,1) EXT(I,2)] along
% dimension I. If EXT is empty (default), then the root extent
% is calculated from the data.
%
% - LVLMAX: maximum tree depth (default: LVLMAX = Inf).
%
% - VERB: display status of the code if VERB = 1 (default: VERB = 0).
start = tic;
% Set sane default parameters
if nargin < 5
pxyfun = [];
end % if
if nargin < 6
opts = [];
end % if
if ~isfield(opts,'ext')
opts.ext = [];
end % if
if ~isfield(opts,'lvlmax')
opts.lvlmax = Inf;
end % if
if ~isfield(opts,'verb')
opts.verb = 0;
end % if
if opts.verb
disp(['This is symmetric positive definite srskelf with hybrid', ...
' admissibility (RS-WS).']);
disp('Diagonal blocks will be factorized with Cholesky.');
end % if
% Build tree to hold the discretization points
N = size(x,2);
tic
t = shypoct(x,occ,opts.lvlmax,opts.ext);
if opts.verb
fprintf(['-'*ones(1,80) '\n'])
fprintf('%5s | %6s | %8s | %8s | %8s | %8s | %10s (s)\n', ...
'lvl','nblk','nRemIn','nRemOut','inRatio','outRatio','time')
% Print summary information about tree construction
fprintf(['-'*ones(1,80) '\n'])
fprintf(' %3s | %63.2e (s)\n','-',toc)
% Count the nonempty boxes at each level
pblk = zeros(t.nlvl+1,1);
for lvl = 1:t.nlvl
pblk(lvl+1) = pblk(lvl);
for i = t.lvp(lvl)+1:t.lvp(lvl+1)
if ~isempty(t.nodes(i).xi)
pblk(lvl+1) = pblk(lvl+1) + 1;
end % if
end % for
end % for
end % if
% Initialize the data structure holding the factorization
nbox = t.lvp(end);
e = cell(nbox,1);
% Each element of F.factors will contain the following data for one box:
% - sk: the skeleton DOF indices
% - rd: the redundant DOF indices
% - nbr: the neighbor (near-field) DOF indices
% - T: the interpolation matrix mapping redundant to skeleton
% - E: the left factor of the (symmmetric) Schur complement update to
% sk
% - L: the Cholesky factor of the diagonal block
% - C: the left factor of the (symmetric) Schur complement update to
% nbr
F = struct('sk',e,'rd',e,'nbr',e,'T',e,'E',e,'L',e,'C',e);
F = struct('N',N,'nlvl',t.nlvl,'lvp',zeros(1,t.nlvl+1),'factors',F);
nlvl = 0;
n = 0;
% Mark every DOF as "remaining", i.e., not yet eliminated.
rem = true(N,1);
lookup_list = zeros(nbox,2);
% Loop over the levels of the tree from bottom to top
for lvl = t.nlvl:-1:1
% For each box, pull up information about skeletons from child boxes
for i = t.lvp(lvl)+1:t.lvp(lvl+1)
t.nodes(i).xi = [t.nodes(i).xi [t.nodes(t.nodes(i).chld).xi]];
end % for
% We factorize both half-integer levels for every level lower than 2
% except the first level otherwise we just have weak skeletonization
if lvl <= 2
ub = 1;
else
ub = 2;
end % if
if lvl == t.nlvl
lb = 2;
else
lb = 1;
end % if
% Loop over half-integer levels
for pass = lb:ub
time = tic;
nlvl = nlvl + 1;
nrem1 = sum(rem);
% Loop over each box in this level
for i = t.lvp(lvl)+1:t.lvp(lvl+1)
slf = t.nodes(i).xi;
nbr = [t.nodes(t.nodes(i).nbor).xi];
nslf = length(slf);
% Sorting not necessary, but makes debugging easier
slf = sort(slf);
nnbr = length(nbr);
% Sorting not necessary, but makes debugging easier
nbr = sort(nbr);
if pass == 1
lst = nbr;
nbr = [];
nnbr = 0;
l = t.lrt/2^(lvl - 1);
else
lst = [t.nodes(t.nodes(i).ilist).xi];
l = t.lrt/2^(lvl - 1) * 5/3;
end % if
% Compute proxy interactions and subselect neighbors
Kpxy = zeros(0,nslf);
if lvl > 2
[Kpxy,lst] = pxyfun(x,slf,lst,l,t.nodes(i).ctr);
end % if
nlst = length(lst);
% Sorting not necessary, but makes debugging easier
lst = sort(lst);
% Compute interaction matrix between box and far-field (pass==2) or
% near-field (pass==1).
K1 = full(A(lst,slf));
K2 = spget('lst','slf');
K = [K1 + K2; Kpxy];
% Compute the skeleton/redundant points and interpolation matrix
[sk,rd,T] = id(K,rank_or_tol);
% Move on to next box if no compression for this box
if isempty(rd)
continue
end % if
% Otherwise, compute the diagonal and off-diagonal blocks for this
% box
K = full(A(slf,slf)) + spget('slf','slf');
if pass == 2
K2 = full(A(nbr,slf)) + spget('nbr','slf');
K2(:,rd) = K2(:,rd) - K2(:,sk)*T;
else
K2 = [];
end % if
% Skeletonize
K(rd,:) = K(rd,:) - T'*K(sk,:);
K(:,rd) = K(:,rd) - K(:,sk)*T;
% Cholesky factor of diagonal block
L = chol(K(rd,rd),'lower');
% Throw Cholesky onto intermediate factors
E = K(sk,rd)/L';
if pass == 1
C = zeros(0,length(rd));
else
C = K2(:,rd)/L';
end % if
% Store matrix factors for this box
n = n + 1;
F.factors(n).sk = slf(sk);
F.factors(n).rd = slf(rd);
if pass == 2
F.factors(n).nbr = nbr;
else
F.factors(n).nbr = [];
end % if
F.factors(n).T = T;
F.factors(n).E = E;
F.factors(n).L = L;
F.factors(n).C = C;
% Box number i for pass is at index n (more sensible for
% non-uniform case)
lookup_list(i,pass) = n;
t.nodes(i).xi = slf(sk);
rem(slf(rd)) = 0;
end % for
% Keep track of end of level
F.lvp(nlvl+1) = n;
% Print summary for the latest level
if opts.verb
nrem2 = sum(rem);
nblk = pblk(lvl) + t.lvp(lvl+1) - t.lvp(lvl);
fprintf('%3d-%1d | %6d | %8d | %8d | %8.2f | %8.2f | %10.2e (s)\n', ...
lvl,pass,nblk,nrem1,nrem2,nrem1/nblk,nrem2/nblk,toc(time))
end % if
end % for
end % for
% Truncate extra storage, and we are done
F.factors = F.factors(1:n);
if opts.verb
fprintf(['-'*ones(1,80) '\n'])
toc(start)
end % if
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
function A = spget(Ityp,Jtyp)
% A = SPGET(ITYP,JTYP) Sparse matrix access function (native MATLAB is
% slow for large matrices). We grab the accumulated Schur complement
% updates to a block of the matrix from previously-skeletonized
% levels. Index sets ITYP and JTYP can be 'slf', 'nbr', or 'lst'.
% Translate input strings to index sets (and their lengths)
if strcmpi(Ityp,'slf')
I_ = slf;
m_ = nslf;
elseif strcmpi(Ityp,'nbr')
I_ = nbr;
m_ = nnbr;
elseif strcmpi(Ityp,'lst')
I_ = lst;
m_ = nlst;
end % if
if strcmpi(Jtyp,'slf')
J_ = slf;
n_ = nslf;
elseif strcmpi(Jtyp,'nbr')
J_ = nbr;
n_ = nnbr;
elseif strcmpi(Jtyp,'lst')
J_ = lst;
n_ = nlst;
end % if
% Initialize an empty matrix to store updates
A = zeros(m_,n_);
% Find the updates, modifying update_list in the function call
update_list = false(nbox,1);
get_update_list(i);
% Translate boxes (indexed relative to tree) to factors (indexed
% relative to factorization)
update_list = lookup_list(flip(find(update_list)'),:);
update_list = update_list(update_list ~=0);
update_list = update_list(:);
for jj = update_list'
g = F.factors(jj);
xj = [g.sk, g.nbr];
f = length(g.sk);
if strcmpi(Ityp,Jtyp)
% If this is a diagonal block, then it is symmetric and has same
% factors on each side
idxI = ismembc2(xj,I_);
tmp1 = idxI~=0;
subI = idxI(tmp1);
idxI1 = tmp1(1:f);
idxI2 = tmp1(f+1:end);
tmp1 = [g.E(idxI1,:); g.C(idxI2,:)];
A(subI, subI) = A(subI,subI) - tmp1*tmp1';
else
% Need different row and column factors
idxI = ismembc2(xj,I_);
idxJ = ismembc2(xj,J_);
tmp1 = idxI~=0;
tmp2 = idxJ~=0;
subI = idxI(tmp1);
subJ = idxJ(tmp2);
idxI1 = tmp1(1:f);
idxI2 = tmp1(f+1:end);
idxJ1 = tmp2(1:f);
idxJ2 = tmp2(f+1:end);
tmp1 = [g.E(idxI1,:); g.C(idxI2,:)];
tmp2 = [g.E(idxJ1,:); g.C(idxJ2,:)]';
A(subI, subJ) = A(subI,subJ) - tmp1*tmp2;
end % if
end % for
function get_update_list(node_idx)
% GET_UPDATE_LIST(NODE_IDX) Recursively get the list of all nodes in
% the tree that could have generated Schur complement updates to
% points in node NODE_IDX
update_list(node_idx) = 1;
update_list(t.nodes(node_idx).snbor) = 1;
for k = t.nodes(node_idx).chld
get_update_list(k);
end % for
end % get_update_list
end % spget
end % srskelf_hybrif