207 lines
4.9 KiB
JavaScript
207 lines
4.9 KiB
JavaScript
"use strict";
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Object.defineProperty(exports, "__esModule", {
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value: true
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});
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exports.createCsSqr = void 0;
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var _csPermute = require("./csPermute.js");
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var _csPost = require("./csPost.js");
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var _csEtree = require("./csEtree.js");
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var _csAmd = require("./csAmd.js");
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var _csCounts = require("./csCounts.js");
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var _factory = require("../../../utils/factory.js");
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var name = 'csSqr';
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var dependencies = ['add', 'multiply', 'transpose'];
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var createCsSqr = /* #__PURE__ */(0, _factory.factory)(name, dependencies, function (_ref) {
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var add = _ref.add,
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multiply = _ref.multiply,
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transpose = _ref.transpose;
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var csAmd = (0, _csAmd.createCsAmd)({
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add: add,
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multiply: multiply,
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transpose: transpose
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});
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var csCounts = (0, _csCounts.createCsCounts)({
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transpose: transpose
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});
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/**
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* Symbolic ordering and analysis for QR and LU decompositions.
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*
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* @param {Number} order The ordering strategy (see csAmd for more details)
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* @param {Matrix} a The A matrix
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* @param {boolean} qr Symbolic ordering and analysis for QR decomposition (true) or
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* symbolic ordering and analysis for LU decomposition (false)
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*
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* @return {Object} The Symbolic ordering and analysis for matrix A
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*
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* Reference: http://faculty.cse.tamu.edu/davis/publications.html
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*/
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return function csSqr(order, a, qr) {
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// a arrays
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var aptr = a._ptr;
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var asize = a._size; // columns
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var n = asize[1]; // vars
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var k; // symbolic analysis result
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var s = {}; // fill-reducing ordering
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s.q = csAmd(order, a); // validate results
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if (order && !s.q) {
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return null;
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} // QR symbolic analysis
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if (qr) {
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// apply permutations if needed
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var c = order ? (0, _csPermute.csPermute)(a, null, s.q, 0) : a; // etree of C'*C, where C=A(:,q)
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s.parent = (0, _csEtree.csEtree)(c, 1); // post order elimination tree
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var post = (0, _csPost.csPost)(s.parent, n); // col counts chol(C'*C)
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s.cp = csCounts(c, s.parent, post, 1); // check we have everything needed to calculate number of nonzero elements
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if (c && s.parent && s.cp && _vcount(c, s)) {
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// calculate number of nonzero elements
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for (s.unz = 0, k = 0; k < n; k++) {
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s.unz += s.cp[k];
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}
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}
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} else {
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// for LU factorization only, guess nnz(L) and nnz(U)
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s.unz = 4 * aptr[n] + n;
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s.lnz = s.unz;
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} // return result S
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return s;
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};
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/**
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* Compute nnz(V) = s.lnz, s.pinv, s.leftmost, s.m2 from A and s.parent
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*/
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function _vcount(a, s) {
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// a arrays
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var aptr = a._ptr;
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var aindex = a._index;
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var asize = a._size; // rows & columns
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var m = asize[0];
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var n = asize[1]; // initialize s arrays
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s.pinv = []; // (m + n)
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s.leftmost = []; // (m)
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// vars
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var parent = s.parent;
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var pinv = s.pinv;
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var leftmost = s.leftmost; // workspace, next: first m entries, head: next n entries, tail: next n entries, nque: next n entries
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var w = []; // (m + 3 * n)
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var next = 0;
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var head = m;
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var tail = m + n;
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var nque = m + 2 * n; // vars
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var i, k, p, p0, p1; // initialize w
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for (k = 0; k < n; k++) {
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// queue k is empty
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w[head + k] = -1;
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w[tail + k] = -1;
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w[nque + k] = 0;
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} // initialize row arrays
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for (i = 0; i < m; i++) {
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leftmost[i] = -1;
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} // loop columns backwards
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for (k = n - 1; k >= 0; k--) {
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// values & index for column k
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for (p0 = aptr[k], p1 = aptr[k + 1], p = p0; p < p1; p++) {
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// leftmost[i] = min(find(A(i,:)))
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leftmost[aindex[p]] = k;
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}
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} // scan rows in reverse order
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for (i = m - 1; i >= 0; i--) {
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// row i is not yet ordered
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pinv[i] = -1;
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k = leftmost[i]; // check row i is empty
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if (k === -1) {
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continue;
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} // first row in queue k
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if (w[nque + k]++ === 0) {
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w[tail + k] = i;
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} // put i at head of queue k
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w[next + i] = w[head + k];
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w[head + k] = i;
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}
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s.lnz = 0;
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s.m2 = m; // find row permutation and nnz(V)
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for (k = 0; k < n; k++) {
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// remove row i from queue k
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i = w[head + k]; // count V(k,k) as nonzero
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s.lnz++; // add a fictitious row
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if (i < 0) {
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i = s.m2++;
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} // associate row i with V(:,k)
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pinv[i] = k; // skip if V(k+1:m,k) is empty
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if (--nque[k] <= 0) {
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continue;
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} // nque[k] is nnz (V(k+1:m,k))
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s.lnz += w[nque + k]; // move all rows to parent of k
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var pa = parent[k];
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if (pa !== -1) {
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if (w[nque + pa] === 0) {
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w[tail + pa] = w[tail + k];
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}
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w[next + w[tail + k]] = w[head + pa];
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w[head + pa] = w[next + i];
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w[nque + pa] += w[nque + k];
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}
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}
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for (i = 0; i < m; i++) {
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if (pinv[i] < 0) {
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pinv[i] = k++;
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}
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}
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return true;
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}
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});
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exports.createCsSqr = createCsSqr; |