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matrix.c @ e83488d

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Last change on this file since e83488d was e83488d, checked in by Olly Betts <olly@…>, 9 months ago

Fix to build with DEBUG_MATRIX_BUILD set to 1

Reported by Eric C. Landgraf.

Property mode set to 100644

File size: 12.3 KB

Rev	Line
[421b7d2]	1	/* matrix.c
[d1b1380]	2	* Matrix building and solving routines
[2d8d46d]	3	* Copyright (C) 1993-2003,2010,2013,2024 Olly Betts
[846746e]	4	*
[89231c4]	5	* This program is free software; you can redistribute it and/or modify
	6	* it under the terms of the GNU General Public License as published by
	7	* the Free Software Foundation; either version 2 of the License, or
	8	* (at your option) any later version.
[846746e]	9	*
	10	* This program is distributed in the hope that it will be useful,
	11	* but WITHOUT ANY WARRANTY; without even the implied warranty of
[89231c4]	12	* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
	13	* GNU General Public License for more details.
[846746e]	14	*
[89231c4]	15	* You should have received a copy of the GNU General Public License
	16	* along with this program; if not, write to the Free Software
[ecbc6c18]	17	* Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA
[d1b1380]	18	*/
	19
[2164fa4]	20	/#define SOR 1/
[702f518]	21
[032ed06]	22	#if 0
	23	# define DEBUG_INVALID 1
	24	#endif
	25
[4c83f84]	26	#include <config.h>
[d1b1380]	27
	28	#include "debug.h"
[a420b49]	29	#include "cavern.h"
[c082b69]	30	#include "filename.h"
	31	#include "message.h"
[d1b1380]	32	#include "netbits.h"
	33	#include "matrix.h"
	34	#include "out.h"
	35
	36	#undef PRINT_MATRICES
	37	#define PRINT_MATRICES 0
	38
	39	#undef DEBUG_MATRIX_BUILD
	40	#define DEBUG_MATRIX_BUILD 0
	41
	42	#undef DEBUG_MATRIX
	43	#define DEBUG_MATRIX 0
	44
	45	#if PRINT_MATRICES
[9965b2b]	46	static void print_matrix(real M, real B, long n);
[d1b1380]	47	#endif
	48
[9965b2b]	49	static void choleski(real M, real B, long n);
[3fde384f]	50
[d1b1380]	51	#ifdef SOR
[9965b2b]	52	static void sor(real M, real B, long n);
[d1b1380]	53	#endif
	54
[a420b49]	55	/* for M(row, col) col must be <= row, so Y <= X */
[9965b2b]	56	# define M(X, Y) ((real )M)[((((OSSIZE_T)(X)) ((X) + 1)) >> 1) + (Y)]
[421b7d2]	57	/* +(Y>X?0printf("row<col (line %d)\n",__LINE__):0) /
[9965b2b]	58	/#define M_(X, Y) ((real )M)[((((OSSIZE_T)(Y)) * ((Y) + 1)) >> 1) + (X)]*/
[d1b1380]	59
[2d8d46d]	60	#define COLOUR_FIXED -1
	61	#define COLOUR_TODO -2
[d1b1380]	62
[2d8d46d]	63	static void set_row(node stn, node from, int row_number) {
	64	// We store the matrix row/column index in stn->colour for quick and easy
	65	// lookup when copying out the solved station coordinates.
	66	stn->colour = row_number;
	67	for (int d = 0; d < 3; d++) {
	68	linkfor *leg = stn->leg[d];
	69	if (!leg) break;
	70	node *to = leg->l.to;
	71	if (to == from \|\| to->colour != COLOUR_TODO) {
	72	continue;
	73	}
	74	if (fZeros(data_here(leg) ? &leg->v : &reverse_leg(leg)->v)) {
	75	set_row(to, stn, row_number);
	76	}
	77	}
	78	}
[d1b1380]	79
[2d8d46d]	80	#ifdef NO_COVARIANCES
	81	# define FACTOR 1
	82	#else
	83	# define FACTOR 3
	84	#endif
[d1b1380]	85
[032ed06]	86	extern void
[d9b5db53]	87	solve_matrix(node *list)
[032ed06]	88	{
	89	node *stn;
[2d8d46d]	90	bool unfixed_stations = false;
[d9b5db53]	91	FOR_EACH_STN(stn, list) {
[103c026]	92	if (!fixed(stn)) {
[2d8d46d]	93	unfixed_stations = true;
	94	stn->colour = COLOUR_TODO;
[103c026]	95	} else {
[2d8d46d]	96	stn->colour = COLOUR_FIXED;
[103c026]	97	}
[032ed06]	98	}
[2d8d46d]	99	if (!unfixed_stations) {
	100	return;
	101	}
[032ed06]	102
[2d8d46d]	103	// Assign a matrix row/column index to each group of stations with the same
	104	// pos.
	105	long n = 0;
[2164fa4]	106	FOR_EACH_STN(stn, list) {
[2d8d46d]	107	if (stn->colour == COLOUR_TODO) {
	108	set_row(stn, NULL, n++);
	109	}
[2164fa4]	110	}
[2d8d46d]	111	SVX_ASSERT(n > 0);
[d1b1380]	112
[2d8d46d]	113	// Array to map from row/column index to pos. We fill this in as we build
	114	// the matrix, and use it to know where to copy the solved station
	115	// coordinates to.
	116	pos *stn_tab = osmalloc((OSSIZE_T)(n ossizeof(pos*)));
[3fde384f]	117
[2d8d46d]	118	/* (OSSIZE_T) cast may be needed if n >= 181 */
	119	real M = osmalloc((OSSIZE_T)((((OSSIZE_T)n FACTOR * (n * FACTOR + 1)) >> 1)) * ossizeof(real));
	120	real B = osmalloc((OSSIZE_T)(n FACTOR * ossizeof(real)));
[dbd68203]	121
[647407d]	122	if (!fQuiet) {
[2d8d46d]	123	if (n == 1)
[a4adf09]	124	out_current_action(msg(/Solving one equation/78));
	125	else
[2d8d46d]	126	out_current_action1(msg(/Solving %d simultaneous equations/75), n);
[dbd68203]	127	}
	128
[3fde384f]	129	#ifdef NO_COVARIANCES
[5bb3dc4]	130	int dim = 2;
[3fde384f]	131	#else
[2d8d46d]	132	int dim = 0; /* Collapse loop to a single iteration. */
[3fde384f]	133	#endif
[a420b49]	134	for ( ; dim >= 0; dim--) {
[907fe10]	135	/* Initialise M and B to zero - zeroing "linearly" will minimise
[421b7d2]	136	* paging when the matrix is large */
[66de220]	137	{
[2d8d46d]	138	int end = n * FACTOR;
	139	for (int row = 0; row < end; row++) B[row] = (real)0.0;
	140	end = ((OSSIZE_T)n * FACTOR * (n * FACTOR + 1)) >> 1;
	141	for (int row = 0; row < end; row++) M[row] = (real)0.0;
[66de220]	142	}
[dbd68203]	143
[3c7ab9a]	144	/* Construct matrix by going through the stn list.
[421b7d2]	145	*
[907fe10]	146	* All legs between two fixed stations can be ignored here.
[421b7d2]	147	*
[3c7ab9a]	148	* Other legs we want to add exactly once to M. To achieve this we
[07ff034]	149	* want to:
[3c7ab9a]	150	*
	151	* - add forward legs between two unfixed stations,
	152	*
	153	* - add legs from unfixed stations to fixed stations (we do them from
	154	* the unfixed end so we don't need to detect when we're at a fixed
	155	* point cut line and determine which side we're currently dealing
	156	* with).
	157	*
	158	* To implement this, we only look at legs from unfixed stations and add
	159	* a leg if to a fixed station, or to an unfixed station and it's a
	160	* forward leg.
	161	*/
[d9b5db53]	162	FOR_EACH_STN(stn, list) {
[2d8d46d]	163	if (dim == 0) {
	164	if (stn->colour != COLOUR_FIXED) {
	165	stn_tab[stn->colour] = stn->name->pos;
	166	}
	167	}
	168
[2164fa4]	169	#ifdef NO_COVARIANCES
	170	real e;
	171	#else
[dac18d8]	172	svar e;
[eb18f4d]	173	delta a;
[2164fa4]	174	#endif
[b5d3988]	175	#if DEBUG_MATRIX_BUILD
[dbd68203]	176	print_prefix(stn->name);
[b5d3988]	177	printf(" used: %d colour %ld\n",
[a420b49]	178	(!!stn->leg[2]) << 2 \| (!!stn -> leg[1]) << 1 \| (!!stn->leg[0]),
[b5d3988]	179	stn->colour);
[3fde384f]	180
[5bb3dc4]	181	for (int dirn = 0; dirn <= 2 && stn->leg[dirn]; dirn++) {
[907fe10]	182	printf("Leg %d, vx=%f, reverse=%d, to ", dirn,
	183	stn->leg[dirn]->v[0], stn->leg[dirn]->l.reverse);
	184	print_prefix(stn->leg[dirn]->l.to->name);
	185	putnl();
	186	}
[dbd68203]	187	putnl();
[d1b1380]	188	#endif /* DEBUG_MATRIX_BUILD */
[b5d3988]	189
[2d8d46d]	190	int f = stn->colour;
	191	if (f != COLOUR_FIXED) {
[5bb3dc4]	192	for (int dirn = 0; dirn <= 2 && stn->leg[dirn]; dirn++) {
[907fe10]	193	linkfor *leg = stn->leg[dirn];
	194	node *to = leg->l.to;
[2d8d46d]	195	int t = to->colour;
	196	if (t == COLOUR_FIXED) {
[907fe10]	197	bool fRev = !data_here(leg);
	198	if (fRev) leg = reverse_leg(leg);
	199	/* Ignore equated nodes */
[3fde384f]	200	#ifdef NO_COVARIANCES
[907fe10]	201	e = leg->v[dim];
	202	if (e != (real)0.0) {
	203	e = ((real)1.0) / e;
	204	M(f,f) += e;
[f52dcc7]	205	B[f] += e * POS(to, dim);
[907fe10]	206	if (fRev) {
[f52dcc7]	207	B[f] += leg->d[dim];
[907fe10]	208	} else {
[f52dcc7]	209	B[f] -= leg->d[dim];
[564f471]	210	}
[907fe10]	211	}
[3fde384f]	212	#else
[907fe10]	213	if (invert_svar(&e, &leg->v)) {
	214	if (fRev) {
	215	adddd(&a, &POSD(to), &leg->d);
	216	} else {
	217	subdd(&a, &POSD(to), &leg->d);
	218	}
[5bb3dc4]	219	delta b;
[907fe10]	220	mulsd(&b, &e, &a);
[5bb3dc4]	221	for (int i = 0; i < 3; i++) {
[907fe10]	222	M(f * FACTOR + i, f * FACTOR + i) += e[i];
	223	B[f * FACTOR + i] += b[i];
[564f471]	224	}
[907fe10]	225	M(f * FACTOR + 1, f * FACTOR) += e[3];
	226	M(f * FACTOR + 2, f * FACTOR) += e[4];
	227	M(f * FACTOR + 2, f * FACTOR + 1) += e[5];
	228	}
[3fde384f]	229	#endif
[907fe10]	230	} else if (data_here(leg)) {
	231	/* forward leg, unfixed -> unfixed */
[d1b1380]	232	#if DEBUG_MATRIX
[907fe10]	233	printf("Leg %d to %d, var %f, delta %f\n", f, t, e,
	234	leg->d[dim]);
[d1b1380]	235	#endif
[907fe10]	236	/* Ignore equated nodes & lollipops */
[3fde384f]	237	#ifdef NO_COVARIANCES
[907fe10]	238	e = leg->v[dim];
	239	if (t != f && e != (real)0.0) {
	240	e = ((real)1.0) / e;
	241	M(f,f) += e;
	242	M(t,t) += e;
	243	if (f < t) M(t,f) -= e; else M(f,t) -= e;
[5bb3dc4]	244	real a = e * leg->d[dim];
[907fe10]	245	B[f] -= a;
	246	B[t] += a;
	247	}
[3fde384f]	248	#else
[907fe10]	249	if (t != f && invert_svar(&e, &leg->v)) {
	250	mulsd(&a, &e, &leg->d);
[5bb3dc4]	251	for (int i = 0; i < 3; i++) {
[907fe10]	252	M(f * FACTOR + i, f * FACTOR + i) += e[i];
	253	M(t * FACTOR + i, t * FACTOR + i) += e[i];
	254	if (f < t)
	255	M(t * FACTOR + i, f * FACTOR + i) -= e[i];
	256	else
	257	M(f * FACTOR + i, t * FACTOR + i) -= e[i];
	258	B[f * FACTOR + i] -= a[i];
	259	B[t * FACTOR + i] += a[i];
	260	}
	261	M(f * FACTOR + 1, f * FACTOR) += e[3];
	262	M(t * FACTOR + 1, t * FACTOR) += e[3];
	263	M(f * FACTOR + 2, f * FACTOR) += e[4];
	264	M(t * FACTOR + 2, t * FACTOR) += e[4];
	265	M(f * FACTOR + 2, f * FACTOR + 1) += e[5];
	266	M(t * FACTOR + 2, t * FACTOR + 1) += e[5];
	267	if (f < t) {
	268	M(t * FACTOR + 1, f * FACTOR) -= e[3];
	269	M(t * FACTOR, f * FACTOR + 1) -= e[3];
	270	M(t * FACTOR + 2, f * FACTOR) -= e[4];
	271	M(t * FACTOR, f * FACTOR + 2) -= e[4];
	272	M(t * FACTOR + 2, f * FACTOR + 1) -= e[5];
	273	M(t * FACTOR + 1, f * FACTOR + 2) -= e[5];
	274	} else {
	275	M(f * FACTOR + 1, t * FACTOR) -= e[3];
	276	M(f * FACTOR, t * FACTOR + 1) -= e[3];
	277	M(f * FACTOR + 2, t * FACTOR) -= e[4];
	278	M(f * FACTOR, t * FACTOR + 2) -= e[4];
	279	M(f * FACTOR + 2, t * FACTOR + 1) -= e[5];
	280	M(f * FACTOR + 1, t * FACTOR + 2) -= e[5];
[dbd68203]	281	}
	282	}
[907fe10]	283	#endif
[564f471]	284	}
[907fe10]	285	}
[dbd68203]	286	}
[d1b1380]	287	}
	288
	289	#if PRINT_MATRICES
[2d8d46d]	290	print_matrix(M, B, n * FACTOR); /* 'ave a look! */
[d1b1380]	291	#endif
	292
	293	#ifdef SOR
[032ed06]	294	/* defined in network.c, may be altered by -z<letters> on command line */
[a420b49]	295	if (optimize & BITA('i'))
[2d8d46d]	296	sor(M, B, n * FACTOR);
[dbd68203]	297	else
[d1b1380]	298	#endif
[2d8d46d]	299	choleski(M, B, n * FACTOR);
[d1b1380]	300
[dbd68203]	301	{
[2d8d46d]	302	for (int m = (int)(n - 1); m >= 0; m--) {
[3fde384f]	303	#ifdef NO_COVARIANCES
[c19f129]	304	stn_tab[m]->p[dim] = B[m];
[4a59b4f]	305	# if !EXPLICIT_FIXED_FLAG
[032ed06]	306	if (dim == 0) {
[4c07c51]	307	SVX_ASSERT2(pos_fixed(stn_tab[m]),
[032ed06]	308	"setting station coordinates didn't mark pos as fixed");
	309	}
[4a59b4f]	310	# endif
[3fde384f]	311	#else
[5bb3dc4]	312	for (int i = 0; i < 3; i++) {
[c19f129]	313	stn_tab[m]->p[i] = B[m * FACTOR + i];
[702f518]	314	}
[4a59b4f]	315	# if !EXPLICIT_FIXED_FLAG
[4c07c51]	316	SVX_ASSERT2(pos_fixed(stn_tab[m]),
[032ed06]	317	"setting station coordinates didn't mark pos as fixed");
[4a59b4f]	318	# endif
[3fde384f]	319	#endif
[4a59b4f]	320	#if EXPLICIT_FIXED_FLAG && !defined NO_COVARIANCES
	321	fixpos(stn_tab[m]);
[d1b1380]	322	#endif
[4a59b4f]	323	}
[dbd68203]	324	}
	325	}
[4a59b4f]	326	#if EXPLICIT_FIXED_FLAG && defined NO_COVARIANCES
[2d8d46d]	327	for (int m = n - 1; m >= 0; m--) fixpos(stn_tab[m]);
[4a59b4f]	328	#endif
[dbd68203]	329	osfree(B);
	330	osfree(M);
[2d8d46d]	331	osfree(stn_tab);
	332
	333	#if DEBUG_MATRIX
	334	FOR_EACH_STN(stn, list) {
	335	printf("(%8.2f, %8.2f, %8.2f ) ", POS(stn, 0), POS(stn, 1), POS(stn, 2));
	336	print_prefix(stn->name);
	337	putnl();
	338	}
	339	#endif
[d1b1380]	340	}
	341
[702f518]	342	/* Solve MX=B for X by Choleski factorisation - modified Choleski actually
	343	* since we factor into LDL' while Choleski is just LL'
	344	*/
[d1b1380]	345	/* Note M must be symmetric positive definite */
	346	/* routine is entitled to scribble on M and B if it wishes */
[a420b49]	347	static void
[9965b2b]	348	choleski(real M, real B, long n)
[a420b49]	349	{
[5bb3dc4]	350	for (int j = 1; j < n; j++) {
[3fde384f]	351	real V;
[5bb3dc4]	352	for (int i = 0; i < j; i++) {
[421b7d2]	353	V = (real)0.0;
[5bb3dc4]	354	for (int k = 0; k < i; k++) V += M(i,k) * M(j,k) * M(k,k);
[a420b49]	355	M(j,i) = (M(j,i) - V) / M(i,i);
[dbd68203]	356	}
	357	V = (real)0.0;
[5bb3dc4]	358	for (int k = 0; k < j; k++) V += M(j,k) * M(j,k) * M(k,k);
[3fde384f]	359	M(j,j) -= V; /* may be best to add M() last for numerical reasons too */
[dbd68203]	360	}
[d1b1380]	361
[dbd68203]	362	/* Multiply x by L inverse */
[5bb3dc4]	363	for (int i = 0; i < n - 1; i++) {
	364	for (int j = i + 1; j < n; j++) {
[dbd68203]	365	B[j] -= M(j,i) * B[i];
[3fde384f]	366	}
[dbd68203]	367	}
[d1b1380]	368
[dbd68203]	369	/* Multiply x by D inverse */
[5bb3dc4]	370	for (int i = 0; i < n; i++) {
[dbd68203]	371	B[i] /= M(i,i);
[3fde384f]	372	}
	373
	374	/* Multiply x by (L transpose) inverse */
[5bb3dc4]	375	for (int i = (int)(n - 1); i > 0; i--) {
	376	for (int j = i - 1; j >= 0; j--) {
[421b7d2]	377	B[j] -= M(i,j) * B[i];
[3fde384f]	378	}
[dbd68203]	379	}
[d1b1380]	380
[dbd68203]	381	/* printf("\n%ld/%ld\n\n",flops,flopsTot); */
[d1b1380]	382	}
	383
	384	#ifdef SOR
	385	/* factor to use for SOR (must have 1 <= SOR_factor < 2) */
[702f518]	386	#define SOR_factor 1.93 /* 1.95 */
[d1b1380]	387
	388	/* Solve MX=B for X by SOR of Gauss-Siedel */
	389	/* routine is entitled to scribble on M and B if it wishes */
[a420b49]	390	static void
[9965b2b]	391	sor(real M, real B, long n)
[a420b49]	392	{
[dbd68203]	393	long it = 0;
[d1b1380]	394
[5bb3dc4]	395	real X = osmalloc(n ossizeof(real));
[d1b1380]	396
[5bb3dc4]	397	const real threshold = 0.00001;
[d1b1380]	398
[647407d]	399	printf("reciprocating diagonal\n"); /* TRANSLATE */
[d1b1380]	400
[3fde384f]	401	/* munge diagonal so we can multiply rather than divide */
[5bb3dc4]	402	for (int row = n - 1; row >= 0; row--) {
[dbd68203]	403	M(row,row) = 1 / M(row,row);
[702f518]	404	X[row] = 0;
[dbd68203]	405	}
[d1b1380]	406
[647407d]	407	printf("starting iteration\n"); /* TRANSLATE */
[d1b1380]	408
[5bb3dc4]	409	real t;
[dbd68203]	410	do {
	411	/printf("");*/
	412	it++;
	413	t = 0.0;
[5bb3dc4]	414	for (int row = 0; row < n; row++) {
	415	real x = B[row];
	416	int col;
[a420b49]	417	for (col = 0; col < row; col++) x -= M(row,col) * X[col];
	418	for (col++; col < n; col++) x -= M(col,row) * X[col];
[dbd68203]	419	x *= M(row,row);
[3b8b342]	420	real sor_delta = (x - X[row]) * SOR_factor;
	421	X[row] += sor_delta;
	422	real t2 = fabs(sor_delta);
[dbd68203]	423	if (t2 > t) t = t2;
	424	}
[3b8b342]	425	printf("% 6ld: %8.6f\n", it, t);
[dbd68203]	426	} while (t >= threshold && it < 100000);
[d1b1380]	427
[dbd68203]	428	if (t >= threshold) {
	429	fprintf(stderr, "not converged after %ld iterations\n", it);
	430	BUG("iteration stinks");
	431	}
[d1b1380]	432
[647407d]	433	printf("%ld iterations\n", it); /* TRANSLATE */
[d1b1380]	434
	435	#if 0
[dbd68203]	436	putnl();
[5bb3dc4]	437	for (int row = n - 1; row >= 0; row--) {
[dbd68203]	438	t = 0.0;
[5bb3dc4]	439	for (int col = 0; col < row; col++) t += M(row, col) * X[col];
[a420b49]	440	t += X[row] / M(row, row);
	441	for (col = row + 1; col < n; col++)
	442	t += M(col, row) * X[col];
[b5d3988]	443	printf("[ %f %f ]\n", t, B[row]);
[dbd68203]	444	}
[d1b1380]	445	#endif
	446
[5bb3dc4]	447	for (int row = n - 1; row >= 0; row--) B[row] = X[row];
[d1b1380]	448
[dbd68203]	449	osfree(X);
[647407d]	450	printf("\ndone\n"); /* TRANSLATE */
[dbd68203]	451	}
[d1b1380]	452	#endif
	453
	454	#if PRINT_MATRICES
[a420b49]	455	static void
[9965b2b]	456	print_matrix(real M, real B, long n)
[a420b49]	457	{
[dbd68203]	458	printf("Matrix, M and vector, B:\n");
[5bb3dc4]	459	for (long row = 0; row < n; row++) {
	460	long col;
[a420b49]	461	for (col = 0; col <= row; col++) printf("%6.2f\t", M(row, col));
	462	for (; col <= n; col++) printf(" \t");
[dbd68203]	463	printf("\t%6.2f\n", B[row]);
	464	}
	465	putnl();
	466	return;
[d1b1380]	467	}
	468	#endif

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source: git/src/matrix.c @ e83488d

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