lemon-benchmark: generators/netgen/netgen.c@3c30bd0f9ccc (annotated)

alpar@6	1	/*** Copyright 1989 Norbert Schlenker. All rights reserved.
alpar@6	2
alpar@6	3	*** This software is distributed subject to the following provisions:
alpar@6	4	*** - this notice may not be removed;
alpar@6	5	*** - you may modify the source code, as long as redistributed
alpar@6	6	*** versions have their modifications clearly marked;
alpar@6	7	*** - no charge, other than a nominal copying fee, may be made
alpar@6	8	*** when providing copies of this source code to others;
alpar@6	9	*** - if this source code is used as part of a product which is
alpar@6	10	*** distributed only as a binary, a copy of this source code
alpar@6	11	*** must be included in the distribution.
alpar@6	12	***
alpar@6	13	*** Unlike the GNU GPL, use of this code does not obligate you to
alpar@6	14	*** disclose your own proprietary source code.
alpar@6	15
alpar@6	16	*** The author of this software provides no warranty, express or
alpar@6	17	*** implied, as to its utility or correctness. That said, reports
alpar@6	18	*** of bugs or compatibility problems will be gladly received by
alpar@6	19	*** nfs@princeton.edu, and fixes will be attempted.
alpar@6	20	***/
alpar@6	21
alpar@6	22
alpar@6	23	/*** netgen - C version of the standard NETGEN network generator
alpar@6	24	*** This program is a functional equivalent of the
alpar@6	25	*** standard network generator NETGEN described in:
alpar@6	26	*** Klingman, D., A. Napier, and J. Stutz, "NETGEN: A Program
alpar@6	27	*** for Generating Large Scale Capacitated Assignment,
alpar@6	28	*** Transportation, and Minimum Cost Flow Network Problems",
alpar@6	29	*** Management Science 20, 5, 814-821 (1974)
alpar@6	30	***
alpar@6	31	*** This software provides a number of interfaces for use by
alpar@6	32	*** network solvers. Standard call interfaces are supplied for
alpar@6	33	*** use by (Unix) C and Fortran solvers, with generation parameters
alpar@6	34	*** passed into the generator and the flow network passed back to
alpar@6	35	*** the solver via large external (COMMON in Fortran) arrays.
alpar@6	36	*** For the DIMACS challenge, this code will produce output files
alpar@6	37	*** in the appropriate format for later reading by solvers.
alpar@6	38	*** Undefine the symbol DIMACS when using the call interface.
alpar@6	39	***
alpar@6	40	*** The generator produces exact duplicates of the networks
alpar@6	41	*** made by the Fortran code (even though that means bugs
alpar@6	42	*** are being perpetuated). It is faster by orders of magnitude
alpar@6	43	*** in generating large networks, primarily by imposing the
alpar@6	44	*** notion of the abstract data type INDEX_LIST and implementing
alpar@6	45	*** the type operations in a reasonably efficient fashion.
alpar@6	46	***/
alpar@6	47
alpar@6	48	/*** Generates transportation problems if:
alpar@6	49	*** SOURCES+SINKS == NODES && TSOURCES == TSINKS == 0
alpar@6	50	***
alpar@6	51	*** Generates assignment problems if above conditions are satisfied, and:
alpar@6	52	*** SOURCES == SINKS && SUPPLY == SOURCES
alpar@6	53	***
alpar@6	54	*** Generates maximum flow problems if not an assignment problem and:
alpar@6	55	*** MINCOST == MAXCOST == 1
alpar@6	56
alpar@6	57	*** Implementation notes:
alpar@6	58	***
alpar@6	59	*** This file contains both a Fortran and a C interface. The
alpar@6	60	*** Fortran interface is suffixed with an underscore to make it
alpar@6	61	*** callable in the normal fashion from Fortran (a Unix convention).
alpar@6	62	***
alpar@6	63	*** Because Fortran has no facility for pointers, the common arrays
alpar@6	64	*** are statically allocated. Static allocation has nothing to recommend
alpar@6	65	*** it except for the need for a Fortran interface.
alpar@6	66	***
alpar@6	67	*** This software expects input parameters to be long integers
alpar@6	68	*** (in the sense of C); that means no INTEGER*2 from Fortran callers.
alpar@6	69	***
alpar@6	70	*** Compiling with -DDIMACS produces a program that reads problem
alpar@6	71	*** parameters, generates the appropriate problem, and prints it.
alpar@6	72	***
alpar@6	73	*** Compiling with -DDEBUG produces code with externally visible
alpar@6	74	*** procedure names, useful for debugging and profiling.
alpar@6	75	***/
alpar@6	76
alpar@6	77
alpar@6	78	/*** System interfaces */
alpar@6	79
alpar@6	80	#include <stdio.h>
alpar@6	81
alpar@6	82
alpar@6	83	/*** Public interfaces */
alpar@6	84
alpar@6	85	#define ALLOCATE_NETWORK
alpar@6	86	#include "netgen.h"
alpar@6	87
alpar@7	88	#include "main.h"
alpar@6	89
alpar@6	90	/*** Private interfaces */
alpar@6	91
alpar@6	92	#ifdef DEBUG
alpar@6	93	#define PRIVATE
alpar@6	94	#else
alpar@6	95	#define PRIVATE static
alpar@6	96	#endif
alpar@6	97
alpar@6	98	#ifdef __STDC__
alpar@6	99	PRIVATE void create_supply(NODE, CAPACITY); /* create supply nodes */
alpar@6	100	PRIVATE void create_assignment(long); / create assignment problem */
alpar@6	101	PRIVATE void sort_skeleton(int); /* sorts skeleton chains */
alpar@6	102	PRIVATE void pick_head(long, int, NODE); / choose destination nodes for rubbish arcs */
alpar@6	103	PRIVATE void error_exit(long); /* print error message and exit */
alpar@6	104	#else
alpar@6	105	PRIVATE void create_supply(); /* create supply nodes */
alpar@6	106	PRIVATE void create_assignment(); /* create assignment problem */
alpar@6	107	PRIVATE void sort_skeleton(); /* sorts skeleton chains */
alpar@6	108	PRIVATE void pick_head(); /* chooses destination nodes for rubbish arcs */
alpar@6	109	PRIVATE void error_exit(); /* print error message and exit */
alpar@6	110	#endif
alpar@6	111
alpar@6	112	/*** Private variables */
alpar@6	113
alpar@6	114	static NODE nodes_left;
alpar@6	115	static ARC arc_count;
alpar@6	116	static NODE pred[MAXARCS];
alpar@6	117	static NODE head[MAXARCS];
alpar@6	118	static NODE tail[MAXARCS];
alpar@6	119
alpar@6	120
alpar@6	121	/*** Local macros */
alpar@6	122
alpar@6	123	#define MIN(x, y) ((x) < (y) ? (x) : (y))
alpar@6	124	#define MAX(x, y) ((x) > (y) ? (x) : (y))
alpar@6	125	#define SAVE_ARC(tail, head, cost, capacity) /* records an arc where our caller can get it */ \
alpar@6	126	{ \
alpar@6	127	FROM[arc_count] = tail; \
alpar@6	128	TO [arc_count] = head; \
alpar@6	129	C [arc_count] = cost; \
alpar@6	130	U [arc_count] = capacity; \
alpar@6	131	arc_count++; \
alpar@6	132	}
alpar@6	133
alpar@6	134
alpar@6	135	/*** Fortran callable interface routine */
alpar@6	136
alpar@6	137	void netgen_(seed, parms, generated_nodes, generated_arcs)
alpar@6	138	long* seed; /* pointer to random seed */
alpar@6	139	long parms[PROBLEM_PARMS]; /* problem parameters */
alpar@6	140	long* generated_nodes; /* number of generated nodes */
alpar@6	141	long* generated_arcs; /* number of generated arcs */
alpar@6	142	{
alpar@6	143	*generated_nodes = NODES;
alpar@6	144	if ((generated_arcs = netgen(seed, parms)) < 0)
alpar@6	145	error_exit(*generated_arcs);
alpar@6	146	}
alpar@6	147
alpar@6	148
alpar@6	149	/*** C callable interface routine */
alpar@6	150
alpar@6	151	ARC netgen(seed, parms)
alpar@6	152	long seed; /* random seed */
alpar@6	153	long parms[]; /* problem parameters */
alpar@6	154	{
alpar@6	155	register NODE i,j,k;
alpar@6	156	NODE source;
alpar@6	157	NODE node;
alpar@6	158	NODE sinks_per_source;
alpar@6	159	NODE* sinks;
alpar@6	160	NODE it;
alpar@6	161	int chain_length;
alpar@6	162	COST cost;
alpar@6	163	CAPACITY cap;
alpar@6	164	INDEX_LIST handle;
alpar@6	165	int supply_per_sink;
alpar@6	166	int partial_supply;
alpar@6	167	int sort_count;
alpar@6	168
alpar@6	169
alpar@6	170	/*** Perform sanity checks on the input */
alpar@6	171
alpar@6	172	if (seed <= 0)
alpar@6	173	return BAD_SEED;
alpar@6	174	if (NODES > MAXNODES \|\| DENSITY > MAXARCS)
alpar@6	175	return TOO_BIG;
alpar@6	176	if ((NODES <= 0) \|\|
alpar@6	177	(NODES > DENSITY) \|\|
alpar@6	178	(SOURCES <= 0) \|\|
alpar@6	179	(SINKS <= 0) \|\|
alpar@6	180	(SOURCES + SINKS > NODES) \|\|
alpar@6	181	(MINCOST > MAXCOST) \|\|
alpar@6	182	(SUPPLY < SOURCES) \|\|
alpar@6	183	(TSOURCES > SOURCES) \|\|
alpar@6	184	(TSINKS > SINKS) \|\|
alpar@6	185	(HICOST < 0 \|\| HICOST > 100) \|\|
alpar@6	186	(CAPACITATED < 0 \|\| CAPACITATED > 100) \|\|
alpar@6	187	(MINCAP > MAXCAP))
alpar@6	188	return BAD_PARMS;
alpar@6	189
alpar@6	190
alpar@6	191	/*** Do a little bit of setting up. */
alpar@6	192
alpar@6	193	set_random(seed);
alpar@6	194
alpar@6	195	arc_count = 0;
alpar@6	196	nodes_left = NODES - SINKS + TSINKS;
alpar@6	197
alpar@6	198	if ((SOURCES-TSOURCES)+(SINKS-TSINKS) == NODES &&
alpar@6	199	(SOURCES-TSOURCES) == (SINKS-TSINKS) &&
alpar@6	200	SOURCES == SUPPLY) {
alpar@6	201	create_assignment(parms);
alpar@6	202	return arc_count;
alpar@6	203	}
alpar@6	204
alpar@6	205	(void)memset((void )B, 0, sizeof(B));/ set supplies and demands to zero */
alpar@6	206
alpar@6	207	create_supply((NODE)SOURCES, (CAPACITY)SUPPLY);
alpar@6	208
alpar@6	209
alpar@6	210	/*** Form most of the network skeleton. First, 60% of the transshipment
alpar@6	211	*** nodes are divided evenly among the various sources; the remainder
alpar@6	212	*** are chained onto the end of the chains belonging to random sources.
alpar@6	213	***/
alpar@6	214
alpar@6	215	for (i = 1; i <= SOURCES; i++) /* point SOURCES at themselves */
alpar@6	216	pred[i] = i;
alpar@6	217	handle = make_index_list((INDEX)(SOURCES + 1), (INDEX)(NODES - SINKS));
alpar@6	218	source = 1;
alpar@6	219	for (i = NODES-SOURCES-SINKS; i > (4*(NODES-SOURCES-SINKS)+9)/10; i--) {
alpar@6	220	node = choose_index(handle, (INDEX)ng_random(1L, (long)index_size(handle)));
alpar@6	221	pred[node] = pred[source];
alpar@6	222	pred[source] = node;
alpar@6	223	if (++source > SOURCES)
alpar@6	224	source = 1;
alpar@6	225	}
alpar@6	226	for ( ; i > 0; --i) {
alpar@6	227	node = choose_index(handle, (INDEX)ng_random(1L, (long)index_size(handle)));
alpar@6	228	source = ng_random(1L, SOURCES);
alpar@6	229	pred[node] = pred[source];
alpar@6	230	pred[source] = node;
alpar@6	231	}
alpar@6	232	free_index_list(handle);
alpar@6	233
alpar@6	234
alpar@6	235	/*** For each source chain, hook it to an "appropriate" number of sinks,
alpar@6	236	*** place capacities and costs on the skeleton edges, and then call
alpar@6	237	*** pick_head to add a bunch of rubbish edges at each node on the chain.
alpar@6	238	***/
alpar@6	239
alpar@6	240	for (source = 1; source <= SOURCES; source++) {
alpar@6	241	sort_count = 0;
alpar@6	242	node = pred[source];
alpar@6	243	while (node != source) {
alpar@6	244	sort_count++;
alpar@6	245	head[sort_count] = node;
alpar@6	246	node = tail[sort_count] = pred[node];
alpar@6	247	}
alpar@6	248	if ((NODES-SOURCES-SINKS) == 0)
alpar@6	249	sinks_per_source = SINKS/SOURCES + 1;
alpar@6	250	else
alpar@6	251	/* changing to handle overflows with large n; Mar 18 -- jc */
alpar@6	252	sinks_per_source = ((double) 2sort_countSINKS) / ((double) NODES-SOURCES-SINKS);
alpar@6	253	sinks_per_source = MAX(2, MIN(sinks_per_source, SINKS));
alpar@6	254	sinks = (NODE) malloc(sinks_per_source sizeof(NODE));
alpar@6	255	handle = make_index_list((INDEX)(NODES - SINKS), (INDEX)(NODES - 1));
alpar@6	256	for (i = 0; i < sinks_per_source; i++) {
alpar@6	257	sinks[i] = choose_index(handle, (INDEX)ng_random(1L, (long)index_size(handle)));
alpar@6	258	}
alpar@6	259	if (source == SOURCES && index_size(handle) > 0) {
alpar@6	260	sinks = (NODE) realloc((void )sinks, (sinks_per_source + index_size(handle)) * sizeof(NODE));
alpar@6	261	while (index_size(handle) > 0) {
alpar@6	262	j = choose_index(handle, 1);
alpar@6	263	if (B[j] == 0)
alpar@6	264	sinks[sinks_per_source++] = j;
alpar@6	265	}
alpar@6	266	}
alpar@6	267	free_index_list(handle);
alpar@6	268
alpar@6	269	chain_length = sort_count;
alpar@6	270	supply_per_sink = B[source-1] / sinks_per_source;
alpar@6	271	k = pred[source];
alpar@6	272	for (i = 0; i < sinks_per_source; i++) {
alpar@6	273	sort_count++;
alpar@6	274	partial_supply = ng_random(1L, (long)supply_per_sink);
alpar@6	275	j = ng_random(0L, (long)sinks_per_source - 1);
alpar@6	276	tail[sort_count] = k;
alpar@6	277	head[sort_count] = sinks[i] + 1;
alpar@6	278	B[sinks[i]] -= partial_supply;
alpar@6	279	B[sinks[j]] -= (supply_per_sink - partial_supply);
alpar@6	280	k = source;
alpar@6	281	for (j = ng_random(1L, (long)chain_length); j > 0; j--)
alpar@6	282	k = pred[k];
alpar@6	283	}
alpar@6	284	B[sinks[0]] -= (B[source-1] % sinks_per_source);
alpar@6	285	free((void *)sinks);
alpar@6	286
alpar@6	287	sort_skeleton(sort_count);
alpar@6	288	tail[sort_count+1] = 0;
alpar@6	289	for (i = 1; i <= sort_count; ) {
alpar@6	290	handle = make_index_list((INDEX)(SOURCES - TSOURCES + 1), (INDEX)NODES);
alpar@6	291	remove_index(handle, (INDEX)tail[i]);
alpar@6	292	it = tail[i];
alpar@6	293	while (it == tail[i]) {
alpar@6	294	remove_index(handle, (INDEX)head[i]);
alpar@6	295	cap = SUPPLY;
alpar@6	296	if (ng_random(1L, 100L) <= CAPACITATED)
alpar@6	297	cap = MAX(B[source-1], MINCAP);
alpar@6	298	cost = MAXCOST;
alpar@6	299	if (ng_random(1L, 100L) > HICOST)
alpar@6	300	cost = ng_random(MINCOST, MAXCOST);
alpar@6	301	SAVE_ARC(it,head[i],cost,cap);
alpar@6	302	i++;
alpar@6	303	}
alpar@6	304	pick_head(parms, handle, it);
alpar@6	305	free_index_list(handle);
alpar@6	306	}
alpar@6	307	}
alpar@6	308
alpar@6	309
alpar@6	310	/*** Add more rubbish edges out of the transshipment sinks. */
alpar@6	311
alpar@6	312	for (i = NODES - SINKS + 1; i <= NODES - SINKS + TSINKS; i++) {
alpar@6	313	handle = make_index_list((INDEX)(SOURCES - TSOURCES + 1), (INDEX)NODES);
alpar@6	314	remove_index(handle, (INDEX)i);
alpar@6	315	pick_head(parms, handle, i);
alpar@6	316	free_index_list(handle);
alpar@6	317	}
alpar@6	318
alpar@6	319	return arc_count;
alpar@6	320	}
alpar@6	321
alpar@6	322
alpar@6	323	PRIVATE void create_supply(sources, supply)
alpar@6	324	NODE sources;
alpar@6	325	CAPACITY supply;
alpar@6	326	{
alpar@6	327	CAPACITY supply_per_source = supply / sources;
alpar@6	328	CAPACITY partial_supply;
alpar@6	329	NODE i;
alpar@6	330
alpar@6	331	for (i = 0; i < sources; i++) {
alpar@6	332	B[i] += (partial_supply = ng_random(1L, (long)supply_per_source));
alpar@6	333	B[ng_random(0L, (long)(sources - 1))] += supply_per_source - partial_supply;
alpar@6	334	}
alpar@6	335	B[ng_random(0L, (long)(sources - 1))] += supply % sources;
alpar@6	336	}
alpar@6	337
alpar@6	338
alpar@6	339	PRIVATE void create_assignment(parms)
alpar@6	340	long parms[];
alpar@6	341	{
alpar@6	342	INDEX_LIST skeleton, handle;
alpar@6	343	INDEX index;
alpar@6	344	NODE source;
alpar@6	345
alpar@6	346	for (source = 0; source < NODES/2; source++)
alpar@6	347	B[source] = 1;
alpar@6	348	for ( ; source < NODES; source++)
alpar@6	349	B[source] = -1;
alpar@6	350
alpar@6	351	skeleton = make_index_list((INDEX)(SOURCES + 1), (INDEX)NODES);
alpar@6	352	for (source = 1; source <= NODES/2; source++) {
alpar@6	353	index = choose_index(skeleton, (INDEX)ng_random(1L, (long)index_size(skeleton)));
alpar@6	354	SAVE_ARC(source, index, ng_random(MINCOST, MAXCOST), 1);
alpar@6	355	handle = make_index_list((INDEX)(SOURCES + 1), (INDEX)NODES);
alpar@6	356	remove_index(handle, index);
alpar@6	357	pick_head(parms, handle, source);
alpar@6	358	free_index_list(handle);
alpar@6	359	}
alpar@6	360	free_index_list(skeleton);
alpar@6	361	}
alpar@6	362
alpar@6	363
alpar@6	364	PRIVATE void sort_skeleton(sort_count) /* Shell sort */
alpar@6	365	int sort_count;
alpar@6	366	{
alpar@6	367	int m,i,j,k;
alpar@6	368	int temp;
alpar@6	369
alpar@6	370	m = sort_count;
alpar@6	371	while ((m /= 2) != 0) {
alpar@6	372	k = sort_count - m;
alpar@6	373	for (j = 1; j <= k; j++) {
alpar@6	374	i = j;
alpar@6	375	while (i >= 1 && tail[i] > tail[i+m]) {
alpar@6	376	temp = tail[i];
alpar@6	377	tail[i] = tail[i+m];
alpar@6	378	tail[i+m] = temp;
alpar@6	379	temp = head[i];
alpar@6	380	head[i] = head[i+m];
alpar@6	381	head[i+m] = temp;
alpar@6	382	i -= m;
alpar@6	383	}
alpar@6	384	}
alpar@6	385	}
alpar@6	386	}
alpar@6	387
alpar@6	388
alpar@6	389	PRIVATE void pick_head(parms, handle, desired_tail)
alpar@6	390	long parms[];
alpar@6	391	INDEX_LIST handle;
alpar@6	392	NODE desired_tail;
alpar@6	393	{
alpar@6	394	NODE non_sources = NODES - SOURCES + TSOURCES;
alpar@6	395
alpar@6	396	/* changing Aug 29 -- jc
alpar@6	397	ARC remaining_arcs = DENSITY - arc_count;
alpar@6	398	*/
alpar@6	399	int remaining_arcs = (int) DENSITY - (int) arc_count;
alpar@6	400
alpar@6	401	INDEX index;
alpar@6	402	int limit;
alpar@6	403	long upper_bound;
alpar@6	404	CAPACITY cap;
alpar@6	405
alpar@6	406	/* changing Aug 29 -- jc
alpar@6	407	*/
alpar@6	408	nodes_left--;
alpar@6	409	if ((2 * (int) nodes_left) >= (int) remaining_arcs)
alpar@6	410	return;
alpar@6	411
alpar@6	412	if ((remaining_arcs + non_sources - pseudo_size(handle) - 1) / (nodes_left + 1) >= non_sources - 1) {
alpar@6	413	limit = non_sources;
alpar@6	414	} else {
alpar@6	415	upper_bound = 2 * (remaining_arcs / (nodes_left + 1) - 1);
alpar@6	416	do {
alpar@6	417	limit = ng_random(1L, upper_bound);
alpar@6	418	if (nodes_left == 0)
alpar@6	419	limit = remaining_arcs;
alpar@6	420	/* changing to handle overflows with large n; Mar 18 -- jc */
alpar@6	421	} while ( ((double) nodes_left * (non_sources - 1)) < ((double) remaining_arcs - limit));
alpar@6	422	}
alpar@6	423
alpar@6	424	for ( ; limit > 0; limit--) {
alpar@6	425	index = choose_index(handle, (INDEX)ng_random(1L, (long)pseudo_size(handle)));
alpar@6	426	cap = SUPPLY;
alpar@6	427	if (ng_random(1L, 100L) <= CAPACITATED)
alpar@6	428	cap = ng_random(MINCAP, MAXCAP);
alpar@6	429
alpar@6	430	/* adding Aug 29 -- jc */
alpar@6	431	if ((1 <= index) && (index <= NODES)) {
alpar@6	432	SAVE_ARC(desired_tail, index, ng_random(MINCOST, MAXCOST), cap);
alpar@6	433	}
alpar@6	434
alpar@6	435	}
alpar@6	436	}
alpar@6	437
alpar@6	438
alpar@6	439	/*** Print an appropriate error message and then exit with a nonzero code. */
alpar@6	440
alpar@6	441	PRIVATE void error_exit(rc)
alpar@6	442	long rc;
alpar@6	443	{
alpar@6	444	switch (rc) {
alpar@6	445	case BAD_SEED:
alpar@6	446	fprintf(stderr, "NETGEN requires a positive random seed\n");
alpar@6	447	break;
alpar@6	448	case TOO_BIG:
alpar@6	449	fprintf(stderr, "Problem too large for generator\n");
alpar@6	450	break;
alpar@6	451	case BAD_PARMS:
alpar@6	452	fprintf(stderr, "Inconsistent parameter settings - check the input\n");
alpar@6	453	break;
alpar@6	454	case ALLOCATION_FAILURE:
alpar@6	455	fprintf(stderr, "Memory allocation failure\n");
alpar@6	456	break;
alpar@6	457	default:
alpar@6	458	fprintf(stderr, "Internal error\n");
alpar@6	459	break;
alpar@6	460	}
alpar@6	461	exit(1000 - (int)rc);
alpar@6	462	}
alpar@6	463
alpar@6	464	#ifdef DIMACS /* generates network on standard output */
alpar@6	465
alpar@6	466	#define READ(v) /* read one variable using scanf */ \
alpar@6	467	switch( scanf("%ld", &v) ) { \
alpar@6	468	case 1: \
alpar@6	469	break; \
alpar@6	470	default: \
alpar@6	471	exit(0); \
alpar@6	472	}
alpar@6	473
alpar@7	474	int orig_main(long seed,long problem,long *parms)
alpar@6	475	{
alpar@6	476	long arcs;
alpar@6	477	int i;
alpar@6	478
alpar@6	479	/*** Read problem parameters and generate networks */
alpar@7	480	{
alpar@6	481	printf("c NETGEN flow network generator (C version)\n");
alpar@6	482	printf("c Problem %2ld input parameters\n", problem);
alpar@6	483	printf("c ---------------------------\n");
alpar@6	484	printf("c Random seed: %10ld\n", seed);
alpar@6	485	printf("c Number of nodes: %10ld\n", NODES);
alpar@6	486	printf("c Source nodes: %10ld\n", SOURCES);
alpar@6	487	printf("c Sink nodes: %10ld\n", SINKS);
alpar@6	488	printf("c Number of arcs: %10ld\n", DENSITY);
alpar@6	489	printf("c Minimum arc cost: %10ld\n", MINCOST);
alpar@6	490	printf("c Maximum arc cost: %10ld\n", MAXCOST);
alpar@6	491	printf("c Total supply: %10ld\n", SUPPLY);
alpar@6	492	printf("c Transshipment -\n");
alpar@6	493	printf("c Sources: %10ld\n", TSOURCES);
alpar@6	494	printf("c Sinks: %10ld\n", TSINKS);
alpar@6	495	printf("c Skeleton arcs -\n");
alpar@6	496	printf("c With max cost: %10ld%%\n", HICOST);
alpar@6	497	printf("c Capacitated: %10ld%%\n", CAPACITATED);
alpar@6	498	printf("c Minimum arc capacity: %10ld\n", MINCAP);
alpar@6	499	printf("c Maximum arc capacity: %10ld\n", MAXCAP);
alpar@6	500
alpar@6	501	if ((arcs = netgen(seed, parms)) < 0)
alpar@6	502	error_exit(arcs);
alpar@6	503	if ((SOURCES-TSOURCES)+(SINKS-TSINKS) == NODES &&
alpar@6	504	(SOURCES-TSOURCES) == (SINKS-TSINKS) &&
alpar@6	505	SOURCES == SUPPLY) {
alpar@6	506	printf("c\n");
alpar@6	507	printf("c * Assignment *\n");
alpar@6	508	printf("c\n");
alpar@6	509	printf("p asn %ld %ld\n", NODES, arcs);
alpar@6	510	for (i = 0; i < NODES; i++) {
alpar@6	511	if (B[i] > 0)
alpar@6	512	printf("n %ld\n", i + 1);
alpar@6	513	}
alpar@6	514	for (i = 0; i < arcs; i++) {
alpar@6	515	printf("a %ld %ld %ld\n", FROM[i], TO[i], C[i]);
alpar@6	516	}
alpar@6	517	} else
alpar@6	518	if (MINCOST == 1 && MAXCOST == 1) {
alpar@6	519	printf("c\n");
alpar@6	520	printf("c * Maximum flow *\n");
alpar@6	521	printf("c\n");
alpar@6	522	printf("p max %ld %ld\n", NODES, arcs);
alpar@6	523	for (i = 0; i < NODES; i++) {
alpar@6	524	if (B[i] > 0)
alpar@6	525	printf("n %ld s\n", i + 1);
alpar@6	526	else
alpar@6	527	if (B[i] < 0)
alpar@6	528	printf("n %ld t\n", i + 1);
alpar@6	529	}
alpar@6	530	for (i = 0; i < arcs; i++) {
alpar@6	531	printf("a %ld %ld %ld\n", FROM[i], TO[i], U[i]);
alpar@6	532	}
alpar@6	533	} else {
alpar@6	534	printf("c\n");
alpar@6	535	printf("c * Minimum cost flow *\n");
alpar@6	536	printf("c\n");
alpar@6	537	printf("p min %ld %ld\n", NODES, arcs);
alpar@6	538	for (i = 0; i < NODES; i++) {
alpar@6	539	if (B[i] != 0)
alpar@6	540	printf("n %ld %ld\n", i + 1, B[i]);
alpar@6	541	}
alpar@6	542	for (i = 0; i < arcs; i++) {
alpar@6	543	printf("a %ld %ld %ld %ld %ld\n", FROM[i], TO[i], 0, U[i], C[i]);
alpar@6	544	}
alpar@6	545	}
alpar@6	546	}
alpar@6	547	return 0;
alpar@6	548	}
alpar@6	549
alpar@6	550	#endif

author	Alpar Juttner <alpar@cs.elte.hu>
	Sun, 11 Dec 2011 06:53:16 +0100
changeset 8	3c30bd0f9ccc
parent 6	a3ef33a8694a
permissions	-rw-r--r--