#include #include #include #include #include "random.c" #define DASH '-' #define VERY_FAR 100000000 /* generator of acyclic random networks for the shortest paths problem; extended DIMACS format for output */ main ( argc, argv ) int argc; char* argv[]; { char args[30]; long n, n0, source, i, i0, j, dij; long m, m0, mc, k; long *p, p_t, l, lx; long seed, seed1, seed2; int ext=0; FILE *fout; /* variables for lengths generating */ /* initialized by default values */ int l_f = 0, ll_f = 0, lm_f = 0, ln_f = 0, ls_f = 0; long ll = 10000, /* upper bound of the interval */ lm = 0; /* lower bound of the interval */ double ln = 0, /* l += ln * |i-j| */ ls = 0; /* l += ls * |i-j|^2 */ /* variables for connecting path(s) */ int c_f = 0, cl_f = 0, ch_f = 0, c_rand = 1; long cl = 1; /* length of path arc */ long ch; /* number of arcs in the path n - by default */ /* variables for artifical source */ int s_f = 0, sl_f = 0, sm_f = 0; long sl = VERY_FAR, /* upper bound of artifical arc */ sm, /* lower bound of artifical arc */ s; /* variables for potentials */ int p_f = 0, pl_f = 0, pm_f = 0, pn_f = 0, ps_f = 0, pa_f = 0, pap_f = 0, pac_f = 0; long pl, /* upper bound of the interval */ pm; /* lower bound of the interval */ double pn = 0, /* l += ln * |i-j| */ ps = 0, /* l += ls * |i-j|^2 */ pap = 0, /* part of nodes with alternative dustribution */ pac = -1; /* multiplier for alternative distribution */ int np; /* number of parameter parsing now */ #define PRINT_ARC( i, j, length )\ {\ l = length;\ if ( p_f ) l += ( p[i] - p[j] );\ printf ("a %8ld %8ld %12ld\n", i, j, l );\ } /* parsing parameters */ if ( argc < 2 ) goto usage; np = 0; strcpy ( args, argv[1] ); if ( ( args[0] == DASH ) && ( args[1] == 'h') ) goto help; if ( argc < 4 ) goto usage; /* first parameter - number of nodes */ np = 1; if ( ( n = atoi ( argv[1] ) ) < 2 ) goto usage; /* second parameter - number of arcs */ np = 2; if ( ( m = atoi ( argv[2] ) ) < n ) goto usage; /* third parameter - seed */ np=3; if ( ( seed = atoi ( argv[3] ) ) <= 0 ) goto usage; /* other parameters */ for ( np = 4; np < argc; np ++ ) { strcpy ( args, argv[np] ); if ( args[0] != DASH ) goto usage; switch ( args[1] ) { case 'l' : /* an interval for arc length */ l_f = 1; switch ( args[2] ) { case 'l': /* length of the interval */ ll_f = 1; ll = (long) atof ( &args[3] ); break; case 'm': /* minimal bound */ lm_f = 1; lm = (long ) atof ( &args[3] ); break; case 'n': /* additional length: l*|i-j| */ ln_f = 1; ln = atof ( &args[3] ); break; case 's': /* additional length: l*|i-j|^2 */ ls_f = 1; ls = atof ( &args[3] ); break; default: /* unknown switch value */ goto usage; } break; case 'c' : /* connecting path(s) */ c_f = 1; switch ( args[2] ) { case 'l': /* length of path arc */ c_rand = 0; /* fixed arc length */ cl_f = 1; cl = (long) atof ( &args[3] ); break; case 'h': /* number of arcs in connecting path */ ch_f = 1; ch = (long) atof ( &args[3] ); if ( ch < 1 || ch > n ) goto usage; break; default: /* unknown switch value */ goto usage; } break; case 's' : /* additional source */ s_f = 1; if ( strlen ( args ) > 2 ) { switch ( args[2] ) { case 'l': /* upper bound of art. arc */ sl_f = 1; sl = (long) atof ( &args[3] ); break; case 'm': /* lower bound of art. arc */ sm_f = 1; sm = (long) atof ( &args[3] ); break; default: /* unknown switch value */ goto usage; } } break; case 'p' : /* potentials */ p_f = 1; if ( strlen ( args ) > 2 ) { switch ( args[2] ) { case 'l': /* length of the interval */ pl_f = 1; pl = (long) atof ( &args[3] ); break; case 'm': /* minimal bound */ pm_f = 1; pm = (long ) atof ( &args[3] ); break; case 'n': /* additional length: l*|i-j| */ pn_f = 1; pn = atof ( &args[3] ); break; case 's': /* additional length: l*|i-j|^2 */ ps_f = 1; ps = atof ( &args[3] ); break; case 'a': /* bipolar distribution */ pa_f = 1; switch ( args[3] ) { case 'p': /* % of alternative potentials */ pap_f = 1; pap = atof ( &args[4] ); if ( pap < 0 ) pap = 0; if ( pap > 100 ) pap = 100; pap /= 100; break; case 'c': /* multiplier */ pac_f = 1; pac = atof ( &args[4] ); break; default: /* unknown switch value */ goto usage; } break; default: /* unknown switch value */ goto usage; } } break; default : /* unknoun case */ goto usage; } } /* ----- ajusting parameters ----- */ n0 = n; m0 = m; /* length parameters */ if ( ll < lm ) { lx = ll; ll = lm; lm = lx; } /* potential parameters */ if ( p_f ) { if ( ! pl_f ) pl = ll; if ( ! pm_f ) pm = lm; if ( pl < pm ) { lx = pl; pl = pm; pm = lx; } } /* path(s) parameters */ if ( ! ch_f ) ch = n - 1; mc = n - 1; /* artifical source parameters */ if ( s_f ) { m0 += n; n0 ++ ; if ( ! sm_f ) sm = sl; if ( sl < sm ) { lx = sl; sl = sm; sm = lx; } } /*----- printing title -----*/ printf ("c acyclic network for shortest paths problem\n"); printf ("c extended DIMACS format\nc\n" ); /* name of the problem */ printf ("t ac_%ld_%ld_%ld_", n, m, seed ); if ( l_f ) printf ("%c", 'l'); if ( c_f ) printf ("%c", 'c'); if ( s_f ) printf ("%c", 's'); if ( p_f ) printf ("%c", 'p'); printf ("\nc\n"); /* printing additional information */ if ( l_f ) printf ("c length -> min: %ld max: %ld k1: %.2f k2: %.2f\n", lm, ll, ln, ls ); if ( c_f ) printf ("c path(s) -> number of arcs: %ld arc length: %ld\n", ch, cl ); if ( s_f ) printf ("c length of arcs from artifical source -> min: %ld max: %ld\n", sm, sl ); if ( p_f ) { printf ("c potentials -> min: %ld max: %ld k1: %.2f k2: %.2f\n", pm, pl, pn, ps ); if ( pa_f ) printf ("c potentials -> part of alternative distribution: %.2f k: %.2f\n", pap, pac ); } printf ("c\n" ); printf ("p sp %8ld %8ld\nc\n", n0, m0 ); source = ( s_f ) ? n0 : 1; printf ("n %8ld\nc\n", source ); if ( p_f ) /* generating potentials */ { seed1 = 2*seed + 1; p = (long*) calloc ( n+2, sizeof (long) ); init_rand ( seed1); pl = pl - pm + 1; for ( i = 0; i <= n; i ++ ) { p_t = pm + nrand ( pl ); if ( pn_f ) p_t += (long) ( i * pn ); if ( ps_f ) p_t += (long) ( i * ( i * ps )); if ( pap_f ) if ( rand01() < pap ) p_t = (long) ( p_t * pac ); p[i] = p_t; } p[n+1] = 0; } if ( s_f ) /* additional arcs from artifical source */ { seed2 = 3*seed + 1; init_rand ( seed2 ); sl = sl - sm + 1; for ( i = n; i > 1; i -- ) { s = sm + nrand ( sl ); PRINT_ARC ( n0, i, s ) } PRINT_ARC ( n0, 1, 0 ) } /* initialize random number generator */ init_rand ( seed ); ll = ll - lm + 1; /* generating connecting path(s) */ for ( i = 1; i < n; i ++ ) { if ( ( (i-1) % ch ) != 0 ) i0 = i; else i0 = 1; if (c_rand) cl = lm + nrand(ll); PRINT_ARC ( i0, i+1, cl ) } /* generating random arcs */ for ( k = 1; k <= m - mc; k ++ ) { i = 1 + nrand ( n ); do j = 1 + nrand ( n ); while ( j == i ); if ( i > j ) { i0 = i; i = j; j = i0; } dij = j - i; l = lm + nrand ( ll ); if ( ln_f ) l += (long) ( dij * ln ); if ( ls_f ) l += (long) ( dij * ( dij * ls ) ); PRINT_ARC ( i, j, l ); } /* all is done */ exit (ext); /* ----- wrong usage ----- */ usage: fprintf ( stderr, "\nusage: %s n m seed [ -ll#i -lm#i -cl#i -p -pl#i -pm#i ... ]\n\ help: %s -h\n\n", argv[0], argv[0] ); if ( np > 0 ) fprintf ( stderr, "error in parameter # %d\n\n", np ); exit (4); /* ---- help ---- */ help: if ( args[2] == 'h') goto hhelp; fprintf ( stderr, "\n'%s' - acyclic network generator for shortest paths problem.\n\ Generates problems in extended DIMACS format.\n\ \n\ %s n m seed [ -ll#i -lm#i -cl#i -p -pl#i -pm#i ... ]\n\ %s -hh\n\ \n\ #i - integer number #f - real number\n\ \n\ -ll#i - #i is the upper bound on arc lengths (default 10000)\n\ -lm#i - #i is the lower bound on arc lengths (default 0)\n\ -cl#i - #i is length of arcs in connecting path(s) (default random)\n\ -p - generate potentials \n\ -pl#i - #i is the upper bound on potentials (default ll)\n\ -pm#i - #i is the lower bound on potentials (default lm)\n\ \n\ -hh - extended help \n\n", argv[0], argv[0], argv[0] ); exit (0); /* --------- sophisticated help ------------ */ hhelp: if ( argc < 3 ) fout = stderr; else fout = fopen ( argv[2], "w" ); if ( fout == NULL ) { fprintf ( stderr, "\nCan't open file '%s' for writing help\n\n", argv[2] ); exit ( 2 ); } fprintf (fout, "\n'%s' - acyclic network generator for shortest paths problem.\n\ Generates problems in extended DIMACS format.\n\ \n\ %s n m seed [ -ll#i -lm#i -ln#f -ls#f\n\ -p -pl#i -pm#i -pn#f -ps#f -pap#i -pac#f\n\ -cl#i -ch#i\n\ -s -sl#i -sm#i\n\ ]\n\ %s -hh file_name\n\ \n\ #i - integer number #f - real number\n\ \n\ Arc length parameters:\n\ -ll#i - #i is the upper bound on arc lengths (default 10000)\n\ -lm#i - #i is the lower bound on arc lengths (default 0)\n\ -ln#f - multipliy l(i, j) by #f * |i-j| (default 0)\n\ -ls#f - multipliy l(i, j) by #f * |i-j|^2 (default 0)\n\ \n\ Potential parameters:\n\ -p - generate potentials \n\ -pl#i - #i is the upper bound on potentials (default ll)\n\ -pm#i - #i is the lower bound on potentials (default lm)\n\ -pn#f - multiply p(i) by #f * i (default 0)\n\ -ps#f - multiply p(i) by #f * i^2 (default 0)\n\ -pap#i - percentage of alternative potential nodes (default 0)\n\ -pac#f - if i is alternative, multiply p(i) by #f (default -1)\n\ \n\ Connecting path(s) parameters:\n\ -cl#i - #i is length of arcs in connecting path(s) (default random)\n\ -ch#i - #i is length of connecting path(s) (default n-1)\n\ \n\ Artificial source parameters:\n\ -s - generate artificial source with default connecting arc lengths\n\ -sl#i - #i is the upper bound on art. arc lengths (default 100000000)\n\ -sm#i - #i is the lower bound on art. arc lengths (default sl)\n\ \n\ -hh file_name - save this help in the file 'file_name'\n\n", argv[0], argv[0], argv[0] ); exit (0); }