1 /* 2 * Copyright (c) 1980, 1993 3 * The Regents of the University of California. All rights reserved. 4 * 5 * %sccs.include.redist.c% 6 */ 7 8 #ifndef lint 9 static char sccsid[] = "@(#)computer.c 8.1 (Berkeley) 05/31/93"; 10 #endif /* not lint */ 11 12 # include "trek.h" 13 # include "getpar.h" 14 # include <stdio.h> 15 /* 16 ** On-Board Computer 17 ** 18 ** A computer request is fetched from the captain. The requests 19 ** are: 20 ** 21 ** chart -- print a star chart of the known galaxy. This includes 22 ** every quadrant that has ever had a long range or 23 ** a short range scan done of it, plus the location of 24 ** all starbases. This is of course updated by any sub- 25 ** space radio broadcasts (unless the radio is out). 26 ** The format is the same as that of a long range scan 27 ** except that ".1." indicates that a starbase exists 28 ** but we know nothing else. 29 ** 30 ** trajectory -- gives the course and distance to every know 31 ** Klingon in the quadrant. Obviously this fails if the 32 ** short range scanners are out. 33 ** 34 ** course -- gives a course computation from whereever you are 35 ** to any specified location. If the course begins 36 ** with a slash, the current quadrant is taken. 37 ** Otherwise the input is quadrant and sector coordi- 38 ** nates of the target sector. 39 ** 40 ** move -- identical to course, except that the move is performed. 41 ** 42 ** score -- prints out the current score. 43 ** 44 ** pheff -- "PHaser EFFectiveness" at a given distance. Tells 45 ** you how much stuff you need to make it work. 46 ** 47 ** warpcost -- Gives you the cost in time and units to move for 48 ** a given distance under a given warp speed. 49 ** 50 ** impcost -- Same for the impulse engines. 51 ** 52 ** distresslist -- Gives a list of the currently known starsystems 53 ** or starbases which are distressed, together with their 54 ** quadrant coordinates. 55 ** 56 ** If a command is terminated with a semicolon, you remain in 57 ** the computer; otherwise, you escape immediately to the main 58 ** command processor. 59 */ 60 61 struct cvntab Cputab[] = 62 { 63 "ch", "art", (int (*)())1, 0, 64 "t", "rajectory", (int (*)())2, 0, 65 "c", "ourse", (int (*)())3, 0, 66 "m", "ove", (int (*)())3, 1, 67 "s", "core", (int (*)())4, 0, 68 "p", "heff", (int (*)())5, 0, 69 "w", "arpcost", (int (*)())6, 0, 70 "i", "mpcost", (int (*)())7, 0, 71 "d", "istresslist", (int (*)())8, 0, 72 0 73 }; 74 75 computer() 76 { 77 int ix, iy; 78 register int i, j; 79 int numout; 80 int tqx, tqy; 81 struct cvntab *r; 82 int cost; 83 int course; 84 double dist, time; 85 double warpfact; 86 struct quad *q; 87 register struct event *e; 88 89 if (check_out(COMPUTER)) 90 return; 91 while (1) 92 { 93 r = getcodpar("\nRequest", Cputab); 94 switch ((int)r->value) 95 { 96 97 case 1: /* star chart */ 98 printf("Computer record of galaxy for all long range sensor scans\n\n"); 99 printf(" "); 100 /* print top header */ 101 for (i = 0; i < NQUADS; i++) 102 printf("-%d- ", i); 103 printf("\n"); 104 for (i = 0; i < NQUADS; i++) 105 { 106 printf("%d ", i); 107 for (j = 0; j < NQUADS; j++) 108 { 109 if (i == Ship.quadx && j == Ship.quady) 110 { 111 printf("$$$ "); 112 continue; 113 } 114 q = &Quad[i][j]; 115 /* 1000 or 1001 is special case */ 116 if (q->scanned >= 1000) 117 if (q->scanned > 1000) 118 printf(".1. "); 119 else 120 printf("/// "); 121 else 122 if (q->scanned < 0) 123 printf("... "); 124 else 125 printf("%3d ", q->scanned); 126 } 127 printf("%d\n", i); 128 } 129 printf(" "); 130 /* print bottom footer */ 131 for (i = 0; i < NQUADS; i++) 132 printf("-%d- ", i); 133 printf("\n"); 134 break; 135 136 case 2: /* trajectory */ 137 if (check_out(SRSCAN)) 138 { 139 break; 140 } 141 if (Etc.nkling <= 0) 142 { 143 printf("No Klingons in this quadrant\n"); 144 break; 145 } 146 /* for each Klingon, give the course & distance */ 147 for (i = 0; i < Etc.nkling; i++) 148 { 149 printf("Klingon at %d,%d", Etc.klingon[i].x, Etc.klingon[i].y); 150 course = kalc(Ship.quadx, Ship.quady, Etc.klingon[i].x, Etc.klingon[i].y, &dist); 151 prkalc(course, dist); 152 } 153 break; 154 155 case 3: /* course calculation */ 156 if (readdelim('/')) 157 { 158 tqx = Ship.quadx; 159 tqy = Ship.quady; 160 } 161 else 162 { 163 ix = getintpar("Quadrant"); 164 if (ix < 0 || ix >= NSECTS) 165 break; 166 iy = getintpar("q-y"); 167 if (iy < 0 || iy >= NSECTS) 168 break; 169 tqx = ix; 170 tqy = iy; 171 } 172 ix = getintpar("Sector"); 173 if (ix < 0 || ix >= NSECTS) 174 break; 175 iy = getintpar("s-y"); 176 if (iy < 0 || iy >= NSECTS) 177 break; 178 course = kalc(tqx, tqy, ix, iy, &dist); 179 if (r->value2) 180 { 181 warp(-1, course, dist); 182 break; 183 } 184 printf("%d,%d/%d,%d to %d,%d/%d,%d", 185 Ship.quadx, Ship.quady, Ship.sectx, Ship.secty, tqx, tqy, ix, iy); 186 prkalc(course, dist); 187 break; 188 189 case 4: /* score */ 190 score(); 191 break; 192 193 case 5: /* phaser effectiveness */ 194 dist = getfltpar("range"); 195 if (dist < 0.0) 196 break; 197 dist *= 10.0; 198 cost = pow(0.90, dist) * 98.0 + 0.5; 199 printf("Phasers are %d%% effective at that range\n", cost); 200 break; 201 202 case 6: /* warp cost (time/energy) */ 203 dist = getfltpar("distance"); 204 if (dist < 0.0) 205 break; 206 warpfact = getfltpar("warp factor"); 207 if (warpfact <= 0.0) 208 warpfact = Ship.warp; 209 cost = (dist + 0.05) * warpfact * warpfact * warpfact; 210 time = Param.warptime * dist / (warpfact * warpfact); 211 printf("Warp %.2f distance %.2f cost %.2f stardates %d (%d w/ shlds up) units\n", 212 warpfact, dist, time, cost, cost + cost); 213 break; 214 215 case 7: /* impulse cost */ 216 dist = getfltpar("distance"); 217 if (dist < 0.0) 218 break; 219 cost = 20 + 100 * dist; 220 time = dist / 0.095; 221 printf("Distance %.2f cost %.2f stardates %d units\n", 222 dist, time, cost); 223 break; 224 225 case 8: /* distresslist */ 226 j = 1; 227 printf("\n"); 228 /* scan the event list */ 229 for (i = 0; i < MAXEVENTS; i++) 230 { 231 e = &Event[i]; 232 /* ignore hidden entries */ 233 if (e->evcode & E_HIDDEN) 234 continue; 235 switch (e->evcode & E_EVENT) 236 { 237 238 case E_KDESB: 239 printf("Klingon is attacking starbase in quadrant %d,%d\n", 240 e->x, e->y); 241 j = 0; 242 break; 243 244 case E_ENSLV: 245 case E_REPRO: 246 printf("Starsystem %s in quadrant %d,%d is distressed\n", 247 Systemname[e->systemname], e->x, e->y); 248 j = 0; 249 break; 250 } 251 } 252 if (j) 253 printf("No known distress calls are active\n"); 254 break; 255 256 } 257 258 /* skip to next semicolon or newline. Semicolon 259 * means get new computer request; newline means 260 * exit computer mode. */ 261 while ((i = cgetc(0)) != ';') 262 { 263 if (i == '\0') 264 exit(1); 265 if (i == '\n') 266 { 267 ungetc(i, stdin); 268 return; 269 } 270 } 271 } 272 } 273 274 275 /* 276 ** Course Calculation 277 ** 278 ** Computes and outputs the course and distance from position 279 ** sqx,sqy/ssx,ssy to tqx,tqy/tsx,tsy. 280 */ 281 282 kalc(tqx, tqy, tsx, tsy, dist) 283 int tqx; 284 int tqy; 285 int tsx; 286 int tsy; 287 double *dist; 288 { 289 double dx, dy; 290 double quadsize; 291 double angle; 292 register int course; 293 294 /* normalize to quadrant distances */ 295 quadsize = NSECTS; 296 dx = (Ship.quadx + Ship.sectx / quadsize) - (tqx + tsx / quadsize); 297 dy = (tqy + tsy / quadsize) - (Ship.quady + Ship.secty / quadsize); 298 299 /* get the angle */ 300 angle = atan2(dy, dx); 301 /* make it 0 -> 2 pi */ 302 if (angle < 0.0) 303 angle += 6.283185307; 304 /* convert from radians to degrees */ 305 course = angle * 57.29577951 + 0.5; 306 dx = dx * dx + dy * dy; 307 *dist = sqrt(dx); 308 return (course); 309 } 310 311 312 prkalc(course, dist) 313 int course; 314 double dist; 315 { 316 printf(": course %d dist %.3f\n", course, dist); 317 } 318