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[/] [ion/] [trunk/] [src/] [adventure/] [misc.c] - Blame information for rev 190

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1 90 ja_rd 
#include "main.h"
2 
#include "misc.h"
3 
#include <stdio.h>
4 
 
5 
#include "adv_baremetal.h"
6 
 
7 
#define TRUE  (0==0)
8 
#define FALSE (0!=0)
9 
 
10 
/*  I/O ROUTINES (SPEAK, PSPEAK, RSPEAK, SETPRM, GETIN, YES) */
11 
 
12 
#undef SPEAK
13 
void fSPEAK(N)long N; {
14 
long BLANK, CASE, I, K, L, NEG, NPARMS, PARM, PRMTYP, STATE;
15 
 
16 
/*  PRINT THE MESSAGE WHICH STARTS AT LINES(N).  PRECEDE IT WITH A BLANK LINE
17 
 *  UNLESS BLKLIN IS FALSE. */
18 
 
19 
 
20 
        if(N == 0)return;
21 
        BLANK=BLKLIN;
22 
        K=N;
23 
        NPARMS=1;
24 
L10:    L=IABS(LINES[K])-1;
25 
        K=K+1;
26 
        LNLENG=0;
27 
        LNPOSN=1;
28 
        STATE=0;
29 
        /* 20 */ for (I=K; I<=L; I++) {
30 
L20:    PUTTXT(LINES[I],STATE,2,I);
31 
        } /* end loop */
32 
        LNPOSN=0;
33 
L30:    LNPOSN=LNPOSN+1;
34 
L32:    if(LNPOSN > LNLENG) goto L40;
35 
        if(INLINE[LNPOSN] != 63) goto L30;
36 
        {long x = LNPOSN+1; PRMTYP=INLINE[x];}
37 
/*  63 IS A "%"; THE NEXT CHARACTER DETERMINE THE TYPE OF PARAMETER:  1 (!) =
38 
 *  SUPPRESS MESSAGE COMPLETELY, 29 (S) = NULL IF PARM=1, ELSE 'S' (OPTIONAL
39 
 *  PLURAL ENDING), 33 (W) = WORD (TWO 30-BIT VALUES) WITH TRAILING SPACES
40 
 *  SUPPRESSED, 22 (L) OR 31 (U) = WORD BUT MAP TO LOWER/UPPER CASE, 13 (C) =
41 
 *  WORD IN LOWER CASE WITH FIRST LETTER CAPITALISED, 30 (T) = TEXT ENDING
42 
 *  WITH A WORD OF -1, 65-73 (1-9) = NUMBER USING THAT MANY CHARACTERS,
43 
 *  12 (B) = VARIABLE NUMBER OF BLANKS. */
44 
        if(PRMTYP == 1)return;
45 
        if(PRMTYP == 29) goto L320;
46 
        if(PRMTYP == 30) goto L340;
47 
        if(PRMTYP == 12) goto L360;
48 
        if(PRMTYP == 33 || PRMTYP == 22 || PRMTYP == 31 || PRMTYP == 13) goto
49 
                L380;
50 
        PRMTYP=PRMTYP-64;
51 
        if(PRMTYP < 1 || PRMTYP > 9) goto L30;
52 
        SHFTXT(LNPOSN+2,PRMTYP-2);
53 
        LNPOSN=LNPOSN+PRMTYP;
54 
        PARM=IABS(PARMS[NPARMS]);
55 
        NEG=0;
56 
        if(PARMS[NPARMS] < 0)NEG=9;
57 
        /* 390 */ for (I=1; I<=PRMTYP; I++) {
58 
        LNPOSN=LNPOSN-1;
59 
        INLINE[LNPOSN]=MOD(PARM,10)+64;
60 
        if(I == 1 || PARM != 0) goto L390;
61 
        INLINE[LNPOSN]=NEG;
62 
        NEG=0;
63 
L390:   PARM=PARM/10;
64 
        } /* end loop */
65 
        LNPOSN=LNPOSN+PRMTYP;
66 
L395:   NPARMS=NPARMS+1;
67 
         goto L32;
68 
 
69 
L320:   SHFTXT(LNPOSN+2,-1);
70 
        INLINE[LNPOSN]=55;
71 
        if(PARMS[NPARMS] == 1)SHFTXT(LNPOSN+1,-1);
72 
         goto L395;
73 
 
74 
L340:   SHFTXT(LNPOSN+2,-2);
75 
        STATE=0;
76 
        CASE=2;
77 
L345:   if(PARMS[NPARMS] < 0) goto L395;
78 
        {long x = NPARMS+1; if(PARMS[x] < 0)CASE=0;}
79 
        PUTTXT(PARMS[NPARMS],STATE,CASE,0);
80 
        NPARMS=NPARMS+1;
81 
         goto L345;
82 
 
83 
L360:   PRMTYP=PARMS[NPARMS];
84 
        SHFTXT(LNPOSN+2,PRMTYP-2);
85 
        if(PRMTYP == 0) goto L395;
86 
        /* 365 */ for (I=1; I<=PRMTYP; I++) {
87 
        INLINE[LNPOSN]=0;
88 
L365:   LNPOSN=LNPOSN+1;
89 
        } /* end loop */
90 
         goto L395;
91 
 
92 
L380:   SHFTXT(LNPOSN+2,-2);
93 
        STATE=0;
94 
        CASE= -1;
95 
        if(PRMTYP == 31)CASE=1;
96 
        if(PRMTYP == 33)CASE=0;
97 
        I=LNPOSN;
98 
        PUTTXT(PARMS[NPARMS],STATE,CASE,0);
99 
        {long x = NPARMS+1; PUTTXT(PARMS[x],STATE,CASE,0);}
100 
        if(PRMTYP == 13 && INLINE[I] >= 37 && INLINE[I] <=
101 
                62)INLINE[I]=INLINE[I]-26;
102 
        NPARMS=NPARMS+2;
103 
         goto L32;
104 
 
105 
L40:    if(BLANK)TYPE0();
106 
        BLANK=FALSE;
107 
        TYPE();
108 
        K=L+1;
109 
        if(LINES[K] >= 0) goto L10;
110 
        return;
111 
}
112 
 
113 
 
114 
 
115 
#define SPEAK(N) fSPEAK(N)
116 
#undef PSPEAK
117 
void fPSPEAK(MSG,SKIP)long MSG, SKIP; {
118 
long I, M;
119 
 
120 
/*  FIND THE SKIP+1ST MESSAGE FROM MSG AND PRINT IT.  MSG SHOULD BE THE INDEX OF
121 
 *  THE INVENTORY MESSAGE FOR OBJECT.  (INVEN+N+1 MESSAGE IS PROP=N MESSAGE). */
122 
 
123 
 
124 
        M=PTEXT[MSG];
125 
        if(SKIP < 0) goto L9;
126 
        /* 3 */ for (I=0; I<=SKIP; I++) {
127 
L1:     M=IABS(LINES[M]);
128 
        if(LINES[M] >= 0) goto L1;
129 
L3:     /*etc*/ ;
130 
        } /* end loop */
131 
L9:     SPEAK(M);
132 
        return;
133 
}
134 
 
135 
 
136 
 
137 
#define PSPEAK(MSG,SKIP) fPSPEAK(MSG,SKIP)
138 
#undef RSPEAK
139 
void fRSPEAK(I)long I; {
140 
;
141 
 
142 
/*  PRINT THE I-TH "RANDOM" MESSAGE (SECTION 6 OF DATABASE). */
143 
 
144 
 
145 
        if(I != 0)SPEAK(RTEXT[I]);
146 
        return;
147 
}
148 
 
149 
 
150 
 
151 
#define RSPEAK(I) fRSPEAK(I)
152 
#undef SETPRM
153 
void fSETPRM(FIRST,P1,P2)long FIRST, P1, P2; {
154 
;
155 
 
156 
/*  STORES PARAMETERS INTO THE PRMCOM PARMS ARRAY FOR USE BY SPEAK.  P1 AND P2
157 
 *  ARE STORED INTO PARMS(FIRST) AND PARMS(FIRST+1). */
158 
 
159 
 
160 
        if(FIRST >= 25)BUG(29);
161 
        PARMS[FIRST]=P1;
162 
        {long x = FIRST+1; PARMS[x]=P2;}
163 
        return;
164 
}
165 
 
166 
 
167 
 
168 
#define SETPRM(FIRST,P1,P2) fSETPRM(FIRST,P1,P2)
169 
#undef GETIN
170 
#define WORD1 (*wORD1)
171 
#define WORD1X (*wORD1X)
172 
#define WORD2 (*wORD2)
173 
#define WORD2X (*wORD2X)
174 
void fGETIN(wORD1,wORD1X,wORD2,wORD2X)long *wORD1, *wORD1X, *wORD2, *wORD2X; {
175 
long JUNK;
176 
 
177 
/*  GET A COMMAND FROM THE ADVENTURER.  SNARF OUT THE FIRST WORD, PAD IT WITH
178 
 *  BLANKS, AND RETURN IT IN WORD1.  CHARS 6 THRU 10 ARE RETURNED IN WORD1X, IN
179 
 *  CASE WE NEED TO PRINT OUT THE WHOLE WORD IN AN ERROR MESSAGE.  ANY NUMBER OF
180 
 *  BLANKS MAY FOLLOW THE WORD.  IF A SECOND WORD APPEARS, IT IS RETURNED IN
181 
 *  WORD2 (CHARS 6 THRU 10 IN WORD2X), ELSE WORD2 IS -1. */
182 
 
183 
 
184 
L10:    if(BLKLIN)TYPE0();
185 
        MAPLIN(FALSE);
186 
        WORD1=GETTXT(TRUE,TRUE,TRUE,0);
187 
        if(BLKLIN && WORD1 < 0) goto L10;
188 
        WORD1X=GETTXT(FALSE,TRUE,TRUE,0);
189 
L12:    JUNK=GETTXT(FALSE,TRUE,TRUE,0);
190 
        if(JUNK > 0) goto L12;
191 
        WORD2=GETTXT(TRUE,TRUE,TRUE,0);
192 
        WORD2X=GETTXT(FALSE,TRUE,TRUE,0);
193 
L22:    JUNK=GETTXT(FALSE,TRUE,TRUE,0);
194 
        if(JUNK > 0) goto L22;
195 
        if(GETTXT(TRUE,TRUE,TRUE,0) <= 0)return;
196 
        RSPEAK(53);
197 
         goto L10;
198 
}
199 
 
200 
 
201 
 
202 
#undef WORD1
203 
#undef WORD1X
204 
#undef WORD2
205 
#undef WORD2X
206 
#define GETIN(WORD1,WORD1X,WORD2,WORD2X) fGETIN(&WORD1,&WORD1X,&WORD2,&WORD2X)
207 
#undef YES
208 
long fYES(X,Y,Z)long X, Y, Z; {
209 
 
210 
long YES, REPLY, JUNK1, JUNK2, JUNK3;
211 
 
212 
/*  PRINT MESSAGE X, WAIT FOR YES/NO ANSWER.  IF YES, PRINT Y AND RETURN TRUE;
213 
 *  IF NO, PRINT Z AND RETURN FALSE. */
214 
 
215 
L1:     RSPEAK(X);
216 
        GETIN(REPLY,JUNK1,JUNK2,JUNK3);
217 
        if(REPLY == MAKEWD(250519) || REPLY == MAKEWD(25)) goto L10;
218 
        if(REPLY == MAKEWD(1415) || REPLY == MAKEWD(14)) goto L20;
219 
        RSPEAK(185);
220 
         goto L1;
221 
L10:    YES=TRUE;
222 
        RSPEAK(Y);
223 
        return(YES);
224 
L20:    YES=FALSE;
225 
        RSPEAK(Z);
226 
        return(YES);
227 
}
228 
 
229 
 
230 
 
231 
 
232 
 
233 
/*  LINE-PARSING ROUTINES (GETNUM, GETTXT, MAKEWD, PUTTXT, SHFTXT, TYPE0)
234 
                */
235 
 
236 
/*  THE ROUTINES ON THIS PAGE HANDLE ALL THE STUFF THAT WOULD NORMALLY BE
237 
 *  TAKEN CARE OF BY FORMAT STATEMENTS.  WE DO IT THIS WAY INSTEAD SO THAT
238 
 *  WE CAN HANDLE TEXTUAL DATA IN A MACHINE INDEPENDENT FASHION.  ALL THE
239 
 *  MACHINE DEPENDENT I/O STUFF IS ON THE FOLLOWING PAGE.  SEE THAT PAGE
240 
 *  FOR A DESCRIPTION OF MAPCOM'S INLINE ARRAY. */
241 
 
242 
#define YES(X,Y,Z) fYES(X,Y,Z)
243 
#undef GETNUM
244 
long fGETNUM(K)long K; {
245 
long DIGIT, GETNUM, SIGN;
246 
 
247 
/*  OBTAIN THE NEXT INTEGER FROM AN INPUT LINE.  IF K>0, WE FIRST READ A
248 
 *  NEW INPUT LINE FROM A FILE; IF K<0, WE READ A LINE FROM THE KEYBOARD;
249 
 *  IF K=0 WE USE A LINE THAT HAS ALREADY BEEN READ (AND PERHAPS PARTIALLY
250 
 *  SCANNED).  IF WE'RE AT THE END OF THE LINE OR ENCOUNTER AN ILLEGAL
251 
 *  CHARACTER (NOT A DIGIT, HYPHEN, OR BLANK), WE RETURN 0. */
252 
 
253 
 
254 
        if(K != 0)MAPLIN(K > 0);
255 
        GETNUM=0;
256 
L10:    if(LNPOSN > LNLENG)return(GETNUM);
257 
        if(INLINE[LNPOSN] != 0) goto L20;
258 
        LNPOSN=LNPOSN+1;
259 
         goto L10;
260 
 
261 
L20:    SIGN=1;
262 
        if(INLINE[LNPOSN] != 9) goto L32;
263 
        SIGN= -1;
264 
L30:    LNPOSN=LNPOSN+1;
265 
L32:    if(LNPOSN > LNLENG || INLINE[LNPOSN] == 0) goto L42;
266 
        DIGIT=INLINE[LNPOSN]-64;
267 
        if(DIGIT < 0 || DIGIT > 9) goto L40;
268 
        GETNUM=GETNUM*10+DIGIT;
269 
         goto L30;
270 
 
271 
L40:    GETNUM=0;
272 
L42:    GETNUM=GETNUM*SIGN;
273 
        LNPOSN=LNPOSN+1;
274 
        return(GETNUM);
275 
}
276 
 
277 
 
278 
 
279 
#define GETNUM(K) fGETNUM(K)
280 
#undef GETTXT
281 
long fGETTXT(SKIP,ONEWRD,UPPER,HASH)long HASH, ONEWRD, SKIP, UPPER; {
282 
long CHAR, GETTXT, I; static long SPLITTING = -1;
283 
 
284 
/*  TAKE CHARACTERS FROM AN INPUT LINE AND PACK THEM INTO 30-BIT WORDS.
285 
 *  SKIP SAYS TO SKIP LEADING BLANKS.  ONEWRD SAYS STOP IF WE COME TO A
286 
 *  BLANK.  UPPER SAYS TO MAP ALL LETTERS TO UPPERCASE.  HASH MAY BE USED
287 
 *  AS A PARAMETER FOR ENCRYPTING THE TEXT IF DESIRED; HOWEVER, A HASH OF 0
288 
 *  SHOULD RESULT IN UNMODIFIED BYTES BEING PACKED.  IF WE REACH THE
289 
 *  END OF THE LINE, THE WORD IS FILLED UP WITH BLANKS (WHICH ENCODE AS 0'S).
290 
 *  IF WE'RE ALREADY AT END OF LINE WHEN GETTXT IS CALLED, WE RETURN -1. */
291 
 
292 
        if(LNPOSN != SPLITTING)SPLITTING = -1;
293 
        GETTXT= -1;
294 
L10:    if(LNPOSN > LNLENG)return(GETTXT);
295 
        if((!SKIP) || INLINE[LNPOSN] != 0) goto L11;
296 
        LNPOSN=LNPOSN+1;
297 
         goto L10;
298 
 
299 
L11:    GETTXT=0;
300 
        /* 15 */ for (I=1; I<=5; I++) {
301 
        GETTXT=GETTXT*64;
302 
        if(LNPOSN > LNLENG || (ONEWRD && INLINE[LNPOSN] == 0)) goto L15;
303 
        CHAR=INLINE[LNPOSN];
304 
        if(CHAR >= 63) goto L12;
305 
        SPLITTING = -1;
306 
        if(UPPER && CHAR >= 37)CHAR=CHAR-26;
307 
        GETTXT=GETTXT+CHAR;
308 
         goto L14;
309 
 
310 
L12:    if(SPLITTING == LNPOSN) goto L13;
311 
        GETTXT=GETTXT+63;
312 
        SPLITTING = LNPOSN;
313 
         goto L15;
314 
 
315 
L13:    GETTXT=GETTXT+CHAR-63;
316 
        SPLITTING = -1;
317 
L14:    LNPOSN=LNPOSN+1;
318 
L15:    /*etc*/ ;
319 
        } /* end loop */
320 
 
321 
        if(HASH)GETTXT=GETTXT+MOD(HASH*13579L+5432L,97531L)*12345L+HASH;
322 
        return(GETTXT);
323 
}
324 
 
325 
 
326 
 
327 
#define GETTXT(SKIP,ONEWRD,UPPER,HASH) fGETTXT(SKIP,ONEWRD,UPPER,HASH)
328 
#undef MAKEWD
329 
long fMAKEWD(LETTRS)long LETTRS; {
330 
long I, L, MAKEWD;
331 
 
332 
/*  COMBINE FIVE UPPERCASE LETTERS (REPRESENTED BY PAIRS OF DECIMAL DIGITS
333 
 *  IN LETTRS) TO FORM A 30-BIT VALUE MATCHING THE ONE THAT GETTXT WOULD
334 
 *  RETURN GIVEN THOSE CHARACTERS PLUS TRAILING BLANKS AND HASH=0.  CAUTION:
335 
 *  LETTRS WILL OVERFLOW 31 BITS IF 5-LETTER WORD STARTS WITH V-Z.  AS A
336 
 *  KLUDGEY WORKAROUND, YOU CAN INCREMENT A LETTER BY 5 BY ADDING 50 TO
337 
 *  THE NEXT PAIR OF DIGITS. */
338 
 
339 
 
340 
        MAKEWD=0;
341 
        I=1;
342 
        L=LETTRS;
343 
L10:    MAKEWD=MAKEWD+I*(MOD(L,50)+10);
344 
        I=I*64;
345 
        if(MOD(L,100) > 50)MAKEWD=MAKEWD+I*5;
346 
        L=L/100;
347 
        if(L != 0) goto L10;
348 
        I=64L*64L*64L*64L*64L/I;
349 
        MAKEWD=MAKEWD*I;
350 
        return(MAKEWD);
351 
}
352 
 
353 
 
354 
 
355 
#define MAKEWD(LETTRS) fMAKEWD(LETTRS)
356 
#undef PUTTXT
357 
#define STATE (*sTATE)
358 
void fPUTTXT(WORD,sTATE,CASE,HASH)long CASE, HASH, *sTATE, WORD; {
359 
long ALPH1, ALPH2, BYTE, DIV, I, W;
360 
 
361 
/*  UNPACK THE 30-BIT VALUE IN WORD TO OBTAIN UP TO 5 INTEGER-ENCODED CHARS,
362 
 *  AND STORE THEM IN INLINE STARTING AT LNPOSN.  IF LNLENG>=LNPOSN, SHIFT
363 
 *  EXISTING CHARACTERS TO THE RIGHT TO MAKE ROOM.  HASH MUST BE THE SAME
364 
 *  AS IT WAS WHEN GETTXT CREATED THE 30-BIT WORD.  STATE WILL BE ZERO WHEN
365 
 *  PUTTXT IS CALLED WITH THE FIRST OF A SEQUENCE OF WORDS, BUT IS THEREAFTER
366 
 *  UNCHANGED BY THE CALLER, SO PUTTXT CAN USE IT TO MAINTAIN STATE ACROSS
367 
 *  CALLS.  LNPOSN AND LNLENG ARE INCREMENTED BY THE NUMBER OF CHARS STORED.
368 
 *  IF CASE=1, ALL LETTERS ARE MADE UPPERCASE; IF -1, LOWERCASE; IF 0, AS IS.
369 
 *  ANY OTHER VALUE FOR CASE IS THE SAME AS 0 BUT ALSO CAUSES TRAILING BLANKS
370 
 *  TO BE INCLUDED (IN ANTICIPATION OF SUBSEQUENT ADDITIONAL TEXT). */
371 
 
372 
 
373 
        ALPH1=13*CASE+24;
374 
        ALPH2=26*IABS(CASE)+ALPH1;
375 
        if(IABS(CASE) > 1)ALPH1=ALPH2;
376 
/*  ALPH1&2 DEFINE RANGE OF WRONG-CASE CHARS, 11-36 OR 37-62 OR EMPTY. */
377 
        DIV=64L*64L*64L*64L;
378 
        W=WORD;
379 
        if(HASH)W=W-MOD(HASH*13579L+5432L,97531L)*12345L-HASH;
380 
        /* 18 */ for (I=1; I<=5; I++) {
381 
        if(W <= 0 && STATE == 0 && IABS(CASE) <= 1)return;
382 
        BYTE=W/DIV;
383 
        if(STATE != 0 || BYTE != 63) goto L12;
384 
        STATE=63;
385 
         goto L18;
386 
 
387 
L12:    SHFTXT(LNPOSN,1);
388 
        STATE=STATE+BYTE;
389 
        if(STATE < ALPH2 && STATE >= ALPH1)STATE=STATE-26*CASE;
390 
        INLINE[LNPOSN]=STATE;
391 
        LNPOSN=LNPOSN+1;
392 
        STATE=0;
393 
L18:    W=(W-BYTE*DIV)*64;
394 
        } /* end loop */
395 
        return;
396 
}
397 
 
398 
 
399 
 
400 
#undef STATE
401 
#define PUTTXT(WORD,STATE,CASE,HASH) fPUTTXT(WORD,&STATE,CASE,HASH)
402 
#undef SHFTXT
403 
void fSHFTXT(FROM,DELTA)long DELTA, FROM; {
404 
long I, II, JJ;
405 
 
406 
/*  MOVE INLINE(N) TO INLINE(N+DELTA) FOR N=FROM,LNLENG.  DELTA CAN BE
407 
 *  NEGATIVE.  LNLENG IS UPDATED; LNPOSN IS NOT CHANGED. */
408 
 
409 
 
410 
        if(LNLENG < FROM || DELTA == 0) goto L2;
411 
        /* 1 */ for (I=FROM; I<=LNLENG; I++) {
412 
        II=I;
413 
        if(DELTA > 0)II=FROM+LNLENG-I;
414 
        JJ=II+DELTA;
415 
L1:     INLINE[JJ]=INLINE[II];
416 
        } /* end loop */
417 
L2:     LNLENG=LNLENG+DELTA;
418 
        return;
419 
}
420 
 
421 
 
422 
 
423 
#define SHFTXT(FROM,DELTA) fSHFTXT(FROM,DELTA)
424 
#undef TYPE0
425 
void fTYPE0() {
426 
long TEMP;
427 
 
428 
/*  TYPE A BLANK LINE.  THIS PROCEDURE IS PROVIDED AS A CONVENIENCE FOR CALLERS
429 
 *  WHO OTHERWISE HAVE NO USE FOR MAPCOM. */
430 
 
431 
 
432 
        TEMP=LNLENG;
433 
        LNLENG=0;
434 
        TYPE();
435 
        LNLENG=TEMP;
436 
        return;
437 
}
438 
 
439 
 
440 
 
441 
#define TYPE0() fTYPE0()
442 
 
443 
 
444 
/*  SUSPEND/RESUME I/O ROUTINES (SAVWDS, SAVARR, SAVWRD) */
445 
 
446 
#undef SAVWDS
447 
void fSAVWDS(W1,W2,W3,W4,W5,W6,W7)long *W1, *W2, *W3, *W4, *W5, *W6, *W7; {
448 
;
449 
 
450 
/*  WRITE OR READ 7 VARIABLES.  SEE SAVWRD. */
451 
 
452 
 
453 
        SAVWRD(0,(*W1));
454 
        SAVWRD(0,(*W2));
455 
        SAVWRD(0,(*W3));
456 
        SAVWRD(0,(*W4));
457 
        SAVWRD(0,(*W5));
458 
        SAVWRD(0,(*W6));
459 
        SAVWRD(0,(*W7));
460 
        return;
461 
}
462 
 
463 
 
464 
#define SAVWDS(W1,W2,W3,W4,W5,W6,W7) fSAVWDS(&W1,&W2,&W3,&W4,&W5,&W6,&W7)
465 
#undef SAVARR
466 
void fSAVARR(ARR,N)long ARR[], N; {
467 
long I;
468 
 
469 
/*  WRITE OR READ AN ARRAY OF N WORDS.  SEE SAVWRD. */
470 
 
471 
 
472 
        /* 1 */ for (I=1; I<=N; I++) {
473 
L1:     SAVWRD(0,ARR[I]);
474 
        } /* end loop */
475 
        return;
476 
}
477 
 
478 
 
479 
 
480 
#define SAVARR(ARR,N) fSAVARR(ARR,N)
481 
#undef SAVWRD
482 
#define WORD (*wORD)
483 
void fSAVWRD(OP,wORD)long OP, *wORD; {
484 
static long BUF[250], CKSUM = 0, H1, HASH = 0, N = 0, STATE = 0;
485 
 
486 
/*  IF OP<0, START WRITING A FILE, USING WORD TO INITIALISE ENCRYPTION; SAVE
487 
 *  WORD IN THE FILE.  IF OP>0, START READING A FILE; READ THE FILE TO FIND
488 
 *  THE VALUE WITH WHICH TO DECRYPT THE REST.  IN EITHER CASE, IF A FILE IS
489 
 *  ALREADY OPEN, FINISH WRITING/READING IT AND DON'T START A NEW ONE.  IF OP=0,
490 
 *  READ/WRITE A SINGLE WORD.  WORDS ARE BUFFERED IN CASE THAT MAKES FOR MORE
491 
 *  EFFICIENT DISK USE.  WE ALSO COMPUTE A SIMPLE CHECKSUM TO CATCH ELEMENTARY
492 
 *  POKING WITHIN THE SAVED FILE.  WHEN WE FINISH READING/WRITING THE FILE,
493 
 *  WE STORE ZERO INTO WORD IF THERE'S NO CHECKSUM ERROR, ELSE NONZERO. */
494 
 
495 
 
496 
        if(OP != 0){long ifvar; ifvar=(STATE); switch (ifvar<0? -1 : ifvar>0? 1 :
497 
                0) { case -1: goto L30; case 0: goto L10; case 1: goto L30; }}
498 
        if(STATE == 0)return;
499 
        if(N == 250)SAVEIO(1,STATE > 0,BUF);
500 
        N=MOD(N,250)+1;
501 
        H1=MOD(HASH*1093L+221573L,1048576L);
502 
        HASH=MOD(H1*1093L+221573L,1048576L);
503 
        H1=MOD(H1,1234)*765432+MOD(HASH,123);
504 
        N--;
505 
        if(STATE > 0)WORD=BUF[N]+H1;
506 
        BUF[N]=WORD-H1;
507 
        N++;
508 
        CKSUM=MOD(CKSUM*13+WORD,1000000000L);
509 
        return;
510 
 
511 
L10:    STATE=OP;
512 
        SAVEIO(0,STATE > 0,BUF);
513 
        N=1;
514 
        if(STATE > 0) goto L15;
515 
        HASH=MOD(WORD,1048576L);
516 
        BUF[0]=1234L*5678L-HASH;
517 
L13:    CKSUM=BUF[0];
518 
        return;
519 
 
520 
L15:    SAVEIO(1,TRUE,BUF);
521 
        HASH=MOD(1234L*5678L-BUF[0],1048576L);
522 
         goto L13;
523 
 
524 
L30:    if(N == 250)SAVEIO(1,STATE > 0,BUF);
525 
        N=MOD(N,250)+1;
526 
        if(STATE > 0) goto L32;
527 
        N--; BUF[N]=CKSUM; N++;
528 
        SAVEIO(1,FALSE,BUF);
529 
L32:    N--; WORD=BUF[N]-CKSUM; N++;
530 
        SAVEIO(-1,STATE > 0,BUF);
531 
        STATE=0;
532 
        return;
533 
}
534 
 
535 
 
536 
 
537 
 
538 
 
539 
/*  DATA STRUC. ROUTINES (VOCAB, DSTROY, JUGGLE, MOVE, PUT, CARRY, DROP, ATDWRF)
540 
                */
541 
 
542 
#undef WORD
543 
#define SAVWRD(OP,WORD) fSAVWRD(OP,&WORD)
544 
#undef VOCAB
545 
long fVOCAB(ID,INIT)long ID, INIT; {
546 
long HASH, I, VOCAB;
547 
 
548 
/*  LOOK UP ID IN THE VOCABULARY (ATAB) AND RETURN ITS "DEFINITION" (KTAB), OR
549 
 *  -1 IF NOT FOUND.  IF INIT IS POSITIVE, THIS IS AN INITIALISATION CALL SETTING
550 
 *  UP A KEYWORD VARIABLE, AND NOT FINDING IT CONSTITUTES A BUG.  IT ALSO MEANS
551 
 *  THAT ONLY KTAB VALUES WHICH TAKEN OVER 1000 EQUAL INIT MAY BE CONSIDERED.
552 
 *  (THUS "STEPS", WHICH IS A MOTION VERB AS WELL AS AN OBJECT, MAY BE LOCATED
553 
 *  AS AN OBJECT.)  AND IT ALSO MEANS THE KTAB VALUE IS TAKEN MOD 1000. */
554 
 
555 
        HASH=10000;
556 
        /* 1 */ for (I=1; I<=TABSIZ; I++) {
557 
        if(KTAB[I] == -1) goto L2;
558 
        HASH=HASH+7;
559 
        if(INIT >= 0 && KTAB[I]/1000 != INIT) goto L1;
560 
        if(ATAB[I] == ID+HASH*HASH) goto L3;
561 
L1:     /*etc*/ ;
562 
        } /* end loop */
563 
        BUG(21);
564 
 
565 
L2:     VOCAB= -1;
566 
        if(INIT < 0)return(VOCAB);
567 
        BUG(5);
568 
 
569 
L3:     VOCAB=KTAB[I];
570 
        if(INIT >= 0)VOCAB=MOD(VOCAB,1000);
571 
        return(VOCAB);
572 
}
573 
 
574 
 
575 
 
576 
#define VOCAB(ID,INIT) fVOCAB(ID,INIT)
577 
#undef DSTROY
578 
void fDSTROY(OBJECT)long OBJECT; {
579 
;
580 
 
581 
/*  PERMANENTLY ELIMINATE "OBJECT" BY MOVING TO A NON-EXISTENT LOCATION. */
582 
 
583 
 
584 
        MOVE(OBJECT,0);
585 
        return;
586 
}
587 
 
588 
 
589 
 
590 
#define DSTROY(OBJECT) fDSTROY(OBJECT)
591 
#undef JUGGLE
592 
void fJUGGLE(OBJECT)long OBJECT; {
593 
long I, J;
594 
 
595 
/*  JUGGLE AN OBJECT BY PICKING IT UP AND PUTTING IT DOWN AGAIN, THE PURPOSE
596 
 *  BEING TO GET THE OBJECT TO THE FRONT OF THE CHAIN OF THINGS AT ITS LOC. */
597 
 
598 
 
599 
        I=PLACE[OBJECT];
600 
        J=FIXED[OBJECT];
601 
        MOVE(OBJECT,I);
602 
        MOVE(OBJECT+100,J);
603 
        return;
604 
}
605 
 
606 
 
607 
 
608 
#define JUGGLE(OBJECT) fJUGGLE(OBJECT)
609 
#undef MOVE
610 
void fMOVE(OBJECT,WHERE)long OBJECT, WHERE; {
611 
long FROM;
612 
 
613 
/*  PLACE ANY OBJECT ANYWHERE BY PICKING IT UP AND DROPPING IT.  MAY ALREADY BE
614 
 *  TOTING, IN WHICH CASE THE CARRY IS A NO-OP.  MUSTN'T PICK UP OBJECTS WHICH
615 
 *  ARE NOT AT ANY LOC, SINCE CARRY WANTS TO REMOVE OBJECTS FROM ATLOC CHAINS. */
616 
 
617 
 
618 
        if(OBJECT > 100) goto L1;
619 
        FROM=PLACE[OBJECT];
620 
         goto L2;
621 
L1:     {long x = OBJECT-100; FROM=FIXED[x];}
622 
L2:     if(FROM > 0 && FROM <= 300)CARRY(OBJECT,FROM);
623 
        DROP(OBJECT,WHERE);
624 
        return;
625 
}
626 
 
627 
 
628 
 
629 
#define MOVE(OBJECT,WHERE) fMOVE(OBJECT,WHERE)
630 
#undef PUT
631 
long fPUT(OBJECT,WHERE,PVAL)long OBJECT, PVAL, WHERE; {
632 
long PUT;
633 
 
634 
/*  PUT IS THE SAME AS MOVE, EXCEPT IT RETURNS A VALUE USED TO SET UP THE
635 
 *  NEGATED PROP VALUES FOR THE REPOSITORY OBJECTS. */
636 
 
637 
 
638 
        MOVE(OBJECT,WHERE);
639 
        PUT=(-1)-PVAL;
640 
        return(PUT);
641 
}
642 
 
643 
 
644 
 
645 
#define PUT(OBJECT,WHERE,PVAL) fPUT(OBJECT,WHERE,PVAL)
646 
#undef CARRY
647 
void fCARRY(OBJECT,WHERE)long OBJECT, WHERE; {
648 
long TEMP;
649 
 
650 
/*  START TOTING AN OBJECT, REMOVING IT FROM THE LIST OF THINGS AT ITS FORMER
651 
 *  LOCATION.  INCR HOLDNG UNLESS IT WAS ALREADY BEING TOTED.  IF OBJECT>100
652 
 *  (MOVING "FIXED" SECOND LOC), DON'T CHANGE PLACE OR HOLDNG. */
653 
 
654 
 
655 
        if(OBJECT > 100) goto L5;
656 
        if(PLACE[OBJECT] == -1)return;
657 
        PLACE[OBJECT]= -1;
658 
        HOLDNG=HOLDNG+1;
659 
L5:     if(ATLOC[WHERE] != OBJECT) goto L6;
660 
        ATLOC[WHERE]=LINK[OBJECT];
661 
        return;
662 
L6:     TEMP=ATLOC[WHERE];
663 
L7:     if(LINK[TEMP] == OBJECT) goto L8;
664 
        TEMP=LINK[TEMP];
665 
         goto L7;
666 
L8:     LINK[TEMP]=LINK[OBJECT];
667 
        return;
668 
}
669 
 
670 
 
671 
 
672 
#define CARRY(OBJECT,WHERE) fCARRY(OBJECT,WHERE)
673 
#undef DROP
674 
void fDROP(OBJECT,WHERE)long OBJECT, WHERE; {
675 
;
676 
 
677 
/*  PLACE AN OBJECT AT A GIVEN LOC, PREFIXING IT ONTO THE ATLOC LIST.  DECR
678 
 *  HOLDNG IF THE OBJECT WAS BEING TOTED. */
679 
 
680 
 
681 
        if(OBJECT > 100) goto L1;
682 
        if(PLACE[OBJECT] == -1)HOLDNG=HOLDNG-1;
683 
        PLACE[OBJECT]=WHERE;
684 
         goto L2;
685 
L1:     {long x = OBJECT-100; FIXED[x]=WHERE;}
686 
L2:     if(WHERE <= 0)return;
687 
        LINK[OBJECT]=ATLOC[WHERE];
688 
        ATLOC[WHERE]=OBJECT;
689 
        return;
690 
}
691 
 
692 
 
693 
 
694 
#define DROP(OBJECT,WHERE) fDROP(OBJECT,WHERE)
695 
#undef ATDWRF
696 
long fATDWRF(WHERE)long WHERE; {
697 
long ATDWRF, I;
698 
 
699 
/*  RETURN THE INDEX OF FIRST DWARF AT THE GIVEN LOCATION, ZERO IF NO DWARF IS
700 
 *  THERE (OR IF DWARVES NOT ACTIVE YET), -1 IF ALL DWARVES ARE DEAD.  IGNORE
701 
 *  THE PIRATE (6TH DWARF). */
702 
 
703 
 
704 
        ATDWRF=0;
705 
        if(DFLAG < 2)return(ATDWRF);
706 
        ATDWRF= -1;
707 
        /* 1 */ for (I=1; I<=5; I++) {
708 
        if(DLOC[I] == WHERE) goto L2;
709 
L1:     if(DLOC[I] != 0)ATDWRF=0;
710 
        } /* end loop */
711 
        return(ATDWRF);
712 
 
713 
L2:     ATDWRF=I;
714 
        return(ATDWRF);
715 
}
716 
 
717 
 
718 
 
719 
 
720 
#define ATDWRF(WHERE) fATDWRF(WHERE)
721 
 
722 
 
723 
 
724 
/*  UTILITY ROUTINES (SETBIT, TSTBIT, RAN, RNDVOC, BUG) */
725 
 
726 
#undef SETBIT
727 
long fSETBIT(BIT)long BIT; {
728 
long I, SETBIT;
729 
 
730 
/*  RETURNS 2**BIT FOR USE IN CONSTRUCTING BIT-MASKS. */
731 
 
732 
 
733 
        SETBIT=1;
734 
        if(BIT <= 0)return(SETBIT);
735 
        /* 1 */ for (I=1; I<=BIT; I++) {
736 
L1:     SETBIT=SETBIT+SETBIT;
737 
        } /* end loop */
738 
        return(SETBIT);
739 
}
740 
 
741 
 
742 
 
743 
#define SETBIT(BIT) fSETBIT(BIT)
744 
#undef TSTBIT
745 
long fTSTBIT(MASK,BIT)long BIT, MASK; {
746 
long TSTBIT;
747 
 
748 
/*  RETURNS TRUE IF THE SPECIFIED BIT IS SET IN THE MASK. */
749 
 
750 
 
751 
        TSTBIT=MOD(MASK/SETBIT(BIT),2) != 0;
752 
        return(TSTBIT);
753 
}
754 
 
755 
 
756 
 
757 
#define TSTBIT(MASK,BIT) fTSTBIT(MASK,BIT)
758 
#undef RAN
759 
long fRAN(RANGE)long RANGE; {
760 
static long D, R = 0, RAN, T;
761 
 
762 
/*  SINCE THE RAN FUNCTION IN LIB40 SEEMS TO BE A REAL LOSE, WE'LL USE ONE OF
763 
 *  OUR OWN.  IT'S BEEN RUN THROUGH MANY OF THE TESTS IN KNUTH VOL. 2 AND
764 
 *  SEEMS TO BE QUITE RELIABLE.  RAN RETURNS A VALUE UNIFORMLY SELECTED
765 
 *  BETWEEN 0 AND RANGE-1. */
766 
 
767 
 
768 
        D=1;
769 
        if(R != 0 && RANGE >= 0) goto L1;
770 
        DATIME(D,T);
771 
        R=MOD(T+5,1048576L);
772 
        D=1000+MOD(D,1000);
773 
L1:     /* 2 */ for (T=1; T<=D; T++) {
774 
L2:     R=MOD(R*1093L+221587L,1048576L);
775 
        } /* end loop */
776 
        RAN=(RANGE*R)/1048576;
777 
        return(RAN);
778 
}
779 
 
780 
 
781 
 
782 
#define RAN(RANGE) fRAN(RANGE)
783 
#undef RNDVOC
784 
long fRNDVOC(CHAR,FORCE)long CHAR, FORCE; {
785 
long DIV, I, J, RNDVOC;
786 
 
787 
/*  SEARCHES THE VOCABULARY FOR A WORD WHOSE SECOND CHARACTER IS CHAR, AND
788 
 *  CHANGES THAT WORD SUCH THAT EACH OF THE OTHER FOUR CHARACTERS IS A
789 
 *  RANDOM LETTER.  IF FORCE IS NON-ZERO, IT IS USED AS THE NEW WORD.
790 
 *  RETURNS THE NEW WORD. */
791 
 
792 
 
793 
        RNDVOC=FORCE;
794 
        if(RNDVOC != 0) goto L3;
795 
        /* 1 */ for (I=1; I<=5; I++) {
796 
        J=11+RAN(26);
797 
        if(I == 2)J=CHAR;
798 
L1:     RNDVOC=RNDVOC*64+J;
799 
        } /* end loop */
800 
L3:     J=10000;
801 
        DIV=64L*64L*64L;
802 
        /* 5 */ for (I=1; I<=TABSIZ; I++) {
803 
        J=J+7;
804 
        if(MOD((ATAB[I]-J*J)/DIV,64L) == CHAR) goto L8;
805 
L5:     /*etc*/ ;
806 
        } /* end loop */
807 
        BUG(5);
808 
 
809 
L8:     ATAB[I]=RNDVOC+J*J;
810 
        return(RNDVOC);
811 
}
812 
 
813 
 
814 
 
815 
#define RNDVOC(CHAR,FORCE) fRNDVOC(CHAR,FORCE)
816 
#undef BUG
817 
void fBUG(NUM)long NUM; {
818 
 
819 
/*  THE FOLLOWING CONDITIONS ARE CURRENTLY CONSIDERED FATAL BUGS.  NUMBERS < 20
820 
 *  ARE DETECTED WHILE READING THE DATABASE; THE OTHERS OCCUR AT "RUN TIME".
821 
 *      0        MESSAGE LINE > 70 CHARACTERS
822 
 *      1       NULL LINE IN MESSAGE
823 
 *      2       TOO MANY WORDS OF MESSAGES
824 
 *      3       TOO MANY TRAVEL OPTIONS
825 
 *      4       TOO MANY VOCABULARY WORDS
826 
 *      5       REQUIRED VOCABULARY WORD NOT FOUND
827 
 *      6       TOO MANY RTEXT MESSAGES
828 
 *      7       TOO MANY HINTS
829 
 *      8       LOCATION HAS COND BIT BEING SET TWICE
830 
 *      9       INVALID SECTION NUMBER IN DATABASE
831 
 *      10      TOO MANY LOCATIONS
832 
 *      11      TOO MANY CLASS OR TURN MESSAGES
833 
 *      20      SPECIAL TRAVEL (500>L>300) EXCEEDS GOTO LIST
834 
 *      21      RAN OFF END OF VOCABULARY TABLE
835 
 *      22      VOCABULARY TYPE (N/1000) NOT BETWEEN 0 AND 3
836 
 *      23      INTRANSITIVE ACTION VERB EXCEEDS GOTO LIST
837 
 *      24      TRANSITIVE ACTION VERB EXCEEDS GOTO LIST
838 
 *      25      CONDITIONAL TRAVEL ENTRY WITH NO ALTERNATIVE
839 
 *      26      LOCATION HAS NO TRAVEL ENTRIES
840 
 *      27      HINT NUMBER EXCEEDS GOTO LIST
841 
 *      28      INVALID MONTH RETURNED BY DATE FUNCTION
842 
 *      29      TOO MANY PARAMETERS GIVEN TO SETPRM */
843 
 
844 177 ja_rd 
    printf("Fatal error %d. See source code for interpretation.\n", NUM);
845 90 ja_rd 
        exit(FALSE);
846 
}
847 
 
848 
 
849 
 
850 
 
851 
 
852 
/*  MACHINE DEPENDENT ROUTINES (MAPLIN, TYPE, MPINIT, SAVEIO) */
853 
 
854 
#define BUG(NUM) fBUG(NUM)
855 
#undef MAPLIN
856 
void fMAPLIN(FIL)long FIL; {
857 
long I, VAL; static MFILE *OPENED = NULL;
858 
 
859 
/*  READ A LINE OF INPUT, EITHER FROM A FILE (IF FIL=.TRUE.) OR FROM THE
860 
 *  KEYBOARD, TRANSLATE THE CHARS TO INTEGERS IN THE RANGE 0-126 AND STORE
861 
 *  THEM IN THE COMMON ARRAY "INLINE".  INTEGER VALUES ARE AS FOLLOWS:
862 
 *     0   = SPACE [ASCII CODE 40 OCTAL, 32 DECIMAL]
863 
 *    1-2  = !" [ASCII 41-42 OCTAL, 33-34 DECIMAL]
864 
 *    3-10 = '()*+,-. [ASCII 47-56 OCTAL, 39-46 DECIMAL]
865 
 *   11-36 = UPPER-CASE LETTERS
866 
 *   37-62 = LOWER-CASE LETTERS
867 
 *    63   = PERCENT (%) [ASCII 45 OCTAL, 37 DECIMAL]
868 
 *   64-73 = DIGITS, 0 THROUGH 9
869 
 *  REMAINING CHARACTERS CAN BE TRANSLATED ANY WAY THAT IS CONVENIENT;
870 
 *  THE "TYPE" ROUTINE BELOW IS USED TO MAP THEM BACK TO CHARACTERS WHEN
871 
 *  NECESSARY.  THE ABOVE MAPPINGS ARE REQUIRED SO THAT CERTAIN SPECIAL
872 
 *  CHARACTERS ARE KNOWN TO FIT IN 6 BITS AND/OR CAN BE EASILY SPOTTED.
873 
 *  ARRAY ELEMENTS BEYOND THE END OF THE LINE SHOULD BE FILLED WITH 0,
874 
 *  AND LNLENG SHOULD BE SET TO THE INDEX OF THE LAST CHARACTER.
875 
 *
876 
 *  IF THE DATA FILE USES A CHARACTER OTHER THAN SPACE (E.G., TAB) TO
877 
 *  SEPARATE NUMBERS, THAT CHARACTER SHOULD ALSO TRANSLATE TO 0.
878 
 *
879 
 *  THIS PROCEDURE MAY USE THE MAP1,MAP2 ARRAYS TO MAINTAIN STATIC DATA FOR
880 
 *  THE MAPPING.  MAP2(1) IS SET TO 0 WHEN THE PROGRAM STARTS
881 
 *  AND IS NOT CHANGED THEREAFTER UNLESS THE ROUTINES ON THIS PAGE CHOOSE
882 
 *  TO DO SO.
883 
 *
884 
 *  NOTE THAT MAPLIN IS EXPECTED TO OPEN THE FILE THE FIRST TIME IT IS
885 
 *  ASKED TO READ A LINE FROM IT.  THAT IS, THERE IS NO OTHER PLACE WHERE
886 
 *  THE DATA FILE IS OPENED. */
887 
 
888 
 
889 
        if(MAP2[1] == 0)MPINIT();
890 
 
891 
        if(FIL) goto L15;
892 
        get_command(INLINE+1);
893 
        /* EMBEDDED: we don't support 'quitting by closing stdin' */
894 
        /* if(feof(stdin)) score(1); */
895 
    goto L20;
896 
 
897 
L15:    if(!OPENED){
898 
                OPENED=mopen("adventure.text","r" /* NOT binary */);
899 177 ja_rd 
                if(!OPENED){printf("Can't read adventure.text!\n"); exit(FALSE);}
900 90 ja_rd 
                }
901 
        mgets(INLINE+1,100,OPENED);
902 
 
903 
L20:    LNLENG=0;
904 
        /* 25 */ for (I=1; I<=100 && INLINE[I]!=0; I++) {
905 
        VAL=INLINE[I]+1;
906 
        INLINE[I]=MAP1[VAL];
907 
L25:    if(INLINE[I] != 0)LNLENG=I;
908 
        } /* end loop */
909 
        LNPOSN=1;
910 
        if(FIL && LNLENG == 0) goto L15;
911 
/*  ABOVE IS TO GET AROUND AN F40 COMPILER BUG WHEREIN IT READS A BLANK
912 
 *  LINE WHENEVER A CRLF IS BROKEN ACROSS A RECORD BOUNDARY. */
913 
        return;
914 
}
915 
 
916 
 
917 
 
918 
#define MAPLIN(FIL) fMAPLIN(FIL)
919 
#undef TYPE
920 
void fTYPE() {
921 
long I, VAL;
922 
 
923 
/*  TYPE THE FIRST "LNLENG" CHARACTERS STORED IN INLINE, MAPPING THEM
924 
 *  FROM INTEGERS TO TEXT PER THE RULES DESCRIBED ABOVE.  INLINE(I),
925 
 *  I=1,LNLENG MAY BE CHANGED BY THIS ROUTINE. */
926 
 
927 
 
928 
        if(LNLENG != 0) goto L10;
929 177 ja_rd 
        printf("\n");
930 90 ja_rd 
        return;
931 
 
932 
L10:    if(MAP2[1] == 0)MPINIT();
933 
        /* 20 */ for (I=1; I<=LNLENG; I++) {
934 
        VAL=INLINE[I];
935 
L20:    {long x = VAL+1; INLINE[I]=MAP2[x];}
936 
        } /* end loop */
937 
        {long x = LNLENG+1; INLINE[x]=0;}
938 177 ja_rd 
        printf(INLINE+1);
939 
        printf("\n");
940 90 ja_rd 
        return;
941 
}
942 
 
943 
 
944 
 
945 
#define TYPE() fTYPE()
946 
#undef MPINIT
947 
void fMPINIT() {
948 
long FIRST, I, J, LAST, VAL;
949 
static const long RUNS[7][2] = {32,34, 39,46, 65,90, 97,122, 37,37, 48,57, 0,126};
950 
 
951 
 
952 
        /* 10 */ for (I=1; I<=128; I++) {
953 
L10:    MAP1[I]= -1;
954 
        } /* end loop */
955 
        VAL=0;
956 
        /* 20 */ for (I=0; I<7; I++) {
957 
        FIRST=RUNS[I][0];
958 
        LAST=RUNS[I][1];
959 
        /* 22 */ for (J=FIRST; J<=LAST; J++) {
960 
        J++; if(MAP1[J] >= 0) goto L22;
961 
        MAP1[J]=VAL;
962 
        VAL=VAL+1;
963 
L22:    J--;
964 
        } /* end loop */
965 
L20:    /*etc*/ ;
966 
        } /* end loop */
967 
        MAP1[128]=MAP1[10];
968 
/*  FOR THIS VERSION, TAB (9) MAPS TO SPACE (32), SO DEL (127) USES TAB'S VALUE */
969 
        MAP1[10]=MAP1[33];
970 
        MAP1[11]=MAP1[33];
971 
 
972 
        /* 30 */ for (I=0; I<=126; I++) {
973 
        I++; VAL=MAP1[I]+1; I--;
974 
        MAP2[VAL]=I*('B'-'A');
975 
L30:    if(I >= 64)MAP2[VAL]=(I-64)*('B'-'A')+'@';
976 
        } /* end loop */
977 
 
978 
        return;
979 
}
980 
 
981 
 
982 
 
983 
#define MPINIT() fMPINIT()
984 
#undef SAVEIO
985 
void fSAVEIO(OP,IN,ARR)long ARR[], IN, OP; {
986 
static FILE *F; char NAME[50];
987 
 
988 
/*  IF OP=0, ASK FOR A FILE NAME AND OPEN A FILE.  (IF IN=.TRUE., THE FILE IS FOR
989 
 *  INPUT, ELSE OUTPUT.)  IF OP>0, READ/WRITE ARR FROM/INTO THE PREVIOUSLY-OPENED
990 
 *  FILE.  (ARR IS A 250-INTEGER ARRAY.)  IF OP<0, FINISH READING/WRITING THE
991 
 *  FILE.  (FINISHING WRITING CAN BE A NO-OP IF A "STOP" STATEMENT DOES IT
992 
 *  AUTOMATICALLY.  FINISHING READING CAN BE A NO-OP AS LONG AS A SUBSEQUENT
993 
 *  SAVEIO(0,.FALSE.,X) WILL STILL WORK.)  IF YOU CAN CATCH ERRORS (E.G., NO SUCH
994 
 *  FILE) AND TRY AGAIN, GREAT.  DEC F40 CAN'T. */
995 
 
996 
/* EMBEDDED version supports no saves */
997 
/*
998 
        {long ifvar; ifvar=(OP); switch (ifvar<0? -1 : ifvar>0? 1 : 0) { case -1:
999 
                goto L10; case 0: goto L20; case 1: goto L30; }}
1000 
 
1001 
L10:    fclose(F);
1002 
        return;
1003 
 
1004 177 ja_rd 
L20:    printf("\nFile name: ");
1005 90 ja_rd 
        gets(NAME);
1006 
        F=mopen(NAME,(IN ? READ_MODE : WRITE_MODE));
1007 177 ja_rd 
        if(F == NULL) {printf("Can't open file, try again.\n"); goto L20;}
1008 90 ja_rd 
        return;
1009 
 
1010 
L30:    if(IN)fread(ARR,4,250,F);
1011 
        if(!IN)fwrite(ARR,4,250,F);
1012 
        return;
1013 
*/
1014 
return;
1015 
}
1016 
 
1017 
 
1018 
 
1019 
long fIABS(N)long N; {return(N<0? -N : N);}
1020 
long fMOD(N,M)long N, M; {return(N%M);}

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