/***************************************************************************** * mktable - table-building program to ease table maintenance problems * * DESCRIPTION * Several parts of the FORTRAN compiler need large tables. * For example, the lexer contains tables of keywords and multicharacter * tokens; the intrinsic-function handler contains a table of all the * FORTRAN intrinsic functions. * Maintaining these tables can be aggravating, since they are typically * large and involve lots of drudge work (like changing many sequentially- * numbered macro definitions) to modify. * * `mktable' can be used to build tables automatically as part of the * usual compiler building process. Its usages and semantics are as * follows. * * `mktable' takes a "table" file on its standard input. Each line of * the table file has one of the following forms: * * # commentary information * "key-string" [index-macro-name [arbitrary-stuff]] * * * The key string and arbitrary-stuff form the contents of a single * table record. The index-macro-name is #define'd to be the index * of the given record in the table. If the index-macro-name is absent or * is an empty string ("") then no macro definition is produced for the * record. * * `mktable' produces its output on four files: * mktable.keys: the key string * mktable.defs: #define * mktable.indx: contains the initialization part of a definition * for an index array for key-letter indexed tables, * or the initialization part of a collision-resolution * table for linear-list hashed tables. * (not generated for sorted or _open-addressed tables.) * mktable.info: contains arbitrary-stuff * * For example, if the table to be defined were named "symtab" and the * table being constructed was of the "sorted" type (suitable for binary * search), * * # contents of symtab: * "alpha" ST_ALPHA 2, 4, MONADIC * "gamma" ST_GAMMA 2, 3, MONADIC * "delta" ST_DELTA 2, 1, DYADIC * "epsilon" * * then `mktable' produces the following in mktable.keys: * * "alpha","delta","epsilon","gamma" * * and the following in mktable.defs: * * #define ST_ALPHA 0 * #define ST_DELTA 1 * #define ST_GAMMA 2 * * and in mktable.info : * * {2, 4, MONADIC}, {2, 1, DYADIC}, {0}, {2, 3, MONADIC} * * The files might be included in a C source program in the * following way: * * #include "mktable.defs" * ... * char *symname[] = { * # include "mktable.keys" * }; * struct syminfo * { * int size; * int cycles; * int arity; * }; * struct syminfo symtab[] = { * # include "mktable.info" * }; * * The `mktable' command itself is used in one of the following ways: * * mktable "open" size #include #include #include #define MAXRECORDS 300 /* maximum-size table we can handle */ #define MAXLINE 82 /* maximum line length (incl "\n\0") */ #define HASHED 0 /* flag used by table loader */ #define LINEAR 1 /* ditto */ #define OPENADDR 2 /* ditto */ #define KEYFILE "mktable.key" /* name of table output file */ #define DEFFILE "mktable.def" /* name of index defs output file */ #define INDEXFILE "mktable.ind" /* name of table index output file */ #define INFOFILE "mktable.inf" /* gots the infos in it */ typedef struct rec { char *key; /* key-string field */ char *id; /* index macro identifier */ char *other; /* other stuff in the record - output untouched */ struct rec *link; /* pointer to next record in hash synonyms list */ } Rec_t; int Upper = 0; FILE *Fkeys, *Findex, *Fdefs, *Finfo; /************************************************************************/ /* Function Prototypes */ /************************************************************************/ void main (int argc, char **argv); void usage (void); void error(char * message); void open_addr(int size); void hash_linear(int size); void sorted(void); void key_letter(void); int load(Rec_t *record, int method, int size); void startoutput(void); void endoutput(void); void outrec(Rec_t *rec); void outdef(char *name, int value); void outinx(int value); void sortrec(Rec_t **rptr, int size); int hash(register char *name); /************************************************************************/ /* Program code */ /************************************************************************/ void __cdecl main ( int argc, char **argv ) { if (argc <= 1) usage(); if(strcmp(argv[1], "-U") == 0) { Upper = 1; argv++; argc--; } if (strcmp(argv[1], "open") == 0) { if (argc != 3) usage(); open_addr(atoi(argv[2])); } else if (strcmp(argv[1], "hashed") == 0) { if (argc != 3) usage(); hash_linear(atoi(argv[2])); } else if (strcmp(argv[1], "sorted") == 0) { if (argc != 2) usage(); sorted(); } else if (strcmp(argv[1], "key-letter") == 0) { if (argc != 2) usage(); key_letter(); } else usage(); exit(0); } void usage ( void ) { error("usage: mktable (open SIZE | hashed SIZE | sorted | key-letter) size) error("too many records to hold in table"); defrec.key = NULL; defrec.id = NULL; for (i = 0; i < size; ++i) { if (record[i].key != NULL) break; } defrec.other = record[i].other; defrec.link = NULL; /* * The `load' routine has built a hash table `record'. * Each entry in `record' is either empty (key == NULL) or contains a record. * Each record may have a NULL link field, or a link field that points to * a hash synonym. * With this section of code, we rearrange the linked lists of hash synonyms * so that all the entries are stored in `record'. */ nextslot = 0; for (i = 0; i < size; ++i) { if ((record[i].key != NULL) && (record[i].link != NULL) && ((record[i].link < record) || (record[i].link >= (record + size)))) { for (prev = i, rp = record[i].link; rp != NULL; rp = rp->link) { while (record[nextslot].key != NULL) ++nextslot; record[prev].link = &record[nextslot]; record[nextslot] = *rp; prev = nextslot; } } } startoutput(); for (i = 0; i < size; ++i) { if (record[i].key == NULL) { outrec(&defrec); outinx(-1); } else { outrec(&record[i]); if (record[i].link == NULL) outinx(-1); else outinx(record[i].link - record); /* cvt. to inx in table */ outdef(record[i].id, i); } } endoutput(); } void sorted( void ) { Rec_t record[MAXRECORDS], *rptr[MAXRECORDS]; register int i, size; size = load(record, LINEAR, MAXRECORDS); for (i = 0; i < size; ++i) rptr[i] = &record[i]; sortrec(rptr, size); startoutput(); for (i = 0; i < size; ++i) { outrec(rptr[i]); outdef(rptr[i]->id, i); } endoutput(); _unlink(INDEXFILE); } void key_letter( void ) { Rec_t record[MAXRECORDS], *rptr[MAXRECORDS], *temp; register int i, size, j, k, l; register char lastletter; size = load(record, LINEAR, MAXRECORDS); for (i = 0; i < size; ++i) rptr[i] = &record[i]; sortrec(rptr, size); for (i = 0; i < size; i = j) { for (j = i; j < size; ++j) { if (rptr[i]->key[0] != rptr[j]->key[0]) break; } l = j - 1; for (k = i; k < l; ++k, --l) { temp = rptr[k]; rptr[k] = rptr[l]; rptr[l] = temp; } } startoutput(); lastletter = (char)((Upper ? 'A' : '_') - 1); for (i = 0; i < size; ++i) { while (rptr[i]->key[0] > lastletter) { outinx(i); ++lastletter; } outrec(rptr[i]); outdef(rptr[i]->id, i); } for (; lastletter < (char)((Upper ? 'Z' : 'z') + 1); ++lastletter) outinx(size); endoutput(); } int load( Rec_t *record, int method, int size ) { char *line; register char *p; int rec, h, chainlen, maxchainlen = 0, collisions = 0; Rec_t r; for (rec = 0; ; ++rec) { if ((line = malloc(MAXLINE)) == NULL) error("insufficient memory to load records"); if (fgets(line, MAXLINE, stdin) == NULL) break; if (rec >= size) error("too many records to handle"); r.key = r.id = r.other = NULL; r.link = NULL; for (p = line; *p && isspace(*p); ++p) ; if (*p != '"') { free(line); --rec; continue; } r.key = ++p; for (; *p != '"'; ++p) { if(Upper && (islower(*p))) *p = (char)toupper(*p); } *p++ = '\0'; for (; *p && isspace(*p); ++p) /* skip space key and id */ ; if (*p == '"' && *(p + 1) == '"') { /* no id */ r.id = NULL; p += 2; } else if (*p) { r.id = p++; /* id start */ for (; *p && ( ! isspace(*p)); ++p) /* til first space */ ; if(*p) { *p++ = '\0'; /* terminate id */ } } for (; *p && isspace(*p); ++p) /* skip space til other info */ ; if(*p) { r.other = p++; for (; *p != '\n' && *p != '\0'; ++p) ; *p = '\0'; } if (method == LINEAR) { record[rec] = r; } else if (method == OPENADDR) { chainlen = 0; for(h = hash(r.key) % size; record[h].key; h = (h+1) % size) { ++chainlen; ++collisions; } maxchainlen = (chainlen < maxchainlen)? maxchainlen: chainlen; record[h] = r; } else { /* method == HASHED */ Rec_t *rp; h = hash(r.key) % size; if (record[h].key == NULL) { record[h] = r; } else { if ((rp = (Rec_t *)malloc(sizeof(Rec_t))) == NULL) error("insufficient memory to store all records"); *rp = record[h]; r.link = rp; record[h] = r; ++collisions; chainlen = 1; for (rp = &record[h]; rp->link != NULL; rp = rp->link) ++chainlen; maxchainlen = (chainlen < maxchainlen)? maxchainlen: chainlen; } } } if (method == HASHED || method == OPENADDR) fprintf(stderr, "%d collisions, max chain length %d\n", collisions, maxchainlen); return rec; } void startoutput( void ) { if ((Fkeys = fopen(KEYFILE, "w")) == NULL) error("can't open keys output file"); if ((Findex = fopen(INDEXFILE, "w")) == NULL) error("can't open index output file"); if ((Fdefs = fopen(DEFFILE, "w")) == NULL) error("can't open definitions output file"); if ((Finfo = fopen(INFOFILE, "w")) == NULL) error("can't open info output file"); } void endoutput( void ) { fclose(Fkeys); fclose(Findex); fclose(Fdefs); fclose(Finfo); } void outrec(Rec_t *rec) { if (rec->key == NULL) fprintf(Fkeys, "NULL,\n"); else fprintf(Fkeys, "\"%s\",\n", ((rec->key) + 1)); if (rec->other == NULL) fprintf(Finfo, "{0},\n"); else fprintf(Finfo, "{%s},\n", rec->other); } void outdef( char *name, int value ) { if (name != NULL) fprintf(Fdefs, "#define %s %d\n", name, value); } void outinx( int value ) { fprintf(Findex, "%d,\n", value); } /* * Following code defines the hash function used in `mktable' and in * the compiler. Since we must guarantee they are the same function, * we use a single source file. * * `mktable' does not use the standard include file that the compiler * uses, so we define the allowable register declarations here. */ #define REG1 register #define REG2 register #define REG3 register void sortrec( Rec_t **rptr, int size ) { register int j, i, gap; Rec_t *temp; for (gap = size / 2; gap > 0; gap /= 2) { for (i = gap; i < size; ++i) { for (j = i - gap; j >= 0; j -= gap) { if (strcmp(rptr[j]->key, rptr[j + gap]->key) <= 0) break; temp = rptr[j]; rptr[j] = rptr[j + gap]; rptr[j + gap] = temp; } } } } int hash( register char *name ) { register int i; i = 0; while(*name) { i += *name++ ; } return(i) ; }