ref: 44ce0097b612a1fefd754065bdf8d9d2e5ef60c8
dir: /utils/libregexp/regcomp.c/
#include <lib9.h> #include "regexp.h" #include "regcomp.h" #define TRUE 1 #define FALSE 0 /* * Parser Information */ typedef struct Node { Reinst* first; Reinst* last; }Node; Reprog RePrOg; #define NSTACK 20 static Node andstack[NSTACK]; static Node *andp; static int atorstack[NSTACK]; static int* atorp; static int cursubid; /* id of current subexpression */ static int subidstack[NSTACK]; /* parallel to atorstack */ static int* subidp; static int lastwasand; /* Last token was operand */ static int nbra; static char* exprp; /* pointer to next character in source expression */ static int lexdone; static int nclass; static Reclass*classp; static Reinst* freep; static int errors; static Rune yyrune; /* last lex'd rune */ static Reclass*yyclassp; /* last lex'd class */ /* predeclared crap */ static void operator(int); static void pushand(Reinst*, Reinst*); static void pushator(int); static void evaluntil(int); static int bldcclass(void); static jmp_buf regkaboom; static void rcerror(char *s) { errors++; regerror(s); longjmp(regkaboom, 1); } static Reinst* newinst(int t) { freep->type = t; freep->u2.left = 0; freep->u1.right = 0; return freep++; } static void operand(int t) { Reinst *i; if(lastwasand) operator(CAT); /* catenate is implicit */ i = newinst(t); if(t == CCLASS || t == NCCLASS) i->u1.cp = yyclassp; if(t == RUNE) i->u1.r = yyrune; pushand(i, i); lastwasand = TRUE; } static void operator(int t) { if(t==RBRA && --nbra<0) rcerror("unmatched right paren"); if(t==LBRA){ if(++cursubid >= NSUBEXP) rcerror ("too many subexpressions"); nbra++; if(lastwasand) operator(CAT); } else evaluntil(t); if(t != RBRA) pushator(t); lastwasand = FALSE; if(t==STAR || t==QUEST || t==PLUS || t==RBRA) lastwasand = TRUE; /* these look like operands */ } static void regerr2(char *s, int c) { char buf[100]; char *cp = buf; while(*s) *cp++ = *s++; *cp++ = c; *cp = '\0'; rcerror(buf); } static void cant(char *s) { char buf[100]; strcpy(buf, "can't happen: "); strcat(buf, s); rcerror(buf); } static void pushand(Reinst *f, Reinst *l) { if(andp >= &andstack[NSTACK]) cant("operand stack overflow"); andp->first = f; andp->last = l; andp++; } static void pushator(int t) { if(atorp >= &atorstack[NSTACK]) cant("operator stack overflow"); *atorp++ = t; *subidp++ = cursubid; } static Node* popand(int op) { Reinst *inst; if(andp <= &andstack[0]){ regerr2("missing operand for ", op); inst = newinst(NOP); pushand(inst,inst); } return --andp; } static int popator(void) { if(atorp <= &atorstack[0]) cant("operator stack underflow"); --subidp; return *--atorp; } static void evaluntil(int pri) { Node *op1, *op2; Reinst *inst1, *inst2; while(pri==RBRA || atorp[-1]>=pri){ switch(popator()){ default: rcerror("unknown operator in evaluntil"); break; case LBRA: /* must have been RBRA */ op1 = popand('('); inst2 = newinst(RBRA); inst2->u1.subid = *subidp; op1->last->u2.next = inst2; inst1 = newinst(LBRA); inst1->u1.subid = *subidp; inst1->u2.next = op1->first; pushand(inst1, inst2); return; case OR: op2 = popand('|'); op1 = popand('|'); inst2 = newinst(NOP); op2->last->u2.next = inst2; op1->last->u2.next = inst2; inst1 = newinst(OR); inst1->u1.right = op1->first; inst1->u2.left = op2->first; pushand(inst1, inst2); break; case CAT: op2 = popand(0); op1 = popand(0); op1->last->u2.next = op2->first; pushand(op1->first, op2->last); break; case STAR: op2 = popand('*'); inst1 = newinst(OR); op2->last->u2.next = inst1; inst1->u1.right = op2->first; pushand(inst1, inst1); break; case PLUS: op2 = popand('+'); inst1 = newinst(OR); op2->last->u2.next = inst1; inst1->u1.right = op2->first; pushand(op2->first, inst1); break; case QUEST: op2 = popand('?'); inst1 = newinst(OR); inst2 = newinst(NOP); inst1->u2.left = inst2; inst1->u1.right = op2->first; op2->last->u2.next = inst2; pushand(inst1, inst2); break; } } } static Reprog* optimize(Reprog *pp) { Reinst *inst, *target; int size; Reprog *npp; Reclass *cl; int diff; /* * get rid of NOOP chains */ for(inst=pp->firstinst; inst->type!=END; inst++){ target = inst->u2.next; while(target->type == NOP) target = target->u2.next; inst->u2.next = target; } /* * The original allocation is for an area larger than * necessary. Reallocate to the actual space used * and then relocate the code. */ size = sizeof(Reprog) + (freep - pp->firstinst)*sizeof(Reinst); npp = (Reprog *)realloc(pp, size); if(npp==0 || npp==pp) return pp; diff = (char *)npp - (char *)pp; freep = (Reinst *)((char *)freep + diff); for(inst=npp->firstinst; inst<freep; inst++){ switch(inst->type){ case OR: case STAR: case PLUS: case QUEST: *(char **)&inst->u1.right += diff; break; case CCLASS: case NCCLASS: *(char **)&inst->u1.right += diff; cl = inst->u1.cp; *(char **)&cl->end += diff; break; } *(char **)&inst->u2.left += diff; } *(char **)&npp->startinst += diff; return npp; } #ifdef DEBUG static void dumpstack(void){ Node *stk; int *ip; print("operators\n"); for(ip=atorstack; ip<atorp; ip++) print("0%o\n", *ip); print("operands\n"); for(stk=andstack; stk<andp; stk++) print("0%o\t0%o\n", stk->first->type, stk->last->type); } static void dump(Reprog *pp) { Reinst *l; Rune *p; l = pp->firstinst; do{ print("%d:\t0%o\t%d\t%d", l-pp->firstinst, l->type, l->u2.left-pp->firstinst, l->u1.right-pp->firstinst); if(l->type == RUNE) print("\t%C\n", l->r); else if(l->type == CCLASS || l->type == NCCLASS){ print("\t["); if(l->type == NCCLASS) print("^"); for(p = l->cp->spans; p < l->cp->end; p += 2) if(p[0] == p[1]) print("%C", p[0]); else print("%C-%C", p[0], p[1]); print("]\n"); } else print("\n"); }while(l++->type); } #endif static Reclass* newclass(void) { if(nclass >= NCLASS) regerr2("too many character classes; limit", NCLASS+'0'); return &(classp[nclass++]); } static int nextc(Rune *rp) { if(lexdone){ *rp = 0; return 1; } exprp += chartorune(rp, exprp); if(*rp == L'\\'){ exprp += chartorune(rp, exprp); return 1; } if(*rp == 0) lexdone = 1; return 0; } static int lex(int literal, int dot_type) { int quoted; quoted = nextc(&yyrune); if(literal || quoted){ if(yyrune == 0) return END; return RUNE; } switch(yyrune){ case 0: return END; case L'*': return STAR; case L'?': return QUEST; case L'+': return PLUS; case L'|': return OR; case L'.': return dot_type; case L'(': return LBRA; case L')': return RBRA; case L'^': return BOL; case L'$': return EOL; case L'[': return bldcclass(); } return RUNE; } static int bldcclass(void) { int type; Rune r[NCCRUNE]; Rune *p, *ep, *np; Rune rune; int quoted; /* we have already seen the '[' */ type = CCLASS; yyclassp = newclass(); /* look ahead for negation */ /* SPECIAL CASE!!! negated classes don't match \n */ ep = r; quoted = nextc(&rune); if(!quoted && rune == L'^'){ type = NCCLASS; quoted = nextc(&rune); *ep++ = L'\n'; *ep++ = L'\n'; } /* parse class into a set of spans */ for(; ep<&r[NCCRUNE];){ if(rune == 0){ rcerror("malformed '[]'"); return 0; } if(!quoted && rune == L']') break; if(!quoted && rune == L'-'){ if(ep == r){ rcerror("malformed '[]'"); return 0; } quoted = nextc(&rune); if((!quoted && rune == L']') || rune == 0){ rcerror("malformed '[]'"); return 0; } *(ep-1) = rune; } else { *ep++ = rune; *ep++ = rune; } quoted = nextc(&rune); } /* sort on span start */ for(p = r; p < ep; p += 2){ for(np = p; np < ep; np += 2) if(*np < *p){ rune = np[0]; np[0] = p[0]; p[0] = rune; rune = np[1]; np[1] = p[1]; p[1] = rune; } } /* merge spans */ np = yyclassp->spans; p = r; if(r == ep) yyclassp->end = np; else { np[0] = *p++; np[1] = *p++; for(; p < ep; p += 2) if(p[0] <= np[1]){ if(p[1] > np[1]) np[1] = p[1]; } else { np += 2; np[0] = p[0]; np[1] = p[1]; } yyclassp->end = np+2; } return type; } static Reprog* regcomp1(char *s, int literal, int dot_type) { int token; Reprog *pp; /* get memory for the program */ pp = (Reprog *)malloc(sizeof(Reprog) + 6*sizeof(Reinst)*strlen(s)); if(pp == 0){ regerror("out of memory"); return 0; } freep = pp->firstinst; classp = pp->class; errors = 0; if(setjmp(regkaboom)) goto out; /* go compile the sucker */ lexdone = 0; exprp = s; nclass = 0; nbra = 0; atorp = atorstack; andp = andstack; subidp = subidstack; lastwasand = FALSE; cursubid = 0; /* Start with a low priority operator to prime parser */ pushator(START-1); while((token = lex(literal, dot_type)) != END){ if((token&0300) == OPERATOR) operator(token); else operand(token); } /* Close with a low priority operator */ evaluntil(START); /* Force END */ operand(END); evaluntil(START); #ifdef DEBUG dumpstack(); #endif if(nbra) rcerror("unmatched left paren"); --andp; /* points to first and only operand */ pp->startinst = andp->first; #ifdef DEBUG dump(pp); #endif pp = optimize(pp); #ifdef DEBUG print("start: %d\n", andp->first-pp->firstinst); dump(pp); #endif out: if(errors){ free(pp); pp = 0; } return pp; } extern Reprog* regcomp(char *s) { return regcomp1(s, 0, ANY); } extern Reprog* regcomplit(char *s) { return regcomp1(s, 1, ANY); } extern Reprog* regcompnl(char *s) { return regcomp1(s, 0, ANYNL); }