mirror of https://github.com/acidanthera/audk.git
424 lines
9.2 KiB
C
424 lines
9.2 KiB
C
#include <stdio.h>
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#include <ctype.h>
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#include "set.h"
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#include "syn.h"
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#include "hash.h"
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#include "generic.h"
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#ifdef __USE_PROTOS
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void dumpset1(set s)
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#else
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void dumpset1(s)
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set s;
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#endif
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{
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if (set_nil(s)) {
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fprintf(stderr,"{}");
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} else {
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s_fprT(stderr,s);
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};
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}
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#ifdef __USE_PROTOS
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void dumpset(set s)
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#else
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void dumpset(s)
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set s;
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#endif
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{
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dumpset1(s);
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fprintf(stderr,"\n");
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}
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#ifdef __USE_PROTOS
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int isEndRule(Node * p)
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#else
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int isEndRule(p)
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Node * p;
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#endif
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{
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int result=0;
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if ( p->ntype == nJunction &&
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( (Junction *) p)->jtype == EndRule) {
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result=1;
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};
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return result;
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}
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#ifdef __USE_PROTOS
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void dumppred1(int depth,Predicate *p)
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#else
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void dumppred1(depth,p)
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int depth;
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Predicate *p;
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#endif
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{
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int i;
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int k;
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for (i=0; i<depth ; i++) {
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fprintf(stderr," ");
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};
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if (p->expr == PRED_AND_LIST ||
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p->expr == PRED_OR_LIST) {
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fprintf(stderr," %s", (p->expr == NULL ? "null expr" : p->expr));
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if (p->inverted) fprintf(stderr," predicate inverted !");
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if (p->redundant) {
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fprintf(stderr," Redundant!");
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};
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if (p->isConst) fprintf(stderr," const %d !",p->constValue);
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fprintf(stderr,"\n");
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} else {
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fprintf(stderr,"predicate k=%d",p->k);
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k=set_int(p->completionSet);
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if (k >= 0) {
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fprintf(stderr," Incomplete Set=%d !",k);
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};
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k=set_int(p->completionTree);
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if (k >= 0) {
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fprintf(stderr," Incomplete Tree=%d !",k);
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};
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if (p->redundant) {
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fprintf(stderr," Redundant!");
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};
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fprintf(stderr," \"%s\" (%x)", (p->expr == NULL ? "null expr" : p->expr) ,p);
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if (p->source != NULL) {
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fprintf(stderr,"line %d",p->source->line);
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};
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if (p->inverted) fprintf(stderr," predicate inverted !");
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fprintf(stderr,"\n");
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for (i=0; i<depth ; i++) {
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fprintf(stderr," ");
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};
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fprintf(stderr,"scontext: ");
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dumpset(p->scontext[1]);
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for (i=0; i<depth ; i++) {
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fprintf(stderr," ");
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};
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fprintf(stderr,"tcontext: ");
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preorder(p->tcontext);
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fprintf(stderr,"\n");
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};
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fprintf(stderr,"\n");
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if (p->down != NULL) {
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dumppred1(depth+1,p->down);
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};
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if (p->right != NULL) {
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dumppred1(depth,p->right);
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};
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}
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#ifdef __USE_PROTOS
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void dumppred(Predicate *p)
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#else
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void dumppred(p)
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Predicate *p;
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#endif
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{
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fprintf(stderr,"---------------------------------\n");
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dumppred1(0,p);
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fprintf(stderr,"\n");
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}
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#ifdef __USE_PROTOS
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void dumppredtree(Predicate *p)
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#else
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void dumppredtree(p)
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Predicate *p;
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#endif
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{
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fprintf(stderr,"predicate k=%d \"%s\" line %d\n",p->k,p->expr,p->source->line);
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dumpset(p->scontext[1]);
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}
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#ifdef __USE_PROTOS
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void dumppredexpr(Predicate *p)
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#else
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void dumppredexpr(p)
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Predicate *p;
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#endif
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{
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fprintf(stderr," pred expr \"%s\"\n",p->expr);
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}
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#ifdef __USE_PROTOS
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void dt(Tree *t)
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#else
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void dt(t)
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Tree *t;
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#endif
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{
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MR_dumpTreeF(stderr,0,t,5);
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}
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#ifdef __USE_PROTOS
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void d(Node * p)
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#else
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void d(p)
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Node * p;
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#endif
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{
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Junction *j;
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RuleRefNode *r;
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TokNode *t;
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ActionNode *a;
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if (p==NULL) {
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fprintf(stderr,"dumpNode: Node is NULL");
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return;
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};
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switch (p->ntype) {
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case nJunction :
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j = (Junction *) p;
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fprintf(stderr, "Junction (#%d in rule %s line %d) ",j->seq,j->rname,j->line);
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if (j->guess) fprintf(stderr,"guess block ");
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switch (j->jtype ) {
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case aSubBlk :
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fprintf(stderr,"aSubBlk");
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break;
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case aOptBlk :
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fprintf(stderr,"aOptBlk");
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break;
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case aLoopBegin :
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fprintf(stderr,"aLoopBeginBlk");
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break;
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case aLoopBlk :
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fprintf(stderr,"aLoopBlk");
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break;
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case aPlusBlk :
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fprintf(stderr,"aPlusBlk");
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break;
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case EndBlk :
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fprintf(stderr,"EndBlk");
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break;
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case RuleBlk :
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fprintf(stderr,"RuleBlk");
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break;
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case Generic :
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fprintf(stderr,"Generic");
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break;
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case EndRule :
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fprintf(stderr,"EndRule");
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break;
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};
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if (j->halt) fprintf(stderr," halt!");
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if (j->p1) fprintf(stderr," p1 valid");
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if (j->p2) {
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if (j->p2->ntype == nJunction) {
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fprintf(stderr," (p2=#%d)",( (Junction *) j->p2)->seq);
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} else {
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fprintf(stderr," (p2 valid)");
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};
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};
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if (j->ignore) fprintf(stderr, " ignore/plus-block-bypass");
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if (j->fset != NULL && set_deg(*j->fset) != 0) {
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fprintf(stderr,"\nfset:\n");
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dumpset(*j->fset);
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};
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if (j->ftree != NULL) {
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fprintf(stderr,"\nftree:\n");
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preorder(j->ftree);
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};
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fprintf(stderr,"\n");
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break;
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case nRuleRef :
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r = (RuleRefNode *) p;
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fprintf(stderr, "RuleRefNode (in rule %s line %d) to rule %s\n", r->rname,r->line,r->text);
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break;
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case nToken :
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t = (TokNode *) p;
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fprintf(stderr, "TokNode (in rule %s line %d) token %s\n",t->rname,t->line,TerminalString(t->token));
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break;
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case nAction :
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a =(ActionNode *) p;
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if (a->is_predicate) {
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fprintf(stderr, "Predicate (in rule %s line %d) %s",a->rname,a->line,a->action);
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if (a->inverted) fprintf(stderr," action inverted !");
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if (a->guardpred != NULL) {
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fprintf(stderr," guarded");
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dumppredexpr(a->guardpred);
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if (a->ampersandPred) {
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fprintf(stderr," \"&&\" style");
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} else {
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fprintf(stderr," \"=>\" style");
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};
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};
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if (a->predEntry != NULL) fprintf(stderr," predEntry \"%s\" ",a->predEntry->str);
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fprintf(stderr,"\n");
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} else if (a->init_action) {
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fprintf(stderr, "Init-Action (in rule %s line %d) %s\n",a->rname,a->line,a->action);
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} else {
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fprintf(stderr, "Action (in rule %s line %d) %s\n",a->rname,a->line,a->action);
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};
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break;
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};
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}
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#ifdef __USE_PROTOS
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Node * dp1(Node * p)
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#else
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Node * dp1(p)
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Node * p;
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#endif
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{
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Node *result=NULL;
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if (p->ntype == nJunction) {
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result=( (Junction *) p )->p1;
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d(result);
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} else {
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fprintf(stderr,"dp1: Not a Junction node");
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};
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return result;
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}
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#ifdef __USE_PROTOS
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Node * dp2(Node * p)
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#else
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Node * dp2(p)
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Node * p;
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#endif
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{
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Node *result=NULL;
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if (p->ntype == nJunction) {
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result=( (Junction *) p )->p2;
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d(result);
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} else {
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fprintf(stderr,"dp2: Not a Junction node");
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};
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return result;
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}
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#ifdef __USE_PROTOS
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Node * dn(Node * p)
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#else
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Node * dn(p)
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Node * p;
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#endif
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{
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Node *result=NULL;
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if (p->ntype == nRuleRef) {
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result=( (RuleRefNode *)p )->next;
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} else if (p->ntype == nAction) {
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result=( (ActionNode *)p )->next;
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} else if (p->ntype == nToken) {
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result=( (TokNode *)p )->next;
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} else {
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fprintf(stderr,"No next field: Neither a RuleRefNode, ActionNode, nor TokNode");
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};
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if (result != NULL) d(result);
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return result;
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}
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#ifdef __USE_PROTOS
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void df(Node * p)
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#else
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void df(p)
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Node * p;
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#endif
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{
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int count=0;
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Node *next;
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fprintf(stderr,"\n#%d ",++count);
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d(p);
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for (next=p; next != NULL && !isEndRule(next) ; ) {
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fprintf(stderr,"#%d ",++count);
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if (next->ntype == nJunction) {
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next=dp1(next);
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} else {
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next=dn(next);
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};
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};
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}
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#ifdef __USE_PROTOS
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Node * dfn(Node * p,int target)
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#else
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Node * dfn(p,target)
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Node * p;
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int target;
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#endif
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{
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Node *result=NULL;
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int count=0;
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Node *next;
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fprintf(stderr,"#%d ",++count);
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d(p);
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for (next=p; next != NULL && !isEndRule(next) ; ) {
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fprintf(stderr,"#%d ",++count);
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if (next->ntype == nJunction) {
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next=dp1(next);
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} else {
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next=dn(next);
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};
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if (count == target) {
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result=next;
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break;
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};
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};
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return result;
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}
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static int findnodeMatch;
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#ifdef __USE_PROTOS
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Junction *findnode1(Node *n)
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#else
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Junction *findnode1(n)
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Node *n;
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#endif
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{
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Node *next;
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Junction *j;
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Junction *match;
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if (n == NULL) return NULL;
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if (n->ntype == nJunction) {
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j=(Junction *) n;
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if (j->seq == findnodeMatch) return j;
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if (j->jtype == EndRule) return NULL;
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if (j->jtype != RuleBlk && j->jtype != EndBlk) {
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if (j->p2 != NULL && !j->ignore) {
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match=findnode1(j->p2);
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if (match != NULL) return match;
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};
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};
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};
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next=MR_advance(n);
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return findnode1(next);
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}
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#ifdef __USE_PROTOS
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Junction *findnode(int match)
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#else
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Junction *findnode(match)
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int match;
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#endif
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{
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Junction *j;
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Junction *result=NULL;
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findnodeMatch=match;
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for (j=SynDiag; j != NULL; j=(Junction *)j->p2) {
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require (j->ntype == nJunction && j->jtype == RuleBlk,"Not a rule block");
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result=findnode1( (Node *) j);
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if (result != NULL) break;
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};
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if (result != NULL) {
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d( (Node *) result);
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};
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return result;
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}
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