400 lines
8.0 KiB
C
400 lines
8.0 KiB
C
/* Parser implementation */
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/* For a description, see the comments at end of this file */
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/* XXX To do: error recovery */
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#include "pgenheaders.h"
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#include "assert.h"
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#include "token.h"
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#include "grammar.h"
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#include "node.h"
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#include "parser.h"
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#include "errcode.h"
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#ifdef DEBUG
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extern int debugging;
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#define D(x) if (!debugging); else x
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#else
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#define D(x)
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#endif
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/* STACK DATA TYPE */
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static void s_reset PROTO((stack *));
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static void
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s_reset(s)
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stack *s;
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{
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s->s_top = &s->s_base[MAXSTACK];
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}
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#define s_empty(s) ((s)->s_top == &(s)->s_base[MAXSTACK])
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static int s_push PROTO((stack *, dfa *, node *));
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static int
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s_push(s, d, parent)
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register stack *s;
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dfa *d;
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node *parent;
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{
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register stackentry *top;
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if (s->s_top == s->s_base) {
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fprintf(stderr, "s_push: parser stack overflow\n");
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return -1;
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}
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top = --s->s_top;
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top->s_dfa = d;
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top->s_parent = parent;
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top->s_state = 0;
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return 0;
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}
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#ifdef DEBUG
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static void s_pop PROTO((stack *));
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static void
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s_pop(s)
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register stack *s;
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{
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if (s_empty(s)) {
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fprintf(stderr, "s_pop: parser stack underflow -- FATAL\n");
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abort();
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}
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s->s_top++;
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}
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#else /* !DEBUG */
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#define s_pop(s) (s)->s_top++
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#endif
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/* PARSER CREATION */
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parser_state *
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newparser(g, start)
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grammar *g;
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int start;
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{
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parser_state *ps;
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if (!g->g_accel)
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addaccelerators(g);
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ps = NEW(parser_state, 1);
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if (ps == NULL)
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return NULL;
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ps->p_grammar = g;
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ps->p_tree = newtree(start);
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if (ps->p_tree == NULL) {
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DEL(ps);
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return NULL;
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}
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s_reset(&ps->p_stack);
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(void) s_push(&ps->p_stack, finddfa(g, start), ps->p_tree);
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return ps;
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}
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void
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delparser(ps)
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parser_state *ps;
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{
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/* NB If you want to save the parse tree,
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you must set p_tree to NULL before calling delparser! */
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freetree(ps->p_tree);
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DEL(ps);
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}
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/* PARSER STACK OPERATIONS */
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static int shift PROTO((stack *, int, char *, int, int));
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static int
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shift(s, type, str, newstate, lineno)
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register stack *s;
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int type;
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char *str;
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int newstate;
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int lineno;
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{
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assert(!s_empty(s));
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if (addchild(s->s_top->s_parent, type, str, lineno) == NULL) {
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fprintf(stderr, "shift: no mem in addchild\n");
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return -1;
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}
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s->s_top->s_state = newstate;
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return 0;
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}
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static int push PROTO((stack *, int, dfa *, int, int));
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static int
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push(s, type, d, newstate, lineno)
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register stack *s;
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int type;
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dfa *d;
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int newstate;
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int lineno;
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{
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register node *n;
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n = s->s_top->s_parent;
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assert(!s_empty(s));
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if (addchild(n, type, (char *)NULL, lineno) == NULL) {
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fprintf(stderr, "push: no mem in addchild\n");
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return -1;
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}
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s->s_top->s_state = newstate;
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return s_push(s, d, CHILD(n, NCH(n)-1));
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}
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/* PARSER PROPER */
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static int classify PROTO((grammar *, int, char *));
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static int
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classify(g, type, str)
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grammar *g;
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register int type;
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char *str;
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{
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register int n = g->g_ll.ll_nlabels;
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if (type == NAME) {
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register char *s = str;
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register label *l = g->g_ll.ll_label;
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register int i;
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for (i = n; i > 0; i--, l++) {
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if (l->lb_type == NAME && l->lb_str != NULL &&
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l->lb_str[0] == s[0] &&
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strcmp(l->lb_str, s) == 0) {
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D(printf("It's a keyword\n"));
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return n - i;
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}
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}
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}
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{
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register label *l = g->g_ll.ll_label;
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register int i;
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for (i = n; i > 0; i--, l++) {
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if (l->lb_type == type && l->lb_str == NULL) {
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D(printf("It's a token we know\n"));
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return n - i;
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}
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}
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}
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D(printf("Illegal token\n"));
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return -1;
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}
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int
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addtoken(ps, type, str, lineno)
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register parser_state *ps;
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register int type;
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char *str;
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int lineno;
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{
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register int ilabel;
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D(printf("Token %s/'%s' ... ", tok_name[type], str));
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/* Find out which label this token is */
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ilabel = classify(ps->p_grammar, type, str);
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if (ilabel < 0)
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return E_SYNTAX;
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/* Loop until the token is shifted or an error occurred */
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for (;;) {
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/* Fetch the current dfa and state */
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register dfa *d = ps->p_stack.s_top->s_dfa;
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register state *s = &d->d_state[ps->p_stack.s_top->s_state];
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D(printf(" DFA '%s', state %d:",
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d->d_name, ps->p_stack.s_top->s_state));
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/* Check accelerator */
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if (s->s_lower <= ilabel && ilabel < s->s_upper) {
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register int x = s->s_accel[ilabel - s->s_lower];
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if (x != -1) {
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if (x & (1<<7)) {
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/* Push non-terminal */
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int nt = (x >> 8) + NT_OFFSET;
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int arrow = x & ((1<<7)-1);
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dfa *d1 = finddfa(ps->p_grammar, nt);
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if (push(&ps->p_stack, nt, d1,
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arrow, lineno) < 0) {
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D(printf(" MemError: push.\n"));
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return E_NOMEM;
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}
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D(printf(" Push ...\n"));
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continue;
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}
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/* Shift the token */
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if (shift(&ps->p_stack, type, str,
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x, lineno) < 0) {
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D(printf(" MemError: shift.\n"));
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return E_NOMEM;
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}
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D(printf(" Shift.\n"));
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/* Pop while we are in an accept-only state */
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while (s = &d->d_state
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[ps->p_stack.s_top->s_state],
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s->s_accept && s->s_narcs == 1) {
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D(printf(" Direct pop.\n"));
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s_pop(&ps->p_stack);
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if (s_empty(&ps->p_stack)) {
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D(printf(" ACCEPT.\n"));
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return E_DONE;
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}
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d = ps->p_stack.s_top->s_dfa;
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}
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return E_OK;
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}
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}
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if (s->s_accept) {
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/* Pop this dfa and try again */
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s_pop(&ps->p_stack);
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D(printf(" Pop ...\n"));
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if (s_empty(&ps->p_stack)) {
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D(printf(" Error: bottom of stack.\n"));
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return E_SYNTAX;
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}
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continue;
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}
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/* Stuck, report syntax error */
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D(printf(" Error.\n"));
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return E_SYNTAX;
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}
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}
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#ifdef DEBUG
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/* DEBUG OUTPUT */
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void
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dumptree(g, n)
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grammar *g;
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node *n;
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{
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int i;
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if (n == NULL)
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printf("NIL");
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else {
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label l;
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l.lb_type = TYPE(n);
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l.lb_str = TYPE(str);
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printf("%s", labelrepr(&l));
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if (ISNONTERMINAL(TYPE(n))) {
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printf("(");
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for (i = 0; i < NCH(n); i++) {
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if (i > 0)
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printf(",");
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dumptree(g, CHILD(n, i));
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}
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printf(")");
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}
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}
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}
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void
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showtree(g, n)
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grammar *g;
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node *n;
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{
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int i;
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if (n == NULL)
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return;
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if (ISNONTERMINAL(TYPE(n))) {
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for (i = 0; i < NCH(n); i++)
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showtree(g, CHILD(n, i));
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}
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else if (ISTERMINAL(TYPE(n))) {
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printf("%s", tok_name[TYPE(n)]);
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if (TYPE(n) == NUMBER || TYPE(n) == NAME)
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printf("(%s)", STR(n));
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printf(" ");
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}
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else
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printf("? ");
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}
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void
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printtree(ps)
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parser_state *ps;
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{
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if (debugging) {
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printf("Parse tree:\n");
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dumptree(ps->p_grammar, ps->p_tree);
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printf("\n");
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printf("Tokens:\n");
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showtree(ps->p_grammar, ps->p_tree);
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printf("\n");
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}
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printf("Listing:\n");
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listtree(ps->p_tree);
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printf("\n");
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}
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#endif /* DEBUG */
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/*
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Description
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-----------
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The parser's interface is different than usual: the function addtoken()
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must be called for each token in the input. This makes it possible to
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turn it into an incremental parsing system later. The parsing system
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constructs a parse tree as it goes.
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A parsing rule is represented as a Deterministic Finite-state Automaton
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(DFA). A node in a DFA represents a state of the parser; an arc represents
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a transition. Transitions are either labeled with terminal symbols or
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with non-terminals. When the parser decides to follow an arc labeled
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with a non-terminal, it is invoked recursively with the DFA representing
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the parsing rule for that as its initial state; when that DFA accepts,
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the parser that invoked it continues. The parse tree constructed by the
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recursively called parser is inserted as a child in the current parse tree.
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The DFA's can be constructed automatically from a more conventional
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language description. An extended LL(1) grammar (ELL(1)) is suitable.
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Certain restrictions make the parser's life easier: rules that can produce
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the empty string should be outlawed (there are other ways to put loops
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or optional parts in the language). To avoid the need to construct
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FIRST sets, we can require that all but the last alternative of a rule
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(really: arc going out of a DFA's state) must begin with a terminal
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symbol.
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As an example, consider this grammar:
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expr: term (OP term)*
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term: CONSTANT | '(' expr ')'
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The DFA corresponding to the rule for expr is:
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------->.---term-->.------->
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^ |
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\----OP----/
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The parse tree generated for the input a+b is:
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(expr: (term: (NAME: a)), (OP: +), (term: (NAME: b)))
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*/
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