ref: e0c19ae048ae671883fd4d27d5f617c02020bdf5
dir: /sys/src/cmd/spin/tl_parse.c/
/***** tl_spin: tl_parse.c *****/ /* * This file is part of the public release of Spin. It is subject to the * terms in the LICENSE file that is included in this source directory. * Tool documentation is available at http://spinroot.com * * Based on the translation algorithm by Gerth, Peled, Vardi, and Wolper, * presented at the PSTV Conference, held in 1995, Warsaw, Poland 1995. */ #include "tl.h" extern int tl_yylex(void); extern int tl_verbose, tl_errs; int tl_yychar = 0; YYSTYPE tl_yylval; static Node *tl_formula(void); static Node *tl_factor(void); static Node *tl_level(int); static int prec[2][4] = { { U_OPER, V_OPER, 0, 0 }, /* left associative */ { OR, AND, IMPLIES, EQUIV, }, /* left associative */ }; static Node * tl_factor(void) { Node *ptr = ZN; switch (tl_yychar) { case '(': ptr = tl_formula(); if (tl_yychar != ')') tl_yyerror("expected ')'"); tl_yychar = tl_yylex(); break; case NOT: ptr = tl_yylval; tl_yychar = tl_yylex(); ptr->lft = tl_factor(); if (!ptr->lft) { fatal("malformed expression", (char *) 0); } ptr = push_negation(ptr); break; case ALWAYS: tl_yychar = tl_yylex(); ptr = tl_factor(); #ifndef NO_OPT if (ptr->ntyp == FALSE || ptr->ntyp == TRUE) break; /* [] false == false */ if (ptr->ntyp == V_OPER) { if (ptr->lft->ntyp == FALSE) break; /* [][]p = []p */ ptr = ptr->rgt; /* [] (p V q) = [] q */ } #endif ptr = tl_nn(V_OPER, False, ptr); break; #ifdef NXT case NEXT: tl_yychar = tl_yylex(); ptr = tl_factor(); if (ptr->ntyp == TRUE) break; /* X true = true */ ptr = tl_nn(NEXT, ptr, ZN); break; #endif case CEXPR: tl_yychar = tl_yylex(); ptr = tl_factor(); if (ptr->ntyp != PREDICATE) { tl_yyerror("expected {...} after c_expr"); } ptr = tl_nn(CEXPR, ptr, ZN); break; case EVENTUALLY: tl_yychar = tl_yylex(); ptr = tl_factor(); #ifndef NO_OPT if (ptr->ntyp == TRUE || ptr->ntyp == FALSE) break; /* <> true == true */ if (ptr->ntyp == U_OPER && ptr->lft->ntyp == TRUE) break; /* <><>p = <>p */ if (ptr->ntyp == U_OPER) { /* <> (p U q) = <> q */ ptr = ptr->rgt; /* fall thru */ } #endif ptr = tl_nn(U_OPER, True, ptr); break; case PREDICATE: ptr = tl_yylval; tl_yychar = tl_yylex(); break; case TRUE: case FALSE: ptr = tl_yylval; tl_yychar = tl_yylex(); break; } if (!ptr) tl_yyerror("expected predicate"); #if 0 printf("factor: "); tl_explain(ptr->ntyp); printf("\n"); #endif return ptr; } static Node * bin_simpler(Node *ptr) { Node *a, *b; if (ptr) switch (ptr->ntyp) { case U_OPER: #ifndef NO_OPT if (ptr->rgt->ntyp == TRUE || ptr->rgt->ntyp == FALSE || ptr->lft->ntyp == FALSE) { ptr = ptr->rgt; break; } if (isequal(ptr->lft, ptr->rgt)) { /* p U p = p */ ptr = ptr->rgt; break; } if (ptr->lft->ntyp == U_OPER && isequal(ptr->lft->lft, ptr->rgt)) { /* (p U q) U p = (q U p) */ ptr->lft = ptr->lft->rgt; break; } if (ptr->rgt->ntyp == U_OPER && ptr->rgt->lft->ntyp == TRUE) { /* p U (T U q) = (T U q) */ ptr = ptr->rgt; break; } #ifdef NXT /* X p U X q == X (p U q) */ if (ptr->rgt->ntyp == NEXT && ptr->lft->ntyp == NEXT) { ptr = tl_nn(NEXT, tl_nn(U_OPER, ptr->lft->lft, ptr->rgt->lft), ZN); } #endif #endif break; case V_OPER: #ifndef NO_OPT if (ptr->rgt->ntyp == FALSE || ptr->rgt->ntyp == TRUE || ptr->lft->ntyp == TRUE) { ptr = ptr->rgt; break; } if (isequal(ptr->lft, ptr->rgt)) { /* p V p = p */ ptr = ptr->rgt; break; } /* F V (p V q) == F V q */ if (ptr->lft->ntyp == FALSE && ptr->rgt->ntyp == V_OPER) { ptr->rgt = ptr->rgt->rgt; break; } /* p V (F V q) == F V q */ if (ptr->rgt->ntyp == V_OPER && ptr->rgt->lft->ntyp == FALSE) { ptr->lft = False; ptr->rgt = ptr->rgt->rgt; break; } #endif break; case IMPLIES: #ifndef NO_OPT if (isequal(ptr->lft, ptr->rgt)) { ptr = True; break; } #endif ptr = tl_nn(OR, Not(ptr->lft), ptr->rgt); ptr = rewrite(ptr); break; case EQUIV: #ifndef NO_OPT if (isequal(ptr->lft, ptr->rgt)) { ptr = True; break; } #endif a = rewrite(tl_nn(AND, dupnode(ptr->lft), dupnode(ptr->rgt))); b = rewrite(tl_nn(AND, Not(ptr->lft), Not(ptr->rgt))); ptr = tl_nn(OR, a, b); ptr = rewrite(ptr); break; case AND: #ifndef NO_OPT /* p && (q U p) = p */ if (ptr->rgt->ntyp == U_OPER && isequal(ptr->rgt->rgt, ptr->lft)) { ptr = ptr->lft; break; } if (ptr->lft->ntyp == U_OPER && isequal(ptr->lft->rgt, ptr->rgt)) { ptr = ptr->rgt; break; } /* p && (q V p) == q V p */ if (ptr->rgt->ntyp == V_OPER && isequal(ptr->rgt->rgt, ptr->lft)) { ptr = ptr->rgt; break; } if (ptr->lft->ntyp == V_OPER && isequal(ptr->lft->rgt, ptr->rgt)) { ptr = ptr->lft; break; } /* (p U q) && (r U q) = (p && r) U q*/ if (ptr->rgt->ntyp == U_OPER && ptr->lft->ntyp == U_OPER && isequal(ptr->rgt->rgt, ptr->lft->rgt)) { ptr = tl_nn(U_OPER, tl_nn(AND, ptr->lft->lft, ptr->rgt->lft), ptr->lft->rgt); break; } /* (p V q) && (p V r) = p V (q && r) */ if (ptr->rgt->ntyp == V_OPER && ptr->lft->ntyp == V_OPER && isequal(ptr->rgt->lft, ptr->lft->lft)) { ptr = tl_nn(V_OPER, ptr->rgt->lft, tl_nn(AND, ptr->lft->rgt, ptr->rgt->rgt)); break; } #ifdef NXT /* X p && X q == X (p && q) */ if (ptr->rgt->ntyp == NEXT && ptr->lft->ntyp == NEXT) { ptr = tl_nn(NEXT, tl_nn(AND, ptr->rgt->lft, ptr->lft->lft), ZN); break; } #endif if (isequal(ptr->lft, ptr->rgt) /* (p && p) == p */ || ptr->rgt->ntyp == FALSE /* (p && F) == F */ || ptr->lft->ntyp == TRUE) /* (T && p) == p */ { ptr = ptr->rgt; break; } if (ptr->rgt->ntyp == TRUE /* (p && T) == p */ || ptr->lft->ntyp == FALSE) /* (F && p) == F */ { ptr = ptr->lft; break; } /* (p V q) && (r U q) == p V q */ if (ptr->rgt->ntyp == U_OPER && ptr->lft->ntyp == V_OPER && isequal(ptr->lft->rgt, ptr->rgt->rgt)) { ptr = ptr->lft; break; } #endif break; case OR: #ifndef NO_OPT /* p || (q U p) == q U p */ if (ptr->rgt->ntyp == U_OPER && isequal(ptr->rgt->rgt, ptr->lft)) { ptr = ptr->rgt; break; } /* p || (q V p) == p */ if (ptr->rgt->ntyp == V_OPER && isequal(ptr->rgt->rgt, ptr->lft)) { ptr = ptr->lft; break; } /* (p U q) || (p U r) = p U (q || r) */ if (ptr->rgt->ntyp == U_OPER && ptr->lft->ntyp == U_OPER && isequal(ptr->rgt->lft, ptr->lft->lft)) { ptr = tl_nn(U_OPER, ptr->rgt->lft, tl_nn(OR, ptr->lft->rgt, ptr->rgt->rgt)); break; } if (isequal(ptr->lft, ptr->rgt) /* (p || p) == p */ || ptr->rgt->ntyp == FALSE /* (p || F) == p */ || ptr->lft->ntyp == TRUE) /* (T || p) == T */ { ptr = ptr->lft; break; } if (ptr->rgt->ntyp == TRUE /* (p || T) == T */ || ptr->lft->ntyp == FALSE) /* (F || p) == p */ { ptr = ptr->rgt; break; } /* (p V q) || (r V q) = (p || r) V q */ if (ptr->rgt->ntyp == V_OPER && ptr->lft->ntyp == V_OPER && isequal(ptr->lft->rgt, ptr->rgt->rgt)) { ptr = tl_nn(V_OPER, tl_nn(OR, ptr->lft->lft, ptr->rgt->lft), ptr->rgt->rgt); break; } /* (p V q) || (r U q) == r U q */ if (ptr->rgt->ntyp == U_OPER && ptr->lft->ntyp == V_OPER && isequal(ptr->lft->rgt, ptr->rgt->rgt)) { ptr = ptr->rgt; break; } #endif break; } return ptr; } static Node * tl_level(int nr) { int i; Node *ptr = ZN; if (nr < 0) return tl_factor(); ptr = tl_level(nr-1); again: for (i = 0; i < 4; i++) if (tl_yychar == prec[nr][i]) { tl_yychar = tl_yylex(); ptr = tl_nn(prec[nr][i], ptr, tl_level(nr-1)); ptr = bin_simpler(ptr); goto again; } if (!ptr) tl_yyerror("syntax error"); #if 0 printf("level %d: ", nr); tl_explain(ptr->ntyp); printf("\n"); #endif return ptr; } static Node * tl_formula(void) { tl_yychar = tl_yylex(); return tl_level(1); /* 2 precedence levels, 1 and 0 */ } void tl_parse(void) { Node *n; /* tl_verbose = 1; */ n = tl_formula(); if (tl_verbose) { printf("formula: "); dump(n); printf("\n"); } if (tl_Getchar() != -1) { tl_yyerror("syntax error"); tl_errs++; return; } trans(n); }