#include #include #include "term.h" #include "termlist.h" #include "mgu.h" #include "type.h" #include "debug.h" #include "specialterm.h" #include "switches.h" /* Most General Unifier Unification etc. New version yields a termlist with substituted variables, which can later be reset to NULL. */ /** * switches.match * 0 typed * 1 basic typeflaws * 2 all typeflaws */ void showSubst (Term t) { #ifdef DEBUG if (!DEBUGL (5)) return; indent (); eprintf ("Substituting "); termPrint (t); eprintf (", typed "); termlistPrint (t->stype); if (realTermLeaf (t->subst)) { eprintf ("->"); termlistPrint (t->subst->stype); } else { eprintf (", composite term"); } if (t->type != VARIABLE) { eprintf (" (bound roleconstant)"); } eprintf ("\n"); #endif } //! See if this is preferred substitution /** * By default, ta->tb will map. Returning 0 (false) will swap them. */ int preferSubstitutionOrder (Term ta, Term tb) { if (termlistLength (ta->stype) == 1 && inTermlist (ta->stype, TERM_Agent)) { /** * If the first one is an agent type, we prefer swapping. */ return 0; } // Per default, leave it as it is. return 1; } //! See if a substitution is valid __inline__ int goodsubst (Term tvar, Term tsubst) { Term tbuf; int res; tbuf = tvar->subst; tvar->subst = tsubst; res = checkTypeTerm (tvar); tvar->subst = tbuf; return res; } //! Undo all substitutions in a list of variables. /** * The termlist should contain only variables. */ void termlistSubstReset (Termlist tl) { while (tl != NULL) { tl->term->subst = NULL; tl = tl->next; } } //! Most general unifier iteration /** * Try to determine the most general unifier of two terms, if so calls function. * * The callback receives a list of variables, that were previously open, but are now closed * in such a way that the two terms unify. * * The callback must return true for the iteration to proceed: if it returns false, a single call would abort the scan. * The return value shows this: it is false if the scan was aborted, and true if not. */ int unify (Term t1, Term t2, Termlist tl, int (*callback) (Termlist)) { int callsubst (Termlist tl, Term t, Term tsubst) { int proceed; t->subst = tsubst; #ifdef DEBUG showSubst (t); #endif tl = termlistAdd (tl, t); proceed = callback (tl); tl = termlistDelTerm (tl); t->subst = NULL; return proceed; } /* added for speed */ t1 = deVar (t1); t2 = deVar (t2); if (t1 == t2) { return callback (tl); } if (!(hasTermVariable (t1) || hasTermVariable (t2))) { // None has a variable if (isTermEqual (t1, t2)) { // Equal! return callback (tl); } else { // Can never be fixed, no variables return true; } } /* * Distinguish a special case where both are unbound variables that will be * connected, and I want to give one priority over the other for readability. * * Because t1 and t2 have been deVar'd means that if they are variables, they * are also unbound. */ if (realTermVariable (t1) && realTermVariable (t2) && goodsubst (t1, t2)) { /* Both are unbound variables. Decide. * * The plan: t1->subst will point to t2. But maybe we prefer the other * way around? */ if (preferSubstitutionOrder (t2, t1)) { Term t3; // Swappy. t3 = t1; t1 = t2; t2 = t3; } return callsubst (tl, t1, t2); } /* symmetrical tests for single variable. */ if (realTermVariable (t2)) { if (termSubTerm (t1, t2) || !goodsubst (t2, t1)) return true; else { return callsubst (tl, t2, t1); } } if (realTermVariable (t1)) { if (termSubTerm (t2, t1) || !goodsubst (t1, t2)) return true; else { return callsubst (tl, t1, t2); } } /* left & right are compounds with variables */ if (t1->type != t2->type) return true; /* identical compound types */ /* encryption first */ if (realTermEncrypt (t1)) { int unify_combined_enc (Termlist tl) { // now the keys are unified (subst in this tl) // and we try the inner terms return unify (TermOp (t1), TermOp (t2), tl, callback); } return unify (TermKey (t1), TermKey (t2), tl, unify_combined_enc); } /* tupling second non-associative version ! TODO other version */ if (isTermTuple (t1)) { int unify_combined_tup (Termlist tl) { // now the keys are unified (subst in this tl) // and we try the inner terms return unify (TermOp2 (t1), TermOp2 (t2), tl, callback); } return unify (TermOp1 (t1), TermOp1 (t2), tl, unify_combined_tup); } return true; } //! Subterm unification /** * Try to unify (a subterm of) tbig with tsmall. * * Callback is called with a list of substitutions, and a list of terms that * need to be decrypted in order for this to work. * * E.g. subtermUnify ( {{m}k1}k2, m ) yields a list : {{m}k1}k2, {m}k1 (where * the {m}k1 is the last added node to the list) * * The callback should return true for the iteration to proceed, or false to abort. * The final result is this flag. */ int subtermUnify (Term tbig, Term tsmall, Termlist tl, Termlist keylist, int (*callback) (Termlist, Termlist)) { int proceed; int keycallback (Termlist tl) { return callback (tl, keylist); } proceed = true; // Devar tbig = deVar (tbig); tsmall = deVar (tsmall); // Three options: // 1. simple unification proceed = proceed && unify (tbig, tsmall, tl, keycallback); // [2/3]: complex if (switches.intruder) { // 2. interm unification // Only if there is an intruder if (realTermTuple (tbig)) { proceed = proceed && subtermUnify (TermOp1 (tbig), tsmall, tl, keylist, callback); proceed = proceed && subtermUnify (TermOp2 (tbig), tsmall, tl, keylist, callback); } // 3. unification with encryption needed if (realTermEncrypt (tbig)) { // extend the keylist keylist = termlistAdd (keylist, tbig); proceed = proceed && subtermUnify (TermOp (tbig), tsmall, tl, keylist, callback); // remove last item again keylist = termlistDelTerm (keylist); } } return proceed; } //! Most general unifier. /** * Try to determine the most general unifier of two terms. * Resulting termlist must be termlistDelete'd. * *@return Returns a list of variables, that were previously open, but are now closed * in such a way that the two terms unify. Returns \ref MGUFAIL if it is impossible. * The termlist should be deleted. */ Termlist termMguTerm (Term t1, Term t2) { /* added for speed */ t1 = deVar (t1); t2 = deVar (t2); if (t1 == t2) return NULL; if (!(hasTermVariable (t1) || hasTermVariable (t2))) { if (isTermEqual (t1, t2)) { return NULL; } else { return MGUFAIL; } } /* * Distinguish a special case where both are unbound variables that will be * connected, and I want to give one priority over the other for readability. * * Because t1 and t2 have been deVar'd means that if they are variables, they * are also unbound. */ if (realTermVariable (t1) && realTermVariable (t2) && goodsubst (t1, t2)) { /* Both are unbound variables. Decide. * * The plan: t1->subst will point to t2. But maybe we prefer the other * way around? */ if (preferSubstitutionOrder (t2, t1)) { Term t3; // Swappy. t3 = t1; t1 = t2; t2 = t3; } t1->subst = t2; #ifdef DEBUG showSubst (t1); #endif return termlistAdd (NULL, t1); } /* symmetrical tests for single variable. */ if (realTermVariable (t2)) { if (termSubTerm (t1, t2) || !goodsubst (t2, t1)) return MGUFAIL; else { t2->subst = t1; #ifdef DEBUG showSubst (t2); #endif return termlistAdd (NULL, t2); } } if (realTermVariable (t1)) { if (termSubTerm (t2, t1) || !goodsubst (t1, t2)) return MGUFAIL; else { t1->subst = t2; #ifdef DEBUG showSubst (t1); #endif return termlistAdd (NULL, t1); } } /* left & right are compounds with variables */ if (t1->type != t2->type) return MGUFAIL; /* identical compounds */ /* encryption first */ if (realTermEncrypt (t1)) { Termlist tl1, tl2; tl1 = termMguTerm (TermKey (t1), TermKey (t2)); if (tl1 == MGUFAIL) { return MGUFAIL; } else { tl2 = termMguTerm (TermOp (t1), TermOp (t2)); if (tl2 == MGUFAIL) { termlistSubstReset (tl1); termlistDelete (tl1); return MGUFAIL; } else { return termlistConcat (tl1, tl2); } } } /* tupling second non-associative version ! TODO other version */ if (isTermTuple (t1)) { Termlist tl1, tl2; tl1 = termMguTerm (TermOp1 (t1), TermOp1 (t2)); if (tl1 == MGUFAIL) { return MGUFAIL; } else { tl2 = termMguTerm (TermOp2 (t1), TermOp2 (t2)); if (tl2 == MGUFAIL) { termlistSubstReset (tl1); termlistDelete (tl1); return MGUFAIL; } else { return termlistConcat (tl1, tl2); } } } return MGUFAIL; } //! Most general interm unifiers of t1 interm t2 /** * Try to determine the most general interm unifiers of two terms. *@returns Nothing. Iteration gets termlist of substitutions. */ int termMguInTerm (Term t1, Term t2, int (*iterator) (Termlist)) { Termlist tl; int flag; flag = 1; t2 = deVar (t2); if (t2 != NULL) { if (realTermTuple (t2)) { // t2 is a tuple, consider interm options as well. flag = flag && termMguInTerm (t1, TermOp1 (t2), iterator); flag = flag && termMguInTerm (t1, TermOp2 (t2), iterator); } // simple clause or combined tl = termMguTerm (t1, t2); if (tl != MGUFAIL) { // Iterate flag = flag && iterator (tl); // Reset variables termlistSubstReset (tl); // Remove list termlistDelete (tl); } } else { if (deVar (t1) != NULL) { flag = 0; } } return flag; } //! Most general subterm unifiers of smallterm subterm bigterm /** * Try to determine the most general subterm unifiers of two terms. *@returns Nothing. Iteration gets termlist of subst, and list of keys needed * to decrypt. This termlist does not need to be deleted, because it is handled * by the mguSubTerm itself. */ int termMguSubTerm (Term smallterm, Term bigterm, int (*iterator) (Termlist, Termlist), Termlist inverses, Termlist cryptlist) { int flag; flag = 1; smallterm = deVar (smallterm); bigterm = deVar (bigterm); if (bigterm != NULL) { Termlist tl; if (!realTermLeaf (bigterm)) { if (realTermTuple (bigterm)) { // 'simple' tuple flag = flag && termMguSubTerm (smallterm, TermOp1 (bigterm), iterator, inverses, cryptlist); flag = flag && termMguSubTerm (smallterm, TermOp2 (bigterm), iterator, inverses, cryptlist); } else { // Must be encryption Term keyneeded; keyneeded = inverseKey (inverses, TermKey (bigterm)); // We can never produce the TERM_Hidden key, thus, this is not a valid iteration. if (!isTermEqual (keyneeded, TERM_Hidden)) { cryptlist = termlistAdd (cryptlist, bigterm); // Append, so the last encrypted term in the list is the most 'inner' one, and the first is the outer one. // Recurse flag = flag && termMguSubTerm (smallterm, TermOp (bigterm), iterator, inverses, cryptlist); cryptlist = termlistDelTerm (cryptlist); } termDelete (keyneeded); } } // simple clause or combined tl = termMguTerm (smallterm, bigterm); if (tl != MGUFAIL) { // Iterate flag = flag && iterator (tl, cryptlist); // Reset variables termlistSubstReset (tl); // Remove list termlistDelete (tl); } } else { if (smallterm != NULL) { flag = 0; } } return flag; } //! Check if role terms might match in some way /** * Interesting case: role names are variables here, so they always match. We catch that case by inspecting the variable list. */ int checkRoletermMatch (const Term t1, const Term t2, const Termlist notmapped) { Termlist tl; // simple clause or combined tl = termMguTerm (t1, t2); if (tl == MGUFAIL) { return false; } else { int result; Termlist vl; result = true; // Reset variables termlistSubstReset (tl); // Check variable list etc: should not contain mapped role names vl = tl; while (vl != NULL) { // This term should not be in the notmapped list if (inTermlist (notmapped, vl->term)) { result = false; break; } vl = vl->next; } // Remove list termlistDelete (tl); return result; } }