/** * *@file prune_theorems.c * * Prune stuff based on theorems. * Pruning leaves complete results. * */ #include "system.h" #include "list.h" #include "switches.h" #include "binding.h" #include "specialterm.h" #include "hidelevel.h" extern Protocol INTRUDER; extern int proofDepth; extern int max_encryption_level; //! Check locals occurrence /* * Returns true if the order is correct */ int correctLocalOrder (const System sys) { int flag; int checkRun (int r1) { int checkTerm (Term t) { if (!isTermVariable (t)) { int r2; int e1, e2; // t is a term from r2 that occurs in r1 r2 = TermRunid (t); e1 = firstOccurrence (sys, r1, t, ANYEVENT); if (e1 >= 0) { if (roledef_shift (sys->runs[r1].start, e1)->type == READ) { e2 = firstOccurrence (sys, r2, t, SEND); if (e2 >= 0) { // thus, it should not be the case that e1 occurs before e2 if (isDependEvent (r1, e1, r2, e2)) { // That's not good! if (switches.output == PROOF) { indentPrint (); eprintf ("Pruned because ordering for term "); termSubstPrint (t); eprintf (" cannot be correct: the first send r%ii%i occurs after the read r%ii%i.\n", r2, e2, r1, e1); } flag = false; return false; } } else { globalError++; eprintf ("Error: term "); termSubstPrint (t); eprintf (" from run %i should occur in run %i, but it doesn't.\n", r2, r2); globalError--; error ("Abort"); } } else { // not a read first? That's definitely impossible (can be caused by choices globalError++; eprintf ("Error: term "); termSubstPrint (t); eprintf (" from run %i should occur in run %i first in a READ event, but it occurs first in event %i.\n", r2, r1, e1); eprintf ("It occurs first in "); roledefPrint (eventRoledef (sys, r1, e1)); eprintf ("\n"); eprintf ("which starts with "); roledefPrint (eventRoledef (sys, r1, 0)); eprintf ("\n"); globalError--; error ("Abort"); } } else { globalError++; eprintf ("Error: term "); termSubstPrint (t); eprintf (" from run %i should occur in run %i, but it doesn't.\n", r2, r1); globalError--; error ("Abort"); } return true; } } return iterateLocalToOther (sys, r1, checkTerm); } flag = true; iterateRegularRuns (sys, checkRun); return flag; } //! Check initiator roles /** * Returns false iff an agent type is wrong */ int initiatorAgentsType (const System sys) { int run; run = 0; while (run < sys->maxruns) { // Only for initiators if (sys->runs[run].role->initiator) { Termlist agents; agents = sys->runs[run].rho; while (agents != NULL) { if (!goodAgentType (agents->term)) { return false; } agents = agents->next; } } run++; } return true; // seems to be okay } //! Prune determination because of theorems /** * When something is pruned because of this function, the state space is still * considered to be complete. * *@returns true iff this state is invalid because of a theorem */ int prune_theorems (const System sys) { Termlist tl; List bl; int run; // Check all types of the local agents according to the matching type if (!checkAllSubstitutions (sys)) { if (switches.output == PROOF) { indentPrint (); eprintf ("Pruned because some local variable was incorrectly subsituted.\n"); } return true; } // Check if all actors are agents for responders (initiators come next) run = 0; while (run < sys->maxruns) { if (!sys->runs[run].role->initiator) { Term actor; actor = agentOfRun (sys, run); if (!goodAgentType (actor)) { if (switches.output == PROOF) { indentPrint (); eprintf ("Pruned because the actor "); termPrint (actor); eprintf (" of run %i is not of a compatible type.\n", run); } return true; } } run++; } // Prune if any initiator run talks to itself /** * This effectively disallows Alice from talking to Alice, for all * initiators. We still allow it for responder runs, because we assume the * responder is not checking this. */ if (switches.initUnique) { if (selfInitiators (sys) > 0) { // XXX TODO // Still need to fix proof output for this // // Pruning because some agents are equal for this role. return true; } } if (switches.respUnique) { if (selfResponders (sys) > 0) { // XXX TODO // Still need to fix proof output for this // // Pruning because some agents are equal for this role. return true; } } // Prune wrong agents type for initators if (!initiatorAgentsType (sys)) { if (switches.output == PROOF) { indentPrint (); eprintf ("Pruned: an initiator role does not have the correct type for one of its agents.\n"); } return true; } // Check if all agents of the main run are valid if (!isRunTrusted (sys, 0)) { if (switches.output == PROOF) { indentPrint (); eprintf ("Pruned because all agents of the claim run must be trusted.\n"); } return true; } // Check if the actors of all other runs are not untrusted if (sys->untrusted != NULL) { int run; run = 1; while (run < sys->maxruns) { if (sys->runs[run].protocol != INTRUDER) { if (sys->runs[run].rho != NULL) { Term actor; actor = agentOfRun (sys, run); if (actor == NULL) { error ("Agent of run %i is NULL", run); } if (!isAgentTrusted (sys, actor)) { if (switches.output == PROOF) { indentPrint (); eprintf ("Pruned because the actor of run %i is untrusted.\n", run); } return true; } } else { Protocol p; globalError++; eprintf ("Run %i: ", run); role_name_print (run); eprintf (" has an empty agents list.\n"); eprintf ("protocol->rolenames: "); p = (Protocol) sys->runs[run].protocol; termlistPrint (p->rolenames); eprintf ("\n"); error ("Aborting."); globalError--; return true; } } run++; } } // Check for c-minimality { if (!bindings_c_minimal ()) { if (switches.output == PROOF) { indentPrint (); eprintf ("Pruned because this is not <=c-minimal.\n"); } return true; } } /* * Check for correct orderings involving local constants */ if (!(switches.experimental & 8)) { if (!correctLocalOrder (sys)) { if (switches.output == PROOF) { indentPrint (); eprintf ("Pruned because this does not have the correct local order.\n"); } return true; } } /** * Check whether the bindings are valid */ bl = sys->bindings; while (bl != NULL) { Binding b; b = bl->data; // Check for "Hidden" interm goals //! @todo in the future, this can be subsumed by adding TERM_Hidden to the hidelevel constructs if (termInTerm (b->term, TERM_Hidden)) { // Prune the state: we can never meet this if (switches.output == PROOF) { indentPrint (); eprintf ("Pruned because intruder can never construnct "); termPrint (b->term); eprintf ("\n"); } return true; } if (switches.experimental & 4) { // Check for SK-type function occurrences //!@todo Needs a LEMMA, although this seems to be quite straightforward to prove. // The idea is that functions are never sent as a whole, but only used in applications. //! @todo Subsumed by hidelevel lemma later if (isTermFunctionName (b->term)) { if (!inKnowledge (sys->know, b->term)) { // Not in initial knowledge of the intruder if (switches.output == PROOF) { indentPrint (); eprintf ("Pruned because the function "); termPrint (b->term); eprintf (" is not known initially to the intruder.\n"); } return true; } } } // Check for encryption levels /* * if (switches.match < 2 *! @todo Doesn't work yet as desired for Tickets. Prove lemma first. */ if (switches.experimental & 2) { if (!hasTicketSubterm (b->term)) { if (term_encryption_level (b->term) > max_encryption_level) { // Prune: we do not need to construct such terms if (switches.output == PROOF) { indentPrint (); eprintf ("Pruned because the encryption level of "); termPrint (b->term); eprintf (" is too high.\n"); } return true; } } } // To be on the safe side, we currently limit the encryption level to two. This is not a problem for known attacks, but should be addressed more carefully at some point. /** * @todo Fix untyped variables reasoning */ if (term_encryption_level (b->term) > 2) { return true; } /** * Prune on the basis of hidelevel lemma */ if (hidelevelImpossible (sys, b->term)) { // Prune: we do not need to construct such terms if (switches.output == PROOF) { indentPrint (); eprintf ("Pruned because the hidelevel of "); termPrint (b->term); eprintf (" is impossible to satisfy.\n"); } return true; } bl = bl->next; } /* check for singular roles */ run = 0; while (run < sys->maxruns) { if (sys->runs[run].role->singular) { // This is a singular role: it therefore should not occur later on again. int run2; Term rolename; rolename = sys->runs[run].role->nameterm; run2 = run + 1; while (run2 < sys->maxruns) { Term rolename2; rolename2 = sys->runs[run2].role->nameterm; if (isTermEqual (rolename, rolename2)) { // This is not allowed: the singular role occurs twice in the semitrace. // Thus we prune. if (switches.output == PROOF) { indentPrint (); eprintf ("Pruned because the singular role "); termPrint (rolename); eprintf (" occurs more than once in the semitrace.\n"); } return true; } run2++; } } run++; } return false; }