/** * Handle bindings for Arache engine. */ #include "list.h" #include "role.h" #include "label.h" #include "system.h" #include "binding.h" #include "warshall.h" #include "debug.h" #include "term.h" #include "termmap.h" #include "arachne.h" #include "switches.h" #include "depend.h" #ifndef OSXHOST #include #endif static System sys; //!< local storage of system pointer extern Protocol INTRUDER; //!< The intruder protocol extern Role I_M; //!< special role; precedes all other events always /* * * Assist stuff * */ //! Create mem for binding Binding binding_create (Term term, int run_to, int ev_to) { Binding b; b = malloc (sizeof (struct binding)); b->done = false; b->blocked = false; b->run_from = -1; b->ev_from = -1; b->run_to = run_to; b->ev_to = ev_to; b->term = term; b->level = 0; return b; } //! Remove mem for binding void binding_destroy (Binding b) { if (b->done) { goal_unbind (b); } free (b); } /* * * Main * */ //! Init module void bindingInit (const System mysys) { sys = mysys; sys->bindings = NULL; dependInit (sys); } //! Close up void bindingDone () { int delete (Binding b) { binding_destroy (b); return true; } list_iterate (sys->bindings, delete); list_destroy (sys->bindings); dependDone (sys); } /** * * Externally available functions * */ //! Print a binding (given a binding list pointer) int binding_print (const Binding b) { if (b->done) eprintf ("Binding (%i,%i) --( ", b->run_from, b->ev_from); else eprintf ("Unbound --( "); termPrint (b->term); eprintf (" )->> (%i,%i)", b->run_to, b->ev_to); if (b->blocked) eprintf ("[blocked]"); return true; } //! Bind a goal (true if success, false if it must be pruned) int goal_bind (const Binding b, const int run, const int ev) { if (b->blocked) { error ("Trying to bind a blocked goal."); } if (!b->done) { #ifdef DEBUG if (run >= sys->maxruns || sys->runs[run].step <= ev) { globalError++; eprintf ("For term: "); termPrint (b->term); eprintf (" needed for r%ii%i.\n", b->run_to, b->ev_to); eprintf ("Current limits: %i runs, %i events for this run.\n", sys->maxruns, sys->runs[run].step); globalError--; error ("trying to bind to something not yet in the semistate: r%ii%i.", run, ev); } #endif b->run_from = run; b->ev_from = ev; if (dependPushEvent (run, ev, b->run_to, b->ev_to)) { b->done = true; if (switches.output == PROOF) { indentPrint (); binding_print (b); eprintf ("\n"); } return true; } } else { globalError++; binding_print (b); error ("Trying to bind a bound goal again."); } return false; } //! Unbind a goal void goal_unbind (const Binding b) { if (b->done) { dependPopEvent (); b->done = false; } else { error ("Trying to unbind an unbound goal again."); } } //! Bind a goal as a dummy (block) /** * Especially made for tuple expansion */ int binding_block (Binding b) { if (!b->blocked) { b->blocked = true; return true; } else { error ("Trying to block a goal again."); } } //! Unblock a binding int binding_unblock (Binding b) { if (b->blocked) { b->blocked = false; return true; } else { error ("Trying to unblock a non-blocked goal."); } } //! Add a goal /** * The int parameter 'level' is just to store additional info. Here, it stores priorities for a goal. * Higher level goals will be selected first. Typically, a normal goal is level 0, a key is 1. * * Returns the number of added goals (sometimes unfolding tuples) */ int goal_add (Term term, const int run, const int ev, const int level) { term = deVar (term); #ifdef DEBUG if (term == NULL) { globalError++; roledefPrint (eventRoledef (sys, run, ev)); eprintf ("\n"); globalError--; error ("Trying to add an emtpy goal term to r%ii%i, with level %i.", run, ev, level); } if (run >= sys->maxruns) error ("Trying to add a goal for a run that does not exist."); if (ev >= sys->runs[run].step) error ("Trying to add a goal for an event that is not in the semistate yet."); #endif if (switches.intruder && realTermTuple (term)) { // Only split if there is an intruder return goal_add (TermOp1 (term), run, ev, level) + goal_add (TermOp2 (term), run, ev, level); } else { // Determine whether we already had it int createnew; int testSame (void *data) { Binding b; b = (Binding) data; if (isTermEqual (b->term, term)) { // binding of same term if (run == b->run_to && ev == b->ev_to) { // identical binding createnew = false; } } return true; } createnew = true; list_iterate (sys->bindings, testSame); if (createnew) { // Add a new binding Binding b; b = binding_create (term, run, ev); b->level = level; sys->bindings = list_insert (sys->bindings, b); #ifdef DEBUG if (DEBUGL (3)) { eprintf ("Adding new binding for "); termPrint (term); eprintf (" to run %i, ev %i.\n", run, ev); } #endif return 1; } } return 0; } //! Remove a goal void goal_remove_last (int n) { while (n > 0) { if (sys->bindings != NULL) { Binding b; b = (Binding) sys->bindings->data; binding_destroy (b); sys->bindings = list_delete (sys->bindings); n--; } else { error ("goal_remove_last error: trying to remove %i too many bindings.", n); } } } //! Determine whether some label set is ordered w.r.t. send/read order. /** * Assumes all these labels exist in the system, within length etc, and that the run mappings are valid. */ int labels_ordered (Termmap runs, Termlist labels) { while (labels != NULL) { // Given this label, and the mapping of runs, we want to know if the order is okay. Thus, we need to know sendrole and readrole Labelinfo linfo; int send_run, send_ev, read_run, read_ev; int get_index (const int run) { Roledef rd; int i; i = 0; rd = sys->runs[run].start; while (rd != NULL && !isTermEqual (rd->label, labels->term)) { rd = rd->next; i++; } #ifdef DEBUG if (rd == NULL) error ("Could not locate send or read for label, after niagree holds, to test for order."); #endif return i; } linfo = label_find (sys->labellist, labels->term); if (!linfo->ignore) { send_run = termmapGet (runs, linfo->sendrole); read_run = termmapGet (runs, linfo->readrole); send_ev = get_index (send_run); read_ev = get_index (read_run); if (!isDependEvent (send_run, send_ev, read_run, read_ev)) { // Not ordered; false return false; } } // Proceed labels = labels->next; } return true; } //! Check whether the binding denotes a sensible thing such that we can use run_from and ev_from int valid_binding (Binding b) { if (b->done && (!b->blocked)) return true; else return false; } //! Iterate over all bindings /** * Iterator should return true to proceed */ int iterate_bindings (int (*func) (Binding b)) { List bl; for (bl = sys->bindings; bl != NULL; bl = bl->next) { Binding b; b = (Binding) bl->data; if (!func (b)) { return false; } } return true; } //! Iterate over preceding bindings (this does not include stuff bound to the same destination) /** * Iterator should return true to proceed */ int iterate_preceding_bindings (const int run, const int ev, int (*func) (Binding b)) { int precs (Binding b) { if (isDependEvent (b->run_to, b->ev_to, run, ev)) { return func (b); } return true; } return iterate_bindings (precs); } //! Check for unique origination /* * Contrary to a previous version, we simply check for unique origination. * This immediately takes care of any 'occurs before' things. Complexity is N * log N. * * Each term should originate only at one point (thus in one binding) * *@returns True, if it's okay. If false, it needs to be pruned. */ int unique_origination () { List bl; bl = sys->bindings; while (bl != NULL) { Binding b; b = (Binding) bl->data; // Check for a valid binding; it has to be 'done' and sensibly bound (not as in tuple expanded stuff) if (valid_binding (b)) { Termlist terms; terms = tuple_to_termlist (b->term); if (terms != NULL) { /* Apparently this is a good term. * Now we check whether it occurs in any previous bindings as well. */ List bl2; bl2 = sys->bindings; while (bl2 != bl) { Binding b2; b2 = (Binding) bl2->data; if (valid_binding (b2)) { Termlist terms2, sharedterms; if (switches.intruder) { // For intruder we work with sets here terms2 = tuple_to_termlist (b2->term); } else { // For regular agents we use terms terms2 = termlistAdd (NULL, b2->term); } sharedterms = termlistConjunct (terms, terms2); // Compare terms if (sharedterms != NULL) { // Apparently, this binding shares a term. // Equal terms should originate at the same point if (b->run_from != b2->run_from || b->ev_from != b2->ev_from) { // Not equal: thus no unique origination. return false; } } termlistDelete (terms2); termlistDelete (sharedterms); } bl2 = bl2->next; } } termlistDelete (terms); } bl = bl->next; } return true; } //! Prune invalid state w.r.t. <=C minimal requirement /** * Intuition says this can be done a lot more efficient. Luckily this is the prototype. * *@returns True, if it's okay. If false, it needs to be pruned. */ int bindings_c_minimal () { if (!unique_origination ()) { return false; } { List bl; // For all goals bl = sys->bindings; while (bl != NULL) { Binding b; b = (Binding) bl->data; // Check for a valid binding; it has to be 'done' and sensibly bound (not as in tuple expanded stuff) if (valid_binding (b)) { int run; // Find all preceding events for (run = 0; run < sys->maxruns; run++) { int ev; //!@todo hardcoded reference to step, should be length for (ev = 0; ev < sys->runs[run].step; ev++) { if (isDependEvent (run, ev, b->run_from, b->ev_from)) { // this node is *before* the from node Roledef rd; int occursthere; rd = roledef_shift (sys->runs[run].start, ev); if (switches.intruder) { // intruder: interm bindings should cater for the first occurrence occursthere = termInTerm (rd->message, b->term); } else { // no intruder, then simple test occursthere = isTermEqual (rd->message, b->term); } if (occursthere) { // This term already occurs in a previous node! #ifdef DEBUG if (DEBUGL (4)) { // Report this indentPrint (); eprintf ("Binding for "); termPrint (b->term); eprintf (" at r%i i%i is not c-minimal because it occurred before at r%i i%i in ", b->run_from, b->ev_from, run, ev); termPrint (rd->message); eprintf ("\n"); } #endif return false; } } else { // If this event is not before the target, then the // next in the run certainly is not either (because // that would imply that this one is before it) // Thus, we effectively exit the loop. break; } } } } bl = bl->next; } } return true; } //! Count the number of bindings that are done. int countBindingsDone () { int count; int countDone (Binding b) { if ((!b->blocked) && b->done) { count++; } return true; } count = 0; iterate_bindings (countDone); return count; }