/**Function********************************************************************
Synopsis [Executes a trace on the fsm given at construction time
using BDDs]
Description [The trace is executed using BDDs, that is a proof that
the fsm is compatible with the trace is built (if such proof
exists). Incomplete traces are filled-in with compatible values for
state and input variables.
Given trace can be either complete or incomplete.
The number of performed steps (transitions) is returned in *n_steps,
if a non-NULL pointer is given. If the initial state is not
compatible -1 is written.]
SideEffects [None]
SeeAlso []
******************************************************************************/
static Trace_ptr
bdd_partial_trace_executor_execute
(const PartialTraceExecutor_ptr partial_executor, const Trace_ptr trace,
const NodeList_ptr language, int* n_steps)
{
/* local references to self */
const BDDPartialTraceExecutor_ptr self = \
BDD_PARTIAL_TRACE_EXECUTOR(partial_executor);
const BaseTraceExecutor_ptr executor = \
BASE_TRACE_EXECUTOR(partial_executor);
Trace_ptr res = TRACE(NULL); /* failure */
int count = -1;
boolean success = true;
DdManager* dd;
BddStates trace_states;
TraceIter step = TRACE_END_ITER;
BddStates fwd_image = (BddStates) NULL;
node_ptr path = Nil; /* forward constrained images will be used
later to compute the complete trace */
const char* trace_description = "BDD Execution";
/* 0- Check prerequisites */
BDD_PARTIAL_TRACE_EXECUTOR_CHECK_INSTANCE(self);
TRACE_CHECK_INSTANCE(trace);
BDD_FSM_CHECK_INSTANCE(self->fsm);
BDD_ENC_CHECK_INSTANCE(self->enc);
dd = BddEnc_get_dd_manager(self->enc);
step = trace_first_iter(trace);
nusmv_assert(TRACE_END_ITER != step);
trace_states = TraceUtils_fetch_as_bdd(trace, step,
TRACE_ITER_SF_SYMBOLS, self->enc);
/* 1- Check Start State */
{
bdd_ptr init_bdd = BddFsm_get_init(self->fsm);
bdd_ptr invar_bdd = BddFsm_get_state_constraints(self->fsm);
BddStates source_states; /* last known states */
source_states = bdd_and(dd, init_bdd, invar_bdd);
bdd_and_accumulate(dd, &source_states, trace_states);
bdd_free(dd, invar_bdd);
bdd_free(dd, init_bdd);
bdd_free(dd, trace_states);
if (!bdd_is_false(dd, source_states)) {
boolean terminate = false;
path = cons(NODE_PTR(bdd_dup(source_states)), Nil);
++ count;
/* 2- Check Consecutive States are related by transition relation */
do {
BddStates last_state; /* (unshifted) next state */
BddStates next_state; /* next state constraints */
BddInputs next_input; /* next input constraints */
BddStatesInputsNexts next_combo; /* state-input-next constraints */
BddStatesInputsNexts constraints;
step = TraceIter_get_next(step);
if (TRACE_END_ITER != step) {
next_input = \
TraceUtils_fetch_as_bdd(trace, step, TRACE_ITER_I_SYMBOLS,
self->enc);
next_combo = \
TraceUtils_fetch_as_bdd(trace, step, TRACE_ITER_COMBINATORIAL,
self->enc);
last_state = \
TraceUtils_fetch_as_bdd(trace, step, TRACE_ITER_SF_SYMBOLS,
self->enc);
next_state = BddEnc_state_var_to_next_state_var(self->enc, last_state);
if (0 < BaseTraceExecutor_get_verbosity(executor)) {
fprintf(BaseTraceExecutor_get_output_stream(executor),
"-- executing step %d ... ", 1 + count);
fflush(BaseTraceExecutor_get_output_stream(executor));
}
/* building constrained fwd image */
constraints = bdd_and(dd, next_input, next_combo);
bdd_and_accumulate(dd, &constraints, next_state);
fwd_image =
BddFsm_get_sins_constrained_forward_image(self->fsm, source_states,
constraints);
/* test whether the constrained fwd image is not empty */
if (!bdd_is_false(dd, fwd_image)) {
if (0 < BaseTraceExecutor_get_verbosity(executor)) {
fprintf(BaseTraceExecutor_get_output_stream(executor), "done\n");
}
path = cons(NODE_PTR(fwd_image), path);
++ count;
}
else {
if (0 < BaseTraceExecutor_get_verbosity(executor)) {
fprintf(BaseTraceExecutor_get_output_stream(executor),
"failed!\n");
}
terminate = true;
success = false;
}
/* no longer used bdd refs */
bdd_free(dd, next_input);
bdd_free(dd, next_combo);
bdd_free(dd, last_state);
bdd_free(dd, next_state);
bdd_free(dd, source_states);
source_states = bdd_dup(fwd_image);
}
else {
if (0 == count) {
fprintf(BaseTraceExecutor_get_error_stream(executor),
"Warning: trace has no transitions.\n");
}
terminate = true;
}
} while (!terminate); /* loop on state/input pairs */
} /* if has initial state */
else {
fprintf(BaseTraceExecutor_get_error_stream(executor),
"Error: starting state is not initial state.\n");
success = false;
}
/* 3- If last state could be reached a complete trace exists */
if (success) {
if (0 < count) {
res = \
bdd_partial_trace_executor_generate(self, fwd_image, path,
count, language,
trace_description);
}
else { /* generates a complete state of trace of length 0 */
res = \
bdd_partial_trace_executor_generate(self, source_states,
Nil, 0, language,
trace_description);
}
nusmv_assert(TRACE(NULL) != res);
/* cleanup */
walk_dd(dd, bdd_free, path);
free_list(path);
}
bdd_free(dd, source_states);
}
/* as a final stage, verify loopbacks consistency using internal
service. The incomplete trace is compatible (that is, a valid
completion exists) iff exactly len(Trace) steps have been
performed *and* loopback data for the incomplete trace applies to
the complete one as well. */
if (TRACE(NULL) != res) {
if (Trace_get_length(trace) == count &&
partial_trace_executor_check_loopbacks(partial_executor, trace, res)) {
fprintf(BaseTraceExecutor_get_output_stream(executor),
"-- Trace was successfully completed.\n");
}
else {
Trace_destroy(res);
res = TRACE(NULL);
}
}
if (TRACE(NULL) == res) {
fprintf(BaseTraceExecutor_get_output_stream(executor),
"-- Trace could not be completed.\n");
}
if (NIL(int) != n_steps) { *n_steps = count; }
return res;
}
int Compass_write_sigref(NuSMVEnv_ptr env,
BddFsm_ptr fsm,
FILE* sigref_file,
FILE* prob_file, /* can be NULL */
FILE* ap_file, /* can be NULL */
Expr_ptr tau, /* can be NULL */
boolean do_indent /* Beautify the XML output */
)
{
BddEnc_ptr enc = BddFsm_get_bdd_encoding(fsm);
DDMgr_ptr dd = BddEnc_get_dd_manager(enc);
const NodeMgr_ptr nodemgr =
NODE_MGR(NuSMVEnv_get_value(env, ENV_NODE_MGR));
const TypeChecker_ptr tc = BaseEnc_get_type_checker(BASE_ENC(enc));
NodeList_ptr ap_list_add = NODE_LIST(NULL);
NodeList_ptr probs_list = NULL;
NodeList_ptr ap_list = NULL;
int retval = 0;
add_ptr prob_add;
add_ptr init_add;
add_ptr trans_add;
add_ptr tau_add;
bdd_ptr bdd_trans;
bdd_ptr state_mask = NULL;
bdd_ptr input_mask = NULL;
bdd_ptr next_state_mask = NULL;
bdd_ptr next_and_curr_state_mask = NULL;
/* preprocessing of the parameters */
/* tau */
if (EXPR(NULL) != tau) {
tau = Compile_FlattenSexp(BaseEnc_get_symb_table(BASE_ENC(enc)),
car(tau) /* gets rid of SIMPWFF */,
Nil);
}
/* prob_file */
if (NULL != prob_file) {
ParserProb_ptr pl_parser = NULL;
pl_parser = ParserProb_create(env);
ParserProb_parse_from_file(pl_parser, prob_file);
probs_list = ParserProb_get_prob_list(pl_parser);
if (NODE_LIST(NULL) != probs_list) {
Compass_check_prob_list(tc, probs_list);
}
ParserProb_destroy(pl_parser);
}
/* ap_file */
if (NULL != ap_file) {
ParserAp_ptr ap_parser = NULL;
ap_parser = ParserAp_create(env);
ParserAp_parse_from_file(ap_parser, ap_file);
ap_list = ParserAp_get_ap_list(ap_parser);
if (NODE_LIST(NULL) != ap_list) {
Compass_check_ap_list(tc, ap_list);
}
ParserAp_destroy(ap_parser);
}
/* collects all required pieces */
state_mask = BddEnc_get_state_frozen_vars_mask_bdd(enc);
input_mask = BddEnc_get_input_vars_mask_bdd(enc);
next_state_mask = BddEnc_state_var_to_next_state_var(enc, state_mask);
next_and_curr_state_mask = bdd_and(dd, state_mask, next_state_mask);
{ /* calculates the initial states */
bdd_ptr bdd_init = BddFsm_get_init(fsm);
bdd_ptr bdd_sinvar = BddFsm_get_state_constraints(fsm);
bdd_ptr bdd_iinvar = BddFsm_get_input_constraints(fsm);
bdd_and_accumulate(dd, &bdd_init, bdd_sinvar);
bdd_and_accumulate(dd, &bdd_init, bdd_iinvar);
bdd_and_accumulate(dd, &bdd_init, state_mask);
init_add = bdd_to_add(dd, bdd_init);
bdd_free(dd, bdd_iinvar);
bdd_free(dd, bdd_sinvar);
bdd_free(dd, bdd_init);
}
{ /* to control dynamic reordering */
dd_reorderingtype method;
int dd_reord_status;
/* Dynamic reordering during monolithic trans can improve performances */
dd_reord_status = dd_reordering_status(dd, &method);
dd_autodyn_enable(dd, method);
{ /* calculates the transition relation */
bdd_ptr bdd_sinvar = BddFsm_get_state_constraints(fsm);
bdd_ptr bdd_nsinvar = BddEnc_state_var_to_next_state_var(enc, bdd_sinvar);
bdd_ptr bdd_iinvar = BddFsm_get_input_constraints(fsm);
bdd_trans = BddFsm_get_monolithic_trans_bdd(fsm);
bdd_and_accumulate(dd, &bdd_trans, bdd_sinvar);
bdd_and_accumulate(dd, &bdd_trans, bdd_nsinvar);
bdd_and_accumulate(dd, &bdd_trans, bdd_iinvar);
bdd_and_accumulate(dd, &bdd_trans, next_and_curr_state_mask);
bdd_and_accumulate(dd, &bdd_trans, input_mask);
/* #define DEBUG_TRANS */
#ifdef DEBUG_TRANS
FILE * p = stdout; // fopen("TRANS.txt", "w");
fprintf(p, "==================================================\n");
fprintf(p, "TRANS\n");
fprintf(p, "==================================================\n");
// print_trans(enc, bdd_trans, p);
dd_printminterm(dd, bdd_trans);
fprintf(p, "==================================================\n");
dd_printminterm(dd, input_mask);
fprintf(p, "==================================================\n");
// fclose(p);
#endif
trans_add = bdd_to_add(dd, bdd_trans);
bdd_free(dd, bdd_iinvar);
bdd_free(dd, bdd_nsinvar);
bdd_free(dd, bdd_sinvar);
}
/* Dynamic reordering is disabled after monolitic
construction. Later it will be re-enabled if it was enable
before entering this block */
dd_autodyn_disable(dd);
/* probability and tau are optional */
if (probs_list != NODE_LIST(NULL)) {
prob_add = Compass_process_prob_list(enc, probs_list, bdd_trans);
}
else prob_add = (add_ptr) NULL;
bdd_free(dd, bdd_trans);
if (tau != (Expr_ptr) NULL) {
tau_add = BddEnc_expr_to_add(enc, tau, Nil);
/* [RC]: This code was disable because it seems masks for input
* var do not work */
/* mask_tau_add = BddEnc_apply_input_vars_mask_add(enc, tau_add); */
/* add_free(dd, tau_add); */
/* tau_add = mask_tau_add; */
}
else
tau_add = (add_ptr) NULL;
if (NODE_LIST(NULL) != ap_list) {
add_ptr expr_add, expr_add_mask;
ListIter_ptr iter;
ap_list_add = NodeList_create();
NODE_LIST_FOREACH(ap_list, iter) {
node_ptr ap_el = (node_ptr)NodeList_get_elem_at(ap_list, iter);
node_ptr lab = car(ap_el);
node_ptr expr = cdr(ap_el);
expr_add = BddEnc_expr_to_add(enc, expr, Nil);
expr_add_mask = BddEnc_apply_state_frozen_vars_mask_add(enc, expr_add);
NodeList_append(ap_list_add, cons(nodemgr, lab, (node_ptr)expr_add_mask));
add_free(dd, expr_add);
/* The expr_add_mask will be freed later when the ap_list_add
will be destroyed */
}
}