Node::Node(ModelAction *act, Node *par, int nthreads, Node *prevfairness) :
read_from_status(READ_FROM_PAST),
action(act),
+ uninit_action(NULL),
parent(par),
num_threads(nthreads),
explored_children(num_threads),
relseq_break_writes(),
relseq_break_index(0),
misc_index(0),
- misc_max(0)
+ misc_max(0),
+ yield_data(NULL)
{
ASSERT(act);
act->set_node(this);
}
}
+int Node::get_yield_data(int tid1, int tid2) const {
+ if (tid1<num_threads && tid2 < num_threads)
+ return yield_data[YIELD_INDEX(tid1,tid2,num_threads)];
+ else
+ return YIELD_S | YIELD_D;
+}
+
+void Node::update_yield(Scheduler * scheduler) {
+ yield_data=(int *) model_calloc(1, sizeof(int)*num_threads*num_threads);
+ //handle base case
+ if (parent == NULL) {
+ for(int i = 0; i < num_threads*num_threads; i++) {
+ yield_data[i] = YIELD_S | YIELD_D;
+ }
+ return;
+ }
+ int curr_tid=id_to_int(action->get_tid());
+
+ for(int u = 0; u < num_threads; u++) {
+ for(int v = 0; v < num_threads; v++) {
+ int yield_state=parent->get_yield_data(u, v);
+ bool next_enabled=scheduler->is_enabled(int_to_id(v));
+ bool curr_enabled=parent->is_enabled(int_to_id(v));
+ if (!next_enabled) {
+ //Compute intersection of ES and E
+ yield_state&=~YIELD_E;
+ //Check to see if we disabled the thread
+ if (u==curr_tid && curr_enabled)
+ yield_state|=YIELD_D;
+ }
+ yield_data[YIELD_INDEX(u, v, num_threads)]=yield_state;
+ }
+ yield_data[YIELD_INDEX(u, curr_tid, num_threads)]=(yield_data[YIELD_INDEX(u, curr_tid, num_threads)]&~YIELD_P)|YIELD_S;
+ }
+ //handle curr.yield(t) part of computation
+ if (action->is_yield()) {
+ for(int v = 0; v < num_threads; v++) {
+ int yield_state=yield_data[YIELD_INDEX(curr_tid, v, num_threads)];
+ if ((yield_state & (YIELD_E | YIELD_D)) && (!(yield_state & YIELD_S)))
+ yield_state |= YIELD_P;
+ yield_state &= YIELD_P;
+ if (scheduler->is_enabled(int_to_id(v))) {
+ yield_state|=YIELD_E;
+ }
+ yield_data[YIELD_INDEX(curr_tid, v, num_threads)]=yield_state;
+ }
+ }
+}
+
/** @brief Node desctructor */
Node::~Node()
{
delete action;
+ if (uninit_action)
+ delete uninit_action;
if (enabled_array)
model_free(enabled_array);
+ if (yield_data)
+ model_free(yield_data);
}
/** Prints debugging info for the ModelAction associated with this Node */
void Node::print() const
{
action->print();
+ model_print(" thread status: ");
+ if (enabled_array) {
+ for (int i = 0; i < num_threads; i++) {
+ char str[20];
+ enabled_type_to_string(enabled_array[i], str);
+ model_print("[%d: %s]", i, str);
+ }
+ model_print("\n");
+ } else
+ model_print("(info not available)\n");
model_print(" backtrack: %s", backtrack_empty() ? "empty" : "non-empty ");
for (int i = 0; i < (int)backtrack.size(); i++)
if (backtrack[i] == true)
return fairness[id_to_int(tid)].priority;
}
+bool Node::has_priority_over(thread_id_t tid1, thread_id_t tid2) const
+{
+ return get_yield_data(id_to_int(tid1), id_to_int(tid2)) & YIELD_P;
+}
+
/*********************************** read from ********************************/
/**
return read_from_promises[read_from_promise_idx]->get_reads_from_promise();
}
+/**
+ * Gets a particular 'read-from-promise' form this Node. Only vlaid for a node
+ * where this->action is a 'read'.
+ * @param i The index of the Promise to get
+ * @return The Promise at index i, if the Promise is still available; NULL
+ * otherwise
+ */
+Promise * Node::get_read_from_promise(int i) const
+{
+ return read_from_promises[i]->get_reads_from_promise();
+}
+
+/** @return The size of the read-from-promise set */
+int Node::get_read_from_promise_size() const
+{
+ return read_from_promises.size();
+}
+
/**
* Checks whether the read_from_promises set for this node is empty.
* @return true if the read_from_promises set is empty.