misc_index(0),
misc_max(0)
{
- if (act) {
- act->set_node(this);
- int currtid=id_to_int(act->get_tid());
- int prevtid=(prevfairness != NULL)?id_to_int(prevfairness->action->get_tid()):0;
-
- if ( model->params.fairwindow != 0 ) {
- for(int i=0;i<nthreads;i++) {
- ASSERT(i<((int)fairness.size()));
- struct fairness_info * fi=& fairness[i];
- struct fairness_info * prevfi=(par!=NULL)&&(i<par->get_num_threads())?&par->fairness[i]:NULL;
- if (prevfi) {
- *fi=*prevfi;
- }
- if (parent->is_enabled(int_to_id(i))) {
- fi->enabled_count++;
- }
- if (i==currtid) {
- fi->turns++;
- fi->priority = false;
- }
- //Do window processing
- if (prevfairness != NULL) {
- if (prevfairness -> parent->is_enabled(int_to_id(i)))
- fi->enabled_count--;
- if (i==prevtid) {
- fi->turns--;
- }
- //Need full window to start evaluating conditions
- //If we meet the enabled count and have no turns, give us priority
- if ((fi->enabled_count >= model->params.enabledcount) &&
- (fi->turns == 0))
- fi->priority = true;
+ ASSERT(act);
+ act->set_node(this);
+ int currtid = id_to_int(act->get_tid());
+ int prevtid = (prevfairness != NULL) ? id_to_int(prevfairness->action->get_tid()) : 0;
+
+ if (model->params.fairwindow != 0) {
+ for (int i = 0; i < nthreads; i++) {
+ ASSERT(i < ((int)fairness.size()));
+ struct fairness_info *fi = &fairness[i];
+ struct fairness_info *prevfi = (par != NULL) && (i < par->get_num_threads()) ? &par->fairness[i] : NULL;
+ if (prevfi) {
+ *fi = *prevfi;
+ }
+ if (parent && parent->is_enabled(int_to_id(i))) {
+ fi->enabled_count++;
+ }
+ if (i == currtid) {
+ fi->turns++;
+ fi->priority = false;
+ }
+ /* Do window processing */
+ if (prevfairness != NULL) {
+ if (prevfairness->parent->is_enabled(int_to_id(i)))
+ fi->enabled_count--;
+ if (i == prevtid) {
+ fi->turns--;
}
+ /* Need full window to start evaluating
+ * conditions
+ * If we meet the enabled count and have no
+ * turns, give us priority */
+ if ((fi->enabled_count >= model->params.enabledcount) &&
+ (fi->turns == 0))
+ fi->priority = true;
}
}
}
/** @brief Node desctructor */
Node::~Node()
{
- if (action)
- delete action;
+ delete action;
if (enabled_array)
model_free(enabled_array);
}
/** Prints debugging info for the ModelAction associated with this Node */
void Node::print()
{
- if (action)
- action->print();
- else
- printf("******** empty action ********\n");
+ action->print();
+ model_print(" backtrack: %s\n", backtrack_empty() ? "empty" : "non-empty");
+ model_print(" future values: %s\n", future_value_empty() ? "empty" : "non-empty");
+ model_print(" read-from: %s\n", read_from_empty() ? "empty" : "non-empty");
+ model_print(" promises: %s\n", promise_empty() ? "empty" : "non-empty");
+ model_print(" misc: %s\n", misc_empty() ? "empty" : "non-empty");
+ model_print(" rel seq break: %s\n", relseq_break_empty() ? "empty" : "non-empty");
}
/** @brief Prints info about may_read_from set */
* @param i The promise index.
* @return true if the promise should be satisfied by the given model action.
*/
-bool Node::get_promise(unsigned int i) {
+bool Node::get_promise(unsigned int i) const
+{
return (i < promises.size()) && ((promises[i] & PROMISE_MASK) == PROMISE_FULFILLED);
}
*/
bool Node::increment_promise() {
DBG();
- unsigned int rmw_count=0;
+ unsigned int rmw_count = 0;
for (unsigned int i = 0; i < promises.size(); i++) {
- if (promises[i]==(PROMISE_RMW|PROMISE_FULFILLED))
+ if (promises[i] == (PROMISE_RMW|PROMISE_FULFILLED))
rmw_count++;
}
-
+
for (unsigned int i = 0; i < promises.size(); i++) {
if ((promises[i] & PROMISE_MASK) == PROMISE_UNFULFILLED) {
if ((rmw_count > 0) && (promises[i] & PROMISE_RMW)) {
* Returns whether the promise set is empty.
* @return true if we have explored all promise combinations.
*/
-bool Node::promise_empty() {
- bool fulfilledrmw=false;
- for (int i = promises.size()-1 ; i>=0; i--) {
- if (promises[i]==PROMISE_UNFULFILLED)
+bool Node::promise_empty() const
+{
+ bool fulfilledrmw = false;
+ for (int i = promises.size() - 1; i >= 0; i--) {
+ if (promises[i] == PROMISE_UNFULFILLED)
return false;
- if (!fulfilledrmw && ((promises[i]&PROMISE_MASK)==PROMISE_UNFULFILLED))
+ if (!fulfilledrmw && ((promises[i]&PROMISE_MASK) == PROMISE_UNFULFILLED))
return false;
- if (promises[i]==(PROMISE_FULFILLED|PROMISE_RMW))
- fulfilledrmw=true;
+ if (promises[i] == (PROMISE_FULFILLED|PROMISE_RMW))
+ fulfilledrmw = true;
}
return true;
}
-void Node::set_misc_max(int i) {
- misc_max=i;
+void Node::set_misc_max(int i)
+{
+ misc_max = i;
}
-int Node::get_misc() {
+int Node::get_misc() const
+{
return misc_index;
}
bool Node::increment_misc() {
- return (misc_index<misc_max)&&((++misc_index)<misc_max);
+ return (misc_index < misc_max) && ((++misc_index) < misc_max);
}
-bool Node::misc_empty() {
- return (misc_index+1)>=misc_max;
+bool Node::misc_empty() const
+{
+ return (misc_index + 1) >= misc_max;
}
/**
- * Adds a value from a weakly ordered future write to backtrack to.
+ * Adds a value from a weakly ordered future write to backtrack to. This
+ * operation may "fail" if the future value has already been run (within some
+ * sloppiness window of this expiration), or if the futurevalues set has
+ * reached its maximum.
+ * @see model_params.maxfuturevalues
+ *
* @param value is the value to backtrack to.
+ * @return True if the future value was successully added; false otherwise
*/
bool Node::add_future_value(uint64_t value, modelclock_t expiration) {
- int suitableindex=-1;
+ int idx = -1; /* Highest index where value is found */
for (unsigned int i = 0; i < future_values.size(); i++) {
if (future_values[i].value == value) {
- if (future_values[i].expiration>=expiration)
+ if (expiration <= future_values[i].expiration)
return false;
- if (future_index < ((int) i)) {
- suitableindex=i;
- }
+ idx = i;
}
}
-
- if (suitableindex!=-1) {
- future_values[suitableindex].expiration=expiration;
+ if (idx > future_index) {
+ /* Future value hasn't been explored; update expiration */
+ future_values[idx].expiration = expiration;
return true;
+ } else if (idx >= 0 && expiration <= future_values[idx].expiration + model->params.expireslop) {
+ /* Future value has been explored and is within the "sloppy" window */
+ return false;
}
- struct future_value newfv={value, expiration};
+
+ /* Limit the size of the future-values set */
+ if (model->params.maxfuturevalues > 0 &&
+ (int)future_values.size() >= model->params.maxfuturevalues)
+ return false;
+
+ struct future_value newfv = {value, expiration};
future_values.push_back(newfv);
return true;
}
* Checks whether the future_values set for this node is empty.
* @return true if the future_values set is empty.
*/
-bool Node::future_value_empty() {
+bool Node::future_value_empty() const
+{
return ((future_index + 1) >= ((int)future_values.size()));
}
* @return true if this thread choice has been explored already, false
* otherwise
*/
-bool Node::has_been_explored(thread_id_t tid)
+bool Node::has_been_explored(thread_id_t tid) const
{
int id = id_to_int(tid);
return explored_children[id];
* Checks if the backtracking set is empty.
* @return true if the backtracking set is empty
*/
-bool Node::backtrack_empty()
+bool Node::backtrack_empty() const
{
return (numBacktracks == 0);
}
* Checks whether the readsfrom set for this node is empty.
* @return true if the readsfrom set is empty.
*/
-bool Node::read_from_empty() {
- return ((read_from_index+1) >= may_read_from.size());
+bool Node::read_from_empty() const
+{
+ return ((read_from_index + 1) >= may_read_from.size());
}
/**
* Mark the appropriate backtracking information for exploring a thread choice.
* @param act The ModelAction to explore
*/
-void Node::explore_child(ModelAction *act, enabled_type_t * is_enabled)
+void Node::explore_child(ModelAction *act, enabled_type_t *is_enabled)
{
- if ( ! enabled_array )
- enabled_array=(enabled_type_t *)model_malloc(sizeof(enabled_type_t)*num_threads);
+ if (!enabled_array)
+ enabled_array = (enabled_type_t *)model_malloc(sizeof(enabled_type_t) * num_threads);
if (is_enabled != NULL)
- memcpy(enabled_array, is_enabled, sizeof(enabled_type_t)*num_threads);
+ memcpy(enabled_array, is_enabled, sizeof(enabled_type_t) * num_threads);
else {
- for(int i=0;i<num_threads;i++)
- enabled_array[i]=THREAD_DISABLED;
+ for (int i = 0; i < num_threads; i++)
+ enabled_array[i] = THREAD_DISABLED;
}
explore(act->get_tid());
bool Node::set_backtrack(thread_id_t id)
{
int i = id_to_int(id);
- ASSERT(i<((int)backtrack.size()));
+ ASSERT(i < ((int)backtrack.size()));
if (backtrack[i])
return false;
backtrack[i] = true;
return int_to_id(i);
}
-bool Node::is_enabled(Thread *t)
+bool Node::is_enabled(Thread *t) const
{
- int thread_id=id_to_int(t->get_id());
+ int thread_id = id_to_int(t->get_id());
return thread_id < num_threads && (enabled_array[thread_id] != THREAD_DISABLED);
}
-enabled_type_t Node::enabled_status(thread_id_t tid) {
- int thread_id=id_to_int(tid);
+enabled_type_t Node::enabled_status(thread_id_t tid) const
+{
+ int thread_id = id_to_int(tid);
if (thread_id < num_threads)
return enabled_array[thread_id];
else
return THREAD_DISABLED;
}
-bool Node::is_enabled(thread_id_t tid)
+bool Node::is_enabled(thread_id_t tid) const
{
- int thread_id=id_to_int(tid);
+ int thread_id = id_to_int(tid);
return thread_id < num_threads && (enabled_array[thread_id] != THREAD_DISABLED);
}
-bool Node::has_priority(thread_id_t tid)
+bool Node::has_priority(thread_id_t tid) const
{
return fairness[id_to_int(tid)].priority;
}
* where this->action is a 'read'.
* @return The first element in future_values
*/
-uint64_t Node::get_future_value() {
- ASSERT(future_index >= 0 && future_index<((int)future_values.size()));
+uint64_t Node::get_future_value() const
+{
+ ASSERT(future_index >= 0 && future_index < ((int)future_values.size()));
return future_values[future_index].value;
}
-modelclock_t Node::get_future_value_expiration() {
- ASSERT(future_index >= 0 && future_index<((int)future_values.size()));
+modelclock_t Node::get_future_value_expiration() const
+{
+ ASSERT(future_index >= 0 && future_index < ((int)future_values.size()));
return future_values[future_index].expiration;
}
-int Node::get_read_from_size() {
+int Node::get_read_from_size() const
+{
return may_read_from.size();
}
* where this->action is a 'read'.
* @return The first element in may_read_from
*/
-const ModelAction * Node::get_read_from() {
+const ModelAction * Node::get_read_from() const
+{
if (read_from_index < may_read_from.size())
return may_read_from[read_from_index];
else
* @return A write that may break the release sequence. If NULL, that means
* the release sequence should not be broken.
*/
-const ModelAction * Node::get_relseq_break()
+const ModelAction * Node::get_relseq_break() const
{
if (relseq_break_index < (int)relseq_break_writes.size())
return relseq_break_writes[relseq_break_index];
* @return True if all writes that may break the release sequence have been
* explored
*/
-bool Node::relseq_break_empty() {
+bool Node::relseq_break_empty() const
+{
return ((relseq_break_index + 1) >= ((int)relseq_break_writes.size()));
}
void Node::explore(thread_id_t tid)
{
int i = id_to_int(tid);
- ASSERT(i<((int)backtrack.size()));
+ ASSERT(i < ((int)backtrack.size()));
if (backtrack[i]) {
backtrack[i] = false;
numBacktracks--;
}
NodeStack::NodeStack() :
- node_list(1, new Node()),
- iter(0),
+ node_list(),
+ head_idx(-1),
total_nodes(0)
{
total_nodes++;
delete node_list[i];
}
-void NodeStack::print()
+void NodeStack::print() const
{
- printf("............................................\n");
- printf("NodeStack printing node_list:\n");
+ model_print("............................................\n");
+ model_print("NodeStack printing node_list:\n");
for (unsigned int it = 0; it < node_list.size(); it++) {
- if (it == this->iter)
- printf("vvv following action is the current iterator vvv\n");
+ if ((int)it == this->head_idx)
+ model_print("vvv following action is the current iterator vvv\n");
node_list[it]->print();
}
- printf("............................................\n");
+ model_print("............................................\n");
}
/** Note: The is_enabled set contains what actions were enabled when
* act was chosen. */
-
-ModelAction * NodeStack::explore_action(ModelAction *act, enabled_type_t * is_enabled)
+ModelAction * NodeStack::explore_action(ModelAction *act, enabled_type_t *is_enabled)
{
DBG();
- ASSERT(!node_list.empty());
-
- if ((iter+1) < node_list.size()) {
- iter++;
- return node_list[iter]->get_action();
+ if ((head_idx + 1) < (int)node_list.size()) {
+ head_idx++;
+ return node_list[head_idx]->get_action();
}
/* Record action */
- get_head()->explore_child(act, is_enabled);
+ Node *head = get_head();
Node *prevfairness = NULL;
- if ( model->params.fairwindow != 0 && iter > model->params.fairwindow ) {
- prevfairness = node_list[iter-model->params.fairwindow];
+ if (head) {
+ head->explore_child(act, is_enabled);
+ if (model->params.fairwindow != 0 && head_idx > (int)model->params.fairwindow)
+ prevfairness = node_list[head_idx - model->params.fairwindow];
}
- node_list.push_back(new Node(act, get_head(), model->get_num_threads(), prevfairness));
+ node_list.push_back(new Node(act, head, model->get_num_threads(), prevfairness));
total_nodes++;
- iter++;
+ head_idx++;
return NULL;
}
void NodeStack::pop_restofstack(int numAhead)
{
/* Diverging from previous execution; clear out remainder of list */
- unsigned int it=iter+numAhead;
- for(unsigned int i=it;i<node_list.size();i++)
+ unsigned int it = head_idx + numAhead;
+ for (unsigned int i = it; i < node_list.size(); i++)
delete node_list[i];
node_list.resize(it);
}
-Node * NodeStack::get_head()
+Node * NodeStack::get_head() const
{
- if (node_list.empty())
+ if (node_list.empty() || head_idx < 0)
return NULL;
- return node_list[iter];
+ return node_list[head_idx];
}
-Node * NodeStack::get_next()
+Node * NodeStack::get_next() const
{
if (node_list.empty()) {
DEBUG("Empty\n");
return NULL;
}
- unsigned int it=iter+1;
+ unsigned int it = head_idx + 1;
if (it == node_list.size()) {
DEBUG("At end\n");
return NULL;
void NodeStack::reset_execution()
{
- iter = 0;
+ head_idx = -1;
}