#include "src/mc/explo/udpor/EventSet.hpp"
#include "src/mc/explo/udpor/Configuration.hpp"
#include "src/mc/explo/udpor/History.hpp"
+#include "src/mc/explo/udpor/UnfoldingEvent.hpp"
+#include "src/xbt/utils/iter/variable_for_loop.hpp"
-#include <iterator>
+#include <stack>
+#include <vector>
namespace simgrid::mc::udpor {
-EventSet::EventSet(Configuration&& config) : EventSet(std::move(config.get_events())) {}
+EventSet::EventSet(Configuration&& config) : EventSet(config.get_events()) {}
-void EventSet::remove(UnfoldingEvent* e)
+void EventSet::remove(const UnfoldingEvent* e)
{
this->events_.erase(e);
}
EventSet EventSet::subtracting(const EventSet& other) const
{
- std::unordered_set<UnfoldingEvent*> result = this->events_;
+ std::unordered_set<const UnfoldingEvent*> result = this->events_;
- for (UnfoldingEvent* e : other.events_)
+ for (const UnfoldingEvent* e : other.events_)
result.erase(e);
return EventSet(std::move(result));
return subtracting(config.get_events());
}
-EventSet EventSet::subtracting(UnfoldingEvent* e) const
+EventSet EventSet::subtracting(const UnfoldingEvent* e) const
{
auto result = this->events_;
result.erase(e);
return EventSet(std::move(result));
}
-void EventSet::insert(UnfoldingEvent* e)
+void EventSet::insert(const UnfoldingEvent* e)
{
this->events_.insert(e);
}
form_union(config.get_events());
}
-EventSet EventSet::make_union(UnfoldingEvent* e) const
+EventSet EventSet::make_union(const UnfoldingEvent* e) const
{
auto result = this->events_;
result.insert(e);
EventSet EventSet::make_union(const EventSet& other) const
{
- std::unordered_set<UnfoldingEvent*> result = this->events_;
+ std::unordered_set<const UnfoldingEvent*> result = this->events_;
- for (UnfoldingEvent* e : other.events_)
+ for (const UnfoldingEvent* e : other.events_)
result.insert(e);
return EventSet(std::move(result));
return make_union(config.get_events());
}
+EventSet EventSet::get_local_config() const
+{
+ return History(*this).get_all_events();
+}
+
size_t EventSet::size() const
{
return this->events_.size();
return this->events_.empty();
}
-bool EventSet::contains(UnfoldingEvent* e) const
+bool EventSet::contains(const UnfoldingEvent* e) const
{
return this->events_.find(e) != this->events_.end();
}
{
/// @invariant: A collection of events `E` is a configuration
/// if and only if following while following the history of
- /// each event `e` of `E`you remain in `E`. In other words, you
+ /// each event `e` of `E` you remain in `E`. In other words, you
/// only see events from set `E`
///
- /// The proof is based on the definition of a configuration
- /// which requires that all
+ /// The simple proof is based on the definition of a configuration
+ /// which requires that all events have their history contained
+ /// in the set
const History history(*this);
- return std::all_of(history.begin(), history.end(), [=](UnfoldingEvent* e) { return this->contains(e); });
+ return contains(history) && is_conflict_free();
+}
+
+bool EventSet::contains(const History& history) const
+{
+ return std::all_of(history.begin(), history.end(), [=](const UnfoldingEvent* e) { return this->contains(e); });
}
-bool EventSet::is_maximal_event_set() const
+bool EventSet::is_maximal() const
{
+ // A set of events is maximal if no event from
+ // the original set is ruled out when traversing
+ // the history of the events
const History history(*this);
return *this == history.get_all_maximal_events();
}
+bool EventSet::is_conflict_free() const
+{
+ const auto begin = simgrid::xbt::variable_for_loop<const EventSet>{{*this}, {*this}};
+ const auto end = simgrid::xbt::variable_for_loop<const EventSet>();
+ return std::none_of(begin, end, [=](const auto event_pair) {
+ const UnfoldingEvent* e1 = *event_pair[0];
+ const UnfoldingEvent* e2 = *event_pair[1];
+ return e1->conflicts_with(e2);
+ });
+}
+
+std::vector<const UnfoldingEvent*> EventSet::get_topological_ordering() const
+{
+ // This is essentially an implementation of detecting cycles
+ // in a graph with coloring, except it makes a topological
+ // ordering out of it
+ if (empty()) {
+ return std::vector<const UnfoldingEvent*>();
+ }
+
+ std::stack<const UnfoldingEvent*> event_stack;
+ std::vector<const UnfoldingEvent*> topological_ordering;
+ EventSet unknown_events = *this;
+ EventSet temporarily_marked_events;
+ EventSet permanently_marked_events;
+
+ while (not unknown_events.empty()) {
+ EventSet discovered_events;
+ event_stack.push(*unknown_events.begin());
+
+ while (not event_stack.empty()) {
+ const UnfoldingEvent* evt = event_stack.top();
+ discovered_events.insert(evt);
+
+ if (not temporarily_marked_events.contains(evt)) {
+ // If this event hasn't yet been marked, do
+ // so now so that if we both see it
+ // again in a child we can detect a cycle
+ temporarily_marked_events.insert(evt);
+
+ EventSet immediate_causes = evt->get_immediate_causes();
+ if (!immediate_causes.empty() && immediate_causes.is_subset_of(temporarily_marked_events)) {
+ throw std::invalid_argument("Attempted to perform a topological sort on a configuration "
+ "whose contents contain a cycle. The configuration (and the graph "
+ "connecting all of the events) is an invalid event structure");
+ }
+ immediate_causes.subtract(discovered_events);
+ immediate_causes.subtract(permanently_marked_events);
+ std::for_each(immediate_causes.begin(), immediate_causes.end(),
+ [&event_stack](const UnfoldingEvent* cause) { event_stack.push(cause); });
+ } else {
+ unknown_events.remove(evt);
+ temporarily_marked_events.remove(evt);
+ permanently_marked_events.insert(evt);
+
+ // In moving this event to the end of the list,
+ // we are saying this events "happens before" other
+ // events that are added later.
+ if (this->contains(evt)) {
+ topological_ordering.push_back(evt);
+ }
+
+ // Only now do we remove the event, i.e. once
+ // we've processed the same event twice
+ event_stack.pop();
+ }
+ }
+ }
+ return topological_ordering;
+}
+
+std::vector<const UnfoldingEvent*> EventSet::get_topological_ordering_of_reverse_graph() const
+{
+ // The implementation exploits the property that
+ // a topological sorting S^R of the reverse graph G^R
+ // of some graph G is simply the reverse of any
+ // topological sorting S of G.
+ auto topological_events = get_topological_ordering();
+ std::reverse(topological_events.begin(), topological_events.end());
+ return topological_events;
+}
+
+std::vector<const UnfoldingEvent*> EventSet::move_into_vector() const&&
+{
+ std::vector<const UnfoldingEvent*> contents;
+ contents.reserve(size());
+
+ for (auto&& event : *this) {
+ contents.push_back(event);
+ }
+
+ return contents;
+}
+
} // namespace simgrid::mc::udpor
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