-std::unique_ptr<CompatibilityGraph>
-Configuration::make_compatibility_graph_filtered_on(std::function<bool(const UnfoldingEvent*)> pred) const
-{
- auto G = std::make_unique<CompatibilityGraph>();
-
- struct UnfoldingEventSearchData {
- int immediate_children_count = 0;
- CompatibilityGraphNode* potential_placement = nullptr;
- std::unordered_set<CompatibilityGraphNode*> conflicts = std::unordered_set<CompatibilityGraphNode*>();
- };
- std::unordered_map<UnfoldingEvent*, UnfoldingEventSearchData> search_data;
-
- for (auto* e : get_topologically_sorted_events_of_reverse_graph()) {
-
- // 1. Figure out where to place `e` in `G`
-
- // Determine which nodes in the graph are in conflict
- // with this event. These nodes would have been added by child
- // events while iterating over the topological ordering of the reverse graph
-
- const auto e_search_data_loc = search_data.find(e);
- const bool e_has_no_search_data = e_search_data_loc == search_data.end();
- const auto e_search_data = e_has_no_search_data ? UnfoldingEventSearchData() : std::move(e_search_data_loc->second);
-
- const auto& e_conflicts = e_search_data.conflicts;
- const auto& e_potential_placement = e_search_data.potential_placement;
- const auto e_child_count = e_search_data.immediate_children_count;
-
- const bool e_should_appear = pred(e);
- CompatibilityGraphNode* e_placement = nullptr;
-
- if (e_should_appear) {
- // The justification is as follows:
- //
- // e_has_no_search_data:
- // The event `e` is a leaf node, so there are no prior
- // nodes in `G` to join
- //
- // child_count >= 2:
- // If there are two or more events that this event causes,
- // then we certainly must be part of a compatibility
- // graph node that conflicts with each of our children
- //
- // e_potential_placement == nullptr:
- // If nobody told us about a placement and yet still have search
- // data, this means means that our child `C` had more than one child itself,
- // so it we could not have moved into `C`'s _potential_ placement.
- const bool new_placement_required =
- e_has_no_search_data || e_child_count >= 2 || e_potential_placement == nullptr;
-
- if (new_placement_required) {
- auto new_graph_node = std::make_unique<CompatibilityGraphNode>(e_conflicts, EventSet({e}));
- e_placement = new_graph_node.get();
- G->insert(std::move(new_graph_node));
- } else {
- xbt_assert(e_child_count == 1, "An event was informed by an immediate child of placement in "
- "the same compatibility graph node, yet the child did not inform "
- "the parent about its presence");
- // A child event told us this node can be in the
- // same compatibility node in the graph G. Add ourselves now
- e_placement = e_potential_placement;
- e_placement->add_event(e);
- }
- }
-
- // 2. Update the children of `e`
-
- const EventSet& e_immediate_causes = e->get_immediate_causes();
-
- // If there is only a single ancestor, then it MAY BE in
- // the same "chain" of events as us. Note that the ancestor must
- // also have only a single child (see the note on `new_placement_required`).
- //
- // If there is more than one child, then each child is in conflict with `e`
- // so we don't potentially place it
- if (e_immediate_causes.size() == 1) {
- UnfoldingEvent* only_ancestor = *e_immediate_causes.begin();
-
- // If `e` is included in the graph, forward its placement on to
- // the sole child. Otherwise attempt to forward `e`'s _potential_
- // (potential is stressed) placement. We can only forward `e`'s
- // potential placement iff `e` has only a single child; for if
- // `e` had more children, then our sole ancestor would conflict with
- // each one of `e`'s children and thus couldn't be in the same group
- // as any of them
- if (e_should_appear) {
- search_data[only_ancestor].potential_placement = e_placement;
- } else {
- search_data[only_ancestor].potential_placement = e_child_count == 1 ? e_potential_placement : nullptr;
- }
- }
-
- // Our ancestors conflict with everyone `e` does else PLUS `e` itself
- // ONLY IF e actually was placed
- auto parent_conflicts = std::move(e_conflicts);
- if (e_should_appear) {
- parent_conflicts.insert(e_placement);
- }
- for (auto* cause : e_immediate_causes) {
- search_data[cause].immediate_children_count += 1;
-
- for (auto parent_conflict : parent_conflicts) {
- search_data[cause].conflicts.insert(parent_conflict);
- }
- }
-
- // This event will only ever be seen once in the
- // topological ordering. Hence, its resources do not
- // need to be kept around
- search_data.erase(e);
- }
-
- return G;
-}
-
-std::unique_ptr<CompatibilityGraph> Configuration::make_compatibility_graph() const
-{
- return make_compatibility_graph_filtered_on([=](const UnfoldingEvent*) { return true; });
-}
-