Linkgraph: Split demand annotations from edge flow annotations

Use sparse storage format for demand annotations
2023-01-05 01:05:40 +00:00
parent 9bc5f69a19
commit 55473bc730
6 changed files with 74 additions and 65 deletions
--- a/src/linkgraph/demands.cpp
+++ b/src/linkgraph/demands.cpp
@@ -244,7 +244,8 @@ void AsymmetricScalerEq::SetDemands(LinkGraphJob &job, NodeID from_id, NodeID to
 */
 inline void Scaler::SetDemands(LinkGraphJob &job, NodeID from_id, NodeID to_id, uint demand_forw)
 {
-	job[from_id].DeliverSupply(to_id, demand_forw);
+	job[from_id].DeliverSupply(demand_forw);
 	job.demand_map[std::make_pair(from_id, to_id)] += demand_forw;
 }
 /**
@@ -476,4 +477,25 @@ DemandCalculator::DemandCalculator(LinkGraphJob &job) :
 			first_unseen++;
 		}
 	} while (first_unseen < size);
 	if (job.demand_map.size() > 0) {
 		job.demand_annotation_store.resize(job.demand_map.size());
 		size_t start_idx = 0;
 		size_t idx = 0;
 		NodeID last_from = job.demand_map.begin()->first.first;
 		auto flush = [&]() {
 			job[last_from].SetDemandAnnotations({ job.demand_annotation_store.data() + start_idx, idx - start_idx });
 		};
 		for (auto &iter : job.demand_map) {
 			if (iter.first.first != last_from) {
 				flush();
 				last_from = iter.first.first;
 				start_idx = idx;
 			}
 			job.demand_annotation_store[idx] = { iter.first.second, iter.second, iter.second };
 			idx++;
 		}
 		flush();
 		job.demand_map.clear();
 	}
 }
--- a/src/linkgraph/linkgraphjob.cpp
+++ b/src/linkgraph/linkgraphjob.cpp
@@ -212,9 +212,7 @@ void LinkGraphJob::Init()
 */
 void LinkGraphJob::EdgeAnnotation::Init()
 {
 	this->demand = 0;
 	this->flow = 0;
 	this->unsatisfied_demand = 0;
 }
 /**
--- a/src/linkgraph/linkgraphjob.h
+++ b/src/linkgraph/linkgraphjob.h
@@ -31,13 +31,21 @@ extern LinkGraphJobPool _link_graph_job_pool;
 * Class for calculation jobs to be run on link graphs.
 */
 class LinkGraphJob : public LinkGraphJobPool::PoolItem<&_link_graph_job_pool>{
 public:
 	/**
 	 * Annotation for a link graph demand edge.
 	 */
 	struct DemandAnnotation {
 		NodeID dest;                 ///< Target node
 		uint demand = 0;             ///< Transport demand between the nodes.
 		uint unsatisfied_demand = 0; ///< Demand over this edge that hasn't been satisfied yet.
 	};
 private:
 	/**
-	 * Annotation for a link graph edge.
+	 * Annotation for a link graph flow edge.
 	 */
 	struct EdgeAnnotation {
 		uint demand;             ///< Transport demand between the nodes.
 		uint unsatisfied_demand; ///< Demand over this edge that hasn't been satisfied yet.
 		uint flow;               ///< Planned flow over this edge.
 		void Init();
 	};
@@ -50,6 +58,7 @@ private:
 		uint received_demand;    ///< Received demand towards this node.
 		PathList paths;          ///< Paths through this node, sorted so that those with flow == 0 are in the back.
 		FlowStatMap flows;       ///< Planned flows to other nodes.
 		span<DemandAnnotation> demands; ///< Demand annotations belonging to this node.
 		void Init(uint supply);
 	};
@@ -79,6 +88,9 @@ protected:
 public:
 	btree::btree_map<std::pair<NodeID, NodeID>, uint> demand_map; ///< Demand map.
 	std::vector<DemandAnnotation> demand_annotation_store;        ///< Demand annotation store.
 	DynUniformArenaAllocator path_allocator; ///< Arena allocator used for paths
 	/**
@@ -96,18 +108,6 @@ public:
 		AnnoEdge(EdgeAnnotation &anno) :
 				anno(anno) {}
 		/**
 		 * Get the transport demand between end the points of the edge.
 		 * @return Demand.
 		 */
 		uint Demand() const { return this->anno.demand; }
 		/**
 		 * Get the transport demand that hasn't been satisfied by flows, yet.
 		 * @return Unsatisfied demand.
 		 */
 		uint UnsatisfiedDemand() const { return this->anno.unsatisfied_demand; }
 		/**
 		 * Get the total flow on the edge.
 		 * @return Flow.
@@ -129,26 +129,6 @@ public:
 			assert(flow <= this->anno.flow);
 			this->anno.flow -= flow;
 		}
 		/**
 		 * Add some (not yet satisfied) demand.
 		 * @param demand Demand to be added.
 		 */
 		void AddDemand(uint demand)
 		{
 			this->anno.demand += demand;
 			this->anno.unsatisfied_demand += demand;
 		}
 		/**
 		 * Satisfy some demand.
 		 * @param demand Demand to be satisfied.
 		 */
 		void SatisfyDemand(uint demand)
 		{
 			assert(demand <= this->anno.unsatisfied_demand);
 			this->anno.unsatisfied_demand -= demand;
 		}
 	};
 	/**
@@ -237,13 +217,11 @@ public:
 		/**
 		 * Deliver some supply, adding demand to the respective edge.
 		 * @param to Destination for supply.
 		 * @param amount Amount of supply to be delivered.
 		 */
-		void DeliverSupply(NodeID to, uint amount)
+		void DeliverSupply(uint amount)
 		{
 			this->node_anno.undelivered_supply -= amount;
 			(*this)[to].AddDemand(amount);
 		}
 		/**
@@ -254,6 +232,16 @@ public:
 		{
 			this->node_anno.received_demand += amount;
 		}
 		span<DemandAnnotation> GetDemandAnnotations() const
 		{
 			return this->node_anno.demands;
 		}
 		void SetDemandAnnotations(span<DemandAnnotation> demands)
 		{
 			this->node_anno.demands = demands;
 		}
 	};
 	/**
--- a/src/linkgraph/linkgraphjob_base.h
+++ b/src/linkgraph/linkgraphjob_base.h
@@ -17,5 +17,6 @@
 typedef LinkGraphJob::Node Node;
 typedef LinkGraphJob::Edge Edge;
 typedef LinkGraphJob::AnnoEdge AnnoEdge;
 typedef LinkGraphJob::DemandAnnotation DemandAnnotation;
 #endif /* LINKGRAPHJOB_BASE_H */
--- a/src/linkgraph/mcf.cpp
+++ b/src/linkgraph/mcf.cpp
@@ -391,20 +391,20 @@ void MultiCommodityFlow::CleanupPaths(NodeID source_id, PathVector &paths)
 /**
 * Push flow along a path and update the unsatisfied_demand of the associated
 * edge.
- * @param edge Edge whose ends the path connects.
+ * @param anno Distance annotation whose ends the path connects.
 * @param path End of the path the flow should be pushed on.
 * @param min_step_size Minimum flow size.
 * @param accuracy Accuracy of the calculation.
 * @param max_saturation If < UINT_MAX only push flow up to the given
 *                       saturation, otherwise the path can be "overloaded".
 */
-uint MultiCommodityFlow::PushFlow(AnnoEdge &edge, Path *path, uint min_step_size, uint accuracy,
+uint MultiCommodityFlow::PushFlow(DemandAnnotation &anno, Path *path, uint min_step_size, uint accuracy,
 		uint max_saturation)
 {
-	assert(edge.UnsatisfiedDemand() > 0);
+	dbg_assert(anno.unsatisfied_demand > 0);
-	uint flow = std::min(std::max(edge.Demand() / accuracy, min_step_size), edge.UnsatisfiedDemand());
+	uint flow = std::min(std::max(anno.demand / accuracy, min_step_size), anno.unsatisfied_demand);
 	flow = path->AddFlow(flow, this->job, max_saturation);
-	edge.SatisfyDemand(flow);
+	anno.unsatisfied_demand -= flow;
 	return flow;
 }
@@ -571,10 +571,10 @@ MCF1stPass::MCF1stPass(LinkGraphJob &job) : MultiCommodityFlow(job)
 		uint64 total_demand = 0;
 		uint demand_count = 0;
 		for (NodeID source = 0; source < size; ++source) {
-			for (NodeID dest = 0; dest < size; ++dest) {
+			const Node &node = job[source];
-				AnnoEdge edge = job[source][dest];
+			for (const DemandAnnotation &anno : node.GetDemandAnnotations()) {
-				if (edge.UnsatisfiedDemand() > 0) {
+				if (anno.unsatisfied_demand > 0) {
-					total_demand += edge.UnsatisfiedDemand();
+					total_demand += anno.unsatisfied_demand;
 					demand_count++;
 				}
 			}
@@ -593,24 +593,24 @@ MCF1stPass::MCF1stPass(LinkGraphJob &job) : MultiCommodityFlow(job)
 			this->Dijkstra<DistanceAnnotation, GraphEdgeIterator>(source, paths);
 			bool source_demand_left = false;
-			for (NodeID dest = 0; dest < size; ++dest) {
+			for (DemandAnnotation &anno : job[source].GetDemandAnnotations()) {
-				AnnoEdge edge = job[source][dest];
+				NodeID dest = anno.dest;
-				if (edge.UnsatisfiedDemand() > 0) {
+				if (anno.unsatisfied_demand > 0) {
 					Path *path = paths[dest];
 					assert(path != nullptr);
 					/* Generally only allow paths that don't exceed the
 					 * available capacity. But if no demand has been assigned
 					 * yet, make an exception and allow any valid path *once*. */
-					if (path->GetFreeCapacity() > 0 && this->PushFlow(edge, path,
+					if (path->GetFreeCapacity() > 0 && this->PushFlow(anno, path,
 							min_step_size, accuracy, this->max_saturation) > 0) {
 						/* If a path has been found there is a chance we can
 						 * find more. */
-						more_loops = more_loops || (edge.UnsatisfiedDemand() > 0);
+						more_loops = more_loops || (anno.unsatisfied_demand > 0);
-					} else if (edge.UnsatisfiedDemand() == edge.Demand() &&
+					} else if (anno.unsatisfied_demand == anno.demand &&
 							path->GetFreeCapacity() > INT_MIN) {
-						this->PushFlow(edge, path, min_step_size, accuracy, UINT_MAX);
+						this->PushFlow(anno, path, min_step_size, accuracy, UINT_MAX);
 					}
-					if (edge.UnsatisfiedDemand() > 0) source_demand_left = true;
+					if (anno.unsatisfied_demand > 0) source_demand_left = true;
 				}
 			}
 			if (!source_demand_left) finished_sources[source] = true;
@@ -640,12 +640,12 @@ MCF2ndPass::MCF2ndPass(LinkGraphJob &job) : MultiCommodityFlow(job)
 			this->Dijkstra<CapacityAnnotation, FlowEdgeIterator>(source, paths);
 			bool source_demand_left = false;
-			for (NodeID dest = 0; dest < size; ++dest) {
+			for (DemandAnnotation &anno : this->job[source].GetDemandAnnotations()) {
-				AnnoEdge edge = this->job[source][dest];
+				if (anno.unsatisfied_demand == 0) continue;
-				Path *path = paths[dest];
+				Path *path = paths[anno.dest];
-				if (edge.UnsatisfiedDemand() > 0 && path->GetFreeCapacity() > INT_MIN) {
+				if (path->GetFreeCapacity() > INT_MIN) {
-					this->PushFlow(edge, path, 1, accuracy, UINT_MAX);
+					this->PushFlow(anno, path, 1, accuracy, UINT_MAX);
-					if (edge.UnsatisfiedDemand() > 0) {
+					if (anno.unsatisfied_demand > 0) {
 						demand_left = true;
 						source_demand_left = true;
 					}
--- a/src/linkgraph/mcf.h
+++ b/src/linkgraph/mcf.h
@@ -24,7 +24,7 @@ protected:
 	template<class Tannotation, class Tedge_iterator>
 	void Dijkstra(NodeID from, PathVector &paths);
-	uint PushFlow(AnnoEdge &edge, Path *path, uint min_step_size, uint accuracy, uint max_saturation);
+	uint PushFlow(DemandAnnotation &anno, Path *path, uint min_step_size, uint accuracy, uint max_saturation);
 	void CleanupPaths(NodeID source, PathVector &paths);