/*
* This file is part of OpenTTD.
* OpenTTD is free software; you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation, version 2.
* OpenTTD is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.
* See the GNU General Public License for more details. You should have received a copy of the GNU General Public License along with OpenTTD. If not, see .
*/
/** @file linkgraphjob.h Declaration of link graph job classes used for cargo distribution. */
#ifndef LINKGRAPHJOB_H
#define LINKGRAPHJOB_H
#include "../thread.h"
#include "linkgraph.h"
#include
class LinkGraphJob;
class Path;
typedef std::list PathList;
/** Type of the pool for link graph jobs. */
typedef Pool LinkGraphJobPool;
/** The actual pool with link graph jobs. */
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:
/**
* Demand between two nodes.
*/
struct DemandAnnotation {
uint demand; ///< Transport demand between the nodes.
uint unsatisfied_demand; ///< Demand over this edge that hasn't been satisfied yet.
};
/**
* Annotation for a link graph edge.
*/
struct EdgeAnnotation {
const LinkGraph::BaseEdge &base; ///< Reference to the edge that is annotated.
uint flow; ///< Planned flow over this edge.
EdgeAnnotation(const LinkGraph::BaseEdge &base) : base(base), flow(0) {}
/**
* Get the total flow on the edge.
* @return Flow.
*/
uint Flow() const { return this->flow; }
/**
* Add some flow.
* @param flow Flow to be added.
*/
void AddFlow(uint flow) { this->flow += flow; }
/**
* Remove some flow.
* @param flow Flow to be removed.
*/
void RemoveFlow(uint flow)
{
assert(flow <= this->flow);
this->flow -= flow;
}
friend inline bool operator <(NodeID dest, const EdgeAnnotation &rhs)
{
return dest < rhs.base.dest_node;
}
};
/**
* Annotation for a link graph node.
*/
struct NodeAnnotation {
const LinkGraph::BaseNode &base; ///< Reference to the node that is annotated.
uint undelivered_supply; ///< Amount of supply that hasn't been distributed yet.
PathList paths; ///< Paths through this node, sorted so that those with flow == 0 are in the back.
FlowStatMap flows; ///< Planned flows to other nodes.
std::vector edges; ///< Annotations for all edges originating at this node.
std::vector demands; ///< Annotations for the demand to all other nodes.
NodeAnnotation(const LinkGraph::BaseNode &node, size_t size) : base(node), undelivered_supply(node.supply), paths(), flows()
{
this->edges.reserve(node.edges.size());
for (auto &e : node.edges) this->edges.emplace_back(e);
this->demands.resize(size);
}
/**
* Retrieve an edge starting at this node.
* @param to Remote end of the edge.
* @return Edge between this node and "to".
*/
EdgeAnnotation &operator[](NodeID to)
{
auto it = std::find_if(this->edges.begin(), this->edges.end(), [=] (const EdgeAnnotation &e) { return e.base.dest_node == to; });
assert(it != this->edges.end());
return *it;
}
/**
* Retrieve an edge starting at this node.
* @param to Remote end of the edge.
* @return Edge between this node and "to".
*/
const EdgeAnnotation &operator[](NodeID to) const
{
auto it = std::find_if(this->edges.begin(), this->edges.end(), [=] (const EdgeAnnotation &e) { return e.base.dest_node == to; });
assert(it != this->edges.end());
return *it;
}
/**
* Get the transport demand between end the points of the edge.
* @return Demand.
*/
uint DemandTo(NodeID to) const { return this->demands[to].demand; }
/**
* Get the transport demand that hasn't been satisfied by flows, yet.
* @return Unsatisfied demand.
*/
uint UnsatisfiedDemandTo(NodeID to) const { return this->demands[to].unsatisfied_demand; }
/**
* Satisfy some demand.
* @param demand Demand to be satisfied.
*/
void SatisfyDemandTo(NodeID to, uint demand)
{
assert(demand <= this->demands[to].unsatisfied_demand);
this->demands[to].unsatisfied_demand -= demand;
}
/**
* 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)
{
this->undelivered_supply -= amount;
this->demands[to].demand += amount;
this->demands[to].unsatisfied_demand += amount;
}
};
private:
typedef std::vector NodeAnnotationVector;
friend SaveLoadTable GetLinkGraphJobDesc();
friend class LinkGraphSchedule;
protected:
const LinkGraph link_graph; ///< Link graph to by analyzed. Is copied when job is started and mustn't be modified later.
const LinkGraphSettings settings; ///< Copy of _settings_game.linkgraph at spawn time.
std::thread thread; ///< Thread the job is running in or a default-constructed thread if it's running in the main thread.
TimerGameCalendar::Date join_date; ///< Date when the job is to be joined.
NodeAnnotationVector nodes; ///< Extra node data necessary for link graph calculation.
std::atomic job_completed; ///< Is the job still running. This is accessed by multiple threads and reads may be stale.
std::atomic job_aborted; ///< Has the job been aborted. This is accessed by multiple threads and reads may be stale.
void EraseFlows(NodeID from);
void JoinThread();
void SpawnThread();
public:
/**
* Bare constructor, only for save/load. link_graph, join_date and actually
* settings have to be brutally const-casted in order to populate them.
*/
LinkGraphJob() : settings(_settings_game.linkgraph),
join_date(CalendarTime::INVALID_DATE), job_completed(false), job_aborted(false) {}
LinkGraphJob(const LinkGraph &orig);
~LinkGraphJob();
void Init();
/**
* Check if job has actually finished.
* This is allowed to spuriously return an incorrect value.
* @return True if job has actually finished.
*/
inline bool IsJobCompleted() const { return this->job_completed.load(std::memory_order_acquire); }
/**
* Check if job has been aborted.
* This is allowed to spuriously return false incorrectly, but is not allowed to incorrectly return true.
* @return True if job has been aborted.
*/
inline bool IsJobAborted() const { return this->job_aborted.load(std::memory_order_acquire); }
/**
* Abort job.
* The job may exit early at the next available opportunity.
* After this method has been called the state of the job is undefined, and the only valid operation
* is to join the thread and discard the job data.
*/
inline void AbortJob() { this->job_aborted.store(true, std::memory_order_release); }
/**
* Check if job is supposed to be finished.
* @return True if job should be finished by now, false if not.
*/
inline bool IsScheduledToBeJoined() const { return this->join_date <= TimerGameCalendar::date; }
/**
* Get the date when the job should be finished.
* @return Join date.
*/
inline TimerGameCalendar::Date JoinDate() const { return join_date; }
/**
* Change the join date on date cheating.
* @param interval Number of days to add.
*/
inline void ShiftJoinDate(TimerGameCalendar::Date interval) { this->join_date += interval; }
/**
* Get the link graph settings for this component.
* @return Settings.
*/
inline const LinkGraphSettings &Settings() const { return this->settings; }
/**
* Get a node abstraction with the specified id.
* @param num ID of the node.
* @return the Requested node.
*/
inline NodeAnnotation &operator[](NodeID num) { return this->nodes[num]; }
/**
* Get the size of the underlying link graph.
* @return Size.
*/
inline NodeID Size() const { return this->link_graph.Size(); }
/**
* Get the cargo of the underlying link graph.
* @return Cargo.
*/
inline CargoID Cargo() const { return this->link_graph.Cargo(); }
/**
* Get the date when the underlying link graph was last compressed.
* @return Compression date.
*/
inline TimerGameCalendar::Date LastCompression() const { return this->link_graph.LastCompression(); }
/**
* Get the ID of the underlying link graph.
* @return Link graph ID.
*/
inline LinkGraphID LinkGraphIndex() const { return this->link_graph.index; }
/**
* Get a reference to the underlying link graph. Only use this for save/load.
* @return Link graph.
*/
inline const LinkGraph &Graph() const { return this->link_graph; }
};
/**
* A leg of a path in the link graph. Paths can form trees by being "forked".
*/
class Path {
public:
static Path *invalid_path;
Path(NodeID n, bool source = false);
virtual ~Path() = default;
/** Get the node this leg passes. */
inline NodeID GetNode() const { return this->node; }
/** Get the overall origin of the path. */
inline NodeID GetOrigin() const { return this->origin; }
/** Get the parent leg of this one. */
inline Path *GetParent() { return this->parent; }
/** Get the overall capacity of the path. */
inline uint GetCapacity() const { return this->capacity; }
/** Get the free capacity of the path. */
inline int GetFreeCapacity() const { return this->free_capacity; }
/**
* Get ratio of free * 16 (so that we get fewer 0) /
* max(total capacity, 1) (so that we don't divide by 0).
* @param free Free capacity.
* @param total Total capacity.
* @return free * 16 / max(total, 1).
*/
inline static int GetCapacityRatio(int free, uint total)
{
return Clamp(free, PATH_CAP_MIN_FREE, PATH_CAP_MAX_FREE) * PATH_CAP_MULTIPLIER / std::max(total, 1U);
}
/**
* Get capacity ratio of this path.
* @return free capacity * 16 / (total capacity + 1).
*/
inline int GetCapacityRatio() const
{
return Path::GetCapacityRatio(this->free_capacity, this->capacity);
}
/** Get the overall distance of the path. */
inline uint GetDistance() const { return this->distance; }
/** Reduce the flow on this leg only by the specified amount. */
inline void ReduceFlow(uint f) { this->flow -= f; }
/** Increase the flow on this leg only by the specified amount. */
inline void AddFlow(uint f) { this->flow += f; }
/** Get the flow on this leg. */
inline uint GetFlow() const { return this->flow; }
/** Get the number of "forked off" child legs of this one. */
inline uint GetNumChildren() const { return this->num_children; }
/**
* Detach this path from its parent.
*/
inline void Detach()
{
if (this->parent != nullptr) {
this->parent->num_children--;
this->parent = nullptr;
}
}
uint AddFlow(uint f, LinkGraphJob &job, uint max_saturation);
void Fork(Path *base, uint cap, int free_cap, uint dist);
protected:
/**
* Some boundaries to clamp against in order to avoid integer overflows.
*/
enum PathCapacityBoundaries {
PATH_CAP_MULTIPLIER = 16,
PATH_CAP_MIN_FREE = (INT_MIN + 1) / PATH_CAP_MULTIPLIER,
PATH_CAP_MAX_FREE = (INT_MAX - 1) / PATH_CAP_MULTIPLIER
};
uint distance; ///< Sum(distance of all legs up to this one).
uint capacity; ///< This capacity is min(capacity) fom all edges.
int free_capacity; ///< This capacity is min(edge.capacity - edge.flow) for the current run of Dijkstra.
uint flow; ///< Flow the current run of the mcf solver assigns.
NodeID node; ///< Link graph node this leg passes.
NodeID origin; ///< Link graph node this path originates from.
uint num_children; ///< Number of child legs that have been forked from this path.
Path *parent; ///< Parent leg of this one.
};
#endif /* LINKGRAPHJOB_H */