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Location: cpp/openttd-patchpack/source/src/linkgraph/demands.cpp
r23439:19bd53812e56
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Fix e4cc06f67: [AzurePipelines] rebase only for PRs
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#include "../stdafx.h"
#include "demands.h"
#include <queue>
#include "../safeguards.h"
typedef std::queue<NodeID> NodeList;
/**
* Scale various things according to symmetric/asymmetric distribution.
*/
class Scaler {
public:
void SetDemands(LinkGraphJob &job, NodeID from, NodeID to, uint demand_forw);
};
/**
* Scaler for symmetric distribution.
*/
class SymmetricScaler : public Scaler {
public:
/**
* Constructor.
* @param mod_size Size modifier to be used. Determines how much demands
* increase with the supply of the remote station.
*/
inline SymmetricScaler(uint mod_size) : mod_size(mod_size), supply_sum(0),
demand_per_node(0)
{}
/**
* Count a node's supply into the sum of supplies.
* @param node Node.
*/
inline void AddNode(const Node &node)
{
this->supply_sum += node.Supply();
}
/**
* Calculate the mean demand per node using the sum of supplies.
* @param num_demands Number of accepting nodes.
*/
inline void SetDemandPerNode(uint num_demands)
{
this->demand_per_node = max(this->supply_sum / num_demands, 1U);
}
/**
* Get the effective supply of one node towards another one. In symmetric
* distribution the supply of the other node is weighed in.
* @param from The supplying node.
* @param to The receiving node.
* @return Effective supply.
*/
inline uint EffectiveSupply(const Node &from, const Node &to)
{
return max(from.Supply() * max(1U, to.Supply()) * this->mod_size / 100 / this->demand_per_node, 1U);
}
/**
* Check if there is any acceptance left for this node. In symmetric distribution
* nodes only accept anything if they also supply something. So if
* undelivered_supply == 0 at the node there isn't any demand left either.
* @param to Node to be checked.
* @return If demand is left.
*/
inline bool HasDemandLeft(const Node &to)
{
return (to.Supply() == 0 || to.UndeliveredSupply() > 0) && to.Demand() > 0;
}
void SetDemands(LinkGraphJob &job, NodeID from, NodeID to, uint demand_forw);
private:
uint mod_size; ///< Size modifier. Determines how much demands increase with the supply of the remote station.
uint supply_sum; ///< Sum of all supplies in the component.
uint demand_per_node; ///< Mean demand associated with each node.
};
/**
* A scaler for asymmetric distribution.
*/
class AsymmetricScaler : public Scaler {
public:
/**
* Nothing to do here.
* @param unused.
*/
inline void AddNode(const Node &)
{
}
/**
* Nothing to do here.
* @param unused.
*/
inline void SetDemandPerNode(uint)
{
}
/**
* Get the effective supply of one node towards another one.
* @param from The supplying node.
* @param unused.
*/
inline uint EffectiveSupply(const Node &from, const Node &)
{
return from.Supply();
}
/**
* Check if there is any acceptance left for this node. In asymmetric distribution
* nodes always accept as long as their demand > 0.
* @param to The node to be checked.
*/
inline bool HasDemandLeft(const Node &to) { return to.Demand() > 0; }
};
/**
* Set the demands between two nodes using the given base demand. In symmetric mode
* this sets demands in both directions.
* @param job The link graph job.
* @param from_id The supplying node.
* @param to_id The receiving node.
* @param demand_forw Demand calculated for the "forward" direction.
*/
void SymmetricScaler::SetDemands(LinkGraphJob &job, NodeID from_id, NodeID to_id, uint demand_forw)
{
if (job[from_id].Demand() > 0) {
uint demand_back = demand_forw * this->mod_size / 100;
uint undelivered = job[to_id].UndeliveredSupply();
if (demand_back > undelivered) {
demand_back = undelivered;
demand_forw = max(1U, demand_back * 100 / this->mod_size);
}
this->Scaler::SetDemands(job, to_id, from_id, demand_back);
}
this->Scaler::SetDemands(job, from_id, to_id, demand_forw);
}
/**
* Set the demands between two nodes using the given base demand. In asymmetric mode
* this only sets demand in the "forward" direction.
* @param job The link graph job.
* @param from_id The supplying node.
* @param to_id The receiving node.
* @param demand_forw Demand calculated for the "forward" direction.
*/
inline void Scaler::SetDemands(LinkGraphJob &job, NodeID from_id, NodeID to_id, uint demand_forw)
{
job[from_id].DeliverSupply(to_id, demand_forw);
}
/**
* Do the actual demand calculation, called from constructor.
* @param job Job to calculate the demands for.
* @tparam Tscaler Scaler to be used for scaling demands.
*/
template<class Tscaler>
void DemandCalculator::CalcDemand(LinkGraphJob &job, Tscaler scaler)
{
NodeList supplies;
NodeList demands;
uint num_supplies = 0;
uint num_demands = 0;
for (NodeID node = 0; node < job.Size(); node++) {
scaler.AddNode(job[node]);
if (job[node].Supply() > 0) {
supplies.push(node);
num_supplies++;
}
if (job[node].Demand() > 0) {
demands.push(node);
num_demands++;
}
}
if (num_supplies == 0 || num_demands == 0) return;
/* Mean acceptance attributed to each node. If the distribution is
* symmetric this is relative to remote supply, otherwise it is
* relative to remote demand. */
scaler.SetDemandPerNode(num_demands);
uint chance = 0;
while (!supplies.empty() && !demands.empty()) {
NodeID from_id = supplies.front();
supplies.pop();
for (uint i = 0; i < num_demands; ++i) {
assert(!demands.empty());
NodeID to_id = demands.front();
demands.pop();
if (from_id == to_id) {
/* Only one node with supply and demand left */
if (demands.empty() && supplies.empty()) return;
demands.push(to_id);
continue;
}
int32 supply = scaler.EffectiveSupply(job[from_id], job[to_id]);
assert(supply > 0);
/* Scale the distance by mod_dist around max_distance */
int32 distance = this->max_distance - (this->max_distance -
(int32)DistanceMaxPlusManhattan(job[from_id].XY(), job[to_id].XY())) *
this->mod_dist / 100;
/* Scale the accuracy by distance around accuracy / 2 */
int32 divisor = this->accuracy * (this->mod_dist - 50) / 100 +
this->accuracy * distance / this->max_distance + 1;
assert(divisor > 0);
uint demand_forw = 0;
if (divisor <= supply) {
/* At first only distribute demand if
* effective supply / accuracy divisor >= 1
* Others are too small or too far away to be considered. */
demand_forw = supply / divisor;
} else if (++chance > this->accuracy * num_demands * num_supplies) {
/* After some trying, if there is still supply left, distribute
* demand also to other nodes. */
demand_forw = 1;
}
demand_forw = min(demand_forw, job[from_id].UndeliveredSupply());
scaler.SetDemands(job, from_id, to_id, demand_forw);
if (scaler.HasDemandLeft(job[to_id])) {
demands.push(to_id);
} else {
num_demands--;
}
if (job[from_id].UndeliveredSupply() == 0) break;
}
if (job[from_id].UndeliveredSupply() != 0) {
supplies.push(from_id);
} else {
num_supplies--;
}
}
}
/**
* Create the DemandCalculator and immediately do the calculation.
* @param job Job to calculate the demands for.
*/
DemandCalculator::DemandCalculator(LinkGraphJob &job) :
max_distance(DistanceMaxPlusManhattan(TileXY(0,0), TileXY(MapMaxX(), MapMaxY())))
{
const LinkGraphSettings &settings = job.Settings();
CargoID cargo = job.Cargo();
this->accuracy = settings.accuracy;
this->mod_dist = settings.demand_distance;
if (this->mod_dist > 100) {
/* Increase effect of mod_dist > 100 */
int over100 = this->mod_dist - 100;
this->mod_dist = 100 + over100 * over100;
}
switch (settings.GetDistributionType(cargo)) {
case DT_SYMMETRIC:
this->CalcDemand<SymmetricScaler>(job, SymmetricScaler(settings.demand_size));
break;
case DT_ASYMMETRIC:
this->CalcDemand<AsymmetricScaler>(job, AsymmetricScaler());
break;
default:
/* Nothing to do. */
break;
}
}
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