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/* $Id$ */
#include "../stdafx.h"
#include "yapf.hpp"
#include "yapf_node_road.hpp"
template <class Types>
class CYapfCostRoadT
{
public:
typedef typename Types::Tpf Tpf; ///< pathfinder (derived from THIS class)
typedef typename Types::TrackFollower TrackFollower; ///< track follower helper
typedef typename Types::NodeList::Titem Node; ///< this will be our node type
typedef typename Node::Key Key; ///< key to hash tables
protected:
/// to access inherited path finder
Tpf& Yapf() {return *static_cast<Tpf*>(this);}
int SlopeCost(TileIndex tile, TileIndex next_tile, Trackdir trackdir)
{
// height of the center of the current tile
int x1 = TileX(tile) * TILE_SIZE;
int y1 = TileY(tile) * TILE_SIZE;
int z1 = GetSlopeZ(x1 + TILE_SIZE / 2, y1 + TILE_SIZE / 2);
// height of the center of the next tile
int x2 = TileX(next_tile) * TILE_SIZE;
int y2 = TileY(next_tile) * TILE_SIZE;
int z2 = GetSlopeZ(x2 + TILE_SIZE / 2, y2 + TILE_SIZE / 2);
if (z2 - z1 > 1) {
/* Slope up */
return Yapf().PfGetSettings().road_slope_penalty;
}
return 0;
}
/** return one tile cost */
FORCEINLINE int OneTileCost(TileIndex tile, Trackdir trackdir)
{
int cost = 0;
// set base cost
if (IsDiagonalTrackdir(trackdir)) {
cost += YAPF_TILE_LENGTH;
switch (GetTileType(tile)) {
case MP_STREET:
/* Increase the cost for level crossings */
if (IsLevelCrossing(tile))
cost += Yapf().PfGetSettings().road_crossing_penalty;
break;
default:
break;
}
} else {
// non-diagonal trackdir
cost = YAPF_TILE_CORNER_LENGTH;
}
return cost;
}
public:
/** Called by YAPF to calculate the cost from the origin to the given node.
* Calculates only the cost of given node, adds it to the parent node cost
* and stores the result into Node::m_cost member */
FORCEINLINE bool PfCalcCost(Node& n)
{
int segment_cost = 0;
// start at n.m_key.m_tile / n.m_key.m_td and walk to the end of segment
TileIndex tile = n.m_key.m_tile;
Trackdir trackdir = n.m_key.m_td;
while (true) {
// base tile cost depending on distance between edges
segment_cost += Yapf().OneTileCost(tile, trackdir);
// stop if we have just entered the depot
if (IsTileDepotType(tile, TRANSPORT_ROAD) && trackdir == DiagdirToDiagTrackdir(ReverseDiagDir(GetRoadDepotDirection(tile)))) {
// next time we will reverse and leave the depot
break;
}
// if there are no reachable trackdirs on new tile, we have end of road
TrackFollower F;
if (!F.Follow(tile, trackdir)) break;
// if there are more trackdirs available & reachable, we are at the end of segment
if (KillFirstBit2x64(F.m_new_td_bits) != 0) break;
Trackdir new_td = (Trackdir)FindFirstBit2x64(F.m_new_td_bits);
// stop if RV is on simple loop with no junctions
if (F.m_new_tile == n.m_key.m_tile && new_td == n.m_key.m_td) return false;
// if we skipped some tunnel tiles, add their cost
segment_cost += F.m_tiles_skipped * YAPF_TILE_LENGTH;
// add hilly terrain penalty
segment_cost += Yapf().SlopeCost(tile, F.m_new_tile, trackdir);
// add min/max speed penalties
int min_speed = 0;
int max_speed = F.GetSpeedLimit(&min_speed);
const Vehicle* v = Yapf().GetVehicle();
if (max_speed < v->max_speed) segment_cost += 1 * (v->max_speed - max_speed);
if (min_speed > v->max_speed) segment_cost += 10 * (min_speed - v->max_speed);
// move to the next tile
tile = F.m_new_tile;
trackdir = new_td;
};
// save end of segment back to the node
n.m_segment_last_tile = tile;
n.m_segment_last_td = trackdir;
// save also tile cost
int parent_cost = (n.m_parent != NULL) ? n.m_parent->m_cost : 0;
n.m_cost = parent_cost + segment_cost;
return true;
}
};
template <class Types>
class CYapfDestinationAnyDepotRoadT
{
public:
typedef typename Types::Tpf Tpf; ///< the pathfinder class (derived from THIS class)
typedef typename Types::TrackFollower TrackFollower;
typedef typename Types::NodeList::Titem Node; ///< this will be our node type
typedef typename Node::Key Key; ///< key to hash tables
/// to access inherited path finder
Tpf& Yapf() {return *static_cast<Tpf*>(this);}
/// Called by YAPF to detect if node ends in the desired destination
FORCEINLINE bool PfDetectDestination(Node& n)
{
bool bDest = IsTileDepotType(n.m_segment_last_tile, TRANSPORT_ROAD);
return bDest;
}
/** Called by YAPF to calculate cost estimate. Calculates distance to the destination
* adds it to the actual cost from origin and stores the sum to the Node::m_estimate */
FORCEINLINE bool PfCalcEstimate(Node& n)
{
n.m_estimate = n.m_cost;
return true;
}
};
template <class Types>
class CYapfDestinationTileRoadT
{
public:
typedef typename Types::Tpf Tpf; ///< the pathfinder class (derived from THIS class)
typedef typename Types::TrackFollower TrackFollower;
typedef typename Types::NodeList::Titem Node; ///< this will be our node type
typedef typename Node::Key Key; ///< key to hash tables
protected:
TileIndex m_destTile;
TrackdirBits m_destTrackdirs;
public:
void SetDestination(TileIndex tile, TrackdirBits trackdirs)
{
m_destTile = tile;
m_destTrackdirs = trackdirs;
}
protected:
/// to access inherited path finder
Tpf& Yapf() {return *static_cast<Tpf*>(this);}
public:
/// Called by YAPF to detect if node ends in the desired destination
FORCEINLINE bool PfDetectDestination(Node& n)
{
bool bDest = (n.m_segment_last_tile == m_destTile) && ((m_destTrackdirs & TrackdirToTrackdirBits(n.m_segment_last_td)) != TRACKDIR_BIT_NONE);
return bDest;
}
/** Called by YAPF to calculate cost estimate. Calculates distance to the destination
* adds it to the actual cost from origin and stores the sum to the Node::m_estimate */
inline bool PfCalcEstimate(Node& n)
{
static int dg_dir_to_x_offs[] = {-1, 0, 1, 0};
static int dg_dir_to_y_offs[] = {0, 1, 0, -1};
if (PfDetectDestination(n)) {
n.m_estimate = n.m_cost;
return true;
}
TileIndex tile = n.m_segment_last_tile;
DiagDirection exitdir = TrackdirToExitdir(n.m_segment_last_td);
int x1 = 2 * TileX(tile) + dg_dir_to_x_offs[(int)exitdir];
int y1 = 2 * TileY(tile) + dg_dir_to_y_offs[(int)exitdir];
int x2 = 2 * TileX(m_destTile);
int y2 = 2 * TileY(m_destTile);
int dx = abs(x1 - x2);
int dy = abs(y1 - y2);
int dmin = min(dx, dy);
int dxy = abs(dx - dy);
int d = dmin * YAPF_TILE_CORNER_LENGTH + (dxy - 1) * (YAPF_TILE_LENGTH / 2);
n.m_estimate = n.m_cost + d;
assert(n.m_estimate >= n.m_parent->m_estimate);
return true;
}
};
template <class Types>
class CYapfFollowRoadT
{
public:
typedef typename Types::Tpf Tpf; ///< the pathfinder class (derived from THIS class)
typedef typename Types::TrackFollower TrackFollower;
typedef typename Types::NodeList::Titem Node; ///< this will be our node type
typedef typename Node::Key Key; ///< key to hash tables
protected:
/// to access inherited path finder
FORCEINLINE Tpf& Yapf() {return *static_cast<Tpf*>(this);}
public:
/** Called by YAPF to move from the given node to the next tile. For each
* reachable trackdir on the new tile creates new node, initializes it
* and adds it to the open list by calling Yapf().AddNewNode(n) */
inline void PfFollowNode(Node& old_node)
{
TrackFollower F;
if (F.Follow(old_node.m_segment_last_tile, old_node.m_segment_last_td))
Yapf().AddMultipleNodes(&old_node, F.m_new_tile, F.m_new_td_bits);
}
/// return debug report character to identify the transportation type
FORCEINLINE char TransportTypeChar() const {return 'r';}
static Trackdir stChooseRoadTrack(Vehicle *v, TileIndex tile, DiagDirection enterdir)
{
Tpf pf;
return pf.ChooseRoadTrack(v, tile, enterdir);
}
FORCEINLINE Trackdir ChooseRoadTrack(Vehicle *v, TileIndex tile, DiagDirection enterdir)
{
// handle special case - when next tile is destination tile
if (tile == v->dest_tile) {
// choose diagonal trackdir reachable from enterdir
return (Trackdir)DiagdirToDiagTrackdir(enterdir);
}
// our source tile will be the next vehicle tile (should be the given one)
TileIndex src_tile = tile;
// get available trackdirs on the start tile
uint ts = GetTileTrackStatus(tile, TRANSPORT_ROAD);
TrackdirBits src_trackdirs = (TrackdirBits)(ts & TRACKDIR_BIT_MASK);
// select reachable trackdirs only
src_trackdirs &= DiagdirReachesTrackdirs(enterdir);
// get available trackdirs on the destination tile
TileIndex dest_tile = v->dest_tile;
uint dest_ts = GetTileTrackStatus(dest_tile, TRANSPORT_ROAD);
TrackdirBits dest_trackdirs = (TrackdirBits)(dest_ts & TRACKDIR_BIT_MASK);
// set origin and destination nodes
Yapf().SetOrigin(src_tile, src_trackdirs);
Yapf().SetDestination(dest_tile, dest_trackdirs);
// find the best path
Yapf().FindPath(v);
// if path not found - return INVALID_TRACKDIR
Trackdir next_trackdir = INVALID_TRACKDIR;
Node* pNode = &Yapf().GetBestNode();
if (pNode != NULL) {
// path was found or at least suggested
// walk through the path back to its origin
while (pNode->m_parent != NULL) {
pNode = pNode->m_parent;
}
// return trackdir from the best origin node (one of start nodes)
Node& best_next_node = *pNode;
assert(best_next_node.GetTile() == tile);
next_trackdir = best_next_node.GetTrackdir();
}
return next_trackdir;
}
static uint stDistanceToTile(const Vehicle *v, TileIndex tile)
{
Tpf pf;
return pf.DistanceToTile(v, tile);
}
FORCEINLINE uint DistanceToTile(const Vehicle *v, TileIndex dst_tile)
{
// handle special case - when current tile is the destination tile
if (dst_tile == v->tile) {
// distance is zero in this case
return 0;
}
if (!SetOriginFromVehiclePos(v)) return UINT_MAX;
// set destination tile, trackdir
// get available trackdirs on the destination tile
uint dest_ts = GetTileTrackStatus(dst_tile, TRANSPORT_ROAD);
TrackdirBits dst_td_bits = (TrackdirBits)(dest_ts & TRACKDIR_BIT_MASK);
Yapf().SetDestination(dst_tile, dst_td_bits);
// find the best path
Yapf().FindPath(v);
// if path not found - return distance = UINT_MAX
uint dist = UINT_MAX;
Node* pNode = &Yapf().GetBestNode();
if (pNode != NULL) {
// path was found or at least suggested
// get the path cost estimate
dist = pNode->GetCostEstimate();
}
return dist;
}
/** Return true if the valid origin (tile/trackdir) was set from the current vehicle position. */
FORCEINLINE bool SetOriginFromVehiclePos(const Vehicle *v)
{
// set origin (tile, trackdir)
TileIndex src_tile = v->tile;
Trackdir src_td = GetVehicleTrackdir(v);
if ((GetTileTrackStatus(src_tile, TRANSPORT_ROAD) & TrackdirToTrackdirBits(src_td)) == 0) {
// sometimes the roadveh is not on the road (it resides on non-existing track)
// how should we handle that situation?
return false;
}
Yapf().SetOrigin(src_tile, TrackdirToTrackdirBits(src_td));
return true;
}
static Depot* stFindNearestDepot(Vehicle* v, TileIndex tile, Trackdir td)
{
Tpf pf;
return pf.FindNearestDepot(v, tile, td);
}
FORCEINLINE Depot* FindNearestDepot(Vehicle* v, TileIndex tile, Trackdir td)
{
// set origin and destination nodes
Yapf().SetOrigin(tile, TrackdirToTrackdirBits(td));
// find the best path
bool bFound = Yapf().FindPath(v);
if (!bFound) return false;
// some path found
// get found depot tile
Node& n = Yapf().GetBestNode();
TileIndex depot_tile = n.m_segment_last_tile;
assert(IsTileDepotType(depot_tile, TRANSPORT_ROAD));
if (!IsTileOwner(depot_tile, (Owner)v->owner)) return false;
Depot* ret = GetDepotByTile(depot_tile);
return ret;
}
};
template <class Tpf_, class Tnode_list, template <class Types> class Tdestination>
struct CYapfRoad_TypesT
{
typedef CYapfRoad_TypesT<Tpf_, Tnode_list, Tdestination> Types;
typedef Tpf_ Tpf;
typedef CFollowTrackRoad TrackFollower;
typedef Tnode_list NodeList;
typedef CYapfBaseT<Types> PfBase;
typedef CYapfFollowRoadT<Types> PfFollow;
typedef CYapfOriginTileT<Types> PfOrigin;
typedef Tdestination<Types> PfDestination;
typedef CYapfSegmentCostCacheNoneT<Types> PfCache;
typedef CYapfCostRoadT<Types> PfCost;
};
struct CYapfRoad1 : CYapfT<CYapfRoad_TypesT<CYapfRoad1 , CRoadNodeListTrackDir, CYapfDestinationTileRoadT > > {};
struct CYapfRoad2 : CYapfT<CYapfRoad_TypesT<CYapfRoad2 , CRoadNodeListExitDir , CYapfDestinationTileRoadT > > {};
struct CYapfRoadAnyDepot1 : CYapfT<CYapfRoad_TypesT<CYapfRoadAnyDepot1, CRoadNodeListTrackDir, CYapfDestinationAnyDepotRoadT> > {};
struct CYapfRoadAnyDepot2 : CYapfT<CYapfRoad_TypesT<CYapfRoadAnyDepot2, CRoadNodeListExitDir , CYapfDestinationAnyDepotRoadT> > {};
Trackdir YapfChooseRoadTrack(Vehicle *v, TileIndex tile, DiagDirection enterdir)
{
// default is YAPF type 2
typedef Trackdir (*PfnChooseRoadTrack)(Vehicle*, TileIndex, DiagDirection);
PfnChooseRoadTrack pfnChooseRoadTrack = &CYapfRoad2::stChooseRoadTrack; // default: ExitDir, allow 90-deg
// check if non-default YAPF type should be used
if (_patches.yapf.disable_node_optimization)
pfnChooseRoadTrack = &CYapfRoad1::stChooseRoadTrack; // Trackdir, allow 90-deg
Trackdir td_ret = pfnChooseRoadTrack(v, tile, enterdir);
return td_ret;
}
uint YapfRoadVehDistanceToTile(const Vehicle* v, TileIndex tile)
{
// default is YAPF type 2
typedef uint (*PfnDistanceToTile)(const Vehicle*, TileIndex);
PfnDistanceToTile pfnDistanceToTile = &CYapfRoad2::stDistanceToTile; // default: ExitDir, allow 90-deg
// check if non-default YAPF type should be used
if (_patches.yapf.disable_node_optimization)
pfnDistanceToTile = &CYapfRoad1::stDistanceToTile; // Trackdir, allow 90-deg
// measure distance in YAPF units
uint dist = pfnDistanceToTile(v, tile);
// convert distance to tiles
if (dist != UINT_MAX)
dist = (dist + 10 - 1) / 10; // TODO: change road YAPF unit from 10 to YAPF_TILE_LENGTH
return dist;
}
Depot* YapfFindNearestRoadDepot(const Vehicle *v)
{
TileIndex tile = v->tile;
if (v->u.road.state == 255) tile = GetVehicleOutOfTunnelTile(v);
Trackdir trackdir = GetVehicleTrackdir(v);
if ((GetTileTrackStatus(tile, TRANSPORT_ROAD) & TrackdirToTrackdirBits(trackdir)) == 0)
return NULL;
// handle the case when our vehicle is already in the depot tile
if (IsTileType(tile, MP_STREET) && IsTileDepotType(tile, TRANSPORT_ROAD)) {
// only what we need to return is the Depot*
return GetDepotByTile(tile);
}
// default is YAPF type 2
typedef Depot* (*PfnFindNearestDepot)(Vehicle*, TileIndex, Trackdir);
PfnFindNearestDepot pfnFindNearestDepot = &CYapfRoadAnyDepot2::stFindNearestDepot;
// check if non-default YAPF type should be used
if (_patches.yapf.disable_node_optimization)
pfnFindNearestDepot = &CYapfRoadAnyDepot1::stFindNearestDepot; // Trackdir, allow 90-deg
Depot* ret = pfnFindNearestDepot(const_cast<Vehicle*>(v), tile, trackdir);
return ret;
}
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