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mirror of https://github.com/vcmi/vcmi.git synced 2024-12-26 22:57:00 +02:00
vcmi/CPathfinder.cpp
Michał W. Urbańczyk 48cb63f144 * possibly fixed bug with the mage guild when no spells available
* events won't be shown and won't block movement
* casualties among hero army and neutral creatures are saved
* it's possible to build lighthouse
* increased thread-safety (may prevent some crashes)
* minor fixes
2008-09-20 18:30:37 +00:00

422 lines
10 KiB
C++

#include "stdafx.h"
#include "global.h"
#include "CPathfinder.h"
#include "CGameInfo.h"
#include "hch/CAmbarCendamo.h"
#include "mapHandler.h"
#include "CGameState.h"
#include "hch/CObjectHandler.h"
#include "hch/CDefObjInfoHandler.h"
using namespace std;
vector<Coordinate>* CPathfinder::GetPath(Coordinate start, Coordinate end, const CGHeroInstance* hero)
{
Start = start;
End = end;
return GetPath(hero);
}
/*
* Does basic input checking and setup for the path calculation.
*/
vector<Coordinate>* CPathfinder::GetPath(const CGHeroInstance* hero)
{
//check input
if ((Start.x < 0)||(Start.y < 0)||(Start.z < 0)||(End.x < 0)||(End.y < 0)||(End.z < 0))
{
return NULL;
}
if ((Start.x >= CGI->mh->sizes.x)||(Start.y >= CGI->mh->sizes.y)||(Start.z >= CGI->mh->sizes.z)
||(End.x >= CGI->mh->sizes.x)||(End.y >= CGI->mh->sizes.y)||(End.z >= CGI->mh->sizes.z))
{
return NULL;
}
Hero = hero;
//Reset the queues
Open = priority_queue < vector<Coordinate>, vector<vector<Coordinate> >, Compare>();
Closed.clear();
//Determine if the hero can move on water
int3 hpos = Hero->getPosition(false);
if (!Hero->canWalkOnSea())
{
if (CGI->mh->ttiles[hpos.x][hpos.y][hpos.z].tileInfo->tertype==water)
blockLandSea=false;
else
blockLandSea=true;
}
else
{
blockLandSea = boost::logic::indeterminate;
}
CalcG(&Start);
Start.h = 0;
CalcG(&End);
CalcH(&End);
//If it is impossible to get to where the user clicked, dont return a path.
if(End.h == -1)
{
return NULL;
}
//Add the Start node to the open list.
vector<Coordinate> startPath;
startPath.push_back(Start);
Open.push(startPath);
//Calculate the path.
vector<Coordinate>* toReturn = CalcPath();
if(toReturn != NULL)
{
//Flip the route since it is calculated in reverse
int size = toReturn->size();
for(int i = 0; i < size/2; i++)
{
Coordinate t = toReturn->at(i);
(*toReturn)[i] = toReturn->at(size-1-i);
(*toReturn)[size-1-i] = t;
}
}
return toReturn;
}
/*
* Does the actual path calculation. Don't call this directly, call GetPath instead.
*/
vector<Coordinate>* CPathfinder::CalcPath()
{
if(Open.empty())
{
return NULL;
}
//Find the path in open with the smallest cost (f = g + h)
//and remove it from open
vector<Coordinate>* branch = new vector<Coordinate>();
*branch = Open.top();
Open.pop();
//Don't search elements in the closed list, for they have been visited already.
if(!ExistsInClosed(branch->back()))
{
//Add it to the closed list.
Closed.push_back(branch->back());
//If it is the destination
if(branch->back().x == End.x && branch->back().y == End.y && branch->back().z == End.z)
{
return branch;
}
//Add neighbors to the open list
AddNeighbors(branch);
}
delete branch;
return CalcPath();
}
/*
* Determines if the given node exists in the closed list, returns true if it does. This is
* used to ensure you dont check the same node twice.
*/
bool CPathfinder::ExistsInClosed(Coordinate node)
{
for(int i = 0; i < Closed.size(); i++)
{
if(node.x == Closed[i].x && node.y == Closed[i].y && node.z == Closed[i].z)
return true;
}
return false;
}
/*
* Adds the neighbors of the current node to the open cue so they can be considered in the
* path creation. If the node has a cost (f = g + h) less than zero, it isn't added to Open.
*/
void CPathfinder::AddNeighbors(vector<Coordinate>* branch)
{
//8 possible Nodes to add
//
// 1 2 3
// 4 X 5
// 6 7 8
Coordinate node = branch->back();
Coordinate c;
for(int i = node.x-1; i<node.x+2;i++)
{
for(int j = node.y-1; j < node.y+2; j++)
{
if(i >= 0 && j >= 0 && i < CGI->mh->sizes.x && j < CGI->mh->sizes.y)
{
c = Coordinate(i,j,node.z);
//Calculate the distance from the end node
CalcG(&c);
//Calculate the movement cost
CalcH(&c);
if(c.g != -1 && c.h != -1)
{
bool pass = true; //checking for allowed visiting direction
for(int b=0; b<CGI->mh->ttiles[i][j][node.z].tileInfo->visitableObjects.size(); ++b) //checking destination tile
{
const TerrainTile * pom = CGI->mh->ttiles[i][j][node.z].tileInfo;
if(!vstd::contains(pom->blockingObjects,pom->visitableObjects[b]))
break;
CGDefInfo * di = pom->visitableObjects[b]->defInfo;
if( (i == node.x-1 && j == node.y-1) && !(di->visitDir & (1<<4)) )
{
pass = false; break;
}
if( (i == node.x && j == node.y-1) && !(di->visitDir & (1<<5)) )
{
pass = false; break;
}
if( (i == node.x+1 && j == node.y-1) && !(di->visitDir & (1<<6)) )
{
pass = false; break;
}
if( (i == node.x+1 && j == node.y) && !(di->visitDir & (1<<7)) )
{
pass = false; break;
}
if( (i == node.x+1 && j == node.y+1) && !(di->visitDir & (1<<0)) )
{
pass = false; break;
}
if( (i == node.x && j == node.y+1) && !(di->visitDir & (1<<1)) )
{
pass = false; break;
}
if( (i == node.x-1 && j == node.y+1) && !(di->visitDir & (1<<2)) )
{
pass = false; break;
}
if( (i == node.x-1 && j == node.y) && !(di->visitDir & (1<<3)) )
{
pass = false; break;
}
}
for(int b=0; b<CGI->mh->ttiles[node.x][node.y][node.z].tileInfo->visitableObjects.size(); ++b) //checking source tile
{
const TerrainTile * pom = CGI->mh->ttiles[node.x][node.y][node.z].tileInfo;
if(!vstd::contains(pom->blockingObjects,pom->visitableObjects[b]))
break;
CGDefInfo * di = pom->visitableObjects[b]->defInfo;
if( (i == node.x-1 && j == node.y-1) && !(di->visitDir & (1<<0)) )
{
pass = false; break;
}
if( (i == node.x && j == node.y-1) && !(di->visitDir & (1<<1)) )
{
pass = false; break;
}
if( (i == node.x+1 && j == node.y-1) && !(di->visitDir & (1<<2)) )
{
pass = false; break;
}
if( (i == node.x+1 && j == node.y) && !(di->visitDir & (1<<3)) )
{
pass = false; break;
}
if( (i == node.x+1 && j == node.y+1) && !(di->visitDir & (1<<4)) )
{
pass = false; break;
}
if( (i == node.x && j == node.y+1) && !(di->visitDir & (1<<5)) )
{
pass = false; break;
}
if( (i == node.x-1 && j == node.y+1) && !(di->visitDir & (1<<6)) )
{
pass = false; break;
}
if( (i == node.x-1 && j == node.y) && !(di->visitDir & (1<<7)) )
{
pass = false; break;
}
}
if(pass)
{
vector<Coordinate> toAdd = *branch;
toAdd.push_back(c);
Open.push(toAdd);
}
}
//delete c;
}
}
}
}
/*
* Calculates the movement cost of the node. Returns -1 if it is impossible to travel on.
*/
void CPathfinder::CalcH(Coordinate* node)
{
/*
* If the terrain is blocked
* If the terrain is rock
* If the Hero cant walk on water and node is in water
* If the Hero is on water and the node is not.
* If there is fog of war on the node.
* => Impossible to move there.
*/
const TerrainTile *pom = CGI->mh->ttiles[node->x][node->y][node->z].tileInfo;
if( (pom->blocked && !(node->x==End.x && node->y==End.y && pom->visitable)) ||
(pom->tertype==rock) ||
((blockLandSea) && (pom->tertype==water)) ||
(!CGI->state->players[Hero->tempOwner].fogOfWarMap[node->x][node->y][node->z]) ||
((!blockLandSea) && (pom->tertype!=water)))
{
//Impossible.
node->h = -1;
return;
}
int ret=-1;
int x = node->x;
int y = node->y;
if(node->x>=CGI->mh->map->width)
x = CGI->mh->map->width-1;
if(node->y>=CGI->mh->map->height)
y = CGI->mh->map->height-1;
//Get the movement cost.
ret = Hero->getTileCost(CGI->mh->ttiles[x][y][node->z].tileInfo->tertype, CGI->mh->map->terrain[x][y][node->z].malle,CGI->mh->map->terrain[x][y][node->z].nuine);
node->h = ret;
}
/*
* Calculates distance from node to end node.
*/
void CPathfinder::CalcG(Coordinate* node)
{
float dist = (End.x-node->x) * (End.x-node->x) + (End.y-node->y) * (End.y-node->y);
node->g = sqrt(dist);
return;
}
/*
* Converts the old Pathfinder format for compatibility reasons. This should be replaced
* eventually by making the need for it obsolete.
*/
CPath* CPathfinder::ConvertToOldFormat(vector<Coordinate>* p)
{
if(p == NULL)
return NULL;
CPath* path = new CPath();
std::vector<int> costs; //vector with costs of tiles
for(int i = 0; i < p->size(); i++)
{
CPathNode temp;
//Set coord
temp.coord = int3(p->at(i).x,p->at(i).y,p->at(i).z);
//Set accesible
if(p->at(i).h == -1)
{
temp.accesible = false;
}
else
{
temp.accesible = true;
}
//set diagonality
float diagonal = 1.0f; //by default
if(i>0)
{
if(p->at(i-1).x != temp.coord.x && p->at(i-1).y != temp.coord.y)
{
diagonal = sqrt(2.0f);
}
}
//Set distance
costs.push_back( i==0 ? 0 : p->at(i - 1).h * diagonal );
//theNodeBefore is never used outside of pathfinding?
//Set visited
temp.visited = false;
path->nodes.push_back(temp);
}
costs.push_back(0);
for(int i=path->nodes.size()-1; i>=0; --i)
{
path->nodes[i].dist = costs[i+1] + ((i == path->nodes.size()-1) ? 0 : path->nodes[i+1].dist);
}
return path;
}
void CPathfinder::convertPath(CPath * path, unsigned int mode) //mode=0 -> from 'manifest' to 'object'
{
if (mode==0)
{
for (int i=0;i<path->nodes.size();i++)
{
path->nodes[i].coord = CGHeroInstance::convertPosition(path->nodes[i].coord,true);
}
}
}
int3 CPath::startPos()
{
return int3(nodes[nodes.size()-1].coord.x,nodes[nodes.size()-1].coord.y,nodes[nodes.size()-1].coord.z);
}
int3 CPath::endPos()
{
return int3(nodes[0].coord.x,nodes[0].coord.y,nodes[0].coord.z);
}
/*
* The function used by the priority cue to determine which node to put at the top.
*/
bool Compare::operator()(const vector<Coordinate>& a, const vector<Coordinate>& b)
{
double aTotal=0;
double bTotal=0;
for(int i = 0; i < a.size(); i++)
{
aTotal += a[i].g*a[i].h;
}
for(int i = 0; i < b.size(); i++)
{
bTotal += b[i].g*b[i].h;
}
return aTotal > bTotal;
}
void Coordinate::operator =(const Coordinate &other)
{
this->x = other.x;
this->y = other.y;
this->z = other.z;
this->g = other.g;
this->h = other.h;
}