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/*
= = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = =
Copyright ( C ) 2000 - 2013 , Raven Software , Inc .
Copyright ( C ) 2001 - 2013 , Activision , Inc .
Copyright ( C ) 2013 - 2015 , OpenJK contributors
This file is part of the OpenJK source code .
OpenJK is free software ; you can redistribute it and / or modify it
under the terms of the GNU General Public License version 2 as
published by the Free Software Foundation .
This program 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 this program ; if not , see < http : //www.gnu.org/licenses/>.
= = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = =
*/
# include "g_headers.h"
# include <algorithm>
# include "b_local.h"
# include "g_navigator.h"
# include "g_nav.h"
extern int NAVNEW_ClearPathBetweenPoints ( vec3_t start , vec3_t end , vec3_t mins , vec3_t maxs , int ignore , int clipmask ) ;
extern qboolean NAV_CheckNodeFailedForEnt ( gentity_t * ent , int nodeNum ) ;
extern qboolean G_EntIsUnlockedDoor ( int entityNum ) ;
extern qboolean G_EntIsDoor ( int entityNum ) ;
extern qboolean G_EntIsBreakable ( int entityNum ) ;
extern qboolean G_EntIsRemovableUsable ( int entNum ) ;
extern cvar_t * d_altRoutes ;
extern cvar_t * d_patched ;
static vec3_t wpMaxs = { 16 , 16 , 32 } ;
static vec3_t wpMins = { - 16 , - 16 , - 24 + STEPSIZE } ; //WTF: was 16??!!!
static byte CHECKED_NO = 0 ;
static byte CHECKED_FAILED = 1 ;
static byte CHECKED_PASSED = 2 ;
/*
- - - - - - - - - - - - - - - - - - - - - - - - -
CEdge
- - - - - - - - - - - - - - - - - - - - - - - - -
*/
CEdge : : CEdge ( void )
{
CEdge ( - 1 , - 1 , - 1 ) ;
}
CEdge : : CEdge ( int first , int second , int cost )
{
m_first = first ;
m_second = second ;
m_cost = cost ;
}
CEdge : : ~ CEdge ( void )
{
}
/*
- - - - - - - - - - - - - - - - - - - - - - - - -
CNode
- - - - - - - - - - - - - - - - - - - - - - - - -
*/
CNode : : CNode ( void )
{
m_numEdges = 0 ;
m_radius = 0 ;
m_ranks = NULL ;
}
CNode : : ~ CNode ( void )
{
m_edges . clear ( ) ;
if ( m_ranks )
delete [ ] m_ranks ;
}
/*
- - - - - - - - - - - - - - - - - - - - - - - - -
Create
- - - - - - - - - - - - - - - - - - - - - - - - -
*/
CNode * CNode : : Create ( vec3_t position , int flags , int radius , int ID )
{
CNode * node = new CNode ;
VectorCopy ( position , node - > m_position ) ;
node - > m_flags = flags ;
node - > m_ID = ID ;
node - > m_radius = radius ;
return node ;
}
/*
- - - - - - - - - - - - - - - - - - - - - - - - -
Create
- - - - - - - - - - - - - - - - - - - - - - - - -
*/
CNode * CNode : : Create ( void )
{
return new CNode ;
}
/*
- - - - - - - - - - - - - - - - - - - - - - - - -
AddEdge
- - - - - - - - - - - - - - - - - - - - - - - - -
*/
void CNode : : AddEdge ( int ID , int cost , int flags )
{
if ( m_numEdges )
{ //already have at least 1
//see if it exists already
edge_v : : iterator ei ;
STL_ITERATE ( ei , m_edges )
{
if ( ( * ei ) . ID = = ID )
{ //found it
( * ei ) . cost = cost ;
( * ei ) . flags = flags ;
return ;
}
}
}
edge_t edge ;
edge . ID = ID ;
edge . cost = cost ;
edge . flags = flags ;
STL_INSERT ( m_edges , edge ) ;
m_numEdges + + ;
assert ( m_numEdges < 9 ) ; //8 is the max
}
/*
- - - - - - - - - - - - - - - - - - - - - - - - -
GetEdge
- - - - - - - - - - - - - - - - - - - - - - - - -
*/
int CNode : : GetEdgeNumToNode ( int ID )
{
int count = 0 ;
edge_v : : iterator ei ;
STL_ITERATE ( ei , m_edges )
{
if ( ( * ei ) . ID = = ID )
{
return count ;
}
count + + ;
}
return - 1 ;
}
/*
- - - - - - - - - - - - - - - - - - - - - - - - -
AddRank
- - - - - - - - - - - - - - - - - - - - - - - - -
*/
void CNode : : AddRank ( int ID , int rank )
{
assert ( m_ranks ) ;
m_ranks [ ID ] = rank ;
}
/*
- - - - - - - - - - - - - - - - - - - - - - - - -
Draw
- - - - - - - - - - - - - - - - - - - - - - - - -
*/
void CNode : : Draw ( qboolean showRadius )
{
CG_DrawNode ( m_position , NODE_NORMAL ) ;
if ( showRadius )
{
CG_DrawRadius ( m_position , m_radius , NODE_NORMAL ) ;
}
}
/*
- - - - - - - - - - - - - - - - - - - - - - - - -
GetEdge
- - - - - - - - - - - - - - - - - - - - - - - - -
*/
int CNode : : GetEdge ( int edgeNum )
{
if ( edgeNum > m_numEdges )
return - 1 ;
int count = 0 ;
edge_v : : iterator ei ;
STL_ITERATE ( ei , m_edges )
{
if ( count = = edgeNum )
{
return ( * ei ) . ID ;
}
count + + ;
}
return - 1 ;
}
/*
- - - - - - - - - - - - - - - - - - - - - - - - -
GetEdgeCost
- - - - - - - - - - - - - - - - - - - - - - - - -
*/
int CNode : : GetEdgeCost ( int edgeNum )
{
if ( edgeNum > m_numEdges )
return Q3_INFINITE ; // return -1;
int count = 0 ;
edge_v : : iterator ei ;
STL_ITERATE ( ei , m_edges )
{
if ( count = = edgeNum )
{
return ( * ei ) . cost ;
}
count + + ;
}
return Q3_INFINITE ; // return -1;
}
/*
- - - - - - - - - - - - - - - - - - - - - - - - -
GetEdgeFlags
- - - - - - - - - - - - - - - - - - - - - - - - -
*/
unsigned char CNode : : GetEdgeFlags ( int edgeNum )
{
if ( edgeNum > m_numEdges )
return 0 ;
int count = 0 ;
edge_v : : iterator ei ;
STL_ITERATE ( ei , m_edges )
{
if ( count = = edgeNum )
{
return ( * ei ) . flags ;
}
count + + ;
}
return 0 ;
}
/*
- - - - - - - - - - - - - - - - - - - - - - - - -
SetEdgeFlags
- - - - - - - - - - - - - - - - - - - - - - - - -
*/
void CNode : : SetEdgeFlags ( int edgeNum , int newFlags )
{
if ( edgeNum > m_numEdges )
return ;
int count = 0 ;
edge_v : : iterator ei ;
STL_ITERATE ( ei , m_edges )
{
if ( count = = edgeNum )
{
( * ei ) . flags = newFlags ;
return ;
}
count + + ;
}
}
/*
- - - - - - - - - - - - - - - - - - - - - - - - -
InitRanks
- - - - - - - - - - - - - - - - - - - - - - - - -
*/
void CNode : : InitRanks ( int size )
{
//Clear it if it's already allocated
if ( m_ranks ! = NULL )
{
delete [ ] m_ranks ;
m_ranks = NULL ;
}
m_ranks = new int [ size ] ;
memset ( m_ranks , - 1 , sizeof ( int ) * size ) ;
}
/*
- - - - - - - - - - - - - - - - - - - - - - - - -
GetRank
- - - - - - - - - - - - - - - - - - - - - - - - -
*/
int CNode : : GetRank ( int ID )
{
assert ( m_ranks ) ;
return m_ranks [ ID ] ;
}
/*
- - - - - - - - - - - - - - - - - - - - - - - - -
Save
- - - - - - - - - - - - - - - - - - - - - - - - -
*/
int CNode : : Save ( int numNodes , fileHandle_t file )
{
int i ;
//Write out the header
unsigned long header = NODE_HEADER_ID ;
gi . FS_Write ( & header , sizeof ( header ) , file ) ;
//Write out the basic information
for ( i = 0 ; i < 3 ; i + + )
gi . FS_Write ( & m_position [ i ] , sizeof ( float ) , file ) ;
gi . FS_Write ( & m_flags , sizeof ( m_flags ) , file ) ;
gi . FS_Write ( & m_ID , sizeof ( m_ID ) , file ) ;
gi . FS_Write ( & m_radius , sizeof ( m_radius ) , file ) ;
//Write out the edge information
gi . FS_Write ( & m_numEdges , sizeof ( m_numEdges ) , file ) ;
edge_v : : iterator ei ;
STL_ITERATE ( ei , m_edges )
{
gi . FS_Write ( & ( * ei ) , sizeof ( edge_t ) , file ) ;
}
//Write out the node ranks
gi . FS_Write ( & numNodes , sizeof ( numNodes ) , file ) ;
for ( i = 0 ; i < numNodes ; i + + )
{
gi . FS_Write ( & m_ranks [ i ] , sizeof ( int ) , file ) ;
}
return true ;
}
/*
- - - - - - - - - - - - - - - - - - - - - - - - -
Load
- - - - - - - - - - - - - - - - - - - - - - - - -
*/
int CNode : : Load ( int numNodes , fileHandle_t file )
{
unsigned long header ;
int i ;
gi . FS_Read ( & header , sizeof ( header ) , file ) ;
//Validate the header
if ( header ! = NODE_HEADER_ID )
return false ;
//Get the basic information
for ( i = 0 ; i < 3 ; i + + )
gi . FS_Read ( & m_position [ i ] , sizeof ( float ) , file ) ;
gi . FS_Read ( & m_flags , sizeof ( m_flags ) , file ) ;
gi . FS_Read ( & m_ID , sizeof ( m_ID ) , file ) ;
gi . FS_Read ( & m_radius , sizeof ( m_radius ) , file ) ;
//Get the edge information
gi . FS_Read ( & m_numEdges , sizeof ( m_numEdges ) , file ) ;
for ( i = 0 ; i < m_numEdges ; i + + )
{
edge_t edge ;
gi . FS_Read ( & edge , sizeof ( edge_t ) , file ) ;
STL_INSERT ( m_edges , edge ) ;
}
//Read the node ranks
int numRanks ;
gi . FS_Read ( & numRanks , sizeof ( numRanks ) , file ) ;
//Allocate the memory
InitRanks ( numRanks ) ;
for ( i = 0 ; i < numRanks ; i + + )
{
gi . FS_Read ( & m_ranks [ i ] , sizeof ( int ) , file ) ;
}
return true ;
}
/*
- - - - - - - - - - - - - - - - - - - - - - - - -
CNavigator
- - - - - - - - - - - - - - - - - - - - - - - - -
*/
CNavigator : : CNavigator ( void )
{
}
CNavigator : : ~ CNavigator ( void )
{
}
/*
- - - - - - - - - - - - - - - - - - - - - - - - -
FlagAllNodes
- - - - - - - - - - - - - - - - - - - - - - - - -
*/
void CNavigator : : FlagAllNodes ( int newFlag )
{
node_v : : iterator ni ;
STL_ITERATE ( ni , m_nodes )
{
( * ni ) - > AddFlag ( newFlag ) ;
}
}
/*
- - - - - - - - - - - - - - - - - - - - - - - - -
GetChar
- - - - - - - - - - - - - - - - - - - - - - - - -
*/
char CNavigator : : GetChar ( fileHandle_t file )
{
char value ;
gi . FS_Read ( & value , sizeof ( value ) , file ) ;
return value ;
}
/*
- - - - - - - - - - - - - - - - - - - - - - - - -
GetInt
- - - - - - - - - - - - - - - - - - - - - - - - -
*/
int CNavigator : : GetInt ( fileHandle_t file )
{
int value ;
gi . FS_Read ( & value , sizeof ( value ) , file ) ;
return value ;
}
/*
- - - - - - - - - - - - - - - - - - - - - - - - -
GetFloat
- - - - - - - - - - - - - - - - - - - - - - - - -
*/
float CNavigator : : GetFloat ( fileHandle_t file )
{
float value ;
gi . FS_Read ( & value , sizeof ( value ) , file ) ;
return value ;
}
/*
- - - - - - - - - - - - - - - - - - - - - - - - -
GetLong
- - - - - - - - - - - - - - - - - - - - - - - - -
*/
long CNavigator : : GetLong ( fileHandle_t file )
{
long value ;
gi . FS_Read ( & value , sizeof ( value ) , file ) ;
return value ;
}
/*
- - - - - - - - - - - - - - - - - - - - - - - - -
Init
- - - - - - - - - - - - - - - - - - - - - - - - -
*/
void CNavigator : : Init ( void )
{
Free ( ) ;
}
/*
- - - - - - - - - - - - - - - - - - - - - - - - -
Free
- - - - - - - - - - - - - - - - - - - - - - - - -
*/
void CNavigator : : Free ( void )
{
node_v : : iterator ni ;
STL_ITERATE ( ni , m_nodes )
{
delete ( * ni ) ;
}
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m_nodes . clear ( ) ;
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}
/*
- - - - - - - - - - - - - - - - - - - - - - - - -
Load
- - - - - - - - - - - - - - - - - - - - - - - - -
*/
bool CNavigator : : Load ( const char * filename , int checksum )
{
fileHandle_t file ;
//Attempt to load the file
gi . FS_FOpenFile ( va ( " maps/%s.nav " , filename ) , & file , FS_READ ) ;
//See if we succeeded
if ( file = = NULL_FILE )
return false ;
//Check the header id
long navID = GetLong ( file ) ;
if ( navID ! = NAV_HEADER_ID )
{
gi . FS_FCloseFile ( file ) ;
return false ;
}
//Check the checksum to see if this file is out of date
int check = GetInt ( file ) ;
if ( check ! = checksum )
{
gi . FS_FCloseFile ( file ) ;
return false ;
}
int numNodes = GetInt ( file ) ;
for ( int i = 0 ; i < numNodes ; i + + )
{
CNode * node = CNode : : Create ( ) ;
if ( node - > Load ( numNodes , file ) = = false )
{
gi . FS_FCloseFile ( file ) ;
return false ;
}
STL_INSERT ( m_nodes , node ) ;
}
//read in the failed edges
gi . FS_Read ( & failedEdges , sizeof ( failedEdges ) , file ) ;
for ( int j = 0 ; j < MAX_FAILED_EDGES ; j + + )
{
m_edgeLookupMap . insert ( std : : pair < int , int > ( failedEdges [ j ] . startID , j ) ) ;
}
gi . FS_FCloseFile ( file ) ;
return true ;
}
/*
- - - - - - - - - - - - - - - - - - - - - - - - -
Save
- - - - - - - - - - - - - - - - - - - - - - - - -
*/
bool CNavigator : : Save ( const char * filename , int checksum )
{
fileHandle_t file ;
//Attempt to load the file
gi . FS_FOpenFile ( va ( " maps/%s.nav " , filename ) , & file , FS_WRITE ) ;
if ( file = = NULL_FILE )
return false ;
//Write out the header id
unsigned long id = NAV_HEADER_ID ;
gi . FS_Write ( & id , sizeof ( id ) , file ) ;
//Write out the checksum
gi . FS_Write ( & checksum , sizeof ( checksum ) , file ) ;
int numNodes = m_nodes . size ( ) ;
//Write out the number of nodes to follow
gi . FS_Write ( & numNodes , sizeof ( numNodes ) , file ) ;
//Write out all the nodes
node_v : : iterator ni ;
STL_ITERATE ( ni , m_nodes )
{
( * ni ) - > Save ( numNodes , file ) ;
}
//write out failed edges
gi . FS_Write ( & failedEdges , sizeof ( failedEdges ) , file ) ;
gi . FS_FCloseFile ( file ) ;
return true ;
}
/*
- - - - - - - - - - - - - - - - - - - - - - - - -
AddRawPoint
- - - - - - - - - - - - - - - - - - - - - - - - -
*/
int CNavigator : : AddRawPoint ( vec3_t point , int flags , int radius )
{
CNode * node = CNode : : Create ( point , flags , radius , m_nodes . size ( ) ) ;
if ( node = = NULL )
{
Com_Error ( ERR_DROP , " Error adding node! \n " ) ;
return - 1 ;
}
//TODO: Validate the position
//TODO: Correct stuck waypoints
STL_INSERT ( m_nodes , node ) ;
return node - > GetID ( ) ;
}
/*
- - - - - - - - - - - - - - - - - - - - - - - - -
GetEdgeCost
- - - - - - - - - - - - - - - - - - - - - - - - -
*/
int CNavigator : : GetEdgeCost ( CNode * first , CNode * second )
{
trace_t trace ;
vec3_t start , end ;
vec3_t mins , maxs ;
//Setup the player size
VectorSet ( mins , - 8 , - 8 , - 8 ) ;
VectorSet ( maxs , 8 , 8 , 8 ) ;
//Setup the points
first - > GetPosition ( start ) ;
second - > GetPosition ( end ) ;
gi . trace ( & trace , start , mins , maxs , end , ENTITYNUM_NONE , MASK_SOLID , G2_NOCOLLIDE , 0 ) ;
if ( trace . fraction < 1.0f | | trace . allsolid | | trace . startsolid )
return Q3_INFINITE ; // return -1;
//Connection successful, return the cost
return Distance ( start , end ) ;
}
void CNavigator : : SetEdgeCost ( int ID1 , int ID2 , int cost )
{
if ( ( ID1 = = - 1 ) | | ( ID2 = = - 1 ) )
{ //not valid nodes, must have come from the ClearAllFailedEdges initization-type calls
return ;
}
CNode * node1 = m_nodes [ ID1 ] ;
CNode * node2 = m_nodes [ ID2 ] ;
if ( cost = = - 1 )
{ //they want us to calc it
//FIXME: can we just remember this instead of recalcing every time?
vec3_t pos1 , pos2 ;
node1 - > GetPosition ( pos1 ) ;
node2 - > GetPosition ( pos2 ) ;
cost = Distance ( pos1 , pos2 ) ;
}
//set it
node1 - > AddEdge ( ID2 , cost ) ;
node2 - > AddEdge ( ID1 , cost ) ;
}
/*
- - - - - - - - - - - - - - - - - - - - - - - - -
AddNodeEdges
- - - - - - - - - - - - - - - - - - - - - - - - -
*/
void CNavigator : : AddNodeEdges ( CNode * node , int addDist , edge_l & edgeList , bool * checkedNodes )
{
//Add all edge
for ( int i = 0 ; i < node - > GetNumEdges ( ) ; i + + )
{
//Make sure we don't add an old edge twice
if ( checkedNodes [ node - > GetEdge ( i ) ] = = true )
continue ;
//Get the node
CNode * nextNode = m_nodes [ node - > GetEdge ( i ) ] ;
//This node has now been checked
checkedNodes [ nextNode - > GetID ( ) ] = true ;
//Add it to the list
STL_INSERT ( edgeList , CEdge ( nextNode - > GetID ( ) , node - > GetID ( ) , addDist + ( node - > GetEdgeCost ( i ) ) ) ) ;
}
}
/*
- - - - - - - - - - - - - - - - - - - - - - - - -
CalculatePath
- - - - - - - - - - - - - - - - - - - - - - - - -
*/
void CNavigator : : CalculatePath ( CNode * node )
{
int curRank = 0 ;
int i ;
CPriorityQueue * pathList = new CPriorityQueue ( ) ;
unsigned char * checked ;
//Init the completion table
checked = new unsigned char [ m_nodes . size ( ) ] ;
memset ( checked , 0 , m_nodes . size ( ) ) ;
//Mark this node as checked
checked [ node - > GetID ( ) ] = true ;
node - > AddRank ( node - > GetID ( ) , curRank + + ) ;
//Add all initial nodes
for ( i = 0 ; i < node - > GetNumEdges ( ) ; i + + )
{
CNode * nextNode = m_nodes [ node - > GetEdge ( i ) ] ;
assert ( nextNode ) ;
checked [ nextNode - > GetID ( ) ] = true ;
pathList - > Push ( new CEdge ( nextNode - > GetID ( ) , nextNode - > GetID ( ) , node - > GetEdgeCost ( i ) ) ) ;
}
CEdge * test ;
//Now flood fill all the others
while ( ! pathList - > Empty ( ) )
{
test = pathList - > Pop ( ) ;
CNode * testNode = m_nodes [ ( * test ) . m_first ] ;
assert ( testNode ) ;
node - > AddRank ( testNode - > GetID ( ) , curRank + + ) ;
//Add in all the new edges
for ( i = 0 ; i < testNode - > GetNumEdges ( ) ; i + + )
{
CNode * addNode = m_nodes [ testNode - > GetEdge ( i ) ] ;
assert ( addNode ) ;
if ( checked [ addNode - > GetID ( ) ] )
continue ;
int newDist = ( * test ) . m_cost + testNode - > GetEdgeCost ( i ) ;
pathList - > Push ( new CEdge ( addNode - > GetID ( ) , ( * test ) . m_second , newDist ) ) ;
checked [ addNode - > GetID ( ) ] = true ;
}
delete test ;
}
node - > RemoveFlag ( NF_RECALC ) ;
delete pathList ;
delete [ ] checked ;
}
/*
- - - - - - - - - - - - - - - - - - - - - - - - -
CalculatePaths
- - - - - - - - - - - - - - - - - - - - - - - - -
*/
extern void CP_FindCombatPointWaypoints ( void ) ;
void CNavigator : : CalculatePaths ( bool recalc )
{
# ifndef FINAL_BUILD
int startTime = gi . Milliseconds ( ) ;
# endif
# if _HARD_CONNECT
# else
# endif
int i ;
for ( i = 0 ; i < ( int ) m_nodes . size ( ) ; i + + )
{
//Allocate the needed memory
m_nodes [ i ] - > InitRanks ( m_nodes . size ( ) ) ;
}
for ( i = 0 ; i < ( int ) m_nodes . size ( ) ; i + + )
{
CalculatePath ( m_nodes [ i ] ) ;
}
# ifndef FINAL_BUILD
if ( pathsCalculated )
{
gi . Printf ( S_COLOR_CYAN " %s recalced paths in %d ms \n " , ( NPC ! = NULL ? NPC - > targetname : " NULL " ) , gi . Milliseconds ( ) - startTime ) ;
}
# endif
if ( ! recalc ) //Mike says doesn't need to happen on recalc
{
CP_FindCombatPointWaypoints ( ) ;
}
pathsCalculated = qtrue ;
}
/*
- - - - - - - - - - - - - - - - - - - - - - - - -
ShowNodes
- - - - - - - - - - - - - - - - - - - - - - - - -
*/
void CNavigator : : ShowNodes ( void )
{
node_v : : iterator ni ;
vec3_t position ;
qboolean showRadius ;
float dist ,
radius ;
STL_ITERATE ( ni , m_nodes )
{
( * ni ) - > GetPosition ( position ) ;
showRadius = qfalse ;
if ( NAVDEBUG_showRadius )
{
dist = DistanceSquared ( g_entities [ 0 ] . currentOrigin , position ) ;
radius = ( * ni ) - > GetRadius ( ) ;
// if player within node radius or 256, draw radius (sometimes the radius is really small, so we check for 256 to catch everything)
if ( ( dist < = radius * radius ) | | dist < = 65536 )
{
showRadius = qtrue ;
}
}
else
{
dist = DistanceSquared ( g_entities [ 0 ] . currentOrigin , position ) ;
}
if ( dist < 1048576 )
{
if ( gi . inPVS ( g_entities [ 0 ] . currentOrigin , position ) )
{
( * ni ) - > Draw ( showRadius ) ;
}
}
}
}
/*
- - - - - - - - - - - - - - - - - - - - - - - - -
ShowEdges
- - - - - - - - - - - - - - - - - - - - - - - - -
*/
typedef std : : map < int , bool > drawMap_m ;
void CNavigator : : ShowEdges ( void )
{
node_v : : iterator ni ;
vec3_t start , end ;
drawMap_m * drawMap ;
drawMap = new drawMap_m [ m_nodes . size ( ) ] ;
STL_ITERATE ( ni , m_nodes )
{
( * ni ) - > GetPosition ( start ) ;
if ( DistanceSquared ( g_entities [ 0 ] . currentOrigin , start ) > = 1048576 )
{
continue ;
}
if ( ! gi . inPVSIgnorePortals ( g_entities [ 0 ] . currentOrigin , start ) )
{
continue ;
}
//Attempt to draw each connection
for ( int i = 0 ; i < ( * ni ) - > GetNumEdges ( ) ; i + + )
{
int id = ( * ni ) - > GetEdge ( i ) ;
if ( id = = - 1 )
continue ;
//Already drawn?
if ( drawMap [ ( * ni ) - > GetID ( ) ] . find ( id ) ! = drawMap [ ( * ni ) - > GetID ( ) ] . end ( ) )
continue ;
unsigned char flags = ( * ni ) - > GetEdgeFlags ( i ) ;
CNode * node = m_nodes [ id ] ;
node - > GetPosition ( end ) ;
//Set this as drawn
drawMap [ id ] [ ( * ni ) - > GetID ( ) ] = true ;
if ( DistanceSquared ( g_entities [ 0 ] . currentOrigin , end ) > = 1048576 )
{
continue ;
}
if ( ! gi . inPVSIgnorePortals ( g_entities [ 0 ] . currentOrigin , end ) )
continue ;
if ( EdgeFailed ( id , ( * ni ) - > GetID ( ) ) ! = - 1 ) //flags & EFLAG_FAILED )
CG_DrawEdge ( start , end , EDGE_FAILED ) ;
else if ( flags & EFLAG_BLOCKED )
CG_DrawEdge ( start , end , EDGE_BLOCKED ) ;
else
CG_DrawEdge ( start , end , EDGE_NORMAL ) ;
}
}
delete [ ] drawMap ;
}
int CNavigator : : GetNodeRadius ( int nodeID )
{
if ( m_nodes . size ( ) = = 0 )
return 0 ;
return m_nodes [ nodeID ] - > GetRadius ( ) ;
}
void CNavigator : : CheckBlockedEdges ( void )
{
CNode * start , * end ;
vec3_t p1 , p2 ;
int flags , first , second ;
trace_t trace ;
qboolean failed ;
int edgeNum ;
node_v : : iterator ni ;
//Go through all edges and test the ones that were blocked
STL_ITERATE ( ni , m_nodes )
{
//Attempt to draw each connection
for ( edgeNum = 0 ; edgeNum < ( * ni ) - > GetNumEdges ( ) ; edgeNum + + )
{
flags = ( * ni ) - > GetEdgeFlags ( edgeNum ) ;
if ( ( flags & EFLAG_BLOCKED ) )
{
first = ( * ni ) - > GetID ( ) ;
second = ( * ni ) - > GetEdge ( edgeNum ) ;
start = m_nodes [ first ] ;
end = m_nodes [ second ] ;
failed = qfalse ;
start - > GetPosition ( p1 ) ;
end - > GetPosition ( p2 ) ;
//FIXME: can't we just store the trace.entityNum from the HardConnect trace? So we don't have to do another trace here...
gi . trace ( & trace , p1 , wpMins , wpMaxs , p2 , ENTITYNUM_NONE , MASK_SOLID | CONTENTS_MONSTERCLIP | CONTENTS_BOTCLIP , G2_NOCOLLIDE , 0 ) ;
if ( trace . entityNum < ENTITYNUM_WORLD & & ( trace . fraction < 1.0f | | trace . startsolid = = qtrue | | trace . allsolid = = qtrue ) )
{ //could be assumed, since failed before
if ( G_EntIsDoor ( trace . entityNum ) )
{ //door
if ( ! G_EntIsUnlockedDoor ( trace . entityNum ) )
{ //locked door
failed = qtrue ;
}
}
else
{
if ( G_EntIsBreakable ( trace . entityNum ) )
{ //do same for breakable brushes/models/glass?
failed = qtrue ;
}
else if ( G_EntIsRemovableUsable ( trace . entityNum ) )
{
failed = qtrue ;
}
else if ( trace . allsolid | | trace . startsolid )
{ //FIXME: the entitynum would be none here, so how do we know if this is stuck inside an ent or the world?
}
else
{ //FIXME: what about func_plats and scripted movers?
}
}
}
if ( failed )
{
//could add the EFLAG_FAILED to the two edges, but we stopped doing that since it was pointless
AddFailedEdge ( ENTITYNUM_NONE , first , second ) ;
}
}
}
}
}
# if _HARD_CONNECT
/*
- - - - - - - - - - - - - - - - - - - - - - - - -
HardConnect
- - - - - - - - - - - - - - - - - - - - - - - - -
*/
void CNavigator : : HardConnect ( int first , int second )
{
CNode * start , * end ;
start = m_nodes [ first ] ;
end = m_nodes [ second ] ;
vec3_t p1 , p2 ;
start - > GetPosition ( p1 ) ;
end - > GetPosition ( p2 ) ;
trace_t trace ;
int flags = EFLAG_NONE ;
gi . trace ( & trace , p1 , wpMins , wpMaxs , p2 , ENTITYNUM_NONE , MASK_SOLID | CONTENTS_BOTCLIP | CONTENTS_MONSTERCLIP , G2_NOCOLLIDE , 0 ) ;
int cost = Distance ( p1 , p2 ) ;
if ( trace . fraction ! = 1.0f | | trace . startsolid = = qtrue | | trace . allsolid = = qtrue )
{
flags | = EFLAG_BLOCKED ;
}
start - > AddEdge ( second , cost , flags ) ;
end - > AddEdge ( first , cost , flags ) ;
}
# endif
/*
- - - - - - - - - - - - - - - - - - - - - - - - -
TestNodePath
- - - - - - - - - - - - - - - - - - - - - - - - -
*/
int CNavigator : : TestNodePath ( gentity_t * ent , int okToHitEntNum , vec3_t position , qboolean includeEnts )
{
int clipmask = ent - > clipmask ;
if ( ! includeEnts )
{
clipmask & = ~ CONTENTS_BODY ;
}
//Check the path
if ( NAV_ClearPathToPoint ( ent , ent - > mins , ent - > maxs , position , clipmask , okToHitEntNum ) = = false )
return false ;
return true ;
}
/*
- - - - - - - - - - - - - - - - - - - - - - - - -
TestNodeLOS
- - - - - - - - - - - - - - - - - - - - - - - - -
*/
int CNavigator : : TestNodeLOS ( gentity_t * ent , vec3_t position )
{
return NPC_ClearLOS ( ent , position ) ;
}
/*
- - - - - - - - - - - - - - - - - - - - - - - - -
TestBestFirst
- - - - - - - - - - - - - - - - - - - - - - - - -
*/
int CNavigator : : TestBestFirst ( gentity_t * ent , int lastID , int flags )
{
//Must be a valid one to begin with
if ( lastID = = NODE_NONE )
return NODE_NONE ;
if ( lastID > = ( int ) m_nodes . size ( ) )
return NODE_NONE ;
//Get the info
vec3_t nodePos ;
CNode * node = m_nodes [ lastID ] ;
CNode * testNode ;
int numEdges = node - > GetNumEdges ( ) ;
float dist ;
node - > GetPosition ( nodePos ) ;
//Setup our last node as our root, and search for a closer one according to its edges
int bestNode = ( TestNodePath ( ent , ENTITYNUM_NONE , nodePos , qtrue ) ) ? lastID : NODE_NONE ;
float bestDist = ( bestNode = = NODE_NONE ) ? Q3_INFINITE : DistanceSquared ( ent - > currentOrigin , nodePos ) ;
//Test all these edges first
for ( int i = 0 ; i < numEdges ; i + + )
{
//Get this node and its distance
testNode = m_nodes [ node - > GetEdge ( i ) ] ;
if ( NodeFailed ( ent , testNode - > GetID ( ) ) )
{
continue ;
}
testNode - > GetPosition ( nodePos ) ;
dist = DistanceSquared ( ent - > currentOrigin , nodePos ) ;
//Test against current best
if ( dist < bestDist )
{
//See if this node is valid
if ( CheckedNode ( testNode - > GetID ( ) , ent - > s . number ) = = CHECKED_PASSED | | TestNodePath ( ent , ENTITYNUM_NONE , nodePos , qtrue ) )
{
bestDist = dist ;
bestNode = testNode - > GetID ( ) ;
SetCheckedNode ( testNode - > GetID ( ) , ent - > s . number , CHECKED_PASSED ) ;
}
else
{
SetCheckedNode ( testNode - > GetID ( ) , ent - > s . number , CHECKED_FAILED ) ;
}
}
}
return bestNode ;
}
/*
- - - - - - - - - - - - - - - - - - - - - - - - -
CollectNearestNodes
- - - - - - - - - - - - - - - - - - - - - - - - -
*/
# define NODE_COLLECT_MAX 16 //Maximum # of nodes collected at any time
# define NODE_COLLECT_RADIUS 512 //Default radius to search for nodes in
# define NODE_COLLECT_RADIUS_SQR ( NODE_COLLECT_RADIUS * NODE_COLLECT_RADIUS )
int CNavigator : : CollectNearestNodes ( vec3_t origin , int radius , int maxCollect , nodeChain_l & nodeChain )
{
node_v : : iterator ni ;
float dist ;
vec3_t position ;
int collected = 0 ;
bool added = false ;
//Get a distance rating for each node in the system
STL_ITERATE ( ni , m_nodes )
{
//If we've got our quota, then stop looking
//Get the distance to the node
( * ni ) - > GetPosition ( position ) ;
dist = DistanceSquared ( position , origin ) ;
//Must be within our radius range
if ( dist > ( float ) ( radius * radius ) )
continue ;
nodeList_t nChain ;
nodeChain_l : : iterator nci ;
//Always add the first node
if ( nodeChain . size ( ) = = 0 )
{
nChain . nodeID = ( * ni ) - > GetID ( ) ;
nChain . distance = dist ;
nodeChain . insert ( nodeChain . begin ( ) , nChain ) ;
continue ;
}
added = false ;
//Compare it to what we already have
STL_ITERATE ( nci , nodeChain )
{
//If we're less, than this entry, then insert before it
if ( dist < ( * nci ) . distance )
{
nChain . nodeID = ( * ni ) - > GetID ( ) ;
nChain . distance = dist ;
nodeChain . insert ( nci , nChain ) ;
collected = nodeChain . size ( ) ;
added = true ;
//If we've hit our collection limit, throw off the oldest one
if ( ( int ) nodeChain . size ( ) > maxCollect )
{
nodeChain . pop_back ( ) ;
}
break ;
}
}
//Otherwise, always pad out the collection if possible so we don't miss anything
if ( ( added = = false ) & & ( ( int ) nodeChain . size ( ) < maxCollect ) )
{
nChain . nodeID = ( * ni ) - > GetID ( ) ;
nChain . distance = dist ;
nodeChain . insert ( nodeChain . end ( ) , nChain ) ;
}
}
return collected ;
}
int CNavigator : : GetBestPathBetweenEnts ( gentity_t * ent , gentity_t * goal , int flags )
{
//Must have nodes
if ( m_nodes . size ( ) = = 0 )
return NODE_NONE ;
# define MAX_Z_DELTA 18
nodeChain_l nodeChain ;
nodeChain_l : : iterator nci ;
nodeChain_l nodeChain2 ;
nodeChain_l : : iterator nci2 ;
//Collect all nodes within a certain radius
CollectNearestNodes ( ent - > currentOrigin , NODE_COLLECT_RADIUS , NODE_COLLECT_MAX , nodeChain ) ;
CollectNearestNodes ( goal - > currentOrigin , NODE_COLLECT_RADIUS , NODE_COLLECT_MAX , nodeChain2 ) ;
vec3_t position ;
vec3_t position2 ;
int radius ;
int cost , pathCost , bestCost = Q3_INFINITE ;
CNode * node , * node2 ;
int nodeNum , nodeNum2 ;
int nextNode = NODE_NONE , bestNode = NODE_NONE ;
int nodeFlags = 0 ;
// bool recalc = false;
ent - > waypoint = NODE_NONE ;
goal - > waypoint = NODE_NONE ;
//Look through all nodes
STL_ITERATE ( nci , nodeChain )
{
node = m_nodes [ ( * nci ) . nodeID ] ;
nodeNum = ( * nci ) . nodeID ;
node - > GetPosition ( position ) ;
if ( CheckedNode ( nodeNum , ent - > s . number ) = = CHECKED_FAILED )
{ //already checked this node against ent and it failed
continue ;
}
if ( CheckedNode ( nodeNum , ent - > s . number ) = = CHECKED_PASSED )
{ //already checked this node against ent and it passed
}
else
{ //haven't checked this node against ent yet
if ( NodeFailed ( ent , nodeNum ) )
{
SetCheckedNode ( nodeNum , ent - > s . number , CHECKED_FAILED ) ;
continue ;
}
//okay, since we only have to do this once, let's check to see if this node is even usable (could help us short-circuit a whole loop of the dest nodes)
radius = node - > GetRadius ( ) ;
//If we're not within the known clear radius of this node OR out of Z height range...
if ( ( signed ) ( * nci ) . distance > = ( radius * radius ) | | ( fabs ( position [ 2 ] - ent - > currentOrigin [ 2 ] ) > = MAX_Z_DELTA ) )
{
//We're not *within* this node, so check clear path, etc.
//FIXME: any way to call G_FindClosestPointOnLineSegment and see if I can at least get to the waypoint's path
if ( flags & NF_CLEAR_PATH ) //|| flags & NF_CLEAR_LOS )
{ //need a clear path or LOS
if ( ! gi . inPVS ( ent - > currentOrigin , position ) )
{ //not even potentially clear
SetCheckedNode ( nodeNum , ent - > s . number , CHECKED_FAILED ) ;
continue ;
}
}
//Do we need a clear path?
if ( flags & NF_CLEAR_PATH )
{
if ( TestNodePath ( ent , goal - > s . number , position , qtrue ) = = false )
{
SetCheckedNode ( nodeNum , ent - > s . number , CHECKED_FAILED ) ;
continue ;
}
}
} //otherwise, inside the node so it must be clear (?)
SetCheckedNode ( nodeNum , ent - > s . number , CHECKED_PASSED ) ;
}
if ( d_altRoutes - > integer )
{
//calc the paths for this node if they're out of date
nodeFlags = node - > GetFlags ( ) ;
if ( ( nodeFlags & NF_RECALC ) )
{
//gi.Printf( S_COLOR_CYAN"%d recalcing paths from node %d\n", level.time, nodeNum );
CalculatePath ( node ) ;
}
}
STL_ITERATE ( nci2 , nodeChain2 )
{
node2 = m_nodes [ ( * nci2 ) . nodeID ] ;
nodeNum2 = ( * nci2 ) . nodeID ;
if ( d_altRoutes - > integer )
{
//calc the paths for this node if they're out of date
nodeFlags = node2 - > GetFlags ( ) ;
if ( ( nodeFlags & NF_RECALC ) )
{
//gi.Printf( S_COLOR_CYAN"%d recalcing paths from node %d\n", level.time, nodeNum2 );
CalculatePath ( node2 ) ;
}
}
node2 - > GetPosition ( position2 ) ;
//Okay, first get the entire path cost, including distance to first node from ents' positions
cost = floor ( Distance ( ent - > currentOrigin , position ) + Distance ( goal - > currentOrigin , position2 ) ) ;
if ( d_altRoutes - > integer )
{
nextNode = GetBestNodeAltRoute ( ( * nci ) . nodeID , ( * nci2 ) . nodeID , & pathCost , bestNode ) ;
cost + = pathCost ;
}
else
{
cost + = GetPathCost ( ( * nci ) . nodeID , ( * nci2 ) . nodeID ) ;
}
if ( cost > = bestCost )
{
continue ;
}
//okay, this is the shortest path we've found yet, check clear path, etc.
if ( CheckedNode ( nodeNum2 , goal - > s . number ) = = CHECKED_FAILED )
{ //already checked this node against goal and it failed
continue ;
}
if ( CheckedNode ( nodeNum2 , goal - > s . number ) = = CHECKED_PASSED )
{ //already checked this node against goal and it passed
}
else
{ //haven't checked this node against goal yet
if ( NodeFailed ( goal , nodeNum2 ) )
{
SetCheckedNode ( nodeNum2 , goal - > s . number , CHECKED_FAILED ) ;
continue ;
}
radius = node2 - > GetRadius ( ) ;
//If we're not within the known clear radius of this node OR out of Z height range...
if ( ( signed ) ( * nci2 ) . distance > = ( radius * radius ) | | ( fabs ( position2 [ 2 ] - goal - > currentOrigin [ 2 ] ) > = MAX_Z_DELTA ) )
{
//We're not *within* this node, so check clear path, etc.
if ( flags & NF_CLEAR_PATH ) //|| flags & NF_CLEAR_LOS )
{ //need a clear path or LOS
if ( ! gi . inPVS ( goal - > currentOrigin , position2 ) )
{ //not even potentially clear
SetCheckedNode ( nodeNum2 , goal - > s . number , CHECKED_FAILED ) ;
continue ;
}
}
//Do we need a clear path?
if ( flags & NF_CLEAR_PATH )
{
if ( TestNodePath ( goal , ent - > s . number , position2 , qfalse ) = = false ) //qtrue?
{
SetCheckedNode ( nodeNum2 , goal - > s . number , CHECKED_FAILED ) ;
continue ;
}
}
} //otherwise, inside the node so it must be clear (?)
SetCheckedNode ( nodeNum2 , goal - > s . number , CHECKED_PASSED ) ;
}
bestCost = cost ;
bestNode = nextNode ;
ent - > waypoint = ( * nci ) . nodeID ;
goal - > waypoint = ( * nci2 ) . nodeID ;
}
}
if ( ! d_altRoutes - > integer )
{ //bestNode would not have been set by GetBestNodeAltRoute above, so get it here
if ( ent - > waypoint ! = NODE_NONE & & goal - > waypoint ! = NODE_NONE )
{ //have 2 valid waypoints which means a valid path
bestNode = GetBestNodeAltRoute ( ent - > waypoint , goal - > waypoint , & bestCost , NODE_NONE ) ;
}
}
return bestNode ;
}
/*
- - - - - - - - - - - - - - - - - - - - - - - - -
GetNearestWaypoint
- - - - - - - - - - - - - - - - - - - - - - - - -
*/
int CNavigator : : GetNearestNode ( gentity_t * ent , int lastID , int flags , int targetID )
{
int bestNode = NODE_NONE ;
//Must have nodes
if ( m_nodes . size ( ) = = 0 )
return NODE_NONE ;
if ( targetID = = NODE_NONE )
{
//Try and find an early match using our last node
bestNode = TestBestFirst ( ent , lastID , flags ) ;
if ( bestNode ! = NODE_NONE )
return bestNode ;
} //else can't rely on testing last, we want best to targetID
/////////////////////////////////////////////////
# define MAX_Z_DELTA 18
/////////////////////////////////////////////////
nodeChain_l nodeChain ;
nodeChain_l : : iterator nci ;
//Collect all nodes within a certain radius
CollectNearestNodes ( ent - > currentOrigin , NODE_COLLECT_RADIUS , NODE_COLLECT_MAX , nodeChain ) ;
vec3_t position ;
int radius ;
int dist , bestDist = Q3_INFINITE ;
CNode * node ;
//Look through all nodes
STL_ITERATE ( nci , nodeChain )
{
node = m_nodes [ ( * nci ) . nodeID ] ;
node - > GetPosition ( position ) ;
radius = node - > GetRadius ( ) ;
if ( NodeFailed ( ent , ( * nci ) . nodeID ) )
{
continue ;
}
//Are we within the known clear radius of this node?
if ( ( signed ) ( * nci ) . distance < ( radius * radius ) )
{
//Do a z-difference sanity check
if ( fabs ( position [ 2 ] - ent - > currentOrigin [ 2 ] ) < MAX_Z_DELTA )
{
//Found one
return ( * nci ) . nodeID ;
}
}
//We're not *within* this node, so...
if ( CheckedNode ( ( * nci ) . nodeID , ent - > s . number ) = = CHECKED_FAILED )
{
continue ;
}
else if ( CheckedNode ( ( * nci ) . nodeID , ent - > s . number ) = = CHECKED_FAILED )
{
continue ;
}
else
{
//Do we need a clear path?
if ( flags & NF_CLEAR_PATH )
{
if ( TestNodePath ( ent , ENTITYNUM_NONE , position , qfalse ) = = false ) //qtrue?
{
SetCheckedNode ( ( * nci ) . nodeID , ent - > s . number , CHECKED_FAILED ) ;
continue ;
}
}
//Do we need a clear line of sight?
/*
if ( flags & NF_CLEAR_LOS )
{
if ( TestNodeLOS ( ent , position ) = = false )
{
nodeChecked [ ( * nci ) . nodeID ] [ ent - > s . number ] = CHECKED_FAILED ;
continue ;
}
}
*/
SetCheckedNode ( ( * nci ) . nodeID , ent - > s . number , CHECKED_PASSED ) ;
}
if ( targetID ! = WAYPOINT_NONE )
{ //we want to find the one with the shortest route here
dist = GetPathCost ( ( * nci ) . nodeID , targetID ) ;
if ( dist < bestDist )
{
bestDist = dist ;
bestNode = ( * nci ) . nodeID ;
}
}
else
{ //first one we find is fine
bestNode = ( * nci ) . nodeID ;
break ;
}
}
//Found one, we're done
return bestNode ;
}
/*
- - - - - - - - - - - - - - - - - - - - - - - - -
ShowPath
- - - - - - - - - - - - - - - - - - - - - - - - -
*/
void CNavigator : : ShowPath ( int start , int end )
{
//Validate the start position
if ( ( start < 0 ) | | ( start > = ( int ) m_nodes . size ( ) ) )
return ;
//Validate the end position
if ( ( end < 0 ) | | ( end > = ( int ) m_nodes . size ( ) ) )
return ;
CNode * startNode = m_nodes [ start ] ;
CNode * endNode = m_nodes [ end ] ;
CNode * moveNode = startNode ;
CNode * testNode = NULL ;
int bestNode ;
vec3_t startPos , endPos ;
int runAway = 0 ;
//Draw out our path
while ( moveNode ! = endNode )
{
bestNode = GetBestNode ( moveNode - > GetID ( ) , end ) ;
//Some nodes may be fragmented
if ( bestNode = = - 1 )
{
Com_Printf ( " No connection possible between node %d and %d \n " , start , end ) ;
return ;
}
//This is our next node on the path
testNode = m_nodes [ bestNode ] ;
//Get their origins
moveNode - > GetPosition ( startPos ) ;
testNode - > GetPosition ( endPos ) ;
//Draw the edge
CG_DrawEdge ( startPos , endPos , EDGE_PATH ) ;
//Take a new best node
moveNode = testNode ;
if ( runAway + + > 64 )
{
Com_Printf ( " Potential Run-away path! \n " ) ;
return ;
}
}
}
static std : : map < int , byte > CheckedNodes ;
void CNavigator : : ClearCheckedNodes ( void )
{
CheckedNodes . clear ( ) ;
}
byte CNavigator : : CheckedNode ( int wayPoint , int ent )
{
assert ( wayPoint > = 0 & & wayPoint < MAX_STORED_WAYPOINTS ) ;
assert ( ent > = 0 & & ent < MAX_GENTITIES ) ;
std : : map < int , byte > : : iterator f = CheckedNodes . find ( wayPoint * MAX_GENTITIES + ent ) ;
if ( f ! = CheckedNodes . end ( ) )
{
return ( * f ) . second ;
}
return CHECKED_NO ;
}
void CNavigator : : SetCheckedNode ( int wayPoint , int ent , byte value )
{
assert ( wayPoint > = 0 & & wayPoint < MAX_STORED_WAYPOINTS ) ;
assert ( ent > = 0 & & ent < MAX_GENTITIES ) ;
assert ( value = = CHECKED_FAILED | | value = = CHECKED_PASSED ) ;
CheckedNodes [ wayPoint * MAX_GENTITIES + ent ] = value ;
}
# define CHECK_FAILED_EDGE_INTERVAL 1000
# define CHECK_FAILED_EDGE_INTITIAL 5000 //10000
void CNavigator : : CheckFailedNodes ( gentity_t * ent )
{
vec3_t nodePos ;
int j ;
//Must have nodes
if ( m_nodes . size ( ) = = 0 )
return ;
if ( ent - > failedWaypointCheckTime & & ent - > failedWaypointCheckTime < level . time )
{
int failed = 0 ;
//do this only once every 1 second
for ( j = 0 ; j < MAX_FAILED_NODES ; j + + )
{
if ( ent - > failedWaypoints [ j ] ! = 0 )
{
failed + + ;
//-1 because 0 is a valid node but also the default, so we add one when we add one
m_nodes [ ent - > failedWaypoints [ j ] - 1 ] - > GetPosition ( nodePos ) ;
if ( ! NAV_ClearPathToPoint ( ent , ent - > mins , ent - > maxs , nodePos , ( CONTENTS_SOLID | CONTENTS_MONSTERCLIP | CONTENTS_BOTCLIP ) , ENTITYNUM_NONE ) )
{ //no path clear of architecture, so clear this since we can't check against entities
ent - > failedWaypoints [ j ] = 0 ;
failed - - ;
}
//have clear architectural path, now check against ents only
else if ( NAV_ClearPathToPoint ( ent , ent - > mins , ent - > maxs , nodePos , CONTENTS_BODY , ENTITYNUM_NONE ) )
{ //clear of ents, too, so all clear, clear this one out
ent - > failedWaypoints [ j ] = 0 ;
failed - - ;
}
}
}
if ( ! failed )
{
ent - > failedWaypointCheckTime = 0 ;
}
else
{
ent - > failedWaypointCheckTime = level . time + CHECK_FAILED_EDGE_INTERVAL + Q_irand ( 0 , 1000 ) ;
}
}
}
void CNavigator : : AddFailedNode ( gentity_t * ent , int nodeID )
{
int j ;
for ( j = 0 ; j < MAX_FAILED_NODES ; j + + )
{
if ( ent - > failedWaypoints [ j ] = = 0 )
{
ent - > failedWaypoints [ j ] = nodeID + 1 ; //+1 because 0 is the default value and that's a valid node, so we take the +1 out when we check the node above
if ( ! ent - > failedWaypointCheckTime )
{
ent - > failedWaypointCheckTime = level . time + CHECK_FAILED_EDGE_INTITIAL ;
}
return ;
}
if ( ent - > failedWaypoints [ j ] = = nodeID + 1 )
{ //already have this one marked as failed
return ;
}
}
if ( j = = MAX_FAILED_NODES ) //check not needed, but...
{ //ran out of failed nodes, get rid of first one, shift rest up
for ( j = 0 ; j < MAX_FAILED_NODES - 1 ; j + + )
{
ent - > failedWaypoints [ j ] = ent - > failedWaypoints [ j + 1 ] ;
}
}
ent - > failedWaypoints [ MAX_FAILED_NODES - 1 ] = nodeID + 1 ;
if ( ! ent - > failedWaypointCheckTime )
{
ent - > failedWaypointCheckTime = level . time + CHECK_FAILED_EDGE_INTITIAL ;
}
}
qboolean CNavigator : : NodeFailed ( gentity_t * ent , int nodeID )
{
for ( int j = 0 ; j < MAX_FAILED_NODES ; j + + )
{
if ( ( ent - > failedWaypoints [ j ] - 1 ) = = nodeID )
{
return qtrue ;
}
}
return qfalse ;
}
qboolean CNavigator : : NodesAreNeighbors ( int startID , int endID )
{ //See if these 2 are neighbors
if ( startID = = endID )
{
return qfalse ;
}
CNode * start = m_nodes [ startID ] ;
int nextID = - 1 ;
//NOTE: we only check start because we assume all connections are 2-way
for ( int i = 0 ; i < start - > GetNumEdges ( ) ; i + + )
{
nextID = start - > GetEdge ( i ) ;
if ( nextID = = endID )
{
return qtrue ;
}
}
//not neighbors
return qfalse ;
}
void CNavigator : : ClearFailedEdge ( failedEdge_t * failedEdge )
{
if ( ! failedEdge )
{
return ;
}
//clear the edge failed flags
/*
CNode * node = m_nodes [ failedEdge - > startID ] ;
int edgeNum = node - > GetEdgeNumToNode ( failedEdge - > endID ) ;
int flags ;
if ( edgeNum ! = - 1 )
{
flags = node - > GetEdgeFlags ( edgeNum ) & ~ EFLAG_FAILED ;
node - > SetEdgeFlags ( edgeNum , flags ) ;
}
node = m_nodes [ failedEdge - > endID ] ;
edgeNum = node - > GetEdgeNumToNode ( failedEdge - > startID ) ;
if ( edgeNum ! = - 1 )
{
flags = node - > GetEdgeFlags ( edgeNum ) & ~ EFLAG_FAILED ;
node - > SetEdgeFlags ( edgeNum , flags ) ;
}
*/
//clear failedEdge info
SetEdgeCost ( failedEdge - > startID , failedEdge - > endID , - 1 ) ;
failedEdge - > startID = failedEdge - > endID = WAYPOINT_NONE ;
failedEdge - > entID = ENTITYNUM_NONE ;
failedEdge - > checkTime = 0 ;
}
void CNavigator : : ClearAllFailedEdges ( void )
{
memset ( & failedEdges , WAYPOINT_NONE , sizeof ( failedEdges ) ) ;
for ( int j = 0 ; j < MAX_FAILED_EDGES ; j + + )
{
ClearFailedEdge ( & failedEdges [ j ] ) ;
}
}
int CNavigator : : EdgeFailed ( int startID , int endID )
{
//OPTIMIZED WAY (bjg 01/02)
//find in lookup map
std : : pair < EdgeMultimapIt , EdgeMultimapIt > findValue ;
findValue = m_edgeLookupMap . equal_range ( startID ) ;
while ( findValue . first ! = findValue . second )
{
if ( failedEdges [ findValue . first - > second ] . endID = = endID )
{
return findValue . first - > second ;
}
+ + findValue . first ;
}
findValue = m_edgeLookupMap . equal_range ( endID ) ;
while ( findValue . first ! = findValue . second )
{
if ( failedEdges [ findValue . first - > second ] . endID = = startID )
{
return findValue . first - > second ;
}
+ + findValue . first ;
}
return - 1 ;
//Old way (linear search)
/*
for ( int j = 0 ; j < MAX_FAILED_EDGES ; j + + )
{
if ( failedEdges [ j ] . startID = = startID )
{
if ( failedEdges [ j ] . endID = = endID )
{
return j ;
}
}
else if ( failedEdges [ j ] . startID = = endID )
{
if ( failedEdges [ j ] . endID = = startID )
{
return j ;
}
}
}
return - 1 ;
*/
}
void CNavigator : : AddFailedEdge ( int entID , int startID , int endID )
{
int j ; //, nextID;
//Must have nodes
if ( m_nodes . size ( ) = = 0 )
return ;
if ( d_patched - > integer )
{ //use patch-style navigation
if ( startID = = endID )
{ //not an edge!
return ;
}
}
//Validate the ent number
if ( ( entID < 0 ) | | ( entID > ENTITYNUM_NONE ) )
{
# ifndef FINAL_BUILD
gi . Printf ( S_COLOR_RED " NAV ERROR: envalid ent %d \n " , entID ) ;
assert ( 0 & & " invalid entID " ) ;
# endif
return ;
}
//Validate the start position
if ( ( startID < 0 ) | | ( startID > = ( int ) m_nodes . size ( ) ) )
{
# ifndef FINAL_BUILD
gi . Printf ( S_COLOR_RED " NAV ERROR: tried to fail invalid waypoint %d \n " , startID ) ;
assert ( 0 & & " invalid failed edge " ) ;
# endif
return ;
}
//Validate the end position
if ( ( endID < 0 ) | | ( endID > = ( int ) m_nodes . size ( ) ) )
{
# ifndef FINAL_BUILD
gi . Printf ( S_COLOR_RED " NAV ERROR: tried to fail invalid waypoint %d \n " , endID ) ;
assert ( 0 & & " invalid failed edge " ) ;
# endif
return ;
}
//First see if we already have this one
if ( ( j = EdgeFailed ( startID , endID ) ) ! = - 1 )
{
//just remember this guy instead
failedEdges [ j ] . entID = entID ;
return ;
}
//Okay, new one, find an empty slot
for ( j = 0 ; j < MAX_FAILED_EDGES ; j + + )
{
if ( failedEdges [ j ] . startID = = WAYPOINT_NONE )
{
failedEdges [ j ] . startID = startID ;
failedEdges [ j ] . endID = endID ;
//Check one second from now to see if it's clear
failedEdges [ j ] . checkTime = level . time + CHECK_FAILED_EDGE_INTERVAL + Q_irand ( 0 , 1000 ) ;
m_edgeLookupMap . insert ( std : : pair < int , int > ( startID , j ) ) ;
/*
//DISABLED this for now, makes people stand around too long when
// collision avoidance just wasn't at it's best but path is clear
CNode * start = m_nodes [ startID ] ;
CNode * end = m_nodes [ endID ] ;
for ( int i = 0 ; i < start - > GetNumEdges ( ) ; i + + )
{
nextID = start - > GetEdge ( i ) ;
if ( EdgeFailed ( startID , nextID ) ! = - 1 )
{
//This edge blocked, check next
continue ;
}
if ( nextID = = endID | | end - > GetRank ( nextID ) > = 0 )
{ //neighbor of or route to end
//There's an alternate route, so don't check this one for 10 seconds
failedEdges [ j ] . checkTime = level . time + CHECK_FAILED_EDGE_INTITIAL ;
break ;
}
}
*/
//Remember who needed it
failedEdges [ j ] . entID = entID ;
//set the edge failed flags
/*
CNode * node = m_nodes [ startID ] ;
int edgeNum = node - > GetEdgeNumToNode ( endID ) ;
int flags ;
if ( edgeNum ! = - 1 )
{
flags = node - > GetEdgeFlags ( edgeNum ) | EFLAG_FAILED ;
node - > SetEdgeFlags ( edgeNum , flags ) ;
}
node = m_nodes [ endID ] ;
edgeNum = node - > GetEdgeNumToNode ( startID ) ;
if ( edgeNum ! = - 1 )
{
flags = node - > GetEdgeFlags ( edgeNum ) | EFLAG_FAILED ;
node - > SetEdgeFlags ( edgeNum , flags ) ;
}
*/
//stuff the index to this one in our lookup map
//now recalc all the paths!
if ( pathsCalculated )
{
//reconnect the nodes and mark every node's flag NF_RECALC
//gi.Printf( S_COLOR_CYAN"%d marking all nodes for recalc\n", level.time );
SetEdgeCost ( startID , endID , Q3_INFINITE ) ;
FlagAllNodes ( NF_RECALC ) ;
}
return ;
}
}
# ifndef FINAL_BUILD
gi . Printf ( S_COLOR_RED " NAV ERROR: too many blocked waypoint connections (%d)!!! \n " , j ) ;
# endif
}
qboolean CNavigator : : CheckFailedEdge ( failedEdge_t * failedEdge )
{
if ( ! failedEdge )
{
return qfalse ;
}
//Every 1 second, see if our failed edges are clear
if ( failedEdge - > checkTime < level . time )
{
if ( failedEdge - > startID ! = WAYPOINT_NONE )
{
vec3_t start , end , mins , maxs ;
int ignore , clipmask ;
gentity_t * ent = ( failedEdge - > entID < ENTITYNUM_WORLD ) ? & g_entities [ failedEdge - > entID ] : NULL ;
int hitEntNum ;
if ( ! ent | | ! ent - > inuse | | ! ent - > client | | ent - > health < = 0 )
{
VectorSet ( mins , DEFAULT_MINS_0 , DEFAULT_MINS_1 , DEFAULT_MINS_2 + STEPSIZE ) ;
VectorSet ( maxs , DEFAULT_MAXS_0 , DEFAULT_MAXS_1 , DEFAULT_MAXS_2 ) ;
ignore = ENTITYNUM_NONE ;
clipmask = MASK_NPCSOLID ;
}
else
{
VectorCopy ( ent - > mins , mins ) ;
mins [ 2 ] + = STEPSIZE ;
VectorCopy ( ent - > maxs , maxs ) ;
ignore = failedEdge - > entID ;
clipmask = ent - > clipmask ;
}
if ( maxs [ 2 ] < mins [ 2 ] )
{ //don't invert bounding box
maxs [ 2 ] = mins [ 2 ] ;
}
m_nodes [ failedEdge - > startID ] - > GetPosition ( start ) ;
m_nodes [ failedEdge - > endID ] - > GetPosition ( end ) ;
//See if it's NAV_ClearPath...
#if 0
hitEntNum = NAVNEW_ClearPathBetweenPoints ( start , end , mins , maxs , ignore , clipmask | CONTENTS_MONSTERCLIP | CONTENTS_BOTCLIP ) ; //NOTE: should we really always include monsterclip (physically blocks NPCs) and botclip (do not enter)?
# else
trace_t trace ;
//Test if they're even conceivably close to one another
if ( ! gi . inPVSIgnorePortals ( start , end ) )
{
return qfalse ;
}
gi . trace ( & trace , start , mins , maxs , end , ignore , clipmask | CONTENTS_MONSTERCLIP | CONTENTS_BOTCLIP , G2_NOCOLLIDE , 0 ) ; //NOTE: should we really always include monsterclip (physically blocks NPCs) and botclip (do not enter)?
if ( trace . startsolid = = qtrue | | trace . allsolid = = qtrue )
{
return qfalse ;
}
hitEntNum = trace . entityNum ;
# endif
//if we did hit something, see if it's just an auto-door and allow it
if ( hitEntNum ! = ENTITYNUM_NONE & & G_EntIsUnlockedDoor ( hitEntNum ) )
{
hitEntNum = ENTITYNUM_NONE ;
}
else if ( hitEntNum = = failedEdge - > entID )
{ //don't hit the person who initially marked the edge failed
hitEntNum = ENTITYNUM_NONE ;
}
if ( hitEntNum = = ENTITYNUM_NONE )
{
//If so, clear it
ClearFailedEdge ( failedEdge ) ;
return qtrue ;
}
else
{
//Check again in one second
failedEdge - > checkTime = level . time + CHECK_FAILED_EDGE_INTERVAL + Q_irand ( 0 , 1000 ) ;
}
}
}
return qfalse ;
}
void CNavigator : : CheckAllFailedEdges ( void )
{
failedEdge_t * failedEdge ;
qboolean clearedAny = qfalse ;
//Must have nodes
if ( m_nodes . size ( ) = = 0 )
return ;
for ( int j = 0 ; j < MAX_FAILED_EDGES ; j + + )
{
failedEdge = & failedEdges [ j ] ;
clearedAny = CheckFailedEdge ( failedEdge ) ? qtrue : clearedAny ;
}
if ( clearedAny )
{ //need to recalc the paths
if ( pathsCalculated )
{
//reconnect the nodes and mark every node's flag NF_RECALC
//gi.Printf( S_COLOR_CYAN"%d marking all nodes for recalc\n", level.time );
FlagAllNodes ( NF_RECALC ) ;
}
}
}
qboolean CNavigator : : RouteBlocked ( int startID , int testEdgeID , int endID , int rejectRank )
{
int nextID , edgeID , lastID , bestNextID = NODE_NONE ;
int bestRank = rejectRank ;
int testRank ;
qboolean allEdgesFailed ;
CNode * end ;
CNode * next ;
if ( EdgeFailed ( startID , testEdgeID ) ! = - 1 )
{
return qtrue ;
}
if ( testEdgeID = = endID )
{ //Neighbors, checked out, all clear
return qfalse ;
}
//Okay, first edge is clear, now check rest of route!
end = m_nodes [ endID ] ;
nextID = testEdgeID ;
lastID = startID ;
while ( 1 )
{
next = m_nodes [ nextID ] ;
allEdgesFailed = qtrue ;
for ( int i = 0 ; i < next - > GetNumEdges ( ) ; i + + )
{
edgeID = next - > GetEdge ( i ) ;
if ( edgeID = = lastID )
{ //Don't backtrack
continue ;
}
if ( edgeID = = startID )
{ //Don't loop around
continue ;
}
if ( EdgeFailed ( nextID , edgeID ) ! = - 1 )
{
//This edge blocked, check next
continue ;
}
if ( edgeID = = endID )
{ //We got there all clear!
return qfalse ;
}
//Still going...
testRank = end - > GetRank ( edgeID ) ;
if ( testRank < 0 )
{ //No route this way
continue ;
}
//Is the rank good enough?
if ( testRank < bestRank )
{
bestNextID = edgeID ;
bestRank = testRank ;
allEdgesFailed = qfalse ;
}
}
if ( allEdgesFailed )
{
//This route has no clear way of getting to end
return qtrue ;
}
else
{
lastID = nextID ;
nextID = bestNextID ;
}
}
}
/*
- - - - - - - - - - - - - - - - - - - - - - - - -
GetBestNodeAltRoute
- - - - - - - - - - - - - - - - - - - - - - - - -
*/
int CNavigator : : GetBestNodeAltRoute ( int startID , int endID , int * pathCost , int rejectID )
{
//Must have nodes
if ( m_nodes . size ( ) = = 0 )
return WAYPOINT_NONE ;
//Validate the start position
if ( ( startID < 0 ) | | ( startID > = ( int ) m_nodes . size ( ) ) )
return WAYPOINT_NONE ;
//Validate the end position
if ( ( endID < 0 ) | | ( endID > = ( int ) m_nodes . size ( ) ) )
return WAYPOINT_NONE ;
//Is it the same node?
if ( startID = = endID )
{
if ( ! d_altRoutes - > integer | | EdgeFailed ( startID , endID ) = = - 1 )
{
return startID ;
}
else
{
return WAYPOINT_NONE ;
}
}
CNode * start = m_nodes [ startID ] ;
int bestNode = - 1 ;
int bestRank = Q3_INFINITE ;
int testRank , rejectRank = Q3_INFINITE ;
int bestCost = Q3_INFINITE ;
* pathCost = 0 ;
//Find the minimum rank of the edge(s) we want to reject as paths
if ( rejectID ! = WAYPOINT_NONE )
{
for ( int i = 0 ; i < start - > GetNumEdges ( ) ; i + + )
{
if ( start - > GetEdge ( i ) = = rejectID )
{
rejectRank = GetPathCost ( startID , endID ) ; //end->GetRank( start->GetEdge(i) );
break ;
}
}
}
for ( int i = 0 ; i < start - > GetNumEdges ( ) ; i + + )
{
int edgeID = start - > GetEdge ( i ) ;
testRank = GetPathCost ( edgeID , endID ) ; //end->GetRank( edgeID );
//Make sure it's not worse than our reject rank
if ( testRank > = rejectRank )
continue ;
//Found one
if ( edgeID = = endID )
{
if ( ! d_altRoutes - > integer | | ! RouteBlocked ( startID , edgeID , endID , rejectRank ) )
{
* pathCost + = start - > GetEdgeCost ( i ) ;
return edgeID ;
}
else
{ //this is blocked, can't consider it
continue ;
}
}
//No possible connection
if ( testRank = = NODE_NONE )
{
* pathCost = Q3_INFINITE ;
return NODE_NONE ;
}
//Found a better one
if ( testRank < bestRank )
{
//FIXME: make sure all the edges down from startID through edgeID to endID
// does NOT include a failedEdge...
if ( ! d_altRoutes - > integer | | ! RouteBlocked ( startID , edgeID , endID , rejectRank ) )
{
bestNode = edgeID ;
bestRank = testRank ;
bestCost = start - > GetEdgeCost ( i ) + testRank ;
}
}
}
* pathCost = bestCost ;
return bestNode ;
}
/*
- - - - - - - - - - - - - - - - - - - - - - - - -
GetBestNodeAltRoute
overloaded so you don ' t have to pass a pathCost int pointer in
- - - - - - - - - - - - - - - - - - - - - - - - -
*/
int CNavigator : : GetBestNodeAltRoute ( int startID , int endID , int rejectID )
{
int junk ;
return GetBestNodeAltRoute ( startID , endID , & junk , rejectID ) ;
}
/*
- - - - - - - - - - - - - - - - - - - - - - - - -
GetBestNode
- - - - - - - - - - - - - - - - - - - - - - - - -
*/
int CNavigator : : GetBestNode ( int startID , int endID , int rejectID )
{
//Validate the start position
if ( ( startID < 0 ) | | ( startID > = ( int ) m_nodes . size ( ) ) )
return WAYPOINT_NONE ;
//Validate the end position
if ( ( endID < 0 ) | | ( endID > = ( int ) m_nodes . size ( ) ) )
return WAYPOINT_NONE ;
if ( startID = = endID )
return startID ;
CNode * start = m_nodes [ startID ] ;
CNode * end = m_nodes [ endID ] ;
int bestNode = - 1 ;
int bestRank = Q3_INFINITE ;
int testRank , rejectRank = 0 ;
if ( rejectID ! = WAYPOINT_NONE )
{
for ( int i = 0 ; i < start - > GetNumEdges ( ) ; i + + )
{
if ( start - > GetEdge ( i ) = = rejectID )
{
rejectRank = end - > GetRank ( start - > GetEdge ( i ) ) ;
break ;
}
}
}
for ( int i = 0 ; i < start - > GetNumEdges ( ) ; i + + )
{
int edgeID = start - > GetEdge ( i ) ;
//Found one
if ( edgeID = = endID )
return edgeID ;
testRank = end - > GetRank ( edgeID ) ;
//Found one
if ( testRank < = rejectRank )
continue ;
//No possible connection
if ( testRank = = NODE_NONE )
return NODE_NONE ;
//Found a better one
if ( testRank < bestRank )
{
bestNode = edgeID ;
bestRank = testRank ;
}
}
return bestNode ;
}
/*
- - - - - - - - - - - - - - - - - - - - - - - - -
GetNodePosition
- - - - - - - - - - - - - - - - - - - - - - - - -
*/
int CNavigator : : GetNodePosition ( int nodeID , vec3_t out )
{
//Validate the number
if ( ( nodeID < 0 ) | | ( nodeID > = ( int ) m_nodes . size ( ) ) )
return false ;
CNode * node = m_nodes [ nodeID ] ;
node - > GetPosition ( out ) ;
return true ;
}
/*
- - - - - - - - - - - - - - - - - - - - - - - - -
GetNodeNumEdges
- - - - - - - - - - - - - - - - - - - - - - - - -
*/
int CNavigator : : GetNodeNumEdges ( int nodeID )
{
if ( ( nodeID < 0 ) | | ( nodeID > = ( int ) m_nodes . size ( ) ) )
return - 1 ;
CNode * node = m_nodes [ nodeID ] ;
assert ( node ) ;
return node - > GetNumEdges ( ) ;
}
/*
- - - - - - - - - - - - - - - - - - - - - - - - -
GetNodeEdge
- - - - - - - - - - - - - - - - - - - - - - - - -
*/
int CNavigator : : GetNodeEdge ( int nodeID , int edge )
{
if ( ( nodeID < 0 ) | | ( nodeID > = ( int ) m_nodes . size ( ) ) )
return - 1 ;
CNode * node = m_nodes [ nodeID ] ;
assert ( node ) ;
return node - > GetEdge ( edge ) ;
}
/*
- - - - - - - - - - - - - - - - - - - - - - - - -
Connected
- - - - - - - - - - - - - - - - - - - - - - - - -
*/
bool CNavigator : : Connected ( int startID , int endID )
{
//Validate the start position
if ( ( startID < 0 ) | | ( startID > = ( int ) m_nodes . size ( ) ) )
return false ;
//Validate the end position
if ( ( endID < 0 ) | | ( endID > = ( int ) m_nodes . size ( ) ) )
return false ;
if ( startID = = endID )
return true ;
CNode * start = m_nodes [ startID ] ;
CNode * end = m_nodes [ endID ] ;
for ( int i = 0 ; i < start - > GetNumEdges ( ) ; i + + )
{
int edgeID = start - > GetEdge ( i ) ;
//Found one
if ( edgeID = = endID )
return true ;
if ( ( end - > GetRank ( edgeID ) ) ! = NODE_NONE )
return true ;
}
return false ;
}
/*
- - - - - - - - - - - - - - - - - - - - - - - - -
GetPathCost
- - - - - - - - - - - - - - - - - - - - - - - - -
*/
unsigned int CNavigator : : GetPathCost ( int startID , int endID )
{
//Validate the start position
if ( ( startID < 0 ) | | ( startID > = ( int ) m_nodes . size ( ) ) )
return Q3_INFINITE ; // return 0;
//Validate the end position
if ( ( endID < 0 ) | | ( endID > = ( int ) m_nodes . size ( ) ) )
return Q3_INFINITE ; // return 0;
CNode * startNode = m_nodes [ startID ] ;
if ( ! startNode - > GetNumEdges ( ) )
{ //WTF? Solitary waypoint! Bad designer!
return Q3_INFINITE ; // return 0;
}
CNode * endNode = m_nodes [ endID ] ;
CNode * moveNode = startNode ;
int bestNode ;
int pathCost = 0 ;
int bestCost ;
int bestRank ;
int testRank ;
//Draw out our path
while ( moveNode ! = endNode )
{
bestRank = WORLD_SIZE ;
bestNode = - 1 ;
bestCost = 0 ;
for ( int i = 0 ; i < moveNode - > GetNumEdges ( ) ; i + + )
{
int edgeID = moveNode - > GetEdge ( i ) ;
//Done
if ( edgeID = = endID )
{
return pathCost + moveNode - > GetEdgeCost ( i ) ;
}
testRank = endNode - > GetRank ( edgeID ) ;
//No possible connection
if ( testRank = = NODE_NONE )
{
return Q3_INFINITE ; // return 0;
}
//Found a better one
if ( testRank < bestRank )
{
bestNode = edgeID ;
bestRank = testRank ;
bestCost = moveNode - > GetEdgeCost ( i ) ;
}
}
pathCost + = bestCost ;
//Take a new best node
moveNode = m_nodes [ bestNode ] ;
}
return pathCost ;
}
/*
- - - - - - - - - - - - - - - - - - - - - - - - -
GetEdgeCost
- - - - - - - - - - - - - - - - - - - - - - - - -
*/
unsigned int CNavigator : : GetEdgeCost ( int startID , int endID )
{
//Validate the start position
if ( ( startID < 0 ) | | ( startID > = ( int ) m_nodes . size ( ) ) )
return Q3_INFINITE ; // return 0;
//Validate the end position
if ( ( endID < 0 ) | | ( endID > = ( int ) m_nodes . size ( ) ) )
return Q3_INFINITE ; // return 0;
CNode * start = m_nodes [ startID ] ;
CNode * end = m_nodes [ endID ] ;
return GetEdgeCost ( start , end ) ;
}
/*
- - - - - - - - - - - - - - - - - - - - - - - - -
GetProjectedNode
- - - - - - - - - - - - - - - - - - - - - - - - -
*/
int CNavigator : : GetProjectedNode ( vec3_t origin , int nodeID )
{
//Validate the start position
if ( ( nodeID < 0 ) | | ( nodeID > = ( int ) m_nodes . size ( ) ) )
return NODE_NONE ;
CNode * node = m_nodes [ nodeID ] ;
CNode * tempNode ;
float bestDot = 0.0f ;
int bestNode = NODE_NONE ;
vec3_t targetDir , basePos , tempDir , tempPos ;
float dot ;
//Setup our target direction
node - > GetPosition ( basePos ) ;
VectorSubtract ( origin , basePos , targetDir ) ;
VectorNormalize ( targetDir ) ;
//Go through all the edges
for ( int i = 0 ; i < node - > GetNumEdges ( ) ; i + + )
{
tempNode = m_nodes [ node - > GetEdge ( i ) ] ;
tempNode - > GetPosition ( tempPos ) ;
VectorSubtract ( tempPos , basePos , tempDir ) ;
VectorNormalize ( tempDir ) ; //FIXME: Retain the length here if you want it
dot = DotProduct ( targetDir , tempDir ) ;
if ( dot < 0.0f )
continue ;
if ( dot > bestDot )
{
bestDot = dot ;
bestNode = tempNode - > GetID ( ) ;
}
}
return bestNode ;
}
// This is the PriorityQueue stuff for lists of connections
// better than linear (1/21/02 BJG)
//////////////////////////////////////////////////////////////////
// Helper pop_mHeap algorithm class
//////////////////////////////////////////////////////////////////
class NodeTotalGreater
{
public :
bool operator ( ) ( CEdge * first , CEdge * second ) const {
return ( first - > m_cost > second - > m_cost ) ;
}
} ;
//////////////////////////////////////////////////////////////////
// Destructor - Deallocate any remaining pointers in the queue
//////////////////////////////////////////////////////////////////
CPriorityQueue : : ~ CPriorityQueue ( )
{
while ( ! Empty ( ) )
{
delete Pop ( ) ;
}
}
//////////////////////////////////////////////////////////////////
// Standard Iterative Search
//////////////////////////////////////////////////////////////////
CEdge * CPriorityQueue : : Find ( int npNum )
{
for ( std : : vector < CEdge * > : : iterator HeapIter = mHeap . begin ( ) ; HeapIter ! = mHeap . end ( ) ; HeapIter + + )
{
if ( ( * HeapIter ) - > m_first = = npNum )
{
return * HeapIter ;
}
}
return 0 ;
}
//////////////////////////////////////////////////////////////////
// Remove Node And Resort
//////////////////////////////////////////////////////////////////
CEdge * CPriorityQueue : : Pop ( )
{
CEdge * edge = mHeap . front ( ) ;
//pop_mHeap will move the node at the front to the position N
//and then sort the mHeap to make positions 1 through N-1 correct
//(STL makes no assumptions about your data and doesn't want to change
//the size of the container.)
std : : pop_heap ( mHeap . begin ( ) , mHeap . end ( ) , NodeTotalGreater ( ) ) ;
//pop_back() will actually remove the last element from the mHeap
//now the mHeap is sorted for positions 1 through N
mHeap . pop_back ( ) ;
return ( edge ) ;
}
//////////////////////////////////////////////////////////////////
// Add New Node And Resort
//////////////////////////////////////////////////////////////////
void CPriorityQueue : : Push ( CEdge * theEdge )
{
//Pushes the node onto the back of the mHeap
mHeap . push_back ( theEdge ) ;
//Sorts the new element into the mHeap
std : : push_heap ( mHeap . begin ( ) , mHeap . end ( ) , NodeTotalGreater ( ) ) ;
}
//////////////////////////////////////////////////////////////////
// Find The Node In Question And Resort mHeap Around It
//////////////////////////////////////////////////////////////////
void CPriorityQueue : : Update ( CEdge * edge )
{
for ( std : : vector < CEdge * > : : iterator i = mHeap . begin ( ) ; i ! = mHeap . end ( ) ; i + + )
{
if ( ( * i ) - > m_first = = edge - > m_first )
{ //Found node - resort from this position in the mHeap
//(its total value was changed before this function was called)
std : : push_heap ( mHeap . begin ( ) , i + 1 , NodeTotalGreater ( ) ) ;
return ;
}
}
}
//////////////////////////////////////////////////////////////////
// Just a wrapper for stl empty function.
//////////////////////////////////////////////////////////////////
bool CPriorityQueue : : Empty ( )
{
return ( mHeap . empty ( ) ) ;
} ;