source-engine/game/server/cstrike/cs_nav_path.h

//========= Copyright Valve Corporation, All rights reserved. ============//
//
// Purpose: 
//
// $NoKeywords: $
//
//=============================================================================//
// nav_path.h
// Navigation Path encapsulation
// Author: Michael S. Booth (mike@turtlerockstudios.com), November 2003

#ifndef _CS_NAV_PATH_H_
#define _CS_NAV_PATH_H_

#include "nav_area.h"
#include "bot_util.h"

class CImprovLocomotor;

//--------------------------------------------------------------------------------------------------------
/**
 * The CCSNavPath class encapsulates a path through space
 */
class CCSNavPath
{
public:
	CCSNavPath( void )
	{
		m_segmentCount = 0;
	}

	struct PathSegment
	{
		CNavArea *area;											///< the area along the path
		NavTraverseType how;									///< how to enter this area from the previous one
		Vector pos;												///< our movement goal position at this point in the path
		const CNavLadder *ladder;								///< if "how" refers to a ladder, this is it
	};

	const PathSegment * operator[] ( int i ) const		{ return (i >= 0 && i < m_segmentCount) ? &m_path[i] : NULL; }
	const PathSegment *GetSegment( int i ) const		{ return (i >= 0 && i < m_segmentCount) ? &m_path[i] : NULL; }
	int GetSegmentCount( void ) const					{ return m_segmentCount; }
	const Vector &GetEndpoint( void ) const				{ return m_path[ m_segmentCount-1 ].pos; }
	bool IsAtEnd( const Vector &pos ) const;					///< return true if position is at the end of the path

	float GetLength( void ) const;								///< return length of path from start to finish
	bool GetPointAlongPath( float distAlong, Vector *pointOnPath ) const;	///< return point a given distance along the path - if distance is out of path bounds, point is clamped to start/end

	/// return the node index closest to the given distance along the path without going over - returns (-1) if error
	int GetSegmentIndexAlongPath( float distAlong ) const;

	bool IsValid( void ) const	{ return (m_segmentCount > 0); }
	void Invalidate( void )		{ m_segmentCount = 0; }

	void Draw( const Vector &color = Vector( 1.0f, 0.3f, 0 ) );	///< draw the path for debugging

	/// compute closest point on path to given point
	bool FindClosestPointOnPath( const Vector *worldPos, int startIndex, int endIndex, Vector *close ) const;

	void Optimize( void );
	
	/**
	 * Compute shortest path from 'start' to 'goal' via A* algorithm.
	 * If returns true, path was build to the goal position.
	 * If returns false, path may either be invalid (use IsValid() to check), or valid but 
	 * doesn't reach all the way to the goal.
	 */
	template< typename CostFunctor >
	bool Compute( const Vector &start, const Vector &goal, CostFunctor &costFunc )
	{
		Invalidate();

		CNavArea *startArea = TheNavMesh->GetNearestNavArea( start + Vector( 0.0f, 0.0f, 1.0f ) );
		if (startArea == NULL)
		{
			return false;
		}

		CNavArea *goalArea = TheNavMesh->GetNavArea( goal );

		// if we are already in the goal area, build trivial path
		if (startArea == goalArea)
		{
			BuildTrivialPath( start, goal );
			return true;
		}

		// make sure path end position is on the ground
		Vector pathEndPosition = goal;
		if (goalArea)
		{
			pathEndPosition.z = goalArea->GetZ( pathEndPosition );
		}
		else
		{
			TheNavMesh->GetGroundHeight( pathEndPosition, &pathEndPosition.z );
		}

		//
		// Compute shortest path to goal
		//
		CNavArea *closestArea;
		bool pathResult = NavAreaBuildPath( startArea, goalArea, &goal, costFunc, &closestArea );

		//
		// Build path by following parent links
		//

		// get count
		int count = 0;
		CNavArea *area;
		for( area = closestArea; area; area = area->GetParent() )
		{
			++count;
		}

		// save room for endpoint
		if (count > MAX_PATH_SEGMENTS-1)
		{
			count = MAX_PATH_SEGMENTS-1;
		}

		if (count == 0)
		{
			return false;
		}

		if (count == 1)
		{
			BuildTrivialPath( start, goal );
			return true;
		}

		// build path
		m_segmentCount = count;
		for( area = closestArea; count && area; area = area->GetParent() )
		{
			--count;
			m_path[ count ].area = area;
			m_path[ count ].how = area->GetParentHow();
		}

		// compute path positions
		if (ComputePathPositions() == false)
		{
			//PrintIfWatched( "CNavPath::Compute: Error building path\n" );
			Invalidate();
			return false;
		}

		// append path end position
		m_path[ m_segmentCount ].area = closestArea;
		m_path[ m_segmentCount ].pos = pathEndPosition;
		m_path[ m_segmentCount ].ladder = NULL;
		m_path[ m_segmentCount ].how = NUM_TRAVERSE_TYPES;
		++m_segmentCount;

		return pathResult;
	}

private:
	enum { MAX_PATH_SEGMENTS = 256 };
	PathSegment m_path[ MAX_PATH_SEGMENTS ];
	int m_segmentCount;

	bool ComputePathPositions( void );									///< determine actual path positions 
	bool BuildTrivialPath( const Vector &start, const Vector &goal );	///< utility function for when start and goal are in the same area

	int FindNextOccludedNode( int anchor );								///< used by Optimize()
};

//--------------------------------------------------------------------------------------------------------
/**
 * Monitor improv movement and determine if it becomes stuck
 */
class CStuckMonitor
{
public:
	CStuckMonitor( void );

	void Reset( void );
	void Update( CImprovLocomotor *improv );
	bool IsStuck( void ) const		{ return m_isStuck; }

	float GetDuration( void ) const	{ return (m_isStuck) ? m_stuckTimer.GetElapsedTime() : 0.0f; }

private:
	bool m_isStuck;													///< if true, we are stuck
	Vector m_stuckSpot;												///< the location where we became stuck
	IntervalTimer m_stuckTimer;										///< how long we have been stuck

	enum { MAX_VEL_SAMPLES = 5 };
	float m_avgVel[ MAX_VEL_SAMPLES ];
	int m_avgVelIndex;
	int m_avgVelCount;
	Vector m_lastCentroid;
	float m_lastTime;
};

//--------------------------------------------------------------------------------------------------------
/**
 * The CNavPathFollower class implements path following behavior
 */
class CNavPathFollower
{
public:
	CNavPathFollower( void );

	void SetImprov( CImprovLocomotor *improv ) { m_improv = improv; }
	void SetPath( CCSNavPath *path ) { m_path = path; }

	void Reset( void );

	#define DONT_AVOID_OBSTACLES false
	void Update( float deltaT, bool avoidObstacles = true );		///< move improv along path
	void Debug( bool status )		{ m_isDebug = status; }			///< turn debugging on/off

	bool IsStuck( void ) const		{ return m_stuckMonitor.IsStuck(); }	///< return true if improv is stuck 
	void ResetStuck( void )			{ m_stuckMonitor.Reset(); }
	float GetStuckDuration( void ) const	{ return m_stuckMonitor.GetDuration(); }	///< return how long we've been stuck

	void FeelerReflexAdjustment( Vector *goalPosition, float height = -1.0f );	///< adjust goal position if "feelers" are touched

private:
	CImprovLocomotor *m_improv;										///< who is doing the path following

	CCSNavPath *m_path;												///< the path being followed

	int m_segmentIndex;												///< the point on the path the improv is moving towards
	int m_behindIndex;												///< index of the node on the path just behind us
	Vector m_goal;													///< last computed follow goal

	bool m_isLadderStarted;

	bool m_isDebug;

	int FindOurPositionOnPath( Vector *close, bool local ) const;	///< return the closest point to our current position on current path
	int FindPathPoint( float aheadRange, Vector *point, int *prevIndex );	///< compute a point a fixed distance ahead along our path.

	CStuckMonitor m_stuckMonitor;
};


#endif	// _CS_NAV_PATH_H_
1 5 years ago			`//========= Copyright Valve Corporation, All rights reserved. ============//`
			`//`
			`// Purpose:`
			`//`
			`// $NoKeywords: $`
			`//`
			`//=============================================================================//`
			`// nav_path.h`
			`// Navigation Path encapsulation`
			`// Author: Michael S. Booth (mike@turtlerockstudios.com), November 2003`

			`#ifndef _CS_NAV_PATH_H_`
			`#define _CS_NAV_PATH_H_`

			`#include "nav_area.h"`
			`#include "bot_util.h"`

			`class CImprovLocomotor;`

			`//--------------------------------------------------------------------------------------------------------`
			`/**`
			`* The CCSNavPath class encapsulates a path through space`
			`*/`
			`class CCSNavPath`
			`{`
			`public:`
			`CCSNavPath( void )`
			`{`
			`m_segmentCount = 0;`
			`}`

			`struct PathSegment`
			`{`
			`CNavArea *area; ///< the area along the path`
			`NavTraverseType how; ///< how to enter this area from the previous one`
			`Vector pos; ///< our movement goal position at this point in the path`
			`const CNavLadder *ladder; ///< if "how" refers to a ladder, this is it`
			`};`

			`const PathSegment * operator[] ( int i ) const { return (i >= 0 && i < m_segmentCount) ? &m_path[i] : NULL; }`
			`const PathSegment *GetSegment( int i ) const { return (i >= 0 && i < m_segmentCount) ? &m_path[i] : NULL; }`
			`int GetSegmentCount( void ) const { return m_segmentCount; }`
			`const Vector &GetEndpoint( void ) const { return m_path[ m_segmentCount-1 ].pos; }`
			`bool IsAtEnd( const Vector &pos ) const; ///< return true if position is at the end of the path`

			`float GetLength( void ) const; ///< return length of path from start to finish`
			`bool GetPointAlongPath( float distAlong, Vector *pointOnPath ) const; ///< return point a given distance along the path - if distance is out of path bounds, point is clamped to start/end`

			`/// return the node index closest to the given distance along the path without going over - returns (-1) if error`
			`int GetSegmentIndexAlongPath( float distAlong ) const;`

			`bool IsValid( void ) const { return (m_segmentCount > 0); }`
			`void Invalidate( void ) { m_segmentCount = 0; }`

			`void Draw( const Vector &color = Vector( 1.0f, 0.3f, 0 ) ); ///< draw the path for debugging`

			`/// compute closest point on path to given point`
			`bool FindClosestPointOnPath( const Vector worldPos, int startIndex, int endIndex, Vector close ) const;`

			`void Optimize( void );`

			`/**`
			`* Compute shortest path from 'start' to 'goal' via A* algorithm.`
			`* If returns true, path was build to the goal position.`
			`* If returns false, path may either be invalid (use IsValid() to check), or valid but`
			`* doesn't reach all the way to the goal.`
			`*/`
			`template< typename CostFunctor >`
			`bool Compute( const Vector &start, const Vector &goal, CostFunctor &costFunc )`
			`{`
			`Invalidate();`

			`CNavArea *startArea = TheNavMesh->GetNearestNavArea( start + Vector( 0.0f, 0.0f, 1.0f ) );`
			`if (startArea == NULL)`
			`{`
			`return false;`
			`}`

			`CNavArea *goalArea = TheNavMesh->GetNavArea( goal );`

			`// if we are already in the goal area, build trivial path`
			`if (startArea == goalArea)`
			`{`
			`BuildTrivialPath( start, goal );`
			`return true;`
			`}`

			`// make sure path end position is on the ground`
			`Vector pathEndPosition = goal;`
			`if (goalArea)`
			`{`
			`pathEndPosition.z = goalArea->GetZ( pathEndPosition );`
			`}`
			`else`
			`{`
			`TheNavMesh->GetGroundHeight( pathEndPosition, &pathEndPosition.z );`
			`}`

			`//`
			`// Compute shortest path to goal`
			`//`
			`CNavArea *closestArea;`
			`bool pathResult = NavAreaBuildPath( startArea, goalArea, &goal, costFunc, &closestArea );`

			`//`
			`// Build path by following parent links`
			`//`

			`// get count`
			`int count = 0;`
			`CNavArea *area;`
			`for( area = closestArea; area; area = area->GetParent() )`
			`{`
			`++count;`
			`}`

			`// save room for endpoint`
			`if (count > MAX_PATH_SEGMENTS-1)`
			`{`
			`count = MAX_PATH_SEGMENTS-1;`
			`}`

			`if (count == 0)`
			`{`
			`return false;`
			`}`

			`if (count == 1)`
			`{`
			`BuildTrivialPath( start, goal );`
			`return true;`
			`}`

			`// build path`
			`m_segmentCount = count;`
			`for( area = closestArea; count && area; area = area->GetParent() )`
			`{`
			`--count;`
			`m_path[ count ].area = area;`
			`m_path[ count ].how = area->GetParentHow();`
			`}`

			`// compute path positions`
			`if (ComputePathPositions() == false)`
			`{`
			`//PrintIfWatched( "CNavPath::Compute: Error building path\n" );`
			`Invalidate();`
			`return false;`
			`}`

			`// append path end position`
			`m_path[ m_segmentCount ].area = closestArea;`
			`m_path[ m_segmentCount ].pos = pathEndPosition;`
			`m_path[ m_segmentCount ].ladder = NULL;`
			`m_path[ m_segmentCount ].how = NUM_TRAVERSE_TYPES;`
			`++m_segmentCount;`

			`return pathResult;`
			`}`

			`private:`
			`enum { MAX_PATH_SEGMENTS = 256 };`
			`PathSegment m_path[ MAX_PATH_SEGMENTS ];`
			`int m_segmentCount;`

			`bool ComputePathPositions( void ); ///< determine actual path positions`
			`bool BuildTrivialPath( const Vector &start, const Vector &goal ); ///< utility function for when start and goal are in the same area`

			`int FindNextOccludedNode( int anchor ); ///< used by Optimize()`
			`};`

			`//--------------------------------------------------------------------------------------------------------`
			`/**`
			`* Monitor improv movement and determine if it becomes stuck`
			`*/`
			`class CStuckMonitor`
			`{`
			`public:`
			`CStuckMonitor( void );`

			`void Reset( void );`
			`void Update( CImprovLocomotor *improv );`
			`bool IsStuck( void ) const { return m_isStuck; }`

			`float GetDuration( void ) const { return (m_isStuck) ? m_stuckTimer.GetElapsedTime() : 0.0f; }`

			`private:`
			`bool m_isStuck; ///< if true, we are stuck`
			`Vector m_stuckSpot; ///< the location where we became stuck`
			`IntervalTimer m_stuckTimer; ///< how long we have been stuck`

			`enum { MAX_VEL_SAMPLES = 5 };`
			`float m_avgVel[ MAX_VEL_SAMPLES ];`
			`int m_avgVelIndex;`
			`int m_avgVelCount;`
			`Vector m_lastCentroid;`
			`float m_lastTime;`
			`};`

			`//--------------------------------------------------------------------------------------------------------`
			`/**`
			`* The CNavPathFollower class implements path following behavior`
			`*/`
			`class CNavPathFollower`
			`{`
			`public:`
			`CNavPathFollower( void );`

			`void SetImprov( CImprovLocomotor *improv ) { m_improv = improv; }`
			`void SetPath( CCSNavPath *path ) { m_path = path; }`

			`void Reset( void );`

			`#define DONT_AVOID_OBSTACLES false`
			`void Update( float deltaT, bool avoidObstacles = true ); ///< move improv along path`
			`void Debug( bool status ) { m_isDebug = status; } ///< turn debugging on/off`

			`bool IsStuck( void ) const { return m_stuckMonitor.IsStuck(); } ///< return true if improv is stuck`
			`void ResetStuck( void ) { m_stuckMonitor.Reset(); }`
			`float GetStuckDuration( void ) const { return m_stuckMonitor.GetDuration(); } ///< return how long we've been stuck`

			`void FeelerReflexAdjustment( Vector *goalPosition, float height = -1.0f ); ///< adjust goal position if "feelers" are touched`

			`private:`
			`CImprovLocomotor *m_improv; ///< who is doing the path following`

			`CCSNavPath *m_path; ///< the path being followed`

			`int m_segmentIndex; ///< the point on the path the improv is moving towards`
			`int m_behindIndex; ///< index of the node on the path just behind us`
			`Vector m_goal; ///< last computed follow goal`

			`bool m_isLadderStarted;`

			`bool m_isDebug;`

			`int FindOurPositionOnPath( Vector *close, bool local ) const; ///< return the closest point to our current position on current path`
			`int FindPathPoint( float aheadRange, Vector point, int prevIndex ); ///< compute a point a fixed distance ahead along our path.`

			`CStuckMonitor m_stuckMonitor;`
			`};`



			`#endif // _CS_NAV_PATH_H_`