//========= Copyright © 1996-2005, Valve Corporation, All rights reserved. ============// // // Purpose: // // $NoKeywords: $ //=============================================================================// #ifndef AI_BASENPC_FLYER_H #define AI_BASENPC_FLYER_H #ifdef _WIN32 #pragma once #endif #include "ai_basenpc.h" #include "ai_navigator.h" //----------------------------------------------------------------------------- // The combot. //----------------------------------------------------------------------------- abstract_class CAI_BaseFlyingBot : public CAI_BaseNPC { DECLARE_CLASS( CAI_BaseFlyingBot, CAI_BaseNPC ); public: DECLARE_DATADESC(); void StartTask( const Task_t *pTask ); void GetVelocity(Vector *vVelocity, AngularImpulse *vAngVelocity); virtual QAngle BodyAngles(); protected: CAI_BaseFlyingBot(); Vector VelocityToAvoidObstacles(float flInterval); virtual float MinGroundDist(void); void TurnHeadToTarget( float flInterval, const Vector &moveTarget ); void MoveInDirection( float flInterval, const Vector &targetDir, float accelXY, float accelZ, float decay) { decay = ExponentialDecay( decay, 1.0, flInterval ); accelXY *= flInterval; accelZ *= flInterval; m_vCurrentVelocity.x = ( decay * m_vCurrentVelocity.x + accelXY * targetDir.x ); m_vCurrentVelocity.y = ( decay * m_vCurrentVelocity.y + accelXY * targetDir.y ); m_vCurrentVelocity.z = ( decay * m_vCurrentVelocity.z + accelZ * targetDir.z ); } void MoveToLocation( float flInterval, const Vector &target, float accelXY, float accelZ, float decay) { Vector targetDir = target - GetLocalOrigin(); VectorNormalize(targetDir); MoveInDirection(flInterval, targetDir, accelXY, accelZ, decay); } void Decelerate( float flInterval, float decay ) { decay *= flInterval; m_vCurrentVelocity.x = (decay * m_vCurrentVelocity.x); m_vCurrentVelocity.y = (decay * m_vCurrentVelocity.y); m_vCurrentVelocity.z = (decay * m_vCurrentVelocity.z); } void AddNoiseToVelocity( float noiseScale = 1.0 ) { if( m_vNoiseMod.x ) { m_vCurrentVelocity.x += noiseScale*sin(m_vNoiseMod.x * gpGlobals->curtime + m_vNoiseMod.x); } if( m_vNoiseMod.y ) { m_vCurrentVelocity.y += noiseScale*cos(m_vNoiseMod.y * gpGlobals->curtime + m_vNoiseMod.y); } if( m_vNoiseMod.z ) { m_vCurrentVelocity.z -= noiseScale*cos(m_vNoiseMod.z * gpGlobals->curtime + m_vNoiseMod.z); } } void LimitSpeed( float zLimit, float maxSpeed = -1 ) { if ( maxSpeed == -1 ) maxSpeed = m_flSpeed; if (m_vCurrentVelocity.Length() > maxSpeed) { VectorNormalize(m_vCurrentVelocity); m_vCurrentVelocity *= maxSpeed; } // Limit fall speed if (zLimit > 0 && m_vCurrentVelocity.z < -zLimit) { m_vCurrentVelocity.z = -zLimit; } } AI_NavPathProgress_t ProgressFlyPath( float flInterval, const CBaseEntity *pNewTarget, unsigned collisionMask, bool bNewTrySimplify = true, float strictPointTolerance = 32.0 ); virtual float GetHeadTurnRate( void ) { return 15.0f; } // Degrees per second const Vector &GetCurrentVelocity() const { return m_vCurrentVelocity; } void SetCurrentVelocity(const Vector &vNewVel) { m_vCurrentVelocity = vNewVel; } const Vector &GetNoiseMod() const { return m_vNoiseMod; } void SetNoiseMod( float x, float y, float z ) { m_vNoiseMod.Init( x, y, z ); } void SetNoiseMod( const Vector &noise ) { m_vNoiseMod = noise; } virtual void MoveToTarget(float flInterval, const Vector &MoveTarget) = 0; void TranslateNavGoal( CBaseEntity *pTarget, Vector &chasePosition ); // ------------------------------- // Movement vars // ------------------------------- Vector m_vCurrentVelocity; Vector m_vCurrentAngularVelocity; Vector m_vCurrentBanking; Vector m_vNoiseMod; float m_fHeadYaw; Vector m_vLastPatrolDir; }; #endif // AI_BASENPC_FLYER_H