// Update is called once per frame
public override void Update()
{
mySteering = new SteeringOutput();
if (myRotateType.GetSteering() != null)
{
mySteering.angular = myRotateType.GetSteering().angular;
}
mySteering.linear = myMoveType.GetSteering().linear;
base.Update();
}
public override void Update()
{
SteeringOutput myMovement = path.GetSteering();
LookWhereGoing look = new LookWhereGoing();
look.target = path.target;
look.ai = this;
SteeringOutput mySteering = look.GetSteering();
linearVelocity += myMovement.linear * Time.deltaTime;
transform.position += linearVelocity * Time.deltaTime;
if (linearVelocity.magnitude > maxSpeed)
{
linearVelocity.Normalize();
linearVelocity *= maxSpeed;
}
if (mySteering != null)
{
angularVelocity += mySteering.angular * Time.deltaTime;
}
if (float.IsNaN(angularVelocity))
{
angularVelocity = 0;
}
transform.eulerAngles += new Vector3(0, angularVelocity * Time.deltaTime, 0);
}
// Update is called once per frame
public override void Update()
{
Seperation seperation = new Seperation();
seperation.targets = obstacles;
seperation.ai = this;
SteeringOutput myMovement = seperation.GetSteering();
LookWhereGoing look = new LookWhereGoing();
look.ai = this;
look.target = target;
SteeringOutput mySteering = look.GetSteering();
if (mySteering != null)
{
//linearVelocity += steering.linear * Time.deltaTime;
angularVelocity += mySteering.angular * Time.deltaTime;
}
linearVelocity += myMovement.linear * Time.deltaTime;
transform.position += linearVelocity * Time.deltaTime;
if (float.IsNaN(angularVelocity))
{
angularVelocity = 0;
}
transform.eulerAngles += new Vector3(0, angularVelocity * Time.deltaTime, 0);
}
// Update is called once per frame
void Update()
{
//Debug.Log(target);
// Check distance to see if steering behavior should be applied to AI
// float targetDist = (transform.position - target.transform.position).magnitude;
// if (!DistanceActivation || targetDist >= activationRange) { }
transform.position += linearVelocity * Time.deltaTime;
// adding angular velocity to current transform rotation y component
if (float.IsNaN(angularVelocity))
{
angularVelocity = 0;
}
transform.eulerAngles += new Vector3(0, angularVelocity * Time.deltaTime, 0);
// control to switch to proper steering behavior
if (avoidObstacles)
{
ObstacleAvoidance avoid = new ObstacleAvoidance();
avoid.ai = this;
SteeringOutput avoidForce = avoid.GetSteering();
if (avoidForce != null)
{
linearVelocity += avoidForce.linear;
}
}
if (seperationObstacles.Length > 0)
{
Seperation seperation = new Seperation();
seperation.targets = seperationObstacles;
seperation.ai = this;
SteeringOutput seperateForce = seperation.GetSteering();
// check to see if steering is greater than zero and lock out control from other steering
if (seperateForce.linear.magnitude > 0)
{
seperating = true;
}
else
{
seperating = false;
}
linearVelocity += seperateForce.linear * Time.deltaTime;
}
if (collisionAvoidance.Length > 0)
{
CollisionAvoidance avoidKinematic = new CollisionAvoidance();
avoidKinematic.ai = this;
avoidKinematic.targets = collisionAvoidance;
SteeringOutput avoidKinematicForce = avoidKinematic.GetSteering();
if (avoidKinematicForce != null)
{
linearVelocity += avoidKinematicForce.linear;
}
}
switch (movementType)
{
case "seek":
Seek mySeek = new Seek();
mySeek.ai = this;
// if seek is false set seek property on class to false to activate flee
mySeek.seek = true;
mySeek.target = target;
SteeringOutput steeringSeek = mySeek.GetSteering();
if (!seperating)
{
linearVelocity += steeringSeek.linear * Time.deltaTime;
}
if (linearVelocity.magnitude > maxSpeed)
{
linearVelocity.Normalize();
linearVelocity *= maxSpeed;
}
break;
case "flee":
Seek myFlee = new Seek();
myFlee.ai = this;
// if seek is false set seek property on class to false to activate flee
myFlee.seek = false;
myFlee.target = target;
SteeringOutput steeringFlee = myFlee.GetSteering();
if (!seperating)
{
linearVelocity += steeringFlee.linear * Time.deltaTime;
}
if (linearVelocity.magnitude > maxSpeed)
{
linearVelocity.Normalize();
linearVelocity *= maxSpeed;
}
break;
case "arrive":
Arrive myArrive = new Arrive();
myArrive.ai = this;
myArrive.target = target;
SteeringOutput steeringArrive = myArrive.GetSteering();
if (!seperating)
{
linearVelocity += steeringArrive.linear * Time.deltaTime;
}
break;
case "pursue":
Pursue myPursue = new Pursue();
myPursue.ai = this;
myPursue.target = target;
SteeringOutput steeringPursue = myPursue.GetSteering();
if (!seperating)
{
linearVelocity += steeringPursue.linear * Time.deltaTime;
}
if (linearVelocity.magnitude > maxSpeed)
{
linearVelocity.Normalize();
linearVelocity *= maxSpeed;
}
break;
case "evade":
Pursue myEvade = new Pursue();
myEvade.ai = this;
myEvade.target = target;
// This changes the seek flag in the parent Seek class of Pursue, sending it the flee vector instead
myEvade.seek = false;
SteeringOutput steeringEvade = myEvade.GetSteering();
if (!seperating)
{
linearVelocity += steeringEvade.linear * Time.deltaTime;
}
if (linearVelocity.magnitude > maxSpeed)
{
linearVelocity.Normalize();
linearVelocity *= maxSpeed;
}
break;
default:
// provide no input
break;
// If obstacles have been provided, return steering to seperate from them
}
switch (rotationType)
{
case "face":
Face myFace = new Face();
myFace.ai = this;
myFace.target = target;
SteeringOutput steeringFace = myFace.GetSteering();
if (steeringFace != null)
{
// linearVelocity += steering.linear * Time.deltaTime;
angularVelocity += steeringFace.angular * Time.deltaTime;
}
break;
case "align":
Align myAlign = new Align();
myAlign.ai = this;
myAlign.target = target;
SteeringOutput steeringAlign = myAlign.GetSteering();
if (steeringAlign != null)
{
//linearVelocity += steering.linear * Time.deltaTime;
angularVelocity += steeringAlign.angular * Time.deltaTime;
}
break;
case "look":
LookWhereGoing myLook = new LookWhereGoing();
myLook.ai = this;
myLook.target = target;
SteeringOutput steeringLook = myLook.GetSteering();
if (steeringLook != null)
{
//linearVelocity += steering.linear * Time.deltaTime;
angularVelocity += steeringLook.angular * Time.deltaTime;
}
break;
default:
//provide no input
break;
}
}
// Update is called once per frame
void Update()
{
transform.position += linearVelocity * Time.deltaTime;
// adding angular velocity to current transform rotation y component
if (float.IsNaN(angularVelocity))
{
angularVelocity = 0;
}
transform.eulerAngles += new Vector3(0, angularVelocity * Time.deltaTime, 0);
//dynamicSteering steering = new Seek();
// control to switch to proper steering behavior
if (!arrive)
{
Seek mySeek = new Seek();
mySeek.ai = this;
// if seek is false set seek property on class to false to activate flee
if (!seek)
{
mySeek.seek = false;
}
else
{
mySeek.seek = true;
}
mySeek.target = target;
SteeringOutput steering = mySeek.GetSteering();
linearVelocity += steering.linear * Time.deltaTime;
angularVelocity += steering.angular * Time.deltaTime;
if (linearVelocity.magnitude > maxSpeed)
{
linearVelocity.Normalize();
linearVelocity *= maxSpeed;
}
}
else
{
Arrive myArrive = new Arrive();
myArrive.ai = this;
myArrive.target = target;
SteeringOutput steering = myArrive.GetSteering();
linearVelocity += steering.linear * Time.deltaTime;
angularVelocity += steering.angular * Time.deltaTime;
}
if (align)
{
Align myAlign = new Align();
myAlign.ai = this;
myAlign.target = target;
SteeringOutput steering = myAlign.GetSteering();
if (steering != null)
{
linearVelocity += steering.linear * Time.deltaTime;
angularVelocity += steering.angular * Time.deltaTime;
}
}
if (lookWhereGoing && !align && !face)
{
LookWhereGoing myLook = new LookWhereGoing();
myLook.ai = this;
myLook.target = target;
SteeringOutput steering = myLook.GetSteering();
if (steering != null)
{
linearVelocity += steering.linear * Time.deltaTime;
angularVelocity += steering.angular * Time.deltaTime;
}
else
{
Debug.Log("Returning Null");
}
}
if (!lookWhereGoing && !align && face)
{
Face myFace = new Face();
myFace.ai = this;
myFace.target = target;
SteeringOutput steering = myFace.GetSteering();
if (steering != null)
{
linearVelocity += steering.linear * Time.deltaTime;
angularVelocity += steering.angular * Time.deltaTime;
}
}
}
void Update()
{
SteeringOutput movementSteering;
//SteeringOutput lookSteering;
//Update position and rotation
transform.position += linearVelocity * Time.deltaTime;
Vector3 angularIncrement = new Vector3(0, angularVelocity * Time.deltaTime, 0);
transform.eulerAngles += angularIncrement;
switch (moveType)
{
case SteeringType.Pursue:
movementSteering = pursueAI.GetSteering();
break;
case SteeringType.Evade:
movementSteering = evadeAI.GetSteering();
break;
case SteeringType.FollowPath:
movementSteering = followAI.GetSteering();
break;
case SteeringType.Seek:
movementSteering = seekAI.GetSteering();
break;
case SteeringType.Flee:
movementSteering = fleeAI.GetSteering();
break;
case SteeringType.Seperation:
movementSteering = seperationAI.GetSteering();
break;
case SteeringType.Arrive:
movementSteering = arriveAI.GetSteering();
break;
case SteeringType.CollisionAvoidance:
movementSteering = avoidAI.GetSteering();
break;
case SteeringType.ObstacleAvoidance:
movementSteering = obstacleAI.GetSteering();
break;
default:
movementSteering = new SteeringOutput();
break;
}
if (movementSteering != null)
{
linearVelocity += movementSteering.linear * Time.deltaTime;
//angularVelocity += movementSteering.angular * Time.deltaTime;
}
switch (lookType)
{
case LookType.None:
break;
case LookType.Align:
lookSteering = alignAI.GetSteering();
break;
case LookType.Face:
lookSteering = faceAI.GetSteering();
break;
case LookType.LookWhereGoing:
lookSteering = lookAI.GetSteering();
break;
default:
lookSteering = alignAI.GetSteering();
break;
}
if (lookSteering != null)
{
angularVelocity += lookSteering.angular * Time.deltaTime;
}
//Update kinematic reference with complex data it can't get by itself
kinematic.GetData(movementSteering);
kinematic.GetData(lookSteering);
}
