public void NewLerp(PositionUpdateData data)
{
var vel = new Vector2(data.XVel, data.YVel);
var pos = new Vector2(data.XPos, data.YPos);
var currentState = new PositionState(AttachedShip.AngularVelocity, AttachedShip.Rotation, AttachedShip.LinearVelocity, AttachedShip.Position);
var nextState = new PositionState(data.AngularVelocity, data.Rotation, vel, pos);
var newState = LerpState(currentState, nextState);
AttachedShip.AngularVelocity = newState.AngularVelocity;
AttachedShip.Rotation = newState.Rotation;
AttachedShip.LinearVelocity = newState.LinearVelocity;
AttachedShip.Position = newState.Position;
}
public PositionLerpState LerpPosition(PositionState current, PositionState next)
{
var currentPosition = current.Position;
var incomingPosition = next.Position;
var incomingVelocity = next.LinearVelocity;
var incomingSpeed = incomingVelocity.Length();
// Prevent divide by zero.
var speed = incomingSpeed == 0f ? 0.00001f : incomingSpeed;
// Our algorithm looks a half second into the future as it's target.
var distanceToSeekIntoFuture = 0.5f;
var distanceInTimespan = speed * distanceToSeekIntoFuture;
var velocityAngle = GetAngleFromVector(incomingVelocity);
// Where the server's client will be in a half second.
var serverFutureX = incomingPosition.X + (distanceInTimespan * (float)Math.Sin(velocityAngle));
var serverFutureY = incomingPosition.Y + (distanceInTimespan * (float)Math.Cos(velocityAngle));
// Where we will be in a half second.
var ourFutureX = currentPosition.X + (distanceInTimespan * (float)Math.Sin(velocityAngle));
var ourFutureY = currentPosition.Y + (distanceInTimespan * (float)Math.Cos(velocityAngle));
var serverFuture = new Vector2(serverFutureX, serverFutureY);
var ourFuture = new Vector2(ourFutureX, ourFutureY);
// How far our ship is from where the server's client will be.
var distanceFromServerFuture = Vector2.Distance(currentPosition, serverFuture) + 0.0001f;
var distanceFromOurFuture = Vector2.Distance(currentPosition, ourFuture) + 0.0001f;
// Grab the different between our target and the server's, then shift us to point at that.
var angleDifference = FindAngle(currentPosition, serverFuture, ourFuture);
var desiredAngle = velocityAngle - angleDifference;
var desiredFutureX = currentPosition.X + (distanceFromServerFuture * (float)Math.Sin(desiredAngle));
var desiredFutureY = currentPosition.Y + (distanceFromServerFuture * (float)Math.Cos(desiredAngle));
var desiredFuture = new Vector2(desiredFutureX, desiredFutureY);
// Adjust the speed based on how far we are from the desired future position.
var speedAdjustmentFactor = Vector2.Distance(currentPosition, desiredFuture) / distanceFromOurFuture;
// Keep things relative to half a second.
var desiredSpeed = speed * speedAdjustmentFactor;
// Nudge velocity angle to point at destination point.
var desiredVelocityX = desiredSpeed * (float)Math.Sin(desiredAngle);
var desiredVelocityY = desiredSpeed * (float)Math.Cos(desiredAngle);
// Number of seconds until lag distance is covered
var timeToMeet = distanceFromServerFuture / speed;
// Snap if we're too de-synced.
if (timeToMeet >= 1f)
{
var distanceBetweenPositions = Vector2.Distance(currentPosition, incomingPosition) * 2f + 0.0001f;
if (distanceBetweenPositions > distanceFromServerFuture)
{
velocityAngle = GetAngleFromVector(incomingPosition - currentPosition);
desiredVelocityX = distanceBetweenPositions * (float)Math.Sin(velocityAngle);
desiredVelocityY = distanceBetweenPositions * (float)Math.Cos(velocityAngle);
}
else
{
currentPosition = incomingPosition;
desiredVelocityX = incomingVelocity.X;
desiredVelocityY = incomingVelocity.Y;
}
}
return(new PositionLerpState(new Vector2(desiredVelocityX, desiredVelocityY), currentPosition));
}
public PositionState LerpState(PositionState current, PositionState next)
{
var newLerpPosition = LerpPosition(current, next);
return(new PositionState(next.AngularVelocity, next.Rotation, newLerpPosition.Velocity, newLerpPosition.Position));
}
