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Assignment for RMIT Mixed Reality in 2020
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vr-space-station/Assets/Scripts/UI/GravityData.cs

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using System.Collections;
using System.Collections.Generic;
using UnityEngine;
using VRTK;
/// <summary>
/// Class which deals with how objects behave when they are dropped
/// </summary>
[RequireComponent(typeof(VRTK_InteractableObject))]
public class GravityData : MonoBehaviour
{
[Header("Data")]
public string Name;
public float Gravity;
[Header("Visual Settings")]
[SerializeField]
private Transform m_planet;
[SerializeField]
private float m_rotationSpeed = 1;
[SerializeField]
private float m_bounceSpeed = 1;
[SerializeField]
private float m_bounceAmplitude = 0.1f;
private Vector3 m_StartPos;
public float m_randomOffset;
/// <summary>
/// The vrtk interactable object on this object
/// </summary>
private VRTK_InteractableObject m_interactable;
/// <summary>
/// Rigid body on this object
/// </summary>
private Rigidbody m_rigid;
private void Awake()
{
//Set up some variables on start
m_interactable = GetComponent<VRTK_InteractableObject>();
m_rigid = GetComponentInChildren<Rigidbody>();
m_StartPos = transform.position;
m_randomOffset = Random.value * 20;
}
private void OnEnable()
{
RegisterEvents(true);
}
private void OnDisable()
{
RegisterEvents(false);
}
private void Update()
{
if (m_planet != null)
{
m_planet.Rotate(Vector3.up, 360 / m_rotationSpeed * Time.deltaTime, Space.Self);
m_planet.localPosition = Vector3.up * Mathf.Sin(Time.time * m_bounceSpeed + m_randomOffset) * m_bounceAmplitude;
}
}
private void OnGrab(object sender, InteractableObjectEventArgs args)
{
StopAllCoroutines();
m_rigid.isKinematic = false;
}
private void OnDrop(object sender, InteractableObjectEventArgs args)
{
StopAllCoroutines();
StartCoroutine(LerpToPosition(m_StartPos, Quaternion.identity, 2.0f));
}
private void OnSnap(object sender, InteractableObjectEventArgs args)
{
StopAllCoroutines();
//m_rigid.isKinematic = true;
}
private void RegisterEvents(bool value)
{
if (value)
{
m_interactable.InteractableObjectSnappedToDropZone += OnSnap;
m_interactable.InteractableObjectGrabbed += OnGrab;
m_interactable.InteractableObjectUngrabbed += OnDrop;
}else
{
m_interactable.InteractableObjectSnappedToDropZone -= OnSnap;
m_interactable.InteractableObjectGrabbed -= OnGrab;
m_interactable.InteractableObjectUngrabbed -= OnDrop;
}
}
#region Coroutines
/// <summary>
/// Lerps object to a position over an amount of time
/// </summary>
/// <param name="SnapPos">End position</param>
/// <param name="SnapRot">End rotation</param>
/// <param name="snapTime">Time it takes to lerp</param>
private IEnumerator LerpToPosition(Vector3 SnapPos, Quaternion SnapRot, float snapTime)
{
Debug.Log("Lerp to position");
//This is based off of SteamVR Lerping code
float dropTimer = -1;
m_rigid.isKinematic = false;
//once again this is all steamVR
while (dropTimer < 1)
{
float t = Mathf.Pow(35, dropTimer);
m_rigid.velocity = Vector3.Lerp(m_rigid.velocity, Vector3.zero, Time.fixedDeltaTime * 4);
if (m_rigid.useGravity)
m_rigid.AddForce(-Physics.gravity);
transform.position = Vector3.Lerp(transform.position, SnapPos, Time.fixedDeltaTime * t * 3);
transform.rotation = Quaternion.Slerp(transform.rotation, SnapRot, Time.fixedDeltaTime * t * 5);
yield return new WaitForFixedUpdate();
dropTimer += Time.fixedDeltaTime / (snapTime / 2);
}
//#Audio: object has just arrived at where it was lerping to
//set correct transform in case object stuck
m_rigid.isKinematic = true;
transform.position = SnapPos;
transform.rotation = SnapRot;
}
#endregion Coroutines
}