Shake() 개인적인 메소드

private Shake ( ) : IEnumerator
리턴 IEnumerator
    private IEnumerator Blink()
    {
        obstacleHitSound.Play();
        animator.SetBool("Blinking", true);
        mainCameraBehaviour.Shake(shake);
        yield return(new WaitForSeconds(blinkTime));

        animator.SetBool("Blinking", false);
    }
예제 #2
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    protected override void OnCollision(Collider2D _collider)
    {
        IceBlock _iceBlock = _collider.GetComponent <IceBlock>();

        ShakeEffect _camera = Camera.main.GetComponent <ShakeEffect>();

        _camera.Shake(0.05f, 0.2f);

        if (_iceBlock)
        {
            Destroy(_iceBlock.gameObject);
        }

        DestroyParticle();
    }
예제 #3
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    public void Update()
    {
        if (!body.Grounded)
        {
            if (airTime > 0)
            {
                airTime -= Time.deltaTime;

                if (!shakeEffect.IsShaking && airTime <= instableTime)
                {
                    shakeEffect.Shake(shakeStrenght, instableTime, false);
                }
            }
            else
            {
                if (shakeEffect.IsShaking)
                {
                    shakeEffect.Stop();
                }
                body.GravityMultiplier = gravityMultiplier;
            }
        }
    }
예제 #4
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 void onCarExplode(CarNeuralCoreBase carNeuralCoreBase)
 {
     shakeEffect.Shake(carNeuralCoreBase.transform.position);
 }
예제 #5
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    // Based on the camera attributes and the target's special camera attributes, find out where the
    // camera should move to.
    public Vector3 GetGoalPosition(float elapsedTime)
    {
        // Our camera script can take attributes from the target.  If there are no attributes attached, we have
        // the following defaults.

        // How high in world space should the camera look above the target?
        float heightOffset = 0.0f;
        // How much should we zoom the camera based on this target?
        float distanceModifier = 1.0f;
        // By default, we won't account for any target velocity or chaos in our calculations;
        float   velocityLookAheadX = 0.0f;
        float   velocityLookAheadY = 0.0f;
        Vector2 maxLookAhead       = new Vector2(0.0f, 0.0f);

        // If our target has special attributes, use these instead of our above defaults.
        if (TargetAttributes != null)
        {
            heightOffset = TargetAttributes.HeightOffset;

            if (TargetAnimator != null && TargetAnimator.IsDead)
            {
                distanceModifier = TargetAttributes.DeathZoom;
            }
            else if (_shakeEffect != null)
            {
                distanceModifier = _shakeEffect.OldDistanceModifier;
            }
            else if (_cinematicOverride)
            {
                distanceModifier = 0.5f;
            }
            else
            {
                distanceModifier = TargetAttributes.DistanceModifier;
            }

            velocityLookAheadX = TargetAttributes.VelocityLookAheadX;
            velocityLookAheadY = TargetAttributes.VelocityLookAheadY;
            maxLookAhead       = TargetAttributes.MaxLookAhead;
        }

        Vector3 goalPosition = Target.position + new Vector3(0, heightOffset, -Distance * distanceModifier);

        Vector3 nearestEnemy = Vector3.zero;

        _enemyFocused = GetNearestEnemy(out nearestEnemy);
        if (_enemyFocused)
        {
            goalPosition += (nearestEnemy - GameManager.Player.transform.position) * 0.5f
                            + new Vector3(0, 0, -Vector3.Distance(nearestEnemy, GameManager.Player.transform.position) * 0.25f);
        }

        // Next, we refine our goalPosition by taking into account our target's current velocity.
        // This will make the camera slightly look ahead to wherever the character is going.

        // First assume there is no velocity.
        // This is so if the camera's target is not a Rigidbody, it won't do any look-ahead calculations because everything will be zero.
        Vector3 targetVelocity = Vector3.zero;

        // If we find a Rigidbody on the target, that means we can access a velocity!
        if (TargetRigidbody)
        {
            targetVelocity = TargetRigidbody.velocity;
        }


        // If the target has a velocity, we use that velocity
        if (TargetAnimator)
        {
            targetVelocity = TargetAnimator.Velocity;
        }


        // Estimate what the target's position will be in velocityLookAhead seconds (position = velocity * time).
        Vector3 lookAhead = targetVelocity;

        lookAhead.x *= velocityLookAheadX;
        lookAhead.y *= velocityLookAheadY;

        // We clamp the lookAhead vector to some sane values so that the target doesn't go offscreen.
        // This calculation could be more advanced (lengthy), taking into account the target's viewport position,
        // but this works pretty well in practice.
        lookAhead.x = Mathf.Clamp(lookAhead.x, -maxLookAhead.x, maxLookAhead.x);
        lookAhead.y = Mathf.Clamp(lookAhead.y, -maxLookAhead.y, maxLookAhead.y);
        // We never want to take z velocity into account as this is 2D.  Just make sure it's zero.
        lookAhead.z = 0.0f;

        // We want to make sure our lookahead accounts for how zoomed in the camera is
        lookAhead *= distanceModifier;

        // Stop looking ahead if we tagged it to false
        if (TargetAnimator != null && TargetAnimator.CurrentState.IsTag("NoLookAhead"))
        {
            lookAhead = Vector3.zero;
        }


        // Now add in our lookAhead calculation.  Our camera following is now a bit better!
        goalPosition += lookAhead;

        // Shake the camera if told
        if (_shakeEffect != null)
        {
            if (!_shakeEffect.IsDone)
            {
                goalPosition += _shakeEffect.Shake(elapsedTime);
            }
            else
            {
                _shakeEffect = null;
            }
        }

        // We will also make it so that the positions beyond the level boundaries are never seen.
        Vector3 clampOffset = Vector3.zero;

        // Temporarily set the camera to the goal position so we can test positions for clamping.
        // But first, save the previous position.
        Vector3 cameraPositionSave = transform.position;

        transform.position = goalPosition;

        // Get the target position in viewport space.  Viewport space is relative to the camera.
        // The bottom left is (0,0) and the upper right is (1,1)
        Vector3 targetViewportPosition = GetComponent <Camera>().WorldToViewportPoint(Target.position);

        // First clamp to the right and top.  After this we will clamp to the bottom and left, so it will override this
        // clamping if it needs to.  This only occurs if the level is really small so that the camera sees more than
        // the entire level at once.

        // What is the world position of the very upper right corner of the camera?
        Vector3 upperRightCameraInWorld = GetComponent <Camera>().ViewportToWorldPoint(new Vector3(1.0f, 1.0f, targetViewportPosition.z));

        // Find out how far outside the world the camera is right now.
        clampOffset.x = Mathf.Min(GameManager.Level.Boundaries.xMax - upperRightCameraInWorld.x, 0.0f);
        clampOffset.y = Mathf.Min((GameManager.Level.Boundaries.yMax - upperRightCameraInWorld.y), 0.0f);

        // Now we apply our clamping to our goalPosition.  Now our camera won't go past the right and top boundaries of the level!
        goalPosition += clampOffset;

        // Now we do basically the same thing, except clamp to the lower left of the level.  This will override any previous clamping
        // if the level is really small.  That way you'll for sure never see past the lower-left of the level, but if the camera is
        // zoomed out too far for the level size, you will see past the right or top of the level.

        transform.position = goalPosition;
        Vector3 lowerLeftCameraInWorld = GetComponent <Camera>().ViewportToWorldPoint(new Vector3(0.0f, 0.0f, targetViewportPosition.z));

        // Find out how far outside the world the camera is right now.
        clampOffset.x = Mathf.Max((GameManager.Level.Boundaries.xMin - lowerLeftCameraInWorld.x), 0.0f);
        clampOffset.y = Mathf.Max((GameManager.Level.Boundaries.yMin - lowerLeftCameraInWorld.y), 0.0f);

        // Now we apply our clamping to our goalPosition once again.  Now our camera won't go past the left and bottom boundaries of the level!
        goalPosition += clampOffset;

        // Now that we're done calling functions on the camera, we can set the position back to the saved position;
        transform.position = cameraPositionSave;


        return(goalPosition);
    }