// Helper routine for creation of a stereo eye.
private void CreateEye(GvrViewer.Eye eye)
{
string nm = name + (eye == GvrViewer.Eye.Left ? " Left" : " Right");
GameObject go = new GameObject(nm);
go.transform.SetParent(transform, false);
go.AddComponent <Camera>().enabled = false;
var GvrEye = go.AddComponent <GvrEye>();
GvrEye.eye = eye;
GvrEye.CopyCameraAndMakeSideBySide(this);
}
public Pose3D GetEyePose(GvrViewer.Eye eye)
{
switch (eye)
{
case GvrViewer.Eye.Left:
return(leftEyePose);
case GvrViewer.Eye.Right:
return(rightEyePose);
default:
return(null);
}
}
// Helper routine for creation of a stereo eye.
private void CreateEye(GvrViewer.Eye eye, string camName)
{
string nm = name + (eye == GvrViewer.Eye.Left ? " Left" : " Right");
GameObject go = new GameObject(nm);
//GameObject go = GameObject.FindWithTag(camName);
go.transform.SetParent(transform, false);
go.AddComponent <Camera>().enabled = false;
go.AddComponent <UnityStandardAssets.CinematicEffects.Bloom> ();
var GvrEye = go.AddComponent <GvrEye>();
GvrEye.eye = eye;
GvrEye.CopyCameraAndMakeSideBySide(this);
}
public Rect GetViewport(GvrViewer.Eye eye,
GvrViewer.Distortion distortion = GvrViewer.Distortion.Distorted)
{
switch (eye)
{
case GvrViewer.Eye.Left:
return(distortion == GvrViewer.Distortion.Distorted ?
leftEyeDistortedViewport : leftEyeUndistortedViewport);
case GvrViewer.Eye.Right:
return(distortion == GvrViewer.Distortion.Distorted ?
rightEyeDistortedViewport : rightEyeUndistortedViewport);
default:
return(new Rect());
}
}
public Matrix4x4 GetProjection(GvrViewer.Eye eye,
GvrViewer.Distortion distortion = GvrViewer.Distortion.Distorted)
{
switch (eye)
{
case GvrViewer.Eye.Left:
return(distortion == GvrViewer.Distortion.Distorted ?
leftEyeDistortedProjection : leftEyeUndistortedProjection);
case GvrViewer.Eye.Right:
return(distortion == GvrViewer.Distortion.Distorted ?
rightEyeDistortedProjection : rightEyeUndistortedProjection);
default:
return(Matrix4x4.identity);
}
}
/// Compute the position of one of the stereo eye cameras. Accounts for both
/// FOV matching and stereo comfort, if those features are enabled. The input is
/// the [1,1] entry of the eye camera's projection matrix, representing the vertical
/// field of view, and the overall scale being applied to the Z axis. Returns the
/// position of the stereo eye camera in local coordinates.
public Vector3 ComputeStereoEyePosition(GvrViewer.Eye eye, float proj11, float zScale)
{
if (centerOfInterest == null || !centerOfInterest.gameObject.activeInHierarchy)
{
return(GvrViewer.Instance.EyePose(eye).Position *stereoMultiplier);
}
// Distance of COI relative to head.
float distance = centerOfInterest != null ?
(centerOfInterest.position - transform.position).magnitude : 0;
// Size of the COI, clamped to [0..distance] for mathematical sanity in following equations.
float radius = Mathf.Clamp(radiusOfInterest, 0, distance);
// Move the eye so that COI has about the same size onscreen as in the mono camera FOV.
// The radius affects the horizon location, which is where the screen-size matching has to
// occur.
float scale = proj11 / cam.projectionMatrix[1, 1]; // vertical FOV
float offset =
Mathf.Sqrt(radius * radius + (distance * distance - radius * radius) * scale * scale);
float eyeOffset = (distance - offset) * Mathf.Clamp01(matchMonoFOV) / zScale;
float ipdScale = stereoMultiplier;
if (checkStereoComfort)
{
// Manage IPD scale based on the distance to the COI.
float minComfort = GvrViewer.Instance.ComfortableViewingRange.x;
float maxComfort = GvrViewer.Instance.ComfortableViewingRange.y;
if (minComfort < maxComfort) // Sanity check.
// If closer than the minimum comfort distance, IPD is scaled down.
// If farther than the maximum comfort distance, IPD is scaled up.
// The result is that parallax is clamped within a reasonable range.
{
float minDistance = (distance - radius) / zScale - eyeOffset;
ipdScale *= minDistance / Mathf.Clamp(minDistance, minComfort, maxComfort);
}
}
return(ipdScale * GvrViewer.Instance.EyePose(eye).Position + eyeOffset * Vector3.forward);
}