# Get view direction relative to scene in vispy?

What is the cleanest way to get the view direction relative to your scene in vispy?

`view.scene.transform` contains a whole chain of transforms:

``````In [88]: view.scene.transform
Out[88]:
<ChainTransform [<STTransform scale=[ 960. -540.    1.    1.] translate=[ 960.  540.    0.    0.] at 0x139757309901840>,
MatrixTransform(matrix=[[26.44507, 0.0, 0.0, 0.0],
[0.0, 47.013458, 0.0, 0.0],
[0.0, 0.0, -1e-06, 0.0],
[-0.0, -0.0, -0.0, 1.0]] at 0x7f1bc8d526d0),
<Inverse of '<ChainTransform [MatrixTransform(matrix=[[0.64390097845776273, -0.18562251042644023, -0.74225050593726238, 0.0],\n                        [0.74851597030808681, 0.35377196489238, 0.56086472437650059, 0.0],\n                        [0.15847830177938896, -0.91672770247177038, 0.36673552784799862, 0.0],\n                        [0.002241050448888897, 0.013296952664039196, 0.015024409939918581, 1.0]] at 0x7f1bc8c81710)] at 0x7f1bc8cb7e90>'>] at 0x7f1bc8e75490>
``````

I could write something to parse lists of transforms of varous types and compose them, and extract the view direction from the composed transform, but I suspect I'm swimming upstream.

Vispy transformations have a `map` and `imap` function you can use to map coordinates between scene and screen coordinates in either direction. I used them on points and threw in a lot of assertions to be safe; there are probably simpler implementations. I tested this for orthographic projection. I ~think it will work for perspective projections too as long as the center of projection is in the middle of the screen.

``````def get_view_direction_in_scene_coordinates(view):
import numpy
tform=view.scene.transform
w,h = view.canvas.size
screen_center = numpy.array([w/2,h/2,0,1]) # in homogeneous screen coordinates
d1 = numpy.array([0,0,1,0]) # in homogeneous screen coordinates
point_in_front_of_screen_center = screen_center + d1 # in homogeneous screen coordinates
p1 = tform.imap(point_in_front_of_screen_center) # in homogeneous scene coordinates
p0 = tform.imap(screen_center) # in homogeneous screen coordinates
assert(abs(p1[3]-1.0) < 1e-5) # normalization necessary before subtraction
assert(abs(p0[3]-1.0) < 1e-5)
d2 = p1 - p0 # in homogeneous screen coordinates
assert(abs(d2[3])< 1e-5)
d3 = d2[0:3] # in 3D screen coordinates
d4 = d3 / numpy.linalg.norm(d3)
return d4
``````