# How to get world coordinates from screen coordinates in Vispy

I am not sure how to get from screen coordinates to world coordinates. I am using VisPy and I would like to implement ray tracing and picking ability in 3D.

I prepared some code based on a cube example. The code below sends a crude ray through the screen by changing z value and prints 3D coordinates (in ''on_mouse_press '' method). However the results are not correct. If i click top right corner of the cube somewhere along the ray should be printed (3,3,3), but it's not. Can anybody help me with this?

``````#!/usr/bin/env python
# -*- coding: utf-8 -*-
# vispy: gallery 50
"""
This example shows how to display 3D objects.
You should see a colored outlined spinning cube.
"""

import numpy as np
from vispy import app, gloo
from vispy.util.transforms import perspective, translate, rotate

vert = """
// Uniforms
// ------------------------------------
uniform   mat4 u_model;
uniform   mat4 u_view;
uniform   mat4 u_projection;
uniform   vec4 u_color;

// Attributes
// ------------------------------------
attribute vec3 a_position;
attribute vec4 a_color;
attribute vec3 a_normal;

// Varying
// ------------------------------------
varying vec4 v_color;

void main()
{
v_color = a_color * u_color;
gl_Position = u_projection * u_view * u_model * vec4(a_position,1.0);
}
"""

frag = """
uniform mat4 u_model;
uniform mat4 u_view;
uniform mat4 u_normal;

uniform vec3 u_light_intensity;
uniform vec3 u_light_position;

varying vec3 v_position;
varying vec3 v_normal;
varying vec4 v_color;

void main()
{
gl_FragColor = v_color;
}
"""

# -----------------------------------------------------------------------------
def cube(num_of_cubes):
"""
Build vertices for a colored cube.

V  is the vertices
I1 is the indices for a filled cube (use with GL_TRIANGLES)
I2 is the indices for an outline cube (use with GL_LINES)
"""

for i in range(0,num_of_cubes):
# Vertices positions
v = np.array([[1, 1, 1], [-1, 1, 1], [-1, -1, 1], [1, -1, 1],
[1, -1, -1], [1, 1, -1], [-1, 1, -1], [-1, -1, -1]],dtype=np.float32)

v[:,0]=v[:,0]+2.
v[:,1]=v[:,1]+2.
v[:,2]=v[:,2]+2.

# Face Normals
n =np.array([[0, 0, 1], [1, 0, 0], [0, 1, 0],
[-1, 0, 1], [0, -1, 0], [0, 0, -1]],dtype=np.float32)
# Vertice colors
c = np.array([[0, 0, 1, 1], [0, 0, 1, 1], [0, 0, 1, 1], [0, 0, 1, 1],
[0, 0, 1, 1], [0, 0, 1, 1], [0, 0, 1, 1], [0, 0, 1, 1]],dtype=np.float32)

V_aux = np.array([(v[0], n[0], c[0]), (v[1], n[0], c[1]),
(v[2], n[0], c[2]), (v[3], n[0], c[3]),
(v[0], n[1], c[0]), (v[3], n[1], c[3]),
(v[4], n[1], c[4]), (v[5], n[1], c[5]),
(v[0], n[2], c[0]), (v[5], n[2], c[5]),
(v[6], n[2], c[6]), (v[1], n[2], c[1]),
(v[1], n[3], c[1]), (v[6], n[3], c[6]),
(v[7], n[3], c[7]), (v[2], n[3], c[2]),
(v[7], n[4], c[7]), (v[4], n[4], c[4]),
(v[3], n[4], c[3]), (v[2], n[4], c[2]),
(v[4], n[5], c[4]), (v[7], n[5], c[7]),
(v[6], n[5], c[6]), (v[5], n[5], c[5])]
)
I1_aux = np.resize(np.array([0, 1, 2, 0, 2, 3], dtype=np.uint32), 6 * (2 * 3))
I1_aux += np.repeat(4 * np.arange(2 * 3, dtype=np.uint32), 6)

I2_aux = np.resize(
np.array([0, 1, 1, 2, 2, 3, 3, 0], dtype=np.uint32), 6 * (2 * 4))
I2_aux += np.repeat(4 * np.arange(6, dtype=np.uint32), 8)

if i==0:
V=V_aux
I1=I1_aux
I2=I2_aux
else:
V=np.vstack((V,V_aux))
I1=np.vstack((I1,I1_aux+i*24))
I2=np.vstack((I2,I2_aux+i*24))

return V, I1, I2

# -----------------------------------------------------------------------------
class Canvas(app.Canvas):

def __init__(self):
app.Canvas.__init__(self, keys='interactive', size=(800, 600))

num_of_cubes=1 #number of cubes to draw
self.V, self.filled, self.outline = cube(num_of_cubes)

self.store_pos=np.array((0,0)) #for mouse interaction

self.vert_data=np.vstack(self.V[:,0])
self.V_buf=np.vstack(self.V[:,0])
self.V_buf.dtype=[('a_position',np.float32,3)]
self.vert_buf=gloo.VertexBuffer(self.V_buf)

self.N_buf=np.vstack(self.V[:,1])
self.N_buf.dtype=[('a_normal',np.float32,3)]
self.norm_buf=gloo.VertexBuffer(self.N_buf)

self.C_buf=np.vstack(self.V[:,2])
self.C_buf.dtype=[('a_color',np.float32,4)]
self.colo_buf=gloo.VertexBuffer(self.C_buf)

self.filled_buf=gloo.IndexBuffer(self.filled.flatten())
self.outline_buf=gloo.IndexBuffer(self.outline.flatten())

self.program = gloo.Program(vert, frag)
self.translate = 1

#self.vert_buf=gloo.VertexBuffer(self.vertices.flatten())
self.program.bind(self.vert_buf)
self.program.bind(self.norm_buf)
self.program.bind(self.colo_buf)

self.view = translate((0, 0, -10))
self.model = np.eye(4, dtype=np.float32)

gloo.set_viewport(0, 0, self.physical_size[0], self.physical_size[1])
self.projection = perspective(45.0, self.size[0] /
float(self.size[1]), 2.0, 10.0)

self.program['u_projection'] = self.projection

self.program['u_model'] = self.model
self.program['u_view'] = self.view

self.theta = 0
self.phi = 0

gloo.set_clear_color('white')
gloo.set_state('opaque')
gloo.set_polygon_offset(1, 1)

self._timer = app.Timer('auto', connect=self.on_timer, start=True)

self.show()
self.t=0

# ---------------------------------
def on_timer(self, event):
self.update()

# ---------------------------------
def print_mouse_event(self, event, what):
modifiers = ', '.join([key.name for key in event.modifiers])
print('%s - pos: %r, button: %s, modifiers: %s, delta: %r' %
(what, event.pos, event.button, modifiers, event.delta))

def on_mouse_press(self, event):
self.print_mouse_event(event, 'Mouse press')

#convert to NDC
left=event.pos[0]*2/self.size[0]-1
bottom=(self.size[1]-event.pos[1])*2/self.size[1]-1

z_clip=np.linspace(-1.,1.,100)
for val in z_clip:
aux=np.dot(np.dot(np.linalg.inv(self.view),np.linalg.inv(self.projection)),np.array((left,bottom,val,1.)))
pos3d=aux/aux[3]
print(pos3d)

def on_mouse_wheel(self, event):

self.translate -= event.delta[1]
self.translate = max(-1, self.translate)
self.view[3,2]=-self.translate

self.program['u_view'] = self.view
self.update()

def on_draw(self, event):
gloo.clear()

# Filled cube

gloo.set_state(blend=False, depth_test=True, polygon_offset_fill=True)
self.program['u_color'] = 1, 0, 1, 1

self.program.draw('triangles', self.filled_buf)

# Outline
self.program['u_color'] = 0, 0, 0, 1

self.program.draw('lines', self.outline_buf)

# -----------------------------------------------------------------------------
if __name__ == '__main__':
c = Canvas()
app.run()
``````

A clicked point on the screen maps to a line in your scene.

The object in `view.scene.transform` represents the mapping between scene and screen coordinates. `.map(points)` will transform points from scene to screen. `.imap(points)` maps from screen coordinates back to world coordinates.

To get the line your screen point corresponds to. You can imap a point on the screen, and another point offset from the screen in z:

``````def get_view_axis_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)
return p0[0:3],p1[0:3] # 2 point representation of view axis in 3d scene coordinates
``````

I adapted it be a bit closer to what you want; you need to replace screen_center with the clicked point. Note, I did this for orthogonal projection; think it works for perspective too but haven't tested it.

• It's not exactly what I was looking for but it helped. Commented Nov 2, 2017 at 18:03

I am not sure about the actual code required to do this, but conceptually this is how I would go about solving this.

When clicking a pixel on the screen, you are essentially choosing an X,Y spot that is considered your viewport camera, which means that the rest of the transforms and rotation that you need is found from the camera.

So really, get the positional and rotational data of the camera, add the relative x,y transform from your viewport, then draw a trace that uses the forward vector from your position that points linearly towards the point that you want. Then when that trace hits, get that object.

If you don't add the relative transform, it would be getting the trace from the center of your viewport, so since the rotation data for all points in the viewport is the same, you just need to add the difference in x,y between where you clicked from the center x,y.

Also, remember that for the viewport, "X" is really the trig value of your yaw,pitch,roll (world) or just yaw,pitch(relative), and for "Y" its your Z axis.

I hope my explanation was clear, I also added this picture to further demonstrate the overview. Hope this helps!

Picture