/usr/share/psychtoolbox-3/PsychDemos/DriftDemo4.m is in psychtoolbox-3-common 3.0.11.20140816.dfsg1-1.
This file is owned by root:root, with mode 0o644.
The actual contents of the file can be viewed below.
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60 61 62 63 64 65 66 67 68 69 70 71 72 73 74 75 76 77 78 79 80 81 82 83 84 85 86 87 88 89 90 91 92 93 94 95 96 97 98 99 100 101 102 103 104 105 106 107 108 109 110 111 112 113 114 115 116 117 118 119 120 121 122 123 124 125 126 127 128 129 130 131 132 133 | function DriftDemo4(angle, cyclespersecond, freq, gratingsize, internalRotation)
% function DriftDemo4([angle=0][, cyclespersecond=1][, freq=1/360][, gratingsize=360][, internalRotation=0])
% ___________________________________________________________________
%
% Display an animated grating, using the new Screen('DrawTexture') command.
% This demo demonstrates fast drawing of such a grating via use of procedural
% texture mapping. It only works on hardware with support for the GLSL
% shading language, vertex- and fragmentshaders. The demo ends if you press
% any key on the keyboard.
%
% The grating is not encoded into a texture, but instead a little algorithm - a
% procedural texture shader - is executed on the graphics processor (GPU)
% to compute the grating on-the-fly during drawing.
%
% This is very fast and efficient! All parameters of the grating can be
% changed dynamically. For a similar approach wrt. Gabors, check out
% ProceduralGaborDemo. For an extremely fast aproach for drawing many Gabor
% patches at once, check out ProceduralGarboriumDemo. That demo could be
% easily customized to draw many sine gratings by mixing code from that
% demo with setup code from this demo.
%
% Optional Parameters:
% 'angle' = Rotation angle of grating in degrees.
% 'internalRotation' = Shall the rectangular image patch be rotated
% (default), or the grating within the rectangular patch?
% gratingsize = Size of 2D grating patch in pixels.
% freq = Frequency of sine grating in cycles per pixel.
% cyclespersecond = Drift speed in cycles per second.
%
% History:
% 3/1/9 mk Written.
% Make sure this is running on OpenGL Psychtoolbox:
AssertOpenGL;
% Initial stimulus parameters for the grating patch:
if nargin < 5 || isempty(internalRotation)
internalRotation = 0;
end
if internalRotation
rotateMode = kPsychUseTextureMatrixForRotation;
else
rotateMode = [];
end
if nargin < 4 || isempty(gratingsize)
gratingsize = 360;
end
% res is the total size of the patch in x- and y- direction, i.e., the
% width and height of the mathematical support:
res = [gratingsize gratingsize];
if nargin < 3 || isempty(freq)
% Frequency of the grating in cycles per pixel: Here 0.01 cycles per pixel:
freq = 1/360;
end
if nargin < 2 || isempty(cyclespersecond)
cyclespersecond = 1;
end
if nargin < 1 || isempty(angle)
% Tilt angle of the grating:
angle = 0;
end
% Amplitude of the grating in units of absolute display intensity range: A
% setting of 0.5 means that the grating will extend over a range from -0.5
% up to 0.5, i.e., it will cover a total range of 1.0 == 100% of the total
% displayable range. As we select a background color and offset for the
% grating of 0.5 (== 50% nominal intensity == a nice neutral gray), this
% will extend the sinewaves values from 0 = total black in the minima of
% the sine wave up to 1 = maximum white in the maxima. Amplitudes of more
% than 0.5 don't make sense, as parts of the grating would lie outside the
% displayable range for your computers displays:
amplitude = 0.5;
% Choose screen with maximum id - the secondary display on a dual-display
% setup for display:
screenid = max(Screen('Screens'));
% Open a fullscreen onscreen window on that display, choose a background
% color of 128 = gray, i.e. 50% max intensity:
win = Screen('OpenWindow', screenid, 128);
% Make sure the GLSL shading language is supported:
AssertGLSL;
% Retrieve video redraw interval for later control of our animation timing:
ifi = Screen('GetFlipInterval', win);
% Phase is the phase shift in degrees (0-360 etc.)applied to the sine grating:
phase = 0;
% Compute increment of phase shift per redraw:
phaseincrement = (cyclespersecond * 360) * ifi;
% Build a procedural sine grating texture for a grating with a support of
% res(1) x res(2) pixels and a RGB color offset of 0.5 -- a 50% gray.
gratingtex = CreateProceduralSineGrating(win, res(1), res(2), [0.5 0.5 0.5 0.0]);
% Wait for release of all keys on keyboard, then sync us to retrace:
KbReleaseWait;
vbl = Screen('Flip', win);
% Animation loop: Repeats until keypress...
while ~KbCheck
% Update some grating animation parameters:
% Increment phase by 1 degree:
phase = phase + phaseincrement;
% Draw the grating, centered on the screen, with given rotation 'angle',
% sine grating 'phase' shift and amplitude, rotating via set
% 'rotateMode'. Note that we pad the last argument with a 4th
% component, which is 0. This is required, as this argument must be a
% vector with a number of components that is an integral multiple of 4,
% i.e. in our case it must have 4 components:
Screen('DrawTexture', win, gratingtex, [], [], angle, [], [], [], [], rotateMode, [phase, freq, amplitude, 0]);
% Show it at next retrace:
vbl = Screen('Flip', win, vbl + 0.5 * ifi);
end
% We're done. Close the window. This will also release all other ressources:
Screen('CloseAll');
% Bye bye!
return;
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