/usr/share/psychtoolbox-3/PsychDemos/LinesDemo.m is in psychtoolbox-3-common 3.0.11.20131230.dfsg1-1build1.
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 99 100 101 102 103 104 105 106 107 108 109 110 111 112 113 114 115 116 117 118 119 120 121 122 123 124 125 126 127 128 129 130 131 132 133 134 135 136 137 138 139 140 141 142 143 144 145 146 147 148 149 150 151 152 153 154 155 156 157 158 159 160 161 | function LinesDemo
% Line motion demo using SCREEN('DrawLines') subfunction
% Derived from DotDemo, whose original author was Keith Schneider, 12/13/04
%
% Caution: This demo is a quick & dirty hack to get you started. It
% demonstrates a lot of inefficient techniques of how not to do this!!!
%HISTORY
%
% mm/dd/yy
% 12/03/06 Derived it from DotDemo. (MK)
AssertOpenGL;
try
% ------------------------
% set line field parameters
% ------------------------
nframes = 1000; % number of animation frames in loop
mon_width = 39; % horizontal dimension of viewable screen (cm)
v_dist = 60; % viewing distance (cm)
dot_speed = 2; % line speed (deg/sec)
ndots = 2000; % number of lines
max_d = 15; % maximum radius of annulus (degrees)
min_d = 1; % minumum
dot_w = 0.1; % width of line (deg)
fix_r = 0.15; % radius of fixation point (deg)
f_kill = 0.01; % fraction of lines to kill each frame (limited lifetime)
differentcolors =1; % Use a different color for each point if == 1. Use common color white if == 0.
differentsizes = 0; % Use different sizes for each point if >= 1. Use one common size if == 0.
waitframes = 1; % Show new line-images at each waitframes'th monitor refresh.
if differentsizes>0 % drawing large lines is a bit slower
ndots=round(ndots/5);
end
% ---------------
% open the screen
% ---------------
screens=Screen('Screens');
screenNumber=max(screens);
[w, rect] = Screen('OpenWindow', screenNumber, 0);
% Enable alpha blending with proper blend-function. We need it
% for drawing of smoothed points:
Screen('BlendFunction', w, GL_SRC_ALPHA, GL_ONE_MINUS_SRC_ALPHA);
[center(1), center(2)] = RectCenter(rect);
fps=Screen('FrameRate',w); % frames per second
ifi=Screen('GetFlipInterval', w);
if fps==0
fps=1/ifi;
end;
white = WhiteIndex(w);
HideCursor; % Hide the mouse cursor
% Do initial flip...
vbl=Screen('Flip', w);
% ---------------------------------------
% initialize line positions and velocities
% ---------------------------------------
ppd = pi * (rect(3)-rect(1)) / atan(mon_width/v_dist/2) / 360; % pixels per degree
pfs = dot_speed * ppd / fps; % line speed (pixels/frame)
s = dot_w * ppd; % line size (pixels)
fix_cord = [center-fix_r*ppd center+fix_r*ppd];
rmax = max_d * ppd; % maximum radius of annulus (pixels from center)
rmin = min_d * ppd; % minimum
r = rmax * sqrt(rand(ndots,1)); % r
r(r<rmin) = rmin;
t = 2*pi*rand(ndots,1); % theta polar coordinate
cs = [cos(t), sin(t)];
xy = [r r] .* cs; % line positions in Cartesian coordinates (pixels from center)
mdir = 2 * floor(rand(ndots,1)+0.5) - 1; % motion direction (in or out) for each line
dr = pfs * mdir; % change in radius per frame (pixels)
dxdy = [dr dr] .* cs; % change in x and y per frame (pixels)
% Create a vector with different colors for each single line, if
% requested:
if (differentcolors==1)
colvect = uint8(round(rand(3,ndots*2)*255));
else
colvect=white;
end;
% Create a vector with different point sizes for each single line, if
% requested:
if (differentsizes>0)
s=(1+rand(1, ndots)*(differentsizes-1))*s;
end;
xymatrix=zeros(2, ndots*2);
% --------------
% animation loop
% --------------
for i = 1:nframes
if (i>1)
Screen('FillOval', w, uint8(white), fix_cord); % draw fixation dot (flip erases it)
Screen('DrawLines', w, xymatrix, s, colvect, center,1); % change 1 to 0 to draw non anti-aliased lines.
Screen('DrawingFinished', w); % Tell PTB that no further drawing commands will follow before Screen('Flip')
end;
if KbCheck % break out of loop
break;
end;
oldxy = xy - 15*dxdy;
xy = xy + dxdy; % move lines
r = r + dr; % update polar coordinates too
% check to see which lines have gone beyond the borders of the
% annuli
r_out = find(r > rmax | r < rmin | rand(ndots,1) < f_kill); % lines to reposition
nout = length(r_out);
if nout
% choose new coordinates
r(r_out) = rmax * sqrt(rand(nout,1));
r(r<rmin) = rmin;
t(r_out) = 2*pi*(rand(nout,1));
% now convert the polar coordinates to Cartesian
cs(r_out,:) = [cos(t(r_out)), sin(t(r_out))];
xy(r_out,:) = [r(r_out) r(r_out)] .* cs(r_out,:);
% compute the new cartesian velocities
dxdy(r_out,:) = [dr(r_out) dr(r_out)] .* cs(r_out,:);
oldxy(r_out, :)= xy(r_out,:);
end;
% Set this 1 to 0 to test performance of slooow non-vectorized code:
if 1
% Vectorized synthesis of lines matrix for next frame:
xymatrix(:, 1:2:(1+(2*ndots-2))) = xy';
xymatrix(:, 2:2:(2+(2*ndots-2))) = oldxy';
else
% Slow synthesis of lines matrix for next frame:
% This is 10-13x slower on Matlab, 320x slower on Octave 3.2!
for j=0:ndots - 1
xymatrix(:, 1 + i*2) = transpose(xy(i+1, :));
xymatrix(:, 2 + i*2) = transpose(oldxy(i+1, :));
end
end
vbl=Screen('Flip', w, vbl + (waitframes-0.5)*ifi);
end;
ShowCursor
Screen('CloseAll');
catch
ShowCursor
Screen('CloseAll');
end
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