psychtoolbox-3-common 3.0.11.20140816.dfsg1-1 / usr / share / psychtoolbox-3 / PsychDemos / DriftDemo2.m

function DriftDemo2(angle, cyclespersecond, f, drawmask, gratingsize)
% function DriftDemo2([angle=30][, cyclespersecond=1][, f=0.05][, drawmask=1][, gratingsize=400])
% ___________________________________________________________________
%
% Display an animated grating using the new Screen('DrawTexture') command.
% In Psychtoolbox 3, the  Screen('DrawTexture') replaces
% Screen('CopyWindow'). The demo will stop after roughly 20 seconds have
% passed or after the user hits a key.
%
% This demo illustrates how to draw an animated 2-D grating online by use of
% only one 1-D grating texture. We create one texture with a static cosine
% grating. In each successive frame we only draw a rectangular subregion of
% the texture onto the screen, basically showing the texture through
% an aperture. The subregion - and therefore our "aperture" is shifted each
% frame, so we create the impression of a moving grating.
%
% The demo also shows how to use alpha-blending for masking the grating
% with a gaussian transparency mask (a texture with transparency layer).
%
% And finally, we demonstrate rotated drawing, as well as how to emulate
% the old OS-9 'WaitBlanking' command with the new 'Flip' command.
%
% Optional parameters:
%
% angle = Angle of the grating with respect to the vertical direction.
% cyclespersecond = Speed of grating in cycles per second.
% f = Frequency of grating in cycles per pixel.
% drawmask = If set to 1, a gaussian aperture is drawn over the grating.
% gratingsize = Visible size of grating in screen pixels.
%
% CopyWindow vs. DrawTexture:
%
% In the OS 9 Psychtoolbox, Screen ('CopyWindow") was used for all
% time-critical display of images, in particular for display of the movie
% frames in animated stimuli. In contrast, Screen('DrawTexture') should not
% be used for display of all graphic elements,  but only for  display of
% MATLAB matrices.  For all other graphical elements, such as lines,  rectangles,
% and ovals we recommend that these be drawn directly to the  display
% window during the animation rather than rendered to offscreen  windows
% prior to the animation.
%
% _________________________________________________________________________
% 
% see also: PsychDemos, MovieDemo

% HISTORY
%  6/7/05    mk     Adapted from Allen Ingling's DriftDemoOSX.m
%  2/28/09   mk     Updated with small fixes and enhancements + additional comments.

if nargin < 5
    gratingsize = [];
end

if isempty(gratingsize)
    % By default the visible grating is 400 pixels by 400 pixels in size:
    gratingsize = 400;
end

if nargin < 4
    drawmask = [];
end

if isempty(drawmask)
    % By default, we mask the grating by a gaussian transparency mask:
    drawmask=1;
end;

if nargin < 3
    f = [];
end

if isempty(f)
    % Grating cycles/pixel: By default 0.05 cycles per pixel.
    f=0.05;
end;

if nargin < 2
    cyclespersecond = [];
end

if isempty(cyclespersecond)
    % Speed of grating in cycles per second: 1 cycle per second by default.
    cyclespersecond=1;
end;

if nargin < 1
    angle = [];
end

if isempty(angle)
    % Angle of the grating: We default to 30 degrees.
    angle=30;
end;

movieDurationSecs=20;   % Abort demo after 20 seconds.

% Define Half-Size of the grating image.
texsize=gratingsize / 2;

% Screen('Preference', 'SkipSyncTests', 1);

try
	% This script calls Psychtoolbox commands available only in OpenGL-based 
	% versions of the Psychtoolbox. (So far, the OS X Psychtoolbox is the
	% only OpenGL-base Psychtoolbox.)  The Psychtoolbox command AssertPsychOpenGL will issue
	% an error message if someone tries to execute this script on a computer without
	% an OpenGL Psychtoolbox
	AssertOpenGL;
	
	% Get the list of screens and choose the one with the highest screen number.
	% Screen 0 is, by definition, the display with the menu bar. Often when 
	% two monitors are connected the one without the menu bar is used as 
	% the stimulus display.  Chosing the display with the highest dislay number is 
	% a best guess about where you want the stimulus displayed.  
	screens=Screen('Screens');
	screenNumber=max(screens);
	
    % Find the color values which correspond to white and black: Usually
	% black is always 0 and white 255, but this rule is not true if one of
	% the high precision framebuffer modes is enabled via the
	% PsychImaging() commmand, so we query the true values via the
	% functions WhiteIndex and BlackIndex:
	white=WhiteIndex(screenNumber);
	black=BlackIndex(screenNumber);
    
    % Round gray to integral number, to avoid roundoff artifacts with some
    % graphics cards:
	gray=round((white+black)/2);

    % This makes sure that on floating point framebuffers we still get a
    % well defined gray. It isn't strictly neccessary in this demo:
    if gray == white
		gray=white / 2;
    end
    
    % Contrast 'inc'rement range for given white and gray values:
	inc=white-gray;

    % Open a double buffered fullscreen window and set default background
	% color to gray:
	[w screenRect]=Screen('OpenWindow',screenNumber, gray);
    
    if drawmask
        % Enable alpha blending for proper combination of the gaussian aperture
        % with the drifting sine grating:
        Screen('BlendFunction', w, GL_SRC_ALPHA, GL_ONE_MINUS_SRC_ALPHA);
    end
    
    % Calculate parameters of the grating:
    
    % First we compute pixels per cycle, rounded up to full pixels, as we
    % need this to create a grating of proper size below:
    p=ceil(1/f);
    
    % Also need frequency in radians:
    fr=f*2*pi;
    
    % This is the visible size of the grating. It is twice the half-width
    % of the texture plus one pixel to make sure it has an odd number of
    % pixels and is therefore symmetric around the center of the texture:
    visiblesize=2*texsize+1;

    % Create one single static grating image:
    %
    % We only need a texture with a single row of pixels(i.e. 1 pixel in height) to
    % define the whole grating! If the 'srcRect' in the 'Drawtexture' call
    % below is "higher" than that (i.e. visibleSize >> 1), the GPU will
    % automatically replicate pixel rows. This 1 pixel height saves memory
    % and memory bandwith, ie. it is potentially faster on some GPUs.
    %
    % However it does need 2 * texsize + p columns, i.e. the visible size
    % of the grating extended by the length of 1 period (repetition) of the
    % sine-wave in pixels 'p':
    x = meshgrid(-texsize:texsize + p, 1);
    
    % Compute actual cosine grating:
    grating=gray + inc*cos(fr*x);

    % Store 1-D single row grating in texture:
    gratingtex=Screen('MakeTexture', w, grating);

    % Create a single gaussian transparency mask and store it to a texture:
    % The mask must have the same size as the visible size of the grating
    % to fully cover it. Here we must define it in 2 dimensions and can't
    % get easily away with one single row of pixels.
    %
    % We create a  two-layer texture: One unused luminance channel which we
    % just fill with the same color as the background color of the screen
    % 'gray'. The transparency (aka alpha) channel is filled with a
    % gaussian (exp()) aperture mask:
    mask=ones(2*texsize+1, 2*texsize+1, 2) * gray;
    [x,y]=meshgrid(-1*texsize:1*texsize,-1*texsize:1*texsize);
    mask(:, :, 2)=white * (1 - exp(-((x/90).^2)-((y/90).^2)));
    masktex=Screen('MakeTexture', w, mask);

    % Query maximum useable priorityLevel on this system:
	priorityLevel=MaxPriority(w); %#ok<NASGU>

    % We don't use Priority() in order to not accidentally overload older
    % machines that can't handle a redraw every 40 ms. If your machine is
    % fast enough, uncomment this to get more accurate timing.
    %Priority(priorityLevel);
    
    % Definition of the drawn rectangle on the screen:
    % Compute it to  be the visible size of the grating, centered on the
    % screen:
    dstRect=[0 0 visiblesize visiblesize];
    dstRect=CenterRect(dstRect, screenRect);

    % Query duration of one monitor refresh interval:
    ifi=Screen('GetFlipInterval', w);
    
    % Translate that into the amount of seconds to wait between screen
    % redraws/updates:
    
    % waitframes = 1 means: Redraw every monitor refresh. If your GPU is
    % not fast enough to do this, you can increment this to only redraw
    % every n'th refresh. All animation paramters will adapt to still
    % provide the proper grating. However, if you have a fine grating
    % drifting at a high speed, the refresh rate must exceed that
    % "effective" grating speed to avoid aliasing artifacts in time, i.e.,
    % to make sure to satisfy the constraints of the sampling theorem
    % (See Wikipedia: "Nyquist?Shannon sampling theorem" for a starter, if
    % you don't know what this means):
    waitframes = 1;
    
    % Translate frames into seconds for screen update interval:
    waitduration = waitframes * ifi;
    
    % Recompute p, this time without the ceil() operation from above.
    % Otherwise we will get wrong drift speed due to rounding errors!
    p=1/f;  % pixels/cycle    

    % Translate requested speed of the grating (in cycles per second) into
    % a shift value in "pixels per frame", for given waitduration: This is
    % the amount of pixels to shift our srcRect "aperture" in horizontal
    % directionat each redraw:
    shiftperframe= cyclespersecond * p * waitduration;

    % Perform initial Flip to sync us to the VBL and for getting an initial
    % VBL-Timestamp as timing baseline for our redraw loop:
    vbl=Screen('Flip', w);

    % We run at most 'movieDurationSecs' seconds if user doesn't abort via keypress.
    vblendtime = vbl + movieDurationSecs;
    i=0;
    
    % Animationloop:
    while(vbl < vblendtime)

        % Shift the grating by "shiftperframe" pixels per frame:
        % the mod'ulo operation makes sure that our "aperture" will snap
        % back to the beginning of the grating, once the border is reached.
        % Fractional values of 'xoffset' are fine here. The GPU will
        % perform proper interpolation of color values in the grating
        % texture image to draw a grating that corresponds as closely as
        % technical possible to that fractional 'xoffset'. GPU's use
        % bilinear interpolation whose accuracy depends on the GPU at hand.
        % Consumer ATI hardware usually resolves 1/64 of a pixel, whereas
        % consumer NVidia hardware usually resolves 1/256 of a pixel. You
        % can run the script "DriftTexturePrecisionTest" to test your
        % hardware...
        xoffset = mod(i*shiftperframe,p);
        i=i+1;
        
        % Define shifted srcRect that cuts out the properly shifted rectangular
        % area from the texture: We cut out the range 0 to visiblesize in
        % the vertical direction although the texture is only 1 pixel in
        % height! This works because the hardware will automatically
        % replicate pixels in one dimension if we exceed the real borders
        % of the stored texture. This allows us to save storage space here,
        % as our 2-D grating is essentially only defined in 1-D:
        srcRect=[xoffset 0 xoffset + visiblesize visiblesize];
        
        % Draw grating texture, rotated by "angle":
        Screen('DrawTexture', w, gratingtex, srcRect, dstRect, angle);

        if drawmask==1
            % Draw gaussian mask over grating:
            Screen('DrawTexture', w, masktex, [0 0 visiblesize visiblesize], dstRect, angle);
        end;

        % Flip 'waitframes' monitor refresh intervals after last redraw.
        % Providing this 'when' timestamp allows for optimal timing
        % precision in stimulus onset, a stable animation framerate and at
        % the same time allows the built-in "skipped frames" detector to
        % work optimally and report skipped frames due to hardware
        % overload:
        vbl = Screen('Flip', w, vbl + (waitframes - 0.5) * ifi);

        % Abort demo if any key is pressed:
        if KbCheck
            break;
        end;
    end;

    % Restore normal priority scheduling in case something else was set
    % before:
    Priority(0);
	
	%The same commands wich close onscreen and offscreen windows also close
	%textures.
	Screen('CloseAll');

catch
    %this "catch" section executes in case of an error in the "try" section
    %above.  Importantly, it closes the onscreen window if its open.
    Screen('CloseAll');
    Priority(0);
    psychrethrow(psychlasterror);
end %try..catch..

% We're done!
return;