Datasets:

benzlxs
/

temp_backup

	function [gist, param] = LMgist(D, HOMEIMAGES, param, HOMEGIST)
	%
	% [gist, param] = LMgist(D, HOMEIMAGES, param);
	% [gist, param] = LMgist(filename, HOMEIMAGES, param);
	% [gist, param] = LMgist(filename, HOMEIMAGES, param, HOMEGIST);
	%
	% For a set of images:
	% gist = LMgist(img, [], param);
	%
	% When calling LMgist with a fourth argument it will store the gists in a
	% new folder structure mirroring the folder structure of the images. Then,
	% when called again, if the gist files already exist, it will just read
	% them without recomputing them:
	%
	% [gist, param] = LMgist(filename, HOMEIMAGES, param, HOMEGIST);
	% [gist, param] = LMgist(D, HOMEIMAGES, param, HOMEGIST);
	%
	%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
	% Modeling the shape of the scene: a holistic representation of the spatial envelope
	% Aude Oliva, Antonio Torralba
	% International Journal of Computer Vision, Vol. 42(3): 145-175, 2001.

	if nargin==4
	precomputed = 1;
	% get list of folders and create non-existing ones
	%listoffolders = {D(:).annotation.folder};

	%for i = 1:length(D);
	% f{i} = D(i).annotation.folder;
	%end
	%[categories,b,class] = unique(f);
	else
	precomputed = 0;
	HOMEGIST = '';
	end


	param.boundaryExtension = 32; % number of pixels to pad

	if nargin<3
	% Default parameters
	param.imageSize = 128;
	param.orientationsPerScale = [8 8 8 8];
	param.numberBlocks = 4;
	param.fc_prefilt = 4;
	param.G = createGabor(param.orientationsPerScale, param.imageSize1+2*param.boundaryExtension);
	else
	if ~isfield(param, 'G')
	param.G = createGabor(param.orientationsPerScale, param.imageSize+2*param.boundaryExtension);
	end
	end

	% Precompute filter transfert functions (only need to do this once, unless
	% image size is changes):
	Nfeatures = size(param.G,3)*param.numberBlocks^2;

	if isstruct(D)
	% [gist, param] = LMgist(D, HOMEIMAGES, param);
	Nscenes = length(D);
	typeD = 1;
	end
	if iscell(D)
	% [gist, param] = LMgist(filename, HOMEIMAGES, param);
	Nscenes = length(D);
	typeD = 2;
	end
	if isnumeric(D)
	% [gist, param] = LMgist(img, HOMEIMAGES, param);
	Nscenes = size(D,4);
	typeD = 3;
	end

	% Loop: Compute gist features for all scenes
	gist = zeros([Nscenes Nfeatures], 'single');
	for n = 1:Nscenes
	g = [];
	todo = 1;

	% if gist has already been computed, just read the file
	if precomputed==1
	filegist = fullfile(HOMEGIST, D(n).annotation.folder, [D(n).annotation.filename(1:end-4) '.mat']);
	if exist(filegist, 'file')
	load(filegist, 'g');
	todo = 0;
	end
	end

	% otherwise compute gist
	if todo==1
	disp([n Nscenes])

	% load image
	try
	switch typeD
	case 1
	img = LMimread(D, n, HOMEIMAGES);
	case 2
	img = imread(fullfile(HOMEIMAGES, D{n}));
	case 3
	img = D(:,:,:,n);
	end
	catch
	disp(D(n).annotation.folder)
	disp(D(n).annotation.filename)
	rethrow(lasterror)
	end

	img = single(img); %jhhays
	if(size(img,3) > 1) %jhhays
	img = rgb2gray(img);
	end

	% resize and crop image to make it square
	%img = imresizecrop(img, param.imageSize, 'bilinear');
	img = imresize(img, param.imageSize, 'bilinear'); %jhhays

	% scale intensities to be in the range [0 255]
	img = img-min(img(:));
	img = 255*img/max(img(:));

	if Nscenes>1
	imshow(uint8(img))
	title(n)
	end

	% prefiltering: local contrast scaling
	%output = prefilt(img, param.fc_prefilt);
	output = img;

	% get gist:
	g = gistGabor(output, param);

	% save gist if a HOMEGIST file is provided
	if precomputed
	mkdir(fullfile(HOMEGIST, D(n).annotation.folder))
	save (filegist, 'g')
	end
	end

	gist(n,:) = g;
	drawnow
	end

	function output = prefilt(img, fc)
	% ima = prefilt(img, fc);
	% fc = 4 (default)
	%
	% Input images are double in the range [0, 255];
	% You can also input a block of images [ncols nrows 3 Nimages]
	%
	% For color images, normalization is done by dividing by the local
	% luminance variance.

	if nargin == 1
	fc = 4; % 4 cycles/image
	end

	w = 5;
	s1 = fc/sqrt(log(2));

	% Pad images to reduce boundary artifacts
	img = log(img+1);
	img = padarray(img, [w w], 'symmetric');
	[sn, sm, c, N] = size(img);
	n = max([sn sm]);
	n = n + mod(n,2);
	img = padarray(img, [n-sn n-sm], 'symmetric','post');

	% Filter
	[fx, fy] = meshgrid(-n/2:n/2-1);
	gf = fftshift(exp(-(fx.^2+fy.^2)/(s1^2)));
	gf = repmat(gf, [1 1 c N]);

	% Whitening
	output = img - real(ifft2(fft2(img).*gf));
	clear img

	% Local contrast normalization
	localstd = repmat(sqrt(abs(ifft2(fft2(mean(output,3).^2).*gf(:,:,1,:)))), [1 1 c 1]);
	output = output./(.2+localstd);

	% Crop output to have same size than the input
	output = output(w+1:sn-w, w+1:sm-w,:,:);



	function g = gistGabor(img, param)
	%
	% Input:
	% img = input image (it can be a block: [nrows, ncols, c, Nimages])
	% param.w = number of windows (w*w)
	% param.G = precomputed transfer functions
	%
	% Output:
	% g: are the global features = [Nfeatures Nimages],
	% Nfeatures = wwNfilters*c

	img = single(img);

	w = param.numberBlocks;
	G = param.G;
	be = param.boundaryExtension;

	if ndims(img)==2
	c = 1;
	N = 1;
	[nrows ncols c] = size(img);
	end
	if ndims(img)==3
	[nrows ncols c] = size(img);
	N = c;
	end
	if ndims(img)==4
	[nrows ncols c N] = size(img);
	img = reshape(img, [nrows ncols c*N]);
	N = c*N;
	end

	[ny nx Nfilters] = size(G);
	W = w*w;
	g = zeros([W*Nfilters N]);

	% pad image
	img = padarray(img, [be be], 'symmetric');

	img = single(fft2(img));
	k=0;
	for n = 1:Nfilters
	ig = abs(ifft2(img.*repmat(G(:,:,n), [1 1 N])));
	ig = ig(be+1:ny-be, be+1:nx-be, :);

	v = downN(ig, w);
	g(k+1:k+W,:) = reshape(v, [W N]);
	k = k + W;
	drawnow
	end

	if c == 3
	% If the input was a color image, then reshape 'g' so that one column
	% is one images output:
	g = reshape(g, [size(g,1)*3 size(g,2)/3]);
	end


	function y=downN(x, N)
	%
	% averaging over non-overlapping square image blocks
	%
	% Input
	% x = [nrows ncols nchanels]
	% Output
	% y = [N N nchanels]

	nx = fix(linspace(0,size(x,1),N+1));
	ny = fix(linspace(0,size(x,2),N+1));
	y = zeros(N, N, size(x,3));
	for xx=1:N
	for yy=1:N
	v=mean(mean(x(nx(xx)+1:nx(xx+1), ny(yy)+1:ny(yy+1),:),1),2);
	y(xx,yy,:)=v(:);
	end
	end