distinguishable_colors.m

function colors = distinguishable_colors(n_colors,bg,func)
% DISTINGUISHABLE_COLORS: pick colors that are maximally perceptually distinct
%
% When plotting a set of lines, you may want to distinguish them by color.
% By default, Matlab chooses a small set of colors and cycles among them,
% and so if you have more than a few lines there will be confusion about
% which line is which. To fix this problem, one would want to be able to
% pick a much larger set of distinct colors, where the number of colors
% equals or exceeds the number of lines you want to plot. Because our
% ability to distinguish among colors has limits, one should choose these
% colors to be "maximally perceptually distinguishable."
%
% This function generates a set of colors which are distinguishable
% by reference to the "Lab" color space, which more closely matches
% human color perception than RGB. Given an initial large list of possible
% colors, it iteratively chooses the entry in the list that is farthest (in
% Lab space) from all previously-chosen entries. While this "greedy"
% algorithm does not yield a global maximum, it is simple and efficient.
% Moreover, the sequence of colors is consistent no matter how many you
% request, which facilitates the users' ability to learn the color order
% and avoids major changes in the appearance of plots when adding or
% removing lines.
%
% Syntax:
%   colors = distinguishable_colors(n_colors)
% Specify the number of colors you want as a scalar, n_colors. This will
% generate an n_colors-by-3 matrix, each row representing an RGB
% color triple. If you don't precisely know how many you will need in
% advance, there is no harm (other than execution time) in specifying
% slightly more than you think you will need.
%
%   colors = distinguishable_colors(n_colors,bg)
% This syntax allows you to specify the background color, to make sure that
% your colors are also distinguishable from the background. Default value
% is white. bg may be specified as an RGB triple or as one of the standard
% "ColorSpec" strings. You can even specify multiple colors:
%     bg = {'w','k'}
% or
%     bg = [1 1 1; 0 0 0]
% will only produce colors that are distinguishable from both white and
% black.
%
%   colors = distinguishable_colors(n_colors,bg,rgb2labfunc)
% By default, distinguishable_colors uses the image processing toolbox's
% color conversion functions makecform and applycform. Alternatively, you
% can supply your own color conversion function.
%
% Example:
%   c = distinguishable_colors(25);
%   figure
%   image(reshape(c,[1 size(c)]))
%
% Example using the file exchange's 'colorspace':
%   func = @(x) colorspace('RGB->Lab',x);
%   c = distinguishable_colors(25,'w',func);

% Copyright 2010-2011 by Timothy E. Holy

  % Parse the inputs
  if (nargin < 2)
    bg = [1 1 1];  % default white background
  else
    if iscell(bg)
      % User specified a list of colors as a cell aray
      bgc = bg;
      for i = 1:length(bgc)
	bgc{i} = parsecolor(bgc{i});
      end
      bg = cat(1,bgc{:});
    else
      % User specified a numeric array of colors (n-by-3)
      bg = parsecolor(bg);
    end
  end

  % Generate a sizable number of RGB triples. This represents our space of
  % possible choices. By starting in RGB space, we ensure that all of the
  % colors can be generated by the monitor.
  n_grid = 30;  % number of grid divisions along each axis in RGB space
  x = linspace(0,1,n_grid);
  [R,G,B] = ndgrid(x,x,x);
  rgb = [R(:) G(:) B(:)];
  if (n_colors > size(rgb,1)/3)
    error('You can''t readily distinguish that many colors');
  end

  % Convert to Lab color space, which more closely represents human
  % perception
  if (nargin > 2)
    lab = func(rgb);
    bglab = func(bg);
  else
    C = makecform('srgb2lab');
    lab = applycform(rgb,C);
    bglab = applycform(bg,C);
  end

  % If the user specified multiple background colors, compute distances
  % from the candidate colors to the background colors
  mindist2 = inf(size(rgb,1),1);
  for i = 1:size(bglab,1)-1
    dX = bsxfun(@minus,lab,bglab(i,:)); % displacement all colors from bg
    dist2 = sum(dX.^2,2);  % square distance
    mindist2 = min(dist2,mindist2);  % dist2 to closest previously-chosen color
  end

  % Iteratively pick the color that maximizes the distance to the nearest
  % already-picked color
  colors = zeros(n_colors,3);
  lastlab = bglab(end,:);   % initialize by making the "previous" color equal to background
  for i = 1:n_colors
    dX = bsxfun(@minus,lab,lastlab); % displacement of last from all colors on list
    dist2 = sum(dX.^2,2);  % square distance
    mindist2 = min(dist2,mindist2);  % dist2 to closest previously-chosen color
    [~,index] = max(mindist2);  % find the entry farthest from all previously-chosen colors
    colors(i,:) = rgb(index,:);  % save for output
    lastlab = lab(index,:);  % prepare for next iteration
  end
end

function c = parsecolor(s)
  if ischar(s)
    c = colorstr2rgb(s);
  elseif isnumeric(s) && size(s,2) == 3
    c = s;
  else
    error('MATLAB:InvalidColorSpec','Color specification cannot be parsed.');
  end
end

function c = colorstr2rgb(c)
  % Convert a color string to an RGB value.
  % This is cribbed from Matlab's whitebg function.
  % Why don't they make this a stand-alone function?
  rgbspec = [1 0 0;0 1 0;0 0 1;1 1 1;0 1 1;1 0 1;1 1 0;0 0 0];
  cspec = 'rgbwcmyk';
  k = find(cspec==c(1));
  if isempty(k)
    error('MATLAB:InvalidColorString','Unknown color string.');
  end
  if k~=3 || length(c)==1,
    c = rgbspec(k,:);
  elseif length(c)>2,
    if strcmpi(c(1:3),'bla')
      c = [0 0 0];
    elseif strcmpi(c(1:3),'blu')
      c = [0 0 1];
    else
      error('MATLAB:UnknownColorString', 'Unknown color string.');
    end
  end
end
	function colors = distinguishable_colors(n_colors,bg,func)
	% DISTINGUISHABLE_COLORS: pick colors that are maximally perceptually distinct
	%
	% When plotting a set of lines, you may want to distinguish them by color.
	% By default, Matlab chooses a small set of colors and cycles among them,
	% and so if you have more than a few lines there will be confusion about
	% which line is which. To fix this problem, one would want to be able to
	% pick a much larger set of distinct colors, where the number of colors
	% equals or exceeds the number of lines you want to plot. Because our
	% ability to distinguish among colors has limits, one should choose these
	% colors to be "maximally perceptually distinguishable."
	%
	% This function generates a set of colors which are distinguishable
	% by reference to the "Lab" color space, which more closely matches
	% human color perception than RGB. Given an initial large list of possible
	% colors, it iteratively chooses the entry in the list that is farthest (in
	% Lab space) from all previously-chosen entries. While this "greedy"
	% algorithm does not yield a global maximum, it is simple and efficient.
	% Moreover, the sequence of colors is consistent no matter how many you
	% request, which facilitates the users' ability to learn the color order
	% and avoids major changes in the appearance of plots when adding or
	% removing lines.
	%
	% Syntax:
	% colors = distinguishable_colors(n_colors)
	% Specify the number of colors you want as a scalar, n_colors. This will
	% generate an n_colors-by-3 matrix, each row representing an RGB
	% color triple. If you don't precisely know how many you will need in
	% advance, there is no harm (other than execution time) in specifying
	% slightly more than you think you will need.
	%
	% colors = distinguishable_colors(n_colors,bg)
	% This syntax allows you to specify the background color, to make sure that
	% your colors are also distinguishable from the background. Default value
	% is white. bg may be specified as an RGB triple or as one of the standard
	% "ColorSpec" strings. You can even specify multiple colors:
	% bg = {'w','k'}
	% or
	% bg = [1 1 1; 0 0 0]
	% will only produce colors that are distinguishable from both white and
	% black.
	%
	% colors = distinguishable_colors(n_colors,bg,rgb2labfunc)
	% By default, distinguishable_colors uses the image processing toolbox's
	% color conversion functions makecform and applycform. Alternatively, you
	% can supply your own color conversion function.
	%
	% Example:
	% c = distinguishable_colors(25);
	% figure
	% image(reshape(c,[1 size(c)]))
	%
	% Example using the file exchange's 'colorspace':
	% func = @(x) colorspace('RGB->Lab',x);
	% c = distinguishable_colors(25,'w',func);

	% Copyright 2010-2011 by Timothy E. Holy

	% Parse the inputs
	if (nargin < 2)
	bg = [1 1 1]; % default white background
	else
	if iscell(bg)
	% User specified a list of colors as a cell aray
	bgc = bg;
	for i = 1:length(bgc)
	bgc{i} = parsecolor(bgc{i});
	end
	bg = cat(1,bgc{:});
	else
	% User specified a numeric array of colors (n-by-3)
	bg = parsecolor(bg);
	end
	end

	% Generate a sizable number of RGB triples. This represents our space of
	% possible choices. By starting in RGB space, we ensure that all of the
	% colors can be generated by the monitor.
	n_grid = 30; % number of grid divisions along each axis in RGB space
	x = linspace(0,1,n_grid);
	[R,G,B] = ndgrid(x,x,x);
	rgb = [R(:) G(:) B(:)];
	if (n_colors > size(rgb,1)/3)
	error('You can''t readily distinguish that many colors');
	end

	% Convert to Lab color space, which more closely represents human
	% perception
	if (nargin > 2)
	lab = func(rgb);
	bglab = func(bg);
	else
	C = makecform('srgb2lab');
	lab = applycform(rgb,C);
	bglab = applycform(bg,C);
	end

	% If the user specified multiple background colors, compute distances
	% from the candidate colors to the background colors
	mindist2 = inf(size(rgb,1),1);
	for i = 1:size(bglab,1)-1
	dX = bsxfun(@minus,lab,bglab(i,:)); % displacement all colors from bg
	dist2 = sum(dX.^2,2); % square distance
	mindist2 = min(dist2,mindist2); % dist2 to closest previously-chosen color
	end

	% Iteratively pick the color that maximizes the distance to the nearest
	% already-picked color
	colors = zeros(n_colors,3);
	lastlab = bglab(end,:); % initialize by making the "previous" color equal to background
	for i = 1:n_colors
	dX = bsxfun(@minus,lab,lastlab); % displacement of last from all colors on list
	dist2 = sum(dX.^2,2); % square distance
	mindist2 = min(dist2,mindist2); % dist2 to closest previously-chosen color
	[~,index] = max(mindist2); % find the entry farthest from all previously-chosen colors
	colors(i,:) = rgb(index,:); % save for output
	lastlab = lab(index,:); % prepare for next iteration
	end
	end

	function c = parsecolor(s)
	if ischar(s)
	c = colorstr2rgb(s);
	elseif isnumeric(s) && size(s,2) == 3
	c = s;
	else
	error('MATLAB:InvalidColorSpec','Color specification cannot be parsed.');
	end
	end

	function c = colorstr2rgb(c)
	% Convert a color string to an RGB value.
	% This is cribbed from Matlab's whitebg function.
	% Why don't they make this a stand-alone function?
	rgbspec = [1 0 0;0 1 0;0 0 1;1 1 1;0 1 1;1 0 1;1 1 0;0 0 0];
	cspec = 'rgbwcmyk';
	k = find(cspec==c(1));
	if isempty(k)
	error('MATLAB:InvalidColorString','Unknown color string.');
	end
	if k~=3 \|\| length(c)==1,
	c = rgbspec(k,:);
	elseif length(c)>2,
	if strcmpi(c(1:3),'bla')
	c = [0 0 0];
	elseif strcmpi(c(1:3),'blu')
	c = [0 0 1];
	else
	error('MATLAB:UnknownColorString', 'Unknown color string.');
	end
	end
	end