Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free, no registration required.

I have a function that takes optional arguments as name/value pairs.

function example(varargin)
% Lots of set up stuff
vargs = varargin;
nargs = length(vargs);
names = vargs(1:2:nargs);
values = vargs(2:2:nargs);

validnames = {'foo', 'bar', 'baz'};    
for name = names
   validatestring(name{:}, validnames);
end

% Do something ...
foo = strmatch('foo', names);
disp(values(foo))
end

example('foo', 1:10, 'bar', 'qwerty')

It seems that there is a lot of effort involved in extracting the appropriate values (and it still isn't particularly robust again badly specified inputs). Is there a better way of handling these name/value pairs? Are there any helper functions that come with MATLAB to assist?

share|improve this question
add comment

10 Answers

up vote 23 down vote accepted

I prefer using structures for my options. This gives you an easy way to store the options and an easy way to define them. Also, the whole thing becomes rather compact.

function example(varargin)

%# define defaults at the beginning of the code so that you do not need to
%# scroll way down in case you want to change something or if the help is
%# incomplete
options = struct('firstparameter',1,'secondparameter',magic(3));

%# read the acceptable names
optionNames = fieldnames(options);

%# count arguments
nArgs = length(varargin);
if round(nArgs/2)~=nArgs/2
   error('EXAMPLE needs propertyName/propertyValue pairs')
end

for pair = reshape(varargin,2,[]) %# pair is {propName;propValue}
   inpName = lower(pair{1}); %# make case insensitive

   if any(strmatch(inpName,optionNames))
      %# overwrite options. If you want you can test for the right class here
      %# Also, if you find out that there is an option you keep getting wrong,
      %# you can use "if strcmp(inpName,'problemOption'),testMore,end"-statements
      options.(inpName) = pair{2};
   else
      error('%s is not a recognized parameter name',inpName)
   end
end
share|improve this answer
    
@gnovice: Thanks! –  Jonas May 5 '10 at 19:59
    
actually, that's kinda cute ... I may have to start using that trick. –  JudoWill May 5 '10 at 20:03
    
This structure idea looks like it tidies things nicely. I might have a go at abstracting this into a general name/value to struct function. –  Richie Cotton May 6 '10 at 9:33
add comment

InputParser helps with this. See Parse Function Inputs for more information.

share|improve this answer
1  
@Matthew: This is probably the best built-in way of dealing with thing. I'm rather taken with Jonas's idea of options structs though, but this is a close second. –  Richie Cotton May 6 '10 at 9:37
add comment

I could yack for hours about this, but still don't have a good gestalt view of general Matlab signature handling. But here's a couple pieces of advice.

First, take a laissez faire approach to validating input types. Trust the caller. If you really want strong type testing, you want a static language like Java. Try to enforce type safety every where in Matlab, and you'll end up with a good part of your LOC and execution time devoted to run time type tests and coercion in userland, which trades in a lot of the power and development speed of Matlab. I learned this the hard way.

For API signatures (functions intended to be called from other functions, instead of from the command lines), consider using a single Args argument instead of varargin. Then it can be passed around between multiple arguments without having to convert it to and from a comma-separated list for varargin signatures. Structs, like Jonas says, are very convenient. There's also a nice isomorphism between structs and n-by-2 {name,value;...} cells, and you could set up a couple functions to convert between them inside your functions to whichever it wants to use internally.

function example(args)
%EXAMPLE
%
% Where args is a struct or {name,val;...} cell array

Whether you use inputParser or roll your own name/val parser like these other fine examples, package it up in a separate standard function that you'll call from the top of your functions that have name/val signatures. Have it accept the default value list in a data structure that's convenient to write out, and your arg-parsing calls will look sort of like function signature declarations, which helps readability, and avoid copy-and-paste boilerplate code.

Here's what the parsing calls could look like.

function out = my_example_function(varargin)
%MY_EXAMPLE_FUNCTION Example function 

% No type handling
args = parsemyargs(varargin, {
    'Stations'  {'ORD','SFO','LGA'}
    'Reading'   'Min Temp'
    'FromDate'  '1/1/2000'
    'ToDate'    today
    'Units'     'deg. C'
    });
fprintf('\nArgs:\n');
disp(args);

% With type handling
typed_args = parsemyargs(varargin, {
    'Stations'  {'ORD','SFO','LGA'}     'cellstr'
    'Reading'   'Min Temp'              []
    'FromDate'  '1/1/2000'              'datenum'
    'ToDate'    today                   'datenum'
    'Units'     'deg. C'                []
    });
fprintf('\nWith type handling:\n');
disp(typed_args);

% And now in your function body, you just reference stuff like
% args.Stations
% args.FromDate

And here's a function to implement the name/val parsing that way. You could hollow it out and replace it with inputParser, your own type conventions, etc. I think the n-by-2 cell convention makes for nicely readable source code; consider keeping that. Structs are typically more convenient to deal with in the receiving code, but the n-by-2 cells are more convenient to construct using expressions and literals. (Structs require the ",..." continuation at each line, and guarding cell values from expanding to nonscalar structs.)

function out = parsemyargs(args, defaults)
%PARSEMYARGS Arg parser helper
%
% out = parsemyargs(Args, Defaults)
%
% Parses name/value argument pairs.
%
% Args is what you pass your varargin in to. It may be
%
% ArgTypes is a list of argument names, default values, and optionally
% argument types for the inputs. It is an n-by-1, n-by-2 or n-by-3 cell in one
% of these forms forms:
%   { Name; ... }
%   { Name, DefaultValue; ... }
%   { Name, DefaultValue, Type; ... }
% You may also pass a struct, which is converted to the first form, or a
% cell row vector containing name/value pairs as 
%   { Name,DefaultValue, Name,DefaultValue,... }
% Row vectors are only supported because it's unambiguous when the 2-d form
% has at most 3 columns. If there were more columns possible, I think you'd
% have to require the 2-d form because 4-element long vectors would be
% ambiguous as to whether they were on record, or two records with two
% columns omitted.
%
% Returns struct.
%
% This is slow - don't use name/value signatures functions that will called
% in tight loops.

args = structify(args);
defaults = parse_defaults(defaults);

% You could normalize case if you want to. I recommend you don't; it's a runtime cost
% and just one more potential source of inconsistency.
%[args,defaults] = normalize_case_somehow(args, defaults);

out = merge_args(args, defaults);

%%
function out = parse_defaults(x)
%PARSE_DEFAULTS Parse the default arg spec structure
%
% Returns n-by-3 cellrec in form {Name,DefaultValue,Type;...}.

if isstruct(x)
    if ~isscalar(x)
        error('struct defaults must be scalar');
    end
    x = [fieldnames(s) struct2cell(s)];
end
if ~iscell(x)
    error('invalid defaults');
end

% Allow {name,val, name,val,...} row vectors
% Does not work for the general case of >3 columns in the 2-d form!
if size(x,1) == 1 && size(x,2) > 3
    x = reshape(x, [numel(x)/2 2]);
end

% Fill in omitted columns
if size(x,2) < 2
    x(:,2) = {[]}; % Make everything default to value []
end
if size(x,2) < 3
    x(:,3) = {[]}; % No default type conversion
end

out = x;

%%
function out = structify(x)
%STRUCTIFY Convert a struct or name/value list or record list to struct

if isempty(x)
    out = struct;
elseif iscell(x)
    % Cells can be {name,val;...} or {name,val,...}
    if (size(x,1) == 1) && size(x,2) > 2
        % Reshape {name,val, name,val, ... } list to {name,val; ... }
        x = reshape(x, [2 numel(x)/2]);
    end
    if size(x,2) ~= 2
        error('Invalid args: cells must be n-by-2 {name,val;...} or vector {name,val,...} list');
    end

    % Convert {name,val, name,val, ...} list to struct
    if ~iscellstr(x(:,1))
        error('Invalid names in name/val argument list');
    end
    % Little trick for building structs from name/vals
    % This protects cellstr arguments from expanding into nonscalar structs
    x(:,2) = num2cell(x(:,2)); 
    x = x';
    x = x(:);
    out = struct(x{:});
elseif isstruct(x)
    if ~isscalar(x)
        error('struct args must be scalar');
    end
    out = x;
end

%%
function out = merge_args(args, defaults)

out = structify(defaults(:,[1 2]));
% Apply user arguments
% You could normalize case if you wanted, but I avoid it because it's a
% runtime cost and one more chance for inconsistency.
names = fieldnames(args);
for i = 1:numel(names)
    out.(names{i}) = args.(names{i});
end
% Check and convert types
for i = 1:size(defaults,1)
    [name,defaultVal,type] = defaults{i,:};
    if ~isempty(type)
        out.(name) = needa(type, out.(name), type);
    end
end

%%
function out = needa(type, value, name)
%NEEDA Check that a value is of a given type, and convert if needed
%
% out = needa(type, value)

% HACK to support common 'pseudotypes' that aren't real Matlab types
switch type
    case 'cellstr'
        isThatType = iscellstr(value);
    case 'datenum'
        isThatType = isnumeric(value);
    otherwise
        isThatType = isa(value, type);
end

if isThatType
    out = value;
else
    % Here you can auto-convert if you're feeling brave. Assumes that the
    % conversion constructor form of all type names works.
    % Unfortunately this ends up with bad results if you try converting
    % between string and number (you get Unicode encoding/decoding). Use
    % at your discretion.
    % If you don't want to try autoconverting, just throw an error instead,
    % with:
    % error('Argument %s must be a %s; got a %s', name, type, class(value));
    try
        out = feval(type, value);
    catch err
        error('Failed converting argument %s from %s to %s: %s',...
            name, class(value), type, err.message);
    end
end

It is so unfortunate that strings and datenums are not first-class types in Matlab.

share|improve this answer
1  
@Andrew: Some good advice here. I agree that all this boilerplate code should be hidden away in a function, and you're probably right about not getting too control freaky with the input checking. –  Richie Cotton May 6 '10 at 8:18
add comment

Read Loren's informative post on this issue. Don't forget to read the comments section... - You will see that there are quite a few different approaches to this topic. They all work, so selecting a prefered method is really a matter of personal taste and maintainability.

share|improve this answer
add comment

Personally I use a custom method based on STATGETARGS, a private function used by some Statistics Toolbox functions (at least that's what it was called at the time I wrote it)

You can read the source code by looking at the file (depending on your MATLAB version):

which -all statgetargs
which -all internal.stats.getargs

In fact in the second case, you can call this utility function directly. Be advised that as the documentation states, using functions that belong to an internal package is strongly discouraged as they could be removed from MATLAB in any subsequent release without notice:

function example(varargin)
    %# parse arguments
    pnames = {'foo', 'bar', 'baz'};
    dflts  = {  'a',    [],    0 };
    [eid,emsg,foo,bar,baz] = internal.stats.getargs(pnames,dflts,varargin{:});
    if ~isempty(eid), error(eid,emsg); return; end

    %# use the variables: foo bar baz
    %# ...
end

Anyways, I believe someone posted a version of it as getargs on the FileExchange..

share|improve this answer
    
@Amro: Very interesting, and in fact, quite similar to the solution I just rolled myself. stackoverflow.com/questions/2775263/… –  Richie Cotton May 7 '10 at 9:24
add comment

I'm a bigger fan of home-grown boiler plate code like this:

function TestExample(req1, req2, varargin)
for i = 1:2:length(varargin)
    if strcmpi(varargin{i}, 'alphabet')
        ALPHA = varargin{i+1};

    elseif strcmpi(varargin{i}, 'cutoff')
        CUTOFF = varargin{i+1};
        %we need to remove these so seqlogo doesn't get confused
        rm_inds = [rm_inds i, i+1]; %#ok<*AGROW>

    elseif strcmpi(varargin{i}, 'colors')
        colors = varargin{i+1};
        rm_inds = [rm_inds i, i+1]; 
    elseif strcmpi(varargin{i}, 'axes_handle')
        handle = varargin{i+1};
        rm_inds = [rm_inds i, i+1]; 
    elseif strcmpi(varargin{i}, 'top-n')
        TOPN = varargin{i+1};
        rm_inds = [rm_inds i, i+1];
    elseif strcmpi(varargin{i}, 'inds')
        npos = varargin{i+1};
        rm_inds = [rm_inds i, i+1];
    elseif strcmpi(varargin{i}, 'letterfile')
        LETTERFILE = varargin{i+1};
        rm_inds = [rm_inds i, i+1];
    elseif strcmpi(varargin{i}, 'letterstruct')
        lo = varargin{i+1};
        rm_inds = [rm_inds i, i+1];
    end
end

This way I can simulate the 'option', value pair that's nearly identical to how most Matlab functions take their arguments.

Hope that helps,

Will

share|improve this answer
2  
@JudoWill: Thanks. This would be cleaner with a switch statement rather than lots if elseif clauses, and an else/otherwise clause would be good for trapping unrecognised inputs. –  Richie Cotton May 6 '10 at 8:24
add comment

Here's the solution I'm trialling, based upon Jonas' idea.

function argStruct = NameValuePairToStruct(defaults, varargin)
%NAMEVALUEPAIRTOSTRUCT Converts name/value pairs to a struct.
% 
% ARGSTRUCT = NAMEVALUEPAIRTOSTRUCT(DEFAULTS, VARARGIN) converts
% name/value pairs to a struct, with defaults.  The function expects an
% even number of arguments to VARARGIN, alternating NAME then VALUE.
% (Each NAME should be a valid variable name.)
% 
% Examples: 
% 
% No defaults
% NameValuePairToStruct(struct, ...
%    'foo', 123, ...
%    'bar', 'qwerty', ...
%    'baz', magic(3))
% 
% With defaults
% NameValuePairToStruct( ...
%    struct('bar', 'dvorak', 'quux', eye(3)), ...
%    'foo', 123, ...
%    'bar', 'qwerty', ...
%    'baz', magic(3))
% 
% See also: inputParser

nArgs = length(varargin);
if rem(nArgs, 2) ~= 0
   error('NameValuePairToStruct:NotNameValuePairs', ...
      'Inputs were not name/value pairs');
end

argStruct = defaults;
for i = 1:2:nArgs
   name = varargin{i};
   if ~isvarname(name)
      error('NameValuePairToStruct:InvalidName', ...
         'A variable name was not valid');
   end
   argStruct = setfield(argStruct, name, varargin{i + 1});  %#ok<SFLD>
end

end
share|improve this answer
add comment
function argtest(varargin)

a = 1;

for ii=1:length(varargin)/2
    [~] = evalc([varargin{2*ii-1} '=''' num2str(varargin{2*ii}) '''']);
end;

disp(a);
who

This does of course not check for correct assignments, but it's simple and any useless variable will be ignored anyway. It also only works for numerics, strings and arrays, but not for matrices, cells or structures.

share|improve this answer
add comment

I ended up writing this today, and then found these mentions. Mine uses struct's and struct 'overlays' for options. It essentially mirrors the functionality of setstructfields() except that new parameters can not be added. It also has an option for recursing, whereas setstructfields() does it automatically. It can take in a cell array of paired values by calling struct(args{:}).

% Overlay default fields with input fields
% Good for option management
% Arguments
%   $opts - Default options
%   $optsIn - Input options
%       Can be struct(), cell of {name, value, ...}, or empty []
%   $recurseStructs - Applies optOverlay to any existing structs, given new
%   value is a struct too and both are 1x1 structs
% Output
%   $opts - Outputs with optsIn values overlayed
function [opts] = optOverlay(opts, optsIn, recurseStructs)
    if nargin < 3
        recurseStructs = false;
    end
    isValid = @(o) isstruct(o) && length(o) == 1;
    assert(isValid(opts), 'Existing options cannot be cell array');
    assert(isValid(optsIn), 'Input options cannot be cell array');
    if ~isempty(optsIn)
        if iscell(optsIn)
            optsIn = struct(optsIn{:});
        end
        assert(isstruct(optsIn));
        fields = fieldnames(optsIn);
        for i = 1:length(fields)
            field = fields{i};
            assert(isfield(opts, field), 'Field does not exist: %s', field);
            newValue = optsIn.(field);
            % Apply recursion
            if recurseStructs
                curValue = opts.(field);
                % Both values must be proper option structs
                if isValid(curValue) && isValid(newValue) 
                    newValue = optOverlay(curValue, newValue, true);
                end
            end
            opts.(field) = newValue;
        end
    end
end

I'd say that using the naming convention 'defaults' and 'new' would probably be better :P

share|improve this answer
    
As an aside, I was able to develop a basic permutation for conducting full-factorial experiments with given overlay options: –  eacousineau Sep 20 '11 at 6:30
    
pastebin.com/qpW4BUFs –  eacousineau Sep 20 '11 at 7:26
add comment

Inspired by Jonas' answer, but more compact:

function example(varargin)
  defaults = struct('A',1, 'B',magic(3));  %define default values

  params = struct(varargin{:});
  for f = fieldnames(defaults)',
    if ~isfield(params, f{1}),
      params.(f{1}) = defaults.(f{1});
    end
  end

  %now just access them as params.A, params.B
share|improve this answer
add comment

Your Answer

 
discard

By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.