Matlab and the Event Dispatch Thread (EDT)

March 10th, 2010

Once again I welcome guest blogger Matt Whitaker, with the long awaited EDT article.

Java Swing’s Event Dispatch Thread (EDT)
or: why does my GUI foul up?

Matlab for the most part is a single threaded environment. That is, all commands are executed sequentially along a single execution thread. The main exception to this are the Handle Graphics (GUI) components whose operations execute on the Java Event Dispatch Thread (EDT). EDT effects are reflected even in mundane Matlab GUI operations.

If we execute the code below we will probably see nothing until the loop completes and the figure appears with the text label showing ‘10000′:

h = figure;
txt = uicontrol('Parent',h, 'Style','text', 'String','1');
for n = 1:10000
    set(txt,'String',int2str(n))
end %for

By adding a couple of drawnow commands we get the figure and text label to render and then we see the count progress to 10000.

h = figure;
txt = uicontrol('Parent',h, 'Style','text', 'String','1');
drawnow;
for n = 1:10000
    set(txt,'String',int2str(n));
    drawnow;
end %for

The drawnow function allows the EDT queue to be flushed and the pending graphics operations to be evaluated. This will also happen with pause and several other commands.

If we want to use Swing (or AWT) components in our user interfaces we need to take this multi-threaded environment into account. The Swing toolkit designers decided to make all the Swing components thread un-safe in order to decrease their complexity. As a consequence, all access to Swing components should be done from the event dispatch thread (EDT), to ensure the operations are executed sequentially, at the exact order in which they were dispatched. Any action on a Swing component done on another thread (Matlab’s main processing thread in our case) risks a race-condition or deadlock with the EDT, which could (and often does) result in weird, non-deterministic and non-repetitive behavior – all of which should be avoided in any application which should behave in a precisely deterministic manner.

In Java, the usual pattern to accomplish EDT dispatching is to create a Runnable object, encapsulate the GUI code in the run method of the Runnable object, then pass the Runnable object to the static EventQueue.invokeLater (or EventQueue.invokeAndWait if we need to block operations to get a return value) method.

Runnable runnable = new Runnable()
{
    public void run()
    {
        //GUI Code here
    }
}
 
EventQueue.invokeLater(runnable);

There are several functions in Matlab that implement this programming pattern for us: javaObjectEDT, javaMethodEDT, awtinvoke, awtcreate and javacomponent. JavaMethodEDT and javaObjectEDT were introduced in version R2008b (7.7) and are minimally and only partially documented although they have reasonably complete help comments. The other three are semi-documented (meaning they are unsupported but if you edit or type their m-file you’ll see a fairly detailed help section), and although there is some overlap in their functionality they are still available.

javaObjectEDT and javaMethodEDT

javaObjectEDT is the the preferred method since R2008b of creating swing components to be used on the EDT. An object created with javaObjectEDT will have all of its subsequent method calls run on the EDT. This is termed Auto Delegation. Auto-delegation greatly simplifies and increases the readability of code. Note that objects created as a result of method calls may not be implemented on the EDT.

If you have an existing Java object, you can pass it to javaObjectEDT at any time - all its subsequent calls will then onward run on the EDT. Note that this useful functionality is an under-documented javaObjectEDT feature: it is not mentioned in the main help section but only implied from the example.

% Create a button on the EDT
btn = javaObjectEDT('javax.swing.JButton');
% this will run on EDT since btn was javaObjectEDT-created
btn.setText('Button');
 
% Create a button NOT on the EDT
btn2 = javax.swing.JButton;
% Dangerous! call will run on main Matlab thread
btn2.setText('Button2');
% modify btn2 so its methods will start running on the EDT
javaObjectEDT(btn2);
btn2.setText('Button2');

The following example shows the use of javaObjectEDT and javaMethodEDT in a more complex situation using a JTable:

function tableExample
hFig = figure;
drawnow; %need to get figure rendered
 
%use Yair's createTable to add a javax.swing.JTable
%http://www.mathworks.com/matlabcentral/fileexchange/14225-java-based-data-table
%wrap ceateTable in javaObjectEDT to put the ensuing method calls on the EDT
f = java.awt.Font(java.lang.String('Dialog'),java.awt.Font.PLAIN,14);
headers = {'Selected','File','Analysis Routine','Task Status'};
tbl = javaObjectEDT(createTable(hFig,headers,[],false,'Font',f));
 
%set column 1 to use check boxes and set up a change callback
tbl.setCheckBoxEditor(1);
jtable = javaObjectEDT(tbl.getTable); %get the underlying Java Table. IMPORTANT: we need to put jtable on the EDT
columnModel = javaObjectEDT(jtable.getColumnModel); %now we can now do direct calls safely on jtable
selectColumn = javaObjectEDT(columnModel.getColumn(0));
selectColumnCellEditor = selectColumn.getCellEditor;
chk = javaMethodEDT('getComponent',selectColumnCellEditor);
set(chk,'ItemStateChangedCallback',@chkChange_Callback);
 
%make column three a combo drop down
analysisTable = {'Analysis1';'Analysis2';'Analysis3'};
cb = javaObjectEDT('com.mathworks.mwswing.MJComboBox',analysisTable);
cb.setEditable(false);
cb.setFont(f);
set(cb,'ItemStateChangedCallback',@cbChange_Callback);
editor = javaObjectEDT('javax.swing.DefaultCellEditor',cb);
analysisColumn = javaObjectEDT(columnModel.getColumn(2));
analysisColumn.setCellEditor(editor);
 
%set some column with restrictions
selectColumn.setMaxWidth(100);
analysisColumn.setPreferredWidth(300);
 
%set the data
SELECTED = java.awt.event.ItemEvent.SELECTED;
tbl.setData({false,'file1','Analysis2','Analysis2';...
             true,'file2','Analysis3','Analysis3'});
drawnow;
 
    function cbChange_Callback(src,ev) %#ok
        jRow = jtable.getSelectedRow;
        stateChange = javaMethodEDT('getStateChange',ev);
        if stateChange == SELECTED
            newData = javaMethodEDT('getItem',ev);
            model = jtable.getModel;
            javaMethodEDT('setValueAt',model,newData,jRow,3);
        end %if
    end %cbChange
 
    function chkChange_Callback(src,ev) %#ok
        chkBox = javaMethodEDT('getItem',ev);
        if logical(javaMethodEDT('isSelected',chkBox))
            beep; %put useful code here
        else
            beep;
            pause(0.1)
            beep; %put useful code here
        end %if
    end %chkChange_Callback
 
end %tableExample

If you are running Matlab R2008a or later, javacomponent uses the javaObjectEDT function to create the returned objects so you do not have to do anything further to these objects to have their calls dispatched on the EDT. Users need to take care that objects added directly to the components created by javacomponent are on the EDT as well as specialized sub-components (e.g. CellRenderers and CellEditors). The overhead of calling javaMethodEDT is fairly small so if in doubt, use it.

javaObjectEDT and its kin first appeared in R2008a, although they only became supported in R2008b. Unfortunately, using them on R2008a sometimes causes hangs and all sorts of other mis-behaviors. This problem was fixed in the R2008b release, when javaObjectEDT became a fully-supported function. The problem with using javaObjectEDT in our application is that if it ever runs on an R2008a platform it might hang! (on Matlab release R2007b and earlier we will get an informative message saying that the javaObjectEDT function does not exist)

For this reason, I am using the following method in my projects:

function result = javaObjEDT(varargin)
%Placeholder of Matlab's buggy javaObjectEDT function on R2008a
 
% Programmed by Yair M. Altman: altmany(at)gmail.com
% $Revision: 1.2 $  $Date: 2009/01/25 11:31:08 $
 
  try
      try
          result = varargin{1};
      catch
          result = [];
      end
      v = version;
      if str2double(v(1:3)) > 7.6
          result = builtin('javaObjectEDT',varargin{:});
      end
  catch
      % never mind
  end
end

Note that javaMethodEDT has the method name as its first input argument, and the object name or reference as its second arg. This is inconsistent with many other Matlab/Java functions, which normally accept the target object as the first argument (compare: invoke, awtinvoke, notify etc.). It also means that we cannot use the familiar obj.javaMethodEDT(methodName) format.

One final note: when javaObjectEDT and javaMethodEDT first appeared in R2008a, they were complemented by the javaObjectMT and javaMethodMT functions, which create and delegate Java objects on the main Matlab computational thread. Their internal documentation says that there are cases when execution must occur on the MT rather than EDT, although I am personally not aware of any such case.

awtcreate and awtinvoke

For users with versions prior to R2008b the user must use the awtcreate function to create objects on the EDT. One huge disadvantage of this older function is that if you have to pass java objects in the parameter list you must use the very cumbersome JNI style notation. For example, for the simple task of setting a button label, one has to use:

btn = awtcreate('javax.swing.JButton');
awtinvoke(btn,'setText(Ljava/lang/String;)','click me')

The other disadvantage is that creating the object using awtcreate does not ensure that its subsequent method calls will be executed on the EDT. The awtinvoke function must be used for each call.

Also, both awtcreate and awtinvoke have some limitations due to bugs in the private parseJavaSignature function (for example, invoking methods which accept a java.lang.Object) which forces one to use the direct call to the method, using the main Matlab thread. This can result in the undesired effects described above. In this situation the best workaround is to call pause(0.01) to allow the event queue to clear.

Versions of javacomponent earlier than R2008a use awtcreate and objects created by these versions must have their subsequent methods called by awtinvoke to be used on the EDT.

A very rare CSSM thread discusses the usage of awtcreate and awtinvoke with some very interesting remarks by MathWorks personnel.

There is an interesting option in awtinvoke that was not carried over into the newer javaMethodEDT. This option allows the user to pass a function handle in the argument list along with its parameters. This option creates an undocumented com.mathworks.jmi.Callback object that has a delayed callback. The delayed callback is dispatched on the EDT so that it will be called once the java method used in awtinvoke is finished. Note that the actual function will still execute on the main Matlab thread the delayed callback will just control when it is called. However this may be useful at times. It is possible to put this functionality into a separate function we can call to delay execution until the event queue is cleared.

%CALLBACKONEDTQUEUE will place a callback on the EDT to asynchronously
%run a function.
%CALLBBACKONEDTQUEUE(FCN) will run function handle FCN once all previous
%methods dispatched to the EDT have completed.
%CALLBBACKONEDTQUEUE(FCN,ARG1,ARG2,...) ill run function handle FCN with
%arguments ARG1,ARG2...once all previous methods dispatched to the EDT
%have completed.
%Note that the function is still executing on the main Matlab thread. This
%function just delays when it will be called.
function callbackOnEDTQueue(varargin)
    validateattributes(varargin{1},{'function_handle'},{});
    callbackObj = handle(com.mathworks.jmi.Callback,'callbackProperties');
    set(callbackObj,'delayedCallback',{@cbEval,varargin(:)});
    callbackObj.postCallback;
 
    function cbEval(src,evt,args) %#ok
        feval(args{:});
    end %cbEval
end %callbackOnEDTQueue
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Posted in GUI, Handle graphics, Java, Medium risk of breaking in future versions, Semi-documented function, UI controls, Undocumented feature | 6 Comments »

Setting desktop tab completions

March 3rd, 2010

This site has lately focused on quite detailed Java-related topics. Next week I will present the promised EDT article, which will dive into even deeper Java territory. So I thought to take a short break and present an entirely pure-Matlab non-Java undocumented feature, which is simple and yet quite useful.

A few months ago, a CSSM reader asked whether it is possible to customize Matlab tab-completion for user-defined functions (see related). A similar question on StackOverflow provided the necessary solution lead:

Apparently, Matlab has a file called TC.xml in its [matlabroot '/toolbox/local/'] folder that contains the definitions of the tab-completable functions and their arguments. In order for a user-defined function’s arguments to support tab-completion, a new entry needs to be added to this XML file.

TC.xml & TC.xsd

The full syntax of the TC.xml file can be found in the TC.xsd file, which is located in the same folder as TC.xml. Here are some sample definitions from my TC.xml file (which might vary across Matlab releases):

<binding name="addpath" ctype="DIR"/>
<binding name="help"    ctype="FUN SUBFUN"/>
<binding name="clear"   ctype="FUN VAR"/>
 
<binding name="whos"    ctype="VAR">
  <arg previous="-file" ctype= "MATFILE"/>
</binding>
 
<binding name="open">
  <arg argn="1" ctype="VAR MATFILE FIGFILE MFILE MDLFILE FILE"/>
</binding>
 
<binding name="openfig">
  <arg argn="1" ctype="FIGFILE"/>
  <arg argn="2" ctype="VAR" value="new visible invisible reuse"/>
</binding>
 
<binding name="mlint"   ctype="FUN">
  <arg argn="2:10" ctype="VAR" value="-struct -string -id"/>
</binding>

The first example defines that an unlimited number of addpath arguments are all of type DIR. Therefore, when completing any argument of this function in the Command-Window, Matlab will present only relevant DIR (=folder) elements in the pop-up window (lexically sorted):

Tab-completion of type DIR

Tab-completion of type DIR

Similarly, help defines all its arguments to be a function or sub-function type, so the popup-up will only be populated with the function names currently visible in the desktop:

Tab-completion of types FUN & SUBFUN

Tab-completion of types FUN & SUBFUN

Similarly, clear defines all its arguments as function names or variables. Note that the list of available functions and variables may change depending on the current execution stack position. The full list of supported types is defined in the TC.xsd file. It is: VAR, FUN, SUBFUN, DIR, FILE, MFILE, MATFILE, FIGFILE and MDLFILE.

The whos function defines all its arguments as VAR, except the single MATFILE argument that follows a ‘-file’ argument (look at whos’s help page to understand why).

The open function defines tab completion only for its first argument (with plenty of possible types…). Likewise, openfig defines its first argument as a FIGFILE, and its second as VAR with a few extra special-purpose strings that are added to the popup-up menu.

Finally, the mlint example shows that multiple arguments can be defined using a single XML definition element. In this case, args #2-10 are defined as VAR (with three extra special-purpose strings), while arg #1 and 11+ are defined as FUN.

The careful user can edit the TC.xml file using any text editor (I strongly suggest saving a backup first):

edit(fullfile(matlabroot,'toolbox/local/TC.xml'))

User-defined functions can easily be added to TC.xml, and we can even add/modify the built-in Matlab functions that are already defined. Note that changes to TC.xml only take effect after a Matlab restart. From then on, all future Matlab sessions will use the modification, so a really simple one-time edit can improve our workflow for a long time - at least until we upgrade Matlab, when we’ll need to redo our edits…

TabComplete utility

In order to facilitate TC.xml editing, I have created a utility called TabComplete, which is now available on the Matlab File Exchange. The use of this utility is very simple. For example:

tabcomplete test file 'DIR +data -data nodata' VAR

defines a user-defined function test that accepts a FILE argument, followed by a DIR argument with three special-purpose strings, followed by any number of VAR arguments. If I wished to define specific argument types without any default type, I would use:

tabcomplete test file 'DIR +data -data nodata' ''

Using TabComplete for user-defined functions

Using TabComplete for user-defined functions

TabComplete can also be used to retrieve the current list of tab-completion definitions:

>> definitions = tabcomplete;
>> definitions(1)
ans = 
    functionName: 'addpath'
     defaultType: 'DIR'
     extraValues: ''
        platform: ''
    functionArgs: []
 
>> definitions(54)
ans = 
    functionName: 'openfig'
     defaultType: ''
     extraValues: ''
        platform: ''
    functionArgs: [1x2 struct]
>> definitions(54).functionArgs(1)
ans = 
    previousArg: ''
        argType: 'FIGFILE'
    extraValues: ''
>> definitions(54).functionArgs(2)
ans = 
    previousArg: ''
        argType: 'VAR'
    extraValues: 'new visible invisible reuse'

TabComplete has a few limitations: it does not support the -previous option described above (you can do this by manually editing TC.xml). There are also some inherent limitations in Matlab’s TC functionality: changes take effect only after a Matlab restart (there might be a way to reload the definitions in the current Matlab session, but I do not know of any); the list of standard types cannot be modified; and the default type does not support extra special-purpose strings as do the numbered arguments.

There is another very annoying limitation: by default, TC.xml only supports lowercase function names. This is stupid, since Matlab has many function names with UPPERCASE characters, and certainly user-defined function names also do. Luckily, this last limitation can easily be overcome by editing the TC.xsd file (note that this is the TC.XSD file, not the TC.XML file). Instead of:

<xsd:simpleType name="tcBindingNameType">
  <xsd:restriction base="xsd:token">
    <xsd:pattern value='[A-Za-z_0-9]+(/[a-z_0-9]+)?'/>
  </xsd:restriction>
</xsd:simpleType>

Change the xsd:pattern definition element to:

    <!-- Yair 21/2/2010: added A-Z -->
    <xsd:pattern value='[A-Za-z_0-9]+(/[A-Za-z_0-9]+)?'/>

(note the way comments can be added to the XSD/XML files)

P.S. an entirely different customization, for user-defined class members, was presented by Michal Kutil.

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Posted in Desktop, Low risk of breaking in future versions, Medium risk of breaking in future versions, Undocumented feature | 3 Comments »

Inactive Control Tooltips & Event Chaining

February 24th, 2010

Once again, I welcome guest blogger Matt Whitaker, who continues his series of articles.

In my last post I explored some tips on tooltips. One of these tips involved displaying tooltips on disabled uicontrols. I explained that displaying tooltips on inactive controls is problematic since Matlab appears to intercept mouse events to these inactive controls, so even setting the tooltip on the underlying Java object will not work: The java object appears not to receive the mouse-hover event and therefore does not “know” that it’s time to display the tooltip.

When Yair and I deliberated this issue, he pointed me to his comment on a previous article showing an undocumented Java technique (Java also has some…) for forcing a tooltip to appear using the ActionMap of the uicontrol’s underlying Java object to get at a postTip action. We discussed using a WindowButtonMotionFcn callback to see if the mouse was above the inactive control, then triggering the forced tooltip display. Yair then went on to remind me and I quote: “you’ll need to chain existing WindowButtonMotionFcn callbacks and take into account ModeManagers that override them.”

Frankly, having written code previously that handles callback chaining, I would rather poke myself in the eye with a fork!

The Image Processing Toolbox has the nice pair of iptaddcallback and iptremovecallback functions that largely handle these issues. But for general Matlab, there seemed to be no alternative until I remembered that events trigger callbacks. I decided to use a listener for the WindowButtonMotion event to detect the mouse motion. Event listeners were briefly explained two weeks ago and deserve a dedicated future article. The advantage of using an event listener is that we don’t disturb any existing WindowButtonMotionFcn callback. We still need to be somewhat careful that our listeners don’t do conflicting things, but it’s a lot easier than trying to manage everything through the single WindowButtonMotionFcn.

A demonstration of this appears below with some comments following (note that this code uses the FindJObj utility):

function inactiveBtnToolTip
  %Illustrates how to make a tooltip appear on an inactive control
  h = figure('WindowButtonMotionFcn',@windowMotion,'Pos',[400,400,200,200]);
  col = get(h,'color');
  lbl = uicontrol('Style','text', 'Pos',[10,160,120,20], ...
                  'Background',col, 'HorizontalAlignment','left');
  btn = uicontrol('Parent',h, 'String','Button', ...
                  'Enable','inactive', 'Pos',[10,40,60,20]);
  uicontrol('Style','check', 'Parent',h, 'String','Enable button tooltip', ...
            'Callback',@chkTooltipEnable, 'Value',1, ...
            'Pos',[10,80,180,20], 'Background',col);
  drawnow;
 
  %create the tooltip and postTip action
  jBtn = findjobj(btn);
  import java.awt.event.ActionEvent;
  javaMethodEDT('setToolTipText',jBtn,'This button is inactive');
  actionMap = javaMethodEDT('getActionMap',jBtn);
  action = javaMethodEDT('get',actionMap,'postTip');
  actionEvent = ActionEvent(jBtn, ActionEvent.ACTION_PERFORMED, 'postTip');
 
  %get the extents plus 2 pixels of the control to compare to the mouse position
  btnPos = getpixelposition(btn)+[-2,-2,4,4]; %give a little band around the control
  left = btnPos(1);
  right = sum(btnPos([1,3]));
  btm = btnPos(2);
  top =  sum(btnPos([2,4]));
 
  % add a listener on mouse movement events
  tm = javax.swing.ToolTipManager.sharedInstance; %tooltip manager
  pointListener = handle.listener(h,'WindowButtonMotionEvent',@figMouseMove);
 
  %inControl is a flag to prevent multiple triggers of the postTip action
  %while mouse remains in the button
  inControl = false;
 
  function figMouseMove(src,evtData) %#ok
    %get the current point
    cPoint = evtData.CurrentPoint;
 
    if cPoint(1) >= left && cPoint(1) <= right &&...
       cPoint(2) >= btm  && cPoint(2) <= top
 
      if ~inControl %we just entered
        inControl = true;
        action.actionPerformed(actionEvent); %show the tooltip
      end %if
    else
      if inControl %we just existed
        inControl = false;
        %toggle to make it disappear when leaving button
        javaMethodEDT('setEnabled',tm,false);
        javaMethodEDT('setEnabled',tm,true);
      end %if
    end %if
  end %gpMouseMove
 
  function windowMotion(varargin)
    %illustrate that we can still do a regular window button motion callback
    set(lbl,'String',sprintf('Mouse position: %d, %d',get(h,'CurrentPoint')));
    drawnow;
  end %windowMotion
 
  function chkTooltipEnable(src,varargin)
    if get(src,'Value')
      set(pointListener,'Enable','on');
    else
      set(pointListener,'Enable','off');
    end %if
  end %chkTooltipEnable
end %inactiveBtnToolTip

Tooltip on an inactive button

Tooltip on an inactive button

Comments on the code:

  1. The code illustrates that we can successfully add an additional listener to listen for mouse motion events while still carrying out the original WindowButtonMotionFcn callback. This makes chaining callbacks much easier.
  2. The handle.listener object has an Enable property that we can use to temporarily turn the listener on and off. This can be seen in the chkTooltipEnable() callback for the check box in the code above. If we wanted to permanently remove the listener we would simply use delete(pointListener). Note that addlistener adds a hidden property to the object being listened to, so that the listener is tied to the object’s lifecycle. If you create a listener directly using handle.listener you are responsible for it’s disposition. Unfortunately, addlistener fails for HG handles on pre-R2009 Matlab releases, so we use handle.listener directly.
  3. The code illustrates a good practice when tracking rapidly firing events like mouse movement of handling reentry into the callback while it is still processing a previous callback. Here we use a flag called inControl to prevent the postTip action being continuously fired while the mouse remains in the control.
  4. I was unable to determine if there is any corresponding action for the postTip to dismiss tips so I resorted to using the ToolTipManager to toggle its own Enable property to cleanly hide the tooltip as the mouse leaves the control.

Each Matlab callback has an associated event with it. Some of the ones that might be immediately useful at the figure-level are WindowButtonDown, WindowButtonUp, WindowKeyPress, and WindowKeyRelease. They can all be accessed through handle.listener or addlistener as in the code above.

Unfortunately, events do not always have names that directly correspond to the callback names. In order to see the list of available events for a particular Matlab object, use the following code, which relies on another undocumented function - classhandle. Here we list the events for gcf:

>> get(get(classhandle(handle(gcf)),'Events'),'Name')
ans = 
    'SerializeEvent'
    'FigureUpdateEvent'
    'ResizeEvent'
    'WindowKeyReleaseEvent'
    'WindowKeyPressEvent'
    'WindowButtonUpEvent'
    'WindowButtonDownEvent'
    'WindowButtonMotionEvent'
    'WindowPostChangeEvent'
    'WindowPreChangeEvent'

Note that I have made extensive use of the javaMethodEDT function to execute Java methods that affect swing components on Swing’s Event Dispatch Thread. I plan to write about this and related functions in my next article.

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Posted in GUI, Handle graphics, Hidden property, Java, Listeners, Medium risk of breaking in future versions, Stock Matlab function, UI controls, Undocumented function | No Comments »

Additional uicontrol tooltip hacks

February 17th, 2010

Once again I’d like to welcome guest blogger Matthew Whitaker. Today Matt will discuss uicontrol tooltips hacks as the first of several posts that follow a logical thread culminating in the long promised article on the EDT.

A while back Yair wrote a cool article, Spicing up Matlab uicontrol tooltips, describing use of HTML formatting and images in uicontrol tooltips. I want to share some limitations I’ve seen with tooltips and their solution using the Matlab control’s underlying Java object.

Situation 1: Displaying a tooltip on disabled controls

One issue with the stock Matlab uicontrol tooltips is that if you turn the uicontrol’s Enable property to ‘inactive’ or ‘off’, its tooltip no longer displays. This is the behavior that we normally want, but occasionally we wish to display a tooltip on a disabled control, for example, to explain why the control is disabled.

You can use the findjobj utility to find the Java handle for the uicontrol. This handle can then be used to set the tooltip text. The tooltip will display if you disable the control using its Java handle’s Enabled property rather than the Matlab handle’s Enable property:

hButton = uicontrol('String','Button');
drawnow;
jButton= findjobj(hButton);
set(jButton,'Enabled',false);
set(jButton,'ToolTipText','This is disabled for a reason');

As customary for Java objects, its properties can also be set using their corresponding accessor methods:

javaMethodEDT('setEnabled',jButton,false);
javaMethodEDT('setToolTipText',jButton,'Button is disabled for a reason');

tooltip on a disabled uicontrol

tooltip on a disabled uicontrol

Unfortunately, this hack does not work for ‘inactive’ controls. There is no direct Java analogy for inactive controls - it’s a Matlab extension. It appears that Matlab somehow intercepts the mouse events associated with inactive controls. My next post will show how event callback can be used to display tooltips for inactive controls.

As an alternative for inactive edit-box controls, we can simulate the inactive behavior by setting the Java object’s Editable property (or by using its setEditable() accessor method), then setting the tooltip. Note that the extremely-useful Java Editable property is unavailable in the Matlab handle, for some inexplicable reason:

hEditbox = uicontrol('String','Edit Text','Style','edit');
drawnow;
jEditbox = findjobj(hEditbox);
set(jEditbox,'Editable',false);
set(jEditbox,'ToolTipText','Text is inactive for a reason');

tooltip on a non-editable editbox

tooltip on a non-editable editbox

Situation 2: Displaying a tooltip on truncated text

If we want to conditionally display a tooltip for an editbox uicontrol when the text exceeds the control’s width, we can use the TipWhenTruncatedEnabled property (or its corresponding setTipWhenTruncatedEnabled() method). This will display a tooltip with the editbox contents if the string is shown truncated. This saves the user having to scroll through the control to see its contents. I often use this for edit controls that may contain long path names:

hEditbox(1) = uicontrol('Style','edit','Units','norm','Pos',[0.1,0.8,0.4,0.05], 'String','Too Short');
hEditbox(2) = uicontrol('Style','edit','Units','norm','Pos',[0.1,0.7,0.2,0.05], 'String','Long Enough to Display a Tool Tip');
drawnow;
jEditbox1 = findjobj(hEditbox(1));
jEditbox2 = findjobj(hEditbox(2));
set(jEditbox1,'TipWhenTruncatedEnabled',true);  % property-based alternative
javaMethod('setTipWhenTruncatedEnabled',jEditbox2,true);  % method-based alternative

TipWhenTruncatedEnabled tooltip

TipWhenTruncatedEnabled tooltip

The TipWhenTruncatedEnabled property property is also available for multi-line editboxes, but has (obviously) no effect when scrollbars are present. Also note that setting the TipWhenTruncatedEnabled property to true overrides any previous tooltip that might have been set for the editbox.

Finally, note that the TipWhenTruncatedEnabled property can also be set for the editbox component of popup-menu (aka drop-down) controls, after they have been set to be editable using their Java Editable property (note that both properties are false by default for Matlab uicontrols). In the following screenshot, the drop-down’s editbox component contained an HTML snippet, that is shown unformatted within the edit-box and HTML-formatted in the de-truncated tooltip:

de-truncated HTML-format tooltip

de-truncated HTML-format tooltip

Situation 3: Controlling tooltip timing

As you have probably noticed, there is a slight delay between the time your mouse enters the control and when the tooltip actually appears. If you display a tooltip over a control for sufficiently long the tooltip will then disappear. Sometimes the default delays are too slow or fast for your application. These times can be controlled through the javax.swing.ToolTipManager. The ToolTipManager sets these parameters globally (including for your Matlab desktop components), but they are not persistent between sessions.

Some examples using the ToolTipManager:

btn = uicontrol('String','Button','Tooltip','This is a button.','Pos',[100,100,75,25]);
txt = uicontrol('Style','edit','String','Edit Text','Tooltip','This is editable text','Pos',[100,50,75,25]);
 
tm = javax.swing.ToolTipManager.sharedInstance; %static method to get ToolTipManager object
initialDelay = javaMethodEDT('getInitialDelay',tm); %get the delay before display in milliseconds (=750 on my system)
javaMethodEDT('setInitialDelay',tm,0); %set tooltips to appear immediately
 
dismissDelay = javaMethodEDT('getDismissDelay',tm); %get the delay before the tooltip disappears (=10000 (10 sec) on my system)
javaMethodEDT('setDismissDelay',tm,2000); %set the dismiss delay to 2 seconds
 
javaMethodEDT('setEnabled',tm,false); %turns off all tooltips in system (including the Matlab desktop)
javaMethodEDT('setEnabled',tm,true);
 
javaMethodEDT('setInitialDelay',tm,initialDelay);
javaMethodEDT('setDismissDelay',tm,dismissDelay);

Note that I have made extensive use of the undocumented built-in javaMethodEDT function to execute Java methods that affect Swing components on the Swing Event Dispatch Thread (EDT). I plan to write about EDT following my next post on event callback chaining.

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Continuous slider callback

February 8th, 2010

Every few months, a CSSM forum reader asks how to set up a continuously-invoked slider callback: Matlab’s slider uicontrol invokes the user callback only when the mouse button is released, and not continuously while the slider’s thumb is dragged. This functionality was again referred-to yesterday, and I decided it merits a dedicated post.

There are three distinct simple ways to achieve continuous callbacks:

Using Java callbacks

As explained in an earlier article, Matlab uicontrols are basically Java Swing objects that possess a large number of useful callbacks. Matlab sliders’ underlying Java objects, which are really not JSliders but JScrollBars, have an AdjustmentValueChangedCallback property that is useful for our purposes and is accessible using the FindJObj utility. Simply download FindJObj from the File Exchange, and then:

hSlider = uicontrol('style','slider', ...);
jScrollBar = findjobj(hSlider);
jScrollBar.AdjustmentValueChangedCallback = @myCbFcn;
% or: set(jScrollBar,'AdjustmentValueChangedCallback',@myCbFcn)

Where myCbFcn is the Matlab callback function that will be invoked continuously when the arrow buttons are depressed or the slider’s thumb is dragged.

Using an event listener

An alternative to the Java route is to use Matlab’s undocumented handle.listener function to listen to the slider’s Action event, as follows:

hListener = handle.listener(hSlider,'ActionEvent',@myCbFcn);

This alternative is used by Matlab’s own imscrollpanel function:

if isJavaFigure
   % Must use these ActionEvents to get continuous events fired as slider
   % thumb is dragged. Regular callbacks on sliders give only one event
   % when the thumb is released.
   hSliderHorListener = handle.listener(hSliderHor,...
      'ActionEvent',@scrollHorizontal);
   hSliderVerListener = handle.listener(hSliderVer,...
      'ActionEvent',@scrollVertical);
   setappdata(hScrollpanel,'sliderListeners',...
      [hSliderHorListener hSliderVerListener]);
else
   % Unfortunately, the event route is only available with Java Figures,
   % so platforms without Java Figure support get discrete events only
   % when the mouse is released from dragging the slider thumb.
   set(hSliderHor,'callback',@scrollHorizontal)
   set(hSliderVer,'callback',@scrollVertical)
end

Using a property listener

The handle.listener function can also be used to listen to property value changes. In our case, set a post-set listener, that gets triggered immediately following Value property updates, as follows:

hhSlider = handle(hSlider);
hProp = findprop(hhSlider,'Value');  % a schema.prop object
hListener = handle.listener(hhSlider,hProp,'PropertyPostSet',@myCbFcn);

In addition to ‘PropertyPostSet’, we could also listen on ‘PropertyPreSet’, which is triggered immediately before the property is modified. There are also corresponding ‘*Get’ options. In relatively old Matlab releases (I believe R2007b and earlier, but I’m not certain), the option names were simply ‘PostSet’, ‘PreSet’ etc., without the ‘Property’ prefix.

Do you know of any other way to achieve continuous callbacks? If so, I would be delighted to hear in the comments section below.

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Solving a MATLAB bug by subclassing

February 7th, 2010

I would like to welcome guest blogger Matthew Whitaker. Many of Matt’s CSSM submissions offer important insight of internal Matlab functionality. As shall be seen by today’s article and some future submissions, Matt has plenty to share vis-a-vis Matlab’s undocumented functionality.

In my day-to-day work I make extensive use of MATLAB’s Image Processing Toolbox (IPT). One area of the toolbox that has seen considerable change over the last few releases has been the development of a set of modular tools to aid in GUI design for image processing applications. In this article, I examine a bug in one of those tools to illustrate how we can use the power of subclassing these objects (using an undocumented property) to design a simple and effective workaround.

The problem

The problem arose as I was refactoring some code that was written in R2006b to R2009b. The code in question uses the impoint tool on an image along with an associated text object that moves with the point to display information as it is dragged around the image. At the time of the R2006b release the impoint tool was written as an API. In R2006b the call to impoint returns a handle to an hggroup containing a structure of function handles in its application data under the tag ‘API’. This programming pattern was common before the advent of the new class syntax in MATLAB version 7.6 (R2008a).

Here is an example of how impoint would be used in R2006b:

function impointBehavior_R2006b
%IMPOINTBEHAVIOR_R2006B shows how impoint would be used in R2006b
%Note: RUN UNDER R2006B (will run under R2009b but actually uses
%classdef impoint so it will show the same issue)
 
  % Display the image in a figure window
  figure;  imshow('rice.png');
 
  % In R2006b calling impoint returns the hggroup handle
  h = impoint(gca,100,200);
 
  % In 2006b iptgetapi returns a structure of function handles
  api = iptgetapi(h);
 
  % Add a new position callback to set the text string
  api.addNewPositionCallback(@newPos_Callback);
 
  % Construct boundary constraint function so we can't go outside the axes
  fcn = makeConstrainToRectFcn('impoint',get(gca,'XLim'),get(gca,'YLim'));
  api.setDragConstraintFcn(fcn);
 
  % Fire callback so we get initial text
  newPos_Callback(api.getPosition());
 
  function newPos_Callback(newPos)
    % Display the current point position in a text label
    api.setString(sprintf('(%1.0f,%1.0f)',newPos(1),newPos(2)));
  end %newPos_Callback
 
end %impointBehavior_R2006b

The code above, when run in R2006b, produces the desired behavior of displaying a text object containing the point coordinates that moves around with the point as it is dragged around the axes.

In R2009b, impoint is now a true MATLAB class using the new classdef syntax, so I wanted to update the existing code. Initially this appeared to be a straightforward translation of the code to make use of the new impoint class syntax. The first attempt to rewrite the code was:

function impointBehavior_R2009b
%IMPOINTBEHAVIOR_R2009B shows the undesirable behavior when
%using the setString method in R2009b. 
 
  % Display the image in a figure window
  figure;  imshow('rice.png');
  h = impoint(gca,100,200);
 
  % Add a new position callback to set the text string
  h.addNewPositionCallback(@newPos_Callback);
 
  % Construct boundary constraint function so we can't go outside the axes
  fcn = makeConstrainToRectFcn('impoint',get(gca,'XLim'),get(gca,'YLim'));
 
  % Enforce boundary constraint function
  h.setPositionConstraintFcn(fcn);
 
  % Fire callback so we get initial text
  newPos_Callback(h.getPosition());
 
  function newPos_Callback(newPos)
    % Display the current point position in a text label
    h.setString(sprintf('(%1.0f,%1.0f)',newPos(1),newPos(2)))
  end %newPos_Callback
 
end %impointBehavior_R2009b

Unfortunately, when this code is run, dragging the mouse around the axes produces a trail of labels as shown below:

Before - buggy behavior

Before - buggy behavior

Opening up impoint.m in the editor and tracing the code revealed that impoint’s setString method creates a new text object each time it is used. I reported this to MATLAB and the bug is now documented on the MathWorks Support site (574846).

The solution

So how do we work around this bug to get to the behavior we want? One solution would be to rewrite the offending MATLAB code but this is somewhat risky in terms of maintainability and compatibility.

A more elegant solution is to subclass the impoint class and substitute the setString behavior we want. Looking at the impoint code we find that impoint is a subclass of imroi. In the imroi property declarations we see a number of undocumented properties that are protected. We can access these properties in a subclass but not outside the class. One of these undocumented properties is h_group which is an hggroup that contains the handle graphic objects that make up the impoint on the screen. The label, when created, becomes part of this hggroup with its Tag property set to ‘label’. When performing the setString method the behavior we want to see is that if the text object exists we want to update its String property. If it does not exist we want it to perform its existing functionality:

classdef impointtextupdate < impoint
%IMPOINTTEXTUPDATE subclasses impoint to override the setString
%method of impoint so that it does not create a new text object
%each time it is called.   
 
  methods
    function obj = impointtextupdate(varargin)
      obj = obj@impoint(varargin{:});
    end %impointtextupdate
 
    function setString(obj,str)
      %override impoint setString
 
      %check to see if there is already a text label
      label = findobj(obj.h_group,'Type','text','Tag','label');
 
      if isempty(label)
        %do the default behavior
        setString@impoint(obj,str);
      else
        %update the existing tag
        set(label(1),'String',str);
      end %if
    end %setString
 
  end %methods
end %impointtextupdate

Substituting calls to impoint with the new impointupdatetext subclass now produces the desired effect as shown below:

After - expected behavior

After - expected behavior

Conclusions

This case illustrates a couple of points:

  • Much of the existing code in the MATLAB toolboxes is being updated to the new object oriented syntax. This presents many opportunities to easily and elegantly modify the default behavior without modifying provided toolbox code In the example above we retain all the desirable behavior of impoint while overriding the undesirable behavior.
  • Many of the properties and methods in the provided toolbox objects are hidden or protected and are undocumented. It takes some simple detective work to find these out through examining the code. MATLAB is very generous in providing much of the existing code openly. Open the functions and classes you use in the editor to really find out how they work. Over the years I’ve learned and adopted a lot of useful MATLAB programming patterns by examining the code in the various toolboxes (there are a few coding horrors as well!).

I hope to explore some other under-documented features of the IPT and other toolboxes in future posts.

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Customizing listbox & editbox scrollbars

February 1st, 2010

A few days ago, a CSSM forum reader asked how to modify Matlab’s listbox scrollbars. Another user asked how to configure line-wrapping. I thought this is a good opportunity to describe how listbox and editbox scrollbars can be customized. The timing is particularly opportune, after I have recently described how the Matlab Editbox can be customized by accessing its underlying Java object using the FindJObj utility.

Both the listbox and the multi-line editbox uicontrols share a similar design: a multi-line Java control embedded within a JViewport within a JScrollPane (note that for historical reasons, the Java view-port class is called JViewport rather than the more standard camel-cased JViewPort). In addition to the view-port, the containing scroll-pane also contains two scrollbars (horizontal and vertical), as expected from standard Java scroll-panes.

JScrollPane components

JScrollPane components

Scrollbar policies

Control of the scroll-pane’s scrollbar behavior is done via the JScrollPane’s VerticalScrollBarPolicy and HorizontalScrollBarPolicy properties.

VerticalScrollBarPolicy accepts the self-explanatory values of:

  • VERTICAL_SCROLLBAR_ALWAYS (=22)
  • VERTICAL_SCROLLBAR_NEVER (=21)
  • and VERTICAL_SCROLLBAR_AS_NEEDED (=20)

HorizontalScrollBarPolicy accepts:

  • HORIZONTAL_SCROLLBAR_ALWAYS (=32)
  • HORIZONTAL_SCROLLBAR_NEVER (=31)
  • and HORIZONTAL_SCROLLBAR_AS_NEEDED (=30)

All these properties are static enumerated constants that can be referred using either their Java notation (e.g., JScrollPane.VERTICAL_SCROLLBAR_ALWAYS) or their equivalent numeric values. Using the non-numeric format is better, since it is more readable and the numeric values may change, but the choice is yours.

By default, Matlab implements a VerticalScrollBarPolicy of VERTICAL_SCROLLBAR_ALWAYS for sufficiently tall uicontrols (>20-25 pixels, which practically means always) and VERTICAL_SCROLLBAR_NEVER for shorter uicontrols.

For the horizontal scrollbar, Matlab implements a HorizontalScrollBarPolicy of HORIZONTAL_SCROLLBAR_NEVER for all editboxes and for narrow listboxes (<35 pixels), and HORIZONTAL_SCROLLBAR_AS_NEEDED for wide listboxes.

These settings are generally satisfactory. However, in some cases users may wish to modify the settings. For example, the default VerticalScrollBarPolicy setting of VERTICAL_SCROLLBAR_ALWAYS causes the vertical scrollbar to appear even when unneeded (the entire editbox content is visible). Also, we may wish to have a horizontal scrollbar on narrow listboxes and editboxes, something that the standard HORIZONTAL_SCROLLBAR_NEVER prevents. In both cases, a *_SCROLLBAR_AS_NEEDED policy might be more appropriate.

To modify these settings, we simply need to get the uicontrol’s underlying Java reference handle (using the FindJObj utility), and modify the appropriate property. For example:

% Create a multi-line (Max>1) editbox uicontrol
hEditbox = uicontrol('style','edit', 'max',5, ...);
 
% Get the Java scroll-pane container reference
jScrollPane = findjobj(hEditbox);
 
% Modify the scroll-pane's scrollbar policies
% (note the equivalent alternative methods used below)
set(jScrollPane,'VerticalScrollBarPolicy',20);  % or: jScrollPane.VERTICAL_SCROLLBAR_AS_NEEDED
jScrollPane.setHorizontalScrollBarPolicy(30);  % or: jScrollPane.HORIZONTAL_SCROLLBAR_AS_NEEDED

default scrollbars (VERTICAL_SCROLLBAR_ALWAYS)

default scrollbars (VERTICAL_SCROLLBAR_ALWAYS)

non-default scrollbars (VERTICAL_SCROLLBAR_AS_NEEDED)     non-default scrollbars (VERTICAL_SCROLLBAR_AS_NEEDED)

non-default scrollbars (VERTICAL_SCROLLBAR_AS_NEEDED)

Note that updating the uicontrol handle (hEditbox)’s Position property has the side-effect of automatically reverting the scrollbar policies to their default values (HORIZONTAL_SCROLLBAR_NEVER and VERTICAL_SCROLLBAR_ALWAYS/NEVER). This also happens whenever the uicontrol is resized interactively (by resizing its container figure window, for example). It is therefore advisable to set jScrollPane’s ComponentResizedCallback property to “unrevert” the policies:

cbStr = sprintf('set(gcbo,''VerticalScrollBarPolicy'',%d)', ...
                jScrollPane.VERTICAL_SCROLLBAR_AS_NEEDED);
hjScrollPane = handle(jScrollPane,'CallbackProperties');
set(hjScrollPane,'ComponentResizedCallback',cbStr);

Line-wrapping

By default, line-wrapping is turned on, effectively disabling horizontal scrolling (which is why Matlab set the HorizontalScrollBarPolicy to HORIZONTAL_SCROLLBAR_NEVER. However, in some cases it may be more useful to turn line-wrapping off and horizontal scrolling on using the TextArea’s setWrapping() method. Here’s a usage example:

jViewPort = jScrollPane.getViewport;
jEditbox = jViewPort.getComponent(0);
jEditbox.setWrapping(false);  % do *NOT* use set(...)!!!
newPolicy = jScrollPane.HORIZONTAL_SCROLLBAR_AS_NEEDED;
set(jScrollPane,'HorizontalScrollBarPolicy',newPolicy);

multi-line editbox with wrapping on

multi-line editbox with wrapping on

multi-line editbox with wrapping off

multi-line editbox with wrapping off

Notes:

  1. setWrapping() only works for the default EditorKit, and fails for HTMLEditorKit – This is due to HTML’s inherent wrapping behavior, as can easily be seen in any browser webpage.
  2. while setWrapping() may seem like a regular setter method for a Wrapping property, in reality it is not. Actually, set(jEditbox,’wrapping’,flag) may crash Matlab. So, always use the setWrapping(flag) method variant, which is entirely safe.
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setPrompt - Setting the Matlab Desktop prompt

January 25th, 2010

A few days ago, a reader emailed me with a challenge to modify the standard matlab Command-Window prompt from “>> ” to some other string, preferably a dynamic prompt with the current timestamp. At first thought this cannot be done: The Command-Window prompts are hard-coded and to the best of my knowledge cannot be modified via properties or system preferences.

So the prompt can (probably) not be modified in advance, but what if it could be modified after being displayed? It is true that my cprintf utility modifies the Command-Window contents in order to display formatted text in a variety of font colors. But this case is different since cprintf runs once synchronously (user-invoked), whereas the prompt appears asynchronously multiple times.

There are two methods of handling multiple asynchronous events in Matlab: setting a callback on the object, and setting a PostSet handle.listener (or schema.listener) on the relevant object property. The first of these methods is a well-known Matlab practice, although we shall see that it uses an undocumented callback and functionality; the PostSet method is entirely undocumented and not well-known and shall be described in some later article. I decided to use the callback method to set the prompt - interested readers can try the PostSet method.

Setting the Command Window’s callback

The solution involved finding the Command-Window reference handle, and setting one of its many callbacks, in our case CaretUpdateCallback. This callback is fired whenever the desktop text is modified, which is an event we trap to replace the displayed prompt:

% Get the reference handle to the Command Window text area
jDesktop = com.mathworks.mde.desk.MLDesktop.getInstance;
try
  cmdWin = jDesktop.getClient('Command Window');
  jTextArea = cmdWin.getComponent(0).getViewport.getComponent(0);
catch
  commandwindow;
  jTextArea = jDesktop.getMainFrame.getFocusOwner;
end
 
% Instrument the text area's callback
if nargin && ~isempty(newPrompt) && ~strcmp(newPrompt,'>> ')
  set(jTextArea,'CaretUpdateCallback',{@setPromptFcn,newPrompt});
else
  set(jTextArea,'CaretUpdateCallback',[]);
end

Now that we have the Command-Window object callback set, we need to set the logic of prompt replacement - this is done in the internal Matlab function setPromptFcn. Here is its core code:

% Does the displayed text end with the default prompt?
% Note: catch a possible trailing newline
try jTextArea = jTextArea.java;  catch,  end  %#ok
cwText = get(jTextArea,'Text');
pos = strfind(cwText(max(1,end-3):end),'>> ');
if ~isempty(pos)
  % Short prompts need to be space-padded
  newLen = jTextArea.getCaretPosition;
  if length(newPrompt)<3
    newPrompt(end+1:3) = ' ';
  elseif length(newPrompt)>3
    fprintfStr = newPrompt(1:end-3);
    fprintf(fprintfStr);
    newLen = newLen + length(fprintfStr);
  end
 
  % The Command-Window text should be modified on the EDT
  awtinvoke(jTextArea,'replaceRange(Ljava.lang.String;II)',...
            newPrompt(end-2:end), newLen-3, newLen);
  awtinvoke(jTextArea,'repaint()');
end

In this code snippet, note that we space-pad prompt string that are shorter than 3 characters: this is done to prevent an internal-Matlab mixup when displaying additional text - Matlab “knows” the Command-Window’s text position and it gets mixed up if it turns out to be shorter than expected.

Also note that I use the semi-documented awtinvoke function to replace the default prompt (and an automatically-appended space) on the Event-Dispatch Thread (more on this in a future article). Since Matlab R2008a, I could use the more convenient javaMethodEDT function, but I wanted my code to work on all prior Matlab 7 versions, where javaMethodEDT was not yet available.

Preventing callback re-entry

The callback snippet above would enter an endless loop if not changed: whenever the prompt is modified the callback would have been re-fired, the prompt re-modified and so on endlessly. There are many methods of preventing callback re-entry - here’s the one I chose:

function setPromptFcn(jTextArea,eventData,newPrompt)
 
  % Prevent overlapping reentry due to prompt replacement
  persistent inProgress
  if isempty(inProgress)
    inProgress = 1;  %#ok unused
  else
    return;
  end
 
  try
    % *** Prompt modification code goes here ***
 
    % force prompt-change callback to fizzle-out...
    pause(0.02);
  catch
    % Never mind - ignore errors...
  end
 
  % Enable new callbacks now that the prompt has been modified
  inProgress = [];
 
end  % setPromptFcn

Handling multiple prompt types

I now wanted my function to handle both static prompt strings (like: ‘[Yair] ‘) and dynamic prompts (like: ‘[25-Jan-2010 01:00:51] ‘). This is done by accepting string-evaluable strings/functions:

% Try to evaluate the new prompt as a function
try
  origNewPrompt = newPrompt;
  newPrompt = feval(newPrompt);
catch
  try
    newPrompt = eval(newPrompt);
  catch
    % Never mind - probably a string...
  end
end
if ~ischar(newPrompt) && ischar(origNewPrompt)
  newPrompt = origNewPrompt;
end

File Exchange submission

I then added some edge-case error handling and wrapped everything in a single utility called setPrompt that is now available on the File Exchange.

In the future, if I find time, energy and interest, maybe I’ll combine cprintf’s font-styling capabilities, to enable setting colored prompts.

Setting a continuously-updated timestamp prompt

Using the code above, we can now display a dynamic timestamp prompt, as follows:

setPrompt usage examples

setPrompt usage examples

However, the displayed timestamp is somewhat problematic in the sense that it indicates the time of prompt creation rather than the time that the associated Command-Window command was executed. In the screenshot above, [25-Jan-2010 01:29:42] is the time that the 234 command was executed, not the time that the setPrompt command was executed. This is somewhat misleading. It would be better if the last (current) timestamp was continuously updated and would therefore always display the latest command’s execution time. This can be done using a Matlab timer as follows:

% This is entered in the main function before setting the prompt:
stopPromptTimers;
if nargin && strcmpi(newPrompt,'timestamp')
  % Update initial prompt & prepare a timer to continuously update it
  newPrompt = @()(['[',datestr(now),'] ']);
  start(timer('Tag','setPromptTimer', 'Name','setPromptTimer', ...
              'ExecutionMode','fixedDelay', 'ObjectVisibility','off', ...
              'Period',0.99, 'StartDelay',0.5, ...
              'TimerFcn',{@setPromptTimerFcn,jTextArea}));
end
 
% Stop & delete any existing prompt timer(s)
function stopPromptTimers
  try
    timers = timerfindall('tag','setPromptTimer');
    if ~isempty(timers)
      stop(timers);
      delete(timers);
    end
  catch
    % Never mind...
  end
end  % stopPromptTimers
 
% Internal timer callback function
function setPromptTimerFcn(timerObj,eventData,jTextArea)
  try
    try jTextArea = jTextArea.java;  catch,  end  %#ok
    pos = getappdata(jTextArea,'setPromptPos');
    newPrompt = datestr(now);
    awtinvoke(jTextArea,'replaceRange(Ljava.lang.String;II)',...
              newPrompt, pos, pos+length(newPrompt));
    awtinvoke(jTextArea,'repaint()');
  catch
    % Never mind...
  end
end  % setPromptTimerFcn

Can you come up with some innovative prompts? If so, please share them in a comment below.

Update 2010-Jan-26: The code in this article was updated since it was first published yesterday.

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Rich Matlab editbox contents

January 20th, 2010

In an earlier post, I mentioned that most Matlab uicontrols support HTML strings. Unfortunately, HTML is not supported in multi-line editbox contents. Today I will show how this limitation can be removed for a multi-line editbox, thereby enabling rich contents (enabling HTML for a single-line editbox needs a different solution).

We first need to get the editbox’s underlying Java object, as explained in my previous article about the findjobj utility. Since a multi-line editbox is contained within a scroll-pane, we need to dig within the scrollpane container to find the actual editable area object:

% Create a multi-line (Max>1) editbox uicontrol
hEditbox = uicontrol('style','edit', 'max',5, ...);
 
% Get the Java scroll-pane container reference
jScrollPane = findjobj(hEditbox);
 
% List the scroll-pane's contents:
>> jScrollPane.list
com.mathworks.hg.peer.utils.UIScrollPane[,0,0,100x50,...]
 javax.swing.JViewport[,1,1,81x48,...]
  com.mathworks.hg.peer.EditTextPeer$hgTextEditMultiline[,0,0,81x48,...,kit=javax.swing.text.StyledEditorKit@ce05fc,...]
 com.mathworks.hg.peer.utils.UIScrollPane$1[,82,1,17x48,...]
  com.sun.java.swing.plaf.windows.WindowsScrollBarUI$WindowsArrowButton[,0,31,17x17,...]
  com.sun.java.swing.plaf.windows.WindowsScrollBarUI$WindowsArrowButton[,0,0,17x17,...]
 com.mathworks.hg.peer.utils.UIScrollPane$2[,0,0,0x0,...]
  com.sun.java.swing.plaf.windows.WindowsScrollBarUI$WindowsArrowButton[,0,0,0x0,...]
  com.sun.java.swing.plaf.windows.WindowsScrollBarUI$WindowsArrowButton[,0,0,0x0,...]

In this listing, we see that jScrollPane contains a JViewport and two scrollbars (horizontal and vertical), as expected from standard Java scroll-panes. We need the internal hgTextEditMultiline object:

jViewPort = jScrollPane.getViewport;
jEditbox = jViewPort.getComponent(0);

The retrieved jEditbox reference, is an object of class com.mathworks.hg.peer.EditTextPeer$hgTextEditMultiline, which indirectly extends the standard javax.swing.JTextPane. The default Matlab implementation of the editbox uicontrol simply enables a multi-line vertical-scrollable text area using the system font. However, the underlying JTextPane object enables many important customizations, including the ability to specify different font attributes (size/color/bold/italic etc.) and paragraph attributes (alignment etc.) for text segments (called style runs) and the ability to embed images, HTML and other controls.

Setting rich contents can be done in several alternative ways. From easiest to hardest:

Setting page URL

Use the setPage(url) method to load a text page from the specified URL (any pre-existing editbox content will be erased). The page contents may be plain text, HTML or RTF. The content type will automatically be determined and the relevant StyledEditorKit and StyledDocument will be chosen for that content. Additional StyledEditorKit content parsers can be registered to handle additional content types. Here’s an example loading an HTML page:

jEditbox.setPage('http://tinyurl.com/c27zpt');

where the URL’s contents are:

<html><body>
<img src="images/dukeWaveRed.gif" width="64" height="64">
This is an uneditable <code>JEditorPane</code>, which was
<em>initialized</em> with <strong>HTML</strong> text 
<font size=-2>from</font> a <font size=+2">URL</font>.
<p>An editor pane uses specialized editor kits to read, write,
display, and edit text of different formats. The Swing text 
package includes editor kits for plain text, HTML, and RTF. 
You can also develop custom editor kits for other formats. 
<script language="JavaScript" 
  src="/js/omi/jsc/s_code_remote.js"></script>
</body></html>

Matlab editbox initialized from an HTML webpage URL

Matlab editbox initialized from an HTML webpage URL

Setting the EditorKit and ContentType

Set the requested StyledEditorKit (via setEditorKit()) or ContentType properties and then use setText() to set the text, which should be of the appropriate content type. Note that setting EditorKit or ContentType clears any existing text and left-aligns the contents (hgTextEditMultiline is center aligned by default). Also note that HTML <div>s get their own separate lines and that <html> and <body> opening and closing tags are accepted but unnecessary. For example:

jEditbox.setEditorKit(javax.swing.text.html.HTMLEditorKit);
% alternative: jEditbox.setContentType('text/html');
htmlStr = ['<b><div style="font-family:impact;color:green">'...
           'Matlab</div></b> GUI is <i>' ...
           '<font color="red">highly</font></i> customizable'];
jEditbox.setText(htmlStr)

HTML contents in a Matlab editbox

HTML contents in a Matlab editbox

Let’s show another usage example, of an event log file, spiced with icons and colored text based on event severity. First, define the logging utility function (the icon filenames may need to be changed based on your Matlab release):

function logMessage(jEditbox,text,severity)
   % Ensure we have an HTML-ready editbox
   HTMLclassname = 'javax.swing.text.html.HTMLEditorKit';
   if ~isa(jEditbox.getEditorKit,HTMLclassname)
      jEditbox.setContentType('text/html');
   end
 
   % Parse the severity and prepare the HTML message segment
   if nargin<3,  severity='info';  end
   switch lower(severity(1))
      case 'i',  icon = 'greenarrowicon.gif'; color='gray';
      case 'w',  icon = 'demoicon.gif';       color='black';
      otherwise, icon = 'warning.gif';        color='red';
   end
   icon = fullfile(matlabroot,'toolbox/matlab/icons',icon);
   iconTxt =['<img src="file:///',icon,'" height=16 width=16>'];
   msgTxt = ['&nbsp;<font color=',color,'>',text,'</font>'];
   newText = [iconTxt,msgTxt];
   endPosition = jEditbox.getDocument.getLength;
   if endPosition>0, newText=['<br/>' newText];  end
 
   % Place the HTML message segment at the bottom of the editbox
   currentHTML = char(jEditbox.getText);
   jEditbox.setText(strrep(currentHTML,'</body>',newText));
   endPosition = jEditbox.getDocument.getLength;
   jEditbox.setCaretPosition(endPosition); % end of content
end

Now, let’s use this logging utility function to log some messages:

logMessage(jEditbox, 'a regular info message...');
logMessage(jEditbox, 'a warning message...', 'warn');
logMessage(jEditbox, 'an error message!!!', 'error');
logMessage(jEditbox, 'a regular message again...', 'info');

Rich editbox contents (a log file)

Rich editbox contents (a log file)

HTML editboxes are normally editable, images included. In actual applications, we may wish to prevent editing the display log. To do this, simply call jEditbox.setEditable(false).

Setting a hyperlink handler is easy: first we need to ensure that we’re using an HTML content-type document. Next, set the editbox to be uneditable (hyperlinks display correctly when the editbox is editable, but are unclickable), using jEditbox.setEditable(false). Finally, set the callback function in the editbox’s HyperlinkUpdateCallback property:

jEditbox.setContentType('text/html');
jEditbox.setText('link: <a href= "http://UndocumentedMatlab.com">UndocumentedMatlab.com</a>');
jEditbox.setEditable(false);
hjEditbox = handle(jEditbox,'CallbackProperties');
set(hjEditbox,'HyperlinkUpdateCallback',@linkCallbackFcn);
 
function linkCallbackFcn(src,eventData)
   url = eventData.getURL;      % a java.net.URL object
   description = eventData.getDescription; % URL string
   jEditbox = eventData.getSource;
   switch char(eventData.getEventType)
      case char(eventData.getEventType.ENTERED)
               disp('link hover enter');
      case char(eventData.getEventType.EXITED)
               disp('link hover exit');
      case char(eventData.getEventType.ACTIVATED)
               jEditbox.setPage(url);
   end
end

Hyperlink in editbox

Hyperlink in editbox

Setting the style runs programmatically

Setting the styles programmatically, one style run after another, can be done via the text-pane’s Document property object. Individual character ranges can be set using the Document’s setCharacterAttributes method, or entire style runs can be inserted via insertString. Attributes are updated using the static methods available in javax.swing.text.StyleConstants. These methods include setting character attributes (font/size/bold/italic/strike-through/underline/subscript/superscript and foreground/background colors), paragraph attributes (indentation/spacing/tab-stops/bidi), image icons and any Swing Component (buttons etc.). Here is the end result:

Rich editbox contents: images, controls & font styles

Rich editbox contents: images, controls & font styles

Note that if a styled multi-line editbox is converted to a single-line editbox (by setting hEditbox’s Max property to 1), it loses all style information, embedded images and components. Returning to multi-line mode will therefore show only the plain-text.

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FindJObj GUI - display container hierarchy

January 12th, 2010

In my previous post, I explained how the findjobj utility can be used to access a Matlab component’s underlying Java component. Findjobj has another role: displaying the component hierarchy of complex Matlab containers such as the figure window, GUIDE or the Editor.

When findjobj is called with no output arguments, the function infers that the user requests to see the GUI version, rather than to get the control’s Java handle:

>> findjobj(gcf);  % or: findjobj(gcf)

FindJObj GUI (click to zoom)

FindJObj GUI (click to zoom)

There are several note-worthy aspects in this graphical hierarchy presentation:

The hierarchy tree itself is displayed using the internal com.mathworks.hg.peer.UITreePeer Java object. This is the object that underlies the semi-documented uitree function. The hierarchy sub-components are presented as tree nodes, each having a separate icon based on the component type. In some cases (toolbar buttons for example), the component’s icon image is used for its corresponding tree node. A javax.swing.JProgressBar is presented while the tree is being populated, an action that can take a few seconds depending on the target figure’s complexity. Some tree branches which are normally uninteresting are automatically collapsed: hidden containers (these are also grayed-out), menubars, toolbars and scrollbars. In parallel to the Java container hierarchy, a separate tree branch is presented with the corresponding Matlab (Handle-Graphics, or HG) hierarchy.

Another GUI example - note the hidden (gray) items, the HG tree branch and the auto-collapsed MJToolBar container

Another GUI example - note the hidden (gray) items, the HG tree branch and the auto-collapsed MJToolBar container

Each node item gets a unique tooltip (see top screenshot above). Similarly, a unique context-menu (right-click menu) is attached to each node item with actions that are relevant for that node:

Item-specific context-menu

Item-specific context-menu

Finally, a node-selection callback is attached to the tree, that will flash a red border around the GUI control when its corresponding Java node-item is clicked/selected:

FindJObj - flashing red border around a toolbar icon

FindJObj - flashing red border around a toolbar icon

Once the tree was done, I set out to display and enable modifications of component properties and callbacks in separate adjacent panels. I used the internal com.mathworks.mlwidgets.inspector.PropertyView component to display the properties (this is the JIDE component that underlies the built-in inspect function). To prevent a JIDE run-time alert, I called com.mathworks.mwswing.MJUtilities.initJIDE. A label is added to the table’s header, displaying the currently selected sub-component’s class (e.g., “javax.swing.JButton”), and a tooltip with a color-coded list of all the control’s properties.

The callbacks table was implemented using com.jidesoft.grid.TreeTable to enable easy column resizing, but this is otherwise used as a simple data table. A checkbox was added to filter out the 30-odd standard Swing callbacks, which are non-unique to the selected sub-component (tree node). All the panels - tree, properties and callbacks - are then placed in resizable javax.swing.JSplitPanes and presented to the user.

I have omitted mention of some other undocumented features in findjobj. After all, space here is limited and the function is over 2500 lines long. I encourage you to download the utility and explore the code, and I gladly welcome your feedback.

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