What are some possible ways to implement a linked list in MATLAB?

Note: I am asking this question for pedagogical value, not practical value. I realize that if you're actually rolling your own linked list in MATLAB, you're probably doing something wrong. However, I'm a TA for a class that is MATLAB-intensive this semester, and my goal in asking this question is to understand the general structure of the language better. As MATLAB's general purpose programming facilities are a bit unusual, I feel a question like this will help me understand them.

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I came across this today. I haven't read it, but it may be of use to you: mathworks.de/access/helpdesk/help/techdoc/index.html?/access/… –  Lucas Sep 12 '09 at 0:42
@Lulu you should turn your comment into an answer. –  Dima Sep 13 '09 at 15:15
Pure MATLAB implementation will have terrible performance - see stackoverflow.com/questions/1446281/matlabs-garbage-collector –  Mikhail Nov 7 '10 at 6:42

I have watched a bit the function of gnovice. I think what the most wannts is not a real linked list of C++ (I think you can generate a linked list only with classes in matlab) but just a general object where you can store random matlab arrays. From the sketch of gnovice I have generated the following:

``````function listObject = listfuncs()

data = cell(0);
'delete_last',@delete_last,'GET_first',@GET_first,'GET_last',@GET_last,'GET',@GET);

function display_list
%# Displays the data in the list
disp(data);
end

function N = listlength
%# Numbers of elements in list
N = length(data);
end

data = [datain;data];
end

data = [datain(:);data];
end

data = [data;datain];
end

data = [data;datain(:)];
end

%# Adds a set of data values after an index in the list, or at the end
%#   of the list if the index is larger than the number of list elements
index = min(index,numel(data));
data = [data(1:index) datain data(index+1:end)];
end

%# Adds a set of data values after an index in the list, or at the end
%#   of the list if the index is larger than the number of list elements
index = min(index,numel(data));
data = [data(1:index) datain(:) data(index+1:end)];
end

function set_element(datain,index)
%# function to just change element at position index
data{index} = datain;
end

function delete_element(index)
%# Deletes an element at an index in the list
if (index<=length(data) && index>0)
data(index) = [];
end
end

function delete_first()
%# Deletes fisrt element
data = data(2:end);
end

function delete_last()
%# Deletes fisrt element
data = data(1:end-1);
end

function dataout = GET_first()
%# get first element
dataout = data{1};
end

function dataout = GET_last()
%# get last element
dataout = data{end};
end

function dataout = GET(index)
%# get element at index here the cell can be transformed to standard arrays
dataout = cell2mat(data(index));
end

end
``````

I use cells as data so I can store random objects. Maybe some of you have some betters ideas

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The link Lulu suggested in the comments is probably the choice I would make if I were wanting to implement a linked list in MATLAB. However, this approach would stray off into the object-oriented features of MATLAB, which may not be what you want since you mention wanting "to understand the general structure of the language better." As such, you may do better with a simpler example that incorporates general core features of MATLAB programming.

A number of general features have been mentioned in other answers, such as matrices and matrix indexing, creating structures, and using nested functions and function handles. I'll go through an example that makes use of all these features and hopefully gives a nice introduction to a number of key concepts in MATLAB...

Sample code:

Save the code below in a file called `linked_list.m` on the MATLAB path:

``````function listObject = linked_list(values)

data = reshape(values,1,[]);
listObject = struct('display',@display_list,...
'delete',@delete_element);

function display_list
%# Displays the data in the list
disp(data);
end

%# Adds a set of data values after an index in the list, or at the end
%#   of the list if the index is larger than the number of list elements
index = min(index,numel(data));
data = [data(1:index) reshape(values,1,[]) data(index+1:end)];
end

function delete_element(index)
%# Deletes an element at an index in the list
data(index) = [];
end

end
``````

Description:

The function `linked_list` accepts an arbitrary-sized matrix and first reshapes it into a row vector using the RESHAPE function. This becomes the initial "linked list", stored in the variable `data`.

Next, a structure is created (using the STRUCT function) which has three elements: `display`, `addAfter`, and `delete`. Each of these fields stores a function handle to one of three functions that is nested within the parent function `linked_list`. These nested functions are able to access the variable `data` stored in the parent function.

The `listObject` structure is returned from `linked_list`. As long as this structure exists in the workspace, and thus as long as the function handles it contains exist, then the `data` variable will persist even after the function `linked_list` returns. We can then invoke the nested functions (using their handles) to modify the variable `data`. Here's an example...

First, create a linked list "object" and display the contents:

``````>> listObj = linked_list([1 2 3]);  %# A linked list with three elements
>> listObj.display()  %# Access the `display` field and invoke the function
1     2     3
``````

Next, add an element "4" after the second list element and display:

``````>> listObj.addAfter(4,2)  %# Access the `addAfter` field and invoke the function
>> listObj.display()
1     2     4     3
``````

And finally, delete the second list element and display:

``````>> listObj.delete(2)  %# Access the `delete` field and invoke the function
>> listObj.display()
1     4     3
``````

Note how the nested functions `add_element` and `delete_element` use matrix indexing to modify the variable `data`.

You can extend this example to create numerous other nested functions for operating on a linked list, adding new fields to the structure to store their function handles.

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nice solution but for big data could this be a bit slow, matlab needs to resize the data all the time. The class solution could be in my opinion more efficient. –  jamk Mar 18 at 9:16
I agree with jamk, this is a list, not a linked list, and hence it deletions and insertions are O(n). One would like to have a linked list to accept that random access is O(n) and deletions and insertions are O(1). –  Herbert May 17 at 13:15

I don't think you (or I) can do dynamic data structures 'in' MATLAB. We have to use MATLAB OO features and MATLAB classes. Since I think that these facilities are really a MATLAB wrapper around Java I make the bold claim that those facilities are outside MATLAB. A matter of semantics, I concede. If you want to do dynamic data structures with MATLAB, you have to use OO and classes, you can't do it with what I think of as the core language, which lacks pointers at the user level.

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I am trying to understand this deeper here. I need a dynamic balanced data-structure and this missing would mean I better choose a better language altogether. Can you clarify `"you have to use OO an classes"`. –  hhh Aug 28 at 16:27

``````>> a=java.util.LinkedList;
>> li=a.listIterator;
>> li.previous();
>> li.add([1 2 3 4 5]);
>> a

a =

[2.0, 77, 77.0, true, [D@66a917, Mr. Bill]

>> a.get(4)

ans =

1
2
3
4
5
``````

The one downside of this approach is because MATLAB doesn't have a way to marshal or serialize arbitrary MATLAB objects into Java, you're limited to floating point numbers, integers (need to cast them in MATLAB using `int8` etc.), booleans, strings, arrays, and Java objects.

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you could argue that being able to use java objects inside that linked list pretty much lets you store anything you want. –  Blindy Nov 13 '09 at 22:15
Well, you can store any Java object. You just can't store some MATLAB objects (like function handles, classes, or structs) in such a list, because they can't be marshalled from MATLAB-land into Java. –  Jason S Nov 13 '09 at 22:21
I like this, because this taught me that you can access basically any java.util.xyz this way. –  Herbert May 17 at 13:16

Creating a linked list in MATLAB isn't actually too bad with the new object oriented structure. I think what most people miss is that most pointer behavior can be achieved in MATLAB through the use of "handle classes".

``````classdef Node < handle

properties
next
prev
value
end

methods
function this = Node(inVal)
this.value = inVal;
end
end
end
``````

``````classdef LinkedList < handle

properties
firstNode
lastNode
end

methods
this.firstNode = newNode;
this.lastNode = newNode;
end
% Add newNode to the end of the list
newNode.prev = this.lastNode;
this.lastNode.next = newNode;
this.lastNode = newNode;
end
end
end
``````

I threw this together pretty quickly so I don't know if this will work as written. But if you're just interested in what the structure of a MATLAB linked list would look like, I'm sure this is enough to get you started.

The key concept here is the handle superclass. Whenever you create a class of type `handle`, you get a "pointer" to that class. That pointer can be passed to other functions or classes thus making it possible to have the nodes of the list point to other nodes.

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You can implement a linked list with a function handle to a nested function which keeps the linked list data in the nested parent's workspace.

--Loren

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Please care to elaborate a little on this approach. I got it very vaguely and not sure if even that is correct! PS. I am trying to implement tree structure in Matlab but with bidirectional traversal capabilities. –  Aamir Jul 12 '10 at 20:49
You can use a Matlab structure consisting of two fields `element` and `next`. `element` would be the element of the list, and `next` would be the index of the next node. Then you can have a global array of these, representing your "memory". You can define "malloc" function that adds an element to this array and returns its index. Then you have a `head` index that is the index of the first element in the list, and you can set the `next` fields appropriately to form a linked list.
If you really want to go crazy, you can also implement a `free` and do your own "memory management" by keeping track of the used and free nodes.