I am a big fan of Stephen Wolfram, but he is definitely one not shy of tooting his own horn. In many references he extols mathematica as a different symbolic programming paradigm. I am not a mathematica user, so my question is what is this symbolic programming, and how does it compare to functional languages such as Haskell?

You can think of Mathematica's symbolic programming as a searchandreplace system where you program by specifying searchandreplace rules. For instance you could specify the following rule
Next time you use
Now, whenever you use You can emulate functional programming by using your replacement rules as function. For instance, if you want to define a function that adds, you could do
Now
Now, Here's an example of an interactive replacement rule
Here, Rules can be defined using conditions which themselves need to go through rulerewriting in order to produce
Here, Mathematica's evaluator greedily rewrites every pattern with one of the rules that apply for that symbol. Sometimes you want to have finer control, and in such case you could define your own rules and apply them manually like this
This will apply rules defined in One drawback of current Mathematica version comes up when you need to use Mathematica's default evaluator (to make use of 


When I hear the phrase "symbolic programming", LISP, Prolog and (yes) Mathematica immediately leap to mind. I would characterize a symbolic programming environment as one in which the expressions used to represent program text also happen to be the primary data structure. As a result, it becomes very easy to build abstractions upon abstractions since data can easily be transformed into code and vice versa. Mathematica exploits this capability heavily. Even more heavily than LISP and Prolog (IMHO). As an example of symbolic programming, consider the following sequence of events. I have a CSV file that looks like this:
I read that file in:
Is the result data or code? It is both. It is the data that results from reading the file, but it also happens to be the expression that will construct that data. As code goes, however, this expression is inert since the result of evaluating it is simply itself. So now I apply a transformation to the result:
Without dwelling on the details, all that has happened is that
Yes, still inert. However, by a remarkable coincidence this last result just happens to be a list of valid directives in Mathematica's builtin domainspecific language for graphics. One last transformation, and things start to happen:
Actually, you would not see that last result. In an epic display of syntactic sugar, Mathematica would show this picture of red and green circles: But the fun doesn't stop there. Underneath all that syntactic sugar we still have a symbolic expression. I can apply another transformation rule:
Presto! The red circle became black. It is this kind of "symbol pushing" that characterizes symbolic programming. A great majority of Mathematica programming is of this nature. Functional vs. SymbolicI won't address the differences between symbolic and functional programming in detail, but I will contribute a few remarks. One could view symbolic programming as an answer to the question: "What would happen if I tried to model everything using only expression transformations?" Functional programming, by contrast, can been seen as an answer to: "What would happen if I tried to model everything using only functions?" Just like symbolic programming, functional programming makes it easy to quickly build up layers of abstractions. The example I gave here could be easily be reproduced in, say, Haskell using a functional reactive animation approach. Functional programming is all about function composition, higher level functions, combinators  all the nifty things that you can do with functions. Mathematica is clearly optimized for symbolic programming. It is possible to write code in functional style, but the functional features in Mathematica are really just a thin veneer over transformations (and a leaky abstraction at that, see the footnote below). Haskell is clearly optimized for functional programming. It is possible to write code in symbolic style, but I would quibble that the syntactic representation of programs and data are quite distinct, making the experience suboptimal. Concluding RemarksIn conclusion, I advocate that there is a distinction between functional programming (as epitomized by Haskell) and symbolic programming (as epitomized by Mathematica). I think that if one studies both, then one will learn substantially more than studying just one  the ultimate test of distinctness. Leaky Functional Abstraction in Mathematica?Yup, leaky. Try this, for example:
Duly reported to, and acknowledged by, WRI. The response: avoid the use of 


As others here already mentioned, Mathematica does a lot of term rewriting. Maybe Haskell isn't the best comparison though, but Pure is a nice functional termrewriting language (that should feel familiar to people with a Haskell background). Maybe reading their Wiki page on term rewriting will clear up a few things for you: 


Mathematica is using term rewriting heavily. The language provides special syntax for various forms of rewriting, special support for rules and strategies. The paradigm is not that "new" and of course it's not unique, but they're definitely on a bleeding edge of this "symbolic programming" thing, alongside with the other strong players such as Axiom. As for comparison to Haskell, well, you could do rewriting there, with a bit of help from scrap your boilerplate library, but it's not nearly as easy as in a dynamically typed Mathematica. 

