There is a lovely trick in Mathematica that creates a table as a side-effect of evaluating function-calls-as-rewrite-rules. Consider the classic slow-fibonacci

```
fib[1] = 1
fib[2] = 1
fib[n_] := fib[n-1] + fib[n-2]
```

The first two lines create table entries for the inputs 1 and 2. This is exactly the same as saying

```
fibTable = {};
fibTable[1] = 1;
fibTable[2] = 1;
```

in JavaScript. The third line of Mathematica says "please install a rewrite rule that will replace any occurrence of `fib[n_]`

, after substituting the pattern variable `n_`

with the actual argument of the occurrence, with `fib[n-1] + fib[n-2]`

." The rewriter will iterate this procedure, and eventually produce the value of `fib[n]`

after an exponential number of rewrites. This is just like the recursive function-call form that we get in JavaScript with

```
function fib(n) {
var result = fibTable[n] || ( fib(n-1) + fib(n-2) );
return result;
}
```

Notice it checks the table first for the two values we have explicitly stored before making the recursive calls. The Mathematica evaluator does this check automatically, because the order of presentation of the rules is important -- Mathematica checks the more specific rules first and the more general rules later. That's why Mathematica has two assignment forms, `=`

and `:=`

: the former is for specific rules whose right-hand sides can be evaluated at the time the rule is defined; the latter is for general rules whose right-hand sides must be evaluated when the rule is applied.

Now, in Mathematica, if we say

```
fib[4]
```

it gets rewritten to

```
fib[3] + fib[2]
```

then to

```
fib[2] + fib[1] + 1
```

then to

```
1 + 1 + 1
```

and finally to 3, which does not change on the next rewrite. You can imagine that if we say `fib[35]`

, we will generate enormous expressions, fill up memory, and melt the CPU. But the trick is to replace the final rewrite rule with the following:

```
fib[n_] := fib[n] = fib[n-1] + fib[n-2]
```

This says "please replace every occurrence of `fib[n_]`

with an expression that will install a new specific rule for the value of `fib[n]`

and also produce the value." This one runs much faster because it expands the rule-base -- the table of values! -- at run time.

We can do likewise in JavaScript

```
function fib(n) {
var result = fibTable[n] || ( fib(n-1) + fib(n-2) );
fibTable[n] = result;
return result;
}
```

This runs MUCH faster than the prior definition of fib.

This is called "automemoization" [sic -- not "memorization" but "memoization" as in creating a memo for yourself].

Of course, in the real world, you must manage the sizes of the tables that get created. To inspect the tables in Mathematica, do

```
DownValues[fib]
```

To inspect them in JavaScript, do just

```
fibTable
```

in a REPL such as that supported by Node.JS.