Let's walk through the evaluation of `flog[1, 2]`

, step-by-step...

**flog[1, 2]**

When this expression is evaluated, Mathematica will substitute `1`

for `x`

and `2`

for `y`

in the definition of `flog`

given in the question. This yields the next step in our tour:

**flog[1, 2] =
f[1, 2] /. v_ :> (PutAppend[Unevaluated[flog[1, 2] = v;], $runningLogFile];
v)**

Note carefully that the assignment here, `flog[1, 2] = ...`

, is part of the definition of `flog`

itself.

`/.`

is an infix operator that is an alternate representation of the ReplaceAll function. `ReplaceAll`

will apply a replacement rule to the value of the first argument. Hold that thought -- we'll come back to it. The first argument is `flog[1, 2] = f[1, 2]`

. This expression will evaluate `f[1, 2]`

and then assign the result to `flog[1, 2]`

. For the sake of discussion, let's assume that `f[1, 2]`

returns `345`

. Thus, a new definition will be added to `flog`

, namely `flog[1, 2] = 345`

. After assignment, we can check the definition of `flog`

:

Observe that where `flog`

only had a single definition initially but now it has two -- the newly added `flog[1, 2]`

definition caching the result of that call. This is frequently called "memoization".

`flog[1, 2] = 345`

may have the side-effect of establishing a new definition for `flog`

but, like every expression in Mathematica, it yields a value as well. The value is `345`

which, after much ado, will be the first argument to `ReplaceAll`

.

The second argument to `ReplaceAll`

is an invocation of the `:>`

operator, an infix expression of the RuleDelayed function. In an effort to keep this post to a manageable size, we'll simply note that the rule evaluates to itself in this context.

So, now we have an expression that involves `/.`

to evaluate...

**345 /. v_ :> (PutAppend[Unevaluated[flog[1, 2] = v;], $runningLogFile]; v**

A replacement expression matches its first argument (`345`

) with the pattern component of the replacement rule (`v_`

). `v_`

matches `345`

(or anything else for that matter) and gives `345`

the name `v`

for purposes of replacement. `ReplaceAll`

then substitutes `345`

for every occurrence of `v`

in the right hand side of the rule. The result is the next expression to be evaluated...

**(PutAppend[Unevaluated[flog[1, 2] = 345;], $runningLogFile]; 345)**

Here we have two expressions separated by a semicolon. Incidentally, `;`

is an infix operator that expands to CompoundExpression. The first expression involves PutAppend which writes the value of its first argument to the file named as the value of the second argument. Note, however, that the first argument is wrapped in Unevaluated. This suppresses the evaluation of the first argument so that it will be written exactly as-is to the file: `flog[1, 2] = 345;`

. Should the current Mathematica session end, the written expression can be read into a future Mathematica session to re-establish the memoized result for `flog[1, 2]`

.

`CompoundExpression`

discards the value of all arguments except the last. Here, the last argument is `345`

. Since we have come to the end of our expression, this will be the final return value of the original call. That is, `flog[1, 2]`

returns `345`

-- although as we saw there were side-effects that saved this result to memory and disk for future reference.

**Future calls to **`flog[1, 2]`

Now if `flog[1, 2]`

is called again, Mathematica will find the new definition `flog[1, 2] = 345`

. `345`

will be returned directly, without any of the complications that we discussed above. In particular, it won't even call `f[1, 2]`

again. This, of course, was the whole motivation for this example. The assumption was that `f`

was very expensive to calculate, justifying all of these gymnastics to minimize the number of times that calculation occurs.