# Memoized recursive functions. How to make them fool-proof?

Memoized functions are functions which remember values they have found. Look in the doc center for some background on this in Mathematica, if necessary.

Suppose you have the following definition

``````f[0] = f[1] = 1
f[x_] := f[x] = f[x - 1] + f[x - 2]
``````

in one of your packages. A user may load the package and start asking right away f[1000]. This will trigger a \$RecursionLimit::reclim error message and abort. Even if the user then tries something smaller, say f[20], by now the definition of f is corrupt and the result is not good anymore.Of course the package developer might increase the recursion limit and warn the user, but my question is:

How can you improve the f definition so that if the user asks for f[1000] he/she gets the answer without any problem? I am interested in a way to trap the user input, analyze it and take whatever steps are necessary to evaluate f[1000].

I can easily imagine that one can change the recursion limit if the input is more than 255 (and then bring it back to the original level), but what I would really like to see is, if there is a way for the f to find out how many values it "knows" (fknownvalues) and accept any input <=fknownvalues+\$RecursionLimit without problems or increase the \$RecursionLimit if the input is higher.

• That looks tricky in the general case, especially if you have more than one parameter, and the recursion does not strictly decrease them in each step. – Thilo Sep 14 '11 at 10:22
• @Thilo If it weren't tricky I would not have asked it :-) – magma Sep 14 '11 at 10:34

Here is the code assuming that you can determine a value of `\$RecursionLimit` from the value of the input argument:

``````Clear[f];
Module[{ff},
ff[0] = ff[1] = 1;
ff[x_] := ff[x] = ff[x - 1] + ff[x - 2];

f[x_Integer] :=f[x] =
Block[{\$RecursionLimit = x + 5},
ff[x]
]]
``````

I am using a local function `ff` to do the main work, while `f` just calls it wrapped in `Block` with a proper value for `\$RecursionLimit`:

``````In[1552]:= f[1000]
Out[1552]=  7033036771142281582183525487718354977018126983635873274260490508715453711819693357974224
9494562611733487750449241765991088186363265450223647106012053374121273867339111198139373125
598767690091902245245323403501
``````

EDIT

If you want to be more precise with the setting of `\$RecursionLimit`, you can modify the part of the code above as:

``````f[x_Integer] :=
f[x] =
Block[{\$RecursionLimit = x - Length[DownValues[ff]] + 10},
Print["Current \$RecursionLimit: ", \$RecursionLimit];
ff[x]]]
``````

The `Print` statement is here for illustration. The value `10` is rather arbitrary - to get a lower bound on it, one has to compute the necessary depth of recursion, and take into account that the number of known results is `Length[DownValues[ff]] - 2` (since `ff` has 2 general definitions). Here is some usage:

``````In[1567]:= f[500]//Short

During evaluation of In[1567]:= Current \$RecursionLimit: 507
Out[1567]//Short= 22559151616193633087251269<<53>>83405015987052796968498626

In[1568]:= f[800]//Short

During evaluation of In[1568]:= Current \$RecursionLimit: 308
Out[1568]//Short= 11210238130165701975392213<<116>>44406006693244742562963426
``````

If you also want to limit the maximal `\$RecursionLimit` possible, this is also easy to do, along the same lines. Here, for example, we will limit it to 10000 (again, this goes inside `Module`):

``````f::tooLarge =
"The parameter value `1` is too large for single recursive step. \
Try building the result incrementally";
f[x_Integer] :=
With[{reclim = x - Length[DownValues[ff]] + 10},
(f[x] =
Block[{\$RecursionLimit = reclim },
Print["Current \$RecursionLimit: ", \$RecursionLimit];
ff[x]]) /; reclim < 10000];

f[x_Integer] := "" /; Message[f::tooLarge, x]]
``````

For example:

``````In[1581]:= f[11000]//Short

During evaluation of In[1581]:= f::tooLarge: The parameter value 11000 is too
large for single recursive step. Try building the result incrementally
Out[1581]//Short= f[11000]

In[1582]:=
f[9000];
f[11000]//Short

During evaluation of In[1582]:= Current \$RecursionLimit: 9007
During evaluation of In[1582]:= Current \$RecursionLimit: 2008
Out[1583]//Short= 5291092912053548874786829<<2248>>91481844337702018068766626
``````
• That is the part that @magma could "easily imagine". Would be nice if there was a way to figure out how far \$RecursionLimit really needs to be raised considering that there are already some memoized values. – Thilo Sep 14 '11 at 10:38
• @Thilo Please see my edit - based on magma's suggestion (assuming recursion depth as `input - number-of-known-results + const`. If it still exceeds that, my last code has a limit which would tell the user that the computation must be split into several steps. – Leonid Shifrin Sep 14 '11 at 11:00
• Since `\$RecursionLimit` is only set locally for this function, why not set it to `Infinity` in the `Block` instead of trying to come up with a "big enough" value? The safety problem still remains in any case: have a too deep recursion, and the kernel will crash. I am not aware of any way to determine the largest crash-safe `\$RecursionLimit`, if anyone knows one, let me know. – Szabolcs Sep 14 '11 at 12:31
• @Szabolcs I guess there is no single universal limiting "safe" value for `\$RecursionLimit`, since it must be determined by the memory used by the stack, which depends on the problem. My experiments resulted in crashes for `\$RecursionLimit` in the range of hundreds thousands. It probably should be possible to have an estimate on the available stack space, although this won't help much. Regardless, I would never use `\$RecursionLimit = Infinity`, since this is a true recipe for disaster. If possible, one should use tail-recursive (in mma sense) functions to reduce recursion to iteration. – Leonid Shifrin Sep 14 '11 at 13:30
• @magma Note that for a large (tens of thousands or more) number of definitions, `DownValues[f]` may take considerable time to execute. If such cases will be frequent, you may want to keep a separate counter (localized inside the same `Module`), which is incremented every time when a new definition is added, to reduce the overhead. – Leonid Shifrin Sep 14 '11 at 13:39

A slight modification on Leonid's code. I guess I should post it as a comment, but the lack of comment formatting makes it impossible.

``````Clear[f];
\$RecursionLimit = 20;
Module[{ff},
ff[0] = ff[1] = 1;
ff[x_] :=
ff[x] = Block[{\$RecursionLimit = \$RecursionLimit + 2},  ff[x - 1] + ff[x - 2]];
f[x_Integer] := f[x] = ff[x]]

f[30]
(*
-> 1346269
*)

\$RecursionLimit
(*
-> 20
*)
``````

Edit

Trying to set \$RecursionLimit sparsely:

``````Clear[f];
\$RecursionLimit = 20;
Module[{ff}, ff[0] = ff[1] = 1;
ff[x_] := ff[x] =
Block[{\$RecursionLimit =
If[Length@Stack[] > \$RecursionLimit - 5, \$RecursionLimit + 5, \$RecursionLimit]},
ff[x - 1] + ff[x - 2]];
f[x_Integer] := f[x] = ff[x]]
``````

Not sure how useful it is ...

• +1. I was thinking of adding something similar to my answer, but you did it first and perhaps more elegantly than what I intended to do. One may want increase the `\$RecursionLimit` step if the overhead of increasing in small steps is too much. – Leonid Shifrin Sep 14 '11 at 13:32
• @Leonid I guess a coarser step control would require incrementing a variable, or at least meassuring the stack depth. – Dr. belisarius Sep 14 '11 at 13:38
• Perhaps you are right. I did not give this suggestion much thought, it may be harder to implement well. – Leonid Shifrin Sep 14 '11 at 13:41
• This is also a very interesting solution, which uses Block inside Block recursion – magma Sep 14 '11 at 15:22