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I like solving algorithm problems on TopCoder site. I can implement most of the basic recursive problems such as backtracking, dfs... However, whenever I encounter a complex recursion, it often takes me hours and hours. And when I check the solution of other coders, I feel so shame on myself. I've been programming for almost 5 years. I can see the significant improvement on other programming technique such as manipulating string, graphics, GUI ... but not recursion? Can anyone share some experiences how to approach a recursive problems? Thanks!


I'm familiar with Unit-Test methodology. Even before I knew Unit Test, I often write some small test functions to see if the result is what I want. When facing recursive problems, I lost this ability naturally. I can insert several "cout" statements to see the current result, but when the call is nested deeply, I no longer can keep track of it. So most of the time, either I solved it using pencil and paper first or I'm done ( can't use regular method like breaking it into smaller pieces ). I feel like recursion has to work as a whole.

Best regards,

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try programming with lisp –  shevski Jan 3 '11 at 5:33
This is why I think all programmers should have math degrees. Once you know math, recursion is so natural... –  Alexandre C. Jan 3 '11 at 18:21
@Alexandre. I majored in both Mathematics and Computer Science. I have no difficulty solving inductive problems. And I strongly believed my Maths skill is not bad at all. The problem that I had with recursion was it's hard to test one piece of code run correctly. –  Chan Jan 4 '11 at 0:44
so try to prove it runs correctly. Recursion and induction are quite the same. –  Alexandre C. Jan 4 '11 at 9:05
@Chan: another way to put it is: when you do an induction proof, you assume the result is true at step n, and you deduce step n + 1 from it. When you program recursive functions, you assume that the inner function call will behave the way you expect it to, and you write the remaining of the code normally. There is really no difference with what you're likely to be used to in mathematics once put into these terms. –  Alexandre C. Jul 28 '11 at 16:46

9 Answers 9

up vote 3 down vote accepted

This is a very good question.

The best answer I have is factoring: divide and conquer. This is a bit tricky in C++ because it doesn't support higher order functions well, but you can do it. The most common routines are things like maps and folds. [C++ already has a cofold called std::accumulate].

The other thing you have to consider carefully is how to structure your code to provide tail recursion where possible. One soon gets to recognize tail calls and think of them as loops, and this reduces the brain overload from recursing everywhere quite a bit.

Another good technique is called trust. What this means is, you write a call to a function you may not even have defined yet, and you trust that it will do what you want without further ado. For example you trust it will visit the nodes of a tree bottom up correctly, even if it has to call the function you're currently writing. Write comments stating what the pre- and post-conditions are.

The other way to do this (and I'm sorry about this) is to use a real programming language like Ocaml or Haskell first, then try to translate the nice clean code into C++. This way you can see the structure more easily without getting bogged down with housekeeping details, ugly syntax, lack of localisation, and other stuff. Once you have it right you can translate it to C++ mechanically. (Or you can use Felix to translate it for you)

The reason I said I'm sorry is .. if you do this you won't want to write C++ much anymore, which will make it hard to find a satisfying job. Example, in Ocaml, just add elements of a list (without using a fold):

let rec addup (ls: int list) : int = match ls with 
| [] -> 0                (* empty list *)
| h::t -> h + addup t    (* add head to addup of tail: TRUST addup to work *)

This isn't tail recursive, but this is:

let addup (ls: int list) : int = 
  let rec helper ls sum = match ls with
  | [] -> sum
  | h :: t -> helper t (h+ sum)
helper ls 0

The transformation above is well known. The second routine is actually simpler when you understand what it is doing. I'm too lazy to translate this into C++, perhaps you can transcode it.. (the structure of the algorithms alone should be enough to figure out the syntax)

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Thanks a lot for sharing your method ! –  Chan Jan 4 '11 at 16:51

I find that a pencil and paper comes in really handy. It's also a good idea to break the problem apart into smaller chunks, such as using a really small data set. The first thing you should do is identify your base condition, the condition that marks the end of the recursive calls. From there you can work on the body of the recursion problem and test/validate it using larger data sets.

I also want to add that speed isn't the only qualifier for being a good engineer. There are many other skills an engineer can possess, including the ability to see and think outside of the box, persuade others as to a particular course of action, break problems down and explain them to the layperson (stakeholders and customers) and much, much more.

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Thanks for your advice. –  Chan Jan 4 '11 at 16:51

What parts of the problem take you hours and hours?

What about the solution of other coders did you not figure out on your own?

As a general piece of advice, remember to think about the base case and then remember the invariants that you believe must hold at each level of the recursion. Bugs often arise because the invariants are not properly being preserved across recursive calls.

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The parts that take me hours are unravelling all the recursions in my head. You can have several of them and the code structure is sensitive to boundary conditions. It's some times hard to know where to "start", usually you have some initial setup then begin recursing, but you can do that almost anywhere in the setup sequence and sometimes its hard to pick the best place. –  Yttrill Jan 3 '11 at 7:48
FYI: I have actual examples of this where it took months to get the functions to work at all, and years to get them to work on a reasonable set of use cases, and even now I don't know when they'll break. Two collections of functions, about 10 or so in each collection with 5-12 parameters each. The first set is performing lookup on an AST with a complex set of rules (including overloading and polymorphism) and the second is the language optimiser. –  Yttrill Jan 3 '11 at 7:52
These are perfect examples where you have to think about the invariants. Invariants are true regardless of where you "start". If you are clear on what invariants you expect to be true, you will be able to reason through your code to see where you might be breaking that invariant before recursing. (Maybe you should also try and find representations that involve fewer parameters.) –  Emil Sit Jan 3 '11 at 20:18

I once went to a summer camp for mad teenagers who liked to program. They taught us the "French Method" (internal refernce) for solving problems (recursive & others).

1) Define your problem in your owner word, and do a few worked examples.

2) Make observations, consider edge cases, contraints (eg: "The algorithm must be at worst O(n log n)")

3) Decide how to tackle the probelem: graph theory, dynamic programming (recusion), combanitromics.

From here onwards recursion specific:

4) Identify the "sub-problem", it can often be helpful to guess how many sub-problems there could be from the constraints, and use that to guess. Eventually, a sub-problem will "click" in your head.

5) Choose a bottom-up or top-down algorithm.

6) Code!

Throughout these steps, everything should be on paper with a nice pen untill step 6. In programming competitions, those who start tapping right away often have below-par performance.

Walking always helps me get an algorithm out, maybe it will help you too!

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I can't emphasize enough how important it is to try to tackle complex problems with good old fashioned paper and writing utensils. Great advice! –  jmort253 Jan 8 '11 at 4:10

Get a copy of The Little Schemer and work through the exercises.

Don't be put off by the book using Scheme instead of C++ or C# or whatever your favorite language is. Douglas Crockford says (of an earlier edition, called The Little LISPer):

In 1974, Daniel P. Friedman published a little book called The Little LISPer. It was only 68 pages, but it did a remarkable thing: It could teach you to think recursively. It used some pretend dialect of LISP (which was written in all caps in those days). The dialect didn't fully conform to any real LISP. But that was ok because it wasn't really about LISP, it was about recursive functions.

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Great thanks! I will enjoy this book. –  Chan Jan 4 '11 at 16:52
The book is enormous fun; it's like doing puzzles except at the end you understand recursion! I used a pencil and paper and worked through it, I met a guy who followed along using a computer to test out his answers, and I imagine you could get a lot out of it without doing the exercises at all. There's a couple of follow up books if you want to take it further. –  Matt Curtis Jan 7 '11 at 3:20

try automatic memoization in c++0x :). The original post: http://slackito.com/2011/03/17/automatic-memoization-in-cplusplus0x/

and my mod for recursive functions:

#include <iostream>
#include <functional>
#include <map>

#include <time.h>

#define TIME(__x) init=clock(); __x; final=clock()-init; std::cout << "time:"<<(double)final / ((double)CLOCKS_PER_SEC)<<std::endl;
#define TIME_INIT  clock_t init, final;
void sleep(unsigned int mseconds) { clock_t goal = mseconds + clock(); while (goal > clock()); }

//the original memoize
template <typename ReturnType, typename... Args>
std::function<ReturnType (Args...)> memoize(std::function<ReturnType (Args...)> func)
    std::map<std::tuple<Args...>, ReturnType> cache;
    return ([=](Args... args) mutable  {
        std::tuple<Args...> t(args...);
        if (cache.find(t) == cache.end()) {
            cache[t] = func(args...);
        return cache[t];

/// wrapped factorial
struct factorial_class {

    /// the original factorial renamed into _factorial
    int _factorial(int n) {
        if (n==0) return 1;
        else {
         std::cout<<" calculating factorial("<<n<<"-1)*"<<n<<std::endl;
         return factorial(n-1)*n;

    /// the trick function :)
    int factorial(int n) {
        if (memo) return (*memo)(n);
        return _factorial(n);

    /// we're not a function, but a function object
    int operator()(int n) {
        return _factorial(n);

    /// the trick holder
    std::function<int(int)>* memo;

    factorial_class() { memo=0; }

int main()
    auto fact=factorial_class(); //virgin wrapper
    auto factorial = memoize( (std::function<int(int)>(fact) ) ); //memoize with the virgin wrapper copy
    fact.memo=&factorial; //spoilt wrapper
    factorial = memoize( (std::function<int(int)>(fact) ) ); //a new memoize with the spoilt wrapper copy

    TIME ( std::cout<<"factorial(3)="<<factorial(3)<<std::endl; ) // 3 calculations
    TIME ( std::cout<<"factorial(4)="<<factorial(4)<<std::endl; ) // 1 calculation
    TIME ( std::cout<<"factorial(6)="<<factorial(6)<<std::endl; ) // 2 calculations
    TIME ( std::cout<<"factorial(5)="<<factorial(5)<<std::endl; ) // 0 calculations

    TIME ( std::cout<<"factorial(12)="<<factorial(12)<<std::endl; )
    TIME ( std::cout<<"factorial(8)="<<factorial(8)<<std::endl;  )
    return 0;
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  • Identify Base case : that is this identifies case when to stop recursive.

    Ex: if (n == null) { return 0; }

  • Identify the sub-problem by splitting problem into smallest possible case.

then we can approach in two ways to solve it by coding

  • head recursion
  • tail recursion

In head recursive approach, recursive call and then processing occurs. we process the “rest of” the list before we process the first node. This allows us to avoid passing extra data in the recursive call.

In tail recursive approach, the processing occurs before the recursive call

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Dynsmic programming helps. Memoization is aslo helpful.

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I don't see how this even remotely tries to answer the OP's question; not to the spelling which looks like you've just hastily entered something and not even looked at it once. –  Mephane Jan 3 '11 at 8:19
@Mephane: Do you see it was edited! lol –  Jack_of_All_Trades Oct 31 '13 at 14:05

I think it is best idea to avoid recursion. Loops are more elegant and easier to understand on most cases.

I have found very few problems for what recursion is the most elegant solution. Usually such problems are about navigation in graph or on surface. Fortunately that field is studied to death so you can find plenty of algorithms on the net.

When navigating in some simpler graph (like tree) that contains nodes of different types visitor pattern is usually simpler than recursion.

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"I think it is best idea to avoid recursion" go and tell this to Haskell programmers... More seriously, recursion is an incredibly helpful tool for a lot of problems. –  Alexandre C. Jan 3 '11 at 18:20
I think that it is best idea to avoid also Haskell-style functional programming paradigm in current C++. What you can gain is a code that confuses even yourself half year after writing it. –  Öö Tiib Jan 3 '11 at 18:34
Quite frequently, "avoid recursion, use loops" leads to "implement your own call-stack, use the loop to drive a hand-coded 'virtual machine'" and that's, well, a lot of effort to avoid understanding recursive functions. –  Vatine Jan 3 '11 at 19:28
If it is quite frequent then please provide some example? Even the ones i gave in answer (navigation) are often about modifying the contents of such "stack" based on new information gained during navigation. –  Öö Tiib Jan 4 '11 at 5:31

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