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Recently I started to enjoy solving algorithm problems. I don't have much time so I try to solve them during my daily home-work-home travel. Archive from TopCoder SRM Div2 is a great place to start algorithms adventure because of provided members' solutions. Unfortunatelly I still have some problems with recognizing, solving and even understanding ready solutions of dynamic programming problems (Div2 Level 3). I read dynamic programming tutorial on TopCoder website and understand basics of this technique but problems still remain. What would you recommend to read in order to get more familiar with dynamic programming? Which problems seem to you enough easy and informative for a beginner?

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Read the chapter in Steven Skiena's Algorithm Design Manual –  Colonel Panic Aug 22 '12 at 11:32

1 Answer 1

up vote 25 down vote accepted

I would like to start by saying that "dynamic programming", sounding like something quite esoteric, is simply an efficient way to brute-force: you try every possible combination, but you optimize your implementation in that you avoid recomputing the same values multiple times. Dynamic programming is closely related to recursion: in fact any dynamic programming algorithm can be implemented recursively.

Perhaps one of the most well-known problems that is very suitable for dynamic programming is the Fibonacci sequence:

1, 1, 2, 3, 5, 8, ...

where the next number in the sequence is the sum of the previous two. In other words, the nth number in the sequence is the sum of the (n-1)th and (n-2)th numbers, so the Fibonacci formula is

F(n) = F(n - 1) + F(n - 2)

Now, that looks very suitable for recursion, doesn't it?! You might be tempted to quickly write a naive recursive algorithm looking something like this (pseudocode):

int F(int n):
    if (n <= 2):
        return 1
        return F(n - 1) + F(n - 2)

But note that this is not quite efficient. Why? At each level of the recursion you spawn two more recursions, which, by definition, are completely isolated from each other. Okay, great, that's part of the solution! But notice that

F(n - 1) = F(n - 2) + F(n - 3)

In the first recursion that you spawn, you spawn another (sub)recursion that is exactly the same as the second recursion you spawned initially! Of course your computer doesn't know that, so it recomputes F(n - 2) twice, F(n - 3) three times, and so on... leading to a very slow algorithm!

That's where dynamic programming comes in! You simply remember (cache) the result for each of the possible values of n, and then reuse the result when you need the same value again. One way to do this is to allocate an array where to store the results:

int[] _cache = new array of some predetermined large size N (one-based)

// initial values
_cache[1] = 1
_cache[2] = 1

int F(int n):
    if n > N:
        report error
    if _cache[n] is undefined: // compute value for n
        _cache[n] = F(n - 1) + F(n - 2)
    return _cache[n]

Dynamic programming need not always be implemented recursively - most of the time you can precompute your cache in a loop. Using the same Fibonacci problem, since you always only use your last two values, you can "prefill" your cache array with the values before you let your function to be called. Then, your function will always return immediately!

// initial values
_cache[1] = 1
_cache[2] = 1

for int i = 3 to N:
    _cache[i] = _cache[i - 1] + _cache[i - 2]

One word of caution: it's great that you use TopCoder to improve your skills, but I'd be against starting from division 2 level 3 problems: these problems are hard, and if they use dynamic programming, it is often with multi-dimensional cache arrays, thus harder to understand. I wouldn't go beyond division 2 levels 1 and 2 just yet. (Note that level 2 can also be quite hard!)

A great resource to get the basics of dynamic programming is Algorithms by S. Dasgupta, C.H. Papadimitriou, and U.V. Vazirani, chapter 6. That's the book where I got my first knowledge of the technique, and I really enjoyed reading about it and solving the problems. The penultimate draft of the book is available online free of charge, which is actually the copy I used.

Have fun!

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Good answer, just wanted to let you know that access to the online book seems to be restricted now. –  Kvass Oct 23 '13 at 1:21
@Kvass thanks for pointing this out! I waited to see if that was an intermittent issue, but appears not. The PDFs are still accessible, just the page isn't, so I changed the link to point to the PDF directory for now. –  Artyom Oct 31 '13 at 9:00
+1: Great answer - you can find this example in wikipedia too: en.wikipedia.org/wiki/Dynamic_programming#Fibonacci_sequence –  vonjd Feb 28 at 17:08

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