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Travelling salesman problem is said to be practically "unsolvable" when number of nodes increase.

What other programming problems that are considered unsolvable?

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Getting marketing people to understand realistic schedules. – Nosredna Nov 14 '09 at 17:36
@Nosredna: that's practically solvable by getting rid of the marketing people. – Eemeli Kantola Nov 14 '09 at 17:41
Love the question but shouldn't it be wiki? – Dave Swersky Nov 14 '09 at 17:51
Stack Overflow is not a discussion forum. Tagging this otherwise marginal question as "discussion" is good enough for me to vote to close. If you want to have a discussion, go to a forum, or write a blog. – dmckee Nov 14 '09 at 19:35
Convincing my co-workers that buzzwords and copy-paste are not programming. – fastcodejava Nov 29 '09 at 6:34

16 Answers 16

up vote 10 down vote accepted

If you're looking for problems that are similar to the traveling salesman problem then I suggest you google for NP-complete problems. This is a class of problems which doesn't have any know efficient solution, meaning an algorithm which computes the result in polynomial time. The intriguing thing with the class of NP problems is that no-one has been able to show that any algorithm for solving them must take exponential time. It's perhaps the biggest unsolved question in computer science.

It should be said though that it is often rather easy to find a solution to an NP problem, the tricky business is to find the optimal solution.

Here's a list of other NP-complete problems:

  • Bin packing, how to fill a container so that an optimal number of things fit in it. I know a guy who runs a company which helps shipping companies to pack their ships in the best possible manner. His program doesn't find the best solution but can typically help packing the ships in a smarter manner than what can be done manually.
  • SAT solving, showing that a propositional formula is satisfiable. This is a rather theoretical problem but it is used by Intel among other to automatically prove that their circuit designs are correct. SAT solvers are getting pretty good these days and can solve rather big problems rather quickly.
  • Scheduling, given a number jobs that need to be done and a number of resources needed to complete these jobs calculate the most efficient way to complete the jobs. Airliners have to solve this problem a lot since they have their resources, personnel and planes, which they want to use as efficiently as possible while still servicing all the flights. Companies like Jeppesen have programs for optimizing this.
  • Graph colouring. Take an undirected graph and try to color every node such that no two adjacent nodes that are connected by an edge have the same color. The goal is to use as few colors as possible. This is used by compilers to assign registers to local variables. The better the graph coloring algorithm, the more variable get put in registers instead of being in memory.

I could go on but I think most other problems I know are rather theoretical. You'd be better off googling by yourself.

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Note: k-Coloring is only NP-complete for k > 2. – Dave Dec 3 '09 at 13:57
Well, the problem is not even well defined if k <= 2 so it goes without saying. – svenningsson Dec 3 '09 at 18:48
Sure it's well-defined, and for the k=2 case the class of graphs for which it has a solution even has a name: bipartite graphs. For k=1 the graphs where it's solvable are rather uninteresting, though... – jk. Dec 13 '09 at 20:21

First, there's a big difference between unsolvable problems and problems that are difficult to solve. I know that sounds obvious, but a lot of people label hard problems (such as traveling salesman) as unsolvable when it's better to say that they're not solvable efficiently, i.e., in polynomial time.

The best known unsolvable problem is the halting problem. See this page for more info. One common technique to show that a problem is unsolvable is to show that it's equivalent to the halting problem.

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You don't have to show equivalence, just that the halting problem reduces to your problem, that is, show that if you could solve that problem, then you could also solve the halting problem. There are unsolvable problems that are strictly harder than the halting problem. – jk. Nov 29 '09 at 21:05
I was trying to avoid getting into the theory of computation :-) Well put and succinct clarification. – Mark Westling Dec 3 '09 at 13:48

The Halting Problem. Proven unsolvable.

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as well as utterly un-interesting outside theoretical domains – Eli Bendersky Nov 14 '09 at 17:42
...and also not a programming problem similar to the TSP. – Eemeli Kantola Nov 14 '09 at 17:44
it's actually a very practical problem, especially for unit tests: "does this piece of code terminate or go on forever in a loop" ? – joemoe Nov 14 '09 at 17:47
@eliben: like joemoe said, it's a very practical problem. Other than the obvious "I can't write a program to detect whether other programs have an infinite loop", there are a lot of other problems that are easily shown equivalent. Just one example: you can't write an algorithm to check what the output of another algorithm is (or even if it equals something). Which means, I can't write a function which checks whether another function, given input X, produces Y. – Edan Maor Nov 14 '09 at 21:36
It's not solvable in all cases, but it is solvable in many cases. I can tell that while(1); doesn't halt, and while(0); halts. Take it from there and you've got static analyzer. – Kornel Dec 4 '09 at 0:07

creating an unbreakable DRM for non interactive content, where intended users still can use the content ...

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Nothing is unbreakable. – Sneakyness Dec 4 '09 at 20:37
Precisely his point... – Daniel Goldberg Dec 6 '09 at 18:53

Internet Explorer 6

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Thanks for ths variant – Ivan Nevostruev Dec 4 '09 at 22:00
Great sense of humor! – bludger Dec 18 '09 at 1:18

Problems which are undecidable can not be solved with any algorithm.

NP Complete problems can be solved in polynomial time non-deterministically. So they are indeed solvable, especially quickly on a quantum computer.

Examples of undecidable problems include the Halting problem, which says: given an algorithm, decide if the algorithm eventually ends or continues on forever (eg: in an infinite loop). Alan Turing proved that the Halting problem is undecidable.

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I don't think quantum computers, as presently understood, can solve NP-hard problems in polynomial time. Not to mention that they barely exist yet - there was news fairly recently of a programmable quantum computer with two qubits, which will solve lots of problems with answers ranging from 0 to 3. – David Thornley Dec 2 '09 at 16:41
Quantum computers - as far as we know - can only provide substantial speedup if they can exploit some kind of symmetries in the input. For example, we can get an exponential speedup for factoring large numbers because the algorithm exploits some deeper structure of the integers. It is conjectured that at most polynomial speed-up is possible for black-box problems, like all currently known NP-complete problems. – Benno Dec 3 '09 at 22:30

Trying to find a dev who is happy with the code they've written!

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[raises hand] I'm quite happy with Addressable: – Bob Aman Dec 4 '09 at 19:09
Good for you. Ignorance is bliss. – Sneakyness Dec 4 '09 at 20:38
Ignorance is bliss.Then why exist? – bludger Dec 5 '09 at 7:57

As many people have already responded, the ur-problem which is impossible to solve is the halting problem: write a program H which takes a program P as input and answers whether the input program P is going to loop forever or not. Note that our program H may answer correctly for many input programs, the challenge is to write a program that can answer this for all programs.

Why is the halting problem unsolvable? The proof is pretty simple and rather fun: Assume that we can write the program H which solves the halting problem. (The goal is to show that by assuming this we are going to produce results which are just nonsense, hence our assumption is faulty.) Now, construct a program EVIL which uses H as a subroutine. We can write EVIL like this:

EVIL p = if H p then loop
                else false

A brief explanation is in order. EVIL takes a program and if that program halts then EVIL loops. It the input program loops forever then EVIL returns false.

The next step is really cool: apply EVIL to itself! The question is, what will the answer of EVIL EVIL be? It clearly depends on whether EVIL is looping forever or not. Let's consider the two alternatives:

  • Suppose EVIL loops forever. But then when we feed is as input program to itself it must return false since H detected that it would loop forever. But returning false contradicts what we first said that EVIL loops forever so that clearly cannot be the case.

  • Ok, so what is EVIL doesn't loop. Well, when we feed EVIL to itself it will just loop because H returned true. So we have a contradiction here as well.

Bummer! Both the alternatives (EVIL loops or it doesn't) leads to contradictions. So our assumptions must be faulty. There is no such program as H which can decide whether a function halts or not.

There are many interesting problems which are uncomputable that derive from the halting problem. Some of my favorites come from compiler technology. For example: finding the smallest equivalent program.

Another one is this: given that you've annotated your program with assertions, write a program which checks if any of the assertions will be violated at runtime. Such a program is sometimes called a model checker, and they can be really useful but they can never be complete, i.e. they sometimes have to answer "I don't know" when the problem gets too hard.

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Technically the program would get stuck in an infinite loop trying to decide if the program halted, at least i think... – RCIX Dec 4 '09 at 9:25

I find the knapsack problem particularly interesting as it's applicable to so many different domains.

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Getting all three of: scope (features), timeframe (schedule), budget (resources—developers); instead of "pick two".

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NP Complete questions are like that.

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Post Correspondence Problem:

Given two lists of words (a1, a2, .., an) and (b1, b2, .., bn), find a sequence of indices so that the concatenated words are equal.

E.g. given the lists (1: a, 2: ab, 3: bba) and (1: baa, 2: aa, 3: bb), the sequence (3, 2, 3, 1) is a solution since bba+ab+bba+a = bb+aa+bb+baa.

This problems looks like there should be an algorithm solving it (we're just talking about finding a sequence so that the strings match, nothing complex like Turing Machines is involved); but it's undecidable just like the halting problem.

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Getting programmers to document their code.

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This is absolutely not unsolvable. – Steinbitglis Dec 4 '09 at 0:03

Actually, NP-complete problems, like the Traveling Salesman, are hard to solve in general, but a specific instance (or even most instances of them in some domain [eg compiling Haskell code]) may be easy to solve!

There are a lot of problems that are, in theory, incredibly difficult – but because the difficult cases are very rare and rather contrived, they’re actually very easy to solve. Two examples of this that I find particularly interesting are both NP complete. Type checking in Haskell is one of them: in fact, the general type inference in Haskell is worse that NP complete: the type validation is NP-complete; type inference is NP-hard. But on real code, it’s effectively approximately linear. The other one is a logic problem called 3-SAT. I once attended a great talk by a guy named Daniel Jackson, talking about a formal specification language he’d designed called Alloy. Alloy reduces its specification checking to 3-SAT. Dan explained this saying: “The bad news is, analyzing Alloy specifications is 3-SAT, so it’s exponential and NP-complete. But the good news is that analyzing Alloy specifications is 3-SAT, so we can solve it really quickly


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Not all programming languages can have solve-able problems. For example I would rather do a regrep with perl then applescript. Most programming languages such as PHP have "bugs" that are unsolve-able until someone at the php team fixes the php engine.

He might mean that the code gets very very complicated and not worth completing the project because it takes too much time

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Many answers have mentioned the Halting Problem. Other examples of unsolvable problems include languages not accepted by Turing machines. An example of such a language is the language of Turing Machines that do not accept their own encoding.

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