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1 The Limits of Computation Intractable and Non-computable functions.

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1 1 The Limits of Computation Intractable and Non-computable functions

2 2 Decision Problems A specific set of computations are classified as decision problems. An algorithm describes a decision problem if its output is simply YES or NO, depending on whether a certain property holds for its input. Example: Given a set of n shapes, can these shapes be arranged into a rectangle?

3 3 Monkey Puzzle Problem Given: A set of n square cards whose sides are imprinted with the upper and lower halves of colored monkeys. n is a square number, such that n = m 2. Cards cannot be rotated. Problem: Determine if an arrangement of the n cards in an m X m grid exists such that each adjacent pair of cards display the upper and lower half of a monkey of the same color. Source: www.dwheeler.com (2002)

4 4 Example Images from: Simonas Šaltenis, Aalborg University, simas@cs.auc.dk 1 23 456 7 89

5 5 Analysis Simple algorithm: Pick one card for each cell of m X m grid. Verify if each pair of touching edges make a full monkey of the same color. If not, try another arrangement until a solution is found or all possible arrangements are checked. Answer "YES" if a solution is found. Otherwise, answer "NO" if all arrangements are analyzed and no solution is found.

6 6 Analysis If there are n = 9 cards (m = 3): To fill the first cell, we have 9 card choices. To fill the second cell, we have 8 card choices left. To fill the third cell, we have 7 card choices remaining. etc. The total number of unique arrangements for n = 9 cards is: 9 * 8 * 7 * 6 * 5 * 4 * 3 * 2 * 1 = 362,880

7 7 Analysis For n cards, the number of arrangements to examine is n! (n factorial) If we can analyze one arrangement in a microsecond: nTime to analyze all arrangements 9362880  s = 0.36288 s 1620922789888000  s 2515511210043330985984000000  s

8 8 Map Coloring Given a map of n territories, can the map be colored using k colors such that no two adjacent territories are colored with the same color? k=4: Answer is always yes. k=2: Only if the map contains no point that is the junction of an odd number of territories.

9 9 Map Coloring

10 10 Map Coloring Given a map of 48 territories, can the map be colored using 3 colors such that no two adjacent territories are colored with the same color? Pick a color for California (3 choices) Pick a color for Nevada (3 choices)... There are 3 48 = 79766443076872509863361 possible colorings (not necessarily valid). No one has come up with a better algorithmic solution that works in general for any map, so far.

11 11 Classifications Algorithms that are O(n k ) for some fixed k are polynomial-time algorithms. O(1), O(log n), O(n), O(n log n), O(n 2 ) reasonable, tractable All other algorithms are super-polynomial-time algorithms. O(2 n ), O(n!), O(n n ) unreasonable, intractable

12 12 Traveling Salesperson Given: a weighted graph of nodes representing cities and edges representing flight paths (weights represent cost) Is there a route that takes the salesperson through every city and back to the starting city with cost no more than k? The salesperson can visit a city only once (except for the start and end of the trip).

13 13 Traveling Salesperson A B D C G E F 12 6 4 5 9 8 10 7 11 3 7 7 Is there a route with cost at most 52?YES (Route above costs 50.) Is there a route with cost at most 48?YES? NO?

14 14 Traveling Salesperson If there are n cities, what is the maximum number of routes that we might need to compute? Worst-case: There is a flight available between every pair of cities. Compute cost of every possible route. Pick a starting city Pick the next city (n-1 choices remaining) Pick the next city (n-2 choices remaining)... Maximum number of routes: (n-1)! = O(n!) how to build a route

15 15 P and NP The class P consists of all those decision problems that can be solved on a deterministic sequential machine (e.g. a computer) in an amount of time that is polynomial with respect to the size of the input The class NP consists of all those decision problems whose positive solutions can be verified in polynomial time given the right information. from Wikipedia

16 16 NP Complete The class NPC consists of all those problems in NP that are least likely to be in P. Each of these problems is called NP Complete. Monkey puzzle, Traveling salesperson, and map coloring are all in NPC. Every problem in NPC can be transformed to another problem in NPC. If there were some way to solve one of these problems in polynomial time, we should be able to solve all of these problems in polynomial time.

17 17 Complexity Classes NP Problems P Problems NP Complete Problems But does P = NP? If P ≠ NP, then all decision problems can be broken down into this classification scheme. If P = NP, then all three classes are one and the same. The Clay Mathematics Institute is offering a $1M prize for the first person to prove P = NP or P ≠ NP. ( http://www.claymath.org/millennium/P_vs_NP/) We know that P < NP, since any problem that can be solved in polynomial time can certainly have a solution verified in polynomial time.

18 18

19 19 It gets worse... Tractable Problems Problems that have reasonable, polynomial- time solutions Intractable Problems Problems that may have no reasonable, polynomial-time solutions Noncomputable Problems Problems that have no algorithms at all to solve them

20 20 Noncomputability and Undecidability An algorithmic problem that has no algorithm is called noncomputable. If the noncomputable algorithm requires only a yes/no answer, the problem is called undecidable.

21 21 Noncomputability and Undecidability Example: Given any set of any number of different tile designs (examples shown above), with an infinite number of each type of tile, can we tile any area with these tiles without rotation so that like colored edges touch? This problem is undecidable!

22 22 Tiling Problem YES Note the periodicity in the tiling.

23 23 Tiling Problem NO For this 3 X 3 room, if we try all 3 9 tiling configurations, no tiling works.

24 24 Tiling Problem Possible algorithm: If we find a repeating pattern, report YES. If we find a floor we cannot tile, report NO. But this algorithm isn’t correct: there are some tilings which have no repeating pattern!

25 25 Tom’s Believe-It-Or-Not! If you take the same problem and allow tile rotations, you can ALWAYS tile any room regardless of the size. This problem is definitely computable!

26 26 Another Undecidable Problem: The Barber Paradox Suppose there is a town with one male barber; and that every man in the town keeps himself clean-shaven: some shave themselves and some are shaved by the barber. Only the barber can shave another man. The barber shaves all and only those men who do not shave themselves. Does the barber shave himself?

27 27 Program Termination Can we determine if a program will terminate given a valid input? Example: x = input (“Input a positive integer”) while x != 1: x = x - 2 Does this algorithm terminate when x = 15105? Does this algorithm terminate when x = 2008? Does this algorithm terminate for any positive x?

28 28 Program Termination Another Example: x = input (“Input a positive integer”) while x != 1: if x % 2 == 0: x = x / 2 else: x = 3 * x + 1 Does this algorithm terminate for x = 15? Does this algorithm terminate for x = 105? Does this algorithm terminate for any positive x?

29 29 The Halting Problem Suppose a program called the Terminator existed that could take ANY program and determine if it terminates or not. What happens if it tries to analyze this “evil” program P? Program P: Run the Terminator on program P (i.e. this program itself) and see what answer it gives. If the Terminator says YES (i.e. this program terminates): go into an infinite loop. Else: halt immediately.

30 30 The Halting Problem Can we write a general program Q that takes as its input any program P and an input I and determines if program P will terminate (halt) when run with input I? It will answer YES if P terminates successfully on input I. It will answer NO if P never terminates on input I. This computational problem is undecidable! No such general program Q can exist! It doesn’t matter how powerful the computer is. It doesn’t matter how much time we devote to the computation. The proof of this involves contradiction. Alan Turing

31 31 start end Does this algorithm end? yes no Contradiction

32 32 Contradiction isn't just for computer scientists...

33 33 The Big Ideas Many problems are Tractable Problems that have reasonable, polynomial-time solutions Some problems are Intractable Problems that have no reasonable, polynomial-time solutions NP Complete problems are those that are least likely to be tractable (but we haven’t proven or disproven this yet) Some problems are noncomputable Problems that have no algorithms at all to solve them in general

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