1 foundations of software design fall 2002 marti hearst lecture 29: computability, turing machines,...
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Foundations of Software DesignFall 2002Marti Hearst
Lecture 29: Computability, Turing Machines, Can Computers Think?
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Computability
• Is there anything a computer cannot compute?• Linked to the notion of what is an algorithm.
3
Alan Turing
• An amazing scientist– Helped solved the Enigma Machine (WWII)– Advances in Probability Theory
• Invented the theory behind computers– Turing Machine– Turing Test
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Turing Machines
• Anything that can be computed by a finite set of rules can be computed by a Turing machine.
• Turing Equivalence– We saw that finite automata are less powerful than TMs
• Can’t compute • Thus not Turing-equivalent
– Modern computers and programming languages are all Turing-equivalent
nnba
5Adapted from slide by Costas Busch, http://www.cs.rpi.edu/courses/fall01/modcomp/
*aRegular Languages
Context-Free Languagesnnba Rww
nnn cba ww
**ba
Languages accepted byTuring Machines
6Adapted from slide by Costas Busch, http://www.cs.rpi.edu/courses/fall01/modcomp/
A Turing Machine
............Tape
Read-Write headControl Unit
7Adapted from slide by Costas Busch, http://www.cs.rpi.edu/courses/fall01/modcomp/
The Tape
............
Read-Write head
No boundaries -- infinite length
The head moves Left or Right
8Adapted from slide by Costas Busch, http://www.cs.rpi.edu/courses/fall01/modcomp/
............
Read-Write head
The head at each time step:
1. Reads a symbol 2. Writes a symbol 3. Moves Left or Right
9Adapted from slide by Costas Busch, http://www.cs.rpi.edu/courses/fall01/modcomp/
............
Example:Time 0
............Time 1
1. Reads2. Writes
a a cb
a b k c
ak
3. Moves Left
10Adapted from slide by Costas Busch, http://www.cs.rpi.edu/courses/fall01/modcomp/
The Input String
............
Blank symbol
head
a b ca
Head starts at the leftmost positionof the input string
Input string
11Adapted from slide by Costas Busch, http://www.cs.rpi.edu/courses/fall01/modcomp/
States & Transitions
1q 2qLba ,
Read Write Move Left
1q 2qRba ,
Move Right
12Adapted from slide by Costas Busch, http://www.cs.rpi.edu/courses/fall01/modcomp/
Example:
1q 2qRba ,
............ a b ca
Time 1
1qcurrent state
13Adapted from slide by Costas Busch, http://www.cs.rpi.edu/courses/fall01/modcomp/
............ a b caTime 1
1q 2qRba ,
............ a b cbTime 2
1q
2q
14Adapted from slide by Costas Busch, http://www.cs.rpi.edu/courses/fall01/modcomp/
Determinism
1q
2qRba ,
Allowed Not Allowed
3qLdb ,
1q
2qRba ,
3qLda ,
Turing Machines are deterministic
15Adapted from slide by Costas Busch, http://www.cs.rpi.edu/courses/fall01/modcomp/
Halting
The machine halts if there areno possible transitions to follow
16Adapted from slide by Costas Busch, http://www.cs.rpi.edu/courses/fall01/modcomp/
Example:
............ a b ca
1q
1q
2qRba ,
3qLdb ,
No possible transition
HALT!!!
17Adapted from slide by Costas Busch, http://www.cs.rpi.edu/courses/fall01/modcomp/
Final States1q 2q Allowed
1q 2q Not Allowed
• Final states have no outgoing transitions• In a final state the machine halts
18Adapted from slide by Costas Busch, http://www.cs.rpi.edu/courses/fall01/modcomp/
AcceptanceAccept Input If machine halts
in a final state
Reject Input
If machine halts in a non-final state or If machine enters an infinite loop
19Adapted from slide by Costas Busch, http://www.cs.rpi.edu/courses/fall01/modcomp/
Infinite Loop Example
0q
Raa ,
L,1q
Lbb ,
A Turing machine for language *aa
20Adapted from slide by Costas Busch, http://www.cs.rpi.edu/courses/fall01/modcomp/
baTime 0
0q
a
0q
Raa ,
L,1q
Lbb ,
21Adapted from slide by Costas Busch, http://www.cs.rpi.edu/courses/fall01/modcomp/
baTime 1
0q
a
0q
Raa ,
L,1q
Lbb ,
22Adapted from slide by Costas Busch, http://www.cs.rpi.edu/courses/fall01/modcomp/
baTime 2
0q
a
0q
Raa ,
L,1q
Lbb ,
23Adapted from slide by Costas Busch, http://www.cs.rpi.edu/courses/fall01/modcomp/
baTime 2
0q
a
baTime 3
0q
a
baTime 4
0q
a
baTime 5
0q
a... Infinite Loop
24Adapted from slides by Lee Wee Sun, http://www.comp.nus.edu.sg/~cs1305/2000/
Church-Turing Thesis
The Church-Turing thesis says that Turing machine algorithms are the same as our intuitive notion of algorithms.– Most people think the Church Turing thesis is correct.– It means, among other things that
• You can simulate any computer program that runs on any hardware in any language with any other program on any other hardware using any other language.
• Tasks that humans agree is an algorithm can always be executed on a computer.
25Adapted from slides by Lee Wee Sun, http://www.comp.nus.edu.sg/~cs1305/2000/
The Halting Problem
• An example of something that is not computable.
• Created by Turing in 1936 to define a problem which no algorithmic procedure can solve.
• Can we write a program that will take in a user's program and inputs and decide whether – it will eventually stop, or– it will run infinitely in some infinite loop ?
26Adapted from slides by Lee Wee Sun, http://www.comp.nus.edu.sg/~cs1305/2000/
Proof (by contradiction)
• Assume that it is possible to write a program to solve the Halting Problem.
• Denote this program by HaltAnswerer(prog,inputs). • HaltAnswerer(prog,inputs) will
– return yes if prog will halt on inputs and – no otherwise.
• A program is just a string of characters– E.g. your Java program is just a long string of characters
• An input can also be considered as just a string of characters
• So HaltAnswerer is effectively just working on two strings
27Adapted from slides by Lee Wee Sun, http://www.comp.nus.edu.sg/~cs1305/2000/
Proof (cont.)
• We can now write another program Loopy(prog) that uses HaltAnswerer
• The program Loopy(prog) does the following:
[1] If HaltAnswerer(prog,prog) returns yes, Loopy will go into an infinite loop.
[2] If HaltAnswerer(prog,prog) returns no, Loopy will halt.
28Adapted from slides by Lee Wee Sun, http://www.comp.nus.edu.sg/~cs1305/2000/
Proof (cont.)
[1] If HaltAnswerer(prog,prog) returns yes, Loopy will go into an infinite loop.
[2] If HaltAnswerer(prog,prog) returns no, Loopy will halt.
• Consider what happens when we run Loopy(Loopy).– If Loopy loops infinitely,
• HaltAnswerer(Loopy,Loopy) return no which by [2] above means Loopy will halt.
– If Loopy halts, • HaltAnswerer(Loopy,Loopy) will return yes which by [1] above
means Loopy will loop infinitely.
• Conclusion: Our assumption that it is possible to write a program to solve the Halting Problem has resulted in a contradiction.
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Diagonalization
• Not Diagon Alley• A proof by contradiction technique
– Uses the notion of Infinity• The name comes from a proof that shows you can’t ever list all
numbers.– Assume you list all possible binary numbers– Diagonalization shows you can always construct a new
number that is not yet in the list• Have to assume numbers can have infinite length
– Construct the new number by choosing the opposite of the number on the diagonal.
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Diagonalization
B1 0 0 0 0 0 …B2 0 0 1 0 1 …B3 1 0 1 1 0 …B4 0 1 1 1 1 …B5 1 1 0 0 0 ……
D 1 1 0 0 1 …
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The Universal Turing Machine
• There are an infinite number of Turing Machines• There are an infinite number of calculations that
can be done with a finite set of rules.• However, we can define a Universal Turing
Machine which can simulate all possible TMs– Comes from the definition of TMs– You convert the description of the TM and its input into
two tapes, and use these as the input to the UTM
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The Halting Problem
• Halting Problem: – There is no procedure for telling whether an arbitrary TM
will halt on a given input.• Use Diagonalization to show this.
– Again, proof by contradiction– Assume there is a rule for deciding if a TM will halt.
• Construct a table as follows:– List all Turing machines down the side– List the possible inputs across the top– In position (j,i) put the result of executing Turing machine j
on input i• If it halts, output H• If it doesn’t halt, output ?
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Diagonalization
1 2 3 4 5 …T1 H H ? H H …T2 ? ? H H H …T3 H H H H H …T4 H H H ? H …T5 H H H H H ……D ? H ? H ? …
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Diagonalization on the Halting Problem
• Now define a new TM called D that will halt for all inputs. It outputs– H if TMi(i) does not halt– ? if TMi(i) does halt
• We already said that the assumption is that we can always decide if a TM halts.
• Also, we said this table lists all possible TMs.– So D must be in the table.
• But this means that we are saying that D outputs halt if it doesn’t halt! – To see this, give D as input to itself.
• This is a contradiction. Hence the premise does not hold: We cannot determine if an arbitrary program will halt.
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“Going Meta”
• This proof based in part on Gödel’s Theorem• If you are interested in these kinds of
questions (and other things related to “going meta” like compiler compilers), see– Gödel, Escher, Bach: An Eternal Golden Braid, by
Douglas Hofstadter.
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The Turing Test
• An observer – Interacts with a keyboard and monitor– Has to distinguish which of two respondents is a
computer and which is human.
• There is a contest with a $100,000 prize!– For the first computer whose responses are
indistinguishable from a human's. – The Loebner Prize http://www.loebner.net/Prizef/loebner-prize.html
• It’s actually pretty easy to fool people over the short term.
• Chat room ’bots work quite well.
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What is Intelligence?
• Do androids dream … ?
• What would it take for a computer’s thoughts to be indistinguishable from a human’s?
• THIS is the deepest question of CS.
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