Transcript PPT

Pairing Functions and Gödel Numbers
This way the equation x, y = z defines functions
x = l(z) and y = r(z).
x, y = z also implies that x, y < z + 1, and therefore
l(z)  z, r(z)  z.
Then we can write:
l(z) = minxz[(y)z(z = x, y)],
r(z) = minyz[(x)z(z = x, y)],
showing that l(z) and r(z) are primitive recursive
functions.
It is also true that x, y = z  x = l(z) & y = r(z).
October 8, 2009
Theory of Computation
Lecture 10: A Universal Program II
1
Pairing Functions and Gödel Numbers
Theorem 8.1 (Pairing Function Theorem):
The functions x, y, l(z) and r(z) have the following
properties:
1.
2.
3.
4.
they are primitive recursive;
l(x, y) = x; r(x, y) = y;
l(z), r(z) = z;
l(z), r(z)  z.
October 8, 2009
Theory of Computation
Lecture 10: A Universal Program II
2
Pairing Functions and Gödel Numbers
We now want to develop primitive recursive functions
that encode and decode arbitrary finite sequences of
numbers.
Our method (actually invented by Gödel) will be
based on the prime power decomposition of integers.
We define the Gödel number of the sequence
(a1, …, an) to be the number
n
[a1 ,..., an ]   p
ai
i
i 1
For example, the Gödel number of the sequence
(7, 6, 4, 4, 3) is
27  36  54  74  113.
October 8, 2009
Theory of Computation
Lecture 10: A Universal Program II
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Pairing Functions and Gödel Numbers
For each n, the function [a1, …, an] is clearly primitive
recursive.
Gödel numbering satisfies the following uniqueness
property:
Theorem 8.2:
If [a1, …, an] = [b1, …, bn] then ai = bi for i = 1, …, n.
This follows immediately from the fundamental
theorem of arithmetic, i.e., the uniqueness of the
factorization of integers into primes.
October 8, 2009
Theory of Computation
Lecture 10: A Universal Program II
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Pairing Functions and Gödel Numbers
However, it is important to note that
[a1, …, an] = [a1, …, an, 0],
because for any n+1, p0n+1 = 1.
Actually, we could add any number of 0s to the right
end of a sequence without changing its Gödel
number.
Since we have 1 = 20 = 2030 = 203050 = … ,
it is useful to define 1 as the Gödel number of the
empty sequence of length 0.
October 8, 2009
Theory of Computation
Lecture 10: A Universal Program II
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Pairing Functions and Gödel Numbers
Obviously, adding a zero to the left of the sequence
will lead to a Gödel number different from the initial
one.
Examples:
[1, 4] = 21  34 = 162
[1, 4, 0] = 21  34  50 = 162
[0, 1, 4] = 20  31  54 = 1875
October 8, 2009
Theory of Computation
Lecture 10: A Universal Program II
6
Pairing Functions and Gödel Numbers
We will now define a primitive recursive function (x)i
so that if x = [a1, …, an], then (x)i = ai.
We set
(x)i = mintx(pit+1 | x).
Then we define the length Lt(x) of the sequence for
the Gödel number x:
Lt(x) = minix((x)i  0 & (j)x(j  i  (x)j = 0)).
Example: If x = 20 = 22  51 = [2, 0, 1],
then (x)1 = 2, (x)2 = 0, (x)3 = 1, (x)4 = (x)5 = … 0,
Lt(x) = 3.
October 8, 2009
Theory of Computation
Lecture 10: A Universal Program II
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Pairing Functions and Gödel Numbers
If x > 1 and Lt(x) = n, then pn divides x but no prime
greater than pn divides x.
Note that Lt([a1, …, an]) = n if and only if an  0.
Theorem 8.3 (Sequence Number Theorem):
a. ([a1, …, an])i = ai
b. ([(x)1, …, (x)n]) = x
October 8, 2009
if
if
1in
n  Lt(x)
Theory of Computation
Lecture 10: A Universal Program II
8
Coding Programs by Numbers
After having developed appropriate coding
techniques, it will be our goal to enumerate all
programs of the language L .
In other words, each program P of L will receive a
number #(P ) so that the program can be retrieved
from its number.
Let us first arrange the variables in the following
order:
Y X1 Z1 X2 Z2 X3 Z3 …
And also the labels:
A1 B1 C1 D1 E1 A2 B2 C2 D2 E2 A3 …
October 8, 2009
Theory of Computation
Lecture 10: A Universal Program II
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Coding Programs by Numbers
We write #(V), #(L) for the position of a given variable
or label in the appropriate ordering.
For example, #(X2) = 4, #(Z) = 3, #(C2) = 8.
Now let I be an instruction (labeled or unlabeled) of
the language L .
October 8, 2009
Theory of Computation
Lecture 10: A Universal Program II
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Coding Programs by Numbers
Then we write
#(I) = a, b, c ,
where
1. if I is unlabeled, then a = 0; if I is labeled L, then
a = #(L);
2. if the variable V is mentioned in I, then c = #(V) – 1;
3. if the statement in I is V  V, V  V+1, or
V  V-1, then b = 0, 1, or 2, respectively;
4. if the statement in I is IF V0 GOTO L’
then b = #(L’) + 2.
October 8, 2009
Theory of Computation
Lecture 10: A Universal Program II
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Coding Programs by Numbers
Examples:
The number of the unlabeled instruction X  X-1 is
0, 2, 1 = 0, 11 = 22.
The number of the instruction [A] X  X-1 is
1, 2, 1 = 1, 11 = 45.
October 8, 2009
Theory of Computation
Lecture 10: A Universal Program II
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Coding Programs by Numbers
Note that for any given number q there is a unique
instruction I with #(I) = q.
We first calculate l(q).
If l(q) = 0, I is unlabeled; otherwise I has the l(q)-th
label in our list.
To find the variable mentioned in I, we compute
i = r(r(q)) + 1 and locate the i-th variable V in our list.
Then the statement will be V  V, V  V+1, or
V  V-1, if l(r(q)) = 0, 1, or 2, respectively;
otherwise, it will be the statement IF V0 GOTO L,
where L is the j-th label in our list and j = l(r(q)) –2.
October 8, 2009
Theory of Computation
Lecture 10: A Universal Program II
13
Coding Programs by Numbers
Finally, for a program P that consists of the
instructions I1, I2, …, Ik, we set
#(P ) = [#(I1), #(I2), …, #(Ik)] – 1.
This way we associated every possible program in L
with a unique number.
October 8, 2009
Theory of Computation
Lecture 10: A Universal Program II
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Coding Programs by Numbers
Gödel numbers are usually very large, even for small
programs.
Let us look at the following example:
[A] X  X+1
IF X0 GOTO A
#(I1) = 1, 1, 1 = 1, 5 = 21
#(I2) = 0, 3, 1 = 0, 23 = 46
So the number of our small program is
221  346 – 1.
October 8, 2009
Theory of Computation
Lecture 10: A Universal Program II
15