« Lambda counting » : différence entre les versions
Aucun résumé des modifications |
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(203 versions intermédiaires par 7 utilisateurs non affichées) | |||
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counting.pdf : [http://www.lama.univ-savoie.fr/~david/ftp/paper/counting.pdf] version on wednesday 07/01 at 17h30. the files below are the good ones. René |
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==Introduction== |
==Introduction== |
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The question is: among programs, what is the probability of having a fixed property. |
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intro : [http://www.lama.univ-savoie.fr/~david/ftp/paper/intro.tex] |
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what kind of program : turing machines, cellular automata, combinatory logic, lambda calculus |
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== lambda== |
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[http://www.lama.univ-savoie.fr/~david/ftp/paper/section-2.tex] |
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==combinatorics== |
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section 3 : [http://www.lama.univ-savoie.fr/~david/ftp/paper/section-3.tex] |
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generating : |
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[http://www.lama.univ-savoie.fr/~david/ftp/paper/generating.tex] |
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==bounds== |
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[http://www.lama.univ-savoie.fr/~david/ftp/paper/section-4.tex] |
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==main results== |
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[http://www.lama.univ-savoie.fr/~david/ftp/paper/section-5.tex] |
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==section 5-2== |
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[http://www.lama.univ-savoie.fr/~david/ftp/paper/section-5-2.tex] |
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section 5-2-2 : |
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[http://www.lama.univ-savoie.fr/~david/ftp/paper/section-5-2-2.tex] |
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section 5-2-3 : |
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[http://www.lama.univ-savoie.fr/~david/ftp/paper/section-5-2-3.tex] |
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section 5-2-4 : |
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[http://www.lama.univ-savoie.fr/~david/ftp/paper/section-5-2-4.tex] |
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==section 5-3== |
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[http://www.lama.univ-savoie.fr/~david/ftp/paper/section-5-3.tex] |
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section 5-3-1 : |
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[http://www.lama.univ-savoie.fr/~david/ftp/paper/section-5-3-1.tex] |
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section 5-3-2 : |
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[http://www.lama.univ-savoie.fr/~david/ftp/paper/section-5-3-2.tex] |
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section 5-3-3 : |
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[http://www.lama.univ-savoie.fr/~david/ftp/paper/section-5-3-3.tex] |
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section 5-3-4 : |
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[http://www.lama.univ-savoie.fr/~david/ftp/paper/section-5-3-4.tex] |
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==other systems== |
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[http://www.lama.univ-savoie.fr/~david/ftp/paper/section-6.tex] |
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section 6.1 : |
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[http://www.lama.univ-savoie.fr/~david/ftp/paper/section-6.1.tex] |
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section 6.2 : |
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[http://www.lama.univ-savoie.fr/~david/ftp/paper/section-6.2.tex] |
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==conclusion== |
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[http://www.lama.univ-savoie.fr/~david/ftp/paper/section-7.tex] |
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section 7.1 : |
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[http://www.lama.univ-savoie.fr/~david/ftp/paper/section-7.1.tex] |
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section 7.2 : |
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[http://www.lama.univ-savoie.fr/~david/ftp/paper/section-7.2.tex] |
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section 7.3 : |
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[http://www.lama.univ-savoie.fr/~david/ftp/paper/section-7.3.tex] |
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==biblio == |
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[http://www.lama.univ-savoie.fr/~david/ftp/paper/biblio.tex] |
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==appendix == |
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[http://www.lama.univ-savoie.fr/~david/ftp/paper/appendix.tex] |
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appendix-1 : |
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[http://www.lama.univ-savoie.fr/~david/ftp/paper/appendix-1.tex] |
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appendix-2 : |
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[http://www.lama.univ-savoie.fr/~david/ftp/paper/appendix-2.tex] |
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What appears below is the old version |
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== Known results for Turing machines and cellular automata == |
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what kind of properties : structural (for functional programs), behaviour (SN, weakly normalizable, ... |
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In this section I propose to comment on paper |
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references to known results on : turing machines, cellular automata |
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[http://tcs.uj.edu.pl/~zaionc/papers_ps/HaltingProblem.pdf] and [http://tcs.uj.edu.pl/~zaionc/papers_ps/Dabramo.pdf]. |
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Guillaume says: I am very skeptical about paper 2 by D'Abramo. I suggest to replace it by the paper by Calude and Stay [http://arxiv.org/abs/cs/0610153]. |
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we concentrate on combinatory logic, lambda calculus |
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== Lambert function, Catalan and Motzkin numbers == |
== Lambert function, Catalan and Motzkin numbers == |
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Usual equivalent: <math>C(n) \sim \frac{4^n}{n^{3/2}\sqrt{\pi}}</math> which is obtained using Strirling formula. |
Usual equivalent: <math>C(n) \sim \frac{4^n}{n^{3/2}\sqrt{\pi}}</math> which is obtained using Strirling formula. |
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However, using stirling |
However, using stirling formula which can be extended as the following double inequality: <math> |
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n! |
\sqrt{2\pi n}n^n e^{\left(-n+\frac{1}{12n+1}\right)} < n! <\sqrt{2\pi n}n^n e^{\left(-n+\frac{1}{12n}\right)}</math> |
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\left( |
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<math>C(n) = \frac{(2n)!}{(n+1)!n!} \geq \frac{4^n}{\sqrt{\pi} (n+1)^{\frac{3}{2}}} \left(\frac{n}{n+1}\right)^n e^{\left(1 + \frac{1}{24n+1}-\frac{1}{12 n + 12}-\frac{1}{12n}\right)}</math> |
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1 |
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+{1\over12n} |
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+{1\over288n^2} |
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-{139\over51840n^3} |
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-{571\over2488320n^4} |
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+ \cdots |
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\right) |
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</math>, we get that for <math>n\geq1</math> we have <math>\sqrt{2\pi n}\left({n\over e}\right)^n \leq n! \leq \frac{7}{6}\sqrt{2\pi n}\left({n\over e}\right)^n</math> |
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Thus, using this and <math>\left(\frac{n}{n+1}\right)^{n} > e^{-1}</math>, we have: |
Thus, using this and <math>\left(\frac{n}{n+1}\right)^{n} > e^{-1}</math>, we have: |
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<math>C(n) |
<math>C(n) \geq \frac{4^n}{\sqrt{\pi} (n+1)^{\frac{3}{2}}} e^{\left(\frac{1}{24n+1}-\frac{1}{12 n + 12}-\frac{1}{12n}\right)} </math> |
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Then, we can check that |
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<math>\frac{1}{24n+1}-\frac{1}{12 n + 12}-\frac{1}{12n} = \frac{-36 n^2 - 14 n - 1}{12(24n+1)(n+1)n} \geq -\frac{51}{288n}</math> |
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Thus finally <math>C(n) \geq \frac{4^n}{\sqrt{\pi} (n+1)^{\frac{3}{2}}} e^{\left(-\frac{17}{96n}\right)} \geq \frac{4^n}{\sqrt{\pi} (n+1)^{\frac{3}{2}}} e^{\left(-\frac{17}{96}\right)} </math> for all <math>n\geq1</math>. |
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===Motzkin numbers=== |
===Motzkin numbers=== |
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In fact, these are not usual Motzkin's numbers because in <math>M(n)</math>, <math>n</math> is the number of inner nodes while |
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usually, this is the total number of nodes, including leaves. The number we use are known as large Schroeder numbers. |
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Let us define <math>M(n,k)</math> the number of unary-binary trees with <math>n</math> inner nodes and <math>k</math> leafs. |
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A tree with <math>n</math> inner node <math>k</math> leafs has exactly <math>k-1</math> binary nodes and therefore <math>n-k+1</math>. |
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Hence we get the following formula |
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<center><math>M(n,k) = C(k-1){n+k-1 \choose n-k+1} </math></center> |
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Then, by summing we define <math>M(n)</math> the number of unary-binary trees with <math>n</math> inner nodes and give an equivalent: |
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<center><math>M(n |
<center><math>M(n) = \sum_{k \geq 1} M(n,k) \sim \left(\frac{1}{3-2\sqrt{2}}\right)^n \frac{1}{n^\frac{3}{2}}</math></center> |
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===Lambert W function=== |
===Lambert W function=== |
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The Lambert function <math>W(x)</math> is defined by the equation <math>x = W(x) e ^ {W(x)} </math> |
The Lambert function <math>W(x)</math> is defined by the equation <math>x = W(x) e ^ {W(x)} </math> |
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which has a unique solution in <math>\mathbb{R}</math>. |
which has a unique solution in <math>\mathbb{R}_+</math>. |
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For <math>x \geq e</math>, we have <math>\ln(x) - \ln(\ln(x)) \leq W(x) \leq \ln(x)</math> which implies that |
For <math>x \geq e</math>, we have <math>\ln(x) - \ln(\ln(x)) \leq W(x) \leq \ln(x)</math> which implies that |
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<center><math>(\ln(x) - \ln(\ln(x))e^{\ln(x)-\ln(\ln(x))} = x \left(1 - \frac{\ln(\ln(x))}{\ln(x)}\right) \leq x \leq x \ln(x) = \ln(x) e^{\ln(x)} </math></center> |
<center><math>(\ln(x) - \ln(\ln(x))e^{\ln(x)-\ln(\ln(x))} = x \left(1 - \frac{\ln(\ln(x))}{\ln(x)}\right) \leq x \leq x \ln(x) = \ln(x) e^{\ln(x)} </math></center> |
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This is not precise enough for our purpose. Using one step of the Newton method from <math>\ln(x) - \ln(\ln(x))</math>, we can find a better upper bound for <math>W(x)</math> because <math>y \mapsto y e^y</math> is increasing and convex. This gives: |
This is not precise enough for our purpose. Using one step of the Newton method from <math>\ln(x) - \ln(\ln(x))</math>, we can find a better upper bound for <math>W(x)</math> because <math>y \mapsto y e^y</math> is increasing and convex when <math>y \geq 0</math>. This gives for <math>x \geq e</math>: |
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<center><math>\ln(x) - \ln(\ln(x)) \leq W(x) \leq \ln(x) - \ln(\ln(x)) + \frac{\ln(\ln(x))}{\ln(x) - \ln(\ln(x)) + 1}</math></center> |
<center><math>\ln(x) - \ln(\ln(x)) \leq W(x) \leq \ln(x) - \ln(\ln(x)) + \frac{\ln(\ln(x))}{\ln(x) - \ln(\ln(x)) + 1}</math></center> |
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== combinatory logic == |
== combinatory logic == |
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Basically the paper already written by Marek |
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results on combinatory logic |
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tex file : [http://www.lama.univ-savoie.fr/~david/ftp/CL.tex] |
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pdf file :[http://www.lama.univ-savoie.fr/~david/ftp/CL.pdf] |
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+ the following |
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As we will see in section ??, theorem ?? does not holds for the Lambda calculus. This may be surprising since there are translations between these systems which respect many properties (for exemple the one of being terminating). However these translations do not preserve the size. |
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The translation <math>T</math> from combinatory logic to lambda calculus is linear, i.e. there is a constant <math>k</math> such that, for all terms, <math>size(T (t)) \leq k * size(t)</math> but the translation <math> S </math> in the other direction is not linear. As far as we know, there is no known bound on the size of <math>S (t)</math> but it is not difficult to find exemples where <math> size(S(t)) </math> is of order <math> size(t)^3</math>. |
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The point is that <math> S </math> has to code the binding in some way and this takes place. It will be interesting to compare the size of <math> S (t) </math> with the one of <math> t </math> using other notion of size than the usual one. See section ?? for some complement. |
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== Generality on lambda calculus == |
== Generality on lambda calculus == |
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what kind of distribution ? |
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we look only for densities, |
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for that we need size. |
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definition |
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different size for variables: zero, one, binary with optimal size, binary with fixed size, debruijn indices in unary... |
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The set <math>\Lambda</math> of lambda terms (or, |
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simply, terms) is defined by the following grammar |
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<math>t, u := Var \ \mid \ \lambda x.t \ \mid \ (t \ u)</math> |
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To be able to define the notion of a ''random'' term we |
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have to define a distribution law on <math>\Lambda</math>. There are many |
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possibilities for that. We choose here the simplest one. Note that this is the one for which, at least at present, we are |
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able to prove some results. It is based on densities. For that we |
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first have to define the ''size'' of a term. |
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The usual |
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definition is the following. |
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definition |
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The size (denoted as <math>size_1(t)</math>) of a term <math>t</math> is defined by the following |
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rules. |
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- <math>size_1(t)=1</math> if <math>t</math> is a variable. |
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- <math>size_1(\lambda x.t)=size_1(t)+1</math> |
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- <math>size_1((t \ u))=size_1(t)+size_1(u)+1</math> |
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In the rest of the paper we will use another definition (denoted |
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as <math>size_0(t)</math>) which is similar but gives simpler computations. |
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We believe (but we have not yet checked the details) that, with |
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<math>size_1</math> we would have similar results. The |
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computation, with <math>size_1</math>, of the upper and lower |
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bounds of the number of terms of size <math>n</math> will be done |
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in section ?? |
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definition |
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The size (denoted as <math>size_0(t)</math> or, more simply <math>size(t)</math>) of a term <math>t</math> is defined by the following |
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rules. |
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- <math>size_0(t)=1</math> if <math>t</math> is a variable. |
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- <math>size_0(\lambda x.t)=size_0(t)+1</math> |
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- <math>size_0((t \ u))=size_0(t)+size_0(u)+1</math> |
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These definitions of the size are, for the implementation point of |
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view, not realistic because, in case a term has a lot of distinct |
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variables, it is not realistic to use a single bit to code them. |
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The usual way to implement this coding is to replace the names of |
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variables by their so called de Bruijn indices: a variable is |
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replaced by the number of <math>\lambda</math> that occur, on the |
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path from the variable to the root, between the variable and the |
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<math>lambda</math> that binds it. Note that, in this case, |
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different occurrences of the same variable may be represented by |
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different indices. |
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Choosing the way we code these de Bruijn indices gives different |
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other ways of defining the size of a term. This can be done in the |
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following ways |
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- Use unary notation, i.e. the size of the index <math>n</math> |
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simply is <math>n</math> itself |
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- Use optimal binary notation, i.e. the size of the index |
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<math>n</math> is <math>log_2(n)</math> i.e. the logarithm of |
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<math>n</math> in base 2. |
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- Use uniform binary notation, i.e. the size of an index is the |
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logarithm, in base 2, of the number of leaves of the term. |
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Remark |
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See section ?? for a discusion about these different size. |
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definition |
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Let <math>n</math> be an integer. We denote by <math>\Lambda_n</math> the set of <math>\lambda</math> terms of size n. |
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definition |
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Let A be a set of <math>\lambda</math> terms. |
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1) We denote by <math>\#(A)</math> the cardinality of A. |
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2) We denote by <math>d(A)</math> the limit, for n going to <math>\infty</math>, |
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of <math>\frac{\#(A\cap \Lambda_n)}{\#(\Lambda_n)}</math>. |
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Remark |
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Note that d is not exactly a measure since <math>d(A)</math> is undefined if the previous limit does not exist |
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definition |
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Let P be a property of terms. We will say that almost every term satisfies P |
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we concentrate on the simple one : variable of size zero (probably similar for size one ) more later for other size |
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(this will be also stated as P holds a.e.) if |
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<math>d(\{t \ | \ P(t) holds\})=1</math> |
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== generating functions == |
== generating functions == |
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=== Upper and lower bounds for <math>L_n</math> === |
=== Upper and lower bounds for <math>L_n</math> === |
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For the lower bound, we will first count the number <math>LB(n,k)</math> of lambda-terms of size <math>n</math> starting with <math>k</math> lambdas and having no other lambda below. This means that the lower part of the term is a binary tree |
For the lower bound, we will first count the number <math>LB(n,k)</math> of lambda-terms of size <math>n</math> starting with <math>k</math> lambdas and having no other lambda below. This means that the lower part of the term is a binary tree with <math>n-k</math> inner nodes with |
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<math>k</math> possibility for each leaf. Therefore we have: |
<math>k</math> possibility for each leaf. Therefore we have: |
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<center><math>LB(n,k) = C(n-k) k^{n-k}</math></center> |
<center><math>LB(n,k) = C(n-k) k^{n-k+1}</math></center> |
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And therefore, for <math>n > k</math>, using our lower bound for <math>C(n)</math> and <math>n + 1 \geq n - k + 1</math>, we get: |
And therefore, for <math>n > k</math>, using our lower bound for <math>C(n)</math> and <math>n + 1 \geq n - k + 1</math>, we get: |
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<center><math>LB(n,k) \geq K \frac{(4k)^{n-k}}{(n+1)^\frac{3}{2}}</math> with <math>K=\frac{ |
<center><math>LB(n,k) \geq K \frac{(4k)^{n-k+1}}{(n+1)^\frac{3}{2}}</math> with <math>K=\frac{e^{-\frac{17}{96}}}{4\sqrt{\pi}}</math></center> |
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Now, for <math>n</math> fixed, we define <math>f(\alpha) = \left(4n\alpha\right)^{n(1-\alpha)}</math> (so <math>LB(n,k) \geq \frac{K}{(n+1)^\frac{3}{2}} f\left(\frac{k}{n}\right)</math>) and look for the maximum of this function. We have <math>f'(\alpha) = |
Now, for <math>n</math> fixed, we define <math>f(\alpha) = \left(4n\alpha\right)^{n(1-\alpha) + 1}</math> (so <math>LB(n,k) \geq \frac{K}{(n+1)^\frac{3}{2}} f\left(\frac{k}{n}\right)</math>) and look for the maximum of this function. We have <math>f'(\alpha) = f(\alpha) \left(-n\ln(4n\alpha) +\frac{n(1-\alpha) + 1}{\alpha}\right)</math>. Thus, <math>f'(\alpha) \geq 0</math> is equivalent to <math>\frac{n+1}{n\alpha}e^{\frac{n+1}{n\alpha}}\geq 4e(n+1)</math>. The Lambert function begin increasing this means that <math>f'(\alpha) \geq 0</math> is equivalent to <math>\alpha \leq \frac{n+1}{nW(4e(n+1))}</math>. Therefore, <math>f(\alpha)</math> reaches a maximum for <math>\alpha = \frac{n+1}{nW(4e(n+1))}</math>. |
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This means that <math>(4k)^{n-k}</math> reaches its maximum for <math>n</math> fixed when <math>k</math> |
This means that <math>(4k)^{n-k}</math> reaches its maximum for <math>n</math> fixed when <math>k</math> |
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is near to <math>\frac{n}{W( |
is near to <math>\frac{n+1}{W(4e(n+1))}</math> which is likely not to be an integer. However, there are at least <math>\left\lfloor \frac{(n+1) (\ln(\ln(4en)) - 1)}{\ln^2(4en)}\right\rfloor</math> integer between <math>\frac{n+1}{W(4e(n+1))}</math> and <math>\frac{n+1}{\ln(4e(n+1))}</math>. Indeed, using our inequalities on Lambert W function, we have: |
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<center><math>\frac{n}{W( |
<center><math>\frac{n+1}{W(4e(n+1))}-\frac{n+1}{\ln(4e(n+1))} = \frac{(n+1) (\ln(4e(n+1)) - W(4e(n+1)))}{W(4e(n+1))\ln(4e(n+1))} \geq \frac{(n+1) (\ln(\ln(4e(n+1))) - 1)}{\ln^2(4e(n+1))}</math></center> |
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Thus, we get the following lowerbound for <math>L_n</math>: |
Thus, we get the following lowerbound for <math>L_n</math>: |
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<center><math>\#(L_n) \geq \sum_{k=1}^{n} LB(n,k) \geq \sum_{k=\lceil\frac{n}{\ln( |
<center><math>\#(L_n) \geq \sum_{k=1}^{n} LB(n,k) \geq \sum_{k=\lceil\frac{n+1}{\ln(4e(n+1))}\rceil}^{\lfloor\frac{n+1}{W(4e(n+1))}\rfloor} K \frac{(4k)^{n-k+1}}{(n+1)^\frac{3}{2}} \geq K \left\lfloor \frac{(n+1) (\ln(\ln(4e(n+1))) - 1)}{\ln^2(4e(n+1))}\right\rfloor \frac{\left(\frac{4(n+1)}{\ln(4e(n+1))}\right)^{n-\frac{n+1}{\ln(4e(n+1))}+1}}{(n+1)^\frac{3}{2}}</math></center> |
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To simplify, |
To simplify, we first remove the constant <math>K</math> and the integer part by replacing the <math>\ln(\ln(4e(n+1))) - 1</math> term by any constant <math>C</math>. This means that for any constant <math>C</math>, we can take <math>n</math> large enough to have: |
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<center><math>\#(L_n) \geq \frac{1}{ |
<center><math>\#(L_n) \geq C\frac{n+1}{\ln^2(4e(n+1))}\frac{\left(\frac{4(n+1)}{\ln(4e(n+1))}\right)^{n-\frac{n+1}{\ln(4e(n+1))}+1}}{(n+1)^\frac{3}{2}} |
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= C\frac{\sqrt{n+1}}{\ln^3(4e(n+1))}\left(\frac{4(n+1)}{\ln(4e(n+1))}\right)^{n-\frac{n+1}{\ln(4e(n+1))}} |
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</math></center> |
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Then, using the facts that <math>\frac{n+1}{\ln(4e(n+1))} \leq \frac{n}{\ln(n)}</math>, <math>\lim_{n\to +\infty}\frac{\ln(n)}{\ln(4e(n+1))} = 1</math> and <math>\lim_{n\to +\infty}\left(\frac{\ln(n)}{\ln(4e(n+1))}\right)^n = 0</math>, we have the following lowerbound (still for <math>n</math> large enough, with <math>C = 1</math>): |
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<center><math>\#(L_n) \geq \frac{\sqrt{n}}{\ln^3(n)}\left(\frac{4n}{\ln(n)}\right)^{n-\frac{n}{\ln(n)}}</math></center> |
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We now compute an upper bound <math>UB(n,k)</math> for the number of lambda-terms of size <math>n</math> with exactly <math>k</math> lambdas (that is with <math>n - k + 1</math> leaves using the Motzkin numbers and allowing any lambda to bind any variable (regardless of the real scope): |
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<center><math>UB(n,k) = M(n,n-k+1) k^{n-k+1}</math></center> |
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If we sum this for all possible <math>k</math> and get an upper bound of <math>k^{n-k+1}</math> using Lambert function as for the lower bound, we get the following upper bound for <math>L_n</math>: |
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<center><math>\#(L_n) \leq M(n) \left(\frac{n+1}{W(e(n+1))}\right)^{n-\frac{n+1}{W(e(n+1))} + 1}</math></center> |
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The ration between our upper bound and lower bound is equivalent to (NEEDS FURTHER CHECKING, OR IS REMOVED because we can do better using Jakob's remark at the end of 7.2): |
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<center><math>\left(\frac{1}{4(3-2\sqrt{2})}\right)^n\frac{\ln^3(n)}{n^2} \simeq 1.46^n\frac{\ln^3(n)}{n^2}</math></center> |
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=== upper and lower bounds for number of lambdas in a term of size n === |
=== upper and lower bounds for number of lambdas in a term of size n === |
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Let <math>S(n,k)</math> be the number of lambda term of size n containing more than <math>\frac{k n}{ln(n)}</math> lambdas. |
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=== Jakub's trik : at least 1 lambda in head position === |
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We search <math>k</math> such that <math>\lim_{n \rightarrow +\infty} \frac{S(n,k)}{L_n} = 0</math>. |
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Using the previous notation, we may write <math>S_n \leq \sum_{p \geq \frac{k n}{ln(n)}} UB(n,p)</math>. We observed that |
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=== at least <math>o(\sqrt{n/\ln(n)})</math> lambdas in head position and number of lambdas in one path === |
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<math>UB(n,p)</math> is decreasing in <math>p</math> if <math>p > \frac{n+1}{W(e(n+1))}</math>. |
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Then, we have <math>W(e(n+1)) \geq \ln(e(n+1)) - \ln(\ln(e(n+1)))</math>. Therefore, if <math>\frac{k n}{ln(n)} > \frac{n+1}{\ln(e(n+1)) - \ln(\ln(e(n+1)))}</math> (i), we have |
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Remark: (may be 4) can be done directly without 3)) |
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<center><math>S(n,k) \leq M(n)\left(\frac{k n}{ln(n)}\right)^{n+1-\frac{k n}{ln(n)}}</math></center> |
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=== each of the <math>o(\sqrt{n/\ln(n)})</math> head lambdas really bind "many" occurrences of the variable === |
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Then, (i) is equivalent to <math>\frac{k n}{n+1} > \frac{ln(n)}{\ln(e(n+1)) - \ln(\ln(e(n+1)))}</math> which is true for <math>n</math> |
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large enough if <math>k>1</math> because <math>\lim_{n \rightarrow +\infty} \frac{ln(n)}{\ln(e(n+1)) - \ln(\ln(e(n+1)))} = 1</math>. |
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Using our lower bound for <math>L_n</math>, we find |
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<center><math>\frac{S(n,k)}{L_n} \leq \frac{M(n)\left(\frac{k n}{ln(n)}\right)^{n+1-\frac{k n}{ln(n)}}}{\frac{\sqrt{n}}{\ln^3(n)}\left(\frac{4n}{\ln(n)}\right)^{n-\frac{n}{\ln(n)}}}</math></center> |
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We now use the fact that <math>M(n) \sim \left(\frac{1}{3-2\sqrt{2}}\right)^n \frac{1}{n^\frac{3}{2}}</math>, |
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for <math>n</math> large enough, we have (we introduce an extra log to compensate for the equivalent) |
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<center><math>\frac{S(n,k)}{L_n} \leq \frac{\ln^4(n)\left(\frac{1}{3-2\sqrt{2}}\right)^n \left(\frac{k n}{ln(n)}\right)^{n+1-\frac{k n}{ln(n)}}}{n^2\left(\frac{4n}{\ln(n)}\right)^{n-\frac{n}{\ln(n)}}}</math></center> |
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We get a simpler upper bound by using the <math>n^2</math> to compensate for the <math>+1</math> exponent and the remaining <math>k\frac{\ln^4(n)}{\ln(n)}</math>, which gives: |
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<center><math>\frac{S(n,k)}{L_n} \leq \frac{\left(\frac{1}{3-2\sqrt{2}}\right)^n \left(\frac{k n}{ln(n)}\right)^{n-\frac{k n}{ln(n)}}}{\left(\frac{4n}{\ln(n)}\right)^{n-\frac{n}{\ln(n)}}} = \left(\frac{k}{4(3-2\sqrt{2})}\right)^n \left(\frac{k n}{ln(n)}\right)^{\frac{-kn}{\ln(n)}}\left(\frac{4n}{ln(n)}\right)^{\frac{n}{\ln(n)}}</math></center> |
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Let us remark that <math>\left(\frac{k n}{ln(n)}\right)^{\frac{-kn}{\ln(n)}} = e^{-kn}\left(\frac{k}{ln(n)}\right)^{\frac{-kn}{\ln(n)}} </math> |
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and <math>\left(\frac{4n}{ln(n)}\right)^{\frac{n}{\ln(n)}} = e^{n}\left(\frac{4}{ln(n)}\right)^{\frac{n}{\ln(n)}} </math> . |
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Thus we have: |
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<center><math>\frac{S(n,k)}{L_n} \leq \left(\frac{ke^{1-k}}{4(3-2\sqrt{2})}\right)^n \left(\frac{4 k^{-k}}{ln^2(n)}\right)^{\frac{n}{\ln(n)}}</math></center> |
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This means that <math>\frac{S(n,k)}{L_n}</math> converges toward zero if <math>\frac{ke^{1-k}}{4(3-2\sqrt{2})} < 1</math>. |
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<math>ke^{1-k}</math> reaches its maximum <math>1</math> in <math>k=1</math> and <math>0 < 4(3-2\sqrt{2}) < 1</math> |
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This means that <math>ke^{1-k} = 4(3-2\sqrt{2})</math> has two solutions, one for <math>k > 1</math> the other for <math>k<1</math>. |
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Because of (i) we need to keep the first solution. It is easy to see that the first solution is smaller than 3 because |
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<math>3e^{1-3} < 3\frac{4}{25} < 4(3-2\sqrt{2})</math>. |
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Corollary. Random lambda term of size n contains asymptotically no more then <math>\frac{3 n}{ln(n)}</math> lambdas. |
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In the same way, we can consider lambda-terms with less than <math>\frac{k n}{ln(n)}</math> and redo exactly the same computation, |
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but replacing (i) by <math>\frac{k n}{ln(n)} < \frac{n+1}{\ln(e(n+1))}</math> (ii). Then we have to take <math>k</math> smaller |
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than the other solution of the equation, and if it easy to see that <math>k < \frac{1}{3}</math> works. |
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Corollary. Random lambda term of size n contains asymptotically no less then <math>\frac{n}{3 ln(n)}</math> lambdas. |
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Once we know this we can improve the upper bound. |
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Let Ll be <math>\Lambda \setminus Ls</math>. In a term from Ll the proportion between unary and binary nodes is smaller then <math>\frac{3}{ln(n)}</math> which is far from typical proportion in unary-binary trees which tends to some nonzero constant. Rough estimation gives |
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<math> |
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Ll_n \leq C(n) {n \choose \frac{3}{ln(n)}} ((1+\epsilon) \frac{n}{ln(n)})^n |
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</math> |
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where C(n) corresponds to the binary structure, <math>{n \choose \frac{3}{ln(n)}}</math> to the possible distribtions of lambdas in binary structure and <math>((1+\epsilon) \frac{n}{ln(n)})^n</math> to the possibilities of bindings (one can optimal number of unary nodes involving Lambert's function to get rid of epsilon here). The crucial observation now is that <math>{n \choose \frac{3}{ln(n)}}</math> is '''subexponential'''. |
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Comparing this upper bound with <math>LB(n,\frac{n}{ln (n)})</math> we would obtain that the asymptotic ratio between upper and lower bound is subexponential. |
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I think it has some serious consequences. In particular it seems that in a random lambda term almost all lambdas lie on one path. |
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'''Proposition.''' \label{prop:typical_depth} There exists a function <math>f\in\Omega\left(\frac{n}{\log(n)}\right)</math> such that the set of terms t having a <math>\lambda</math>-depth greater than <math>f(size(t))</math> has density 1. |
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=== Lambdas in head position === |
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'''Theorem'''. \label{th:starting_lambdas} Let <math>g\in o\left(\frac{n}{\log(n)}\right)</math>. The set <math>\Lambda_g</math> of terms t starting with less than <math>g(size(t))</math> lambdas has density 0. |
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'''Proof'''. By proposition \ref{prop:typical_depth}, for some function f such that <math>g\in o(f)</math>, we can restrict to the set <math>\Gamma_f</math> of terms t having <math>\lambda</math>-depth at least <math>f(size(t))</math> (because <math>\Gamma_f</math> has density 1). To prove the theorem it is sufficient to exhibit a one-to-one function <math>\phi</math> from <math>\Lambda_g\cap\Gamma_f</math> into <math>\Gamma_f</math> whose image set has density 0. We now define <math>\phi</math> by describing <math>\phi(t)</math> where t is an arbitrary term of size n belonging to <math>\Lambda_g\cap\Gamma_f</math>. By hypothesis, the term t starts with a chain of p <math>\lambda</math>-nodes, where <math>p\leq g(n)</math>. So <math>t=\lambda x_1\cdots\lambda x_p.A</math> where A is a term starting by an application and containing at least one <math>\lambda</math> (for n large enough). Now let B be the maximal purely applicative prefix of A. Precisely, B is the maximal binary tree whose leaves are either special leaves or variables among <math>x_1,\ldots,x_p</math> and such that <math>A=B(t_1,\ldots,t_k)</math> where <math>t_1,\ldots,t_k</math> are terms starting with a lambda, and <math>B(t_1,\ldots,t_k)</math> denotes the term obtained by replacing successive special leaves of B by terms <math>t_1,\ldots,t_k</math> respectively. By hypothesis on term t, we have <math>k\geq 1</math>. Let <math>t'_1,\ldots,t'_k</math> denote the terms obtained from <math>t_1,\ldots,t_k</math> by removing the leading lambda. |
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Consider the term <math>T=\lambda x_1\cdots\lambda x_p.(t'_1(t'_2(\cdots(t'_{k-1}t'_k)\cdots)</math> which is of size <math>n-1-b</math>, where b is the number of application nodes in B. Finally, let <math>U_{b,f(n)}</math> be the set of purely applicative terms of size b whose variables are chosen among a set of size <math>f(n)</math>. Consider the leftmost deepmost lambda of term T (leftmost among deepmost), and let <math>\lambda y.C</math> denote the term rooted at this position. For any <math>u\in U_{b,f(n)}</math>, we define the term <math>T(u)</math> by subsituting <math>\lambda y.C</math> with <math>\lambda y.(u.C)</math> in T and binding all variables of u according to their name to lambda above u. Firstly, <math>T(u)</math> is a well-defined closed term because the insertion of u occurs at depth at least <math>f(n)</math> and u has at most <math>f(n)</math> different variables. Secondly, <math>T(u)</math> has size exactly n. |
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The set <math>X_{b,p}</math> of binary trees with b internal nodes and leaves labelled either 'special' or by a variable among <math>x_1,\ldots,x_p</math> has cardinality <math>(p+1)^{b+1}C(b)</math> (where <math>C(b)</math> denotes the Catalan number). Besides, the set <math>U_{b,f(n)}</math> has carinality <math>f(n)^{b+1}C(b)</math>. Therefore, since <math>p\leq g(n)</math> and <math>g\in o(f)</math>, there exists a function <math>\rho</math> with <math>\rho(n)\rightarrow\infty</math> and a function <math>\Psi_{b,p,n}</math> from <math>X_{b,p}</math> to subsets of <math>U_{b,f(n)}</math> such that: |
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* for each <math>x\in X_{b,p}</math>, <math>\Psi_{b,p,n}(x)</math> contains <math>\rho(n)</math> elements; |
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* for n large enough, <math>x\not=x'\Rightarrow \Psi_{b,p,n}(x)\cap\Psi_{b,p,n}(x')=\emptyset</math>. |
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What we have established so far is the following: to term <math>t\in\Lambda_g\cap\Gamma_f</math> we assosiate '''injectively''' the 4-uple <math>(b,p,n,B,T)</math>; then, if u is the first element of <math>\Psi_{b,p,n}(B)</math> in some arbitrary (but fixed) order, we assotiate to <math>(b,p,n,B,T)</math> the term <math>\phi(t) = T(u)</math>. By hypothesis on function <math>\Psi_{b,p,n}</math> defined above, the function <math>\phi : t\mapsto \phi(t)</math> is injective for n large enough. Moreover, we have <math>\left|\phi(\Gamma_f\cap\Lambda_g\cap L_n)\right|\leq\frac{|\Gamma_f\cap L_n|}{\rho(n)}</math> so the image set of <math>\phi</math> has density 0 and the theorem follows. |
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=== Head lambdas bind "many" occurrences of the corresponding variables === |
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'''Theorem'''. \label{th:biding_lambdas} Let g and h be two functions belonging to <math>o\left(\frac{n}{\log(n)}\right)</math> and let <math>\Lambda_{g,h}</math> be the set of terms t where the total number of occurrences of variables bound to one of the <math>g(size(t))</math> head lambdas is less than <math>h(size(t))</math>. Then <math>\Lambda_{g,h}</math> has density 0. |
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'''Remark'''. The proof of this theorem uses arguments similar to those used in proof of theorem 'starting lambdas'. But is this theorem useful ? |
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Yes, since it is used in the next theorem. However, it is enough to show that for fixed integers k and k' each of k head lambdas binds at least k' variables. |
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[http://tcs.uj.edu.pl/~grygiel/lambdan/manyheadlambdas.pdf pdf] |
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[http://tcs.uj.edu.pl/~grygiel/lambdan/manyheadlambdas.tex tex] |
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=== every fixed closed term (including the identity !) does not appear in a random term (in fact we have much more than that) === |
=== every fixed closed term (including the identity !) does not appear in a random term (in fact we have much more than that) === |
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Let <math>\Lambda^{t_0}</math> denote the set of lambda terms which have <math>t_0</math> as a subterm and let <math>T_k</math> be the set of those lambda trees in which the number of unbounded leaves (occurrences of free variables) is equal to <math>k</math>. |
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; Theorem : |
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For any integers <math>k</math> and <math>k'\geq k+1</math> and for any term <math>t_0 \in T_k</math> of length <math>k'</math> the following holds: |
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<center> |
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<math> \lim_{n \to \infty} \frac{\# (\Lambda_n \cap \Lambda^{t_0})}{\# \Lambda_n} =0.</math> |
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</center> |
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; Proof : |
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Fix <math>k</math> and <math>k'\geq k+1</math>. Let <math>t_0</math> be a lambda tree of size <math>k'</math> with exactly <math>k</math> occurrences of free variables, denoted <math>x_1,\ldots,x_k</math> (not necessarily distinct). Since there are at most <math>k'-k+1</math> occurrences of lambdas and at most <math>k'+1</math> leaves in <math>t_0</math>, there are at most |
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<center> |
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<math>K=M(k')(k'+1)^{k'+1}</math> |
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</center> |
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such trees and we can enumerate them in a fixed way. Let <math>m</math> be the number of <math>t_0</math>. The tree <math>t_0</math> contains at least one occurrence of lambda, otherwise it would either contain more free variables or would be of a bigger size. |
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<br /> |
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Let <math>n</math> be an integer satisfying <math>\sqrt{\frac{n}{\ln(n)}} \geq K</math>. |
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<br /> |
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We will construct an injective function <math>f \colon \Lambda_n \cap \Lambda^{t_0} \to \Lambda_n</math> such that its image is of density 0 in <math>\Lambda_n</math>. |
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<br /> |
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Let <math>t</math> be a term of size <math>n</math> with <math>t_0</math> as its subterm. Let us consider the tree <math>T</math> which is built from the tree <math>t</math> by adding an additional unary node (labelled with <math>\lambda x</math>) at depth <math>m</math>. Next, let <math>T'</math> be the tree obtained by replacing the subtree <math>t_0</math> in <math>T</math> by the tree <math>t_1=UB</math>, where <math>U</math> is a binary tree of size <math>k'-k-1</math> such that <math>U=x(x(\ldots (xx)\ldots))</math> and <math>B=x_1(x_2(\ldots (x_{k-1}x_k)\ldots))</math>, so the size of <math>B</math> is equal to <math>k-1</math>. Thus, the size of <math>T'</math> is equal to <math>n</math>. The variable <math>x</math> is bound by the <math>m</math>-th lambda in the tree <math>T'</math>. Let us take <math>f(t)=T'</math>. Since <math>m</math> is the number of the tree <math>t_0</math>, the function <math>f</math> is injective. |
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<br /> |
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By Theorem \ref{?}, each of <math>K</math> head lambdas in a random tree of size <math>n</math> binds more than <math>k'</math> variables. Trees from the image <math>f(\Lambda_n \cap \Lambda^{t_0})</math> do not have this property, since the <math>m</math>-th lmabda binds only <math>k'</math> variables. Thus, those trees are negligible among all trees of size <math>n</math>. |
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; Corollary : |
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Let <math>t_0</math> be a closed lambda term. Then the density of <math>\Lambda^{t_0}</math> is equal to <math>0</math>. |
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; Corollary : |
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Let <math>t_0</math> be a lambda term in which there are at least two occurrences of lambdas. Then the density of <math>\Lambda^{t_0}</math> is equal to <math>0</math>. |
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comment : so different situation in combinatory logic and lambda calculus ; the coding uses a big size so need to count variables in a different way |
comment : so different situation in combinatory logic and lambda calculus ; the coding uses a big size so need to count variables in a different way |
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=== Random lambda terms are strongly normalizable === |
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Sketch of the proof [http://tcs.uj.edu.pl/~jkozik/LTCount/rSN.pdf pdf] [http://tcs.uj.edu.pl/~jkozik/LTCount/rSN.tex tex] |
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Jakub says: I think that it might be possible to simplify the proof, by using other argument for the proof that the density of the image of encoding equals 0. |
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Chambéry says: we checked the proof and we are convinced by the result. Since Jakub made an important step for the second time, we suggest to explicitely acknowledge his contribution in the paper (for instance, by naming some key lemma/theorems "Jakub's lemma/theorem"). Here are the points to fix in the proof: |
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* as René said, the definition of "dangerous redex" must be changed to allow a single occurrence of x in A (and a proof sketch of why "no dangerous redex" implies SN must be added) |
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* version 1 of encoding is sufficient |
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* in the encoding, there is some substituion of variable to do in C (to have a closed term at the end, and also to ensure that the decoding is unambiguous) |
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* to complete the proof with the new definition of "dangerous redex" we need the result saying that terms containing identity have density 0 (as said by Jakub by e-mail). We don't see how to conclude without that. However, we have to further check if there is no shorter proof... |
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== Experiments == |
== Experiments == |
Dernière version du 7 janvier 2009 à 16:33
counting.pdf : [1] version on wednesday 07/01 at 17h30. the files below are the good ones. René
Introduction
intro : [2]
lambda
combinatorics
section 3 : [4]
generating : [5]
bounds
main results
section 5-2
section 5-2-2 : [9]
section 5-2-3 :
[10]
section 5-2-4 : [11]
section 5-3
section 5-3-1 : [13]
section 5-3-2 :
[14]
section 5-3-3 : [15]
section 5-3-4 : [16]
other systems
section 6.1 : [18]
section 6.2 : [19]
conclusion
section 7.1 : [21]
section 7.2 : [22]
section 7.3 : [23]
biblio
appendix
appendix-1 : [26]
appendix-2 : [27]
What appears below is the old version
Known results for Turing machines and cellular automata
In this section I propose to comment on paper [28] and [29].
Guillaume says: I am very skeptical about paper 2 by D'Abramo. I suggest to replace it by the paper by Calude and Stay [30].
Lambert function, Catalan and Motzkin numbers
Catalan numbers
- : Catalan numbers
Usual equivalent: which is obtained using Strirling formula. However, using stirling formula which can be extended as the following double inequality:
Thus, using this and , we have:
Then, we can check that
Thus finally for all .
Motzkin numbers
In fact, these are not usual Motzkin's numbers because in , is the number of inner nodes while usually, this is the total number of nodes, including leaves. The number we use are known as large Schroeder numbers.
Let us define the number of unary-binary trees with inner nodes and leafs. A tree with inner node leafs has exactly binary nodes and therefore . Hence we get the following formula
Then, by summing we define the number of unary-binary trees with inner nodes and give an equivalent:
Lambert W function
The Lambert function is defined by the equation which has a unique solution in .
For , we have which implies that near . To prove this, it is enough to remark that
This is not precise enough for our purpose. Using one step of the Newton method from , we can find a better upper bound for because is increasing and convex when . This gives for :
Indeed, if we define , we have and therefore, newton's method from gives a point at position:
Finally, we show that for , we have:
Indeed, for , we have , which implies and therefore .
combinatory logic
Basically the paper already written by Marek
tex file : [31]
pdf file :[32]
+ the following
As we will see in section ??, theorem ?? does not holds for the Lambda calculus. This may be surprising since there are translations between these systems which respect many properties (for exemple the one of being terminating). However these translations do not preserve the size.
The translation from combinatory logic to lambda calculus is linear, i.e. there is a constant such that, for all terms, but the translation in the other direction is not linear. As far as we know, there is no known bound on the size of but it is not difficult to find exemples where is of order .
The point is that has to code the binding in some way and this takes place. It will be interesting to compare the size of with the one of using other notion of size than the usual one. See section ?? for some complement.
Generality on lambda calculus
definition
The set of lambda terms (or, simply, terms) is defined by the following grammar
To be able to define the notion of a random term we
have to define a distribution law on . There are many
possibilities for that. We choose here the simplest one. Note that this is the one for which, at least at present, we are
able to prove some results. It is based on densities. For that we
first have to define the size of a term.
The usual definition is the following.
definition
The size (denoted as ) of a term is defined by the following rules.
- if is a variable.
-
-
In the rest of the paper we will use another definition (denoted
as ) which is similar but gives simpler computations.
We believe (but we have not yet checked the details) that, with
we would have similar results. The
computation, with , of the upper and lower
bounds of the number of terms of size will be done
in section ??
definition
The size (denoted as or, more simply ) of a term is defined by the following rules.
- if is a variable.
-
-
These definitions of the size are, for the implementation point of
view, not realistic because, in case a term has a lot of distinct
variables, it is not realistic to use a single bit to code them.
The usual way to implement this coding is to replace the names of
variables by their so called de Bruijn indices: a variable is
replaced by the number of that occur, on the
path from the variable to the root, between the variable and the
that binds it. Note that, in this case,
different occurrences of the same variable may be represented by
different indices.
Choosing the way we code these de Bruijn indices gives different other ways of defining the size of a term. This can be done in the following ways
- Use unary notation, i.e. the size of the index simply is itself
- Use optimal binary notation, i.e. the size of the index is i.e. the logarithm of in base 2.
- Use uniform binary notation, i.e. the size of an index is the logarithm, in base 2, of the number of leaves of the term.
Remark
See section ?? for a discusion about these different size.
definition
Let be an integer. We denote by the set of terms of size n.
definition
Let A be a set of terms.
1) We denote by the cardinality of A.
2) We denote by the limit, for n going to , of .
Remark
Note that d is not exactly a measure since is undefined if the previous limit does not exist
definition
Let P be a property of terms. We will say that almost every term satisfies P (this will be also stated as P holds a.e.) if
generating functions
this does not work (by now) because radius of convergence 0
no known results for the number of terms of size n (denoted )
our results
(the proof of result of section k needs the result of section (k-1))
Upper and lower bounds for
For the lower bound, we will first count the number of lambda-terms of size starting with lambdas and having no other lambda below. This means that the lower part of the term is a binary tree with inner nodes with possibility for each leaf. Therefore we have:
And therefore, for , using our lower bound for and , we get:
Now, for fixed, we define (so ) and look for the maximum of this function. We have . Thus, is equivalent to . The Lambert function begin increasing this means that is equivalent to . Therefore, reaches a maximum for .
This means that reaches its maximum for fixed when is near to which is likely not to be an integer. However, there are at least integer between and . Indeed, using our inequalities on Lambert W function, we have:
Thus, we get the following lowerbound for :
To simplify, we first remove the constant and the integer part by replacing the term by any constant . This means that for any constant , we can take large enough to have:
Then, using the facts that , and , we have the following lowerbound (still for large enough, with ):
We now compute an upper bound for the number of lambda-terms of size with exactly lambdas (that is with leaves using the Motzkin numbers and allowing any lambda to bind any variable (regardless of the real scope):
If we sum this for all possible and get an upper bound of using Lambert function as for the lower bound, we get the following upper bound for :
The ration between our upper bound and lower bound is equivalent to (NEEDS FURTHER CHECKING, OR IS REMOVED because we can do better using Jakob's remark at the end of 7.2):
upper and lower bounds for number of lambdas in a term of size n
Let be the number of lambda term of size n containing more than lambdas. We search such that .
Using the previous notation, we may write . We observed that is decreasing in if .
Then, we have . Therefore, if (i), we have
Then, (i) is equivalent to which is true for large enough if because .
Using our lower bound for , we find
We now use the fact that , for large enough, we have (we introduce an extra log to compensate for the equivalent)
We get a simpler upper bound by using the to compensate for the exponent and the remaining , which gives:
Let us remark that and .
Thus we have:
This means that converges toward zero if . reaches its maximum in and This means that has two solutions, one for the other for . Because of (i) we need to keep the first solution. It is easy to see that the first solution is smaller than 3 because .
Corollary. Random lambda term of size n contains asymptotically no more then lambdas.
In the same way, we can consider lambda-terms with less than and redo exactly the same computation, but replacing (i) by (ii). Then we have to take smaller than the other solution of the equation, and if it easy to see that works.
Corollary. Random lambda term of size n contains asymptotically no less then lambdas.
Once we know this we can improve the upper bound.
Let Ll be . In a term from Ll the proportion between unary and binary nodes is smaller then which is far from typical proportion in unary-binary trees which tends to some nonzero constant. Rough estimation gives
where C(n) corresponds to the binary structure, to the possible distribtions of lambdas in binary structure and to the possibilities of bindings (one can optimal number of unary nodes involving Lambert's function to get rid of epsilon here). The crucial observation now is that is subexponential.
Comparing this upper bound with we would obtain that the asymptotic ratio between upper and lower bound is subexponential.
I think it has some serious consequences. In particular it seems that in a random lambda term almost all lambdas lie on one path.
Proposition. \label{prop:typical_depth} There exists a function such that the set of terms t having a -depth greater than has density 1.
Lambdas in head position
Theorem. \label{th:starting_lambdas} Let . The set of terms t starting with less than lambdas has density 0.
Proof. By proposition \ref{prop:typical_depth}, for some function f such that , we can restrict to the set of terms t having -depth at least (because has density 1). To prove the theorem it is sufficient to exhibit a one-to-one function from into whose image set has density 0. We now define by describing where t is an arbitrary term of size n belonging to . By hypothesis, the term t starts with a chain of p -nodes, where . So where A is a term starting by an application and containing at least one (for n large enough). Now let B be the maximal purely applicative prefix of A. Precisely, B is the maximal binary tree whose leaves are either special leaves or variables among and such that where are terms starting with a lambda, and denotes the term obtained by replacing successive special leaves of B by terms respectively. By hypothesis on term t, we have . Let denote the terms obtained from by removing the leading lambda. Consider the term which is of size , where b is the number of application nodes in B. Finally, let be the set of purely applicative terms of size b whose variables are chosen among a set of size . Consider the leftmost deepmost lambda of term T (leftmost among deepmost), and let denote the term rooted at this position. For any , we define the term by subsituting with in T and binding all variables of u according to their name to lambda above u. Firstly, is a well-defined closed term because the insertion of u occurs at depth at least and u has at most different variables. Secondly, has size exactly n.
The set of binary trees with b internal nodes and leaves labelled either 'special' or by a variable among has cardinality (where denotes the Catalan number). Besides, the set has carinality . Therefore, since and , there exists a function with and a function from to subsets of such that:
- for each , contains elements;
- for n large enough, .
What we have established so far is the following: to term we assosiate injectively the 4-uple ; then, if u is the first element of in some arbitrary (but fixed) order, we assotiate to the term . By hypothesis on function defined above, the function is injective for n large enough. Moreover, we have so the image set of has density 0 and the theorem follows.
Head lambdas bind "many" occurrences of the corresponding variables
Theorem. \label{th:biding_lambdas} Let g and h be two functions belonging to and let be the set of terms t where the total number of occurrences of variables bound to one of the head lambdas is less than . Then has density 0.
Remark. The proof of this theorem uses arguments similar to those used in proof of theorem 'starting lambdas'. But is this theorem useful ?
Yes, since it is used in the next theorem. However, it is enough to show that for fixed integers k and k' each of k head lambdas binds at least k' variables.
every fixed closed term (including the identity !) does not appear in a random term (in fact we have much more than that)
Let denote the set of lambda terms which have as a subterm and let be the set of those lambda trees in which the number of unbounded leaves (occurrences of free variables) is equal to .
- Theorem
For any integers and and for any term of length the following holds:
- Proof
Fix and . Let be a lambda tree of size with exactly occurrences of free variables, denoted (not necessarily distinct). Since there are at most occurrences of lambdas and at most leaves in , there are at most
such trees and we can enumerate them in a fixed way. Let be the number of . The tree contains at least one occurrence of lambda, otherwise it would either contain more free variables or would be of a bigger size.
Let be an integer satisfying .
We will construct an injective function such that its image is of density 0 in .
Let be a term of size with as its subterm. Let us consider the tree which is built from the tree by adding an additional unary node (labelled with ) at depth . Next, let be the tree obtained by replacing the subtree in by the tree , where is a binary tree of size such that and , so the size of is equal to . Thus, the size of is equal to . The variable is bound by the -th lambda in the tree . Let us take . Since is the number of the tree , the function is injective.
By Theorem \ref{?}, each of head lambdas in a random tree of size binds more than variables. Trees from the image do not have this property, since the -th lmabda binds only variables. Thus, those trees are negligible among all trees of size .
- Corollary
Let be a closed lambda term. Then the density of is equal to .
- Corollary
Let be a lambda term in which there are at least two occurrences of lambdas. Then the density of is equal to .
comment : so different situation in combinatory logic and lambda calculus ; the coding uses a big size so need to count variables in a different way
Random lambda terms are strongly normalizable
Jakub says: I think that it might be possible to simplify the proof, by using other argument for the proof that the density of the image of encoding equals 0.
Chambéry says: we checked the proof and we are convinced by the result. Since Jakub made an important step for the second time, we suggest to explicitely acknowledge his contribution in the paper (for instance, by naming some key lemma/theorems "Jakub's lemma/theorem"). Here are the points to fix in the proof:
- as René said, the definition of "dangerous redex" must be changed to allow a single occurrence of x in A (and a proof sketch of why "no dangerous redex" implies SN must be added)
- version 1 of encoding is sufficient
- in the encoding, there is some substituion of variable to do in C (to have a closed term at the end, and also to ensure that the decoding is unambiguous)
- to complete the proof with the new definition of "dangerous redex" we need the result saying that terms containing identity have density 0 (as said by Jakub by e-mail). We don't see how to conclude without that. However, we have to further check if there is no shorter proof...
Experiments
results of the experiments we have done
some experiments that have to be done : e.g. density of terms having or big Omega pattern ...
to be done
Upper and lower bounds for with other size for variables especially one, binary with fixed size
Open questions and Future work
.....