# -*- coding: utf-8 -*- #+TITLE: =randaut= #+SETUPFILE: setup.org #+HTML_LINK_UP: tools.html The =randaut= tool generates random (connected) automata. By default, it will generate a random TGBA with 10 states, no acceptance sets, and using a set of atomic proposition you have to supply. #+NAME: randaut1 #+BEGIN_SRC sh :results verbatim :exports code randaut a b #+END_SRC #+RESULTS: randaut1 #+begin_example digraph G { rankdir=LR fontname="Lato" node [fontname="Lato"] edge [fontname="Lato"] node[style=filled, fillcolor="#ffffa0"] I [label="", style=invis, width=0] I -> 0 0 [label="0"] 0 -> 8 [label=] 0 -> 4 [label=] 1 [label="1"] 1 -> 2 [label=] 1 -> 7 [label=] 1 -> 4 [label=] 2 [label="2"] 2 -> 2 [label=] 2 -> 0 [label=] 2 -> 5 [label=] 3 [label="3"] 3 -> 6 [label=] 4 [label="4"] 4 -> 8 [label=] 4 -> 2 [label=] 4 -> 3 [label=] 4 -> 7 [label=] 5 [label="5"] 5 -> 9 [label=] 5 -> 3 [label=] 5 -> 7 [label=] 6 [label="6"] 6 -> 7 [label=] 6 -> 1 [label=] 7 [label="7"] 7 -> 3 [label=] 8 [label="8"] 8 -> 8 [label=] 9 [label="9"] 9 -> 0 [label=] 9 -> 6 [label=] } #+end_example #+BEGIN_SRC dot :file randaut1.png :cmdline -Tpng :var txt=randaut1 :exports results $txt #+END_SRC #+RESULTS: [[file:randaut1.png]] As for [[file:randltl.org][=randltl=]], you can supply a number of atomic propositions instead of giving a list of atomic propositions. * States and density The numbers of states can be controlled using the =-S= option. This option will accept a range as argument, so for instance =-S3..6= will generate an automaton with 3 to 6 states. The number of edges can be controlled using the =-d= (or =--density=) option. The argument should be a number between 0 and 1. In an automaton with $S$ states and density $d$, the degree of each state will follow a normal distribution with mean $1+(S-1)d$ and variance $(S-1)d(1-d)$. In particular =-d0= will cause all states to have 1 successors, and =-d1= will cause all states to be interconnected. #+NAME: randaut2 #+BEGIN_SRC sh :results verbatim :exports code randaut -S3 -d0 2 #+END_SRC #+RESULTS: randaut2 #+begin_example digraph G { rankdir=LR fontname="Lato" node [fontname="Lato"] edge [fontname="Lato"] node[style=filled, fillcolor="#ffffa0"] I [label="", style=invis, width=0] I -> 0 0 [label="0"] 0 -> 2 [label=] 1 [label="1"] 1 -> 1 [label=] 2 [label="2"] 2 -> 1 [label=] } #+end_example #+BEGIN_SRC dot :file randaut2.png :cmdline -Tpng :var txt=randaut2 :exports results $txt #+END_SRC #+RESULTS: [[file:randaut2.png]] #+NAME: randaut3 #+BEGIN_SRC sh :results verbatim :exports code randaut -S3 -d1 2 #+END_SRC #+RESULTS: randaut3 #+begin_example digraph G { rankdir=LR fontname="Lato" node [fontname="Lato"] edge [fontname="Lato"] node[style=filled, fillcolor="#ffffa0"] I [label="", style=invis, width=0] I -> 0 0 [label="0"] 0 -> 2 [label=] 0 -> 0 [label=] 0 -> 1 [label=] 1 [label="1"] 1 -> 1 [label=] 1 -> 2 [label=] 1 -> 0 [label=] 2 [label="2"] 2 -> 1 [label=] 2 -> 0 [label=] 2 -> 2 [label=] } #+end_example #+BEGIN_SRC dot :file randaut3.png :cmdline -Tpng :var txt=randaut3 :exports results $txt #+END_SRC #+RESULTS: [[file:randaut3.png]] * Acceptance sets The generation of acceptance sets is controlled with the following three parameters: - =-A= (or =--acc-sets=) controls the number of acceptance sets. This can be given as a range (e.g. =-A1..3=) in case you want this number to be picked at random in the range. - =-a= (or =--acc-probability=) controls the probability that any transition belong to a given acceptance set. - =--state-acc= requests that the automaton use state-based acceptance. In this case, =-a= is the probability that a /state/ belong to the acceptance set. (Because Spot only deals with transition-based acceptance internally, this options force all transitions leaving a state to belong to the same acceptance sets. But if the output format allows state-acceptance, it will be used.) In addition, =-B= (or =--ba=) is a shorthand for =-A1 --state-acc=. #+NAME: randaut4 #+BEGIN_SRC sh :results verbatim :exports code randaut -S3 -d0.5 -A3 -a0.5 2 #+END_SRC #+RESULTS: randaut4 #+begin_example digraph G { rankdir=LR fontname="Lato" node [fontname="Lato"] edge [fontname="Lato"] node[style=filled, fillcolor="#ffffa0"] I [label="", style=invis, width=0] I -> 0 0 [label="0"] 0 -> 1 [label=] 0 -> 0 [label=❷>] 1 [label="1"] 1 -> 2 [label=❶❷>] 2 [label="2"] 2 -> 2 [label=⓿>] 2 -> 1 [label=⓿❶>] } #+end_example #+BEGIN_SRC dot :file randaut4.png :cmdline -Tpng :var txt=randaut4 :exports results $txt #+END_SRC #+RESULTS: [[file:randaut4.png]] #+NAME: randaut5 #+BEGIN_SRC sh :results verbatim :exports code randaut -S3 -d0.4 -B -a0.7 2 #+END_SRC #+RESULTS: randaut5 #+begin_example digraph G { rankdir=LR fontname="Lato" node [fontname="Lato"] edge [fontname="Lato"] node[style=filled, fillcolor="#ffffa0"] I [label="", style=invis, width=0] I -> 0 0 [label="0"] 0 -> 2 [label=] 1 [label="1"] 1 -> 2 [label=] 2 [label="2", peripheries=2] 2 -> 1 [label=] 2 -> 0 [label=] } #+end_example #+BEGIN_SRC dot :file randaut5.png :cmdline -Tpng :var txt=randaut5 :exports results $txt #+END_SRC #+RESULTS: [[file:randaut5.png]] * Determinism The output can only contain a single edge between two given states. By default, the label of this edge is a random assignment of all atomic propositions. Two edges leaving the same state may therefore have the same label. If the =-D= (or =--deterministic=) option is supplied, the labels are generated differently: once the degree $m$ of a state has been decided, the algorithm will compute a set of $m$ disjoint Boolean formulas over the given atomic propositions, such that the sum of all these formulas is $\top$. The resulting automaton is therefore deterministic and complete. #+NAME: randaut6 #+BEGIN_SRC sh :results verbatim :exports code randaut -D -S3 -d0.6 -A2 -a0.5 2 #+END_SRC #+RESULTS: randaut6 #+begin_example digraph G { rankdir=LR fontname="Lato" node [fontname="Lato"] edge [fontname="Lato"] node[style=filled, fillcolor="#ffffa0"] I [label="", style=invis, width=0] I -> 0 0 [label="0"] 0 -> 1 [label=] 0 -> 2 [label=] 1 [label="1"] 1 -> 2 [label=❶>] 1 -> 0 [label=⓿>] 2 [label="2"] 2 -> 2 [label=⓿>] 2 -> 0 [label=❶>] 2 -> 1 [label=⓿>] } #+end_example #+BEGIN_SRC dot :file randaut6.png :cmdline -Tpng :var txt=randaut6 :exports results $txt #+END_SRC #+RESULTS: [[file:randaut6.png]] Note that in a deterministic automaton with $a$ atomic propositions, it is not possible to have states with more than $2^a$ successors. If the combination of =-d= and =-S= allows the situation where a state can have more than $2^a$ successors, the degree will be clipped to $2^a$. When working with random deterministic automata over $a$ atomic propositions, we suggest you always request more than $2^a$ states. * Output formats The output format can be controlled using [[file:oaut.org][the common output options]] like =--hoaf=, =--dot==, =--lbtt=, and =--spin=. Note that =--spin= automatically implies =--ba=. * Generating a stream of automata Use option =-n= to specify a number of automata to build. A negative value will cause an infinite number of automata to be produced. This generation of multiple automata is probably useful only with =--hoaf=, when piped to another tool that can read this format and process automata in batches.