4 User friendly ways to give semigroups and automata This chapter describes two Tcl/Tk graphical interfaces that can be used to define and edit semigroups and automata. 4.1 Finite automata 4.1-1 XAutomaton XAutomaton( [A] )  function The function  Xautomaton  without arguments opens a new window where an automaton may be specified. A finite automaton (which may then be edited) may be given as argument.  Example  gap> XAutomaton();    It opens a window like the following:  Var  is the GAP name of the automaton,  States  is the number of states,  Alphabet  represents the alphabet and may be given through a positive integer (in this case the alphabet is understood to be  a,b,c,... ) or through a string whose symbols, in order, being the letters of the alphabet. The numbers corresponding to the initial and accepting states are placed in the respective boxes. The automaton may be specified to be deterministic, non deterministic or with epsilon transitions. After pressing the  transition matrix  button the window gets larger and the transition matrix of the automaton may be given. The ith row of the matrix describes the action of the ith letter on the states. A non deterministic automaton may be given as follows: By pressing the button  Ok  the GAP shell aquires the aspect shown in the following picture and the automaton  ndAUT  may be used to do computations. Some computations such as getting a rational expression representing the language of the automaton, the (complete) minimal automaton representing the same language or the transition semigroup of the automaton, may be done directly after pressing the  Functions button. By pressing the button  View  an image representing the automaton is displayed in a new window. An automaton with epsilon transitions may be given as follows shown in the following picture. The last letter of the alphabet is always considered to be the ϵ. In the images it is represented by @. A new window with an image representing the automaton may be obtained by pressing the button  View . In the next example it is given an argument to the function XAutomaton.  Example  gap> A := RandomAutomaton("det",2,2); < deterministic automaton on 2 letters with 2 states > gap> XAutomaton(A);    It opens a window like the following: 4.2 Finite semigroups The most common ways to give a semigroup to are through generators and relations, a set of (partial) transformations as generating set and as syntactic semigroups of automata or rational languages. 4.2-1 XSemigroup XSemigroup( [S] )  function The function  XSemigroup  without arguments opens a new window where a semigroup (or monoid) may be specified. A finite semigroup (which may then be edited) may be given as argument.  Example  gap> XSemigroup();    It opens a window like the following: where one may choose how to give the semigroup. 4.2-2 Semigroups given through generators and relations In the window opened by XSemigroup, by pressing the button Proceed the window should enlarge and have the following aspect. (If the window does not enlarge automatically, use the mouse to do it.)  GAP variable  is the GAP name of the semigroup. One has then to specify the number of generators, the number of relations (which does not to be exact) and whether one wants to produce a monoid or a semigroup. Pressing the Proceed button one gets: 4.2-3 Semigroups given by partial transformations XSemigroup(poi3); would pop up the following window, where everything should be clear: 4.2-4 Syntatic semigroups XSemigroup(); would pop up the following window, where we would select "Syntatic semigroup", press the Proceed button and then choose either to give a "Rational expression" or an "Automaton" by pressing one of those buttons: If "Rational expression" is chosen, a new window pops up where the expression can be specified: After pressing the Ok button, notice that the menu button Functions appears on the main window (lower right corner) meaning that GAP already recognizes the given semigroup: