let A be Euclidean preIfWhileAlgebra; :: thesis:
let X be non empty countable set ; :: thesis:
let s be Element of Funcs X,INT ; :: thesis:
let b be Element of X; :: thesis:
let g be Euclidean ExecutionFunction of A, Funcs X,INT ,(Funcs X,INT ) \ b,0 ; :: thesis:
let I be Element of A; :: thesis:
let i, n be Variable of g; :: thesis:
given d being Function such that A1: d . b = 0 and
A2: d . n = 1 and
A3: d . i = 2 ; :: thesis:
set J = i += 1;
set C = i leq n;
set S = Funcs X,INT ;
set h = g;
assume A4: for s being Element of Funcs X,INT holds
( (g . s,I) . n = s . n & (g . s,I) . i = s . i ) ; :: thesis:
deffunc H₁( Element of Funcs X,INT ) -> Element of NAT = In ((($1 . n) + 1) - ($1 . i)),NAT ;
defpred S₁[ Element of Funcs X,INT ] means $1 . i <= $1 . n;
set T = (Funcs X,INT ) \ b,0 ;
A5: i <> n by A2, A3;
A6: for s being Element of Funcs X,INT st S₁[s] holds
( ( S₁[g . s,((I \; (i += 1)) \; (i leq n))] implies g . s,((I \; (i += 1)) \; (i leq n)) in (Funcs X,INT ) \ b,0 ) & ( g . s,((I \; (i += 1)) \; (i leq n)) in (Funcs X,INT ) \ b,0 implies S₁[g . s,((I \; (i += 1)) \; (i leq n))] ) & H₁(g . s,((I \; (i += 1)) \; (i leq n))) < H₁(s) )

let s be Element of Funcs X,INT ; :: thesis:
set s1 = g . s,I;
set q = g . s,(I \; (i += 1));
set q1 = g . (g . s,(I \; (i += 1))),(i leq n);
A7: g . s,(I \; (i += 1)) = g . (g . s,I),(i += 1) by AOFA_000:def 29;
(g . s,I) . i = s . i by A4;
then (g . s,(I \; (i += 1))) . i = (s . i) + 1 by A7, Th28;
then A8: (g . (g . s,(I \; (i += 1))),(i leq n)) . i = (s . i) + 1 by A1, A3, Th35;
A9: ( (g . s,(I \; (i += 1))) . i > (g . s,(I \; (i += 1))) . n implies (g . (g . s,(I \; (i += 1))),(i leq n)) . b = 0 ) by Th35;
assume S₁[s] ; :: thesis:
then reconsider ni = (s . n) - (s . i) as Element of NAT by INT_1:16, XREAL_1:50;
A10: g . (g . s,(I \; (i += 1))),(i leq n) = g . s,((I \; (i += 1)) \; (i leq n)) by AOFA_000:def 29;
A11: ( (g . s,(I \; (i += 1))) . i <= (g . s,(I \; (i += 1))) . n implies (g . (g . s,(I \; (i += 1))),(i leq n)) . b = 1 ) by Th35;
(g . (g . s,(I \; (i += 1))),(i leq n)) . i = (g . s,(I \; (i += 1))) . i by A1, A3, Th35;
hence ( S₁[g . s,((I \; (i += 1)) \; (i leq n))] iff g . s,((I \; (i += 1)) \; (i leq n)) in (Funcs X,INT ) \ b,0 ) by A1, A2, A9, A11, A10, Th2, Th35; :: thesis:
A12: H₁(s) = ni + 1 by FUNCT_7:def 1;
(g . s,I) . n = s . n by A4;
then (g . s,(I \; (i += 1))) . n = s . n by A5, A7, Th28;
then (g . (g . s,(I \; (i += 1))),(i leq n)) . n = s . n by A1, A2, Th35;
then H₁(g . (g . s,(I \; (i += 1))),(i leq n)) = ni by A8, FUNCT_7:def 1;
hence H₁(g . s,((I \; (i += 1)) \; (i leq n))) < H₁(s) by A10, A12, NAT_1:13; :: thesis:

end;

reconsider s1 = g . s,(i leq n) as Element of Funcs X,INT ;
A13: ( s . i > s . n implies s1 . b = 0 ) by Th35;
A14: ( s . i <= s . n implies s1 . b = 1 ) by Th35;
s1 . i = s . i by A1, A3, Th35;
then A15: ( s1 in (Funcs X,INT ) \ b,0 iff S₁[s1] ) by A1, A2, A13, A14, Th2, Th35;
g iteration_terminates_for (I \; (i += 1)) \; (i leq n),s1 from AOFA_000:sch 3(A15, A6);
hence g iteration_terminates_for (I \; (i += 1)) \; (i leq n),g . s,(i leq n) ; :: thesis: