defpred S1[ set , set , set ] means ( ( $2 is DIJK:Labeling of G & ex Gn, Gn1 being DIJK:Labeling of G st
( $2 = Gn & $3 = Gn1 & Gn1 = DIJK:Step Gn ) ) or ( $2 is not DIJK:Labeling of G & $2 = $3 ) );
now let n,
x be
set ;
ex y being set st S1[n,x,y]hence
ex
y being
set st
S1[
n,
x,
y]
;
verum end;
then A1:
for n being Element of NAT
for x being set ex y being set st S1[n,x,y]
;
consider IT being Function such that
A2:
( dom IT = NAT & IT . 0 = DIJK:Init src & ( for n being Element of NAT holds S1[n,IT . n,IT . (n + 1)] ) )
from RECDEF_1:sch 1(A1);
reconsider IT = IT as ManySortedSet of NAT by A2, PARTFUN1:def 2, RELAT_1:def 18;
defpred S2[ Nat] means IT . $1 is DIJK:Labeling of G;
A5:
S2[ 0 ]
by A2;
for n being Nat holds S2[n]
from NAT_1:sch 2(A5, A3);
then reconsider IT = IT as DIJK:LabelingSeq of G by Def10;
reconsider IT = IT as DIJK:LabelingSeq of G ;
take
IT
; ( IT . 0 = DIJK:Init src & ( for n being Nat holds IT . (n + 1) = DIJK:Step (IT . n) ) )
thus
IT . 0 = DIJK:Init src
by A2; for n being Nat holds IT . (n + 1) = DIJK:Step (IT . n)
let n be Nat; IT . (n + 1) = DIJK:Step (IT . n)
reconsider n9 = n as Element of NAT by ORDINAL1:def 12;
ex Gn, Gn1 being DIJK:Labeling of G st
( IT . n9 = Gn & IT . (n + 1) = Gn1 & Gn1 = DIJK:Step Gn )
by A2;
hence
IT . (n + 1) = DIJK:Step (IT . n)
; verum