let G be finite _Graph; :: thesis: for L being LexBFS:Labeling of G
for x being set st not x in dom (L `1 ) & dom (L `1 ) <> the_Vertices_of G holds
((L `2 ) . x),1 -bag <= ((L `2 ) . (LexBFS:PickUnnumbered L)),1 -bag , InvLexOrder NAT
let L be LexBFS:Labeling of G; :: thesis: for x being set st not x in dom (L `1 ) & dom (L `1 ) <> the_Vertices_of G holds
((L `2 ) . x),1 -bag <= ((L `2 ) . (LexBFS:PickUnnumbered L)),1 -bag , InvLexOrder NAT
let x be set ; :: thesis: ( not x in dom (L `1 ) & dom (L `1 ) <> the_Vertices_of G implies ((L `2 ) . x),1 -bag <= ((L `2 ) . (LexBFS:PickUnnumbered L)),1 -bag , InvLexOrder NAT )
assume that
A1: not x in dom (L `1 ) and
A2: dom (L `1 ) <> the_Vertices_of G ; :: thesis: ((L `2 ) . x),1 -bag <= ((L `2 ) . (LexBFS:PickUnnumbered L)),1 -bag , InvLexOrder NAT
set VG = the_Vertices_of G;
set V2G = L `2 ;
set VLG = L `1 ;
set w = LexBFS:PickUnnumbered L;
consider S being non empty finite Subset of (bool NAT ), B being non empty finite Subset of (Bags NAT ), F being Function such that
A3: S = rng F and
A4: F = (L `2 ) | ((the_Vertices_of G) \ (dom (L `1 ))) and
A5: for x being finite Subset of NAT st x in S holds
x,1 -bag in B and
A6: for x being set st x in B holds
ex y being finite Subset of NAT st
( y in S & x = y,1 -bag ) and
A7: LexBFS:PickUnnumbered L = choose (F " {(support (max B,(InvLexOrder NAT )))}) by A2, Def12;
A8: dom F = (dom (L `2 )) /\ ((the_Vertices_of G) \ (dom (L `1 ))) by A4, RELAT_1:90;
set mw = max B,(InvLexOrder NAT );
max B,(InvLexOrder NAT ) in B by Def5;
then consider y being finite Subset of NAT such that
A9: y in S and
A10: max B,(InvLexOrder NAT ) = y,1 -bag by A6;
A11: y = support (max B,(InvLexOrder NAT )) by A10, UPROOTS:10;
then A12: not F " {(support (max B,(InvLexOrder NAT )))} is empty by A3, A9, FUNCT_1:142;
then LexBFS:PickUnnumbered L in dom F by A7, FUNCT_1:def 13;
then A13: (L `2 ) . (LexBFS:PickUnnumbered L) = F . (LexBFS:PickUnnumbered L) by A4, FUNCT_1:70;
F . (LexBFS:PickUnnumbered L) in {(support (max B,(InvLexOrder NAT )))} by A7, A12, FUNCT_1:def 13;
then A14: ((L `2 ) . (LexBFS:PickUnnumbered L)),1 -bag = max B,(InvLexOrder NAT ) by A10, A11, A13, TARSKI:def 1;
A15: dom (L `2 ) = the_Vertices_of G by FUNCT_2:def 1;
per cases ( x in the_Vertices_of G or not x in the_Vertices_of G ) ;
suppose x in the_Vertices_of G ; :: thesis: ((L `2 ) . x),1 -bag <= ((L `2 ) . (LexBFS:PickUnnumbered L)),1 -bag , InvLexOrder NAT
then x in (the_Vertices_of G) \ (dom (L `1 )) by A1, XBOOLE_0:def 5;
then A16: x in dom F by A15, A8, XBOOLE_0:def 4;
then A17: F . x in S by A3, FUNCT_1:def 5;
F . x = (L `2 ) . x by A4, A16, FUNCT_1:70;
then ((L `2 ) . x),1 -bag in B by A5, A17;
hence ((L `2 ) . x),1 -bag <= ((L `2 ) . (LexBFS:PickUnnumbered L)),1 -bag , InvLexOrder NAT by A14, Def5; :: thesis: verum
end;
suppose not x in the_Vertices_of G ; :: thesis: ((L `2 ) . x),1 -bag <= ((L `2 ) . (LexBFS:PickUnnumbered L)),1 -bag , InvLexOrder NAT
then (L `2 ) . x = {} by A15, FUNCT_1:def 4;
then ((L `2 ) . x),1 -bag = EmptyBag NAT by UPROOTS:11;
hence ((L `2 ) . x),1 -bag <= ((L `2 ) . (LexBFS:PickUnnumbered L)),1 -bag , InvLexOrder NAT by TERMORD:9; :: thesis: verum
end;
end;