let C1 be non empty AltGraph ; :: thesis: for C2 being non empty reflexive AltGraph
for o2 being object of
for m being Morphism of ,
for F being feasible Covariant FunctorStr of C1,C2 st F = C1 --> m holds
for o, o' being object of
for f being Morphism of , st <^o,o'^> <> {} holds
F . f = m
let C2 be non empty reflexive AltGraph ; :: thesis: for o2 being object of
for m being Morphism of ,
for F being feasible Covariant FunctorStr of C1,C2 st F = C1 --> m holds
for o, o' being object of
for f being Morphism of , st <^o,o'^> <> {} holds
F . f = m
let o2 be object of ; :: thesis: for m being Morphism of ,
for F being feasible Covariant FunctorStr of C1,C2 st F = C1 --> m holds
for o, o' being object of
for f being Morphism of , st <^o,o'^> <> {} holds
F . f = m
A1: <^o2,o2^> <> {} by ALTCAT_2:def 7;
let m be Morphism of ,; :: thesis: for F being feasible Covariant FunctorStr of C1,C2 st F = C1 --> m holds
for o, o' being object of
for f being Morphism of , st <^o,o'^> <> {} holds
F . f = m
let F be feasible Covariant FunctorStr of C1,C2; :: thesis: ( F = C1 --> m implies for o, o' being object of
for f being Morphism of , st <^o,o'^> <> {} holds
F . f = m )
assume A2: F = C1 --> m ; :: thesis: for o, o' being object of
for f being Morphism of , st <^o,o'^> <> {} holds
F . f = m
let o, o' be object of ; :: thesis: for f being Morphism of , st <^o,o'^> <> {} holds
F . f = m
let f be Morphism of ,; :: thesis: ( <^o,o'^> <> {} implies F . f = m )
assume A3: <^o,o'^> <> {} ; :: thesis: F . f = m
then <^(F . o),(F . o')^> <> {} by Def19;
hence F . f = (Morph-Map F,o,o') . f by A3, Def16
.= m by A1, A2, A3, Th25 ;
:: thesis: verum