In category theory, a faithful functor is a functor that is injective on hom-sets, and a full functor is surjective on hom-sets. A functor that has both properties is called a fully faithful functor.
Formal definitions
Explicitly, let C and D be (locally small) categories and let F : C → D be a functor from C to D. The functor F induces a function
for every pair of objects X and Y in C. The functor F is said to be
- faithful if FX,Y is injective
- full if FX,Y is surjective
- fully faithful (= full and faithful) if FX,Y is bijective
for each X and Y in C.
Properties
A faithful functor need not be injective on objects or morphisms. That is, two objects X and X′ may map to the same object in D (which is why the range of a full and faithful functor is not necessarily isomorphic to C), and two morphisms f : X → Y and f′ : X′ → Y′ (with different domains/codomains) may map to the same morphism in D. Likewise, a full functor need not be surjective on objects or morphisms. There may be objects in D not of the form FX for some X in C. Morphisms between such objects clearly cannot come from morphisms in C.
A full and faithful functor is necessarily injective on objects up to isomorphism. That is, if F : C → D is a full and faithful functor and 
then 
.
Examples
- The forgetful functor U : Grp → Set maps groups to their underlying set, "forgetting" the group operation. U is faithful because two group homomorphisms with the same domains and codomains are equal if they are given by the same functions on the underlying sets. This functor is not full as there are functions between the underlying sets of groups that are not group homomorphisms. A category with a faithful functor to Set is (by definition) a concrete category; in general, that forgetful functor is not full.
- The inclusion functor Ab → Grp is fully faithful, since Ab (the category of abelian groups) is by definition the full subcategory of Grp induced by the abelian groups.
Generalization to (∞, 1)-categories
The notion of a functor being 'full' or 'faithful' does not translate to the notion of a (∞, 1)-category. In an (∞, 1)-category, the maps between any two objects are given by a space only up to homotopy. Since the notion of injection and surjection are not homotopy invariant notions (consider an interval embedding into the real numbers vs. an interval mapping to a point), we do not have the notion of a functor being "full" or "faithful." However, we can define a functor of quasi-categories to be fully faithful if for every X and Y in C, the map 
is a weak equivalence.
See also
- Full subcategory
- Equivalence of categories
Notes
- Mac Lane (1971), p. 15
- Jacobson (2009), p. 22
- Mac Lane (1971), p. 14
References
In category theory a faithful functor is a functor that is injective on hom sets and a full functor is surjective on hom sets A functor that has both properties is called a fully faithful functor Formal definitionsExplicitly let C and D be locally small categories and let F C D be a functor from C to D The functor F induces a function FX Y HomC X Y HomD F X F Y displaystyle F X Y colon mathrm Hom mathcal C X Y rightarrow mathrm Hom mathcal D F X F Y for every pair of objects X and Y in C The functor F is said to be faithful if FX Y is injective full if FX Y is surjective fully faithful full and faithful if FX Y is bijective for each X and Y in C PropertiesA faithful functor need not be injective on objects or morphisms That is two objects X and X may map to the same object in D which is why the range of a full and faithful functor is not necessarily isomorphic to C and two morphisms f X Y and f X Y with different domains codomains may map to the same morphism in D Likewise a full functor need not be surjective on objects or morphisms There may be objects in D not of the form FX for some X in C Morphisms between such objects clearly cannot come from morphisms in C A full and faithful functor is necessarily injective on objects up to isomorphism That is if F C D is a full and faithful functor and F X F Y displaystyle F X cong F Y then X Y displaystyle X cong Y ExamplesThe forgetful functor U Grp Set maps groups to their underlying set forgetting the group operation U is faithful because two group homomorphisms with the same domains and codomains are equal if they are given by the same functions on the underlying sets This functor is not full as there are functions between the underlying sets of groups that are not group homomorphisms A category with a faithful functor to Set is by definition a concrete category in general that forgetful functor is not full The inclusion functor Ab Grp is fully faithful since Ab the category of abelian groups is by definition the full subcategory of Grp induced by the abelian groups Generalization to 1 categoriesThe notion of a functor being full or faithful does not translate to the notion of a 1 category In an 1 category the maps between any two objects are given by a space only up to homotopy Since the notion of injection and surjection are not homotopy invariant notions consider an interval embedding into the real numbers vs an interval mapping to a point we do not have the notion of a functor being full or faithful However we can define a functor of quasi categories to be fully faithful if for every X and Y in C the map FX Y displaystyle F X Y is a weak equivalence See alsoFull subcategory Equivalence of categoriesNotesMac Lane 1971 p 15 Jacobson 2009 p 22 Mac Lane 1971 p 14ReferencesMac Lane Saunders September 1998 Categories for the Working Mathematician second ed Springer ISBN 0 387 98403 8 Jacobson Nathan 2009 Basic algebra Vol 2 2nd ed Dover ISBN 978 0 486 47187 7
