\[ \require{mathtools} \let\DeclarePairedDelimiter\DeclarePairedDelimiters % MathJax typo %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % symbol %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % sets \newcommand{\N}{\mathbb{N}} % natural numbers \newcommand{\Z}{\mathbb{Z}} % integers \newcommand{\Q}{\mathbb{Q}} % rational numbers \newcommand{\R}{\mathbb{R}} % real numbers \newcommand{\C}{\mathbb{C}} % complex numbers % category \newcommand{\catf}[1]{{\mathbf{#1}}} \newcommand{\cA}{\catf{A}} \newcommand{\cB}{\catf{B}} \newcommand{\cC}{\catf{C}} \newcommand{\cD}{\catf{D}} \newcommand{\cE}{\catf{E}} \newcommand{\cF}{\catf{F}} \newcommand{\cG}{\catf{G}} \newcommand{\cH}{\catf{H}} \newcommand{\cI}{\catf{I}} \newcommand{\cJ}{\catf{J}} \newcommand{\cK}{\catf{K}} \newcommand{\cL}{\catf{L}} \newcommand{\cM}{\catf{M}} \newcommand{\cN}{\catf{N}} \newcommand{\cO}{\catf{O}} \newcommand{\cP}{\catf{P}} \newcommand{\cQ}{\catf{Q}} \newcommand{\cR}{\catf{R}} \newcommand{\cS}{\catf{S}} 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\newcommand{\xtoot}[2]{\xrightleftharpoons[#2]{#1}} \newcommand{\iso}{\cong} % ~= \newcommand{\klto}{\rightsquigarrow} % ~> \newcommand{\mono}{\rightarrowtail} % >-> \newcommand{\epi}{\twoheadrightarrow} % ->> \newcommand{\ihom}{\multimap} % -o % category \newcommand{\incl}{\hookrightarrow} \newcommand{\adjto}[2]{\overset{{}\xto[]{#1}{}}{\underset{{}\xot[#2]{}{}}{\bot}}} % functor \newcommand{\nat}{\Rightarrow} % => \newcommand{\xnat}{\xRightarrow} % => \newcommand{\comma}{\downarrow} \newcommand{\adj}{\dashv} % -| %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % delimiter %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% \DeclarePairedDelimiter{\parens}{(}{)} % parentheses ( ) \DeclarePairedDelimiter{\bracks}{[}{]} % brackets [ ] \DeclarePairedDelimiter{\braces}{\{}{\}} % braces { } \DeclarePairedDelimiter{\angles}{\langle}{\rangle} % angles \DeclarePairedDelimiter{\floor}{\lfloor}{\rfloor} \DeclarePairedDelimiter{\ceil}{\lceil}{\rceil} \newcommand{\set}{\braces} \newcommand{\singleton}{{\set{*}}} %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % operator %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% \newcommand{\compL}{\mathbin{\circ}} \newcommand{\compR}{\mathbin{;}} \newcommand{\Kl}{\mathrm{Kl}} \DeclareMathOperator{\Obj}{Obj} \DeclareMathOperator{\Hom}{Hom} \DeclareMathOperator{\Sub}{Sub} \DeclareMathOperator{\Eq}{Eq} \DeclareMathOperator{\Coeq}{Coeq} \DeclareMathOperator{\Pull}{Pull} \DeclareMathOperator{\Push}{Push} \DeclareMathOperator{\Lan}{Lan} \DeclareMathOperator{\Ran}{Ran} \DeclareMathOperator{\Lift}{Lift} \DeclareMathOperator{\Rift}{Rift} \DeclareMathOperator{\id}{id} \DeclareMathOperator{\colim}{colim} % exponential \DeclareMathOperator{\partf}{partial} \DeclareMathOperator{\curry}{curry} % natural number \DeclareMathOperator{\zero}{zero} \DeclareMathOperator{\successor}{succ} % list \DeclareMathOperator{\nil}{nil} \DeclareMathOperator{\cons}{cons} \newcommand{\concat}{\mathbin{{+}\mspace{-8mu}{+}}} % fold \DeclareMathOperator{\fold}{fold} \DeclareMathOperator{\map}{map} \DeclareMathOperator{\filter}{filter} % bool \DeclareMathOperator{\cond}{cond} %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % order %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% \newcommand{\meet}{\wedge} \newcommand{\join}{\vee} \newcommand{\bigmeet}{\bigwedge} \newcommand{\bigjoin}{\bigvee} %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % logic %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% \newcommand{\lT}{\top} \newcommand{\lF}{\bot} % logical connective \newcommand{\binop}[1]{\mathbin{#1}} % conjunction AND \newcommand{\lcon}{\binop{\wedge}} % not conjunction NAND \newcommand{\lncon}{\binop{\uparrow}} % disjunction OR \newcommand{\ldis}{\binop{\vee}} % not disjunction NOR \newcommand{\lndis}{\binop{\downarrow}} % implication \newcommand{\limp}{\binop{\rightarrow}} % not implication \newcommand{\lnimp}{\binop{\nrightarrow}} % converse implication \newcommand{\lcim}{\binop{\leftarrow}} % not converse implication \newcommand{\lncim}{\binop{\nleftarrow}} % equivalence XNOR \newcommand{\leqv}{\binop{\leftrightarrow}} % not equivalence XOR \newcommand{\lneqv}{\binop{\nleftrightarrow}} \newcommand{\lproves}{\binop{\vdash}} % |- \newcommand{\lmodels}{\binop{\vDash}} % |= \newcommand{\lnproves}{\binop{\nvdash}} % |/- \newcommand{\lnmodels}{\binop{\nvDash}} % |/= \newcommand{\truth}{{\set{\lT, \lF}}} \newcommand{\quant}{{[0, \infty]}} \newcommand{\inter}{{[0, 1]}} \newcommand{\qnot}{\mathord{\sim}} \newcommand{\qcon}{\binop{\otimes}} \newcommand{\qdis}{\binop{\oplus}} \newcommand{\qimp}{\binop{\multimap}} \DeclareMathOperator*{\qforall}{\triangledown} \DeclareMathOperator*{\qexists}{\vartriangle} \]

A monad is a structure that describes generalized objects and morphisms.

1 Monad

The category \([\cC, \cC]\) of endofunctors is a strict monoidal category with the functor composition as the monoidal product and the identity functor \(\id_\cC\) as the monoidal unit.

A monad in a category \(\cC\) is an endofunctor \(T: \cC \to \cC\) equipped with two natural transformations:

composition \(\mu: TT \nat T\)
unit \(\eta: \id_\cC \nat T\)

subject to

associativity: \(\mu (T \mu) = \mu (\mu T)\)
identity: \(\mu (\eta T) = \id_T = \mu (T \eta)\)

In other words, a monad is a monoid in the category of endofunctors.

/assets/diagrams/monad_associativity_fun.svg

/assets/diagrams/monad_associativity_str.svg

-- bind
(>>=) :: Monad m => m a -> (a -> m b) -> m b
(=<<) :: Monad m => (a -> m b) -> m a -> m b
(>>)  :: Monad m => m a -> m b -> m b
(>=>) :: Monad m => (a -> m b) -> (b -> m c) -> (a -> m c)
(<=<) :: Monad m => (b -> m c) -> (a -> m b) -> (a -> m c)

2 Algebra

2.1 Endofunctor algebra

For an endofunctor \(F: \cC \to \cC\), an algebra over an endofunctor \((A, \alpha_A)\) consists of an object \(A\) (carrier) and a morphism \(\alpha_A: FA \to A\).

An endofunctor algebra homomorphism from \((A, \alpha_A)\) to \((B, \alpha_B)\) is a morphism \(f: A \to B\) such that \(\alpha_B \compL Ff = f \compL \alpha_A\).

/assets/diagrams/endofunctor_algebra_homomorphism.svg

For an endofunctor \(F: \cC \to \cC\), a coalgebra over an endofunctor \((A, \alpha_A)\) consists of an object \(A\) (carrier) and a morphism \(\alpha_A: A \to FA\).

An endofunctor coalgebra homomorphism from \((A, \alpha_A)\) to \((B, \alpha_B)\) is a morphism \(f: A \to B\) such that \(\alpha_B \compL f = Ff \compL \alpha_A\).

/assets/diagrams/endofunctor_coalgebra_homomorphism.svg

2.1.1 Initial algebra

An initial algebra of an endofunctor \(F\) is an initial object in the category of endofunctor algebras.

If an endofunctor \(F\) has an initial algebra \((\mu F, i)\), then \(F \mu F \iso \mu F\).

\((F \mu F, Fi)\) is an endofunctor algebra, so there exists a unique endofunctor algebra homomorphism \(u: \mu F \to F \mu F\).
\(i \compL u: \mu F \to \mu F\) is an endofunctor algebra homomorphism from the initial algebra and thus is unique, \(i \compL u = \id_{\mu F}\).
\(u \compL i = Fi \compL Fu = F(i \compL u) = F \id_{\mu F} = \id_{F \mu F}\).

In a category \(\cC\) with a terminal object \(1\), a natural numbers object (NNO) \(\N\) is an initial algebra of the endofunctor \(X \mapsto 1 + X\).

\[\begin{aligned} \begin{array}{rccccc} & 1 &+& \N &\to& \N \\ \zero: & * && &\mapsto& 0 \\ \successor: && & n &\mapsto& n+1 \end{array} \end{aligned}\]

In a category \(\cC\) with a terminal object \(1\) and binary products, an \(A\)-valued list object \([A]\) is an initial algebra of the endofunctor \(X \mapsto 1 + A \times X\).

\[\begin{aligned} \begin{array}{rccccc} & 1 &+& A \times [A] &\to& [A] \\ \nil: & * && &\mapsto& [] \\ \cons: & && (x, xs) &\mapsto& x:xs \end{array} \end{aligned}\]

2.2 Monoid algebra

For a monoid object \((M, \mu, \eta)\) in a monoidal category \((\cC, \otimes, I, \alpha, \lambda, \rho)\), a (left) algebra over a monoid is an endofunctor algebra \((A, \alpha_A: M \otimes A \to A)\) for the endofunctor

\[\begin{aligned} (M \otimes -): \cC &\to \cC \\ A &\mapsto M \otimes A \\ f &\mapsto \id_M \otimes f \end{aligned}\]

that is compatible with

monoid product: \(\alpha_A \compL (\id_M \otimes \alpha_A) \compL \alpha_{M, M, A} = \alpha_A \compL (\mu \otimes \id_A)\)
monoid unit: \(\alpha_A \compL (\eta \otimes \id_A) = \lambda_A\)

/assets/diagrams/monoid_algebra_associativity.svg

/assets/diagrams/monoid_algebra_identity.svg

An monoid algebra homomorphism is an endofunctor algebra homomorphism.

/assets/diagrams/monoid_algebra_homomorphism.svg

2.3 Monad algebra

For a monad \((T, \mu, \eta)\), a (left) algebra over a monad is a monoid algebra \((A, \alpha_A: TA \to A)\) in the category of endofunctors over the constant functor \(\Delta A\).

Thus, a monad algebra is compatible with

monad composition: \(\alpha_A \compL T \alpha_A = \alpha_A \compL \mu_A\)
monad unit: \(\alpha_A \compL \eta_A = \id_A\)

/assets/diagrams/monad_algebra_composition.svg

A monad algebra homomorphism is an endofunctor algebra homomorphism.

/assets/diagrams/monad_algebra_homomorphism.svg

For a monad \((T, \mu, \eta)\) in a category \(\cC\), the Eilenberg–Moore category \(\cC^T\) is a category of monad algebras and monad algebra homomorphisms.

3 Kleisli category

For a monad \((T, \mu, \eta)\) in a category \(\cC\), the Kleisli category \(\cC_T\) is a category whose

objects are \(\cC\)-objects \(\Obj_{\cC_T} := \Obj_\cC\)
morphisms are Kleisli morphisms \(\Hom_{\cC_T}(A, B) := \Hom_\cC(A, TB)\)
composition is the Kleisli composition \(g_\Kl \compL_T f_\Kl := \mu_C \compL Tg_\Kl \compL f_\Kl\)
identity morphism is the monad unit \(\id_A := \eta_A: A \to TA\)

/assets/diagrams/Kleisli_composition.svg

4 Monadic adjunction

4.1 Adjunction to monad

An adjunction

\[(F: \cC \toot \cD: G, \epsilon: FG \nat \id_\cD, \eta: \id_\cC \nat GF)\]

gives rise to a monad

\[(GF: \cC \to \cC, G \epsilon F: GFGF \nat GF, \eta: \id_\cC \nat GF)\]

/assets/diagrams/adjunction_monad_associativity_str.svg

/assets/diagrams/adjunction_monad_identity_str.svg

and a comonad

\[(FG: \cD \to \cD, F \eta G: FG \nat FGFG, \epsilon: FG \nat \id_\cD)\]

4.2 Monad to adjunction

5 Examples

5.1 Maybe

\(MA = 1 + A\) nothing or values
\(Mf = 1 + f\) computation with failure
\(\mu: MM \nat M\) failure propagation
\(\eta: \id \nat M\) just
\(A \to MB\) partial function
\(MA \to A\) pointed object

5.2 List

free monoid

\([]: 1 \to LA\) empty list
\(\concat: LA \times LA \to LA\) concatenation

free monoid monad

\(LA\) list
\(Lf\) list map
\(\mu: LL \nat L\) concatenation
\(\eta: \id \nat L\) singleton
\(A \to LB\) list function
\(LA \to A\) monoid \((A, \fold [e: 1 \to A, \cdot: A \times A \to A])\)
- right identity \([a]\)
- left identity \([[], [a]]\)
- associativity \([[a, b], [c]]\)

5.3 Powerset

\(PA = 2^A\) powerset
\(Pf\) set map
\(\mu: PP \nat P\) union
\(\eta: \id \nat P\) singleton
\(A \to PB\) set function
\(PA \to A\) suplattice

5.4 Multiset

\(NA = \N^A\) multiset
\(Nf\) sum map
\(\mu: NN \nat N\) multiplication
\(\eta: \id \nat N\) singleton
\(A \to NB\) multiset function
\(NA \to A\) commutative monoid

5.5 Probability

Giry monad \(\text{measurable space } (A, \Sigma_A) \mapsto (\set{\text{probability measure } \mu: \Sigma_A \to [0, 1]}, \set{\epsilon_U: \mu \mapsto \mu(U) \mid U \in \Sigma_A})\)

\(PA\) probability measures
\(Pf\) pushforward measure
\(\mu: PP \nat P\) marginalization
\(\eta: \id \nat P\) Dirac measure
\(A \to PB\) conditional probability
\(PA \to A\) expectation

5.6 State

\([S, S \times A]\)

5.7 Continuation

\([[A, R], R]\)

6 Monoidal monad

A monoidal monad is a monad in the 2-category of monoidal categories, lax monoidal functors, and monoidal natural transformations.

7 Monoidal Kleisli category

For a monoidal monad \((T, \mu_T, \eta_T, \mu, \eta)\) in \((\cC, \otimes, I)\), the Kleisli category \(\cC_T\) inherits the monoidal structure from \(\cC\), whose

monoidal product \(\otimes_\Kl\) on objects is the monoidal product \(\otimes\) on \(\cC\)
monoidal product \(\otimes_\Kl\) on morphisms is obtained by \(f_\Kl \otimes_\Kl g_\Kl := \mu (f_\Kl \otimes g_\Kl)\)

\[(A \xto{f_\Kl} TB) \otimes_\Kl (C \xto{g_\Kl} TD) = A \otimes C \xto{f_\Kl \otimes_\Kl g_\Kl} T(B\otimes D) = A \otimes C \xto{f_\Kl \otimes g_\Kl} TB \otimes TD \xto{\mu_{B, D}} T(B \otimes D)\]
monoidal unit, associator, and left/right unitors are those of \(\cC\)