# Morphisms of algebras of polynomial endofunctors
```agda
module trees.morphisms-algebras-polynomial-endofunctors where
```
<details><summary>Imports</summary>
```agda
open import foundation.action-on-identifications-functions
open import foundation.contractible-types
open import foundation.dependent-pair-types
open import foundation.equivalences
open import foundation.function-types
open import foundation.functoriality-dependent-pair-types
open import foundation.fundamental-theorem-of-identity-types
open import foundation.homotopies
open import foundation.homotopy-induction
open import foundation.identity-types
open import foundation.structure-identity-principle
open import foundation.torsorial-type-families
open import foundation.universe-levels
open import foundation.whiskering-homotopies-composition
open import trees.algebras-polynomial-endofunctors
open import trees.polynomial-endofunctors
```
</details>
## Idea
A **morphism** of algebras of a polynomial endofunctor `P A B` consists of a map
`f : X → Y$ between the underlying types, equipped with a homotopy witnessing
that the square
```text
P A B f
P A B X ---------> P A B Y
| |
| |
∨ ∨
X -------------> Y
f
```
commutes.
## Definitions
### Morphisms of algebras for polynomial endofunctors
```agda
hom-algebra-polynomial-endofunctor :
{l1 l2 l3 l4 : Level} {A : UU l1} {B : A → UU l2}
(X : algebra-polynomial-endofunctor l3 A B) →
(Y : algebra-polynomial-endofunctor l4 A B) → UU (l1 ⊔ l2 ⊔ l3 ⊔ l4)
hom-algebra-polynomial-endofunctor {A = A} {B} X Y =
Σ ( type-algebra-polynomial-endofunctor X →
type-algebra-polynomial-endofunctor Y)
( λ f →
( f ∘ (structure-algebra-polynomial-endofunctor X)) ~
( ( structure-algebra-polynomial-endofunctor Y) ∘
( map-polynomial-endofunctor A B f)))
map-hom-algebra-polynomial-endofunctor :
{l1 l2 l3 l4 : Level} {A : UU l1} {B : A → UU l2}
(X : algebra-polynomial-endofunctor l3 A B) →
(Y : algebra-polynomial-endofunctor l4 A B) →
hom-algebra-polynomial-endofunctor X Y →
type-algebra-polynomial-endofunctor X →
type-algebra-polynomial-endofunctor Y
map-hom-algebra-polynomial-endofunctor X Y f = pr1 f
structure-hom-algebra-polynomial-endofunctor :
{l1 l2 l3 l4 : Level} {A : UU l1} {B : A → UU l2}
(X : algebra-polynomial-endofunctor l3 A B) →
(Y : algebra-polynomial-endofunctor l4 A B) →
(f : hom-algebra-polynomial-endofunctor X Y) →
( ( map-hom-algebra-polynomial-endofunctor X Y f) ∘
( structure-algebra-polynomial-endofunctor X)) ~
( ( structure-algebra-polynomial-endofunctor Y) ∘
( map-polynomial-endofunctor A B
( map-hom-algebra-polynomial-endofunctor X Y f)))
structure-hom-algebra-polynomial-endofunctor X Y f = pr2 f
```
## Properties
### The identity type of morphisms of algebras of polynomial endofunctors
```agda
module _
{l1 l2 l3 l4 : Level} {A : UU l1} {B : A → UU l2}
(X : algebra-polynomial-endofunctor l3 A B)
(Y : algebra-polynomial-endofunctor l4 A B)
(f : hom-algebra-polynomial-endofunctor X Y)
where
htpy-hom-algebra-polynomial-endofunctor :
(g : hom-algebra-polynomial-endofunctor X Y) → UU (l1 ⊔ l2 ⊔ l3 ⊔ l4)
htpy-hom-algebra-polynomial-endofunctor g =
Σ ( map-hom-algebra-polynomial-endofunctor X Y f ~
map-hom-algebra-polynomial-endofunctor X Y g)
( λ H →
( ( structure-hom-algebra-polynomial-endofunctor X Y f) ∙h
( ( structure-algebra-polynomial-endofunctor Y) ·l
( htpy-polynomial-endofunctor A B H))) ~
( ( H ·r structure-algebra-polynomial-endofunctor X) ∙h
( structure-hom-algebra-polynomial-endofunctor X Y g)))
refl-htpy-hom-algebra-polynomial-endofunctor :
htpy-hom-algebra-polynomial-endofunctor f
pr1 refl-htpy-hom-algebra-polynomial-endofunctor = refl-htpy
pr2 refl-htpy-hom-algebra-polynomial-endofunctor z =
( ap
( λ t →
concat
( structure-hom-algebra-polynomial-endofunctor X Y f z)
( structure-algebra-polynomial-endofunctor Y
( map-polynomial-endofunctor A B
( map-hom-algebra-polynomial-endofunctor X Y f) z))
( ap (structure-algebra-polynomial-endofunctor Y) t))
( coh-refl-htpy-polynomial-endofunctor A B
( map-hom-algebra-polynomial-endofunctor X Y f) z)) ∙
( right-unit)
htpy-eq-hom-algebra-polynomial-endofunctor :
(g : hom-algebra-polynomial-endofunctor X Y) →
f = g → htpy-hom-algebra-polynomial-endofunctor g
htpy-eq-hom-algebra-polynomial-endofunctor .f refl =
refl-htpy-hom-algebra-polynomial-endofunctor
is-torsorial-htpy-hom-algebra-polynomial-endofunctor :
is-torsorial htpy-hom-algebra-polynomial-endofunctor
is-torsorial-htpy-hom-algebra-polynomial-endofunctor =
is-torsorial-Eq-structure
( is-torsorial-htpy (map-hom-algebra-polynomial-endofunctor X Y f))
( pair (map-hom-algebra-polynomial-endofunctor X Y f) refl-htpy)
( is-contr-equiv'
( Σ ( ( (pr1 f) ∘ pr2 X) ~
( pr2 Y ∘ map-polynomial-endofunctor A B (pr1 f)))
( λ H → (pr2 f) ~ H))
( equiv-tot
( λ H →
( equiv-concat-htpy
( λ x →
ap
( concat
( pr2 f x)
( structure-algebra-polynomial-endofunctor Y
( map-polynomial-endofunctor A B (pr1 f) x)))
( ap
( ap (pr2 Y))
( coh-refl-htpy-polynomial-endofunctor A B (pr1 f) x)))
( H)) ∘e
( equiv-concat-htpy right-unit-htpy H)))
( is-torsorial-htpy (pr2 f)))
is-equiv-htpy-eq-hom-algebra-polynomial-endofunctor :
(g : hom-algebra-polynomial-endofunctor X Y) →
is-equiv (htpy-eq-hom-algebra-polynomial-endofunctor g)
is-equiv-htpy-eq-hom-algebra-polynomial-endofunctor =
fundamental-theorem-id
( is-torsorial-htpy-hom-algebra-polynomial-endofunctor)
( htpy-eq-hom-algebra-polynomial-endofunctor)
extensionality-hom-algebra-polynomial-endofunctor :
(g : hom-algebra-polynomial-endofunctor X Y) →
(f = g) ≃ htpy-hom-algebra-polynomial-endofunctor g
pr1 (extensionality-hom-algebra-polynomial-endofunctor g) =
htpy-eq-hom-algebra-polynomial-endofunctor g
pr2 (extensionality-hom-algebra-polynomial-endofunctor g) =
is-equiv-htpy-eq-hom-algebra-polynomial-endofunctor g
eq-htpy-hom-algebra-polynomial-endofunctor :
(g : hom-algebra-polynomial-endofunctor X Y) →
htpy-hom-algebra-polynomial-endofunctor g → f = g
eq-htpy-hom-algebra-polynomial-endofunctor g =
map-inv-is-equiv (is-equiv-htpy-eq-hom-algebra-polynomial-endofunctor g)
```