metabrush/src/lib/Math/Bezier/Cubic.hs

{-# LANGUAGE AllowAmbiguousTypes   #-}
{-# LANGUAGE BangPatterns          #-}
{-# LANGUAGE DeriveAnyClass        #-}
{-# LANGUAGE DeriveGeneric         #-}
{-# LANGUAGE DeriveTraversable     #-}
{-# LANGUAGE DerivingVia           #-}
{-# LANGUAGE FlexibleInstances     #-}
{-# LANGUAGE MultiParamTypeClasses #-}
{-# LANGUAGE NamedFieldPuns        #-}
{-# LANGUAGE NegativeLiterals      #-}
{-# LANGUAGE RecordWildCards       #-}
{-# LANGUAGE ScopedTypeVariables   #-}
{-# LANGUAGE StandaloneDeriving    #-}
{-# LANGUAGE TypeApplications      #-}
{-# LANGUAGE UndecidableInstances  #-}

module Math.Bezier.Cubic
  ( Bezier(..)
  , fromQuadratic
  , bezier, bezier', bezier''
  , curvature, squaredCurvature
  , subdivide
  , ddist, closestPoint
  , drag
  )
  where

-- base
import Data.List.NonEmpty
  ( NonEmpty(..) )
import Data.Monoid
  ( Ap(..) )
import Data.Semigroup
  ( ArgMin, Min(..), Arg(..) )
import GHC.Generics
  ( Generic, Generic1 )

-- acts
import Data.Act
  ( Act(..)
  , Torsor
    ( (-->) )
  )

-- deepseq
import Control.DeepSeq
  ( NFData, NFData1 )

-- generic-data
import Generic.Data
  ( GenericProduct(..), Generically1(..) )

-- groups
import Data.Group
  ( Group )

-- groups-generic
import Data.Group.Generics
  ()

-- primitive
import Data.Primitive.Types
  ( Prim )

-- MetaBrush
import qualified Math.Bezier.Quadratic as Quadratic
  ( Bezier(..), bezier )
import Math.Epsilon
  ( epsilon )
import Math.Module
  ( Module (..)
  , lerp
  , Inner(..), squaredNorm
  )
import Math.Roots
  ( realRoots )

--------------------------------------------------------------------------------

-- | Points defining a cubic Bézier curve (Bernstein form).
--
-- @ p0 @ and @ p3 @ are endpoints, whereas @ p1 @ and @ p2 @ are control points.
data Bezier p
  = Bezier
    { p0, p1, p2, p3 :: !p }
  deriving stock ( Show, Generic, Generic1, Functor, Foldable, Traversable )
  deriving ( Semigroup, Monoid, Group )
    via GenericProduct ( Bezier p )
  deriving Applicative
    via Generically1 Bezier
  deriving anyclass ( NFData, NFData1 )

deriving via Ap Bezier p
  instance {-# OVERLAPPING #-} Act v p => Act v ( Bezier p )

-- | Degree raising: convert a quadratic Bézier curve to a cubic Bézier curve.
fromQuadratic :: forall v r p. ( Torsor v p, Module r v, Fractional r ) => Quadratic.Bezier p -> Bezier p
fromQuadratic ( Quadratic.Bezier { p0 = q0, p1 = q1, p2 = q2 } ) = Bezier {..}
  where
    p0 = q0
    p1 = lerp @v (2/3) q0 q1
    p2 = lerp @v (1/3) q1 q2
    p3 = q2

-- | Cubic Bézier curve.
bezier :: forall v r p. ( Torsor v p, Module r v ) => Bezier p -> r -> p
bezier ( Bezier {..} ) t =
  lerp @v t
    ( Quadratic.bezier @v ( Quadratic.Bezier p0 p1 p2 ) t )
    ( Quadratic.bezier @v ( Quadratic.Bezier p1 p2 p3 ) t )

-- | Derivative of cubic Bézier curve.
bezier' :: forall v r p. ( Torsor v p, Module r v ) => Bezier p -> r -> v
bezier' ( Bezier {..} ) t
  = ( 3 *^ )
  $ lerp @v t
      ( lerp @v t ( p0 --> p1 ) ( p1 --> p2 ) )
      ( lerp @v t ( p1 --> p2 ) ( p2 --> p3 ) )

-- | Second derivative of a cubic Bézier curve.
bezier'' :: forall v r p. ( Torsor v p, Module r v ) => Bezier p -> r -> v
bezier'' ( Bezier {..} ) t
  = ( 6 *^ )
  $ lerp @v t
      ( p1 --> p0 ^+^ p1 --> p2 )
      ( p2 --> p1 ^+^ p2 --> p3 )

-- | Curvature of a quadratic Bézier curve.
curvature :: forall v r p. ( Torsor v p, Inner r v, RealFloat r ) => Bezier p -> r -> r
curvature bez t = sqrt $ squaredCurvature @v bez t

-- | Square of curvature of a quadratic Bézier curve.
squaredCurvature :: forall v r p. ( Torsor v p, Inner r v, RealFloat r ) => Bezier p -> r -> r
squaredCurvature bez t
  | sq_nm_g' < epsilon
  = 1 / 0
  | otherwise
  = ( sq_nm_g' * squaredNorm @v g'' - ( g' ^.^ g'' ) ^ ( 2 :: Int ) )
  / ( sq_nm_g' ^ ( 3 :: Int ) )
  where
    g', g'' :: v
    g'  = bezier'  @v bez t
    g'' = bezier'' @v bez t
    sq_nm_g' :: r
    sq_nm_g' = squaredNorm @v g'


-- | Subdivide a cubic Bézier curve into two parts.
subdivide :: forall v r p. ( Torsor v p, Module r v ) => Bezier p -> r -> ( Bezier p, Bezier p )
subdivide ( Bezier {..} ) t = ( Bezier p0 q1 q2 pt, Bezier pt r1 r2 p3 )
  where
    pt, s, q1, q2, r1, r2 :: p
    q1 = lerp @v t p0 p1
    s  = lerp @v t p1 p2
    r2 = lerp @v t p2 p3
    q2 = lerp @v t q1 s
    r1 = lerp @v t s  r2
    pt = lerp @v t q2 r1

-- | Polynomial coefficients of the derivative of the distance to a cubic Bézier curve.
ddist :: forall v r p. ( Torsor v p, Inner r v, RealFloat r ) => Bezier p -> p -> [ r ]
ddist ( Bezier {..} ) c = [ a5, a4, a3, a2, a1, a0 ]
  where
    v, v', v'', v''' :: v
    !v    = c  --> p0
    !v'   = p0 --> p1
    !v''  = p1 --> p0 ^+^ p1 --> p2
    !v''' = p0 --> p3 ^+^ 3 *^ ( p2 --> p1 )

    a0, a1, a2, a3, a4, a5 :: r
    !a0 = v ^.^ v'
    !a1 = 3 * squaredNorm v' + 2 * v ^.^ v''
    !a2 = 9 * v' ^.^ v'' + v ^.^ v'''
    !a3 = 6 * squaredNorm v'' + 4 * v' ^.^ v'''
    !a4 = 5 * v'' ^.^ v'''
    !a5 = squaredNorm v'''

-- | Finds the closest point to a given point on a cubic Bézier curve.
closestPoint
  :: forall v r p. ( Torsor v p, Inner r v, RealFloat r, Prim r )
  => Bezier p -> p -> ArgMin r ( r, p )
closestPoint pts c = pickClosest ( 0 :| 1 : roots ) -- todo: also include the self-intersection point if one exists
  where
    roots :: [ r ]
    roots = filter ( \ r -> r > 0 && r < 1 ) ( realRoots 2000 $ ddist @v pts c )

    pickClosest :: NonEmpty r -> ArgMin r ( r, p )
    pickClosest ( s :| ss ) = go s q nm0 ss
      where
        q :: p
        q  = bezier @v pts s
        nm0 :: r
        nm0 = squaredNorm ( c --> q :: v )
        go t p nm []  = Min ( Arg nm ( t, p ) )
        go t p nm ( t' : ts )
          | nm' < nm  = go t' p' nm' ts
          | otherwise = go t  p  nm  ts
          where
            p' :: p
            p' = bezier @v pts t'
            nm' :: r
            nm' = squaredNorm ( c --> p' :: v )

-- | Drag a cubic Bézier curve to pass through a given point.
--
-- Given a cubic Bézier curve, a time \( 0 < t < 1 \) and a point `q`,
-- modifies the control points to make the curve pass through `q` at time `t`.
--
-- Affects the two control points depending on how far along the dragged point is.
-- For instance, dragging near the middle moves both control points equally,
-- while dragging near an endpoint will mostly affect the control point associated with that endpoint.
drag :: forall v r p. ( Torsor v p, Module r v, Fractional r ) => Bezier p -> r -> p -> Bezier p
drag ( Bezier {..} ) t q = Bezier { p0, p1 = p1', p2 = p2', p3 }
  where
    v0, v1, v2, v3, delta :: v
    v0 = q --> p0
    v1 = q --> p1
    v2 = q --> p2
    v3 = q --> p3
    delta = ( recip $ t * ( -3 + t * ( 9 + t * ( -12 + 6 * t ) ) ) )
          *^ bezier @v ( Bezier v0 v1 v2 v3 ) t
    p1', p2' :: p
    p1' = ( ( 1 - t ) *^ delta ) • p1
    p2' = (     t     *^ delta ) • p2
add MenuBar 2020-08-05 20:23:16 +00:00			`{-# LANGUAGE AllowAmbiguousTypes #-}`
optimise root-finding functions * use PrimArray to represent polynomials * add some strictness annotations * turn on some optimisation flags * use quadratic formula for quadratic polynomials 2020-09-18 22:01:02 +00:00			`{-# LANGUAGE BangPatterns #-}`
add parallelism for brush outline computation * also enable varying the fitting parameters (UI todo) 2020-09-07 15:38:22 +00:00			`{-# LANGUAGE DeriveAnyClass #-}`
add MenuBar 2020-08-05 20:23:16 +00:00			`{-# LANGUAGE DeriveGeneric #-}`
			`{-# LANGUAGE DeriveTraversable #-}`
compute and render brush stroke outlines 2020-08-29 01:03:29 +00:00			`{-# LANGUAGE DerivingVia #-}`
add MenuBar 2020-08-05 20:23:16 +00:00			`{-# LANGUAGE FlexibleInstances #-}`
			`{-# LANGUAGE MultiParamTypeClasses #-}`
add backend implementation of curve dragging 2020-09-17 03:47:53 +00:00			`{-# LANGUAGE NamedFieldPuns #-}`
			`{-# LANGUAGE NegativeLiterals #-}`
add MenuBar 2020-08-05 20:23:16 +00:00			`{-# LANGUAGE RecordWildCards #-}`
			`{-# LANGUAGE ScopedTypeVariables #-}`
compute and render brush stroke outlines 2020-08-29 01:03:29 +00:00			`{-# LANGUAGE StandaloneDeriving #-}`
add MenuBar 2020-08-05 20:23:16 +00:00			`{-# LANGUAGE TypeApplications #-}`
			`{-# LANGUAGE UndecidableInstances #-}`
WIP 2020-08-04 06:15:06 +00:00
			`module Math.Bezier.Cubic`
			`( Bezier(..)`
add backend implementation of curve dragging 2020-09-17 03:47:53 +00:00			`, fromQuadratic`
fix incorrect brush join computation * also add some curvature calculations (unused at the moment) 2020-09-16 21:56:19 +00:00			`, bezier, bezier', bezier''`
			`, curvature, squaredCurvature`
basic rendering, mousewheel scrolling 2020-08-10 14:38:27 +00:00			`, subdivide`
fitting a cubic Bézier to a sequence of points * WIP: current code exhibits convergence issues / instability 2020-08-23 22:40:16 +00:00			`, ddist, closestPoint`
add backend implementation of curve dragging 2020-09-17 03:47:53 +00:00			`, drag`
WIP 2020-08-04 06:15:06 +00:00			`)`
			`where`

			`-- base`
add root solving code, coalesce event handling 2020-08-12 20:43:47 +00:00			`import Data.List.NonEmpty`
			`( NonEmpty(..) )`
compute and render brush stroke outlines 2020-08-29 01:03:29 +00:00			`import Data.Monoid`
			`( Ap(..) )`
add selection UI 2020-08-13 22:47:10 +00:00			`import Data.Semigroup`
			`( ArgMin, Min(..), Arg(..) )`
WIP 2020-08-04 06:15:06 +00:00			`import GHC.Generics`
compute and render brush stroke outlines 2020-08-29 01:03:29 +00:00			`( Generic, Generic1 )`
WIP 2020-08-04 06:15:06 +00:00
			`-- acts`
			`import Data.Act`
compute and render brush stroke outlines 2020-08-29 01:03:29 +00:00			`( Act(..)`
			`, Torsor`
WIP 2020-08-04 06:15:06 +00:00			`( (-->) )`
			`)`

add parallelism for brush outline computation * also enable varying the fitting parameters (UI todo) 2020-09-07 15:38:22 +00:00			`-- deepseq`
			`import Control.DeepSeq`
			`( NFData, NFData1 )`

compute and render brush stroke outlines 2020-08-29 01:03:29 +00:00			`-- generic-data`
			`import Generic.Data`
			`( GenericProduct(..), Generically1(..) )`

			`-- groups`
			`import Data.Group`
			`( Group )`

			`-- groups-generic`
			`import Data.Group.Generics`
			`()`

optimise root-finding functions * use PrimArray to represent polynomials * add some strictness annotations * turn on some optimisation flags * use quadratic formula for quadratic polynomials 2020-09-18 22:01:02 +00:00			`-- primitive`
			`import Data.Primitive.Types`
			`( Prim )`

WIP 2020-08-04 06:15:06 +00:00			`-- MetaBrush`
add root solving code, coalesce event handling 2020-08-12 20:43:47 +00:00			`import qualified Math.Bezier.Quadratic as Quadratic`
add backend implementation of curve dragging 2020-09-17 03:47:53 +00:00			`( Bezier(..), bezier )`
fix incorrect brush join computation * also add some curvature calculations (unused at the moment) 2020-09-16 21:56:19 +00:00			`import Math.Epsilon`
			`( epsilon )`
WIP 2020-08-04 06:15:06 +00:00			`import Math.Module`
			`( Module (..)`
			`, lerp`
add root solving code, coalesce event handling 2020-08-12 20:43:47 +00:00			`, Inner(..), squaredNorm`
WIP 2020-08-04 06:15:06 +00:00			`)`
fitting a cubic Bézier to a sequence of points * WIP: current code exhibits convergence issues / instability 2020-08-23 22:40:16 +00:00			`import Math.Roots`
add root solving code, coalesce event handling 2020-08-12 20:43:47 +00:00			`( realRoots )`
WIP 2020-08-04 06:15:06 +00:00
			`--------------------------------------------------------------------------------`

fitting a cubic Bézier to a sequence of points * WIP: current code exhibits convergence issues / instability 2020-08-23 22:40:16 +00:00			`-- \| Points defining a cubic Bézier curve (Bernstein form).`
WIP 2020-08-04 06:15:06 +00:00			`--`
			`-- @ p0 @ and @ p3 @ are endpoints, whereas @ p1 @ and @ p2 @ are control points.`
			`data Bezier p`
			`= Bezier`
fitting a cubic Bézier to a sequence of points * WIP: current code exhibits convergence issues / instability 2020-08-23 22:40:16 +00:00			`{ p0, p1, p2, p3 :: !p }`
compute and render brush stroke outlines 2020-08-29 01:03:29 +00:00			`deriving stock ( Show, Generic, Generic1, Functor, Foldable, Traversable )`
			`deriving ( Semigroup, Monoid, Group )`
			`via GenericProduct ( Bezier p )`
			`deriving Applicative`
			`via Generically1 Bezier`
add parallelism for brush outline computation * also enable varying the fitting parameters (UI todo) 2020-09-07 15:38:22 +00:00			`deriving anyclass ( NFData, NFData1 )`
compute and render brush stroke outlines 2020-08-29 01:03:29 +00:00
			`deriving via Ap Bezier p`
add backend implementation of curve dragging 2020-09-17 03:47:53 +00:00			`instance {-# OVERLAPPING #-} Act v p => Act v ( Bezier p )`

			`-- \| Degree raising: convert a quadratic Bézier curve to a cubic Bézier curve.`
			`fromQuadratic :: forall v r p. ( Torsor v p, Module r v, Fractional r ) => Quadratic.Bezier p -> Bezier p`
			`fromQuadratic ( Quadratic.Bezier { p0 = q0, p1 = q1, p2 = q2 } ) = Bezier {..}`
			`where`
			`p0 = q0`
			`p1 = lerp @v (2/3) q0 q1`
			`p2 = lerp @v (1/3) q1 q2`
			`p3 = q2`
WIP 2020-08-04 06:15:06 +00:00
			`-- \| Cubic Bézier curve.`
			`bezier :: forall v r p. ( Torsor v p, Module r v ) => Bezier p -> r -> p`
create/move/delete guides: drag from ruler area 2020-09-05 22:35:00 +00:00			`bezier ( Bezier {..} ) t =`
WIP 2020-08-04 06:15:06 +00:00			`lerp @v t`
add MenuBar 2020-08-05 20:23:16 +00:00			`( Quadratic.bezier @v ( Quadratic.Bezier p0 p1 p2 ) t )`
			`( Quadratic.bezier @v ( Quadratic.Bezier p1 p2 p3 ) t )`
WIP 2020-08-04 06:15:06 +00:00
			`-- \| Derivative of cubic Bézier curve.`
			`bezier' :: forall v r p. ( Torsor v p, Module r v ) => Bezier p -> r -> v`
create/move/delete guides: drag from ruler area 2020-09-05 22:35:00 +00:00			`bezier' ( Bezier {..} ) t`
WIP 2020-08-04 06:15:06 +00:00			`= ( 3 *^ )`
			`$ lerp @v t`
			`( lerp @v t ( p0 --> p1 ) ( p1 --> p2 ) )`
			`( lerp @v t ( p1 --> p2 ) ( p2 --> p3 ) )`
basic rendering, mousewheel scrolling 2020-08-10 14:38:27 +00:00
fix incorrect brush join computation * also add some curvature calculations (unused at the moment) 2020-09-16 21:56:19 +00:00			`-- \| Second derivative of a cubic Bézier curve.`
			`bezier'' :: forall v r p. ( Torsor v p, Module r v ) => Bezier p -> r -> v`
			`bezier'' ( Bezier {..} ) t`
			`= ( 6 *^ )`
			`$ lerp @v t`
			`( p1 --> p0 ^+^ p1 --> p2 )`
			`( p2 --> p1 ^+^ p2 --> p3 )`

			`-- \| Curvature of a quadratic Bézier curve.`
			`curvature :: forall v r p. ( Torsor v p, Inner r v, RealFloat r ) => Bezier p -> r -> r`
			`curvature bez t = sqrt $ squaredCurvature @v bez t`

			`-- \| Square of curvature of a quadratic Bézier curve.`
			`squaredCurvature :: forall v r p. ( Torsor v p, Inner r v, RealFloat r ) => Bezier p -> r -> r`
			`squaredCurvature bez t`
			`\| sq_nm_g' < epsilon`
			`= 1 / 0`
			`\| otherwise`
			`= ( sq_nm_g' * squaredNorm @v g'' - ( g' ^.^ g'' ) ^ ( 2 :: Int ) )`
			`/ ( sq_nm_g' ^ ( 3 :: Int ) )`
			`where`
			`g', g'' :: v`
			`g' = bezier' @v bez t`
			`g'' = bezier'' @v bez t`
			`sq_nm_g' :: r`
			`sq_nm_g' = squaredNorm @v g'`


basic rendering, mousewheel scrolling 2020-08-10 14:38:27 +00:00			`-- \| Subdivide a cubic Bézier curve into two parts.`
			`subdivide :: forall v r p. ( Torsor v p, Module r v ) => Bezier p -> r -> ( Bezier p, Bezier p )`
create/move/delete guides: drag from ruler area 2020-09-05 22:35:00 +00:00			`subdivide ( Bezier {..} ) t = ( Bezier p0 q1 q2 pt, Bezier pt r1 r2 p3 )`
basic rendering, mousewheel scrolling 2020-08-10 14:38:27 +00:00			`where`
			`pt, s, q1, q2, r1, r2 :: p`
			`q1 = lerp @v t p0 p1`
			`s = lerp @v t p1 p2`
			`r2 = lerp @v t p2 p3`
			`q2 = lerp @v t q1 s`
			`r1 = lerp @v t s r2`
			`pt = lerp @v t q2 r1`
add root solving code, coalesce event handling 2020-08-12 20:43:47 +00:00
fitting a cubic Bézier to a sequence of points * WIP: current code exhibits convergence issues / instability 2020-08-23 22:40:16 +00:00			`-- \| Polynomial coefficients of the derivative of the distance to a cubic Bézier curve.`
			`ddist :: forall v r p. ( Torsor v p, Inner r v, RealFloat r ) => Bezier p -> p -> [ r ]`
optimise root-finding functions * use PrimArray to represent polynomials * add some strictness annotations * turn on some optimisation flags * use quadratic formula for quadratic polynomials 2020-09-18 22:01:02 +00:00			`ddist ( Bezier {..} ) c = [ a5, a4, a3, a2, a1, a0 ]`
add root solving code, coalesce event handling 2020-08-12 20:43:47 +00:00			`where`
			`v, v', v'', v''' :: v`
optimise root-finding functions * use PrimArray to represent polynomials * add some strictness annotations * turn on some optimisation flags * use quadratic formula for quadratic polynomials 2020-09-18 22:01:02 +00:00			`!v = c --> p0`
			`!v' = p0 --> p1`
			`!v'' = p1 --> p0 ^+^ p1 --> p2`
			`!v''' = p0 --> p3 ^+^ 3 *^ ( p2 --> p1 )`
add root solving code, coalesce event handling 2020-08-12 20:43:47 +00:00
			`a0, a1, a2, a3, a4, a5 :: r`
optimise root-finding functions * use PrimArray to represent polynomials * add some strictness annotations * turn on some optimisation flags * use quadratic formula for quadratic polynomials 2020-09-18 22:01:02 +00:00			`!a0 = v ^.^ v'`
			`!a1 = 3 * squaredNorm v' + 2 * v ^.^ v''`
			`!a2 = 9 * v' ^.^ v'' + v ^.^ v'''`
			`!a3 = 6 * squaredNorm v'' + 4 * v' ^.^ v'''`
			`!a4 = 5 * v'' ^.^ v'''`
			`!a5 = squaredNorm v'''`
add root solving code, coalesce event handling 2020-08-12 20:43:47 +00:00
fitting a cubic Bézier to a sequence of points * WIP: current code exhibits convergence issues / instability 2020-08-23 22:40:16 +00:00			`-- \| Finds the closest point to a given point on a cubic Bézier curve.`
optimise root-finding functions * use PrimArray to represent polynomials * add some strictness annotations * turn on some optimisation flags * use quadratic formula for quadratic polynomials 2020-09-18 22:01:02 +00:00			`closestPoint`
			`:: forall v r p. ( Torsor v p, Inner r v, RealFloat r, Prim r )`
			`=> Bezier p -> p -> ArgMin r ( r, p )`
Implement programmable brush framework 2020-11-12 17:34:46 +00:00			`closestPoint pts c = pickClosest ( 0 :\| 1 : roots ) -- todo: also include the self-intersection point if one exists`
fitting a cubic Bézier to a sequence of points * WIP: current code exhibits convergence issues / instability 2020-08-23 22:40:16 +00:00			`where`
			`roots :: [ r ]`
optimise root-finding functions * use PrimArray to represent polynomials * add some strictness annotations * turn on some optimisation flags * use quadratic formula for quadratic polynomials 2020-09-18 22:01:02 +00:00			`roots = filter ( \ r -> r > 0 && r < 1 ) ( realRoots 2000 $ ddist @v pts c )`
fitting a cubic Bézier to a sequence of points * WIP: current code exhibits convergence issues / instability 2020-08-23 22:40:16 +00:00
add selection UI 2020-08-13 22:47:10 +00:00			`pickClosest :: NonEmpty r -> ArgMin r ( r, p )`
add root solving code, coalesce event handling 2020-08-12 20:43:47 +00:00			`pickClosest ( s :\| ss ) = go s q nm0 ss`
			`where`
			`q :: p`
			`q = bezier @v pts s`
			`nm0 :: r`
			`nm0 = squaredNorm ( c --> q :: v )`
add selection UI 2020-08-13 22:47:10 +00:00			`go t p nm [] = Min ( Arg nm ( t, p ) )`
add root solving code, coalesce event handling 2020-08-12 20:43:47 +00:00			`go t p nm ( t' : ts )`
			`\| nm' < nm = go t' p' nm' ts`
			`\| otherwise = go t p nm ts`
			`where`
			`p' :: p`
			`p' = bezier @v pts t'`
			`nm' :: r`
			`nm' = squaredNorm ( c --> p' :: v )`
add backend implementation of curve dragging 2020-09-17 03:47:53 +00:00
			`-- \| Drag a cubic Bézier curve to pass through a given point.`
			`--`
			-- Given a cubic Bézier curve, a time \( 0 < t < 1 \) and a point `q`,
			-- modifies the control points to make the curve pass through `q` at time `t`.
			`--`
			`-- Affects the two control points depending on how far along the dragged point is.`
			`-- For instance, dragging near the middle moves both control points equally,`
			`-- while dragging near an endpoint will mostly affect the control point associated with that endpoint.`
			`drag :: forall v r p. ( Torsor v p, Module r v, Fractional r ) => Bezier p -> r -> p -> Bezier p`
			`drag ( Bezier {..} ) t q = Bezier { p0, p1 = p1', p2 = p2', p3 }`
			`where`
			`v0, v1, v2, v3, delta :: v`
			`v0 = q --> p0`
			`v1 = q --> p1`
			`v2 = q --> p2`
			`v3 = q --> p3`
			`delta = ( recip $ t * ( -3 + t * ( 9 + t * ( -12 + 6 * t ) ) ) )`
			`*^ bezier @v ( Bezier v0 v1 v2 v3 ) t`
			`p1', p2' :: p`
			`p1' = ( ( 1 - t ) *^ delta ) • p1`
			`p2' = ( t *^ delta ) • p2`