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open StdLabels
(** Common module for ensuring that the function is evaluated only once *)
module type REPRESENTABLE = sig
type t
(** Represent the path *)
val repr
: t -> (module Path.Repr.M with type point = Path.Point.t and type t = 's) -> 's -> 's
end
type printer =
[ `Fill
| `Line
| `Ductus ]
module type P = sig
include Path.Repr.M
type repr
val create_path
: (repr -> repr) -> t
val get
: t -> repr
end
module MakePrinter(M:Repr.LAYER) : P with type point = M.point and type t = M.t and type repr = M.repr = struct
type t = M.t
type point = M.point
type repr = M.repr
let get
: t -> repr
= M.get
let create_path
: (repr -> repr) -> t
= M.create_path
let start
: Path.Point.t -> t -> t
= fun pt t ->
M.start pt pt t
let line_to
: Path.Point.t -> Path.Point.t -> t -> t
= fun p0 p1 t ->
M.line_to
( p0
, p1 )
( Path.Point.copy p0 @@ Path.Point.get_coord' p0
, Path.Point.copy p1 @@ Path.Point.get_coord' p1 )
t
let quadratic_to
: (Path.Point.t * Gg.v2 * Gg.v2 * Path.Point.t) -> t -> t
= fun (p0, ctrl0, ctrl1, p1) t ->
let ctrl0' = Path.Point.get_coord' @@ Path.Point.copy p0 ctrl0
and ctrl1' = Path.Point.get_coord' @@ Path.Point.copy p1 ctrl1 in
M.quadratic_to
(p0, ctrl0, ctrl1, p1)
(Path.Point.copy p0 @@ Path.Point.get_coord' p0, ctrl0', ctrl1', Path.Point.copy p1 @@ Path.Point.get_coord' p1)
t
let stop = M.stop
end
(* Canva representation *)
module FillCanvaRepr = MakePrinter(FillPrinter.Make(CanvaPrinter))
module DuctusCanvaRepr = MakePrinter(DuctusPrinter.Make(CanvaPrinter))
module LineCanvaRepr = MakePrinter(LinePrinter.Make(CanvaPrinter))
(* SVG representation *)
module FillSVGRepr = MakePrinter(FillPrinter.Make(Svg))
module DuctusSVGRepr = MakePrinter(DuctusPrinter.Make(Svg))
(** Draw a path to a canva *)
let to_canva
: (module REPRESENTABLE with type t = 's) -> 's -> Brr_canvas.C2d.t -> printer -> unit
= fun (type s) (module R:REPRESENTABLE with type t = s) path ctx -> function
| `Fill ->
R.repr
path
(module FillCanvaRepr)
(FillCanvaRepr.create_path (fun p -> Brr_canvas.C2d.fill ctx p; p))
|> FillCanvaRepr.get
|> Brr_canvas.C2d.stroke ctx
| `Line ->
R.repr
path
(module LineCanvaRepr)
(LineCanvaRepr.create_path (fun p -> Brr_canvas.C2d.fill ctx p; p))
|> LineCanvaRepr.get
|> Brr_canvas.C2d.stroke ctx
| `Ductus ->
R.repr
path
(module DuctusCanvaRepr)
(DuctusCanvaRepr.create_path (fun p -> Brr_canvas.C2d.fill ctx p; p))
|> DuctusCanvaRepr.get
|> Brr_canvas.C2d.stroke ctx
(** Draw a path and represent it as SVG *)
let to_svg
: (module REPRESENTABLE with type t = 's) -> color:Jstr.t -> 's -> printer -> Brr.El.t
= fun (type s) (module R:REPRESENTABLE with type t = s) ~color path -> function
| `Fill ->
(* In order to deal with over crossing path, I cut the path in as
many segment as there is curve, and fill them all. Then, all of theme
are grouped inside a single element *)
let paths = ref [] in
let _ = R.repr
path
(module FillSVGRepr)
(FillSVGRepr.create_path
(fun p ->
let repr = Svg.path
~at:Brr.At.[ v (Jstr.v "d") p ]
[] in
paths := repr::!paths;
Jstr.empty)) in
Brr.El.v (Jstr.v "g")
~at:Brr.At.[
v (Jstr.v "fill") color
; v (Jstr.v "stroke") color]
!paths
| `Ductus ->
let svg_path = R.repr
path
(module DuctusSVGRepr)
(DuctusSVGRepr.create_path (fun _ -> Jstr.empty))
|> DuctusSVGRepr.get in
Svg.path
~at:Brr.At.[
v (Jstr.v "fill") color
; v (Jstr.v "stroke") color
; v (Jstr.v "d") svg_path ]
[]
| `Line ->
raise Not_found
(** Transform the two fixed path, into a single one. *)
module ReprFixed = struct
type t = Path.Fixed.t * Path.Fixed.t
module R = struct
type point = Path.Point.t
type repr' =
| Move of (point)
| Line_to of (point * point)
| Quadratic of (point * Gg.v2 * Gg.v2 * point)
type t = repr' list
let start t actions =
(Move t)::actions
let line_to p0 p1 actions =
Line_to (p0, p1)::actions
let quadratic_to
: (point * Gg.v2 * Gg.v2 * point) -> t -> t
= fun q actions ->
(Quadratic q)::actions
let stop
: t -> t
= fun v -> List.rev v
end
let repr
: t -> (module Path.Repr.M with type point = Path.Point.t and type t = 's) -> 's -> 's
= fun (type s) (path, _) (module Repr:Path.Repr.M with type point = Path.Point.t and type t = s) state ->
let elems = Path.Fixed.repr path (module R) [] in
let state = List.fold_left elems
~init:state
~f:(fun state -> function
| R.Move pt -> Repr.start pt state
| R.Line_to (p0, p1) -> Repr.line_to p0 p1 state
| R.Quadratic t -> Repr.quadratic_to t state
)
in Repr.stop state
end
|