WebGPU-Art/lagopus

Calcit binding for lagopus.ts , for WebGPU based toys

Lagopus in Calcit

tiny tool for drawing 3D shapes with WebGPU, wraps on Lagopus.ts.

• Demo https://r.tiye.me/Triadica/lagopus/
• Boilerplate https://github.com/Triadica/lagopus-workflow

APIs

:lagopus.alias :refer $ object

object $ {}
  :shader demo-wgsl
  :topology :triangle-list
  :attrs-list $ []
    :: :float32x3 :position
    :: :float32x3 :color
  :data $ []
    :: :vertex (v3 0 0 0) (v3 1 0 0)
    :: :vertex (v3 100 0 0) (v3 0 1 0)
    :: :vertex (v3 0 100 0) (v3 0 0 1)

• :shader custom shader file string
• :topology topology symbol, :triangle-list or :line-strip
• :attrs-list list of attributes, first value providing type, second value is a name(history reason...)
• :data list of data, each data is a map with keys matching :attrs-list, nested list is supported
• optional :indices list of indices, each index is a number. nested list is supported
• :get-params, to add custom params with uniform buffer, for example fn () (js-array 1 1 1 1), notice the values should obey memory alignments

Alternatively, there's also object-writer which provides a writer API, which replaces :data:

  :writer $ fn (write!)
    write! $ []
      :: :vertex (v3 1 1 1)

Shader

Shader file expects 3 parts:

• params(could be empty)
• vertex_main, here you call transform_perspective to display point in 3d
• fragment_main

// to include `lagopus-perpective.wgsl` , provide function `transform_perspective`
#import lagopus::perspective

struct Params {
  _t: f32,
}

@group(0) @binding(0) var<uniform> params: Params;

// structure passing from Vertex to Fragment
struct VertexOut {
  @builtin(position) position: vec4f,
};

@vertex
fn vertex_main(
  @location(0) position: vec3f,
  // data added from attributes put here
) -> VertexOut {
  var output: VertexOut;
  let p = transform_perspective(position.xyz).point_position;
  let scale: f32 = 0.002;

  output.position = vec4(p.xyz * scale, 1.0);
  return output;
}

@fragment
fn fragment_main(vtx_out: VertexOut) -> @location(0) vec4f {
  return vec4f(0.0, 0.0, 0.0, 1.0);
}

Builtin functions

#import lagopus::perspective

• fn transform_perspective(p: vec3f) -> PointResult

#import lagopus::colors

• fn hsl2rgb(hsl: vec3f) -> vec3f
• fn hsl(h: f32, s: f32, l: f32) -> vec3f

#import lagopus::rand

• fn rand(n: f32) -> f32
• fn rand_balanced(n: f32) -> f32
• fn noise(p: f32) -> f32
• fn rand2(n: vec2<f32>) -> f32
• fn noise2(n: vec2<f32>) -> f32

#import lagopus::simplex

• fn simplexNoise2(v: vec2<f32>) -> f32

#import lagopus::hsluv

• fn hsluvToRgb(tuple: vec3f) -> vec3f based on 360 and 100

Components

Curves

lagopus.comp.curves :refer $ comp-curves comp-polylines break-mark

comp-curves $ {} (; :topology :line-strip)
  :curves $ []
    -> (range 400)
      map $ fn (idx)
        let
            angle $ * 0.1 idx
            r 40
          {}
            :position $ []
              * r $ cos angle
              * 0.6 idx
              * r $ sin angle
            :width 2

Another way of defining lines is comp-polylines that seperate segments with :: :breaks. It does not require "flatterned" list so is supposed to be a little performant.

note that : vertex p is a short form for :: :vertex p since Calcit 0.7.2 .

comp-polylines $ {} (; :topology :line-strip)
  :writer $ fn $ (write!)
    write! $ []
      : vertex ([] 0 0 0) width
      : vertex ([] 100 100 0) width
      , break-mark
      : vertex ([] 0 0 10) width
      : vertex ([] 200 0 10) width
      : vertex ([] 200 20 0) width
      : vertex ([] 100 40 0) width
      : vertex ([] 100 20 200) width
      , break-mark

also if you want an extra mark for controlling colors:

comp-polylines-marked $ {} (; :topology :line-strip)
  :writer $ fn (write!)
    write! $ []
      : vertex ([] 0 0 0) width 0
      : vertex ([] 100 100 0) width 0
      , break-mark
      : vertex ([] 0 0 10) width 2
      : vertex ([] 200 0 10) width 2
      : vertex ([] 200 20 0) width 2
      : vertex ([] 100 40 0) width 2
      : vertex ([] 100 20 200) width 2
      , break-mark

Spots

lagopus.comp.spots :refer $ comp-spots comp-bubbles

comp-spots $ {} (; :topology :line-strip)
  :radius 6
  :vertex-count 8
  :shift 12
  :points $ -> (range 80)
    map $ fn (idx)
      let
          r $ * idx 4
        [] r
          * r $ cos (* 0.1129 idx)
          * r $ sin (* 0.123 idx)

comp-bubbles $ {}
  :bubbles $ -> (range 600)
    map $ fn (idx)
      [] (rand-shift 0 area) (rand-shift 0 area) (rand-shift 0 area) (+ 6 $ rand 120)

Axis

laopus.comp.curves :refer $ comp-axis

comp-axis $ {} (:n 20)
  :unit 20

Cube

lagopus.comp.cube :refer $ comp-cube

comp-cube $ {}
  :position $ [] 40 0 0
  :radius 40

Sphere

lagopus.comp.sphere :refer $ comp-sphere

comp-sphere $ {} (; :topology :line-strip)
  :iteration 4
  :radius 160

Plate

lagopus.comp.plate :refer $ comp-plate

comp-plate $ {} (; :topology :line-strip)
  :iteration 20
  :radius 160
  :color $ [] 0.04 0.8 0.6
  :transformer $ fn (i)
    v+ i $ [] 0 0 -10
  ; :x-direction $ [] 1 0 0
  ; :y-direction $ [] 0 1 0
  :chromatism 0.14

Controls

lagopus.comp.button :refer $ comp-button comp-slider comp-drag-point

comp-button
  {}
    :position $ [] 240 260 0
    :color $ [] 0.2 0.9 0.6 1
    :size 20
  fn (e d!)
    d! :tab :sphere

comp-slider
  {} $ :position ([] 0 0 0)
  fn (change on-slide)
    js/console.log "\"Slide" change

comp-drag-point
  {}
    :position $ :pos state
    :color $ [] 0.6 0.6 1.0 1.0
  fn (move d!)
    d! cursor $ assoc state :pos move

Stitch

lagopus.comp.stitch :refer $ comp-stitch

comp-stitch $ {}
  :chars $ [] 0xf2dfea34 0xc3c4a59d 0x88737645
  :position $ [] 0 0 0

Cursor

lagopus.cursor :refer $ update-states >>

Math functions in lagopus.math

• fibo-grid-range total create a list of points constructing Fibonacci Sphere
• rotate-3d origin axis-0 angle p rotate point p around axis-0
• rotate-3d origin axis-0 angle create a function to rotate point p

Resources

Shader functions from https://gist.github.com/munrocket/236ed5ba7e409b8bdf1ff6eca5dcdc39

License

MIT