updated shader post. copy-paste from mozilla

2020-12-28 15:44:28 +11:00 · 2020-12-28 15:44:28 +11:00 · f789e7680f
parent aabe051aff
commit f789e7680f
3 changed files with 332 additions and 49 deletions
--- a/_assets/javascript/gl-matrix-min.js
+++ b/_assets/javascript/gl-matrix-min.js
--- a/_assets/javascript/shaderCanvas3.js
+++ b/_assets/javascript/shaderCanvas3.js
@ -0,0 +1,301 @@
 var squareRotation = 0.0;
 //main();
 window.addEventListener("load", main);
 //
 // Start here
 //
 function main() {
  const canvas = document.querySelector('#canvas');
  const gl = canvas.getContext('webgl');
  // If we don't have a GL context, give up now
  if (!gl) {
    alert('Unable to initialize WebGL. Your browser or machine may not support it.');
    return;
  }
  // Vertex shader program
  const vsSource = `
    attribute vec4 aVertexPosition;
    attribute vec4 aVertexColor;
    uniform mat4 uModelViewMatrix;
    uniform mat4 uProjectionMatrix;
    varying lowp vec4 vColor;
    void main(void) {
      gl_Position = uProjectionMatrix * uModelViewMatrix * aVertexPosition;
      vColor = aVertexColor;
    }
  `;
  // Fragment shader program
  const fsSource = `
    varying lowp vec4 vColor;
    void main(void) {
      gl_FragColor = vColor;
    }
  `;
  // Initialize a shader program; this is where all the lighting
  // for the vertices and so forth is established.
  const shaderProgram = initShaderProgram(gl, vsSource, fsSource);
  // Collect all the info needed to use the shader program.
  // Look up which attributes our shader program is using
  // for aVertexPosition, aVevrtexColor and also
  // look up uniform locations.
  const programInfo = {
    program: shaderProgram,
    attribLocations: {
      vertexPosition: gl.getAttribLocation(shaderProgram, 'aVertexPosition'),
      vertexColor: gl.getAttribLocation(shaderProgram, 'aVertexColor'),
    },
    uniformLocations: {
      projectionMatrix: gl.getUniformLocation(shaderProgram, 'uProjectionMatrix'),
      modelViewMatrix: gl.getUniformLocation(shaderProgram, 'uModelViewMatrix'),
    },
  };
  // Here's where we call the routine that builds all the
  // objects we'll be drawing.
  const buffers = initBuffers(gl);
  var then = 0;
  // Draw the scene repeatedly
  function render(now) {
    now *= 0.001;  // convert to seconds
    const deltaTime = now - then;
    then = now;
    drawScene(gl, programInfo, buffers, deltaTime);
    requestAnimationFrame(render);
  }
  requestAnimationFrame(render);
 }
 //
 // initBuffers
 //
 // Initialize the buffers we'll need. For this demo, we just
 // have one object -- a simple two-dimensional square.
 //
 function initBuffers(gl) {
  // Create a buffer for the square's positions.
  const positionBuffer = gl.createBuffer();
  // Select the positionBuffer as the one to apply buffer
  // operations to from here out.
  gl.bindBuffer(gl.ARRAY_BUFFER, positionBuffer);
  // Now create an array of positions for the square.
  const positions = [
     1.0,  1.0,
    -1.0,  1.0,
     1.0, -1.0,
    -1.0, -1.0,
  ];
  // Now pass the list of positions into WebGL to build the
  // shape. We do this by creating a Float32Array from the
  // JavaScript array, then use it to fill the current buffer.
  gl.bufferData(gl.ARRAY_BUFFER, new Float32Array(positions), gl.STATIC_DRAW);
  // Now set up the colors for the vertices
  const colors = [
    1.0,  0.5,  1.0,  1.0,    // white
    1.0,  0.6,  1.0,  1.0,    // red
    1.0,  0.7,  1.0,  1.0,    // green
    1.0,  0.3,  1.0,  1.0,    // blue
  ];
  const colorBuffer = gl.createBuffer();
  gl.bindBuffer(gl.ARRAY_BUFFER, colorBuffer);
  gl.bufferData(gl.ARRAY_BUFFER, new Float32Array(colors), gl.STATIC_DRAW);
  return {
    position: positionBuffer,
    color: colorBuffer,
  };
 }
 //
 // Draw the scene.
 //
 function drawScene(gl, programInfo, buffers, deltaTime) {
  gl.clearColor(0.0, 0.0, 0.0, 1.0);  // Clear to black, fully opaque
  gl.clearDepth(1.0);                 // Clear everything
  gl.enable(gl.DEPTH_TEST);           // Enable depth testing
  gl.depthFunc(gl.LEQUAL);            // Near things obscure far things
  // Clear the canvas before we start drawing on it.
  gl.clear(gl.COLOR_BUFFER_BIT | gl.DEPTH_BUFFER_BIT);
  // Create a perspective matrix, a special matrix that is
  // used to simulate the distortion of perspective in a camera.
  // Our field of view is 45 degrees, with a width/height
  // ratio that matches the display size of the canvas
  // and we only want to see objects between 0.1 units
  // and 100 units away from the camera.
  const fieldOfView = 45 * Math.PI / 180;   // in radians
  const aspect = gl.canvas.clientWidth / gl.canvas.clientHeight;
  const zNear = 0.1;
  const zFar = 100.0;
  const projectionMatrix = mat4.create();
  // note: glmatrix.js always has the first argument
  // as the destination to receive the result.
  mat4.perspective(projectionMatrix,
                   fieldOfView,
                   aspect,
                   zNear,
                   zFar);
  // Set the drawing position to the "identity" point, which is
  // the center of the scene.
  const modelViewMatrix = mat4.create();
  // Now move the drawing position a bit to where we want to
  // start drawing the square.
  mat4.translate(modelViewMatrix,     // destination matrix
                 modelViewMatrix,     // matrix to translate
                 [-0.0, 0.0, -6.0]);  // amount to translate
  mat4.rotate(modelViewMatrix,  // destination matrix
              modelViewMatrix,  // matrix to rotate
              squareRotation,   // amount to rotate in radians
              [0, 0, 1]);       // axis to rotate around
  // Tell WebGL how to pull out the positions from the position
  // buffer into the vertexPosition attribute
  {
    const numComponents = 2;
    const type = gl.FLOAT;
    const normalize = false;
    const stride = 0;
    const offset = 0;
    gl.bindBuffer(gl.ARRAY_BUFFER, buffers.position);
    gl.vertexAttribPointer(
        programInfo.attribLocations.vertexPosition,
        numComponents,
        type,
        normalize,
        stride,
        offset);
    gl.enableVertexAttribArray(
        programInfo.attribLocations.vertexPosition);
  }
  // Tell WebGL how to pull out the colors from the color buffer
  // into the vertexColor attribute.
  {
    const numComponents = 4;
    const type = gl.FLOAT;
    const normalize = false;
    const stride = 0;
    const offset = 0;
    gl.bindBuffer(gl.ARRAY_BUFFER, buffers.color);
    gl.vertexAttribPointer(
        programInfo.attribLocations.vertexColor,
        numComponents,
        type,
        normalize,
        stride,
        offset);
    gl.enableVertexAttribArray(
        programInfo.attribLocations.vertexColor);
  }
  // Tell WebGL to use our program when drawing
  gl.useProgram(programInfo.program);
  // Set the shader uniforms
  gl.uniformMatrix4fv(
      programInfo.uniformLocations.projectionMatrix,
      false,
      projectionMatrix);
  gl.uniformMatrix4fv(
      programInfo.uniformLocations.modelViewMatrix,
      false,
      modelViewMatrix);
  {
    const offset = 0;
    const vertexCount = 4;
    gl.drawArrays(gl.TRIANGLE_STRIP, offset, vertexCount);
  }
  // Update the rotation for the next draw
  squareRotation += deltaTime;
 }
 //
 // Initialize a shader program, so WebGL knows how to draw our data
 //
 function initShaderProgram(gl, vsSource, fsSource) {
  const vertexShader = loadShader(gl, gl.VERTEX_SHADER, vsSource);
  const fragmentShader = loadShader(gl, gl.FRAGMENT_SHADER, fsSource);
  // Create the shader program
  const shaderProgram = gl.createProgram();
  gl.attachShader(shaderProgram, vertexShader);
  gl.attachShader(shaderProgram, fragmentShader);
  gl.linkProgram(shaderProgram);
  // If creating the shader program failed, alert
  if (!gl.getProgramParameter(shaderProgram, gl.LINK_STATUS)) {
    alert('Unable to initialize the shader program: ' + gl.getProgramInfoLog(shaderProgram));
    return null;
  }
  return shaderProgram;
 }
 //
 // creates a shader of the given type, uploads the source and
 // compiles it.
 //
 function loadShader(gl, type, source) {
  const shader = gl.createShader(type);
  // Send the source to the shader object
  gl.shaderSource(shader, source);
  // Compile the shader program
  gl.compileShader(shader);
  // See if it compiled successfully
  if (!gl.getShaderParameter(shader, gl.COMPILE_STATUS)) {
    alert('An error occurred compiling the shaders: ' + gl.getShaderInfoLog(shader));
    gl.deleteShader(shader);
    return null;
  }
  return shader;
 }
--- a/_posts/2020-12-18-shader.markdown
+++ b/_posts/2020-12-18-shader.markdown
@ -4,54 +4,8 @@ title: "Shader fun"
 date: 2020-12-28
 categories: design
 ---
-<canvas id="canvas" width="1080" height="1080" style="border:1px solid white;
+<canvas id="canvas" width="1080" height="1080" style="//border:1px solid white;
 width:100%;"></canvas>
-<script id="node-vertex-shader" type="x-shader/x-vertex">
+<script src="https://cdnjs.cloudflare.com/ajax/libs/gl-matrix/2.8.1/gl-matrix-min.js" integrity="sha512-zhHQR0/H5SEBL3Wn6yYSaTTZej12z0hVZKOv3TwCUXT1z5qeqGcXJLLrbERYRScEDDpYIJhPC1fk31gqR783iQ==" crossorigin="anonymous" defer=""></script>
-  uniform vec2 u_resolution;
+{% asset shaderCanvas3.js %}
  attribute vec2 a_position;
  attribute vec2 a_center;
  attribute float a_radius;
  varying vec2 center;
  varying vec2 resolution;
  varying float radius;
  void main() {
    vec2 clipspace = a_position / u_resolution * 2.0 - 1.0;
    gl_Position = vec4(clipspace * vec2(1, -1), 0, 1);
    radius = a_radius;
    center = a_center;
    resolution = u_resolution;
  }
 </script>
 <script id="node-fragment-shader" type="x-shader/x-fragment">
  precision mediump float;
  varying vec2 center;
  varying vec2 resolution;
  varying float radius;
  void main() {
    vec4 color0 = vec4(0.0, 0.0, 0.0, 0.0);
    float x = gl_FragCoord.x;
    float y = resolution[1] - gl_FragCoord.y;
    float dx = center[0] - x;
    float dy = center[1] - y;
    float distance = sqrt(dx*dx + dy*dy);
    if ( distance < radius )
      gl_FragColor = vec4(1.0, 0.5, 0.0, 1.0);
    else 
      gl_FragColor = color0;
  }
 </script>
 {% asset shaderCanvas2.js %}