【愚公系列】2022年09月微信小程序-WebGL立体图形的绘制

愚公搬代码

发布于 2022-09-28 15:00:10

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发布于 2022-09-28 15:00:10

文章目录

前言

WebGL（全写Web Graphics Library）是一种3D绘图协议，这种绘图技术标准允许把JavaScript和OpenGL ES 2.0结合在一起，通过增加OpenGL ES 2.0的一个JavaScript绑定，WebGL可以为HTML5 Canvas提供硬件3D加速渲染，这样Web开发人员就可以借助系统显卡来在浏览器里更流畅地展示3D场景和模型了，还能创建复杂的导航和数据视觉化。显然，WebGL技术标准免去了开发网页专用渲染插件的麻烦，可被用于创建具有复杂3D结构的网站页面，甚至可以用来设计3D网页游戏等等。–百度百科

在现实中webgl的用途很多，比如医院运维网站，地铁运维网站，海绵城市，可以以三维网页形式展示出现实状态。

一、webgl的使用

安装第三方包：npm i --save threejs-miniprogram

1.立体图形的绘制

import drawCube from './drawCube'
 

Page({

  /**
   * 页面的初始数据
   */
  data: {

  },

  /**
   * 生命周期函数--监听页面加载
   */
  onLoad: function (options) {

  },

  /**
   * 生命周期函数--监听页面初次渲染完成
   */
  onReady: function () {
    wx.createSelectorQuery()
      .select('#myCanvas1')
      .node()
      .exec((res) => {
        const canvas = res[0].node
        const gl = canvas.getContext('webgl')
        if (!gl) {
          console.log('webgl未受支持');
          return
        }
        // 检查所有支持的扩展
        var available_extensions = gl.getSupportedExtensions();
        console.log(available_extensions);

        // 清除画布
        // 使用完全不透明的黑色清除所有图像，我们将清除色设为黑色，此时并没有开始清除
        gl.clearColor(0.0, 0.0, 0.0, 1.0);
        // 用上面指定的颜色清除缓冲区
        gl.clear(gl.COLOR_BUFFER_BIT);

        // 画的是一个正方形
        drawCube(gl, canvas)
})

import {
  mat4
} from '../../lib/gl-matrix'

var cubeRotation = 0.0;

//
// Start here
//
function drawCube(gl,canvas) {
  // 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);

    canvas.requestAnimationFrame(render);
  }
  canvas.requestAnimationFrame(render);
}

//
// initBuffers
//
// Initialize the buffers we'll need. For this demo, we just
// have one object -- a simple three-dimensional cube.
//
function initBuffers(gl) {

  // Create a buffer for the cube's vertex 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 cube.

  const positions = [
    // Front face
    -1.0, -1.0,  1.0,
    1.0, -1.0,  1.0,
    1.0,  1.0,  1.0,
    -1.0,  1.0,  1.0,

    // Back face
    -1.0, -1.0, -1.0,
    -1.0,  1.0, -1.0,
    1.0,  1.0, -1.0,
    1.0, -1.0, -1.0,

   // Top face
   -1.0,  1.0, -1.0,
   -1.0,  1.0,  1.0,
    1.0,  1.0,  1.0,
    1.0,  1.0, -1.0,
 
    // Bottom face
   -1.0, -1.0, -1.0,
    1.0, -1.0, -1.0,
    1.0, -1.0,  1.0,
   -1.0, -1.0,  1.0,

    // Right face
    1.0, -1.0, -1.0,
    1.0,  1.0, -1.0,
    1.0,  1.0,  1.0,
    1.0, -1.0,  1.0,

    // Left face
    -1.0, -1.0, -1.0,
    -1.0, -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 faces. We'll use solid colors
  // for each face.

  const faceColors = [
    [1.0,  1.0,  1.0,  1.0],    // Front face: white
    [1.0,  0.0,  0.0,  1.0],    // Back face: red
    [0.0,  1.0,  0.0,  1.0],    // Top face: green
    [0.0,  0.0,  1.0,  1.0],    // Bottom face: blue
    [1.0,  1.0,  0.0,  1.0],    // Right face: yellow
    [1.0,  0.0,  1.0,  1.0],    // Left face: purple
  ];

  // Convert the array of colors into a table for all the vertices.

  var colors = [];

  for (var j = 0; j < faceColors.length; ++j) {
    const c = faceColors[j];

    // Repeat each color four times for the four vertices of the face
    colors = colors.concat(c, c, c, c);
    // colors = colors.concat(c);
    // colors = colors.concat(c);
    // colors = colors.concat(c);
    // colors = colors.concat(c);
  }

  const colorBuffer = gl.createBuffer();
  gl.bindBuffer(gl.ARRAY_BUFFER, colorBuffer);
  gl.bufferData(gl.ARRAY_BUFFER, new Float32Array(colors), gl.STATIC_DRAW);

  // Build the element array buffer; this specifies the indices
  // into the vertex arrays for each face's vertices.

  const indexBuffer = gl.createBuffer();
  gl.bindBuffer(gl.ELEMENT_ARRAY_BUFFER, indexBuffer);

  // This array defines each face as two triangles, using the
  // indices into the vertex array to specify each triangle's
  // position.

  const indices = [
    0,  1,  2,      0,  2,  3,    // front
    4,  5,  6,      4,  6,  7,    // back
    8,  9,  10,     8,  10, 11,   // top
    12, 13, 14,     12, 14, 15,   // bottom
    16, 17, 18,     16, 18, 19,   // right
    20, 21, 22,     20, 22, 23,   // left
  ];

  // Now send the element array to GL

  gl.bufferData(gl.ELEMENT_ARRAY_BUFFER,
      new Uint16Array(indices), gl.STATIC_DRAW);

  return {
    position: positionBuffer,
    color: colorBuffer,
    indices: indexBuffer,
  };
}

//
// 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
              cubeRotation,     // amount to rotate in radians
              [0, 0, 1]);       // axis to rotate around (Z)

  mat4.rotate(modelViewMatrix,  // destination matrix
              modelViewMatrix,  // matrix to rotate
              cubeRotation * .7,// amount to rotate in radians
              [0, 1, 0]);       // axis to rotate around (Y)

  // Tell WebGL how to pull out the positions from the position
  // buffer into the vertexPosition attribute
  {
    const numComponents = 3;
    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);
  }

// gl.ARRAY_BUFFER: 包含顶点属性的Buffer，如顶点坐标，纹理坐标数据或顶点颜色数据。
// gl.ELEMENT_ARRAY_BUFFER: 用于元素索引的Buffer。

  // Tell WebGL which indices to use to index the vertices
  gl.bindBuffer(gl.ELEMENT_ARRAY_BUFFER, buffers.indices);

  // 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);

  {
    // 6个面，12个三角形，每个三角3个顶点，共36个顶点
    const vertexCount = 36;
    const type = gl.UNSIGNED_SHORT;
    const offset = 0;
    gl.drawElements(gl.TRIANGLES, vertexCount, type, offset);
  }

  // Update the rotation for the next draw

  cubeRotation += 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;
}

export default drawCube

实际效果