054af09032
This updates ESLint and our shared eslint-config-openlayers to use Prettier. Most formatting changes were automatically applied with this:
npm run lint -- --fix
A few manual changes were required:
* In `examples/offscreen-canvas.js`, the `//eslint-disable-line` comment needed to be moved to the appropriate line to disable the error about the `'worker-loader!./offscreen-canvas.worker.js'` import.
* In `examples/webpack/exapmle-builder.js`, spaces could not be added after a couple `function`s for some reason. While editing this, I reworked `ExampleBuilder` to be a class.
* In `src/ol/format/WMSGetFeatureInfo.js`, the `// @ts-ignore` comment needed to be moved down one line so it applied to the `parsersNS` argument.
166 lines
4.7 KiB
JavaScript
166 lines
4.7 KiB
JavaScript
import Map from '../src/ol/Map.js';
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import View from '../src/ol/View.js';
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import {Image as ImageLayer, Tile as TileLayer} from '../src/ol/layer.js';
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import {OSM, Raster, XYZ} from '../src/ol/source.js';
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/**
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* Generates a shaded relief image given elevation data. Uses a 3x3
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* neighborhood for determining slope and aspect.
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* @param {Array<ImageData>} inputs Array of input images.
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* @param {Object} data Data added in the "beforeoperations" event.
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* @return {ImageData} Output image.
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*/
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function shade(inputs, data) {
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const elevationImage = inputs[0];
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const width = elevationImage.width;
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const height = elevationImage.height;
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const elevationData = elevationImage.data;
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const shadeData = new Uint8ClampedArray(elevationData.length);
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const dp = data.resolution * 2;
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const maxX = width - 1;
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const maxY = height - 1;
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const pixel = [0, 0, 0, 0];
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const twoPi = 2 * Math.PI;
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const halfPi = Math.PI / 2;
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const sunEl = (Math.PI * data.sunEl) / 180;
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const sunAz = (Math.PI * data.sunAz) / 180;
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const cosSunEl = Math.cos(sunEl);
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const sinSunEl = Math.sin(sunEl);
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let pixelX,
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pixelY,
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x0,
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x1,
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y0,
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y1,
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offset,
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z0,
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z1,
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dzdx,
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dzdy,
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slope,
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aspect,
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cosIncidence,
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scaled;
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for (pixelY = 0; pixelY <= maxY; ++pixelY) {
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y0 = pixelY === 0 ? 0 : pixelY - 1;
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y1 = pixelY === maxY ? maxY : pixelY + 1;
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for (pixelX = 0; pixelX <= maxX; ++pixelX) {
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x0 = pixelX === 0 ? 0 : pixelX - 1;
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x1 = pixelX === maxX ? maxX : pixelX + 1;
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// determine elevation for (x0, pixelY)
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offset = (pixelY * width + x0) * 4;
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pixel[0] = elevationData[offset];
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pixel[1] = elevationData[offset + 1];
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pixel[2] = elevationData[offset + 2];
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pixel[3] = elevationData[offset + 3];
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z0 = data.vert * (pixel[0] + pixel[1] * 2 + pixel[2] * 3);
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// determine elevation for (x1, pixelY)
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offset = (pixelY * width + x1) * 4;
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pixel[0] = elevationData[offset];
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pixel[1] = elevationData[offset + 1];
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pixel[2] = elevationData[offset + 2];
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pixel[3] = elevationData[offset + 3];
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z1 = data.vert * (pixel[0] + pixel[1] * 2 + pixel[2] * 3);
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dzdx = (z1 - z0) / dp;
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// determine elevation for (pixelX, y0)
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offset = (y0 * width + pixelX) * 4;
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pixel[0] = elevationData[offset];
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pixel[1] = elevationData[offset + 1];
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pixel[2] = elevationData[offset + 2];
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pixel[3] = elevationData[offset + 3];
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z0 = data.vert * (pixel[0] + pixel[1] * 2 + pixel[2] * 3);
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// determine elevation for (pixelX, y1)
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offset = (y1 * width + pixelX) * 4;
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pixel[0] = elevationData[offset];
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pixel[1] = elevationData[offset + 1];
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pixel[2] = elevationData[offset + 2];
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pixel[3] = elevationData[offset + 3];
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z1 = data.vert * (pixel[0] + pixel[1] * 2 + pixel[2] * 3);
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dzdy = (z1 - z0) / dp;
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slope = Math.atan(Math.sqrt(dzdx * dzdx + dzdy * dzdy));
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aspect = Math.atan2(dzdy, -dzdx);
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if (aspect < 0) {
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aspect = halfPi - aspect;
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} else if (aspect > halfPi) {
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aspect = twoPi - aspect + halfPi;
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} else {
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aspect = halfPi - aspect;
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}
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cosIncidence =
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sinSunEl * Math.cos(slope) +
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cosSunEl * Math.sin(slope) * Math.cos(sunAz - aspect);
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offset = (pixelY * width + pixelX) * 4;
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scaled = 255 * cosIncidence;
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shadeData[offset] = scaled;
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shadeData[offset + 1] = scaled;
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shadeData[offset + 2] = scaled;
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shadeData[offset + 3] = elevationData[offset + 3];
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}
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}
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return {data: shadeData, width: width, height: height};
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}
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const elevation = new XYZ({
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url: 'https://{a-d}.tiles.mapbox.com/v3/aj.sf-dem/{z}/{x}/{y}.png',
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crossOrigin: 'anonymous',
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});
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const raster = new Raster({
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sources: [elevation],
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operationType: 'image',
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operation: shade,
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});
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const map = new Map({
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target: 'map',
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layers: [
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new TileLayer({
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source: new OSM(),
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}),
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new ImageLayer({
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opacity: 0.3,
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source: raster,
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}),
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],
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view: new View({
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extent: [-13675026, 4439648, -13580856, 4580292],
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center: [-13615645, 4497969],
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minZoom: 10,
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maxZoom: 16,
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zoom: 13,
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}),
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});
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const controlIds = ['vert', 'sunEl', 'sunAz'];
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const controls = {};
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controlIds.forEach(function (id) {
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const control = document.getElementById(id);
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const output = document.getElementById(id + 'Out');
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control.addEventListener('input', function () {
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output.innerText = control.value;
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raster.changed();
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});
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output.innerText = control.value;
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controls[id] = control;
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});
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raster.on('beforeoperations', function (event) {
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// the event.data object will be passed to operations
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const data = event.data;
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data.resolution = event.resolution;
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for (const id in controls) {
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data[id] = Number(controls[id].value);
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}
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});
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