coopgo/node_modules/ol/reproj.js

/**
 * @module ol/reproj
 */
import { IMAGE_SMOOTHING_DISABLED } from './renderer/canvas/common.js';
import { assign } from './obj.js';
import { containsCoordinate, createEmpty, extend, forEachCorner, getCenter, getHeight, getTopLeft, getWidth, } from './extent.js';
import { createCanvasContext2D } from './dom.js';
import { getPointResolution, transform } from './proj.js';
import { solveLinearSystem } from './math.js';
var brokenDiagonalRendering_;
/**
 * @type {Array<HTMLCanvasElement>}
 */
export var canvasPool = [];
/**
 * This draws a small triangle into a canvas by setting the triangle as the clip region
 * and then drawing a (too large) rectangle
 *
 * @param {CanvasRenderingContext2D} ctx The context in which to draw the triangle
 * @param {number} u1 The x-coordinate of the second point. The first point is 0,0.
 * @param {number} v1 The y-coordinate of the second point.
 * @param {number} u2 The x-coordinate of the third point.
 * @param {number} v2 The y-coordinate of the third point.
 */
function drawTestTriangle(ctx, u1, v1, u2, v2) {
    ctx.beginPath();
    ctx.moveTo(0, 0);
    ctx.lineTo(u1, v1);
    ctx.lineTo(u2, v2);
    ctx.closePath();
    ctx.save();
    ctx.clip();
    ctx.fillRect(0, 0, Math.max(u1, u2) + 1, Math.max(v1, v2));
    ctx.restore();
}
/**
 * Given the data from getImageData, see if the right values appear at the provided offset.
 * Returns true if either the color or transparency is off
 *
 * @param {Uint8ClampedArray} data The data returned from getImageData
 * @param {number} offset The pixel offset from the start of data.
 * @return {boolean} true if the diagonal rendering is broken
 */
function verifyBrokenDiagonalRendering(data, offset) {
    // the values ought to be close to the rgba(210, 0, 0, 0.75)
    return (Math.abs(data[offset * 4] - 210) > 2 ||
        Math.abs(data[offset * 4 + 3] - 0.75 * 255) > 2);
}
/**
 * Determines if the current browser configuration can render triangular clip regions correctly.
 * This value is cached so the function is only expensive the first time called.
 * Firefox on Windows (as of now) does not if HWA is enabled. See https://bugzilla.mozilla.org/show_bug.cgi?id=1606976
 * IE also doesn't. Chrome works, and everything seems to work on OSX and Android. This function caches the
 * result. I suppose that it is conceivably possible that a browser might flip modes while the app is
 * running, but lets hope not.
 *
 * @return {boolean} true if the Diagonal Rendering is broken.
 */
function isBrokenDiagonalRendering() {
    if (brokenDiagonalRendering_ === undefined) {
        var ctx = document.createElement('canvas').getContext('2d');
        ctx.globalCompositeOperation = 'lighter';
        ctx.fillStyle = 'rgba(210, 0, 0, 0.75)';
        drawTestTriangle(ctx, 4, 5, 4, 0);
        drawTestTriangle(ctx, 4, 5, 0, 5);
        var data = ctx.getImageData(0, 0, 3, 3).data;
        brokenDiagonalRendering_ =
            verifyBrokenDiagonalRendering(data, 0) ||
                verifyBrokenDiagonalRendering(data, 4) ||
                verifyBrokenDiagonalRendering(data, 8);
    }
    return brokenDiagonalRendering_;
}
/**
 * Calculates ideal resolution to use from the source in order to achieve
 * pixel mapping as close as possible to 1:1 during reprojection.
 * The resolution is calculated regardless of what resolutions
 * are actually available in the dataset (TileGrid, Image, ...).
 *
 * @param {import("./proj/Projection.js").default} sourceProj Source projection.
 * @param {import("./proj/Projection.js").default} targetProj Target projection.
 * @param {import("./coordinate.js").Coordinate} targetCenter Target center.
 * @param {number} targetResolution Target resolution.
 * @return {number} The best resolution to use. Can be +-Infinity, NaN or 0.
 */
export function calculateSourceResolution(sourceProj, targetProj, targetCenter, targetResolution) {
    var sourceCenter = transform(targetCenter, targetProj, sourceProj);
    // calculate the ideal resolution of the source data
    var sourceResolution = getPointResolution(targetProj, targetResolution, targetCenter);
    var targetMetersPerUnit = targetProj.getMetersPerUnit();
    if (targetMetersPerUnit !== undefined) {
        sourceResolution *= targetMetersPerUnit;
    }
    var sourceMetersPerUnit = sourceProj.getMetersPerUnit();
    if (sourceMetersPerUnit !== undefined) {
        sourceResolution /= sourceMetersPerUnit;
    }
    // Based on the projection properties, the point resolution at the specified
    // coordinates may be slightly different. We need to reverse-compensate this
    // in order to achieve optimal results.
    var sourceExtent = sourceProj.getExtent();
    if (!sourceExtent || containsCoordinate(sourceExtent, sourceCenter)) {
        var compensationFactor = getPointResolution(sourceProj, sourceResolution, sourceCenter) /
            sourceResolution;
        if (isFinite(compensationFactor) && compensationFactor > 0) {
            sourceResolution /= compensationFactor;
        }
    }
    return sourceResolution;
}
/**
 * Calculates ideal resolution to use from the source in order to achieve
 * pixel mapping as close as possible to 1:1 during reprojection.
 * The resolution is calculated regardless of what resolutions
 * are actually available in the dataset (TileGrid, Image, ...).
 *
 * @param {import("./proj/Projection.js").default} sourceProj Source projection.
 * @param {import("./proj/Projection.js").default} targetProj Target projection.
 * @param {import("./extent.js").Extent} targetExtent Target extent
 * @param {number} targetResolution Target resolution.
 * @return {number} The best resolution to use. Can be +-Infinity, NaN or 0.
 */
export function calculateSourceExtentResolution(sourceProj, targetProj, targetExtent, targetResolution) {
    var targetCenter = getCenter(targetExtent);
    var sourceResolution = calculateSourceResolution(sourceProj, targetProj, targetCenter, targetResolution);
    if (!isFinite(sourceResolution) || sourceResolution <= 0) {
        forEachCorner(targetExtent, function (corner) {
            sourceResolution = calculateSourceResolution(sourceProj, targetProj, corner, targetResolution);
            return isFinite(sourceResolution) && sourceResolution > 0;
        });
    }
    return sourceResolution;
}
/**
 * @typedef {Object} ImageExtent
 * @property {import("./extent.js").Extent} extent Extent.
 * @property {HTMLCanvasElement|HTMLImageElement|HTMLVideoElement} image Image.
 */
/**
 * Renders the source data into new canvas based on the triangulation.
 *
 * @param {number} width Width of the canvas.
 * @param {number} height Height of the canvas.
 * @param {number} pixelRatio Pixel ratio.
 * @param {number} sourceResolution Source resolution.
 * @param {import("./extent.js").Extent} sourceExtent Extent of the data source.
 * @param {number} targetResolution Target resolution.
 * @param {import("./extent.js").Extent} targetExtent Target extent.
 * @param {import("./reproj/Triangulation.js").default} triangulation Calculated triangulation.
 * @param {Array<ImageExtent>} sources Array of sources.
 * @param {number} gutter Gutter of the sources.
 * @param {boolean} [opt_renderEdges] Render reprojection edges.
 * @param {boolean} [opt_interpolate] Use linear interpolation when resampling.
 * @return {HTMLCanvasElement} Canvas with reprojected data.
 */
export function render(width, height, pixelRatio, sourceResolution, sourceExtent, targetResolution, targetExtent, triangulation, sources, gutter, opt_renderEdges, opt_interpolate) {
    var context = createCanvasContext2D(Math.round(pixelRatio * width), Math.round(pixelRatio * height), canvasPool);
    if (!opt_interpolate) {
        assign(context, IMAGE_SMOOTHING_DISABLED);
    }
    if (sources.length === 0) {
        return context.canvas;
    }
    context.scale(pixelRatio, pixelRatio);
    function pixelRound(value) {
        return Math.round(value * pixelRatio) / pixelRatio;
    }
    context.globalCompositeOperation = 'lighter';
    var sourceDataExtent = createEmpty();
    sources.forEach(function (src, i, arr) {
        extend(sourceDataExtent, src.extent);
    });
    var canvasWidthInUnits = getWidth(sourceDataExtent);
    var canvasHeightInUnits = getHeight(sourceDataExtent);
    var stitchContext = createCanvasContext2D(Math.round((pixelRatio * canvasWidthInUnits) / sourceResolution), Math.round((pixelRatio * canvasHeightInUnits) / sourceResolution));
    if (!opt_interpolate) {
        assign(stitchContext, IMAGE_SMOOTHING_DISABLED);
    }
    var stitchScale = pixelRatio / sourceResolution;
    sources.forEach(function (src, i, arr) {
        var xPos = src.extent[0] - sourceDataExtent[0];
        var yPos = -(src.extent[3] - sourceDataExtent[3]);
        var srcWidth = getWidth(src.extent);
        var srcHeight = getHeight(src.extent);
        // This test should never fail -- but it does. Need to find a fix the upstream condition
        if (src.image.width > 0 && src.image.height > 0) {
            stitchContext.drawImage(src.image, gutter, gutter, src.image.width - 2 * gutter, src.image.height - 2 * gutter, xPos * stitchScale, yPos * stitchScale, srcWidth * stitchScale, srcHeight * stitchScale);
        }
    });
    var targetTopLeft = getTopLeft(targetExtent);
    triangulation.getTriangles().forEach(function (triangle, i, arr) {
        /* Calculate affine transform (src -> dst)
         * Resulting matrix can be used to transform coordinate
         * from `sourceProjection` to destination pixels.
         *
         * To optimize number of context calls and increase numerical stability,
         * we also do the following operations:
         * trans(-topLeftExtentCorner), scale(1 / targetResolution), scale(1, -1)
         * here before solving the linear system so [ui, vi] are pixel coordinates.
         *
         * Src points: xi, yi
         * Dst points: ui, vi
         * Affine coefficients: aij
         *
         * | x0 y0 1  0  0 0 |   |a00|   |u0|
         * | x1 y1 1  0  0 0 |   |a01|   |u1|
         * | x2 y2 1  0  0 0 | x |a02| = |u2|
         * |  0  0 0 x0 y0 1 |   |a10|   |v0|
         * |  0  0 0 x1 y1 1 |   |a11|   |v1|
         * |  0  0 0 x2 y2 1 |   |a12|   |v2|
         */
        var source = triangle.source;
        var target = triangle.target;
        var x0 = source[0][0], y0 = source[0][1];
        var x1 = source[1][0], y1 = source[1][1];
        var x2 = source[2][0], y2 = source[2][1];
        // Make sure that everything is on pixel boundaries
        var u0 = pixelRound((target[0][0] - targetTopLeft[0]) / targetResolution);
        var v0 = pixelRound(-(target[0][1] - targetTopLeft[1]) / targetResolution);
        var u1 = pixelRound((target[1][0] - targetTopLeft[0]) / targetResolution);
        var v1 = pixelRound(-(target[1][1] - targetTopLeft[1]) / targetResolution);
        var u2 = pixelRound((target[2][0] - targetTopLeft[0]) / targetResolution);
        var v2 = pixelRound(-(target[2][1] - targetTopLeft[1]) / targetResolution);
        // Shift all the source points to improve numerical stability
        // of all the subsequent calculations. The [x0, y0] is used here.
        // This is also used to simplify the linear system.
        var sourceNumericalShiftX = x0;
        var sourceNumericalShiftY = y0;
        x0 = 0;
        y0 = 0;
        x1 -= sourceNumericalShiftX;
        y1 -= sourceNumericalShiftY;
        x2 -= sourceNumericalShiftX;
        y2 -= sourceNumericalShiftY;
        var augmentedMatrix = [
            [x1, y1, 0, 0, u1 - u0],
            [x2, y2, 0, 0, u2 - u0],
            [0, 0, x1, y1, v1 - v0],
            [0, 0, x2, y2, v2 - v0],
        ];
        var affineCoefs = solveLinearSystem(augmentedMatrix);
        if (!affineCoefs) {
            return;
        }
        context.save();
        context.beginPath();
        if (isBrokenDiagonalRendering() || !opt_interpolate) {
            // Make sure that all lines are horizontal or vertical
            context.moveTo(u1, v1);
            // This is the diagonal line. Do it in 4 steps
            var steps = 4;
            var ud = u0 - u1;
            var vd = v0 - v1;
            for (var step = 0; step < steps; step++) {
                // Go horizontally
                context.lineTo(u1 + pixelRound(((step + 1) * ud) / steps), v1 + pixelRound((step * vd) / (steps - 1)));
                // Go vertically
                if (step != steps - 1) {
                    context.lineTo(u1 + pixelRound(((step + 1) * ud) / steps), v1 + pixelRound(((step + 1) * vd) / (steps - 1)));
                }
            }
            // We are almost at u0r, v0r
            context.lineTo(u2, v2);
        }
        else {
            context.moveTo(u1, v1);
            context.lineTo(u0, v0);
            context.lineTo(u2, v2);
        }
        context.clip();
        context.transform(affineCoefs[0], affineCoefs[2], affineCoefs[1], affineCoefs[3], u0, v0);
        context.translate(sourceDataExtent[0] - sourceNumericalShiftX, sourceDataExtent[3] - sourceNumericalShiftY);
        context.scale(sourceResolution / pixelRatio, -sourceResolution / pixelRatio);
        context.drawImage(stitchContext.canvas, 0, 0);
        context.restore();
    });
    if (opt_renderEdges) {
        context.save();
        context.globalCompositeOperation = 'source-over';
        context.strokeStyle = 'black';
        context.lineWidth = 1;
        triangulation.getTriangles().forEach(function (triangle, i, arr) {
            var target = triangle.target;
            var u0 = (target[0][0] - targetTopLeft[0]) / targetResolution;
            var v0 = -(target[0][1] - targetTopLeft[1]) / targetResolution;
            var u1 = (target[1][0] - targetTopLeft[0]) / targetResolution;
            var v1 = -(target[1][1] - targetTopLeft[1]) / targetResolution;
            var u2 = (target[2][0] - targetTopLeft[0]) / targetResolution;
            var v2 = -(target[2][1] - targetTopLeft[1]) / targetResolution;
            context.beginPath();
            context.moveTo(u1, v1);
            context.lineTo(u0, v0);
            context.lineTo(u2, v2);
            context.closePath();
            context.stroke();
        });
        context.restore();
    }
    return context.canvas;
}
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