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@@ -3,9 +3,8 @@ import * as d3geoProjection from 'd3-geo-projection'; |
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import * as d3geoPolygon from 'd3-geo-polygon'; |
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import * as d3geoPolygon from 'd3-geo-polygon'; |
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import { PNG } from 'pngjs'; |
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import { PNG } from 'pngjs'; |
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import * as Png from './png'; |
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import * as Png from './png'; |
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export type Point = [number, number] |
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export type Bounds = [Point, Point] |
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import { ProjectBounds } from './common'; |
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import { getCountryGeometry } from './geo'; |
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type Projection = [string, ...unknown[]] |
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type Projection = [string, ...unknown[]] |
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@@ -15,7 +14,7 @@ type Rect = { |
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} |
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} |
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export type ProjectOptions = { |
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export type ProjectOptions = { |
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bounds: Bounds, |
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bounds: ProjectBounds, |
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wrapAround: boolean, |
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wrapAround: boolean, |
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outputSize?: Partial<Rect>, |
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outputSize?: Partial<Rect>, |
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outputPadding?: { |
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outputPadding?: { |
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@@ -47,7 +46,7 @@ const getProjectionFunction = (projectionFunctionName: string): GeoProjectionFac |
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throw new Error(`Unknown projection: ${properProjectionName}`); |
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throw new Error(`Unknown projection: ${properProjectionName}`); |
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}; |
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}; |
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const buildProjection = (projection: Projection) => { |
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const loadProjection = (projection: Projection) => { |
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const [projectionName, ...projectionArgs] = projection; |
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const [projectionName, ...projectionArgs] = projection; |
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// eslint-disable-next-line @typescript-eslint/no-unsafe-assignment |
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// eslint-disable-next-line @typescript-eslint/no-unsafe-assignment |
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const projectionFunction = getProjectionFunction(`${geoProjectionNamePrefix}${projectionName}`); |
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const projectionFunction = getProjectionFunction(`${geoProjectionNamePrefix}${projectionName}`); |
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@@ -55,45 +54,42 @@ const buildProjection = (projection: Projection) => { |
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return projectionFunction(projectionArgs) as d3geo.GeoProjection; |
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return projectionFunction(projectionArgs) as d3geo.GeoProjection; |
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}; |
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}; |
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const getCenter = (bounds: Bounds): Point => { |
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const [nw, se] = bounds; |
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const [nwLng, nwLat] = nw; |
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const [seLng, seLat] = se; |
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let seLngNorm = seLng; |
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const getMidpoint = (a: GeoJSON.Position, b: GeoJSON.Position) => [ |
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(a[0] + b[0]) / 2, |
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(a[1] + b[1]) / 2, |
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]; |
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while (seLngNorm < nwLng) { |
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seLngNorm += 360; |
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const getCentroid = (boundsRaw: d3geo.GeoGeometryObjects): GeoJSON.Position => { |
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if (boundsRaw.type === 'Polygon') { |
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return boundsRaw.coordinates[0].reduce(getMidpoint); |
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} |
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} |
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return [ |
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((((nwLng + 180) + (seLngNorm + 180)) / 2) % 360) - 180, |
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(nwLat + seLat) / 2, |
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]; |
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if (boundsRaw.type === 'MultiPolygon') { |
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return boundsRaw.coordinates |
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.map((polygon) => polygon[0].reduce(getMidpoint)) |
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.reduce(getMidpoint); |
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} |
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throw new Error(`Invalid type: ${boundsRaw.type}`); |
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}; |
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}; |
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const transformGeoProjection = ( |
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geoProjection: d3geo.GeoProjection, |
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const buildGeoProjection = ( |
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projection: Projection, |
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boundsGeoJson: d3geo.GeoGeometryObjects, |
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options: ProjectOptions, |
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options: ProjectOptions, |
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inputWidth: number, |
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inputWidth: number, |
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) => { |
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) => { |
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const center = getCenter(options.bounds); |
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const geoProjection = loadProjection(projection); |
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const center2 = d3geo.geoCentroid(boundsGeoJson); // why is d3geo's centroid different than our simple centroid function? |
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const center = getCentroid(boundsGeoJson); |
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console.log(center, center2); |
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const transformedGeoProjection = geoProjection |
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const transformedGeoProjection = geoProjection |
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.reflectX(false) |
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.reflectX(false) |
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.reflectY(false) |
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.reflectY(false) |
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.rotate([-center[0], -center[1]]); |
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.rotate([-center[0], -center[1]]); |
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const boundsGeoJson: GeoJSON.Polygon = { |
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type: 'Polygon', |
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coordinates: [ |
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[ |
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[options.bounds[0][0], options.bounds[0][1]], |
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[options.bounds[1][0], options.bounds[0][1]], |
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[options.bounds[1][0], options.bounds[1][1]], |
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[options.bounds[0][0], options.bounds[1][1]], |
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], |
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], |
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}; |
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// fixme: fitX() methods don't modify scale, only the dimensions? |
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if (typeof options.outputSize?.width === 'number') { |
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if (typeof options.outputSize?.width === 'number') { |
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if (typeof options.outputSize.height === 'number') { |
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if (typeof options.outputSize.height === 'number') { |
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const paddingX = options.outputPadding?.x ?? 0; |
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const paddingX = options.outputPadding?.x ?? 0; |
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@@ -121,108 +117,123 @@ const transformGeoProjection = ( |
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return transformedGeoProjection.fitWidth(inputWidth, boundsGeoJson); |
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return transformedGeoProjection.fitWidth(inputWidth, boundsGeoJson); |
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}; |
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}; |
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const computeLatitudeSensitiveProjectionVerticalBounds = ( |
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const computeOutputBounds = ( |
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transformedGeoProjection: d3geo.GeoProjection, |
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transformedGeoProjection: d3geo.GeoProjection, |
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bounds: Bounds, |
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outputWidthRaw: number, |
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_projectionName: string, |
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bounds: d3geo.GeoGeometryObjects, |
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) => { |
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) => { |
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// web mercator clipping |
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// const maxAbsLatitude |
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// = ((2 * Math.atan(Math.E ** Math.PI) - (Math.PI / 2)) / (Math.PI * 2)) * 360; |
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const maxAbsLatitude = 85.0511287798066; |
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const adjustedNwBoundsRaw = transformedGeoProjection([ |
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bounds[0][0], |
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Math.min(bounds[0][1], maxAbsLatitude), |
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]); |
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const adjustedSeBoundsRaw = transformedGeoProjection([ |
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bounds[1][0], |
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Math.max(bounds[1][1], -maxAbsLatitude), |
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]); |
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if (!(adjustedNwBoundsRaw && adjustedSeBoundsRaw)) { |
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return null; |
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} |
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const path = d3geo.geoPath(transformedGeoProjection); |
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return [ |
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Math.round(outputWidthRaw), |
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Math.round(adjustedSeBoundsRaw[1] - adjustedNwBoundsRaw[1]), |
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]; |
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}; |
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const computeLongitudeSensitiveProjectionHorizontalBounds = ( |
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transformedGeoProjection: d3geo.GeoProjection, |
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bounds: Bounds, |
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outputHeightRaw: number, |
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) => { |
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const adjustedWBoundsRaw = transformedGeoProjection([ |
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bounds[0][0], |
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(bounds[0][1] + bounds[1][1]) / 2, |
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]); |
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const adjustedEBoundsRaw = transformedGeoProjection([ |
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bounds[1][0], |
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(bounds[0][1] + bounds[1][1]) / 2, |
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]); |
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if (!(adjustedWBoundsRaw && adjustedEBoundsRaw)) { |
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return null; |
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} |
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const bbox = path.bounds(bounds); |
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// console.log(bbox); |
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return [ |
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return [ |
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Math.round(adjustedEBoundsRaw[0] - adjustedWBoundsRaw[0]), |
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Math.round(outputHeightRaw), |
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Math.round(Math.abs(bbox[1][0] - bbox[0][0])), |
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Math.round(Math.abs(bbox[1][1] - bbox[0][1])), |
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]; |
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]; |
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}; |
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}; |
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const computeOutputBounds = ( |
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transformedGeoProjection: d3geo.GeoProjection, |
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projectionName: string, |
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bounds: Bounds, |
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outputSize?: Partial<Rect>, |
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) => { |
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// TODO: what would it be for polygonal projections? |
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if ( |
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typeof outputSize?.width === 'number' |
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&& typeof outputSize.height === 'number' |
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) { |
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return [ |
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outputSize.width, |
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outputSize.height, |
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]; |
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// const computeOutputBounds = ( |
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// transformedGeoProjection: d3geo.GeoProjection, |
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// projectionName: string, |
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// bounds: d3geo.GeoGeometryObjects, |
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// outputSize?: Partial<Rect>, |
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// ) => { |
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// // TODO: what would it be for polygonal projections? |
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// |
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// if ( |
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// typeof outputSize?.width === 'number' |
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// && typeof outputSize.height === 'number' |
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// ) { |
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// return [ |
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// outputSize.width, |
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// outputSize.height, |
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// ]; |
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// } |
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// |
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// const path = d3.geoPath(transformedGeoProjection); |
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// |
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// path.bounds(bounds) |
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// // TODO better way to compute width and height directly from d3? |
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// |
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// let extremeProjectedBoundsRaw: Bounds | null | undefined; |
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// if (bounds.type === 'Polygon') { |
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// extremeProjectedBoundsRaw = bounds.coordinates[0].reduce( |
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// (theBounds, point) => { |
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// const projected = transformedGeoProjection(point as [number, number]); |
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// |
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// if (projected === null) { |
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// return null; |
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// } |
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// |
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// if (theBounds === null) { |
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// return [ |
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// projected, |
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// projected, |
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// ]; |
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// } |
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// |
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// return [ |
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// [ |
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// Math.min(theBounds[0][0], projected[0]), |
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// Math.max(theBounds[0][1], projected[1]), |
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// ], |
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// [ |
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// Math.max(theBounds[1][0], projected[0]), |
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// Math.min(theBounds[1][1], projected[1]), |
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// ], |
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// ]; |
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// }, |
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// null as unknown as (GeoJSON.Position[] | null), |
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// ); |
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// } |
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// |
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// if (!extremeProjectedBoundsRaw) { |
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// return null; |
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// } |
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// |
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// const [nwBoundsRaw, seBoundsRaw] = extremeProjectedBoundsRaw; |
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// const outputWidthRaw = seBoundsRaw[0] - nwBoundsRaw[0]; |
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// const outputHeightRaw = seBoundsRaw[1] - nwBoundsRaw[1]; |
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// |
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// // switch (projectionName) { |
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// // case 'Mercator': |
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// // return computeLatitudeSensitiveProjectionVerticalBounds( |
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// // transformedGeoProjection, |
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// // bounds, |
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// // outputWidthRaw, |
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// // ); |
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// // case 'Robinson': |
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// // case 'Sinusoidal': |
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// // return computeLongitudeSensitiveProjectionHorizontalBounds( |
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// // transformedGeoProjection, |
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// // bounds, |
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// // outputHeightRaw, |
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// // ); |
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// // default: |
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// // break; |
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// // } |
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// |
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// return [ |
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// Math.round(outputWidthRaw), |
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// Math.round(outputHeightRaw), |
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// ]; |
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// }; |
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const determineGeoJsonBounds = async (bounds: ProjectBounds): Promise<d3geo.GeoGeometryObjects> => { |
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if (bounds.type === 'country') { |
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const countryGeometry = await getCountryGeometry( |
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bounds.value, |
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{ mergeBoundingBoxes: true }, |
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); |
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return countryGeometry.geometry; |
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} |
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} |
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const nwBoundsRaw = transformedGeoProjection(bounds[0]); |
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const seBoundsRaw = transformedGeoProjection(bounds[1]); |
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if (!(nwBoundsRaw && seBoundsRaw)) { |
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return null; |
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if (bounds.type === 'geojson') { |
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return bounds.value; |
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} |
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} |
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const outputWidthRaw = seBoundsRaw[0] - nwBoundsRaw[0]; |
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const outputHeightRaw = seBoundsRaw[1] - nwBoundsRaw[1]; |
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switch (projectionName) { |
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case 'Mercator': |
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return computeLatitudeSensitiveProjectionVerticalBounds( |
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transformedGeoProjection, |
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bounds, |
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outputWidthRaw, |
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); |
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case 'Robinson': |
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case 'Sinusoidal': |
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return computeLongitudeSensitiveProjectionHorizontalBounds( |
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transformedGeoProjection, |
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bounds, |
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outputHeightRaw, |
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); |
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default: |
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break; |
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} |
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return [ |
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Math.round(outputWidthRaw), |
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Math.round(outputHeightRaw), |
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]; |
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throw new Error(`Invalid bounds type: ${(bounds as Record<string, string>).type}`); |
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}; |
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}; |
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export const project = async ( |
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export const project = async ( |
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@@ -230,15 +241,27 @@ export const project = async ( |
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projection: Projection, |
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projection: Projection, |
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options = { |
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options = { |
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wrapAround: false, |
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wrapAround: false, |
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bounds: [[-180, 90], [180, -90]], |
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bounds: { |
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type: 'geojson', |
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value: { |
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type: 'Sphere', |
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}, |
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}, |
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outputSize: undefined, |
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outputSize: undefined, |
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} as ProjectOptions, |
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} as ProjectOptions, |
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) => { |
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) => { |
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console.log(options); |
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const inputPng = await Png.load(pngInput); |
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const inputPng = await Png.load(pngInput); |
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const geoProjection = buildProjection(projection); |
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const [projectionName] = projection; |
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const theBounds = await determineGeoJsonBounds(options.bounds); |
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const transformedGeoProjection = transformGeoProjection(geoProjection, options, inputPng.width); |
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const transformedGeoProjection = buildGeoProjection( |
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projection, |
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theBounds, |
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options, |
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inputPng.width, |
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); |
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const [projectionName] = projection; |
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if (!transformedGeoProjection.invert) { |
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if (!transformedGeoProjection.invert) { |
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throw new Error(`No invert() function for projection "${projectionName}"`); |
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throw new Error(`No invert() function for projection "${projectionName}"`); |
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} |
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} |
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@@ -246,8 +269,7 @@ export const project = async ( |
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const outputBounds = computeOutputBounds( |
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const outputBounds = computeOutputBounds( |
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transformedGeoProjection, |
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transformedGeoProjection, |
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projectionName, |
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projectionName, |
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options.bounds, |
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options.outputSize, |
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theBounds, |
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); |
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); |
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if (!outputBounds) { |
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if (!outputBounds) { |
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@@ -272,24 +294,38 @@ export const project = async ( |
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for (let x = 0; x < outputWidth; x += 1) { |
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for (let x = 0; x < outputWidth; x += 1) { |
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const projected = transformedGeoProjection.invert([x, y]); |
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const projected = transformedGeoProjection.invert([x, y]); |
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if (projected) { |
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if (projected) { |
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const reversed = transformedGeoProjection(projected); |
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if (reversed) { |
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const isSamePoint = ( |
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Math.abs(reversed[0] - x) < 0.5 |
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&& Math.abs(reversed[1] - y) < 0.5 |
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); |
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if (isSamePoint) { |
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const [lambda, phi] = projected; |
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if (!(lambda > 180 || lambda < -180 || phi > 90 || phi < -90)) { |
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if (options.wrapAround) { |
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const [lambda, phi] = projected; |
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if (!(lambda > 180 || lambda < -180 || phi > 90 || phi < -90)) { |
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// eslint-disable-next-line no-bitwise |
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const q = (((90 - phi) / 180) * inputPng.height | 0) * inputPng.width |
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// eslint-disable-next-line no-bitwise |
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// eslint-disable-next-line no-bitwise |
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const q = (((90 - phi) / 180) * inputPng.height | 0) * inputPng.width |
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+ (((180 + lambda) / 360) * inputPng.width | 0) << 2; |
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outputData[i] = inputData[q]; |
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outputData[i + 1] = inputData[q + 1]; |
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outputData[i + 2] = inputData[q + 2]; |
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outputData[i + 3] = inputData[q + 3]; |
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} |
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} else { |
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const reversed = transformedGeoProjection(projected); |
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if (reversed) { |
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const isSamePoint = ( |
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Math.abs(reversed[0] - x) < 0.5 |
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&& Math.abs(reversed[1] - y) < 0.5 |
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); |
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if (isSamePoint) { |
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const [lambda, phi] = projected; |
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if (!(lambda > 180 || lambda < -180 || phi > 90 || phi < -90)) { |
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// eslint-disable-next-line no-bitwise |
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// eslint-disable-next-line no-bitwise |
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+ (((180 + lambda) / 360) * inputPng.width | 0) << 2; |
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outputData[i] = inputData[q]; |
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outputData[i + 1] = inputData[q + 1]; |
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outputData[i + 2] = inputData[q + 2]; |
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outputData[i + 3] = inputData[q + 3]; |
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const q = (((90 - phi) / 180) * inputPng.height | 0) * inputPng.width |
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// eslint-disable-next-line no-bitwise |
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+ (((180 + lambda) / 360) * inputPng.width | 0) << 2; |
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outputData[i] = inputData[q]; |
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outputData[i + 1] = inputData[q + 1]; |
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outputData[i + 2] = inputData[q + 2]; |
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outputData[i + 3] = inputData[q + 3]; |
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} |
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} |
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} |
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} |
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} |
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} |
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} |
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