mirror of
https://github.com/Azgaar/Fantasy-Map-Generator.git
synced 2025-12-16 17:31:24 +01:00
05de284e02
* feat: render states - use global fn * feat: render states - separate pole detection from layer render * feat: render provinces * chore: unify drawFillWithGap * refactor: drawIce * refactor: drawBorders * refactor: drawHeightmap * refactor: drawTemperature * refactor: drawBiomes * refactor: drawPrec * refactor: drawPrecipitation * refactor: drawPopulation * refactor: drawCells * refactor: geColor * refactor: drawMarkers * refactor: drawScaleBar * refactor: drawScaleBar * refactor: drawMilitary * refactor: pump version to 1.104.00 * refactor: pump version to 1.104.00 * refactor: drawCoastline and createDefaultRuler * refactor: drawCoastline * refactor: Features module start * refactor: features - define distance fields * feat: drawFeatures * feat: drawIce don't hide * feat: detect coastline - fix issue with border feature * feat: separate labels rendering from generation process * feat: auto-update and restore layers * refactor - change layers * refactor - sort layers * fix: regenerate burgs to re-render layers * fix: getColor is not defined * fix: burgs overview - don't auto-show labels on hover * fix: redraw population on change * refactor: improve tooltip logic for burg labels and icons * chore: pump version to 1.104.0 * fefactor: edit coastline and lake * fix: minot fixes * fix: submap --------- Co-authored-by: Azgaar <azgaar.fmg@yandex.com>
116 lines
3.8 KiB
JavaScript
116 lines
3.8 KiB
JavaScript
"use strict";
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window.Lakes = (function () {
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const LAKE_ELEVATION_DELTA = 0.1;
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// check if lake can be potentially open (not in deep depression)
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const detectCloseLakes = h => {
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const {cells} = pack;
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const ELEVATION_LIMIT = +byId("lakeElevationLimitOutput").value;
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pack.features.forEach(feature => {
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if (feature.type !== "lake") return;
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delete feature.closed;
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const MAX_ELEVATION = feature.height + ELEVATION_LIMIT;
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if (MAX_ELEVATION > 99) {
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feature.closed = false;
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return;
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}
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let isDeep = true;
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const lowestShorelineCell = feature.shoreline.sort((a, b) => h[a] - h[b])[0];
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const queue = [lowestShorelineCell];
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const checked = [];
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checked[lowestShorelineCell] = true;
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while (queue.length && isDeep) {
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const cellId = queue.pop();
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for (const neibCellId of cells.c[cellId]) {
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if (checked[neibCellId]) continue;
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if (h[neibCellId] >= MAX_ELEVATION) continue;
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if (h[neibCellId] < 20) {
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const nFeature = pack.features[cells.f[neibCellId]];
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if (nFeature.type === "ocean" || feature.height > nFeature.height) isDeep = false;
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}
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checked[neibCellId] = true;
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queue.push(neibCellId);
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}
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}
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feature.closed = isDeep;
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});
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};
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const defineClimateData = function (heights) {
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const {cells, features} = pack;
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const lakeOutCells = new Uint16Array(cells.i.length);
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features.forEach(feature => {
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if (feature.type !== "lake") return;
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feature.flux = getFlux(feature);
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feature.temp = getLakeTemp(feature);
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feature.evaporation = getLakeEvaporation(feature);
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if (feature.closed) return; // no outlet for lakes in depressed areas
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feature.outCell = getLowestShoreCell(feature);
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lakeOutCells[feature.outCell] = feature.i;
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});
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return lakeOutCells;
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function getFlux(lake) {
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return lake.shoreline.reduce((acc, c) => acc + grid.cells.prec[cells.g[c]], 0);
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}
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function getLakeTemp(lake) {
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if (lake.cells < 6) return grid.cells.temp[cells.g[lake.firstCell]];
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return rn(d3.mean(lake.shoreline.map(c => grid.cells.temp[cells.g[c]])), 1);
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}
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function getLakeEvaporation(lake) {
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const height = (lake.height - 18) ** heightExponentInput.value; // height in meters
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const evaporation = ((700 * (lake.temp + 0.006 * height)) / 50 + 75) / (80 - lake.temp); // based on Penman formula, [1-11]
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return rn(evaporation * lake.cells);
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}
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function getLowestShoreCell(lake) {
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return lake.shoreline.sort((a, b) => heights[a] - heights[b])[0];
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}
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};
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const cleanupLakeData = function () {
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for (const feature of pack.features) {
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if (feature.type !== "lake") continue;
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delete feature.river;
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delete feature.enteringFlux;
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delete feature.outCell;
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delete feature.closed;
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feature.height = rn(feature.height, 3);
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const inlets = feature.inlets?.filter(r => pack.rivers.find(river => river.i === r));
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if (!inlets || !inlets.length) delete feature.inlets;
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else feature.inlets = inlets;
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const outlet = feature.outlet && pack.rivers.find(river => river.i === feature.outlet);
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if (!outlet) delete feature.outlet;
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}
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};
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const getHeight = function (feature) {
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const heights = pack.cells.h;
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const minShoreHeight = d3.min(feature.shoreline.map(cellId => heights[cellId])) || 20;
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return rn(minShoreHeight - LAKE_ELEVATION_DELTA, 2);
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};
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const getName = function (feature) {
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const landCell = pack.cells.c[feature.firstCell].find(c => pack.cells.h[c] >= 20);
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const culture = pack.cells.culture[landCell];
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return Names.getCulture(culture);
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};
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return {defineClimateData, cleanupLakeData, detectCloseLakes, getHeight, getName};
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})();
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