import { Data, Location, Polygon, CollisionClass } from "./Components"; import { Id, Join } from "./Data"; import { TfPolygon } from "./Location"; interface Candidate { id: Id; class: CollisionClass; poly: Polygon; }; function hash(minX: number, minY: number, maxX: number, maxY: number, cellSize: number): string[] { let minXCell = Math.floor(minX/cellSize); let minYCell = Math.floor(minY/cellSize); let maxXCell = Math.floor(maxX/cellSize); let maxYCell = Math.floor(maxY/cellSize); const results = []; for(let xCell = minXCell; xCell <= maxXCell; xCell++) { for(let yCell = minYCell; yCell <= maxYCell; yCell++) { results.push(`${xCell},${yCell}`); } } return results; } function hashPolygon({points}: Polygon, cellSize: number): string[] { let minX = 1/0; let minY = 1/0; let maxX = -1/0; let maxY = -1/0; for(let i = 0; i < points.length; i += 2) { minX = Math.min(minX, points[i]); minY = Math.min(minY, points[i+1]); maxX = Math.max(maxX, points[i]); maxY = Math.max(maxY, points[i+1]); } return hash(minX, minY, maxX, maxY, cellSize); } function projectPolygonToAxis(axisX: number, axisY: number, points: number[]): [number, number] { let min = 1/0; let max = -1/0; for(let i = 0; i < points.length; i += 2) { // dot product doesn't need normalizing since we only compare magnitudes const value = (axisX * points[i]) + (axisY * points[i+1]); min = Math.min(min, value); max = Math.max(max, value); } return [min, max]; } /** * Return true if the axis contains a gap between the two polygons */ function testPolygonSeparatingAxis(axisX: number, axisY: number, aPoints: number[], bPoints: number[]): boolean { const [minA, maxA] = projectPolygonToAxis(axisX, axisY, aPoints); const [minB, maxB] = projectPolygonToAxis(axisX, axisY, bPoints); return !((minA < maxB) && (minB < maxA)); } function halfCollideConvexPolygons(aPoints: number[], bPoints: number[]): boolean { for(let i = 2; i < aPoints.length; i += 2) { const dx = aPoints[i] - aPoints[i-2]; const dy = aPoints[i+1] - aPoints[i-1]; if(testPolygonSeparatingAxis(-dy, dx, aPoints, bPoints)) { return false; } } const dx = aPoints[0] - aPoints[aPoints.length-2]; const dy = aPoints[1] - aPoints[aPoints.length-1]; if(testPolygonSeparatingAxis(-dy, dx, aPoints, bPoints)) { return false; } // no gaps found in this half return true; } function collideConvexPolygons({points: aPoints}: Polygon, {points: bPoints}: Polygon): boolean { return halfCollideConvexPolygons(aPoints, bPoints) && halfCollideConvexPolygons(bPoints, aPoints); } export function FindCollisions(data: Data, cellSize: number, callback: (className: string, sourceId: Id, targetId: Id) => void) { const spatialMap: Record = {}; Join(data, "collisionTargetClass", "location", "bounds", "id").map( ([targetClass, location, poly, id]) => { const workingPoly = TfPolygon(poly, location); const candidate = { id, class: targetClass, poly: workingPoly }; hashPolygon(workingPoly, cellSize).forEach(key => { if(!spatialMap[key]) spatialMap[key] = []; spatialMap[key].push(candidate); }); } ); Join(data, "collisionSourceClass", "location", "bounds", "id").map( ([sourceClass, location, poly, id]) => { const workingPoly = TfPolygon(poly, location); const candidates: Record = {}; hashPolygon(workingPoly, cellSize).forEach(key => { if(spatialMap[key]) { for(const candidate of spatialMap[key]) { // dedup targets to test candidates[candidate.id[0]] = candidate; } } }); for(const bareId in candidates) { const target = candidates[bareId]; if(collideConvexPolygons(workingPoly, target.poly)) { const className = `${sourceClass.name}>${target.class.name}`; callback(className, id, target.id); } } } ); }