"use strict"; const TypoGeom = require("typo-geom"); const Point = require("../../support/point"); const CurveUtil = require("../../support/curve-util"); module.exports = finalizeGlyphs; function finalizeGlyphs(para, glyphStore) { suppressNaN(glyphStore); const skew = Math.tan(((para.slopeAngle || 0) / 180) * Math.PI); regulateGlyphStore(skew, glyphStore); return glyphStore; } /////////////////////////////////////////////////////////////////////////////////////////////////// function suppressNaN(glyphStore) { for (const g of glyphStore.glyphs()) { if (!g.contours) continue; for (let k = 0; k < g.contours.length; k++) { let contour = g.contours[k]; for (let z of contour) { if (!isFinite(z.x)) z.x = 0; if (!isFinite(z.y)) z.y = 0; } } } } /////////////////////////////////////////////////////////////////////////////////////////////////// function regulateGlyphStore(skew, glyphStore) { for (const g of glyphStore.glyphs()) { if (!g.semanticInclusions || !g.contours) continue; if (g.isPureComposite()) regulateCompositeGlyph(glyphStore, g); } for (const g of glyphStore.glyphs()) regulateSimpleGlyph(g, skew); } /////////////////////////////////////////////////////////////////////////////////////////////////// function regulateCompositeGlyph(glyphStore, g) { const references = []; for (const sr of g.semanticInclusions) { const gn = glyphStore.queryNameOf(sr.glyph); if (!gn || sr.glyph.autoRefPriority < 0) return; references.push({ glyph: gn, x: sr.x, y: sr.y }); } g.semanticInclusions = []; g.contours = []; g.references = references; } function regulateSimpleGlyph(g, skew) { if (!g.contours || !g.contours.length) return; for (const contour of g.contours) for (const z of contour) z.x -= z.y * skew; g.contours = simplifyContours(g.contours); for (const contour of g.contours) for (const z of contour) z.x += z.y * skew; } /////////////////////////////////////////////////////////////////////////////////////////////////// function simplifyContours(source) { const sink = new FairizedShapeSink(); TypoGeom.ShapeConv.transferGenericShape( TypoGeom.Fairize.fairizeBezierShape( TypoGeom.Boolean.removeOverlap( CurveUtil.convertShapeToArcs(source), TypoGeom.Boolean.PolyFillType.pftNonZero, CurveUtil.BOOLE_RESOLUTION ) ), sink, CurveUtil.GEOMETRY_PRECISION ); return sink.contours; } class FairizedShapeSink { constructor() { this.contours = []; this.lastContour = []; } beginShape() {} endShape() { if (this.lastContour.length > 2) { const zFirst = this.lastContour[0], zLast = this.lastContour[this.lastContour.length - 1]; if (zFirst.on && zLast.on && zFirst.x === zLast.x && zFirst.y === zLast.y) { this.lastContour.pop(); } this.contours.push(this.lastContour); } this.lastContour = []; } moveTo(x, y) { this.endShape(); this.lineTo(x, y); } lineTo(x, y) { const z = Point.cornerFromXY(x, y).round(CurveUtil.RECIP_GEOMETRY_PRECISION); while (this.lastContour.length >= 2) { const a = this.lastContour[this.lastContour.length - 2], b = this.lastContour[this.lastContour.length - 1]; if (isLineExtend(a, b, z)) { this.lastContour.pop(); } else { break; } } this.lastContour.push(z); } arcTo(arc, x, y) { const offPoints = TypoGeom.Quadify.auto(arc, 1, 16); if (offPoints) { for (const z of offPoints) this.lastContour.push(Point.offFrom(z).round(CurveUtil.RECIP_GEOMETRY_PRECISION)); } this.lineTo(x, y); } } function isLineExtend(a, b, c) { return ( a.on && c.on && ((aligned(a.x, b.x, c.x) && between(a.y, b.y, c.y)) || (aligned(a.y, b.y, c.y) && between(a.x, b.x, c.x))) ); } function geometryPrecisionEqual(a, b) { return ( Math.round(a * CurveUtil.RECIP_GEOMETRY_PRECISION) === Math.round(b * CurveUtil.RECIP_GEOMETRY_PRECISION) ); } function aligned(a, b, c) { return geometryPrecisionEqual(a, b) && geometryPrecisionEqual(b, c); } function between(a, b, c) { return (a <= b && b <= c) || (a >= b && b >= c); }