package G; import a.AbstractC0105a; import android.graphics.Path; import android.util.Log; import com.google.android.gms.maps.model.BitmapDescriptorFactory; import com.google.firebase.remoteconfig.FirebaseRemoteConfig; /* loaded from: classes.dex */ public final class f { /* renamed from: a, reason: collision with root package name */ public char f563a; /* renamed from: b, reason: collision with root package name */ public final float[] f564b; public f(char c4, float[] fArr) { this.f563a = c4; this.f564b = fArr; } public static void a(Path path, float f2, float f4, float f5, float f6, float f7, float f8, float f9, boolean z3, boolean z4) { double d4; double d5; double radians = Math.toRadians(f9); double cos = Math.cos(radians); double sin = Math.sin(radians); double d6 = f2; double d7 = f4; double d8 = f7; double d9 = ((d7 * sin) + (d6 * cos)) / d8; double d10 = f8; double d11 = ((d7 * cos) + ((-f2) * sin)) / d10; double d12 = f6; double d13 = ((d12 * sin) + (f5 * cos)) / d8; double d14 = ((d12 * cos) + ((-f5) * sin)) / d10; double d15 = d9 - d13; double d16 = d11 - d14; double d17 = (d9 + d13) / 2.0d; double d18 = (d11 + d14) / 2.0d; double d19 = (d16 * d16) + (d15 * d15); if (d19 == FirebaseRemoteConfig.DEFAULT_VALUE_FOR_DOUBLE) { Log.w("PathParser", " Points are coincident"); return; } double d20 = (1.0d / d19) - 0.25d; if (d20 < FirebaseRemoteConfig.DEFAULT_VALUE_FOR_DOUBLE) { Log.w("PathParser", "Points are too far apart " + d19); float sqrt = (float) (Math.sqrt(d19) / 1.99999d); a(path, f2, f4, f5, f6, f7 * sqrt, sqrt * f8, f9, z3, z4); return; } double sqrt2 = Math.sqrt(d20); double d21 = sqrt2 * d15; double d22 = sqrt2 * d16; if (z3 == z4) { d4 = d17 - d22; d5 = d18 + d21; } else { d4 = d17 + d22; d5 = d18 - d21; } double atan2 = Math.atan2(d11 - d5, d9 - d4); double atan22 = Math.atan2(d14 - d5, d13 - d4) - atan2; if (z4 != (atan22 >= FirebaseRemoteConfig.DEFAULT_VALUE_FOR_DOUBLE)) { atan22 = atan22 > FirebaseRemoteConfig.DEFAULT_VALUE_FOR_DOUBLE ? atan22 - 6.283185307179586d : atan22 + 6.283185307179586d; } double d23 = d4 * d8; double d24 = d5 * d10; double d25 = (d23 * cos) - (d24 * sin); double d26 = (d24 * cos) + (d23 * sin); int ceil = (int) Math.ceil(Math.abs((atan22 * 4.0d) / 3.141592653589793d)); double cos2 = Math.cos(radians); double sin2 = Math.sin(radians); double cos3 = Math.cos(atan2); double sin3 = Math.sin(atan2); double d27 = -d8; double d28 = d27 * cos2; double d29 = d10 * sin2; double d30 = (d28 * sin3) - (d29 * cos3); double d31 = d27 * sin2; double d32 = d10 * cos2; double d33 = atan22 / ceil; double d34 = (cos3 * d32) + (sin3 * d31); double d35 = d6; double d36 = d7; int i = 0; double d37 = atan2; while (i < ceil) { double d38 = d37 + d33; double sin4 = Math.sin(d38); double cos4 = Math.cos(d38); int i4 = ceil; double d39 = (((d8 * cos2) * cos4) + d25) - (d29 * sin4); double d40 = (d32 * sin4) + (d8 * sin2 * cos4) + d26; double d41 = (d28 * sin4) - (d29 * cos4); double d42 = (cos4 * d32) + (sin4 * d31); double d43 = d38 - d37; double tan = Math.tan(d43 / 2.0d); double sqrt3 = ((Math.sqrt(((tan * 3.0d) * tan) + 4.0d) - 1.0d) * Math.sin(d43)) / 3.0d; path.rLineTo(BitmapDescriptorFactory.HUE_RED, BitmapDescriptorFactory.HUE_RED); path.cubicTo((float) ((d30 * sqrt3) + d35), (float) ((d34 * sqrt3) + d36), (float) (d39 - (sqrt3 * d41)), (float) (d40 - (sqrt3 * d42)), (float) d39, (float) d40); i++; d36 = d40; cos2 = cos2; d31 = d31; d37 = d38; d34 = d42; d35 = d39; ceil = i4; d30 = d41; d33 = d33; } } /* JADX WARN: Multi-variable type inference failed */ public static void b(f[] fVarArr, Path path) { int i; int i4; f fVar; int i5; char c4; float f2; float f4; float f5; float f6; f fVar2; boolean z3; float f7; float f8; float f9; float f10; float f11; float f12; float f13; float f14; Path path2 = path; float[] fArr = new float[6]; int length = fVarArr.length; char c5 = 'm'; int i6 = 0; char c6 = 'm'; int i7 = 0; while (i7 < length) { f fVar3 = fVarArr[i7]; char c7 = fVar3.f563a; float f15 = fArr[i6]; float f16 = fArr[1]; float f17 = fArr[2]; float f18 = fArr[3]; float f19 = fArr[4]; float f20 = fArr[5]; switch (c7) { case 'A': case 'a': i = 7; break; case 'C': case 'c': i = 6; break; case 'H': case 'V': case 'h': case 'v': i = 1; break; case 'Q': case 'S': case 'q': case 's': i = 4; break; case 'Z': case 'z': path2.close(); path2.moveTo(f19, f20); f15 = f19; f17 = f15; f16 = f20; f18 = f16; break; } i = 2; float f21 = f16; float f22 = f19; float f23 = f20; float f24 = f15; int i8 = i6; while (true) { float[] fArr2 = fVar3.f564b; if (i8 < fArr2.length) { int i9 = i6; if (c7 == 'A') { i4 = i8; fVar = fVar3; float f25 = f24; float f26 = f21; i5 = i7; c4 = c7; int i10 = i4 + 5; int i11 = i4 + 6; a(path, f25, f26, fArr2[i10], fArr2[i11], fArr2[i4], fArr2[i4 + 1], fArr2[i4 + 2], fArr2[i4 + 3] != BitmapDescriptorFactory.HUE_RED ? 1 : i9, fArr2[i4 + 4] != BitmapDescriptorFactory.HUE_RED ? 1 : i9); f17 = fArr2[i10]; f2 = fArr2[i11]; f18 = f2; f4 = f17; } else if (c7 == 'C') { i4 = i8; i5 = i7; fVar = fVar3; c4 = c7; int i12 = i4 + 2; int i13 = i4 + 3; int i14 = i4 + 4; int i15 = i4 + 5; path2.cubicTo(fArr2[i4], fArr2[i4 + 1], fArr2[i12], fArr2[i13], fArr2[i14], fArr2[i15]); float f27 = fArr2[i14]; float f28 = fArr2[i15]; f17 = fArr2[i12]; f18 = fArr2[i13]; f2 = f28; f4 = f27; } else if (c7 != 'H') { if (c7 == 'Q') { i4 = i8; i5 = i7; fVar = fVar3; c4 = c7; int i16 = i4 + 1; int i17 = i4 + 2; int i18 = i4 + 3; path2.quadTo(fArr2[i4], fArr2[i16], fArr2[i17], fArr2[i18]); f5 = fArr2[i4]; float f29 = fArr2[i16]; f6 = fArr2[i17]; f18 = f29; f2 = fArr2[i18]; } else if (c7 == 'V') { i4 = i8; i5 = i7; fVar = fVar3; f4 = f24; c4 = c7; path2.lineTo(f4, fArr2[i4]); f2 = fArr2[i4]; } else if (c7 != 'a') { if (c7 == 'c') { i4 = i8; int i19 = i4 + 2; int i20 = i4 + 3; int i21 = i4 + 4; int i22 = i4 + 5; path2.rCubicTo(fArr2[i4], fArr2[i4 + 1], fArr2[i19], fArr2[i20], fArr2[i21], fArr2[i22]); float f30 = fArr2[i19] + f24; float f31 = f21 + fArr2[i20]; f24 += fArr2[i21]; f21 += fArr2[i22]; f17 = f30; f18 = f31; } else if (c7 != 'h') { if (c7 != 'q') { if (c7 != 'v') { if (c7 == 'L') { i4 = i8; int i23 = i4 + 1; path2.lineTo(fArr2[i4], fArr2[i23]); f4 = fArr2[i4]; f2 = fArr2[i23]; } else if (c7 == 'M') { i4 = i8; f4 = fArr2[i4]; f2 = fArr2[i4 + 1]; if (i4 > 0) { path2.lineTo(f4, f2); } else { path2.moveTo(f4, f2); f22 = f4; f23 = f2; } } else if (c7 == 'S') { i4 = i8; if (c6 == 'c' || c6 == 's' || c6 == 'C' || c6 == 'S') { f24 = (f24 * 2.0f) - f17; f21 = (f21 * 2.0f) - f18; } float f32 = f24; float f33 = f21; int i24 = i4 + 1; int i25 = i4 + 2; int i26 = i4 + 3; path2.cubicTo(f32, f33, fArr2[i4], fArr2[i24], fArr2[i25], fArr2[i26]); f5 = fArr2[i4]; float f34 = fArr2[i24]; f6 = fArr2[i25]; f18 = f34; f2 = fArr2[i26]; i5 = i7; fVar = fVar3; c4 = c7; } else if (c7 == 'T') { i4 = i8; if (c6 == 'q' || c6 == 't' || c6 == 'Q' || c6 == 'T') { f24 = (f24 * 2.0f) - f17; f21 = (f21 * 2.0f) - f18; } float f35 = f21; float f36 = fArr2[i4]; int i27 = i4 + 1; path2.quadTo(f24, f35, f36, fArr2[i27]); f18 = f35; f4 = fArr2[i4]; f2 = fArr2[i27]; i5 = i7; fVar = fVar3; f17 = f24; c4 = c7; } else if (c7 == 'l') { i4 = i8; int i28 = i4 + 1; path2.rLineTo(fArr2[i4], fArr2[i28]); f24 += fArr2[i4]; f10 = fArr2[i28]; } else if (c7 == c5) { i4 = i8; float f37 = fArr2[i4]; f24 += f37; float f38 = fArr2[i4 + 1]; f21 += f38; if (i4 > 0) { path2.rLineTo(f37, f38); } else { path2.rMoveTo(f37, f38); fVar = fVar3; f4 = f24; f22 = f4; f2 = f21; f23 = f2; i5 = i7; c4 = c7; } } else if (c7 == 's') { if (c6 == 'c' || c6 == 's' || c6 == 'C' || c6 == 'S') { f11 = f21 - f18; f12 = f24 - f17; } else { f12 = BitmapDescriptorFactory.HUE_RED; f11 = BitmapDescriptorFactory.HUE_RED; } int i29 = i8 + 1; int i30 = i8 + 2; int i31 = i8 + 3; i4 = i8; path2.rCubicTo(f12, f11, fArr2[i8], fArr2[i29], fArr2[i30], fArr2[i31]); f7 = fArr2[i4] + f24; f8 = f21 + fArr2[i29]; f24 += fArr2[i30]; f9 = fArr2[i31]; } else if (c7 != 't') { i4 = i8; } else { if (c6 == 'q' || c6 == 't' || c6 == 'Q' || c6 == 'T') { f13 = f24 - f17; f14 = f21 - f18; } else { f14 = BitmapDescriptorFactory.HUE_RED; f13 = BitmapDescriptorFactory.HUE_RED; } int i32 = i8 + 1; path2.rQuadTo(f13, f14, fArr2[i8], fArr2[i32]); float f39 = f13 + f24; float f40 = f21 + f14; float f41 = f24 + fArr2[i8]; f21 += fArr2[i32]; f18 = f40; i4 = i8; fVar = fVar3; f4 = f41; f17 = f39; f2 = f21; i5 = i7; c4 = c7; } i5 = i7; fVar = fVar3; c4 = c7; } else { i4 = i8; path2.rLineTo(BitmapDescriptorFactory.HUE_RED, fArr2[i4]); f10 = fArr2[i4]; } f21 += f10; } else { i4 = i8; int i33 = i4 + 1; int i34 = i4 + 2; int i35 = i4 + 3; path2.rQuadTo(fArr2[i4], fArr2[i33], fArr2[i34], fArr2[i35]); f7 = fArr2[i4] + f24; f8 = f21 + fArr2[i33]; f24 += fArr2[i34]; f9 = fArr2[i35]; } f21 += f9; f17 = f7; f18 = f8; } else { i4 = i8; path2.rLineTo(fArr2[i4], BitmapDescriptorFactory.HUE_RED); f24 += fArr2[i4]; } fVar = fVar3; f4 = f24; f2 = f21; i5 = i7; c4 = c7; } else { i4 = i8; int i36 = i4 + 5; float f42 = fArr2[i36] + f24; int i37 = i4 + 6; float f43 = fArr2[i37] + f21; float f44 = fArr2[i4]; float f45 = fArr2[i4 + 1]; float f46 = fArr2[i4 + 2]; if (fArr2[i4 + 3] != BitmapDescriptorFactory.HUE_RED) { fVar2 = fVar3; z3 = 1; } else { fVar2 = fVar3; z3 = i9; } fVar = fVar2; float f47 = f24; c4 = c7; float f48 = f21; i5 = i7; a(path, f47, f48, f42, f43, f44, f45, f46, z3, fArr2[i4 + 4] != BitmapDescriptorFactory.HUE_RED ? 1 : i9); f4 = f47 + fArr2[i36]; f2 = f48 + fArr2[i37]; f17 = f4; f18 = f2; } f17 = f5; f4 = f6; } else { i4 = i8; fVar = fVar3; c4 = c7; f2 = f21; i5 = i7; path2.lineTo(fArr2[i4], f2); f4 = fArr2[i4]; } c7 = c4; fVar3 = fVar; i7 = i5; i6 = i9; c5 = 'm'; f24 = f4; f21 = f2; c6 = c7; i8 = i4 + i; path2 = path; } } int i38 = i6; fArr[i38] = f24; fArr[1] = f21; fArr[2] = f17; fArr[3] = f18; fArr[4] = f22; fArr[5] = f23; c6 = fVar3.f563a; i7++; path2 = path; i6 = i38; c5 = 'm'; } } public f(f fVar) { this.f563a = fVar.f563a; float[] fArr = fVar.f564b; this.f564b = AbstractC0105a.n(fArr, fArr.length); } }