push .static contents

2024-02-10 22:38:35 +05:00 · 2024-02-10 22:38:35 +05:00 · 760f947c00
commit 760f947c00
parent bb479c9371
8 changed files with 482 additions and 1 deletions
--- a/.gitattributes
+++ b/.gitattributes
@ -0,0 +1,2 @@
 *.png filter=lfs diff=lfs merge=lfs -text
 *.gif filter=lfs diff=lfs merge=lfs -text
--- a/.gitignore
+++ b/.gitignore
@ -1,6 +1,9 @@
 **/__pycache__/*
 html/
-**/.*/
+./.*/
 [articles/**/.static/]
 articles/**/.dynamic/
 articles/**/.temp/
 **/*.jpg/
 **/*.png/
 **/*.upload-checksum
--- a/articles/2d-visibility/.static/Visibility2D.gd.txt
+++ b/articles/2d-visibility/.static/Visibility2D.gd.txt
@ -0,0 +1,178 @@
 extends Node
 class_name Visibility2D
 # Based on: https://www.redblobgames.com/articles/visibility/Visibility.hx
 # Limitations:
 # - Segments cant intersect each other, splitting is required for such cases.
 # todo: Make it extend plain object, handle lifetime manually.
 class EndPoint:
    var point: Vector2
    var begin: bool
    var segment: int
    var angle: float
    static func sort(p_a: EndPoint, p_b: EndPoint) -> bool:
        if p_a.angle > p_b.angle: return true
        elif p_a.angle < p_b.angle: return false
        elif not p_a.begin and p_b.begin: return true
        else: return false
 var _endpoints: Array # of EndPoint
 var _sorted_endpoints: Array # of EndPoint
 var _open: PoolIntArray # of Segment indices
 var center: Vector2
 var output: PoolVector2Array
 # todo: Ability to cache builder state for static geometry.
 class Builder:
    var target
    func view_point(p_point: Vector2) -> Builder:
        target.center = p_point
        return self
    # todo: Use it to cull out endpoints out of working region.
    func bounds(p_area: Rect2) -> Builder:
        target._add_segment(p_area.position, Vector2(p_area.end.x, p_area.position.y))
        target._add_segment(Vector2(p_area.end.x, p_area.position.y), p_area.end)
        target._add_segment(p_area.end, Vector2(p_area.position.x, p_area.end.y))
        target._add_segment(Vector2(p_area.position.x, p_area.end.y), p_area.position)
        return self
    func line(p_line: Line2D) -> Builder:
        for i in range(0, p_line.points.size() - 1):
            target._add_segment(p_line.position + p_line.points[i],
                p_line.position + p_line.points[i + 1])
        return self
    func polygon(p_polygon: Polygon2D) -> Builder:
        var points := p_polygon.polygon
        for i in range(0, points.size() - 1):
            target._add_segment(p_polygon.position + points[i],
                p_polygon.position + points[i + 1])
        target._add_segment(p_polygon.position + points[points.size() - 1],
            p_polygon.position + points[0])
        return self
    func occluder(p_object: Object) -> Builder:
        if p_object is Line2D:
            return line(p_object)
        elif p_object is Polygon2D:
            return polygon(p_object)
        else:
            push_error("Unknown occluder type")
            return self
    func finalize():
        target._finalize()
 func _add_segment(p_point0: Vector2, p_point1: Vector2):
    var point0 := EndPoint.new()
    var point1 := EndPoint.new()
    point0.segment = _endpoints.size()
    point1.segment = _endpoints.size()
    point0.point = p_point0
    point1.point = p_point1
    _endpoints.append(point0)
    _endpoints.append(point1)
 func init_builder() -> Builder:
    # todo: Reuse
    _endpoints.resize(0)
    var result := Builder.new()
    result.target = self
    return result
 func _finalize():
    # todo: Only needs to be done when endpoints or center is changed.
    for segment in range(0, _endpoints.size(), 2):
        var p1 := _endpoints[segment] as EndPoint
        var p2 := _endpoints[segment + 1] as EndPoint
        p1.angle = (p1.point - center).angle()
        p2.angle = (p2.point - center).angle()
        # todo: Simplify to one expression.
        var da := p2.angle - p1.angle
        if da <= PI: da += TAU
        if da > PI: da -= TAU
        p1.begin = da > 0.0
        p2.begin = not p1.begin
 func _is_segment_in_front(p_segment1: int, p_segment2: int) -> bool:
    var s1p1 := _endpoints[p_segment1].point as Vector2
    var s1p2 := _endpoints[p_segment1 + 1].point as Vector2
    var s2p1 := _endpoints[p_segment2].point as Vector2
    var s2p2 := _endpoints[p_segment2 + 1].point as Vector2
    # todo: Can we use something simpler than interpolation?
    var d := s1p2 - s1p1
    var p := s2p1.linear_interpolate(s2p2, 0.01)
    var a1 := (d.x * (p.y - s1p1.y) \
             - d.y * (p.x - s1p1.x)) < 0.0
    p = s2p2.linear_interpolate(s2p1, 0.01)
    var a2 := (d.x * (p.y - s1p1.y) \
             - d.y * (p.x - s1p1.x)) < 0.0
    var a3 := (d.x * (center.y - s1p1.y) \
             - d.y * (center.x - s1p1.x)) < 0.0
    if a1 == a2 and a2 == a3: return true
    d = s2p2 - s2p1
    p = s1p1.linear_interpolate(s1p2, 0.01)
    var b1 := (d.x * (p.y - s2p1.y) \
             - d.y * (p.x - s2p1.x)) < 0.0
    p = s1p2.linear_interpolate(s1p1, 0.01)
    var b2 := (d.x * (p.y - s2p1.y) \
             - d.y * (p.x - s2p1.x)) < 0.0
    var b3 := (d.x * (center.y - s2p1.y) \
             - d.y * (center.x - s2p1.x)) < 0.0
    return b1 == b2 and b2 != b3
 func sweep() -> PoolVector2Array:
    output.resize(0)
    # todo: Only duplicate and sort on change.
    _sorted_endpoints = _endpoints.duplicate()
    _sorted_endpoints.sort_custom(EndPoint, "sort")
    var start_angle := 0.0
    # todo: Inline passes.
    for n_pass in range(2):
        for p_idx in range(_sorted_endpoints.size() - 1, -1, -1):
            var p := _sorted_endpoints[p_idx] as EndPoint
            var old := -1 if _open.empty() else _open[0]
            if p.begin:
                var idx := 0
                while idx < _open.size() and _is_segment_in_front(p.segment, _open[idx]):
                    idx += 1
                # warning-ignore:return_value_discarded
                _open.insert(idx, p.segment)
            else:
                var idx := _open.rfind(p.segment)
                if idx != -1: _open.remove(idx)
                # todo: Second pass can assume that it will be found.
                # _open.remove(_open.rfind(p.segment))
            if old != (-1 if _open.empty() else _open[0]):
                if n_pass == 1:
                    # todo: Distance should be configurable.
                    var p3 := _endpoints[old].point as Vector2 if old != -1 else \
                        center + Vector2(cos(start_angle), sin(start_angle)) * 500.0
                    var t2 := Vector2(cos(p.angle), sin(p.angle))
                    var p4 := p3.direction_to(_endpoints[old + 1].point) if old != -1 else t2 
                    var l = Geometry.line_intersects_line_2d(p3, p4, center,
                        Vector2(cos(start_angle), sin(start_angle)))
                    if l != null: output.append(l)
                    l = Geometry.line_intersects_line_2d(p3, p4, center, t2)
                    if l != null: output.append(l)
                start_angle = p.angle
    _open.resize(0)
    return output
--- a/articles/2d-visibility/.static/example.gif
+++ b/articles/2d-visibility/.static/example.gif
--- a/articles/hand-opt-simplex-2d/.static/noise.png
+++ b/articles/hand-opt-simplex-2d/.static/noise.png
--- a/articles/incremental-delaunay/.static/incremental-delaunay.zig.txt
+++ b/articles/incremental-delaunay/.static/incremental-delaunay.zig.txt
@ -0,0 +1,286 @@
 //! Based on: https://www.cs.umd.edu/class/spring2020/cmsc754/Lects/lect13-delaun-alg.pdf
 //! Optimizations involved:
 //! - Cached neighbors for traversal.
 //! - Minimal memory footprint.
 //! - Cached circumferences.
 //! - No circumference calculations for new subdivisions, - circumferences of neighbors are used instead.
 //! - Lazy circumference calculation, as some places might not be neighboring new subdivisions.
 //! - Extensive use of vectorization.
 //! - Care given to linear access of memory.
 // todo: This method allows zero area triangles, we need to eliminate them.
 //       Points that lie on edges can be detected in pointRelation function by == 0 comparison.
 const std = @import("std");
 // Could be redefined as pleased, but i consider these to be most sensical for given implementation.
 pub const VertexComponent = f32;
 pub const Vertex = @Vector(2, VertexComponent);
 pub const Index = u15;
 pub const Area = GenericArea(VertexComponent);
 pub const Builder = struct {
    triangles: std.ArrayList(Triangle),
    vertices: std.ArrayList(Vertex),
    allocator: std.mem.Allocator,
    // todo: init with expected amount of points to preallocate beforehand.
    pub fn init(allocator: std.mem.Allocator, area: Area) !@This() {
        var triangles = try std.ArrayList(Triangle).initCapacity(allocator, 2);
        errdefer triangles.deinit();
        var vertices = try std.ArrayList(Vertex).initCapacity(allocator, 4);
        errdefer vertices.deinit();
        try vertices.ensureUnusedCapacity(4);
        try triangles.ensureUnusedCapacity(2);
        for (area.corners()) |corner|
            vertices.append(corner) catch unreachable;
        triangles.append(Triangle{
            .points = [3]Index{ 0, 2, 1 },
            .neighbors = [3]?Index{ null, 1, null },
        }) catch unreachable;
        triangles.append(Triangle{
            .points = [3]Index{ 3, 1, 2 },
            .neighbors = [3]?Index{ null, 0, null },
        }) catch unreachable;
        return .{
            .triangles = triangles,
            .vertices = vertices,
            .allocator = allocator,
        };
    }
    pub fn insertAtRandom(self: *@This(), point: Vertex, generator: std.rand.Random) !void {
        // Find a triangle the point lies starting from some random triangle.
        var abc_index: Index = @intCast(generator.int(Index) % self.triangles.items.len);
        var abc = &self.triangles.items[abc_index];
        var relation = abc.pointRelation(self.vertices, point);
        while (relation != .contained) {
            abc_index = abc.neighbors[@intCast(@intFromEnum(relation))].?;
            abc = &self.triangles.items[abc_index];
            relation = abc.pointRelation(self.vertices, point);
        }
        // Allocate two new triangles, as well as new vertex.
        const new_vertex_index: Index = @intCast(self.vertices.items.len);
        try self.vertices.append(point);
        const pbc_index: Index = @intCast(self.triangles.items.len);
        const apc_index: Index = @intCast(self.triangles.items.len + 1);
        try self.triangles.ensureUnusedCapacity(2);
        // Divide the abc triangle into three.
        abc = &self.triangles.items[abc_index];
        // Insert pbc.
        self.triangles.append(Triangle{
            .points = [3]Index{ new_vertex_index, abc.points[1], abc.points[2] },
            .neighbors = [3]?Index{ abc_index, abc.neighbors[1], apc_index },
        }) catch unreachable;
        // Insert apc.
        self.triangles.append(Triangle{
            .points = [3]Index{ abc.points[0], new_vertex_index, abc.points[2] },
            .neighbors = [3]?Index{ abc_index, pbc_index, abc.neighbors[2] },
        }) catch unreachable;
        // Update neighbors to be aware of new triangles.
        inline for (abc.neighbors[1..], [2]Index{ pbc_index, apc_index }) |n, e|
            if (n) |i| {
                const p = &self.triangles.items[i];
                p.neighbors[p.neighborPosition(abc_index)] = e;
            };
        // Existing abc is reused.
        abc.points[2] = new_vertex_index;
        abc.neighbors[1] = pbc_index;
        abc.neighbors[2] = apc_index;
        abc.circumference = null;
        // Recursively adjust edges of triangles so that circumferences are only encasing 3 points at a time.
        // todo: Try inlining initial calls via @call(.always_inline, ...).
        self.trySwapping(abc_index, 0);
        self.trySwapping(pbc_index, 1);
        self.trySwapping(apc_index, 2);
    }
    fn trySwapping(self: @This(), triangle_index: Index, edge: u2) void {
        // First find opposite to edge point that lies in neighbor.
        const triangle = &self.triangles.items[triangle_index];
        const neighbor_index = triangle.neighbors[edge];
        if (neighbor_index == null)
            return;
        const neighbor = &self.triangles.items[neighbor_index.?];
        if (neighbor.circumference == null)
            neighbor.circumference = Triangle.Circumference.init(neighbor.*, self.vertices);
        // Position of neighbor's point opposide to shared with triangle edge.
        const point_order = neighbor.nextAfter(triangle.points[edge]);
        const point_index = neighbor.points[point_order];
        const prev_edge = if (edge == 0) 2 else edge - 1;
        if (neighbor.doesFailIncircleTest(self.vertices.items[triangle.points[prev_edge]])) {
            // Incircle test failed, swap edges of two triangles and then try swapping newly swapped ones.
            const next_edge = (edge + 1) % 3;
            const next_point_order = (point_order + 1) % 3;
            const prev_point_order = if (point_order == 0) 2 else point_order - 1;
            // Update neighbors of triangles in which edge was swapped.
            if (triangle.neighbors[next_edge]) |i| {
                const n = &self.triangles.items[i];
                n.neighbors[n.neighborPosition(triangle_index)] = neighbor_index.?;
            }
            if (neighbor.neighbors[prev_point_order]) |i| {
                const n = &self.triangles.items[i];
                n.neighbors[n.neighborPosition(neighbor_index.?)] = triangle_index;
            }
            const neighbor_prev_point_order_neighbor_index_cache = neighbor.neighbors[prev_point_order];
            neighbor.points[prev_point_order] = triangle.points[prev_edge];
            neighbor.neighbors[next_point_order] = triangle.neighbors[next_edge];
            neighbor.neighbors[prev_point_order] = triangle_index;
            neighbor.circumference = null;
            triangle.points[next_edge] = point_index;
            triangle.neighbors[next_edge] = neighbor_index.?;
            triangle.neighbors[edge] = neighbor_prev_point_order_neighbor_index_cache;
            triangle.circumference = null;
            self.trySwapping(triangle_index, edge);
            self.trySwapping(neighbor_index.?, point_order);
        }
    }
 };
 const Triangle = struct {
    // References to vertices it's composed of, named abc, in CCW orientation.
    points: [3]Index,
    // References to triangles that are on other side of any edge, if any.
    // Order is: ab, bc, ca
    neighbors: [3]?Index,
    // Lazily calculated and cached for incircle tests.
    circumference: ?Circumference = null,
    pub const Circumference = struct {
        center: Vertex,
        radius_squared: VertexComponent, // todo: Way to get a type capable of holding squared values.
        pub fn init(triangle: Triangle, vertices: std.ArrayList(Vertex)) @This() {
            const a = vertices.items[triangle.points[0]];
            const b = vertices.items[triangle.points[1]];
            const c = vertices.items[triangle.points[2]];
            const ab: Vertex = @splat(magnitudeSquared(a));
            const cd: Vertex = @splat(magnitudeSquared(b));
            const ef: Vertex = @splat(magnitudeSquared(c));
            const cmb = @shuffle(VertexComponent, c - b, undefined, [2]i32{ 1, 0 });
            const amc = @shuffle(VertexComponent, a - c, undefined, [2]i32{ 1, 0 });
            const bma = @shuffle(VertexComponent, b - a, undefined, [2]i32{ 1, 0 });
            const center = ((ab * cmb + cd * amc + ef * bma) / (a * cmb + b * amc + c * bma)) / @as(Vertex, @splat(2));
            return .{
                .center = center,
                .radius_squared = magnitudeSquared(a - center),
            };
        }
    };
    // todo: Try perpendicular dot product approach.
    pub fn pointRelation(self: @This(), vertices: std.ArrayList(Vertex), point: Vertex) enum(u2) {
        outside_ab = 0,
        outside_bc = 1,
        outside_ca = 2,
        contained = 3,
    } {
        const a = vertices.items[self.points[0]];
        const b = vertices.items[self.points[1]];
        const c = vertices.items[self.points[2]];
        // https://stackoverflow.com/questions/1560492/how-to-tell-whether-a-point-is-to-the-right-or-left-side-of-a-line
        const p = point;
        // Calculate cross products for all edges at once.
        const q = @Vector(12, VertexComponent){ b[0], b[1], c[0], c[1], a[0], a[1], p[1], p[0], p[1], p[0], p[1], p[0] };
        const w = @Vector(12, VertexComponent){ a[0], a[1], b[0], b[1], c[0], c[1], a[1], a[0], b[1], b[0], c[1], c[0] };
        const e = q - w;
        const r = @shuffle(VertexComponent, e, undefined, [6]i32{ 0, 1, 2, 3, 4, 5 });
        const t = @shuffle(VertexComponent, e, undefined, [6]i32{ 6, 7, 8, 9, 10, 11 });
        const y = r * t;
        const u = @shuffle(VertexComponent, y, undefined, [3]i32{ 0, 2, 4 });
        const i = @shuffle(VertexComponent, y, undefined, [3]i32{ 1, 3, 5 });
        const o = (u - i) > @Vector(3, VertexComponent){ 0, 0, 0 };
        // const o = (u - i) <= @Vector(3, VertexComponent){ 0, 0, 0 };
        // if (@reduce(.And, o))
        //     return .contained
        // else if (!o[0])
        //     return .outside_ab
        // else if (!o[1])
        //     return .outside_bc
        // else
        //     return .outside_ca;
        const mask = @as(u3, @intFromBool(o[0])) << 2 | @as(u3, @intFromBool(o[1])) << 1 | @as(u3, @intFromBool(o[2]));
        return @enumFromInt(@clz(mask));
    }
    pub inline fn doesFailIncircleTest(self: @This(), point: Vertex) bool {
        return magnitudeSquared(self.circumference.?.center - point) < self.circumference.?.radius_squared;
    }
    // todo: Shouldn't be here.
    pub inline fn magnitudeSquared(p: Vertex) VertexComponent {
        return @reduce(.Add, p * p);
    }
    // Finds which point comes after given one, by index, CCW.
    // Used to translate point names when traveling between neighbors.
    pub inline fn nextAfter(self: @This(), point_index: Index) u2 {
        inline for (self.points, 0..) |p, i|
            if (point_index == p)
                return @intCast((i + 1) % 3);
        unreachable;
    }
    pub inline fn neighborPosition(self: @This(), triangle_index: Index) usize {
        inline for (self.neighbors, 0..) |n, i|
            if (triangle_index == n)
                return i;
        unreachable;
    }
 };
 pub fn GenericArea(comptime T: type) type {
    return struct {
        // note: Upper-left origin is assumed, if second point lies left or up of first it willn't work.
        xyxy: @Vector(4, T),
        /// Order: Upperleft, upperright, bottomleft, bottomright.
        pub fn corners(self: @This()) [4]@Vector(2, T) {
            return [4]@Vector(2, T){
                @Vector(2, T){ self.xyxy[0], self.xyxy[1] },
                @Vector(2, T){ self.xyxy[2], self.xyxy[1] },
                @Vector(2, T){ self.xyxy[0], self.xyxy[3] },
                @Vector(2, T){ self.xyxy[2], self.xyxy[3] },
            };
        }
    };
 }
--- a/articles/incremental-delaunay/.static/web.png
+++ b/articles/incremental-delaunay/.static/web.png
--- a/articles/vector-pi-rotation/.static/noise.png
+++ b/articles/vector-pi-rotation/.static/noise.png
		`@ -0,0 +1,2 @@`
							`*.png filter=lfs diff=lfs merge=lfs -text`
							`*.gif filter=lfs diff=lfs merge=lfs -text`