const std = @import("std"); const example = @embedFile("example"); const input = @embedFile("input"); var allocator: std.mem.Allocator = undefined; pub fn main() anyerror!void { var arena = std.heap.ArenaAllocator.init(std.heap.page_allocator); defer arena.deinit(); allocator = arena.allocator(); try std.testing.expectEqual(try solve(example, 10), 26); const result = try solve(input, 2000000); try std.io.getStdOut().writer().print("{}\n", .{result}); } const Interval = struct { l: i64, r: i64, }; fn lesserThan(context: void, a: *Interval, b: *Interval) bool { _ = context; return a.l < b.l; } fn solve(puzzle: []const u8, yline: i64) !i64 { var it = std.mem.tokenize(u8, puzzle, "\n"); var intervals = std.ArrayList(*Interval).init(allocator); // process input while (it.next()) |line| { var coords = std.mem.tokenize(u8, line, "Sensor at x=, y=: closest beacon is at x=, y="); const sx = try std.fmt.parseInt(i64, coords.next() orelse continue, 10); const sy = try std.fmt.parseInt(i64, coords.next() orelse unreachable, 10); const bx = try std.fmt.parseInt(i64, coords.next() orelse unreachable, 10); const by = try std.fmt.parseInt(i64, coords.next() orelse unreachable, 10); const d = try std.math.absInt(sx - bx) + try std.math.absInt(sy - by); if (sy - d > yline or sy + d < yline) { continue; } const l = d - try std.math.absInt(yline - sy); var i = try allocator.create(Interval); i.* = Interval{ .l = sx - l, .r = sx + l }; try intervals.append(i); } // sort by left bound std.sort.sort(*Interval, intervals.items, {}, lesserThan); // Reduce intervals and compute results var n: i64 = 0; var i: usize = 0; while (i < intervals.items.len) : (i += 1) { var int = intervals.items[i]; var j = i + 1; while (j < intervals.items.len) { const jnt = intervals.items[j]; if (jnt.l <= int.r) { // jint overlaps if (jnt.r > int.r) { int.r = jnt.r; } _ = intervals.orderedRemove(j); continue; } else { break; } j += 1; } n = n + int.r - int.l; } return n; }