advent-of-code-2023/day11/main.zig

const std = @import("std");

const Galaxy = struct { row: usize, col: usize };

pub fn main() !void {
    const content = @embedFile("data.txt");

    var gpa = std.heap.GeneralPurposeAllocator(.{}){};
    const allocator = gpa.allocator();

    // put into ArrayList of ArrayLists
    var grid = try parseGrid(content, allocator);
    defer grid.deinit();
    std.debug.print("grid: {any}\n", .{grid});

    // find empty rows
    const emptyRows = try findEmptyRows(grid, allocator);
    std.debug.print("empty rows: {any}\n", .{emptyRows});

    // find empty columns
    const emptyColumns = try findEmptyColumns(grid, allocator);
    std.debug.print("empty cols: {any}\n", .{emptyColumns});

    // duplicate empty rows
    // NOTE: not doing this any more, using Part 2 solution for Part 1
    //
    // for (emptyRows.items, 0..) |row, i| {
    //     try grid.insert(row + i, grid.items[row + i]);
    // }
    //
    // // duplicate empty columns
    // for (emptyColumns.items, 0..) |col, i| {
    //     for (grid.items, 0..) |_, row| {
    //         try grid.items[row].insert(col + i, '.');
    //     }
    // }

    // find original galaxy locations
    var galaxies = std.ArrayList(Galaxy).init(allocator);
    for (grid.items, 0..) |row, i| {
        for (row.items, 0..) |char, j| {
            if (char == '#') {
                try galaxies.append(Galaxy{ .row = i, .col = j });
            }
        }
    }

    var galaxies1 = std.ArrayList(Galaxy).init(allocator);
    var galaxies2 = std.ArrayList(Galaxy).init(allocator);

    for (galaxies.items) |g| {
        const row = g.row;
        const col = g.col;

        // how many expanded rows & cols before this galaxy?
        var expandedRows: usize = 0;
        for (emptyRows.items) |r| {
            if (r > row) {
                break;
            }
            expandedRows += 1;
        }

        var expandedColumns: usize = 0;
        for (emptyColumns.items) |c| {
            if (c > col) {
                break;
            }
            expandedColumns += 1;
        }

        const expansionFactor = 1_000_000;

        try galaxies1.append(Galaxy{ .row = row + expandedRows, .col = col + expandedColumns });
        try galaxies2.append(Galaxy{ .row = row + (expansionFactor - 1) * expandedRows, .col = col + (expansionFactor - 1) * expandedColumns });
    }

    // add up all their distances
    var part1: usize = 0;
    for (0..galaxies1.items.len - 1) |i| {
        for (i + 1..galaxies1.items.len) |j| {
            part1 += dist(galaxies1.items[j], galaxies1.items[i]);
        }
    }

    std.debug.print("Part 1: {d}\n", .{part1});

    var part2: usize = 0;
    for (0..galaxies2.items.len - 1) |i| {
        for (i + 1..galaxies2.items.len) |j| {
            part2 += dist(galaxies2.items[j], galaxies2.items[i]);
        }
    }

    std.debug.print("Part 2: {d}\n", .{part2});
}

fn dist(a: Galaxy, b: Galaxy) usize {
    const x = if (a.row > b.row) a.row - b.row else b.row - a.row;
    const y = if (a.col > b.col) a.col - b.col else b.col - a.col;
    return x + y;
}

fn findEmptyColumns(grid: std.ArrayList(std.ArrayList(u8)), allocator: std.mem.Allocator) !std.ArrayList(usize) {
    var cols = std.ArrayList(usize).init(allocator);
    const height = grid.items.len;
    const width = grid.items[0].items.len;

    for (0..width) |col| {
        var allEmpty = true;
        for (0..height) |row| {
            if (grid.items[row].items[col] == '#') {
                allEmpty = false;
            }
        }
        if (allEmpty) {
            try cols.append(col);
        }
    }
    return cols;
}

fn findEmptyRows(grid: std.ArrayList(std.ArrayList(u8)), allocator: std.mem.Allocator) !std.ArrayList(usize) {
    var rows = std.ArrayList(usize).init(allocator);

    for (grid.items, 0..) |row, idx| {
        var allEmpty = true;
        for (row.items) |char| {
            if (char == '#') {
                allEmpty = false;
            }
        }
        if (allEmpty) {
            try rows.append(idx);
        }
    }
    return rows;
}

fn parseGrid(content: []const u8, allocator: std.mem.Allocator) !std.ArrayList(std.ArrayList(u8)) {
    var grid = std.ArrayList(std.ArrayList(u8)).init(allocator);
    var lines = std.mem.split(u8, content, "\n");

    while (lines.next()) |line| {
        if (line.len < 1) {
            break;
        }

        var al = std.ArrayList(u8).init(allocator);
        for (line) |char| {
            try al.append(char);
        }

        try grid.append(al);
    }

    return grid;
}
So much easier than day10. Man this year is crazy 11 months ago			`const std = @import("std");`

			`const Galaxy = struct { row: usize, col: usize };`

			`pub fn main() !void {`
			`const content = @embedFile("data.txt");`

			`var gpa = std.heap.GeneralPurposeAllocator(.{}){};`
			`const allocator = gpa.allocator();`

			`// put into ArrayList of ArrayLists`
			`var grid = try parseGrid(content, allocator);`
			`defer grid.deinit();`
			`std.debug.print("grid: {any}\n", .{grid});`

			`// find empty rows`
			`const emptyRows = try findEmptyRows(grid, allocator);`
			`std.debug.print("empty rows: {any}\n", .{emptyRows});`

			`// find empty columns`
			`const emptyColumns = try findEmptyColumns(grid, allocator);`
			`std.debug.print("empty cols: {any}\n", .{emptyColumns});`

			`// duplicate empty rows`
			`// NOTE: not doing this any more, using Part 2 solution for Part 1`
			`//`
			`// for (emptyRows.items, 0..) \|row, i\| {`
			`// try grid.insert(row + i, grid.items[row + i]);`
			`// }`
			`//`
			`// // duplicate empty columns`
			`// for (emptyColumns.items, 0..) \|col, i\| {`
			`// for (grid.items, 0..) \|_, row\| {`
			`// try grid.items[row].insert(col + i, '.');`
			`// }`
			`// }`

			`// find original galaxy locations`
			`var galaxies = std.ArrayList(Galaxy).init(allocator);`
			`for (grid.items, 0..) \|row, i\| {`
			`for (row.items, 0..) \|char, j\| {`
			`if (char == '#') {`
			`try galaxies.append(Galaxy{ .row = i, .col = j });`
			`}`
			`}`
			`}`

			`var galaxies1 = std.ArrayList(Galaxy).init(allocator);`
			`var galaxies2 = std.ArrayList(Galaxy).init(allocator);`

			`for (galaxies.items) \|g\| {`
			`const row = g.row;`
			`const col = g.col;`

			`// how many expanded rows & cols before this galaxy?`
			`var expandedRows: usize = 0;`
			`for (emptyRows.items) \|r\| {`
			`if (r > row) {`
			`break;`
			`}`
			`expandedRows += 1;`
			`}`

			`var expandedColumns: usize = 0;`
			`for (emptyColumns.items) \|c\| {`
			`if (c > col) {`
			`break;`
			`}`
			`expandedColumns += 1;`
			`}`

			`const expansionFactor = 1_000_000;`

			`try galaxies1.append(Galaxy{ .row = row + expandedRows, .col = col + expandedColumns });`
			`try galaxies2.append(Galaxy{ .row = row + (expansionFactor - 1) * expandedRows, .col = col + (expansionFactor - 1) * expandedColumns });`
			`}`

			`// add up all their distances`
			`var part1: usize = 0;`
			`for (0..galaxies1.items.len - 1) \|i\| {`
			`for (i + 1..galaxies1.items.len) \|j\| {`
			`part1 += dist(galaxies1.items[j], galaxies1.items[i]);`
			`}`
			`}`

			`std.debug.print("Part 1: {d}\n", .{part1});`

			`var part2: usize = 0;`
			`for (0..galaxies2.items.len - 1) \|i\| {`
			`for (i + 1..galaxies2.items.len) \|j\| {`
			`part2 += dist(galaxies2.items[j], galaxies2.items[i]);`
			`}`
			`}`

			`std.debug.print("Part 2: {d}\n", .{part2});`
			`}`

			`fn dist(a: Galaxy, b: Galaxy) usize {`
			`const x = if (a.row > b.row) a.row - b.row else b.row - a.row;`
			`const y = if (a.col > b.col) a.col - b.col else b.col - a.col;`
			`return x + y;`
			`}`

			`fn findEmptyColumns(grid: std.ArrayList(std.ArrayList(u8)), allocator: std.mem.Allocator) !std.ArrayList(usize) {`
			`var cols = std.ArrayList(usize).init(allocator);`
			`const height = grid.items.len;`
			`const width = grid.items[0].items.len;`

			`for (0..width) \|col\| {`
			`var allEmpty = true;`
			`for (0..height) \|row\| {`
			`if (grid.items[row].items[col] == '#') {`
			`allEmpty = false;`
			`}`
			`}`
			`if (allEmpty) {`
			`try cols.append(col);`
			`}`
			`}`
			`return cols;`
			`}`

			`fn findEmptyRows(grid: std.ArrayList(std.ArrayList(u8)), allocator: std.mem.Allocator) !std.ArrayList(usize) {`
			`var rows = std.ArrayList(usize).init(allocator);`

			`for (grid.items, 0..) \|row, idx\| {`
			`var allEmpty = true;`
			`for (row.items) \|char\| {`
			`if (char == '#') {`
			`allEmpty = false;`
			`}`
			`}`
			`if (allEmpty) {`
			`try rows.append(idx);`
			`}`
			`}`
			`return rows;`
			`}`

			`fn parseGrid(content: []const u8, allocator: std.mem.Allocator) !std.ArrayList(std.ArrayList(u8)) {`
			`var grid = std.ArrayList(std.ArrayList(u8)).init(allocator);`
			`var lines = std.mem.split(u8, content, "\n");`

			`while (lines.next()) \|line\| {`
			`if (line.len < 1) {`
			`break;`
			`}`

			`var al = std.ArrayList(u8).init(allocator);`
			`for (line) \|char\| {`
			`try al.append(char);`
			`}`

			`try grid.append(al);`
			`}`

			`return grid;`
			`}`