// // We've absorbed a lot of information about the variations of types // we can use in Zig. Roughly, in order we have: // // u8 single item // *u8 single-item pointer // []u8 slice (size known at runtime) // [5]u8 array of 5 u8s // [*]u8 many-item pointer (zero or more) // enum {a, b} set of unique values a and b // error {e, f} set of unique error values e and f // struct {y: u8, z: i32} group of values y and z // union(enum) {a: u8, b: i32} single value either u8 or i32 // // Values of any of the above types can be assigned as "var" or "const" // to allow or disallow changes (mutability) via the assigned name: // // const a: u8 = 5; // immutable // var b: u8 = 5; // mutable // // We can also make error unions or optional types from any of // the above: // // var a: E!u8 = 5; // can be u8 or error from set E // var b: ?u8 = 5; // can be u8 or null // // Knowing all of this, maybe we can help out a local hermit. He made // a little Zig program to help him plan his trips through the woods, // but it has some mistakes. // // ************************************************************* // * A NOTE ABOUT THIS EXERCISE * // * * // * You do NOT have to read and understand every bit of this * // * program. This is a very big example. Feel free to skim * // * through it and then just focus on the few parts that are * // * actually broken! * // * * // ************************************************************* // const print = @import("std").debug.print; // The grue is a nod to Zork. const TripError = error{ Unreachable, EatenByAGrue }; // Let's start with the Places on the map. Each has a name and a // distance or difficulty of travel (as judged by the hermit). // // Note that we declare the places as mutable (var) because we need to // assign the paths later. And why is that? Because paths contain // pointers to places and assigning them now would create a dependency // loop! const Place = struct { name: []const u8, paths: []const Path = undefined, }; var a = Place{ .name = "Archer's Point" }; var b = Place{ .name = "Bridge" }; var c = Place{ .name = "Cottage" }; var d = Place{ .name = "Dogwood Grove" }; var e = Place{ .name = "East Pond" }; var f = Place{ .name = "Fox Pond" }; // The hermit's hand-drawn ASCII map // +---------------------------------------------------+ // | * Archer's Point ~~~~ | // | ~~~ ~~~~~~~~ | // | ~~~| |~~~~~~~~~~~~ ~~~~~~~ | // | Bridge ~~~~~~~~ | // | ^ ^ ^ | // | ^ ^ / \ | // | ^ ^ ^ ^ |_| Cottage | // | Dogwood Grove | // | ^ | // | ^ ^ ^ ^ ~~~~~~~~~~~~~ ^ ^ | // | ^ ~~ East Pond ~~~ | // | ^ ^ ^ ~~~~~~~~~~~~~~ | // | ~~ ^ | // | ^ ~~~ <-- short waterfall | // | ^ ~~~~~ | // | ~~~~~~~~~~~~~~~~~ | // | ~~~~ Fox Pond ~~~~~~~ ^ ^ | // | ^ ~~~~~~~~~~~~~~~ ^ ^ | // | ~~~~~ | // +---------------------------------------------------+ // // We'll be reserving memory in our program based on the number of // places on the map. Note that we do not have to specify the type of // this value because we don't actually use it in our program once // it's compiled! (Don't worry if this doesn't make sense yet.) const place_count = 6; // Now let's create all of the paths between sites. A path goes from // one place to another and has a distance. const Path = struct { from: *const Place, to: *const Place, dist: u8, }; // By the way, if the following code seems like a lot of tedious // manual labor, you're right! One of Zig's killer features is letting // us write code that runs at compile time to "automate" repetitive // code (much like macros in other languages), but we haven't learned // how to do that yet! const a_paths = [_]Path{ Path{ .from = &a, // from: Archer's Point .to = &b, // to: Bridge .dist = 2, }, }; const b_paths = [_]Path{ Path{ .from = &b, // from: Bridge .to = &a, // to: Archer's Point .dist = 2, }, Path{ .from = &b, // from: Bridge .to = &d, // to: Dogwood Grove .dist = 1, }, }; const c_paths = [_]Path{ Path{ .from = &c, // from: Cottage .to = &d, // to: Dogwood Grove .dist = 3, }, Path{ .from = &c, // from: Cottage .to = &e, // to: East Pond .dist = 2, }, }; const d_paths = [_]Path{ Path{ .from = &d, // from: Dogwood Grove .to = &b, // to: Bridge .dist = 1, }, Path{ .from = &d, // from: Dogwood Grove .to = &c, // to: Cottage .dist = 3, }, Path{ .from = &d, // from: Dogwood Grove .to = &f, // to: Fox Pond .dist = 7, }, }; const e_paths = [_]Path{ Path{ .from = &e, // from: East Pond .to = &c, // to: Cottage .dist = 2, }, Path{ .from = &e, // from: East Pond .to = &f, // to: Fox Pond .dist = 1, // (one-way down a short waterfall!) }, }; const f_paths = [_]Path{ Path{ .from = &f, // from: Fox Pond .to = &d, // to: Dogwood Grove .dist = 7, }, }; // Once we've plotted the best course through the woods, we'll make a // "trip" out of it. A trip is a series of Places connected by Paths. // We use a TripItem union to allow both Places and Paths to be in the // same array. const TripItem = union(enum) { place: *const Place, path: *const Path, // This is a little helper function to print the two different // types of item correctly. fn printMe(self: TripItem) void { switch (self) { // Oops! The hermit forgot how to capture the union values // in a switch statement. Please capture both values as // 'p' so the print statements work! .place => |p| print("{s}", .{p.name}), .path => |p| print("--{}->", .{p.dist}), } } }; // The Hermit's Notebook is where all the magic happens. A notebook // entry is a Place discovered on the map along with the Path taken to // get there and the distance to reach it from the start point. If we // find a better Path to reach a Place (shorter distance), we update the // entry. Entries also serve as a "todo" list which is how we keep // track of which paths to explore next. const NotebookEntry = struct { place: *const Place, coming_from: ?*const Place, via_path: ?*const Path, dist_to_reach: u16, }; // +------------------------------------------------+ // | ~ Hermit's Notebook ~ | // +---+----------------+----------------+----------+ // | | Place | From | Distance | // +---+----------------+----------------+----------+ // | 0 | Archer's Point | null | 0 | // | 1 | Bridge | Archer's Point | 2 | < next_entry // | 2 | Dogwood Grove | Bridge | 1 | // | 3 | | | | < end_of_entries // | ... | // +---+----------------+----------------+----------+ // const HermitsNotebook = struct { // Remember the array repetition operator `**`? It is no mere // novelty, it's also a great way to assign multiple items in an // array without having to list them one by one. Here we use it to // initialize an array with null values. entries: [place_count]?NotebookEntry = .{null} ** place_count, // The next entry keeps track of where we are in our "todo" list. next_entry: u8 = 0, // Mark the start of empty space in the notebook. end_of_entries: u8 = 0, // We'll often want to find an entry by Place. If one is not // found, we return null. fn getEntry(self: *HermitsNotebook, place: *const Place) ?*NotebookEntry { for (self.entries) |*entry, i| { if (i >= self.end_of_entries) break; // Here's where the hermit got stuck. We need to return // an optional pointer to a NotebookEntry. // // What we have with "entry" is the opposite: a pointer to // an optional NotebookEntry! // // To get one from the other, we need to dereference // "entry" (with .*) and get the non-null value from the // optional (with .?) and return the address of that. The // if statement provides some clues about how the // dereference and optional value "unwrapping" look // together. Remember that you return the address with the // "&" operator. if (place == entry.*.?.place) return &entry.*.?; // Try to make your answer this long:__________; } return null; } // The checkNote() method is the beating heart of the magical // notebook. Given a new note in the form of a NotebookEntry // struct, we check to see if we already have an entry for the // note's Place. // // If we DON'T, we'll add the entry to the end of the notebook // along with the Path taken and distance. // // If we DO, we check to see if the path is "better" (shorter // distance) than the one we'd noted before. If it is, we // overwrite the old entry with the new one. fn checkNote(self: *HermitsNotebook, note: NotebookEntry) void { var existing_entry = self.getEntry(note.place); if (existing_entry == null) { self.entries[self.end_of_entries] = note; self.end_of_entries += 1; } else if (note.dist_to_reach < existing_entry.?.dist_to_reach) { existing_entry.?.* = note; } } // The next two methods allow us to use the notebook as a "todo" // list. fn hasNextEntry(self: *HermitsNotebook) bool { return self.next_entry < self.end_of_entries; } fn getNextEntry(self: *HermitsNotebook) *const NotebookEntry { defer self.next_entry += 1; // Increment after getting entry return &self.entries[self.next_entry].?; } // After we've completed our search of the map, we'll have // computed the shortest Path to every Place. To collect the // complete trip from the start to the destination, we need to // walk backwards from the destination's notebook entry, following // the coming_from pointers back to the start. What we end up with // is an array of TripItems with our trip in reverse order. // // We need to take the trip array as a parameter because we want // the main() function to "own" the array memory. What do you // suppose could happen if we allocated the array in this // function's stack frame (the space allocated for a function's // "local" data) and returned a pointer or slice to it? // // Looks like the hermit forgot something in the return value of // this function. What could that be? fn getTripTo(self: *HermitsNotebook, trip: []?TripItem, dest: *Place) TripError!void { // We start at the destination entry. const destination_entry = self.getEntry(dest); // This function needs to return an error if the requested // destination was never reached. (This can't actually happen // in our map since every Place is reachable by every other // Place.) if (destination_entry == null) { return TripError.Unreachable; } // Variables hold the entry we're currently examining and an // index to keep track of where we're appending trip items. var current_entry = destination_entry.?; var i: u8 = 0; // At the end of each looping, a continue expression increments // our index. Can you see why we need to increment by two? while (true) : (i += 2) { trip[i] = TripItem{ .place = current_entry.place }; // An entry "coming from" nowhere means we've reached the // start, so we're done. if (current_entry.coming_from == null) break; // Otherwise, entries have a path. trip[i + 1] = TripItem{ .path = current_entry.via_path.? }; // Now we follow the entry we're "coming from". If we // aren't able to find the entry we're "coming from" by // Place, something has gone horribly wrong with our // program! (This really shouldn't ever happen. Have you // checked for grues?) // Note: you do not need to fix anything here. const previous_entry = self.getEntry(current_entry.coming_from.?); if (previous_entry == null) return TripError.EatenByAGrue; current_entry = previous_entry.?; } } }; pub fn main() void { // Here's where the hermit decides where he would like to go. Once // you get the program working, try some different Places on the // map! const start = &a; // Archer's Point const destination = &f; // Fox Pond // Store each Path array as a slice in each Place. As mentioned // above, we needed to delay making these references to avoid // creating a dependency loop when the compiler is trying to // figure out how to allocate space for each item. a.paths = a_paths[0..]; b.paths = b_paths[0..]; c.paths = c_paths[0..]; d.paths = d_paths[0..]; e.paths = e_paths[0..]; f.paths = f_paths[0..]; // Now we create an instance of the notebook and add the first // "start" entry. Note the null values. Read the comments for the // checkNote() method above to see how this entry gets added to // the notebook. var notebook = HermitsNotebook{}; var working_note = NotebookEntry{ .place = start, .coming_from = null, .via_path = null, .dist_to_reach = 0, }; notebook.checkNote(working_note); // Get the next entry from the notebook (the first being the // "start" entry we just added) until we run out, at which point // we'll have checked every reachable Place. while (notebook.hasNextEntry()) { var place_entry = notebook.getNextEntry(); // For every Path that leads FROM the current Place, create a // new note (in the form of a NotebookEntry) with the // destination Place and the total distance from the start to // reach that place. Again, read the comments for the // checkNote() method to see how this works. for (place_entry.place.paths) |*path| { working_note = NotebookEntry{ .place = path.to, .coming_from = place_entry.place, .via_path = path, .dist_to_reach = place_entry.dist_to_reach + path.dist, }; notebook.checkNote(working_note); } } // Once the loop above is complete, we've calculated the shortest // path to every reachable Place! What we need to do now is set // aside memory for the trip and have the hermit's notebook fill // in the trip from the destination back to the path. Note that // this is the first time we've actually used the destination! var trip = [_]?TripItem{null} ** (place_count * 2); notebook.getTripTo(trip[0..], destination) catch |err| { print("Oh no! {}\n", .{err}); return; }; // Print the trip with a little helper function below. printTrip(trip[0..]); } // Remember that trips will be a series of alternating TripItems // containing a Place or Path from the destination back to the start. // The remaining space in the trip array will contain null values, so // we need to loop through the items in reverse, skipping nulls, until // we reach the destination at the front of the array. fn printTrip(trip: []?TripItem) void { // We convert the usize length to a u8 with @intCast(), a // builtin function just like @import(). We'll learn about // these properly in a later exercise. var i: u8 = @intCast(u8, trip.len); while (i > 0) { i -= 1; if (trip[i] == null) continue; trip[i].?.printMe(); } print("\n", .{}); } // Going deeper: // // In computer science terms, our map places are "nodes" or "vertices" and // the paths are "edges". Together, they form a "weighted, directed // graph". It is "weighted" because each path has a distance (also // known as a "cost"). It is "directed" because each path goes FROM // one place TO another place (undirected graphs allow you to travel // on an edge in either direction). // // Since we append new notebook entries at the end of the list and // then explore each sequentially from the beginning (like a "todo" // list), we are treating the notebook as a "First In, First Out" // (FIFO) queue. // // Since we examine all closest paths first before trying further ones // (thanks to the "todo" queue), we are performing a "Breadth-First // Search" (BFS). // // By tracking "lowest cost" paths, we can also say that we're // performing a "least-cost search". // // Even more specifically, the Hermit's Notebook most closely // resembles the Shortest Path Faster Algorithm (SPFA), attributed to // Edward F. Moore. By replacing our simple FIFO queue with a // "priority queue", we would basically have Dijkstra's algorithm. A // priority queue retrieves items sorted by "weight" (in our case, it // would keep the paths with the shortest distance at the front of the // queue). Dijkstra's algorithm is more efficient because longer paths // can be eliminated more quickly. (Work it out on paper to see why!)