This is a project I have started mainly to teach myself Rust and get a glimpse of how it could possibly feel to write a great game engine.
I fondly remember the first time I played Another World (or Out of this World as it is known in North America) as a kid, and the disbelief that ensued. A game by Eric Chahi released in 1991, it redefined the way video games could be designed to tell a story. No UI, no score, no dialogues, no ammo, no health indicator. No sprites that moved over a background layer made of fixed-size tiles - the game was rendered almost entirely using polygons, and this made it feel very different. It was alive, unpredictable, not constrained by limited game mechanics and hand-drawn sprites. Anything could happen, and very often anything did happen. Although heavily scripted, the game felt like it was having an existence of its own.
Look at the screen above and try to picture all the things that are happening. Of course, you notice that the beast has noticed you, and you know you will meet again. There is one bird passing by in the background, and on the foreground a dandelion-like plant moves by the wind. The water makes small waves. But there is also dust being randomly blown your way - you need to pay more attention to notice this one.
The whole game is built with this level of detail, and for the time it was mind-blowing. This was made possible thanks to the use of a cooperatively multi-threaded virtual machine allowing for very complex in-game scripts, and which incidentally also made porting the game much easier. In 1991, this was both an artistic and a technical tour-de-force.
The technical tale of Another World has been told much better than I could by Fabien Sanglard with his C++ reimplementation of the original game engine and Polygons of Another World series. This work has been the main source of guidance for the present project, along with his C++ reimplementation of the engine.
Another invaluable reference was Eric Chahi's original technical notes (in French, mind you), which are provided along with the 20th anniversary edition.
Contrary to Fabien's work, which apparently aimed at staying as close as possible to the original program (going as far as emulating the layout of DOS conventional memory to load the resources), this project takes a few liberties where it felt right to do so, because you just cannot program in Rust like it's 1991. The goals are:
- Write in idiomatic, clean Rust as much as possible (and learn how to do so at the same time).
- Use proper data structures and comment extensively so this repository can also be used as a way to understand the game.
- Be respectful of the technical limitations of the time - writing idiomatic and structure Rust code is not an excuse for introducing extra overhead. For instance, once loaded the game's resources are not moved, reprocessed or augmented (beyond fixing endianness) and thus do not take more space than they did originally.
- Provide an experience as authentic as possible, but offer options to leverage modern hardware and have fun with it (e.g. high-resolution polygon rendering accelerated by the GPU).
These points are ideals and the current code is still far from reflecting them.
SDL2 is used for all input and output.
What is working:
- Virtual machine,
- Rendering of polygons, bitmaps, and text,
- Input,
- Sounds effects,
- Background music.
This makes the game completable with a good experience.
First you need a copy of the original DOS game data, which comes in the form of one memlist.bin and a bunch of bank0x files. Sadly the 20th anniversary edition does not include the data in this format.
Put the game data it in the root directory of this project, then build and run, e.g:
cargo run --release -- --scene=1
Options:
--scene=x
This will start the game at scene x. Mostly useful to skip the password protection screen (use --scene=1 to start directly at the intro). Note that some scenes depend on the state left by the previous one, so expect crashes if with some scene numbers.
--render=(raster | gl_raster | gl_poly | gl_line)
Choose the rendering method.
raster is a pure software renderer at the original 320x200 resolution and tries to show the game the way God Eric Chahi intended. The final 320x200 image is scaled up to the actual window size using SDL2.
gl_raster is similar to raster, but uses a GL shader to convert and scale the game screen to our modern displays. It is more efficient than raster, but introduces a dependency to OpenGL.
gl_poly creates triangles from the polygons and renders them using OpenGL. This makes rendering fast and smooth at higher resolutions. However, since that's clearly not how the game was designed to be rendered, artefacts in the form of gaps and misshaped objects are to be expected.
gl_line is also a mode that uses OpenGL, but renders the polygons' outlines only. Useful to study how they are designed, not so much for enjoying the game.
Up,Down,Left,Right: Move.Space: Action.P: Pause/resume. While in pause:N: Take a snapshot of the game's state and continue up to the next frame.B: Restore the last snapshot (moving back to the previous frame if you pressedN).
F: Fast-forward, useful to make some cinematic scenes go faster.B: Rewind to the last snapshot. Snapshots are taken roughly every 5 seconds. Useful to retry a part after you die (and die a lot you will).