Pygame wrapper: Difference between revisions
Rizwan1218 (talk | contribs) No edit summary |
m (Reverted edits by Rizwan1218 (Talk) to last revision by Quozl) |
||
Line 13: | Line 13: | ||
The [[Pygame]] wrapper for the OLPC [[Sugar]] platform is called OLPCGames. This page explores the differences between standard Pygame programming and OLPCGames-mediated Pygame programming. |
The [[Pygame]] wrapper for the OLPC [[Sugar]] platform is called OLPCGames. This page explores the differences between standard Pygame programming and OLPCGames-mediated Pygame programming. |
||
The automatically generated [http://dev.laptop.org/~mcfletch/OLPCGames/pydoc/olpcgames.html Pydoc documentation for OLPCGames] is the canonical reference work for the |
The automatically generated [http://dev.laptop.org/~mcfletch/OLPCGames/pydoc/olpcgames.html Pydoc documentation for OLPCGames] is the canonical reference work for the documentation. |
||
=Strategic Rationale= |
=Strategic Rationale= |
Latest revision as of 20:33, 25 July 2013
(See also Sugargame.)
The Pygame wrapper for the OLPC Sugar platform is called OLPCGames. This page explores the differences between standard Pygame programming and OLPCGames-mediated Pygame programming.
The automatically generated Pydoc documentation for OLPCGames is the canonical reference work for the documentation.
Strategic Rationale
The particular value of the OLPCGames wrapper is not, in fact, the ability to run Pygame games on the OLPC. The particular value is that by using Pygame for your game, and OLPCGames as your wrapper, you should not need to worry about the underlying details of the (rapidly changing, and rather breakage-prone) Sugar API.
Historically that changing API has forced each (PyGTK) developer to revise their activities time and again. OLPCGames, which is effectively the "Sugar" side of your Pygame activity, is shared among many projects, so that when it is fixed, all of the games using it are fixed along with it (generally only needing to replace the version of OLPCGames they are using and re-publishing the .xo file).
In addition, there are platforms where creating a working Sugar development environment is a non-trivial task. For those environments, it is often possible to set up a simple Pygame environment, write your game/Activity in that environment, and then port (or have someone port) the Activity to the XO in a matter of minutes.
Tutorials
- PyCon 2008 Tutorial (Code) -- Hello World, Participant Tracking in Games, Networked TicTacToe, Journal integration, SVG and Pango rendering
- Porting pygame games to the XO -- Phil Hassey's notes on porting two of his games to the XO. Much shorter and higher-level presentation, assumes you already have a working Pygame game, know your way around your game's code base, and just need to know what's different about OLPCGames under Sugar
- Game development HOWTO -- describes the process of building a new skeleton project
- OOP tutorial for PyGame
Getting the wrapper
You can either download the wrapper as a .zip or .tar.gz
wget http://dev.laptop.org/~mcfletch/OLPCGames/OLPCGames-1.6.zip
or you can check it out of the git repository on dev.laptop.org (note, do not attempt this on an XO or other space-constrained device, GIT downloads the entire history of the project, which is over 120MB in this case).
git clone git://dev.laptop.org/projects/games-misc
The 'olpcgames' directory is the package in question. Submodules you can access are activity, canvas, camera, mesh, and pangofont. The wrapper also replaces certain Python modules (e.g. pygame.event with 'eventwrap' (which can also be imported separately)), so we document those here too.
Activities
The following Activities use OLPCGames and can serve as example code, (note that some of these projects may not be finished yet):
- Story Builder -- Environment for creating story modules to be used in MaMaMedia, uses the PGU GUI library extensively
- Productive -- A Real-time Strategy game written explicitly for the OLPC platform. Includes networking via the mesh module (and raw Telepathy primitives). Graphics are via raw Pygame coding.
- FiftyTwo -- A set of card games
- Maze -- Maze navigation game
- Camera Test -- example of using the
olpcgames.camera
module XO - Sound Test -- example showing simple multi-channel sound usage XO
- SVG Sprite Test -- example showing use of the
olpcgames.svgsprite
module XO
- Video Test -- example showing use of the GStreamer-based
olpcgames.video
module XO - Quinteti -- Tic Tac Toe like game XO
Differences from Pygame
The SDL Pygame wrapper allows for nested Pygame windows using a separate thread. It forwards GTK events and converts them to Pygame events. Games under the wrapper may not work exactly the same way and porting is not completely seamless -- you should be aware of a few OLPC-specific caveats:
- You cannot set the display mode using pygame.display.set_mode. You must set it in the wrapper boilerplate instead (see Game development HOWTO).
- It is not recommended that you use the regular Pygame.font text drawing. You can use the wrapper to draw text using the 'olpcgames.pangofont' module instead which supports proper internationalization. See Pangofont.
- NOTE: If you are developing on an AMD64/EMT64 platform, there is a bug in Pygame 1.7.x which prevents it from working with the SVG or PangoFont modules. This bug has been fixed on the trunk of Pygame and should show up with the next release.
- The event module is shadowed by Eventwrap and some methods may not work exactly the same. Certain methods in pygame.mouse and pygame.key are also shadowed.
- There's no CD-ROM on OLPC-XOs, so the 'cdrom' module isn't generally useful.
Keyboard and Mouse
Keyboard and mouse work approximately as they do under Pygame. We simulate repeated key-down events when a key is held down for a period in order to simulate Pygame's operation.
The "gamepad" buttons on the left and right of the screen come in as Numpad number keys (i.e., pygame.K_KP1
through pygame.K_KP9
):
D-Pad (left of screen) Gamepad (right of screen) 8 9 O 4 6 7 1 [] V 2 3 X
The D-pad (directional pad) mappings make sense as the traditional arrow keys on the numeric keypad of 101-key keyboards. The gamepad mappings make sense when you realize that 9/3 are page-up/page-down and 7/1 are home/end. The d-pad has 8 directions of articulation. You detect the diagonals by looking for two keys pressed at the same time.
When designing your interfaces keep in mind that an OLPC-XO in tablet mode only has the eight "keys" above available (as well as a resize-and-rotate key, but that's already mapped by the operating system).
Keep in mind that your activities will need to be localized into many languages, so binding, for instance "p" to "produce" is sub-optimal. If possible provide a run-time configuration, or at least a localization-time configuration mechanism (such as a configuration file) that lets more natural keys be chosen for each language's keyboard.
OLPC-XO (B4) Hardware Notes
The D-Pad control is usable for general control operations, but it is not a precise/fast control device as seen on gaming console controllers. It often slips from a cardinal direction to the adjacent intermediate direction (i.e. from left to left+up). You should not expect a traditional "platformer" game to be played with this control without some heuristics to clean up the input.
The checkmark button (K_KP1) is far easier to click than the X button, so "click" for "fire" should likely be the checkmark rather than the X. (Which makes sense to English users, at least). The Game pad buttons are small and close enough that asking a user to rapidly switch between them will likely result in a lot of multiple-button push events. Again, some heuristic code would be needed to clean up the input.
Cursors
See Sugar Standard Icons for instructions on how to create and use a standard Sugar cursor within Pygame-based games. The arrow and hand cursor there should likely be sufficient for most games.
Antialiased Lines
The bit-depth chosen by the wrapper (16 bit on OLPC-XOs, normally) tends to make antialiased lines fail. The reason this is so hasn't been extensively investigated, so it's not known whether this is a hard-and-fast limitation, or just an optimization hint.
Journal Integration
OLPCGames produces events to tell you about Journal save/restore requests:
- pygame.USEREVENT
- code = olpcgames.FILE_READ_REQUEST (OLPCGames 1.6+)
- filename -- the filename to be read
- metadata -- metadata object (dictionary like)
- code = olpcgames.FILE_WRITE_REQUEST (OLPCGames 1.6+)
- filename -- the filename to be written
- metadata -- metadata object (dictionary like)
- code = olpcgames.FILE_READ_REQUEST (OLPCGames 1.6+)
which are generated to allow you to save/restore to/from the Journal/Datastore on the OLPC.
Window Resizing
Window resizing doesn't work yet (i.e., resizing windows via the screen rotate button), but we will try to get this working soon.
Module Reference
The pydoc-generated documentation for the OLPCGames package serves as the canonical reference work at this point.
Customizing the Toolbar
If you want to add stuff to the standard toolbar you can override build_toolbar in your PyGameActivity subclass like this:
import pygame import olpcgames from sugar.graphics.toolbutton import ToolButton from gettext import gettext as _ ... def build_toolbar( self ): """Build our Activity toolbar for the Sugar system.""" toolbar = super( MyActivityClass, self ).build_toolbar() # Add a button mybutton = ToolButton('activity-mybutton') # put the icon file here: MyGame.activity/icons/activity-mybutton.svg mybutton.set_tooltip(_('Something')) mybutton.connect('clicked', self._mybutton_cb) toolbar.insert(mybutton, 2) mybutton.show() return toolbar def _ mybutton_cb(self, button): pygame.event.post(olpcgames.eventwrap.Event(pygame.USEREVENT, action='mybutton'))
Then in your event handler do this:
if event.type == pygame.USEREVENT: if event.action == 'mybutton': self.dosomething() else: print "Unknown user event action:", event.action