1. CSCE 552 Spring 2010 Language and Programming By Jijun Tang

2. Announcements Send me group names and logos XNA demo/learning on Feb 1 st, in 1D11  Install XNA Game Studio and VC# Express on your laptop  Please bring your laptop to the class Presentation on Feb 3 rd  In 1D11  Each group 10 minutes to present, 3 minutes to answer question Homework #1

3. Game Design Presentation Expecting formal presentations with powerpoint files, pictures, musics, etc 10 points total for this presentation Grade will be group based, you can have the whole group or part of the group to present Grade will be based on scores from me and from the class

4. Homework #1 Game Treatment Document Due on Feb 8 th after class Each group turn in one hard copy and the grade will be assigned based on group

5. Example of Treatment http://www.csc.kth.se/utbildning/kth/kur ser/DH2650/spel08/The%20Game%20 Treatment.doc

6. Design Procedure Waterfall method  Development methodology  Design and production are broken into phases Iterative development  Practice of producing things incrementally  Refining and re-refining the product  May iterate many cycles before get it right

7. Waterfall vs. Iterative testing

8. Brainstorming Generating ideas without discrimination Evaluation after elaboration, can be unfocused

9. Programming Teams In the 1980s programmers developed the whole game (and did the art and sounds too!) Now programmers write code to support designers and artists (content creators)

10. Different Programs Game code Anything related directly to the game Game engine Any code that can be reused between different games Tools In house tools Plug-ins for off-the-shelf tools

11. Methodologies: Code and Fix Unfortunately very common Little or no planning Always reacting to events Poor quality and unreliability of finished product “Crunch” time normal

12. Methodologies: Waterfall Very well-defined steps in development Lots of planning ahead of time Great for creating a detailed milestone schedule Doesn't react well to changes Game development is too unpredictable for this approach

13. Methodologies: Iterative Multiple development cycles during a single project  Each delivering a new set of functionality  Refinements are needed The game could ship at any moment Allows for planning but also for changes

14. Methodologies: Agile Methods Deal with the unexpected Very short iterations: 2-3 weeks Iterate based on feedback of what was learned so far Very good visibility of state of game Difficult for publishers or even developers to adopt because it's relatively new

15. Make Coding Easier Version control Coding standards Automated build Code review Unit testing and acceptance testing

16. Version Control Recommended to use for team project Version control is  Database with all the files and history.  Only way to work properly with a team.  Branching and merging can be very useful  Used for source code as well as game assets (text and binary) Tools:  CVS is one of the most popular tool  Source anywhere

17. Coding standards Coding standards are  Set of coding rules for the whole team to follow  Improves readability and maintainability of the code  Easier to work with other people's code  They vary a lot from place to place Some simple, some complex Get used to different styles Sample standards can be found at: http://www.chris- lott.org/resources/cstyle/CppCodingStandard.htmlhttp://www.chris- lott.org/resources/cstyle/CppCodingStandard.html

18. Automated builds Dedicated build server builds the game from scratch Takes the source code and creates an executable Also takes assets and builds them into game-specific format Build must never break

19. Quality Control Code reviews  Knowing others will read the code will make coding more carefully  Another programmer reads over some code and tries to find problems  Sometimes done before code is committed to version control  Can be beneficial if done correctly Follow coding standards, and put comments

20. Avoid Run-time Errors Run-time errors are hardest to trace and have the biggest damage Initialize variables, use tools (Visual.Net is good at this), check boundaries, etc.  purify on Windows  valgrind on Linux Asserts and crashes  Use asserts anytime the game could crash or something could go very wrong  An assert is a controlled crash in the debug version  Much easier to debug and fix  Happens right where the problem occurred  Don't use them for things that a user could do Open a non-existing file Press the wrong button

21. Leveraging Existing Code A lot of code that games use is the same It's a total waste of time to write it over and over Instead, spend your time in what's going to make your game unique Avoid Not Invented Here (NIH) syndrome!

22. Where Are Existing Codes Reuse code from previous project  Easier in a large company if you have an engine and tools group Use freeware code and tools  No support  Make sure license allows it Middleware  Companies provide with components used in game development physics, animation, graphics, etc Commercial game engines  You can license the whole engine and tools and a single package  Good if you're doing exactly that type of game

23. Languages C/C++ Java Script: Flash, Python, LISP, etc. C# XNA for PC and Xbox

24. C++ C used to be the most popular language for games Today, C++ is the language of choice for game development

25. C++: Strengths - I Performance  Control over low-level functionality (memory management, etc)  Can switch to assembly or C whenever necessary  Good interface with OS, hardware, and other languages High-level, object-oriented  High-level language features are essential for making today's complex games  Has inheritance, polymorphism, templates, and exceptions  Strongly typed, so it has improved reliability

26. C++: Strengths - II C Heritage  C++ is the only high-level language that is backwards-compatible with C  Has APIs and compiler support in all platforms  Easier transition for experienced programmers Libraries  STL (Standard Template Library) Comprehensive set of standard libraries  Boost: widely used library with wide variety of functionality  Many commercial C++ libraries also available

27. C++: Weaknesses - I Too low-level  Still forces programmers to deal with low-level issues  Too error-prone  Attention to low-level details is overkill for high-level features or tools Slow iteration  C++ is fully compiled into binary format from source code  Compiling large numbers of files is very slow  This will only become more of a problem as games become more complex

28. C++: Weaknesses - II Too complicated  Because of its C heritage, C++ is very complicated  Long learning curve to become competent with the language Lacking features  No reflection or introspection features  No method of object serialization  No native support for message passing

29. C++: When to Use It? When performance is crucial If your current code base is mostly C and C++ If you have a lot of in-house expertise in C++ Avoid using it for high-level code, such as tools

30. Java for Game Development Why use Java?  It's a high-level OO language that simplifies many C++ features  Adds several useful high-level features  Easy to develop for multiple platforms because of intermediate bytecode  Good library support

31. Java Performance Has typically been Java's weak point Has improved in the last few years: still not up to C++ level, but very close Uses Just-In-Time compiling and HotSpot optimizations Now has high-performance libraries Also has access to native functionality

32. Java Platforms Well suited to downloadable and browser-based games Dominates development on mobile and handheld platforms Possible to use in full PC games, but more likely to be embedded into a game

33. Commercial Games using Java Downloadable games like those from PopCap Games: Mummy Maze, etc Online card games PC games using Java as a scripting language: Vampire: The Masquerade, Star Wars Galaxies PC games fully written in Java: You Don't Know Jack, Who Wants to Be a Millionaire

34. C# Developed by MS, now ISO standard A simple, modern, general-purpose, object- oriented programming language Support for software engineering principles:  strong type checking  array bounds checking  detection of attempts to use uninitialized variables  automatic garbage collection. Software robustness, durability, and programmer productivity are important.

35. Strength and Weakness C# is intended to be suitable for writing applications for both hosted and embedded systems Source code portability is very important, as is programmer portability Although is intended to be economical (memory/processing power), it cannot compete directly with C or assembly language.

36. Scripting Languages Why use scripting languages?  Ease and speed of development  Short iteration time  Code becomes a game asset  Offer additional features and are customizable

37. Drawbacks of Scripting Languages Slow performance Limited tool support Dynamic typing makes it difficult to catch errors Awkward interface with the rest of the game Difficult to implement well

38. Popular scripting languages Python Lua Other off-the-shelf options such as Ruby, Perl, Javascript Custom scripting languages  UnrealScript, QuakeC, NWNScript

39. Lua Example

40. Choose a Scripting Languages Consider whether you need one at all What features do you need? What kind of performance do you need? What debugging facilities does the language have? On what platforms does it need to run? What resources and expertise are available?

41. Programming Fundamentals

42. Data Structures: Array Elements are adjacent in memory (great cache consistency)  Requires continuous memory space They never grow or get reallocated  Use dynamic incremental array concept  GCC has a remalloc function In C++ there's no check for going out of bounds  Use vector if possible  Keep in mind of checking boundaries Inserting and deleting elements in the middle is expensive

43. List Very cheap to add/remove elements. Available in the STL (std::list) Every element is allocated separately, not placed contiguously in memory  Lots of little allocations  Bad cache awareness, but can use arrays to hold pre-allocated items Single/Double linked list

44. Lists

45. Dictionaries Maps a set of keys to some data. std::map, std::hash, etc Very fast access to data Perfect for mapping IDs to pointers, or resource handles to objects May waste space, need to design comparison operators

46. Hash Table

47. Others Stacks  First in, last out  std::stack adaptor in STL Queues  First in, first out  std::deque  Priority queue is useful in game to schedule events

48. Stack/Queue/Priority Queue

49. Bit packing Fold all necessary data into a smaller number of bits Bool in C++ may use up to 4 bytes, thus is very expensive Very useful for storing boolean flags: pack 32 in an integer Possible to apply to numerical values if we can give up range or accuracy Very low level trick  Use shifts to handle the operation or use assembly  Only use when absolutely necessary

50. Bits

51. Inheritance Models “is-a” relationship Extends behavior of existing classes by making minor changes Do not overuse, if possible, use component systerm UML diagram representing inheritance

52. Polymorphism The ability to refer to an object through a reference (or pointer) of the type of a parent class Key concept of object oriented design C++ implements it using virtual functions

53. Multiple Inheritance Allows a class to have more than one base class Derived class adopts characteristics of all parent classes Huge potential for problems (clashes, casting, dreaded diamond, etc) Multiple inheritance of abstract interfaces is much less error prone (virtual inheritance) Java has no multiple inheritance

54. Dreaded Diamond It is an ambiguity that arises when two classes B and C inherit from A, and class D inherits from both B and C. If a method in D calls a method defined in A (and does not override the method), and B and C have overridden that method differently, then from which class does it inherit: B, or C?

55. Component Systems Component system organization

56. Object Factory Creates objects by name Pluggable factory allows for new object types to be registered at runtime Extremely useful in game development for passing messages, creating new objects, loading games, or instantiating new content after game ships

57. Factory Pattern

58. Simple Sample Factory - I

59. Simple Sample Factory - II

60. Singleton Implements a single instance of a class with global point of creation and access For example, GUI Don't overuse it!!!

61. Singleton Example

62. Adapter Convert the interface of a class into another interface clients expect. Adapter lets classes work together that couldn't otherwise because of incompatible interfaces Real interface

63. Adapter Pattern

64. Adapter Example - I

65. Adapter Example - II

66. Observer Allows objects to be notified of specific events with minimal coupling to the source of the event Two parts  subject and observer

67. Observer Pattern

68. Composite Allow a group of objects to be treated as a single object Very useful for GUI elements, hierarchical objects, inventory systems, etc

69. Composite Pattern

70. Composite Pattern Example - I Add many more inherited classes

71. The Five Step Debugging Process 1. Reproduce the problem consistently 2. Collect clues 3. Pinpoint the error 4. Repair the problem 5. Test the solution

72. Expert Debugging Tips Question assumptions Minimize interactions and interference Minimize randomness Break complex calculations into steps Check boundary conditions, use assertions Disrupt parallel computations Exploit tools in the debugger (VC is good, purify) Check code that has recently changed Explain the bug to someone else Debug with a partner (A second pair of eyes) Take a break from the problem Get outside help (call people)