Porting

This article is about moving software to a different system. For engine tuning, see porting (engine). For porting of telephone numbers, see local number portability.

In software engineering, porting is the process of adapting software so that an executable program can be created for a computing environment that is different from the one for which it was originally designed (e.g. different CPU, operating system, or third party library). The term is also used when software/hardware is changed to make them usable in different environments.

Software is portable when the cost of porting it to a new platform is significantly less than the cost of writing it from scratch. The lower the cost of porting software, relative to its implementation cost, the more portable it is said to be.

Etymology

The term "port" is derived from the Italian portare, meaning "to carry". When code is not compatible with a particular operating system or architecture, the code must be "carried" to the new system.

The term is not generally applied to the process of adapting software to run with less memory on the same CPU and operating system, nor is it applied to the rewriting of source code in a different language (i.e. language conversion or translation).

Software developers often claim that the software they write is portable, meaning that little effort is needed to adapt it to a new environment. The amount of effort actually needed depends on several factors, including the extent to which the original environment (the source platform) differs from the new environment (the target platform), the experience of the original authors in knowing which programming language constructs and third party library calls are unlikely to be portable, and the amount of effort invested by the original authors in only using portable constructs (platform specific constructs often provide a cheaper solution).

History

The number of significantly different CPUs and operating systems used on the desktop today is much smaller than in the past. The dominance of the x86 architecture means that most desktop software is never ported to a different CPU. In that same market, the choice of operating systems has effectively been reduced to three: Microsoft Windows, OS X, and BSD Unix/Linux. However, in the embedded systems market, portability remains a significant issue.

International standards, such as those promulgated by the ISO, greatly facilitate porting by specifying details of the computing environment in a way that helps reduce differences between different standards-conforming platforms. Writing software that stays within the bounds specified by these standards represents a practical although nontrivial effort. Porting such a program between two standards-compliant platforms (such as POSIX.1) can be just a matter of loading the source code and recompiling it on the new platform. However, practitioners often find that various minor corrections are required, due to subtle platform differences. Most standards suffer from "gray areas" where differences in interpretation of standards lead to small variations from platform to platform.

There also exists an ever-increasing number of tools to facilitate porting, such as the GNU Compiler Collection, which provides consistent programming languages on different platforms, and Autotools, which automates the detection of minor variations in the environment and adapts the software accordingly before compilation.

The compilers for some high-level programming languages (e.g. Eiffel, Esterel) gain portability by outputting source code in another high level intermediate language (such as C) for which compilers for many platforms are generally available.

Two activities related to (but distinct from) porting are emulating and cross-compiling

Porting compilers

Instead of translating directly into machine code, modern compilers translate to a machine independent intermediate code in order to enhance portability of the compiler and minimize design efforts. The intermediate language defines a virtual machine that can execute all programs written in the intermediate language (a machine is defined by its language and vice versa).[1] The intermediate code instructions are translated into equivalent machine code sequences by a code generator to create executable code. It is also possible to skip the generation of machine code by actually implementing the virtual machine in machine code. This virtual machine implementation is called an interpreter, because it reads in the intermediate code instructions one by one and after each read executes the equivalent machine code sequences (the interpretation) of the read intermediate instruction directly.[2]

The use of intermediate code enhances portability of the compiler, because only the machine dependent code (the interpreter or the code generator) of the compiler itself needs to be ported to the target machine. The remainder of the compiler can be imported as intermediate code and then further processed by the ported code generator or interpreter, thus producing the compiler software or directly executing the intermediate code on the interpreter. The machine independent part can be developed and tested on another machine (the host machine). This greatly reduces design efforts, because the machine independent part needs to be developed only once to create portable intermediate code.[3]

An interpreter is less complex and therefore easier to port than a code generator, because it is not able to do code optimizations due to its limited view of the program code (it only sees one instruction at a time and you need a sequence to do optimization). Some interpreters are extremely easy to port, because they only make minimal assumptions about the instruction set of the underlying hardware. As a result the virtual machine is even simpler than the target CPU.[4]

Writing the compiler sources entirely in the programming language the compiler is supposed to translate, makes the following approach, better known as compiler bootstrapping, feasible on the target machine:

  1. Port the interpreter. This needs to be coded in assembly code, using an already present assembler on the target.
  2. Adapt the source of the code generator to the new machine.
  3. Execute the adapted source using the interpreter with the code generator source as input. This will generate the machine code for the code generator.

The difficult part of coding the optimization routines is done using the high-level language instead of the assembly language of the target.

According to the designers of the BCPL language, interpreted code (in the BCPL case) is more compact than machine code; typically by a factor of two to one. Interpreted code however runs about ten times slower than compiled code on the same machine.[5]

The designers of the Java programming language try to take advantage of the compactness of interpreted code, because in Java a program needs to be transmitted over the Internet before execution can start on the target's Java Virtual Machine.

Porting of video games

"Port (video gaming)" and "Porting of video games" redirect here. For other uses, see Video game port.

Porting is also the term used when a video game designed to run on one platform, be it an arcade, video game console, or personal computer, is converted to run on a different platform. Earlier video game "ports" were often not true ports, but rather reworked versions of the games. However, many 21st century video games are developed using software that can output code for one or more consoles as well as for a PC without the need for actual porting.

Many early ports suffered significant gameplay quality issues because computers greatly differed.[6] Reviews complained of ports of Apple II series games like Crush, Crumble and Chomp not using superior Atari 8-bit features.[7] Lord British stated in 1984 that Origin Systems developed computer games for the Apple II first then ported them to Commodore 64 and Atari, because the latter machines' sprites and other sophisticated features made porting from them to Apple "far more difficult, perhaps even impossible ... the Apple version will never get done".[8] Others worked differently. Ozark Softscape, for example, wrote M.U.L.E. for the Atari first because it preferred to develop for the most advanced computers, removing or altering features as necessary during porting. Such a policy was not always feasible; Dani Bunten stated that "M.U.L.E. can't be done for an Apple".[6]

Arcade perfect video games are those that have been ported from an arcade version to another platform, such as a console or computer, without any alterations to the game's workings. This means that graphics, sound and gameplay, along with the game's other characteristics (including bugs), are identical to the arcade version.

"(Console) port" is a game that was originally made for a console (such as Wii or Xbox 360) before an identical version is created which can be played on a personal computer or any other console. This term has been widely used by the gaming community. The process of porting a game from a console to a PC is often regarded negatively due to the higher levels of performance that computers generally have been underutilized, partially due to console hardware being fixed throughout their run (with games being developed for console specs), while PCs become more powerful as hardware evolves, but also due to ported games sometimes being poorly optimized for PCs, or lazily ported.

See also

Notes

  1. Tanenbaum 1984, Section 1.1 - LANGUAGES,LEVELS, AND VIRTUAL MACHINES, p. 3, describes the terms and their relations.
  2. Tanenbaum 1984, Chapter 1 - INTRODUCTION, p. 2, explains translation and interpretation.
  3. Richards,Whitby-Strevens 1984, Section 7.1 - Introduction, p. 124, explains compiler portability using intermediate code.
  4. Richards,Whitby-Strevens 1984, Section 7.4 - The bootstrapping process and INTCODE, p. 133, explains the role of the INTCODE interpreter.
  5. Richards,Whitby-Strevens 1984, Section 7.4.3 - Example, p. 136, gives an example translation of a BCPL program into INTCODE for the interpreter.
  6. 1 2 Bunten, Dan (December 1984). "Dispatches / Insights From the Strategy Game Design Front". Computer Gaming World. p. 40.
  7. Stanton, Jeffrey; Wells, Robert P. Ph.D.; Rochowansky, Sandra; Mellid, Michael Ph.D., ed. (1984). The Addison-Wesley Book of Atari Software. Addison-Wesley. pp. 21,44,126. ISBN 0-201-16454-X.
  8. "The CGW Computer Game Conference". Computer Gaming World (panel discussion). October 1984. p. 30.

References

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