Library (computing)

In computing, a library is a collection of resources that is leveraged during software development to implement a computer program. Commonly, a library consists of executable code such as compiled functions and classes, or a library can be a collection of source code. A resource library may contain data such as images and text.

A library can be used by multiple, independent consumers (programs and other libraries). This differs from resources defined in a program which can usually only be used by that program. When a consumer uses a library resource, it gains the value of the library without having to implement it itself. Libraries encourage software reuse in a modular fashion. Libraries can use other libraries resulting in a hierarchy of libraries in a program.

When writing code that uses a library, a programmer only needs to know how to use it – not its the internal details. For example, a program could use a library that abstracts a complicated system call so that the programmer can use the system feature without spending time to learn the intricacies of the system function.

History

The idea of a computer library dates back to the first computers created by Charles Babbage. An 1888 paper on his Analytical Engine suggested that computer operations could be punched on separate cards from numerical input. If these operation punch cards were saved for reuse then "by degrees the engine would have a library of its own."^[1]

A woman working next to a filing cabinet containing the subroutine library on reels of punched tape for the EDSAC computer.

In 1947 Goldstine and von Neumann speculated that it would be useful to create a "library" of subroutines for their work on the IAS machine, an early computer that was not yet operational at that time.^[2] They envisioned a physical library of magnetic wire recordings, with each wire storing reusable computer code.^[3]

Inspired by von Neumann, Wilkes and his team constructed EDSAC. A filing cabinet of punched tape held the subroutine library for this computer.^[4] Programs for EDSAC consisted of a main program and a sequence of subroutines copied from the subroutine library.^[5] In 1951 the team published the first textbook on programming, The Preparation of Programs for an Electronic Digital Computer, which detailed the creation and the purpose of the library.^[6]

COBOL included "primitive capabilities for a library system" in 1959,^[7] but Jean Sammet described them as "inadequate library facilities" in retrospect.^[8]

JOVIAL has a Communication Pool (COMPOOL), roughly a library of header files.

Another major contributor to the modern library concept came in the form of the subprogram innovation of FORTRAN. FORTRAN subprograms can be compiled independently of each other, but the compiler lacked a linker. So prior to the introduction of modules in Fortran-90, type checking between FORTRAN^{[NB 1]} subprograms was impossible.^[9]

By the mid 1960s, copy and macro libraries for assemblers were common. Starting with the popularity of the IBM System/360, libraries containing other types of text elements, e.g., system parameters, also became common.

In IBM's OS/360 and its successors this is called a partitioned data set.

The first object-oriented programming language, Simula, developed in 1965, supported adding classes to libraries via its compiler. ^[10] ^[11]

Linking

The linking (or binding) process resolves references known as symbols (or links) by searching for them in various locations including configured libraries. If a linker (or binder) does not find a symbol, then it fails, but multiple matches may or may not cause failure.

Static linking describes the process of linking at build-time such that the library executable code is included in the program. Dynamic linking describes the process of linking at run-time and involves building the program with information that supports run-time linking to a dynamic link library (DLL). For dynamic linking, a compatible DLL file must be available to the program at run-time, but for static linking, the program is standalone.

Smart linking describes a feature of a build tool that excludes unused code. For example, a program that only uses integers for arithmetic, or does no arithmetic operations at all, can exclude floating-point library routines. This can lead to smaller program file size and reduced memory usage.

Relocation

Some references in a program or library module are stored in a relative or symbolic form which cannot be resolved until all code and libraries are assigned final static addresses. Relocation is the process of adjusting these references, and is done either by the linker or the loader. In general, relocation cannot be done to individual libraries themselves because the addresses in memory may vary depending on the program using them and other libraries they are combined with. Position-independent code avoids references to absolute addresses and therefore does not require relocation.

Categories

Executable

An executable library consists of code that has been converted from source code into machine code or an intermediate form such as bytecode. A linker allows for using library objects by associating each reference with an address at which the object is located. For example, in C, a library function is invoked via C's normal function call syntax and semantics.^[12]

Static

A static library is an executable library that is linked into a program at build-time by a linker (or whatever the build tool is called that does linking).^[13]^[14] This process, and the resulting stand-alone file, is known as a static build of the program. A static build may not need any further relocation if virtual memory is used and no address space layout randomization is desired.^[15]

A static library is sometimes called an archive on Unix-like systems.

Dynamic

A dynamic library is linked when the program is run – either at load-time or runtime. The dynamic library was intended after the static library to support additional software deployment flexibility.

Source

A source library consists of source code; not compiled code.

Shared

A shared library is a library that is intended to be used by multiple consumers such as different programs, at the same time or in different contexts. Shared can apply to any other classification including static, dynamic, executable and source.

Object

Although generally an obsolete technology today, an object library exposes resources for object-oriented programming (OOP) and a distributed object is a remote object library. Examples include: COM/DCOM, SOM/DSOM, DOE, PDO and various CORBA-based systems.

The object library technology was developed since as OOP became popular, it became apparent that OOP runtime binding required information than contemporary libraries did not provide. In addition to the names and entry points of the code located within, due to inheritance, OOP binding also requires a list of dependencies – since the full definition of a method may be in different places. Further, this requires more than listing that one library requires the services of another. In OOP, the libraries themselves may not be known at compile time, and vary from system to system.

The remote object technology was developed in parallel to support multi-tier programs with a user interface application running on a personal computer (PC) using services of a mainframe or minicomputer such as data storage and processing. For instance, a program on a PC would send messages to a minicomputer via remote procedure call (RPC) to retrieve relatively small samples from a relatively large dataset. In response, distrubuted object technology was developed.

Class

A class library contains classes that can be used to create objects. In Java, for example, classes are contained in JAR files and objects are created at runtime from the classes. However, in Smalltalk, a class library is the starting point for a system image that includes the entire state of the environment, classes and all instantiated objects. Most class libraries are stored in a package repository (such as Maven Central for Java). Client code explicitly specifies dependencies to external libraries in build configuration files (such as a Maven Pom in Java).

Remote

A remote library runs on another computer and its assets are accessed via remote procedure call (RPC) over a network. This distributed architecture allows for minimizing installation of the library and support for it on each consuming system and ensuring consistent versioning. A significant downside is that each library call entails significantly more overhead than for a local library.

Runtime

A runtime library provides access to the runtime environment that is available to a program – tailored to the host platform.

Language standard

Many modern programming languages specify a standard library that provides a base level of functionality for the language environment.

Code generation

A code generation library has a high-level API generating or transforming byte code for Java. They are used by aspect-oriented programming, some data access frameworks, and for testing to generate dynamic proxy objects. They also are used to intercept field access.^[16]

File naming

Unix-like

On most modern Unix-like systems, library files are stored in directories such as /lib, /usr/lib and /usr/local/lib. A filename typically starts with lib, and ends with .a for a static library (archive) or .so for a shared object (dynamically linked library). For example, libfoo.a and libfoo.so.

Often, symbolic link files are used to manage versioning of a library by providing a link file named without a version that links to a file named with a version. For example, libfoo.so.2 might be version 2 of library foo and a link file named libfoo.so provides a version independent name to that file that programs link to. The link file could be changed to a refer to a version 3 (libfoo.so.3) such that consuming programs will then use version 3 without having to change the program.

Files with extension .la are libtool archives; not usable by the system.

macOS

The macOS system inherits static library conventions from BSD, with the library stored in a .a file. It uses either .so or .dylib for dynamic libraries. Most libraries in macOS, however, consist of "frameworks", placed inside special directories called "bundles" which wrap the library's required files and metadata. For example, a framework called Abc would be implemented in a bundle called Abc.framework, with Abc.framework/Abc being either the dynamically linked library file or a symlink to the dynamically linked library file in Abc.framework/Versions/Current/Abc.

Windows

Often, a Windows dynamic-link library (DLL) has the file extension .dll,^[17] although sometimes different extensions are used to indicate general content, e.g. .ocx for a OLE library.

A .lib file can be either a static library or contain the information needed to build an application that consumes the associated DLL. In the latter case, the associated DLL file must be present at runtime.

Notes

^ It was possible earlier between, e.g., Ada subprograms.

References

^ Babbage, H. P. (1888-09-12). "The Analytical Engine". Proceedings of the British Association. Bath.
^ Goldstine, Herman H. (2008-12-31). The Computer from Pascal to von Neumann. Princeton: Princeton University Press. doi:10.1515/9781400820139. ISBN 978-1-4008-2013-9.
^ Goldstine, Herman; von Neumann, John (1947). Planning and coding of problems for an electronic computing instrument (Report). Institute for Advanced Study. pp. 3, 21–22. OCLC 26239859. it will probably be very important to develop an extensive "library" of subroutines
^ Wilkes, M. V. (1951). "The EDSAC Computer". 1951 International Workshop on Managing Requirements Knowledge. 1951 International Workshop on Managing Requirements Knowledge. IEEE. p. 79. doi:10.1109/afips.1951.13.
^ Campbell-Kelly, Martin (September 2011). "In Praise of 'Wilkes, Wheeler, and Gill'". Communications of the ACM. 54 (9): 25–27. doi:10.1145/1995376.1995386. S2CID 20261972.
^ Wilkes, Maurice; Wheeler, David; Gill, Stanley (1951). The Preparation of Programs for an Electronic Digital Computer. Addison-Wesley. pp. 45, 80–91, 100. OCLC 641145988.
^ Wexelblat, Richard (1981). History of Programming Languages. ACM Monograph Series. New York, NY: Academic Press (A subsidiary of Harcourt Brace). p. 274. ISBN 0-12-745040-8.
^ Wexelblat, op. cit., p. 258
^ Wilson, Leslie B.; Clark, Robert G. (1988). Comparative Programming Languages. Wokingham, England: Addison-Wesley. p. 126. ISBN 0-201-18483-4.
^ Wilson and Clark, op. cit., p. 52
^ Wexelblat, op. cit., p. 716
^ Deshpande, Prasad (2013). Metamorphic Detection Using Function Call Graph Analysis (Thesis). San Jose State University Library. doi:10.31979/etd.t9xm-ahsc.
^ "Static Libraries". TLDP. Archived from the original on 2013-07-03. Retrieved 2013-10-03.
^ Kaminsky, Dan (2008). "Chapter 3 - Portable Executable and Executable and Linking Formats". Reverse Engineering Code with IDA Pro. Elsevier. pp. 37–66. doi:10.1016/b978-1-59749-237-9.00003-x. ISBN 978-1-59749-237-9. Retrieved 2021-05-27.
^ Collberg, Christian; Hartman, John H.; Babu, Sridivya; Udupa, Sharath K. (2003). SLINKY: Static Linking Reloaded. USENIX '05. Department of Computer Science, University of Arizona. Archived from the original on 2016-03-23. Retrieved 2016-03-17.
^ "Code Generation Library". Source Forge. Archived from the original on 2010-01-12. Retrieved 2010-03-03. Byte Code Generation Library is high level API to generate and transform JAVA byte code. It is used by AOP, testing, data access frameworks to generate dynamic proxy objects and intercept field access.
^ Bresnahan, Christine; Blum, Richard (2015-04-27). LPIC-1 Linux Professional Institute Certification Study Guide: Exam 101-400 and Exam 102-400. John Wiley & Sons (published 2015). p. 82. ISBN 9781119021186. Archived from the original on 2015-09-24. Retrieved 2015-09-03. Linux shared libraries are similar to the dynamic link libraries (DLLs) of Windows. Windows DLLs are usually identified by .dll filename extensions.

v t e Computer science
Note: This template roughly follows the 2012 ACM Computing Classification System.
Hardware	Printed circuit board Peripheral Integrated circuit Very Large Scale Integration Systems on Chip (SoCs) Energy consumption (Green computing) Electronic design automation Hardware acceleration Processor Size / Form
Computer systems organization	Computer architecture Computational complexity Dependability Embedded system Real-time computing
Networks	Network architecture Network protocol Network components Network scheduler Network performance evaluation Network service
Software organization	Interpreter Middleware Virtual machine Operating system Software quality
Software notations and tools	Programming paradigm Programming language Compiler Domain-specific language Modeling language Software framework Integrated development environment Software configuration management Software library Software repository
Software development	Control variable Software development process Requirements analysis Software design Software construction Software deployment Software engineering Software maintenance Programming team Open-source model
Theory of computation	Model of computation Stochastic Formal language Automata theory Computability theory Computational complexity theory Logic Semantics
Algorithms	Algorithm design Analysis of algorithms Algorithmic efficiency Randomized algorithm Computational geometry
Mathematics of computing	Discrete mathematics Probability Statistics Mathematical software Information theory Mathematical analysis Numerical analysis Theoretical computer science
Information systems	Database management system Information storage systems Enterprise information system Social information systems Geographic information system Decision support system Process control system Multimedia information system Data mining Digital library Computing platform Digital marketing World Wide Web Information retrieval
Security	Cryptography Formal methods Security hacker Security services Intrusion detection system Hardware security Network security Information security Application security
Human–computer interaction	Interaction design Social computing Ubiquitous computing Visualization Accessibility
Concurrency	Concurrent computing Parallel computing Distributed computing Multithreading Multiprocessing
Artificial intelligence	Natural language processing Knowledge representation and reasoning Computer vision Automated planning and scheduling Search methodology Control method Philosophy of artificial intelligence Distributed artificial intelligence
Machine learning	Supervised learning Unsupervised learning Reinforcement learning Multi-task learning Cross-validation
Graphics	Animation Extended reality Augmented Mixed Virtual Rendering Photograph manipulation Graphics processing unit Image compression Solid modeling
Applied computing	Quantum Computing E-commerce Enterprise software Computational mathematics Computational physics Computational chemistry Computational biology Computational social science Computational engineering Differentiable computing Computational healthcare Digital art Electronic publishing Cyberwarfare Electronic voting Video games Word processing Operations research Educational technology Document management
Category Outline Glossaries

v t e Application binary interface (ABI)
Parts, conventions	Alignment Calling convention Call stack Library static Machine code Memory segmentation Name mangling Object code Opaque pointer Position-independent code Relocation System call Virtual method table
Related topics	Binary-code compatibility Foreign function interface Language binding Linker dynamic Loader Year 2038 problem

Authority control databases
International	FAST
National	Germany United States Czech Republic Israel