Software bug

Software development
Core activities
Paradigms and models
Methodologies and frameworks
Supporting disciplines
Tools
Standards and BOKs

A software bug is an error, flaw, failure or fault in a computer program or system that causes it to produce an incorrect or unexpected result, or to behave in unintended ways.

Most bugs arise from mistakes and errors made in either a program's source code or its design, or in components and operating systems used by such programs. A few are caused by compilers producing incorrect code. A program that contains a large number of bugs, and/or bugs that seriously interfere with its functionality, is said to be buggy (defective). Bugs trigger errors that may have ripple effects. Bugs may have subtle effects or cause the program to crash or freeze the computer. Others qualify as security bugs and might, for example, enable a malicious user to bypass access controls in order to obtain unauthorized privileges.

Bugs in code that controls the Therac-25 radiation therapy machine were directly responsible for patient deaths in the 1980s. In 1996, the European Space Agency's US$1 billion prototype Ariane 5 rocket had to be destroyed less than a minute after launch due to a bug in the on-board guidance computer program. In June 1994, a Royal Air Force Chinook helicopter crashed into the Mull of Kintyre, killing 29. This was initially dismissed as pilot error, but an investigation by Computer Weekly convinced a House of Lords inquiry that it may have been caused by a software bug in the aircraft's engine control computer.[1]

In 2002, a study commissioned by the US Department of Commerce's National Institute of Standards and Technology concluded that "software bugs, or errors, are so prevalent and so detrimental that they cost the US economy an estimated $59 billion annually, or about 0.6 percent of the gross domestic product".[2]

Etymology

The term "bug" to describe defects has been a part of engineering jargon for many decades and predates computers and computer software; it may have originally been used in hardware engineering to describe mechanical malfunctions. For instance, Thomas Edison wrote the following words in a letter to an associate in 1878:

It has been just so in all of my inventions. The first step is an intuition, and comes with a burst, then difficulties arise—this thing gives out and [it is] then that "Bugs"—as such little faults and difficulties are called—show themselves and months of intense watching, study and labor are requisite before commercial success or failure is certainly reached.[3]

The Middle English word bugge is the basis for the terms "bugbear" and "bugaboo", terms used for a monster.[4] Baffle Ball, the first mechanical pinball game, was advertised as being "free of bugs" in 1931.[5] Problems with military gear during World War II were referred to as bugs (or glitches).[6] In a book published in 1942, Louise Dickinson Rich, speaking of a powered ice cutting machine, said, "Ice sawing was suspended until the creator could be brought in to take the bugs out of his darling."[7]

Isaac Asimov uses the term bug to relate to issues with a robot in his short story "Catch That Rabbit", published in 1944, and included in his well-known collection of short stories I, Robot. From page 1 of "Catch That Rabbit": "U.S. Robots had to get the bugs out of the multiple robot, and there were plenty of bugs, and there are always at least half a dozen bugs left for the field-testing."

A page from the Harvard Mark II electromechanical computer's log, featuring a dead moth that was removed from the device

The term "bug" was used in an account by computer pioneer Grace Hopper, who publicized the cause of a malfunction in an early electromechanical computer.[8] A typical version of the story is:

In 1946, when Hopper was released from active duty, she joined the Harvard Faculty at the Computation Laboratory where she continued her work on the Mark II and Mark III. Operators traced an error in the Mark II to a moth trapped in a relay, coining the term bug. This bug was carefully removed and taped to the log book. Stemming from the first bug, today we call errors or glitches in a program a bug.[9]

Hopper did not find the bug, as she readily acknowledged. The date in the log book was September 9, 1947.[10][11][12] The operators who found it, including William "Bill" Burke, later of the Naval Weapons Laboratory, Dahlgren, Virginia,[13] were familiar with the engineering term and amusedly kept the insect with the notation "First actual case of bug being found." Hopper loved to recount the story.[14] This log book, complete with attached moth, is part of the collection of the Smithsonian National Museum of American History.[11]

The related term "debug" also appears to predate its usage in computing: the Oxford English Dictionary's etymology of the word contains an attestation from 1945, in the context of aircraft engines.[15]

History

The concept that software might contain errors dates back to Ada Lovelace's 1843 notes on the analytical engine, in which she speaks of the possibility of program "cards" for Charles Babbage's analytical engine being erroneous:

... an analysing process must equally have been performed in order to furnish the Analytical Engine with the necessary operative data; and that herein may also lie a possible source of error. Granted that the actual mechanism is unerring in its processes, the cards may give it wrong orders.

"Bugs in the System" report

The Open Technology Institute, run by the group, New America,[16] released a report "Bugs in the System" in August 2016 stating that U.S. policymakers should make reforms to help researchers identify and address software bugs. The report "highlights the need for reform in the field of software vulnerability discovery and disclosure."[17] One of the report’s authors said that Congress has not done enough to address cyber software vulnerability, even though Congress has passed a number of bills to combat the larger issue of cyber security.[17]

Government researchers, companies, and cyber security experts are the people who typically discover software flaws. The report calls for reforming computer crime and copyright laws.[17]

"The Computer Fraud and Abuse Act, the Digital Millennium Copyright Act and the Electronic Communications Privacy Act criminalize and create civil penalties for actions that security researchers routinely engage in while conducting legitimate security research, the report said."[17]

Terminology

There is ongoing debate over the use of the term "bug" to describe software errors. One argument is that the word "bug" is divorced from a sense that a human being caused the problem, and instead implies that the defect arose on its own, leading to a push to abandon the term "bug" in favor of terms such as "defect", with limited success.[18] Since the 1970s Gary Kildall somewhat humorously suggested to use the term "blunder".[19][20]

In software engineering, mistake metamorphism (from Greek meta = "change", morph = "form") refers to the evolution of a defect in the final stage of software deployment. Transformation of a "mistake" committed by an analyst in the early stages of the software development lifecycle, which leads to a "defect" in the final stage of the cycle has been called 'mistake metamorphism'.[21]

Different stages of a "mistake" in the entire cycle may be described as "mistakes", "anomalies", "faults", "failures", "errors", "exceptions", "crashes", "bugs", "defects", "incidents", or "side effects".[21]

Prevention

The software industry has put much effort into reducing bug counts.[22][23] These include:

Typographical errors

Bugs usually appear when the programmer makes a logic error. Various innovations in programming style and defensive programming are designed to make these bugs less likely, or easier to spot. Some typos, especially of symbols or logical/mathematical operators, allow the program to operate incorrectly, while others such as a missing symbol or misspelled name may prevent the program from operating. Compiled languages can reveal some typos when the source code is compiled.

Development methodologies

Several schemes assist managing programmer activity so that fewer bugs are produced. Software engineering (which addresses software design issues as well) applies many techniques to prevent defects. For example, formal program specifications state the exact behavior of programs so that design bugs may be eliminated. Unfortunately, formal specifications are impractical for anything but the shortest programs, because of problems of combinatorial explosion and indeterminacy.

Unit testing involves writing a test for every function (unit) that a program is to perform.

In test-driven development unit tests are written before the code and the code is not considered complete until all tests complete successfully.

Agile software development involves frequent software releases with relatively small changes. Defects are revealed by user feedback.

Open source development allows anyone to examine source code. A school of thought popularized by Eric S. Raymond as Linus's Law says that popular open-source software has more chance of having few or no bugs than other software, because "given enough eyeballs, all bugs are shallow".[24] This assertion has been disputed, however: computer security specialist Elias Levy wrote that "it is easy to hide vulnerabilities in complex, little understood and undocumented source code," because, "even if people are reviewing the code, that doesn't mean they're qualified to do so."[25] An example of this actually happening, accidentally, was the 2008 OpenSSL vulnerability in Debian.

Programming language support

Programming languages include features to help prevent bugs, such as static type systems, restricted namespaces and modular programming. For example, when a programmer writes (pseudocode) LET REAL_VALUE PI = "THREE AND A BIT", although this may be syntactically correct, the code fails a type check. Compiled languages catch this without having to run the program. Interpreted languages catch such errors at runtime. Some languages deliberate exclude features that easily lead to bugs, at the expense of slower performance: the general principle being that, it is almost always better to write simpler, slower code than inscrutable code that runs slightly faster, especially considering that maintenance cost is substantial. For example, the Java programming language does not support pointer arithmetic; implementations of some languages such as Pascal and scripting languages often have runtime bounds checking of arrays, at least in a debugging build.

Code analysis

Tools for code analysis help developers by inspecting the program text beyond the compiler's capabilities to spot potential problems. Although in general the problem of finding all programming errors given a specification is not solvable (see halting problem), these tools exploit the fact that human programmers tend to make certain kinds of simple mistakes often when writing software.

Instrumentation

Tools to monitor the performance of the software as it is running, either specifically to find problems such as bottlenecks or to give assurance as to correct working, may be embedded in the code explicitly (perhaps as simple as a statement saying PRINT "I AM HERE"), or provided as tools. It is often a surprise to find where most of the time is taken by a piece of code, and this removal of assumptions might cause the code to be rewritten.

Testing

Software testers are people whose primary task is to find bugs, or write code to support testing. On some projects, more resources may be spent on testing than in developing the program.

Measurements during testing can provide an estimate of the number of likely bugs remaining; this becomes more reliable the longer a product is tested and developed.

Debugging

The typical bug history (GNU Classpath project data). A new bug submitted by the user is unconfirmed. Once it has been reproduced by a developer, it is a confirmed bug. The confirmed bugs are later fixed. Bugs belonging to other categories (unreproducible, will not be fixed, etc.) are usually in the minority

Finding and fixing bugs, or debugging, is a major part of computer programming. Maurice Wilkes, an early computing pioneer, described his realization in the late 1940s that much of the rest of his life would be spent finding mistakes in his own programs.[26]

Usually, the most difficult part of debugging is finding the bug. Once it is found, correcting it is usually relatively easy. Programs known as debuggers help programmers locate bugs by executing code line by line, watching variable values, and other features to observe program behavior. Without a debugger, code may be added so that messages or values may be written to a console or to a window or log file to trace program execution or show values.

However, even with the aid of a debugger, locating bugs is something of an art. It is not uncommon for a bug in one section of a program to cause failures in a completely different section, thus making it especially difficult to track (for example, an error in a graphics rendering routine causing a file I/O routine to fail), in an apparently unrelated part of the system.

Sometimes, a bug is not an isolated flaw, but represents an error of thinking or planning on the part of the programmer. Such logic errors require a section of the program to be overhauled or rewritten. As a part of code review, stepping through the code and imagining or transcribing the execution process may often find errors without ever reproducing the bug as such.

More typically, the first step in locating a bug is to reproduce it reliably. Once the bug is reproducible, the programmer may use a debugger or other tool while reproducing the error to find the point at which the program went astray.

Some bugs are revealed by inputs that may be difficult for the programmer to re-create. One cause of the Therac-25 radiation machine deaths was a bug (specifically, a race condition) that occurred only when the machine operator very rapidly entered a treatment plan; it took days of practice to become able to do this, so the bug did not manifest in testing or when the manufacturer attempted to duplicate it. Other bugs may disappear when the program is run with a debugger; these heisenbugs (humorously named after the Heisenberg uncertainty principle).

Since the 1990s, particularly following the Ariane 5 Flight 501 disaster, interest in automated aids to debugging rose, such as static code analysis by abstract interpretation.

Some classes of bugs have nothing to do with the code. Faulty documentation or hardware may lead to problems in system use, even though the code matches the documentation. In some cases, changes to the code eliminate the problem even though the code then no longer matches the documentation. Embedded systems frequently work around hardware bugs, since to make a new version of a ROM is much cheaper than remanufacturing the hardware, especially if they are commodity items.

Bug management

Bug management includes the process of documenting, categorizing, assigning, reproducing, correcting and releasing the corrected code. Proposed changes to software – bugs as well as enhancement requests and even entire releases – are commonly tracked and managed using bug tracking systems or issue tracking systems. The items added may be called defects, tickets, issues, or, following the agile development paradigm, stories and epics. Categories may be objective, subjective or a combination, such as version number, area of the software, severity and priority, as well as what type of issue it is, such as a feature request or a bug.

Severity

Severity is the impact the bug has on system operation. This impact may be data loss, financial, loss of goodwill and wasted effort. Severity levels are not standardized. Impacts differ across industry. A crash in a video game has a totally different impact than a crash in a web browser, or real time monitoring system. For example, bug severity levels might be "crash or hang", "no workaround" (meaning there is no way the customer can accomplish a given task), "has workaround" (meaning the user can still accomplish the task), "visual defect" (for example, a missing image or displaced button or form element), or "documentation error". Some software publishers use more qualified severities such as "critical", "high", "low", "blocker" or "trivial".[27] The severity of a bug may be a separate category to its priority for fixing, and the two may be quantified and managed separately.

Priority

Priority controls where a bug falls on the list of planned changes. The priority is decided by each software producer. Priorities are sometimes numerical and sometimes named, such as "critical," "high," "low" or "deferred"; note that these may be similar or even identical to severity ratings when looking at different software producers. For example, priority 1 bugs may always be fixed for the next release, while "5" bugs may never be fixed. Industry practice employs an inverted scale, so that highest priority are low numbers (0 and 1), while larger numbers indicate lower priority.

Relationship between priority and severity

Severe bugs may still not be of high priority. For example, a crash (high severity) that happens only rarely may be low priority. Priority is a strictly increasing function of probability of occurrence and severity. Given probability p = 1, the severity defines the priority. When p = 0, severity is irrelevant. Low severity bugs may get low priority regardless of the probability of occurrence.

One formula for defining the relationship is:

where p is the probability while S is the severity, k a scaling constant, and to invert the value B is the base. The ceiling function limits the domain of priority to only integers. It also assigns priority-B to almost never occurring bugs.

Software releases

It is common practice to release software with known, low-priority bugs. Most big software projects maintain two lists of "known bugs" – those known to the software team, and those to be told to users. The second list informs users about bugs that are not fixed in a specific release and workarounds may be offered. Releases are of different kinds. Bugs of sufficiently high priority may warrant a special release of part of the code containing only modules with those fixes. These are known as patches. Most releases include a mixture of behavior changes and multiple bug fixes. Releases that emphasize bug fixes are known as maintenance releases. Releases that emphasize feature additions/changes are known as major releases and often have names to distinguish the new features from the old.

Reasons that a software publisher opts not to patch or even fix a particular bug include:

Types

In software development projects, a "mistake" or "fault" may be introduced at any stage. Bugs arise from oversights or misunderstandings made by a software team during specification, design, coding, data entry or documentation. For example, a relatively simple program to alphabetize a list of words, the design might fail to consider what should happen when a word contains a hyphen. Or when converting an abstract design into code, the coder might inadvertently create an off-by-one error and fail to sort the last word in a list. Errors may be as simple as a typing error: a "<" where a ">" was intended.

Another category of bug is called a race condition that may occur when programs have multiple components executing at the same time. If the components interact in a different order than the developer intended, they could interfere with each other and stop the program from completing its tasks. These bugs may be difficult to detect or anticipate, since they may not occur during every execution of a program.

Conceptual errors are a developer's misunderstanding of what the software must do. The resulting may perform according to the developer's understanding, but not what is really needed. Other types:

Arithmetic

Logic

Syntax

Resource

Multi-threading

Interfacing

Teamworking

Implications

The amount and type of damage a software bug may cause naturally affects decision-making, processes and policy regarding software quality. In applications such as manned space travel or automotive safety, since software flaws have the potential to cause human injury or even death, such software will have far more scrutiny and quality control than, for example, an online shopping website. In applications such as banking, where software flaws have the potential to cause serious financial damage to a bank or its customers, quality control is also more important than, say, a photo editing application. NASA's Software Assurance Technology Center managed to reduce the number of errors to fewer than 0.1 per 1000 lines of code (SLOC) but this was not felt to be feasible for projects in the business world.

Well-known bugs

A number of software bugs have become well-known, usually due to their severity: examples include various space and military aircraft crashes. Possibly the most famous bug is the Year 2000 problem, also known as the Y2K bug, in which it was feared that worldwide economic collapse would happen at the start of the year 2000 as a result of computers thinking it was 1900. (In the end, no major problems occurred.)

The 2012 stock trading disruption involved one such incompatibility between the old API and a new API.

See also

Notes

  1. Prof. Simon Rogerson. "The Chinook Helicopter Disaster". Ccsr.cse.dmu.ac.uk. Retrieved September 24, 2012.
  2. "Software bugs cost US economy dear". Web.archive.org. June 10, 2009. Archived from the original on June 10, 2009. Retrieved September 24, 2012.
  3. Edison to Puskas, 13 November 1878, Edison papers, Edison National Laboratory, U.S. National Park Service, West Orange, N.J., cited in Hughes, Thomas Parke (1989). American Genesis: A Century of Invention and Technological Enthusiasm, 1870–1970. Penguin Books. p. 75. ISBN 978-0-14-009741-2.
  4. Computerworld staff (September 3, 2011). "Moth in the machine: Debugging the origins of 'bug'". Computerworld.
  5. "Baffle Ball". Internet Pinball Database. (See image of advertisement in reference entry)
  6. "Modern Aircraft Carriers are Result of 20 Years of Smart Experimentation". Life. June 29, 1942. p. 25. Retrieved November 17, 2011.
  7. Dickinson Rich, Louise (1942), We Took to the Woods, JB Lippincott Co, p. 93, LCCN 42024308, OCLC 405243.
  8. FCAT NRT Test, Harcourt, March 18, 2008
  9. "Danis, Sharron Ann: "Rear Admiral Grace Murray Hopper"". ei.cs.vt.edu. February 16, 1997. Retrieved January 31, 2010.
  10. "Bug", The Jargon File, ver. 4.4.7. Retrieved June 3, 2010.
  11. 1 2 "Log Book With Computer Bug", National Museum of American History, Smithsonian Institution.
  12. "The First "Computer Bug", Naval Historical Center. But note the Harvard Mark II computer was not complete until the summer of 1947.
  13. IEEE Annals of the History of Computing, Vol 22 Issue 1, 2000
  14. James S. Huggins. "First Computer Bug". Jamesshuggins.com. Archived from the original on August 16, 2000. Retrieved September 24, 2012.
  15. Journal of the Royal Aeronautical Society. 49, 183/2, 1945 "It ranged ... through the stage of type test and flight test and 'debugging' ..."
  16. Wilson, Andi; Schulman, Ross; Bankston, Kevin; Herr, Trey. "Bugs in the System" (PDF). Open Policy Institute. Retrieved 2016-08-22.
  17. 1 2 3 4 Rozens, Tracy (2016-08-12). "Cyber reforms needed to strengthen software bug discovery and disclosure: New America report – Homeland Preparedness News". Retrieved 2016-08-23.
  18. "News at SEI 1999 Archive". cmu.edu.
  19. Shustek, Len (2016-08-02). "In His Own Words: Gary Kildall". Remarkable People. Computer History Museum.
  20. Kildall, Gary Arlen (2016-08-02) [1993]. Kildall, Scott; Kildall, Kristin, eds. "Computer Connections: People, Places, and Events in the Evolution of the Personal Computer Industry" (Manuscript, part 1). Kildall Family: 14–15. Retrieved 2016-11-17.
  21. 1 2 "Testing experience : te : the magazine for professional testers". Testing Experience. Germany: testingexperience: 42. March 2012. ISSN 1866-5705. (subscription required)
  22. Huizinga, Dorota; Kolawa, Adam (2007). Automated Defect Prevention: Best Practices in Software Management. Wiley-IEEE Computer Society Press. p. 426. ISBN 0-470-04212-5.
  23. McDonald, Marc; Musson, Robert; Smith, Ross (2007). The Practical Guide to Defect Prevention. Microsoft Press. p. 480. ISBN 0-7356-2253-1. Archived from the original on 2006-12-02.
  24. "Release Early, Release Often", Eric S. Raymond, The Cathedral and the Bazaar
  25. "Wide Open Source", Elias Levy, SecurityFocus, April 17, 2000
  26. Maurice Wilkes Quotes
  27. "5.3. Anatomy of a Bug". bugzilla.org.
  28. "The Next Generation 1996 Lexicon A to Z: Slipstream Release". Next Generation. No. 15. Imagine Media. March 1996. p. 41.
  29. Kimbler, K. (1998). Feature Interactions in Telecommunications and Software Systems V. IOS Press. p. 8. ISBN 978-90-5199-431-5.
  30. Syed,, Mahbubur Rahman (1 July 2001). Multimedia Networking: Technology, Management and Applications: Technology, Management and Applications. Idea Group Inc (IGI). p. 398. ISBN 978-1-59140-005-9.
  31. Wu, Chwan-Hwa (John); Irwin, J. David (19 April 2016). Introduction to Computer Networks and Cybersecurity. CRC Press. p. 500. ISBN 978-1-4665-7214-0.
  32. RFC 1263: "TCP Extensions Considered Harmful" quote: "the time to distribute the new version of the protocol to all hosts can be quite long (forever in fact). ... If there is the slightest incompatibly between old and new versions, chaos can result."

Further reading

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