Boolean data type

In computer science, the Boolean data type is a data type, having two values (usually denoted true and false), intended to represent the truth values of logic and Boolean algebra. It is named after George Boole, who first defined an algebraic system of logic in the mid 19th century. The Boolean data type is primarily associated with conditional statements, which allow different actions and change control flow depending on whether a programmer-specified Boolean condition evaluates to true or false. It is a special case of a more general logical data type; logic does not always have to be Boolean.

Generalities

In programming languages that have a built-in Boolean data type, such as Pascal and Java, the comparison operators such as > and are usually defined to return a Boolean value. Conditional and iterative commands may be defined to test Boolean-valued expressions.

Languages without an explicit Boolean data type, like C90 and Lisp, may still represent truth values by some other data type. Common Lisp uses an empty list for false, and any other value for true. C uses an integer type, where relational expressions like i > j and logical expressions connected by && and || are defined to have value 1 if true and 0 if false, whereas the test parts of if, while, for, etc., treat any non-zero value as true.[1][2] Indeed, a Boolean variable may be regarded (and be implemented) as a numerical variable with a single binary digit (bit), which can store only two values. It is worth noting that the implementation of Booleans in computers are most likely represented as a full word, rather than a bit; this is usually due to the ways computers transfer blocks of information.

Most programming languages, even those that do not have an explicit Boolean type, have support for Boolean algebraic operations such as conjunction (AND, &, *), disjunction (OR, |, +), equivalence (EQV, =, ==), exclusive or/non-equivalence (XOR, NEQV, ^, !=), and negation (NOT, ~, !).

In some languages, like Ruby, Smalltalk, and Alice the "true" and "false" values belong to separate classes—i.e. True and False, resp.—so there is no single Boolean "type."

In SQL, which uses a three-valued logic for explicit comparisons because of its special treatment of Nulls, the Boolean data type (introduced in SQL:1999) is also defined to include more than two truth values, so that SQL "Booleans" can store all logical values resulting from the evaluation of predicates in SQL. A column of Boolean type can also be restricted to just TRUE and FALSE though.

ALGOL and the built in boolean type

One of the earliest programming languages to provide an explicit boolean data type was ALGOL 60 (1960) with values true and false and logical operators denoted by symbols '' (and), '' (or), '' (implies), '' (equivalence), and '' (not). Due to input device and character set limitations on many computers of the time, however, most compilers used alternative representations for many of the operators, such as AND or 'AND'.

This approach with boolean as a built-in (either primitive or otherwise predefined) data type was adopted by many later programming languages, such as Simula 67 (1967), ALGOL 68 (1970),[3] Pascal (1970), Ada (1980), Java (1995), and C# (2000), among others.

Fortran

The first version of FORTRAN (1957) and its successor FORTRAN II (1958) did not have logical values or operations; even the conditional IF statement took an arithmetic expression and branched to one of three locations according to its sign; see arithmetic IF. FORTRAN IV (1962), however, followed the ALGOL 60 example by providing a Boolean data type (LOGICAL), truth literals (.TRUE. and .FALSE.), Boolean-valued numeric comparison operators (.EQ., .GT., etc.), and logical operators (.NOT., .AND., .OR.). In FORMAT statements, a specific control character ('L') was provided for the parsing or formatting of logical values.[4]

Lisp and Scheme

The Lisp language (1958) never had a built-in Boolean data type. Instead, conditional constructs like cond assume that the logical value "false" is represented by the empty list (), which is defined to be the same as the special atom nil or NIL; whereas any other s-expression is interpreted as "true". For convenience, most modern dialects of Lisp predefine the atom t to have value t, so that one can use t as a mnemonic notation for "true".

This approach ("any value can be used as a Boolean value") was retained in most Lisp dialects (Common Lisp, Scheme, Emacs Lisp), and similar models were adopted by many scripting languages, even ones that do have a distinct Boolean type or Boolean values; although which values are interpreted as "false" and which are "true" vary from language to language. In Scheme, for example, the "false" value is an atom distinct from the empty list, so the latter is interpreted as "true".

Pascal, Ada, and Haskell

The Pascal language (1970) introduced the concept of programmer-defined enumerated types. A built-in Boolean data type was then provided as a predefined enumerated type with values FALSE and TRUE. By definition, all comparisons, logical operations, and conditional statements applied to and/or yielded Boolean values. Otherwise, the Boolean type had all the facilities which were available for enumerated types in general — such as ordering and use as indices. On the other hand, the conversion between Booleans and integers (or any other types) still required explicit tests or function calls, as in ALGOL 60. This approach ("Boolean is an enumerated type") was adopted by most later languages which had enumerated types, such as Modula, Ada and Haskell.

C, C++, Objective-C, AWK

The initial implementations of the C language (1972) provided no Boolean type, and to this day Boolean values are commonly represented by integers (ints) in C programs. The comparison operators (>, ==, etc.) are defined to return a signed integer (int) result, either 0 (for false) or 1 (for true). Logical operators (&&, ||, !, etc.) and condition-testing statements (if, while) assume that zero is false and all other values are true.

After enumerated types (enums) were added to the ANSI version of C (1989), many C programmers got used to defining their own Boolean types as such, for readability reasons. However, enumerated types are equivalent to integers according to the language standards; so the effective identity between Booleans and integers is still valid for C programs.

Standard C (since C99) provides a boolean type, called _Bool. By including the header stdbool.h one can use the more intuitive name bool and the constants true and false. The language guarantees that any two true values will compare equal (which was impossible to achieve before the introduction of the type). Boolean values still behave as integers, can be stored in integer variables, and used anywhere integers would be valid, including in indexing, arithmetic, parsing, and formatting. This approach ("Boolean values are just integers") has been retained in all later versions of C.

C++ has a separate Boolean data type bool, but with automatic conversions from scalar and pointer values that are very similar to those of C. This approach was adopted also by many later languages, especially by some scripting ones such as AWK.

Objective-C also has a separate Boolean data type BOOL, with possible values being YES or NO, equivalents of true and false respectively.[5] In addition, in Objective-C compilers that support C99, the C's _Bool type can be used since Objective-C is a superset of C.

Perl and Lua

In Perl, there is no boolean data type. Instead, any value can behave as boolean in boolean context (condition of if or while statement, argument of && or ||, etc.). The number 0, the strings "0" and "", the empty list (), and the special value undef evaluate to false.[6] Everything else evaluates to true.

In Lua, there is a boolean data type, but non-boolean value can also behave as boolean. The non-value nil evaluate to false, whereas every other data type always evaluates to true, regardless of value.

Python, Ruby, and JavaScript

In Python from version 2.3 forward, there is a bool type which is a subclass of int, the standard integer type.[7] It has two possible values: True and False, which are "special versions" of 1 and 0 respectively and behave as such in arithmetic contexts. In addition, a numeric value of zero (integer or fractional), the null value (None), the empty string, and empty containers (i.e. lists, sets, etc.) are considered Boolean false; all other values are considered Boolean true by default.[8] Classes can define how their instances are treated in a Boolean context through the special method __nonzero__ (Python 2) or __bool__ (Python 3). For containers, __len__ (the special method for determining the length of containers) is used if the explicit Boolean conversion method is not defined.

In Ruby, on the other hand, only nil (Ruby's null value) and a special false object are "false", everything else (including the integer 0 and empty arrays) is "true".

In JavaScript, the empty string (""), null, undefined, NaN, +0, −0 and false[9] are sometimes called "falsy", and their complement, "truthy", to distinguish between strictly type-checked and coerced Booleans.[10] Languages such as PHP also use this approach.

SQL

The SQL:1999 standard introduced a BOOLEAN data type as an optional feature (T031). When restricted by a NOT NULL constraint, a SQL BOOLEAN behaves like Booleans in other languages. In SQL however, the BOOLEAN type is nullable by default like all other SQL data types, meaning it can have the special null value as well. Although the SQL standard defines three literals for the BOOLEAN typeTRUE, FALSE and UNKNOWN, it also says that the NULL BOOLEAN and UNKNOWN "may be used interchangeably to mean exactly the same thing".[11][12] This has caused some controversy because the identification subjects UNKNOWN to the equality comparison rules for NULL. More precisely UNKNOWN = UNKNOWN is not TRUE but UNKNOWN/NULL.[13] As of 2012 few major SQL systems implement the T031 feature.[14] PostgreSQL is a notable exception, although it does not implement the UNKNOWN literal; NULL can be used instead.[15]

See also

References

  1. Kernighan, Brian W; Ritchie, Dennis M (1978). The C Programming Language (1st ed.). Englewood Cliffs, NJ: Prentice Hall. p. 41. ISBN 0-13-110163-3.
  2. Plauger, PJ; Brodie, Jim (1992) [1989]. ANSI and ISO Standard C Programmer's reference. Microsoft Press. pp. 86–93. ISBN 1-55615-359-7.
  3. "Report on the Algorithmic Language ALGOL 68, Section 10.2.2." (PDF). August 1968. Retrieved April 2007. Check date values in: |access-date= (help)
  4. Digital Equipment Corporation, DECSystem10 FORTRAN IV Programmers Reference Manual. Reprinted in Mathematical Languages Handbook. Online version accessed 2011-11-16.
  5. http://developer.apple.com/library/ios/#documentation/cocoa/conceptual/ProgrammingWithObjectiveC/FoundationTypesandCollections/FoundationTypesandCollections.html
  6. "perlsyn - Perl Syntax / Truth and Falsehood". Retrieved 10 September 2013.
  7. Van Rossum, Guido (3 April 2002). "PEP 285 -- Adding a bool type". Retrieved 15 May 2013.
  8. "Expressions". Python v3.3.2 documentation. Retrieved 15 May 2013.
  9. "ECMAScript Language Specification" (PDF). p. 43.
  10. "The Elements of JavaScript Style". Douglas Crockford. Retrieved 5 March 2011.
  11. C. Date (2011). SQL and Relational Theory: How to Write Accurate SQL Code. O'Reilly Media, Inc. p. 83. ISBN 978-1-4493-1640-2.
  12. ISO/IEC 9075-2:2011 §4.5
  13. Martyn Prigmore (2007). Introduction to Databases With Web Applications. Pearson Education Canada. p. 197. ISBN 978-0-321-26359-9.
  14. Troels Arvin, Survey of BOOLEAN data type implementation
  15. http://www.postgresql.org/docs/current/static/datatype-boolean.html
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