Value (computer science)

In computer science and software programming, a value is the representation of some entity that can be manipulated by a program. The members of a type are the values of that type.^[1]

The "value of a variable" is given by the corresponding mapping in the environment.^[2] In languages with assignable variables, it becomes necessary to distinguish between the r-value (or contents) and the l-value (or location) of a variable.^[3]

In declarative (high-level) languages, values have to be referentially transparent. This means that the resulting value is independent of the location of the expression needed to compute the value. Only the contents of the location (the bits, whether they are 1 or 0) and their interpretation are significant.^{[citation needed]}

Value category

Despite its name, in the C++ language standards this terminology is used to categorize expressions, not values.^[4]: 8.2.1

Assignment: l-values and r-values

Some languages use the idea of l-values and r-values, deriving from the typical mode of evaluation on the left and right-hand side of an assignment statement. An l-value refers to an object that persists beyond a single expression. An r-value is a temporary value that does not persist beyond the expression that uses it.^[5]

The notion of l-values and r-values was introduced by Combined Programming Language (CPL). The notions in an expression of r-value, l-value, and r-value/l-value are analogous to the parameter modes of input parameter (has a value), output parameter (can be assigned), and input/output parameter (has a value and can be assigned), though the technical details differ between contexts and languages.

R-values and addresses

In many languages, notably the C family, l-values have storage addresses that are programmatically accessible to the running program (e.g., via some address-of operator like "&" in C/C++), meaning that they are variables or de-referenced references to a certain memory location. R-values can be l-values (see below) or non-l-values—a term only used to distinguish from l-values. Consider the C expression 4 + 9. When executed, the computer generates an integer value of 13, but because the program has not explicitly designated where in the computer this 13 is stored, the expression is a non l-value. On the other hand, if a C program declares a variable x and assigns the value of 13 to x, then the expression x has a value of 13 and is an l-value.

In C, the term l-value originally meant something that could be assigned to (hence the name, indicating it is on the left side of the assignment operator), but since the reserved word const (constant) was added to the language, the term is now 'modifiable l-value'. In C++11 a special semantic-glyph && exists ( not to be confused with the && operator used for logical operations ), to denote the use/access of the expression's address for the compiler only; i.e., the address cannot be retrieved using the address-of & operator during the run-time of the program (see the use of move semantics). The addition of move semantics complicated the value classification taxonomy by adding to it the concept of an xvalue (expiring value) which refers to an object near the end of its lifetime whose resources can be reused (typically by moving them). This also lead to the creation of the categories glvalue (generalized lvalue) which are lvalues and xvalues and prvalues (pure rvalues) which are rvalues that are not xvalues.^[6]

This type of reference can be applied to all r-values including non-l-values as well as l-values. Some processors provide one or more instructions which take an immediate value, sometimes referred to as "immediate" for short. An immediate value is stored as part of the instruction which employs it, usually to load into, add to, or subtract from, a register. The other parts of the instruction are the opcode, and destination. The latter may be implicit. (A non-immediate value may reside in a register, or be stored elsewhere in memory, requiring the instruction to contain a direct or indirect address [e.g., index register address] to the value.)

The l-value expression designates (refers to) an object. A non-modifiable l-value is addressable, but not assignable. A modifiable l-value allows the designated object to be changed as well as examined. An r-value is any expression, a non-l-value is any expression that is not an l-value. One example is an "immediate value" (see above) and consequently not addressable.

In assembly language

A value can be virtually any kind of data by a given data type, for instance a string, a digit, a single letter.

Processors often support more than one size of immediate data, e.g. 8 or 16 bit, employing a unique opcode and mnemonic for each instruction variant. If a programmer supplies a data value that will not fit, the assembler issues an "Out of range" error message. Most assemblers allow an immediate value to be expressed as ASCII, decimal, hexadecimal, octal, or binary data. Thus, the ASCII character 'A' is the same as 65 or 0x41. The byte order of strings may differ between processors, depending on the assembler and computer architecture.

Notes

1. Mitchell 1996, p. 9.
2. Aho, Alfred V.; Lam, Monica S.; Sethi, Ravi; Ullman, Jeffrey D. (1986). Compilers: Principles, Techniques, and Tools. Addison-Wesley Publishing Company. ISBN 0-201-10088-6.
3. Mitchell 1996, pp. 389–390.
4. "ISO/IEC 14882:2017 Programming languages — C++". 2017.
5. "Lvalues and Rvalues (Visual C++)". Microsoft Developer Network. Retrieved 3 September 2016.
6. William M. Miller. "A Taxonomy of Expression Value Categories" (PDF).

References

• Mitchell, John C. (1996). Foundations for Programming Languages. The MIT Press. ISBN 0-262-13321-0.
• Strachey, Christopher (2000). "Fundamental Concepts in Programming Languages". Higher-Order and Symbolic Computation. 13: 11–49. doi:10.1023/A:1010000313106. S2CID 14124601.

External links

• Value Object
• Transfer Object Pattern