computing Computing is any goal-oriented activity requiring, benefiting from, or creating computing machinery. It includes the study and experimentation of algorithmic processes, and development of both hardware and software. Computing has scientific, ...

, compile-time function execution (or compile time function evaluation, or general constant expressions) is the ability of a

compiler In computing, a compiler is a computer program that translates computer code written in one programming language (the ''source'' language) into another language (the ''target'' language). The name "compiler" is primarily used for programs tha ...

, that would normally compile a

function Function or functionality may refer to: Computing * Function key, a type of key on computer keyboards * Function model, a structured representation of processes in a system * Function object or functor or functionoid, a concept of object-oriente ...

machine code In computer programming, machine code is any low-level programming language, consisting of machine language instructions, which are used to control a computer's central processing unit (CPU). Each instruction causes the CPU to perform a ve ...

and

execute Execute, in capital punishment, is to put someone to death. Execute may also refer to: * Execution (computing), the running of a computer program * ''Execute'' (album), a 2001 Garage hip-hop album by Oxide & Neutrino * USS ''Execute'' (AM-232), a ...

it at

run time Run(s) or RUN may refer to: Places * Run (island), one of the Banda Islands in Indonesia * Run (stream), a stream in the Dutch province of North Brabant People * Run (rapper), Joseph Simmons, now known as "Reverend Run", from the hip-hop group ...

, to execute the function at

compile time In computer science, compile time (or compile-time) describes the time window during which a computer program is compiled. The term is used as an adjective to describe concepts related to the context of program compilation, as opposed to concep ...

. This is possible if the arguments to the function are known at compile time, and the function does not make any reference to or attempt to modify any global state (i.e. it is a

pure function In computer programming, a pure function is a function that has the following properties: # the function return values are identical for identical arguments (no variation with local static variables, non-local variables, mutable reference argume ...

). If the value of only some of the arguments are known, the compiler may still be able to perform some level of compile-time function execution ( partial evaluation), possibly producing more optimized code than if no arguments were known.

Examples

Lisp

The Lisp macro system is an early example of the use of compile-time evaluation of user-defined functions in the same language.

C++

The Metacode extension to C++ (Vandevoorde 2003) was an early experimental system to allow compile-time function evaluation (CTFE) and code injection as an improved syntax for C++

template metaprogramming Template metaprogramming (TMP) is a metaprogramming technique in which templates are used by a compiler to generate temporary source code, which is merged by the compiler with the rest of the source code and then compiled. The output of these t ...

. In earlier versions of

C++ C++ (pronounced "C plus plus") is a high-level general-purpose programming language created by Danish computer scientist Bjarne Stroustrup as an extension of the C programming language, or "C with Classes". The language has expanded significan ...

is often used to compute values at compile time, such as: template struct Factorial ; template <> struct Factorial<0> ; // Factorial<4>::value

24 // Factorial<0>::value

1 void Foo() Using compile-time function evaluation, code used to compute the factorial would be similar to what one would write for run-time evaluation e.g. using C++11 constexpr. #include constexpr int Factorial(int n) constexpr int f10 = Factorial(10); int main() In

C++11 C++11 is a version of the ISO/ IEC 14882 standard for the C++ programming language. C++11 replaced the prior version of the C++ standard, called C++03, and was later replaced by C++14. The name follows the tradition of naming language versions b ...

, this technique is known as generalized constant expressions (constexpr).

C++14 C++14 is a version of the ISO/IEC 14882 standard for the C++ programming language. It is intended to be a small extension over C++11, featuring mainly bug fixes and small improvements, and was replaced by C++17. Its approval was announced on Augus ...

relaxes the constraints on constexpr – allowing local declarations and use of conditionals and loops (the general restriction that all data required for the execution be available at compile-time remains). Here's an example of compile time function evaluation in C++14: // Iterative factorial at compile time. constexpr int Factorial(int n) int main()

Immediate functions (C++)

C++20 C20 or C-20 may refer to: Science and technology * Carbon-20 (C-20 or 20C), an isotope of carbon * C20, the smallest possible fullerene (a carbon molecule) * C20 (engineering), a mix of concrete that has a compressive strength of 20 newtons per sq ...

, immediate functions were introduced, and compile-time function execution was made more accessible and flexible with relaxed constexpr restrictions. // Iterative factorial at compile time. consteval int Factorial(int n) int main() Since function Factorial is marked consteval, it is guaranteed to invoke at compile-time without being forced in another manifestly constant-evaluated context. Hence, the usage of immediate functions offers wide uses in metaprogramming, and compile-time checking (used in C++20 text formatting library). Here's an example of using immediate functions in compile-time function execution: void you_see_this_error_because_assertion_fails() consteval void cassert(bool b) consteval void test() int main() In this example, the compilation fails because the immediate function invoked function which is not usable in constant expressions. In other words, the compilation stops after failed assertion. The typical compilation error message would display: In function 'int main()': in 'constexpr' expansion of 'test()' in 'constexpr' expansion of 'cassert(x

12)' error: call to non-'constexpr' function 'you_see_this_error_because_assertion_fails()' you_see_this_error_because_assertion_fails(); ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~^~ ... Here's another example of using immediate functions as constructors which enables compile-time argument checking: #include #include void you_see_this_error_because_the_message_ends_with_exclamation_point() struct checked_message ; void send_calm_message(checked_message arg) int main() The compilation fails here with the message: In function 'int main()': in 'constexpr' expansion of 'checked_message(((const char*)"Hello, world!"))' error: call to non-'constexpr' function 'void you_see_this_error_because_the_message_ends_with_exclamation_point()' you_see_this_error_because_the_message_ends_with_exclamation_point(); ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~^~ ...

D

Here's an example of compile time function evaluation in the

D programming language D, also known as dlang, is a multi-paradigm system programming language created by Walter Bright at Digital Mars and released in 2001. Andrei Alexandrescu joined the design and development effort in 2007. Though it originated as a re-engineer ...

: int factorial(int n) // computed at compile time enum y = factorial(0); //

1 enum x = factorial(4); //

24 This example specifies a valid D function called "factorial" which would typically be evaluated at run time. The use of enum tells the compiler that the initializer for the variables must be computed at compile time. Note that the arguments to the function must be able to be resolved at compile time as well.D 2.0 language specification: Attributes
/ref> CTFE can be used to populate data structures at compile-time in a simple way (D version 2): int[] genFactorials(int n) enum factorials = genFactorials(13); void main() // 'factorials' contains at compile-time: // [1, 1, 2, 6, 24, 120, 720, 5_040, 40_320, 362_880, 3_628_800, // 39_916_800, 479_001_600] CTFE can be used to generate strings which are then parsed and compiled as D code in D.

References

External links

Rosettacode examples of compile-time function evaluation in various languages
{{Compiler optimizations Compiler construction Articles with example D code Compiler optimizations