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Sequence of program instructions invokable by other software From Wikipedia, the free encyclopedia
In computer programming, a function (also procedure, method, subroutine, routine, or subprogram) is a callable unit[1] of software logic that has a well-defined interface and behavior and can be invoked multiple times.
Callable units provide a powerful programming tool.[2] The primary purpose is to allow for the decomposition of a large and/or complicated problem into chunks that have relatively low cognitive load and to assign the chunks meaningful names (unless they are anonymous). Judicious application can reduce the cost of developing and maintaining software, while increasing its quality and reliability.[3]
Callable units are present at multiple levels of abstraction in the programming environment. For example, a programmer may write a function in source code that is compiled to machine code that implements similar semantics. There is a callable unit in the source code and an associated one in the machine code, but they are different kinds of callable units – with different implications and features.
The meaning of each callable term (function, procedure, method, ...) is, in fact, different. They are not synonymous. Nevertheless, they each add a capability to programming that has commonality.
The term used tends to reflect the context in which it is used – usually based on the language being used. For example:
Sub
, short for subroutine or subprocedure, is the name of a callable that does not return a value whereas a Function
does return a valueThe idea of a callable unit was initially conceived by John Mauchly and Kathleen Antonelli during their work on ENIAC and recorded in a January 1947 Harvard symposium on "Preparation of Problems for EDVAC-type Machines."[4] Maurice Wilkes, David Wheeler, and Stanley Gill are generally credited with the formal invention of this concept, which they termed a closed sub-routine,[5][6] contrasted with an open subroutine or macro.[7] However, Alan Turing had discussed subroutines in a paper of 1945 on design proposals for the NPL ACE, going so far as to invent the concept of a return address stack.[8]
The idea of a subroutine was worked out after computing machines had already existed for some time. The arithmetic and conditional jump instructions were planned ahead of time and have changed relatively little, but the special instructions used for procedure calls have changed greatly over the years. The earliest computers and microprocessors, such as the Manchester Baby and the RCA 1802, did not have a single subroutine call instruction. Subroutines could be implemented, but they required programmers to use the call sequence—a series of instructions—at each call site.
Subroutines were implemented in Konrad Zuse's Z4 in 1945.
In 1945, Alan M. Turing used the terms "bury" and "unbury" as a means of calling and returning from subroutines.[9][10]
In January 1947 John Mauchly presented general notes at 'A Symposium of Large Scale Digital Calculating Machinery' under the joint sponsorship of Harvard University and the Bureau of Ordnance, United States Navy. Here he discusses serial and parallel operation suggesting
...the structure of the machine need not be complicated one bit. It is possible, since all the logical characteristics essential to this procedure are available, to evolve a coding instruction for placing the subroutines in the memory at places known to the machine, and in such a way that they may easily be called into use.
In other words, one can designate subroutine A as division and subroutine B as complex multiplication and subroutine C as the evaluation of a standard error of a sequence of numbers, and so on through the list of subroutines needed for a particular problem. ... All these subroutines will then be stored in the machine, and all one needs to do is make a brief reference to them by number, as they are indicated in the coding.[4]
Kay McNulty had worked closely with John Mauchly on the ENIAC team and developed an idea for subroutines for the ENIAC computer she was programming during World War II.[11] She and the other ENIAC programmers used the subroutines to help calculate missile trajectories.[11]
Goldstine and von Neumann wrote a paper dated 16 August 1948 discussing the use of subroutines.[12]
Some very early computers and microprocessors, such as the IBM 1620, the Intel 4004 and Intel 8008, and the PIC microcontrollers, have a single-instruction subroutine call that uses a dedicated hardware stack to store return addresses—such hardware supports only a few levels of subroutine nesting, but can support recursive subroutines. Machines before the mid-1960s—such as the UNIVAC I, the PDP-1, and the IBM 1130—typically use a calling convention which saved the instruction counter in the first memory location of the called subroutine. This allows arbitrarily deep levels of subroutine nesting but does not support recursive subroutines. The IBM System/360 had a subroutine call instruction that placed the saved instruction counter value into a general-purpose register; this can be used to support arbitrarily deep subroutine nesting and recursive subroutines. The Burroughs B5000[13] (1961) is one of the first computers to store subroutine return data on a stack.
The DEC PDP-6[14] (1964) is one of the first accumulator-based machines to have a subroutine call instruction that saved the return address in a stack addressed by an accumulator or index register. The later PDP-10 (1966), PDP-11 (1970) and VAX-11 (1976) lines followed suit; this feature also supports both arbitrarily deep subroutine nesting and recursive subroutines.[15]
In the very early assemblers, subroutine support was limited. Subroutines were not explicitly separated from each other or from the main program, and indeed the source code of a subroutine could be interspersed with that of other subprograms. Some assemblers would offer predefined macros to generate the call and return sequences. By the 1960s, assemblers usually had much more sophisticated support for both inline and separately assembled subroutines that could be linked together.
One of the first programming languages to support user-written subroutines and functions was FORTRAN II. The IBM FORTRAN II compiler was released in 1958. ALGOL 58 and other early programming languages also supported procedural programming.
Even with this cumbersome approach, subroutines proved very useful. They allowed the use of the same code in many different programs. Memory was a very scarce resource on early computers, and subroutines allowed significant savings in the size of programs.
Many early computers loaded the program instructions into memory from a punched paper tape. Each subroutine could then be provided by a separate piece of tape, loaded or spliced before or after the main program (or "mainline"[16]); and the same subroutine tape could then be used by many different programs. A similar approach was used in computers that loaded program instructions from punched cards. The name subroutine library originally meant a library, in the literal sense, which kept indexed collections of tapes or decks of cards for collective use.
To remove the need for self-modifying code, computer designers eventually provided an indirect jump instruction, whose operand, instead of being the return address itself, was the location of a variable or processor register containing the return address.
On those computers, instead of modifying the function's return jump, the calling program would store the return address in a variable so that when the function completed, it would execute an indirect jump that would direct execution to the location given by the predefined variable.
Another advance was the jump to subroutine instruction, which combined the saving of the return address with the calling jump, thereby minimizing overhead significantly.
In the IBM System/360, for example, the branch instructions BAL or BALR, designed for procedure calling, would save the return address in a processor register specified in the instruction, by convention register 14. To return, the subroutine had only to execute an indirect branch instruction (BR) through that register. If the subroutine needed that register for some other purpose (such as calling another subroutine), it would save the register's contents to a private memory location or a register stack.
In systems such as the HP 2100, the JSB instruction would perform a similar task, except that the return address was stored in the memory location that was the target of the branch. Execution of the procedure would actually begin at the next memory location. In the HP 2100 assembly language, one would write, for example
...
JSB MYSUB (Calls subroutine MYSUB.)
BB ... (Will return here after MYSUB is done.)
to call a subroutine called MYSUB from the main program. The subroutine would be coded as
MYSUB NOP (Storage for MYSUB's return address.)
AA ... (Start of MYSUB's body.)
...
JMP MYSUB,I (Returns to the calling program.)
The JSB instruction placed the address of the NEXT instruction (namely, BB) into the location specified as its operand (namely, MYSUB), and then branched to the NEXT location after that (namely, AA = MYSUB + 1). The subroutine could then return to the main program by executing the indirect jump JMP MYSUB, I which branched to the location stored at location MYSUB.
Compilers for Fortran and other languages could easily make use of these instructions when available. This approach supported multiple levels of calls; however, since the return address, parameters, and return values of a subroutine were assigned fixed memory locations, it did not allow for recursive calls.
Incidentally, a similar method was used by Lotus 1-2-3, in the early 1980s, to discover the recalculation dependencies in a spreadsheet. Namely, a location was reserved in each cell to store the return address. Since circular references are not allowed for natural recalculation order, this allows a tree walk without reserving space for a stack in memory, which was very limited on small computers such as the IBM PC.
Most modern implementations of a function call use a call stack, a special case of the stack data structure, to implement function calls and returns. Each procedure call creates a new entry, called a stack frame, at the top of the stack; when the procedure returns, its stack frame is deleted from the stack, and its space may be used for other procedure calls. Each stack frame contains the private data of the corresponding call, which typically includes the procedure's parameters and internal variables, and the return address.
The call sequence can be implemented by a sequence of ordinary instructions (an approach still used in reduced instruction set computing (RISC) and very long instruction word (VLIW) architectures), but many traditional machines designed since the late 1960s have included special instructions for that purpose.
The call stack is usually implemented as a contiguous area of memory. It is an arbitrary design choice whether the bottom of the stack is the lowest or highest address within this area, so that the stack may grow forwards or backwards in memory; however, many architectures chose the latter.[citation needed]
Some designs, notably some Forth implementations, used two separate stacks, one mainly for control information (like return addresses and loop counters) and the other for data. The former was, or worked like, a call stack and was only indirectly accessible to the programmer through other language constructs while the latter was more directly accessible.
When stack-based procedure calls were first introduced, an important motivation was to save precious memory.[citation needed] With this scheme, the compiler does not have to reserve separate space in memory for the private data (parameters, return address, and local variables) of each procedure. At any moment, the stack contains only the private data of the calls that are currently active (namely, which have been called but haven't returned yet). Because of the ways in which programs were usually assembled from libraries, it was (and still is) not uncommon to find programs that include thousands of functions, of which only a handful are active at any given moment.[citation needed] For such programs, the call stack mechanism could save significant amounts of memory. Indeed, the call stack mechanism can be viewed as the earliest and simplest method for automatic memory management.
However, another advantage of the call stack method is that it allows recursive function calls, since each nested call to the same procedure gets a separate instance of its private data.
In a multi-threaded environment, there is generally more than one stack.[17] An environment that fully supports coroutines or lazy evaluation may use data structures other than stacks to store their activation records.
One disadvantage of the call stack mechanism is the increased cost of a procedure call and its matching return.[clarification needed] The extra cost includes incrementing and decrementing the stack pointer (and, in some architectures, checking for stack overflow), and accessing the local variables and parameters by frame-relative addresses, instead of absolute addresses. The cost may be realized in increased execution time, or increased processor complexity, or both.
This overhead is most obvious and objectionable in leaf procedures or leaf functions, which return without making any procedure calls themselves.[18][19][20] To reduce that overhead, many modern compilers try to delay the use of a call stack until it is really needed.[citation needed] For example, the call of a procedure P may store the return address and parameters of the called procedure in certain processor registers, and transfer control to the procedure's body by a simple jump. If the procedure P returns without making any other call, the call stack is not used at all. If P needs to call another procedure Q, it will then use the call stack to save the contents of any registers (such as the return address) that will be needed after Q returns.
In general, a callable unit is a list of instructions that, starting at the first instruction, executes sequentially except as directed via its internal logic. It can be invoked (called) many times during the execution of a program. Execution continues at the next instruction after the call instruction when it returns control.
The features of implementations of callable units evolved over time and varies by context. This section describes features of the various common implementations.
Most modern programming languages provide features to define and call functions, including syntax for accessing such features, including:
Some languages, such as Pascal, Fortran, Ada and many dialects of BASIC, use a different name for a callable unit that returns a value (function or subprogram) vs. one that does not (subroutine or procedure).
Other languages, such as C, C++, C# and Lisp, use only one name for a callable unit, function. The C-family languages use the keyword void
to indicate no return value.
If declared to return a value, a call can be embedded in an expression in order to consume the return value. For example, a square root callable unit might be called like y = sqrt(x)
.
A callable unit that does not return a value is called as a stand-alone statement like print("hello")
. This syntax can also be used for a callable unit that returns a value, but the return value will be ignored.
Some older languages require a keyword for calls that do not consume a return value, like CALL print("hello")
.
Most implementations, especially in modern languages, support parameters which the callable declares as formal parameters. A caller passes actual parameters, a.k.a. arguments, to match. Different programming languages provide different conventions for passing arguments.
Convention | Description | Used in |
---|---|---|
by value | A copy of the argment is passed | Default in most Algol-like languages after Algol 60, such as Pascal, Delphi, Simula, CPL, PL/M, Modula, Oberon, Ada, and many others including C, C++ and Java |
by reference | A reference to the argument is passed; typically its address | Selectable in most Algol-like languages after Algol 60, such as Algol 68, Pascal, Delphi, Simula, CPL, PL/M, Modula, Oberon, Ada, and many others including C++, Fortran, PL/I |
by result | The value computed during the call is copied to the argument on return | Ada OUT parameters |
by value-result | A copy of the argument is passed in and the value computed during the call is copied to the argument on return | Algol, Swift in-out parameters |
by name | Like a macro – replace the parameters with the unevaluated argument expressions, then evaluate the argument in the context of the caller every time that the callable uses the parameter | Algol, Scala |
by constant value | Like by-value except that the parameter is treated as a constant | PL/I NONASSIGNABLE parameters, Ada IN parameters |
In some languages, such as BASIC, a callable has different syntax (i.e. keyword) for a callable that returns a value vs. one that does not.
In other languages, the syntax is the same regardless.
In some of these languages an extra keyword is used to declare no return value; for example void
in C, C++ and C#.
In some languages, such as Python, the difference is whether the body contains a return statement with a value, and a particular callable may return with or without a value based on control flow.
In many contexts, a callable may have side effect behavior such as modifying passed or global data, reading from or writing to a peripheral device, accessing a file, halting the program or the machine, or temporarily pausing program execution.
Side effects are considered undesireble by Robert C. Martin, who is known for promoting design principles. Martin argues that side effects can result in temporal coupling or order dependencies.[21]
In strictly functional programming languages such as Haskell, a function can have no side effects, which means it cannot change the state of the program. Functions always return the same result for the same input. Such languages typically only support functions that return a value, since there is no value in a function that has neither return value nor side effect.
Most contexts support local variables – memory owned by a callable to hold intermediate values. These variables are typically stored in the call's activation record on the call stack along with other information such as the return address.
If supported by the language, a callable may call itself, causing its execution to suspend while another nested execution of the same callable executes. Recursion is a useful means to simplify some complex algorithms and break down complex problems. Recursive languages provide a new copy of local variables on each call. If the programmer desires the recursive callable to use the same variables instead of using locals, they typically declare them in a shared context such static or global.
Languages going back to ALGOL, PL/I and C and modern languages, almost invariably use a call stack, usually supported by the instruction sets to provide an activation record for each call. That way, a nested call can modify its local variables without affecting any of the suspended calls variables.
Recursion allows direct implementation of functionality defined by mathematical induction and recursive divide and conquer algorithms. Here is an example of a recursive function in C/C++ to find Fibonacci numbers:
int Fib(int n) {
if (n <= 1) {
return n;
}
return Fib(n - 1) + Fib(n - 2);
}
Early languages like Fortran did not initially support recursion because only one set of variables and return address were allocated for each callable.[22] Early computer instruction sets made storing return addresses and variables on a stack difficult. Machines with index registers or general-purpose registers, e.g., CDC 6000 series, PDP-6, GE 635, System/360, UNIVAC 1100 series, could use one of those registers as a stack pointer.
Some languages, e.g., Ada, Pascal, PL/I, Python, support declaring and defining a function inside, e.g., a function body, such that the name of the inner is only visible within the body of the outer.
If a callable can be executed properly even when another execution of the same callable is already in progress, that callable is said to be reentrant. A reentrant callable is also useful in multi-threaded situations since multiple threads can call the same callable without fear of interfering with each other. In the IBM CICS transaction processing system, quasi-reentrant was a slightly less restrictive, but similar, requirement for application programs that were shared by many threads.
Some languages support overloading – allow multiple callables with the same name in the same scope, but operating on different types of input. Consider the square root function applied to real number, complex number and matrix input. The algorithm for each type of input is different, and the return value may have a different type. By writing three separate callables with the same name. i.e. sqrt, the resulting code may be easier to write and to maintain since each one has a name that is relatively easy to understand and to remember instead of giving longer and more complicated names like sqrt_real, sqrt_complex, qrt_matrix.
Overloading is supported in many languages that support strong typing. Often the compiler selects the overload to call based on the type of the input arguments or it fails if the input arguments do not select an overload. Older and weakly-typed languages generally do not support overloading.
Here is an example of overloading in C++, two functions Area
that accept different types:
// returns the area of a rectangle defined by height and width
double Area(double h, double w) { return h * w; }
// returns the area of a circle defined by radius
double Area(double r) { return r * r * 3.14; }
int main() {
double rectangle_area = Area(3, 4);
double circle_area = Area(5);
}
PL/I has the GENERIC
attribute to define a generic name for a set of entry references called with different types of arguments. Example:
DECLARE gen_name GENERIC( name WHEN(FIXED BINARY), flame WHEN(FLOAT), pathname OTHERWISE);
Multiple argument definitions may be specified for each entry. A call to "gen_name" will result in a call to "name" when the argument is FIXED BINARY, "flame" when FLOAT", etc. If the argument matches none of the choices "pathname" will be called.
A closure is a callable plus values of some of its variables captured from the environment in which it was created. Closures were a notable feature of the Lisp programming language, introduced by John McCarthy. Depending on the implementation, closures can serve as a mechanism for side-effects.
Besides its happy path behavior, a callable may need to inform the caller about an exceptional condition that occurred during its execution.
Most modern languages support exceptions which allows for exceptional control flow that pops the call stack until an exception handler is found to handle the condition.
Languages that do not support exceptions can use the return value to indicate success or failure of a call. Another approach is to use a well-known location like a global variable for success indication. A callable writes the value and the caller reads it after a call.
In the IBM System/360, where return code was expected from a subroutine, the return value was often designed to be a multiple of 4—so that it could be used as a direct branch table index into a branch table often located immediately after the call instruction to avoid extra conditional tests, further improving efficiency. In the System/360 assembly language, one would write, for example:
BAL 14, SUBRTN01 go to a subroutine, storing return address in R14
B TABLE(15) use returned value in reg 15 to index the branch table,
* branching to the appropriate branch instr.
TABLE B OK return code =00 GOOD }
B BAD return code =04 Invalid input } Branch table
B ERROR return code =08 Unexpected condition }
A call has runtime overhead, which may include but is not limited to:
Various techniques are employed to minimize the runtime cost of calls.
Some optimizations for minimizing call overhead may seem straight forward, but cannot be used if the callable has side effects. For example, in the expression (f(x)-1)/(f(x)+1)
, the function f
cannot be called only once with its value used two times since the two calls may return different results. Moreover, in the few languages which define the order of evaluation of the division operator's operands, the value of x
must be fetched again before the second call, since the first call may have changed it. Determining whether a callable has a side effect is difficult – indeed, undecidable by virtue of Rice's theorem. So, while this optimization is safe in a purely functional programming language, a compiler for an language not limited to functional typically assumes the worst case, that every callable may have side effects.
Inlining eliminates calls for particular callables. The compiler replaces each call with the compiled code of the callable. Not only does this avoid the call overhead, but it also allows the compiler to optimize code of the caller more effectively by taking into account the context and arguments at that call. Inlining, however, usually increases the compiled code size, except when only called once or the body is very short, like one line.
Callables can be defined within a program, or separately in a library that can be used by multiple programs.
A compiler translates call and return statements into machine instructions according to a well-defined calling convention. For code compiled by the same or a compatible compiler, functions can be compiled separately from the programs that call them. The instruction sequences corresponding to call and return statements are called the procedure's prologue and epilogue.
A built-in function, or builtin function, or intrinsic function, is a function for which the compiler generates code at compile time or provides in a way other than for other functions.[23] A built-in function does not need to be defined like other functions since it is built in to the programming language.[24]
Advantages of breaking a program into functions include:
Compared to using in-line code, invoking a function imposes some computational overhead in the call mechanism.[citation needed]
A function typically requires standard housekeeping code – both at the entry to, and exit from, the function (function prologue and epilogue – usually saving general purpose registers and return address as a minimum).
Many programming conventions have been developed regarding callables.
With respect to naming, many developers name a callable with a phrase starting with a verb when it does a certain task, with an adjective when it makes an inquiry, and with a noun when it is used to substitute variables.
Some programmers suggest that a callable should perform exactly one task, and if it performs more than one task, it should be split up into multiple callables. They argue that callables are key components in software maintenance, and their roles in the program must remain distinct.
Proponents of modular programming advocate that each callable should have minimal dependency on the rest of the codebase. For example, the use of global variables is generally deemed unwise, because it adds coupling between all callables that use the global variables. If such coupling is not necessary, they advise to refactor callables to accept passed parameters instead.
Early BASIC variants require each line to have a unique number (line number) that orders the lines for execution, provides no separation of the code that is callable, no mechanism for passing arguments or to return a value and all variables are global. It provides the command GOSUB
where sub is short for sub procedure, subprocedure or subroutine. Control jumps to the specified line number and then continues on the next line on return.
10 REM A BASIC PROGRAM
20 GOSUB 100
30 GOTO 20
100 INPUT “GIVE ME A NUMBER”; N
110 PRINT “THE SQUARE ROOT OF”; N;
120 PRINT “IS”; SQRT(N)
130 RETURN
This code repeatedly asks the user to enter a number and reports the square root of the value. Lines 100-130 are the callable.
In Microsoft Small Basic, targeted to the student first learning how to program in a text-based language, a callable unit is called a subroutine.
The Sub
keyword denotes the start of a subroutine and is followed by a name identifier. Subsequent lines are the body which ends with the EndSub
keyword.
[25]
Sub SayHello
TextWindow.WriteLine("Hello!")
EndSub
This can be called as SayHello()
.
[26]
In later versions of Visual Basic (VB), including the latest product line and VB6, the term procedure is used for the callable unit concept. The keyword Sub
is used to return no value and Function
to return a value. When used in the context of a class, a procedure is a method.
[27]
Each parameter has a data type that can be specified, but if not, defaults to Object
for later versions based on .NET and variant for VB6.[28]
VB supports parameter passing conventions by value and by reference via the keywords ByVal
and ByRef
, respectively.
Unless ByRef
is specified, an argument is passed ByVal
. Therefore, ByVal
is rarely explicitly specified.
For a simple type like a number these conventions are relatively clear. Passing ByRef
allows the procedure to modify the passed variable whereas passing ByVal
does not. For an object, semantics can confuse programmers since an object is always treated as a reference. Passing an object ByVal
copies the reference; not the state of the object. The called procedure can modify the state of the object via its methods yet cannot modify the object reference of the actual parameter.
Sub DoSomething()
' Some Code Here
End Sub
The does not return a value and has to be called stand-alone, like DoSomething
Function GiveMeFive() as Integer
GiveMeFive= 5
End Function
This returns the value 5, and a call can be part of an expression like y = x + GiveMeFive()
Sub AddTwo(ByRef intValue as Integer)
intValue = intValue + 2
End Sub
This has a side-effect – modifies the variable passed by reference and could be called for variable v
like AddTwo(v)
. Giving v is 5 before the call, it will be 7 after.
In C and C++, a callable unit is called a function.
A function definition starts with the name of the type of value that it returns or void
to indicate that it does not return a value. This is followed by the function name, formal arguments in parentheses, and body lines in braces.
In C++, a function declared in a class (as non-static) is called a member function or method. A function outside of a class can be called a free function to distinguish it from a member function. [29]
void doSomething() {
/* some code */
}
This function does not return a value and is always called stand-alone, like doSomething()
int giveMeFive() {
return 5;
}
This function returns the integer value 5. The call can be stand-alone or in an expression like y = x + giveMeFive()
void addTwo(int *pi) {
*pi += 2;
}
This function has a side-effect – modifies the value passed by address to the input value plus 2. It could be called for variable v
as addTwo(&v)
where the ampersand (&) tells the compiler to pass the address of a variable. Giving v is 5 before the call, it will be 7 after.
void addTwo(int& i) {
i += 2;
}
This function requires C++ – would not compile as C. It has the same behavior as the preceding example but passes the actual parameter by reference rather than passing its address. A call such as addTwo(v)
does not include an ampersand since the compiler handles passing by reference without syntax in the call.
In PL/I a called procedure may be passed a descriptor providing information about the argument, such as string lengths and array bounds. This allows the procedure to be more general and eliminates the need for the programmer to pass such information. By default PL/I passes arguments by reference. A (trivial) function to change the sign of each element of a two-dimensional array might look like:
change_sign: procedure(array); declare array(*,*) float; array = -array; end change_sign;
This could be called with various arrays as follows:
/* first array bounds from -5 to +10 and 3 to 9 */ declare array1 (-5:10, 3:9)float; /* second array bounds from 1 to 16 and 1 to 16 */ declare array2 (16,16) float; call change_sign(array1); call change_sign(array2);
In Python, the keyword def
denotes the start of a function definition. The statements of the function body follow as indented on subsequent lines and end at the line that is indented the same as the first line or end of file.[30]
def format_greeting(name):
return "Welcome " + name
def greet_martin():
print(format_greeting("Martin"))
The first function returns greeting text that includes the name passed by the caller. The second function calls the first and is called like greet_martin()
to write "Welcome Martin" to the console.
In the procedural interpretation of logic programs, logical implications behave as goal-reduction procedures. A rule (or clause) of the form:
A :- B
which has the logical reading:
A if B
behaves as a procedure that reduces goals that unify with A
to subgoals that are instances ofB
.
Consider, for example, the Prolog program:
mother_child(elizabeth, charles).
father_child(charles, william).
father_child(charles, harry).
parent_child(X, Y) :- mother_child(X, Y).
parent_child(X, Y) :- father_child(X, Y).
Notice that the motherhood function, X = mother(Y)
is represented by a relation, as in a relational database. However, relations in Prolog function as callable units.
For example, the procedure call ?- parent_child(X, charles)
produces the output X = elizabeth
. But the same procedure can be called with other input-output patterns. For example:
?- parent_child(elizabeth, Y).
Y = charles.
?- parent_child(X, Y).
X = elizabeth,
Y = charles.
X = charles,
Y = harry.
X = charles,
Y = william.
?- parent_child(william, harry).
no.
?- parent_child(elizabeth, charles).
yes.
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