POSIX APIs and System Calls
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elsiddik
Mar 4, 2008, 1:35:37 PM3/4/08
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POSIX APIs and System Calls
Let's start by stressing the difference between an application
programmer interface (API) and a system call. The former is a function
definition that specifies how to obtain a given service, while the
latter is an explicit request to the kernel made via a software
interrupt.
Unix systems include several libraries of functions that provide APIs
to programmers. Some of the APIs defined by the libc standard C
library refer to wrapper routines (routines whose only purpose is to
issue a system call). Usually, each system call has a corresponding
wrapper routine, which defines the API that application programs
should employ.
The converse is not true, by the way--an API does not necessarily
correspond to a specific system call. First of all, the API could
offer its services directly in User Mode. (For something abstract like
math functions, there may be no reason to make system calls.) Second,
a single API function could make several system calls. Moreover,
several API functions could make the same system call, but wrap extra
functionality around it. For instance, in Linux, the malloc( ),
calloc( ), and free( ) APIs are implemented in the libc library. The
code in this library keeps track of the allocation and deallocation
requests and uses the brk( ) system call to enlarge or shrink the
process heap (see Section 8.6).
The POSIX standard refers to APIs and not to system calls. A system
can be certified as POSIX-compliant if it offers the proper set of
APIs to the application programs, no matter how the corresponding
functions are implemented. As a matter of fact, several non-Unix
systems have been certified as POSIX-compliant, since they offer all
traditional Unix services in User Mode libraries.
From the programmer's point of view, the distinction between an API
and a system call is irrelevant -- the only things that matter are the
function name, the parameter types, and the meaning of the return
code. From the kernel designer's point of view, however, the
distinction does matter since system calls belong to the kernel, while
User Mode libraries don't.
Most wrapper routines return an integer value, whose meaning depends
on the corresponding system call. A return value of -1 usually
indicates that the kernel was unable to satisfy the process request. A
failure in the system call handler may be caused by invalid
parameters, a lack of available resources, hardware problems, and so
on. The specific error code is contained in the errno variable, which
is defined in the libc library.
Each error code is defined as a macro constant, which yields a
corresponding positive integer value. The POSIX standard specifies the
macro names of several error codes. In Linux, on 80 x 86 systems,
these macros are defined in the header file include/asm-i386/errno.h.
To allow portability of C programs among Unix systems, the include/asm-
i386/errno.h header file is included, in turn, in the standard /usr/
include/errno.h C library header file. Other systems have their own
specialized subdirectories of header files.
read full article on
http://eduunix.ccut.edu.cn/index/html/linux/O'Reilly%20-%20Understanding.the%20Linux%20Kernel%20-%202nd%20Edition/064.htm
zaher el siddik
http://www.unixshells.nl/
http://elsiddik.blogspot.com/
Let's start by stressing the difference between an application
programmer interface (API) and a system call. The former is a function
definition that specifies how to obtain a given service, while the
latter is an explicit request to the kernel made via a software
interrupt.
Unix systems include several libraries of functions that provide APIs
to programmers. Some of the APIs defined by the libc standard C
library refer to wrapper routines (routines whose only purpose is to
issue a system call). Usually, each system call has a corresponding
wrapper routine, which defines the API that application programs
should employ.
The converse is not true, by the way--an API does not necessarily
correspond to a specific system call. First of all, the API could
offer its services directly in User Mode. (For something abstract like
math functions, there may be no reason to make system calls.) Second,
a single API function could make several system calls. Moreover,
several API functions could make the same system call, but wrap extra
functionality around it. For instance, in Linux, the malloc( ),
calloc( ), and free( ) APIs are implemented in the libc library. The
code in this library keeps track of the allocation and deallocation
requests and uses the brk( ) system call to enlarge or shrink the
process heap (see Section 8.6).
The POSIX standard refers to APIs and not to system calls. A system
can be certified as POSIX-compliant if it offers the proper set of
APIs to the application programs, no matter how the corresponding
functions are implemented. As a matter of fact, several non-Unix
systems have been certified as POSIX-compliant, since they offer all
traditional Unix services in User Mode libraries.
From the programmer's point of view, the distinction between an API
and a system call is irrelevant -- the only things that matter are the
function name, the parameter types, and the meaning of the return
code. From the kernel designer's point of view, however, the
distinction does matter since system calls belong to the kernel, while
User Mode libraries don't.
Most wrapper routines return an integer value, whose meaning depends
on the corresponding system call. A return value of -1 usually
indicates that the kernel was unable to satisfy the process request. A
failure in the system call handler may be caused by invalid
parameters, a lack of available resources, hardware problems, and so
on. The specific error code is contained in the errno variable, which
is defined in the libc library.
Each error code is defined as a macro constant, which yields a
corresponding positive integer value. The POSIX standard specifies the
macro names of several error codes. In Linux, on 80 x 86 systems,
these macros are defined in the header file include/asm-i386/errno.h.
To allow portability of C programs among Unix systems, the include/asm-
i386/errno.h header file is included, in turn, in the standard /usr/
include/errno.h C library header file. Other systems have their own
specialized subdirectories of header files.
read full article on
http://eduunix.ccut.edu.cn/index/html/linux/O'Reilly%20-%20Understanding.the%20Linux%20Kernel%20-%202nd%20Edition/064.htm
zaher el siddik
http://www.unixshells.nl/
http://elsiddik.blogspot.com/
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