Copyright © 2004 Free Standards Group
Permission is granted to copy, distribute and/or modify this document under the terms of the GNU Free Documentation License, Version 1.1; with no Invariant Sections, with no Front-Cover Texts, and with no Back-Cover Texts. A copy of the license is included in the section entitled "GNU Free Documentation License".
Portions of the text are copyrighted by the following parties:
The Regents of the University of California
Free Software Foundation
Ian F. Darwin
Paul Vixie
BSDI (now Wind River)
Andrew G Morgan
Jean-loup Gailly and Mark Adler
Massachusetts Institute of Technology
These excerpts are being used in accordance with their respective licenses.
Linux is a trademark of Linus Torvalds.
UNIX a registered trademark of the Open Group in the United States and other countries.
LSB is a trademark of the Free Standards Group in the USA and other countries.
AMD is a trademark of Advanced Micro Devices, Inc.
Intel and Itanium are registered trademarks and Intel386 is a trademarks of Intel Corporation.
OpenGL is a registered trademark of Silicon Graphics, Inc.
This is version 3.0Preview1 of the Linux Standard Base Core Specification. An implementation of this version of the specification may not claim to be an implementation of the Linux Standard Base unless it has successfully completed the compliance process as defined by the Free Standards Group.
The LSB defines a binary interface for application programs that are compiled and packaged for LSB-conforming implementations on many different hardware architectures. Since a binary specification shall include information specific to the computer processor architecture for which it is intended, it is not possible for a single document to specify the interface for all possible LSB-conforming implementations. Therefore, the LSB is a family of specifications, rather than a single one.
This document should be used in conjunction with the documents it references. This document enumerates the system components it includes, but descriptions of those components may be included entirely or partly in this document, partly in other documents, or entirely in other reference documents. For example, the section that describes system service routines includes a list of the system routines supported in this interface, formal declarations of the data structures they use that are visible to applications, and a pointer to the underlying referenced specification for information about the syntax and semantics of each call. Only those routines not described in standards referenced by this document, or extensions to those standards, are described in the detail. Information referenced in this way is as much a part of this document as is the information explicitly included here.
The specification carries a version number of either the form x.y or x.y.z. This version number carries the following meaning:
The first number (x) is the major version number. All versions with the same major version number should share binary compatibility. Any addition or deletion of a new library results in a new version number. Interfaces marked as deprecated may be removed from the specification at a major version change.
The second number (y) is the minor version number. Individual interfaces may be added if all certified implementations already had that (previously undocumented) interface. Interfaces may be marked as deprecated at a minor version change. Other minor changes may be permitted at the discretion of the LSB workgroup.
The third number (z), if present, is the editorial level. Only editorial changes should be included in such versions.
The Linux Standard Base (LSB) defines a system interface for compiled applications and a minimal environment for support of installation scripts. Its purpose is to enable a uniform industry standard environment for high-volume applications conforming to the LSB.
These specifications are composed of two basic parts: A common specification ("LSB-generic") describing those parts of the interface that remain constant across all implementations of the LSB, and an architecture-specific specification ("LSB-arch") describing the parts of the interface that vary by processor architecture. Together, the LSB-generic and the architecture-specific supplement for a single hardware architecture provide a complete interface specification for compiled application programs on systems that share a common hardware architecture.
The LSB-generic document shall be used in conjunction with an architecture-specific supplement. Whenever a section of the LSB-generic specification shall be supplemented by architecture-specific information, the LSB-generic document includes a reference to the architecture supplement. Architecture supplements may also contain additional information that is not referenced in the LSB-generic document.
The LSB contains both a set of Application Program Interfaces (APIs) and Application Binary Interfaces (ABIs). APIs may appear in the source code of portable applications, while the compiled binary of that application may use the larger set of ABIs. A conforming implementation shall provide all of the ABIs listed here. The compilation system may replace (e.g. by macro definition) certain APIs with calls to one or more of the underlying binary interfaces, and may insert calls to binary interfaces as needed.
The LSB is primarily a binary interface definition. Not all of the source level APIs available to applications may be contained in this specification.
This is the Core module of the Linux Standards Base (LSB). This module provides the fundamental system interfaces, libraries, and runtime environment upon which all conforming applications and libraries depend.
Interfaces described in this module are mandatory except where explicitly listed otherwise. Core interfaces may be supplemented by other modules; all modules are built upon the core.
The specifications listed below are referenced in whole or in part by the Linux Standard Base. In this specification, where only a particular section of one of these references is identified, then the normative reference is to that section alone, and the rest of the referenced document is informative.
Table 2-1. Normative References
Name | Title | URL |
---|---|---|
DWARF Debugging Information Format | DWARF Debugging Information Format, Revision 2.0.0 (July 27, 1993) | http://www.eagercon.com/dwarf/dwarf-2.0.0.pdf |
Filesystem Hierarchy Standard | Filesystem Hierarchy Standard (FHS) 2.3 | http://www.pathname.com/fhs/ |
Gdk 2.6.2 Reference Manual | Gdk 2.6.2 Reference Manual | http://www.gtk.org/api/2.6/gdk/index.html |
Gdk-pixbuf 2.6.2 Reference Manual | Gdk-pixbuf 2.6.2 Reference Manual | http://www.gtk.org/api/2.6/gdk-pixbuf/index.html |
Glib 2.6.2 Reference Manual | Glib 2.6.2 Reference Manual | http://www.gtk.org/api/2.6/glib/index.html |
Gobject 2.6.2 Reference Manual | Gobject 2.6.2 Reference Manual | http://www.gtk.org/api/2.6/gobject/index.html |
Gtk 2.6.2 Reference Manual | Gtk 2.6.2 Reference Manual | http://www.gtk.org/api/2.6/gtk/index.html |
IEEE Std 754-1985 | IEEE Standard 754 for Binary Floating-Point Arithmetic | http://www.ieee.org/ |
ISO C (1999) | ISO/IEC 9899: 1999, Programming Languages --C | |
ISO POSIX (2003) | ISO/IEC 9945-1:2003 Information technology -- Portable Operating System Interface (POSIX) -- Part 1: Base Definitions ISO/IEC 9945-2:2003 Information technology -- Portable Operating System Interface (POSIX) -- Part 2: System Interfaces ISO/IEC 9945-3:2003 Information technology -- Portable Operating System Interface (POSIX) -- Part 3: Shell and Utilities ISO/IEC 9945-4:2003 Information technology -- Portable Operating System Interface (POSIX) -- Part 4: Rationale Including Technical Cor. 1: 2004 | http://www.unix.org/version3/ |
ISO/IEC TR14652 | ISO/IEC Technical Report 14652:2002 Specification method for cultural conventions | |
ITU-T V.42 | International Telecommunication Union Recommendation V.42 (2002): Error-correcting procedures for DCEs using asynchronous-to-synchronous conversionITUV | http://www.itu.int/rec/recommendation.asp?type=folders&lang=e&parent=T-REC-V.42 |
Large File Support | Large File Support | http://www.UNIX-systems.org/version2/whatsnew/lfs20mar.html |
Li18nux Globalization Specification | LI18NUX 2000 Globalization Specification, Version 1.0 with Amendment 4 | http://www.li18nux.org/docs/html/LI18NUX-2000-amd4.htm |
Linux Allocated Device Registry | LINUX ALLOCATED DEVICES | http://www.lanana.org/docs/device-list/devices.txt |
PAM | Open Software Foundation, Request For Comments: 86.0 , October 1995, V. Samar & R.Schemers (SunSoft) | http://www.opengroup.org/tech/rfc/mirror-rfc/rfc86.0.txt |
RFC 1321: The MD5 Message-Digest Algorithm | IETF RFC 1321: The MD5 Message-Digest Algorithm | http://www.ietf.org/rfc/rfc1321.txt |
RFC 1833: Binding Protocols for ONC RPC Version 2 | IETF RFC 1833: Binding Protocols for ONC RPC Version 2 | http://www.ietf.org/rfc/rfc1833.txt |
RFC 1950: ZLIB Compressed Data Format Specication | IETF RFC 1950: ZLIB Compressed Data Format Specification | http://www.ietf.org/rfc/rfc1950.txt |
RFC 1951: DEFLATE Compressed Data Format Specification | IETF RFC 1951: DEFLATE Compressed Data Format Specification version 1.3 | http://www.ietf.org/rfc/rfc1951.txt |
RFC 1952: GZIP File Format Specification | IETF RFC 1952: GZIP file format specification version 4.3 | http://www.ietf.org/rfc/rfc1952.txt |
RFC 2440: OpenPGP Message Format | IETF RFC 2440: OpenPGP Message Format | http://www.ietf.org/rfc/rfc2440.txt |
RFC 2821:Simple Mail Transfer Protocol | IETF RFC 2821: Simple Mail Transfer Protocol | http://www.ietf.org/rfc/rfc2821.txt |
RFC 2822:Internet Message Format | IETF RFC 2822: Internet Message Format | http://www.ietf.org/rfc/rfc2822.txt |
RFC 791:Internet Protocol | IETF RFC 791: Internet Protocol Specification | http://www.ietf.org/rfc/rfc791.txt |
SUSv2 | CAE Specification, January 1997, System Interfaces and Headers (XSH),Issue 5 (ISBN: 1-85912-181-0, C606) | http://www.opengroup.org/publications/catalog/un.htm |
SUSv2 Commands and Utilities | The Single UNIX® Specification(SUS) Version 2, Commands and Utilities (XCU), Issue 5 (ISBN: 1-85912-191-8, C604) | http://www.opengroup.org/publications/catalog/un.htm |
SVID Issue 3 | American Telephone and Telegraph Company, System V Interface Definition, Issue 3 ; Morristown, NJ, UNIX Press, 1989.(ISBN 0201566524) | |
SVID Issue 4 | System V Interface Definition,Fourth Edition | |
System V ABI | System V Application Binary Interface, Edition 4.1 | http://www.caldera.com/developers/devspecs/gabi41.pdf |
System V ABI Update | System V Application Binary Interface - DRAFT - 17 December 2003 | http://www.caldera.com/developers/gabi/2003-12-17/contents.html |
this specification | Linux Standard Base | http://www.linuxbase.org/spec/ |
X/Open Curses | CAE Specification, May 1996, X/Open Curses, Issue 4, Version 2 (ISBN: 1-85912-171-3, C610), plus Corrigendum U018 | http://www.opengroup.org/publications/catalog/un.htm |
The libraries listed in Table 3-1 shall be available on a Linux Standard Base system, with the specified runtime names. The libraries listed in Table 3-2 are architecture specific, but shall be available on all LSB conforming systems. This list may be supplemented or amended by the architecture-specific specification.
Table 3-1. Standard Library Names
Library | Runtime Name |
---|---|
libdl | libdl.so.2 |
libcrypt | libcrypt.so.1 |
libz | libz.so.1 |
libncurses | libncurses.so.5 |
libutil | libutil.so.1 |
libpthread | libpthread.so.0 |
libpam | libpam.so.0 |
libgcc_s | libgcc_s.so.1 |
Table 3-2. Standard Library Names defined in the Architecture Specific Supplement
Library | Runtime Name |
---|---|
libm | See archLSB |
libc | See archLSB |
proginterp | See archLSB |
These libraries will be in an implementation-defined directory which the dynamic linker shall search by default.
A conforming implementation shall satisfy the following requirements:
The implementation shall implement fully the architecture described in the hardware manual for the target processor architecture.
The implementation shall be capable of executing compiled applications having the format and using the system interfaces described in this document.
The implementation shall provide libraries containing the interfaces specified by this document, and shall provide a dynamic linking mechanism that allows these interfaces to be attached to applications at runtime. All the interfaces shall behave as specified in this document.
The map of virtual memory provided by the implementation shall conform to the requirements of this document.
The implementation's low-level behavior with respect to function call linkage, system traps, signals, and other such activities shall conform to the formats described in this document.
The implementation shall provide all of the mandatory interfaces in their entirety.
The implementation may provide one or more of the optional interfaces. Each optional interface that is provided shall be provided in its entirety. The product documentation shall state which optional interfaces are provided.
The implementation shall provide all files and utilities specified as part of this document in the format defined here and in other referenced documents. All commands and utilities shall behave as required by this document. The implementation shall also provide all mandatory components of an application's runtime environment that are included or referenced in this document.
The implementation, when provided with standard data formats and values at a named interface, shall provide the behavior defined for those values and data formats at that interface. However, a conforming implementation may consist of components which are separately packaged and/or sold. For example, a vendor of a conforming implementation might sell the hardware, operating system, and windowing system as separately packaged items.
The implementation may provide additional interfaces with different names. It may also provide additional behavior corresponding to data values outside the standard ranges, for standard named interfaces.
A conforming application shall satisfy the following requirements:
Its executable files are either shell scripts or object files in the format defined for the Object File Format system interface.
Its object files participate in dynamic linking as defined in the Program Loading and Linking System interface.
It employs only the instructions, traps, and other low-level facilities defined in the Low-Level System interface as being for use by applications.
If it requires any optional interface defined in this document in order to be installed or to execute successfully, the requirement for that optional interface is stated in the application's documentation.
It does not use any interface or data format that is not required to be provided by a conforming implementation, unless:
If such an interface or data format is supplied by another application through direct invocation of that application during execution, that application is in turn an LSB conforming application.
The use of that interface or data format, as well as its source, is identified in the documentation of the application.
It shall not use any values for a named interface that are reserved for vendor extensions.
For the purposes of this document, the following definitions, as specified in the ISO/IEC Directives, Part 2, 2001, 4th Edition, apply:
be able to; there is a possibility of; it is possible to
be unable to; there is no possibilty of; it is not possible to
is permitted; is allowed; is permissible
it is not required that; no...is required
is to; is required to; it is required that; has to; only...is permitted; it is necessary
is not allowed [permitted] [acceptable] [permissible]; is required to be not; is required that...be not; is not to be
it is recommended that; ought to
it is not recommended that; ought not to
For the purposes of this document, the following terms apply:
The architectural part of the LSB Specification which describes the specific parts of the interface that are platform specific. The archLSB is complementary to the gLSB.
The total set of interfaces that are available to be used in the compiled binary code of a conforming application.
The common part of the LSB Specification that describes those parts of the interface that remain constant across all hardware implementations of the LSB.
Describes a value or behavior that is not defined by this document but is selected by an implementor. The value or behavior may vary among implementations that conform to this document. An application should not rely on the existence of the value or behavior. An application that relies on such a value or behavior cannot be assured to be portable across conforming implementations. The implementor shall document such a value or behavior so that it can be used correctly by an application.
A file that is read by an interpreter (e.g., awk). The first line of the shell script includes a reference to its interpreter binary.
The set of interfaces that are available to be used in the source code of a conforming application.
Describes the nature of a value or behavior not defined by this document which results from use of an invalid program construct or invalid data input. The value or behavior may vary among implementations that conform to this document. An application should not rely on the existence or validity of the value or behavior. An application that relies on any particular value or behavior cannot be assured to be portable across conforming implementations.
Describes the nature of a value or behavior not specified by this document which results from use of a valid program construct or valid data input. The value or behavior may vary among implementations that conform to this document. An application should not rely on the existence or validity of the value or behavior. An application that relies on any particular value or behavior cannot be assured to be portable across conforming implementations.
Other terms and definitions used in this document shall have the same meaning as defined in Chapter 3 of the Base Definitions volume of ISO POSIX (2003).
Throughout this document, the following typographic conventions are used:
the name of a function
the name of a command or utility
CONSTANT
a constant value
a parameter
variable
a variable
Throughout this specification, several tables of interfaces are presented. Each entry in these tables has the following format:
the name of the interface
An optional symbol version identifier, if required.
A reference number indexing the table of referenced specifications that follows this table.
For example,
refers to the interface named forkpty() with symbol versionGLIBC_2.0
that is defined in the
first of the listed references below the table.This specification includes many interfaces described in ISO POSIX (2003). Unless otherwise specified, such interfaces should behave exactly as described in that specification. Any conflict between the requirements described here and the ISO POSIX (2003) standard is unintentional, except as explicitly noted otherwise.
Note: In addition to the differences noted inline in this specification, PDTR 24715 has extracted the differences between this specification and ISO POSIX (2003) into a single place. It is the long term plan of the LSB to converge with ISO/IEC 9945 POSIX.
The LSB Specification Authority is responsible for deciding the meaning of conformance to normative referenced standards in the LSB context. Problem Reports regarding underlying or referenced standards in any other context will be referred to the relevant maintenance body for that standard.
LSB-conforming applications shall assume that stack, heap and other allocated memory regions will be non-executable. The application must take steps to make them executable if needed.
LSB-conforming applications shall use the data representation as defined in the Arcitecture specific ELF documents.
In addition to the fundamental types specified in the Architecture specific ELF documents, a 1 byte data type is defined here.
LSB-conforming implementations shall support the object file Executable and Linking Format (ELF), which is defined by the following documents:
this document
an architecture-specific LSB specification
As described in System V ABI, an ELF object file contains a number of sections.
The section header table is an array of
Elf32_Shdr or
Elf64_Shdr structures as
described in System V ABI. The
sh_type
member shall be either a value from
Table 4-1, drawn from the System V
ABI, or one of the additional values specified in Table 4-2.
A section header's sh_type
member specifies the sections's semantics.
The following section types are defined in the System V ABI and the System V ABI Update.
Table 4-1. ELF Section Types
Name | Value | Description |
---|---|---|
SHT_DYNAMIC | 0x6 | The section holds information for dynamic linking. Currently, an object file shall have only one dynamic section, but this restriction may be relaxed in the future. See `Dynamic Section' in Chapter 5 for details. |
SHT_DYNSYM | 0xb | This section holds a minimal set of symbols adequate for dynamic linking. See also SHT_SYMTAB. Currently, an object file may have either a section of SHT_SYMTAB type or a section of SHT_DYNSYM type, but not both. This restriction may be relaxed in the future. |
SHT_FINI_ARRAY | 0xf | This section contains an array of pointers to termination functions, as described in `Initialization and Termination Functions' in Chapter 5. Each pointer in the array is taken as a parameterless procedure with a void return. |
SHT_HASH | 0x5 | The section holds a symbol hash table. Currently, an object file shall have only one hash table, but this restriction may be relaxed in the future. See `Hash Table' in the Chapter 5 for details. |
SHT_HIPROC | 0x7fffffff | Values in this inclusive range are reserved for processor-specific semantics. |
SHT_HIUSER | 0xffffffff | This value specifies the upper bound of the range of indexes reserved for application programs. Section types between SHT_LOUSER and SHT_HIUSER can be used by the application, without conflicting with current or future system-defined section types. |
SHT_INIT_ARRAY | 0xe | This section contains an array of pointers to initialization functions, as described in `Initialization and Termination Functions' in Chapter 5. Each pointer in the array is taken as a parameterless procedure with a void return. |
SHT_LOPROC | 0x70000000 | Values in this inclusive range are reserved for processor-specific semantics. |
SHT_LOUSER | 0x80000000 | This value specifies the lower bound of the range of indexes reserved for application programs. |
SHT_NOBITS | 0x8 | A section of this type occupies no space in the file but otherwise resembles SHT_PROGBITS. Although this section contains no bytes, the sh_offset member contains the conceptual file offset. |
SHT_NOTE | 0x7 | The section holds information that marks the file in some way. See `Note Section' in Chapter 5 for details. |
SHT_NULL | 0x0 | This value marks the section header as inactive; it does not have an associated section. Other members of the section header have undefined values. |
SHT_PREINIT_ARRAY | 0x10 | This section contains an array of pointers to functions that are invoked before all other initialization functions, as described in `Initialization and Termination Functions' in Chapter 5. Each pointer in the array is taken as a parameterless proceure with a void return. |
SHT_PROGBITS | 0x1 | The section holds information defined by the program, whose format and meaning are determined solely by the program. |
SHT_REL | 0x9 | The section holds relocation entries without explicit addends, such as type Elf32_Rel for the 32-bit class of object files or type Elf64_Rel for the 64-bit class of object files. An object file may have multiple relocation sections. See "Relocation" |
SHT_RELA | 0x4 | The section holds relocation entries with explicit addends, such as type Elf32_Rela for the 32-bit class of object files or type Elf64_Rela for the 64-bit class of object files. An object file may have multiple relocation sections. `Relocation' b |
SHT_SHLIB | 0xa | This section type is reserved but has unspecified semantics. |
SHT_STRTAB | 0x3 | The section holds a string table. An object file may have multiple string table sections. See `String Table' below for details. |
SHT_SYMTAB | 0x2 | This section holds a symbol table. Currently, an object file may have either a section of SHT_SYMTAB type or a section of SHT_DYNSYM type, but not both. This restriction may be relaxed in the future. Typically, SHT_SYMTAB provides symbols for link editing, though it may also be used for dynamic linking. As a complete symbol table, it may contain many symbols unnecessary for dynamic linking. |
Various sections hold program and control information. Sections in the lists below are used by the system and have the indicated types and attributes.
The following sections are defined in the System V ABI and the System V ABI Update.
Table 5-1. ELF Special Sections
Name | Type | Attributes |
---|---|---|
.bss | SHT_NOBITS | SHF_ALLOC+SHF_WRITE |
.comment | SHT_PROGBITS | 0 |
.data | SHT_PROGBITS | SHF_ALLOC+SHF_WRITE |
.data1 | SHT_PROGBITS | SHF_ALLOC+SHF_WRITE |
.debug | SHT_PROGBITS | 0 |
.dynamic | SHT_DYNAMIC | SHF_ALLOC+SHF_WRITE |
.dynstr | SHT_STRTAB | SHF_ALLOC |
.dynsym | SHT_DYNSYM | SHF_ALLOC |
.fini | SHT_PROGBITS | SHF_ALLOC+SHF_EXECINSTR |
.fini_array | SHT_FINI_ARRAY | SHF_ALLOC+SHF_WRITE |
.hash | SHT_HASH | SHF_ALLOC |
.init | SHT_PROGBITS | SHF_ALLOC+SHF_EXECINSTR |
.init_array | SHT_INIT_ARRAY | SHF_ALLOC+SHF_WRITE |
.interp | SHT_PROGBITS | SHF_ALLOC |
.line | SHT_PROGBITS | 0 |
.note | SHT_NOTE | 0 |
.preinit_array | SHT_PREINIT_ARRAY | SHF_ALLOC+SHF_WRITE |
.rodata | SHT_PROGBITS | SHF_ALLOC |
.rodata1 | SHT_PROGBITS | SHF_ALLOC |
.shstrtab | SHT_STRTAB | 0 |
.strtab | SHT_STRTAB | SHF_ALLOC |
.symtab | SHT_SYMTAB | SHF_ALLOC |
.tbss | SHT_NOBITS | SHF_ALLOC+SHF_WRITE+SHF_TLS |
.tdata | SHT_PROGBITS | SHF_ALLOC+SHF_WRITE+SHF_TLS |
.text | SHT_PROGBITS | SHF_ALLOC+SHF_EXECINSTR |
This section holds data that contributes to the program's memory image. The program may treat this data as uninitialized. However, the system shall initialize this data with zeroes when the program begins to run. The section occupies no file space, as indicated by the section type, SHT_NOBITS
This section holds version control information.
This section holds initialized data that contribute to the program's memory image.
This section holds initialized data that contribute to the program's memory image.
This section holds information for symbolic debugging. The contents are unspecified. All section names with the prefix .debug hold information for symbolic debugging. The contents of these sections are unspecified.
This section holds dynamic linking information. The section's attributes will include the SHF_ALLOC bit. Whether the SHF_WRITE bit is set is processor specific. See Chapter 5 for more information.
This section holds strings needed for dynamic linking, most commonly the strings that represent the names associated with symbol table entries. See Chapter 5 for more information.
This section holds the dynamic linking symbol table, as described in `Symbol Table'. See Chapter 5 for more information.
This section holds executable instructions that contribute to the process termination code. That is, when a program exits normally, the system arranges to execute the code in this section.
This section holds an array of function pointers that contributes to a single termination array for the executable or shared object containing the section.
This section holds a symbol hash table. See `Hash Table' in Chapter 5 for more information.
This section holds executable instructions that contribute to the process initialization code. When a program starts to run, the system arranges to execute the code in this section before calling the main program entry point (called main for C programs)
This section holds an array of function pointers that contributes to a single initialization array for the executable or shared object containing the section.
This section holds the path name of a program interpreter. If the file has a loadable segment that includes relocation, the sections' attributes will include the SHF_ALLOC bit; otherwise, that bit will be off. See Chapter 5 for more information.
This section holds line number information for symbolic debugging, which describes the correspondence between the source program and the machine code. The contents are unspecified.
This section holds information in the format that `Note Section' in Chapter 5 describes of the System V Application Binary Interface, Edition 4.1.
This section holds an array of function pointers that contributes to a single pre-initialization array for the executable or shared object containing the section.
This section holds read-only data that typically contribute to a non-writable segment in the process image. See `Program Header' in Chapter 5 for more information.
This section hold sread-only data that typically contribute to a non-writable segment in the process image. See `Program Header' in Chapter 5 for more information.
This section holds section names.
This section holds strings, most commonly the strings that represent the names associated with symbol table entries. If the file has a loadable segment that includes the symbol string table, the section's attributes will include the SHF_ALLOC bit; otherwi
This section holds a symbol table, as `Symbol Table'. in this chapter describes. If the file has a loadable segment that includes the symbol table, the section's attributes will include the SHF_ALLOC bit; otherwise, that bit will be off.
This section holds uninitialized thread-local data that contribute to the program's memory image. By definition, the system initializes the data with zeros when the data is instantiated for each new execution flow. The section occupies no file space, as indicated by the section type, SHT_NOBITS. Implementations need not support thread-local storage.
This section holds initialized thread-local data that contributes to the program's memory image. A copy of its contents is instantiated by the system for each new execution flow. Implementations need not support thread-local storage.
This section holds the `text,' or executable instructions, of a program.
Object files in an LSB conforming application may also contain one or more of the additional special sections described below.
Table 5-2. Additional Special Sections
Name | Type | Attributes |
---|---|---|
.ctors | SHT_PROGBITS | SHF_ALLOC+SHF_WRITE |
.dtors | SHT_PROGBITS | SHF_ALLOC+SHF_WRITE |
.eh_frame | SHT_PROGBITS | SHF_ALLOC |
.eh_frame_hdr | SHT_PROGBITS | SHF_ALLOC |
.gnu.version | SHT_GNU_versym | SHF_ALLOC |
.gnu.version_d | SHT_GNU_verdef | SHF_ALLOC |
.gnu.version_r | SHT_GNU_verneed | SHF_ALLOC |
.jcr | SHT_PROGBITS | SHF_ALLOC+SHF_WRITE |
.note.ABI-tag | SHT_NOTE | SHF_ALLOC |
.stab | SHT_PROGBITS | 0 |
.stabstr | SHT_STRTAB | 0 |
This section contains a list of global constructor function pointers.
This section contains a list of global destructor function pointers.
This section contains information necessary for frame unwinding during exception handling.
This section contains a pointer to the .eh_frame section which is accessible to the runtime support code of a C++ application. This section may also contain a binary search table which may be used by the runtime support code to more efficiently access records in the .eh_frame section.
This section contains the Symbol Version Table.
This section contains the Version Definitions.
This section contains the Version Requirments.
This section contains information necessary for registering compiled Java classes. The contents are compiler-specific and used by compiler initialization functions.
Specify ABI details.
This section contains debugging information. The contents are not specified as part of the LSB.
This section contains strings associated with the debugging infomation contained in the .stab section.
This chapter defines how names are mapped from the source symbol to the object symbol.
Symbols in a source program are translated by the compilation system into symbols that exist in the object file. The rules for this translation are defined here.
In addition to the Call Frame Instructions defined in section 6.4.2 of DWARF Debugging Information Format, the following Call Frame Instructions may also be used.
Table 7-1. Additional DWARF Call Frame Instructions
Name | Value | Meaning |
---|---|---|
DW_CFA_expression | 0x10 | The DW_CFA_expression instruction takes two operands: an unsigned LEB128 value representing a register number, and a DW_FORM_block value representing a DWARF expression. The required action is to establish the DWARF expression as the means by which the address in which the given register contents are found may be computed. The value of the CFA is pushed on the DWARF evaluation stack prior to execution of the DWARF expression. The DW_OP_call2, DW_OP_call4, DW_OP_call_ref and DW_OP_push_object_address DWARF operators (see Section 2.4.1 of DWARF Debugging Information Format) cannot be used in such a DWARF expression. |
DW_CFA_offset_extended_sf | 0x11 | The DW_CFA_offset_extended_sf instruction takes two operands: an unsigned LEB128 value representing a register number and a signed LEB128 factored offset. This instruction is identical to DW_CFA_offset_extended except that the second operand is signed. |
DW_CFA_def_cfa_sf | 0x12 | The DW_CFA_def_cfa_sf instruction takes two operands: an unsigned LEB128 value representing a register number and a signed LEB128 factored offset. This instruction is identical to DW_CFA_def_cfa except that the second operand is signed and factored. |
DW_CFA_def_cfa_offset_sf | 0x13 | The DW_CFA_def_cfa_offset_sf instruction takes a signed LEB128 operand representing a factored offset. This instruction is identical to DW_CFA_def_cfa_offset except that the operand is signed and factored. |
DW_CFA_GNU_args_size | 0x2e | The DW_CFA_def_cfa_offset_sf instruction takes an unsigned LEB128 operand representing an argument size. |
DW_CFA_GNU_negative_offset_extended | 0x2f | The DW_CFA_def_cfa_sf instruction takes two operands: an unsigned LEB128 value representing a register number and an unsigned LEB128 which represents the magnitude of the offset. This instruction is identical to DW_CFA_offset_extended_sf except that the operand is subtracted to produce the offset. This instructions is obsoleted by DW_CFA_offset_extended_sf. |
This chapter will contain a formal description of the contents of the .eh_frame_hdr section.
The .eh_frame_hdr section contains additional information about the .eh_frame section. A pointer to the start of the .eh_frame data, and optionally, a binary search table of pointers to the .eh_frame records are found in this section.
Data in this section is encoded according to the DWARF Exception Header Encoding described below.
Table 9-1. .eh_frame_hdr Section Format
Encoding | Field |
---|---|
unsigned byte | version |
unsigned byte | eh_frame_ptr_enc |
unsigned byte | fde_count_enc |
unsigned byte | table_enc |
encoded | eh_frame_ptr |
encoded | fde_count |
binary search table |
Version of the .eh_frame_hdr format. This value shall be 1.
The encoding format of the eh_frame_ptr field.
The encoding format of the fde_count field. A value of DW_EH_PE_omit indicates the binary search table is not present.
The encoding format of the entries in the binary search table. A value of DW_EH_PE_omit indicates the binary search table is not present.
The encoded value of the pointer to the start of the .eh_frame section.
The encoded value of the count of entries in the binary search table.
A binary search table containing fde_count entries. Each entry of the table consist of two encoded values, the initial location, and the address. The entries are sorted in an increasing order by the initial location value.
The DWARF Exception Header Encoding is used to describe the type of data used in the .eh_frame_hdr section. The upper 4 bits indicate how the value is to be applied. The lower 4 bits indicate the format of the data.
Table 9-2. DWARF Exception Header value format
Name | Value | Meaning |
---|---|---|
DW_EH_PE_omit | 0xff | No value is present. |
DW_EH_PE_uleb128 | 0x01 | Unsigned value is encoded using the Little Endian Base 128 (LEB128) as defined by DWARF Debugging Information Format. |
DW_EH_PE_udata2 | 0x02 | A 2 bytes unsigned value. |
DW_EH_PE_udata4 | 0x03 | A 4 bytes unsigned value. |
DW_EH_PE_udata8 | 0x04 | An 8 bytes unsigned value. |
DW_EH_PE_sleb128 | 0x09 | Signed value is encoded using the Little Endian Base 128 (LEB128) as defined by DWARF Debugging Information Format. |
DW_EH_PE_sdata2 | 0x0A | A 2 bytes signed value. |
DW_EH_PE_sdata4 | 0x0B | A 4 bytes signed value. |
DW_EH_PE_sdata8 | 0x0C | An 8 bytes signed value. |
Table 9-3. DWARF Exception Header application
Name | Value | Meaning |
---|---|---|
DW_EH_PE_absptr | 0x00 | Value is used with no modification. |
DW_EH_PE_pcrel | 0x10 | Value is reletive to the current program counter. |
DW_EH_PE_datarel | 0x30 | Value is reletive to the beginning of the .eh_frame_hdr section. |
DW_EH_PE_omit | 0xff | No value is present. |
This chapter describes the Symbol Versioning mechanism. All ELF objects may provide or depend on versioned symbols. Symbol Versioning is implemented by 3 section types: SHT_GNU_versym, SHT_GNU_verdef, and SHT_GNU_verneed.
The prefix Elfxx in the following descriptions and code fragments stands for either "Elf32" or "Elf64", depending on the architecture.
Versions are described by strings. The structures that are used for symbol versions also contain a member that holds the ELF hashing values of the strings. This allows for more efficient processing.
The special section .gnu.version which has a section type of SHT_GNU_versym shall contain the Symbol Version Table. This section shall have the same number of entries as the Dynamic Symbol Table in the .dynsym section.
The .gnu.version section shall contain an array of elements of type Elfxx_Half. Each entry specifies the version defined for or required by the corresponding symbol in the Dynamic Symbol Table.
The values in the Symbol Version Table are specific to the object in which they
are located. These values are identifiers that are provided by the the
vna_other
member of the
Elfxx_Vernaux structure or the
vd_ndx
member of the
Elfxx_Verdef structure.
The values 0 and 1 are reserved.
The symbol is local, not available outside the object.
The symbol is defined in this object and is globally available.
All other values are used to identify version strings located in one of the other Symbol Version sections. The value itself is not the version associated with the symbol. The string identified by the value defines the version of the symbol.
Symbol definitions are contained in the special section .gnu.version_d which has a section type of SHT_GNU_verdef. The number of entries in this section is contained in the DT_VERDEFNUM entry of the Dynamic Section. The sh_link member of the section header points to the section that contains the strings referenced by this section.
The special section .gnu.version_d which has a section type of SHT_GNU_verdef shall contain symbol version definitions. The number of entries in this section shall be contained in the DT_VERDEFNUM entry of the Dynamic Section .dynamic. The sh_link member of the section header (see figure 4-8 in the System V ABI) shall point to the section that contains the strings referenced by this section.
The section shall contain an array of Elfxx_Verdef structures, as described in Figure 10-1, optionally followed by an array of Elfxx_Verdaux structures, as defined in Figure 10-2.
typedef struct { Elfxx_Half vd_version; Elfxx_Half vd_flags; Elfxx_Half vd_ndx; Elfxx_Half vd_cnt; Elfxx_Word vd_hash; Elfxx_Word vd_aux; Elfxx_Word vd_next; } Elfxx_Verdef; |
Figure 10-1. Version Definition Entries
vd_version
Version revision. This field shall be set to 1.
vd_flags
Version information flag bitmask.
vd_ndx
Version index numeric value referencing the SHT_GNU_versym section.
vd_cnt
Number of associated verdaux array entries.
vd_hash
Version name hash value (ELF hash function).
vd_aux
Offset in bytes to a corresponding entry in an array of Elfxx_Verdaux structures as defined in Figure 10-2
vd_next
Offset to the next verdef entry, in bytes.
typedef struct { Elfxx_Word vda_name; Elfxx_Word vda_next; } Elfxx_Verdaux; |
Figure 10-2. Version Definition Auxiliary Entries
vda_name
Offset to the version or dependency name string in the section header, in bytes.
vda_next
Offset to the next verdaux entry, in bytes.
The special section .gnu.version_r which has a section type of
SHT_GNU_verneed
shall contain required symbol version definitions. The number of entries in
this section shall be contained in the DT_VERNEEDNUM entry of the Dynamic
Section .dynamic.
The sh_link
member of the section header (see figure 4-8 in
System V ABI)
shall point to the section that contains the strings referenced by this section.
The section shall contain an array of Elfxx_Verneed structures, as described in Figure 10-3, optionally followed by an array of Elfxx_Vernaux structures, as defined in Figure 10-4.
typedef struct { Elfxx_Half vn_version; Elfxx_Half vn_cnt; Elfxx_Word vn_file; Elfxx_Word vn_aux; Elfxx_Word vn_next; } Elfxx_Verneed; |
Figure 10-3. Version Needed Entries
vn_version
Version of structure. This value is currently set to 1, and will be reset if the versioning implementation is incompatibly altered.
vn_cnt
Number of associated verneed array entries.
vn_file
Offset to the file name string in the section header, in bytes.
vn_aux
Offset to a corresponding entry in the vernaux array, in bytes.
vn_next
Offset to the next verneed entry, in bytes.
typedef struct { Elfxx_Word vna_hash; Elfxx_Half vna_flags; Elfxx_Half vna_other; Elfxx_Word vna_name; Elfxx_Word vna_next; } Elfxx_Vernaux; |
Figure 10-4. Version Needed Auxiliary Entries
vna_hash
Dependency name hash value (ELF hash function).
vna_flags
Dependency information flag bitmask.
vna_other
Object file version identifier used in the .gnu.version symbol version array. Bit number 15 controls whether or not the object is hidden; if this bit is set, the object cannot be used and the static linker will ignore the symbol's presence in the object.
vna_name
Offset to the dependency name string in the section header, in bytes.
vna_next
Offset to the next vernaux entry, in bytes.
When loading a sharable object the system shall analyze version definition data from the loaded object to assure that it meets the version requirements of the calling object. This step is referred to as definition testing. The dynamic loader shall retrieve the entries in the caller's Elfxx_Verneed array and attempt to find matching definition information in the loaded Elfxx_Verdef table.
Each object and dependency shall be tested in turn. If a symbol definition is missing and the vna_flags bit for VER_FLG_WEAK is not set, the loader shall return an error and exit. If the vna_flags bit for VER_FLG_WEAK is set in the Elfxx_Vernaux entry, and the loader shall issue a warning and continue operation.
When the versions referenced by undefined symbols in the loaded object are found, version availability is certified. The test completes without error and the object shall be made available.
When symbol versioning is used in an object, relocations extend definition testing beyond the simple match of symbol name strings: the version of the reference shall also equal the name of the definition.
The same index that is used in the symbol table can be referenced in the SHT_GNU_versym section, and the value of this index is then used to acquire name data. The corresponding requirement string is retrieved from the Elfxx_Verneed array, and likewise, the corresponding definition string from the Elfxx_Verdef table.
If the high order bit (bit number 15) of the version symbolis set, the object cannot be used and the static linker shall ignore the symbol's presence in the object.
When an object with a reference and an object with the definition are being linked, the following rules shall govern the result:
The object with the reference and the object with the definitions both use
versioning. All described matching is processed in this case. A fatal error
shall be triggered when no matching definition can be found in the object whose
name is the one referenced by the vn_name
element in the
Elfxx_Verneed entry.
The object with the reference does not use versioning, while the object with the definitions does. In this instance, only the definitions with index numbers 1 and 2 will be used in the reference match, the same identified by the static linker as the base definition. In cases where the static linker was not used, such as in calls to dlopen(), a version that does not have the base definition index shall be acceptable if it is the only version for which the symbol is defined.
The object with the reference uses versioning, but the object with the definitions specifies none. A matching symbol shall be accepted in this case. A fatal error shall be triggered if a corruption in the required symbols list obscures an outdated object file and causes a match on the object filename in the Elfxx_Verneed entry.
Neither the object with the reference nor the object with the definitions use versioning. The behavior in this instance shall default to pre-existing symbol rules.
Every executable shall contain a section named .note.ABI-tag of type SHT_NOTE. This section is structured as a note section as documented in the ELF spec. The section shall contain at least the following entry. The name field (namesz/name) contains the string "GNU". The type field shall be 1. The descsz field shall be at least 16, and the first 16 bytes of the desc field shall be as follows.
The first 32-bit word of the desc field shall be 0 (this signifies a Linux executable). The second, third, and fourth 32-bit words of the desc field contain the earliest compatible kernel version. For example, if the 3 words are 2, 2, and 5, this signifies a 2.2.5 kernel.
LSB-conforming implementations shall support the object file information and system actions that create running programs as specified in the System V ABI and System V ABI Update and as supplemented by this document and an architecture-specific LSB specification.
Any shared object that is loaded shall contain sufficient DT_NEEDED records to satisfy the symbols on the shared library.
In addition to the Segment Types defined in the System V ABI and System V ABI Update the following Segment Types shall also be supported.
The array element specifies the location and size of the exception handling information as defined by the .eh_frame_hdr section.
The p_flags
member specifies the permissions on the segment containing the stack
and is used to indicate wether the stack should be executable. The absense of
this header indicates that the stack will be executable.
As described in System V ABI, if an object file participates in dynamic linking, its program header table shall have an element of type PT_DYNAMIC. This `segment' contains the .dynamic section. A special symbol, _DYNAMIC, labels the section, which contains an array of the following structures.
typedef struct { Elf32_Sword d_tag; union { Elf32_Word d_val; Elf32_Addr d_ptr; } d_un; } Elf32_Dyn; extern Elf32_Dyn _DYNAMIC[]; typedef struct { Elf64_Sxword d_tag; union { Elf64_Xword d_val; Elf64_Addr d_ptr; } d_un; } Elf64_Dyn; extern Elf64_Dyn _DYNAMIC[]; |
Figure 14-1. Dynamic Structure
For each object with this type, d_tag
controls the interpretation of d_un
.
The following dynamic entries are defined in the System V ABI and System V ABI Update.
Process relocations of object
For debugging; unspecified
Address of termination function
Address of symbol hash table
End of processor-specific
Address of init function
Address of PLT relocs
Start of processor-specific
Name of needed library
Marks end of dynamic section
Type of reloc in PLT
Size in bytes of PLT relocs
Address of Rel relocs
Address of Rela relocs
Size of one Rela reloc
Total size of Rela relocs
Size of one Rel reloc
Total size of Rel relocs
Library search path
Name of shared object
Size of string table
Address of string table
Start symbol search here
Size of one symbol table entry
Address of symbol table
Reloc might modify .text
An LSB conforming object may also use the following additional Dynamic Entry types.
Values from DT_ADDRRNGLO through DT_ADDRRNGHI are reserved for definition by an archLSB.
Values from DT_ADDRRNGLO through DT_ADDRRNGHI are reserved for definition by an archLSB.
Shared object to load before self
Shared object to get values from
The address of an array of pointers to termination functions.
Size in bytes of DT_FINI_ARRAY
Values from DT_LOOS through DT_HIOS are reserved for definition by specific operating systems.
The address of an array of pointers to initialization functions.
Size in bytes of DT_INIT_ARRAY
Values from DT_LOOS through DT_HIOS are reserved for definition by specific operating systems.
Number of dynamic entry tags defined (excepting reserved ranges).
Flags for DT_* entries, effecting the following DT_* entry
All Elf32_Rel R_*_RELATIVE relocations have been placed into a single block and this entry specifies the number of entries in that block. This permits ld.so.1 to streamline the processing of RELATIVE relocations.
null-terminated library search path string
Entry size of syminfo
Address of the Syminfo table.
Size of syminfo table (in bytes)
Entries which fall between DT_VALRNGHI & DT_VALRNGLO use the Dyn.d_un.d_val field of the Elf*_Dyn structure.
Entries which fall between DT_VALRNGHI & DT_VALRNGLO use the Dyn.d_un.d_val field of the Elf*_Dyn structure.
Address of version definition table
Number of version definitions
Address of table with needed versions
Number of needed versions
Address of the table provided by the .gnu.version section.
An LSB-conforming implementation shall support the following base libraries which provide interfaces for accessing the operating system, processor and other hardware in the system.
libc
libm
libgcc_s
libdl
libcrypt
libpam
The Program Interpreter is specified in the appropriate architecture-specific LSB specification.
Table 1-1 defines the library name and shared object name for the libc library
The behavior of the interfaces in this library is specified by the following specifications:
Large File Support |
this specification |
SUSv2 |
ISO POSIX (2003) |
SVID Issue 3 |
SVID Issue 4 |
An LSB conforming implementation shall provide the generic functions for RPC specified in Table 1-2, with the full mandatory functionality as described in the referenced underlying specification.
Table 1-2. libc - RPC Function Interfaces
authnone_create [1] | svc_getreqset [2] | svcudp_create [3] | xdr_int [2] | xdr_u_long [2] |
clnt_create [1] | svc_register [3] | xdr_accepted_reply [2] | xdr_long [2] | xdr_u_short [2] |
clnt_pcreateerror [1] | svc_run [3] | xdr_array [2] | xdr_opaque [2] | xdr_union [2] |
clnt_perrno [1] | svc_sendreply [3] | xdr_bool [2] | xdr_opaque_auth [2] | xdr_vector [2] |
clnt_perror [1] | svcerr_auth [2] | xdr_bytes [2] | xdr_pointer [2] | xdr_void [2] |
clnt_spcreateerror [1] | svcerr_decode [2] | xdr_callhdr [2] | xdr_reference [2] | xdr_wrapstring [2] |
clnt_sperrno [1] | svcerr_noproc [2] | xdr_callmsg [2] | xdr_rejected_reply [2] | xdrmem_create [2] |
clnt_sperror [1] | svcerr_noprog [2] | xdr_char [2] | xdr_replymsg [2] | xdrrec_create [2] |
key_decryptsession [2] | svcerr_progvers [2] | xdr_double [2] | xdr_short [2] | xdrrec_eof [2] |
pmap_getport [3] | svcerr_systemerr [2] | xdr_enum [2] | xdr_string [2] | |
pmap_set [3] | svcerr_weakauth [2] | xdr_float [2] | xdr_u_char [2] | |
pmap_unset [3] | svctcp_create [3] | xdr_free [2] | xdr_u_int [3] |
Referenced Specification(s)
[1]. SVID Issue 4
[2]. SVID Issue 3
[3]. this specification
An LSB conforming implementation shall provide the generic functions for System Calls specified in Table 1-3, with the full mandatory functionality as described in the referenced underlying specification.
Table 1-3. libc - System Calls Function Interfaces
__fxstat [1] | fchmod [2] | getwd [2] | read [2] | setrlimit [2] |
__getpgid [1] | fchown [2] | initgroups [1] | readdir [2] | setrlimit64 [3] |
__lxstat [1] | fcntl [1] | ioctl [1] | readdir_r [2] | setsid [2] |
__xmknod [1] | fdatasync [2] | kill [1] | readlink [2] | setuid [2] |
__xstat [1] | flock [1] | killpg [2] | readv [2] | sleep [2] |
access [2] | fork [2] | lchown [2] | rename [2] | statvfs [2] |
acct [1] | fstatvfs [2] | link [1] | rmdir [2] | stime [1] |
alarm [2] | fsync [2] | lockf [2] | sbrk [4] | symlink [2] |
brk [4] | ftime [2] | lseek [2] | sched_get_priority_max [2] | sync [2] |
chdir [2] | ftruncate [2] | mkdir [2] | sched_get_priority_min [2] | sysconf [2] |
chmod [2] | getcontext [2] | mkfifo [2] | sched_getparam [2] | time [2] |
chown [2] | getegid [2] | mlock [2] | sched_getscheduler [2] | times [2] |
chroot [4] | geteuid [2] | mlockall [2] | sched_rr_get_interval [2] | truncate [2] |
clock [2] | getgid [2] | mmap [2] | sched_setparam [2] | ulimit [2] |
close [2] | getgroups [2] | mprotect [2] | sched_setscheduler [2] | umask [2] |
closedir [2] | getitimer [2] | msync [2] | sched_yield [2] | uname [2] |
creat [2] | getloadavg [1] | munlock [2] | select [2] | unlink [1] |
dup [2] | getpagesize [4] | munlockall [2] | setcontext [2] | utime [2] |
dup2 [2] | getpgid [2] | munmap [2] | setegid [2] | utimes [2] |
execl [2] | getpgrp [2] | nanosleep [2] | seteuid [2] | vfork [2] |
execle [2] | getpid [2] | nice [2] | setgid [2] | wait [2] |
execlp [2] | getppid [2] | open [2] | setitimer [2] | wait4 [1] |
execv [2] | getpriority [2] | opendir [2] | setpgid [2] | waitpid [1] |
execve [2] | getrlimit [2] | pathconf [2] | setpgrp [2] | write [2] |
execvp [2] | getrusage [2] | pause [2] | setpriority [2] | writev [2] |
exit [2] | getsid [2] | pipe [2] | setregid [2] | |
fchdir [2] | getuid [2] | poll [2] | setreuid [2] |
Referenced Specification(s)
[1]. this specification
[2]. ISO POSIX (2003)
[3]. Large File Support
[4]. SUSv2
An LSB conforming implementation shall provide the generic functions for Standard I/O specified in Table 1-4, with the full mandatory functionality as described in the referenced underlying specification.
Table 1-4. libc - Standard I/O Function Interfaces
_IO_feof [1] | fgetpos [2] | fsetpos [2] | putchar [2] | sscanf [1] |
_IO_getc [1] | fgets [2] | ftell [2] | putchar_unlocked [2] | telldir [2] |
_IO_putc [1] | fgetwc_unlocked [1] | ftello [2] | puts [2] | tempnam [2] |
_IO_puts [1] | fileno [2] | fwrite [2] | putw [3] | ungetc [2] |
asprintf [1] | flockfile [2] | getc [2] | remove [2] | vasprintf [1] |
clearerr [2] | fopen [2] | getc_unlocked [2] | rewind [2] | vdprintf [1] |
ctermid [2] | fprintf [2] | getchar [2] | rewinddir [2] | vfprintf [2] |
fclose [2] | fputc [2] | getchar_unlocked [2] | scanf [1] | vprintf [2] |
fdopen [2] | fputs [2] | getw [3] | seekdir [2] | vsnprintf [2] |
feof [2] | fread [2] | pclose [2] | setbuf [2] | vsprintf [2] |
ferror [2] | freopen [2] | popen [2] | setbuffer [1] | |
fflush [2] | fscanf [1] | printf [2] | setvbuf [2] | |
fflush_unlocked [1] | fseek [2] | putc [2] | snprintf [2] | |
fgetc [2] | fseeko [2] | putc_unlocked [2] | sprintf [2] |
Referenced Specification(s)
[1]. this specification
[2]. ISO POSIX (2003)
[3]. SUSv2
An LSB conforming implementation shall provide the generic data interfaces for Standard I/O specified in Table 1-5, with the full mandatory functionality as described in the referenced underlying specification.
Referenced Specification(s)
[1]. ISO POSIX (2003)
An LSB conforming implementation shall provide the generic functions for Signal Handling specified in Table 1-6, with the full mandatory functionality as described in the referenced underlying specification.
Table 1-6. libc - Signal Handling Function Interfaces
__libc_current_sigrtmax [1] | sigaction [2] | sighold [2] | sigorset [1] | sigset [2] |
__libc_current_sigrtmin [1] | sigaddset [2] | sigignore [2] | sigpause [2] | sigsuspend [2] |
__sigsetjmp [1] | sigaltstack [2] | siginterrupt [2] | sigpending [2] | sigtimedwait [2] |
__sysv_signal [1] | sigandset [1] | sigisemptyset [1] | sigprocmask [2] | sigwait [2] |
bsd_signal [2] | sigdelset [2] | sigismember [2] | sigqueue [2] | sigwaitinfo [2] |
psignal [1] | sigemptyset [2] | siglongjmp [2] | sigrelse [2] | |
raise [2] | sigfillset [2] | signal [2] | sigreturn [1] |
Referenced Specification(s)
[1]. this specification
[2]. ISO POSIX (2003)
An LSB conforming implementation shall provide the generic data interfaces for Signal Handling specified in Table 1-7, with the full mandatory functionality as described in the referenced underlying specification.
Referenced Specification(s)
[1]. this specification
An LSB conforming implementation shall provide the generic functions for Localization Functions specified in Table 1-8, with the full mandatory functionality as described in the referenced underlying specification.
Table 1-8. libc - Localization Functions Function Interfaces
bind_textdomain_codeset [1] | dcgettext [1] | freelocale(GLIBC_2.3) [1] | localeconv [2] | textdomain [1] |
bindtextdomain [1] | dcngettext [1] | gettext [1] | newlocale(GLIBC_2.3) [1] | uselocale(GLIBC_2.3) [1] |
catclose [2] | dgettext [1] | iconv [2] | ngettext [1] | |
catgets [2] | dngettext [1] | iconv_close [2] | nl_langinfo [2] | |
catopen [2] | duplocale(GLIBC_2.3) [1] | iconv_open [2] | setlocale [2] |
Referenced Specification(s)
[1]. this specification
[2]. ISO POSIX (2003)
An LSB conforming implementation shall provide the generic data interfaces for Localization Functions specified in Table 1-9, with the full mandatory functionality as described in the referenced underlying specification.
Referenced Specification(s)
[1]. this specification
An LSB conforming implementation shall provide the generic functions for Socket Interface specified in Table 1-10, with the full mandatory functionality as described in the referenced underlying specification.
Table 1-10. libc - Socket Interface Function Interfaces
__h_errno_location [1] | gethostname [2] | if_nameindex [2] | send [2] | socket [2] |
accept [2] | getpeername [2] | if_nametoindex [2] | sendmsg [2] | socketpair [2] |
bind [2] | getsockname [2] | listen [2] | sendto [2] | |
bindresvport [1] | getsockopt [1] | recv [2] | setsockopt [1] | |
connect [2] | if_freenameindex [2] | recvfrom [2] | shutdown [2] | |
gethostid [2] | if_indextoname [2] | recvmsg [2] | sockatmark [2] |
Referenced Specification(s)
[1]. this specification
[2]. ISO POSIX (2003)
An LSB conforming implementation shall provide the generic functions for Wide Characters specified in Table 1-11, with the full mandatory functionality as described in the referenced underlying specification.
Table 1-11. libc - Wide Characters Function Interfaces
__wcstod_internal [1] | mbsinit [2] | vwscanf [1] | wcsnlen [1] | wcstoumax [2] |
__wcstof_internal [1] | mbsnrtowcs [1] | wcpcpy [1] | wcsnrtombs [1] | wcstouq [1] |
__wcstol_internal [1] | mbsrtowcs [2] | wcpncpy [1] | wcspbrk [2] | wcswcs [2] |
__wcstold_internal [1] | mbstowcs [2] | wcrtomb [2] | wcsrchr [2] | wcswidth [2] |
__wcstoul_internal [1] | mbtowc [2] | wcscasecmp [1] | wcsrtombs [2] | wcsxfrm [2] |
btowc [2] | putwc [2] | wcscat [2] | wcsspn [2] | wctob [2] |
fgetwc [2] | putwchar [2] | wcschr [2] | wcsstr [2] | wctomb [2] |
fgetws [2] | swprintf [2] | wcscmp [2] | wcstod [2] | wctrans [2] |
fputwc [2] | swscanf [1] | wcscoll [2] | wcstof [2] | wctype [2] |
fputws [2] | towctrans [2] | wcscpy [2] | wcstoimax [2] | wcwidth [2] |
fwide [2] | towlower [2] | wcscspn [2] | wcstok [2] | wmemchr [2] |
fwprintf [2] | towupper [2] | wcsdup [1] | wcstol [2] | wmemcmp [2] |
fwscanf [1] | ungetwc [2] | wcsftime [2] | wcstold [2] | wmemcpy [2] |
getwc [2] | vfwprintf [2] | wcslen [2] | wcstoll [2] | wmemmove [2] |
getwchar [2] | vfwscanf [1] | wcsncasecmp [1] | wcstombs [2] | wmemset [2] |
mblen [2] | vswprintf [2] | wcsncat [2] | wcstoq [1] | wprintf [2] |
mbrlen [2] | vswscanf [1] | wcsncmp [2] | wcstoul [2] | wscanf [1] |
mbrtowc [2] | vwprintf [2] | wcsncpy [2] | wcstoull [2] |
Referenced Specification(s)
[1]. this specification
[2]. ISO POSIX (2003)
An LSB conforming implementation shall provide the generic functions for String Functions specified in Table 1-12, with the full mandatory functionality as described in the referenced underlying specification.
Table 1-12. libc - String Functions Function Interfaces
__mempcpy [1] | bzero [2] | strcasestr [1] | strncat [2] | strtok [2] |
__rawmemchr [1] | ffs [2] | strcat [2] | strncmp [2] | strtok_r [2] |
__stpcpy [1] | index [2] | strchr [2] | strncpy [2] | strtold [2] |
__strdup [1] | memccpy [2] | strcmp [2] | strndup [1] | strtoll [2] |
__strtod_internal [1] | memchr [2] | strcoll [2] | strnlen [1] | strtoq [1] |
__strtof_internal [1] | memcmp [2] | strcpy [2] | strpbrk [2] | strtoull [2] |
__strtok_r [1] | memcpy [2] | strcspn [2] | strptime [1] | strtoumax [2] |
__strtol_internal [1] | memmove [2] | strdup [2] | strrchr [2] | strtouq [1] |
__strtold_internal [1] | memrchr [1] | strerror [2] | strsep [1] | strxfrm [2] |
__strtoll_internal [1] | memset [2] | strerror_r [1] | strsignal [1] | swab [2] |
__strtoul_internal [1] | rindex [2] | strfmon [2] | strspn [2] | |
__strtoull_internal [1] | stpcpy [1] | strftime [2] | strstr [2] | |
bcmp [2] | stpncpy [1] | strlen [2] | strtof [2] | |
bcopy [2] | strcasecmp [2] | strncasecmp [2] | strtoimax [2] |
Referenced Specification(s)
[1]. this specification
[2]. ISO POSIX (2003)
An LSB conforming implementation shall provide the generic functions for IPC Functions specified in Table 1-13, with the full mandatory functionality as described in the referenced underlying specification.
Table 1-13. libc - IPC Functions Function Interfaces
ftok [1] | msgrcv [1] | semget [1] | shmctl [1] | |
msgctl [1] | msgsnd [1] | semop [1] | shmdt [1] | |
msgget [1] | semctl [1] | shmat [1] | shmget [1] |
Referenced Specification(s)
[1]. ISO POSIX (2003)
An LSB conforming implementation shall provide the generic functions for Regular Expressions specified in Table 1-14, with the full mandatory functionality as described in the referenced underlying specification.
Table 1-14. libc - Regular Expressions Function Interfaces
regcomp [1] | regerror [1] | regexec [2] | regfree [1] |
Referenced Specification(s)
[1]. ISO POSIX (2003)
[2]. this specification
An LSB conforming implementation shall provide the generic functions for Character Type Functions specified in Table 1-15, with the full mandatory functionality as described in the referenced underlying specification.
Table 1-15. libc - Character Type Functions Function Interfaces
__ctype_b_loc(GLIBC_2.3) [1] | isalpha [2] | ispunct [2] | iswctype [2] | iswupper [2] |
__ctype_get_mb_cur_max [1] | isascii [2] | isspace [2] | iswdigit [2] | iswxdigit [2] |
__ctype_tolower_loc(GLIBC_2.3) [1] | iscntrl [2] | isupper [2] | iswgraph [2] | isxdigit [2] |
__ctype_toupper_loc(GLIBC_2.3) [1] | isdigit [2] | iswalnum [2] | iswlower [2] | toascii [2] |
_tolower [2] | isgraph [2] | iswalpha [2] | iswprint [2] | tolower [2] |
_toupper [2] | islower [2] | iswblank [2] | iswpunct [2] | toupper [2] |
isalnum [2] | isprint [2] | iswcntrl [2] | iswspace [2] |
Referenced Specification(s)
[1]. this specification
[2]. ISO POSIX (2003)
An LSB conforming implementation shall provide the generic functions for Time Manipulation specified in Table 1-16, with the full mandatory functionality as described in the referenced underlying specification.
Table 1-16. libc - Time Manipulation Function Interfaces
adjtime [1] | ctime [2] | gmtime [2] | localtime_r [2] | ualarm [2] |
asctime [2] | ctime_r [2] | gmtime_r [2] | mktime [2] | |
asctime_r [2] | difftime [2] | localtime [2] | tzset [2] |
Referenced Specification(s)
[1]. this specification
[2]. ISO POSIX (2003)
An LSB conforming implementation shall provide the generic data interfaces for Time Manipulation specified in Table 1-17, with the full mandatory functionality as described in the referenced underlying specification.
Table 1-17. libc - Time Manipulation Data Interfaces
__daylight [1] | __tzname [1] | timezone [2] | ||
__timezone [1] | daylight [2] | tzname [2] |
Referenced Specification(s)
[1]. this specification
[2]. ISO POSIX (2003)
An LSB conforming implementation shall provide the generic functions for Terminal Interface Functions specified in Table 1-18, with the full mandatory functionality as described in the referenced underlying specification.
Table 1-18. libc - Terminal Interface Functions Function Interfaces
cfgetispeed [1] | cfsetispeed [1] | tcdrain [1] | tcgetattr [1] | tcsendbreak [1] |
cfgetospeed [1] | cfsetospeed [1] | tcflow [1] | tcgetpgrp [1] | tcsetattr [1] |
cfmakeraw [2] | cfsetspeed [2] | tcflush [1] | tcgetsid [1] | tcsetpgrp [1] |
Referenced Specification(s)
[1]. ISO POSIX (2003)
[2]. this specification
An LSB conforming implementation shall provide the generic functions for System Database Interface specified in Table 1-19, with the full mandatory functionality as described in the referenced underlying specification.
Table 1-19. libc - System Database Interface Function Interfaces
endgrent [1] | getgrgid_r [1] | getprotoent [1] | getservent [1] | setgroups [2] |
endprotoent [1] | getgrnam [1] | getpwent [1] | getutent [2] | setprotoent [1] |
endpwent [1] | getgrnam_r [1] | getpwnam [1] | getutent_r [2] | setpwent [1] |
endservent [1] | getgrouplist [2] | getpwnam_r [1] | getutxent [1] | setservent [1] |
endutent [3] | gethostbyaddr [1] | getpwuid [1] | getutxid [1] | setutent [2] |
endutxent [1] | gethostbyname [1] | getpwuid_r [1] | getutxline [1] | setutxent [1] |
getgrent [1] | getprotobyname [1] | getservbyname [1] | pututxline [1] | utmpname [2] |
getgrgid [1] | getprotobynumber [1] | getservbyport [1] | setgrent [1] |
Referenced Specification(s)
[1]. ISO POSIX (2003)
[2]. this specification
[3]. SUSv2
An LSB conforming implementation shall provide the generic functions for Language Support specified in Table 1-20, with the full mandatory functionality as described in the referenced underlying specification.
Table 1-20. libc - Language Support Function Interfaces
__libc_start_main [1] | __register_atfork(GLIBC_2.3.2) [1] |
Referenced Specification(s)
[1]. this specification
An LSB conforming implementation shall provide the generic functions for Large File Support specified in Table 1-21, with the full mandatory functionality as described in the referenced underlying specification.
Table 1-21. libc - Large File Support Function Interfaces
__fxstat64 [1] | fopen64 [2] | ftello64 [2] | lseek64 [2] | readdir64 [2] |
__lxstat64 [1] | freopen64 [2] | ftruncate64 [2] | mkstemp64 [2] | statvfs64 [2] |
__xstat64 [1] | fseeko64 [2] | ftw64 [2] | mmap64 [2] | tmpfile64 [2] |
creat64 [2] | fsetpos64 [2] | getrlimit64 [2] | nftw64 [2] | truncate64 [2] |
fgetpos64 [2] | fstatvfs64 [2] | lockf64 [2] | open64 [2] |
Referenced Specification(s)
[1]. this specification
[2]. Large File Support
An LSB conforming implementation shall provide the generic functions for Standard Library specified in Table 1-22, with the full mandatory functionality as described in the referenced underlying specification.
Table 1-22. libc - Standard Library Function Interfaces
_Exit [1] | dirname [1] | glob [1] | lsearch [1] | srand48 [1] |
__assert_fail [2] | div [1] | glob64 [2] | makecontext [1] | srandom [1] |
__cxa_atexit [2] | drand48 [1] | globfree [1] | malloc [1] | strtod [1] |
__errno_location [2] | ecvt [1] | globfree64 [2] | memmem [2] | strtol [1] |
__fpending [2] | erand48 [1] | grantpt [1] | mkstemp [1] | strtoul [1] |
__getpagesize [2] | err [2] | hcreate [1] | mktemp [1] | swapcontext [1] |
__isinf [2] | error [2] | hdestroy [1] | mrand48 [1] | syslog [1] |
__isinff [2] | errx [2] | hsearch [1] | nftw [1] | system [2] |
__isinfl [2] | fcvt [1] | htonl [1] | nrand48 [1] | tdelete [1] |
__isnan [2] | fmtmsg [1] | htons [1] | ntohl [1] | tfind [1] |
__isnanf [2] | fnmatch [1] | imaxabs [1] | ntohs [1] | tmpfile [1] |
__isnanl [2] | fpathconf [1] | imaxdiv [1] | openlog [1] | tmpnam [1] |
__sysconf [2] | free [1] | inet_addr [1] | perror [1] | tsearch [1] |
_exit [1] | freeaddrinfo [1] | inet_ntoa [1] | posix_memalign [1] | ttyname [1] |
_longjmp [1] | ftrylockfile [1] | inet_ntop [1] | posix_openpt [1] | ttyname_r [1] |
_setjmp [1] | ftw [1] | inet_pton [1] | ptsname [1] | twalk [1] |
a64l [1] | funlockfile [1] | initstate [1] | putenv [1] | unlockpt [1] |
abort [1] | gai_strerror [1] | insque [1] | qsort [1] | unsetenv [1] |
abs [1] | gcvt [1] | isatty [1] | rand [1] | usleep [1] |
atof [1] | getaddrinfo [1] | isblank [1] | rand_r [1] | verrx [2] |
atoi [1] | getcwd [1] | jrand48 [1] | random [1] | vfscanf [2] |
atol [1] | getdate [1] | l64a [1] | realloc [1] | vscanf [2] |
atoll [1] | getenv [1] | labs [1] | realpath [1] | vsscanf [2] |
basename [1] | getlogin [1] | lcong48 [1] | remque [1] | vsyslog [2] |
bsearch [1] | getnameinfo [1] | ldiv [1] | seed48 [1] | warn [2] |
calloc [1] | getopt [2] | lfind [1] | setenv [1] | warnx [2] |
closelog [1] | getopt_long [2] | llabs [1] | sethostname [2] | wordexp [1] |
confstr [1] | getopt_long_only [2] | lldiv [1] | setlogmask [1] | wordfree [1] |
cuserid [3] | getsubopt [1] | longjmp [1] | setstate [1] | |
daemon [2] | gettimeofday [1] | lrand48 [1] | srand [1] |
Referenced Specification(s)
[1]. ISO POSIX (2003)
[2]. this specification
[3]. SUSv2
An LSB conforming implementation shall provide the generic data interfaces for Standard Library specified in Table 1-23, with the full mandatory functionality as described in the referenced underlying specification.
Table 1-23. libc - Standard Library Data Interfaces
__environ [1] | _sys_errlist [1] | getdate_err [2] | opterr [2] | optopt [2] |
_environ [1] | environ [2] | optarg [2] | optind [2] |
Referenced Specification(s)
[1]. this specification
[2]. ISO POSIX (2003)
This section defines global identifiers and their values that are associated with interfaces contained in libc. These definitions are organized into groups that correspond to system headers. This convention is used as a convenience for the reader, and does not imply the existence of these headers, or their content.
These definitions are intended to supplement those provided in the referenced underlying specifications.
This specification uses ISO/IEC 9899 C Language as the reference programming language, and data definitions are specified in ISO C format. The C language is used here as a convenient notation. Using a C language description of these data objects does not preclude their use by other programming languages.
enum { _ISupper, _ISlower, _ISalpha, _ISdigit, _ISxdigit, _ISspace, _ISprint, _ISgraph, _ISblank, _IScntrl, _ISpunct, _ISalnum } ; |
typedef struct __dirstream DIR; struct dirent { long int d_ino; off_t d_off; unsigned short d_reclen; unsigned char d_type; char d_name[256]; } ; struct dirent64 { uint64_t d_ino; int64_t d_off; unsigned short d_reclen; unsigned char d_type; char d_name[256]; } ; |
ISO POSIX (2003) requires that each error value shall be unique, with permission for EAGAIN and EWOULDBLOCK possibly having the same value. This specification also requires that ENOTSUP and EOPNOTSUPP have the same value.
Note: A defect report against ISO POSIX (2003) has been filed to request that specification also permit these two symbols to have the same value.
#define errno (*__errno_location()) #define EPERM 1 #define ECHILD 10 #define ENETDOWN 100 #define ENETUNREACH 101 #define ENETRESET 102 #define ECONNABORTED 103 #define ECONNRESET 104 #define ENOBUFS 105 #define EISCONN 106 #define ENOTCONN 107 #define ESHUTDOWN 108 #define ETOOMANYREFS 109 #define EAGAIN 11 #define ETIMEDOUT 110 #define ECONNREFUSED 111 #define EHOSTDOWN 112 #define EHOSTUNREACH 113 #define EALREADY 114 #define EINPROGRESS 115 #define ESTALE 116 #define EUCLEAN 117 #define ENOTNAM 118 #define ENAVAIL 119 #define ENOMEM 12 #define EISNAM 120 #define EREMOTEIO 121 #define EDQUOT 122 #define ENOMEDIUM 123 #define EMEDIUMTYPE 124 #define ECANCELED 125 #define EACCES 13 #define EFAULT 14 #define ENOTBLK 15 #define EBUSY 16 #define EEXIST 17 #define EXDEV 18 #define ENODEV 19 #define ENOENT 2 #define ENOTDIR 20 #define EISDIR 21 #define EINVAL 22 #define ENFILE 23 #define EMFILE 24 #define ENOTTY 25 #define ETXTBSY 26 #define EFBIG 27 #define ENOSPC 28 #define ESPIPE 29 #define ESRCH 3 #define EROFS 30 #define EMLINK 31 #define EPIPE 32 #define EDOM 33 #define ERANGE 34 #define EDEADLK 35 #define ENAMETOOLONG 36 #define ENOLCK 37 #define ENOSYS 38 #define ENOTEMPTY 39 #define EINTR 4 #define ELOOP 40 #define ENOMSG 42 #define EIDRM 43 #define ECHRNG 44 #define EL2NSYNC 45 #define EL3HLT 46 #define EL3RST 47 #define ELNRNG 48 #define EUNATCH 49 #define EIO 5 #define ENOANO 55 #define EBADRQC 56 #define EBADSLT 57 #define EBFONT 59 #define ENXIO 6 #define ENOSTR 60 #define ENODATA 61 #define ETIME 62 #define ENOSR 63 #define ENONET 64 #define ENOPKG 65 #define EREMOTE 66 #define ENOLINK 67 #define EADV 68 #define ESRMNT 69 #define E2BIG 7 #define ECOMM 70 #define EPROTO 71 #define EMULTIHOP 72 #define EDOTDOT 73 #define EBADMSG 74 #define EOVERFLOW 75 #define ENOTUNIQ 76 #define EBADFD 77 #define EREMCHG 78 #define ELIBACC 79 #define ENOEXEC 8 #define ELIBBAD 80 #define ELIBSCN 81 #define ELIBMAX 82 #define ELIBEXEC 83 #define EILSEQ 84 #define ERESTART 85 #define ESTRPIPE 86 #define EUSERS 87 #define ENOTSOCK 88 #define EDESTADDRREQ 89 #define EBADF 9 #define EMSGSIZE 90 #define EPROTOTYPE 91 #define ENOPROTOOPT 92 #define EPROTONOSUPPORT 93 #define ESOCKTNOSUPPORT 94 #define EOPNOTSUPP 95 #define EPFNOSUPPORT 96 #define EAFNOSUPPORT 97 #define EADDRINUSE 98 #define EADDRNOTAVAIL 99 #define EWOULDBLOCK EAGAIN #define ENOTSUP EOPNOTSUPP |
#define O_RDONLY 00 #define O_ACCMODE 0003 #define O_WRONLY 01 #define O_CREAT 0100 #define O_TRUNC 01000 #define O_SYNC 010000 #define O_RDWR 02 #define O_EXCL 0200 #define O_APPEND 02000 #define O_ASYNC 020000 #define O_NOCTTY 0400 #define O_NDELAY 04000 #define O_NONBLOCK 04000 #define FD_CLOEXEC 1 struct flock { short l_type; short l_whence; off_t l_start; off_t l_len; pid_t l_pid; } ; struct flock64 { short l_type; short l_whence; loff_t l_start; loff_t l_len; pid_t l_pid; } ; #define F_DUPFD 0 #define F_RDLCK 0 #define F_GETFD 1 #define F_WRLCK 1 #define F_SETFD 2 #define F_UNLCK 2 #define F_GETFL 3 #define F_SETFL 4 #define F_GETLK 5 #define F_SETLK 6 #define F_SETLKW 7 #define F_SETOWN 8 #define F_GETOWN 9 |
#define MM_HARD 1 #define MM_NRECOV 128 #define MM_UTIL 16 #define MM_SOFT 2 #define MM_OPSYS 32 #define MM_FIRM 4 #define MM_RECOVER 64 #define MM_APPL 8 #define MM_NOSEV 0 #define MM_HALT 1 #define MM_ERROR 2 #define MM_NULLLBL ((char *) 0) |
#define FNM_PATHNAME (1<<0) #define FNM_NOESCAPE (1<<1) #define FNM_PERIOD (1<<2) #define FNM_NOMATCH 1 |
#define FTW_D FTW_D #define FTW_DNR FTW_DNR #define FTW_DP FTW_DP #define FTW_F FTW_F #define FTW_NS FTW_NS #define FTW_SL FTW_SL #define FTW_SLN FTW_SLN enum { FTW_F, FTW_D, FTW_DNR, FTW_NS, FTW_SL, FTW_DP, FTW_SLN } ; enum { FTW_PHYS, FTW_MOUNT, FTW_CHDIR, FTW_DEPTH } ; struct FTW { int base; int level; } ; typedef int (*__ftw_func_t) (char *__filename, struct stat * __status, int __flag); typedef int (*__ftw64_func_t) (char *__filename, struct stat64 * __status, int __flag); typedef int (*__nftw_func_t) (char *__filename, struct stat * __status, int __flag, struct FTW * __info); typedef int (*__nftw64_func_t) (char *__filename, struct stat64 * __status, int __flag, struct FTW * __info); |
#define no_argument 0 #define required_argument 1 #define optional_argument 2 struct option { char *name; int has_arg; int *flag; int val; } ; |
#define GLOB_ERR (1<<0) #define GLOB_MARK (1<<1) #define GLOB_BRACE (1<<10) #define GLOB_NOMAGIC (1<<11) #define GLOB_TILDE (1<<12) #define GLOB_ONLYDIR (1<<13) #define GLOB_TILDE_CHECK (1<<14) #define GLOB_NOSORT (1<<2) #define GLOB_DOOFFS (1<<3) #define GLOB_NOCHECK (1<<4) #define GLOB_APPEND (1<<5) #define GLOB_NOESCAPE (1<<6) #define GLOB_PERIOD (1<<7) #define GLOB_MAGCHAR (1<<8) #define GLOB_ALTDIRFUNC (1<<9) #define GLOB_NOSPACE 1 #define GLOB_ABORTED 2 #define GLOB_NOMATCH 3 #define GLOB_NOSYS 4 typedef struct { size_t gl_pathc; char **gl_pathv; size_t gl_offs; int gl_flags; void (*gl_closedir) (void *); struct dirent *(*gl_readdir) (void *); void *(*gl_opendir) (const char *); int (*gl_lstat) (const char *, struct stat *); int (*gl_stat) (const char *, struct stat *); } glob_t; typedef struct { size_t gl_pathc; char **gl_pathv; size_t gl_offs; int gl_flags; void (*gl_closedir) (void *); struct dirent64 *(*gl_readdir64) (void *); void *(*gl_opendir) (const char *); int (*gl_lstat) (const char *, struct stat *); int (*gl_stat) (const char *, struct stat *); } glob64_t; |
typedef lldiv_t imaxdiv_t; typedef unsigned char uint8_t; typedef unsigned short uint16_t; typedef unsigned int uint32_t; |
#define ABDAY_1 0x20000 #define ABDAY_2 0x20001 #define ABDAY_3 0x20002 #define ABDAY_4 0x20003 #define ABDAY_5 0x20004 #define ABDAY_6 0x20005 #define ABDAY_7 0x20006 #define DAY_1 0x20007 #define DAY_2 0x20008 #define DAY_3 0x20009 #define DAY_4 0x2000A #define DAY_5 0x2000B #define DAY_6 0x2000C #define DAY_7 0x2000D #define ABMON_1 0x2000E #define ABMON_2 0x2000F #define ABMON_3 0x20010 #define ABMON_4 0x20011 #define ABMON_5 0x20012 #define ABMON_6 0x20013 #define ABMON_7 0x20014 #define ABMON_8 0x20015 #define ABMON_9 0x20016 #define ABMON_10 0x20017 #define ABMON_11 0x20018 #define ABMON_12 0x20019 #define MON_1 0x2001A #define MON_2 0x2001B #define MON_3 0x2001C #define MON_4 0x2001D #define MON_5 0x2001E #define MON_6 0x2001F #define MON_7 0x20020 #define MON_8 0x20021 #define MON_9 0x20022 #define MON_10 0x20023 #define MON_11 0x20024 #define MON_12 0x20025 #define AM_STR 0x20026 #define PM_STR 0x20027 #define D_T_FMT 0x20028 #define D_FMT 0x20029 #define T_FMT 0x2002A #define T_FMT_AMPM 0x2002B #define ERA 0x2002C #define ERA_D_FMT 0x2002E #define ALT_DIGITS 0x2002F #define ERA_D_T_FMT 0x20030 #define ERA_T_FMT 0x20031 #define CODESET 14 #define CRNCYSTR 0x4000F #define RADIXCHAR 0x10000 #define THOUSEP 0x10001 #define YESEXPR 0x50000 #define NOEXPR 0x50001 #define YESSTR 0x50002 #define NOSTR 0x50003 |
#define LLONG_MIN (-LLONG_MAX-1LL) #define ULLONG_MAX 18446744073709551615ULL #define OPEN_MAX 256 #define PATH_MAX 4096 #define LLONG_MAX 9223372036854775807LL #define SSIZE_MAX LONG_MAX #define MB_LEN_MAX 16 #define SCHAR_MIN (-128) #define SCHAR_MAX 127 #define UCHAR_MAX 255 #define CHAR_BIT 8 #define SHRT_MIN (-32768) #define SHRT_MAX 32767 #define USHRT_MAX 65535 #define INT_MIN (-INT_MAX-1) #define INT_MAX 2147483647 #define __INT_MAX__ 2147483647 #define UINT_MAX 4294967295U #define LONG_MIN (-LONG_MAX-1L) #define PTHREAD_KEYS_MAX 1024 #define PTHREAD_STACK_MIN 16384 #define PTHREAD_THREADS_MAX 16384 #define PTHREAD_DESTRUCTOR_ITERATIONS 4 |
struct lconv { char *decimal_point; char *thousands_sep; char *grouping; char *int_curr_symbol; char *currency_symbol; char *mon_decimal_point; char *mon_thousands_sep; char *mon_grouping; char *positive_sign; char *negative_sign; char int_frac_digits; char frac_digits; char p_cs_precedes; char p_sep_by_space; char n_cs_precedes; char n_sep_by_space; char p_sign_posn; char n_sign_posn; char int_p_cs_precedes; char int_p_sep_by_space; char int_n_cs_precedes; char int_n_sep_by_space; char int_p_sign_posn; char int_n_sign_posn; } ; #define LC_GLOBAL_LOCALE ((locale_t) -1L) #define LC_CTYPE 0 #define LC_NUMERIC 1 #define LC_TELEPHONE 10 #define LC_MEASUREMENT 11 #define LC_IDENTIFICATION 12 #define LC_TIME 2 #define LC_COLLATE 3 #define LC_MONETARY 4 #define LC_MESSAGES 5 #define LC_ALL 6 #define LC_PAPER 7 #define LC_NAME 8 #define LC_ADDRESS 9 typedef struct __locale_struct { struct locale_data *__locales[13]; const unsigned short *__ctype_b; const int *__ctype_tolower; const int *__ctype_toupper; const char *__names[13]; } *__locale_t; typedef struct __locale_struct *locale_t; #define LC_ADDRESS_MASK (1 << LC_ADDRESS) #define LC_COLLATE_MASK (1 << LC_COLLATE) #define LC_IDENTIFICATION_MASK (1 << LC_IDENTIFICATION) #define LC_MEASUREMENT_MASK (1 << LC_MEASUREMENT) #define LC_MESSAGES_MASK (1 << LC_MESSAGES) #define LC_MONETARY_MASK (1 << LC_MONETARY) #define LC_NAME_MASK (1 << LC_NAME) #define LC_NUMERIC_MASK (1 << LC_NUMERIC) #define LC_PAPER_MASK (1 << LC_PAPER) #define LC_TELEPHONE_MASK (1 << LC_TELEPHONE) #define LC_TIME_MASK (1 << LC_TIME) #define LC_CTYPE_MASK (1<<LC_CTYPE) #define LC_ALL_MASK (LC_CTYPE_MASK| LC_NUMERIC_MASK| LC_TIME_MASK| LC_COLLATE_MASK| LC_MONETARY_MASK| LC_MESSAGES_MASK| LC_PAPER_MASK| LC_NAME_MASK| LC_ADDRESS_MASK| LC_TELEPHONE_MASK| LC_MEASUREMENT_MASK| LC_IDENTIFICATION_MASK) |
#define IF_NAMESIZE 16 #define IFF_UP 0x01 #define IFF_BROADCAST 0x02 #define IFF_DEBUG 0x04 #define IFF_LOOPBACK 0x08 #define IFF_POINTOPOINT 0x10 #define IFF_PROMISC 0x100 #define IFF_MULTICAST 0x1000 #define IFF_NOTRAILERS 0x20 #define IFF_RUNNING 0x40 #define IFF_NOARP 0x80 struct if_nameindex { unsigned int if_index; char *if_name; } ; struct ifaddr { struct sockaddr ifa_addr; union { struct sockaddr ifu_broadaddr; struct sockaddr ifu_dstaddr; } ifa_ifu; void *ifa_ifp; void *ifa_next; } ; #define IFNAMSIZ IF_NAMESIZE struct ifreq { union { char ifrn_name[IFNAMSIZ]; } ifr_ifrn; union { struct sockaddr ifru_addr; struct sockaddr ifru_dstaddr; struct sockaddr ifru_broadaddr; struct sockaddr ifru_netmask; struct sockaddr ifru_hwaddr; short ifru_flags; int ifru_ivalue; int ifru_mtu; char ifru_slave[IFNAMSIZ]; char ifru_newname[IFNAMSIZ]; caddr_t ifru_data; struct ifmap ifru_map; } ifr_ifru; } ; struct ifconf { int ifc_len; union { caddr_t ifcu_buf; struct ifreq *ifcu_req; } ifc_ifcu; } ; |
#define NETDB_INTERNAL -1 #define NETDB_SUCCESS 0 #define HOST_NOT_FOUND 1 #define IPPORT_RESERVED 1024 #define NI_MAXHOST 1025 #define TRY_AGAIN 2 #define NO_RECOVERY 3 #define NI_MAXSERV 32 #define NO_DATA 4 #define h_addr h_addr_list[0] #define NO_ADDRESS NO_DATA struct servent { char *s_name; char **s_aliases; int s_port; char *s_proto; } ; struct hostent { char *h_name; char **h_aliases; int h_addrtype; int h_length; char **h_addr_list; } ; struct protoent { char *p_name; char **p_aliases; int p_proto; } ; struct netent { char *n_name; char **n_aliases; int n_addrtype; unsigned int n_net; } ; #define AI_PASSIVE 0x0001 #define AI_CANONNAME 0x0002 #define AI_NUMERICHOST 0x0004 struct addrinfo { int ai_flags; int ai_family; int ai_socktype; int ai_protocol; socklen_t ai_addrlen; struct sockaddr *ai_addr; char *ai_canonname; struct addrinfo *ai_next; } ; #define NI_NUMERICHOST 1 #define NI_DGRAM 16 #define NI_NUMERICSERV 2 #define NI_NOFQDN 4 #define NI_NAMEREQD 8 #define EAI_BADFLAGS -1 #define EAI_MEMORY -10 #define EAI_SYSTEM -11 #define EAI_NONAME -2 #define EAI_AGAIN -3 #define EAI_FAIL -4 #define EAI_NODATA -5 #define EAI_FAMILY -6 #define EAI_SOCKTYPE -7 #define EAI_SERVICE -8 #define EAI_ADDRFAMILY -9 |
#define IPPROTO_IP 0 #define IPPROTO_ICMP 1 #define IPPROTO_UDP 17 #define IPPROTO_IGMP 2 #define IPPROTO_RAW 255 #define IPPROTO_IPV6 41 #define IPPROTO_ICMPV6 58 #define IPPROTO_TCP 6 typedef uint16_t in_port_t; struct in_addr { uint32_t s_addr; } ; typedef uint32_t in_addr_t; #define INADDR_NONE ((in_addr_t) 0xffffffff) #define INADDR_BROADCAST (0xffffffff) #define INADDR_ANY 0 struct in6_addr { union { uint8_t u6_addr8[16]; uint16_t u6_addr16[8]; uint32_t u6_addr32[4]; } in6_u; } ; #define IN6ADDR_ANY_INIT { { { 0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,0 } } } #define IN6ADDR_LOOPBACK_INIT { { { 0,0,0,0,0,0,0,0,0,0,0,0,0,0,0,1 } } } #define INET_ADDRSTRLEN 16 struct sockaddr_in { sa_family_t sin_family; unsigned short sin_port; struct in_addr sin_addr; unsigned char sin_zero[8]; } ; #define INET6_ADDRSTRLEN 46 struct sockaddr_in6 { unsigned short sin6_family; uint16_t sin6_port; uint32_t sin6_flowinfo; struct in6_addr sin6_addr; uint32_t sin6_scope_id; } ; #define SOL_IP 0 #define IP_TOS 1 #define IPV6_UNICAST_HOPS 16 #define IPV6_MULTICAST_IF 17 #define IPV6_MULTICAST_HOPS 18 #define IPV6_MULTICAST_LOOP 19 #define IP_TTL 2 #define IPV6_JOIN_GROUP 20 #define IPV6_LEAVE_GROUP 21 #define IPV6_V6ONLY 26 #define IP_MULTICAST_IF 32 #define IP_MULTICAST_TTL 33 #define IP_MULTICAST_LOOP 34 #define IP_ADD_MEMBERSHIP 35 #define IP_DROP_MEMBERSHIP 36 #define IP_OPTIONS 4 struct ipv6_mreq { struct in6_addr ipv6mr_multiaddr; int ipv6mr_interface; } ; struct ip_mreq { struct in_addr imr_multiaddr; struct in_addr imr_interface; } ; |
#define IPTOS_LOWCOST 0x02 #define IPTOS_RELIABILITY 0x04 #define IPTOS_THROUGHPUT 0x08 #define IPTOS_LOWDELAY 0x10 #define IPTOS_TOS_MASK 0x1e #define IPTOS_MINCOST IPTOS_LOWCOST #define IPTOS_PREC_MASK 0xe0 |
#define NL_CAT_LOCALE 1 #define NL_SETD 1 typedef void *nl_catd; typedef int nl_item; |
struct winsize { unsigned short ws_row; unsigned short ws_col; unsigned short ws_xpixel; unsigned short ws_ypixel; } ; |
struct passwd { char *pw_name; char *pw_passwd; uid_t pw_uid; gid_t pw_gid; char *pw_gecos; char *pw_dir; char *pw_shell; } ; |
typedef unsigned long int reg_syntax_t; typedef struct re_pattern_buffer { unsigned char *buffer; unsigned long int allocated; unsigned long int used; reg_syntax_t syntax; char *fastmap; char *translate; size_t re_nsub; unsigned int can_be_null:1; unsigned int regs_allocated:2; unsigned int fastmap_accurate:1; unsigned int no_sub:1; unsigned int not_bol:1; unsigned int not_eol:1; unsigned int newline_anchor:1; } regex_t; typedef int regoff_t; typedef struct { regoff_t rm_so; regoff_t rm_eo; } regmatch_t; #define REG_ICASE (REG_EXTENDED<<1) #define REG_NEWLINE (REG_ICASE<<1) #define REG_NOSUB (REG_NEWLINE<<1) #define REG_EXTENDED 1 #define REG_NOTEOL (1<<1) #define REG_NOTBOL 1 typedef enum { REG_ENOSYS, REG_NOERROR, REG_NOMATCH, REG_BADPAT, REG_ECOLLATE, REG_ECTYPE, REG_EESCAPE, REG_ESUBREG, REG_EBRACK, REG_EPAREN, REG_EBRACE, REG_BADBR, REG_ERANGE, REG_ESPACE, REG_BADRPT, REG_EEND, REG_ESIZE, REG_ERPAREN } reg_errcode_t; |
enum auth_stat { AUTH_OK, AUTH_BADCRED = 1, AUTH_REJECTEDCRED = 2, AUTH_BADVERF = 3, AUTH_REJECTEDVERF = 4, AUTH_TOOWEAK = 5, AUTH_INVALIDRESP = 6, AUTH_FAILED = 7 } ; union des_block { struct { u_int32_t high; u_int32_t low; } key; char c[8]; } ; struct opaque_auth { enum_t oa_flavor; caddr_t oa_base; u_int oa_length; } ; typedef struct AUTH { struct opaque_auth ah_cred; struct opaque_auth ah_verf; union des_block ah_key; struct auth_ops *ah_ops; caddr_t ah_private; } AUTH; struct auth_ops { void (*ah_nextverf) (struct AUTH *); int (*ah_marshal) (struct AUTH *, XDR *); int (*ah_validate) (struct AUTH *, struct opaque_auth *); int (*ah_refresh) (struct AUTH *); void (*ah_destroy) (struct AUTH *); } ; |
#define clnt_control(cl,rq,in) ((*(cl)->cl_ops->cl_control)(cl,rq,in)) #define clnt_abort(rh) ((*(rh)->cl_ops->cl_abort)(rh)) #define clnt_call(rh, proc, xargs, argsp, xres, resp, secs) ((*(rh)->cl_ops->cl_call)(rh, proc, xargs, argsp, xres, resp, secs)) #define clnt_destroy(rh) ((*(rh)->cl_ops->cl_destroy)(rh)) #define clnt_freeres(rh,xres,resp) ((*(rh)->cl_ops->cl_freeres)(rh,xres,resp)) #define clnt_geterr(rh,errp) ((*(rh)->cl_ops->cl_geterr)(rh, errp)) #define NULLPROC ((u_long)0) #define CLSET_TIMEOUT 1 #define CLGET_XID 10 #define CLSET_XID 11 #define CLGET_VERS 12 #define CLSET_VERS 13 #define CLGET_PROG 14 #define CLSET_PROG 15 #define CLGET_TIMEOUT 2 #define CLGET_SERVER_ADDR 3 #define CLSET_RETRY_TIMEOUT 4 #define CLGET_RETRY_TIMEOUT 5 #define CLGET_FD 6 #define CLGET_SVC_ADDR 7 #define CLSET_FD_CLOSE 8 #define CLSET_FD_NCLOSE 9 enum clnt_stat { RPC_SUCCESS, RPC_CANTENCODEARGS = 1, RPC_CANTDECODERES = 2, RPC_CANTSEND = 3, RPC_CANTRECV = 4, RPC_TIMEDOUT = 5, RPC_VERSMISMATCH = 6, RPC_AUTHERROR = 7, RPC_PROGUNAVAIL = 8, RPC_PROGVERSMISMATCH = 9, RPC_PROCUNAVAIL = 10, RPC_CANTDECODEARGS = 11, RPC_SYSTEMERROR = 12, RPC_NOBROADCAST = 21, RPC_UNKNOWNHOST = 13, RPC_UNKNOWNPROTO = 17, RPC_UNKNOWNADDR = 19, RPC_RPCBFAILURE = 14, RPC_PROGNOTREGISTERED = 15, RPC_N2AXLATEFAILURE = 22, RPC_FAILED = 16, RPC_INTR = 18, RPC_TLIERROR = 20, RPC_UDERROR = 23, RPC_INPROGRESS = 24, RPC_STALERACHANDLE = 25 } ; struct rpc_err { enum clnt_stat re_status; union { int RE_errno; enum auth_stat RE_why; struct { u_long low; u_long high; } RE_vers; struct { long int s1; long int s2; } RE_lb; } ru; } ; typedef struct CLIENT { struct AUTH *cl_auth; struct clnt_ops *cl_ops; caddr_t cl_private; } CLIENT; struct clnt_ops { enum clnt_stat (*cl_call) (struct CLIENT *, u_long, xdrproc_t, caddr_t, xdrproc_t, caddr_t, struct timeval); void (*cl_abort) (void); void (*cl_geterr) (struct CLIENT *, struct rpc_err *); bool_t (*cl_freeres) (struct CLIENT *, xdrproc_t, caddr_t); void (*cl_destroy) (struct CLIENT *); bool_t (*cl_control) (struct CLIENT *, int, char *); } ; |
enum msg_type { CALL, REPLY = 1 } ; enum reply_stat { MSG_ACCEPTED, MSG_DENIED = 1 } ; enum accept_stat { SUCCESS, PROG_UNAVAIL = 1, PROG_MISMATCH = 2, PROC_UNAVAIL = 3, GARBAGE_ARGS = 4, SYSTEM_ERR = 5 } ; enum reject_stat { RPC_MISMATCH, AUTH_ERROR = 1 } ; struct accepted_reply { struct opaque_auth ar_verf; enum accept_stat ar_stat; union { struct { unsigned long int low; unsigned long int high; } AR_versions; struct { caddr_t where; xdrproc_t proc; } AR_results; } ru; } ; struct rejected_reply { enum reject_stat rj_stat; union { struct { unsigned long int low; unsigned long int high; } RJ_versions; enum auth_stat RJ_why; } ru; } ; struct reply_body { enum reply_stat rp_stat; union { struct accepted_reply RP_ar; struct rejected_reply RP_dr; } ru; } ; struct call_body { unsigned long int cb_rpcvers; unsigned long int cb_prog; unsigned long int cb_vers; unsigned long int cb_proc; struct opaque_auth cb_cred; struct opaque_auth cb_verf; } ; struct rpc_msg { unsigned long int rm_xid; enum msg_type rm_direction; union { struct call_body RM_cmb; struct reply_body RM_rmb; } ru; } ; |
#define svc_freeargs(xprt,xargs, argsp) (*(xprt)->xp_ops->xp_freeargs)((xprt), (xargs), (argsp)) #define svc_getargs(xprt,xargs, argsp) (*(xprt)->xp_ops->xp_getargs)((xprt), (xargs), (argsp)) #define RPC_ANYSOCK -1 typedef struct SVCXPRT { int xp_sock; u_short xp_port; struct xp_ops *xp_ops; int xp_addrlen; struct sockaddr_in xp_raddr; struct opaque_auth xp_verf; caddr_t xp_p1; caddr_t xp_p2; char xp_pad[256]; } SVCXPRT; struct svc_req { rpcprog_t rq_prog; rpcvers_t rq_vers; rpcproc_t rq_proc; struct opaque_auth rq_cred; caddr_t rq_clntcred; SVCXPRT *rq_xprt; } ; typedef void (*__dispatch_fn_t) (struct svc_req *, SVCXPRT *); struct xp_ops { bool_t (*xp_recv) (SVCXPRT * __xprt, struct rpc_msg * __msg); enum xprt_stat (*xp_stat) (SVCXPRT * __xprt); bool_t (*xp_getargs) (SVCXPRT * __xprt, xdrproc_t __xdr_args, caddr_t args_ptr); bool_t (*xp_reply) (SVCXPRT * __xprt, struct rpc_msg * __msg); bool_t (*xp_freeargs) (SVCXPRT * __xprt, xdrproc_t __xdr_args, caddr_t args_ptr); void (*xp_destroy) (SVCXPRT * __xprt); } ; |
typedef int bool_t; typedef int enum_t; typedef unsigned long int rpcprog_t; typedef unsigned long int rpcvers_t; typedef unsigned long int rpcproc_t; typedef unsigned long int rpcprot_t; |
enum xdr_op { XDR_ENCODE, XDR_DECODE, XDR_FREE } ; typedef struct XDR { enum xdr_op x_op; struct xdr_ops *x_ops; caddr_t x_public; caddr_t x_private; caddr_t x_base; int x_handy; } XDR; struct xdr_ops { bool_t (*x_getlong) (XDR * __xdrs, long int *__lp); bool_t (*x_putlong) (XDR * __xdrs, long int *__lp); bool_t (*x_getbytes) (XDR * __xdrs, caddr_t __addr, u_int __len); bool_t (*x_putbytes) (XDR * __xdrs, char *__addr, u_int __len); u_int (*x_getpostn) (XDR * __xdrs); bool_t (*x_setpostn) (XDR * __xdrs, u_int __pos); int32_t *(*x_inline) (XDR * __xdrs, int __len); void (*x_destroy) (XDR * __xdrs); bool_t (*x_getint32) (XDR * __xdrs, int32_t * __ip); bool_t (*x_putint32) (XDR * __xdrs, int32_t * __ip); } ; typedef bool_t (*xdrproc_t) (XDR *, void *, ...); struct xdr_discrim { int value; xdrproc_t proc; } ; |
#define SCHED_OTHER 0 #define SCHED_FIFO 1 #define SCHED_RR 2 struct sched_param { int sched_priority; } ; |
typedef struct entry { char *key; void *data; } ENTRY; typedef enum { FIND, ENTER } ACTION; typedef enum { preorder, postorder, endorder, leaf } VISIT; typedef void (*__action_fn_t) (void *__nodep, VISIT __value, int __level); |
#define setjmp(env) _setjmp(env) #define sigsetjmp(a,b) __sigsetjmp(a,b) struct __jmp_buf_tag { __jmp_buf __jmpbuf; int __mask_was_saved; sigset_t __saved_mask; } ; typedef struct __jmp_buf_tag jmp_buf[1]; typedef jmp_buf sigjmp_buf; |
#define _SIGSET_NWORDS (1024/(8*sizeof(unsigned long))) #define SIGRTMAX (__libc_current_sigrtmax ()) #define SIGRTMIN (__libc_current_sigrtmin ()) #define SIG_BLOCK 0 #define SIG_UNBLOCK 1 #define SIG_SETMASK 2 #define NSIG 65 typedef int sig_atomic_t; typedef void (*sighandler_t) (int); #define SIG_HOLD ((sighandler_t) 2) #define SIG_ERR ((sighandler_t)-1) #define SIG_DFL ((sighandler_t)0) #define SIG_IGN ((sighandler_t)1) #define SIGHUP 1 #define SIGUSR1 10 #define SIGSEGV 11 #define SIGUSR2 12 #define SIGPIPE 13 #define SIGALRM 14 #define SIGTERM 15 #define SIGSTKFLT 16 #define SIGCHLD 17 #define SIGCONT 18 #define SIGSTOP 19 #define SIGINT 2 #define SIGTSTP 20 #define SIGTTIN 21 #define SIGTTOU 22 #define SIGURG 23 #define SIGXCPU 24 #define SIGXFSZ 25 #define SIGVTALRM 26 #define SIGPROF 27 #define SIGWINCH 28 #define SIGIO 29 #define SIGQUIT 3 #define SIGPWR 30 #define SIGSYS 31 #define SIGUNUSED 31 #define SIGILL 4 #define SIGTRAP 5 #define SIGABRT 6 #define SIGIOT 6 #define SIGBUS 7 #define SIGFPE 8 #define SIGKILL 9 #define SIGCLD SIGCHLD #define SIGPOLL SIGIO #define SV_ONSTACK (1<<0) #define SV_INTERRUPT (1<<1) #define SV_RESETHAND (1<<2) typedef union sigval { int sival_int; void *sival_ptr; } sigval_t; #define SIGEV_SIGNAL 0 #define SIGEV_NONE 1 #define SIGEV_THREAD 2 #define SIGEV_MAX_SIZE 64 typedef struct sigevent { sigval_t sigev_value; int sigev_signo; int sigev_notify; union { int _pad[SIGEV_PAD_SIZE]; struct { void (*sigev_thread_func) (sigval_t); void *_attribute; } _sigev_thread; } _sigev_un; } sigevent_t; #define SI_MAX_SIZE 128 #define si_pid _sifields._kill._pid #define si_uid _sifields._kill._uid #define si_value _sifields._rt._sigval #define si_int _sifields._rt._sigval.sival_int #define si_ptr _sifields._rt._sigval.sival_ptr #define si_status _sifields._sigchld._status #define si_stime _sifields._sigchld._stime #define si_utime _sifields._sigchld._utime #define si_addr _sifields._sigfault._addr #define si_band _sifields._sigpoll._band #define si_fd _sifields._sigpoll._fd #define si_timer1 _sifields._timer._timer1 #define si_timer2 _sifields._timer._timer2 typedef struct siginfo { int si_signo; int si_errno; int si_code; union { int _pad[SI_PAD_SIZE]; struct { pid_t _pid; uid_t _uid; } _kill; struct { unsigned int _timer1; unsigned int _timer2; } _timer; struct { pid_t _pid; uid_t _uid; sigval_t _sigval; } _rt; struct { pid_t _pid; uid_t _uid; int _status; clock_t _utime; clock_t _stime; } _sigchld; struct { void *_addr; } _sigfault; struct { int _band; int _fd; } _sigpoll; } _sifields; } siginfo_t; #define SI_QUEUE -1 #define SI_TIMER -2 #define SI_MESGQ -3 #define SI_ASYNCIO -4 #define SI_SIGIO -5 #define SI_TKILL -6 #define SI_ASYNCNL -60 #define SI_USER 0 #define SI_KERNEL 0x80 #define ILL_ILLOPC 1 #define ILL_ILLOPN 2 #define ILL_ILLADR 3 #define ILL_ILLTRP 4 #define ILL_PRVOPC 5 #define ILL_PRVREG 6 #define ILL_COPROC 7 #define ILL_BADSTK 8 #define FPE_INTDIV 1 #define FPE_INTOVF 2 #define FPE_FLTDIV 3 #define FPE_FLTOVF 4 #define FPE_FLTUND 5 #define FPE_FLTRES 6 #define FPE_FLTINV 7 #define FPE_FLTSUB 8 #define SEGV_MAPERR 1 #define SEGV_ACCERR 2 #define BUS_ADRALN 1 #define BUS_ADRERR 2 #define BUS_OBJERR 3 #define TRAP_BRKPT 1 #define TRAP_TRACE 2 #define CLD_EXITED 1 #define CLD_KILLED 2 #define CLD_DUMPED 3 #define CLD_TRAPPED 4 #define CLD_STOPPED 5 #define CLD_CONTINUED 6 #define POLL_IN 1 #define POLL_OUT 2 #define POLL_MSG 3 #define POLL_ERR 4 #define POLL_PRI 5 #define POLL_HUP 6 typedef struct { unsigned long int sig[_SIGSET_NWORDS]; } sigset_t; #define SA_NOCLDSTOP 0x00000001 #define SA_NOCLDWAIT 0x00000002 #define SA_SIGINFO 0x00000004 #define SA_ONSTACK 0x08000000 #define SA_RESTART 0x10000000 #define SA_INTERRUPT 0x20000000 #define SA_NODEFER 0x40000000 #define SA_RESETHAND 0x80000000 #define SA_NOMASK SA_NODEFER #define SA_ONESHOT SA_RESETHAND typedef struct sigaltstack { void *ss_sp; int ss_flags; size_t ss_size; } stack_t; #define SS_ONSTACK 1 #define SS_DISABLE 2 |
#define offsetof(TYPE,MEMBER) ((size_t)& ((TYPE*)0)->MEMBER) #define NULL (0L) typedef int wchar_t; |
#define EOF (-1) #define P_tmpdir "/tmp" #define FOPEN_MAX 16 #define L_tmpnam 20 #define FILENAME_MAX 4096 #define BUFSIZ 8192 #define L_ctermid 9 #define L_cuserid 9 typedef struct { off_t __pos; mbstate_t __state; } fpos_t; typedef struct { off64_t __pos; mbstate_t __state; } fpos64_t; typedef struct _IO_FILE FILE; #define _IOFBF 0 #define _IOLBF 1 #define _IONBF 2 |
#define MB_CUR_MAX (__ctype_get_mb_cur_max()) #define EXIT_SUCCESS 0 #define EXIT_FAILURE 1 #define RAND_MAX 2147483647 typedef int (*__compar_fn_t) (const void *, const void *); struct random_data { int32_t *fptr; int32_t *rptr; int32_t *state; int rand_type; int rand_deg; int rand_sep; int32_t *end_ptr; } ; typedef struct { int quot; int rem; } div_t; typedef struct { long int quot; long int rem; } ldiv_t; typedef struct { long long int quot; long long int rem; } lldiv_t; |
#define IPC_PRIVATE ((key_t)0) #define IPC_RMID 0 #define IPC_CREAT 00001000 #define IPC_EXCL 00002000 #define IPC_NOWAIT 00004000 #define IPC_SET 1 #define IPC_STAT 2 |
#define MAP_FAILED ((void*)-1) #define PROT_NONE 0x0 #define MAP_SHARED 0x01 #define MAP_PRIVATE 0x02 #define PROT_READ 0x1 #define MAP_FIXED 0x10 #define PROT_WRITE 0x2 #define MAP_ANONYMOUS 0x20 #define PROT_EXEC 0x4 #define MS_ASYNC 1 #define MS_INVALIDATE 2 #define MS_SYNC 4 #define MAP_ANON MAP_ANONYMOUS |
#define POLLIN 0x0001 #define POLLPRI 0x0002 #define POLLOUT 0x0004 #define POLLERR 0x0008 #define POLLHUP 0x0010 #define POLLNVAL 0x0020 struct pollfd { int fd; short events; short revents; } ; typedef unsigned long int nfds_t; |
#define RUSAGE_CHILDREN (-1) #define RUSAGE_BOTH (-2) #define RLIM_INFINITY (~0UL) #define RLIM_SAVED_CUR -1 #define RLIM_SAVED_MAX -1 #define RLIMIT_CPU 0 #define RUSAGE_SELF 0 #define RLIMIT_FSIZE 1 #define RLIMIT_DATA 2 #define RLIMIT_STACK 3 #define RLIMIT_CORE 4 #define RLIMIT_NOFILE 7 #define RLIMIT_AS 9 typedef unsigned long int rlim_t; typedef unsigned long long int rlim64_t; typedef int __rlimit_resource_t; struct rlimit { rlim_t rlim_cur; rlim_t rlim_max; } ; struct rlimit64 { rlim64_t rlim_cur; rlim64_t rlim_max; } ; struct rusage { struct timeval ru_utime; struct timeval ru_stime; long int ru_maxrss; long int ru_ixrss; long int ru_idrss; long int ru_isrss; long int ru_minflt; long int ru_majflt; long int ru_nswap; long int ru_inblock; long int ru_oublock; long int ru_msgsnd; long int ru_msgrcv; long int ru_nsignals; long int ru_nvcsw; long int ru_nivcsw; } ; enum __priority_which { PRIO_PROCESS, PRIO_PGRP = 1, PRIO_USER = 2 } ; #define PRIO_PGRP PRIO_PGRP #define PRIO_PROCESS PRIO_PROCESS #define PRIO_USER PRIO_USER typedef enum __priority_which __priority_which_t; |
#define SEM_UNDO 0x1000 #define GETPID 11 #define GETVAL 12 #define GETALL 13 #define GETNCNT 14 #define GETZCNT 15 #define SETVAL 16 #define SETALL 17 struct sembuf { short sem_num; short sem_op; short sem_flg; } ; |
#define SHM_RDONLY 010000 #define SHM_W 0200 #define SHM_RND 020000 #define SHM_R 0400 #define SHM_REMAP 040000 #define SHM_LOCK 11 #define SHM_UNLOCK 12 |
#define CMSG_NXTHDR(mhdr,cmsg) ( ((cmsg) == NULL) ? CMSG_FIRSTHDR(mhdr) : (((unsigned char *)(cmsg) + CMSG_ALIGN((cmsg)->cmsg_len) + CMSG_ALIGN(sizeof(struct cmsghdr)) > (unsigned char *)((mhdr)->msg_control) + (mhdr)->msg_controllen) ? (struct cmsghdr *)NULL :(struct cmsghdr *)((unsi #define CMSG_ALIGN(len) (((len)+sizeof(size_t)-1)& (size_t)~(sizeof(size_t)-1)) #define CMSG_FIRSTHDR(msg) ((size_t) (mhdr)->msg_controllen >= sizeof (struct cmsghdr) ? (struct cmsghdr *) (mhdr)->msg_control : (struct cmsghdr *) NULL) #define CMSG_DATA(cmsg) ((unsigned char *) (cmsg) + CMSG_ALIGN(sizeof(struct cmsghdr))) #define CMSG_LEN(len) (CMSG_ALIGN(sizeof(struct cmsghdr))+(len)) #define CMSG_SPACE(len) (CMSG_ALIGN(sizeof(struct cmsghdr))+CMSG_ALIGN(len)) #define SCM_RIGHTS 0x01 #define SOL_SOCKET 1 #define SOMAXCONN 128 #define SOL_RAW 255 struct linger { int l_onoff; int l_linger; } ; struct cmsghdr { size_t cmsg_len; int cmsg_level; int cmsg_type; } ; struct iovec { void *iov_base; size_t iov_len; } ; typedef unsigned short sa_family_t; typedef unsigned int socklen_t; struct sockaddr { sa_family_t sa_family; char sa_data[14]; } ; struct sockaddr_storage { sa_family_t ss_family; __ss_aligntype __ss_align; char __ss_padding[(128 - (2 * sizeof (__ss_aligntype)))]; } ; struct msghdr { void *msg_name; int msg_namelen; struct iovec *msg_iov; size_t msg_iovlen; void *msg_control; size_t msg_controllen; unsigned int msg_flags; } ; #define AF_UNSPEC 0 #define AF_UNIX 1 #define AF_INET6 10 #define AF_INET 2 #define PF_INET AF_INET #define PF_INET6 AF_INET6 #define PF_UNIX AF_UNIX #define PF_UNSPEC AF_UNSPEC #define SOCK_STREAM 1 #define SOCK_PACKET 10 #define SOCK_DGRAM 2 #define SOCK_RAW 3 #define SOCK_RDM 4 #define SOCK_SEQPACKET 5 #define SO_DEBUG 1 #define SO_OOBINLINE 10 #define SO_NO_CHECK 11 #define SO_PRIORITY 12 #define SO_LINGER 13 #define SO_REUSEADDR 2 #define SO_TYPE 3 #define SO_ACCEPTCONN 30 #define SO_ERROR 4 #define SO_DONTROUTE 5 #define SO_BROADCAST 6 #define SO_SNDBUF 7 #define SO_RCVBUF 8 #define SO_KEEPALIVE 9 #define SIOCGIFFLAGS 0x8913 #define SIOCGIFADDR 0x8915 #define SIOCGIFNETMASK 0x891b #define SHUT_RD 0 #define SHUT_WR 1 #define SHUT_RDWR 2 #define MSG_DONTROUTE 4 #define MSG_WAITALL 0x100 #define MSG_TRUNC 0x20 #define MSG_EOR 0x80 #define MSG_OOB 1 #define MSG_PEEK 2 #define MSG_CTRUNC 8 |
#define S_ISBLK(m) (((m)& S_IFMT)==S_IFBLK) #define S_ISCHR(m) (((m)& S_IFMT)==S_IFCHR) #define S_ISDIR(m) (((m)& S_IFMT)==S_IFDIR) #define S_ISFIFO(m) (((m)& S_IFMT)==S_IFIFO) #define S_ISLNK(m) (((m)& S_IFMT)==S_IFLNK) #define S_ISREG(m) (((m)& S_IFMT)==S_IFREG) #define S_ISSOCK(m) (((m)& S_IFMT)==S_IFSOCK) #define S_TYPEISMQ(buf) ((buf)->st_mode - (buf)->st_mode) #define S_TYPEISSEM(buf) ((buf)->st_mode - (buf)->st_mode) #define S_TYPEISSHM(buf) ((buf)->st_mode - (buf)->st_mode) #define S_IRWXU (S_IREAD|S_IWRITE|S_IEXEC) #define S_IROTH (S_IRGRP>>3) #define S_IRGRP (S_IRUSR>>3) #define S_IRWXO (S_IRWXG>>3) #define S_IRWXG (S_IRWXU>>3) #define S_IWOTH (S_IWGRP>>3) #define S_IWGRP (S_IWUSR>>3) #define S_IXOTH (S_IXGRP>>3) #define S_IXGRP (S_IXUSR>>3) #define S_ISVTX 01000 #define S_IXUSR 0x0040 #define S_IWUSR 0x0080 #define S_IRUSR 0x0100 #define S_ISGID 0x0400 #define S_ISUID 0x0800 #define S_IFIFO 0x1000 #define S_IFCHR 0x2000 #define S_IFDIR 0x4000 #define S_IFBLK 0x6000 #define S_IFREG 0x8000 #define S_IFLNK 0xa000 #define S_IFSOCK 0xc000 #define S_IFMT 0xf000 #define st_atime st_atim.tv_sec #define st_ctime st_ctim.tv_sec #define st_mtime st_mtim.tv_sec #define S_IREAD S_IRUSR #define S_IWRITE S_IWUSR #define S_IEXEC S_IXUSR |
#define ITIMER_REAL 0 #define ITIMER_VIRTUAL 1 #define ITIMER_PROF 2 struct timezone { int tz_minuteswest; int tz_dsttime; } ; typedef int __itimer_which_t; struct timespec { time_t tv_sec; long int tv_nsec; } ; struct timeval { time_t tv_sec; suseconds_t tv_usec; } ; struct itimerval { struct timeval it_interval; struct timeval it_value; } ; |
struct timeb { time_t time; unsigned short millitm; short timezone; short dstflag; } ; |
struct tms { clock_t tms_utime; clock_t tms_stime; clock_t tms_cutime; clock_t tms_cstime; } ; |
#define FD_ISSET(d,set) ((set)->fds_bits[((d)/(8*sizeof(long)))]& (1<<((d)%(8*sizeof(long))))) #define FD_CLR(d,set) ((set)->fds_bits[((d)/(8*sizeof(long)))]& =~(1<<((d)%(8*sizeof(long))))) #define FD_SET(d,set) ((set)->fds_bits[((d)/(8*sizeof(long)))]|=(1<<((d)%(8*sizeof(long))))) #define FALSE 0 #define TRUE 1 #define FD_SETSIZE 1024 #define FD_ZERO(fdsetp) bzero(fdsetp, sizeof(*(fdsetp))) typedef signed char int8_t; typedef short int16_t; typedef int int32_t; typedef unsigned char u_int8_t; typedef unsigned short u_int16_t; typedef unsigned int u_int32_t; typedef unsigned int uid_t; typedef int pid_t; typedef unsigned long int off_t; typedef int key_t; typedef long int suseconds_t; typedef unsigned int u_int; typedef struct { int __val[2]; } fsid_t; typedef unsigned int useconds_t; typedef unsigned long int blksize_t; typedef long int fd_mask; typedef int timer_t; typedef int clockid_t; typedef unsigned int id_t; typedef unsigned long long int ino64_t; typedef long long int loff_t; typedef unsigned long int blkcnt_t; typedef unsigned long int fsblkcnt_t; typedef unsigned long int fsfilcnt_t; typedef unsigned long long int blkcnt64_t; typedef unsigned long long int fsblkcnt64_t; typedef unsigned long long int fsfilcnt64_t; typedef unsigned char u_char; typedef unsigned short u_short; typedef unsigned long int u_long; typedef unsigned long int ino_t; typedef unsigned int gid_t; typedef unsigned long long int dev_t; typedef unsigned int mode_t; typedef unsigned long int nlink_t; typedef char *caddr_t; typedef struct { unsigned long int fds_bits[__FDSET_LONGS]; } fd_set; typedef long int clock_t; typedef long int time_t; |
#define UNIX_PATH_MAX 108 struct sockaddr_un { sa_family_t sun_family; char sun_path[UNIX_PATH_MAX]; } ; |
#define SYS_NMLN 65 struct utsname { char sysname[65]; char nodename[65]; char release[65]; char version[65]; char machine[65]; char domainname[65]; } ; |
#define WIFSIGNALED(status) (!WIFSTOPPED(status) & & !WIFEXITED(status)) #define WIFSTOPPED(status) (((status) & 0xff) == 0x7f) #define WEXITSTATUS(status) (((status) & 0xff00) >> 8) #define WTERMSIG(status) ((status) & 0x7f) #define WCOREDUMP(status) ((status) & 0x80) #define WIFEXITED(status) (WTERMSIG(status) == 0) #define WNOHANG 0x00000001 #define WUNTRACED 0x00000002 #define WCOREFLAG 0x80 #define WSTOPSIG(status) WEXITSTATUS(status) typedef enum { P_ALL, P_PID, P_PGID } idtype_t; |
#define LOG_EMERG 0 #define LOG_PRIMASK 0x07 #define LOG_ALERT 1 #define LOG_CRIT 2 #define LOG_ERR 3 #define LOG_WARNING 4 #define LOG_NOTICE 5 #define LOG_INFO 6 #define LOG_DEBUG 7 #define LOG_KERN (0<<3) #define LOG_AUTHPRIV (10<<3) #define LOG_FTP (11<<3) #define LOG_USER (1<<3) #define LOG_MAIL (2<<3) #define LOG_DAEMON (3<<3) #define LOG_AUTH (4<<3) #define LOG_SYSLOG (5<<3) #define LOG_LPR (6<<3) #define LOG_NEWS (7<<3) #define LOG_UUCP (8<<3) #define LOG_CRON (9<<3) #define LOG_FACMASK 0x03f8 #define LOG_LOCAL0 (16<<3) #define LOG_LOCAL1 (17<<3) #define LOG_LOCAL2 (18<<3) #define LOG_LOCAL3 (19<<3) #define LOG_LOCAL4 (20<<3) #define LOG_LOCAL5 (21<<3) #define LOG_LOCAL6 (22<<3) #define LOG_LOCAL7 (23<<3) #define LOG_UPTO(pri) ((1 << ((pri)+1)) - 1) #define LOG_MASK(pri) (1 << (pri)) #define LOG_PID 0x01 #define LOG_CONS 0x02 #define LOG_ODELAY 0x04 #define LOG_NDELAY 0x08 #define LOG_NOWAIT 0x10 #define LOG_PERROR 0x20 |
#define TCIFLUSH 0 #define TCOOFF 0 #define TCSANOW 0 #define BS0 0000000 #define CR0 0000000 #define FF0 0000000 #define NL0 0000000 #define TAB0 0000000 #define VT0 0000000 #define OPOST 0000001 #define OCRNL 0000010 #define ONOCR 0000020 #define ONLRET 0000040 #define OFILL 0000100 #define OFDEL 0000200 #define NL1 0000400 #define TCOFLUSH 1 #define TCOON 1 #define TCSADRAIN 1 #define TCIOFF 2 #define TCIOFLUSH 2 #define TCSAFLUSH 2 #define TCION 3 typedef unsigned int speed_t; typedef unsigned char cc_t; typedef unsigned int tcflag_t; #define NCCS 32 struct termios { tcflag_t c_iflag; tcflag_t c_oflag; tcflag_t c_cflag; tcflag_t c_lflag; cc_t c_line; cc_t c_cc[NCCS]; speed_t c_ispeed; speed_t c_ospeed; } ; #define VINTR 0 #define VQUIT 1 #define VLNEXT 15 #define VERASE 2 #define VKILL 3 #define VEOF 4 #define IGNBRK 0000001 #define BRKINT 0000002 #define IGNPAR 0000004 #define PARMRK 0000010 #define INPCK 0000020 #define ISTRIP 0000040 #define INLCR 0000100 #define IGNCR 0000200 #define ICRNL 0000400 #define IXANY 0004000 #define IMAXBEL 0020000 #define CS5 0000000 #define ECHO 0000010 #define B0 0000000 #define B50 0000001 #define B75 0000002 #define B110 0000003 #define B134 0000004 #define B150 0000005 #define B200 0000006 #define B300 0000007 #define B600 0000010 #define B1200 0000011 #define B1800 0000012 #define B2400 0000013 #define B4800 0000014 #define B9600 0000015 #define B19200 0000016 #define B38400 0000017 |
#define CLK_TCK ((clock_t)__sysconf(2)) #define CLOCK_REALTIME 0 #define TIMER_ABSTIME 1 #define CLOCKS_PER_SEC 1000000l struct tm { int tm_sec; int tm_min; int tm_hour; int tm_mday; int tm_mon; int tm_year; int tm_wday; int tm_yday; int tm_isdst; long int tm_gmtoff; char *tm_zone; } ; struct itimerspec { struct timespec it_interval; struct timespec it_value; } ; |
The LSB requires
_XOPEN_REALTIME
to be defined to 1, but does not require
all the set of functions required by the
ISO POSIX (2003) XSI Option Group _XOPEN_REALTIME.
For example,
the asynchronous input/output functions are optional for LSB
conforming systems.
#define SEEK_SET 0 #define STDIN_FILENO 0 #define SEEK_CUR 1 #define STDOUT_FILENO 1 #define SEEK_END 2 #define STDERR_FILENO 2 typedef long long int off64_t; #define F_OK 0 #define X_OK 1 #define W_OK 2 #define R_OK 4 #define _POSIX_VDISABLE '\0' #define _POSIX_CHOWN_RESTRICTED 1 #define _POSIX_JOB_CONTROL 1 #define _POSIX_NO_TRUNC 1 #define _POSIX_SHELL 1 #define _POSIX_FSYNC 200112 #define _POSIX_MAPPED_FILES 200112 #define _POSIX_MEMLOCK 200112 #define _POSIX_MEMLOCK_RANGE 200112 #define _POSIX_MEMORY_PROTECTION 200112 #define _POSIX_SEMAPHORES 200112 #define _POSIX_SHARED_MEMORY_OBJECTS 200112 #define _POSIX_TIMERS 200112 #define _POSIX2_C_BIND 200112L #define _POSIX_THREADS 200112L #define _PC_LINK_MAX 0 #define _PC_MAX_CANON 1 #define _PC_ASYNC_IO 10 #define _PC_PRIO_IO 11 #define _PC_FILESIZEBITS 13 #define _PC_REC_INCR_XFER_SIZE 14 #define _PC_REC_MIN_XFER_SIZE 16 #define _PC_REC_XFER_ALIGN 17 #define _PC_ALLOC_SIZE_MIN 18 #define _PC_MAX_INPUT 2 #define _PC_2_SYMLINKS 20 #define _PC_NAME_MAX 3 #define _PC_PATH_MAX 4 #define _PC_PIPE_BUF 5 #define _PC_CHOWN_RESTRICTED 6 #define _PC_NO_TRUNC 7 #define _PC_VDISABLE 8 #define _PC_SYNC_IO 9 #define _SC_ARG_MAX 0 #define _SC_CHILD_MAX 1 #define _SC_PRIORITY_SCHEDULING 10 #define _SC_TIMERS 11 #define _SC_ASYNCHRONOUS_IO 12 #define _SC_XBS5_ILP32_OFF32 125 #define _SC_XBS5_ILP32_OFFBIG 126 #define _SC_XBS5_LP64_OFF64 127 #define _SC_XBS5_LPBIG_OFFBIG 128 #define _SC_XOPEN_LEGACY 129 #define _SC_PRIORITIZED_IO 13 #define _SC_XOPEN_REALTIME 130 #define _SC_XOPEN_REALTIME_THREADS 131 #define _SC_ADVISORY_INFO 132 #define _SC_BARRIERS 133 #define _SC_CLOCK_SELECTION 137 #define _SC_CPUTIME 138 #define _SC_THREAD_CPUTIME 139 #define _SC_SYNCHRONIZED_IO 14 #define _SC_MONOTONIC_CLOCK 149 #define _SC_FSYNC 15 #define _SC_READER_WRITER_LOCKS 153 #define _SC_SPIN_LOCKS 154 #define _SC_REGEXP 155 #define _SC_SHELL 157 #define _SC_SPAWN 159 #define _SC_MAPPED_FILES 16 #define _SC_SPORADIC_SERVER 160 #define _SC_THREAD_SPORADIC_SERVER 161 #define _SC_TIMEOUTS 164 #define _SC_TYPED_MEMORY_OBJECTS 165 #define _SC_2_PBS_ACCOUNTING 169 #define _SC_MEMLOCK 17 #define _SC_2_PBS_LOCATE 170 #define _SC_2_PBS_MESSAGE 171 #define _SC_2_PBS_TRACK 172 #define _SC_SYMLOOP_MAX 173 #define _SC_2_PBS_CHECKPOINT 175 #define _SC_V6_ILP32_OFF32 176 #define _SC_V6_ILP32_OFFBIG 177 #define _SC_V6_LP64_OFF64 178 #define _SC_V6_LPBIG_OFFBIG 179 #define _SC_MEMLOCK_RANGE 18 #define _SC_HOST_NAME_MAX 180 #define _SC_TRACE 181 #define _SC_TRACE_EVENT_FILTER 182 #define _SC_TRACE_INHERIT 183 #define _SC_TRACE_LOG 184 #define _SC_MEMORY_PROTECTION 19 #define _SC_CLK_TCK 2 #define _SC_MESSAGE_PASSING 20 #define _SC_SEMAPHORES 21 #define _SC_SHARED_MEMORY_OBJECTS 22 #define _SC_AIO_LISTIO_MAX 23 #define _SC_AIO_MAX 24 #define _SC_AIO_PRIO_DELTA_MAX 25 #define _SC_DELAYTIMER_MAX 26 #define _SC_MQ_OPEN_MAX 27 #define _SC_MQ_PRIO_MAX 28 #define _SC_VERSION 29 #define _SC_NGROUPS_MAX 3 #define _SC_PAGESIZE 30 #define _SC_PAGE_SIZE 30 #define _SC_RTSIG_MAX 31 #define _SC_SEM_NSEMS_MAX 32 #define _SC_SEM_VALUE_MAX 33 #define _SC_SIGQUEUE_MAX 34 #define _SC_TIMER_MAX 35 #define _SC_BC_BASE_MAX 36 #define _SC_BC_DIM_MAX 37 #define _SC_BC_SCALE_MAX 38 #define _SC_BC_STRING_MAX 39 #define _SC_OPEN_MAX 4 #define _SC_COLL_WEIGHTS_MAX 40 #define _SC_EXPR_NEST_MAX 42 #define _SC_LINE_MAX 43 #define _SC_RE_DUP_MAX 44 #define _SC_2_VERSION 46 #define _SC_2_C_BIND 47 #define _SC_2_C_DEV 48 #define _SC_2_FORT_DEV 49 #define _SC_STREAM_MAX 5 #define _SC_2_FORT_RUN 50 #define _SC_2_SW_DEV 51 #define _SC_2_LOCALEDEF 52 #define _SC_TZNAME_MAX 6 #define _SC_IOV_MAX 60 #define _SC_THREADS 67 #define _SC_THREAD_SAFE_FUNCTIONS 68 #define _SC_GETGR_R_SIZE_MAX 69 #define _SC_JOB_CONTROL 7 #define _SC_GETPW_R_SIZE_MAX 70 #define _SC_LOGIN_NAME_MAX 71 #define _SC_TTY_NAME_MAX 72 #define _SC_THREAD_DESTRUCTOR_ITERATIONS 73 #define _SC_THREAD_KEYS_MAX 74 #define _SC_THREAD_STACK_MIN 75 #define _SC_THREAD_THREADS_MAX 76 #define _SC_THREAD_ATTR_STACKADDR 77 #define _SC_THREAD_ATTR_STACKSIZE 78 #define _SC_THREAD_PRIORITY_SCHEDULING 79 #define _SC_SAVED_IDS 8 #define _SC_THREAD_PRIO_INHERIT 80 #define _SC_THREAD_PRIO_PROTECT 81 #define _SC_THREAD_PROCESS_SHARED 82 #define _SC_ATEXIT_MAX 87 #define _SC_PASS_MAX 88 #define _SC_XOPEN_VERSION 89 #define _SC_REALTIME_SIGNALS 9 #define _SC_XOPEN_UNIX 91 #define _SC_XOPEN_CRYPT 92 #define _SC_XOPEN_ENH_I18N 93 #define _SC_XOPEN_SHM 94 #define _SC_2_CHAR_TERM 95 #define _SC_2_C_VERSION 96 #define _SC_2_UPE 97 #define _CS_PATH 0 #define _POSIX_REGEXP 1 #define _CS_XBS5_ILP32_OFF32_CFLAGS 1100 #define _CS_XBS5_ILP32_OFF32_LDFLAGS 1101 #define _CS_XBS5_ILP32_OFF32_LIBS 1102 #define _CS_XBS5_ILP32_OFF32_LINTFLAGS 1103 #define _CS_XBS5_ILP32_OFFBIG_CFLAGS 1104 #define _CS_XBS5_ILP32_OFFBIG_LDFLAGS 1105 #define _CS_XBS5_ILP32_OFFBIG_LIBS 1106 #define _CS_XBS5_ILP32_OFFBIG_LINTFLAGS 1107 #define _CS_XBS5_LP64_OFF64_CFLAGS 1108 #define _CS_XBS5_LP64_OFF64_LDFLAGS 1109 #define _CS_XBS5_LP64_OFF64_LIBS 1110 #define _CS_XBS5_LP64_OFF64_LINTFLAGS 1111 #define _CS_XBS5_LPBIG_OFFBIG_CFLAGS 1112 #define _CS_XBS5_LPBIG_OFFBIG_LDFLAGS 1113 #define _CS_XBS5_LPBIG_OFFBIG_LIBS 1114 #define _CS_XBS5_LPBIG_OFFBIG_LINTFLAGS 1115 #define _XOPEN_XPG4 1 #define F_ULOCK 0 #define F_LOCK 1 #define F_TLOCK 2 #define F_TEST 3 |
#define UT_HOSTSIZE 256 #define UT_LINESIZE 32 #define UT_NAMESIZE 32 struct exit_status { short e_termination; short e_exit; } ; #define EMPTY 0 #define RUN_LVL 1 #define BOOT_TIME 2 #define NEW_TIME 3 #define OLD_TIME 4 #define INIT_PROCESS 5 #define LOGIN_PROCESS 6 #define USER_PROCESS 7 #define DEAD_PROCESS 8 #define ACCOUNTING 9 |
#define WEOF (0xffffffffu) #define WCHAR_MAX 0x7FFFFFFF #define WCHAR_MIN 0x80000000 |
typedef unsigned long int wctype_t; typedef unsigned int wint_t; typedef const int32_t *wctrans_t; typedef struct { int count; wint_t value; } __mbstate_t; typedef __mbstate_t mbstate_t; |
enum { WRDE_DOOFFS, WRDE_APPEND, WRDE_NOCMD, WRDE_REUSE, WRDE_SHOWERR, WRDE_UNDEF, __WRDE_FLAGS } ; typedef struct { int we_wordc; char **we_wordv; int we_offs; } wordexp_t; enum { WRDE_NOSYS, WRDE_NOSPACE, WRDE_BADCHAR, WRDE_BADVAL, WRDE_CMDSUB, WRDE_SYNTAX } ; |
The following interfaces are included in libc and are defined by this specification. Unless otherwise noted, these interfaces shall be included in the source standard.
Other interfaces listed above for libc shall behave as described in the referenced base document.
_IO_feof() tests the end-of-file indicator for the stream pointed to by __fp, returning a non-zero value if it is set.
_IO_feof() is not in the source standard; it is only in the binary standard.
_IO_getc() reads the next character from
__fp and returns it as an unsigned char cast
to an int, or EOF
on end-of-file or error.
_IO_getc() is not in the source standard; it is only in the binary standard.
_IO_putc() writes the character __c, cast to an unsigned char, to __fp.
_IO_putc() is not in the source standard; it is only in the binary standard.
_IO_puts() writes the string __s
and a trailing newline to stdout
.
_IO_puts() is not in the source standard; it is only in the binary standard.
The __assert_fail() function is used to implement the assert() interface of ISO POSIX (2003). The __assert_fail() function shall print the given file filename, line line number, function function name and a message on the standard error stream in an unspecified format, and abort program execution via the abort() function. For example:
a.c:10: foobar: Assertion a == b failed.
If function is NULL, __assert_fail() shall omit information about the function.
assertion, file, and line shall be non-NULL.
The __assert_fail() function is not in the source standard; it is only in the binary standard. The assert() interface is not in the binary standard; it is only in the source standard. The assert() may be implemented as a macro.
The __ctype_b_loc()
function shall return a pointer into an array of
characters in the current locale that contains characteristics for each
character in the current character set. The array shall contain a total of
384
characters, and can be indexed with any signed or unsigned char (i.e. with an
index value between -128
and
255
). If the application is multithreaded, the
array shall be local to the current thread.
This interface is not in the source standard; it is only in the binary standard.
The __ctype_b_loc() function shall return a pointer to the array of characters to be used for the ctype() family of functions (see <ctype.h>).
__ctype_get_mb_cur_max() returns the maximum length of a multibyte character in the current locale.
__ctype_get_mb_cur_max() is not in the source standard; it is only in the binary standard.
The __ctype_tolower_loc()
function shall return a pointer into an array of
characters in the current locale that contains lower case equivalents for each
character in the current character set. The array shall contain a total of
384
characters, and can be indexed with any signed or unsigned char (i.e. with an
index value between -128
and
255
). If the application is multithreaded, the
array shall be local to the current thread.
This interface is not in the source standard; it is only in the binary standard.
The __ctype_tolower_loc() function shall return a pointer to the array of characters to be used for the ctype() family of functions (see <ctype.h>).
The __ctype_toupper_loc()
function shall return a pointer into an array of
characters in the current locale that contains upper case equivalents for each
character in the current character set. The array shall contain a total of
384
characters, and can be indexed with any signed or unsigned char (i.e. with an
index value between -128
and
255
). If the application is multithreaded, the
array shall be local to the current thread.
This interface is not in the source standard; it is only in the binary standard.
The __ctype_toupper_loc() function shall return a pointer to the array of characters to be used for the ctype() family of functions (see <ctype.h>).
__cxa_atexit() registers a function to be called by exit or when a shared library is unloaded.
The __cxa_atexit() function is used to implement atexit(), as described in ISO POSIX (2003). Calling
atexit(func) |
__cxa_atexit(func, NULL, NULL) |
__cxa_atexit() is not in the source standard; it is only in the binary standard. atexit() is not in the binary standard; it is only in the source standard.
The integer variable __daylight
shall implement the daylight savings time flag daylight
as specified in the
ISO POSIX (2003) header file <time.h>.
__daylight
is not in the source standard;
it is only in the binary standard. daylight
is not in the binary standard; it is only in the source standard.
__environ
is an alias for environ
- user environment.
__environ
has the same specification as
environ
.
__environ
is not in the source standard;
it is only in the binary standard.
__fpending() returns the amount of output in bytes pending on a stream.
__fpending() is not in the source standard; it is only in the binary standard.
__getpagesize() is an alias for getpagesize() - get current page size.
__getpagesize() has the same specification as getpagesize().
__getpagesize() is not in the source standard; it is only in the binary standard.
__getpgid() has the same specification as getpgid().
__getpgid() is not in the source standard; it is only in the binary standard.
__h_errno_location() returns the address of the
h_errno
variable, where h_errno
is as specified in ISO POSIX (2003).
__h_errno_location() is not in the source standard;
it is only in the binary standard. Note that h_errno
itself is only in the source standard; it is not in the binary standard.
__isinf() has the same specification as isinf() in ISO POSIX (2003), except that the argument type for __isinf() is known to be double.
__isinf() is not in the source standard; it is only in the binary standard.
__isinff() has the same specification as isinf() in ISO POSIX (2003) except that the argument type for __isinff() is known to be float.
__isinff() is not in the source standard; it is only in the binary standard.
__isinfl() has the same specification as isinf() in the ISO POSIX (2003), except that the argument type for __isinfl() is known to be long double.
__isinfl() is not in the source standard; it is only in the binary standard.
__isnan() has the same specification as isnan() in ISO POSIX (2003), except that the argument type for __isnan() is known to be double.
__isnan() is not in the source standard; it is only in the binary standard.
__isnanf() has the same specification as isnan() in ISO POSIX (2003), except that the argument type for __isnanf() is known to be float.
__isnanf() is not in the source standard; it is only in the binary standard.
__isnanl() has the same specification as isnan() in ISO POSIX (2003), except that the argument type for __isnanl() is known to be long double.
__isnanl() is not in the source standard; it is only in the binary standard.
__libc_current_sigrtmax() returns the number of an available real-time signal with the lowest priority.
__libc_current_sigrtmax() is not in the source standard; it is only in the binary standard.
__libc_current_sigrtmin() returns the number of an available real-time signal with the highest priority.
__libc_current_sigrtmin() is not in the source standard; it is only in the binary standard.
The __libc_start_main() function shall initialize the process, call the main function with appropriate arguments, and handle the return from main().
__libc_start_main() is not in the source standard; it is only in the binary standard.
__lxstat() is an inline wrapper around call to lxstat().
__lxstat() is not in the source standard; it is only in the binary standard.
__mempcpy() copies n bytes of source to destination, returning pointer to bytes after the last written byte.
__mempcpy() is not in the source standard; it is only in the binary standard.
__rawmemchr() searches in s for c.
__rawmemchr() is a weak alias to rawmemchr(). It is similar to memchr(), but it has no length limit.
__rawmemchr() is not in the source standard; it is only in the binary standard.
__register_atfork() implements pthread_atfork() as specified in ISO POSIX (2003). The additional parameter __dso_handle allows a shared object to pass in it's handle so that functions registered by __register_atfork() can be unregistered by the runtime when the shared object is unloaded.
__sigsetjmp() has the same behavior as sigsetjmp() as specified by ISO POSIX (2003).
__sigsetjmp() is not in the source standard; it is only in the binary standard.
__stpcpy() copies the string src (including the terminating /0 character) to the array dest. The strings may not overlap, and dest must be large enough to receive the copy.
__stpcpy() returns a pointer to the end of the string dest (that is, the address of the terminating NULL character) rather than the beginning.
__stpcpy() has the same specification as stpcpy().
__stpcpy() is not in the source standard; it is only in the binary standard.
__strdup() has the same specification as strdup().
__strdup() is not in the source standard; it is only in the binary standard.
__group shall be 0 or the behavior of __strtod_internal() is undefined.
__strtod_internal(__nptr, __endptr, 0)() has the same specification as strtod(__nptr, __endptr)().
__strtod_internal() is not in the source standard; it is only in the binary standard.
__group shall be 0 or the behavior of __strtof_internal() is undefined.
__strtof_internal(__nptr, __endptr, 0)() has the same specification as strtof(__nptr, __endptr)().
__strtof_internal() is not in the source standard; it is only in the binary standard.
__strtok_r() has the same specification as strtok_r().
__strtok_r() is not in the source standard; it is only in the binary standard.
__group shall be 0 or the behavior of __strtol_internal() is undefined.
__strtol_internal(__nptr, __endptr, __base, 0) has the same specification as strtol(__nptr, __endptr, __base).
__strtol_internal() is not in the source standard; it is only in the binary standard.
__group shall be 0 or the behavior of __strtold_internal() is undefined.
__strtold_internal(__nptr, __endptr, 0) has the same specification as strtold(__nptr, __endptr).
__strtold_internal() is not in the source standard; it is only in the binary standard.
__group shall be 0 or the behavior of __strtoll_internal() is undefined.
__strtoll_internal(__nptr, __endptr, __base, 0) has the same specification as strtoll(__nptr, __endptr, __base).
__strtoll_internal() is not in the source standard; it is only in the binary standard.
__group shall be 0 or the behavior of __strtoul_internal() is undefined.
__strtoul_internal(__nptr, __endptr, __base, 0) has the same specification as strtoul(__nptr, __endptr, __base).
__strtoul_internal() is not in the source standard; it is only in the binary standard.
__group shall be 0 or the behavior of __strtoull_internal() is undefined.
__strtoull_internal(__nptr, __endptr, __base, 0) has the same specification as strtoull(__nptr, __endptr, __base).
__strtoull_internal() is not in the source standard; it is only in the binary standard.
__sysconf() gets configuration information at runtime.
__sysconf() is weak alias to sysconf().
__sysconf() has the same specification as sysconf().
__sysconf() is not in the source standard; it is only in the binary standard.
__sysv_signal() has the same behavior as signal() as specified by ISO POSIX (2003).
__sysv_signal() is not in the source standard; it is only in the binary standard.
__tzname
has the same specification as
tzname
in the
ISO POSIX (2003).
Note that the array size of 2 is explicit in the ISO POSIX (2003), but not in the SUSv2.
group shall be 0 or the behavior of __wcstod_internal() is undefined.
__wcstod_internal(nptr, endptr, 0) has the same specification as wcstod(nptr, endptr).
__wcstod_internal() is not in the source standard; it is only in the binary standard.
group shall be 0 or the behavior of __wcstof_internal() is undefined.
__wcstof_internal(nptr, endptr, 0) has the same specification as wcstof(nptr, endptr).
__wcstof_internal() is not in the source standard; it is only in the binary standard.
group shall be 0 or the behavior of __wcstol_internal() is undefined.
__wcstol_internal(nptr, endptr, base, 0) has the same specification as wcstol(nptr, endptr, base).
__wcstol_internal() is not in the source standard; it is only in the binary standard.
group shall be 0 or the behavior of __wcstold_internal() is undefined.
__wcstold_internal(nptr, endptr, 0) has the same specification as wcstold(nptr, endptr).
__wcstold_internal() is not in the source standard; it is only in the binary standard.
group shall be 0 or the behavior of __wcstoul_internal() is undefined.
__wcstoul_internal(nptr, endptr, base, 0)() has the same specification as wcstoul(nptr, endptr, base)().
__wcstoul_internal() is not in the source standard; it is only in the binary standard.
The __xmknod() shall implement the mknod() interface from ISO POSIX (2003).
__xmknod(1, path, mode, dev) has the same specification as mknod(path, mode, dev).
ver shall be 1 or the behavior of __xmknod() is undefined.
The __xmknod() function is not in the source standard; it is only in the binary standard. The mknod() function is not in the binary standard; it is only in the source standard.
The functions __xstat(), __lxstat(), and __fxstat() shall implement the ISO POSIX (2003) functions stat(), lstat(), and fstat() respectively.
ver shall be 3 or the behavior of these functions is undefined.
__xstat(3, path, stat_buf) shall behave as stat(path, stat_buf) as specified by ISO POSIX (2003).
__lxstat(3, path, stat_buf) shall behave as lstat(path, stat_buf) as specified by ISO POSIX (2003).
__fxstat(3, fildes, stat_buf) shall behave as fstat(fildes, stat_buf) as specified by ISO POSIX (2003).
__xstat(), __lxstat(), and __fxstat() are not in the source standard; they are only in the binary standard.
stat(), lstat(), and fstat() are not in the binary standard; they are only in the source standard.
The functions __xstat64(), __lxstat64(), and __fxstat64() shall implement the Large File Support functions stat64(), lstat64(), and fstat64() respectively.
ver shall be 3 or the behavior of these functions is undefined.
__xstat64(3, path, stat_buf) shall behave as stat(path, stat_buf) as specified by Large File Support.
__lxstat64(3, path, stat_buf) shall behave as lstat(path, stat_buf) as specified by Large File Support.
__fxstat64(3, fildes, stat_buf) shall behave as fstat(fildes, stat_buf) as specified by Large File Support.
__xstat64(), __lxstat64(), and __fxstat64() are not in the source standard; they are only in the binary standard.
stat64(), lstat64(), and fstat64() are not in the binary standard; they are only in the source standard.
_nl_msg_cat_cntr
is incremented each time a new
catalong is loaded. It is a variable defined in
loadmsgcat.c and is used by Message catalogs
for internationalization.
_sys_errlist
is an array containing the "C" locale
strings used by strerror(). This normally should not
be used directly. strerror() provides all of the
needed functionality.
_sys_siglist
is an array containing the names of
the signal names.
The _sys_siglist
array
is only in the binary standard; it is not in the source standard.
Applications wishing to access the names of signals should use
the strsignal() function.
When filename is the name of an existing file, acct() turns accounting on and appends a record to filename for each terminating process. When filename is NULL, acct() turns accounting off.
On success, 0 is returned.
On error, -1 is returned and
the global variable errno
is set appropriately.
BSD process accounting has not been enabled when the operating system kernel was compiled. The kernel configuration parameter controlling this feature is CONFIG_BSD_PROCESS_ACCT.
Out of memory.
The calling process has no permission to enable process accounting.
filename is not a regular file.
Error writing to the filename.
There are no more free file structures or we run out of memory.
adjtime() makes small adjustments to the system time as returned by gettimeofday()(2), advancing or retarding it by the time specified by the timeval delta. If delta is negative, the clock is slowed down by incrementing it more slowly than normal until the correction is complete. If delta is positive, a larger increment than normal is used. The skew used to perform the correction is generally a fraction of one percent. Thus, the time is always a monotonically increasing function. A time correction from an earlier call to adjtime() may not be finished when adjtime() is called again. If olddelta is non-NULL, the structure pointed to will contain, upon return, the number of microseconds still to be corrected from the earlier call.
adjtime() may be used by time servers that synchronize the clocks of computers in a local area network. Such time servers would slow down the clocks of some machines and speed up the clocks of others to bring them to the average network time.
The adjtime() is restricted to the super-user.
On success, 0 is returned.
On error, -1 is returned and
the global variable errno
is set appropriately.
An argument points outside the process's allocated address space.
The process's effective user ID is not that of the super-user.
The asprintf() function shall behave as sprintf(), except that the output string shall be dynamically allocated space of sufficient length to hold the resulting string. The address of this dynamically allocated string shall be stored in the location referenced by ptr.
The bind_textdomain_codeset function can be used to specify the output codeset for message catalogs for domain domainname. The codeset argument shall be a valid codeset name which can be used tor the iconv_open function, or a null pointer. If the codeset argument is the null pointer, then function returns the currently selected codeset for the domain with the name domainname. It shall return a null pointer if no codeset has yet been selected
Each successive call to bind_textdomain_codeset() function overrrides the settings made by the preceding call with the same domainname.
The bind_textdomain_codeset() function shall return a pointer to a string containing the name of the selected codeset. The string shall be allocated internally in the function and shall not be changed or freed by the user.
The bind_textdomain_codeset() function returns a pointer to a string containing the name of the selected codeset. The string is allocated internally in the function and shall not be changed by the user.
The domainname argument is applied to the currently active LC_MESSAGE locale. It is equivalent in syntax and meaning to the domainname argument to textdomain, except that the selection of the domain is valid only for the duration of the call.
The name of the output codeset for the selected domain, or NULL to select the current codeset.
If domainname is the null pointer, or is an empty
string, bind_textdomain_codeset() shall fail, but need not
set errno
.
Returns the currently selected codeset name. It returns a null pointer if no codeset has yet been selected.
If the process has appropriate privilege, the bindresvport() function shall bind a socket to a privileged IP port.
On success, 0 is returned.
On error, -1 is returned and
the global variable errno
is set appropriately.
EPERM
The process did not have appropriate privilege.
EPFNOSUPPORT
Address of sin did not match address family of sd.
The bindtextdomain() shall set the the base directory of the hierarchy containing message catalogs for a given message domain.
The bindtextdomain() function specifies that the domainname message catalog can be found in the dirname directory hierarchy, rather than in the system default locale data base.
If dirname is not
NULL
, the base directory for message catalogs
belonging to domain
domainname shall be set to
dirname.
If dirname is NULL
,
the base directory for message catalogs shall not be altered.
The function shall make copies of the argument strings as needed.
dirname can be an absolute or relative pathname.
Note: Applications that wish to use chdir() should always use absolute pathnames to avoid misadvertently selecting the wrong or non-existant directory.
If domainname is the null pointer, or is an empty
string, bindtextdomain() shall fail, but need not
set errno
.
The bindtextdomain() function shall return a pointer to a string containing the name of the selected directory. The string shall be allocated internally in the function and shall not be changed or freed by the user.
On success, bindtextdomain() shall return a
pointer to a string containing the
directory pathname currently bound to the domain. On failure, a
NULL pointer is returned, and the global variable
errno
may be set to indicate the error.
gettext, dgettext, ngettext, dngettext, dcgettext, dcngettext, textdomain, bind_textdomain_codeset
The cfmakeraw() function shall set the attributes of the termios structure referenced by termios_p as follows:
termios_p->c_iflag &= ~(IGNBRK|BRKINT|PARMRK|ISTRIP |INLCR|IGNCR|ICRNL|IXON); termios_p->c_oflag &= ~OPOST; termios_p->c_lflag &= ~(ECHO|ECHONL|ICANON|ISIG|IEXTEN); termios_p->c_cflag &= ~(CSIZE|PARENB); termios_p->c_cflag |= CS8; |
termios_p shall point to a termios structure that contains the following members:
tcflag_t c_iflag; /* input modes */ tcflag_t c_oflag; /* output modes */ tcflag_t c_cflag; /* control modes */ tcflag_t c_lflag; /* local modes */ cc_t c_cc[NCCS]; /* control chars */ |
cfsetspeed() sets the baud rate values in the termios structure. The effects of the function on the terminal as described below do not become effective, nor are all errors detected, until the tcsetattr() function is called. Certain values for baud rates set in termios and passed to tcsetattr() have special meanings.
Input and output baud rates are found in the
termios structure. The unsigned integer
speed_t
is typdef'd in the include file
termios.h. The value of the integer corresponds
directly to the baud rate being represented; however, the following
symbolic values are defined.
#define B0 0 #define B50 50 #define B75 75 #define B110 110 #define B134 134 #define B150 150 #define B200 200 #define B300 300 #define B600 600 #define B1200 1200 #define B1800 1800 #define B2400 2400 #define B4800 4800 #define B9600 9600 #define B19200 19200 #define B38400 38400 #ifndef _POSIX_SOURCE #define EXTA 19200 #define EXTB 38400 #endif /*_POSIX_SOURCE */ |
cfsetspeed() sets both the input and output baud
rates in the termios structure referenced by
t
to speed.
On success, 0 is returned.
On error, -1 is returned and
the global variable errno
is set appropriately.
The daemon() function shall create a new process, detached from the controlling terminal. If successful, the calling process shall exit and the new process shall continue to execute the application in the background. If nochdir evaluates to true, the current directory shall not be changed. Otherwise, daemon() shall change the current working directory to the root (`/'). If noclose evaluates to true the standard input, standard output, and standard error file descriptors shall not be altered. Otherwise, daemon() shall close the standard input, standard output and standard error file descriptors and reopen them attached to /dev/null.
On error, -1 is returned, and the global
variable errno
is set to any of the errors
specified for the library functions fork() and
setsid().
The dcgettext() function is a domain specified version of gettext().
The dcgettext() function shall lookup the translation in the current locale of the message identified by msgid in the domain specified by domainname and in the locale category specified by category. If domainname is NULL, the current default domain shall be used. The msgid argument shall be a NULL-terminated string to be matched in the catalogue. category shall specify the locale category to be used for retrieving message strings. The category parameter shall be one of LC_CTYPE, LC_COLLATE, LC_MESSAGES, LC_MONETARY, LC_NUMERIC, or LC_TIME. The default domain shall not be changed by a call to dcgettext.
If a translation was found in one of the specified catalogs, it shall be converted to the current locale's codeset and returned. The resulting NULL-terminated string shall be allocated by the dcgettext function, and must not be modified or freed. If no translation was found, or category was invalid, msgid shall be returned.
gettext, dgettext, ngettext, dngettext, dcngettext, textdomain, bindtextdomain, bind_textdomain_codeset
The dcngettext() function is a domain specific version of gettext, capable of returning either a singular or plural form of the message. The dcngettext() function shall lookup the translation in the current locale of the message identified by msgid1 in the domain specified by domainname and in the locale category specified by category. If domainname is NULL, the current default domain shall be used. The msgid1 argument shall be a NULL-terminated string to be matched in the catalogue. category shall specify the locale category to be used for retrieving message strings. The category parameter shall be one of LC_CTYPE, LC_COLLATE, LC_MESSAGES, LC_MONETARY, LC_NUMERIC, or LC_TIME. The default domain shall not be changed by a call to dcgettext(). If n is 1 then the singular version of the message is returned, otherwise one of the plural forms is returned, depending on the value of n and the current locale settings.
If a translation corresponding to the value of n was found in one of the specified catalogs for msgid1, it shall be converted to the current locale's codeset and returned. The resulting NULL-terminated string shall be allocated by the dcngettext() function, and must not be modified or freed. If no translation was found, or category was invalid, msgid1 shall be returned if n has the value 1, otherwise msgid2 shall be returned.
gettext, dgettext, ngettext, dngettext, dcgettext, textdomain, bindtextdomain, bind_textdomain_codeset
dgettext() applies domainname to the currently active LC_MESSAGE locale. This usage is equivalent in syntax and meaning to the textdomain() function's application of domainname, except that the selection of the domain in dgettext() is valid only for the duration of the call.
a NULL-terminated string to be matched in the catalogue with respect to a specific domain and the current locale.
On success of a msgid query, the translated NULL-terminated string is returned. On error, the original msgid is returned. The length of the string returned is undetermined until dgettext() is called.
gettext, dgettext, ngettext, dngettext, dcgettext, dcngettext, textdomain, bindtextdomain, bind_textdomain_codeset
dngettext() shall be equivalent to a call to
dcngettext(domainname, msgid1, msgid2, n, LC_MESSAGES) |
gettext, dgettext, ngettext, dcgettext, dcngettext, textdomain, bindtextdomain, bind_textdomain_codeset
The duplocale() function shall provide a new locale object based on the locale object provided in locale, suitable for use in the newlocale() or uselocale() functions. The new object may be released by calling freelocale().
On success, the duplocale() function shall return
a locale object. Otherwise, it shall return
NULL
, and set errno
to indicate the error.
The err() function
shall display a formatted error message on the standard
error stream.
First, err() shall write
the last component of the program name, a colon
character, and a space character. If fmt is non-NULL, it shall be used as a
format string for the printf()
family of functions, and err() shall
write the formatted message, a
colon character, and a space.
Finally, the error message
string affiliated with the current value of the global variable
errno
shall be
written, followed by a newline character.
The err() function shall not return, the program shall terminate with the exit value of eval.
error() shall print a message to standard error.
error() shall build the message from the following elements in their specified order:
the program name. If the application has provided a function named
error_print_progname(), error()
shall call this to supply the program name;
otherwise, error()
uses the content of the global variable program_name
.
the colon and space characters, then the result of using the printf-style format and the optional arguments.
if errnum is nonzero,
error() shall add the colon and
space characters, then the result of
strerror(errnum
).
a newline.
If exitstatus is nonzero,
error() shall call
exit(exitstatus
).
The errx() function shall display a formatted error message on the standard error stream. The last component of the program name, a colon character, and a space shall be output. If fmt is non-NULL, it shall be used as the format string for the printf() family of functions, and the formatted error message, a colon character, and a space shall be output. The output shall be followed by a newline character.
errx() does not return, but shall exit with the value of eval.
fcntl() is as specified in ISO POSIX (2003), but with differences as listed below.
O_LARGEFILE
According to ISO POSIX (2003),
only an application sets
fcntl() flags, for example
O_LARGEFILE
. However, this specification
also allows an implementation to set the O_LARGEFILE
flag in the case where the programming environment is one of
_POSIX_V6_ILP32_OFFBIG
, _POSIX_V6_LP64_OFF64
, _POSIX_V6_LPBIG_OFFBIG
. See getconf and c99
in ISO POSIX (2003)
for a description of these environments.
Thus, calling fcntl() with the
F_GETFL command may return
O_LARGEFILE
as well as flags explicitly
set by the application in the case that both the implementation and
the application support an off_t of at least 64 bits.
fflush_unlocked() is the same as fflush() except that it need not be thread safe. That is, it may only be invoked in the ways which are legal for getc_unlocked().
fgetwc_unlocked() is the same as fgetwc() except that it need not be thread safe. That is, it may only be invoked in the ways which are legal for getc_unlocked().
flock() applies or removes an advisory lock on the open file fd. Valid operation types are:
Shared lock. More than one process may hold a shared lock for a given file at a given time.
Exclusive lock. Only one process may hold an exclusive lock for a given file at a given time.
Unlock.
Don't block when locking. May be specified (by oring) along with one of the other operations.
A single file may not simultaneously have both shared and exclusive locks.
On success, 0 is returned.
On error, -1 is returned and
the global variable errno
is set appropriately.
The freelocale() function shall free the locale object locale, and release any resources associated with it.
The scanf() family of functions shall behave as described in ISO POSIX (2003), except as noted below.
The
%s,
%S and
%[ conversion specifiers shall accept an
option length modifier
a,
which shall cause a memory buffer to be allocated to hold the string converted.
In such a case, the argument corresponding to the conversion specifier should be
a reference to a pointer value that will receive a pointer to the allocated
buffer. If there is insufficient memory to allocate a buffer, the
function may set
errno
to ENOMEM and a
conversion error results.
Note: This directly conflicts with the ISO C (1999) usage of %a as a conversion specifier for hexadecimal float values. While this conversion specifier should be supported, a format specifier such as "%aseconds" will have a different meaning on an LSB conforming system.
The scanf() family of functions shall behave as described in ISO POSIX (2003), except as noted below.
The
%s,
%S and
%[ conversion specifiers shall accept an
option length modifier
a,
which shall cause a memory buffer to be allocated to hold the string converted.
In such a case, the argument corresponding to the conversion specifier should be
a reference to a pointer value that will receive a pointer to the allocated
buffer. If there is insufficient memory to allocate a buffer, the
function may set
errno
to ENOMEM and a
conversion error results.
Note: This directly conflicts with the ISO C (1999) usage of %a as a conversion specifier for hexadecimal float values. While this conversion specifier should be supported, a format specifier such as "%aseconds" will have a different meaning on an LSB conforming system.
The getgrouplist() function shall fill in the array groups with the supplementary groups for the user specified by user. On entry, ngroups shall refer to an integer containing the maximum number of gid_t members in the groups array. The group group shall also be included. On success, the value referred to by ngroups shall be updated to contain the number of gid_t objects copied.
On success, if there was sufficient room to copy all the
supplementatry group identifiers to the array
identified by groups,
getgrouplist() shall return the number of
gid_t objects copied, and the value referenced by
ngroups shall be updated.
If there was not sufficient room to copy all the supplementary
group identifiers, grouplist() shall return
-1
, and update the value referenced
by ngroups to the number actually copied.
If user does not refer to a valid
user on the system, getgrouplist() shall
return 0
, and set the value referenced by
ngroups to 0
.
getloadavg() returns the number of processes in the system run queue averaged over various periods of time. Up to nelem samples are retrieved and assigned to successive elements of loadavg[]. The system imposes a maximum of 3 samples, representing averages over the last 1, 5, and 15 minutes, respectively.
The getopt() function shall parse command line arguments as described in ISO POSIX (2003), with the following exceptions, where LSB and POSIX specifications vary. LSB systems shall implement the modified behaviors described below.
The getopt() function can process command line arguments referenced by argv in one of three ways:
the order of arguments in argv is altered so that all options (and their arguments) are moved in front of all of the operands. This is the default behavior.
Note: This behavior has undefined results if argv is not modifiable. This is to support historic behavior predating the use of const and ISO C (1999). The function prototype was aligned with ISO POSIX (2003) despite the fact that it modifies argv, and the library maintainers are unwilling to change this.
The arguments in
argv are processed in exactly the order
given, and option processing stops when the first non-option argument
is reached, or when the element of argv is "--". This ordering
can be enforced either by setting the environment variable
POSIXLY_CORRECT
, or by setting the first character
of optstring to '+'.
The order of arguments is not altered, and all arguments are processed. Non-option arguments (operands) are handled as if they were the argument to an option with the value 1 ('\001'). This ordering is selected by setting the first character of optstring to '-';
LSB specifies that:
an element of argv that starts with "-" (and is not exactly "-" or "--") is an option element.
characters of an option element, aside from the initial "-", are option characters.
POSIX specifies that:
applications using getopt() shall obey the following syntax guidelines:
option name is a single alphanumeric character from the portable character set
option is preceded by the '-' delimiter character
options without option-arguments should be accepted when grouped behind one '-' delimiter
each option and option-argument is a separate argument
option-arguments are not optional
all options should precede operands on the command line
the argument "--" is accepted as a delimiter indicating the end of options and the consideration of subsequent arguments, if any, as operands
historical implementations of getopt() support other characters as options as an allowed extension, but applications that use extensions are not maximally portable.
support for multi-byte option characters is only possible when such characters can be represented as type int.
applications that call any utility with a first operand starting with '-' should usually specify "--" to mark the end of the options. Standard utilities that do not support this guideline indicate that fact in the OPTIONS section of the utility description.
LSB specifies that:
if a character is followed by two colons, the option takes an optional argument; if there is text in the current argv element, it is returned in optarg, otherwise optarg is set to 0.
if optstring contains W followed by a semi-colon (;), then -W foo is treated as the long option --foo.
Note: See getopt_long() for a description of long options.
The first character of optstring shall modify the behavior of getopt() as follows:
if the first character is '+', then
REQUIRE_ORDER
processing shall be in
effect (see above)
if the first character is '-', then
RETURN_IN_ORDER
processing shall be in
effect (see above)
if the first character is ':', then
getopt() shall return ':' instead of '?'
to indicate a missing option argument, and shall not print any
diagnostic message to stderr
.
POSIX specifies that:
the -W
option is reserved for implementation extensions.
LSB specifies the following additional getopt() return values:
'\001' is returned
if RETURN_IN_ORDER
argument ordering is in effect,
and the next argument is an operand, not an option. The argument is
available in optarg
.
POSIX specifies the following getopt() return values:
the next option character is returned, if found successfully.
':' is returned if a parameter is missing for
one of the options and the first character of optstring
is
':'.
'?' is returned if an unknown option
character not in optstring
is encountered, or if
getopt() detects a missing argument and the first
character of optstring
is not ':'.
-1 is returned for the end of the option list.
LSB specifies that:
if the variable POSIXLY_CORRECT
is set, option
processing stops as soon as a non-option argument is encountered.
the variable _[PID]_GNU_nonoption_argv_flags_
(where [PID] is the process ID for the
current process), contains a space separated list of arguments that should
not be treated as arguments even though they appear to be so.
Rationale: This was used by bash 2.0 to communicate to GNU libc which arguments resulted from wildcard expansion and so should not be considered as options. This behavior was removed in bash version 2.01, but the support remains in GNU libc.
getopt_long() works like getopt() except that it also accepts long options, started out by two dashes. Long option names may be abbreviated if the abbreviation is unique or is an exact match for some defined option. A long option may take a parameter, of the form --arg=param or --arg param.
longopts is a pointer to the first element of an array of struct option declared in getopt.h as:
struct option { const char *name; int has_arg; int *flag; int val; }; |
The fields in this structure have the following meaning:
name
The name of the long option.
has_arg
One of:
no_argument (or 0) if the option does not take an argument, |
required_argument (or 1) if the option requires an argument, or |
optional_argument (or 2) if the option takes an optional argument. |
flag
specifies how results are returned for a long option.
If flag
is NULL
, then
getopt_long() shall return val
.
(For example, the
calling program may set val to the equivalent short option character.)
Otherwise, getopt_long() returns
0, and flag
shall point to
a variable which shall be set to val
if the option is found, but left unchanged if the option is not found.
val
The value to return, or to load into the variable pointed to by flag.
getopt_long() returns the option character if a short option was found successfully, or ":" if there was a missing parameter for one of the options, or "?" for an unknown option character, or -1 for the end of the option list.
For a long option,
getopt_long() returns val
if flag
is NULL, and 0
otherwise. Error and -1 returns are the
same as for getopt(), plus
"?" for an ambiguous match or an
extraneous parameter.
getopt_long_only() is like getopt_long(), but "-" as well as "--" can indicate a long option. If an option that starts with "-" (not "--") doesn't match a long option, but does match a short option, it is parsed as a short option instead.
Note: The getopt_long_only() function is intended only for supporting certain programs whose command line syntax was designed before the Utility Syntax Guidelines of ISO POSIX (2003) were developed. New programs should generally call getopt_long() instead, which provides the --option syntax for long options, which is preferred by GNU and consistent with ISO POSIX (2003).
getopt_long_only() returns the option character if the option was found successfully, or ":" if there was a missing parameter for one of the options, or "?" for an unknown option character, or -1 for the end of the option list.
getopt_long_only() also returns the option character when a short option is recognized. For a long option, they return val if flag is NULL, and 0 otherwise. Error and -1 returns are the same as for getopt(), plus "?" for an ambiguous match or an extraneous parameter.
The getsockopt() function shall behave as specified in ISO POSIX (2003), with the following extensions.
If the level parameter is
IPPROTO_IP
, the following values shall be supported for
option_name (see RFC 791:Internet Protocol for
further details):
IP_OPTIONS
Get the Internet Protocol options sent with every packet from this socket. The option_value shall point to a memory buffer in which the options shall be placed; on entry option_len shall point to an integer value indicating the maximum size of the memory buffer, in bytes. On successful return, the value referenced by option_len shall be updated to the size of data copied to the buffer. For IPv4, the maximum length of options is 40 bytes.
IP_TTL
Get the current unicast Internet Protocol Time To Live value used when sending packets with this socket. The option_value shall point to a buffer large enough to hold the time to live value (at least 1 byte), and option_len shall point to an integer value holding the maximum size of that buffer. On successful return, the value referenced by option_len shall be updated to contain the number of bytes copied into the buffer, which shall be no larger than the initial value, and option_value shall point to an integer containing the time to live value.
IP_TOS
Get the Internet Protocol type of service indicator used when sending packets with this socket. The option_value shall point to a buffer large enough to hold the type of service indicator (at least 1 byte), and option_len shall point to an integer value holding the maximum size of that buffer. On successful return, the value referenced by option_len shall be updated to contain the number of bytes copied into the buffer, which shall be no larger than the initial value, and option_value shall point to an integer containing the time to live value.
The gettext() function shall search the currently selected message catalogs for a string identified by the string msgid. If a string is located, that string shall be returned.
The gettext() function is equivalent to dcgettext(NULL, msgid, LC_MESSAGES).
If a string is found in the currently selected message catalogs for msgid, then a pointer to that string shall be returned. Otherwise, a pointer to msgid shall be returned.
Applications shall not modify the string returned by gettext().
dgettext, ngettext, dngettext, dcgettext, dcngettext, textdomain, bindtextdomain, bind_textdomain_codeset
Upon successful completion, getutent() shall return a pointer to a utmp structure containing a copy of the requested entry in the user accounting database. Otherwise, a null pointer shall be returned. The return value may point to a static area which is overwritten by a subsequent call to getutent().
The getutent_r() function is a reentrant version of the getutent() function. On entry, buffer should point to a user supplied buffer to which the next entry in the database will be copied, and result should point to a location where the result will be stored.
On success, getutent_r() shall return 0 and set
the location referenced by result to a pointer
to buffer. Otherwise, getutent_r()
shall return -1
and set the location referenced
by result to NULL
.
The glob64() function is a large-file version of the glob() defined in ISO POSIX (2003). It shall search for pathnames matching pattern according to the rules used by the shell, /bin/sh. No tilde expansion or parameter substitution is done; see wordexp().
The results of a glob64()
call are stored in the structure pointed to by pglob,
which is a glob64_t
declared in
glob.h with the following members:
typedef struct { size_t |
Structure members with the same name as corresponding members of a
glob_t
as
defined in ISO POSIX (2003) shall have the same purpose.
Other members are defined as follows:
gl_flags
reserved for internal use
gl_closedir
pointer to a function capable of closing a directory opened by
gl_opendir
gl_readdir64
pointer to a function capable of reading entries in a large directory
gl_opendir
pointer to a function capable of opening a large directory
gl_stat
pointer to a function capable of returning file status for a large file
gl_lstat
pointer to a function capable of returning file status information for a large file or symbolic link
A large file or large directory is one with a size which cannot be represented by a variable of type off_t.
On success, 0 is returned. Other possible returns are:
out of memory
read error
no match found
globfree64() frees the dynamically allocated storage from an earlier call to glob64().
globfree64() is a 64-bit version of globfree().
If the process has appropriate privilege, the initgroups() function shall initialize the Supplementary Group IDs for the current process by reading the group database and using all groups of which user is a member. The additional group group is also added to the list.
On success, 0 is returned.
On error, -1 is returned and
the global variable errno
is set appropriately.
The calling process does not have sufficient privileges.
Insufficient memory to allocate group information structure.
The ioctl() function shall manipulate the underlying device parameters of special files. fildes shall be an open file descriptor referring to a special file. The ioctl() function shall take three parameters; the type and value of the third parameter is dependent on the device and request.
Conforming LSB applications shall not call ioctl() except in situations explicitly stated in this specification.
On success, 0 is returned.
An ioctl() may use the return value as an
output parameter and return a non-negative value on success.
On error, -1 is returned and
the global variable errno
is set appropriately.
fildes is not a valid descriptor.
The third parameter references an inaccessible memory area.
fildes is not associated with a character special device.
The specified request does not apply to the kind of object that fildes references.
request or the third parameter is not valid.
It should be noted that ISO POSIX (2003) contains an interface named ioctl(). The LSB only defines behavior when fildes refers to a socket (see sockio) or terminal device (see ttyio), while ISO POSIX (2003) only defines behavior when fildes refers to a STREAMS device. An implementation may support both behaviors; the LSB does not require any STREAMS support.
Socket ioctl() commands are a subset of the ioctl() calls, which can perform a variety of functions on sockets. sockfd shall be an open file descriptor referring to a socket (see the socket() or accept() functions).
Socket ioctl() commands apply to the underlying network interfaces, and affect the entire system, not just the file descriptor used to issue the ioctl().
The following values for request are accepted:
Get the interface configuration list for the system.
Note: The SIOCGIFCONF interface is superceded by the if_nameindex() family of functions (see ISO POSIX (2003)). A future version of this specification may withdraw this value for request.
ifc_ifcu.ifcu_req
field
to point to an array of ifreq structures, and
set ifc_len
to the size in bytes of this allocated
array. Upon return, ifc_len
will contain the size in bytes of the array which was actually used.
If it is the same as the length upon calling, the caller
should assume that the array was too small and try again with a
larger array.On success, SIOCGIFCONF shall return a nonnegative value.
Rationale: Historical UNIX systems disagree on the meaning of the return value.
Get the interface flags for the indicated interface.
argp shall point to a
ifreq structure. Before calling, the
caller should fill in the ifr_name
field with the interface name, and upon return, the
ifr_ifru.ifru_flags
field is set
with the interface flags.
Get the interface address for the given interface.
argp shall point to a
ifreq structure. Before calling, the
caller should fill in the ifr_name
field with the interface name, and upon return, the
ifr_ifru.ifru_addr
field is set
with the interface address.
Get the interface broadcast address for the given interface.
argp shall point to a
ifreq structure. Before calling, the
caller should fill in the ifr_name
field with the interface name, and upon return, the
ifr_ifru.ifru_broadcast
field is set
with the interface broadcast address.
Get the network mask for the given interface.
argp shall point to a
ifreq structure. Before calling, the
caller should fill in the ifr_name
field with the interface name, and upon return, the
ifr_ifru.ifru_netmask
field is set
with the network mask.
Get the Maximum Transmission Unit (MTU) size for the given interface.
argp shall point to a
ifreq structure. Before calling, the
caller should fill in the ifr_name
field with the interface name, and upon return, the
ifr_ifru.ifru_mtu
field is set
with the MTU.
Get the amount of queued unread data in the receive buffer. argp shall point to an integer where the result is to be placed.
On success, if request is
SIOCGIFCONF, a non-negative integer shall be returned.
If request is not SIOCGIFCONF, on success
0 is returned.
On error, -1 is returned and
the global variable errno
is set appropriately.
sockfd is not a valid descriptor.
argp references an inaccessible memory area.
The specified request does not apply to the kind of object that the descriptor sockfd references.
Either request or argp is invalid.
The operation is only defined on a connected socket, but the socket wasn't connected.
Tty ioctl commands are a subset of the ioctl() calls, which can perform a variety of functions on tty devices. fd shall be an open file descriptor referring to a terminal device.
The following ioctl()s are provided:
Get the size attributes of the tty. argp is a pointer to a winsize structure.
On success, 0 is returned.
On error, -1 is returned and
the global variable errno
is set appropriately.
fd is not a valid descriptor.
argp references an inaccessible memory area.
request and argp are not valid.
kill() is as specified in the ISO POSIX (2003), but with differences as listed below.
If pid is specified as -1, sig shall not be sent to the calling process. Other than this, the rules in the ISO POSIX (2003) apply.
Rationale: This was a deliberate Linus decision after an unpopular experiment in including the calling process in the 2.5.1 kernel. See "What does it mean to signal everybody?", Linux Weekly News, 20 December 2001, http://lwn.net/2001/1220/kernel.php3
The link() function shall behave as specified in ISO POSIX (2003), except with differences as listed below.
ISO POSIX (2003) specifies that pathname resolution shall follow symbolic links during pathname resolution unless the function is required to act on the symbolic link itself, or certain arguments direct that the function act on the symbolic link itself. The link() function in ISO POSIX (2003) contains no such requirement to operate on a symbolic link. However, a conforming LSB implementation need not follow a symbolic link for the path1 argument.
mbsnrtowcs() is like mbsrtowcs(), except that the number of bytes to be converted, starting at src, is limited to nms.
If dest is not a NULL pointer, mbsnrtowcs() converts at most nms bytes from the multibyte string src to a wide-character string starting at dest. At most, len wide characters are written to dest. The state ps is updated.
The conversion is effectively performed by repeatedly calling:
mbrtowc(dest, *src, n, ps) |
The conversion can stop for three reasons:
An invalid multibyte sequence has been encountered. In this case
src is left pointing to the invalid multibyte
sequence, (size_t)(-1) is returned, and errno
is
set to EILSEQ.
The nms limit forces a stop, or len non-L'\0' wide characters have been stored at dest. In this case, src is left pointing to the next multibyte sequence to be converted, and the number of wide characters written to dest is returned.
The multibyte string has been completely converted, including the terminating '\0' (which has the side effect of bringing back ps to the initial state). In this case, src is set to NULL, and the number of wide characters written to dest, excluding the terminating L'\0' character, is returned.
If dest is NULL, len is ignored, and the conversion proceeds as above, except that the converted wide characters are not written out to memory, and that no destination length limit exists.
In both of the above cases, if ps is a NULL pointer, a static anonymous state only known to mbsnrtowcs() is used instead.
The programmer shall ensure that there is room for at least len wide characters at dest.
mbsnrtowcs() returns the number of wide characters
that make up the converted part of the wide character string, not
including the terminating null wide character. If an invalid multibyte
sequence was encountered, (size_t)(-1) is returned, and the global
variable errno
is set to EILSEQ.
The behavior of mbsnrtowcs() depends on the
LC_CTYPE
category of the current locale.
Passing NULL as ps is not multi-thread safe.
memmem() finds the start of the first occurrence of the byte array referenced by needle of length needlelen in the memory area haystack of length haystacklen.
memmem() returns a pointer to the beginning of the byte array, or NULL if the byte array is not found.
Earlier versions of the C library (prior to glibc 2.1) contained a memmem() with various problems, and application developers should treat this function with care.
The memrchr() function shall locate the last occurence of c (converted to an unsigned char) in the initial n bytes (each interpreted as an unsigned char) of the object pointed to by s.
The memrchr() shall return a pointer to the located byte, or a null pointer if the byte does not occur in the object.
The newlocale() function shall initialize
a locale object. If base is
NULL
, then newlocale()
shall first allocate the object; otherwise it shall use the locale
object referenced by base.
The object shall be initialized for the locale named
by locale, and for the categories selected
in category_mask. The
category_mask value is a bitwise
inclusive OR of the required
LC_name_MASK
values, or the value LC_ALL_MASK
.
On success, the newlocale() function shall return
the initialized locale object. Otherwise, it shall return
NULL
, and set errno
to indicate the error.
The newlocale() function shall fail if:
Insufficient memory.
An invalid category_mask was provided, or
the locale was NULL
.
The only portable way to allocate a locale object is to call
newlocale() with a NULL
base. The allocated object may be reinitialized
to a new locale by passing it back to newlocale().
The new object may be released by calling freelocale().
The ngettext() function shall search the currently selected message catalogs for a string matching the singular string msgid1. If a string is located, and if n is 1, that string shall be returned. If n is not 1, a pluralized version (dependant on n) of the string shall be returned.
The ngettext() function is equivalent to dcngettext(NULL, msgid1, msgid2, n, LC_MESSAGES)().
If a string is found in the currently selected message catalogs for
msgid1, then if n is
1
a pointer to the located string shall be returned.
If n is not 1
, a pointer to an
appropriately pluralized version of the string shall be returned.
If no message could be found in the currently selected mesage catalogs,
then if n is 1
,
a pointer to msgid1 shall be returned, otherwise
a pointer to msgid2 shall be returned.
Applications shall not modify the string returned by ngettext().
gettext, dgettext, ngettext, dngettext, dcgettext, dcngettext, textdomain, bindtextdomain, bind_textdomain_codeset
The pmap_getport() function shall
return the port number assigned to a service registered with a
RPC Binding service running on a given target system,
using the protocol described in
RFC 1833: Binding Protocols for ONC RPC Version 2.
The pmap_getport() function shall be called given the
RPC program number program,
the program version version, and transport
protocol protocol. Conforming implementations shall
support both IPPROTO_UDP
and
IPPROTO_TCP
protocols. On entry,
address shall specify the address of the
system on which the portmapper to be
contacted resides. The value of address->sin_port
shall be ignored, and the standard
value for the portmapper port shall always be used.
Note: Security and network restrictions may prevent a conforming application from contacting a remote RPC Binding Service.
On success, the pmap_getport() function shall return
the port number in host byte order of the RPC application
registered with the remote portmapper. On failure,
if either the program was not
registered or the remote portmapper service could not be reached,
the pmap_getport() function
shall return 0. If the remote portmap service could not be reached, the status
is left in the global variable rpc_createerr
.
pmap_set() establishes a mapping between the
triple [program,version,protocol] and
port on the machine's RPC Bind
service. The value of protocol
is most likely IPPROTO_UDP
or IPPROTO_TCP
. Automatically done by svc_register().
As a user interface to the RPC Bind service,
pmap_unset() destroys all mapping between the triple
[prognum,versnum,
*] and ports
on the machine's
RPC Bind service.
The psignal() function shall
display a message on the stderr
stream.
If s is not the null pointer, and does
not point to an empty string (e.g. "\0"), the
message shall consist
of the string s, a colon, a space, and a string
describing the signal number sig; otherwise
psignal() shall display only a message describing
the signal number sig. If
sig is invalid, the message displayed shall
indicate an unknown signal.
The array sys_siglist
holds the signal description
strings indexed by signal number.
The regexec() function shall behave as specified in ISO POSIX (2003), except with differences as listed below.
Certain aspects of regular expression matching are optional; see Internationalization and Regular Expressions.
The scanf() family of functions shall behave as described in ISO POSIX (2003), except as noted below.
The
%s,
%S and
%[ conversion specifiers shall accept an
option length modifier
a,
which shall cause a memory buffer to be allocated to hold the string converted.
In such a case, the argument corresponding to the conversion specifier should be
a reference to a pointer value that will receive a pointer to the allocated
buffer. If there is insufficient memory to allocate a buffer, the
function may set
errno
to ENOMEM and a
conversion error results.
Note: This directly conflicts with the ISO C (1999) usage of %a as a conversion specifier for hexadecimal float values. While this conversion specifier should be supported, a format specifier such as "%aseconds" will have a different meaning on an LSB conforming system.
setbuffer() is an alias for the call to setvbuf(). It works the same, except that the size of the buffer in setbuffer() is up to the caller, rather than being determined by the default BUFSIZ.
If the process has appropriate privilege,
the setgroups() function shall set
the supplementary group IDs for
the current process. list shall reference
an array of size group IDs. A process
may have at most NGROUPS_MAX
supplementary
group IDs.
On successful completion, 0 is returned.
On error, -1 is returned and
the errno
is set to indicate the error.
list has an invalid address.
The process does not have appropriate privileges.
size is greater than NGROUPS_MAX
.
If the process has appropriate privileges, the sethostname() function shall change the host name for the current macine. The name shall point to a null-terminated string of at most len bytes that holds the new hostname.
If the symbol HOST_NAME_MAX
is defined, or if
sysconf(_SC_HOST_NAME_MAX)() returns a value greater
than 0, this value shall represent the maximum length of the new hostname.
Otherwise, if the symbol MAXHOSTLEN
is defined, this value
shall represent the maximum length for the new hostname. If none of these
values are defined, the maximum length shall be the size of the
nodename
field of the
utsname structure.
On success, 0 is returned.
On error, -1 is returned and
the global variable errno
is set appropriately.
len is negative or larger than the maximum allowed size.
the process did not have appropriate privilege.
name is an invalid address.
ISO POSIX (2003) guarantees that:
Maximum length of a host name (not including the terminating null) as returned from the gethostname() function shall be at least 255 bytes.
The glibc C library does not currently define HOST_NAME_MAX
,
and although it provides the name _SC_HOST_NAME_MAX
a call to sysconf() returns -1
and does not alter errno
in this case (indicating that
there is no restriction on the hostname length). However, the glibc
manual idicates that some implementations may have
MAXHOSTNAMELEN
as a means of detecting the maximum length,
while the Linux kernel at release 2.4 and 2.6 stores this hostname
in the utsname structure.
While the glibc manual suggests simply shortening the name until
sethostname() succeeds, the LSB requires
that one of the first four mechanisms works.
Future versions of glibc may provide a more reasonable result from
sysconf(_SC_HOST_NAME_MAX
).
The setsockopt() function shall behave as specified in ISO POSIX (2003), with the following extensions.
If the level parameter is
IPPROTO_IP
, the following values shall be supported for
option_name (see RFC 791:Internet Protocol for
further details):
IP_OPTIONS
Set the Internet Protocol options sent with every packet from this socket. The option_value shall point to a memory buffer containing the options and option_len shall contain the size in bytes of that buffer. For IPv4, the maximum length of options is 40 bytes.
IP_TOS
Set the Type of Service flags to use when sending packets with this socket. The option_value shall point to a value containing the type of service value. The least significant two bits of the value shall contain the new Type of Service indicator. Use of other bits in the value is unspecified. The option_len parameter shall hold the size, in bytes, of the buffer referred to by option_value.
IP_TTL
Set the current unicast Internet Protocol Time To Live value used when sending packets with this socket. The option_value shall point to a value containing the time to live value, which shall be between 1 and 255. The option_len parameter shall hold the size, in bytes, of the buffer referred to by option_value.
The setutent() function shall reset the user accounting database such that the next call to getutent() shall be return the first record in the database. It is recommended to call it before any of the other functions that operate on the user accounting databases (e.g. getutent())
The sigandset() shall combine the two signal sets referenced by left and right, using a logical AND operation, and shall place the result in the location referenced by set, The resulting signal set shall contain only signals that are in both the set referenced by left and the set referenced by right.
On success, sigandset() shall return 0. Otherise, sigandset() shall return
-1 and set errno
to indicate
the error.
The sigisemptyset() function shall return
a positive non-zero value if the signal set referenced by
set is empty, or zero if this set is empty.
On error, sigisemptyset() shall return -1 and set errno
to indicate the error.
The sigorset() shall combine the two signal sets referenced by left and right, using a logical OR operation, and shall place the result in the location referenced by set, The resulting signal set shall contain only signals that are in either the set referenced by left or the set referenced by right.
On success, sigorset() shall return 0. Otherise, sigorset() shall return
-1 and set errno
to indicate
the error.
The sigreturn() function is used by the system to cleanup after a signal handler has returned. This function is not in the source standard; it is only in the binary standard.
The scanf() family of functions shall behave as described in ISO POSIX (2003), except as noted below.
The
%s,
%S and
%[ conversion specifiers shall accept an
option length modifier
a,
which shall cause a memory buffer to be allocated to hold the string converted.
In such a case, the argument corresponding to the conversion specifier should be
a reference to a pointer value that will receive a pointer to the allocated
buffer. If there is insufficient memory to allocate a buffer, the
function may set
errno
to ENOMEM and a
conversion error results.
Note: This directly conflicts with the ISO C (1999) usage of %a as a conversion specifier for hexadecimal float values. While this conversion specifier should be supported, a format specifier such as "%aseconds" will have a different meaning on an LSB conforming system.
If the process has appropriate privilege, the stime() function shall set the system's idea of the time and date. Time, referenced by t, is measured in seconds from the epoch (defined in ISO POSIX (2003) as 00:00:00 UTC January 1, 1970).
On success, stime() shall return
0.
Otherwise, stime() shall return
-1 and
errno
shall be set to indicate the error.
The stpcpy() function shall copy the string pointed to by src (including the terminating '\0' character) to the array pointed to by dest. The strings may not overlap, and the destination string dest shall be large enough to receive the copy.
stpcpy() returns a pointer to the end of the string dest (that is, the address of the terminating '\0' character) rather than the beginning.
This program uses stpcpy() to concatenate foo and bar to produce foobar, which it then prints.
#include <string.h> int main (void) { char buffer[256]; char *to = buffer; to = stpcpy (to, "foo"); to = stpcpy (to, "bar"); printf ("%s\n", buffer); } |
The stpncpy() function shall copy at most n characters from the string pointed to by src, including the terminating \0 character, to the array pointed to by dest. Exactly n characters are written at dest. If the length strlen()(src) is smaller than n, the remaining characters in dest are filled with \0 characters. If the length strlen()(src) is greater than or equal to n, dest will not be \0 terminated.
The strings may not overlap.
The programmer shall ensure that there is room for at least n characters at dest.
The stpncpy() function shall return a pointer to the terminating NULL in dest, or, if dest is not NULL-terminated, dest + n.
The strcasestr() shall behave as strstr(), except that it shall ignore the case of both strings. The strcasestr() function shall be locale aware; that is strcasestr() shall behave as if both strings had been converted to lower case in the current locale before the comparison is performed.
Upon successful completion, strcasestr() shall return a pointer to the located string or a null pointer if the string is not found. If s2 points to a string with zero length, the function shall return s1.
The strerror_r() shall behave as specified in ISO POSIX (2003), except as described below.
On success, strerror_r() shall return a pointer
to the generated message string (determined by the setting of the
LC_MESSAGES
category in the current locale).
Otherwise, strerror_r() shall return the string
corresponding to "Unknown error".
The strndup() function shall return a malloc()'d copy of at most n bytes of string. The resultant string shall be terminated even if no NULL terminator appears before string+n.
On success, strndup() shall return a pointer to a newly
allocated block of memory containing a copy of at most n
bytes of string. Otherwise, strndup()
shall return NULL and set errno
to indicate the error.
strnlen() returns the number of characters in the string s, not including the terminating \0 character, but at most maxlen. In doing this, strnlen() looks only at the first maxlen characters at s and never beyond s + maxlen.
strnlen() returns strlen(s), if that is less than maxlen, or maxlen if there is no \0 character among the first maxlen characters pointed to by s.
The strptime() shall behave as specified in the ISO POSIX (2003) with differences as listed below.
The ISO POSIX (2003) specifies fields for which "leading zeros are
permitted but not required"; however, applications shall not expect to
be able to supply more leading zeroes for these fields than would be
implied by the range of the field. Implementations may choose to
either match an input with excess leading zeroes, or treat this as a
non-matching input. For example, %j
has a range of
001 to 366, so 0,
00, 000, 001,
and 045 are acceptable inputs, but inputs such as
0000, 0366 and the like are not.
glibc developers consider it appropriate behavior to forbid excess leading zeroes. When trying to parse a given input against several format strings, forbidding excess leading zeroes could be helpful. For example, if one matches 0011-12-26 against %m-%d-%Y and then against %Y-%m-%d, it seems useful for the first match to fail, as it would be perverse to parse that date as November 12, year 26. The second pattern parses it as December 26, year 11.
The ISO POSIX (2003) is not explicit that an unlimited number of leading zeroes are required, although it may imply this. The LSB explicitly allows implementations to have either behavior. Future versions of this standard may require implementations to forbid excess leading zeroes.
An Interpretation Request is currently pending against ISO POSIX (2003) for this matter.
The strsep() function shall find the first token in the string referenced by the pointer stringp, using the characters in delim as delimiters.
If stringp is NULL, strsep() shall return NULL and do nothing else.
If stringp is non-NULL, strsep() shall find the first token in the string referenced by stringp, where tokens are delimited by characters in the string delim. This token shall be terminated with a \0 character by overwriting the delimiter, and stringp shall be updated to point past the token. In case no delimiter was found, the token is taken to be the entire string referenced by stringp, and the location referenced by stringp is made NULL.
The strsep() function was introduced as a replacement for strtok(), since the latter cannot handle empty fields. However, strtok() conforms to ISO C (1999) and to ISO POSIX (2003) and hence is more portable.
The strsignal() function shall return a pointer to a string describing the signal number sig. The string can only be used until the next call to strsignal().
The array sys_siglist
holds the signal description
strings indexed by signal number. This array should not be accessed
directly by applications.
If sig is a valid signal number, strsignal() shall return a pointer to the appropriate description string. Otherwise, strsignal() shall return either a pointer to the string "unknown signal", or a null pointer.
Although the function is not declared as returning a pointer to a constant character string, applications shall not modify the returned string.
strtoq() converts the string nptr to a quadt value. The conversion is done according to the given base, which shall be between 2 and 36 inclusive, or be the special value 0.
nptr may begin with an arbitrary amount of white space (as determined by isspace()(3)), followed by a single optional + or - sign character. If base is 0 or 16, the string may then include a 0x prefix, and the number will be read in base 16; otherwise, a 0 base is taken as 10 (decimal), unless the next character is 0, in which case it is taken as 8 (octal).
The remainder of the string is converted to a long value in the obvious manner, stopping at the first character which is not a valid digit in the given base. (In bases above 10, the letter A in either upper or lower case represents 10, B represents 11, and so forth, with Z representing 35.)
strtoq() returns the result of the conversion,
unless the value would underflow or overflow. If an underflow occurs,
strtoq() returns QUAD_MIN
. If
an overflow occurs, strtoq() returns
QUAD_MAX
. In both cases, the global variable
errno
is set to ERANGE.
strtouq() converts the string nptr to an unsigned long long value. The conversion is done according to the given base, which shall be between 2 and 36 inclusive, or be the special value 0.
nptr may begin with an arbitrary amount of white space (as determined by isspace()(3)), followed by a single optional + or - sign character. If base is 0 or 16, the string may then include a 0x prefix, and the number will be read in base 16; otherwise, a 0 base is taken as 10 (decimal), unless the next character is 0, in which case it is taken as 8 (octal).
The remainder of the string is converted to an unsigned long value in the obvious manner, stopping at the end of the string or at the first character that does not produce a valid digit in the given base. (In bases above 10, the letter A in either upper or lower case represents 10, B represents 11, and so forth, with Z representing 35.)
On success, strtouq() returns either the result of
the conversion or, if there was a leading minus sign, the negation of
the result of the conversion, unless the original (non-negated) value
would overflow. In the case of an overflow the function returns
UQUAD_MAX
and the global variable errno
is set to ERANGE.
The svc_register() function shall associate
the program identified by prognum at version
versnum
with the service dispatch procedure, dispatch.
If protocol is zero, the service is not registered with the
portmap
service. If protocol is
non-zero, then a mapping of the triple [prognum,
versnum, protocol] to
xprt->xp_port
is established with the local
portmap
service. The
procedure dispatch has the following form:
The svc_run() function shall wait for RPC requests to arrive, read and unpack each request, and dispatch it to the appropriate registered handler. Under normal conditions, svc_run() shall not return; it shall only return if serious errors occur that prevent further processing.
Called by an RPC service's dispatch routine to send the results of a remote procedure call. The parameter xprt is the request's associated transport handle; outproc is the XDR routine which is used to encode the results; and out is the address of the results. This routine returns one if it succeeds, zero other-wise.
svctcp_create() cretes a TCP/IP-based RPC service transport,
to which it returns a pointer. The transport is associated with the socket
sock, which may be RPC_ANYSOCK
, in
which case a new socket is created. If the socket is not bound to a local TCP
port, then this routine binds it to an arbitrary port. Upon completion,
xprt->xp_sock
is the transport's socket descriptor,
and xprt->xp_port
is the transport's port number. Since
TCP-based RPC uses buffered I/O, users may specify the size of buffers;
values of zero choose suitable defaults.
svctcp_create() returns NULL if it fails, or a pointer to the RPC service transport otherwise.
The scanf() family of functions shall behave as described in ISO POSIX (2003), except as noted below.
The
%s,
%S and
%[ conversion specifiers shall accept an
option length modifier
a,
which shall cause a memory buffer to be allocated to hold the string converted.
In such a case, the argument corresponding to the conversion specifier should be
a reference to a pointer value that will receive a pointer to the allocated
buffer. If there is insufficient memory to allocate a buffer, the
function may set
errno
to ENOMEM and a
conversion error results.
Note: This directly conflicts with the ISO C (1999) usage of %a as a conversion specifier for hexadecimal float values. While this conversion specifier should be supported, a format specifier such as "%aseconds" will have a different meaning on an LSB conforming system.
The fact that system() ignores interrupts is often not what a program wants. ISO POSIX (2003) describes some of the consequences; an additional consequence is that a program calling system() from a loop cannot be reliably interrupted. Many programs will want to use the exec() family of functions instead.
Do not use system() from a program with
suid
or sgid
privileges,
because unexpected values for some environment variables might be used
to subvert system integrity. Use the exec()
family of functions instead, but not execlp()
or execvp(). system() will
not, in fact, work properly from programs with suid
or sgid
privileges on systems on which
/bin/sh is bash version 2,
since bash 2 drops privileges on startup.
(Debian uses a modified bash which does not do
this when invoked as sh.)
The check for the availability of /bin/sh is not actually performed; it is always assumed to be available. ISO C (1999) specifies the check, but ISO POSIX (2003) specifies that the return shall always be nonzero, since a system without the shell is not conforming, and it is this that is implemented.
It is possible for the shell command to return
127, so that code is not a sure
indication that the execve() call failed; check
the global variable errno
to make sure.
The textdomain() function shall set the current default message domain to domainname. Subsequent calls to gettext() and ngettext() use the default message domain.
If domainname is NULL, the default message domain shall not be altered.
If domainname is "", textdomain() shall reset the default domain to the system default of "messages".
On success, textdomain() shall return the currently
selected domain. Otherwise, a null pointer shall be returned, and
errno
set to indicate the error.
unlink() is as specified in ISO POSIX (2003), but with differences as listed below.
See also Additional behaviors: unlink/link on directory.
If path specifies a directory, the implementation may return EISDIR instead of EPERM as specified by ISO POSIX (2003).
Rationale: The Linux kernel has deliberately chosen EISDIR for this case and does not expect to change (Al Viro, personal communication).
The uselocale() function shall set the locale for the calling thread to the locale specified by newloc.
If newloc is the value
LC_GLOBAL_LOCALE
,
the thread's locale shall be set to the process current
global locale, as set
by setlocale().
If newloc is NULL
, the
thread's locale is not altered.
The uselocale() function shall return the previous locale,
or LC_GLOBAL_LOCALE
if the thread local locale
has not been previously set.
The utmpname() function shall cause the user accounting database used by the getutent(), getutent_r(), getutxent(), getutxid(), getutxline(), and pututxline() functions to be that named by dbname, instead of the system default database. See Section 4.2 for further information.
Note: The LSB does not specify the format of the user accounting database, nor the names of the file or files that may contain it.
The vasprintf() function shall write formatted output to a dynamically allocated string, and store the address of that string in the location referenced by ptr. It shall behave as asprintf(), except that instead of being called with a variable number of arguments, it is called with an argument list as defined by <stdarg.h>.
The vdprintf() shall behave as vfprintf(), except that the first argument is a file descriptor rather than a STDIO stream.
The verrx() shall behave as errx() except that instead of being called with a variable number of arguments, it is called with an argument list as defined by <stdarg.h>.
verrx() does not return, but exits with the value of eval.
The scanf() family of functions shall behave as described in ISO POSIX (2003), except as noted below.
The
%s,
%S and
%[ conversion specifiers shall accept an
option length modifier
a,
which shall cause a memory buffer to be allocated to hold the string converted.
In such a case, the argument corresponding to the conversion specifier should be
a reference to a pointer value that will receive a pointer to the allocated
buffer. If there is insufficient memory to allocate a buffer, the
function may set
errno
to ENOMEM and a
conversion error results.
Note: This directly conflicts with the ISO C (1999) usage of %a as a conversion specifier for hexadecimal float values. While this conversion specifier should be supported, a format specifier such as "%aseconds" will have a different meaning on an LSB conforming system.
The scanf() family of functions shall behave as described in ISO POSIX (2003), except as noted below.
The
%s,
%S and
%[ conversion specifiers shall accept an
option length modifier
a,
which shall cause a memory buffer to be allocated to hold the string converted.
In such a case, the argument corresponding to the conversion specifier should be
a reference to a pointer value that will receive a pointer to the allocated
buffer. If there is insufficient memory to allocate a buffer, the
function may set
errno
to ENOMEM and a
conversion error results.
Note: This directly conflicts with the ISO C (1999) usage of %a as a conversion specifier for hexadecimal float values. While this conversion specifier should be supported, a format specifier such as "%aseconds" will have a different meaning on an LSB conforming system.
The scanf() family of functions shall behave as described in ISO POSIX (2003), except as noted below.
The
%s,
%S and
%[ conversion specifiers shall accept an
option length modifier
a,
which shall cause a memory buffer to be allocated to hold the string converted.
In such a case, the argument corresponding to the conversion specifier should be
a reference to a pointer value that will receive a pointer to the allocated
buffer. If there is insufficient memory to allocate a buffer, the
function may set
errno
to ENOMEM and a
conversion error results.
Note: This directly conflicts with the ISO C (1999) usage of %a as a conversion specifier for hexadecimal float values. While this conversion specifier should be supported, a format specifier such as "%aseconds" will have a different meaning on an LSB conforming system.
The scanf() family of functions shall behave as described in ISO POSIX (2003), except as noted below.
The
%s,
%S and
%[ conversion specifiers shall accept an
option length modifier
a,
which shall cause a memory buffer to be allocated to hold the string converted.
In such a case, the argument corresponding to the conversion specifier should be
a reference to a pointer value that will receive a pointer to the allocated
buffer. If there is insufficient memory to allocate a buffer, the
function may set
errno
to ENOMEM and a
conversion error results.
Note: This directly conflicts with the ISO C (1999) usage of %a as a conversion specifier for hexadecimal float values. While this conversion specifier should be supported, a format specifier such as "%aseconds" will have a different meaning on an LSB conforming system.
The scanf() family of functions shall behave as described in ISO POSIX (2003), except as noted below.
The
%s,
%S and
%[ conversion specifiers shall accept an
option length modifier
a,
which shall cause a memory buffer to be allocated to hold the string converted.
In such a case, the argument corresponding to the conversion specifier should be
a reference to a pointer value that will receive a pointer to the allocated
buffer. If there is insufficient memory to allocate a buffer, the
function may set
errno
to ENOMEM and a
conversion error results.
Note: This directly conflicts with the ISO C (1999) usage of %a as a conversion specifier for hexadecimal float values. While this conversion specifier should be supported, a format specifier such as "%aseconds" will have a different meaning on an LSB conforming system.
The vsyslog() function is identical to syslog() as specified in ISO POSIX (2003), except that arglist (as defined by stdarg.h) replaces the variable number of arguments.
The scanf() family of functions shall behave as described in ISO POSIX (2003), except as noted below.
The
%s,
%S and
%[ conversion specifiers shall accept an
option length modifier
a,
which shall cause a memory buffer to be allocated to hold the string converted.
In such a case, the argument corresponding to the conversion specifier should be
a reference to a pointer value that will receive a pointer to the allocated
buffer. If there is insufficient memory to allocate a buffer, the
function may set
errno
to ENOMEM and a
conversion error results.
Note: This directly conflicts with the ISO C (1999) usage of %a as a conversion specifier for hexadecimal float values. While this conversion specifier should be supported, a format specifier such as "%aseconds" will have a different meaning on an LSB conforming system.
wait4() suspends execution of the current process until a child (as specified by pid) has exited, or until a signal is delivered whose action is to terminate the current process or to call a signal handling function. If a child (as requested by pid) has already exited by the time of the call (a so-called "zombie" process), the function returns immediately. Any system resources used by the child are freed.
The value of pid can be one of:
wait for any child process whose process group ID is equal to the absolute value of pid.
wait for any child process; this is equivalent to calling wait3().
wait for any child process whose process group ID is equal to that of the calling process.
wait for the child whose process ID is equal to the value of pid.
The value of options is a bitwise or of zero or more of the following constants:
return immediately if no child is there to be waited for.
return for children that are stopped, and whose status has not been reported.
If status is not NULL, wait4() stores status information in the location status. This status can be evaluated with the following macros:
Note: These macros take the
status
value (an int) as an argument -- not a pointer to the value!
is nonzero if the child exited normally.
evaluates to the least significant eight bits of the return code of the child that terminated, which may have been set as the argument to a call to exit() or as the argument for a return statement in the main program. This macro can only be evaluated if WIFEXITED() returned nonzero.
returns true if the child process exited because of a signal that was not caught.
returns the number of the signal that caused the child process to terminate. This macro can only be evaluated if WIFSIGNALED() returned nonzero.
returns true if the child process that caused the return is currently stopped; this is only possible if the call was done using WUNTRACED().
returns the number of the signal that caused the child to stop. This macro can only be evaluated if WIFSTOPPED() returned nonzero.
If rusage is not NULL, the struct rusage (as defined in sys/resource.h) that it points to will be filled with accounting information. (See getrusage()(2) for details.
On success, the process ID of the child that exited is returned. On
error, -1 is returned (in particular, when
no unwaited-for child processes of the specified kind exist), or
0 if WNOHANG() was used
and no child was available yet. In the latter two cases, the global
variable errno
is set appropriately.
No unwaited-for child process as specified does exist.
A WNOHANG() was not set and an unblocked signal or
a SIGCHILD
was caught. This error is returned by
the system call. The library interface is not allowed to return
ERESTARTSYS, but will return
EINTR.
The warn() function
shall display a formatted error message on the standard
error stream.
The output shall consist of the last component of the program name, a colon
character, and a space character. If fmt is non-NULL, it shall be used as a
format string for the printf()
family of functions, and the formatted message, a
colon character, and a space are written to stderr
.
Finally, the error message
string affiliated with the current value of the global variable
errno
shall be
written to stderr
, followed by a newline character.
The warnx() function shall display a formatted error message on the standard error stream. The last component of the program name, a colon character, and a space shall be output. If fmt is non-NULL, it shall be used as the format string for the printf() family of functions, and the formatted error message, a colon character, and a space shall be output. The output shall be followed by a newline character.
wcpcpy() is the wide-character equivalent of stpcpy(). It copies the wide character string src, including the terminating L'\0' character, to the array dest.
The strings may not overlap.
The programmer shall ensure that there is room for at least wcslen()(src)+1 wide characters at dest.
wcpcpy() returns a pointer to the end of the wide-character string dest, that is, a pointer to the terminating L'\0' character.
wcpncpy() is the wide-character equivalent of stpncpy(). It copies at most n wide characters from the wide-character string src, including the terminating L'\0' character, to the array dest. Exactly n wide characters are written at dest. If the length wcslen()(src) is smaller than n, the remaining wide characters in the array dest are filled with L'\0' characters. If the length wcslen()(src) is greater than or equal to n, the string dest will not be L'\0' terminated.
The strings may not overlap.
The programmer shall ensure that there is room for at least n wide characters at dest.
wcpncpy() returns a pointer to the wide character one past the last non-null wide character written.
wcscasecmp() is the wide-character equivalent of strcasecmp(). It compares the wide-character string s1 and the wide-character string s2, ignoring case differences (towupper, towlower).
wcscasecmp() returns 0 if the wide-character strings s1 and s2 are equal except for case distinctions. It returns a positive integer if s1 is greater than s2, ignoring case. It returns a negative integer if s1 is smaller than s2, ignoring case.
wcsdup() is the wide-character equivalent of strdup(). It allocates and returns a new wide-character string whose initial contents is a duplicate of the wide-character string s.
Memory for the new wide-character string is obtained with malloc(), and can be freed with free().
wcsdup() returns a pointer to the new wide-character string, or NULL if sufficient memory was not available.
wcsncasecmp() is the wide-character equivalent of strncasecmp(). It compares the wide-character string s1 and the wide-character string s2, but at most n wide characters from each string, ignoring case differences (towupper, towlower).
wcscasecmp() returns 0 if the wide-character strings s1 and s2, truncated to at most length n, are equal except for case distinctions. It returns a positive integer if truncated s1 is greater than truncated s2, ignoring case. It returns a negative integer if truncated s1 is smaller than truncated s2, ignoring case.
wcsnlen() is the wide-character equivalent of strnlen(). It returns the number of wide-characters in the string s, not including the terminating L'\0' character, but at most maxlen. In doing this, wcsnlen() looks only at the first maxlen wide-characters at s and never beyond s + maxlen.
wcsnlen() returns wcslen()(s) if that is less than maxlen, or maxlen if there is no L'\0' character among the first maxlen wide characters pointed to by s.
wcsnrtombs() is like wcsrtombs(), except that the number of wide characters to be converted, starting at src, is limited to nwc.
If dest is not a NULL pointer, wcsnrtombs() converts at most nwc wide characters from the wide-character string src to a multibyte string starting at dest. At most len bytes are written to dest. The state ps is updated.
The conversion is effectively performed by repeatedly calling:
wcrtomb(dest, *src, ps) |
The conversion can stop for three reasons:
A wide character has been encountered that cannot be represented as a
multibyte sequence (according to the current locale). In this case
src is left pointing to the invalid wide character,
(size_t)(-1) is returned, and errno
is
set to EILSEQ.
nws wide characters have been converted without encountering a L'\0', or the length limit forces a stop. In this case, src is left pointing to the next wide character to be converted, and the number bytes written to dest is returned.
The wide-character string has been completely converted, including the terminating L'\0' (which has the side effect of bringing back ps to the initial state). In this case, src is set to NULL, and the number of bytes written to dest, excluding the terminating L'\0' byte, is returned.
If dest is NULL, len is ignored, and the conversion proceeds as above, except that the converted bytes are not written out to memory, and that no destination length limit exists.
In both of the above cases, if ps is a NULL pointer, a static anonymous state only known to wcsnrtombs() is used instead.
The programmer shall ensure that there is room for at least len bytes at dest.
wcsnrtombs() returns the number of bytes that
make up the converted part of multibyte sequence, not including
the terminating L'\0' byte. If a wide character was
encountered which could not be converted, (size_t)(-1) is returned,
and the global variable errno
set to
EILSEQ.
The behavior of wcsnrtombs() depends on the
LC_CTYPE
category of the current locale.
Passing NULL as ps is not multi-thread safe.
The wcstoq() function shall convert the initial portion of the wide string nptr to long long int representation. It is identical to wcstoll().
The wcstouq() function shall convert the initial portion of the wide string nptr to unsigned long long int representation. It is identical to wcstoull().
The scanf() family of functions shall behave as described in ISO POSIX (2003), except as noted below.
The
%s,
%S and
%[ conversion specifiers shall accept an
option length modifier
a,
which shall cause a memory buffer to be allocated to hold the string converted.
In such a case, the argument corresponding to the conversion specifier should be
a reference to a pointer value that will receive a pointer to the allocated
buffer. If there is insufficient memory to allocate a buffer, the
function may set
errno
to ENOMEM and a
conversion error results.
Note: This directly conflicts with the ISO C (1999) usage of %a as a conversion specifier for hexadecimal float values. While this conversion specifier should be supported, a format specifier such as "%aseconds" will have a different meaning on an LSB conforming system.
Table 1-24 defines the library name and shared object name for the libm library
The behavior of the interfaces in this library is specified by the following specifications:
ISO C (1999) |
this specification |
SUSv2 |
ISO POSIX (2003) |
An LSB conforming implementation shall provide the generic functions for Math specified in Table 1-25, with the full mandatory functionality as described in the referenced underlying specification.
Table 1-25. libm - Math Function Interfaces
__finite [1] | ccosl [2] | exp [2] | j1l [1] | powf [2] |
__finitef [1] | ceil [2] | exp2 [2] | jn [2] | powl [2] |
__finitel [1] | ceilf [2] | exp2f [2] | jnf [1] | remainder [2] |
__fpclassify [3] | ceill [2] | expf [2] | jnl [1] | remainderf [2] |
__fpclassifyf [3] | cexp [2] | expl [2] | ldexp [2] | remainderl [2] |
__signbit [1] | cexpf [2] | expm1 [2] | ldexpf [2] | remquo [2] |
__signbitf [1] | cexpl [2] | expm1f [2] | ldexpl [2] | remquof [2] |
acos [2] | cimag [2] | expm1l [2] | lgamma [2] | remquol [2] |
acosf [2] | cimagf [2] | fabs [2] | lgamma_r [1] | rint [2] |
acosh [2] | cimagl [2] | fabsf [2] | lgammaf [2] | rintf [2] |
acoshf [2] | clog [2] | fabsl [2] | lgammaf_r [1] | rintl [2] |
acoshl [2] | clog10 [1] | fdim [2] | lgammal [2] | round [2] |
acosl [2] | clog10f [1] | fdimf [2] | lgammal_r [1] | roundf [2] |
asin [2] | clog10l [1] | fdiml [2] | llrint [2] | roundl [2] |
asinf [2] | clogf [2] | feclearexcept [2] | llrintf [2] | scalb [2] |
asinh [2] | clogl [2] | fegetenv [2] | llrintl [2] | scalbf [1] |
asinhf [2] | conj [2] | fegetexceptflag [2] | llround [2] | scalbl [1] |
asinhl [2] | conjf [2] | fegetround [2] | llroundf [2] | scalbln [2] |
asinl [2] | conjl [2] | feholdexcept [2] | llroundl [2] | scalblnf [2] |
atan [2] | copysign [2] | feraiseexcept [2] | log [2] | scalblnl [2] |
atan2 [2] | copysignf [2] | fesetenv [2] | log10 [2] | scalbn [2] |
atan2f [2] | copysignl [2] | fesetexceptflag [2] | log10f [2] | scalbnf [2] |
atan2l [2] | cos [2] | fesetround [2] | log10l [2] | scalbnl [2] |
atanf [2] | cosf [2] | fetestexcept [2] | log1p [2] | significand [1] |
atanh [2] | cosh [2] | feupdateenv [2] | log1pf [2] | significandf [1] |
atanhf [2] | coshf [2] | finite [4] | log1pl [2] | significandl [1] |
atanhl [2] | coshl [2] | finitef [1] | log2 [2] | sin [2] |
atanl [2] | cosl [2] | finitel [1] | log2f [2] | sincos [1] |
cabs [2] | cpow [2] | floor [2] | log2l [2] | sincosf [1] |
cabsf [2] | cpowf [2] | floorf [2] | logb [2] | sincosl [1] |
cabsl [2] | cpowl [2] | floorl [2] | logbf [2] | sinf [2] |
cacos [2] | cproj [2] | fma [2] | logbl [2] | sinh [2] |
cacosf [2] | cprojf [2] | fmaf [2] | logf [2] | sinhf [2] |
cacosh [2] | cprojl [2] | fmal [2] | logl [2] | sinhl [2] |
cacoshf [2] | creal [2] | fmax [2] | lrint [2] | sinl [2] |
cacoshl [2] | crealf [2] | fmaxf [2] | lrintf [2] | sqrt [2] |
cacosl [2] | creall [2] | fmaxl [2] | lrintl [2] | sqrtf [2] |
carg [2] | csin [2] | fmin [2] | lround [2] | sqrtl [2] |
cargf [2] | csinf [2] | fminf [2] | lroundf [2] | tan [2] |
cargl [2] | csinh [2] | fminl [2] | lroundl [2] | tanf [2] |
casin [2] | csinhf [2] | fmod [2] | matherr [1] | tanh [2] |
casinf [2] | csinhl [2] | fmodf [2] | modf [2] | tanhf [2] |
casinh [2] | csinl [2] | fmodl [2] | modff [2] | tanhl [2] |
casinhf [2] | csqrt [2] | frexp [2] | modfl [2] | tanl [2] |
casinhl [2] | csqrtf [2] | frexpf [2] | nan [2] | tgamma [2] |
casinl [2] | csqrtl [2] | frexpl [2] | nanf [2] | tgammaf [2] |
catan [2] | ctan [2] | gamma [4] | nanl [2] | tgammal [2] |
catanf [2] | ctanf [2] | gammaf [1] | nearbyint [2] | trunc [2] |
catanh [2] | ctanh [2] | gammal [1] | nearbyintf [2] | truncf [2] |
catanhf [2] | ctanhf [2] | hypot [2] | nearbyintl [2] | truncl [2] |
catanhl [2] | ctanhl [2] | hypotf [2] | nextafter [2] | y0 [2] |
catanl [2] | ctanl [2] | hypotl [2] | nextafterf [2] | y0f [1] |
cbrt [2] | dremf [1] | ilogb [2] | nextafterl [2] | y0l [1] |
cbrtf [2] | dreml [1] | ilogbf [2] | nexttoward [2] | y1 [2] |
cbrtl [2] | erf [2] | ilogbl [2] | nexttowardf [2] | y1f [1] |
ccos [2] | erfc [2] | j0 [2] | nexttowardl [2] | y1l [1] |
ccosf [2] | erfcf [2] | j0f [1] | pow [2] | yn [2] |
ccosh [2] | erfcl [2] | j0l [1] | pow10 [1] | ynf [1] |
ccoshf [2] | erff [2] | j1 [2] | pow10f [1] | ynl [1] |
ccoshl [2] | erfl [2] | j1f [1] | pow10l [1] |
Referenced Specification(s)
[1]. ISO C (1999)
[2]. ISO POSIX (2003)
[3]. this specification
[4]. SUSv2
An LSB conforming implementation shall provide the generic data interfaces for Math specified in Table 1-26, with the full mandatory functionality as described in the referenced underlying specification.
Referenced Specification(s)
[1]. ISO POSIX (2003)
This section defines global identifiers and their values that are associated with interfaces contained in libm. These definitions are organized into groups that correspond to system headers. This convention is used as a convenience for the reader, and does not imply the existence of these headers, or their content.
These definitions are intended to supplement those provided in the referenced underlying specifications.
This specification uses ISO/IEC 9899 C Language as the reference programming language, and data definitions are specified in ISO C format. The C language is used here as a convenient notation. Using a C language description of these data objects does not preclude their use by other programming languages.
#define DOMAIN 1 #define SING 2 struct exception { int type; char *name; double arg1; double arg2; double retval; } ; #define FP_NAN 0 #define FP_INFINITE 1 #define FP_ZERO 2 #define FP_SUBNORMAL 3 #define FP_NORMAL 4 #define isnormal(x) (fpclassify (x) == FP_NORMAL) #define isfinite(x) (sizeof (x) == sizeof (float) ? __finitef (x) : sizeof (x) == sizeof (double)? __finite (x) : __finitel (x)) #define isinf(x) (sizeof (x) == sizeof (float) ? __isinff (x): sizeof (x) == sizeof (double) ? __isinf (x) : __isinfl (x)) #define isnan(x) (sizeof (x) == sizeof (float) ? __isnanf (x) : sizeof (x) == sizeof (double) ? __isnan (x) : __isnanl (x)) #define HUGE_VAL 0x1.0p2047 #define HUGE_VALF 0x1.0p255f #define HUGE_VALL 0x1.0p32767L #define NAN ((float)0x7fc00000UL) #define M_1_PI 0.31830988618379067154 #define M_LOG10E 0.43429448190325182765 #define M_2_PI 0.63661977236758134308 #define M_LN2 0.69314718055994530942 #define M_SQRT1_2 0.70710678118654752440 #define M_PI_4 0.78539816339744830962 #define M_2_SQRTPI 1.12837916709551257390 #define M_SQRT2 1.41421356237309504880 #define M_LOG2E 1.4426950408889634074 #define M_PI_2 1.57079632679489661923 #define M_LN10 2.30258509299404568402 #define M_E 2.7182818284590452354 #define M_PI 3.14159265358979323846 #define INFINITY HUGE_VALF #define MATH_ERRNO 1 #define MATH_ERREXCEPT 2 #define isunordered(u, v) (__extension__({ __typeof__(u) __u = (u); __typeof__(v) __v = (v);fpclassify (__u) == FP_NAN || fpclassify (__v) == FP_NAN; })) #define islessgreater(x, y) (__extension__({ __typeof__(x) __x = (x); __typeof__(y) __y = (y);!isunordered (__x, __y) & & (__x < __y || __y < __x); })) #define isless(x,y) (__extension__({ __typeof__(x) __x = (x); __typeof__(y) __y = (y);!isunordered (__x, __y) & & __x < __y; })) #define islessequal(x, y) (__extension__({ __typeof__(x) __x = (x); __typeof__(y) __y = (y);!isunordered (__x, __y) & & __x <= __y; })) #define isgreater(x,y) (__extension__({ __typeof__(x) __x = (x); __typeof__(y) __y = (y);!isunordered (__x, __y) & & __x > __y; })) #define isgreaterequal(x,y) (__extension__({ __typeof__(x) __x = (x); __typeof__(y) __y = (y);!isunordered (__x, __y) & & __x >= __y; })) |
The following interfaces are included in libm and are defined by this specification. Unless otherwise noted, these interfaces shall be included in the source standard.
Other interfaces listed above for libm shall behave as described in the referenced base document.
__fpclassify() has the same specification as fpclassify() in ISO POSIX (2003), except that the argument type for __fpclassify() is known to be double.
__fpclassify() is not in the source standard; it is only in the binary standard.
__fpclassifyf() has the same specification as fpclassifyf() in ISO POSIX (2003), except that the argument type for __fpclassifyf() is known to be float.
__fpclassifyf() is not in the source standard; it is only in the binary standard.
Table 1-27 defines the library name and shared object name for the libpthread library
The behavior of the interfaces in this library is specified by the following specifications:
Large File Support |
this specification |
ISO POSIX (2003) |
An LSB conforming implementation shall provide the generic functions for Realtime Threads specified in Table 1-28, with the full mandatory functionality as described in the referenced underlying specification.
Table 1-28. libpthread - Realtime Threads Function Interfaces
pthread_attr_getinheritsched [1] | pthread_attr_getscope [1] | pthread_attr_setschedpolicy [1] | pthread_getschedparam [1] | pthread_setschedprio(GLIBC_2.3.4) [1] |
pthread_attr_getschedpolicy [1] | pthread_attr_setinheritsched [1] | pthread_attr_setscope [1] | pthread_setschedparam [1] |
Referenced Specification(s)
[1]. ISO POSIX (2003)
No external functions are defined for libpthread - Advanced Realtime Threads
An LSB conforming implementation shall provide the generic functions for Posix Threads specified in Table 1-29, with the full mandatory functionality as described in the referenced underlying specification.
Table 1-29. libpthread - Posix Threads Function Interfaces
_pthread_cleanup_pop [1] | pthread_attr_setstacksize [2] | pthread_getspecific [2] | pthread_rwlock_destroy [2] | pthread_setspecific [2] |
_pthread_cleanup_push [1] | pthread_cancel [2] | pthread_join [2] | pthread_rwlock_init [2] | pthread_sigmask [2] |
pread [2] | pthread_cond_broadcast [2] | pthread_key_create [2] | pthread_rwlock_rdlock [2] | pthread_testcancel [2] |
pread64 [3] | pthread_cond_destroy [2] | pthread_key_delete [2] | pthread_rwlock_timedrdlock [2] | pwrite [2] |
pthread_attr_destroy [2] | pthread_cond_init [2] | pthread_kill [2] | pthread_rwlock_timedwrlock [2] | pwrite64 [3] |
pthread_attr_getdetachstate [2] | pthread_cond_signal [2] | pthread_mutex_destroy [2] | pthread_rwlock_tryrdlock [2] | sem_close [2] |
pthread_attr_getguardsize [2] | pthread_cond_timedwait [2] | pthread_mutex_init [2] | pthread_rwlock_trywrlock [2] | sem_destroy [2] |
pthread_attr_getschedparam [2] | pthread_cond_wait [2] | pthread_mutex_lock [2] | pthread_rwlock_unlock [2] | sem_getvalue [2] |
pthread_attr_getstack [2] | pthread_condattr_destroy [2] | pthread_mutex_trylock [2] | pthread_rwlock_wrlock [2] | sem_init [2] |
pthread_attr_getstackaddr [2] | pthread_condattr_getpshared [2] | pthread_mutex_unlock [2] | pthread_rwlockattr_destroy [2] | sem_open [2] |
pthread_attr_getstacksize [2] | pthread_condattr_init [2] | pthread_mutexattr_destroy [2] | pthread_rwlockattr_getpshared [2] | sem_post [2] |
pthread_attr_init [2] | pthread_condattr_setpshared [2] | pthread_mutexattr_getpshared [2] | pthread_rwlockattr_init [2] | sem_timedwait [2] |
pthread_attr_setdetachstate [2] | pthread_create [2] | pthread_mutexattr_gettype [2] | pthread_rwlockattr_setpshared [2] | sem_trywait [2] |
pthread_attr_setguardsize [2] | pthread_detach [2] | pthread_mutexattr_init [2] | pthread_self [2] | sem_unlink [2] |
pthread_attr_setschedparam [2] | pthread_equal [2] | pthread_mutexattr_setpshared [2] | pthread_setcancelstate [2] | sem_wait [2] |
pthread_attr_setstack [2] | pthread_exit [2] | pthread_mutexattr_settype [2] | pthread_setcanceltype [2] | |
pthread_attr_setstackaddr [2] | pthread_getconcurrency [2] | pthread_once [2] | pthread_setconcurrency [2] |
Referenced Specification(s)
[1]. this specification
[2]. ISO POSIX (2003)
[3]. Large File Support
This section defines global identifiers and their values that are associated with interfaces contained in libpthread. These definitions are organized into groups that correspond to system headers. This convention is used as a convenience for the reader, and does not imply the existence of these headers, or their content.
These definitions are intended to supplement those provided in the referenced underlying specifications.
This specification uses ISO/IEC 9899 C Language as the reference programming language, and data definitions are specified in ISO C format. The C language is used here as a convenient notation. Using a C language description of these data objects does not preclude their use by other programming languages.
#define PTHREAD_SCOPE_SYSTEM 0 #define PTHREAD_MUTEX_DEFAULT 1 #define PTHREAD_MUTEX_NORMAL 1 #define PTHREAD_SCOPE_PROCESS 1 #define PTHREAD_MUTEX_RECURSIVE 2 #define PTHREAD_RWLOCK_DEFAULT_NP 2 #define PTHREAD_MUTEX_ERRORCHECK 3 #define pthread_cleanup_pop(execute) _pthread_cleanup_pop(& _buffer,(execute));} #define __LOCK_INITIALIZER { 0, 0 } #define PTHREAD_RWLOCK_INITIALIZER { __LOCK_INITIALIZER, 0, NULL, NULL, NULL,PTHREAD_RWLOCK_DEFAULT_NP, PTHREAD_PROCESS_PRIVATE } #define PTHREAD_MUTEX_INITIALIZER {0,0,0,PTHREAD_MUTEX_NORMAL,__LOCK_INITIALIZER} #define pthread_cleanup_push(routine,arg) {struct _pthread_cleanup_buffer _buffer;_pthread_cleanup_push(& _buffer,(routine),(arg)); #define PTHREAD_COND_INITIALIZER {__LOCK_INITIALIZER,0} struct _pthread_cleanup_buffer { void (*__routine) (void *); void *__arg; int __canceltype; struct _pthread_cleanup_buffer *__prev; } ; typedef unsigned int pthread_key_t; typedef int pthread_once_t; typedef long long int __pthread_cond_align_t; typedef unsigned long int pthread_t; struct _pthread_fastlock { long int __status; int __spinlock; } ; typedef struct _pthread_descr_struct *_pthread_descr; typedef struct { int __m_reserved; int __m_count; _pthread_descr __m_owner; int __m_kind; struct _pthread_fastlock __m_lock; } pthread_mutex_t; typedef struct { int __mutexkind; } pthread_mutexattr_t; typedef struct { int __detachstate; int __schedpolicy; struct sched_param __schedparam; int __inheritsched; int __scope; size_t __guardsize; int __stackaddr_set; void *__stackaddr; unsigned long int __stacksize; } pthread_attr_t; typedef struct { struct _pthread_fastlock __c_lock; _pthread_descr __c_waiting; char __padding[48 - sizeof (struct _pthread_fastlock) - sizeof (_pthread_descr) - sizeof (__pthread_cond_align_t)]; __pthread_cond_align_t __align; } pthread_cond_t; typedef struct { int __dummy; } pthread_condattr_t; typedef struct _pthread_rwlock_t { struct _pthread_fastlock __rw_lock; int __rw_readers; _pthread_descr __rw_writer; _pthread_descr __rw_read_waiting; _pthread_descr __rw_write_waiting; int __rw_kind; int __rw_pshared; } pthread_rwlock_t; typedef struct { int __lockkind; int __pshared; } pthread_rwlockattr_t; #define PTHREAD_CREATE_JOINABLE 0 #define PTHREAD_INHERIT_SCHED 0 #define PTHREAD_ONCE_INIT 0 #define PTHREAD_PROCESS_PRIVATE 0 #define PTHREAD_CREATE_DETACHED 1 #define PTHREAD_EXPLICIT_SCHED 1 #define PTHREAD_PROCESS_SHARED 1 #define PTHREAD_CANCELED ((void*)-1) #define PTHREAD_CANCEL_DEFERRED 0 #define PTHREAD_CANCEL_ENABLE 0 #define PTHREAD_CANCEL_ASYNCHRONOUS 1 #define PTHREAD_CANCEL_DISABLE 1 |
typedef struct { struct _pthread_fastlock __sem_lock; int __sem_value; _pthread_descr __sem_waiting; } sem_t; #define SEM_FAILED ((sem_t*)0) #define SEM_VALUE_MAX ((int)((~0u)>>1)) |
The following interfaces are included in libpthread and are defined by this specification. Unless otherwise noted, these interfaces shall be included in the source standard.
Other interfaces listed above for libpthread shall behave as described in the referenced base document.
The _pthread_cleanup_pop() function provides an implementation of the pthread_cleanup_pop() macro described in ISO POSIX (2003).
The _pthread_cleanup_pop() function is not in the source standard; it is only in the binary standard.
The _pthread_cleanup_push() function provides an implementation of the pthread_cleanup_push() macro described in ISO POSIX (2003).
The _pthread_cleanup_push() function is not in the source standard; it is only in the binary standard.
Table 1-30 defines the library name and shared object name for the libgcc_s library
No external functions are defined for libgcc_s - Unwind Library
This section defines global identifiers and their values that are associated with interfaces contained in libgcc_s. These definitions are organized into groups that correspond to system headers. This convention is used as a convenience for the reader, and does not imply the existence of these headers, or their content.
These definitions are intended to supplement those provided in the referenced underlying specifications.
This specification uses ISO/IEC 9899 C Language as the reference programming language, and data definitions are specified in ISO C format. The C language is used here as a convenient notation. Using a C language description of these data objects does not preclude their use by other programming languages.
struct dwarf_eh_base { void *tbase; void *dbase; void *func; } ; struct _Unwind_Context; typedef unsigned int _Unwind_Ptr; typedef unsigned int _Unwind_Word; typedef enum { _URC_NO_REASON, _URC_FOREIGN_EXCEPTION_CAUGHT = 1, _URC_FATAL_PHASE2_ERROR = 2, _URC_FATAL_PHASE1_ERROR = 3, _URC_NORMAL_STOP = 4, _URC_END_OF_STACK = 5, _URC_HANDLER_FOUND = 6, _URC_INSTALL_CONTEXT = 7, _URC_CONTINUE_UNWIND = 8 } _Unwind_Reason_Code; struct _Unwind_Exception { _Unwind_Exception_Class; _Unwind_Exception_Cleanup_Fn; _Unwind_Word; _Unwind_Word; } ; #define _UA_SEARCH_PHASE 1 #define _UA_END_OF_STACK 16 #define _UA_CLEANUP_PHASE 2 #define _UA_HANDLER_FRAME 4 #define _UA_FORCE_UNWIND 8 |
Table 1-31 defines the library name and shared object name for the libdl library
The behavior of the interfaces in this library is specified by the following specifications:
this specification |
ISO POSIX (2003) |
An LSB conforming implementation shall provide the generic functions for Dynamic Loader specified in Table 1-32, with the full mandatory functionality as described in the referenced underlying specification.
Table 1-32. libdl - Dynamic Loader Function Interfaces
dladdr [1] | dlclose [2] | dlerror [2] | dlopen [1] | dlsym [1] |
Referenced Specification(s)
[1]. this specification
[2]. ISO POSIX (2003)
This section defines global identifiers and their values that are associated with interfaces contained in libdl. These definitions are organized into groups that correspond to system headers. This convention is used as a convenience for the reader, and does not imply the existence of these headers, or their content.
These definitions are intended to supplement those provided in the referenced underlying specifications.
This specification uses ISO/IEC 9899 C Language as the reference programming language, and data definitions are specified in ISO C format. The C language is used here as a convenient notation. Using a C language description of these data objects does not preclude their use by other programming languages.
#define RTLD_NEXT ((void *) -1l) #define RTLD_LOCAL 0 #define RTLD_LAZY 0x00001 #define RTLD_NOW 0x00002 #define RTLD_GLOBAL 0x00100 typedef struct { char *dli_fname; void *dli_fbase; char *dli_sname; void *dli_saddr; } Dl_info; |
The following interfaces are included in libdl and are defined by this specification. Unless otherwise noted, these interfaces shall be included in the source standard.
Other interfaces listed above for libdl shall behave as described in the referenced base document.
#include <dlfcn.h> typedef struct { const char |
The dladdr() function shall query the dynamic linker for information about the shared object containing the address addr. The information shall be returned in the user supplied data structure referenced by dlip.
The structure shall contain at least the following members:
dli_fname
The pathname of the shared object containing the address
dli_fbase
The base address at which the shared object is mapped into the address space of the calling process.
dli_sname
The name of the nearest runtime symbol with value less than or equal to addr. Where possible, the symbol name shall be returned as it would appear in C source code.
If no symbol with a suitable value is found,
both this field and dli_saddr
shall be set to NULL.
dli_saddr
The address of the symbol returned in
dli_sname
.
The behavior of dladdr() is only specified in dynamically linked programs.
On success, dladdr() shall return non-zero, and the structure referenced by dlip shall be filled in as described. Otherwise, dladdr() shall return zero, and the cause of the error can be fetched with dlerr().
dlopen shall behave as specified in ISO POSIX (2003), but with additional behaviors listed below.
If the file argument does not contain a slash character, then the system shall look for a library of that name in at least the following directories, and use the first one which is found:
The directories specified by the
DT_RPATH
dynamic entry.
The directories specified in the
LD_LIBRARY_PATH
environment variable (which is a colon separated list of pathnames).
This step shall be skipped for setuid
and setgid executables.
A set of directories sufficient to contain the libraries specified in this standard.
Note: Traditionally, /lib and /usr/lib. This case would also cover cases in which the system used the mechanism of /etc/ld.so.conf and /etc/ld.so.cache to provide access.
Example: An application which is not linked against libm may choose to dlopen libm.
dlsym() is as specified in the ISO POSIX (2003), but with differences as listed below.
The value RTLD_NEXT, which is reserved for future use shall be available, with the behavior as described in ISO POSIX (2003).
Table 1-33 defines the library name and shared object name for the libcrypt library
The behavior of the interfaces in this library is specified by the following specifications:
ISO POSIX (2003) |
An LSB conforming implementation shall provide the generic functions for Encryption specified in Table 1-34, with the full mandatory functionality as described in the referenced underlying specification.
Referenced Specification(s)
[1]. ISO POSIX (2003)
Table 1-35 defines the library name and shared object name for the libpam library
A single service name, other
, shall always be present.
The behavior of this service shall be determined by the system administrator.
Additional service names may also exist.
[1]
The behavior of the interfaces in this library is specified by the following specifications:
this specification |
An LSB conforming implementation shall provide the generic functions for Pluggable Authentication API specified in Table 1-36, with the full mandatory functionality as described in the referenced underlying specification.
Table 1-36. libpam - Pluggable Authentication API Function Interfaces
pam_acct_mgmt [1] | pam_close_session [1] | pam_get_item [1] | pam_set_item [1] | pam_strerror [1] |
pam_authenticate [1] | pam_end [1] | pam_getenvlist [1] | pam_setcred [1] | |
pam_chauthtok [1] | pam_fail_delay [1] | pam_open_session [1] | pam_start [1] |
Referenced Specification(s)
[1]. this specification
This section defines global identifiers and their values that are associated with interfaces contained in libpam. These definitions are organized into groups that correspond to system headers. This convention is used as a convenience for the reader, and does not imply the existence of these headers, or their content.
These definitions are intended to supplement those provided in the referenced underlying specifications.
This specification uses ISO/IEC 9899 C Language as the reference programming language, and data definitions are specified in ISO C format. The C language is used here as a convenient notation. Using a C language description of these data objects does not preclude their use by other programming languages.
typedef struct pam_handle pam_handle_t; struct pam_message { int msg_style; const char *msg; } ; struct pam_response { char *resp; int resp_retcode; } ; struct pam_conv { int (*conv) (int num_msg, const struct pam_message * *msg, struct pam_response * *resp, void *appdata_ptr); void *appdata_ptr; } ; #define PAM_PROMPT_ECHO_OFF 1 #define PAM_PROMPT_ECHO_ON 2 #define PAM_ERROR_MSG 3 #define PAM_TEXT_INFO 4 #define PAM_SERVICE 1 #define PAM_USER 2 #define PAM_TTY 3 #define PAM_RHOST 4 #define PAM_CONV 5 #define PAM_RUSER 8 #define PAM_USER_PROMPT 9 #define PAM_SUCCESS 0 #define PAM_OPEN_ERR 1 #define PAM_USER_UNKNOWN 10 #define PAM_MAXTRIES 11 #define PAM_NEW_AUTHTOK_REQD 12 #define PAM_ACCT_EXPIRED 13 #define PAM_SESSION_ERR 14 #define PAM_CRED_UNAVAIL 15 #define PAM_CRED_EXPIRED 16 #define PAM_CRED_ERR 17 #define PAM_CONV_ERR 19 #define PAM_SYMBOL_ERR 2 #define PAM_AUTHTOK_ERR 20 #define PAM_AUTHTOK_RECOVER_ERR 21 #define PAM_AUTHTOK_LOCK_BUSY 22 #define PAM_AUTHTOK_DISABLE_AGING 23 #define PAM_TRY_AGAIN 24 #define PAM_ABORT 26 #define PAM_AUTHTOK_EXPIRED 27 #define PAM_BAD_ITEM 29 #define PAM_SERVICE_ERR 3 #define PAM_SYSTEM_ERR 4 #define PAM_BUF_ERR 5 #define PAM_PERM_DENIED 6 #define PAM_AUTH_ERR 7 #define PAM_CRED_INSUFFICIENT 8 #define PAM_AUTHINFO_UNAVAIL 9 #define PAM_DISALLOW_NULL_AUTHTOK 0x0001U #define PAM_ESTABLISH_CRED 0x0002U #define PAM_DELETE_CRED 0x0004U #define PAM_REINITIALIZE_CRED 0x0008U #define PAM_REFRESH_CRED 0x0010U #define PAM_CHANGE_EXPIRED_AUTHTOK 0x0020U #define PAM_SILENT 0x8000U |
The following interfaces are included in libpam and are defined by this specification. Unless otherwise noted, these interfaces shall be included in the source standard.
Other interfaces listed above for libpam shall behave as described in the referenced base document.
pam_acct_mgmt() establishes the account's usability and the user's accessibility to the system. It is typically called after the user has been authenticated.
flags may be specified as any valid flag (namely,
one of those applicable to the flags argument of
pam_authenticate()). Additionally, the value of
flags may be logically or'd
with PAM_SILENT
.
Success.
User is valid, but user's authentication token has expired. The correct response to this return-value is to require that the user satisfy the pam_chauthtok() function before obtaining service. It may not be possible for an application to do this. In such a case, the user should be denied access until the account password is updated.
User is no longer permitted access to the system.
Authentication error.
User is not permitted to gain access at this time.
User is not known to a module's account management component.
pam_authenticate() serves as an interface to the authentication mechanisms of the loaded modules.
flags is an optional parameter that may be specified by the following value:
Instruct the authentication modules to return PAM_AUTH_ERR
if the user does not have a registered authorization token.
Additionally, the value of flags may be
logically or'd with PAM_SILENT
.
The process may need to be privileged in order to successfully call this function.
Success.
User was not authenticated or process did not have sufficient privileges to perform authentication.
Application does not have sufficient credentials to authenticate the user.
Modules were not able to access the authentication information. This might be due to a network or hardware failure, etc.
Supplied username is not known to the authentication service.
One or more authentication modules has reached its limit of tries authenticating the user. Do not try again.
One or more authentication modules failed to load.
pam_chauthtok() is used to change the authentication token for a given user as indicated by the state associated with the handle pamh.
flags is an optional parameter that may be specified by the following value:
User's authentication token should only be changed if it has expired.
Additionally, the value of flags may be
logically or'd with PAM_SILENT
.
Success.
A module was unable to obtain the new authentication token.
A module was unable to obtain the old authentication token.
One or more modules were unable to change the authentication token since it is currently locked.
Authentication token aging has been disabled for at least one of the modules.
Permission denied.
Not all modules were in a position to update the authentication token(s). In such a case, none of the user's authentication tokens are updated.
User is not known to the authentication token changing service.
pam_close_session() is used to indicate that an authenticated session has ended. It is used to inform the module that the user is exiting a session. It should be possible for the PAM library to open a session and close the same session from different applications.
flags may have the value
PAM_SILENT
to indicate that no output
should be generated as a result of this function call.
Success.
One of the required loaded modules was unable to close a session for the user.
pam_end() terminates use of the PAM library. On success, the contents of *pamh are no longer valid, and all memory associated with it is invalid.
Normally, pam_status is passed the value
PAM_SUCCESS
, but in the event of an
unsuccessful service application, the appropriate PAM error
return value should be used.
pam_fail_delay() specifies the minimum delay for the PAM library to use when an authentication error occurs. The actual delay can vary by as much at 25%. If this function is called multiple times, the longest time specified by any of the call will be used.
The delay is invoked if an authentication error occurs during the pam_authenticate() or pam_chauthtok() function calls.
Independent of the success of pam_authenticate() or pam_chauthtok(), the delay time is reset to its default value of 0 when the PAM library returns control to the application from these two functions.
pam_get_item() obtains the value of the indicated item_type. The possible values of item_type are the same as listed for pam_set_item().
On success, item contains a pointer to the value of the corresponding item. Note that this is a pointer to the actual data and should not be free()'d or over-written.
Success.
Application passed a NULL
pointer for
item
.
Application attempted to get an undefined item.
pam_getenvlist() returns a pointer to the complete
PAM environment. This pointer points to an array of pointers to
NUL
-terminated strings and must be terminated by a
NULL
pointer. Each string has the form "name=value".
The PAM library module allocates memory for the returned value and the associated strings. The calling application is responsible for freeing this memory.
pam_getenvlist() returns an array of string pointers
containing the PAM environment. On error, NULL
is returned.
pam_handle_t() is used to indicate that an authenticated session has begun. It is used to inform the module that the user is currently in a session. It should be possible for the PAM library to open a session and close the same session from different applications.
flags may have the value
PAM_SILENT
to indicate that no output be
generated as a rsult of this function call.
Success.
One of the loaded modules was unable to open a session for the user.
pam_set_item() (re)sets the value of one of the following item_types:
service name
user name
terminal name
The value for a device file should include the /dev/
prefix. The value for graphical, X-based, applications should be the
$DISPLAY
variable.
remote host name
conversation structure
remote user name
string to be used when prompting for a user's name
The default value for this string is Please enter username: .
For all item_types other than
PAM_CONV
, item is a pointer
to a NULL
-terminated character string. In the case
of PAM_CONV
, item points to
an initialized pam_conv structure.
Success.
An attempt was made to replace the conversation structure with a
NULL
value.
Function ran out of memory making a copy of the item.
Application attempted to set an undefined item.
pam_setcred() sets the module-specific credentials of the user. It is usually called after the user has been authenticated, after the account management function has been called and after a session has been opened for the user.
flags maybe specified from among the following values:
set credentials for the authentication service
delete credentials associated with the authentication service
reinitialize the user credentials
extend lifetime of the user credentials
Additionally, the value of flags may be
logically or'd with PAM_SILENT
.
Success.
Module cannot retrieve the user's credentials.
User's credentials have expired.
User is not known to an authentication module.
Module was unable to set the credentials of the user.
pam_start() is used to initialize the PAM library. It must be called prior to any other usage of the PAM library. On success, *pamh becomes a handle that provides continuity for successive calls to the PAM library. pam_start() expects arguments as follows: the service_name of the program, the username of the individual to be authenticated, a pointer to an application-supplied pam_conv structure, and a pointer to a pam_handle_t pointer.
An application must provide the conversation function used for direct communication between a loaded module and the application. The application also typically provides a means for the module to prompt the user for a password, etc.
The structure, pam_conv, is defined to be,
struct pam_conv { int (*conv) (int num_msg, const struct pam_message * *msg, struct pam_response * *resp, void *appdata_ptr); void *appdata_ptr; }; |
When a module calls the referenced conv() function, appdata_ptr is set to the second element of this structure.
The other arguments of a call to conv() concern the information exchanged by module and application. num_msg holds the length of the array of pointers passed via msg. On success, the pointer resp points to an array of num_msg pam_response structures, holding the application-supplied text. Note that resp is a struct pam_response array and not an array of pointers.
On success, this function returns a description of the indicated error.
The application
should not free or modify this string.
Otherwise, a string
indicating that the error is unknown shall be returned.
It is unspecified whether or not the string returned is translated according to
the setting of LC_MESSAGES
.
An LSB-conforming implementation shall also support the following utility libraries which are built on top of the interfaces provided by the base libraries. These libraries implement common functionality, and hide additional system dependent information such as file formats and device names.
libz
libcurses
libutil
Table 2-1 defines the library name and shared object name for the libz library
The behavior of the interfaces in this library is specified by the following specifications:
this specification |
An LSB conforming implementation shall provide the generic functions for Compression Library specified in Table 2-2, with the full mandatory functionality as described in the referenced underlying specification.
Table 2-2. libz - Compression Library Function Interfaces
adler32 [1] | deflateInit2_ [1] | gzerror [1] | gzrewind [1] | inflateReset [1] |
compress [1] | deflateInit_ [1] | gzflush [1] | gzseek [1] | inflateSetDictionary [1] |
compress2 [1] | deflateParams [1] | gzgetc [1] | gzsetparams [1] | inflateSync [1] |
compressBound [1] | deflateReset [1] | gzgets [1] | gztell [1] | inflateSyncPoint [1] |
crc32 [1] | deflateSetDictionary [1] | gzopen [1] | gzwrite [1] | uncompress [1] |
deflate [1] | get_crc_table [1] | gzprintf [1] | inflate [1] | zError [1] |
deflateBound [1] | gzclose [1] | gzputc [1] | inflateEnd [1] | zlibVersion [1] |
deflateCopy [1] | gzdopen [1] | gzputs [1] | inflateInit2_ [1] | |
deflateEnd [1] | gzeof [1] | gzread [1] | inflateInit_ [1] |
Referenced Specification(s)
[1]. this specification
This section defines global identifiers and their values that are associated with interfaces contained in libz. These definitions are organized into groups that correspond to system headers. This convention is used as a convenience for the reader, and does not imply the existence of these headers, or their content.
These definitions are intended to supplement those provided in the referenced underlying specifications.
This specification uses ISO/IEC 9899 C Language as the reference programming language, and data definitions are specified in ISO C format. The C language is used here as a convenient notation. Using a C language description of these data objects does not preclude their use by other programming languages.
In addition to the values below, the zlib.h
header shall define the
ZLIB_VERSION
macro. This macro may be used
to check that the version of the library at run time matches that
at compile time.
See also the zlibVersion() function, which returns the library version at run time. The first character of the version at compile time should always match the first character at run time.
#define Z_NULL 0 #define MAX_WBITS 15 #define MAX_MEM_LEVEL 9 #define deflateInit2(strm,level,method,windowBits,memLevel,strategy) deflateInit2_((strm),(level),(method),(windowBits),(memLevel),(strategy),ZLIB_VERSION,sizeof(z_stream)) #define deflateInit(strm,level) deflateInit_((strm), (level), ZLIB_VERSION, sizeof(z_stream)) #define inflateInit2(strm,windowBits) inflateInit2_((strm), (windowBits), ZLIB_VERSION, sizeof(z_stream)) #define inflateInit(strm) inflateInit_((strm), ZLIB_VERSION, sizeof(z_stream)) typedef char charf; typedef int intf; typedef void *voidpf; typedef unsigned int uInt; typedef unsigned long int uLong; typedef uLong uLongf; typedef void *voidp; typedef unsigned char Byte; typedef off_t z_off_t; typedef void *const voidpc; typedef voidpf (*alloc_func) (voidpf opaque, uInt items, uInt size); typedef void (*free_func) (voidpf opaque, voidpf address); struct internal_state { int dummy; } ; typedef Byte Bytef; typedef uInt uIntf; typedef struct z_stream_s { Bytef *next_in; uInt avail_in; uLong total_in; Bytef *next_out; uInt avail_out; uLong total_out; char *msg; struct internal_state *state; alloc_func zalloc; free_func zfree; voidpf opaque; int data_type; uLong adler; uLong reserved; } z_stream; typedef z_stream *z_streamp; typedef voidp gzFile; #define Z_NO_FLUSH 0 #define Z_PARTIAL_FLUSH 1 #define Z_SYNC_FLUSH 2 #define Z_FULL_FLUSH 3 #define Z_FINISH 4 #define Z_ERRNO (-1) #define Z_STREAM_ERROR (-2) #define Z_DATA_ERROR (-3) #define Z_MEM_ERROR (-4) #define Z_BUF_ERROR (-5) #define Z_VERSION_ERROR (-6) #define Z_OK 0 #define Z_STREAM_END 1 #define Z_NEED_DICT 2 #define Z_DEFAULT_COMPRESSION (-1) #define Z_NO_COMPRESSION 0 #define Z_BEST_SPEED 1 #define Z_BEST_COMPRESSION 9 #define Z_DEFAULT_STRATEGY 0 #define Z_FILTERED 1 #define Z_HUFFMAN_ONLY 2 #define Z_BINARY 0 #define Z_ASCII 1 #define Z_UNKNOWN 2 #define Z_DEFLATED 8 |
The following interfaces are included in libz and are defined by this specification. Unless otherwise noted, these interfaces shall be included in the source standard.
Other interfaces listed above for libz shall behave as described in the referenced base document.
The adler32() function shall compute a running Adler-32 checksum (as described in RFC 1950: ZLIB Compressed Data Format Specication). On entry, adler is the previous value for the checksum, and buf shall point to an array of len bytes of data to be added to this checksum. The adler32() function shall return the new checksum.
If buf is NULL
(or
Z_NULL
), adler32()
shall return the initial checksum.
The following code fragment demonstrates typical usage of the adler32() function:
uLong adler = adler32(0L, Z_NULL, 0); while (read_buffer(buffer, length) != EOF) { adler = adler32(adler, buffer, length); } if (adler != original_adler) error(); |
The compress() function shall attempt to compress sourceLen bytes of data in the buffer source, placing the result in the buffer dest.
On entry, destLen should point to a value describing the size of the dest buffer. The application should ensure that this value be at least (sourceLen × 1.001) + 12. On successful exit, the variable referenced by destLen shall be updated to hold the length of compressed data in dest.
The compress() function is equivalent to
compress2() with a level of
Z_DEFAULT_LEVEL
.
On success, compress() shall return Z_OK. Otherwise, compress() shall return a value to indicate the error.
On error, compress() shall return a value as described below:
Z_BUF_ERROR
The buffer dest was not large enough to hold the compressed data.
Z_MEM_ERROR
Insufficient memory.
The compress2() function shall attempt to compress
sourceLen bytes of data in the buffer
source, placing the result in the buffer
dest, at the level described by
level.
The level supplied shall be a value between
0
and 9
, or the value
Z_DEFAULT_COMPRESSION
. A level
of 1
requests the highest speed, while a level
of 9
requests the highest compression.
A level of 0
indicates that no
compression should be used, and the output shall be the same as the input.
On entry, destLen should point to a value describing the size of the dest buffer. The application should ensure that this value be at least (sourceLen × 1.001) + 12. On successful exit, the variable referenced by destLen shall be updated to hold the length of compressed data in dest.
The compress() function is equivalent to
compress2() with a level of
Z_DEFAULT_LEVEL
.
On success, compress2() shall return Z_OK. Otherwise, compress2() shall return a value to indicate the error.
On error, compress2() shall return a value as described below:
Z_BUF_ERROR
The buffer dest was not large enough to hold the compressed data.
Z_MEM_ERROR
Insufficient memory.
Z_STREAM_ERROR
The level was not Z_DEFAULT_LEVEL
,
or was not between 0 and 9.
The compressBound() function shall estimate the size of buffer required to compress sourceLen bytes of data using the compress() or compress2() functions. If successful, the value returned shall be an upper bound for the size of buffer required to compress sourceLen bytes of data, using the parameters stored in stream, in a single call to compress() or compress2().
The compressBound() shall return a value representing the upper bound of an array to allocate to hold the compressed data in a single call to compress() or compress2(). This function may return a conservative value that may be larger than sourceLen.
The crc32() function shall compute a running Cyclic Redundancy Check checksum, as defined in ITU-T V.42. On entry, crc is the previous value for the checksum, and buf shall point to an array of len bytes of data to be added to this checksum. The crc32() function shall return the new checksum.
If buf is NULL
(or
Z_NULL
), crc32()
shall return the initial checksum.
The following code fragment demonstrates typical usage of the crc32() function:
uLong crc = crc32(0L, Z_NULL, 0); while (read_buffer(buffer, length) != EOF) { crc = crc32(crc, buffer, length); } if (crc != original_crc) error(); |
The deflate() function shall attempt to compress data until either the input buffer is empty or the output buffer is full. The stream references a z_stream structure. Before the first call to deflate(), this structure should have been initialized by a call to deflateInit2_().
Note: deflateInit2_() is only in the binary standard; source level applications should initialize stream via a call to deflateInit() or deflateInit2().
next_in
should point to the data to be compressed.
avail_in
should contain the number of bytes of data in the
buffer referenced by next_in
.
next_out
should point to a buffer where compressed data may be placed.
avail_out
should contain the size in bytes of the
buffer referenced by next_out
The deflate() function shall perform one or both of the following actions:
Compress input data from next_in
and update next_in
,
avail_in
and
total_in
to reflect the data that has been
compressed.
Fill the output buffer referenced by next_out
,
and update next_out
,
avail_out
and
total_out
to reflect the compressed data that
has been placed there. If flush is not
Z_NO_FLUSH
, and
avail_out
indicates that there is still space in
output buffer, this action shall always occur (see below for further details).
The deflate() function shall return when either
avail_in
reaches zero (indicating that all the input
data has been compressed), or avail_out
reaches
zero (indicating that the output buffer is full).
On success, the deflate() function shall set the
adler
field of the stream
to the adler32() checksum of all the input data compressed
so far (represented by total_in
).
If the deflate() function shall attempt to determine
the type of input data, and set field data_type
in stream to Z_ASCII
if the
majority of the data bytes fall within the ASCII (ISO 646) printable
character range. Otherwise, it shall set data_type
to Z_BINARY
.
This data type is informational only, and does not affect the compression
algorithm.
Note: Future versions of the LSB may remove this requirement, since it is based on an outdated character set that does not support Internationalization, and does not affect the algorithm. It is included for information only at this release. Applications should not depend on this field.
The parameter flush determines when compressed bits
are added to the output buffer in next_out
.
If flush is Z_NO_FLUSH
,
deflate()
may return with some data pending output, and not yet added to the
output buffer.
If flush is Z_SYNC_FLUSH
,
deflate() shall flush all pending output to
next_out
and align the output to a byte
boundary. A synchronization point is generated in the output.
If flush is Z_FULL_FLUSH
,
all output shall be flushed, as for Z_SYNC_FLUSH
,
and the compression state shall be reset.
A synchronization point is generated in the output.
Rationale:
Z_SYNC_FLUSH
is intended to ensure that the compressed data contains all the data compressed so far, and allows a decompressor to reconstruct all of the input data.Z_FULL_FLUSH
allows decompression to restart from this point if the previous compressed data has been lost or damaged. Flushing is likely to degrade the performance of the compression system, and should only be used where necessary.
If flush is set to Z_FINISH
,
all pending input shall be processed and deflate()
shall return with Z_STREAM_END if there is
sufficient space in the output buffer at next_out
,
as indicated by avail_out
. If
deflate() is called with flush
set to Z_FINISH
and there is insufficient space to store
the compressed data, and no other error has occurred during compression,
deflate() shall return Z_OK,
and the application should call deflate() again with
flush unchanged, and having updated next_out
and avail_out
.
If all the compression is to be done in a single step,
deflate()
may be called with flush set to
Z_FINISH
immediately after the stream
has been initialized if avail_out
is set to at least the value returned by deflateBound().
On success, deflate() shall return
Z_OK, unless flush was set
to Z_FINISH
and there was sufficient space in the output buffer
to compress all of the input data. In this case, deflate()
shall return Z_STREAM_END.
On error, deflate() shall return a value to indicate
the error.
Note: If deflate() returns Z_OK and has set
avail_out
to zero, the function should be called again with the same value for flush, and with updatednext_out
andavail_out
until deflate() returns with Z_OK (or Z_STREAM_END if flush is set toZ_FINISH
) and a non-zeroavail_out
.
On error, deflate() shall return a value as described
below, and set the msg
field of
stream to point to a string describing the error:
Z_BUF_ERROR
No progress is possible; either avail_in
or avail_out
was zero.
Z_MEM_ERROR
Insufficient memory.
Z_STREAM_ERROR
The state (as represented in stream) is inconsistent, or
stream was NULL
.
The deflateBound() function shall estimate the size
of buffer required to compress sourceLen
bytes of data. If successful, the value returned shall be an upper
bound for the size of buffer required to compress
sourceLen bytes of data, using the
parameters stored in stream,
in a single
call to deflate() with flush set to
Z_FINISH
.
On entry, stream should have been initialized via a call to deflateInit_() or deflateInit2_().
The deflateBound() shall return a value
representing the upper bound of an array to allocate to hold
the compressed data in a single call to deflate().
If the stream is not correctly initialized,
or is NULL
, then deflateBound()
may return a conservative value that may be larger than
sourceLen.
The deflateCopy() function shall copy the compression state information in source to the uninitialized z_stream structure referenced by dest.
On successful return, dest will be an exact copy
of the stream referenced by source. The input and
output buffer pointers in next_in
and
next_out
will reference the same data.
On success, deflateCopy() shall return Z_OK. Otherwise it shall return a value less than zero to indicate the error.
On error, deflateCopy() shall return a value as described below:
Z_STREAM_ERROR
The state in source is inconsistent, or
either source or
dest was NULL
.
Z_MEM_ERROR
Insufficient memory available.
This function can be useful when several compression strategies will be tried, for example when there are several ways of pre-processing the input data with a filter. The streams that will be discarded should then be freed by calling deflateEnd(). Note that deflateCopy() duplicates the internal compression state which can be quite large, so this strategy may be slow and can consume lots of memory.
The deflateEnd() function shall free all allocated state information referenced by stream. All pending output is discarded, and unprocessed input is ignored.
On success, deflateEnd() shall return Z_OK, or Z_DATA_ERROR if there was pending output discarded or input unprocessed. Otherwise it shall return Z_STREAM_ERROR to indicate the error.
On error, deflateEnd() shall return Z_STREAM_ERROR. The following conditions shall be treated as an error:
The state in stream is inconsistent or inappropriate.
stream
is NULL
.
The deflateInit2_() function shall initialize the compression system. On entry, strm shall refer to a user supplied z_stream object (a z_stream_s structure). The following fields shall be set on entry:
zalloc
a pointer to an alloc_func function, used to allocate state information.
If this is NULL
, a default allocation function will be used.
zfree
a pointer to a free_func function, used to free memory allocated by the
zalloc
function. If this is NULL
a default free function will be used.
opaque
If alloc_func
is not NULL
,
opaque
is a user supplied pointer to data that will be passed to the
alloc_func
and free_func
functions.
If the version requested is not compatible with the version
implemented, or if the size of the z_stream_s structure
provided in stream_size does not match the size in the library
implementation, deflateInit2_() shall fail, and return
Z_VERSION_ERROR
.
The level supplied shall be a value between
0
and 9
, or the value
Z_DEFAULT_COMPRESSION
. A level
of 1
requests the highest speed, while a level
of 9
requests the highest compression.
A level of 0
indicates that no
compression should be used, and the output shall be the same as the input.
The method selects the compression algorithm to use. LSB
conforming implementation shall support the Z_DEFLATED
method,
and may support other implementation defined methods.
The windowBits parameter shall be a base 2 logarithm of the window
size to use, and shall be a value between 8
and 15
.
A smaller value will use less memory, but will result in a poorer compression ratio,
while a higher value will
give better compression but utilize more memory.
The memLevel parameter specifies how much memory to use for the
internal state. The value of memLevel shall be between
1
and MAX_MEM_LEVEL
. Smaller values
use less memory but are slower, while higher values use more memory to gain compression speed.
The strategy parameter selects the compression strategy to use:
Z_DEFAULT_STRATEGY
use the system default compression strategy. Z_DEFAULT_STRATEGY
is particularly appropriate for text data.
Z_FILTERED
use a compression strategy tuned for data consisting largely of small values with a
fairly random distribution. Z_FILTERED
uses more Huffman encoding
and less string matching than Z_DEFAULT_STRATEGY
.
Z_HUFFMAN_ONLY
force Huffman encoding only, with no string match.
The deflateInit2_() function is not in the source standard; it is only in the binary standard. Source applications should use the deflateInit2() macro.
On success, the deflateInit2_() function shall return
Z_OK
.
Otherwise, deflateInit2_() shall return
a value as described below to indicate the error.
On error, deflateInit2_() shall return one of the following error indicators:
Z_STREAM_ERROR
Invalid parameter.
Z_MEM_ERROR
Insufficient memory available.
Z_VERSION_ERROR
The version requested is not compatible with the library version, or the z_stream size differs from that used by the library.
In addition, the msg
field of the strm
may be set to an error message.
The deflateInit_() function shall initialize the compression system. On entry, stream shall refer to a user supplied z_stream object (a z_stream_s structure). The following fields shall be set on entry:
zalloc
a pointer to an alloc_func function, used to allocate state information.
If this is NULL
, a default allocation function will be used.
zfree
a pointer to a free_func function, used to free memory
allocated by the
zalloc
function. If this is
NULL
a default free function will be used.
opaque
If alloc_func
is not NULL
,
opaque
is a user supplied pointer to data
that will be passed to the
alloc_func
and
free_func
functions.
If the version requested is not compatible with
the version implemented, or if the size of the
z_stream_s structure
provided in stream_size does not match the size
in the library
implementation, deflateInit_() shall fail, and return
Z_VERSION_ERROR
.
The level supplied shall be a value between
0
and 9
, or the value
Z_DEFAULT_COMPRESSION
. A level
of 1
requests the highest speed, while a
level
of 9
requests the highest compression.
A level of 0
indicates that no
compression should be used, and the output shall be the same as the input.
The deflateInit_() function is not in the source standard; it is only in the binary standard. Source applications should use the deflateInit() macro.
The deflateInit_() function is equivalent to
deflateInit2_(stream, level, Z_DEFLATED, MAX_WBITS, DEF_MEM_LEVEL, Z_DEFAULT_STRATEGY, version, stream_size); |
On success, the deflateInit_() function shall return
Z_OK
.
Otherwise, deflateInit_() shall return
a value as described below to indicate the error.
On error, deflateInit_() shall return one of the following error indicators:
Z_STREAM_ERROR
Invalid parameter.
Z_MEM_ERROR
Insufficient memory available.
Z_VERSION_ERROR
The version requested is not compatible with the library version, or the z_stream size differs from that used by the library.
In addition, the msg
field of the
stream
may be set to an error message.
The deflateParams() function shall dynamically alter the compression parameters for the compression stream object stream. On entry, stream shall refer to a user supplied z_stream object (a z_stream_s structure), already initialized via a call to deflateInit_() or deflateInit2_().
The level supplied shall be a value between
0
and 9
, or the value
Z_DEFAULT_COMPRESSION
. A level
of 1
requests the highest speed, while a level
of 9
requests the highest compression.
A level of 0
indicates that no
compression should be used, and the output shall be the same as the input.
If the compression level is altered by deflateParams(),
and some data has already been compressed with this stream
(i.e. total_in
is not zero),
and the new level requires a different
underlying compression method, then stream
shall be flushed by a call to deflate().
The strategy parameter selects the compression strategy to use:
Z_DEFAULT_STRATEGY
use the system default compression strategy. Z_DEFAULT_STRATEGY
is particularly appropriate for text data.
Z_FILTERED
use a compression strategy tuned for data consisting largely of small values with a
fairly random distribution. Z_FILTERED
uses more Huffman encoding
and less string matching than Z_DEFAULT_STRATEGY
.
Z_HUFFMAN_ONLY
force Huffman encoding only, with no string match.
On success, the deflateParams() function shall return
Z_OK
.
Otherwise, deflateParams() shall return
a value as described below to indicate the error.
On error, deflateParams() shall return one of the following error indicators:
Z_STREAM_ERROR
Invalid parameter.
Z_MEM_ERROR
Insufficient memory available.
Z_BUF_ERROR
Insufficient space in stream to flush the current output.
In addition, the msg
field of the strm
may be set to an error message.
Applications should ensure that the stream is flushed,
e.g. by a call to deflate(stream, Z_SYNC_FLUSH)
before calling deflateParams(), or ensure that there is
sufficient space in next_out
(as identified by
avail_out
) to ensure that all pending output and
all uncompressed input can be flushed in a single call to
deflate().
Rationale: Although the deflateParams() function should flush pending output and compress all pending input, the result is unspecified if there is insufficient space in the output buffer. Applications should only call deflateParams() when the stream is effectively empty (flushed).
The deflateParams() can be used to switch between compression and straight copy of the input data, or to switch to a different kind of input data requiring a different strategy.
The deflateReset() function shall reset all state
associated with stream.
All pending output shall be discarded, and the counts of processed
bytes (total_in
and
total_out
) shall be reset to zero.
On success, deflateReset() shall return Z_OK. Otherwise it shall return Z_STREAM_ERROR to indicate the error.
On error, deflateReset() shall return Z_STREAM_ERROR. The following conditions shall be treated as an error:
The state in stream is inconsistent or inappropriate.
stream
is NULL
.
The deflateSetDictionary() function shall initialize the compression dictionary associated with stream using the dictlen bytes referenced by dictionary.
The implementation may silently use a subset of the provided dictionary if the dictionary cannot fit in the current window associated with stream (see deflateInit2_()). The application should ensure that the dictionary is sorted such that the most commonly used strings occur at the end of the dictionary.
If the dictionary is successfully set, the Adler32 checksum of the entire
provided dictionary
shall be stored in the adler
member of
stream. This value may be used by the decompression
system to select the correct dictionary. The compression and decompression
systems must use the same dictionary.
stream shall reference an initialized compression
stream, with total_in
zero (i.e. no data
has been compressed since the stream was initialized).
On success, deflateSetDictionary() shall return Z_OK. Otherwise it shall return Z_STREAM_ERROR to indicate an error.
On error, deflateSetDictionary() shall return a value as described below:
Z_STREAM_ERROR
The state in stream is inconsistent, or
stream
was NULL
.
The application should provide a dictionary consisting of strings {{{ed note: do we really mean "strings"? Null terminated?}}} that are likely to be encountered in the data to be compressed. The application should ensure that the dictionary is sorted such that the most commonly used strings occur at the end of the dictionary.
The use of a dictionary is optional; however if the data to be compressed is relatively short and has a predictable structure, the use of a dictionary can substantially improve the compression ratio.
Generate tables for a byte-wise 32-bit CRC calculation based on the polynomial: x32+x26+x23+x22+x16+x12+x11+x10+x8+x7+x5+x4+x2+x+1
In a multi-threaded application, get_crc_table() should be called by one thread to initialize the tables before any other thread calls any libz function.
The get_crc_table() function shall return a pointer to the first of a set of tables used internally to calculate CRC-32 values (see crc32()).
The gzclose() function shall close the compressed file stream file. If file was open for writing, gzclose() shall first flush any pending output. Any state information allocated shall be freed.
On success, gzclose() shall return Z_OK. Otherwise, gzclose() shall return an error value as described below.
On error, gzclose() may set
the global variable errno
to indicate the error.
The gzclose() shall return a value other than Z_OK
on error.
Z_STREAM_ERROR
file was NULL
(or Z_NULL
),
or did not refer to an open compressed file stream.
Z_ERRNO
An error occurred in the underlying base libraries, and the application should check
errno
for further information.
Z_BUF_ERROR
no compression progress is possible during buffer flush (see deflate()).
The gzdopen() function shall attempt to associate the open file referenced by fd with a gzFile object. The mode argument is based on that of fopen(), but the mode parameter may also contain the following characters:
set the compression level to digit. A low value (e.g. 1) means high speed, while a high value (e.g. 9) means high compression. A compression level of 0 (zero) means no compression. See defaultInit2_() for further details.
set the compression strategy to [fhR]. The letter f corresponds to filtered data, the letter h corresponds to Huffman only compression, and the letter R corresponds to Run Length Encoding. See defaultInit2_() for further details.
If fd refers to an uncompressed file, and mode refers to a read mode, gzdopen() shall attempt to open the file and return a gzFile object suitable for reading directly from the file without any decompression.
If mode
is NULL, or if mode does not contain
one of r, w, or a,
gzdopen() shall return Z_NULL
,
and need not set any other error condition.
On success, gzdopen() shall return a
gzFile object. On failure,
gzdopen() shall return Z_NULL
and
may set errno
accordingly.
Note: At version 1.2.2,
zlib
does not seterrno
for several error conditions. Applications may not be able to determine the cause of an error.
If file was open for reading and end of file has been reached, gzeof() shall return 1. Otherwise, gzeof() shall return 0.
The gzerror() function shall return a string describing the last error to have occurred associated with the open compressed file stream referred to by file. It shall also set the location referenced by errnum to an integer value that further identifies the error.
The gzerror() function shall return a string that describes the last error associated with the given file compressed file stream. This string shall have the format "%s: %s", with the name of the file, followed by a colon, a space, and the description of the error. If the compressed file stream was opened by a call to gzdopen(), the format of the filename is unspecified.
Rationale: Although in all current implementations of libz file descriptors are named "<fd:%d>", the code suggests that this is for debugging purposes only, and may change in a future release.
It is unspecified if the string returned is determined by the setting
of the LC_MESSAGES
category in the current locale.
The gzflush() function shall flush pending output to the compressed file stream identified by file, which must be open for writing.
The parameter flush determines which compressed bits
are added to the output file.
If flush is Z_NO_FLUSH
,
gzflush()
may return with some data pending output, and not yet written to the file.
If flush is Z_SYNC_FLUSH
,
gzflush() shall flush all pending output to
file and align the output to a byte
boundary.
There may still be data pending compression that is not flushed.
If flush is Z_FULL_FLUSH
,
all output shall be flushed, as for Z_SYNC_FLUSH
,
and the compression state shall be reset.
There may still be data pending compression that is not flushed.
Rationale:
Z_SYNC_FLUSH
is intended to ensure that the compressed data contains all the data compressed so far, and allows a decompressor to reconstruct all of the input data.Z_FULL_FLUSH
allows decompression to restart from this point if the previous compressed data has been lost or damaged. Flushing is likely to degrade the performance of the compression system, and should only be used where necessary.
If flush is set to Z_FINISH
,
all pending uncompressed data shall be compressed
and all output shall be flushed.
On success, gzflush() shall return the value Z_OK. Otherwise gzflush() shall return a value to indicate the error, and may set the error number associated with the compressed file stream file.
Note: If flush is set to
Z_FINISH
and the flush operation is successful, gzflush() will return Z_OK, but the compressed file stream error value may be set toZ_STREAM_END
.
On error, gzwrite() shall return an error value, and may set the error number associated with the stream identified by file to indicate the error. Applications may use gzerror() to access this error value.
Z_ERRNO
An underlying base library function has indicated an error.
The global variable errno
may be examined
for further information.
Z_STREAM_ERROR
The stream is invalid, is not open for writing, or is in an invalid state.
Z_BUF_ERROR
no compression progress is possible (see deflate()).
Z_MEM_ERROR
Insufficient memory available to compress.
The gzgetc() function shall read the next single character from the compressed file stream referenced by file, which shall have been opened in a read mode (see gzopen() and gzdopen()).
On success, gzgetc() shall return the uncompressed character read, otherwise, on end of file or error, gzgetc() shall return -1.
On end of file or error, gzgetc() shall return -1. Further information can be found by calling gzerror() with a pointer to the compressed file stream.
The gzgets() function shall attempt to read data from the compressed file stream file, uncompressing it into buf until either len-1 bytes have been inserted into buf, or until a newline character has been uncompressed into buf. A null byte shall be appended to the uncompressed data. The file shall have been opened in for reading (see gzopen() and gzdopen()).
On success, gzgets() shall return a pointer to buf. Otherwise, gzgets() shall return Z_NULL. Applications may examine the cause using gzerror().
On error, gzgets() shall return Z_NULL. The following conditions shall always be treated as an error:
file is NULL ,
or does not refer to a file open for reading; |
buf is NULL ; |
len is less than or equal to zero. |
The gzopen() function shall open the compressed file named by path. The mode argument is based on that of fopen(), but the mode parameter may also contain the following characters:
set the compression level to digit. A low value (e.g. 1) means high speed, while a high value (e.g. 9) means high compression. A compression level of 0 (zero) means no compression. See defaultInit2_() for further details.
set the compression strategy to [fhR]. The letter f corresponds to filtered data, the letter h corresponds to Huffman only compression, and the letter R corresponds to Run Length Encoding. See defaultInit2_() for further details.
If path refers to an uncompressed file, and mode refers to a read mode, gzopen() shall attempt to open the file and return a gzFile object suitable for reading directly from the file without any decompression.
If path or mode
is NULL, or if mode does not contain
one of r, w, or a,
gzopen() shall return Z_NULL
,
and need not set any other error condition.
The gzFile object is also referred to as a compressed file stream.
gzopen("file.gz", "w6h"); |
On success, gzopen() shall return a
gzFile object (also known as a compressed
file stream). On failure,
gzopen() shall return Z_NULL
and
may set errno
accordingly.
Note: At version 1.2.2,
zlib
does not seterrno
for several error conditions. Applications may not be able to determine the cause of an error.
The gzprintf() function shall format data as for fprintf(), and write the resulting string to the compressed file stream file.
The gzprintf() function
shall return the number of uncompressed bytes
actually written, or a value less than or equal to
0
in the event of an error.
If file is NULL
, or refers to a
compressed file stream that has not been opened for writing,
gzprintf() shall return Z_STREAM_ERROR.
Otherwise, errors are as for gzwrite().
The gzputc() function shall write the single character c, converted from integer to unsigned character, to the compressed file referenced by file, which shall have been opened in a write mode (see gzopen() and gzdopen()).
On success, gzputc() shall return the value written, otherwise gzputc() shall return -1.
The gzputs() function shall write the null terminated string s to the compressed file referenced by file, which shall have been opened in a write mode (see gzopen() and gzdopen()). The terminating null character shall not be written. The gzputs() function shall return the number of uncompressed bytes actually written.
On success, gzputs() shall return the number of uncompressed
bytes actually written to file.
On error gzputs() shall return a value
less than or equal to 0
.
Applications may examine the cause using gzerror().
On error, gzputs() shall set
the error number associated with the stream identified by
file
to indicate the error. Applications should use gzerror()
to access this error value.
If file is NULL
,
gzputs() shall return Z_STREAM_ERR
.
Z_ERRNO
An underlying base library function has indicated an error.
The global variable errno
may be examined
for further information.
Z_STREAM_ERROR
The stream is invalid, is not open for writing, or is in an invalid state.
Z_BUF_ERROR
no compression progress is possible (see deflate()).
Z_MEM_ERROR
Insufficient memory available to compress.
The gzread() function shall read data from the compressed file referenced by file, which shall have been opened in a read mode (see gzopen() and gzdopen()). The gzread() function shall read data from file, and uncompress it into buf. At most, len bytes of uncompressed data shall be copied to buf. If the file is not compressed, gzread() shall simply copy data from file to buf without alteration.
On success, gzread() shall return the number of bytes
decompressed into buf.
If gzread() returns 0
,
either the end-of-file has been reached
or an underlying read error has occurred. Applications
should use gzerror() or gzeof()
to determine which occurred.
On other errors,
gzread() shall return a value less than
0
and
and applications may examine the cause using gzerror().
On error, gzread() shall set the error number associated with the stream identified by file to indicate the error. Applications should use gzerror() to access this error value.
Z_ERRNO
An underlying base library function has indicated an error.
The global variable errno
may be examined
for further information.
Z_STREAM_END
End of file has been reached on input.
Z_DATA_ERROR
A CRC error occurred when reading data; the file is corrupt.
Z_STREAM_ERROR
The stream is invalid, or is in an invalid state.
Z_NEED_DICT
A dictionary is needed (see inflateSetDictionary()).
Z_MEM_ERROR
Insufficient memory available to decompress.
The gzrewind() function shall set the starting position for the next read on compressed file stream file to the beginning of file. file must be open for reading.
gzrewind() is equivalent to
(int)gzseek(file, 0L, SEEK_SET) |
On success, gzrewind() shall return 0. On error, gzrewind() shall return -1, and may set the error value for file accordingly.
On error, gzrewind() shall return -1
,
indicating that file is
NULL
, or does not represent
an open compressed file stream, or represents a compressed file stream
that is open for writing and is not currently at the beginning of file.
The gzseek() function shall set the file-position indicator for the compressed file stream file. The file-position indicator controls where the next read or write operation on the compressed file stream shall take place. The offset indicates a byte offset in the uncompressed data. The whence parameter may be one of:
SEEK_SET
the offset is relative to the start of the uncompressed data.
SEEK_CUR
the offset is relative to the current positition in the uncompressed data.
Note: The value
SEEK_END
need not be supported.
If the file is open for writing, the new offset must be greater than or equal to the current offset. In this case, gzseek() shall compress a sequence of null bytes to fill the gap from the previous offset to the new offset.
On success, gzseek() shall return the resulting offset in the file expressed as a byte position in the uncompressed data stream. On error, gzseek() shall return -1, and may set the error value for file accordingly.
On error, gzseek() shall return -1. The following conditions shall always result in an error:
file is NULL
file does not represent an open compressed file stream.
file refers to a compressed file stream that is open for writing, and the newly computed offset is less than the current offset.
The newly computed offset is less than zero.
whence is not one of the supported values.
If file is open for reading, the implementation may still need to uncompress all of the data up to the new offset. As a result, gzseek() may be extremely slow in some circumstances.
The gzsetparams() function shall set the compression level and compression strategy on the compressed file stream referenced by file. The compressed file stream shall have been opened in a write mode. The level and strategy are as defined in deflateInit2_. If there is any data pending writing, it shall be flushed before the parameters are updated.
On error, gzsetparams() shall return one of the following error indications:
Z_STREAM_ERROR
Invalid parameter, or file not open for writing.
Z_BUF_ERROR
An internal inconsistency was detected while flushing the previous buffer.
The gztell() function shall return the starting position for the next read or write operation on compressed file stream file. This position represents the number of bytes from the beginning of file in the uncompressed data.
gztell() is equivalent to
gzseek(file, 0L, SEEK_SET) |
gztell() shall return the current offset in the file expressed as a byte position in the uncompressed data stream. On error, gztell() shall return -1, and may set the error value for file accordingly.
On error, gztell() shall return -1
,
indicating that file is
NULL
, or does not represent
an open compressed file stream.
The gzwrite() function shall write data to the compressed file referenced by file, which shall have been opened in a write mode (see gzopen() and gzdopen()). On entry, buf shall point to a buffer containing lenbytes of uncompressed data. The gzwrite() function shall compress this data and write it to file. The gzwrite() function shall return the number of uncompressed bytes actually written.
On success, gzwrite() shall return the number of
uncompressed bytes actually written to file.
On error gzwrite() shall return a value
less than or equal to 0
.
Applications may examine the cause using gzerror().
On error, gzwrite() shall set the error number associated with the stream identified by file to indicate the error. Applications should use gzerror() to access this error value.
Z_ERRNO
An underlying base library function has indicated an error.
The global variable errno
may be examined
for further information.
Z_STREAM_ERROR
The stream is invalid, is not open for writing, or is in an invalid state.
Z_BUF_ERROR
no compression progress is possible (see deflate()).
Z_MEM_ERROR
Insufficient memory available to compress.
The inflate() function shall attempt to decompress data until either the input buffer is empty or the output buffer is full. The stream references a z_stream structure. Before the first call to inflate(), this structure should have been initialized by a call to inflateInit2_().
Note: inflateInit2_() is only in the binary standard; source level applications should initialize stream via a call to inflateInit() or inflateInit2().
next_in
should point to the data to be decompressed.
avail_in
should contain the number of bytes of data in the
buffer referenced by next_in
.
next_out
should point to a buffer where decompressed data may be placed.
avail_out
should contain the size in bytes of the
buffer referenced by next_out
The inflate() function shall perform one or both of the following actions:
Decompress input data from next_in
and update next_in
,
avail_in
and
total_in
to reflect the data that has been
decompressed.
Fill the output buffer referenced by next_out
,
and update next_out
,
avail_out
, and
total_out
to reflect the decompressed data that
has been placed there. If flush is not
Z_NO_FLUSH
, and
avail_out
indicates that there is still space in
output buffer, this action shall always occur (see below for further details).
The inflate() function shall return when either
avail_in
reaches zero (indicating that all the input
data has been compressed), or avail_out
reaches
zero (indicating that the output buffer is full).
On success, the inflate() function shall set the
adler
field of the stream
to the Adler-32 checksum of all the input data compressed
so far (represented by total_in
).
The parameter flush determines when uncompressed bytes
are added to the output buffer in next_out
.
If flush is Z_NO_FLUSH
,
inflate()
may return with some data pending output, and not yet added to the
output buffer.
If flush is Z_SYNC_FLUSH
,
inflate() shall flush all pending output to
next_out
, and update
next_out
and avail_out
accordingly.
If flush is set to Z_BLOCK
,
inflate() shall stop adding data to the output
buffer if and when the next compressed block boundary is reached
(see RFC 1951: DEFLATE Compressed Data Format Specification).
If flush is set to Z_FINISH
,
all of the compressed input shall be decompressed and added to
the output. If there is insufficient output space (i.e. the compressed
input data uncompresses to more than avail_out
bytes), then inflate() shall fail and return
Z_BUF_ERROR.
On success, inflate() shall return Z_OK if decompression progress has been made, or Z_STREAM_END if all of the input data has been decompressed and there was sufficient space in the output buffer to store the uncompressed result. On error, inflate() shall return a value to indicate the error.
Note: If inflate() returns Z_OK and has set
avail_out
to zero, the function should be called again with the same value for flush, and with updatednext_out
andavail_out
until inflate() returns with either Z_OK or Z_STREAM_END and a non-zeroavail_out
.
On success, inflate() shall set the
adler
to the Adler-32 checksum of
the output produced so far (i.e. total_out
bytes).
On error, inflate() shall return a value as described
below, and may set the msg
field of
stream to point to a string describing the error:
Z_BUF_ERROR
No progress is possible; either avail_in
or avail_out
was zero.
Z_MEM_ERROR
Insufficient memory.
Z_STREAM_ERROR
The state (as represented in stream) is inconsistent, or
stream was NULL
.
Z_NEED_DICT
A preset dictionary is required. The adler
field shall be set to the Adler-32 checksum of the dictionary chosen
by the compressor.
The inflateEnd() function shall free all allocated state information referenced by stream. All pending output is discarded, and unprocessed input is ignored.
On success, inflateEnd() shall return Z_OK. Otherwise it shall return Z_STREAM_ERROR to indicate the error.
On error, inflateEnd() shall return Z_STREAM_ERROR. The following conditions shall be treated as an error:
The state in stream is inconsistent.
stream
is NULL
.
The zfree
function pointer is
NULL
.
The inflateInit2_() function shall initialize the decompression system. On entry, strm shall refer to a user supplied z_stream object (a z_stream_s structure). The following fields shall be set on entry:
zalloc
a pointer to an alloc_func function, used to allocate state information.
If this is NULL
, a default allocation function will be used.
zfree
a pointer to a free_func function, used to free memory allocated by the
zalloc
function. If this is NULL
a default free function will be used.
opaque
If alloc_func
is not NULL
,
opaque
is a user supplied pointer to data that will be passed to the
alloc_func
and free_func
functions.
If the version requested is not compatible with the version
implemented, or if the size of the z_stream_s structure
provided in stream_size does not match the size in the library
implementation, inflateInit2_() shall fail, and return
Z_VERSION_ERROR
.
The windowBits parameter shall be a base 2 logarithm of the maximum
window
size to use, and shall be a value between 8
and 15
.
If the input data was compressed with a larger window size, subsequent attempts to
decompress this data will fail with Z_DATA_ERROR
, rather than try to
allocate a larger window.
The inflateInit2_() function is not in the source standard; it is only in the binary standard. Source applications should use the inflateInit2() macro.
On success, the inflateInit2_() function shall return
Z_OK
.
Otherwise, inflateInit2_() shall return
a value as described below to indicate the error.
On error, inflateInit2_() shall return one of the following error indicators:
Z_STREAM_ERROR
Invalid parameter.
Z_MEM_ERROR
Insufficient memory available.
Z_VERSION_ERROR
The version requested is not compatible with the library version, or the z_stream size differs from that used by the library.
In addition, the msg
field of the strm
may be set to an error message.
The inflateInit_() function shall initialize the decompression system. On entry, stream shall refer to a user supplied z_stream object (a z_stream_s structure). The following fields shall be set on entry:
zalloc
a pointer to an alloc_func function, used to allocate state information.
If this is NULL
, a default allocation function will be used.
zfree
a pointer to a free_func function, used to free memory allocated by the
zalloc
function. If this is NULL
a default free function will be used.
opaque
If alloc_func
is not NULL
,
opaque
is a user supplied pointer to data that will be passed to the
alloc_func
and free_func
functions.
If the version requested is not compatible with the version
implemented, or if the size of the z_stream_s structure
provided in stream_size does not match the size in the library
implementation, inflateInit_() shall fail, and return
Z_VERSION_ERROR
.
The inflateInit_() function is not in the source standard; it is only in the binary standard. Source applications should use the inflateInit() macro.
The inflateInit_() shall be equivalent to
inflateInit2_(strm, DEF_WBITS, version, stream_size); |
On success, the inflateInit_() function shall return
Z_OK
.
Otherwise, inflateInit_() shall return
a value as described below to indicate the error.
On error, inflateInit_() shall return one of the following error indicators:
Z_STREAM_ERROR
Invalid parameter.
Z_MEM_ERROR
Insufficient memory available.
Z_VERSION_ERROR
The version requested is not compatible with the library version, or the z_stream size differs from that used by the library.
In addition, the msg
field of the strm
may be set to an error message.
The inflateReset() function shall reset all state
associated with stream.
All pending output shall be discarded, and the counts of processed
bytes (total_in
and
total_out
) shall be reset to zero.
On success, inflateReset() shall return Z_OK. Otherwise it shall return Z_STREAM_ERROR to indicate the error.
On error, inflateReset() shall return Z_STREAM_ERROR. The following conditions shall be treated as an error:
The state in stream is inconsistent or inappropriate.
stream
is NULL
.
The inflateSetDictionary() function shall initialize the decompression dictionary associated with stream using the dictlen bytes referenced by dictionary.
The inflateSetDictionary() function should be called immediately after a call to inflate() has failed with return value Z_NEED_DICT. The dictionary must have the same Adler-32 checksum as the dictionary used for the compression (see deflateSetDictionary()).
stream shall reference an initialized decompression
stream, with total_in
zero (i.e. no data
has been decompressed since the stream was initialized).
On success, inflateSetDictionary() shall return Z_OK. Otherwise it shall return a value as indicated below.
On error, inflateSetDictionary() shall return a value as described below:
Z_STREAM_ERROR
The state in stream is inconsistent, or
stream
was NULL
.
Z_DATA_ERROR
The Adler-32 checksum of the supplied dictionary does not match that used for the compression.
The application should provide a dictionary consisting of strings {{{ed note: do we really mean "strings"? Null terminated?}}} that are likely to be encountered in the data to be compressed. The application should ensure that the dictionary is sorted such that the most commonly used strings occur at the end of the dictionary.
The use of a dictionary is optional; however if the data to be compressed is relatively short and has a predictable structure, the use of a dictionary can substantially improve the compression ratio.
The inflateSync() function shall advance through the
compressed data in stream, skipping any invalid
compressed data, until the next full flush point is reached, or all
input is exhausted. See the
description for deflate() with flush level
Z_FULL_FLUSH
.
No output is placed in next_out
.
On success, inflateSync() shall return
Z_OK, and update the
next_in
,, avail_in
, and, total_in
fields of stream to reflect the number
of bytes of compressed data that have been skipped.
Otherwise, inflateSync()
shall return a value as described below to indicate the
error.
On error, inflateSync() shall return a value as described below:
Z_STREAM_ERROR
The state (as represented in stream) is inconsistent, or
stream was NULL
.
Z_BUF_ERROR
There is no data available to skip over.
Z_DATA_ERROR
No sync point was found.
The inflateSyncPoint() function shall return a non-zero calue if the compressed data stream referenced by stream is at a synchronization point.
If the compressed data in stream is at
a synchronization point (see deflate()
with a flush level of Z_SYNC_FLUSH
or
Z_FULL_FLUSH
), inflateSyncPoint()
shall return a non-zero value, other than Z_STREAM_ERROR
.
Otherwise, if the stream is valid,
inflateSyncPoint() shall return 0.
If stream is invalid, or in an invalid state,
inflateSyncPoint() shall return
Z_STREAM_ERROR to indicate the error.
On error, inflateSyncPoint() shall return a value as described below:
Z_STREAM_ERROR
The state (as represented in stream) is inconsistent, or
stream was NULL
.
The uncompress() function shall attempt to uncompress sourceLen bytes of data in the buffer source, placing the result in the buffer dest.
On entry, destLen should point to a value describing the size of the dest buffer. The application should ensure that this value is large enough to hold the entire uncompressed data.
Note: The LSB does not describe any mechanism by which a compressor can communicate the size required to the uncompressor.
On success, uncompress() shall return Z_OK. Otherwise, uncompress() shall return a value to indicate the error.
On error, uncompress() shall return a value as described below:
Z_BUF_ERROR
The buffer dest was not large enough to hold the uncompressed data.
Z_MEM_ERROR
Insufficient memory.
Z_DATA_ERROR
The compressed data (referenced by source) was corrupted.
The zError() function shall return the string identifying the error associated with err. This allows for conversion from error code to string for functions such as compress() and uncompress(), that do not always set the string version of an error.
The zError() function shall return a the string identifying the error associated with err, or NULL if err is not a valid error code.
It is unspecified if the string returned is determined by the setting
of the LC_MESSAGES
category in the current locale.
The zlibVersion() function shall return the string identifying the interface version at the time the library was built.
Applications should compare the value returned from
zlibVersion() with the macro constant
ZLIB_VERSION
for compatibility.
Table 2-3 defines the library name and shared object name for the libncurses library
The behavior of the interfaces in this library is specified by the following specifications:
X/Open Curses |
An LSB conforming implementation shall provide the generic functions for Curses specified in Table 2-4, with the full mandatory functionality as described in the referenced underlying specification.
Table 2-4. libncurses - Curses Function Interfaces
addch [1] | has_ic [1] | mvwaddchnstr [1] | scr_init [1] | vwscanw [1] |
addchnstr [1] | has_il [1] | mvwaddchstr [1] | scr_restore [1] | waddch [1] |
addchstr [1] | hline [1] | mvwaddnstr [1] | scr_set [1] | waddchnstr [1] |
addnstr [1] | idcok [1] | mvwaddstr [1] | scrl [1] | waddchstr [1] |
addstr [1] | idlok [1] | mvwchgat [1] | scroll [1] | waddnstr [1] |
attr_get [1] | immedok [1] | mvwdelch [1] | scrollok [1] | waddstr [1] |
attr_off [1] | inch [1] | mvwgetch [1] | set_curterm [1] | wattr_get [1] |
attr_on [1] | inchnstr [1] | mvwgetnstr [1] | set_term [1] | wattr_off [1] |
attr_set [1] | inchstr [1] | mvwgetstr [1] | setscrreg [1] | wattr_on [1] |
attroff [1] | init_color [1] | mvwhline [1] | setupterm [1] | wattr_set [1] |
attron [1] | init_pair [1] | mvwin [1] | slk_attr_set [1] | wattroff [1] |
attrset [1] | initscr [1] | mvwinch [1] | slk_attroff [1] | wattron [1] |
baudrate [1] | innstr [1] | mvwinchnstr [1] | slk_attron [1] | wattrset [1] |
beep [1] | insch [1] | mvwinchstr [1] | slk_attrset [1] | wbkgd [1] |
bkgd [1] | insdelln [1] | mvwinnstr [1] | slk_clear [1] | wbkgdset [1] |
bkgdset [1] | insertln [1] | mvwinsch [1] | slk_color [1] | wborder [1] |
border [1] | insnstr [1] | mvwinsnstr [1] | slk_init [1] | wchgat [1] |
box [1] | insstr [1] | mvwinsstr [1] | slk_label [1] | wclear [1] |
can_change_color [1] | instr [1] | mvwinstr [1] | slk_noutrefresh [1] | wclrtobot [1] |
cbreak [1] | intrflush [1] | mvwprintw [1] | slk_refresh [1] | wclrtoeol [1] |
chgat [1] | is_linetouched [1] | mvwscanw [1] | slk_restore [1] | wcolor_set [1] |
clear [1] | is_wintouched [1] | mvwvline [1] | slk_set [1] | wcursyncup [1] |
clearok [1] | isendwin [1] | napms [1] | slk_touch [1] | wdelch [1] |
clrtobot [1] | keyname [1] | newpad [1] | standend [1] | wdeleteln [1] |
clrtoeol [1] | keypad [1] | newterm [1] | standout [1] | wechochar [1] |
color_content [1] | killchar [1] | newwin [1] | start_color [1] | werase [1] |
color_set [1] | leaveok [1] | nl [1] | subpad [1] | wgetch [1] |
copywin [1] | longname [1] | nocbreak [1] | subwin [1] | wgetnstr [1] |
curs_set [1] | meta [1] | nodelay [1] | syncok [1] | wgetstr [1] |
def_prog_mode [1] | move [1] | noecho [1] | termattrs [1] | whline [1] |
def_shell_mode [1] | mvaddch [1] | nonl [1] | termname [1] | winch [1] |
del_curterm [1] | mvaddchnstr [1] | noqiflush [1] | tgetent [1] | winchnstr [1] |
delay_output [1] | mvaddchstr [1] | noraw [1] | tgetflag [1] | winchstr [1] |
delch [1] | mvaddnstr [1] | notimeout [1] | tgetnum [1] | winnstr [1] |
deleteln [1] | mvaddstr [1] | overlay [1] | tgetstr [1] | winsch [1] |
delscreen [1] | mvchgat [1] | overwrite [1] | tgoto [1] | winsdelln [1] |
delwin [1] | mvcur [1] | pair_content [1] | tigetflag [1] | winsertln [1] |
derwin [1] | mvdelch [1] | pechochar [1] | tigetnum [1] | winsnstr [1] |
doupdate [1] | mvderwin [1] | pnoutrefresh [1] | tigetstr [1] | winsstr [1] |
dupwin [1] | mvgetch [1] | prefresh [1] | timeout [1] | winstr [1] |
echo [1] | mvgetnstr [1] | printw [1] | touchline [1] | wmove [1] |
echochar [1] | mvgetstr [1] | putp [1] | touchwin [1] | wnoutrefresh [1] |
endwin [1] | mvhline [1] | putwin [1] | tparm [1] | wprintw [1] |
erase [1] | mvinch [1] | qiflush [1] | tputs [1] | wredrawln [1] |
erasechar [1] | mvinchnstr [1] | raw [1] | typeahead [1] | wrefresh [1] |
filter [1] | mvinchstr [1] | redrawwin [1] | unctrl [1] | wscanw [1] |
flash [1] | mvinnstr [1] | refresh [1] | ungetch [1] | wscrl [1] |
flushinp [1] | mvinsch [1] | reset_prog_mode [1] | untouchwin [1] | wsetscrreg [1] |
getbkgd [1] | mvinsnstr [1] | reset_shell_mode [1] | use_env [1] | wstandend [1] |
getch [1] | mvinsstr [1] | resetty [1] | vidattr [1] | wstandout [1] |
getnstr [1] | mvinstr [1] | restartterm [1] | vidputs [1] | wsyncdown [1] |
getstr [1] | mvprintw [1] | ripoffline [1] | vline [1] | wsyncup [1] |
getwin [1] | mvscanw [1] | savetty [1] | vw_printw [1] | wtimeout [1] |
halfdelay [1] | mvvline [1] | scanw [1] | vw_scanw [1] | wtouchln [1] |
has_colors [1] | mvwaddch [1] | scr_dump [1] | vwprintw [1] | wvline [1] |
Referenced Specification(s)
[1]. X/Open Curses
An LSB conforming implementation shall provide the generic data interfaces for Curses specified in Table 2-5, with the full mandatory functionality as described in the referenced underlying specification.
Table 2-5. libncurses - Curses Data Interfaces
COLORS [1] | COLS [1] | acs_map [1] | curscr [1] | |
COLOR_PAIRS [1] | LINES [1] | cur_term [1] | stdscr [1] |
Referenced Specification(s)
[1]. X/Open Curses
This section defines global identifiers and their values that are associated with interfaces contained in libncurses. These definitions are organized into groups that correspond to system headers. This convention is used as a convenience for the reader, and does not imply the existence of these headers, or their content.
These definitions are intended to supplement those provided in the referenced underlying specifications.
This specification uses ISO/IEC 9899 C Language as the reference programming language, and data definitions are specified in ISO C format. The C language is used here as a convenient notation. Using a C language description of these data objects does not preclude their use by other programming languages.
#define ERR (-1) #define OK (0) #define ACS_RARROW (acs_map['+']) #define ACS_LARROW (acs_map[',']) #define ACS_UARROW (acs_map['-']) #define ACS_DARROW (acs_map['.']) #define ACS_BLOCK (acs_map['0']) #define ACS_CKBOARD (acs_map['a']) #define ACS_DEGREE (acs_map['f']) #define ACS_PLMINUS (acs_map['g']) #define ACS_BOARD (acs_map['h']) #define ACS_LANTERN (acs_map['i']) #define ACS_LRCORNER (acs_map['j']) #define ACS_URCORNER (acs_map['k']) #define ACS_ULCORNER (acs_map['l']) #define ACS_LLCORNER (acs_map['m']) #define ACS_PLUS (acs_map['n']) #define ACS_S1 (acs_map['o']) #define ACS_HLINE (acs_map['q']) #define ACS_S9 (acs_map['s']) #define ACS_LTEE (acs_map['t']) #define ACS_RTEE (acs_map['u']) #define ACS_BTEE (acs_map['v']) #define ACS_TTEE (acs_map['w']) #define ACS_VLINE (acs_map['x']) #define ACS_DIAMOND (acs_map['`']) #define ACS_BULLET (acs_map['~']) #define getmaxyx(win,y,x) (y=(win)?((win)->_maxy+1):ERR,x=(win)?((win)->_maxx+1):ERR) #define getbegyx(win,y,x) (y=(win)?(win)->_begy:ERR,x=(win)?(win)->_begx:ERR) #define getyx(win,y,x) (y=(win)?(win)->_cury:ERR,x=(win)?(win)->_curx:ERR) #define getparyx(win,y,x) (y=(win)?(win)->_pary:ERR,x=(win)?(win)->_parx:ERR) #define WA_ALTCHARSET A_ALTCHARSET #define WA_ATTRIBUTES A_ATTRIBUTES #define WA_BLINK A_BLINK #define WA_BOLD A_BOLD #define WA_DIM A_DIM #define WA_HORIZONTAL A_HORIZONTAL #define WA_INVIS A_INVIS #define WA_LEFT A_LEFT #define WA_LOW A_LOW #define WA_NORMAL A_NORMAL #define WA_PROTECT A_PROTECT #define WA_REVERSE A_REVERSE #define WA_RIGHT A_RIGHT #define WA_STANDOUT A_STANDOUT #define WA_TOP A_TOP #define WA_UNDERLINE A_UNDERLINE #define WA_VERTICAL A_VERTICAL #define A_REVERSE NCURSES_BITS(1UL,10) #define COLOR_BLACK 0 #define COLOR_RED 1 #define COLOR_GREEN 2 #define COLOR_YELLOW 3 #define COLOR_BLUE 4 #define COLOR_MAGENTA 5 #define COLOR_CYAN 6 #define COLOR_WHITE 7 #define _SUBWIN 0x01 #define _ENDLINE 0x02 #define _FULLWIN 0x04 #define _ISPAD 0x10 #define _HASMOVED 0x20 typedef unsigned char bool; typedef unsigned long int chtype; typedef struct screen SCREEN; typedef struct _win_st WINDOW; typedef chtype attr_t; typedef struct { attr_t attr; wchar_t chars[5]; } cchar_t; struct pdat { short _pad_y; short _pad_x; short _pad_top; short _pad_left; short _pad_bottom; short _pad_right; } ; struct _win_st { short _cury; short _curx; short _maxy; short _maxx; short _begy; short _begx; short _flags; attr_t _attrs; chtype _bkgd; bool _notimeout; bool _clear; bool _leaveok; bool _scroll; bool _idlok; bool _idcok; bool _immed; bool _sync; bool _use_keypad; int _delay; struct ldat *_line; short _regtop; short _regbottom; int _parx; int _pary; WINDOW *_parent; struct pdat _pad; short _yoffset; cchar_t _bkgrnd; } ; #define KEY_CODE_YES 0400 #define KEY_BREAK 0401 #define KEY_MIN 0401 #define KEY_DOWN 0402 #define KEY_UP 0403 #define KEY_LEFT 0404 #define KEY_RIGHT 0405 #define KEY_HOME 0406 #define KEY_BACKSPACE 0407 #define KEY_F0 0410 #define KEY_DL 0510 #define KEY_IL 0511 #define KEY_DC 0512 #define KEY_IC 0513 #define KEY_EIC 0514 #define KEY_CLEAR 0515 #define KEY_EOS 0516 #define KEY_EOL 0517 #define KEY_SF 0520 #define KEY_SR 0521 #define KEY_NPAGE 0522 #define KEY_PPAGE 0523 #define KEY_STAB 0524 #define KEY_CTAB 0525 #define KEY_CATAB 0526 #define KEY_ENTER 0527 #define KEY_SRESET 0530 #define KEY_RESET 0531 #define KEY_PRINT 0532 #define KEY_LL 0533 #define KEY_A1 0534 #define KEY_A3 0535 #define KEY_B2 0536 #define KEY_C1 0537 #define KEY_C3 0540 #define KEY_BTAB 0541 #define KEY_BEG 0542 #define KEY_CANCEL 0543 #define KEY_CLOSE 0544 #define KEY_COMMAND 0545 #define KEY_COPY 0546 #define KEY_CREATE 0547 #define KEY_END 0550 #define KEY_EXIT 0551 #define KEY_FIND 0552 #define KEY_HELP 0553 #define KEY_MARK 0554 #define KEY_MESSAGE 0555 #define KEY_MOVE 0556 #define KEY_NEXT 0557 #define KEY_OPEN 0560 #define KEY_OPTIONS 0561 #define KEY_PREVIOUS 0562 #define KEY_REDO 0563 #define KEY_REFERENCE 0564 #define KEY_REFRESH 0565 #define KEY_REPLACE 0566 #define KEY_RESTART 0567 #define KEY_RESUME 0570 #define KEY_SAVE 0571 #define KEY_SBEG 0572 #define KEY_SCANCEL 0573 #define KEY_SCOMMAND 0574 #define KEY_SCOPY 0575 #define KEY_SCREATE 0576 #define KEY_SDC 0577 #define KEY_SDL 0600 #define KEY_SELECT 0601 #define KEY_SEND 0602 #define KEY_SEOL 0603 #define KEY_SEXIT 0604 #define KEY_SFIND 0605 #define KEY_SHELP 0606 #define KEY_SHOME 0607 #define KEY_SIC 0610 #define KEY_SLEFT 0611 #define KEY_SMESSAGE 0612 #define KEY_SMOVE 0613 #define KEY_SNEXT 0614 #define KEY_SOPTIONS 0615 #define KEY_SPREVIOUS 0616 #define KEY_SPRINT 0617 #define KEY_SREDO 0620 #define KEY_SREPLACE 0621 #define KEY_SRIGHT 0622 #define KEY_SRSUME 0623 #define KEY_SSAVE 0624 #define KEY_SSUSPEND 0625 #define KEY_SUNDO 0626 #define KEY_SUSPEND 0627 #define KEY_UNDO 0630 #define KEY_MOUSE 0631 #define KEY_RESIZE 0632 #define KEY_MAX 0777 #define PAIR_NUMBER(a) (((a)& A_COLOR)>>8) #define NCURSES_BITS(mask,shift) ((mask)<<((shift)+8)) #define A_CHARTEXT (NCURSES_BITS(1UL,0)-1UL) #define A_NORMAL 0L #define NCURSES_ATTR_SHIFT 8 #define A_COLOR NCURSES_BITS(((1UL)<<8)-1UL,0) #define A_BLINK NCURSES_BITS(1UL,11) #define A_DIM NCURSES_BITS(1UL,12) #define A_BOLD NCURSES_BITS(1UL,13) #define A_ALTCHARSET NCURSES_BITS(1UL,14) #define A_INVIS NCURSES_BITS(1UL,15) #define A_PROTECT NCURSES_BITS(1UL,16) #define A_HORIZONTAL NCURSES_BITS(1UL,17) #define A_LEFT NCURSES_BITS(1UL,18) #define A_LOW NCURSES_BITS(1UL,19) #define A_RIGHT NCURSES_BITS(1UL,20) #define A_TOP NCURSES_BITS(1UL,21) #define A_VERTICAL NCURSES_BITS(1UL,22) #define A_STANDOUT NCURSES_BITS(1UL,8) #define A_UNDERLINE NCURSES_BITS(1UL,9) #define COLOR_PAIR(n) NCURSES_BITS(n,0) #define A_ATTRIBUTES NCURSES_BITS(~(1UL-1UL),0) |
Table 2-6 defines the library name and shared object name for the libutil library
The behavior of the interfaces in this library is specified by the following specifications:
this specification |
An LSB conforming implementation shall provide the generic functions for Utility Functions specified in Table 2-7, with the full mandatory functionality as described in the referenced underlying specification.
Table 2-7. libutil - Utility Functions Function Interfaces
forkpty [1] | login_tty [1] | logwtmp [1] | ||
login [1] | logout [1] | openpty [1] |
Referenced Specification(s)
[1]. this specification
The following interfaces are included in libutil and are defined by this specification. Unless otherwise noted, these interfaces shall be included in the source standard.
Other interfaces listed above for libutil shall behave as described in the referenced base document.
The forkpty() function shall find and open a pseudo-terminal device pair in the same manner as the openpty() function. If a pseudo-terminal is available, forkpty() shall create a new process in the same manner as the fork() function, and prepares the new process for login in the same manner as login_tty().
If termp is not null,
it shall refer to a termios
structure that shall be used
to initialize the characteristics of the slave device.
If winp is not null, it
shall refer to a winsize
structure used to
initialize the window size of the
slave device.
On success, the parent process shall return the process id of the child, and the
child shall return 0. On error, no new process shall be created, -1 shall be
returned, and errno
shall be set appropriately.
On success, the parent process shall receive the file descriptor of the master
side of the pseudo-terminal in the location referenced by
amaster, and, if name is
not NULL, the filename of the slave device in
name.
Unable to create a new process.
There are no available pseudo-terminals.
Insufficient memory was available.
The login() function shall update the user accounting databases. The ut parameter shall reference a utmp structure for all fields except the following:
The ut_type
field shall be set to USER_PROCESS
.
The ut_pid
field shall be set to the process identifier
for the current process.
The ut_line
field shall be set to the name of the
controlling terminal device.
The name shall be found by examining the device associated with the
standard input, output and error streams in sequence, until one associated with
a terminal device is found.
If none of these streams refers to a terminal device, the
ut_line
field shall be set to "???"
.
If the terminal device is in the /dev directory
hierarchy, the ut_line
field shall not contain the leading
"/dev/"
, otherwise it shall be set to the final component
of the pathname of the device.
If the user
accounting database imposes a limit on the size of the
ut_line
field, it shall
truncate the name, but any such limit shall not be smaller than
UT_LINESIZE
(including a terminating null character).
The login_tty() function shall prepare the terminal device referenced by the file descriptor fdr. This function shall create a new session, make the terminal the controlling terminal for the current process, and set the standard input, output, and error streams of the current process to the terminal. If fdr is not the standard input, output or error stream, then login_tty() shall close fdr.
On success, login_tty() shall return zero; otherwise -1 is returned, and errno shall be set appropriately.
Given the device line,
the logout() function shall search
the user accounting database which is read by getutent()
for an entry with the corresponding line,
and with the type of USER_PROCESS
.
If a corresponding entry is located, it shall be updated as follows:
The ut_name
field shall be set to zeroes
(UT_NAMESIZE
NUL bytes).
The ut_host
field shall be set to zeroes
(UT_HOSTSIZE
NUL bytes).
The ut_tv
shall be set to the current
time of day.
The ut_type
field shall be set to
DEAD_PROCESS
.
On success, the logout() function shall return non-zero. Zero is returned if there was no entry to remove, or if the utmp file could not be opened or updated.
If the process has permission to update the user accounting databases, the logwtmp() function shall append a record to the user accounting database that records all logins and logouts. The record to be appended shall be constructed as follows:
The ut_line
field shall be initialized
from line.
If the user accounting database imposes a limit on the size of the
ut_line
field, it shall
truncate the value, but any such limit shall not be smaller than
UT_LINESIZE
(including a terminating null character).
The ut_name
field shall be initialized
from name.
If the user accounting database imposes a limit on the size of the
ut_name
field, it shall
truncate the value, but any such limit shall not be smaller than
UT_NAMESIZE
(including a terminating null character).
The ut_host
field shall be initialized
from host.
If the user accounting database imposes a limit on the size of the
ut_host
field, it shall
truncate the value, but any such limit shall not be smaller than
UT_HOSTSIZE
(including a terminating null character).
If the name parameter does not refer
to an empty string (i.e. ""
),
the ut_type
field shall be set to
USER_PROCESS
; otherwise the
ut_type
field shall be set to
DEAD_PROCESS
.
The ut_id
field shall be set to the
process identifier for the current process.
The ut_tv
field shall be set to the
current time of day.
Note: If a process does not have write access to the the user accounting database, the logwtmp() function will not update it. Since the function does not return any value, an application has no way of knowing whether it succeeded or failed.
The openpty()
function shall find an available pseudo-terminal
and return file descriptors for the master and slave devices in
the locations referenced by
amaster and aslave
respectively.
If name is not NULL,
the filename of the slave shall be placed in the user supplied buffer
referenced by name.
If termp is not NULL, it shall
point to a termios
structure used to initialize
the terminal parameters of the slave pseudo-terminal device.
If winp is not NULL, it shall
point to a winsize
structure used to initialize
the window size parameters of the slave pseudo-terminal device.
An LSB conforming implementation shall provide the commands and utilities as described in Table 3-1, with at least the behavior described as mandatory in the referenced underlying specification, with the following execptions:
If any operand (except one which follows --
) starts with a
hyphen, the behavior is unspecified.
Rationale (Informative): Applications should place options before operands, or use
--
, as needed. This text is needed because, by default, GNU option parsing differs from POSIX, unless the environment variablePOSIXLY_CORRECT
is set. For example, ls . -a in GNU ls means to list the current directory, showing all files (that is,"."
is an operand and-a
is an option). In POSIX,"."
and-a
are both operands, and the command means to list the current directory, and also the file named -a. Suggesting that applications rely on the setting of thePOSIXLY_CORRECT
environment variable, or try to set it, seems worse than just asking the applictions to invoke commands in ways which work with either the POSIX or GNU behaviors.
Table 3-1. Commands And Utilities
[ [1] | dmesg [2] | id [1] | more [2] | sleep [1] |
ar [2] | du [2] | install [2] | mount [2] | sort [1] |
at [2] | echo [2] | install_initd [2] | msgfmt [2] | split [1] |
awk [2] | ed [1] | ipcrm [2] | mv [1] | strip [1] |
basename [1] | egrep [2] | ipcs [2] | newgrp [2] | stty [1] |
batch [2] | env [1] | join [1] | nice [1] | su [2] |
bc [2] | expand [1] | kill [1] | nl [1] | sync [2] |
cat [1] | expr [1] | killall [2] | nohup [1] | tail [1] |
chfn [2] | false [1] | ln [1] | od [2] | tar [2] |
chgrp [2] | fgrep [2] | locale [1] | passwd [2] | tee [1] |
chmod [1] | file [2] | localedef [1] | paste [1] | test [1] |
chown [2] | find [2] | logger [1] | patch [2] | time [1] |
chsh [2] | fold [1] | logname [1] | pathchk [1] | touch [1] |
cksum [1] | fuser [2] | lp [1] | pax [1] | tr [1] |
cmp [1] | gencat [1] | lpr [2] | pidof [2] | true [1] |
col [2] | getconf [1] | ls [2] | pr [1] | tsort [1] |
comm [1] | gettext [2] | lsb_release [2] | printf [1] | tty [1] |
cp [1] | grep [2] | lsbinstall [2] | ps [1] | umount [2] |
cpio [2] | groupadd [2] | m4 [2] | pwd [1] | uname [1] |
crontab [2] | groupdel [2] | mailx [1] | remove_initd [2] | unexpand [1] |
csplit [1] | groupmod [2] | make [1] | renice [2] | uniq [1] |
cut [2] | groups [2] | man [1] | rm [1] | useradd [2] |
date [1] | gunzip [2] | md5sum [2] | rmdir [1] | userdel [2] |
dd [1] | gzip [2] | mkdir [1] | sed [2] | usermod [2] |
df [2] | head [1] | mkfifo [1] | sendmail [2] | wc [1] |
diff [1] | hostname [2] | mknod [2] | sh [1] | xargs [2] |
dirname [1] | iconv [1] | mktemp [2] | shutdown [2] |
Referenced Specification(s)
[1]. ISO POSIX (2003)
[2]. this specification
An LSB conforming implementation shall provide the shell built in utilities as described in Table 3-2, with at least the behavior described as mandatory in the referenced underlying specification, with the following execptions:
The built in commands and utilities shall be provided by the sh utility itself, and need not be implemented in a manner so that they can be accessed via the exec family of functions as defined in ISO POSIX (2003) and should not be invoked directly by those standard utilities that execute other utilities ( env, find, nice, nohup, time, xargs).
Rationale (Informative): Since the built in utilities must affect the environment of the calling process, they have no effect when executed as a file.
Referenced Specification(s)
[1]. ISO POSIX (2003)
This section contains descriptions for commands and utilities whose specified behavior in the LSB contradicts or extends the standards referenced. It also contains commands and utilities only required by the LSB and not specified by other standards.
ar is deprecated from the LSB and is expected to disappear from a future version of the LSB.
Rationale: The LSB generally does not include software development utilities nor does it specify .o and .a file formats.
ar is as specified in ISO POSIX (2003) but with differences as listed below.
need not be accepted.
has unspecified behavior.
has unspecified behavior; using -r is suggested.
is functionally equivalent to the -r option specified in ISO POSIX (2003).
need not be supported, but the '-d' option is equivalent.
need not be supported.
Certain aspects of internationalized regular expressions are optional; see Internationalization and Regular Expressions.
The specification for batch is as specified in ISO POSIX (2003), but with differences as listed below.
The bc language may be extended in an implementation defined manner. If an implementation supports extensions, it shall also support the additional options:
processes exactly the POSIX bc language.
gives warnings for extensions to POSIX bc.
chfn shall update the user database. An unprivileged user may only change the fields for their own account, a user with appropriate privileges may change the fields for any account.
The fields full_name and home_phone may contain any character except:
any control character |
comma |
colon |
equal sign |
If none of the options are selected, chfn operates in an interactive fashion. The prompts and expected input in interactive mode are unspecified and should not be relied upon.
As it is possible for the system to be configured to restrict which fields a non-privileged user is permitted to change, applications should be written to gracefully handle these situations.
sets the user's full name.
sets the user's home phone number.
The following two options are expected to be added in a future version of the LSB:
sets the user's office room number.
sets the user's office phone number.
Note that some implementations contain a "-o other" option which specifies an additional field called "other". Traditionally, this field is not subject to the constraints about legitimate characters in fields. Also, one traditionally shall have appropriate privileges to change the other field. At this point there is no consensus about whether it is desirable to specify the other field; applications may wish to avoid using it.
The "-w work_phone" field found in some implementations should be replaced by the "-p office_phone" field. The "-r room_number" field found in some implementations is the equivalent of the "-o office" option mentioned above; which one of these two options to specify will depend on implementation experience and the decision regarding the other field.
chsh changes the user login shell. This determines the name of the user's initial login command. An unprivileged user may only change the login shell for their own account, a user with appropriate privilege may change the login shell for any account specified by user.
Unless the user has appropriate privilege, the initial login command name shall be one of those listed in /etc/shells. The login_shell shall be the absolute path (i.e. it must start with '/') to an executable file. Accounts which are restricted (in an implementation-defined manner) may not change their login shell.
If the -s option is not selected, chsh operates in an interactive mode. The prompts and expected input in this mode are unspecified.
The -p option has unspecified behavior.
Note: Although col is shown as legacy in SUSv2, it is not (yet) deprecated in the LSB.
Some elements of the Pattern Matching Notation are optional; see Internationalization and Pattern Matching Notation.
The implementation shall support the XSI optional behavior for access control; however the files cron.allow and cron.deny may reside in /etc rather than /usr/lib/cron.
The df command shall behave as specified in ISO POSIX (2003), but with differences as listed below.
If the -k option is not specified, disk space is shown in unspecified units. If the -P option is specified, the size of the unit shall be printed on the header line in the format "%4s-blocks". Applications should specify -k.
The XSI option -t has unspecified behavior. Applications should not specify -t.
Rationale: The most common implementation of df uses the -t option for a different purpose (restricting output to a particular filesystem type), and use of -t is therefore non-portable.
If an argument is the absolute file name of a special file containing a mounted filesystem, df shall show the space available on that filesystem rather than on the filesystem containing the special file (which is typically the root filesystem).
Note: In ISO POSIX (2003) the XSI optional behavior permits an operand to name a special file, but appears to require the operation be performed on the filesystem containing the special file. A defect report has been submitted for this case.
dmesg examines or controls the system message buffer. Only a user with appropriate privileges may modify the system message buffer parameters or contents.
If the user has appropriate privilege, clears the system message buffer contents after printing.
If the user has appropriate privilege, sets the level at which logging of messages is done to the console.
uses a buffer of bufsize to query the system message buffer. This is 16392 by default (this matches the default kernel syslog buffer size since 2.1.113). If you have set the kernel buffer to larger than the default then this option can be used to view the entire buffer.
If the -k option is not specified, disk space is shown in unspecified units. Applications should specify -k.
The echo command is as specified in ISO POSIX (2003), but with the following differences.
Implementations may support implementation-defined options to echo. The behavior of echo if any arguments contain backslashes is also implementation defined.
Conforming applications shall not run echo with a first argument starting with a hyphen, or with any arguments containing backslashes; they should use printf in those cases.
Note: The behavior specified here is similar to that specified by ISO POSIX (2003) without the XSI option. However, the LSB forbids a conforming application from using any options (even if the implementation provides them) while ISO POSIX (2003) specifies behavior if the first operand is the string -n.
find shall behave as specified in ISO POSIX (2003), but with differences as listed below.
Some elements of the Pattern Matching Notation are optional; see Internationalization and Pattern Matching Notation.
Options and operands to find shall behave as described in ISO POSIX (2003), except as follows:
need not be supported
need not be supported
argument aggregation need not be supported
Rationale: The -H and -L options are only supported in the most recent versions of find, as is argument aggregation. When this verion of find becomes widely adopted, these limitations will be removed.
The fuser command is a system administration utility, see Path For System Administration Utilities.
The gettext utility retrieves a translated text string corresponding to string msgid from a message object generated with msgfmt utility.
The message object name is derived from the optional argument
textdomain if
present, otherwise from the TEXTDOMAIN
environment variable. If no domain is
specified, or if a corresponding string cannot be found,
gettext prints
msgid.
Ordinarily gettext
looks for its message object in
dirname/lang/LC_MESSAGES
where dirname
is the implementation-defined default directory and
lang is
the locale name. If present, the TEXTDOMAINDIR
environment variable replaces
the dirname.
This utility interprets C escape sequences such as \t for tab. Use \\ to print a backslash. To produce a message on a line of its own, either put a \n at the end of msgid, or use this command in conjunction with the printf utility.
When used with the -s option the gettext utility behaves like the echo utility, except that the message corresponding to msgid in the selected catalog provides the arguments.
PARAMETER translated messages from domainname.
Enable expansion of some escape sequences.
Suppress trailing newline.
The following operands are supported:
A domain name used to retrieve the messages.
A key to retrieve the localized message.
LANGUAGE
Specifies one or more locale names.
LANG
Specifies locale name.
LC_MESSAGES
Specifies messaging locale, and if present overrides LANG for messages.
TEXTDOMAIN
Specifies the text domain name, which is identical to the message object filename without .mo suffix.
TEXTDOMAINDIR
Specifies the pathname to the message catalog, and if present replaces the implementation-defined default directory.
Certain aspects of regular expression matching are optional; see Internationalization and Regular Expressions.
If the caller has appropriate privilege, the groupadd command shall create a new group named group. The group name shall be unique in the group database. If no gid is specified, groupadd shall create the new group with a unique group ID.
The groupadd command is a system administration utility, see Path For System Administration Utilities.
The new group shall have group ID gid. If the -o option is not used, no other group shall have this group ID. The value of gidshall be non-negative.
If the caller has sufficient privilege, the groupdel command shall modify the system group database, deleting the group named group. If the group named group does not exist, groupdel shall issue a diagnostic message and exit with a non-zero exit status.
The groupdel command is a system administration utility, see Path For System Administration Utilities.
If the caller has appropriate privilege, the groupmod command shall modify the entry in the system group database corresponding to a group named group.
The groupmod command is a system administration utility, see Path For System Administration Utilities.
Modify the group's group ID, setting it to gid. If the -o option is not used, no other group shall have this group ID. The value of gidshall be non-negative.
Note: Only the group ID in the database is altered; any files with group ownership set to the original group ID are unchanged by this modification.
changes the name of the group from group to group_name.
The groups command shall behave as id -Gn [user], as specified in ISO POSIX (2003). The optional user parameter will display the groups for the named user.
The gzip command shall attempt to reduce the size of the named files. Whenever possible, each file is replaced by one with the extension .gz, while keeping the same ownership modes, access and modification times. If no files are specified, or if a file name is -, the standard input is compressed to the standard output. gzip shall only attempt to compress regular files. In particular, it will ignore symbolic links.
When compressing, gzip uses the deflate algorithm specified in RFC 1951: DEFLATE Compressed Data Format Specification and stores the result in a file using the gzip file format specified in RFC 1952: GZIP File Format Specification.
writes output on standard output, leaving the original files unchanged. If there are several input files, the output consists of a sequence of independently compressed members. To obtain better compression, concatenate all input files before compressing them.
the name operands are compressed files, and gzip shall decompress them.
forces compression or decompression even if the file has multiple links or the corresponding file already exists, or if the compressed data is read from or written to a terminal. If the input data is not in a format recognized by gzip, and if the option --stdout is also given, copy the input data without change to the standard ouput: let gzip behave as cat. If -f is not given, and when not running in the background, gzip prompts to verify whether an existing file should be overwritten.
lists the compressed size, uncompressed size, ration and uncompressed
name for each compressed file. Gives the uncompressed size as
-1
for
files not in gzip format. Additionally displays method,
crc and timestamp for the uncompress file when used in combination with
--verbose.
For decompression, gzip shall support at least the following compression methods:
deflate (RFC 1951: DEFLATE Compressed Data Format Specification)
compress (ISO POSIX (2003))
ffffffff
for a file
not in gzip format.With --name, the uncompressed name, date and time are those stored within the compress file, if present.
With --verbose, the size totals and compression ratio for all files is also displayed, unless some sizes are unknown. With --quiet, the title and totals lines are not displayed.
displays the gzip license and quit.
does not save the original file name and time stamp by default when compressing. (The original name is always saved if the name had to be truncated.) When decompressing, do not restore the original file name if present (remove only the gzip suffix from the compressed file name) and do not restore the original time stamp if present (copy it from the compressed file). This option is the default when decompressing.
always saves the original file name and time stamp when compressing; this is the default. When decompressing, restore the original file name and time stamp if present. This option is useful on systems which have a limit on file name length or when the time stamp has been lost after a file transfer.
suppresses all warnings.
travels the directory structure recursively. If any of the file names specified on the command line are directories, gzip will descend into the directory and compress all the files it finds there (or decompress them in the case of gunzip).
uses suffix .suf instead of .gz.
checks the compressed file integrity.
displays the name and percentage reduction for each file compressed or decompressed.
regulates the speed of compression using the specified digit #, where -1 or --fast indicates the fastest compression method (less compression) and -9 or --best indicates the slowest compression method (best compression). The default compression level is -6 (that is, biased towards high compression at expense of speed).
The behaviors specified in this section are expected to disappear from a future version of the LSB; applications should only use the non-LSB-deprecated behaviors.
displays the version number and compilation options, then quits.
hostname is used to either display or, with appropriate privileges, set the current host name of the system. The host name is used by many applications to identify the machine.
When called without any arguments, the program displays the name of the system as returned by the gethostname() function.
When called with a name argument, and the user has appropriate privilege, the command sets the host name.
Note: It is not specified if the hostname displayed will be a fully qualified domain name. Applications requiring a particular format of hostname should check the output and take appropriate action.
In the first two formats, copy SOURCE to DEST or multiple SOURCE(s) to the existing DIRECTORY, optionally setting permission modes and file ownership. In the third format, each DIRECTORY and any missing parent directories shall be created.
makes a backup of each existing destination file. METHOD may be one of the following:
none or off never make backups.
numbered or t make numbered backups. A numbered backup has the form "%s.~%d~", target_name, version_number. Each backup shall increment the version number by 1.
existing or nil numbered if numbered backups exist, or simple otherwise.
simple or never
append a suffix to the name. The default suffix is '~',
but can be overriden by setting SIMPLE_BACKUP_SUFFIX
in
the environment, or via the -S or --suffix
option.
If no METHOD is specified, the environment variable
VERSION_CONTROL
shall be examined for one of the above.
Unambiguous abbreviations of METHOD shall be accepted.
If no METHOD is specified, or if METHOD
is empty, the backup method shall default to existing
.
If METHOD is invalid or ambiguous, install shall fail and issue a diagnostic message.
is equivalent to --backup=existing.
treats all arguments as directory names; creates all components of the specified directories.
creates all leading components of DEST except the last, then copies SOURCE to DEST; useful in the 1st format.
if the user has appropriate privilege, sets group ownership, instead of process' current group. GROUP is either a name in the user group database, or a positive integer, which shall be used as a group-id.
sets permission mode (specified as in chmod), instead of the default rwxr-xr-x.
if the user has appropriate privilege, sets ownership. OWNER is either a name in the user login database, or a positive integer, which shall be used as a user-id.
copies the access and modification times of SOURCE files to corresponding destination files.
strips symbol tables, only for 1st and 2nd formats.
equivalent to --backup=existing, except if a simple suffix is required, use SUFFIX.
prints the name of each directory as it is created.
print the name of each file before copying it to stdout
.
install_initd shall install a system initialization file that has been copied to the /etc/init.d location such that this file shall be run at the appropriate point during system initialization. The install_initrd command is typically called in the postinstall script of a package. See also Section 8.4.
If any of the -q, -Q, -s, -S, -m, or -M arguments are given, the ipcrm shall behave as described in ISO POSIX (2003).
Otherwise, ipcrm shall remove the resource of the specified type identified by id.
A future revision of this specification may deprecate the second synopsis form.
Rationale: In its first Linux implementation, ipcrm used the second syntax shown in the SYNOPSIS. Functionality present in other implementations of ipcrm has since been added, namely the ability to delete resources by key (not just identifier), and to respect the same command line syntax. The previous syntax is still supported for backwards compatibility only.
ipcs provides information on the ipc facilities for which the calling process has read access.
Note: Although this command has many similarities with the optional ipcs utility described in ISO POSIX (2003), it has substantial differences and is therefore described separately. The options specified here have similar meaning to those in ISO POSIX (2003); other options specified there have unspecified behavior on an LSB conforming implementation. See Application Usage below. The output format is not specified.
In some implementations of ipcs the -a option will print all information available. In other implementations the -a option will print all resource types. Therefore, applications shall not use the -a option.
Some implementations of ipcs provide more output formats than are specified here. These options are not consistent between differing implementations of ipcs. Therefore, only the -t, -c and -p option formatting flags may be used. At least one of the -t, -c and -p options, and at least one of -m, -q and -s options, shall be specified.
killall sends a signal to all processes running any of
the specified commands. If no signal name is specified, SIGTERM
is sent.
Signals can be specified either by name (e.g. -HUP
) or by number
(e.g. -1
). Signal 0
(check if a process exists) can only be specified
by number.
If the command name contains a slash (/), processes executing that particular file will be selected for killing, independent of their name.
killall returns a non-zero return code if no process has been killed for any of the listed commands. If at least one process has been killed for each command, killall returns zero.
A killall process never kills itself (but may kill other killall processes).
requires an exact match for very long names. If a command name is longer than 15 characters, the full name may be unavailable (i.e. it is swapped out). In this case, killall will kill everything that matches within the first 15 characters. With -e, such entries are skipped. killall prints a message for each skipped entry if -v is specified in addition to -e.
kills the process group to which the process belongs. The kill signal is only sent once per group, even if multiple processes belonging to the same process group were found.
asks interactively for confirmation before killing.
lists all known signal names.
does not complain if no processes were killed.
reports if the signal was successfully sent.
The behaviors specified in this section are expected to disappear from a future version of the LSB; applications should only use the non-LSB-deprecated behaviors.
displays version information.
lpr uses a spooling daemon to print the named files when facilities become available. If no names appear, the standard input is assumed.
identifies binary data that is not to be filtered but sent as raw input to printer.
formats with "pr" before sending to printer.
sends output to the printer named printer instead of the default printer.
suppresses header page.
uses symbolic links.
specifies copies as the number of copies to print.
specifies name as the job name for the header page.
specifies title as the title used for "pr".
If the file is a character special or block special file, the size of the file shall be replaced with two unsigned numbers in the format "%u, %u", representing the major and minor device numbers associated with the special file.
Note: The LSB does not specify the meaning of the major and minor devices numbers.
in addition to ISO POSIX (2003) XSI optional behavior of printing a slash for a directory, ls -p may display other characters for other file types.
The lsb_release command prints certain LSB (Linux Standard Base) and Distribution information.
If no options are given, the -v option is assumed.
displays version of LSB against which distribution is compliant. The version is expressed as a colon seperated list of LSB module descriptions. LSB module descriptions are dash seperated tuples containing the module name, version, and architecture name. The output is a single line of text of the following format:
LSB Version:\t<ListAsDescribedAbove>
displays string id of distributor. The output is a single line of text of the following format:
Distributor ID:\t<DistributorID>
displays single line text description of distribution. The output is of the following format:
Description:\t<Description>
displays release number of distribution. The output is a single line of text of the following format:
Release:\t<Release>
displays codename according to distribution release. The output is a single line of text of the following format.
Codename:\t<Codename>
displays all of the above information.
displays all of the above information in short output format.
displays a human-readable help message.
The following command will list the LSB Profiles which are currently supported on this platform.
example% lsb_release -v LSB Version: core-2.0-ia32:core-2.0-noarch:graphics-2.0-ia32:graphics-2.0-noarch |
The lsbinstall command may be used to install certain types of files into system specific locations. This command may be used during a package post installation script to add package specific data to system wide repositories. A user may need appropriate privilege to invoke lsbinstall.
install a font file into the systemwide font repository. There shall be one operand, that names a font file.
install an init script into the system specific location. There shall be one operand, that names an init script file.
install a profile script into the system specific location. There shall be one operand, that names a profile shell script. The behavior is unspecified if this name does not have the suffix .sh.
ensure a service name and number pair is know to the system service database. There must be at least two operands. The first operand shall have the format %d/%s with the port number and protocol values (e.g. 22/tcp), and the second operand shall be the name of the service. Any subsequent operands provide aliases for this service.
add an entry to the systems inet super daemon configuration. There shall be one operand, that names a file with the following format:
service <service_name> { <attribute> <assign-op> <value ...> } |
Install a crontab into the system specific location. There shall be one operand, that names a crontab file. See Cron Jobs.
install a desktop menu entry into the system menu database. There shall be one operand, that names a menu file.
Register a directory that contains shared libraries with the system. There shall be one operand, that names a directory.
forces all builtins to be prefixed with m4_. For example, define becomes m4_define.
Add directory to the end of the search path for includes.
For each file, write to standard output a line containing the MD5 message digest of that file, followed by one or more blank characters, followed by the name of the file. The MD5 message digest shall be calculated according to RFC 1321: The MD5 Message-Digest Algorithm and output as 32 hexadecimal digits.
If no file names are specified as operands, read from standard input and use "-" as the file name in the output.
checks the MD5 message digest of all files named in file
against the message digest listed
in the same file. The actual format of file
is the same as the output
of md5sum. That is, each line in the file describes a file.
If file
is not specified, read
message digests from stdin
.
md5sum shall exit with status 0 if the sum was generated successfully, or, in check mode, if the check matched. Otherwise, md5sum shall exit with a non-zero status.
The mknod command shall create a special file named name of the given type.
The type shall be one of the following:
creates a block (buffered) special file with the specified major and minor device numbers.
creates a character (unbuffered) special file with the specified major and minor device numbers.
creates a FIFO.
create the special file with file access permissions set as described in mode. The permissions may be any absolute value (i.e. one not containing '+' or '-') acceptable to the chmod command.
output version information and exit.
Note: This option may be deprecated in a future release of this specification.
If type is pparameter, major and minor shall not be specified. Otherwise, these parameters are mandatory.
This command may be deprecated in a future version of this specification. The major and minor operands are insufficently portable to be specified usefully here. Only a FIFO can be portably created by this command, and the mkfifo command is a simpler interface for that purpose.
The mktemp command takes the given file name template and overwrites a portion of it to create a file name. This file name shall be unique and suitable for use by the application.
The template should have at least six trailing 'X' characters. These characters are replaced with characters from the portable filename character set in order to generate a unique name.
If mktemp can successfully generate a unique file name, and the -u option is not present, the file shall be created with read and write permission only for the current user. The mktemp command shall write the filename generated to the standard output.
fail silently if an error occurs. Diagnostic messages to stderr
are suppressed, but the command shall still exit with a non-zero exit status
if an error occurs.
operates in `unsafe' mode. A unique name is generated, but the temporary file shall be unlinked before mktemp exits. Use of this option is not encouraged.
The more command need not respect the LINES and COLUMNS environment variables.
The following additional options may be supported:
specifies an integer which is the screen size (in lines).
starts at line number num.
Start at the first line matching the pattern, equivalent to executing the search forward (/) command with the given pattern immediately after opening each file.
The following options from ISO POSIX (2003) may behave differently:
has unspecified behavior.
has unspecified behavior.
has unspecified behavior.
Either clear the whole screen before displaying any text (instead of the usual scrolling behavior), or provide the behavior specified by ISO POSIX (2003). In the latter case, the syntax is "-p command".
has unspecified behavior.
The more command need not support the following interactive commands:
g |
G |
u |
control u |
control f |
newline |
j |
k |
r |
R |
m |
' (return to mark) |
/! |
? |
N |
:e |
:t |
control g |
ZZ |
The +num and +/string options are deprecated in SUSv2, and have been removed in ISO POSIX (2003); however this specification continues to specify them because the publicly available util-linux package does not support the replacement (-p command). The +command option as found in SUSv2 is more general than is specified here, but the util-linux package appears to only support the more specific +num and +/string forms.
As described in ISO POSIX (2003), all files in the system are organized in a directed graph, known as the file hierarchy, rooted at /. These files can be spread out over several underlying devices. The mount command shall attach the file system found on some underlying device to the file hierarchy.
invoke verbose mode. The mount command shall provide diagnostic
messages on stdout
.
mount all filesystems (of the given types) mentioned in /etc/fstab.
If the -a option is also present, fork a new incarnation of mount for each device to be mounted. This will do the mounts on different devices or different NFS servers in parallel.
cause everything to be done except for the actual system call; if it's not obvious, this `fakes' mounting the file system.
mount without writing in /etc/mtab. This is necessary for example when /etc is on a read-only file system.
ignore mount options not supported by a filesystem type. Not all filesystems support this option.
mount the file system read-only. A synonym is -o ro.
mount the file system read/write. (default) A synonym is -o rw.
If the file /proc/partitions is supported, mount the partition that has the specified label.
If the file /proc/partitions is supported, mount the partition that has the specified uuid.
indicate a file system type of vfstype.
More than one type may be specified in a comma separated list. The list of file system types can be prefixed with no to specify the file system types on which no action should be taken.
options are specified with a -o flag followed by a comma-separated string of options. Some of these options are only useful when they appear in the /etc/fstab file. The following options apply to any file system that is being mounted:
perform all I/O to the file system asynchronously.
update inode access time for each access. (default)
in /etc/fstab, indicate the device is mountable with -a.
use default options: rw, suid, dev, exec, auto, nouser, async.
interpret character or block special devices on the file system.
permit execution of binaries.
do not update file access times on this file system.
in /etc/fstab, indicates the device is only explicitly mountable.
do not interpret character or block special devices on the file system.
do not allow execution of any binaries on the mounted file system.
do not allow set-user-identifier or set-group-identifier bits to take effect.
forbid an unprivileged user to mount the file system. (default)
remount an already-mounted file system. This is commonly used to change the mount options for a file system, especially to make a read-only file system writable.
mount the file system read-only.
mount the file system read-write.
allow set-user-identifier or set-group-identifier bits to take effect.
do all I/O to the file system synchronously.
allow an unprivilieged user to mount the file system. This option implies the options noexec, nosuid, nodev unless overridden by subsequent options.
The behaviors specified in this section are expected to disappear from a future version of the LSB; applications should only use the non-LSB-deprecated behaviors.
output version and exit.
The msgfmt command generates a binary message catalog from a textual translation description. Message catalogs, or message object files, are stored in files with a .mo extension.
Note: The format of message object files is not guaranteed to be portable. Message catalogs should always be generated on the target architecture using the msgfmt command.
The source message files, otherwise known as portable object files, have a .po extension.
The filename operands shall be portable object files. The .po file contains messages to be displayed to users by system utilities or by application programs. The portable object files are text files, and the messages in them can be rewritten in any language supported by the system.
If any filename is -, a portable object file shall be read from the standard input.
The msgfmt command interprets data as characters
according to the current setting of the
LC_CTYPE
locale category.
Detect and diagnose input file anomalies which might represent translation errors. The msgid and msgstr strings are studied and compared. It is considered abnormal that one string starts or ends with a newline while the other does not.
If the message is flagged as c-format (see Comment Handling), check that the msgid string and the msgstr translation have the same number of % format specifiers, with matching types.
Add directory to list for input files search. If filename is not an absolute pathname and filename cannot be opened, search for it in directory. This option may be repeated. Directories shall be searched in order, with the leftmost directory searched first.
Use entries marked as fuzzy in output. If this option is not specified, such entries are not included into the output. See Comment Handling below.
Specify the output file name as output-file. If multiple domains or duplicate msgids in the .po file are present, the behavior is unspecified. If output-file is -, output is written to standard output.
Ensure that all output files have a .mo extension. Output files are named either by the -o (or --output-file) option, or by domains found in the input files.
Print additional information to the standard error, including the number of translated strings processed.
The filename operands are treated as portable object files. The format of portable object files is defined in EXTENDED DESCRIPTION.
LANGUAGE
Specifies one or more locale names.
LANG
Specifies locale name.
LC_ALL
Specifies locale name for all categories. If defined, overrides LANG
,
LC_CTYPE
and LC_MESSAGES
.
LC_CTYPE
Determine the locale for the interpretation of sequences of bytes of text data as characters (for example, single-byte as opposed to multi-byte characters in arguments and input files).
LC_MESSAGES
Specifies messaging locale, and if present overrides LANG
for messages.
The standard output is not used unless the option-argument of the -o option is specified as -.
The format of portable object files (.po files) is defined as follows. Each .po file contains one or more lines, with each line containing either a comment or a statement. Comments start the line with a hash mark (#) and end with the newline character. Empty lines, or lines containing only white-space, shall be ignored. Comments can in certain circumstances alter the behavior of msgfmt. See Comment Handling below for details on comment processing. The format of a statement is:
directive value
Each directive starts at the beginning of the line and is separated from value by white space (such as one or more space or tab characters). The value consists of one or more quoted strings separated by white space. If two or more strings are specified as value, they are normalized into single string using the string normalization syntax specified in ISO C (1999). The following directives are supported:
domain domainname
msgid message_identifier
msgid_plural untranslated_string_plural
msgstr message_string
msgstr[n] message_string
The behavior of the domain directive is affected by the options used. See OPTIONS for the behavior when the -o option is specified. If the -o option is not specified, the behavior of the domain directive is as follows:
All msgids from the beginning of each .po file to the first domain directive are put into a default message object file, messages (or messages.mo if the --strict option is specified).
When msgfmt encounters a domain domainname directive in the .po file, all following msgids until the next domain directive are put into the message object file domainname (or domainname.mo if --strict option is specified).
Duplicate msgids are defined in the scope of each domain. That is, a msgid is considered a duplicate only if the identical msgid exists in the same domain.
All duplicate msgids are ignored.
The msgid directive specifies the value of a message identifier associated with the directive that follows it. The msgid_plural directive specifies the plural form message specified to the plural message handling functions ngettext(), dngettext() or dcngettext(). The message_identifier string identifies a target string to be used at retrieval time. Each statement containing a msgid directive shall be followed by a statement containing a msgstr directive or msgstr[n] directives.
The msgstr directive specifies the target string associated with the message_identifier string declared in the immediately preceding msgid directive.
The msgstr[n] (where n = 0, 1, 2, ...) directive specifies the target string to be used with plural form handling functions ngettext(), dngettext() and dcngettext().
Message strings can contain the following escape sequences:
Table 3-1. Escape Sequences
\n | newline |
\t | tab |
\v | vertical tab |
\b | backspace |
\r | carriage return |
\f | formfeed |
\\ | backslash |
\" | double quote |
\ddd | octal bit pattern |
\xHH | hexadecimal bit pattern |
Comments are introduced by a #, and continue to the end of the line. The second character (i.e. the character following the #) has special meaning. Regular comments should follow a space character. Other comment types include:
# normal-comments
#. automatic-comments
#: reference...
#, flag
Automatic and reference comments are typically generated by external utilities, and are not specified by the LSB. The msgfmt command shall ignore such comments.
Note: Portable object files may be produced by unspecified tools. Some of the comment types described here may arise from the use of such tools. It is beyond the scope of this specification to describe these tools.
The #, comments require one or more flags separated by the comma (,) character. The following flags can be specified:
This flag shows that the following msgstr string might not be a correct translation. Only the translator (i.e. the individual undertaking the translation) can judge if the translation requires further modification, or is acceptable as is. Once satisfied with the translation, the translator then removes this fuzzy flag.
If this flag is specified, the msgfmt utility will not generate the entry for the immediately following msgid in the output message catalog, unless the --use-fuzzy is specified.
The c-format flag indicates that the msgid string is used as format string by printf()-like functions. If the c-format flag is given for a string the msgfmt utility may perform additional tests to check to validity of the translation.
The msgid entry with empty string ("") is called the header entry and is treated specially. If the message string for the header entry contains nplurals=value, the value indicates the number of plural forms. For example, if nplurals=4, there are 4 plural forms. If nplurals is defined, there should be a plural=expression on the same line, separated by a semicolon (;) character. The expression is a C language expression to determine which version of msgstr[n] to be used based on the value of n, the last argument of ngettext(), dngettext() or dcngettext(). For example:
nplurals=2; plural=n == 1 ? 0 : 1 |
indicates that there are 2 plural forms in the language; msgstr[0] is used if n == 1, otherwise msgstr[1] is used. Another example:
nplurals=3; plural=n==1 ? 0 : n==2 ? 1 : 2 |
indicates that there are 3 plural forms in the language; msgstr[0] is used if n == 1, msgstr[1] is used if n == 2, otherwise msgstr[2] is used.
If the header entry contains charset=codeset string, the codeset is used to indicate the codeset to be used to encode the message strings. If the output string's codeset is different from the message string's codeset, codeset conversion from the message strings's codeset to the output string's codeset will be performed upon the call of gettext(), dgettext(), dcgettext(), ngettext(), dngettext(), and dcngettext(). The output string's codeset is determined by the current locale's codeset (the return value of nl_langinfo(CODESET)) by default, and can be changed by the call of bind_textdomain_codeset().
Neither msgfmt nor any gettext() function imposes a limit on the total length of a message. Installing message catalogs under the C locale is pointless, since they are ignored for the sake of efficiency.
Example 1: Examples of creating message objects from message files.
In this example module1.po, module2.po and module3.po are portable message object files.
example% cat module1.po # default domain "messages" msgid "message one" msgstr "mensaje nśmero uno" # domain "help_domain" msgid "help two" msgstr "ayuda nśmero dos" # domain "error_domain" msgid "error three" msgstr "error nśmero tres" |
example% cat module2.po # default domain "messages" msgid "message four" msgstr "mensaje nśmero cuatro" # domain "error_domain" msgid "error five" msgstr "error nśmero cinco" # domain "window_domain" msgid "window six" msgstr "ventana nśmero seises" |
example% cat module3.po # default domain "messages" msgid "message seven" msgstr "mensaje nśmero siete" |
The following command will produce the output files messages, help_domain, and error_domain.
example% msgfmt module1.po |
The following command will produce the output files messages.mo, help_domain.mo, error_domain.mo, and window_domain.mo.
example% msgfmt module1.po module2.po |
The following example will produce the output file hello.mo.
example% msgfmt -o hello.mo module3.po |
The newgrp command is as specified in ISO POSIX (2003), but with differences as listed below.
The od command shall provide all of the madatory functionality specified in ISO POSIX (2003), but with extensions and differences to the XSI optional behavior as listed below.
unspecified behavior.
Note: Applications wishing to achieve the ISO POSIX (2003) behavior for -s should instead use -t d2.
each output line is limited to width bytes from the input.
accepts arguments in traditional form, see Traditional Usage below.
Note: The XSI optional behavior for offset handling described in ISO POSIX (2003) is not supported unless the --traditional option is also specified.
The LSB supports mixing options between the mandatory and XSI optional synopsis forms in ISO POSIX (2003). The LSB shall support the following options:
is equivalent to -t a, selects named characters.
is equivalent to -t o1, selects octal bytes.
is equivalent to -t c, selects characters.
is equivalent to -t u2, selects unsigned decimal two byte units.
is equivalent to -t fF, selects floats.
is equivalent to -t d2, selects decimal two byte units.
Note: This usage may change in future releases; portable applications should use -t d2.
is equivalent to -t d4, selects decimal longs.
is equivalent to -t o2, selects octal two byte units.
is equivalent to -t x2, selects hexadecimal two byte units.
Note that the XSI option -s need not be supported.
If the --traditional option is specified, there may be between zero and three operands specified.
If no operands are specified, then od shall read the standard input.
If there is exactly one operand, and it is an offset of the form [+]offset[.][b], then it shall be interpreted as specified in ISO POSIX (2003). The file to be dumped shall be the standard input.
If there are exactly two operands, and they are both of the form [+]offset[.][b], then the first shall be an treated as an offset (as above), and the second shall be a label, in the same format as the offset. If a label is specified, then the first output line produced for each input block shall be preceded by the input offset, cumulative across input files, of the next byte to be written, followed by the label, in parentheses. The label shall increment in the same manner as the offset.
If there are three operands, then the first shall be the file to dump, the second the offset, and the third the label.
Note: Recent versions of coreutils contain an od utility that conforms to ISO POSIX (2003). However, in April 2005, this version was not in widespread use. A future version of this specification may remove the differences.
passwd changes passwords for user and group accounts. A normal user may only change the password for their own account, the super user may change the password for any account. passwd also changes password expiry dates and intervals. Applications may not assume the format of prompts and anticipated input for user interaction, because they are unspecified.
sets the maximum number of days a password remains valid.
sets the minimum number of days before a password may be changed.
sets the number of days warning the user will receive before their password will expire.
disables an account after the password has been expired for the given number of days.
disables an account by changing the password to a value which matches no possible encrypted value.
re-enables an account by changing the password back to its previous value.
reads and write all files in binary mode, except for standard output and /dev/tty. This option has no effect on POSIX-compliant systems.
interprets the patch file as a unified context diff.
Return the process ID of a process which is running the program named on the command line.
The pidof command is a system administration utility, see Path For System Administration Utilities.
instructs the program to only return one pid.
causes the program to also return process id's of shells running the named scripts.
omits processes with specified process id.
remove_initd processes the removal of the modifications made to a distribution's boot script system by the install_initd program. This cleanup is performed in the preuninstall script of a package; however, the package manager is still responsible for removing the /etc/init.d file. See also Section 8.4.
Certain aspects of internationalized regular expressions are optional; see Internationalization and Regular Expressions.
To deliver electronic mail (email), applications shall support the interface provided by sendmail (described here). This interface shall be the default delivery method for applications.
This program sends an email message to one or more recipients, routing the message as necessary. This program is not intended as a user interface routine.
With no options, sendmail reads its standard input up to an end-of-file or a line consisting only of a single dot and sends a copy of the message found there to all of the addresses listed. It determines the network(s) to use based on the syntax and contents of the addresses.
If an address is preceded by a backslash, '\', it is unspecified if the address is subject to local alias expansion.
The format of messages shall be as defined in RFC 2822:Internet Message Format.
read mail from standard input and deliver it to the recipient addresses. This is the default mode of operation.
If the user has sufficient privilege, list information about messages currently in the mail queue.
use the SMTP protocol as described in RFC 2821:Simple Mail Transfer Protocol; read SMTP commands on standard input and write SMTP responses on standard output.
In this mode, sendmail shall accept \r\n (CR-LF), as required by RFC 2821:Simple Mail Transfer Protocol, and \n (LF) line terminators.
explicitly set the full name of the sender for incoming mail unless the message already contains a From: message header.
If the user running sendmail is not sufficiently trusted, then the actual sender may be indicated in the message, depending on the configuration of the agent.
explicitly set the envelope sender address for incoming mail. If there is no From: header, the address specified in the From: header will also be set.
If the user running sendmail is not sufficiently trusted, then the actual sender shall be indicated in the message.
ignore dots alone on lines by themselves in incoming messages. If this options is not specified, a line consisting of a single dot shall terminate the input. If -bs is also used, the behavior is unspecified.
deliver any mail in background, if supported; otherwise ignored.
deliver any mail in foreground, if supported; otherwise ignored.
mail errors back to the sender. (default)
write errors to the standard error output.
do not send notification of errors to the sender. This only works for mail delivered locally.
is equivalent to -i.
indicate that the sender of a message should receive a copy of the message if the sender appears in an alias expansion. Ignored if aliases are not supported.
read the message to obtain recipients from the To:, Cc:, and Bcc: headers in the message instead of from the command arguments. If a Bcc: header is present, it is removed from the message unless there is no To: or Cc: header, in which case a Bcc: header with no data is created, in accordance with RFC 2822:Internet Message Format.
If there are any operands, the recipients list is unspecified.
This option may be ignored when not in -bm mode (the default).
Note: It is recommended that applications use as few options as necessary, none if possible.
successful completion on all addresses. This does not indicate successful delivery.
there was an error.
This page is intended to reflect functionality provided by smail, exim and other implementations, not just the sendmail implementation.
The shutdown command
shall shut the system down in a secure way (first synopsis), or cancel
a pending shutdown (second synopsis).
When the shutdown is initiated, all logged-in users
shall be notified immediately that the system is going down, and users shall be
prevented from logging in to the system.
The time specifies when the actual
shutdown shall commence. See below for details. At the specified time
all processes are first notified that the system is
going down by the signal SIGTERM
. After an interval
(see -t) all processes shall be sent the signal
SIGKILL
.
If neither the -h or the
-r argument is specified, then the default behavior
shall be to take the system to a runlevel where administrative tasks can
be run. See also Run Levels.
Note: This is sometimes referred to as "single user mode".
The -h and -r options are mutually exclusive. If either the -h or -r options are specified, the system shall be halted or rebooted respectively.
use access control. See below.
tell the system to wait sec seconds between sending processes the warning and the kill signal, before changing to another runlevel. The default period is three seconds.
do not really shutdown; only send the warning messages to everybody.
reboot after shutdown.
halt after shutdown. Actions after halting are unspecified (e.g. power off).
advise the system to skip file system consistency checks on reboot.
advise the system to force file system consistency checks on reboot.
cancel an already running shutdown.
specify when to shut down.
The time argument shall have the following format: [now | [+]mins | hh:mm] If the format is hh:mm, hh shall specify the hour (1 or 2 digits) and mm is the minute of the hour (exactly two digits), and the shutdown shall commence at the next occurence of the specified time. If the format is mins (or +mins), where mins is a decimal number, shutdown shall commence in the specified number of minutes. The word now is an alias for +0.
specify a message to send to all users.
su is used to become another user during a login session. Invoked without a username, su defaults to becoming the super user. The optional argument - may be used to provide an environment similar to what the user would expect had the user logged in directly.
The user will be prompted for a password, if appropriate. Invalid passwords will produce an error message. All attempts, both valid and invalid, are logged to detect abuses of the system. Applications may not assume the format of prompts and anticipated input for user interaction, because they are unspecified.
An optional command can be executed. This is done by the shell specified in /etc/passwd for the target user unless the -s or -m options are used. Any arguments supplied after the username will be passed to the invoked shell (shell shall support the -c command line option in order for a command to be passed to it).
The current environment is passed to the new shell. The value of $PATH is reset to /bin:/usr/bin for normal users, or /sbin:/bin:/usr/sbin:/usr/bin for the super user. This may be changed with the ENV_PATH and ENV_SUPATH definitions in /etc/login.defs. When using the -m or -p options, the user's environment is not changed.
A subsystem login is indicated by the presense of a "*" as the first character of the login shell. The given home directory will be used as the root of a new filesystem which the user is actually logged into.
makes this a login shell.
passes command to the invoked shell. It is passed directly to the invoked shell (using the shell's -c option), so its syntax is whatever that shell can accept.
does not reset environment variables, and keeps the same shell if it is present in /etc/shells.
uses shell instead of the default in /etc/passwd. The shell specified shall be present in /etc/shells.
Some elements of the Pattern Matching Notation are optional; see Internationalization and Pattern Matching Notation.
doesn't dump symlinks; dumps the files they point to.
filters the archive through gzip.
umount detaches the file system(s) mentioned from the file hierarchy. A file system is specified by giving the directory where it has been mounted.
invokes verbose mode.
unmounts without writing in /etc/mtab.
tries to remount read-only if unmounting fails.
unmounts all of the file systems described in /etc/mtab except for the proc filesystem.
indicates that the actions should only be taken on file systems of the specified type. More than one type may be specified in a comma separated list. The list of file system types can be prefixed with no to specify the file system types on which no action should be taken.
forces unmount (in case of an unreachable NFS system).
The behaviors specified in this section are expected to disappear from a future version of the LSB; applications should only use the non-LSB-deprecated behaviors.
print version and exits.
When invoked without the -D option, and with appropriate privilege, useradd creates a new user account using the values specified on the command line and the default values from the system. The new user account will be entered into the system files as needed, the home directory will be created, and initial files copied, depending on the command line options.
When invoked with the -D option, useradd will either display the current default values, or, with appropriate privilege, update the default values from the command line. If no options are specified, useradd displays the current default values.
The useradd command is a system administration utility, see Path For System Administration Utilities.
specifies the new user's password file comment field value.
creates the new user using home_dir as the value for the user's login directory. The default is to append the login name to default_home and use that as the login directory name.
specifies the group name or number of the user's initial login group. The group name shall exist. A group number shall refer to an already existing group. If -g is not specified, the implementation will follow the normal user default for that system. This may create a new group or choose a default group that normal users are placed in. Applications which require control of the groups into which a user is placed should specify -g.
specifies a list of supplementary groups which the user is also a member of. Each group is separated from the next by a comma, with no intervening whitespace. The groups are subject to the same restrictions as the group given with the -g option. The default is for the user to belong only to the initial group.
specifies the user's home directory will be created if it does not exist. The files contained in skeleton_dir will be copied to the home directory if the -k option is used, otherwise the files contained in /etc/skel will be used instead. Any directories contained in skeleton_dir or /etc/skel will be created in the user's home directory as well. The -k option is only valid in conjunction with the -m option. The default is to not create the directory and to not copy any files.
is the encrypted password, as returned by crypt(). The default is to disable the account.
creates a system account, that is, a user with a UID in the range reserved for system account users. If there is not a UID free in the reserved range the command will fail.
specifies the name of the user's login shell. The default is to leave this field blank, which causes the system to select the default login shell.
specifies the numerical value of the user's ID. This value shall be unique, unless the -o option is used. The value shall be non-negative. The default is the smallest ID value greater than 499 which is not yet used.
specifies the initial path prefix for a new user's home directory. The user's name will be affixed to the end of default_home to create the new directory name if the -d option is not used when creating a new account.
specifies the group name or ID for a new user's initial group. The named group shall exist, and a numerical group ID shall have an existing entry.
specifies the name of the new user's login shell. The named program will be used for all future new user accounts.
specifies the new user's password file comment field value.
The -D option will typically be used by system administration packages. Most applications should not change defaults which will affect other applications and users.
Delete the user account named login. If there is also a group named login, this command may delete the group as well, or may leave it alone.
The userdel command is a system administration utility, see Path For System Administration Utilities.
removes files in the user's home directory along with the home directory itself. Files located in other file system will have to be searched for and deleted manually.
The usermod command shall modify an entry in the user account database.
The usermod command is a system administration utility, see Path For System Administration Utilities.
specifies the new value of the user's password file comment field.
specifies the user's new login directory. If the -m option is given the contents of the current home directory will be moved to the new home directory, which is created if it does not already exist.
specifies the group name or number of the user's new initial login group. The group name shall exist. A group number shall refer to an already existing group.
specifies a list of supplementary groups which the user is also a member of. Each group is separated from the next by a comma, with no intervening whitespace. The groups are subject to the same restrictions as the group given with the -g option. If the user is currently a member of a group which is not listed, the user will be removed from the group.
changes the name of the user from login to login_name. Nothing else is changed. In particular, the user's home directory name should probably be changed to reflect the new login name.
is the encrypted password, as returned by crypt(3).
specifies the name of the user's new login shell. Setting this field to blank causes the system to select the default login shell.
specifies the numerical value of the user's ID. This value shall be unique, unless the -o option is used. The value shall be non-negative. Any files which the user owns and which are located in the directory tree rooted at the user's home directory will have the file user ID changed automatically. Files outside of the user's home directory shall be altered manually.
has unspecified behavior.
has unspecified behavior.
has unspecified behavior.
Note: These options have been implemented in findutils-4.2.9, but this version of the utilities is not in widespread use as of April 2005. However, future versions of this specification will require support for these arguments.
An LSB conforming implementation shall provide the mandatory portions of the filesystem hierarchy specified in the Filesystem Hierarchy Standard (FHS), together with any additional requirements made in this specification.
An LSB conforming application shall conform to the Filesystem Hierarchy Standard.
The FHS allows many components or subsystems to be optional. An application shall check for the existence of an optional component before using it, and should behave in a reasonable manner if the optional component is not present.
The FHS requirement to locate the operating system kernel in either / or /boot does not apply if the operating system kernel does not exist as a file in the filesystem.
The FHS specifies certain behaviors for a variety of commands if they are present (for example, ping or python). However, LSB applications shall not rely on any commands beyond those specified by the LSB. The mere existence of a command may not be used as an indication that the command behaves in any particular way.
The following directories or links need not be present: /etc/X11 /usr/bin/X11 /usr/lib/X11 /proc
The following shall exist under /dev. Other devices may also exist in /dev. Device names may exist as symbolic links to other device nodes located in /dev or subdirectories of /dev. There is no requirement concerning major/minor number values.
An infinite data source and data sink. Data written to this device shall be discarded. Reads from this device shall always return end-of-file (EOF).
This device is a source of zeroed out data. All data written to this device shall be discarded. A read from this device shall always return the requested number of bytes, each initialized to the value '\0'.
In each process, a synonym for the controlling terminal associated with the process group of that process, if any. All reads and writes to this device shall behave as if the actual controlling terminal device had been opened.
The Filesystem Hierarchy Standard specifies two optional locations for user accounting databases used by the getutent(), getutent_r(), getutxent(), getutxid(), getutxline(), and pututxline() functions. These are /var/run/utmp and /var/run/wtmp.
The LSB does not specify the format or structure of these files, or even if they are files at all. They should be used only as "magic cookies" to the utmpname() function.
Certain utilities used for system administration
(and other privilieged commands)
may be stored in
/sbin,
/usr/sbin, and
/usr/local/sbin. Applications
requiring to use commands identified as system administration utilities
should add these directories to their
PATH
. By default, as described in
ISO POSIX (2003), standard utilities shall be found on the
PATH
returned
by getconf CS_PATH.
In this Chapter "System" means an "LSB conforming implementation" and "application" means an "LSB conforming (third party vendor) application".
The system shall grant to the application read and execute permissions on files needed to use all system interfaces (ABIs) required by the LSB specification.
The application should not depend on having directory write permission outside /tmp, /var/tmp, invoking user's home directory and /var/opt/package, (where package is the name of the application package).
The application should not depend on owning these directories.
For these directories the application should be able to work
with directory write permissions restricted by the
S_ISVTXT
bit (otherwise known as the "sticky bit").
The application should not depend on file write permission on files not owned by the user it runs under with the exception of its personal inbox /var/mail/username.
The application should not depend on having read permission to every file and directory.
The application should not depend on the set user ID or set group ID
(the S_ISUID
or S_ISGID
permissions of a
file not packaged with the application. Instead, the distribution is
responsible for assuming that all system commands have the required
permissions and work correctly.
Rationale: In order to implement common security policies it is strongly advisable for applications to use the minimum set of security attributes necessary for correct operation. Applications that require substantial appropriate privilege are likely to cause problems with such security policies.
In general, applications should not depend on running as a privileged user. This specification uses the term "appropriate privilege" throughout to identify operations that cannot be achieved without some special granting of additional privilege.
Applications that have a reason to run with appropriate privilege should outline this reason clearly in their documentation. Users of the application should be informed, that "this application demands security privileges, which could interfere with system security".
The application should not contain binary-only software that requires being run with appropriate privilege, as this makes security auditing harder or even impossible.
The application shall not change permissions of files and directories that do not belong to its own package. Should an application require that certain files and directories not directly belonging to the package have a particular ownership, the application shall document this requirement, and may fail during installation if the permissions on these files is inappropriate.
Applications that expect to be runnable from removable media should not depend on logging in as a privileged user, and should be prepared to deal with a restrictive environment. Examples of such restrictions could be default mount options that disable set-user/group-ID attributes, disabling block or character-special files on the medium, or remapping the user and group IDs of files away from any privileged value.
Rationale: System vendors and local system administrators want to run applications from removable media, but want the possibility to control what the application can do.
Where the installation of an application needs additional privileges, it must clearly document all files and system databases that are modified outside of those in /opt/pkg-name and /var/opt/pkg-name, other than those that may be updated by system logging or auditing activities.
Without this, the local system administrator would have to blindly trust a piece of software, particularly with respect to its security.
This section specifies behaviors in which there is optional behavior in one of the standards on which the LSB relies, and where the LSB requires a specific behavior.
Note: The LSB does not require the kernel to be Linux; the set of mandated options reflects current existing practice, but may be modified in future releases.
LSB conforming implementations shall support the following options defined within the ISO POSIX (2003):
_POSIX_FSYNC |
_POSIX_MAPPED_FILES |
_POSIX_MEMLOCK |
_POSIX_MEMLOCK_RANGE |
_POSIX_MEMORY_PROTECTION |
_POSIX_PRIORITY_SCHEDULING |
_POSIX_REALTIME_SIGNALS |
_POSIX_THREAD_ATTR_STACKADDR |
_POSIX_THREAD_ATTR_STACKSIZE |
_POSIX_THREAD_PROCESS_SHARED |
_POSIX_THREAD_SAFE_FUNCTIONS |
_POSIX_THREADS |
The opendir()
function shall consume a file descriptor in the same
fashion as open(), and therefore may fail with
EMFILE
or ENFILE
.
The START
and
STOP
termios
characters shall be changeable, as
described as optional behavior in the "General Terminal Interface"
section of the
ISO POSIX (2003).
The access() function
function shall fail with errno
set to EINVAL
if the
amode argument contains bits other than
those set by the bitwise inclusive OR of
R_OK
,
W_OK
,
X_OK
and
F_OK
.
The link() function shall require access to the existing file in order to succeed, as described as optional behavior in the ISO POSIX (2003).
Calling unlink() on a directory shall fail. Calling link() specifying a directory as the first argument shall fail. See also unlink.
Note: Linux allows rename() on a directory without having write access, but the LSB does not require this.
LSB conforming systems shall enforce certain special additional restrictions above and beyond those required by ISO POSIX (2003).
Note: These additional restrictions are required in order to support the testing and certification programs associated with the LSB. In each case, these are values that defined macros must not have; conforming applications that use these values shall trigger a failure in the interface that is otherwise described as a "may fail".
The fcntl() function shall treat the "cmd" value -1 as invalid.
The whence value -1
shall be an invalid value for the
lseek(), fseek() and
fcntl() functions.
The value -5
shall be an invalid signal number.
If the sigaddset() or
sigdelset() functions are passed an
invalid signal number, they shall return with EINVAL.
Implementations
are only required to enforce this requirement for signal numbers which
are specified to be invalid by this specification (such as the -5
mentioned above).
The mode value -1
to the access()
function shall be treated as
invalid.
A value of -1
shall be an invalid "_PC_..." value for
pathconf().
A value of -1
shall be an invalid "_SC..." value for
sysconf().
The nl_item value -1
shall be invalid for nl_langinfo().
The value -1
shall be an invalid "_CS_..." value for
confstr().
The value "a"
shall be an invalid mode
argument to popen().
In order to install a message catalog, the installation procedure shall supply the message catalog in a format readable by the msgfmt utility, which shall be invoked to compile the message catalog into an appropriate binary format on the target system.
Rationale: The original intent was to allow an application to contain the binary GNU MO format files. However, the format of these files is not officially stable, hence it is necessary to compile these catalogs on the target system. These binary catalogs may differ from architecture to architecture as well.
Implementations shall support the POSIX and C locales as specified in ISO POSIX (2003). Implementations may define additional locale categories not defined by that standard.
Note: Implementations choosing additional locale categories should be aware of ISO/IEC TR14652 and are advised not to choose names that conflict with that specification. If implementations provide locale categories whose names are part of the FDCC set of ISO/IEC TR14652, they should behave as defined by that specification.
Utilities that process regular expressions shall support Basic Regular Expressions and Extended Regular Expressions as specified in ISO POSIX (2003), with the following exceptions:
Range expression (such as [a-z]) can be based on code point order instead of collating element order.
Equivalence class expression (such as [=a=]) and multi-character collating element expression (such as [.ch.]) are optional.
Handling of a multi-character collating element is optional.
This affects at least the following utilities:
It also affects the behavior of interfaces in the base libraries, including at leastregexec() (see regexec)
Utilities that perform filename pattern matching (also known as Filename Globbing) shall do it as specified in ISO POSIX (2003), Pattern Matching Notation, with the following exceptions:
Pattern bracket expressions (such as [a-z]) can be based on code point order instead of collating element order.
Equivalence class expression (such as [=a=]) and multi-character collating element expression (such as [.ch.]) are optional.
Handling of a multi-character collating element is optional.
This affects at least the following utilities: cpio (cpio), find (find) and tar (tar).
In addition to the individual user crontab files specified by ISO POSIX (2003) stored under /var/spool/cron, the process that executes scheduled commands shall also process the following additional crontab files: /etc/crontab, /etc/cron.d/*. The installation of a package shall not modify the configuration file /etc/crontab.
If a package wishes to install a job that has to be executed periodically, it shall place an executable file in one of the following directories:
/etc/cron.daily |
/etc/cron.weekly |
/etc/cron.monthly |
As these directory names suggest, the files within them are executed on a daily, weekly, or monthly basis, respectively, under the control of an entry in one of the system crontab files, at an unspecified time of day. See below for the rules concerning the names of files in these directories.
Note: It is recommended that files installed in any of these directories be scripts (e.g. shell scripts, Perl scripts, etc.) so that they may be modified by the local system administrator.
The scripts in these directories should check if all necessary programs are installed before they try to execute them. Otherwise, problems will arise if a package is removed (but not purged), since the configuration files are kept on the system in this situation.
If a certain task has to be executed at a different frequency (e.g. more frequently than daily), the package shall install a file /etc/cron.d/cron-name. The file shall have the same format as that described for the crontab command in ISO POSIX (2003), except that there shall be an additional field, username, before the name of the command to execute. For completeness, the seven fields shall be:
Minute [0,59]
Hour [0,23]
Day of the month [1,31]
Month of the year [1,12]
Day of the week [0,6] (with 0=Sunday)
Username
command [args ...]
To avoid namespace conflicts in the /etc/cron.* directories, the filenames used by LSB-compliant packages in /etc/cron.daily, /etc/cron.weekly, /etc/cron.monthly, or /etc/cron.d shall come from a managed namespace. These filenames may be assigned using one of the following methods:
Assigned names. Such names must be chosen from the character set [a-z0-9]. In order to avoid conflicts these names shall be reserved through the Linux Assigned Names and Numbers Authority (LANANA). Information about the LANANA may be found at www.lanana.org.
Note: Commonly used names should be reserved in advance; developers for projects should be encouraged reserve names from LANANA, so that each distribution can use the same name, and to avoid conflicts with other projects.
Hierarchical names. Script names in this category take the form: <hier1>-<hier2>-...-<name>, where name is taken from the character set [a-z0-9], and where there may be one or more <hier-n> components. <hier1> may either be an LSB provider name assigned by the LANANA, or it may be owners' DNS name in lower case, with at least one '.'. e.g. "debian.org", "staroffice.sun.com", etc. The LSB provider name assigned by LANANA shall only consist of the ASCII characters [a-z0-9].
Reserved names. Names that begin with the character '_' are reserved for distribution use only. These names should be used for essential system packages only.
Init files provided by LSB applications shall accept one argument, saying what to do:
start | start the service |
stop | stop the service |
restart | stop and restart the service if the service is already running, otherwise start the service |
try-restart | restart the service if the service is already running |
reload | cause the configuration of the service to be reloaded without actually stopping and restarting the service |
force-reload | cause the configuration to be reloaded if the service supports this, otherwise restart the service if it is running |
status | print the current status of the service |
The start, stop, restart, force-reload, and status commands shall be supported by all init files; the reload and the try-restart options are optional. Other init script actions may be defined by the init script.
Init files shall ensure that they will behave sensibly if invoked with start when the service is already running, or with stop when it isn't, and that they don't kill unfortunately-named user processes. The best way to achieve this is to use the init-script functions provided by /lib/lsb/init-functions.
If a service reloads its configuration automatically (as in the case of cron, for example), the reload option of the init file shall behave as if the configuration has been reloaded successfully. The restart, try-restart, reload and force-reload action may be atomic; i.e. if a service is known not be operational after a restart or reload, the script may return an error without any further action.
These executable files shall not fail obscurely when the configuration files remain but the package has been removed, as the default in [the packaging system] is to leave configuration files on the system after the package has been removed. Only when it is executed with the [purge] option will [the packaging system] remove configuration files. Therefore, you should include a test statement at the top of the file, like this:
test -f program-executed-later-in-file || exit 5 |
If the status command is given, the init script will return the following exit status codes.
0 | program is running or service is OK |
1 | program is dead and /var/run pid file exists |
2 | program is dead and /var/lock lock file exists |
3 | program is not running |
4 | program or service status is unknown |
5-99 | reserved for future LSB use |
100-149 | reserved for distribution use |
150-199 | reserved for application use |
200-254 | reserved |
In the case of init script commands other than "status" (i.e., "start", "stop", "restart", "try-restart", "reload", and "force-reload"), the init script shall return an exit status of zero if the action described by the argument has been successful. Otherwise, the exit status shall be non-zero, as defined below. In addition to straightforward success, the following situations are also to be considered successful:
restarting a service (instead of reloading it) with the "force-reload" argument
running "start" on a service already running
running "stop" on a service already stopped or not running
running "restart" on a service already stopped or not running
running "try-restart" on a service already stopped or not running
In case of an error, while processing any init script action except for "status", the init script shall print an error message and return one of the following non-zero exit status codes.
1 | generic or unspecified error (current practice) |
2 | invalid or excess argument(s) |
3 | unimplemented feature (for example, "reload") |
4 | user had insufficient privilege |
5 | program is not installed |
6 | program is not configured |
7 | program is not running |
8-99 | reserved for future LSB use |
100-149 | reserved for distribution use |
150-199 | reserved for application use |
200-254 | reserved |
Error and status messages should be printed with the logging functions such as log_failure_msg and so on. Scripts may write to standard error or standard output, but implementations need not present text written to standard error/output to the user or do anything else with it.
Since init files may be run manually by a system administrator with non-standard environment variable values for PATH, USER, LOGNAME, etc. init files shall not depend on the values of these environment variables. They should set them to some known/default values if they are needed.
LSB applications which need to execute script(s) at bootup and/or shutdown may provide one or more init.d files. These files are installed by the install_initd program described below, which copies it into a standard directory and makes whatever other adjustments (creation of symlinks, creation of entries in a database, etc.) are necessary so that the script can be run at boot-time.
Note: This specification does not require, but is designed to allow, the development of a system which runs boot scripts in parallel. Hence, enforced-serialization of scripts is avoided unless it is explicitly necessary.
In the init.d file, information about the shell script shall be delimited by the lines "### BEGIN INIT INFO" and "### END INIT INFO". These delimiter lines may containg trailing whitespace, which shall be ignored. Inside this block there shall be lines of the form "# {keyword}: [arg1] [arg2] ...". (All lines inside this block start with a hash ('#') character in the first column, so that shell treats them as comments.) There shall be exactly one space character between "#" and the keyword.
Note: More than one space, or a tab character, indicates the continuation line.
# Provides: boot_facility_1 [ boot_facility_2 ...] # Required-Start: boot_facility_1 [ boot_facility_2 ...] # Required-Stop: boot_facility_1 [ boot_facility_2 ...] # Should-Start: boot_facility_1 [ boot_facility_2 ...] # Should-Stop: boot_facility_1 [ boot_facility_2 ...] # Default-Start: run_level_1 [ run_level_2 ...] # Default-Stop: run_level_1 [ run_level_2 ...] # Short-Description: short_description # Description: multiline_description |
Additional keywords may be defined in future LSB specifications. Distributions may define local extensions by using the prefix "X-[distribution name]" --- for example, "X-RedHat-foobardecl", or "X-Debian-xyzzydecl".
An init.d shell script may declare using the "Required-Start: " header that it shall not be run until certain boot facilities are provided. This information is used by the installation tool or the boot-time boot-script execution facility to assure that init scripts are run in the correct order. When an init script is run with a "start" argument, the boot facility or facilities specified in the "Provides" header shall be considered present, and hence init scripts which require those boot facilities would then be eligble to be run. When an init script is run with a "stop" argument, the boot facilities specified in the "Provides" header are considered no longer present. There are naming conventions for boot facilities and system facilities, as described in a following section.
Similarly, the "Required-Stop:" header defines which facilities shall still be available during the shutdown of that service. Hence, the init script system should avoid stopping shell scripts which provide those facilities until this shell script is stopped.
The "Should-Start:" header defines which facilities if present should be started before this service. This allows for weak dependencies which do not cause the service to fail if a facility is not available. But may cause reduced functionality of the service. Compliant applications should not rely on the existence of this feature.
The "Should-Stop:" header defines which facilities should be still available during the shutdown of that service.
The "Default-Start" and "Default-Stop" headers define which run levels should by default run the script with a start or stop argument, respectively, to start or stop the services controlled by the init script.
Note: For example, if you want a service to run in runlevels 3, 4, and 5 (only), specify "Default-Start: 3 4 5" and "Default-Stop: 0 1 2 6".
The "Short-Description" and "Description" header fields are used to provide text which describes the actions of the init script. The "short_description" shall be a relatively short, pithy description of the init script, where as the "multiline_description" can be a much longer piece of text that may span mulitple lines. In a multiline description, each continuation line shall begin with a '#' followed by tab character or a '#' followed by at least two space characters. The multiline description is terminated by the first line that does not match this criteria.
The comment conventions described in this session are only required for use by LSB-compliant applications; system init scripts as provided by LSB-compliant run-time environments are not required to use the scheme outlined here.
An init.d file is installed in /etc/init.d (which may be a symlink to another location). This can be done by the package installer. See Script Names. During the package's postinstall script, the program /usr/lib/lsb/install_initd configures the distribution's boot script system to call the package's init.d file at the appropriate time.
Note: For example, install_initd might create symbolic links in /etc/rc2.d and other such directories which point to the files in /etc/init.d (or it might update a database, or some other mechanism). The init.d files themselves should already be in /etc/init.d before running install_initd.
The install_initd program takes a single argument, the pathname to the /etc/init.d file. For example:
/usr/lib/lsb/install_initd /etc/init.d/example.com-coffeed |
The install_initd program shall return an exit status of zero if the init.d file has been successfully installed or if the the init.d file was already installed. If the required boot facilities cannot be fulfilled an exit status of one shall be returned and the init.d file shall not be installed.
When a software package is removed, the package's preuninstall script shall call /usr/lib/lsb/remove_initd and pass the pathname to the /etc/init.d file. The package manager is still responsible for removing the /etc/init.d file; the remove_initd program is provided in case the distribution needs to clean up any other modifications in the distribution's boot script system that might have been made by the install_initd program. For example:
/usr/lib/lsb/remove_initd /etc/init.d/example.com-coffeed |
The remove_initd program shall return an exit status of zero if the init.d file has been successfully removed or if the the init.d file is not installed. If another init.d file which depends on a boot facility provided by this init.d file is installed, an exit status of one shall be returned and the init.d file shall remained installed.
Note: There should be a tool available to the user (e.g., RedHat's chkconfig) which can be used by the system administrator to easily manipulate at which init levels a particular init.d script is started or stopped. This specification currently does not specify such an interface, however.
The following run levels are specified for use by the "Default-Start:" and "Default-Stop:" specifiers as defined by the section Comment Conventions for Init Scripts. Many LSB run-time environments commonly use these run level definitions, and in the absence of other considerations, providers of run-time environments are strongly encouraged to follow this convention to provide consistency for system administrators who need to work with multiple distributions. However, it is not required that LSB-compliant run-time environments use these run levels; the distribution-provided install_initd script may map the run levels specified below to whatever distribution-specified run levels are most appropriate.
0 | halt |
1 | single user mode |
2 | multiuser with no network services exported |
3 | normal/full multiuser |
4 | reserved for local use, default is normal/full multiuser |
5 | multiuser with xdm or equivalent |
6 | reboot |
Boot facilities are used to indicate dependencies in init scripts, as defined in a previous section. Facility names that begin with a dollar sign ('$') are system facility names, defined by the LSB, and SHALL be provided by distributions.
Note: The dollar sign does not indicate variable expansion as in many Linux utilities. Starting a facility name with a dollar sign is merely a way of dividing the namespace between the system and applications.
$local_fs | all local filesystems are mounted |
$network | low level networking (ethernet card; may imply PCMCIA running) |
$named | daemons which may provide hostname resolution (if present) are running. For example, daemons to query DNS, NIS+, or LDAP. |
$portmap | daemons providing SunRPC/ONCRPC portmapping service as defined in RFC 1833 (if present) are running |
$remote_fs | all remote filesystems are mounted. In some LSB run-time environments, filesystems such as /usr may be remote. Many applications that require $local_fs will probably require also require $remote_fs. |
$syslog | system logger is operational |
$time | the system time has been set, for example by using a network-based time program such as ntp or rdate, or via the hardware Real Time Clock. |
Other (non-system) facilities may be defined by other LSB applications. These facilities shall be named using the same conventions defined for naming init.d script names. Commonly, the facility provided by an LSB application init.d script will have the same name as the name assigned to the init.d script.
Since init scripts live in a single directory, they must share a single namespace. To avoid conflicts, three means of assigning names from this namespace are provided:
Assigned names. Such names must be chosen from characters in the set [a-z0-9]. This category is desirable for scripts which system administrators may need to run manually: e.g., /etc/init.d/named restart. In order to avoid conflicts these names shall be reserved through the Linux Assigned Names and Numbers Authority (LANANA). Information about the LANANA may be found at www.lanana.org.
Note: Commonly used names should be reserved in advance; developers for projects are encouraged to reserve names from LANANA, so that each distribution can use the same name for the project's init script and avoid conflicts with other projects.
Hierarchical names. Script names in this category take the form <hier1>-<hier2>-...-<name>, where name is chosen from characters in the set [a-z0-9], and where there may be one or more <hier-n> components. <hier1> may either be an LSB provider name assigned by the LANANA, or it may be the owners' DNS name in lower case, with at least one '.' (e.g., "debian.org", or "staroffice.sun.com"). The LSB provider name assigned by LANANA shall consist only of characters chosen from the set [a-z0-9].
Reserved names. Names in this category begin with the character '_', and are reserved for distribution use only. These names should be used for essential system packages only, and in general use of this part of the namespace is highly discouraged.
Note: In general, if a package or some system function is likely to be used on multiple systems, the package developers or the distribution should get a registered name through LANANA, and distributions should strive to use the same name whenever possible. For applications which may not be essential or may not be commonly installed, the hierarchical namespace may be more appropriate. An advantage to the hierarchical namespace is that there is no need to consult with the LANANA before obtaining an assigned name.
Short names are highly desirable, since system administrators may need to manually start and stop services. Given this, they should be standardized on a per-package basis. This is the rationale behind having the LANANA organization assign these names. The LANANA may be called upon to handle other namespace issues, such as package/prerequisites naming.
Each LSB-compliant init.d script shall source the file /lib/lsb/init-functions. This file shall cause the following shell script commands to be defined in an unspecified manner.
Note: This can be done either by adding a directory to the
PATH
variable which defines these commands, or by defining shell aliases.Although the commands made available via this mechanism need not be LSB conforming applications in their own right, applications that use them should only depend on features described in the LSB.
The start_daemon, killproc and pidofproc functions shall use the following algorithm for determining the status and the process identifiers of the specified program.
If the -p pidfile option is specified, and the named pidfile exists, a single line at the start of the pidfile shall be read. If this line contains one or more numeric values, separated by spaces, these values shall be used.
Otherwise, /var/run/basename.pid shall be read in a similar fashion. If this contains one or more numeric values on the first line, these values shall be used.
Optionally, if neither of the above methods has determined the process identifiers required, implementations may use unspecified additional methods to locate the process identifiers required.
Note: Commonly used methods check either for the existence of the /proc/pid directory or use /proc/pid/exe and /proc/pid/cmdline. Relying only on /proc/pid/exe is discouraged since the LSB does not specify the existence of, or semantics for, /proc. Additionally, using /proc/pid/exe may result in a not-running status for daemons that are written in a script language.
This runs the specified program as a daemon. The start_daemon function shall check if the program is already running using the algorithm given above. If so, it shall not start another copy of the daemon unless the -f option is given. The -n option specifies a nice level. See nice. start_daemon shall return the LSB defined exit status codes. It shall return 0 if the program has been successfully started or is running and not 0 otherwise.
The killproc function
shall stop the specified program. The program is
found using the algorithm given above. If a
signal is specified, using the
-signal_name or
-signal_number syntaxes
as specified by the kill command,
the program is sent that signal.
Otherwise, a SIGTERM
followed by a
SIGKILL
after an unspecified number of seconds shall be sent.
If a program has been terminated, the pidfile
should be removed if the
terminated process has not already done so.
The killproc function
shall return the LSB defined exit status codes. If called
without a signal, it shall return 0 if the program has been stopped or
is not running and not 0 otherwise. If a signal is given, it shall return 0
only if the program is running.
The pidofproc function shall return one or more process identifiers for a particular daemon using the algorithm given above. Only process identifiers of running processes should be returned. Multiple process identifiers shall be separated by a single space.
Note: A process may exit between pidofproc discovering its identity and the caller of pidofproc being able to act on that identity. As a result, no test assertion can be made that the process identifiers returned by pidofproc shall be running processes.
The log_success_msg function shall cause the system to print a success message.
Note: The message should be relatively short; no more than 60 characters is highly desirable.
The log_failure_msg function shall cause the system to print a failure message.
Note: The message should be relatively short; no more than 60 characters is highly desirable.
The log_warning_msg function shall cause the system to print a warning message.
Note: The message should be relatively short; no more than 60 characters is highly desirable.
The format of the User and Group databases is not specified. Programs may only read these databases using the provided API. Changes to these databases should be made using the provided commands.
Below is a table of required mnemonic user and group names. This specification makes no attempt to numerically assign uid or gid numbers. The exception is the uid and gid for "root" which are equal to 0.
Table 9-1. Required User & Group Names
User | Group | Comments |
root | root | Administrative user with all appropriate privileges |
bin | bin | Legacy UID/GID[a] |
daemon | daemon | Legacy UID/GID[b] |
Notes: a. The 'bin' UID/GID is included for compatibility with legacy applications. New applications should no longer use the 'bin' UID/GID. b. The 'daemon' UID/GID was used as an unprivileged UID/GID for daemons to execute under in order to limit their access to the system. Generally daemons should now run under individual UID/GIDs in order to further partition daemons from one another. |
Below is a table of optional mnemonic user and group names. This specification makes no attempt to numerically assign uid or gid numbers. If the username exists on a system, then they should be in the suggested corresponding group. These user and group names are for use by distributions, not by applications.
Table 9-2. Optional User & Group Names
User | Group | Comments |
adm | adm | Administrative special privileges |
lp | lp | Printer special privileges |
sync | sync | Login to sync the system |
shutdown | shutdown | Login to shutdown the system |
halt | halt | Login to halt the system |
Mail special privileges | ||
news | news | News special privileges |
uucp | uucp | UUCP special privileges |
operator | root | Operator special privileges |
man | man | Man special privileges |
nobody | nobody | Used by NFS |
The differences in numeric values of the uids and gids between systems on a network can be reconciled via NIS, rdist(1), rsync(1), or ugidd(8). Only a minimum working set of "user names" and their corresponding "user groups" are required. Applications cannot assume non system user or group names will be defined.
Applications cannot assume any policy for the default umask or the default directory permissions a user may have. Applications should enforce user only file permissions on private files such as mailboxes. The location of the users home directory is also not defined by policy other than the recommendations of the FHS and shall be obtained by the *pwnam(3) calls.
The system UIDs from 0 to 99 should be statically allocated by the system, and shall not be created by applications.
The system UIDs from 100 to 499 should be reserved for dynamic allocation by system administrators and post install scripts using useradd(1).
The purpose of specifying optional users and groups is to reduce the potential for name conflicts between applications and distributions.
The behaviour of the interfaces in this library is specified by the following Standards.
Large File Support |
this specification |
SUSv2 |
ISO POSIX (2003) |
SVID Issue 3 |
SVID Issue 4 |
Table A-1. libc Function Interfaces
_Exit(GLIBC_2.1.1)[1] | getrlimit(GLIBC_2.1.1)[1] | sigaction(GLIBC_2.1.1)[1] |
_IO_feof(GLIBC_2.0)[1] | getrlimit64(GLIBC_2.0)[1] | sigaddset(GLIBC_2.0)[1] |
_IO_getc(GLIBC_2.0)[1] | getrusage(GLIBC_2.0)[1] | sigaltstack(GLIBC_2.0)[1] |
_IO_putc(GLIBC_2.0)[1] | getservbyname(GLIBC_2.0)[1] | sigandset(GLIBC_2.0)[1] |
_IO_puts(GLIBC_2.0)[1] | getservbyport(GLIBC_2.0)[1] | sigdelset(GLIBC_2.0)[1] |
__assert_fail(GLIBC_2.0)[1] | getservent(GLIBC_2.0)[1] | sigemptyset(GLIBC_2.0)[1] |
__ctype_b_loc[1] | getsid()[1] | sigfillset()[1] |
__ctype_get_mb_cur_max(GLIBC_2.0)[1] | getsockname(GLIBC_2.0)[1] | sighold(GLIBC_2.0)[1] |
__ctype_tolower_loc[1] | getsockopt()[1] | sigignore()[1] |
__ctype_toupper_loc[1] | getsubopt()[1] | siginterrupt()[1] |
__cxa_atexit(GLIBC_2.1.3)[1] | gettext(GLIBC_2.1.3)[1] | sigisemptyset(GLIBC_2.1.3)[1] |
__errno_location(GLIBC_2.0)[1] | gettimeofday(GLIBC_2.0)[1] | sigismember(GLIBC_2.0)[1] |
__fpending(GLIBC_2.2)[1] | getuid(GLIBC_2.2)[1] | siglongjmp(GLIBC_2.2)[1] |
__fxstat(GLIBC_2.0)[1] | getutent(GLIBC_2.0)[1] | signal(GLIBC_2.0)[1] |
__fxstat64(GLIBC_2.2)[1] | getutent_r(GLIBC_2.2)[1] | sigorset(GLIBC_2.2)[1] |
__getpagesize(GLIBC_2.0)[1] | getutxent(GLIBC_2.0)[1] | sigpause(GLIBC_2.0)[1] |
__getpgid(GLIBC_2.0)[1] | getutxid(GLIBC_2.0)[1] | sigpending(GLIBC_2.0)[1] |
__h_errno_location[1] | getutxline()[1] | sigprocmask()[1] |
__isinf[1] | getw()[1] | sigqueue()[1] |
__isinff[1] | getwc()[1] | sigrelse()[1] |
__isinfl[1] | getwchar()[1] | sigreturn()[1] |
__isnan[1] | getwd()[1] | sigset()[1] |
__isnanf[1] | glob()[1] | sigsuspend()[1] |
__isnanl[1] | glob64()[1] | sigtimedwait()[1] |
__libc_current_sigrtmax(GLIBC_2.1)[1] | globfree(GLIBC_2.1)[1] | sigwait(GLIBC_2.1)[1] |
__libc_current_sigrtmin(GLIBC_2.1)[1] | globfree64(GLIBC_2.1)[1] | sigwaitinfo(GLIBC_2.1)[1] |
__libc_start_main(GLIBC_2.0)[1] | gmtime(GLIBC_2.0)[1] | sleep(GLIBC_2.0)[1] |
__lxstat(GLIBC_2.0)[1] | gmtime_r(GLIBC_2.0)[1] | snprintf(GLIBC_2.0)[1] |
__lxstat64(GLIBC_2.2)[1] | grantpt(GLIBC_2.2)[1] | sockatmark[1] |
__mempcpy(GLIBC_2.0)[1] | hcreate(GLIBC_2.0)[1] | socket(GLIBC_2.0)[1] |
__rawmemchr(GLIBC_2.1)[1] | hdestroy(GLIBC_2.1)[1] | socketpair(GLIBC_2.1)[1] |
__register_atfork[1] | hsearch()[1] | sprintf()[1] |
__sigsetjmp(GLIBC_2.0)[1] | htonl(GLIBC_2.0)[1] | srand(GLIBC_2.0)[1] |
__stpcpy(GLIBC_2.0)[1] | htons(GLIBC_2.0)[1] | srand48(GLIBC_2.0)[1] |
__strdup(GLIBC_2.0)[1] | iconv(GLIBC_2.0)[1] | srandom(GLIBC_2.0)[1] |
__strtod_internal(GLIBC_2.0)[1] | iconv_close(GLIBC_2.0)[1] | sscanf(GLIBC_2.0)[1] |
__strtof_internal(GLIBC_2.0)[1] | iconv_open(GLIBC_2.0)[1] | statvfs(GLIBC_2.0)[1] |
__strtok_r(GLIBC_2.0)[1] | if_freenameindex[1] | statvfs64[1] |
__strtol_internal(GLIBC_2.0)[1] | if_indextoname[1] | stime(GLIBC_2.0)[1] |
__strtold_internal(GLIBC_2.0)[1] | if_nameindex[1] | stpcpy(GLIBC_2.0)[1] |
__strtoll_internal(GLIBC_2.0)[1] | if_nametoindex[1] | stpncpy(GLIBC_2.0)[1] |
__strtoul_internal(GLIBC_2.0)[1] | imaxabs(GLIBC_2.0)[1] | strcasecmp(GLIBC_2.0)[1] |
__strtoull_internal(GLIBC_2.0)[1] | imaxdiv(GLIBC_2.0)[1] | strcasestr(GLIBC_2.0)[1] |
__sysconf(GLIBC_2.2)[1] | index(GLIBC_2.2)[1] | strcat(GLIBC_2.2)[1] |
__sysv_signal(GLIBC_2.0)[1] | inet_addr(GLIBC_2.0)[1] | strchr(GLIBC_2.0)[1] |
__wcstod_internal(GLIBC_2.0)[1] | inet_ntoa(GLIBC_2.0)[1] | strcmp(GLIBC_2.0)[1] |
__wcstof_internal(GLIBC_2.0)[1] | inet_ntop[1] | strcoll(GLIBC_2.0)[1] |
__wcstol_internal(GLIBC_2.0)[1] | inet_pton[1] | strcpy(GLIBC_2.0)[1] |
__wcstold_internal(GLIBC_2.0)[1] | initgroups(GLIBC_2.0)[1] | strcspn(GLIBC_2.0)[1] |
__wcstoul_internal(GLIBC_2.0)[1] | initstate(GLIBC_2.0)[1] | strdup(GLIBC_2.0)[1] |
__xmknod(GLIBC_2.0)[1] | insque(GLIBC_2.0)[1] | strerror(GLIBC_2.0)[1] |
__xstat(GLIBC_2.0)[1] | ioctl(GLIBC_2.0)[1] | strerror_r(GLIBC_2.0)[1] |
__xstat64(GLIBC_2.2)[1] | isalnum(GLIBC_2.2)[1] | strfmon(GLIBC_2.2)[1] |
_exit(GLIBC_2.0)[1] | isalpha(GLIBC_2.0)[1] | strftime(GLIBC_2.0)[1] |
_longjmp(GLIBC_2.0)[1] | isascii(GLIBC_2.0)[1] | strlen(GLIBC_2.0)[1] |
_setjmp(GLIBC_2.0)[1] | isatty(GLIBC_2.0)[1] | strncasecmp(GLIBC_2.0)[1] |
_tolower(GLIBC_2.0)[1] | isblank(GLIBC_2.0)[1] | strncat(GLIBC_2.0)[1] |
_toupper(GLIBC_2.0)[1] | iscntrl(GLIBC_2.0)[1] | strncmp(GLIBC_2.0)[1] |
a64l(GLIBC_2.0)[1] | isdigit(GLIBC_2.0)[1] | strncpy(GLIBC_2.0)[1] |
abort(GLIBC_2.0)[1] | isgraph(GLIBC_2.0)[1] | strndup(GLIBC_2.0)[1] |
abs(GLIBC_2.0)[1] | islower(GLIBC_2.0)[1] | strnlen(GLIBC_2.0)[1] |
accept(GLIBC_2.0)[1] | isprint(GLIBC_2.0)[1] | strpbrk(GLIBC_2.0)[1] |
access(GLIBC_2.0)[1] | ispunct(GLIBC_2.0)[1] | strptime(GLIBC_2.0)[1] |
acct(GLIBC_2.0)[1] | isspace(GLIBC_2.0)[1] | strrchr(GLIBC_2.0)[1] |
adjtime(GLIBC_2.0)[1] | isupper(GLIBC_2.0)[1] | strsep(GLIBC_2.0)[1] |
alarm(GLIBC_2.0)[1] | iswalnum(GLIBC_2.0)[1] | strsignal(GLIBC_2.0)[1] |
asctime(GLIBC_2.0)[1] | iswalpha(GLIBC_2.0)[1] | strspn(GLIBC_2.0)[1] |
asctime_r(GLIBC_2.0)[1] | iswblank(GLIBC_2.0)[1] | strstr(GLIBC_2.0)[1] |
asprintf(GLIBC_2.0)[1] | iswcntrl(GLIBC_2.0)[1] | strtod(GLIBC_2.0)[1] |
atof(GLIBC_2.0)[1] | iswctype(GLIBC_2.0)[1] | strtof(GLIBC_2.0)[1] |
atoi(GLIBC_2.0)[1] | iswdigit(GLIBC_2.0)[1] | strtoimax(GLIBC_2.0)[1] |
atol(GLIBC_2.0)[1] | iswgraph(GLIBC_2.0)[1] | strtok(GLIBC_2.0)[1] |
atoll[1] | iswlower()[1] | strtok_r()[1] |
authnone_create(GLIBC_2.0)[1] | iswprint(GLIBC_2.0)[1] | strtol(GLIBC_2.0)[1] |
basename(GLIBC_2.0)[1] | iswpunct(GLIBC_2.0)[1] | strtold(GLIBC_2.0)[1] |
bcmp(GLIBC_2.0)[1] | iswspace(GLIBC_2.0)[1] | strtoll(GLIBC_2.0)[1] |
bcopy(GLIBC_2.0)[1] | iswupper(GLIBC_2.0)[1] | strtoq(GLIBC_2.0)[1] |
bind(GLIBC_2.0)[1] | iswxdigit(GLIBC_2.0)[1] | strtoul(GLIBC_2.0)[1] |
bind_textdomain_codeset[1] | isxdigit()[1] | strtoull()[1] |
bindresvport(GLIBC_2.0)[1] | jrand48(GLIBC_2.0)[1] | strtoumax(GLIBC_2.0)[1] |
bindtextdomain(GLIBC_2.0)[1] | key_decryptsession(GLIBC_2.0)[1] | strtouq(GLIBC_2.0)[1] |
brk(GLIBC_2.0)[1] | kill(GLIBC_2.0)[1] | strxfrm(GLIBC_2.0)[1] |
bsd_signal(GLIBC_2.0)[1] | killpg(GLIBC_2.0)[1] | svc_getreqset(GLIBC_2.0)[1] |
bsearch(GLIBC_2.0)[1] | l64a(GLIBC_2.0)[1] | svc_register(GLIBC_2.0)[1] |
btowc(GLIBC_2.0)[1] | labs(GLIBC_2.0)[1] | svc_run(GLIBC_2.0)[1] |
bzero(GLIBC_2.0)[1] | lchown(GLIBC_2.0)[1] | svc_sendreply(GLIBC_2.0)[1] |
calloc(GLIBC_2.0)[1] | lcong48(GLIBC_2.0)[1] | svcerr_auth(GLIBC_2.0)[1] |
catclose(GLIBC_2.0)[1] | ldiv(GLIBC_2.0)[1] | svcerr_decode(GLIBC_2.0)[1] |
catgets(GLIBC_2.0)[1] | lfind(GLIBC_2.0)[1] | svcerr_noproc(GLIBC_2.0)[1] |
catopen(GLIBC_2.0)[1] | link(GLIBC_2.0)[1] | svcerr_noprog(GLIBC_2.0)[1] |
cfgetispeed(GLIBC_2.0)[1] | listen(GLIBC_2.0)[1] | svcerr_progvers(GLIBC_2.0)[1] |
cfgetospeed(GLIBC_2.0)[1] | llabs(GLIBC_2.0)[1] | svcerr_systemerr(GLIBC_2.0)[1] |
cfmakeraw(GLIBC_2.0)[1] | lldiv(GLIBC_2.0)[1] | svcerr_weakauth(GLIBC_2.0)[1] |
cfsetispeed(GLIBC_2.0)[1] | localeconv(GLIBC_2.0)[1] | svctcp_create(GLIBC_2.0)[1] |
cfsetospeed(GLIBC_2.0)[1] | localtime(GLIBC_2.0)[1] | svcudp_create(GLIBC_2.0)[1] |
cfsetspeed(GLIBC_2.0)[1] | localtime_r(GLIBC_2.0)[1] | swab(GLIBC_2.0)[1] |
chdir(GLIBC_2.0)[1] | lockf(GLIBC_2.0)[1] | swapcontext(GLIBC_2.0)[1] |
chmod(GLIBC_2.0)[1] | lockf64(GLIBC_2.0)[1] | swprintf(GLIBC_2.0)[1] |
chown(GLIBC_2.1)[1] | longjmp(GLIBC_2.1)[1] | swscanf(GLIBC_2.1)[1] |
chroot(GLIBC_2.0)[1] | lrand48(GLIBC_2.0)[1] | symlink(GLIBC_2.0)[1] |
clearerr(GLIBC_2.0)[1] | lsearch(GLIBC_2.0)[1] | sync(GLIBC_2.0)[1] |
clnt_create(GLIBC_2.0)[1] | lseek(GLIBC_2.0)[1] | sysconf(GLIBC_2.0)[1] |
clnt_pcreateerror(GLIBC_2.0)[1] | lseek64(GLIBC_2.0)[1] | syslog(GLIBC_2.0)[1] |
clnt_perrno(GLIBC_2.0)[1] | makecontext(GLIBC_2.0)[1] | system(GLIBC_2.0)[1] |
clnt_perror(GLIBC_2.0)[1] | malloc(GLIBC_2.0)[1] | tcdrain(GLIBC_2.0)[1] |
clnt_spcreateerror(GLIBC_2.0)[1] | mblen(GLIBC_2.0)[1] | tcflow(GLIBC_2.0)[1] |
clnt_sperrno(GLIBC_2.0)[1] | mbrlen(GLIBC_2.0)[1] | tcflush(GLIBC_2.0)[1] |
clnt_sperror(GLIBC_2.0)[1] | mbrtowc(GLIBC_2.0)[1] | tcgetattr(GLIBC_2.0)[1] |
clock(GLIBC_2.0)[1] | mbsinit(GLIBC_2.0)[1] | tcgetpgrp(GLIBC_2.0)[1] |
close(GLIBC_2.0)[1] | mbsnrtowcs(GLIBC_2.0)[1] | tcgetsid(GLIBC_2.0)[1] |
closedir(GLIBC_2.0)[1] | mbsrtowcs(GLIBC_2.0)[1] | tcsendbreak(GLIBC_2.0)[1] |
closelog(GLIBC_2.0)[1] | mbstowcs(GLIBC_2.0)[1] | tcsetattr(GLIBC_2.0)[1] |
confstr(GLIBC_2.0)[1] | mbtowc(GLIBC_2.0)[1] | tcsetpgrp(GLIBC_2.0)[1] |
connect(GLIBC_2.0)[1] | memccpy(GLIBC_2.0)[1] | tdelete[1] |
creat(GLIBC_2.0)[1] | memchr(GLIBC_2.0)[1] | telldir(GLIBC_2.0)[1] |
creat64(GLIBC_2.1)[1] | memcmp(GLIBC_2.1)[1] | tempnam(GLIBC_2.1)[1] |
ctermid(GLIBC_2.0)[1] | memcpy(GLIBC_2.0)[1] | textdomain(GLIBC_2.0)[1] |
ctime(GLIBC_2.0)[1] | memmem(GLIBC_2.0)[1] | tfind(GLIBC_2.0)[1] |
ctime_r(GLIBC_2.0)[1] | memmove(GLIBC_2.0)[1] | time(GLIBC_2.0)[1] |
cuserid(GLIBC_2.0)[1] | memrchr(GLIBC_2.0)[1] | times(GLIBC_2.0)[1] |
daemon(GLIBC_2.0)[1] | memset(GLIBC_2.0)[1] | tmpfile(GLIBC_2.0)[1] |
dcgettext(GLIBC_2.0)[1] | mkdir(GLIBC_2.0)[1] | tmpfile64(GLIBC_2.0)[1] |
dcngettext[1] | mkfifo()[1] | tmpnam()[1] |
dgettext[1] | mkstemp()[1] | toascii()[1] |
difftime(GLIBC_2.0)[1] | mkstemp64(GLIBC_2.0)[1] | tolower(GLIBC_2.0)[1] |
dirname(GLIBC_2.0)[1] | mktemp(GLIBC_2.0)[1] | toupper(GLIBC_2.0)[1] |
div(GLIBC_2.0)[1] | mktime(GLIBC_2.0)[1] | towctrans(GLIBC_2.0)[1] |
dngettext[1] | mlock()[1] | towlower()[1] |
drand48(GLIBC_2.0)[1] | mlockall(GLIBC_2.0)[1] | towupper(GLIBC_2.0)[1] |
dup(GLIBC_2.0)[1] | mmap(GLIBC_2.0)[1] | truncate(GLIBC_2.0)[1] |
dup2(GLIBC_2.0)[1] | mmap64(GLIBC_2.0)[1] | truncate64(GLIBC_2.0)[1] |
duplocale[1] | mprotect()[1] | tsearch()[1] |
ecvt(GLIBC_2.0)[1] | mrand48(GLIBC_2.0)[1] | ttyname(GLIBC_2.0)[1] |
endgrent(GLIBC_2.0)[1] | msgctl(GLIBC_2.0)[1] | ttyname_r(GLIBC_2.0)[1] |
endprotoent(GLIBC_2.0)[1] | msgget(GLIBC_2.0)[1] | twalk(GLIBC_2.0)[1] |
endpwent(GLIBC_2.0)[1] | msgrcv(GLIBC_2.0)[1] | tzset(GLIBC_2.0)[1] |
endservent(GLIBC_2.0)[1] | msgsnd(GLIBC_2.0)[1] | ualarm(GLIBC_2.0)[1] |
endutent(GLIBC_2.0)[1] | msync(GLIBC_2.0)[1] | ulimit(GLIBC_2.0)[1] |
endutxent(GLIBC_2.1)[1] | munlock(GLIBC_2.1)[1] | umask(GLIBC_2.1)[1] |
erand48(GLIBC_2.0)[1] | munlockall(GLIBC_2.0)[1] | uname(GLIBC_2.0)[1] |
err(GLIBC_2.0)[1] | munmap(GLIBC_2.0)[1] | ungetc(GLIBC_2.0)[1] |
error(GLIBC_2.0)[1] | nanosleep(GLIBC_2.0)[1] | ungetwc(GLIBC_2.0)[1] |
errx(GLIBC_2.0)[1] | newlocale[1] | unlink(GLIBC_2.0)[1] |
execl(GLIBC_2.0)[1] | nftw(GLIBC_2.0)[1] | unlockpt(GLIBC_2.0)[1] |
execle(GLIBC_2.0)[1] | nftw64(GLIBC_2.0)[1] | unsetenv[1] |
execlp(GLIBC_2.0)[1] | ngettext[1] | uselocale[1] |
execv(GLIBC_2.0)[1] | nice(GLIBC_2.0)[1] | usleep(GLIBC_2.0)[1] |
execve(GLIBC_2.0)[1] | nl_langinfo(GLIBC_2.0)[1] | utime(GLIBC_2.0)[1] |
execvp(GLIBC_2.0)[1] | nrand48(GLIBC_2.0)[1] | utimes(GLIBC_2.0)[1] |
exit(GLIBC_2.0)[1] | ntohl(GLIBC_2.0)[1] | utmpname[1] |
fchdir(GLIBC_2.0)[1] | ntohs(GLIBC_2.0)[1] | vasprintf(GLIBC_2.0)[1] |
fchmod(GLIBC_2.0)[1] | open(GLIBC_2.0)[1] | vdprintf(GLIBC_2.0)[1] |
fchown(GLIBC_2.0)[1] | open64(GLIBC_2.0)[1] | verrx(GLIBC_2.0)[1] |
fclose(GLIBC_2.1)[1] | opendir(GLIBC_2.1)[1] | vfork(GLIBC_2.1)[1] |
fcntl(GLIBC_2.0)[1] | openlog(GLIBC_2.0)[1] | vfprintf(GLIBC_2.0)[1] |
fcvt(GLIBC_2.0)[1] | pathconf(GLIBC_2.0)[1] | vfscanf[1] |
fdatasync(GLIBC_2.0)[1] | pause(GLIBC_2.0)[1] | vfwprintf(GLIBC_2.0)[1] |
fdopen(GLIBC_2.1)[1] | pclose(GLIBC_2.1)[1] | vfwscanf(GLIBC_2.1)[1] |
feof(GLIBC_2.0)[1] | perror(GLIBC_2.0)[1] | vprintf(GLIBC_2.0)[1] |
ferror(GLIBC_2.0)[1] | pipe(GLIBC_2.0)[1] | vscanf[1] |
fflush(GLIBC_2.0)[1] | pmap_getport(GLIBC_2.0)[1] | vsnprintf(GLIBC_2.0)[1] |
fflush_unlocked(GLIBC_2.0)[1] | pmap_set(GLIBC_2.0)[1] | vsprintf(GLIBC_2.0)[1] |
ffs(GLIBC_2.0)[1] | pmap_unset(GLIBC_2.0)[1] | vsscanf[1] |
fgetc(GLIBC_2.0)[1] | poll(GLIBC_2.0)[1] | vswprintf(GLIBC_2.0)[1] |
fgetpos(GLIBC_2.0)[1] | popen(GLIBC_2.0)[1] | vswscanf(GLIBC_2.0)[1] |
fgetpos64(GLIBC_2.1)[1] | posix_memalign(GLIBC_2.1)[1] | vsyslog[1] |
fgets(GLIBC_2.0)[1] | posix_openpt[1] | vwprintf(GLIBC_2.0)[1] |
fgetwc(GLIBC_2.2)[1] | printf(GLIBC_2.2)[1] | vwscanf(GLIBC_2.2)[1] |
fgetwc_unlocked(GLIBC_2.2)[1] | psignal(GLIBC_2.2)[1] | wait(GLIBC_2.2)[1] |
fgetws(GLIBC_2.2)[1] | ptsname(GLIBC_2.2)[1] | wait4(GLIBC_2.2)[1] |
fileno(GLIBC_2.0)[1] | putc(GLIBC_2.0)[1] | waitpid(GLIBC_2.0)[1] |
flock(GLIBC_2.0)[1] | putc_unlocked(GLIBC_2.0)[1] | warn(GLIBC_2.0)[1] |
flockfile(GLIBC_2.0)[1] | putchar(GLIBC_2.0)[1] | warnx(GLIBC_2.0)[1] |
fmtmsg(GLIBC_2.1)[1] | putchar_unlocked(GLIBC_2.1)[1] | wcpcpy(GLIBC_2.1)[1] |
fnmatch(GLIBC_2.2.3)[1] | putenv(GLIBC_2.2.3)[1] | wcpncpy(GLIBC_2.2.3)[1] |
fopen(GLIBC_2.1)[1] | puts(GLIBC_2.1)[1] | wcrtomb(GLIBC_2.1)[1] |
fopen64(GLIBC_2.1)[1] | pututxline(GLIBC_2.1)[1] | wcscasecmp(GLIBC_2.1)[1] |
fork(GLIBC_2.0)[1] | putw(GLIBC_2.0)[1] | wcscat(GLIBC_2.0)[1] |
fpathconf(GLIBC_2.0)[1] | putwc(GLIBC_2.0)[1] | wcschr(GLIBC_2.0)[1] |
fprintf(GLIBC_2.0)[1] | putwchar(GLIBC_2.0)[1] | wcscmp(GLIBC_2.0)[1] |
fputc(GLIBC_2.0)[1] | qsort(GLIBC_2.0)[1] | wcscoll(GLIBC_2.0)[1] |
fputs(GLIBC_2.0)[1] | raise(GLIBC_2.0)[1] | wcscpy(GLIBC_2.0)[1] |
fputwc(GLIBC_2.2)[1] | rand(GLIBC_2.2)[1] | wcscspn(GLIBC_2.2)[1] |
fputws(GLIBC_2.2)[1] | rand_r(GLIBC_2.2)[1] | wcsdup(GLIBC_2.2)[1] |
fread(GLIBC_2.0)[1] | random(GLIBC_2.0)[1] | wcsftime(GLIBC_2.0)[1] |
free(GLIBC_2.0)[1] | read(GLIBC_2.0)[1] | wcslen(GLIBC_2.0)[1] |
freeaddrinfo[1] | readdir()[1] | wcsncasecmp()[1] |
freelocale[1] | readdir64()[1] | wcsncat()[1] |
freopen(GLIBC_2.0)[1] | readdir_r[1] | wcsncmp(GLIBC_2.0)[1] |
freopen64(GLIBC_2.1)[1] | readlink(GLIBC_2.1)[1] | wcsncpy(GLIBC_2.1)[1] |
fscanf(GLIBC_2.0)[1] | readv(GLIBC_2.0)[1] | wcsnlen(GLIBC_2.0)[1] |
fseek(GLIBC_2.0)[1] | realloc(GLIBC_2.0)[1] | wcsnrtombs(GLIBC_2.0)[1] |
fseeko(GLIBC_2.1)[1] | realpath(GLIBC_2.1)[1] | wcspbrk(GLIBC_2.1)[1] |
fseeko64(GLIBC_2.1)[1] | recv(GLIBC_2.1)[1] | wcsrchr(GLIBC_2.1)[1] |
fsetpos(GLIBC_2.0)[1] | recvfrom(GLIBC_2.0)[1] | wcsrtombs(GLIBC_2.0)[1] |
fsetpos64(GLIBC_2.1)[1] | recvmsg(GLIBC_2.1)[1] | wcsspn(GLIBC_2.1)[1] |
fstatvfs(GLIBC_2.1)[1] | regcomp(GLIBC_2.1)[1] | wcsstr(GLIBC_2.1)[1] |
fstatvfs64(GLIBC_2.1)[1] | regerror(GLIBC_2.1)[1] | wcstod(GLIBC_2.1)[1] |
fsync(GLIBC_2.0)[1] | regexec(GLIBC_2.0)[1] | wcstof(GLIBC_2.0)[1] |
ftell(GLIBC_2.0)[1] | regfree(GLIBC_2.0)[1] | wcstoimax(GLIBC_2.0)[1] |
ftello(GLIBC_2.1)[1] | remove(GLIBC_2.1)[1] | wcstok(GLIBC_2.1)[1] |
ftello64(GLIBC_2.1)[1] | remque(GLIBC_2.1)[1] | wcstol(GLIBC_2.1)[1] |
ftime(GLIBC_2.0)[1] | rename(GLIBC_2.0)[1] | wcstold(GLIBC_2.0)[1] |
ftok(GLIBC_2.0)[1] | rewind(GLIBC_2.0)[1] | wcstoll(GLIBC_2.0)[1] |
ftruncate(GLIBC_2.0)[1] | rewinddir(GLIBC_2.0)[1] | wcstombs(GLIBC_2.0)[1] |
ftruncate64(GLIBC_2.1)[1] | rindex(GLIBC_2.1)[1] | wcstoq(GLIBC_2.1)[1] |
ftrylockfile(GLIBC_2.0)[1] | rmdir(GLIBC_2.0)[1] | wcstoul(GLIBC_2.0)[1] |
ftw(GLIBC_2.0)[1] | sbrk(GLIBC_2.0)[1] | wcstoull(GLIBC_2.0)[1] |
ftw64(GLIBC_2.1)[1] | scanf(GLIBC_2.1)[1] | wcstoumax(GLIBC_2.1)[1] |
funlockfile(GLIBC_2.0)[1] | sched_get_priority_max(GLIBC_2.0)[1] | wcstouq(GLIBC_2.0)[1] |
fwide(GLIBC_2.2)[1] | sched_get_priority_min(GLIBC_2.2)[1] | wcswcs(GLIBC_2.2)[1] |
fwprintf(GLIBC_2.2)[1] | sched_getparam(GLIBC_2.2)[1] | wcswidth(GLIBC_2.2)[1] |
fwrite(GLIBC_2.0)[1] | sched_getscheduler(GLIBC_2.0)[1] | wcsxfrm(GLIBC_2.0)[1] |
fwscanf(GLIBC_2.2)[1] | sched_rr_get_interval(GLIBC_2.2)[1] | wctob(GLIBC_2.2)[1] |
gai_strerror[1] | sched_setparam()[1] | wctomb()[1] |
gcvt(GLIBC_2.0)[1] | sched_setscheduler(GLIBC_2.0)[1] | wctrans(GLIBC_2.0)[1] |
getaddrinfo[1] | sched_yield()[1] | wctype()[1] |
getc(GLIBC_2.0)[1] | seed48(GLIBC_2.0)[1] | wcwidth(GLIBC_2.0)[1] |
getc_unlocked(GLIBC_2.0)[1] | seekdir(GLIBC_2.0)[1] | wmemchr(GLIBC_2.0)[1] |
getchar(GLIBC_2.0)[1] | select(GLIBC_2.0)[1] | wmemcmp(GLIBC_2.0)[1] |
getchar_unlocked(GLIBC_2.0)[1] | semctl(GLIBC_2.0)[1] | wmemcpy(GLIBC_2.0)[1] |
getcontext(GLIBC_2.1)[1] | semget(GLIBC_2.1)[1] | wmemmove(GLIBC_2.1)[1] |
getcwd(GLIBC_2.0)[1] | semop(GLIBC_2.0)[1] | wmemset(GLIBC_2.0)[1] |
getdate(GLIBC_2.1)[1] | send(GLIBC_2.1)[1] | wordexp(GLIBC_2.1)[1] |
getegid(GLIBC_2.0)[1] | sendmsg(GLIBC_2.0)[1] | wordfree(GLIBC_2.0)[1] |
getenv(GLIBC_2.0)[1] | sendto(GLIBC_2.0)[1] | wprintf(GLIBC_2.0)[1] |
geteuid(GLIBC_2.0)[1] | setbuf(GLIBC_2.0)[1] | write(GLIBC_2.0)[1] |
getgid(GLIBC_2.0)[1] | setbuffer(GLIBC_2.0)[1] | writev(GLIBC_2.0)[1] |
getgrent(GLIBC_2.0)[1] | setcontext(GLIBC_2.0)[1] | wscanf(GLIBC_2.0)[1] |
getgrgid(GLIBC_2.0)[1] | setegid(GLIBC_2.0)[1] | xdr_accepted_reply(GLIBC_2.0)[1] |
getgrgid_r(GLIBC_2.0)[1] | setenv[1] | xdr_array(GLIBC_2.0)[1] |
getgrnam(GLIBC_2.0)[1] | seteuid(GLIBC_2.0)[1] | xdr_bool(GLIBC_2.0)[1] |
getgrnam_r(GLIBC_2.0)[1] | setgid(GLIBC_2.0)[1] | xdr_bytes(GLIBC_2.0)[1] |
getgrouplist[1] | setgrent()[1] | xdr_callhdr()[1] |
getgroups(GLIBC_2.0)[1] | setgroups(GLIBC_2.0)[1] | xdr_callmsg(GLIBC_2.0)[1] |
gethostbyaddr(GLIBC_2.0)[1] | sethostname(GLIBC_2.0)[1] | xdr_char(GLIBC_2.0)[1] |
gethostbyname(GLIBC_2.0)[1] | setitimer(GLIBC_2.0)[1] | xdr_double(GLIBC_2.0)[1] |
gethostid(GLIBC_2.0)[1] | setlocale(GLIBC_2.0)[1] | xdr_enum(GLIBC_2.0)[1] |
gethostname(GLIBC_2.0)[1] | setlogmask(GLIBC_2.0)[1] | xdr_float(GLIBC_2.0)[1] |
getitimer(GLIBC_2.0)[1] | setpgid(GLIBC_2.0)[1] | xdr_free(GLIBC_2.0)[1] |
getloadavg(GLIBC_2.2)[1] | setpgrp(GLIBC_2.2)[1] | xdr_int(GLIBC_2.2)[1] |
getlogin(GLIBC_2.0)[1] | setpriority(GLIBC_2.0)[1] | xdr_long(GLIBC_2.0)[1] |
getnameinfo[1] | setprotoent()[1] | xdr_opaque()[1] |
getopt(GLIBC_2.0)[1] | setpwent(GLIBC_2.0)[1] | xdr_opaque_auth(GLIBC_2.0)[1] |
getopt_long(GLIBC_2.0)[1] | setregid(GLIBC_2.0)[1] | xdr_pointer(GLIBC_2.0)[1] |
getopt_long_only(GLIBC_2.0)[1] | setreuid(GLIBC_2.0)[1] | xdr_reference(GLIBC_2.0)[1] |
getpagesize(GLIBC_2.0)[1] | setrlimit(GLIBC_2.0)[1] | xdr_rejected_reply(GLIBC_2.0)[1] |
getpeername(GLIBC_2.0)[1] | setrlimit64[1] | xdr_replymsg(GLIBC_2.0)[1] |
getpgid(GLIBC_2.0)[1] | setservent(GLIBC_2.0)[1] | xdr_short(GLIBC_2.0)[1] |
getpgrp(GLIBC_2.0)[1] | setsid(GLIBC_2.0)[1] | xdr_string(GLIBC_2.0)[1] |
getpid(GLIBC_2.0)[1] | setsockopt(GLIBC_2.0)[1] | xdr_u_char(GLIBC_2.0)[1] |
getppid(GLIBC_2.0)[1] | setstate(GLIBC_2.0)[1] | xdr_u_int(GLIBC_2.0)[1] |
getpriority(GLIBC_2.0)[1] | setuid(GLIBC_2.0)[1] | xdr_u_long(GLIBC_2.0)[1] |
getprotobyname(GLIBC_2.0)[1] | setutent(GLIBC_2.0)[1] | xdr_u_short(GLIBC_2.0)[1] |
getprotobynumber(GLIBC_2.0)[1] | setutxent(GLIBC_2.0)[1] | xdr_union(GLIBC_2.0)[1] |
getprotoent(GLIBC_2.0)[1] | setvbuf(GLIBC_2.0)[1] | xdr_vector(GLIBC_2.0)[1] |
getpwent(GLIBC_2.0)[1] | shmat(GLIBC_2.0)[1] | xdr_void(GLIBC_2.0)[1] |
getpwnam(GLIBC_2.0)[1] | shmctl(GLIBC_2.0)[1] | xdr_wrapstring(GLIBC_2.0)[1] |
getpwnam_r(GLIBC_2.0)[1] | shmdt(GLIBC_2.0)[1] | xdrmem_create(GLIBC_2.0)[1] |
getpwuid(GLIBC_2.0)[1] | shmget(GLIBC_2.0)[1] | xdrrec_create(GLIBC_2.0)[1] |
getpwuid_r(GLIBC_2.0)[1] | shutdown(GLIBC_2.0)[1] | xdrrec_eof(GLIBC_2.0)[1] |
The behaviour of the interfaces in this library is specified by the following Standards.
ISO POSIX (2003) |
The behaviour of the interfaces in this library is specified by the following Standards.
this specification |
ISO POSIX (2003) |
The behaviour of the interfaces in this library is specified by the following Standards.
ISO C (1999) |
this specification |
SUSv2 |
ISO POSIX (2003) |
Table A-5. libm Function Interfaces
__finite[1] | csinhf()[1] | log10()[1] |
__finitef[1] | csinhl()[1] | log10f[1] |
__finitel[1] | csinl()[1] | log10l[1] |
__fpclassify[1] | csqrt()[1] | log1p()[1] |
__fpclassifyf[1] | csqrtf()[1] | log1pf[1] |
__signbit[1] | csqrtl()[1] | log1pl[1] |
__signbitf[1] | ctan()[1] | log2[1] |
acos(GLIBC_2.0)[1] | ctanf(GLIBC_2.0)[1] | log2f[1] |
acosf(GLIBC_2.0)[1] | ctanh(GLIBC_2.0)[1] | log2l[1] |
acosh(GLIBC_2.0)[1] | ctanhf(GLIBC_2.0)[1] | logb(GLIBC_2.0)[1] |
acoshf(GLIBC_2.0)[1] | ctanhl(GLIBC_2.0)[1] | logbf[1] |
acoshl(GLIBC_2.0)[1] | ctanl(GLIBC_2.0)[1] | logbl[1] |
acosl(GLIBC_2.0)[1] | dremf(GLIBC_2.0)[1] | logf[1] |
asin(GLIBC_2.0)[1] | dreml(GLIBC_2.0)[1] | logl[1] |
asinf(GLIBC_2.0)[1] | erf(GLIBC_2.0)[1] | lrint(GLIBC_2.0)[1] |
asinh(GLIBC_2.0)[1] | erfc(GLIBC_2.0)[1] | lrintf(GLIBC_2.0)[1] |
asinhf(GLIBC_2.0)[1] | erfcf(GLIBC_2.0)[1] | lrintl(GLIBC_2.0)[1] |
asinhl(GLIBC_2.0)[1] | erfcl(GLIBC_2.0)[1] | lround(GLIBC_2.0)[1] |
asinl(GLIBC_2.0)[1] | erff(GLIBC_2.0)[1] | lroundf(GLIBC_2.0)[1] |
atan(GLIBC_2.0)[1] | erfl(GLIBC_2.0)[1] | lroundl(GLIBC_2.0)[1] |
atan2(GLIBC_2.0)[1] | exp(GLIBC_2.0)[1] | matherr(GLIBC_2.0)[1] |
atan2f(GLIBC_2.0)[1] | exp2[1] | modf(GLIBC_2.0)[1] |
atan2l(GLIBC_2.0)[1] | exp2f[1] | modff(GLIBC_2.0)[1] |
atanf(GLIBC_2.0)[1] | expf[1] | modfl(GLIBC_2.0)[1] |
atanh(GLIBC_2.0)[1] | expl[1] | nan(GLIBC_2.0)[1] |
atanhf(GLIBC_2.0)[1] | expm1(GLIBC_2.0)[1] | nanf(GLIBC_2.0)[1] |
atanhl(GLIBC_2.0)[1] | expm1f[1] | nanl(GLIBC_2.0)[1] |
atanl(GLIBC_2.0)[1] | expm1l[1] | nearbyint(GLIBC_2.0)[1] |
cabs(GLIBC_2.1)[1] | fabs(GLIBC_2.1)[1] | nearbyintf(GLIBC_2.1)[1] |
cabsf(GLIBC_2.1)[1] | fabsf(GLIBC_2.1)[1] | nearbyintl(GLIBC_2.1)[1] |
cabsl(GLIBC_2.1)[1] | fabsl(GLIBC_2.1)[1] | nextafter(GLIBC_2.1)[1] |
cacos(GLIBC_2.1)[1] | fdim(GLIBC_2.1)[1] | nextafterf(GLIBC_2.1)[1] |
cacosf(GLIBC_2.1)[1] | fdimf(GLIBC_2.1)[1] | nextafterl(GLIBC_2.1)[1] |
cacosh(GLIBC_2.1)[1] | fdiml(GLIBC_2.1)[1] | nexttoward(GLIBC_2.1)[1] |
cacoshf(GLIBC_2.1)[1] | feclearexcept(GLIBC_2.1)[1] | nexttowardf(GLIBC_2.1)[1] |
cacoshl(GLIBC_2.1)[1] | fegetenv(GLIBC_2.1)[1] | nexttowardl(GLIBC_2.1)[1] |
cacosl(GLIBC_2.1)[1] | fegetexceptflag(GLIBC_2.1)[1] | pow(GLIBC_2.1)[1] |
carg(GLIBC_2.1)[1] | fegetround(GLIBC_2.1)[1] | pow10(GLIBC_2.1)[1] |
cargf(GLIBC_2.1)[1] | feholdexcept(GLIBC_2.1)[1] | pow10f(GLIBC_2.1)[1] |
cargl(GLIBC_2.1)[1] | feraiseexcept(GLIBC_2.1)[1] | pow10l(GLIBC_2.1)[1] |
casin(GLIBC_2.1)[1] | fesetenv(GLIBC_2.1)[1] | powf(GLIBC_2.1)[1] |
casinf(GLIBC_2.1)[1] | fesetexceptflag(GLIBC_2.1)[1] | powl(GLIBC_2.1)[1] |
casinh(GLIBC_2.1)[1] | fesetround(GLIBC_2.1)[1] | remainder(GLIBC_2.1)[1] |
casinhf(GLIBC_2.1)[1] | fetestexcept(GLIBC_2.1)[1] | remainderf(GLIBC_2.1)[1] |
casinhl(GLIBC_2.1)[1] | feupdateenv(GLIBC_2.1)[1] | remainderl(GLIBC_2.1)[1] |
casinl(GLIBC_2.1)[1] | finite(GLIBC_2.1)[1] | remquo(GLIBC_2.1)[1] |
catan(GLIBC_2.1)[1] | finitef(GLIBC_2.1)[1] | remquof(GLIBC_2.1)[1] |
catanf(GLIBC_2.1)[1] | finitel(GLIBC_2.1)[1] | remquol(GLIBC_2.1)[1] |
catanh(GLIBC_2.1)[1] | floor(GLIBC_2.1)[1] | rint(GLIBC_2.1)[1] |
catanhf(GLIBC_2.1)[1] | floorf(GLIBC_2.1)[1] | rintf(GLIBC_2.1)[1] |
catanhl(GLIBC_2.1)[1] | floorl(GLIBC_2.1)[1] | rintl(GLIBC_2.1)[1] |
catanl(GLIBC_2.1)[1] | fma(GLIBC_2.1)[1] | round(GLIBC_2.1)[1] |
cbrt(GLIBC_2.0)[1] | fmaf(GLIBC_2.0)[1] | roundf(GLIBC_2.0)[1] |
cbrtf(GLIBC_2.0)[1] | fmal(GLIBC_2.0)[1] | roundl(GLIBC_2.0)[1] |
cbrtl(GLIBC_2.0)[1] | fmax(GLIBC_2.0)[1] | scalb(GLIBC_2.0)[1] |
ccos(GLIBC_2.1)[1] | fmaxf(GLIBC_2.1)[1] | scalbf(GLIBC_2.1)[1] |
ccosf(GLIBC_2.1)[1] | fmaxl(GLIBC_2.1)[1] | scalbl(GLIBC_2.1)[1] |
ccosh(GLIBC_2.1)[1] | fmin(GLIBC_2.1)[1] | scalbln(GLIBC_2.1)[1] |
ccoshf(GLIBC_2.1)[1] | fminf(GLIBC_2.1)[1] | scalblnf(GLIBC_2.1)[1] |
ccoshl(GLIBC_2.1)[1] | fminl(GLIBC_2.1)[1] | scalblnl(GLIBC_2.1)[1] |
ccosl(GLIBC_2.1)[1] | fmod(GLIBC_2.1)[1] | scalbn(GLIBC_2.1)[1] |
ceil(GLIBC_2.0)[1] | fmodf(GLIBC_2.0)[1] | scalbnf(GLIBC_2.0)[1] |
ceilf(GLIBC_2.0)[1] | fmodl(GLIBC_2.0)[1] | scalbnl(GLIBC_2.0)[1] |
ceill(GLIBC_2.0)[1] | frexp(GLIBC_2.0)[1] | significand(GLIBC_2.0)[1] |
cexp(GLIBC_2.1)[1] | frexpf(GLIBC_2.1)[1] | significandf(GLIBC_2.1)[1] |
cexpf(GLIBC_2.1)[1] | frexpl(GLIBC_2.1)[1] | significandl(GLIBC_2.1)[1] |
cexpl(GLIBC_2.1)[1] | gamma(GLIBC_2.1)[1] | sin(GLIBC_2.1)[1] |
cimag(GLIBC_2.1)[1] | gammaf(GLIBC_2.1)[1] | sincos(GLIBC_2.1)[1] |
cimagf(GLIBC_2.1)[1] | gammal(GLIBC_2.1)[1] | sincosf(GLIBC_2.1)[1] |
cimagl(GLIBC_2.1)[1] | hypot(GLIBC_2.1)[1] | sincosl(GLIBC_2.1)[1] |
clog(GLIBC_2.1)[1] | hypotf(GLIBC_2.1)[1] | sinf(GLIBC_2.1)[1] |
clog10(GLIBC_2.1)[1] | hypotl(GLIBC_2.1)[1] | sinh(GLIBC_2.1)[1] |
clog10f(GLIBC_2.1)[1] | ilogb(GLIBC_2.1)[1] | sinhf(GLIBC_2.1)[1] |
clog10l(GLIBC_2.1)[1] | ilogbf(GLIBC_2.1)[1] | sinhl(GLIBC_2.1)[1] |
clogf(GLIBC_2.1)[1] | ilogbl(GLIBC_2.1)[1] | sinl(GLIBC_2.1)[1] |
clogl(GLIBC_2.1)[1] | j0(GLIBC_2.1)[1] | sqrt(GLIBC_2.1)[1] |
conj(GLIBC_2.1)[1] | j0f(GLIBC_2.1)[1] | sqrtf(GLIBC_2.1)[1] |
conjf(GLIBC_2.1)[1] | j0l(GLIBC_2.1)[1] | sqrtl(GLIBC_2.1)[1] |
conjl(GLIBC_2.1)[1] | j1(GLIBC_2.1)[1] | tan(GLIBC_2.1)[1] |
copysign(GLIBC_2.0)[1] | j1f(GLIBC_2.0)[1] | tanf(GLIBC_2.0)[1] |
copysignf(GLIBC_2.0)[1] | j1l(GLIBC_2.0)[1] | tanh(GLIBC_2.0)[1] |
copysignl(GLIBC_2.0)[1] | jn(GLIBC_2.0)[1] | tanhf(GLIBC_2.0)[1] |
cos(GLIBC_2.0)[1] | jnf(GLIBC_2.0)[1] | tanhl(GLIBC_2.0)[1] |
cosf(GLIBC_2.0)[1] | jnl(GLIBC_2.0)[1] | tanl(GLIBC_2.0)[1] |
cosh(GLIBC_2.0)[1] | ldexp(GLIBC_2.0)[1] | tgamma(GLIBC_2.0)[1] |
coshf(GLIBC_2.0)[1] | ldexpf(GLIBC_2.0)[1] | tgammaf(GLIBC_2.0)[1] |
coshl(GLIBC_2.0)[1] | ldexpl(GLIBC_2.0)[1] | tgammal(GLIBC_2.0)[1] |
cosl(GLIBC_2.0)[1] | lgamma(GLIBC_2.0)[1] | trunc(GLIBC_2.0)[1] |
cpow(GLIBC_2.1)[1] | lgamma_r(GLIBC_2.1)[1] | truncf(GLIBC_2.1)[1] |
cpowf(GLIBC_2.1)[1] | lgammaf(GLIBC_2.1)[1] | truncl(GLIBC_2.1)[1] |
cpowl(GLIBC_2.1)[1] | lgammaf_r(GLIBC_2.1)[1] | y0(GLIBC_2.1)[1] |
cproj(GLIBC_2.1)[1] | lgammal(GLIBC_2.1)[1] | y0f(GLIBC_2.1)[1] |
cprojf(GLIBC_2.1)[1] | lgammal_r(GLIBC_2.1)[1] | y0l(GLIBC_2.1)[1] |
cprojl(GLIBC_2.1)[1] | llrint(GLIBC_2.1)[1] | y1(GLIBC_2.1)[1] |
creal(GLIBC_2.1)[1] | llrintf(GLIBC_2.1)[1] | y1f(GLIBC_2.1)[1] |
crealf(GLIBC_2.1)[1] | llrintl(GLIBC_2.1)[1] | y1l(GLIBC_2.1)[1] |
creall(GLIBC_2.1)[1] | llround(GLIBC_2.1)[1] | yn(GLIBC_2.1)[1] |
csin(GLIBC_2.1)[1] | llroundf(GLIBC_2.1)[1] | ynf(GLIBC_2.1)[1] |
csinf(GLIBC_2.1)[1] | llroundl(GLIBC_2.1)[1] | ynl(GLIBC_2.1)[1] |
csinh(GLIBC_2.1)[1] | log(GLIBC_2.1)[1] |
The behaviour of the interfaces in this library is specified by the following Standards.
X/Open Curses |
Table A-7. libncurses Function Interfaces
addch[1] | mvdelch[1] | slk_refresh[1] |
addchnstr[1] | mvderwin[1] | slk_restore[1] |
addchstr[1] | mvgetch[1] | slk_set[1] |
addnstr[1] | mvgetnstr[1] | slk_touch[1] |
addstr[1] | mvgetstr[1] | standend[1] |
attr_get[1] | mvhline[1] | standout[1] |
attr_off[1] | mvinch[1] | start_color[1] |
attr_on[1] | mvinchnstr[1] | subpad[1] |
attr_set[1] | mvinchstr[1] | subwin[1] |
attroff[1] | mvinnstr[1] | syncok[1] |
attron[1] | mvinsch[1] | termattrs[1] |
attrset[1] | mvinsnstr[1] | termname[1] |
baudrate[1] | mvinsstr[1] | tgetent[1] |
beep[1] | mvinstr[1] | tgetflag[1] |
bkgd[1] | mvprintw[1] | tgetnum[1] |
bkgdset[1] | mvscanw[1] | tgetstr[1] |
border[1] | mvvline[1] | tgoto[1] |
box[1] | mvwaddch[1] | tigetflag[1] |
can_change_color[1] | mvwaddchnstr[1] | tigetnum[1] |
cbreak[1] | mvwaddchstr[1] | tigetstr[1] |
chgat[1] | mvwaddnstr[1] | timeout[1] |
clear[1] | mvwaddstr[1] | touchline[1] |
clearok[1] | mvwchgat[1] | touchwin[1] |
clrtobot[1] | mvwdelch[1] | tparm[1] |
clrtoeol[1] | mvwgetch[1] | tputs[1] |
color_content[1] | mvwgetnstr[1] | typeahead[1] |
color_set[1] | mvwgetstr[1] | unctrl[1] |
copywin[1] | mvwhline[1] | ungetch[1] |
curs_set[1] | mvwin[1] | untouchwin[1] |
def_prog_mode[1] | mvwinch[1] | use_env[1] |
def_shell_mode[1] | mvwinchnstr[1] | vidattr[1] |
del_curterm[1] | mvwinchstr[1] | vidputs[1] |
delay_output[1] | mvwinnstr[1] | vline[1] |
delch[1] | mvwinsch[1] | vw_printw[1] |
deleteln[1] | mvwinsnstr[1] | vw_scanw[1] |
delscreen[1] | mvwinsstr[1] | vwprintw[1] |
delwin[1] | mvwinstr[1] | vwscanw[1] |
derwin[1] | mvwprintw[1] | waddch[1] |
doupdate[1] | mvwscanw[1] | waddchnstr[1] |
dupwin[1] | mvwvline[1] | waddchstr[1] |
echo[1] | napms[1] | waddnstr[1] |
echochar[1] | newpad[1] | waddstr[1] |
endwin[1] | newterm[1] | wattr_get[1] |
erase[1] | newwin[1] | wattr_off[1] |
erasechar[1] | nl[1] | wattr_on[1] |
filter[1] | nocbreak[1] | wattr_set[1] |
flash[1] | nodelay[1] | wattroff[1] |
flushinp[1] | noecho[1] | wattron[1] |
getbkgd[1] | nonl[1] | wattrset[1] |
getch[1] | noqiflush[1] | wbkgd[1] |
getnstr[1] | noraw[1] | wbkgdset[1] |
getstr[1] | notimeout[1] | wborder[1] |
getwin[1] | overlay[1] | wchgat[1] |
halfdelay[1] | overwrite[1] | wclear[1] |
has_colors[1] | pair_content[1] | wclrtobot[1] |
has_ic[1] | pechochar[1] | wclrtoeol[1] |
has_il[1] | pnoutrefresh[1] | wcolor_set[1] |
hline[1] | prefresh[1] | wcursyncup[1] |
idcok[1] | printw[1] | wdelch[1] |
idlok[1] | putp[1] | wdeleteln[1] |
immedok[1] | putwin[1] | wechochar[1] |
inch[1] | qiflush[1] | werase[1] |
inchnstr[1] | raw[1] | wgetch[1] |
inchstr[1] | redrawwin[1] | wgetnstr[1] |
init_color[1] | refresh[1] | wgetstr[1] |
init_pair[1] | reset_prog_mode[1] | whline[1] |
initscr[1] | reset_shell_mode[1] | winch[1] |
innstr[1] | resetty[1] | winchnstr[1] |
insch[1] | restartterm[1] | winchstr[1] |
insdelln[1] | ripoffline[1] | winnstr[1] |
insertln[1] | savetty[1] | winsch[1] |
insnstr[1] | scanw[1] | winsdelln[1] |
insstr[1] | scr_dump[1] | winsertln[1] |
instr[1] | scr_init[1] | winsnstr[1] |
intrflush[1] | scr_restore[1] | winsstr[1] |
is_linetouched[1] | scr_set[1] | winstr[1] |
is_wintouched[1] | scrl[1] | wmove[1] |
isendwin[1] | scroll[1] | wnoutrefresh[1] |
keyname[1] | scrollok[1] | wprintw[1] |
keypad[1] | set_curterm[1] | wredrawln[1] |
killchar[1] | set_term[1] | wrefresh[1] |
leaveok[1] | setscrreg[1] | wscanw[1] |
longname[1] | setupterm[1] | wscrl[1] |
meta[1] | slk_attr_set[1] | wsetscrreg[1] |
move[1] | slk_attroff[1] | wstandend[1] |
mvaddch[1] | slk_attron[1] | wstandout[1] |
mvaddchnstr[1] | slk_attrset[1] | wsyncdown[1] |
mvaddchstr[1] | slk_clear[1] | wsyncup[1] |
mvaddnstr[1] | slk_color[1] | wtimeout[1] |
mvaddstr[1] | slk_init[1] | wtouchln[1] |
mvchgat[1] | slk_label[1] | wvline[1] |
mvcur[1] | slk_noutrefresh[1] |
The behaviour of the interfaces in this library is specified by the following Standards.
this specification |
The behaviour of the interfaces in this library is specified by the following Standards.
Large File Support |
this specification |
ISO POSIX (2003) |
Table A-10. libpthread Function Interfaces
_pthread_cleanup_pop[1] | pthread_condattr_destroy()[1] | pthread_rwlock_timedwrlock[1] |
_pthread_cleanup_push[1] | pthread_condattr_getpshared[1] | pthread_rwlock_tryrdlock()[1] |
pread(GLIBC_2.1)[1] | pthread_condattr_init(GLIBC_2.1)[1] | pthread_rwlock_trywrlock(GLIBC_2.1)[1] |
pread64(GLIBC_2.1)[1] | pthread_condattr_setpshared[1] | pthread_rwlock_unlock(GLIBC_2.1)[1] |
pthread_attr_destroy(GLIBC_2.0)[1] | pthread_create(GLIBC_2.0)[1] | pthread_rwlock_wrlock(GLIBC_2.0)[1] |
pthread_attr_getdetachstate(GLIBC_2.0)[1] | pthread_detach(GLIBC_2.0)[1] | pthread_rwlockattr_destroy(GLIBC_2.0)[1] |
pthread_attr_getguardsize(GLIBC_2.1)[1] | pthread_equal(GLIBC_2.1)[1] | pthread_rwlockattr_getpshared(GLIBC_2.1)[1] |
pthread_attr_getinheritsched(GLIBC_2.0)[1] | pthread_exit(GLIBC_2.0)[1] | pthread_rwlockattr_init(GLIBC_2.0)[1] |
pthread_attr_getschedparam(GLIBC_2.0)[1] | pthread_getconcurrency[1] | pthread_rwlockattr_setpshared(GLIBC_2.0)[1] |
pthread_attr_getschedpolicy(GLIBC_2.0)[1] | pthread_getschedparam(GLIBC_2.0)[1] | pthread_self(GLIBC_2.0)[1] |
pthread_attr_getscope(GLIBC_2.0)[1] | pthread_getspecific(GLIBC_2.0)[1] | pthread_setcancelstate(GLIBC_2.0)[1] |
pthread_attr_getstack[1] | pthread_join()[1] | pthread_setcanceltype()[1] |
pthread_attr_getstackaddr(GLIBC_2.1)[1] | pthread_key_create(GLIBC_2.1)[1] | pthread_setconcurrency[1] |
pthread_attr_getstacksize(GLIBC_2.1)[1] | pthread_key_delete(GLIBC_2.1)[1] | pthread_setschedparam(GLIBC_2.1)[1] |
pthread_attr_init(GLIBC_2.1)[1] | pthread_kill(GLIBC_2.1)[1] | pthread_setschedprio[1] |
pthread_attr_setdetachstate(GLIBC_2.0)[1] | pthread_mutex_destroy(GLIBC_2.0)[1] | pthread_setspecific(GLIBC_2.0)[1] |
pthread_attr_setguardsize(GLIBC_2.1)[1] | pthread_mutex_init(GLIBC_2.1)[1] | pthread_sigmask(GLIBC_2.1)[1] |
pthread_attr_setinheritsched(GLIBC_2.0)[1] | pthread_mutex_lock(GLIBC_2.0)[1] | pthread_testcancel(GLIBC_2.0)[1] |
pthread_attr_setschedparam(GLIBC_2.0)[1] | pthread_mutex_trylock(GLIBC_2.0)[1] | pwrite(GLIBC_2.0)[1] |
pthread_attr_setschedpolicy(GLIBC_2.0)[1] | pthread_mutex_unlock(GLIBC_2.0)[1] | pwrite64(GLIBC_2.0)[1] |
pthread_attr_setscope(GLIBC_2.0)[1] | pthread_mutexattr_destroy(GLIBC_2.0)[1] | sem_close(GLIBC_2.0)[1] |
pthread_attr_setstack[1] | pthread_mutexattr_getpshared()[1] | sem_destroy()[1] |
pthread_attr_setstackaddr(GLIBC_2.1)[1] | pthread_mutexattr_gettype(GLIBC_2.1)[1] | sem_getvalue(GLIBC_2.1)[1] |
pthread_attr_setstacksize(GLIBC_2.1)[1] | pthread_mutexattr_init(GLIBC_2.1)[1] | sem_init(GLIBC_2.1)[1] |
pthread_cancel(GLIBC_2.0)[1] | pthread_mutexattr_setpshared(GLIBC_2.0)[1] | sem_open(GLIBC_2.0)[1] |
pthread_cond_broadcast(GLIBC_2.0)[1] | pthread_mutexattr_settype(GLIBC_2.0)[1] | sem_post(GLIBC_2.0)[1] |
pthread_cond_destroy(GLIBC_2.0)[1] | pthread_once(GLIBC_2.0)[1] | sem_timedwait(GLIBC_2.0)[1] |
pthread_cond_init(GLIBC_2.0)[1] | pthread_rwlock_destroy(GLIBC_2.0)[1] | sem_trywait(GLIBC_2.0)[1] |
pthread_cond_signal(GLIBC_2.0)[1] | pthread_rwlock_init(GLIBC_2.0)[1] | sem_unlink(GLIBC_2.0)[1] |
pthread_cond_timedwait(GLIBC_2.0)[1] | pthread_rwlock_rdlock(GLIBC_2.0)[1] | sem_wait(GLIBC_2.0)[1] |
pthread_cond_wait(GLIBC_2.0)[1] | pthread_rwlock_timedrdlock[1] |
The behaviour of the interfaces in this library is specified by the following Standards.
this specification |
The behaviour of the interfaces in this library is specified by the following Standards.
this specification |
Table A-12. libz Function Interfaces
adler32[1] | gzclose[1] | gztell[1] |
compress[1] | gzdopen[1] | gzwrite[1] |
compress2[1] | gzeof[1] | inflate[1] |
compressBound[1] | gzerror[1] | inflateEnd[1] |
crc32[1] | gzflush[1] | inflateInit2_[1] |
deflate[1] | gzgetc[1] | inflateInit_[1] |
deflateBound[1] | gzgets[1] | inflateReset[1] |
deflateCopy[1] | gzopen[1] | inflateSetDictionary[1] |
deflateEnd[1] | gzprintf[1] | inflateSync[1] |
deflateInit2_[1] | gzputc[1] | inflateSyncPoint[1] |
deflateInit_[1] | gzputs[1] | uncompress[1] |
deflateParams[1] | gzread[1] | zError[1] |
deflateReset[1] | gzrewind[1] | zlibVersion[1] |
deflateSetDictionary[1] | gzseek[1] | |
get_crc_table[1] | gzsetparams[1] |
Applications shall either be packaged in the RPM packaging format as defined in this specification, or supply an installer which is LSB conforming (for example, calls LSB commands and utilities). [2]
Distributions shall provide a mechanism for installing applications in this packaging format with some restrictions listed below. [3]
An RPM format file consists of 4 sections, the Lead, Signature, Header, and the Payload. All values are stored in network byte order.
These 4 sections shall exist in the order specified.
The lead section is used to identify the package file.
The signature section is used to verify the integrity, and optionally, the authenticity of the majority of the package file.
The header section contains all available information about the package. Entries such as the package's name, version, and file list, are contained in the header.
The payload section holds the files to be install.
struct rpmlead { unsigned char magic[4]; unsigned char major, minor; short type; short archnum; char name[66]; short osnum; short signature_type; char reserved[16]; } ; |
magic
Value identifying this file as an RPM format file. This value shall be "\355\253\356\333".
major
Value indicating the major version number of the file format version. This value shall be 3.
minor
Value indicating the minor revision number of file format version. This value shall be 0.
type
Value indicating whether this is a source or binary package. This value shall be 0 to indicate a binary package.
archnum
Value indicating the architecture for which this package is valid. This value is specified in the architecture-specific LSB specification.
name
A NUL terminated string that provides the package name. This name shall conform with the Package Naming section of this specification.
osnum
Value indicating the Operating System for which this package is valid. This value shall be 1.
signature_type
Value indicating the type of the signature used in the Signature part of the file. This value shall be 5.
reserved
Reserved space. The value is undefined.
The Header structure is used for both the Signature and Header Sections. A Header Structure consists of 3 parts, a Header record, followed by 1 or more Index records, followed by 0 or more bytes of data associated with the Index records. A Header structure shall be aligned to an 8 byte boundary.
struct rpmheader { unsigned char magic[4]; unsigned char reserved[4]; int nindex; int hsize; } ; |
magic
Value identifying this record as an RPM header record. This value shall be "\216\255\350\001".
reserved
Reserved space. This value shall be "\000\000\000\000".
nindex
The number of Index Records that follow this Header Record. There should be at least 1 Index Record.
hsize
The size in bytes of the storage area for the data pointed to by the Index Records.
struct rpmhdrindex { int tag; int type; int offset; int count; } ; |
tag
Value identifying the purpose of the data associated with this Index Record. This value of this field is dependent on the context in which the Index Record is used, and is defined below and in later sections.
type
Value identifying the type of the data associated with this Index Record. The
possible type
values are defined below.
offset
Location in the Store of the data associated with this Index Record. This value
should between 0 and the value contained in the hsize
of the Header Structure.
count
Size of the data associated with this Index Record. The
count
is the number of elements whose size is
defined by the type of this Record.
The possible values for the type
field are defined
in this table.
Table 1-3. Index Type values
Type | Value | Size (in bytes) | Alignment |
---|---|---|---|
RPM_NULL_TYPE | 0 | Not Implemented. | |
RPM_CHAR_TYPE | 1 | 1 | 1 |
RPM_INT8_TYPE | 2 | 1 | 1 |
RPM_INT16_TYPE | 3 | 2 | 2 |
RPM_INT32_TYPE | 4 | 4 | 4 |
RPM_INT64_TYPE | 5 | Reserved. | |
RPM_STRING_TYPE | 6 | variable, NUL terminated | 1 |
RPM_BIN_TYPE | 7 | 1 | 1 |
RPM_STRING_ARRAY_TYPE | 8 | Variable, sequence of NUL terminated strings | 1 |
RPM_I18NSTRING_TYPE | 9 | variable, sequence of NUL terminated strings | 1 |
The string arrays specified for enties of type
RPM_STRING_ARRAY_TYPE
and
RPM_I18NSTRING_TYPE
are vectors of strings in a contiguous block of memory, each element separated
from its neighbors by a NUL character.
Index records with type RPM_I18NSTRING_TYPE
shall always
have a count
of 1. The array entries in an index of
type RPM_I18NSTRING_TYPE
correspond to the locale names
contained in the RPMTAG_HDRI18NTABLE
index.
Some values are designated as header private, and may appear in any header structure. These are defined here. Additional values are defined in later sections.
Table 1-4. Header Private Tag Values
Name | Tag Value | Type | Count | Status |
---|---|---|---|---|
RPMTAG_HEADERSIGNATURES | 62 | BIN | 16 | Optional |
RPMTAG_HEADERIMMUTABLE | 63 | BIN | 16 | Optional |
RPMTAG_HEADERI18NTABLE | 100 | STRING_ARRAY | Required |
The signature tag differentiates a signature header from a metadata header, and identifies the original contents of the signature header.
This tag contains an index record which specifies the portion of the Header Record which was used for the calculation of a signature. This data shall be preserved or any header-only signature will be invalidated.
Contains a list of locales for which strings are provided in other parts of the package.
Not all Index records defined here will be present in all packages. Each tag value has a status which is defined here.
This Index Record shall be present.
This Index Record may be present.
This Index Record may be present, but does not contribute to the processing of the package.
This Index Record should not be present.
This Index Record shall not be present.
This Index Record shall not be present.
The header store contains the values specified by the Index structures. These values are aligned according to their type and padding is used if needed. The store is located immediately following the Index structures.
The Signature section is implemented using the Header structure. The signature section defines the following additional tag values which may be used in the Index structures.
These values exist to provide additional information about the rest of the package.
Table 1-5. Signature Tag Values
Name | Tag Value | Type | Count | Status |
---|---|---|---|---|
SIGTAG_SIGSIZE | 1000 | INT32 | 1 | Required |
SIGTAG_PAYLOADSIZE | 1007 | INT32 | 1 | Optional |
This tag specifies the combined size of the Header and Payload sections.
This tag specifies the uncompressed size of the Payload archive, including the cpio headers.
These values exist to ensure the integrity of the rest of the package.
Table 1-6. Signature Digest Tag Values
Name | Tag Value | Type | Count | Status |
---|---|---|---|---|
SIGTAG_MD5 | 1004 | BIN | 16 | Required |
SIGTAG_SHA1HEADER | 1010 | STRING | 1 | Optional |
This tag specifies the 128-bit MD5 checksum of the combined Header and Archive sections.
This index contains the SHA1 checksum of the entire Header Section, including the Header Record, Index Records and Header store.
These values exist to provide authentication of the package.
Table 1-7. Signature Signing Tag Values
Name | Tag Value | Type | Count | Status |
---|---|---|---|---|
SIGTAG_PGP | 1002 | BIN | 1 | Optional |
SIGTAG_GPG | 1005 | BIN | 65 | Optional |
SIGTAG_DSAHEADER | 1011 | BIN | 1 | Optional |
SIGTAG_RSAHEADER | 1012 | BIN | 1 | Optional |
This tag specifies the RSA signature of the combined Header and Payload sections. The data is formatted as a Version 3 Signature Packet as specified in RFC 2440: OpenPGP Message Format.
The tag contains the DSA signature of the combined Header and Payload sections. The data is formatted as a Version 3 Signature Packet as specified in RFC 2440: OpenPGP Message Format.
The tag contains the DSA signature of the Header section. The data is formatted as a Version 3 Signature Packet as specified in RFC 2440: OpenPGP Message Format. If this tag is present,then the SIGTAG_GPG tag shall also be present.
The tag contains the RSA signature of the Header section.The data is formatted as a Version 3 Signature Packet as specified in RFC 2440: OpenPGP Message Format. If this tag is present, then the SIGTAG_PGP shall also be present.
The Header section is implemented using the Header structure. The Header section defines the following additional tag values which may be used in the Index structures.
The following tag values are used to indicate information that describes the package as a whole.
Table 1-8. Package Info Tag Values
Name | Tag Value | Type | Count | Status |
---|---|---|---|---|
RPMTAG_NAME | 1000 | STRING | 1 | Required |
RPMTAG_VERSION | 1001 | STRING | 1 | Required |
RPMTAG_RELEASE | 1002 | STRING | 1 | Required |
RPMTAG_SUMMARY | 1004 | I18NSTRING | 1 | Required |
RPMTAG_DESCRIPTION | 1005 | I18NSTRING | 1 | Required |
RPMTAG_SIZE | 1009 | INT32 | 1 | Required |
RPMTAG_DISTRIBUTION | 1010 | STRING | 1 | Informational |
RPMTAG_VENDOR | 1011 | STRING | 1 | Informational |
RPMTAG_LICENSE | 1014 | STRING | 1 | Required |
RPMTAG_GROUP | 1016 | I18NSTRING | 1 | Required |
RPMTAG_URL | 1020 | STRING | 1 | Informational |
RPMTAG_OS | 1021 | STRING | 1 | Required |
RPMTAG_ARCH | 1022 | STRING | 1 | Required |
RPMTAG_SOURCERPM | 1044 | STRING | 1 | Informational |
RPMTAG_ARCHIVESIZE | 1046 | INT32 | 1 | Optional |
RPMTAG_RPMVERSION | 1064 | STRING | 1 | Informational |
RPMTAG_COOKIE | 1094 | STRING | 1 | Optional |
RPMTAG_DISTURL | 1123 | STRING | 1 | Informational |
RPMTAG_PAYLOADFORMAT | 1124 | STRING | 1 | Required |
RPMTAG_PAYLOADCOMPRESSOR | 1125 | STRING | 1 | Required |
RPMTAG_PAYLOADFLAGS | 1126 | STRING | 1 | Required |
This tag specifies the name of the package.
This tag specifies the version of the package.
This tag specifies the release of the package.
This tag specifies the summary description of the package. The summary value pointed to by this index record contains a one line description of the package.
This tag specifies the description of the package. The description value pointed to by this index record contains a full desription of the package.
This tag specifies the sum of the sizes of the regular files in the archive.
A string containing the name of the distribution on which the package was built.
A string containing the name of the organization that produced the package.
This tag specifies the license which applies to this package.
This tag specifies the administrative group to which this package belongs.
URL for what??
This tag specifies the OS of the package. The OS value pointed to by this index record shall be "linux".
This tag specifies the architecture of the package. The architecture value pointed to by this index record is defined in architecture specific LSB specification.
This tag specifies the name of the source RPM
This tag specifies the uncompressed size of the Payload archive, including the cpio headers.
This tag indicates the version of RPM tool used to build this package. The value is unused.
This tag contains an opaque string whose contents are undefined.
URL of the distribution?
This tag specifies the format of the Archive section. The format value pointed to by this index record shall be 'cpio'.
This tag specifies the compression used on the Archive section. The compression value pointed to by this index record shall be 'gzip'
This tag indicates the compression level used for the Payload. This value shall always be '9'.
The following tag values are used to provide information needed during the installation of the package.
Table 1-9. Installation Tag Values
Name | Tag Value | Type | Count | Status |
---|---|---|---|---|
RPMTAG_PREIN | 1023 | STRING | 1 | Optional |
RPMTAG_POSTIN | 1024 | STRING | 1 | Optional |
RPMTAG_PREUN | 1025 | STRING | 1 | Optional |
RPMTAG_POSTUN | 1026 | STRING | 1 | Optional |
RPMTAG_PREINPROG | 1085 | STRING | 1 | Optional |
RPMTAG_POSTINPROG | 1086 | STRING | 1 | Optional |
RPMTAG_PREUNPROG | 1087 | STRING | 1 | Optional |
RPMTAG_POSTUNPROG | 1088 | STRING | 1 | Optional |
This tag specifies the preinstall scriptlet. If present, then RPMTAG_PREINPROG shall also be present.
This tag specifies the postinstall scriptlet. If present, then RPMTAG_POSTINPROG shall also be present.
his tag specifies the preuninstall scriptlet. If present, then RPMTAG_PREUNPROG shall also be present.
This tag specified the postuninstall scriptlet. If present, then RPMTAG_POSTUNPROG shall also be present.
This tag specifies the name of the intepreter to which the preinstall scriptlet will be passed. The intepreter pointed to by this index record shall be '/bin/sh'.
This tag specifies the name of the intepreter to which the postinstall scriptlet will be passed. The intepreter pointed to by this index record shall be '/bin/sh'.
This tag specifies the name of the intepreter to which the preuninstall scriptlet will be passed. The intepreter pointed to by this index record shall be '/bin/sh'.
This program specifies the name of the intepreter to which the postuninstall scriptlet will be passed. The intepreter pointed to by this index record shall be '/bin/sh'.
The following tag values are used to provide information about the files in the payload. This information is provided in the header to allow more efficient access of the information.
Table 1-10. File Info Tag Values
Name | Tag Value | Type | Count | Status |
---|---|---|---|---|
RPMTAG_OLDFILENAMES | 1027 | STRING_ARRAY | Optional | |
RPMTAG_FILESIZES | 1028 | INT32 | Required | |
RPMTAG_FILEMODES | 1030 | INT16 | Required | |
RPMTAG_FILERDEVS | 1033 | INT16 | Required | |
RPMTAG_FILEMTIMES | 1034 | INT32 | Required | |
RPMTAG_FILEMD5S | 1035 | STRING_ARRAY | Required | |
RPMTAG_FILELINKTOS | 1036 | STRING_ARRAY | Required | |
RPMTAG_FILEFLAGS | 1037 | INT32 | Required | |
RPMTAG_FILEUSERNAME | 1039 | STRING_ARRAY | Required | |
RPMTAG_FILEGROUPNAME | 1040 | STRING_ARRAY | Required | |
RPMTAG_FILEDEVICES | 1095 | INT32 | Required | |
RPMTAG_FILEINODES | 1096 | INT32 | Required | |
RPMTAG_FILELANGS | 1097 | STRING_ARRAY | Required | |
RPMTAG_DIRINDEXES | 1116 | INT32 | Optional | |
RPMTAG_BASENAMES | 1117 | STRING_ARRAY | Optional | |
RPMTAG_DIRNAMES | 1118 | STRING_ARRAY | Optional |
This tag specifies the filenames when not in a compressed format as determined by the absense of rpmlib(CompressedFileNames) in the RPMTAG_REQUIRENAME index.
This tag specifies the size of each file in the archive.
This tag specifies the mode of each file in the archive.
This tag specifies the device number from which the file was copied.
This tag specifies the modification time in seconds since the epoch of each file in the archive.
This tag specifies the ASCII representation of the MD5 sum of the corresponding file contents. This value is empty if the corresponding archive entry is not a regular file.
The target for a symlink, otherwise NULL.
This tag specifies the bit(s) to classify and control how files are to be installed.
This tag specifies the owner of the corresponding file.
This tag specifies the of the corresponding file.
This tag specifies the 16 bit device number from which the file was copied.
This tag specifies the inode value from the original file on the build host.
This tag specifies a per-file locale marker used to install only locale specific subsets of files when the package is installed.
This tag specifies the index into the array provided by the RPMTAG_DIRNAMES Index which contains the directory name for the corresponding filename.
This tag specifies the base portion of the corresponding filename.
This tag specifies the directory portion of the corresponding filename. Each directory name shall contain a trailing '/'.
One of RPMTAG_OLDFILENAMES or the tuple RPMTAG_DIRINDEXES,RPMTAG_BASENAMES,RPMTAG_DIRNAMES shall be present, but not both.
The following tag values are used to provide information about interdependencies between packages.
Table 1-11. Package Dependency Tag Values
Name | Tag Value | Type | Count | Status |
---|---|---|---|---|
RPMTAG_PROVIDENAME | 1047 | STRING_ARRAY | 1 | Required |
RPMTAG_REQUIREFLAGS | 1048 | INT32 | Required | |
RPMTAG_REQUIRENAME | 1049 | STRING_ARRAY | Required | |
RPMTAG_REQUIREVERSION | 1050 | STRING_ARRAY | Required | |
RPMTAG_CONFLICTFLAGS | 1053 | INT32 | Optional | |
RPMTAG_CONFLICTNAME | 1054 | STRING_ARRAY | Optional | |
RPMTAG_CONFLICTVERSION | 1055 | STRING_ARRAY | Optional | |
RPMTAG_OBSOLETENAME | 1090 | STRING_ARRAY | Optional | |
RPMTAG_PROVIDEFLAGS | 1112 | INT32 | Required | |
RPMTAG_PROVIDEVERSION | 1113 | STRING_ARRAY | Required | |
RPMTAG_OBSOLETEFLAGS | 1114 | INT32 | 1 | Optional |
RPMTAG_OBSOLETEVERSION | 1115 | STRING_ARRAY | Optional |
This tag indicates the name of the dependency provided by this package.
Bits(s) to specify the dependency range and context.
This tag indicates the dependencies for this package.
This tag indicates the versions associated with the values found in the RPMTAG_REQUIRENAME Index.
Bits(s) to specify the conflict range and context.
This tag indicates the conflictind dependencies for this package.
This tag indicates the versions associated with the values found in the RPMTAG_CONFLICTNAME Index.
This tag indicates the obsoleted dependencies for this package.
Bits(s) to specify the conflict range and context.
This tag indicates the versions associated with the values found in the RPMTAG_PROVIDENAME Index.
Bits(s) to specify the conflict range and context.
This tag indicates the versions associated with the values found in the RPMTAG_OBSOLETENAME Index.
The package dependencies are stored in the
RPMTAG_REQUIRENAME
and
RPMTAG_REQUIREVERSION
index records. The following values may be used.
Table 1-12. Index Type values
Name | Version | Meaning | Status |
---|---|---|---|
rpmlib(VersionedDependencies) | 3.0.3-1 | Indicates that the package contains RPMTAG_PROVIDENAME, RPMTAG_OBSOLETENAME or RPMTAG_PREREQ records that have a version associated with them. | Optional |
rpmlib(PayloadFilesHavePrefix) | 4.0-1 | Indicates the filenames in the Archive have had "." prepended to them. | Optional |
rpmlib(CompressedFileNames) | 3.0.4-1 | Indicates that the filenames in the Payload are represented in the RPMTAG_DIRINDEXES, RPMTAG_DIRNAME and RPMTAG_BASENAMES indexes. | Optional |
/bin/sh | Interpreter usually required for installation scripts. | Optional |
Additional dependencies are specified in the Package Dependencies section of this document, and the architecture specific documents.
The package dependency attributes are stored in the
RPMTAG_REQUIREFLAGS
,
RPMTAG_PROVIDEFLAGS
and
RPMTAG_OBSOLETEFLAGS
index records. The following values may be used.
The following tag values are also found in the Header section.
Table 1-14. Other Tag Values
Name | Tag Value | Type | Count | Status |
---|---|---|---|---|
RPMTAG_BUILDTIME | 1006 | INT32 | 1 | Informational |
RPMTAG_BUILDHOST | 1007 | STRING | 1 | Informational |
RPMTAG_FILEVERIFYFLAGS | 1045 | INT32 | Optional | |
RPMTAG_CHANGELOGTIME | 1080 | INT32 | Optional | |
RPMTAG_CHANGELOGNAME | 1081 | STRING_ARRAY | Optional | |
RPMTAG_CHANGELOGTEXT | 1082 | STRING_ARRAY | Optional | |
RPMTAG_OPTFLAGS | 1122 | STRING | 1 | Informational |
RPMTAG_RHNPLATFORM | 1131 | STRING | 1 | Deprecated |
RPMTAG_PLATFORM | 1132 | STRING | 1 | Informational |
This tag specifies the time as seconds since the epoch at which the package was built.
This tag specifies the hostname of the system on which which the package was built.
This tag specifies the bit(s) to control how files are to be verified after install, specifying which checks should be performed.
This tag specifies the Unix time in seconds since the epoch associated with each entry in the Changelog file.
This tag specifies the name of who made a change to this package
This tag specifies the changes asssociated with a changelog entry.
This tag indicates additional flags which may have been passed to the compiler when building this package.
This tag contains an opaque string whose contents are undefined.
This tag contains an opaque string whose contents are undefined.
The Payload section contains a compressed cpio archive. The format of this section is defined by RFC 1952: GZIP File Format Specification.
When uncompressed, the cpio archive contains a sequence of records for each file. Each record contains a CPIO Header, Filename, Padding, and File Data.
Table 1-15. CPIO File Format
CPIO Header | Header structure as defined below. |
Filename | NUL terminated ASCII string containing the name of the file. |
Padding | 0-3 bytes as needed to align the file stream to a 4 byte boundary. |
File data | The contents of the file. |
Padding | 0-3 bytes as needed to align the file stream to a 4 byte boundary. |
The CPIO Header uses the following header structure (sometimes referred to
as "new ASCII" or "SVR4 cpio"). All numbers are stored as ASCII
representations of their hexadecimal value with leading zeros as needed to fill
the field. With the exception of c_namesize
and the corresponding name string, and c_checksum
,
all information contained in the CPIO Header is also represented in the
Header Section.
The values in in the CPIO Header shall match the values contained in the
Header Section.
struct { char c_magic[6]; char c_ino[8]; char c_mode[8]; char c_uid[8]; char c_gid[8]; char c_nlink[8]; char c_mtime[8]; char c_filesize[8]; char c_devmajor[8]; char c_devminor[8]; char c_rdevmajor[8]; char c_rdevminor[8]; char c_namesize[8]; char c_checksum[8]; }; |
c_magic
Value identifying this cpio format. This value shall be "070701".
c_ino
This field contains the inode number from the filesystem from which the
file was read.
This field is ignored when installing a package.
This field shall match the corresponding value in the
RPMTAG_FILEINODES
index in the Header section.
c_mode
Permission bits of the file. This is an ascii representation of the hexadecimal
number representing the bit as defined for the
st_mode
field of the stat
structure defined for the stat
function.
This field shall match the corresponding value in the
RPMTAG_FILEMODES
index in the Header section.
c_uid
Value identifying this owner of this file. This value matches the uid value of the corresponding user in the RPMTAG_FILEUSERNAME as found on the system where this package was built. The username specified in RPMTAG_FILEUSERNAME should take precedence when installing the package.
c_gid
Value identifying this group of this file. This value matches the gid value of the corresponding user in the RPMTAG_FILEGROUPNAME as found on the system where this package was built. The groupname specified in RPMTAG_FILEGROUPNAME should take precedence when installing the package.
c_nlink
Value identifying the number of links associated with this file. If the value is greater than 1, then this filename will be linked to 1 or more files in this archive that has a matching value for the c_ino, c_devmajor and c_devminor fields.
c_mtime
Value identifying the modification time of the file when it was read.
This field shall match the corresponding value in the
RPMTAG_FILEMTIMES
index in the Header section.
c_filesize
Value identifying the size of the file.
This field shall match the corresponding value in the
RPMTAG_FILESIZES
index in the Header section.
c_devmajor
The major number of the device containing the file system from which the
file was read.
With the exception of processing files with c_nlink >1, this field is ignored
when installing a package.
This field shall match the corresponding value in the
RPMTAG_FILEDEVICES
index in the Header section.
c_devminor
The minor number of the device containing the file system from which the
file was read.
With the exception of processing files with c_nlink >1, this field is ignored
when installing a package.
This field shall match the corresponding value in the
RPMTAG_FILEDEVICES
index in the Header section.
c_rdevmajor
The major number of the raw device containing the file system from which the
file was read.
This field is ignored when installing a package.
This field shall match the corresponding value in the
RPMTAG_RDEVS
index in the Header section.
c_rdevminor
The minor number of the raw device containing the file system from which the
file was read.
This field is ignored when installing a package.
This field shall match the corresponding value in the
RPMTAG_RDEVS
index in the Header section.
c_namesize
Value identifying the length of the filename, which is located immediately following the CPIO Header structure.
c_checksum
Value containing the CRC checksum of the file data. This field is not used, and shall contain the value "00000000". This field is ignored when installing a package.
A record with the filename "TRAILER!!!" indicates the last record in the archive.
Scripts used as part of the package install and uninstall shall only use commands and interfaces that are specified by the LSB. All other commands are not guaranteed to be present, or to behave in expected ways.
Packages shall not use RPM triggers.
Packages shall not depend on the order in which scripts are executed (pre-install, pre-uninstall, &c), when doing an upgrade.
The LSB does not specify the interface to the tools used to manipulate LSB-conformant packages. Each conforming distribution shall provide documentation for installing LSB packages.
Packages supplied by distributions and applications must follow the following rules for the name field within the package. These rules are not required for the filename of the package file itself.[4]
The following rules apply to the name field alone, not including any release or version.[5]
If the name begins with "lsb-" and contains no other hyphens, the name shall be assigned by the Linux Assigned Names and Numbers Authority (LANANA), which shall maintain a registry of LSB names. The name may be registered by either a distribution or an application.
If the package name begins with "lsb-" and contains more than one hyphen (for example "lsb-distro.example.com-database" or "lsb-gnome-gnumeric"), then the portion of the package name between first and second hyphens shall either be an LSB provider name assigned by the LANANA, or it may be one of the owners' fully-qualified domain names in lower case (e.g., "debian.org", "staroffice.sun.com"). The LSB provider name assigned by LANANA shall only consist of the ASCII characters [a-z0-9]. The provider name or domain name may be either that of a distribution or an application.
Package names containing no hyphens are reserved for use by distributions. Applications must not use such names.[6]
Package names which do not start with "lsb-" and which contain a hyphen are open to both distributions and applications. Distributions may name packages in any part of this namespace. They are encouraged to use names from one of the other namespaces available to them, but this is not required due to the large amount of current practice to the contrary.[7] Applications may name their packages this way, but only if the portion of the name before the first hyphen is a provider name or registered domain name as described above.[8]Note that package names in this namespace are available to both the distribution and an application. Distributions and applications will need to consider this potential for conflicts when deciding to use these names rather than the alternatives (such as names starting with "lsb-").
Packages shall have a dependency that indicates which LSB modules are required. LSB module descriptions are dash seperated tuples containing the name 'lsb', the module name, and the architecture name. The following dependencies may be used.
This dependency is used to indicate that the application is dependent on features contained in the LSB-Core specification.
This dependency is used to indicate that the application is dependent on features contained in the LSB-Core specification and that the package does not contain any architecture specific files.
These dependencies shall have a version of 3.0.
Packages shall not depend on other system-provided dependencies. They shall not depend on non-system-provided dependencies unless those dependencies are fulfilled by packages which are part of the same application. A package may only provide a virtual package name which is registered to that application.
Other modules in the LSB may supplement this list. The architecture specific dependencies are described in the relevant architecture specific LSB.
Packages which do not contain any architecture specific files must specify an architecture of noarch. A LSB runtime environment must accept values noarch, or the value specified in the architecture specific supplement.
Additional specifications or restrictions may be found in the architecture specific LSB specification.
Version 1.1, March 2000
Copyright (C) 2000 Free Software Foundation, Inc. 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA Everyone is permitted to copy and distribute verbatim copies of this license document, but changing it is not allowed.
The purpose of this License is to make a manual, textbook, or other written document "free" in the sense of freedom: to assure everyone the effective freedom to copy and redistribute it, with or without modifying it, either commercially or noncommercially. Secondarily, this License preserves for the author and publisher a way to get credit for their work, while not being considered responsible for modifications made by others.
This License is a kind of "copyleft", which means that derivative works of the document must themselves be free in the same sense. It complements the GNU General Public License, which is a copyleft license designed for free software.
We have designed this License in order to use it for manuals for free software, because free software needs free documentation: a free program should come with manuals providing the same freedoms that the software does. But this License is not limited to software manuals; it can be used for any textual work, regardless of subject matter or whether it is published as a printed book. We recommend this License principally for works whose purpose is instruction or reference.
This License applies to any manual or other work that contains a notice placed by the copyright holder saying it can be distributed under the terms of this License. The "Document", below, refers to any such manual or work. Any member of the public is a licensee, and is addressed as "you".
A "Modified Version" of the Document means any work containing the Document or a portion of it, either copied verbatim, or with modifications and/or translated into another language.
A "Secondary Section" is a named appendix or a front-matter section of the Document that deals exclusively with the relationship of the publishers or authors of the Document to the Document's overall subject (or to related matters) and contains nothing that could fall directly within that overall subject. (For example, if the Document is in part a textbook of mathematics, a Secondary Section may not explain any mathematics.) The relationship could be a matter of historical connection with the subject or with related matters, or of legal, commercial, philosophical, ethical or political position regarding them.
The "Invariant Sections" are certain Secondary Sections whose titles are designated, as being those of Invariant Sections, in the notice that says that the Document is released under this License.
The "Cover Texts" are certain short passages of text that are listed, as Front-Cover Texts or Back-Cover Texts, in the notice that says that the Document is released under this License.
A "Transparent" copy of the Document means a machine-readable copy, represented in a format whose specification is available to the general public, whose contents can be viewed and edited directly and straightforwardly with generic text editors or (for images composed of pixels) generic paint programs or (for drawings) some widely available drawing editor, and that is suitable for input to text formatters or for automatic translation to a variety of formats suitable for input to text formatters. A copy made in an otherwise Transparent file format whose markup has been designed to thwart or discourage subsequent modification by readers is not Transparent. A copy that is not "Transparent" is called "Opaque".
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The "Title Page" means, for a printed book, the title page itself, plus such following pages as are needed to hold, legibly, the material this License requires to appear in the title page. For works in formats which do not have any title page as such, "Title Page" means the text near the most prominent appearance of the work's title, preceding the beginning of the body of the text.
You may copy and distribute the Document in any medium, either commercially or noncommercially, provided that this License, the copyright notices, and the license notice saying this License applies to the Document are reproduced in all copies, and that you add no other conditions whatsoever to those of this License. You may not use technical measures to obstruct or control the reading or further copying of the copies you make or distribute. However, you may accept compensation in exchange for copies. If you distribute a large enough number of copies you must also follow the conditions in section 3.
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If you publish printed copies of the Document numbering more than 100, and the Document's license notice requires Cover Texts, you must enclose the copies in covers that carry, clearly and legibly, all these Cover Texts: Front-Cover Texts on the front cover, and Back-Cover Texts on the back cover. Both covers must also clearly and legibly identify you as the publisher of these copies. The front cover must present the full title with all words of the title equally prominent and visible. You may add other material on the covers in addition. Copying with changes limited to the covers, as long as they preserve the title of the Document and satisfy these conditions, can be treated as verbatim copying in other respects.
If the required texts for either cover are too voluminous to fit legibly, you should put the first ones listed (as many as fit reasonably) on the actual cover, and continue the rest onto adjacent pages.
If you publish or distribute Opaque copies of the Document numbering more than 100, you must either include a machine-readable Transparent copy along with each Opaque copy, or state in or with each Opaque copy a publicly-accessible computer-network location containing a complete Transparent copy of the Document, free of added material, which the general network-using public has access to download anonymously at no charge using public-standard network protocols. If you use the latter option, you must take reasonably prudent steps, when you begin distribution of Opaque copies in quantity, to ensure that this Transparent copy will remain thus accessible at the stated location until at least one year after the last time you distribute an Opaque copy (directly or through your agents or retailers) of that edition to the public.
It is requested, but not required, that you contact the authors of the Document well before redistributing any large number of copies, to give them a chance to provide you with an updated version of the Document.
You may copy and distribute a Modified Version of the Document under the conditions of sections 2 and 3 above, provided that you release the Modified Version under precisely this License, with the Modified Version filling the role of the Document, thus licensing distribution and modification of the Modified Version to whoever possesses a copy of it. In addition, you must do these things in the Modified Version:
Use in the Title Page (and on the covers, if any) a title distinct from that of the Document, and from those of previous versions (which should, if there were any, be listed in the History section of the Document). You may use the same title as a previous version if the original publisher of that version gives permission.
List on the Title Page, as authors, one or more persons or entities responsible for authorship of the modifications in the Modified Version, together with at least five of the principal authors of the Document (all of its principal authors, if it has less than five).
State on the Title page the name of the publisher of the Modified Version, as the publisher.
Preserve all the copyright notices of the Document.
Add an appropriate copyright notice for your modifications adjacent to the other copyright notices.
Include, immediately after the copyright notices, a license notice giving the public permission to use the Modified Version under the terms of this License, in the form shown in the Addendum below.
Preserve in that license notice the full lists of Invariant Sections and required Cover Texts given in the Document's license notice.
Include an unaltered copy of this License.
Preserve the section entitled "History", and its title, and add to it an item stating at least the title, year, new authors, and publisher of the Modified Version as given on the Title Page. If there is no section entitled "History" in the Document, create one stating the title, year, authors, and publisher of the Document as given on its Title Page, then add an item describing the Modified Version as stated in the previous sentence.
Preserve the network location, if any, given in the Document for public access to a Transparent copy of the Document, and likewise the network locations given in the Document for previous versions it was based on. These may be placed in the "History" section. You may omit a network location for a work that was published at least four years before the Document itself, or if the original publisher of the version it refers to gives permission.
In any section entitled "Acknowledgements" or "Dedications", preserve the section's title, and preserve in the section all the substance and tone of each of the contributor acknowledgements and/or dedications given therein.
Preserve all the Invariant Sections of the Document, unaltered in their text and in their titles. Section numbers or the equivalent are not considered part of the section titles.
Delete any section entitled "Endorsements". Such a section may not be included in the Modified Version.
Do not retitle any existing section as "Endorsements" or to conflict in title with any Invariant Section.
If the Modified Version includes new front-matter sections or appendices that qualify as Secondary Sections and contain no material copied from the Document, you may at your option designate some or all of these sections as invariant. To do this, add their titles to the list of Invariant Sections in the Modified Version's license notice. These titles must be distinct from any other section titles.
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To use this License in a document you have written, include a copy of the License in the document and put the following copyright and license notices just after the title page:
Copyright (c) YEAR YOUR NAME. Permission is granted to copy, distribute and/or modify this document under the terms of the GNU Free Documentation License, Version 1.1 or any later version published by the Free Software Foundation; with the Invariant Sections being LIST THEIR TITLES, with the Front-Cover Texts being LIST, and with the Back-Cover Texts being LIST. A copy of the license is included in the section entitled "GNU Free Documentation License".
If you have no Invariant Sections, write "with no Invariant Sections" instead of saying which ones are invariant. If you have no Front-Cover Texts, write "no Front-Cover Texts" instead of "Front-Cover Texts being LIST"; likewise for Back-Cover Texts.
If your document contains nontrivial examples of program code, we recommend releasing these examples in parallel under your choice of free software license, such as the GNU General Public License, to permit their use in free software.
[1] | Future versions of this specification might define additional service names. |
[2] | Supplying an RPM format package is encouraged because it makes systems easier to manage. A future version of the LSB may require RPM, or specify a way for an installer to update a package database. Applications are also encouraged to uninstall cleanly. |
[3] | The distribution itself may use a different packaging format for its own packages, and of course it may use any available mechanism for installing the LSB-conformant packages. |
[4] | For example, there are discrepancies among distributions concerning whether the name might be frobnicator-1.7-21-ppc32.rpm or frobnicator-1.7-21-powerpc32.rpm. The architecture aside, recommended practice is for the filename of the package file to match the name within the package. |
[5] | For example, if the name with the release and version is frobnicator-1.7-21, the name part is frobnicator and falls under the rules for a name with no hyphens. |
[6] | For example, "frobnicator". |
[7] | For example, ssh-common, ssh-client, kernel-pcmcia, and the like. Possible alternative names include sshcommon, foolinux-ssh-common (where foolinux is registered to the distribution), or lsb-foolinux-ssh-common. |
[8] | For example, if an application vendor has domain name visicalc.example.com and has registered visicalc as a provider name, they might name packages visicalc-base, visicalc.example.com-charting, and the like. |