Linux Standard Base Specification for the Itanium™ Architecture 1.3

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Portions of the text were taken from other copyrighted documents in accordance with the respective licenses of those documents.

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.

Intel386 and Itanium are trademarks of Intel Corporation.

OpenGL is a registered trademark of Silicon Graphics, Inc.


Table of Contents
I. Introduction
1. Introduction
Introduction
Purpose
Related Standards
Relevant Libraries
How to Use this Standard
Definitions
Terminology
II. Low Level System Information
2. Machine Interface
Processor Architecture
Data Representation
3. Function Calling Sequence
CPU Registers
Floating Point Registers
Stack Frame
Arguments
Return Values
4. Operating System Interface
Processor Execution Mode
Exception Interface
Signal Delivery
5. Process Initialization
Special Registers
Process Stack (on entry)
Auxiliary Vector
Environment
6. Coding Examples
Code Model Overview/Architecture Constraints
Position-Independent Function Prologue
Data Objects
Function Calls
Branching
7. C Stack Frame
Variable Argument List
Dynamic Allocation of Stack Space
8. Debug Information
III. Object Format
9. ELF Header
Machine Information
10. Sections
Special Sections
Linux Special Sections
Section Types
Section Attribute Flags
Special Section Types
11. Symbol Table
12. Relocation
Relocation Types
IV. Program Loading and Dynamic Linking
13. Program Header
Types
Flags
14. Program Loading
15. Dynamic Linking
Program Interpreter/Dynamic Linker
Dynamic Section
Global Offset Table
Shared Object Dependencies
Function Addresses
Procedure Linkage Table
Initialization and Termination Functions
V. Base Libraries
16. Libraries
Interfaces for libc
Data Definitions for libc
Interfaces for libm
Data Definitions for libm
Interfaces for libpthread
Data Definitions for libpthread
Interfaces for libdl
Data Definitions for libdl
Interfaces for libcrypt
Data Definitions for libcrypt
VI. Package Format and Installation
17. Software Installation
Package Architecture Considerations
A. Alphabetical Listing of Interfaces
B. GNU Free Documentation License
PREAMBLE
APPLICABILITY AND DEFINITIONS
VERBATIM COPYING
COPYING IN QUANTITY
MODIFICATIONS
COMBINING DOCUMENTS
COLLECTIONS OF DOCUMENTS
AGGREGATION WITH INDEPENDENT WORKS
TRANSLATION
TERMINATION
FUTURE REVISIONS OF THIS LICENSE
How to use this License for your documents
C. Build Environment
Introduction
Build Environment
Pre-Defined Preprocessor Symbols
Pre-Defined Preprocessor Assertions
Compiler Pragmas
ILP32 ABI
Synchronization Primitives
Thread-Local Storage
List of Tables
1-1. Related Standards
1-2. Standard Library Names
2-1. Scalar Types
9-1. Additional Processor-Specific Flags
10-1. ELF Special Sections
10-2. Additional Special Sections
16-1. libc Definition
16-2. libc - RPC Function Interfaces
16-3. libc - System Calls Function Interfaces
16-4. libc - System Calls Deprecated Function Interfaces
16-5. libc - Standard I/O Function Interfaces
16-6. libc - Standard I/O Deprecated Function Interfaces
16-7. libc - Standard I/O Data Interfaces
16-8. libc - Signal Handling Function Interfaces
16-9. libc - Signal Handling Data Interfaces
16-10. libc - Localization Functions Function Interfaces
16-11. libc - Localization Functions Deprecated Function Interfaces
16-12. libc - Localization Functions Data Interfaces
16-13. libc - Socket Interface Function Interfaces
16-14. libc - Wide Characters Function Interfaces
16-15. libc - String Functions Function Interfaces
16-16. libc - IPC Functions Function Interfaces
16-17. libc - Regular Expressions Function Interfaces
16-18. libc - Regular Expressions Data Interfaces
16-19. libc - Character Type Functions Function Interfaces
16-20. libc - Character Type Functions Data Interfaces
16-21. libc - Time Manipulation Function Interfaces
16-22. libc - Time Manipulation Data Interfaces
16-23. libc - Terminal Interface Functions Function Interfaces
16-24. libc - System Database Interface Function Interfaces
16-25. libc - System Database Interface Deprecated Function Interfaces
16-26. libc - Language Support Function Interfaces
16-27. libc - Large File Support Function Interfaces
16-28. libc - Large File Support Deprecated Function Interfaces
16-29. libc - Standard Library Function Interfaces
16-30. libc - Standard Library Data Interfaces
16-31. libm Definition
16-32. libm - Math Function Interfaces
16-33. libm - Math Data Interfaces
16-34. libpthread Definition
16-35. libpthread - Posix Threads Function Interfaces
16-36. libdl Definition
16-37. libcrypt Definition
C-1. Pre-Defined Preprocessor Symbols
C-2. Intrinsic Functions
List of Figures
2-1. Structure Smaller Than A Word
2-2. No Padding
2-3. Internal and Tail Padding
2-4. Bit-Field Ranges

I. Introduction

Table of Contents
1. Introduction

Chapter 1. Introduction

Introduction

This is version 1.3 of the Linux Standard Base Specification for the Itanium™ Architecture. 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.


Purpose

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.

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 must 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.

The LSB is composed of two basic parts: A common part of the specification describes those parts of the interface that remain constant across all hardware implementations of the LSB, and an architecture-specific part of the specification describes the parts of the specification that are specific to a particular processor architecture. Together, the generic LSB 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.

This document is the architecture-specific supplement. It must be used in conjunction with the generic LSB. This document provides architecture-specific information that supplements the generic LSB as well as additional information that is not found in the generic LSB.

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.


Related Standards

The specifications listed below are referenced in whole or in part by the Linux Standard Base. Such references may be normative or non-normative; a reference to specification shall only be considered normative if it is explicitly cited as such. The LSB may make normative references to a portion of these specifications (that is, to define a specific function or group of functions); in such cases, only the explicitly referenced portion of the specification is to be considered normative.

Table 1-1. Related Standards

System V Application Binary Interface - DRAFT - 22 June 2000http://www.caldera.com/developers/gabi/2000-07-17/contents.html
DWARF Debugging Information Format, Revision 2.0.0 (July 27, 1993)
Filesystem Hierarchy Standard (FHS) 2.2http://www.pathname.com/fhs/
IEEE Standard for Binary Floating-Point Arithmetichttp://www.ieee.org/
System V Application Binary Interface, Edition 4.1http://www.caldera.com/developers/devspecs/gabi41.pdf
Intel® Itanium ™ Processor-specific Application Binary Interfacehttp://developer.intel.com/design/itanium/downloads/245370.htm
Itanium ™ Software Conventions & Runtime Architecture Guidehttp://developer.intel.com/design/itanium/downloads/24535803s.htm
Itanium ™ Architecture Software Developer's Manual Volume 1: Application Architecturehttp://developer.intel.com/design/itanium/downloads/24531703s.htm
Itanium ™ Architecture Software Developer's Manual Volume 2: System Architecturehttp://developer.intel.com/design/itanium/downloads/24531803s.htm
Itanium ™ Architecture Software Developer's Manual Volume 3: Instruction Set Referencehttp://developer.intel.com/design/itanium/downloads/24531903s.htm
IA-64 Processor Reference: Intel® Itanium ™ Processor Reference Manual for Software Developmenthttp://developer.intel.com/design/itanium/downloads/24532003s.htm
ISO/IEC 9899: 1990, Programming Languages --C
ISO/IEC 9899: 1999, Programming Languages --C
ISO/IEC 14882: 1998(E) Programming languages --C++
Linux Assigned Names And Numbers Authorityhttp://www.lanana.org/
Large File Supporthttp://www.UNIX-systems.org/version2/whatsnew/lfs20mar.html
LI18NUX 2000 Globalization Specification, Version 1.0 with Amendment 4http://www.li18nux.org/docs/html/LI18NUX-2000-amd4.htm
Linux Standard Basehttp://www.linuxbase.org/spec/
OpenGL® Application Binary Interface for Linuxhttp://oss.sgi.com/projects/ogl-sample/ABI/
OSF-RFC 86.0http://www.opengroup.org/tech/rfc/mirror-rfc/rfc86.0.txt
IEEE Std POSIX 1003.2-1992 (ISO/IEC 9945-2:1993)http://www.ieee.org/
POSIX 1003.1chttp://www.ieee.org/
RFC 1952: GZIP file format specification version 4.3http://www.ietf.org/rfc/rfc1952.txt
RFC 2440: OpenPGP Message Format
CAE Specification, May 1996, X/Open Curses, Issue 4, Version 2 (ISBN: 1-85912-171-3, C610), plus Corrigendum U018http://www.opengroup.org/publications/catalog/un.htm
CAE Specification, January 1997, System Interface Definitions (XBD),Issue 5 (ISBN: 1-85912-186-1, C605)http://www.opengroup.org/publications/catalog/un.htm
CAE Specification, January 1997, Commands and Utilities (XCU), Issue 5 (ISBN: 1-85912-191-8, C604)http://www.opengroup.org/publications/catalog/un.htm
CAE Specification, February 1997, Networking Services (XNS), Issue 5(ISBN: 1-85912-165-9, C523)http://www.opengroup.org/
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
The Single UNIX® Specification(SUS) Version 1 (UNIX 95) System Interfaces & Headershttp://www.opengroup.org/publications/catalog/un.htm
The Single UNIX® Specification(SUS) Version 3http://www.unix.org/version3/
System V Interface Definition, Issue 3 (ISBN 0201566524)
System V Interface Definition,Fourth Edition
Double Buffer Extension Libraryhttp://www.x.org/
X Display Power Management Signaling (DPMS) Extension, Library Specificationhttp://www.x.org/
X Record Extension Libraryhttp://www.x.org/
Security Extension Specification, Version 7.1http://www.x.org/
X Nonrectangular Window Shape Extension Library Version 1.0http://www.x.org/
MIT-SHM--The MIT Shared Memory Extensionhttp://www.x.org/
X Synchronization Extension Libraryhttp://www.x.org/
XTEST Extension Libraryhttp://www.x.org/
X11R6.4 X Inter-Client Exchange (ICE) Protocolhttp://www.x.org/
X11R6.4 X11 Input Extension Libraryhttp://www.x.org/
X11R6.4 Xlib - C libraryhttp://www.x.org/
X/Open Portability Guide, Issue 4http://www.opengroup.org/
X11R6.4 X Session Management Libraryhttp://www.x.org/
X11R6.4 X Toolkit Intrinsicshttp://www.x.org/
zlib 1.1.3 Manualhttp://www.gzip.org/zlib/

Relevant Libraries

The libraries listed here shall be available on a Linux Standard Base system. This list is an addition to the list in the general specification.

Table 1-2. Standard Library Names

LibraryRuntime Name
libmlibm.so.6.1
libdllibdl.so.2
libcryptlibcrypt.so.1
libclibc.so.6.1
libpthreadlibpthread.so.0
proginterp/lib/ld-lsb-ia64.so.1

These libraries will be in an implementation-dependent directory which the dynamic linker will search by default.


How to Use this Standard

The complete LSB specification is composed of a generic LSB specification and this supplemental processor-specific specification. These two documents constitute a specification that should be used in conjunction with the publicly-available standards documents it references. The LSB enumerates the system components it includes, but descriptions of those components may be included entirely in the LSB, partly in the LSB and partly in other documents, or entirely in other reference documents.


Definitions

gLSB

The common part of the LSB Specification that describes those parts of the interface that remain constant across all hardware implementations of the LSB.

archLSB

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.

LSB Implementation Conformance

An implementation satisfying the following requirements:

  1. The implementation shall implement fully the architecture described in the hardware manual for the target processor architecture.

  2. The implementation shall be capable of executing compiled applications having the format and using the system interfaces described in this document.

  3. 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.

  4. The map of virtual memory provided by the implementation shall conform to the requirements of this document.

  5. 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.

  6. The implementation shall provide all of the mandatory interfaces in their entirety.

  7. 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.

  8. 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.

  9. 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.

  10. 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.

LSB Application Conformance

An application with the following characteristics:

  1. Its executable files are either shell scripts or object files in the format defined for the Object File Format system interface.

  2. Its object files participate in dynamic linking as defined in the Program Loading and Linking System interface.

  3. It employs only the instructions, traps, and other low-level facilities defined in the Low-Level System interface as being for use by applications.

  4. 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.

  5. 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.

  6. It must not use any values for a named interface that are reserved for vendor extensions.

A strictly conforming application does not require or use any interface, facility, or implementation-defined extension that is not defined in this document in order to be installed or to execute successfully.

Rationale

An LSB conforming application is expected to have no dependencies on any vendor extensions to this document. The most common such extensions are additional function entry points and additional libraries other than the ones defined in this document. If an application requires such extensions, it is not portable, since other LSB conforming implementations may not provide those extensions.

An LSB conforming application is required to use system services on the implementation on which it is running, rather than importing system routines from some other implementation. Thus, it must link dynamically to any routines in the implementation that perform system traps to kernel services.

It is to be expected that some applications may be companion applications to other applications. For example, a query application may be a companion to a database application; a preprocessor may be an adjunct to one or more compilers; a data reformatter may convert data from one document manager to another. In such cases, the application may or may not be LSB conforming, regardless of whether the other application on which it is dependent is LSB conforming. If such an application merely uses data produced by another application, the application's compliance is independent of the other application's compliance. If such an application actually invokes another application during execution (as, for example, a third-party math library), the invoking application is LSB conforming only if it also constitutes a LSB conforming application in combination with the invoked application.

Shell Script

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.


Terminology

can

Describes a permissible optional feature or behavior available to the user or application. The feature or behavior is mandatory for an implementation that conforms to this document. An application can rely on the existence of the feature or behavior.

implementation-defined

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.

may

Describes a feature or behavior that is optional for an implementation that conforms to this document. An application should not rely on the existence of the feature or behavior. An application that relies on such a feature or behavior cannot be assured to be portable across conforming implementations.

To avoid ambiguity, the opposite of may is expressed as need not, instead of may not.

must

Describes a feature or behavior that is mandatory for an application or user. An implementation that conforms to this document shall support this feature or behavior.

shall

Describes a feature or behavior that is mandatory for an implementation that conforms to this document. An application can rely on the existence of the feature or behavior.

should

For an implementation that conforms to this document, describes a feature or behavior that is recommended but not mandatory. An application should not rely on the existence of the feature or behavior. An application that relies on such a feature or behavior cannot be assured to be portable across conforming implementations.

For an application, describes a feature or behavior that is recommended programming practice for optimum portability.

undefined

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.

unspecified

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.

will

Same meaning as shall; shall is the preferred term.


Chapter 2. Machine Interface

Processor Architecture

The Itanium™ Architecture is specified by the following documents

Only the features of the Itanium™ processor instruction set may be assumed to be present. An application is responsible for determining if any additional instruction set features are available before using those additional features. If a feature is not present, then the application may not use it.

There are some features of the Itanium™ processor architecture that need not be supported by a conforming implementation. These are described in this chapter. A conforming application shall not rely on these features.

Applications conforming to this specification must provide feedback to the user if a feature that is required for correct execution of the application is not present. Applications conforming to this specification should attempt to execute in a diminished capacity if a required feature is not present.

This specfication does not provide any performance guarantees of a conforming system. A system conforming to this specification may be implemented in either hardware or software.

This specification describes only LP64 (i.e. 32-bit integers, 64-bit longs and pointers) based implementations. Implementations may also provide ILP32 (32-bit integers, longs, and pointers), but conforming applications shall not rely on support for ILP32. See section 1.2 of the Intel® Itanium ™ Processor-specific Application Binary Interface for further information.


Data Representation

See Itanium ™ Software Conventions & Runtime Architecture Guide Chapter 4.

Within this specification, the term byte refers to an 8-bit object, the term halfword refers to a 16-bit object, the term word refers to a 32-bit object, the term doubleword refers to a 64-bit object, and the term quadword refers to a 128-bit object. Although the Itanium™ architecture also supports 120-bit addressable objects, this specification does not require LSB-conforming implementations to provide support for these objects.


Byte Ordering

LSB-conforming applications shall use little-endian byte ordering. LSB-conforming implementations may support big-endian applications.


Fundamental Types

Table 2-1 describes how fundemental C language data types shall be represented:

Table 2-1. Scalar Types

TypeCsizeofAlignment (bytes)Notes
Integralchar11 
signed char
unsigned char
short22 
signed short
unsigned short
int44 
signed int
unsigned int
long88 
signed long
unsigned long
long long88See Note Below
signed long long
unsigned long long
Pointerany-type *88 
any-type (*)()
Floating-Pointfloat44 
double88 
long double1616 

Note

Support for the long long data type is dependent on support for ISO9899:1999 C language. This standard is not required for LSB-conformance, but this data type is important when developing applications for the Itanium™ architecture. The GNU Compiler Collection (gcc) includes support for long long of ISO9899:1999.

A null pointer (for all types) shall have the value zero.


Aggregates and Unions

Aggregates (structures and arrays) and unions assume the alignment of their most strictly aligned component. The size of any object, including aggregates and unions, shall always be a multiple of the object's alignment. An array uses the same alignment as its elements. Structure and union objects may require padding to meet size and element constraints. The contents of such padding is undefined.

  • An entire structure or union object shall be aligned on the same boundary as its most strictly aligned member.

  • Each member shall be assigned to the lowest available offset with the appropriate alignment. This may require internal padding, depending on the previous member.

  • A structure's size shall be increased, if necessary, to make it a multiple of the alignment. This may require tail padding, depending on the last member.

A conforming application shall not read padding.

Figure 2-1. Structure Smaller Than A Word

    struct {
        char c;
    }
   
Byte aligned, sizeof is 1
OffsetByte 0
0c0

Figure 2-2. No Padding

    struct {
        char  c;
        char  d;
        short s;
        int   i;
        long  l;
    }
   
Doubleword Aligned, sizeof is 16
OffsetByte 3Byte 2Byte 1Byte 0
0s2d1c0
4i0
8l0
12 

Figure 2-3. Internal and Tail Padding

    struct {
        char  c;
        long  l;
        int   i;
        short s;
    }
   
Doubleword Aligned, sizeof is 24
OffsetByte 3Byte 2Byte 1Byte 0
0pad1c0
4pad1
8l0
12 
16i0
20pad2s0


Bit Fields

C struct and union definitions may have bit-fields, which define integral objects with a specified number of bits.

Bit fields that are declared with neither signed nor unsigned specifier shall always be treated as unsigned. Bit fields obey the same size and alignment rules as other structure and union members, with the following additional properties:

  • Bit-fields are allocated from right to left (least to most significant).

  • A bit-field must entirely reside in a storage unit for its appropriate type. A bit field shall never cross its unit boundary.

  • Bit-fields may share a storage unit with other struct/union members, including members that are not bit fields. Such other struct/union members shall occupy different parts of the storage unit.

  • The type of unnamed bit-fields shall not affect the alignment of a structure or union, although individual bit-field member offsets shall obey the alignment constraints.

Figure 2-4. Bit-Field Ranges

Bit-field TypeWidth wRange
signed char
char
unsigned char
     
1 to 8
-2w-1 to 2w-1-1
0 to 2w-1
0 to 2w-1
     
signed short
short
unsigned short
     
1 to 16
-2w-1 to 2w-1-1
0 to 2w-1
0 to 2w-1
     
signed int
int
unsigned int
     
1 to 32
-2w-1 to 2w-1-1
0 to 2w-1
0 to 2w-1
     
signed long
long
unsigned long
     
1 to 64
-2w-1 to 2w-1-1
0 to 2w-1
0 to 2w-1
     


Chapter 3. Function Calling Sequence

LSB-conforming applications shall use the procedure linkage and function calling sequence as defined in Chapter 8.4 of the Itanium ™ Software Conventions & Runtime Architecture Guide.


CPU Registers

The CPU general and other registers are as defined in the Itanium ™ Architecture Software Developer's Manual Volume 1: Application Architecture Section 3.1.


Floating Point Registers

The floating point registers are as defined in the Itanium ™ Architecture Software Developer's Manual Volume 1: Application Architecture Section 3.1.


Stack Frame

The stackframe layout is as described in the Itanium ™ Software Conventions & Runtime Architecture Guide Chapter 8.4.


Arguments

The procedure argument passing mechanism is as described in the Itanium ™ Software Conventions & Runtime Architecture Guide Chapter 8.5.


Return Values

See Itanium ™ Software Conventions & Runtime Architecture Guide Chapter 8.6.


Void

Functions that return no value (void functions) are not required to put any particular value in any general register.


Struct and Union

See Itanium ™ Software Conventions & Runtime Architecture Guide Chapter 8.6 (aggregate return values). Depending on the size (including any padding), aggregate data types may be passed in one or more general registers, or in memory.


Chapter 4. Operating System Interface

LSB-conforming applications shall use the Operating System Interfaces as defined in Chapter 3 of the Intel® Itanium ™ Processor-specific Application Binary Interface.


Processor Execution Mode

Applications must assume that they will execute in the least privileged user mode (i.e. level 3). Other privilege levels are reserved for the Operating System.


Chapter 5. Process Initialization

LSB-conforming applications shall use the Process Startup as defined in Section 3.3.5 of the Intel® Itanium ™ Processor-specific Application Binary Interface.


Special Registers

Intel® Itanium ™ Processor-specific Application Binary Interface, section 3.3.5, defines required register initializations for process startup.


Process Stack (on entry)

As defined in Intel® Itanium ™ Processor-specific Application Binary Interface, section 3.3.5, the return pointer register (rp) shall contain a valid return address, such that if the application program returns from the main entry routine, the implementation shall cause the application to exit normally, using the returned value as the exit status. Further, the unwind information for this "bottom of stack" routine in the implementation shall provide a mechanism for recognizing the bottom of the stack during a stack unwind.


Auxiliary Vector

The auxiliary vector conveys information from the operating system to the application. Only the terminating null auxiliary vector entry is required, but if any other entries are present, they shall be interpreted as follows. This vector is an array of the following structures.

typedef struct
{
  long int a_type;              /* Entry type */
  union
    {
      long int a_val;           /* Integer value */
      void *a_ptr;              /* Pointer value */
      void (*a_fcn) (void);     /* Function pointer value */
    } a_un;
} auxv_t;

The application shall interpret the a_un value according to the a_type. Other auxiliary vector types are reserved.

The a_type field shall contain one of the following values:

AT_NULL

The last entry in the array has type AT_NULL. The value in a_un is undefined.

AT_IGNORE

The value in a_un is undefined, and should be ignored.

AT_EXECFD

File descriptor of program

AT_PHDR

Program headers for program

AT_PHENT

Size of program header entry

AT_PHNUM

Number of program headers

AT_PAGESZ

System page size

AT_BASE

Base address of interpreter

AT_FLAGS

Flags

AT_ENTRY

Entry point of program

AT_NOTELF

Program is not ELF

AT_UID

Real uid

AT_EUID

Effective uid

AT_GID

Real gid

AT_EGID

Effective gid

AT_CLKTCK

Frequency of times()

AT_PLATFORM

String identifying platform.

AT_HWCAP

Machine dependent hints about processor capabilities.

AT_FPUCW

Used FPU control word

AT_DCACHEBSIZE

Data cache block size

AT_ICACHEBSIZE

Instruction cache block size

AT_UCACHEBSIZE

Unified cache block size

Note

The auxiliary vector is intended for passing information from the operating system to a program interpreter, such as /lib/ld-lsb-ia64.so.1.


Environment

Although a pointer to the environment vector should be available as a third argument to the main entry point, conforming applications should use getenv to access the environment. (See The Single UNIX® Specification(SUS) Version 1 (UNIX 95) System Interfaces & Headers, Section exec).


Chapter 6. Coding Examples

LSB-conforming applications may implement fundamental operations using the Coding Examples as shown below.

Sample code sequences and coding conventions can be found in Itanium ™ Software Conventions & Runtime Architecture Guide, Chapter 9.


Code Model Overview/Architecture Constraints

As defined in Intel® Itanium ™ Processor-specific Application Binary Interface, relocatable files, executable files, and shared object files that are supplied as part of an application must use Position Independent Code, as described in Itanium ™ Software Conventions & Runtime Architecture Guide, Chapter 12.


Position-Independent Function Prologue

See Itanium ™ Software Conventions & Runtime Architecture Guide, Chapter 8.4.


Data Objects

See Intel® Itanium ™ Processor-specific Application Binary Interface, Chapter 5.3.4, and Itanium ™ Software Conventions & Runtime Architecture Guide, Chapter 12.3.


Absolute Load & Store

Conforming applications shall not use absolute addressing.


Position Relative Load & Store

See Intel® Itanium ™ Processor-specific Application Binary Interface, Chapter 5.3.4.


Function Calls

See Itanium ™ Software Conventions & Runtime Architecture Guide, Chapter 8.4.

Four types of procedure call are defined in Itanium ™ Software Conventions & Runtime Architecture Guide, Chapter 8.3. Although special calling conventions are permitted, provided that the compiler and runtime library agree on these conventions, none are defined for this standard. Consequently, no application shall depend on a type of procedure call other than Direct Calls, Direct Dynamically Linked Calls, or Indirect Calls, as defined in Itanium ™ Software Conventions & Runtime Architecture Guide, Chapter 8.3.


Absolute Direct Function Call

Conforming applications shall not use absolute addressing.


Absolute Indirect Function Call

Conforming applications shall not use absolute addressing.


Position-Independent Direct Function Call

See Itanium ™ Software Conventions & Runtime Architecture Guide, Chapter 8.4.1.


Position-Independent Indirect Function Call

See Itanium ™ Software Conventions & Runtime Architecture Guide, Chapter 8.4.2.


Branching

Branching is described in IA-64 Processor Reference: Intel® Itanium ™ Processor Reference Manual for Software Development, Chapter 4.5.


Absolute switch() code

Conforming applications shall not use absolute addressing.


Position-Independent switch() code

Where there are several possible targets for a branch, the compiler may use a number of different code generation strategies. See Itanium ™ Software Conventions & Runtime Architecture Guide, Chapter 9.1.7.


Chapter 7. C Stack Frame

Variable Argument List

See Itanium ™ Software Conventions & Runtime Architecture Guide, Chapter 8.5.2, and 8.5.4.


Dynamic Allocation of Stack Space

The C library alloca function should be used to dynamically allocate stack space.


Chapter 8. Debug Information

The LSB does not currently specify the format of Debug information.

III. Object Format

LSB-conforming implementations shall support an object file , called Executable and Linking Format (ELF) as defined by the System V Application Binary Interface, Edition 4.1, Intel® Itanium ™ Processor-specific Application Binary Interface and as supplemented by the Linux Standard Base Specification and this document.

Table of Contents
9. ELF Header
10. Sections
11. Symbol Table
12. Relocation

Chapter 9. ELF Header

Machine Information

LSB-conforming applications shall use the Machine Information as defined in Intel® Itanium ™ Processor-specific Application Binary Interface, Chapter 4. Implementations shall support the LP64 model. It is unspecified whether or not the ILP32 model shall also be supported.


File Class

For LP64 relocatable objects, the file class value in e_ident[EI_CLASS] may be either ELFCLASS32 or ELFCLASS64, and a conforming linker must be able to process either or both classes.


Data Encoding

Implementations shall support 2's complement, little endian data encoding. The data encoding value in e_ident[EI_DATA] shall contain the value ELFDATA2LSB.


OS Identification

The OS Identification field e_ident[EI_OSABI] shall contain the value ELFOSABI_LINUX.


Processor Identification

The processor identification value held in e_machine shall contain the value EM_IA_64.


Processor Specific Flags

The flags field e_flags shall be as described in Intel® Itanium ™ Processor-specific Application Binary Interface, Chapter 4.1.1.6.

The following additional processor-specific flags are defined:

Table 9-1. Additional Processor-Specific Flags

NameValue
EF_IA_64_LINUX_EXECUTABLE_STACK0x00000001

EF_IA_64_LINUX_EXECUTABLE_STACK

The stack and heap sections are executable. If this flag is not set, code can not be executed from the stack or heap.


Chapter 10. Sections

The Itanium™ architecture defines two processor-specific section types, as described in Intel® Itanium ™ Processor-specific Application Binary Interface, Chapter 4.


Special Sections

The following sections are defined in the Intel® Itanium ™ Processor-specific Application Binary Interface.

Table 10-1. ELF Special Sections

NameTypeAttributes
.gotSHT_PROGBITSSHF_ALLOC+SHF_WRITE+SHF_IA_64_SHORT
.IA_64.archextSHT_IA_64_EXT0
.IA_64.pltoffSHT_PROGBITSSHF_ALLOC+SHF_WRITE+SHF_IA_64_SHORT
.IA_64.unwindSHT_IA_64_UNWINDSHF_ALLOC+SHF_LINK_ORDER
.IA_64.unwind_infoSHT_PROGBITSSHF_ALLOC
.pltSHT_PROGBITSSHF_ALLOC+SHF_EXECINSTR
.sbssSHT_NOBITSSHF_ALLOC+SHF_WRITE+SHF_IA_64_SHORT
.sdataSHT_PROGBITSSHF_ALLOC+SHF_WRITE+SHF_IA_64_SHORT
.sdata1SHT_PROGBITSSHF_ALLOC+SHF_WRITE+SHF_IA_64_SHORT

.got

This section holds the Global Offset Table. See `Coding Examples' in Chapter 3, `Special Sections' in Chapter 4, and `Global Offset Table' in Chapter 5 of the processor supplement for more information.

.IA_64.archext

This section holds product-specific extension bits. The link editor will perform a logical "or" of the extension bits of each object when creating an executable so that it creates only a single .IA_64.archext section in the executable.

.IA_64.pltoff

This section holds local function descriptor entries.

.IA_64.unwind

This section holds the unwind function table. The contents are described in the Intel (r) Itanium (tm) Processor Specific ABI.

.IA_64.unwind_info

This section holds stack unwind and and exception handling information. The exception handling information is programming language specific, and is unspecified.

.plt

This section holds the Procedure Linkage Table.

.sbss

This section holds uninitialized data that contribute to the program''s memory image. Data objects contained in this section are recommended to be eight bytes or less in size. The system initializes the data with zeroes when the program begins to run. The section occupies no file space, as indicated by the section type SHT_NOBITS. The .sbss section is placed so it may be accessed using short direct addressing (22 bit offset from gp).

.sdata

This section and the .sdata1 section hold initialized data that contribute to the program''s memory image. Data objects contained in this section are recommended to be eight bytes or less in size. The .sdata and .sdata1 sections are placed so they may be accessed using short direct addressing (22 bit offset from gp).

.sdata1

See .sdata.


Linux Special Sections

The following Linux IA-64 specific sections are defined here.

Table 10-2. Additional Special Sections

NameTypeAttributes
.rela.dynSHT_RELASHF_ALLOC
.rela.IA_64.pltoffSHT_RELASHF_ALLOC

.rela.dyn

This section holds relocation information, as described in `Relocation'. These relocations are applied to the .dyn section.

.rela.IA_64.pltoff

This section holds relocation information, as described in `Relocation'. These relocations are applied to the .IA_64.pltoff section.


Section Types

Section Types are described in the Intel® Itanium ™ Processor-specific Application Binary Interface, Chapter 4.2. LSB conforming implementations are not required to use any sections in the range from SHT_IA_64_LOPSREG to SHT_IA_64_HIPSREG. Additionally, LSB conforming implementations are not required to support the SHT_IA_64_PRIORITY_INIT section, beyond the gABI requirements for the handling of unrecognized section types, linking them into a contiguous section in the object file created by the static linker.


Chapter 11. Symbol Table

If an executable file contains a reference to a function defined in one of its associated shared objects, the symbol table section for that file shall contain an entry for that symbol. The st_shndx member of that symbol table entry contains SHN_UNDEF. This signals to the dynamic linker that the symbol definition for that function is not contained in the executable file itself. If that symbol has been allocated a procedure linkage table entry in the executable file, and the st_value member for that symbol table entry is non-zero, the value shall contain the virtual address of the first instruction of that procedure linkage table entry. Otherwise, the st_value member contains zero. This procedure linkage table entry address is used by the dynamic linker in resolving references to the address of the function.

Note

Need to add something here about st_info and st_other ...


Chapter 12. Relocation

LSB-conforming applications shall use Relocations as defined in Intel® Itanium ™ Processor-specific Application Binary Interface, Chapter 4.3.

IV. Program Loading and Dynamic Linking

LSB-conforming implementations shall support the object file information and system actions that create running programs as specified in the System V Application Binary Interface, Edition 4.1, Intel® Itanium ™ Processor-specific Application Binary Interface and as supplemented by the Linux Standard Base Specification and this document.


Chapter 14. Program Loading

See Intel® Itanium ™ Processor-specific Application Binary Interface, Chapter 5.2.


Chapter 15. Dynamic Linking

See Intel® Itanium ™ Processor-specific Application Binary Interface, Chapter 5.3.


Program Interpreter/Dynamic Linker

The LSB specifies the Program Interpreter to be /lib/ld-lsb-ia64.so.1.


Dynamic Section

The following dynamic entries are defined in the Intel® Itanium ™ Processor-specific Application Binary Interface, Chapter 5.3.2.

DT_PLTGOT

This entry's d_ptr member gives the address of the first byte in the procedure linkage table


Shared Object Dependencies

See Intel® Itanium ™ Processor-specific Application Binary Interface, Chapter 5.3.3.


Initialization and Termination Functions

See Intel® Itanium ™ Processor-specific Application Binary Interface, Chapter 5.3.7.

V. Base Libraries

Table of Contents
16. Libraries

Chapter 16. Libraries

An LSB-conforming implementation shall support base libraries which provide interfaces for accessing the operating system, processor and other hardware in the system.

Only those interfaces that are unique to the Itanium™ platform are defined here. This section should be used in conjunction with the corresponding section in the Linux Standard Base Specification.

An LSB conforming implementation need not define an Unwind library interface as required by the Intel® Itanium ™ Processor-specific Application Binary Interface. If such an interface is provided, it shall conform to the specification in the Intel® Itanium ™ Processor-specific Application Binary Interface. A conforming application shall not depend on this interface.


Interfaces for libc

Table 16-1. libc Definition

Library:libc
SONAME:libc.so.6.1

The behavior of the interfaces in this library is specified by the following standards.

ISO/IEC 9899: 1999, Programming Languages --C[1]
Large File Support[2]
Linux Standard Base[3]
IEEE Std POSIX.1-1996 [ISO/IEC 9945-1:1996][4]
CAE Specification, February 1997, Networking Services (XNS), Issue 5(ISBN: 1-85912-165-9, C523)[5]
CAE Specification, January 1997, System Interfaces and Headers (XSH),Issue 5 (ISBN: 1-85912-181-0, C606)[6]
The Single UNIX® Specification(SUS) Version 3[7]
System V Interface Definition, Issue 3 (ISBN 0201566524)[8]
System V Interface Definition,Fourth Edition[9]


RPC

Table 16-2. libc - RPC Function Interfaces

authnone_create(GLIBC_2.2)[9]svc_getreqset(GLIBC_2.2)[8]xdr_bytes(GLIBC_2.2)[8]xdr_opaque_auth(GLIBC_2.2)[8]xdr_union(GLIBC_2.2)[8]
clnt_create(GLIBC_2.2)[9]svcerr_auth(GLIBC_2.2)[8]xdr_callhdr(GLIBC_2.2)[8]xdr_pointer(GLIBC_2.2)[8]xdr_vector(GLIBC_2.2)[8]
clnt_pcreateerror(GLIBC_2.2)[9]svcerr_decode(GLIBC_2.2)[8]xdr_callmsg(GLIBC_2.2)[8]xdr_reference(GLIBC_2.2)[8]xdr_void(GLIBC_2.2)[8]
clnt_perrno(GLIBC_2.2)[9]svcerr_noproc(GLIBC_2.2)[8]xdr_char(GLIBC_2.2)[8]xdr_rejected_reply(GLIBC_2.2)[8]xdr_wrapstring(GLIBC_2.2)[8]
clnt_perror(GLIBC_2.2)[9]svcerr_noprog(GLIBC_2.2)[8]xdr_double(GLIBC_2.2)[8]xdr_replymsg(GLIBC_2.2)[8]xdrmem_create(GLIBC_2.2)[8]
clnt_spcreateerror(GLIBC_2.2)[9]svcerr_progvers(GLIBC_2.2)[8]xdr_enum(GLIBC_2.2)[8]xdr_short(GLIBC_2.2)[8]xdrrec_create(GLIBC_2.2)[8]
clnt_sperrno(GLIBC_2.2)[9]svcerr_systemerr(GLIBC_2.2)[8]xdr_float(GLIBC_2.2)[8]xdr_string(GLIBC_2.2)[8]xdrrec_eof(GLIBC_2.2)[8]
clnt_sperror(GLIBC_2.2)[9]svcerr_weakauth(GLIBC_2.2)[8]xdr_free(GLIBC_2.2)[8]xdr_u_char(GLIBC_2.2)[8] 
getdomainname(GLIBC_2.2)[3]xdr_accepted_reply(GLIBC_2.2)[8]xdr_int(GLIBC_2.2)[8]xdr_u_int(GLIBC_2.2)[3] 
key_decryptsession(GLIBC_2.2)[8]xdr_array(GLIBC_2.2)[8]xdr_long(GLIBC_2.2)[8]xdr_u_long(GLIBC_2.2)[8] 
setdomainname(GLIBC_2.2)[3]xdr_bool(GLIBC_2.2)[8]xdr_opaque(GLIBC_2.2)[8]xdr_u_short(GLIBC_2.2)[8] 

System Calls

Table 16-3. libc - System Calls Function Interfaces

__fxstat(GLIBC_2.2)[3]fchown(GLIBC_2.2)[6]initgroups(GLIBC_2.2)[3]read(GLIBC_2.2)[6]setrlimit64(GLIBC_2.2)[2]
__getpgid(GLIBC_2.2)[3]fcntl(GLIBC_2.2)[3]ioctl(GLIBC_2.2)[3]readdir(GLIBC_2.2)[6]setsid(GLIBC_2.2)[6]
__lxstat(GLIBC_2.2)[3]fdatasync(GLIBC_2.2)[6]kill(GLIBC_2.2)[3]readdir_r(GLIBC_2.2)[6]setuid(GLIBC_2.2)[6]
__xmknod(GLIBC_2.2)[3]flock(GLIBC_2.2)[3]killpg(GLIBC_2.2)[6]readlink(GLIBC_2.2)[6]sleep(GLIBC_2.2)[6]
__xstat(GLIBC_2.2)[3]fork(GLIBC_2.2)[6]lchown(GLIBC_2.2)[6]readv(GLIBC_2.2)[6]statfs(GLIBC_2.2)[3]
access(GLIBC_2.2)[6]fstatfs(GLIBC_2.2)[3]link(GLIBC_2.2)[6]rename(GLIBC_2.2)[6]statvfs(GLIBC_2.2)[6]
acct(GLIBC_2.2)[3]fstatvfs(GLIBC_2.2)[6]lockf(GLIBC_2.2)[6]rmdir(GLIBC_2.2)[6]stime(GLIBC_2.2)[3]
alarm(GLIBC_2.2)[6]fsync(GLIBC_2.2)[6]lseek(GLIBC_2.2)[6]sbrk(GLIBC_2.2)[6]symlink(GLIBC_2.2)[6]
brk(GLIBC_2.2)[6]ftime(GLIBC_2.2)[6]mkdir(GLIBC_2.2)[6]sched_get_priority_max(GLIBC_2.2)[6]sync(GLIBC_2.2)[6]
chdir(GLIBC_2.2)[6]ftruncate(GLIBC_2.2)[6]mkfifo(GLIBC_2.2)[6]sched_get_priority_min(GLIBC_2.2)[6]sysconf(GLIBC_2.2)[6]
chmod(GLIBC_2.2)[6]getcontext(GLIBC_2.2)[6]mlock(GLIBC_2.2)[6]sched_getparam(GLIBC_2.2)[6]time(GLIBC_2.2)[6]
chown(GLIBC_2.2)[6]getegid(GLIBC_2.2)[6]mlockall(GLIBC_2.2)[6]sched_getscheduler(GLIBC_2.2)[6]times(GLIBC_2.2)[6]
chroot(GLIBC_2.2)[6]geteuid(GLIBC_2.2)[6]mmap(GLIBC_2.2)[6]sched_rr_get_interval(GLIBC_2.2)[6]truncate(GLIBC_2.2)[6]
clock(GLIBC_2.2)[6]getgid(GLIBC_2.2)[6]mprotect(GLIBC_2.2)[6]sched_setparam(GLIBC_2.2)[6]ulimit(GLIBC_2.2)[6]
close(GLIBC_2.2)[6]getgroups(GLIBC_2.2)[6]msync(GLIBC_2.2)[6]sched_setscheduler(GLIBC_2.2)[6]umask(GLIBC_2.2)[6]
closedir(GLIBC_2.2)[6]getitimer(GLIBC_2.2)[6]munlock(GLIBC_2.2)[6]sched_yield(GLIBC_2.2)[6]uname(GLIBC_2.2)[6]
creat(GLIBC_2.2)[6]getloadavg(GLIBC_2.2)[3]munlockall(GLIBC_2.2)[6]select(GLIBC_2.2)[5]unlink(GLIBC_2.2)[3]
dup(GLIBC_2.2)[6]getpagesize(GLIBC_2.2)[6]munmap(GLIBC_2.2)[6]setcontext(GLIBC_2.2)[6]utime(GLIBC_2.2)[6]
dup2(GLIBC_2.2)[6]getpgid(GLIBC_2.2)[6]nanosleep(GLIBC_2.2)[6]setegid(GLIBC_2.2)[3]utimes(GLIBC_2.2)[6]
execl(GLIBC_2.2)[6]getpgrp(GLIBC_2.2)[6]nice(GLIBC_2.2)[3]seteuid(GLIBC_2.2)[3]vfork(GLIBC_2.2)[6]
execle(GLIBC_2.2)[6]getpid(GLIBC_2.2)[6]open(GLIBC_2.2)[6]setgid(GLIBC_2.2)[6]wait(GLIBC_2.2)[6]
execlp(GLIBC_2.2)[6]getppid(GLIBC_2.2)[6]opendir(GLIBC_2.2)[6]setitimer(GLIBC_2.2)[6]wait3(GLIBC_2.2)[3]
execv(GLIBC_2.2)[6]getpriority(GLIBC_2.2)[6]pathconf(GLIBC_2.2)[6]setpgid(GLIBC_2.2)[6]wait4(GLIBC_2.2)[3]
execve(GLIBC_2.2)[6]getrlimit(GLIBC_2.2)[6]pause(GLIBC_2.2)[6]setpgrp(GLIBC_2.2)[6]waitid(GLIBC_2.2)[3]
execvp(GLIBC_2.2)[6]getrusage(GLIBC_2.2)[6]pipe(GLIBC_2.2)[6]setpriority(GLIBC_2.2)[6]waitpid(GLIBC_2.2)[3]
exit(GLIBC_2.2)[6]getsid(GLIBC_2.2)[6]poll(GLIBC_2.2)[6]setregid(GLIBC_2.2)[6]write(GLIBC_2.2)[6]
fchdir(GLIBC_2.2)[6]getuid(GLIBC_2.2)[6]pread(GLIBC_2.2)[6]setreuid(GLIBC_2.2)[6]writev(GLIBC_2.2)[6]
fchmod(GLIBC_2.2)[6]getwd(GLIBC_2.2)[6]pwrite(GLIBC_2.2)[6]setrlimit(GLIBC_2.2)[6] 

Table 16-4. libc - System Calls Deprecated Function Interfaces

fstatfs(GLIBC_2.2)[3]statfs(GLIBC_2.2)[3]waitid(GLIBC_2.2)[3]  

Standard I/O

Table 16-5. libc - Standard I/O Function Interfaces

_IO_feof(GLIBC_2.2)[3]fgetc(GLIBC_2.2)[6]fseeko(GLIBC_2.2)[6]putc(GLIBC_2.2)[6]snprintf(GLIBC_2.2)[6]
_IO_getc(GLIBC_2.2)[3]fgetpos(GLIBC_2.2)[6]fsetpos(GLIBC_2.2)[6]putc_unlocked(GLIBC_2.2)[6]sprintf(GLIBC_2.2)[6]
_IO_putc(GLIBC_2.2)[3]fgets(GLIBC_2.2)[6]ftell(GLIBC_2.2)[6]putchar(GLIBC_2.2)[6]sscanf(GLIBC_2.2)[6]
_IO_puts(GLIBC_2.2)[3]fgetwc_unlocked(GLIBC_2.2)[6]ftello(GLIBC_2.2)[6]putchar_unlocked(GLIBC_2.2)[6]telldir(GLIBC_2.2)[6]
alphasort(GLIBC_2.2)[3]fileno(GLIBC_2.2)[6]fwrite(GLIBC_2.2)[6]puts(GLIBC_2.2)[6]tempnam(GLIBC_2.2)[6]
asprintf(GLIBC_2.2)[3]flockfile(GLIBC_2.2)[6]getc(GLIBC_2.2)[6]putw(GLIBC_2.2)[6]ungetc(GLIBC_2.2)[6]
clearerr(GLIBC_2.2)[6]fopen(GLIBC_2.2)[6]getc_unlocked(GLIBC_2.2)[6]remove(GLIBC_2.2)[6]vasprintf(GLIBC_2.2)[3]
ctermid(GLIBC_2.2)[6]fprintf(GLIBC_2.2)[6]getchar(GLIBC_2.2)[6]rewind(GLIBC_2.2)[6]vdprintf(GLIBC_2.2)[3]
fclose(GLIBC_2.2)[6]fputc(GLIBC_2.2)[6]getchar_unlocked(GLIBC_2.2)[6]rewinddir(GLIBC_2.2)[6]vfprintf(GLIBC_2.2)[6]
fdopen(GLIBC_2.2)[6]fputs(GLIBC_2.2)[6]gets(GLIBC_2.2)[3]scanf(GLIBC_2.2)[6]vprintf(GLIBC_2.2)[6]
feof(GLIBC_2.2)[6]fread(GLIBC_2.2)[6]getw(GLIBC_2.2)[6]seekdir(GLIBC_2.2)[6]vsnprintf(GLIBC_2.2)[6]
ferror(GLIBC_2.2)[6]freopen(GLIBC_2.2)[6]pclose(GLIBC_2.2)[6]setbuf(GLIBC_2.2)[6]vsprintf(GLIBC_2.2)[6]
fflush(GLIBC_2.2)[6]fscanf(GLIBC_2.2)[6]popen(GLIBC_2.2)[6]setbuffer(GLIBC_2.2)[3] 
fflush_unlocked(GLIBC_2.2)[6]fseek(GLIBC_2.2)[6]printf(GLIBC_2.2)[6]setvbuf(GLIBC_2.2)[6] 

Table 16-6. libc - Standard I/O Deprecated Function Interfaces

alphasort(GLIBC_2.2)[3]    

Table 16-7. libc - Standard I/O Data Interfaces

stderr(GLIBC_2.2)[6]stdin(GLIBC_2.2)[6]stdout(GLIBC_2.2)[6]  

Signal Handling

Table 16-8. libc - Signal Handling Function Interfaces

__libc_current_sigrtmax(GLIBC_2.2)[3]sigaddset(GLIBC_2.2)[6]sighold(GLIBC_2.2)[6]sigpause(GLIBC_2.2)[6]sigsuspend(GLIBC_2.2)[6]
__libc_current_sigrtmin(GLIBC_2.2)[3]sigaltstack(GLIBC_2.2)[6]sigignore(GLIBC_2.2)[6]sigpending(GLIBC_2.2)[6]sigtimedwait(GLIBC_2.2)[6]
__sigsetjmp(GLIBC_2.2)[3]sigandset(GLIBC_2.2)[3]siginterrupt(GLIBC_2.2)[6]sigprocmask(GLIBC_2.2)[6]sigwait(GLIBC_2.2)[6]
__sysv_signal(GLIBC_2.2)[3]sigblock(GLIBC_2.2)[3]sigisemptyset(GLIBC_2.2)[3]sigqueue(GLIBC_2.2)[6]sigwaitinfo(GLIBC_2.2)[6]
bsd_signal(GLIBC_2.2)[6]sigdelset(GLIBC_2.2)[6]sigismember(GLIBC_2.2)[6]sigrelse(GLIBC_2.2)[6] 
psignal(GLIBC_2.2)[3]sigemptyset(GLIBC_2.2)[6]siglongjmp(GLIBC_2.2)[6]sigreturn(GLIBC_2.2)[3] 
raise(GLIBC_2.2)[6]sigfillset(GLIBC_2.2)[6]signal(GLIBC_2.2)[6]sigset(GLIBC_2.2)[6] 
sigaction(GLIBC_2.2)[6]siggetmask(GLIBC_2.2)[3]sigorset(GLIBC_2.2)[3]sigstack(GLIBC_2.2)[6] 

Table 16-9. libc - Signal Handling Data Interfaces

_sys_siglist(GLIBC_2.2)[3]    

Localization Functions

Table 16-10. libc - Localization Functions Function Interfaces

__dcgettext(GLIBC_2.2)[3]catgets(GLIBC_2.2)[6]dgettext(GLIBC_2.2)[3]iconv_close(GLIBC_2.2)[6]nl_langinfo(GLIBC_2.2)[6]
bind_textdomain_codeset(GLIBC_2.2)[3]catopen(GLIBC_2.2)[6]dngettext(GLIBC_2.2)[3]iconv_open(GLIBC_2.2)[6]setlocale(GLIBC_2.2)[6]
bindtextdomain(GLIBC_2.2)[3]dcgettext(GLIBC_2.2)[3]gettext(GLIBC_2.2)[3]localeconv(GLIBC_2.2)[6]textdomain(GLIBC_2.2)[3]
catclose(GLIBC_2.2)[6]dcngettext(GLIBC_2.2)[3]iconv(GLIBC_2.2)[6]ngettext(GLIBC_2.2)[3] 

Table 16-11. libc - Localization Functions Deprecated Function Interfaces

__dcgettext(GLIBC_2.2)[3]    

Table 16-12. libc - Localization Functions Data Interfaces

_nl_msg_cat_cntr(GLIBC_2.2)[3]    

Socket Interface

Table 16-13. libc - Socket Interface Function Interfaces

__h_errno_location(GLIBC_2.2)[3]gethostbyname_r(GLIBC_2.2)[3]getsockopt(GLIBC_2.2)[5]send(GLIBC_2.2)[5]socket(GLIBC_2.2)[5]
accept(GLIBC_2.2)[5]gethostid(GLIBC_2.2)[6]listen(GLIBC_2.2)[5]sendmsg(GLIBC_2.2)[5]socketpair(GLIBC_2.2)[5]
bind(GLIBC_2.2)[5]gethostname(GLIBC_2.2)[5]recv(GLIBC_2.2)[5]sendto(GLIBC_2.2)[5] 
bindresvport(GLIBC_2.2)[3]getpeername(GLIBC_2.2)[5]recvfrom(GLIBC_2.2)[5]setsockopt(GLIBC_2.2)[5] 
connect(GLIBC_2.2)[5]getsockname(GLIBC_2.2)[5]recvmsg(GLIBC_2.2)[5]shutdown(GLIBC_2.2)[5] 

Wide Characters

Table 16-14. libc - Wide Characters Function Interfaces

__wcstod_internal(GLIBC_2.2)[3]mbsinit(GLIBC_2.2)[6]vwscanf(GLIBC_2.2)[1]wcsnlen(GLIBC_2.2)[3]wcstoumax(GLIBC_2.2)[1]
__wcstof_internal(GLIBC_2.2)[3]mbsnrtowcs(GLIBC_2.2)[3]wcpcpy(GLIBC_2.2)[3]wcsnrtombs(GLIBC_2.2)[3]wcstouq(GLIBC_2.2)[3]
__wcstol_internal(GLIBC_2.2)[3]mbsrtowcs(GLIBC_2.2)[6]wcpncpy(GLIBC_2.2)[3]wcspbrk(GLIBC_2.2)[1]wcswcs(GLIBC_2.2)[6]
__wcstold_internal(GLIBC_2.2)[3]mbstowcs(GLIBC_2.2)[6]wcrtomb(GLIBC_2.2)[6]wcsrchr(GLIBC_2.2)[6]wcswidth(GLIBC_2.2)[6]
__wcstoul_internal(GLIBC_2.2)[3]mbtowc(GLIBC_2.2)[6]wcscasecmp(GLIBC_2.2)[3]wcsrtombs(GLIBC_2.2)[6]wcsxfrm(GLIBC_2.2)[6]
btowc(GLIBC_2.2)[6]putwc(GLIBC_2.2)[1]wcscat(GLIBC_2.2)[6]wcsspn(GLIBC_2.2)[6]wctob(GLIBC_2.2)[6]
fgetwc(GLIBC_2.2)[6]putwchar(GLIBC_2.2)[1]wcschr(GLIBC_2.2)[6]wcsstr(GLIBC_2.2)[6]wctomb(GLIBC_2.2)[6]
fgetws(GLIBC_2.2)[1]swprintf(GLIBC_2.2)[6]wcscmp(GLIBC_2.2)[6]wcstod(GLIBC_2.2)[6]wctrans(GLIBC_2.2)[6]
fputwc(GLIBC_2.2)[1]swscanf(GLIBC_2.2)[1]wcscoll(GLIBC_2.2)[6]wcstof(GLIBC_2.2)[1]wctype(GLIBC_2.2)[6]
fputws(GLIBC_2.2)[1]towctrans(GLIBC_2.2)[6]wcscpy(GLIBC_2.2)[6]wcstoimax(GLIBC_2.2)[1]wcwidth(GLIBC_2.2)[6]
fwide(GLIBC_2.2)[1]towlower(GLIBC_2.2)[1]wcscspn(GLIBC_2.2)[6]wcstok(GLIBC_2.2)[6]wmemchr(GLIBC_2.2)[6]
fwprintf(GLIBC_2.2)[6]towupper(GLIBC_2.2)[6]wcsdup(GLIBC_2.2)[3]wcstol(GLIBC_2.2)[6]wmemcmp(GLIBC_2.2)[6]
fwscanf(GLIBC_2.2)[1]ungetwc(GLIBC_2.2)[1]wcsftime(GLIBC_2.2)[1]wcstold(GLIBC_2.2)[1]wmemcpy(GLIBC_2.2)[6]
getwc(GLIBC_2.2)[1]vfwprintf(GLIBC_2.2)[1]wcslen(GLIBC_2.2)[6]wcstoll(GLIBC_2.2)[1]wmemmove(GLIBC_2.2)[6]
getwchar(GLIBC_2.2)[6]vfwscanf(GLIBC_2.2)[1]wcsncasecmp(GLIBC_2.2)[3]wcstombs(GLIBC_2.2)[6]wmemset(GLIBC_2.2)[6]
mblen(GLIBC_2.2)[6]vswprintf(GLIBC_2.2)[1]wcsncat(GLIBC_2.2)[6]wcstoq(GLIBC_2.2)[3]wprintf(GLIBC_2.2)[1]
mbrlen(GLIBC_2.2)[6]vswscanf(GLIBC_2.2)[1]wcsncmp(GLIBC_2.2)[6]wcstoul(GLIBC_2.2)[6]wscanf(GLIBC_2.2)[1]
mbrtowc(GLIBC_2.2)[6]vwprintf(GLIBC_2.2)[1]wcsncpy(GLIBC_2.2)[6]wcstoull(GLIBC_2.2)[1] 

String Functions

Table 16-15. libc - String Functions Function Interfaces

__mempcpy(GLIBC_2.2)[3]bzero(GLIBC_2.2)[6]strcasestr(GLIBC_2.2)[3]strncasecmp(GLIBC_2.2)[6]strtoimax(GLIBC_2.2)[1]
__rawmemchr(GLIBC_2.2)[3]ffs(GLIBC_2.2)[6]strcat(GLIBC_2.2)[6]strncat(GLIBC_2.2)[6]strtok(GLIBC_2.2)[6]
__stpcpy(GLIBC_2.2)[3]index(GLIBC_2.2)[6]strchr(GLIBC_2.2)[6]strncmp(GLIBC_2.2)[6]strtok_r(GLIBC_2.2)[3]
__strdup(GLIBC_2.2)[3]memccpy(GLIBC_2.2)[6]strcmp(GLIBC_2.2)[6]strncpy(GLIBC_2.2)[6]strtold(GLIBC_2.2)[1]
__strtod_internal(GLIBC_2.2)[3]memchr(GLIBC_2.2)[6]strcoll(GLIBC_2.2)[6]strndup(GLIBC_2.2)[3]strtoll(GLIBC_2.2)[1]
__strtof_internal(GLIBC_2.2)[3]memcmp(GLIBC_2.2)[6]strcpy(GLIBC_2.2)[6]strnlen(GLIBC_2.2)[3]strtoq(GLIBC_2.2)[3]
__strtok_r(GLIBC_2.2)[3]memcpy(GLIBC_2.2)[6]strcspn(GLIBC_2.2)[6]strpbrk(GLIBC_2.2)[6]strtoull(GLIBC_2.2)[1]
__strtol_internal(GLIBC_2.2)[3]memmove(GLIBC_2.2)[6]strdup(GLIBC_2.2)[6]strptime(GLIBC_2.2)[3]strtoumax(GLIBC_2.2)[1]
__strtold_internal(GLIBC_2.2)[3]memrchr(GLIBC_2.2)[3]strerror(GLIBC_2.2)[6]strrchr(GLIBC_2.2)[6]strtouq(GLIBC_2.2)[3]
__strtoll_internal(GLIBC_2.2)[3]memset(GLIBC_2.2)[6]strerror_r(GLIBC_2.2)[3]strsep(GLIBC_2.2)[3]strverscmp(GLIBC_2.2)[3]
__strtoul_internal(GLIBC_2.2)[3]rindex(GLIBC_2.2)[6]strfmon(GLIBC_2.2)[6]strsignal(GLIBC_2.2)[3]strxfrm(GLIBC_2.2)[6]
__strtoull_internal(GLIBC_2.2)[3]stpcpy(GLIBC_2.2)[3]strfry(GLIBC_2.2)[3]strspn(GLIBC_2.2)[6]swab(GLIBC_2.2)[6]
bcmp(GLIBC_2.2)[6]stpncpy(GLIBC_2.2)[3]strftime(GLIBC_2.2)[6]strstr(GLIBC_2.2)[6] 
bcopy(GLIBC_2.2)[6]strcasecmp(GLIBC_2.2)[6]strlen(GLIBC_2.2)[6]strtof(GLIBC_2.2)[1] 

IPC Functions

Table 16-16. libc - IPC Functions Function Interfaces

ftok(GLIBC_2.2)[6]msgrcv(GLIBC_2.2)[6]semget(GLIBC_2.2)[6]shmctl(GLIBC_2.2)[6] 
msgctl(GLIBC_2.2)[6]msgsnd(GLIBC_2.2)[6]semop(GLIBC_2.2)[6]shmdt(GLIBC_2.2)[6] 
msgget(GLIBC_2.2)[6]semctl(GLIBC_2.2)[6]shmat(GLIBC_2.2)[6]shmget(GLIBC_2.2)[6] 

Regular Expressions

Table 16-17. libc - Regular Expressions Function Interfaces

advance(GLIBC_2.2)[6]re_exec(GLIBC_2.2)[6]regerror(GLIBC_2.2)[6]regfree(GLIBC_2.2)[6] 
re_comp(GLIBC_2.2)[6]regcomp(GLIBC_2.2)[6]regexec(GLIBC_2.2)[6]step(GLIBC_2.2)[6] 

Table 16-18. libc - Regular Expressions Data Interfaces

loc1(GLIBC_2.2)[6]loc2(GLIBC_2.2)[6]locs(GLIBC_2.2)[6]  

Character Type Functions

Table 16-19. libc - Character Type Functions Function Interfaces

__ctype_get_mb_cur_max(GLIBC_2.2)[3]isdigit(GLIBC_2.2)[6]iswalnum(GLIBC_2.2)[6]iswlower(GLIBC_2.2)[6]toascii(GLIBC_2.2)[6]
_tolower(GLIBC_2.2)[6]isgraph(GLIBC_2.2)[6]iswalpha(GLIBC_2.2)[6]iswprint(GLIBC_2.2)[6]tolower(GLIBC_2.2)[6]
_toupper(GLIBC_2.2)[6]islower(GLIBC_2.2)[6]iswblank(GLIBC_2.2)[7]iswpunct(GLIBC_2.2)[6]toupper(GLIBC_2.2)[6]
isalnum(GLIBC_2.2)[6]isprint(GLIBC_2.2)[6]iswcntrl(GLIBC_2.2)[6]iswspace(GLIBC_2.2)[6] 
isalpha(GLIBC_2.2)[6]ispunct(GLIBC_2.2)[6]iswctype(GLIBC_2.2)[3]iswupper(GLIBC_2.2)[6] 
isascii(GLIBC_2.2)[6]isspace(GLIBC_2.2)[6]iswdigit(GLIBC_2.2)[6]iswxdigit(GLIBC_2.2)[6] 
iscntrl(GLIBC_2.2)[6]isupper(GLIBC_2.2)[6]iswgraph(GLIBC_2.2)[6]isxdigit(GLIBC_2.2)[6] 

Table 16-20. libc - Character Type Functions Data Interfaces

__ctype_b(GLIBC_2.2)[3]__ctype_tolower(GLIBC_2.2)[3]__ctype_toupper(GLIBC_2.2)[3]  

Time Manipulation

Table 16-21. libc - Time Manipulation Function Interfaces

adjtime(GLIBC_2.2)[3]asctime_r(GLIBC_2.2)[6]difftime(GLIBC_2.2)[6]localtime(GLIBC_2.2)[6]tzset(GLIBC_2.2)[6]
adjtimex(GLIBC_2.2)[3]ctime(GLIBC_2.2)[6]gmtime(GLIBC_2.2)[6]localtime_r(GLIBC_2.2)[6]ualarm(GLIBC_2.2)[6]
asctime(GLIBC_2.2)[6]ctime_r(GLIBC_2.2)[6]gmtime_r(GLIBC_2.2)[6]mktime(GLIBC_2.2)[6] 

Table 16-22. libc - Time Manipulation Data Interfaces

__daylight(GLIBC_2.2)[3]__tzname(GLIBC_2.2)[3]timezone(GLIBC_2.2)[6]  
__timezone(GLIBC_2.2)[3]daylight(GLIBC_2.2)[6]tzname(GLIBC_2.2)[6]  

Terminal Interface Functions

Table 16-23. libc - Terminal Interface Functions Function Interfaces

cfgetispeed(GLIBC_2.2)[6]cfsetispeed(GLIBC_2.2)[6]tcdrain(GLIBC_2.2)[6]tcgetattr(GLIBC_2.2)[6]tcsendbreak(GLIBC_2.2)[6]
cfgetospeed(GLIBC_2.2)[6]cfsetospeed(GLIBC_2.2)[6]tcflow(GLIBC_2.2)[6]tcgetpgrp(GLIBC_2.2)[6]tcsetattr(GLIBC_2.2)[6]
cfmakeraw(GLIBC_2.2)[3]cfsetspeed(GLIBC_2.2)[3]tcflush(GLIBC_2.2)[6]tcgetsid(GLIBC_2.2)[6]tcsetpgrp(GLIBC_2.2)[6]

System Database Interface

Table 16-24. libc - System Database Interface Function Interfaces

endgrent(GLIBC_2.2)[6]getgrgid(GLIBC_2.2)[6]getpwent(GLIBC_2.2)[6]getutxent(GLIBC_2.2)[6]setprotoent(GLIBC_2.2)[5]
endhostent(GLIBC_2.2)[5]getgrgid_r(GLIBC_2.2)[6]getpwnam(GLIBC_2.2)[6]getutxid(GLIBC_2.2)[6]setpwent(GLIBC_2.2)[6]
endnetent(GLIBC_2.2)[5]getgrnam(GLIBC_2.2)[6]getpwuid(GLIBC_2.2)[6]getutxline(GLIBC_2.2)[6]setservent(GLIBC_2.2)[5]
endprotoent(GLIBC_2.2)[5]gethostbyaddr(GLIBC_2.2)[5]getpwuid_r(GLIBC_2.2)[6]pututxline(GLIBC_2.2)[6]setutent(GLIBC_2.2)[3]
endpwent(GLIBC_2.2)[6]gethostbyname(GLIBC_2.2)[3]getservbyname(GLIBC_2.2)[3]setgrent(GLIBC_2.2)[6]setutxent(GLIBC_2.2)[6]
endservent(GLIBC_2.2)[5]getnetbyaddr(GLIBC_2.2)[5]getservbyport(GLIBC_2.2)[5]setgroups(GLIBC_2.2)[3] 
endutent(GLIBC_2.2)[6]getprotobyname(GLIBC_2.2)[6]getservent(GLIBC_2.2)[3]sethostent(GLIBC_2.2)[5] 
endutxent(GLIBC_2.2)[6]getprotobynumber(GLIBC_2.2)[5]getutent(GLIBC_2.2)[3]setmntent(GLIBC_2.2)[3] 
getgrent(GLIBC_2.2)[6]getprotoent(GLIBC_2.2)[6]getutent_r(GLIBC_2.2)[3]setnetent(GLIBC_2.2)[5] 

Table 16-25. libc - System Database Interface Deprecated Function Interfaces

endhostent(GLIBC_2.2)[5]sethostent(GLIBC_2.2)[5]setmntent(GLIBC_2.2)[3]  

Language Support

Table 16-26. libc - Language Support Function Interfaces

__libc_start_main(GLIBC_2.2)[3]_obstack_begin(GLIBC_2.2)[3]_obstack_newchunk(GLIBC_2.2)[3]obstack_free(GLIBC_2.2)[3] 

Large File Support

Table 16-27. libc - Large File Support Function Interfaces

__fxstat64(GLIBC_2.2)[3]fopen64(GLIBC_2.2)[2]ftello64(GLIBC_2.2)[2]mkstemp64(GLIBC_2.2)[2]readdir64(GLIBC_2.2)[2]
__lxstat64(GLIBC_2.2)[3]freopen64(GLIBC_2.2)[2]ftruncate64(GLIBC_2.2)[2]mmap64(GLIBC_2.2)[2]statvfs64(GLIBC_2.2)[2]
__xstat64(GLIBC_2.2)[3]fseeko64(GLIBC_2.2)[2]ftw64(GLIBC_2.2)[2]nftw64(GLIBC_2.2)[2]tmpfile64(GLIBC_2.2)[2]
alphasort64(GLIBC_2.2)[3]fsetpos64(GLIBC_2.2)[2]getrlimit64(GLIBC_2.2)[2]open64(GLIBC_2.2)[2]truncate64(GLIBC_2.2)[2]
creat64(GLIBC_2.2)[2]fstatfs64(GLIBC_2.2)[3]lockf64(GLIBC_2.2)[2]pread64(GLIBC_2.2)[2] 
fgetpos64(GLIBC_2.2)[2]fstatvfs64(GLIBC_2.2)[2]lseek64(GLIBC_2.2)[2]pwrite64(GLIBC_2.2)[2] 

Table 16-28. libc - Large File Support Deprecated Function Interfaces

alphasort64(GLIBC_2.2)[3]fstatfs64(GLIBC_2.2)[3]   

Standard Library

Table 16-29. libc - Standard Library Function Interfaces

_Exit(GLIBC_2.2)[1]div(GLIBC_2.2)[6]globfree64(GLIBC_2.2)[3]longjmp(GLIBC_2.2)[6]srand(GLIBC_2.2)[6]
__assert_fail(GLIBC_2.2)[3]drand48(GLIBC_2.2)[6]grantpt(GLIBC_2.2)[6]lrand48(GLIBC_2.2)[6]srand48(GLIBC_2.2)[6]
__cxa_atexit(GLIBC_2.2)[3]ecvt(GLIBC_2.2)[6]hcreate(GLIBC_2.2)[6]lsearch(GLIBC_2.2)[6]srandom(GLIBC_2.2)[6]
__errno_location(GLIBC_2.2)[3]erand48(GLIBC_2.2)[6]hdestroy(GLIBC_2.2)[6]makecontext(GLIBC_2.2)[6]strtod(GLIBC_2.2)[6]
__fpending(GLIBC_2.2)[3]err(GLIBC_2.2)[3]hsearch(GLIBC_2.2)[6]malloc(GLIBC_2.2)[6]strtol(GLIBC_2.2)[6]
__getpagesize(GLIBC_2.2)[3]error(GLIBC_2.2)[3]htonl(GLIBC_2.2)[5]memmem(GLIBC_2.2)[3]strtoul(GLIBC_2.2)[6]
__isinf(GLIBC_2.2)[3]errx(GLIBC_2.2)[3]htons(GLIBC_2.2)[5]mkstemp(GLIBC_2.2)[6]swapcontext(GLIBC_2.2)[6]
__isinff(GLIBC_2.2)[3]fcvt(GLIBC_2.2)[6]imaxabs(GLIBC_2.2)[1]mktemp(GLIBC_2.2)[6]syslog(GLIBC_2.2)[6]
__isinfl(GLIBC_2.2)[3]fmtmsg(GLIBC_2.2)[6]imaxdiv(GLIBC_2.2)[1]mrand48(GLIBC_2.2)[6]system(GLIBC_2.2)[3]
__isnan(GLIBC_2.2)[3]fnmatch(GLIBC_2.2)[6]inet_addr(GLIBC_2.2)[5]nftw(GLIBC_2.2)[6]tdelete(GLIBC_2.2)[6]
__isnanf(GLIBC_2.2)[3]fpathconf(GLIBC_2.2)[6]inet_aton(GLIBC_2.2)[5]nrand48(GLIBC_2.2)[6]tfind(GLIBC_2.2)[6]
__isnanl(GLIBC_2.2)[3]free(GLIBC_2.2)[6]inet_ntoa(GLIBC_2.2)[5]ntohl(GLIBC_2.2)[5]tmpfile(GLIBC_2.2)[6]
__sysconf(GLIBC_2.2)[3]freeaddrinfo(GLIBC_2.2)[7]inet_ntop(GLIBC_2.2)[7]ntohs(GLIBC_2.2)[5]tmpnam(GLIBC_2.2)[6]
_exit(GLIBC_2.2)[6]ftrylockfile(GLIBC_2.2)[6]inet_pton(GLIBC_2.2)[7]openlog(GLIBC_2.2)[6]tsearch(GLIBC_2.2)[6]
_longjmp(GLIBC_2.2)[6]ftw(GLIBC_2.2)[6]initstate(GLIBC_2.2)[6]perror(GLIBC_2.2)[6]ttyname(GLIBC_2.2)[6]
_setjmp(GLIBC_2.2)[6]funlockfile(GLIBC_2.2)[6]insque(GLIBC_2.2)[6]posix_memalign(GLIBC_2.2)[4]ttyname_r(GLIBC_2.2)[6]
a64l(GLIBC_2.2)[6]gai_strerror(GLIBC_2.2)[7]isatty(GLIBC_2.2)[6]ptsname(GLIBC_2.2)[6]twalk(GLIBC_2.2)[6]
abort(GLIBC_2.2)[6]gcvt(GLIBC_2.2)[6]isblank(GLIBC_2.2)[7]putenv(GLIBC_2.2)[6]unlockpt(GLIBC_2.2)[6]
abs(GLIBC_2.2)[6]getaddrinfo(GLIBC_2.2)[7]isinf(GLIBC_2.2)[1]qsort(GLIBC_2.2)[6]unsetenv(GLIBC_2.2)[3]
atexit(GLIBC_2.2)[6]getcwd(GLIBC_2.2)[6]isinff(GLIBC_2.2)rand(GLIBC_2.2)[6]usleep(GLIBC_2.2)[6]
atof(GLIBC_2.2)[6]getdate(GLIBC_2.2)[6]isinfl(GLIBC_2.2)[1]rand_r(GLIBC_2.2)[6]verrx(GLIBC_2.2)[3]
atoi(GLIBC_2.2)[6]getenv(GLIBC_2.2)[6]isnan(GLIBC_2.2)[1]random(GLIBC_2.2)[6]vfscanf(GLIBC_2.2)[1]
atol(GLIBC_2.2)[6]getlogin(GLIBC_2.2)[6]isnanf(GLIBC_2.2)[1]random_r(GLIBC_2.2)[3]vscanf(GLIBC_2.2)[1]
atoll(GLIBC_2.2)[1]getnameinfo(GLIBC_2.2)[7]isnanl(GLIBC_2.2)[1]realloc(GLIBC_2.2)[6]vsscanf(GLIBC_2.2)[1]
basename(GLIBC_2.2)[6]getopt(GLIBC_2.2)[3]jrand48(GLIBC_2.2)[6]realpath(GLIBC_2.2)[6]vsyslog(GLIBC_2.2)[3]
bsearch(GLIBC_2.2)[6]getopt_long(GLIBC_2.2)[3]l64a(GLIBC_2.2)[6]remque(GLIBC_2.2)[6]warn(GLIBC_2.2)[3]
calloc(GLIBC_2.2)[6]getopt_long_only(GLIBC_2.2)[3]labs(GLIBC_2.2)[6]seed48(GLIBC_2.2)[6]warnx(GLIBC_2.2)[3]
closelog(GLIBC_2.2)[6]getsubopt(GLIBC_2.2)[6]lcong48(GLIBC_2.2)[6]setenv(GLIBC_2.2)[3]wordexp(GLIBC_2.2)[6]
confstr(GLIBC_2.2)[6]gettimeofday(GLIBC_2.2)[6]ldiv(GLIBC_2.2)[6]sethostid(GLIBC_2.2)[3]wordfree(GLIBC_2.2)[6]
cuserid(GLIBC_2.2)[6]glob(GLIBC_2.2)[6]lfind(GLIBC_2.2)[6]sethostname(GLIBC_2.2)[3] 
daemon(GLIBC_2.2)[3]glob64(GLIBC_2.2)[3]llabs(GLIBC_2.2)[1]setlogmask(GLIBC_2.2)[6] 
dirname(GLIBC_2.2)[6]globfree(GLIBC_2.2)[6]lldiv(GLIBC_2.2)[1]setstate(GLIBC_2.2)[6] 

Table 16-30. libc - Standard Library Data Interfaces

__environ(GLIBC_2.2)[3]_sys_errlist(GLIBC_2.2)[3]getdate_err(GLIBC_2.2)[6]opterr(GLIBC_2.2)[3]optopt(GLIBC_2.2)[3]
_environ(GLIBC_2.2)[3]environ(GLIBC_2.2)[6]optarg(GLIBC_2.2)[6]optind(GLIBC_2.2)[3] 

Data Definitions for libc

This section contains standard data definitions that describe system data. 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.

ISO C serves as the LSB 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.


errno.h




#define EDEADLOCK	EDEADLK

inttypes.h






typedef long intmax_t;
typedef unsigned long uintmax_t;
typedef unsigned long uintptr_t;

limits.h


#define LONG_MAX	0x7FFFFFFFFFFFFFFFL
#define ULONG_MAX	0xFFFFFFFFFFFFFFFFUL






#define CHAR_MAX	SCHAR_MAX
#define CHAR_MIN	SCHAR_MIN

setjmp.h






typedef long __jmp_buf[70] __attribute__ ((aligned (16)));

signal.h
























struct sigaction
{
  union
  {
    __sighandler_t _sa_handler;
    void (*_sa_sigaction) (int, siginfo_t *, void *);
  }
  __sigaction_handler;
  unsigned long sa_flags;
  sigset_t sa_mask;
}
 ;





struct ia64_fpreg
{
  union
  {
    unsigned long bits[2];
  }
  u;
}
__attribute__ ((aligned (16)));





struct sigcontext
{
  unsigned long sc_flags;
  unsigned long sc_nat;
  stack_t sc_stack;
  unsigned long sc_ip;
  unsigned long sc_cfm;
  unsigned long sc_um;
  unsigned long sc_ar_rsc;
  unsigned long sc_ar_bsp;
  unsigned long sc_ar_rnat;
  unsigned long sc_ar_ccv;
  unsigned long sc_ar_unat;
  unsigned long sc_ar_fpsr;
  unsigned long sc_ar_pfs;
  unsigned long sc_ar_lc;
  unsigned long sc_pr;
  unsigned long sc_br[8];
  unsigned long sc_gr[32];
  struct ia64_fpreg sc_fr[128];
  unsigned long sc_rbs_base;
  unsigned long sc_loadrs;
  unsigned long sc_rsvd[14];
  unsigned long sc_mask;
}
 ;

stddef.h



typedef long ptrdiff_t;
typedef unsigned long size_t;

sys/ioctl.h


#define FIONREAD	0x541B
#define TIOCNOTTY	0x5422

sys/ipc.h



struct ipc_perm
{
  key_t __key;
  uid_t uid;
  gid_t gid;
  uid_t cuid;
  uid_t cgid;
  mode_t mode;
  unsigned short __seq;
  unsigned short __pad1;
  unsigned long __unused1;
  unsigned long __unused2;
}
 ;

sys/mman.h


#define MCL_CURRENT	1
#define MCL_FUTURE	2

sys/msg.h









struct msqid_ds
{
  struct ipc_perm msg_perm;
  time_t msg_stime;
  time_t msg_rtime;
  time_t msg_ctime;
  unsigned long __msg_cbytes;
  unsigned long msg_qnum;
  unsigned long msg_qbytes;
  pid_t msg_lspid;
  pid_t msg_lrpid;
  unsigned long __unused1;
  unsigned long __unused2;
}
 ;

sys/sem.h



struct semid_ds
{
  struct ipc_perm sem_perm;
  time_t sem_otime;
  time_t sem_ctime;
  unsigned long sem_nsems;
  unsigned long __unused1;
  unsigned long __unused2;
}
 ;

sys/shm.h


#define SHMLBA	(1024*1024)








struct shmid_ds
{
  struct ipc_perm shm_perm;
  size_t shm_segsz;
  time_t shm_atime;
  time_t shm_dtime;
  time_t shm_ctime;
  pid_t shm_cpid;
  pid_t shm_lpid;
  unsigned long shm_nattch;
  unsigned long __unused1;
  unsigned long __unused2;
}
 ;

sys/stat.h


#define _STAT_VER	1


struct stat
{
  unsigned long st_dev;
  unsigned long st_ino;
  unsigned long st_nlink;
  unsigned int st_mode;
  unsigned int st_uid;
  unsigned int st_gid;
  unsigned int pad0;
  unsigned long st_rdev;
  unsigned long st_size;
  unsigned long st_atime;
  unsigned long __reserved0;
  unsigned long st_mtime;
  unsigned long __reserved1;
  unsigned long st_ctime;
  unsigned long __reserved2;
  unsigned long st_blksize;
  long st_blocks;
  unsigned long __unused[3];
}
 ;
struct stat64
{
  unsigned long st_dev;
  unsigned long st_ino;
  unsigned long st_nlink;
  unsigned int st_mode;
  unsigned int st_uid;
  unsigned int st_gid;
  unsigned int pad0;
  unsigned long st_rdev;
  unsigned long st_size;
  unsigned long st_atime;
  unsigned long __reserved0;
  unsigned long st_mtime;
  unsigned long __reserved1;
  unsigned long st_ctime;
  unsigned long __reserved2;
  unsigned long st_blksize;
  long st_blocks;
  unsigned long __unused[3];
}
 ;

sys/statvfs.h



struct statvfs
{
  unsigned long f_bsize;
  unsigned long f_frsize;
  fsblkcnt64_t f_blocks;
  fsblkcnt64_t f_bfree;
  fsblkcnt64_t f_bavail;
  fsfilcnt64_t f_files;
  fsfilcnt64_t f_ffree;
  fsfilcnt64_t f_favail;
  unsigned long f_fsid;
  unsigned long f_flag;
  unsigned long f_namemax;
  unsigned int __f_spare[6];
}
 ;
struct statvfs64
{
  unsigned long f_bsize;
  unsigned long f_frsize;
  fsblkcnt64_t f_blocks;
  fsblkcnt64_t f_bfree;
  fsblkcnt64_t f_bavail;
  fsfilcnt64_t f_files;
  fsfilcnt64_t f_ffree;
  fsfilcnt64_t f_favail;
  unsigned long f_fsid;
  unsigned long f_flag;
  unsigned long f_namemax;
  unsigned int __f_spare[6];
}
 ;

sys/types.h



typedef int64_t ssize_t;

termios.h


#define OLCUC	0000002
#define ONLCR	0000004
#define XCASE	0000004
#define NLDLY	0000400
#define CR1	0001000
#define IUCLC	0001000
#define CR2	0002000
#define CR3	0003000
#define CRDLY	0003000
#define TAB1	0004000
#define TAB2	0010000
#define TAB3	0014000
#define TABDLY	0014000
#define BS1	0020000
#define BSDLY	0020000
#define VT1	0040000
#define VTDLY	0040000
#define FF1	0100000
#define FFDLY	0100000









#define VSUSP	10
#define VEOL	11
#define VREPRINT	12
#define VDISCARD	13
#define VWERASE	14
#define VEOL2	16
#define VMIN	6
#define VSWTC	7
#define VSTART	8
#define VSTOP	9



#define IXON	0002000
#define IXOFF	0010000






#define CS6	0000020
#define CS7	0000040
#define CS8	0000060
#define CSIZE	0000060
#define CSTOPB	0000100
#define CREAD	0000200
#define PARENB	0000400
#define PARODD	0001000
#define HUPCL	0002000
#define CLOCAL	0004000
#define VTIME	5



#define ISIG	0000001
#define ICANON	0000002
#define ECHOE	0000020
#define ECHOK	0000040
#define ECHONL	0000100
#define NOFLSH	0000200
#define TOSTOP	0000400
#define ECHOCTL	0001000
#define ECHOPRT	0002000
#define ECHOKE	0004000
#define FLUSHO	0010000
#define PENDIN	0040000
#define IEXTEN	0100000

ucontext.h


#define _SC_GR0_OFFSET	(((char *) & ((struct sigcontext *) 0)->sc_gr[0]) - (char *) 0)


























typedef struct sigcontext mcontext_t;


typedef struct ucontext
{
  union
  {
    mcontext_t _mc;
    struct
    {
      unsigned long _pad[_SC_GR0_OFFSET / 8];
      struct ucontext *_link;
    }
    _uc;
  }
  _u;
}
ucontext_t;

unistd.h



typedef long intptr_t;

Interfaces for libm

Table 16-31. libm Definition

Library:libm
SONAME:libm.so.6.1

The behavior of the interfaces in this library is specified by the following standards.

ISO/IEC 9899: 1999, Programming Languages --C[10]
CAE Specification, January 1997, System Interfaces and Headers (XSH),Issue 5 (ISBN: 1-85912-181-0, C606)[11]


Math

Table 16-32. libm - Math Function Interfaces

acos(GLIBC_2.2)[11]cexp(GLIBC_2.2)[10]expf(GLIBC_2.2)[10]jnf(GLIBC_2.2)[10]remquof(GLIBC_2.2)[10]
acosf(GLIBC_2.2)[10]cexpf(GLIBC_2.2)[10]expl(GLIBC_2.2)[10]jnl(GLIBC_2.2)[10]remquol(GLIBC_2.2)[10]
acosh(GLIBC_2.2)[11]cexpl(GLIBC_2.2)[10]expm1(GLIBC_2.2)[11]ldexp(GLIBC_2.2)[11]rint(GLIBC_2.2)[11]
acoshf(GLIBC_2.2)[10]cimag(GLIBC_2.2)[10]fabs(GLIBC_2.2)[11]ldexpf(GLIBC_2.2)[10]rintf(GLIBC_2.2)[10]
acoshl(GLIBC_2.2)[10]cimagf(GLIBC_2.2)[10]fabsf(GLIBC_2.2)[10]ldexpl(GLIBC_2.2)[10]rintl(GLIBC_2.2)[10]
acosl(GLIBC_2.2)[10]cimagl(GLIBC_2.2)[10]fabsl(GLIBC_2.2)[10]lgamma(GLIBC_2.2)[11]round(GLIBC_2.2)[10]
asin(GLIBC_2.2)[11]clog(GLIBC_2.2)[10]fdim(GLIBC_2.2)[10]lgamma_r(GLIBC_2.2)[10]roundf(GLIBC_2.2)[10]
asinf(GLIBC_2.2)[10]clog10(GLIBC_2.2)[10]fdimf(GLIBC_2.2)[10]lgammaf(GLIBC_2.2)[10]roundl(GLIBC_2.2)[10]
asinh(GLIBC_2.2)[11]clog10f(GLIBC_2.2)[10]fdiml(GLIBC_2.2)[10]lgammaf_r(GLIBC_2.2)[10]scalb(GLIBC_2.2)[11]
asinhf(GLIBC_2.2)[10]clog10l(GLIBC_2.2)[10]feclearexcept(GLIBC_2.2)[10]lgammal(GLIBC_2.2)[10]scalbf(GLIBC_2.2)[10]
asinhl(GLIBC_2.2)[10]clogf(GLIBC_2.2)[10]fegetenv(GLIBC_2.2)[10]lgammal_r(GLIBC_2.2)[10]scalbl(GLIBC_2.2)[10]
asinl(GLIBC_2.2)[10]clogl(GLIBC_2.2)[10]fegetexceptflag(GLIBC_2.2)[10]llrint(GLIBC_2.2)[10]scalbln(GLIBC_2.2)[10]
atan(GLIBC_2.2)[11]conj(GLIBC_2.2)[10]fegetround(GLIBC_2.2)[10]llrintf(GLIBC_2.2)[10]scalblnf(GLIBC_2.2)[10]
atan2(GLIBC_2.2)[11]conjf(GLIBC_2.2)[10]feholdexcept(GLIBC_2.2)[10]llrintl(GLIBC_2.2)[10]scalblnl(GLIBC_2.2)[10]
atan2f(GLIBC_2.2)[10]conjl(GLIBC_2.2)[10]feraiseexcept(GLIBC_2.2)[10]llround(GLIBC_2.2)[10]scalbn(GLIBC_2.2)[10]
atan2l(GLIBC_2.2)[10]copysign(GLIBC_2.2)[10]fesetenv(GLIBC_2.2)[10]llroundf(GLIBC_2.2)[10]scalbnf(GLIBC_2.2)[10]
atanf(GLIBC_2.2)[10]copysignf(GLIBC_2.2)[10]fesetexceptflag(GLIBC_2.2)[10]llroundl(GLIBC_2.2)[10]scalbnl(GLIBC_2.2)[10]
atanh(GLIBC_2.2)[11]copysignl(GLIBC_2.2)[10]fesetround(GLIBC_2.2)[10]log(GLIBC_2.2)[11]significand(GLIBC_2.2)[10]
atanhf(GLIBC_2.2)[10]cos(GLIBC_2.2)[11]fetestexcept(GLIBC_2.2)[10]log10(GLIBC_2.2)[11]significandf(GLIBC_2.2)[10]
atanhl(GLIBC_2.2)[10]cosf(GLIBC_2.2)[10]feupdateenv(GLIBC_2.2)[10]log10f(GLIBC_2.2)[10]significandl(GLIBC_2.2)[10]
atanl(GLIBC_2.2)[10]cosh(GLIBC_2.2)[11]finite(GLIBC_2.2)[11]log10l(GLIBC_2.2)[10]sin(GLIBC_2.2)[11]
cabs(GLIBC_2.2)[11]coshf(GLIBC_2.2)[10]finitef(GLIBC_2.2)[10]log1p(GLIBC_2.2)[11]sincos(GLIBC_2.2)[10]
cabsf(GLIBC_2.2)[10]coshl(GLIBC_2.2)[10]finitel(GLIBC_2.2)[10]logb(GLIBC_2.2)[11]sincosf(GLIBC_2.2)[10]
cabsl(GLIBC_2.2)[10]cosl(GLIBC_2.2)[10]floor(GLIBC_2.2)[11]logf(GLIBC_2.2)[10]sincosl(GLIBC_2.2)[10]
cacos(GLIBC_2.2)[10]cpow(GLIBC_2.2)[10]floorf(GLIBC_2.2)[10]logl(GLIBC_2.2)[10]sinf(GLIBC_2.2)[10]
cacosf(GLIBC_2.2)[10]cpowf(GLIBC_2.2)[10]floorl(GLIBC_2.2)[10]lrint(GLIBC_2.2)[10]sinh(GLIBC_2.2)[11]
cacosh(GLIBC_2.2)[10]cpowl(GLIBC_2.2)[10]fma(GLIBC_2.2)[10]lrintf(GLIBC_2.2)[10]sinhf(GLIBC_2.2)[10]
cacoshf(GLIBC_2.2)[10]cproj(GLIBC_2.2)[10]fmaf(GLIBC_2.2)[10]lrintl(GLIBC_2.2)[10]sinhl(GLIBC_2.2)[10]
cacoshl(GLIBC_2.2)[10]cprojf(GLIBC_2.2)[10]fmal(GLIBC_2.2)[10]lround(GLIBC_2.2)[10]sinl(GLIBC_2.2)[10]
cacosl(GLIBC_2.2)[10]cprojl(GLIBC_2.2)[10]fmax(GLIBC_2.2)[10]lroundf(GLIBC_2.2)[10]sqrt(GLIBC_2.2)[11]
carg(GLIBC_2.2)[10]creal(GLIBC_2.2)[10]fmaxf(GLIBC_2.2)[10]lroundl(GLIBC_2.2)[10]sqrtf(GLIBC_2.2)[10]
cargf(GLIBC_2.2)[10]crealf(GLIBC_2.2)[10]fmaxl(GLIBC_2.2)[10]matherr(GLIBC_2.2)[10]sqrtl(GLIBC_2.2)[10]
cargl(GLIBC_2.2)[10]creall(GLIBC_2.2)[10]fmin(GLIBC_2.2)[10]modf(GLIBC_2.2)[11]tan(GLIBC_2.2)[11]
casin(GLIBC_2.2)[10]csin(GLIBC_2.2)[10]fminf(GLIBC_2.2)[10]modff(GLIBC_2.2)[10]tanf(GLIBC_2.2)[10]
casinf(GLIBC_2.2)[10]csinf(GLIBC_2.2)[10]fminl(GLIBC_2.2)[10]modfl(GLIBC_2.2)[10]tanh(GLIBC_2.2)[11]
casinh(GLIBC_2.2)[10]csinh(GLIBC_2.2)[10]fmod(GLIBC_2.2)[11]nan(GLIBC_2.2)[10]tanhf(GLIBC_2.2)[10]
casinhf(GLIBC_2.2)[10]csinhf(GLIBC_2.2)[10]fmodf(GLIBC_2.2)[10]nanf(GLIBC_2.2)[10]tanhl(GLIBC_2.2)[10]
casinhl(GLIBC_2.2)[10]csinhl(GLIBC_2.2)[10]fmodl(GLIBC_2.2)[10]nanl(GLIBC_2.2)[10]tanl(GLIBC_2.2)[10]
casinl(GLIBC_2.2)[10]csinl(GLIBC_2.2)[10]frexp(GLIBC_2.2)[11]nearbyint(GLIBC_2.2)[10]tgamma(GLIBC_2.2)[10]
catan(GLIBC_2.2)[10]csqrt(GLIBC_2.2)[10]frexpf(GLIBC_2.2)[10]nearbyintf(GLIBC_2.2)[10]tgammaf(GLIBC_2.2)[10]
catanf(GLIBC_2.2)[10]csqrtf(GLIBC_2.2)[10]frexpl(GLIBC_2.2)[10]nearbyintl(GLIBC_2.2)[10]tgammal(GLIBC_2.2)[10]
catanh(GLIBC_2.2)[10]csqrtl(GLIBC_2.2)[10]gamma(GLIBC_2.2)[11]nextafter(GLIBC_2.2)[11]trunc(GLIBC_2.2)[10]
catanhf(GLIBC_2.2)[10]ctan(GLIBC_2.2)[10]gammaf(GLIBC_2.2)[10]nextafterf(GLIBC_2.2)[10]truncf(GLIBC_2.2)[10]
catanhl(GLIBC_2.2)[10]ctanf(GLIBC_2.2)[10]gammal(GLIBC_2.2)[10]nextafterl(GLIBC_2.2)[10]truncl(GLIBC_2.2)[10]
catanl(GLIBC_2.2)[10]ctanh(GLIBC_2.2)[10]hypot(GLIBC_2.2)[11]nexttoward(GLIBC_2.2)[10]y0(GLIBC_2.2)[11]
cbrt(GLIBC_2.2)[11]ctanhf(GLIBC_2.2)[10]hypotf(GLIBC_2.2)[10]nexttowardf(GLIBC_2.2)[10]y0f(GLIBC_2.2)[10]
cbrtf(GLIBC_2.2)[10]ctanhl(GLIBC_2.2)[10]hypotl(GLIBC_2.2)[10]nexttowardl(GLIBC_2.2)[10]y0l(GLIBC_2.2)[10]
cbrtl(GLIBC_2.2)[10]ctanl(GLIBC_2.2)[10]ilogb(GLIBC_2.2)[11]pow(GLIBC_2.2)[10]y1(GLIBC_2.2)[11]
ccos(GLIBC_2.2)[10]dremf(GLIBC_2.2)[10]ilogbf(GLIBC_2.2)[10]pow10(GLIBC_2.2)[10]y1f(GLIBC_2.2)[10]
ccosf(GLIBC_2.2)[10]dreml(GLIBC_2.2)[10]ilogbl(GLIBC_2.2)[10]pow10f(GLIBC_2.2)[10]y1l(GLIBC_2.2)[10]
ccosh(GLIBC_2.2)[10]erf(GLIBC_2.2)[11]j0(GLIBC_2.2)[11]pow10l(GLIBC_2.2)[10]yn(GLIBC_2.2)[11]
ccoshf(GLIBC_2.2)[10]erfc(GLIBC_2.2)[11]j0f(GLIBC_2.2)[10]powf(GLIBC_2.2)[10]ynf(GLIBC_2.2)[10]
ccoshl(GLIBC_2.2)[10]erfcf(GLIBC_2.2)[10]j0l(GLIBC_2.2)[10]powl(GLIBC_2.2)[10]ynl(GLIBC_2.2)[10]
ccosl(GLIBC_2.2)[10]erfcl(GLIBC_2.2)[10]j1(GLIBC_2.2)[11]remainder(GLIBC_2.2)[11] 
ceil(GLIBC_2.2)[11]erff(GLIBC_2.2)[10]j1f(GLIBC_2.2)[10]remainderf(GLIBC_2.2)[10] 
ceilf(GLIBC_2.2)[10]erfl(GLIBC_2.2)[10]j1l(GLIBC_2.2)[10]remainderl(GLIBC_2.2)[10] 
ceill(GLIBC_2.2)[10]exp(GLIBC_2.2)[11]jn(GLIBC_2.2)[11]remquo(GLIBC_2.2)[10] 

Table 16-33. libm - Math Data Interfaces

signgam(GLIBC_2.2)[11]    

Data Definitions for libm

This section contains standard data definitions that describe system data. 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.

ISO C serves as the LSB 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.


Interfaces for libpthread

Table 16-34. libpthread Definition

Library:libpthread
SONAME:libpthread.so.0

The behavior of the interfaces in this library is specified by the following standards.

Linux Standard Base[12]
CAE Specification, January 1997, System Interfaces and Headers (XSH),Issue 5 (ISBN: 1-85912-181-0, C606)[13]


Posix Threads

Table 16-35. libpthread - Posix Threads Function Interfaces

pthread_attr_destroy(GLIBC_2.2)[13]pthread_attr_setstackaddr(GLIBC_2.2)[13]pthread_getspecific(GLIBC_2.2)[13]pthread_once(GLIBC_2.2)[13]pthread_setcanceltype(GLIBC_2.2)[13]
pthread_attr_getdetachstate(GLIBC_2.2)[13]pthread_attr_setstacksize(GLIBC_2.2)[13]pthread_join(GLIBC_2.2)[13]pthread_rwlock_destroy(GLIBC_2.2)[13]pthread_setconcurrency(GLIBC_2.2)[13]
pthread_attr_getguardsize(GLIBC_2.2)[13]pthread_cancel(GLIBC_2.2)[13]pthread_key_create(GLIBC_2.2)[13]pthread_rwlock_init(GLIBC_2.2)[13]pthread_setschedparam(GLIBC_2.2)[13]
pthread_attr_getinheritsched(GLIBC_2.2)[13]pthread_cond_broadcast(GLIBC_2.2)[13]pthread_key_delete(GLIBC_2.2)[13]pthread_rwlock_rdlock(GLIBC_2.2)[13]pthread_setspecific(GLIBC_2.2)[13]
pthread_attr_getschedparam(GLIBC_2.2)[13]pthread_cond_destroy(GLIBC_2.2)[13]pthread_kill(GLIBC_2.2)[13]pthread_rwlock_timedrdlock(GLIBC_2.2)[13]pthread_sigmask(GLIBC_2.2)[13]
pthread_attr_getschedpolicy(GLIBC_2.2)[13]pthread_cond_init(GLIBC_2.2)[13]pthread_mutex_destroy(GLIBC_2.2)[13]pthread_rwlock_timedwrlock(GLIBC_2.2)[13]pthread_testcancel(GLIBC_2.2)[13]
pthread_attr_getscope(GLIBC_2.2)[13]pthread_cond_signal(GLIBC_2.2)[13]pthread_mutex_init(GLIBC_2.2)[13]pthread_rwlock_tryrdlock(GLIBC_2.2)[13]sem_close(GLIBC_2.2)[13]
pthread_attr_getstackaddr(GLIBC_2.2)[13]pthread_cond_timedwait(GLIBC_2.2)[13]pthread_mutex_lock(GLIBC_2.2)[13]pthread_rwlock_trywrlock(GLIBC_2.2)[13]sem_destroy(GLIBC_2.2)[13]
pthread_attr_getstacksize(GLIBC_2.2)[13]pthread_cond_wait(GLIBC_2.2)[13]pthread_mutex_trylock(GLIBC_2.2)[13]pthread_rwlock_unlock(GLIBC_2.2)[13]sem_getvalue(GLIBC_2.2)[13]
pthread_attr_init(GLIBC_2.2)[13]pthread_condattr_destroy(GLIBC_2.2)[13]pthread_mutex_unlock(GLIBC_2.2)[13]pthread_rwlock_wrlock(GLIBC_2.2)[13]sem_init(GLIBC_2.2)[13]
pthread_attr_setdetachstate(GLIBC_2.2)[13]pthread_condattr_init(GLIBC_2.2)[13]pthread_mutexattr_destroy(GLIBC_2.2)[13]pthread_rwlockattr_destroy(GLIBC_2.2)[13]sem_open(GLIBC_2.2)[13]
pthread_attr_setguardsize(GLIBC_2.2)[13]pthread_create(GLIBC_2.2)[13]pthread_mutexattr_getpshared(GLIBC_2.2)[13]pthread_rwlockattr_getpshared(GLIBC_2.2)[13]sem_post(GLIBC_2.2)[13]
pthread_attr_setinheritsched(GLIBC_2.2)[13]pthread_detach(GLIBC_2.2)[13]pthread_mutexattr_gettype(GLIBC_2.2)[13]pthread_rwlockattr_init(GLIBC_2.2)[13]sem_timedwait(GLIBC_2.2)[12]
pthread_attr_setschedparam(GLIBC_2.2)[13]pthread_equal(GLIBC_2.2)[13]pthread_mutexattr_init(GLIBC_2.2)[13]pthread_rwlockattr_setpshared(GLIBC_2.2)[13]sem_trywait(GLIBC_2.2)[13]
pthread_attr_setschedpolicy(GLIBC_2.2)[13]pthread_exit(GLIBC_2.2)[13]pthread_mutexattr_setpshared(GLIBC_2.2)[13]pthread_self(GLIBC_2.2)[13]sem_unlink(GLIBC_2.2)[13]
pthread_attr_setscope(GLIBC_2.2)[13]pthread_getschedparam(GLIBC_2.2)[13]pthread_mutexattr_settype(GLIBC_2.2)[13]pthread_setcancelstate(GLIBC_2.2)[13]sem_wait(GLIBC_2.2)[13]

Data Definitions for libpthread

This section contains standard data definitions that describe system data. 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.

ISO C serves as the LSB 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.


Interfaces for libdl

Table 16-36. libdl Definition

Library:libdl
SONAME:libdl.so.2


Dynamic Loader


Data Definitions for libdl

This section contains standard data definitions that describe system data. 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.

ISO C serves as the LSB 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.


Interfaces for libcrypt

Table 16-37. libcrypt Definition

Library:libcrypt
SONAME:libcrypt.so.1


Encryption


Data Definitions for libcrypt

This section contains standard data definitions that describe system data. 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.

ISO C serves as the LSB 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.

VI. Package Format and Installation

Table of Contents
17. Software Installation

Chapter 17. Software Installation


Package Architecture Considerations

All packages must specify an architecture of IA64. A LSB runtime environment must accept an architecture of IA64 even if the native architecture is different.

The archnum value in the Lead Section shall be 0x0009.


Appendix A. Alphabetical Listing of Interfaces


Appendix B. GNU Free Documentation License

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.


PREAMBLE

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.


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COMBINING DOCUMENTS

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COLLECTIONS OF DOCUMENTS

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TERMINATION

You may not copy, modify, sublicense, or distribute the Document except as expressly provided for under this License. Any other attempt to copy, modify, sublicense or distribute the Document is void, and will automatically terminate your rights under this License. However, parties who have received copies, or rights, from you under this License will not have their licenses terminated so long as such parties remain in full compliance.


FUTURE REVISIONS OF THIS LICENSE

The Free Software Foundation may publish new, revised versions of the GNU Free Documentation License from time to time. Such new versions will be similar in spirit to the present version, but may differ in detail to address new problems or concerns. See http://www.gnu.org/copyleft/.

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How to use this License for your documents

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.


Appendix C. Build Environment

Introduction

This section is informative, and carries no normative requirements on the Itanium™ Application Binary Interface. The interfaces described here should be available in an Itanium™ LSB Build Environment. An LSB Build Environment is a platform on which LSB conforming applications can be built from source code. Platforms providing an LSB Build Environment need not provide an LSB Runtime Environment.


Build Environment

A conforming LSB Build Environment should provide a compiler capable of producing objects that conform to this standard.

Such a compiler should provide the following predefined symbols, pre-processor assertions, and compiler pragmas.


Pre-Defined Preprocessor Symbols

Table C-1. Pre-Defined Preprocessor Symbols

SymbolDescription
__ia64This symbol should be used when testing for the target architecture at compile time. The initial value shall be 1. Further information on the architecture can be determined from the ELF header flags.
_LP64Value is defined as 1. The architecture supports 64 bit longs, long longs, and pointers. Integers are 32 bit.

Note

The gcc compiler currently pre-defines the symbol __LP64__, but not the symbol _LP64. The gcc team are aware of this deficiency.


Pre-Defined Preprocessor Assertions

Preprocessor assertions are deprecated, and conforming applications should not require any preprocessor assertion support. LSB Conforming Build Environments are not required to provide any predefined preprocessor assertions.

Note

The Intel® Itanium ™ Processor-specific Application Binary Interface requires preprocessor assertion support. However, this feature is deprecated in some compilers (most notably gcc), and applications should not use it.


Compiler Pragmas

The Intel® Itanium ™ Processor-specific Application Binary Interface, chapter 7.2.3, defines a number of compiler pragmas specific to the Intel Itanium™ compiler. These pragmas are not required to be supported by other compilers.


ILP32 ABI

Support for the IA32/ILP32 ABI is optional. See Intel® Itanium ™ Processor-specific Application Binary Interface Chapter 7.3.


Synchronization Primitives

The synchronization primitives listed below should be available to applications in the LSB Build Environment for Itanium™. These intrinsic functions need not be provided in any system library, and the compiler may treat these as inline functions in all cases. See Intel® Itanium ™ Processor-specific Application Binary Interface, Chapter 7.4 for details.

Table C-2. Intrinsic Functions

SymbolDescription
__sync_fetch_and_addAtomically add a value to a referenced location and return the previous value
__sync_fetch_and_subAtomically subtract a value from a referenced location and return the previous value
__sync_fetch_and_orAtomically bitwise or a value with a referenced location and return the previous value
__sync_fetch_and_andAtomically bitwise and a value with a referenced location and return the previous value
__sync_fetch_and_xorAtomically bitwise exclusive or a value with a referenced location and return the previous value
__sync_fetch_and_nandAtomically bitwise not-and a value with a referenced location and return the previous value
__sync_add_and_fetchAtomically add a value to a referenced location and return the new value
__sync_sub_and_fetchAtomically subtract a value from a referenced location and return the new value
__sync_or_and_fetchAtomically bitwise or a value with a referenced location and return the new value
__sync_and_and_fetchAtomically bitwise and a value with a referenced location and return the new value
__sync_xor_and_fetchAtomically bitwise exclusive or a value with a referenced location and return the new value
__sync_nand_and_fetchAtomically bitwise not-and a value with a referenced location and return the new value
__sync_bool_compare_and_swapAtomically compare a referenced location with a given value. If equal, replace the contents of the location with a new value, and return 1 (true), otherwise return 0 (false).
__sync_val_compare_and_swapAtomically compare a referenced location with a given value. If equal, replace the contents of the location with a new value. Return the resulting value.
__sync_synchronizeA synchronization point.
__sync_lock_test_and_setAtomically set a referenced location to a value and return the old value. Acquire a lock on the referenced location.
__sync_lock_releaseRelease a lock acquired previously.

Notes

[1]

ISO/IEC 9899: 1999, Programming Languages --C

[2]

Large File Support

[3]

Linux Standard Base

[4]

IEEE Std POSIX.1-1996 [ISO/IEC 9945-1:1996]

[5]

CAE Specification, February 1997, Networking Services (XNS), Issue 5(ISBN: 1-85912-165-9, C523)

[6]

CAE Specification, January 1997, System Interfaces and Headers (XSH),Issue 5 (ISBN: 1-85912-181-0, C606)

[7]

The Single UNIX® Specification(SUS) Version 3

[8]

System V Interface Definition, Issue 3 (ISBN 0201566524)

[9]

System V Interface Definition,Fourth Edition

[10]

ISO/IEC 9899: 1999, Programming Languages --C

[11]

CAE Specification, January 1997, System Interfaces and Headers (XSH),Issue 5 (ISBN: 1-85912-181-0, C606)

[12]

Linux Standard Base

[13]

CAE Specification, January 1997, System Interfaces and Headers (XSH),Issue 5 (ISBN: 1-85912-181-0, C606)