Feature-test macros provide a means for writing portable programs. They ensure that the Compaq C RTL symbolic names used by a program do not clash with the symbolic names supplied by the implementation. The Compaq C RTL header files are coded to support the use of a number of feature-test macros. When an application defines a feature-test macro, the Compaq C RTL header files supply the symbols and prototypes defined by that feature-test macro and nothing else. If a program does not define such a macro, the Compaq C RTL header files define symbols without restriction. The feature-test macros supported by the Compaq C RTL fall into the following broad categories for controlling the visibility of symbols in header files according to the following: o Standards o Multiple-version support o Compatibility
1 – Standards Macros
The Compaq C RTL implements parts of the following standards: o X/Open CAE Specification, System Interfaces and Headers, Issue 4, Version 2, also known as XPG4 V2. o X/Open CAE Specification, System Interfaces and Headers, Issue 4, also known as XPG4. o Standard for Information Technology - Portable Operating System Interface (POSIX) - Part 1: System Application Program Interface (API)-Amendment 2: Threads Extension [C Language], also known as POSIX 1003.1c-1995 or IEEE 1003.1c-1995. o ISO/IEC 9945-2:1993 - Information Technology - Portable Operating System Interface (POSIX) - Part 2: Shell and Utilities, also known as ISO POSIX-2. o ISO/IEC 9945-1:1990 - Information Technology - Portable Operating System Interface (POSIX) - Part 1: System Application Programming Interface (API) (C Language), also known as ISO POSIX-1. o ANSI/ISO/IEC 9899:1999 - The C99 standard, published by ISO in December, 1999 and adopted as an ANSI standard in April, 2000. o ISO/IEC 9899:1990-1994 - Programming Languages - C, Amendment 1: Integrity, also known as ISO C, Amendment 1. o ISO/IEC 9899:1990 - Programming Languages - C, also known as ISO C. The normative part is the same as X3.159-1989, American National Standard for Information Systems - Programming Language C, also known as ANSI C.
2 – Selecting a Standard
You can define a feature-test macro to select each standard. You can do this either with a #define preprocessor directive in your C source before the inclusion of any header file, or with the /DEFINE qualifier on the CC command line. Features not defined by one of the previously named standards are considered Compaq C extensions and are selected by not defining any standards-related, feature-test macros. If you do not explicitly define feature test macros to control header file definitions, you implicitly include all defined symbols as well as Compaq C extensions.
2.1 – XOPEN SOURCE EXTENDED
Makes visible XPG4-extended features, including traditional UNIX based interfaces not previously adopted by X/Open. Standard Selected: XPG4 V2 Other Standards Implied: XPG4, ISO POSIX-2, ISO POSIX-1, ANSI C
2.2 – XOPEN SOURCE
Makes visible XPG4 standard symbols and causes _POSIX_C_SOURCE to be set to 2 if it is not already defined with a value greater than 2. Notes: o Where the ISO C Amendment 1 includes symbols not specified by XPG4, defining __STDC_VERSION__ == 199409 and _XOPEN_SOURCE (or _XOPEN_SOURCE_EXTENDED) selects both ISO C and XPG4 APIs. Conflicts that arise when compiling with both XPG4 and ISO C Amendment 1 resolve in favor of ISO C Amendment 1. o Where XPG4 extends the ISO C Amendment 1, defining _XOPEN_ SOURCE or _XOPEN_SOURCE_EXTENDED selects ISO C APIs as well as the XPG4 extensions available in the header file. This mode of compilation makes XPG4 extensions visible. Standard Selected: XPG4 Other Standards Implied: XPG4, ISO POSIX-2, ISO POSIX-1, ANSI C
2.3 – POSIX C SOURCE==199506
Header files defined by ANSI C make visible those symbols required by IEEE 1003.1c-1995. Standard Selected: IEEE 1003.1c-1995 Other Standards Implied: ISO POSIX-2, ISO POSIX-1, ANSI C
2.4 – POSIX C SOURCE==2
Header files defined by ANSI C make visible those symbols required by ISO POSIX-2 plus those required by ISO POSIX-1. Standard Selected: ISO POSIX-2 Other Standards Implied: ISO POSIX-1, ANSI C
2.5 – POSIX C SOURCE==1
Header files defined by ANSI C make visible those symbols required by ISO POSIX-1. Standard Selected: ISO POSIX-1 Other Standards Implied: ANSI C
2.6 – STDC VERSION ==199409
Makes ISO C Amendment 1 symbols visible. Standard Selected: ISO C Amendment 1 Other Standards Implied: ANSI C
2.7 – ANSI C SOURCE
Makes ANSI C standard symbols visible. Standard Selected: ANSI C Other Standards Implied: None.
2.8 – Interactions with the /STANDARD Qualifier
The /STANDARD qualifier selects the dialect of the C language supported. With the exception of /STANDARD=ANSI89 and /STANDARD=ISOC94, the selection of C dialect and the selection of Compaq C RTL APIs to use are independent choices. All other values for /STANDARD cause the entire set of APIs to be available, including extensions. Specifying /STANDARD=ANSI89 restricts the default API set to the ANSI C set. In this case, to select a broader set of APIs, you must also specify the appropriate feature-test macro. To select the ANSI C dialect and all APIs, including extensions, undefine __HIDE_FORBIDDEN_NAMES before including any header file. Compiling with /STANDARD=ISOC94 sets __STDC_VERSION__ to 199409. Conflicts that arise when compiling with both XPG4 and ISO C Amendment 1 resolve in favor of ISO C Amendment 1. XPG4 extensions to ISO C Amendment 1 are selected by defining _XOPEN_ SOURCE. The following examples help clarify these rules: o The fdopen function is an ISO POSIX-1 extension to <stdio.h>. Therefore, <stdio.h> defines fdopen only if one or more of the following is true: - The program including it is not compiled in strict ANSI C mode (/STANDARD=ANSI89). - _POSIX_C_SOURCE is defined as 1 or greater. - _XOPEN_SOURCE is defined. - _XOPEN_SOURCE_EXTENDED is defined. o The popen function is an ISO POSIX-2 extension to <stdio.h>. Therefore, <stdio.h> defines popen only if one or more of the following is true: - The program including it is not compiled in strict ANSI C mode (/STANDARD=ANSI89). - _POSIX_C_SOURCE is defined as 2 or greater. - _XOPEN_SOURCE is defined. - _XOPEN_SOURCE_EXTENDED is defined. o The getw function is an X/Open extension to <stdio.h>. Therefore, <stdio.h> defines getw only if one or more of the following is true: - The program is not compiled in strict ANSI C mode (/STANDARD=ANSI89). - _XOPEN_SOURCE is defined. - _XOPEN_SOURCE_EXTENDED is defined. o The X/Open Extended symbolic constants _SC_PAGESIZE, _SC_PAGE_SIZE, _SC_ATEXIT_MAX, and _SC_IOV_MAX were added to <unistd.h> to support the sysconf function. However, these constants are not defined by _POSIX_C_SOURCE. The <unistd.h> header file defines these constants only if a program does not define _POSIX_C_SOURCE and does define _XOPEN_SOURCE_EXTENDED. If _POSIX_C_SOURCE is defined, these constants are not visible in <unistd.h>. Note that _POSIX_C_SOURCE is defined only for programs compiled in strict ANSI C mode. o The fgetname function is a Compaq C RTL extension to <stdio.h>. Therefore, <stdio.h> defines fgetname only if the program is not compiled in strict ANSI C mode (/STANDARD=ANSI89). o The macro _PTHREAD_KEYS_MAX is defined by POSIX 1003.1c-1995. This macro is made visible in <limits.h> when compiling for this standard with _POSIX_C_SOURCE == 199506 defined, or by default when compiling without any standards-defining, feature-test macros. o The macro WCHAR_MAX defined in <wchar.h> is required by ISO C Amendment 1 but not by XPG4. Therefore: - Compiling for ISO C Amendment 1 makes this symbol visible, but compiling for XPG4 compliance does not. - Compiling for both ISO C Amendment 1 and XPG4 makes this symbol visible. Similarly, the functions wcsftime and wcstok in <wchar.h> are defined slightly differently by the ISO C Amendment 1 and XPG4: - Compiling for ISO C Amendment 1 makes the ISO C Amendment 1 prototypes visible. - Compiling for XPG4 compliance makes the XPG4 prototypes visible. - Compiling for both ISO C Amendment 1 and XPG4 selects the ISO C prototypes because conflicts resulting from this mode of compilation resolve in favor of ISO C. - Compiling without any standard selecting feature test macros makes ISO C Amendment 1 features visible. In this example, compiling with no standard-selecting feature-test macros makes WCHAR_MAX and the ISO C Amendment 1 prototypes for wcsftime and wcstok visible. o The wcswidth and wcwidth functions are XPG4 extensions to ISO C Amendment 1. Their prototypes are in <wchar.h>. These symbols are visible if: - Compiling for XPG4 compliance by defining _XOPEN_SOURCE or _XOPEN_SOURCE_EXTENDED. - Compiling for DEC C Version 4.0 compatibility or on pre- OpenVMS Version 7.0 systems. - Compiling with no standard-selecting feature-test macros. - Compiling for both ISO C Amendment 1 and XPG4 compilance because these symbols are XPG4 extensions to ISO C Amendment 1. Compiling for strict ISO C Amendment 1 does not make them visible.
3 – Multiple-Version-Support Macro
By default, the header files enable APIs in the Compaq C RTL provided by the version of the operating system on which the compilation occurs. This is accomplished by the predefined setting of the __VMS_VER macro, as described in the Compaq C User's Guide for OpenVMS Systems. For example, compiling on OpenVMS Version 6.2 causes only Compaq C RTL APIs from Version 6.2 and earlier to be made available. Another example of the use of the __VMS_VER macro is support for the 64-bit versions of Compaq C RTL functions available with OpenVMS Alpha Version 7.0 and higher. In all header files, functions that provide 64-bit support are conditionalized so that they are visible only if __VMS_VER indicates a version of OpenVMS that is greater than or equal to 7.0. To target an older version of the operating system, do the following: 1. Define a logical DECC$SHR to point to the old version of DECC$SHR. The compiler uses a table from DECC$SHR to perform routine name prefixing. 2. Define __VMS_VER appropriately, either with the /DEFINE qualifier or with a combination of the #undef and #define preprocessor directives. With /DEFINE, you may need to disable the warning regarding redefinition of a predefined macro. Targeting a newer version of the operating system might not always be possible. For some versions, you can expect that the new DECC$SHR.EXE will require new features of the operating system that are not present. For such versions, the defining if the logical DECC$SHR in Step 1 would cause the compilation to fail. To override the value of __VMS_VER, define __VMS_VER_OVERRIDE on the compiler command line. Defining __VMS_VER_OVERRIDE without a value sets __VMS_VER to the maximum value.
4 – Compatibility Modes
The following predefined macros are used to select header-file compatibility with previous versions of DEC C) or the OpenVMS operating system: o _DECC_V4_SOURCE o _VMS_V6_SOURCE There are two types of incompatibilities that can be controlled in the header files: o To conform to standards, some changes are source-code incompatible but binary compatible. To select DEC C Version 4.0 source compatibility, use the _DECC_V4_SOURCE macro. o Other changes to conform to standards introduce a binary or run-time incompatibility. In general, programs that recompile get new behaviors. In these cases, use the _VMS_V6_SOURCE feature test macro to retain previous behaviors. However, for the exit, kill, and wait functions, the OpenVMS Version 7.0 changes to make these routines ISO POSIX-1 compliant were considered too incompatible to become the default. Therefore, in these cases the default behavior is the same as on pre-OpenVMS Version 7.0 systems. To access the versions of these routines that comply with ISO POSIX-1, use the _POSIX_EXIT feature test macro. The following examples help clarify the use of these macros: o To conform to the ISO POSIX-1 standard, typedefs for the following have been added to <types.h>: dev_t off_t gid_t pid_t ino_t size_t mode_t ssize_t nlink_t uid_t Previous development environments using a version of DEC C earlier than Version 5.2 may have compensated for the lack of these typedefs in <types.h> by adding them to another module. If this is the case on your system, then compiling with the <types.h> provided with DEC C Version 5.2 might cause compilation errors. To maintain your current environment and include the DEC C Version 5.2 <types.h>, compile with _DECC_V4_SOURCE defined. This will omit incompatible references from the DEC C Version 5.2 headers. In <types.h>, for example, the previously listed typedefs will not be visible. o As of OpenVMS Version 7.0, the Compaq C RTL getuid and geteuid functions are defined to return an OpenVMS UIC (user identification code) that contains both the group and member portions of the UIC. In previous versions of the DEC C RTL, these functions returned only the member number from the UIC code. Note that the prototypes for getuid and geteuid in <unistd.h> (as required by the ISO POSIX-1 standard) and in <unixlib.h> (for Compaq C RTL compatibility) have not changed. By default, newly compiled programs that call getuid and geteuid get the new definitions. That is, these functions will return an OpenVMS UIC. To let programs retain the pre-OpenVMS Version 7.0 behavior of getuid and geteuid, compile with the _VMS_V6_SOURCE feature- test macro defined. o As of OpenVMS Version 7.0, the Compaq C RTL exit function is defined with ISO POSIX-1 semantics. As a result, the input status argument to exit takes a number between 0 and 255. (Prior to this, exit could take an OpenVMS condition code in its status parameter.) By default, the behavior for exit on OpenVMS systems is the same as before: exit accepts an OpenVMS condition code. To enable the ISO POSIX-1 compatible exit function, compile with the _POSIX_EXIT feature-test macro defined.
5 – Curses and Socket Compatibility Macros
The following feature-test macros are used to control the Curses and Socket subsets of the Compaq C RTL library: o _BSD44_CURSES This macro selects the Curses package from the 4.4BSD Berkeley Software Distribution. o _VMS_CURSES This macro selects a Curses package based on the VAX C compiler. This is the default Curses package. o _SOCKADDR_LEN This macro is used to select 4.4BSD-compatible and XPG4 V2- compatible socket interfaces. These interfaces require support in your underlying TCP/IP software. Contact your TCP/IP vendor to inquire if the version of TCP/IP software you run supports 4.4BSD sockets. Strict XPG4 V2 compliance requires the 4.4BSD-compatible socket interface. Therefore, if _XOPEN_SOURCE_EXTENDED is defined on OpenVMS Version 7.0 or higher, _SOCKADDR_LEN is defined to be 1. The following examples help clarify the use of these macros: o Symbolic constants like AE, AL, AS, AM, BC, which represent pointers to termcap fields used by the BSD Curses package, are only visible in <curses.h> if _BSD44_CURSES is defined. o The <socket.h> header file defines a 4.4BSD sockaddr structure only if _SOCKADDR_LEN or _XOPEN_SOURCE_EXTENDED is defined. Otherwise, <socket.h> defines a pre-4.4BSD sockaddr structure. If _SOCKADDR_LEN is defined and _XOPEN_SOURCE_EXTENDED is not defined, The <socket.h> header file also defines an osockaddr structure, which is a 4.3BSD sockaddr structure to be used for compatibility purposes. Since XPG4 V2 does not define an osockaddr structure, it is not visible in _XOPEN_SOURCE_ EXTENDED mode.
6 – 2 GB File Size Macro
The C RTL provides support for compiling applications to use file sizes and offsets that are 2 GB and larger. This is accomplished by allowing file offsets of 64-bit integers. The fseeko and ftello functions, which have the same behavior as fseek and ftell, accept or return values of type off_t, which allows for a 64-bit variant of off_t to be used. C RTL functions lseek, mmap, ftuncate, truncate, stat, fstat, and ftw can also accommodate a 64-bit file offset. The new 64-bit interfaces can be selected at compile time by defining the _LARGEFILE feature macro.
7 – 32-Bit UID and GID Macro (Integrity servers, Alpha)
The C RTL supports 32-bit User Identification (UID) and Group Identification (GID). When an application is compiled to use 32-bit UID/GID, the UID and GID are derived from the UIC as in previous versions of the operating system. To compile an application for 16-bit UID/GID support on systems that by default use 32-bit UIDs/GIDs, define the _DECC_SHORT_GID_ T macro to 1. Not specifying _DECC_SHORT_GID_T provides long (32-bit) UID/GID. Compiling on older OpenVMS systems where long UID/GID is not supported, or compiling for legacy compatibility (_DECC_V4_SOURCE for HP C Version 4 or _VMS_V6_SOURCE for OpenVMS Version 6), forces use of short (16-bit) UID/GID.
8 – Standard-Compliant stat Structure (Integrity servers, Alpha)
The C RTL supports an X/Open standard-compliant definition of the stat structure and associated definitions. To use these new definitions, applications must compile with the _USE_STD_STAT feature-test macro defined. Use of _USE_STD_STAT specifies long (32-bit) GIDs. When compiled with _USE_STD_STAT, the stat structure includes these changes: o Type ino_t is defined as an unsigned quadword int. Without _ USE_STD_STAT, it is an unsigned short. o Type dev_t is defined as a 64-bit integer. Without _USE_STD_ STAT, it is a 32-bit character pointer. o Type off_t is defined as a 64-bit integer, as if the _ LARGEFILE macro has been defined. Without _USE_STD_STAT, off_t is a 32-bit integer. o Fields st_dev and st_rdev will have unique values per device. Without _USE_STD_STAT, uniqueness is not assured. o Fields st_blksize and st_blocks are added. Without _USE_STD_ STAT, these fields do not exist.
9 – Using Legacy toupper and tolower Behavior (Integrity servers, Alpha)
As of OpenVMS Version 8.3, to comply with the C99 ANSI standard and X/Open Specification, the _tolower and _toupper macros by default do not evaluate their parameter more than once. They simply call their respective tolower or toupper function. This avoids side effects (such as i++ or function calls) where the user can tell how many times an expression is evaluated. To retain the older, optimized behavior of the _tolower and _ toupper macros, compile with /DEFINE=_FAST_TOUPPER. Then, as in previous releases, these macros optimize the call to avoid the overhead of a runtime call. However, the macro's parameter is evaluated more than once to determine how to calculate the result, possibly creating unwanted side effects.
10 – Using Faster, Inlined Put and Get Functions (Integrity servers, Alpha)
Compiling with the __UNIX_PUTC macro defined enables an optimization that sets the following I/O functions to use faster, inlined functions: fgetc fputc putc putchar fgetc_unlocked fputc_unlocked putc_unlocked putchar_unlocked
11 – POSIX Style exit (Integrity servers, Alpha)
The HP C and C++ Version 7.1 and higher compilers have a /MAIN=POSIX_EXIT qualifier that defines the _POSIX_EXIT macro and causes the main program to call __posix_exit instead of exit when returning from the main program. This qualifier should be used with programs ported from UNIX that do not explicitly call exit and do not use OpenVMS specific exit codes. For older compilers, the following sample code can be used to force the existing main module to have a different name so that a simple main program will call it but force the exit status to be through the __posix_exit call. The replacement main function can be in a different module, so that /DEFINE="main=real_main" is all that is needed for modifying the build of the existing main function. #define _POSIX_EXIT 1 #include <stdlib.h> int real_main(int argc, char **argv); /* Make sure POSIXized exit is used */ int main(int argc, char **argv) { int ret_status; ret_status = real_main(argc, argv); exit (ret_status); } #define main real_main Unless your C program is intentionally using OpenVMS status codes for exit values, it is strongly recommended that both the _POSIX_ EXIT macro be defined and, if needed, the /MAIN=POSIX_EXIT or the alternative main replacement be used so that DCL, BASH, and the accounting file get usable exit values.