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This chapter describes the guidelines and procedures for customizing
your language environment. It includes sections on changing your C
header files to work with C++, organizing your C++ files, interfacing
to other programming languages, and designing upwardly compatible C++
classes.
3.1 Using Existing C Header Files
C header files that already conform to ANSI C standards must be modified slightly to be usable by Compaq C++ programs. In particular, be sure to address the following issues:
The compiler provides some C header files that have been modified to work with C++, including standard ANSI C header files. These headers are in the sys$library directory.
The following sections provide details on how to properly modify your
headers.
3.1.1 Providing C and C++ Linkage
To modify header files, use conditional compilation and the extern specifier.
When programming header files to be used for both C and C++ programs, use the following convention for predefined macros. The system header files also provide an example of correct usage of the predefined macros.
#if defined __cplusplus /* If the functions in this header have C linkage, this * will specify linkage for all C++ language compilers. */ extern "C" { #endif # if defined __DECC || defined __DECCXX /* If you are using pragmas that are defined only * with DEC C and DEC C++, this line is necessary * for both C and C++ compilers. A common error * is to only have #ifdef __DECC, which causes * the compiler to skip the conditionalized * code. */ # pragma __extern_model __save # pragma __extern_model __strict_refdef extern const char some_definition []; # pragma __extern_model __restore # endif /* ...some data and function definitions go here... */ #if defined __cplusplus } /* matches the linkage specification at the beginning. */ #endif |
See §r.7.4 of The C++ Programming Language, 3nd Edition for more information on linkage
specifications.
3.1.2 Resolving C++ Keyword Conflicts
If your program uses any of the following C++ language keywords as identifiers, you must replace them with nonconflicting identifiers:
asm | bool | catch | class |
const_cast | delete | dynamic_cast | explicit |
export | false | friend | inline |
mutable | namespace | new | operator |
private | protected | public | reinterpret_cast |
static_cast | template | this | throw |
true | try | typeid | typename |
virtual | wchar_t |
Alternative representation keywords are as follows:
and, and_eq, bitand, bitor, compl, not, not_eq, or, or_eq, xor, xor_eq |
Distinctions between ANSI C and C++ include slight differences in rules concerning scope. Therefore, you may need to modify some ANSI C header files to use them with C++.
The following sample code fragment generates an error regarding incompatible types, but the root cause is the difference in scope rules between C and C++. In ANSI C, the compiler promotes tag names defined in structure or union declarations to the containing block or file scope. This does not happen in C++.
struct Screen { struct _XDisplay *display; }; typedef struct _XDisplay { // ... } Display; struct Screen s1; Display *s2; main() { s1.display = s2; } |
The offending line in this sample is s1.display = s2 . The types of s1.display and s2 are the same in C but different in C++. You can solve the problem by adding the declaration struct _XDisplay; to the beginning of this code fragment, as follows:
struct _XDisplay; // this is the added line struct Screen { struct _XDisplay *display; }; typedef struct _XDisplay { // ... } Display; // ... |
The C compiler special built-in macros defined in the header files <stdarg.h> and <varargs.h> . These step through the argument list of a routine.
Programs that take the address of a parameter, and use pointer arithmetic to step through the argument list to obtain the value of other parameters, assume that all arguments reside on the stack and that arguments appear in increasing order. These assumptions are not valid for Compaq C++. The macros in <varargs.h> can be used only by C functions with old-style definitions that are not legal in C++. To reference variable-length argument lists, use the <stdarg.h> header file.
The OpenVMS Alpha calling standard mechanism for returning structures
larger than 8 bytes by value uses a hidden parameter. The parameter is
a pointer to storage in the caller's frame. The
va_count
macro includes this parameter in its count.
3.2 Using Compaq C++ with Other Languages
The following are suggestions regarding the use of Compaq C++ with other languages:
extern "C" int myroutine(int, float); |
With linkage specifications, you can both import code and data written
in other languages into a Compaq C++ program and export
Compaq C++ code and data for use with other languages. See §4.4
of The C++ Programming Language, 3nd Edition for details on the
extern "C"
declaration.
3.4 How to Organize Your C++ Code
This section explains the best way for compiler users to organize an
application into files; it assumes that you are using automatic
instantiation to instantiate any template classes and functions.
3.4.1 Code That Does Not Use Templates
The general rule is to place declarations in header files and place definitions in library source files. The following items belong in header files:
And the following items belong in library source files:
Header files should be directly included by modules that need them. Because several modules may include the same header file, a header file must not contain definitions that would generate multiply defined symbols when all the modules are linked together.
Library source files should be compiled individually and then linked into your application. Because each library source file is compiled only once, the definitions it contains will exist in only one object module and multiply defined symbols are thus avoided.
For example, to create a class called "array" you would create the following two files:
Header file, arrayInt.hxx:
// arrayInt.hxx #ifndef ARRAY_H #define ARRAY_H class arrayInt { private: int curr_size; static int max_array_size; public: arrayInt() :curr_size(0) {;} arrayInt(int); }; #endif |
Library source file, arrayInt.cxx:
// arrayInt.cxx #include "arrayInt.hxx" int array::max_array_size = 256; arrayInt::arrayInt(int size) : curr_size(size) { ...; } |
You would then compile the arrayInt.cxx library source file using the following command:
cxx/include=[.include] arrayInt.cxx |
The resulting object file could either be linked directly into your application or placed in a library (see Section 3.4.4).
The header file uses header guards, which is a
technique to prevent multiple inclusion of the same header file.
3.4.2 Code That Uses Templates
With the widespread use of templates in C++, determining the proper place to put declarations and definitions becomes more complicated.
The general rule is to place template declarations and definitions in header files, and to place specializations in library source files.
Thus, the following items belong in template declaration files:
The following items can be placed either in the header file with the corresponding template declaration or in a separate header file that can be implicitly included when needed. This file has the same basename as the corresponding declaration header file, with a suffix that is found by implicit inclusion. For example, if the declaration is in the header file inc1.h , these corresponding definitions could be in file inc1.cxx .
The following must be placed in library source files to prevent multiple definition errors:
These guidelines also apply to nontemplate nested classes inside of template classes.
Do not place definitions of nontemplate class members, nontemplate functions, or global data within template definition files; these must be placed in library source files. |
All these header files should use header guards, to ensure that they are not included more that once either explicitly or by implicit inclusion.
For example, the array class from Section 3.4.1, modified to use templates, would now look as follows:
Template declaration file, array.hxx:
// array.hxx #ifndef ARRAY_HXX #define ARRAY_HXX template <class T> class array { private: int curr_size; static int max_array_size; public: array() :curr_size(0) {;} array(int size,const T& value = T()); }; #endif |
Template definition file, array.cxx:
// array.cxx template <class T> int array<T>::max_array_size = 256; template <class T> array<T>::array(int size,const T& value ) {... ; } |
Then you would create a source file myprog.cxx that uses the array class as follows:
// myprog.cxx #include "array.hxx" main() { array<int> ai; // ... } |
Figure 3-1 shows the placement of these files.
Figure 3-1 Placement of Template Declaration and Definition Files
You would then compile myprog.cxx in the mydir directory with the following command:
cxx/incl=[.include] myprog.cxx |
In this case, you do not need to create library source files because the static member data and out-of-line members of the array template class are instantiated at the time you compile myprog.cxx .
However, you would need to create library source files for the following cases:
Table 3-1 describes where to place declarations and definitions, as discussed in Section 3.4.1 and Section 3.4.2.
Feature | Declaration | Out-of-Line Definition |
---|---|---|
Class | Header file | |
Static member data | Within class declaration | Library source file |
Member function | Within class declaration | Library source file |
Global function | Header file | Library source file |
Global data | Header file | Library source file |
Template class | Template declaration file | |
Static member data of template class | Within template class declaration | Template definition file |
Member function of template class | Within template class declaration | Template definition file |
Global template function | Template declaration file | Template definition file |
Global, nontemplate friend function of template class | Within template class declaration | Library source file |
Specialization of template class | Template declaration file | |
Specialization of template function | Template declaration file | Library source file |
Libraries are useful for organizing the sources within your application as well as for providing a set of routines for other applications to use. Libraries can be either object libraries or shareable libraries. Use an object library when you want the library code to be contained within an application's image; use shareable libraries when you want multiple applications to share the same library code.
Creating a library from nontemplate code is straightforward: you simply compile each library source file and place the resulting object file in your library.
Creating a library from template code requires that you explicitly request the instantiations that you want to provide in your library. See Chapter 7 for details.
If you make your library available to other users, you must also supply the corresponding declarations and definitions that are needed at compile time. For nontemplate interfaces, you must supply the header files that declare your classes, functions, and global data. For template interfaces, you must provide your template declaration files as well as your template definition files.
For more information on creating libraries, see the OpenVMS Command
Definition, Librarian, and Messages Utilities Manual and the
OpenVMS Linker Utility Manual.
3.5 Sample Code for Creating OpenVMS Shareable Images
The SW_SHR sample code consists of several source modules, a command procedure and this description. Table 3-2 lists each of the constituent modules, which are located in the directory SYS$COMMON:[SYSHLP.EXAMPLES.CXX] on your system.
The code creates an OpenVMS shareable image called SW_SHR.EXE that supplies a Stopwatch class identical to the C++ Class Library's Stopwatch class. For detailed information about the Stopwatch class, refer to the Compaq C++ Class Library Reference Manual .
SW_SHR also provides an instance of a Stopwatch class named G_sw that shows how to export a class instance from a shareable image. The exportation occurs in the same way that cout , cin , cerr , and clog are exported from the C++ Class Library shareable image.
Module Name | Description |
---|---|
SW_DEFS.MAR | Macro definitions for use by both the SW_VEC_ALPHA and SW_VEC_VAX macro source files. |
SW_DEFS_ALPHA.MAR | Macro definitions of globally accessible class objects defined within the shareable image. |
SW_DEFS_VAX.MAR | Entry point macro definitions and macro definitions of globally accessible class objects defined within the shareable image. |
SW_SHARE.HXX | General use macros to make exporting of global data (class instances) from shareable images more transparent to the users of class objects. |
SW.HXX | The definition of the Stopwatch class supplied by the shareable image. |
SW.CXX | Source associated with the public functions defined in SW.HXX. It also contains the declaration of the global Stopwatch (G_sw) class instance. |
SW_TEST.CXX | A test of each of the Stopwatch's public access points and also the G_sw class instance. |
SW_BUILD.COM | A DCL command procedure used to build both the shareable image and the program. |
SW_SHR _ALPHA.OPT | An OpenVMS Linker options file, used on OpenVMS Alpha systems, that contains the SYMBOL_VECTOR entry points and other shareable image linker directives. |
SW_SHR _VAX.OPT | An OpenVMS Linker options file, used on OpenVMS VAX, that contains shareable image linker directives. |
When you create shared images on OpenVMS systems, you must export
guard variables for template static data members or for static
variables defined in inline functions. These guard variables, which are
prefixed by
__SDG
and
__LSG
respectively, ensure that static data is initialized only once. You
must also export the static variables in inlined functions and template
static data members from the shared image so that they have only one
definition.
3.6 Hints for Designing Upwardly Compatible C++ Classes
If you produce a library of C++ classes and expect to release future revisions of your library, you should consider the upward compatibility of your library. Having your library upwardly compatible makes upgrading to higher versions of your library easier for users. And if you design your library properly from the start, you can accomplish upward compatibility with minimal development costs.
The levels of compatibility discussed in this section are as follows:
The format in which your library ships determines the levels of compatibility that apply:
Library Format | Compatibility Level |
---|---|
Source format | Source compatibility only |
Object format | Source and link compatibility |
Shareable library format | All three kinds of compatibility |
If you break compatibility between releases, you should at least
document the incompatible changes and provide hints for upgrading
between releases.
3.6.1 Source Compatibility
Achieving source compatibility means that users of your library will not have to make any source code changes when they upgrade to your new library release. Their applications will compile cleanly against your updated header files and will have the same run-time behavior as with your previous release.
To maintain source compatibility, you must ensure that existing functions continue to have the same semantics from the user's standpoint. In general, you can make the following changes to your library and still maintain source compatibility:
Achieving link compatibility means that users of your library can relink an application against your new object or shareable library and not be required to recompile their sources.
To maintain link compatibility, the internal representation of class objects and interfaces must remain constant. In general, you can make the following changes to your library and still maintain link compatibility:
Because the user may be linking object modules from your previous release with object modules from your new release, the layout and size of class objects must be consistent between releases. Any user-visible interfaces must also remain unchanged; even the seemingly innocent change of adding const to an existing function will change the mangled name and thus break link compatibility.
The following are changes that you cannot make in your library:
Designing Your C++ Classes for Link Compatibility
Although the changes you are allowed to make in your library are severely restricted when you aim for link compatibility, you can take steps to prepare for this and thereby reduce the restrictions. Compaq suggests using one of the following design approaches:
Achieving run compatibility means that users of your library can run an application against your new shareable library and not be required to recompile or relink the application.
This requires that you follow the guidelines for link compatibility as
well as any operating system guidelines for shareable libraries. On
OpenVMS systems, you need to create an upwardly compatible
shareable image using a transfer vector on OpenVMS VAX and a symbol
table on OpenVMS Alpha. Refer to the OpenVMS Linker Utility Manual for information on
creating a shareable image.
3.6.4 Additional Reading
The C++ Programming Language, 3nd Edition offers some advice on compatibility issues. Another good reference is Designing and Coding Reusable C++, Chapter 7, by Martin D. Carroll and Margaret E. Ellis.
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