Defines | Typedefs

Global_Macros.h File Reference

#include "ace/config-lite.h"
#include "ace/Assert.h"
#include "ace/OS_Errno.h"

Defines

#define ACE_BEGIN_DUMP   ACE_TEXT ("\n====\n(%P|%t|%x)\n")
#define ACE_END_DUMP   ACE_TEXT ("====\n")
#define ACE_DB(X)   X
#define ACE_NO_HEAP_CHECK
#define ACE_ITOA(X)   #X
#define ACE_SERVER_ADDRESS(H, P)   H ACE_TEXT(":") P
#define ACE_POW(X)   (((X) == 0)?1:(X-=1,X|=X>>1,X|=X>>2,X|=X>>4,X|=X>>8,X|=X>>16,(++X)))
#define ACE_EVEN(NUM)   (((NUM) & 1) == 0)
#define ACE_ODD(NUM)   (((NUM) & 1) == 1)
#define ACE_BIT_ENABLED(WORD, BIT)   (((WORD) & (BIT)) != 0)
#define ACE_BIT_DISABLED(WORD, BIT)   (((WORD) & (BIT)) == 0)
#define ACE_BIT_CMP_MASK(WORD, BIT, MASK)   (((WORD) & (BIT)) == MASK)
#define ACE_SET_BITS(WORD, BITS)   (WORD |= (BITS))
#define ACE_CLR_BITS(WORD, BITS)   (WORD &= ~(BITS))
#define ACE_ENDLESS_LOOP
#define ACE_UNIMPLEMENTED_FUNC(f)   f;
#define ACE_GUARD_ACTION(MUTEX, OBJ, LOCK, ACTION, REACTION)
#define ACE_GUARD_REACTION(MUTEX, OBJ, LOCK, REACTION)   ACE_GUARD_ACTION(MUTEX, OBJ, LOCK, ;, REACTION)
#define ACE_GUARD(MUTEX, OBJ, LOCK)   ACE_GUARD_REACTION(MUTEX, OBJ, LOCK, return)
#define ACE_GUARD_RETURN(MUTEX, OBJ, LOCK, RETURN)   ACE_GUARD_REACTION(MUTEX, OBJ, LOCK, return RETURN)
#define ACE_WRITE_GUARD(MUTEX, OBJ, LOCK)
#define ACE_WRITE_GUARD_RETURN(MUTEX, OBJ, LOCK, RETURN)
#define ACE_READ_GUARD(MUTEX, OBJ, LOCK)
#define ACE_READ_GUARD_RETURN(MUTEX, OBJ, LOCK, RETURN)
#define ACE_UNEXPECTED(RETVAL)
#define ACE_DES_NOFREE(POINTER, CLASS)
#define ACE_DES_ARRAY_NOFREE(POINTER, SIZE, CLASS)
#define ACE_DES_FREE(POINTER, DEALLOCATOR, CLASS)
#define ACE_DES_ARRAY_FREE(POINTER, SIZE, DEALLOCATOR, CLASS)
#define ACE_DES_NOFREE_TEMPLATE(POINTER, T_CLASS, T_PARAMETER)
#define ACE_DES_ARRAY_NOFREE_TEMPLATE(POINTER, SIZE, T_CLASS, T_PARAMETER)
#define ACE_DES_FREE_TEMPLATE(POINTER, DEALLOCATOR, T_CLASS, T_PARAMETER)
#define ACE_DES_ARRAY_FREE_TEMPLATE(POINTER, SIZE, DEALLOCATOR, T_CLASS, T_PARAMETER)
#define ACE_DES_FREE_TEMPLATE2(POINTER, DEALLOCATOR, T_CLASS, T_PARAM1, T_PARAM2)
#define ACE_DES_FREE_TEMPLATE3(POINTER, DEALLOCATOR, T_CLASS, T_PARAM1, T_PARAM2, T_PARAM3)
#define ACE_DES_FREE_TEMPLATE4(POINTER, DEALLOCATOR, T_CLASS, T_PARAM1, T_PARAM2, T_PARAM3, T_PARAM4)
#define ACE_DES_ARRAY_FREE_TEMPLATE2(POINTER, SIZE, DEALLOCATOR, T_CLASS, T_PARAM1, T_PARAM2)
#define LPSECURITY_ATTRIBUTES   int
#define GENERIC_READ   0
#define FILE_SHARE_READ   0
#define OPEN_EXISTING   0
#define FILE_ATTRIBUTE_NORMAL   0
#define MAXIMUM_WAIT_OBJECTS   0
#define FILE_FLAG_OVERLAPPED   0
#define FILE_FLAG_SEQUENTIAL_SCAN   0
#define FILE_FLAG_WRITE_THROUGH   0
#define PIPE_WAIT   0
#define PIPE_NOWAIT   0
#define PIPE_READMODE_BYTE   0
#define PIPE_READMODE_MESSAGE   0
#define PIPE_TYPE_BYTE   0
#define PIPE_TYPE_MESSAGE   0
#define ACE_ALLOCATOR_RETURN(POINTER, ALLOCATOR, RET_VAL)
#define ACE_ALLOCATOR(POINTER, ALLOCATOR)
#define ACE_ALLOCATOR_NORETURN(POINTER, ALLOCATOR)
#define ACE_NEW_MALLOC_RETURN(POINTER, ALLOCATOR, CONSTRUCTOR, RET_VAL)
#define ACE_NEW_MALLOC(POINTER, ALLOCATOR, CONSTRUCTOR)
#define ACE_NEW_MALLOC_NORETURN(POINTER, ALLOCATOR, CONSTRUCTOR)
#define ACE_NEW_MALLOC_ARRAY_RETURN(POINTER, ALLOCATOR, CONSTRUCTOR, COUNT, RET_VAL)
#define ACE_NEW_MALLOC_ARRAY(POINTER, ALLOCATOR, CONSTRUCTOR, COUNT)
#define ACE_NOOP(x)
#define ACE_SEH_TRY   if (1)
#define ACE_SEH_EXCEPT(X)   while (0)
#define ACE_SEH_FINALLY   if (1)
#define ACE_SYNCH_DECL   class _ACE_SYNCH_MUTEX_T, class _ACE_SYNCH_CONDITION_T
#define ACE_SYNCH_USE   _ACE_SYNCH_MUTEX_T, _ACE_SYNCH_CONDITION_T
#define ACE_SYNCH_MUTEX_T   _ACE_SYNCH_MUTEX_T
#define ACE_SYNCH_CONDITION_T   _ACE_SYNCH_CONDITION_T
#define ACE_SYNCH_SEMAPHORE_T   _ACE_SYNCH_SEMAPHORE_T
#define ACE_MEM_POOL_1   class _ACE_MEM_POOL, class _ACE_MEM_POOL_OPTIONS
#define ACE_MEM_POOL_2   _ACE_MEM_POOL, _ACE_MEM_POOL_OPTIONS
#define ACE_MEM_POOL   _ACE_MEM_POOL
#define ACE_MEM_POOL_OPTIONS   _ACE_MEM_POOL_OPTIONS
#define ACE_PEER_STREAM_1   class _ACE_PEER_STREAM, class _ACE_PEER_ADDR
#define ACE_PEER_STREAM_2   _ACE_PEER_STREAM, _ACE_PEER_ADDR
#define ACE_PEER_STREAM   _ACE_PEER_STREAM
#define ACE_PEER_STREAM_ADDR   _ACE_PEER_ADDR
#define ACE_PEER_ACCEPTOR_1   class _ACE_PEER_ACCEPTOR, class _ACE_PEER_ADDR
#define ACE_PEER_ACCEPTOR_2   _ACE_PEER_ACCEPTOR, _ACE_PEER_ADDR
#define ACE_PEER_ACCEPTOR   _ACE_PEER_ACCEPTOR
#define ACE_PEER_ACCEPTOR_ADDR   _ACE_PEER_ADDR
#define ACE_PEER_CONNECTOR_1   class _ACE_PEER_CONNECTOR, class _ACE_PEER_ADDR
#define ACE_PEER_CONNECTOR_2   _ACE_PEER_CONNECTOR, _ACE_PEER_ADDR
#define ACE_PEER_CONNECTOR   _ACE_PEER_CONNECTOR
#define ACE_PEER_CONNECTOR_ADDR   _ACE_PEER_ADDR
#define ACE_PEER_CONNECTOR_ADDR_ANY   ACE_PEER_CONNECTOR_ADDR::sap_any
#define ACE_SOCK_ACCEPTOR   ACE_SOCK_Acceptor, ACE_INET_Addr
#define ACE_SOCK_CONNECTOR   ACE_SOCK_Connector, ACE_INET_Addr
#define ACE_SOCK_STREAM   ACE_SOCK_Stream, ACE_INET_Addr
#define ACE_SOCK_DGRAM   ACE_SOCK_Dgram, ACE_INET_Addr
#define ACE_SOCK_DGRAM_BCAST   ACE_SOCK_Dgram_Bcast, ACE_INET_Addr
#define ACE_SOCK_DGRAM_MCAST   ACE_SOCK_Dgram_Mcast, ACE_INET_Addr
#define ACE_SOCK_SEQPACK_ACCEPTOR   ACE_SOCK_SEQPACK_Acceptor, ACE_Multihomed_INET_Addr
#define ACE_SOCK_SEQPACK_CONNECTOR   ACE_SOCK_SEQPACK_Connector, ACE_Multihomed_INET_Addr
#define ACE_SOCK_SEQPACK_ASSOCIATION   ACE_SOCK_SEQPACK_Association, ACE_Multihomed_INET_Addr
#define ACE_MEM_ACCEPTOR   ACE_MEM_Acceptor, ACE_MEM_Addr
#define ACE_MEM_CONNECTOR   ACE_MEM_Connector, ACE_INET_Addr
#define ACE_MEM_STREAM   ACE_MEM_Stream, ACE_INET_Addr
#define ACE_LSOCK_ACCEPTOR   ACE_LSOCK_Acceptor, ACE_UNIX_Addr
#define ACE_LSOCK_CONNECTOR   ACE_LSOCK_Connector, ACE_UNIX_Addr
#define ACE_LSOCK_STREAM   ACE_LSOCK_Stream, ACE_UNIX_Addr
#define ACE_TLI_ACCEPTOR   ACE_TLI_Acceptor, ACE_INET_Addr
#define ACE_TLI_CONNECTOR   ACE_TLI_Connector, ACE_INET_Addr
#define ACE_TLI_STREAM   ACE_TLI_Stream, ACE_INET_Addr
#define ACE_SPIPE_ACCEPTOR   ACE_SPIPE_Acceptor, ACE_SPIPE_Addr
#define ACE_SPIPE_CONNECTOR   ACE_SPIPE_Connector, ACE_SPIPE_Addr
#define ACE_SPIPE_STREAM   ACE_SPIPE_Stream, ACE_SPIPE_Addr
#define ACE_UPIPE_ACCEPTOR   ACE_UPIPE_Acceptor, ACE_SPIPE_Addr
#define ACE_UPIPE_CONNECTOR   ACE_UPIPE_Connector, ACE_SPIPE_Addr
#define ACE_UPIPE_STREAM   ACE_UPIPE_Stream, ACE_SPIPE_Addr
#define ACE_FILE_CONNECTOR   ACE_FILE_Connector, ACE_FILE_Addr
#define ACE_FILE_STREAM   ACE_FILE_IO, ACE_FILE_Addr
#define ACE_MMAP_MEMORY_POOL   ACE_MMAP_Memory_Pool, ACE_MMAP_Memory_Pool_Options
#define ACE_LITE_MMAP_MEMORY_POOL   ACE_Lite_MMAP_Memory_Pool, ACE_MMAP_Memory_Pool_Options
#define ACE_SBRK_MEMORY_POOL   ACE_Sbrk_Memory_Pool, ACE_Sbrk_Memory_Pool_Options
#define ACE_SHARED_MEMORY_POOL   ACE_Shared_Memory_Pool, ACE_Shared_Memory_Pool_Options
#define ACE_LOCAL_MEMORY_POOL   ACE_Local_Memory_Pool, ACE_Local_Memory_Pool_Options
#define ACE_PAGEFILE_MEMORY_POOL   ACE_Pagefile_Memory_Pool, ACE_Pagefile_Memory_Pool_Options
#define ACE_STATIC_CONSTANT(TYPE, ASSIGNMENT)   static TYPE const ASSIGNMENT
Service Configurator macros

The following macros are used to define helper objects used in ACE's Service Configurator framework, which is described in Chapter 5 of C++NPv2 <www.cs.wustl.edu/~schmidt/ACE/book2/>. This framework implements the Component Configurator pattern, which is described in Chapter 2 of POSA2 <www.cs.wustl.edu/~schmidt/POSA/>. The intent of this pattern is to allow developers to dynamically load and configure services into a system. With a little help from this macros statically linked services can also be dynamically configured.

More details about this component are available in the documentation of the ACE_Service_Configurator class and also ACE_Dynamic_Service.

Notice that in all the macros the SERVICE_CLASS parameter must be the name of a class derived from ACE_Service_Object.

#define ACE_STATIC_SVC_DECLARE(SERVICE_CLASS)   extern ACE_Static_Svc_Descriptor ace_svc_desc_##SERVICE_CLASS ;
#define ACE_STATIC_SVC_DECLARE_EXPORT(EXPORT_NAME, SERVICE_CLASS)   extern EXPORT_NAME##_Export ACE_Static_Svc_Descriptor ace_svc_desc_##SERVICE_CLASS;
#define ACE_STATIC_SVC_DEFINE(SERVICE_CLASS, NAME, TYPE, FN, FLAGS, ACTIVE)   ACE_Static_Svc_Descriptor ace_svc_desc_##SERVICE_CLASS = { NAME, TYPE, FN, FLAGS, ACTIVE };
#define ACE_STATIC_SVC_REQUIRE(SERVICE_CLASS)
 Automatically register a service with the service configurator.
#define ACE_STATIC_SVC_REGISTER(SERVICE_CLASS)   do {} while (0)
#define ACE_PREPROC_CONCATENATE_IMPL(A, B)   A ## B
#define ACE_PREPROC_CONCATENATE(A, B)   ACE_PREPROC_CONCATENATE_IMPL(A,B)
#define ACE_MAKE_SVC_CONFIG_FUNCTION_NAME(PREFIX, VERSIONED_NAMESPACE, SERVICE_CLASS)   PREFIX ## _ ## SERVICE_CLASS
#define ACE_MAKE_SVC_CONFIG_FACTORY_NAME(VERSIONED_NAMESPACE, SERVICE_CLASS)   ACE_MAKE_SVC_CONFIG_FUNCTION_NAME(_make,VERSIONED_NAMESPACE,SERVICE_CLASS)
#define ACE_MAKE_SVC_CONFIG_GOBBLER_NAME(VERSIONED_NAMESPACE, SERVICE_CLASS)   ACE_MAKE_SVC_CONFIG_FUNCTION_NAME(_gobble,VERSIONED_NAMESPACE,SERVICE_CLASS)
#define ACE_FACTORY_DECLARE(CLS, SERVICE_CLASS)
#define ACE_Local_Service_Export
#define ACE_FACTORY_DEFINE(CLS, SERVICE_CLASS)
#define ACE_FACTORY_NAMESPACE_DEFINE(CLS, SERVICE_CLASS, NAMESPACE_CLASS)
#define ACE_SVC_NAME(SERVICE_CLASS)   ACE_MAKE_SVC_CONFIG_FACTORY_NAME(ACE_VERSIONED_NAMESPACE_NAME,SERVICE_CLASS)
 The canonical name for a service factory method.
#define ACE_SVC_INVOKE(SERVICE_CLASS)   ACE_SVC_NAME(SERVICE_CLASS) (0)
Helper macros for services defined in the netsvcs library.

The ACE services defined in netsvcs use this helper macros for simplicity.

#define ACE_SVC_FACTORY_DECLARE(X)   ACE_FACTORY_DECLARE (ACE_Svc, X)
#define ACE_SVC_FACTORY_DEFINE(X)   ACE_FACTORY_DEFINE (ACE_Svc, X)

Typedefs

typedef void(* ACE_Service_Object_Exterminator )(void *)

Detailed Description

Id:
Global_Macros.h 91459 2010-08-25 09:51:01Z mcorino
Author:
Douglas C. Schmidt <schmidt@cs.wustl.edu>
Jesper S. M|ller<stophph@diku.dk>
and a cast of thousands...

This one is split from the famous OS.h


Define Documentation

#define ACE_ALLOCATOR (   POINTER,
  ALLOCATOR 
)
Value:
do { POINTER = ALLOCATOR; \
     if (POINTER == 0) { errno = ENOMEM; return; } \
   } while (0)
#define ACE_ALLOCATOR_NORETURN (   POINTER,
  ALLOCATOR 
)
Value:
do { POINTER = ALLOCATOR; \
     if (POINTER == 0) { errno = ENOMEM; } \
   } while (0)
#define ACE_ALLOCATOR_RETURN (   POINTER,
  ALLOCATOR,
  RET_VAL 
)
Value:
do { POINTER = ALLOCATOR; \
     if (POINTER == 0) { errno = ENOMEM; return RET_VAL; } \
   } while (0)
#define ACE_BEGIN_DUMP   ACE_TEXT ("\n====\n(%P|%t|%x)\n")
#define ACE_BIT_CMP_MASK (   WORD,
  BIT,
  MASK 
)    (((WORD) & (BIT)) == MASK)
#define ACE_BIT_DISABLED (   WORD,
  BIT 
)    (((WORD) & (BIT)) == 0)
#define ACE_BIT_ENABLED (   WORD,
  BIT 
)    (((WORD) & (BIT)) != 0)
#define ACE_CLR_BITS (   WORD,
  BITS 
)    (WORD &= ~(BITS))
#define ACE_DB (   X  )     X
#define ACE_DES_ARRAY_FREE (   POINTER,
  SIZE,
  DEALLOCATOR,
  CLASS 
)
Value:
do { \
        if (POINTER) \
          { \
            for (size_t i = 0; \
                 i < SIZE; \
                 ++i) \
            { \
              (&(POINTER)[i])->~CLASS (); \
            } \
            DEALLOCATOR (POINTER); \
          } \
      } \
   while (0)
#define ACE_DES_ARRAY_FREE_TEMPLATE (   POINTER,
  SIZE,
  DEALLOCATOR,
  T_CLASS,
  T_PARAMETER 
)
Value:
do { \
            if (POINTER) \
              { \
                for (size_t i = 0; \
                     i < SIZE; \
                     ++i) \
                { \
                  POINTER[i].T_CLASS T_PARAMETER::~T_CLASS (); \
                } \
                DEALLOCATOR (POINTER); \
              } \
          } \
       while (0)
#define ACE_DES_ARRAY_FREE_TEMPLATE2 (   POINTER,
  SIZE,
  DEALLOCATOR,
  T_CLASS,
  T_PARAM1,
  T_PARAM2 
)
Value:
do { \
            if (POINTER) \
              { \
                for (size_t i = 0; \
                     i < SIZE; \
                     ++i) \
                { \
                  POINTER[i].T_CLASS <T_PARAM1, T_PARAM2>::~T_CLASS (); \
                } \
                DEALLOCATOR (POINTER); \
              } \
          } \
       while (0)
#define ACE_DES_ARRAY_NOFREE (   POINTER,
  SIZE,
  CLASS 
)
Value:
do { \
        if (POINTER) \
          { \
            for (size_t i = 0; \
                 i < SIZE; \
                 ++i) \
            { \
              (&(POINTER)[i])->~CLASS (); \
            } \
          } \
      } \
   while (0)
#define ACE_DES_ARRAY_NOFREE_TEMPLATE (   POINTER,
  SIZE,
  T_CLASS,
  T_PARAMETER 
)
Value:
do { \
          if (POINTER) \
            { \
              for (size_t i = 0; \
                   i < SIZE; \
                   ++i) \
              { \
                (POINTER)[i].T_CLASS T_PARAMETER::~T_CLASS (); \
              } \
            } \
        } \
     while (0)
#define ACE_DES_FREE (   POINTER,
  DEALLOCATOR,
  CLASS 
)
Value:
do { \
        if (POINTER) \
          { \
            (POINTER)->~CLASS (); \
            DEALLOCATOR (POINTER); \
          } \
      } \
   while (0)
#define ACE_DES_FREE_TEMPLATE (   POINTER,
  DEALLOCATOR,
  T_CLASS,
  T_PARAMETER 
)
Value:
do { \
            if (POINTER) \
              { \
                POINTER->T_CLASS T_PARAMETER::~T_CLASS (); \
                DEALLOCATOR (POINTER); \
              } \
          } \
       while (0)
#define ACE_DES_FREE_TEMPLATE2 (   POINTER,
  DEALLOCATOR,
  T_CLASS,
  T_PARAM1,
  T_PARAM2 
)
Value:
do { \
            if (POINTER) \
              { \
                POINTER->T_CLASS <T_PARAM1, T_PARAM2>::~T_CLASS (); \
                DEALLOCATOR (POINTER); \
              } \
          } \
       while (0)
#define ACE_DES_FREE_TEMPLATE3 (   POINTER,
  DEALLOCATOR,
  T_CLASS,
  T_PARAM1,
  T_PARAM2,
  T_PARAM3 
)
Value:
do { \
            if (POINTER) \
              { \
                POINTER->T_CLASS <T_PARAM1, T_PARAM2, T_PARAM3>::~T_CLASS (); \
                DEALLOCATOR (POINTER); \
              } \
          } \
       while (0)
#define ACE_DES_FREE_TEMPLATE4 (   POINTER,
  DEALLOCATOR,
  T_CLASS,
  T_PARAM1,
  T_PARAM2,
  T_PARAM3,
  T_PARAM4 
)
Value:
do { \
            if (POINTER) \
              { \
                POINTER->T_CLASS <T_PARAM1, T_PARAM2, T_PARAM3, T_PARAM4>::~T_CLASS (); \
                DEALLOCATOR (POINTER); \
              } \
          } \
       while (0)
#define ACE_DES_NOFREE (   POINTER,
  CLASS 
)
Value:
do { \
        if (POINTER) \
          { \
            (POINTER)->~CLASS (); \
          } \
      } \
   while (0)
#define ACE_DES_NOFREE_TEMPLATE (   POINTER,
  T_CLASS,
  T_PARAMETER 
)
Value:
do { \
          if (POINTER) \
            { \
              (POINTER)->T_CLASS T_PARAMETER::~T_CLASS (); \
            } \
        } \
     while (0)
#define ACE_END_DUMP   ACE_TEXT ("====\n")
#define ACE_ENDLESS_LOOP
#define ACE_EVEN (   NUM  )     (((NUM) & 1) == 0)
#define ACE_FACTORY_DECLARE (   CLS,
  SERVICE_CLASS 
)
Value:
extern "C" CLS##_Export ACE_VERSIONED_NAMESPACE_NAME::ACE_Service_Object * \
ACE_MAKE_SVC_CONFIG_FACTORY_NAME(ACE_VERSIONED_NAMESPACE_NAME,SERVICE_CLASS) (ACE_Service_Object_Exterminator *);

Declare the factory method used to create dynamically loadable services. Once the service implementation is dynamically loaded the Service Configurator uses a factory method to create the object. This macro declares such a factory function with the proper interface and export macros. Normally used in the header file that declares the service implementation.

Parameters:
CLS must match the prefix of the export macro used for this service.
SERVICE_CLASS must match the name of the class that implements the service.
#define ACE_FACTORY_DEFINE (   CLS,
  SERVICE_CLASS 
)
Value:
void ACE_MAKE_SVC_CONFIG_GOBBLER_NAME(ACE_VERSIONED_NAMESPACE_NAME,SERVICE_CLASS) (void *p) { \
  ACE_VERSIONED_NAMESPACE_NAME::ACE_Service_Object * _p = \
    static_cast< ACE_VERSIONED_NAMESPACE_NAME::ACE_Service_Object *> (p); \
  ACE_ASSERT (_p != 0); \
  delete _p; } \
extern "C" CLS##_Export ACE_VERSIONED_NAMESPACE_NAME::ACE_Service_Object *\
ACE_MAKE_SVC_CONFIG_FACTORY_NAME(ACE_VERSIONED_NAMESPACE_NAME,SERVICE_CLASS) (ACE_Service_Object_Exterminator *gobbler) \
{ \
  ACE_TRACE (#SERVICE_CLASS); \
  if (gobbler != 0) \
    *gobbler = (ACE_Service_Object_Exterminator) ACE_MAKE_SVC_CONFIG_GOBBLER_NAME(ACE_VERSIONED_NAMESPACE_NAME,SERVICE_CLASS); \
  return new SERVICE_CLASS; \
}

Declare a the data structure required to register a statically linked service into the service configurator. The macro should be used in the header file where the service is declared, its only argument is usually the name of the class that implements the service.

Parameters:
SERVICE_CLASS The name of the class implementing the service.
#define ACE_FACTORY_NAMESPACE_DEFINE (   CLS,
  SERVICE_CLASS,
  NAMESPACE_CLASS 
)
Value:
void ACE_MAKE_SVC_CONFIG_GOBBLER_NAME(ACE_VERSIONED_NAMESPACE_NAME,SERVICE_CLASS) (void *p) { \
  ACE_VERSIONED_NAMESPACE_NAME::ACE_Service_Object * _p = \
    static_cast< ACE_VERSIONED_NAMESPACE_NAME::ACE_Service_Object *> (p); \
  ACE_ASSERT (_p != 0); \
  delete _p; } \
extern "C" CLS##_Export ACE_VERSIONED_NAMESPACE_NAME::ACE_Service_Object *\
ACE_MAKE_SVC_CONFIG_FACTORY_NAME(ACE_VERSIONED_NAMESPACE_NAME,SERVICE_CLASS) (ACE_Service_Object_Exterminator *gobbler) \
{ \
  ACE_TRACE (#SERVICE_CLASS); \
  if (gobbler != 0) \
    *gobbler = (ACE_Service_Object_Exterminator) ACE_MAKE_SVC_CONFIG_GOBBLER_NAME(ACE_VERSIONED_NAMESPACE_NAME,SERVICE_CLASS); \
  return new NAMESPACE_CLASS; \
}

For service classes scoped within namespaces, use this macro in place of ACE_FACTORY_DEFINE. The third argument in this case is the fully scoped name of the class as it is to be instantiated. For example, given: namespace ACE { namespace Foo { class Bar : public ACE_Service_Object {}; }; };

ACE_FACTORY_DECLARE(ACE,ACE_Foo_Bar)

you would then use:

ACE_FACTORY_NAMESPACE_DEFINE(ACE,ACE_Foo_Bar,ACE::Foo::Bar)

Note that in this example, the ACE_FACTORY_DECLARE is done outside the namespace scope. Then, the SERVICE_CLASS name is the same as the fully scoped class name, but with '::' replaced with '_'. Doing this will ensure unique generated signatures for the various C style functions.

#define ACE_FILE_CONNECTOR   ACE_FILE_Connector, ACE_FILE_Addr
#define ACE_FILE_STREAM   ACE_FILE_IO, ACE_FILE_Addr
#define ACE_GUARD (   MUTEX,
  OBJ,
  LOCK 
)    ACE_GUARD_REACTION(MUTEX, OBJ, LOCK, return)
#define ACE_GUARD_ACTION (   MUTEX,
  OBJ,
  LOCK,
  ACTION,
  REACTION 
)
Value:
ACE_Guard< MUTEX > OBJ (LOCK); \
   if (OBJ.locked () != 0) { ACTION; } \
   else { REACTION; }
#define ACE_GUARD_REACTION (   MUTEX,
  OBJ,
  LOCK,
  REACTION 
)    ACE_GUARD_ACTION(MUTEX, OBJ, LOCK, ;, REACTION)
#define ACE_GUARD_RETURN (   MUTEX,
  OBJ,
  LOCK,
  RETURN 
)    ACE_GUARD_REACTION(MUTEX, OBJ, LOCK, return RETURN)
#define ACE_ITOA (   X  )     #X
#define ACE_LITE_MMAP_MEMORY_POOL   ACE_Lite_MMAP_Memory_Pool, ACE_MMAP_Memory_Pool_Options
#define ACE_LOCAL_MEMORY_POOL   ACE_Local_Memory_Pool, ACE_Local_Memory_Pool_Options
#define ACE_Local_Service_Export

Define the factory method (and destructor) for a dynamically loadable service. Use with arguments matching ACE_FACTORY_DECLARE. Normally used in the .cpp file that defines the service implementation.

This macro defines both the factory method and the function used to cleanup the service object.

If this macro is used to define a factory function that need not be exported (for example, in a static service situation), CLS can be specified as ACE_Local_Service.

#define ACE_LSOCK_ACCEPTOR   ACE_LSOCK_Acceptor, ACE_UNIX_Addr
#define ACE_LSOCK_CONNECTOR   ACE_LSOCK_Connector, ACE_UNIX_Addr
#define ACE_LSOCK_STREAM   ACE_LSOCK_Stream, ACE_UNIX_Addr
#define ACE_MAKE_SVC_CONFIG_FACTORY_NAME (   VERSIONED_NAMESPACE,
  SERVICE_CLASS 
)    ACE_MAKE_SVC_CONFIG_FUNCTION_NAME(_make,VERSIONED_NAMESPACE,SERVICE_CLASS)

Declare a the data structure required to register a statically linked service into the service configurator. The macro should be used in the header file where the service is declared, its only argument is usually the name of the class that implements the service.

Parameters:
SERVICE_CLASS The name of the class implementing the service.
#define ACE_MAKE_SVC_CONFIG_FUNCTION_NAME (   PREFIX,
  VERSIONED_NAMESPACE,
  SERVICE_CLASS 
)    PREFIX ## _ ## SERVICE_CLASS

Declare a the data structure required to register a statically linked service into the service configurator. The macro should be used in the header file where the service is declared, its only argument is usually the name of the class that implements the service.

Parameters:
SERVICE_CLASS The name of the class implementing the service.
#define ACE_MAKE_SVC_CONFIG_GOBBLER_NAME (   VERSIONED_NAMESPACE,
  SERVICE_CLASS 
)    ACE_MAKE_SVC_CONFIG_FUNCTION_NAME(_gobble,VERSIONED_NAMESPACE,SERVICE_CLASS)

Declare a the data structure required to register a statically linked service into the service configurator. The macro should be used in the header file where the service is declared, its only argument is usually the name of the class that implements the service.

Parameters:
SERVICE_CLASS The name of the class implementing the service.
#define ACE_MEM_ACCEPTOR   ACE_MEM_Acceptor, ACE_MEM_Addr
#define ACE_MEM_CONNECTOR   ACE_MEM_Connector, ACE_INET_Addr
#define ACE_MEM_POOL   _ACE_MEM_POOL
#define ACE_MEM_POOL_1   class _ACE_MEM_POOL, class _ACE_MEM_POOL_OPTIONS
#define ACE_MEM_POOL_2   _ACE_MEM_POOL, _ACE_MEM_POOL_OPTIONS
#define ACE_MEM_POOL_OPTIONS   _ACE_MEM_POOL_OPTIONS
#define ACE_MEM_STREAM   ACE_MEM_Stream, ACE_INET_Addr
#define ACE_MMAP_MEMORY_POOL   ACE_MMAP_Memory_Pool, ACE_MMAP_Memory_Pool_Options
#define ACE_NEW_MALLOC (   POINTER,
  ALLOCATOR,
  CONSTRUCTOR 
)
Value:
do { POINTER = ALLOCATOR; \
     if (POINTER == 0) { errno = ENOMEM; return;} \
     else { (void) new (POINTER) CONSTRUCTOR; } \
   } while (0)
#define ACE_NEW_MALLOC_ARRAY (   POINTER,
  ALLOCATOR,
  CONSTRUCTOR,
  COUNT 
)
Value:
do { POINTER = ALLOCATOR; \
     if (POINTER == 0) { errno = ENOMEM; return;} \
     else { (void) new (POINTER) CONSTRUCTOR [COUNT]; } \
   } while (0)
#define ACE_NEW_MALLOC_ARRAY_RETURN (   POINTER,
  ALLOCATOR,
  CONSTRUCTOR,
  COUNT,
  RET_VAL 
)
Value:
do { POINTER = ALLOCATOR; \
     if (POINTER == 0) { errno = ENOMEM; return RET_VAL;} \
     else { (void) new (POINTER) CONSTRUCTOR [COUNT]; } \
   } while (0)
#define ACE_NEW_MALLOC_NORETURN (   POINTER,
  ALLOCATOR,
  CONSTRUCTOR 
)
Value:
do { POINTER = ALLOCATOR; \
     if (POINTER == 0) { errno = ENOMEM;} \
     else { (void) new (POINTER) CONSTRUCTOR; } \
   } while (0)
#define ACE_NEW_MALLOC_RETURN (   POINTER,
  ALLOCATOR,
  CONSTRUCTOR,
  RET_VAL 
)
Value:
do { POINTER = ALLOCATOR; \
     if (POINTER == 0) { errno = ENOMEM; return RET_VAL;} \
     else { (void) new (POINTER) CONSTRUCTOR; } \
   } while (0)
#define ACE_NO_HEAP_CHECK
#define ACE_NOOP (   x  ) 
#define ACE_ODD (   NUM  )     (((NUM) & 1) == 1)
#define ACE_PAGEFILE_MEMORY_POOL   ACE_Pagefile_Memory_Pool, ACE_Pagefile_Memory_Pool_Options
#define ACE_PEER_ACCEPTOR   _ACE_PEER_ACCEPTOR
#define ACE_PEER_ACCEPTOR_1   class _ACE_PEER_ACCEPTOR, class _ACE_PEER_ADDR
#define ACE_PEER_ACCEPTOR_2   _ACE_PEER_ACCEPTOR, _ACE_PEER_ADDR
#define ACE_PEER_ACCEPTOR_ADDR   _ACE_PEER_ADDR
#define ACE_PEER_CONNECTOR   _ACE_PEER_CONNECTOR
#define ACE_PEER_CONNECTOR_1   class _ACE_PEER_CONNECTOR, class _ACE_PEER_ADDR
#define ACE_PEER_CONNECTOR_2   _ACE_PEER_CONNECTOR, _ACE_PEER_ADDR
#define ACE_PEER_CONNECTOR_ADDR   _ACE_PEER_ADDR
#define ACE_PEER_CONNECTOR_ADDR_ANY   ACE_PEER_CONNECTOR_ADDR::sap_any
#define ACE_PEER_STREAM   _ACE_PEER_STREAM
#define ACE_PEER_STREAM_1   class _ACE_PEER_STREAM, class _ACE_PEER_ADDR
#define ACE_PEER_STREAM_2   _ACE_PEER_STREAM, _ACE_PEER_ADDR
#define ACE_PEER_STREAM_ADDR   _ACE_PEER_ADDR
#define ACE_POW (   X  )     (((X) == 0)?1:(X-=1,X|=X>>1,X|=X>>2,X|=X>>4,X|=X>>8,X|=X>>16,(++X)))
#define ACE_PREPROC_CONCATENATE (   A,
  B 
)    ACE_PREPROC_CONCATENATE_IMPL(A,B)

Declare a the data structure required to register a statically linked service into the service configurator. The macro should be used in the header file where the service is declared, its only argument is usually the name of the class that implements the service.

Parameters:
SERVICE_CLASS The name of the class implementing the service.
#define ACE_PREPROC_CONCATENATE_IMPL (   A,
  B 
)    A ## B

Declare a the data structure required to register a statically linked service into the service configurator. The macro should be used in the header file where the service is declared, its only argument is usually the name of the class that implements the service.

Parameters:
SERVICE_CLASS The name of the class implementing the service.
#define ACE_READ_GUARD (   MUTEX,
  OBJ,
  LOCK 
)
Value:
ACE_Read_Guard< MUTEX > OBJ (LOCK); \
    if (OBJ.locked () == 0) return;
#define ACE_READ_GUARD_RETURN (   MUTEX,
  OBJ,
  LOCK,
  RETURN 
)
Value:
ACE_Read_Guard< MUTEX > OBJ (LOCK); \
    if (OBJ.locked () == 0) return RETURN;
#define ACE_SBRK_MEMORY_POOL   ACE_Sbrk_Memory_Pool, ACE_Sbrk_Memory_Pool_Options
#define ACE_SEH_EXCEPT (   X  )     while (0)
#define ACE_SEH_FINALLY   if (1)
#define ACE_SEH_TRY   if (1)
#define ACE_SERVER_ADDRESS (   H,
  P 
)    H ACE_TEXT(":") P
#define ACE_SET_BITS (   WORD,
  BITS 
)    (WORD |= (BITS))
#define ACE_SHARED_MEMORY_POOL   ACE_Shared_Memory_Pool, ACE_Shared_Memory_Pool_Options
#define ACE_SOCK_ACCEPTOR   ACE_SOCK_Acceptor, ACE_INET_Addr
#define ACE_SOCK_CONNECTOR   ACE_SOCK_Connector, ACE_INET_Addr
#define ACE_SOCK_DGRAM   ACE_SOCK_Dgram, ACE_INET_Addr
#define ACE_SOCK_DGRAM_BCAST   ACE_SOCK_Dgram_Bcast, ACE_INET_Addr
#define ACE_SOCK_DGRAM_MCAST   ACE_SOCK_Dgram_Mcast, ACE_INET_Addr
#define ACE_SOCK_SEQPACK_ACCEPTOR   ACE_SOCK_SEQPACK_Acceptor, ACE_Multihomed_INET_Addr
#define ACE_SOCK_SEQPACK_ASSOCIATION   ACE_SOCK_SEQPACK_Association, ACE_Multihomed_INET_Addr
#define ACE_SOCK_SEQPACK_CONNECTOR   ACE_SOCK_SEQPACK_Connector, ACE_Multihomed_INET_Addr
#define ACE_SOCK_STREAM   ACE_SOCK_Stream, ACE_INET_Addr
#define ACE_SPIPE_ACCEPTOR   ACE_SPIPE_Acceptor, ACE_SPIPE_Addr
#define ACE_SPIPE_CONNECTOR   ACE_SPIPE_Connector, ACE_SPIPE_Addr
#define ACE_SPIPE_STREAM   ACE_SPIPE_Stream, ACE_SPIPE_Addr
#define ACE_STATIC_CONSTANT (   TYPE,
  ASSIGNMENT 
)    static TYPE const ASSIGNMENT
#define ACE_STATIC_SVC_DECLARE (   SERVICE_CLASS  )     extern ACE_Static_Svc_Descriptor ace_svc_desc_##SERVICE_CLASS ;

Declare a the data structure required to register a statically linked service into the service configurator. The macro should be used in the header file where the service is declared, its only argument is usually the name of the class that implements the service.

Parameters:
SERVICE_CLASS The name of the class implementing the service.
#define ACE_STATIC_SVC_DECLARE_EXPORT (   EXPORT_NAME,
  SERVICE_CLASS 
)    extern EXPORT_NAME##_Export ACE_Static_Svc_Descriptor ace_svc_desc_##SERVICE_CLASS;

As ACE_STATIC_SVC_DECLARE, but using an export macro for NT compilers. NT compilers require the use of explicit directives to export and import symbols from a DLL. If you need to define a service in a dynamic library you should use this version instead. Normally ACE uses a macro to inject the correct export/import directives on NT. Naturally it also the macro expands to a blank on platforms that do not require such directives. The first argument (EXPORT_NAME) is the prefix for this export macro, the full name is formed by appending _Export. ACE provides tools to generate header files that define the macro correctly on all platforms, please see $ACE_ROOT/bin/generate_export_file.pl

Parameters:
EXPORT_NAME The export macro name prefix.
SERVICE_CLASS The name of the class implementing the service.
#define ACE_STATIC_SVC_DEFINE (   SERVICE_CLASS,
  NAME,
  TYPE,
  FN,
  FLAGS,
  ACTIVE 
)    ACE_Static_Svc_Descriptor ace_svc_desc_##SERVICE_CLASS = { NAME, TYPE, FN, FLAGS, ACTIVE };

Define the data structure used to register a statically linked service into the Service Configurator. The service configurator requires several arguments to build and control an statically linked service, including its name, the factory function used to construct the service, and some flags. All those parameters are configured in a single structure, an instance of this structure is statically initialized using the following macro.

Parameters:
SERVICE_CLASS The name of the class that implements the service, must be derived (directly or indirectly) from ACE_Service_Object.
NAME The name for this service, this name is used by the service configurator to match configuration options provided in the svc.conf file.
TYPE The type of object. Objects can be streams or service objects. Please read the ACE_Service_Configurator and ASX documentation for more details.
FN The name of the factory function, usually the ACE_SVC_NAME macro can be used to generate the name. The factory function is often defined using ACE_FACTORY_DECLARE and ACE_FACTORY_DEFINE.
FLAGS Flags to control the ownership and lifecycle of the object. Please read the ACE_Service_Configurator documentation for more details.
ACTIVE If not zero then a thread will be dedicate to the service. Please read the ACE_Service_Configurator documentation for more details.
#define ACE_STATIC_SVC_REGISTER (   SERVICE_CLASS  )     do {} while (0)

Declare a the data structure required to register a statically linked service into the service configurator. The macro should be used in the header file where the service is declared, its only argument is usually the name of the class that implements the service.

Parameters:
SERVICE_CLASS The name of the class implementing the service.
#define ACE_STATIC_SVC_REQUIRE (   SERVICE_CLASS  ) 
Value:
class ACE_Static_Svc_##SERVICE_CLASS {\
public:\
  ACE_Static_Svc_##SERVICE_CLASS() { \
    ACE_Service_Config::insert (\
         &ace_svc_desc_##SERVICE_CLASS); \
    } \
};\
static ACE_Static_Svc_##SERVICE_CLASS ace_static_svc_##SERVICE_CLASS;

Automatically register a service with the service configurator.

In some applications the services must be automatically registered with the service configurator, before main() starts. The ACE_STATIC_SVC_REQUIRE macro defines a class whose constructor register the service, it also defines a static instance of that class to ensure that the service is registered before main.

On platforms that lack adequate support for static C++ objects the macro ACE_STATIC_SVC_REGISTER can be used to explicitly register the service.

Todo:
One class per-Service_Object seems wasteful. It should be possible to define a single class and re-use it for all the service objects, just by passing the Service_Descriptor as an argument to the constructor.
#define ACE_SVC_FACTORY_DECLARE (   X  )     ACE_FACTORY_DECLARE (ACE_Svc, X)
#define ACE_SVC_FACTORY_DEFINE (   X  )     ACE_FACTORY_DEFINE (ACE_Svc, X)
#define ACE_SVC_INVOKE (   SERVICE_CLASS  )     ACE_SVC_NAME(SERVICE_CLASS) (0)

The canonical way to invoke (i.e. construct) a service factory method.

#define ACE_SVC_NAME (   SERVICE_CLASS  )     ACE_MAKE_SVC_CONFIG_FACTORY_NAME(ACE_VERSIONED_NAMESPACE_NAME,SERVICE_CLASS)

The canonical name for a service factory method.

#define ACE_SYNCH_CONDITION_T   _ACE_SYNCH_CONDITION_T
#define ACE_SYNCH_DECL   class _ACE_SYNCH_MUTEX_T, class _ACE_SYNCH_CONDITION_T
#define ACE_SYNCH_MUTEX_T   _ACE_SYNCH_MUTEX_T
#define ACE_SYNCH_SEMAPHORE_T   _ACE_SYNCH_SEMAPHORE_T
#define ACE_SYNCH_USE   _ACE_SYNCH_MUTEX_T, _ACE_SYNCH_CONDITION_T
#define ACE_TLI_ACCEPTOR   ACE_TLI_Acceptor, ACE_INET_Addr
#define ACE_TLI_CONNECTOR   ACE_TLI_Connector, ACE_INET_Addr
#define ACE_TLI_STREAM   ACE_TLI_Stream, ACE_INET_Addr
#define ACE_UNEXPECTED (   RETVAL  ) 
Value:
do { \
    std::unexpected(); \
  } while (0)
#define ACE_UNIMPLEMENTED_FUNC (   f  )     f;
#define ACE_UPIPE_ACCEPTOR   ACE_UPIPE_Acceptor, ACE_SPIPE_Addr
#define ACE_UPIPE_CONNECTOR   ACE_UPIPE_Connector, ACE_SPIPE_Addr
#define ACE_UPIPE_STREAM   ACE_UPIPE_Stream, ACE_SPIPE_Addr
#define ACE_WRITE_GUARD (   MUTEX,
  OBJ,
  LOCK 
)
Value:
ACE_Write_Guard< MUTEX > OBJ (LOCK); \
    if (OBJ.locked () == 0) return;
#define ACE_WRITE_GUARD_RETURN (   MUTEX,
  OBJ,
  LOCK,
  RETURN 
)
Value:
ACE_Write_Guard< MUTEX > OBJ (LOCK); \
    if (OBJ.locked () == 0) return RETURN;
#define FILE_ATTRIBUTE_NORMAL   0
#define FILE_FLAG_OVERLAPPED   0
#define FILE_FLAG_SEQUENTIAL_SCAN   0
#define FILE_FLAG_WRITE_THROUGH   0
#define FILE_SHARE_READ   0
#define GENERIC_READ   0
#define LPSECURITY_ATTRIBUTES   int
#define MAXIMUM_WAIT_OBJECTS   0
#define OPEN_EXISTING   0
#define PIPE_NOWAIT   0
#define PIPE_READMODE_BYTE   0
#define PIPE_READMODE_MESSAGE   0
#define PIPE_TYPE_BYTE   0
#define PIPE_TYPE_MESSAGE   0
#define PIPE_WAIT   0

Typedef Documentation

typedef void(* ACE_Service_Object_Exterminator)(void *)

Service Objects, i.e., objects dynamically loaded via the service configurator, must provide a destructor function with the following prototype to perform object cleanup.

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