Uno/Article/Multi-Thread Programming

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Note: The technology described in this article depends on the presence of the extended Binary Uno threading-model, which has been integrated into URE 1.3 (SRC680_m212).

Uno is inherently multi-threaded, every Uno object may be accessed by multiple threads concurrently. The Uno Threading-Model provides support for simplifying multi-thread programming.

There are actually three things important to know about, when doing multi-threading with Uno. These are

  • the dedicated, thread related environments,
  • how to use these environments when creating particular implementations,
  • and certainly, how to use threads wrt. Uno objects.

Environments, mappings and objects are at the heart of Uno, please read Working with Environments, Mappings & Objects for an introduction.

Objects

Going to implement an Uno object, you need to decide on the threading-architecture. You basically have the following choices, the object can either be

Purpose

Thread-Unsafe

Thread unsafe is the choice for most cases. Actually leaving proper synchronization of method calls to the Uno runtime.

Thread-Safe

There are only rare cases where you actually want to implement your object thread-safe. Either

  • your object should or must allow the parallel execution of some of its methods, or
  • you want to avoid any overhead associated with leaving synchronization to the Uno runtime.

One case, where your object must allow the parallel execution of methods is, when you want to be able to abort a running invocation of one of its methods. Uno currently does not offer a mechanism to do this generically, so that particular objects must provide dedicated methods for abortion. An example for this is the util/io/Acceptor implementation.

The overhead for automatic synchronization only affects inter-environment calls. The threading-architecture of a particular application should be designed in a way, that closely connected objects happen to exist in the same Uno environment, basically ensuring a low inter-environment call frequency, converting any potential advantage of self synchronized methods to the reverse.

Note: Scalability may be achieved by the introduction of named environments, actually allowing any number of thread-unsafe purpose environments to exist simultaneously and to be activated by multiple threads independently.

Thread-Affine

Thread-affine objects are rare. In OOo they are needed to encapsulate the Win32 respectively the OLE/COM thread-affinity. See Make Vcl Thread-Transparent for details.

Implementation

Every object needs to be implemented somewhere. Dependent on the location, different actions need to be taken, to ensure correct usage of the object with respect to its threading-architecture.

Components

The easiest way to implement an object is a component, as a component actively provides the managing environments of its objects. This means, that components do not need to ensure proper mapping etc., this is all taken care of by the component loader already.

C++ Example - A thread-unsafe Component

The component_getImplementationEnvironment function of a component does return the single managing environment for all objects provided by this component. The implementation of this function for thread-unsafe objects may look like this:

extern "C" void SAL_CALL component_getImplementationEnvironment(
  sal_Char        const ** ppEnvTypeName, 
  uno_Environment       ** ppEnv
)
{
  *ppEnvTypeName = CPPU_CURRENT_LANGUAGE_BINDING_NAME ":unsafe";
}
C++ Example - A thread variable Component

A component implementing thread-safe and thread-transparent objects may want to utilize these capabilities by avoiding any mapping, this can be done by implementing the component_getImplementationEnvironmentExt function, instead of the component_getImplementationEnvironment function. The implementation of this function for a thread variable component may look like this:

#include "cppu/EnvDcp.hxx"
 
extern "C" void SAL_CALL component_getImplementationEnvironmentExt(
  sal_Char        const ** ppEnvTypeName, 
  uno_Environment       ** ppEnv,
  sal_Char        const  * pImplName,
  uno_Environment        * pSrcEnv
)
{
  rtl::OUString envName(RTL_CONSTASCII_USTRINGPARAM(CPPU_CURRENT_LANGUAGE_BINDING));
  envName += cppu::EnvDcp::getPurpose(Environment(pSrcEnv).getTypeName());
 
  uno_getEnvironment(ppEnv, envName.pData, NULL);
}

Libraries&Applications

Uno objects may as well be implemented in libraries or applications. Caller and callee must agree one the managing environment for passed or returned objects, to not break Uno/Term/Environment Integrity.

All public Uno libraries always do return appropriate objects, the implementations of the API are only OBI specialized and dynamically map the return or parameter objects according to the callers (purpose) environment.

Note: No convention, except documentation, has yet been introduced to identify any environment specialization of a function.

C++ Example - Function always returning a thread-safe Object

The following example shows a function always returning a thread-safe object, while the objects implementation itself is thread-unsafe. For this function to work properly, the client must have left any thread-unsafe environment.

Callee:

// This function is environment specialized on "c++".
uno::Reference<uno::XInterface> create_threadSafeObject(void) {
  uno::Reference<uno::XInterface>  result_Obj;
 
  // We may want to ensure that we are in the "c++" only environment.
  assert(uno::Environment::getCurrent().getTypeName() == rtl::OUString(RTL_CONSTASCII_PARAM("c++")));
 
  // We may want to open a new scope, to ensure that "result_Obj" does
  // not get destructed while "c++:unsafe" is active.
  {
    // We activate (enter) the "c++:unsafe" environment.
    // Note: Any other environment suiteable for "MyUnsafeObject" would work as well.
    cppu::EnvGuard unsafeGuard(uno::Environment(rtl::OUString(RTL_CONSTASCII_PARAM("c++:unsafe"))));
 
    // This reference points to a "thread-unsafe" object.
    uno::Reference<uno::XInterface> unsafeEnv_Obj(new MyUnsafeObject());
 
    // We may do some invocations on "unsafeEnv_Obj" while being in the "unsafe" environment.
    unsafeEnv_Obj->doThis();
    unsafeEnv_Obj->doThat();
 
    // We "shield" the object and assign it to "result_Obj"
    result_Obj.set(cppu::shield(unsafeEnv_Obj), SAL_NO_ACQUIRE);
 
    // We may _not_ activate result_obj, as we are still in the "c++:unsafe" environment.
  }
 
  // Using "result_obj" is fine here.
  return result_Obj;
}

Caller:

...
{
  // We just leave all "purpose" environments here, as "create_threadSafeObject" returns
  // "c++" (thread-safe) objects only.
  cppu::AntiEnvGuard antiGuard;
 
  uno::Reference safe_obj(create_threadSafeObject());
}
...
C++ Example - Function only accepting thread-safe Parameters

In the following example, the called function gets a thread-safe parameter, which needs to be mapped appropriately to the "c++:unsafe" environment, to be able to pass a thread-unsafe object to the set method of the parameter. For the function to work properly, the client must be in the thread-safe environment.

Callee:

// This function is environment specialized on "c++".
void setUnsafeObject(uno::Reference<...> const & rObj) {
  // We may want to ensure that we are in the "c++" only environment.
  assert(uno::Environment::getCurrent().getTypeName() == rtl::OUString(RTL_CONSTASCII_PARAM("c++")));
 
  // We now activate (enter) the "c++:unsafe" environment.
  // Note: Any other environment suiteable for "MyUnsafeObject" would work as well.
  cppu::EnvGuard unsafeGuard(uno::Environment(rtl::OUString(RTL_CONSTASCII_PARAM("c++:unsafe"))));
 
  // We "unshield" the parameter.
  uno::Reference<...> unsafeEnv_Obj.set(cppu::unshield(rObj), SAL_NO_ACQUIRE);
 
  // MyUnsafeObj has a C++ OBI and is thread-unsafe
  unsafeEnv_Obj->set(new MyUnsafeObject());
}

Caller:

...
{
  // We leave all "purpose" environments here, as "setUnsafeObject" accepts
  // "c++" (thread-safe) objects only.
  cppu::AntiEnvGuard antiGuard;
 
  uno::Reference<...> obj(...);
  setUnsafeObj(obj);
}
...

Environments

Every Uno reference points to an object with particular characteristics. Among implementing a concrete interface and Object Binary Interface (OBI), the object may have one or multiple "purposes" associated with it. The OBI and the "purposes" are expressed in the descriptor of the objects managing environment, e.g. the environment described by "gcc3:unsafe" manages objects with a GCC3 C++ OBI (if named properly, it would have been called "g++3" or "gpp3"), which are thread-unsafe.

The Uno threading-model introduces thread-affine purpose environments and thread-unsafe purpose environments. Objects not belonging to one of these two purpose environments are assumed to be thread-safe.

Examples:

Thread-Safe

Any environment with neither ":unsafe" nor ":affine" in its description is a thread-safe environment. Objects managed by such an environment may very well be called directly by concurrent threads. Examples for thread-safe environments are "gcc3" or "java", and also "gcc3:debug" or "uno:debug".

Thread-Unsafe

Any environment with an ":unsafe" in its description is a thread-unsafe environment. Objects managed by such an environment may not be called directly by multiple threads. See the specification of the thread-unsafety bridge for details.

C++ Example - Activating a thread-unsafe Environment

The semantics of "entering" or "invoking" a thread-unsafe environment are the same.

...
{
  // Enter the "gcc3:unsafe" environment
  cppu::EnvGuard unsafeGuard(uno::Environment(rtl::OUString(RTL_CONSTASCII_USTRINGPARAM("gcc3:unsafe"))));
  // Now we can safely directly call on any object belonging to this environment,
  // no second thread can enter this environment in parallel
  pObj->doSomething();
 
  // We implicity leave the "gcc3:unsafe" environment by destruction of the unsafeGuard
}
...

Basically, only one thread at a time can have activated any "<OBI>:unsafe" environment in one particular process.

Thread-Affine

Any environment with an ":affine" in its description is a thread-affine environment. Objects managed by such an environment may not be called directly by multiple threads. See the specification of the thread-affinity bridge for details.

Actually, the semantics of "entering" or "invoking" a thread-affine environment differ. Entering a thread-affine environment is only possible, if no thread has been associated with this environment yet, if a thread has already been associated, the entering thread waits until the already associated thread leaves the environment. An associated thread may only leave a thread-affine environment, in case no object is more managed (e.g. the last managed object has been removed). Finally, the entering thread becomes the associated thread of the thread-affine environment. All invocations of objects of this thread-affine environment get dispatched into the associated thread.

In contrast, "invoking" a thread-affine environment creates a new, dedicated and hidden thread to be associated with it, in case no thread has been associated with it yet, all invocations of objects or functions are then dispatched to this (new) thread. This new thread gets terminated when the last managed objects becomes removed.

C++ Example - Entering a thread-affine Environment

In the following example, the newly created instance of "MyUnoObject" is guaranteed to only be called by the creating thread. When trying to leave the thread-affine environment, the d'tor of the affineGuard will block as long as objects are managed by this environment, basically ensuring that the objects are still reachable.

class MyUnoObject ...;
 
...
{
  cppu::EnvGuard affineGuard(uno::Environment(rtl::OUString(RTL_CONSTASCII_USTRINGPARAM("gcc3:affine"))));
 
  uno::Reference<XMultiServiceFactory> smgr(...);
 
  smgr->createInstanceWithArguments(new MyUnoObject());
 
  // The implicit leave of the "gcc3:affine" blocks, until all managed objects (MyUnoObjects) are removed.
}
...

C++ Example - Invoking a thread-affine Environment

This example shows, how to correctly invoke a thread-affine environment, as always, all objects need to be managed properly by their managing environments.

class MyUnoObject ...;
 
void doSomething(va_list param)
{
  XMultiServiceFactory * pSmgr = va_arg(param, XMultiServiceFactory *);
  pSmgr->createInstanceWithArguments(new MyUnoObject());
}
 
...
{
  uno::Environment affineEnv(uno::Environment(rtl::OUString(RTL_CONSTASCII_USTRINGPARAM("gcc3:affine"))));
 
  uno::Mapping curr2affine(uno::Environment::getCurrent(), affineEnv);
 
  void * affineSmgr = curr2affine.mapInterface(smgr, typeof(smgr));
  affineEnv.invoke(s_doSomething, affineSmgr);
  affineEnv.get()->pExtEnv->releaseInterface(affineSmgr);
}
...

Helpers

The helpers ease the mapping of objects from particular purpose environment to another. Where mappings may be independently used to map any object to anywhere, the helpers take into account the current context.

Map Helpers

Shield Helpers

C++ Shield Helpers

The "shield" helpers basically allow to shorten the mapping of an object

Please have a look a the shield helpers specification for more details.

C++ Example - Map Object to Thread-Safe

Do the mapping by hand:

...
uno::XInterface * pUnsafe_Object ...;
uno::Mapping curr2safe(uno::getCurrentEnvironment(), 
                       rtl::OUString(RTL_CONSTASCII_USTRINGPARAM(CPPU_STRINGIFY(CPPU_ENV))));
 
uno::XInterface * pSafe_Object = reinterpret_cast<uno::XInterface *>(
                                    curr2safe.mapInterface(
                                      pObject, 
                                      getCppuType((uno::Reference<uno::XInterface> *)NULL)
                                    )
                                 );
...

Can be simply replaced with:

...
uno::XInterface * pUnsafe_Object ...;
uno::XInterface * pSafe_Object = cppu::shield(pUnsafe_Object);
...
C++ Example - Map Object from Thread-Safe

Do the mapping by hand:

...
uno::XInterface * pSafe_Object ...;
uno::Mapping safe2curr(rtl::OUString(RTL_CONSTASCII_USTRINGPARAM(CPPU_STRINGIFY(CPPU_ENV))),
                       uno::getCurrentEnvironment());
 
uno::XInterface * pUnsafe_Object = reinterpret_cast<uno::XInterface *>(
                                     safe2curr.mapInterface(
                                       pObject, 
                                       getCppuType((uno::Reference<uno::XInterface> *)NULL)
                                     )
                                   );
...

Can be simply replaced with:

...
uno::XInterface * pSafe_Object ...;
uno::XInterface * pUnsafe_Object = cppu::unshield(pSafe_Object);
...
C++ Example - Map uno::Any to Thread-Safe

Do the mapping by hand:

...
uno::Any unsafeAny = ...
 
uno::Mapping curr2safe(uno::getCurrentEnvironment(),
                       rtl::OUString(RTL_CONSTASCII_USTRINGPARAM(CPPU_STRINGIFY(CPPU_ENV))));
 
uno::Any safeAny;
uno_any_destruct(&safeAny, (uno_ReleaseFunc)uno::cpp_release);
uno_type_any_constructAndConvert(&safeAny,
                                 const_cast<void *>(unsafeAny.getValue()),
                                 unsafeAny.getValueTypeRef(),
                                 curr2safe.get());
...

Can be simply replaced with:

]
...
uno::Any unsafeAny = ...
uno::Any safeAny(cppu::shieldAny(unsafeAny));
...
C++ Example - Map uno::Any from Thread-Safe

Do the mapping by hand:

...
uno::Any safeAny = ...
 
uno::Mapping safe2curr(uno::getCurrentEnvironment(),
                       rtl::OUString(RTL_CONSTASCII_USTRINGPARAM(CPPU_STRINGIFY(CPPU_ENV))));
 
uno::Any unsafeAny;
uno_any_destruct(&unsafeAny, (uno_ReleaseFunc)uno::cpp_release);
uno_type_any_constructAndConvert(&unsafeAny,
                                 const_cast<void *>(safeAny.getValue()),
                                 safeAny.getValueTypeRef(),
                                 safe2curr.get());
...

Can be simply replaced with:

...
uno::Any safeAny = ...
uno::Any unsafeAny(cppu::unshieldAny(safeAny));
...

Threads

Thinking about threads, thread related environments and Uno objects, we roughly can identify the following types,

  • asynchronous threads, which run in the thread-safe environment,
  • synchronous threads, which run in a thread-unsafe or thread-affine environment,
  • hidden threads, which run behind an objects implementation only.

Mixed types are certainly possible.

Asynchronous

The asynchronous thread holds one or multiple references to thread-safe Uno objects. During its execution it may call on one or another of these objects. Every call may compete with any another threads call to the same particular object. In case a called object is not thread-safe (e.g. thread-unsafe or thread-affine), the appropriate environment becomes activated respectively deactivated implicitly before and after the call.

Synchronous

The synchronous thread holds one or multiple references to thread-unsafe or thread-affine objects. Before actually invoking any object, the thread does activate the (respectively any) managing environment. The calls are therefor not competing with any other thread and the call sequence is atomic. After a sequence of calls, the thread deactivates the managing environment again.

Hidden

The hidden thread is an implementation detail of a particular object only. Proper synchronization (e.g. acquiring / releasing mutexes) is taken care of by the implementer.

C++ Examples

Asynchronous Thread

Do not activate any environment explicitly, just run in the thread-safe environment. Only implicitly activate other environments when invoking mapped objects (e.g. thread-unsafe object).

class MyThread : public Thread 
{
  uno::Reference<...> m_safe_obj; // this points to a "thread-safe" object
 
protected:
  virtual void SAL_CALL run()
  {
    m_safe_obj.doThis();
    m_safe_obj.doThat();
  }
 
public:
  MyThread(uno::Reference<...> const & object)
    : m_safe_obj(cppu::shield(object), SAL_NO_ACQUIRE)
  {}
};

Synchronous Thread

Just enter an environment and do all calls while being in it. Obviously, releasing the objects also needs to be done in the environment.

class MyThread : public Thread 
{
  uno::Environment    m_refEnv;
  uno::Reference<...> m_unsafe_obj;
 
  static void s_clear(va_list param)
  {
    MyThread * pMyThread = va_arg(param, MyThread *);
    pMyThread->m_unsafe_obj.clear();
  }
 
  static void s_doSomething(va_list param)
  {
    MyThread * pMyThread = va_arg(param, MyThread *);
    // do not do any slow/blocking operations here, as the target environment is
    // currently activated, and no other thread may enter at the moment...
    m_unsafe_obj->doThis();
    m_unsafe_obj->doThat();  
    pMyThread->i_doSomething();
  }
 
public:
  MyThread(uno::Reference<...> const & object);
    : m_unsafe_obj(object), m_refEnv(uno::Environment::getCurrent());
  {}
 
  MyThread::~MyThread() 
  {
    // the object needs to be released in the managing environment.
    // unfortunately, there is not yet a SAL_NO_RELEASE
    m_refEnv.invoke(s_clear, this);
  }
 
  virtual void SAL_CALL run()
  {
    m_refEnv.invoke(s_doSomething, this);
  }
};

Specifications

The relevant specifications can be found here:

In particular:

See also

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