Boost.Interprocess does not work only with processes but also with threads. Boost.Interprocess synchronization mechanisms can synchronize threads from different processes, but also threads from the same process.

In the traditional programming model an operating system has multiple processes running and each process has its own address space. To share information between processes we have several alternatives:

One of the biggest issues with interprocess communication mechanisms is the lifetime of the interprocess communication mechanism. It's important to know when an interprocess communication mechanism disappears from the system. In Boost.Interprocess, we can have 3 types of persistence:

Some native POSIX and Windows IPC mechanisms have different persistence so it's difficult to achieve portability between Windows and POSIX native mechanisms. Boost.Interprocess classes have the following persistence:

As you can see, Boost.Interprocess defines some mechanisms with "Kernel or Filesystem" persistence. This is because POSIX allows this possibility to native interprocess communication implementations. One could, for example, implement shared memory using memory mapped files and obtain filesystem persistence (for example, there is no proper known way to emulate kernel persistence with a user library for Windows shared memory using native shared memory, or process persistence for POSIX shared memory, so the only portable way is to define "Kernel or Filesystem" persistence).

Some interprocess mechanisms are anonymous objects created in shared memory or memory-mapped files but other interprocess mechanisms need a name or identifier so that two unrelated processes can use the same interprocess mechanism object. Examples of this are shared memory, named mutexes and named semaphores (for example, native windows CreateMutex/CreateSemaphore API family).

The name used to identify an interprocess mechanism is not portable, even between UNIX systems. For this reason, Boost.Interprocess limits this name to a C++ variable identifier or keyword:

Named Boost.Interprocess resources (shared memory, memory mapped files, named mutexes/conditions/semaphores) have kernel or filesystem persistency. This means that even if all processes that have opened those resources end, the resource will still be accessible to be opened again and the resource can only be destructed via an explicit call to their static member remove function. This behavior can be easily understood, since it's the same mechanism used by functions controlling file opening/creation/erasure:

Now the correspondence between POSIX and Boost.Interprocess regarding shared memory and named semaphores:

The most important property is that destructors of named resources don't remove the resource from the system, they only liberate resources allocated by the system for use by the process for the named resource. To remove the resource from the system the programmer must use remove.

Named resources offered by Boost.Interprocess must cope with platform-dependant permission issues also present when creating files. If a programmer wants to shared shared memory, memory mapped files or named synchronization mechanisms (mutexes, semaphores, etc...) between users, it's necessary to specify those permissions. Sadly, traditional UNIX and Windows permissions are very different and Boost.Interprocess does not try to standardize permissions, but does not ignore them.

All named resource creation functions take an optional permissions object that can be configured with platform-dependant permissions.

Since each mechanism can be emulated through different mechanisms (a semaphore might be implement using mapped files or native semaphores) permissions types could vary when the implementation of a named resource changes (eg.: in Windows mutexes require synchronize permissions, but that's not the case of files). To avoid this, Boost.Interprocess relies on file-like permissions, requiring file read-write-delete permissions to open named synchronization mechanisms (mutex, semaphores, etc.) and appropriate read or read-write-delete permissions for shared memory. This approach has two advantages: it's similar to the UNIX philosophy and the programmer does not need to know how the named resource is implemented.