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From reading revision N3242 of the c++11 draft, it appears that some components of the standard library's interfaces (notably threading and locking) depend on exception handling.

Since I do a lot of work with exceptions disabled, I am wondering which library components/features will be (practically or logically) unusable without exception handling enabled?

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Practically, all features are usable, until an actual exception is thrown. Then your program crashes. If a library function can throw, this is specified in the standard, so in a way there is a list — the standard itself. – n.m. Sep 12 '11 at 11:32
@n.m. it seems you've may have read my post using the wrong definition of 'practically': if not, there is a difference in the complexity and locality of things like versus a program/environment's threading and locking. having implemented threading and locking libraries, i can tell you that you can defend yourself against the former easily and predictably. (cont) – justin Sep 12 '11 at 22:11
(cont) defending yourself from the latter is far more complex. when things do go wrong, an unhandled exception is not a solution (for some of us). i can't just ignore these errors :) thus, i can't rely on the library's threading and locking implementations because the only defence offered by the library is exceptions. in conclusion, the threading and locking interfaces are not a good fit for programs where exceptions are disabled. hope that helps. – justin Sep 12 '11 at 22:13

First of all (just as a reminder), disabling exceptions and RTTI are compiler specific extensions the Standard has no consideration for.

Since the Standard Library is usually tied to the compiler, it may be that your implementation of the Standard Library has been specifically designed to cope with this (and in particular, to cope with new returning null pointers instead of raising std::bad_alloc).

Therefore, what you ask for is non-sensical. Check the documentation of your own library for a complete list.

That being said, the Standard does guarantee that a number of operations will never throw. I don't know of any operation that swallows exceptions, I would suppose that most of them are actually safe to use as-is.

For example, all algorithms should be safe.

Still, once again, I can only recommend reading the documentation of your implementation.

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there are common new variants for the purpose of avoiding bad_alloc. nothrow_t is the built in form the library provides, others (including user defined allocators) may be user defined via placement new. for collections, one can specify an allocator which does not throw: std::vector<double, my_nonthrowing_allocator<double> > and then vector's interface is largely usable provided you adhere to the rules. (cont) – justin Sep 13 '11 at 19:54
(cont) there are complex high quality c++ programs which do not rely on exceptions. your post does have merits (+1), but i think some generalizations can be made in this case -- again, my examples of threading (unsafe), locking (unsafe), and now vector (interface may be used safely if nobody's life depends on it). – justin Sep 13 '11 at 19:55
@Justin: I do not say it is not possible, I just say it is not Standard. For example, even though new (nothrow_t) exists, a vector might not use it. Now, I do know that some libraries compile without exceptions, LLVM/Clang is one of them for example. However they redefined most of the utility classes too. – Matthieu M. Sep 14 '11 at 7:00
ah, sorry for the misunderstanding. – justin Sep 14 '11 at 8:01
up vote 0 down vote accepted

This question is over one month old, and unanswered.

I am providing an answer which can be considered a community wiki, add to it as needed.

  • std::thread Section 30.2.2. Transitive. Abstraction implemented using native implementations.

  • std::mutex, std::recursive_mutex, std::timed_mutex, std::recursive_timed_mutex. Section 30.4.1, Intransitive if you supply your own exception free locking (via BasicLockable, Lockable, TimedLockable). Abstraction implemented using native implementations.

  • std::condition_variable Section 30.5. Transitive. Abstraction implemented using native implementations.

note: There will be more.

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