I'm assuming you mean the C++11 standard library, not the STL (which is a library of algorithms, iterators and containers from the 1990s).
The answer depends what you mean by "implemented manually". Do you mean in pure C++? i.e. no assembly code and no OS-specific features such as POSIX memory allocation functions, or even lower-level system calls to the kernel?
Because if you're prepared to write assembly and call directly into the kernel, you can implement nearly everything, but it's not very practical. Even writing your own
operator new is very hard without building it on top of something lower-level such as
sbrk(). Without something like
malloc it's hard to write
std::allocator and so hard to implement
std::system_clock also relies on facilities provided by the operating system, you either need a lower-level API such as POSIX's
clock_gettime() or access to a hardware clock in the CPU. Even
std::time() defined in
<ctime> needs something like that.
So let's assume relying on the C library for features such as
malloc is OK, but we want to avoid writing assembly and non-C++.
It is not possible to implement
std::atomic efficiently in pure C++. You need some compiler magic or assembly code to provide the necessary synchronization guarantees. The libstdc++ implementation of
std::atomic relies on GCC's __atomic built-ins which are "compiler magic". The libc++ implementation of
std::atomic makes use of the
_Atomic keyword, which is defined by C11 and supported by
clang++ but is not defined in standard C++. In both cases the library implementation relies on non-standard features of the compiler to provide the platform-specific assembly necessary to provide the required behaviour.
Alternatively, you could just implement
std::atomic inefficiently using a mutex, but that just shifts the requirement for "magical" synchronization properties onto the mutex type. At the very least, an implementation needs to provide
std::atomic_flag which can't be done in pure C++. Without
std::atomic_flag the other atomic types and
std::mutex cannot be implemented in pure C++, so require either platform-specific assembly code, or require using a lower-level library such as Pthreads which provides the necessary primitives (which themselves will either be implemented in assembly or with non-portable compiler magic).
As pointed out at How does std::async "store" an arbitrary exception? there are parts of the C++ runtime such as
std::exception_ptr which can be written in C++, but not portably. The runtime has to define the data structures and internal details of RTTI and exception handling, and provide entry points that the compiler will call so that e.g.
throw in your C++ code calls the relevant routine from the runtime to allocate an exception object. So you could implement those things yourself, but unless you conform to the right API the compiler won't use them so they won't work!
But even if you're prepared to write assembly and call directly into the kernel, several type traits rely on compiler magic and cannot be implemented by the user, for example
is_trivially_constructible and the other
is_trivially_xxx traits. These all depend on properties of a type which cannot be tested for in code, only the compiler can do the necessary inspection and tell you if a type has the property (and the same applies to the C++14