In C++, I've a
Stream object which abstracts an
HANDLE on Windows, and I've also various derivatives objects, such as
Pipe which derives directly from that
Stream object, and then I've also a
RequestIo object which is my own version of the extended
OVERLAPPED object, that is, the
RequestIo directly inherits from the
From now, saying
RequesIo is the same as saying
RequestIo object I store several useful things that couldn't be stored in a single
OVERLAPPED structure, such as flags, user pointers and so on.
There I also store a pointer to the next
RequestIo object, in order to have an intrusive linked list of these objects.
Stream object has 2 heads of this intrusive linked list, one for
RequestIo objects for reading, and another one for writing. In this way the
Stream object can have a little pool of these
RequestIo objects, and don't have to allocate/deallocate them at every i/o operation, nor needs locking because the 2 intrusive list are separated for readings a writings which are the 2 kind of operations that may occur in 2 different threads simultaneously in IOCPs.
When I'll have stream-like objects (such as sockets, or pipes) I will have only 1
RequestIo for reading (more than one are just not needed) and one for writing, so I basically do not need locking because at the first
socket.read() a new
RequestIo is allocated, inserted in the linked list, and it will be reused over and over again, until the socket is closed and destroyed, the same for writings.
But, there are not stream-like objects (such as random access file, udp sockets) which can issue more than one
RequestIo for both reading or writing. Let's just consider an UDP socket that can issue N pending
RequestIo objects for reading datagrams, or a random access file that can issue several
RequestIo packets for reading/writing to/from different parts of the file.
Here things get complicated. If I have that linked list of
RequestIo objects, I actually have to traverse that list and see which
RequestIo is NOT pending and issue a new i/o operation with that one.
Said that like this seems easy, but its not:
despite I can set a flag to a
RequestIo which says "its pending", the problem is not solved: shouldn't that flag be an atomic integer? Since that flag will be unset by some other thread. And what about retrieving the first
RequestIo available from the linked list, when there are multiple
RequestIo instanced? Shouldn't also that be an interlocked operation? And insertion on that linked list? E.g. when I allocate a new
RequestIo packet because all others are pending.
A possible solution I was thinking is to traverse this linked list and check an atomic integer in the
RequestIo object with CAS (CompareAndSwap) instruction, if 0 it means its not pending, and immediately set it to 1, so another thread will see that one as pending and will go to the next
RequestIo object. If it can't find any
RequestIo object it allocates a new one, but here it should lock the linked list head...to insert the new allocated
So, what is basically the fastest and the most effective way to correctly manage a pool of N
RequestIo in my case) objects, without incurring in massive locking which would degrade performance and the purpose of multithreaded IOCPs?