I've been researching these topics for a couple weeks to a month now. I've learned that the techniques of UDP hole punching, which is for true direct connection between 2 peers, is imperfect due to some possible combinations of NAT types involved. What this means is that UDP hole punching is not always going to work perfectly. Furthermore, there are standardized protocols in place to handle this process that we can use instead of writing our own. You don't have to start from scratch, which is what I did, writing my own relay server. Instead, we can latch onto the existing standards (getting to this later).
The way to claim 100% operability, albeit not always completely direct, is to, in the cases where a p2p connection is impossible, use a relay server. The process of discovering whether a true p2p connection is possible has been standardized by ICE,TURN,and STUN. iirc, TURN has a STUN server within it. I have not learned enough about the application of these 3, and I will not go into the different NAT types. All I know is that using ICE/TURN/STUN seems to be a standardized strategy in subverting the NAT problem. It can facilitate true p2p and offer relaying services when necessary. That's all I can say for now, until I learn more.
Note: I use the term p2p in this answer to distinguish a truly direct connection between 2 endpoints, not to be confused with overlay networks and the like.
Advanced Users: It is possible to gain more direct p2p connections capability by introducing more complicated strategies to cooperate with symmetric NAT behaviour, such as port prediction, etc. But I have found that the complexities introduced are costly, both to your programming and the NAT itself, and may not be worth it. I'm sorry but I don't have links on me demonstrating these methods. I will update with links later.
I have not explained in detail the different types of NAT connection possibilities. There are RFC's out there and I will try to update my answer with links in the future. We will see. But the point is that you can avert a lot of this learning by refocusing on implementing TURN/STUN/ICE, learn how they are implemented and how you can use their standardized behaviour
- PJSIP - contains a stand-alone high level NAT traversal library for C/C++, also has bindings for other langauges. If you just want the NAT Traversal library sub-component, see PJNATH
- LibJingle - a P2P (peer-to-peer) and RTC (real-time communication) stack that builds on XMPP. Note that many of LibJingle implementation is not interoperable with actual XMPP Jingle specification and subsidiary specifications.
These may add considerable complexity to the program, which is why it can be compelling to implement some of the mechanisms myself.
I have heard that the eventual migration to IPv6 may squash the NAT traversal problem, but [probably not]. Someone could enlighten this topic. Either way, the progression to IPv6 appears slow from my non-experienced viewpoint, and I wouldn't count on it as a solution.