The standard leaves "certain" behaviour undefined in order to allow a variety of implementations, without burdening those implementations with the overhead of detecting "certain" situations, or burdening the programmer with constraints required to prevent those situations arising in the first place.
There was a time when avoiding this overhead was a major advantage of C and C++ for a huge range of projects.
Computers are now several thousand times faster than they were when C was invented, and the overheads of things like checking array bounds all the time, or having a few megabytes of code to implement a sandboxed runtime, don't seem like a big deal for most projects. Furthermore, the cost of (e.g.) overrunning a buffer has increased by several factors, now that our programs handle many megabytes of potentially-malicious data per second.
It is therefore somewhat frustrating that there is no language which has all of C++'s useful features, and which in addition has the property that the behaviour of every program which compiles is defined (subject to implementation-specific behaviour). But only somewhat - it's not actually all that difficult in Java to write code whose behaviour is so confusing that from the POV of debugging, if not security, it might as well be undefined. It's also not at all difficult to write insecure Java code - it's just that the insecurity usually is limited to leaking sensitive information or granting incorrect privileges over the app, rather than giving up complete control of the OS process the JVM is running in.
So the way I see it is that good software engineering requires discipline in all languages, the difference is what happens when our discipline fails, and how much we're charged by other languages (in performance and footprint and C++ features you like) for insurance against that. If the insurance provided by some other language is worth it for your project, take it. If the features provided by C++ are worth paying for with the risk of undefined behaviour, take C++. I don't think there's much mileage in trying to argue, as if it was a global property that's the same for everyone, whether the benefits of C++ "justify" the costs. They're justified within the terms of reference for the design of the C++ language, which are that you don't pay for what you don't use. Hence, correct programs should not be made slower in order that incorrect programs get a useful error message instead of UB, and most of the time behaviour in unusual cases (e.g.
<< 32 of a 32-bit value) should not be defined (e.g. to result in 0) if that would require the unusual case to be checked for explicitly on hardware which the committee wants to support C++ "efficiently".
Look at another example: I don't think the performance benefits of Intel's professional C and C++ compiler justify the cost of buying it. Hence, I haven't bought it. Doesn't mean others will make the same calculation I made, or that I will always make the same calculation in future.