Java is basically designed completely end-to-end to speed up that precise scenario:
- objects are always accessed by reference (so that you can mix and match different types within the same class hierarchy. You can make an array of Fruit objects, and it can naturally store Banana objects as well. This doesn't affect performance, it but it makes code using run-time polymorphism easier and simpler to write.
- It uses a garbage collector which allows objects to be moved around in memory after allocation, so that, even though an array just stores references, the referenced objects can be packed together in contiguous memory to minimize cache misses which would otherwise hurt performance badly
- The language is JIT'ed (or in some cases interpreted), so that at run-time, the JVM can look at a virtual call, and in many cases optimize it into a regular function call.
C++ doesn't have all this machinery: having to store and access objects by reference/pointer in C++ is both tedious and error-prone, but also inefficient (the objects pointed to by the members of an array won't be allocated next to each others, so accessing each object will likely result in a cache miss).
And when the C++ compiler comes across a virtual call, it usually can't determine which function is going to be called, so it can't optimize away the virtual-ness. And when it can't do that, it also can't inline the call (which C++ compilers rely heavily on for performance).
But on the other hand C++ doesn't need to rely on this as much either. C++ instead gives you powerful static polymorphism, which can often be used instead, eliminating the overhead completely.
So yes, run-time polymorphism, with virtual calls and with inheritance often is more expensive in C++, because it doesn't have the extensive plumbing necessary to speed it up.
But at the same time, C++ also makes run-time polymorphism more difficult to use, and in many cases it provides alternatives you can use instead.
People often claim that "the cost of a virtual call is just a pointer indirection", but it has many subtle costs, as hinted at above: it inhibits function inlining, and it requires objects to be handled using reference semantics, which again affects memory locality which hurts the CPU cache utilization. It has wide-ranging effects, and Java is effectively designed from scratch to compensate for as many of these as possible. C++ isn't, and in most cases, has to take the performance hit when run-time polymorphism is used.
Of course, it is likely also true that typical C++ programmers are just more concerned about performance than Java programmers are (you don't often hear Java programmers discuss their code's CPU cache utilization, for example)
If i have to develop a runtime in c++ which hosts applications on it which are also developed in c++, i would take the following approach <...>
Please don't. As said above, C++ code generally doesn't, and shouldn't, use runtime polymorphism to solve every problem. In Java, it is effectively the only tool you have access to, and it is used, and must be used, and should be used very extensively. In C++, it is one tool in an entire toolbox of options. And when alternatives are available, it is often best avoided.
there is a cost involved but this also gives us decoupling of app from the runtime. if no virtual methods, the app will always have link time dependency with the runtime.
And? Is there a problem in having such a link-time dependency? Are you going to swap out the app while it's running?