C, C++, and other statically compiled languages are compiled into native machine code, which means the CPU of the computer can directly execute them. The code it compiles to is unintelligible binary data, but you can kind of imagine that a C code fragment like this:
int x = 10;
int y = x * 2;
will be compiled into a series of binary instructions that mean something like the following:
store 10 into memory address 200
multiply the contents of memory address 200 by 2, treating them as integers
store the result of the last instruction into memory address 300
Where the compiler has assigned memory addresses to the variables
y that appeared in the code. Note that actual machine code is more complex than this, and is obviously encoded into short binary codewords, not English phrases. But that's the very basic idea. A particular point to note is that the compiler knew to use integer multiplication because it knew that
y are integers. The CPU itself knows nothing at all about the meaning of the contents of memory address 200, it just knows about bits and can be told to shuffle them around in various ways, one of which is integer multiplication.
Now Python is compiled to byte code. That actually doesn't mean much very interesting when we're talking about these issues. Python byte code, unlike machine code, doesn't encode low level operations that can be directly executed by the machine. In fact, it basically just encodes the very same Python-level operations you wrote in your Python source code, and the CPU can't do anything at all with Python byte code. The Python interpreter is a program that has the job of carrying out the instructions encoded in Python byte code. All the byte-code compilation does is allow the interpreter to operate on a form of the code that is easier and faster to manipulate; it doesn't have to do all the string processing necessary to understand Python source code directly.
So here's where dynamic typing and the performance difference come in. A C++ compiler that sees
x * 2 knows it can compile this to a single integer multiplication instruction for the CPU, because it knows the types of everything involved ahead of time.
A Python interpreter that sees
x * 2 has to go through many steps to see whether
x is any of the built in types that support multiplication, or whether it is a class that implements custom multiplication, or whether it is a class that doesn't implement multiplication but inherits from something else that does, or whether it should create an exception. And if
x is an integer there are then steps to get the machine-level value of
x out of the data-structure that represents a Python integer, and then 1 single machine level instruction to actually have the CPU do integer multiplication, then more instructions to wrap the result back up into a Python integer data structure.
All of that code is many compiled machine code instructions (usually; for PyPy running on top of CPython they're Python byte code instructions!); the compiled code of the Python interpreter itself. You might think Python's byte code compiler could figure out which path to take ahead of time and translate the Python source code into those machine instructions, but it can't because Python is dynamically typed;
x could be an integer the first time that line of code is executed, then a string next time, and a list the time after that, and maybe even one day a class instance. So all of that logic has to be done every single time, because Python can't know ahead of time what it's going to need. So even if you wrote a program that compiled Python source code into native machine code, mostly it would have to emit machine code that basically does the same thing as the Python interpreter.
That covers most of your questions, as a very simple overview. You also ask about PyPy, without really giving any details of what you're interested in. I presume it's "why is PyPy faster than CPython (some of the time)?" Basically PyPy has a JIT compiler, which is a bit like a C++ compiler except that it compiles code during the execution of your program. This can (sometimes) get around the problem of Python not being able to know whether
x is an integer, a float, a list, or a something else. On any one execution of a bit of code,
x is just one thing. And in most Python code,
x is only ever one thing, or occasionally one of a few things. So by compiling code at runtime (after waiting to see which is the code that is executed really often), PyPy's JIT can (sometimes) turn
x * 2 into a single integer multiplication machine code instruction. If we execute that line of code with
x as an integer millions of times, this can be a big performance boost. But it's still possible that the next time
x will be a string, so the JIT has to include some fallback logic so that it can still handle all the possibilities that Python allows. But it can gain speed by waiting to see which of the many possibilities are actually used often, and then optimising for those. A JIT can even make some optimisations that C++ compilers can't, because it can wait to see what is going on at runtime, whereas C++ has to emit code that will work whatever happens at runtime (but it can make assumptions based on the types, which will never change).