You can't "step into" functions; Godbolt isn't a debugger, it's a disassembler (in "binary" mode, otherwise a compiler asm-text output filter / viewer). Your program doesn't run, it just gets compiled. (And unless you choose the "binary" output option, it only compiles to asm, not to machine code, and doesn't actually link.)
But regardless of terminology, no, you can't get Godbolt to show you disassembly for whatever version of a library it happens to have installed.
Single-step the program on your desktop. (Compile with gcc -O3 -fno-plt to avoid having to step through PLT lazy dynamic linking.)
(I did, and libstdc++ 6.2.1 on Arch Linux runs cpuid in the constructor for std::random_device. If rdrand is available, it uses it on calls to _M_getval(). Figuring this out from just disassembly would have been tricky; there are several levels of function calls and branching, and without symbols it would have been hard to figure out what's what. My Skylake has rdseed available, but it didn't use it. Yes, as you commented, that would be a better choice.)
Different compilers can generate different versions of library functions from the same source, that's the main point of the compiler explorer's existence. And no, it doesn't have a separate version of libstdc++ compiled by every compiler in the dropdown.
There'd be no guarantee that the library code you saw would match what's on your desktop, or anything.
It does actually have x86-64 Linux libraries installed, though, so in theory it would be possible for Godbolt to give you an option to find and disassemble certain library functions, but that functionality does not exist currently. And would only work for targets where the "binary" option is available; I think for most of the cross-compile targets it only has headers not libraries. Or maybe there's some other reason it won't link and disassemble for non-x86 ISAs.
Using -static and binary mode shows stuff, but not what we want.
I tried compiling with -static -fno-plt -fno-exceptions -fno-rtti -nostartfiles -O3 -march=skylake (so rdrand and rdseed would be available in case they got inlined; they don't). -fno-plt is redundant with -static, but it's useful without to remove that clutter.
-static causes the library code to actually end up in the linked binary that Godbolt disassembles. But the output is limited to 500 lines, and the definition of std::random_device::_M_getval() happens not to be near the start of the file.
-nostartfiles avoids cluttering the binary with _start and so on from CRT startup files. I think Godbolt already filters these out of the disassembly, though, because you don't see them in the normal binary output (without -static). You're not going to run the program, so it doesn't matter that the linker couldn't find a _start symbol and just defaulted to putting the ELF entry point at the start of the .text section.
Despite compiling with -fno-exceptions -fno-rtti (so no unwind handler for your function is included), libstdc++ functions were compiled with exception handling enabled. So linking them pulls in boatloads of exception code. The static executable starts out with definitions for functions like std::__throw_bad_exception(): and std::__throw_bad_alloc():
BTW, without -fno-exceptions, there's also a get_random_seed() [clone .cold]: definition, which I think is an unwind handler. It's not a definition of your actual function. Near the start of the static binary is operator new(unsigned long) [clone .cold]: which again I think is libstdc++'s exception-handler code.
I think the .text.cold or .init sections got linked first, unfortunately, so none of the interesting functions are going to be visible in the first 500 lines.
Even if this had worked, it's only binary-mode disassembly, not compiler asm
Even with debug symbols, we wouldn't know which struct member was being accessed, just numeric offsets from registers, because objdump doesn't fill those in.
And with lots of branching, it's hard to follow complicated logic possibilities. Single-stepping at run-time automatically follows the actual path of execution.
Related:
/dev/random, unless your glibc is compiled with-march=ivybridgeor newer. (rdrandisn't baseline for x86-64! It was new in IvB, and AMD later added support, too.) Or glibc might not define_GLIBCXX_X86_RDRANDby default even if it is available, because not everyone 100% trusts Intel's black-box RNG not to have subtle patterns introduced by the NSA or something. lwn.net/Articles/760584 is an article about the kernel driver for/dev/randomand whether it fully trustsrdrand(e.g. for early boot-time randomness).rdrandis available, and if so uses it. It was pretty simple to step through with GDB (after compiling amainthat called this function, usinggcc -O3 -fno-plt). I was fooled by the code the OP posted in a comment, but I guess_M_fileis how it checks whether to use the/dev/randomfile or not after init.