Your question confuses a virtual address with using an address as a way of identification, so the first step to understanding is to separate the concepts.
A working example is the C runtime library function
sprintf(). When properly declared and called, it is incorporated into a program as a shared object module, along with all the subfunctions it needs. The address of
sprintf varies from program to program because the library is loaded in an available free address. For a simple hello world program, sprintf might be loaded at address 0x101000. For a complex program which calculates taxes, it might be loaded at 0x763f8000 (because of all the yucky logic the main program contains goes before the libraries it references). From a system perspective, the shared library is loaded into memory in one place only, but the address window (range of addresses) that each process sees that memory is unique to that executable.
Of course, this is complicated further by some of the features of Security Enhanced Linux (SELinux) which randomizes the addresses at which different program sections are loaded into memory, including shared library mapping.
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As someone correctly points out, the virtual address mapping of each process is specific to each process, not unlike its set of file descriptors, socket connections, process parent and children, etc. That is, p1 might map address 0x1000 to physical 0x710000 while p2 maps address 0x1000 to a page fault, and p3 is mapped to some shared library at physical 0x9f32a000. The virtual address mapping is carefully supervised by the operating system, arguably for providing features such as swapping and paging, but also to provide features like shared code and data, and interprocess shared data.