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This is a very basic question boggling mind since the day I heard about the concept of virtual and physical memory concept in my OS class. Now I know that at load time and compile time , virtual address and logical adress binding scheme is same but at execution time they differ.

First of all why is it beneficial to generate virtual address at compile and load time and and what is returned when we apply the ampersand operator to get the address of a variable, naive datatypes , user-defined type and function definition addresses?

And how does OS maps exactly from virtual to physical address when it does so? These questions are hust out from curiosity and I would love some good and deep insights considering modern day OS' , How was it in early days OS' .I am only C/C++ specific since I don't know much about other languages.

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The address of a variable is not determined at compile time... that should answer most of this. –  Ed S. Mar 27 '13 at 8:24
    
"Now I know that at load time and compile time , virtual address is generated but at execution time physical address is generated?" -- No. If you think that, then you don't understand what virtual and physical addresses are and need to study the issue further. The answer to your question is "virtual addresses" ... that's the only kind of address programs see or deal with (except for technical exceptions involving certain systems calls on some systems). –  Jim Balter Mar 27 '13 at 8:26
    
@JimBalter: I have corrected it . –  Kavish Dwivedi Mar 27 '13 at 8:31
    
No, you haven't, you've just expressed a different confusion. –  Jim Balter Mar 27 '13 at 8:46

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Physical addresses occur in hardware, not software. A possible/occasional exception is in the operating system kernel. Physical means it's the address that the system bus and the RAM chips see.

Not only are physical addresses useless to software, but it could be a security issue. Being able to access any physical memory without address translation, and knowing the addresses of other processes, would allow unfettered access to the machine.

That said, smaller or embedded machines might have no virtual memory, and some older operating systems did allow shared libraries to specify their final physical memory location. Such policies hurt security and are obsolete.

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Security issue point is very significant . –  Kavish Dwivedi Mar 27 '13 at 9:01
    
Physical addresses are irrelevant to security. Access control is relevant. Every process could share one address space as long as the hardware prevented one process from accessing the memory of another process. In fact, mathematically, the combination of (process ID, virtual address) is identical to a single address space (in which the process ID is concatenated with the virtual address). –  Eric Postpischil Mar 27 '13 at 13:29
    
@EricPostpischil Ideally, yeah, but it doesn't help when a malicious program knows where to get the stuff it shouldn't, once it has the keys to the castle. In practical terms, malware will get root access so it's worthwhile to de-trivialize applying patches to shared libraries. –  Potatoswatter Mar 27 '13 at 13:42

At the application level (e.g. Linux application process), only virtual addresses exist. Local variables are on the stack (or in registers). The stack is organized in call frames. The compiler generates the offset of a local variable within the current call frame, usually an offset relative to the stack pointer or frame pointer register (so the address of a local variable, e.g. in a recursive function, is known only at runtime).

Try to step by step a recursive function in your gdb debugger and display the address of some local variable to understand more. Try also the bt command of gdb.

Type

cat /proc/self/maps

to understand the address space (and virtual memory mapping) of the process executing that cat command.

Within the kernel, the mapping from virtual addresses to physical RAM is done by code implementing paging and driving the MMU. Some system calls (notably mmap(2) and others) can change the address space of your process.

Some early computers (e.g. those from the 1950-s or early 1960-s like CAB 500 or IBM 1130 or IBM 1620) did not have any MMU, even the original Intel 8086 didn't have any memory protection. At that time (1960-s), C did not exist. On processors without MMU you don't have virtual addresses (only physical ones, including in your embedded C code for a washing-machine manufacturer). Some machines could protect writing into some memory banks thru physical switches. Today, some low end cheap processors (those in washing machines) don't have any MMU. Most cheap microcontrollers don't have any MMU. Often (but not always), the program is in some ROM so cannot be overwritten by buggy code.

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Um, Intel 8086's didn't have MMU's, and they were produced far more recently than the 1950's. Heck, many embedded CPUs still don't have MMUs. –  Jim Balter Mar 27 '13 at 8:29
    
It was more for micro computers than for computers –  Basile Starynkevitch Mar 27 '13 at 8:31
    
Microcomputers are computers. Every desktop, laptop, tablet, and phone computer is a microcomputer. –  Jim Balter Mar 27 '13 at 8:32
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I never understood if my micro-oven or my washing-machine is a computer or not. For me, a computer is something I can program (and I did program, as a teenager in a museum in the mid 1970s, both IBM1620 & CAB500). Then, my Android phone is not a computer (even if I know it is): I am too lazy to program on it.... –  Basile Starynkevitch Mar 27 '13 at 8:34
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I believe the term you are looking for is "microcontroller", which is not just a smaller chip, but also generally less powerful than a desktop computer CPU. Unlike desktop CPUs, microcontrollers have hardware peripheral circuits on-board, for example UART, CAN, analog-to-digital converters etc. Another difference more relevant to this discussion is that most of the smaller microcontrollers (8- and 16-bit) do not have a MMU, but only uses physical addresses. –  Lundin Mar 27 '13 at 8:41

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