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Processes on Linux 3.0 on x86_64 architecture have a 64-bit virtual address space.

It is clear that 0 is guaranteed to be an invalid memory address [see definition below] in this address space, as this is used to indicate a NULL pointer.

What other 64-bit numbers (if any) are guaranteed never to be valid memory addresses, and why?

For example, can 1 ever be a valid address? What about 2^64-1?

Definition: What do you mean "guaranteed to be an invalid memory address" ?

void deref_and_assign(uint64_t i)
    char* p = (char*) i;
    *p = 42;

For the purposes of this question a guaranteed invalid memory reference means that the function deref_and_assign will always raise a SIGSEGV.

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Out of curiosity, why is this information you're looking for? It's probably not information you should write code based upon. For research, of course, anything goes. ;) –  Dan Fego Jan 25 '12 at 4:39
Curiosity is good. I am implementing a non-portable dynamic type (for a Linux/x86_64 target) and I am considering my options as far as overloading the lead 64-bit value "code unit". One way to do it is to partition the code unit into (a) immediate values and (b) pointer to more info. As a trivial example you could represent a dynamic number/string type as follows: (0-4095) it's a number represented immediately as the integers 0,1,2...4095; (4096-2^64) It's a pointer to a null-terminated string. For a more real world example take a look at how rubys VALUE type works. ruby.h in ruby.tgz –  Andrew Tomazos Jan 25 '12 at 6:29

2 Answers 2

up vote 3 down vote accepted

On x86/64 if page translation enabled and the memory at virtual address 0 isn't accessible (because of the way physical memory is mapped into the virtual address space), 1 ... 4095 won't be accessible either because all these 4096 addresses correspond to a single page of memory and it can only be available or unavailable as a whole. It is a good idea to never map memory at virtual address 0. Not mapping it will help to catch many NULL pointer dereferences. The CPU here will generate a page fault (aka #PF) on unmapped locations or locations requiring higher privilege than the currently executing code.

In 64-bit mode the CPU may implement fewer (48+) than 64 virtual address bits and 64-bit addresses must contain either all zeroes or all ones in the bits that aren't implemented (the value, 0 or 1, must be the same as the value of the most significant implemented address bit, all of which can be interpreted as address sign-extension). Such addresses are called canonical. If you try to read or write memory using a non-canonical address, you'll get a general protection fault (AKA #GP).

So, depending on the OS (effectively, on its memory layout) and actual CPU you may come up with ranges of "invalid" memory addresses. If you try to read/write the kernel's memory from a user mode application, you'll get #PF. If you try to read/write unmapped memory (e.g. at address 0 through 4095), you'll get #PF. If you try to read/write at a non-canonical address, you'll get a #GP.

Is that the kind of thing you're looking for?

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Yes, 0..4095 is clear that the first page can't exist, thank you. It is not clear about the 48 bit mode. Can you give an example of a x86_64/Linux CPU that does that? On my machine I see in /proc/*/maps that vsyscall is mapped to ffffffffff600000-ffffffffff601000 for example, which is almost the top of vm. Also: How can you "try" and read from kernel memory in userland? All words used as memory addresses in userland dereference to vm. –  Andrew Tomazos Jan 25 '12 at 3:23
ffffffffff600000 isn't necessarily the top. I've already mentioned that the top unimplemented bits are copies of the top implemented bit. So, if there're only 48 bits implemented, only the ffffff600000 part is "meaningful" and the rest, the top 16 bits (ffff) are just copies of the most significant "meaningful" bit, which is equal to 1. –  Alexey Frunze Jan 25 '12 at 4:14
You can use any address you like in both kernel and user mode. But the memory protection mechanisms won't let you actually read/write kernel memory from user mode code. Nothing prevents you from loading an arbitrary value (address) into, say, rbx and trying to execute mov al, [rbx] to read into al the value of the byte at the address contained in rbx. You can try. But the processor won't execute this instruction if there aren't sufficient privileges. Instead it will generate a #GP or #PF, which the OS will handle and the only meaningful action here would be to terminate the app. –  Alexey Frunze Jan 25 '12 at 4:18
How can I tell how many virtual address bits are implemented on my target platform (Linux 3.0 / x86_64) ? –  Andrew Tomazos Jan 25 '12 at 4:26
I had a different understanding (perhaps incorrect) of kernel mode vs user mode as it relates to memory addressing. I thought that when a process is in userland (outside of a syscall) any memory dereferenced (eg mov al, [rbx]) was treated as a virtual address in the processes virtual address space, and the page table was looked up by the CPU. When the process enters a syscall it goes into kernel mode and then memory addresses are real physical addresses, but now that I write it down I think I'm wrong/confused. –  Andrew Tomazos Jan 25 '12 at 4:38

You checked that a Linux process cannot mmap with MAP_FIXED a segment starting at (void*)0.

So for practical purposes you can safely assume that the very first page 0 - 0xfff is never mmap-ed (the 4Kb size of pages is processor and system dependent, but it is very often 4kb). Then you can assume that dereferencing pointers (from inside a Linux application) inside this first page gives SIGSEGV

Likewise for the last page ending at 0xffffffffffffffff (ie 2^64-1)

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mmap(0, 4096, PROT_READ | PROT_WRITE, MAP_PRIVATE | MAP_FIXED | MAP_ANONYMOUS, -1, 0) returns -1 and EPERM, so no you are wrong sorry. –  Andrew Tomazos Jan 25 '12 at 7:03
Well, I believe I am even more right, because I did write that you can assume that the first page is not mmap-ed. I edited my answer. –  Basile Starynkevitch Jan 25 '12 at 7:04

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