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So I know what the following registers and their uses are supposed to be:

  • CS = Code Segment (used for IP)

  • DS = Data Segment (used for MOV)

  • ES = Destination Segment (used for MOVS, etc.)

  • SS = Stack Segment (used for SP)

But what are the following registers intended to be used for?

  • FS = "File Segment"?

  • GS = ???

Note: I'm not asking about any particular operating system -- I'm asking about what they were intended to be used for by the CPU, if anything.

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As far as I know, the F and G in these two do not stand for anything. It's just that there was room on the CPU (and in the instruction set) for six user-specifiable segment registers, and someone noticed that besides the "S"tack segment, the letters "C" and "D" (code and data) were in sequence, so "E" was the "extra" segment, and then "F" and "G" just sort of followed. – torek May 30 '12 at 5:08
@torek: Oh haha what... I thought "F" was for "File" though. – Mehrdad May 30 '12 at 5:11
Could have been, it's always hard to know what was going on in someone else's head unless you were there at the time (and I was on the other coast, nowhere near Intel's design team). – torek May 30 '12 at 5:14
Just think of how much fun we could have had with BS register :-} – Ira Baxter May 30 '12 at 5:38
I always used GS as the "Graphics Segment". :-) – Brian Knoblauch May 30 '12 at 11:49

2 Answers 2

up vote 48 down vote accepted

There is what they were intended for, and what they are used for by Windows and Linux.

The original intention behind the segment registers was to allow a program to access many different (large) segments of memory that were intended to be independent and part of a persistent virtual store. The idea was taken from the 1966 Multics operating system, that treated files as simply addressable memory segments. No BS "Open file, write record, close file", just "Store this value into that virtual data segment" with dirty page flushing.

Our current 2010 operating systems are a giant step backwards, which is why they are called "Eunuchs". You can only address your process space's single segment, giving a so-called "flat (IMHO dull) address space". The segment registers on the x86-32 machine can still be used for real segment registers, but nobody has bothered (Andy Grove, former Intel president, had a rather famous public fit last century when he figured out after all those Intel engineers spent energy and his money to implement this feature, that nobody was going to use it. Go, Andy!)

AMD in going to 64 bits decided they didn't care if they eliminated Multics as a choice (that's the charitable interpretation; the uncharitable one is they were clueless about Multics) and so disabled the general capability of segment registers in 64 bit mode. There was still a need for threads to access thread local store, and each thread needed a a pointer ... somewhere in the immediately accessible thread state (e.g, in the registers) ... to thread local store. Since Windows and Linux both used FS for this purpose in the 32 bit version, AMD decided to let the 64 bit segment registers (GS and FS) be used essentially only for this purpose (I think you can make them point anywhere in your process space; dunno if the application code can load them or not). Intel in their panic to not lose market share to AMD on 64 bits, and Andy being retired, decided to just copy AMD's scheme.

It would have been architecturally prettier IMHO to make each thread's memory map have an absolute virtual address (e.g, 0-FFF say) that was its thread local storage (no [segment] register pointer needed!); I did this in an 8 bit OS back in the 1970s and it was extremely handy, like having another big stack of registers to work in.

So, the segment registers are now kind of like your appendix. They serve a vestigial purpose. To our collective loss.

Those that don't know history aren't doomed to repeat it; they're doomed to doing something dumber.

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The 8086's segmenting was brilliant. I know of no better scheme for allowing a machine with a given register size to access an effective address space 16 times as big. Even today 8086-style segmentation (but with a 32-bit segment register shifted and added to a 32-bit offset) could be better than linear addressing, allowing 32-bit object references to access 64GB of addressing space. With some slight tweaks, the useful range of 32-bit object references could be pushed out even further. – supercat Sep 17 '13 at 20:42
@supercat: A simpler, more brilliant scheme that would have let them address 65536 times as much storage, would been to have treated the segment registers as full upper 16 bit extension of the lower 16 bits, which is in essence what the 286, 386 and Multics did. – Ira Baxter Sep 17 '13 at 21:59
@IraBaxter: The problem with that approach is that 80286-style segments have a sufficiently high overhead than one ends up having to store many objects in each segment, and thus store both segment and offset on every pointer. By contrast, if one is willing to round memory allocations up to multiples of 16 bytes, 8086-style segmentation allows one to use the segment alone as a means of identifying an object. Rounding allocations up to 16 bytes might have been slightly irksome in 1980, but would represent a win today if it reduced the size of each object reference from 8 bytes to four. – supercat Sep 17 '13 at 22:27
It mostly speaks for itself. Each thread needs storage of its own. Having that storage at a known, constant address makes it convenient to access (Windows TLS storage takes several machine instructions to access if you cheat, and dozens if you call the official GetTLS API). Setting aside virtual page zero would achieve this; the OS would have to set a map page for each thread when it scheduled the thread; that's presumably cheap. ... – Ira Baxter Dec 14 '13 at 15:04
+1 "Those that don't know history aren't doomed to repeat it" What a way to finish the answer! – higuaro Sep 22 '14 at 20:12

The registers FS and GS are segment registers. They have no processor-defined purpose, but instead are given purpose by the OS's running them. In Windows the GS register is used to point to operating system defined structures. FS and GS are commonly used by OS kernels to access thread-specific memory. In windows, the GS register is used to manage thread-specific memory. The linux kernel uses GS to access cpu-specific memory.

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Were they intended to be used for OS-defined purposes, or to facilitate code which needs to do something like *dest++ = lookup[*src++]; which would otherwise be rather awkward if dest, lookup, and src were at three unrelated locations. – supercat Sep 17 '13 at 20:23
On Windows FS is indeed for thread specific storage. See documented map of the block pointed by FS here – Nedko Aug 21 at 11:28

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