Why not just follow existing naming convention
Because the low 8 names aren't an arbitrary sequence or a convention, they're named for their specific purpose. r8-r15 don't have any specific purpose and almost no implicit uses or specialness. All of the original 8 registers have at least one instruction that uses that register implicitly. See https://www.swansontec.com/sregisters.html for what the names mean. (It's possible that EDX=data is a backronym, but A for accumulator and C for counter are clearly not a coincidence).
AMD64 was designed around 2000, and aims to be as orthogonal as possible so it's a better compiler target (compilers have an easier time when it doesn't matter which register a value is in).
It was already well established in 2000 point that it's normal to have numbered registers when there's nothing special about them; all RISC ISAs and many more-recent CISC ISAs do that. (See @Hans' answer)
Early x86 extensions (especially 186 / 386) made the ISA more orthogonal than 8086 by adding a multi-operand
imul r,r/m and
imul r, r/m, imm that doesn't need EAX/AX,
movsx as a non-EAX version of
cbw (and also 8->32 in one instruction), and especially 32-bit addressing modes allowing any register for anything, not just
[bx|bp] + [si|di] + disp0/8/16. But no new registers were added, and the implicit uses were not removed when more flexible ways were added, so in modern x86 the names are just reminders of the implicit uses, not what you have to use each register for.
Dave Christie (an AMD64 CPU architect at AMD) posted this on the x86-64.org mailing list on 2000-sep-15, in reply to a discussion about renaming the old registers R0..R7, or naming the upper registers UAX / ....
Figuring out how to best name the registers was actually
one of the hardest parts of doing the register extension.
The primary motivation for keeping the AX, BX, etc,
nomenclature for the lower eight was exactly what Honza
suggests [in an earlier message in the thread] -- there are various special-case uses of most
of those registers, which experienced x86 programmers
are very familiar with, and which are actually reflected
in the mnemonics (A=accumulator, C=Count, SP=Stack Pointer,
SI=Source Index, etc), which helps newbies remember these
There are some artifacts of this special-case functionality that are
reflected in the upper registers, but only for instruction encoding1 --
none of the special functionality is reflected, so it would really be
misleading to use UAX, etc. We ended up naming them R8-R15,
acknowledging that some people might prefer to think of the lower set
as R0-R7, but never using such names in our documentation, to avoid
An assembler is free to define such aliases, although as Alex points
out, we feel it would increase the chances of confusion and mistakes
if both sets of names were simultaneously allowed. So if such aliases
are defined, I'd recommend it be done in a way that a programmer be
allowed to enable only one set or the other.
(footnote added by me: the upper-register special cases are in addressing-mode encodings: R13 is like RBP, and can't be a base with no displacement. R12 is like RSP and needs a SIB byte. But unlike RSP, it can be an index. See the bottom of my answer on Why are rbp and rsp called general purpose registers?)
The x86-64.org mailing list archives have some interesting discussions between gcc and (Linux) kernel developers, and AMD64 architects. If you've ever wondered exactly how the x86-64 System V calling convention was designed, and why it passes the first few args in
rdi, rsi, rdx, rcx, it turns out that Jan (Honza) Hubicka designed it based on (dynamic) instruction counts and (static) code-size for SPECint using a build of then-current gcc which maybe liked to inline
rep movs for small copies. See Why does Windows64 use a different calling convention from all other OSes on x86-64? for mailing list archive links and more details.
Nobody in that discussion suggested using letters like
rfx and so on.
It would have been an alphabet soup, and a separate naming scheme makes it really easy to distinguish new registers from old. This lets you see when an instruction needs a REX prefix or not (smaller code-size is almost always better). e.g.
mov eax, edx is 1 byte shorter than
mov eax, r8d.
And also, a REX prefix means you can't access AH/CH/DH/BH, so if you're using those byte regs you have to keep track of what you're doing. (e.g. you can unpack bytes from a qword with
movzx r8d, bl /
movzx ecx, bh /
shr rbx, 16, but you can't
movzx r9d, bh (REX.B for a high reg) or
movsx rcx, bh (REX.W for 64-bit destination.)
Making it easy to see / remember which regs are new is also helpful for kernel developers, e.g. in a kernel entry-point from 32-bit user-space, the valuable user-space state is only in eax..esi, and it's easy to remember that r8-r15 are "new" registers that 32-bit code can't touch.
This may seem minor now, but when an ISA is new all the asm programmers have to learn it. The architects at AMD working on AMD64 put a lot of thought into naming schemes, and IMO did a nice job.