AMD needed some room to add new opcodes for
REX prefixes and some other new instructions when they developed the 64-bit x86 extensions. They changed the meaning of some of the opcodes to those new instructions.
Several of the instructions were simply short-forms of existing instructions or were otherwise not necessary.
PUSHA was one of the victims. It's not clear why they banned
PUSHA though, it doesn't seem to overlap any new instruction opcodes. Perhaps they are reserved the
POPA opcodes for future use, since they are completely redundant and won't be any faster and won't occur frequently enough in code to matter.
The order of
PUSHA was the order of the instruction encoding:
edi. Note that it redundantly pushed
esp! You need to know
esp to find the data it pushed!
If you are converting code from 64-bit the
PUSHA code is no good anyway, you need to update it to push the new registers
r15. You also need to save and restore a much larger SSE state,
xmm15. Assuming you are going to clobber them.
If the interrupt handler code is simply a stub that forwards to C code, you don't need to save all of the registers. You can assume that the C compiler will generate code that will be preserving
r15. You should only need to save and restore
r11. (Note: on Linux or other System V ABI platforms, the compiler will be preserving
r15, you can expect
The segment registers hold no value in long mode (if the interrupted thread is running in 32-bit compatibility mode you must preserve the segment registers, thanks ughoavgfhw). Actually, they got rid of most of the segmentation in long mode, but
FS is still reserved for operating systems to use as a base address for thread local data. The register value itself doesn't matter, the base of
GS are set through MSRs
0xC0000101. Assuming you won't be using
FS you don't need to worry about it, just remember that any thread local data accessed by the C code could be using any random thread's TLS. Be careful of that because C runtime libraries use TLS for some functionality (example: strtok typically uses TLS).
Loading a value into
GS (even in user mode) will overwrite the
GSBASE MSR. Since some operating systems use
GS as "processor local" storage (they need a way to have a pointer to a structure for each CPU), they need to keep it somewhere that won't get clobbered by loading
GS in user mode. To solve this problem, there are two MSRs reserved for the
GSBASE register: one active one and one hidden one. In kernel mode, the kernel's
GSBASE is held in the usual
GSBASE MSR and the user mode base is in the other (hidden)
GSBASE MSR. When context switching from kernel mode to a user mode context, and when saving a user mode context and entering kernel mode, the context switch code must execute the SWAPGS instruction, which swaps the values of the visible and hidden
GSBASE MSR. Since the kernel's
GSBASE is safely hidden in the other MSR in user mode, the user mode code can't clobber the kernel's
GSBASE by loading a value into
GS. When the CPU reenters kernel mode, the context save code will execute
SWAPGS and restore the kernel's