static int func_name (const uint8_t * address)
{
int result;
asm ("movl $1f, %0; movzbl %1, %0; 1:"
: "=&a" (result) : "m" (*address));
return result;
}
I have gone through inline assembly references over internet. But i am unable to figure out what this code is doing, eg. what is $1f ? And what does "m" means? Isn't the normal inline convention to use "=r" and "r" ?
The code is functionally identical to return *address but not absolutely equivalent to this wrt. to the generated binary / object file.
In ELF, the usage of the forward reference (i.e. the mov $1f, ... to retrieve the address of the assembly local label) results in the creation of what's called a relocation. A relocation is an instruction to the linker (either at executable creation or later to the dynamic linker at executable/library loading) to insert a value only known at link/load time. In the object code, this looks like:
Disassembly of section .text: 0000000000000000 : 0: b8 00 00 00 00 mov $0x0,%eax 5: 0f b6 07 movzbl (%rdi),%eax 8: c3 retq
Notice the value (at offset 1 into the .text section) is zero here even though that's actually not correct - it depends on where in the running code the function will end up. Only the (dynamic) linker can ultimately know this, and the information that this piece of memory needs to be updated as it is loaded is actually placed into the object file:
$ readelf -a xqf.o
ELF Header:
[ ... ]
Section Headers:
[Nr] Name Type Address Offset
Size EntSize Flags Link Info Align
[ 0] NULL 0000000000000000 00000000
0000000000000000 0000000000000000 0 0 0
[ 1] .text PROGBITS 0000000000000000 00000040
0000000000000009 0000000000000000 AX 0 0 16
[ 2] .rela.text RELA 0000000000000000 000004e0
0000000000000018 0000000000000018 10 1 8
[ ... ]
Relocation section '.rela.text' at offset 0x4e0 contains 1 entries:
Offset Info Type Sym. Value Sym. Name + Addend
000000000001 00020000000a R_X86_64_32 0000000000000000 .text + 8
[ ... ]
This ELF section entry says:
1 into the .text sectionR_X86_64_32). This may have been intended for use in 32-bit code, but in a 64-bit non-PIE executable that's still the most efficient way to put an address into a register; smaller than lea 1f(%rip), %0 for a R_X86_64_PC32 RIP-relative relocation. And yes a RIP-relative LEA into a 32-bit register is legal, and saves a byte of machine code if you don't care about truncating the address..text + 8 (which will have to be computed at link / load time)This entry is created thanks to the mov $1f, %0 instruction. If you leave that out (or just write return *address), it won't be there.
I've forced code generation for the above by removing the static qualifier; without doing so, a simple compile actually creates no code at all (static code gets eliminated if not used, and, a lot of the time, inlined if used).
Due to the fact that the function is static, as said, it'll normally be inlined at the call site by the compiler. The information where it's used therefore usually gets lost, as does the ability of a debugger to instrument it. But the trick shown here can recover this (indirectly), because there will be one relocation entry created per use of the function. In addition to that, methods like this can be used to establish instrumentation points within the binary; insert well-known/strictly-defined but functionally-meaningless small assembly statements at locations recoverable through the object file format, and then let e.g. the debugger / tracing utilities replace them with "more useful" things when needed.
$1f is the address of the 1 label. The f specifies to look for the first label named 1 in the forward direction. "m" is an input operand that is in memory. "=&a" is an output operand that uses the eax register. a specifies the register to use, = makes it an output operand, and & guarantees that other operands will not share the same register.
Here, %0 will be replaced with the first operand (the eax register) and %1 by the second operand (The address pointed to by address).
All these and more are explained in the GCC documentation on Inline assembly and asm contraints.
This piece of code (apart from being non-compilable due to two typos) is hardly useful.
This is what it turns into (use the -S switch):
_func_name:
movl 4(%esp), %edx ; edx = the "address" parameter
movl $1f, %eax ; eax = the address of the "1" label
movzbl (%edx), %eax; eax = byte from address in edx, IOW, "*address"
1:
ret
So the entire body of the function can be replaced with just
return *address;
return *address is not correct; there's a slight, functionally meaningless but nonetheless for certain purposes inevitable difference ... and that is the creation of a relocation at a rather known address within the function. Such things are useful for debugging and/or runtime tracing, particular in a situation like the above where the code is declared static and therefore will, at higher optimization levels, usually be inlined at the call site; the reloc sections in the ELF file can then be used to track where the code got inlined, for example.
This is a code snippet from the PintOS project.
The function here is used by the OS kernel to read a byte at address from the user address space. That is done by movzbl %1, %0 where 0% is result and 1% is address. But before that, the kernel has to move the address of $1f(which is the address of the instruction right after movzbl %1, %0) to the eax register. This move seems useless because some context information is missing. The kernel does that for the page fault interrupt handler to use it. Because address could be an invalid one offered by the user, and it might cause a page fault. When that happened, the interrupt handler would take over, set eip equal to eax(which is the memory address of $1f), and also set eax to -1 to indicate that the read failed. After that, the kernel was able to return from the handler to $1f and move on. Without saving the address of $1f, the handler would have no idea where it should return to, and could only go back to movzbl %1, %0 again and again.
