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A production issue has led our team to the following questions:

  1. Under RHEL6 using GCC 4.4.6, how are ntohs and ntohl implemented?
  2. Are the implementations known to be fast or slow?
  3. How can I actually see the generated assembly code for the functions?

I know the implications behind questions may seem far-fetched and ridiculous, but I have been asked to investigate.

The hardware in question is an Intel box, little endian, 64-bit processor and compiled in 64 bit.

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GCC.4.4 is a very old version of GCC. Current one is 4.8.1. You should consider upgrading your compiler (notice that C++ support improved a lot since GCC 4.4) – Basile Starynkevitch Jul 30 '13 at 18:14
2  
@Basile, 4.4 is the system compiler on RHEL6 and is supported and maintained, so it's not unreasonable to stick with it – Jonathan Wakely Jul 30 '13 at 19:18
    
@BasileStarynkevitch: Indeed, I use GCC 4.7.2 and 4.8.1 for most development and R&D type work, but we use 4.4 for production code because that is what is distributed with the distro. – John Dibling Jul 30 '13 at 20:15
    
@Charles: I think the RHEL6 tag is relevant in this case. Why did you remove it? – John Dibling Jul 31 '13 at 12:26
1  
@JohnDibling, given the answers, I'd actually sooner suggest tagging with glibc than creating a tag for RHEL 6, as the functions in question as provided by glibc, not the operating system itself. – Charles Jul 31 '13 at 18:36
up vote 11 down vote accepted
+100
  1. They're provided by glibc, not GCC, look in /usr/include/bits/byteswap.h for the __bswap_16 and __bswap_32 functions, which are used when optimization is enabled (see <netinet/in.h> for details of how.)
  2. You didn't say what architecture you're using, on a big-endian system they're no-ops, so optimally fast! On little-endian they're architecture-specific hand-optimized assembly code.
  3. Use GCC's -save-temps option to keep the intermediate .s files, or use -S to stop after compilation and before assembling the code, or use http://gcc.godbolt.org/
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Sorry, quite right. This is a x86_64 machine, so little endian. – John Dibling Jul 30 '13 at 17:30
up vote 12 down vote
+200

Do the following:

test.c

#include <arpa/inet.h>
int main()
{
   volatile uint32_t x = 0x12345678;
   x = ntohl(x);
   return 0;
}

Then compile with:

$ gcc -O3 -g -save-temps test.c

And analyze the resulting test.s file, or alternatively run objdump -S test.o.

In my machine (Ubuntu 13.4) the relevant asssembler is:

movl    $305419896, 12(%esp)
movl    12(%esp), %eax
bswap   %eax
movl    %eax, 12(%esp)

Hints:

  • 305419896 is 0x12345678 in decimal.
  • 12(%esp) is the address of the volatile variable.
  • All the movl instructions are there for the volatile-ness of x. The only really interesting instruction is bswap.
  • Obviously, ntohl is compiled as an inline-intrinsic.

Moreover, if I look at the test.i (precompiled output), I find that the ntohl is #defined as simply __bswap_32(), which is an inline function with just a call to __builtin_bswap32().

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Thank you. This was super helpful. – John Dibling Jul 30 '13 at 17:34
1  
+1. Also note that without the volatile, GCC will propagate the constant and swap it at compile time (the glibc implementation uses builtin_constant_p to achieve this). So the short answer to this question is "It's zero or one instructions so you can ignore it". This has been true since long before RHEL 6. – Nemo Jul 30 '13 at 19:18

These are implemented in glibc. Look at /usr/include/netinet/in.h. They will most likely rely on the glibc byteswap macros (/usr/include/bits/byteswap.h on my machine)

These are implemented in assembly in my header so should be pretty fast. For constants, this is done at compile time.

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GCC/glibc causes ntohl() and htonl() to be inlined into the calling code. Therefore, the function call overhead is avoided. Furthermore, each ntohl() or htonl() call is translated into a single bswap assembler operation. According to the "Intel® 64 and IA-32 Architectures Optimization Reference Manual" bswap has both latency and throughput of "1" on all current Intel CPUs. So, only a single CPU clock is required to execute ntohl() or htonl().

ntohs() and htons() are implented as a rotation by 8 bit. This effectively swaps the two halfs of the 16-bit operand. Latency and throughput are similiar to that of bswap.

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