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This program prints 65k bytes per line.

I measure the throughput with ./a.out | pv >/dev/null and get around 3 GB/s.

As soon as I change the line length to 70k, the throughput drops to ~ 1 GB/s.

Which bottleneck (CPU cache, libc idiosynchrasy, etc.) am I hitting here?

#include <stdio.h>
#include <string.h>

#define LEN 65000     // high throughput
// #define LEN 70000  // low throughput

int main ()
{
  char s[LEN]; memset(s, 'a', LEN-1); s[LEN-1] = '\0';

  while (1)
    printf ("%s\n", s);
}

Update: I'm running this on Ubuntu 12.04 64-bit, which has EGLIBC 2.15, on a Core i5-2520M.

Update: puts (s) has the same problem.

share|improve this question
    
What processor is this? –  Mysticial Aug 7 '12 at 19:04
5  
Widescreen monitor? <g> –  Martin James Aug 7 '12 at 19:05
2  
Also significant - what libc are you using, and what version? –  duskwuff Aug 7 '12 at 19:07
2  
Probably internal buffer of libc, especially inside printf. How about puts? –  Yuxiu Li Aug 7 '12 at 19:07
2  
I'm not sure if this is useful information, but 65000 fits in two bytes, whereas 70000 needs three. Maybe that could be a jumping off point for someone more knowledgeable than me? –  Gordon Bailey Aug 7 '12 at 19:08
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1 Answer 1

up vote 6 down vote accepted

You are suffering from under utilizing the kernel I/O buffer in your data transfer. If we assume 64KB is the kernel I/O buffer size, then a 70000 write will block after 64KB is written. When it is drained the remaining 4KB + change is written into the I/O buffer. pv ends up doing two reads to read each 70000 bytes transfered, resulting in about half your normal throughput due to bad buffer utilization. The stall in I/O during write probably makes up the rest.

You can specify a smaller read size to pv, and this will increase your throughput, by increasing your average bytes transferred per time slice. Writes will be more efficient on average, and keeps read buffers full.

$ ./a.out | pv -B 70000 > /dev/null
9.25GB 0:00:09 [1.01GB/s] [        <=>                                        ]

$ ./a.out | pv -B 30k > /dev/null
9.01GB 0:00:05 [1.83GB/s] [    <=>                                            ]

Edit: Three more runs (2.7GHz core i7)

$ ./a.out | pv -B 16k > /dev/null
  15GB 0:00:08 [1.95GB/s] [       <=>                                         ]

$ ./a.out | pv -B 16k > /dev/null
 9.3GB 0:00:05 [1.85GB/s] [    <=>                                            ]

$ ./a.out | pv -B 16k > /dev/null
19.2GB 0:00:11 [1.82GB/s] [          <=>                                      ]
share|improve this answer
    
The difference in block size seems to be negligible on my machine. –  Mysticial Aug 7 '12 at 19:38
    
@Mysticial: How many sizes did you try? How about 16k? –  jxh Aug 7 '12 at 19:43
    
I tried 30k, 80k, and 500k. All within 15% of each other. The 65000 and 70000 in the code makes a 2x difference though. –  Mysticial Aug 7 '12 at 19:44
1  
@nh2 It's actually only 32k per core. But you're right that both test cases fit comfortably into the L2 caches. –  Mysticial Aug 7 '12 at 20:10
1  
@nh2 Here's some more numbers to look at: pastebin.com/WyEeN5Lp With the exception of the 200k block size, there's basically no difference. (edit: updated link with more detail) –  Mysticial Aug 7 '12 at 20:16
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