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I've been working my way through the Linux char driver examples on the web but run across a behavior that I can't explain.

static ssize_t my_read(struct file *f, char __user *user_buf, size_t cnt, loff_t* off)
   printk( KERN_INFO "Read called for %zd bytes\n", cnt );
   return cnt;

The message always indicates that cnt=4096 bytes regardless of what the number of bytes specified in the user space call to read (e.g..

[11043.021789] Read called for 4096 bytes

However, the user space read calls

retval = fread(_rx_buffer, sizeof(char), 5, file_ptr);
printf( "fread returned %d bytes\n", retval );

The output from user space is

fread returned 5 bytes.

How is it that the value of the size in my_read is always 4096 but the value from fread indicates 5 ? I know there's something I'm missing but not sure what...

share|improve this question
Could this be readahead into an intermediate buffer with page granularity (4096 is a very widely used page size in CPU configuration), or maybe the hard disk's block size (512 for older, 4096 for newer, multi TB drives)? Did you try what happens when calling for, say, 9345 bytes? – Sam Nov 8 '13 at 19:36
It looks that way. If I ask for 10, 20, or 4096 bytes via user space, I see "Read called for 4096 bytes" in the logfile. If I asked for 4097 bytes via user space, I see two new entries of "Read called for 4096 bytes" in the logfile. Asking for 9345 results in two entries in the logfile, "Read called for 8192 bytes" and "Read called for 4096 bytes". – DnRng Nov 8 '13 at 19:54
up vote 9 down vote accepted

Try read(2) (in unistd.h) and it should output 5 characters. When using libc (fread(3), fwrite(3), etc.), you're using the internal libc buffer, which is usually the size of a page (which is almost always 4 kiB).

I believe that the first time you call fread for 5 bytes, libc does an internal read of 4096 bytes and the following fread will simply return bytes libc already has in the buffer associated with the FILE structure you use. Until you reach 4096. The 4097th byte will issue another read of 4096 bytes and so on.

This also happens when you write, for example when using printf, which is just fprintf with stdout as its first argument. libc won't call write(2) directly, but put your stuff in its internal buffer instead (also of 4096 bytes). It will flush if you call


yourself, or anytime it finds the byte 0x0a (newline in ASCII) within the bytes sent.

Try it, you shall see:

#include <stdio.h>
#include <unistd.h> /* for sleep() */

int main(void) {
    printf("the following message won't show up\n");
    printf("hello, world!");
    printf("\nuntil now...\n");

    return 0;

This will work however (not using libc's buffering):

#include <stdio.h>
#include <unistd.h> /* for sleep() and write() */

int main(void) {
    printf("the following message WILL show up\n");
    write(0, "hello!", 6);

    return 0;

Of course you should know that 0 is the default file descriptor for the standard output.

Flushing everytime there's a newline is essential for the user of a terminal to see messages instantly, and is also helpful for per-line processing, which is done a lot in a Unix environment.

So, even if libc uses read and write syscalls directly to fill and flush its buffers (and by the way the Microsoft implementation of the C standard library must be using Windows stuff, probably ReadFile and WriteFile), those syscalls absolutely do not know libc. This leads to interesting behaviours when using both:

#include <stdio.h>
#include <unistd.h> /* for write() */

int main(void) {
    printf("1. first message (flushed now)\n");
    printf("2. second message (without flushing)");
    write(0, "3. third message (flushed now)", 30);

    return 0;

which outputs:

1. first message (flushed now)
3. third message (flushed now)2. second message (without flushing)

(third before second!).

Also, note that you can turn off libc's buffering with setvbuf(3). Example:

#include <stdio.h>
#include <unistd.h> /* for sleep() */

int main(void) {
    setvbuf(stdout, NULL, _IONBF, 0);
    printf("the following message WILL show up\n");

    return 0;

I never tried, but I guess you could do the same with the FILE* you get when fopening your character device and disable I/O buffering for this one:

FILE* fh = fopen("/dev/my-char-device", "rb");
setvbuf(fh, NULL, _IONBF, 0);
share|improve this answer
+1 - however is the write guaranteed to flush libc buffer for printf? I always thought that it goes directly to kernel syscall but I cannot find in specification any information regarding the behaviour. – Maciej Piechotka Nov 8 '13 at 20:09
write doesn't know libc. I will add an example to my answer to illustrate this. – eepp Nov 8 '13 at 20:11
I figured it had to have something to do with buffering but didn't understand enough to know why this was occurring (and more specifically how to be able to request a specific # of bytes). Excellent explanation! Thanks. – DnRng Nov 8 '13 at 21:01

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