When checking the disassembly of the object file through the readelf
, I see the data
and the bss
segments contain the same offset address.
The data
section will contain the initialized global and static variables. BSS will contain un-initialized global and static variables.
1 #include<stdio.h>
2
3 static void display(int i, int* ptr);
4
5 int main(){
6 int x = 5;
7 int* xptr = &x;
8 printf("\n In main() program! \n");
9 printf("\n x address : 0x%x x value : %d \n",(unsigned int)&x,x);
10 printf("\n xptr points to : 0x%x xptr value : %d \n",(unsigned int)xptr,*xptr);
11 display(x,xptr);
12 return 0;
13 }
14
15 void display(int y,int* yptr){
16 char var[7] = "ABCDEF";
17 printf("\n In display() function \n");
18 printf("\n y value : %d y address : 0x%x \n",y,(unsigned int)&y);
19 printf("\n yptr points to : 0x%x yptr value : %d \n",(unsigned int)yptr,*yptr);
20 }
output:
SSS:~$ size a.out
text data bss dec hex filename
1311 260 8 1579 62b a.out
Here in the above program I don't have any un-initialized data but the BSS has occupied 8 bytes. Why does it occupy 8 bytes? Also when I disassemble the object file,
EDITED :
[ 3] .data PROGBITS 00000000 000110 000000 00 WA 0 0 4
[ 4] .bss NOBITS 00000000 000110 000000 00 WA 0 0 4
[ 5] .rodata PROGBITS 00000000 000110 0000cf 00 A 0 0 4
data
, rodata
and bss
has the same offset address. Does it mean the rodata
, data
and bss
refer to the same address?
Do Data section, rodata section and the bss section contain the data values in the same address, if so how to distinguish the data section, bss section and rodata section?
The .bss
section is guaranteed to be all zeros when the program is loaded into memory. So any global data that is uninitialized, or initialized to zero is placed in the .bss
section. For example:
static int g_myGlobal = 0; // <--- in .bss section
The nice part about this is, the .bss
section data doesn't have to be included in the ELF file on disk (ie. there isn't a whole region of zeros in the file for the .bss
section). Instead, the loader knows from the section headers how much to allocate for the .bss
section, and simply zero it out before handing control over to your program.
Notice the readelf
output:
[ 3] .data PROGBITS 00000000 000110 000000 00 WA 0 0 4
[ 4] .bss NOBITS 00000000 000110 000000 00 WA 0 0 4
.data
is marked as PROGBITS
. That means there are "bits" of program data in the ELF file that the loader needs to read out into memory for you. .bss
on the other hand is marked NOBITS
, meaning there's nothing in the file that needs to be read into memory as part of the load.
Example:
// bss.c
static int g_myGlobal = 0;
int main(int argc, char** argv)
{
return 0;
}
Compile it with $ gcc -m32 -Xlinker -Map=bss.map -o bss bss.c
Look at the section headers with $ readelf -S bss
Section Headers:
[Nr] Name Type Addr Off Size ES Flg Lk Inf Al
[ 0] NULL 00000000 000000 000000 00 0 0 0
:
[13] .text PROGBITS 080482d0 0002d0 000174 00 AX 0 0 16
:
[24] .data PROGBITS 0804964c 00064c 000004 00 WA 0 0 4
[25] .bss NOBITS 08049650 000650 000008 00 WA 0 0 4
:
Now we look for our variable in the symbol table: $ readelf -s bss | grep g_myGlobal
37: 08049654 4 OBJECT LOCAL DEFAULT 25 g_myGlobal
Note that g_myGlobal
is shown to be a part of section 25. If we look back in the section headers, we see that 25 is .bss
.
To answer your real question:
Here in the above program I dont have any un-intialised data but the BSS has occupied 8 bytes. Why does it occupy 8 bytes ?
Continuing with my example, we look for any symbol in section 25:
$ readelf -s bss | grep 25
9: 0804825c 0 SECTION LOCAL DEFAULT 9
25: 08049650 0 SECTION LOCAL DEFAULT 25
32: 08049650 1 OBJECT LOCAL DEFAULT 25 completed.5745
37: 08049654 4 OBJECT LOCAL DEFAULT 25 g_myGlobal
The third column is the size. We see our expected 4-byte g_myGlobal
, and this 1-byte completed.5745
. This is probably a function-static variable from somewhere in the C runtime initialization - remember, a lot of "stuff" happens before main()
is ever called.
4+1=5 bytes. However, if we look back at the .bss
section header, we see the last column Al
is 4. That is the section alignment, meaning this section, when loaded, will always be a multiple of 4 bytes. The next multiple up from 5 is 8, and that's why the .bss
section is 8 bytes.
Additionally We can look at the map file generated by the linker to see what object files got placed where in the final output.
.bss 0x0000000008049650 0x8
*(.dynbss)
.dynbss 0x0000000000000000 0x0 /usr/lib/gcc/x86_64-redhat-linux/4.7.2/../../../../lib/crt1.o
*(.bss .bss.* .gnu.linkonce.b.*)
.bss 0x0000000008049650 0x0 /usr/lib/gcc/x86_64-redhat-linux/4.7.2/../../../../lib/crt1.o
.bss 0x0000000008049650 0x0 /usr/lib/gcc/x86_64-redhat-linux/4.7.2/../../../../lib/crti.o
.bss 0x0000000008049650 0x1 /usr/lib/gcc/x86_64-redhat-linux/4.7.2/32/crtbegin.o
.bss 0x0000000008049654 0x4 /tmp/ccKF6q1g.o
.bss 0x0000000008049658 0x0 /usr/lib/libc_nonshared.a(elf-init.oS)
.bss 0x0000000008049658 0x0 /usr/lib/gcc/x86_64-redhat-linux/4.7.2/32/crtend.o
.bss 0x0000000008049658 0x0 /usr/lib/gcc/x86_64-redhat-linux/4.7.2/../../../../lib/crtn.o
Again, the third column is the size.
We see 4 bytes of .bss
came from /tmp/ccKF6q1g.o
. In this trivial example, we know that is the temporary object file from the compilation of our bss.c file. The other 1 byte came from crtbegin.o
, which is part of the C runtime.
Finally, since we know that this 1 byte mystery bss variable is from crtbegin.o
, and it's named completed.xxxx
, it's real name is completed
and it's probably a static inside some function. Looking at crtstuff.c
we find the culprit: a static _Bool completed
inside of __do_global_dtors_aux()
.