A core dump is the recorded state of the working memory of a computer program at a specific time, generally when the program has terminated abnormally (crashed).[1] In practice, other key pieces of program state are usually dumped at the same time, including the processor registers, which may include the program counter and stack pointer, memory management information, and other processor and operating system flags and information. The name comes from the once-standard memory technology core memory. Core dumps are often used to diagnose or debug errors in computer programs.
On many operating systems, a fatal error in a program automatically triggers a core dump, and by extension the phrase "to dump core" has come to mean, in many cases, any fatal error, regardless of whether a record of the program memory is created.
The term is used in jargon to indicate any circumstance where large amounts of unedited data are deposited for further examination.
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先看看我用的是个什么机器:
$ uname -a
Linux dev 2.4.21-9.30AXsmp #1 SMP Wed May 26 23:37:09 EDT 2004 i686 i686 i386 GNU/Linux
再看看默认的一些参数,注意core file size是个0,程序出错时不会产生core文件了。
$ ulimit -a
core file size (blocks, -c) 0
data seg size (kbytes, -d) unlimited
file size (blocks, -f) unlimited
max locked memory (kbytes, -l) 4
max memory size (kbytes, -m) unlimited
open files (-n) 2048
pipe size (512 bytes, -p) 8
stack size (kbytes, -s) 10240
cpu time (seconds, -t) unlimited
max user processes (-u) 7168
virtual memory (kbytes, -v) unlimited
写个简单的程序,看看core文件是不是会被产生。
$ more foo.c
#include <stdio.h>
static void sub(void);
int main(void)
{
sub();
return 0;
}
static void sub(void)
{
int *p = NULL;
/* derefernce a null pointer, expect core dump. */
printf("%d", *p);
}
$ gcc -Wall -g foo.c
$ ./a.out
Segmentation fault
$ ls -l core.*
ls: core.*: No such file or directory
没有找到core文件,我们改改ulimit的设置,让它产生。1024是随便取的,要是core文件大于1024个块,就产生不出来了。
$ ulimit -c 1024 (转者注: 使用-c unlimited不限制core文件大小)
$ ulimit -a
core file size (blocks, -c) 1024
data seg size (kbytes, -d) unlimited
file size (blocks, -f) unlimited
max locked memory (kbytes, -l) 4
max memory size (kbytes, -m) unlimited
open files (-n) 2048
pipe size (512 bytes, -p) 8
stack size (kbytes, -s) 10240
cpu time (seconds, -t) unlimited
max user processes (-u) 7168
virtual memory (kbytes, -v) unlimited
$ ./a.out
Segmentation fault (core dumped)
$ ls -l core.*
-rw------- 1 uniware uniware 53248 Jun 30 17:10 core.9128
注意看上述的输出信息,多了个(core dumped)。确实产生了一个core文件,9128是该进程的PID。我们用GDB来看看这个core。
$ gdb --core=core.9128
GNU gdb Asianux (6.0post-0.20040223.17.1AX)
Copyright 2004 Free Software Foundation, Inc.
GDB is free software, covered by the GNU General Public License, and you are
welcome to change it and/or distribute copies of it under certain conditions.
Type "show copying" to see the conditions.
There is absolutely no warranty for GDB. Type "show warranty" for details.
This GDB was configured as "i386-asianux-linux-gnu".
Core was generated by `./a.out'.
Program terminated with signal 11, Segmentation fault.
#0 0x08048373 in ?? ()
(gdb) bt
#0 0x08048373 in ?? ()
#1 0xbfffd8f8 in ?? ()
#2 0x0804839e in ?? ()
#3 0xb74cc6b3 in ?? ()
#4 0x00000000 in ?? ()
此时用bt看不到backtrace,也就是调用堆栈,原来GDB还不知道符号信息在哪里。我们告诉它一下:
(gdb) file ./a.out
Reading symbols from ./a.out...done.
Using host libthread_db library "/lib/tls/libthread_db.so.1".
(gdb) bt
#0 0x08048373 in sub () at foo.c:17
#1 0x08048359 in main () at foo.c:8
此时backtrace出来了。
(gdb) l
8 sub();
9 return 0;
10 }
11
12 static void sub(void)
13 {
14 int *p = NULL;
15
16 /* derefernce a null pointer, expect core dump. */
17 printf("%d", *p);
下面文章转自:http://blog.csdn.net/wen0006/article/details/3945845
最来在项目中遇到大型程序出现SIGSEGV ,一直不知道用core dump工具来调试程序,花了近一周的时间,才定位问题,老大很生气,后果很严重,呵呵,事后仔细学习了这块的知识,了解一点core dump的知识。
在使用半导体作为内存的材料前,人类是利用线圈当作内存的材料(发明者为王安),线圈就叫作core ,用线圈做的内存就叫作“core memory”。(线圈的单词应该是coil,呵呵)如今,半导体工业澎勃发展,已经没有人用线圈当内存了,不过,在许多情况下,人们还是把内存叫作“core”。所以注意了:这里的core不是核心,而是内存。不过结合实际来看,好像也有点“内核所占内存”的意思。
core dump又是什么东东? 我们在开发(或使用)一个程序时,最怕的就是程序莫明其妙地挂掉。虽然系统没事,但我们下次仍可能遇到相同的问题。于是,这时操作系统就会把程序挂掉时的内存内容写入一个叫做core的文件里(这个写入的动作就叫dump,dump的英语意思是垃圾、倾倒。从这里来看,这些内存的内容是程序错误运行的结果,所以算是垃圾,把他弄出来就好比从大的内存池里“倾倒”。),以便于我们调试。这个过程,因此叫做core dump。
1. 在嵌入式系统中,有时core dump直接从串口打印出来,结合objdump查找ra和epa地址,运用栈回溯,可以找到程序出错的地方。
2. 在一般Linux系统中,默认是不会产生core dump文件的,通过ulimit -c来查看core dump文件的大小,一般开始是0,可以设置core文件大小,ulimit -c 1024(kbytes单位)或者ulimit -c unlimited。
3. core dump文件输出设置,一般默认是当前目录,可以在/proc/sys/kernel中找到core-user-pid,通过
echo "1" > /proc/sys/kernel/core-user-pid使core文件名加上pid号,还可以用
mkdir -p /root/corefile
echo "/root/corefile/core-%e-%p-%t" > /proc/sys/kernel/core-pattern控制core文件保存位置和文件名格式。
以下是参数列表:
%p - insert pid into filename 添加pid
%u - insert current uid into filename 添加当前uid
%g - insert current gid into filename 添加当前gid
%s - insert signal that caused the coredump into the filename 添加导致产生core的信号
%t - insert UNIX time that the coredump occurred into filename 添加core文件生成时的unix时间
%h - insert hostname where the coredump happened into filename 添加主机名
%e - insert coredumping executable name into filename 添加命令名
4. 用gdb查看core文件:
下面我们可以在发生运行时信号引起的错误时发生core dump了.编译时加上-g
发生core dump之后, 用gdb进行查看core文件的内容, 以定位文件中引发core dump的行.
gdb [exec file] [core file]
如:
gdb ./test test.core
在进入gdb后, 用bt命令查看backtrace以检查发生程序运行到哪里, 来定位core dump的文件行.
5. 给个例子
test.c
void a()
{
char *p = NULL;
printf("%d/n", *p);
}
int main()
{
a();
return 0;
}
编译 gcc -g -o test test.c
运行 ./test
报segmentation fault(core dump)
gdb ./test test.core如果生成的是test.core.