ARM Linux内核驱动异常定位方法分析--反汇编方式

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原文链接:http://blog.csdn.net/hunhunzi/article/details/7052032

最近在搞Atmel 的SAM9x25平台,Linux系统,用于工业设备。这也是我首次参与工业设备的研发。在调试Atmel SAM9x25的Linux串口设备的时候,发现无论是读还是写,都会产生异常。相关的异常信息如下:

==================================================================================================================

Unable to handle kernel NULL pointer dereference at virtual address 00000000
pgd = c0004000
[00000000] *pgd=00000000
Internal error: Oops: 17 [#1]
last sysfs file: /sys/devices/virtual/vc/vcsa1/dev
Modules linked in:
CPU: 0    Not tainted  (2.6.39 #1)
PC is at atmel_tasklet_func+0x110/0x69c
LR is at atmel_tasklet_func+0x10/0x69c
pc : []    lr : []    psr: 20000013
sp : c7825f50  ip : c045e0bc  fp : 00000000
r10: c0456a80  r9 : 0000000a  r8 : 00000000
r7 : c7874568  r6 : c045e0a8  r5 : 00000100  r4 : c045dfb4
r3 : 00000002  r2 : 00000ffc  r1 : 00000001  r0 : 00000001
Flags: nzCv  IRQs on  FIQs on  Mode SVC_32  ISA ARM  Segment kernel
Control: 0005317f  Table: 27aec000  DAC: 00000017
Process ksoftirqd/0 (pid: 3, stack limit = 0xc7824270)
Stack: (0xc7825f50 to 0xc7826000)
5f40:                                     00000100 c7824000 00000001 00000018
5f60: 0000000a c0456a80 c7825f84 00000000 00000100 c7824000 00000001 00000018
5f80: c0456a80 c0047b70 00000006 c0047650 c0432e50 00000000 c7824000 00000000
5fa0: 00000000 c0047938 00000000 00000000 00000000 c00479a0 c7825fd4 c7819f60
5fc0: 00000000 c0058c64 c00335f4 00000000 00000000 00000000 c7825fd8 c7825fd8
5fe0: 00000000 c7819f60 c0058be0 c00335f4 00000013 c00335f4 0c200050 fc3b9beb

[] (atmel_tasklet_func+0x110/0x69c) from [] (tasklet_action+0x80/0xe4)
[] (tasklet_action+0x80/0xe4) from [] (__do_softirq+0x74/0x104)
[] (__do_softirq+0x74/0x104) from [] (run_ksoftirqd+0x68/0x108)
[] (run_ksoftirqd+0x68/0x108) from [] (kthread+0x84/0x8c)
[] (kthread+0x84/0x8c) from [] (kernel_thread_exit+0x0/0x8)
Code: 1a000002 e59f057c e59f157c ebfa416c (e5983000) 
---[ end trace 6b8e1841ba3a56c9 ]---
Kernel panic - not syncing: Fatal exception in interrupt
[] (unwind_backtrace+0x0/0xf0) from [] (panic+0x54/0x178)
[] (panic+0x54/0x178) from [] (die+0x17c/0x1bc)
[] (die+0x17c/0x1bc) from [] (__do_kernel_fault+0x64/0x84)
[] (__do_kernel_fault+0x64/0x84) from [] (do_page_fault+0x1b8/0x1cc)
[] (do_page_fault+0x1b8/0x1cc) from [] (do_DataAbort+0x38/0x9c)
[] (do_DataAbort+0x38/0x9c) from [] (__dabt_svc+0x4c/0x60)
Exception stack(0xc7825f08 to 0xc7825f50)
5f00:                   00000001 00000001 00000ffc 00000002 c045dfb4 00000100
5f20: c045e0a8 c7874568 00000000 0000000a c0456a80 00000000 c045e0bc c7825f50
5f40: c01a4e30 c01a4f30 20000013 ffffffff
[] (__dabt_svc+0x4c/0x60) from [] (atmel_tasklet_func+0x110/0x69c)
[] (atmel_tasklet_func+0x110/0x69c) from [] (tasklet_action+0x80/0xe4)
[] (tasklet_action+0x80/0xe4) from [] (__do_softirq+0x74/0x104)
[] (__do_softirq+0x74/0x104) from [] (run_ksoftirqd+0x68/0x108)
[] (run_ksoftirqd+0x68/0x108) from [] (kthread+0x84/0x8c)
[] (kthread+0x84/0x8c) from [] (kernel_thread_exit+0x0/0x8)

==================================================================================================================

通常认为,产生异常的地址是lr寄存器的值,从上面的异常信息可以看到[lr]的值是c01a4e30。

接下来,我们可以通过内核镜像文件反汇编来找到这个地址。内核编译完成后,会在内核代码根目录下生成vmlinux文件,我们可以通过以下命令来反汇编:

arm-none-eabi-objdump -Dz -S vmlinux >linux.dump

值得注意的是,arm-none-eabi-objdump的参数-S表示尽可能的把原来的代码和反汇编出来的代码一起呈现出来,-S参数需要结合arm-linux-gcc编译参数-g,才能达到反汇编时同时输出原来的代码。所以,我在linux内核代码根目录的Makefile中增加-g编译参数:

KBUILD_CFLAGS   := -g -Wall -Wundef -Wstrict-prototypes -Wno-trigraphs \
     -fno-strict-aliasing -fno-common \
     -Werror-implicit-function-declaration \
     -Wno-format-security \
     -fno-delete-null-pointer-checks

修改Makefile后,重新编译内核,在根目录中生成的vmlinux文件就会包含了原来的代码信息,因此,该文件的大小也比原来大一倍!

最后执行“arm-none-eabi-objdump -Dz-S vmlinux >linux.dump”,由于加入了-g编译参数,执行这个反汇编命令需要很长时间(本人在虚拟机上执行,花了近6个小时!),反汇编出来的linux.dump文件也比原来的44MB增大到惊人的503MB。

接下来可以用UltraEdit打开linux.dump文件,查找“c01a4e30”字符串。

最后定位到的信息是:

==================================================================================================================

/*
 * tasklet handling tty stuff outside the interrupt handler.
 */
static void atmel_tasklet_func(unsigned long data)
{
c01a4e20: e92d45f0  push {r4, r5, r6, r7, r8, sl, lr}
c01a4e24: e24dd01c  sub sp, sp, #28 ; 0x1c
c01a4e28: e1a04000  mov r4, r0
 /* The interrupt handler does not take the lock */
 spin_lock(&port->lock);

 if (atmel_use_pdc_tx(port))
  atmel_tx_pdc(port);
 else if (atmel_use_dma_tx(port))
c01a4e2c: ebfffda1  bl c01a44b8
c01a4e30: e3500000  cmp r0, #0 ; 0x0
c01a4e34: e5943034  ldr r3, [r4, #52]
c01a4e38: 0a00007b  beq c01a502c

==================================================================================================================

可以看出来,异常的产生位于atmel_tasklet_func函数的 else if (atmel_use_dma_tx(port))一行

估计atmel_use_dma_tx(port)的“port”参数为空指针所致!

 

最后,我把串口的DMA功能去掉,改为直接传送,这样做虽然效率低了点,但产生异常的现象消失了。

到后面再仔细分析为什么会产生这个异常,彻底解决这个问题。

 

关键字:ARM atmel  SAM9x25 Linux内核驱动异常 调试 反汇编 objdump


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