I'm using libcurl in my program, and running into a segfault. Before I filed a bug with the curl project, I thought I'd do a little debugging. What I found seemed very odd to me, and I haven't been able to make sense of it yet.
First, the segfault traceback:
Program received signal SIGSEGV, Segmentation fault. [Switching to Thread 0x7fffe77f6700 (LWP 592)] 0x00007ffff6a2ea5c in memcpy () from /lib/x86_64-linux-gnu/libc.so.6 (gdb) bt #0 0x00007ffff6a2ea5c in memcpy () from /lib/x86_64-linux-gnu/libc.so.6 #1 0x00007ffff5bc29e5 in x509_name_oneline (a=0x7fffe3d9c3c0, buf=0x7fffe77f4ec0 "C=US; O=The Go Daddy Group, Inc.; OU=Go Daddy Class 2 Certification Authority\375\034<M_r\206\233\261\310\340\371\023.Jg\205\244\304\325\347\372\016#9Ph%", size=255) at ssluse.c:629 #2 0x00007ffff5bc2a6f in cert_verify_callback (ok=1, ctx=0x7fffe77f50b0) at ssluse.c:645 #3 0x00007ffff72c9a80 in ?? () from /lib/libcrypto.so.0.9.8 #4 0x00007ffff72ca430 in X509_verify_cert () from /lib/libcrypto.so.0.9.8 #5 0x00007ffff759af58 in ssl_verify_cert_chain () from /lib/libssl.so.0.9.8 #6 0x00007ffff75809f3 in ssl3_get_server_certificate () from /lib/libssl.so.0.9.8 #7 0x00007ffff7583e50 in ssl3_connect () from /lib/libssl.so.0.9.8 #8 0x00007ffff5bc48f0 in ossl_connect_step2 (conn=0x7fffe315e9a8, sockindex=0) at ssluse.c:1724 #9 0x00007ffff5bc700f in ossl_connect_common (conn=0x7fffe315e9a8, sockindex=0, nonblocking=false, done=0x7fffe77f543f) at ssluse.c:2498 #10 0x00007ffff5bc7172 in Curl_ossl_connect (conn=0x7fffe315e9a8, sockindex=0) at ssluse.c:2544 #11 0x00007ffff5ba76b9 in Curl_ssl_connect (conn=0x7fffe315e9a8, sockindex=0) ...
The call to memcpy looks like this:
memcpy(buf, biomem->data, size); (gdb) p buf $46 = 0x7fffe77f4ec0 "C=US; O=The Go Daddy Group, Inc.; OU=Go Daddy Class 2 Certification Authority\375\034<M_r\206\233\261\310\340\371\023.Jg\205\244\304\325\347\372\016#9Ph%" (gdb) p biomem->data $47 = 0x7fffe3e1ef60 "C=US; O=The Go Daddy Group, Inc.; OU=Go Daddy Class 2 Certification Authority\375\034<M_r\206\233\261\310\340\371\023.Jg\205\244\304\325\347\372\016#9Ph%" (gdb) p size $48 = 255
If I go up a frame, I see that the pointer passed in for buf came from a local variable defined in the calling function:
Here's where it starts to get weird. I can manually inspect all 256 bytes of both buf and biomem->data without gdb complaining that the memory isn't accesible. I can also manually write all 256 bytes of buf using the gdb set command, without any error. So if all the memory involved is readable and writable, why does memcpy fail?
Also interesting is that I can use gdb to manually call memcpy with the pointers involved. As long as I pass a size <= 160, it runs without a problem. As soon as I pass 161 or higher, gdb gets a sigsegv. I know buf is larger than 160, because it was created on the stack as an array of 256. biomem->data is a little harder to figure, but I can read well past byte 160 with gdb.
I should also mention that this function (or rather the curl method I call that leads to this) completes successfully many times before the crash. My program uses curl to repeatedly call a web service API while it runs. It calls the API every five seconds or so, and runs for about 14 hours before it crashes. It's possible that something else in my app is writing out of bounds and stomping on something that creates the error condition. But it seems suspicious that it crashes at exactly the same point every time, although the timing varies. And all the pointers seem ok in gdb, but memcpy still fails. Valgrind doesn't find any bounds errors, but I haven't let my program run with valgrind for 14 hours.
Within memcpy itself, the disassembly looks like this:
(gdb) x/20i $rip-10 0x7ffff6a2ea52 <memcpy+242>: jbe 0x7ffff6a2ea74 <memcpy+276> 0x7ffff6a2ea54 <memcpy+244>: lea 0x20(%rdi),%rdi 0x7ffff6a2ea58 <memcpy+248>: je 0x7ffff6a2ea90 <memcpy+304> 0x7ffff6a2ea5a <memcpy+250>: dec %ecx => 0x7ffff6a2ea5c <memcpy+252>: mov (%rsi),%rax 0x7ffff6a2ea5f <memcpy+255>: mov 0x8(%rsi),%r8 0x7ffff6a2ea63 <memcpy+259>: mov 0x10(%rsi),%r9 0x7ffff6a2ea67 <memcpy+263>: mov 0x18(%rsi),%r10 0x7ffff6a2ea6b <memcpy+267>: mov %rax,(%rdi) 0x7ffff6a2ea6e <memcpy+270>: mov %r8,0x8(%rdi) 0x7ffff6a2ea72 <memcpy+274>: mov %r9,0x10(%rdi) 0x7ffff6a2ea76 <memcpy+278>: mov %r10,0x18(%rdi) 0x7ffff6a2ea7a <memcpy+282>: lea 0x20(%rsi),%rsi 0x7ffff6a2ea7e <memcpy+286>: lea 0x20(%rdi),%rdi 0x7ffff6a2ea82 <memcpy+290>: jne 0x7ffff6a2ea30 <memcpy+208> 0x7ffff6a2ea84 <memcpy+292>: data32 data32 nopw %cs:0x0(%rax,%rax,1) 0x7ffff6a2ea90 <memcpy+304>: and $0x1f,%edx 0x7ffff6a2ea93 <memcpy+307>: mov -0x8(%rsp),%rax 0x7ffff6a2ea98 <memcpy+312>: jne 0x7ffff6a2e969 <memcpy+9> 0x7ffff6a2ea9e <memcpy+318>: repz retq (gdb) info registers rax 0x0 0 rbx 0x7fffe77f50b0 140737077268656 rcx 0x1 1 rdx 0xff 255 rsi 0x7fffe3e1f000 140737016623104 rdi 0x7fffe77f4f60 140737077268320 rbp 0x7fffe77f4e90 0x7fffe77f4e90 rsp 0x7fffe77f4e48 0x7fffe77f4e48 r8 0x11 17 r9 0x10 16 r10 0x1 1 r11 0x7ffff6a28f7a 140737331236730 r12 0x7fffe3dde490 140737016358032 r13 0x7ffff5bc2a0c 140737316137484 r14 0x7fffe3d69b50 140737015880528 r15 0x0 0 rip 0x7ffff6a2ea5c 0x7ffff6a2ea5c <memcpy+252> eflags 0x10203 [ CF IF RF ] cs 0x33 51 ss 0x2b 43 ds 0x0 0 es 0x0 0 fs 0x0 0 gs 0x0 0 (gdb) p/x $rsi $50 = 0x7fffe3e1f000 (gdb) x/20x $rsi 0x7fffe3e1f000: 0x00000000 0x00000000 0x00000000 0x00000000 0x7fffe3e1f010: 0x00000000 0x00000000 0x00000000 0x00000000 0x7fffe3e1f020: 0x00000000 0x00000000 0x00000000 0x00000000 0x7fffe3e1f030: 0x00000000 0x00000000 0x00000000 0x00000000 0x7fffe3e1f040: 0x00000000 0x00000000 0x00000000 0x00000000
I'm using libcurl version 7.21.6, c-ares version 1.7.4, and openssl version 1.0.0d. My program is multithreaded, but I have registered mutex callbacks with openssl. The program is running on Ubuntu 11.04 desktop, 64-bit. libc is 2.13.