CS计算机代考程序代写 chain compiler c++ data structure ECS 150 – GDB tutorial

ECS 150 – GDB tutorial
Prof. Joël Porquet-Lupine
UC Davis – 2020/2021
Copyright © 2017-2021 Joël Porquet-Lupine – CC BY-NC-SA 4.0 International License /
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GDB
GNU project
Started by Richard Stallman in 1983
Free software, mass collaboration project in response to proprietary UNIX
Copyleft license: GNU GPL
User programs: text editor (Emacs), compiler (GCC toolchain), debugger (GDB), and various utilities (ls, grep, awk, make, etc.)
Kernel: GNU Hurd
GDB
GNU DeBugger
Supports many languages
Including C and C++
Inspection of program during execution
Execution flow
Data
Helps finding errors like segmentation fault
Read the fully-detailed manual: https://sourceware.org/gdb/current/onlinedocs/gdb/
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GDB usage
Compilation flags
Canonical compilation command line:
$ gcc [cflags] -o Optimize for speed (-O2)
$ gcc -Wall -Werror -O2 -o myprogram main.c Enable debugging support (-g)
$ gcc -Wall -Werror -g myprogram main.c
Not recommended to use debugging along with optimizations No optimization option is equivalent to -O0
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GDB usage
Makefile digression
During development, very useful to be able to debug your program
For production, probably better to disable the debug support and activate all possible optimization support
Reduce size of the executable (can easily be by 50%!) Increase performance (can also be by 50%!)
Makefile automation
ifeq ($(D),1)
CFLAGS += -g # Enable debugging else
CFLAGS += -O2 # Enable optimization endif
Building mode
$ make D=1 # compile with debug support and no optimization
$ make # compile with optimizations (production)
Probably want to use make clean when changing building mode
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GDB usage
Starting GDB
Start GDB, specify the program to debug
$ gdb

(gdb) file myprogram
Reading symbols from myprogram…done. (gdb)
Or, start GDB with the program to debug as argument
$ gdb myprogram

Reading symbols from myprogram…done. (gdb)
Running the program
Without any argument:
(gdb) run
With arguments:
(gdb) run argv1 argv2…
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GDB usage
Interactive help
GDB offers an interactive shell
History management Auto-complete (with TAB)
In order to discover what you can do, just ask:
(gdb) help
List of classes of commands:
aliases — Aliases of other commands
breakpoints — Making program stop at certain points …
(gdb) help breakpoints
Making program stop at certain points.
List of commands:
awatch — Set a watchpoint for an expression break — Set breakpoint at specified location …
(gdb) help break
Set breakpoint at specified location.
break [PROBE_MODIFIER] [LOCATION] [thread THREADNUM] [if CONDITION] …
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GDB usage
Possible scenarios
1. Program doesn’t have bugs:
It will run fine until completion 2. Best-case scenario, regarding bugs:
Segmentation fault 3. Worst-case scenario:
Doesn’t crash but wrong result
Bugs that don’t trigger any segmentation fault
In this case, you’ll probably have to spend more time…
$ ./myprogram
I worked, hurray!
$ ./myprogram
segmentation fault (core dumped) ./myprogram
$ ./myprogram
I work��, ��rray!
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Segmentation faults
Example #1
#include #include #include
size_t foo_len (const char *s) {
return strlen(s); }
int main (int argc, char *argv[]) {
char *a = NULL;
printf (“size of a = %d\n”, foo_len(a));
return 0; }
Execution
$ ./strlen-test
zsh: segmentation fault (core dumped) ./strlen-test
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Segmentation faults
Run with GDB
(After compiling the code with -g)
$ gdb ./strlen-test
(gdb) run
Starting program: /home/joel/tmp/test/strlen-test
Program received signal SIGSEGV, Segmentation fault.
0x00007ffff7abc446 in strlen () from /usr/lib/libc.so.6
(gdb)
Backtrace
First thing to do when getting a segfault:
Understand what is the sequence of calls that brought us there
Investigate
foo_len() is supposed to receive a pointer
Here it receives 0 (aka NULL)
Looks like this NULL pointer probably gets dereferenced in strlen()…
(gdb) backtrace # use just ‘bt’
#0 0x00007ffff7abc446 in strlen () from /usr/lib/libc.so.6
#1 0x000000000040055e in foo_len (s=0x0) at strlen-test.c:7
#2 0x0000000000400583 in main (argc=1, argv=0x7fffffffd788) at strlen-test.c:14
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Segmentation faults
Fix…
Here, the problem is fairly obvious
size_t foo_len (const char *s) {
return strlen(s); }
int main (int argc, char *argv[]) {
char *a = “This is a valid string”;
printf (“size of a = %d\n”, foo_len(a));
return 0; }
And, celebrate!
$ ./strlen-test size of a = 22
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Segmentation faults
Better fix
Prevent the same bug from happening again
size_t foo_len (const char *s) {
assert(s && “String cannot be NULL here!”);
return strlen(s); }
int main (int argc, char *argv[]) {
char *a = NULL;
printf (“size of a = %d\n”, foo_len(a));
return 0; }
$ ./strlen-test
strlen-test: strlen-test.c:8: foo_len:
Assertion `s && “String cannot be NULL here!”‘ failed.
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Segmentation faults
Example #2
#include #include
const static int len = 10;
int main(void) {
int *tab; unsigned int i;
tab = malloc(len * sizeof(int)); for (i = len – 1; i >= 0; i–)
tab[i] = i;
free(tab);
return 0; }
Execution
$ ./tablen-test
segmentation fault (core dumped) ./tablen-test
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Segmentation faults
Run GDB
$ gdb ./tablen-test
(gdb) run
Starting program: /home/joel/tmp/test/tablen-test
Program received signal SIGSEGV, Segmentation fault.
0x0000000000400535 in main () at tablen-test.c:14
14 tab[i] = i;
Backtrace
Except that here, it’s not much of help…
Inspect variables
Display index i so that we know which index in the array was being accessed:
(gdb) bt
#0 0x0000000000400535 in main () at tablen-test.c:14
(gdb) print i $1 = 4294967295
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Segmentation faults
Fix…
Problem is a case of overflow
An unsigned int type automatically wraps from 0 to 4294967295
#include #include
const static int len = 10;
int main(void) {
int *tab; int i;
tab = malloc(len * sizeof(int)); for (i = len – 1; i >= 0; i–)
tab[i] = i;
free(tab);
return 0; }
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Tracking bugs
Behavior bugs
Behavioral bugs more complicated to find because program doesn’t crash It’s just that the output is wrong
#include #include #include
int main(void)
{
int i;
char str[] = “Tracking bugs is my passion”;
printf(“Before: %s\n”, str);
for (i = 0; i < strlen(str) - 1; i++) str[i] = toupper(str[i]); printf("After: %s\n", str); return 0; } Execution Before: Tracking bugs is my passion After: TRACKING BUGS IS MY PASSIOn 15 / 24 / Tracking bugs Setting breakpoints Stop the program during the execution at a designated point Set as many breakpoints as necessary GDB will always stop the execution when reaching them Breaking at exact location in code (gdb) break string-test.c:13 Breakpoint 1 at 0x4005ef: file string-test.c, line 13. (gdb) r Starting program: /home/joel/tmp/test/string-test Before: Tracking bugs is my passion Breakpoint 1, main () at string-test.c:13 13 str[i] = toupper(str[i]); 16 / 24 / Tracking bugs Breaking at a particular function (gdb) b main Breakpoint 1 at 0x40059f: file string-test.c, line 8. (gdb) r Starting program: /home/joel/tmp/test/string-test Breakpoint 1, main () at string-test.c:8 8 char str[] = "Tracking bugs is my passion"; Breaking only if condition is satisfied (gdb) b string-test.c:13 if i == 5 Breakpoint 1 at 0x4005ef: file string-test.c, line 13. (gdb) r Starting program: /home/joel/tmp/test/string-test Before: Tracking bugs is my passion Breakpoint 1, main () at string-test.c:13 13 str[i] = toupper(str[i]); (gdb) print i $1 = 5 17 / 24 / Tracking bugs Dealing with breakpoints Set at least one breakpoint before running the program Otherwise the program will run until completion Once the program stops and the gdb shell is available, a few options: 1. Continue the execution until hitting the same or another breakpoint (gdb) continue # or just 'c' 2. Execute only the next line of code and break again (gdb) step # or just 's' Careful, step enters function calls 3. Jump over function calls (gdb) next # or just 'n' Tip: typing in the interactive GDB shell repeats the last command
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Tracking bugs
Printing variables
int a = 2;
char b = ‘x’;
int *c = &a;
char *s = “A string”;

// <= breaking here print Inspect the value of all your variables with command Default By default, prints variables according to their type Tweak Can tweak both the way print prints and what it prints (gdb) print a $1 = 2 (gdb) p b $2 = 120 'x' (gdb) p c $3 = (int *) 0x7fffffffd65c (gdb) p s $4 = 0x40070b "A string" (gdb) print /x a $1 = 0x2 (gdb) p /c b+2 $2 = 122 'z' (gdb) p *c $3 = 2 (gdb) p s[0] $4 = 65 'A' 19 / 24 / Tracking bugs Printing data structures struct entry { int key; char *name; } obj = { .key = 2, .name = "toto", }; struct entry *e = &obj; print With , you can access the pointer and the object it's pointing to: (gdb) print e $1 = (struct entry *) 0x7fffffffd640 (gdb) print &obj $2 = (struct entry *) 0x7fffffffd640 (gdb) p *e $3 = {key = 2, name = 0x400734 "toto"} (gdb) p e->key
$4 = 2
(gdb) p obj.name
$5 = 0x400734 “toto”
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Misc
Setting watchpoint
Breakpoints are for interrupting the execution flow at a specific location Watchpoints are for interrupting the program when a variable is modified
(gdb) watch i
Hardware watchpoint 2: i
(gdb) c
Continuing.
Before: Tracking bugs is my passion
Hardware watchpoint 2: i
Old value = 0
New value = 1
0x0000000000400612 in main () at string-test.c:12
12 for (i = 0; i < strlen(str) - 1; i++) 21 / 24 / Misc Other useful commands finish Runs until the current function is finished until When executed in a loop, continues the execution until the loop ends info breakpoints Shows informations about all declared breakpoints (gdb) info b Num Type Disp Enb Address What 1 breakpoint keep y 0x000000000040059f in main at string-test.c:8 breakpoint already hit 1 time 2 hw watchpoint keep y i breakpoint already hit 2 times delete Deletes a breakpoint 22 / 24 / Valgrind Example #include void f(void)
{
int *x = malloc(10 * sizeof(int));
x[10] = 0; }
int main(void) {
f();
return 0; }
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Valgrind
Run
$ valgrind –leak-check=full ./valgrind_example

==31134== Invalid write of size 4
==31134== at 0x108668: f (in /home/joel/work/ecs150/slides/tuto_gdb/code/valgrind_example) ==31134== by 0x108679: main (in /home/joel/work/ecs150/slides/tuto_gdb/code/valgrind_example) ==31134== Address 0x51f0068 is 0 bytes after a block of size 40 alloc’d
==31134==
==31134==
==31134==
==31134==
==31134==
==31134== HEAP SUMMARY:
==31134== in use at exit: 40 bytes in 1 blocks
==31134== total heap usage: 1 allocs, 0 frees, 40 bytes allocated
==31134==
at 0x4C2CEDF: malloc (vg_replace_malloc.c:299)
by 0x10865B: f (in /home/joel/work/ecs150/slides/tuto_gdb/code/valgrind_example)
by 0x108679: main (in /home/joel/work/ecs150/slides/tuto_gdb/code/valgrind_example)
==31134== 40 bytes in 1 blocks are definitely lost in loss record 1 of 1
==31134==
==31134==
==31134==
==31134==
==31134== LEAK SUMMARY:
at 0x4C2CEDF: malloc (vg_replace_malloc.c:299)
by 0x10865B: f (in /home/joel/work/ecs150/slides/tuto_gdb/code/valgrind_example)
by 0x108679: main (in /home/joel/work/ecs150/slides/tuto_gdb/code/valgrind_example)
==31134==
==31134==
==31134==
==31134==
==31134==
==31134==
==31134== For counts of detected and suppressed errors, rerun with: -v
==31134== ERROR SUMMARY: 2 errors from 2 contexts (suppressed: 0 from 0)
definitely lost: 40 bytes in 1 blocks
indirectly lost: 0 bytes in 0 blocks
possibly lost: 0 bytes in 0 blocks
still reachable: 0 bytes in 0 blocks
suppressed: 0 bytes in 0 blocks
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