When __builtin_object_size(ptr, 1) is used in code compiled without optimization (-O0), it always returns -1. In order to get actual object size, code must be compiled with at least -O1. I would like to enable it at -O0 too, but so far I am unable to find which option enables it. I checked outputs printed generated by gcc executed with options -Q --help=optimizers, -Q --help=common and -Q --help=c and found which options are added by -O1. Unfortunately when I added them manually to command line, __builtin_object_size still returned -1.
Do you know if it is possible to somehow enable this feature when compiling at -O0?
I am using gcc 4.8.4 on Linux/x86_64.
For reference I am adding code which I used for testing:
#include <stdio.h>
#include <stdlib.h>
inline void f(const char* ptr)
{
printf("%d\n", (int)__builtin_object_size(ptr, 1));
}
int main()
{
char* buf = malloc(10);
f(buf);
return 0;
}
This is not possible, gcc does not run analysis passes necessary to compute result of __builtin_object_size at -O0.
Related
I am getting the following error
rudimentary_calc.c: In function ‘main’:
rudimentary_calc.c:9:6: error: conflicting types for ‘getline’
9 | int getline(char line[], int max) ;
| ^~~~~~~
In file included from rudimentary_calc.c:1:
/usr/include/stdio.h:616:18: note: previous declaration of ‘getline’ was here
616 | extern __ssize_t getline (char **__restrict __lineptr,
| ^~~~~~~
when I ran the following code
#include <stdio.h>
#define maxline 100
int main()
{
double sum, atof(char[]);
char line[maxline];
int getline(char line[], int max) ;
sum = 0;
while (getline(line, maxline) > 0)
printf("\t %g \n", sum += atof(line));
return 0;
}
What am I doing wrong? I am very new to C, so I don't know what went wrong.
Generally, you should not have to declare "built-in" functions as long as you #include the appropriate header files (in this case stdio.h). The compiler is complaining that your declaration is not exactly the same as the one in stdio.h.
The venerable K&R book defines a function named getline. The GNU C library also defines a non-standard function named getline. It is not compatible with the function defined in K&R. It is declared in the standard <stdio.h> header. So there is a name conflict (something that every C programmer has do deal with).
You can instruct GCC to ignore non-standard names found in standard headers. You need to supply a compilation flag such as -std=c99 or -std=c11 or any other std=c<year> flag that yout compiler supports.
Live demo
Always use one of these flags, plus at least -Wall, to compile any C code, including code from K&R. You may encounter some compiler warnings or even errors. This is good. Thy will tell you that there are some code constructs that were good in the days of K&R, but are considered problematic now. You want to know about those. The book is rather old and the best practices and the C language itself have evolved since.
I have a strange segmentation fault that doesn't exist when everything is in 1 .c file, but does exist when I put part of the code in a dynamically linked library and link it to a test file. The complete code for the working 1 .c file code is at the bottom, the complete code for the error system with 2 .c and 1 .h file come first.
Here is the error system:
example.h:
#include <stdio.h>
#include <stdlib.h>
typedef struct MYARRAY {
int len;
void* items[];
} MYARRAY;
MYARRAY *collection;
void
mypush(void* p);
example.c:
#include "example.h"
void
mypush(void* p) {
printf("Here %lu\n", sizeof collection);
puts("FOO");
int len = collection->len++;
puts("BAR");
collection->items[len] = p;
}
example2.c:
This is essentially a test file:
#include "example.h"
void
test_print() {
puts("Here1");
mypush("foo");
puts("Here2");
}
int
main() {
collection = malloc(sizeof *collection + (sizeof collection->items[0] * 1000));
collection->len = 0;
puts("Start");
test_print();
puts("Done");
return 0;
}
Makefile:
I link example to example2 here, and run:
example:
#clang -I . -dynamiclib \
-undefined dynamic_lookup \
-o example.dylib example.c
#clang example2.c example.dylib -o example2.o
#./example2.o
.PHONY: example
The output is:
$ make example
Start
Here1
Here 8
FOO
make: *** [example] Segmentation fault: 11
But it should show the full output of:
$ make example
Start
Here1
Here 8
FOO
BAR
Here2
Done
The weird thing is everything works if it is this system:
example.c:
#include <stdio.h>
#include <stdlib.h>
typedef struct MYARRAY {
int len;
void* items[];
} MYARRAY;
MYARRAY *collection;
void
mypush(void* p) {
printf("Here %lu\n", sizeof collection);
puts("FOO");
int len = collection->len++;
puts("BAR");
collection->items[len] = p;
}
void
test_print() {
puts("Here1");
mypush("foo");
puts("Here");
}
int
main() {
collection = malloc(sizeof *collection + (sizeof collection->items[0] * 1000));
collection->len = 0;
puts("ASF");
test_print();
return 0;
}
Makefile:
example:
#clang -o example example.c
#./example
.PHONY: example
Wondering why it's creating a segmentation fault when it is linked like this, and what I am doing wrong.
I have checked otool and with DYLD_PRINT_LIBRARIES=YES and it shows it is importing the dynamically linked libraries, but for some reason it's segmentation faulting when linked but works fine when it isn't linked.
Your problem is this, in example.h:
MYARRAY *collection;
Since both main.c and example.c include this file, you end up defining collection twice, which results in undefined behavior. You need to make sure you define each object only once. The details are relatively unimportant since anything can happen with undefined behavior, but what's probably happening is that main.c is allocating memory for one object, but the one example.c is using is still NULL. As mentioned in the comments, since you define collection in main.c your linker is able to build the executable without needing to look for that symbol in the dynamic library, so you don't get a link time warning about it being defined there too, and obviously there'd be no cause for a warning at the time you compile the library.
It works for you when you put everything in one file because obviously then you're not defining anything twice, anymore. The error itself is nothing to do with the fact you're using a dynamic library, although that may have made it harder to detect.
It would be better to define this in example.c and provide a constructor function, there's no need for main() to be able to access it directly. But if you must do this, then define it in example.c and just declare an extern identifier in the header file to tell main.c that the object is defined somewhere else.
I am trying to run sample rsa/dsa code using libtomcrypt.
I have installed LibTomMath first as make install, as a result following files are created.
/usr/lib/libtommath.a
/usr/include/tommath.h
After that I installed libtomcrypt with LibTomMath as external library
CFLAGS="-DLTM_DESC -DUSE_LTM -I/usr/include" EXTRALIBS="/usr/lib/libtommath.a " make install
As a result following file is created
/usr/lib/libtomcrypt.a
I am not getting any error while running following command
CFLAGS="-DLTM_DESC -DUSE_LTM -I/usr/include" EXTRALIBS="/usr/lib/libtommath.a " make test
I have gone through this document libtomcrypt_installation and libtomcrypt_resolved to successfully compile using
gcc -DLTM_DESC rsa_make_key_example.c -o rsa -ltomcrypt
or
gcc rsa_make_key_example.c -o rsa -ltomcrypt
no compile error. However when I try to run, I got following error.
./rsa
LTC_ARGCHK 'ltc_mp.name != NULL' failure on line 34 of file src/pk/rsa/rsa_make_key.c
Aborted
Here is my sample rsa code
#include <tomcrypt.h>
#include <stdio.h>
int main(void) {
# ifdef USE_LTM
ltc_mp = ltm_desc;
# elif defined (USE_TFM)
ltc_mp = tfm_desc;
# endif
rsa_key key;
int err;
register_prng(&sprng_desc);
if ((err = rsa_make_key(NULL, find_prng("sprng"), 1024/8, 65537,&key)) != CRYPT_OK) {
printf("make_key error: %s\n", error_to_string(err));
return -1;
}
/* use the key ... */
return 0;
}
Here is my sample dsa code
#include <tomcrypt.h>
#include <stdio.h>
int main(void) {
# ifdef USE_LTM
ltc_mp = ltm_desc;
# elif defined (USE_TFM)
ltc_mp = tfm_desc;
# endif
int err;
register_prng(&sprng_desc);
dsa_key key;
if ((err = dsa_make_key(NULL, find_prng("sprng"), 20, 128,&key)) != CRYPT_OK) {
printf("make_key error: %s\n", error_to_string(err));
return -1;
}
/* use the key ... */
return 0;
}
Here is how I have compiled it successfully,
gcc dsa_make_key_example.c -o dsa -ltomcrypt
When I try to run the code , I am getting following error .
./dsa
segmentation fault
EDIT 1:
I investigated further and found the reason for segmentation fault
#ifdef LTC_MPI
#include <stdarg.h>
int ltc_init_multi(void **a, ...)
{
...
...
if (mp_init(cur) != CRYPT_OK) ---> This line causes segmentation fault
Where am I making mistakes ? How to resolve this problem to run these programs successfully?
I am using linux , gcc. Any help/link will be highly appreciated. Thanks in advance.
It's been a year or so since this was asked, but I have some component of an answer, and a workaround.
The reason mp_init fails is that the "math_descriptor" is uninitialized. mp_init is a defined as
#define mp_init(a) ltc_mp.init(a)
where ltc_mp is a global struct (of type ltc_math_descriptor) that holds pointers to the math routines.
There are several implementations of the math routines available, and a user can choose which they want. For whatever reason, there does not seem to be a default math implementation chosen for certain builds of libtomcrypt. Thus, the init member of ltc_mp is null, and we get the SIGSEGV.
Here is a manual workaround:
You can make your desired ltc_math_descriptor struct available to your main() routine by #defineing one of
LTM_DESC -- built-in math lib
TFM_DESC -- an external fast math package
GMP_DESC -- presumably a GNU MultiPrecision implementation?
Before #include <tomcrypt.h> (or by using -D on the command-line).
Whichever you choose, a corresponding object will be declared:
extern const ltc_math_descriptor ltm_desc;
extern const ltc_math_descriptor tfm_desc;
extern const ltc_math_descriptor gmp_desc;
To use it, manually copy it to the global math descriptor:
E.g., in my case, for the local math imlpementation,
ltc_mp = ltm_desc;
Now libtomcrypt works.
Does gcc's inline __attribute__((__always_inline__)) generate warning, when compiler can't inline function?
Because VS does http://msdn.microsoft.com/en-us/library/z8y1yy88.aspx:
If the compiler cannot inline a function declared with __forceinline,
it generates a level 1 warning.
You need -Winline to get warnings about non-inlined functions.
If you want to verify this you can try taking the address of an inline function (which prevents it from being inlined) and then you should see a warning.
#include <stdio.h>
static inline __attribute__ ((always_inline)) int add(int a, int b)
{
return a + b;
}
int main(void)
{
printf("%d\n", add(21, 21));
printf("%p\n", add);
return 0;
}
EDIT
I've been trying to produce a warning with the above code and other examples without success - it seems that the behaviour of current versions of gcc and clang may have changed in this area. I'll delete this answer if I can't code up with a better example that generates a warning.
As this is my first post to stackoverflow I want to thank you all for your valuable posts that helped me a lot in the past.
I use MinGW (gcc 4.4.0) on Windows-7(64) - more specifically I use Nokia Qt + MinGW but Qt is not involved in my Question.
I need to find the address and -more important- the length of specific functions of my application at runtime, in order to encode/decode these functions and implement a software protection system.
I already found a solution on how to compute the length of a function, by assuming that static functions placed one after each other in a source-file, it is logical to be also sequentially placed in the compiled object file and subsequently in memory.
Unfortunately this is true only if the whole CPP file is compiled with option: "g++ -O0" (optimization level = 0).
If I compile it with "g++ -O2" (which is the default for my project) the compiler seems to relocate some of the functions and as a result the computed function length seems to be both incorrect and negative(!).
This is happening even if I put a "#pragma GCC optimize 0" line in the source file,
which is supposed to be the equivalent of a "g++ -O0" command line option.
I suppose that "g++ -O2" instructs the compiler to perform some global file-level optimization (some function relocation?) which is not avoided by using the #pragma directive.
Do you have any idea how to prevent this, without having to compile the whole file with -O0 option?
OR: Do you know of any other method to find the length of a function at runtime?
I prepare a small example for you, and the results with different compilation options, to highlight the case.
The Source:
// ===================================================================
// test.cpp
//
// Intention: To find the addr and length of a function at runtime
// Problem: The application output is correct when compiled with: "g++ -O0"
// but it's erroneous when compiled with "g++ -O2"
// (although a directive "#pragma GCC optimize 0" is present)
// ===================================================================
#include <stdio.h>
#include <math.h>
#pragma GCC optimize 0
static int test_01(int p1)
{
putchar('a');
putchar('\n');
return 1;
}
static int test_02(int p1)
{
putchar('b');
putchar('b');
putchar('\n');
return 2;
}
static int test_03(int p1)
{
putchar('c');
putchar('\n');
return 3;
}
static int test_04(int p1)
{
putchar('d');
putchar('\n');
return 4;
}
// Print a HexDump of a specific address and length
void HexDump(void *startAddr, long len)
{
unsigned char *buf = (unsigned char *)startAddr;
printf("addr:%ld, len:%ld\n", (long )startAddr, len);
len = (long )fabs(len);
while (len)
{
printf("%02x.", *buf);
buf++;
len--;
}
printf("\n");
}
int main(int argc, char *argv[])
{
printf("======================\n");
long fun_len = (long )test_02 - (long )test_01;
HexDump((void *)test_01, fun_len);
printf("======================\n");
fun_len = (long )test_03 - (long )test_02;
HexDump((void *)test_02, fun_len);
printf("======================\n");
fun_len = (long )test_04 - (long )test_03;
HexDump((void *)test_03, fun_len);
printf("Test End\n");
getchar();
// Just a trick to block optimizer from eliminating test_xx() functions as unused
if (argc > 1)
{
test_01(1);
test_02(2);
test_03(3);
test_04(4);
}
}
The (correct) Output when compiled with "g++ -O0":
[note the 'c3' byte (= assembly 'ret') at the end of all functions]
======================
addr:4199344, len:37
55.89.e5.83.ec.18.c7.04.24.61.00.00.00.e8.4e.62.00.00.c7.04.24.0a.00.00.00.e8.42
.62.00.00.b8.01.00.00.00.c9.c3.
======================
addr:4199381, len:49
55.89.e5.83.ec.18.c7.04.24.62.00.00.00.e8.29.62.00.00.c7.04.24.62.00.00.00.e8.1d
.62.00.00.c7.04.24.0a.00.00.00.e8.11.62.00.00.b8.02.00.00.00.c9.c3.
======================
addr:4199430, len:37
55.89.e5.83.ec.18.c7.04.24.63.00.00.00.e8.f8.61.00.00.c7.04.24.0a.00.00.00.e8.ec
.61.00.00.b8.03.00.00.00.c9.c3.
Test End
The erroneous Output when compiled with "g++ -O2":
(a) function test_01 addr & len seem correct
(b) functions test_02, test_03 have negative lengths,
and fun. test_02 length is also incorrect.
======================
addr:4199416, len:36
83.ec.1c.c7.04.24.61.00.00.00.e8.c5.61.00.00.c7.04.24.0a.00.00.00.e8.b9.61.00.00
.b8.01.00.00.00.83.c4.1c.c3.
======================
addr:4199452, len:-72
83.ec.1c.c7.04.24.62.00.00.00.e8.a1.61.00.00.c7.04.24.62.00.00.00.e8.95.61.00.00
.c7.04.24.0a.00.00.00.e8.89.61.00.00.b8.02.00.00.00.83.c4.1c.c3.57.56.53.83.ec.2
0.8b.5c.24.34.8b.7c.24.30.89.5c.24.08.89.7c.24.04.c7.04.
======================
addr:4199380, len:-36
83.ec.1c.c7.04.24.63.00.00.00.e8.e9.61.00.00.c7.04.24.0a.00.00.00.e8.dd.61.00.00
.b8.03.00.00.00.83.c4.1c.c3.
Test End
This is happening even if I put a "#pragma GCC optimize 0" line in the source file, which is supposed to be the equivalent of a "g++ -O0" command line option.
I don't believe this is true: it is supposed to be the equivalent of attaching __attribute__((optimize(0))) to subsequently defined functions, which causes those functions to be compiled with a different optimisation level. But this does not affect what goes on at the top level, whereas the command line option does.
If you really must do horrible things that rely on top level ordering, try the -fno-toplevel-reorder option. And I suspect that it would be a good idea to add __attribute__((noinline)) to the functions in question as well.