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What is segmentation fault? Is it different in C and C++? How are segmentation fault and dangling pointer related?

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11  
Honestly speaking, its not homework. I just wanted to know from geeks here directly before googling. –  mag Feb 27 '10 at 9:47
16  
segmentation fault makes the compiler feel bad. –  pinouchon Sep 12 '11 at 14:32

9 Answers 9

up vote 153 down vote accepted

Segmentation fault is a specific kind of error caused by accessing memory that “does not belong to you.” It’s a helper mechanism that keeps you from corrupting the memory and introducing hard-to-debug memory bugs. Whenever you get a segfault you know you are doing something wrong with memory – accessing variable that has already been freed, writing to a read-only portion of the memory, etc. Segmentation fault is essentially the same in most languages that let you mess with the memory management, there is no principial difference between segfaults in C and C++.

There are many ways to get a segfault, at least in the lower-level languages such as C(++). A common way to get a segfault is to dereference a null pointer:

int *p = NULL;
*p = 1;

Another segfault happens when you try to write to a portion of memory that was marked as read-only:

char *str = "Foo"; // Compiler marks the constant string as read-only
*str = 'b'; // Which means this is illegal and results in a segfault

Dangling pointer points to a thing that does not exist any more, like here:

char *p = NULL;
{
    char c;
    p = &c;
}
// Now p is dangling

The pointer p dangles because it points to character variable c that ceased to exist after the block ended. And when you try to dereference dangling pointer (like *p='A'), you would probably get a segfault.

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1  
That was understandable. Can you please provide an example of segfault and dangling pointer each. Thanks. –  mag Feb 27 '10 at 9:50
    
I get it, thanks. +1 –  mag Feb 27 '10 at 10:13
20  
The last example is particularly nasty, when I build: int main() { char *p = 0; { char c = 'x'; p = &c; } printf( "%c\n",*p); return 0; } With either gcc or several other compilers, it 'appears' to work. No warnings on compile. No segfault. This is because the '}' out of scope, doesn't actually delete the data, just marks it as free to be used again. The code can run fine on a production system for years, you alter another part of the code, change compiler or something else and BOOOOOM! –  Chris Huang-Leaver Apr 13 '10 at 9:06
    
Sorry for the bump but just a side note... none of your examples necessarily cause a segfault, in fact it's just undefined behavior ;-) –  oldrinb Sep 15 '12 at 3:01
    
Wow, good point @Chris Huang-Leaver, thanks for lighting up this. –  Kusavil May 25 at 17:25

It would be worth noting that segmentation fault isn't caused by directly accessing another process memory (this is what I'm hearing sometimes), as it is simply not possible. With virtual memory every process has its own virtual address space and there is no way to access another one using any value of pointer. Exception to this can be shared libraries which are same physical address space mapped to (possibly) different virtual addresses and kernel memory which is even mapped in the same way in every process (to avoid TLB flushing on syscall, I think). And things like shmat ;) - these are what I count as 'indirect' access. One can, however, check that they are usually located long way from process code and we are usually able to access them (this is why they are there, nevertheless accessing them in a improper way will produce segmentation fault).

Still, segmentation fault can occur in case of accessing our own (process) memory in improper way (for instance trying to write to non-writable space). But the most common reason for it is the access to the part of the virtual address space that is not mapped to physical one at all.

And all of this with respect to virtual memory systems.

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With shared memory/memory mapped files it is possible for someone else to mess with your memory. In WIN32 there are nasty API's like 'WriteProcessMemory' too! –  paulm Feb 17 at 23:46
    
@paulm: Yes, I know. This is what I had on mind in "And things like shmat ;) - these are what I count as 'indirect' access." –  konrad.kruczynski Feb 18 at 10:08

A segmentation fault is a particular error condition that can occur during the operation of computer software. A segmentation fault occurs when a program attempts to access a memory location that it is not allowed to access, or attempts to access a memory location in a way that is not allowed (for example, attempting to write to a read-only location, or to overwrite part of the operating system). Systems based on processors like the Motorola 68000 tend to refer to these events as address or bus errors.

Segmentation is one approach to memory management and protection in the operating system. It has been superseded by paging for most purposes, but much of the terminology of segmentation is still used, "segmentation fault" being an example. Some operating systems still have segmentation at some logical level although paging is used as the main memory management policy.

On Unix-like operating systems, a process that accesses invalid memory receives the SIGSEGV signal. On Microsoft Windows, a process that accesses invalid memory receives the STATUS_ACCESS_VIOLATION exception, and usually a window asking the user to send an error report to Microsoft appears.

Here is an example of ANSI C code that should create a segmentation fault on platforms with memory protection:

char *s = "hello world";
*s = 'H';

When the program containing this code is compiled, the string "hello world" is placed in the section of the program binary marked as read-only; when loaded, the operating system places it with other strings and constant data in a read-only segment of memory. When executed, a variable, s, is set to point to the string's location, and an attempt is made to write an H character through the variable into the memory, causing a segmentation fault. Compiling such a program with a compiler that does not check for the assignment of read-only locations at compile time, and running it on a Unix-like operating system produces the following runtime error:

$ gcc segfault.c -g -o segfault
$ ./segfault
Segmentation fault

Backtrace from gdb:

Program received signal SIGSEGV, Segmentation fault.
0x1c0005c2 in main () at segfault.c:6
6               *s = 'H';

The conditions under which segmentation violations occur and how they manifest themselves are specific to an operating system.

Because a very common program error is a null pointer dereference (a read or write through the null pointer, a null pointer, used in C to mean "pointer to no object" and as an error indicator), most operating systems map the null pointer's address such that accessing it causes a segmentation fault.

int* ptr = NULL;
*ptr = 1;

This sample code creates a null pointer, and tries to assign a value to its non-existent target. Doing so causes a segmentation fault at runtime on many compilers.

Another way to cause a segmentation fault is to recurse without a base case, which causes a stack overflow:

int main() {
    main();
}
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A segmentation fault is caused by a request for a page that the process does not have listed in its descriptor table, or an invalid request for a page that it does have listed (e.g. a write request on a read-only page).

A dangling pointer is a pointer that may or may not point to a valid page, but does point to an "unexpected" segment of memory.

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1  
This is true, but would it really help you if you already didn’t know what a segmentation fault is? –  zoul Feb 27 '10 at 9:37
    
@zoul: homework tag means "guide", not "give". –  Ignacio Vazquez-Abrams Feb 27 '10 at 9:38

According to wikipedia:

A segmentation fault occurs when a program attempts to access a memory location that it is not allowed to access, or attempts to access a memory location in a way that is not allowed (for example, attempting to write to a read-only location, or to overwrite part of the operating system).

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To be honest, as other posters have mentioned, Wikipedia has a very good article on this so have a look there. This type of error is very common and often called other things such as Access Violation or General Protection Fault.

They are no different in C, C++ or any other language that allows pointers. These kinds of errors are usually caused by pointers that are

  1. Used before being properly initialised
  2. Used after the memory they point to has been realloced or deleted.
  3. Used in an indexed array where the index is outside of the array bounds. This is generally only when you're doing pointer math on traditional arrays or c-strings, not STL / Boost based collections (in C++.)
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Segmentation fault occurs when a process (running instance of a program) is trying to access read-only memory address or memory range which is being used by other process or access the non-existent (invalid) memory address. Dangling Reference (pointer) problem means that trying to access an object or variable whose contents have already been deleted from memory, e.g:

int *arr = new int[20];
delete arr;
cout<<arr[1];  //dangling problem occurs here
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Segmentation fault is also caused for hardware failures, in this case the RAM memories. This is the less common cause, but if you don't find an error in your code, maybe a memtest could help you.

The solution in this case, change the RAM.

edit:

Here there is a reference: Segmentation fault by hardware

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why a negative vote? –  Alejo Bernardin Jul 1 at 19:20

Wiki Segmentation_fault has very nice description about it, Just pointed out the causes and reasons. Have a look into the wiki for a detail description.

In computing, a segmentation fault (often shortened to segfault) or access violation is a fault raised by hardware with memory protection, notifying an operating system (OS) about a memory access violation.

The following are some typical causes of a segmentation fault:

  • Dereferencing NULL pointers – this is special-cased by memory management hardware
  • Attempting to access a nonexistent memory address (outside process's address space)
  • Attempting to access memory the program does not have rights to (such as kernel structures in process context)
  • Attempting to write read-only memory (such as code segment)

These in turn are often caused by programming errors that result in invalid memory access:

  • Dereferencing or assigning to an uninitialized pointer (wild pointer, which points to a random memory address)

  • Dereferencing or assigning to a freed pointer (dangling pointer, which points to memory that has been freed/deallocated/deleted)

  • A buffer overflow.

  • A stack overflow.

  • Attempting to execute a program that does not compile correctly. (Some compilers will output an executable file despite the presence of compile-time errors.)

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