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I noticed there's not question with a list of common causes of segmentation faults in C++, so I thought I'd add it.

Naturally it's community Wiki, since there's no one correct answer.

I think this might be useful for newer programmers learning C++, feel free to close it if you disagree.

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closed as not constructive by BЈовић, sharptooth, Donotalo, Bo Persson, Prasoon Saurav Aug 3 '11 at 9:33

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Uhm... looks like I can't move this to community wiki. Hopefully someone with more permissions comes along. –  fluffels Aug 3 '11 at 8:26
    
How about: "What can cause segmentation faults in C++?". An embedded system without MMU won't give you any segfault at all - even when "writing" to the ROM. –  mbx Aug 3 '11 at 8:44
    
You are correct, I'll change it. –  fluffels Aug 3 '11 at 8:50
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9 Answers 9

up vote 12 down vote accepted

Segmentation fault is caused by bad accesses to memory, only if your OS has a MMU. Otherwise, you won't get it but only strange behavior.

The virtual memory (the entire memory accessible to you = 2 ^ sizeof(pointer type)) is mapped to physical memory in units named pages or segments (paging superseded segmentation but they are still used).

Each page has some protection rights, if you try to read from a page with no-read access you'll get a segfault. If you try to write to a readonly location you'll get a SIGSEGV.

If you have an unitialized pointer and use it it may happen that it will point to another good location so you'll don't get a segfault. If you have a small array reading after it's bound may corrupt other memory areas if it doesn't get past the page boundary.

Also, since there are many pages, not all of them are really mapped. If you touch a non-mapped page you'll get a segfault. Actually, any access to a non mapped page will have to take into account copy on write, pages on swap, lazy loading, memory mapped files and other things. See this article on page fault handling, especially the second diagram there, posted here below too (but read the article for more explanations)

page fault handling

You are mainly interested in what happens in user space and all paths leading to SIGSEGV. but kernel space is also interesting.

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Very interesting, thanks! –  fluffels Aug 3 '11 at 8:52
    
The link you have provided is useful but is it legit? I cannot read what I assume to be chinese so could you clarify the legal status? If it's all ok feel free to delete this comment. –  Francesco Aug 3 '11 at 9:09
    
Updated link with another resource on the same topic. –  Mihai Maruseac Aug 3 '11 at 9:18
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Many of the ways to 'segfault' C++ aren't necessarily guaranteed to happen, in fact, that is the case with most of the examples posted here. It's merely good luck (or bad luck, depending on how you look at it!) if you can perform these operations without a segfault occuring.

That is actually one of the things in C++ that separates it from other languages; undefined behaviour. Whereas in Java or C# you might get an 'InvalidOperationException' or similar, which is guaranteed to happen when these operations are performed; in C++, the standard just says 'undefined behaviour', which is basically luck of the draw, and you never want that to happen.

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So true about C++ and undefined behaviour. –  fluffels Aug 3 '11 at 8:51
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Dereferencing NULL pointers.

#include <cstddef> //For NULL.
int* p1 = NULL; //p1 points to no memory address
*p1 = 3; //Segfault.
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Where is your definition of NULL? –  mbx Aug 3 '11 at 8:41
1  
In <stddef.h>, and a couple of other headers. In practice, it's probably included indirectly with most C++ headers, but it's best to be sure, and include <stddef.h> or <cstddef> anyway. –  James Kanze Aug 3 '11 at 8:46
    
Thanks. I think my compiler includes it by default, I didn't know that others don't. –  fluffels Aug 3 '11 at 8:53
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Accessing an array out of bounds (Possible):

int ia[10];
ia[10] = 4; // Someone forgot that arrays are 0-indexed! Possible Segfault.
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3  
No guarantee this will segfault. –  sharptooth Aug 3 '11 at 8:28
    
@sharptooth - Uh, possible segfault then. Edited. –  Schnommus Aug 3 '11 at 8:29
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The obvious answer is “undefined behavior”, but this begs the question for an unexperienced programmer, and some types of undefined behavior are much less likely to cause a segmentation fault (or another type of crash) than others. The most frequent causes of segmentation faults are generally pointer related: dereferencing an uninitialized pointer, a null pointer, or a previously freed pointer; accessing beyond the end (or in front of the beginning, but that's less frequent) of an object (array or other); using the results of an illegal pointer cast (static_cast to a derived type, when the object doesn't actually have that type, or most reinterpret_cast); etc.

Perhaps the most important point to keep in mind here, however, is that in general, these are not guaranteed to cause a segmentation fault, and that often, the segmentation fault that they cause will only occur sometime later, in a completely unrelated operation. Thus, writing beyond the end of a local array will usually “work”, but will modify whatever happens to follow the array on the stack: some other local variable (modifying the vptr of an object on the stack may lead to a segmentation fault when you attempt to call a virtual function on the object), the frame pointer of the calling function (which will probably cause a segmentation fault in that function, after you've returned), or the return address (which may cause all sorts of strange behavior—a segmentation fault or an illegal instruction trap are probably the best that can occur). Writing beyond the end of freed memory, or through an already freed pointer, can corrupt the free space arena, causing a segmentation fault in a much (sometime much, much) later allocation or free; it can also modify some other, totally unrelated object, corrupting its vptr or some other pointer in the object, or just some random data—again, a segmentation fault is probably the best possible result (far preferrable to continuing with corrupted data).

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Indeed. You make a very good point regarding segfaults being preferable to corrupted data. –  fluffels Aug 3 '11 at 8:56
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A favourite of mine:

#include <iostream>
struct A {
    virtual void f() {
        std::cout << "A::f();\n";
    }
    int i;
};

struct B : A {
    virtual void f() {
        std::cout << "B::f();\n";
    }
    int j;
};

void seti(A* arr, size_t size) {
    for (size_t i = 0; i < size; ++i)
        arr[i].i = 0;
}

int main() {
    B b[10];
    seti(b, 10);
    b[3].f();
}

As with most things that can cause a segfault, this can also fail to fail. On ideone, for example, b[3].f() fails, but b[2].f() works.

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Hold on. Why would this segfault? –  fluffels Aug 5 '11 at 6:32
1  
@fluffels - Simple answer: it's UB, so it may. Technically, it's because void seti(A*, size_t) overwrites the vtable of some elements b, which leads to any calls to virtual functions causing a segfault. Or not causing a segfault, if they are miraculously overwritten to point to a function. UB is UB. –  Anton Golov Aug 5 '11 at 21:07
    
Holy crap. Would this work properly with classes? –  fluffels Aug 16 '11 at 8:37
    
@fluffels - No. See stackoverflow.com/questions/92859/… –  Anton Golov Aug 17 '11 at 15:47
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Forgetting to initialize pointers, leaving them with random memory addresses. Note: this may not always segfault, but it could.

int* p1; //No initialization.
*p1 = 3; //Possible segfault.
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4  
No guarantee this will segfault. Maybe it will, maybe not. –  sharptooth Aug 3 '11 at 8:26
    
Right again. I'm looking for examples of things that could cause segfaults, so I wasn't being specific enough. Edited. –  fluffels Aug 3 '11 at 8:35
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Dereferencing freed memory could potentially cause a segfault.

SomeClass* someObject = new SomeClass();
delete someObject;
someObject->someMethod();  //Could cause a segfault.
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Not always happening. –  Mihai Maruseac Aug 3 '11 at 8:41
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Trying to modify string literals:

char* mystr = "test";
mystr[2] = 'w';

This CAN cause segmentation fault.

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