245

I am assigning values in a C++ program out of the bounds like this:

#include <iostream>
using namespace std;
int main()
{
    int array[2];
    array[0] = 1;
    array[1] = 2;
    array[3] = 3;
    array[4] = 4;
    cout << array[3] << endl;
    cout << array[4] << endl;
    return 0;
}

The program prints 3 and 4. It should not be possible. I am using g++ 4.3.3

Here is compile and run command

$ g++ -W -Wall errorRange.cpp -o errorRange
$ ./errorRange
3
4

Only when assigning array[3000]=3000 does it give me a segmentation fault.

If gcc doesn't check for array bounds, how can I be sure if my program is correct, as it can lead to some serious issues later?

I replaced the above code with

vector<int> vint(2);
vint[0] = 0;
vint[1] = 1;
vint[2] = 2;
vint[5] = 5;
cout << vint[2] << endl;
cout << vint[5] << endl;

and this one also produces no error.

24
  • 3
    Related question: stackoverflow.com/questions/671703/…
    – TSomKes
    Commented Aug 6, 2009 at 16:15
  • 24
    The code is buggy, of course, but it generates undefined behavior. Undefined means it may or may not run to completion. There is no guarantee of a crash. Commented Aug 6, 2009 at 16:17
  • 4
    You can be sure your program is correct by not screwing around with raw arrays. C++ programmers should use container classes instead, except in embedded/OS programming. Read this for reasons to user containers. parashift.com/c++-faq-lite/containers.html
    – jkeys
    Commented Aug 6, 2009 at 16:25
  • 11
    Bear in mind that vectors do not necessarily range-check using []. Using .at() does the same thing as [] but does range-check. Commented Aug 6, 2009 at 16:31
  • 5
    A vector does not auto-resize when accessing out-of-bounds elements! It's just U.B.! Commented Aug 6, 2009 at 17:02

18 Answers 18

488

Welcome to every C/C++ programmer's bestest friend: Undefined Behavior.

There is a lot that is not specified by the language standard, for a variety of reasons. This is one of them.

In general, whenever you encounter undefined behavior, anything might happen. The application may crash, it may freeze, it may eject your CD-ROM drive or make demons come out of your nose. It may format your harddrive or email all your porn to your grandmother.

It may even, if you are really unlucky, appear to work correctly.

The language simply says what should happen if you access the elements within the bounds of an array. It is left undefined what happens if you go out of bounds. It might seem to work today, on your compiler, but it is not legal C or C++, and there is no guarantee that it'll still work the next time you run the program. Or that it hasn't overwritten essential data even now, and you just haven't encountered the problems, that it is going to cause — yet.

As for why there is no bounds checking, there are a couple aspects to the answer:

  • An array is a leftover from C. C arrays are about as primitive as you can get. Just a sequence of elements with contiguous addresses. There is no bounds checking because it is simply exposing raw memory. Implementing a robust bounds-checking mechanism would have been almost impossible in C.
  • In C++, bounds-checking is possible on class types. But an array is still the plain old C-compatible one. It is not a class. Further, C++ is also built on another rule which makes bounds-checking non-ideal. The C++ guiding principle is "you don't pay for what you don't use". If your code is correct, you don't need bounds-checking, and you shouldn't be forced to pay for the overhead of runtime bounds-checking.
  • So C++ offers the std::vector class template, which allows both. operator[] is designed to be efficient. The language standard does not require that it performs bounds checking (although it does not forbid it either). A vector also has the at() member function which is guaranteed to perform bounds-checking. So in C++, you get the best of both worlds if you use a vector. You get array-like performance without bounds-checking, and you get the ability to use bounds-checked access when you want it.
13
  • 5
    @Jaif : we have been using this array thing for so long, but still why are there no test to check such simple error ? Commented Aug 6, 2009 at 16:40
  • 14
    C++ design principle was that it shouldn't be slower than the equivalent C code, and C doesn't do array bound checking. C design principle was basically speed as it was aimed for system programming. Array bound checking takes time, and so is not done. For most uses in C++, you should be using a container rather than array anyway, and you can have your choice of bound check or no bound check by either accessing an element via .at() or [] respectively.
    – KTC
    Commented Aug 6, 2009 at 16:47
  • 5
    @seg Such a check costs something. If you write correct code, you don't want to pay that price. Having said that, I've become a complete convert to std::vector's at() method, which IS checked. Using it has exxposed quite a few errors in what I thought was "correct" code.
    – anon
    Commented Aug 6, 2009 at 16:48
  • 11
    I believe old versions of GCC actually launched Emacs and an a simulation of Towers of Hanoi in it, when it encountered certain types of undefined behavior. Like I said, anything may happen. ;) Commented Aug 6, 2009 at 17:18
  • 5
    Everythings already been said, so this only warrants a small addendum. Debug builds can be very forgiving in these circumstances when compared to release builds. Due to debug information being included in debug binaries, there's less of a chance that something vital is overwritten. That's sometimes why the debug builds seem to work fine whilst the release build crash.
    – Rich
    Commented Aug 6, 2009 at 18:02
42

Using g++, you can add the command line option: -fstack-protector-all.

On your example it resulted in the following:

> g++ -o t -fstack-protector-all t.cc
> ./t
3
4
/bin/bash: line 1: 15450 Segmentation fault      ./t

It doesn't really help you find or solve the problem, but at least the segfault will let you know that something is wrong.

5
  • 13
    I just found even a better option: -fmudflap
    – Hi-Angel
    Commented Dec 24, 2014 at 8:00
  • 4
    @Hi-Angel: Modern equivalent is -fsanitize=address which catches this bug both at compile time (if optimizing) and at runtime. Commented Jul 15, 2020 at 14:10
  • 2
    @NateEldredge +1, nowadays I even use -fsanitize=undefined,address. But it's worth noting that there are rare corner cases with std library, when out of bounds access is not detected by sanitizer. For this reason I'd recommend to additionally use -D_GLIBCXX_DEBUG option, which adds even more checks.
    – Hi-Angel
    Commented Jul 15, 2020 at 15:23
  • 2
    Thank you Hi-Angel. when -fmudflap and -fsanitize=address didn't work for me, -fsanitize=undefined,address found not only a function that wasn't returning an value, it also found the array assignment that was happening out of bounds.
    – Nav
    Commented Nov 30, 2020 at 8:18
  • Do we have this on other compilers, i.e apple clang?
    – KcFnMi
    Commented Oct 5, 2022 at 16:44
15

g++ does not check for array bounds, and you may be overwriting something with 3,4 but nothing really important, if you try with higher numbers you'll get a crash.

You are just overwriting parts of the stack that are not used, you could continue till you reach the end of the allocated space for the stack and it'd crash eventually

EDIT: You have no way of dealing with that, maybe a static code analyzer could reveal those failures, but that's too simple, you may have similar(but more complex) failures undetected even for static analyzers

2
  • 7
    Where do you get if from that at the address of array[3] and array[4], there is "nothing really important"??
    – namezero
    Commented Sep 9, 2013 at 10:08
  • What numbers might be considered higher numbers?
    – KcFnMi
    Commented Oct 6, 2022 at 2:22
10

It's undefined behavior as far as I know. Run a larger program with that and it will crash somewhere along the way. Bounds checking is not a part of raw arrays (or even std::vector).

Use std::vector with std::vector::iterator's instead so you don't have to worry about it.

Edit:

Just for fun, run this and see how long until you crash:

int main()
{
   int arr[1];

   for (int i = 0; i != 100000; i++)
   {
       arr[i] = i;
   }

   return 0; //will be lucky to ever reach this
}

Edit2:

Don't run that.

Edit3:

OK, here is a quick lesson on arrays and their relationships with pointers:

When you use array indexing, you are really using a pointer in disguise (called a "reference"), that is automatically dereferenced. This is why instead of *(array+1), array[1] automatically returns the value at that index.

When you have a pointer to an array, like this:

int arr[5];
int *ptr = arr;

Then the "array" in the second declaration is really decaying to a pointer to the first array. This is equivalent behavior to this:

int *ptr = &arr[0];

When you try to access beyond what you allocated, you are really just using a pointer to other memory (which C++ won't complain about). Taking my example program above, that is equivalent to this:

int main()
{
   int arr[1];
   int *ptr = arr;

   for (int i = 0; i != 100000; i++, ptr++)
   {
       *ptr++ = i;
   }

   return 0; //will be lucky to ever reach this
}

The compiler won't complain because in programming, you often have to communicate with other programs, especially the operating system. This is done with pointers quite a bit.

4
  • 3
    I think you forgot to increment "ptr" in your last example there. You've accidentally produced some well-defined code.
    – user13300
    Commented Aug 6, 2009 at 16:39
  • 1
    Haha, see why you shouldn't be using raw arrays?
    – jkeys
    Commented Aug 6, 2009 at 16:51
  • 1
    "This is why instead of *(array[1]), array[1] automatically returns the value at that value." Are you sure *(array[1]) will work properly? I think it should be *(array + 1). p.s : Lol, it is like sending a message to the past. But, anyway:
    – muyustan
    Commented Apr 7, 2020 at 10:23
  • 1
    @muyustan lol, you spoke to the past and the past responded. Edited with your suggested changes.
    – jkeys
    Commented Mar 13, 2021 at 6:44
5

Run this through Valgrind and you might see an error.

As Falaina pointed out, valgrind does not detect many instances of stack corruption. I just tried the sample under valgrind, and it does indeed report zero errors. However, Valgrind can be instrumental in finding many other types of memory problems, it's just not particularly useful in this case unless you modify your bulid to include the --stack-check option. If you build and run the sample as

g++ --stack-check -W -Wall errorRange.cpp -o errorRange
valgrind ./errorRange

valgrind will report an error.

3
  • 3
    Actually, Valgrind is quite poor at determining incorrect array accesses on the stack. (and rightfully so, the best it can do is mark the entire stack as a valid write location )
    – Falaina
    Commented Aug 6, 2009 at 16:24
  • @Falaina - good point, but Valgrind can detect at least some stack errors.
    – Todd Stout
    Commented Aug 6, 2009 at 17:35
  • And valgrind will see nothing wrong with the code because the compiler is smart enough to optimize the array away and simply output a literal 3 and 4. That optimization happens before gcc checks the array bounds which is why the out-of-bounds warning gcc does have is not shown. Commented Jan 17, 2019 at 15:08
5

Hint

If you want to have fast constraint size arrays with range error check, try using boost::array, (also std::tr1::array from <tr1/array> it will be standard container in next C++ specification). It's much faster then std::vector. It reserve memory on heap or inside class instance, just like int array[].
This is simple sample code:

#include <iostream>
#include <boost/array.hpp>
int main()
{
    boost::array<int,2> array;
    array.at(0) = 1; // checking index is inside range
    array[1] = 2;    // no error check, as fast as int array[2];
    try
    {
       // index is inside range
       std::cout << "array.at(0) = " << array.at(0) << std::endl;

       // index is outside range, throwing exception
       std::cout << "array.at(2) = " << array.at(2) << std::endl; 

       // never comes here
       std::cout << "array.at(1) = " << array.at(1) << std::endl;  
    }
    catch(const std::out_of_range& r)
    {
        std::cout << "Something goes wrong: " << r.what() << std::endl;
    }
    return 0;
}

This program will print:

array.at(0) = 1
Something goes wrong: array<>: index out of range
1
  • 1
    Note for readers: Outdated answer. Since C++11 it should be #include<array> and std::array from the standard library instead of the boost equivalents. Commented Mar 6, 2022 at 16:24
4

C or C++ will not check the bounds of an array access.

You are allocating the array on the stack. Indexing the array via array[3] is equivalent to *(array + 3), where array is a pointer to &array[0]. This will result in undefined behavior.

One way to catch this sometimes in C is to use a static checker, such as splint. If you run:

splint +bounds array.c

on,

int main(void)
{
    int array[1];

    array[1] = 1;

    return 0;
}

then you will get the warning:

array.c: (in function main) array.c:5:9: Likely out-of-bounds store: array[1] Unable to resolve constraint: requires 0 >= 1 needed to satisfy precondition: requires maxSet(array @ array.c:5:9) >= 1 A memory write may write to an address beyond the allocated buffer.

2
  • Correction: it's already been allocated by the OS or another program. He is overwriting other memory.
    – jkeys
    Commented Aug 6, 2009 at 16:20
  • 1
    Saying that "C/C++ will not check the bounds" isn't entirely correct - there's nothing precluding a particular compliant implementation from doing so, either by default, or with some compilation flags. It's just that none of them bother. Commented Aug 6, 2009 at 17:02
3

You are certainly overwriting your stack, but the program is simple enough that effects of this go unnoticed.

1
  • 2
    Whether the stack is overwritten or not depends on the platform. Commented Aug 6, 2009 at 16:34
2

libstdc++, which is part of gcc, has a special debug mode for error checking. It is enabled by compiler flag -D_GLIBCXX_DEBUG. Among other things it does bounds checking for std::vector at the cost of performance. Here is online demo with recent version of gcc.

So actually you can do bounds checking with libstdc++ debug mode but you should do it only when testing because it costs notable performance compared to normal libstdc++ mode.

2
  • Do we have this on other compilers, i.e apple clang?
    – KcFnMi
    Commented Oct 6, 2022 at 2:21
  • Yes, LLVM implementation of C++ Standard Library also has a similar debug mode, see libcxx.llvm.org/DesignDocs/DebugMode.html.
    – ks1322
    Commented Oct 6, 2022 at 10:55
1

Undefined behavior working in your favor. Whatever memory you're clobbering apparently isn't holding anything important. Note that C and C++ do not do bounds checking on arrays, so stuff like that isn't going to be caught at compile or run time.

2
  • 8
    No, Undefined behavior "works in your favor" when it crashes cleanly. When it appears to work, that's about the worst possible scenario. Commented Aug 6, 2009 at 17:06
  • @JohnBode: Then it would be better if you correct wording as per jalf's comment
    – Destructor
    Commented Nov 30, 2016 at 4:24
1

When you write 'array[index]' in C it translates it to machine instructions.

The translation is goes something like:

  1. 'get the address of array'
  2. 'get the size of the type of objects array is made up of'
  3. 'multiply the size of the type by index'
  4. 'add the result to the address of array'
  5. 'read what's at the resulting address'

The result addresses something which may, or may not, be part of the array. In exchange for the blazing speed of machine instructions you lose the safety net of the computer checking things for you. If you're meticulous and careful it's not a problem. If you're sloppy or make a mistake you get burnt. Sometimes it might generate an invalid instruction that causes an exception, sometimes not.

0

When you initialize the array with int array[2], space for 2 integers is allocated; but the identifier array simply points to the beginning of that space. When you then access array[3] and array[4], the compiler then simply increments that address to point to where those values would be, if the array was long enough; try accessing something like array[42] without initializing it first, you'll end up getting whatever value happened to already be in memory at that location.

Edit:

More info on pointers/arrays: http://home.netcom.com/~tjensen/ptr/pointers.htm

0

As I understand, local variables are allocated on stack, so going out of bounds on your own stack can only overwrite some other local variable, unless you go oob too much and exceed your stack size. Since you have no other variables declared in your function - it does not cause any side effects. Try declaring another variable/array right after your first one and see what will happen with it.

0

A nice approach that i have seen often and I had been used actually is to inject some NULL type element (or a created one, like uint THIS_IS_INFINITY = 82862863263;) at end of the array.

Then at the loop condition check, TYPE *pagesWords is some kind of pointer array:

int pagesWordsLength = sizeof(pagesWords) / sizeof(pagesWords[0]);

realloc (pagesWords, sizeof(pagesWords[0]) * (pagesWordsLength + 1);

pagesWords[pagesWordsLength] = MY_NULL;

for (uint i = 0; i < 1000; i++)
{
  if (pagesWords[i] == MY_NULL)
  {
    break;
  }
}

This solution won't word if array is filled with struct types.

0

As mentioned now in the question using std::vector::at will solve the problem and make a bound check before accessing.

If you need a constant size array that is located on the stack as your first code use the C++11 new container std::array; as vector there is std::array::at function. In fact the function exists in all standard containers in which it have a meaning,i.e, where operator[] is defined :( deque, map, unordered_map) with the exception of std::bitset in which it is called std::bitset::test.

0

If you change your program slightly:

#include <iostream>
using namespace std;
int main()
{
    int array[2];
    INT NOTHING;
    CHAR FOO[4];
    STRCPY(FOO, "BAR");
    array[0] = 1;
    array[1] = 2;
    array[3] = 3;
    array[4] = 4;
    cout << array[3] << endl;
    cout << array[4] << endl;
    COUT << FOO << ENDL;
    return 0;
}

(Changes in capitals -- put those in lower case if you're going to try this.)

You will see that the variable foo has been trashed. Your code will store values into the nonexistent array[3] and array[4], and be able to properly retrieve them, but the actual storage used will be from foo.

So you can "get away" with exceeding the bounds of the array in your original example, but at the cost of causing damage elsewhere -- damage which may prove to be very hard to diagnose.

As to why there is no automatic bounds checking -- a correctly written program does not need it. Once that has been done, there is no reason to do run-time bounds checking and doing so would just slow down the program. Best to get that all figured out during design and coding.

C++ is based on C, which was designed to be as close to assembly language as possible.

1
  • There is no guarantee that this will happen, but it may happen. Commented Mar 6, 2022 at 16:16
-1

when you declare int array[2]; you reserve 2 memory spaces of 4 bytes each(32bit program). if you type array[4] in your code it still corresponds to a valid call but only at run time will it throw an unhandled exception. C++ uses manual memory management. This is actually a security flaw that was used for hacking programs

this can help understanding:

int * somepointer;

somepointer[0]=somepointer[5];

-1

The behavior can depend on your system. Typically, you will have a margin for out of bounds, sometimes with value of 0 or garbage values. For the details you can check with memory allocation mechanism used in your OS. On top of that, if you use the programming language like c/c++, it will not check the bounds when you using some containers, like array. So, you will meet "undefined event" because you do not know what the OS did below the surface. But like the programming language Java, it will check the bound. If you step outside of the bound, you will get an exception.

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