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i always reading, not to throw an std::string or some other classes allocating memory. like here or more inportant here on point 3. - Don't embed a std::string object.

so now i'm trying to insert boost::exception to my project and what do i see: lot of strings.

why is boost don't comply it's own recommendation?

and if i have parameters which can't be hardcodet, like safed in an config-file, how can i put them into an exception, whithout using std::string?

or is the guideline don't use std::string only a do use std::string as seldom as possible guideline? i'm a bit confused...


till waitiing i've done some research. please correct me if i'm wrong.

if i understand it right, it's all about the allocation during the throw and what is happening to the allocated memory. so the memory get lost if i allocate it in the constructor and can't be freed in the destructor of the exception, that will produce a memory-leak. but it's ok to allocate this before throwing, so the exception is clean.

i tried this:

struct xexception {
  int *ttt[10];
  xexception() {
    ttt[0] = new int[0xfffffffL];
    ttt[1] = new int[0xfffffffL];
    ttt[2] = new int[0xfffffffL];
    ttt[3] = new int[0xfffffffL];
    ttt[4] = new int[0xfffffffL];
    ttt[5] = new int[0xfffffffL];
    ttt[6] = new int[0xfffffffL];
    ttt[7] = new int[0xfffffffL];
    ttt[8] = new int[0xfffffffL];
    ttt[9] = new int[0xfffffffL];

  ~xexception() throw() {
    //never happen
    delete[] ttt[0];
    delete[] ttt[1];
    delete[] ttt[2];
    delete[] ttt[3];
    delete[] ttt[4];
    delete[] ttt[5];
    delete[] ttt[6];
    delete[] ttt[7];
    delete[] ttt[8];
    delete[] ttt[9];

int main(int argc, const char *argv[]) {
  try {
  catch (const xexception &e) {
    std::cerr << "\nttt " << e.ttt[0][0] << std::endl;
  catch (std::bad_alloc) {
    std::cerr << "bad alloc" << std::endl;

  return 0;

the result is, i get the bad_alloc. and a huge memory leak.

now if i do the allocation before, it also throw me the bad_alloc but before the exception is created.

my exception to the exception concept is:

who tf cares? if i have a bad_alloc in my programm, because of a memory_leak or something else (i'm talking about programms on pc's not microcontrollers) i have truly other problems. may i can figur out that an bad_alloc happend, but where? on my alloc during a function (one of maybe 1000) or in the std::string (well i know it's the string but ... no posibility to manipulate the memory of the string... or its to dissipated).

try {
  // where is the error???
  int *x = new int[100];  // here?
  int *y = new int[100];  // or here?
  int *z = new int[100];
  int *w = new int[100];
  int *t = new int[100];
  int *f = new int[100];


  std::string str("asdfasdfasdfasdfasdfasdfasdf"); // maybe here
catch (the error) {

and then? shall i try to figure out where it happening? therefore i would use valgrind not exceptions.

void foo() {
  int *i = new int[1];

try {
chatch( bad_boy ) {
  go_exception_handler_go(parameters); // oh, shit happens: also an stack_overflow may happend, cause stack is also full

or shall i manipulate the errormessage and log it, what definitively would throw the next bad_alloc.

please don't missunderstand me. since i've seen the boost::exception i've rewritten my exception class (till waiting on an answer :). but i also think it is not realy necessary to pick up every grain of sand.

share|improve this question
I don't see any std::strings that are members of exception. – Joseph Mansfield Apr 5 '13 at 10:01
std::runtime_error uses a std::string. – Alex Chamberlain Apr 5 '13 at 10:12
so using a string as parameter is ok? – user1810087 Apr 5 '13 at 10:20
std::runtime_error has a parameter that is a reference to a string. Nowhere does it say that it stores one (or creates any copies). – Bo Persson Apr 5 '13 at 11:21
This "rule" comes from an overblown concern that an exception thrown when the program is out of memory will lead to a call to terminate, which will, as the name suggests, terminate the application. Yes, that happens. If the program is out of memory, there's usually very little you can do about it, and terminating is usually the right solution. – Pete Becker Apr 5 '13 at 15:13

2 Answers 2

up vote 13 down vote accepted

The advice is basically telling you "Don't use any construct that might throw an exception in an exception". That's because if you get an exception while trying to throw an exception, the C++ runtime will just immediately call terminate() and kill your program.

Now if (either) of the exceptions involved would just call terminate() anyways (as is the default for an uncaught exception), then you don't really need to worry about it. For example, if your application can't handle bad_alloc (can't recover from out-of-memory), then you don't need to worry about copy constructors (such as std::string) that might throw it.

But if you want to be able to catch and recover from a bad_alloc, you need to ensure that none of your exception copy constructors can cause one. If you're writing a library that other applications will use, you should not assume that the application does not want to handle bad_alloc.

C++11 make this much easier by using move constructors (instead of copy constructors) where possible. Since the move constructor for std::string never throws exceptions you can safely use a std:string in your exception type as long as you properly implement move constructors, and ensure that they are used. Note that the initial construction of the object to be thrown in a throw expression is NOT part of the exception throwing process, so that constructor can throw an exception without causing a double exception (and terminate()). So if you have:

throw some_function();

some_function might throw an exception (such as bad_alloc) without returning an object to be thrown and that's fine. If it doesn't throw an exception (and returns a valid object), the move constructor for the exception type will be used (if available) for the exception throwing process, and that move constructor must not throw an exception.

Completely independent of the above, whenever you call new you need to ensure that exactly one spot will call delete in every possible case, or you'll leak memory (or crash from a double delete). This becomes tricky any time you have a function that calls new and then does something else that might throw an exception (such as call new again). If this happens in a constructor, the destructor for the object will not be called (though destructors for base classes and fields will be), so you can't do the cleanup in the destructor as you are trying to do with your example.

Fortunately std::unique_ptr exists to make this much easier. If you write your exception class as:

struct xexception {
  std::unique_ptr<int[]> ttt[10];
  xexception() {
    ttt[0].reset(new int[0xfffffffL]);
    ttt[1].reset(new int[0xfffffffL]);
    ttt[2].reset(new int[0xfffffffL]);
    ttt[3].reset(new int[0xfffffffL]);
    ttt[4].reset(new int[0xfffffffL]);
    ttt[5].reset(new int[0xfffffffL]);
    ttt[6].reset(new int[0xfffffffL]);
    ttt[7].reset(new int[0xfffffffL]);
    ttt[8].reset(new int[0xfffffffL]);
    ttt[9].reset(new int[0xfffffffL]);

it should work and not leak memory.

share|improve this answer
"you can safely use a std:string in your exception type" What about constructing (composing) the initial std::string? This might as well result in an exception (it's as probable to raise a bad_alloc as any copy operation of the string IMHO). – dyp Apr 6 '13 at 17:48
@DyP: Creating the initial object that will be thrown is not part of actually throwing the exception, so if it causes a bad_alloc it won't cause a double exception immeditate terminate() – Chris Dodd Apr 6 '13 at 18:17
True, but I think it's a reason for not using std::string as exception non-static (non-ref, non-ptr) data members (because it has to be created / composed). – dyp Apr 6 '13 at 18:38

While I think not using std::string for core, fundamental exceptions may be a good guideline, I don't think user-facing libraries/applications should necessarily follow this.

There may be other reasons, but you hit on the primary one: you'd like to indicate to the user (or developer) contextually meaningful information, which you often cannot do with a mere literal string. A dynamic allocation must occur in order to do this. If, for some reason, you had a bad_alloc, you're probably already hosed to begin with, so it doesn't buy/lose you anything.


By the way: the destructor of std::exception is marked as virtual for a reason!

share|improve this answer
Why has this contextually meaningful information to be stored in a string? Why not use specifically derived exception types with specific data members (it might be necessary to use strings here)? Composing the string while creating the exception is futile if noone uses it, so why not create it on-demand? – dyp Apr 6 '13 at 14:00
I'm not saying it's necessary; I'm saying it may be useful. Also, all exceptions will be effectively dynamically allocated, anyways. (Just think, how does std::exception const& become MyException const&?). Dynamic allocations for exceptions should be avoided, but I wouldn't say it's a no-no. The point was, if you don't have enough memory to allocate a string to provide a meaningful error, you've probably got issues elsewhere. – Nathan Ernst Apr 9 '13 at 1:40
"also, all exceptions will be effectively dynamically allocated, anyways." that is to say - otherwise the runtime must know statically at link time the size of all possible exceptions which may occur. And there are certainly circumstances on which it may not know. – Nathan Ernst Apr 9 '13 at 1:42

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