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I have a recursive function written in C++ that dynamically allocates 2D arrays using new. How could I measure the total amount space function allocates on heap and stack during it's entire lifetime ?

Here is an example(it is not my code) of how to measure Stack.

unsigned int maxStackLocation ; 
unsigned int minStackLocation ; 
main () 
{ 
    //get the address of a local variable before calling Quicksort 
    //the stack grows down, so this is the max stack location 
    int localVariable;
    void *currPtrLocation = (void*)(&localVariable); 
    maxStackLocation = *(unsigned int *)(&currPtrLocation); 
    //we get the value for the minimum stack location in quicksort itself 
    //call quicksort 
    Quick (A, num); 
    space = maxStackLocation - minStackLocation;
} 
//some redundant function whose stack usage will be measured
void Quick (unsigned int A[], int num) 
{ 
    if (num <= 1) 
    { 
        //check the stack usage 
        //figure out where we are on the stack by looking at the byte  
        // address of the local variable 
        //we do this by making a pointer to a local variable, and then  
        //casting it to a integer 
        void *currPtrLocation = (void*)(&num); 
        unsigned int currStackLocation = *(unsigned int*)(&currPtrLocation); 
        if (currStackLocation < minStackLocation) 
            minStackLocation = currStackLocation; 
        return; 
    }
}

Edit
Borgleader points out that my original question "Measuring max space function allocates on heap and stack during it's entire lifetime" is incorrect. I have changed "max" to "total".

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3  
There's an entire section in one of the books by Scott Meyer's on how there is no reliable way to differentiate between heap and stack allocation. You might be able to get total allocation but you wouldn't know in which of the two it happened. –  Borgleader Dec 2 '12 at 7:14
    
@Borgleader Good point, I will probably revise my question. –  newprint Dec 2 '12 at 7:19
    
Keep a global variable and update it wherever you have a new statement –  AsheeshR Dec 2 '12 at 7:32
    
@Borgleader - Please let me know which of Scott Meyer's books has this section... and which section? Thanks. –  phonetagger Dec 3 '12 at 16:15
    
@phonetagger: IIRC it's in "More Effective C++" Item 27: Requiring or prohibiting heap-based objects. –  Borgleader Dec 3 '12 at 16:44

3 Answers 3

up vote 1 down vote accepted

Your example for measuring stack usage is spot-on, and will give you a (very nearly) correct answer. I have a suggestion for determining heap usage as well, but first....

In his book “More Effective C++” in item 27, Scott Meyers (incidentally my favorite author on C++) describes why it’s not possible in the general sense and within the bounds of portable or semi-portable C++ to definitively distinguish whether an object has been allocated on the stack, heap, or is statically allocated. But his explanation pertains to allocated objects from the perspective of the objects themselves, not allocations from the perspective of the code that requests such an allocation. From the perspective of code that requests an allocation you can know with certainty whether an object, regardless of its type, is allocated on the heap or stack based on how you requested its allocation. (Sidebar: Of course this depends on your system actually using a runtime stack, which some are quick to point out that the C++ standard does not guarantee, yet none of these standards snobs ever point out any real-world example of an otherwise standard-conforming C++ compiler that does not use a runtime stack. Back to our discussion...) For example:

int Fred;  // Fred is allocated on the stack
int *Barney = new int; // Barney is allocated on the heap

Fred will destruct when he goes out of scope; you must explicitly delete Barney when you’re done with him. This works the same for user-defined types, including STL types:

std::string Fred; // Fred is allocated on the stack (see disclaimer*)
std::string *Barney = new std::string(); // Barney is allocated on the heap

// *Disclaimer:  May not be totally true on some small embedded processors that
//               implement the runtime stack in a special small address space
//               separate from “normal” RAM.

...BUT: Though the std::string object known as Fred is itself allocated on the stack, we know of course that its data cannot be stack-allocated, because its data is variable-length and must be able to expand indefinitely as we add characters to it. So only the management portion of a std::string (i.e. the std::string object itself) can be stack-allocated.

Back to Scott Meyer’s item 27 and it applicability to this discussion:

myClass *someFunction() {
    int someInputParameter = 42;
    myClass Fred(someInputParameter); // Fred is allocated on the stack
    myClass *Barney = new myClass(someInputParameter); // Barney is allocated on the heap
    return Barney;
}

According to Scott Meyer’s item 27, neither Fred nor Barney can know for themselves whether they are stack- or heap-allocated, or for that matter, statically-allocated (i.e. “global” or “file scope” or a “static member of some other class”). But within someFunction(), we can know because we know how we requested the allocation.


Now, back to your problem:

As I said, the example you show for measuring stack usage is spot-on. You know for certain in main() that ‘localVariable’ is allocated on the stack. And you know for certain in Quick() that ‘currPtrLocation’ is on the stack. And if your stack grows down, you know for certain that because main() calls Quick(), the address of ‘currPtrLocation’ in Quick() will be lower than the address of ‘localVariable’ in main(), so your arithmetic works. It won’t give a perfectly correct answer because there may be other variables in Quick() that are allocated at stack locations yet lower than ‘currPtrLocation’, but your measurement will be really close; certainly as close as you should care about. Whatever the error amount is, it’s a fixed error regardless of how deep your call stack goes, and if you recurse any significant number of times, the error as a percentage of the whole will be negligible. One last thing: If you want the solution to be portable even to systems where the stack grows UP, you can detect the direction of the difference between the address of ‘localVariable’ and ‘currPtrLocation’ and compute the difference (i.e. swap the arguments in the subtraction) accordingly.

Regarding heap usage:

Your system may have hooks you can tie into for measuring heap usage stats, but if you don’t want to delve into that, you can do something along the lines of what Synxis proposed, but there are some serious problems with that answer. First of all, Synxis's suggestion misses all of the stack overhead, including return addresses, spilled registers, etc, which are not insignificant. Second, if you use the stack measuring technique like you show in your question, there’s no need to painstakingly maintain a sum of allocations for stack-allocated objects anyway. Third, assuming you only sum the allocations of heap-allocated objects (whose size you can get with the sizeof() operator), you can’t just keep summing them. You’d have to subtract the allocations’ sizes when you delete them so your “totalSize” maintains the total size of all currently allocated objects, and you’d want to separately keep track of the high-water-mark of the totalSize. That way you can know the largest amount of memory that your algorithm used at any one time. Without doing that, you might be confused when your algorithm reports that it used something like 758 Gigabytes even though you only have 4G of RAM. And finally, whether you allocate a given object itself on the stack or heap, it may make its own internal allocations on the heap. (If it makes temporary allocations on the stack when you call a method on that object, unless you put your stack-tracking code in that method as well, your stack total won't be exactly correct as I already described, but the error will continue to be more-or-less constant, depending on whether the method executes conditionals that might alter its calling behavior.) Anyway, regarding this "given object" that you allocate on the stack or heap; if it allocates its own internal heap memory, unless you add heap allocation tracking to the internal objects, you'll miss whatever amount of heap memory was allocated to those internal objects. So maybe you'd be better off looking into the heap stats hooks your system might make available.

Now, assuming you want to do track heap allocations yourself... Another option you might explore would be to write a base class from which your algorithm can derive for all of the objects it creates. Your base class could override operator new & operator delete such that the base class itself does all of the totalSize tracking (adding for ‘new’ and subtracting for ‘delete’) using a static class variable in the base class.

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Valgrind actually can do a quite precise measurement for you. All that you need is to write as simplest as possible example which calls your function.

for example a program which just prints its arguments (passed to the main() function) using for-loop and std::cout produce the following output:

zaufi@gentop /work/tests $ valgrind --tool=drd --show-stack-usage=yes ./stack-usage-test-1
==26999== drd, a thread error detector
==26999== Copyright (C) 2006-2012, and GNU GPL'd, by Bart Van Assche.
==26999== Using Valgrind-3.8.1 and LibVEX; rerun with -h for copyright info
==26999== Command: ./stack-usage-test-1
==26999==
./stack-usage-test-1
==26999== thread 1 finished and used 11944 bytes out of 8388608 on its stack. Margin: 8376664 bytes.
==26999==
==26999== For counts of detected and suppressed errors, rerun with: -v
==26999== ERROR SUMMARY: 0 errors from 0 contexts (suppressed: 0 from 0)

As one may see the only thread will consume almost 12K on stack. And definitely most of this space was "wasted" before the main(). To make a better measurement it is necessary to run a target function in a separate thread. Smth like this:

#include <iostream>
#include <thread>

int main(int argc, char* argv[])
{
    auto thr = std::thread([](){std::cout << __PRETTY_FUNCTION__ << std::endl;});
    thr.join();
    return 0;
}

This code will produce the following output:

==27029== thread 2 finished and used 1840 bytes out of 8384512 on its stack. Margin: 8382672 bytes.
==27029== thread 1 finished and used 11992 bytes out of 8388608 on its stack. Margin: 8376616 bytes.

that is definitely better. So measuring a function which do nothing, you've got a minimum stack usage (in the last example it's about 1840 bytes). So if you would call your target function in a separate thread, you have to substract 1840 bytes (or even less) from a result...


almost the same you can do yourself using the following simple algorithm:

  1. allocate 8M buffer from a heap (default stack size for linux/pthreads, but you may alloc actually any other (reasonable) size)
  2. fill it w/ some pattern
  3. fork a new thread with a stack assigned to just allocated and filled area (using pthread_attr_setstack() (or friends))
  4. as soon as you can call your target function whithin that thread and exit
  5. in the main thread, after pthread_join() successed, analyze your buffer to find an area, where the pattern you assigned before has not preserved

(even) in that case you'd better to do a first measurement on a thread which is do nothing -- just to get a minimum usage size as above.

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Ho come you failed to mention Valgrind's heap profiler? Massif does report peak heap usage, as well as allocation statistics on snapshots –  sehe Dec 3 '12 at 23:34

Having the exact total size is almost impossible, as it depends on your platform, the calling conventions, the optimization mode, etc... But you can have an estimate. I don't count parameters, as there are not always handled by the called function (depending on the calling convention).

There are no C++ nor C features to do this.
I don't know any debugger that would indicate this number. I never used Valgrind and co so I can't tell you if they can show you this number (I doubt they do)
So, last option: count by yourself...

unsigned int totalSize = 0;

int partition(unsigned int A[], int num, int left, int right, int pivot)
{
    /// UpdateTotalSize
    totalSize += sizeof(unsigned int);
    /// /UpdateTotalSize
    unsigned int value = A[pivot];
    A[pivot] = A[right];
    A[right] = value;

    /// UpdateTotalSize
    totalSize += sizeof(int);
    /// /UpdateTotalSize
    int store = left;

    for(int i = left; i < right; i++)
        if(A[i] < value)
        {
            // This variable does not count in the total size:
            // allocated, then deallocated, and so on...
            unsigned int tmp = A[i];
            A[i] = A[store];
            A[store] = tmp;
            store++;
        }

    /// UpdateTotalSize
    totalSize += sizeof(int);
    /// /UpdateTotalSize
    int tmp = A[store];
    A[store] = A[right];
    A[right] = tmp;
    return store;
}

void quick(unsigned int A[], int num, int left = -1, int right = -1)
{
    if(num <= 1)
        return;

    if(left <= -1)
        left = 0;
    if(right <= -1)
        right = right = num - 1;

    if(left >= right)
        return;

    /// UpdateTotalSize
    totalSize += sizeof(int);
    /// /UpdateTotalSize
    int pivot = (left + right) / 2;

    /// UpdateTotalSize
    totalSize += sizeof(int);
    /// /UpdateTotalSize
    int pivotNew = partition(A, num, left, right, pivot);

    quick(A, num, left, pivotNew - 1);
    quick(A, num, pivotNew + 1, right);
}

Note that this is just an estimation of the total size. Also, for this example, it can be done mentally.

Last but not least: this count is unreliable when optimizations are turned on, so use it only whithout optimizations!

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