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int sum(const int numbers[], const int size){
    if (size == 0)
        return 0;
        return numbers[0] + sum(numbers+1, size-1);

This is a simple recursive function from MIT 6.096 for adding an arbitrary number of integers, and it works.

The thing I cannot understand is in the last line:

How does numbers+1 work, given numbers[] is an int array and you shouldn't be able to add an integer to an int[] constant?

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This is C code. Using a recursive function to calculate the sum of an array is really the worst possible example they could have picked. Who writes examples like this? A recursive function is best used on a necessarily recursive algorithm. – tadman Mar 28 at 15:11
Here, const int numbers[] is the same as const int* numbers: A non constant pointer to constant values – Dieter Lücking Mar 28 at 15:12
@tadman for some reason, on some compilers, if they spot a tail recursion, they generate faster code than they would for a loop. However, I agree it is not easy reading. – Tom Tanner Mar 28 at 15:57
@TomTanner I'd really like to see some benchmarks for that because it sounds like an urban legend to me. – tadman Mar 28 at 15:58
@TomTanner It doesn't really matter here because this example isn't tail-recursive. – Random832 Mar 28 at 17:29

how does "numbers+1" work, given numbers[] is an int array and you shouldn't be able to add an integer to an int[] constant?

There's no int[] constant. numbers is decayed to a pointer and numbers+1 is simple pointer arithmetic applied to the parameter passed to the recursive call.

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"numbers is decayed to a pointer". No it isn't. It is declared as a pointer. The token sequence const int numbers[], when it appears in a formal parameter list, declares a pointer and not an array. – Ben Voigt Mar 28 at 19:32
From 8.3.5p5: "The type of a function is determined using the following rules. The type of each parameter (including function parameter packs) is determined from its own decl-specifier-seq and declarator . After determining the type of each parameter, any parameter of type 'array of T' or 'function returning T' is adjusted to be 'pointer to T' or 'pointer to function returning T', respectively." – Ben Voigt Mar 28 at 19:34
@BenVoigt I feel like πάντα ῥεῖ is saying that numbers decays to an int* to be passed into int sum(const int numbers[], const int size). If you disagree with that perhaps you should answer separately illustrating the delineation. – Jonathan Mee Mar 28 at 19:56
@BenVoigt Is right. numbers - the function parameter - isn't an array, thus it doesn't get implicitly converted ("decays") to a pointer. It always was a pointer. – Daniel Jour Mar 28 at 21:01
@JonathanMee Sure do, it is in the std (13.1.3): Parameter declarations that differ only in a pointer * versus an array [] are equivalent. That is, the array declaration is adjusted to become a pointer declaration. Only the second and subsequent array dimensions are significant in parameter types – Chris A Mar 29 at 9:12

As a side note to @πάντα ῥεῖ's very succinct and apt answer, here are a few clarifications on the terminology:

The following is another way to depict array notation:

The phrase numbers[1] can also be expressed as *(numbers + 1) Where the * operator is said to dereference the pointer address numbers + 1. dereference can be thought of in this case as read the value pointed to by.

So, the code in your example is using pointer arithmetic. The phrase numbers + 1 is pointer notation, pointing to the second int location of the pointer numbers. size - 1 is a count of bytes from the memory location starting at numbers to the end of the array.

As to the meaning of decayed:
Generally, within the context of C array arguments, decay conveys the idea that the array argument experiences loss of type and dimension information. Your const int numbers[] is said (arguably) to decay into an int *, therefore no longer able to provide array size information. (Using the sizeof() macro for example does not provide length of array, but size of the pointer.) This also is the reason a second argument is provided, to convey size information.

However, in the context of this question, the meaning of decay is academic, as pointed out by @Ben Voigt: The token sequence const int numbers[], when it appears in a formal parameter list, declares a pointer and not an array. (It never decayed into a pointer because it was a pointer to begin with.)

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I was about to hijack this question but then found some info here So C/C++ is smart enough to figure out the actual address given the type of the array? For example if numbers is at location C00 then numbers+1 isn't actually C01 but C04 because an int is 4 bytes long? I was a bit suprised you didn't need to do numbers+1*sizeof(int) or something. – Celeritas Mar 29 at 8:04
@Celeritas - LOL, hijack? should I be frightened? :) So C/C++ is smart enough to figure out the actual address given the type of the array?. True, when a pointer is passed as an argument, the function prototype conveys the type information for that pointer. Regarding: then numbers+1 isn't actually C01 but C04. Yes, if in that implementation an int is defined having 32 bits. That is often true, but not always. The address is changed by increments (or decrements) of the variable type it is associated with, however that variable type is defined. – ryyker Mar 29 at 13:17
I guess I'm surprised that C/C++ is friendly enough/smart enough to do this automatically. – Celeritas Mar 29 at 21:16

As πάντα ῥεῖ says int[] decays to int*.

But this sum function is the poor man's solution, you should prefer accumulate:

cout << accumulate(numbers, next(numbers, size), decay_t<decltype(numbers[0])>{});

Live Example

If you have C++17 and a statically allocated array, such as int numbers[size], you can take advantage of cbegin and cend:

cout << accumulate(cbegin(numbers), cend(numbers), decay_t<decltype(numbers[0])>{});

I've attempted to benchmark the recursive sum against accumulate, however sum runs out of stack space before I am able to reach a vector size with a meaningful difference, making accumulate the clear winner.

I associate the type of accumulate's init agument with the type of numbers' elements: decay_t<decltype(numbers[0])>{}. The reason for this is if someone was to come back and change the type of numbers, and not change the type of accumulate's init argument the accumulation would be assigned to the wrong type.

For example if we use the accumulation line: cout << accumulate(cbegin(numbers), cend(numbers), 0), this is fine for int numbers[]. The problem would arise if we switched to define: double numbers[] = {1.3, 2.3, 3.3, 4.3}; but we failed to change the init argument we would sum doubles into an int. This would result in 10 rather than 11.2:

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Yeah cos decay_t<decltype(numbers[0])> is super-expressive and easy to understand. WTG C++! – Lightness Races in Orbit Mar 28 at 16:14
Extremely sarcastic. C++ is terrible. – Lightness Races in Orbit Mar 28 at 16:42
@BarryTheHatchet: Yeah, unless you're deliberately trying to obfuscate your code (which IMHO is the only rationale for about 2/3 of C++ 'features'), use a for loop. – jamesqf Mar 28 at 17:55
@JamesAdkison: It's a common, humourous, deliberate error. – Lightness Races in Orbit Mar 28 at 18:18
Isn't the extent already removed because you do decltype(numbers[0]), so an element in the array which doesn't have an extent? – Felix Dombek Mar 28 at 18:33
int sum(int *num,int size)
int total=0;
                                   /* function to sum integer array */
if (size <= 0) return(ERROR);
while(size--) total+= *num++;
return total;

Is faster, more compact, and error tolerant.

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@TomTanner says that "Some compilers, if they spot a tail recursion, they generate faster code than they would for a loop." So when you say your code is "faster" have you timed that? – Jonathan Mee Mar 29 at 11:07
I've updated my answer with benchmarking, and I'm certain that your "faster" claim is false. I cannot reach statistical difference between any of these solutions without running out of stack space. In other words, the compiler is turning them all into the exact same solution. – Jonathan Mee Mar 29 at 11:58
@Jonathan Mee: Could we say "no slower" instead of "faster"? I would expect a good compiler (in Intel architecture, anyway) to effectively parallelize that construct with SSE instructions. Also remember that if we're talking about large arrays, time reading from memory is important, and it's generally faster to do a linear read. And regardless of execution speed, this is one heck of a lot easier to understand than any alternative. – jamesqf Mar 29 at 18:50

numbers is a pointer ; on each iteration the function sum() advances through the array (this is what numbers+1 does), at the same time decreasing size by 1 (--size would work just as well).

When size reaches 0 this is the exit condition, and the recursion ends.

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Consider combining your answers into a single answer. – Jonathan Mee Mar 29 at 11:09

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