# Can array indexing start at a number other than 0 in C or C++?

Is it possible to start an array at an index not zero...I.E. you have an array a[35], of 35 elements, now I want to index at say starting 100, so the numbers would be a[100], a[101], ... a[134], is that possible?

I'm attempting to generate a "memory map" for a board and I'll have one array called SRAM[10000] and another called BRAM[5000] for example, but in the "memory" visibility they're contiguous, I.E. BRAM starts right after SRAM, so therefore if I try to point to memory location 11000 I would read it see that it's over 10000 then pass it to BRAM.

While typing this I realized I could I suppose then subtract the 10K from the number and pass that into BRAM, but for the sake of argument, is this possible to index passing 11000 to BRAM?

In the actual architecture I will be implementing, there can/may be a gap between the SRAM and BRAM so for example the address 11008 might not be visible in the memory map, thus writing a giant array full of memory then "partitioning" it will work, but I'll still have to do logic to determine if it's within the ranges of "SRAM and BRAM". Which is what I wanted to avoid in the first place.

• What kind of sequence is 100, 101...34? :o And no, index's always start from 0. you'll need to do some math. Feb 18, 2010 at 15:06
• I'm guessing a[100], a[101], ... a[34] should be a[100], a[101], ... a[134]. Could someone edit this please? Feb 18, 2010 at 15:14
• sorry I missed the 1 in there, I meant 100, 101,... 134...sorry Feb 18, 2010 at 15:18
• You could always define SRAM[10035] and ignore the first 10000 elements, memory is cheap nowadays... :-) Feb 18, 2010 at 15:19
• Also, are you trying to do this in C, or in C++? They are two very different things, with two very different approaches to getting what you want. You can do it (almost) transparently in C++ by building your own array class. You can do it in C too, but your code will be clunkier, function calls each time you access the array. Feb 18, 2010 at 15:34

Is it possible to start an array at an index not zero...I.E. you have an array a[35], of 35 elements, now I want to index at say starting 100, so the numbers would be a[100], a[101], ... a[134], is that possible?

No, you cannot do this in C. Arrays always start at zero. In C++, you could write your own class, say OffsetArray and overload the [] operator to access the underlying array while subtracting an offset from the index.

I'm attempting to generate a "memory map" for a board and I'll have one array called SRAM[10000] and another called BRAM[5000] for example, but in the "memory" visiblity they're contiguous, I.E. BRAM starts right after SRAM, so therefore if I try to point to memory location 11000 I would read it see that it's over 10000 then pass it to bram.

You could try something like this:

char memory[150000];
char *sram = &memory[0];
char *bram = &memory[100000];


Now, when you access sram[110000] you'll be accessing something that's "in bram"

• +1, in fact it would make sense using memory to access the whole memory map and sran and bram to access specific subobjects Feb 18, 2010 at 15:18
• In general I like this idea, but I still wish for there to be that "upper bound" but I suppose that can and will be user defined. Feb 18, 2010 at 15:38
• How about using a macro: #define ARRAY_OFFSET ((x) - 100) and accessing the array like memory[ARRAY_OFFSET(100)]. The macro has some delusions to it, but it is compatible with both C and C++. Feb 18, 2010 at 20:00

C++ provides quite a bit more than C in this respect. You can overload operator[] to do the subtraction, and if you want report an error (e.g., throw an exception) if the subscript is out of range.

As a minimal demo, consider the following:

#include <iostream>
#include <stdexcept>

template <class T, int lower, int upper>
class array {
T data[upper-lower];
public:
T &operator[](int index) {
if (index < lower || index >= upper)
throw std::range_error("Index out of range");
return data[index-lower];
}
T *begin() { return data; }
T *end() { return data + (upper-lower); }
};

int main() {
array<int, -3, 5> data;

for (int i=-3; i<5; i++)
data[i] = i;

for (auto const &i : data)
std::cout << i << "\t";
std::cout << "\n";
}

• I hope you're just pointing this out as a possible solution and not recommending it. :-) Overloading the [] operator leads to unnecessary complexity. Feb 18, 2010 at 15:13
• @Steve: Not really. Overloading operators to do what they normally don't is confusing. Making a + b write a and b to a file is confusing. [] is for indexing. That said, It's probably easier just to get a new pointer by adding an offset and using the built-in operator[]. For any more complex indexing scheme's, making a wrapper class with operator[] is definitely cleanest. Feb 18, 2010 at 15:21
• There's no built-in operator[] for classes unless you provide one. Feb 18, 2010 at 15:38
• @Steve:I'd say exactly the opposite: this a case of overloading the operator to do exactly what the user would expect, so it eliminates unnecessary complexity instead of adding it. Feb 18, 2010 at 16:28
• For higher dimensions, you can overload operator(), or you can do multiple overloads of operator[], as shown in another answer. Apr 13, 2019 at 17:52

I remember reading in the book Expert C Programming - Deep C Secrets by Peter Van der Linden discloses a trick to fool the compiler into thinking array offsets starts at 1. Theoretically the trick can be accomplished, I do not have the book with me, but offhand, I recall reading it; it is not portable and may produce undefined behavior.

See here section 6.17 on the C-FAQ. WARNING: Not Portable and Undefined behavior! To quote from the source here.

6.17: Here's a neat trick: if I write

int realarray[10];
int *array = &realarray[-1];


I can treat "array" as if it were a 1-based array.

A: Although this technique is attractive (and was used in old editions of the book Numerical Recipes in C), it is not strictly conforming to the C Standard. Pointer arithmetic is defined only as long as the pointer points within the same allocated block of memory, or to the imaginary "terminating" element one past it; otherwise, the behavior is undefined, even if the pointer is not dereferenced. The code above could fail if, while subtracting the offset, an illegal address were generated (perhaps because the address tried to "wrap around" past the beginning of some memory segment).

References: K&R2 Sec. 5.3 p. 100, Sec. 5.4 pp. 102-3, Sec. A7.7 pp. 205-6; ISO Sec. 6.3.6; Rationale Sec. 3.2.2.3.

• Even though it is undefined behaviour from an language perspective, it should technically work reliably due to the way modern computers address their memory. The only danger is, that the optimizer figures out that you are invoking undefined behaviour, and optimizes your code away. Jan 11, 2014 at 17:53
• Where does it say technically work reliably? It is undefined behaviour for that reason alone, i.e. not to be used everyday, and depends on the C Compiler in question and also the environment itself. There are no guarantees either, regardless if the code optimizes away or not. It may crash, segfault, clobber some other memory part. Using code like that, will raise alarms among code reviewers and be cause of concern as well - i.e. code smells. Jan 11, 2014 at 18:03
• Well, do some assembler coding, and you'll know why it's technically reliable. Pointers are nothing else than 32 or 64 bit integers under the hood, the hardware does not even distinguish between signed and unsigned (because it does not need to). Anything involved in pointer arithmetic is identical to unsigned integer arithmetic. Jan 11, 2014 at 18:19
• On a system using segmentation, even attempting to form an address before the beginning of an array could throw a hardware exception. Segmentation-based virtual memory is no longer common, but has been used in real systems fairly recently (e.g., OS/2 1.x, 16-bit Windows). On such systems, this code most certainly could fail to the extent of throwing an exception as the program was loading, so none of it would run at all. Sep 24, 2014 at 12:51

You could cheat with macro:

int myarray[35];

#define a (myarray - 100)

a[100] = 0;


A pointer could also be used.

No — as in you can't modify the lower bound in declaration like VB6.

Yes — as in you can do tricks like

int a[35];
int* actual_a = a-100;
printf("%d", actual_a[101]);
...


because x[a] is equivalent to *(x+a). This is highly unrecommended.

• As forming the pointer a - 100 results in undefined behaviour, I would go further than just saying "highly unrecommended". Feb 18, 2010 at 15:35
• I see how storing the result is UB. But in the expression (a-100)[101], would the sub-expression already cause UB? C has a lot of latitude in reordering evaluation. So, it appears the expressions *(a-100+101), *(a+101-100) and *(a+(101-100)) are all equal, as all can be reordered to the same result. But as the latter is not UB, it seems none should be UB. The reason I wonder is because a macro #define ACTUAL_A (a-100) would expand to this form. Feb 19, 2010 at 9:27

You're not very clear on exactly how you want to use these arrays, but its easy enough to set up a single contiguous array that can appear to be two different arrays:

int   ram[15000];
int * sram=&ram[0];
int * bram=&ram[10000];


I used the &foo[xxx] notation just to make it explicit what you're doing. Anyway, you can now use ram to index anywhere into the entire array, or sram and bram to index into particular parts.

• A scary thought: the solution allows access to regions of undefined memory or it provides memory where there isn't any. Feb 18, 2010 at 20:04
• Well, yes and no. It provides no more unrestricted access to memory than does standard array indexing in C. Provided that one doesn't index out of bounds, one is just as safe as with normal arrays. Feb 19, 2010 at 20:18

strictly speaking, this solution does not loet you define an array starting at an index different from 0, but you may declare your memory this way:

typedef union
{
unsigned char all[15000];
struct
{
unsigned char sram[10000];
unsigned char bram[5000];
};
} memory;


this does convey the intent that the memory is contiguous, and that it is split in 2 parts. note that you should beware of the alignment of bram and sram, a #pragma pack(1) may be necessary.

As others have noted, you can technically achieve what you want by invoking pointer arithmetic like this:

int* myArray = malloc((upperBound - lowerBound) * sizeof(*myArray));
myArray -= lowerBound;
...
for(int i = lowerBound; i < upperBound; i++) {
myArray[i];
}


While this will work flawlessly with -O0, it is undefined behaviour from a language point of view. The machine, however, has absolutely no objections to this, to the machine the pointer arithmetic involved is the same as any unsigned integer arithmetic with uintptr_t. Thus, the only danger to this approach is the optimizer.

Now, you can easily defeat the optimizer by splitting the code above into two different compilation units, i. e. have one ".c" file with the function

int* fancyIntArray(size_t lowerBound, size_t upperBound) {
return intMalloc(upperBound - lowerBound) - lowerBound;
}


and put the function intMalloc() into a different ".c" file:

int* intMalloc(size_t size) {
return malloc(size_t*sizeof(int));
}


Now, you are safe, because when the optimizer looks at the pointer arithmetic in fancyIntArray(), it does not know that there is no allocated memory in front of the address that intMalloc() returns, as it does not know anything about intMalloc() itself. As such, it is forced to leave your code intact.

And, of course, you should use independent compiler calls to compile the different ".c" files, so that the optimizer really cannot deduce anything about intMalloc().

• What exactly could the optimizer do to the code of the first example? Apr 18, 2014 at 20:08
• @MichaelLehn The danger of the optimizer is, that it is allowed to remove code of which it can prove that it invokes undefined behavior. I. e. it may replace the undefined behavior with the behavior of doing nothing. Sounds smart, but it creates quite a few traps where people unknowingly invoke undefined behavior - in the first example, it might just remove the entire loop. So, if you really want to use something that is technically undefined behavior, at least make sure that the optimizer is not able to deduce what's going on. Apr 18, 2014 at 21:42

Not in C. You have to do the arithmetic yourself. There are probably bizarre work-arounds that work most of the time, like making a new pointer that is BRAM-11000 and using that instead.

The simplest way to do this:

you have:

int *array = memory ; // starts with 0;
array-= 1000 ; // now array[1000] is 0


In c++ just create class with operator[]

• That'll probably work in most C compilers but it's not guaranteed by the standard. Only pointers within an array or one past the end are guaranteed. Feb 18, 2010 at 15:16
• @paxdiablo: Let's get pedantic and technical here. Does the C standard not guarantee dereferencing of pointers outside an array or does it not guarantee pointer arithmetic beyond the array boundaries? In my experience, one could define a pointer to the first UART register and adjust the pointer for other contiguous registers, even though an array was never declared. Feb 18, 2010 at 20:07
• Pointer arithmetic is guaranteed up to and including one past the end; derefering is guaranteed for the actual array elements only. The difference is so you can use pointer arithmetic to determine if you have hit the end of an array, before dereferencing the pointer. Pointers to UART registers are always UB. Feb 19, 2010 at 9:32

Pointers and arrays are very similar in C, so you could easilly do something like

element SRAM_MEM[10000];
element BRAM_MEM[5000];

element* SRAM = SRAM_MEM;
element* BRAM = BRAM_MEM-10000;

BRAM[10001] = 0; // sets the first element of BRAM_MEM


Just have a variable that takes into account the offset. Even if possible, having an array that doesn't start at the conventional 0 would be highly unreadable.

Perhaps you can use union?

#pragma pack(0)
union
{
char array[15000];
struct { char sram[10000]; char bram[5000];  } map;
} combination;


They are physically contiguous. If you access 'array' then it will go into either bram or sram based on the offset

You need the pragma to tell the compiler to NOT align struct members on word boundaries. This prevents a number of bytes of space between the two parts of the map structure.