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I am writing a library for various mathematical computations in C. Several of these need some "scratch" space -- memory that is used for intermediate calculations. The space required depends on the size of the inputs, so it cannot be statically allocated. The library will typically be used to perform many iterations of the same type of calculation with the same size inputs, so I'd prefer not to malloc and free inside the library for each call; it would be much more efficient to allocate a large enough block once, re-use it for all the calculations, then free it.

My intended strategy is to request a void pointer to a single block of memory, perhaps with an accompanying allocation function. Say, something like this:

void *allocateScratch(size_t rows, size_t columns);
void doCalculation(size_t rows, size_t columns, double *data, void *scratch);

The idea is that if the user intends to do several calculations of the same size, he may use the allocate function to grab a block that is large enough, then use that same block of memory to perform the calculation for each of the inputs. The allocate function is not strictly necessary, but it simplifies the interface and makes it easier to change the storage requirements in the future, without each user of the library needing to know exactly how much space is required.

In many cases, the block of memory I need is just a large array of type double, no problems there. But in some cases I need mixed data types -- say a block of doubles AND a block of integers. My code needs to be portable and should conform to the ANSI standard. I know that it is OK to cast a void pointer to any other pointer type, but I'm concerned about alignment issues if I try to use the same block for two types.

So, specific example. Say I need a block of 3 doubles and 5 ints. Can I implement my functions like this:

void *allocateScratch(...) {
    return malloc(3 * sizeof(double) + 5 * sizeof(int));

void doCalculation(..., void *scratch) {
    double *dblArray = scratch;
    int *intArray = ((unsigned char*)scratch) + 3 * sizeof(double);

Is this legal? The alignment probably works out OK in this example, but what if I switch it around and take the int block first and the double block second, that will shift the alignment of the double's (assuming 64-bit doubles and 32-bit ints). Is there a better way to do this? Or a more standard approach I should consider?

My biggest goals are as follows:

  • I'd like to use a single block if possible so the user doesn't have to deal with multiple blocks or a changing number of blocks required.
  • I'd like the block to be a valid block obtained by malloc so the user can call free when finished. This means I don't want to do something like creating a small struct that has pointers to each block and then allocating each block separately, which would require a special destroy function; I'm willing to do that if that's the "only" way.
  • The algorithms and memory requirements may change, so I'm trying to use the allocate function so that future versions can get different amounts of memory for potentially different types of data without breaking backward compatibility.

Maybe this issue is addressed in the C standard, but I haven't been able to find it.

share|improve this question
The first example is ok, in the second you will have to pad to the next nearest address divisible by sizeof( double ). – this Jan 15 '14 at 6:51
Yeah, that's sort of what I expected. Is that guaranteed to be acceptable though? It seems that trying to ensure correct alignment manually may not be worth the effort. – Jeremy West Jan 15 '14 at 6:53
Yes, it is correct. In that way you will waste memory of only the last member. If you use an union you will waste for every member. Just make sure you know where int ends and double begins. – this Jan 15 '14 at 6:57
(note: you can't perform arithmetic on void*, so in your scratch + N*sizeof(double) you should cast scratch to char*, or to double* and then adding only N, and finally re-cast it to int* – ShinTakezou Jan 15 '14 at 7:23
@ShinTakezou Oh, yes, good catch! Obviously, I didn't compile my example code :). – Jeremy West Jan 15 '14 at 7:24
up vote 2 down vote accepted

If the user is calling your library's allocation function, then they should call your library's freeing function. This is very typical (and good) interface design.

So I would say just go with the struct of pointers to different pools for your different types. That's clean, simple, and portable, and anybody who reads your code will see exactly what you are up to.

If you do not mind wasting memory and insist on a single block, you could create a union with all of your types and then allocate an array of those...

Trying to find appropriately aligned memory in a massive block is just a mess. I am not even sure you can do it portably. What's the plan? Cast pointers to intptr_t, do some rounding, then cast back to a pointer?

share|improve this answer
I considered the union option, but it does seem a bit wasteful. In the end, I'll probably go with the "struct of pointers" solution because it is definitely correct (and clear). I'm probably working too hard to avoid multiple allocations. – Jeremy West Jan 15 '14 at 6:43
likely. Moreover, in ANSI C there's no intptr_t and to perform alignment "by hand" of the second block you would have needed to cast it into the proper integral type, producing not-so-portable code. – ShinTakezou Jan 15 '14 at 7:21

The latest C11 standard has the max_align_t type (and _Alignas specifier and _Alignof operator and <stdalign.h> header).

GCC compiler has a __BIGGEST_ALIGNMENT__ macro (giving the maximal size alignment). It also proves some extensions related to alignment.

Often, using 2*sizeof(void*) (as the biggest relevant alignment) is in practice quite safe (at least on most of the systems I heard about these days; but one could imagine weird processors and systems where it is not the case, perhaps some DSP-s). To be sure, study the details of the ABI and calling conventions of your particular implementation, e.g. x86-64 ABI and x86 calling conventions...

And the system malloc is guaranteed to return a sufficiently aligned pointer (for all purposes).

On some systems and targets and some processors giving a larger alignment might give performance benefit (notably when asking the compiler to optimize). You may have to (or want to) tell the compiler about that, e.g. on GCC using variable attributes...

Don't forget that according to Fulton

there is no such thing as portable software, only software that has been ported.

but intptr_t and max_align_t is here to help you....

share|improve this answer
So, to clarify, you're suggesting that as long as I split my scratch space into blocks that are multiples of sizeof(max_align_t), I'm fine? – Jeremy West Jan 15 '14 at 6:35
Read the question carefully... He wants one block of memory, some of which will hold (e.g.) a sequence of double, and some of which will hold (e.g.) a sequence of int. None of your observations help in this case. – Nemo Jan 15 '14 at 6:35
+1 for revealing that c11 has max_align_t. It is defined with a hack. – this Jan 15 '14 at 7:02

The memory of a single malloc can be partitioned for use in multiple arrays as shown below.

Suppose we want arrays of types A, B, and C with NA, NB, and NC elements. We do this:

size_t Offset = 0;

ptrdiff_t OffsetA = Offset;           // Put array at current offset.
Offset += NA * sizeof(A);             // Move offset to end of array.

Offset = RoundUp(Offset, sizeof(B));  // Align sufficiently for type.
ptrdiff_t OffsetB = Offset;           // Put array at current offset.
Offset += NB * sizeof(B);             // Move offset to end of array.

Offset = RoundUp(Offset, sizeof(C));  // Align sufficiently for type.
ptrdiff_t OffsetC = Offset;           // Put array at current offset.
Offset += NC * sizeof(C);             // Move offset to end of array.

unsigned char *Memory = malloc(Offset);  // Allocate memory.

// Set pointers for arrays.
A *pA = Memory + OffsetA;
B *pB = Memory + OffsetB;
C *pC = Memory + OffsetC;

where RoundUp is:

// Return Offset rounded up to a multiple of Size.
size_t RoundUp(size_t Offset, size_t Size)
    size_t x = Offset + Size - 1;
    return x - x % Size;

This uses the fact, as noted by R.., that the size of a type must be a multiple of the alignment requirement for that type. In C 2011, sizeof in the RoundUp calls can be changed to _Alignof, and this may save a small amount of space when the alignment requirement of a type is less than its size.

share|improve this answer

Note that the required alignment for any type must evenly divide the size of the type; this is a consequence of the representation of array types. Thus, in the absence of C11 features to determine the required alignment for a type, you can just estimate conservatively and use the type's size. In other words, if you want to carve up part of an allocation from malloc for use storing doubles, make sure it starts at an offset that's a multiple of sizeof(double).

share|improve this answer
Is that guaranteed to be safe? Or just likely? – Jeremy West Jan 15 '14 at 6:46
Just very likely – Basile Starynkevitch Jan 15 '14 at 8:29
@BasileStarynkevitch: How do you figure it is just very likely? The size of an object must be a multiple of its alignment requirement (due to C‘s requirements for arrays). Therefore, if the offset from the start of the allocation (which is guaranteed to be suitably aligned for any object with a fundamental alignment requirement) is a multiple of the size of an object, the address is suitably aligned for the object. – Eric Postpischil Jan 15 '14 at 11:22
It is related to the ABI specification of your particular implementation. – Basile Starynkevitch Jan 15 '14 at 11:42
@BasileStarynkevitch: I do not see how that answers the question. Please show an example where aligning an object to a multiple of its size would not produce the alignment required for the object. – Eric Postpischil Jan 15 '14 at 14:59

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