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I have long wondered whether storing items of different types in a continuous block of memory is well defined by the standard.

I already have experience making homogeneous containers using malloc and pointer arithmetic to manage the elements individually.

Now I want to go further, I plan to store several different types contiguously in a single block.

It is important to ignore alternatives such as variant or tag-union because the purpose is low-level storage to implement interpreters and virtual machines that require direct contact with memory for maximum possible performance.

In the following example I store a char, followed by an int and finally a double.

char* block = (char*)malloc(16);

//storage char

(char*) a = block;
*a = 'Z';

//storage int

(int*) b = block+4;

*b = 777;

//storage double

(double*) c = block+8;

*c = 3.1415;

free(block)

enter image description here

This is useful to use in a new interpreter that allows to execute a new programming language where its rules allow instantiating structure objects whose members are defined at run time.

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  • 4
    char* block = malloc(16); -- this is not C++, it will not compile.
    – 3CxEZiVlQ
    Commented Apr 5, 2023 at 18:47
  • 1
    This is legal starting with C++20 as long as you are using implicit lifetime types. It should be noted that malloc doesn't have to returned aligned memory, so this can cause code that will fail to work on certain architectures. Commented Apr 5, 2023 at 18:47
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    That's what structures and classes are all about: Store variables of different type in a collective block of memory. Please use structures and classes instead, then you don't have to worry about things like alignment and padding etc. It will all be handled for you by the compiler. Commented Apr 5, 2023 at 18:49
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    FWIW, The C++ ways to make a heterogenous container are: std::tuple, std::some_container_name<std::variant<your_type_set>>, std:;some_container<std::any> Commented Apr 5, 2023 at 18:49
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    @NathanOliver Cppreference says the returned memory alignment must be suitable for any scalar type. Commented Apr 5, 2023 at 18:55

2 Answers 2

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Looks mostly legal, but:

  1. You should use sizeof and alignof to compute the offsets in a portable manner.

  2. You need to std::launder the pointers. Like this: std::launder(reinterpret_cast<T *>(block + i)).

  3. If your types are not scalars (not implicit lifetime types, rather), or if you're not using C++20 or newer, you must start the object lifetime using ::new((void *)address) T (note, must not use std::launder here yet) (if you preserve the returned pointer from new, instead of recomputing it independently, you can drop launder).

In practice, you may or may not be able to get away with not doing [2] (especially pre-C++17, where there's no launder), and with not doing [3] for trivially constructible types (such as scalars), but technically this would be UB.

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  • Even before C++20 clarified the rules, I'm pretty sure trivial types just kind of pop into existence as needed. The only rule for beginning their lifetime is "when storage with the proper alignment and size for type T is obtained" (see [basic.life]). Commented Apr 5, 2023 at 19:20
  • The C++ rules on "object creation" are self-contradictory, while the rules on object lifetime are clear. Stick to the rules on lifetime.
    – Ben Voigt
    Commented Apr 5, 2023 at 19:26
  • @BenVoigt Can you elaborate what rules you're referring to, and where the contradictions are? Commented Apr 5, 2023 at 19:42
  • @MilesBudnek It's been a while since I've dealt with it, but C++17 and earlier appear to have a contradiction. Your quote contradicts with [intro.object]/1, which pre-C++20 doesn't allow implicit object creation. Then there's P0593R6 (which is what added implicit lifetime stuff to C++20, I think?), and it refers to [intro.object]/1 as a proof that implicit lifetime wasn't a thing. Commented Apr 5, 2023 at 19:50
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    @HolyBlackCat: If the rules in the Standard fit neither the actual behavior of compilers nor the tasks that programmers need to accomplish, why should anyone care what they are?
    – supercat
    Commented Apr 5, 2023 at 21:45
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Pre C++20: Eh, maybe? The rules are unclear and contradictory.
In C++20 and later: this is pretty much fine

Before C++20 the rules around object creation and lifetime weren't well written. Even for something simple like this it's unclear if the result is well-defined (even though it's the normal and expected use of malloc):

char* a = (char*)malloc(10);
a[0] = 'a';

So everyone basically just ignored the exact wording of the standard and made this work, since it clearly should.


C++20 fixed the wording of the standard by creating a new category of implicit-lifetime objects. These objects must be of implicit-lifetime types: scalar types and class types that are aggregates or have a trivial constructor.

malloc is now defined to implicitly create objects of implicit-lifetime types in the storage that it allocates. Exactly which types of objects malloc implicitly creates is unspecified. As long as there's some set of types that causes the program to be well-defined, that's the type of objects it creates.

In your original example, if malloc created a char, an int, and a double in the region of storage that it returned, then the program would be well-defined, so that's what we say it implicitly did.


Keep in mind that all of the above only applies to trivial types. For anything that requires non-trivial construction you will need to use placement-new to create the object in the storage returned by malloc.

Of course, there's no real reason not to use placement-new to initialize trivial types as well, so you would probably be better off sidestepping the entire issue by just using placement-new for everything. For instance, your original example could be rewritten like this to avoid all of these language-lawyery issues:

template <typename T>
std::size_t align_for(std::size_t n) {
    return n % alignof(T) == 0 ? 0 : alignof(T) - (n % alignof(T));
}


int main() {
    std::size_t size = 1;  // For the char
    size += align_for<int>(size) + sizeof(int);
    size += align_for<double>(size) + sizeof(double);
    size += align_for<std::string>(size) + sizeof(std::string);
    char* block = reinterpret_cast<char*>(std::malloc(size));
    std::size_t next = 0;
    
    //store char
    char* a = new (block + next) char('Z');
    next += 1;
    
    //store int
    next += align_for<int>(next);
    int* b = new (block + next) int(777);
    next += sizeof(int);
    
    //store double
    next += align_for<double>(next);
    double* c = new (block + next) double(3.1415);
    next += sizeof(double);
    
    //store non-trivial type: std::string
    next += align_for<std::string>(next);
    std::string* d = new (block + next) std::string("hello world");
    next += sizeof(std::string);
    
    //Note: must manually call the destructor of non-trivial types,
    //      but it's also harmless to do so for trivial types as well
    std::destroy_at(a);
    std::destroy_at(b);
    std::destroy_at(c);
    std::destroy_at(d);
    
    std::free(block);
}

Demo

Note that in this example I have:

  1. Used alignof and sizeof to calculate the size of the buffer and position of the objects within it in a portable way.
  2. Used placement-new for everything to ensure objects are properly created and initialized. This isn't necessary for implicit-lifetime types, but it also doesn't hurt and is required for non-trivial types.
  3. Explicitly destroyed everything. Again, this is not necessary for trivial types, but is required otherwise. It doesn't hurt to explicitly destroy trivial types though (and the calls will likely result in no extra code being generated by the compiler).
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  • Note that in both clang and gcc, if storage is observed holding a certain bit pattern using one type, a sequence of operations using another type which would leave the storage holding the same bit pattern may retroactively cause the type of the storage to revert to the earlier type.
    – supercat
    Commented Apr 5, 2023 at 21:42

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