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When I was reading seastar source code, I noticed that there is a union structure called tx_side which has only one member. Is this some hack to deal with a certain problem?

FYI, I paste the tx_side structure below:

union tx_side {
    tx_side() {}
    ~tx_side() {}
    void init() { new (&a) aa; }
    struct aa {
        std::deque<work_item*> pending_fifo;
    } a;
} _tx;
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    Potential duplicate of stackoverflow.com/questions/26572432/…. – Max Langhof Nov 27 '19 at 9:32
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    @MaxLanghof This question and corresponding answers didn't mention about the purpose of using such union structure. – daoliker Nov 27 '19 at 9:37
  • Have you an example for a use of this member? – n314159 Nov 27 '19 at 9:39
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    That's why I didn't actually use my binding close vote. But I'm not sure what exactly you expect from answers to your question that doesn't follow directly from the answers over there. Presumably the purpose of using union instead of struct is one or more of the differences between the two. It's a pretty obscure technique so unless the original author of that code comes along I'm not sure somebody can give you an authoritative answer which problem they're hoping to solve with this (if any). – Max Langhof Nov 27 '19 at 9:40
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    My best guess is that union is used to either delay construction (which is somewhat pointless in this case) or prevent destruction (which leads to memory leak) of pending_fifo. But hard to say without example of usage. – Konstantin Stupnik Nov 27 '19 at 9:53
87

Because tx_side is a union, tx_side() doesn't automatically initialize/construct a, and ~tx_side() doesn't automatically destruct it. This allows a fine-grained control over the lifetime of a and pending_fifo, via placement-new and manual destructor calls (a poor man's std::optional).

Here's an example:

#include <iostream>

struct A
{
    A() {std::cout << "A()\n";}
    ~A() {std::cout << "~A()\n";}
};

union B
{
    A a;
    B() {}
    ~B() {}
};

int main()
{
    B b;
}

Here, B b; prints nothing, because a is not constructed nor destructed.

If B was a struct, B() would call A(), and ~B() would call ~A(), and you wouldn't be able to prevent that.

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    @daoliker not necessarily random, but unpredictable by you. Same as any other uninitialized variable. You can't assume it's random; for all you know it could hold the user's password that you previously asked them to type in. – user253751 Nov 27 '19 at 10:20
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    @daoliker: The previous comment is too optimistic. Random bytes would have values in the range 0-255, but if you read an uninitialized byte into an int you may get 0xCCCCCCCC. Reading uninitialized data is Undefined Behavior, and what might happen is that the compiler simply discards the attempt. This is not just theory. Debian made this exact mistake, and it broke their OpenSSL implementation. They had some real random bytes, added an uninitialized variable, and the compiler said "well the result is undefined, so it might as well be zero". Zero obviously isn't random anymore. – MSalters Nov 28 '19 at 10:49
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    @MSalters: Do you have a source for this claim? Because what I can find suggests that is not what happened: it wasn't the compiler that removed it, but the developers. Honestly, I'd be amazed if any compiler writer made such an incredibly bad decision. (see stackoverflow.com/questions/45395435/… ) – Jack Aidley Nov 28 '19 at 12:21
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    @JackAidley: Which precise claim? You do have a good link, seems I got the story inverted. OpenSSL got the logic wrong, and used an uninitialized variable in such a way that a compiler could legally assume any result. Debian correctly spotted that, but broke the fix. As for "compilers making such bad decisions"; they don't make that decision. The Undefined Behavior is the bad decision. Optimizers are designed to run on correct code. GCC for instance actively assumes no signed overflow. Assuming "no uninitialized data" is equally reasonable; it can be used to eliminate impossible code paths. – MSalters Nov 28 '19 at 12:37
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    @JackAidley I've encountered similar issues to what @MSalters mentions in my own code; I erroneously assumed an uninitialized variable would be empty, and was baffled when a subsequent != 0 comparison yielded true. I've since added compiler flags to treat uninitialized variables as errors to make sure I won't fall into that trap again. – Tom Lint Nov 28 '19 at 12:41
0

In simple words, unless explicitly assigned/initialized a value the single member union does not initialize the allocated memory. This functionality can be achieved with std:: optional in c++17.

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    That's a misleading answer. Union with only one member will have the same size as the member. This memory simply won't be initialized till the member is initialized. – Kirill Dmitrenko Dec 6 '19 at 15:51

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