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From this comment in GCC bug #53119:

In C, {0} is the universal zero initializer equivalent to C++'s {} (the latter being invalid in C). It is necessary to use whenever you want a zero-initialized object of a complete but conceptually-opaque or implementation-defined type. The classic example in the C standard library is mbstate_t:

mbstate_t state = { 0 }; /* correctly zero-initialized */

versus the common but nonportable:

mbstate_t state;
memset(&state, 0, sizeof state);

It strikes me as odd that the latter version could be unportable (even for implementation-defined types, the compiler has to know the size). What is the issue here and when is a memset(x, 0, sizeof x) unportable?

0
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memset(p, 0, n) sets to all-bits-0.
An initializer of { 0 } sets to the value 0.
On just about any machine you've ever heard of, the two concepts are equivalent.

However, there have been machines where the floating-point value 0.0 was not represented by a bit pattern of all-bits-0. And there have been machines where a null pointer was not represented by a bit pattern of all-bits-0, either. On those machines, an initializer of { 0 } would always get you the zero initialization you wanted, while memset might not.

See also question 7.31 and question 5.17 in the C FAQ list.


Postscript: It's not clear to me why mbstate_t would be a "classic example" of this issue, though.


P.P.S. One other difference, as pointed out by @ryker: memset will set any "holes" in a padded structure to 0, while setting that structure to { 0 } might not.

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  • I was about to write the same. I was working on the soviet computer where float numbers with all words set to zero was a trap representation :) Nov 30 '21 at 13:30
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    It used to puzzle me that all-bits-0 could ever not be the floating-point value 0.0. But once you learn how floating-point values work inside, typically using an offset representation for the signed exponent, it's kind of surprising that all-bits-0 does represent 0.0, since an exponent value of 0 is typically represented as the biased form 0x80 or 0x400. (But of course in IEEE-754 0.0 is not stored with an actual exponent value of 0, so it works out.) Nov 30 '21 at 13:36
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    Classic may not be apropos, but because of the variability of how mbstate_t can be defined, it is a good example.
    – ryyker
    Nov 30 '21 at 17:49
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    @ThomasWeller For nonzero pointer examples, see question 5.17 in the C FAQ list. I don't have any names to hand of machines that had nonzero representations of floating-point 0.0, but I have it on good authority they existed. Nov 30 '21 at 22:09
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    @benrg Good point about monotonicity. Yet another way of looking at it is that 0.0 sits very nicely among the subnormals, where it surely belongs, because it obviously doesn't have an implicit "1" bit, either. Dec 1 '21 at 1:11
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The reason for this has to do with how types are represented.

Section 6.7.9p10 of the C standard describes how fields are initialized as follows:

If an object that has automatic storage duration is not initialized explicitly, its value is indeterminate. If an object that has static or thread storage duration is not initialized

explicitly, then:

  • if it has pointer type, it is initialized to a null pointer;

  • if it has arithmetic type, it is initialized to (positive or unsigned) zero;

  • if it is an aggregate, every member is initialized (recursively) according to these rules, and any padding is initialized to zero bits;

  • if it is a union, the first named member is initialized (recursively) according to these rules, and any padding is initialized to zero bits

And p21 also states:

If there are fewer initializers in a brace-enclosed list than there are elements or members of an aggregate, or fewer characters in a string literal used to initialize an array of known size than there are elements in the array, the remainder of the aggregate shall be initialized implicitly the same as objects that have static storage duration

The difference between this and setting all bytes to zero is that some of the above values may not necessarily be represented by all bits zero.

For example, there are some architectures where the address 0 is a valid address. This means that a null pointer is not represented as all bits zero. (Note: (void *)0 is specified as a null pointer constant by the standard, however the implementation will treat this as whatever the representation of a null pointer is)

The standard also doesn't mandate a particular representation for floating point types. While the most common representation, IEEE754, does use all bits 0 to represent the value +0, this is not necessarily true for other representations.

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  • "that a NULL pointer " better as "that a null pointer" (lower case). The null pointer constant NULL carries it set of difficulties. NULL may be int 0, yet a null pointer may differ from all zero bits. Nov 30 '21 at 14:11
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Noting a difference in behavior between the two methods...

In ...= {0}; if padding bytes exist, they will not be cleared.
But a call to memset() will clear padding.

From here

"Possible implementation of mbstate_t is a struct type holding an array representing the incomplete multibyte character, an integer counter indicating the number of bytes in the array that have been processed, and a representation of the current shift state."

In the case mbstate_t is implemented as a struct it is notable that {0} will not set padding bytes that may exist to zero, making the following assumption debatable:

mbstate_t state = { 0 }; /* correctly zero-initialized */
 

memset() however does include padding bytes.

memset(state , 0, sizeof state);//all bytes in memory region of test will be cleared

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