What trait / concept can guarantee memsetting an object is well defined?











up vote
14
down vote

favorite
3












Let's say I have defined a zero_initialize() function:



template<class T>
T zero_initialize()
{
T result;
std::memset(&result, 0, sizeof(result));
return result;
}

// usage: auto data = zero_initialize<Data>();


Calling zero_initialize() for some types would lead to undefined behavior1, 2. I'm currently enforcing T to verify std::is_pod. With that trait being deprecated in C++20 and the coming of concepts, I'm curious how zero_initialize() should evolve.




  1. What (minimal) trait / concept can guarantee memsetting an object is well defined?

  2. Should I use std::uninitialized_fill instead of std::memset? And why?

  3. Is this function made obsolete by one of C++ initialization syntaxes for a subset of types? Or will it be with the upcoming of future C++ versions?




1)Erase all members of a class.
2)What would be reason for “undefined behaviors” upon using memset on library class(std::string)? [closed]










share|improve this question


















  • 1




    Possible duplicate of Why is std::is_pod deprecated in C++20?
    – Alan Birtles
    yesterday






  • 7




    @AlanBirtles Are you serious?
    – YSC
    yesterday






  • 5




    @AlanBirtles: Not a duplicate. memset is a different beast.
    – Nicol Bolas
    yesterday










  • Sometimes i think these are bots
    – Croll
    19 hours ago















up vote
14
down vote

favorite
3












Let's say I have defined a zero_initialize() function:



template<class T>
T zero_initialize()
{
T result;
std::memset(&result, 0, sizeof(result));
return result;
}

// usage: auto data = zero_initialize<Data>();


Calling zero_initialize() for some types would lead to undefined behavior1, 2. I'm currently enforcing T to verify std::is_pod. With that trait being deprecated in C++20 and the coming of concepts, I'm curious how zero_initialize() should evolve.




  1. What (minimal) trait / concept can guarantee memsetting an object is well defined?

  2. Should I use std::uninitialized_fill instead of std::memset? And why?

  3. Is this function made obsolete by one of C++ initialization syntaxes for a subset of types? Or will it be with the upcoming of future C++ versions?




1)Erase all members of a class.
2)What would be reason for “undefined behaviors” upon using memset on library class(std::string)? [closed]










share|improve this question


















  • 1




    Possible duplicate of Why is std::is_pod deprecated in C++20?
    – Alan Birtles
    yesterday






  • 7




    @AlanBirtles Are you serious?
    – YSC
    yesterday






  • 5




    @AlanBirtles: Not a duplicate. memset is a different beast.
    – Nicol Bolas
    yesterday










  • Sometimes i think these are bots
    – Croll
    19 hours ago













up vote
14
down vote

favorite
3









up vote
14
down vote

favorite
3






3





Let's say I have defined a zero_initialize() function:



template<class T>
T zero_initialize()
{
T result;
std::memset(&result, 0, sizeof(result));
return result;
}

// usage: auto data = zero_initialize<Data>();


Calling zero_initialize() for some types would lead to undefined behavior1, 2. I'm currently enforcing T to verify std::is_pod. With that trait being deprecated in C++20 and the coming of concepts, I'm curious how zero_initialize() should evolve.




  1. What (minimal) trait / concept can guarantee memsetting an object is well defined?

  2. Should I use std::uninitialized_fill instead of std::memset? And why?

  3. Is this function made obsolete by one of C++ initialization syntaxes for a subset of types? Or will it be with the upcoming of future C++ versions?




1)Erase all members of a class.
2)What would be reason for “undefined behaviors” upon using memset on library class(std::string)? [closed]










share|improve this question













Let's say I have defined a zero_initialize() function:



template<class T>
T zero_initialize()
{
T result;
std::memset(&result, 0, sizeof(result));
return result;
}

// usage: auto data = zero_initialize<Data>();


Calling zero_initialize() for some types would lead to undefined behavior1, 2. I'm currently enforcing T to verify std::is_pod. With that trait being deprecated in C++20 and the coming of concepts, I'm curious how zero_initialize() should evolve.




  1. What (minimal) trait / concept can guarantee memsetting an object is well defined?

  2. Should I use std::uninitialized_fill instead of std::memset? And why?

  3. Is this function made obsolete by one of C++ initialization syntaxes for a subset of types? Or will it be with the upcoming of future C++ versions?




1)Erase all members of a class.
2)What would be reason for “undefined behaviors” upon using memset on library class(std::string)? [closed]







c++ c++14 metaprogramming sfinae c++20






share|improve this question













share|improve this question











share|improve this question




share|improve this question










asked yesterday









YSC

19.2k34591




19.2k34591








  • 1




    Possible duplicate of Why is std::is_pod deprecated in C++20?
    – Alan Birtles
    yesterday






  • 7




    @AlanBirtles Are you serious?
    – YSC
    yesterday






  • 5




    @AlanBirtles: Not a duplicate. memset is a different beast.
    – Nicol Bolas
    yesterday










  • Sometimes i think these are bots
    – Croll
    19 hours ago














  • 1




    Possible duplicate of Why is std::is_pod deprecated in C++20?
    – Alan Birtles
    yesterday






  • 7




    @AlanBirtles Are you serious?
    – YSC
    yesterday






  • 5




    @AlanBirtles: Not a duplicate. memset is a different beast.
    – Nicol Bolas
    yesterday










  • Sometimes i think these are bots
    – Croll
    19 hours ago








1




1




Possible duplicate of Why is std::is_pod deprecated in C++20?
– Alan Birtles
yesterday




Possible duplicate of Why is std::is_pod deprecated in C++20?
– Alan Birtles
yesterday




7




7




@AlanBirtles Are you serious?
– YSC
yesterday




@AlanBirtles Are you serious?
– YSC
yesterday




5




5




@AlanBirtles: Not a duplicate. memset is a different beast.
– Nicol Bolas
yesterday




@AlanBirtles: Not a duplicate. memset is a different beast.
– Nicol Bolas
yesterday












Sometimes i think these are bots
– Croll
19 hours ago




Sometimes i think these are bots
– Croll
19 hours ago












3 Answers
3






active

oldest

votes

















up vote
19
down vote



accepted










There is technically no object property in C++ which specifies that user code can legally memset a C++ object. And that includes POD, so if you want to be technical, your code was never correct. Even TriviallyCopyable is a property about doing byte-wise copies between existing objects (sometimes through an intermediary byte buffer); it says nothing about inventing data and shoving it into the object's bits.



That being said, you can be reasonably sure this will work if you test is_trivially_copyable and is_trivially_default_constructible. That last one is important, because some TriviallyCopyable types still want to be able to control their contents. For example, such a type could have a private int variable that is always 5, initialized in its default constructor. So long as no code with access to the variable changes it, it will always be 5. The C++ object model guarantees this.



So you can't memset such an object and still get well-defined behavior from the object model.






share|improve this answer

















  • 3




    I appreciate the double answer (language-lawyer/real life exists).
    – YSC
    yesterday


















up vote
8
down vote














What (minimal) trait / concept can guarantee memsetting an object is well defined?




Per the std::memset reference on cppreference the behavior of memset on a non TriviallyCopyable type is undefined. So if it is okay to memset a TriviallyCopyable then you can add a static_assert to your class to check for that like



template<class T>
T zero_initialize()
{
static_assert(std::is_trivial_v<T>, "Error: T must be TriviallyCopyable");
T result;
std::memset(&result, 0, sizeof(result));
return result;
}


Here we use std::is_trivial_v to make sure that not only is the class trivially copyable but it also has a trivial default constructor so we know it is safe to be zero initialized.




Should I use std::uninitialized_fill instead of std::memset? And why?




You don't need to here since you are only initializing a single object.




Is this function made obsolete by one of C++ initialization syntaxes for a subset of types? Or will it be with the upcoming of future C++ versions?




Value or braced initialization does make this function "obsolete". T() and T{} will give you a value initialized T and if T doesn't have a default constructor it will be zero initialized. That means you could rewrite the function as



template<class T>
T zero_initialize()
{
static_assert(std::is_trivial_v<T>, "Error: T must be TriviallyCopyable");
return {};
}





share|improve this answer



















  • 2




    Pardon, but OP used std::memset, not std::memcpy. Does it make a difference though?
    – Rafał Górczewski
    yesterday






  • 1




    @RafałGórczewski OMG. Can't believe I did that. memset has the same requirements so I've just swapped the link and the function names.
    – NathanOliver
    yesterday






  • 2




    It should be noted that TriviallyCopyable only guarantees that byte copying works. Setting the value of a type through a byte array is, as far as I'm aware, not allowed. Plus, TriviallyCopyable does not guarantee default-constructible. So your zero_initialize function isn't allowed. It would only work if you also verified trivially_default_constructible.
    – Nicol Bolas
    yesterday












  • @NicolBolas Good point. I've updated the code to use std::is_trivial_v to guarantee the class is completely trivial.
    – NathanOliver
    yesterday


















up vote
0
down vote













The most general definable trait that guarantees your zero_initialize will actually zero-initialize objects is



template <typename T>
struct can_zero_initialize :
std::bool_constant<std::is_integral_v<
std::remove_cv_t<std::remove_all_extents_t<T>>>> {};


Not too useful. But the only guarantee about bitwise or bytewise representations of fundamental types in the Standard is [basic.fundamental]/7 "The representations of integral types shall define values by use of a pure binary numeration system." There is no guarantee that a floating-point value with all bytes zero is a zero value. There is no guarantee that any pointer or pointer-to-member value with all bytes zero is a null pointer value. (Though both of these are usually true in practice.)



If all non-static members of a trivially-copyable class type are (arrays of) (cv-qualified) integral types, I think that would also be okay, but there's no possible way to test for that, unless reflection comes to C++.






share|improve this answer

















  • 1




    This is true, but I think It does matter to me. Even if for some impl/arch a zero-representation doesn't imply a zero-semantic for some type, zero_initialize() is still well defined. It's up to the user not to assume things.
    – YSC
    yesterday













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3 Answers
3






active

oldest

votes








3 Answers
3






active

oldest

votes









active

oldest

votes






active

oldest

votes








up vote
19
down vote



accepted










There is technically no object property in C++ which specifies that user code can legally memset a C++ object. And that includes POD, so if you want to be technical, your code was never correct. Even TriviallyCopyable is a property about doing byte-wise copies between existing objects (sometimes through an intermediary byte buffer); it says nothing about inventing data and shoving it into the object's bits.



That being said, you can be reasonably sure this will work if you test is_trivially_copyable and is_trivially_default_constructible. That last one is important, because some TriviallyCopyable types still want to be able to control their contents. For example, such a type could have a private int variable that is always 5, initialized in its default constructor. So long as no code with access to the variable changes it, it will always be 5. The C++ object model guarantees this.



So you can't memset such an object and still get well-defined behavior from the object model.






share|improve this answer

















  • 3




    I appreciate the double answer (language-lawyer/real life exists).
    – YSC
    yesterday















up vote
19
down vote



accepted










There is technically no object property in C++ which specifies that user code can legally memset a C++ object. And that includes POD, so if you want to be technical, your code was never correct. Even TriviallyCopyable is a property about doing byte-wise copies between existing objects (sometimes through an intermediary byte buffer); it says nothing about inventing data and shoving it into the object's bits.



That being said, you can be reasonably sure this will work if you test is_trivially_copyable and is_trivially_default_constructible. That last one is important, because some TriviallyCopyable types still want to be able to control their contents. For example, such a type could have a private int variable that is always 5, initialized in its default constructor. So long as no code with access to the variable changes it, it will always be 5. The C++ object model guarantees this.



So you can't memset such an object and still get well-defined behavior from the object model.






share|improve this answer

















  • 3




    I appreciate the double answer (language-lawyer/real life exists).
    – YSC
    yesterday













up vote
19
down vote



accepted







up vote
19
down vote



accepted






There is technically no object property in C++ which specifies that user code can legally memset a C++ object. And that includes POD, so if you want to be technical, your code was never correct. Even TriviallyCopyable is a property about doing byte-wise copies between existing objects (sometimes through an intermediary byte buffer); it says nothing about inventing data and shoving it into the object's bits.



That being said, you can be reasonably sure this will work if you test is_trivially_copyable and is_trivially_default_constructible. That last one is important, because some TriviallyCopyable types still want to be able to control their contents. For example, such a type could have a private int variable that is always 5, initialized in its default constructor. So long as no code with access to the variable changes it, it will always be 5. The C++ object model guarantees this.



So you can't memset such an object and still get well-defined behavior from the object model.






share|improve this answer












There is technically no object property in C++ which specifies that user code can legally memset a C++ object. And that includes POD, so if you want to be technical, your code was never correct. Even TriviallyCopyable is a property about doing byte-wise copies between existing objects (sometimes through an intermediary byte buffer); it says nothing about inventing data and shoving it into the object's bits.



That being said, you can be reasonably sure this will work if you test is_trivially_copyable and is_trivially_default_constructible. That last one is important, because some TriviallyCopyable types still want to be able to control their contents. For example, such a type could have a private int variable that is always 5, initialized in its default constructor. So long as no code with access to the variable changes it, it will always be 5. The C++ object model guarantees this.



So you can't memset such an object and still get well-defined behavior from the object model.







share|improve this answer












share|improve this answer



share|improve this answer










answered yesterday









Nicol Bolas

278k33455627




278k33455627








  • 3




    I appreciate the double answer (language-lawyer/real life exists).
    – YSC
    yesterday














  • 3




    I appreciate the double answer (language-lawyer/real life exists).
    – YSC
    yesterday








3




3




I appreciate the double answer (language-lawyer/real life exists).
– YSC
yesterday




I appreciate the double answer (language-lawyer/real life exists).
– YSC
yesterday












up vote
8
down vote














What (minimal) trait / concept can guarantee memsetting an object is well defined?




Per the std::memset reference on cppreference the behavior of memset on a non TriviallyCopyable type is undefined. So if it is okay to memset a TriviallyCopyable then you can add a static_assert to your class to check for that like



template<class T>
T zero_initialize()
{
static_assert(std::is_trivial_v<T>, "Error: T must be TriviallyCopyable");
T result;
std::memset(&result, 0, sizeof(result));
return result;
}


Here we use std::is_trivial_v to make sure that not only is the class trivially copyable but it also has a trivial default constructor so we know it is safe to be zero initialized.




Should I use std::uninitialized_fill instead of std::memset? And why?




You don't need to here since you are only initializing a single object.




Is this function made obsolete by one of C++ initialization syntaxes for a subset of types? Or will it be with the upcoming of future C++ versions?




Value or braced initialization does make this function "obsolete". T() and T{} will give you a value initialized T and if T doesn't have a default constructor it will be zero initialized. That means you could rewrite the function as



template<class T>
T zero_initialize()
{
static_assert(std::is_trivial_v<T>, "Error: T must be TriviallyCopyable");
return {};
}





share|improve this answer



















  • 2




    Pardon, but OP used std::memset, not std::memcpy. Does it make a difference though?
    – Rafał Górczewski
    yesterday






  • 1




    @RafałGórczewski OMG. Can't believe I did that. memset has the same requirements so I've just swapped the link and the function names.
    – NathanOliver
    yesterday






  • 2




    It should be noted that TriviallyCopyable only guarantees that byte copying works. Setting the value of a type through a byte array is, as far as I'm aware, not allowed. Plus, TriviallyCopyable does not guarantee default-constructible. So your zero_initialize function isn't allowed. It would only work if you also verified trivially_default_constructible.
    – Nicol Bolas
    yesterday












  • @NicolBolas Good point. I've updated the code to use std::is_trivial_v to guarantee the class is completely trivial.
    – NathanOliver
    yesterday















up vote
8
down vote














What (minimal) trait / concept can guarantee memsetting an object is well defined?




Per the std::memset reference on cppreference the behavior of memset on a non TriviallyCopyable type is undefined. So if it is okay to memset a TriviallyCopyable then you can add a static_assert to your class to check for that like



template<class T>
T zero_initialize()
{
static_assert(std::is_trivial_v<T>, "Error: T must be TriviallyCopyable");
T result;
std::memset(&result, 0, sizeof(result));
return result;
}


Here we use std::is_trivial_v to make sure that not only is the class trivially copyable but it also has a trivial default constructor so we know it is safe to be zero initialized.




Should I use std::uninitialized_fill instead of std::memset? And why?




You don't need to here since you are only initializing a single object.




Is this function made obsolete by one of C++ initialization syntaxes for a subset of types? Or will it be with the upcoming of future C++ versions?




Value or braced initialization does make this function "obsolete". T() and T{} will give you a value initialized T and if T doesn't have a default constructor it will be zero initialized. That means you could rewrite the function as



template<class T>
T zero_initialize()
{
static_assert(std::is_trivial_v<T>, "Error: T must be TriviallyCopyable");
return {};
}





share|improve this answer



















  • 2




    Pardon, but OP used std::memset, not std::memcpy. Does it make a difference though?
    – Rafał Górczewski
    yesterday






  • 1




    @RafałGórczewski OMG. Can't believe I did that. memset has the same requirements so I've just swapped the link and the function names.
    – NathanOliver
    yesterday






  • 2




    It should be noted that TriviallyCopyable only guarantees that byte copying works. Setting the value of a type through a byte array is, as far as I'm aware, not allowed. Plus, TriviallyCopyable does not guarantee default-constructible. So your zero_initialize function isn't allowed. It would only work if you also verified trivially_default_constructible.
    – Nicol Bolas
    yesterday












  • @NicolBolas Good point. I've updated the code to use std::is_trivial_v to guarantee the class is completely trivial.
    – NathanOliver
    yesterday













up vote
8
down vote










up vote
8
down vote










What (minimal) trait / concept can guarantee memsetting an object is well defined?




Per the std::memset reference on cppreference the behavior of memset on a non TriviallyCopyable type is undefined. So if it is okay to memset a TriviallyCopyable then you can add a static_assert to your class to check for that like



template<class T>
T zero_initialize()
{
static_assert(std::is_trivial_v<T>, "Error: T must be TriviallyCopyable");
T result;
std::memset(&result, 0, sizeof(result));
return result;
}


Here we use std::is_trivial_v to make sure that not only is the class trivially copyable but it also has a trivial default constructor so we know it is safe to be zero initialized.




Should I use std::uninitialized_fill instead of std::memset? And why?




You don't need to here since you are only initializing a single object.




Is this function made obsolete by one of C++ initialization syntaxes for a subset of types? Or will it be with the upcoming of future C++ versions?




Value or braced initialization does make this function "obsolete". T() and T{} will give you a value initialized T and if T doesn't have a default constructor it will be zero initialized. That means you could rewrite the function as



template<class T>
T zero_initialize()
{
static_assert(std::is_trivial_v<T>, "Error: T must be TriviallyCopyable");
return {};
}





share|improve this answer















What (minimal) trait / concept can guarantee memsetting an object is well defined?




Per the std::memset reference on cppreference the behavior of memset on a non TriviallyCopyable type is undefined. So if it is okay to memset a TriviallyCopyable then you can add a static_assert to your class to check for that like



template<class T>
T zero_initialize()
{
static_assert(std::is_trivial_v<T>, "Error: T must be TriviallyCopyable");
T result;
std::memset(&result, 0, sizeof(result));
return result;
}


Here we use std::is_trivial_v to make sure that not only is the class trivially copyable but it also has a trivial default constructor so we know it is safe to be zero initialized.




Should I use std::uninitialized_fill instead of std::memset? And why?




You don't need to here since you are only initializing a single object.




Is this function made obsolete by one of C++ initialization syntaxes for a subset of types? Or will it be with the upcoming of future C++ versions?




Value or braced initialization does make this function "obsolete". T() and T{} will give you a value initialized T and if T doesn't have a default constructor it will be zero initialized. That means you could rewrite the function as



template<class T>
T zero_initialize()
{
static_assert(std::is_trivial_v<T>, "Error: T must be TriviallyCopyable");
return {};
}






share|improve this answer














share|improve this answer



share|improve this answer








edited yesterday

























answered yesterday









NathanOliver

82k15111172




82k15111172








  • 2




    Pardon, but OP used std::memset, not std::memcpy. Does it make a difference though?
    – Rafał Górczewski
    yesterday






  • 1




    @RafałGórczewski OMG. Can't believe I did that. memset has the same requirements so I've just swapped the link and the function names.
    – NathanOliver
    yesterday






  • 2




    It should be noted that TriviallyCopyable only guarantees that byte copying works. Setting the value of a type through a byte array is, as far as I'm aware, not allowed. Plus, TriviallyCopyable does not guarantee default-constructible. So your zero_initialize function isn't allowed. It would only work if you also verified trivially_default_constructible.
    – Nicol Bolas
    yesterday












  • @NicolBolas Good point. I've updated the code to use std::is_trivial_v to guarantee the class is completely trivial.
    – NathanOliver
    yesterday














  • 2




    Pardon, but OP used std::memset, not std::memcpy. Does it make a difference though?
    – Rafał Górczewski
    yesterday






  • 1




    @RafałGórczewski OMG. Can't believe I did that. memset has the same requirements so I've just swapped the link and the function names.
    – NathanOliver
    yesterday






  • 2




    It should be noted that TriviallyCopyable only guarantees that byte copying works. Setting the value of a type through a byte array is, as far as I'm aware, not allowed. Plus, TriviallyCopyable does not guarantee default-constructible. So your zero_initialize function isn't allowed. It would only work if you also verified trivially_default_constructible.
    – Nicol Bolas
    yesterday












  • @NicolBolas Good point. I've updated the code to use std::is_trivial_v to guarantee the class is completely trivial.
    – NathanOliver
    yesterday








2




2




Pardon, but OP used std::memset, not std::memcpy. Does it make a difference though?
– Rafał Górczewski
yesterday




Pardon, but OP used std::memset, not std::memcpy. Does it make a difference though?
– Rafał Górczewski
yesterday




1




1




@RafałGórczewski OMG. Can't believe I did that. memset has the same requirements so I've just swapped the link and the function names.
– NathanOliver
yesterday




@RafałGórczewski OMG. Can't believe I did that. memset has the same requirements so I've just swapped the link and the function names.
– NathanOliver
yesterday




2




2




It should be noted that TriviallyCopyable only guarantees that byte copying works. Setting the value of a type through a byte array is, as far as I'm aware, not allowed. Plus, TriviallyCopyable does not guarantee default-constructible. So your zero_initialize function isn't allowed. It would only work if you also verified trivially_default_constructible.
– Nicol Bolas
yesterday






It should be noted that TriviallyCopyable only guarantees that byte copying works. Setting the value of a type through a byte array is, as far as I'm aware, not allowed. Plus, TriviallyCopyable does not guarantee default-constructible. So your zero_initialize function isn't allowed. It would only work if you also verified trivially_default_constructible.
– Nicol Bolas
yesterday














@NicolBolas Good point. I've updated the code to use std::is_trivial_v to guarantee the class is completely trivial.
– NathanOliver
yesterday




@NicolBolas Good point. I've updated the code to use std::is_trivial_v to guarantee the class is completely trivial.
– NathanOliver
yesterday










up vote
0
down vote













The most general definable trait that guarantees your zero_initialize will actually zero-initialize objects is



template <typename T>
struct can_zero_initialize :
std::bool_constant<std::is_integral_v<
std::remove_cv_t<std::remove_all_extents_t<T>>>> {};


Not too useful. But the only guarantee about bitwise or bytewise representations of fundamental types in the Standard is [basic.fundamental]/7 "The representations of integral types shall define values by use of a pure binary numeration system." There is no guarantee that a floating-point value with all bytes zero is a zero value. There is no guarantee that any pointer or pointer-to-member value with all bytes zero is a null pointer value. (Though both of these are usually true in practice.)



If all non-static members of a trivially-copyable class type are (arrays of) (cv-qualified) integral types, I think that would also be okay, but there's no possible way to test for that, unless reflection comes to C++.






share|improve this answer

















  • 1




    This is true, but I think It does matter to me. Even if for some impl/arch a zero-representation doesn't imply a zero-semantic for some type, zero_initialize() is still well defined. It's up to the user not to assume things.
    – YSC
    yesterday

















up vote
0
down vote













The most general definable trait that guarantees your zero_initialize will actually zero-initialize objects is



template <typename T>
struct can_zero_initialize :
std::bool_constant<std::is_integral_v<
std::remove_cv_t<std::remove_all_extents_t<T>>>> {};


Not too useful. But the only guarantee about bitwise or bytewise representations of fundamental types in the Standard is [basic.fundamental]/7 "The representations of integral types shall define values by use of a pure binary numeration system." There is no guarantee that a floating-point value with all bytes zero is a zero value. There is no guarantee that any pointer or pointer-to-member value with all bytes zero is a null pointer value. (Though both of these are usually true in practice.)



If all non-static members of a trivially-copyable class type are (arrays of) (cv-qualified) integral types, I think that would also be okay, but there's no possible way to test for that, unless reflection comes to C++.






share|improve this answer

















  • 1




    This is true, but I think It does matter to me. Even if for some impl/arch a zero-representation doesn't imply a zero-semantic for some type, zero_initialize() is still well defined. It's up to the user not to assume things.
    – YSC
    yesterday















up vote
0
down vote










up vote
0
down vote









The most general definable trait that guarantees your zero_initialize will actually zero-initialize objects is



template <typename T>
struct can_zero_initialize :
std::bool_constant<std::is_integral_v<
std::remove_cv_t<std::remove_all_extents_t<T>>>> {};


Not too useful. But the only guarantee about bitwise or bytewise representations of fundamental types in the Standard is [basic.fundamental]/7 "The representations of integral types shall define values by use of a pure binary numeration system." There is no guarantee that a floating-point value with all bytes zero is a zero value. There is no guarantee that any pointer or pointer-to-member value with all bytes zero is a null pointer value. (Though both of these are usually true in practice.)



If all non-static members of a trivially-copyable class type are (arrays of) (cv-qualified) integral types, I think that would also be okay, but there's no possible way to test for that, unless reflection comes to C++.






share|improve this answer












The most general definable trait that guarantees your zero_initialize will actually zero-initialize objects is



template <typename T>
struct can_zero_initialize :
std::bool_constant<std::is_integral_v<
std::remove_cv_t<std::remove_all_extents_t<T>>>> {};


Not too useful. But the only guarantee about bitwise or bytewise representations of fundamental types in the Standard is [basic.fundamental]/7 "The representations of integral types shall define values by use of a pure binary numeration system." There is no guarantee that a floating-point value with all bytes zero is a zero value. There is no guarantee that any pointer or pointer-to-member value with all bytes zero is a null pointer value. (Though both of these are usually true in practice.)



If all non-static members of a trivially-copyable class type are (arrays of) (cv-qualified) integral types, I think that would also be okay, but there's no possible way to test for that, unless reflection comes to C++.







share|improve this answer












share|improve this answer



share|improve this answer










answered yesterday









aschepler

51k574126




51k574126








  • 1




    This is true, but I think It does matter to me. Even if for some impl/arch a zero-representation doesn't imply a zero-semantic for some type, zero_initialize() is still well defined. It's up to the user not to assume things.
    – YSC
    yesterday
















  • 1




    This is true, but I think It does matter to me. Even if for some impl/arch a zero-representation doesn't imply a zero-semantic for some type, zero_initialize() is still well defined. It's up to the user not to assume things.
    – YSC
    yesterday










1




1




This is true, but I think It does matter to me. Even if for some impl/arch a zero-representation doesn't imply a zero-semantic for some type, zero_initialize() is still well defined. It's up to the user not to assume things.
– YSC
yesterday






This is true, but I think It does matter to me. Even if for some impl/arch a zero-representation doesn't imply a zero-semantic for some type, zero_initialize() is still well defined. It's up to the user not to assume things.
– YSC
yesterday




















 

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