no, not really, they're just syntactical sugar mostly
you can see that in languages like Scala where every function is an operator, but that can lead to some rather badly readable code
user7659542
I am reading the SDM of my x86 CPU, which states:
user7659542
The Intel486 processor (and newer processors since) guarantees that the following basic memory operations will
always be carried out atomically:
• Reading or writing a word aligned on a 16-bit boundary
I have a program which occasionally gives the wrong result. Even with the same input 99% of the time it's correct but for some reason it's occasionally wrong. Does this mean there's undefined behavior somewhere?
also you were quoting some very different things, the 16-bit alignment of x86 is only spuriosly related to the 16-byte alignment of some SIMD instructions
Out of curiosity how do variable length instructions works on CISC? I guess the first part of the instructor allows the processor to tell how long the entire instruction is?
Valgrind is detecting race conditions and I may know why. What could go wrong if two threads modify the same element in a std::vector<vector> to the same value? For example t1 and t2 at the same time change myVec.at(1) = false
If both threads are setting it to the same value shouldn't it be ok?
The type of a C++ enum is the enum itself. Its range is rather arbitrary, but in practical terms, its underlying type is an int.
It is implicitly cast to int wherever it's used, though.
C++11 changes
This has changed since C++11, which introduced typed enums. An untyped enum now is defined as ...
If you use "enum class", you'll force the scope of the enum, so the values will not be accessible through the "parent" code, but will be accessible only with the enum scope you specify.
Is there still a race condition if both threads are writing the same value to the same element in a std::vector<bool>? I kind of doubt it because the values are the same.
Actually I still don't see what difference <bool> makes in this specific situation? As long as the same value is being addressed isn't that all that matters? How would <char> be different? @PeterT
guys i have a little problem over here after defining a new input file object i get an error error: aggregate 'std::ifstream file' has incomplete type and cannot be defined|
I am finding it difficult to really understand why the compiler synthesizes a copy-assignment operator declaration as a deleted function if a data member is const or a reference. Please can anyone demonstrate this with a simple example for me to understand it better?
That's understandable, because by the time the copy-assignment operator is called on the object, the object has already been created and the const member initialized? Okay.
well that's a little bit more complicated, you can't rebind a reference and it would be confusing in some cases if you would just call the copy assignment of the non-reference version.
I have been running b2 --prefix="..\" --toolset=msvc architecture=x86 address-model=64 --build-type=complete --link=static install, and boost was built, but it won't install, aka copying the libs to a place where I can include the folder properly. Any way to fix this? I am on Windows 10.
@PeterT does that means that the reason is just because the data member (of the left operand of =) that's a reference will remain bound to the object to which it did before the copy-assignment operation and not to the object the reference data member (of the right operand of =) is bound to, is why it's prevented?
@octopus I always just assumed that was the reason, I don't remember it being written down anywhere. The standard just says what the rules are, not why
Declares an unscoped enumeration type whose underlying type is not fixed (in this case, the underlying type is an implementation-defined integral type that can represent all enumerator values; this type is not larger than int unless the value of an enumerator cannot fit in an int or unsigned int. If the enumerator-list is empty, the underlying type is as if the enumeration had a single enumerator with value 0).
it means if you do enum A {B,C,D}; Then the compiler can make A be char, short or int , because A,C,B are only 3 values and can be represented by any of those types
enum A {B=500} can only be short or int, because char would be too small
so let's say enum A{B,C,D} gets interpreded by compiler as char values. What happends if i have more than 255 elements in the list? they are promoted to next integer type which can holds it ?
@PeterT you said enum A {B=500} can only be short or int, because char would be too small but what about int_16 or uint16 these types cant be valid data type representations for enumerators?
Yeah, I don't really get it either. Might be something like "You can define the operators this way and they will keep the same logic that's used for them normally"
Don't worry about it, this is just a chat room, if I don't want to answer I just wont. I'm interested in learning the details of C++ as well. That's what I like about Stackoverflow because people may ask questions I've never really thought of.
In C++ unspecified is usually "compilers are allowed to do this specific thing in a specific way they want, but they have to do it so that the rest keeps working as described"
undefined means "the compiler can completely ignore what would happen if the programmer did this, it is allowed to crash, to work as the programmer expected, it's allowed to call 911 and have your arrested"
Values of integer, floating-point, and enumeration types can be converted by static_cast or explicit cast, to any enumeration type. If the underlying type is not fixed and the source value is out of range, the result is unspecified (until C++17)undefined (since C++17). ___(The source value, as converted to the enumeration's underlying type if floating-point, is in range if it would fit in the smallest bit field large enough to hold all enumerators of the target enumeration.)___ Otherwise, the result is the same as the result of implicit conversion to the underlying type.
but i dont understand what is meant by this example assert((rwe & read) && (rwe & write) && (rwe & exec));
this is some weird stuff. enum access_t { read = 1, write = 2, exec = 4 }; contains 0b0001, ob0010, 0b0100 and they say that now a 7 which is 0b0111 in binary can be converted to that enum without undefined behaviour. How does it comes?
The type of a C++ enum is the enum itself. Its range is rather arbitrary, but in practical terms, its underlying type is an int.
It is implicitly cast to int wherever it's used, though.
C++11 changes
This has changed since C++11, which introduced typed enums. An untyped enum now is defined as ...
