C++ Questions and Answers

Arkadiusz Koćma

02:55

@sehe In a (single threaded) io_context, if several coroutines enqueue an async_write on a shared resource (such as a socket), can the writes get interleaved?

Yashas

09:46

why is that the STL definition of lower_bound not identical to the mathematical definition of lower_bound?

they behave the same for equal ranges

but the two definitions give different results if the key is not present in the set

If we take the key as {key} (as a subset of a partial order relation (S, <)), the greatest lower bound should be the largest element (defined by <) which is the predecessor of key.

nwp

@ArkadiuszKoćma Only if the async_write has a yield.

Yashas

but std::lower_bound gives an element which is a successor of key

nwp

@Yashas std::lower_bound gives you the smallest value that is greater or equal to the key.

I don't know the relationship to math.

But it generally makes sense when you are looking for a range of values.

Yashas

@nwp but the mathematical definition of lower bound in order theory is an element which is the predecessor of all the elements in a given key set.

Upper and lower bounds

In mathematics, especially in order theory, an upper bound of a subset S of some partially ordered set (K, ≤) is an element of K which is greater than or equal to every element of S. The term lower bound is defined dually as an element of K which is less than or equal to every element of S. A set with an upper bound is said to be bounded from above by that bound, a set with a lower bound is said to be bounded from below by that bound. The terms bounded above (bounded below) are also used in the mathematical literature for sets that have upper (respectively lower) bounds. == Examples == For example...

nwp

@Yashas Ah, right, I do know that definition.

I never noticed that.

Poor naming I suppose.

Yashas

09:59

and upper_bound gives least upper bound

upper_bound doesn't match with the mathematical definition of least upper bound too! it fails for equal ranges

nwp

I'm gonna say "Don't mix math and programming". Despite what everyone says they are not closely related and cause more confusion than clarity.

milleniumbug

@Yashas [lower_bound, upper_bound) makes a STL range you can iterate over

Yashas

@milleniumbug doesn't that work only if the key forms an equal range?

milleniumbug

If there are no equal elements, the lower_bound is equal to upper_bound and therefore, range has 0 elements

Yashas

yea but the mathematical definition would have given a different answer

milleniumbug

10:05

hence why C++ doesn't use it

Yashas

wait even with equal ranges, std::upper_bound doesn't work the way it should

nvm

C++ definitions of lower bound & upper bound are not the same as the math definitions of the same

I'm going to leave it there and digest it

Arkadiusz Koćma

@nwp It does.

milleniumbug

@Yashas lower_bound returns begin, and upper_bound returns end, what else is to digest?

Yashas

@milleniumbug they don't follow the math definition

ratchet freak

@Yashas because this way is more useful to the programmer

milleniumbug

10:27

@Yashas oh, and one more thing: if std::lower_bound were to follow the math definition, what would it return for {2, 4, 6} when you pass it 0? There's no "one before beginning" sentinel value

Yashas

@milleniumbug interesting

that's a problem

what's `auto main()
-> int`?

4

A: rationale for std::lower_bound and std::upper_bound?

Consider the sequence 1 2 3 4 5 6 6 6 7 8 9 lower bound for 6 is the position of the first 6. upper bound for 6 is the position of the 7. these positions serve as common (begin, end) pair designating the run of 6-values. Example: #include <algorithm> #include <iostream> #include <vector>

nwp

@Yashas Trailing return type

milleniumbug

10:55

the same as int main() except ^

Yashas

what's the use of such a syntax over int main?

nwp

You sometimes need it for when the return type depends on the argument. Something like auto add(T a, U b) -> decltype(a+b). For main you don't need it, but some people do it anyways for consistency. It is not commonly done for main though and usually just causes useless style debates.

milleniumbug

triggering some people

trailing return type also works for nested types

Foo::T Foo::bar() vs auto Foo::bar() -> T

Yashas

12:06

declaring int arr[N] inside the function would cause it to be stored in the stack or the heap?

ratchet freak

compiler is free to choose as long as it gets reclaimed on return

nwp

In automatic storage which is commonly referred to as the stack.

Yashas

12:21

then allocating space for that would be as fast as int arr[100000], right?

I don't know how it works by putting a variable sized array into the stack

it can create room by just moving the SP down by required number of units

but then every other variable after that array will have its address depend on the array size

there will be a need for extra instructions to calculate the correct address of a local variable

nwp

If N is a template parameter it is the same. Otherwise it is not C++ but gnu-c++ which has different rules that do who knows what.

Yashas

N is not a template parameter

nwp

Then that is a compilation error in C++.

Yashas

I was using GCC and it was allowing me to do that

nwp

gcc defaults to gnu-c++11 I think. If you change it to -std=c++11 it should fail to compile.

Yashas

12:25

it compiles in C++14

it compiled in C++98 too

// Example program
#include <iostream>
#include <string>

using namespace std;
int main()
{
  int N;
  cin>>N;
  int arr[N];
  cout<<arr[3];
}

cpp.sh

nwp

> ISO C++ forbids variable length array 'arr'

styrofoam fly

16:25

hey guys, lets say we have `class x { x(int){}};` and a function `void f(x){}`. When calling `f(10)` we create an x object and pass it to `f`. But if we add a new function, `void f(int){}`, when calling `f(10)` this will fire up the new function without any warning, since it matches better. This is a situation I understand (or so I think).
Now, if we put one `f` function into class `CF` and the other function in class `CFF`, create a new class CC which inherits both from CF and CFF, and then call CC::f(10), we will get a compilation error. Why?

it says that it has two functions which match this signature and does not know which one to choose

ratchet freak

16:39

overload resolution has some pretty complex rules..

styrofoam fly

could you point me some materials which explain this situation?

Jerry Coffin

@styrofoamfly Essentially the only material that really covers things like this is (at least a draft of) the standard.

styrofoam fly

eh, thanks for that

Jerry Coffin

If you really need to do this, there is a fairly simple way to make it work: add using CF::f; using CFF::f; to your CC, and then the two become a simple overload set, and it can resolve which one to call.

coliru.stacked-crooked.com/a/fb8be4e76c3b9b9f

styrofoam fly

It's not about doing it, it's about understanding the mechanism, why it fails to resolve

it's purely educational

ratchet freak

16:54

en.cppreference.com/w/cpp/language/overload_resolution

styrofoam fly

Thank you very much!

ratchet freak

each implicit conversion is a penalty, so f(x) is worse than f(int) when called with f(10)

if there are 2 equally good candidates the compiler errors out with ambiguous

styrofoam fly

yes, but what I find weird, is that doesn't have a problem with f(x) and f(int) , but it has a probelm if they are in two different classes from which we inherit

Jerry Coffin

It starts by searching the derived class. Since that doesn't declare an `f`, it searches the base classes individually, then merges together the results from those searches. If those differ, then the lookup is considered ambiguous, and the code is ill-formed. The exact text is at [class.member.lookup]/6:

Otherwise (i.e., C does not contain a declaration of f or the resulting declaration set is empty), S(f, C) is initially empty. If C has base classes, calculate the lookup set for f in each direct base class subobject Bi , and merge each such lookup set S(f, Bi ) in turn into S(f, C).

So, it starts with an empty set (i.e., what if found in the derived class). It then merges the overloads from (say) CF into the empty set by copying the overload set from CF into the intermediate set. Then it tries to merge the overload set from CFF into the intermediate set. It differs from the current intermediate set, so the result is invalid. Therefore, the code is ill-formed.

Note that this isn't really "ambiguous" in the normal sense, like you'd get when you have a normal overload set containing two functions that are both equally good fits for the value(s) you passed.

styrofoam fly

17:14

I see, thank you

iksemyonov

17:25

@JerryCoffin Good afternoon (I guess)! Is that a quote of the Standard or do you know the area by heart? (I'm honestly impressed, thus the question.)

Jerry Coffin

@iksemyonov That's a cut-n-paste. I know the standard well enough to (generally) find the right parts, but I certainly haven't memorized the whole text.

@iksemyonov Oh, and for what little it's worth, it's actually still morning (0940) where I am (southern California).

iksemyonov

17:45

@JerryCoffin Still, you know the mechanism well enough to easily navigate the required reference (and be able to explain it). I'm currently learning C++ "for real" for the first time in years of "using" it and sometimes I get the feeling that it seems damn difficult to keep those algorithms and peculiarities in memory.

@JerryCoffin That's an 11-hour difference then. Just out of curiosity - do you have a chance to see the whales in your everyday life - or are you far enough away from the ocean?

nwp

Jerry's family isn't that fat and doesn't live in the ocean. Don't be mean.

Jerry Coffin