This c++ code cannot compile:
#include <iostream>
int main()
{
constexpr int kInt = 123;
struct LocalClass {
void func(){
const int b = std::max(kInt, 12);
// ^~~~
// error: use of local variable with automatic storage fr...
Simple case. Take $X_{\bullet}$ a cosimplicial space. Is it true that the chain complex of its homotopy totalization is quasi-isomorphic to the homotopy totalization of its chain complex? Because of the computations listed in "homotopy totalization" at nlab, this boils down to a quasi-isomorphism...
Here i am attaching my problem. I want my repository to be hairbodyskin-production. But it is not changing
I tried this `
git config remote.origin.url https://x-token-auth:ATCTT3xFfGN02teIasCShaVu_OFcBiXmEGz5eXTLrjSOrRtyaZt-OU3r0II2rUS58_5auPxITl-L7aEVEge-aCHSUOZI4Cl0fgEtHSAzgX9Gg75Zrn2_pC1s7966...
Let $f_1(x)\in \mathbb{Z}[x]$ be a fixed irreducible degree 4 polynomial such that its splitting field $F_1$ is an $S_4$-Galois extension over $\mathbb{Q}$ and the discriminant of $F_1$ is of the form $-k^2$ for some integer $k$. It is possible to show that $F_1$ contains $\mathbb{Q}(\sqrt{-1})$....
Consider the polynomial
$$
27x^4 - 256 y^3 = k^2,
$$
where $k$ is an integer. As $k$ varies over all positive integers, is it possible to show that there are infinitely many distinct integral solutions $(X,Y,k)$?
There exists at least one solution: $x=12, y=-9, k=864$.
NOTE: If $(X,Y,k)$ is a sol...
Prove that for all $k \in \mathbb{N}$ then there exists $n$ such that
$$
7^k \mid 2^n + 5^n + 3
$$
My idea is to construct $n$ such that the equation above is valid. However, the construction that I got is $$n = 3 \cdot 7^{k - 1} + 1$$
which is very weird and almost impossible to find without ...
Dirichlet’s Theorem on Arithmetic Progressions says that if $a, m$ are natural numbers such that $gcd (a,m) = 1$, then there are infinitely many prime numbers in the arithmetic progression $a + km, k \in \mathbb{N}$.
I would like to know what is the idea of the proof, and the sketch of the proof,...