Can someone give me an example of a compact topological space that is not first-countable such that there is a sequence $(x_n)_{n \in \mathbb{N}}$, with the property that for every subsequence $(x_{n_p})_{p \in \mathbb{N}}$ of $(x_n)_{n \in \mathbb{N}}$, the subsequence wouldn't converge?
In our topology course we learned that in a compact space, every net has a convergent subnet. Now a sequence is of course also a net, so it has to have a convergent subnet. But generally a subnet of a sequence need not be a sequence; but could it still be possible in compact space to choose as subnet of a sequence another sequence? It is of course important that this space should not be first countable, because if it were we wouldn't have to deal with the cumbersome nets. Compactness and first-countable would imply that every sequence contains a convergent subsequence, so my question would be meaningless.