Let $Dom$ be a uniform space, and $\hspace{.04 in}f$ be a continuous function from $Dom$ to itself satisfying:

 1. For all non-empty open subsets $U$ and $V$ of $Dom$, there exists a natural
<br>number $n$ and a member $x$ of $U$ such that $f^n(x)$ is a member of $V$.

 2. The periodic points of $f$ are dense in $Dom$.

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Does it follow that $f$ satisfies (3)?

$\;\;$3.$\:\:$There exists an entourage $E$ of $Dom$ such that for all members $x$ of
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$\quad \;\;$ $Dom$ and all neighborhoods $U$ of $x$, there exists a member $y$ of $U$ and
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$\quad \;\;$ a natural number $n$ such that $\:\langle \hspace{.05 in}f^n(x)\hspace{.02 in},\hspace{.03 in}f^n(\hspace{.03 in}y)\rangle\:$ is not a member of $E$.

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According to [this paper](http://pb.math.univ.gda.pl/chaos/pdf/on_intervals.pdf), the implication holds in metric spaces.