Abstract: Hypothesis selection, also known as density estimation, is a fundamental problem in statistics and learning theory. Suppose we are given a sample set from an unknown distribution $P$ and a finite class of candidate distributions (called hypotheses) $\mathcal{H} \coloneqq \{H_1, H_2, \ldots, H_n\}$. The aim is to design an algorithm that selects a distribution $\hat H$ in $\mathcal{H}$ that best fits the data. The algorithm's accuracy is measured based on the distance between $\hat{H}$ and $P$ compared to the distance of the closest distribution in $\mathcal{H}$ to $P$ (denoted by $OPT$). Concretely, we aim for $\|\hat{H} - P\|_{TV}$ to be at most $ \alpha \cdot OPT + \epsilon$ for some small $\epsilon$ and $\alpha$. While it is possible to decrease the value of $\epsilon$ as the number of samples increases, $\alpha$ is an inherent characteristic of the algorithm. In fact, one cannot hope to achieve $\alpha < 3$ even when there are only two candidate hypotheses, unless the number of samples is proportional to the domain size of $P$ [Bousquet, Kane, Moran '19]. Finding the best $\alpha$ has been one of the main focuses of studies of the problem since early work of [Devroye, Lugosi '01]. Prior to our work, no algorithm was known that achieves $\alpha = 3$ in near-linear time. We provide the first algorithm that operates in almost linear time ($\tilde{O}(n/\epsilon^3)$ time) and achieves $\alpha = 3$. This result improves upon a long list of results in hypothesis selection. Previously known algorithms either had worse time complexity, a larger factor $\alpha$, or extra assumptions about the problem setting.In addition to this algorithm, we provide another (almost) linear-time algorithm with better dependency on the additive accuracy parameter $\epsilon$, albeit with a slightly worse accuracy parameter, $\alpha = 4$.