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use super::plumbing::*; use super::*; use std::fmt::{self, Debug}; /// The `split` function takes arbitrary data and a closure that knows how to /// split it, and turns this into a `ParallelIterator`. /// /// # Examples /// /// As a simple example, Rayon can recursively split ranges of indices /// /// ``` /// use rayon::iter; /// use rayon::prelude::*; /// use std::ops::Range; /// /// /// // We define a range of indices as follows /// type Range1D = Range<usize>; /// /// // Splitting it in two can be done like this /// fn split_range1(r: Range1D) -> (Range1D, Option<Range1D>) { /// // We are mathematically unable to split the range if there is only /// // one point inside of it, but we could stop splitting before that. /// if r.end - r.start <= 1 { return (r, None); } /// /// // Here, our range is considered large enough to be splittable /// let midpoint = r.start + (r.end - r.start) / 2; /// (r.start..midpoint, Some(midpoint..r.end)) /// } /// /// // By using iter::split, Rayon will split the range until it has enough work /// // to feed the CPU cores, then give us the resulting sub-ranges /// iter::split(0..4096, split_range1).for_each(|sub_range| { /// // As our initial range had a power-of-two size, the final sub-ranges /// // should have power-of-two sizes too /// assert!((sub_range.end - sub_range.start).is_power_of_two()); /// }); /// ``` /// /// This recursive splitting can be extended to two or three dimensions, /// to reproduce a classic "block-wise" parallelization scheme of graphics and /// numerical simulations: /// /// ``` /// # use rayon::iter; /// # use rayon::prelude::*; /// # use std::ops::Range; /// # type Range1D = Range<usize>; /// # fn split_range1(r: Range1D) -> (Range1D, Option<Range1D>) { /// # if r.end - r.start <= 1 { return (r, None); } /// # let midpoint = r.start + (r.end - r.start) / 2; /// # (r.start..midpoint, Some(midpoint..r.end)) /// # } /// # /// // A two-dimensional range of indices can be built out of two 1D ones /// struct Range2D { /// // Range of horizontal indices /// pub rx: Range1D, /// /// // Range of vertical indices /// pub ry: Range1D, /// } /// /// // We want to recursively split them by the largest dimension until we have /// // enough sub-ranges to feed our mighty multi-core CPU. This function /// // carries out one such split. /// fn split_range2(r2: Range2D) -> (Range2D, Option<Range2D>) { /// // Decide on which axis (horizontal/vertical) the range should be split /// let width = r2.rx.end - r2.rx.start; /// let height = r2.ry.end - r2.ry.start; /// if width >= height { /// // This is a wide range, split it on the horizontal axis /// let (split_rx, ry) = (split_range1(r2.rx), r2.ry); /// let out1 = Range2D { /// rx: split_rx.0, /// ry: ry.clone(), /// }; /// let out2 = split_rx.1.map(|rx| Range2D { rx, ry }); /// (out1, out2) /// } else { /// // This is a tall range, split it on the vertical axis /// let (rx, split_ry) = (r2.rx, split_range1(r2.ry)); /// let out1 = Range2D { /// rx: rx.clone(), /// ry: split_ry.0, /// }; /// let out2 = split_ry.1.map(|ry| Range2D { rx, ry, }); /// (out1, out2) /// } /// } /// /// // Again, rayon can handle the recursive splitting for us /// let range = Range2D { rx: 0..800, ry: 0..600 }; /// iter::split(range, split_range2).for_each(|sub_range| { /// // If the sub-ranges were indeed split by the largest dimension, then /// // if no dimension was twice larger than the other initially, this /// // property will remain true in the final sub-ranges. /// let width = sub_range.rx.end - sub_range.rx.start; /// let height = sub_range.ry.end - sub_range.ry.start; /// assert!((width / 2 <= height) && (height / 2 <= width)); /// }); /// ``` /// pub fn split<D, S>(data: D, splitter: S) -> Split<D, S> where D: Send, S: Fn(D) -> (D, Option<D>) + Sync, { Split { data, splitter } } /// `Split` is a parallel iterator using arbitrary data and a splitting function. /// This struct is created by the [`split()`] function. /// /// [`split()`]: fn.split.html #[derive(Clone)] pub struct Split<D, S> { data: D, splitter: S, } impl<D: Debug, S> Debug for Split<D, S> { fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result { f.debug_struct("Split").field("data", &self.data).finish() } } impl<D, S> ParallelIterator for Split<D, S> where D: Send, S: Fn(D) -> (D, Option<D>) + Sync + Send, { type Item = D; fn drive_unindexed<C>(self, consumer: C) -> C::Result where C: UnindexedConsumer<Self::Item>, { let producer = SplitProducer { data: self.data, splitter: &self.splitter, }; bridge_unindexed(producer, consumer) } } struct SplitProducer<'a, D, S> { data: D, splitter: &'a S, } impl<'a, D, S> UnindexedProducer for SplitProducer<'a, D, S> where D: Send, S: Fn(D) -> (D, Option<D>) + Sync, { type Item = D; fn split(mut self) -> (Self, Option<Self>) { let splitter = self.splitter; let (left, right) = splitter(self.data); self.data = left; (self, right.map(|data| SplitProducer { data, splitter })) } fn fold_with<F>(self, folder: F) -> F where F: Folder<Self::Item>, { folder.consume(self.data) } }