par_iter/
range.rs

1//! Parallel iterator types for [ranges][std::range],
2//! the type for values created by `a..b` expressions
3//!
4//! You will rarely need to interact with this module directly unless you have
5//! need to name one of the iterator types.
6//!
7//! ```
8//! use par_iter::prelude::*;
9//!
10//! let r = (0..100u64).into_par_iter()
11//!                    .sum();
12//!
13//! // compare result with sequential calculation
14//! assert_eq!((0..100).sum::<u64>(), r);
15//! ```
16//!
17//! [std::range]: https://doc.rust-lang.org/core/ops/struct.Range.html
18
19use std::ops::Range;
20
21use crate::iter::{plumbing::*, *};
22
23/// Parallel iterator over a range, implemented for all integer types and
24/// `char`.
25///
26/// **Note:** The `zip` operation requires `IndexedParallelIterator`
27/// which is not implemented for `u64`, `i64`, `u128`, or `i128`.
28///
29/// ```
30/// use par_iter::prelude::*;
31///
32/// let p = (0..25usize).into_par_iter()
33///                   .zip(0..25usize)
34///                   .filter(|&(x, y)| x % 5 == 0 || y % 5 == 0)
35///                   .map(|(x, y)| x * y)
36///                   .sum::<usize>();
37///
38/// let s = (0..25usize).zip(0..25)
39///                   .filter(|&(x, y)| x % 5 == 0 || y % 5 == 0)
40///                   .map(|(x, y)| x * y)
41///                   .sum();
42///
43/// assert_eq!(p, s);
44/// ```
45#[derive(Debug, Clone)]
46pub struct Iter<T> {
47    range: Range<T>,
48}
49
50/// Implemented for ranges of all primitive integer types and `char`.
51impl<T> IntoParallelIterator for Range<T>
52where
53    Iter<T>: ParallelIterator,
54{
55    type Item = <Iter<T> as ParallelIterator>::Item;
56    type Iter = Iter<T>;
57
58    fn into_par_iter(self) -> Self::Iter {
59        Iter { range: self }
60    }
61}
62
63struct IterProducer<T> {
64    range: Range<T>,
65}
66
67impl<T> IntoIterator for IterProducer<T>
68where
69    Range<T>: Iterator,
70{
71    type IntoIter = Range<T>;
72    type Item = <Range<T> as Iterator>::Item;
73
74    fn into_iter(self) -> Self::IntoIter {
75        self.range
76    }
77}
78
79/// These traits help drive integer type inference. Without them, an unknown
80/// `{integer}` type only has constraints on `Iter<{integer}>`, which will
81/// probably give up and use `i32`. By adding these traits on the item type, the
82/// compiler can see a more direct constraint to infer like `{integer}:
83/// RangeInteger`, which works better. See `test_issue_833` for an example.
84///
85/// They have to be `pub` since they're seen in the public `impl
86/// ParallelIterator` constraints, but we put them in a private modules so
87/// they're not actually reachable in our public API.
88mod private {
89    use super::*;
90
91    /// Implementation details of `ParallelIterator for Iter<Self>`
92    pub trait RangeInteger: Sized + Send {
93        private_decl! {}
94
95        fn drive_unindexed<C>(iter: Iter<Self>, consumer: C) -> C::Result
96        where
97            C: UnindexedConsumer<Self>;
98
99        fn opt_len(iter: &Iter<Self>) -> Option<usize>;
100    }
101
102    /// Implementation details of `IndexedParallelIterator for Iter<Self>`
103    pub trait IndexedRangeInteger: RangeInteger {
104        private_decl! {}
105
106        fn drive<C>(iter: Iter<Self>, consumer: C) -> C::Result
107        where
108            C: Consumer<Self>;
109
110        fn len(iter: &Iter<Self>) -> usize;
111
112        fn with_producer<CB>(iter: Iter<Self>, callback: CB) -> CB::Output
113        where
114            CB: ProducerCallback<Self>;
115    }
116}
117use private::{IndexedRangeInteger, RangeInteger};
118
119impl<T: RangeInteger> ParallelIterator for Iter<T> {
120    type Item = T;
121
122    fn drive_unindexed<C>(self, consumer: C) -> C::Result
123    where
124        C: UnindexedConsumer<T>,
125    {
126        T::drive_unindexed(self, consumer)
127    }
128
129    #[inline]
130    fn opt_len(&self) -> Option<usize> {
131        T::opt_len(self)
132    }
133}
134
135impl<T: IndexedRangeInteger> IndexedParallelIterator for Iter<T> {
136    fn drive<C>(self, consumer: C) -> C::Result
137    where
138        C: Consumer<T>,
139    {
140        T::drive(self, consumer)
141    }
142
143    #[inline]
144    fn len(&self) -> usize {
145        T::len(self)
146    }
147
148    fn with_producer<CB>(self, callback: CB) -> CB::Output
149    where
150        CB: ProducerCallback<T>,
151    {
152        T::with_producer(self, callback)
153    }
154}
155
156macro_rules! indexed_range_impl {
157    ( $t:ty ) => {
158        impl RangeInteger for $t {
159            private_impl! {}
160
161            fn drive_unindexed<C>(iter: Iter<$t>, consumer: C) -> C::Result
162            where
163                C: UnindexedConsumer<$t>,
164            {
165                bridge(iter, consumer)
166            }
167
168            fn opt_len(iter: &Iter<$t>) -> Option<usize> {
169                Some(iter.range.len())
170            }
171        }
172
173        impl IndexedRangeInteger for $t {
174            private_impl! {}
175
176            fn drive<C>(iter: Iter<$t>, consumer: C) -> C::Result
177            where
178                C: Consumer<$t>,
179            {
180                bridge(iter, consumer)
181            }
182
183            fn len(iter: &Iter<$t>) -> usize {
184                iter.range.len()
185            }
186
187            fn with_producer<CB>(iter: Iter<$t>, callback: CB) -> CB::Output
188            where
189                CB: ProducerCallback<$t>,
190            {
191                callback.callback(IterProducer { range: iter.range })
192            }
193        }
194
195        impl Producer for IterProducer<$t> {
196            type IntoIter = Range<$t>;
197            type Item = <Range<$t> as Iterator>::Item;
198
199            fn into_iter(self) -> Self::IntoIter {
200                self.range
201            }
202
203            fn split_at(self, index: usize) -> (Self, Self) {
204                assert!(index <= self.range.len());
205                // For signed $t, the length and requested index could be greater than $t::MAX,
206                // and then `index as $t` could wrap to negative, so wrapping_add is
207                // necessary.
208                let mid = self.range.start.wrapping_add(index as $t);
209                let left = self.range.start..mid;
210                let right = mid..self.range.end;
211                (IterProducer { range: left }, IterProducer { range: right })
212            }
213        }
214    };
215}
216
217trait UnindexedRangeLen<L> {
218    fn unindexed_len(&self) -> L;
219}
220
221macro_rules! unindexed_range_impl {
222    ( $t:ty, $len_t:ty ) => {
223        impl UnindexedRangeLen<$len_t> for Range<$t> {
224            fn unindexed_len(&self) -> $len_t {
225                let &Range { start, end } = self;
226                if end > start {
227                    end.wrapping_sub(start) as $len_t
228                } else {
229                    0
230                }
231            }
232        }
233
234        impl RangeInteger for $t {
235            private_impl! {}
236
237            fn drive_unindexed<C>(iter: Iter<$t>, consumer: C) -> C::Result
238            where
239                C: UnindexedConsumer<$t>,
240            {
241                #[inline]
242                fn offset(start: $t) -> impl Fn(usize) -> $t {
243                    move |i| start.wrapping_add(i as $t)
244                }
245
246                if let Some(len) = iter.opt_len() {
247                    // Drive this in indexed mode for better `collect`.
248                    (0..len)
249                        .into_par_iter()
250                        .map(offset(iter.range.start))
251                        .drive(consumer)
252                } else {
253                    bridge_unindexed(IterProducer { range: iter.range }, consumer)
254                }
255            }
256
257            fn opt_len(iter: &Iter<$t>) -> Option<usize> {
258                usize::try_from(iter.range.unindexed_len()).ok()
259            }
260        }
261
262        impl UnindexedProducer for IterProducer<$t> {
263            type Item = $t;
264
265            fn split(mut self) -> (Self, Option<Self>) {
266                let index = self.range.unindexed_len() / 2;
267                if index > 0 {
268                    let mid = self.range.start.wrapping_add(index as $t);
269                    let right = mid..self.range.end;
270                    self.range.end = mid;
271                    (self, Some(IterProducer { range: right }))
272                } else {
273                    (self, None)
274                }
275            }
276
277            fn fold_with<F>(self, folder: F) -> F
278            where
279                F: Folder<Self::Item>,
280            {
281                folder.consume_iter(self)
282            }
283        }
284    };
285}
286
287// all Range<T> with ExactSizeIterator
288indexed_range_impl! {u8}
289indexed_range_impl! {u16}
290indexed_range_impl! {u32}
291indexed_range_impl! {usize}
292indexed_range_impl! {i8}
293indexed_range_impl! {i16}
294indexed_range_impl! {i32}
295indexed_range_impl! {isize}
296
297// other Range<T> with just Iterator
298unindexed_range_impl! {u64, u64}
299unindexed_range_impl! {i64, u64}
300unindexed_range_impl! {u128, u128}
301unindexed_range_impl! {i128, u128}
302
303// char is special because of the surrogate range hole
304macro_rules! convert_char {
305    ( $self:ident . $method:ident ( $( $arg:expr ),* ) ) => {{
306        let start = $self.range.start as u32;
307        let end = $self.range.end as u32;
308        if start < 0xD800 && 0xE000 < end {
309            // chain the before and after surrogate range fragments
310            (start..0xD800)
311                .into_par_iter()
312                .chain(0xE000..end)
313                .map(|codepoint| unsafe { char::from_u32_unchecked(codepoint) })
314                .$method($( $arg ),*)
315        } else {
316            // no surrogate range to worry about
317            (start..end)
318                .into_par_iter()
319                .map(|codepoint| unsafe { char::from_u32_unchecked(codepoint) })
320                .$method($( $arg ),*)
321        }
322    }};
323}
324
325impl ParallelIterator for Iter<char> {
326    type Item = char;
327
328    fn drive_unindexed<C>(self, consumer: C) -> C::Result
329    where
330        C: UnindexedConsumer<Self::Item>,
331    {
332        convert_char!(self.drive(consumer))
333    }
334
335    fn opt_len(&self) -> Option<usize> {
336        Some(self.len())
337    }
338}
339
340impl IndexedParallelIterator for Iter<char> {
341    // Split at the surrogate range first if we're allowed to
342    fn drive<C>(self, consumer: C) -> C::Result
343    where
344        C: Consumer<Self::Item>,
345    {
346        convert_char!(self.drive(consumer))
347    }
348
349    fn len(&self) -> usize {
350        // Taken from <char as Step>::steps_between
351        let start = self.range.start as u32;
352        let end = self.range.end as u32;
353        if start < end {
354            let mut count = end - start;
355            if start < 0xd800 && 0xe000 <= end {
356                count -= 0x800
357            }
358            count as usize
359        } else {
360            0
361        }
362    }
363
364    fn with_producer<CB>(self, callback: CB) -> CB::Output
365    where
366        CB: ProducerCallback<Self::Item>,
367    {
368        convert_char!(self.with_producer(callback))
369    }
370}
371
372#[test]
373fn check_range_split_at_overflow() {
374    // Note, this split index overflows i8!
375    let producer = IterProducer { range: -100i8..100 };
376    let (left, right) = producer.split_at(150);
377    let r1: i32 = left.range.map(i32::from).sum();
378    let r2: i32 = right.range.map(i32::from).sum();
379    assert_eq!(r1 + r2, -100);
380}
381
382#[test]
383fn test_i128_len_doesnt_overflow() {
384    // Using parse because some versions of rust don't allow long literals
385    let octillion: i128 = "1000000000000000000000000000".parse().unwrap();
386    let producer = IterProducer {
387        range: 0..octillion,
388    };
389
390    assert_eq!(octillion as u128, producer.range.unindexed_len());
391    assert_eq!(octillion as u128, (0..octillion).unindexed_len());
392    assert_eq!(
393        2 * octillion as u128,
394        (-octillion..octillion).unindexed_len()
395    );
396
397    assert_eq!(u128::MAX, (i128::MIN..i128::MAX).unindexed_len());
398}
399
400#[test]
401fn test_u64_opt_len() {
402    assert_eq!(Some(100), (0..100u64).into_par_iter().opt_len());
403    assert_eq!(
404        Some(usize::MAX),
405        (0..usize::MAX as u64).into_par_iter().opt_len()
406    );
407    if (usize::MAX as u64) < u64::MAX {
408        assert_eq!(
409            None,
410            (0..(usize::MAX as u64).wrapping_add(1))
411                .into_par_iter()
412                .opt_len()
413        );
414        assert_eq!(None, (0..u64::MAX).into_par_iter().opt_len());
415    }
416}
417
418#[test]
419fn test_u128_opt_len() {
420    assert_eq!(Some(100), (0..100u128).into_par_iter().opt_len());
421    assert_eq!(
422        Some(usize::MAX),
423        (0..usize::MAX as u128).into_par_iter().opt_len()
424    );
425    assert_eq!(None, (0..1 + usize::MAX as u128).into_par_iter().opt_len());
426    assert_eq!(None, (0..u128::MAX).into_par_iter().opt_len());
427}
428
429// // `usize as i64` can overflow, so make sure to wrap it appropriately
430// // when using the `opt_len` "indexed" mode.
431// #[test]
432// #[cfg(target_pointer_width = "64")]
433// fn test_usize_i64_overflow() {
434//     use crate::ThreadPoolBuilder;
435
436//     let iter = (-2..i64::MAX).into_par_iter();
437//     assert_eq!(iter.opt_len(), Some(i64::MAX as usize + 2));
438
439//     // always run with multiple threads to split into, or this will take
440// forever...     let pool =
441// ThreadPoolBuilder::new().num_threads(8).build().unwrap();     pool.install(||
442// assert_eq!(iter.find_last(|_| true), Some(i64::MAX - 1))); }
443
444#[test]
445fn test_issue_833() {
446    fn is_even(n: i64) -> bool {
447        n % 2 == 0
448    }
449
450    // The integer type should be inferred from `is_even`
451    let v: Vec<_> = (1..100).into_par_iter().filter(|&x| is_even(x)).collect();
452    assert!(v.into_iter().eq((2..100).step_by(2)));
453
454    // Try examples with indexed iterators too
455    let pos = (0..100).into_par_iter().position_any(|x| x == 50i16);
456    assert_eq!(pos, Some(50usize));
457
458    assert!((0..100)
459        .into_par_iter()
460        .zip(0..100)
461        .all(|(a, b)| i16::eq(&a, &b)));
462}