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//- // Copyright 2017, 2018 Jason Lingle // // Licensed under the Apache License, Version 2.0 <LICENSE-APACHE or // http://www.apache.org/licenses/LICENSE-2.0> or the MIT license // <LICENSE-MIT or http://opensource.org/licenses/MIT>, at your // option. This file may not be copied, modified, or distributed // except according to those terms. //! Strategies for generating values by taking samples of collections. //! //! Note that the strategies in this module are not native combinators; that //! is, the input collection is not itself a strategy, but is rather fixed when //! the strategy is created. use crate::std_facade::{Arc, Cow, Vec}; use core::fmt; use core::mem; use core::ops::Range; use core::u64; use rand::Rng; use crate::bits::{self, BitSetValueTree, SampledBitSetStrategy, VarBitSet}; use crate::num; use crate::strategy::*; use crate::test_runner::*; /// Re-exported to make usage more ergonomic. pub use crate::collection::{size_range, SizeRange}; /// Sample subsequences whose size are within `size` from the given collection /// `values`. /// /// A subsequence is a subset of the elements in a collection in the order they /// occur in that collection. The elements are not chosen to be contiguous. /// /// This is roughly analogous to `rand::sample`, except that it guarantees that /// the order is preserved. /// /// `values` may be a static slice or a `Vec`. /// /// ## Panics /// /// Panics if the maximum size implied by `size` is larger than the size of /// `values`. /// /// Panics if `size` is a zero-length range. pub fn subsequence<T: Clone + 'static>( values: impl Into<Cow<'static, [T]>>, size: impl Into<SizeRange>, ) -> Subsequence<T> { let values = values.into(); let len = values.len(); let size = size.into(); size.assert_nonempty(); assert!( size.end_incl() <= len, "Maximum size of subsequence {} exceeds length of input {}", size.end_incl(), len ); Subsequence { values: Arc::new(values), bit_strategy: bits::varsize::sampled(size, 0..len), } } /// Strategy to generate `Vec`s by sampling a subsequence from another /// collection. /// /// This is created by the `subsequence` function in the same module. #[derive(Debug, Clone)] #[must_use = "strategies do nothing unless used"] pub struct Subsequence<T: Clone + 'static> { values: Arc<Cow<'static, [T]>>, bit_strategy: SampledBitSetStrategy<VarBitSet>, } impl<T: fmt::Debug + Clone + 'static> Strategy for Subsequence<T> { type Tree = SubsequenceValueTree<T>; type Value = Vec<T>; fn new_tree(&self, runner: &mut TestRunner) -> NewTree<Self> { Ok(SubsequenceValueTree { values: Arc::clone(&self.values), inner: self.bit_strategy.new_tree(runner)?, }) } } /// `ValueTree` type for `Subsequence`. #[derive(Debug, Clone)] pub struct SubsequenceValueTree<T: Clone + 'static> { values: Arc<Cow<'static, [T]>>, inner: BitSetValueTree<VarBitSet>, } impl<T: fmt::Debug + Clone + 'static> ValueTree for SubsequenceValueTree<T> { type Value = Vec<T>; fn current(&self) -> Self::Value { let inner = self.inner.current(); let ret = inner.iter().map(|ix| self.values[ix].clone()).collect(); ret } fn simplify(&mut self) -> bool { self.inner.simplify() } fn complicate(&mut self) -> bool { self.inner.complicate() } } #[derive(Debug, Clone)] struct SelectMapFn<T: Clone + 'static>(Arc<Cow<'static, [T]>>); impl<T: fmt::Debug + Clone + 'static> statics::MapFn<usize> for SelectMapFn<T> { type Output = T; fn apply(&self, ix: usize) -> T { self.0[ix].clone() } } opaque_strategy_wrapper! { /// Strategy to produce one value from a fixed collection of options. /// /// Created by the `select()` in the same module. #[derive(Clone, Debug)] pub struct Select[<T>][where T : Clone + fmt::Debug + 'static]( statics::Map<Range<usize>, SelectMapFn<T>>) -> SelectValueTree<T>; /// `ValueTree` corresponding to `Select`. #[derive(Clone, Debug)] pub struct SelectValueTree[<T>][where T : Clone + fmt::Debug + 'static]( statics::Map<num::usize::BinarySearch, SelectMapFn<T>>) -> T; } /// Create a strategy which uniformly selects one value from `values`. /// /// `values` should be a `&'static [T]` or a `Vec<T>`, or potentially another /// type that can be coerced to `Cow<'static,[T]>`. /// /// This is largely equivalent to making a `Union` of a bunch of `Just` /// strategies, but is substantially more efficient and shrinks by binary /// search. /// /// If `values` is also to be generated by a strategy, see /// [`Index`](struct.Index.html) for a more efficient way to select values than /// using `prop_flat_map()`. pub fn select<T: Clone + fmt::Debug + 'static>( values: impl Into<Cow<'static, [T]>>, ) -> Select<T> { let cow = values.into(); Select(statics::Map::new(0..cow.len(), SelectMapFn(Arc::new(cow)))) } /// A stand-in for an index into a slice or similar collection or conceptually /// similar things. /// /// At the lowest level, `Index` is a mechanism for generating `usize` values /// in the range [0..N), for some N whose value is not known until it is /// needed. (Contrast with using `0..N` itself as a strategy, where you need to /// know N when you define the strategy.) /// /// For any upper bound, the actual index produced by an `Index` is the same no /// matter how many times it is used. Different upper bounds will produce /// different but not independent values. /// /// Shrinking will cause the index to binary search through the underlying /// collection(s) it is used to sample. /// /// Note that `Index` _cannot_ currently be used as a slice index (e.g., /// `slice[index]`) due to the trait coherence rules. /// /// ## Example /// /// If the collection itself being indexed is itself generated by a strategy, /// you can make separately define that strategy and a strategy generating one /// or more `Index`es and then join the two after input generation, avoiding a /// call to `prop_flat_map()`. /// /// ``` /// use proptest::prelude::*; /// /// proptest! { /// # /* /// #[test] /// # */ /// fn my_test( /// names in prop::collection::vec("[a-z]+", 10..20), /// indices in prop::collection::vec(any::<prop::sample::Index>(), 5..10) /// ) { /// // We now have Vec<String> of ten to twenty names, and a Vec<Index> /// // of five to ten indices and can combine them however we like. /// for index in &indices { /// println!("Accessing item by index: {}", names[index.index(names.len())]); /// println!("Accessing item by convenience method: {}", index.get(&names)); /// } /// // Test stuff... /// } /// } /// # /// # fn main() { my_test(); } /// ``` #[derive(Clone, Copy, Debug)] pub struct Index(usize); impl Index { /// Return the real index that would be used to index a collection of size `size`. /// /// ## Panics /// /// Panics if `size == 0`. pub fn index(&self, size: usize) -> usize { assert!(size > 0, "Attempt to use `Index` with 0-size collection"); // No platforms currently have `usize` wider than 64 bits, so `u128` is // sufficient to hold the result of a full multiply, letting us do a // simple fixed-point multiply. ((size as u128) * (self.0 as u128) >> (mem::size_of::<usize>() * 8)) as usize } /// Return a reference to the element in `slice` that this `Index` refers to. /// /// A shortcut for `&slice[index.index(slice.len())]`. pub fn get<'a, T>(&self, slice: &'a [T]) -> &'a T { &slice[self.index(slice.len())] } /// Return a mutable reference to the element in `slice` that this `Index` /// refers to. /// /// A shortcut for `&mut slice[index.index(slice.len())]`. pub fn get_mut<'a, T>(&self, slice: &'a mut [T]) -> &'a mut T { let ix = self.index(slice.len()); &mut slice[ix] } } mapfn! { [] fn UsizeToIndex[](raw: usize) -> Index { Index(raw) } } opaque_strategy_wrapper! { /// Strategy to create `Index`es. /// /// Created via `any::<Index>()`. #[derive(Clone, Debug)] pub struct IndexStrategy[][]( statics::Map<num::usize::Any, UsizeToIndex>) -> IndexValueTree; /// `ValueTree` corresponding to `IndexStrategy`. #[derive(Clone, Debug)] pub struct IndexValueTree[][]( statics::Map<num::usize::BinarySearch,UsizeToIndex>) -> Index; } impl IndexStrategy { pub(crate) fn new() -> Self { IndexStrategy(statics::Map::new(num::usize::ANY, UsizeToIndex)) } } /// A value for picking random values out of iterators. /// /// This is, in a sense, a more flexible variant of /// [`Index`](struct.Index.html) in that it can operate on arbitrary /// `IntoIterator` values. /// /// Initially, the selection is roughly uniform, with a very slight bias /// towards items earlier in the iterator. /// /// Shrinking causes the selection to move toward items earlier in the /// iterator, ultimately settling on the very first, but this currently happens /// in a very haphazard way that may fail to find the earliest failing input. /// /// ## Example /// /// Generate a non-indexable collection and a value to pick out of it. /// /// ``` /// use proptest::prelude::*; /// /// proptest! { /// # /* /// #[test] /// # */ /// fn my_test( /// names in prop::collection::hash_set("[a-z]+", 10..20), /// selector in any::<prop::sample::Selector>() /// ) { /// println!("Selected name: {}", selector.select(&names)); /// // Test stuff... /// } /// } /// # /// # fn main() { my_test(); } /// ``` #[derive(Clone, Debug)] pub struct Selector { rng: TestRng, bias_increment: u64, } /// Strategy to create `Selector`s. /// /// Created via `any::<Selector>()`. #[derive(Debug)] pub struct SelectorStrategy { _nonexhaustive: (), } /// `ValueTree` corresponding to `SelectorStrategy`. #[derive(Debug)] pub struct SelectorValueTree { rng: TestRng, reverse_bias_increment: num::u64::BinarySearch, } impl SelectorStrategy { pub(crate) fn new() -> Self { SelectorStrategy { _nonexhaustive: () } } } impl Strategy for SelectorStrategy { type Tree = SelectorValueTree; type Value = Selector; fn new_tree(&self, runner: &mut TestRunner) -> NewTree<Self> { Ok(SelectorValueTree { rng: runner.new_rng(), reverse_bias_increment: num::u64::BinarySearch::new(u64::MAX), }) } } impl ValueTree for SelectorValueTree { type Value = Selector; fn current(&self) -> Selector { Selector { rng: self.rng.clone(), bias_increment: u64::MAX - self.reverse_bias_increment.current(), } } fn simplify(&mut self) -> bool { self.reverse_bias_increment.simplify() } fn complicate(&mut self) -> bool { self.reverse_bias_increment.complicate() } } impl Selector { /// Pick a random element from iterable `it`. /// /// The selection is unaffected by the elements themselves, and is /// dependent only on the actual length of `it`. /// /// `it` is always iterated completely. /// /// ## Panics /// /// Panics if `it` has no elements. pub fn select<T: IntoIterator>(&self, it: T) -> T::Item { self.try_select(it).expect("select from empty iterator") } /// Pick a random element from iterable `it`. /// /// Returns `None` if `it` is empty. /// /// The selection is unaffected by the elements themselves, and is /// dependent only on the actual length of `it`. /// /// `it` is always iterated completely. pub fn try_select<T: IntoIterator>(&self, it: T) -> Option<T::Item> { let mut bias = 0u64; let mut min_score = 0; let mut best = None; let mut rng = self.rng.clone(); for item in it { let score = bias.saturating_add(rng.gen()); if best.is_none() || score < min_score { best = Some(item); min_score = score; } bias = bias.saturating_add(self.bias_increment); } best } } #[cfg(test)] mod test { use crate::std_facade::BTreeSet; use super::*; use crate::arbitrary::any; #[test] fn sample_slice() { static VALUES: &[usize] = &[0, 1, 2, 3, 4, 5, 6, 7]; let mut size_counts = [0; 8]; let mut value_counts = [0; 8]; let mut runner = TestRunner::deterministic(); let input = subsequence(VALUES, 3..7); for _ in 0..2048 { let value = input.new_tree(&mut runner).unwrap().current(); // Generated the correct number of items assert!(value.len() >= 3 && value.len() < 7); // Chose distinct items assert_eq!( value.len(), value.iter().cloned().collect::<BTreeSet<_>>().len() ); // Values are in correct order let mut sorted = value.clone(); sorted.sort(); assert_eq!(sorted, value); size_counts[value.len()] += 1; for value in value { value_counts[value] += 1; } } for i in 3..7 { assert!( size_counts[i] >= 256 && size_counts[i] < 1024, "size {} was chosen {} times", i, size_counts[i] ); } for (ix, &v) in value_counts.iter().enumerate() { assert!( v >= 1024 && v < 1500, "Value {} was chosen {} times", ix, v ); } } #[test] fn sample_vec() { // Just test that the types work out let values = vec![0, 1, 2, 3, 4]; let mut runner = TestRunner::deterministic(); let input = subsequence(values, 1..3); let _ = input.new_tree(&mut runner).unwrap().current(); } #[test] fn test_select() { let values = vec![0, 1, 2, 3, 4, 5, 6, 7]; let mut counts = [0; 8]; let mut runner = TestRunner::deterministic(); let input = select(values); for _ in 0..1024 { counts[input.new_tree(&mut runner).unwrap().current()] += 1; } for (ix, &count) in counts.iter().enumerate() { assert!( count >= 64 && count < 256, "Generated value {} {} times", ix, count ); } } #[test] fn test_sample_sanity() { check_strategy_sanity(subsequence(vec![0, 1, 2, 3, 4], 1..3), None); } #[test] fn test_select_sanity() { check_strategy_sanity(select(vec![0, 1, 2, 3, 4]), None); } #[test] fn subseq_empty_vec_works() { let mut runner = TestRunner::deterministic(); let input = subsequence(Vec::<()>::new(), 0..1); assert_eq!( Vec::<()>::new(), input.new_tree(&mut runner).unwrap().current() ); } #[test] fn subseq_full_vec_works() { let v = vec![1u32, 2u32, 3u32]; let mut runner = TestRunner::deterministic(); let input = subsequence(v.clone(), 3); assert_eq!(v, input.new_tree(&mut runner).unwrap().current()); } #[test] fn index_works() { let mut runner = TestRunner::deterministic(); let input = any::<Index>(); let col = vec!["foo", "bar", "baz"]; let mut seen = BTreeSet::new(); for _ in 0..16 { let mut tree = input.new_tree(&mut runner).unwrap(); seen.insert(*tree.current().get(&col)); while tree.simplify() {} assert_eq!("foo", *tree.current().get(&col)); } assert_eq!(col.into_iter().collect::<BTreeSet<_>>(), seen); } #[test] fn selector_works() { let mut runner = TestRunner::deterministic(); let input = any::<Selector>(); let col: BTreeSet<&str> = vec!["foo", "bar", "baz"].into_iter().collect(); let mut seen = BTreeSet::new(); for _ in 0..16 { let mut tree = input.new_tree(&mut runner).unwrap(); seen.insert(*tree.current().select(&col)); while tree.simplify() {} assert_eq!("bar", *tree.current().select(&col)); } assert_eq!(col, seen); } }