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fuchsia / third_party / rust / 346aec9b02f3c74f3fce97fd6bda24709d220e49 / . / src / librustc_index / bit_set / tests.rs
blob: 6cc3e9427d1a717ec0c1f639cf95447e888f2f57 [file] [log] [blame]
use super::*;
extern crate test;
use test::Bencher;
#[test]
fn test_new_filled() {
for i in 0..128 {
let idx_buf = BitSet::new_filled(i);
let elems: Vec<usize> = idx_buf.iter().collect();
let expected: Vec<usize> = (0..i).collect();
assert_eq!(elems, expected);
}
}
#[test]
fn bitset_iter_works() {
let mut bitset: BitSet<usize> = BitSet::new_empty(100);
bitset.insert(1);
bitset.insert(10);
bitset.insert(19);
bitset.insert(62);
bitset.insert(63);
bitset.insert(64);
bitset.insert(65);
bitset.insert(66);
bitset.insert(99);
assert_eq!(bitset.iter().collect::<Vec<_>>(), [1, 10, 19, 62, 63, 64, 65, 66, 99]);
}
#[test]
fn bitset_iter_works_2() {
let mut bitset: BitSet<usize> = BitSet::new_empty(320);
bitset.insert(0);
bitset.insert(127);
bitset.insert(191);
bitset.insert(255);
bitset.insert(319);
assert_eq!(bitset.iter().collect::<Vec<_>>(), [0, 127, 191, 255, 319]);
}
#[test]
fn union_two_sets() {
let mut set1: BitSet<usize> = BitSet::new_empty(65);
let mut set2: BitSet<usize> = BitSet::new_empty(65);
assert!(set1.insert(3));
assert!(!set1.insert(3));
assert!(set2.insert(5));
assert!(set2.insert(64));
assert!(set1.union(&set2));
assert!(!set1.union(&set2));
assert!(set1.contains(3));
assert!(!set1.contains(4));
assert!(set1.contains(5));
assert!(!set1.contains(63));
assert!(set1.contains(64));
}
#[test]
fn hybrid_bitset() {
let mut sparse038: HybridBitSet<usize> = HybridBitSet::new_empty(256);
assert!(sparse038.is_empty());
assert!(sparse038.insert(0));
assert!(sparse038.insert(1));
assert!(sparse038.insert(8));
assert!(sparse038.insert(3));
assert!(!sparse038.insert(3));
assert!(sparse038.remove(1));
assert!(!sparse038.is_empty());
assert_eq!(sparse038.iter().collect::<Vec<_>>(), [0, 3, 8]);
for i in 0..256 {
if i == 0 || i == 3 || i == 8 {
assert!(sparse038.contains(i));
} else {
assert!(!sparse038.contains(i));
}
}
let mut sparse01358 = sparse038.clone();
assert!(sparse01358.insert(1));
assert!(sparse01358.insert(5));
assert_eq!(sparse01358.iter().collect::<Vec<_>>(), [0, 1, 3, 5, 8]);
let mut dense10 = HybridBitSet::new_empty(256);
for i in 0..10 {
assert!(dense10.insert(i));
}
assert!(!dense10.is_empty());
assert_eq!(dense10.iter().collect::<Vec<_>>(), [0, 1, 2, 3, 4, 5, 6, 7, 8, 9]);
let mut dense256 = HybridBitSet::new_empty(256);
assert!(dense256.is_empty());
dense256.insert_all();
assert!(!dense256.is_empty());
for i in 0..256 {
assert!(dense256.contains(i));
}
assert!(sparse038.superset(&sparse038)); // sparse + sparse (self)
assert!(sparse01358.superset(&sparse038)); // sparse + sparse
assert!(dense10.superset(&sparse038)); // dense + sparse
assert!(dense10.superset(&dense10)); // dense + dense (self)
assert!(dense256.superset(&dense10)); // dense + dense
let mut hybrid = sparse038;
assert!(!sparse01358.union(&hybrid)); // no change
assert!(hybrid.union(&sparse01358));
assert!(hybrid.superset(&sparse01358) && sparse01358.superset(&hybrid));
assert!(!dense10.union(&sparse01358));
assert!(!dense256.union(&dense10));
let mut dense = dense10;
assert!(dense.union(&dense256));
assert!(dense.superset(&dense256) && dense256.superset(&dense));
assert!(hybrid.union(&dense256));
assert!(hybrid.superset(&dense256) && dense256.superset(&hybrid));
assert_eq!(dense256.iter().count(), 256);
let mut dense0 = dense256;
for i in 0..256 {
assert!(dense0.remove(i));
}
assert!(!dense0.remove(0));
assert!(dense0.is_empty());
}
#[test]
fn grow() {
let mut set: GrowableBitSet<usize> = GrowableBitSet::with_capacity(65);
for index in 0..65 {
assert!(set.insert(index));
assert!(!set.insert(index));
}
set.ensure(128);
// Check if the bits set before growing are still set
for index in 0..65 {
assert!(set.contains(index));
}
// Check if the new bits are all un-set
for index in 65..128 {
assert!(!set.contains(index));
}
// Check that we can set all new bits without running out of bounds
for index in 65..128 {
assert!(set.insert(index));
assert!(!set.insert(index));
}
}
#[test]
fn matrix_intersection() {
let mut matrix: BitMatrix<usize, usize> = BitMatrix::new(200, 200);
// (*) Elements reachable from both 2 and 65.
matrix.insert(2, 3);
matrix.insert(2, 6);
matrix.insert(2, 10); // (*)
matrix.insert(2, 64); // (*)
matrix.insert(2, 65);
matrix.insert(2, 130);
matrix.insert(2, 160); // (*)
matrix.insert(64, 133);
matrix.insert(65, 2);
matrix.insert(65, 8);
matrix.insert(65, 10); // (*)
matrix.insert(65, 64); // (*)
matrix.insert(65, 68);
matrix.insert(65, 133);
matrix.insert(65, 160); // (*)
let intersection = matrix.intersect_rows(2, 64);
assert!(intersection.is_empty());
let intersection = matrix.intersect_rows(2, 65);
assert_eq!(intersection, &[10, 64, 160]);
}
#[test]
fn matrix_iter() {
let mut matrix: BitMatrix<usize, usize> = BitMatrix::new(64, 100);
matrix.insert(3, 22);
matrix.insert(3, 75);
matrix.insert(2, 99);
matrix.insert(4, 0);
matrix.union_rows(3, 5);
matrix.insert_all_into_row(6);
let expected = [99];
let mut iter = expected.iter();
for i in matrix.iter(2) {
let j = *iter.next().unwrap();
assert_eq!(i, j);
}
assert!(iter.next().is_none());
let expected = [22, 75];
let mut iter = expected.iter();
assert_eq!(matrix.count(3), expected.len());
for i in matrix.iter(3) {
let j = *iter.next().unwrap();
assert_eq!(i, j);
}
assert!(iter.next().is_none());
let expected = [0];
let mut iter = expected.iter();
assert_eq!(matrix.count(4), expected.len());
for i in matrix.iter(4) {
let j = *iter.next().unwrap();
assert_eq!(i, j);
}
assert!(iter.next().is_none());
let expected = [22, 75];
let mut iter = expected.iter();
assert_eq!(matrix.count(5), expected.len());
for i in matrix.iter(5) {
let j = *iter.next().unwrap();
assert_eq!(i, j);
}
assert!(iter.next().is_none());
assert_eq!(matrix.count(6), 100);
let mut count = 0;
for (idx, i) in matrix.iter(6).enumerate() {
assert_eq!(idx, i);
count += 1;
}
assert_eq!(count, 100);
if let Some(i) = matrix.iter(7).next() {
panic!("expected no elements in row, but contains element {:?}", i);
}
}
#[test]
fn sparse_matrix_iter() {
let mut matrix: SparseBitMatrix<usize, usize> = SparseBitMatrix::new(100);
matrix.insert(3, 22);
matrix.insert(3, 75);
matrix.insert(2, 99);
matrix.insert(4, 0);
matrix.union_rows(3, 5);
let expected = [99];
let mut iter = expected.iter();
for i in matrix.iter(2) {
let j = *iter.next().unwrap();
assert_eq!(i, j);
}
assert!(iter.next().is_none());
let expected = [22, 75];
let mut iter = expected.iter();
for i in matrix.iter(3) {
let j = *iter.next().unwrap();
assert_eq!(i, j);
}
assert!(iter.next().is_none());
let expected = [0];
let mut iter = expected.iter();
for i in matrix.iter(4) {
let j = *iter.next().unwrap();
assert_eq!(i, j);
}
assert!(iter.next().is_none());
let expected = [22, 75];
let mut iter = expected.iter();
for i in matrix.iter(5) {
let j = *iter.next().unwrap();
assert_eq!(i, j);
}
assert!(iter.next().is_none());
}
/// Merge dense hybrid set into empty sparse hybrid set.
#[bench]
fn union_hybrid_sparse_empty_to_dense(b: &mut Bencher) {
let mut pre_dense: HybridBitSet<usize> = HybridBitSet::new_empty(256);
for i in 0..10 {
assert!(pre_dense.insert(i));
}
let pre_sparse: HybridBitSet<usize> = HybridBitSet::new_empty(256);
b.iter(|| {
let dense = pre_dense.clone();
let mut sparse = pre_sparse.clone();
sparse.union(&dense);
})
}
/// Merge dense hybrid set into full hybrid set with same indices.
#[bench]
fn union_hybrid_sparse_full_to_dense(b: &mut Bencher) {
let mut pre_dense: HybridBitSet<usize> = HybridBitSet::new_empty(256);
for i in 0..10 {
assert!(pre_dense.insert(i));
}
let mut pre_sparse: HybridBitSet<usize> = HybridBitSet::new_empty(256);
for i in 0..SPARSE_MAX {
assert!(pre_sparse.insert(i));
}
b.iter(|| {
let dense = pre_dense.clone();
let mut sparse = pre_sparse.clone();
sparse.union(&dense);
})
}
/// Merge dense hybrid set into full hybrid set with indices over the whole domain.
#[bench]
fn union_hybrid_sparse_domain_to_dense(b: &mut Bencher) {
let mut pre_dense: HybridBitSet<usize> = HybridBitSet::new_empty(SPARSE_MAX * 64);
for i in 0..10 {
assert!(pre_dense.insert(i));
}
let mut pre_sparse: HybridBitSet<usize> = HybridBitSet::new_empty(SPARSE_MAX * 64);
for i in 0..SPARSE_MAX {
assert!(pre_sparse.insert(i * 64));
}
b.iter(|| {
let dense = pre_dense.clone();
let mut sparse = pre_sparse.clone();
sparse.union(&dense);
})
}
/// Merge dense hybrid set into empty hybrid set where the domain is very small.
#[bench]
fn union_hybrid_sparse_empty_small_domain(b: &mut Bencher) {
let mut pre_dense: HybridBitSet<usize> = HybridBitSet::new_empty(SPARSE_MAX);
for i in 0..SPARSE_MAX {
assert!(pre_dense.insert(i));
}
let pre_sparse: HybridBitSet<usize> = HybridBitSet::new_empty(SPARSE_MAX);
b.iter(|| {
let dense = pre_dense.clone();
let mut sparse = pre_sparse.clone();
sparse.union(&dense);
})
}
/// Merge dense hybrid set into full hybrid set where the domain is very small.
#[bench]
fn union_hybrid_sparse_full_small_domain(b: &mut Bencher) {
let mut pre_dense: HybridBitSet<usize> = HybridBitSet::new_empty(SPARSE_MAX);
for i in 0..SPARSE_MAX {
assert!(pre_dense.insert(i));
}
let mut pre_sparse: HybridBitSet<usize> = HybridBitSet::new_empty(SPARSE_MAX);
for i in 0..SPARSE_MAX {
assert!(pre_sparse.insert(i));
}
b.iter(|| {
let dense = pre_dense.clone();
let mut sparse = pre_sparse.clone();
sparse.union(&dense);
})
}