Reform power_of_two methods for perf increase & semantic change to consider 0 not a power of 2.
Vec panics when attempting to reserve capacity > int::MAX (uint::MAX / 2).
This commit is contained in:
Aaron Liblong
parent
99d6956c3b
commit
f6328b60da
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@ -710,20 +710,10 @@ impl<T> Vec<T> {
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#[unstable = "matches collection reform specification, waiting for dust to settle"]
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pub fn reserve(&mut self, additional: uint) {
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if self.cap - self.len < additional {
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match self.len.checked_add(additional) {
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None => panic!("Vec::reserve: `uint` overflow"),
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// if the checked_add
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Some(new_cap) => {
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let amort_cap = new_cap.next_power_of_two();
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// next_power_of_two will overflow to exactly 0 for really big capacities
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let cap = if amort_cap == 0 {
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new_cap
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} else {
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amort_cap
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};
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self.grow_capacity(cap)
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}
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}
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let err_msg = "Vec::reserve: `uint` overflow";
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let new_cap = self.len.checked_add(additional).expect(err_msg)
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.checked_next_power_of_two().expect(err_msg);
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self.grow_capacity(new_cap);
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}
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}
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@ -673,35 +673,30 @@ signed_int_impl! { int }
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#[unstable = "recently settled as part of numerics reform"]
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pub trait UnsignedInt: Int {
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/// Returns `true` iff `self == 2^k` for some `k`.
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#[inline]
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fn is_power_of_two(self) -> bool {
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(self - Int::one()) & self == Int::zero()
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(self - Int::one()) & self == Int::zero() && !(self == Int::zero())
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}
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/// Returns the smallest power of two greater than or equal to `self`.
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/// Unspecified behavior on overflow.
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#[inline]
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fn next_power_of_two(self) -> Self {
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let halfbits = size_of::<Self>() * 4;
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let mut tmp = self - Int::one();
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let mut shift = 1u;
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while shift <= halfbits {
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tmp = tmp | (tmp >> shift);
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shift = shift << 1u;
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}
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tmp + Int::one()
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let bits = size_of::<Self>() * 8;
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let one: Self = Int::one();
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one << ((bits - (self - one).leading_zeros()) % bits)
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}
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/// Returns the smallest power of two greater than or equal to `n`. If the
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/// next power of two is greater than the type's maximum value, `None` is
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/// returned, otherwise the power of two is wrapped in `Some`.
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fn checked_next_power_of_two(self) -> Option<Self> {
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let halfbits = size_of::<Self>() * 4;
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let mut tmp = self - Int::one();
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let mut shift = 1u;
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while shift <= halfbits {
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tmp = tmp | (tmp >> shift);
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shift = shift << 1u;
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let npot = self.next_power_of_two();
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if npot >= self {
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Some(npot)
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} else {
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None
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}
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tmp.checked_add(Int::one())
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}
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}
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@ -623,10 +623,10 @@ impl<K: Eq + Hash<S>, V, S, H: Hasher<S>> HashMap<K, V, H> {
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/// Resizes the internal vectors to a new capacity. It's your responsibility to:
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/// 1) Make sure the new capacity is enough for all the elements, accounting
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/// for the load factor.
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/// 2) Ensure new_capacity is a power of two.
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/// 2) Ensure new_capacity is a power of two or zero.
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fn resize(&mut self, new_capacity: uint) {
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assert!(self.table.size() <= new_capacity);
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assert!(new_capacity.is_power_of_two());
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assert!(new_capacity.is_power_of_two() || new_capacity == 0);
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let mut old_table = replace(&mut self.table, RawTable::new(new_capacity));
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let old_size = old_table.size();
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@ -664,11 +664,32 @@ mod tests {
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assert_eq!(third.checked_mul(4), None);
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}
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macro_rules! test_is_power_of_two {
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($test_name:ident, $T:ident) => (
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fn $test_name() {
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#![test]
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assert_eq!((0 as $T).is_power_of_two(), false);
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assert_eq!((1 as $T).is_power_of_two(), true);
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assert_eq!((2 as $T).is_power_of_two(), true);
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assert_eq!((3 as $T).is_power_of_two(), false);
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assert_eq!((4 as $T).is_power_of_two(), true);
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assert_eq!((5 as $T).is_power_of_two(), false);
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assert!(($T::MAX / 2 + 1).is_power_of_two(), true);
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}
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)
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}
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test_is_power_of_two!{ test_is_power_of_two_u8, u8 }
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test_is_power_of_two!{ test_is_power_of_two_u16, u16 }
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test_is_power_of_two!{ test_is_power_of_two_u32, u32 }
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test_is_power_of_two!{ test_is_power_of_two_u64, u64 }
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test_is_power_of_two!{ test_is_power_of_two_uint, uint }
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macro_rules! test_next_power_of_two {
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($test_name:ident, $T:ident) => (
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fn $test_name() {
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#![test]
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assert_eq!((0 as $T).next_power_of_two(), 0);
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assert_eq!((0 as $T).next_power_of_two(), 1);
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let mut next_power = 1;
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for i in range::<$T>(1, 40) {
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assert_eq!(i.next_power_of_two(), next_power);
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@ -688,15 +709,15 @@ mod tests {
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($test_name:ident, $T:ident) => (
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fn $test_name() {
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#![test]
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assert_eq!((0 as $T).checked_next_power_of_two(), None);
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assert_eq!((0 as $T).checked_next_power_of_two(), Some(1));
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assert!(($T::MAX / 2).checked_next_power_of_two().is_some());
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assert_eq!(($T::MAX - 1).checked_next_power_of_two(), None);
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assert_eq!($T::MAX.checked_next_power_of_two(), None);
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let mut next_power = 1;
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for i in range::<$T>(1, 40) {
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assert_eq!(i.checked_next_power_of_two(), Some(next_power));
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if i == next_power { next_power *= 2 }
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}
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assert!(($T::MAX / 2).checked_next_power_of_two().is_some());
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assert_eq!(($T::MAX - 1).checked_next_power_of_two(), None);
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assert_eq!($T::MAX.checked_next_power_of_two(), None);
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}
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)
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}
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