// Copyright 2012 The Rust Project Developers. See the COPYRIGHT // file at the top-level directory of this distribution and at // http://rust-lang.org/COPYRIGHT. // // Licensed under the Apache License, Version 2.0 or the MIT license // , at your // option. This file may not be copied, modified, or distributed // except according to those terms. //! A structure for holding a set of enum variants //! //! This module defines a container which uses an efficient bit mask //! representation to hold C-like enum variants. #[deriving(Clone, Eq, IterBytes, ToStr)] /// A specialized Set implementation to use enum types. pub struct EnumSet { // We must maintain the invariant that no bits are set // for which no variant exists priv bits: uint } /// An interface for casting C-like enum to uint and back. pub trait CLike { /// Converts C-like enum to uint. fn to_uint(&self) -> uint; /// Converts uint to C-like enum. fn from_uint(uint) -> Self; } fn bit(e: E) -> uint { 1 << e.to_uint() } impl EnumSet { /// Returns an empty EnumSet. pub fn empty() -> EnumSet { EnumSet {bits: 0} } /// Returns true if an EnumSet is empty. pub fn is_empty(&self) -> bool { self.bits == 0 } /// Returns true if an EnumSet contains any enum of a given EnumSet pub fn intersects(&self, e: EnumSet) -> bool { (self.bits & e.bits) != 0 } /// Returns an intersection of both EnumSets. pub fn intersection(&self, e: EnumSet) -> EnumSet { EnumSet {bits: self.bits & e.bits} } /// Returns true if a given EnumSet is included in an EnumSet. pub fn contains(&self, e: EnumSet) -> bool { (self.bits & e.bits) == e.bits } /// Returns a union of both EnumSets. pub fn union(&self, e: EnumSet) -> EnumSet { EnumSet {bits: self.bits | e.bits} } /// Add an enum to an EnumSet pub fn add(&mut self, e: E) { self.bits |= bit(e); } /// Returns true if an EnumSet contains a given enum pub fn contains_elem(&self, e: E) -> bool { (self.bits & bit(e)) != 0 } /// Returns an iterator over an EnumSet pub fn iter(&self) -> EnumSetIterator { EnumSetIterator::new(self.bits) } } impl Sub, EnumSet> for EnumSet { fn sub(&self, e: &EnumSet) -> EnumSet { EnumSet {bits: self.bits & !e.bits} } } impl BitOr, EnumSet> for EnumSet { fn bitor(&self, e: &EnumSet) -> EnumSet { EnumSet {bits: self.bits | e.bits} } } impl BitAnd, EnumSet> for EnumSet { fn bitand(&self, e: &EnumSet) -> EnumSet { EnumSet {bits: self.bits & e.bits} } } /// An iterator over an EnumSet pub struct EnumSetIterator { priv index: uint, priv bits: uint, } impl EnumSetIterator { fn new(bits: uint) -> EnumSetIterator { EnumSetIterator { index: 0, bits: bits } } } impl Iterator for EnumSetIterator { fn next(&mut self) -> Option { if (self.bits == 0) { return None; } while (self.bits & 1) == 0 { self.index += 1; self.bits >>= 1; } let elem = CLike::from_uint(self.index); self.index += 1; self.bits >>= 1; Some(elem) } fn size_hint(&self) -> (uint, Option) { let exact = self.bits.population_count(); (exact, Some(exact)) } } #[cfg(test)] mod test { use std::cast; use enum_set::*; #[deriving(Eq)] #[repr(uint)] enum Foo { A, B, C } impl CLike for Foo { fn to_uint(&self) -> uint { *self as uint } fn from_uint(v: uint) -> Foo { unsafe { cast::transmute(v) } } } #[test] fn test_empty() { let e: EnumSet = EnumSet::empty(); assert!(e.is_empty()); } /////////////////////////////////////////////////////////////////////////// // intersect #[test] fn test_two_empties_do_not_intersect() { let e1: EnumSet = EnumSet::empty(); let e2: EnumSet = EnumSet::empty(); assert!(!e1.intersects(e2)); } #[test] fn test_empty_does_not_intersect_with_full() { let e1: EnumSet = EnumSet::empty(); let mut e2: EnumSet = EnumSet::empty(); e2.add(A); e2.add(B); e2.add(C); assert!(!e1.intersects(e2)); } #[test] fn test_disjoint_intersects() { let mut e1: EnumSet = EnumSet::empty(); e1.add(A); let mut e2: EnumSet = EnumSet::empty(); e2.add(B); assert!(!e1.intersects(e2)); } #[test] fn test_overlapping_intersects() { let mut e1: EnumSet = EnumSet::empty(); e1.add(A); let mut e2: EnumSet = EnumSet::empty(); e2.add(A); e2.add(B); assert!(e1.intersects(e2)); } /////////////////////////////////////////////////////////////////////////// // contains and contains_elem #[test] fn test_contains() { let mut e1: EnumSet = EnumSet::empty(); e1.add(A); let mut e2: EnumSet = EnumSet::empty(); e2.add(A); e2.add(B); assert!(!e1.contains(e2)); assert!(e2.contains(e1)); } #[test] fn test_contains_elem() { let mut e1: EnumSet = EnumSet::empty(); e1.add(A); assert!(e1.contains_elem(A)); assert!(!e1.contains_elem(B)); assert!(!e1.contains_elem(C)); e1.add(A); e1.add(B); assert!(e1.contains_elem(A)); assert!(e1.contains_elem(B)); assert!(!e1.contains_elem(C)); } /////////////////////////////////////////////////////////////////////////// // iter #[test] fn test_iterator() { let mut e1: EnumSet = EnumSet::empty(); let elems: ~[Foo] = e1.iter().collect(); assert_eq!(~[], elems) e1.add(A); let elems: ~[Foo] = e1.iter().collect(); assert_eq!(~[A], elems) e1.add(C); let elems: ~[Foo] = e1.iter().collect(); assert_eq!(~[A,C], elems) e1.add(C); let elems: ~[Foo] = e1.iter().collect(); assert_eq!(~[A,C], elems) e1.add(B); let elems: ~[Foo] = e1.iter().collect(); assert_eq!(~[A,B,C], elems) } /////////////////////////////////////////////////////////////////////////// // operators #[test] fn test_operators() { let mut e1: EnumSet = EnumSet::empty(); e1.add(A); e1.add(C); let mut e2: EnumSet = EnumSet::empty(); e2.add(B); e2.add(C); let e_union = e1 | e2; let elems: ~[Foo] = e_union.iter().collect(); assert_eq!(~[A,B,C], elems) let e_intersection = e1 & e2; let elems: ~[Foo] = e_intersection.iter().collect(); assert_eq!(~[C], elems) let e_subtract = e1 - e2; let elems: ~[Foo] = e_subtract.iter().collect(); assert_eq!(~[A], elems) } }