indexmap_amortized/macros.rs
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#[cfg(has_std)]
#[macro_export]
/// Create an `IndexMap` from a list of key-value pairs
///
/// ## Example
///
/// ```
/// use indexmap_amortized::indexmap;
///
/// let map = indexmap!{
/// "a" => 1,
/// "b" => 2,
/// };
/// assert_eq!(map["a"], 1);
/// assert_eq!(map["b"], 2);
/// assert_eq!(map.get("c"), None);
///
/// // "a" is the first key
/// assert_eq!(map.keys().next(), Some(&"a"));
/// ```
macro_rules! indexmap {
(@single $($x:tt)*) => (());
(@count $($rest:expr),*) => (<[()]>::len(&[$($crate::indexmap!(@single $rest)),*]));
($($key:expr => $value:expr,)+) => { $crate::indexmap!($($key => $value),+) };
($($key:expr => $value:expr),*) => {
{
let _cap = $crate::indexmap!(@count $($key),*);
let mut _map = $crate::IndexMap::with_capacity(_cap);
$(
_map.insert($key, $value);
)*
_map
}
};
}
#[cfg(has_std)]
#[macro_export]
/// Create an `IndexSet` from a list of values
///
/// ## Example
///
/// ```
/// use indexmap_amortized::indexset;
///
/// let set = indexset!{
/// "a",
/// "b",
/// };
/// assert!(set.contains("a"));
/// assert!(set.contains("b"));
/// assert!(!set.contains("c"));
///
/// // "a" is the first value
/// assert_eq!(set.iter().next(), Some(&"a"));
/// ```
macro_rules! indexset {
(@single $($x:tt)*) => (());
(@count $($rest:expr),*) => (<[()]>::len(&[$($crate::indexset!(@single $rest)),*]));
($($value:expr,)+) => { $crate::indexset!($($value),+) };
($($value:expr),*) => {
{
let _cap = $crate::indexset!(@count $($value),*);
let mut _set = $crate::IndexSet::with_capacity(_cap);
$(
_set.insert($value);
)*
_set
}
};
}
// generate all the Iterator methods by just forwarding to the underlying
// self.iter and mapping its element.
macro_rules! iterator_methods {
// $map_elt is the mapping function from the underlying iterator's element
// same mapping function for both options and iterators
($map_elt:expr) => {
fn next(&mut self) -> Option<Self::Item> {
self.iter.next().map($map_elt)
}
fn size_hint(&self) -> (usize, Option<usize>) {
self.iter.size_hint()
}
fn count(self) -> usize {
self.iter.len()
}
fn nth(&mut self, n: usize) -> Option<Self::Item> {
self.iter.nth(n).map($map_elt)
}
fn last(mut self) -> Option<Self::Item> {
self.next_back()
}
fn collect<C>(self) -> C
where
C: FromIterator<Self::Item>,
{
// NB: forwarding this directly to standard iterators will
// allow it to leverage unstable traits like `TrustedLen`.
self.iter.map($map_elt).collect()
}
};
}
macro_rules! double_ended_iterator_methods {
// $map_elt is the mapping function from the underlying iterator's element
// same mapping function for both options and iterators
($map_elt:expr) => {
fn next_back(&mut self) -> Option<Self::Item> {
self.iter.next_back().map($map_elt)
}
};
}