9b32e09551
# Objective Now that #13432 has been merged, it's important we update our reflected types to properly opt into this feature. If we do not, then this could cause issues for users downstream who want to make use of reflection-based cloning. ## Solution This PR is broken into 4 commits: 1. Add `#[reflect(Clone)]` on all types marked `#[reflect(opaque)]` that are also `Clone`. This is mandatory as these types would otherwise cause the cloning operation to fail for any type that contains it at any depth. 2. Update the reflection example to suggest adding `#[reflect(Clone)]` on opaque types. 3. Add `#[reflect(clone)]` attributes on all fields marked `#[reflect(ignore)]` that are also `Clone`. This prevents the ignored field from causing the cloning operation to fail. Note that some of the types that contain these fields are also `Clone`, and thus can be marked `#[reflect(Clone)]`. This makes the `#[reflect(clone)]` attribute redundant. However, I think it's safer to keep it marked in the case that the `Clone` impl/derive is ever removed. I'm open to removing them, though, if people disagree. 4. Finally, I added `#[reflect(Clone)]` on all types that are also `Clone`. While not strictly necessary, it enables us to reduce the generated output since we can just call `Clone::clone` directly instead of calling `PartialReflect::reflect_clone` on each variant/field. It also means we benefit from any optimizations or customizations made in the `Clone` impl, including directly dereferencing `Copy` values and increasing reference counters. Along with that change I also took the liberty of adding any missing registrations that I saw could be applied to the type as well, such as `Default`, `PartialEq`, and `Hash`. There were hundreds of these to edit, though, so it's possible I missed quite a few. That last commit is **_massive_**. There were nearly 700 types to update. So it's recommended to review the first three before moving onto that last one. Additionally, I can break the last commit off into its own PR or into smaller PRs, but I figured this would be the easiest way of doing it (and in a timely manner since I unfortunately don't have as much time as I used to for code contributions). ## Testing You can test locally with a `cargo check`: ``` cargo check --workspace --all-features ```
226 lines
7.3 KiB
Rust
226 lines
7.3 KiB
Rust
use bevy_reflect::Reflect;
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use core::iter;
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use core::iter::FusedIterator;
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use thiserror::Error;
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use wgpu_types::IndexFormat;
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/// A disjunction of four iterators. This is necessary to have a well-formed type for the output
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/// of [`Mesh::triangles`](super::Mesh::triangles), which produces iterators of four different types depending on the
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/// branch taken.
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pub(crate) enum FourIterators<A, B, C, D> {
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First(A),
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Second(B),
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Third(C),
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Fourth(D),
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}
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impl<A, B, C, D, I> Iterator for FourIterators<A, B, C, D>
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where
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A: Iterator<Item = I>,
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B: Iterator<Item = I>,
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C: Iterator<Item = I>,
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D: Iterator<Item = I>,
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{
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type Item = I;
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fn next(&mut self) -> Option<Self::Item> {
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match self {
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FourIterators::First(iter) => iter.next(),
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FourIterators::Second(iter) => iter.next(),
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FourIterators::Third(iter) => iter.next(),
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FourIterators::Fourth(iter) => iter.next(),
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}
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}
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}
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/// An error that occurred while trying to invert the winding of a [`Mesh`](super::Mesh).
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#[derive(Debug, Error)]
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pub enum MeshWindingInvertError {
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/// This error occurs when you try to invert the winding for a mesh with [`PrimitiveTopology::PointList`](super::PrimitiveTopology::PointList).
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#[error("Mesh winding inversion does not work for primitive topology `PointList`")]
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WrongTopology,
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/// This error occurs when you try to invert the winding for a mesh with
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/// * [`PrimitiveTopology::TriangleList`](super::PrimitiveTopology::TriangleList), but the indices are not in chunks of 3.
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/// * [`PrimitiveTopology::LineList`](super::PrimitiveTopology::LineList), but the indices are not in chunks of 2.
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#[error("Indices weren't in chunks according to topology")]
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AbruptIndicesEnd,
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}
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/// An error that occurred while trying to extract a collection of triangles from a [`Mesh`](super::Mesh).
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#[derive(Debug, Error)]
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pub enum MeshTrianglesError {
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#[error("Source mesh does not have primitive topology TriangleList or TriangleStrip")]
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WrongTopology,
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#[error("Source mesh lacks position data")]
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MissingPositions,
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#[error("Source mesh position data is not Float32x3")]
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PositionsFormat,
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#[error("Source mesh lacks face index data")]
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MissingIndices,
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#[error("Face index data references vertices that do not exist")]
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BadIndices,
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}
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/// An array of indices into the [`VertexAttributeValues`](super::VertexAttributeValues) for a mesh.
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///
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/// It describes the order in which the vertex attributes should be joined into faces.
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#[derive(Debug, Clone, Reflect)]
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#[reflect(Clone)]
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pub enum Indices {
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U16(Vec<u16>),
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U32(Vec<u32>),
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}
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impl Indices {
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/// Returns an iterator over the indices.
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pub fn iter(&self) -> impl Iterator<Item = usize> + '_ {
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match self {
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Indices::U16(vec) => IndicesIter::U16(vec.iter()),
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Indices::U32(vec) => IndicesIter::U32(vec.iter()),
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}
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}
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/// Returns the number of indices.
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pub fn len(&self) -> usize {
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match self {
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Indices::U16(vec) => vec.len(),
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Indices::U32(vec) => vec.len(),
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}
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}
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/// Returns `true` if there are no indices.
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pub fn is_empty(&self) -> bool {
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match self {
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Indices::U16(vec) => vec.is_empty(),
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Indices::U32(vec) => vec.is_empty(),
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}
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}
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/// Add an index. If the index is greater than `u16::MAX`,
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/// the storage will be converted to `u32`.
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pub fn push(&mut self, index: u32) {
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self.extend([index]);
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}
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}
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/// Extend the indices with indices from an iterator.
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/// Semantically equivalent to calling [`push`](Indices::push) for each element in the iterator,
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/// but more efficient.
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impl Extend<u32> for Indices {
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fn extend<T: IntoIterator<Item = u32>>(&mut self, iter: T) {
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let mut iter = iter.into_iter();
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match self {
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Indices::U32(indices) => indices.extend(iter),
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Indices::U16(indices) => {
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indices.reserve(iter.size_hint().0);
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while let Some(index) = iter.next() {
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match u16::try_from(index) {
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Ok(index) => indices.push(index),
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Err(_) => {
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let new_vec = indices
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.iter()
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.map(|&index| u32::from(index))
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.chain(iter::once(index))
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.chain(iter)
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.collect::<Vec<u32>>();
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*self = Indices::U32(new_vec);
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break;
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}
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}
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}
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}
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}
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}
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}
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/// An Iterator for the [`Indices`].
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enum IndicesIter<'a> {
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U16(core::slice::Iter<'a, u16>),
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U32(core::slice::Iter<'a, u32>),
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}
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impl Iterator for IndicesIter<'_> {
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type Item = usize;
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fn next(&mut self) -> Option<Self::Item> {
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match self {
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IndicesIter::U16(iter) => iter.next().map(|val| *val as usize),
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IndicesIter::U32(iter) => iter.next().map(|val| *val as usize),
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}
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}
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fn size_hint(&self) -> (usize, Option<usize>) {
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match self {
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IndicesIter::U16(iter) => iter.size_hint(),
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IndicesIter::U32(iter) => iter.size_hint(),
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}
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}
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}
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impl<'a> ExactSizeIterator for IndicesIter<'a> {}
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impl<'a> FusedIterator for IndicesIter<'a> {}
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impl From<&Indices> for IndexFormat {
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fn from(indices: &Indices) -> Self {
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match indices {
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Indices::U16(_) => IndexFormat::Uint16,
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Indices::U32(_) => IndexFormat::Uint32,
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}
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}
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}
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#[cfg(test)]
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mod tests {
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use crate::Indices;
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use wgpu_types::IndexFormat;
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#[test]
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fn test_indices_push() {
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let mut indices = Indices::U16(Vec::new());
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indices.push(10);
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assert_eq!(IndexFormat::Uint16, IndexFormat::from(&indices));
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assert_eq!(vec![10], indices.iter().collect::<Vec<_>>());
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// Add a value that is too large for `u16` so the storage should be converted to `U32`.
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indices.push(0x10000);
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assert_eq!(IndexFormat::Uint32, IndexFormat::from(&indices));
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assert_eq!(vec![10, 0x10000], indices.iter().collect::<Vec<_>>());
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indices.push(20);
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indices.push(0x20000);
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assert_eq!(IndexFormat::Uint32, IndexFormat::from(&indices));
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assert_eq!(
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vec![10, 0x10000, 20, 0x20000],
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indices.iter().collect::<Vec<_>>()
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);
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}
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#[test]
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fn test_indices_extend() {
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let mut indices = Indices::U16(Vec::new());
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indices.extend([10, 11]);
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assert_eq!(IndexFormat::Uint16, IndexFormat::from(&indices));
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assert_eq!(vec![10, 11], indices.iter().collect::<Vec<_>>());
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// Add a value that is too large for `u16` so the storage should be converted to `U32`.
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indices.extend([12, 0x10013, 0x10014]);
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assert_eq!(IndexFormat::Uint32, IndexFormat::from(&indices));
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assert_eq!(
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vec![10, 11, 12, 0x10013, 0x10014],
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indices.iter().collect::<Vec<_>>()
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);
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indices.extend([15, 0x10016]);
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assert_eq!(IndexFormat::Uint32, IndexFormat::from(&indices));
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assert_eq!(
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vec![10, 11, 12, 0x10013, 0x10014, 15, 0x10016],
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indices.iter().collect::<Vec<_>>()
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);
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}
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}
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