bevy/examples/asset/asset_decompression.rs

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Added Method to Allow Pipelined Asset Loading (#10565) # Objective - Fixes #10518 ## Solution I've added a method to `LoadContext`, `load_direct_with_reader`, which mirrors the behaviour of `load_direct` with a single key difference: it is provided with the `Reader` by the caller, rather than getting it from the contained `AssetServer`. This allows for an `AssetLoader` to process its `Reader` stream, and then directly hand the results off to the `LoadContext` to handle further loading. The outer `AssetLoader` can control how the `Reader` is interpreted by providing a relevant `AssetPath`. For example, a Gzip decompression loader could process the asset `images/my_image.png.gz` by decompressing the bytes, then handing the decompressed result to the `LoadContext` with the new path `images/my_image.png.gz/my_image.png`. This intuitively reflects the nature of contained assets, whilst avoiding unintended behaviour, since the generated path cannot be a real file path (a file and folder of the same name cannot coexist in most file-systems). ```rust #[derive(Asset, TypePath)] pub struct GzAsset { pub uncompressed: ErasedLoadedAsset, } #[derive(Default)] pub struct GzAssetLoader; impl AssetLoader for GzAssetLoader { type Asset = GzAsset; type Settings = (); type Error = GzAssetLoaderError; fn load<'a>( &'a self, reader: &'a mut Reader, _settings: &'a (), load_context: &'a mut LoadContext, ) -> BoxedFuture<'a, Result<Self::Asset, Self::Error>> { Box::pin(async move { let compressed_path = load_context.path(); let file_name = compressed_path .file_name() .ok_or(GzAssetLoaderError::IndeterminateFilePath)? .to_string_lossy(); let uncompressed_file_name = file_name .strip_suffix(".gz") .ok_or(GzAssetLoaderError::IndeterminateFilePath)?; let contained_path = compressed_path.join(uncompressed_file_name); let mut bytes_compressed = Vec::new(); reader.read_to_end(&mut bytes_compressed).await?; let mut decoder = GzDecoder::new(bytes_compressed.as_slice()); let mut bytes_uncompressed = Vec::new(); decoder.read_to_end(&mut bytes_uncompressed)?; // Now that we have decompressed the asset, let's pass it back to the // context to continue loading let mut reader = VecReader::new(bytes_uncompressed); let uncompressed = load_context .load_direct_with_reader(&mut reader, contained_path) .await?; Ok(GzAsset { uncompressed }) }) } fn extensions(&self) -> &[&str] { &["gz"] } } ``` Because this example is so prudent, I've included an `asset_decompression` example which implements this exact behaviour: ```rust fn main() { App::new() .add_plugins(DefaultPlugins) .init_asset::<GzAsset>() .init_asset_loader::<GzAssetLoader>() .add_systems(Startup, setup) .add_systems(Update, decompress::<Image>) .run(); } fn setup(mut commands: Commands, asset_server: Res<AssetServer>) { commands.spawn(Camera2dBundle::default()); commands.spawn(( Compressed::<Image> { compressed: asset_server.load("data/compressed_image.png.gz"), ..default() }, Sprite::default(), TransformBundle::default(), VisibilityBundle::default(), )); } fn decompress<A: Asset>( mut commands: Commands, asset_server: Res<AssetServer>, mut compressed_assets: ResMut<Assets<GzAsset>>, query: Query<(Entity, &Compressed<A>)>, ) { for (entity, Compressed { compressed, .. }) in query.iter() { let Some(GzAsset { uncompressed }) = compressed_assets.remove(compressed) else { continue; }; let uncompressed = uncompressed.take::<A>().unwrap(); commands .entity(entity) .remove::<Compressed<A>>() .insert(asset_server.add(uncompressed)); } } ``` A key limitation to this design is how to type the internally loaded asset, since the example `GzAssetLoader` is unaware of the internal asset type `A`. As such, in this example I store the contained asset as an `ErasedLoadedAsset`, and leave it up to the consumer of the `GzAsset` to handle typing the final result, which is the purpose of the `decompress` system. This limitation can be worked around by providing type information to the `GzAssetLoader`, such as `GzAssetLoader<Image, ImageAssetLoader>`, but this would require registering the asset loader for every possible decompression target. Aside from this limitation, nested asset containerisation works as an end user would expect; if the user registers a `TarAssetLoader`, and a `GzAssetLoader`, then they can load assets with compound containerisation, such as `images.tar.gz`. --- ## Changelog - Added `LoadContext::load_direct_with_reader` - Added `asset_decompression` example ## Notes - While I believe my implementation of a Gzip asset loader is reasonable, I haven't included it as a public feature of `bevy_asset` to keep the scope of this PR as focussed as possible. - I have included `flate2` as a `dev-dependency` for the example; it is not included in the main dependency graph.
2023-11-16 17:47:31 +00:00
//! Implements loader for a Gzip compressed asset.
use bevy::{
asset::{
io::{Reader, VecReader},
Optimize common usages of `AssetReader` (#14082) # Objective The `AssetReader` trait allows customizing the behavior of fetching bytes for an `AssetPath`, and expects implementors to return `dyn AsyncRead + AsyncSeek`. This gives implementors of `AssetLoader` great flexibility to tightly integrate their asset loading behavior with the asynchronous task system. However, almost all implementors of `AssetLoader` don't use the async functionality at all, and just call `AsyncReadExt::read_to_end(&mut Vec<u8>)`. This is incredibly inefficient, as this method repeatedly calls `poll_read` on the trait object, filling the vector 32 bytes at a time. At my work we have assets that are hundreds of megabytes which makes this a meaningful overhead. ## Solution Turn the `Reader` type alias into an actual trait, with a provided method `read_to_end`. This provided method should be more efficient than the existing extension method, as the compiler will know the underlying type of `Reader` when generating this function, which removes the repeated dynamic dispatches and allows the compiler to make further optimizations after inlining. Individual implementors are able to override the provided implementation -- for simple asset readers that just copy bytes from one buffer to another, this allows removing a large amount of overhead from the provided implementation. Now that `Reader` is an actual trait, I also improved the ergonomics for implementing `AssetReader`. Currently, implementors are expected to box their reader and return it as a trait object, which adds unnecessary boilerplate to implementations. This PR changes that trait method to return a pseudo trait alias, which allows implementors to return `impl Reader` instead of `Box<dyn Reader>`. Now, the boilerplate for boxing occurs in `ErasedAssetReader`. ## Testing I made identical changes to my company's fork of bevy. Our app, which makes heavy use of `read_to_end` for asset loading, still worked properly after this. I am not aware if we have a more systematic way of testing asset loading for correctness. --- ## Migration Guide The trait method `bevy_asset::io::AssetReader::read` (and `read_meta`) now return an opaque type instead of a boxed trait object. Implementors of these methods should change the type signatures appropriately ```rust impl AssetReader for MyReader { // Before async fn read<'a>(&'a self, path: &'a Path) -> Result<Box<Reader<'a>>, AssetReaderError> { let reader = // construct a reader Box::new(reader) as Box<Reader<'a>> } // After async fn read<'a>(&'a self, path: &'a Path) -> Result<impl Reader + 'a, AssetReaderError> { // create a reader } } ``` `bevy::asset::io::Reader` is now a trait, rather than a type alias for a trait object. Implementors of `AssetLoader::load` will need to adjust the method signature accordingly ```rust impl AssetLoader for MyLoader { async fn load<'a>( &'a self, // Before: reader: &'a mut bevy::asset::io::Reader, // After: reader: &'a mut dyn bevy::asset::io::Reader, _: &'a Self::Settings, load_context: &'a mut LoadContext<'_>, ) -> Result<Self::Asset, Self::Error> { } ``` Additionally, implementors of `AssetReader` that return a type implementing `futures_io::AsyncRead` and `AsyncSeek` might need to explicitly implement `bevy::asset::io::Reader` for that type. ```rust impl bevy::asset::io::Reader for MyAsyncReadAndSeek {} ```
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AssetLoader, ErasedLoadedAsset, LoadContext, LoadDirectError,
Added Method to Allow Pipelined Asset Loading (#10565) # Objective - Fixes #10518 ## Solution I've added a method to `LoadContext`, `load_direct_with_reader`, which mirrors the behaviour of `load_direct` with a single key difference: it is provided with the `Reader` by the caller, rather than getting it from the contained `AssetServer`. This allows for an `AssetLoader` to process its `Reader` stream, and then directly hand the results off to the `LoadContext` to handle further loading. The outer `AssetLoader` can control how the `Reader` is interpreted by providing a relevant `AssetPath`. For example, a Gzip decompression loader could process the asset `images/my_image.png.gz` by decompressing the bytes, then handing the decompressed result to the `LoadContext` with the new path `images/my_image.png.gz/my_image.png`. This intuitively reflects the nature of contained assets, whilst avoiding unintended behaviour, since the generated path cannot be a real file path (a file and folder of the same name cannot coexist in most file-systems). ```rust #[derive(Asset, TypePath)] pub struct GzAsset { pub uncompressed: ErasedLoadedAsset, } #[derive(Default)] pub struct GzAssetLoader; impl AssetLoader for GzAssetLoader { type Asset = GzAsset; type Settings = (); type Error = GzAssetLoaderError; fn load<'a>( &'a self, reader: &'a mut Reader, _settings: &'a (), load_context: &'a mut LoadContext, ) -> BoxedFuture<'a, Result<Self::Asset, Self::Error>> { Box::pin(async move { let compressed_path = load_context.path(); let file_name = compressed_path .file_name() .ok_or(GzAssetLoaderError::IndeterminateFilePath)? .to_string_lossy(); let uncompressed_file_name = file_name .strip_suffix(".gz") .ok_or(GzAssetLoaderError::IndeterminateFilePath)?; let contained_path = compressed_path.join(uncompressed_file_name); let mut bytes_compressed = Vec::new(); reader.read_to_end(&mut bytes_compressed).await?; let mut decoder = GzDecoder::new(bytes_compressed.as_slice()); let mut bytes_uncompressed = Vec::new(); decoder.read_to_end(&mut bytes_uncompressed)?; // Now that we have decompressed the asset, let's pass it back to the // context to continue loading let mut reader = VecReader::new(bytes_uncompressed); let uncompressed = load_context .load_direct_with_reader(&mut reader, contained_path) .await?; Ok(GzAsset { uncompressed }) }) } fn extensions(&self) -> &[&str] { &["gz"] } } ``` Because this example is so prudent, I've included an `asset_decompression` example which implements this exact behaviour: ```rust fn main() { App::new() .add_plugins(DefaultPlugins) .init_asset::<GzAsset>() .init_asset_loader::<GzAssetLoader>() .add_systems(Startup, setup) .add_systems(Update, decompress::<Image>) .run(); } fn setup(mut commands: Commands, asset_server: Res<AssetServer>) { commands.spawn(Camera2dBundle::default()); commands.spawn(( Compressed::<Image> { compressed: asset_server.load("data/compressed_image.png.gz"), ..default() }, Sprite::default(), TransformBundle::default(), VisibilityBundle::default(), )); } fn decompress<A: Asset>( mut commands: Commands, asset_server: Res<AssetServer>, mut compressed_assets: ResMut<Assets<GzAsset>>, query: Query<(Entity, &Compressed<A>)>, ) { for (entity, Compressed { compressed, .. }) in query.iter() { let Some(GzAsset { uncompressed }) = compressed_assets.remove(compressed) else { continue; }; let uncompressed = uncompressed.take::<A>().unwrap(); commands .entity(entity) .remove::<Compressed<A>>() .insert(asset_server.add(uncompressed)); } } ``` A key limitation to this design is how to type the internally loaded asset, since the example `GzAssetLoader` is unaware of the internal asset type `A`. As such, in this example I store the contained asset as an `ErasedLoadedAsset`, and leave it up to the consumer of the `GzAsset` to handle typing the final result, which is the purpose of the `decompress` system. This limitation can be worked around by providing type information to the `GzAssetLoader`, such as `GzAssetLoader<Image, ImageAssetLoader>`, but this would require registering the asset loader for every possible decompression target. Aside from this limitation, nested asset containerisation works as an end user would expect; if the user registers a `TarAssetLoader`, and a `GzAssetLoader`, then they can load assets with compound containerisation, such as `images.tar.gz`. --- ## Changelog - Added `LoadContext::load_direct_with_reader` - Added `asset_decompression` example ## Notes - While I believe my implementation of a Gzip asset loader is reasonable, I haven't included it as a public feature of `bevy_asset` to keep the scope of this PR as focussed as possible. - I have included `flate2` as a `dev-dependency` for the example; it is not included in the main dependency graph.
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},
prelude::*,
reflect::TypePath,
};
use flate2::read::GzDecoder;
use std::{io::prelude::*, marker::PhantomData};
Added Method to Allow Pipelined Asset Loading (#10565) # Objective - Fixes #10518 ## Solution I've added a method to `LoadContext`, `load_direct_with_reader`, which mirrors the behaviour of `load_direct` with a single key difference: it is provided with the `Reader` by the caller, rather than getting it from the contained `AssetServer`. This allows for an `AssetLoader` to process its `Reader` stream, and then directly hand the results off to the `LoadContext` to handle further loading. The outer `AssetLoader` can control how the `Reader` is interpreted by providing a relevant `AssetPath`. For example, a Gzip decompression loader could process the asset `images/my_image.png.gz` by decompressing the bytes, then handing the decompressed result to the `LoadContext` with the new path `images/my_image.png.gz/my_image.png`. This intuitively reflects the nature of contained assets, whilst avoiding unintended behaviour, since the generated path cannot be a real file path (a file and folder of the same name cannot coexist in most file-systems). ```rust #[derive(Asset, TypePath)] pub struct GzAsset { pub uncompressed: ErasedLoadedAsset, } #[derive(Default)] pub struct GzAssetLoader; impl AssetLoader for GzAssetLoader { type Asset = GzAsset; type Settings = (); type Error = GzAssetLoaderError; fn load<'a>( &'a self, reader: &'a mut Reader, _settings: &'a (), load_context: &'a mut LoadContext, ) -> BoxedFuture<'a, Result<Self::Asset, Self::Error>> { Box::pin(async move { let compressed_path = load_context.path(); let file_name = compressed_path .file_name() .ok_or(GzAssetLoaderError::IndeterminateFilePath)? .to_string_lossy(); let uncompressed_file_name = file_name .strip_suffix(".gz") .ok_or(GzAssetLoaderError::IndeterminateFilePath)?; let contained_path = compressed_path.join(uncompressed_file_name); let mut bytes_compressed = Vec::new(); reader.read_to_end(&mut bytes_compressed).await?; let mut decoder = GzDecoder::new(bytes_compressed.as_slice()); let mut bytes_uncompressed = Vec::new(); decoder.read_to_end(&mut bytes_uncompressed)?; // Now that we have decompressed the asset, let's pass it back to the // context to continue loading let mut reader = VecReader::new(bytes_uncompressed); let uncompressed = load_context .load_direct_with_reader(&mut reader, contained_path) .await?; Ok(GzAsset { uncompressed }) }) } fn extensions(&self) -> &[&str] { &["gz"] } } ``` Because this example is so prudent, I've included an `asset_decompression` example which implements this exact behaviour: ```rust fn main() { App::new() .add_plugins(DefaultPlugins) .init_asset::<GzAsset>() .init_asset_loader::<GzAssetLoader>() .add_systems(Startup, setup) .add_systems(Update, decompress::<Image>) .run(); } fn setup(mut commands: Commands, asset_server: Res<AssetServer>) { commands.spawn(Camera2dBundle::default()); commands.spawn(( Compressed::<Image> { compressed: asset_server.load("data/compressed_image.png.gz"), ..default() }, Sprite::default(), TransformBundle::default(), VisibilityBundle::default(), )); } fn decompress<A: Asset>( mut commands: Commands, asset_server: Res<AssetServer>, mut compressed_assets: ResMut<Assets<GzAsset>>, query: Query<(Entity, &Compressed<A>)>, ) { for (entity, Compressed { compressed, .. }) in query.iter() { let Some(GzAsset { uncompressed }) = compressed_assets.remove(compressed) else { continue; }; let uncompressed = uncompressed.take::<A>().unwrap(); commands .entity(entity) .remove::<Compressed<A>>() .insert(asset_server.add(uncompressed)); } } ``` A key limitation to this design is how to type the internally loaded asset, since the example `GzAssetLoader` is unaware of the internal asset type `A`. As such, in this example I store the contained asset as an `ErasedLoadedAsset`, and leave it up to the consumer of the `GzAsset` to handle typing the final result, which is the purpose of the `decompress` system. This limitation can be worked around by providing type information to the `GzAssetLoader`, such as `GzAssetLoader<Image, ImageAssetLoader>`, but this would require registering the asset loader for every possible decompression target. Aside from this limitation, nested asset containerisation works as an end user would expect; if the user registers a `TarAssetLoader`, and a `GzAssetLoader`, then they can load assets with compound containerisation, such as `images.tar.gz`. --- ## Changelog - Added `LoadContext::load_direct_with_reader` - Added `asset_decompression` example ## Notes - While I believe my implementation of a Gzip asset loader is reasonable, I haven't included it as a public feature of `bevy_asset` to keep the scope of this PR as focussed as possible. - I have included `flate2` as a `dev-dependency` for the example; it is not included in the main dependency graph.
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use thiserror::Error;
#[derive(Asset, TypePath)]
struct GzAsset {
uncompressed: ErasedLoadedAsset,
Added Method to Allow Pipelined Asset Loading (#10565) # Objective - Fixes #10518 ## Solution I've added a method to `LoadContext`, `load_direct_with_reader`, which mirrors the behaviour of `load_direct` with a single key difference: it is provided with the `Reader` by the caller, rather than getting it from the contained `AssetServer`. This allows for an `AssetLoader` to process its `Reader` stream, and then directly hand the results off to the `LoadContext` to handle further loading. The outer `AssetLoader` can control how the `Reader` is interpreted by providing a relevant `AssetPath`. For example, a Gzip decompression loader could process the asset `images/my_image.png.gz` by decompressing the bytes, then handing the decompressed result to the `LoadContext` with the new path `images/my_image.png.gz/my_image.png`. This intuitively reflects the nature of contained assets, whilst avoiding unintended behaviour, since the generated path cannot be a real file path (a file and folder of the same name cannot coexist in most file-systems). ```rust #[derive(Asset, TypePath)] pub struct GzAsset { pub uncompressed: ErasedLoadedAsset, } #[derive(Default)] pub struct GzAssetLoader; impl AssetLoader for GzAssetLoader { type Asset = GzAsset; type Settings = (); type Error = GzAssetLoaderError; fn load<'a>( &'a self, reader: &'a mut Reader, _settings: &'a (), load_context: &'a mut LoadContext, ) -> BoxedFuture<'a, Result<Self::Asset, Self::Error>> { Box::pin(async move { let compressed_path = load_context.path(); let file_name = compressed_path .file_name() .ok_or(GzAssetLoaderError::IndeterminateFilePath)? .to_string_lossy(); let uncompressed_file_name = file_name .strip_suffix(".gz") .ok_or(GzAssetLoaderError::IndeterminateFilePath)?; let contained_path = compressed_path.join(uncompressed_file_name); let mut bytes_compressed = Vec::new(); reader.read_to_end(&mut bytes_compressed).await?; let mut decoder = GzDecoder::new(bytes_compressed.as_slice()); let mut bytes_uncompressed = Vec::new(); decoder.read_to_end(&mut bytes_uncompressed)?; // Now that we have decompressed the asset, let's pass it back to the // context to continue loading let mut reader = VecReader::new(bytes_uncompressed); let uncompressed = load_context .load_direct_with_reader(&mut reader, contained_path) .await?; Ok(GzAsset { uncompressed }) }) } fn extensions(&self) -> &[&str] { &["gz"] } } ``` Because this example is so prudent, I've included an `asset_decompression` example which implements this exact behaviour: ```rust fn main() { App::new() .add_plugins(DefaultPlugins) .init_asset::<GzAsset>() .init_asset_loader::<GzAssetLoader>() .add_systems(Startup, setup) .add_systems(Update, decompress::<Image>) .run(); } fn setup(mut commands: Commands, asset_server: Res<AssetServer>) { commands.spawn(Camera2dBundle::default()); commands.spawn(( Compressed::<Image> { compressed: asset_server.load("data/compressed_image.png.gz"), ..default() }, Sprite::default(), TransformBundle::default(), VisibilityBundle::default(), )); } fn decompress<A: Asset>( mut commands: Commands, asset_server: Res<AssetServer>, mut compressed_assets: ResMut<Assets<GzAsset>>, query: Query<(Entity, &Compressed<A>)>, ) { for (entity, Compressed { compressed, .. }) in query.iter() { let Some(GzAsset { uncompressed }) = compressed_assets.remove(compressed) else { continue; }; let uncompressed = uncompressed.take::<A>().unwrap(); commands .entity(entity) .remove::<Compressed<A>>() .insert(asset_server.add(uncompressed)); } } ``` A key limitation to this design is how to type the internally loaded asset, since the example `GzAssetLoader` is unaware of the internal asset type `A`. As such, in this example I store the contained asset as an `ErasedLoadedAsset`, and leave it up to the consumer of the `GzAsset` to handle typing the final result, which is the purpose of the `decompress` system. This limitation can be worked around by providing type information to the `GzAssetLoader`, such as `GzAssetLoader<Image, ImageAssetLoader>`, but this would require registering the asset loader for every possible decompression target. Aside from this limitation, nested asset containerisation works as an end user would expect; if the user registers a `TarAssetLoader`, and a `GzAssetLoader`, then they can load assets with compound containerisation, such as `images.tar.gz`. --- ## Changelog - Added `LoadContext::load_direct_with_reader` - Added `asset_decompression` example ## Notes - While I believe my implementation of a Gzip asset loader is reasonable, I haven't included it as a public feature of `bevy_asset` to keep the scope of this PR as focussed as possible. - I have included `flate2` as a `dev-dependency` for the example; it is not included in the main dependency graph.
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}
#[derive(Default)]
struct GzAssetLoader;
Added Method to Allow Pipelined Asset Loading (#10565) # Objective - Fixes #10518 ## Solution I've added a method to `LoadContext`, `load_direct_with_reader`, which mirrors the behaviour of `load_direct` with a single key difference: it is provided with the `Reader` by the caller, rather than getting it from the contained `AssetServer`. This allows for an `AssetLoader` to process its `Reader` stream, and then directly hand the results off to the `LoadContext` to handle further loading. The outer `AssetLoader` can control how the `Reader` is interpreted by providing a relevant `AssetPath`. For example, a Gzip decompression loader could process the asset `images/my_image.png.gz` by decompressing the bytes, then handing the decompressed result to the `LoadContext` with the new path `images/my_image.png.gz/my_image.png`. This intuitively reflects the nature of contained assets, whilst avoiding unintended behaviour, since the generated path cannot be a real file path (a file and folder of the same name cannot coexist in most file-systems). ```rust #[derive(Asset, TypePath)] pub struct GzAsset { pub uncompressed: ErasedLoadedAsset, } #[derive(Default)] pub struct GzAssetLoader; impl AssetLoader for GzAssetLoader { type Asset = GzAsset; type Settings = (); type Error = GzAssetLoaderError; fn load<'a>( &'a self, reader: &'a mut Reader, _settings: &'a (), load_context: &'a mut LoadContext, ) -> BoxedFuture<'a, Result<Self::Asset, Self::Error>> { Box::pin(async move { let compressed_path = load_context.path(); let file_name = compressed_path .file_name() .ok_or(GzAssetLoaderError::IndeterminateFilePath)? .to_string_lossy(); let uncompressed_file_name = file_name .strip_suffix(".gz") .ok_or(GzAssetLoaderError::IndeterminateFilePath)?; let contained_path = compressed_path.join(uncompressed_file_name); let mut bytes_compressed = Vec::new(); reader.read_to_end(&mut bytes_compressed).await?; let mut decoder = GzDecoder::new(bytes_compressed.as_slice()); let mut bytes_uncompressed = Vec::new(); decoder.read_to_end(&mut bytes_uncompressed)?; // Now that we have decompressed the asset, let's pass it back to the // context to continue loading let mut reader = VecReader::new(bytes_uncompressed); let uncompressed = load_context .load_direct_with_reader(&mut reader, contained_path) .await?; Ok(GzAsset { uncompressed }) }) } fn extensions(&self) -> &[&str] { &["gz"] } } ``` Because this example is so prudent, I've included an `asset_decompression` example which implements this exact behaviour: ```rust fn main() { App::new() .add_plugins(DefaultPlugins) .init_asset::<GzAsset>() .init_asset_loader::<GzAssetLoader>() .add_systems(Startup, setup) .add_systems(Update, decompress::<Image>) .run(); } fn setup(mut commands: Commands, asset_server: Res<AssetServer>) { commands.spawn(Camera2dBundle::default()); commands.spawn(( Compressed::<Image> { compressed: asset_server.load("data/compressed_image.png.gz"), ..default() }, Sprite::default(), TransformBundle::default(), VisibilityBundle::default(), )); } fn decompress<A: Asset>( mut commands: Commands, asset_server: Res<AssetServer>, mut compressed_assets: ResMut<Assets<GzAsset>>, query: Query<(Entity, &Compressed<A>)>, ) { for (entity, Compressed { compressed, .. }) in query.iter() { let Some(GzAsset { uncompressed }) = compressed_assets.remove(compressed) else { continue; }; let uncompressed = uncompressed.take::<A>().unwrap(); commands .entity(entity) .remove::<Compressed<A>>() .insert(asset_server.add(uncompressed)); } } ``` A key limitation to this design is how to type the internally loaded asset, since the example `GzAssetLoader` is unaware of the internal asset type `A`. As such, in this example I store the contained asset as an `ErasedLoadedAsset`, and leave it up to the consumer of the `GzAsset` to handle typing the final result, which is the purpose of the `decompress` system. This limitation can be worked around by providing type information to the `GzAssetLoader`, such as `GzAssetLoader<Image, ImageAssetLoader>`, but this would require registering the asset loader for every possible decompression target. Aside from this limitation, nested asset containerisation works as an end user would expect; if the user registers a `TarAssetLoader`, and a `GzAssetLoader`, then they can load assets with compound containerisation, such as `images.tar.gz`. --- ## Changelog - Added `LoadContext::load_direct_with_reader` - Added `asset_decompression` example ## Notes - While I believe my implementation of a Gzip asset loader is reasonable, I haven't included it as a public feature of `bevy_asset` to keep the scope of this PR as focussed as possible. - I have included `flate2` as a `dev-dependency` for the example; it is not included in the main dependency graph.
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/// Possible errors that can be produced by [`GzAssetLoader`]
#[non_exhaustive]
#[derive(Debug, Error)]
Fix some doc warnings (#12961) # Objective - Fix some doc warnings - Add doc-scrape-examples to all examples Moved from #12692 I run `cargo +nightly doc --workspace --all-features --no-deps -Zunstable-options -Zrustdoc-scrape-examples` <details> ``` warning: public documentation for `GzAssetLoaderError` links to private item `GzAssetLoader` --> examples/asset/asset_decompression.rs:24:47 | 24 | /// Possible errors that can be produced by [`GzAssetLoader`] | ^^^^^^^^^^^^^ this item is private | = note: this link will resolve properly if you pass `--document-private-items` = note: `#[warn(rustdoc::private_intra_doc_links)]` on by default warning: `bevy` (example "asset_decompression") generated 1 warning warning: unresolved link to `shape::Quad` --> examples/2d/mesh2d.rs:3:15 | 3 | //! [`Quad`]: shape::Quad | ^^^^^^^^^^^ no item named `shape` in scope | = note: `#[warn(rustdoc::broken_intra_doc_links)]` on by default warning: `bevy` (example "mesh2d") generated 1 warning warning: unresolved link to `WorldQuery` --> examples/ecs/custom_query_param.rs:1:49 | 1 | //! This example illustrates the usage of the [`WorldQuery`] derive macro, which allows | ^^^^^^^^^^ no item named `WorldQuery` in scope | = help: to escape `[` and `]` characters, add '\' before them like `\[` or `\]` = note: `#[warn(rustdoc::broken_intra_doc_links)]` on by default warning: `bevy` (example "custom_query_param") generated 1 warning warning: unresolved link to `shape::Quad` --> examples/2d/mesh2d_vertex_color_texture.rs:4:15 | 4 | //! [`Quad`]: shape::Quad | ^^^^^^^^^^^ no item named `shape` in scope | = note: `#[warn(rustdoc::broken_intra_doc_links)]` on by default warning: `bevy` (example "mesh2d_vertex_color_texture") generated 1 warning warning: public documentation for `TextPlugin` links to private item `CoolText` --> examples/asset/processing/asset_processing.rs:48:9 | 48 | /// * [`CoolText`]: a custom RON text format that supports dependencies and embedded dependencies | ^^^^^^^^ this item is private | = note: this link will resolve properly if you pass `--document-private-items` = note: `#[warn(rustdoc::private_intra_doc_links)]` on by default warning: public documentation for `TextPlugin` links to private item `Text` --> examples/asset/processing/asset_processing.rs:49:9 | 49 | /// * [`Text`]: a "normal" plain text file | ^^^^ this item is private | = note: this link will resolve properly if you pass `--document-private-items` warning: public documentation for `TextPlugin` links to private item `CoolText` --> examples/asset/processing/asset_processing.rs:51:57 | 51 | /// It also defines an asset processor that will load [`CoolText`], resolve embedded dependenc... | ^^^^^^^^ this item is private | = note: this link will resolve properly if you pass `--document-private-items` warning: `bevy` (example "asset_processing") generated 3 warnings warning: public documentation for `CustomAssetLoaderError` links to private item `CustomAssetLoader` --> examples/asset/custom_asset.rs:20:47 | 20 | /// Possible errors that can be produced by [`CustomAssetLoader`] | ^^^^^^^^^^^^^^^^^ this item is private | = note: this link will resolve properly if you pass `--document-private-items` = note: `#[warn(rustdoc::private_intra_doc_links)]` on by default warning: public documentation for `BlobAssetLoaderError` links to private item `CustomAssetLoader` --> examples/asset/custom_asset.rs:61:47 | 61 | /// Possible errors that can be produced by [`CustomAssetLoader`] | ^^^^^^^^^^^^^^^^^ this item is private | = note: this link will resolve properly if you pass `--document-private-items` ``` ``` warning: `bevy` (example "mesh2d") generated 1 warning warning: public documentation for `log_layers_ecs` links to private item `update_subscriber` --> examples/app/log_layers_ecs.rs:6:18 | 6 | //! Inside the [`update_subscriber`] function we will create a [`mpsc::Sender`] and a [`mpsc::R... | ^^^^^^^^^^^^^^^^^ this item is private | = note: this link will resolve properly if you pass `--document-private-items` = note: `#[warn(rustdoc::private_intra_doc_links)]` on by default warning: unresolved link to `AdvancedLayer` --> examples/app/log_layers_ecs.rs:7:72 | 7 | ... will go into the [`AdvancedLayer`] and the [`Receiver`](mpsc::Receiver) will | ^^^^^^^^^^^^^ no item named `AdvancedLayer` in scope | = help: to escape `[` and `]` characters, add '\' before them like `\[` or `\]` = note: `#[warn(rustdoc::broken_intra_doc_links)]` on by default warning: unresolved link to `LogEvents` --> examples/app/log_layers_ecs.rs:8:42 | 8 | //! go into a non-send resource called [`LogEvents`] (It has to be non-send because [`Receiver`... | ^^^^^^^^^ no item named `LogEvents` in scope | = help: to escape `[` and `]` characters, add '\' before them like `\[` or `\]` warning: public documentation for `log_layers_ecs` links to private item `transfer_log_events` --> examples/app/log_layers_ecs.rs:9:30 | 9 | //! From there we will use [`transfer_log_events`] to transfer log events from [`LogEvents`] to... | ^^^^^^^^^^^^^^^^^^^ this item is private | = note: this link will resolve properly if you pass `--document-private-items` warning: unresolved link to `LogEvents` --> examples/app/log_layers_ecs.rs:9:82 | 9 | ...nsfer log events from [`LogEvents`] to an ECS event called [`LogEvent`]. | ^^^^^^^^^ no item named `LogEvents` in scope | = help: to escape `[` and `]` characters, add '\' before them like `\[` or `\]` warning: public documentation for `log_layers_ecs` links to private item `LogEvent` --> examples/app/log_layers_ecs.rs:9:119 | 9 | ...nts`] to an ECS event called [`LogEvent`]. | ^^^^^^^^ this item is private | = note: this link will resolve properly if you pass `--document-private-items` warning: public documentation for `log_layers_ecs` links to private item `LogEvent` --> examples/app/log_layers_ecs.rs:11:49 | 11 | //! Finally, after all that we can access the [`LogEvent`] event from our systems and use it. | ^^^^^^^^ this item is private | = note: this link will resolve properly if you pass `--document-private-items` ``` <details/>
2024-04-14 15:23:44 +00:00
enum GzAssetLoaderError {
Added Method to Allow Pipelined Asset Loading (#10565) # Objective - Fixes #10518 ## Solution I've added a method to `LoadContext`, `load_direct_with_reader`, which mirrors the behaviour of `load_direct` with a single key difference: it is provided with the `Reader` by the caller, rather than getting it from the contained `AssetServer`. This allows for an `AssetLoader` to process its `Reader` stream, and then directly hand the results off to the `LoadContext` to handle further loading. The outer `AssetLoader` can control how the `Reader` is interpreted by providing a relevant `AssetPath`. For example, a Gzip decompression loader could process the asset `images/my_image.png.gz` by decompressing the bytes, then handing the decompressed result to the `LoadContext` with the new path `images/my_image.png.gz/my_image.png`. This intuitively reflects the nature of contained assets, whilst avoiding unintended behaviour, since the generated path cannot be a real file path (a file and folder of the same name cannot coexist in most file-systems). ```rust #[derive(Asset, TypePath)] pub struct GzAsset { pub uncompressed: ErasedLoadedAsset, } #[derive(Default)] pub struct GzAssetLoader; impl AssetLoader for GzAssetLoader { type Asset = GzAsset; type Settings = (); type Error = GzAssetLoaderError; fn load<'a>( &'a self, reader: &'a mut Reader, _settings: &'a (), load_context: &'a mut LoadContext, ) -> BoxedFuture<'a, Result<Self::Asset, Self::Error>> { Box::pin(async move { let compressed_path = load_context.path(); let file_name = compressed_path .file_name() .ok_or(GzAssetLoaderError::IndeterminateFilePath)? .to_string_lossy(); let uncompressed_file_name = file_name .strip_suffix(".gz") .ok_or(GzAssetLoaderError::IndeterminateFilePath)?; let contained_path = compressed_path.join(uncompressed_file_name); let mut bytes_compressed = Vec::new(); reader.read_to_end(&mut bytes_compressed).await?; let mut decoder = GzDecoder::new(bytes_compressed.as_slice()); let mut bytes_uncompressed = Vec::new(); decoder.read_to_end(&mut bytes_uncompressed)?; // Now that we have decompressed the asset, let's pass it back to the // context to continue loading let mut reader = VecReader::new(bytes_uncompressed); let uncompressed = load_context .load_direct_with_reader(&mut reader, contained_path) .await?; Ok(GzAsset { uncompressed }) }) } fn extensions(&self) -> &[&str] { &["gz"] } } ``` Because this example is so prudent, I've included an `asset_decompression` example which implements this exact behaviour: ```rust fn main() { App::new() .add_plugins(DefaultPlugins) .init_asset::<GzAsset>() .init_asset_loader::<GzAssetLoader>() .add_systems(Startup, setup) .add_systems(Update, decompress::<Image>) .run(); } fn setup(mut commands: Commands, asset_server: Res<AssetServer>) { commands.spawn(Camera2dBundle::default()); commands.spawn(( Compressed::<Image> { compressed: asset_server.load("data/compressed_image.png.gz"), ..default() }, Sprite::default(), TransformBundle::default(), VisibilityBundle::default(), )); } fn decompress<A: Asset>( mut commands: Commands, asset_server: Res<AssetServer>, mut compressed_assets: ResMut<Assets<GzAsset>>, query: Query<(Entity, &Compressed<A>)>, ) { for (entity, Compressed { compressed, .. }) in query.iter() { let Some(GzAsset { uncompressed }) = compressed_assets.remove(compressed) else { continue; }; let uncompressed = uncompressed.take::<A>().unwrap(); commands .entity(entity) .remove::<Compressed<A>>() .insert(asset_server.add(uncompressed)); } } ``` A key limitation to this design is how to type the internally loaded asset, since the example `GzAssetLoader` is unaware of the internal asset type `A`. As such, in this example I store the contained asset as an `ErasedLoadedAsset`, and leave it up to the consumer of the `GzAsset` to handle typing the final result, which is the purpose of the `decompress` system. This limitation can be worked around by providing type information to the `GzAssetLoader`, such as `GzAssetLoader<Image, ImageAssetLoader>`, but this would require registering the asset loader for every possible decompression target. Aside from this limitation, nested asset containerisation works as an end user would expect; if the user registers a `TarAssetLoader`, and a `GzAssetLoader`, then they can load assets with compound containerisation, such as `images.tar.gz`. --- ## Changelog - Added `LoadContext::load_direct_with_reader` - Added `asset_decompression` example ## Notes - While I believe my implementation of a Gzip asset loader is reasonable, I haven't included it as a public feature of `bevy_asset` to keep the scope of this PR as focussed as possible. - I have included `flate2` as a `dev-dependency` for the example; it is not included in the main dependency graph.
2023-11-16 17:47:31 +00:00
/// An [IO](std::io) Error
#[error("Could not load asset: {0}")]
Io(#[from] std::io::Error),
/// An error caused when the asset path cannot be used to determine the uncompressed asset type.
Added Method to Allow Pipelined Asset Loading (#10565) # Objective - Fixes #10518 ## Solution I've added a method to `LoadContext`, `load_direct_with_reader`, which mirrors the behaviour of `load_direct` with a single key difference: it is provided with the `Reader` by the caller, rather than getting it from the contained `AssetServer`. This allows for an `AssetLoader` to process its `Reader` stream, and then directly hand the results off to the `LoadContext` to handle further loading. The outer `AssetLoader` can control how the `Reader` is interpreted by providing a relevant `AssetPath`. For example, a Gzip decompression loader could process the asset `images/my_image.png.gz` by decompressing the bytes, then handing the decompressed result to the `LoadContext` with the new path `images/my_image.png.gz/my_image.png`. This intuitively reflects the nature of contained assets, whilst avoiding unintended behaviour, since the generated path cannot be a real file path (a file and folder of the same name cannot coexist in most file-systems). ```rust #[derive(Asset, TypePath)] pub struct GzAsset { pub uncompressed: ErasedLoadedAsset, } #[derive(Default)] pub struct GzAssetLoader; impl AssetLoader for GzAssetLoader { type Asset = GzAsset; type Settings = (); type Error = GzAssetLoaderError; fn load<'a>( &'a self, reader: &'a mut Reader, _settings: &'a (), load_context: &'a mut LoadContext, ) -> BoxedFuture<'a, Result<Self::Asset, Self::Error>> { Box::pin(async move { let compressed_path = load_context.path(); let file_name = compressed_path .file_name() .ok_or(GzAssetLoaderError::IndeterminateFilePath)? .to_string_lossy(); let uncompressed_file_name = file_name .strip_suffix(".gz") .ok_or(GzAssetLoaderError::IndeterminateFilePath)?; let contained_path = compressed_path.join(uncompressed_file_name); let mut bytes_compressed = Vec::new(); reader.read_to_end(&mut bytes_compressed).await?; let mut decoder = GzDecoder::new(bytes_compressed.as_slice()); let mut bytes_uncompressed = Vec::new(); decoder.read_to_end(&mut bytes_uncompressed)?; // Now that we have decompressed the asset, let's pass it back to the // context to continue loading let mut reader = VecReader::new(bytes_uncompressed); let uncompressed = load_context .load_direct_with_reader(&mut reader, contained_path) .await?; Ok(GzAsset { uncompressed }) }) } fn extensions(&self) -> &[&str] { &["gz"] } } ``` Because this example is so prudent, I've included an `asset_decompression` example which implements this exact behaviour: ```rust fn main() { App::new() .add_plugins(DefaultPlugins) .init_asset::<GzAsset>() .init_asset_loader::<GzAssetLoader>() .add_systems(Startup, setup) .add_systems(Update, decompress::<Image>) .run(); } fn setup(mut commands: Commands, asset_server: Res<AssetServer>) { commands.spawn(Camera2dBundle::default()); commands.spawn(( Compressed::<Image> { compressed: asset_server.load("data/compressed_image.png.gz"), ..default() }, Sprite::default(), TransformBundle::default(), VisibilityBundle::default(), )); } fn decompress<A: Asset>( mut commands: Commands, asset_server: Res<AssetServer>, mut compressed_assets: ResMut<Assets<GzAsset>>, query: Query<(Entity, &Compressed<A>)>, ) { for (entity, Compressed { compressed, .. }) in query.iter() { let Some(GzAsset { uncompressed }) = compressed_assets.remove(compressed) else { continue; }; let uncompressed = uncompressed.take::<A>().unwrap(); commands .entity(entity) .remove::<Compressed<A>>() .insert(asset_server.add(uncompressed)); } } ``` A key limitation to this design is how to type the internally loaded asset, since the example `GzAssetLoader` is unaware of the internal asset type `A`. As such, in this example I store the contained asset as an `ErasedLoadedAsset`, and leave it up to the consumer of the `GzAsset` to handle typing the final result, which is the purpose of the `decompress` system. This limitation can be worked around by providing type information to the `GzAssetLoader`, such as `GzAssetLoader<Image, ImageAssetLoader>`, but this would require registering the asset loader for every possible decompression target. Aside from this limitation, nested asset containerisation works as an end user would expect; if the user registers a `TarAssetLoader`, and a `GzAssetLoader`, then they can load assets with compound containerisation, such as `images.tar.gz`. --- ## Changelog - Added `LoadContext::load_direct_with_reader` - Added `asset_decompression` example ## Notes - While I believe my implementation of a Gzip asset loader is reasonable, I haven't included it as a public feature of `bevy_asset` to keep the scope of this PR as focussed as possible. - I have included `flate2` as a `dev-dependency` for the example; it is not included in the main dependency graph.
2023-11-16 17:47:31 +00:00
#[error("Could not determine file path of uncompressed asset")]
IndeterminateFilePath,
/// An error caused by the internal asset loader.
#[error("Could not load contained asset: {0}")]
LoadDirectError(#[from] LoadDirectError),
}
impl AssetLoader for GzAssetLoader {
type Asset = GzAsset;
type Settings = ();
type Error = GzAssetLoaderError;
async fn load(
&self,
reader: &mut dyn Reader,
_settings: &(),
load_context: &mut LoadContext<'_>,
Use async-fn in traits rather than BoxedFuture (#12550) # Objective Simplify implementing some asset traits without Box::pin(async move{}) shenanigans. Fixes (in part) https://github.com/bevyengine/bevy/issues/11308 ## Solution Use async-fn in traits when possible in all traits. Traits with return position impl trait are not object safe however, and as AssetReader and AssetWriter are both used with dynamic dispatch, you need a Boxed version of these futures anyway. In the future, Rust is [adding ](https://blog.rust-lang.org/2023/12/21/async-fn-rpit-in-traits.html)proc macros to generate these traits automatically, and at some point in the future dyn traits should 'just work'. Until then.... this seemed liked the right approach given more ErasedXXX already exist, but, no clue if there's plans here! Especially since these are public now, it's a bit of an unfortunate API, and means this is a breaking change. In theory this saves some performance when these traits are used with static dispatch, but, seems like most code paths go through dynamic dispatch, which boxes anyway. I also suspect a bunch of the lifetime annotations on these function could be simplified now as the BoxedFuture was often the only thing returned which needed a lifetime annotation, but I'm not touching that for now as traits + lifetimes can be so tricky. This is a revival of [pull/11362](https://github.com/bevyengine/bevy/pull/11362) after a spectacular merge f*ckup, with updates to the latest Bevy. Just to recap some discussion: - Overall this seems like a win for code quality, especially when implementing these traits, but a loss for having to deal with ErasedXXX variants. - `ConditionalSend` was the preferred name for the trait that might be Send, to deal with wasm platforms. - When reviewing be sure to disable whitespace difference, as that's 95% of the PR. ## Changelog - AssetReader, AssetWriter, AssetLoader, AssetSaver and Process now use async-fn in traits rather than boxed futures. ## Migration Guide - Custom implementations of AssetReader, AssetWriter, AssetLoader, AssetSaver and Process should switch to async fn rather than returning a bevy_utils::BoxedFuture. - Simultaniously, to use dynamic dispatch on these traits you should instead use dyn ErasedXXX.
2024-03-18 17:56:57 +00:00
) -> Result<Self::Asset, Self::Error> {
let compressed_path = load_context.path();
let file_name = compressed_path
.file_name()
.ok_or(GzAssetLoaderError::IndeterminateFilePath)?
.to_string_lossy();
let uncompressed_file_name = file_name
.strip_suffix(".gz")
.ok_or(GzAssetLoaderError::IndeterminateFilePath)?;
let contained_path = compressed_path.join(uncompressed_file_name);
Added Method to Allow Pipelined Asset Loading (#10565) # Objective - Fixes #10518 ## Solution I've added a method to `LoadContext`, `load_direct_with_reader`, which mirrors the behaviour of `load_direct` with a single key difference: it is provided with the `Reader` by the caller, rather than getting it from the contained `AssetServer`. This allows for an `AssetLoader` to process its `Reader` stream, and then directly hand the results off to the `LoadContext` to handle further loading. The outer `AssetLoader` can control how the `Reader` is interpreted by providing a relevant `AssetPath`. For example, a Gzip decompression loader could process the asset `images/my_image.png.gz` by decompressing the bytes, then handing the decompressed result to the `LoadContext` with the new path `images/my_image.png.gz/my_image.png`. This intuitively reflects the nature of contained assets, whilst avoiding unintended behaviour, since the generated path cannot be a real file path (a file and folder of the same name cannot coexist in most file-systems). ```rust #[derive(Asset, TypePath)] pub struct GzAsset { pub uncompressed: ErasedLoadedAsset, } #[derive(Default)] pub struct GzAssetLoader; impl AssetLoader for GzAssetLoader { type Asset = GzAsset; type Settings = (); type Error = GzAssetLoaderError; fn load<'a>( &'a self, reader: &'a mut Reader, _settings: &'a (), load_context: &'a mut LoadContext, ) -> BoxedFuture<'a, Result<Self::Asset, Self::Error>> { Box::pin(async move { let compressed_path = load_context.path(); let file_name = compressed_path .file_name() .ok_or(GzAssetLoaderError::IndeterminateFilePath)? .to_string_lossy(); let uncompressed_file_name = file_name .strip_suffix(".gz") .ok_or(GzAssetLoaderError::IndeterminateFilePath)?; let contained_path = compressed_path.join(uncompressed_file_name); let mut bytes_compressed = Vec::new(); reader.read_to_end(&mut bytes_compressed).await?; let mut decoder = GzDecoder::new(bytes_compressed.as_slice()); let mut bytes_uncompressed = Vec::new(); decoder.read_to_end(&mut bytes_uncompressed)?; // Now that we have decompressed the asset, let's pass it back to the // context to continue loading let mut reader = VecReader::new(bytes_uncompressed); let uncompressed = load_context .load_direct_with_reader(&mut reader, contained_path) .await?; Ok(GzAsset { uncompressed }) }) } fn extensions(&self) -> &[&str] { &["gz"] } } ``` Because this example is so prudent, I've included an `asset_decompression` example which implements this exact behaviour: ```rust fn main() { App::new() .add_plugins(DefaultPlugins) .init_asset::<GzAsset>() .init_asset_loader::<GzAssetLoader>() .add_systems(Startup, setup) .add_systems(Update, decompress::<Image>) .run(); } fn setup(mut commands: Commands, asset_server: Res<AssetServer>) { commands.spawn(Camera2dBundle::default()); commands.spawn(( Compressed::<Image> { compressed: asset_server.load("data/compressed_image.png.gz"), ..default() }, Sprite::default(), TransformBundle::default(), VisibilityBundle::default(), )); } fn decompress<A: Asset>( mut commands: Commands, asset_server: Res<AssetServer>, mut compressed_assets: ResMut<Assets<GzAsset>>, query: Query<(Entity, &Compressed<A>)>, ) { for (entity, Compressed { compressed, .. }) in query.iter() { let Some(GzAsset { uncompressed }) = compressed_assets.remove(compressed) else { continue; }; let uncompressed = uncompressed.take::<A>().unwrap(); commands .entity(entity) .remove::<Compressed<A>>() .insert(asset_server.add(uncompressed)); } } ``` A key limitation to this design is how to type the internally loaded asset, since the example `GzAssetLoader` is unaware of the internal asset type `A`. As such, in this example I store the contained asset as an `ErasedLoadedAsset`, and leave it up to the consumer of the `GzAsset` to handle typing the final result, which is the purpose of the `decompress` system. This limitation can be worked around by providing type information to the `GzAssetLoader`, such as `GzAssetLoader<Image, ImageAssetLoader>`, but this would require registering the asset loader for every possible decompression target. Aside from this limitation, nested asset containerisation works as an end user would expect; if the user registers a `TarAssetLoader`, and a `GzAssetLoader`, then they can load assets with compound containerisation, such as `images.tar.gz`. --- ## Changelog - Added `LoadContext::load_direct_with_reader` - Added `asset_decompression` example ## Notes - While I believe my implementation of a Gzip asset loader is reasonable, I haven't included it as a public feature of `bevy_asset` to keep the scope of this PR as focussed as possible. - I have included `flate2` as a `dev-dependency` for the example; it is not included in the main dependency graph.
2023-11-16 17:47:31 +00:00
Use async-fn in traits rather than BoxedFuture (#12550) # Objective Simplify implementing some asset traits without Box::pin(async move{}) shenanigans. Fixes (in part) https://github.com/bevyengine/bevy/issues/11308 ## Solution Use async-fn in traits when possible in all traits. Traits with return position impl trait are not object safe however, and as AssetReader and AssetWriter are both used with dynamic dispatch, you need a Boxed version of these futures anyway. In the future, Rust is [adding ](https://blog.rust-lang.org/2023/12/21/async-fn-rpit-in-traits.html)proc macros to generate these traits automatically, and at some point in the future dyn traits should 'just work'. Until then.... this seemed liked the right approach given more ErasedXXX already exist, but, no clue if there's plans here! Especially since these are public now, it's a bit of an unfortunate API, and means this is a breaking change. In theory this saves some performance when these traits are used with static dispatch, but, seems like most code paths go through dynamic dispatch, which boxes anyway. I also suspect a bunch of the lifetime annotations on these function could be simplified now as the BoxedFuture was often the only thing returned which needed a lifetime annotation, but I'm not touching that for now as traits + lifetimes can be so tricky. This is a revival of [pull/11362](https://github.com/bevyengine/bevy/pull/11362) after a spectacular merge f*ckup, with updates to the latest Bevy. Just to recap some discussion: - Overall this seems like a win for code quality, especially when implementing these traits, but a loss for having to deal with ErasedXXX variants. - `ConditionalSend` was the preferred name for the trait that might be Send, to deal with wasm platforms. - When reviewing be sure to disable whitespace difference, as that's 95% of the PR. ## Changelog - AssetReader, AssetWriter, AssetLoader, AssetSaver and Process now use async-fn in traits rather than boxed futures. ## Migration Guide - Custom implementations of AssetReader, AssetWriter, AssetLoader, AssetSaver and Process should switch to async fn rather than returning a bevy_utils::BoxedFuture. - Simultaniously, to use dynamic dispatch on these traits you should instead use dyn ErasedXXX.
2024-03-18 17:56:57 +00:00
let mut bytes_compressed = Vec::new();
Added Method to Allow Pipelined Asset Loading (#10565) # Objective - Fixes #10518 ## Solution I've added a method to `LoadContext`, `load_direct_with_reader`, which mirrors the behaviour of `load_direct` with a single key difference: it is provided with the `Reader` by the caller, rather than getting it from the contained `AssetServer`. This allows for an `AssetLoader` to process its `Reader` stream, and then directly hand the results off to the `LoadContext` to handle further loading. The outer `AssetLoader` can control how the `Reader` is interpreted by providing a relevant `AssetPath`. For example, a Gzip decompression loader could process the asset `images/my_image.png.gz` by decompressing the bytes, then handing the decompressed result to the `LoadContext` with the new path `images/my_image.png.gz/my_image.png`. This intuitively reflects the nature of contained assets, whilst avoiding unintended behaviour, since the generated path cannot be a real file path (a file and folder of the same name cannot coexist in most file-systems). ```rust #[derive(Asset, TypePath)] pub struct GzAsset { pub uncompressed: ErasedLoadedAsset, } #[derive(Default)] pub struct GzAssetLoader; impl AssetLoader for GzAssetLoader { type Asset = GzAsset; type Settings = (); type Error = GzAssetLoaderError; fn load<'a>( &'a self, reader: &'a mut Reader, _settings: &'a (), load_context: &'a mut LoadContext, ) -> BoxedFuture<'a, Result<Self::Asset, Self::Error>> { Box::pin(async move { let compressed_path = load_context.path(); let file_name = compressed_path .file_name() .ok_or(GzAssetLoaderError::IndeterminateFilePath)? .to_string_lossy(); let uncompressed_file_name = file_name .strip_suffix(".gz") .ok_or(GzAssetLoaderError::IndeterminateFilePath)?; let contained_path = compressed_path.join(uncompressed_file_name); let mut bytes_compressed = Vec::new(); reader.read_to_end(&mut bytes_compressed).await?; let mut decoder = GzDecoder::new(bytes_compressed.as_slice()); let mut bytes_uncompressed = Vec::new(); decoder.read_to_end(&mut bytes_uncompressed)?; // Now that we have decompressed the asset, let's pass it back to the // context to continue loading let mut reader = VecReader::new(bytes_uncompressed); let uncompressed = load_context .load_direct_with_reader(&mut reader, contained_path) .await?; Ok(GzAsset { uncompressed }) }) } fn extensions(&self) -> &[&str] { &["gz"] } } ``` Because this example is so prudent, I've included an `asset_decompression` example which implements this exact behaviour: ```rust fn main() { App::new() .add_plugins(DefaultPlugins) .init_asset::<GzAsset>() .init_asset_loader::<GzAssetLoader>() .add_systems(Startup, setup) .add_systems(Update, decompress::<Image>) .run(); } fn setup(mut commands: Commands, asset_server: Res<AssetServer>) { commands.spawn(Camera2dBundle::default()); commands.spawn(( Compressed::<Image> { compressed: asset_server.load("data/compressed_image.png.gz"), ..default() }, Sprite::default(), TransformBundle::default(), VisibilityBundle::default(), )); } fn decompress<A: Asset>( mut commands: Commands, asset_server: Res<AssetServer>, mut compressed_assets: ResMut<Assets<GzAsset>>, query: Query<(Entity, &Compressed<A>)>, ) { for (entity, Compressed { compressed, .. }) in query.iter() { let Some(GzAsset { uncompressed }) = compressed_assets.remove(compressed) else { continue; }; let uncompressed = uncompressed.take::<A>().unwrap(); commands .entity(entity) .remove::<Compressed<A>>() .insert(asset_server.add(uncompressed)); } } ``` A key limitation to this design is how to type the internally loaded asset, since the example `GzAssetLoader` is unaware of the internal asset type `A`. As such, in this example I store the contained asset as an `ErasedLoadedAsset`, and leave it up to the consumer of the `GzAsset` to handle typing the final result, which is the purpose of the `decompress` system. This limitation can be worked around by providing type information to the `GzAssetLoader`, such as `GzAssetLoader<Image, ImageAssetLoader>`, but this would require registering the asset loader for every possible decompression target. Aside from this limitation, nested asset containerisation works as an end user would expect; if the user registers a `TarAssetLoader`, and a `GzAssetLoader`, then they can load assets with compound containerisation, such as `images.tar.gz`. --- ## Changelog - Added `LoadContext::load_direct_with_reader` - Added `asset_decompression` example ## Notes - While I believe my implementation of a Gzip asset loader is reasonable, I haven't included it as a public feature of `bevy_asset` to keep the scope of this PR as focussed as possible. - I have included `flate2` as a `dev-dependency` for the example; it is not included in the main dependency graph.
2023-11-16 17:47:31 +00:00
Use async-fn in traits rather than BoxedFuture (#12550) # Objective Simplify implementing some asset traits without Box::pin(async move{}) shenanigans. Fixes (in part) https://github.com/bevyengine/bevy/issues/11308 ## Solution Use async-fn in traits when possible in all traits. Traits with return position impl trait are not object safe however, and as AssetReader and AssetWriter are both used with dynamic dispatch, you need a Boxed version of these futures anyway. In the future, Rust is [adding ](https://blog.rust-lang.org/2023/12/21/async-fn-rpit-in-traits.html)proc macros to generate these traits automatically, and at some point in the future dyn traits should 'just work'. Until then.... this seemed liked the right approach given more ErasedXXX already exist, but, no clue if there's plans here! Especially since these are public now, it's a bit of an unfortunate API, and means this is a breaking change. In theory this saves some performance when these traits are used with static dispatch, but, seems like most code paths go through dynamic dispatch, which boxes anyway. I also suspect a bunch of the lifetime annotations on these function could be simplified now as the BoxedFuture was often the only thing returned which needed a lifetime annotation, but I'm not touching that for now as traits + lifetimes can be so tricky. This is a revival of [pull/11362](https://github.com/bevyengine/bevy/pull/11362) after a spectacular merge f*ckup, with updates to the latest Bevy. Just to recap some discussion: - Overall this seems like a win for code quality, especially when implementing these traits, but a loss for having to deal with ErasedXXX variants. - `ConditionalSend` was the preferred name for the trait that might be Send, to deal with wasm platforms. - When reviewing be sure to disable whitespace difference, as that's 95% of the PR. ## Changelog - AssetReader, AssetWriter, AssetLoader, AssetSaver and Process now use async-fn in traits rather than boxed futures. ## Migration Guide - Custom implementations of AssetReader, AssetWriter, AssetLoader, AssetSaver and Process should switch to async fn rather than returning a bevy_utils::BoxedFuture. - Simultaniously, to use dynamic dispatch on these traits you should instead use dyn ErasedXXX.
2024-03-18 17:56:57 +00:00
reader.read_to_end(&mut bytes_compressed).await?;
Added Method to Allow Pipelined Asset Loading (#10565) # Objective - Fixes #10518 ## Solution I've added a method to `LoadContext`, `load_direct_with_reader`, which mirrors the behaviour of `load_direct` with a single key difference: it is provided with the `Reader` by the caller, rather than getting it from the contained `AssetServer`. This allows for an `AssetLoader` to process its `Reader` stream, and then directly hand the results off to the `LoadContext` to handle further loading. The outer `AssetLoader` can control how the `Reader` is interpreted by providing a relevant `AssetPath`. For example, a Gzip decompression loader could process the asset `images/my_image.png.gz` by decompressing the bytes, then handing the decompressed result to the `LoadContext` with the new path `images/my_image.png.gz/my_image.png`. This intuitively reflects the nature of contained assets, whilst avoiding unintended behaviour, since the generated path cannot be a real file path (a file and folder of the same name cannot coexist in most file-systems). ```rust #[derive(Asset, TypePath)] pub struct GzAsset { pub uncompressed: ErasedLoadedAsset, } #[derive(Default)] pub struct GzAssetLoader; impl AssetLoader for GzAssetLoader { type Asset = GzAsset; type Settings = (); type Error = GzAssetLoaderError; fn load<'a>( &'a self, reader: &'a mut Reader, _settings: &'a (), load_context: &'a mut LoadContext, ) -> BoxedFuture<'a, Result<Self::Asset, Self::Error>> { Box::pin(async move { let compressed_path = load_context.path(); let file_name = compressed_path .file_name() .ok_or(GzAssetLoaderError::IndeterminateFilePath)? .to_string_lossy(); let uncompressed_file_name = file_name .strip_suffix(".gz") .ok_or(GzAssetLoaderError::IndeterminateFilePath)?; let contained_path = compressed_path.join(uncompressed_file_name); let mut bytes_compressed = Vec::new(); reader.read_to_end(&mut bytes_compressed).await?; let mut decoder = GzDecoder::new(bytes_compressed.as_slice()); let mut bytes_uncompressed = Vec::new(); decoder.read_to_end(&mut bytes_uncompressed)?; // Now that we have decompressed the asset, let's pass it back to the // context to continue loading let mut reader = VecReader::new(bytes_uncompressed); let uncompressed = load_context .load_direct_with_reader(&mut reader, contained_path) .await?; Ok(GzAsset { uncompressed }) }) } fn extensions(&self) -> &[&str] { &["gz"] } } ``` Because this example is so prudent, I've included an `asset_decompression` example which implements this exact behaviour: ```rust fn main() { App::new() .add_plugins(DefaultPlugins) .init_asset::<GzAsset>() .init_asset_loader::<GzAssetLoader>() .add_systems(Startup, setup) .add_systems(Update, decompress::<Image>) .run(); } fn setup(mut commands: Commands, asset_server: Res<AssetServer>) { commands.spawn(Camera2dBundle::default()); commands.spawn(( Compressed::<Image> { compressed: asset_server.load("data/compressed_image.png.gz"), ..default() }, Sprite::default(), TransformBundle::default(), VisibilityBundle::default(), )); } fn decompress<A: Asset>( mut commands: Commands, asset_server: Res<AssetServer>, mut compressed_assets: ResMut<Assets<GzAsset>>, query: Query<(Entity, &Compressed<A>)>, ) { for (entity, Compressed { compressed, .. }) in query.iter() { let Some(GzAsset { uncompressed }) = compressed_assets.remove(compressed) else { continue; }; let uncompressed = uncompressed.take::<A>().unwrap(); commands .entity(entity) .remove::<Compressed<A>>() .insert(asset_server.add(uncompressed)); } } ``` A key limitation to this design is how to type the internally loaded asset, since the example `GzAssetLoader` is unaware of the internal asset type `A`. As such, in this example I store the contained asset as an `ErasedLoadedAsset`, and leave it up to the consumer of the `GzAsset` to handle typing the final result, which is the purpose of the `decompress` system. This limitation can be worked around by providing type information to the `GzAssetLoader`, such as `GzAssetLoader<Image, ImageAssetLoader>`, but this would require registering the asset loader for every possible decompression target. Aside from this limitation, nested asset containerisation works as an end user would expect; if the user registers a `TarAssetLoader`, and a `GzAssetLoader`, then they can load assets with compound containerisation, such as `images.tar.gz`. --- ## Changelog - Added `LoadContext::load_direct_with_reader` - Added `asset_decompression` example ## Notes - While I believe my implementation of a Gzip asset loader is reasonable, I haven't included it as a public feature of `bevy_asset` to keep the scope of this PR as focussed as possible. - I have included `flate2` as a `dev-dependency` for the example; it is not included in the main dependency graph.
2023-11-16 17:47:31 +00:00
Use async-fn in traits rather than BoxedFuture (#12550) # Objective Simplify implementing some asset traits without Box::pin(async move{}) shenanigans. Fixes (in part) https://github.com/bevyengine/bevy/issues/11308 ## Solution Use async-fn in traits when possible in all traits. Traits with return position impl trait are not object safe however, and as AssetReader and AssetWriter are both used with dynamic dispatch, you need a Boxed version of these futures anyway. In the future, Rust is [adding ](https://blog.rust-lang.org/2023/12/21/async-fn-rpit-in-traits.html)proc macros to generate these traits automatically, and at some point in the future dyn traits should 'just work'. Until then.... this seemed liked the right approach given more ErasedXXX already exist, but, no clue if there's plans here! Especially since these are public now, it's a bit of an unfortunate API, and means this is a breaking change. In theory this saves some performance when these traits are used with static dispatch, but, seems like most code paths go through dynamic dispatch, which boxes anyway. I also suspect a bunch of the lifetime annotations on these function could be simplified now as the BoxedFuture was often the only thing returned which needed a lifetime annotation, but I'm not touching that for now as traits + lifetimes can be so tricky. This is a revival of [pull/11362](https://github.com/bevyengine/bevy/pull/11362) after a spectacular merge f*ckup, with updates to the latest Bevy. Just to recap some discussion: - Overall this seems like a win for code quality, especially when implementing these traits, but a loss for having to deal with ErasedXXX variants. - `ConditionalSend` was the preferred name for the trait that might be Send, to deal with wasm platforms. - When reviewing be sure to disable whitespace difference, as that's 95% of the PR. ## Changelog - AssetReader, AssetWriter, AssetLoader, AssetSaver and Process now use async-fn in traits rather than boxed futures. ## Migration Guide - Custom implementations of AssetReader, AssetWriter, AssetLoader, AssetSaver and Process should switch to async fn rather than returning a bevy_utils::BoxedFuture. - Simultaniously, to use dynamic dispatch on these traits you should instead use dyn ErasedXXX.
2024-03-18 17:56:57 +00:00
let mut decoder = GzDecoder::new(bytes_compressed.as_slice());
Added Method to Allow Pipelined Asset Loading (#10565) # Objective - Fixes #10518 ## Solution I've added a method to `LoadContext`, `load_direct_with_reader`, which mirrors the behaviour of `load_direct` with a single key difference: it is provided with the `Reader` by the caller, rather than getting it from the contained `AssetServer`. This allows for an `AssetLoader` to process its `Reader` stream, and then directly hand the results off to the `LoadContext` to handle further loading. The outer `AssetLoader` can control how the `Reader` is interpreted by providing a relevant `AssetPath`. For example, a Gzip decompression loader could process the asset `images/my_image.png.gz` by decompressing the bytes, then handing the decompressed result to the `LoadContext` with the new path `images/my_image.png.gz/my_image.png`. This intuitively reflects the nature of contained assets, whilst avoiding unintended behaviour, since the generated path cannot be a real file path (a file and folder of the same name cannot coexist in most file-systems). ```rust #[derive(Asset, TypePath)] pub struct GzAsset { pub uncompressed: ErasedLoadedAsset, } #[derive(Default)] pub struct GzAssetLoader; impl AssetLoader for GzAssetLoader { type Asset = GzAsset; type Settings = (); type Error = GzAssetLoaderError; fn load<'a>( &'a self, reader: &'a mut Reader, _settings: &'a (), load_context: &'a mut LoadContext, ) -> BoxedFuture<'a, Result<Self::Asset, Self::Error>> { Box::pin(async move { let compressed_path = load_context.path(); let file_name = compressed_path .file_name() .ok_or(GzAssetLoaderError::IndeterminateFilePath)? .to_string_lossy(); let uncompressed_file_name = file_name .strip_suffix(".gz") .ok_or(GzAssetLoaderError::IndeterminateFilePath)?; let contained_path = compressed_path.join(uncompressed_file_name); let mut bytes_compressed = Vec::new(); reader.read_to_end(&mut bytes_compressed).await?; let mut decoder = GzDecoder::new(bytes_compressed.as_slice()); let mut bytes_uncompressed = Vec::new(); decoder.read_to_end(&mut bytes_uncompressed)?; // Now that we have decompressed the asset, let's pass it back to the // context to continue loading let mut reader = VecReader::new(bytes_uncompressed); let uncompressed = load_context .load_direct_with_reader(&mut reader, contained_path) .await?; Ok(GzAsset { uncompressed }) }) } fn extensions(&self) -> &[&str] { &["gz"] } } ``` Because this example is so prudent, I've included an `asset_decompression` example which implements this exact behaviour: ```rust fn main() { App::new() .add_plugins(DefaultPlugins) .init_asset::<GzAsset>() .init_asset_loader::<GzAssetLoader>() .add_systems(Startup, setup) .add_systems(Update, decompress::<Image>) .run(); } fn setup(mut commands: Commands, asset_server: Res<AssetServer>) { commands.spawn(Camera2dBundle::default()); commands.spawn(( Compressed::<Image> { compressed: asset_server.load("data/compressed_image.png.gz"), ..default() }, Sprite::default(), TransformBundle::default(), VisibilityBundle::default(), )); } fn decompress<A: Asset>( mut commands: Commands, asset_server: Res<AssetServer>, mut compressed_assets: ResMut<Assets<GzAsset>>, query: Query<(Entity, &Compressed<A>)>, ) { for (entity, Compressed { compressed, .. }) in query.iter() { let Some(GzAsset { uncompressed }) = compressed_assets.remove(compressed) else { continue; }; let uncompressed = uncompressed.take::<A>().unwrap(); commands .entity(entity) .remove::<Compressed<A>>() .insert(asset_server.add(uncompressed)); } } ``` A key limitation to this design is how to type the internally loaded asset, since the example `GzAssetLoader` is unaware of the internal asset type `A`. As such, in this example I store the contained asset as an `ErasedLoadedAsset`, and leave it up to the consumer of the `GzAsset` to handle typing the final result, which is the purpose of the `decompress` system. This limitation can be worked around by providing type information to the `GzAssetLoader`, such as `GzAssetLoader<Image, ImageAssetLoader>`, but this would require registering the asset loader for every possible decompression target. Aside from this limitation, nested asset containerisation works as an end user would expect; if the user registers a `TarAssetLoader`, and a `GzAssetLoader`, then they can load assets with compound containerisation, such as `images.tar.gz`. --- ## Changelog - Added `LoadContext::load_direct_with_reader` - Added `asset_decompression` example ## Notes - While I believe my implementation of a Gzip asset loader is reasonable, I haven't included it as a public feature of `bevy_asset` to keep the scope of this PR as focussed as possible. - I have included `flate2` as a `dev-dependency` for the example; it is not included in the main dependency graph.
2023-11-16 17:47:31 +00:00
Use async-fn in traits rather than BoxedFuture (#12550) # Objective Simplify implementing some asset traits without Box::pin(async move{}) shenanigans. Fixes (in part) https://github.com/bevyengine/bevy/issues/11308 ## Solution Use async-fn in traits when possible in all traits. Traits with return position impl trait are not object safe however, and as AssetReader and AssetWriter are both used with dynamic dispatch, you need a Boxed version of these futures anyway. In the future, Rust is [adding ](https://blog.rust-lang.org/2023/12/21/async-fn-rpit-in-traits.html)proc macros to generate these traits automatically, and at some point in the future dyn traits should 'just work'. Until then.... this seemed liked the right approach given more ErasedXXX already exist, but, no clue if there's plans here! Especially since these are public now, it's a bit of an unfortunate API, and means this is a breaking change. In theory this saves some performance when these traits are used with static dispatch, but, seems like most code paths go through dynamic dispatch, which boxes anyway. I also suspect a bunch of the lifetime annotations on these function could be simplified now as the BoxedFuture was often the only thing returned which needed a lifetime annotation, but I'm not touching that for now as traits + lifetimes can be so tricky. This is a revival of [pull/11362](https://github.com/bevyengine/bevy/pull/11362) after a spectacular merge f*ckup, with updates to the latest Bevy. Just to recap some discussion: - Overall this seems like a win for code quality, especially when implementing these traits, but a loss for having to deal with ErasedXXX variants. - `ConditionalSend` was the preferred name for the trait that might be Send, to deal with wasm platforms. - When reviewing be sure to disable whitespace difference, as that's 95% of the PR. ## Changelog - AssetReader, AssetWriter, AssetLoader, AssetSaver and Process now use async-fn in traits rather than boxed futures. ## Migration Guide - Custom implementations of AssetReader, AssetWriter, AssetLoader, AssetSaver and Process should switch to async fn rather than returning a bevy_utils::BoxedFuture. - Simultaniously, to use dynamic dispatch on these traits you should instead use dyn ErasedXXX.
2024-03-18 17:56:57 +00:00
let mut bytes_uncompressed = Vec::new();
Added Method to Allow Pipelined Asset Loading (#10565) # Objective - Fixes #10518 ## Solution I've added a method to `LoadContext`, `load_direct_with_reader`, which mirrors the behaviour of `load_direct` with a single key difference: it is provided with the `Reader` by the caller, rather than getting it from the contained `AssetServer`. This allows for an `AssetLoader` to process its `Reader` stream, and then directly hand the results off to the `LoadContext` to handle further loading. The outer `AssetLoader` can control how the `Reader` is interpreted by providing a relevant `AssetPath`. For example, a Gzip decompression loader could process the asset `images/my_image.png.gz` by decompressing the bytes, then handing the decompressed result to the `LoadContext` with the new path `images/my_image.png.gz/my_image.png`. This intuitively reflects the nature of contained assets, whilst avoiding unintended behaviour, since the generated path cannot be a real file path (a file and folder of the same name cannot coexist in most file-systems). ```rust #[derive(Asset, TypePath)] pub struct GzAsset { pub uncompressed: ErasedLoadedAsset, } #[derive(Default)] pub struct GzAssetLoader; impl AssetLoader for GzAssetLoader { type Asset = GzAsset; type Settings = (); type Error = GzAssetLoaderError; fn load<'a>( &'a self, reader: &'a mut Reader, _settings: &'a (), load_context: &'a mut LoadContext, ) -> BoxedFuture<'a, Result<Self::Asset, Self::Error>> { Box::pin(async move { let compressed_path = load_context.path(); let file_name = compressed_path .file_name() .ok_or(GzAssetLoaderError::IndeterminateFilePath)? .to_string_lossy(); let uncompressed_file_name = file_name .strip_suffix(".gz") .ok_or(GzAssetLoaderError::IndeterminateFilePath)?; let contained_path = compressed_path.join(uncompressed_file_name); let mut bytes_compressed = Vec::new(); reader.read_to_end(&mut bytes_compressed).await?; let mut decoder = GzDecoder::new(bytes_compressed.as_slice()); let mut bytes_uncompressed = Vec::new(); decoder.read_to_end(&mut bytes_uncompressed)?; // Now that we have decompressed the asset, let's pass it back to the // context to continue loading let mut reader = VecReader::new(bytes_uncompressed); let uncompressed = load_context .load_direct_with_reader(&mut reader, contained_path) .await?; Ok(GzAsset { uncompressed }) }) } fn extensions(&self) -> &[&str] { &["gz"] } } ``` Because this example is so prudent, I've included an `asset_decompression` example which implements this exact behaviour: ```rust fn main() { App::new() .add_plugins(DefaultPlugins) .init_asset::<GzAsset>() .init_asset_loader::<GzAssetLoader>() .add_systems(Startup, setup) .add_systems(Update, decompress::<Image>) .run(); } fn setup(mut commands: Commands, asset_server: Res<AssetServer>) { commands.spawn(Camera2dBundle::default()); commands.spawn(( Compressed::<Image> { compressed: asset_server.load("data/compressed_image.png.gz"), ..default() }, Sprite::default(), TransformBundle::default(), VisibilityBundle::default(), )); } fn decompress<A: Asset>( mut commands: Commands, asset_server: Res<AssetServer>, mut compressed_assets: ResMut<Assets<GzAsset>>, query: Query<(Entity, &Compressed<A>)>, ) { for (entity, Compressed { compressed, .. }) in query.iter() { let Some(GzAsset { uncompressed }) = compressed_assets.remove(compressed) else { continue; }; let uncompressed = uncompressed.take::<A>().unwrap(); commands .entity(entity) .remove::<Compressed<A>>() .insert(asset_server.add(uncompressed)); } } ``` A key limitation to this design is how to type the internally loaded asset, since the example `GzAssetLoader` is unaware of the internal asset type `A`. As such, in this example I store the contained asset as an `ErasedLoadedAsset`, and leave it up to the consumer of the `GzAsset` to handle typing the final result, which is the purpose of the `decompress` system. This limitation can be worked around by providing type information to the `GzAssetLoader`, such as `GzAssetLoader<Image, ImageAssetLoader>`, but this would require registering the asset loader for every possible decompression target. Aside from this limitation, nested asset containerisation works as an end user would expect; if the user registers a `TarAssetLoader`, and a `GzAssetLoader`, then they can load assets with compound containerisation, such as `images.tar.gz`. --- ## Changelog - Added `LoadContext::load_direct_with_reader` - Added `asset_decompression` example ## Notes - While I believe my implementation of a Gzip asset loader is reasonable, I haven't included it as a public feature of `bevy_asset` to keep the scope of this PR as focussed as possible. - I have included `flate2` as a `dev-dependency` for the example; it is not included in the main dependency graph.
2023-11-16 17:47:31 +00:00
Use async-fn in traits rather than BoxedFuture (#12550) # Objective Simplify implementing some asset traits without Box::pin(async move{}) shenanigans. Fixes (in part) https://github.com/bevyengine/bevy/issues/11308 ## Solution Use async-fn in traits when possible in all traits. Traits with return position impl trait are not object safe however, and as AssetReader and AssetWriter are both used with dynamic dispatch, you need a Boxed version of these futures anyway. In the future, Rust is [adding ](https://blog.rust-lang.org/2023/12/21/async-fn-rpit-in-traits.html)proc macros to generate these traits automatically, and at some point in the future dyn traits should 'just work'. Until then.... this seemed liked the right approach given more ErasedXXX already exist, but, no clue if there's plans here! Especially since these are public now, it's a bit of an unfortunate API, and means this is a breaking change. In theory this saves some performance when these traits are used with static dispatch, but, seems like most code paths go through dynamic dispatch, which boxes anyway. I also suspect a bunch of the lifetime annotations on these function could be simplified now as the BoxedFuture was often the only thing returned which needed a lifetime annotation, but I'm not touching that for now as traits + lifetimes can be so tricky. This is a revival of [pull/11362](https://github.com/bevyengine/bevy/pull/11362) after a spectacular merge f*ckup, with updates to the latest Bevy. Just to recap some discussion: - Overall this seems like a win for code quality, especially when implementing these traits, but a loss for having to deal with ErasedXXX variants. - `ConditionalSend` was the preferred name for the trait that might be Send, to deal with wasm platforms. - When reviewing be sure to disable whitespace difference, as that's 95% of the PR. ## Changelog - AssetReader, AssetWriter, AssetLoader, AssetSaver and Process now use async-fn in traits rather than boxed futures. ## Migration Guide - Custom implementations of AssetReader, AssetWriter, AssetLoader, AssetSaver and Process should switch to async fn rather than returning a bevy_utils::BoxedFuture. - Simultaniously, to use dynamic dispatch on these traits you should instead use dyn ErasedXXX.
2024-03-18 17:56:57 +00:00
decoder.read_to_end(&mut bytes_uncompressed)?;
Added Method to Allow Pipelined Asset Loading (#10565) # Objective - Fixes #10518 ## Solution I've added a method to `LoadContext`, `load_direct_with_reader`, which mirrors the behaviour of `load_direct` with a single key difference: it is provided with the `Reader` by the caller, rather than getting it from the contained `AssetServer`. This allows for an `AssetLoader` to process its `Reader` stream, and then directly hand the results off to the `LoadContext` to handle further loading. The outer `AssetLoader` can control how the `Reader` is interpreted by providing a relevant `AssetPath`. For example, a Gzip decompression loader could process the asset `images/my_image.png.gz` by decompressing the bytes, then handing the decompressed result to the `LoadContext` with the new path `images/my_image.png.gz/my_image.png`. This intuitively reflects the nature of contained assets, whilst avoiding unintended behaviour, since the generated path cannot be a real file path (a file and folder of the same name cannot coexist in most file-systems). ```rust #[derive(Asset, TypePath)] pub struct GzAsset { pub uncompressed: ErasedLoadedAsset, } #[derive(Default)] pub struct GzAssetLoader; impl AssetLoader for GzAssetLoader { type Asset = GzAsset; type Settings = (); type Error = GzAssetLoaderError; fn load<'a>( &'a self, reader: &'a mut Reader, _settings: &'a (), load_context: &'a mut LoadContext, ) -> BoxedFuture<'a, Result<Self::Asset, Self::Error>> { Box::pin(async move { let compressed_path = load_context.path(); let file_name = compressed_path .file_name() .ok_or(GzAssetLoaderError::IndeterminateFilePath)? .to_string_lossy(); let uncompressed_file_name = file_name .strip_suffix(".gz") .ok_or(GzAssetLoaderError::IndeterminateFilePath)?; let contained_path = compressed_path.join(uncompressed_file_name); let mut bytes_compressed = Vec::new(); reader.read_to_end(&mut bytes_compressed).await?; let mut decoder = GzDecoder::new(bytes_compressed.as_slice()); let mut bytes_uncompressed = Vec::new(); decoder.read_to_end(&mut bytes_uncompressed)?; // Now that we have decompressed the asset, let's pass it back to the // context to continue loading let mut reader = VecReader::new(bytes_uncompressed); let uncompressed = load_context .load_direct_with_reader(&mut reader, contained_path) .await?; Ok(GzAsset { uncompressed }) }) } fn extensions(&self) -> &[&str] { &["gz"] } } ``` Because this example is so prudent, I've included an `asset_decompression` example which implements this exact behaviour: ```rust fn main() { App::new() .add_plugins(DefaultPlugins) .init_asset::<GzAsset>() .init_asset_loader::<GzAssetLoader>() .add_systems(Startup, setup) .add_systems(Update, decompress::<Image>) .run(); } fn setup(mut commands: Commands, asset_server: Res<AssetServer>) { commands.spawn(Camera2dBundle::default()); commands.spawn(( Compressed::<Image> { compressed: asset_server.load("data/compressed_image.png.gz"), ..default() }, Sprite::default(), TransformBundle::default(), VisibilityBundle::default(), )); } fn decompress<A: Asset>( mut commands: Commands, asset_server: Res<AssetServer>, mut compressed_assets: ResMut<Assets<GzAsset>>, query: Query<(Entity, &Compressed<A>)>, ) { for (entity, Compressed { compressed, .. }) in query.iter() { let Some(GzAsset { uncompressed }) = compressed_assets.remove(compressed) else { continue; }; let uncompressed = uncompressed.take::<A>().unwrap(); commands .entity(entity) .remove::<Compressed<A>>() .insert(asset_server.add(uncompressed)); } } ``` A key limitation to this design is how to type the internally loaded asset, since the example `GzAssetLoader` is unaware of the internal asset type `A`. As such, in this example I store the contained asset as an `ErasedLoadedAsset`, and leave it up to the consumer of the `GzAsset` to handle typing the final result, which is the purpose of the `decompress` system. This limitation can be worked around by providing type information to the `GzAssetLoader`, such as `GzAssetLoader<Image, ImageAssetLoader>`, but this would require registering the asset loader for every possible decompression target. Aside from this limitation, nested asset containerisation works as an end user would expect; if the user registers a `TarAssetLoader`, and a `GzAssetLoader`, then they can load assets with compound containerisation, such as `images.tar.gz`. --- ## Changelog - Added `LoadContext::load_direct_with_reader` - Added `asset_decompression` example ## Notes - While I believe my implementation of a Gzip asset loader is reasonable, I haven't included it as a public feature of `bevy_asset` to keep the scope of this PR as focussed as possible. - I have included `flate2` as a `dev-dependency` for the example; it is not included in the main dependency graph.
2023-11-16 17:47:31 +00:00
Use async-fn in traits rather than BoxedFuture (#12550) # Objective Simplify implementing some asset traits without Box::pin(async move{}) shenanigans. Fixes (in part) https://github.com/bevyengine/bevy/issues/11308 ## Solution Use async-fn in traits when possible in all traits. Traits with return position impl trait are not object safe however, and as AssetReader and AssetWriter are both used with dynamic dispatch, you need a Boxed version of these futures anyway. In the future, Rust is [adding ](https://blog.rust-lang.org/2023/12/21/async-fn-rpit-in-traits.html)proc macros to generate these traits automatically, and at some point in the future dyn traits should 'just work'. Until then.... this seemed liked the right approach given more ErasedXXX already exist, but, no clue if there's plans here! Especially since these are public now, it's a bit of an unfortunate API, and means this is a breaking change. In theory this saves some performance when these traits are used with static dispatch, but, seems like most code paths go through dynamic dispatch, which boxes anyway. I also suspect a bunch of the lifetime annotations on these function could be simplified now as the BoxedFuture was often the only thing returned which needed a lifetime annotation, but I'm not touching that for now as traits + lifetimes can be so tricky. This is a revival of [pull/11362](https://github.com/bevyengine/bevy/pull/11362) after a spectacular merge f*ckup, with updates to the latest Bevy. Just to recap some discussion: - Overall this seems like a win for code quality, especially when implementing these traits, but a loss for having to deal with ErasedXXX variants. - `ConditionalSend` was the preferred name for the trait that might be Send, to deal with wasm platforms. - When reviewing be sure to disable whitespace difference, as that's 95% of the PR. ## Changelog - AssetReader, AssetWriter, AssetLoader, AssetSaver and Process now use async-fn in traits rather than boxed futures. ## Migration Guide - Custom implementations of AssetReader, AssetWriter, AssetLoader, AssetSaver and Process should switch to async fn rather than returning a bevy_utils::BoxedFuture. - Simultaniously, to use dynamic dispatch on these traits you should instead use dyn ErasedXXX.
2024-03-18 17:56:57 +00:00
// Now that we have decompressed the asset, let's pass it back to the
// context to continue loading
Added Method to Allow Pipelined Asset Loading (#10565) # Objective - Fixes #10518 ## Solution I've added a method to `LoadContext`, `load_direct_with_reader`, which mirrors the behaviour of `load_direct` with a single key difference: it is provided with the `Reader` by the caller, rather than getting it from the contained `AssetServer`. This allows for an `AssetLoader` to process its `Reader` stream, and then directly hand the results off to the `LoadContext` to handle further loading. The outer `AssetLoader` can control how the `Reader` is interpreted by providing a relevant `AssetPath`. For example, a Gzip decompression loader could process the asset `images/my_image.png.gz` by decompressing the bytes, then handing the decompressed result to the `LoadContext` with the new path `images/my_image.png.gz/my_image.png`. This intuitively reflects the nature of contained assets, whilst avoiding unintended behaviour, since the generated path cannot be a real file path (a file and folder of the same name cannot coexist in most file-systems). ```rust #[derive(Asset, TypePath)] pub struct GzAsset { pub uncompressed: ErasedLoadedAsset, } #[derive(Default)] pub struct GzAssetLoader; impl AssetLoader for GzAssetLoader { type Asset = GzAsset; type Settings = (); type Error = GzAssetLoaderError; fn load<'a>( &'a self, reader: &'a mut Reader, _settings: &'a (), load_context: &'a mut LoadContext, ) -> BoxedFuture<'a, Result<Self::Asset, Self::Error>> { Box::pin(async move { let compressed_path = load_context.path(); let file_name = compressed_path .file_name() .ok_or(GzAssetLoaderError::IndeterminateFilePath)? .to_string_lossy(); let uncompressed_file_name = file_name .strip_suffix(".gz") .ok_or(GzAssetLoaderError::IndeterminateFilePath)?; let contained_path = compressed_path.join(uncompressed_file_name); let mut bytes_compressed = Vec::new(); reader.read_to_end(&mut bytes_compressed).await?; let mut decoder = GzDecoder::new(bytes_compressed.as_slice()); let mut bytes_uncompressed = Vec::new(); decoder.read_to_end(&mut bytes_uncompressed)?; // Now that we have decompressed the asset, let's pass it back to the // context to continue loading let mut reader = VecReader::new(bytes_uncompressed); let uncompressed = load_context .load_direct_with_reader(&mut reader, contained_path) .await?; Ok(GzAsset { uncompressed }) }) } fn extensions(&self) -> &[&str] { &["gz"] } } ``` Because this example is so prudent, I've included an `asset_decompression` example which implements this exact behaviour: ```rust fn main() { App::new() .add_plugins(DefaultPlugins) .init_asset::<GzAsset>() .init_asset_loader::<GzAssetLoader>() .add_systems(Startup, setup) .add_systems(Update, decompress::<Image>) .run(); } fn setup(mut commands: Commands, asset_server: Res<AssetServer>) { commands.spawn(Camera2dBundle::default()); commands.spawn(( Compressed::<Image> { compressed: asset_server.load("data/compressed_image.png.gz"), ..default() }, Sprite::default(), TransformBundle::default(), VisibilityBundle::default(), )); } fn decompress<A: Asset>( mut commands: Commands, asset_server: Res<AssetServer>, mut compressed_assets: ResMut<Assets<GzAsset>>, query: Query<(Entity, &Compressed<A>)>, ) { for (entity, Compressed { compressed, .. }) in query.iter() { let Some(GzAsset { uncompressed }) = compressed_assets.remove(compressed) else { continue; }; let uncompressed = uncompressed.take::<A>().unwrap(); commands .entity(entity) .remove::<Compressed<A>>() .insert(asset_server.add(uncompressed)); } } ``` A key limitation to this design is how to type the internally loaded asset, since the example `GzAssetLoader` is unaware of the internal asset type `A`. As such, in this example I store the contained asset as an `ErasedLoadedAsset`, and leave it up to the consumer of the `GzAsset` to handle typing the final result, which is the purpose of the `decompress` system. This limitation can be worked around by providing type information to the `GzAssetLoader`, such as `GzAssetLoader<Image, ImageAssetLoader>`, but this would require registering the asset loader for every possible decompression target. Aside from this limitation, nested asset containerisation works as an end user would expect; if the user registers a `TarAssetLoader`, and a `GzAssetLoader`, then they can load assets with compound containerisation, such as `images.tar.gz`. --- ## Changelog - Added `LoadContext::load_direct_with_reader` - Added `asset_decompression` example ## Notes - While I believe my implementation of a Gzip asset loader is reasonable, I haven't included it as a public feature of `bevy_asset` to keep the scope of this PR as focussed as possible. - I have included `flate2` as a `dev-dependency` for the example; it is not included in the main dependency graph.
2023-11-16 17:47:31 +00:00
Use async-fn in traits rather than BoxedFuture (#12550) # Objective Simplify implementing some asset traits without Box::pin(async move{}) shenanigans. Fixes (in part) https://github.com/bevyengine/bevy/issues/11308 ## Solution Use async-fn in traits when possible in all traits. Traits with return position impl trait are not object safe however, and as AssetReader and AssetWriter are both used with dynamic dispatch, you need a Boxed version of these futures anyway. In the future, Rust is [adding ](https://blog.rust-lang.org/2023/12/21/async-fn-rpit-in-traits.html)proc macros to generate these traits automatically, and at some point in the future dyn traits should 'just work'. Until then.... this seemed liked the right approach given more ErasedXXX already exist, but, no clue if there's plans here! Especially since these are public now, it's a bit of an unfortunate API, and means this is a breaking change. In theory this saves some performance when these traits are used with static dispatch, but, seems like most code paths go through dynamic dispatch, which boxes anyway. I also suspect a bunch of the lifetime annotations on these function could be simplified now as the BoxedFuture was often the only thing returned which needed a lifetime annotation, but I'm not touching that for now as traits + lifetimes can be so tricky. This is a revival of [pull/11362](https://github.com/bevyengine/bevy/pull/11362) after a spectacular merge f*ckup, with updates to the latest Bevy. Just to recap some discussion: - Overall this seems like a win for code quality, especially when implementing these traits, but a loss for having to deal with ErasedXXX variants. - `ConditionalSend` was the preferred name for the trait that might be Send, to deal with wasm platforms. - When reviewing be sure to disable whitespace difference, as that's 95% of the PR. ## Changelog - AssetReader, AssetWriter, AssetLoader, AssetSaver and Process now use async-fn in traits rather than boxed futures. ## Migration Guide - Custom implementations of AssetReader, AssetWriter, AssetLoader, AssetSaver and Process should switch to async fn rather than returning a bevy_utils::BoxedFuture. - Simultaniously, to use dynamic dispatch on these traits you should instead use dyn ErasedXXX.
2024-03-18 17:56:57 +00:00
let mut reader = VecReader::new(bytes_uncompressed);
Added Method to Allow Pipelined Asset Loading (#10565) # Objective - Fixes #10518 ## Solution I've added a method to `LoadContext`, `load_direct_with_reader`, which mirrors the behaviour of `load_direct` with a single key difference: it is provided with the `Reader` by the caller, rather than getting it from the contained `AssetServer`. This allows for an `AssetLoader` to process its `Reader` stream, and then directly hand the results off to the `LoadContext` to handle further loading. The outer `AssetLoader` can control how the `Reader` is interpreted by providing a relevant `AssetPath`. For example, a Gzip decompression loader could process the asset `images/my_image.png.gz` by decompressing the bytes, then handing the decompressed result to the `LoadContext` with the new path `images/my_image.png.gz/my_image.png`. This intuitively reflects the nature of contained assets, whilst avoiding unintended behaviour, since the generated path cannot be a real file path (a file and folder of the same name cannot coexist in most file-systems). ```rust #[derive(Asset, TypePath)] pub struct GzAsset { pub uncompressed: ErasedLoadedAsset, } #[derive(Default)] pub struct GzAssetLoader; impl AssetLoader for GzAssetLoader { type Asset = GzAsset; type Settings = (); type Error = GzAssetLoaderError; fn load<'a>( &'a self, reader: &'a mut Reader, _settings: &'a (), load_context: &'a mut LoadContext, ) -> BoxedFuture<'a, Result<Self::Asset, Self::Error>> { Box::pin(async move { let compressed_path = load_context.path(); let file_name = compressed_path .file_name() .ok_or(GzAssetLoaderError::IndeterminateFilePath)? .to_string_lossy(); let uncompressed_file_name = file_name .strip_suffix(".gz") .ok_or(GzAssetLoaderError::IndeterminateFilePath)?; let contained_path = compressed_path.join(uncompressed_file_name); let mut bytes_compressed = Vec::new(); reader.read_to_end(&mut bytes_compressed).await?; let mut decoder = GzDecoder::new(bytes_compressed.as_slice()); let mut bytes_uncompressed = Vec::new(); decoder.read_to_end(&mut bytes_uncompressed)?; // Now that we have decompressed the asset, let's pass it back to the // context to continue loading let mut reader = VecReader::new(bytes_uncompressed); let uncompressed = load_context .load_direct_with_reader(&mut reader, contained_path) .await?; Ok(GzAsset { uncompressed }) }) } fn extensions(&self) -> &[&str] { &["gz"] } } ``` Because this example is so prudent, I've included an `asset_decompression` example which implements this exact behaviour: ```rust fn main() { App::new() .add_plugins(DefaultPlugins) .init_asset::<GzAsset>() .init_asset_loader::<GzAssetLoader>() .add_systems(Startup, setup) .add_systems(Update, decompress::<Image>) .run(); } fn setup(mut commands: Commands, asset_server: Res<AssetServer>) { commands.spawn(Camera2dBundle::default()); commands.spawn(( Compressed::<Image> { compressed: asset_server.load("data/compressed_image.png.gz"), ..default() }, Sprite::default(), TransformBundle::default(), VisibilityBundle::default(), )); } fn decompress<A: Asset>( mut commands: Commands, asset_server: Res<AssetServer>, mut compressed_assets: ResMut<Assets<GzAsset>>, query: Query<(Entity, &Compressed<A>)>, ) { for (entity, Compressed { compressed, .. }) in query.iter() { let Some(GzAsset { uncompressed }) = compressed_assets.remove(compressed) else { continue; }; let uncompressed = uncompressed.take::<A>().unwrap(); commands .entity(entity) .remove::<Compressed<A>>() .insert(asset_server.add(uncompressed)); } } ``` A key limitation to this design is how to type the internally loaded asset, since the example `GzAssetLoader` is unaware of the internal asset type `A`. As such, in this example I store the contained asset as an `ErasedLoadedAsset`, and leave it up to the consumer of the `GzAsset` to handle typing the final result, which is the purpose of the `decompress` system. This limitation can be worked around by providing type information to the `GzAssetLoader`, such as `GzAssetLoader<Image, ImageAssetLoader>`, but this would require registering the asset loader for every possible decompression target. Aside from this limitation, nested asset containerisation works as an end user would expect; if the user registers a `TarAssetLoader`, and a `GzAssetLoader`, then they can load assets with compound containerisation, such as `images.tar.gz`. --- ## Changelog - Added `LoadContext::load_direct_with_reader` - Added `asset_decompression` example ## Notes - While I believe my implementation of a Gzip asset loader is reasonable, I haven't included it as a public feature of `bevy_asset` to keep the scope of this PR as focussed as possible. - I have included `flate2` as a `dev-dependency` for the example; it is not included in the main dependency graph.
2023-11-16 17:47:31 +00:00
Use async-fn in traits rather than BoxedFuture (#12550) # Objective Simplify implementing some asset traits without Box::pin(async move{}) shenanigans. Fixes (in part) https://github.com/bevyengine/bevy/issues/11308 ## Solution Use async-fn in traits when possible in all traits. Traits with return position impl trait are not object safe however, and as AssetReader and AssetWriter are both used with dynamic dispatch, you need a Boxed version of these futures anyway. In the future, Rust is [adding ](https://blog.rust-lang.org/2023/12/21/async-fn-rpit-in-traits.html)proc macros to generate these traits automatically, and at some point in the future dyn traits should 'just work'. Until then.... this seemed liked the right approach given more ErasedXXX already exist, but, no clue if there's plans here! Especially since these are public now, it's a bit of an unfortunate API, and means this is a breaking change. In theory this saves some performance when these traits are used with static dispatch, but, seems like most code paths go through dynamic dispatch, which boxes anyway. I also suspect a bunch of the lifetime annotations on these function could be simplified now as the BoxedFuture was often the only thing returned which needed a lifetime annotation, but I'm not touching that for now as traits + lifetimes can be so tricky. This is a revival of [pull/11362](https://github.com/bevyengine/bevy/pull/11362) after a spectacular merge f*ckup, with updates to the latest Bevy. Just to recap some discussion: - Overall this seems like a win for code quality, especially when implementing these traits, but a loss for having to deal with ErasedXXX variants. - `ConditionalSend` was the preferred name for the trait that might be Send, to deal with wasm platforms. - When reviewing be sure to disable whitespace difference, as that's 95% of the PR. ## Changelog - AssetReader, AssetWriter, AssetLoader, AssetSaver and Process now use async-fn in traits rather than boxed futures. ## Migration Guide - Custom implementations of AssetReader, AssetWriter, AssetLoader, AssetSaver and Process should switch to async fn rather than returning a bevy_utils::BoxedFuture. - Simultaniously, to use dynamic dispatch on these traits you should instead use dyn ErasedXXX.
2024-03-18 17:56:57 +00:00
let uncompressed = load_context
Make LoadContext use the builder pattern for loading dependent assets (#13465) # Objective - Fixes #13445. ## Solution - Removes all `load_` methods from `LoadContext`. - Introduces `fn loader()` which returns a builder. ## Testing - I've tested with `cargo test --package=bevy_asset` and run the two relevant examples (`asset_processing` & `asset_decompression`). --- ## Changelog - Replaced all `load_` methods on `LoadContext` with the new `loader()` pattern. ## Migration Guide - Several LoadContext method calls will need to be updated: - `load_context.load_with_settings(path, settings)` => `load_context.loader().with_settings(settings).load(path)` - `load_context.load_untyped(path)` => `load_context.loader().untyped().load(path)` - `load_context.load_direct(path)` => `load_context.loader().direct().load(path)` - `load_context.load_direct_untyped(path)` => `load_context.loader().direct().untyped().load(path)` - `load_context.load_direct_with_settings(path, settings)` => `load_context.loader().with_settings(settings).direct().load(path)` - `load_context.load_direct_with_reader(reader, path)` => `load_context.loader().direct().with_reader(reader).load(path)` - `load_context.load_direct_with_reader_and_settings(reader, path, settings)` => `load_context.loader().with_settings(settings).direct().with_reader(reader).load(path)` - `load_context.load_direct_untyped_with_reader(reader, path)` => `load_context.loader().direct().with_reader(reader).untyped().load(path)` --- CC @alice-i-cecile / @bushrat011899 Examples: ```rust load_context.loader() .with_asset_type::<A>() .with_asset_type_id(TypeId::of::<A>()) .with_settings(|mut settings| { settings.key = value; }) // Then, for a Handle<A>: .load::<A>() // Or, for a Handle<LoadedUntypedAsset>: .untyped() .load() // Or, to load an `A` directly: .direct() .load::<A>() .await // Or, to load an `ErasedLoadedAsset` directly: .direct() .untyped() .load() .await ```
2024-05-22 23:35:41 +00:00
.loader()
bevy_asset: Improve `NestedLoader` API (#15509) # Objective The `NestedLoader` API as it stands right now is somewhat lacking: - It consists of several types `NestedLoader`, `UntypedNestedLoader`, `DirectNestedLoader`, and `UntypedDirectNestedLoader`, where a typestate pattern on `NestedLoader` would be make it more obvious what it does, and allow centralising the documentation - The term "untyped" in the asset loader code is overloaded. It can mean either: - we have literally no idea what the type of this asset will be when we load it (I dub this "unknown type") - we know what type of asset it will be, but we don't know it statically - we only have a TypeId (I dub this "dynamic type" / "erased") - There is no way to get an `UntypedHandle` (erased) given a `TypeId` ## Solution Changes `NestedLoader` into a type-state pattern, adding two type params: - `T` determines the typing - `StaticTyped`, the default, where you pass in `A` statically into `fn load<A>() -> ..` - `DynamicTyped`, where you give a `TypeId`, giving you a `UntypedHandle` - `UnknownTyped`, where you have literally no idea what type of asset you're loading, giving you a `Handle<LoadedUntypedAsset>` - `M` determines the "mode" (bikeshedding TBD, I couldn't come up with a better name) - `Deferred`, the default, won't load the asset when you call `load`, but it does give you a `Handle` to it (this is nice since it can be a sync fn) - `Immediate` will load the asset as soon as you call it, and give you access to it, but you must be in an async context to call it Changes some naming of internals in `AssetServer` to fit the new definitions of "dynamic type" and "unknown type". Note that I didn't do a full pass over this code to keep the diff small. That can probably be done in a new PR - I think the definiton I laid out of unknown type vs. erased makes it pretty clear where each one applies. <details> <summary>Old issue</summary> The only real problem I have with this PR is the requirement to pass in `type_name` (from `core::any::type_name`) into Erased. Users might not have that type name, only the ID, and it just seems sort of weird to *have* to give an asset type name. However, the reason we need it is because of this: ```rs pub(crate) fn get_or_create_path_handle_erased( &mut self, path: AssetPath<'static>, type_id: TypeId, type_name: &str, loading_mode: HandleLoadingMode, meta_transform: Option<MetaTransform>, ) -> (UntypedHandle, bool) { let result = self.get_or_create_path_handle_internal( path, Some(type_id), loading_mode, meta_transform, ); // it is ok to unwrap because TypeId was specified above unwrap_with_context(result, type_name).unwrap() } pub(crate) fn unwrap_with_context<T>( result: Result<T, GetOrCreateHandleInternalError>, type_name: &str, ) -> Option<T> { match result { Ok(value) => Some(value), Err(GetOrCreateHandleInternalError::HandleMissingButTypeIdNotSpecified) => None, Err(GetOrCreateHandleInternalError::MissingHandleProviderError(_)) => { panic!("Cannot allocate an Asset Handle of type '{type_name}' because the asset type has not been initialized. \ Make sure you have called app.init_asset::<{type_name}>()") } } } ``` This `unwrap_with_context` is literally the only reason we need the `type_name`. Potentially, this can be turned into an `impl Into<Option<&str>>`, and output a different error message if the type name is missing. Since if we are loading an asset where we only know the type ID, by definition we can't output that error message, since we don't have the type name. I'm open to suggestions on this. </details> ## Testing Not sure how to test this, since I kept most of the actual NestedLoader logic the same. The only new API is loading an `UntypedHandle` when in the `DynamicTyped, Immediate` state. ## Migration Guide Code which uses `bevy_asset`'s `LoadContext::loader` / `NestedLoader` will see some naming changes: - `untyped` is replaced by `with_unknown_type` - `with_asset_type` is replaced by `with_static_type` - `with_asset_type_id` is replaced by `with_dynamic_type` - `direct` is replaced by `immediate` (the opposite of "immediate" is "deferred")
2024-10-01 14:14:04 +00:00
.with_unknown_type()
.immediate()
Make LoadContext use the builder pattern for loading dependent assets (#13465) # Objective - Fixes #13445. ## Solution - Removes all `load_` methods from `LoadContext`. - Introduces `fn loader()` which returns a builder. ## Testing - I've tested with `cargo test --package=bevy_asset` and run the two relevant examples (`asset_processing` & `asset_decompression`). --- ## Changelog - Replaced all `load_` methods on `LoadContext` with the new `loader()` pattern. ## Migration Guide - Several LoadContext method calls will need to be updated: - `load_context.load_with_settings(path, settings)` => `load_context.loader().with_settings(settings).load(path)` - `load_context.load_untyped(path)` => `load_context.loader().untyped().load(path)` - `load_context.load_direct(path)` => `load_context.loader().direct().load(path)` - `load_context.load_direct_untyped(path)` => `load_context.loader().direct().untyped().load(path)` - `load_context.load_direct_with_settings(path, settings)` => `load_context.loader().with_settings(settings).direct().load(path)` - `load_context.load_direct_with_reader(reader, path)` => `load_context.loader().direct().with_reader(reader).load(path)` - `load_context.load_direct_with_reader_and_settings(reader, path, settings)` => `load_context.loader().with_settings(settings).direct().with_reader(reader).load(path)` - `load_context.load_direct_untyped_with_reader(reader, path)` => `load_context.loader().direct().with_reader(reader).untyped().load(path)` --- CC @alice-i-cecile / @bushrat011899 Examples: ```rust load_context.loader() .with_asset_type::<A>() .with_asset_type_id(TypeId::of::<A>()) .with_settings(|mut settings| { settings.key = value; }) // Then, for a Handle<A>: .load::<A>() // Or, for a Handle<LoadedUntypedAsset>: .untyped() .load() // Or, to load an `A` directly: .direct() .load::<A>() .await // Or, to load an `ErasedLoadedAsset` directly: .direct() .untyped() .load() .await ```
2024-05-22 23:35:41 +00:00
.with_reader(&mut reader)
.load(contained_path)
Use async-fn in traits rather than BoxedFuture (#12550) # Objective Simplify implementing some asset traits without Box::pin(async move{}) shenanigans. Fixes (in part) https://github.com/bevyengine/bevy/issues/11308 ## Solution Use async-fn in traits when possible in all traits. Traits with return position impl trait are not object safe however, and as AssetReader and AssetWriter are both used with dynamic dispatch, you need a Boxed version of these futures anyway. In the future, Rust is [adding ](https://blog.rust-lang.org/2023/12/21/async-fn-rpit-in-traits.html)proc macros to generate these traits automatically, and at some point in the future dyn traits should 'just work'. Until then.... this seemed liked the right approach given more ErasedXXX already exist, but, no clue if there's plans here! Especially since these are public now, it's a bit of an unfortunate API, and means this is a breaking change. In theory this saves some performance when these traits are used with static dispatch, but, seems like most code paths go through dynamic dispatch, which boxes anyway. I also suspect a bunch of the lifetime annotations on these function could be simplified now as the BoxedFuture was often the only thing returned which needed a lifetime annotation, but I'm not touching that for now as traits + lifetimes can be so tricky. This is a revival of [pull/11362](https://github.com/bevyengine/bevy/pull/11362) after a spectacular merge f*ckup, with updates to the latest Bevy. Just to recap some discussion: - Overall this seems like a win for code quality, especially when implementing these traits, but a loss for having to deal with ErasedXXX variants. - `ConditionalSend` was the preferred name for the trait that might be Send, to deal with wasm platforms. - When reviewing be sure to disable whitespace difference, as that's 95% of the PR. ## Changelog - AssetReader, AssetWriter, AssetLoader, AssetSaver and Process now use async-fn in traits rather than boxed futures. ## Migration Guide - Custom implementations of AssetReader, AssetWriter, AssetLoader, AssetSaver and Process should switch to async fn rather than returning a bevy_utils::BoxedFuture. - Simultaniously, to use dynamic dispatch on these traits you should instead use dyn ErasedXXX.
2024-03-18 17:56:57 +00:00
.await?;
Added Method to Allow Pipelined Asset Loading (#10565) # Objective - Fixes #10518 ## Solution I've added a method to `LoadContext`, `load_direct_with_reader`, which mirrors the behaviour of `load_direct` with a single key difference: it is provided with the `Reader` by the caller, rather than getting it from the contained `AssetServer`. This allows for an `AssetLoader` to process its `Reader` stream, and then directly hand the results off to the `LoadContext` to handle further loading. The outer `AssetLoader` can control how the `Reader` is interpreted by providing a relevant `AssetPath`. For example, a Gzip decompression loader could process the asset `images/my_image.png.gz` by decompressing the bytes, then handing the decompressed result to the `LoadContext` with the new path `images/my_image.png.gz/my_image.png`. This intuitively reflects the nature of contained assets, whilst avoiding unintended behaviour, since the generated path cannot be a real file path (a file and folder of the same name cannot coexist in most file-systems). ```rust #[derive(Asset, TypePath)] pub struct GzAsset { pub uncompressed: ErasedLoadedAsset, } #[derive(Default)] pub struct GzAssetLoader; impl AssetLoader for GzAssetLoader { type Asset = GzAsset; type Settings = (); type Error = GzAssetLoaderError; fn load<'a>( &'a self, reader: &'a mut Reader, _settings: &'a (), load_context: &'a mut LoadContext, ) -> BoxedFuture<'a, Result<Self::Asset, Self::Error>> { Box::pin(async move { let compressed_path = load_context.path(); let file_name = compressed_path .file_name() .ok_or(GzAssetLoaderError::IndeterminateFilePath)? .to_string_lossy(); let uncompressed_file_name = file_name .strip_suffix(".gz") .ok_or(GzAssetLoaderError::IndeterminateFilePath)?; let contained_path = compressed_path.join(uncompressed_file_name); let mut bytes_compressed = Vec::new(); reader.read_to_end(&mut bytes_compressed).await?; let mut decoder = GzDecoder::new(bytes_compressed.as_slice()); let mut bytes_uncompressed = Vec::new(); decoder.read_to_end(&mut bytes_uncompressed)?; // Now that we have decompressed the asset, let's pass it back to the // context to continue loading let mut reader = VecReader::new(bytes_uncompressed); let uncompressed = load_context .load_direct_with_reader(&mut reader, contained_path) .await?; Ok(GzAsset { uncompressed }) }) } fn extensions(&self) -> &[&str] { &["gz"] } } ``` Because this example is so prudent, I've included an `asset_decompression` example which implements this exact behaviour: ```rust fn main() { App::new() .add_plugins(DefaultPlugins) .init_asset::<GzAsset>() .init_asset_loader::<GzAssetLoader>() .add_systems(Startup, setup) .add_systems(Update, decompress::<Image>) .run(); } fn setup(mut commands: Commands, asset_server: Res<AssetServer>) { commands.spawn(Camera2dBundle::default()); commands.spawn(( Compressed::<Image> { compressed: asset_server.load("data/compressed_image.png.gz"), ..default() }, Sprite::default(), TransformBundle::default(), VisibilityBundle::default(), )); } fn decompress<A: Asset>( mut commands: Commands, asset_server: Res<AssetServer>, mut compressed_assets: ResMut<Assets<GzAsset>>, query: Query<(Entity, &Compressed<A>)>, ) { for (entity, Compressed { compressed, .. }) in query.iter() { let Some(GzAsset { uncompressed }) = compressed_assets.remove(compressed) else { continue; }; let uncompressed = uncompressed.take::<A>().unwrap(); commands .entity(entity) .remove::<Compressed<A>>() .insert(asset_server.add(uncompressed)); } } ``` A key limitation to this design is how to type the internally loaded asset, since the example `GzAssetLoader` is unaware of the internal asset type `A`. As such, in this example I store the contained asset as an `ErasedLoadedAsset`, and leave it up to the consumer of the `GzAsset` to handle typing the final result, which is the purpose of the `decompress` system. This limitation can be worked around by providing type information to the `GzAssetLoader`, such as `GzAssetLoader<Image, ImageAssetLoader>`, but this would require registering the asset loader for every possible decompression target. Aside from this limitation, nested asset containerisation works as an end user would expect; if the user registers a `TarAssetLoader`, and a `GzAssetLoader`, then they can load assets with compound containerisation, such as `images.tar.gz`. --- ## Changelog - Added `LoadContext::load_direct_with_reader` - Added `asset_decompression` example ## Notes - While I believe my implementation of a Gzip asset loader is reasonable, I haven't included it as a public feature of `bevy_asset` to keep the scope of this PR as focussed as possible. - I have included `flate2` as a `dev-dependency` for the example; it is not included in the main dependency graph.
2023-11-16 17:47:31 +00:00
Use async-fn in traits rather than BoxedFuture (#12550) # Objective Simplify implementing some asset traits without Box::pin(async move{}) shenanigans. Fixes (in part) https://github.com/bevyengine/bevy/issues/11308 ## Solution Use async-fn in traits when possible in all traits. Traits with return position impl trait are not object safe however, and as AssetReader and AssetWriter are both used with dynamic dispatch, you need a Boxed version of these futures anyway. In the future, Rust is [adding ](https://blog.rust-lang.org/2023/12/21/async-fn-rpit-in-traits.html)proc macros to generate these traits automatically, and at some point in the future dyn traits should 'just work'. Until then.... this seemed liked the right approach given more ErasedXXX already exist, but, no clue if there's plans here! Especially since these are public now, it's a bit of an unfortunate API, and means this is a breaking change. In theory this saves some performance when these traits are used with static dispatch, but, seems like most code paths go through dynamic dispatch, which boxes anyway. I also suspect a bunch of the lifetime annotations on these function could be simplified now as the BoxedFuture was often the only thing returned which needed a lifetime annotation, but I'm not touching that for now as traits + lifetimes can be so tricky. This is a revival of [pull/11362](https://github.com/bevyengine/bevy/pull/11362) after a spectacular merge f*ckup, with updates to the latest Bevy. Just to recap some discussion: - Overall this seems like a win for code quality, especially when implementing these traits, but a loss for having to deal with ErasedXXX variants. - `ConditionalSend` was the preferred name for the trait that might be Send, to deal with wasm platforms. - When reviewing be sure to disable whitespace difference, as that's 95% of the PR. ## Changelog - AssetReader, AssetWriter, AssetLoader, AssetSaver and Process now use async-fn in traits rather than boxed futures. ## Migration Guide - Custom implementations of AssetReader, AssetWriter, AssetLoader, AssetSaver and Process should switch to async fn rather than returning a bevy_utils::BoxedFuture. - Simultaniously, to use dynamic dispatch on these traits you should instead use dyn ErasedXXX.
2024-03-18 17:56:57 +00:00
Ok(GzAsset { uncompressed })
Added Method to Allow Pipelined Asset Loading (#10565) # Objective - Fixes #10518 ## Solution I've added a method to `LoadContext`, `load_direct_with_reader`, which mirrors the behaviour of `load_direct` with a single key difference: it is provided with the `Reader` by the caller, rather than getting it from the contained `AssetServer`. This allows for an `AssetLoader` to process its `Reader` stream, and then directly hand the results off to the `LoadContext` to handle further loading. The outer `AssetLoader` can control how the `Reader` is interpreted by providing a relevant `AssetPath`. For example, a Gzip decompression loader could process the asset `images/my_image.png.gz` by decompressing the bytes, then handing the decompressed result to the `LoadContext` with the new path `images/my_image.png.gz/my_image.png`. This intuitively reflects the nature of contained assets, whilst avoiding unintended behaviour, since the generated path cannot be a real file path (a file and folder of the same name cannot coexist in most file-systems). ```rust #[derive(Asset, TypePath)] pub struct GzAsset { pub uncompressed: ErasedLoadedAsset, } #[derive(Default)] pub struct GzAssetLoader; impl AssetLoader for GzAssetLoader { type Asset = GzAsset; type Settings = (); type Error = GzAssetLoaderError; fn load<'a>( &'a self, reader: &'a mut Reader, _settings: &'a (), load_context: &'a mut LoadContext, ) -> BoxedFuture<'a, Result<Self::Asset, Self::Error>> { Box::pin(async move { let compressed_path = load_context.path(); let file_name = compressed_path .file_name() .ok_or(GzAssetLoaderError::IndeterminateFilePath)? .to_string_lossy(); let uncompressed_file_name = file_name .strip_suffix(".gz") .ok_or(GzAssetLoaderError::IndeterminateFilePath)?; let contained_path = compressed_path.join(uncompressed_file_name); let mut bytes_compressed = Vec::new(); reader.read_to_end(&mut bytes_compressed).await?; let mut decoder = GzDecoder::new(bytes_compressed.as_slice()); let mut bytes_uncompressed = Vec::new(); decoder.read_to_end(&mut bytes_uncompressed)?; // Now that we have decompressed the asset, let's pass it back to the // context to continue loading let mut reader = VecReader::new(bytes_uncompressed); let uncompressed = load_context .load_direct_with_reader(&mut reader, contained_path) .await?; Ok(GzAsset { uncompressed }) }) } fn extensions(&self) -> &[&str] { &["gz"] } } ``` Because this example is so prudent, I've included an `asset_decompression` example which implements this exact behaviour: ```rust fn main() { App::new() .add_plugins(DefaultPlugins) .init_asset::<GzAsset>() .init_asset_loader::<GzAssetLoader>() .add_systems(Startup, setup) .add_systems(Update, decompress::<Image>) .run(); } fn setup(mut commands: Commands, asset_server: Res<AssetServer>) { commands.spawn(Camera2dBundle::default()); commands.spawn(( Compressed::<Image> { compressed: asset_server.load("data/compressed_image.png.gz"), ..default() }, Sprite::default(), TransformBundle::default(), VisibilityBundle::default(), )); } fn decompress<A: Asset>( mut commands: Commands, asset_server: Res<AssetServer>, mut compressed_assets: ResMut<Assets<GzAsset>>, query: Query<(Entity, &Compressed<A>)>, ) { for (entity, Compressed { compressed, .. }) in query.iter() { let Some(GzAsset { uncompressed }) = compressed_assets.remove(compressed) else { continue; }; let uncompressed = uncompressed.take::<A>().unwrap(); commands .entity(entity) .remove::<Compressed<A>>() .insert(asset_server.add(uncompressed)); } } ``` A key limitation to this design is how to type the internally loaded asset, since the example `GzAssetLoader` is unaware of the internal asset type `A`. As such, in this example I store the contained asset as an `ErasedLoadedAsset`, and leave it up to the consumer of the `GzAsset` to handle typing the final result, which is the purpose of the `decompress` system. This limitation can be worked around by providing type information to the `GzAssetLoader`, such as `GzAssetLoader<Image, ImageAssetLoader>`, but this would require registering the asset loader for every possible decompression target. Aside from this limitation, nested asset containerisation works as an end user would expect; if the user registers a `TarAssetLoader`, and a `GzAssetLoader`, then they can load assets with compound containerisation, such as `images.tar.gz`. --- ## Changelog - Added `LoadContext::load_direct_with_reader` - Added `asset_decompression` example ## Notes - While I believe my implementation of a Gzip asset loader is reasonable, I haven't included it as a public feature of `bevy_asset` to keep the scope of this PR as focussed as possible. - I have included `flate2` as a `dev-dependency` for the example; it is not included in the main dependency graph.
2023-11-16 17:47:31 +00:00
}
fn extensions(&self) -> &[&str] {
&["gz"]
}
}
#[derive(Component, Default)]
struct Compressed<T> {
compressed: Handle<GzAsset>,
_phantom: PhantomData<T>,
}
fn main() {
App::new()
.add_plugins(DefaultPlugins)
.init_asset::<GzAsset>()
.init_asset_loader::<GzAssetLoader>()
.add_systems(Startup, setup)
.add_systems(Update, decompress::<Sprite, Image>)
Added Method to Allow Pipelined Asset Loading (#10565) # Objective - Fixes #10518 ## Solution I've added a method to `LoadContext`, `load_direct_with_reader`, which mirrors the behaviour of `load_direct` with a single key difference: it is provided with the `Reader` by the caller, rather than getting it from the contained `AssetServer`. This allows for an `AssetLoader` to process its `Reader` stream, and then directly hand the results off to the `LoadContext` to handle further loading. The outer `AssetLoader` can control how the `Reader` is interpreted by providing a relevant `AssetPath`. For example, a Gzip decompression loader could process the asset `images/my_image.png.gz` by decompressing the bytes, then handing the decompressed result to the `LoadContext` with the new path `images/my_image.png.gz/my_image.png`. This intuitively reflects the nature of contained assets, whilst avoiding unintended behaviour, since the generated path cannot be a real file path (a file and folder of the same name cannot coexist in most file-systems). ```rust #[derive(Asset, TypePath)] pub struct GzAsset { pub uncompressed: ErasedLoadedAsset, } #[derive(Default)] pub struct GzAssetLoader; impl AssetLoader for GzAssetLoader { type Asset = GzAsset; type Settings = (); type Error = GzAssetLoaderError; fn load<'a>( &'a self, reader: &'a mut Reader, _settings: &'a (), load_context: &'a mut LoadContext, ) -> BoxedFuture<'a, Result<Self::Asset, Self::Error>> { Box::pin(async move { let compressed_path = load_context.path(); let file_name = compressed_path .file_name() .ok_or(GzAssetLoaderError::IndeterminateFilePath)? .to_string_lossy(); let uncompressed_file_name = file_name .strip_suffix(".gz") .ok_or(GzAssetLoaderError::IndeterminateFilePath)?; let contained_path = compressed_path.join(uncompressed_file_name); let mut bytes_compressed = Vec::new(); reader.read_to_end(&mut bytes_compressed).await?; let mut decoder = GzDecoder::new(bytes_compressed.as_slice()); let mut bytes_uncompressed = Vec::new(); decoder.read_to_end(&mut bytes_uncompressed)?; // Now that we have decompressed the asset, let's pass it back to the // context to continue loading let mut reader = VecReader::new(bytes_uncompressed); let uncompressed = load_context .load_direct_with_reader(&mut reader, contained_path) .await?; Ok(GzAsset { uncompressed }) }) } fn extensions(&self) -> &[&str] { &["gz"] } } ``` Because this example is so prudent, I've included an `asset_decompression` example which implements this exact behaviour: ```rust fn main() { App::new() .add_plugins(DefaultPlugins) .init_asset::<GzAsset>() .init_asset_loader::<GzAssetLoader>() .add_systems(Startup, setup) .add_systems(Update, decompress::<Image>) .run(); } fn setup(mut commands: Commands, asset_server: Res<AssetServer>) { commands.spawn(Camera2dBundle::default()); commands.spawn(( Compressed::<Image> { compressed: asset_server.load("data/compressed_image.png.gz"), ..default() }, Sprite::default(), TransformBundle::default(), VisibilityBundle::default(), )); } fn decompress<A: Asset>( mut commands: Commands, asset_server: Res<AssetServer>, mut compressed_assets: ResMut<Assets<GzAsset>>, query: Query<(Entity, &Compressed<A>)>, ) { for (entity, Compressed { compressed, .. }) in query.iter() { let Some(GzAsset { uncompressed }) = compressed_assets.remove(compressed) else { continue; }; let uncompressed = uncompressed.take::<A>().unwrap(); commands .entity(entity) .remove::<Compressed<A>>() .insert(asset_server.add(uncompressed)); } } ``` A key limitation to this design is how to type the internally loaded asset, since the example `GzAssetLoader` is unaware of the internal asset type `A`. As such, in this example I store the contained asset as an `ErasedLoadedAsset`, and leave it up to the consumer of the `GzAsset` to handle typing the final result, which is the purpose of the `decompress` system. This limitation can be worked around by providing type information to the `GzAssetLoader`, such as `GzAssetLoader<Image, ImageAssetLoader>`, but this would require registering the asset loader for every possible decompression target. Aside from this limitation, nested asset containerisation works as an end user would expect; if the user registers a `TarAssetLoader`, and a `GzAssetLoader`, then they can load assets with compound containerisation, such as `images.tar.gz`. --- ## Changelog - Added `LoadContext::load_direct_with_reader` - Added `asset_decompression` example ## Notes - While I believe my implementation of a Gzip asset loader is reasonable, I haven't included it as a public feature of `bevy_asset` to keep the scope of this PR as focussed as possible. - I have included `flate2` as a `dev-dependency` for the example; it is not included in the main dependency graph.
2023-11-16 17:47:31 +00:00
.run();
}
fn setup(mut commands: Commands, asset_server: Res<AssetServer>) {
commands.spawn(Camera2d);
Added Method to Allow Pipelined Asset Loading (#10565) # Objective - Fixes #10518 ## Solution I've added a method to `LoadContext`, `load_direct_with_reader`, which mirrors the behaviour of `load_direct` with a single key difference: it is provided with the `Reader` by the caller, rather than getting it from the contained `AssetServer`. This allows for an `AssetLoader` to process its `Reader` stream, and then directly hand the results off to the `LoadContext` to handle further loading. The outer `AssetLoader` can control how the `Reader` is interpreted by providing a relevant `AssetPath`. For example, a Gzip decompression loader could process the asset `images/my_image.png.gz` by decompressing the bytes, then handing the decompressed result to the `LoadContext` with the new path `images/my_image.png.gz/my_image.png`. This intuitively reflects the nature of contained assets, whilst avoiding unintended behaviour, since the generated path cannot be a real file path (a file and folder of the same name cannot coexist in most file-systems). ```rust #[derive(Asset, TypePath)] pub struct GzAsset { pub uncompressed: ErasedLoadedAsset, } #[derive(Default)] pub struct GzAssetLoader; impl AssetLoader for GzAssetLoader { type Asset = GzAsset; type Settings = (); type Error = GzAssetLoaderError; fn load<'a>( &'a self, reader: &'a mut Reader, _settings: &'a (), load_context: &'a mut LoadContext, ) -> BoxedFuture<'a, Result<Self::Asset, Self::Error>> { Box::pin(async move { let compressed_path = load_context.path(); let file_name = compressed_path .file_name() .ok_or(GzAssetLoaderError::IndeterminateFilePath)? .to_string_lossy(); let uncompressed_file_name = file_name .strip_suffix(".gz") .ok_or(GzAssetLoaderError::IndeterminateFilePath)?; let contained_path = compressed_path.join(uncompressed_file_name); let mut bytes_compressed = Vec::new(); reader.read_to_end(&mut bytes_compressed).await?; let mut decoder = GzDecoder::new(bytes_compressed.as_slice()); let mut bytes_uncompressed = Vec::new(); decoder.read_to_end(&mut bytes_uncompressed)?; // Now that we have decompressed the asset, let's pass it back to the // context to continue loading let mut reader = VecReader::new(bytes_uncompressed); let uncompressed = load_context .load_direct_with_reader(&mut reader, contained_path) .await?; Ok(GzAsset { uncompressed }) }) } fn extensions(&self) -> &[&str] { &["gz"] } } ``` Because this example is so prudent, I've included an `asset_decompression` example which implements this exact behaviour: ```rust fn main() { App::new() .add_plugins(DefaultPlugins) .init_asset::<GzAsset>() .init_asset_loader::<GzAssetLoader>() .add_systems(Startup, setup) .add_systems(Update, decompress::<Image>) .run(); } fn setup(mut commands: Commands, asset_server: Res<AssetServer>) { commands.spawn(Camera2dBundle::default()); commands.spawn(( Compressed::<Image> { compressed: asset_server.load("data/compressed_image.png.gz"), ..default() }, Sprite::default(), TransformBundle::default(), VisibilityBundle::default(), )); } fn decompress<A: Asset>( mut commands: Commands, asset_server: Res<AssetServer>, mut compressed_assets: ResMut<Assets<GzAsset>>, query: Query<(Entity, &Compressed<A>)>, ) { for (entity, Compressed { compressed, .. }) in query.iter() { let Some(GzAsset { uncompressed }) = compressed_assets.remove(compressed) else { continue; }; let uncompressed = uncompressed.take::<A>().unwrap(); commands .entity(entity) .remove::<Compressed<A>>() .insert(asset_server.add(uncompressed)); } } ``` A key limitation to this design is how to type the internally loaded asset, since the example `GzAssetLoader` is unaware of the internal asset type `A`. As such, in this example I store the contained asset as an `ErasedLoadedAsset`, and leave it up to the consumer of the `GzAsset` to handle typing the final result, which is the purpose of the `decompress` system. This limitation can be worked around by providing type information to the `GzAssetLoader`, such as `GzAssetLoader<Image, ImageAssetLoader>`, but this would require registering the asset loader for every possible decompression target. Aside from this limitation, nested asset containerisation works as an end user would expect; if the user registers a `TarAssetLoader`, and a `GzAssetLoader`, then they can load assets with compound containerisation, such as `images.tar.gz`. --- ## Changelog - Added `LoadContext::load_direct_with_reader` - Added `asset_decompression` example ## Notes - While I believe my implementation of a Gzip asset loader is reasonable, I haven't included it as a public feature of `bevy_asset` to keep the scope of this PR as focussed as possible. - I have included `flate2` as a `dev-dependency` for the example; it is not included in the main dependency graph.
2023-11-16 17:47:31 +00:00
commands.spawn(Compressed::<Image> {
compressed: asset_server.load("data/compressed_image.png.gz"),
..default()
});
Added Method to Allow Pipelined Asset Loading (#10565) # Objective - Fixes #10518 ## Solution I've added a method to `LoadContext`, `load_direct_with_reader`, which mirrors the behaviour of `load_direct` with a single key difference: it is provided with the `Reader` by the caller, rather than getting it from the contained `AssetServer`. This allows for an `AssetLoader` to process its `Reader` stream, and then directly hand the results off to the `LoadContext` to handle further loading. The outer `AssetLoader` can control how the `Reader` is interpreted by providing a relevant `AssetPath`. For example, a Gzip decompression loader could process the asset `images/my_image.png.gz` by decompressing the bytes, then handing the decompressed result to the `LoadContext` with the new path `images/my_image.png.gz/my_image.png`. This intuitively reflects the nature of contained assets, whilst avoiding unintended behaviour, since the generated path cannot be a real file path (a file and folder of the same name cannot coexist in most file-systems). ```rust #[derive(Asset, TypePath)] pub struct GzAsset { pub uncompressed: ErasedLoadedAsset, } #[derive(Default)] pub struct GzAssetLoader; impl AssetLoader for GzAssetLoader { type Asset = GzAsset; type Settings = (); type Error = GzAssetLoaderError; fn load<'a>( &'a self, reader: &'a mut Reader, _settings: &'a (), load_context: &'a mut LoadContext, ) -> BoxedFuture<'a, Result<Self::Asset, Self::Error>> { Box::pin(async move { let compressed_path = load_context.path(); let file_name = compressed_path .file_name() .ok_or(GzAssetLoaderError::IndeterminateFilePath)? .to_string_lossy(); let uncompressed_file_name = file_name .strip_suffix(".gz") .ok_or(GzAssetLoaderError::IndeterminateFilePath)?; let contained_path = compressed_path.join(uncompressed_file_name); let mut bytes_compressed = Vec::new(); reader.read_to_end(&mut bytes_compressed).await?; let mut decoder = GzDecoder::new(bytes_compressed.as_slice()); let mut bytes_uncompressed = Vec::new(); decoder.read_to_end(&mut bytes_uncompressed)?; // Now that we have decompressed the asset, let's pass it back to the // context to continue loading let mut reader = VecReader::new(bytes_uncompressed); let uncompressed = load_context .load_direct_with_reader(&mut reader, contained_path) .await?; Ok(GzAsset { uncompressed }) }) } fn extensions(&self) -> &[&str] { &["gz"] } } ``` Because this example is so prudent, I've included an `asset_decompression` example which implements this exact behaviour: ```rust fn main() { App::new() .add_plugins(DefaultPlugins) .init_asset::<GzAsset>() .init_asset_loader::<GzAssetLoader>() .add_systems(Startup, setup) .add_systems(Update, decompress::<Image>) .run(); } fn setup(mut commands: Commands, asset_server: Res<AssetServer>) { commands.spawn(Camera2dBundle::default()); commands.spawn(( Compressed::<Image> { compressed: asset_server.load("data/compressed_image.png.gz"), ..default() }, Sprite::default(), TransformBundle::default(), VisibilityBundle::default(), )); } fn decompress<A: Asset>( mut commands: Commands, asset_server: Res<AssetServer>, mut compressed_assets: ResMut<Assets<GzAsset>>, query: Query<(Entity, &Compressed<A>)>, ) { for (entity, Compressed { compressed, .. }) in query.iter() { let Some(GzAsset { uncompressed }) = compressed_assets.remove(compressed) else { continue; }; let uncompressed = uncompressed.take::<A>().unwrap(); commands .entity(entity) .remove::<Compressed<A>>() .insert(asset_server.add(uncompressed)); } } ``` A key limitation to this design is how to type the internally loaded asset, since the example `GzAssetLoader` is unaware of the internal asset type `A`. As such, in this example I store the contained asset as an `ErasedLoadedAsset`, and leave it up to the consumer of the `GzAsset` to handle typing the final result, which is the purpose of the `decompress` system. This limitation can be worked around by providing type information to the `GzAssetLoader`, such as `GzAssetLoader<Image, ImageAssetLoader>`, but this would require registering the asset loader for every possible decompression target. Aside from this limitation, nested asset containerisation works as an end user would expect; if the user registers a `TarAssetLoader`, and a `GzAssetLoader`, then they can load assets with compound containerisation, such as `images.tar.gz`. --- ## Changelog - Added `LoadContext::load_direct_with_reader` - Added `asset_decompression` example ## Notes - While I believe my implementation of a Gzip asset loader is reasonable, I haven't included it as a public feature of `bevy_asset` to keep the scope of this PR as focussed as possible. - I have included `flate2` as a `dev-dependency` for the example; it is not included in the main dependency graph.
2023-11-16 17:47:31 +00:00
}
fn decompress<T: Component + From<Handle<A>>, A: Asset>(
Added Method to Allow Pipelined Asset Loading (#10565) # Objective - Fixes #10518 ## Solution I've added a method to `LoadContext`, `load_direct_with_reader`, which mirrors the behaviour of `load_direct` with a single key difference: it is provided with the `Reader` by the caller, rather than getting it from the contained `AssetServer`. This allows for an `AssetLoader` to process its `Reader` stream, and then directly hand the results off to the `LoadContext` to handle further loading. The outer `AssetLoader` can control how the `Reader` is interpreted by providing a relevant `AssetPath`. For example, a Gzip decompression loader could process the asset `images/my_image.png.gz` by decompressing the bytes, then handing the decompressed result to the `LoadContext` with the new path `images/my_image.png.gz/my_image.png`. This intuitively reflects the nature of contained assets, whilst avoiding unintended behaviour, since the generated path cannot be a real file path (a file and folder of the same name cannot coexist in most file-systems). ```rust #[derive(Asset, TypePath)] pub struct GzAsset { pub uncompressed: ErasedLoadedAsset, } #[derive(Default)] pub struct GzAssetLoader; impl AssetLoader for GzAssetLoader { type Asset = GzAsset; type Settings = (); type Error = GzAssetLoaderError; fn load<'a>( &'a self, reader: &'a mut Reader, _settings: &'a (), load_context: &'a mut LoadContext, ) -> BoxedFuture<'a, Result<Self::Asset, Self::Error>> { Box::pin(async move { let compressed_path = load_context.path(); let file_name = compressed_path .file_name() .ok_or(GzAssetLoaderError::IndeterminateFilePath)? .to_string_lossy(); let uncompressed_file_name = file_name .strip_suffix(".gz") .ok_or(GzAssetLoaderError::IndeterminateFilePath)?; let contained_path = compressed_path.join(uncompressed_file_name); let mut bytes_compressed = Vec::new(); reader.read_to_end(&mut bytes_compressed).await?; let mut decoder = GzDecoder::new(bytes_compressed.as_slice()); let mut bytes_uncompressed = Vec::new(); decoder.read_to_end(&mut bytes_uncompressed)?; // Now that we have decompressed the asset, let's pass it back to the // context to continue loading let mut reader = VecReader::new(bytes_uncompressed); let uncompressed = load_context .load_direct_with_reader(&mut reader, contained_path) .await?; Ok(GzAsset { uncompressed }) }) } fn extensions(&self) -> &[&str] { &["gz"] } } ``` Because this example is so prudent, I've included an `asset_decompression` example which implements this exact behaviour: ```rust fn main() { App::new() .add_plugins(DefaultPlugins) .init_asset::<GzAsset>() .init_asset_loader::<GzAssetLoader>() .add_systems(Startup, setup) .add_systems(Update, decompress::<Image>) .run(); } fn setup(mut commands: Commands, asset_server: Res<AssetServer>) { commands.spawn(Camera2dBundle::default()); commands.spawn(( Compressed::<Image> { compressed: asset_server.load("data/compressed_image.png.gz"), ..default() }, Sprite::default(), TransformBundle::default(), VisibilityBundle::default(), )); } fn decompress<A: Asset>( mut commands: Commands, asset_server: Res<AssetServer>, mut compressed_assets: ResMut<Assets<GzAsset>>, query: Query<(Entity, &Compressed<A>)>, ) { for (entity, Compressed { compressed, .. }) in query.iter() { let Some(GzAsset { uncompressed }) = compressed_assets.remove(compressed) else { continue; }; let uncompressed = uncompressed.take::<A>().unwrap(); commands .entity(entity) .remove::<Compressed<A>>() .insert(asset_server.add(uncompressed)); } } ``` A key limitation to this design is how to type the internally loaded asset, since the example `GzAssetLoader` is unaware of the internal asset type `A`. As such, in this example I store the contained asset as an `ErasedLoadedAsset`, and leave it up to the consumer of the `GzAsset` to handle typing the final result, which is the purpose of the `decompress` system. This limitation can be worked around by providing type information to the `GzAssetLoader`, such as `GzAssetLoader<Image, ImageAssetLoader>`, but this would require registering the asset loader for every possible decompression target. Aside from this limitation, nested asset containerisation works as an end user would expect; if the user registers a `TarAssetLoader`, and a `GzAssetLoader`, then they can load assets with compound containerisation, such as `images.tar.gz`. --- ## Changelog - Added `LoadContext::load_direct_with_reader` - Added `asset_decompression` example ## Notes - While I believe my implementation of a Gzip asset loader is reasonable, I haven't included it as a public feature of `bevy_asset` to keep the scope of this PR as focussed as possible. - I have included `flate2` as a `dev-dependency` for the example; it is not included in the main dependency graph.
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mut commands: Commands,
asset_server: Res<AssetServer>,
mut compressed_assets: ResMut<Assets<GzAsset>>,
query: Query<(Entity, &Compressed<A>)>,
) {
for (entity, Compressed { compressed, .. }) in query.iter() {
let Some(GzAsset { uncompressed }) = compressed_assets.remove(compressed) else {
continue;
};
let uncompressed = uncompressed.take::<A>().unwrap();
commands
.entity(entity)
.remove::<Compressed<A>>()
.insert(T::from(asset_server.add(uncompressed)));
Added Method to Allow Pipelined Asset Loading (#10565) # Objective - Fixes #10518 ## Solution I've added a method to `LoadContext`, `load_direct_with_reader`, which mirrors the behaviour of `load_direct` with a single key difference: it is provided with the `Reader` by the caller, rather than getting it from the contained `AssetServer`. This allows for an `AssetLoader` to process its `Reader` stream, and then directly hand the results off to the `LoadContext` to handle further loading. The outer `AssetLoader` can control how the `Reader` is interpreted by providing a relevant `AssetPath`. For example, a Gzip decompression loader could process the asset `images/my_image.png.gz` by decompressing the bytes, then handing the decompressed result to the `LoadContext` with the new path `images/my_image.png.gz/my_image.png`. This intuitively reflects the nature of contained assets, whilst avoiding unintended behaviour, since the generated path cannot be a real file path (a file and folder of the same name cannot coexist in most file-systems). ```rust #[derive(Asset, TypePath)] pub struct GzAsset { pub uncompressed: ErasedLoadedAsset, } #[derive(Default)] pub struct GzAssetLoader; impl AssetLoader for GzAssetLoader { type Asset = GzAsset; type Settings = (); type Error = GzAssetLoaderError; fn load<'a>( &'a self, reader: &'a mut Reader, _settings: &'a (), load_context: &'a mut LoadContext, ) -> BoxedFuture<'a, Result<Self::Asset, Self::Error>> { Box::pin(async move { let compressed_path = load_context.path(); let file_name = compressed_path .file_name() .ok_or(GzAssetLoaderError::IndeterminateFilePath)? .to_string_lossy(); let uncompressed_file_name = file_name .strip_suffix(".gz") .ok_or(GzAssetLoaderError::IndeterminateFilePath)?; let contained_path = compressed_path.join(uncompressed_file_name); let mut bytes_compressed = Vec::new(); reader.read_to_end(&mut bytes_compressed).await?; let mut decoder = GzDecoder::new(bytes_compressed.as_slice()); let mut bytes_uncompressed = Vec::new(); decoder.read_to_end(&mut bytes_uncompressed)?; // Now that we have decompressed the asset, let's pass it back to the // context to continue loading let mut reader = VecReader::new(bytes_uncompressed); let uncompressed = load_context .load_direct_with_reader(&mut reader, contained_path) .await?; Ok(GzAsset { uncompressed }) }) } fn extensions(&self) -> &[&str] { &["gz"] } } ``` Because this example is so prudent, I've included an `asset_decompression` example which implements this exact behaviour: ```rust fn main() { App::new() .add_plugins(DefaultPlugins) .init_asset::<GzAsset>() .init_asset_loader::<GzAssetLoader>() .add_systems(Startup, setup) .add_systems(Update, decompress::<Image>) .run(); } fn setup(mut commands: Commands, asset_server: Res<AssetServer>) { commands.spawn(Camera2dBundle::default()); commands.spawn(( Compressed::<Image> { compressed: asset_server.load("data/compressed_image.png.gz"), ..default() }, Sprite::default(), TransformBundle::default(), VisibilityBundle::default(), )); } fn decompress<A: Asset>( mut commands: Commands, asset_server: Res<AssetServer>, mut compressed_assets: ResMut<Assets<GzAsset>>, query: Query<(Entity, &Compressed<A>)>, ) { for (entity, Compressed { compressed, .. }) in query.iter() { let Some(GzAsset { uncompressed }) = compressed_assets.remove(compressed) else { continue; }; let uncompressed = uncompressed.take::<A>().unwrap(); commands .entity(entity) .remove::<Compressed<A>>() .insert(asset_server.add(uncompressed)); } } ``` A key limitation to this design is how to type the internally loaded asset, since the example `GzAssetLoader` is unaware of the internal asset type `A`. As such, in this example I store the contained asset as an `ErasedLoadedAsset`, and leave it up to the consumer of the `GzAsset` to handle typing the final result, which is the purpose of the `decompress` system. This limitation can be worked around by providing type information to the `GzAssetLoader`, such as `GzAssetLoader<Image, ImageAssetLoader>`, but this would require registering the asset loader for every possible decompression target. Aside from this limitation, nested asset containerisation works as an end user would expect; if the user registers a `TarAssetLoader`, and a `GzAssetLoader`, then they can load assets with compound containerisation, such as `images.tar.gz`. --- ## Changelog - Added `LoadContext::load_direct_with_reader` - Added `asset_decompression` example ## Notes - While I believe my implementation of a Gzip asset loader is reasonable, I haven't included it as a public feature of `bevy_asset` to keep the scope of this PR as focussed as possible. - I have included `flate2` as a `dev-dependency` for the example; it is not included in the main dependency graph.
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}
}