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135 commits
Author | SHA1 | Message | Date | |
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Patrick Walton
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16531fb3e3
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Implement GPU frustum culling. (#12889)
This commit implements opt-in GPU frustum culling, built on top of the infrastructure in https://github.com/bevyengine/bevy/pull/12773. To enable it on a camera, add the `GpuCulling` component to it. To additionally disable CPU frustum culling, add the `NoCpuCulling` component. Note that adding `GpuCulling` without `NoCpuCulling` *currently* does nothing useful. The reason why `GpuCulling` doesn't automatically imply `NoCpuCulling` is that I intend to follow this patch up with GPU two-phase occlusion culling, and CPU frustum culling plus GPU occlusion culling seems like a very commonly-desired mode. Adding the `GpuCulling` component to a view puts that view into *indirect mode*. This mode makes all drawcalls indirect, relying on the mesh preprocessing shader to allocate instances dynamically. In indirect mode, the `PreprocessWorkItem` `output_index` points not to a `MeshUniform` instance slot but instead to a set of `wgpu` `IndirectParameters`, from which it allocates an instance slot dynamically if frustum culling succeeds. Batch building has been updated to allocate and track indirect parameter slots, and the AABBs are now supplied to the GPU as `MeshCullingData`. A small amount of code relating to the frustum culling has been borrowed from meshlets and moved into `maths.wgsl`. Note that standard Bevy frustum culling uses AABBs, while meshlets use bounding spheres; this means that not as much code can be shared as one might think. This patch doesn't provide any way to perform GPU culling on shadow maps, to avoid making this patch bigger than it already is. That can be a followup. ## Changelog ### Added * Frustum culling can now optionally be done on the GPU. To enable it, add the `GpuCulling` component to a camera. * To disable CPU frustum culling, add `NoCpuCulling` to a camera. Note that `GpuCulling` doesn't automatically imply `NoCpuCulling`. |
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BD103
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7b8d502083
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Fix beta lints (#12980)
# Objective - Fixes #12976 ## Solution This one is a doozy. - Run `cargo +beta clippy --workspace --all-targets --all-features` and fix all issues - This includes: - Moving inner attributes to be outer attributes, when the item in question has both inner and outer attributes - Use `ptr::from_ref` in more scenarios - Extend the valid idents list used by `clippy:doc_markdown` with more names - Use `Clone::clone_from` when possible - Remove redundant `ron` import - Add backticks to **so many** identifiers and items - I'm sorry whoever has to review this --- ## Changelog - Added links to more identifiers in documentation. |
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Patrick Walton
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1141e731ff
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Implement alpha to coverage (A2C) support. (#12970)
[Alpha to coverage] (A2C) replaces alpha blending with a hardware-specific multisample coverage mask when multisample antialiasing is in use. It's a simple form of [order-independent transparency] that relies on MSAA. ["Anti-aliased Alpha Test: The Esoteric Alpha To Coverage"] is a good summary of the motivation for and best practices relating to A2C. This commit implements alpha to coverage support as a new variant for `AlphaMode`. You can supply `AlphaMode::AlphaToCoverage` as the `alpha_mode` field in `StandardMaterial` to use it. When in use, the standard material shader automatically applies the texture filtering method from ["Anti-aliased Alpha Test: The Esoteric Alpha To Coverage"]. Objects with alpha-to-coverage materials are binned in the opaque pass, as they're fully order-independent. The `transparency_3d` example has been updated to feature an object with alpha to coverage. Happily, the example was already using MSAA. This is part of #2223, as far as I can tell. [Alpha to coverage]: https://en.wikipedia.org/wiki/Alpha_to_coverage [order-independent transparency]: https://en.wikipedia.org/wiki/Order-independent_transparency ["Anti-aliased Alpha Test: The Esoteric Alpha To Coverage"]: https://bgolus.medium.com/anti-aliased-alpha-test-the-esoteric-alpha-to-coverage-8b177335ae4f --- ## Changelog ### Added * The `AlphaMode` enum now supports `AlphaToCoverage`, to provide limited order-independent transparency when multisample antialiasing is in use. |
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Patrick Walton
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5caf085dac
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Divide the single VisibleEntities list into separate lists for 2D meshes, 3D meshes, lights, and UI elements, for performance. (#12582)
This commit splits `VisibleEntities::entities` into four separate lists: one for lights, one for 2D meshes, one for 3D meshes, and one for UI elements. This allows `queue_material_meshes` and similar methods to avoid examining entities that are obviously irrelevant. In particular, this separation helps scenes with many skinned meshes, as the individual bones are considered visible entities but have no rendered appearance. Internally, `VisibleEntities::entities` is a `HashMap` from the `TypeId` representing a `QueryFilter` to the appropriate `Entity` list. I had to do this because `VisibleEntities` is located within an upstream crate from the crates that provide lights (`bevy_pbr`) and 2D meshes (`bevy_sprite`). As an added benefit, this setup allows apps to provide their own types of renderable components, by simply adding a specialized `check_visibility` to the schedule. This provides a 16.23% end-to-end speedup on `many_foxes` with 10,000 foxes (24.06 ms/frame to 20.70 ms/frame). ## Migration guide * `check_visibility` and `VisibleEntities` now store the four types of renderable entities--2D meshes, 3D meshes, lights, and UI elements--separately. If your custom rendering code examines `VisibleEntities`, it will now need to specify which type of entity it's interested in using the `WithMesh2d`, `WithMesh`, `WithLight`, and `WithNode` types respectively. If your app introduces a new type of renderable entity, you'll need to add an explicit call to `check_visibility` to the schedule to accommodate your new component or components. ## Analysis `many_foxes`, 10,000 foxes: `main`: ![Screenshot 2024-03-31 114444](https://github.com/bevyengine/bevy/assets/157897/16ecb2ff-6e04-46c0-a4b0-b2fde2084bad) `many_foxes`, 10,000 foxes, this branch: ![Screenshot 2024-03-31 114256](https://github.com/bevyengine/bevy/assets/157897/94dedae4-bd00-45b2-9aaf-dfc237004ddb) `queue_material_meshes` (yellow = this branch, red = `main`): ![Screenshot 2024-03-31 114637](https://github.com/bevyengine/bevy/assets/157897/f90912bd-45bd-42c4-bd74-57d98a0f036e) `queue_shadows` (yellow = this branch, red = `main`): ![Screenshot 2024-03-31 114607](https://github.com/bevyengine/bevy/assets/157897/6ce693e3-20c0-4234-8ec9-a6f191299e2d) |
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Patrick Walton
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d59b1e71ef
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Implement percentage-closer filtering (PCF) for point lights. (#12910)
I ported the two existing PCF techniques to the cubemap domain as best I could. Generally, the technique is to create a 2D orthonormal basis using Gram-Schmidt normalization, then apply the technique over that basis. The results look fine, though the shadow bias often needs adjusting. For comparison, Unity uses a 4-tap pattern for PCF on point lights of (1, 1, 1), (-1, -1, 1), (-1, 1, -1), (1, -1, -1). I tried this but didn't like the look, so I went with the design above, which ports the 2D techniques to the 3D domain. There's surprisingly little material on point light PCF. I've gone through every example using point lights and verified that the shadow maps look fine, adjusting biases as necessary. Fixes #3628. --- ## Changelog ### Added * Shadows from point lights now support percentage-closer filtering (PCF), and as a result look less aliased. ### Changed * `ShadowFilteringMethod::Castano13` and `ShadowFilteringMethod::Jimenez14` have been renamed to `ShadowFilteringMethod::Gaussian` and `ShadowFilteringMethod::Temporal` respectively. ## Migration Guide * `ShadowFilteringMethod::Castano13` and `ShadowFilteringMethod::Jimenez14` have been renamed to `ShadowFilteringMethod::Gaussian` and `ShadowFilteringMethod::Temporal` respectively. |
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Patrick Walton
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11817f4ba4
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Generate MeshUniform s on the GPU via compute shader where available. (#12773)
Currently, `MeshUniform`s are rather large: 160 bytes. They're also somewhat expensive to compute, because they involve taking the inverse of a 3x4 matrix. Finally, if a mesh is present in multiple views, that mesh will have a separate `MeshUniform` for each and every view, which is wasteful. This commit fixes these issues by introducing the concept of a *mesh input uniform* and adding a *mesh uniform building* compute shader pass. The `MeshInputUniform` is simply the minimum amount of data needed for the GPU to compute the full `MeshUniform`. Most of this data is just the transform and is therefore only 64 bytes. `MeshInputUniform`s are computed during the *extraction* phase, much like skins are today, in order to avoid needlessly copying transforms around on CPU. (In fact, the render app has been changed to only store the translation of each mesh; it no longer cares about any other part of the transform, which is stored only on the GPU and the main world.) Before rendering, the `build_mesh_uniforms` pass runs to expand the `MeshInputUniform`s to the full `MeshUniform`. The mesh uniform building pass does the following, all on GPU: 1. Copy the appropriate fields of the `MeshInputUniform` to the `MeshUniform` slot. If a single mesh is present in multiple views, this effectively duplicates it into each view. 2. Compute the inverse transpose of the model transform, used for transforming normals. 3. If applicable, copy the mesh's transform from the previous frame for TAA. To support this, we double-buffer the `MeshInputUniform`s over two frames and swap the buffers each frame. The `MeshInputUniform`s for the current frame contain the index of that mesh's `MeshInputUniform` for the previous frame. This commit produces wins in virtually every CPU part of the pipeline: `extract_meshes`, `queue_material_meshes`, `batch_and_prepare_render_phase`, and especially `write_batched_instance_buffer` are all faster. Shrinking the amount of CPU data that has to be shuffled around speeds up the entire rendering process. | Benchmark | This branch | `main` | Speedup | |------------------------|-------------|---------|---------| | `many_cubes -nfc` | 17.259 | 24.529 | 42.12% | | `many_cubes -nfc -vpi` | 302.116 | 312.123 | 3.31% | | `many_foxes` | 3.227 | 3.515 | 8.92% | Because mesh uniform building requires compute shader, and WebGL 2 has no compute shader, the existing CPU mesh uniform building code has been left as-is. Many types now have both CPU mesh uniform building and GPU mesh uniform building modes. Developers can opt into the old CPU mesh uniform building by setting the `use_gpu_uniform_builder` option on `PbrPlugin` to `false`. Below are graphs of the CPU portions of `many-cubes --no-frustum-culling`. Yellow is this branch, red is `main`. `extract_meshes`: ![Screenshot 2024-04-02 124842](https://github.com/bevyengine/bevy/assets/157897/a6748ea4-dd05-47b6-9254-45d07d33cb10) It's notable that we get a small win even though we're now writing to a GPU buffer. `queue_material_meshes`: ![Screenshot 2024-04-02 124911](https://github.com/bevyengine/bevy/assets/157897/ecb44d78-65dc-448d-ba85-2de91aa2ad94) There's a bit of a regression here; not sure what's causing it. In any case it's very outweighed by the other gains. `batch_and_prepare_render_phase`: ![Screenshot 2024-04-02 125123](https://github.com/bevyengine/bevy/assets/157897/4e20fc86-f9dd-4e5c-8623-837e4258f435) There's a huge win here, enough to make batching basically drop off the profile. `write_batched_instance_buffer`: ![Screenshot 2024-04-02 125237](https://github.com/bevyengine/bevy/assets/157897/401a5c32-9dc1-4991-996d-eb1cac6014b2) There's a massive improvement here, as expected. Note that a lot of it simply comes from the fact that `MeshInputUniform` is `Pod`. (This isn't a maintainability problem in my view because `MeshInputUniform` is so simple: just 16 tightly-packed words.) ## Changelog ### Added * Per-mesh instance data is now generated on GPU with a compute shader instead of CPU, resulting in rendering performance improvements on platforms where compute shaders are supported. ## Migration guide * Custom render phases now need multiple systems beyond just `batch_and_prepare_render_phase`. Code that was previously creating custom render phases should now add a `BinnedRenderPhasePlugin` or `SortedRenderPhasePlugin` as appropriate instead of directly adding `batch_and_prepare_render_phase`. |
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Robert Swain
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ab7cbfa8fc
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Consolidate Render(Ui)Materials(2d) into RenderAssets (#12827)
# Objective - Replace `RenderMaterials` / `RenderMaterials2d` / `RenderUiMaterials` with `RenderAssets` to enable implementing changes to one thing, `RenderAssets`, that applies to all use cases rather than duplicating changes everywhere for multiple things that should be one thing. - Adopts #8149 ## Solution - Make RenderAsset generic over the destination type rather than the source type as in #8149 - Use `RenderAssets<PreparedMaterial<M>>` etc for render materials --- ## Changelog - Changed: - The `RenderAsset` trait is now implemented on the destination type. Its `SourceAsset` associated type refers to the type of the source asset. - `RenderMaterials`, `RenderMaterials2d`, and `RenderUiMaterials` have been replaced by `RenderAssets<PreparedMaterial<M>>` and similar. ## Migration Guide - `RenderAsset` is now implemented for the destination type rather that the source asset type. The source asset type is now the `RenderAsset` trait's `SourceAsset` associated type. |
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Patrick Walton
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37522fd0ae
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Micro-optimize queue_material_meshes , primarily to remove bit manipulation. (#12791)
This commit makes the following optimizations: ## `MeshPipelineKey`/`BaseMeshPipelineKey` split `MeshPipelineKey` has been split into `BaseMeshPipelineKey`, which lives in `bevy_render` and `MeshPipelineKey`, which lives in `bevy_pbr`. Conceptually, `BaseMeshPipelineKey` is a superclass of `MeshPipelineKey`. For `BaseMeshPipelineKey`, the bits start at the highest (most significant) bit and grow downward toward the lowest bit; for `MeshPipelineKey`, the bits start at the lowest bit and grow upward toward the highest bit. This prevents them from colliding. The goal of this is to avoid having to reassemble bits of the pipeline key for every mesh every frame. Instead, we can just use a bitwise or operation to combine the pieces that make up a `MeshPipelineKey`. ## `specialize_slow` Previously, all of `specialize()` was marked as `#[inline]`. This bloated `queue_material_meshes` unnecessarily, as a large chunk of it ended up being a slow path that was rarely hit. This commit refactors the function to move the slow path to `specialize_slow()`. Together, these two changes shave about 5% off `queue_material_meshes`: ![Screenshot 2024-03-29 130002](https://github.com/bevyengine/bevy/assets/157897/a7e5a994-a807-4328-b314-9003429dcdd2) ## Migration Guide - The `primitive_topology` field on `GpuMesh` is now an accessor method: `GpuMesh::primitive_topology()`. - For performance reasons, `MeshPipelineKey` has been split into `BaseMeshPipelineKey`, which lives in `bevy_render`, and `MeshPipelineKey`, which lives in `bevy_pbr`. These two should be combined with bitwise-or to produce the final `MeshPipelineKey`. |
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Cameron
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01649f13e2
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Refactor App and SubApp internals for better separation (#9202)
# Objective This is a necessary precursor to #9122 (this was split from that PR to reduce the amount of code to review all at once). Moving `!Send` resource ownership to `App` will make it unambiguously `!Send`. `SubApp` must be `Send`, so it can't wrap `App`. ## Solution Refactor `App` and `SubApp` to not have a recursive relationship. Since `SubApp` no longer wraps `App`, once `!Send` resources are moved out of `World` and into `App`, `SubApp` will become unambiguously `Send`. There could be less code duplication between `App` and `SubApp`, but that would break `App` method chaining. ## Changelog - `SubApp` no longer wraps `App`. - `App` fields are no longer publicly accessible. - `App` can no longer be converted into a `SubApp`. - Various methods now return references to a `SubApp` instead of an `App`. ## Migration Guide - To construct a sub-app, use `SubApp::new()`. `App` can no longer convert into `SubApp`. - If you implemented a trait for `App`, you may want to implement it for `SubApp` as well. - If you're accessing `app.world` directly, you now have to use `app.world()` and `app.world_mut()`. - `App::sub_app` now returns `&SubApp`. - `App::sub_app_mut` now returns `&mut SubApp`. - `App::get_sub_app` now returns `Option<&SubApp>.` - `App::get_sub_app_mut` now returns `Option<&mut SubApp>.` |
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Patrick Walton
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4dadebd9c4
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Improve performance by binning together opaque items instead of sorting them. (#12453)
Today, we sort all entities added to all phases, even the phases that don't strictly need sorting, such as the opaque and shadow phases. This results in a performance loss because our `PhaseItem`s are rather large in memory, so sorting is slow. Additionally, determining the boundaries of batches is an O(n) process. This commit makes Bevy instead applicable place phase items into *bins* keyed by *bin keys*, which have the invariant that everything in the same bin is potentially batchable. This makes determining batch boundaries O(1), because everything in the same bin can be batched. Instead of sorting each entity, we now sort only the bin keys. This drops the sorting time to near-zero on workloads with few bins like `many_cubes --no-frustum-culling`. Memory usage is improved too, with batch boundaries and dynamic indices now implicit instead of explicit. The improved memory usage results in a significant win even on unbatchable workloads like `many_cubes --no-frustum-culling --vary-material-data-per-instance`, presumably due to cache effects. Not all phases can be binned; some, such as transparent and transmissive phases, must still be sorted. To handle this, this commit splits `PhaseItem` into `BinnedPhaseItem` and `SortedPhaseItem`. Most of the logic that today deals with `PhaseItem`s has been moved to `SortedPhaseItem`. `BinnedPhaseItem` has the new logic. Frame time results (in ms/frame) are as follows: | Benchmark | `binning` | `main` | Speedup | | ------------------------ | --------- | ------- | ------- | | `many_cubes -nfc -vpi` | 232.179 | 312.123 | 34.43% | | `many_cubes -nfc` | 25.874 | 30.117 | 16.40% | | `many_foxes` | 3.276 | 3.515 | 7.30% | (`-nfc` is short for `--no-frustum-culling`; `-vpi` is short for `--vary-per-instance`.) --- ## Changelog ### Changed * Render phases have been split into binned and sorted phases. Binned phases, such as the common opaque phase, achieve improved CPU performance by avoiding the sorting step. ## Migration Guide - `PhaseItem` has been split into `BinnedPhaseItem` and `SortedPhaseItem`. If your code has custom `PhaseItem`s, you will need to migrate them to one of these two types. `SortedPhaseItem` requires the fewest code changes, but you may want to pick `BinnedPhaseItem` if your phase doesn't require sorting, as that enables higher performance. ## Tracy graphs `many-cubes --no-frustum-culling`, `main` branch: <img width="1064" alt="Screenshot 2024-03-12 180037" src="https://github.com/bevyengine/bevy/assets/157897/e1180ce8-8e89-46d2-85e3-f59f72109a55"> `many-cubes --no-frustum-culling`, this branch: <img width="1064" alt="Screenshot 2024-03-12 180011" src="https://github.com/bevyengine/bevy/assets/157897/0899f036-6075-44c5-a972-44d95895f46c"> You can see that `batch_and_prepare_binned_render_phase` is a much smaller fraction of the time. Zooming in on that function, with yellow being this branch and red being `main`, we see: <img width="1064" alt="Screenshot 2024-03-12 175832" src="https://github.com/bevyengine/bevy/assets/157897/0dfc8d3f-49f4-496e-8825-a66e64d356d0"> The binning happens in `queue_material_meshes`. Again with yellow being this branch and red being `main`: <img width="1064" alt="Screenshot 2024-03-12 175755" src="https://github.com/bevyengine/bevy/assets/157897/b9b20dc1-11c8-400c-a6cc-1c2e09c1bb96"> We can see that there is a small regression in `queue_material_meshes` performance, but it's not nearly enough to outweigh the large gains in `batch_and_prepare_binned_render_phase`. --------- Co-authored-by: James Liu <contact@jamessliu.com> |
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JMS55
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4f20faaa43
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Meshlet rendering (initial feature) (#10164)
# Objective - Implements a more efficient, GPU-driven (https://github.com/bevyengine/bevy/issues/1342) rendering pipeline based on meshlets. - Meshes are split into small clusters of triangles called meshlets, each of which acts as a mini index buffer into the larger mesh data. Meshlets can be compressed, streamed, culled, and batched much more efficiently than monolithic meshes. ![image](https://github.com/bevyengine/bevy/assets/47158642/cb2aaad0-7a9a-4e14-93b0-15d4e895b26a) ![image](https://github.com/bevyengine/bevy/assets/47158642/7534035b-1eb7-4278-9b99-5322e4401715) # Misc * Future work: https://github.com/bevyengine/bevy/issues/11518 * Nanite reference: https://advances.realtimerendering.com/s2021/Karis_Nanite_SIGGRAPH_Advances_2021_final.pdf Two pass occlusion culling explained very well: https://medium.com/@mil_kru/two-pass-occlusion-culling-4100edcad501 --------- Co-authored-by: Ricky Taylor <rickytaylor26@gmail.com> Co-authored-by: vero <email@atlasdostal.com> Co-authored-by: François <mockersf@gmail.com> Co-authored-by: atlas dostal <rodol@rivalrebels.com> |
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NiseVoid
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ce75dec3b8
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Add setting to enable/disable shadows to MaterialPlugin (#12538)
# Objective - Not all materials need shadow, but a queue_shadows system is always added to the `Render` schedule and executed ## Solution - Make a setting for shadows, it defaults to true ## Changelog - Added `shadows_enabled` setting to `MaterialPlugin` ## Migration Guide - `MaterialPlugin` now has a `shadows_enabled` setting, if you didn't spawn the plugin using `::default()` or `..default()`, you'll need to set it. `shadows_enabled: true` is the same behavior as the previous version, and also the default value. |
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robtfm
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1323de7cd7
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stop retrying removed assets (#12505)
# Objective assets that don't load before they get removed are retried forever, causing buffer churn and slowdown. ## Solution stop trying to prepare dead assets. |
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Patrick Walton
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f9cc91d5a1
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Intern mesh vertex buffer layouts so that we don't have to compare them over and over. (#12216)
Although we cached hashes of `MeshVertexBufferLayout`, we were paying the cost of `PartialEq` on `InnerMeshVertexBufferLayout` for every entity, every frame. This patch changes that logic to place `MeshVertexBufferLayout`s in `Arc`s so that they can be compared and hashed by pointer. This results in a 28% speedup in the `queue_material_meshes` phase of `many_cubes`, with frustum culling disabled. Additionally, this patch contains two minor changes: 1. This commit flattens the specialized mesh pipeline cache to one level of hash tables instead of two. This saves a hash lookup. 2. The example `many_cubes` has been given a `--no-frustum-culling` flag, to aid in benchmarking. See the Tracy profile: <img width="1064" alt="Screenshot 2024-02-29 144406" src="https://github.com/bevyengine/bevy/assets/157897/18632f1d-1fdd-4ac7-90ed-2d10306b2a1e"> ## Migration guide * Duplicate `MeshVertexBufferLayout`s are now combined into a single object, `MeshVertexBufferLayoutRef`, which contains an atomically-reference-counted pointer to the layout. Code that was using `MeshVertexBufferLayout` may need to be updated to use `MeshVertexBufferLayoutRef` instead. |
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Alice Cecile
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599e5e4e76
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Migrate from LegacyColor to bevy_color::Color (#12163)
# Objective - As part of the migration process we need to a) see the end effect of the migration on user ergonomics b) check for serious perf regressions c) actually migrate the code - To accomplish this, I'm going to attempt to migrate all of the remaining user-facing usages of `LegacyColor` in one PR, being careful to keep a clean commit history. - Fixes #12056. ## Solution I've chosen to use the polymorphic `Color` type as our standard user-facing API. - [x] Migrate `bevy_gizmos`. - [x] Take `impl Into<Color>` in all `bevy_gizmos` APIs - [x] Migrate sprites - [x] Migrate UI - [x] Migrate `ColorMaterial` - [x] Migrate `MaterialMesh2D` - [x] Migrate fog - [x] Migrate lights - [x] Migrate StandardMaterial - [x] Migrate wireframes - [x] Migrate clear color - [x] Migrate text - [x] Migrate gltf loader - [x] Register color types for reflection - [x] Remove `LegacyColor` - [x] Make sure CI passes Incidental improvements to ease migration: - added `Color::srgba_u8`, `Color::srgba_from_array` and friends - added `set_alpha`, `is_fully_transparent` and `is_fully_opaque` to the `Alpha` trait - add and immediately deprecate (lol) `Color::rgb` and friends in favor of more explicit and consistent `Color::srgb` - standardized on white and black for most example text colors - added vector field traits to `LinearRgba`: ~~`Add`, `Sub`, `AddAssign`, `SubAssign`,~~ `Mul<f32>` and `Div<f32>`. Multiplications and divisions do not scale alpha. `Add` and `Sub` have been cut from this PR. - added `LinearRgba` and `Srgba` `RED/GREEN/BLUE` - added `LinearRgba_to_f32_array` and `LinearRgba::to_u32` ## Migration Guide Bevy's color types have changed! Wherever you used a `bevy::render::Color`, a `bevy::color::Color` is used instead. These are quite similar! Both are enums storing a color in a specific color space (or to be more precise, using a specific color model). However, each of the different color models now has its own type. TODO... - `Color::rgba`, `Color::rgb`, `Color::rbga_u8`, `Color::rgb_u8`, `Color::rgb_from_array` are now `Color::srgba`, `Color::srgb`, `Color::srgba_u8`, `Color::srgb_u8` and `Color::srgb_from_array`. - `Color::set_a` and `Color::a` is now `Color::set_alpha` and `Color::alpha`. These are part of the `Alpha` trait in `bevy_color`. - `Color::is_fully_transparent` is now part of the `Alpha` trait in `bevy_color` - `Color::r`, `Color::set_r`, `Color::with_r` and the equivalents for `g`, `b` `h`, `s` and `l` have been removed due to causing silent relatively expensive conversions. Convert your `Color` into the desired color space, perform your operations there, and then convert it back into a polymorphic `Color` enum. - `Color::hex` is now `Srgba::hex`. Call `.into` or construct a `Color::Srgba` variant manually to convert it. - `WireframeMaterial`, `ExtractedUiNode`, `ExtractedDirectionalLight`, `ExtractedPointLight`, `ExtractedSpotLight` and `ExtractedSprite` now store a `LinearRgba`, rather than a polymorphic `Color` - `Color::rgb_linear` and `Color::rgba_linear` are now `Color::linear_rgb` and `Color::linear_rgba` - The various CSS color constants are no longer stored directly on `Color`. Instead, they're defined in the `Srgba` color space, and accessed via `bevy::color::palettes::css`. Call `.into()` on them to convert them into a `Color` for quick debugging use, and consider using the much prettier `tailwind` palette for prototyping. - The `LIME_GREEN` color has been renamed to `LIMEGREEN` to comply with the standard naming. - Vector field arithmetic operations on `Color` (add, subtract, multiply and divide by a f32) have been removed. Instead, convert your colors into `LinearRgba` space, and perform your operations explicitly there. This is particularly relevant when working with emissive or HDR colors, whose color channel values are routinely outside of the ordinary 0 to 1 range. - `Color::as_linear_rgba_f32` has been removed. Call `LinearRgba::to_f32_array` instead, converting if needed. - `Color::as_linear_rgba_u32` has been removed. Call `LinearRgba::to_u32` instead, converting if needed. - Several other color conversion methods to transform LCH or HSL colors into float arrays or `Vec` types have been removed. Please reimplement these externally or open a PR to re-add them if you found them particularly useful. - Various methods on `Color` such as `rgb` or `hsl` to convert the color into a specific color space have been removed. Convert into `LinearRgba`, then to the color space of your choice. - Various implicitly-converting color value methods on `Color` such as `r`, `g`, `b` or `h` have been removed. Please convert it into the color space of your choice, then check these properties. - `Color` no longer implements `AsBindGroup`. Store a `LinearRgba` internally instead to avoid conversion costs. --------- Co-authored-by: Alice Cecile <alice.i.cecil@gmail.com> Co-authored-by: Afonso Lage <lage.afonso@gmail.com> Co-authored-by: Rob Parrett <robparrett@gmail.com> Co-authored-by: Zachary Harrold <zac@harrold.com.au> |
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Elabajaba
|
78b6fa1f1b
|
sort alpha masked pipelines by pipeline & mesh instead of by distance (#12117)
# Objective - followup to https://github.com/bevyengine/bevy/pull/11671 - I forgot to change the alpha masked phases. ## Solution - Change the sorting for alpha mask phases to sort by pipeline+mesh instead of distance, for much better batching for alpha masked materials. I also fixed some docs that I missed in the previous PR. --- ## Changelog - Alpha masked materials are now sorted by pipeline and mesh. |
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eri
|
5f8f3b532c
|
Check cfg during CI and fix feature typos (#12103)
# Objective - Add the new `-Zcheck-cfg` checks to catch more warnings - Fixes #12091 ## Solution - Create a new `cfg-check` to the CI that runs `cargo check -Zcheck-cfg --workspace` using cargo nightly (and fails if there are warnings) - Fix all warnings generated by the new check --- ## Changelog - Remove all redundant imports - Fix cfg wasm32 targets - Add 3 dead code exceptions (should StandardColor be unused?) - Convert ios_simulator to a feature (I'm not sure if this is the right way to do it, but the check complained before) ## Migration Guide No breaking changes --------- Co-authored-by: Alice Cecile <alice.i.cecile@gmail.com> |
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Alice Cecile
|
de004da8d5
|
Rename bevy_render::Color to LegacyColor (#12069)
# Objective The migration process for `bevy_color` (#12013) will be fairly involved: there will be hundreds of affected files, and a large number of APIs. ## Solution To allow us to proceed granularly, we're going to keep both `bevy_color::Color` (new) and `bevy_render::Color` (old) around until the migration is complete. However, simply doing this directly is confusing! They're both called `Color`, making it very hard to tell when a portion of the code has been ported. As discussed in #12056, by renaming the old `Color` type, we can make it easier to gradually migrate over, one API at a time. ## Migration Guide THIS MIGRATION GUIDE INTENTIONALLY LEFT BLANK. This change should not be shipped to end users: delete this section in the final migration guide! --------- Co-authored-by: Alice Cecile <alice.i.cecil@gmail.com> |
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IceSentry
|
e79b9b62ce
|
Make more things pub in the renderer (#12053)
# Objective - Some properties of public types are private but sometimes it's useful to be able to set those ## Solution - Make more stuff pub --- ## Changelog - `MaterialBindGroupId` internal id is now pub and added a new() constructor - `ExtractedPointLight` and `ExtractedDirectionalLight` properties are now all pub --------- Co-authored-by: James Liu <contact@jamessliu.com> |
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Ame
|
9d67edc3a6
|
fix some typos (#12038)
# Objective Split - containing only the fixed typos - https://github.com/bevyengine/bevy/pull/12036#pullrequestreview-1894738751 # Migration Guide In `crates/bevy_mikktspace/src/generated.rs` ```rs // before pub struct SGroup { pub iVertexRepresentitive: i32, .. } // after pub struct SGroup { pub iVertexRepresentative: i32, .. } ``` In `crates/bevy_core_pipeline/src/core_2d/mod.rs` ```rs // before Node2D::ConstrastAdaptiveSharpening // after Node2D::ContrastAdaptiveSharpening ``` --------- Co-authored-by: Alice Cecile <alice.i.cecile@gmail.com> Co-authored-by: James Liu <contact@jamessliu.com> Co-authored-by: François <mockersf@gmail.com> |
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James Liu
|
6d547d7ce6
|
Allow Mesh-related queue phase systems to parallelize (#11804)
# Objective Partially addresses #3548. `queue_shadows` and `queue_material_meshes` cannot parallelize because of the `ResMut<RenderMeshInstances>` parameter for `queue_material_meshes`. ## Solution Change the `material_bind_group` field to use atomics instead of needing full mutable access. Change the `ResMut` to a `Res`, which should allow both sets of systems to parallelize without issue. ## Performance Tested against `many_foxes`, this has a significant improvement over the entire render schedule. (Yellow is this PR, red is main) ![image](https://github.com/bevyengine/bevy/assets/3137680/6cc7f346-4f50-4f12-a383-682a9ce1daf6) The use of atomics does seem to have a negative effect on `queue_material_meshes` (roughly a 8.29% increase in time spent in the system). ![image](https://github.com/bevyengine/bevy/assets/3137680/7907079a-863d-4760-aa5b-df68c006ea36) `queue_shadows` seems to be ever so slightly slower (1.6% more time spent) in the system. ![image](https://github.com/bevyengine/bevy/assets/3137680/6d90af73-b922-45e4-bae5-df200e8b9784) `batch_and_prepare_render_phase` seems to be a mix, but overall seems to be slightly *faster* by about 5%. ![image](https://github.com/bevyengine/bevy/assets/3137680/fac638ff-8c90-436b-9362-c6209b18957c) |
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Patrick Walton
|
3af8526786
|
Stop extracting mesh entities to the render world. (#11803)
This fixes a `FIXME` in `extract_meshes` and results in a performance improvement. As a result of this change, meshes in the render world might not be attached to entities anymore. Therefore, the `entity` parameter to `RenderCommand::render()` is now wrapped in an `Option`. Most applications that use the render app's ECS can simply unwrap the `Option`. Note that for now sprites, gizmos, and UI elements still use the render world as usual. ## Migration guide * For efficiency reasons, some meshes in the render world may not have corresponding `Entity` IDs anymore. As a result, the `entity` parameter to `RenderCommand::render()` is now wrapped in an `Option`. Custom rendering code may need to be updated to handle the case in which no `Entity` exists for an object that is to be rendered. |
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Patrick Walton
|
4c15dd0fc5
|
Implement irradiance volumes. (#10268)
# Objective Bevy could benefit from *irradiance volumes*, also known as *voxel global illumination* or simply as light probes (though this term is not preferred, as multiple techniques can be called light probes). Irradiance volumes are a form of baked global illumination; they work by sampling the light at the centers of each voxel within a cuboid. At runtime, the voxels surrounding the fragment center are sampled and interpolated to produce indirect diffuse illumination. ## Solution This is divided into two sections. The first is copied and pasted from the irradiance volume module documentation and describes the technique. The second part consists of notes on the implementation. ### Overview An *irradiance volume* is a cuboid voxel region consisting of regularly-spaced precomputed samples of diffuse indirect light. They're ideal if you have a dynamic object such as a character that can move about static non-moving geometry such as a level in a game, and you want that dynamic object to be affected by the light bouncing off that static geometry. To use irradiance volumes, you need to precompute, or *bake*, the indirect light in your scene. Bevy doesn't currently come with a way to do this. Fortunately, [Blender] provides a [baking tool] as part of the Eevee renderer, and its irradiance volumes are compatible with those used by Bevy. The [`bevy-baked-gi`] project provides a tool, `export-blender-gi`, that can extract the baked irradiance volumes from the Blender `.blend` file and package them up into a `.ktx2` texture for use by the engine. See the documentation in the `bevy-baked-gi` project for more details as to this workflow. Like all light probes in Bevy, irradiance volumes are 1×1×1 cubes that can be arbitrarily scaled, rotated, and positioned in a scene with the [`bevy_transform::components::Transform`] component. The 3D voxel grid will be stretched to fill the interior of the cube, and the illumination from the irradiance volume will apply to all fragments within that bounding region. Bevy's irradiance volumes are based on Valve's [*ambient cubes*] as used in *Half-Life 2* ([Mitchell 2006], slide 27). These encode a single color of light from the six 3D cardinal directions and blend the sides together according to the surface normal. The primary reason for choosing ambient cubes is to match Blender, so that its Eevee renderer can be used for baking. However, they also have some advantages over the common second-order spherical harmonics approach: ambient cubes don't suffer from ringing artifacts, they are smaller (6 colors for ambient cubes as opposed to 9 for spherical harmonics), and evaluation is faster. A smaller basis allows for a denser grid of voxels with the same storage requirements. If you wish to use a tool other than `export-blender-gi` to produce the irradiance volumes, you'll need to pack the irradiance volumes in the following format. The irradiance volume of resolution *(Rx, Ry, Rz)* is expected to be a 3D texture of dimensions *(Rx, 2Ry, 3Rz)*. The unnormalized texture coordinate *(s, t, p)* of the voxel at coordinate *(x, y, z)* with side *S* ∈ *{-X, +X, -Y, +Y, -Z, +Z}* is as follows: ```text s = x t = y + ⎰ 0 if S ∈ {-X, -Y, -Z} ⎱ Ry if S ∈ {+X, +Y, +Z} ⎧ 0 if S ∈ {-X, +X} p = z + ⎨ Rz if S ∈ {-Y, +Y} ⎩ 2Rz if S ∈ {-Z, +Z} ``` Visually, in a left-handed coordinate system with Y up, viewed from the right, the 3D texture looks like a stacked series of voxel grids, one for each cube side, in this order: | **+X** | **+Y** | **+Z** | | ------ | ------ | ------ | | **-X** | **-Y** | **-Z** | A terminology note: Other engines may refer to irradiance volumes as *voxel global illumination*, *VXGI*, or simply as *light probes*. Sometimes *light probe* refers to what Bevy calls a reflection probe. In Bevy, *light probe* is a generic term that encompasses all cuboid bounding regions that capture indirect illumination, whether based on voxels or not. Note that, if binding arrays aren't supported (e.g. on WebGPU or WebGL 2), then only the closest irradiance volume to the view will be taken into account during rendering. [*ambient cubes*]: https://advances.realtimerendering.com/s2006/Mitchell-ShadingInValvesSourceEngine.pdf [Mitchell 2006]: https://advances.realtimerendering.com/s2006/Mitchell-ShadingInValvesSourceEngine.pdf [Blender]: http://blender.org/ [baking tool]: https://docs.blender.org/manual/en/latest/render/eevee/render_settings/indirect_lighting.html [`bevy-baked-gi`]: https://github.com/pcwalton/bevy-baked-gi ### Implementation notes This patch generalizes light probes so as to reuse as much code as possible between irradiance volumes and the existing reflection probes. This approach was chosen because both techniques share numerous similarities: 1. Both irradiance volumes and reflection probes are cuboid bounding regions. 2. Both are responsible for providing baked indirect light. 3. Both techniques involve presenting a variable number of textures to the shader from which indirect light is sampled. (In the current implementation, this uses binding arrays.) 4. Both irradiance volumes and reflection probes require gathering and sorting probes by distance on CPU. 5. Both techniques require the GPU to search through a list of bounding regions. 6. Both will eventually want to have falloff so that we can smoothly blend as objects enter and exit the probes' influence ranges. (This is not implemented yet to keep this patch relatively small and reviewable.) To do this, we generalize most of the methods in the reflection probes patch #11366 to be generic over a trait, `LightProbeComponent`. This trait is implemented by both `EnvironmentMapLight` (for reflection probes) and `IrradianceVolume` (for irradiance volumes). Using a trait will allow us to add more types of light probes in the future. In particular, I highly suspect we will want real-time reflection planes for mirrors in the future, which can be easily slotted into this framework. ## Changelog > This section is optional. If this was a trivial fix, or has no externally-visible impact, you can delete this section. ### Added * A new `IrradianceVolume` asset type is available for baked voxelized light probes. You can bake the global illumination using Blender or another tool of your choice and use it in Bevy to apply indirect illumination to dynamic objects. |
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Elabajaba
|
2a1ebc4ac4
|
sort by pipeline then mesh for non transparent passes for massively better batching (#11671)
# Objective Bevy does ridiculous amount of drawcalls, and our batching isn't very effective because we sort by distance and only batch if we get multiple of the same object in a row. This can give us slightly better GPU performance when not using the depth prepass (due to less overdraw), but ends up being massively CPU bottlenecked due to doing thousands of unnecessary drawcalls. ## Solution Change the sort functions to sort by pipeline key then by mesh id for large performance gains in more realistic scenes than our stress tests. Pipelines changed: - Opaque3d - Opaque3dDeferred - Opaque3dPrepass ![image](https://github.com/bevyengine/bevy/assets/177631/8c355256-ad86-4b47-81a0-f3906797fe7e) --- ## Changelog - Opaque3d drawing order is now sorted by pipeline and mesh, rather than by distance. This trades off a bit of GPU time in exchange for massively better batching in scenes that aren't only drawing huge amounts of a single object. |
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AxiomaticSemantics
|
2ebf5a303e
|
Remove TypeUuid (#11497)
# Objective TypeUuid is deprecated, remove it. ## Migration Guide Convert any uses of `#[derive(TypeUuid)]` with `#[derive(TypePath]` for more complex uses see the relevant [documentation](https://docs.rs/bevy/latest/bevy/prelude/trait.TypePath.html) for more information. --------- Co-authored-by: ebola <dev@axiomatic> |
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Alice Cecile
|
eb07d16871
|
Revert rendering-related associated type name changes (#11027)
# Objective > Can anyone explain to me the reasoning of renaming all the types named Query to Data. I'm talking about this PR https://github.com/bevyengine/bevy/pull/10779 It doesn't make sense to me that a bunch of types that are used to run queries aren't named Query anymore. Like ViewQuery on the ViewNode is the type of the Query. I don't really understand the point of the rename, it just seems like it hides the fact that a query will run based on those types. [@IceSentry](https://discord.com/channels/691052431525675048/692572690833473578/1184946251431694387) ## Solution Revert several renames in #10779. ## Changelog - `ViewNode::ViewData` is now `ViewNode::ViewQuery` again. ## Migration Guide - This PR amends the migration guide in https://github.com/bevyengine/bevy/pull/10779 --------- Co-authored-by: atlas dostal <rodol@rivalrebels.com> |
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Patrick Walton
|
83d6600267
|
Implement minimal reflection probes (fixed macOS, iOS, and Android). (#11366)
This pull request re-submits #10057, which was backed out for breaking macOS, iOS, and Android. I've tested this version on macOS and Android and on the iOS simulator. # Objective This pull request implements *reflection probes*, which generalize environment maps to allow for multiple environment maps in the same scene, each of which has an axis-aligned bounding box. This is a standard feature of physically-based renderers and was inspired by [the corresponding feature in Blender's Eevee renderer]. ## Solution This is a minimal implementation of reflection probes that allows artists to define cuboid bounding regions associated with environment maps. For every view, on every frame, a system builds up a list of the nearest 4 reflection probes that are within the view's frustum and supplies that list to the shader. The PBR fragment shader searches through the list, finds the first containing reflection probe, and uses it for indirect lighting, falling back to the view's environment map if none is found. Both forward and deferred renderers are fully supported. A reflection probe is an entity with a pair of components, *LightProbe* and *EnvironmentMapLight* (as well as the standard *SpatialBundle*, to position it in the world). The *LightProbe* component (along with the *Transform*) defines the bounding region, while the *EnvironmentMapLight* component specifies the associated diffuse and specular cubemaps. A frequent question is "why two components instead of just one?" The advantages of this setup are: 1. It's readily extensible to other types of light probes, in particular *irradiance volumes* (also known as ambient cubes or voxel global illumination), which use the same approach of bounding cuboids. With a single component that applies to both reflection probes and irradiance volumes, we can share the logic that implements falloff and blending between multiple light probes between both of those features. 2. It reduces duplication between the existing *EnvironmentMapLight* and these new reflection probes. Systems can treat environment maps attached to cameras the same way they treat environment maps applied to reflection probes if they wish. Internally, we gather up all environment maps in the scene and place them in a cubemap array. At present, this means that all environment maps must have the same size, mipmap count, and texture format. A warning is emitted if this restriction is violated. We could potentially relax this in the future as part of the automatic mipmap generation work, which could easily do texture format conversion as part of its preprocessing. An easy way to generate reflection probe cubemaps is to bake them in Blender and use the `export-blender-gi` tool that's part of the [`bevy-baked-gi`] project. This tool takes a `.blend` file containing baked cubemaps as input and exports cubemap images, pre-filtered with an embedded fork of the [glTF IBL Sampler], alongside a corresponding `.scn.ron` file that the scene spawner can use to recreate the reflection probes. Note that this is intentionally a minimal implementation, to aid reviewability. Known issues are: * Reflection probes are basically unsupported on WebGL 2, because WebGL 2 has no cubemap arrays. (Strictly speaking, you can have precisely one reflection probe in the scene if you have no other cubemaps anywhere, but this isn't very useful.) * Reflection probes have no falloff, so reflections will abruptly change when objects move from one bounding region to another. * As mentioned before, all cubemaps in the world of a given type (diffuse or specular) must have the same size, format, and mipmap count. Future work includes: * Blending between multiple reflection probes. * A falloff/fade-out region so that reflected objects disappear gradually instead of vanishing all at once. * Irradiance volumes for voxel-based global illumination. This should reuse much of the reflection probe logic, as they're both GI techniques based on cuboid bounding regions. * Support for WebGL 2, by breaking batches when reflection probes are used. These issues notwithstanding, I think it's best to land this with roughly the current set of functionality, because this patch is useful as is and adding everything above would make the pull request significantly larger and harder to review. --- ## Changelog ### Added * A new *LightProbe* component is available that specifies a bounding region that an *EnvironmentMapLight* applies to. The combination of a *LightProbe* and an *EnvironmentMapLight* offers *reflection probe* functionality similar to that available in other engines. [the corresponding feature in Blender's Eevee renderer]: https://docs.blender.org/manual/en/latest/render/eevee/light_probes/reflection_cubemaps.html [`bevy-baked-gi`]: https://github.com/pcwalton/bevy-baked-gi [glTF IBL Sampler]: https://github.com/KhronosGroup/glTF-IBL-Sampler |
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François
|
3d996639a0
|
Revert "Implement minimal reflection probes. (#10057)" (#11307)
# Objective - Fix working on macOS, iOS, Android on main - Fixes #11281 - Fixes #11282 - Fixes #11283 - Fixes #11299 ## Solution - Revert #10057 |
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Jakob Hellermann
|
a657478675
|
resolve all internal ambiguities (#10411)
- ignore all ambiguities that are not a problem - remove `.before(Assets::<Image>::track_assets),` that points into a different schedule (-> should this be caught?) - add some explicit orderings: - run `poll_receivers` and `update_accessibility_nodes` after `window_closed` in `bevy_winit::accessibility` - run `bevy_ui::accessibility::calc_bounds` after `CameraUpdateSystem` - run ` bevy_text::update_text2d_layout` and `bevy_ui::text_system` after `font_atlas_set::remove_dropped_font_atlas_sets` - add `app.ignore_ambiguity(a, b)` function for cases where you want to ignore an ambiguity between two independent plugins `A` and `B` - add `IgnoreAmbiguitiesPlugin` in `DefaultPlugins` that allows cross-crate ambiguities like `bevy_animation`/`bevy_ui` - Fixes https://github.com/bevyengine/bevy/issues/9511 ## Before **Render** ![render_schedule_Render dot](https://github.com/bevyengine/bevy/assets/22177966/1c677968-7873-40cc-848c-91fca4c8e383) **PostUpdate** ![schedule_PostUpdate dot](https://github.com/bevyengine/bevy/assets/22177966/8fc61304-08d4-4533-8110-c04113a7367a) ## After **Render** ![render_schedule_Render dot](https://github.com/bevyengine/bevy/assets/22177966/462f3b28-cef7-4833-8619-1f5175983485) **PostUpdate** ![schedule_PostUpdate dot](https://github.com/bevyengine/bevy/assets/22177966/8cfb3d83-7842-4a84-9082-46177e1a6c70) --------- Co-authored-by: Alice Cecile <alice.i.cecile@gmail.com> Co-authored-by: Alice Cecile <alice.i.cecil@gmail.com> Co-authored-by: François <mockersf@gmail.com> |
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Patrick Walton
|
54a943d232
|
Implement minimal reflection probes. (#10057)
# Objective This pull request implements *reflection probes*, which generalize environment maps to allow for multiple environment maps in the same scene, each of which has an axis-aligned bounding box. This is a standard feature of physically-based renderers and was inspired by [the corresponding feature in Blender's Eevee renderer]. ## Solution This is a minimal implementation of reflection probes that allows artists to define cuboid bounding regions associated with environment maps. For every view, on every frame, a system builds up a list of the nearest 4 reflection probes that are within the view's frustum and supplies that list to the shader. The PBR fragment shader searches through the list, finds the first containing reflection probe, and uses it for indirect lighting, falling back to the view's environment map if none is found. Both forward and deferred renderers are fully supported. A reflection probe is an entity with a pair of components, *LightProbe* and *EnvironmentMapLight* (as well as the standard *SpatialBundle*, to position it in the world). The *LightProbe* component (along with the *Transform*) defines the bounding region, while the *EnvironmentMapLight* component specifies the associated diffuse and specular cubemaps. A frequent question is "why two components instead of just one?" The advantages of this setup are: 1. It's readily extensible to other types of light probes, in particular *irradiance volumes* (also known as ambient cubes or voxel global illumination), which use the same approach of bounding cuboids. With a single component that applies to both reflection probes and irradiance volumes, we can share the logic that implements falloff and blending between multiple light probes between both of those features. 2. It reduces duplication between the existing *EnvironmentMapLight* and these new reflection probes. Systems can treat environment maps attached to cameras the same way they treat environment maps applied to reflection probes if they wish. Internally, we gather up all environment maps in the scene and place them in a cubemap array. At present, this means that all environment maps must have the same size, mipmap count, and texture format. A warning is emitted if this restriction is violated. We could potentially relax this in the future as part of the automatic mipmap generation work, which could easily do texture format conversion as part of its preprocessing. An easy way to generate reflection probe cubemaps is to bake them in Blender and use the `export-blender-gi` tool that's part of the [`bevy-baked-gi`] project. This tool takes a `.blend` file containing baked cubemaps as input and exports cubemap images, pre-filtered with an embedded fork of the [glTF IBL Sampler], alongside a corresponding `.scn.ron` file that the scene spawner can use to recreate the reflection probes. Note that this is intentionally a minimal implementation, to aid reviewability. Known issues are: * Reflection probes are basically unsupported on WebGL 2, because WebGL 2 has no cubemap arrays. (Strictly speaking, you can have precisely one reflection probe in the scene if you have no other cubemaps anywhere, but this isn't very useful.) * Reflection probes have no falloff, so reflections will abruptly change when objects move from one bounding region to another. * As mentioned before, all cubemaps in the world of a given type (diffuse or specular) must have the same size, format, and mipmap count. Future work includes: * Blending between multiple reflection probes. * A falloff/fade-out region so that reflected objects disappear gradually instead of vanishing all at once. * Irradiance volumes for voxel-based global illumination. This should reuse much of the reflection probe logic, as they're both GI techniques based on cuboid bounding regions. * Support for WebGL 2, by breaking batches when reflection probes are used. These issues notwithstanding, I think it's best to land this with roughly the current set of functionality, because this patch is useful as is and adding everything above would make the pull request significantly larger and harder to review. --- ## Changelog ### Added * A new *LightProbe* component is available that specifies a bounding region that an *EnvironmentMapLight* applies to. The combination of a *LightProbe* and an *EnvironmentMapLight* offers *reflection probe* functionality similar to that available in other engines. [the corresponding feature in Blender's Eevee renderer]: https://docs.blender.org/manual/en/latest/render/eevee/light_probes/reflection_cubemaps.html [`bevy-baked-gi`]: https://github.com/pcwalton/bevy-baked-gi [glTF IBL Sampler]: https://github.com/KhronosGroup/glTF-IBL-Sampler |
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JMS55
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44424391fe
|
Unload render assets from RAM (#10520)
# Objective - No point in keeping Meshes/Images in RAM once they're going to be sent to the GPU, and kept in VRAM. This saves a _significant_ amount of memory (several GBs) on scenes like bistro. - References - https://github.com/bevyengine/bevy/pull/1782 - https://github.com/bevyengine/bevy/pull/8624 ## Solution - Augment RenderAsset with the capability to unload the underlying asset after extracting to the render world. - Mesh/Image now have a cpu_persistent_access field. If this field is RenderAssetPersistencePolicy::Unload, the asset will be unloaded from Assets<T>. - A new AssetEvent is sent upon dropping the last strong handle for the asset, which signals to the RenderAsset to remove the GPU version of the asset. --- ## Changelog - Added `AssetEvent::NoLongerUsed` and `AssetEvent::is_no_longer_used()`. This event is sent when the last strong handle of an asset is dropped. - Rewrote the API for `RenderAsset` to allow for unloading the asset data from the CPU. - Added `RenderAssetPersistencePolicy`. - Added `Mesh::cpu_persistent_access` for memory savings when the asset is not needed except for on the GPU. - Added `Image::cpu_persistent_access` for memory savings when the asset is not needed except for on the GPU. - Added `ImageLoaderSettings::cpu_persistent_access`. - Added `ExrTextureLoaderSettings`. - Added `HdrTextureLoaderSettings`. ## Migration Guide - Asset loaders (GLTF, etc) now load meshes and textures without `cpu_persistent_access`. These assets will be removed from `Assets<Mesh>` and `Assets<Image>` once `RenderAssets<Mesh>` and `RenderAssets<Image>` contain the GPU versions of these assets, in order to reduce memory usage. If you require access to the asset data from the CPU in future frames after the GLTF asset has been loaded, modify all dependent `Mesh` and `Image` assets and set `cpu_persistent_access` to `RenderAssetPersistencePolicy::Keep`. - `Mesh` now requires a new `cpu_persistent_access` field. Set it to `RenderAssetPersistencePolicy::Keep` to mimic the previous behavior. - `Image` now requires a new `cpu_persistent_access` field. Set it to `RenderAssetPersistencePolicy::Keep` to mimic the previous behavior. - `MorphTargetImage::new()` now requires a new `cpu_persistent_access` parameter. Set it to `RenderAssetPersistencePolicy::Keep` to mimic the previous behavior. - `DynamicTextureAtlasBuilder::add_texture()` now requires that the `TextureAtlas` you pass has an `Image` with `cpu_persistent_access: RenderAssetPersistencePolicy::Keep`. Ensure you construct the image properly for the texture atlas. - The `RenderAsset` trait has significantly changed, and requires adapting your existing implementations. - The trait now requires `Clone`. - The `ExtractedAsset` associated type has been removed (the type itself is now extracted). - The signature of `prepare_asset()` is slightly different - A new `persistence_policy()` method is now required (return RenderAssetPersistencePolicy::Unload to match the previous behavior). - Match on the new `NoLongerUsed` variant for exhaustive matches of `AssetEvent`. |
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Patrick Walton
|
dd14f3a477
|
Implement lightmaps. (#10231)
![Screenshot](https://i.imgur.com/A4KzWFq.png) # Objective Lightmaps, textures that store baked global illumination, have been a mainstay of real-time graphics for decades. Bevy currently has no support for them, so this pull request implements them. ## Solution The new `Lightmap` component can be attached to any entity that contains a `Handle<Mesh>` and a `StandardMaterial`. When present, it will be applied in the PBR shader. Because multiple lightmaps are frequently packed into atlases, each lightmap may have its own UV boundaries within its texture. An `exposure` field is also provided, to control the brightness of the lightmap. Note that this PR doesn't provide any way to bake the lightmaps. That can be done with [The Lightmapper] or another solution, such as Unity's Bakery. --- ## Changelog ### Added * A new component, `Lightmap`, is available, for baked global illumination. If your mesh has a second UV channel (UV1), and you attach this component to the entity with that mesh, Bevy will apply the texture referenced in the lightmap. [The Lightmapper]: https://github.com/Naxela/The_Lightmapper --------- Co-authored-by: Carter Anderson <mcanders1@gmail.com> |
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Brian Reavis
|
846a871cb2
|
Export tonemapping_pipeline_key (2d), alpha_mode_pipeline_key (#11166)
This expands upon https://github.com/bevyengine/bevy/pull/11134. I found myself needing `tonemapping_pipeline_key` for some custom 2d draw functions. #11134 exported the 3d version of `tonemapping_pipeline_key` and this PR exports the 2d version. I also made `alpha_mode_pipeline_key` public for good measure. |
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Marco Buono
|
c2ab3a0402
|
Do not load prepass normals for transmissive materials (#11140)
Turns out whenever a normal prepass was active (which includes whenever you use SSAO) we were attempting to read the normals from the prepass for the specular transmissive material. Since transmissive materials don't participate in the prepass (unlike opaque materials) we were reading the normals from “behind” the mesh, producing really weird visual results. # Objective - Fixes #11112. ## Solution - We introduce a new `READS_VIEW_TRANSMISSION_TEXTURE` mesh pipeline key; - We set it whenever the material properties has the `reads_view_transmission_texture` flag set; (i.e. the material is transmissive) - If this key is set we prevent the reading of normals from the prepass, by not setting the `LOAD_PREPASS_NORMALS` shader def. --- ## Changelog ### Fixed - Specular transmissive materials no longer attempt to erroneously load prepass normals, and now work correctly even with the normal prepass active (e.g. when using SSAO) |
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JMS55
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3d3a065820
|
Misc cleanup (#11134)
Re-exports a few types/functions I need that have no reason to be private, and some minor code quality changes. |
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Mantas
|
5af2f022d8
|
Rename WorldQueryData & WorldQueryFilter to QueryData & QueryFilter (#10779)
# Rename `WorldQueryData` & `WorldQueryFilter` to `QueryData` & `QueryFilter` Fixes #10776 ## Solution Traits `WorldQueryData` & `WorldQueryFilter` were renamed to `QueryData` and `QueryFilter`, respectively. Related Trait types were also renamed. --- ## Changelog - Trait `WorldQueryData` has been renamed to `QueryData`. Derive macro's `QueryData` attribute `world_query_data` has been renamed to `query_data`. - Trait `WorldQueryFilter` has been renamed to `QueryFilter`. Derive macro's `QueryFilter` attribute `world_query_filter` has been renamed to `query_filter`. - Trait's `ExtractComponent` type `Query` has been renamed to `Data`. - Trait's `GetBatchData` types `Query` & `QueryFilter` has been renamed to `Data` & `Filter`, respectively. - Trait's `ExtractInstance` type `Query` has been renamed to `Data`. - Trait's `ViewNode` type `ViewQuery` has been renamed to `ViewData`. - Trait's `RenderCommand` types `ViewWorldQuery` & `ItemWorldQuery` has been renamed to `ViewData` & `ItemData`, respectively. ## Migration Guide Note: if merged before 0.13 is released, this should instead modify the migration guide of #10776 with the updated names. - Rename `WorldQueryData` & `WorldQueryFilter` trait usages to `QueryData` & `QueryFilter` and their respective derive macro attributes `world_query_data` & `world_query_filter` to `query_data` & `query_filter`. - Rename the following trait type usages: - Trait's `ExtractComponent` type `Query` to `Data`. - Trait's `GetBatchData` type `Query` to `Data`. - Trait's `ExtractInstance` type `Query` to `Data`. - Trait's `ViewNode` type `ViewQuery` to `ViewData`' - Trait's `RenderCommand` types `ViewWolrdQuery` & `ItemWorldQuery` to `ViewData` & `ItemData`, respectively. ```rust // Before #[derive(WorldQueryData)] #[world_query_data(derive(Debug))] struct EmptyQuery { empty: (), } // After #[derive(QueryData)] #[query_data(derive(Debug))] struct EmptyQuery { empty: (), } // Before #[derive(WorldQueryFilter)] struct CustomQueryFilter<T: Component, P: Component> { _c: With<ComponentC>, _d: With<ComponentD>, _or: Or<(Added<ComponentC>, Changed<ComponentD>, Without<ComponentZ>)>, _generic_tuple: (With<T>, With<P>), } // After #[derive(QueryFilter)] struct CustomQueryFilter<T: Component, P: Component> { _c: With<ComponentC>, _d: With<ComponentD>, _or: Or<(Added<ComponentC>, Changed<ComponentD>, Without<ComponentZ>)>, _generic_tuple: (With<T>, With<P>), } // Before impl ExtractComponent for ContrastAdaptiveSharpeningSettings { type Query = &'static Self; type Filter = With<Camera>; type Out = (DenoiseCAS, CASUniform); fn extract_component(item: QueryItem<Self::Query>) -> Option<Self::Out> { //... } } // After impl ExtractComponent for ContrastAdaptiveSharpeningSettings { type Data = &'static Self; type Filter = With<Camera>; type Out = (DenoiseCAS, CASUniform); fn extract_component(item: QueryItem<Self::Data>) -> Option<Self::Out> { //... } } // Before impl GetBatchData for MeshPipeline { type Param = SRes<RenderMeshInstances>; type Query = Entity; type QueryFilter = With<Mesh3d>; type CompareData = (MaterialBindGroupId, AssetId<Mesh>); type BufferData = MeshUniform; fn get_batch_data( mesh_instances: &SystemParamItem<Self::Param>, entity: &QueryItem<Self::Query>, ) -> (Self::BufferData, Option<Self::CompareData>) { // .... } } // After impl GetBatchData for MeshPipeline { type Param = SRes<RenderMeshInstances>; type Data = Entity; type Filter = With<Mesh3d>; type CompareData = (MaterialBindGroupId, AssetId<Mesh>); type BufferData = MeshUniform; fn get_batch_data( mesh_instances: &SystemParamItem<Self::Param>, entity: &QueryItem<Self::Data>, ) -> (Self::BufferData, Option<Self::CompareData>) { // .... } } // Before impl<A> ExtractInstance for AssetId<A> where A: Asset, { type Query = Read<Handle<A>>; type Filter = (); fn extract(item: QueryItem<'_, Self::Query>) -> Option<Self> { Some(item.id()) } } // After impl<A> ExtractInstance for AssetId<A> where A: Asset, { type Data = Read<Handle<A>>; type Filter = (); fn extract(item: QueryItem<'_, Self::Data>) -> Option<Self> { Some(item.id()) } } // Before impl ViewNode for PostProcessNode { type ViewQuery = ( &'static ViewTarget, &'static PostProcessSettings, ); fn run( &self, _graph: &mut RenderGraphContext, render_context: &mut RenderContext, (view_target, _post_process_settings): QueryItem<Self::ViewQuery>, world: &World, ) -> Result<(), NodeRunError> { // ... } } // After impl ViewNode for PostProcessNode { type ViewData = ( &'static ViewTarget, &'static PostProcessSettings, ); fn run( &self, _graph: &mut RenderGraphContext, render_context: &mut RenderContext, (view_target, _post_process_settings): QueryItem<Self::ViewData>, world: &World, ) -> Result<(), NodeRunError> { // ... } } // Before impl<P: CachedRenderPipelinePhaseItem> RenderCommand<P> for SetItemPipeline { type Param = SRes<PipelineCache>; type ViewWorldQuery = (); type ItemWorldQuery = (); #[inline] fn render<'w>( item: &P, _view: (), _entity: (), pipeline_cache: SystemParamItem<'w, '_, Self::Param>, pass: &mut TrackedRenderPass<'w>, ) -> RenderCommandResult { // ... } } // After impl<P: CachedRenderPipelinePhaseItem> RenderCommand<P> for SetItemPipeline { type Param = SRes<PipelineCache>; type ViewData = (); type ItemData = (); #[inline] fn render<'w>( item: &P, _view: (), _entity: (), pipeline_cache: SystemParamItem<'w, '_, Self::Param>, pass: &mut TrackedRenderPass<'w>, ) -> RenderCommandResult { // ... } } ``` |
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tygyh
|
fd308571c4
|
Remove unnecessary path prefixes (#10749)
# Objective - Shorten paths by removing unnecessary prefixes ## Solution - Remove the prefixes from many paths which do not need them. Finding the paths was done automatically using built-in refactoring tools in Jetbrains RustRover. |
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JMS55
|
4bf20e7d27
|
Swap material and mesh bind groups (#10485)
# Objective - Materials should be a more frequent rebind then meshes (due to being able to use a single vertex buffer, such as in #10164) and therefore should be in a higher bind group. --- ## Changelog - For 2d and 3d mesh/material setups (but not UI materials, or other rendering setups such as gizmos, sprites, or text), mesh data is now in bind group 1, and material data is now in bind group 2, which is swapped from how they were before. ## Migration Guide - Custom 2d and 3d mesh/material shaders should now use bind group 2 `@group(2) @binding(x)` for their bound resources, instead of bind group 1. - Many internal pieces of rendering code have changed so that mesh data is now in bind group 1, and material data is now in bind group 2. Semi-custom rendering setups (that don't use the Material or Material2d APIs) should adapt to these changes. |
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Marco Buono
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44928e0df4
|
StandardMaterial Light Transmission (#8015)
# Objective
<img width="1920" alt="Screenshot 2023-04-26 at 01 07 34"
src="https://user-images.githubusercontent.com/418473/234467578-0f34187b-5863-4ea1-88e9-7a6bb8ce8da3.png">
This PR adds both diffuse and specular light transmission capabilities
to the `StandardMaterial`, with support for screen space refractions.
This enables realistically representing a wide range of real-world
materials, such as:
- Glass; (Including frosted glass)
- Transparent and translucent plastics;
- Various liquids and gels;
- Gemstones;
- Marble;
- Wax;
- Paper;
- Leaves;
- Porcelain.
Unlike existing support for transparency, light transmission does not
rely on fixed function alpha blending, and therefore works with both
`AlphaMode::Opaque` and `AlphaMode::Mask` materials.
## Solution
- Introduces a number of transmission related fields in the
`StandardMaterial`;
- For specular transmission:
- Adds logic to take a view main texture snapshot after the opaque
phase; (in order to perform screen space refractions)
- Introduces a new `Transmissive3d` phase to the renderer, to which all
meshes with `transmission > 0.0` materials are sent.
- Calculates a light exit point (of the approximate mesh volume) using
`ior` and `thickness` properties
- Samples the snapshot texture with an adaptive number of taps across a
`roughness`-controlled radius enabling “blurry” refractions
- For diffuse transmission:
- Approximates transmitted diffuse light by using a second, flipped +
displaced, diffuse-only Lambertian lobe for each light source.
## To Do
- [x] Figure out where `fresnel_mix()` is taking place, if at all, and
where `dielectric_specular` is being calculated, if at all, and update
them to use the `ior` value (Not a blocker, just a nice-to-have for more
correct BSDF)
- To the _best of my knowledge, this is now taking place, after
|
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Nicola Papale
|
66f72dd25b
|
Use wildcard imports in bevy_pbr (#9847)
# Objective - the style of import used by bevy guarantees merge conflicts when any file change - This is especially true when import lists are large, such as in `bevy_pbr` - Merge conflicts are tricky to resolve. This bogs down rendering PRs and makes contributing to bevy's rendering system more difficult than it needs to ## Solution - Use wildcard imports to replace multiline import list in `bevy_pbr` I suspect this is controversial, but I'd like to hear alternatives. Because this is one of many papercuts that makes developing render features near impossible. |
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Griffin
|
1bd7e5a8e6
|
View Transformations (#9726)
# Objective - Add functions for common view transformations. --------- Co-authored-by: Robert Swain <robert.swain@gmail.com> |
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robtfm
|
c99351f7c2
|
allow extensions to StandardMaterial (#7820)
# Objective allow extending `Material`s (including the built in `StandardMaterial`) with custom vertex/fragment shaders and additional data, to easily get pbr lighting with custom modifications, or otherwise extend a base material. # Solution - added `ExtendedMaterial<B: Material, E: MaterialExtension>` which contains a base material and a user-defined extension. - added example `extended_material` showing how to use it - modified AsBindGroup to have "unprepared" functions that return raw resources / layout entries so that the extended material can combine them note: doesn't currently work with array resources, as i can't figure out how to make the OwnedBindingResource::get_binding() work, as wgpu requires a `&'a[&'a TextureView]` and i have a `Vec<TextureView>`. # Migration Guide manual implementations of `AsBindGroup` will need to be adjusted, the changes are pretty straightforward and can be seen in the diff for e.g. the `texture_binding_array` example. --------- Co-authored-by: Robert Swain <robert.swain@gmail.com> |
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Marco Buono
|
5733d2403e
|
*_PREPASS Shader Def Cleanup (#10136)
# Objective - This PR aims to make the various `*_PREPASS` shader defs we have (`NORMAL_PREPASS`, `DEPTH_PREPASS`, `MOTION_VECTORS_PREPASS` AND `DEFERRED_PREPASS`) easier to use and understand: - So that their meaning is now consistent across all contexts; (“prepass X is enabled for the current view”) - So that they're also consistently set across all contexts. - It also aims to enable us to (with a follow up PR) to conditionally gate the `BindGroupEntry` and `BindGroupLayoutEntry` items associated with these prepasses, saving us up to 4 texture slots in WebGL (currently globally limited to 16 per shader, regardless of bind groups) ## Solution - We now consistently set these from `PrepassPipeline`, the `MeshPipeline` and the `DeferredLightingPipeline`, we also set their `MeshPipelineKey`s; - We introduce `PREPASS_PIPELINE`, `MESH_PIPELINE` and `DEFERRED_LIGHTING_PIPELINE` that can be used to detect where the code is running, without overloading the meanings of the prepass shader defs; - We also gate the WGSL functions in `bevy_pbr::prepass_utils` with `#ifdef`s for their respective shader defs, so that shader code can provide a fallback whenever they're not available. - This allows us to conditionally include the bindings for these prepass textures (My next PR, which will hopefully unblock #8015) - @robtfm mentioned [these were being used to prevent accessing the same binding as read/write in the prepass](https://discord.com/channels/691052431525675048/743663924229963868/1163270458393759814), however even after reversing the `#ifndef`s I had no issues running the code, so perhaps the compiler is already smart enough even without tree shaking to know they're not being used, thanks to `#ifdef PREPASS_PIPELINE`? ## Comparison ### Before | Shader Def | `PrepassPipeline` | `MeshPipeline` | `DeferredLightingPipeline` | | ------------------------ | ----------------- | -------------- | -------------------------- | | `NORMAL_PREPASS` | Yes | No | No | | `DEPTH_PREPASS` | Yes | No | No | | `MOTION_VECTORS_PREPASS` | Yes | No | No | | `DEFERRED_PREPASS` | Yes | No | No | | View Key | `PrepassPipeline` | `MeshPipeline` | `DeferredLightingPipeline` | | ------------------------ | ----------------- | -------------- | -------------------------- | | `NORMAL_PREPASS` | Yes | Yes | No | | `DEPTH_PREPASS` | Yes | No | No | | `MOTION_VECTORS_PREPASS` | Yes | No | No | | `DEFERRED_PREPASS` | Yes | Yes\* | No | \* Accidentally was being set twice, once with only `deferred_prepass.is_some()` as a condition, and once with `deferred_p repass.is_some() && !forward` as a condition. ### After | Shader Def | `PrepassPipeline` | `MeshPipeline` | `DeferredLightingPipeline` | | ---------------------------- | ----------------- | --------------- | -------------------------- | | `NORMAL_PREPASS` | Yes | Yes | Yes | | `DEPTH_PREPASS` | Yes | Yes | Yes | | `MOTION_VECTORS_PREPASS` | Yes | Yes | Yes | | `DEFERRED_PREPASS` | Yes | Yes | Unconditionally | | `PREPASS_PIPELINE` | Unconditionally | No | No | | `MESH_PIPELINE` | No | Unconditionally | No | | `DEFERRED_LIGHTING_PIPELINE` | No | No | Unconditionally | | View Key | `PrepassPipeline` | `MeshPipeline` | `DeferredLightingPipeline` | | ------------------------ | ----------------- | -------------- | -------------------------- | | `NORMAL_PREPASS` | Yes | Yes | Yes | | `DEPTH_PREPASS` | Yes | Yes | Yes | | `MOTION_VECTORS_PREPASS` | Yes | Yes | Yes | | `DEFERRED_PREPASS` | Yes | Yes | Unconditionally | --- ## Changelog - Cleaned up WGSL `*_PREPASS` shader defs so they're now consistently used everywhere; - Introduced `PREPASS_PIPELINE`, `MESH_PIPELINE` and `DEFERRED_LIGHTING_PIPELINE` WGSL shader defs for conditionally compiling logic based the current pipeline; - WGSL functions from `bevy_pbr::prepass_utils` are now guarded with `#ifdef` based on the currently enabled prepasses; ## Migration Guide - When using functions from `bevy_pbr::prepass_utils` (`prepass_depth()`, `prepass_normal()`, `prepass_motion_vector()`) in contexts where these prepasses might be disabled, you should now wrap your calls with the appropriate `#ifdef` guards, (`#ifdef DEPTH_PREPASS`, `#ifdef NORMAL_PREPASS`, `#ifdef MOTION_VECTOR_PREPASS`) providing fallback logic where applicable. --------- Co-authored-by: Carter Anderson <mcanders1@gmail.com> Co-authored-by: IceSentry <IceSentry@users.noreply.github.com> |
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Edgar Geier
|
e23d7cf501
|
Explain usage of prepass shaders in docs for Material trait (#9025)
# Objective - Fixes #8696. ## Solution - Added a paragraph describing the usage of the `prepass_vertex_shader` and `prepass_fragment_shader`. |
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Jan Češpivo
|
4a61f894b7
|
chore: Renamed RenderInstance trait to ExtractInstance (#10065)
# Objective Fixes [#10061] ## Solution Renamed `RenderInstance` to `ExtractInstance`, `RenderInstances` to `ExtractedInstances` and `RenderInstancePlugin` to `ExtractInstancesPlugin` |
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Griffin
|
a15d152635
|
Deferred Renderer (#9258)
# Objective - Add a [Deferred Renderer](https://en.wikipedia.org/wiki/Deferred_shading) to Bevy. - This allows subsequent passes to access per pixel material information before/during shading. - Accessing this per pixel material information is needed for some features, like GI. It also makes other features (ex. Decals) simpler to implement and/or improves their capability. There are multiple approaches to accomplishing this. The deferred shading approach works well given the limitations of WebGPU and WebGL2. Motivation: [I'm working on a GI solution for Bevy](https://youtu.be/eH1AkL-mwhI) # Solution - The deferred renderer is implemented with a prepass and a deferred lighting pass. - The prepass renders opaque objects into the Gbuffer attachment (`Rgba32Uint`). The PBR shader generates a `PbrInput` in mostly the same way as the forward implementation and then [packs it into the Gbuffer]( |
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Patrick Walton
|
e67d63aa79
|
Refactor the render instance logic in #9903 so that it's easier for other components to adopt. (#10002)
# Objective Currently, the only way for custom components that participate in rendering to opt into the higher-performance extraction method in #9903 is to implement the `RenderInstances` data structure and the extraction logic manually. This is inconvenient compared to the `ExtractComponent` API. ## Solution This commit creates a new `RenderInstance` trait that mirrors the existing `ExtractComponent` method but uses the higher-performance approach that #9903 uses. Additionally, `RenderInstance` is more flexible than `ExtractComponent`, because it can extract multiple components at once. This makes high-performance rendering components essentially as easy to write as the existing ones based on component extraction. --- ## Changelog ### Added A new `RenderInstance` trait is available mirroring `ExtractComponent`, but using a higher-performance method to extract one or more components to the render world. If you have custom components that rendering takes into account, you may consider migration from `ExtractComponent` to `RenderInstance` for higher performance. |
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JMS55
|
1f95a484ed
|
PCF For DirectionalLight/SpotLight Shadows (#8006)
# Objective - Improve antialiasing for non-point light shadow edges. - Very partially addresses https://github.com/bevyengine/bevy/issues/3628. ## Solution - Implements "The Witness"'s shadow map sampling technique. - Ported from @superdump's old branch, all credit to them :) - Implements "Call of Duty: Advanced Warfare"'s stochastic shadow map sampling technique when the velocity prepass is enabled, for use with TAA. - Uses interleaved gradient noise to generate a random angle, and then averages 8 samples in a spiral pattern, rotated by the random angle. - I also tried spatiotemporal blue noise, but it was far too noisy to be filtered by TAA alone. In the future, we should try spatiotemporal blue noise + a specialized shadow denoiser such as https://gpuopen.com/fidelityfx-denoiser/#shadow. This approach would also be useful for hybrid rasterized applications with raytraced shadows. - The COD presentation has an interesting temporal dithering of the noise for use with temporal supersampling that we should revisit when we get DLSS/FSR/other TSR. --- ## Changelog * Added `ShadowFilteringMethod`. Improved directional light and spotlight shadow edges to be less aliased. ## Migration Guide * Shadows cast by directional lights or spotlights now have smoother edges. To revert to the old behavior, add `ShadowFilteringMethod::Hardware2x2` to your cameras. --------- Co-authored-by: IceSentry <c.giguere42@gmail.com> Co-authored-by: Daniel Chia <danstryder@gmail.com> Co-authored-by: robtfm <50659922+robtfm@users.noreply.github.com> Co-authored-by: Brandon Dyer <brandondyer64@gmail.com> Co-authored-by: Edgar Geier <geieredgar@gmail.com> Co-authored-by: Robert Swain <robert.swain@gmail.com> Co-authored-by: Elabajaba <Elabajaba@users.noreply.github.com> Co-authored-by: IceSentry <IceSentry@users.noreply.github.com> |
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Robert Swain
|
b6ead2be95
|
Use EntityHashMap<Entity, T> for render world entity storage for better performance (#9903)
# Objective - Improve rendering performance, particularly by avoiding the large system commands costs of using the ECS in the way that the render world does. ## Solution - Define `EntityHasher` that calculates a hash from the `Entity.to_bits()` by `i | (i.wrapping_mul(0x517cc1b727220a95) << 32)`. `0x517cc1b727220a95` is something like `u64::MAX / N` for N that gives a value close to π and that works well for hashing. Thanks for @SkiFire13 for the suggestion and to @nicopap for alternative suggestions and discussion. This approach comes from `rustc-hash` (a.k.a. `FxHasher`) with some tweaks for the case of hashing an `Entity`. `FxHasher` and `SeaHasher` were also tested but were significantly slower. - Define `EntityHashMap` type that uses the `EntityHashser` - Use `EntityHashMap<Entity, T>` for render world entity storage, including: - `RenderMaterialInstances` - contains the `AssetId<M>` of the material associated with the entity. Also for 2D. - `RenderMeshInstances` - contains mesh transforms, flags and properties about mesh entities. Also for 2D. - `SkinIndices` and `MorphIndices` - contains the skin and morph index for an entity, respectively - `ExtractedSprites` - `ExtractedUiNodes` ## Benchmarks All benchmarks have been conducted on an M1 Max connected to AC power. The tests are run for 1500 frames. The 1000th frame is captured for comparison to check for visual regressions. There were none. ### 2D Meshes `bevymark --benchmark --waves 160 --per-wave 1000 --mode mesh2d` #### `--ordered-z` This test spawns the 2D meshes with z incrementing back to front, which is the ideal arrangement allocation order as it matches the sorted render order which means lookups have a high cache hit rate. <img width="1112" alt="Screenshot 2023-09-27 at 07 50 45" src="https://github.com/bevyengine/bevy/assets/302146/e140bc98-7091-4a3b-8ae1-ab75d16d2ccb"> -39.1% median frame time. #### Random This test spawns the 2D meshes with random z. This not only makes the batching and transparent 2D pass lookups get a lot of cache misses, it also currently means that the meshes are almost certain to not be batchable. <img width="1108" alt="Screenshot 2023-09-27 at 07 51 28" src="https://github.com/bevyengine/bevy/assets/302146/29c2e813-645a-43ce-982a-55df4bf7d8c4"> -7.2% median frame time. ### 3D Meshes `many_cubes --benchmark` <img width="1112" alt="Screenshot 2023-09-27 at 07 51 57" src="https://github.com/bevyengine/bevy/assets/302146/1a729673-3254-4e2a-9072-55e27c69f0fc"> -7.7% median frame time. ### Sprites **NOTE: On `main` sprites are using `SparseSet<Entity, T>`!** `bevymark --benchmark --waves 160 --per-wave 1000 --mode sprite` #### `--ordered-z` This test spawns the sprites with z incrementing back to front, which is the ideal arrangement allocation order as it matches the sorted render order which means lookups have a high cache hit rate. <img width="1116" alt="Screenshot 2023-09-27 at 07 52 31" src="https://github.com/bevyengine/bevy/assets/302146/bc8eab90-e375-4d31-b5cd-f55f6f59ab67"> +13.0% median frame time. #### Random This test spawns the sprites with random z. This makes the batching and transparent 2D pass lookups get a lot of cache misses. <img width="1109" alt="Screenshot 2023-09-27 at 07 53 01" src="https://github.com/bevyengine/bevy/assets/302146/22073f5d-99a7-49b0-9584-d3ac3eac3033"> +0.6% median frame time. ### UI **NOTE: On `main` UI is using `SparseSet<Entity, T>`!** `many_buttons` <img width="1111" alt="Screenshot 2023-09-27 at 07 53 26" src="https://github.com/bevyengine/bevy/assets/302146/66afd56d-cbe4-49e7-8b64-2f28f6043d85"> +15.1% median frame time. ## Alternatives - Cart originally suggested trying out `SparseSet<Entity, T>` and indeed that is slightly faster under ideal conditions. However, `PassHashMap<Entity, T>` has better worst case performance when data is randomly distributed, rather than in sorted render order, and does not have the worst case memory usage that `SparseSet`'s dense `Vec<usize>` that maps from the `Entity` index to sparse index into `Vec<T>`. This dense `Vec` has to be as large as the largest Entity index used with the `SparseSet`. - I also tested `PassHashMap<u32, T>`, intending to use `Entity.index()` as the key, but this proved to sometimes be slower and mostly no different. - The only outstanding approach that has not been implemented and tested is to _not_ clear the render world of its entities each frame. That has its own problems, though they could perhaps be solved. - Performance-wise, if the entities and their component data were not cleared, then they would incur table moves on spawn, and should not thereafter, rather just their component data would be overwritten. Ideally we would have a neat way of either updating data in-place via `&mut T` queries, or inserting components if not present. This would likely be quite cumbersome to have to remember to do everywhere, but perhaps it only needs to be done in the more performance-sensitive systems. - The main problem to solve however is that we want to both maintain a mapping between main world entities and render world entities, be able to run the render app and world in parallel with the main app and world for pipelined rendering, and at the same time be able to spawn entities in the render world in such a way that those Entity ids do not collide with those spawned in the main world. This is potentially quite solvable, but could well be a lot of ECS work to do it in a way that makes sense. --- ## Changelog - Changed: Component data for entities to be drawn are no longer stored on entities in the render world. Instead, data is stored in a `EntityHashMap<Entity, T>` in various resources. This brings significant performance benefits due to the way the render app clears entities every frame. Resources of most interest are `RenderMeshInstances` and `RenderMaterialInstances`, and their 2D counterparts. ## Migration Guide Previously the render app extracted mesh entities and their component data from the main world and stored them as entities and components in the render world. Now they are extracted into essentially `EntityHashMap<Entity, T>` where `T` are structs containing an appropriate group of data. This means that while extract set systems will continue to run extract queries against the main world they will store their data in hash maps. Also, systems in later sets will either need to look up entities in the available resources such as `RenderMeshInstances`, or maintain their own `EntityHashMap<Entity, T>` for their own data. Before: ```rust fn queue_custom( material_meshes: Query<(Entity, &MeshTransforms, &Handle<Mesh>), With<InstanceMaterialData>>, ) { ... for (entity, mesh_transforms, mesh_handle) in &material_meshes { ... } } ``` After: ```rust fn queue_custom( render_mesh_instances: Res<RenderMeshInstances>, instance_entities: Query<Entity, With<InstanceMaterialData>>, ) { ... for entity in &instance_entities { let Some(mesh_instance) = render_mesh_instances.get(&entity) else { continue; }; // The mesh handle in `AssetId<Mesh>` form, and the `MeshTransforms` can now // be found in `mesh_instance` which is a `RenderMeshInstance` ... } } ``` --------- Co-authored-by: robtfm <50659922+robtfm@users.noreply.github.com> |
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Robert Swain
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5c884c5a15
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Automatic batching/instancing of draw commands (#9685)
# Objective - Implement the foundations of automatic batching/instancing of draw commands as the next step from #89 - NOTE: More performance improvements will come when more data is managed and bound in ways that do not require rebinding such as mesh, material, and texture data. ## Solution - The core idea for batching of draw commands is to check whether any of the information that has to be passed when encoding a draw command changes between two things that are being drawn according to the sorted render phase order. These should be things like the pipeline, bind groups and their dynamic offsets, index/vertex buffers, and so on. - The following assumptions have been made: - Only entities with prepared assets (pipelines, materials, meshes) are queued to phases - View bindings are constant across a phase for a given draw function as phases are per-view - `batch_and_prepare_render_phase` is the only system that performs this batching and has sole responsibility for preparing the per-object data. As such the mesh binding and dynamic offsets are assumed to only vary as a result of the `batch_and_prepare_render_phase` system, e.g. due to having to split data across separate uniform bindings within the same buffer due to the maximum uniform buffer binding size. - Implement `GpuArrayBuffer` for `Mesh2dUniform` to store Mesh2dUniform in arrays in GPU buffers rather than each one being at a dynamic offset in a uniform buffer. This is the same optimisation that was made for 3D not long ago. - Change batch size for a range in `PhaseItem`, adding API for getting or mutating the range. This is more flexible than a size as the length of the range can be used in place of the size, but the start and end can be otherwise whatever is needed. - Add an optional mesh bind group dynamic offset to `PhaseItem`. This avoids having to do a massive table move just to insert `GpuArrayBufferIndex` components. ## Benchmarks All tests have been run on an M1 Max on AC power. `bevymark` and `many_cubes` were modified to use 1920x1080 with a scale factor of 1. I run a script that runs a separate Tracy capture process, and then runs the bevy example with `--features bevy_ci_testing,trace_tracy` and `CI_TESTING_CONFIG=../benchmark.ron` with the contents of `../benchmark.ron`: ```rust ( exit_after: Some(1500) ) ``` ...in order to run each test for 1500 frames. The recent changes to `many_cubes` and `bevymark` added reproducible random number generation so that with the same settings, the same rng will occur. They also added benchmark modes that use a fixed delta time for animations. Combined this means that the same frames should be rendered both on main and on the branch. The graphs compare main (yellow) to this PR (red). ### 3D Mesh `many_cubes --benchmark` <img width="1411" alt="Screenshot 2023-09-03 at 23 42 10" src="https://github.com/bevyengine/bevy/assets/302146/2088716a-c918-486c-8129-090b26fd2bc4"> The mesh and material are the same for all instances. This is basically the best case for the initial batching implementation as it results in 1 draw for the ~11.7k visible meshes. It gives a ~30% reduction in median frame time. The 1000th frame is identical using the flip tool: ![flip many_cubes-main-mesh3d many_cubes-batching-mesh3d 67ppd ldr](https://github.com/bevyengine/bevy/assets/302146/2511f37a-6df8-481a-932f-706ca4de7643) ``` Mean: 0.000000 Weighted median: 0.000000 1st weighted quartile: 0.000000 3rd weighted quartile: 0.000000 Min: 0.000000 Max: 0.000000 Evaluation time: 0.4615 seconds ``` ### 3D Mesh `many_cubes --benchmark --material-texture-count 10` <img width="1404" alt="Screenshot 2023-09-03 at 23 45 18" src="https://github.com/bevyengine/bevy/assets/302146/5ee9c447-5bd2-45c6-9706-ac5ff8916daf"> This run uses 10 different materials by varying their textures. The materials are randomly selected, and there is no sorting by material bind group for opaque 3D so any batching is 'random'. The PR produces a ~5% reduction in median frame time. If we were to sort the opaque phase by the material bind group, then this should be a lot faster. This produces about 10.5k draws for the 11.7k visible entities. This makes sense as randomly selecting from 10 materials gives a chance that two adjacent entities randomly select the same material and can be batched. The 1000th frame is identical in flip: ![flip many_cubes-main-mesh3d-mtc10 many_cubes-batching-mesh3d-mtc10 67ppd ldr](https://github.com/bevyengine/bevy/assets/302146/2b3a8614-9466-4ed8-b50c-d4aa71615dbb) ``` Mean: 0.000000 Weighted median: 0.000000 1st weighted quartile: 0.000000 3rd weighted quartile: 0.000000 Min: 0.000000 Max: 0.000000 Evaluation time: 0.4537 seconds ``` ### 3D Mesh `many_cubes --benchmark --vary-per-instance` <img width="1394" alt="Screenshot 2023-09-03 at 23 48 44" src="https://github.com/bevyengine/bevy/assets/302146/f02a816b-a444-4c18-a96a-63b5436f3b7f"> This run varies the material data per instance by randomly-generating its colour. This is the worst case for batching and that it performs about the same as `main` is a good thing as it demonstrates that the batching has minimal overhead when dealing with ~11k visible mesh entities. The 1000th frame is identical according to flip: ![flip many_cubes-main-mesh3d-vpi many_cubes-batching-mesh3d-vpi 67ppd ldr](https://github.com/bevyengine/bevy/assets/302146/ac5f5c14-9bda-4d1a-8219-7577d4aac68c) ``` Mean: 0.000000 Weighted median: 0.000000 1st weighted quartile: 0.000000 3rd weighted quartile: 0.000000 Min: 0.000000 Max: 0.000000 Evaluation time: 0.4568 seconds ``` ### 2D Mesh `bevymark --benchmark --waves 160 --per-wave 1000 --mode mesh2d` <img width="1412" alt="Screenshot 2023-09-03 at 23 59 56" src="https://github.com/bevyengine/bevy/assets/302146/cb02ae07-237b-4646-ae9f-fda4dafcbad4"> This spawns 160 waves of 1000 quad meshes that are shaded with ColorMaterial. Each wave has a different material so 160 waves currently should result in 160 batches. This results in a 50% reduction in median frame time. Capturing a screenshot of the 1000th frame main vs PR gives: ![flip bevymark-main-mesh2d bevymark-batching-mesh2d 67ppd ldr](https://github.com/bevyengine/bevy/assets/302146/80102728-1217-4059-87af-14d05044df40) ``` Mean: 0.001222 Weighted median: 0.750432 1st weighted quartile: 0.453494 3rd weighted quartile: 0.969758 Min: 0.000000 Max: 0.990296 Evaluation time: 0.4255 seconds ``` So they seem to produce the same results. I also double-checked the number of draws. `main` does 160000 draws, and the PR does 160, as expected. ### 2D Mesh `bevymark --benchmark --waves 160 --per-wave 1000 --mode mesh2d --material-texture-count 10` <img width="1392" alt="Screenshot 2023-09-04 at 00 09 22" src="https://github.com/bevyengine/bevy/assets/302146/4358da2e-ce32-4134-82df-3ab74c40849c"> This generates 10 textures and generates materials for each of those and then selects one material per wave. The median frame time is reduced by 50%. Similar to the plain run above, this produces 160 draws on the PR and 160000 on `main` and the 1000th frame is identical (ignoring the fps counter text overlay). ![flip bevymark-main-mesh2d-mtc10 bevymark-batching-mesh2d-mtc10 67ppd ldr](https://github.com/bevyengine/bevy/assets/302146/ebed2822-dce7-426a-858b-b77dc45b986f) ``` Mean: 0.002877 Weighted median: 0.964980 1st weighted quartile: 0.668871 3rd weighted quartile: 0.982749 Min: 0.000000 Max: 0.992377 Evaluation time: 0.4301 seconds ``` ### 2D Mesh `bevymark --benchmark --waves 160 --per-wave 1000 --mode mesh2d --vary-per-instance` <img width="1396" alt="Screenshot 2023-09-04 at 00 13 53" src="https://github.com/bevyengine/bevy/assets/302146/b2198b18-3439-47ad-919a-cdabe190facb"> This creates unique materials per instance by randomly-generating the material's colour. This is the worst case for 2D batching. Somehow, this PR manages a 7% reduction in median frame time. Both main and this PR issue 160000 draws. The 1000th frame is the same: ![flip bevymark-main-mesh2d-vpi bevymark-batching-mesh2d-vpi 67ppd ldr](https://github.com/bevyengine/bevy/assets/302146/a2ec471c-f576-4a36-a23b-b24b22578b97) ``` Mean: 0.001214 Weighted median: 0.937499 1st weighted quartile: 0.635467 3rd weighted quartile: 0.979085 Min: 0.000000 Max: 0.988971 Evaluation time: 0.4462 seconds ``` ### 2D Sprite `bevymark --benchmark --waves 160 --per-wave 1000 --mode sprite` <img width="1396" alt="Screenshot 2023-09-04 at 12 21 12" src="https://github.com/bevyengine/bevy/assets/302146/8b31e915-d6be-4cac-abf5-c6a4da9c3d43"> This just spawns 160 waves of 1000 sprites. There should be and is no notable difference between main and the PR. ### 2D Sprite `bevymark --benchmark --waves 160 --per-wave 1000 --mode sprite --material-texture-count 10` <img width="1389" alt="Screenshot 2023-09-04 at 12 36 08" src="https://github.com/bevyengine/bevy/assets/302146/45fe8d6d-c901-4062-a349-3693dd044413"> This spawns the sprites selecting a texture at random per instance from the 10 generated textures. This has no significant change vs main and shouldn't. ### 2D Sprite `bevymark --benchmark --waves 160 --per-wave 1000 --mode sprite --vary-per-instance` <img width="1401" alt="Screenshot 2023-09-04 at 12 29 52" src="https://github.com/bevyengine/bevy/assets/302146/762c5c60-352e-471f-8dbe-bbf10e24ebd6"> This sets the sprite colour as being unique per instance. This can still all be drawn using one batch. There should be no difference but the PR produces median frame times that are 4% higher. Investigation showed no clear sources of cost, rather a mix of give and take that should not happen. It seems like noise in the results. ### Summary | Benchmark | % change in median frame time | | ------------- | ------------- | | many_cubes | 🟩 -30% | | many_cubes 10 materials | 🟩 -5% | | many_cubes unique materials | 🟩 ~0% | | bevymark mesh2d | 🟩 -50% | | bevymark mesh2d 10 materials | 🟩 -50% | | bevymark mesh2d unique materials | 🟩 -7% | | bevymark sprite | 🟥 2% | | bevymark sprite 10 materials | 🟥 0.6% | | bevymark sprite unique materials | 🟥 4.1% | --- ## Changelog - Added: 2D and 3D mesh entities that share the same mesh and material (same textures, same data) are now batched into the same draw command for better performance. --------- Co-authored-by: robtfm <50659922+robtfm@users.noreply.github.com> Co-authored-by: Nicola Papale <nico@nicopap.ch> |