bevy/examples/3d/irradiance_volumes.rs

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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.
2024-02-06 23:23:20 +00:00
//! This example shows how irradiance volumes affect the indirect lighting of
//! objects in a scene.
//!
//! The controls are as follows:
//!
//! * Space toggles the irradiance volume on and off.
//!
//! * Enter toggles the camera rotation on and off.
//!
//! * Tab switches the object between a plain sphere and a running fox.
//!
//! * Backspace shows and hides the voxel cubes.
//!
//! * Clicking anywhere moves the object.
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>
2024-02-29 19:35:12 +00:00
use bevy::color::palettes::css::*;
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.
2024-02-06 23:23:20 +00:00
use bevy::core_pipeline::Skybox;
use bevy::math::{uvec3, vec3};
use bevy::pbr::irradiance_volume::IrradianceVolume;
use bevy::pbr::{ExtendedMaterial, MaterialExtension, NotShadowCaster};
use bevy::prelude::*;
use bevy::render::render_resource::{AsBindGroup, ShaderRef, ShaderType};
use bevy::window::PrimaryWindow;
// Rotation speed in radians per frame.
const ROTATION_SPEED: f32 = 0.2;
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.
2024-02-06 23:23:20 +00:00
const FOX_SCALE: f32 = 0.05;
const SPHERE_SCALE: f32 = 2.0;
const IRRADIANCE_VOLUME_INTENSITY: f32 = 1800.0;
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.
2024-02-06 23:23:20 +00:00
const AMBIENT_LIGHT_BRIGHTNESS: f32 = 0.06;
const VOXEL_CUBE_SCALE: f32 = 0.4;
static DISABLE_IRRADIANCE_VOLUME_HELP_TEXT: &str = "Space: Disable the irradiance volume";
static ENABLE_IRRADIANCE_VOLUME_HELP_TEXT: &str = "Space: Enable the irradiance volume";
static HIDE_VOXELS_HELP_TEXT: &str = "Backspace: Hide the voxels";
static SHOW_VOXELS_HELP_TEXT: &str = "Backspace: Show the voxels";
static STOP_ROTATION_HELP_TEXT: &str = "Enter: Stop rotation";
static START_ROTATION_HELP_TEXT: &str = "Enter: Start rotation";
static SWITCH_TO_FOX_HELP_TEXT: &str = "Tab: Switch to a skinned mesh";
static SWITCH_TO_SPHERE_HELP_TEXT: &str = "Tab: Switch to a plain sphere mesh";
static CLICK_TO_MOVE_HELP_TEXT: &str = "Left click: Move the object";
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>
2024-02-29 19:35:12 +00:00
static GIZMO_COLOR: Color = Color::Srgba(YELLOW);
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.
2024-02-06 23:23:20 +00:00
Normalise matrix naming (#13489) # Objective - Fixes #10909 - Fixes #8492 ## Solution - Name all matrices `x_from_y`, for example `world_from_view`. ## Testing - I've tested most of the 3D examples. The `lighting` example particularly should hit a lot of the changes and appears to run fine. --- ## Changelog - Renamed matrices across the engine to follow a `y_from_x` naming, making the space conversion more obvious. ## Migration Guide - `Frustum`'s `from_view_projection`, `from_view_projection_custom_far` and `from_view_projection_no_far` were renamed to `from_clip_from_world`, `from_clip_from_world_custom_far` and `from_clip_from_world_no_far`. - `ComputedCameraValues::projection_matrix` was renamed to `clip_from_view`. - `CameraProjection::get_projection_matrix` was renamed to `get_clip_from_view` (this affects implementations on `Projection`, `PerspectiveProjection` and `OrthographicProjection`). - `ViewRangefinder3d::from_view_matrix` was renamed to `from_world_from_view`. - `PreviousViewData`'s members were renamed to `view_from_world` and `clip_from_world`. - `ExtractedView`'s `projection`, `transform` and `view_projection` were renamed to `clip_from_view`, `world_from_view` and `clip_from_world`. - `ViewUniform`'s `view_proj`, `unjittered_view_proj`, `inverse_view_proj`, `view`, `inverse_view`, `projection` and `inverse_projection` were renamed to `clip_from_world`, `unjittered_clip_from_world`, `world_from_clip`, `world_from_view`, `view_from_world`, `clip_from_view` and `view_from_clip`. - `GpuDirectionalCascade::view_projection` was renamed to `clip_from_world`. - `MeshTransforms`' `transform` and `previous_transform` were renamed to `world_from_local` and `previous_world_from_local`. - `MeshUniform`'s `transform`, `previous_transform`, `inverse_transpose_model_a` and `inverse_transpose_model_b` were renamed to `world_from_local`, `previous_world_from_local`, `local_from_world_transpose_a` and `local_from_world_transpose_b` (the `Mesh` type in WGSL mirrors this, however `transform` and `previous_transform` were named `model` and `previous_model`). - `Mesh2dTransforms::transform` was renamed to `world_from_local`. - `Mesh2dUniform`'s `transform`, `inverse_transpose_model_a` and `inverse_transpose_model_b` were renamed to `world_from_local`, `local_from_world_transpose_a` and `local_from_world_transpose_b` (the `Mesh2d` type in WGSL mirrors this). - In WGSL, in `bevy_pbr::mesh_functions`, `get_model_matrix` and `get_previous_model_matrix` were renamed to `get_world_from_local` and `get_previous_world_from_local`. - In WGSL, `bevy_sprite::mesh2d_functions::get_model_matrix` was renamed to `get_world_from_local`.
2024-06-03 16:56:53 +00:00
static VOXEL_FROM_WORLD: Mat4 = Mat4::from_cols_array_2d(&[
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.
2024-02-06 23:23:20 +00:00
[-42.317566, 0.0, 0.0, 0.0],
[0.0, 0.0, 44.601563, 0.0],
[0.0, 16.73776, 0.0, 0.0],
[0.0, 6.544792, 0.0, 1.0],
]);
// The mode the application is in.
#[derive(Resource)]
struct AppStatus {
// Whether the user wants the irradiance volume to be applied.
irradiance_volume_present: bool,
// Whether the user wants the unskinned sphere mesh or the skinned fox mesh.
model: ExampleModel,
// Whether the user has requested the scene to rotate.
rotating: bool,
// Whether the user has requested the voxels to be displayed.
voxels_visible: bool,
}
// Which model the user wants to display.
#[derive(Clone, Copy, PartialEq)]
enum ExampleModel {
// The plain sphere.
Sphere,
// The fox, which is skinned.
Fox,
}
// Handles to all the assets used in this example.
#[derive(Resource)]
struct ExampleAssets {
// The glTF scene containing the colored floor.
main_scene: Handle<Scene>,
// The 3D texture containing the irradiance volume.
irradiance_volume: Handle<Image>,
// The plain sphere mesh.
main_sphere: Handle<Mesh>,
// The material used for the sphere.
main_sphere_material: Handle<StandardMaterial>,
// The glTF scene containing the animated fox.
fox: Handle<Scene>,
Implement the `AnimationGraph`, allowing for multiple animations to be blended together. (#11989) This is an implementation of RFC #51: https://github.com/bevyengine/rfcs/blob/main/rfcs/51-animation-composition.md Note that the implementation strategy is different from the one outlined in that RFC, because two-phase animation has now landed. # Objective Bevy needs animation blending. The RFC for this is [RFC 51]. ## Solution This is an implementation of the RFC. Note that the implementation strategy is different from the one outlined there, because two-phase animation has now landed. This is just a draft to get the conversation started. Currently we're missing a few things: - [x] A fully-fleshed-out mechanism for transitions - [x] A serialization format for `AnimationGraph`s - [x] Examples are broken, other than `animated_fox` - [x] Documentation --- ## Changelog ### Added * The `AnimationPlayer` has been reworked to support blending multiple animations together through an `AnimationGraph`, and as such will no longer function unless a `Handle<AnimationGraph>` has been added to the entity containing the player. See [RFC 51] for more details. * Transition functionality has moved from the `AnimationPlayer` to a new component, `AnimationTransitions`, which works in tandem with the `AnimationGraph`. ## Migration Guide * `AnimationPlayer`s can no longer play animations by themselves and need to be paired with a `Handle<AnimationGraph>`. Code that was using `AnimationPlayer` to play animations will need to create an `AnimationGraph` asset first, add a node for the clip (or clips) you want to play, and then supply the index of that node to the `AnimationPlayer`'s `play` method. * The `AnimationPlayer::play_with_transition()` method has been removed and replaced with the `AnimationTransitions` component. If you were previously using `AnimationPlayer::play_with_transition()`, add all animations that you were playing to the `AnimationGraph`, and create an `AnimationTransitions` component to manage the blending between them. [RFC 51]: https://github.com/bevyengine/rfcs/blob/main/rfcs/51-animation-composition.md --------- Co-authored-by: Rob Parrett <robparrett@gmail.com>
2024-03-07 20:22:42 +00:00
// The graph containing the animation that the fox will play.
fox_animation_graph: Handle<AnimationGraph>,
// The node within the animation graph containing the animation.
fox_animation_node: AnimationNodeIndex,
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.
2024-02-06 23:23:20 +00:00
// The voxel cube mesh.
voxel_cube: Handle<Mesh>,
// The skybox.
skybox: Handle<Image>,
}
// The sphere and fox both have this component.
#[derive(Component)]
struct MainObject;
// Marks each of the voxel cubes.
#[derive(Component)]
struct VoxelCube;
// Marks the voxel cube parent object.
#[derive(Component)]
struct VoxelCubeParent;
type VoxelVisualizationMaterial = ExtendedMaterial<StandardMaterial, VoxelVisualizationExtension>;
#[derive(Asset, TypePath, AsBindGroup, Debug, Clone)]
struct VoxelVisualizationExtension {
#[uniform(100)]
irradiance_volume_info: VoxelVisualizationIrradianceVolumeInfo,
}
#[derive(ShaderType, Debug, Clone)]
struct VoxelVisualizationIrradianceVolumeInfo {
Normalise matrix naming (#13489) # Objective - Fixes #10909 - Fixes #8492 ## Solution - Name all matrices `x_from_y`, for example `world_from_view`. ## Testing - I've tested most of the 3D examples. The `lighting` example particularly should hit a lot of the changes and appears to run fine. --- ## Changelog - Renamed matrices across the engine to follow a `y_from_x` naming, making the space conversion more obvious. ## Migration Guide - `Frustum`'s `from_view_projection`, `from_view_projection_custom_far` and `from_view_projection_no_far` were renamed to `from_clip_from_world`, `from_clip_from_world_custom_far` and `from_clip_from_world_no_far`. - `ComputedCameraValues::projection_matrix` was renamed to `clip_from_view`. - `CameraProjection::get_projection_matrix` was renamed to `get_clip_from_view` (this affects implementations on `Projection`, `PerspectiveProjection` and `OrthographicProjection`). - `ViewRangefinder3d::from_view_matrix` was renamed to `from_world_from_view`. - `PreviousViewData`'s members were renamed to `view_from_world` and `clip_from_world`. - `ExtractedView`'s `projection`, `transform` and `view_projection` were renamed to `clip_from_view`, `world_from_view` and `clip_from_world`. - `ViewUniform`'s `view_proj`, `unjittered_view_proj`, `inverse_view_proj`, `view`, `inverse_view`, `projection` and `inverse_projection` were renamed to `clip_from_world`, `unjittered_clip_from_world`, `world_from_clip`, `world_from_view`, `view_from_world`, `clip_from_view` and `view_from_clip`. - `GpuDirectionalCascade::view_projection` was renamed to `clip_from_world`. - `MeshTransforms`' `transform` and `previous_transform` were renamed to `world_from_local` and `previous_world_from_local`. - `MeshUniform`'s `transform`, `previous_transform`, `inverse_transpose_model_a` and `inverse_transpose_model_b` were renamed to `world_from_local`, `previous_world_from_local`, `local_from_world_transpose_a` and `local_from_world_transpose_b` (the `Mesh` type in WGSL mirrors this, however `transform` and `previous_transform` were named `model` and `previous_model`). - `Mesh2dTransforms::transform` was renamed to `world_from_local`. - `Mesh2dUniform`'s `transform`, `inverse_transpose_model_a` and `inverse_transpose_model_b` were renamed to `world_from_local`, `local_from_world_transpose_a` and `local_from_world_transpose_b` (the `Mesh2d` type in WGSL mirrors this). - In WGSL, in `bevy_pbr::mesh_functions`, `get_model_matrix` and `get_previous_model_matrix` were renamed to `get_world_from_local` and `get_previous_world_from_local`. - In WGSL, `bevy_sprite::mesh2d_functions::get_model_matrix` was renamed to `get_world_from_local`.
2024-06-03 16:56:53 +00:00
world_from_voxel: Mat4,
voxel_from_world: Mat4,
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.
2024-02-06 23:23:20 +00:00
resolution: UVec3,
intensity: f32,
}
fn main() {
// Create the example app.
App::new()
.add_plugins(DefaultPlugins.set(WindowPlugin {
primary_window: Some(Window {
title: "Bevy Irradiance Volumes Example".into(),
..default()
}),
..default()
}))
.add_plugins(MaterialPlugin::<VoxelVisualizationMaterial>::default())
.init_resource::<AppStatus>()
.init_resource::<ExampleAssets>()
.insert_resource(AmbientLight {
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>
2024-02-29 19:35:12 +00:00
color: Color::WHITE,
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.
2024-02-06 23:23:20 +00:00
brightness: 0.0,
})
.add_systems(Startup, setup)
.add_systems(PreUpdate, create_cubes)
.add_systems(Update, rotate_camera)
.add_systems(Update, play_animations)
.add_systems(
Update,
handle_mouse_clicks
.after(rotate_camera)
.after(play_animations),
)
.add_systems(
Update,
change_main_object
.after(rotate_camera)
.after(play_animations),
)
.add_systems(
Update,
toggle_irradiance_volumes
.after(rotate_camera)
.after(play_animations),
)
.add_systems(
Update,
toggle_voxel_visibility
.after(rotate_camera)
.after(play_animations),
)
.add_systems(
Update,
toggle_rotation.after(rotate_camera).after(play_animations),
)
.add_systems(
Update,
draw_gizmo
.after(handle_mouse_clicks)
.after(change_main_object)
.after(toggle_irradiance_volumes)
.after(toggle_voxel_visibility)
.after(toggle_rotation),
)
.add_systems(
Update,
update_text
.after(handle_mouse_clicks)
.after(change_main_object)
.after(toggle_irradiance_volumes)
.after(toggle_voxel_visibility)
.after(toggle_rotation),
)
.run();
}
// Spawns all the scene objects.
fn setup(mut commands: Commands, assets: Res<ExampleAssets>, app_status: Res<AppStatus>) {
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.
2024-02-06 23:23:20 +00:00
spawn_main_scene(&mut commands, &assets);
spawn_camera(&mut commands, &assets);
spawn_irradiance_volume(&mut commands, &assets);
spawn_light(&mut commands);
spawn_sphere(&mut commands, &assets);
spawn_voxel_cube_parent(&mut commands);
spawn_fox(&mut commands, &assets);
spawn_text(&mut commands, &app_status);
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.
2024-02-06 23:23:20 +00:00
}
fn spawn_main_scene(commands: &mut Commands, assets: &ExampleAssets) {
commands.spawn(SceneBundle {
scene: assets.main_scene.clone(),
..SceneBundle::default()
});
}
fn spawn_camera(commands: &mut Commands, assets: &ExampleAssets) {
commands
.spawn(Camera3dBundle {
transform: Transform::from_xyz(-10.012, 4.8605, 13.281).looking_at(Vec3::ZERO, Vec3::Y),
..default()
})
.insert(Skybox {
image: assets.skybox.clone(),
brightness: 150.0,
});
}
fn spawn_irradiance_volume(commands: &mut Commands, assets: &ExampleAssets) {
commands
.spawn(SpatialBundle {
Normalise matrix naming (#13489) # Objective - Fixes #10909 - Fixes #8492 ## Solution - Name all matrices `x_from_y`, for example `world_from_view`. ## Testing - I've tested most of the 3D examples. The `lighting` example particularly should hit a lot of the changes and appears to run fine. --- ## Changelog - Renamed matrices across the engine to follow a `y_from_x` naming, making the space conversion more obvious. ## Migration Guide - `Frustum`'s `from_view_projection`, `from_view_projection_custom_far` and `from_view_projection_no_far` were renamed to `from_clip_from_world`, `from_clip_from_world_custom_far` and `from_clip_from_world_no_far`. - `ComputedCameraValues::projection_matrix` was renamed to `clip_from_view`. - `CameraProjection::get_projection_matrix` was renamed to `get_clip_from_view` (this affects implementations on `Projection`, `PerspectiveProjection` and `OrthographicProjection`). - `ViewRangefinder3d::from_view_matrix` was renamed to `from_world_from_view`. - `PreviousViewData`'s members were renamed to `view_from_world` and `clip_from_world`. - `ExtractedView`'s `projection`, `transform` and `view_projection` were renamed to `clip_from_view`, `world_from_view` and `clip_from_world`. - `ViewUniform`'s `view_proj`, `unjittered_view_proj`, `inverse_view_proj`, `view`, `inverse_view`, `projection` and `inverse_projection` were renamed to `clip_from_world`, `unjittered_clip_from_world`, `world_from_clip`, `world_from_view`, `view_from_world`, `clip_from_view` and `view_from_clip`. - `GpuDirectionalCascade::view_projection` was renamed to `clip_from_world`. - `MeshTransforms`' `transform` and `previous_transform` were renamed to `world_from_local` and `previous_world_from_local`. - `MeshUniform`'s `transform`, `previous_transform`, `inverse_transpose_model_a` and `inverse_transpose_model_b` were renamed to `world_from_local`, `previous_world_from_local`, `local_from_world_transpose_a` and `local_from_world_transpose_b` (the `Mesh` type in WGSL mirrors this, however `transform` and `previous_transform` were named `model` and `previous_model`). - `Mesh2dTransforms::transform` was renamed to `world_from_local`. - `Mesh2dUniform`'s `transform`, `inverse_transpose_model_a` and `inverse_transpose_model_b` were renamed to `world_from_local`, `local_from_world_transpose_a` and `local_from_world_transpose_b` (the `Mesh2d` type in WGSL mirrors this). - In WGSL, in `bevy_pbr::mesh_functions`, `get_model_matrix` and `get_previous_model_matrix` were renamed to `get_world_from_local` and `get_previous_world_from_local`. - In WGSL, `bevy_sprite::mesh2d_functions::get_model_matrix` was renamed to `get_world_from_local`.
2024-06-03 16:56:53 +00:00
transform: Transform::from_matrix(VOXEL_FROM_WORLD),
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.
2024-02-06 23:23:20 +00:00
..SpatialBundle::default()
})
.insert(IrradianceVolume {
voxels: assets.irradiance_volume.clone(),
intensity: IRRADIANCE_VOLUME_INTENSITY,
})
.insert(LightProbe);
}
fn spawn_light(commands: &mut Commands) {
commands.spawn(PointLightBundle {
point_light: PointLight {
intensity: 250000.0,
shadows_enabled: true,
..default()
},
transform: Transform::from_xyz(4.0762, 5.9039, 1.0055),
..default()
});
}
fn spawn_sphere(commands: &mut Commands, assets: &ExampleAssets) {
commands
.spawn(PbrBundle {
mesh: assets.main_sphere.clone(),
material: assets.main_sphere_material.clone(),
transform: Transform::from_xyz(0.0, SPHERE_SCALE, 0.0)
.with_scale(Vec3::splat(SPHERE_SCALE)),
..default()
})
.insert(MainObject);
}
fn spawn_voxel_cube_parent(commands: &mut Commands) {
commands
.spawn(SpatialBundle {
visibility: Visibility::Hidden,
..default()
})
.insert(VoxelCubeParent);
}
fn spawn_fox(commands: &mut Commands, assets: &ExampleAssets) {
commands
.spawn(SceneBundle {
scene: assets.fox.clone(),
visibility: Visibility::Hidden,
transform: Transform::from_scale(Vec3::splat(FOX_SCALE)),
..default()
})
.insert(MainObject);
}
fn spawn_text(commands: &mut Commands, app_status: &AppStatus) {
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.
2024-02-06 23:23:20 +00:00
commands.spawn(
TextBundle {
text: app_status.create_text(),
..default()
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.
2024-02-06 23:23:20 +00:00
}
.with_style(Style {
position_type: PositionType::Absolute,
bottom: Val::Px(12.0),
left: Val::Px(12.0),
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.
2024-02-06 23:23:20 +00:00
..default()
}),
);
}
// A system that updates the help text.
fn update_text(mut text_query: Query<&mut Text>, app_status: Res<AppStatus>) {
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.
2024-02-06 23:23:20 +00:00
for mut text in text_query.iter_mut() {
*text = app_status.create_text();
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.
2024-02-06 23:23:20 +00:00
}
}
impl AppStatus {
// Constructs the help text at the bottom of the screen based on the
// application status.
fn create_text(&self) -> Text {
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.
2024-02-06 23:23:20 +00:00
let irradiance_volume_help_text = if self.irradiance_volume_present {
DISABLE_IRRADIANCE_VOLUME_HELP_TEXT
} else {
ENABLE_IRRADIANCE_VOLUME_HELP_TEXT
};
let voxels_help_text = if self.voxels_visible {
HIDE_VOXELS_HELP_TEXT
} else {
SHOW_VOXELS_HELP_TEXT
};
let rotation_help_text = if self.rotating {
STOP_ROTATION_HELP_TEXT
} else {
START_ROTATION_HELP_TEXT
};
let switch_mesh_help_text = match self.model {
ExampleModel::Sphere => SWITCH_TO_FOX_HELP_TEXT,
ExampleModel::Fox => SWITCH_TO_SPHERE_HELP_TEXT,
};
Text::from_section(
format!(
"{}\n{}\n{}\n{}\n{}",
CLICK_TO_MOVE_HELP_TEXT,
voxels_help_text,
irradiance_volume_help_text,
rotation_help_text,
switch_mesh_help_text
),
TextStyle::default(),
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.
2024-02-06 23:23:20 +00:00
)
}
}
// Rotates the camera a bit every frame.
fn rotate_camera(
mut camera_query: Query<&mut Transform, With<Camera3d>>,
time: Res<Time>,
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.
2024-02-06 23:23:20 +00:00
app_status: Res<AppStatus>,
) {
if !app_status.rotating {
return;
}
for mut transform in camera_query.iter_mut() {
transform.translation = Vec2::from_angle(ROTATION_SPEED * time.delta_seconds())
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.
2024-02-06 23:23:20 +00:00
.rotate(transform.translation.xz())
.extend(transform.translation.y)
.xzy();
transform.look_at(Vec3::ZERO, Vec3::Y);
}
}
// Toggles between the unskinned sphere model and the skinned fox model if the
// user requests it.
fn change_main_object(
keyboard: Res<ButtonInput<KeyCode>>,
mut app_status: ResMut<AppStatus>,
mut sphere_query: Query<
&mut Visibility,
(With<MainObject>, With<Handle<Mesh>>, Without<Handle<Scene>>),
>,
mut fox_query: Query<&mut Visibility, (With<MainObject>, With<Handle<Scene>>)>,
) {
if !keyboard.just_pressed(KeyCode::Tab) {
return;
}
let Some(mut sphere_visibility) = sphere_query.iter_mut().next() else {
return;
};
let Some(mut fox_visibility) = fox_query.iter_mut().next() else {
return;
};
match app_status.model {
ExampleModel::Sphere => {
*sphere_visibility = Visibility::Hidden;
*fox_visibility = Visibility::Visible;
app_status.model = ExampleModel::Fox;
}
ExampleModel::Fox => {
*sphere_visibility = Visibility::Visible;
*fox_visibility = Visibility::Hidden;
app_status.model = ExampleModel::Sphere;
}
}
}
impl Default for AppStatus {
fn default() -> Self {
Self {
irradiance_volume_present: true,
rotating: true,
model: ExampleModel::Sphere,
voxels_visible: false,
}
}
}
// Turns on and off the irradiance volume as requested by the user.
fn toggle_irradiance_volumes(
mut commands: Commands,
keyboard: Res<ButtonInput<KeyCode>>,
light_probe_query: Query<Entity, With<LightProbe>>,
mut app_status: ResMut<AppStatus>,
assets: Res<ExampleAssets>,
mut ambient_light: ResMut<AmbientLight>,
) {
if !keyboard.just_pressed(KeyCode::Space) {
return;
};
let Some(light_probe) = light_probe_query.iter().next() else {
return;
};
if app_status.irradiance_volume_present {
commands.entity(light_probe).remove::<IrradianceVolume>();
ambient_light.brightness = AMBIENT_LIGHT_BRIGHTNESS * IRRADIANCE_VOLUME_INTENSITY;
app_status.irradiance_volume_present = false;
} else {
commands.entity(light_probe).insert(IrradianceVolume {
voxels: assets.irradiance_volume.clone(),
intensity: IRRADIANCE_VOLUME_INTENSITY,
});
ambient_light.brightness = 0.0;
app_status.irradiance_volume_present = true;
}
}
fn toggle_rotation(keyboard: Res<ButtonInput<KeyCode>>, mut app_status: ResMut<AppStatus>) {
if keyboard.just_pressed(KeyCode::Enter) {
app_status.rotating = !app_status.rotating;
}
}
// Handles clicks on the plane that reposition the object.
fn handle_mouse_clicks(
buttons: Res<ButtonInput<MouseButton>>,
windows: Query<&Window, With<PrimaryWindow>>,
cameras: Query<(&Camera, &GlobalTransform)>,
mut main_objects: Query<&mut Transform, With<MainObject>>,
) {
if !buttons.pressed(MouseButton::Left) {
return;
}
let Some(mouse_position) = windows
.iter()
.next()
.and_then(|window| window.cursor_position())
else {
return;
};
let Some((camera, camera_transform)) = cameras.iter().next() else {
return;
};
// Figure out where the user clicked on the plane.
let Some(ray) = camera.viewport_to_world(camera_transform, mouse_position) else {
return;
};
let Some(ray_distance) = ray.intersect_plane(Vec3::ZERO, InfinitePlane3d::new(Vec3::Y)) else {
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.
2024-02-06 23:23:20 +00:00
return;
};
let plane_intersection = ray.origin + ray.direction.normalize() * ray_distance;
// Move all the main objeccts.
for mut transform in main_objects.iter_mut() {
transform.translation = vec3(
plane_intersection.x,
transform.translation.y,
plane_intersection.z,
);
}
}
impl FromWorld for ExampleAssets {
fn from_world(world: &mut World) -> Self {
let fox_animation =
world.load_asset(GltfAssetLabel::Animation(1).from_asset("models/animated/Fox.glb"));
Implement the `AnimationGraph`, allowing for multiple animations to be blended together. (#11989) This is an implementation of RFC #51: https://github.com/bevyengine/rfcs/blob/main/rfcs/51-animation-composition.md Note that the implementation strategy is different from the one outlined in that RFC, because two-phase animation has now landed. # Objective Bevy needs animation blending. The RFC for this is [RFC 51]. ## Solution This is an implementation of the RFC. Note that the implementation strategy is different from the one outlined there, because two-phase animation has now landed. This is just a draft to get the conversation started. Currently we're missing a few things: - [x] A fully-fleshed-out mechanism for transitions - [x] A serialization format for `AnimationGraph`s - [x] Examples are broken, other than `animated_fox` - [x] Documentation --- ## Changelog ### Added * The `AnimationPlayer` has been reworked to support blending multiple animations together through an `AnimationGraph`, and as such will no longer function unless a `Handle<AnimationGraph>` has been added to the entity containing the player. See [RFC 51] for more details. * Transition functionality has moved from the `AnimationPlayer` to a new component, `AnimationTransitions`, which works in tandem with the `AnimationGraph`. ## Migration Guide * `AnimationPlayer`s can no longer play animations by themselves and need to be paired with a `Handle<AnimationGraph>`. Code that was using `AnimationPlayer` to play animations will need to create an `AnimationGraph` asset first, add a node for the clip (or clips) you want to play, and then supply the index of that node to the `AnimationPlayer`'s `play` method. * The `AnimationPlayer::play_with_transition()` method has been removed and replaced with the `AnimationTransitions` component. If you were previously using `AnimationPlayer::play_with_transition()`, add all animations that you were playing to the `AnimationGraph`, and create an `AnimationTransitions` component to manage the blending between them. [RFC 51]: https://github.com/bevyengine/rfcs/blob/main/rfcs/51-animation-composition.md --------- Co-authored-by: Rob Parrett <robparrett@gmail.com>
2024-03-07 20:22:42 +00:00
let (fox_animation_graph, fox_animation_node) =
AnimationGraph::from_clip(fox_animation.clone());
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.
2024-02-06 23:23:20 +00:00
ExampleAssets {
main_sphere: world.add_asset(Sphere::default().mesh().uv(32, 18)),
fox: world.load_asset(GltfAssetLabel::Scene(0).from_asset("models/animated/Fox.glb")),
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>
2024-02-29 19:35:12 +00:00
main_sphere_material: world.add_asset(Color::from(SILVER)),
main_scene: world.load_asset(
GltfAssetLabel::Scene(0)
.from_asset("models/IrradianceVolumeExample/IrradianceVolumeExample.glb"),
),
irradiance_volume: world.load_asset("irradiance_volumes/Example.vxgi.ktx2"),
Implement the `AnimationGraph`, allowing for multiple animations to be blended together. (#11989) This is an implementation of RFC #51: https://github.com/bevyengine/rfcs/blob/main/rfcs/51-animation-composition.md Note that the implementation strategy is different from the one outlined in that RFC, because two-phase animation has now landed. # Objective Bevy needs animation blending. The RFC for this is [RFC 51]. ## Solution This is an implementation of the RFC. Note that the implementation strategy is different from the one outlined there, because two-phase animation has now landed. This is just a draft to get the conversation started. Currently we're missing a few things: - [x] A fully-fleshed-out mechanism for transitions - [x] A serialization format for `AnimationGraph`s - [x] Examples are broken, other than `animated_fox` - [x] Documentation --- ## Changelog ### Added * The `AnimationPlayer` has been reworked to support blending multiple animations together through an `AnimationGraph`, and as such will no longer function unless a `Handle<AnimationGraph>` has been added to the entity containing the player. See [RFC 51] for more details. * Transition functionality has moved from the `AnimationPlayer` to a new component, `AnimationTransitions`, which works in tandem with the `AnimationGraph`. ## Migration Guide * `AnimationPlayer`s can no longer play animations by themselves and need to be paired with a `Handle<AnimationGraph>`. Code that was using `AnimationPlayer` to play animations will need to create an `AnimationGraph` asset first, add a node for the clip (or clips) you want to play, and then supply the index of that node to the `AnimationPlayer`'s `play` method. * The `AnimationPlayer::play_with_transition()` method has been removed and replaced with the `AnimationTransitions` component. If you were previously using `AnimationPlayer::play_with_transition()`, add all animations that you were playing to the `AnimationGraph`, and create an `AnimationTransitions` component to manage the blending between them. [RFC 51]: https://github.com/bevyengine/rfcs/blob/main/rfcs/51-animation-composition.md --------- Co-authored-by: Rob Parrett <robparrett@gmail.com>
2024-03-07 20:22:42 +00:00
fox_animation_graph: world.add_asset(fox_animation_graph),
fox_animation_node,
voxel_cube: world.add_asset(Cuboid::default()),
// Just use a specular map for the skybox since it's not too blurry.
// In reality you wouldn't do this--you'd use a real skybox texture--but
// reusing the textures like this saves space in the Bevy repository.
skybox: world.load_asset("environment_maps/pisa_specular_rgb9e5_zstd.ktx2"),
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.
2024-02-06 23:23:20 +00:00
}
}
}
// Plays the animation on the fox.
Implement the `AnimationGraph`, allowing for multiple animations to be blended together. (#11989) This is an implementation of RFC #51: https://github.com/bevyengine/rfcs/blob/main/rfcs/51-animation-composition.md Note that the implementation strategy is different from the one outlined in that RFC, because two-phase animation has now landed. # Objective Bevy needs animation blending. The RFC for this is [RFC 51]. ## Solution This is an implementation of the RFC. Note that the implementation strategy is different from the one outlined there, because two-phase animation has now landed. This is just a draft to get the conversation started. Currently we're missing a few things: - [x] A fully-fleshed-out mechanism for transitions - [x] A serialization format for `AnimationGraph`s - [x] Examples are broken, other than `animated_fox` - [x] Documentation --- ## Changelog ### Added * The `AnimationPlayer` has been reworked to support blending multiple animations together through an `AnimationGraph`, and as such will no longer function unless a `Handle<AnimationGraph>` has been added to the entity containing the player. See [RFC 51] for more details. * Transition functionality has moved from the `AnimationPlayer` to a new component, `AnimationTransitions`, which works in tandem with the `AnimationGraph`. ## Migration Guide * `AnimationPlayer`s can no longer play animations by themselves and need to be paired with a `Handle<AnimationGraph>`. Code that was using `AnimationPlayer` to play animations will need to create an `AnimationGraph` asset first, add a node for the clip (or clips) you want to play, and then supply the index of that node to the `AnimationPlayer`'s `play` method. * The `AnimationPlayer::play_with_transition()` method has been removed and replaced with the `AnimationTransitions` component. If you were previously using `AnimationPlayer::play_with_transition()`, add all animations that you were playing to the `AnimationGraph`, and create an `AnimationTransitions` component to manage the blending between them. [RFC 51]: https://github.com/bevyengine/rfcs/blob/main/rfcs/51-animation-composition.md --------- Co-authored-by: Rob Parrett <robparrett@gmail.com>
2024-03-07 20:22:42 +00:00
fn play_animations(
mut commands: Commands,
assets: Res<ExampleAssets>,
mut players: Query<(Entity, &mut AnimationPlayer), Without<Handle<AnimationGraph>>>,
) {
for (entity, mut player) in players.iter_mut() {
commands
.entity(entity)
.insert(assets.fox_animation_graph.clone());
player.play(assets.fox_animation_node).repeat();
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.
2024-02-06 23:23:20 +00:00
}
}
fn create_cubes(
image_assets: Res<Assets<Image>>,
mut commands: Commands,
irradiance_volumes: Query<(&IrradianceVolume, &GlobalTransform)>,
voxel_cube_parents: Query<Entity, With<VoxelCubeParent>>,
voxel_cubes: Query<Entity, With<VoxelCube>>,
example_assets: Res<ExampleAssets>,
mut voxel_visualization_material_assets: ResMut<Assets<VoxelVisualizationMaterial>>,
) {
// If voxel cubes have already been spawned, don't do anything.
if !voxel_cubes.is_empty() {
return;
}
let Some(voxel_cube_parent) = voxel_cube_parents.iter().next() else {
return;
};
for (irradiance_volume, global_transform) in irradiance_volumes.iter() {
let Some(image) = image_assets.get(&irradiance_volume.voxels) else {
continue;
};
let resolution = image.texture_descriptor.size;
let voxel_cube_material = voxel_visualization_material_assets.add(ExtendedMaterial {
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>
2024-02-29 19:35:12 +00:00
base: StandardMaterial::from(Color::from(RED)),
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.
2024-02-06 23:23:20 +00:00
extension: VoxelVisualizationExtension {
irradiance_volume_info: VoxelVisualizationIrradianceVolumeInfo {
Normalise matrix naming (#13489) # Objective - Fixes #10909 - Fixes #8492 ## Solution - Name all matrices `x_from_y`, for example `world_from_view`. ## Testing - I've tested most of the 3D examples. The `lighting` example particularly should hit a lot of the changes and appears to run fine. --- ## Changelog - Renamed matrices across the engine to follow a `y_from_x` naming, making the space conversion more obvious. ## Migration Guide - `Frustum`'s `from_view_projection`, `from_view_projection_custom_far` and `from_view_projection_no_far` were renamed to `from_clip_from_world`, `from_clip_from_world_custom_far` and `from_clip_from_world_no_far`. - `ComputedCameraValues::projection_matrix` was renamed to `clip_from_view`. - `CameraProjection::get_projection_matrix` was renamed to `get_clip_from_view` (this affects implementations on `Projection`, `PerspectiveProjection` and `OrthographicProjection`). - `ViewRangefinder3d::from_view_matrix` was renamed to `from_world_from_view`. - `PreviousViewData`'s members were renamed to `view_from_world` and `clip_from_world`. - `ExtractedView`'s `projection`, `transform` and `view_projection` were renamed to `clip_from_view`, `world_from_view` and `clip_from_world`. - `ViewUniform`'s `view_proj`, `unjittered_view_proj`, `inverse_view_proj`, `view`, `inverse_view`, `projection` and `inverse_projection` were renamed to `clip_from_world`, `unjittered_clip_from_world`, `world_from_clip`, `world_from_view`, `view_from_world`, `clip_from_view` and `view_from_clip`. - `GpuDirectionalCascade::view_projection` was renamed to `clip_from_world`. - `MeshTransforms`' `transform` and `previous_transform` were renamed to `world_from_local` and `previous_world_from_local`. - `MeshUniform`'s `transform`, `previous_transform`, `inverse_transpose_model_a` and `inverse_transpose_model_b` were renamed to `world_from_local`, `previous_world_from_local`, `local_from_world_transpose_a` and `local_from_world_transpose_b` (the `Mesh` type in WGSL mirrors this, however `transform` and `previous_transform` were named `model` and `previous_model`). - `Mesh2dTransforms::transform` was renamed to `world_from_local`. - `Mesh2dUniform`'s `transform`, `inverse_transpose_model_a` and `inverse_transpose_model_b` were renamed to `world_from_local`, `local_from_world_transpose_a` and `local_from_world_transpose_b` (the `Mesh2d` type in WGSL mirrors this). - In WGSL, in `bevy_pbr::mesh_functions`, `get_model_matrix` and `get_previous_model_matrix` were renamed to `get_world_from_local` and `get_previous_world_from_local`. - In WGSL, `bevy_sprite::mesh2d_functions::get_model_matrix` was renamed to `get_world_from_local`.
2024-06-03 16:56:53 +00:00
world_from_voxel: VOXEL_FROM_WORLD.inverse(),
voxel_from_world: VOXEL_FROM_WORLD,
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.
2024-02-06 23:23:20 +00:00
resolution: uvec3(
resolution.width,
resolution.height,
resolution.depth_or_array_layers,
),
intensity: IRRADIANCE_VOLUME_INTENSITY,
},
},
});
let scale = vec3(
1.0 / resolution.width as f32,
1.0 / resolution.height as f32,
1.0 / resolution.depth_or_array_layers as f32,
);
// Spawn a cube for each voxel.
for z in 0..resolution.depth_or_array_layers {
for y in 0..resolution.height {
for x in 0..resolution.width {
let uvw = (uvec3(x, y, z).as_vec3() + 0.5) * scale - 0.5;
let pos = global_transform.transform_point(uvw);
let voxel_cube = commands
.spawn(MaterialMeshBundle {
mesh: example_assets.voxel_cube.clone(),
material: voxel_cube_material.clone(),
transform: Transform::from_scale(Vec3::splat(VOXEL_CUBE_SCALE))
.with_translation(pos),
..default()
})
.insert(VoxelCube)
.insert(NotShadowCaster)
.id();
commands.entity(voxel_cube_parent).add_child(voxel_cube);
}
}
}
}
}
// Draws a gizmo showing the bounds of the irradiance volume.
fn draw_gizmo(
mut gizmos: Gizmos,
irradiance_volume_query: Query<&GlobalTransform, With<IrradianceVolume>>,
app_status: Res<AppStatus>,
) {
if app_status.voxels_visible {
for transform in irradiance_volume_query.iter() {
gizmos.cuboid(*transform, GIZMO_COLOR);
}
}
}
// Handles a request from the user to toggle the voxel visibility on and off.
fn toggle_voxel_visibility(
keyboard: Res<ButtonInput<KeyCode>>,
mut app_status: ResMut<AppStatus>,
mut voxel_cube_parent_query: Query<&mut Visibility, With<VoxelCubeParent>>,
) {
if !keyboard.just_pressed(KeyCode::Backspace) {
return;
}
app_status.voxels_visible = !app_status.voxels_visible;
for mut visibility in voxel_cube_parent_query.iter_mut() {
*visibility = if app_status.voxels_visible {
Visibility::Visible
} else {
Visibility::Hidden
};
}
}
impl MaterialExtension for VoxelVisualizationExtension {
fn fragment_shader() -> ShaderRef {
"shaders/irradiance_volume_voxel_visualization.wgsl".into()
}
}