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//! Producing the WGSL forms of types, for use in error messages.
use crate::proc::GlobalCtx;
use crate::Handle;
impl crate::proc::TypeResolution {
pub fn to_wgsl(&self, gctx: &GlobalCtx) -> String {
match *self {
crate::proc::TypeResolution::Handle(handle) => handle.to_wgsl(gctx),
crate::proc::TypeResolution::Value(ref inner) => inner.to_wgsl(gctx),
}
}
}
impl Handle<crate::Type> {
/// Formats the type as it is written in wgsl.
///
/// For example `vec3<f32>`.
pub fn to_wgsl(self, gctx: &GlobalCtx) -> String {
let ty = &gctx.types[self];
match ty.name {
Some(ref name) => name.clone(),
None => ty.inner.to_wgsl(gctx),
}
}
}
impl crate::TypeInner {
/// Formats the type as it is written in wgsl.
///
/// For example `vec3<f32>`.
///
/// Note: `TypeInner::Struct` doesn't include the name of the
/// struct type. Therefore this method will simply return "struct"
/// for them.
pub fn to_wgsl(&self, gctx: &GlobalCtx) -> String {
use crate::TypeInner as Ti;
match *self {
Ti::Scalar(scalar) => scalar.to_wgsl(),
Ti::Vector { size, scalar } => {
format!("vec{}<{}>", size as u32, scalar.to_wgsl())
}
Ti::Matrix {
columns,
rows,
scalar,
} => {
format!(
"mat{}x{}<{}>",
columns as u32,
rows as u32,
scalar.to_wgsl(),
)
}
Ti::Atomic(scalar) => {
format!("atomic<{}>", scalar.to_wgsl())
}
Ti::Pointer { base, .. } => {
let name = base.to_wgsl(gctx);
format!("ptr<{name}>")
}
Ti::ValuePointer { scalar, .. } => {
format!("ptr<{}>", scalar.to_wgsl())
}
Ti::Array { base, size, .. } => {
let base = base.to_wgsl(gctx);
match size {
crate::ArraySize::Constant(size) => format!("array<{base}, {size}>"),
crate::ArraySize::Dynamic => format!("array<{base}>"),
}
}
Ti::Struct { .. } => {
// TODO: Actually output the struct?
"struct".to_string()
}
Ti::Image {
dim,
arrayed,
class,
} => {
let dim_suffix = match dim {
crate::ImageDimension::D1 => "_1d",
crate::ImageDimension::D2 => "_2d",
crate::ImageDimension::D3 => "_3d",
crate::ImageDimension::Cube => "_cube",
};
let array_suffix = if arrayed { "_array" } else { "" };
let class_suffix = match class {
crate::ImageClass::Sampled { multi: true, .. } => "_multisampled",
crate::ImageClass::Depth { multi: false } => "_depth",
crate::ImageClass::Depth { multi: true } => "_depth_multisampled",
crate::ImageClass::Sampled { multi: false, .. }
| crate::ImageClass::Storage { .. } => "",
};
let type_in_brackets = match class {
crate::ImageClass::Sampled { kind, .. } => {
// Note: The only valid widths are 4 bytes wide.
// The lexer has already verified this, so we can safely assume it here.
let element_type = crate::Scalar { kind, width: 4 }.to_wgsl();
format!("<{element_type}>")
}
crate::ImageClass::Depth { multi: _ } => String::new(),
crate::ImageClass::Storage { format, access } => {
if access.contains(crate::StorageAccess::STORE) {
format!("<{},write>", format.to_wgsl())
} else {
format!("<{}>", format.to_wgsl())
}
}
};
format!("texture{class_suffix}{dim_suffix}{array_suffix}{type_in_brackets}")
}
Ti::Sampler { .. } => "sampler".to_string(),
Ti::AccelerationStructure => "acceleration_structure".to_string(),
Ti::RayQuery => "ray_query".to_string(),
Ti::BindingArray { base, size, .. } => {
let member_type = &gctx.types[base];
let base = member_type.name.as_deref().unwrap_or("unknown");
match size {
crate::ArraySize::Constant(size) => format!("binding_array<{base}, {size}>"),
crate::ArraySize::Dynamic => format!("binding_array<{base}>"),
}
}
}
}
}
impl crate::Scalar {
/// Format a scalar kind+width as a type is written in wgsl.
///
/// Examples: `f32`, `u64`, `bool`.
pub fn to_wgsl(self) -> String {
let prefix = match self.kind {
crate::ScalarKind::Sint => "i",
crate::ScalarKind::Uint => "u",
crate::ScalarKind::Float => "f",
crate::ScalarKind::Bool => return "bool".to_string(),
crate::ScalarKind::AbstractInt => return "{AbstractInt}".to_string(),
crate::ScalarKind::AbstractFloat => return "{AbstractFloat}".to_string(),
};
format!("{}{}", prefix, self.width * 8)
}
}
impl crate::StorageFormat {
pub const fn to_wgsl(self) -> &'static str {
use crate::StorageFormat as Sf;
match self {
Sf::R8Unorm => "r8unorm",
Sf::R8Snorm => "r8snorm",
Sf::R8Uint => "r8uint",
Sf::R8Sint => "r8sint",
Sf::R16Uint => "r16uint",
Sf::R16Sint => "r16sint",
Sf::R16Float => "r16float",
Sf::Rg8Unorm => "rg8unorm",
Sf::Rg8Snorm => "rg8snorm",
Sf::Rg8Uint => "rg8uint",
Sf::Rg8Sint => "rg8sint",
Sf::R32Uint => "r32uint",
Sf::R32Sint => "r32sint",
Sf::R32Float => "r32float",
Sf::Rg16Uint => "rg16uint",
Sf::Rg16Sint => "rg16sint",
Sf::Rg16Float => "rg16float",
Sf::Rgba8Unorm => "rgba8unorm",
Sf::Rgba8Snorm => "rgba8snorm",
Sf::Rgba8Uint => "rgba8uint",
Sf::Rgba8Sint => "rgba8sint",
Sf::Bgra8Unorm => "bgra8unorm",
Sf::Rgb10a2Uint => "rgb10a2uint",
Sf::Rgb10a2Unorm => "rgb10a2unorm",
Sf::Rg11b10Ufloat => "rg11b10float",
Sf::Rg32Uint => "rg32uint",
Sf::Rg32Sint => "rg32sint",
Sf::Rg32Float => "rg32float",
Sf::Rgba16Uint => "rgba16uint",
Sf::Rgba16Sint => "rgba16sint",
Sf::Rgba16Float => "rgba16float",
Sf::Rgba32Uint => "rgba32uint",
Sf::Rgba32Sint => "rgba32sint",
Sf::Rgba32Float => "rgba32float",
Sf::R16Unorm => "r16unorm",
Sf::R16Snorm => "r16snorm",
Sf::Rg16Unorm => "rg16unorm",
Sf::Rg16Snorm => "rg16snorm",
Sf::Rgba16Unorm => "rgba16unorm",
Sf::Rgba16Snorm => "rgba16snorm",
}
}
}
mod tests {
#[test]
fn to_wgsl() {
use std::num::NonZeroU32;
let mut types = crate::UniqueArena::new();
let mytype1 = types.insert(
crate::Type {
name: Some("MyType1".to_string()),
inner: crate::TypeInner::Struct {
members: vec![],
span: 0,
},
},
Default::default(),
);
let mytype2 = types.insert(
crate::Type {
name: Some("MyType2".to_string()),
inner: crate::TypeInner::Struct {
members: vec![],
span: 0,
},
},
Default::default(),
);
let gctx = crate::proc::GlobalCtx {
types: &types,
constants: &crate::Arena::new(),
overrides: &crate::Arena::new(),
global_expressions: &crate::Arena::new(),
};
let array = crate::TypeInner::Array {
base: mytype1,
stride: 4,
size: crate::ArraySize::Constant(unsafe { NonZeroU32::new_unchecked(32) }),
};
assert_eq!(array.to_wgsl(&gctx), "array<MyType1, 32>");
let mat = crate::TypeInner::Matrix {
rows: crate::VectorSize::Quad,
columns: crate::VectorSize::Bi,
scalar: crate::Scalar::F64,
};
assert_eq!(mat.to_wgsl(&gctx), "mat2x4<f64>");
let ptr = crate::TypeInner::Pointer {
base: mytype2,
space: crate::AddressSpace::Storage {
access: crate::StorageAccess::default(),
},
};
assert_eq!(ptr.to_wgsl(&gctx), "ptr<MyType2>");
let img1 = crate::TypeInner::Image {
dim: crate::ImageDimension::D2,
arrayed: false,
class: crate::ImageClass::Sampled {
kind: crate::ScalarKind::Float,
multi: true,
},
};
assert_eq!(img1.to_wgsl(&gctx), "texture_multisampled_2d<f32>");
let img2 = crate::TypeInner::Image {
dim: crate::ImageDimension::Cube,
arrayed: true,
class: crate::ImageClass::Depth { multi: false },
};
assert_eq!(img2.to_wgsl(&gctx), "texture_depth_cube_array");
let img3 = crate::TypeInner::Image {
dim: crate::ImageDimension::D2,
arrayed: false,
class: crate::ImageClass::Depth { multi: true },
};
assert_eq!(img3.to_wgsl(&gctx), "texture_depth_multisampled_2d");
let array = crate::TypeInner::BindingArray {
base: mytype1,
size: crate::ArraySize::Constant(unsafe { NonZeroU32::new_unchecked(32) }),
};
assert_eq!(array.to_wgsl(&gctx), "binding_array<MyType1, 32>");
}
}