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use super::{compose::validate_compose, FunctionInfo, ModuleInfo, ShaderStages, TypeFlags};
use crate::arena::UniqueArena;
use crate::{
arena::Handle,
proc::{IndexableLengthError, ResolveError},
};
#[derive(Clone, Debug, thiserror::Error)]
#[cfg_attr(test, derive(PartialEq))]
pub enum ExpressionError {
#[error("Used by a statement before it was introduced into the scope by any of the dominating blocks")]
NotInScope,
#[error("Base type {0:?} is not compatible with this expression")]
InvalidBaseType(Handle<crate::Expression>),
#[error("Accessing with index {0:?} can't be done")]
InvalidIndexType(Handle<crate::Expression>),
#[error("Accessing {0:?} via a negative index is invalid")]
NegativeIndex(Handle<crate::Expression>),
#[error("Accessing index {1} is out of {0:?} bounds")]
IndexOutOfBounds(Handle<crate::Expression>, u32),
#[error("Function argument {0:?} doesn't exist")]
FunctionArgumentDoesntExist(u32),
#[error("Loading of {0:?} can't be done")]
InvalidPointerType(Handle<crate::Expression>),
#[error("Array length of {0:?} can't be done")]
InvalidArrayType(Handle<crate::Expression>),
#[error("Get intersection of {0:?} can't be done")]
InvalidRayQueryType(Handle<crate::Expression>),
#[error("Splatting {0:?} can't be done")]
InvalidSplatType(Handle<crate::Expression>),
#[error("Swizzling {0:?} can't be done")]
InvalidVectorType(Handle<crate::Expression>),
#[error("Swizzle component {0:?} is outside of vector size {1:?}")]
InvalidSwizzleComponent(crate::SwizzleComponent, crate::VectorSize),
#[error(transparent)]
Compose(#[from] super::ComposeError),
#[error(transparent)]
IndexableLength(#[from] IndexableLengthError),
#[error("Operation {0:?} can't work with {1:?}")]
InvalidUnaryOperandType(crate::UnaryOperator, Handle<crate::Expression>),
#[error("Operation {0:?} can't work with {1:?} and {2:?}")]
InvalidBinaryOperandTypes(
crate::BinaryOperator,
Handle<crate::Expression>,
Handle<crate::Expression>,
),
#[error("Selecting is not possible")]
InvalidSelectTypes,
#[error("Relational argument {0:?} is not a boolean vector")]
InvalidBooleanVector(Handle<crate::Expression>),
#[error("Relational argument {0:?} is not a float")]
InvalidFloatArgument(Handle<crate::Expression>),
#[error("Type resolution failed")]
Type(#[from] ResolveError),
#[error("Not a global variable")]
ExpectedGlobalVariable,
#[error("Not a global variable or a function argument")]
ExpectedGlobalOrArgument,
#[error("Needs to be an binding array instead of {0:?}")]
ExpectedBindingArrayType(Handle<crate::Type>),
#[error("Needs to be an image instead of {0:?}")]
ExpectedImageType(Handle<crate::Type>),
#[error("Needs to be an image instead of {0:?}")]
ExpectedSamplerType(Handle<crate::Type>),
#[error("Unable to operate on image class {0:?}")]
InvalidImageClass(crate::ImageClass),
#[error("Derivatives can only be taken from scalar and vector floats")]
InvalidDerivative,
#[error("Image array index parameter is misplaced")]
InvalidImageArrayIndex,
#[error("Inappropriate sample or level-of-detail index for texel access")]
InvalidImageOtherIndex,
#[error("Image array index type of {0:?} is not an integer scalar")]
InvalidImageArrayIndexType(Handle<crate::Expression>),
#[error("Image sample or level-of-detail index's type of {0:?} is not an integer scalar")]
InvalidImageOtherIndexType(Handle<crate::Expression>),
#[error("Image coordinate type of {1:?} does not match dimension {0:?}")]
InvalidImageCoordinateType(crate::ImageDimension, Handle<crate::Expression>),
#[error("Comparison sampling mismatch: image has class {image:?}, but the sampler is comparison={sampler}, and the reference was provided={has_ref}")]
ComparisonSamplingMismatch {
image: crate::ImageClass,
sampler: bool,
has_ref: bool,
},
#[error("Sample offset must be a const-expression")]
InvalidSampleOffsetExprType,
#[error("Sample offset constant {1:?} doesn't match the image dimension {0:?}")]
InvalidSampleOffset(crate::ImageDimension, Handle<crate::Expression>),
#[error("Depth reference {0:?} is not a scalar float")]
InvalidDepthReference(Handle<crate::Expression>),
#[error("Depth sample level can only be Auto or Zero")]
InvalidDepthSampleLevel,
#[error("Gather level can only be Zero")]
InvalidGatherLevel,
#[error("Gather component {0:?} doesn't exist in the image")]
InvalidGatherComponent(crate::SwizzleComponent),
#[error("Gather can't be done for image dimension {0:?}")]
InvalidGatherDimension(crate::ImageDimension),
#[error("Sample level (exact) type {0:?} is not a scalar float")]
InvalidSampleLevelExactType(Handle<crate::Expression>),
#[error("Sample level (bias) type {0:?} is not a scalar float")]
InvalidSampleLevelBiasType(Handle<crate::Expression>),
#[error("Sample level (gradient) of {1:?} doesn't match the image dimension {0:?}")]
InvalidSampleLevelGradientType(crate::ImageDimension, Handle<crate::Expression>),
#[error("Unable to cast")]
InvalidCastArgument,
#[error("Invalid argument count for {0:?}")]
WrongArgumentCount(crate::MathFunction),
#[error("Argument [{1}] to {0:?} as expression {2:?} has an invalid type.")]
InvalidArgumentType(crate::MathFunction, u32, Handle<crate::Expression>),
#[error(
"workgroupUniformLoad result type can't be {0:?}. It can only be a constructible type."
)]
InvalidWorkGroupUniformLoadResultType(Handle<crate::Type>),
#[error("Shader requires capability {0:?}")]
MissingCapabilities(super::Capabilities),
#[error(transparent)]
Literal(#[from] LiteralError),
#[error("{0:?} is not supported for Width {2} {1:?} arguments yet, see https://github.com/gfx-rs/wgpu/issues/5276")]
UnsupportedWidth(crate::MathFunction, crate::ScalarKind, crate::Bytes),
}
#[derive(Clone, Debug, thiserror::Error)]
#[cfg_attr(test, derive(PartialEq))]
pub enum ConstExpressionError {
#[error("The expression is not a constant or override expression")]
NonConstOrOverride,
#[error("The expression is not a fully evaluated constant expression")]
NonFullyEvaluatedConst,
#[error(transparent)]
Compose(#[from] super::ComposeError),
#[error("Splatting {0:?} can't be done")]
InvalidSplatType(Handle<crate::Expression>),
#[error("Type resolution failed")]
Type(#[from] ResolveError),
#[error(transparent)]
Literal(#[from] LiteralError),
#[error(transparent)]
Width(#[from] super::r#type::WidthError),
}
#[derive(Clone, Debug, thiserror::Error)]
#[cfg_attr(test, derive(PartialEq))]
pub enum LiteralError {
#[error("Float literal is NaN")]
NaN,
#[error("Float literal is infinite")]
Infinity,
#[error(transparent)]
Width(#[from] super::r#type::WidthError),
}
struct ExpressionTypeResolver<'a> {
root: Handle<crate::Expression>,
types: &'a UniqueArena<crate::Type>,
info: &'a FunctionInfo,
}
impl<'a> std::ops::Index<Handle<crate::Expression>> for ExpressionTypeResolver<'a> {
type Output = crate::TypeInner;
#[allow(clippy::panic)]
fn index(&self, handle: Handle<crate::Expression>) -> &Self::Output {
if handle < self.root {
self.info[handle].ty.inner_with(self.types)
} else {
// `Validator::validate_module_handles` should have caught this.
panic!(
"Depends on {:?}, which has not been processed yet",
self.root
)
}
}
}
impl super::Validator {
pub(super) fn validate_const_expression(
&self,
handle: Handle<crate::Expression>,
gctx: crate::proc::GlobalCtx,
mod_info: &ModuleInfo,
global_expr_kind: &crate::proc::ExpressionKindTracker,
) -> Result<(), ConstExpressionError> {
use crate::Expression as E;
if !global_expr_kind.is_const_or_override(handle) {
return Err(ConstExpressionError::NonConstOrOverride);
}
match gctx.global_expressions[handle] {
E::Literal(literal) => {
self.validate_literal(literal)?;
}
E::Constant(_) | E::ZeroValue(_) => {}
E::Compose { ref components, ty } => {
validate_compose(
ty,
gctx,
components.iter().map(|&handle| mod_info[handle].clone()),
)?;
}
E::Splat { value, .. } => match *mod_info[value].inner_with(gctx.types) {
crate::TypeInner::Scalar { .. } => {}
_ => return Err(ConstExpressionError::InvalidSplatType(value)),
},
_ if global_expr_kind.is_const(handle) || !self.allow_overrides => {
return Err(ConstExpressionError::NonFullyEvaluatedConst)
}
// the constant evaluator will report errors about override-expressions
_ => {}
}
Ok(())
}
#[allow(clippy::too_many_arguments)]
pub(super) fn validate_expression(
&self,
root: Handle<crate::Expression>,
expression: &crate::Expression,
function: &crate::Function,
module: &crate::Module,
info: &FunctionInfo,
mod_info: &ModuleInfo,
global_expr_kind: &crate::proc::ExpressionKindTracker,
) -> Result<ShaderStages, ExpressionError> {
use crate::{Expression as E, Scalar as Sc, ScalarKind as Sk, TypeInner as Ti};
let resolver = ExpressionTypeResolver {
root,
types: &module.types,
info,
};
let stages = match *expression {
E::Access { base, index } => {
let base_type = &resolver[base];
match *base_type {
Ti::Matrix { .. }
| Ti::Vector { .. }
| Ti::Array { .. }
| Ti::Pointer { .. }
| Ti::ValuePointer { size: Some(_), .. }
| Ti::BindingArray { .. } => false,
ref other => {
log::error!("Indexing of {:?}", other);
return Err(ExpressionError::InvalidBaseType(base));
}
};
match resolver[index] {
//TODO: only allow one of these
Ti::Scalar(Sc {
kind: Sk::Sint | Sk::Uint,
..
}) => {}
ref other => {
log::error!("Indexing by {:?}", other);
return Err(ExpressionError::InvalidIndexType(index));
}
}
// If we know both the length and the index, we can do the
// bounds check now.
if let crate::proc::IndexableLength::Known(known_length) =
base_type.indexable_length(module)?
{
match module
.to_ctx()
.eval_expr_to_u32_from(index, &function.expressions)
{
Ok(value) => {
if value >= known_length {
return Err(ExpressionError::IndexOutOfBounds(base, value));
}
}
Err(crate::proc::U32EvalError::Negative) => {
return Err(ExpressionError::NegativeIndex(base))
}
Err(crate::proc::U32EvalError::NonConst) => {}
}
}
ShaderStages::all()
}
E::AccessIndex { base, index } => {
fn resolve_index_limit(
module: &crate::Module,
top: Handle<crate::Expression>,
ty: &crate::TypeInner,
top_level: bool,
) -> Result<u32, ExpressionError> {
let limit = match *ty {
Ti::Vector { size, .. }
| Ti::ValuePointer {
size: Some(size), ..
} => size as u32,
Ti::Matrix { columns, .. } => columns as u32,
Ti::Array {
size: crate::ArraySize::Constant(len),
..
} => len.get(),
Ti::Array { .. } | Ti::BindingArray { .. } => u32::MAX, // can't statically know, but need run-time checks
Ti::Pointer { base, .. } if top_level => {
resolve_index_limit(module, top, &module.types[base].inner, false)?
}
Ti::Struct { ref members, .. } => members.len() as u32,
ref other => {
log::error!("Indexing of {:?}", other);
return Err(ExpressionError::InvalidBaseType(top));
}
};
Ok(limit)
}
let limit = resolve_index_limit(module, base, &resolver[base], true)?;
if index >= limit {
return Err(ExpressionError::IndexOutOfBounds(base, limit));
}
ShaderStages::all()
}
E::Splat { size: _, value } => match resolver[value] {
Ti::Scalar { .. } => ShaderStages::all(),
ref other => {
log::error!("Splat scalar type {:?}", other);
return Err(ExpressionError::InvalidSplatType(value));
}
},
E::Swizzle {
size,
vector,
pattern,
} => {
let vec_size = match resolver[vector] {
Ti::Vector { size: vec_size, .. } => vec_size,
ref other => {
log::error!("Swizzle vector type {:?}", other);
return Err(ExpressionError::InvalidVectorType(vector));
}
};
for &sc in pattern[..size as usize].iter() {
if sc as u8 >= vec_size as u8 {
return Err(ExpressionError::InvalidSwizzleComponent(sc, vec_size));
}
}
ShaderStages::all()
}
E::Literal(literal) => {
self.validate_literal(literal)?;
ShaderStages::all()
}
E::Constant(_) | E::Override(_) | E::ZeroValue(_) => ShaderStages::all(),
E::Compose { ref components, ty } => {
validate_compose(
ty,
module.to_ctx(),
components.iter().map(|&handle| info[handle].ty.clone()),
)?;
ShaderStages::all()
}
E::FunctionArgument(index) => {
if index >= function.arguments.len() as u32 {
return Err(ExpressionError::FunctionArgumentDoesntExist(index));
}
ShaderStages::all()
}
E::GlobalVariable(_handle) => ShaderStages::all(),
E::LocalVariable(_handle) => ShaderStages::all(),
E::Load { pointer } => {
match resolver[pointer] {
Ti::Pointer { base, .. }
if self.types[base.index()]
.flags
.contains(TypeFlags::SIZED | TypeFlags::DATA) => {}
Ti::ValuePointer { .. } => {}
ref other => {
log::error!("Loading {:?}", other);
return Err(ExpressionError::InvalidPointerType(pointer));
}
}
ShaderStages::all()
}
E::ImageSample {
image,
sampler,
gather,
coordinate,
array_index,
offset,
level,
depth_ref,
} => {
// check the validity of expressions
let image_ty = Self::global_var_ty(module, function, image)?;
let sampler_ty = Self::global_var_ty(module, function, sampler)?;
let comparison = match module.types[sampler_ty].inner {
Ti::Sampler { comparison } => comparison,
_ => return Err(ExpressionError::ExpectedSamplerType(sampler_ty)),
};
let (class, dim) = match module.types[image_ty].inner {
Ti::Image {
class,
arrayed,
dim,
} => {
// check the array property
if arrayed != array_index.is_some() {
return Err(ExpressionError::InvalidImageArrayIndex);
}
if let Some(expr) = array_index {
match resolver[expr] {
Ti::Scalar(Sc {
kind: Sk::Sint | Sk::Uint,
..
}) => {}
_ => return Err(ExpressionError::InvalidImageArrayIndexType(expr)),
}
}
(class, dim)
}
_ => return Err(ExpressionError::ExpectedImageType(image_ty)),
};
// check sampling and comparison properties
let image_depth = match class {
crate::ImageClass::Sampled {
kind: crate::ScalarKind::Float,
multi: false,
} => false,
crate::ImageClass::Sampled {
kind: crate::ScalarKind::Uint | crate::ScalarKind::Sint,
multi: false,
} if gather.is_some() => false,
crate::ImageClass::Depth { multi: false } => true,
_ => return Err(ExpressionError::InvalidImageClass(class)),
};
if comparison != depth_ref.is_some() || (comparison && !image_depth) {
return Err(ExpressionError::ComparisonSamplingMismatch {
image: class,
sampler: comparison,
has_ref: depth_ref.is_some(),
});
}
// check texture coordinates type
let num_components = match dim {
crate::ImageDimension::D1 => 1,
crate::ImageDimension::D2 => 2,
crate::ImageDimension::D3 | crate::ImageDimension::Cube => 3,
};
match resolver[coordinate] {
Ti::Scalar(Sc {
kind: Sk::Float, ..
}) if num_components == 1 => {}
Ti::Vector {
size,
scalar:
Sc {
kind: Sk::Float, ..
},
} if size as u32 == num_components => {}
_ => return Err(ExpressionError::InvalidImageCoordinateType(dim, coordinate)),
}
// check constant offset
if let Some(const_expr) = offset {
if !global_expr_kind.is_const(const_expr) {
return Err(ExpressionError::InvalidSampleOffsetExprType);
}
match *mod_info[const_expr].inner_with(&module.types) {
Ti::Scalar(Sc { kind: Sk::Sint, .. }) if num_components == 1 => {}
Ti::Vector {
size,
scalar: Sc { kind: Sk::Sint, .. },
} if size as u32 == num_components => {}
_ => {
return Err(ExpressionError::InvalidSampleOffset(dim, const_expr));
}
}
}
// check depth reference type
if let Some(expr) = depth_ref {
match resolver[expr] {
Ti::Scalar(Sc {
kind: Sk::Float, ..
}) => {}
_ => return Err(ExpressionError::InvalidDepthReference(expr)),
}
match level {
crate::SampleLevel::Auto | crate::SampleLevel::Zero => {}
_ => return Err(ExpressionError::InvalidDepthSampleLevel),
}
}
if let Some(component) = gather {
match dim {
crate::ImageDimension::D2 | crate::ImageDimension::Cube => {}
crate::ImageDimension::D1 | crate::ImageDimension::D3 => {
return Err(ExpressionError::InvalidGatherDimension(dim))
}
};
let max_component = match class {
crate::ImageClass::Depth { .. } => crate::SwizzleComponent::X,
_ => crate::SwizzleComponent::W,
};
if component > max_component {
return Err(ExpressionError::InvalidGatherComponent(component));
}
match level {
crate::SampleLevel::Zero => {}
_ => return Err(ExpressionError::InvalidGatherLevel),
}
}
// check level properties
match level {
crate::SampleLevel::Auto => ShaderStages::FRAGMENT,
crate::SampleLevel::Zero => ShaderStages::all(),
crate::SampleLevel::Exact(expr) => {
match resolver[expr] {
Ti::Scalar(Sc {
kind: Sk::Float, ..
}) => {}
_ => return Err(ExpressionError::InvalidSampleLevelExactType(expr)),
}
ShaderStages::all()
}
crate::SampleLevel::Bias(expr) => {
match resolver[expr] {
Ti::Scalar(Sc {
kind: Sk::Float, ..
}) => {}
_ => return Err(ExpressionError::InvalidSampleLevelBiasType(expr)),
}
ShaderStages::FRAGMENT
}
crate::SampleLevel::Gradient { x, y } => {
match resolver[x] {
Ti::Scalar(Sc {
kind: Sk::Float, ..
}) if num_components == 1 => {}
Ti::Vector {
size,
scalar:
Sc {
kind: Sk::Float, ..
},
} if size as u32 == num_components => {}
_ => {
return Err(ExpressionError::InvalidSampleLevelGradientType(dim, x))
}
}
match resolver[y] {
Ti::Scalar(Sc {
kind: Sk::Float, ..
}) if num_components == 1 => {}
Ti::Vector {
size,
scalar:
Sc {
kind: Sk::Float, ..
},
} if size as u32 == num_components => {}
_ => {
return Err(ExpressionError::InvalidSampleLevelGradientType(dim, y))
}
}
ShaderStages::all()
}
}
}
E::ImageLoad {
image,
coordinate,
array_index,
sample,
level,
} => {
let ty = Self::global_var_ty(module, function, image)?;
match module.types[ty].inner {
Ti::Image {
class,
arrayed,
dim,
} => {
match resolver[coordinate].image_storage_coordinates() {
Some(coord_dim) if coord_dim == dim => {}
_ => {
return Err(ExpressionError::InvalidImageCoordinateType(
dim, coordinate,
))
}
};
if arrayed != array_index.is_some() {
return Err(ExpressionError::InvalidImageArrayIndex);
}
if let Some(expr) = array_index {
match resolver[expr] {
Ti::Scalar(Sc {
kind: Sk::Sint | Sk::Uint,
width: _,
}) => {}
_ => return Err(ExpressionError::InvalidImageArrayIndexType(expr)),
}
}
match (sample, class.is_multisampled()) {
(None, false) => {}
(Some(sample), true) => {
if resolver[sample].scalar_kind() != Some(Sk::Sint) {
return Err(ExpressionError::InvalidImageOtherIndexType(
sample,
));
}
}
_ => {
return Err(ExpressionError::InvalidImageOtherIndex);
}
}
match (level, class.is_mipmapped()) {
(None, false) => {}
(Some(level), true) => {
if resolver[level].scalar_kind() != Some(Sk::Sint) {
return Err(ExpressionError::InvalidImageOtherIndexType(level));
}
}
_ => {
return Err(ExpressionError::InvalidImageOtherIndex);
}
}
}
_ => return Err(ExpressionError::ExpectedImageType(ty)),
}
ShaderStages::all()
}
E::ImageQuery { image, query } => {
let ty = Self::global_var_ty(module, function, image)?;
match module.types[ty].inner {
Ti::Image { class, arrayed, .. } => {
let good = match query {
crate::ImageQuery::NumLayers => arrayed,
crate::ImageQuery::Size { level: None } => true,
crate::ImageQuery::Size { level: Some(_) }
| crate::ImageQuery::NumLevels => class.is_mipmapped(),
crate::ImageQuery::NumSamples => class.is_multisampled(),
};
if !good {
return Err(ExpressionError::InvalidImageClass(class));
}
}
_ => return Err(ExpressionError::ExpectedImageType(ty)),
}
ShaderStages::all()
}
E::Unary { op, expr } => {
use crate::UnaryOperator as Uo;
let inner = &resolver[expr];
match (op, inner.scalar_kind()) {
(Uo::Negate, Some(Sk::Float | Sk::Sint))
| (Uo::LogicalNot, Some(Sk::Bool))
| (Uo::BitwiseNot, Some(Sk::Sint | Sk::Uint)) => {}
other => {
log::error!("Op {:?} kind {:?}", op, other);
return Err(ExpressionError::InvalidUnaryOperandType(op, expr));
}
}
ShaderStages::all()
}
E::Binary { op, left, right } => {
use crate::BinaryOperator as Bo;
let left_inner = &resolver[left];
let right_inner = &resolver[right];
let good = match op {
Bo::Add | Bo::Subtract => match *left_inner {
Ti::Scalar(scalar) | Ti::Vector { scalar, .. } => match scalar.kind {
Sk::Uint | Sk::Sint | Sk::Float => left_inner == right_inner,
Sk::Bool | Sk::AbstractInt | Sk::AbstractFloat => false,
},
Ti::Matrix { .. } => left_inner == right_inner,
_ => false,
},
Bo::Divide | Bo::Modulo => match *left_inner {
Ti::Scalar(scalar) | Ti::Vector { scalar, .. } => match scalar.kind {
Sk::Uint | Sk::Sint | Sk::Float => left_inner == right_inner,
Sk::Bool | Sk::AbstractInt | Sk::AbstractFloat => false,
},
_ => false,
},
Bo::Multiply => {
let kind_allowed = match left_inner.scalar_kind() {
Some(Sk::Uint | Sk::Sint | Sk::Float) => true,
Some(Sk::Bool | Sk::AbstractInt | Sk::AbstractFloat) | None => false,
};
let types_match = match (left_inner, right_inner) {
// Straight scalar and mixed scalar/vector.
(&Ti::Scalar(scalar1), &Ti::Scalar(scalar2))
| (
&Ti::Vector {
scalar: scalar1, ..
},
&Ti::Scalar(scalar2),
)
| (
&Ti::Scalar(scalar1),
&Ti::Vector {
scalar: scalar2, ..
},
) => scalar1 == scalar2,
// Scalar/matrix.
(
&Ti::Scalar(Sc {
kind: Sk::Float, ..
}),
&Ti::Matrix { .. },
)
| (
&Ti::Matrix { .. },
&Ti::Scalar(Sc {
kind: Sk::Float, ..
}),
) => true,
// Vector/vector.
(
&Ti::Vector {
size: size1,
scalar: scalar1,
},
&Ti::Vector {
size: size2,
scalar: scalar2,
},
) => scalar1 == scalar2 && size1 == size2,
// Matrix * vector.
(
&Ti::Matrix { columns, .. },
&Ti::Vector {
size,
scalar:
Sc {
kind: Sk::Float, ..
},
},
) => columns == size,
// Vector * matrix.
(
&Ti::Vector {
size,
scalar:
Sc {
kind: Sk::Float, ..
},
},
&Ti::Matrix { rows, .. },
) => size == rows,
(&Ti::Matrix { columns, .. }, &Ti::Matrix { rows, .. }) => {
columns == rows
}
_ => false,
};
let left_width = left_inner.scalar_width().unwrap_or(0);
let right_width = right_inner.scalar_width().unwrap_or(0);
kind_allowed && types_match && left_width == right_width
}
Bo::Equal | Bo::NotEqual => left_inner.is_sized() && left_inner == right_inner,
Bo::Less | Bo::LessEqual | Bo::Greater | Bo::GreaterEqual => {
match *left_inner {
Ti::Scalar(scalar) | Ti::Vector { scalar, .. } => match scalar.kind {
Sk::Uint | Sk::Sint | Sk::Float => left_inner == right_inner,
Sk::Bool | Sk::AbstractInt | Sk::AbstractFloat => false,
},
ref other => {
log::error!("Op {:?} left type {:?}", op, other);
false
}
}
}
Bo::LogicalAnd | Bo::LogicalOr => match *left_inner {
Ti::Scalar(Sc { kind: Sk::Bool, .. })
| Ti::Vector {
scalar: Sc { kind: Sk::Bool, .. },
..
} => left_inner == right_inner,
ref other => {
log::error!("Op {:?} left type {:?}", op, other);
false
}
},
Bo::And | Bo::InclusiveOr => match *left_inner {
Ti::Scalar(scalar) | Ti::Vector { scalar, .. } => match scalar.kind {
Sk::Bool | Sk::Sint | Sk::Uint => left_inner == right_inner,
Sk::Float | Sk::AbstractInt | Sk::AbstractFloat => false,
},
ref other => {
log::error!("Op {:?} left type {:?}", op, other);
false
}
},
Bo::ExclusiveOr => match *left_inner {
Ti::Scalar(scalar) | Ti::Vector { scalar, .. } => match scalar.kind {
Sk::Sint | Sk::Uint => left_inner == right_inner,
Sk::Bool | Sk::Float | Sk::AbstractInt | Sk::AbstractFloat => false,
},
ref other => {
log::error!("Op {:?} left type {:?}", op, other);
false
}
},
Bo::ShiftLeft | Bo::ShiftRight => {
let (base_size, base_scalar) = match *left_inner {
Ti::Scalar(scalar) => (Ok(None), scalar),
Ti::Vector { size, scalar } => (Ok(Some(size)), scalar),
ref other => {
log::error!("Op {:?} base type {:?}", op, other);
(Err(()), Sc::BOOL)
}
};
let shift_size = match *right_inner {
Ti::Scalar(Sc { kind: Sk::Uint, .. }) => Ok(None),
Ti::Vector {
size,
scalar: Sc { kind: Sk::Uint, .. },
} => Ok(Some(size)),
ref other => {
log::error!("Op {:?} shift type {:?}", op, other);
Err(())
}
};
match base_scalar.kind {
Sk::Sint | Sk::Uint => base_size.is_ok() && base_size == shift_size,
Sk::Float | Sk::AbstractInt | Sk::AbstractFloat | Sk::Bool => false,
}
}
};
if !good {
log::error!(
"Left: {:?} of type {:?}",
function.expressions[left],
left_inner
);
log::error!(
"Right: {:?} of type {:?}",
function.expressions[right],
right_inner
);
return Err(ExpressionError::InvalidBinaryOperandTypes(op, left, right));
}
ShaderStages::all()
}
E::Select {
condition,
accept,
reject,
} => {
let accept_inner = &resolver[accept];
let reject_inner = &resolver[reject];
let condition_good = match resolver[condition] {
Ti::Scalar(Sc {
kind: Sk::Bool,
width: _,
}) => {
// When `condition` is a single boolean, `accept` and
// `reject` can be vectors or scalars.
match *accept_inner {
Ti::Scalar { .. } | Ti::Vector { .. } => true,
_ => false,
}
}
Ti::Vector {
size,
scalar:
Sc {
kind: Sk::Bool,
width: _,
},
} => match *accept_inner {
Ti::Vector {
size: other_size, ..
} => size == other_size,
_ => false,
},
_ => false,
};
if !condition_good || accept_inner != reject_inner {
return Err(ExpressionError::InvalidSelectTypes);
}
ShaderStages::all()
}
E::Derivative { expr, .. } => {
match resolver[expr] {
Ti::Scalar(Sc {
kind: Sk::Float, ..
})
| Ti::Vector {
scalar:
Sc {
kind: Sk::Float, ..
},
..
} => {}
_ => return Err(ExpressionError::InvalidDerivative),
}
ShaderStages::FRAGMENT
}
E::Relational { fun, argument } => {
use crate::RelationalFunction as Rf;
let argument_inner = &resolver[argument];
match fun {
Rf::All | Rf::Any => match *argument_inner {
Ti::Vector {
scalar: Sc { kind: Sk::Bool, .. },
..
} => {}
ref other => {
log::error!("All/Any of type {:?}", other);
return Err(ExpressionError::InvalidBooleanVector(argument));
}
},
Rf::IsNan | Rf::IsInf => match *argument_inner {
Ti::Scalar(scalar) | Ti::Vector { scalar, .. }
if scalar.kind == Sk::Float => {}
ref other => {
log::error!("Float test of type {:?}", other);
return Err(ExpressionError::InvalidFloatArgument(argument));
}
},
}
ShaderStages::all()
}
E::Math {
fun,
arg,
arg1,
arg2,
arg3,
} => {
use crate::MathFunction as Mf;
let resolve = |arg| &resolver[arg];
let arg_ty = resolve(arg);
let arg1_ty = arg1.map(resolve);
let arg2_ty = arg2.map(resolve);
let arg3_ty = arg3.map(resolve);
match fun {
Mf::Abs => {
if arg1_ty.is_some() || arg2_ty.is_some() || arg3_ty.is_some() {
return Err(ExpressionError::WrongArgumentCount(fun));
}
let good = match *arg_ty {
Ti::Scalar(scalar) | Ti::Vector { scalar, .. } => {
scalar.kind != Sk::Bool
}
_ => false,
};
if !good {
return Err(ExpressionError::InvalidArgumentType(fun, 0, arg));
}
}
Mf::Min | Mf::Max => {
let arg1_ty = match (arg1_ty, arg2_ty, arg3_ty) {
(Some(ty1), None, None) => ty1,
_ => return Err(ExpressionError::WrongArgumentCount(fun)),
};
let good = match *arg_ty {
Ti::Scalar(scalar) | Ti::Vector { scalar, .. } => {
scalar.kind != Sk::Bool
}
_ => false,
};
if !good {
return Err(ExpressionError::InvalidArgumentType(fun, 0, arg));
}
if arg1_ty != arg_ty {
return Err(ExpressionError::InvalidArgumentType(
fun,
1,
arg1.unwrap(),
));
}
}
Mf::Clamp => {
let (arg1_ty, arg2_ty) = match (arg1_ty, arg2_ty, arg3_ty) {
(Some(ty1), Some(ty2), None) => (ty1, ty2),
_ => return Err(ExpressionError::WrongArgumentCount(fun)),
};
let good = match *arg_ty {
Ti::Scalar(scalar) | Ti::Vector { scalar, .. } => {
scalar.kind != Sk::Bool
}
_ => false,
};
if !good {
return Err(ExpressionError::InvalidArgumentType(fun, 0, arg));
}
if arg1_ty != arg_ty {
return Err(ExpressionError::InvalidArgumentType(
fun,
1,
arg1.unwrap(),
));
}
if arg2_ty != arg_ty {
return Err(ExpressionError::InvalidArgumentType(
fun,
2,
arg2.unwrap(),
));
}
}
Mf::Saturate
| Mf::Cos
| Mf::Cosh
| Mf::Sin
| Mf::Sinh
| Mf::Tan
| Mf::Tanh
| Mf::Acos
| Mf::Asin
| Mf::Atan
| Mf::Asinh
| Mf::Acosh
| Mf::Atanh
| Mf::Radians
| Mf::Degrees
| Mf::Ceil
| Mf::Floor
| Mf::Round
| Mf::Fract
| Mf::Trunc
| Mf::Exp
| Mf::Exp2
| Mf::Log
| Mf::Log2
| Mf::Length
| Mf::Sqrt
| Mf::InverseSqrt => {
if arg1_ty.is_some() || arg2_ty.is_some() || arg3_ty.is_some() {
return Err(ExpressionError::WrongArgumentCount(fun));
}
match *arg_ty {
Ti::Scalar(scalar) | Ti::Vector { scalar, .. }
if scalar.kind == Sk::Float => {}
_ => return Err(ExpressionError::InvalidArgumentType(fun, 0, arg)),
}
}
Mf::Sign => {
if arg1_ty.is_some() || arg2_ty.is_some() || arg3_ty.is_some() {
return Err(ExpressionError::WrongArgumentCount(fun));
}
match *arg_ty {
Ti::Scalar(Sc {
kind: Sk::Float | Sk::Sint,
..
})
| Ti::Vector {
scalar:
Sc {
kind: Sk::Float | Sk::Sint,
..
},
..
} => {}
_ => return Err(ExpressionError::InvalidArgumentType(fun, 0, arg)),
}
}
Mf::Atan2 | Mf::Pow | Mf::Distance | Mf::Step => {
let arg1_ty = match (arg1_ty, arg2_ty, arg3_ty) {
(Some(ty1), None, None) => ty1,
_ => return Err(ExpressionError::WrongArgumentCount(fun)),
};
match *arg_ty {
Ti::Scalar(scalar) | Ti::Vector { scalar, .. }
if scalar.kind == Sk::Float => {}
_ => return Err(ExpressionError::InvalidArgumentType(fun, 0, arg)),
}
if arg1_ty != arg_ty {
return Err(ExpressionError::InvalidArgumentType(
fun,
1,
arg1.unwrap(),
));
}
}
Mf::Modf | Mf::Frexp => {
if arg1_ty.is_some() || arg2_ty.is_some() || arg3_ty.is_some() {
return Err(ExpressionError::WrongArgumentCount(fun));
}
if !matches!(*arg_ty,
Ti::Scalar(scalar) | Ti::Vector { scalar, .. }
if scalar.kind == Sk::Float)
{
return Err(ExpressionError::InvalidArgumentType(fun, 1, arg));
}
}
Mf::Ldexp => {
let arg1_ty = match (arg1_ty, arg2_ty, arg3_ty) {
(Some(ty1), None, None) => ty1,
_ => return Err(ExpressionError::WrongArgumentCount(fun)),
};
let size0 = match *arg_ty {
Ti::Scalar(Sc {
kind: Sk::Float, ..
}) => None,
Ti::Vector {
scalar:
Sc {
kind: Sk::Float, ..
},
size,
} => Some(size),
_ => {
return Err(ExpressionError::InvalidArgumentType(fun, 0, arg));
}
};
let good = match *arg1_ty {
Ti::Scalar(Sc { kind: Sk::Sint, .. }) if size0.is_none() => true,
Ti::Vector {
size,
scalar: Sc { kind: Sk::Sint, .. },
} if Some(size) == size0 => true,
_ => false,
};
if !good {
return Err(ExpressionError::InvalidArgumentType(
fun,
1,
arg1.unwrap(),
));
}
}
Mf::Dot => {
let arg1_ty = match (arg1_ty, arg2_ty, arg3_ty) {
(Some(ty1), None, None) => ty1,
_ => return Err(ExpressionError::WrongArgumentCount(fun)),
};
match *arg_ty {
Ti::Vector {
scalar:
Sc {
kind: Sk::Float | Sk::Sint | Sk::Uint,
..
},
..
} => {}
_ => return Err(ExpressionError::InvalidArgumentType(fun, 0, arg)),
}
if arg1_ty != arg_ty {
return Err(ExpressionError::InvalidArgumentType(
fun,
1,
arg1.unwrap(),
));
}
}
Mf::Outer | Mf::Reflect => {
let arg1_ty = match (arg1_ty, arg2_ty, arg3_ty) {
(Some(ty1), None, None) => ty1,
_ => return Err(ExpressionError::WrongArgumentCount(fun)),
};
match *arg_ty {
Ti::Vector {
scalar:
Sc {
kind: Sk::Float, ..
},
..
} => {}
_ => return Err(ExpressionError::InvalidArgumentType(fun, 0, arg)),
}
if arg1_ty != arg_ty {
return Err(ExpressionError::InvalidArgumentType(
fun,
1,
arg1.unwrap(),
));
}
}
Mf::Cross => {
let arg1_ty = match (arg1_ty, arg2_ty, arg3_ty) {
(Some(ty1), None, None) => ty1,
_ => return Err(ExpressionError::WrongArgumentCount(fun)),
};
match *arg_ty {
Ti::Vector {
scalar:
Sc {
kind: Sk::Float, ..
},
size: crate::VectorSize::Tri,
} => {}
_ => return Err(ExpressionError::InvalidArgumentType(fun, 0, arg)),
}
if arg1_ty != arg_ty {
return Err(ExpressionError::InvalidArgumentType(
fun,
1,
arg1.unwrap(),
));
}
}
Mf::Refract => {
let (arg1_ty, arg2_ty) = match (arg1_ty, arg2_ty, arg3_ty) {
(Some(ty1), Some(ty2), None) => (ty1, ty2),
_ => return Err(ExpressionError::WrongArgumentCount(fun)),
};
match *arg_ty {
Ti::Vector {
scalar:
Sc {
kind: Sk::Float, ..
},
..
} => {}
_ => return Err(ExpressionError::InvalidArgumentType(fun, 0, arg)),
}
if arg1_ty != arg_ty {
return Err(ExpressionError::InvalidArgumentType(
fun,
1,
arg1.unwrap(),
));
}
match (arg_ty, arg2_ty) {
(
&Ti::Vector {
scalar:
Sc {
width: vector_width,
..
},
..
},
&Ti::Scalar(Sc {
width: scalar_width,
kind: Sk::Float,
}),
) if vector_width == scalar_width => {}
_ => {
return Err(ExpressionError::InvalidArgumentType(
fun,
2,
arg2.unwrap(),
))
}
}
}
Mf::Normalize => {
if arg1_ty.is_some() || arg2_ty.is_some() || arg3_ty.is_some() {
return Err(ExpressionError::WrongArgumentCount(fun));
}
match *arg_ty {
Ti::Vector {
scalar:
Sc {
kind: Sk::Float, ..
},
..
} => {}
_ => return Err(ExpressionError::InvalidArgumentType(fun, 0, arg)),
}
}
Mf::FaceForward | Mf::Fma | Mf::SmoothStep => {
let (arg1_ty, arg2_ty) = match (arg1_ty, arg2_ty, arg3_ty) {
(Some(ty1), Some(ty2), None) => (ty1, ty2),
_ => return Err(ExpressionError::WrongArgumentCount(fun)),
};
match *arg_ty {
Ti::Scalar(Sc {
kind: Sk::Float, ..
})
| Ti::Vector {
scalar:
Sc {
kind: Sk::Float, ..
},
..
} => {}
_ => return Err(ExpressionError::InvalidArgumentType(fun, 0, arg)),
}
if arg1_ty != arg_ty {
return Err(ExpressionError::InvalidArgumentType(
fun,
1,
arg1.unwrap(),
));
}
if arg2_ty != arg_ty {
return Err(ExpressionError::InvalidArgumentType(
fun,
2,
arg2.unwrap(),
));
}
}
Mf::Mix => {
let (arg1_ty, arg2_ty) = match (arg1_ty, arg2_ty, arg3_ty) {
(Some(ty1), Some(ty2), None) => (ty1, ty2),
_ => return Err(ExpressionError::WrongArgumentCount(fun)),
};
let arg_width = match *arg_ty {
Ti::Scalar(Sc {
kind: Sk::Float,
width,
})
| Ti::Vector {
scalar:
Sc {
kind: Sk::Float,
width,
},
..
} => width,
_ => return Err(ExpressionError::InvalidArgumentType(fun, 0, arg)),
};
if arg1_ty != arg_ty {
return Err(ExpressionError::InvalidArgumentType(
fun,
1,
arg1.unwrap(),
));
}
// the last argument can always be a scalar
match *arg2_ty {
Ti::Scalar(Sc {
kind: Sk::Float,
width,
}) if width == arg_width => {}
_ if arg2_ty == arg_ty => {}
_ => {
return Err(ExpressionError::InvalidArgumentType(
fun,
2,
arg2.unwrap(),
));
}
}
}
Mf::Inverse | Mf::Determinant => {
if arg1_ty.is_some() || arg2_ty.is_some() || arg3_ty.is_some() {
return Err(ExpressionError::WrongArgumentCount(fun));
}
let good = match *arg_ty {
Ti::Matrix { columns, rows, .. } => columns == rows,
_ => false,
};
if !good {
return Err(ExpressionError::InvalidArgumentType(fun, 0, arg));
}
}
Mf::Transpose => {
if arg1_ty.is_some() || arg2_ty.is_some() || arg3_ty.is_some() {
return Err(ExpressionError::WrongArgumentCount(fun));
}
match *arg_ty {
Ti::Matrix { .. } => {}
_ => return Err(ExpressionError::InvalidArgumentType(fun, 0, arg)),
}
}
Mf::CountLeadingZeros
| Mf::CountTrailingZeros
| Mf::CountOneBits
| Mf::ReverseBits
| Mf::FirstLeadingBit
| Mf::FirstTrailingBit => {
if arg1_ty.is_some() || arg2_ty.is_some() || arg3_ty.is_some() {
return Err(ExpressionError::WrongArgumentCount(fun));
}
match *arg_ty {
Ti::Scalar(scalar) | Ti::Vector { scalar, .. } => match scalar.kind {
Sk::Sint | Sk::Uint => {
if scalar.width != 4 {
return Err(ExpressionError::UnsupportedWidth(
fun,
scalar.kind,
scalar.width,
));
}
}
_ => return Err(ExpressionError::InvalidArgumentType(fun, 0, arg)),
},
_ => return Err(ExpressionError::InvalidArgumentType(fun, 0, arg)),
}
}
Mf::InsertBits => {
let (arg1_ty, arg2_ty, arg3_ty) = match (arg1_ty, arg2_ty, arg3_ty) {
(Some(ty1), Some(ty2), Some(ty3)) => (ty1, ty2, ty3),
_ => return Err(ExpressionError::WrongArgumentCount(fun)),
};
match *arg_ty {
Ti::Scalar(Sc {
kind: Sk::Sint | Sk::Uint,
..
})
| Ti::Vector {
scalar:
Sc {
kind: Sk::Sint | Sk::Uint,
..
},
..
} => {}
_ => return Err(ExpressionError::InvalidArgumentType(fun, 0, arg)),
}
if arg1_ty != arg_ty {
return Err(ExpressionError::InvalidArgumentType(
fun,
1,
arg1.unwrap(),
));
}
match *arg2_ty {
Ti::Scalar(Sc { kind: Sk::Uint, .. }) => {}
_ => {
return Err(ExpressionError::InvalidArgumentType(
fun,
2,
arg2.unwrap(),
))
}
}
match *arg3_ty {
Ti::Scalar(Sc { kind: Sk::Uint, .. }) => {}
_ => {
return Err(ExpressionError::InvalidArgumentType(
fun,
2,
arg3.unwrap(),
))
}
}
for &arg in [arg_ty, arg1_ty, arg2_ty, arg3_ty].iter() {
match *arg {
Ti::Scalar(scalar) | Ti::Vector { scalar, .. } => {
if scalar.width != 4 {
return Err(ExpressionError::UnsupportedWidth(
fun,
scalar.kind,
scalar.width,
));
}
}
_ => {}
}
}
}
Mf::ExtractBits => {
let (arg1_ty, arg2_ty) = match (arg1_ty, arg2_ty, arg3_ty) {
(Some(ty1), Some(ty2), None) => (ty1, ty2),
_ => return Err(ExpressionError::WrongArgumentCount(fun)),
};
match *arg_ty {
Ti::Scalar(Sc {
kind: Sk::Sint | Sk::Uint,
..
})
| Ti::Vector {
scalar:
Sc {
kind: Sk::Sint | Sk::Uint,
..
},
..
} => {}
_ => return Err(ExpressionError::InvalidArgumentType(fun, 0, arg)),
}
match *arg1_ty {
Ti::Scalar(Sc { kind: Sk::Uint, .. }) => {}
_ => {
return Err(ExpressionError::InvalidArgumentType(
fun,
2,
arg1.unwrap(),
))
}
}
match *arg2_ty {
Ti::Scalar(Sc { kind: Sk::Uint, .. }) => {}
_ => {
return Err(ExpressionError::InvalidArgumentType(
fun,
2,
arg2.unwrap(),
))
}
}
for &arg in [arg_ty, arg1_ty, arg2_ty].iter() {
match *arg {
Ti::Scalar(scalar) | Ti::Vector { scalar, .. } => {
if scalar.width != 4 {
return Err(ExpressionError::UnsupportedWidth(
fun,
scalar.kind,
scalar.width,
));
}
}
_ => {}
}
}
}
Mf::Pack2x16unorm | Mf::Pack2x16snorm | Mf::Pack2x16float => {
if arg1_ty.is_some() || arg2_ty.is_some() || arg3_ty.is_some() {
return Err(ExpressionError::WrongArgumentCount(fun));
}
match *arg_ty {
Ti::Vector {
size: crate::VectorSize::Bi,
scalar:
Sc {
kind: Sk::Float, ..
},
} => {}
_ => return Err(ExpressionError::InvalidArgumentType(fun, 0, arg)),
}
}
Mf::Pack4x8snorm | Mf::Pack4x8unorm => {
if arg1_ty.is_some() || arg2_ty.is_some() || arg3_ty.is_some() {
return Err(ExpressionError::WrongArgumentCount(fun));
}
match *arg_ty {
Ti::Vector {
size: crate::VectorSize::Quad,
scalar:
Sc {
kind: Sk::Float, ..
},
} => {}
_ => return Err(ExpressionError::InvalidArgumentType(fun, 0, arg)),
}
}
mf @ (Mf::Pack4xI8 | Mf::Pack4xU8) => {
let scalar_kind = match mf {
Mf::Pack4xI8 => Sk::Sint,
Mf::Pack4xU8 => Sk::Uint,
_ => unreachable!(),
};
if arg1_ty.is_some() || arg2_ty.is_some() || arg3_ty.is_some() {
return Err(ExpressionError::WrongArgumentCount(fun));
}
match *arg_ty {
Ti::Vector {
size: crate::VectorSize::Quad,
scalar: Sc { kind, .. },
} if kind == scalar_kind => {}
_ => return Err(ExpressionError::InvalidArgumentType(fun, 0, arg)),
}
}
Mf::Unpack2x16float
| Mf::Unpack2x16snorm
| Mf::Unpack2x16unorm
| Mf::Unpack4x8snorm
| Mf::Unpack4x8unorm
| Mf::Unpack4xI8
| Mf::Unpack4xU8 => {
if arg1_ty.is_some() || arg2_ty.is_some() || arg3_ty.is_some() {
return Err(ExpressionError::WrongArgumentCount(fun));
}
match *arg_ty {
Ti::Scalar(Sc { kind: Sk::Uint, .. }) => {}
_ => return Err(ExpressionError::InvalidArgumentType(fun, 0, arg)),
}
}
}
ShaderStages::all()
}
E::As {
expr,
kind,
convert,
} => {
let mut base_scalar = match resolver[expr] {
crate::TypeInner::Scalar(scalar) | crate::TypeInner::Vector { scalar, .. } => {
scalar
}
crate::TypeInner::Matrix { scalar, .. } => scalar,
_ => return Err(ExpressionError::InvalidCastArgument),
};
base_scalar.kind = kind;
if let Some(width) = convert {
base_scalar.width = width;
}
if self.check_width(base_scalar).is_err() {
return Err(ExpressionError::InvalidCastArgument);
}
ShaderStages::all()
}
E::CallResult(function) => mod_info.functions[function.index()].available_stages,
E::AtomicResult { .. } => {
// These expressions are validated when we check the `Atomic` statement
// that refers to them, because we have all the information we need at
// that point. The checks driven by `Validator::needs_visit` ensure
// that this expression is indeed visited by one `Atomic` statement.
ShaderStages::all()
}
E::WorkGroupUniformLoadResult { ty } => {
if self.types[ty.index()]
.flags
// Sized | Constructible is exactly the types currently supported by
// WorkGroupUniformLoad
.contains(TypeFlags::SIZED | TypeFlags::CONSTRUCTIBLE)
{
ShaderStages::COMPUTE
} else {
return Err(ExpressionError::InvalidWorkGroupUniformLoadResultType(ty));
}
}
E::ArrayLength(expr) => match resolver[expr] {
Ti::Pointer { base, .. } => {
let base_ty = &resolver.types[base];
if let Ti::Array {
size: crate::ArraySize::Dynamic,
..
} = base_ty.inner
{
ShaderStages::all()
} else {
return Err(ExpressionError::InvalidArrayType(expr));
}
}
ref other => {
log::error!("Array length of {:?}", other);
return Err(ExpressionError::InvalidArrayType(expr));
}
},
E::RayQueryProceedResult => ShaderStages::all(),
E::RayQueryGetIntersection {
query,
committed: _,
} => match resolver[query] {
Ti::Pointer {
base,
space: crate::AddressSpace::Function,
} => match resolver.types[base].inner {
Ti::RayQuery => ShaderStages::all(),
ref other => {
log::error!("Intersection result of a pointer to {:?}", other);
return Err(ExpressionError::InvalidRayQueryType(query));
}
},
ref other => {
log::error!("Intersection result of {:?}", other);
return Err(ExpressionError::InvalidRayQueryType(query));
}
},
E::SubgroupBallotResult | E::SubgroupOperationResult { .. } => self.subgroup_stages,
};
Ok(stages)
}
fn global_var_ty(
module: &crate::Module,
function: &crate::Function,
expr: Handle<crate::Expression>,
) -> Result<Handle<crate::Type>, ExpressionError> {
use crate::Expression as Ex;
match function.expressions[expr] {
Ex::GlobalVariable(var_handle) => Ok(module.global_variables[var_handle].ty),
Ex::FunctionArgument(i) => Ok(function.arguments[i as usize].ty),
Ex::Access { base, .. } | Ex::AccessIndex { base, .. } => {
match function.expressions[base] {
Ex::GlobalVariable(var_handle) => {
let array_ty = module.global_variables[var_handle].ty;
match module.types[array_ty].inner {
crate::TypeInner::BindingArray { base, .. } => Ok(base),
_ => Err(ExpressionError::ExpectedBindingArrayType(array_ty)),
}
}
_ => Err(ExpressionError::ExpectedGlobalVariable),
}
}
_ => Err(ExpressionError::ExpectedGlobalVariable),
}
}
pub fn validate_literal(&self, literal: crate::Literal) -> Result<(), LiteralError> {
self.check_width(literal.scalar())?;
check_literal_value(literal)?;
Ok(())
}
}
pub fn check_literal_value(literal: crate::Literal) -> Result<(), LiteralError> {
let is_nan = match literal {
crate::Literal::F64(v) => v.is_nan(),
crate::Literal::F32(v) => v.is_nan(),
_ => false,
};
if is_nan {
return Err(LiteralError::NaN);
}
let is_infinite = match literal {
crate::Literal::F64(v) => v.is_infinite(),
crate::Literal::F32(v) => v.is_infinite(),
_ => false,
};
if is_infinite {
return Err(LiteralError::Infinity);
}
Ok(())
}
#[cfg(test)]
/// Validate a module containing the given expression, expecting an error.
fn validate_with_expression(
expr: crate::Expression,
caps: super::Capabilities,
) -> Result<ModuleInfo, crate::span::WithSpan<super::ValidationError>> {
use crate::span::Span;
let mut function = crate::Function::default();
function.expressions.append(expr, Span::default());
function.body.push(
crate::Statement::Emit(function.expressions.range_from(0)),
Span::default(),
);
let mut module = crate::Module::default();
module.functions.append(function, Span::default());
let mut validator = super::Validator::new(super::ValidationFlags::EXPRESSIONS, caps);
validator.validate(&module)
}
#[cfg(test)]
/// Validate a module containing the given constant expression, expecting an error.
fn validate_with_const_expression(
expr: crate::Expression,
caps: super::Capabilities,
) -> Result<ModuleInfo, crate::span::WithSpan<super::ValidationError>> {
use crate::span::Span;
let mut module = crate::Module::default();
module.global_expressions.append(expr, Span::default());
let mut validator = super::Validator::new(super::ValidationFlags::CONSTANTS, caps);
validator.validate(&module)
}
/// Using F64 in a function's expression arena is forbidden.
#[test]
fn f64_runtime_literals() {
let result = validate_with_expression(
crate::Expression::Literal(crate::Literal::F64(0.57721_56649)),
super::Capabilities::default(),
);
let error = result.unwrap_err().into_inner();
assert!(matches!(
error,
crate::valid::ValidationError::Function {
source: super::FunctionError::Expression {
source: ExpressionError::Literal(LiteralError::Width(
super::r#type::WidthError::MissingCapability {
name: "f64",
flag: "FLOAT64",
}
),),
..
},
..
}
));
let result = validate_with_expression(
crate::Expression::Literal(crate::Literal::F64(0.57721_56649)),
super::Capabilities::default() | super::Capabilities::FLOAT64,
);
assert!(result.is_ok());
}
/// Using F64 in a module's constant expression arena is forbidden.
#[test]
fn f64_const_literals() {
let result = validate_with_const_expression(
crate::Expression::Literal(crate::Literal::F64(0.57721_56649)),
super::Capabilities::default(),
);
let error = result.unwrap_err().into_inner();
assert!(matches!(
error,
crate::valid::ValidationError::ConstExpression {
source: ConstExpressionError::Literal(LiteralError::Width(
super::r#type::WidthError::MissingCapability {
name: "f64",
flag: "FLOAT64",
}
)),
..
}
));
let result = validate_with_const_expression(
crate::Expression::Literal(crate::Literal::F64(0.57721_56649)),
super::Capabilities::default() | super::Capabilities::FLOAT64,
);
assert!(result.is_ok());
}