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use super::Capabilities;
use crate::{arena::Handle, proc::Alignment};
bitflags::bitflags! {
/// Flags associated with [`Type`]s by [`Validator`].
///
/// [`Type`]: crate::Type
/// [`Validator`]: crate::valid::Validator
#[cfg_attr(feature = "serialize", derive(serde::Serialize))]
#[cfg_attr(feature = "deserialize", derive(serde::Deserialize))]
#[repr(transparent)]
#[derive(Clone, Copy, Debug, Eq, PartialEq)]
pub struct TypeFlags: u8 {
/// Can be used for data variables.
///
/// This flag is required on types of local variables, function
/// arguments, array elements, and struct members.
///
/// This includes all types except `Image`, `Sampler`,
/// and some `Pointer` types.
const DATA = 0x1;
/// The data type has a size known by pipeline creation time.
///
/// Unsized types are quite restricted. The only unsized types permitted
/// by Naga, other than the non-[`DATA`] types like [`Image`] and
/// [`Sampler`], are dynamically-sized [`Array`s], and [`Struct`s] whose
/// last members are such arrays. See the documentation for those types
/// for details.
///
/// [`DATA`]: TypeFlags::DATA
/// [`Image`]: crate::Type::Image
/// [`Sampler`]: crate::Type::Sampler
/// [`Array`]: crate::Type::Array
/// [`Struct`]: crate::Type::struct
const SIZED = 0x2;
/// The data can be copied around.
const COPY = 0x4;
/// Can be be used for user-defined IO between pipeline stages.
///
/// This covers anything that can be in [`Location`] binding:
/// non-bool scalars and vectors, matrices, and structs and
/// arrays containing only interface types.
const IO_SHAREABLE = 0x8;
/// Can be used for host-shareable structures.
const HOST_SHAREABLE = 0x10;
/// This type can be passed as a function argument.
const ARGUMENT = 0x40;
/// A WGSL [constructible] type.
///
/// The constructible types are scalars, vectors, matrices, fixed-size
/// arrays of constructible types, and structs whose members are all
/// constructible.
///
/// [constructible]: https://gpuweb.github.io/gpuweb/wgsl/#constructible
const CONSTRUCTIBLE = 0x80;
}
}
#[derive(Clone, Copy, Debug, thiserror::Error)]
pub enum Disalignment {
#[error("The array stride {stride} is not a multiple of the required alignment {alignment}")]
ArrayStride { stride: u32, alignment: Alignment },
#[error("The struct span {span}, is not a multiple of the required alignment {alignment}")]
StructSpan { span: u32, alignment: Alignment },
#[error("The struct member[{index}] offset {offset} is not a multiple of the required alignment {alignment}")]
MemberOffset {
index: u32,
offset: u32,
alignment: Alignment,
},
#[error("The struct member[{index}] offset {offset} must be at least {expected}")]
MemberOffsetAfterStruct {
index: u32,
offset: u32,
expected: u32,
},
#[error("The struct member[{index}] is not statically sized")]
UnsizedMember { index: u32 },
#[error("The type is not host-shareable")]
NonHostShareable,
}
#[derive(Clone, Debug, thiserror::Error)]
pub enum TypeError {
#[error("Capability {0:?} is required")]
MissingCapability(Capabilities),
#[error("The {0:?} scalar width {1} is not supported for an atomic")]
InvalidAtomicWidth(crate::ScalarKind, crate::Bytes),
#[error("Invalid type for pointer target {0:?}")]
InvalidPointerBase(Handle<crate::Type>),
#[error("Unsized types like {base:?} must be in the `Storage` address space, not `{space:?}`")]
InvalidPointerToUnsized {
base: Handle<crate::Type>,
space: crate::AddressSpace,
},
#[error("Expected data type, found {0:?}")]
InvalidData(Handle<crate::Type>),
#[error("Base type {0:?} for the array is invalid")]
InvalidArrayBaseType(Handle<crate::Type>),
#[error("Matrix elements must always be floating-point types")]
MatrixElementNotFloat,
#[error("The constant {0:?} is specialized, and cannot be used as an array size")]
UnsupportedSpecializedArrayLength(Handle<crate::Constant>),
#[error("Array stride {stride} does not match the expected {expected}")]
InvalidArrayStride { stride: u32, expected: u32 },
#[error("Field '{0}' can't be dynamically-sized, has type {1:?}")]
InvalidDynamicArray(String, Handle<crate::Type>),
#[error("The base handle {0:?} has to be a struct")]
BindingArrayBaseTypeNotStruct(Handle<crate::Type>),
#[error("Structure member[{index}] at {offset} overlaps the previous member")]
MemberOverlap { index: u32, offset: u32 },
#[error(
"Structure member[{index}] at {offset} and size {size} crosses the structure boundary of size {span}"
)]
MemberOutOfBounds {
index: u32,
offset: u32,
size: u32,
span: u32,
},
#[error("Structure types must have at least one member")]
EmptyStruct,
#[error(transparent)]
WidthError(#[from] WidthError),
}
#[derive(Clone, Debug, thiserror::Error)]
#[cfg_attr(test, derive(PartialEq))]
pub enum WidthError {
#[error("The {0:?} scalar width {1} is not supported")]
Invalid(crate::ScalarKind, crate::Bytes),
#[error("Using `{name}` values requires the `naga::valid::Capabilities::{flag}` flag")]
MissingCapability {
name: &'static str,
flag: &'static str,
},
#[error("64-bit integers are not yet supported")]
Unsupported64Bit,
#[error("Abstract types may only appear in constant expressions")]
Abstract,
}
// Only makes sense if `flags.contains(HOST_SHAREABLE)`
type LayoutCompatibility = Result<Alignment, (Handle<crate::Type>, Disalignment)>;
fn check_member_layout(
accum: &mut LayoutCompatibility,
member: &crate::StructMember,
member_index: u32,
member_layout: LayoutCompatibility,
parent_handle: Handle<crate::Type>,
) {
*accum = match (*accum, member_layout) {
(Ok(cur_alignment), Ok(alignment)) => {
if alignment.is_aligned(member.offset) {
Ok(cur_alignment.max(alignment))
} else {
Err((
parent_handle,
Disalignment::MemberOffset {
index: member_index,
offset: member.offset,
alignment,
},
))
}
}
(Err(e), _) | (_, Err(e)) => Err(e),
};
}
/// Determine whether a pointer in `space` can be passed as an argument.
///
/// If a pointer in `space` is permitted to be passed as an argument to a
/// user-defined function, return `TypeFlags::ARGUMENT`. Otherwise, return
/// `TypeFlags::empty()`.
///
/// Pointers passed as arguments to user-defined functions must be in the
/// `Function` or `Private` address space.
const fn ptr_space_argument_flag(space: crate::AddressSpace) -> TypeFlags {
use crate::AddressSpace as As;
match space {
As::Function | As::Private => TypeFlags::ARGUMENT,
As::Uniform | As::Storage { .. } | As::Handle | As::PushConstant | As::WorkGroup => {
TypeFlags::empty()
}
}
}
#[derive(Clone, Debug)]
pub(super) struct TypeInfo {
pub flags: TypeFlags,
pub uniform_layout: LayoutCompatibility,
pub storage_layout: LayoutCompatibility,
}
impl TypeInfo {
const fn dummy() -> Self {
TypeInfo {
flags: TypeFlags::empty(),
uniform_layout: Ok(Alignment::ONE),
storage_layout: Ok(Alignment::ONE),
}
}
const fn new(flags: TypeFlags, alignment: Alignment) -> Self {
TypeInfo {
flags,
uniform_layout: Ok(alignment),
storage_layout: Ok(alignment),
}
}
}
impl super::Validator {
const fn require_type_capability(&self, capability: Capabilities) -> Result<(), TypeError> {
if self.capabilities.contains(capability) {
Ok(())
} else {
Err(TypeError::MissingCapability(capability))
}
}
pub(super) const fn check_width(&self, scalar: crate::Scalar) -> Result<(), WidthError> {
let good = match scalar.kind {
crate::ScalarKind::Bool => scalar.width == crate::BOOL_WIDTH,
crate::ScalarKind::Float => {
if scalar.width == 8 {
if !self.capabilities.contains(Capabilities::FLOAT64) {
return Err(WidthError::MissingCapability {
name: "f64",
flag: "FLOAT64",
});
}
true
} else {
scalar.width == 4
}
}
crate::ScalarKind::Sint | crate::ScalarKind::Uint => {
if scalar.width == 8 {
return Err(WidthError::Unsupported64Bit);
}
scalar.width == 4
}
crate::ScalarKind::AbstractInt | crate::ScalarKind::AbstractFloat => {
return Err(WidthError::Abstract);
}
};
if good {
Ok(())
} else {
Err(WidthError::Invalid(scalar.kind, scalar.width))
}
}
pub(super) fn reset_types(&mut self, size: usize) {
self.types.clear();
self.types.resize(size, TypeInfo::dummy());
self.layouter.clear();
}
pub(super) fn validate_type(
&self,
handle: Handle<crate::Type>,
gctx: crate::proc::GlobalCtx,
) -> Result<TypeInfo, TypeError> {
use crate::TypeInner as Ti;
Ok(match gctx.types[handle].inner {
Ti::Scalar(scalar) => {
self.check_width(scalar)?;
let shareable = if scalar.kind.is_numeric() {
TypeFlags::IO_SHAREABLE | TypeFlags::HOST_SHAREABLE
} else {
TypeFlags::empty()
};
TypeInfo::new(
TypeFlags::DATA
| TypeFlags::SIZED
| TypeFlags::COPY
| TypeFlags::ARGUMENT
| TypeFlags::CONSTRUCTIBLE
| shareable,
Alignment::from_width(scalar.width),
)
}
Ti::Vector { size, scalar } => {
self.check_width(scalar)?;
let shareable = if scalar.kind.is_numeric() {
TypeFlags::IO_SHAREABLE | TypeFlags::HOST_SHAREABLE
} else {
TypeFlags::empty()
};
TypeInfo::new(
TypeFlags::DATA
| TypeFlags::SIZED
| TypeFlags::COPY
| TypeFlags::HOST_SHAREABLE
| TypeFlags::ARGUMENT
| TypeFlags::CONSTRUCTIBLE
| shareable,
Alignment::from(size) * Alignment::from_width(scalar.width),
)
}
Ti::Matrix {
columns: _,
rows,
scalar,
} => {
if scalar.kind != crate::ScalarKind::Float {
return Err(TypeError::MatrixElementNotFloat);
}
self.check_width(scalar)?;
TypeInfo::new(
TypeFlags::DATA
| TypeFlags::SIZED
| TypeFlags::COPY
| TypeFlags::HOST_SHAREABLE
| TypeFlags::ARGUMENT
| TypeFlags::CONSTRUCTIBLE,
Alignment::from(rows) * Alignment::from_width(scalar.width),
)
}
Ti::Atomic(crate::Scalar { kind, width }) => {
let good = match kind {
crate::ScalarKind::Bool
| crate::ScalarKind::Float
| crate::ScalarKind::AbstractInt
| crate::ScalarKind::AbstractFloat => false,
crate::ScalarKind::Sint | crate::ScalarKind::Uint => width == 4,
};
if !good {
return Err(TypeError::InvalidAtomicWidth(kind, width));
}
TypeInfo::new(
TypeFlags::DATA | TypeFlags::SIZED | TypeFlags::HOST_SHAREABLE,
Alignment::from_width(width),
)
}
Ti::Pointer { base, space } => {
use crate::AddressSpace as As;
let base_info = &self.types[base.index()];
if !base_info.flags.contains(TypeFlags::DATA) {
return Err(TypeError::InvalidPointerBase(base));
}
// Runtime-sized values can only live in the `Storage` address
// space, so it's useless to have a pointer to such a type in
// any other space.
//
// Detecting this problem here prevents the definition of
// functions like:
//
// fn f(p: ptr<workgroup, UnsizedType>) -> ... { ... }
//
// which would otherwise be permitted, but uncallable. (They
// may also present difficulties in code generation).
if !base_info.flags.contains(TypeFlags::SIZED) {
match space {
As::Storage { .. } => {}
_ => {
return Err(TypeError::InvalidPointerToUnsized { base, space });
}
}
}
// `Validator::validate_function` actually checks the address
// space of pointer arguments explicitly before checking the
// `ARGUMENT` flag, to give better error messages. But it seems
// best to set `ARGUMENT` accurately anyway.
let argument_flag = ptr_space_argument_flag(space);
// Pointers cannot be stored in variables, structure members, or
// array elements, so we do not mark them as `DATA`.
TypeInfo::new(
argument_flag | TypeFlags::SIZED | TypeFlags::COPY,
Alignment::ONE,
)
}
Ti::ValuePointer {
size: _,
scalar,
space,
} => {
// ValuePointer should be treated the same way as the equivalent
// Pointer / Scalar / Vector combination, so each step in those
// variants' match arms should have a counterpart here.
//
// However, some cases are trivial: All our implicit base types
// are DATA and SIZED, so we can never return
// `InvalidPointerBase` or `InvalidPointerToUnsized`.
self.check_width(scalar)?;
// `Validator::validate_function` actually checks the address
// space of pointer arguments explicitly before checking the
// `ARGUMENT` flag, to give better error messages. But it seems
// best to set `ARGUMENT` accurately anyway.
let argument_flag = ptr_space_argument_flag(space);
// Pointers cannot be stored in variables, structure members, or
// array elements, so we do not mark them as `DATA`.
TypeInfo::new(
argument_flag | TypeFlags::SIZED | TypeFlags::COPY,
Alignment::ONE,
)
}
Ti::Array { base, size, stride } => {
let base_info = &self.types[base.index()];
if !base_info.flags.contains(TypeFlags::DATA | TypeFlags::SIZED) {
return Err(TypeError::InvalidArrayBaseType(base));
}
let base_layout = self.layouter[base];
let general_alignment = base_layout.alignment;
let uniform_layout = match base_info.uniform_layout {
Ok(base_alignment) => {
let alignment = base_alignment
.max(general_alignment)
.max(Alignment::MIN_UNIFORM);
if alignment.is_aligned(stride) {
Ok(alignment)
} else {
Err((handle, Disalignment::ArrayStride { stride, alignment }))
}
}
Err(e) => Err(e),
};
let storage_layout = match base_info.storage_layout {
Ok(base_alignment) => {
let alignment = base_alignment.max(general_alignment);
if alignment.is_aligned(stride) {
Ok(alignment)
} else {
Err((handle, Disalignment::ArrayStride { stride, alignment }))
}
}
Err(e) => Err(e),
};
let type_info_mask = match size {
crate::ArraySize::Constant(_) => {
TypeFlags::DATA
| TypeFlags::SIZED
| TypeFlags::COPY
| TypeFlags::HOST_SHAREABLE
| TypeFlags::ARGUMENT
| TypeFlags::CONSTRUCTIBLE
}
crate::ArraySize::Dynamic => {
// Non-SIZED types may only appear as the last element of a structure.
// This is enforced by checks for SIZED-ness for all compound types,
// and a special case for structs.
TypeFlags::DATA | TypeFlags::COPY | TypeFlags::HOST_SHAREABLE
}
};
TypeInfo {
flags: base_info.flags & type_info_mask,
uniform_layout,
storage_layout,
}
}
Ti::Struct { ref members, span } => {
if members.is_empty() {
return Err(TypeError::EmptyStruct);
}
let mut ti = TypeInfo::new(
TypeFlags::DATA
| TypeFlags::SIZED
| TypeFlags::COPY
| TypeFlags::HOST_SHAREABLE
| TypeFlags::IO_SHAREABLE
| TypeFlags::ARGUMENT
| TypeFlags::CONSTRUCTIBLE,
Alignment::ONE,
);
ti.uniform_layout = Ok(Alignment::MIN_UNIFORM);
let mut min_offset = 0;
let mut prev_struct_data: Option<(u32, u32)> = None;
for (i, member) in members.iter().enumerate() {
let base_info = &self.types[member.ty.index()];
if !base_info.flags.contains(TypeFlags::DATA) {
return Err(TypeError::InvalidData(member.ty));
}
if !base_info.flags.contains(TypeFlags::HOST_SHAREABLE) {
if ti.uniform_layout.is_ok() {
ti.uniform_layout = Err((member.ty, Disalignment::NonHostShareable));
}
if ti.storage_layout.is_ok() {
ti.storage_layout = Err((member.ty, Disalignment::NonHostShareable));
}
}
ti.flags &= base_info.flags;
if member.offset < min_offset {
// HACK: this could be nicer. We want to allow some structures
// to not bother with offsets/alignments if they are never
// used for host sharing.
if member.offset == 0 {
ti.flags.set(TypeFlags::HOST_SHAREABLE, false);
} else {
return Err(TypeError::MemberOverlap {
index: i as u32,
offset: member.offset,
});
}
}
let base_size = gctx.types[member.ty].inner.size(gctx);
min_offset = member.offset + base_size;
if min_offset > span {
return Err(TypeError::MemberOutOfBounds {
index: i as u32,
offset: member.offset,
size: base_size,
span,
});
}
check_member_layout(
&mut ti.uniform_layout,
member,
i as u32,
base_info.uniform_layout,
handle,
);
check_member_layout(
&mut ti.storage_layout,
member,
i as u32,
base_info.storage_layout,
handle,
);
// Validate rule: If a structure member itself has a structure type S,
// then the number of bytes between the start of that member and
// the start of any following member must be at least roundUp(16, SizeOf(S)).
if let Some((span, offset)) = prev_struct_data {
let diff = member.offset - offset;
let min = Alignment::MIN_UNIFORM.round_up(span);
if diff < min {
ti.uniform_layout = Err((
handle,
Disalignment::MemberOffsetAfterStruct {
index: i as u32,
offset: member.offset,
expected: offset + min,
},
));
}
};
prev_struct_data = match gctx.types[member.ty].inner {
crate::TypeInner::Struct { span, .. } => Some((span, member.offset)),
_ => None,
};
// The last field may be an unsized array.
if !base_info.flags.contains(TypeFlags::SIZED) {
let is_array = match gctx.types[member.ty].inner {
crate::TypeInner::Array { .. } => true,
_ => false,
};
if !is_array || i + 1 != members.len() {
let name = member.name.clone().unwrap_or_default();
return Err(TypeError::InvalidDynamicArray(name, member.ty));
}
if ti.uniform_layout.is_ok() {
ti.uniform_layout =
Err((handle, Disalignment::UnsizedMember { index: i as u32 }));
}
}
}
let alignment = self.layouter[handle].alignment;
if !alignment.is_aligned(span) {
ti.uniform_layout = Err((handle, Disalignment::StructSpan { span, alignment }));
ti.storage_layout = Err((handle, Disalignment::StructSpan { span, alignment }));
}
ti
}
Ti::Image {
dim,
arrayed,
class: _,
} => {
if arrayed && matches!(dim, crate::ImageDimension::Cube) {
self.require_type_capability(Capabilities::CUBE_ARRAY_TEXTURES)?;
}
TypeInfo::new(TypeFlags::ARGUMENT, Alignment::ONE)
}
Ti::Sampler { .. } => TypeInfo::new(TypeFlags::ARGUMENT, Alignment::ONE),
Ti::AccelerationStructure => {
self.require_type_capability(Capabilities::RAY_QUERY)?;
TypeInfo::new(TypeFlags::ARGUMENT, Alignment::ONE)
}
Ti::RayQuery => {
self.require_type_capability(Capabilities::RAY_QUERY)?;
TypeInfo::new(
TypeFlags::DATA | TypeFlags::CONSTRUCTIBLE | TypeFlags::SIZED,
Alignment::ONE,
)
}
Ti::BindingArray { base, size } => {
if base >= handle {
return Err(TypeError::InvalidArrayBaseType(base));
}
let type_info_mask = match size {
crate::ArraySize::Constant(_) => TypeFlags::SIZED | TypeFlags::HOST_SHAREABLE,
crate::ArraySize::Dynamic => {
// Final type is non-sized
TypeFlags::HOST_SHAREABLE
}
};
let base_info = &self.types[base.index()];
if base_info.flags.contains(TypeFlags::DATA) {
// Currently Naga only supports binding arrays of structs for non-handle types.
match gctx.types[base].inner {
crate::TypeInner::Struct { .. } => {}
_ => return Err(TypeError::BindingArrayBaseTypeNotStruct(base)),
};
}
TypeInfo::new(base_info.flags & type_info_mask, Alignment::ONE)
}
})
}
}