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Quelle handles.rs
Sprache: unbekannt
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//! Implementation of `Validator::validate_module_handles`.
use crate::{
arena::{BadHandle, BadRangeError},
diagnostic_filter::DiagnosticFilterNode,
Handle,
};
use crate::non_max_u32::NonMaxU32;
use crate::{Arena, UniqueArena};
use super::ValidationError;
use std::{convert::TryInto, hash::Hash};
impl super::Validator {
/// Validates that all handles within `module` are:
///
/// * Valid, in the sense that they contain indices within each arena structure inside the
/// [`crate::Module`] type.
/// * No arena contents contain any items that have forward dependencies; that is, the value
/// associated with a handle only may contain references to handles in the same arena that
/// were constructed before it.
///
/// By validating the above conditions, we free up subsequent logic to assume that handle
/// accesses are infallible.
///
/// # Errors
///
/// Errors returned by this method are intentionally sparse, for simplicity of implementation.
/// It is expected that only buggy frontends or fuzzers should ever emit IR that fails this
/// validation pass.
pub(super) fn validate_module_handles(module: &crate::Module) -> Result<(), ValidationError> {
let &crate::Module {
ref constants,
ref overrides,
ref entry_points,
ref functions,
ref global_variables,
ref types,
ref special_types,
ref global_expressions,
ref diagnostic_filters,
ref diagnostic_filter_leaf,
} = module;
// Because types can refer to global expressions and vice versa, to
// ensure the overall structure is free of cycles, we must traverse them
// both in tandem.
//
// Try to visit all types and global expressions in an order such that
// each item refers only to previously visited items. If we succeed,
// that shows that there cannot be any cycles, since walking any edge
// advances you towards the beginning of the visiting order.
//
// Validate all the handles in types and expressions as we traverse the
// arenas.
let mut global_exprs_iter = global_expressions.iter().peekable();
for (th, t) in types.iter() {
// Imagine the `for` loop and `global_exprs_iter` as two fingers
// walking the type and global expression arenas. They don't visit
// elements at the same rate: sometimes one processes a bunch of
// elements while the other one stays still. But at each point, they
// check that the two ranges of elements they've visited only refer
// to other elements in those ranges.
//
// For brevity, we'll say 'handles behind `global_exprs_iter`' to
// mean handles that have already been produced by
// `global_exprs_iter`. Once `global_exprs_iter` returns `None`, all
// global expression handles are 'behind' it.
//
// At this point:
//
// - All types visited by prior iterations (that is, before
// `th`/`t`) refer only to expressions behind `global_exprs_iter`.
//
// On the first iteration, this is obviously true: there are no
// prior iterations, and `global_exprs_iter` hasn't produced
// anything yet. At the bottom of the loop, we'll claim that it's
// true for `th`/`t` as well, so the condition remains true when
// we advance to the next type.
//
// - All expressions behind `global_exprs_iter` refer only to
// previously visited types.
//
// Again, trivially true at the start, and we'll show it's true
// about each expression that `global_exprs_iter` produces.
//
// Once we also check that arena elements only refer to prior
// elements in that arena, we can see that `th`/`t` does not
// participate in a cycle: it only refers to previously visited
// types and expressions behind `global_exprs_iter`, and none of
// those refer to `th`/`t`, because they passed the same checks
// before we reached `th`/`t`.
if let Some(max_expr) = Self::validate_type_handles((th, t), overrides)? {
max_expr.check_valid_for(global_expressions)?;
// Since `t` refers to `max_expr`, if we want our invariants to
// remain true, we must advance `global_exprs_iter` beyond
// `max_expr`.
while let Some((eh, e)) = global_exprs_iter.next_if(|&(eh, _)| eh <= max_expr) {
if let Some(max_type) =
Self::validate_const_expression_handles((eh, e), constants, overrides)?
{
// Show that `eh` refers only to previously visited types.
th.check_dep(max_type)?;
}
// We've advanced `global_exprs_iter` past `eh` already. But
// since we now know that `eh` refers only to previously
// visited types, it is again true that all expressions
// behind `global_exprs_iter` refer only to previously
// visited types. So we can continue to the next expression.
}
}
// Here we know that if `th` refers to any expressions at all,
// `max_expr` is the latest one. And we know that `max_expr` is
// behind `global_exprs_iter`. So `th` refers only to expressions
// behind `global_exprs_iter`, and the invariants will still be
// true on the next iteration.
}
// Since we also enforced the usual intra-arena rules that expressions
// refer only to prior expressions, expressions can only form cycles if
// they include types. But we've shown that all types are acyclic, so
// all expressions must be acyclic as well.
//
// Validate the remaining expressions normally.
for handle_and_expr in global_exprs_iter {
Self::validate_const_expression_handles(handle_and_expr, constants, overrides)?;
}
let validate_type = |handle| Self::validate_type_handle(handle, types);
let validate_const_expr =
|handle| Self::validate_expression_handle(handle, global_expressions);
for (_handle, constant) in constants.iter() {
let &crate::Constant { name: _, ty, init } = constant;
validate_type(ty)?;
validate_const_expr(init)?;
}
for (_handle, override_) in overrides.iter() {
let &crate::Override {
name: _,
id: _,
ty,
init,
} = override_;
validate_type(ty)?;
if let Some(init_expr) = init {
validate_const_expr(init_expr)?;
}
}
for (_handle, global_variable) in global_variables.iter() {
let &crate::GlobalVariable {
name: _,
space: _,
binding: _,
ty,
init,
} = global_variable;
validate_type(ty)?;
if let Some(init_expr) = init {
validate_const_expr(init_expr)?;
}
}
let validate_function = |function_handle, function: &_| -> Result<_, InvalidHandleError> {
let &crate::Function {
name: _,
ref arguments,
ref result,
ref local_variables,
ref expressions,
ref named_expressions,
ref body,
ref diagnostic_filter_leaf,
} = function;
for arg in arguments.iter() {
let &crate::FunctionArgument {
name: _,
ty,
binding: _,
} = arg;
validate_type(ty)?;
}
if let &Some(crate::FunctionResult { ty, binding: _ }) = result {
validate_type(ty)?;
}
for (_handle, local_variable) in local_variables.iter() {
let &crate::LocalVariable { name: _, ty, init } = local_variable;
validate_type(ty)?;
if let Some(init) = init {
Self::validate_expression_handle(init, expressions)?;
}
}
for handle in named_expressions.keys().copied() {
Self::validate_expression_handle(handle, expressions)?;
}
for handle_and_expr in expressions.iter() {
Self::validate_expression_handles(
handle_and_expr,
constants,
overrides,
global_expressions,
types,
local_variables,
global_variables,
functions,
function_handle,
)?;
}
Self::validate_block_handles(body, expressions, functions)?;
if let Some(handle) = *diagnostic_filter_leaf {
handle.check_valid_for(diagnostic_filters)?;
}
Ok(())
};
for entry_point in entry_points.iter() {
validate_function(None, &entry_point.function)?;
if let Some(sizes) = entry_point.workgroup_size_overrides {
for size in sizes.iter().filter_map(|x| *x) {
validate_const_expr(size)?;
}
}
}
for (function_handle, function) in functions.iter() {
validate_function(Some(function_handle), function)?;
}
if let Some(ty) = special_types.ray_desc {
validate_type(ty)?;
}
if let Some(ty) = special_types.ray_intersection {
validate_type(ty)?;
}
for (handle, _node) in diagnostic_filters.iter() {
let DiagnosticFilterNode { inner: _, parent } = diagnostic_filters[handle];
handle.check_dep_opt(parent)?;
}
if let Some(handle) = *diagnostic_filter_leaf {
handle.check_valid_for(diagnostic_filters)?;
}
Ok(())
}
fn validate_type_handle(
handle: Handle<crate::Type>,
types: &UniqueArena<crate::Type>,
) -> Result<(), InvalidHandleError> {
handle.check_valid_for_uniq(types).map(|_| ())
}
fn validate_constant_handle(
handle: Handle<crate::Constant>,
constants: &Arena<crate::Constant>,
) -> Result<(), InvalidHandleError> {
handle.check_valid_for(constants).map(|_| ())
}
fn validate_override_handle(
handle: Handle<crate::Override>,
overrides: &Arena<crate::Override>,
) -> Result<(), InvalidHandleError> {
handle.check_valid_for(overrides).map(|_| ())
}
fn validate_expression_handle(
handle: Handle<crate::Expression>,
expressions: &Arena<crate::Expression>,
) -> Result<(), InvalidHandleError> {
handle.check_valid_for(expressions).map(|_| ())
}
fn validate_function_handle(
handle: Handle<crate::Function>,
functions: &Arena<crate::Function>,
) -> Result<(), InvalidHandleError> {
handle.check_valid_for(functions).map(|_| ())
}
/// Validate all handles that occur in `ty`, whose handle is `handle`.
///
/// If `ty` refers to any expressions, return the highest-indexed expression
/// handle that it uses. This is used for detecting cycles between the
/// expression and type arenas.
fn validate_type_handles(
(handle, ty): (Handle<crate::Type>, &crate::Type),
overrides: &Arena<crate::Override>,
) -> Result<Option<Handle<crate::Expression>>, InvalidHandleError> {
let max_expr = match ty.inner {
crate::TypeInner::Scalar { .. }
| crate::TypeInner::Vector { .. }
| crate::TypeInner::Matrix { .. }
| crate::TypeInner::ValuePointer { .. }
| crate::TypeInner::Atomic { .. }
| crate::TypeInner::Image { .. }
| crate::TypeInner::Sampler { .. }
| crate::TypeInner::AccelerationStructure
| crate::TypeInner::RayQuery => None,
crate::TypeInner::Pointer { base, space: _ } => {
handle.check_dep(base)?;
None
}
crate::TypeInner::Array { base, size, .. }
| crate::TypeInner::BindingArray { base, size, .. } => {
handle.check_dep(base)?;
match size {
crate::ArraySize::Pending(pending) => match pending {
crate::PendingArraySize::Expression(expr) => Some(expr),
crate::PendingArraySize::Override(h) => {
Self::validate_override_handle(h, overrides)?;
let override_ = &overrides[h];
handle.check_dep(override_.ty)?;
override_.init
}
},
crate::ArraySize::Constant(_) | crate::ArraySize::Dynamic => None,
}
}
crate::TypeInner::Struct {
ref members,
span: _,
} => {
handle.check_dep_iter(members.iter().map(|m| m.ty))?;
None
}
};
Ok(max_expr)
}
/// Validate all handles that occur in `expression`, whose handle is `handle`.
///
/// If `expression` refers to any `Type`s, return the highest-indexed type
/// handle that it uses. This is used for detecting cycles between the
/// expression and type arenas.
fn validate_const_expression_handles(
(handle, expression): (Handle<crate::Expression>, &crate::Expression),
constants: &Arena<crate::Constant>,
overrides: &Arena<crate::Override>,
) -> Result<Option<Handle<crate::Type>>, InvalidHandleError> {
let validate_constant = |handle| Self::validate_constant_handle(handle, constants);
let validate_override = |handle| Self::validate_override_handle(handle, overrides);
let max_type = match *expression {
crate::Expression::Literal(_) => None,
crate::Expression::Constant(constant) => {
validate_constant(constant)?;
handle.check_dep(constants[constant].init)?;
None
}
crate::Expression::Override(override_) => {
validate_override(override_)?;
if let Some(init) = overrides[override_].init {
handle.check_dep(init)?;
}
None
}
crate::Expression::ZeroValue(ty) => Some(ty),
crate::Expression::Compose { ty, ref components } => {
handle.check_dep_iter(components.iter().copied())?;
Some(ty)
}
_ => None,
};
Ok(max_type)
}
#[allow(clippy::too_many_arguments)]
fn validate_expression_handles(
(handle, expression): (Handle<crate::Expression>, &crate::Expression),
constants: &Arena<crate::Constant>,
overrides: &Arena<crate::Override>,
global_expressions: &Arena<crate::Expression>,
types: &UniqueArena<crate::Type>,
local_variables: &Arena<crate::LocalVariable>,
global_variables: &Arena<crate::GlobalVariable>,
functions: &Arena<crate::Function>,
// The handle of the current function or `None` if it's an entry point
current_function: Option<Handle<crate::Function>>,
) -> Result<(), InvalidHandleError> {
let validate_constant = |handle| Self::validate_constant_handle(handle, constants);
let validate_override = |handle| Self::validate_override_handle(handle, overrides);
let validate_const_expr =
|handle| Self::validate_expression_handle(handle, global_expressions);
let validate_type = |handle| Self::validate_type_handle(handle, types);
match *expression {
crate::Expression::Access { base, index } => {
handle.check_dep(base)?.check_dep(index)?;
}
crate::Expression::AccessIndex { base, .. } => {
handle.check_dep(base)?;
}
crate::Expression::Splat { value, .. } => {
handle.check_dep(value)?;
}
crate::Expression::Swizzle { vector, .. } => {
handle.check_dep(vector)?;
}
crate::Expression::Literal(_) => {}
crate::Expression::Constant(constant) => {
validate_constant(constant)?;
}
crate::Expression::Override(override_) => {
validate_override(override_)?;
}
crate::Expression::ZeroValue(ty) => {
validate_type(ty)?;
}
crate::Expression::Compose { ty, ref components } => {
validate_type(ty)?;
handle.check_dep_iter(components.iter().copied())?;
}
crate::Expression::FunctionArgument(_arg_idx) => (),
crate::Expression::GlobalVariable(global_variable) => {
global_variable.check_valid_for(global_variables)?;
}
crate::Expression::LocalVariable(local_variable) => {
local_variable.check_valid_for(local_variables)?;
}
crate::Expression::Load { pointer } => {
handle.check_dep(pointer)?;
}
crate::Expression::ImageSample {
image,
sampler,
gather: _,
coordinate,
array_index,
offset,
level,
depth_ref,
} => {
if let Some(offset) = offset {
validate_const_expr(offset)?;
}
handle
.check_dep(image)?
.check_dep(sampler)?
.check_dep(coordinate)?
.check_dep_opt(array_index)?;
match level {
crate::SampleLevel::Auto | crate::SampleLevel::Zero => (),
crate::SampleLevel::Exact(expr) => {
handle.check_dep(expr)?;
}
crate::SampleLevel::Bias(expr) => {
handle.check_dep(expr)?;
}
crate::SampleLevel::Gradient { x, y } => {
handle.check_dep(x)?.check_dep(y)?;
}
};
handle.check_dep_opt(depth_ref)?;
}
crate::Expression::ImageLoad {
image,
coordinate,
array_index,
sample,
level,
} => {
handle
.check_dep(image)?
.check_dep(coordinate)?
.check_dep_opt(array_index)?
.check_dep_opt(sample)?
.check_dep_opt(level)?;
}
crate::Expression::ImageQuery { image, query } => {
handle.check_dep(image)?;
match query {
crate::ImageQuery::Size { level } => {
handle.check_dep_opt(level)?;
}
crate::ImageQuery::NumLevels
| crate::ImageQuery::NumLayers
| crate::ImageQuery::NumSamples => (),
};
}
crate::Expression::Unary {
op: _,
expr: operand,
} => {
handle.check_dep(operand)?;
}
crate::Expression::Binary { op: _, left, right } => {
handle.check_dep(left)?.check_dep(right)?;
}
crate::Expression::Select {
condition,
accept,
reject,
} => {
handle
.check_dep(condition)?
.check_dep(accept)?
.check_dep(reject)?;
}
crate::Expression::Derivative { expr: argument, .. } => {
handle.check_dep(argument)?;
}
crate::Expression::Relational { fun: _, argument } => {
handle.check_dep(argument)?;
}
crate::Expression::Math {
fun: _,
arg,
arg1,
arg2,
arg3,
} => {
handle
.check_dep(arg)?
.check_dep_opt(arg1)?
.check_dep_opt(arg2)?
.check_dep_opt(arg3)?;
}
crate::Expression::As {
expr: input,
kind: _,
convert: _,
} => {
handle.check_dep(input)?;
}
crate::Expression::CallResult(function) => {
Self::validate_function_handle(function, functions)?;
if let Some(handle) = current_function {
handle.check_dep(function)?;
}
}
crate::Expression::AtomicResult { .. }
| crate::Expression::RayQueryProceedResult
| crate::Expression::SubgroupBallotResult
| crate::Expression::SubgroupOperationResult { .. }
| crate::Expression::WorkGroupUniformLoadResult { .. } => (),
crate::Expression::ArrayLength(array) => {
handle.check_dep(array)?;
}
crate::Expression::RayQueryGetIntersection {
query,
committed: _,
} => {
handle.check_dep(query)?;
}
}
Ok(())
}
fn validate_block_handles(
block: &crate::Block,
expressions: &Arena<crate::Expression>,
functions: &Arena<crate::Function>,
) -> Result<(), InvalidHandleError> {
let validate_block = |block| Self::validate_block_handles(block, expressions, functions);
let validate_expr = |handle| Self::validate_expression_handle(handle, expressions);
let validate_expr_opt = |handle_opt| {
if let Some(handle) = handle_opt {
validate_expr(handle)?;
}
Ok(())
};
block.iter().try_for_each(|stmt| match *stmt {
crate::Statement::Emit(ref expr_range) => {
expr_range.check_valid_for(expressions)?;
Ok(())
}
crate::Statement::Block(ref block) => {
validate_block(block)?;
Ok(())
}
crate::Statement::If {
condition,
ref accept,
ref reject,
} => {
validate_expr(condition)?;
validate_block(accept)?;
validate_block(reject)?;
Ok(())
}
crate::Statement::Switch {
selector,
ref cases,
} => {
validate_expr(selector)?;
for &crate::SwitchCase {
value: _,
ref body,
fall_through: _,
} in cases
{
validate_block(body)?;
}
Ok(())
}
crate::Statement::Loop {
ref body,
ref continuing,
break_if,
} => {
validate_block(body)?;
validate_block(continuing)?;
validate_expr_opt(break_if)?;
Ok(())
}
crate::Statement::Return { value } => validate_expr_opt(value),
crate::Statement::Store { pointer, value } => {
validate_expr(pointer)?;
validate_expr(value)?;
Ok(())
}
crate::Statement::ImageStore {
image,
coordinate,
array_index,
value,
} => {
validate_expr(image)?;
validate_expr(coordinate)?;
validate_expr_opt(array_index)?;
validate_expr(value)?;
Ok(())
}
crate::Statement::Atomic {
pointer,
fun,
value,
result,
} => {
validate_expr(pointer)?;
match fun {
crate::AtomicFunction::Add
| crate::AtomicFunction::Subtract
| crate::AtomicFunction::And
| crate::AtomicFunction::ExclusiveOr
| crate::AtomicFunction::InclusiveOr
| crate::AtomicFunction::Min
| crate::AtomicFunction::Max => (),
crate::AtomicFunction::Exchange { compare } => validate_expr_opt(compare)?,
};
validate_expr(value)?;
if let Some(result) = result {
validate_expr(result)?;
}
Ok(())
}
crate::Statement::ImageAtomic {
image,
coordinate,
array_index,
fun: _,
value,
} => {
validate_expr(image)?;
validate_expr(coordinate)?;
validate_expr_opt(array_index)?;
validate_expr(value)?;
Ok(())
}
crate::Statement::WorkGroupUniformLoad { pointer, result } => {
validate_expr(pointer)?;
validate_expr(result)?;
Ok(())
}
crate::Statement::Call {
function,
ref arguments,
result,
} => {
Self::validate_function_handle(function, functions)?;
for arg in arguments.iter().copied() {
validate_expr(arg)?;
}
validate_expr_opt(result)?;
Ok(())
}
crate::Statement::RayQuery { query, ref fun } => {
validate_expr(query)?;
match *fun {
crate::RayQueryFunction::Initialize {
acceleration_structure,
descriptor,
} => {
validate_expr(acceleration_structure)?;
validate_expr(descriptor)?;
}
crate::RayQueryFunction::Proceed { result } => {
validate_expr(result)?;
}
crate::RayQueryFunction::Terminate => {}
}
Ok(())
}
crate::Statement::SubgroupBallot { result, predicate } => {
validate_expr_opt(predicate)?;
validate_expr(result)?;
Ok(())
}
crate::Statement::SubgroupCollectiveOperation {
op: _,
collective_op: _,
argument,
result,
} => {
validate_expr(argument)?;
validate_expr(result)?;
Ok(())
}
crate::Statement::SubgroupGather {
mode,
argument,
result,
} => {
validate_expr(argument)?;
match mode {
crate::GatherMode::BroadcastFirst => {}
crate::GatherMode::Broadcast(index)
| crate::GatherMode::Shuffle(index)
| crate::GatherMode::ShuffleDown(index)
| crate::GatherMode::ShuffleUp(index)
| crate::GatherMode::ShuffleXor(index) => validate_expr(index)?,
}
validate_expr(result)?;
Ok(())
}
crate::Statement::Break
| crate::Statement::Continue
| crate::Statement::Kill
| crate::Statement::Barrier(_) => Ok(()),
})
}
}
impl From<BadHandle> for ValidationError {
fn from(source: BadHandle) -> Self {
Self::InvalidHandle(source.into())
}
}
impl From<FwdDepError> for ValidationError {
fn from(source: FwdDepError) -> Self {
Self::InvalidHandle(source.into())
}
}
impl From<BadRangeError> for ValidationError {
fn from(source: BadRangeError) -> Self {
Self::InvalidHandle(source.into())
}
}
#[derive(Clone, Debug, thiserror::Error)]
#[cfg_attr(test, derive(PartialEq))]
pub enum InvalidHandleError {
#[error(transparent)]
BadHandle(#[from] BadHandle),
#[error(transparent)]
ForwardDependency(#[from] FwdDepError),
#[error(transparent)]
BadRange(#[from] BadRangeError),
}
#[derive(Clone, Debug, thiserror::Error)]
#[cfg_attr(test, derive(PartialEq))]
#[error(
"{subject:?} of kind {subject_kind:?} depends on {depends_on:?} of kind {depends_on_kind}, \
which has not been processed yet"
)]
pub struct FwdDepError {
// This error is used for many `Handle` types, but there's no point in making this generic, so
// we just flatten them all to `Handle<()>` here.
subject: Handle<()>,
subject_kind: &'static str,
depends_on: Handle<()>,
depends_on_kind: &'static str,
}
impl<T> Handle<T> {
/// Check that `self` is valid within `arena` using [`Arena::check_contains_handle`].
pub(self) fn check_valid_for(self, arena: &Arena<T>) -> Result<(), InvalidHandleError> {
arena.check_contains_handle(self)?;
Ok(())
}
/// Check that `self` is valid within `arena` using [`UniqueArena::check_contains_handle`].
pub(self) fn check_valid_for_uniq(
self,
arena: &UniqueArena<T>,
) -> Result<(), InvalidHandleError>
where
T: Eq + Hash,
{
arena.check_contains_handle(self)?;
Ok(())
}
/// Check that `depends_on` was constructed before `self` by comparing handle indices.
///
/// If `self` is a valid handle (i.e., it has been validated using [`Self::check_valid_for`])
/// and this function returns [`Ok`], then it may be assumed that `depends_on` is also valid.
/// In [`naga`](crate)'s current arena-based implementation, this is useful for validating
/// recursive definitions of arena-based values in linear time.
///
/// # Errors
///
/// If `depends_on`'s handle is from the same [`Arena`] as `self'`s, but not constructed earlier
/// than `self`'s, this function returns an error.
pub(self) fn check_dep(self, depends_on: Self) -> Result<Self, FwdDepError> {
if depends_on < self {
Ok(self)
} else {
let erase_handle_type = |handle: Handle<_>| {
Handle::new(NonMaxU32::new((handle.index()).try_into().unwrap()).unwrap())
};
Err(FwdDepError {
subject: erase_handle_type(self),
subject_kind: std::any::type_name::<T>(),
depends_on: erase_handle_type(depends_on),
depends_on_kind: std::any::type_name::<T>(),
})
}
}
/// Like [`Self::check_dep`], except for [`Option`]al handle values.
pub(self) fn check_dep_opt(self, depends_on: Option<Self>) -> Result<Self, FwdDepError> {
self.check_dep_iter(depends_on.into_iter())
}
/// Like [`Self::check_dep`], except for [`Iterator`]s over handle values.
pub(self) fn check_dep_iter(
self,
depends_on: impl Iterator<Item = Self>,
) -> Result<Self, FwdDepError> {
for handle in depends_on {
self.check_dep(handle)?;
}
Ok(self)
}
}
impl<T> crate::arena::Range<T> {
pub(self) fn check_valid_for(&self, arena: &Arena<T>) -> Result<(), BadRangeError> {
arena.check_contains_range(self)
}
}
#[test]
fn constant_deps() {
use crate::{Constant, Expression, Literal, Span, Type, TypeInner};
let nowhere = Span::default();
let mut types = UniqueArena::new();
let mut const_exprs = Arena::new();
let mut fun_exprs = Arena::new();
let mut constants = Arena::new();
let overrides = Arena::new();
let i32_handle = types.insert(
Type {
name: None,
inner: TypeInner::Scalar(crate::Scalar::I32),
},
nowhere,
);
// Construct a self-referential constant by misusing a handle to
// fun_exprs as a constant initializer.
let fun_expr = fun_exprs.append(Expression::Literal(Literal::I32(42)), nowhere);
let self_referential_const = constants.append(
Constant {
name: None,
ty: i32_handle,
init: fun_expr,
},
nowhere,
);
let _self_referential_expr =
const_exprs.append(Expression::Constant(self_referential_const), nowhere);
for handle_and_expr in const_exprs.iter() {
assert!(super::Validator::validate_const_expression_handles(
handle_and_expr,
&constants,
&overrides,
)
.is_err());
}
}
#[test]
fn array_size_deps() {
use super::Validator;
use crate::{ArraySize, Expression, PendingArraySize, Scalar, Span, Type, TypeInner};
let nowhere = Span::default();
let mut m = crate::Module::default();
let ty_u32 = m.types.insert(
Type {
name: Some("u32".to_string()),
inner: TypeInner::Scalar(Scalar::U32),
},
nowhere,
);
let ex_zero = m
.global_expressions
.append(Expression::ZeroValue(ty_u32), nowhere);
let ty_arr = m.types.insert(
Type {
name: Some("bad_array".to_string()),
inner: TypeInner::Array {
base: ty_u32,
size: ArraySize::Pending(PendingArraySize::Expression(ex_zero)),
stride: 4,
},
},
nowhere,
);
// Everything should be okay now.
assert!(Validator::validate_module_handles(&m).is_ok());
// Mutate `ex_zero`'s type to `ty_arr`, introducing a cycle.
// Validation should catch the cycle.
m.global_expressions[ex_zero] = Expression::ZeroValue(ty_arr);
assert!(Validator::validate_module_handles(&m).is_err());
}
#[test]
fn array_size_override() {
use super::Validator;
use crate::{ArraySize, Override, PendingArraySize, Scalar, Span, Type, TypeInner};
let nowhere = Span::default();
let mut m = crate::Module::default();
let ty_u32 = m.types.insert(
Type {
name: Some("u32".to_string()),
inner: TypeInner::Scalar(Scalar::U32),
},
nowhere,
);
let bad_override: Handle<Override> = Handle::new(NonMaxU32::new(1000).unwrap());
let _ty_arr = m.types.insert(
Type {
name: Some("bad_array".to_string()),
inner: TypeInner::Array {
base: ty_u32,
size: ArraySize::Pending(PendingArraySize::Override(bad_override)),
stride: 4,
},
},
nowhere,
);
assert!(Validator::validate_module_handles(&m).is_err());
}
#[test]
fn override_init_deps() {
use super::Validator;
use crate::{ArraySize, Expression, Override, PendingArraySize, Scalar, Span, Type, TypeInner};
let nowhere = Span::default();
let mut m = crate::Module::default();
let ty_u32 = m.types.insert(
Type {
name: Some("u32".to_string()),
inner: TypeInner::Scalar(Scalar::U32),
},
nowhere,
);
let ex_zero = m
.global_expressions
.append(Expression::ZeroValue(ty_u32), nowhere);
let r#override = m.overrides.append(
Override {
name: Some("bad_override".into()),
id: None,
ty: ty_u32,
init: Some(ex_zero),
},
nowhere,
);
let ty_arr = m.types.insert(
Type {
name: Some("bad_array".to_string()),
inner: TypeInner::Array {
base: ty_u32,
size: ArraySize::Pending(PendingArraySize::Override(r#override)),
stride: 4,
},
},
nowhere,
);
let ex_arr = m
.global_expressions
.append(Expression::ZeroValue(ty_arr), nowhere);
assert!(Validator::validate_module_handles(&m).is_ok());
// Mutate `r#override`'s initializer to `ex_arr`, introducing a cycle.
// Validation should catch the cycle.
m.overrides[r#override].init = Some(ex_arr);
assert!(Validator::validate_module_handles(&m).is_err());
}
[ Dauer der Verarbeitung: 0.55 Sekunden
(vorverarbeitet)
]
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2026-04-04
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