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use std::iter;
use arrayvec::ArrayVec;
use crate::{
arena::{Arena, Handle, HandleVec, UniqueArena},
ArraySize, BinaryOperator, Constant, Expression, Literal, Override, ScalarKind, Span, Type,
TypeInner, UnaryOperator,
};
/// A macro that allows dollar signs (`$`) to be emitted by other macros. Useful for generating
/// `macro_rules!` items that, in turn, emit their own `macro_rules!` items.
///
/// Technique stolen directly from
macro_rules! with_dollar_sign {
($($body:tt)*) => {
macro_rules! __with_dollar_sign { $($body)* }
__with_dollar_sign!($);
}
}
macro_rules! gen_component_wise_extractor {
(
$ident:ident -> $target:ident,
literals: [$( $literal:ident => $mapping:ident: $ty:ident ),+ $(,)?],
scalar_kinds: [$( $scalar_kind:ident ),* $(,)?],
) => {
/// A subset of [`Literal`]s intended to be used for implementing numeric built-ins.
#[derive(Debug)]
#[cfg_attr(test, derive(PartialEq))]
enum $target<const N: usize> {
$(
#[doc = concat!(
"Maps to [`Literal::",
stringify!($literal),
"`]",
)]
$mapping([$ty; N]),
)+
}
impl From<$target<1>> for Expression {
fn from(value: $target<1>) -> Self {
match value {
$(
$target::$mapping([value]) => {
Expression::Literal(Literal::$literal(value))
}
)+
}
}
}
#[doc = concat!(
"Attempts to evaluate multiple `exprs` as a combined [`",
stringify!($target),
"`] to pass to `handler`. ",
)]
/// If `exprs` are vectors of the same length, `handler` is called for each corresponding
/// component of each vector.
///
/// `handler`'s output is registered as a new expression. If `exprs` are vectors of the
/// same length, a new vector expression is registered, composed of each component emitted
/// by `handler`.
fn $ident<const N: usize, const M: usize, F>(
eval: &mut ConstantEvaluator<'_>,
span: Span,
exprs: [Handle<Expression>; N],
mut handler: F,
) -> Result<Handle<Expression>, ConstantEvaluatorError>
where
$target<M>: Into<Expression>,
F: FnMut($target<N>) -> Result<$target<M>, ConstantEvaluatorError> + Clone,
{
assert!(N > 0);
let err = ConstantEvaluatorError::InvalidMathArg;
let mut exprs = exprs.into_iter();
macro_rules! sanitize {
($expr:expr) => {
eval.eval_zero_value_and_splat($expr, span)
.map(|expr| &eval.expressions[expr])
};
}
let new_expr = match sanitize!(exprs.next().unwrap())? {
$(
&Expression::Literal(Literal::$literal(x)) => iter::once(Ok(x))
.chain(exprs.map(|expr| {
sanitize!(expr).and_then(|expr| match expr {
&Expression::Literal(Literal::$literal(x)) => Ok(x),
_ => Err(err.clone()),
})
}))
.collect::<Result<ArrayVec<_, N>, _>>()
.map(|a| a.into_inner().unwrap())
.map($target::$mapping)
.and_then(|comps| Ok(handler(comps)?.into())),
)+
&Expression::Compose { ty, ref components } => match &eval.types[ty].inner {
&TypeInner::Vector { size, scalar } => match scalar.kind {
$(ScalarKind::$scalar_kind)|* => {
let first_ty = ty;
let mut component_groups =
ArrayVec::<ArrayVec<_, { crate::VectorSize::MAX }>, N>::new();
component_groups.push(crate::proc::flatten_compose(
first_ty,
components,
eval.expressions,
eval.types,
).collect());
component_groups.extend(
exprs
.map(|expr| {
sanitize!(expr).and_then(|expr| match expr {
&Expression::Compose { ty, ref components }
if &eval.types[ty].inner
== &eval.types[first_ty].inner =>
{
Ok(crate::proc::flatten_compose(
ty,
components,
eval.expressions,
eval.types,
).collect())
}
_ => Err(err.clone()),
})
})
.collect::<Result<ArrayVec<_, { crate::VectorSize::MAX }>, _>>(
)?,
);
let component_groups = component_groups.into_inner().unwrap();
let mut new_components =
ArrayVec::<_, { crate::VectorSize::MAX }>::new();
for idx in 0..(size as u8).into() {
let group = component_groups
.iter()
.map(|cs| cs[idx])
.collect::<ArrayVec<_, N>>()
.into_inner()
.unwrap();
new_components.push($ident(
eval,
span,
group,
handler.clone(),
)?);
}
Ok(Expression::Compose {
ty: first_ty,
components: new_components.into_iter().collect(),
})
}
_ => return Err(err),
},
_ => return Err(err),
},
_ => return Err(err),
}?;
eval.register_evaluated_expr(new_expr, span)
}
with_dollar_sign! {
($d:tt) => {
#[allow(unused)]
#[doc = concat!(
"A convenience macro for using the same RHS for each [`",
stringify!($target),
"`] variant in a call to [`",
stringify!($ident),
"`].",
)]
macro_rules! $ident {
(
$eval:expr,
$span:expr,
[$d ($d expr:expr),+ $d (,)?],
|$d ($d arg:ident),+| $d tt:tt
) => {
$ident($eval, $span, [$d ($d expr),+], |args| match args {
$(
$target::$mapping([$d ($d arg),+]) => {
let res = $d tt;
Result::map(res, $target::$mapping)
},
)+
})
};
}
};
}
};
}
gen_component_wise_extractor! {
component_wise_scalar -> Scalar,
literals: [
AbstractFloat => AbstractFloat: f64,
F32 => F32: f32,
AbstractInt => AbstractInt: i64,
U32 => U32: u32,
I32 => I32: i32,
U64 => U64: u64,
I64 => I64: i64,
],
scalar_kinds: [
Float,
AbstractFloat,
Sint,
Uint,
AbstractInt,
],
}
gen_component_wise_extractor! {
component_wise_float -> Float,
literals: [
AbstractFloat => Abstract: f64,
F32 => F32: f32,
],
scalar_kinds: [
Float,
AbstractFloat,
],
}
gen_component_wise_extractor! {
component_wise_concrete_int -> ConcreteInt,
literals: [
U32 => U32: u32,
I32 => I32: i32,
],
scalar_kinds: [
Sint,
Uint,
],
}
gen_component_wise_extractor! {
component_wise_signed -> Signed,
literals: [
AbstractFloat => AbstractFloat: f64,
AbstractInt => AbstractInt: i64,
F32 => F32: f32,
I32 => I32: i32,
],
scalar_kinds: [
Sint,
AbstractInt,
Float,
AbstractFloat,
],
}
#[derive(Debug)]
enum Behavior<'a> {
Wgsl(WgslRestrictions<'a>),
Glsl(GlslRestrictions<'a>),
}
impl Behavior<'_> {
/// Returns `true` if the inner WGSL/GLSL restrictions are runtime restrictions.
const fn has_runtime_restrictions(&self) -> bool {
matches!(
self,
&Behavior::Wgsl(WgslRestrictions::Runtime(_))
| &Behavior::Glsl(GlslRestrictions::Runtime(_))
)
}
}
/// A context for evaluating constant expressions.
///
/// A `ConstantEvaluator` points at an expression arena to which it can append
/// newly evaluated expressions: you pass [`try_eval_and_append`] whatever kind
/// of Naga [`Expression`] you like, and if its value can be computed at compile
/// time, `try_eval_and_append` appends an expression representing the computed
/// value - a tree of [`Literal`], [`Compose`], [`ZeroValue`], and [`Swizzle`]
/// expressions - to the arena. See the [`try_eval_and_append`] method for details.
///
/// A `ConstantEvaluator` also holds whatever information we need to carry out
/// that evaluation: types, other constants, and so on.
///
/// [`try_eval_and_append`]: ConstantEvaluator::try_eval_and_append
/// [`Compose`]: Expression::Compose
/// [`ZeroValue`]: Expression::ZeroValue
/// [`Literal`]: Expression::Literal
/// [`Swizzle`]: Expression::Swizzle
#[derive(Debug)]
pub struct ConstantEvaluator<'a> {
/// Which language's evaluation rules we should follow.
behavior: Behavior<'a>,
/// The module's type arena.
///
/// Because expressions like [`Splat`] contain type handles, we need to be
/// able to add new types to produce those expressions.
///
/// [`Splat`]: Expression::Splat
types: &'a mut UniqueArena<Type>,
/// The module's constant arena.
constants: &'a Arena<Constant>,
/// The module's override arena.
overrides: &'a Arena<Override>,
/// The arena to which we are contributing expressions.
expressions: &'a mut Arena<Expression>,
/// Tracks the constness of expressions residing in [`Self::expressions`]
expression_kind_tracker: &'a mut ExpressionKindTracker,
}
#[derive(Debug)]
enum WgslRestrictions<'a> {
/// - const-expressions will be evaluated and inserted in the arena
Const(Option<FunctionLocalData<'a>>),
/// - const-expressions will be evaluated and inserted in the arena
/// - override-expressions will be inserted in the arena
Override,
/// - const-expressions will be evaluated and inserted in the arena
/// - override-expressions will be inserted in the arena
/// - runtime-expressions will be inserted in the arena
Runtime(FunctionLocalData<'a>),
}
#[derive(Debug)]
enum GlslRestrictions<'a> {
/// - const-expressions will be evaluated and inserted in the arena
Const,
/// - const-expressions will be evaluated and inserted in the arena
/// - override-expressions will be inserted in the arena
/// - runtime-expressions will be inserted in the arena
Runtime(FunctionLocalData<'a>),
}
#[derive(Debug)]
struct FunctionLocalData<'a> {
/// Global constant expressions
global_expressions: &'a Arena<Expression>,
emitter: &'a mut super::Emitter,
block: &'a mut crate::Block,
}
#[derive(Debug, PartialEq, Eq, PartialOrd, Ord, Clone, Copy)]
pub enum ExpressionKind {
/// If const is also implemented as const
ImplConst,
Const,
Override,
Runtime,
}
#[derive(Debug)]
pub struct ExpressionKindTracker {
inner: HandleVec<Expression, ExpressionKind>,
}
impl ExpressionKindTracker {
pub const fn new() -> Self {
Self {
inner: HandleVec::new(),
}
}
/// Forces the the expression to not be const
pub fn force_non_const(&mut self, value: Handle<Expression>) {
self.inner[value] = ExpressionKind::Runtime;
}
pub fn insert(&mut self, value: Handle<Expression>, expr_type: ExpressionKind) {
self.inner.insert(value, expr_type);
}
pub fn is_const(&self, h: Handle<Expression>) -> bool {
matches!(
self.type_of(h),
ExpressionKind::Const | ExpressionKind::ImplConst
)
}
/// Returns `true` if naga can also evaluate expression as const
pub fn is_impl_const(&self, h: Handle<Expression>) -> bool {
matches!(self.type_of(h), ExpressionKind::ImplConst)
}
pub fn is_const_or_override(&self, h: Handle<Expression>) -> bool {
matches!(
self.type_of(h),
ExpressionKind::Const | ExpressionKind::Override | ExpressionKind::ImplConst
)
}
fn type_of(&self, value: Handle<Expression>) -> ExpressionKind {
self.inner[value]
}
pub fn from_arena(arena: &Arena<Expression>) -> Self {
let mut tracker = Self {
inner: HandleVec::with_capacity(arena.len()),
};
for (handle, expr) in arena.iter() {
tracker
.inner
.insert(handle, tracker.type_of_with_expr(expr));
}
tracker
}
fn type_of_with_expr(&self, expr: &Expression) -> ExpressionKind {
use crate::MathFunction as Mf;
match *expr {
Expression::Literal(_) | Expression::ZeroValue(_) | Expression::Constant(_) => {
ExpressionKind::ImplConst
}
Expression::Override(_) => ExpressionKind::Override,
Expression::Compose { ref components, .. } => {
let mut expr_type = ExpressionKind::ImplConst;
for component in components {
expr_type = expr_type.max(self.type_of(*component))
}
expr_type
}
Expression::Splat { value, .. } => self.type_of(value),
Expression::AccessIndex { base, .. } => self.type_of(base),
Expression::Access { base, index } => self.type_of(base).max(self.type_of(index)),
Expression::Swizzle { vector, .. } => self.type_of(vector),
Expression::Unary { expr, .. } => self.type_of(expr),
Expression::Binary { left, right, .. } => self
.type_of(left)
.max(self.type_of(right))
.max(ExpressionKind::Const),
Expression::Math {
fun,
arg,
arg1,
arg2,
arg3,
} => self
.type_of(arg)
.max(
arg1.map(|arg| self.type_of(arg))
.unwrap_or(ExpressionKind::Const),
)
.max(
arg2.map(|arg| self.type_of(arg))
.unwrap_or(ExpressionKind::Const),
)
.max(
arg3.map(|arg| self.type_of(arg))
.unwrap_or(ExpressionKind::Const),
)
.max(
if matches!(
fun,
Mf::Dot
| Mf::Outer
| Mf::Cross
| Mf::Distance
| Mf::Length
| Mf::Normalize
| Mf::FaceForward
| Mf::Reflect
| Mf::Refract
| Mf::Ldexp
| Mf::Modf
| Mf::Mix
| Mf::Frexp
) {
ExpressionKind::Const
} else {
ExpressionKind::ImplConst
},
),
Expression::As { convert, expr, .. } => self.type_of(expr).max(if convert.is_some() {
ExpressionKind::ImplConst
} else {
ExpressionKind::Const
}),
Expression::Select {
condition,
accept,
reject,
} => self
.type_of(condition)
.max(self.type_of(accept))
.max(self.type_of(reject))
.max(ExpressionKind::Const),
Expression::Relational { argument, .. } => self.type_of(argument),
Expression::ArrayLength(expr) => self.type_of(expr),
_ => ExpressionKind::Runtime,
}
}
}
#[derive(Clone, Debug, thiserror::Error)]
#[cfg_attr(test, derive(PartialEq))]
pub enum ConstantEvaluatorError {
#[error("Constants cannot access function arguments")]
FunctionArg,
#[error("Constants cannot access global variables")]
GlobalVariable,
#[error("Constants cannot access local variables")]
LocalVariable,
#[error("Cannot get the array length of a non array type")]
InvalidArrayLengthArg,
#[error("Constants cannot get the array length of a dynamically sized array")]
ArrayLengthDynamic,
#[error("Constants cannot call functions")]
Call,
#[error("Constants don't support workGroupUniformLoad")]
WorkGroupUniformLoadResult,
#[error("Constants don't support atomic functions")]
Atomic,
#[error("Constants don't support derivative functions")]
Derivative,
#[error("Constants don't support load expressions")]
Load,
#[error("Constants don't support image expressions")]
ImageExpression,
#[error("Constants don't support ray query expressions")]
RayQueryExpression,
#[error("Constants don't support subgroup expressions")]
SubgroupExpression,
#[error("Cannot access the type")]
InvalidAccessBase,
#[error("Cannot access at the index")]
InvalidAccessIndex,
#[error("Cannot access with index of type")]
InvalidAccessIndexTy,
#[error("Constants don't support array length expressions")]
ArrayLength,
#[error("Cannot cast scalar components of expression `{from}` to type `{to}`")]
InvalidCastArg { from: String, to: String },
#[error("Cannot apply the unary op to the argument")]
InvalidUnaryOpArg,
#[error("Cannot apply the binary op to the arguments")]
InvalidBinaryOpArgs,
#[error("Cannot apply math function to type")]
InvalidMathArg,
#[error("{0:?} built-in function expects {1:?} arguments but {2:?} were supplied")]
InvalidMathArgCount(crate::MathFunction, usize, usize),
#[error("value of `low` is greater than `high` for clamp built-in function")]
InvalidClamp,
#[error("Splat is defined only on scalar values")]
SplatScalarOnly,
#[error("Can only swizzle vector constants")]
SwizzleVectorOnly,
#[error("swizzle component not present in source expression")]
SwizzleOutOfBounds,
#[error("Type is not constructible")]
TypeNotConstructible,
#[error("Subexpression(s) are not constant")]
SubexpressionsAreNotConstant,
#[error("Not implemented as constant expression: {0}")]
NotImplemented(String),
#[error("{0} operation overflowed")]
Overflow(String),
#[error(
"the concrete type `{to_type}` cannot represent the abstract value `{value}` accurately"
)]
AutomaticConversionLossy {
value: String,
to_type: &'static str,
},
#[error("abstract floating-point values cannot be automatically converted to integers")]
AutomaticConversionFloatToInt { to_type: &'static str },
#[error("Division by zero")]
DivisionByZero,
#[error("Remainder by zero")]
RemainderByZero,
#[error("RHS of shift operation is greater than or equal to 32")]
ShiftedMoreThan32Bits,
#[error(transparent)]
Literal(#[from] crate::valid::LiteralError),
#[error("Can't use pipeline-overridable constants in const-expressions")]
Override,
#[error("Unexpected runtime-expression")]
RuntimeExpr,
#[error("Unexpected override-expression")]
OverrideExpr,
}
impl<'a> ConstantEvaluator<'a> {
/// Return a [`ConstantEvaluator`] that will add expressions to `module`'s
/// constant expression arena.
///
/// Report errors according to WGSL's rules for constant evaluation.
pub fn for_wgsl_module(
module: &'a mut crate::Module,
global_expression_kind_tracker: &'a mut ExpressionKindTracker,
in_override_ctx: bool,
) -> Self {
Self::for_module(
Behavior::Wgsl(if in_override_ctx {
WgslRestrictions::Override
} else {
WgslRestrictions::Const(None)
}),
module,
global_expression_kind_tracker,
)
}
/// Return a [`ConstantEvaluator`] that will add expressions to `module`'s
/// constant expression arena.
///
/// Report errors according to GLSL's rules for constant evaluation.
pub fn for_glsl_module(
module: &'a mut crate::Module,
global_expression_kind_tracker: &'a mut ExpressionKindTracker,
) -> Self {
Self::for_module(
Behavior::Glsl(GlslRestrictions::Const),
module,
global_expression_kind_tracker,
)
}
fn for_module(
behavior: Behavior<'a>,
module: &'a mut crate::Module,
global_expression_kind_tracker: &'a mut ExpressionKindTracker,
) -> Self {
Self {
behavior,
types: &mut module.types,
constants: &module.constants,
overrides: &module.overrides,
expressions: &mut module.global_expressions,
expression_kind_tracker: global_expression_kind_tracker,
}
}
/// Return a [`ConstantEvaluator`] that will add expressions to `function`'s
/// expression arena.
///
/// Report errors according to WGSL's rules for constant evaluation.
pub fn for_wgsl_function(
module: &'a mut crate::Module,
expressions: &'a mut Arena<Expression>,
local_expression_kind_tracker: &'a mut ExpressionKindTracker,
emitter: &'a mut super::Emitter,
block: &'a mut crate::Block,
is_const: bool,
) -> Self {
let local_data = FunctionLocalData {
global_expressions: &module.global_expressions,
emitter,
block,
};
Self {
behavior: Behavior::Wgsl(if is_const {
WgslRestrictions::Const(Some(local_data))
} else {
WgslRestrictions::Runtime(local_data)
}),
types: &mut module.types,
constants: &module.constants,
overrides: &module.overrides,
expressions,
expression_kind_tracker: local_expression_kind_tracker,
}
}
/// Return a [`ConstantEvaluator`] that will add expressions to `function`'s
/// expression arena.
///
/// Report errors according to GLSL's rules for constant evaluation.
pub fn for_glsl_function(
module: &'a mut crate::Module,
expressions: &'a mut Arena<Expression>,
local_expression_kind_tracker: &'a mut ExpressionKindTracker,
emitter: &'a mut super::Emitter,
block: &'a mut crate::Block,
) -> Self {
Self {
behavior: Behavior::Glsl(GlslRestrictions::Runtime(FunctionLocalData {
global_expressions: &module.global_expressions,
emitter,
block,
})),
types: &mut module.types,
constants: &module.constants,
overrides: &module.overrides,
expressions,
expression_kind_tracker: local_expression_kind_tracker,
}
}
pub fn to_ctx(&self) -> crate::proc::GlobalCtx {
crate::proc::GlobalCtx {
types: self.types,
constants: self.constants,
overrides: self.overrides,
global_expressions: match self.function_local_data() {
Some(data) => data.global_expressions,
None => self.expressions,
},
}
}
fn check(&self, expr: Handle<Expression>) -> Result<(), ConstantEvaluatorError> {
if !self.expression_kind_tracker.is_const(expr) {
log::debug!("check: SubexpressionsAreNotConstant");
return Err(ConstantEvaluatorError::SubexpressionsAreNotConstant);
}
Ok(())
}
fn check_and_get(
&mut self,
expr: Handle<Expression>,
) -> Result<Handle<Expression>, ConstantEvaluatorError> {
match self.expressions[expr] {
Expression::Constant(c) => {
// Are we working in a function's expression arena, or the
// module's constant expression arena?
if let Some(function_local_data) = self.function_local_data() {
// Deep-copy the constant's value into our arena.
self.copy_from(
self.constants[c].init,
function_local_data.global_expressions,
)
} else {
// "See through" the constant and use its initializer.
Ok(self.constants[c].init)
}
}
_ => {
self.check(expr)?;
Ok(expr)
}
}
}
/// Try to evaluate `expr` at compile time.
///
/// The `expr` argument can be any sort of Naga [`Expression`] you like. If
/// we can determine its value at compile time, we append an expression
/// representing its value - a tree of [`Literal`], [`Compose`],
/// [`ZeroValue`], and [`Swizzle`] expressions - to the expression arena
/// `self` contributes to.
///
/// If `expr`'s value cannot be determined at compile time, and `self` is
/// contributing to some function's expression arena, then append `expr` to
/// that arena unchanged (and thus unevaluated). Otherwise, `self` must be
/// contributing to the module's constant expression arena; since `expr`'s
/// value is not a constant, return an error.
///
/// We only consider `expr` itself, without recursing into its operands. Its
/// operands must all have been produced by prior calls to
/// `try_eval_and_append`, to ensure that they have already been reduced to
/// an evaluated form if possible.
///
/// [`Literal`]: Expression::Literal
/// [`Compose`]: Expression::Compose
/// [`ZeroValue`]: Expression::ZeroValue
/// [`Swizzle`]: Expression::Swizzle
pub fn try_eval_and_append(
&mut self,
expr: Expression,
span: Span,
) -> Result<Handle<Expression>, ConstantEvaluatorError> {
match self.expression_kind_tracker.type_of_with_expr(&expr) {
ExpressionKind::ImplConst => self.try_eval_and_append_impl(&expr, span),
ExpressionKind::Const => {
let eval_result = self.try_eval_and_append_impl(&expr, span);
// We should be able to evaluate `Const` expressions at this
// point. If we failed to, then that probably means we just
// haven't implemented that part of constant evaluation. Work
// around this by simply emitting it as a run-time expression.
if self.behavior.has_runtime_restrictions()
&& matches!(
eval_result,
Err(ConstantEvaluatorError::NotImplemented(_)
| ConstantEvaluatorError::InvalidBinaryOpArgs,)
)
{
Ok(self.append_expr(expr, span, ExpressionKind::Runtime))
} else {
eval_result
}
}
ExpressionKind::Override => match self.behavior {
Behavior::Wgsl(WgslRestrictions::Override | WgslRestrictions::Runtime(_)) => {
Ok(self.append_expr(expr, span, ExpressionKind::Override))
}
Behavior::Wgsl(WgslRestrictions::Const(_)) => {
Err(ConstantEvaluatorError::OverrideExpr)
}
Behavior::Glsl(_) => {
unreachable!()
}
},
ExpressionKind::Runtime => {
if self.behavior.has_runtime_restrictions() {
Ok(self.append_expr(expr, span, ExpressionKind::Runtime))
} else {
Err(ConstantEvaluatorError::RuntimeExpr)
}
}
}
}
/// Is the [`Self::expressions`] arena the global module expression arena?
const fn is_global_arena(&self) -> bool {
matches!(
self.behavior,
Behavior::Wgsl(WgslRestrictions::Const(None) | WgslRestrictions::Override)
| Behavior::Glsl(GlslRestrictions::Const)
)
}
const fn function_local_data(&self) -> Option<&FunctionLocalData<'a>> {
match self.behavior {
Behavior::Wgsl(
WgslRestrictions::Runtime(ref function_local_data)
| WgslRestrictions::Const(Some(ref function_local_data)),
)
| Behavior::Glsl(GlslRestrictions::Runtime(ref function_local_data)) => {
Some(function_local_data)
}
_ => None,
}
}
fn try_eval_and_append_impl(
&mut self,
expr: &Expression,
span: Span,
) -> Result<Handle<Expression>, ConstantEvaluatorError> {
log::trace!("try_eval_and_append: {:?}", expr);
match *expr {
Expression::Constant(c) if self.is_global_arena() => {
// "See through" the constant and use its initializer.
// This is mainly done to avoid having constants pointing to other constants.
Ok(self.constants[c].init)
}
Expression::Override(_) => Err(ConstantEvaluatorError::Override),
Expression::Literal(_) | Expression::ZeroValue(_) | Expression::Constant(_) => {
self.register_evaluated_expr(expr.clone(), span)
}
Expression::Compose { ty, ref components } => {
let components = components
.iter()
.map(|component| self.check_and_get(*component))
.collect::<Result<Vec<_>, _>>()?;
self.register_evaluated_expr(Expression::Compose { ty, components }, span)
}
Expression::Splat { size, value } => {
let value = self.check_and_get(value)?;
self.register_evaluated_expr(Expression::Splat { size, value }, span)
}
Expression::AccessIndex { base, index } => {
let base = self.check_and_get(base)?;
self.access(base, index as usize, span)
}
Expression::Access { base, index } => {
let base = self.check_and_get(base)?;
let index = self.check_and_get(index)?;
self.access(base, self.constant_index(index)?, span)
}
Expression::Swizzle {
size,
vector,
pattern,
} => {
let vector = self.check_and_get(vector)?;
self.swizzle(size, span, vector, pattern)
}
Expression::Unary { expr, op } => {
let expr = self.check_and_get(expr)?;
self.unary_op(op, expr, span)
}
Expression::Binary { left, right, op } => {
let left = self.check_and_get(left)?;
let right = self.check_and_get(right)?;
self.binary_op(op, left, right, span)
}
Expression::Math {
fun,
arg,
arg1,
arg2,
arg3,
} => {
let arg = self.check_and_get(arg)?;
let arg1 = arg1.map(|arg| self.check_and_get(arg)).transpose()?;
let arg2 = arg2.map(|arg| self.check_and_get(arg)).transpose()?;
let arg3 = arg3.map(|arg| self.check_and_get(arg)).transpose()?;
self.math(arg, arg1, arg2, arg3, fun, span)
}
Expression::As {
convert,
expr,
kind,
} => {
let expr = self.check_and_get(expr)?;
match convert {
Some(width) => self.cast(expr, crate::Scalar { kind, width }, span),
None => Err(ConstantEvaluatorError::NotImplemented(
"bitcast built-in function".into(),
)),
}
}
Expression::Select { .. } => Err(ConstantEvaluatorError::NotImplemented(
"select built-in function".into(),
)),
Expression::Relational { fun, .. } => Err(ConstantEvaluatorError::NotImplemented(
format!("{fun:?} built-in function"),
)),
Expression::ArrayLength(expr) => match self.behavior {
Behavior::Wgsl(_) => Err(ConstantEvaluatorError::ArrayLength),
Behavior::Glsl(_) => {
let expr = self.check_and_get(expr)?;
self.array_length(expr, span)
}
},
Expression::Load { .. } => Err(ConstantEvaluatorError::Load),
Expression::LocalVariable(_) => Err(ConstantEvaluatorError::LocalVariable),
Expression::Derivative { .. } => Err(ConstantEvaluatorError::Derivative),
Expression::CallResult { .. } => Err(ConstantEvaluatorError::Call),
Expression::WorkGroupUniformLoadResult { .. } => {
Err(ConstantEvaluatorError::WorkGroupUniformLoadResult)
}
Expression::AtomicResult { .. } => Err(ConstantEvaluatorError::Atomic),
Expression::FunctionArgument(_) => Err(ConstantEvaluatorError::FunctionArg),
Expression::GlobalVariable(_) => Err(ConstantEvaluatorError::GlobalVariable),
Expression::ImageSample { .. }
| Expression::ImageLoad { .. }
| Expression::ImageQuery { .. } => Err(ConstantEvaluatorError::ImageExpression),
Expression::RayQueryProceedResult | Expression::RayQueryGetIntersection { .. } => {
Err(ConstantEvaluatorError::RayQueryExpression)
}
Expression::SubgroupBallotResult { .. } => {
Err(ConstantEvaluatorError::SubgroupExpression)
}
Expression::SubgroupOperationResult { .. } => {
Err(ConstantEvaluatorError::SubgroupExpression)
}
}
}
/// Splat `value` to `size`, without using [`Splat`] expressions.
///
/// This constructs [`Compose`] or [`ZeroValue`] expressions to
/// build a vector with the given `size` whose components are all
/// `value`.
///
/// Use `span` as the span of the inserted expressions and
/// resulting types.
///
/// [`Splat`]: Expression::Splat
/// [`Compose`]: Expression::Compose
/// [`ZeroValue`]: Expression::ZeroValue
fn splat(
&mut self,
value: Handle<Expression>,
size: crate::VectorSize,
span: Span,
) -> Result<Handle<Expression>, ConstantEvaluatorError> {
match self.expressions[value] {
Expression::Literal(literal) => {
let scalar = literal.scalar();
let ty = self.types.insert(
Type {
name: None,
inner: TypeInner::Vector { size, scalar },
},
span,
);
let expr = Expression::Compose {
ty,
components: vec![value; size as usize],
};
self.register_evaluated_expr(expr, span)
}
Expression::ZeroValue(ty) => {
let inner = match self.types[ty].inner {
TypeInner::Scalar(scalar) => TypeInner::Vector { size, scalar },
_ => return Err(ConstantEvaluatorError::SplatScalarOnly),
};
let res_ty = self.types.insert(Type { name: None, inner }, span);
let expr = Expression::ZeroValue(res_ty);
self.register_evaluated_expr(expr, span)
}
_ => Err(ConstantEvaluatorError::SplatScalarOnly),
}
}
fn swizzle(
&mut self,
size: crate::VectorSize,
span: Span,
src_constant: Handle<Expression>,
pattern: [crate::SwizzleComponent; 4],
) -> Result<Handle<Expression>, ConstantEvaluatorError> {
let mut get_dst_ty = |ty| match self.types[ty].inner {
TypeInner::Vector { size: _, scalar } => Ok(self.types.insert(
Type {
name: None,
inner: TypeInner::Vector { size, scalar },
},
span,
)),
_ => Err(ConstantEvaluatorError::SwizzleVectorOnly),
};
match self.expressions[src_constant] {
Expression::ZeroValue(ty) => {
let dst_ty = get_dst_ty(ty)?;
let expr = Expression::ZeroValue(dst_ty);
self.register_evaluated_expr(expr, span)
}
Expression::Splat { value, .. } => {
let expr = Expression::Splat { size, value };
self.register_evaluated_expr(expr, span)
}
Expression::Compose { ty, ref components } => {
let dst_ty = get_dst_ty(ty)?;
let mut flattened = [src_constant; 4]; // dummy value
let len =
crate::proc::flatten_compose(ty, components, self.expressions, self.types)
.zip(flattened.iter_mut())
.map(|(component, elt)| *elt = component)
.count();
let flattened = &flattened[..len];
let swizzled_components = pattern[..size as usize]
.iter()
.map(|&sc| {
let sc = sc as usize;
if let Some(elt) = flattened.get(sc) {
Ok(*elt)
} else {
Err(ConstantEvaluatorError::SwizzleOutOfBounds)
}
})
.collect::<Result<Vec<Handle<Expression>>, _>>()?;
let expr = Expression::Compose {
ty: dst_ty,
components: swizzled_components,
};
self.register_evaluated_expr(expr, span)
}
_ => Err(ConstantEvaluatorError::SwizzleVectorOnly),
}
}
fn math(
&mut self,
arg: Handle<Expression>,
arg1: Option<Handle<Expression>>,
arg2: Option<Handle<Expression>>,
arg3: Option<Handle<Expression>>,
fun: crate::MathFunction,
span: Span,
) -> Result<Handle<Expression>, ConstantEvaluatorError> {
let expected = fun.argument_count();
let given = Some(arg)
.into_iter()
.chain(arg1)
.chain(arg2)
.chain(arg3)
.count();
if expected != given {
return Err(ConstantEvaluatorError::InvalidMathArgCount(
fun, expected, given,
));
}
// NOTE: We try to match the declaration order of `MathFunction` here.
match fun {
// comparison
crate::MathFunction::Abs => {
component_wise_scalar(self, span, [arg], |args| match args {
Scalar::AbstractFloat([e]) => Ok(Scalar::AbstractFloat([e.abs()])),
Scalar::F32([e]) => Ok(Scalar::F32([e.abs()])),
Scalar::AbstractInt([e]) => Ok(Scalar::AbstractInt([e.abs()])),
Scalar::I32([e]) => Ok(Scalar::I32([e.wrapping_abs()])),
Scalar::U32([e]) => Ok(Scalar::U32([e])), // TODO: just re-use the expression, ezpz
Scalar::I64([e]) => Ok(Scalar::I64([e.wrapping_abs()])),
Scalar::U64([e]) => Ok(Scalar::U64([e])),
})
}
crate::MathFunction::Min => {
component_wise_scalar!(self, span, [arg, arg1.unwrap()], |e1, e2| {
Ok([e1.min(e2)])
})
}
crate::MathFunction::Max => {
component_wise_scalar!(self, span, [arg, arg1.unwrap()], |e1, e2| {
Ok([e1.max(e2)])
})
}
crate::MathFunction::Clamp => {
component_wise_scalar!(
self,
span,
[arg, arg1.unwrap(), arg2.unwrap()],
|e, low, high| {
if low > high {
Err(ConstantEvaluatorError::InvalidClamp)
} else {
Ok([e.clamp(low, high)])
}
}
)
}
crate::MathFunction::Saturate => {
component_wise_float!(self, span, [arg], |e| { Ok([e.clamp(0., 1.)]) })
}
// trigonometry
crate::MathFunction::Cos => {
component_wise_float!(self, span, [arg], |e| { Ok([e.cos()]) })
}
crate::MathFunction::Cosh => {
component_wise_float!(self, span, [arg], |e| { Ok([e.cosh()]) })
}
crate::MathFunction::Sin => {
component_wise_float!(self, span, [arg], |e| { Ok([e.sin()]) })
}
crate::MathFunction::Sinh => {
component_wise_float!(self, span, [arg], |e| { Ok([e.sinh()]) })
}
crate::MathFunction::Tan => {
component_wise_float!(self, span, [arg], |e| { Ok([e.tan()]) })
}
crate::MathFunction::Tanh => {
component_wise_float!(self, span, [arg], |e| { Ok([e.tanh()]) })
}
crate::MathFunction::Acos => {
component_wise_float!(self, span, [arg], |e| { Ok([e.acos()]) })
}
crate::MathFunction::Asin => {
component_wise_float!(self, span, [arg], |e| { Ok([e.asin()]) })
}
crate::MathFunction::Atan => {
component_wise_float!(self, span, [arg], |e| { Ok([e.atan()]) })
}
crate::MathFunction::Asinh => {
component_wise_float!(self, span, [arg], |e| { Ok([e.asinh()]) })
}
crate::MathFunction::Acosh => {
component_wise_float!(self, span, [arg], |e| { Ok([e.acosh()]) })
}
crate::MathFunction::Atanh => {
component_wise_float!(self, span, [arg], |e| { Ok([e.atanh()]) })
}
crate::MathFunction::Radians => {
component_wise_float!(self, span, [arg], |e1| { Ok([e1.to_radians()]) })
}
crate::MathFunction::Degrees => {
component_wise_float!(self, span, [arg], |e| { Ok([e.to_degrees()]) })
}
// decomposition
crate::MathFunction::Ceil => {
component_wise_float!(self, span, [arg], |e| { Ok([e.ceil()]) })
}
crate::MathFunction::Floor => {
component_wise_float!(self, span, [arg], |e| { Ok([e.floor()]) })
}
crate::MathFunction::Round => {
// TODO: this hit stable on 1.77, but MSRV hasn't caught up yet
// This polyfill is shamelessly [~~stolen from~~ inspired by `ndarray-image`][polyfill source],
// which has licensing compatible with ours. See also
//
// [polyfill source]: https://github.com/imeka/ndarray-ndimage/blob/8b14b4d6ecfbc96a8a052f802e342a7049c68d8f/src/lib.rs#L98
fn round_ties_even(x: f64) -> f64 {
let i = x as i64;
let f = (x - i as f64).abs();
if f == 0.5 {
if i & 1 == 1 {
// -1.5, 1.5, 3.5, ...
(x.abs() + 0.5).copysign(x)
} else {
(x.abs() - 0.5).copysign(x)
}
} else {
x.round()
}
}
component_wise_float(self, span, [arg], |e| match e {
Float::Abstract([e]) => Ok(Float::Abstract([round_ties_even(e)])),
Float::F32([e]) => Ok(Float::F32([(round_ties_even(e as f64) as f32)])),
})
}
crate::MathFunction::Fract => {
component_wise_float!(self, span, [arg], |e| {
// N.B., Rust's definition of `fract` is `e - e.trunc()`, so we can't use that
// here.
Ok([e - e.floor()])
})
}
crate::MathFunction::Trunc => {
component_wise_float!(self, span, [arg], |e| { Ok([e.trunc()]) })
}
// exponent
crate::MathFunction::Exp => {
component_wise_float!(self, span, [arg], |e| { Ok([e.exp()]) })
}
crate::MathFunction::Exp2 => {
component_wise_float!(self, span, [arg], |e| { Ok([e.exp2()]) })
}
crate::MathFunction::Log => {
component_wise_float!(self, span, [arg], |e| { Ok([e.ln()]) })
}
crate::MathFunction::Log2 => {
component_wise_float!(self, span, [arg], |e| { Ok([e.log2()]) })
}
crate::MathFunction::Pow => {
component_wise_float!(self, span, [arg, arg1.unwrap()], |e1, e2| {
Ok([e1.powf(e2)])
})
}
// computational
crate::MathFunction::Sign => {
component_wise_signed!(self, span, [arg], |e| { Ok([e.signum()]) })
}
crate::MathFunction::Fma => {
component_wise_float!(
self,
span,
[arg, arg1.unwrap(), arg2.unwrap()],
|e1, e2, e3| { Ok([e1.mul_add(e2, e3)]) }
)
}
crate::MathFunction::Step => {
component_wise_float!(self, span, [arg, arg1.unwrap()], |edge, x| {
Ok([if edge <= x { 1.0 } else { 0.0 }])
})
}
crate::MathFunction::Sqrt => {
component_wise_float!(self, span, [arg], |e| { Ok([e.sqrt()]) })
}
crate::MathFunction::InverseSqrt => {
component_wise_float!(self, span, [arg], |e| { Ok([1. / e.sqrt()]) })
}
// bits
crate::MathFunction::CountTrailingZeros => {
component_wise_concrete_int!(self, span, [arg], |e| {
#[allow(clippy::useless_conversion)]
Ok([e
.trailing_zeros()
.try_into()
.expect("bit count overflowed 32 bits, somehow!?")])
})
}
crate::MathFunction::CountLeadingZeros => {
component_wise_concrete_int!(self, span, [arg], |e| {
#[allow(clippy::useless_conversion)]
Ok([e
.leading_zeros()
.try_into()
.expect("bit count overflowed 32 bits, somehow!?")])
})
}
crate::MathFunction::CountOneBits => {
component_wise_concrete_int!(self, span, [arg], |e| {
#[allow(clippy::useless_conversion)]
Ok([e
.count_ones()
.try_into()
.expect("bit count overflowed 32 bits, somehow!?")])
})
}
crate::MathFunction::ReverseBits => {
component_wise_concrete_int!(self, span, [arg], |e| { Ok([e.reverse_bits()]) })
}
crate::MathFunction::FirstTrailingBit => {
component_wise_concrete_int(self, span, [arg], |ci| Ok(first_trailing_bit(ci)))
}
crate::MathFunction::FirstLeadingBit => {
component_wise_concrete_int(self, span, [arg], |ci| Ok(first_leading_bit(ci)))
}
fun => Err(ConstantEvaluatorError::NotImplemented(format!(
"{fun:?} built-in function"
))),
}
}
fn array_length(
&mut self,
array: Handle<Expression>,
span: Span,
) -> Result<Handle<Expression>, ConstantEvaluatorError> {
match self.expressions[array] {
Expression::ZeroValue(ty) | Expression::Compose { ty, .. } => {
match self.types[ty].inner {
TypeInner::Array { size, .. } => match size {
ArraySize::Constant(len) => {
let expr = Expression::Literal(Literal::U32(len.get()));
self.register_evaluated_expr(expr, span)
}
ArraySize::Dynamic => Err(ConstantEvaluatorError::ArrayLengthDynamic),
},
_ => Err(ConstantEvaluatorError::InvalidArrayLengthArg),
}
}
_ => Err(ConstantEvaluatorError::InvalidArrayLengthArg),
}
}
fn access(
&mut self,
base: Handle<Expression>,
index: usize,
span: Span,
) -> Result<Handle<Expression>, ConstantEvaluatorError> {
match self.expressions[base] {
Expression::ZeroValue(ty) => {
let ty_inner = &self.types[ty].inner;
let components = ty_inner
.components()
.ok_or(ConstantEvaluatorError::InvalidAccessBase)?;
if index >= components as usize {
Err(ConstantEvaluatorError::InvalidAccessBase)
} else {
let ty_res = ty_inner
.component_type(index)
.ok_or(ConstantEvaluatorError::InvalidAccessIndex)?;
let ty = match ty_res {
crate::proc::TypeResolution::Handle(ty) => ty,
crate::proc::TypeResolution::Value(inner) => {
self.types.insert(Type { name: None, inner }, span)
}
};
self.register_evaluated_expr(Expression::ZeroValue(ty), span)
}
}
Expression::Splat { size, value } => {
if index >= size as usize {
Err(ConstantEvaluatorError::InvalidAccessBase)
} else {
Ok(value)
}
}
Expression::Compose { ty, ref components } => {
let _ = self.types[ty]
.inner
.components()
.ok_or(ConstantEvaluatorError::InvalidAccessBase)?;
crate::proc::flatten_compose(ty, components, self.expressions, self.types)
.nth(index)
.ok_or(ConstantEvaluatorError::InvalidAccessIndex)
}
_ => Err(ConstantEvaluatorError::InvalidAccessBase),
}
}
fn constant_index(&self, expr: Handle<Expression>) -> Result<usize, ConstantEvaluatorError> {
match self.expressions[expr] {
Expression::ZeroValue(ty)
if matches!(
self.types[ty].inner,
TypeInner::Scalar(crate::Scalar {
kind: ScalarKind::Uint,
..
})
) =>
{
Ok(0)
}
Expression::Literal(Literal::U32(index)) => Ok(index as usize),
_ => Err(ConstantEvaluatorError::InvalidAccessIndexTy),
}
}
/// Lower [`ZeroValue`] and [`Splat`] expressions to [`Literal`] and [`Compose`] expressions.
///
/// [`ZeroValue`]: Expression::ZeroValue
/// [`Splat`]: Expression::Splat
/// [`Literal`]: Expression::Literal
/// [`Compose`]: Expression::Compose
fn eval_zero_value_and_splat(
&mut self,
expr: Handle<Expression>,
span: Span,
) -> Result<Handle<Expression>, ConstantEvaluatorError> {
match self.expressions[expr] {
Expression::ZeroValue(ty) => self.eval_zero_value_impl(ty, span),
Expression::Splat { size, value } => self.splat(value, size, span),
_ => Ok(expr),
}
}
/// Lower [`ZeroValue`] expressions to [`Literal`] and [`Compose`] expressions.
///
/// [`ZeroValue`]: Expression::ZeroValue
/// [`Literal`]: Expression::Literal
/// [`Compose`]: Expression::Compose
fn eval_zero_value(
&mut self,
expr: Handle<Expression>,
span: Span,
) -> Result<Handle<Expression>, ConstantEvaluatorError> {
match self.expressions[expr] {
Expression::ZeroValue(ty) => self.eval_zero_value_impl(ty, span),
_ => Ok(expr),
}
}
/// Lower [`ZeroValue`] expressions to [`Literal`] and [`Compose`] expressions.
///
/// [`ZeroValue`]: Expression::ZeroValue
/// [`Literal`]: Expression::Literal
/// [`Compose`]: Expression::Compose
fn eval_zero_value_impl(
&mut self,
ty: Handle<Type>,
span: Span,
) -> Result<Handle<Expression>, ConstantEvaluatorError> {
match self.types[ty].inner {
TypeInner::Scalar(scalar) => {
let expr = Expression::Literal(
Literal::zero(scalar).ok_or(ConstantEvaluatorError::TypeNotConstructible)?,
);
self.register_evaluated_expr(expr, span)
}
TypeInner::Vector { size, scalar } => {
let scalar_ty = self.types.insert(
Type {
name: None,
inner: TypeInner::Scalar(scalar),
},
span,
);
let el = self.eval_zero_value_impl(scalar_ty, span)?;
let expr = Expression::Compose {
ty,
components: vec![el; size as usize],
};
self.register_evaluated_expr(expr, span)
}
TypeInner::Matrix {
columns,
rows,
scalar,
} => {
let vec_ty = self.types.insert(
Type {
name: None,
inner: TypeInner::Vector { size: rows, scalar },
},
span,
);
let el = self.eval_zero_value_impl(vec_ty, span)?;
let expr = Expression::Compose {
ty,
components: vec![el; columns as usize],
};
self.register_evaluated_expr(expr, span)
}
TypeInner::Array {
base,
size: ArraySize::Constant(size),
..
} => {
let el = self.eval_zero_value_impl(base, span)?;
let expr = Expression::Compose {
ty,
components: vec![el; size.get() as usize],
};
self.register_evaluated_expr(expr, span)
}
TypeInner::Struct { ref members, .. } => {
let types: Vec<_> = members.iter().map(|m| m.ty).collect();
let mut components = Vec::with_capacity(members.len());
for ty in types {
components.push(self.eval_zero_value_impl(ty, span)?);
}
let expr = Expression::Compose { ty, components };
self.register_evaluated_expr(expr, span)
}
_ => Err(ConstantEvaluatorError::TypeNotConstructible),
}
}
/// Convert the scalar components of `expr` to `target`.
///
/// Treat `span` as the location of the resulting expression.
pub fn cast(
&mut self,
expr: Handle<Expression>,
target: crate::Scalar,
span: Span,
) -> Result<Handle<Expression>, ConstantEvaluatorError> {
use crate::Scalar as Sc;
let expr = self.eval_zero_value(expr, span)?;
let make_error = || -> Result<_, ConstantEvaluatorError> {
let from = format!("{:?} {:?}", expr, self.expressions[expr]);
#[cfg(feature = "wgsl-in")]
let to = target.to_wgsl();
#[cfg(not(feature = "wgsl-in"))]
let to = format!("{target:?}");
Err(ConstantEvaluatorError::InvalidCastArg { from, to })
};
let expr = match self.expressions[expr] {
Expression::Literal(literal) => {
let literal = match target {
Sc::I32 => Literal::I32(match literal {
Literal::I32(v) => v,
Literal::U32(v) => v as i32,
Literal::F32(v) => v as i32,
Literal::Bool(v) => v as i32,
Literal::F64(_) | Literal::I64(_) | Literal::U64(_) => {
return make_error();
}
Literal::AbstractInt(v) => i32::try_from_abstract(v)?,
Literal::AbstractFloat(v) => i32::try_from_abstract(v)?,
}),
Sc::U32 => Literal::U32(match literal {
Literal::I32(v) => v as u32,
Literal::U32(v) => v,
Literal::F32(v) => v as u32,
Literal::Bool(v) => v as u32,
Literal::F64(_) | Literal::I64(_) | Literal::U64(_) => {
return make_error();
}
Literal::AbstractInt(v) => u32::try_from_abstract(v)?,
Literal::AbstractFloat(v) => u32::try_from_abstract(v)?,
}),
Sc::I64 => Literal::I64(match literal {
Literal::I32(v) => v as i64,
Literal::U32(v) => v as i64,
Literal::F32(v) => v as i64,
Literal::Bool(v) => v as i64,
Literal::F64(v) => v as i64,
Literal::I64(v) => v,
Literal::U64(v) => v as i64,
Literal::AbstractInt(v) => i64::try_from_abstract(v)?,
Literal::AbstractFloat(v) => i64::try_from_abstract(v)?,
}),
Sc::U64 => Literal::U64(match literal {
Literal::I32(v) => v as u64,
Literal::U32(v) => v as u64,
Literal::F32(v) => v as u64,
Literal::Bool(v) => v as u64,
Literal::F64(v) => v as u64,
Literal::I64(v) => v as u64,
Literal::U64(v) => v,
Literal::AbstractInt(v) => u64::try_from_abstract(v)?,
Literal::AbstractFloat(v) => u64::try_from_abstract(v)?,
}),
Sc::F32 => Literal::F32(match literal {
Literal::I32(v) => v as f32,
Literal::U32(v) => v as f32,
Literal::F32(v) => v,
Literal::Bool(v) => v as u32 as f32,
Literal::F64(_) | Literal::I64(_) | Literal::U64(_) => {
return make_error();
}
Literal::AbstractInt(v) => f32::try_from_abstract(v)?,
Literal::AbstractFloat(v) => f32::try_from_abstract(v)?,
}),
Sc::F64 => Literal::F64(match literal {
Literal::I32(v) => v as f64,
Literal::U32(v) => v as f64,
Literal::F32(v) => v as f64,
Literal::F64(v) => v,
Literal::Bool(v) => v as u32 as f64,
Literal::I64(_) | Literal::U64(_) => return make_error(),
Literal::AbstractInt(v) => f64::try_from_abstract(v)?,
Literal::AbstractFloat(v) => f64::try_from_abstract(v)?,
}),
Sc::BOOL => Literal::Bool(match literal {
Literal::I32(v) => v != 0,
Literal::U32(v) => v != 0,
Literal::F32(v) => v != 0.0,
Literal::Bool(v) => v,
Literal::F64(_)
| Literal::I64(_)
| Literal::U64(_)
| Literal::AbstractInt(_)
| Literal::AbstractFloat(_) => {
return make_error();
}
}),
Sc::ABSTRACT_FLOAT => Literal::AbstractFloat(match literal {
Literal::AbstractInt(v) => {
// Overflow is forbidden, but inexact conversions
// are fine. The range of f64 is far larger than
// that of i64, so we don't have to check anything
// here.
v as f64
}
Literal::AbstractFloat(v) => v,
_ => return make_error(),
}),
_ => {
log::debug!("Constant evaluator refused to convert value to {target:?}");
return make_error();
}
};
Expression::Literal(literal)
}
Expression::Compose {
ty,
components: ref src_components,
} => {
let ty_inner = match self.types[ty].inner {
TypeInner::Vector { size, .. } => TypeInner::Vector {
size,
scalar: target,
},
TypeInner::Matrix { columns, rows, .. } => TypeInner::Matrix {
columns,
rows,
scalar: target,
},
_ => return make_error(),
};
let mut components = src_components.clone();
for component in &mut components {
*component = self.cast(*component, target, span)?;
}
let ty = self.types.insert(
Type {
name: None,
inner: ty_inner,
},
span,
);
Expression::Compose { ty, components }
}
Expression::Splat { size, value } => {
let value_span = self.expressions.get_span(value);
let cast_value = self.cast(value, target, value_span)?;
Expression::Splat {
size,
value: cast_value,
}
}
_ => return make_error(),
};
self.register_evaluated_expr(expr, span)
}
/// Convert the scalar leaves of `expr` to `target`, handling arrays.
///
/// `expr` must be a `Compose` expression whose type is a scalar, vector,
/// matrix, or nested arrays of such.
///
/// This is basically the same as the [`cast`] method, except that that
/// should only handle Naga [`As`] expressions, which cannot convert arrays.
///
/// Treat `span` as the location of the resulting expression.
///
/// [`cast`]: ConstantEvaluator::cast
/// [`As`]: crate::Expression::As
pub fn cast_array(
&mut self,
expr: Handle<Expression>,
target: crate::Scalar,
span: Span,
) -> Result<Handle<Expression>, ConstantEvaluatorError> {
let Expression::Compose { ty, ref components } = self.expressions[expr] else {
return self.cast(expr, target, span);
};
let TypeInner::Array {
base: _,
size,
stride: _,
} = self.types[ty].inner
else {
return self.cast(expr, target, span);
};
let mut components = components.clone();
for component in &mut components {
*component = self.cast_array(*component, target, span)?;
}
let first = components.first().unwrap();
let new_base = match self.resolve_type(*first)? {
crate::proc::TypeResolution::Handle(ty) => ty,
crate::proc::TypeResolution::Value(inner) => {
self.types.insert(Type { name: None, inner }, span)
}
};
let new_base_stride = self.types[new_base].inner.size(self.to_ctx());
let new_array_ty = self.types.insert(
Type {
name: None,
inner: TypeInner::Array {
base: new_base,
size,
stride: new_base_stride,
},
},
span,
);
let compose = Expression::Compose {
ty: new_array_ty,
components,
};
self.register_evaluated_expr(compose, span)
}
fn unary_op(
&mut self,
op: UnaryOperator,
expr: Handle<Expression>,
span: Span,
) -> Result<Handle<Expression>, ConstantEvaluatorError> {
let expr = self.eval_zero_value_and_splat(expr, span)?;
let expr = match self.expressions[expr] {
Expression::Literal(value) => Expression::Literal(match op {
UnaryOperator::Negate => match value {
Literal::I32(v) => Literal::I32(v.wrapping_neg()),
Literal::F32(v) => Literal::F32(-v),
Literal::AbstractInt(v) => Literal::AbstractInt(v.wrapping_neg()),
Literal::AbstractFloat(v) => Literal::AbstractFloat(-v),
_ => return Err(ConstantEvaluatorError::InvalidUnaryOpArg),
},
UnaryOperator::LogicalNot => match value {
Literal::Bool(v) => Literal::Bool(!v),
_ => return Err(ConstantEvaluatorError::InvalidUnaryOpArg),
},
UnaryOperator::BitwiseNot => match value {
Literal::I32(v) => Literal::I32(!v),
Literal::U32(v) => Literal::U32(!v),
Literal::AbstractInt(v) => Literal::AbstractInt(!v),
_ => return Err(ConstantEvaluatorError::InvalidUnaryOpArg),
},
}),
Expression::Compose {
ty,
components: ref src_components,
} => {
match self.types[ty].inner {
TypeInner::Vector { .. } | TypeInner::Matrix { .. } => (),
_ => return Err(ConstantEvaluatorError::InvalidUnaryOpArg),
}
let mut components = src_components.clone();
for component in &mut components {
*component = self.unary_op(op, *component, span)?;
}
Expression::Compose { ty, components }
}
_ => return Err(ConstantEvaluatorError::InvalidUnaryOpArg),
};
self.register_evaluated_expr(expr, span)
}
fn binary_op(
&mut self,
op: BinaryOperator,
left: Handle<Expression>,
right: Handle<Expression>,
span: Span,
) -> Result<Handle<Expression>, ConstantEvaluatorError> {
let left = self.eval_zero_value_and_splat(left, span)?;
let right = self.eval_zero_value_and_splat(right, span)?;
let expr = match (&self.expressions[left], &self.expressions[right]) {
(&Expression::Literal(left_value), &Expression::Literal(right_value)) => {
let literal = match op {
BinaryOperator::Equal => Literal::Bool(left_value == right_value),
BinaryOperator::NotEqual => Literal::Bool(left_value != right_value),
BinaryOperator::Less => Literal::Bool(left_value < right_value),
BinaryOperator::LessEqual => Literal::Bool(left_value <= right_value),
BinaryOperator::Greater => Literal::Bool(left_value > right_value),
BinaryOperator::GreaterEqual => Literal::Bool(left_value >= right_value),
_ => match (left_value, right_value) {
(Literal::I32(a), Literal::I32(b)) => Literal::I32(match op {
BinaryOperator::Add => a.checked_add(b).ok_or_else(|| {
ConstantEvaluatorError::Overflow("addition".into())
})?,
BinaryOperator::Subtract => a.checked_sub(b).ok_or_else(|| {
ConstantEvaluatorError::Overflow("subtraction".into())
})?,
BinaryOperator::Multiply => a.checked_mul(b).ok_or_else(|| {
ConstantEvaluatorError::Overflow("multiplication".into())
})?,
BinaryOperator::Divide => a.checked_div(b).ok_or_else(|| {
if b == 0 {
ConstantEvaluatorError::DivisionByZero
} else {
ConstantEvaluatorError::Overflow("division".into())
}
})?,
BinaryOperator::Modulo => a.checked_rem(b).ok_or_else(|| {
if b == 0 {
ConstantEvaluatorError::RemainderByZero
} else {
ConstantEvaluatorError::Overflow("remainder".into())
}
})?,
BinaryOperator::And => a & b,
BinaryOperator::ExclusiveOr => a ^ b,
BinaryOperator::InclusiveOr => a | b,
_ => return Err(ConstantEvaluatorError::InvalidBinaryOpArgs),
}),
(Literal::I32(a), Literal::U32(b)) => Literal::I32(match op {
BinaryOperator::ShiftLeft => {
if (if a.is_negative() { !a } else { a }).leading_zeros() <= b {
return Err(ConstantEvaluatorError::Overflow("<<".to_string()));
}
a.checked_shl(b)
.ok_or(ConstantEvaluatorError::ShiftedMoreThan32Bits)?
}
BinaryOperator::ShiftRight => a
.checked_shr(b)
.ok_or(ConstantEvaluatorError::ShiftedMoreThan32Bits)?,
_ => return Err(ConstantEvaluatorError::InvalidBinaryOpArgs),
}),
(Literal::U32(a), Literal::U32(b)) => Literal::U32(match op {
BinaryOperator::Add => a.checked_add(b).ok_or_else(|| {
ConstantEvaluatorError::Overflow("addition".into())
})?,
BinaryOperator::Subtract => a.checked_sub(b).ok_or_else(|| {
ConstantEvaluatorError::Overflow("subtraction".into())
})?,
BinaryOperator::Multiply => a.checked_mul(b).ok_or_else(|| {
ConstantEvaluatorError::Overflow("multiplication".into())
})?,
BinaryOperator::Divide => a
.checked_div(b)
.ok_or(ConstantEvaluatorError::DivisionByZero)?,
BinaryOperator::Modulo => a
.checked_rem(b)
.ok_or(ConstantEvaluatorError::RemainderByZero)?,
BinaryOperator::And => a & b,
BinaryOperator::ExclusiveOr => a ^ b,
BinaryOperator::InclusiveOr => a | b,
BinaryOperator::ShiftLeft => a
.checked_mul(
1u32.checked_shl(b)
.ok_or(ConstantEvaluatorError::ShiftedMoreThan32Bits)?,
)
.ok_or(ConstantEvaluatorError::Overflow("<<".to_string()))?,
BinaryOperator::ShiftRight => a
.checked_shr(b)
.ok_or(ConstantEvaluatorError::ShiftedMoreThan32Bits)?,
_ => return Err(ConstantEvaluatorError::InvalidBinaryOpArgs),
}),
(Literal::F32(a), Literal::F32(b)) => Literal::F32(match op {
BinaryOperator::Add => a + b,
BinaryOperator::Subtract => a - b,
BinaryOperator::Multiply => a * b,
BinaryOperator::Divide => a / b,
BinaryOperator::Modulo => a % b,
_ => return Err(ConstantEvaluatorError::InvalidBinaryOpArgs),
}),
(Literal::AbstractInt(a), Literal::AbstractInt(b)) => {
Literal::AbstractInt(match op {
BinaryOperator::Add => a.checked_add(b).ok_or_else(|| {
ConstantEvaluatorError::Overflow("addition".into())
})?,
BinaryOperator::Subtract => a.checked_sub(b).ok_or_else(|| {
ConstantEvaluatorError::Overflow("subtraction".into())
})?,
BinaryOperator::Multiply => a.checked_mul(b).ok_or_else(|| {
ConstantEvaluatorError::Overflow("multiplication".into())
})?,
BinaryOperator::Divide => a.checked_div(b).ok_or_else(|| {
if b == 0 {
ConstantEvaluatorError::DivisionByZero
} else {
ConstantEvaluatorError::Overflow("division".into())
}
})?,
BinaryOperator::Modulo => a.checked_rem(b).ok_or_else(|| {
if b == 0 {
ConstantEvaluatorError::RemainderByZero
} else {
ConstantEvaluatorError::Overflow("remainder".into())
}
})?,
BinaryOperator::And => a & b,
BinaryOperator::ExclusiveOr => a ^ b,
BinaryOperator::InclusiveOr => a | b,
_ => return Err(ConstantEvaluatorError::InvalidBinaryOpArgs),
})
}
(Literal::AbstractFloat(a), Literal::AbstractFloat(b)) => {
Literal::AbstractFloat(match op {
BinaryOperator::Add => a + b,
BinaryOperator::Subtract => a - b,
BinaryOperator::Multiply => a * b,
BinaryOperator::Divide => a / b,
BinaryOperator::Modulo => a % b,
_ => return Err(ConstantEvaluatorError::InvalidBinaryOpArgs),
})
}
(Literal::Bool(a), Literal::Bool(b)) => Literal::Bool(match op {
BinaryOperator::LogicalAnd => a && b,
BinaryOperator::LogicalOr => a || b,
_ => return Err(ConstantEvaluatorError::InvalidBinaryOpArgs),
}),
_ => return Err(ConstantEvaluatorError::InvalidBinaryOpArgs),
},
};
Expression::Literal(literal)
}
(
&Expression::Compose {
components: ref src_components,
ty,
},
&Expression::Literal(_),
) => {
let mut components = src_components.clone();
for component in &mut components {
*component = self.binary_op(op, *component, right, span)?;
}
Expression::Compose { ty, components }
}
(
&Expression::Literal(_),
&Expression::Compose {
components: ref src_components,
ty,
},
) => {
let mut components = src_components.clone();
for component in &mut components {
*component = self.binary_op(op, left, *component, span)?;
}
Expression::Compose { ty, components }
}
(
&Expression::Compose {
components: ref left_components,
ty: left_ty,
},
&Expression::Compose {
components: ref right_components,
ty: right_ty,
},
) => {
// We have to make a copy of the component lists, because the
// call to `binary_op_vector` needs `&mut self`, but `self` owns
// the component lists.
let left_flattened = crate::proc::flatten_compose(
left_ty,
left_components,
self.expressions,
self.types,
);
let right_flattened = crate::proc::flatten_compose(
right_ty,
right_components,
self.expressions,
self.types,
);
// `flatten_compose` doesn't return an `ExactSizeIterator`, so
// make a reasonable guess of the capacity we'll need.
let mut flattened = Vec::with_capacity(left_components.len());
flattened.extend(left_flattened.zip(right_flattened));
match (&self.types[left_ty].inner, &self.types[right_ty].inner) {
(
&TypeInner::Vector {
size: left_size, ..
},
&TypeInner::Vector {
size: right_size, ..
},
) if left_size == right_size => {
self.binary_op_vector(op, left_size, &flattened, left_ty, span)?
}
_ => return Err(ConstantEvaluatorError::InvalidBinaryOpArgs),
}
}
_ => return Err(ConstantEvaluatorError::InvalidBinaryOpArgs),
};
self.register_evaluated_expr(expr, span)
}
fn binary_op_vector(
&mut self,
op: BinaryOperator,
size: crate::VectorSize,
components: &[(Handle<Expression>, Handle<Expression>)],
left_ty: Handle<Type>,
span: Span,
) -> Result<Expression, ConstantEvaluatorError> {
let ty = match op {
// Relational operators produce vectors of booleans.
BinaryOperator::Equal
| BinaryOperator::NotEqual
| BinaryOperator::Less
| BinaryOperator::LessEqual
| BinaryOperator::Greater
| BinaryOperator::GreaterEqual => self.types.insert(
Type {
name: None,
inner: TypeInner::Vector {
size,
scalar: crate::Scalar::BOOL,
},
},
span,
),
// Other operators produce the same type as their left
// operand.
BinaryOperator::Add
| BinaryOperator::Subtract
| BinaryOperator::Multiply
| BinaryOperator::Divide
| BinaryOperator::Modulo
| BinaryOperator::And
| BinaryOperator::ExclusiveOr
| BinaryOperator::InclusiveOr
| BinaryOperator::LogicalAnd
| BinaryOperator::LogicalOr
| BinaryOperator::ShiftLeft
| BinaryOperator::ShiftRight => left_ty,
};
let components = components
.iter()
.map(|&(left, right)| self.binary_op(op, left, right, span))
.collect::<Result<Vec<_>, _>>()?;
Ok(Expression::Compose { ty, components })
}
/// Deep copy `expr` from `expressions` into `self.expressions`.
///
/// Return the root of the new copy.
///
/// This is used when we're evaluating expressions in a function's
/// expression arena that refer to a constant: we need to copy the
/// constant's value into the function's arena so we can operate on it.
fn copy_from(
&mut self,
expr: Handle<Expression>,
expressions: &Arena<Expression>,
) -> Result<Handle<Expression>, ConstantEvaluatorError> {
let span = expressions.get_span(expr);
match expressions[expr] {
ref expr @ (Expression::Literal(_)
| Expression::Constant(_)
| Expression::ZeroValue(_)) => self.register_evaluated_expr(expr.clone(), span),
Expression::Compose { ty, ref components } => {
let mut components = components.clone();
for component in &mut components {
*component = self.copy_from(*component, expressions)?;
}
self.register_evaluated_expr(Expression::Compose { ty, components }, span)
}
Expression::Splat { size, value } => {
let value = self.copy_from(value, expressions)?;
self.register_evaluated_expr(Expression::Splat { size, value }, span)
}
_ => {
log::debug!("copy_from: SubexpressionsAreNotConstant");
Err(ConstantEvaluatorError::SubexpressionsAreNotConstant)
}
}
}
fn register_evaluated_expr(
&mut self,
expr: Expression,
span: Span,
) -> Result<Handle<Expression>, ConstantEvaluatorError> {
// It suffices to only check literals, since we only register one
// expression at a time, `Compose` expressions can only refer to other
// expressions, and `ZeroValue` expressions are always okay.
if let Expression::Literal(literal) = expr {
crate::valid::check_literal_value(literal)?;
}
Ok(self.append_expr(expr, span, ExpressionKind::Const))
}
fn append_expr(
&mut self,
expr: Expression,
span: Span,
expr_type: ExpressionKind,
) -> Handle<Expression> {
let h = match self.behavior {
Behavior::Wgsl(
WgslRestrictions::Runtime(ref mut function_local_data)
| WgslRestrictions::Const(Some(ref mut function_local_data)),
)
| Behavior::Glsl(GlslRestrictions::Runtime(ref mut function_local_data)) => {
let is_running = function_local_data.emitter.is_running();
let needs_pre_emit = expr.needs_pre_emit();
if is_running && needs_pre_emit {
function_local_data
.block
.extend(function_local_data.emitter.finish(self.expressions));
let h = self.expressions.append(expr, span);
function_local_data.emitter.start(self.expressions);
h
} else {
self.expressions.append(expr, span)
}
}
_ => self.expressions.append(expr, span),
};
self.expression_kind_tracker.insert(h, expr_type);
h
}
fn resolve_type(
&self,
expr: Handle<Expression>,
) -> Result<crate::proc::TypeResolution, ConstantEvaluatorError> {
use crate::proc::TypeResolution as Tr;
use crate::Expression as Ex;
let resolution = match self.expressions[expr] {
Ex::Literal(ref literal) => Tr::Value(literal.ty_inner()),
Ex::Constant(c) => Tr::Handle(self.constants[c].ty),
Ex::ZeroValue(ty) | Ex::Compose { ty, .. } => Tr::Handle(ty),
Ex::Splat { size, value } => {
let Tr::Value(TypeInner::Scalar(scalar)) = self.resolve_type(value)? else {
return Err(ConstantEvaluatorError::SplatScalarOnly);
};
Tr::Value(TypeInner::Vector { scalar, size })
}
_ => {
log::debug!("resolve_type: SubexpressionsAreNotConstant");
return Err(ConstantEvaluatorError::SubexpressionsAreNotConstant);
}
};
Ok(resolution)
}
}
fn first_trailing_bit(concrete_int: ConcreteInt<1>) -> ConcreteInt<1> {
// NOTE: Bit indices for this built-in start at 0 at the "right" (or LSB). For example, a value
// of 1 means the least significant bit is set. Therefore, an input of `0x[80 00…]` would
// return a right-to-left bit index of 0.
let trailing_zeros_to_bit_idx = |e: u32| -> u32 {
match e {
idx @ 0..=31 => idx,
32 => u32::MAX,
_ => unreachable!(),
}
};
match concrete_int {
ConcreteInt::U32([e]) => ConcreteInt::U32([trailing_zeros_to_bit_idx(e.trailing_zeros())]),
ConcreteInt::I32([e]) => {
ConcreteInt::I32([trailing_zeros_to_bit_idx(e.trailing_zeros()) as i32])
}
}
}
#[test]
fn first_trailing_bit_smoke() {
assert_eq!(
first_trailing_bit(ConcreteInt::I32([0])),
ConcreteInt::I32([-1])
);
assert_eq!(
first_trailing_bit(ConcreteInt::I32([1])),
ConcreteInt::I32([0])
);
assert_eq!(
first_trailing_bit(ConcreteInt::I32([2])),
ConcreteInt::I32([1])
);
assert_eq!(
first_trailing_bit(ConcreteInt::I32([-1])),
ConcreteInt::I32([0]),
);
assert_eq!(
first_trailing_bit(ConcreteInt::I32([i32::MIN])),
ConcreteInt::I32([31]),
);
assert_eq!(
first_trailing_bit(ConcreteInt::I32([i32::MAX])),
ConcreteInt::I32([0]),
);
for idx in 0..32 {
assert_eq!(
first_trailing_bit(ConcreteInt::I32([1 << idx])),
ConcreteInt::I32([idx])
)
}
assert_eq!(
first_trailing_bit(ConcreteInt::U32([0])),
ConcreteInt::U32([u32::MAX])
);
assert_eq!(
first_trailing_bit(ConcreteInt::U32([1])),
ConcreteInt::U32([0])
);
assert_eq!(
first_trailing_bit(ConcreteInt::U32([2])),
ConcreteInt::U32([1])
);
assert_eq!(
first_trailing_bit(ConcreteInt::U32([1 << 31])),
ConcreteInt::U32([31]),
);
assert_eq!(
first_trailing_bit(ConcreteInt::U32([u32::MAX])),
ConcreteInt::U32([0]),
);
for idx in 0..32 {
assert_eq!(
first_trailing_bit(ConcreteInt::U32([1 << idx])),
ConcreteInt::U32([idx])
)
}
}
fn first_leading_bit(concrete_int: ConcreteInt<1>) -> ConcreteInt<1> {
// NOTE: Bit indices for this built-in start at 0 at the "right" (or LSB). For example, 1 means
// the least significant bit is set. Therefore, an input of 1 would return a right-to-left bit
// index of 0.
let rtl_to_ltr_bit_idx = |e: u32| -> u32 {
match e {
idx @ 0..=31 => 31 - idx,
32 => u32::MAX,
_ => unreachable!(),
}
};
match concrete_int {
ConcreteInt::I32([e]) => ConcreteInt::I32([{
let rtl_bit_index = if e.is_negative() {
e.leading_ones()
} else {
e.leading_zeros()
};
rtl_to_ltr_bit_idx(rtl_bit_index) as i32
}]),
ConcreteInt::U32([e]) => ConcreteInt::U32([rtl_to_ltr_bit_idx(e.leading_zeros())]),
}
}
#[test]
fn first_leading_bit_smoke() {
assert_eq!(
first_leading_bit(ConcreteInt::I32([-1])),
ConcreteInt::I32([-1])
);
assert_eq!(
first_leading_bit(ConcreteInt::I32([0])),
ConcreteInt::I32([-1])
);
assert_eq!(
first_leading_bit(ConcreteInt::I32([1])),
ConcreteInt::I32([0])
);
assert_eq!(
first_leading_bit(ConcreteInt::I32([-2])),
ConcreteInt::I32([0])
);
assert_eq!(
first_leading_bit(ConcreteInt::I32([1234 + 4567])),
ConcreteInt::I32([12])
);
assert_eq!(
first_leading_bit(ConcreteInt::I32([i32::MAX])),
ConcreteInt::I32([30])
);
assert_eq!(
first_leading_bit(ConcreteInt::I32([i32::MIN])),
ConcreteInt::I32([30])
);
// NOTE: Ignore the sign bit, which is a separate (above) case.
for idx in 0..(32 - 1) {
assert_eq!(
first_leading_bit(ConcreteInt::I32([1 << idx])),
ConcreteInt::I32([idx])
);
}
for idx in 1..(32 - 1) {
assert_eq!(
first_leading_bit(ConcreteInt::I32([-(1 << idx)])),
ConcreteInt::I32([idx - 1])
);
}
assert_eq!(
first_leading_bit(ConcreteInt::U32([0])),
ConcreteInt::U32([u32::MAX])
);
assert_eq!(
first_leading_bit(ConcreteInt::U32([1])),
ConcreteInt::U32([0])
);
assert_eq!(
first_leading_bit(ConcreteInt::U32([u32::MAX])),
ConcreteInt::U32([31])
);
for idx in 0..32 {
assert_eq!(
first_leading_bit(ConcreteInt::U32([1 << idx])),
ConcreteInt::U32([idx])
)
}
}
/// Trait for conversions of abstract values to concrete types.
trait TryFromAbstract<T>: Sized {
/// Convert an abstract literal `value` to `Self`.
///
/// Since Naga's `AbstractInt` and `AbstractFloat` exist to support
/// WGSL, we follow WGSL's conversion rules here:
///
/// - WGSL §6.1.2. Conversion Rank says that automatic conversions
/// to integers are either lossless or an error.
///
/// - WGSL §14.6.4 Floating Point Conversion says that conversions
/// to floating point in constant expressions and override
/// expressions are errors if the value is out of range for the
/// destination type, but rounding is okay.
///
/// [`AbstractInt`]: crate::Literal::AbstractInt
/// [`Float`]: crate::Literal::Float
fn try_from_abstract(value: T) -> Result<Self, ConstantEvaluatorError>;
}
impl TryFromAbstract<i64> for i32 {
fn try_from_abstract(value: i64) -> Result<i32, ConstantEvaluatorError> {
i32::try_from(value).map_err(|_| ConstantEvaluatorError::AutomaticConversionLossy {
value: format!("{value:?}"),
to_type: "i32",
})
}
}
impl TryFromAbstract<i64> for u32 {
fn try_from_abstract(value: i64) -> Result<u32, ConstantEvaluatorError> {
u32::try_from(value).map_err(|_| ConstantEvaluatorError::AutomaticConversionLossy {
value: format!("{value:?}"),
to_type: "u32",
})
}
}
impl TryFromAbstract<i64> for u64 {
fn try_from_abstract(value: i64) -> Result<u64, ConstantEvaluatorError> {
u64::try_from(value).map_err(|_| ConstantEvaluatorError::AutomaticConversionLossy {
value: format!("{value:?}"),
to_type: "u64",
})
}
}
impl TryFromAbstract<i64> for i64 {
fn try_from_abstract(value: i64) -> Result<i64, ConstantEvaluatorError> {
Ok(value)
}
}
impl TryFromAbstract<i64> for f32 {
fn try_from_abstract(value: i64) -> Result<Self, ConstantEvaluatorError> {
let f = value as f32;
// The range of `i64` is roughly ±18 × 10¹⁸, whereas the range of
// `f32` is roughly ±3.4 × 10³⁸, so there's no opportunity for
// overflow here.
Ok(f)
}
}
impl TryFromAbstract<f64> for f32 {
fn try_from_abstract(value: f64) -> Result<f32, ConstantEvaluatorError> {
let f = value as f32;
if f.is_infinite() {
return Err(ConstantEvaluatorError::AutomaticConversionLossy {
value: format!("{value:?}"),
to_type: "f32",
});
}
Ok(f)
}
}
impl TryFromAbstract<i64> for f64 {
fn try_from_abstract(value: i64) -> Result<Self, ConstantEvaluatorError> {
let f = value as f64;
// The range of `i64` is roughly ±18 × 10¹⁸, whereas the range of
// `f64` is roughly ±1.8 × 10³⁰⁸, so there's no opportunity for
// overflow here.
Ok(f)
}
}
impl TryFromAbstract<f64> for f64 {
fn try_from_abstract(value: f64) -> Result<f64, ConstantEvaluatorError> {
Ok(value)
}
}
impl TryFromAbstract<f64> for i32 {
fn try_from_abstract(_: f64) -> Result<Self, ConstantEvaluatorError> {
Err(ConstantEvaluatorError::AutomaticConversionFloatToInt { to_type: "i32" })
}
}
impl TryFromAbstract<f64> for u32 {
fn try_from_abstract(_: f64) -> Result<Self, ConstantEvaluatorError> {
Err(ConstantEvaluatorError::AutomaticConversionFloatToInt { to_type: "u32" })
}
}
impl TryFromAbstract<f64> for i64 {
fn try_from_abstract(_: f64) -> Result<Self, ConstantEvaluatorError> {
Err(ConstantEvaluatorError::AutomaticConversionFloatToInt { to_type: "i64" })
}
}
impl TryFromAbstract<f64> for u64 {
fn try_from_abstract(_: f64) -> Result<Self, ConstantEvaluatorError> {
Err(ConstantEvaluatorError::AutomaticConversionFloatToInt { to_type: "u64" })
}
}
#[cfg(test)]
mod tests {
use std::vec;
use crate::{
Arena, Constant, Expression, Literal, ScalarKind, Type, TypeInner, UnaryOperator,
UniqueArena, VectorSize,
};
use super::{Behavior, ConstantEvaluator, ExpressionKindTracker, WgslRestrictions};
#[test]
fn unary_op() {
let mut types = UniqueArena::new();
let mut constants = Arena::new();
let overrides = Arena::new();
let mut global_expressions = Arena::new();
let scalar_ty = types.insert(
Type {
name: None,
inner: TypeInner::Scalar(crate::Scalar::I32),
},
Default::default(),
);
let vec_ty = types.insert(
Type {
name: None,
inner: TypeInner::Vector {
size: VectorSize::Bi,
scalar: crate::Scalar::I32,
},
},
Default::default(),
);
let h = constants.append(
Constant {
name: None,
ty: scalar_ty,
init: global_expressions
.append(Expression::Literal(Literal::I32(4)), Default::default()),
},
Default::default(),
);
let h1 = constants.append(
Constant {
name: None,
ty: scalar_ty,
init: global_expressions
.append(Expression::Literal(Literal::I32(8)), Default::default()),
},
Default::default(),
);
let vec_h = constants.append(
Constant {
name: None,
ty: vec_ty,
init: global_expressions.append(
Expression::Compose {
ty: vec_ty,
components: vec![constants[h].init, constants[h1].init],
},
Default::default(),
),
},
Default::default(),
);
let expr = global_expressions.append(Expression::Constant(h), Default::default());
let expr1 = global_expressions.append(Expression::Constant(vec_h), Default::default());
let expr2 = Expression::Unary {
op: UnaryOperator::Negate,
expr,
};
let expr3 = Expression::Unary {
op: UnaryOperator::BitwiseNot,
expr,
};
let expr4 = Expression::Unary {
op: UnaryOperator::BitwiseNot,
expr: expr1,
};
let expression_kind_tracker = &mut ExpressionKindTracker::from_arena(&global_expressions);
let mut solver = ConstantEvaluator {
behavior: Behavior::Wgsl(WgslRestrictions::Const(None)),
types: &mut types,
constants: &constants,
overrides: &overrides,
expressions: &mut global_expressions,
expression_kind_tracker,
};
let res1 = solver
.try_eval_and_append(expr2, Default::default())
.unwrap();
let res2 = solver
.try_eval_and_append(expr3, Default::default())
.unwrap();
let res3 = solver
.try_eval_and_append(expr4, Default::default())
.unwrap();
assert_eq!(
global_expressions[res1],
Expression::Literal(Literal::I32(-4))
);
assert_eq!(
global_expressions[res2],
Expression::Literal(Literal::I32(!4))
);
let res3_inner = &global_expressions[res3];
match *res3_inner {
Expression::Compose {
ref ty,
ref components,
} => {
assert_eq!(*ty, vec_ty);
let mut components_iter = components.iter().copied();
assert_eq!(
global_expressions[components_iter.next().unwrap()],
Expression::Literal(Literal::I32(!4))
);
assert_eq!(
global_expressions[components_iter.next().unwrap()],
Expression::Literal(Literal::I32(!8))
);
assert!(components_iter.next().is_none());
}
_ => panic!("Expected vector"),
}
}
#[test]
fn cast() {
let mut types = UniqueArena::new();
let mut constants = Arena::new();
let overrides = Arena::new();
let mut global_expressions = Arena::new();
let scalar_ty = types.insert(
Type {
name: None,
inner: TypeInner::Scalar(crate::Scalar::I32),
},
Default::default(),
);
let h = constants.append(
Constant {
name: None,
ty: scalar_ty,
init: global_expressions
.append(Expression::Literal(Literal::I32(4)), Default::default()),
},
Default::default(),
);
let expr = global_expressions.append(Expression::Constant(h), Default::default());
let root = Expression::As {
expr,
kind: ScalarKind::Bool,
convert: Some(crate::BOOL_WIDTH),
};
let expression_kind_tracker = &mut ExpressionKindTracker::from_arena(&global_expressions);
let mut solver = ConstantEvaluator {
behavior: Behavior::Wgsl(WgslRestrictions::Const(None)),
types: &mut types,
constants: &constants,
overrides: &overrides,
expressions: &mut global_expressions,
expression_kind_tracker,
};
let res = solver
.try_eval_and_append(root, Default::default())
.unwrap();
assert_eq!(
global_expressions[res],
Expression::Literal(Literal::Bool(true))
);
}
#[test]
fn access() {
let mut types = UniqueArena::new();
let mut constants = Arena::new();
let overrides = Arena::new();
let mut global_expressions = Arena::new();
let matrix_ty = types.insert(
Type {
name: None,
inner: TypeInner::Matrix {
columns: VectorSize::Bi,
rows: VectorSize::Tri,
scalar: crate::Scalar::F32,
},
},
Default::default(),
);
let vec_ty = types.insert(
Type {
name: None,
inner: TypeInner::Vector {
size: VectorSize::Tri,
scalar: crate::Scalar::F32,
},
},
Default::default(),
);
let mut vec1_components = Vec::with_capacity(3);
let mut vec2_components = Vec::with_capacity(3);
for i in 0..3 {
let h = global_expressions.append(
Expression::Literal(Literal::F32(i as f32)),
Default::default(),
);
vec1_components.push(h)
}
for i in 3..6 {
let h = global_expressions.append(
Expression::Literal(Literal::F32(i as f32)),
Default::default(),
);
vec2_components.push(h)
}
let vec1 = constants.append(
Constant {
name: None,
ty: vec_ty,
init: global_expressions.append(
Expression::Compose {
ty: vec_ty,
components: vec1_components,
},
Default::default(),
),
},
Default::default(),
);
let vec2 = constants.append(
Constant {
name: None,
ty: vec_ty,
init: global_expressions.append(
Expression::Compose {
ty: vec_ty,
components: vec2_components,
},
Default::default(),
),
},
Default::default(),
);
let h = constants.append(
Constant {
name: None,
ty: matrix_ty,
init: global_expressions.append(
Expression::Compose {
ty: matrix_ty,
components: vec![constants[vec1].init, constants[vec2].init],
},
Default::default(),
),
},
Default::default(),
);
let base = global_expressions.append(Expression::Constant(h), Default::default());
let expression_kind_tracker = &mut ExpressionKindTracker::from_arena(&global_expressions);
let mut solver = ConstantEvaluator {
behavior: Behavior::Wgsl(WgslRestrictions::Const(None)),
types: &mut types,
constants: &constants,
overrides: &overrides,
expressions: &mut global_expressions,
expression_kind_tracker,
};
let root1 = Expression::AccessIndex { base, index: 1 };
let res1 = solver
.try_eval_and_append(root1, Default::default())
.unwrap();
let root2 = Expression::AccessIndex {
base: res1,
index: 2,
};
let res2 = solver
.try_eval_and_append(root2, Default::default())
.unwrap();
match global_expressions[res1] {
Expression::Compose {
ref ty,
ref components,
} => {
assert_eq!(*ty, vec_ty);
let mut components_iter = components.iter().copied();
assert_eq!(
global_expressions[components_iter.next().unwrap()],
Expression::Literal(Literal::F32(3.))
);
assert_eq!(
global_expressions[components_iter.next().unwrap()],
Expression::Literal(Literal::F32(4.))
);
assert_eq!(
global_expressions[components_iter.next().unwrap()],
Expression::Literal(Literal::F32(5.))
);
assert!(components_iter.next().is_none());
}
_ => panic!("Expected vector"),
}
assert_eq!(
global_expressions[res2],
Expression::Literal(Literal::F32(5.))
);
}
#[test]
fn compose_of_constants() {
let mut types = UniqueArena::new();
let mut constants = Arena::new();
let overrides = Arena::new();
let mut global_expressions = Arena::new();
let i32_ty = types.insert(
Type {
name: None,
inner: TypeInner::Scalar(crate::Scalar::I32),
},
Default::default(),
);
let vec2_i32_ty = types.insert(
Type {
name: None,
inner: TypeInner::Vector {
size: VectorSize::Bi,
scalar: crate::Scalar::I32,
},
},
Default::default(),
);
let h = constants.append(
Constant {
name: None,
ty: i32_ty,
init: global_expressions
.append(Expression::Literal(Literal::I32(4)), Default::default()),
},
Default::default(),
);
let h_expr = global_expressions.append(Expression::Constant(h), Default::default());
let expression_kind_tracker = &mut ExpressionKindTracker::from_arena(&global_expressions);
let mut solver = ConstantEvaluator {
behavior: Behavior::Wgsl(WgslRestrictions::Const(None)),
types: &mut types,
constants: &constants,
overrides: &overrides,
expressions: &mut global_expressions,
expression_kind_tracker,
};
let solved_compose = solver
.try_eval_and_append(
Expression::Compose {
ty: vec2_i32_ty,
components: vec![h_expr, h_expr],
},
Default::default(),
)
.unwrap();
let solved_negate = solver
.try_eval_and_append(
Expression::Unary {
op: UnaryOperator::Negate,
expr: solved_compose,
},
Default::default(),
)
.unwrap();
let pass = match global_expressions[solved_negate] {
Expression::Compose { ty, ref components } => {
ty == vec2_i32_ty
&& components.iter().all(|&component| {
let component = &global_expressions[component];
matches!(*component, Expression::Literal(Literal::I32(-4)))
})
}
_ => false,
};
if !pass {
panic!("unexpected evaluation result")
}
}
#[test]
fn splat_of_constant() {
let mut types = UniqueArena::new();
let mut constants = Arena::new();
let overrides = Arena::new();
let mut global_expressions = Arena::new();
let i32_ty = types.insert(
Type {
name: None,
inner: TypeInner::Scalar(crate::Scalar::I32),
},
Default::default(),
);
let vec2_i32_ty = types.insert(
Type {
name: None,
inner: TypeInner::Vector {
size: VectorSize::Bi,
scalar: crate::Scalar::I32,
},
},
Default::default(),
);
let h = constants.append(
Constant {
name: None,
ty: i32_ty,
init: global_expressions
.append(Expression::Literal(Literal::I32(4)), Default::default()),
},
Default::default(),
);
let h_expr = global_expressions.append(Expression::Constant(h), Default::default());
let expression_kind_tracker = &mut ExpressionKindTracker::from_arena(&global_expressions);
let mut solver = ConstantEvaluator {
behavior: Behavior::Wgsl(WgslRestrictions::Const(None)),
types: &mut types,
constants: &constants,
overrides: &overrides,
expressions: &mut global_expressions,
expression_kind_tracker,
};
let solved_compose = solver
.try_eval_and_append(
Expression::Splat {
size: VectorSize::Bi,
value: h_expr,
},
Default::default(),
)
.unwrap();
let solved_negate = solver
.try_eval_and_append(
Expression::Unary {
op: UnaryOperator::Negate,
expr: solved_compose,
},
Default::default(),
)
.unwrap();
let pass = match global_expressions[solved_negate] {
Expression::Compose { ty, ref components } => {
ty == vec2_i32_ty
&& components.iter().all(|&component| {
let component = &global_expressions[component];
matches!(*component, Expression::Literal(Literal::I32(-4)))
})
}
_ => false,
};
if !pass {
panic!("unexpected evaluation result")
}
}
}