use crate::arena::Handle; #[cfg(feature = "validate")] use crate::arena::{Arena, UniqueArena}; #[cfg(feature = "validate")] use super::validate_atomic_compare_exchange_struct; use super::{ analyzer::{UniformityDisruptor, UniformityRequirements}, ExpressionError, FunctionInfo, ModuleInfo, }; use crate::span::WithSpan; #[cfg(feature = "validate")] use crate::span::{AddSpan as _, MapErrWithSpan as _}; #[cfg(feature = "validate")] use bit_set::BitSet; #[derive(Clone, Debug, thiserror::Error)] #[cfg_attr(test, derive(PartialEq))] pub enum CallError { #[error("Argument {index} expression is invalid")] Argument { index: usize, source: ExpressionError, }, #[error("Result expression {0:?} has already been introduced earlier")] ResultAlreadyInScope(Handle), #[error("Result value is invalid")] ResultValue(#[source] ExpressionError), #[error("Requires {required} arguments, but {seen} are provided")] ArgumentCount { required: usize, seen: usize }, #[error("Argument {index} value {seen_expression:?} doesn't match the type {required:?}")] ArgumentType { index: usize, required: Handle, seen_expression: Handle, }, #[error("The emitted expression doesn't match the call")] ExpressionMismatch(Option>), } #[derive(Clone, Debug, thiserror::Error)] #[cfg_attr(test, derive(PartialEq))] pub enum AtomicError { #[error("Pointer {0:?} to atomic is invalid.")] InvalidPointer(Handle), #[error("Operand {0:?} has invalid type.")] InvalidOperand(Handle), #[error("Result type for {0:?} doesn't match the statement")] ResultTypeMismatch(Handle), } #[derive(Clone, Debug, thiserror::Error)] #[cfg_attr(test, derive(PartialEq))] pub enum LocalVariableError { #[error("Local variable has a type {0:?} that can't be stored in a local variable.")] InvalidType(Handle), #[error("Initializer doesn't match the variable type")] InitializerType, } #[derive(Clone, Debug, thiserror::Error)] #[cfg_attr(test, derive(PartialEq))] pub enum FunctionError { #[error("Expression {handle:?} is invalid")] Expression { handle: Handle, source: ExpressionError, }, #[error("Expression {0:?} can't be introduced - it's already in scope")] ExpressionAlreadyInScope(Handle), #[error("Local variable {handle:?} '{name}' is invalid")] LocalVariable { handle: Handle, name: String, source: LocalVariableError, }, #[error("Argument '{name}' at index {index} has a type that can't be passed into functions.")] InvalidArgumentType { index: usize, name: String }, #[error("The function's given return type cannot be returned from functions")] NonConstructibleReturnType, #[error("Argument '{name}' at index {index} is a pointer of space {space:?}, which can't be passed into functions.")] InvalidArgumentPointerSpace { index: usize, name: String, space: crate::AddressSpace, }, #[error("There are instructions after `return`/`break`/`continue`")] InstructionsAfterReturn, #[error("The `break` is used outside of a `loop` or `switch` context")] BreakOutsideOfLoopOrSwitch, #[error("The `continue` is used outside of a `loop` context")] ContinueOutsideOfLoop, #[error("The `return` is called within a `continuing` block")] InvalidReturnSpot, #[error("The `return` value {0:?} does not match the function return value")] InvalidReturnType(Option>), #[error("The `if` condition {0:?} is not a boolean scalar")] InvalidIfType(Handle), #[error("The `switch` value {0:?} is not an integer scalar")] InvalidSwitchType(Handle), #[error("Multiple `switch` cases for {0:?} are present")] ConflictingSwitchCase(crate::SwitchValue), #[error("The `switch` contains cases with conflicting types")] ConflictingCaseType, #[error("The `switch` is missing a `default` case")] MissingDefaultCase, #[error("Multiple `default` cases are present")] MultipleDefaultCases, #[error("The last `switch` case contains a `falltrough`")] LastCaseFallTrough, #[error("The pointer {0:?} doesn't relate to a valid destination for a store")] InvalidStorePointer(Handle), #[error("The value {0:?} can not be stored")] InvalidStoreValue(Handle), #[error("Store of {value:?} into {pointer:?} doesn't have matching types")] InvalidStoreTypes { pointer: Handle, value: Handle, }, #[error("Image store parameters are invalid")] InvalidImageStore(#[source] ExpressionError), #[error("Call to {function:?} is invalid")] InvalidCall { function: Handle, #[source] error: CallError, }, #[error("Atomic operation is invalid")] InvalidAtomic(#[from] AtomicError), #[error("Ray Query {0:?} is not a local variable")] InvalidRayQueryExpression(Handle), #[error("Acceleration structure {0:?} is not a matching expression")] InvalidAccelerationStructure(Handle), #[error("Ray descriptor {0:?} is not a matching expression")] InvalidRayDescriptor(Handle), #[error("Ray Query {0:?} does not have a matching type")] InvalidRayQueryType(Handle), #[error( "Required uniformity of control flow for {0:?} in {1:?} is not fulfilled because of {2:?}" )] NonUniformControlFlow( UniformityRequirements, Handle, UniformityDisruptor, ), #[error("Functions that are not entry points cannot have `@location` or `@builtin` attributes on their arguments: \"{name}\" has attributes")] PipelineInputRegularFunction { name: String }, #[error("Functions that are not entry points cannot have `@location` or `@builtin` attributes on their return value types")] PipelineOutputRegularFunction, } bitflags::bitflags! { #[repr(transparent)] struct ControlFlowAbility: u8 { /// The control can return out of this block. const RETURN = 0x1; /// The control can break. const BREAK = 0x2; /// The control can continue. const CONTINUE = 0x4; } } #[cfg(feature = "validate")] struct BlockInfo { stages: super::ShaderStages, finished: bool, } #[cfg(feature = "validate")] struct BlockContext<'a> { abilities: ControlFlowAbility, info: &'a FunctionInfo, expressions: &'a Arena, types: &'a UniqueArena, local_vars: &'a Arena, global_vars: &'a Arena, functions: &'a Arena, special_types: &'a crate::SpecialTypes, prev_infos: &'a [FunctionInfo], return_type: Option>, } #[cfg(feature = "validate")] impl<'a> BlockContext<'a> { fn new( fun: &'a crate::Function, module: &'a crate::Module, info: &'a FunctionInfo, prev_infos: &'a [FunctionInfo], ) -> Self { Self { abilities: ControlFlowAbility::RETURN, info, expressions: &fun.expressions, types: &module.types, local_vars: &fun.local_variables, global_vars: &module.global_variables, functions: &module.functions, special_types: &module.special_types, prev_infos, return_type: fun.result.as_ref().map(|fr| fr.ty), } } const fn with_abilities(&self, abilities: ControlFlowAbility) -> Self { BlockContext { abilities, ..*self } } fn get_expression(&self, handle: Handle) -> &'a crate::Expression { &self.expressions[handle] } fn resolve_type_impl( &self, handle: Handle, valid_expressions: &BitSet, ) -> Result<&crate::TypeInner, WithSpan> { if handle.index() >= self.expressions.len() { Err(ExpressionError::DoesntExist.with_span()) } else if !valid_expressions.contains(handle.index()) { Err(ExpressionError::NotInScope.with_span_handle(handle, self.expressions)) } else { Ok(self.info[handle].ty.inner_with(self.types)) } } fn resolve_type( &self, handle: Handle, valid_expressions: &BitSet, ) -> Result<&crate::TypeInner, WithSpan> { self.resolve_type_impl(handle, valid_expressions) .map_err_inner(|source| FunctionError::Expression { handle, source }.with_span()) } fn resolve_pointer_type( &self, handle: Handle, ) -> Result<&crate::TypeInner, FunctionError> { if handle.index() >= self.expressions.len() { Err(FunctionError::Expression { handle, source: ExpressionError::DoesntExist, }) } else { Ok(self.info[handle].ty.inner_with(self.types)) } } } impl super::Validator { #[cfg(feature = "validate")] fn validate_call( &mut self, function: Handle, arguments: &[Handle], result: Option>, context: &BlockContext, ) -> Result> { let fun = &context.functions[function]; if fun.arguments.len() != arguments.len() { return Err(CallError::ArgumentCount { required: fun.arguments.len(), seen: arguments.len(), } .with_span()); } for (index, (arg, &expr)) in fun.arguments.iter().zip(arguments).enumerate() { let ty = context .resolve_type_impl(expr, &self.valid_expression_set) .map_err_inner(|source| { CallError::Argument { index, source } .with_span_handle(expr, context.expressions) })?; let arg_inner = &context.types[arg.ty].inner; if !ty.equivalent(arg_inner, context.types) { return Err(CallError::ArgumentType { index, required: arg.ty, seen_expression: expr, } .with_span_handle(expr, context.expressions)); } } if let Some(expr) = result { if self.valid_expression_set.insert(expr.index()) { self.valid_expression_list.push(expr); } else { return Err(CallError::ResultAlreadyInScope(expr) .with_span_handle(expr, context.expressions)); } match context.expressions[expr] { crate::Expression::CallResult(callee) if fun.result.is_some() && callee == function => {} _ => { return Err(CallError::ExpressionMismatch(result) .with_span_handle(expr, context.expressions)) } } } else if fun.result.is_some() { return Err(CallError::ExpressionMismatch(result).with_span()); } let callee_info = &context.prev_infos[function.index()]; Ok(callee_info.available_stages) } #[cfg(feature = "validate")] fn emit_expression( &mut self, handle: Handle, context: &BlockContext, ) -> Result<(), WithSpan> { if self.valid_expression_set.insert(handle.index()) { self.valid_expression_list.push(handle); Ok(()) } else { Err(FunctionError::ExpressionAlreadyInScope(handle) .with_span_handle(handle, context.expressions)) } } #[cfg(feature = "validate")] fn validate_atomic( &mut self, pointer: Handle, fun: &crate::AtomicFunction, value: Handle, result: Handle, context: &BlockContext, ) -> Result<(), WithSpan> { let pointer_inner = context.resolve_type(pointer, &self.valid_expression_set)?; let (ptr_kind, ptr_width) = match *pointer_inner { crate::TypeInner::Pointer { base, .. } => match context.types[base].inner { crate::TypeInner::Atomic { kind, width } => (kind, width), ref other => { log::error!("Atomic pointer to type {:?}", other); return Err(AtomicError::InvalidPointer(pointer) .with_span_handle(pointer, context.expressions) .into_other()); } }, ref other => { log::error!("Atomic on type {:?}", other); return Err(AtomicError::InvalidPointer(pointer) .with_span_handle(pointer, context.expressions) .into_other()); } }; let value_inner = context.resolve_type(value, &self.valid_expression_set)?; match *value_inner { crate::TypeInner::Scalar { width, kind } if kind == ptr_kind && width == ptr_width => {} ref other => { log::error!("Atomic operand type {:?}", other); return Err(AtomicError::InvalidOperand(value) .with_span_handle(value, context.expressions) .into_other()); } } if let crate::AtomicFunction::Exchange { compare: Some(cmp) } = *fun { if context.resolve_type(cmp, &self.valid_expression_set)? != value_inner { log::error!("Atomic exchange comparison has a different type from the value"); return Err(AtomicError::InvalidOperand(cmp) .with_span_handle(cmp, context.expressions) .into_other()); } } self.emit_expression(result, context)?; match context.expressions[result] { crate::Expression::AtomicResult { ty, comparison } if { let scalar_predicate = |ty: &crate::TypeInner| { *ty == crate::TypeInner::Scalar { kind: ptr_kind, width: ptr_width, } }; match &context.types[ty].inner { ty if !comparison => scalar_predicate(ty), &crate::TypeInner::Struct { ref members, .. } if comparison => { validate_atomic_compare_exchange_struct( context.types, members, scalar_predicate, ) } _ => false, } } => {} _ => { return Err(AtomicError::ResultTypeMismatch(result) .with_span_handle(result, context.expressions) .into_other()) } } Ok(()) } #[cfg(feature = "validate")] fn validate_block_impl( &mut self, statements: &crate::Block, context: &BlockContext, ) -> Result> { use crate::{Statement as S, TypeInner as Ti}; let mut finished = false; let mut stages = super::ShaderStages::all(); for (statement, &span) in statements.span_iter() { if finished { return Err(FunctionError::InstructionsAfterReturn .with_span_static(span, "instructions after return")); } match *statement { S::Emit(ref range) => { for handle in range.clone() { self.emit_expression(handle, context)?; } } S::Block(ref block) => { let info = self.validate_block(block, context)?; stages &= info.stages; finished = info.finished; } S::If { condition, ref accept, ref reject, } => { match *context.resolve_type(condition, &self.valid_expression_set)? { Ti::Scalar { kind: crate::ScalarKind::Bool, width: _, } => {} _ => { return Err(FunctionError::InvalidIfType(condition) .with_span_handle(condition, context.expressions)) } } stages &= self.validate_block(accept, context)?.stages; stages &= self.validate_block(reject, context)?.stages; } S::Switch { selector, ref cases, } => { let uint = match context .resolve_type(selector, &self.valid_expression_set)? .scalar_kind() { Some(crate::ScalarKind::Uint) => true, Some(crate::ScalarKind::Sint) => false, _ => { return Err(FunctionError::InvalidSwitchType(selector) .with_span_handle(selector, context.expressions)) } }; self.switch_values.clear(); for case in cases { match case.value { crate::SwitchValue::I32(_) if !uint => {} crate::SwitchValue::U32(_) if uint => {} crate::SwitchValue::Default => {} _ => { return Err(FunctionError::ConflictingCaseType.with_span_static( case.body .span_iter() .next() .map_or(Default::default(), |(_, s)| *s), "conflicting switch arm here", )); } }; if !self.switch_values.insert(case.value) { return Err(match case.value { crate::SwitchValue::Default => FunctionError::MultipleDefaultCases .with_span_static( case.body .span_iter() .next() .map_or(Default::default(), |(_, s)| *s), "duplicated switch arm here", ), _ => FunctionError::ConflictingSwitchCase(case.value) .with_span_static( case.body .span_iter() .next() .map_or(Default::default(), |(_, s)| *s), "conflicting switch arm here", ), }); } } if !self.switch_values.contains(&crate::SwitchValue::Default) { return Err(FunctionError::MissingDefaultCase .with_span_static(span, "missing default case")); } if let Some(case) = cases.last() { if case.fall_through { return Err(FunctionError::LastCaseFallTrough.with_span_static( case.body .span_iter() .next() .map_or(Default::default(), |(_, s)| *s), "bad switch arm here", )); } } let pass_through_abilities = context.abilities & (ControlFlowAbility::RETURN | ControlFlowAbility::CONTINUE); let sub_context = context.with_abilities(pass_through_abilities | ControlFlowAbility::BREAK); for case in cases { stages &= self.validate_block(&case.body, &sub_context)?.stages; } } S::Loop { ref body, ref continuing, break_if, } => { // special handling for block scoping is needed here, // because the continuing{} block inherits the scope let base_expression_count = self.valid_expression_list.len(); let pass_through_abilities = context.abilities & ControlFlowAbility::RETURN; stages &= self .validate_block_impl( body, &context.with_abilities( pass_through_abilities | ControlFlowAbility::BREAK | ControlFlowAbility::CONTINUE, ), )? .stages; stages &= self .validate_block_impl( continuing, &context.with_abilities(ControlFlowAbility::empty()), )? .stages; if let Some(condition) = break_if { match *context.resolve_type(condition, &self.valid_expression_set)? { Ti::Scalar { kind: crate::ScalarKind::Bool, width: _, } => {} _ => { return Err(FunctionError::InvalidIfType(condition) .with_span_handle(condition, context.expressions)) } } } for handle in self.valid_expression_list.drain(base_expression_count..) { self.valid_expression_set.remove(handle.index()); } } S::Break => { if !context.abilities.contains(ControlFlowAbility::BREAK) { return Err(FunctionError::BreakOutsideOfLoopOrSwitch .with_span_static(span, "invalid break")); } finished = true; } S::Continue => { if !context.abilities.contains(ControlFlowAbility::CONTINUE) { return Err(FunctionError::ContinueOutsideOfLoop .with_span_static(span, "invalid continue")); } finished = true; } S::Return { value } => { if !context.abilities.contains(ControlFlowAbility::RETURN) { return Err(FunctionError::InvalidReturnSpot .with_span_static(span, "invalid return")); } let value_ty = value .map(|expr| context.resolve_type(expr, &self.valid_expression_set)) .transpose()?; let expected_ty = context.return_type.map(|ty| &context.types[ty].inner); // We can't return pointers, but it seems best not to embed that // assumption here, so use `TypeInner::equivalent` for comparison. let okay = match (value_ty, expected_ty) { (None, None) => true, (Some(value_inner), Some(expected_inner)) => { value_inner.equivalent(expected_inner, context.types) } (_, _) => false, }; if !okay { log::error!( "Returning {:?} where {:?} is expected", value_ty, expected_ty ); if let Some(handle) = value { return Err(FunctionError::InvalidReturnType(value) .with_span_handle(handle, context.expressions)); } else { return Err(FunctionError::InvalidReturnType(value) .with_span_static(span, "invalid return")); } } finished = true; } S::Kill => { stages &= super::ShaderStages::FRAGMENT; finished = true; } S::Barrier(_) => { stages &= super::ShaderStages::COMPUTE; } S::Store { pointer, value } => { let mut current = pointer; loop { let _ = context .resolve_pointer_type(current) .map_err(|e| e.with_span())?; match context.expressions[current] { crate::Expression::Access { base, .. } | crate::Expression::AccessIndex { base, .. } => current = base, crate::Expression::LocalVariable(_) | crate::Expression::GlobalVariable(_) | crate::Expression::FunctionArgument(_) => break, _ => { return Err(FunctionError::InvalidStorePointer(current) .with_span_handle(pointer, context.expressions)) } } } let value_ty = context.resolve_type(value, &self.valid_expression_set)?; match *value_ty { Ti::Image { .. } | Ti::Sampler { .. } => { return Err(FunctionError::InvalidStoreValue(value) .with_span_handle(value, context.expressions)); } _ => {} } let pointer_ty = context .resolve_pointer_type(pointer) .map_err(|e| e.with_span())?; let good = match *pointer_ty { Ti::Pointer { base, space: _ } => match context.types[base].inner { Ti::Atomic { kind, width } => *value_ty == Ti::Scalar { kind, width }, ref other => value_ty == other, }, Ti::ValuePointer { size: Some(size), kind, width, space: _, } => *value_ty == Ti::Vector { size, kind, width }, Ti::ValuePointer { size: None, kind, width, space: _, } => *value_ty == Ti::Scalar { kind, width }, _ => false, }; if !good { return Err(FunctionError::InvalidStoreTypes { pointer, value } .with_span() .with_handle(pointer, context.expressions) .with_handle(value, context.expressions)); } if let Some(space) = pointer_ty.pointer_space() { if !space.access().contains(crate::StorageAccess::STORE) { return Err(FunctionError::InvalidStorePointer(pointer) .with_span_static( context.expressions.get_span(pointer), "writing to this location is not permitted", )); } } } S::ImageStore { image, coordinate, array_index, value, } => { //Note: this code uses a lot of `FunctionError::InvalidImageStore`, // and could probably be refactored. let var = match *context.get_expression(image) { crate::Expression::GlobalVariable(var_handle) => { &context.global_vars[var_handle] } // We're looking at a binding index situation, so punch through the index and look at the global behind it. crate::Expression::Access { base, .. } | crate::Expression::AccessIndex { base, .. } => { match *context.get_expression(base) { crate::Expression::GlobalVariable(var_handle) => { &context.global_vars[var_handle] } _ => { return Err(FunctionError::InvalidImageStore( ExpressionError::ExpectedGlobalVariable, ) .with_span_handle(image, context.expressions)) } } } _ => { return Err(FunctionError::InvalidImageStore( ExpressionError::ExpectedGlobalVariable, ) .with_span_handle(image, context.expressions)) } }; // Punch through a binding array to get the underlying type let global_ty = match context.types[var.ty].inner { Ti::BindingArray { base, .. } => &context.types[base].inner, ref inner => inner, }; let value_ty = match *global_ty { Ti::Image { class, arrayed, dim, } => { match context .resolve_type(coordinate, &self.valid_expression_set)? .image_storage_coordinates() { Some(coord_dim) if coord_dim == dim => {} _ => { return Err(FunctionError::InvalidImageStore( ExpressionError::InvalidImageCoordinateType( dim, coordinate, ), ) .with_span_handle(coordinate, context.expressions)); } }; if arrayed != array_index.is_some() { return Err(FunctionError::InvalidImageStore( ExpressionError::InvalidImageArrayIndex, ) .with_span_handle(coordinate, context.expressions)); } if let Some(expr) = array_index { match *context.resolve_type(expr, &self.valid_expression_set)? { Ti::Scalar { kind: crate::ScalarKind::Sint | crate::ScalarKind::Uint, width: _, } => {} _ => { return Err(FunctionError::InvalidImageStore( ExpressionError::InvalidImageArrayIndexType(expr), ) .with_span_handle(expr, context.expressions)); } } } match class { crate::ImageClass::Storage { format, .. } => { crate::TypeInner::Vector { kind: format.into(), size: crate::VectorSize::Quad, width: 4, } } _ => { return Err(FunctionError::InvalidImageStore( ExpressionError::InvalidImageClass(class), ) .with_span_handle(image, context.expressions)); } } } _ => { return Err(FunctionError::InvalidImageStore( ExpressionError::ExpectedImageType(var.ty), ) .with_span() .with_handle(var.ty, context.types) .with_handle(image, context.expressions)) } }; if *context.resolve_type(value, &self.valid_expression_set)? != value_ty { return Err(FunctionError::InvalidStoreValue(value) .with_span_handle(value, context.expressions)); } } S::Call { function, ref arguments, result, } => match self.validate_call(function, arguments, result, context) { Ok(callee_stages) => stages &= callee_stages, Err(error) => { return Err(error.and_then(|error| { FunctionError::InvalidCall { function, error } .with_span_static(span, "invalid function call") })) } }, S::Atomic { pointer, ref fun, value, result, } => { self.validate_atomic(pointer, fun, value, result, context)?; } S::RayQuery { query, ref fun } => { let query_var = match *context.get_expression(query) { crate::Expression::LocalVariable(var) => &context.local_vars[var], ref other => { log::error!("Unexpected ray query expression {other:?}"); return Err(FunctionError::InvalidRayQueryExpression(query) .with_span_static(span, "invalid query expression")); } }; match context.types[query_var.ty].inner { Ti::RayQuery => {} ref other => { log::error!("Unexpected ray query type {other:?}"); return Err(FunctionError::InvalidRayQueryType(query_var.ty) .with_span_static(span, "invalid query type")); } } match *fun { crate::RayQueryFunction::Initialize { acceleration_structure, descriptor, } => { match *context .resolve_type(acceleration_structure, &self.valid_expression_set)? { Ti::AccelerationStructure => {} _ => { return Err(FunctionError::InvalidAccelerationStructure( acceleration_structure, ) .with_span_static(span, "invalid acceleration structure")) } } let desc_ty_given = context.resolve_type(descriptor, &self.valid_expression_set)?; let desc_ty_expected = context .special_types .ray_desc .map(|handle| &context.types[handle].inner); if Some(desc_ty_given) != desc_ty_expected { return Err(FunctionError::InvalidRayDescriptor(descriptor) .with_span_static(span, "invalid ray descriptor")); } } crate::RayQueryFunction::Proceed { result } => { self.emit_expression(result, context)?; } crate::RayQueryFunction::Terminate => {} } } } } Ok(BlockInfo { stages, finished }) } #[cfg(feature = "validate")] fn validate_block( &mut self, statements: &crate::Block, context: &BlockContext, ) -> Result> { let base_expression_count = self.valid_expression_list.len(); let info = self.validate_block_impl(statements, context)?; for handle in self.valid_expression_list.drain(base_expression_count..) { self.valid_expression_set.remove(handle.index()); } Ok(info) } #[cfg(feature = "validate")] fn validate_local_var( &self, var: &crate::LocalVariable, types: &UniqueArena, constants: &Arena, ) -> Result<(), LocalVariableError> { log::debug!("var {:?}", var); let type_info = self .types .get(var.ty.index()) .ok_or(LocalVariableError::InvalidType(var.ty))?; if !type_info .flags .contains(super::TypeFlags::DATA | super::TypeFlags::SIZED) { return Err(LocalVariableError::InvalidType(var.ty)); } if let Some(const_handle) = var.init { match constants[const_handle].inner { crate::ConstantInner::Scalar { width, ref value } => { let ty_inner = crate::TypeInner::Scalar { width, kind: value.scalar_kind(), }; if types[var.ty].inner != ty_inner { return Err(LocalVariableError::InitializerType); } } crate::ConstantInner::Composite { ty, components: _ } => { if ty != var.ty { return Err(LocalVariableError::InitializerType); } } } } Ok(()) } pub(super) fn validate_function( &mut self, fun: &crate::Function, module: &crate::Module, mod_info: &ModuleInfo, #[cfg_attr(not(feature = "validate"), allow(unused))] entry_point: bool, ) -> Result> { #[cfg_attr(not(feature = "validate"), allow(unused_mut))] let mut info = mod_info.process_function(fun, module, self.flags, self.capabilities)?; #[cfg(feature = "validate")] for (var_handle, var) in fun.local_variables.iter() { self.validate_local_var(var, &module.types, &module.constants) .map_err(|source| { FunctionError::LocalVariable { handle: var_handle, name: var.name.clone().unwrap_or_default(), source, } .with_span_handle(var.ty, &module.types) .with_handle(var_handle, &fun.local_variables) })?; } #[cfg(feature = "validate")] for (index, argument) in fun.arguments.iter().enumerate() { match module.types[argument.ty].inner.pointer_space() { Some( crate::AddressSpace::Private | crate::AddressSpace::Function | crate::AddressSpace::WorkGroup, ) | None => {} Some(other) => { return Err(FunctionError::InvalidArgumentPointerSpace { index, name: argument.name.clone().unwrap_or_default(), space: other, } .with_span_handle(argument.ty, &module.types)) } } // Check for the least informative error last. if !self.types[argument.ty.index()] .flags .contains(super::TypeFlags::ARGUMENT) { return Err(FunctionError::InvalidArgumentType { index, name: argument.name.clone().unwrap_or_default(), } .with_span_handle(argument.ty, &module.types)); } if !entry_point && argument.binding.is_some() { return Err(FunctionError::PipelineInputRegularFunction { name: argument.name.clone().unwrap_or_default(), } .with_span_handle(argument.ty, &module.types)); } } #[cfg(feature = "validate")] if let Some(ref result) = fun.result { if !self.types[result.ty.index()] .flags .contains(super::TypeFlags::CONSTRUCTIBLE) { return Err(FunctionError::NonConstructibleReturnType .with_span_handle(result.ty, &module.types)); } if !entry_point && result.binding.is_some() { return Err(FunctionError::PipelineOutputRegularFunction .with_span_handle(result.ty, &module.types)); } } self.valid_expression_set.clear(); self.valid_expression_list.clear(); for (handle, expr) in fun.expressions.iter() { if expr.needs_pre_emit() { self.valid_expression_set.insert(handle.index()); } #[cfg(feature = "validate")] if self.flags.contains(super::ValidationFlags::EXPRESSIONS) { match self.validate_expression( handle, expr, fun, module, &info, &mod_info.functions, ) { Ok(stages) => info.available_stages &= stages, Err(source) => { return Err(FunctionError::Expression { handle, source } .with_span_handle(handle, &fun.expressions)) } } } } #[cfg(feature = "validate")] if self.flags.contains(super::ValidationFlags::BLOCKS) { let stages = self .validate_block( &fun.body, &BlockContext::new(fun, module, &info, &mod_info.functions), )? .stages; info.available_stages &= stages; } Ok(info) } }