CSY/reowolf Changeset - 85419b0950c7 · Centrum Wiskunde & Informatica (CWI)

Changeset - 85419b0950c7

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MH - 4 years ago 2021-05-20 16:47:55
contact@maxhenger.nl

Rewrote typing to use indices.

Currently it is slower than before, because we do a HashMap lookup
followed up by actually using the index. But it serves as the basis
for a faster type inferencer.

The main goal, however, is to fix the manner in which polymorph
types are determined. The typing queue of functions still needs to
correctly write this data to the type table.

5 files changed:

src/collections/sets.rs

src/protocol/ast.rs

src/protocol/ast_printer.rs

src/protocol/eval/value.rs

src/protocol/parser/mod.rs

Changeset was too big and was cut off... Show full diff anyway

0 comments (0 inline, 0 general)

src/collections/sets.rs

➞

Show inline comments

 use std::collections::VecDeque;
 /// Simple double ended queue that ensures that all elements are unique. Queue
 /// is not ordered.
 /// elements are not ordered (use case is that the queue should be rather
 /// small).
 pub struct DequeSet<T: Eq> {
     inner: VecDeque<T>,
+}
 impl<T: Eq> DequeSet<T> {
     pub fn new() -> Self {
         Self{ inner: VecDeque::new() }
+    }
     #[inline]
     pub fn pop_front(&mut self) -> Option<T> {
         self.inner.pop_front()
+    }
     #[inline]
     pub fn pop_back(&mut self) -> Option<T> {
         self.inner.pop_back()
+    }
     #[inline]
     pub fn push_back(&mut self, to_push: T) {
         for element in self.inner.iter() {
             if *element == to_push {
                 return;
+            }
+        }
         self.inner.push_back(to_push);
+    }
     #[inline]
     pub fn push_front(&mut self, to_push: T) {
         for element in self.inner.iter() {
             if *element == to_push {
                 return;
+            }
+        }
         self.inner.push_front(to_push);
+    }
     #[inline]
     pub fn clear(&mut self) {
         self.inner.clear();
+    }
     #[inline]
     pub fn is_empty(&self) -> bool {
         self.inner.is_empty()
+    }
+}
@@ \ No newline at end of file @@

src/protocol/ast.rs

➞

Show inline comments

@@ @@ -15,897 +15,887 @@ macro_rules! define_aliased_ast_id { @@
     // Variant where we just defined the alias, without any indexing
     ($name:ident, $parent:ty) => {
         pub type $name = $parent;
     };
     // Variant where we define the type, and the Index and IndexMut traits
+    (
         $name:ident, $parent:ty,
         index($indexed_type:ty, $indexed_arena:ident)
     ) => {
         define_aliased_ast_id!($name, $parent);
         impl Index<$name> for Heap {
             type Output = $indexed_type;
             fn index(&self, index: $name) -> &Self::Output {
                 &self.$indexed_arena[index]
+            }
+        }
         impl IndexMut<$name> for Heap {
             fn index_mut(&mut self, index: $name) -> &mut Self::Output {
                 &mut self.$indexed_arena[index]
+            }
+        }
     };
     // Variant where we define type, Index(Mut) traits and an allocation function
+    (
         $name:ident, $parent:ty,
         index($indexed_type:ty, $indexed_arena:ident),
         alloc($fn_name:ident)
     ) => {
         define_aliased_ast_id!($name, $parent, index($indexed_type, $indexed_arena));
         impl Heap {
             pub fn $fn_name(&mut self, f: impl FnOnce($name) -> $indexed_type) -> $name {
                 self.$indexed_arena.alloc_with_id(|id| f(id))
+            }
+        }
     };
+}
 /// Helper macro that defines a wrapper type for a particular variant of an AST
 /// element ID. Only used to define single-wrapping IDs.
 macro_rules! define_new_ast_id {
     // Variant where we just defined the new type, without any indexing
     ($name:ident, $parent:ty) => {
         #[derive(Debug, Clone, Copy, PartialEq, Eq, Hash)]
         pub struct $name (pub(crate) $parent);
         #[allow(dead_code)]
         impl $name {
             pub(crate) fn new_invalid() -> Self     { Self(<$parent>::new_invalid()) }
             pub(crate) fn is_invalid(&self) -> bool { self.0.is_invalid() }
             pub fn upcast(self) -> $parent          { self.0 }
+        }
     };
     // Variant where we define the type, and the Index and IndexMut traits
+    (
         $name:ident, $parent:ty,
         index($indexed_type:ty, $wrapper_type:path, $indexed_arena:ident)
     ) => {
         define_new_ast_id!($name, $parent);
         impl Index<$name> for Heap {
             type Output = $indexed_type;
             fn index(&self, index: $name) -> &Self::Output {
                 if let $wrapper_type(v) = &self.$indexed_arena[index.0] {
+                    v
                 } else {
                     unreachable!()
+                }
+            }
+        }
         impl IndexMut<$name> for Heap {
             fn index_mut(&mut self, index: $name) -> &mut Self::Output {
                 if let $wrapper_type(v) = &mut self.$indexed_arena[index.0] {
+                    v
                 } else {
                     unreachable!()
+                }
+            }
+        }
     };
     // Variant where we define the type, the Index and IndexMut traits, and an allocation function
+    (
         $name:ident, $parent:ty,
         index($indexed_type:ty, $wrapper_type:path, $indexed_arena:ident),
         alloc($fn_name:ident)
     ) => {
         define_new_ast_id!($name, $parent, index($indexed_type, $wrapper_type, $indexed_arena));
         impl Heap {
             pub fn $fn_name(&mut self, f: impl FnOnce($name) -> $indexed_type) -> $name {
                 $name(
                     self.$indexed_arena.alloc_with_id(|id| {
                         $wrapper_type(f($name(id)))
                     })
+                )
+            }
+        }
+    }
+}
 define_aliased_ast_id!(RootId, Id<Root>, index(Root, protocol_descriptions), alloc(alloc_protocol_description));
 define_aliased_ast_id!(PragmaId, Id<Pragma>, index(Pragma, pragmas), alloc(alloc_pragma));
 define_aliased_ast_id!(ImportId, Id<Import>, index(Import, imports), alloc(alloc_import));
 define_aliased_ast_id!(ParserTypeId, Id<ParserType>, index(ParserType, parser_types), alloc(alloc_parser_type));
 define_aliased_ast_id!(VariableId, Id<Variable>, index(Variable, variables), alloc(alloc_variable));
 define_aliased_ast_id!(DefinitionId, Id<Definition>, index(Definition, definitions));
 define_new_ast_id!(StructDefinitionId, DefinitionId, index(StructDefinition, Definition::Struct, definitions), alloc(alloc_struct_definition));
 define_new_ast_id!(EnumDefinitionId, DefinitionId, index(EnumDefinition, Definition::Enum, definitions), alloc(alloc_enum_definition));
 define_new_ast_id!(UnionDefinitionId, DefinitionId, index(UnionDefinition, Definition::Union, definitions), alloc(alloc_union_definition));
 define_new_ast_id!(ComponentDefinitionId, DefinitionId, index(ComponentDefinition, Definition::Component, definitions), alloc(alloc_component_definition));
 define_new_ast_id!(FunctionDefinitionId, DefinitionId, index(FunctionDefinition, Definition::Function, definitions), alloc(alloc_function_definition));
 define_aliased_ast_id!(StatementId, Id<Statement>, index(Statement, statements));
 define_new_ast_id!(BlockStatementId, StatementId, index(BlockStatement, Statement::Block, statements), alloc(alloc_block_statement));
 define_new_ast_id!(EndBlockStatementId, StatementId, index(EndBlockStatement, Statement::EndBlock, statements), alloc(alloc_end_block_statement));
 define_new_ast_id!(LocalStatementId, StatementId, index(LocalStatement, Statement::Local, statements), alloc(alloc_local_statement));
 define_new_ast_id!(MemoryStatementId, LocalStatementId);
 define_new_ast_id!(ChannelStatementId, LocalStatementId);
 define_new_ast_id!(LabeledStatementId, StatementId, index(LabeledStatement, Statement::Labeled, statements), alloc(alloc_labeled_statement));
 define_new_ast_id!(IfStatementId, StatementId, index(IfStatement, Statement::If, statements), alloc(alloc_if_statement));
 define_new_ast_id!(EndIfStatementId, StatementId, index(EndIfStatement, Statement::EndIf, statements), alloc(alloc_end_if_statement));
 define_new_ast_id!(WhileStatementId, StatementId, index(WhileStatement, Statement::While, statements), alloc(alloc_while_statement));
 define_new_ast_id!(EndWhileStatementId, StatementId, index(EndWhileStatement, Statement::EndWhile, statements), alloc(alloc_end_while_statement));
 define_new_ast_id!(BreakStatementId, StatementId, index(BreakStatement, Statement::Break, statements), alloc(alloc_break_statement));
 define_new_ast_id!(ContinueStatementId, StatementId, index(ContinueStatement, Statement::Continue, statements), alloc(alloc_continue_statement));
 define_new_ast_id!(SynchronousStatementId, StatementId, index(SynchronousStatement, Statement::Synchronous, statements), alloc(alloc_synchronous_statement));
 define_new_ast_id!(EndSynchronousStatementId, StatementId, index(EndSynchronousStatement, Statement::EndSynchronous, statements), alloc(alloc_end_synchronous_statement));
 define_new_ast_id!(ReturnStatementId, StatementId, index(ReturnStatement, Statement::Return, statements), alloc(alloc_return_statement));
 define_new_ast_id!(GotoStatementId, StatementId, index(GotoStatement, Statement::Goto, statements), alloc(alloc_goto_statement));
 define_new_ast_id!(NewStatementId, StatementId, index(NewStatement, Statement::New, statements), alloc(alloc_new_statement));
 define_new_ast_id!(ExpressionStatementId, StatementId, index(ExpressionStatement, Statement::Expression, statements), alloc(alloc_expression_statement));
 define_aliased_ast_id!(ExpressionId, Id<Expression>, index(Expression, expressions));
 define_new_ast_id!(AssignmentExpressionId, ExpressionId, index(AssignmentExpression, Expression::Assignment, expressions), alloc(alloc_assignment_expression));
 define_new_ast_id!(BindingExpressionId, ExpressionId, index(BindingExpression, Expression::Binding, expressions), alloc(alloc_binding_expression));
 define_new_ast_id!(ConditionalExpressionId, ExpressionId, index(ConditionalExpression, Expression::Conditional, expressions), alloc(alloc_conditional_expression));
 define_new_ast_id!(BinaryExpressionId, ExpressionId, index(BinaryExpression, Expression::Binary, expressions), alloc(alloc_binary_expression));
 define_new_ast_id!(UnaryExpressionId, ExpressionId, index(UnaryExpression, Expression::Unary, expressions), alloc(alloc_unary_expression));
 define_new_ast_id!(IndexingExpressionId, ExpressionId, index(IndexingExpression, Expression::Indexing, expressions), alloc(alloc_indexing_expression));
 define_new_ast_id!(SlicingExpressionId, ExpressionId, index(SlicingExpression, Expression::Slicing, expressions), alloc(alloc_slicing_expression));
 define_new_ast_id!(SelectExpressionId, ExpressionId, index(SelectExpression, Expression::Select, expressions), alloc(alloc_select_expression));
 define_new_ast_id!(LiteralExpressionId, ExpressionId, index(LiteralExpression, Expression::Literal, expressions), alloc(alloc_literal_expression));
 define_new_ast_id!(CallExpressionId, ExpressionId, index(CallExpression, Expression::Call, expressions), alloc(alloc_call_expression));
 define_new_ast_id!(VariableExpressionId, ExpressionId, index(VariableExpression, Expression::Variable, expressions), alloc(alloc_variable_expression));
 // TODO: @cleanup - pub qualifiers can be removed once done
 #[derive(Debug)]
 pub struct Heap {
     // Root arena, contains the entry point for different modules. Each root
     // contains lists of IDs that correspond to the other arenas.
     pub(crate) protocol_descriptions: Arena<Root>,
     // Contents of a file, these are the elements the `Root` elements refer to
     pragmas: Arena<Pragma>,
     pub(crate) imports: Arena<Import>,
     pub(crate) parser_types: Arena<ParserType>,
     pub(crate) variables: Arena<Variable>,
     pub(crate) definitions: Arena<Definition>,
     pub(crate) statements: Arena<Statement>,
     pub(crate) expressions: Arena<Expression>,
+}
 impl Heap {
     pub fn new() -> Heap {
         Heap {
             // string_alloc: StringAllocator::new(),
             protocol_descriptions: Arena::new(),
             pragmas: Arena::new(),
             imports: Arena::new(),
             parser_types: Arena::new(),
             variables: Arena::new(),
             definitions: Arena::new(),
             statements: Arena::new(),
             expressions: Arena::new(),
+        }
+    }
     pub fn alloc_memory_statement(
         &mut self,
         f: impl FnOnce(MemoryStatementId) -> MemoryStatement,
     ) -> MemoryStatementId {
         MemoryStatementId(LocalStatementId(self.statements.alloc_with_id(|id| {
             Statement::Local(LocalStatement::Memory(
                 f(MemoryStatementId(LocalStatementId(id)))
             ))
         })))
+    }
     pub fn alloc_channel_statement(
         &mut self,
         f: impl FnOnce(ChannelStatementId) -> ChannelStatement,
     ) -> ChannelStatementId {
         ChannelStatementId(LocalStatementId(self.statements.alloc_with_id(|id| {
             Statement::Local(LocalStatement::Channel(
                 f(ChannelStatementId(LocalStatementId(id)))
             ))
         })))
+    }
+}
 impl Index<MemoryStatementId> for Heap {
     type Output = MemoryStatement;
     fn index(&self, index: MemoryStatementId) -> &Self::Output {
         &self.statements[index.0.0].as_memory()
+    }
+}
 impl Index<ChannelStatementId> for Heap {
     type Output = ChannelStatement;
     fn index(&self, index: ChannelStatementId) -> &Self::Output {
         &self.statements[index.0.0].as_channel()
+    }
+}
 #[derive(Debug, Clone)]
 pub struct Root {
     pub this: RootId,
     // Phase 1: parser
     // pub position: InputPosition,
     pub pragmas: Vec<PragmaId>,
     pub imports: Vec<ImportId>,
     pub definitions: Vec<DefinitionId>,
+}
 impl Root {
     // TODO: @Cleanup
     pub fn get_definition_ident(&self, h: &Heap, id: &[u8]) -> Option<DefinitionId> {
         for &def in self.definitions.iter() {
             if h[def].identifier().value.as_bytes() == id {
                 return Some(def);
+            }
+        }
         None
+    }
+}
 #[derive(Debug, Clone)]
 pub enum Pragma {
     Version(PragmaVersion),
     Module(PragmaModule),
+}
 impl Pragma {
     pub(crate) fn as_module(&self) -> &PragmaModule {
         match self {
             Pragma::Module(pragma) => pragma,
             _ => unreachable!("Tried to obtain {:?} as PragmaModule", self),
+        }
+    }
+}
 #[derive(Debug, Clone)]
 pub struct PragmaVersion {
     pub this: PragmaId,
     // Phase 1: parser
     pub span: InputSpan, // of full pragma
     pub version: u64,
+}
 #[derive(Debug, Clone)]
 pub struct PragmaModule {
     pub this: PragmaId,
     // Phase 1: parser
     pub span: InputSpan, // of full pragma
     pub value: Identifier,
+}
 #[derive(Debug, Clone)]
 pub enum Import {
     Module(ImportModule),
     Symbols(ImportSymbols)
+}
 impl Import {
     pub(crate) fn span(&self) -> InputSpan {
         match self {
             Import::Module(v) => v.span,
             Import::Symbols(v) => v.span,
+        }
+    }
     pub(crate) fn as_module(&self) -> &ImportModule {
         match self {
             Import::Module(m) => m,
             _ => unreachable!("Unable to cast 'Import' to 'ImportModule'")
+        }
+    }
     pub(crate) fn as_symbols(&self) -> &ImportSymbols {
         match self {
             Import::Symbols(m) => m,
             _ => unreachable!("Unable to cast 'Import' to 'ImportSymbols'")
+        }
+    }
     pub(crate) fn as_symbols_mut(&mut self) -> &mut ImportSymbols {
         match self {
             Import::Symbols(m) => m,
             _ => unreachable!("Unable to cast 'Import' to 'ImportSymbols'")
+        }
+    }
+}
 #[derive(Debug, Clone)]
 pub struct ImportModule {
     pub this: ImportId,
     // Phase 1: parser
     pub span: InputSpan,
     pub module: Identifier,
     pub alias: Identifier,
     pub module_id: RootId,
+}
 #[derive(Debug, Clone)]
 pub struct AliasedSymbol {
     pub name: Identifier,
     pub alias: Option<Identifier>,
     pub definition_id: DefinitionId,
+}
 #[derive(Debug, Clone)]
 pub struct ImportSymbols {
     pub this: ImportId,
     // Phase 1: parser
     pub span: InputSpan,
     pub module: Identifier,
     pub module_id: RootId,
     pub symbols: Vec<AliasedSymbol>,
+}
 #[derive(Debug, Clone)]
 pub struct Identifier {
     pub span: InputSpan,
     pub value: StringRef<'static>,
+}
 impl PartialEq for Identifier {
     fn eq(&self, other: &Self) -> bool {
         return self.value == other.value
+    }
+}
 impl Display for Identifier {
     fn fmt(&self, f: &mut Formatter<'_>) -> fmt::Result {
         write!(f, "{}", self.value.as_str())
+    }
+}
 #[derive(Debug, Clone, PartialEq, Eq)]
 pub enum ParserTypeVariant {
     // Special builtin, only usable by the compiler and not constructable by the
     // programmer
     Void,
     InputOrOutput,
     ArrayLike,
     IntegerLike,
     // Basic builtin
     Message,
     Bool,
     UInt8, UInt16, UInt32, UInt64,
     SInt8, SInt16, SInt32, SInt64,
     Character, String,
     // Literals (need to get concrete builtin type during typechecking)
     IntegerLiteral,
     // Marker for inference
     Inferred,
     // Builtins expecting one subsequent type
     Array,
     Input,
     Output,
     // User-defined types
     PolymorphicArgument(DefinitionId, u32), // u32 = index into polymorphic variables
     Definition(DefinitionId, u32), // u32 = number of following subtypes
+}
 impl ParserTypeVariant {
     pub(crate) fn num_embedded(&self) -> usize {
         use ParserTypeVariant::*;
         match self {
             Void | IntegerLike |
             Message | Bool |
             UInt8 | UInt16 | UInt32 | UInt64 |
             SInt8 | SInt16 | SInt32 | SInt64 |
             Character | String | IntegerLiteral |
             Inferred | PolymorphicArgument(_, _) =>
 ,
             ArrayLike | InputOrOutput | Array | Input | Output =>
 ,
             Definition(_, num) => *num,
+            Definition(_, num) => *num as usize,
+        }
+    }
+}
 #[derive(Debug, Clone)]
 pub struct ParserTypeElement {
     // TODO: @cleanup, do we ever need the span of a user-defined type after
     //  constructing it?
     pub full_span: InputSpan, // full span of type, including any polymorphic arguments
     pub variant: ParserTypeVariant,
+}
 /// ParserType is a specification of a type during the parsing phase and initial
 /// linker/validator phase of the compilation process. These types may be
 /// (partially) inferred or represent literals (e.g. a integer whose bytesize is
 /// not yet determined).
 #[derive(Debug, Clone)]
 pub struct ParserType {
     pub elements: Vec<ParserTypeElement>
+}
 impl ParserType {
     pub(crate) fn iter_embedded(&self, parent_idx: usize) -> ParserTypeIter {
         ParserTypeIter::new(&self.elements, parent_idx)
+    }
+}
 /// Iterator over the embedded elements of a specific element.
 pub struct ParserTypeIter<'a> {
     pub elements: &'a [ParserTypeElement],
     pub cur_embedded_idx: usize,
+}
 impl<'a> ParserTypeIter<'a> {
     fn new(elements: &'a [ParserTypeElement], parent_idx: usize) -> Self {
         debug_assert!(parent_idx < elements.len(), "parent index exceeds number of elements in ParserType");
         if elements[0].variant.num_embedded() == 0 {
             // Parent element does not have any embedded types, place
             // `cur_embedded_idx` at end so we will always return `None`
             Self{ elements, cur_embedded_idx: elements.len() }
         } else {
             // Parent element has an embedded type
             Self{ elements, cur_embedded_idx: parent_idx + 1 }
+        }
+    }
+}
 impl<'a> Iterator for ParserTypeIter<'a> {
     type Item = &'a [ParserTypeElement];
     fn next(&mut self) -> Option<Self::Item> {
         let elements_len = self.elements.len();
         if self.cur_embedded_idx >= elements_len {
             return None;
+        }
         // Seek to the end of the subtree
         let mut depth = 1;
         let start_element = self.cur_embedded_idx;
         while self.cur_embedded_idx < elements_len {
             let cur_element = &self.elements[self.cur_embedded_idx];
             let depth_change = cur_element.variant.num_embedded() as i32 - 1;
             depth += depth_change;
             debug_assert!(depth >= 0, "illegally constructed ParserType: {:?}", self.elements);
             self.cur_embedded_idx += 1;
             if depth == 0 {
                 break;
+            }
+        }
         debug_assert!(depth == 0, "illegally constructed ParserType: {:?}", self.elements);
         return Some(&self.elements[start_element..self.cur_embedded_idx]);
+    }
+}
 /// Specifies whether the symbolic type points to an actual user-defined type,
 /// or whether it points to a polymorphic argument within the definition (e.g.
 /// a defined variable `T var` within a function `int func<T>()`
 #[derive(Debug, Clone)]
 pub enum SymbolicParserTypeVariant {
     Definition(DefinitionId),
     // TODO: figure out if I need the DefinitionId here
     PolyArg(DefinitionId, usize), // index of polyarg in the definition
+}
 /// ConcreteType is the representation of a type after resolving symbolic types
 /// and performing type inference
 #[derive(Debug, Clone, Copy, Eq, PartialEq)]
 pub enum ConcreteTypePart {
     // Special types (cannot be explicitly constructed by the programmer)
     Void,
     // Builtin types without nested types
     Message,
     Bool,
     UInt8, UInt16, UInt32, UInt64,
     SInt8, SInt16, SInt32, SInt64,
     Character, String,
     // Builtin types with one nested type
     Array,
     Slice,
     Input,
     Output,
     // User defined type with any number of nested types
     Instance(DefinitionId, u32),
+}
 #[derive(Debug, Clone, Eq, PartialEq)]
 pub struct ConcreteType {
     pub(crate) parts: Vec<ConcreteTypePart>
+}
 impl Default for ConcreteType {
     fn default() -> Self {
         Self{ parts: Vec::new() }
+    }
+}
 impl ConcreteType {
     pub(crate) fn has_marker(&self) -> bool {
         self.parts
             .iter()
             .any(|p| {
                 if let ConcreteTypePart::Marker(_) = p { true } else { false }
             })
+    }
+}
 // TODO: Remove at some point
 #[derive(Debug, Clone, PartialEq, Eq)]
 pub enum PrimitiveType {
     Unassigned,
     Input,
     Output,
     Message,
     Boolean,
     Byte,
     Short,
     Int,
     Long,
+}
 #[derive(Debug, Clone, PartialEq, Eq)]
 pub struct Type {
     pub primitive: PrimitiveType,
     pub array: bool,
+}
 #[allow(dead_code)]
 impl Type {
     pub const UNASSIGNED: Type = Type { primitive: PrimitiveType::Unassigned, array: false };
     pub const INPUT: Type = Type { primitive: PrimitiveType::Input, array: false };
     pub const OUTPUT: Type = Type { primitive: PrimitiveType::Output, array: false };
     pub const MESSAGE: Type = Type { primitive: PrimitiveType::Message, array: false };
     pub const BOOLEAN: Type = Type { primitive: PrimitiveType::Boolean, array: false };
     pub const BYTE: Type = Type { primitive: PrimitiveType::Byte, array: false };
     pub const SHORT: Type = Type { primitive: PrimitiveType::Short, array: false };
     pub const INT: Type = Type { primitive: PrimitiveType::Int, array: false };
     pub const LONG: Type = Type { primitive: PrimitiveType::Long, array: false };
     pub const INPUT_ARRAY: Type = Type { primitive: PrimitiveType::Input, array: true };
     pub const OUTPUT_ARRAY: Type = Type { primitive: PrimitiveType::Output, array: true };
     pub const MESSAGE_ARRAY: Type = Type { primitive: PrimitiveType::Message, array: true };
     pub const BOOLEAN_ARRAY: Type = Type { primitive: PrimitiveType::Boolean, array: true };
     pub const BYTE_ARRAY: Type = Type { primitive: PrimitiveType::Byte, array: true };
     pub const SHORT_ARRAY: Type = Type { primitive: PrimitiveType::Short, array: true };
     pub const INT_ARRAY: Type = Type { primitive: PrimitiveType::Int, array: true };
     pub const LONG_ARRAY: Type = Type { primitive: PrimitiveType::Long, array: true };
+}
 impl Display for Type {
     fn fmt(&self, f: &mut Formatter<'_>) -> fmt::Result {
         match &self.primitive {
             PrimitiveType::Unassigned => {
                 write!(f, "unassigned")?;
+            }
             PrimitiveType::Input => {
                 write!(f, "in")?;
+            }
             PrimitiveType::Output => {
                 write!(f, "out")?;
+            }
             PrimitiveType::Message => {
                 write!(f, "msg")?;
+            }
             PrimitiveType::Boolean => {
                 write!(f, "boolean")?;
+            }
             PrimitiveType::Byte => {
                 write!(f, "byte")?;
+            }
             PrimitiveType::Short => {
                 write!(f, "short")?;
+            }
             PrimitiveType::Int => {
                 write!(f, "int")?;
+            }
             PrimitiveType::Long => {
                 write!(f, "long")?;
+            }
+        }
         if self.array {
             write!(f, "[]")
         } else {
             Ok(())
+        }
+    }
+}
 #[derive(Debug, Clone)]
 pub enum Field {
     Length,
     Symbolic(FieldSymbolic),
+}
 impl Field {
     pub fn is_length(&self) -> bool {
         match self {
             Field::Length => true,
             _ => false,
+        }
+    }
     pub fn as_symbolic(&self) -> &FieldSymbolic {
         match self {
             Field::Symbolic(v) => v,
             _ => unreachable!("attempted to get Field::Symbolic from {:?}", self)
+        }
+    }
+}
 #[derive(Debug, Clone)]
 pub struct FieldSymbolic {
     // Phase 1: Parser
     pub(crate) identifier: Identifier,
     // Phase 3: Typing
     // TODO: @Monomorph These fields cannot be trusted because the last time it
     //  was typed it may refer to a different monomorph.
     pub(crate) definition: Option<DefinitionId>,
     pub(crate) field_idx: usize,
+}
 #[derive(Debug, Clone, Copy)]
 pub enum Scope {
     Definition(DefinitionId),
     Regular(BlockStatementId),
     Synchronous((SynchronousStatementId, BlockStatementId)),
+}
 impl Scope {
     pub fn is_block(&self) -> bool {
         match &self {
             Scope::Definition(_) => false,
             Scope::Regular(_) => true,
             Scope::Synchronous(_) => true,
+        }
+    }
     pub fn to_block(&self) -> BlockStatementId {
         match &self {
             Scope::Regular(id) => *id,
             Scope::Synchronous((_, id)) => *id,
             _ => panic!("unable to get BlockStatement from Scope")
+        }
+    }
+}
 #[derive(Debug, Clone)]
 pub enum VariableKind {
     Parameter,
     Local,
+}
 #[derive(Debug, Clone)]
 pub struct Variable {
     pub this: VariableId,
     // Parsing
     pub kind: VariableKind,
     pub parser_type: ParserType,
     pub identifier: Identifier,
     // Validator/linker
     pub relative_pos_in_block: u32,
     pub unique_id_in_scope: i32, // Temporary fix until proper bytecode/asm is generated
+}
 #[derive(Debug, Clone)]
 pub enum Definition {
     Struct(StructDefinition),
     Enum(EnumDefinition),
     Union(UnionDefinition),
     Component(ComponentDefinition),
     Function(FunctionDefinition),
+}
 impl Definition {
     pub fn is_struct(&self) -> bool {
         match self {
             Definition::Struct(_) => true,
             _ => false
+        }
+    }
     pub(crate) fn as_struct(&self) -> &StructDefinition {
         match self {
             Definition::Struct(result) => result,
             _ => panic!("Unable to cast 'Definition' to 'StructDefinition'"),
+        }
+    }
     pub(crate) fn as_struct_mut(&mut self) -> &mut StructDefinition {
         match self {
             Definition::Struct(result) => result,
             _ => panic!("Unable to cast 'Definition' to 'StructDefinition'"),
+        }
+    }
     pub fn is_enum(&self) -> bool {
         match self {
             Definition::Enum(_) => true,
             _ => false,
+        }
+    }
     pub(crate) fn as_enum(&self) -> &EnumDefinition {
         match self {
             Definition::Enum(result) => result,
             _ => panic!("Unable to cast 'Definition' to 'EnumDefinition'"),
+        }
+    }
     pub(crate) fn as_enum_mut(&mut self) -> &mut EnumDefinition {
         match self {
             Definition::Enum(result) => result,
             _ => panic!("Unable to cast 'Definition' to 'EnumDefinition'"),
+        }
+    }
     pub fn is_union(&self) -> bool {
         match self {
             Definition::Union(_) => true,
             _ => false,
+        }
+    }
     pub(crate) fn as_union(&self) -> &UnionDefinition {
         match self {
             Definition::Union(result) => result,
             _ => panic!("Unable to cast 'Definition' to 'UnionDefinition'"),
+        }
+    }
     pub(crate) fn as_union_mut(&mut self) -> &mut UnionDefinition {
         match self {
             Definition::Union(result) => result,
             _ => panic!("Unable to cast 'Definition' to 'UnionDefinition'"),
+        }
+    }
     pub fn is_component(&self) -> bool {
         match self {
             Definition::Component(_) => true,
             _ => false,
+        }
+    }
     pub(crate) fn as_component(&self) -> &ComponentDefinition {
         match self {
             Definition::Component(result) => result,
             _ => panic!("Unable to cast `Definition` to `Component`"),
+        }
+    }
     pub(crate) fn as_component_mut(&mut self) -> &mut ComponentDefinition {
         match self {
             Definition::Component(result) => result,
             _ => panic!("Unable to cast `Definition` to `Component`"),
+        }
+    }
     pub fn is_function(&self) -> bool {
         match self {
             Definition::Function(_) => true,
             _ => false,
+        }
+    }
     pub(crate) fn as_function(&self) -> &FunctionDefinition {
         match self {
             Definition::Function(result) => result,
             _ => panic!("Unable to cast `Definition` to `Function`"),
+        }
+    }
     pub(crate) fn as_function_mut(&mut self) -> &mut FunctionDefinition {
         match self {
             Definition::Function(result) => result,
             _ => panic!("Unable to cast `Definition` to `Function`"),
+        }
+    }
     pub fn parameters(&self) -> &Vec<VariableId> {
         match self {
             Definition::Component(def) => &def.parameters,
             Definition::Function(def) => &def.parameters,
             _ => panic!("Called parameters() on {:?}", self)
+        }
+    }
     pub fn defined_in(&self) -> RootId {
         match self {
             Definition::Struct(def) => def.defined_in,
             Definition::Enum(def) => def.defined_in,
             Definition::Union(def) => def.defined_in,
             Definition::Component(def) => def.defined_in,
             Definition::Function(def) => def.defined_in,
+        }
+    }
     pub fn identifier(&self) -> &Identifier {
         match self {
             Definition::Struct(def) => &def.identifier,
             Definition::Enum(def) => &def.identifier,
             Definition::Union(def) => &def.identifier,
             Definition::Component(def) => &def.identifier,
             Definition::Function(def) => &def.identifier,
+        }
+    }
     pub fn poly_vars(&self) -> &Vec<Identifier> {
         match self {
             Definition::Struct(def) => &def.poly_vars,
             Definition::Enum(def) => &def.poly_vars,
             Definition::Union(def) => &def.poly_vars,
             Definition::Component(def) => &def.poly_vars,
             Definition::Function(def) => &def.poly_vars,
+        }
+    }
+}
 #[derive(Debug, Clone)]
 pub struct StructFieldDefinition {
     pub span: InputSpan,
     pub field: Identifier,
     pub parser_type: ParserType,
+}
 #[derive(Debug, Clone)]
 pub struct StructDefinition {
     pub this: StructDefinitionId,
     pub defined_in: RootId,
     // Phase 1: symbol scanning
     pub span: InputSpan,
     pub identifier: Identifier,
     pub poly_vars: Vec<Identifier>,
     // Phase 2: parsing
     pub fields: Vec<StructFieldDefinition>
+}
 impl StructDefinition {
     pub(crate) fn new_empty(
         this: StructDefinitionId, defined_in: RootId, span: InputSpan,
         identifier: Identifier, poly_vars: Vec<Identifier>
     ) -> Self {
         Self{ this, defined_in, span, identifier, poly_vars, fields: Vec::new() }
+    }
+}
 #[derive(Debug, Clone)]
 pub enum EnumVariantValue {
     None,
     Integer(i64),
+}
 #[derive(Debug, Clone)]
 pub struct EnumVariantDefinition {
     pub identifier: Identifier,
     pub value: EnumVariantValue,
+}
 #[derive(Debug, Clone)]
 pub struct EnumDefinition {
     pub this: EnumDefinitionId,
     pub defined_in: RootId,
     // Phase 1: symbol scanning
     pub span: InputSpan,
     pub identifier: Identifier,
     pub poly_vars: Vec<Identifier>,
     // Phase 2: parsing
     pub variants: Vec<EnumVariantDefinition>,
+}
 impl EnumDefinition {
     pub(crate) fn new_empty(
         this: EnumDefinitionId, defined_in: RootId, span: InputSpan,
         identifier: Identifier, poly_vars: Vec<Identifier>
     ) -> Self {
         Self{ this, defined_in, span, identifier, poly_vars, variants: Vec::new() }
+    }
+}
 #[derive(Debug, Clone)]
 pub enum UnionVariantValue {
     None,
     Embedded(Vec<ParserType>),
+}
 #[derive(Debug, Clone)]
 pub struct UnionVariantDefinition {
     pub span: InputSpan,
     pub identifier: Identifier,
     pub value: UnionVariantValue,
+}
 #[derive(Debug, Clone)]
 pub struct UnionDefinition {
     pub this: UnionDefinitionId,
     pub defined_in: RootId,
     // Phase 1: symbol scanning
     pub span: InputSpan,
     pub identifier: Identifier,
     pub poly_vars: Vec<Identifier>,
     // Phase 2: parsing
     pub variants: Vec<UnionVariantDefinition>,
+}
 impl UnionDefinition {
     pub(crate) fn new_empty(
         this: UnionDefinitionId, defined_in: RootId, span: InputSpan,
         identifier: Identifier, poly_vars: Vec<Identifier>
     ) -> Self {
         Self{ this, defined_in, span, identifier, poly_vars, variants: Vec::new() }

src/protocol/ast_printer.rs

➞

Show inline comments

@@ @@ -482,493 +482,486 @@ impl ASTWriter { @@
                 self.kv(indent).with_id(PREFIX_ENDWHILE_STMT_ID, stmt.this.0.index)
                     .with_s_key("EndWhile");
                 self.kv(indent2).with_s_key("StartWhile").with_disp_val(&stmt.start_while.0.index);
                 self.kv(indent2).with_s_key("Next").with_disp_val(&stmt.next.index);
             },
             Statement::Break(stmt) => {
                 self.kv(indent).with_id(PREFIX_BREAK_STMT_ID, stmt.this.0.index)
                     .with_s_key("Break");
                 self.kv(indent2).with_s_key("Label")
                     .with_opt_identifier_val(stmt.label.as_ref());
                 self.kv(indent2).with_s_key("Target")
                     .with_opt_disp_val(stmt.target.as_ref().map(|v| &v.0.index));
             },
             Statement::Continue(stmt) => {
                 self.kv(indent).with_id(PREFIX_CONTINUE_STMT_ID, stmt.this.0.index)
                     .with_s_key("Continue");
                 self.kv(indent2).with_s_key("Label")
                     .with_opt_identifier_val(stmt.label.as_ref());
                 self.kv(indent2).with_s_key("Target")
                     .with_opt_disp_val(stmt.target.as_ref().map(|v| &v.0.index));
             },
             Statement::Synchronous(stmt) => {
                 self.kv(indent).with_id(PREFIX_SYNC_STMT_ID, stmt.this.0.index)
                     .with_s_key("Synchronous");
                 self.kv(indent2).with_s_key("EndSync").with_disp_val(&stmt.end_sync.0.index);
                 self.kv(indent2).with_s_key("Body");
                 self.write_stmt(heap, stmt.body.upcast(), indent3);
             },
             Statement::EndSynchronous(stmt) => {
                 self.kv(indent).with_id(PREFIX_ENDSYNC_STMT_ID, stmt.this.0.index)
                     .with_s_key("EndSynchronous");
                 self.kv(indent2).with_s_key("StartSync").with_disp_val(&stmt.start_sync.0.index);
                 self.kv(indent2).with_s_key("Next").with_disp_val(&stmt.next.index);
             },
             Statement::Return(stmt) => {
                 self.kv(indent).with_id(PREFIX_RETURN_STMT_ID, stmt.this.0.index)
                     .with_s_key("Return");
                 self.kv(indent2).with_s_key("Expressions");
                 for expr_id in &stmt.expressions {
                     self.write_expr(heap, *expr_id, indent3);
+                }
             },
             Statement::Goto(stmt) => {
                 self.kv(indent).with_id(PREFIX_GOTO_STMT_ID, stmt.this.0.index)
                     .with_s_key("Goto");
                 self.kv(indent2).with_s_key("Label").with_identifier_val(&stmt.label);
                 self.kv(indent2).with_s_key("Target")
                     .with_opt_disp_val(stmt.target.as_ref().map(|v| &v.0.index));
             },
             Statement::New(stmt) => {
                 self.kv(indent).with_id(PREFIX_NEW_STMT_ID, stmt.this.0.index)
                     .with_s_key("New");
                 self.kv(indent2).with_s_key("Expression");
                 self.write_expr(heap, stmt.expression.upcast(), indent3);
                 self.kv(indent2).with_s_key("Next").with_disp_val(&stmt.next.index);
             },
             Statement::Expression(stmt) => {
                 self.kv(indent).with_id(PREFIX_EXPR_STMT_ID, stmt.this.0.index)
                     .with_s_key("ExpressionStatement");
                 self.write_expr(heap, stmt.expression, indent2);
                 self.kv(indent2).with_s_key("Next").with_disp_val(&stmt.next.index);
+            }
+        }
+    }
     fn write_expr(&mut self, heap: &Heap, expr_id: ExpressionId, indent: usize) {
         let expr = &heap[expr_id];
         let indent2 = indent + 1;
         let indent3 = indent2 + 1;
         let def_id = self.cur_definition.unwrap();
         match expr {
             Expression::Assignment(expr) => {
                 self.kv(indent).with_id(PREFIX_ASSIGNMENT_EXPR_ID, expr.this.0.index)
                     .with_s_key("AssignmentExpr");
                 self.kv(indent2).with_s_key("Operation").with_debug_val(&expr.operation);
                 self.kv(indent2).with_s_key("Left");
                 self.write_expr(heap, expr.left, indent3);
                 self.kv(indent2).with_s_key("Right");
                 self.write_expr(heap, expr.right, indent3);
                 self.kv(indent2).with_s_key("Parent")
                     .with_custom_val(|v| write_expression_parent(v, &expr.parent));
                 self.kv(indent2).with_s_key("ConcreteType")
                     .with_custom_val(|v| write_concrete_type(v, heap, def_id, &expr.concrete_type));
             },
             Expression::Binding(expr) => {
                 self.kv(indent).with_id(PREFIX_BINARY_EXPR_ID, expr.this.0.index)
                     .with_s_key("BindingExpr");
                 self.kv(indent2).with_s_key("LeftExpression");
                 self.write_expr(heap, expr.left.upcast(), indent3);
                 self.kv(indent2).with_s_key("RightExpression");
                 self.write_expr(heap, expr.right, indent3);
                 self.kv(indent2).with_s_key("Parent")
                     .with_custom_val(|v| write_expression_parent(v, &expr.parent));
                 self.kv(indent2).with_s_key("ConcreteType")
                     .with_custom_val(|v| write_concrete_type(v, heap, def_id, &expr.concrete_type));
             },
             Expression::Conditional(expr) => {
                 self.kv(indent).with_id(PREFIX_CONDITIONAL_EXPR_ID, expr.this.0.index)
                     .with_s_key("ConditionalExpr");
                 self.kv(indent2).with_s_key("Condition");
                 self.write_expr(heap, expr.test, indent3);
                 self.kv(indent2).with_s_key("TrueExpression");
                 self.write_expr(heap, expr.true_expression, indent3);
                 self.kv(indent2).with_s_key("FalseExpression");
                 self.write_expr(heap, expr.false_expression, indent3);
                 self.kv(indent2).with_s_key("Parent")
                     .with_custom_val(|v| write_expression_parent(v, &expr.parent));
                 self.kv(indent2).with_s_key("ConcreteType")
                     .with_custom_val(|v| write_concrete_type(v, heap, def_id, &expr.concrete_type));
             },
             Expression::Binary(expr) => {
                 self.kv(indent).with_id(PREFIX_BINARY_EXPR_ID, expr.this.0.index)
                     .with_s_key("BinaryExpr");
                 self.kv(indent2).with_s_key("Operation").with_debug_val(&expr.operation);
                 self.kv(indent2).with_s_key("Left");
                 self.write_expr(heap, expr.left, indent3);
                 self.kv(indent2).with_s_key("Right");
                 self.write_expr(heap, expr.right, indent3);
                 self.kv(indent2).with_s_key("Parent")
                     .with_custom_val(|v| write_expression_parent(v, &expr.parent));
                 self.kv(indent2).with_s_key("ConcreteType")
                     .with_custom_val(|v| write_concrete_type(v, heap, def_id, &expr.concrete_type));
             },
             Expression::Unary(expr) => {
                 self.kv(indent).with_id(PREFIX_UNARY_EXPR_ID, expr.this.0.index)
                     .with_s_key("UnaryExpr");
                 self.kv(indent2).with_s_key("Operation").with_debug_val(&expr.operation);
                 self.kv(indent2).with_s_key("Argument");
                 self.write_expr(heap, expr.expression, indent3);
                 self.kv(indent2).with_s_key("Parent")
                     .with_custom_val(|v| write_expression_parent(v, &expr.parent));
                 self.kv(indent2).with_s_key("ConcreteType")
                     .with_custom_val(|v| write_concrete_type(v, heap, def_id, &expr.concrete_type));
             },
             Expression::Indexing(expr) => {
                 self.kv(indent).with_id(PREFIX_INDEXING_EXPR_ID, expr.this.0.index)
                     .with_s_key("IndexingExpr");
                 self.kv(indent2).with_s_key("Subject");
                 self.write_expr(heap, expr.subject, indent3);
                 self.kv(indent2).with_s_key("Index");
                 self.write_expr(heap, expr.index, indent3);
                 self.kv(indent2).with_s_key("Parent")
                     .with_custom_val(|v| write_expression_parent(v, &expr.parent));
                 self.kv(indent2).with_s_key("ConcreteType")
                     .with_custom_val(|v| write_concrete_type(v, heap, def_id, &expr.concrete_type));
             },
             Expression::Slicing(expr) => {
                 self.kv(indent).with_id(PREFIX_SLICING_EXPR_ID, expr.this.0.index)
                     .with_s_key("SlicingExpr");
                 self.kv(indent2).with_s_key("Subject");
                 self.write_expr(heap, expr.subject, indent3);
                 self.kv(indent2).with_s_key("FromIndex");
                 self.write_expr(heap, expr.from_index, indent3);
                 self.kv(indent2).with_s_key("ToIndex");
                 self.write_expr(heap, expr.to_index, indent3);
                 self.kv(indent2).with_s_key("Parent")
                     .with_custom_val(|v| write_expression_parent(v, &expr.parent));
                 self.kv(indent2).with_s_key("ConcreteType")
                     .with_custom_val(|v| write_concrete_type(v, heap, def_id, &expr.concrete_type));
             },
             Expression::Select(expr) => {
                 self.kv(indent).with_id(PREFIX_SELECT_EXPR_ID, expr.this.0.index)
                     .with_s_key("SelectExpr");
                 self.kv(indent2).with_s_key("Subject");
                 self.write_expr(heap, expr.subject, indent3);
                 match &expr.field {
                     Field::Length => {
                         self.kv(indent2).with_s_key("Field").with_s_val("length");
                     },
                     Field::Symbolic(field) => {
                         self.kv(indent2).with_s_key("Field").with_identifier_val(&field.identifier);
                         self.kv(indent3).with_s_key("Definition").with_opt_disp_val(field.definition.as_ref().map(|v| &v.index));
                         self.kv(indent3).with_s_key("Index").with_disp_val(&field.field_idx);
+                    }
+                }
                 self.kv(indent2).with_s_key("Parent")
                     .with_custom_val(|v| write_expression_parent(v, &expr.parent));
                 self.kv(indent2).with_s_key("ConcreteType")
                     .with_custom_val(|v| write_concrete_type(v, heap, def_id, &expr.concrete_type));
             },
             Expression::Literal(expr) => {
                 self.kv(indent).with_id(PREFIX_LITERAL_EXPR_ID, expr.this.0.index)
                     .with_s_key("LiteralExpr");
                 let val = self.kv(indent2).with_s_key("Value");
                 match &expr.value {
                     Literal::Null => { val.with_s_val("null"); },
                     Literal::True => { val.with_s_val("true"); },
                     Literal::False => { val.with_s_val("false"); },
                     Literal::Character(data) => { val.with_disp_val(data); },
                     Literal::String(data) => {
                         // Stupid hack
                         let string = String::from(data.as_str());
                         val.with_disp_val(&string);
                     },
                     Literal::Integer(data) => { val.with_debug_val(data); },
                     Literal::Struct(data) => {
                         val.with_s_val("Struct");
                         let indent4 = indent3 + 1;
                         self.kv(indent3).with_s_key("ParserType")
                             .with_custom_val(|t| write_parser_type(t, heap, &data.parser_type));
                         self.kv(indent3).with_s_key("Definition").with_disp_val(&data.definition.index);
                         for field in &data.fields {
                             self.kv(indent3).with_s_key("Field");
                             self.kv(indent4).with_s_key("Name").with_identifier_val(&field.identifier);
                             self.kv(indent4).with_s_key("Index").with_disp_val(&field.field_idx);
                             self.kv(indent4).with_s_key("ParserType");
                             self.write_expr(heap, field.value, indent4 + 1);
+                        }
                     },
                     Literal::Enum(data) => {
                         val.with_s_val("Enum");
                         self.kv(indent3).with_s_key("ParserType")
                             .with_custom_val(|t| write_parser_type(t, heap, &data.parser_type));
                         self.kv(indent3).with_s_key("Definition").with_disp_val(&data.definition.index);
                         self.kv(indent3).with_s_key("VariantIdx").with_disp_val(&data.variant_idx);
                     },
                     Literal::Union(data) => {
                         val.with_s_val("Union");
                         let indent4 = indent3 + 1;
                         self.kv(indent3).with_s_key("ParserType")
                             .with_custom_val(|t| write_parser_type(t, heap, &data.parser_type));
                         self.kv(indent3).with_s_key("Definition").with_disp_val(&data.definition.index);
                         self.kv(indent3).with_s_key("VariantIdx").with_disp_val(&data.variant_idx);
                         for value in &data.values {
                             self.kv(indent3).with_s_key("Value");
                             self.write_expr(heap, *value, indent4);
+                        }
+                    }
                     Literal::Array(data) => {
                         val.with_s_val("Array");
                         let indent4 = indent3 + 1;
                         self.kv(indent3).with_s_key("Elements");
                         for expr_id in data {
                             self.write_expr(heap, *expr_id, indent4);
+                        }
+                    }
+                }
                 self.kv(indent2).with_s_key("Parent")
                     .with_custom_val(|v| write_expression_parent(v, &expr.parent));
                 self.kv(indent2).with_s_key("ConcreteType")
                     .with_custom_val(|v| write_concrete_type(v, heap, def_id, &expr.concrete_type));
             },
             Expression::Call(expr) => {
                 self.kv(indent).with_id(PREFIX_CALL_EXPR_ID, expr.this.0.index)
                     .with_s_key("CallExpr");
                 let definition = &heap[expr.definition];
                 match definition {
                     Definition::Component(definition) => {
                         self.kv(indent2).with_s_key("BuiltIn").with_disp_val(&false);
                         self.kv(indent2).with_s_key("Variant").with_debug_val(&definition.variant);
                     },
                     Definition::Function(definition) => {
                         self.kv(indent2).with_s_key("BuiltIn").with_disp_val(&definition.builtin);
                         self.kv(indent2).with_s_key("Variant").with_s_val("Function");
                     },
                     _ => unreachable!()
+                }
                 self.kv(indent2).with_s_key("MethodName").with_identifier_val(definition.identifier());
                 self.kv(indent2).with_s_key("ParserType")
                     .with_custom_val(|t| write_parser_type(t, heap, &expr.parser_type));
                 // Arguments
                 self.kv(indent2).with_s_key("Arguments");
                 for arg_id in &expr.arguments {
                     self.write_expr(heap, *arg_id, indent3);
+                }
                 // Parent
                 self.kv(indent2).with_s_key("Parent")
                     .with_custom_val(|v| write_expression_parent(v, &expr.parent));
                 self.kv(indent2).with_s_key("ConcreteType")
                     .with_custom_val(|v| write_concrete_type(v, heap, def_id, &expr.concrete_type));
             },
             Expression::Variable(expr) => {
                 self.kv(indent).with_id(PREFIX_VARIABLE_EXPR_ID, expr.this.0.index)
                     .with_s_key("VariableExpr");
                 self.kv(indent2).with_s_key("Name").with_identifier_val(&expr.identifier);
                 self.kv(indent2).with_s_key("Definition")
                     .with_opt_disp_val(expr.declaration.as_ref().map(|v| &v.index));
                 self.kv(indent2).with_s_key("Parent")
                     .with_custom_val(|v| write_expression_parent(v, &expr.parent));
                 self.kv(indent2).with_s_key("ConcreteType")
                     .with_custom_val(|v| write_concrete_type(v, heap, def_id, &expr.concrete_type));
+            }
+        }
+    }
     fn write_variable(&mut self, heap: &Heap, variable_id: VariableId, indent: usize) {
         let var = &heap[variable_id];
         let indent2 = indent + 1;
         self.kv(indent).with_id(PREFIX_VARIABLE_ID, variable_id.index)
             .with_s_key("Variable");
         self.kv(indent2).with_s_key("Name").with_identifier_val(&var.identifier);
         self.kv(indent2).with_s_key("Kind").with_debug_val(&var.kind);
         self.kv(indent2).with_s_key("ParserType")
             .with_custom_val(|w| write_parser_type(w, heap, &var.parser_type));
         self.kv(indent2).with_s_key("RelativePos").with_disp_val(&var.relative_pos_in_block);
         self.kv(indent2).with_s_key("UniqueScopeID").with_disp_val(&var.unique_id_in_scope);
+    }
     //--------------------------------------------------------------------------
     // Printing Utilities
     //--------------------------------------------------------------------------
     fn kv(&mut self, indent: usize) -> KV {
         KV::new(&mut self.buffer, &mut self.temp1, &mut self.temp2, indent)
+    }
     fn flush<W: IOWrite>(&mut self, w: &mut W) {
         w.write(self.buffer.as_bytes()).unwrap();
         self.buffer.clear()
+    }
+}
 fn write_option<V: Display>(target: &mut String, value: Option<V>) {
     target.clear();
     match &value {
         Some(v) => target.push_str(&format!("Some({})", v)),
         None => target.push_str("None")
     };
+}
 fn write_parser_type(target: &mut String, heap: &Heap, t: &ParserType) {
     use ParserTypeVariant as PTV;
     fn write_element(target: &mut String, heap: &Heap, t: &ParserType, mut element_idx: usize) -> usize {
         let element = &t.elements[element_idx];
         match &element.variant {
             PTV::Void => target.push_str("void"),
             PTV::InputOrOutput => {
                 target.push_str("portlike<");
                 element_idx = write_element(target, heap, t, element_idx + 1);
                 target.push('>');
             },
             PTV::ArrayLike => {
                 element_idx = write_element(target, heap, t, element_idx + 1);
                 target.push_str("[???]");
             },
             PTV::IntegerLike => target.push_str("integerlike"),
             PTV::Message => { target.push_str(KW_TYPE_MESSAGE_STR); },
             PTV::Bool => { target.push_str(KW_TYPE_BOOL_STR); },
             PTV::UInt8 => { target.push_str(KW_TYPE_UINT8_STR); },
             PTV::UInt16 => { target.push_str(KW_TYPE_UINT16_STR); },
             PTV::UInt32 => { target.push_str(KW_TYPE_UINT32_STR); },
             PTV::UInt64 => { target.push_str(KW_TYPE_UINT64_STR); },
             PTV::SInt8 => { target.push_str(KW_TYPE_SINT8_STR); },
             PTV::SInt16 => { target.push_str(KW_TYPE_SINT16_STR); },
             PTV::SInt32 => { target.push_str(KW_TYPE_SINT32_STR); },
             PTV::SInt64 => { target.push_str(KW_TYPE_SINT64_STR); },
             PTV::Character => { target.push_str(KW_TYPE_CHAR_STR); },
             PTV::String => { target.push_str(KW_TYPE_STRING_STR); },
             PTV::IntegerLiteral => { target.push_str("int_literal"); },
             PTV::Inferred => { target.push_str(KW_TYPE_INFERRED_STR); },
             PTV::Array => {
                 element_idx = write_element(target, heap, t, element_idx + 1);
                 target.push_str("[]");
             },
             PTV::Input => {
                 target.push_str(KW_TYPE_IN_PORT_STR);
                 target.push('<');
                 element_idx = write_element(target, heap, t, element_idx + 1);
                 target.push('>');
             },
             PTV::Output => {
                 target.push_str(KW_TYPE_OUT_PORT_STR);
                 target.push('<');
                 element_idx = write_element(target, heap, t, element_idx + 1);
                 target.push('>');
             },
             PTV::PolymorphicArgument(definition_id, arg_idx) => {
                 let definition = &heap[*definition_id];
                 let poly_var = &definition.poly_vars()[*arg_idx].value;
+                let poly_var = &definition.poly_vars()[*arg_idx as usize].value;
                 target.push_str(poly_var.as_str());
             },
             PTV::Definition(definition_id, num_embedded) => {
                 let definition = &heap[*definition_id];
                 let definition_ident = definition.identifier().value.as_str();
                 target.push_str(definition_ident);
                 let num_embedded = *num_embedded;
                 if num_embedded != 0 {
                     target.push('<');
                     for embedded_idx in 0..num_embedded {
                         if embedded_idx != 0 {
                             target.push(',');
+                        }
                         element_idx = write_element(target, heap, t, element_idx + 1);
+                    }
                     target.push('>');
+                }
+            }
+        }
         element_idx
+    }
     write_element(target, heap, t, 0);
+}
 // TODO: @Cleanup, this is littered at three places in the codebase
 fn write_concrete_type(target: &mut String, heap: &Heap, def_id: DefinitionId, t: &ConcreteType) {
     use ConcreteTypePart as CTP;
     fn write_concrete_part(target: &mut String, heap: &Heap, def_id: DefinitionId, t: &ConcreteType, mut idx: usize) -> usize {
         if idx >= t.parts.len() {
             return idx;
+        }
         match &t.parts[idx] {
             CTP::Marker(marker) => {
                 // Marker points to polymorphic variable index
                 let definition = &heap[def_id];
                 let poly_var_ident = &definition.poly_vars()[*marker];
                 target.push_str(poly_var_ident.value.as_str());
                 idx = write_concrete_part(target, heap, def_id, t, idx + 1);
             },
             CTP::Void => target.push_str("void"),
             CTP::Message => target.push_str("msg"),
             CTP::Bool => target.push_str("bool"),
             CTP::UInt8 => target.push_str(KW_TYPE_UINT8_STR),
             CTP::UInt16 => target.push_str(KW_TYPE_UINT16_STR),
             CTP::UInt32 => target.push_str(KW_TYPE_UINT32_STR),
             CTP::UInt64 => target.push_str(KW_TYPE_UINT64_STR),
             CTP::SInt8 => target.push_str(KW_TYPE_SINT8_STR),
             CTP::SInt16 => target.push_str(KW_TYPE_SINT16_STR),
             CTP::SInt32 => target.push_str(KW_TYPE_SINT32_STR),
             CTP::SInt64 => target.push_str(KW_TYPE_SINT64_STR),
             CTP::Character => target.push_str(KW_TYPE_CHAR_STR),
             CTP::String => target.push_str(KW_TYPE_STRING_STR),
             CTP::Array => {
                 idx = write_concrete_part(target, heap, def_id, t, idx + 1);
                 target.push_str("[]");
             },
             CTP::Slice => {
                 idx = write_concrete_part(target, heap, def_id, t, idx + 1);
                 target.push_str("[..]");
+            }
             CTP::Input => {
                 target.push_str("in<");
                 idx = write_concrete_part(target, heap, def_id, t, idx + 1);
                 target.push('>');
             },
             CTP::Output => {
                 target.push_str("out<");
                 idx = write_concrete_part(target, heap, def_id, t, idx + 1);
                 target.push('>')
             },
             CTP::Instance(definition_id, num_embedded) => {
                 let identifier = heap[*definition_id].identifier();
                 target.push_str(identifier.value.as_str());
                 target.push('<');
                 for idx_embedded in 0..*num_embedded {
                     if idx_embedded != 0 {
                         target.push_str(", ");
+                    }
                     idx = write_concrete_part(target, heap, def_id, t, idx + 1);
+                }
                 target.push('>');
+            }
+        }
         idx + 1
+    }
     write_concrete_part(target, heap, def_id, t, 0);
+}
 fn write_expression_parent(target: &mut String, parent: &ExpressionParent) {
     use ExpressionParent as EP;
     *target = match parent {
         EP::None => String::from("None"),
         EP::If(id) => format!("IfStmt({})", id.0.index),
         EP::While(id) => format!("WhileStmt({})", id.0.index),
         EP::Return(id) => format!("ReturnStmt({})", id.0.index),
         EP::New(id) => format!("NewStmt({})", id.0.index),
         EP::ExpressionStmt(id) => format!("ExprStmt({})", id.0.index),
         EP::Expression(id, idx) => format!("Expr({}, {})", id.index, idx)
     };
+}
@@ \ No newline at end of file @@

src/protocol/eval/value.rs

➞

Show inline comments

 use super::store::*;
 use crate::PortId;
 use crate::protocol::ast::{
     AssignmentOperator,
     BinaryOperator,
     UnaryOperator,
 };
 pub type StackPos = u32;
 pub type HeapPos = u32;
 #[derive(Debug, Copy, Clone)]
 pub enum ValueId {
     Stack(StackPos), // place on stack
     Heap(HeapPos, u32), // allocated region + values within that region
+}
 /// Represents a value stored on the stack or on the heap. Some values contain
 /// a `HeapPos`, implying that they're stored in the store's `Heap`. Clearing
 /// a `Value` with a `HeapPos` from a stack must also clear the associated
 /// region from the `Heap`.
 #[derive(Debug, Clone)]
 pub enum Value {
     // Special types, never encountered during evaluation if the compiler works correctly
     Unassigned,                 // Marker when variables are first declared, immediately followed by assignment
     PrevStackBoundary(isize),   // Marker for stack frame beginning, so we can pop stack values
     Ref(ValueId),               // Reference to a value, used by expressions producing references
     // Builtin types
     Input(PortId),
     Output(PortId),
     Message(HeapPos),
     Null,
     Bool(bool),
     Char(char),
     String(HeapPos),
     UInt8(u8),
     UInt16(u16),
     UInt32(u32),
     UInt64(u64),
     SInt8(i8),
     SInt16(i16),
     SInt32(i32),
     SInt64(i64),
     Array(HeapPos),
     // Instances of user-defined types
     Enum(i64),
     Union(i64, HeapPos),
     Struct(HeapPos),
+}
 macro_rules! impl_union_unpack_as_value {
     ($func_name:ident, $variant_name:path, $return_type:ty) => {
         impl Value {
             pub(crate) fn $func_name(&self) -> $return_type {
                 match self {
                     $variant_name(v) => *v,
                     _ => panic!(concat!("called ", stringify!($func_name()), " on {:?}"), self),
+                }
+            }
+        }
+    }
+}
 impl_union_unpack_as_value!(as_stack_boundary, Value::PrevStackBoundary, isize);
 impl_union_unpack_as_value!(as_ref,     Value::Ref,     ValueId);
 impl_union_unpack_as_value!(as_input,   Value::Input,   PortId);
 impl_union_unpack_as_value!(as_output,  Value::Output,  PortId);
 impl_union_unpack_as_value!(as_message, Value::Message, HeapPos);
 impl_union_unpack_as_value!(as_bool,    Value::Bool,    bool);
 impl_union_unpack_as_value!(as_char,    Value::Char,    char);
 impl_union_unpack_as_value!(as_string,  Value::String,  HeapPos);
 impl_union_unpack_as_value!(as_uint8,   Value::UInt8,   u8);
 impl_union_unpack_as_value!(as_uint16,  Value::UInt16,  u16);
 impl_union_unpack_as_value!(as_uint32,  Value::UInt32,  u32);
 impl_union_unpack_as_value!(as_uint64,  Value::UInt64,  u64);
 impl_union_unpack_as_value!(as_sint8,   Value::SInt8,   i8);
 impl_union_unpack_as_value!(as_sint16,  Value::SInt16,  i16);
 impl_union_unpack_as_value!(as_sint32,  Value::SInt32,  i32);
 impl_union_unpack_as_value!(as_sint64,  Value::SInt64,  i64);
 impl_union_unpack_as_value!(as_array,   Value::Array,   HeapPos);
 impl_union_unpack_as_value!(as_enum,    Value::Enum,    i64);
 impl_union_unpack_as_value!(as_struct,  Value::Struct,  HeapPos);
 impl Value {
     pub(crate) fn as_union(&self) -> (i64, HeapPos) {
         match self {
             Value::Union(tag, v) => (*tag, *v),
             _ => panic!("called as_union on {:?}", self),
+        }
+    }
     pub(crate) fn is_integer(&self) -> bool {
         match self {
             Value::UInt8(_) | Value::UInt16(_) | Value::UInt32(_) | Value::UInt64(_) |
             Value::SInt8(_) | Value::SInt16(_) | Value::SInt32(_) | Value::SInt64(_) => true,
             _ => false
+        }
+    }
     pub(crate) fn is_unsigned_integer(&self) -> bool {
         match self {
             Value::UInt8(_) | Value::UInt16(_) | Value::UInt32(_) | Value::UInt64(_) => true,
             _ => false
+        }
+    }
     pub(crate) fn is_signed_integer(&self) -> bool {
         match self {
             Value::SInt8(_) | Value::SInt16(_) | Value::SInt32(_) | Value::SInt64(_) => true,
             _ => false
+        }
+    }
     pub(crate) fn as_unsigned_integer(&self) -> u64 {
         match self {
             Value::UInt8(v)  => *v as u64,
             Value::UInt16(v) => *v as u64,
             Value::UInt32(v) => *v as u64,
             Value::UInt64(v) => *v as u64,
             _ => unreachable!("called as_unsigned_integer on {:?}", self),
+        }
+    }
     pub(crate) fn as_signed_integer(&self) -> i64 {
         match self {
             Value::SInt8(v)  => *v as i64,
             Value::SInt16(v) => *v as i64,
             Value::SInt32(v) => *v as i64,
             Value::SInt64(v) => *v as i64,
             _ => unreachable!("called as_signed_integer on {:?}", self)
+        }
+    }
     /// Returns the heap position associated with the value. If the value
     /// doesn't store anything in the heap then we return `None`.
     pub(crate) fn get_heap_pos(&self) -> Option<HeapPos> {
         match self {
             Value::Message(v) => Some(*v),
             Value::Array(v) => Some(*v),
             Value::Union(_, v) => Some(*v),
             Value::Struct(v) => Some(*v),
             _ => None
+        }
+    }
+}
 /// When providing arguments to a new component, or when transferring values
 /// from one component's store to a newly instantiated component, one has to
 /// transfer stack and heap values. This `ValueGroup` represents such a
 /// temporary group of values with potential heap allocations.
 ///
 /// Constructing such a ValueGroup manually requires some extra care to make
 /// sure all elements of `values` point to valid elements of `regions`.
 ///
 /// Again: this is a temporary thing, hopefully removed once we move to a
 /// bytecode interpreter.
 pub struct ValueGroup {
     pub(crate) values: Vec<Value>,
     pub(crate) regions: Vec<Vec<Value>>
+}
 impl ValueGroup {
     pub(crate) fn new_stack(values: Vec<Value>) -> Self {
         debug_assert!(values.iter().all(|v| v.get_heap_pos().is_none()));
         Self{
             values,
             regions: Vec::new(),
+        }
+    }
     pub(crate) fn from_store(store: &Store, values: &[Value]) -> Self {
         let mut group = ValueGroup{
             values: Vec::with_capacity(values.len()),
             regions: Vec::with_capacity(values.len()), // estimation
         };
         for value in values {
             let transferred = group.retrieve_value(value, store);
             group.values.push(transferred);
+        }
         group
+    }
     /// Transfers a provided value from a store into a local value with its
     /// heap allocations (if any) stored in the ValueGroup. Calling this
     /// function will not store the returned value in the `values` member.
     fn retrieve_value(&mut self, value: &Value, from_store: &Store) -> Value {
         if let Some(heap_pos) = value.get_heap_pos() {
             // Value points to a heap allocation, so transfer the heap values
             // internally.
             let from_region = &from_store.heap_regions[heap_pos as usize].values;
             let mut new_region = Vec::with_capacity(from_region.len());
             for value in from_region {
                 let transferred = self.retrieve_value(value, from_store);
                 new_region.push(transferred);
+            }
             // Region is constructed, store internally and return the new value.
             let new_region_idx = self.regions.len() as HeapPos;
             self.regions.push(new_region);
             return match value {
                 Value::Message(_)    => Value::Message(new_region_idx),
                 Value::String(_)     => Value::String(new_region_idx),
                 Value::Array(_)      => Value::Array(new_region_idx),
                 Value::Union(tag, _) => Value::Union(*tag, new_region_idx),
                 Value::Struct(_)     => Value::Struct(new_region_idx),
                 _ => unreachable!(),
             };
         } else {
             return value.clone();
+        }
+    }
     /// Transfers the heap values and the stack values into the store. Stack
     /// values are pushed onto the Store's stack in the order in which they
     /// appear in the value group.
     pub(crate) fn into_store(self, store: &mut Store) {
         for value in &self.values {
             let transferred = self.provide_value(value, store);
             store.stack.push(transferred);
+        }
+    }
     fn provide_value(&self, value: &Value, to_store: &mut Store) -> Value {
         if let Some(from_heap_pos) = value.get_heap_pos() {
             let from_heap_pos = from_heap_pos as usize;
             let to_heap_pos = to_store.alloc_heap();
             let to_heap_pos_usize = to_heap_pos as usize;
             to_store.heap_regions[to_heap_pos_usize].values.reserve(self.regions[from_heap_pos].len());
             for value in &self.regions[from_heap_pos as usize] {
                 let transferred = self.provide_value(value, to_store);
                 to_store.heap_regions[to_heap_pos_usize].values.push(transferred);
+            }
             return match value {
                 Value::Message(_)    => Value::Message(to_heap_pos),
                 Value::String(_)     => Value::String(to_heap_pos),
                 Value::Array(_)      => Value::Array(to_heap_pos),
                 Value::Union(tag, _) => Value::Union(*tag, to_heap_pos),
                 Value::Struct(_)     => Value::Struct(to_heap_pos),
                 _ => unreachable!(),
             };
         } else {
             return value.clone();
+        }
+    }
+}
 impl Default for ValueGroup {
     /// Returns an empty ValueGroup
     fn default() -> Self {
         Self { values: Vec::new(), regions: Vec::new() }
+    }
+}
 pub(crate) fn apply_assignment_operator(store: &mut Store, lhs: ValueId, op: AssignmentOperator, rhs: Value) {
     use AssignmentOperator as AO;
     macro_rules! apply_int_op {
         ($lhs:ident, $assignment_tokens:tt, $operator:ident, $rhs:ident) => {
             match $lhs {
                 Value::UInt8(v)  => { *v $assignment_tokens $rhs.as_uint8();  },
                 Value::UInt16(v) => { *v $assignment_tokens $rhs.as_uint16(); },
                 Value::UInt32(v) => { *v $assignment_tokens $rhs.as_uint32(); },
                 Value::UInt64(v) => { *v $assignment_tokens $rhs.as_uint64(); },
                 Value::SInt8(v)  => { *v $assignment_tokens $rhs.as_sint8();  },
                 Value::SInt16(v) => { *v $assignment_tokens $rhs.as_sint16(); },
                 Value::SInt32(v) => { *v $assignment_tokens $rhs.as_sint32(); },
                 Value::SInt64(v) => { *v $assignment_tokens $rhs.as_sint64(); },
                 _ => unreachable!("apply_assignment_operator {:?} on lhs {:?} and rhs {:?}", $operator, $lhs, $rhs),
+            }
+        }
+    }
     // let rhs = store.maybe_read_ref(&rhs).clone(); // we don't own this thing, so don't drop it
     let lhs = store.read_mut_ref(lhs);
     let mut to_dealloc = None;
     match op {
         AO::Set => {
             match lhs {
                 Value::Unassigned => { *lhs = rhs; },
                 Value::Input(v)  => { *v = rhs.as_input(); },
                 Value::Output(v) => { *v = rhs.as_output(); },
                 Value::Message(v)  => { to_dealloc = Some(*v); *v = rhs.as_message(); },
                 Value::Bool(v)    => { *v = rhs.as_bool(); },
                 Value::Char(v) => { *v = rhs.as_char(); },
                 Value::String(v) => { *v = rhs.as_string().clone(); },
                 Value::UInt8(v) => { *v = rhs.as_uint8(); },
                 Value::UInt16(v) => { *v = rhs.as_uint16(); },
                 Value::UInt32(v) => { *v = rhs.as_uint32(); },
                 Value::UInt64(v) => { *v = rhs.as_uint64(); },
                 Value::SInt8(v) => { *v = rhs.as_sint8(); },
                 Value::SInt16(v) => { *v = rhs.as_sint16(); },
                 Value::SInt32(v) => { *v = rhs.as_sint32(); },
                 Value::SInt64(v) => { *v = rhs.as_sint64(); },
                 Value::Array(v) => { to_dealloc = Some(*v); *v = rhs.as_array(); },
                 Value::Enum(v) => { *v = rhs.as_enum(); },
                 Value::Union(lhs_tag, lhs_heap_pos) => {
                     to_dealloc = Some(*lhs_heap_pos);
                     let (rhs_tag, rhs_heap_pos) = rhs.as_union();
                     *lhs_tag = rhs_tag;
                     *lhs_heap_pos = rhs_heap_pos;
+                }
                 Value::Struct(v) => { to_dealloc = Some(*v); *v = rhs.as_struct(); },
                 _ => unreachable!("apply_assignment_operator {:?} on lhs {:?} and rhs {:?}", op, lhs, rhs),
+            }
         },
         AO::Multiplied =>   { apply_int_op!(lhs, *=,  op, rhs) },
         AO::Divided =>      { apply_int_op!(lhs, /=,  op, rhs) },
         AO::Remained =>     { apply_int_op!(lhs, %=,  op, rhs) },
         AO::Added =>        { apply_int_op!(lhs, +=,  op, rhs) },
         AO::Subtracted =>   { apply_int_op!(lhs, -=,  op, rhs) },
         AO::ShiftedLeft =>  { apply_int_op!(lhs, <<=, op, rhs) },
         AO::ShiftedRight => { apply_int_op!(lhs, >>=, op, rhs) },
         AO::BitwiseAnded => { apply_int_op!(lhs, &=,  op, rhs) },
         AO::BitwiseXored => { apply_int_op!(lhs, ^=,  op, rhs) },
         AO::BitwiseOred =>  { apply_int_op!(lhs, |=,  op, rhs) },
+    }
     if let Some(heap_pos) = to_dealloc {
         store.drop_heap_pos(heap_pos);
+    }
+}
 pub(crate) fn apply_binary_operator(store: &mut Store, lhs: &Value, op: BinaryOperator, rhs: &Value) -> Value {
     use BinaryOperator as BO;
     macro_rules! apply_int_op_and_return_self {
         ($lhs:ident, $operator_tokens:tt, $operator:ident, $rhs:ident) => {
             return match $lhs {
                 Value::UInt8(v)  => { Value::UInt8( *v $operator_tokens $rhs.as_uint8() ) },
                 Value::UInt16(v) => { Value::UInt16(*v $operator_tokens $rhs.as_uint16()) },
                 Value::UInt32(v) => { Value::UInt32(*v $operator_tokens $rhs.as_uint32()) },
                 Value::UInt64(v) => { Value::UInt64(*v $operator_tokens $rhs.as_uint64()) },
                 Value::SInt8(v)  => { Value::SInt8( *v $operator_tokens $rhs.as_sint8() ) },
                 Value::SInt16(v) => { Value::SInt16(*v $operator_tokens $rhs.as_sint16()) },
                 Value::SInt32(v) => { Value::SInt32(*v $operator_tokens $rhs.as_sint32()) },
                 Value::SInt64(v) => { Value::SInt64(*v $operator_tokens $rhs.as_sint64()) },
                 _ => unreachable!("apply_binary_operator {:?} on lhs {:?} and rhs {:?}", $operator, $lhs, $rhs)
             };
+        }
+    }
     macro_rules! apply_int_op_and_return_bool {
         ($lhs:ident, $operator_tokens:tt, $operator:ident, $rhs:ident) => {
             return match $lhs {
                 Value::UInt8(v)  => { Value::Bool(*v $operator_tokens $rhs.as_uint8() ) },
                 Value::UInt16(v) => { Value::Bool(*v $operator_tokens $rhs.as_uint16()) },
                 Value::UInt32(v) => { Value::Bool(*v $operator_tokens $rhs.as_uint32()) },
                 Value::UInt64(v) => { Value::Bool(*v $operator_tokens $rhs.as_uint64()) },
                 Value::SInt8(v)  => { Value::Bool(*v $operator_tokens $rhs.as_sint8() ) },
                 Value::SInt16(v) => { Value::Bool(*v $operator_tokens $rhs.as_sint16()) },
                 Value::SInt32(v) => { Value::Bool(*v $operator_tokens $rhs.as_sint32()) },
                 Value::SInt64(v) => { Value::Bool(*v $operator_tokens $rhs.as_sint64()) },
                 _ => unreachable!("apply_binary_operator {:?} on lhs {:?} and rhs {:?}", $operator, $lhs, $rhs)
             };
+        }
+    }
     // We need to handle concatenate in a special way because it needs the store
     // mutably.
     if op == BO::Concatenate {
         let target_heap_pos = store.alloc_heap();
         let lhs_heap_pos;
         let rhs_heap_pos;
         let lhs = store.maybe_read_ref(lhs);
         let rhs = store.maybe_read_ref(rhs);
-        enum ValueKind { Message, String, Array };
         enum ValueKind { Message, String, Array }
         let value_kind;
         match lhs {
             Value::Message(lhs_pos) => {
                 lhs_heap_pos = *lhs_pos;
                 rhs_heap_pos = rhs.as_message();
                 value_kind = ValueKind::Message;
             },
             Value::String(lhs_pos) => {
                 lhs_heap_pos = *lhs_pos;
                 rhs_heap_pos = rhs.as_string();
                 value_kind = ValueKind::String;
             },
             Value::Array(lhs_pos) => {
                 lhs_heap_pos = *lhs_pos;
                 rhs_heap_pos = rhs.as_array();
                 value_kind = ValueKind::Array;
             },
             _ => unreachable!("apply_binary_operator {:?} on lhs {:?} and rhs {:?}", op, lhs, rhs)
+        }
         let lhs_heap_pos = lhs_heap_pos as usize;
         let rhs_heap_pos = rhs_heap_pos as usize;
         // TODO: I hate this, but fine...
         let mut concatenated = Vec::new();
         let lhs_len = store.heap_regions[lhs_heap_pos].values.len();
         let rhs_len = store.heap_regions[rhs_heap_pos].values.len();
         concatenated.reserve(lhs_len + rhs_len);
         for idx in 0..lhs_len {
             concatenated.push(store.clone_value(store.heap_regions[lhs_heap_pos].values[idx].clone()));
+        }
         for idx in 0..rhs_len {
             concatenated.push(store.clone_value(store.heap_regions[rhs_heap_pos].values[idx].clone()));
+        }
         store.heap_regions[target_heap_pos as usize].values = concatenated;
         return match value_kind{
             ValueKind::Message => Value::Message(target_heap_pos),
             ValueKind::String => Value::String(target_heap_pos),
             ValueKind::Array => Value::Array(target_heap_pos),
         };
+    }
     // If any of the values are references, retrieve the thing they're referring
     // to.
     let lhs = store.maybe_read_ref(lhs);
     let rhs = store.maybe_read_ref(rhs);
     match op {
         BO::Concatenate => unreachable!(),
         BO::LogicalOr => {
             return Value::Bool(lhs.as_bool() || rhs.as_bool());
         },
         BO::LogicalAnd => {
             return Value::Bool(lhs.as_bool() && rhs.as_bool());
         },
         BO::BitwiseOr        => { apply_int_op_and_return_self!(lhs, |,  op, rhs); },
         BO::BitwiseXor       => { apply_int_op_and_return_self!(lhs, ^,  op, rhs); },
         BO::BitwiseAnd       => { apply_int_op_and_return_self!(lhs, &,  op, rhs); },
         BO::Equality         => { Value::Bool(apply_equality_operator(store, lhs, rhs)) },
         BO::Inequality       => { Value::Bool(apply_inequality_operator(store, lhs, rhs)) },
         BO::LessThan         => { apply_int_op_and_return_bool!(lhs, <,  op, rhs); },
         BO::GreaterThan      => { apply_int_op_and_return_bool!(lhs, >,  op, rhs); },
         BO::LessThanEqual    => { apply_int_op_and_return_bool!(lhs, <=, op, rhs); },
         BO::GreaterThanEqual => { apply_int_op_and_return_bool!(lhs, >=, op, rhs); },
         BO::ShiftLeft        => { apply_int_op_and_return_self!(lhs, <<, op, rhs); },
         BO::ShiftRight       => { apply_int_op_and_return_self!(lhs, >>, op, rhs); },
         BO::Add              => { apply_int_op_and_return_self!(lhs, +,  op, rhs); },
         BO::Subtract         => { apply_int_op_and_return_self!(lhs, -,  op, rhs); },
         BO::Multiply         => { apply_int_op_and_return_self!(lhs, *,  op, rhs); },
         BO::Divide           => { apply_int_op_and_return_self!(lhs, /,  op, rhs); },
         BO::Remainder        => { apply_int_op_and_return_self!(lhs, %,  op, rhs); }
+    }
+}
 pub(crate) fn apply_unary_operator(store: &mut Store, op: UnaryOperator, value: &Value) -> Value {
     use UnaryOperator as UO;
     macro_rules! apply_int_expr_and_return {
         ($value:ident, $apply:tt, $op:ident) => {
             return match $value {
                 Value::UInt8(v)  => Value::UInt8($apply *v),
                 Value::UInt16(v) => Value::UInt16($apply *v),
                 Value::UInt32(v) => Value::UInt32($apply *v),
                 Value::UInt64(v) => Value::UInt64($apply *v),
                 Value::SInt8(v)  => Value::SInt8($apply *v),
                 Value::SInt16(v) => Value::SInt16($apply *v),
                 Value::SInt32(v) => Value::SInt32($apply *v),
                 Value::SInt64(v) => Value::SInt64($apply *v),
                 _ => unreachable!("apply_unary_operator {:?} on value {:?}", $op, $value),
             };
+        }
+    }
     // If the value is a reference, retrieve the thing it is referring to
     let value = store.maybe_read_ref(value);
     match op {
         UO::Positive => {
             debug_assert!(value.is_integer());
             return value.clone();
         },
         UO::Negative => {
             // TODO: Error on negating unsigned integers
             return match value {
                 Value::SInt8(v) => Value::SInt8(-*v),
                 Value::SInt16(v) => Value::SInt16(-*v),
                 Value::SInt32(v) => Value::SInt32(-*v),
                 Value::SInt64(v) => Value::SInt64(-*v),
                 _ => unreachable!("apply_unary_operator {:?} on value {:?}", op, value),
+            }
         },
         UO::BitwiseNot => { apply_int_expr_and_return!(value, !, op)},
         UO::LogicalNot => { return Value::Bool(!value.as_bool()); },
         UO::PreIncrement => { todo!("implement") },
         UO::PreDecrement => { todo!("implement") },
         UO::PostIncrement => { todo!("implement") },
         UO::PostDecrement => { todo!("implement") },
+    }
+}
 pub(crate) fn apply_equality_operator(store: &Store, lhs: &Value, rhs: &Value) -> bool {
     let lhs = store.maybe_read_ref(lhs);
     let rhs = store.maybe_read_ref(rhs);
     fn eval_equality_heap(store: &Store, lhs_pos: HeapPos, rhs_pos: HeapPos) -> bool {
         let lhs_vals = &store.heap_regions[lhs_pos as usize].values;
         let rhs_vals = &store.heap_regions[rhs_pos as usize].values;
         let lhs_len = lhs_vals.len();
         if lhs_len != rhs_vals.len() {
             return false;
+        }
         for idx in 0..lhs_len {
             let lhs_val = &lhs_vals[idx];
             let rhs_val = &rhs_vals[idx];
             if !apply_equality_operator(store, lhs_val, rhs_val) {
                 return false;
+            }
+        }
         return true;
+    }
     match lhs {
         Value::Input(v) => *v == rhs.as_input(),
         Value::Output(v) => *v == rhs.as_output(),
         Value::Message(lhs_pos) => eval_equality_heap(store, *lhs_pos, rhs.as_message()),
         Value::Null => todo!("remove null"),
         Value::Bool(v) => *v == rhs.as_bool(),
         Value::Char(v) => *v == rhs.as_char(),
         Value::String(lhs_pos) => eval_equality_heap(store, *lhs_pos, rhs.as_string()),
         Value::UInt8(v) => *v == rhs.as_uint8(),
         Value::UInt16(v) => *v == rhs.as_uint16(),
         Value::UInt32(v) => *v == rhs.as_uint32(),
         Value::UInt64(v) => *v == rhs.as_uint64(),
         Value::SInt8(v) => *v == rhs.as_sint8(),
         Value::SInt16(v) => *v == rhs.as_sint16(),
         Value::SInt32(v) => *v == rhs.as_sint32(),
         Value::SInt64(v) => *v == rhs.as_sint64(),
         Value::Array(lhs_pos) => eval_equality_heap(store, *lhs_pos, rhs.as_array()),
         Value::Enum(v) => *v == rhs.as_enum(),
         Value::Union(lhs_tag, lhs_pos) => {
             let (rhs_tag, rhs_pos) = rhs.as_union();
             if *lhs_tag != rhs_tag {
                 return false;
+            }
             eval_equality_heap(store, *lhs_pos, rhs_pos)
         },
         Value::Struct(lhs_pos) => eval_equality_heap(store, *lhs_pos, rhs.as_struct()),
         _ => unreachable!("apply_equality_operator to lhs {:?}", lhs),
+    }
+}
 pub(crate) fn apply_inequality_operator(store: &Store, lhs: &Value, rhs: &Value) -> bool {
     let lhs = store.maybe_read_ref(lhs);
     let rhs = store.maybe_read_ref(rhs);
     fn eval_inequality_heap(store: &Store, lhs_pos: HeapPos, rhs_pos: HeapPos) -> bool {
         let lhs_vals = &store.heap_regions[lhs_pos as usize].values;
         let rhs_vals = &store.heap_regions[rhs_pos as usize].values;
         let lhs_len = lhs_vals.len();
         if lhs_len != rhs_vals.len() {
             return true;
+        }
         for idx in 0..lhs_len {
             let lhs_val = &lhs_vals[idx];
             let rhs_val = &rhs_vals[idx];
             if apply_inequality_operator(store, lhs_val, rhs_val) {
                 return true;
+            }
+        }
         return false;
+    }
     match lhs {
         Value::Input(v) => *v != rhs.as_input(),
         Value::Output(v) => *v != rhs.as_output(),
         Value::Message(lhs_pos) => eval_inequality_heap(store, *lhs_pos, rhs.as_message()),
         Value::Null => todo!("remove null"),
         Value::Bool(v) => *v != rhs.as_bool(),
         Value::Char(v) => *v != rhs.as_char(),
         Value::String(lhs_pos) => eval_inequality_heap(store, *lhs_pos, rhs.as_string()),
         Value::UInt8(v) => *v != rhs.as_uint8(),
         Value::UInt16(v) => *v != rhs.as_uint16(),
         Value::UInt32(v) => *v != rhs.as_uint32(),
         Value::UInt64(v) => *v != rhs.as_uint64(),
         Value::SInt8(v) => *v != rhs.as_sint8(),
         Value::SInt16(v) => *v != rhs.as_sint16(),
         Value::SInt32(v) => *v != rhs.as_sint32(),
         Value::SInt64(v) => *v != rhs.as_sint64(),
         Value::Enum(v) => *v != rhs.as_enum(),
         Value::Union(lhs_tag, lhs_pos) => {
             let (rhs_tag, rhs_pos) = rhs.as_union();
             if *lhs_tag != rhs_tag {
                 return true;
+            }
             eval_inequality_heap(store, *lhs_pos, rhs_pos)
         },
         Value::String(lhs_pos) => eval_inequality_heap(store, *lhs_pos, rhs.as_struct()),
         _ => unreachable!("apply_inequality_operator to lhs {:?}", lhs)
+    }
+}
@@ \ No newline at end of file @@

src/protocol/parser/mod.rs

➞

Show inline comments

 mod depth_visitor;
 pub(crate) mod symbol_table;
 pub(crate) mod type_table;
 pub(crate) mod tokens;
 pub(crate) mod token_parsing;
 pub(crate) mod pass_tokenizer;
 pub(crate) mod pass_symbols;
 pub(crate) mod pass_imports;
 pub(crate) mod pass_definitions;
 pub(crate) mod pass_validation_linking;
 pub(crate) mod pass_typing;
 mod visitor;
 use depth_visitor::*;
 use tokens::*;
 use crate::collections::*;
 use visitor::Visitor2;
 use pass_tokenizer::PassTokenizer;
 use pass_symbols::PassSymbols;
 use pass_imports::PassImport;
 use pass_definitions::PassDefinitions;
 use pass_validation_linking::PassValidationLinking;
 use pass_typing::{PassTyping, ResolveQueue};
 use symbol_table::*;
 use type_table::TypeTable;
 use crate::protocol::ast::*;
 use crate::protocol::input_source::*;
 use crate::protocol::ast_printer::ASTWriter;
 use crate::protocol::parser::type_table::PolymorphicVariable;
 #[derive(Debug, PartialEq, Eq, PartialOrd, Ord)]
 pub enum ModuleCompilationPhase {
     Source,                 // only source is set
     Tokenized,              // source is tokenized
     SymbolsScanned,         // all definitions are linked to their type class
     ImportsResolved,        // all imports are added to the symbol table
     DefinitionsParsed,      // produced the AST for the entire module
     TypesAddedToTable,      // added all definitions to the type table
     ValidatedAndLinked,     // AST is traversed and has linked the required AST nodes
     Typed,                  // Type inference and checking has been performed
+}
 pub struct Module {
     // Buffers
     pub source: InputSource,
     pub tokens: TokenBuffer,
     // Identifiers
     pub root_id: RootId,
     pub name: Option<(PragmaId, StringRef<'static>)>,
     pub version: Option<(PragmaId, i64)>,
     pub phase: ModuleCompilationPhase,
+}
 pub struct PassCtx<'a> {
     heap: &'a mut Heap,
     symbols: &'a mut SymbolTable,
     pool: &'a mut StringPool,
+}
 pub struct Parser {
     pub(crate) heap: Heap,
     pub(crate) string_pool: StringPool,
     pub(crate) modules: Vec<Module>,
     pub(crate) symbol_table: SymbolTable,
     pub(crate) type_table: TypeTable,
     // Compiler passes
     pass_tokenizer: PassTokenizer,
     pass_symbols: PassSymbols,
     pass_import: PassImport,
     pass_definitions: PassDefinitions,
     pass_validation: PassValidationLinking,
     pass_typing: PassTyping,
+}
 impl Parser {
     pub fn new() -> Self {
         let mut parser = Parser{
             heap: Heap::new(),
             string_pool: StringPool::new(),
             modules: Vec::new(),
             symbol_table: SymbolTable::new(),
             type_table: TypeTable::new(),
             pass_tokenizer: PassTokenizer::new(),
             pass_symbols: PassSymbols::new(),
             pass_import: PassImport::new(),
             pass_definitions: PassDefinitions::new(),
             pass_validation: PassValidationLinking::new(),
             pass_typing: PassTyping::new(),
         };
         parser.symbol_table.insert_scope(None, SymbolScope::Global);
         fn quick_type(variants: &[ParserTypeVariant]) -> ParserType {
             let mut t = ParserType{ elements: Vec::with_capacity(variants.len()) };
             for variant in variants {
                 t.elements.push(ParserTypeElement{ full_span: InputSpan::new(), variant: variant.clone() });
+            }
+            t
+        }
         use ParserTypeVariant as PTV;
         insert_builtin_function(&mut parser, "get", &["T"], |id| (
             vec![
                 ("input", quick_type(&[PTV::Input, PTV::PolymorphicArgument(id.upcast(), 0)]))
             ],
             quick_type(&[PTV::PolymorphicArgument(id.upcast(), 0)])
         ));
         insert_builtin_function(&mut parser, "put", &["T"], |id| (
             vec![
                 ("output", quick_type(&[PTV::Output, PTV::PolymorphicArgument(id.upcast(), 0)])),
                 ("value", quick_type(&[PTV::PolymorphicArgument(id.upcast(), 0)])),
             ],
             quick_type(&[PTV::Void])
         ));
         insert_builtin_function(&mut parser, "fires", &["T"], |id| (
             vec![
                 ("port", quick_type(&[PTV::InputOrOutput, PTV::PolymorphicArgument(id.upcast(), 0)]))
             ],
             quick_type(&[PTV::Bool])
         ));
         insert_builtin_function(&mut parser, "create", &["T"], |id| (
             vec![
                 ("length", quick_type(&[PTV::IntegerLike]))
             ],
             quick_type(&[PTV::ArrayLike, PTV::PolymorphicArgument(id.upcast(), 0)])
         ));
         insert_builtin_function(&mut parser, "length", &["T"], |id| (
             vec![
                 ("array", quick_type(&[PTV::ArrayLike, PTV::PolymorphicArgument(id.upcast(), 0)]))
             ],
             quick_type(&[PTV::IntegerLike])
         ));
         insert_builtin_function(&mut parser, "assert", &[], |id| (
             vec![
                 ("condition", quick_type(&[PTV::Bool])),
             ],
             quick_type(&[PTV::Void])
         ));
         parser
+    }
     pub fn feed(&mut self, mut source: InputSource) -> Result<(), ParseError> {
         // TODO: @Optimize
         let mut token_buffer = TokenBuffer::new();
         self.pass_tokenizer.tokenize(&mut source, &mut token_buffer)?;
         let module = Module{
             source,
             tokens: token_buffer,
             root_id: RootId::new_invalid(),
             name: None,
             version: None,
             phase: ModuleCompilationPhase::Tokenized,
         };
         self.modules.push(module);
         Ok(())
+    }
     pub fn parse(&mut self) -> Result<(), ParseError> {
         let mut pass_ctx = PassCtx{
             heap: &mut self.heap,
             symbols: &mut self.symbol_table,
             pool: &mut self.string_pool,
         };
         // Advance all modules to the phase where all symbols are scanned
         for module_idx in 0..self.modules.len() {
             self.pass_symbols.parse(&mut self.modules, module_idx, &mut pass_ctx)?;
+        }
         // With all symbols scanned, perform further compilation until we can
         // add all base types to the type table.
         for module_idx in 0..self.modules.len() {
             self.pass_import.parse(&mut self.modules, module_idx, &mut pass_ctx)?;
             self.pass_definitions.parse(&mut self.modules, module_idx, &mut pass_ctx)?;
+        }
         // Add every known type to the type table
         self.type_table.build_base_types(&mut self.modules, &mut pass_ctx)?;
         // Continue compilation with the remaining phases now that the types
         // are all in the type table
         for module_idx in 0..self.modules.len() {
             // TODO: Remove the entire Visitor abstraction. It really doesn't
             //  make sense considering the amount of special handling we do
             //  in each pass.
             let mut ctx = visitor::Ctx{
                 heap: &mut self.heap,
                 module: &mut self.modules[module_idx],
                 symbols: &mut self.symbol_table,
                 types: &mut self.type_table,
             };
             self.pass_validation.visit_module(&mut ctx)?;
+        }
         // Perform typechecking on all modules
         let mut queue = ResolveQueue::new();
         for module in &mut self.modules {
             let ctx = visitor::Ctx{
                 heap: &mut self.heap,
                 module,
                 symbols: &mut self.symbol_table,
                 types: &mut self.type_table,
             };
             PassTyping::queue_module_definitions(&ctx, &mut queue);
         };
         while !queue.is_empty() {
             let top = queue.pop().unwrap();
             let mut ctx = visitor::Ctx{
                 heap: &mut self.heap,
                 module: &mut self.modules[top.root_id.index as usize],
                 symbols: &mut self.symbol_table,
                 types: &mut self.type_table,
             };
             self.pass_typing.handle_module_definition(&mut ctx, &mut queue, top)?;
+        }
         // Perform remaining steps
         // TODO: Phase out at some point
         for module in &self.modules {
             let root_id = module.root_id;
             if let Err((position, message)) = Self::parse_inner(&mut self.heap, root_id) {
                 return Err(ParseError::new_error_str_at_pos(&self.modules[0].source, position, &message))
+            }
+        }
         let mut writer = ASTWriter::new();
         let mut file = std::fs::File::create(std::path::Path::new("ast.txt")).unwrap();
         writer.write_ast(&mut file, &self.heap);
         Ok(())
+    }
     pub fn parse_inner(h: &mut Heap, pd: RootId) -> VisitorResult {
         // TODO: @cleanup, slowly phasing out old compiler
         // NestedSynchronousStatements::new().visit_protocol_description(h, pd)?;
         // ChannelStatementOccurrences::new().visit_protocol_description(h, pd)?;
         // FunctionStatementReturns::new().visit_protocol_description(h, pd)?;
         // ComponentStatementReturnNew::new().visit_protocol_description(h, pd)?;
         // CheckBuiltinOccurrences::new().visit_protocol_description(h, pd)?;
         // BuildSymbolDeclarations::new().visit_protocol_description(h, pd)?;
         // LinkCallExpressions::new().visit_protocol_description(h, pd)?;
         // BuildScope::new().visit_protocol_description(h, pd)?;
         // ResolveVariables::new().visit_protocol_description(h, pd)?;
         LinkStatements::new().visit_protocol_description(h, pd)?;
         // BuildLabels::new().visit_protocol_description(h, pd)?;
         // ResolveLabels::new().visit_protocol_description(h, pd)?;
         AssignableExpressions::new().visit_protocol_description(h, pd)?;
         IndexableExpressions::new().visit_protocol_description(h, pd)?;
         SelectableExpressions::new().visit_protocol_description(h, pd)?;
         Ok(())
+    }
+}
 // Note: args and return type need to be a function because we need to know the function ID.
 fn insert_builtin_function<T: Fn(FunctionDefinitionId) -> (Vec<(&'static str, ParserType)>, ParserType)> (
     p: &mut Parser, func_name: &str, polymorphic: &[&str], arg_and_return_fn: T) {
     let mut poly_vars = Vec::with_capacity(polymorphic.len());
     for poly_var in polymorphic {
         poly_vars.push(Identifier{ span: InputSpan::new(), value: p.string_pool.intern(poly_var.as_bytes()) });
+    }
     let func_ident_ref = p.string_pool.intern(func_name.as_bytes());
     let func_id = p.heap.alloc_function_definition(|this| FunctionDefinition{
         this,
         defined_in: RootId::new_invalid(),
         builtin: true,
         span: InputSpan::new(),
         identifier: Identifier{ span: InputSpan::new(), value: func_ident_ref.clone() },
         poly_vars,
         return_types: Vec::new(),
         parameters: Vec::new(),
         body: BlockStatementId::new_invalid(),
         num_expressions_in_body: -1,
     });
     let (args, ret) = arg_and_return_fn(func_id);
     let mut parameters = Vec::with_capacity(args.len());
     for (arg_name, arg_type) in args {
         let identifier = Identifier{ span: InputSpan::new(), value: p.string_pool.intern(arg_name.as_bytes()) };
         let param_id = p.heap.alloc_variable(|this| Variable{
             this,
             kind: VariableKind::Parameter,
             parser_type: arg_type.clone(),
             identifier,
             relative_pos_in_block: 0,
             unique_id_in_scope: 0
         });
         parameters.push(param_id);
+    }
     let func = &mut p.heap[func_id];
     func.parameters = parameters;
     func.return_types.push(ret);
     p.symbol_table.insert_symbol(SymbolScope::Global, Symbol{
         name: func_ident_ref,
         variant: SymbolVariant::Definition(SymbolDefinition{
             defined_in_module: RootId::new_invalid(),
             defined_in_scope: SymbolScope::Global,
             definition_span: InputSpan::new(),
             identifier_span: InputSpan::new(),
             imported_at: None,
             class: DefinitionClass::Function,
             definition_id: func_id.upcast(),
         })
     }).unwrap();
+}
@@ \ No newline at end of file @@

Changeset was too big and was cut off... Show full diff anyway

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