self.expressions

                .alloc_with_id(|id| Expression::Select(f(SelectExpressionId(id)))),

        )

    }

    pub fn alloc_array_expression(

        &mut self,

        f: impl FnOnce(ArrayExpressionId) -> ArrayExpression,

    ) -> ArrayExpressionId {

        ArrayExpressionId(

            self.expressions

                .alloc_with_id(|id| Expression::Array(f(ArrayExpressionId(id)))),

        )

    }

    pub fn alloc_literal_expression(

        &mut self,

        f: impl FnOnce(LiteralExpressionId) -> LiteralExpression,

    ) -> LiteralExpressionId {

        LiteralExpressionId(

            self.expressions.alloc_with_id(|id| {

                Expression::Literal(f(LiteralExpressionId(id)))

            }),

        )

    }

    pub fn alloc_call_expression(

        &mut self,

        f: impl FnOnce(CallExpressionId) -> CallExpression,

    ) -> CallExpressionId {

        CallExpressionId(

            self.expressions

                .alloc_with_id(|id| Expression::Call(f(CallExpressionId(id)))),

        )

    }

    pub fn alloc_variable_expression(

        &mut self,

        f: impl FnOnce(VariableExpressionId) -> VariableExpression,

    ) -> VariableExpressionId {

        VariableExpressionId(

            self.expressions.alloc_with_id(|id| {

                Expression::Variable(f(VariableExpressionId(id)))

            }),

        )

    }

    pub fn alloc_block_statement(

        &mut self,

        f: impl FnOnce(BlockStatementId) -> BlockStatement,

    ) -> BlockStatementId {

        BlockStatementId(

            self.statements

                .alloc_with_id(|id| Statement::Block(f(BlockStatementId(id)))),

        )

    }

    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)))

            ))

        })))

    }

    pub fn alloc_skip_statement(

        &mut self,

        f: impl FnOnce(SkipStatementId) -> SkipStatement,

    ) -> SkipStatementId {

        SkipStatementId(

            self.statements

                .alloc_with_id(|id| Statement::Skip(f(SkipStatementId(id)))),

        )

    }

    pub fn alloc_if_statement(

        &mut self,

        f: impl FnOnce(IfStatementId) -> IfStatement,

    ) -> IfStatementId {

        IfStatementId(

            self.statements.alloc_with_id(|id| Statement::If(f(IfStatementId(id)))),

        )

    }

    pub fn alloc_end_if_statement(

        &mut self,

        f: impl FnOnce(EndIfStatementId) -> EndIfStatement,

    ) -> EndIfStatementId {

        EndIfStatementId(

            self.statements

                .alloc_with_id(|id| Statement::EndIf(f(EndIfStatementId(id)))),

        )

    }

    pub fn alloc_while_statement(

        &mut self,

        f: impl FnOnce(WhileStatementId) -> WhileStatement,

    ) -> WhileStatementId {

        WhileStatementId(

            self.statements

                .alloc_with_id(|id| Statement::While(f(WhileStatementId(id)))),

        )

    }

    pub fn alloc_end_while_statement(

        &mut self,

        f: impl FnOnce(EndWhileStatementId) -> EndWhileStatement,

    ) -> EndWhileStatementId {

        EndWhileStatementId(

            self.statements

                .alloc_with_id(|id| Statement::EndWhile(f(EndWhileStatementId(id)))),

        )

    }

    pub fn alloc_break_statement(

        &mut self,

        f: impl FnOnce(BreakStatementId) -> BreakStatement,

    ) -> BreakStatementId {

        BreakStatementId(

            self.statements

                .alloc_with_id(|id| Statement::Break(f(BreakStatementId(id)))),

        )

    }

    pub fn alloc_continue_statement(

        &mut self,

        f: impl FnOnce(ContinueStatementId) -> ContinueStatement,

    ) -> ContinueStatementId {

        ContinueStatementId(

            self.statements

                .alloc_with_id(|id| Statement::Continue(f(ContinueStatementId(id)))),

        )

    }

    pub fn alloc_synchronous_statement(

        &mut self,

        f: impl FnOnce(SynchronousStatementId) -> SynchronousStatement,

    ) -> SynchronousStatementId {

        SynchronousStatementId(self.statements.alloc_with_id(|id| {

            Statement::Synchronous(f(SynchronousStatementId(id)))

        }))

    }

    pub fn alloc_end_synchronous_statement(

        &mut self,

        f: impl FnOnce(EndSynchronousStatementId) -> EndSynchronousStatement,

    ) -> EndSynchronousStatementId {

        EndSynchronousStatementId(self.statements.alloc_with_id(|id| {

            Statement::EndSynchronous(f(EndSynchronousStatementId(id)))

        }))

    }

    pub fn alloc_return_statement(

        &mut self,

        f: impl FnOnce(ReturnStatementId) -> ReturnStatement,

    ) -> ReturnStatementId {

        ReturnStatementId(

            self.statements

                .alloc_with_id(|id| Statement::Return(f(ReturnStatementId(id)))),

        )

    }

    pub fn alloc_assert_statement(

        &mut self,

        f: impl FnOnce(AssertStatementId) -> AssertStatement,

    ) -> AssertStatementId {

        AssertStatementId(

            self.statements

                .alloc_with_id(|id| Statement::Assert(f(AssertStatementId(id)))),

        )

    }

    pub fn alloc_goto_statement(

        &mut self,

        f: impl FnOnce(GotoStatementId) -> GotoStatement,

    ) -> GotoStatementId {

        GotoStatementId(

            self.statements

                .alloc_with_id(|id| Statement::Goto(f(GotoStatementId(id)))),

        )

    }

    pub fn alloc_new_statement(

        &mut self,

        f: impl FnOnce(NewStatementId) -> NewStatement,

    ) -> NewStatementId {

        NewStatementId(

            self.statements.alloc_with_id(|id| Statement::New(f(NewStatementId(id)))),

        )

    }

    pub fn alloc_labeled_statement(

        &mut self,

        f: impl FnOnce(LabeledStatementId) -> LabeledStatement,

    ) -> LabeledStatementId {

        LabeledStatementId(

            self.statements

                .alloc_with_id(|id| Statement::Labeled(f(LabeledStatementId(id)))),

        )

    }

    pub fn alloc_expression_statement(

        &mut self,

        f: impl FnOnce(ExpressionStatementId) -> ExpressionStatement,

    ) -> ExpressionStatementId {

        ExpressionStatementId(

            self.statements.alloc_with_id(|id| {

                Statement::Expression(f(ExpressionStatementId(id)))

            }),

        )

    }

    pub fn alloc_struct_definition(&mut self, f: impl FnOnce(StructId) -> StructDefinition) -> StructId {

        StructId(self.definitions.alloc_with_id(|id| {

            Definition::Struct(f(StructId(id)))

        }))

    }

    pub fn alloc_enum_definition(&mut self, f: impl FnOnce(EnumId) -> EnumDefinition) -> EnumId {

        EnumId(self.definitions.alloc_with_id(|id| {

            Definition::Enum(f(EnumId(id)))

        }))

    }

    pub fn alloc_component(&mut self, f: impl FnOnce(ComponentId) -> Component) -> ComponentId {

        ComponentId(self.definitions.alloc_with_id(|id| {

            Definition::Component(f(ComponentId(id)))

        }))

    }

    pub fn alloc_function(&mut self, f: impl FnOnce(FunctionId) -> Function) -> FunctionId {

        FunctionId(

            self.definitions

                .alloc_with_id(|id| Definition::Function(f(FunctionId(id)))),

        )

    }

    pub fn alloc_pragma(&mut self, f: impl FnOnce(PragmaId) -> Pragma) -> PragmaId {

        self.pragmas.alloc_with_id(|id| f(id))

    }

    pub fn alloc_import(&mut self, f: impl FnOnce(ImportId) -> Import) -> ImportId {

        self.imports.alloc_with_id(|id| f(id))

    }

    pub fn alloc_protocol_description(&mut self, f: impl FnOnce(RootId) -> Root) -> RootId {

        self.protocol_descriptions.alloc_with_id(|id| f(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, serde::Serialize, serde::Deserialize)]

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 {

    pub fn get_definition_ident(&self, h: &Heap, id: &[u8]) -> Option<DefinitionId> {

        for &def in self.definitions.iter() {

            if h[def].identifier().value == id {

                return Some(def);

            }

        }

        None

    }

}

impl SyntaxElement for Root {

    fn position(&self) -> InputPosition {

        self.position

    }

}

#[derive(Debug, Clone, serde::Serialize, serde::Deserialize)]

pub enum Pragma {

    Version(PragmaVersion),

    Module(PragmaModule)

}

#[derive(Debug, Clone, serde::Serialize, serde::Deserialize)]

pub struct PragmaVersion {

    pub this: PragmaId,

    // Phase 1: parser

    pub position: InputPosition,

    pub version: u64,

}

#[derive(Debug, Clone, serde::Serialize, serde::Deserialize)]

pub struct PragmaModule {

    pub this: PragmaId,

    // Phase 1: parser

    pub position: InputPosition,

    pub value: Vec<u8>,

}

#[derive(Debug, Clone, serde::Serialize, serde::Deserialize)]

pub struct PragmaOld {

    pub this: PragmaId,

    // Phase 1: parser

    pub position: InputPosition,

    pub value: Vec<u8>,

}

impl SyntaxElement for PragmaOld {

    fn position(&self) -> InputPosition {

        self.position

    }

}

#[derive(Debug, Clone, serde::Serialize, serde::Deserialize)]

pub enum Import {

    Module(ImportModule),

    Symbols(ImportSymbols)

}

impl Import {

    pub(crate) fn as_module(&self) -> &ImportModule {

        match self {

            Import::Module(m) => m,

            _ => panic!("Unable to cast 'Import' to 'ImportModule'")

        }

    }

    pub(crate) fn as_symbols(&self) -> &ImportSymbols {

        match self {

            Import::Symbols(m) => m,

            _ => panic!("Unable to cast 'Import' to 'ImportSymbols'")

        }

    }

}

impl SyntaxElement for Import {

    fn position(&self) -> InputPosition {

        match self {

            Import::Module(m) => m.position,

            Import::Symbols(m) => m.position

        }

    }

}

#[derive(Debug, Clone, serde::Serialize, serde::Deserialize)]

pub struct ImportModule {

    pub this: ImportId,

    // Phase 1: parser

    pub position: InputPosition,

    pub module_name: Vec<u8>,

    pub alias: Vec<u8>,

    // Phase 2: module resolving

    pub module_id: Option<RootId>,

}

#[derive(Debug, Clone, serde::Serialize, serde::Deserialize)]

pub struct AliasedSymbol {

    // Phase 1: parser

    pub position: InputPosition,

    pub name: Vec<u8>,

    pub alias: Vec<u8>,

    // Phase 2: symbol resolving

    pub definition_id: Option<DefinitionId>,

}

#[derive(Debug, Clone, serde::Serialize, serde::Deserialize)]

pub struct ImportSymbols {

    pub this: ImportId,

    // Phase 1: parser

    pub position: InputPosition,

    pub module_name: Vec<u8>,

    // Phase 2: module resolving

    pub module_id: Option<RootId>,

    // Phase 1&2

    // if symbols is empty, then we implicitly import all symbols without any

    // aliases for them. If it is not empty, then symbols are explicitly

    // specified, and optionally given an alias.

    pub symbols: Vec<AliasedSymbol>,

}

#[derive(Debug, Clone, serde::Serialize, serde::Deserialize)]

pub struct Identifier {

    pub position: InputPosition,

    pub value: Vec<u8>

}

#[derive(Debug, Clone, serde::Serialize, serde::Deserialize)]

pub struct NamespacedIdentifier {

    pub position: InputPosition,

    pub num_namespaces: u8,

    pub value: Vec<u8>,

}

impl NamespacedIdentifier {

    pub(crate) fn iter(&self) -> NamespacedIdentifierIter {

        NamespacedIdentifierIter{

            value: &self.value,

            cur_offset: 0,

            num_returned: 0,

            num_total: self.num_namespaces

        }

    }

}

impl PartialEq for NamespacedIdentifier {

    fn eq(&self, other: &Self) -> bool {

        return self.value == other.value

    }

}

// TODO: Just keep ref to NamespacedIdentifier

pub(crate) struct NamespacedIdentifierIter<'a> {

    value: &'a Vec<u8>,

    cur_offset: usize,

    num_returned: u8,

    num_total: u8,

}

impl<'a> NamespacedIdentifierIter<'a> {

    pub(crate) fn num_returned(&self) -> u8 {

        return self.num_returned;

    }

    pub(crate) fn num_remaining(&self) -> u8 {

        return self.num_total - self.num_returned

    }

    pub(crate) fn returned_section(&self) -> &[u8] {

        // Offset always includes the two trailing ':' characters

        let end = if self.cur_offset >= 2 { self.cur_offset - 2 } else { self.cur_offset };

        return &self.value[..end]

    }

}

impl<'a> Iterator for NamespacedIdentifierIter<'a> {

    type Item = &'a [u8];

    fn next(&mut self) -> Option<Self::Item> {

        if self.cur_offset >= self.value.len() {

            debug_assert_eq!(self.num_returned, self.num_total);

            None

        } else {

            debug_assert!(self.num_returned < self.num_total);

            let start = self.cur_offset;

            let mut end = start;

            while end < self.value.len() - 1 {

                if self.value[end] == b':' && self.value[end + 1] == b':' {

                    self.cur_offset = end + 2;

                    self.num_returned += 1;

                    return Some(&self.value[start..end]);

                }

                end += 1;

            }

            // If NamespacedIdentifier is constructed properly, then we cannot

            // end with "::" in the value, so

            debug_assert!(end == 0 || (self.value[end - 1] != b':' && self.value[end] != b':'));

            debug_assert_eq!(self.num_returned + 1, self.num_total);

            self.cur_offset = self.value.len();

            self.num_returned += 1;

            return Some(&self.value[start..]);

        }

    }

}

impl Display for Identifier {

    fn fmt(&self, f: &mut Formatter<'_>) -> fmt::Result {

        // A source identifier is in ASCII range.

        write!(f, "{}", String::from_utf8_lossy(&self.value))

    }

}

/// TODO: @types Remove the Message -> Byte hack at some point...

#[derive(Debug, Clone, serde::Serialize, serde::Deserialize)]

pub enum ParserTypeVariant {

    // Basic builtin

    Message,

    Bool,

    Byte,

    Short,

    Int,

    Long,

    String,

    // Literals (need to get concrete builtin type during typechecking)

    IntegerLiteral,

    Inferred,

    // Complex builtins

    Array(ParserTypeId), // array of a type

    Input(ParserTypeId), // typed input endpoint of a channel

    Output(ParserTypeId), // typed output endpoint of a channel

    Symbolic(SymbolicParserType), // symbolic type (definition or polyarg)

}

impl ParserTypeVariant {

    pub(crate) fn supports_polymorphic_args(&self) -> bool {

        use ParserTypeVariant::*;

        match self {

            Message | Bool | Byte | Short | Int | Long | String | IntegerLiteral | Inferred => false,

            _ => true

        }

    }

}

/// 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, serde::Serialize, serde::Deserialize)]

pub struct ParserType {

    pub this: ParserTypeId,

    pub pos: InputPosition,

    pub variant: ParserTypeVariant,

}

/// SymbolicParserType is the specification of a symbolic type. During the

/// parsing phase we will only store the identifier of the type. During the

/// validation phase we will determine whether it refers to a user-defined type,

/// or a polymorphic argument. After the validation phase it may still be the

/// case that the resulting `variant` will not pass the typechecker.

#[derive(Debug, Clone, serde::Serialize, serde::Deserialize)]

pub struct SymbolicParserType {

    // Phase 1: parser

    pub identifier: NamespacedIdentifier,

    /// The user-specified polymorphic arguments. Zero-length implies that the

    /// user did not specify any of them, and they're either not needed or all

    /// need to be inferred. Otherwise the number of polymorphic arguments must

    /// match those of the corresponding definition

    pub poly_args: Vec<ParserTypeId>,

    // Phase 2: validation/linking (for types in function/component bodies) and

    //  type table construction (for embedded types of structs/unions)

    pub variant: Option<SymbolicParserTypeVariant>

}

/// 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, serde::Serialize, serde::Deserialize)]

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, serde::Serialize, serde::Deserialize)]

pub enum ConcreteTypePart {

    // Markers for the use of polymorphic types within a procedure's body that

    // refer to polymorphic variables on the procedure's definition. Different

    // from markers in the `InferenceType`, these will not contain nested types.

    Marker(usize),

    // Special types (cannot be explicitly constructed by the programmer)

    Void,

    // Builtin types without nested types

    Message,

    Bool,

    Byte,

    Short,

    Int,

    Long,

    String,

    // Builtin types with one nested type

    Array,

    Slice,

    Input,

    Output,

    // User defined type with any number of nested types

    Instance(DefinitionId, usize),

}

#[derive(Debug, Clone, Eq, PartialEq, serde::Serialize, serde::Deserialize)]

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, serde::Serialize, serde::Deserialize)]

pub enum PrimitiveType {

    Unassigned,

    Input,

    Output,

    Message,

    Boolean,

    Byte,

    Short,

    Int,

    Long,

    Symbolic(PrimitiveSymbolic)

}

// TODO: @cleanup, remove PartialEq implementations

#[derive(Debug, Clone, serde::Serialize, serde::Deserialize)]

pub struct PrimitiveSymbolic {

    // Phase 1: parser

    pub(crate) identifier: NamespacedIdentifier,

    // Phase 2: typing

    pub(crate) definition: Option<DefinitionId>

}

impl PartialEq for PrimitiveSymbolic {

    fn eq(&self, other: &Self) -> bool {

        self.identifier == other.identifier

    }

}

impl Eq for PrimitiveSymbolic{}

#[derive(Debug, Clone, PartialEq, Eq, serde::Serialize, serde::Deserialize)]

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")?;

            }

            PrimitiveType::Symbolic(data) => {

                // Type data is in ASCII range.

                if let Some(id) = &data.definition {

                    write!(

                        f, "Symbolic({}, id: {})", 

                        String::from_utf8_lossy(&data.identifier.value),

                        id.index

                    )?;

                } else {

                    write!(

                        f, "Symbolic({}, id: Unresolved)",

                        String::from_utf8_lossy(&data.identifier.value)

                    )?;

                }

            }

        }

        if self.array {

            write!(f, "[]")

        } else {

            Ok(())

        }

    }

}

type LiteralCharacter = Vec<u8>;

type LiteralInteger = i64; // TODO: @int_literal

#[derive(Debug, Clone, serde::Serialize, serde::Deserialize)]

pub enum Literal {

    Null, // message

    True,

    False,

    Character(LiteralCharacter),

    Integer(LiteralInteger),

    Struct(LiteralStruct),

}

#[derive(Debug, Clone, serde::Serialize, serde::Deserialize)]

pub struct LiteralStructField {

    // Phase 1: parser

    pub(crate) identifier: Identifier,

    pub(crate) value: ExpressionId,

    // Phase 2: linker

    pub(crate) field_idx: usize, // in struct definition

}

#[derive(Debug, Clone, serde::Serialize, serde::Deserialize)]

pub struct LiteralStruct {

    // Phase 1: parser

    pub(crate) identifier: NamespacedIdentifier,

    pub(crate) poly_args: Vec<ParserTypeId>,

    pub(crate) fields: Vec<LiteralStructField>,

    // Phase 2: linker

    pub(crate) definition: Option<DefinitionId>

}

#[derive(Debug, Clone, serde::Serialize, serde::Deserialize)]

pub enum Method {

    Get,

    Put,

    Fires,

    Create,

    Symbolic(MethodSymbolic)

}

#[derive(Debug, Clone, serde::Serialize, serde::Deserialize)]

pub struct MethodSymbolic {

    pub(crate) identifier: NamespacedIdentifier,

    pub(crate) definition: Option<DefinitionId>

}

#[derive(Debug, Clone, serde::Serialize, serde::Deserialize)]

pub enum Field {

    Length,

    Symbolic(Identifier),

}

impl Field {

    pub fn is_length(&self) -> bool {

        match self {

            Field::Length => true,

            _ => false,

        }

    }

}

#[derive(Debug, Clone, Copy, serde::Serialize, serde::Deserialize)]

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")

        }

    }

}

pub trait VariableScope {

    fn parent_scope(&self, h: &Heap) -> Option<Scope>;

    fn get_variable(&self, h: &Heap, id: &Identifier) -> Option<VariableId>;

}

impl VariableScope for Scope {

    fn parent_scope(&self, h: &Heap) -> Option<Scope> {

        match self {

            Scope::Definition(def) => h[*def].parent_scope(h),

            Scope::Regular(stmt) => h[*stmt].parent_scope(h),

            Scope::Synchronous((stmt, _)) => h[*stmt].parent_scope(h),

        }

    }

    fn get_variable(&self, h: &Heap, id: &Identifier) -> Option<VariableId> {

        match self {

            Scope::Definition(def) => h[*def].get_variable(h, id),

            Scope::Regular(stmt) => h[*stmt].get_variable(h, id),

            Scope::Synchronous((stmt, _)) => h[*stmt].get_variable(h, id),

        }

    }

}

#[derive(Debug, Clone, serde::Serialize, serde::Deserialize)]

pub enum Variable {

    Parameter(Parameter),

    Local(Local),

}

impl Variable {

    pub fn identifier(&self) -> &Identifier {

        match self {

            Variable::Parameter(var) => &var.identifier,

            Variable::Local(var) => &var.identifier,

        }

    }

    pub fn is_parameter(&self) -> bool {

        match self {

            Variable::Parameter(_) => true,

            _ => false,

        }

    }

    pub fn as_parameter(&self) -> &Parameter {

        match self {

            Variable::Parameter(result) => result,

            _ => panic!("Unable to cast `Variable` to `Parameter`"),

        }

    }

    pub fn as_local(&self) -> &Local {

        match self {

            Variable::Local(result) => result,

            _ => panic!("Unable to cast `Variable` to `Local`"),

        }