// TODO: @cleanup, rigorous cleanup of dead code and silly object-oriented

//  trait impls where I deem them unfit.

use std::fmt;

use std::fmt::{Debug, Display, Formatter};

use std::ops::{Index, IndexMut};

use super::arena::{Arena, Id};

use crate::protocol::inputsource::*;

/// Global limits to the AST, should be checked by lexer and parser. Some are

/// arbitrary

const MAX_LEVEL: usize = 128;

const MAX_NAMESPACES: usize = 64;

/// Helper macro that defines a type alias for a AST element ID. In this case 

/// only used to alias the `Id<T>` types.

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, $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]

            }

        }

    }

}

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

        pub struct $name (pub(crate) $parent);

        impl $name {

            pub fn upcast(self) -> $parent {

                self.0

            }

        }

    };

    // Variant where we define the type, and the Index and IndexMut traits

    ($name:ident, $parent:ty, $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!()

                }

            }

        }

    }

}

define_aliased_ast_id!(RootId, Id<Root>, Root, protocol_descriptions);

define_aliased_ast_id!(PragmaId, Id<Pragma>, Pragma, pragmas);

define_aliased_ast_id!(ImportId, Id<Import>, Import, imports);

define_aliased_ast_id!(ParserTypeId, Id<ParserType>, ParserType, parser_types);

define_aliased_ast_id!(VariableId, Id<Variable>, Variable, variables);

define_new_ast_id!(ParameterId, VariableId, Parameter, Variable::Parameter, variables);

define_new_ast_id!(LocalId, VariableId, Local, Variable::Local, variables);

define_aliased_ast_id!(DefinitionId, Id<Definition>, Definition, definitions);

define_new_ast_id!(StructId, DefinitionId, StructDefinition, Definition::Struct, definitions);

define_new_ast_id!(EnumId, DefinitionId, EnumDefinition, Definition::Enum, definitions);

define_new_ast_id!(ComponentId, DefinitionId, Component, Definition::Component, definitions);

define_new_ast_id!(FunctionId, DefinitionId, Function, Definition::Function, definitions);

define_aliased_ast_id!(StatementId, Id<Statement>, Statement, statements);

define_new_ast_id!(BlockStatementId, StatementId, BlockStatement, Statement::Block, statements);

define_new_ast_id!(LocalStatementId, StatementId, LocalStatement, Statement::Local, statements);

define_new_ast_id!(MemoryStatementId, LocalStatementId);

define_new_ast_id!(ChannelStatementId, LocalStatementId);

define_new_ast_id!(SkipStatementId, StatementId, SkipStatement, Statement::Skip, statements);

define_new_ast_id!(LabeledStatementId, StatementId, LabeledStatement, Statement::Labeled, statements);

define_new_ast_id!(IfStatementId, StatementId, IfStatement, Statement::If, statements);

define_new_ast_id!(EndIfStatementId, StatementId, EndIfStatement, Statement::EndIf, statements);

define_new_ast_id!(WhileStatementId, StatementId, WhileStatement, Statement::While, statements);

define_new_ast_id!(EndWhileStatementId, StatementId, EndWhileStatement, Statement::EndWhile, statements);

define_new_ast_id!(BreakStatementId, StatementId, BreakStatement, Statement::Break, statements);

define_new_ast_id!(ContinueStatementId, StatementId, ContinueStatement, Statement::Continue, statements);

define_new_ast_id!(SynchronousStatementId, StatementId, SynchronousStatement, Statement::Synchronous, statements);

define_new_ast_id!(EndSynchronousStatementId, StatementId, EndSynchronousStatement, Statement::EndSynchronous, statements);

define_new_ast_id!(ReturnStatementId, StatementId, ReturnStatement, Statement::Return, statements);

define_new_ast_id!(AssertStatementId, StatementId, AssertStatement, Statement::Assert, statements);

define_new_ast_id!(GotoStatementId, StatementId, GotoStatement, Statement::Goto, statements);

define_new_ast_id!(NewStatementId, StatementId, NewStatement, Statement::New, statements);

define_new_ast_id!(ExpressionStatementId, StatementId, ExpressionStatement, Statement::Expression, statements);

define_aliased_ast_id!(ExpressionId, Id<Expression>, Expression, expressions);

define_new_ast_id!(AssignmentExpressionId, ExpressionId, AssignmentExpression, Expression::Assignment, expressions);

define_new_ast_id!(ConditionalExpressionId, ExpressionId, ConditionalExpression, Expression::Conditional, expressions);

define_new_ast_id!(BinaryExpressionId, ExpressionId, BinaryExpression, Expression::Binary, expressions);

define_new_ast_id!(UnaryExpressionId, ExpressionId, UnaryExpression, Expression::Unary, expressions);

define_new_ast_id!(IndexingExpressionId, ExpressionId, IndexingExpression, Expression::Indexing, expressions);

define_new_ast_id!(SlicingExpressionId, ExpressionId, SlicingExpression, Expression::Slicing, expressions);

define_new_ast_id!(SelectExpressionId, ExpressionId, SelectExpression, Expression::Select, expressions);

define_new_ast_id!(ArrayExpressionId, ExpressionId, ArrayExpression, Expression::Array, expressions);

define_new_ast_id!(LiteralExpressionId, ExpressionId, LiteralExpression, Expression::Literal, expressions);

define_new_ast_id!(CallExpressionId, ExpressionId, CallExpression, Expression::Call, expressions);

define_new_ast_id!(VariableExpressionId, ExpressionId, VariableExpression, Expression::Variable, expressions);

// TODO: @cleanup - pub qualifiers can be removed once done

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

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>,

    identifiers: Arena<Identifier>,

    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(),

            identifiers: Arena::new(),

            parser_types: Arena::new(),

            variables: Arena::new(),

            definitions: Arena::new(),

            statements: Arena::new(),

            expressions: Arena::new(),

        }

    }

    pub fn alloc_parser_type(

        &mut self,

        f: impl FnOnce(ParserTypeId) -> ParserType,

    ) -> ParserTypeId {

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

    }

    pub fn alloc_parameter(&mut self, f: impl FnOnce(ParameterId) -> Parameter) -> ParameterId {

        ParameterId(

            self.variables.alloc_with_id(|id| Variable::Parameter(f(ParameterId(id)))),

        )

    }

    pub fn alloc_local(&mut self, f: impl FnOnce(LocalId) -> Local) -> LocalId {

        LocalId(

            self.variables.alloc_with_id(|id| Variable::Local(f(LocalId(id)))),

        )

    }

    pub fn alloc_assignment_expression(

        &mut self,

        f: impl FnOnce(AssignmentExpressionId) -> AssignmentExpression,

    ) -> AssignmentExpressionId {

        AssignmentExpressionId(

            self.expressions.alloc_with_id(|id| {

                Expression::Assignment(f(AssignmentExpressionId(id)))

            })

        )

    }

    pub fn alloc_conditional_expression(

        &mut self,

        f: impl FnOnce(ConditionalExpressionId) -> ConditionalExpression,

    ) -> ConditionalExpressionId {

        ConditionalExpressionId(

            self.expressions.alloc_with_id(|id| {

                Expression::Conditional(f(ConditionalExpressionId(id)))

            })

        )

    }

    pub fn alloc_binary_expression(

        &mut self,

        f: impl FnOnce(BinaryExpressionId) -> BinaryExpression,

    ) -> BinaryExpressionId {

        BinaryExpressionId(

            self.expressions

                .alloc_with_id(|id| Expression::Binary(f(BinaryExpressionId(id)))),

        )

    }

    pub fn alloc_unary_expression(

        &mut self,

        f: impl FnOnce(UnaryExpressionId) -> UnaryExpression,

    ) -> UnaryExpressionId {

        UnaryExpressionId(

            self.expressions

                .alloc_with_id(|id| Expression::Unary(f(UnaryExpressionId(id)))),

        )

    }

    pub fn alloc_slicing_expression(

        &mut self,

        f: impl FnOnce(SlicingExpressionId) -> SlicingExpression,

    ) -> SlicingExpressionId {

        SlicingExpressionId(

            self.expressions

                .alloc_with_id(|id| Expression::Slicing(f(SlicingExpressionId(id)))),

        )

    }

    pub fn alloc_indexing_expression(

        &mut self,

        f: impl FnOnce(IndexingExpressionId) -> IndexingExpression,

    ) -> IndexingExpressionId {

        IndexingExpressionId(

            self.expressions.alloc_with_id(|id| {

                Expression::Indexing(f(IndexingExpressionId(id)))

            }),

        )

    }

    pub fn alloc_select_expression(

        &mut self,

        f: impl FnOnce(SelectExpressionId) -> SelectExpression,

    ) -> SelectExpressionId {

        SelectExpressionId(

            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: Identifier,

    // 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: Identifier,

    pub alias: Identifier,

    // 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>

}

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 {

        // A source identifier is in ASCII range.

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

    }

}

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

pub enum NamespacedIdentifierPart {

    // Regular identifier

    Identifier{start: u16, end: u16},

    // Polyargs associated with a preceding identifier

    PolyArgs{start: u16, end: u16},

}

impl NamespacedIdentifierPart {

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

        match self {

            NamespacedIdentifierPart::Identifier{..} => true,

            NamespacedIdentifierPart::PolyArgs{..} => false,

        }

    }

    pub(crate) fn as_identifier(&self) -> (u16, u16) {

        match self {

            NamespacedIdentifierPart::Identifier{start, end} => (*start, *end),

            NamespacedIdentifierPart::PolyArgs{..} => {

                unreachable!("Tried to obtain {:?} as Identifier", self);

            }

        }

    }

    pub(crate) fn as_poly_args(&self) -> (u16, u16) {

        match self {

            NamespacedIdentifierPart::PolyArgs{start, end} => (*start, *end),

            NamespacedIdentifierPart::Identifier{..} => {

                unreachable!("Tried to obtain {:?} as PolyArgs", self)

            }

        }

    }

}

/// An identifier with optional namespaces and polymorphic variables. Note that 

/// we allow each identifier to be followed by polymorphic arguments during the 

/// parsing phase (e.g. Foo<A,B>::Bar<C,D>::Qux). But in our current language 

/// implementation we can only have valid namespaced identifier that contain one

/// set of polymorphic arguments at the appropriate position.

/// TODO: @tokens Reimplement/rename once we have a tokenizer

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

pub struct NamespacedIdentifier {

    pub position: InputPosition,

    pub value: Vec<u8>, // Full name as it resides in the input source

    pub poly_args: Vec<ParserTypeId>, // All poly args littered throughout the namespaced identifier

    pub parts: Vec<NamespacedIdentifierPart>, // Indices into value/poly_args

}

impl NamespacedIdentifier {

    /// Returns the identifier value without any of the specific polymorphic

    /// arguments.

    pub fn strip_poly_args(&self) -> Vec<u8> {

        debug_assert!(!self.parts.is_empty() && self.parts[0].is_identifier());

        let mut result = Vec::with_capacity(self.value.len());

        let mut iter = self.iter();

        let (first_ident, _) = iter.next().unwrap();

        result.extend(first_ident);

        for (ident, _) in iter.next() {

            result.push(b':');

            result.push(b':');

            result.extend(ident);

        }

        result

    }

    /// Returns an iterator of the elements in the namespaced identifier

    pub fn iter(&self) -> NamespacedIdentifierIter {

        return NamespacedIdentifierIter{

            identifier: self,

            element_idx: 0

        }

    }

    pub fn get_poly_args(&self) -> Option<&[ParserTypeId]> {

        let has_poly_args = self.parts.iter().any(|v| !v.is_identifier());

        if has_poly_args {

            Some(&self.poly_args)

        } else {

            None

        }

    }

    // Check if two namespaced identifiers match eachother when not considering

    // the polymorphic arguments

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

        let mut iter_self = self.iter();

        let mut iter_other = other.iter();

        loop {

            let val_self = iter_self.next();

            let val_other = iter_other.next();

            if val_self.is_some() != val_other.is_some() {

                // One is longer than the other

                return false;

            }

            if val_self.is_none() {

                // Both are none

                return true;

            }

            // Both are something

            let (val_self, _) = val_self.unwrap();

            let (val_other, _) = val_other.unwrap();

            if val_self != val_other { return false; }

        }

    }

    // Check if the namespaced identifier matches an identifier when not 

    // considering the polymorphic arguments

    pub fn matches_identifier(&self, other: &Identifier) -> bool {

        let mut iter = self.iter();

        let (first_ident, _) = iter.next().unwrap();

        if first_ident != other.value { 

            return false;

        }

        if iter.next().is_some() {

            return false;

        }

        return true;

    }

}

/// Iterator over elements of the namespaced identifier. The element index will

/// only ever be at the start of an identifier element.

#[derive(Debug)]

pub struct NamespacedIdentifierIter<'a> {

    identifier: &'a NamespacedIdentifier,

    element_idx: usize,

}

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

    type Item = (&'a [u8], Option<&'a [ParserTypeId]>);

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

        match self.get(self.element_idx) {

            Some((ident, poly)) => {

                self.element_idx += 1;

                if poly.is_some() {

                    self.element_idx += 1;

                }

                Some((ident, poly))

            },

            None => None

        }

    }

}

impl<'a> NamespacedIdentifierIter<'a> {

    /// Returns number of parts iterated over, may not correspond to number of

    /// times one called `next()` because returning an identifier with 

    /// polymorphic arguments increments the internal counter by 2.

    pub fn num_returned(&self) -> usize {

        return self.element_idx;

    }

    pub fn num_remaining(&self) -> usize {

        return self.identifier.parts.len() - self.element_idx;

    }

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

        if self.element_idx == 0 { return &self.identifier.value[0..0]; }

        let last_idx = match &self.identifier.parts[self.element_idx - 1] {

            NamespacedIdentifierPart::Identifier{end, ..} => *end,

            NamespacedIdentifierPart::PolyArgs{end, ..} => *end,

        };

        return &self.identifier.value[..last_idx as usize];

    }

    /// Returns a specific element from the namespaced identifier

    pub fn get(&self, idx: usize) -> Option<<Self as Iterator>::Item> {

        if idx >= self.identifier.parts.len() { 

            return None 

        }

        let cur_part = &self.identifier.parts[idx];

        let next_part = self.identifier.parts.get(idx + 1);

        let (ident_start, ident_end) = cur_part.as_identifier();

        let poly_slice = match next_part {

            Some(part) => match part {

                NamespacedIdentifierPart::Identifier{..} => None,

                NamespacedIdentifierPart::PolyArgs{start, end} => Some(

                    &self.identifier.poly_args[*start as usize..*end as usize]

                ),

            },

            None => None

        };

        Some((

            &self.identifier.value[ident_start as usize..ident_end as usize],

            poly_slice

        ))

    }

    /// Returns the previously returend index into the parts array of the 

    /// identifier.

    pub fn prev_idx(&self) -> Option<usize> {

        if self.element_idx == 0 { 

            return None;

        };

        if self.identifier.parts[self.element_idx - 1].is_identifier() { 

            return Some(self.element_idx - 1);

        }

        // Previous part had polymorphic arguments, so the one before that must

        // be an identifier (if well formed)

        debug_assert!(self.element_idx >= 2 && self.identifier.parts[self.element_idx - 2].is_identifier());

        return Some(self.element_idx - 2)

    }

    /// Returns the previously returned result from `next()`

    pub fn prev(&self) -> Option<<Self as Iterator>::Item> {

        match self.prev_idx() {

            None => None,

            Some(idx) => self.get(idx)

        }

    }

}

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