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!(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));

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!(ForkStatementId, StatementId, index(ForkStatement, Statement::Fork, statements), alloc(alloc_fork_statement));

define_new_ast_id!(EndForkStatementId, StatementId, index(EndForkStatement, Statement::EndFork, statements), alloc(alloc_end_fork_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!(CastExpressionId, ExpressionId, index(CastExpression, Expression::Cast, expressions), alloc(alloc_cast_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));

#[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) 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(),

            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 {

    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 {

        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() }

    }

}

#[derive(Debug, Clone, Copy)]

pub enum ComponentVariant {

    Primitive,

    Composite,

}

#[derive(Debug, Clone)]

pub struct ComponentDefinition {

    pub this: ComponentDefinitionId,

    pub defined_in: RootId,

    // Symbol scanning

    pub span: InputSpan,

    pub variant: ComponentVariant,

    pub identifier: Identifier,

    pub poly_vars: Vec<Identifier>,

    // Parsing

    pub parameters: Vec<VariableId>,

    pub body: BlockStatementId,

    // Validation/linking

    pub num_expressions_in_body: i32,

}

impl ComponentDefinition {

    // Used for preallocation during symbol scanning

    pub(crate) fn new_empty(

        this: ComponentDefinitionId, defined_in: RootId, span: InputSpan,

        variant: ComponentVariant, identifier: Identifier, poly_vars: Vec<Identifier>

    ) -> Self {

        Self{ 

            this, defined_in, span, variant, identifier, poly_vars,

            parameters: Vec::new(), 

            body: BlockStatementId::new_invalid(),

            num_expressions_in_body: -1,

        }

    }

}

// Note that we will have function definitions for builtin functions as well. In

// that case the span, the identifier span and the body are all invalid.

#[derive(Debug, Clone)]

pub struct FunctionDefinition {

    pub this: FunctionDefinitionId,

    pub defined_in: RootId,

    // Symbol scanning

    pub builtin: bool,

    pub span: InputSpan,

    pub identifier: Identifier,

    pub poly_vars: Vec<Identifier>,

    // Parser

    pub return_types: Vec<ParserType>,

    pub parameters: Vec<VariableId>,

    pub body: BlockStatementId,

    // Validation/linking

    pub num_expressions_in_body: i32,

}

impl FunctionDefinition {

    pub(crate) fn new_empty(

        this: FunctionDefinitionId, defined_in: RootId, span: InputSpan,

        identifier: Identifier, poly_vars: Vec<Identifier>

    ) -> Self {

        Self {

            this, defined_in,

            builtin: false,

            span, identifier, poly_vars,

            return_types: Vec::new(),

            parameters: Vec::new(),

            body: BlockStatementId::new_invalid(),

            num_expressions_in_body: -1,

        }

    }

}

#[derive(Debug, Clone)]

pub enum Statement {

    Block(BlockStatement),

    EndBlock(EndBlockStatement),

    Local(LocalStatement),

    Labeled(LabeledStatement),

    If(IfStatement),

    EndIf(EndIfStatement),

    While(WhileStatement),

    EndWhile(EndWhileStatement),

    Break(BreakStatement),

    Continue(ContinueStatement),

    Synchronous(SynchronousStatement),

    EndSynchronous(EndSynchronousStatement),

    Fork(ForkStatement),

    EndFork(EndForkStatement),

    Return(ReturnStatement),

    Goto(GotoStatement),

    New(NewStatement),

    Expression(ExpressionStatement),

}

impl Statement {

    pub fn as_block(&self) -> &BlockStatement {

        match self {

            Statement::Block(result) => result,

            _ => panic!("Unable to cast `Statement` to `BlockStatement`"),

        }

    }

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

        match self {

            Statement::Local(result) => result,

            _ => panic!("Unable to cast `Statement` to `LocalStatement`"),

        }

    }

    pub fn as_memory(&self) -> &MemoryStatement {

        self.as_local().as_memory()

    }

    pub fn as_channel(&self) -> &ChannelStatement {

        self.as_local().as_channel()

    }

    pub fn as_new(&self) -> &NewStatement {

        match self {

            Statement::New(result) => result,

            _ => panic!("Unable to cast `Statement` to `NewStatement`"),

        }

    }

    pub fn span(&self) -> InputSpan {

        match self {

            Statement::Block(v) => v.span,

            Statement::Local(v) => v.span(),

            Statement::Labeled(v) => v.label.span,

            Statement::If(v) => v.span,

            Statement::While(v) => v.span,

            Statement::Break(v) => v.span,

            Statement::Continue(v) => v.span,

            Statement::Synchronous(v) => v.span,

            Statement::Fork(v) => v.span,

            Statement::Return(v) => v.span,

            Statement::Goto(v) => v.span,

            Statement::New(v) => v.span,

            Statement::Expression(v) => v.span,

        }

    }

    pub fn link_next(&mut self, next: StatementId) {

        match self {

            Statement::Block(stmt) => stmt.next = next,

            Statement::EndBlock(stmt) => stmt.next = next,

            Statement::Local(stmt) => match stmt {

                LocalStatement::Channel(stmt) => stmt.next = next,

                LocalStatement::Memory(stmt) => stmt.next = next,

            },

            Statement::EndIf(stmt) => stmt.next = next,

            Statement::EndWhile(stmt) => stmt.next = next,

            Statement::EndSynchronous(stmt) => stmt.next = next,

            Statement::EndFork(stmt) => stmt.next = next,

            Statement::New(stmt) => stmt.next = next,

            Statement::Expression(stmt) => stmt.next = next,

            Statement::Return(_)

            | Statement::Break(_)

            | Statement::Continue(_)

            | Statement::Synchronous(_)

            | Statement::Fork(_)

            | Statement::Goto(_)

            | Statement::While(_)

            | Statement::Labeled(_)

            | Statement::If(_) => unreachable!(),

        }

    }

}

#[derive(Debug, Clone)]

pub struct BlockStatement {

    pub this: BlockStatementId,

    // Phase 1: parser

    pub is_implicit: bool,

    pub span: InputSpan, // of the complete block

    pub statements: Vec<StatementId>,

    pub end_block: EndBlockStatementId,

    // Phase 2: linker

    pub scope_node: ScopeNode,

    pub first_unique_id_in_scope: i32, // Temporary fix until proper bytecode/asm is generated

    pub next_unique_id_in_scope: i32, // Temporary fix until proper bytecode/asm is generated

    pub relative_pos_in_parent: u32,

    pub locals: Vec<VariableId>,

    pub labels: Vec<LabeledStatementId>,

    pub next: StatementId,

}

#[derive(Debug, Clone)]

pub struct EndBlockStatement {

    pub this: EndBlockStatementId,

    // Parser

    pub start_block: BlockStatementId,

    // Validation/Linking

    pub next: StatementId,

}

#[derive(Debug, Clone)]

pub enum LocalStatement {

    Memory(MemoryStatement),

    Channel(ChannelStatement),

}

impl LocalStatement {

    pub fn this(&self) -> LocalStatementId {

        match self {

            LocalStatement::Memory(stmt) => stmt.this.upcast(),

            LocalStatement::Channel(stmt) => stmt.this.upcast(),

        }

    }

    pub fn as_memory(&self) -> &MemoryStatement {

        match self {

            LocalStatement::Memory(result) => result,

            _ => panic!("Unable to cast `LocalStatement` to `MemoryStatement`"),

        }

    }

    pub fn as_channel(&self) -> &ChannelStatement {

        match self {

            LocalStatement::Channel(result) => result,

            _ => panic!("Unable to cast `LocalStatement` to `ChannelStatement`"),

        }

    }

    pub fn span(&self) -> InputSpan {

        match self {

            LocalStatement::Channel(v) => v.span,

            LocalStatement::Memory(v) => v.span,

        }

    }

}

#[derive(Debug, Clone)]

pub struct MemoryStatement {

    pub this: MemoryStatementId,

    // Phase 1: parser

    pub span: InputSpan,

    pub variable: VariableId,

    // Phase 2: linker

    pub next: StatementId,

}

/// ChannelStatement is the declaration of an input and output port associated

/// with the same channel. Note that the polarity of the ports are from the

/// point of view of the component. So an output port is something that a

/// component uses to send data over (i.e. it is the "input end" of the

/// channel), and vice versa.

#[derive(Debug, Clone)]

pub struct ChannelStatement {

    pub this: ChannelStatementId,

    // Phase 1: parser

    pub span: InputSpan, // of the "channel" keyword

    pub from: VariableId, // output

    pub to: VariableId,   // input

    // Phase 2: linker

    pub relative_pos_in_block: u32,

    pub next: StatementId,

}

#[derive(Debug, Clone)]

    // Phase 2: linker

    pub relative_pos_in_block: u32,

    pub in_sync: SynchronousStatementId, // may be invalid

}

#[derive(Debug, Clone)]

pub struct IfStatement {

    pub this: IfStatementId,

    // Phase 1: parser

    pub span: InputSpan, // of the "if" keyword

    pub test: ExpressionId,

    pub true_body: BlockStatementId,

    pub false_body: Option<BlockStatementId>,

    pub end_if: EndIfStatementId,

}

#[derive(Debug, Clone)]

pub struct EndIfStatement {

    pub this: EndIfStatementId,

    pub start_if: IfStatementId,

    pub next: StatementId,

}

#[derive(Debug, Clone)]

pub struct WhileStatement {

    pub this: WhileStatementId,

    // Phase 1: parser

    pub span: InputSpan, // of the "while" keyword

    pub test: ExpressionId,

    pub body: BlockStatementId,

    pub end_while: EndWhileStatementId,

    pub in_sync: SynchronousStatementId, // may be invalid

}

#[derive(Debug, Clone)]

pub struct EndWhileStatement {

    pub this: EndWhileStatementId,

    pub start_while: WhileStatementId,

    // Phase 2: linker

    pub next: StatementId,

}

#[derive(Debug, Clone)]

pub struct BreakStatement {

    pub this: BreakStatementId,

    // Phase 1: parser

    pub span: InputSpan, // of the "break" keyword

    pub label: Option<Identifier>,

    // Phase 2: linker

    pub target: Option<EndWhileStatementId>,

}

#[derive(Debug, Clone)]

pub struct ContinueStatement {

    pub this: ContinueStatementId,

    // Phase 1: parser

    pub span: InputSpan, // of the "continue" keyword

    pub label: Option<Identifier>,

    // Phase 2: linker

    pub target: Option<WhileStatementId>,

}

#[derive(Debug, Clone)]

pub struct SynchronousStatement {

    pub this: SynchronousStatementId,

    // Phase 1: parser

    pub span: InputSpan, // of the "sync" keyword

    pub body: BlockStatementId,

    pub end_sync: EndSynchronousStatementId,

}

#[derive(Debug, Clone)]

pub struct EndSynchronousStatement {

    pub this: EndSynchronousStatementId,

    pub start_sync: SynchronousStatementId,

    // Phase 2: linker

    pub next: StatementId,

}

#[derive(Debug, Clone)]

pub struct ForkStatement {

    pub this: ForkStatementId,

    // Phase 1: parser

    pub span: InputSpan, // of the "fork" keyword

    pub left_body: BlockStatementId,

    pub right_body: Option<BlockStatementId>,

    pub end_fork: EndForkStatementId,

}

#[derive(Debug, Clone)]

pub struct EndForkStatement {

    pub this: EndForkStatementId,

    pub start_fork: ForkStatementId,

    pub next: StatementId,

}

#[derive(Debug, Clone)]

pub struct ReturnStatement {

    pub this: ReturnStatementId,

    // Phase 1: parser

    pub span: InputSpan, // of the "return" keyword

    pub expressions: Vec<ExpressionId>,

}

#[derive(Debug, Clone)]

pub struct GotoStatement {

    pub this: GotoStatementId,

    // Phase 1: parser

    pub span: InputSpan, // of the "goto" keyword

    pub label: Identifier,

    // Phase 2: linker

    pub target: Option<LabeledStatementId>,

}

#[derive(Debug, Clone)]

pub struct NewStatement {

    pub this: NewStatementId,

    // Phase 1: parser

    pub span: InputSpan, // of the "new" keyword

    pub expression: CallExpressionId,

    // Phase 2: linker

    pub next: StatementId,

}

#[derive(Debug, Clone)]

pub struct ExpressionStatement {

    pub this: ExpressionStatementId,

    // Phase 1: parser

    pub span: InputSpan,

    pub expression: ExpressionId,

    // Phase 2: linker

    pub next: StatementId,

}

#[derive(Debug, PartialEq, Eq, Clone, Copy)]

pub enum ExpressionParent {

    None, // only set during initial parsing

    If(IfStatementId),

    While(WhileStatementId),

    Return(ReturnStatementId),

    New(NewStatementId),

    ExpressionStmt(ExpressionStatementId),

    Expression(ExpressionId, u32) // index within expression (e.g LHS or RHS of expression)

}

impl ExpressionParent {

    pub fn is_new(&self) -> bool {

        match self {

            ExpressionParent::New(_) => true,

            _ => false,

        }

    }

    pub fn as_expression(&self) -> ExpressionId {

        match self {

            ExpressionParent::Expression(id, _) => *id,

            _ => panic!("called as_expression() on {:?}", self),

        }

    }

}

#[derive(Debug, Clone)]

pub enum Expression {

    Assignment(AssignmentExpression),

    Binding(BindingExpression),

    Conditional(ConditionalExpression),

    Binary(BinaryExpression),

    Unary(UnaryExpression),

    Indexing(IndexingExpression),

    Slicing(SlicingExpression),

    Select(SelectExpression),

    Literal(LiteralExpression),

    Cast(CastExpression),

    Call(CallExpression),

    Variable(VariableExpression),

}

impl Expression {

    pub fn as_variable(&self) -> &VariableExpression {

        match self {

            Expression::Variable(result) => result,

            _ => panic!("Unable to cast `Expression` to `VariableExpression`"),

        }

    }

    /// Returns operator span, function name, a binding's "let" span, etc. An

    /// indicator for the kind of expression that is being applied.

    pub fn operation_span(&self) -> InputSpan {

        match self {

            Expression::Assignment(expr) => expr.operator_span,

            Expression::Binding(expr) => expr.operator_span,

            Expression::Conditional(expr) => expr.operator_span,

#![allow(dead_code)]

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

use std::io::Write as IOWrite;

use super::ast::*;

use super::token_parsing::*;

const INDENT: usize = 2;

const PREFIX_EMPTY: &'static str = "    ";

const PREFIX_ROOT_ID: &'static str = "Root";

const PREFIX_PRAGMA_ID: &'static str = "Prag";

const PREFIX_IMPORT_ID: &'static str = "Imp ";

const PREFIX_TYPE_ANNOT_ID: &'static str = "TyAn";

const PREFIX_VARIABLE_ID: &'static str = "Var ";

const PREFIX_DEFINITION_ID: &'static str = "Def ";

const PREFIX_STRUCT_ID: &'static str = "DefS";

const PREFIX_ENUM_ID: &'static str = "DefE";

const PREFIX_UNION_ID: &'static str = "DefU";

const PREFIX_COMPONENT_ID: &'static str = "DefC";

const PREFIX_FUNCTION_ID: &'static str = "DefF";

const PREFIX_STMT_ID: &'static str = "Stmt";

const PREFIX_BLOCK_STMT_ID: &'static str = "SBl ";

const PREFIX_ENDBLOCK_STMT_ID: &'static str = "SEBl";

const PREFIX_LOCAL_STMT_ID: &'static str = "SLoc";

const PREFIX_MEM_STMT_ID: &'static str = "SMem";

const PREFIX_CHANNEL_STMT_ID: &'static str = "SCha";

const PREFIX_SKIP_STMT_ID: &'static str = "SSki";

const PREFIX_LABELED_STMT_ID: &'static str = "SLab";

const PREFIX_IF_STMT_ID: &'static str = "SIf ";

const PREFIX_ENDIF_STMT_ID: &'static str = "SEIf";

const PREFIX_WHILE_STMT_ID: &'static str = "SWhi";

const PREFIX_ENDWHILE_STMT_ID: &'static str = "SEWh";

const PREFIX_BREAK_STMT_ID: &'static str = "SBre";

const PREFIX_CONTINUE_STMT_ID: &'static str = "SCon";

const PREFIX_SYNC_STMT_ID: &'static str = "SSyn";

const PREFIX_ENDSYNC_STMT_ID: &'static str = "SESy";

const PREFIX_FORK_STMT_ID: &'static str = "SFrk";

const PREFIX_END_FORK_STMT_ID: &'static str = "SEFk";

const PREFIX_RETURN_STMT_ID: &'static str = "SRet";

const PREFIX_ASSERT_STMT_ID: &'static str = "SAsr";

const PREFIX_GOTO_STMT_ID: &'static str = "SGot";

const PREFIX_NEW_STMT_ID: &'static str = "SNew";

const PREFIX_PUT_STMT_ID: &'static str = "SPut";

const PREFIX_EXPR_STMT_ID: &'static str = "SExp";

const PREFIX_ASSIGNMENT_EXPR_ID: &'static str = "EAsi";

const PREFIX_BINDING_EXPR_ID: &'static str = "EBnd";

const PREFIX_CONDITIONAL_EXPR_ID: &'static str = "ECnd";

const PREFIX_BINARY_EXPR_ID: &'static str = "EBin";

const PREFIX_UNARY_EXPR_ID: &'static str = "EUna";

const PREFIX_INDEXING_EXPR_ID: &'static str = "EIdx";

const PREFIX_SLICING_EXPR_ID: &'static str = "ESli";

const PREFIX_SELECT_EXPR_ID: &'static str = "ESel";

const PREFIX_LITERAL_EXPR_ID: &'static str = "ELit";

const PREFIX_CAST_EXPR_ID: &'static str = "ECas";

const PREFIX_CALL_EXPR_ID: &'static str = "ECll";

const PREFIX_VARIABLE_EXPR_ID: &'static str = "EVar";

struct KV<'a> {

    buffer: &'a mut String,

    prefix: Option<(&'static str, i32)>,

    indent: usize,

    temp_key: &'a mut String,

    temp_val: &'a mut String,

}

impl<'a> KV<'a> {

    fn new(buffer: &'a mut String, temp_key: &'a mut String, temp_val: &'a mut String, indent: usize) -> Self {

        temp_key.clear();

        temp_val.clear();

        KV{

            buffer,

            prefix: None,

            indent,

            temp_key,

            temp_val

        }

    }

    fn with_id(mut self, prefix: &'static str, id: i32) -> Self {

        self.prefix = Some((prefix, id));

        self

    }

    fn with_s_key(self, key: &str) -> Self {

        self.temp_key.push_str(key);

        self

    }

    fn with_d_key<D: Display>(self, key: &D) -> Self {

        self.temp_key.push_str(&key.to_string());

        self

    }

    fn with_s_val(self, val: &str) -> Self {

        self.temp_val.push_str(val);

        self

    }

    fn with_disp_val<D: Display>(self, val: &D) -> Self {

        self.temp_val.push_str(&format!("{}", val));

        self

    }

    fn with_debug_val<D: Debug>(self, val: &D) -> Self {

        self.temp_val.push_str(&format!("{:?}", val));

        self

    }

    fn with_identifier_val(self, val: &Identifier) -> Self {

        self.temp_val.push_str(val.value.as_str());

        self

    }

    fn with_opt_disp_val<D: Display>(self, val: Option<&D>) -> Self {

        match val {

            Some(v) => { self.temp_val.push_str(&format!("Some({})", v)); },

            None => { self.temp_val.push_str("None"); }

        }

        self

    }

    fn with_opt_identifier_val(self, val: Option<&Identifier>) -> Self {

        match val {

            Some(v) => {

                self.temp_val.push_str("Some(");

                self.temp_val.push_str(v.value.as_str());

                self.temp_val.push(')');

            },

            None => {

                self.temp_val.push_str("None");

            }

        }

        self

    }

            },

            Statement::Labeled(stmt) => {

                self.kv(indent).with_id(PREFIX_LABELED_STMT_ID, stmt.this.0.index)

                    .with_s_key("Labeled");

                self.kv(indent2).with_s_key("Label").with_identifier_val(&stmt.label);

                self.kv(indent2).with_s_key("Statement");

                self.write_stmt(heap, stmt.body, indent3);

            },

            Statement::If(stmt) => {

                self.kv(indent).with_id(PREFIX_IF_STMT_ID, stmt.this.0.index)

                    .with_s_key("If");

                self.kv(indent2).with_s_key("EndIf").with_disp_val(&stmt.end_if.0.index);

                self.kv(indent2).with_s_key("Condition");

                self.write_expr(heap, stmt.test, indent3);

                self.kv(indent2).with_s_key("TrueBody");

                self.write_stmt(heap, stmt.true_body.upcast(), indent3);

                if let Some(false_body) = stmt.false_body {

                    self.kv(indent2).with_s_key("FalseBody");

                    self.write_stmt(heap, false_body.upcast(), indent3);

                }

            },

            Statement::EndIf(stmt) => {

                self.kv(indent).with_id(PREFIX_ENDIF_STMT_ID, stmt.this.0.index)

                    .with_s_key("EndIf");

                self.kv(indent2).with_s_key("StartIf").with_disp_val(&stmt.start_if.0.index);

                self.kv(indent2).with_s_key("Next").with_disp_val(&stmt.next.index);

            },

            Statement::While(stmt) => {

                self.kv(indent).with_id(PREFIX_WHILE_STMT_ID, stmt.this.0.index)

                    .with_s_key("While");

                self.kv(indent2).with_s_key("EndWhile").with_disp_val(&stmt.end_while.0.index);

                self.kv(indent2).with_s_key("InSync")

                    .with_disp_val(&stmt.in_sync.0.index);

                self.kv(indent2).with_s_key("Condition");

                self.write_expr(heap, stmt.test, indent3);

                self.kv(indent2).with_s_key("Body");

                self.write_stmt(heap, stmt.body.upcast(), indent3);

            },

            Statement::EndWhile(stmt) => {

                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);