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));

    Block(BlockStatement),

    EndBlock(EndBlockStatement),

    Local(LocalStatement),

    Labeled(LabeledStatement),

    If(IfStatement),

    EndIf(EndIfStatement),

    While(WhileStatement),

    EndWhile(EndWhileStatement),

    Break(BreakStatement),

    Continue(ContinueStatement),

    Synchronous(SynchronousStatement),

    EndSynchronous(EndSynchronousStatement),

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

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

            Statement::Return(_)

            | Statement::Break(_)

            | Statement::Continue(_)

            | Statement::Synchronous(_)

            | Statement::Goto(_)

            | Statement::While(_)

            | Statement::Labeled(_)

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

        }

    }

}

#[derive(Debug, Clone)]

pub struct BlockStatement {

    pub this: BlockStatementId,

    // 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 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

                let while_stmt = &mut ctx.heap[id];

                while_stmt.end_while = end_while;

            } else if ident == KW_STMT_BREAK {

                let id = self.consume_break_statement(module, iter, ctx)?;

                section.push(id.upcast());

            } else if ident == KW_STMT_CONTINUE {

                let id = self.consume_continue_statement(module, iter, ctx)?;

                section.push(id.upcast());

            } else if ident == KW_STMT_SYNC {

                let id = self.consume_synchronous_statement(module, iter, ctx)?;

                section.push(id.upcast());

                });

                section.push(end_sync.upcast());

                let sync_stmt = &mut ctx.heap[id];

                sync_stmt.end_sync = end_sync;

            } else if ident == KW_STMT_RETURN {

                let id = self.consume_return_statement(module, iter, ctx)?;

                section.push(id.upcast());

            } else if ident == KW_STMT_GOTO {

                let id = self.consume_goto_statement(module, iter, ctx)?;

                section.push(id.upcast());

            } else if ident == KW_STMT_NEW {

                let id = self.consume_new_statement(module, iter, ctx)?;

                section.push(id.upcast());

            } else if ident == KW_STMT_CHANNEL {

                let id = self.consume_channel_statement(module, iter, ctx)?;

                section.push(id.upcast().upcast());

    ) -> Result<SynchronousStatementId, ParseError> {

        let synchronous_span = consume_exact_ident(&module.source, iter, KW_STMT_SYNC)?;

        let body = self.consume_block_or_wrapped_statement(module, iter, ctx)?;

        Ok(ctx.heap.alloc_synchronous_statement(|this| SynchronousStatement{

            this,

            span: synchronous_span,

            body,

            end_sync: EndSynchronousStatementId::new_invalid(),

        }))

    }

    fn consume_return_statement(

        &mut self, module: &Module, iter: &mut TokenIter, ctx: &mut PassCtx

    ) -> Result<ReturnStatementId, ParseError> {

        let return_span = consume_exact_ident(&module.source, iter, KW_STMT_RETURN)?;

        let mut scoped_section = self.expressions.start_section();

        consume_comma_separated_until(

            TokenKind::SemiColon, &module.source, iter, ctx,

            |_source, iter, ctx| self.consume_expression(module, iter, ctx),

            &mut scoped_section, "an expression", None

        )?;

        let expressions = scoped_section.into_vec();

        self.visit_block_stmt(ctx, body_id)?;

        Ok(())

    }

    fn visit_synchronous_stmt(&mut self, ctx: &mut Ctx, id: SynchronousStatementId) -> VisitorResult {

        let sync_stmt = &ctx.heap[id];

        let body_id = sync_stmt.body;

        self.visit_block_stmt(ctx, body_id)

    }

    fn visit_return_stmt(&mut self, ctx: &mut Ctx, id: ReturnStatementId) -> VisitorResult {

        let return_stmt = &ctx.heap[id];

        debug_assert_eq!(return_stmt.expressions.len(), 1);

        let expr_id = return_stmt.expressions[0];

        self.visit_expr(ctx, expr_id)

    }

    fn visit_new_stmt(&mut self, ctx: &mut Ctx, id: NewStatementId) -> VisitorResult {

        let new_stmt = &ctx.heap[id];

        let call_expr_id = new_stmt.expression;

use crate::collections::{ScopedBuffer};

use crate::protocol::ast::*;

use crate::protocol::input_source::*;

use crate::protocol::parser::symbol_table::*;

use crate::protocol::parser::type_table::*;

use super::visitor::{

    STMT_BUFFER_INIT_CAPACITY,

    EXPR_BUFFER_INIT_CAPACITY,

    Ctx,

    Visitor,

    VisitorResult

        // Visit test expression

        debug_assert_eq!(self.expr_parent, ExpressionParent::None);

        debug_assert!(self.in_test_expr.is_invalid());

        self.in_test_expr = id.upcast();

        self.expr_parent = ExpressionParent::If(id);

        self.visit_expr(ctx, test_expr_id)?;

        self.in_test_expr = StatementId::new_invalid();

        self.expr_parent = ExpressionParent::None;

        // Visit true and false branch. Executor chooses next statement based on

        assign_then_erase_next_stmt!(self, ctx, id.upcast());

        self.visit_block_stmt(ctx, true_stmt_id)?;

        assign_then_erase_next_stmt!(self, ctx, end_if_id.upcast());

        if let Some(false_id) = false_stmt_id {

            self.visit_block_stmt(ctx, false_id)?;

            assign_then_erase_next_stmt!(self, ctx, end_if_id.upcast());

        }

        self.prev_stmt = end_if_id.upcast();

        Ok(())

    }

        let sync_body = ctx.heap[id].body;

        debug_assert!(self.in_sync.is_invalid());

        self.in_sync = id;

        self.visit_block_stmt_with_hint(ctx, sync_body, Some(id))?;

        assign_and_replace_next_stmt!(self, ctx, end_sync_id.upcast());

        self.in_sync = SynchronousStatementId::new_invalid();

        Ok(())

    }

    fn visit_return_stmt(&mut self, ctx: &mut Ctx, id: ReturnStatementId) -> VisitorResult {

        // Check if "return" occurs within a function

        let stmt = &ctx.heap[id];

        if !self.def_type.is_function() {

            return Err(ParseError::new_error_str_at_span(

                &ctx.module().source, stmt.span,

                "return statements may only appear in function bodies"

            ));

        }

        // If here then we are within a function

        assign_then_erase_next_stmt!(self, ctx, id.upcast());

pub(crate) const KW_FUNC_PRINT:  &'static [u8] = b"print";

// Keywords - statements

pub(crate) const KW_STMT_CHANNEL:  &'static [u8] = b"channel";

pub(crate) const KW_STMT_IF:       &'static [u8] = b"if";

pub(crate) const KW_STMT_ELSE:     &'static [u8] = b"else";

pub(crate) const KW_STMT_WHILE:    &'static [u8] = b"while";

pub(crate) const KW_STMT_BREAK:    &'static [u8] = b"break";

pub(crate) const KW_STMT_CONTINUE: &'static [u8] = b"continue";

pub(crate) const KW_STMT_GOTO:     &'static [u8] = b"goto";

pub(crate) const KW_STMT_RETURN:   &'static [u8] = b"return";

pub(crate) const KW_STMT_SYNC:     &'static [u8] = b"sync";

pub(crate) const KW_STMT_NEW:      &'static [u8] = b"new";

// Keywords - types

// Since types are needed for returning diagnostic information to the user, the

// string variants are put here as well.

pub(crate) const KW_TYPE_IN_PORT_STR:  &'static str = "in";

pub(crate) const KW_TYPE_OUT_PORT_STR: &'static str = "out";

pub(crate) const KW_TYPE_MESSAGE_STR:  &'static str = "msg";

pub(crate) const KW_TYPE_BOOL_STR:     &'static str = "bool";

pub(crate) const KW_TYPE_UINT8_STR:    &'static str = "u8";

pub(crate) const KW_TYPE_UINT16_STR:   &'static str = "u16";

pub(crate) const KW_TYPE_UINT32_STR:   &'static str = "u32";

fn is_reserved_definition_keyword(text: &[u8]) -> bool {

    match text {

        KW_STRUCT | KW_ENUM | KW_UNION | KW_FUNCTION | KW_PRIMITIVE | KW_COMPOSITE => true,

        _ => false,

    }

}

fn is_reserved_statement_keyword(text: &[u8]) -> bool {

    match text {

        KW_IMPORT | KW_AS |

        KW_STMT_CHANNEL | KW_STMT_IF | KW_STMT_WHILE |

        KW_STMT_BREAK | KW_STMT_CONTINUE | KW_STMT_GOTO | KW_STMT_RETURN |

        _ => false,

    }

}

fn is_reserved_expression_keyword(text: &[u8]) -> bool {

    match text {

        KW_LET | KW_CAST |

        KW_LIT_TRUE | KW_LIT_FALSE | KW_LIT_NULL |

        KW_FUNC_GET | KW_FUNC_PUT | KW_FUNC_FIRES | KW_FUNC_CREATE | KW_FUNC_ASSERT | KW_FUNC_LENGTH | KW_FUNC_PRINT => true,

        _ => false,

    }

}

                let this = stmt.this;

                self.visit_break_stmt(ctx, this)

            },

            Statement::Continue(stmt) => {

                let this = stmt.this;

                self.visit_continue_stmt(ctx, this)

            },

            Statement::Synchronous(stmt) => {

                let this = stmt.this;

                self.visit_synchronous_stmt(ctx, this)

            },

            Statement::EndSynchronous(_stmt) => Ok(()),

            Statement::Return(stmt) => {

                let this = stmt.this;

                self.visit_return_stmt(ctx, this)

            },

            Statement::Goto(stmt) => {

                let this = stmt.this;

                self.visit_goto_stmt(ctx, this)

            },

            Statement::New(stmt) => {

                let this = stmt.this;

                self.visit_new_stmt(ctx, this)

            },

    }

    // --- enum variant handling

    fn visit_block_stmt(&mut self, _ctx: &mut Ctx, _id: BlockStatementId) -> VisitorResult { Ok(()) }

    fn visit_local_memory_stmt(&mut self, _ctx: &mut Ctx, _id: MemoryStatementId) -> VisitorResult { Ok(()) }

    fn visit_local_channel_stmt(&mut self, _ctx: &mut Ctx, _id: ChannelStatementId) -> VisitorResult { Ok(()) }

    fn visit_labeled_stmt(&mut self, _ctx: &mut Ctx, _id: LabeledStatementId) -> VisitorResult { Ok(()) }

    fn visit_if_stmt(&mut self, _ctx: &mut Ctx, _id: IfStatementId) -> VisitorResult { Ok(()) }

    fn visit_while_stmt(&mut self, _ctx: &mut Ctx, _id: WhileStatementId) -> VisitorResult { Ok(()) }

    fn visit_break_stmt(&mut self, _ctx: &mut Ctx, _id: BreakStatementId) -> VisitorResult { Ok(()) }

    fn visit_continue_stmt(&mut self, _ctx: &mut Ctx, _id: ContinueStatementId) -> VisitorResult { Ok(()) }

    fn visit_synchronous_stmt(&mut self, _ctx: &mut Ctx, _id: SynchronousStatementId) -> VisitorResult { Ok(()) }

    fn visit_return_stmt(&mut self, _ctx: &mut Ctx, _id: ReturnStatementId) -> VisitorResult { Ok(()) }

    fn visit_goto_stmt(&mut self, _ctx: &mut Ctx, _id: GotoStatementId) -> VisitorResult { Ok(()) }

    fn visit_new_stmt(&mut self, _ctx: &mut Ctx, _id: NewStatementId) -> VisitorResult { Ok(()) }

    fn visit_expr_stmt(&mut self, _ctx: &mut Ctx, _id: ExpressionStatementId) -> VisitorResult { Ok(()) }

    // Expressions

    // --- enum matching

    fn visit_expr(&mut self, ctx: &mut Ctx, id: ExpressionId) -> VisitorResult {

        match &ctx.heap[id] {

            Expression::Assignment(expr) => {

                let this = expr.this;

                self.visit_assignment_expr(ctx, this)