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

                    self.write_stmt(heap, right_body_id, indent3);

                }

            },

            Statement::EndFork(stmt) => {

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

                    .with_s_key("EndFork");

                self.kv(indent2).with_s_key("StartFork").with_disp_val(&stmt.start_fork.0.index);

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

            },

            Statement::Select(stmt) => {

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

                    .with_s_key("Select");

                self.kv(indent2).with_s_key("EndSelect").with_disp_val(&stmt.end_select.0.index);

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

                let indent3 = indent2 + 1;

                let indent4 = indent3 + 1;

                for case in &stmt.cases {

                    self.kv(indent3).with_s_key("Guard");

                    self.write_stmt(heap, case.guard, indent4);

                    self.kv(indent3).with_s_key("Block");

                    self.write_stmt(heap, case.body, indent4);

                }

            },

            Statement::EndSelect(stmt) => {

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

                    .with_s_key("EndSelect");

                self.kv(indent2).with_s_key("StartSelect").with_disp_val(&stmt.start_select.0.index);

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

            }

            Statement::Return(stmt) => {

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

                    .with_s_key("Return");

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

                for expr_id in &stmt.expressions {

                    self.write_expr(heap, *expr_id, indent3);

                }

            },

            Statement::Goto(stmt) => {

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

                    .with_s_key("Goto");

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

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

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

            },

            Statement::New(stmt) => {

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

                            self.write_expr(heap, *expr_id, indent4);

                        }

                    }

                }

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

                    .with_custom_val(|v| write_expression_parent(v, &expr.parent));

            },

            Expression::Cast(expr) => {

                self.kv(indent).with_id(PREFIX_CAST_EXPR_ID, expr.this.0.index)

                    .with_s_key("CallExpr");

                self.kv(indent2).with_s_key("TypeIndex").with_disp_val(&expr.type_index);

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

                    .with_custom_val(|t| write_parser_type(t, heap, &expr.to_type));

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

                self.write_expr(heap, expr.subject, indent3);

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

                    .with_custom_val(|v| write_expression_parent(v, &expr.parent));

            }

            Expression::Call(expr) => {

                self.kv(indent).with_id(PREFIX_CALL_EXPR_ID, expr.this.0.index)

                    .with_s_key("CallExpr");

                self.kv(indent2).with_s_key("TypeIndex").with_disp_val(&expr.type_index);

                // Arguments

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

                for arg_id in &expr.arguments {

                    self.write_expr(heap, *arg_id, indent3);

                }

                // Parent

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

                    .with_custom_val(|v| write_expression_parent(v, &expr.parent));

            },

            Expression::Variable(expr) => {

                self.kv(indent).with_id(PREFIX_VARIABLE_EXPR_ID, expr.this.0.index)

                    .with_s_key("VariableExpr");

                self.kv(indent2).with_s_key("TypeIndex").with_disp_val(&expr.type_index);

                self.kv(indent2).with_s_key("Name").with_identifier_val(&expr.identifier);

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

                    .with_opt_disp_val(expr.declaration.as_ref().map(|v| &v.index));

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

                    .with_custom_val(|v| write_expression_parent(v, &expr.parent));

            }

        }

    }

    // Printing Utilities

    //--------------------------------------------------------------------------

    fn kv(&mut self, indent: usize) -> KV {

        KV::new(&mut self.buffer, &mut self.temp1, &mut self.temp2, indent)

    }

    fn flush<W: IOWrite>(&mut self, w: &mut W) {

        w.write(self.buffer.as_bytes()).unwrap();

        self.buffer.clear()

    }

}

fn write_option<V: Display>(target: &mut String, value: Option<V>) {

    target.clear();

    match &value {

        Some(v) => target.push_str(&format!("Some({})", v)),

        None => target.push_str("None")

    };

}

fn write_parser_type(target: &mut String, heap: &Heap, t: &ParserType) {

    use ParserTypeVariant as PTV;

    fn write_element(target: &mut String, heap: &Heap, t: &ParserType, mut element_idx: usize) -> usize {

        let element = &t.elements[element_idx];

        match &element.variant {

            PTV::Void => target.push_str("void"),

            PTV::InputOrOutput => {

                target.push_str("portlike<");

                element_idx = write_element(target, heap, t, element_idx + 1);

                target.push('>');

            },

            PTV::ArrayLike => {

                element_idx = write_element(target, heap, t, element_idx + 1);

                target.push_str("[???]");

            },

            PTV::IntegerLike => target.push_str("integerlike"),

            PTV::Message => { target.push_str(KW_TYPE_MESSAGE_STR); },

            PTV::Bool => { target.push_str(KW_TYPE_BOOL_STR); },

            PTV::UInt8 => { target.push_str(KW_TYPE_UINT8_STR); },

            PTV::UInt16 => { target.push_str(KW_TYPE_UINT16_STR); },

            PTV::UInt32 => { target.push_str(KW_TYPE_UINT32_STR); },

            PTV::UInt64 => { target.push_str(KW_TYPE_UINT64_STR); },

            PTV::SInt8 => { target.push_str(KW_TYPE_SINT8_STR); },

            PTV::SInt16 => { target.push_str(KW_TYPE_SINT16_STR); },

            PTV::SInt32 => { target.push_str(KW_TYPE_SINT32_STR); },

            PTV::SInt64 => { target.push_str(KW_TYPE_SINT64_STR); },

use std::collections::VecDeque;

use super::value::*;

use super::store::*;

use super::error::*;

use crate::protocol::*;

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

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

macro_rules! debug_log {

    ($format:literal) => {

    };

    ($format:literal, $($args:expr),*) => {

    };

}

#[derive(Debug, Clone)]

pub(crate) enum ExprInstruction {

    EvalExpr(ExpressionId),

    PushValToFront,

}

#[derive(Debug, Clone)]

pub(crate) struct Frame {

    pub(crate) definition: ProcedureDefinitionId,

    pub(crate) monomorph_type_id: TypeId,

    pub(crate) monomorph_index: usize,

    pub(crate) position: StatementId,

    pub(crate) expr_stack: VecDeque<ExprInstruction>, // hack for expression evaluation, evaluated by popping from back

    pub(crate) expr_values: VecDeque<Value>, // hack for expression results, evaluated by popping from front/back

    pub(crate) max_stack_size: u32,

}

impl Frame {

    /// Creates a new execution frame. Does not modify the stack in any way.

    pub fn new(heap: &Heap, definition_id: ProcedureDefinitionId, monomorph_type_id: TypeId, monomorph_index: u32) -> Self {

        let definition = &heap[definition_id];

    pub(crate) types: TypeTable,

    pub(crate) pool: Mutex<StringPool>,

}

#[derive(Debug, Clone)]

pub(crate) struct ComponentState {

    pub(crate) prompt: Prompt,

}

#[derive(Debug)]

pub enum ComponentCreationError {

    ModuleDoesntExist,

    DefinitionDoesntExist,

    DefinitionNotComponent,

    InvalidNumArguments,

    InvalidArgumentType(usize),

    UnownedPort,

    InSync,

}

impl ProtocolDescription {

    pub fn parse(buffer: &[u8]) -> Result<Self, String> {

        let source = InputSource::new(String::new(), Vec::from(buffer));

        let mut parser = Parser::new();

        parser.feed(source).expect("failed to feed source");

        if let Err(err) = parser.parse() {

            println!("ERROR:\n{}", err);

            return Err(format!("{}", err))

        }

        debug_assert_eq!(parser.modules.len(), 1, "only supporting one module here for now");

        let modules: Vec<Module> = parser.modules.into_iter()

            .map(|module| Module{

                source: module.source,

                root_id: module.root_id,

                name: module.name.map(|(_, name)| name)

            })

            .collect();

        return Ok(ProtocolDescription {

            modules,

            heap: parser.heap,

            types: parser.type_table,

            pool: Mutex::new(parser.string_pool),

        });

    }

    pub(crate) fn new_component(

        &self, module_name: &[u8], identifier: &[u8], arguments: ValueGroup

                let false_case_scope_id = ctx.heap.alloc_scope(|this| Scope::new(this, ScopeAssociation::If(last_if_stmt_id, false)));

                link_existing_child_to_new_parent_scope(ctx, &mut self.scope_buffer, false_case_scope_id, scope_id, 0);

                link_new_child_to_existing_parent_scope(ctx, &mut self.scope_buffer, last_parent_scope_id, false_case_scope_id, last_relative_pos);

                set_ast_if_statement_false_body(ctx, last_if_stmt_id, last_end_if_stmt_id, IfStatementCase{ body: if_stmt_id.upcast(), scope: false_case_scope_id });

                let end_if_stmt = &mut ctx.heap[end_if_stmt_id];

                end_if_stmt.next = last_end_if_stmt_id.upcast();

                last_if_stmt_id = if_stmt_id;

                last_end_if_stmt_id = end_if_stmt_id;

                last_parent_scope_id = false_case_scope_id;

                last_relative_pos = 0;

            }

        }

        // Final steps: set the statements of the replacement block statement,

        // link all of those statements together, and update the scopes.

        let first_stmt_id = transformed_stmts[0];

        let mut last_stmt_id = transformed_stmts[0];

        for stmt_id in transformed_stmts.iter().skip(1).copied() {

            set_ast_statement_next(ctx, last_stmt_id, stmt_id);

            last_stmt_id = stmt_id;

        }

        let outer_block_stmt = &mut ctx.heap[outer_block_id];

        outer_block_stmt.next = first_stmt_id;

        outer_block_stmt.statements = transformed_stmts;

        return Ok(())

    }

}

// -----------------------------------------------------------------------------

// Utilities to create compiler-generated AST nodes

// -----------------------------------------------------------------------------

#[derive(Clone, Copy)]

enum TypeIdReference {

    DirectTypeId(TypeId),

    IndirectSameAsExpr(i32), // by type index

}

fn create_ast_variable(ctx: &mut Ctx, scope_id: ScopeId) -> VariableId {

    let variable_id = ctx.heap.alloc_variable(|this| Variable{

        this,

        kind: VariableKind::Local,

        parser_type: ParserType{

            elements: Vec::new(),

                    self.mode_port = port_id;

                    return Ok(CompScheduling::Sleep);

                }

            },

            EC::Put(port_id, value) => {

                debug_assert_eq!(self.mode, Mode::Sync);

                sched_ctx.log(&format!("Putting value {:?}", value));

                let port_id = port_id_from_eval(port_id);

                let port_handle = comp_ctx.get_port_handle(port_id);

                let port_info = comp_ctx.get_port(port_handle);

                if port_info.state.is_blocked() {

                    self.mode = Mode::BlockedPut;

                    self.mode_port = port_id;

                    self.mode_value = value;

                    self.exec_ctx.stmt = ExecStmt::PerformedPut; // prepare for when we become unblocked

                    return Ok(CompScheduling::Sleep);

                } else {

                    self.send_data_message_and_wake_up(sched_ctx, comp_ctx, port_handle, value);

                    self.exec_ctx.stmt = ExecStmt::PerformedPut;

                    return Ok(CompScheduling::Immediate);

                }

            },

            EC::SelectStart(num_cases, _num_ports) => {

                debug_assert_eq!(self.mode, Mode::Sync);

                self.select.handle_select_start(num_cases);

                return Ok(CompScheduling::Requeue);

            },

            EC::SelectRegisterPort(case_index, port_index, port_id) => {

                debug_assert_eq!(self.mode, Mode::Sync);

                let port_id = port_id_from_eval(port_id);

                if let Err(_err) = self.select.register_select_case_port(comp_ctx, case_index, port_index, port_id) {

                    todo!("handle registering a port multiple times");

                }

                return Ok(CompScheduling::Immediate);

            },

            EC::SelectWait => {

                debug_assert_eq!(self.mode, Mode::Sync);

                let select_decision = self.select.handle_select_waiting_point(&self.inbox_main, comp_ctx);

                if let SelectDecision::Case(case_index) = select_decision {

                    // Reached a conclusion, so we can continue immediately

                    self.exec_ctx.stmt = ExecStmt::PerformedSelectWait(case_index);

                    self.mode = Mode::Sync;

                    return Ok(CompScheduling::Immediate);

                } else {

                    // No decision yet

                    self.mode = Mode::BlockedSelect;

                    return Ok(CompScheduling::Sleep);

                }

            },

            // Results that can be returned outside of sync mode

            EC::ComponentTerminated => {

                self.mode = Mode::StartExit; // next call we'll take care of the exit

                return Ok(CompScheduling::Immediate);

            },

            EC::SyncBlockStart => {

                debug_assert_eq!(self.mode, Mode::NonSync);

                self.handle_sync_start(sched_ctx, comp_ctx);

                return Ok(CompScheduling::Immediate);

            },

            EC::NewComponent(definition_id, type_id, arguments) => {

                debug_assert_eq!(self.mode, Mode::NonSync);

    primitive sender(out<u32> tx, u32 num_sends) {

        auto index = 0;

        while (index < num_sends) {

            sync {

                put(tx, index);

                index += 1;

            }

        }

    }

    composite constructor() {

        auto num_sends = 15;

        channel tx_a -> rx_a;

        channel tx_b -> rx_b;

        new sender(tx_a, num_sends);

        new receiver(rx_a, rx_b, num_sends);

        new sender(tx_b, num_sends);

    }

    ").expect("compilation");

    let rt = Runtime::new(3, false, pd);

    create_component(&rt, "", "constructor", no_args());

}

#[test]

    let pd = ProtocolDescription::parse(b"

        u32 index = 0;

        while (index < 5) {

            sync select { auto v = () -> print(\"hello\"); }

            index += 1;

        }

    }

    ").expect("compilation");

    let rt = Runtime::new(3, false, pd);

}

#[test]

    let pd = ProtocolDescription::parse(b"

    primitive constructor() {

        u32 index = 0;

        while (index < 5) {

        }

    }

    ").expect("compilation");

    let rt = Runtime::new(3, false, pd);

    create_component(&rt, "", "constructor", no_args());

}