pub struct LabeledStatement {

    pub this: LabeledStatementId,

    // Phase 1: parser

    pub label: Identifier,

    pub body: StatementId,

    // 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 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 &heap[id] {

            Expression::Assignment(expr) => {

                self.serialize_expression(heap, expr.left);

                self.serialize_expression(heap, expr.right);

            },

            Expression::Binding(expr) => {

                self.serialize_expression(heap, expr.bound_to);

                self.serialize_expression(heap, expr.bound_from);

            },

            Expression::Conditional(expr) => {

                self.serialize_expression(heap, expr.test);

            },

            Expression::Binary(expr) => {

                self.serialize_expression(heap, expr.left);

                self.serialize_expression(heap, expr.right);

            },

            Expression::Unary(expr) => {

                self.serialize_expression(heap, expr.expression);

            },

            Expression::Indexing(expr) => {

                self.serialize_expression(heap, expr.index);

                self.serialize_expression(heap, expr.subject);

            },

            Expression::Slicing(expr) => {

                self.serialize_expression(heap, expr.from_index);

                self.serialize_expression(heap, expr.to_index);

                self.serialize_expression(heap, expr.subject);

            },

            Expression::Select(expr) => {

                self.serialize_expression(heap, expr.subject);

            },

            Expression::Literal(expr) => {

                // Here we only care about literals that have subexpressions

                match &expr.value {

                    Literal::Null | Literal::True | Literal::False |

                    Literal::Character(_) | Literal::String(_) |

                    Literal::Integer(_) | Literal::Enum(_) => {

                        // No subexpressions

                    },

                    Literal::Struct(literal) => {

                        // Note: fields expressions are evaluated in programmer-

                        // specified order. But struct construction expects them

                        // in type-defined order. I might want to come back to

                        // this.

                        let mut _num_pushed = 0;

                        for want_field_idx in 0..literal.fields.len() {

                            for field in &literal.fields {

                                if field.field_idx == want_field_idx {

                                    _num_pushed += 1;

                                    self.expr_stack.push_back(ExprInstruction::PushValToFront);

                                    self.serialize_expression(heap, field.value);

                                }

                            }

                        }

                        debug_assert_eq!(_num_pushed, literal.fields.len())

                    },

                    Literal::Union(literal) => {

                        for value_expr_id in &literal.values {

                            self.expr_stack.push_back(ExprInstruction::PushValToFront);

                            self.serialize_expression(heap, *value_expr_id);

                        }

                    },

                    Literal::Array(value_expr_ids) => {

                        for value_expr_id in value_expr_ids {

                            self.expr_stack.push_back(ExprInstruction::PushValToFront);

                            self.serialize_expression(heap, *value_expr_id);

                        }

                    }

                }

            },

            Expression::Cast(expr) => {

                self.serialize_expression(heap, expr.subject);

            }

            Expression::Call(expr) => {

                for arg_expr_id in &expr.arguments {

                    self.expr_stack.push_back(ExprInstruction::PushValToFront);

                    self.serialize_expression(heap, *arg_expr_id);

                }

            },

            Expression::Variable(_expr) => {

                // No subexpressions

            }

        }

    }

}

type EvalResult = Result<EvalContinuation, EvalError>;

pub enum EvalContinuation {

    Stepping,

    Inconsistent,

    Terminal,

    SyncBlockStart,

    SyncBlockEnd,

    NewComponent(DefinitionId, i32, ValueGroup),

    NewChannel,

    BlockFires(PortId),

    BlockGet(PortId),

    Put(PortId, Value),

}

// Note: cloning is fine, methinks. cloning all values and the heap regions then

// we end up with valid "pointers" to heap regions.

#[derive(Debug, Clone)]

pub struct Prompt {

    pub(crate) frames: Vec<Frame>,

    pub(crate) store: Store,

}

impl Prompt {

    pub fn new(_types: &TypeTable, heap: &Heap, def: DefinitionId, monomorph_idx: i32, args: ValueGroup) -> Self {

        let mut prompt = Self{

            frames: Vec::new(),

            store: Store::new(),

        };

        // Maybe do typechecking in the future?

        debug_assert!((monomorph_idx as usize) < _types.get_base_definition(&def).unwrap().definition.procedure_monomorphs().len());

        let new_frame = Frame::new(heap, def, monomorph_idx);

        let max_stack_size = new_frame.max_stack_size;

        prompt.frames.push(new_frame);

        args.into_store(&mut prompt.store);

        prompt.store.reserve_stack(max_stack_size);

        prompt

    }

    /// Big 'ol function right here. Didn't want to break it up unnecessarily.

    /// It consists of, in sequence: executing any expressions that should be

    /// executed before the next statement can be evaluated, then a section that

    /// performs debug printing, and finally a section that takes the next

    /// statement and executes it. If the statement requires any expressions to

    /// be evaluated, then they will be added such that the next time `step` is

    /// called, all of these expressions are indeed evaluated.

    pub(crate) fn step(&mut self, types: &TypeTable, heap: &Heap, modules: &[Module], ctx: &mut impl RunContext) -> EvalResult {

        // Helper function to transfer multiple values from the expression value

        // array into a heap region (e.g. constructing arrays or structs).

        fn transfer_expression_values_front_into_heap(cur_frame: &mut Frame, store: &mut Store, num_values: usize) -> HeapPos {

            let heap_pos = store.alloc_heap();

            // Do the transformation first (because Rust...)

            for val_idx in 0..num_values {

                cur_frame.expr_values[val_idx] = store.read_take_ownership(cur_frame.expr_values[val_idx].clone());

            }

            // And now transfer to the heap region

            let values = &mut store.heap_regions[heap_pos as usize].values;

            debug_assert!(values.is_empty());

            values.reserve(num_values);

            for _ in 0..num_values {

                values.push(cur_frame.expr_values.pop_front().unwrap());

            }

            heap_pos

        }

        // Helper function to make sure that an index into an aray is valid.

        fn array_inclusive_index_is_invalid(store: &Store, array_heap_pos: u32, idx: i64) -> bool {

            let array_len = store.heap_regions[array_heap_pos as usize].values.len();

            return idx < 0 || idx >= array_len as i64;

        }

        fn array_exclusive_index_is_invalid(store: &Store, array_heap_pos: u32, idx: i64) -> bool {

            let array_len = store.heap_regions[array_heap_pos as usize].values.len();

            return idx < 0 || idx > array_len as i64;

        }

        fn construct_array_error(prompt: &Prompt, modules: &[Module], heap: &Heap, expr_id: ExpressionId, heap_pos: u32, idx: i64) -> EvalError {

            let array_len = prompt.store.heap_regions[heap_pos as usize].values.len();

            return EvalError::new_error_at_expr(

                prompt, modules, heap, expr_id,

                format!("index {} is out of bounds: array length is {}", idx, array_len)

            )

        }

        // Checking if we're at the end of execution

        let cur_frame = self.frames.last_mut().unwrap();

        if cur_frame.position.is_invalid() {

            if heap[cur_frame.definition].is_function() {

                todo!("End of function without return, return an evaluation error");

            }

            return Ok(EvalContinuation::Terminal);

        }

        debug_log!("Taking step in '{}'", heap[cur_frame.definition].identifier().value.as_str());

        // Execute all pending expressions

        while !cur_frame.expr_stack.is_empty() {

            let next = cur_frame.expr_stack.pop_back().unwrap();

            debug_log!("Expr stack: {:?}", next);

            match next {

                ExprInstruction::PushValToFront => {

            },

            Statement::EndBlock(stmt) => {

                let block = &heap[stmt.start_block];

                self.store.clear_stack(block.first_unique_id_in_scope as usize);

                cur_frame.position = stmt.next;

                Ok(EvalContinuation::Stepping)

            },

            Statement::Local(stmt) => {

                match stmt {

                    LocalStatement::Memory(stmt) => {

                        let variable = &heap[stmt.variable];

                        self.store.write(ValueId::Stack(variable.unique_id_in_scope as u32), Value::Unassigned);

                        cur_frame.position = stmt.next;

                        Ok(EvalContinuation::Stepping)

                    },

                    LocalStatement::Channel(stmt) => {

                        // Need to create a new channel by requesting it from

                        // the runtime.

                        match ctx.get_channel() {

                            None => {

                                // No channel is pending. So request one

                                Ok(EvalContinuation::NewChannel)

                            },

                            Some((put_port, get_port)) => {

                                self.store.write(ValueId::Stack(heap[stmt.from].unique_id_in_scope as u32), put_port);

                                self.store.write(ValueId::Stack(heap[stmt.to].unique_id_in_scope as u32), get_port);

                                cur_frame.position = stmt.next;

                                Ok(EvalContinuation::Stepping)

                            }

                        }

                    }

                }

            },

            Statement::Labeled(stmt) => {

                cur_frame.position = stmt.body;

                Ok(EvalContinuation::Stepping)

            },

            Statement::If(stmt) => {

                debug_assert_eq!(cur_frame.expr_values.len(), 1, "expected one expr value for if statement");

                let test_value = cur_frame.expr_values.pop_back().unwrap();

                let test_value = self.store.maybe_read_ref(&test_value).as_bool();

                if test_value {

                    cur_frame.position = stmt.true_body.upcast();

                } else if let Some(false_body) = stmt.false_body {

                    cur_frame.position = false_body.upcast();

                } else {

                    // Not true, and no false body

                    cur_frame.position = stmt.end_if.upcast();

                }

                Ok(EvalContinuation::Stepping)

            },

            Statement::EndIf(stmt) => {

                cur_frame.position = stmt.next;

                Ok(EvalContinuation::Stepping)

            },

            Statement::While(stmt) => {

                debug_assert_eq!(cur_frame.expr_values.len(), 1, "expected one expr value for while statement");

                let test_value = cur_frame.expr_values.pop_back().unwrap();

                let test_value = self.store.maybe_read_ref(&test_value).as_bool();

                if test_value {

                    cur_frame.position = stmt.body.upcast();

                } else {

                    cur_frame.position = stmt.end_while.upcast();

                }

                Ok(EvalContinuation::Stepping)

            },

            Statement::EndWhile(stmt) => {

                cur_frame.position = stmt.next;

                Ok(EvalContinuation::Stepping)

            },

            Statement::Break(stmt) => {

                cur_frame.position = stmt.target.unwrap().upcast();

                Ok(EvalContinuation::Stepping)

            },

            Statement::Continue(stmt) => {

                cur_frame.position = stmt.target.unwrap().upcast();

                Ok(EvalContinuation::Stepping)

            },

            Statement::Synchronous(stmt) => {

                cur_frame.position = stmt.body.upcast();

                Ok(EvalContinuation::SyncBlockStart)

            },

            Statement::EndSynchronous(stmt) => {

                cur_frame.position = stmt.next;

                Ok(EvalContinuation::SyncBlockEnd)

            },

            Statement::Return(_stmt) => {

                debug_assert!(heap[cur_frame.definition].is_function());

                debug_assert_eq!(cur_frame.expr_values.len(), 1, "expected one expr value for return statement");

                // The preceding frame has executed a call, so is expecting the

                // return expression on its expression value stack. Note that

                // we may be returning a reference to something on our stack,

                // so we need to read that value and clone it.

                let return_value = cur_frame.expr_values.pop_back().unwrap();

                let return_value = match return_value {

                    Value::Ref(value_id) => self.store.read_copy(value_id),

                    _ => return_value,

                };

                // Pre-emptively pop our stack frame

                self.frames.pop();

                // Clean up our section of the stack

                self.store.clear_stack(0);

                self.store.stack.truncate(self.store.cur_stack_boundary + 1);

                let prev_stack_idx = self.store.stack.pop().unwrap().as_stack_boundary();

                // TODO: Temporary hack for testing, remove at some point

                if self.frames.is_empty() {

                    debug_assert!(prev_stack_idx == -1);

                    debug_assert!(self.store.stack.len() == 0);

                    self.store.stack.push(return_value);

                    return Ok(EvalContinuation::Terminal);

                }

                debug_assert!(prev_stack_idx >= 0);

                // Return to original state of stack frame

                self.store.cur_stack_boundary = prev_stack_idx as usize;

                let cur_frame = self.frames.last_mut().unwrap();

                cur_frame.expr_values.push_back(return_value);

                // We just returned to the previous frame, which might be in

                // the middle of evaluating expressions for a particular

                // statement. So we don't want to enter the code below.

                return Ok(EvalContinuation::Stepping);

            },

            Statement::Goto(stmt) => {

                cur_frame.position = stmt.target.unwrap().upcast();

                Ok(EvalContinuation::Stepping)

            },

            Statement::New(stmt) => {

                let call_expr = &heap[stmt.expression];

                debug_assert!(heap[call_expr.definition].is_component());

                debug_assert_eq!(

                    cur_frame.expr_values.len(), heap[call_expr.definition].parameters().len(),

                    "mismatch in expr stack size and number of arguments for new statement"

                );

                let mono_data = types.get_procedure_expression_data(&cur_frame.definition, cur_frame.monomorph_idx);

                let expr_data = &mono_data.expr_data[call_expr.unique_id_in_definition as usize];

                // Note that due to expression value evaluation they exist in

                // reverse order on the stack.

                // TODO: Revise this code, keep it as is to be compatible with current runtime

                let mut args = Vec::new();

                while let Some(value) = cur_frame.expr_values.pop_front() {

                    args.push(value);

                }

                // Construct argument group, thereby copying heap regions

                let argument_group = ValueGroup::from_store(&self.store, &args);

                // println!("Creating {} with\n{:#?}", heap[call_expr.definition].identifier().value.as_str(), argument_group);

                // Clear any heap regions

                for arg in &args {

                    self.store.drop_value(arg.get_heap_pos());

                }

                cur_frame.position = stmt.next;

                Ok(EvalContinuation::NewComponent(call_expr.definition, expr_data.field_or_monomorph_idx, argument_group))

            },

            Statement::Expression(stmt) => {

                // The expression has just been completely evaluated. Some

                // values might have remained on the expression value stack.

                // cur_frame.expr_values.clear(); PROPER CLEARING

                cur_frame.position = stmt.next;

                Ok(EvalContinuation::Stepping)

            },

        };

        assert!(

            cur_frame.expr_values.is_empty(),

            "This is a debugging assertion that will fail if you perform expressions without \

            assigning to anything. This should be completely valid, and this assertion should be \

            replaced by something that clears the expression values if needed, but I'll keep this \

            in for now for debugging purposes."

        );

        }

        // - check number of arguments

        let expr_data = self.types.get_procedure_expression_data(&definition_id, 0);

        if expr_data.arg_types.len() != arguments.values.len() {

            return Err(ComponentCreationError::InvalidNumArguments);

        }

        // - for each argument try to make sure the types match

        for arg_idx in 0..arguments.values.len() {

            let expected_type = &expr_data.arg_types[arg_idx];

            let provided_value = &arguments.values[arg_idx];

            if !self.verify_same_type(expected_type, 0, &arguments, provided_value) {

                return Err(ComponentCreationError::InvalidArgumentType(arg_idx));

            }

        }

        // By now we're sure that all of the arguments are correct. So create

        // the connector.

        return Ok(ComponentState{

            prompt: Prompt::new(&self.types, &self.heap, definition_id, 0, arguments),

        });

    }

    fn lookup_module_root(&self, module_name: &[u8]) -> Option<RootId> {

        for module in self.modules.iter() {

            match &module.name {

                Some(name) => if name.as_bytes() == module_name {

                    return Some(module.root_id);

                },

                None => if module_name.is_empty() {

                    return Some(module.root_id);

                }

            }

        }

        return None;

    }

    fn verify_same_type(&self, expected: &ConcreteType, expected_idx: usize, arguments: &ValueGroup, argument: &Value) -> bool {

        use ConcreteTypePart as CTP;

        match &expected.parts[expected_idx] {

            CTP::Void | CTP::Message | CTP::Slice | CTP::Function(_, _) | CTP::Component(_, _) => unreachable!(),

            CTP::Bool => if let Value::Bool(_) = argument { true } else { false },

            CTP::UInt8 => if let Value::UInt8(_) = argument { true } else { false },

            CTP::UInt16 => if let Value::UInt16(_) = argument { true } else { false },

            CTP::UInt32 => if let Value::UInt32(_) = argument { true } else { false },

            CTP::UInt64 => if let Value::UInt64(_) = argument { true } else { false },

            CTP::SInt8 => if let Value::SInt8(_) = argument { true } else { false },

            CTP::SInt16 => if let Value::SInt16(_) = argument { true } else { false },

            CTP::SInt32 => if let Value::SInt32(_) = argument { true } else { false },

            CTP::SInt64 => if let Value::SInt64(_) = argument { true } else { false },

            CTP::Character => if let Value::Char(_) = argument { true } else { false },

            CTP::String => {

                // Match outer string type and embedded character types

                if let Value::String(heap_pos) = argument {

                    for element in &arguments.regions[*heap_pos as usize] {

                        if let Value::Char(_) = element {} else {

                            return false;

                        }

                    }

                } else {

                    return false;

                }

                return true;

            },

            CTP::Array => {

                if let Value::Array(heap_pos) = argument {

                    let heap_pos = *heap_pos;

                    for element in &arguments.regions[heap_pos as usize] {

                        if !self.verify_same_type(expected, expected_idx + 1, arguments, element) {

                            return false;

                        }

                    }

                    return true;

                } else {

                    return false;

                }

            },

            CTP::Input => if let Value::Input(_) = argument { true } else { false },

            CTP::Output => if let Value::Output(_) = argument { true } else { false },

            CTP::Instance(_definition_id, _num_embedded) => {

                todo!("implement full type checking on user-supplied arguments");

                return false;

            },

        }

    }

}

// TODO: @temp Should just become a concrete thing that is passed in

pub trait RunContext {

    fn did_put(&mut self, port: PortId) -> bool;

    fn get(&mut self, port: PortId) -> Option<ValueGroup>; // None if still waiting on message

    fn fires(&mut self, port: PortId) -> Option<Value>; // None if not yet branched

    fn get_channel(&mut self) -> Option<(Value, Value)>; // None if not yet prepared

}

#[derive(Debug)]

pub enum RunResult {

    // Can only occur outside sync blocks

    ComponentTerminated, // component has exited its procedure

    ComponentAtSyncStart,

    NewComponent(DefinitionId, i32, ValueGroup), // should also be possible inside sync

    NewChannel, // should also be possible inside sync

    // Can only occur inside sync blocks

    BranchInconsistent, // branch has inconsistent behaviour

    BranchMissingPortState(PortId), // branch doesn't know about port firing

    BranchMissingPortValue(PortId), // branch hasn't received message on input port yet

    BranchAtSyncEnd,

    BranchPut(PortId, ValueGroup),

}

impl ComponentState {

    pub(crate) fn run(&mut self, ctx: &mut impl RunContext, pd: &ProtocolDescription) -> RunResult {

        use EvalContinuation as EC;

        use RunResult as RR;

        loop {

            let step_result = self.prompt.step(&pd.types, &pd.heap, &pd.modules, ctx);

            match step_result {

                Err(reason) => {

                    // TODO: @temp

                    println!("Evaluation error:\n{}", reason);

                    todo!("proper error handling/bubbling up");

                },

                Ok(continuation) => match continuation {

                    // TODO: Probably want to remove this translation

                    EC::Stepping => continue,

                    EC::Inconsistent => return RR::BranchInconsistent,

                    EC::Terminal => return RR::ComponentTerminated,

                    EC::SyncBlockStart => return RR::ComponentAtSyncStart,

                    EC::SyncBlockEnd => return RR::BranchAtSyncEnd,

                    EC::NewComponent(definition_id, monomorph_idx, args) =>

                        return RR::NewComponent(definition_id, monomorph_idx, args),

                    EC::NewChannel =>

                        return RR::NewChannel,

                    EC::BlockFires(port_id) => return RR::BranchMissingPortState(port_id),

                    EC::BlockGet(port_id) => return RR::BranchMissingPortValue(port_id),

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

                        let value_group = ValueGroup::from_store(&self.prompt.store, &[value]);

                        return RR::BranchPut(port_id, value_group);

                    },

                }

            }

        }

    }

}

// TODO: @remove the old stuff

impl ComponentState {

    pub(crate) fn nonsync_run<'a: 'b, 'b>(

        &'a mut self,

        context: &'b mut NonsyncProtoContext<'b>,

        pd: &'a ProtocolDescription,

    ) -> NonsyncBlocker {

        let mut context = EvalContext::Nonsync(context);

        loop {

            let result = self.prompt.step(&pd.types, &pd.heap, &pd.modules, &mut context);

            match result {

                Err(err) => {

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

                    panic!("proper error handling when component fails");

                },

                Ok(cont) => match cont {

                    EvalContinuation::Stepping => continue,

                    EvalContinuation::Inconsistent => return NonsyncBlocker::Inconsistent,

                    EvalContinuation::Terminal => return NonsyncBlocker::ComponentExit,

                    EvalContinuation::SyncBlockStart => return NonsyncBlocker::SyncBlockStart,

                    // Not possible to end sync block if never entered one

                    EvalContinuation::SyncBlockEnd => unreachable!(),

                    EvalContinuation::NewComponent(definition_id, monomorph_idx, args) => {

                        // Look up definition (TODO for now, assume it is a definition)

                        let mut moved_ports = HashSet::new();

                        for arg in args.values.iter() {

                            match arg {

                                Value::Output(port) => {

                                    moved_ports.insert(*port);

                                }

                                Value::Input(port) => {

                                    moved_ports.insert(*port);

                                }

                                _ => {}

                            }

                        }

                        for region in args.regions.iter() {

                            for arg in region {

                                match arg {

                                    Value::Output(port) => { moved_ports.insert(*port); },

                                    Value::Input(port) => { moved_ports.insert(*port); },

                                    _ => {},

                                }

                            }

                        }

                        let init_state = ComponentState { prompt: Prompt::new(&pd.types, &pd.heap, definition_id, monomorph_idx, args) };

                        context.new_component(moved_ports, init_state);

                        // Continue stepping

                        continue;

                    },

                    EvalContinuation::NewChannel => {

                        // Because of the way we emulate the old context for now, we can safely

                        // assume that this will never happen. The old context thingamajig always

                        // creates a channel, it never bubbles a "need to create a channel" message

                        // to the runtime

                        unreachable!();

                    },

                    // Outside synchronous blocks, no fires/get/put happens

                    EvalContinuation::BlockFires(_) => unreachable!(),

                    EvalContinuation::BlockGet(_) => unreachable!(),

                    EvalContinuation::Put(_, _) => unreachable!(),

                },

            }

        }

    }

    pub(crate) fn sync_run<'a: 'b, 'b>(

        &'a mut self,

        context: &'b mut SyncProtoContext<'b>,

        pd: &'a ProtocolDescription,

    ) -> SyncBlocker {

        let mut context = EvalContext::Sync(context);

        loop {

            let result = self.prompt.step(&pd.types, &pd.heap, &pd.modules, &mut context);

            match result {

                Err(err) => {

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

                    panic!("proper error handling when component fails");

                },

                Ok(cont) => match cont {

                    EvalContinuation::Stepping => continue,

                    EvalContinuation::Inconsistent => return SyncBlocker::Inconsistent,

                    // First need to exit synchronous block before definition may end

                    EvalContinuation::Terminal => unreachable!(),

                    // No nested synchronous blocks

                    EvalContinuation::SyncBlockStart => unreachable!(),

                    EvalContinuation::SyncBlockEnd => return SyncBlocker::SyncBlockEnd,

                    // Not possible to create component in sync block

                    EvalContinuation::NewComponent(_, _, _) => unreachable!(),

                    EvalContinuation::NewChannel => unreachable!(),

                    EvalContinuation::BlockFires(port) => {

                        return SyncBlocker::CouldntCheckFiring(port);

                    },

                    EvalContinuation::BlockGet(port) => {

                        return SyncBlocker::CouldntReadMsg(port);

                    },

                    EvalContinuation::Put(port, message) => {

                        let payload;

                        match message {

                            Value::Null => {

                                return SyncBlocker::Inconsistent;

                            },

                            Value::Message(heap_pos) => {

                                // Create a copy of the payload