use crate::random::Random;

use crate::protocol::*;

use crate::protocol::ast::ProcedureDefinitionId;

use crate::protocol::eval::{

    PortId as EvalPortId, Prompt,

    ValueGroup, Value,

    EvalContinuation, EvalResult, EvalError

};

use crate::runtime2::runtime::CompId;

use crate::runtime2::scheduler::SchedulerCtx;

use crate::runtime2::communication::*;

use super::component::{

    self,

    InboxMain, InboxBackup, GetResult,

    CompExecState, Component, CompScheduling, CompError, CompMode, ExitReason,

    port_id_from_eval, port_id_to_eval

};

use super::component_context::*;

use super::control_layer::*;

use super::consensus::Consensus;

pub enum ExecStmt {

    CreatedChannel((Value, Value)),

    PerformedPut,

    PerformedGet(ValueGroup),

    PerformedSelectWait(u32),

    None,

}

impl ExecStmt {

    fn take(&mut self) -> ExecStmt {

        let mut value = ExecStmt::None;

        std::mem::swap(self, &mut value);

        return value;

    }

    fn is_none(&self) -> bool {

        match self {

            ExecStmt::None => return true,

            _ => return false,

        }

    }

}

pub struct ExecCtx {

    stmt: ExecStmt,

}

impl RunContext for ExecCtx {

    fn performed_put(&mut self, _port: EvalPortId) -> bool {

        match self.stmt.take() {

            ExecStmt::None => return false,

            ExecStmt::PerformedPut => return true,

            _ => unreachable!(),

        }

    }

    fn performed_get(&mut self, _port: EvalPortId) -> Option<ValueGroup> {

        match self.stmt.take() {

            ExecStmt::None => return None,

            ExecStmt::PerformedGet(value) => return Some(value),

            _ => unreachable!(),

        }

    }

    fn fires(&mut self, _port: EvalPortId) -> Option<Value> {

        todo!("remove fires")

    }

    fn performed_fork(&mut self) -> Option<bool> {

        todo!("remove fork")

    }

    fn created_channel(&mut self) -> Option<(Value, Value)> {

        match self.stmt.take() {

            ExecStmt::None => return None,

            ExecStmt::CreatedChannel(ports) => return Some(ports),

            _ => unreachable!(),

        }

    }

    fn performed_select_wait(&mut self) -> Option<u32> {

        match self.stmt.take() {

            ExecStmt::None => return None,

            ExecStmt::PerformedSelectWait(selected_case) => Some(selected_case),

            _v => unreachable!(),

        }

    }

}

struct SelectCase {

    involved_ports: Vec<LocalPortHandle>,

}

// TODO: @Optimize, flatten cases into single array, have index-pointers to next case

struct SelectState {

    cases: Vec<SelectCase>,

    next_case: u32,

    num_cases: u32,

    random: Random,

    candidates_workspace: Vec<usize>,

}

enum SelectDecision {

    None,

    Case(u32), // contains case index, should be passed along to PDL code

}

impl SelectState {

    fn new() -> Self {

        return Self{

            cases: Vec::new(),

            next_case: 0,

            num_cases: 0,

            random: Random::new(),

            candidates_workspace: Vec::new(),

        }

    }

    fn handle_select_start(&mut self, num_cases: u32) {

        self.cases.clear();

        self.next_case = 0;

        self.num_cases = num_cases;

    }

    /// Register a port as belonging to a particular case. As for correctness of

    /// PDL code one cannot register the same port twice, this function might

    /// return an error

    fn register_select_case_port(&mut self, comp_ctx: &CompCtx, case_index: u32, _port_index: u32, port_id: PortId) -> Result<(), PortId> {

        // Retrieve case and port handle

        self.ensure_at_case(case_index);

        let cur_case = &mut self.cases[case_index as usize];

        let port_handle = comp_ctx.get_port_handle(port_id);

        debug_assert_eq!(cur_case.involved_ports.len(), _port_index as usize);

        // Make sure port wasn't added before, we disallow having the same port

        // in the same select guard twice.

        if cur_case.involved_ports.contains(&port_handle) {

            return Err(port_id);

        }

        cur_case.involved_ports.push(port_handle);

        return Ok(());

    }

    /// Notification that all ports have been registered and we should now wait

    /// until the appropriate messages have come in.

    fn handle_select_waiting_point(&mut self, inbox: &InboxMain, comp_ctx: &CompCtx) -> SelectDecision {

        if self.num_cases != self.next_case {

            // This happens when there are >=1 select cases written at the end

            // of the select block.

            self.ensure_at_case(self.num_cases - 1);

        }

        return self.has_decision(inbox, comp_ctx);

    }

    fn handle_updated_inbox(&mut self, inbox: &InboxMain, comp_ctx: &CompCtx) -> SelectDecision {

        return self.has_decision(inbox, comp_ctx);

    }

    /// Internal helper, pushes empty cases inbetween last case and provided new

    /// case index.

    fn ensure_at_case(&mut self, new_case_index: u32) {

        // Push an empty case for all intermediate cases that were not

        // registered with a port.

        debug_assert!(new_case_index >= self.next_case && new_case_index < self.num_cases);

        for _ in self.next_case..new_case_index + 1 {

            self.cases.push(SelectCase{ involved_ports: Vec::new() });

        }

        self.next_case = new_case_index + 1;

    }

    /// Checks if a decision can be reached

    fn has_decision(&mut self, inbox: &InboxMain, comp_ctx: &CompCtx) -> SelectDecision {

        self.candidates_workspace.clear();

        if self.cases.is_empty() {

            // If there are no cases then we can immediately reach a "bogus

            // decision".

            return SelectDecision::Case(0);

        }

        // Need to check for valid case

        'case_loop: for (case_index, case) in self.cases.iter().enumerate() {

            for port_handle in case.involved_ports.iter().copied() {

                let port_index = comp_ctx.get_port_index(port_handle);

                if inbox[port_index].is_none() {

                    // Condition not satisfied

                    continue 'case_loop;

                }

            }

            // If here then the case guard is satisfied

            self.candidates_workspace.push(case_index);

        }

        if self.candidates_workspace.is_empty() {

            return SelectDecision::None;

        } else {

            let candidate_index = self.random.get_u64() as usize % self.candidates_workspace.len();

            return SelectDecision::Case(self.candidates_workspace[candidate_index] as u32);

        }

    }

}

pub(crate) struct CompPDL {

    pub exec_state: CompExecState,

    select_state: SelectState,

    pub prompt: Prompt,

    pub control: ControlLayer,

    pub consensus: Consensus,

    pub sync_counter: u32,

    pub exec_ctx: ExecCtx,

    // TODO: Temporary field, simulates future plans of having one storage place

    //  reserved per port.

    // Should be same length as the number of ports. Corresponding indices imply

    // message is intended for that port.

    pub inbox_main: InboxMain,

    pub inbox_backup: Vec<DataMessage>,

}

impl Component for CompPDL {

    fn on_creation(&mut self, _id: CompId, _sched_ctx: &SchedulerCtx) {

        // Intentionally empty

    }

    fn on_shutdown(&mut self, _sched_ctx: &SchedulerCtx) {

        // Intentionally empty

    }

    fn adopt_message(&mut self, comp_ctx: &mut CompCtx, message: DataMessage) {

        let port_handle = comp_ctx.get_port_handle(message.data_header.target_port);

        let port_index = comp_ctx.get_port_index(port_handle);

        if self.inbox_main[port_index].is_none() {

            self.inbox_main[port_index] = Some(message);

        } else {

            self.inbox_backup.push(message);

        }

    }

    fn handle_message(&mut self, sched_ctx: &mut SchedulerCtx, comp_ctx: &mut CompCtx, mut message: Message) {

        // sched_ctx.log(&format!("handling message: {:?}", message));

        if let Some(new_target) = self.control.should_reroute(&mut message) {

            let mut target = sched_ctx.runtime.get_component_public(new_target); // TODO: @NoDirectHandle

            target.send_message(&sched_ctx.runtime, message, false); // not waking up: we schedule once we've received all PortPeerChanged Acks

            let _should_remove = target.decrement_users();

            debug_assert!(_should_remove.is_none());

            return;

        }

        match message {

            Message::Data(message) => {

                self.handle_incoming_data_message(sched_ctx, comp_ctx, message);

            },

            Message::Control(message) => {

                if let Err(location_and_message) = component::default_handle_control_message(

                    &mut self.exec_state, &mut self.control, &mut self.consensus,

                    message, sched_ctx, comp_ctx

                ) {

                    self.handle_generic_component_error(sched_ctx, location_and_message);

                }

            },

            Message::Sync(message) => {

                self.handle_incoming_sync_message(sched_ctx, comp_ctx, message);

            },

            Message::Poll => {

                unreachable!(); // because we never register at the polling thread

            }

        }

    }

    fn run(&mut self, sched_ctx: &mut SchedulerCtx, comp_ctx: &mut CompCtx) -> CompScheduling {

        use EvalContinuation as EC;

        sched_ctx.log(&format!("Running component (mode: {:?})", self.exec_state.mode));

        // Depending on the mode don't do anything at all, take some special

        // actions, or fall through and run the PDL code.

        match self.exec_state.mode {

            CompMode::NonSync | CompMode::Sync => {

                // continue and run PDL code

            },

            CompMode::SyncEnd | CompMode::BlockedGet | CompMode::BlockedPut | CompMode::BlockedSelect => {

                return CompScheduling::Sleep;

            }

            CompMode::StartExit => return component::default_handle_start_exit(

                &mut self.exec_state, &mut self.control, sched_ctx, comp_ctx, &mut self.consensus

            ),

            CompMode::BusyExit => return component::default_handle_busy_exit(

                &mut self.exec_state, &self.control, sched_ctx

            ),

            CompMode::Exit => return component::default_handle_exit(&self.exec_state),

        }

        let run_result = self.execute_prompt(&sched_ctx);

        if let Err(error) = run_result {

            self.handle_component_error(sched_ctx, CompError::Executor(error));

            return CompScheduling::Immediate;

        }

        let run_result = run_result.unwrap();

        match run_result {

            EC::Stepping => unreachable!(), // execute_prompt runs until this is no longer returned

            EC::BranchInconsistent | EC::NewFork | EC::BlockFires(_) => todo!("remove these"),

            // Results that can be returned in sync mode

            EC::SyncBlockEnd => {

                component::default_handle_sync_end(&mut self.exec_state, sched_ctx, comp_ctx, &mut self.consensus);

                return CompScheduling::Immediate;

            },

            EC::BlockGet(expr_id, port_id) => {

                debug_assert_eq!(self.exec_state.mode, CompMode::Sync);

                debug_assert!(self.exec_ctx.stmt.is_none());

                let port_id = port_id_from_eval(port_id);

                match component::default_attempt_get(

                    &mut self.exec_state, port_id, PortInstruction::SourceLocation(expr_id),

                    &mut self.inbox_main, &mut self.inbox_backup, sched_ctx, comp_ctx,

                    &mut self.control, &mut self.consensus

                ) {

                    GetResult::Received(message) => {

                        self.exec_ctx.stmt = ExecStmt::PerformedGet(message.content);

                        return CompScheduling::Immediate;

                    },

                    GetResult::NoMessage => {

                        return CompScheduling::Sleep;

                    },

                    GetResult::Error(location_and_message) => {

                        self.handle_generic_component_error(sched_ctx, location_and_message);

                        return CompScheduling::Immediate;

                    }

                }

            },

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

                debug_assert_eq!(self.exec_state.mode, CompMode::Sync);

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

                // Send the message

                let target_port_id = port_id_from_eval(port_id);

                let send_result = component::default_send_data_message(

                    &mut self.exec_state, target_port_id,

                    PortInstruction::SourceLocation(expr_id), value,

                    sched_ctx, &mut self.consensus, comp_ctx

                );

                if let Err(location_and_message) = send_result {

                    self.handle_generic_component_error(sched_ctx, location_and_message);

                    return CompScheduling::Immediate;

                } else {

                    // When `run` is called again (potentially after becoming

                    // unblocked) we need to instruct the executor that we performed

                    // the `put`

                    let scheduling = send_result.unwrap();

                    self.exec_ctx.stmt = ExecStmt::PerformedPut;

                    return scheduling;

                }

            },

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

                debug_assert_eq!(self.exec_state.mode, CompMode::Sync);

                self.select_state.handle_select_start(num_cases);

                return CompScheduling::Requeue;

            },

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

                debug_assert_eq!(self.exec_state.mode, CompMode::Sync);

                let port_id = port_id_from_eval(port_id);

                let port_handle = comp_ctx.get_port_handle(port_id);

                // Note: we register the "last_instruction" here already. This

                // way if we get a `ClosePort` message, the condition to fail

                // the synchronous round is satisfied.

                let port_info = comp_ctx.get_port_mut(port_handle);

                port_info.last_instruction = PortInstruction::SourceLocation(expr_id);

                let port_is_closed = port_info.state == PortState::Closed;

                // Register port as part of select guard

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

                    // Failure occurs if a port is used twice in the same guard

                    let protocol = &sched_ctx.runtime.protocol;

                    self.handle_component_error(sched_ctx, CompError::Executor(EvalError::new_error_at_expr(

                        &self.prompt, &protocol.modules, &protocol.heap, expr_id,

                        String::from("Cannot have the one port appear in the same guard twice")

                    )));

                } else if port_is_closed {

                    // Port is closed

                    let peer_id = comp_ctx.get_port(port_handle).peer_comp_id;

                    let protocol = &sched_ctx.runtime.protocol;

                    self.handle_component_error(sched_ctx, CompError::Executor(EvalError::new_error_at_expr(

                        &self.prompt, &protocol.modules, &protocol.heap, expr_id,

                        format!("Cannot register port, as the peer component (id:{}) has shut down", peer_id.0)

                    )));

                }

                return CompScheduling::Immediate;

            },

            EC::SelectWait => {

                debug_assert_eq!(self.exec_state.mode, CompMode::Sync);

                let select_decision = self.select_state.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.exec_state.mode = CompMode::Sync;

                    return CompScheduling::Immediate;

                } else {

                    // No decision yet

                    self.exec_state.mode = CompMode::BlockedSelect;

                    return CompScheduling::Sleep;

                }

            },

            // Results that can be returned outside of sync mode

            EC::ComponentTerminated => {

                self.exec_state.set_as_start_exit(ExitReason::Termination);

                return CompScheduling::Immediate;

            },

            EC::SyncBlockStart => {

                component::default_handle_sync_start(

                    &mut self.exec_state, &mut self.inbox_main, sched_ctx, comp_ctx, &mut self.consensus

                );

                return CompScheduling::Immediate;

            },

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

                debug_assert_eq!(self.exec_state.mode, CompMode::NonSync);

                self.create_component_and_transfer_ports(

                    sched_ctx, comp_ctx,

                    definition_id, type_id, arguments

                );

                return CompScheduling::Requeue;

            },

            EC::NewChannel => {

                debug_assert_eq!(self.exec_state.mode, CompMode::NonSync);

                debug_assert!(self.exec_ctx.stmt.is_none());

                let channel = comp_ctx.create_channel();

                self.exec_ctx.stmt = ExecStmt::CreatedChannel((

                    Value::Output(port_id_to_eval(channel.putter_id)),

                    Value::Input(port_id_to_eval(channel.getter_id))

                ));

                self.inbox_main.push(None);

                self.inbox_main.push(None);

                return CompScheduling::Immediate;

            }

        }

    }

}

impl CompPDL {

    pub(crate) fn new(initial_state: Prompt, num_ports: usize) -> Self {

        let mut inbox_main = Vec::new();

        inbox_main.reserve(num_ports);

        for _ in 0..num_ports {

            inbox_main.push(None);

        }

        return Self{

            exec_state: CompExecState::new(),

            select_state: SelectState::new(),

            prompt: initial_state,

            control: ControlLayer::default(),

            consensus: Consensus::new(),

            sync_counter: 0,

            exec_ctx: ExecCtx{

                stmt: ExecStmt::None,

            },

            inbox_main,

            inbox_backup: Vec::new(),

        }

    }

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

    // Running component and handling changes in global component state

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

    fn execute_prompt(&mut self, sched_ctx: &SchedulerCtx) -> EvalResult {

        let mut step_result = EvalContinuation::Stepping;

        while let EvalContinuation::Stepping = step_result {

            step_result = self.prompt.step(

                &sched_ctx.runtime.protocol.types, &sched_ctx.runtime.protocol.heap,

                &sched_ctx.runtime.protocol.modules, &mut self.exec_ctx,

            )?;

        }

        return Ok(step_result)

    }

    fn handle_sync_start(&mut self, sched_ctx: &SchedulerCtx, comp_ctx: &mut CompCtx) {

        sched_ctx.log("Component starting sync mode");

        self.consensus.notify_sync_start(comp_ctx);

        for message in self.inbox_main.iter() {

            if let Some(message) = message {

                self.consensus.handle_incoming_data_message(comp_ctx, message);

            }

        }

        debug_assert_eq!(self.exec_state.mode, CompMode::NonSync);

        self.exec_state.mode = CompMode::Sync;

    }

    fn handle_component_exit(&mut self, sched_ctx: &SchedulerCtx, comp_ctx: &mut CompCtx) {

        sched_ctx.log(&format!("Component exiting (reason: {:?}", self.exec_state.exit_reason));

        debug_assert_eq!(self.exec_state.mode, CompMode::StartExit);

        self.exec_state.mode = CompMode::BusyExit;

        let exit_inside_sync = self.exec_state.exit_reason.is_in_sync();

        // Doing this by index, then retrieving the handle is a bit rediculous,

        // but Rust is being Rust with its borrowing rules.

        for port_index in 0..comp_ctx.num_ports() {

            let port = comp_ctx.get_port_by_index_mut(port_index);

            if port.state == PortState::Closed {

                // Already closed, or in the process of being closed

                continue;

            }

            // Mark as closed

            let port_id = port.self_id;

            port.state = PortState::Closed;

            // Notify peer of closing

            let port_handle = comp_ctx.get_port_handle(port_id);

            let (peer, message) = self.control.initiate_port_closing(port_handle, exit_inside_sync, comp_ctx);

            let peer_info = comp_ctx.get_peer(peer);

            peer_info.handle.send_message(&sched_ctx.runtime, Message::Control(message), true);

        }

    }

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

    // Handling messages

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

    /// Handles a message that came in through the public inbox. This function

    /// will handle putting it in the correct place, and potentially blocking

    /// the port in case too many messages are being received.

    fn handle_incoming_data_message(&mut self, sched_ctx: &SchedulerCtx, comp_ctx: &mut CompCtx, message: DataMessage) {

        use component::IncomingData;

        // Whatever we do, glean information from headers in message

        if self.exec_state.mode.is_in_sync_block() {

            self.consensus.handle_incoming_data_message(comp_ctx, &message);

        }

        match component::default_handle_incoming_data_message(

            &mut self.exec_state, &mut self.inbox_main, comp_ctx, message,

            sched_ctx, &mut self.control

        ) {

            IncomingData::PlacedInSlot => {

                if self.exec_state.mode == CompMode::BlockedSelect {

                    let select_decision = self.select_state.handle_updated_inbox(&self.inbox_main, comp_ctx);

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

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

                        self.exec_state.mode = CompMode::Sync;

                    }

                }

            },

            IncomingData::SlotFull(message) => {

                self.inbox_backup.push(message);

            }

        }

    }

    fn handle_incoming_sync_message(&mut self, sched_ctx: &SchedulerCtx, comp_ctx: &mut CompCtx, message: SyncMessage) {

        let decision = self.consensus.receive_sync_message(sched_ctx, comp_ctx, message);

        component::default_handle_sync_decision(sched_ctx, &mut self.exec_state, comp_ctx, decision, &mut self.consensus);

    }

    /// Handles an error coming from the generic `component::handle_xxx`

    /// functions. Hence accepts argument as a tuple.

    fn handle_generic_component_error(&mut self, sched_ctx: &SchedulerCtx, location_and_message: (PortInstruction, String)) {

        // Retrieve location and message, display in terminal

        let (location, message) = location_and_message;

        let error = match location {

            PortInstruction::None => CompError::Component(message),

            PortInstruction::NoSource => unreachable!(), // for debugging: all in-sync errors are associated with a source location

            PortInstruction::SourceLocation(expression_id) => {

                let protocol = &sched_ctx.runtime.protocol;

                CompError::Executor(EvalError::new_error_at_expr(

                    &self.prompt, &protocol.modules, &protocol.heap,

                    expression_id, message

                ))

            }

        };

        self.handle_component_error(sched_ctx, error);

    }

    fn handle_component_error(&mut self, sched_ctx: &SchedulerCtx, error: CompError) {

        sched_ctx.error(&format!("{}", error));

        // Set state to handle subsequent error

        let exit_reason = if self.exec_state.mode.is_in_sync_block() {

            ExitReason::ErrorInSync

        } else {

            ExitReason::ErrorNonSync

        };

        self.exec_state.set_as_start_exit(exit_reason);

    }

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

    // Handling ports

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

    /// Creates a new component and transfers ports. Because of the stepwise

    /// process in which memory is allocated, ports are transferred, messages

    /// are exchanged, component lifecycle methods are called, etc. This

    /// function facilitates a lot of implicit assumptions (e.g. when the

    /// `Component::on_creation` method is called, the component is already

    /// registered at the runtime).

    fn create_component_and_transfer_ports(

        &mut self,

        sched_ctx: &SchedulerCtx, creator_ctx: &mut CompCtx,

        definition_id: ProcedureDefinitionId, type_id: TypeId, mut arguments: ValueGroup

    ) {

        struct PortPair{

            creator_handle: LocalPortHandle,

            creator_id: PortId,

            created_handle: LocalPortHandle,

            created_id: PortId,

        }

        let mut opened_port_id_pairs = Vec::new();

        let mut closed_port_id_pairs = Vec::new();

        let reservation = sched_ctx.runtime.start_create_pdl_component();

        let mut created_ctx = CompCtx::new(&reservation);

        let other_proc = &sched_ctx.runtime.protocol.heap[definition_id];

        let self_proc = &sched_ctx.runtime.protocol.heap[self.prompt.frames[0].definition];

        // dbg_code!({

        //     sched_ctx.log(&format!(

        //         "DEBUG: Comp '{}' (ID {:?}) is creating comp '{}' (ID {:?})",

        //         self_proc.identifier.value.as_str(), creator_ctx.id,

        //         other_proc.identifier.value.as_str(), reservation.id()

        //     ));

        // });

        // Take all the ports ID that are in the `args` (and currently belong to

        // the creator component) and translate them into new IDs that are

        // associated with the component we're about to create

        let mut arg_iter = ValueGroupPortIter::new(&mut arguments);

        while let Some(port_reference) = arg_iter.next() {

            // Create port entry for new component

            let creator_port_id = port_reference.id;

            let creator_port_handle = creator_ctx.get_port_handle(creator_port_id);

            let creator_port = creator_ctx.get_port(creator_port_handle);

            let created_port_handle = created_ctx.add_port(

                creator_port.peer_comp_id, creator_port.peer_port_id,

                creator_port.kind, creator_port.state

            );

            let created_port = created_ctx.get_port(created_port_handle);

            let created_port_id = created_port.self_id;

            let port_id_pair = PortPair {

                creator_handle: creator_port_handle,

                creator_id: creator_port_id,

                created_handle: created_port_handle,

                created_id: created_port_id,

            };

            if creator_port.state == PortState::Closed {

                closed_port_id_pairs.push(port_id_pair)

            } else {

                opened_port_id_pairs.push(port_id_pair);

            }

            // Modify value in arguments (bit dirty, but double vec in ValueGroup causes lifetime issues)

            let arg_value = if let Some(heap_pos) = port_reference.heap_pos {

                &mut arg_iter.group.regions[heap_pos][port_reference.index]

            } else {

                &mut arg_iter.group.values[port_reference.index]

            };

            match arg_value {

                Value::Input(id) => *id = port_id_to_eval(created_port_id),

                Value::Output(id) => *id = port_id_to_eval(created_port_id),

                _ => unreachable!(),

            }

        }

        // For each transferred port pair set their peer components to the

        // correct values. This will only change the values for the ports of

        // the new component.

        let mut created_component_has_remote_peers = false;

        for pair in opened_port_id_pairs.iter() {

            let creator_port_info = creator_ctx.get_port(pair.creator_handle);

            let created_port_info = created_ctx.get_port_mut(pair.created_handle);

            if created_port_info.peer_comp_id == creator_ctx.id {

                // Port peer is owned by the creator as well

                let created_peer_port_index = opened_port_id_pairs

                    .iter()

                    .position(|v| v.creator_id == creator_port_info.peer_port_id);

                match created_peer_port_index {

                    Some(created_peer_port_index) => {

                        // Peer port moved to the new component as well. So

                        // adjust IDs appropriately.

                        let peer_pair = &opened_port_id_pairs[created_peer_port_index];

                        created_port_info.peer_port_id = peer_pair.created_id;

                        created_port_info.peer_comp_id = reservation.id();

                        todo!("either add 'self peer', or remove that idea from Ctx altogether")

                    },

                    None => {

                        // Peer port remains with creator component.

                        created_port_info.peer_comp_id = creator_ctx.id;

                        created_ctx.add_peer(pair.created_handle, sched_ctx, creator_ctx.id, None);

                    }

                }

            } else {

                // Peer is a different component. We'll deal with sending the

                // appropriate messages later

                let peer_handle = creator_ctx.get_peer_handle(created_port_info.peer_comp_id);

                let peer_info = creator_ctx.get_peer(peer_handle);

                created_ctx.add_peer(pair.created_handle, sched_ctx, peer_info.id, Some(&peer_info.handle));

                created_component_has_remote_peers = true;

            }

        }

        // We'll now actually turn our reservation for a new component into an

        // actual component. Note that we initialize it as "not sleeping" as

        // its initial scheduling might be performed based on `Ack`s in response

        // to message exchanges between remote peers.

        let total_num_ports = opened_port_id_pairs.len() + closed_port_id_pairs.len();

        let component = component::create_component(&sched_ctx.runtime.protocol, definition_id, type_id, arguments, total_num_ports);

        let (created_key, component) = sched_ctx.runtime.finish_create_pdl_component(

            reservation, component, created_ctx, false,

        );

        component.component.on_creation(created_key.downgrade(), sched_ctx);

        // Now modify the creator's ports: remove every transferred port and

        // potentially remove the peer component.

        for pair in opened_port_id_pairs.iter() {

            // Remove peer if appropriate

            let creator_port_info = creator_ctx.get_port(pair.creator_handle);

            let creator_port_index = creator_ctx.get_port_index(pair.creator_handle);

            let creator_peer_comp_id = creator_port_info.peer_comp_id;

            creator_ctx.remove_peer(sched_ctx, pair.creator_handle, creator_peer_comp_id, false);

            creator_ctx.remove_port(pair.creator_handle);

            // Transfer any messages

            if let Some(mut message) = self.inbox_main.remove(creator_port_index) {

                message.data_header.target_port = pair.created_id;

                component.component.adopt_message(&mut component.ctx, message)

            }

            let mut message_index = 0;

            while message_index < self.inbox_backup.len() {

                let message = &self.inbox_backup[message_index];

                if message.data_header.target_port == pair.creator_id {

                    // transfer message

                    let mut message = self.inbox_backup.remove(message_index);

                    message.data_header.target_port = pair.created_id;

                    component.component.adopt_message(&mut component.ctx, message);

                } else {

                    message_index += 1;

                }

            }

            // Handle potential channel between creator and created component

            let created_port_info = component.ctx.get_port(pair.created_handle);

            if created_port_info.peer_comp_id == creator_ctx.id {

                let peer_port_handle = creator_ctx.get_port_handle(created_port_info.peer_port_id);

                let peer_port_info = creator_ctx.get_port_mut(peer_port_handle);

                peer_port_info.peer_comp_id = component.ctx.id;

                peer_port_info.peer_port_id = created_port_info.self_id;

                creator_ctx.add_peer(peer_port_handle, sched_ctx, component.ctx.id, None);

            }

        }

        for pair in closed_port_id_pairs.iter() {

            let port_index = creator_ctx.get_port_index(pair.creator_handle);

            creator_ctx.remove_port(pair.creator_handle);

        }

        // By now all ports and messages have been transferred. If there are any

        // peers that need to be notified about this new component, then we

        // initiate the protocol that will notify everyone here.

        if created_component_has_remote_peers {

            let created_ctx = &component.ctx;

            let schedule_entry_id = self.control.add_schedule_entry(created_ctx.id);

            for pair in opened_port_id_pairs.iter() {

                let port_info = created_ctx.get_port(pair.created_handle);

                if port_info.peer_comp_id != creator_ctx.id && port_info.peer_comp_id != created_ctx.id {

                    let message = self.control.add_reroute_entry(

                        creator_ctx.id, port_info.peer_port_id, port_info.peer_comp_id,

                        pair.creator_id, pair.created_id, created_ctx.id,

                        schedule_entry_id

                    );

                    let peer_handle = created_ctx.get_peer_handle(port_info.peer_comp_id);

                    let peer_info = created_ctx.get_peer(peer_handle);

                    peer_info.handle.send_message(&sched_ctx.runtime, message, true);

                }

            }

        } else {

            // Peer can be scheduled immediately

            sched_ctx.runtime.enqueue_work(created_key);

        }

    }

}

/// Recursively goes through the value group, attempting to find ports.

/// Duplicates will only be added once.

pub(crate) fn find_ports_in_value_group(value_group: &ValueGroup, ports: &mut Vec<PortId>) {

    // Helper to check a value for a port and recurse if needed.

    fn find_port_in_value(group: &ValueGroup, value: &Value, ports: &mut Vec<PortId>) {

        match value {

            Value::Input(port_id) | Value::Output(port_id) => {

                // This is an actual port

                let cur_port = PortId(port_id.id);

                for prev_port in ports.iter() {

                    if *prev_port == cur_port {

                        // Already added

                        return;

                    }

                }

                ports.push(cur_port);

            },

            Value::Array(heap_pos) |

            Value::Message(heap_pos) |

            Value::String(heap_pos) |

            Value::Struct(heap_pos) |

            Value::Union(_, heap_pos) => {

                // Reference to some dynamic thing which might contain ports,

                // so recurse

                let heap_region = &group.regions[*heap_pos as usize];

                for embedded_value in heap_region {

                    find_port_in_value(group, embedded_value, ports);

                }

            },

            _ => {}, // values we don't care about

        }

    }

    // Clear the ports, then scan all the available values

    ports.clear();

    for value in &value_group.values {

        find_port_in_value(value_group, value, ports);

    }

}

struct ValueGroupPortIter<'a> {

    group: &'a mut ValueGroup,

    heap_stack: Vec<(usize, usize)>,

    index: usize,

}

impl<'a> ValueGroupPortIter<'a> {

    fn new(group: &'a mut ValueGroup) -> Self {

        return Self{ group, heap_stack: Vec::new(), index: 0 }

    }

}

struct ValueGroupPortRef {

    id: PortId,