pub fn prepare_single_expression(&mut self, heap: &Heap, expr_id: ExpressionId) {

        debug_assert!(self.expr_stack.is_empty());

        self.expr_values.clear(); // May not be empty if last expression result(s) were discarded

        self.serialize_expression(heap, expr_id);

    }

    /// Prepares multiple expressions for execution (i.e. evaluating all

    /// function arguments or all elements of an array/union literal). Per

    /// expression this works the same as `prepare_single_expression`. However

    /// after each expression is evaluated we insert a `PushValToFront`

    /// instruction

    pub fn prepare_multiple_expressions(&mut self, heap: &Heap, expr_ids: &[ExpressionId]) {

        debug_assert!(self.expr_stack.is_empty());

        self.expr_values.clear();

        for expr_id in expr_ids {

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

            self.serialize_expression(heap, *expr_id);

        }

    }

    /// Performs depth-first serialization of expression tree. Let's not care

    /// about performance for a temporary runtime implementation

    fn serialize_expression(&mut self, heap: &Heap, id: ExpressionId) {

        self.expr_stack.push_back(ExprInstruction::EvalExpr(id));

        match &heap[id] {

            Expression::Assignment(expr) => {

                self.serialize_expression(heap, expr.left);

                self.serialize_expression(heap, expr.right);

            },

            Expression::Binding(expr) => {

                todo!("implement binding expression");

            },

            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::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),

    BlockFires(Value),

    BlockGet(Value),

    Put(Value, 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());

        prompt.frames.push(Frame::new(heap, def, monomorph_idx));

        args.into_store(&mut prompt.store);

        prompt

    }

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

                                self.store.heap_regions[new_heap_pos as usize].values = values;

                            } // else: empty range

                            cur_frame.expr_values.push_back(Value::Array(new_heap_pos));

                            // Dropping the original subject, because we don't

                            // want to drop something on the stack

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

                        },

                        Expression::Select(expr) => {

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

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

                            let field_idx = mono_data.expr_data[expr.unique_id_in_definition as usize].field_or_monomorph_idx as u32;

                            // Note: same as above: clone if value lives on expr stack, simply

                            // refer to it if it already lives on the stack/heap.

                            let (deallocate_heap_pos, value_to_push) = match subject {

                                Value::Ref(value_ref) => {

                                    let subject = self.store.read_ref(value_ref);

                                    let subject_heap_pos = subject.as_struct();

                                    (None, Value::Ref(ValueId::Heap(subject_heap_pos, field_idx)))

                                },

                                _ => {

                                    let subject_heap_pos = subject.as_struct();

                                    let subject_indexed = Value::Ref(ValueId::Heap(subject_heap_pos, field_idx));

                                    (Some(subject_heap_pos), self.store.clone_value(subject_indexed))

                                },

                            };

                            cur_frame.expr_values.push_back(value_to_push);

                            self.store.drop_value(deallocate_heap_pos);

                        },

                        Expression::Literal(expr) => {

                            let value = match &expr.value {

                                Literal::Null => Value::Null,

                                Literal::True => Value::Bool(true),

                                Literal::False => Value::Bool(false),

                                Literal::Character(lit_value) => Value::Char(*lit_value),

                                Literal::String(lit_value) => {

                                    let heap_pos = self.store.alloc_heap();

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

                                    let value = lit_value.as_str();

                                    debug_assert!(values.is_empty());

                                    values.reserve(value.len());

                                    for character in value.as_bytes() {

                                        debug_assert!(character.is_ascii());

                                        values.push(Value::Char(*character as char));

                                    }

                                    Value::String(heap_pos)

                                }

                                Literal::Integer(lit_value) => {

                                    use ConcreteTypePart as CTP;

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

                                    let concrete_type = &def_types.expr_data[expr.unique_id_in_definition as usize].expr_type;

                                    debug_assert_eq!(concrete_type.parts.len(), 1);

                                    match concrete_type.parts[0] {

                                        CTP::UInt8  => Value::UInt8(lit_value.unsigned_value as u8),

                                        CTP::UInt16 => Value::UInt16(lit_value.unsigned_value as u16),

                                        CTP::UInt32 => Value::UInt32(lit_value.unsigned_value as u32),

                                        CTP::UInt64 => Value::UInt64(lit_value.unsigned_value as u64),

                                        CTP::SInt8  => Value::SInt8(lit_value.unsigned_value as i8),

                                        CTP::SInt16 => Value::SInt16(lit_value.unsigned_value as i16),

                                        CTP::SInt32 => Value::SInt32(lit_value.unsigned_value as i32),

                                        CTP::SInt64 => Value::SInt64(lit_value.unsigned_value as i64),

                                        _ => unreachable!("got concrete type {:?} for integer literal at expr {:?}", concrete_type, expr_id),

                                    }

                                }

                                Literal::Struct(lit_value) => {

                                    let heap_pos = transfer_expression_values_front_into_heap(

                                        cur_frame, &mut self.store, lit_value.fields.len()

                                    );

                                    Value::Struct(heap_pos)

                                }

                                Literal::Enum(lit_value) => {

                                    Value::Enum(lit_value.variant_idx as i64)

                                }

                                Literal::Union(lit_value) => {

                                    let heap_pos = transfer_expression_values_front_into_heap(

                                        cur_frame, &mut self.store, lit_value.values.len()

                                    );

                                    Value::Union(lit_value.variant_idx as i64, heap_pos)

                                }

                                Literal::Array(lit_value) => {

                                    let heap_pos = transfer_expression_values_front_into_heap(

                                        cur_frame, &mut self.store, lit_value.len()

                                    );

                                    Value::Array(heap_pos)

                                }

                            };

                            cur_frame.expr_values.push_back(value);

                        },

                        }

                        Expression::Call(expr) => {

                            // Push a new frame. Note that all expressions have

                            // been pushed to the front, so they're in the order

                            // of the definition.

                            let num_args = expr.arguments.len();

                            // Determine stack boundaries

                            let cur_stack_boundary = self.store.cur_stack_boundary;

                            let new_stack_boundary = self.store.stack.len();

                            // Push new boundary and function arguments for new frame

                            self.store.stack.push(Value::PrevStackBoundary(cur_stack_boundary as isize));

                            for _ in 0..num_args {

                                let argument = self.store.read_take_ownership(cur_frame.expr_values.pop_front().unwrap());

                                self.store.stack.push(argument);

                            }

                            // Determine the monomorph index of the function we're calling

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

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

                            // Push the new frame

                            self.frames.push(Frame::new(heap, expr.definition, call_data.field_or_monomorph_idx));

                            self.store.cur_stack_boundary = new_stack_boundary;

                            // To simplify the logic a little bit we will now

                            // return and ask our caller to call us again

                            return Ok(EvalContinuation::Stepping);

                        },

                        Expression::Variable(expr) => {

                            let variable = &heap[expr.declaration.unwrap()];

                            cur_frame.expr_values.push_back(Value::Ref(ValueId::Stack(variable.unique_id_in_scope as StackPos)));

                        }

                    }

                }

            }

        }

        debug_log!("Frame [{:?}] at {:?}, stack size = {}", cur_frame.definition, cur_frame.position, self.store.stack.len());

        if debug_enabled!() {

            debug_log!("Stack:");

            for (stack_idx, stack_val) in self.store.stack.iter().enumerate() {

                debug_log!("  [{:03}] {:?}", stack_idx, stack_val);

            }

            debug_log!("Heap:");

            for (heap_idx, heap_region) in self.store.heap_regions.iter().enumerate() {

                let is_free = self.store.free_regions.iter().any(|idx| *idx as usize == heap_idx);

                debug_log!("  [{:03}] in_use: {}, len: {}, vals: {:?}", heap_idx, !is_free, heap_region.values.len(), &heap_region.values);

            }

        }

        // No (more) expressions to evaluate. So evaluate statement (that may

        // depend on the result on the last evaluated expression(s))

        let stmt = &heap[cur_frame.position];

        let return_value = match stmt {

            Statement::Block(stmt) => {

                // Reserve space on stack, but also make sure excess stack space

                // is cleared

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

                self.store.reserve_stack(stmt.next_unique_id_in_scope as usize);

                cur_frame.position = stmt.statements[0];

                Ok(EvalContinuation::Stepping)

            },

            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;

                    },

                    LocalStatement::Channel(stmt) => {

                        let [from_value, to_value] = ctx.new_channel();

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

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

                        cur_frame.position = stmt.next;

                    }

                }

                Ok(EvalContinuation::Stepping)

            },

            Statement::Labeled(stmt) => {

                cur_frame.position = stmt.body;

                Ok(EvalContinuation::Stepping)

            },

use super::store::*;

use crate::PortId;

use crate::protocol::ast::{

    AssignmentOperator,

    BinaryOperator,

    UnaryOperator,

};

pub type StackPos = u32;

pub type HeapPos = u32;

#[derive(Debug, Copy, Clone)]

pub enum ValueId {

    Stack(StackPos), // place on stack

    Heap(HeapPos, u32), // allocated region + values within that region

}

/// Represents a value stored on the stack or on the heap. Some values contain

/// a `HeapPos`, implying that they're stored in the store's `Heap`. Clearing

/// a `Value` with a `HeapPos` from a stack must also clear the associated

/// region from the `Heap`.

#[derive(Debug, Clone)]

pub enum Value {

    // Special types, never encountered during evaluation if the compiler works correctly

    Unassigned,                 // Marker when variables are first declared, immediately followed by assignment

    PrevStackBoundary(isize),   // Marker for stack frame beginning, so we can pop stack values

    Ref(ValueId),               // Reference to a value, used by expressions producing references

    // Builtin types

    Input(PortId),

    Output(PortId),

    Message(HeapPos),

    Null,

    Bool(bool),

    Char(char),

    String(HeapPos),

    UInt8(u8),

    UInt16(u16),

    UInt32(u32),

    UInt64(u64),

    SInt8(i8),

    SInt16(i16),

    SInt32(i32),

    SInt64(i64),

    Array(HeapPos),

    // Instances of user-defined types

    Enum(i64),

    Union(i64, HeapPos),

    Struct(HeapPos),

}

macro_rules! impl_union_unpack_as_value {

    ($func_name:ident, $variant_name:path, $return_type:ty) => {

        impl Value {

            pub(crate) fn $func_name(&self) -> $return_type {

                match self {

                    $variant_name(v) => *v,

                    _ => panic!(concat!("called ", stringify!($func_name()), " on {:?}"), self),

                }

            }

        }

    }

}

impl_union_unpack_as_value!(as_stack_boundary, Value::PrevStackBoundary, isize);

impl_union_unpack_as_value!(as_ref,     Value::Ref,     ValueId);

impl_union_unpack_as_value!(as_input,   Value::Input,   PortId);

impl_union_unpack_as_value!(as_output,  Value::Output,  PortId);

impl_union_unpack_as_value!(as_message, Value::Message, HeapPos);

impl_union_unpack_as_value!(as_bool,    Value::Bool,    bool);

impl_union_unpack_as_value!(as_char,    Value::Char,    char);

impl_union_unpack_as_value!(as_string,  Value::String,  HeapPos);

impl_union_unpack_as_value!(as_uint8,   Value::UInt8,   u8);

impl_union_unpack_as_value!(as_uint16,  Value::UInt16,  u16);

impl_union_unpack_as_value!(as_uint32,  Value::UInt32,  u32);

impl_union_unpack_as_value!(as_uint64,  Value::UInt64,  u64);

impl_union_unpack_as_value!(as_sint8,   Value::SInt8,   i8);

impl_union_unpack_as_value!(as_sint16,  Value::SInt16,  i16);

impl_union_unpack_as_value!(as_sint32,  Value::SInt32,  i32);

impl_union_unpack_as_value!(as_sint64,  Value::SInt64,  i64);

impl_union_unpack_as_value!(as_array,   Value::Array,   HeapPos);

impl_union_unpack_as_value!(as_enum,    Value::Enum,    i64);

impl_union_unpack_as_value!(as_struct,  Value::Struct,  HeapPos);

impl Value {

    pub(crate) fn as_union(&self) -> (i64, HeapPos) {

        match self {

            Value::Union(tag, v) => (*tag, *v),

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

        }

    }

    pub(crate) fn is_integer(&self) -> bool {

        match self {

            Value::UInt8(_) | Value::UInt16(_) | Value::UInt32(_) | Value::UInt64(_) |

            Value::SInt8(_) | Value::SInt16(_) | Value::SInt32(_) | Value::SInt64(_) => true,

            _ => false

        }

    }

    pub(crate) fn is_unsigned_integer(&self) -> bool {

        match self {

            Value::UInt8(_) | Value::UInt16(_) | Value::UInt32(_) | Value::UInt64(_) => true,

        let rhs_len = store.heap_regions[rhs_heap_pos].values.len();

        concatenated.reserve(lhs_len + rhs_len);

        for idx in 0..lhs_len {

            concatenated.push(store.clone_value(store.heap_regions[lhs_heap_pos].values[idx].clone()));

        }

        for idx in 0..rhs_len {

            concatenated.push(store.clone_value(store.heap_regions[rhs_heap_pos].values[idx].clone()));

        }

        store.heap_regions[target_heap_pos as usize].values = concatenated;

        return match value_kind{

            ValueKind::Message => Value::Message(target_heap_pos),

            ValueKind::String => Value::String(target_heap_pos),

            ValueKind::Array => Value::Array(target_heap_pos),

        };

    }

    // If any of the values are references, retrieve the thing they're referring

    // to.

    let lhs = store.maybe_read_ref(lhs);

    let rhs = store.maybe_read_ref(rhs);

    match op {

        BO::Concatenate => unreachable!(),

        BO::LogicalOr => {

            return Value::Bool(lhs.as_bool() || rhs.as_bool());

        },

        BO::LogicalAnd => {

            return Value::Bool(lhs.as_bool() && rhs.as_bool());

        },

        BO::BitwiseOr        => { apply_int_op_and_return_self!(lhs, |,  op, rhs); },

        BO::BitwiseXor       => { apply_int_op_and_return_self!(lhs, ^,  op, rhs); },

        BO::BitwiseAnd       => { apply_int_op_and_return_self!(lhs, &,  op, rhs); },

        BO::Equality         => { Value::Bool(apply_equality_operator(store, lhs, rhs)) },

        BO::Inequality       => { Value::Bool(apply_inequality_operator(store, lhs, rhs)) },

        BO::LessThan         => { apply_int_op_and_return_bool!(lhs, <,  op, rhs); },

        BO::GreaterThan      => { apply_int_op_and_return_bool!(lhs, >,  op, rhs); },

        BO::LessThanEqual    => { apply_int_op_and_return_bool!(lhs, <=, op, rhs); },

        BO::GreaterThanEqual => { apply_int_op_and_return_bool!(lhs, >=, op, rhs); },

        BO::ShiftLeft        => { apply_int_op_and_return_self!(lhs, <<, op, rhs); },

        BO::ShiftRight       => { apply_int_op_and_return_self!(lhs, >>, op, rhs); },

        BO::Add              => { apply_int_op_and_return_self!(lhs, +,  op, rhs); },

        BO::Subtract         => { apply_int_op_and_return_self!(lhs, -,  op, rhs); },

        BO::Multiply         => { apply_int_op_and_return_self!(lhs, *,  op, rhs); },

        BO::Divide           => { apply_int_op_and_return_self!(lhs, /,  op, rhs); },

        BO::Remainder        => { apply_int_op_and_return_self!(lhs, %,  op, rhs); }

    }

}

pub(crate) fn apply_unary_operator(store: &mut Store, op: UnaryOperator, value: &Value) -> Value {

    use UnaryOperator as UO;

    macro_rules! apply_int_expr_and_return {

        ($value:ident, $apply:tt, $op:ident) => {

            return match $value {

                Value::UInt8(v)  => Value::UInt8($apply *v),

                Value::UInt16(v) => Value::UInt16($apply *v),

                Value::UInt32(v) => Value::UInt32($apply *v),

                Value::UInt64(v) => Value::UInt64($apply *v),

                Value::SInt8(v)  => Value::SInt8($apply *v),

                Value::SInt16(v) => Value::SInt16($apply *v),

                Value::SInt32(v) => Value::SInt32($apply *v),

                Value::SInt64(v) => Value::SInt64($apply *v),

                _ => unreachable!("apply_unary_operator {:?} on value {:?}", $op, $value),

            };

        }

    }

    // If the value is a reference, retrieve the thing it is referring to

    let value = store.maybe_read_ref(value);

    match op {

        UO::Positive => {

            debug_assert!(value.is_integer());

            return value.clone();

        },

        UO::Negative => {

            // TODO: Error on negating unsigned integers

            return match value {

                Value::SInt8(v) => Value::SInt8(-*v),

                Value::SInt16(v) => Value::SInt16(-*v),

                Value::SInt32(v) => Value::SInt32(-*v),

                Value::SInt64(v) => Value::SInt64(-*v),

                _ => unreachable!("apply_unary_operator {:?} on value {:?}", op, value),

            }

        },

        UO::BitwiseNot => { apply_int_expr_and_return!(value, !, op)},

        UO::LogicalNot => { return Value::Bool(!value.as_bool()); },

        UO::PreIncrement => { todo!("implement") },

        UO::PreDecrement => { todo!("implement") },

        UO::PostIncrement => { todo!("implement") },

        UO::PostDecrement => { todo!("implement") },

    }

}

pub(crate) fn apply_equality_operator(store: &Store, lhs: &Value, rhs: &Value) -> bool {

    let lhs = store.maybe_read_ref(lhs);

    let rhs = store.maybe_read_ref(rhs);

    fn eval_equality_heap(store: &Store, lhs_pos: HeapPos, rhs_pos: HeapPos) -> bool {

        let lhs_vals = &store.heap_regions[lhs_pos as usize].values;

        let rhs_vals = &store.heap_regions[rhs_pos as usize].values;

        let lhs_len = lhs_vals.len();

        if lhs_len != rhs_vals.len() {

            return false;

        }

        for idx in 0..lhs_len {

            let lhs_val = &lhs_vals[idx];

            let rhs_val = &rhs_vals[idx];

            if !apply_equality_operator(store, lhs_val, rhs_val) {

                return false;

            }

        }

        return true;

    }

    match lhs {

        Value::Input(v) => *v == rhs.as_input(),

        Value::Output(v) => *v == rhs.as_output(),

        Value::Message(lhs_pos) => eval_equality_heap(store, *lhs_pos, rhs.as_message()),

        Value::Null => todo!("remove null"),

        Value::Bool(v) => *v == rhs.as_bool(),

        Value::Char(v) => *v == rhs.as_char(),

        Value::String(lhs_pos) => eval_equality_heap(store, *lhs_pos, rhs.as_string()),

        Value::UInt8(v) => *v == rhs.as_uint8(),

        Value::UInt16(v) => *v == rhs.as_uint16(),

        Value::UInt32(v) => *v == rhs.as_uint32(),

        Value::UInt64(v) => *v == rhs.as_uint64(),

        Value::SInt8(v) => *v == rhs.as_sint8(),

        Value::SInt16(v) => *v == rhs.as_sint16(),

        Value::SInt32(v) => *v == rhs.as_sint32(),

        Value::SInt64(v) => *v == rhs.as_sint64(),

        Value::Array(lhs_pos) => eval_equality_heap(store, *lhs_pos, rhs.as_array()),

        Value::Enum(v) => *v == rhs.as_enum(),

        Value::Union(lhs_tag, lhs_pos) => {

            let (rhs_tag, rhs_pos) = rhs.as_union();

            if *lhs_tag != rhs_tag {

                return false;

            }

            eval_equality_heap(store, *lhs_pos, rhs_pos)

        },

        Value::Struct(lhs_pos) => eval_equality_heap(store, *lhs_pos, rhs.as_struct()),

        _ => unreachable!("apply_equality_operator to lhs {:?}", lhs),

    }

}

pub(crate) fn apply_inequality_operator(store: &Store, lhs: &Value, rhs: &Value) -> bool {

    let lhs = store.maybe_read_ref(lhs);

    let rhs = store.maybe_read_ref(rhs);

    fn eval_inequality_heap(store: &Store, lhs_pos: HeapPos, rhs_pos: HeapPos) -> bool {

        let lhs_vals = &store.heap_regions[lhs_pos as usize].values;

        let rhs_vals = &store.heap_regions[rhs_pos as usize].values;

        let lhs_len = lhs_vals.len();

        if lhs_len != rhs_vals.len() {

            return true;

        }

        for idx in 0..lhs_len {

            let lhs_val = &lhs_vals[idx];

            let rhs_val = &rhs_vals[idx];

            if apply_inequality_operator(store, lhs_val, rhs_val) {

                return true;

            }

        }

        return false;

    }

    match lhs {

        Value::Input(v) => *v != rhs.as_input(),

        Value::Output(v) => *v != rhs.as_output(),

        Value::Message(lhs_pos) => eval_inequality_heap(store, *lhs_pos, rhs.as_message()),

        Value::Null => todo!("remove null"),

        Value::Bool(v) => *v != rhs.as_bool(),

        Value::Char(v) => *v != rhs.as_char(),

        Value::String(lhs_pos) => eval_inequality_heap(store, *lhs_pos, rhs.as_string()),

        Value::UInt8(v) => *v != rhs.as_uint8(),

        Value::UInt16(v) => *v != rhs.as_uint16(),

        Value::UInt32(v) => *v != rhs.as_uint32(),

        Value::UInt64(v) => *v != rhs.as_uint64(),

        Value::SInt8(v) => *v != rhs.as_sint8(),

        Value::SInt16(v) => *v != rhs.as_sint16(),

        Value::SInt32(v) => *v != rhs.as_sint32(),

        Value::SInt64(v) => *v != rhs.as_sint64(),

        Value::Enum(v) => *v != rhs.as_enum(),

        Value::Union(lhs_tag, lhs_pos) => {

            let (rhs_tag, rhs_pos) = rhs.as_union();

            if *lhs_tag != rhs_tag {

/// pass_typing

///

/// Performs type inference and type checking. Type inference is implemented by

/// applying constraints on (sub)trees of types. During this process the

/// resolver takes the `ParserType` structs (the representation of the types

/// written by the programmer), converts them to `InferenceType` structs (the

/// temporary data structure used during type inference) and attempts to arrive

/// at `ConcreteType` structs (the representation of a fully checked and

/// validated type).

///

/// The resolver will visit every statement and expression relevant to the

/// procedure and insert and determine its initial type based on context (e.g. a

/// return statement's expression must match the function's return type, an

/// if statement's test expression must evaluate to a boolean). When all are

/// visited we attempt to make progress in evaluating the types. Whenever a type

/// is progressed we queue the related expressions for further type progression.

/// Once no more expressions are in the queue the algorithm is finished. At this

/// point either all types are inferred (or can be trivially implicitly

/// error.

///

/// TODO: Needs a thorough rewrite:

///  2. We're doing a lot of extra work. It seems better to apply the initial

///  3. Remove the `msg` type?

///  4. Disallow certain types in certain operations (e.g. `Void`).

macro_rules! debug_log_enabled {

    () => { false };

}

macro_rules! debug_log {

    ($format:literal) => {

        enabled_debug_print!(false, "types", $format);

    };

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

        enabled_debug_print!(false, "types", $format, $($args),*);

    };

}

use std::collections::{HashMap, HashSet};

use crate::collections::DequeSet;

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

use crate::protocol::input_source::ParseError;

use crate::protocol::parser::ModuleCompilationPhase;

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

use crate::protocol::parser::token_parsing::*;

use super::visitor::{

    STMT_BUFFER_INIT_CAPACITY,

    EXPR_BUFFER_INIT_CAPACITY,

    Ctx,

    Visitor2,

    VisitorResult

};

const VOID_TEMPLATE: [InferenceTypePart; 1] = [ InferenceTypePart::Void ];

const MESSAGE_TEMPLATE: [InferenceTypePart; 2] = [ InferenceTypePart::Message, InferenceTypePart::UInt8 ];

const BOOL_TEMPLATE: [InferenceTypePart; 1] = [ InferenceTypePart::Bool ];

const CHARACTER_TEMPLATE: [InferenceTypePart; 1] = [ InferenceTypePart::Character ];

const STRING_TEMPLATE: [InferenceTypePart; 1] = [ InferenceTypePart::String ];

const NUMBERLIKE_TEMPLATE: [InferenceTypePart; 1] = [ InferenceTypePart::NumberLike ];

const INTEGERLIKE_TEMPLATE: [InferenceTypePart; 1] = [ InferenceTypePart::IntegerLike ];

const ARRAY_TEMPLATE: [InferenceTypePart; 2] = [ InferenceTypePart::Array, InferenceTypePart::Unknown ];

const SLICE_TEMPLATE: [InferenceTypePart; 2] = [ InferenceTypePart::Slice, InferenceTypePart::Unknown ];

const ARRAYLIKE_TEMPLATE: [InferenceTypePart; 2] = [ InferenceTypePart::ArrayLike, InferenceTypePart::Unknown ];

/// TODO: @performance Turn into PartialOrd+Ord to simplify checks

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

pub(crate) enum InferenceTypePart {

    // When we infer types of AST elements that support polymorphic arguments,

    // then we might have the case that multiple embedded types depend on the

    // polymorphic type (e.g. func bla(T a, T[] b) -> T[][]). If we can infer

    // the type in one place (e.g. argument a), then we may propagate this

    // information to other types (e.g. argument b and the return type). For

    // this reason we place markers in the `InferenceType` instances such that

    // we know which part of the type was originally a polymorphic argument.

    Marker(u32),

    // Completely unknown type, needs to be inferred

    Unknown,

    // Partially known type, may be inferred to to be the appropriate related 

    // type.

    // IndexLike,      // index into array/slice

    NumberLike,     // any kind of integer/float

    IntegerLike,    // any kind of integer

    ArrayLike,      // array or slice. Note that this must have a subtype

    PortLike,       // input or output port

    // Special types that cannot be instantiated by the user

    Void, // For builtin functions that do not return anything

    // Concrete types without subtypes

    Bool,