_ => false,

        }

    }

    fn is_concrete_msg_array_or_slice(&self) -> bool {

        use InferenceTypePart as ITP;

        match self {

            ITP::Array | ITP::Slice | ITP::Message => true,

            _ => false,

        }

    }

    fn is_concrete_port(&self) -> bool {

        use InferenceTypePart as ITP;

        match self {

            ITP::Input | ITP::Output => true,

            _ => false,

        }

    }

    /// Checks if a part is less specific than the argument. Only checks for 

    /// single-part inference (i.e. not the replacement of an `Unknown` variant 

    /// with the argument)

    fn may_be_inferred_from(&self, arg: &InferenceTypePart) -> bool {

        use InferenceTypePart as ITP;

        (*self == ITP::IntegerLike && arg.is_concrete_integer()) ||

        (*self == ITP::NumberLike && (arg.is_concrete_number() || *arg == ITP::IntegerLike)) ||

        (*self == ITP::ArrayLike && arg.is_concrete_msg_array_or_slice()) ||

        (*self == ITP::PortLike && arg.is_concrete_port())

    }

    /// Returns the change in "iteration depth" when traversing this particular

    /// part. The iteration depth is used to traverse the tree in a linear 

    /// fashion. It is basically `number_of_subtypes - 1`

    fn depth_change(&self) -> i32 {

        use InferenceTypePart as ITP;

        match &self {

            ITP::Unknown | ITP::NumberLike | ITP::IntegerLike |

            ITP::Void | ITP::Bool |

            ITP::Byte | ITP::Short | ITP::Int | ITP::Long | 

            ITP::String => {

                -1

            },

            ITP::MarkerDefinition(_) | ITP::MarkerBody(_) |

            ITP::ArrayLike | ITP::Message | ITP::Array | ITP::Slice |

            ITP::PortLike | ITP::Input | ITP::Output => {

                // One subtype, so do not modify depth

                0

            },

            ITP::Instance(_, num_args) => {

                (*num_args as i32) - 1

            }

        }

    }

}

impl From<ConcreteTypePart> for InferenceTypePart {

    fn from(v: ConcreteTypePart) -> InferenceTypePart {

        use ConcreteTypePart as CTP;

        use InferenceTypePart as ITP;

        match v {

            CTP::Marker(_) => {

                unreachable!("encountered marker while converting concrete type to inferred type");

            }

            CTP::Void => ITP::Void,

            CTP::Message => ITP::Message,

            CTP::Bool => ITP::Bool,

            CTP::Byte => ITP::Byte,

            CTP::Short => ITP::Short,

            CTP::Int => ITP::Int,

            CTP::Long => ITP::Long,

            CTP::String => ITP::String,

            CTP::Array => ITP::Array,

            CTP::Slice => ITP::Slice,

            CTP::Input => ITP::Input,

            CTP::Output => ITP::Output,

            CTP::Instance(id, num) => ITP::Instance(id, num),

        }

    }

}

#[derive(Debug)]

struct InferenceType {

    has_body_marker: bool,

    is_done: bool,

    parts: Vec<InferenceTypePart>,

}

impl InferenceType {

    /// Generates a new InferenceType. The two boolean flags will be checked in

    /// debug mode.

    fn new(has_body_marker: bool, is_done: bool, parts: Vec<InferenceTypePart>) -> Self {

        if cfg!(debug_assertions) {

            debug_assert!(!parts.is_empty());

        }

        Self{ has_body_marker: has_body_marker, is_done, parts }

    }

    /// Replaces a type subtree with the provided subtree. The caller must make

    /// sure the the replacement is a well formed type subtree.

    fn replace_subtree(&mut self, start_idx: usize, with: &[InferenceTypePart]) {

        let end_idx = Self::find_subtree_end_idx(&self.parts, start_idx);

        debug_assert_eq!(with.len(), Self::find_subtree_end_idx(with, 0));

        self.parts.splice(start_idx..end_idx, with.iter().cloned());

        self.recompute_is_done();

    }

    // TODO: @performance, might all be done inline in the type inference methods

    fn recompute_is_done(&mut self) {

        self.is_done = self.parts.iter().all(|v| v.is_concrete());

    }

    /// Seeks a body marker starting at the specified position. If a marker is

    /// found then its value and the index of the type subtree that follows it

    /// is returned.

    fn find_body_marker(&self, mut start_idx: usize) -> Option<(usize, usize)> {

        while start_idx < self.parts.len() {

            if let InferenceTypePart::MarkerBody(marker) = &self.parts[start_idx] {

                return Some((*marker, start_idx + 1))

            }

            start_idx += 1;

        }

        None

    }

    /// Returns an iterator over all body markers and the partial type tree that

    /// follows those markers. If it is a problem that `InferenceType` is 

    /// borrowed by the iterator, then use `find_body_marker`.

    fn body_marker_iter(&self) -> InferenceTypeMarkerIter {

        InferenceTypeMarkerIter::new(&self.parts)

    }

    /// Given that the `parts` are a depth-first serialized tree of types, this

    /// function finds the subtree anchored at a specific node. The returned 

    /// index is exclusive.

    fn find_subtree_end_idx(parts: &[InferenceTypePart], start_idx: usize) -> usize {

        let mut depth = 1;

        let mut idx = start_idx;

        while idx < parts.len() {

            depth += parts[idx].depth_change();

            if depth == 0 {

                return idx + 1;

            }

            idx += 1;

        }

        // If here, then the inference type is malformed

        unreachable!();

    }

    /// Call that attempts to infer the part at `to_infer.parts[to_infer_idx]` 

    /// using the subtree at `template.parts[template_idx]`. Will return 

    /// `Some(depth_change_due_to_traversal)` if type inference has been 

    /// applied. In this case the indices will also be modified to point to the 

    /// next part in both templates. If type inference has not (or: could not) 

    /// be applied then `None` will be returned. Note that this might mean that 

    /// the types are incompatible.

    ///

    /// As this is a helper functions, some assumptions: the parts are not 

    /// exactly equal, and neither of them contains a marker. Also: only the

    /// `to_infer` parts are checked for inference. It might be that this 

    /// function returns `None`, but that that `template` is still compatible

    /// with `to_infer`, e.g. when `template` has an `Unknown` part.

    fn infer_part_for_single_type(

        to_infer: &mut InferenceType, to_infer_idx: &mut usize,

        template_parts: &[InferenceTypePart], template_idx: &mut usize,

    ) -> Option<i32> {

        use InferenceTypePart as ITP;

        let to_infer_part = &to_infer.parts[*to_infer_idx];

        let template_part = &template_parts[*template_idx];

        // TODO: Maybe do this differently?

        let mut template_definition_marker = None;

        if *template_idx > 0 {

            if let ITP::MarkerDefinition(marker) = &template_parts[*template_idx - 1] {

                template_definition_marker = Some(*marker)

            }

        }

        // Check for programmer mistakes

        debug_assert_ne!(to_infer_part, template_part);

        debug_assert!(!to_infer_part.is_marker(), "marker encountered in 'infer part'");

        debug_assert!(!template_part.is_marker(), "marker encountered in 'template part'");

        // Inference of a somewhat-specified type

        if to_infer_part.may_be_inferred_from(template_part) {

    fn visit_unary_expr(&mut self, ctx: &mut Ctx, id: UnaryExpressionId) -> VisitorResult {

        let upcast_id = id.upcast();

        self.insert_initial_expr_inference_type(ctx, upcast_id)?;

        let unary_expr = &ctx.heap[id];

        let arg_expr_id = unary_expr.expression;

        self.visit_expr(ctx, arg_expr_id)?;

        self.progress_unary_expr(ctx, id)

    }

    fn visit_indexing_expr(&mut self, ctx: &mut Ctx, id: IndexingExpressionId) -> VisitorResult {

        let upcast_id = id.upcast();

        self.insert_initial_expr_inference_type(ctx, upcast_id)?;

        let indexing_expr = &ctx.heap[id];

        let subject_expr_id = indexing_expr.subject;

        let index_expr_id = indexing_expr.index;

        self.visit_expr(ctx, subject_expr_id)?;

        self.visit_expr(ctx, index_expr_id)?;

        self.progress_indexing_expr(ctx, id)

    }

    fn visit_slicing_expr(&mut self, ctx: &mut Ctx, id: SlicingExpressionId) -> VisitorResult {

        let upcast_id = id.upcast();

        self.insert_initial_expr_inference_type(ctx, upcast_id)?;

        let slicing_expr = &ctx.heap[id];

        let subject_expr_id = slicing_expr.subject;

        let from_expr_id = slicing_expr.from_index;

        let to_expr_id = slicing_expr.to_index;

        self.visit_expr(ctx, subject_expr_id)?;

        self.visit_expr(ctx, from_expr_id)?;

        self.visit_expr(ctx, to_expr_id)?;

        self.progress_slicing_expr(ctx, id)

    }

    fn visit_select_expr(&mut self, ctx: &mut Ctx, id: SelectExpressionId) -> VisitorResult {

        let upcast_id = id.upcast();

        self.insert_initial_expr_inference_type(ctx, upcast_id)?;

        let select_expr = &ctx.heap[id];

        let subject_expr_id = select_expr.subject;

        self.visit_expr(ctx, subject_expr_id)?;

        self.progress_select_expr(ctx, id)

    }

    fn visit_array_expr(&mut self, ctx: &mut Ctx, id: ArrayExpressionId) -> VisitorResult {

        let upcast_id = id.upcast();

        self.insert_initial_expr_inference_type(ctx, upcast_id)?;

        let array_expr = &ctx.heap[id];

        // TODO: @performance

        for element_id in array_expr.elements.clone().into_iter() {

            self.visit_expr(ctx, element_id)?;

        }

        self.progress_array_expr(ctx, id)

    }

    fn visit_literal_expr(&mut self, ctx: &mut Ctx, id: LiteralExpressionId) -> VisitorResult {

        let upcast_id = id.upcast();

        self.insert_initial_expr_inference_type(ctx, upcast_id)?;

        let literal_expr = &ctx.heap[id];

        match &literal_expr.value {

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

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

                // No subexpressions

            },

            Literal::Struct(literal) => {

                // TODO: @performance

                let expr_ids: Vec<_> = literal.fields

                    .iter()

                    .map(|f| f.value)

                    .collect();

                self.insert_initial_struct_polymorph_data(ctx, id);

                for expr_id in expr_ids {

                    self.visit_expr(ctx, expr_id)?;

                }

            },

            Literal::Enum(_) => {

                // Enumerations do not carry any subexpressions, but may still

                // have a user-defined polymorphic marker variable. For this 

                // reason we may still have to apply inference to this 

                // polymorphic variable

                self.insert_initial_enum_polymorph_data(ctx, id);

            }

        }

        self.progress_literal_expr(ctx, id)

    }

    fn visit_call_expr(&mut self, ctx: &mut Ctx, id: CallExpressionId) -> VisitorResult {

        let upcast_id = id.upcast();

        self.insert_initial_expr_inference_type(ctx, upcast_id)?;

        self.insert_initial_call_polymorph_data(ctx, id);

        // TODO: @performance

        let call_expr = &ctx.heap[id];

        for arg_expr_id in call_expr.arguments.clone() {

            self.visit_expr(ctx, arg_expr_id)?;

        }

        self.progress_call_expr(ctx, id)

    }

    fn visit_variable_expr(&mut self, ctx: &mut Ctx, id: VariableExpressionId) -> VisitorResult {

        let upcast_id = id.upcast();

        self.insert_initial_expr_inference_type(ctx, upcast_id)?;

        let var_expr = &ctx.heap[id];

        debug_assert!(var_expr.declaration.is_some());

        let var_data = self.var_types.get_mut(var_expr.declaration.as_ref().unwrap()).unwrap();

        var_data.used_at.push(upcast_id);

        self.progress_variable_expr(ctx, id)

    }

}

macro_rules! debug_assert_expr_ids_unique_and_known {

    // Base case for a single expression ID

    ($resolver:ident, $id:ident) => {

        if cfg!(debug_assertions) {

            $resolver.expr_types.contains_key(&$id);

        }

    };

    // Base case for two expression IDs

    ($resolver:ident, $id1:ident, $id2:ident) => {

        debug_assert_ne!($id1, $id2);

        debug_assert_expr_ids_unique_and_known!($resolver, $id1);

        debug_assert_expr_ids_unique_and_known!($resolver, $id2);

    };

    // Generic case

    ($resolver:ident, $id1:ident, $id2:ident, $($tail:ident),+) => {

        debug_assert_ne!($id1, $id2);

        debug_assert_expr_ids_unique_and_known!($resolver, $id1);

        debug_assert_expr_ids_unique_and_known!($resolver, $id2, $($tail),+);

    };

}

macro_rules! debug_assert_ptrs_distinct {

    // Base case

    ($ptr1:ident, $ptr2:ident) => {

        debug_assert!(!std::ptr::eq($ptr1, $ptr2));

    };

    // Generic case

    ($ptr1:ident, $ptr2:ident, $($tail:ident),+) => {

        debug_assert_ptrs_distinct!($ptr1, $ptr2);

        debug_assert_ptrs_distinct!($ptr2, $($tail),+);

    };

}

impl TypeResolvingVisitor {

    fn resolve_types(&mut self, ctx: &mut Ctx, queue: &mut ResolveQueue) -> Result<(), ParseError> {

        // Keep inferring until we can no longer make any progress

        while let Some(next_expr_id) = self.expr_queued.iter().next() {

            let next_expr_id = *next_expr_id;

            self.expr_queued.remove(&next_expr_id);

            self.progress_expr(ctx, next_expr_id)?;

        }

        // We check if we have all the types we need. If we're typechecking a 

        // polymorphic procedure more than once, then we have already annotated

        // the AST and have now performed typechecking for a different 

        // monomorph. In that case we just need to perform typechecking, no need

        // to annotate the AST again.

        let definition_id = match &self.definition_type {

            DefinitionType::Component(id) => id.upcast(),

            DefinitionType::Function(id) => id.upcast(),

            _ => unreachable!(),

        };

        let already_checked = ctx.types.get_base_definition(&definition_id).unwrap().has_any_monomorph();

        for (expr_id, expr_type) in self.expr_types.iter_mut() {

            if !expr_type.is_done {

                // Auto-infer numberlike/integerlike types to a regular int

                if expr_type.parts.len() == 1 && expr_type.parts[0] == InferenceTypePart::IntegerLike {

                    expr_type.parts[0] = InferenceTypePart::Int;

                } else {

                    let expr = &ctx.heap[*expr_id];

                    return Err(ParseError::new_error(

                        &ctx.module.source, expr.position(),

                }

                debug_log!("   - Field poly progress | {:?}", poly_progress);

                // Same for the type of the struct itself

                let signature_type: *mut _ = &mut extra.returned;

                let expr_type: *mut _ = self.expr_types.get_mut(&upcast_id).unwrap();

                let (_, progress_expr) = Self::apply_equal2_signature_constraint(

                    ctx, upcast_id, None, extra, &mut poly_progress,

                    signature_type, 0, expr_type, 0

                )?;

                debug_log!(

                    "   - Ret type | sig: {}, expr: {}",

                    unsafe{&*signature_type}.display_name(&ctx.heap),

                    unsafe{&*expr_type}.display_name(&ctx.heap)

                );

                debug_log!("   - Ret poly progress | {:?}", poly_progress);

                if progress_expr {

                    // TODO: @cleanup, cannot call utility self.queue_parent thingo

                    if let Some(parent_id) = ctx.heap[upcast_id].parent_expr_id() {

                        self.expr_queued.insert(parent_id);

                    }

                }

                // Check which expressions use the polymorphic arguments. If the

                // polymorphic variables have been progressed then we try to 

                // progress them inside the expression as well.

                debug_log!(" * During (reinferring from progressed polyvars):");

                // For all field expressions

                for field_idx in 0..extra.embedded.len() {

                    debug_assert_eq!(field_idx, data.fields[field_idx].field_idx, "confusing, innit?");

                    let signature_type: *mut _ = &mut extra.embedded[field_idx];

                    let field_expr_id = data.fields[field_idx].value;

                    let field_type: *mut _ = self.expr_types.get_mut(&field_expr_id).unwrap();

                    let progress_arg = Self::apply_equal2_polyvar_constraint(&ctx.heap,

                        extra, &poly_progress, signature_type, field_type

                    );

                    debug_log!(

                        "   - Field {} type | sig: {}, field: {}", field_idx,

                        unsafe{&*signature_type}.display_name(&ctx.heap),

                        unsafe{&*field_type}.display_name(&ctx.heap)

                    );

                    if progress_arg {

                        self.expr_queued.insert(field_expr_id);

                    }

                }

                // For the return type

                let signature_type: *mut _ = &mut extra.returned;

                let expr_type: *mut _ = self.expr_types.get_mut(&upcast_id).unwrap();

                let progress_expr = Self::apply_equal2_polyvar_constraint(

                    &ctx.heap, extra, &poly_progress, signature_type, expr_type

                );

                progress_expr

            },

            Literal::Enum(_) => {

                let extra = self.extra_data.get_mut(&upcast_id).unwrap();

                for poly in &extra.poly_vars {

                    debug_log!(" * Poly: {}", poly.display_name(&ctx.heap));

                }

                let mut poly_progress = HashSet::new();

                debug_log!(" * During (inferring types from return type)");

                let signature_type: *mut _ = &mut extra.returned;

                let expr_type: *mut _ = self.expr_types.get_mut(&upcast_id).unwrap();

                let (_, progress_expr) = Self::apply_equal2_signature_constraint(

                    ctx, upcast_id, None, extra, &mut poly_progress,

                    signature_type, 0, expr_type, 0

                )?;

                debug_log!(

                    "   - Ret type | sig: {}, expr: {}",

                    unsafe{&*signature_type}.display_name(&ctx.heap),

                    unsafe{&*expr_type}.display_name(&ctx.heap)

                );

                if progress_expr {

                    // TODO: @cleanup

                    if let Some(parent_id) = ctx.heap[upcast_id].parent_expr_id() {

                        self.expr_queued.insert(parent_id);

                    }

                }

                debug_log!(" * During (reinferring from progress polyvars):");

                let progress_expr = Self::apply_equal2_polyvar_constraint(

                    &ctx.heap, extra, &poly_progress, signature_type, expr_type

                );

                progress_expr

            }

        };

        debug_log!(" * After:");

        debug_log!("   - Expr type: {}", self.expr_types.get(&upcast_id).unwrap().display_name(&ctx.heap));

        // TODO: FIX!!!!

        if progress_expr { self.queue_expr_parent(ctx, upcast_id); }

        Ok(())

    }

    // TODO: @cleanup, see how this can be cleaned up once I implement

    //  polymorphic struct/enum/union literals. These likely follow the same

    //  pattern as here.

    fn progress_call_expr(&mut self, ctx: &mut Ctx, id: CallExpressionId) -> Result<(), ParseError> {

        let upcast_id = id.upcast();

        let expr = &ctx.heap[id];

        let extra = self.extra_data.get_mut(&upcast_id).unwrap();

        debug_log!("Call expr '{}': {}", match &expr.method {

            Method::Create => String::from("create"),

            Method::Fires => String::from("fires"),

            Method::Get => String::from("get"),

            Method::Put => String::from("put"),

            Method::Symbolic(method) => String::from_utf8_lossy(&method.identifier.value).to_string()

        },upcast_id.index);

        debug_log!(" * Before:");

        debug_log!("   - Expr type: {}", self.expr_types.get(&upcast_id).unwrap().display_name(&ctx.heap));

        debug_log!(" * During (inferring types from arguments and return type):");

        // Check if we can make progress using the arguments and/or return types

        // while keeping track of the polyvars we've extended

        let mut poly_progress = HashSet::new();

        debug_assert_eq!(extra.embedded.len(), expr.arguments.len());

        for (arg_idx, arg_id) in expr.arguments.clone().into_iter().enumerate() {

            let signature_type: *mut _ = &mut extra.embedded[arg_idx];

            let argument_type: *mut _ = self.expr_types.get_mut(&arg_id).unwrap();

            let (_, progress_arg) = Self::apply_equal2_signature_constraint(

                ctx, upcast_id, Some(arg_id), extra, &mut poly_progress,

                signature_type, 0, argument_type, 0

            )?;

            debug_log!(

                "   - Arg {} type | sig: {}, arg: {}", arg_idx,

                unsafe{&*signature_type}.display_name(&ctx.heap), 

                unsafe{&*argument_type}.display_name(&ctx.heap));

            if progress_arg {

                // Progressed argument expression

                self.expr_queued.insert(arg_id);

            }

        }

        // Do the same for the return type

        let signature_type: *mut _ = &mut extra.returned;

        let expr_type: *mut _ = self.expr_types.get_mut(&upcast_id).unwrap();

        let (_, progress_expr) = Self::apply_equal2_signature_constraint(

            ctx, upcast_id, None, extra, &mut poly_progress,

            signature_type, 0, expr_type, 0

        )?;

        debug_log!(

            "   - Ret type | sig: {}, expr: {}", 

            unsafe{&*signature_type}.display_name(&ctx.heap), 

            unsafe{&*expr_type}.display_name(&ctx.heap)

        );

        if progress_expr {

            // TODO: @cleanup, cannot call utility self.queue_parent thingo

            if let Some(parent_id) = ctx.heap[upcast_id].parent_expr_id() {

                self.expr_queued.insert(parent_id);

            }

        }

        // If we did not have an error in the polymorph inference above, then

        // reapplying the polymorph type to each argument type and the return

        // type should always succeed.

        debug_log!(" * During (reinferring from progressed polyvars):");

        for (poly_idx, poly_var) in extra.poly_vars.iter().enumerate() {

            debug_log!("   - Poly {} | sig: {}", poly_idx, poly_var.display_name(&ctx.heap));

        }

        // TODO: @performance If the algorithm is changed to be more "on demand

        //  argument re-evaluation", instead of "all-argument re-evaluation",

        //  then this is no longer true

        for arg_idx in 0..extra.embedded.len() {

            let signature_type: *mut _ = &mut extra.embedded[arg_idx];

            let arg_expr_id = expr.arguments[arg_idx];

            let arg_type: *mut _ = self.expr_types.get_mut(&arg_expr_id).unwrap();

            let progress_arg = Self::apply_equal2_polyvar_constraint(&ctx.heap,

                extra, &poly_progress,

                signature_type, arg_type

            );

                let definition = &ctx.heap[symbolic.definition.unwrap()];

                match definition {

                    Definition::Component(definition) => {

                        debug_assert_eq!(poly_vars.len(), definition.poly_vars.len());

                        let mut parameter_types = Vec::with_capacity(definition.parameters.len());

                        for param_id in definition.parameters.clone() {

                            let param = &ctx.heap[param_id];

                            let param_parser_type_id = param.parser_type;

                            parameter_types.push(self.determine_inference_type_from_parser_type(ctx, param_parser_type_id, false));

                        }

                        (parameter_types, InferenceType::new(false, true, vec![InferenceTypePart::Void]))

                    },

                    Definition::Function(definition) => {

                        debug_assert_eq!(poly_vars.len(), definition.poly_vars.len());

                        let mut parameter_types = Vec::with_capacity(definition.parameters.len());

                        for param_id in definition.parameters.clone() {

                            let param = &ctx.heap[param_id];

                            let param_parser_type_id = param.parser_type;

                            parameter_types.push(self.determine_inference_type_from_parser_type(ctx, param_parser_type_id, false));

                        }

                        let return_type = self.determine_inference_type_from_parser_type(ctx, definition.return_type, false);

                        (parameter_types, return_type)

                    },

                    Definition::Struct(_) | Definition::Enum(_) | Definition::Union(_) => {

                        unreachable!("insert initial polymorph data for struct/enum/union");

                    }

                }

            }

        };

        self.extra_data.insert(call_id.upcast(), ExtraData {

            poly_vars,

            embedded: embedded_types,

            returned: return_type

        });

    }

    fn insert_initial_struct_polymorph_data(

        &mut self, ctx: &mut Ctx, lit_id: LiteralExpressionId,

    ) {

        use InferenceTypePart as ITP;

        let literal = ctx.heap[lit_id].value.as_struct();

        // Handle polymorphic arguments

        let mut poly_vars = Vec::with_capacity(literal.poly_args2.len());

        let mut total_num_poly_parts = 0;

        for poly_arg_type_id in literal.poly_args2.clone() { // TODO: @performance

            let inference_type = self.determine_inference_type_from_parser_type(

                ctx, poly_arg_type_id, true

            ); 

            total_num_poly_parts += inference_type.parts.len();

            poly_vars.push(inference_type);

        }

        // Handle parser types on struct definition

        let definition = &ctx.heap[literal.definition.unwrap()];

        let definition = match definition {

            Definition::Struct(definition) => {

                debug_assert_eq!(poly_vars.len(), definition.poly_vars.len());

                definition

            },

            _ => unreachable!("definition for struct literal does not point to struct definition")

        };

        // Note: programmer is capable of specifying fields in a struct literal

        // in a different order than on the definition. We take the literal-

        // specified order to be leading.

        let mut embedded_types = Vec::with_capacity(definition.fields.len());

        for lit_field in literal.fields.iter() {

            let def_field = &definition.fields[lit_field.field_idx];

            let inference_type = self.determine_inference_type_from_parser_type(

                ctx, def_field.parser_type, false

            );

            embedded_types.push(inference_type);

        }

        // Return type is the struct type itself, with the appropriate 

        // polymorphic variables. So:

        // - 1 part for definition

        // - N_poly_arg marker parts for each polymorphic argument

        // - all the parts for the currently known polymorphic arguments 

        let parts_reserved = 1 + poly_vars.len() + total_num_poly_parts;

        let mut parts = Vec::with_capacity(parts_reserved);

        parts.push(ITP::Instance(definition.this.upcast(), poly_vars.len()));

        let mut return_type_done = true;

        for (poly_var_idx, poly_var) in poly_vars.iter().enumerate() {

            if !poly_var.is_done { return_type_done = false; }

            parts.push(ITP::MarkerBody(poly_var_idx));

            parts.extend(poly_var.parts.iter().cloned());

        }

        debug_assert_eq!(parts.len(), parts_reserved);

        self.extra_data.insert(lit_id.upcast(), ExtraData{

            poly_vars, 

            embedded: embedded_types,

            returned: return_type,

        });

    }

    /// Inserts the extra polymorphic data struct for enum expressions. These

    fn insert_initial_enum_polymorph_data(

        &mut self, ctx: &Ctx, lit_id: LiteralExpressionId

    ) {

        use InferenceTypePart as ITP;

        let literal = ctx.heap[lit_id].value.as_enum();

        // Handle polymorphic arguments to the enum

        let mut poly_vars = Vec::with_capacity(literal.poly_args2.len());

        let mut total_num_poly_parts = 0;

        for poly_arg_type_id in literal.poly_args2.clone() { // TODO: @performance

            let inference_type = self.determine_inference_type_from_parser_type(

                ctx, poly_arg_type_id, true

            );

            total_num_poly_parts += inference_type.parts.len();

            poly_vars.push(inference_type);

        }

        // Handle enum type itself

        let parts_reserved = 1 + poly_vars.len() + total_num_poly_parts;

        let mut parts = Vec::with_capacity(parts_reserved);

        parts.push(ITP::Instance(literal.definition.unwrap(), poly_vars.len()));

        let mut enum_type_done = true;

        for (poly_var_idx, poly_var) in poly_vars.iter().enumerate() {

            if !poly_var.is_done { enum_type_done = false; }

            parts.push(ITP::MarkerBody(poly_var_idx));

            parts.extend(poly_var.parts.iter().cloned());

        }

        debug_assert_eq!(parts.len(), parts_reserved);

        self.extra_data.insert(lit_id.upcast(), ExtraData{

            poly_vars,

            embedded: Vec::new(),

            returned: enum_type,

        });

    }