}

    // TODO: @cleanup

    pub fn parent(&self) -> &ExpressionParent {

        match self {

            Expression::Assignment(expr) => &expr.parent,

            Expression::Binding(expr) => &expr.parent,

            Expression::Conditional(expr) => &expr.parent,

            Expression::Binary(expr) => &expr.parent,

            Expression::Unary(expr) => &expr.parent,

            Expression::Indexing(expr) => &expr.parent,

            Expression::Slicing(expr) => &expr.parent,

            Expression::Select(expr) => &expr.parent,

            Expression::Literal(expr) => &expr.parent,

            Expression::Cast(expr) => &expr.parent,

            Expression::Call(expr) => &expr.parent,

            Expression::Variable(expr) => &expr.parent,

        }

    }

    // TODO: @cleanup

    pub fn parent_expr_id(&self) -> Option<ExpressionId> {

        if let ExpressionParent::Expression(id, _) = self.parent() {

            Some(*id)

        } else {

            None

        }

    }

    pub fn get_unique_id_in_definition(&self) -> i32 {

        match self {

            Expression::Assignment(expr) => expr.unique_id_in_definition,

            Expression::Binding(expr) => expr.unique_id_in_definition,

            Expression::Conditional(expr) => expr.unique_id_in_definition,

            Expression::Binary(expr) => expr.unique_id_in_definition,

            Expression::Unary(expr) => expr.unique_id_in_definition,

            Expression::Indexing(expr) => expr.unique_id_in_definition,

            Expression::Slicing(expr) => expr.unique_id_in_definition,

            Expression::Select(expr) => expr.unique_id_in_definition,

            Expression::Literal(expr) => expr.unique_id_in_definition,

            Expression::Cast(expr) => expr.unique_id_in_definition,

            Expression::Call(expr) => expr.unique_id_in_definition,

            Expression::Variable(expr) => expr.unique_id_in_definition,

        }

    }

}

#[derive(Debug, Clone, Copy)]

pub enum AssignmentOperator {

    Set,

    Multiplied,

    Divided,

    Remained,

    Added,

    Subtracted,

    ShiftedLeft,

    ShiftedRight,

    BitwiseAnded,

    BitwiseXored,

    BitwiseOred,

}

#[derive(Debug, Clone)]

pub struct AssignmentExpression {

    pub this: AssignmentExpressionId,

    // Parsing

    pub span: InputSpan, // of the operator

    pub left: ExpressionId,

    pub operation: AssignmentOperator,

    pub right: ExpressionId,

    // Validator/Linker

    pub parent: ExpressionParent,

    pub unique_id_in_definition: i32,

}

#[derive(Debug, Clone)]

pub struct BindingExpression {

    pub this: BindingExpressionId,

    // Parsing

    pub span: InputSpan, // of the binding keyword

    pub bound_to: ExpressionId,

    pub bound_from: ExpressionId,

    // Validator/Linker

    pub parent: ExpressionParent,

    pub unique_id_in_definition: i32,

}

#[derive(Debug, Clone)]

pub struct ConditionalExpression {

    pub this: ConditionalExpressionId,

    // Parsing

    pub span: InputSpan, // of question mark operator

    pub test: ExpressionId,

    pub true_expression: ExpressionId,

    pub false_expression: ExpressionId,

    // Validator/Linking

    pub parent: ExpressionParent,

    pub unique_id_in_definition: i32,

                                    }

                                    // 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 and reserve its stack size

                                    let new_frame = Frame::new(heap, expr.definition, call_data.field_or_monomorph_idx);

                                    let new_stack_size = new_frame.max_stack_size;

                                    self.frames.push(new_frame);

                                    self.store.cur_stack_boundary = new_stack_boundary;

                                    self.store.reserve_stack(new_stack_size);

                                    // 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()];

                            let ref_value = if expr.used_as_binding_target {

                                Value::Binding(variable.unique_id_in_scope as StackPos)

                            } else {

                                Value::Ref(ValueId::Stack(variable.unique_id_in_scope as StackPos))

                            };

                            cur_frame.expr_values.push_back(ref_value);

                        }

                    }

                }

            }

        }

        debug_log!("Frame [{:?}] at {:?}", cur_frame.definition, cur_frame.position);

        if debug_enabled!() {

            debug_log!("Expression value stack (size = {}):", cur_frame.expr_values.len());

            for (_stack_idx, _stack_val) in cur_frame.expr_values.iter().enumerate() {

                debug_log!("  [{:03}] {:?}", _stack_idx, _stack_val);

            }

            debug_log!("Stack (size = {}):", self.store.stack.len());

            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);

            }

        }

        // 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) => {

                debug_assert!(stmt.statements.is_empty() || stmt.next == stmt.statements[0]);

                cur_frame.position = stmt.next;

                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)

            },

            Statement::If(stmt) => {

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

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

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

                if test_value {

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

        } else {

            return value.clone();

        }

    }

    /// Transfers the heap values and the stack values into the store. Stack

    /// values are pushed onto the Store's stack in the order in which they

    /// appear in the value group.

    pub(crate) fn into_store(self, store: &mut Store) {

        for value in &self.values {

            let transferred = self.provide_value(value, store);

            store.stack.push(transferred);

        }

    }

    fn provide_value(&self, value: &Value, to_store: &mut Store) -> Value {

        if let Some(from_heap_pos) = value.get_heap_pos() {

            let from_heap_pos = from_heap_pos as usize;

            let to_heap_pos = to_store.alloc_heap();

            let to_heap_pos_usize = to_heap_pos as usize;

            to_store.heap_regions[to_heap_pos_usize].values.reserve(self.regions[from_heap_pos].len());

            for value in &self.regions[from_heap_pos as usize] {

                let transferred = self.provide_value(value, to_store);

                to_store.heap_regions[to_heap_pos_usize].values.push(transferred);

            }

            return match value {

                Value::Message(_)    => Value::Message(to_heap_pos),

                Value::String(_)     => Value::String(to_heap_pos),

                Value::Array(_)      => Value::Array(to_heap_pos),

                Value::Union(tag, _) => Value::Union(*tag, to_heap_pos),

                Value::Struct(_)     => Value::Struct(to_heap_pos),

                _ => unreachable!(),

            };

        } else {

            return value.clone();

        }

    }

}

impl Default for ValueGroup {

    /// Returns an empty ValueGroup

    fn default() -> Self {

        Self { values: Vec::new(), regions: Vec::new() }

    }

}

pub(crate) fn apply_assignment_operator(store: &mut Store, lhs: ValueId, op: AssignmentOperator, rhs: Value) {

    use AssignmentOperator as AO;

    macro_rules! apply_int_op {

        ($lhs:ident, $assignment_tokens:tt, $operator:ident, $rhs:ident) => {

            match $lhs {

                Value::UInt8(v)  => { *v $assignment_tokens $rhs.as_uint8();  },

                Value::UInt16(v) => { *v $assignment_tokens $rhs.as_uint16(); },

                Value::UInt32(v) => { *v $assignment_tokens $rhs.as_uint32(); },

                Value::UInt64(v) => { *v $assignment_tokens $rhs.as_uint64(); },

                Value::SInt8(v)  => { *v $assignment_tokens $rhs.as_sint8();  },

                Value::SInt16(v) => { *v $assignment_tokens $rhs.as_sint16(); },

                Value::SInt32(v) => { *v $assignment_tokens $rhs.as_sint32(); },

                Value::SInt64(v) => { *v $assignment_tokens $rhs.as_sint64(); },

                _ => unreachable!("apply_assignment_operator {:?} on lhs {:?} and rhs {:?}", $operator, $lhs, $rhs),

            }

        }

    }

    let lhs = store.read_mut_ref(lhs);

    let mut to_dealloc = None;

    match op {

        AO::Set => {

            match lhs {

                Value::Unassigned => { *lhs = rhs; },

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

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

                Value::Message(v)  => { to_dealloc = Some(*v); *v = rhs.as_message(); },

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

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

                Value::String(v) => { *v = rhs.as_string().clone(); },

                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(v) => { to_dealloc = Some(*v); *v = rhs.as_array(); },

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

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

                    to_dealloc = Some(*lhs_heap_pos);

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

                    *lhs_tag = rhs_tag;

                    *lhs_heap_pos = rhs_heap_pos;

                }

                Value::Struct(v) => { to_dealloc = Some(*v); *v = rhs.as_struct(); },

                _ => unreachable!("apply_assignment_operator {:?} on lhs {:?} and rhs {:?}", op, lhs, rhs),

            }

        },

        AO::Multiplied =>   { apply_int_op!(lhs, *=,  op, rhs) },

        AO::Divided =>      { apply_int_op!(lhs, /=,  op, rhs) },

        AO::Remained =>     { apply_int_op!(lhs, %=,  op, rhs) },

        AO::Added =>        { apply_int_op!(lhs, +=,  op, rhs) },

        AO::Subtracted =>   { apply_int_op!(lhs, -=,  op, rhs) },

        AO::ShiftedLeft =>  { apply_int_op!(lhs, <<=, op, rhs) },

        AO::ShiftedRight => { apply_int_op!(lhs, >>=, op, rhs) },

        AO::BitwiseAnded => { apply_int_op!(lhs, &=,  op, rhs) },

        AO::BitwiseXored => { apply_int_op!(lhs, ^=,  op, rhs) },

        AO::BitwiseOred =>  { apply_int_op!(lhs, |=,  op, rhs) },

    }

    if let Some(heap_pos) = to_dealloc {

        store.drop_heap_pos(heap_pos);

    }

}

pub(crate) fn apply_binary_operator(store: &mut Store, lhs: &Value, op: BinaryOperator, rhs: &Value) -> Value {

    use BinaryOperator as BO;

    macro_rules! apply_int_op_and_return_self {

        ($lhs:ident, $operator_tokens:tt, $operator:ident, $rhs:ident) => {

            return match $lhs {

                Value::UInt8(v)  => { Value::UInt8( *v $operator_tokens $rhs.as_uint8() ) },

                Value::UInt16(v) => { Value::UInt16(*v $operator_tokens $rhs.as_uint16()) },

                Value::UInt32(v) => { Value::UInt32(*v $operator_tokens $rhs.as_uint32()) },

                Value::UInt64(v) => { Value::UInt64(*v $operator_tokens $rhs.as_uint64()) },

                Value::SInt8(v)  => { Value::SInt8( *v $operator_tokens $rhs.as_sint8() ) },

                Value::SInt16(v) => { Value::SInt16(*v $operator_tokens $rhs.as_sint16()) },

                Value::SInt32(v) => { Value::SInt32(*v $operator_tokens $rhs.as_sint32()) },

                Value::SInt64(v) => { Value::SInt64(*v $operator_tokens $rhs.as_sint64()) },

                _ => unreachable!("apply_binary_operator {:?} on lhs {:?} and rhs {:?}", $operator, $lhs, $rhs)

            };

        }

    }

    macro_rules! apply_int_op_and_return_bool {

        ($lhs:ident, $operator_tokens:tt, $operator:ident, $rhs:ident) => {

            return match $lhs {

                Value::UInt8(v)  => { Value::Bool(*v $operator_tokens $rhs.as_uint8() ) },

                Value::UInt16(v) => { Value::Bool(*v $operator_tokens $rhs.as_uint16()) },

                Value::UInt32(v) => { Value::Bool(*v $operator_tokens $rhs.as_uint32()) },

                Value::UInt64(v) => { Value::Bool(*v $operator_tokens $rhs.as_uint64()) },

                Value::SInt8(v)  => { Value::Bool(*v $operator_tokens $rhs.as_sint8() ) },

                Value::SInt16(v) => { Value::Bool(*v $operator_tokens $rhs.as_sint16()) },

                Value::SInt32(v) => { Value::Bool(*v $operator_tokens $rhs.as_sint32()) },

                Value::SInt64(v) => { Value::Bool(*v $operator_tokens $rhs.as_sint64()) },

                _ => unreachable!("apply_binary_operator {:?} on lhs {:?} and rhs {:?}", $operator, $lhs, $rhs)

            };

        }

    }

    // We need to handle concatenate in a special way because it needs the store

    // mutably.

    if op == BO::Concatenate {

        let target_heap_pos = store.alloc_heap();

        let lhs_heap_pos;

        let rhs_heap_pos;

        let lhs = store.maybe_read_ref(lhs);

        let rhs = store.maybe_read_ref(rhs);

        let value_kind;

        match lhs {

            Value::Message(lhs_pos) => {

                lhs_heap_pos = *lhs_pos;

                rhs_heap_pos = rhs.as_message();

                value_kind = ValueKind::Message;

            },

            Value::String(lhs_pos) => {

                lhs_heap_pos = *lhs_pos;

                rhs_heap_pos = rhs.as_string();

                value_kind = ValueKind::String;

            },

            Value::Array(lhs_pos) => {

                lhs_heap_pos = *lhs_pos;

                rhs_heap_pos = rhs.as_array();

                value_kind = ValueKind::Array;

            },

            _ => unreachable!("apply_binary_operator {:?} on lhs {:?} and rhs {:?}", op, lhs, rhs)

        }

        let lhs_heap_pos = lhs_heap_pos as usize;

        let rhs_heap_pos = rhs_heap_pos as usize;

        // TODO: I hate this, but fine...

        let mut concatenated = Vec::new();

        let lhs_len = store.heap_regions[lhs_heap_pos].values.len();

        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);

        ));

        parser

    }

    pub fn feed(&mut self, mut source: InputSource) -> Result<(), ParseError> {

        // TODO: @Optimize

        let mut token_buffer = TokenBuffer::new();

        self.pass_tokenizer.tokenize(&mut source, &mut token_buffer)?;

        let module = Module{

            source,

            tokens: token_buffer,

            root_id: RootId::new_invalid(),

            name: None,

            version: None,

            phase: ModuleCompilationPhase::Tokenized,

        };

        self.modules.push(module);

        Ok(())

    }

    pub fn parse(&mut self) -> Result<(), ParseError> {

        let mut pass_ctx = PassCtx{

            heap: &mut self.heap,

            symbols: &mut self.symbol_table,

            pool: &mut self.string_pool,

        };

        // Advance all modules to the phase where all symbols are scanned

        for module_idx in 0..self.modules.len() {

            self.pass_symbols.parse(&mut self.modules, module_idx, &mut pass_ctx)?;

        }

        // With all symbols scanned, perform further compilation until we can

        // add all base types to the type table.

        for module_idx in 0..self.modules.len() {

            self.pass_import.parse(&mut self.modules, module_idx, &mut pass_ctx)?;

            self.pass_definitions.parse(&mut self.modules, module_idx, &mut pass_ctx)?;

        }

        // Add every known type to the type table

        self.type_table.build_base_types(&mut self.modules, &mut pass_ctx)?;

        // Continue compilation with the remaining phases now that the types

        // are all in the type table

        for module_idx in 0..self.modules.len() {

            let mut ctx = visitor::Ctx{

                heap: &mut self.heap,

                module: &mut self.modules[module_idx],

                symbols: &mut self.symbol_table,

                types: &mut self.type_table,

            };

            self.pass_validation.visit_module(&mut ctx)?;

        }

        // Perform typechecking on all modules

        let mut queue = ResolveQueue::new();

        for module in &mut self.modules {

            let mut ctx = visitor::Ctx{

                heap: &mut self.heap,

                module,

                symbols: &mut self.symbol_table,

                types: &mut self.type_table,

            };

            PassTyping::queue_module_definitions(&mut ctx, &mut queue);

        };

        while !queue.is_empty() {

            let top = queue.pop().unwrap();

            let mut ctx = visitor::Ctx{

                heap: &mut self.heap,

                module: &mut self.modules[top.root_id.index as usize],

                symbols: &mut self.symbol_table,

                types: &mut self.type_table,

            };

            self.pass_typing.handle_module_definition(&mut ctx, &mut queue, top)?;

        }

        // Write out desired information

        if let Some(filename) = &self.write_ast_to {

            let mut writer = ASTWriter::new();

            let mut file = std::fs::File::create(std::path::Path::new(filename)).unwrap();

            writer.write_ast(&mut file, &self.heap);

        }

        Ok(())

    }

}

// Note: args and return type need to be a function because we need to know the function ID.

fn insert_builtin_function<T: Fn(FunctionDefinitionId) -> (Vec<(&'static str, ParserType)>, ParserType)> (

    p: &mut Parser, func_name: &str, polymorphic: &[&str], arg_and_return_fn: T) {

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

    for poly_var in polymorphic {

        // If here then one of the preconditions for a memory statement was not

        // met. So recover the iterator and return

        iter.load(iter_state);

        Ok(None)

    }

    fn consume_expression_statement(

        &mut self, module: &Module, iter: &mut TokenIter, ctx: &mut PassCtx

    ) -> Result<ExpressionStatementId, ParseError> {

        let start_pos = iter.last_valid_pos();

        let expression = self.consume_expression(module, iter, ctx)?;

        let end_pos = iter.last_valid_pos();

        consume_token(&module.source, iter, TokenKind::SemiColon)?;

        Ok(ctx.heap.alloc_expression_statement(|this| ExpressionStatement{

            this,

            span: InputSpan::from_positions(start_pos, end_pos),

            expression,

            next: StatementId::new_invalid(),

        }))

    }

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

    // Expression Parsing

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

    // TODO: @Cleanup This is fine for now. But I prefer my stacktraces not to

    //  look like enterprise Java code...

    fn consume_expression(

        &mut self, module: &Module, iter: &mut TokenIter, ctx: &mut PassCtx

    ) -> Result<ExpressionId, ParseError> {

        self.consume_assignment_expression(module, iter, ctx)

    }

    fn consume_assignment_expression(

        &mut self, module: &Module, iter: &mut TokenIter, ctx: &mut PassCtx

    ) -> Result<ExpressionId, ParseError> {

        // Utility to convert token into assignment operator

        fn parse_assignment_operator(token: Option<TokenKind>) -> Option<AssignmentOperator> {

            use TokenKind as TK;

            use AssignmentOperator as AO;

            if token.is_none() {

                return None

            }

            match token.unwrap() {

                TK::Equal               => Some(AO::Set),

                TK::StarEquals          => Some(AO::Multiplied),

                TK::SlashEquals         => Some(AO::Divided),

                TK::PercentEquals       => Some(AO::Remained),

                TK::PlusEquals          => Some(AO::Added),

                TK::MinusEquals         => Some(AO::Subtracted),

                TK::ShiftLeftEquals     => Some(AO::ShiftedLeft),

                TK::ShiftRightEquals    => Some(AO::ShiftedRight),

                TK::AndEquals           => Some(AO::BitwiseAnded),

                TK::CaretEquals         => Some(AO::BitwiseXored),

                TK::OrEquals            => Some(AO::BitwiseOred),

                _                       => None

            }

        }

        let expr = self.consume_conditional_expression(module, iter, ctx)?;

        if let Some(operation) = parse_assignment_operator(iter.next()) {

            let span = iter.next_span();

            iter.consume();

            let left = expr;

            let right = self.consume_expression(module, iter, ctx)?;

            Ok(ctx.heap.alloc_assignment_expression(|this| AssignmentExpression{

                this, span, left, operation, right,

                parent: ExpressionParent::None,

                unique_id_in_definition: -1,

            }).upcast())

        } else {

            Ok(expr)

        }

    }

    fn consume_conditional_expression(

        &mut self, module: &Module, iter: &mut TokenIter, ctx: &mut PassCtx

    ) -> Result<ExpressionId, ParseError> {

        let result = self.consume_concat_expression(module, iter, ctx)?;

        if let Some(TokenKind::Question) = iter.next() {

            let span = iter.next_span();

            iter.consume();

            let test = result;

            let true_expression = self.consume_expression(module, iter, ctx)?;

            consume_token(&module.source, iter, TokenKind::Colon)?;

            let false_expression = self.consume_expression(module, iter, ctx)?;

            Ok(ctx.heap.alloc_conditional_expression(|this| ConditionalExpression{

                this, span, test, true_expression, false_expression,

                parent: ExpressionParent::None,

                unique_id_in_definition: -1,

            token_kind = TokenKind::SemiColon;

        } else if first_char == b'<' {

            source.consume();

            let next = source.next();

            if let Some(b'<') = next {

                source.consume();

                if let Some(b'=') = source.next() {

                    source.consume();

                    token_kind = TokenKind::ShiftLeftEquals;

                } else {

                    token_kind = TokenKind::ShiftLeft;

                }

            } else if let Some(b'=') = next {

                source.consume();

                token_kind = TokenKind::LessEquals;

            } else {

                token_kind = TokenKind::OpenAngle;

            }

        } else if first_char == b'=' {

            source.consume();

            if let Some(b'=') = source.next() {

                source.consume();

                token_kind = TokenKind::EqualEqual;

            } else {

                token_kind = TokenKind::Equal;

            }

        } else if first_char == b'>' {

            source.consume();

            let next = source.next();

            if Some(b'>') == next {

                source.consume();

                if Some(b'=') == source.next() {

                    source.consume();

                    token_kind = TokenKind::ShiftRightEquals;

                } else {

                    token_kind = TokenKind::ShiftRight;

                }

            } else if Some(b'=') == next {

                source.consume();

                token_kind = TokenKind::GreaterEquals;

            } else {

                token_kind = TokenKind::CloseAngle;

            }

        } else if first_char == b'?' {

            source.consume();

            token_kind = TokenKind::Question;

        } else if first_char == b'@' {

            source.consume();

        } else if first_char == b'[' {

            source.consume();

            token_kind = TokenKind::OpenSquare;

        } else if first_char == b']' {

            source.consume();

            token_kind = TokenKind::CloseSquare;

        } else if first_char == b'^' {

            source.consume();

            if let Some(b'=') = source.next() {

                source.consume();

                token_kind = TokenKind::CaretEquals;

            } else {

                token_kind = TokenKind::Caret;

            }

        } else if first_char == b'{' {

            source.consume();

            token_kind = TokenKind::OpenCurly;

        } else if first_char == b'|' {

            source.consume();

            let next = source.next();

            if Some(b'|') == next {

                source.consume();

                token_kind = TokenKind::OrOr;

            } else if Some(b'=') == next {

                source.consume();

                token_kind = TokenKind::OrEquals;

            } else {

                token_kind = TokenKind::Or;

            }

        } else if first_char == b'}' {

            source.consume();

            token_kind = TokenKind::CloseCurly;

        } else if first_char == b'~' {

            source.consume();

            token_kind = TokenKind::Tilde;

        } else {

            self.check_ascii(source)?;

            return Ok(None);

        }

        target.tokens.push(Token::new(token_kind, pos));

        Ok(Some((token_kind, pos)))

    }

    fn consume_char_literal(&mut self, source: &mut InputSource, target: &mut TokenBuffer) -> Result<(), ParseError> {

        let begin_pos = source.pos();

        // Consume the leading quote

                let id = expr.this;

                self.progress_slicing_expr(ctx, id)

            },

            Expression::Select(expr) => {

                let id = expr.this;

                self.progress_select_expr(ctx, id)

            },

            Expression::Literal(expr) => {

                let id = expr.this;

                self.progress_literal_expr(ctx, id)

            },

            Expression::Cast(expr) => {

                let id = expr.this;

                self.progress_cast_expr(ctx, id)

            },

            Expression::Call(expr) => {

                let id = expr.this;

                self.progress_call_expr(ctx, id)

            },

            Expression::Variable(expr) => {

                let id = expr.this;

                self.progress_variable_expr(ctx, id)

            }

        }

    }

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

        use AssignmentOperator as AO;

        let upcast_id = id.upcast();

        let expr = &ctx.heap[id];

        let arg1_expr_id = expr.left;

        let arg2_expr_id = expr.right;

        debug_log!("Assignment expr '{:?}': {}", expr.operation, upcast_id.index);

        debug_log!(" * Before:");

        debug_log!("   - Arg1 type: {}", self.debug_get_display_name(ctx, arg1_expr_id));

        debug_log!("   - Arg2 type: {}", self.debug_get_display_name(ctx, arg2_expr_id));

        debug_log!("   - Expr type: {}", self.debug_get_display_name(ctx, upcast_id));

        // Assignment does not return anything (it operates like a statement)

        let progress_expr = self.apply_forced_constraint(ctx, upcast_id, &VOID_TEMPLATE)?;

        // Apply forced constraint to LHS value

        let progress_forced = match expr.operation {

            AO::Set =>

                false,

            AO::Multiplied | AO::Divided | AO::Added | AO::Subtracted =>

                self.apply_template_constraint(ctx, arg1_expr_id, &NUMBERLIKE_TEMPLATE)?,

            AO::Remained | AO::ShiftedLeft | AO::ShiftedRight |

            AO::BitwiseAnded | AO::BitwiseXored | AO::BitwiseOred =>

                self.apply_template_constraint(ctx, arg1_expr_id, &INTEGERLIKE_TEMPLATE)?,

        };

        let (progress_arg1, progress_arg2) = self.apply_equal2_constraint(

            ctx, upcast_id, arg1_expr_id, 0, arg2_expr_id, 0

        )?;

        debug_log!(" * After:");

        debug_log!("   - Arg1 type [{}]: {}", progress_forced || progress_arg1, self.debug_get_display_name(ctx, arg1_expr_id));

        debug_log!("   - Arg2 type [{}]: {}", progress_arg2, self.debug_get_display_name(ctx, arg2_expr_id));

        debug_log!("   - Expr type [{}]: {}", progress_expr, self.debug_get_display_name(ctx, upcast_id));

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

        if progress_forced || progress_arg1 { self.queue_expr(ctx, arg1_expr_id); }

        if progress_arg2 { self.queue_expr(ctx, arg2_expr_id); }

        Ok(())

    }

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

        let upcast_id = id.upcast();

        let binding_expr = &ctx.heap[id];

        let bound_from_id = binding_expr.bound_from;

        let bound_to_id = binding_expr.bound_to;

        // Output is always a boolean. The two arguments should be of equal

        // type.

        let progress_expr = self.apply_forced_constraint(ctx, upcast_id, &BOOL_TEMPLATE)?;

        let (progress_from, progress_to) = self.apply_equal2_constraint(ctx, upcast_id, bound_from_id, 0, bound_to_id, 0)?;

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

        if progress_from { self.queue_expr(ctx, bound_from_id); }

        if progress_to { self.queue_expr(ctx, bound_to_id); }

        Ok(())

    }

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

        // Note: test expression type is already enforced

        let upcast_id = id.upcast();

        let expr = &ctx.heap[id];

        let arg1_expr_id = expr.true_expression;

        let arg2_expr_id = expr.false_expression;

        debug_log!("Conditional expr: {}", upcast_id.index);

        debug_log!(" * Before:");

        debug_log!("   - Arg1 type: {}", self.debug_get_display_name(ctx, arg1_expr_id));

        debug_log!("   - Arg2 type: {}", self.debug_get_display_name(ctx, arg2_expr_id));

        debug_log!("   - Expr type: {}", self.debug_get_display_name(ctx, upcast_id));

        // I keep confusing myself: this applies equality of types between the

        // condition branches' types, and the result from the conditional

        // expression, because the result from the conditional is one of the

};

/// Represents a particular kind of token. Some tokens represent

/// variable-character tokens. Such a token is always followed by a

/// `TokenKind::SpanEnd` token.