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use crate::nodes::InnerNode;
use crate::nodes::InspectVec;
use crate::source::Range;
use crate::Node;
/// Represents opening a singleton class (i.e. `class << foo; ... end;`)
#[derive(Debug, Clone, PartialEq)]
pub struct SClass {
    /// Expression that is used to get a singleton class
    ///
    /// `Lvar("foo")` for `class << foo; end`
    pub expr: Box<Node>,
    /// Body of the block
    pub body: Option<Box<Node>>,
    /// Location of the `class` keyword
    ///
    /// ```text
    /// class << foo; end
    /// ~~~~~
    /// ```
    pub keyword_l: Range,
    /// Location of the `<<` operator
    ///
    /// ```text
    /// class << foo; end
    ///       ~~
    /// ```
    pub operator_l: Range,
    /// Location of the `end` keyword
    ///
    /// ```text
    /// class << foo; end
    ///               ~~~
    /// ```
    pub end_l: Range,
    /// Location of the full expression
    ///
    /// ```text
    /// class << foo; end
    /// ~~~~~~~~~~~~~~~~~
    /// ```
    pub expression_l: Range,
}


impl InnerNode for SClass {
    fn expression(&self) -> &Range {
        &self.expression_l
    }

    fn inspected_children(&self, indent: usize) -> Vec<String> {
        let mut result = InspectVec::new(indent);
        result.push_node(&self.expr);
        result.push_maybe_node_or_nil(&self.body);
        result.strings()
    }

    fn str_type(&self) -> &'static str {
        "sclass"
    }

    fn print_with_locs(&self) {
        println!("{}", self.inspect(0));
        self.expression_l.print("expression");
        self.end_l.print("end");
        self.operator_l.print("operator");
        self.keyword_l.print("keyword");
        if let Some(node) = &self.body {
            node.inner().print_with_locs();
        }
        self.expr.inner().print_with_locs();
    }
}