use super::{estimate_complexity, Extractor};
use crate::models::FunctionInfo;
use tree_sitter::Node;
pub struct RubyExtractor;
impl Extractor for RubyExtractor {
fn extract(&self, content: &str) -> Vec<FunctionInfo> {
super::with_parsed_tree(tree_sitter_ruby::LANGUAGE.into(), content, |tree| {
let lines: Vec<&str> = content.lines().collect();
let mut functions = Vec::new();
traverse(tree.root_node(), content, &lines, &mut functions, false);
functions.retain(|f| f.name != "?");
functions.sort_by_key(|f| f.line_start);
functions
})
.unwrap_or_default()
}
}
fn traverse(
node: Node,
content: &str,
lines: &[&str],
functions: &mut Vec<FunctionInfo>,
in_class: bool,
) {
let kind = node.kind();
if kind == "method" || kind == "singleton_method" {
if let Some(info) =
parse_method(node, content, lines, in_class || kind == "singleton_method")
{
functions.push(info);
}
} else if (kind == "class" || kind == "module")
&& let Some(info) = parse_class(node, content, lines)
{
functions.push(info);
}
let is_class_body = kind == "class" || kind == "module";
let mut cursor = node.walk();
for child in node.children(&mut cursor) {
traverse(child, content, lines, functions, in_class || is_class_body);
}
}
fn parse_method(
node: Node,
content: &str,
lines: &[&str],
is_method: bool,
) -> Option<FunctionInfo> {
let mut name = String::new();
let mut params_str = String::new();
if let Some(name_node) = node.child_by_field_name("name") {
name = name_node.utf8_text(content.as_bytes()).unwrap_or("").to_string();
}
if let Some(params_node) = node.child_by_field_name("parameters") {
params_str = params_node.utf8_text(content.as_bytes()).unwrap_or("").to_string();
}
if name.is_empty() || name == "?" || name == "?obj" {
return None;
}
let start_line = node.start_position().row + 1;
let end_line = node.end_position().row + 1;
let block = &lines[start_line.saturating_sub(1)..end_line.min(lines.len())];
let complexity = estimate_complexity(block);
let mut parameters = Vec::new();
let trimmed_params = params_str.trim_start_matches('(').trim_end_matches(')');
if !trimmed_params.is_empty() {
for p in trimmed_params.split(',') {
let p_trim = p.trim();
if !p_trim.is_empty() {
parameters.push(p_trim.to_string());
}
}
}
Some(FunctionInfo {
name,
line_start: start_line,
line_end: end_line,
parameters,
is_async: false,
is_method,
is_class: false,
docstring: None,
decorators: vec![],
complexity,
})
}
fn parse_class(node: Node, content: &str, _lines: &[&str]) -> Option<FunctionInfo> {
let mut name = String::new();
if let Some(name_node) = node.child_by_field_name("name") {
name = name_node.utf8_text(content.as_bytes()).unwrap_or("").to_string();
}
if name.is_empty() {
name = "?".to_string();
}
let start_line = node.start_position().row + 1;
let end_line = node.end_position().row + 1;
Some(FunctionInfo {
name,
line_start: start_line,
line_end: end_line,
parameters: vec![],
is_async: false,
is_method: false,
is_class: true,
docstring: None,
decorators: vec![],
complexity: 1,
})
}
#[cfg(test)]
mod tests {
use super::*;
#[test]
fn test_extract_ruby_functions() {
let content = r#"
module Utils
def self.log(msg)
puts msg
end
end
class User
def initialize(name)
@name = name
end
def name
@name
end
end
"#;
let extractor = RubyExtractor;
let mut fns = extractor.extract(content);
fns.sort_by(|a, b| a.name.cmp(&b.name));
assert_eq!(fns.len(), 5);
let u = fns.iter().find(|f| f.name == "Utils").unwrap();
assert!(u.is_class);
let log = fns.iter().find(|f| f.name == "log").unwrap();
assert!(log.is_method);
assert_eq!(log.parameters, vec!["msg"]);
let user = fns.iter().find(|f| f.name == "User").unwrap();
assert!(user.is_class);
let init = fns.iter().find(|f| f.name == "initialize").unwrap();
assert!(init.is_method);
}
}