use super::TypeScriptParser;
use crate::io::format::format_utc_timestamp;
use crate::parsing::NodeTracker;
use crate::types::FileId;
use std::collections::{HashMap, HashSet};
use thiserror::Error;
use tree_sitter::{Node, Parser};
#[derive(Error, Debug)]
pub enum AuditError {
#[error("Failed to read file: {0}")]
FileRead(#[from] std::io::Error),
#[error("Failed to set language: {0}")]
LanguageSetup(String),
#[error("Failed to parse code")]
ParseFailure,
#[error("Failed to create parser: {0}")]
ParserCreation(String),
}
pub struct TypeScriptParserAudit {
pub grammar_nodes: HashMap<String, u16>,
pub implemented_nodes: HashSet<String>,
pub extracted_symbol_kinds: HashSet<String>,
}
impl TypeScriptParserAudit {
pub fn audit_file(file_path: &str) -> Result<Self, AuditError> {
let code = std::fs::read_to_string(file_path)?;
Self::audit_code(&code)
}
pub fn audit_code(code: &str) -> Result<Self, AuditError> {
let mut parser = Parser::new();
let language = tree_sitter_typescript::LANGUAGE_TSX.into();
parser
.set_language(&language)
.map_err(|e| AuditError::LanguageSetup(e.to_string()))?;
let tree = parser.parse(code, None).ok_or(AuditError::ParseFailure)?;
let mut grammar_nodes = HashMap::new();
discover_nodes(tree.root_node(), &mut grammar_nodes);
let mut ts_parser =
TypeScriptParser::new().map_err(|e| AuditError::ParserCreation(e.to_string()))?;
let file_id = FileId(1);
let mut symbol_counter = crate::types::SymbolCounter::new();
let symbols = ts_parser.parse(code, file_id, &mut symbol_counter);
let mut extracted_symbol_kinds = HashSet::new();
for symbol in &symbols {
extracted_symbol_kinds.insert(format!("{:?}", symbol.kind));
}
let implemented_nodes: HashSet<String> = ts_parser
.get_handled_nodes()
.iter()
.map(|handled_node| handled_node.name.clone())
.collect();
Ok(Self {
grammar_nodes,
implemented_nodes,
extracted_symbol_kinds,
})
}
pub fn generate_report(&self) -> String {
let mut report = String::new();
report.push_str("# TypeScript Parser Coverage Report\n\n");
report.push_str(&format!("*Generated: {}*\n\n", format_utc_timestamp()));
let key_nodes = vec![
"class_declaration",
"interface_declaration",
"enum_declaration",
"type_alias_declaration",
"function_declaration",
"method_definition",
"public_field_definition",
"accessibility_modifier", "variable_declaration",
"lexical_declaration",
"arrow_function",
"function_expression",
"generator_function_declaration",
"import_statement",
"export_statement",
"namespace_import",
"named_imports",
"required_parameter",
"optional_parameter",
"rest_pattern",
"type_parameter",
"type_annotation",
"predefined_type",
"internal_module",
"module", "ambient_declaration", "jsx_element",
"jsx_self_closing_element",
];
let key_implemented = key_nodes
.iter()
.filter(|n| self.implemented_nodes.contains(**n))
.count();
report.push_str("## Summary\n");
report.push_str(&format!(
"- Key nodes: {}/{} ({}%)\n",
key_implemented,
key_nodes.len(),
(key_implemented * 100) / key_nodes.len()
));
report.push_str(&format!(
"- Symbol kinds extracted: {}\n",
self.extracted_symbol_kinds.len()
));
report.push_str(
"\n> **Note:** Key nodes are symbol-producing constructs (classes, functions, imports).\n\n",
);
report.push_str("## Coverage Table\n\n");
report.push_str("| Node Type | ID | Status |\n");
report.push_str("|-----------|-----|--------|\n");
let mut gaps = Vec::new();
let mut missing = Vec::new();
for node_name in &key_nodes {
let status = if let Some(id) = self.grammar_nodes.get(*node_name) {
if self.implemented_nodes.contains(*node_name) {
format!("{id} | ✅ implemented")
} else {
gaps.push(node_name);
format!("{id} | ⚠️ gap")
}
} else {
missing.push(node_name);
"- | ❌ not found".to_string()
};
report.push_str(&format!("| {node_name} | {status} |\n"));
}
report.push_str("\n## Legend\n\n");
report
.push_str("- ✅ **implemented**: Node type is recognized and handled by the parser\n");
report.push_str("- ⚠️ **gap**: Node type exists in the grammar but not handled by parser (needs implementation)\n");
report.push_str("- ❌ **not found**: Node type not present in the example file (may need better examples)\n");
report.push_str("\n## Recommended Actions\n\n");
if !gaps.is_empty() {
report.push_str("### Priority 1: Implementation Gaps\n");
report.push_str("These nodes exist in your code but aren't being captured:\n\n");
for gap in &gaps {
report.push_str(&format!("- `{gap}`: Add parsing logic in parser.rs\n"));
}
report.push('\n');
}
if !missing.is_empty() {
report.push_str("### Priority 2: Missing Examples\n");
report.push_str("These nodes aren't in the comprehensive example. Consider:\n\n");
for node in &missing {
report.push_str(&format!(
"- `{node}`: Add example to comprehensive.ts or verify node name\n"
));
}
report.push('\n');
}
if gaps.is_empty() && missing.is_empty() {
report.push_str("✨ **Excellent coverage!** All key nodes are implemented.\n");
}
report
}
}
fn discover_nodes(node: Node, registry: &mut HashMap<String, u16>) {
registry.insert(node.kind().to_string(), node.kind_id());
let mut cursor = node.walk();
for child in node.children(&mut cursor) {
discover_nodes(child, registry);
}
}
#[cfg(test)]
mod tests {
use super::*;
#[test]
fn test_audit_simple_typescript() {
let code = r#"
interface Example {
name: string;
getValue(): number;
}
class MyClass implements Example {
name: string = "test";
getValue(): number {
return 42;
}
}
"#;
let audit = TypeScriptParserAudit::audit_code(code).unwrap();
assert!(audit.grammar_nodes.contains_key("interface_declaration"));
assert!(audit.grammar_nodes.contains_key("class_declaration"));
assert!(audit.grammar_nodes.contains_key("method_definition"));
assert!(audit.extracted_symbol_kinds.contains("Interface"));
assert!(audit.extracted_symbol_kinds.contains("Class"));
}
}