crates/ide-ssr/src/lib.rs - third_party/github.com/rust-lang/rust-analyzer - Git at Google

 //! Structural Search Replace
 //!
 //! Allows searching the AST for code that matches one or more patterns and then replacing that code
 //! based on a template.

 // Feature: Structural Search and Replace
 //
 // Search and replace with named wildcards that will match any expression, type, path, pattern or item.
 // The syntax for a structural search replace command is `<search_pattern> ==>> <replace_pattern>`.
 // A `$<name>` placeholder in the search pattern will match any AST node and `$<name>` will reference it in the replacement.
 // Within a macro call, a placeholder will match up until whatever token follows the placeholder.
 //
 // All paths in both the search pattern and the replacement template must resolve in the context
 // in which this command is invoked. Paths in the search pattern will then match the code if they
 // resolve to the same item, even if they're written differently. For example if we invoke the
 // command in the module `foo` with a pattern of `Bar`, then code in the parent module that refers
 // to `foo::Bar` will match.
 //
 // Paths in the replacement template will be rendered appropriately for the context in which the
 // replacement occurs. For example if our replacement template is `foo::Bar` and we match some
 // code in the `foo` module, we'll insert just `Bar`.
 //
 // Inherent method calls should generally be written in UFCS form. e.g. `foo::Bar::baz($s, $a)` will
 // match `$s.baz($a)`, provided the method call `baz` resolves to the method `foo::Bar::baz`. When a
 // placeholder is the receiver of a method call in the search pattern (e.g. `$s.foo()`), but not in
 // the replacement template (e.g. `bar($s)`), then *, & and &mut will be added as needed to mirror
 // whatever autoderef and autoref was happening implicitly in the matched code.
 //
 // The scope of the search / replace will be restricted to the current selection if any, otherwise
 // it will apply to the whole workspace.
 //
 // Placeholders may be given constraints by writing them as `${<name>:<constraint1>:<constraint2>...}`.
 //
 // Supported constraints:
 //
 // | Constraint    | Restricts placeholder |
 // |---------------|------------------------|
 // | kind(literal) | Is a literal (e.g. `42` or `"forty two"`) |
 // | not(a)        | Negates the constraint `a` |
 //
 // Available via the command `rust-analyzer.ssr`.
 //
 // ```rust
 // // Using structural search replace command [foo($a, $b) ==>> ($a).foo($b)]
 //
 // // BEFORE
 // String::from(foo(y + 5, z))
 //
 // // AFTER
 // String::from((y + 5).foo(z))
 // ```
 //
 // | Editor  | Action Name |
 // |---------|--------------|
 // | VS Code | **rust-analyzer: Structural Search Replace** |
 //
 // Also available as an assist, by writing a comment containing the structural
 // search and replace rule. You will only see the assist if the comment can
 // be parsed as a valid structural search and replace rule.
 //
 // ```rust
 // // Place the cursor on the line below to see the assist 💡.
 // // foo($a, $b) ==>> ($a).foo($b)
 // ```

 mod fragments;
 mod from_comment;
 mod matching;
 mod nester;
 mod parsing;
 mod replacing;
 mod resolving;
 mod search;
 #[macro_use]
 mod errors;
 #[cfg(test)]
 mod tests;

 pub use crate::{errors::SsrError, from_comment::ssr_from_comment, matching::Match};

 use crate::{errors::bail, matching::MatchFailureReason};
 use hir::{FileRange, Semantics};
 use ide_db::symbol_index::SymbolsDatabase;
 use ide_db::text_edit::TextEdit;
 use ide_db::{EditionedFileId, FileId, FxHashMap, RootDatabase, base_db::SourceDatabase};
 use resolving::ResolvedRule;
 use syntax::{AstNode, SyntaxNode, TextRange, ast};

 // A structured search replace rule. Create by calling `parse` on a str.
 #[derive(Debug)]
 pub struct SsrRule {
     /// A structured pattern that we're searching for.
     pattern: parsing::RawPattern,
     /// What we'll replace it with.
     template: parsing::RawPattern,
     parsed_rules: Vec<parsing::ParsedRule>,
 }

 #[derive(Debug)]
 pub struct SsrPattern {
     parsed_rules: Vec<parsing::ParsedRule>,
 }

 #[derive(Debug, Default)]
 pub struct SsrMatches {
     pub matches: Vec<Match>,
 }

 /// Searches a crate for pattern matches and possibly replaces them with something else.
 pub struct MatchFinder<'db> {
     /// Our source of information about the user's code.
     sema: Semantics<'db, ide_db::RootDatabase>,
     rules: Vec<ResolvedRule>,
     resolution_scope: resolving::ResolutionScope<'db>,
     restrict_ranges: Vec<ide_db::FileRange>,
 }

 impl<'db> MatchFinder<'db> {
     /// Constructs a new instance where names will be looked up as if they appeared at
     /// `lookup_context`.
     pub fn in_context(
         db: &'db RootDatabase,
         lookup_context: ide_db::FilePosition,
         mut restrict_ranges: Vec<ide_db::FileRange>,
     ) -> Result<MatchFinder<'db>, SsrError> {
         restrict_ranges.retain(|range| !range.range.is_empty());
         let sema = Semantics::new(db);
         let file_id = sema
             .attach_first_edition(lookup_context.file_id)
             .unwrap_or_else(|| EditionedFileId::current_edition(db, lookup_context.file_id));
         let resolution_scope = resolving::ResolutionScope::new(
             &sema,
             hir::FilePosition { file_id, offset: lookup_context.offset },
         )
         .ok_or_else(|| SsrError("no resolution scope for file".into()))?;
         Ok(MatchFinder { sema, rules: Vec::new(), resolution_scope, restrict_ranges })
     }

     /// Constructs an instance using the start of the first file in `db` as the lookup context.
     pub fn at_first_file(db: &'db ide_db::RootDatabase) -> Result<MatchFinder<'db>, SsrError> {
         if let Some(first_file_id) = db
             .local_roots()
             .iter()
             .next()
             .and_then(|root| db.source_root(*root).source_root(db).iter().next())
         {
             MatchFinder::in_context(
                 db,
                 ide_db::FilePosition { file_id: first_file_id, offset: 0.into() },
                 vec![],
             )
         } else {
             bail!("No files to search");
         }
     }

     /// Adds a rule to be applied. The order in which rules are added matters. Earlier rules take
     /// precedence. If a node is matched by an earlier rule, then later rules won't be permitted to
     /// match to it.
     pub fn add_rule(&mut self, rule: SsrRule) -> Result<(), SsrError> {
         for parsed_rule in rule.parsed_rules {
             self.rules.push(ResolvedRule::new(
                 parsed_rule,
                 &self.resolution_scope,
                 self.rules.len(),
             )?);
         }
         Ok(())
     }

     /// Finds matches for all added rules and returns edits for all found matches.
     pub fn edits(&self) -> FxHashMap<FileId, TextEdit> {
         let mut matches_by_file = FxHashMap::default();
         for m in self.matches().matches {
             matches_by_file
                 .entry(m.range.file_id.file_id(self.sema.db))
                 .or_insert_with(SsrMatches::default)
                 .matches
                 .push(m);
         }
         matches_by_file
             .into_iter()
             .map(|(file_id, matches)| {
                 (
                     file_id,
                     replacing::matches_to_edit(
                         self.sema.db,
                         &matches,
                         &self.sema.db.file_text(file_id).text(self.sema.db),
                         &self.rules,
                     ),
                 )
             })
             .collect()
     }

     /// Adds a search pattern. For use if you intend to only call `find_matches_in_file`. If you
     /// intend to do replacement, use `add_rule` instead.
     pub fn add_search_pattern(&mut self, pattern: SsrPattern) -> Result<(), SsrError> {
         for parsed_rule in pattern.parsed_rules {
             self.rules.push(ResolvedRule::new(
                 parsed_rule,
                 &self.resolution_scope,
                 self.rules.len(),
             )?);
         }
         Ok(())
     }

     /// Returns matches for all added rules.
     pub fn matches(&self) -> SsrMatches {
         let mut matches = Vec::new();
         let mut usage_cache = search::UsageCache::default();
         for rule in &self.rules {
             self.find_matches_for_rule(rule, &mut usage_cache, &mut matches);
         }
         nester::nest_and_remove_collisions(matches, &self.sema)
     }

     /// Finds all nodes in `file_id` whose text is exactly equal to `snippet` and attempts to match
     /// them, while recording reasons why they don't match. This API is useful for command
     /// line-based debugging where providing a range is difficult.
     pub fn debug_where_text_equal(
         &self,
         file_id: EditionedFileId,
         snippet: &str,
     ) -> Vec<MatchDebugInfo> {
         let file = self.sema.parse(file_id);
         let mut res = Vec::new();
         let file_text = self.sema.db.file_text(file_id.file_id(self.sema.db)).text(self.sema.db);
         let mut remaining_text = &*file_text;
         let mut base = 0;
         let len = snippet.len() as u32;
         while let Some(offset) = remaining_text.find(snippet) {
             let start = base + offset as u32;
             let end = start + len;
             self.output_debug_for_nodes_at_range(
                 file.syntax(),
                 FileRange { file_id, range: TextRange::new(start.into(), end.into()) },
                 &None,
                 &mut res,
             );
             remaining_text = &remaining_text[offset + snippet.len()..];
             base = end;
         }
         res
     }

     fn output_debug_for_nodes_at_range(
         &self,
         node: &SyntaxNode,
         range: FileRange,
         restrict_range: &Option<FileRange>,
         out: &mut Vec<MatchDebugInfo>,
     ) {
         for node in node.children() {
             let node_range = self.sema.original_range(&node);
             if node_range.file_id != range.file_id || !node_range.range.contains_range(range.range)
             {
                 continue;
             }
             if node_range.range == range.range {
                 for rule in &self.rules {
                     // For now we ignore rules that have a different kind than our node, otherwise
                     // we get lots of noise. If at some point we add support for restricting rules
                     // to a particular kind of thing (e.g. only match type references), then we can
                     // relax this. We special-case expressions, since function calls can match
                     // method calls.
                     if rule.pattern.node.kind() != node.kind()
                         && !(ast::Expr::can_cast(rule.pattern.node.kind())
                             && ast::Expr::can_cast(node.kind()))
                     {
                         continue;
                     }
                     out.push(MatchDebugInfo {
                         matched: matching::get_match(true, rule, &node, restrict_range, &self.sema)
                             .map_err(|e| MatchFailureReason {
                                 reason: e.reason.unwrap_or_else(|| {
                                     "Match failed, but no reason was given".to_owned()
                                 }),
                             }),
                         pattern: rule.pattern.node.clone(),
                         node: node.clone(),
                     });
                 }
             } else if let Some(macro_call) = ast::MacroCall::cast(node.clone()) {
                 if let Some(expanded) = self.sema.expand_macro_call(&macro_call) {
                     if let Some(tt) = macro_call.token_tree() {
                         self.output_debug_for_nodes_at_range(
                             &expanded.value,
                             range,
                             &Some(self.sema.original_range(tt.syntax())),
                             out,
                         );
                     }
                 }
             }
             self.output_debug_for_nodes_at_range(&node, range, restrict_range, out);
         }
     }
 }

 pub struct MatchDebugInfo {
     node: SyntaxNode,
     /// Our search pattern parsed as an expression or item, etc
     pattern: SyntaxNode,
     matched: Result<Match, MatchFailureReason>,
 }

 impl std::fmt::Debug for MatchDebugInfo {
     fn fmt(&self, f: &mut std::fmt::Formatter<'_>) -> std::fmt::Result {
         match &self.matched {
             Ok(_) => writeln!(f, "Node matched")?,
             Err(reason) => writeln!(f, "Node failed to match because: {}", reason.reason)?,
         }
         writeln!(
             f,
             "============ AST ===========\n\
             {:#?}",
             self.node
         )?;
         writeln!(f, "========= PATTERN ==========")?;
         writeln!(f, "{:#?}", self.pattern)?;
         writeln!(f, "============================")?;
         Ok(())
     }
 }

 impl SsrMatches {
     /// Returns `self` with any nested matches removed and made into top-level matches.
     pub fn flattened(self) -> SsrMatches {
         let mut out = SsrMatches::default();
         self.flatten_into(&mut out);
         out
     }

     fn flatten_into(self, out: &mut SsrMatches) {
         for mut m in self.matches {
             for p in m.placeholder_values.values_mut() {
                 std::mem::take(&mut p.inner_matches).flatten_into(out);
             }
             out.matches.push(m);
         }
     }
 }

 impl Match {
     pub fn matched_text(&self) -> String {
         self.matched_node.text().to_string()
     }
 }

 impl std::error::Error for SsrError {}

 #[cfg(test)]
 impl MatchDebugInfo {
     pub fn match_failure_reason(&self) -> Option<&str> {
         self.matched.as_ref().err().map(|r| r.reason.as_str())
     }
 }
	//! Structural Search Replace
	//!
	//! Allows searching the AST for code that matches one or more patterns and then replacing that code
	//! based on a template.

	// Feature: Structural Search and Replace
	//
	// Search and replace with named wildcards that will match any expression, type, path, pattern or item.
	// The syntax for a structural search replace command is `<search_pattern> ==>> <replace_pattern>`.
	// A `$<name>` placeholder in the search pattern will match any AST node and `$<name>` will reference it in the replacement.
	// Within a macro call, a placeholder will match up until whatever token follows the placeholder.
	//
	// All paths in both the search pattern and the replacement template must resolve in the context
	// in which this command is invoked. Paths in the search pattern will then match the code if they
	// resolve to the same item, even if they're written differently. For example if we invoke the
	// command in the module `foo` with a pattern of `Bar`, then code in the parent module that refers
	// to `foo::Bar` will match.
	//
	// Paths in the replacement template will be rendered appropriately for the context in which the
	// replacement occurs. For example if our replacement template is `foo::Bar` and we match some
	// code in the `foo` module, we'll insert just `Bar`.
	//
	// Inherent method calls should generally be written in UFCS form. e.g. `foo::Bar::baz($s, $a)` will
	// match `$s.baz($a)`, provided the method call `baz` resolves to the method `foo::Bar::baz`. When a
	// placeholder is the receiver of a method call in the search pattern (e.g. `$s.foo()`), but not in
	// the replacement template (e.g. `bar($s)`), then *, & and &mut will be added as needed to mirror
	// whatever autoderef and autoref was happening implicitly in the matched code.
	//
	// The scope of the search / replace will be restricted to the current selection if any, otherwise
	// it will apply to the whole workspace.
	//
	// Placeholders may be given constraints by writing them as `${<name>:<constraint1>:<constraint2>...}`.
	//
	// Supported constraints:
	//
	// \| Constraint \| Restricts placeholder \|
	// \|---------------\|------------------------\|
	// \| kind(literal) \| Is a literal (e.g. `42` or `"forty two"`) \|
	// \| not(a) \| Negates the constraint `a` \|
	//
	// Available via the command `rust-analyzer.ssr`.
	//
	// ```rust
	// // Using structural search replace command [foo($a, $b) ==>> ($a).foo($b)]
	//
	// // BEFORE
	// String::from(foo(y + 5, z))
	//
	// // AFTER
	// String::from((y + 5).foo(z))
	// ```
	//
	// \| Editor \| Action Name \|
	// \|---------\|--------------\|
	// \| VS Code \| rust-analyzer: Structural Search Replace \|
	//
	// Also available as an assist, by writing a comment containing the structural
	// search and replace rule. You will only see the assist if the comment can
	// be parsed as a valid structural search and replace rule.
	//
	// ```rust
	// // Place the cursor on the line below to see the assist 💡.
	// // foo($a, $b) ==>> ($a).foo($b)
	// ```

	mod fragments;
	mod from_comment;
	mod matching;
	mod nester;
	mod parsing;
	mod replacing;
	mod resolving;
	mod search;
	#[macro_use]
	mod errors;
	#[cfg(test)]
	mod tests;

	pub use crate::{errors::SsrError, from_comment::ssr_from_comment, matching::Match};

	use crate::{errors::bail, matching::MatchFailureReason};
	use hir::{FileRange, Semantics};
	use ide_db::symbol_index::SymbolsDatabase;
	use ide_db::text_edit::TextEdit;
	use ide_db::{EditionedFileId, FileId, FxHashMap, RootDatabase, base_db::SourceDatabase};
	use resolving::ResolvedRule;
	use syntax::{AstNode, SyntaxNode, TextRange, ast};

	// A structured search replace rule. Create by calling `parse` on a str.
	#[derive(Debug)]
	pub struct SsrRule {
	/// A structured pattern that we're searching for.
	pattern: parsing::RawPattern,
	/// What we'll replace it with.
	template: parsing::RawPattern,
	parsed_rules: Vec<parsing::ParsedRule>,
	}

	#[derive(Debug)]
	pub struct SsrPattern {
	parsed_rules: Vec<parsing::ParsedRule>,
	}

	#[derive(Debug, Default)]
	pub struct SsrMatches {
	pub matches: Vec<Match>,
	}

	/// Searches a crate for pattern matches and possibly replaces them with something else.
	pub struct MatchFinder<'db> {
	/// Our source of information about the user's code.
	sema: Semantics<'db, ide_db::RootDatabase>,
	rules: Vec<ResolvedRule>,
	resolution_scope: resolving::ResolutionScope<'db>,
	restrict_ranges: Vec<ide_db::FileRange>,
	}

	impl<'db> MatchFinder<'db> {
	/// Constructs a new instance where names will be looked up as if they appeared at
	/// `lookup_context`.
	pub fn in_context(
	db: &'db RootDatabase,
	lookup_context: ide_db::FilePosition,
	mut restrict_ranges: Vec<ide_db::FileRange>,
	) -> Result<MatchFinder<'db>, SsrError> {
	restrict_ranges.retain(\|range\| !range.range.is_empty());
	let sema = Semantics::new(db);
	let file_id = sema
	.attach_first_edition(lookup_context.file_id)
	.unwrap_or_else(\|\| EditionedFileId::current_edition(db, lookup_context.file_id));
	let resolution_scope = resolving::ResolutionScope::new(
	&sema,
	hir::FilePosition { file_id, offset: lookup_context.offset },
	)
	.ok_or_else(\|\| SsrError("no resolution scope for file".into()))?;
	Ok(MatchFinder { sema, rules: Vec::new(), resolution_scope, restrict_ranges })
	}

	/// Constructs an instance using the start of the first file in `db` as the lookup context.
	pub fn at_first_file(db: &'db ide_db::RootDatabase) -> Result<MatchFinder<'db>, SsrError> {
	if let Some(first_file_id) = db
	.local_roots()
	.iter()
	.next()
	.and_then(\|root\| db.source_root(*root).source_root(db).iter().next())
	{
	MatchFinder::in_context(
	db,
	ide_db::FilePosition { file_id: first_file_id, offset: 0.into() },
	vec![],
	)
	} else {
	bail!("No files to search");
	}
	}

	/// Adds a rule to be applied. The order in which rules are added matters. Earlier rules take
	/// precedence. If a node is matched by an earlier rule, then later rules won't be permitted to
	/// match to it.
	pub fn add_rule(&mut self, rule: SsrRule) -> Result<(), SsrError> {
	for parsed_rule in rule.parsed_rules {
	self.rules.push(ResolvedRule::new(
	parsed_rule,
	&self.resolution_scope,
	self.rules.len(),
	)?);
	}
	Ok(())
	}

	/// Finds matches for all added rules and returns edits for all found matches.
	pub fn edits(&self) -> FxHashMap<FileId, TextEdit> {
	let mut matches_by_file = FxHashMap::default();
	for m in self.matches().matches {
	matches_by_file
	.entry(m.range.file_id.file_id(self.sema.db))
	.or_insert_with(SsrMatches::default)
	.matches
	.push(m);
	}
	matches_by_file
	.into_iter()
	.map(\|(file_id, matches)\| {
	(
	file_id,
	replacing::matches_to_edit(
	self.sema.db,
	&matches,
	&self.sema.db.file_text(file_id).text(self.sema.db),
	&self.rules,
	),
	)
	})
	.collect()
	}

	/// Adds a search pattern. For use if you intend to only call `find_matches_in_file`. If you
	/// intend to do replacement, use `add_rule` instead.
	pub fn add_search_pattern(&mut self, pattern: SsrPattern) -> Result<(), SsrError> {
	for parsed_rule in pattern.parsed_rules {
	self.rules.push(ResolvedRule::new(
	parsed_rule,
	&self.resolution_scope,
	self.rules.len(),
	)?);
	}
	Ok(())
	}

	/// Returns matches for all added rules.
	pub fn matches(&self) -> SsrMatches {
	let mut matches = Vec::new();
	let mut usage_cache = search::UsageCache::default();
	for rule in &self.rules {
	self.find_matches_for_rule(rule, &mut usage_cache, &mut matches);
	}
	nester::nest_and_remove_collisions(matches, &self.sema)
	}

	/// Finds all nodes in `file_id` whose text is exactly equal to `snippet` and attempts to match
	/// them, while recording reasons why they don't match. This API is useful for command
	/// line-based debugging where providing a range is difficult.
	pub fn debug_where_text_equal(
	&self,
	file_id: EditionedFileId,
	snippet: &str,
	) -> Vec<MatchDebugInfo> {
	let file = self.sema.parse(file_id);
	let mut res = Vec::new();
	let file_text = self.sema.db.file_text(file_id.file_id(self.sema.db)).text(self.sema.db);
	let mut remaining_text = &*file_text;
	let mut base = 0;
	let len = snippet.len() as u32;
	while let Some(offset) = remaining_text.find(snippet) {
	let start = base + offset as u32;
	let end = start + len;
	self.output_debug_for_nodes_at_range(
	file.syntax(),
	FileRange { file_id, range: TextRange::new(start.into(), end.into()) },
	&None,
	&mut res,
	);
	remaining_text = &remaining_text[offset + snippet.len()..];
	base = end;
	}
	res
	}

	fn output_debug_for_nodes_at_range(
	&self,
	node: &SyntaxNode,
	range: FileRange,
	restrict_range: &Option<FileRange>,
	out: &mut Vec<MatchDebugInfo>,
	) {
	for node in node.children() {
	let node_range = self.sema.original_range(&node);
	if node_range.file_id != range.file_id \|\| !node_range.range.contains_range(range.range)
	{
	continue;
	}
	if node_range.range == range.range {
	for rule in &self.rules {
	// For now we ignore rules that have a different kind than our node, otherwise
	// we get lots of noise. If at some point we add support for restricting rules
	// to a particular kind of thing (e.g. only match type references), then we can
	// relax this. We special-case expressions, since function calls can match
	// method calls.
	if rule.pattern.node.kind() != node.kind()
	&& !(ast::Expr::can_cast(rule.pattern.node.kind())
	&& ast::Expr::can_cast(node.kind()))
	{
	continue;
	}
	out.push(MatchDebugInfo {
	matched: matching::get_match(true, rule, &node, restrict_range, &self.sema)
	.map_err(\|e\| MatchFailureReason {
	reason: e.reason.unwrap_or_else(\|\| {
	"Match failed, but no reason was given".to_owned()
	}),
	}),
	pattern: rule.pattern.node.clone(),
	node: node.clone(),
	});
	}
	} else if let Some(macro_call) = ast::MacroCall::cast(node.clone()) {
	if let Some(expanded) = self.sema.expand_macro_call(&macro_call) {
	if let Some(tt) = macro_call.token_tree() {
	self.output_debug_for_nodes_at_range(
	&expanded.value,
	range,
	&Some(self.sema.original_range(tt.syntax())),
	out,
	);
	}
	}
	}
	self.output_debug_for_nodes_at_range(&node, range, restrict_range, out);
	}
	}
	}

	pub struct MatchDebugInfo {
	node: SyntaxNode,
	/// Our search pattern parsed as an expression or item, etc
	pattern: SyntaxNode,
	matched: Result<Match, MatchFailureReason>,
	}

	impl std::fmt::Debug for MatchDebugInfo {
	fn fmt(&self, f: &mut std::fmt::Formatter<'_>) -> std::fmt::Result {
	match &self.matched {
	Ok(_) => writeln!(f, "Node matched")?,
	Err(reason) => writeln!(f, "Node failed to match because: {}", reason.reason)?,
	}
	writeln!(
	f,
	"============ AST ===========\n\
	{:#?}",
	self.node
	)?;
	writeln!(f, "========= PATTERN ==========")?;
	writeln!(f, "{:#?}", self.pattern)?;
	writeln!(f, "============================")?;
	Ok(())
	}
	}

	impl SsrMatches {
	/// Returns `self` with any nested matches removed and made into top-level matches.
	pub fn flattened(self) -> SsrMatches {
	let mut out = SsrMatches::default();
	self.flatten_into(&mut out);
	out
	}

	fn flatten_into(self, out: &mut SsrMatches) {
	for mut m in self.matches {
	for p in m.placeholder_values.values_mut() {
	std::mem::take(&mut p.inner_matches).flatten_into(out);
	}
	out.matches.push(m);
	}
	}
	}

	impl Match {
	pub fn matched_text(&self) -> String {
	self.matched_node.text().to_string()
	}
	}

	impl std::error::Error for SsrError {}

	#[cfg(test)]
	impl MatchDebugInfo {
	pub fn match_failure_reason(&self) -> Option<&str> {
	self.matched.as_ref().err().map(\|r\| r.reason.as_str())
	}
	}