//! This module contains tests for macro expansion. Effectively, it covers `tt`, //! `mbe`, `proc_macro_api` and `hir_expand` crates. This might seem like a //! wrong architecture at the first glance, but is intentional. //! //! Physically, macro expansion process is intertwined with name resolution. You //! can not expand *just* the syntax. So, to be able to write integration tests //! of the "expand this code please" form, we have to do it after name //! resolution. That is, in this crate. We *could* fake some dependencies and //! write unit-tests (in fact, we used to do that), but that makes tests brittle //! and harder to understand. mod mbe; use std::{iter, ops::Range}; use base_db::{fixture::WithFixture, SourceDatabase}; use expect_test::Expect; use hir_expand::{db::AstDatabase, InFile, MacroFile}; use stdx::format_to; use syntax::{ ast::{self, edit::IndentLevel}, AstNode, SyntaxKind::{self, IDENT, LIFETIME_IDENT}, SyntaxNode, T, }; use crate::{ db::DefDatabase, nameres::ModuleSource, resolver::HasResolver, test_db::TestDB, AsMacroCall, }; fn check(ra_fixture: &str, mut expect: Expect) { let db = TestDB::with_files(ra_fixture); let krate = db.crate_graph().iter().next().unwrap(); let def_map = db.crate_def_map(krate); let local_id = def_map.root(); let module = def_map.module_id(local_id); let resolver = module.resolver(&db); let source = def_map[local_id].definition_source(&db); let source_file = match source.value { ModuleSource::SourceFile(it) => it, ModuleSource::Module(_) | ModuleSource::BlockExpr(_) => panic!(), }; let mut expansions = Vec::new(); for macro_call in source_file.syntax().descendants().filter_map(ast::MacroCall::cast) { let macro_call = InFile::new(source.file_id, ¯o_call); let macro_call_id = macro_call .as_call_id_with_errors( &db, krate, |path| resolver.resolve_path_as_macro(&db, &path), &mut |err| panic!("{}", err), ) .unwrap() .unwrap(); let macro_file = MacroFile { macro_call_id }; let expansion_result = db.parse_macro_expansion(macro_file); expansions.push((macro_call.value.clone(), expansion_result)); } let mut expanded_text = source_file.to_string(); for (call, exp) in expansions.into_iter().rev() { let mut expn_text = String::new(); if let Some(err) = exp.err { format_to!(expn_text, "/* error: {} */", err); } if let Some((parse, _token_map)) = exp.value { let pp = pretty_print_macro_expansion(parse.syntax_node()); let indent = IndentLevel::from_node(call.syntax()); let pp = reindent(indent, pp); format_to!(expn_text, "{}", pp); } let range = call.syntax().text_range(); let range: Range = range.into(); expanded_text.replace_range(range, &expn_text) } expect.indent(false); expect.assert_eq(&expanded_text); } fn reindent(indent: IndentLevel, pp: String) -> String { if !pp.contains('\n') { return pp; } let mut lines = pp.split_inclusive('\n'); let mut res = lines.next().unwrap().to_string(); for line in lines { if line.trim().is_empty() { res.push_str(&line) } else { format_to!(res, "{}{}", indent, line) } } res } fn pretty_print_macro_expansion(expn: SyntaxNode) -> String { let mut res = String::new(); let mut prev_kind = SyntaxKind::EOF; for token in iter::successors(expn.first_token(), |t| t.next_token()) { let curr_kind = token.kind(); let space = match (prev_kind, curr_kind) { _ if prev_kind.is_trivia() || curr_kind.is_trivia() => "", (T![=], _) | (_, T![=]) => " ", (_, T!['{']) => " ", (T![;] | T!['}'], _) => "\n", (IDENT | LIFETIME_IDENT, IDENT | LIFETIME_IDENT) => " ", (IDENT, _) if curr_kind.is_keyword() => " ", (_, IDENT) if prev_kind.is_keyword() => " ", _ => "", }; res.push_str(space); prev_kind = curr_kind; format_to!(res, "{}", token) } res }