mirror of
https://github.com/MaskRay/ccls.git
synced 2024-11-25 17:11:59 +00:00
902 lines
30 KiB
C++
902 lines
30 KiB
C++
#include "indexer.h"
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#include "serializer.h"
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IndexedFile::IndexedFile(const std::string& path, IdCache* id_cache)
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: path(path), id_cache(id_cache) {
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// TODO: Reconsider if we should still be reusing the same id_cache.
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// Preallocate any existing resolved ids.
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for (const auto& entry : id_cache->usr_to_type_id)
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types.push_back(IndexedTypeDef(entry.second, entry.first));
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for (const auto& entry : id_cache->usr_to_func_id)
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funcs.push_back(IndexedFuncDef(entry.second, entry.first));
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for (const auto& entry : id_cache->usr_to_var_id)
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vars.push_back(IndexedVarDef(entry.second, entry.first));
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}
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// TODO: Optimize for const char*?
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TypeId IndexedFile::ToTypeId(const std::string& usr) {
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auto it = id_cache->usr_to_type_id.find(usr);
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if (it != id_cache->usr_to_type_id.end())
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return it->second;
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TypeId id(types.size());
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types.push_back(IndexedTypeDef(id, usr));
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id_cache->usr_to_type_id[usr] = id;
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id_cache->type_id_to_usr[id] = usr;
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return id;
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}
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FuncId IndexedFile::ToFuncId(const std::string& usr) {
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auto it = id_cache->usr_to_func_id.find(usr);
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if (it != id_cache->usr_to_func_id.end())
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return it->second;
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FuncId id(funcs.size());
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funcs.push_back(IndexedFuncDef(id, usr));
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id_cache->usr_to_func_id[usr] = id;
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id_cache->func_id_to_usr[id] = usr;
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return id;
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}
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VarId IndexedFile::ToVarId(const std::string& usr) {
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auto it = id_cache->usr_to_var_id.find(usr);
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if (it != id_cache->usr_to_var_id.end())
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return it->second;
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VarId id(vars.size());
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vars.push_back(IndexedVarDef(id, usr));
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id_cache->usr_to_var_id[usr] = id;
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id_cache->var_id_to_usr[id] = usr;
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return id;
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}
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TypeId IndexedFile::ToTypeId(const CXCursor& cursor) {
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return ToTypeId(clang::Cursor(cursor).get_usr());
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}
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FuncId IndexedFile::ToFuncId(const CXCursor& cursor) {
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return ToFuncId(clang::Cursor(cursor).get_usr());
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}
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VarId IndexedFile::ToVarId(const CXCursor& cursor) {
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return ToVarId(clang::Cursor(cursor).get_usr());
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}
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IndexedTypeDef* IndexedFile::Resolve(TypeId id) {
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return &types[id.id];
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}
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IndexedFuncDef* IndexedFile::Resolve(FuncId id) {
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return &funcs[id.id];
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}
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IndexedVarDef* IndexedFile::Resolve(VarId id) {
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return &vars[id.id];
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}
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std::string IndexedFile::ToString() {
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rapidjson::StringBuffer output;
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rapidjson::PrettyWriter<rapidjson::StringBuffer> writer(output);
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writer.SetFormatOptions(
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rapidjson::PrettyFormatOptions::kFormatSingleLineArray);
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writer.SetIndent(' ', 2);
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Serialize(writer, this);
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return output.GetString();
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}
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IndexedTypeDef::IndexedTypeDef(TypeId id, const std::string& usr) : id(id), def(usr) {
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assert(usr.size() > 0);
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//std::cout << "Creating type with usr " << usr << std::endl;
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}
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void IndexedTypeDef::AddUsage(Location loc, bool insert_if_not_present) {
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for (int i = uses.size() - 1; i >= 0; --i) {
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if (uses[i].IsEqualTo(loc)) {
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if (loc.interesting)
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uses[i].interesting = true;
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return;
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}
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}
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if (insert_if_not_present)
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uses.push_back(loc);
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}
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IdCache::IdCache() {
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// Reserve id 0 for unfound.
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file_path_to_file_id[""] = FileId(0);
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file_id_to_file_path[FileId(0)] = "";
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}
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Location IdCache::Resolve(const CXSourceLocation& cx_loc, bool interesting) {
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CXFile file;
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unsigned int line, column, offset;
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clang_getSpellingLocation(cx_loc, &file, &line, &column, &offset);
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FileId file_id(-1);
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if (file != nullptr) {
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std::string path = clang::ToString(clang_getFileName(file));
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auto it = file_path_to_file_id.find(path);
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if (it != file_path_to_file_id.end()) {
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file_id = it->second;
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}
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else {
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file_id = FileId(file_path_to_file_id.size());
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file_path_to_file_id[path] = file_id;
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file_id_to_file_path[file_id] = path;
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}
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}
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return Location(interesting, file_id, line, column);
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}
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Location IdCache::Resolve(const CXIdxLoc& cx_idx_loc, bool interesting) {
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CXSourceLocation cx_loc = clang_indexLoc_getCXSourceLocation(cx_idx_loc);
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return Resolve(cx_loc, interesting);
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}
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Location IdCache::Resolve(const CXCursor& cx_cursor, bool interesting) {
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return Resolve(clang_getCursorLocation(cx_cursor), interesting);
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}
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Location IdCache::Resolve(const clang::Cursor& cursor, bool interesting) {
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return Resolve(cursor.cx_cursor, interesting);
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}
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template<typename T>
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bool Contains(const std::vector<T>& vec, const T& element) {
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for (const T& entry : vec) {
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if (entry == element)
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return true;
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}
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return false;
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}
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int abortQuery(CXClientData client_data, void *reserved) {
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// 0 -> continue
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return 0;
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}
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void diagnostic(CXClientData client_data, CXDiagnosticSet, void *reserved) {}
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CXIdxClientFile enteredMainFile(CXClientData client_data, CXFile mainFile, void *reserved) {
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return nullptr;
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}
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CXIdxClientFile ppIncludedFile(CXClientData client_data, const CXIdxIncludedFileInfo *) {
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return nullptr;
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}
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CXIdxClientASTFile importedASTFile(CXClientData client_data, const CXIdxImportedASTFileInfo *) {
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return nullptr;
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}
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CXIdxClientContainer startedTranslationUnit(CXClientData client_data, void *reserved) {
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return nullptr;
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}
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clang::VisiterResult DumpVisitor(clang::Cursor cursor, clang::Cursor parent, int* level) {
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for (int i = 0; i < *level; ++i)
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std::cout << " ";
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std::cout << clang::ToString(cursor.get_kind()) << " " << cursor.get_spelling() << std::endl;
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*level += 1;
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cursor.VisitChildren(&DumpVisitor, level);
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*level -= 1;
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return clang::VisiterResult::Continue;
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}
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void Dump(clang::Cursor cursor) {
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int level = 0;
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cursor.VisitChildren(&DumpVisitor, &level);
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}
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struct FindChildOfKindParam {
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CXCursorKind target_kind;
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optional<clang::Cursor> result;
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FindChildOfKindParam(CXCursorKind target_kind) : target_kind(target_kind) {}
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};
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clang::VisiterResult FindChildOfKindVisitor(clang::Cursor cursor, clang::Cursor parent, FindChildOfKindParam* param) {
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if (cursor.get_kind() == param->target_kind) {
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param->result = cursor;
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return clang::VisiterResult::Break;
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}
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return clang::VisiterResult::Recurse;
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}
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optional<clang::Cursor> FindChildOfKind(clang::Cursor cursor, CXCursorKind kind) {
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FindChildOfKindParam param(kind);
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cursor.VisitChildren(&FindChildOfKindVisitor, ¶m);
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return param.result;
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}
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clang::VisiterResult FindTypeVisitor(clang::Cursor cursor, clang::Cursor parent, optional<clang::Cursor>* result) {
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switch (cursor.get_kind()) {
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case CXCursor_TypeRef:
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case CXCursor_TemplateRef:
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*result = cursor;
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return clang::VisiterResult::Break;
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}
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return clang::VisiterResult::Recurse;
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}
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optional<clang::Cursor> FindType(clang::Cursor cursor) {
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optional<clang::Cursor> result;
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cursor.VisitChildren(&FindTypeVisitor, &result);
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return result;
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}
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struct NamespaceHelper {
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std::unordered_map<std::string, std::string> container_usr_to_qualified_name;
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void RegisterQualifiedName(std::string usr, const CXIdxContainerInfo* container, std::string qualified_name) {
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if (container) {
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std::string container_usr = clang::Cursor(container->cursor).get_usr();
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auto it = container_usr_to_qualified_name.find(container_usr);
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if (it != container_usr_to_qualified_name.end()) {
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container_usr_to_qualified_name[usr] = it->second + qualified_name + "::";
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return;
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}
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}
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container_usr_to_qualified_name[usr] = qualified_name + "::";
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}
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std::string QualifiedName(const CXIdxContainerInfo* container, std::string unqualified_name) {
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if (container) {
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std::string container_usr = clang::Cursor(container->cursor).get_usr();
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auto it = container_usr_to_qualified_name.find(container_usr);
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if (it != container_usr_to_qualified_name.end())
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return it->second + unqualified_name;
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// Anonymous namespaces are not processed by indexDeclaration. If we
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// encounter one insert it into map.
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if (container->cursor.kind == CXCursor_Namespace) {
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assert(clang::Cursor(container->cursor).get_spelling() == "");
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container_usr_to_qualified_name[container_usr] = "::";
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return "::" + unqualified_name;
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}
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}
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return unqualified_name;
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}
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};
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struct IndexParam {
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IndexedFile* db;
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NamespaceHelper* ns;
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// Record the last type usage location we recorded. Clang will sometimes
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// visit the same expression twice so we wan't to avoid double-reporting
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// usage information for those locations.
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Location last_type_usage_location;
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Location last_func_usage_location;
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IndexParam(IndexedFile* db, NamespaceHelper* ns) : db(db), ns(ns) {}
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};
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/*
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std::string GetNamespacePrefx(const CXIdxDeclInfo* decl) {
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const CXIdxContainerInfo* container = decl->lexicalContainer;
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while (container) {
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}
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}
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*/
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bool IsTypeDefinition(const CXIdxContainerInfo* container) {
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if (!container)
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return false;
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switch (container->cursor.kind) {
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case CXCursor_EnumDecl:
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case CXCursor_UnionDecl:
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case CXCursor_StructDecl:
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case CXCursor_ClassDecl:
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return true;
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default:
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return false;
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}
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}
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struct VisitDeclForTypeUsageParam {
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IndexedFile* db;
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bool is_interesting;
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int has_processed_any = false;
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optional<clang::Cursor> previous_cursor;
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optional<TypeId> initial_type;
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VisitDeclForTypeUsageParam(IndexedFile* db, bool is_interesting)
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: db(db), is_interesting(is_interesting) {}
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};
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void VisitDeclForTypeUsageVisitorHandler(clang::Cursor cursor, VisitDeclForTypeUsageParam* param) {
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param->has_processed_any = true;
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IndexedFile* db = param->db;
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// TODO: Something in STL (type_traits)? reports an empty USR.
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std::string referenced_usr = cursor.get_referenced().get_usr();
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if (referenced_usr == "")
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return;
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TypeId ref_type_id = db->ToTypeId(referenced_usr);
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if (!param->initial_type)
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param->initial_type = ref_type_id;
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if (param->is_interesting) {
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IndexedTypeDef* ref_type_def = db->Resolve(ref_type_id);
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Location loc = db->id_cache->Resolve(cursor, true /*interesting*/);
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ref_type_def->AddUsage(loc);
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}
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}
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clang::VisiterResult VisitDeclForTypeUsageVisitor(clang::Cursor cursor, clang::Cursor parent, VisitDeclForTypeUsageParam* param) {
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switch (cursor.get_kind()) {
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case CXCursor_TemplateRef:
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case CXCursor_TypeRef:
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if (param->previous_cursor) {
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VisitDeclForTypeUsageVisitorHandler(param->previous_cursor.value(), param);
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// This if is inside the above if because if there are multiple TypeRefs,
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// we always want to process the first one. If we did not always process
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// the first one, we cannot tell if there are more TypeRefs after it and
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// logic for fetching the return type breaks. This happens in ParmDecl
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// instances which only have one TypeRef child but are not interesting
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// usages.
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if (!param->is_interesting)
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return clang::VisiterResult::Break;
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}
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param->previous_cursor = cursor;
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}
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return clang::VisiterResult::Continue;
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}
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optional<TypeId> ResolveDeclToType(IndexedFile* db, clang::Cursor decl_cursor,
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bool is_interesting, const CXIdxContainerInfo* semantic_container,
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const CXIdxContainerInfo* lexical_container) {
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//
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// The general AST format for definitions follows this pattern:
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//
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// template<typename A, typename B>
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// struct Container;
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//
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// struct S1;
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// struct S2;
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//
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// Container<Container<S1, S2>, S2> foo;
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//
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// =>
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//
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// VarDecl
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// TemplateRef Container
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// TemplateRef Container
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// TypeRef struct S1
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// TypeRef struct S2
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// TypeRef struct S2
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//
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// We skip the last type reference for methods/variables which are defined
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// out-of-line w.r.t. the parent type.
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//
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// S1* Foo::foo() {}
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//
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// The above example looks like this in the AST:
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//
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// CXXMethod foo
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// TypeRef struct S1
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// TypeRef class Foo
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// CompoundStmt
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// ...
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//
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// The second TypeRef is an uninteresting usage.
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bool process_last_type_ref = true;
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if (IsTypeDefinition(semantic_container) && !IsTypeDefinition(lexical_container)) {
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assert(decl_cursor.is_definition());
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process_last_type_ref = false;
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}
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VisitDeclForTypeUsageParam param(db, is_interesting);
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decl_cursor.VisitChildren(&VisitDeclForTypeUsageVisitor, ¶m);
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// VisitDeclForTypeUsageVisitor guarantees that if there are multiple TypeRef
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// children, the first one will always be visited.
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if (param.previous_cursor && process_last_type_ref) {
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VisitDeclForTypeUsageVisitorHandler(param.previous_cursor.value(), ¶m);
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}
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else {
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// If we are not processing the last type ref, it *must* be a TypeRef (ie,
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// and not a TemplateRef).
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assert(!param.previous_cursor.has_value() ||
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param.previous_cursor.value().get_kind() == CXCursor_TypeRef);
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}
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return param.initial_type;
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}
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void indexDeclaration(CXClientData client_data, const CXIdxDeclInfo* decl) {
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bool is_system_def = clang_Location_isInSystemHeader(clang_getCursorLocation(decl->cursor));
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IndexParam* param = static_cast<IndexParam*>(client_data);
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IndexedFile* db = param->db;
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NamespaceHelper* ns = param->ns;
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switch (decl->entityInfo->kind) {
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case CXIdxEntity_CXXNamespace:
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{
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ns->RegisterQualifiedName(decl->entityInfo->USR, decl->semanticContainer, decl->entityInfo->name);
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break;
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}
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case CXIdxEntity_EnumConstant:
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case CXIdxEntity_Field:
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case CXIdxEntity_Variable:
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case CXIdxEntity_CXXStaticVariable:
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{
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clang::Cursor decl_cursor = decl->cursor;
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VarId var_id = db->ToVarId(decl->entityInfo->USR);
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IndexedVarDef* var_def = db->Resolve(var_id);
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var_def->is_bad_def = is_system_def;
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// TODO: Eventually run with this if. Right now I want to iron out bugs this may shadow.
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// TODO: Verify this gets called multiple times
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//if (!decl->isRedeclaration) {
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var_def->def.short_name = decl->entityInfo->name;
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var_def->def.qualified_name = ns->QualifiedName(decl->semanticContainer, var_def->def.short_name);
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//}
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Location decl_loc = db->id_cache->Resolve(decl->loc, false /*interesting*/);
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if (decl->isDefinition)
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var_def->def.definition = decl_loc;
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else
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var_def->def.declaration = decl_loc;
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var_def->uses.push_back(decl_loc);
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// Declaring variable type information. Note that we do not insert an
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// interesting reference for parameter declarations - that is handled when
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// the function declaration is encountered since we won't receive ParmDecl
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// declarations for unnamed parameters.
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optional<TypeId> var_type = ResolveDeclToType(db, decl_cursor, decl_cursor.get_kind() != CXCursor_ParmDecl /*is_interesting*/, decl->semanticContainer, decl->lexicalContainer);
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if (var_type.has_value())
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var_def->def.variable_type = var_type.value();
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if (decl->isDefinition && IsTypeDefinition(decl->semanticContainer)) {
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TypeId declaring_type_id = db->ToTypeId(decl->semanticContainer->cursor);
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IndexedTypeDef* declaring_type_def = db->Resolve(declaring_type_id);
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var_def->def.declaring_type = declaring_type_id;
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declaring_type_def->def.vars.push_back(var_id);
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}
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break;
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}
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case CXIdxEntity_Function:
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case CXIdxEntity_CXXConstructor:
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case CXIdxEntity_CXXDestructor:
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case CXIdxEntity_CXXInstanceMethod:
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case CXIdxEntity_CXXStaticMethod:
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case CXIdxEntity_CXXConversionFunction:
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{
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clang::Cursor decl_cursor = decl->cursor;
|
|
FuncId func_id = db->ToFuncId(decl->entityInfo->USR);
|
|
IndexedFuncDef* func_def = db->Resolve(func_id);
|
|
|
|
func_def->is_bad_def = is_system_def;
|
|
|
|
// TODO: Eventually run with this if. Right now I want to iron out bugs this may shadow.
|
|
//if (!decl->isRedeclaration) {
|
|
func_def->def.short_name = decl->entityInfo->name;
|
|
func_def->def.qualified_name = ns->QualifiedName(decl->semanticContainer, func_def->def.short_name);
|
|
//}
|
|
|
|
Location decl_loc = db->id_cache->Resolve(decl->loc, false /*interesting*/);
|
|
if (decl->isDefinition)
|
|
func_def->def.definition = decl_loc;
|
|
else
|
|
func_def->declarations.push_back(decl_loc);
|
|
func_def->uses.push_back(decl_loc);
|
|
|
|
bool is_pure_virtual = clang_CXXMethod_isPureVirtual(decl->cursor);
|
|
bool is_ctor_or_dtor = decl->entityInfo->kind == CXIdxEntity_CXXConstructor || decl->entityInfo->kind == CXIdxEntity_CXXDestructor;
|
|
//bool process_declaring_type = is_pure_virtual || is_ctor_or_dtor;
|
|
|
|
// Add function usage information. We only want to do it once per
|
|
// definition/declaration. Do it on definition since there should only ever
|
|
// be one of those in the entire program.
|
|
if (IsTypeDefinition(decl->semanticContainer)) {
|
|
TypeId declaring_type_id = db->ToTypeId(decl->semanticContainer->cursor);
|
|
IndexedTypeDef* declaring_type_def = db->Resolve(declaring_type_id);
|
|
func_def->def.declaring_type = declaring_type_id;
|
|
|
|
// Mark a type reference at the ctor/dtor location.
|
|
// TODO: Should it be interesting?
|
|
if (is_ctor_or_dtor) {
|
|
Location type_usage_loc = decl_loc;
|
|
declaring_type_def->AddUsage(type_usage_loc);
|
|
}
|
|
|
|
// Register function in declaring type if it hasn't been registered yet.
|
|
if (!Contains(declaring_type_def->def.funcs, func_id))
|
|
declaring_type_def->def.funcs.push_back(func_id);
|
|
}
|
|
|
|
|
|
|
|
// We don't actually need to know the return type, but we need to mark it
|
|
// as an interesting usage.
|
|
ResolveDeclToType(db, decl_cursor, true /*is_interesting*/, decl->semanticContainer, decl->lexicalContainer);
|
|
|
|
//TypeResolution ret_type = ResolveToType(db, decl_cursor.get_type().get_return_type());
|
|
//if (ret_type.resolved_type)
|
|
// AddInterestingUsageToType(db, ret_type, FindLocationOfTypeSpecifier(decl_cursor));
|
|
|
|
if (decl->isDefinition || is_pure_virtual) {
|
|
// Mark type usage for parameters as interesting. We handle this here
|
|
// instead of inside var declaration because clang will not emit a var
|
|
// declaration for an unnamed parameter, but we still want to mark the
|
|
// usage as interesting.
|
|
// TODO: Do a similar thing for function decl parameter usages. Mark
|
|
// prototype params as interesting type usages but also relate mark
|
|
// them as as usages on the primary variable - requires USR to be
|
|
// the same. We can work around it by declaring which variables a
|
|
// parameter has declared and update the USR in the definition.
|
|
clang::Cursor cursor = decl->cursor;
|
|
for (clang::Cursor arg : cursor.get_arguments()) {
|
|
switch (arg.get_kind()) {
|
|
case CXCursor_ParmDecl:
|
|
// We don't need to know the arg type, but we do want to mark it as
|
|
// an interesting usage.
|
|
ResolveDeclToType(db, arg, true /*is_interesting*/, decl->semanticContainer, decl->lexicalContainer);
|
|
|
|
//TypeResolution arg_type = ResolveToType(db, arg.get_type());
|
|
//if (arg_type.resolved_type)
|
|
// AddInterestingUsageToType(db, arg_type, FindLocationOfTypeSpecifier(arg));
|
|
break;
|
|
}
|
|
}
|
|
|
|
|
|
// Process inheritance.
|
|
//void clang_getOverriddenCursors(CXCursor cursor, CXCursor **overridden, unsigned *num_overridden);
|
|
//void clang_disposeOverriddenCursors(CXCursor *overridden);
|
|
if (clang_CXXMethod_isVirtual(decl->cursor)) {
|
|
CXCursor* overridden;
|
|
unsigned int num_overridden;
|
|
clang_getOverriddenCursors(decl->cursor, &overridden, &num_overridden);
|
|
|
|
// TODO: How to handle multiple parent overrides??
|
|
for (unsigned int i = 0; i < num_overridden; ++i) {
|
|
clang::Cursor parent = overridden[i];
|
|
FuncId parent_id = db->ToFuncId(parent.get_usr());
|
|
IndexedFuncDef* parent_def = db->Resolve(parent_id);
|
|
func_def = db->Resolve(func_id); // ToFuncId invalidated func_def
|
|
|
|
func_def->def.base = parent_id;
|
|
parent_def->derived.push_back(func_id);
|
|
}
|
|
|
|
clang_disposeOverriddenCursors(overridden);
|
|
}
|
|
}
|
|
|
|
/*
|
|
optional<FuncId> base;
|
|
std::vector<FuncId> derived;
|
|
std::vector<VarId> locals;
|
|
std::vector<FuncRef> callers;
|
|
std::vector<FuncRef> callees;
|
|
std::vector<Location> uses;
|
|
*/
|
|
break;
|
|
}
|
|
|
|
case CXIdxEntity_Typedef:
|
|
case CXIdxEntity_CXXTypeAlias:
|
|
{
|
|
optional<TypeId> alias_of = ResolveDeclToType(db, decl->cursor, true /*is_interesting*/, decl->semanticContainer, decl->lexicalContainer);
|
|
|
|
TypeId type_id = db->ToTypeId(decl->entityInfo->USR);
|
|
IndexedTypeDef* type_def = db->Resolve(type_id);
|
|
|
|
type_def->is_bad_def = is_system_def;
|
|
|
|
if (alias_of)
|
|
type_def->def.alias_of = alias_of.value();
|
|
|
|
type_def->def.short_name = decl->entityInfo->name;
|
|
type_def->def.qualified_name = ns->QualifiedName(decl->semanticContainer, type_def->def.short_name);
|
|
|
|
Location decl_loc = db->id_cache->Resolve(decl->loc, true /*interesting*/);
|
|
type_def->def.definition = decl_loc.WithInteresting(false);
|
|
type_def->AddUsage(decl_loc);
|
|
break;
|
|
}
|
|
|
|
case CXIdxEntity_Enum:
|
|
case CXIdxEntity_Union:
|
|
case CXIdxEntity_Struct:
|
|
case CXIdxEntity_CXXClass:
|
|
{
|
|
TypeId type_id = db->ToTypeId(decl->entityInfo->USR);
|
|
IndexedTypeDef* type_def = db->Resolve(type_id);
|
|
|
|
type_def->is_bad_def = is_system_def;
|
|
|
|
// TODO: Eventually run with this if. Right now I want to iron out bugs this may shadow.
|
|
// TODO: For type section, verify if this ever runs for non definitions?
|
|
//if (!decl->isRedeclaration) {
|
|
|
|
// name can be null in an anonymous struct (see tests/types/anonymous_struct.cc).
|
|
if (decl->entityInfo->name) {
|
|
ns->RegisterQualifiedName(decl->entityInfo->USR, decl->semanticContainer, decl->entityInfo->name);
|
|
type_def->def.short_name = decl->entityInfo->name;
|
|
}
|
|
else {
|
|
type_def->def.short_name = "<anonymous>";
|
|
}
|
|
|
|
type_def->def.qualified_name = ns->QualifiedName(decl->semanticContainer, type_def->def.short_name);
|
|
|
|
// }
|
|
|
|
assert(decl->isDefinition);
|
|
Location decl_loc = db->id_cache->Resolve(decl->loc, true /*interesting*/);
|
|
type_def->def.definition = decl_loc.WithInteresting(false);
|
|
type_def->AddUsage(decl_loc);
|
|
|
|
//type_def->alias_of
|
|
//type_def->funcs
|
|
//type_def->types
|
|
//type_def->uses
|
|
//type_def->vars
|
|
|
|
// Add type-level inheritance information.
|
|
CXIdxCXXClassDeclInfo const* class_info = clang_index_getCXXClassDeclInfo(decl);
|
|
if (class_info) {
|
|
for (unsigned int i = 0; i < class_info->numBases; ++i) {
|
|
const CXIdxBaseClassInfo* base_class = class_info->bases[i];
|
|
|
|
optional<TypeId> parent_type_id = ResolveDeclToType(db, base_class->cursor, true /*is_interesting*/, decl->semanticContainer, decl->lexicalContainer);
|
|
IndexedTypeDef* type_def = db->Resolve(type_id); // type_def ptr could be invalidated by ResolveDeclToType.
|
|
if (parent_type_id) {
|
|
IndexedTypeDef* parent_type_def = db->Resolve(parent_type_id.value());
|
|
parent_type_def->derived.push_back(type_id);
|
|
type_def->def.parents.push_back(parent_type_id.value());
|
|
}
|
|
}
|
|
}
|
|
break;
|
|
}
|
|
|
|
default:
|
|
std::cout << "!! Unhandled indexDeclaration: " << clang::Cursor(decl->cursor).ToString() << " at " << db->id_cache->Resolve(decl->loc, false /*interesting*/).ToString() << std::endl;
|
|
std::cout << " entityInfo->kind = " << decl->entityInfo->kind << std::endl;
|
|
std::cout << " entityInfo->USR = " << decl->entityInfo->USR << std::endl;
|
|
if (decl->declAsContainer)
|
|
std::cout << " declAsContainer = " << clang::Cursor(decl->declAsContainer->cursor).ToString() << std::endl;
|
|
if (decl->semanticContainer)
|
|
std::cout << " semanticContainer = " << clang::Cursor(decl->semanticContainer->cursor).ToString() << std::endl;
|
|
if (decl->lexicalContainer)
|
|
std::cout << " lexicalContainer = " << clang::Cursor(decl->lexicalContainer->cursor).get_usr() << std::endl;
|
|
break;
|
|
}
|
|
}
|
|
|
|
bool IsFunction(CXCursorKind kind) {
|
|
switch (kind) {
|
|
case CXCursor_CXXMethod:
|
|
case CXCursor_FunctionDecl:
|
|
return true;
|
|
}
|
|
|
|
return false;
|
|
}
|
|
|
|
void indexEntityReference(CXClientData client_data, const CXIdxEntityRefInfo* ref) {
|
|
IndexParam* param = static_cast<IndexParam*>(client_data);
|
|
IndexedFile* db = param->db;
|
|
clang::Cursor cursor(ref->cursor);
|
|
|
|
switch (ref->referencedEntity->kind) {
|
|
case CXIdxEntity_EnumConstant:
|
|
case CXIdxEntity_CXXStaticVariable:
|
|
case CXIdxEntity_Variable:
|
|
case CXIdxEntity_Field:
|
|
{
|
|
VarId var_id = db->ToVarId(ref->referencedEntity->cursor);
|
|
IndexedVarDef* var_def = db->Resolve(var_id);
|
|
var_def->uses.push_back(db->id_cache->Resolve(ref->loc, false /*interesting*/));
|
|
break;
|
|
}
|
|
|
|
case CXIdxEntity_CXXConversionFunction:
|
|
case CXIdxEntity_CXXStaticMethod:
|
|
case CXIdxEntity_CXXInstanceMethod:
|
|
case CXIdxEntity_Function:
|
|
case CXIdxEntity_CXXConstructor:
|
|
case CXIdxEntity_CXXDestructor:
|
|
{
|
|
// TODO: Redirect container to constructor for the following example, ie,
|
|
// we should be inserting an outgoing function call from the Foo
|
|
// ctor.
|
|
//
|
|
// int Gen() { return 5; }
|
|
// class Foo {
|
|
// int x = Gen();
|
|
// }
|
|
|
|
// Don't report duplicate usages.
|
|
// TODO: search full history?
|
|
Location loc = db->id_cache->Resolve(ref->loc, false /*interesting*/);
|
|
if (param->last_func_usage_location == loc) break;
|
|
param->last_func_usage_location = loc;
|
|
|
|
// Note: be careful, calling db->ToFuncId invalidates the FuncDef* ptrs.
|
|
FuncId called_id = db->ToFuncId(ref->referencedEntity->USR);
|
|
if (IsFunction(ref->container->cursor.kind)) {
|
|
FuncId caller_id = db->ToFuncId(ref->container->cursor);
|
|
IndexedFuncDef* caller_def = db->Resolve(caller_id);
|
|
IndexedFuncDef* called_def = db->Resolve(called_id);
|
|
|
|
caller_def->def.callees.push_back(FuncRef(called_id, loc));
|
|
called_def->callers.push_back(FuncRef(caller_id, loc));
|
|
called_def->uses.push_back(loc);
|
|
}
|
|
else {
|
|
IndexedFuncDef* called_def = db->Resolve(called_id);
|
|
called_def->uses.push_back(loc);
|
|
}
|
|
|
|
// For constructor/destructor, also add a usage against the type. Clang
|
|
// will insert and visit implicit constructor references, so we also check
|
|
// the location of the ctor call compared to the parent call. If they are
|
|
// the same, this is most likely an implicit ctors.
|
|
clang::Cursor ref_cursor = ref->cursor;
|
|
if (ref->referencedEntity->kind == CXIdxEntity_CXXConstructor ||
|
|
ref->referencedEntity->kind == CXIdxEntity_CXXDestructor) {
|
|
|
|
Location parent_loc = db->id_cache->Resolve(ref->parentEntity->cursor, true /*interesting*/);
|
|
Location our_loc = db->id_cache->Resolve(ref->loc, true /*is_interesting*/);
|
|
if (!parent_loc.IsEqualTo(our_loc)) {
|
|
IndexedFuncDef* called_def = db->Resolve(called_id);
|
|
assert(called_def->def.declaring_type.has_value());
|
|
IndexedTypeDef* type_def = db->Resolve(called_def->def.declaring_type.value());
|
|
type_def->AddUsage(our_loc);
|
|
}
|
|
}
|
|
break;
|
|
}
|
|
|
|
case CXIdxEntity_Typedef:
|
|
case CXIdxEntity_CXXTypeAlias:
|
|
case CXIdxEntity_Enum:
|
|
case CXIdxEntity_Union:
|
|
case CXIdxEntity_Struct:
|
|
case CXIdxEntity_CXXClass:
|
|
{
|
|
TypeId referenced_id = db->ToTypeId(ref->referencedEntity->USR);
|
|
IndexedTypeDef* referenced_def = db->Resolve(referenced_id);
|
|
|
|
// We will not get a declaration visit for forward declared types. Try to mark them as non-bad
|
|
// defs here so we will output usages/etc.
|
|
if (referenced_def->is_bad_def) {
|
|
bool is_system_def = clang_Location_isInSystemHeader(clang_getCursorLocation(ref->referencedEntity->cursor));
|
|
Location loc = db->id_cache->Resolve(ref->referencedEntity->cursor, false /*interesting*/);
|
|
if (!is_system_def && loc.raw_file_id != -1)
|
|
referenced_def->is_bad_def = false;
|
|
}
|
|
//
|
|
// The following will generate two TypeRefs to Foo, both located at the
|
|
// same spot (line 3, column 3). One of the parents will be set to
|
|
// CXIdxEntity_Variable, the other will be CXIdxEntity_Function. There does
|
|
// not appear to be a good way to disambiguate these references, as using
|
|
// parent type alone breaks other indexing tasks.
|
|
//
|
|
// To work around this, we check to see if the usage location has been
|
|
// inserted into all_uses previously.
|
|
//
|
|
// struct Foo {};
|
|
// void Make() {
|
|
// Foo f;
|
|
// }
|
|
//
|
|
referenced_def->AddUsage(db->id_cache->Resolve(ref->loc, false /*interesting*/));
|
|
break;
|
|
}
|
|
|
|
default:
|
|
std::cout << "!! Unhandled indexEntityReference: " << cursor.ToString() << " at " << db->id_cache->Resolve(ref->loc, false /*interesting*/).ToString() << std::endl;
|
|
std::cout << " ref->referencedEntity->kind = " << ref->referencedEntity->kind << std::endl;
|
|
if (ref->parentEntity)
|
|
std::cout << " ref->parentEntity->kind = " << ref->parentEntity->kind << std::endl;
|
|
std::cout << " ref->loc = " << db->id_cache->Resolve(ref->loc, false /*interesting*/).ToString() << std::endl;
|
|
std::cout << " ref->kind = " << ref->kind << std::endl;
|
|
if (ref->parentEntity)
|
|
std::cout << " parentEntity = " << clang::Cursor(ref->parentEntity->cursor).ToString() << std::endl;
|
|
if (ref->referencedEntity)
|
|
std::cout << " referencedEntity = " << clang::Cursor(ref->referencedEntity->cursor).ToString() << std::endl;
|
|
if (ref->container)
|
|
std::cout << " container = " << clang::Cursor(ref->container->cursor).ToString() << std::endl;
|
|
break;
|
|
}
|
|
}
|
|
|
|
|
|
IndexedFile Parse(IdCache* id_cache, std::string filename, std::vector<std::string> args, bool dump_ast) {
|
|
clang::Index index(0 /*excludeDeclarationsFromPCH*/, 0 /*displayDiagnostics*/);
|
|
clang::TranslationUnit tu(index, filename, args);
|
|
|
|
if (dump_ast)
|
|
Dump(tu.document_cursor());
|
|
|
|
CXIndexAction index_action = clang_IndexAction_create(index.cx_index);
|
|
|
|
IndexerCallbacks callbacks[] = {
|
|
{ &abortQuery, &diagnostic, &enteredMainFile, &ppIncludedFile, &importedASTFile, &startedTranslationUnit, &indexDeclaration, &indexEntityReference }
|
|
/*
|
|
callbacks.abortQuery = &abortQuery;
|
|
callbacks.diagnostic = &diagnostic;
|
|
callbacks.enteredMainFile = &enteredMainFile;
|
|
callbacks.ppIncludedFile = &ppIncludedFile;
|
|
callbacks.importedASTFile = &importedASTFile;
|
|
callbacks.startedTranslationUnit = &startedTranslationUnit;
|
|
callbacks.indexDeclaration = &indexDeclaration;
|
|
callbacks.indexEntityReference = &indexEntityReference;
|
|
*/
|
|
};
|
|
|
|
IndexedFile db(filename, id_cache);
|
|
NamespaceHelper ns;
|
|
IndexParam param(&db, &ns);
|
|
clang_indexTranslationUnit(index_action, ¶m, callbacks, sizeof(callbacks),
|
|
CXIndexOpt_IndexFunctionLocalSymbols | CXIndexOpt_SkipParsedBodiesInSession, tu.cx_tu);
|
|
|
|
clang_IndexAction_dispose(index_action);
|
|
|
|
return db;
|
|
}
|