// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception // -*- Mode: C++ -*- // // Copyright (C) 2020 Google, Inc. // // Author: Matthias Maennich /// @file /// /// This program tests symtab invariants through abg-corpus. #include #include #include #include #include "abg-corpus.h" #include "abg-dwarf-reader.h" #include "abg-fwd.h" #include "abg-ir.h" #include "abg-tools-utils.h" #include "lib/catch.hpp" #include "test-utils.h" using namespace abigail; using dwarf_reader::create_read_context; using dwarf_reader::read_context_sptr; using dwarf_reader::read_corpus_from_elf; using ir::environment; using ir::environment_sptr; using suppr::suppressions_type; static const std::string test_data_dir = std::string(abigail::tests::get_src_dir()) + "/tests/data/test-symtab/"; dwarf_reader::status read_corpus(const std::string& path, corpus_sptr& result, const std::vector& whitelist_paths = std::vector()) { const std::string& absolute_path = test_data_dir + path; environment_sptr env(new environment); const std::vector debug_info_root_paths; read_context_sptr ctxt = create_read_context(absolute_path, debug_info_root_paths, env.get(), /* load_all_type = */ true, /* linux_kernel_mode = */ true); if (!whitelist_paths.empty()) { const suppressions_type& wl_suppr = tools_utils::gen_suppr_spec_from_kernel_abi_whitelists( whitelist_paths); REQUIRE_FALSE(wl_suppr.empty()); dwarf_reader::add_read_context_suppressions(*ctxt, wl_suppr); } dwarf_reader::status status = dwarf_reader::STATUS_UNKNOWN; result = read_corpus_from_elf(*ctxt, status); REQUIRE(status != dwarf_reader::STATUS_UNKNOWN); return status; } TEST_CASE("Symtab::Empty", "[symtab, basic]") { const std::string binary = "basic/empty.so"; corpus_sptr corpus_ptr; const dwarf_reader::status status = read_corpus(binary, corpus_ptr); REQUIRE(!corpus_ptr); REQUIRE((status & dwarf_reader::STATUS_NO_SYMBOLS_FOUND)); } TEST_CASE("Symtab::NoDebugInfo", "[symtab, basic]") { const std::string binary = "basic/no_debug_info.so"; corpus_sptr corpus_ptr; const dwarf_reader::status status = read_corpus(binary, corpus_ptr); REQUIRE(corpus_ptr); REQUIRE(status == (dwarf_reader::STATUS_OK | dwarf_reader::STATUS_DEBUG_INFO_NOT_FOUND)); } // this value indicates in the following helper method, that we do not want to // assert for this particular value. In other words, N is a placeholder for an // arbitrary value. #define N std::numeric_limits::max() corpus_sptr assert_symbol_count(const std::string& path, size_t function_symbols = 0, size_t variable_symbols = 0, size_t undefined_function_symbols = 0, size_t undefined_variable_symbols = 0, const std::vector& whitelist_paths = std::vector()) { corpus_sptr corpus_ptr; const dwarf_reader::status status = read_corpus(path, corpus_ptr, whitelist_paths); REQUIRE(corpus_ptr); REQUIRE((status & dwarf_reader::STATUS_OK)); const corpus& corpus = *corpus_ptr; size_t total_symbols = 0; if (function_symbols != N) { CHECK(corpus.get_sorted_fun_symbols().size() == function_symbols); CHECK(corpus.get_fun_symbol_map().size() == function_symbols); total_symbols += function_symbols; } if (variable_symbols != N) { CHECK(corpus.get_sorted_var_symbols().size() == variable_symbols); CHECK(corpus.get_var_symbol_map().size() == variable_symbols); total_symbols += variable_symbols; } if (undefined_variable_symbols != N) { CHECK(corpus.get_sorted_undefined_fun_symbols().size() == undefined_function_symbols); CHECK(corpus.get_undefined_fun_symbol_map().size() == undefined_function_symbols); total_symbols += undefined_function_symbols; } if (undefined_function_symbols != N) { CHECK(corpus.get_sorted_undefined_var_symbols().size() == undefined_variable_symbols); CHECK(corpus.get_undefined_var_symbol_map().size() == undefined_variable_symbols); total_symbols += undefined_variable_symbols; } // assert the corpus reports being empty consistently with the symbol count CHECK(corpus.is_empty() == (total_symbols == 0)); return corpus_ptr; } TEST_CASE("Symtab::SimpleSymtabs", "[symtab, basic]") { GIVEN("a binary with no exported symbols") { // TODO: should pass, but does currently not as empty tables are treated // like the error case, but this is an edge case anyway. // assert_symbol_count("empty.so"); } GIVEN("a binary with a single exported function") { const std::string binary = "basic/single_function.so"; const corpus_sptr& corpus = assert_symbol_count(binary, 1, 0); const elf_symbol_sptr& symbol = corpus->lookup_function_symbol("exported_function"); REQUIRE(symbol); CHECK(!corpus->lookup_variable_symbol("exported_function")); CHECK(symbol == corpus->lookup_function_symbol(*symbol)); CHECK(symbol != corpus->lookup_variable_symbol(*symbol)); } GIVEN("a binary with a single exported variable") { const std::string binary = "basic/single_variable.so"; const corpus_sptr& corpus = assert_symbol_count(binary, 0, 1); const elf_symbol_sptr& symbol = corpus->lookup_variable_symbol("exported_variable"); REQUIRE(symbol); CHECK(!corpus->lookup_function_symbol("exported_variable")); CHECK(symbol == corpus->lookup_variable_symbol(*symbol)); CHECK(symbol != corpus->lookup_function_symbol(*symbol)); } GIVEN("a binary with one function and one variable exported") { const std::string binary = "basic/one_function_one_variable.so"; const corpus_sptr& corpus = assert_symbol_count(binary, 1, 1); CHECK(corpus->lookup_function_symbol("exported_function")); CHECK(!corpus->lookup_variable_symbol("exported_function")); CHECK(corpus->lookup_variable_symbol("exported_variable")); CHECK(!corpus->lookup_function_symbol("exported_variable")); } GIVEN("a binary with a single undefined function") { const std::string binary = "basic/single_undefined_function.so"; const corpus_sptr corpus = assert_symbol_count(binary, 0, 0, 1, 0); } GIVEN("a binary with a single undefined variable") { const std::string binary = "basic/single_undefined_variable.so"; const corpus_sptr corpus = assert_symbol_count(binary, 0, 0, 0, 1); } GIVEN("a binary with one function and one variable undefined") { const std::string binary = "basic/one_function_one_variable_undefined.so"; const corpus_sptr corpus = assert_symbol_count(binary, 0, 0, 1, 1); } } TEST_CASE("Symtab::SymtabWithWhitelist", "[symtab, whitelist]") { GIVEN("a binary with one function and one variable exported") { const std::string binary = "basic/one_function_one_variable.so"; GIVEN("we read the binary without any whitelists") { const corpus_sptr& corpus = assert_symbol_count(binary, 1, 1); CHECK(corpus->lookup_function_symbol("exported_function")); CHECK(!corpus->lookup_variable_symbol("exported_function")); CHECK(corpus->lookup_variable_symbol("exported_variable")); CHECK(!corpus->lookup_function_symbol("exported_variable")); } GIVEN("we read the binary with all symbols on the whitelists") { std::vector whitelists; whitelists.push_back(test_data_dir + "basic/one_function_one_variable_all.whitelist"); const corpus_sptr& corpus = assert_symbol_count(binary, 1, 1, 0, 0, whitelists); CHECK(corpus->lookup_function_symbol("exported_function")); CHECK(!corpus->lookup_variable_symbol("exported_function")); CHECK(corpus->lookup_variable_symbol("exported_variable")); CHECK(!corpus->lookup_function_symbol("exported_variable")); } GIVEN("we read the binary with only irrelevant symbols whitelisted") { std::vector whitelists; whitelists.push_back( test_data_dir + "basic/one_function_one_variable_irrelevant.whitelist"); corpus_sptr corpus_ptr; const dwarf_reader::status status = read_corpus(binary, corpus_ptr, whitelists); REQUIRE(!corpus_ptr); REQUIRE((status & dwarf_reader::STATUS_NO_SYMBOLS_FOUND)); } GIVEN("we read the binary with only the function whitelisted") { std::vector whitelists; whitelists.push_back( test_data_dir + "basic/one_function_one_variable_function.whitelist"); const corpus_sptr& corpus = assert_symbol_count(binary, 1, 0, 0, 0, whitelists); CHECK(corpus->lookup_function_symbol("exported_function")); CHECK(!corpus->lookup_variable_symbol("exported_function")); CHECK(!corpus->lookup_variable_symbol("exported_variable")); CHECK(!corpus->lookup_function_symbol("exported_variable")); } GIVEN("we read the binary with only the variable whitelisted") { std::vector whitelists; whitelists.push_back( test_data_dir + "basic/one_function_one_variable_variable.whitelist"); const corpus_sptr& corpus = assert_symbol_count(binary, 0, 1, 0, 0, whitelists); CHECK(!corpus->lookup_function_symbol("exported_function")); CHECK(!corpus->lookup_variable_symbol("exported_function")); CHECK(corpus->lookup_variable_symbol("exported_variable")); CHECK(!corpus->lookup_function_symbol("exported_variable")); } } } TEST_CASE("Symtab::AliasedFunctionSymbols", "[symtab, functions, aliases]") { const std::string binary = "basic/aliases.so"; const corpus_sptr& corpus = assert_symbol_count(binary, 5, 5); // The main symbol is not necessarily the one that is aliased to in the // code So, this can't be decided by just looking at ELF. Hence acquire the // main symbol. const elf_symbol_sptr& main_symbol = corpus->lookup_function_symbol("exported_function")->get_main_symbol(); REQUIRE(main_symbol); // But since we know that 'exported_function' is the main symbol and this // can be discovered from DWARF CHECK(corpus->lookup_function_symbol("exported_function")->is_main_symbol()); CHECK(corpus->lookup_function_symbol("exported_function") ->get_number_of_aliases() == 4); CHECK(main_symbol->has_aliases()); CHECK(main_symbol->get_number_of_aliases() == 4); CHECK(main_symbol->get_main_symbol() == main_symbol); } TEST_CASE("Symtab::AliasedVariableSymbols", "[symtab, variables, aliases]") { const std::string binary = "basic/aliases.so"; const corpus_sptr& corpus = assert_symbol_count(binary, 5, 5); // The main symbol is not necessarily the one that is aliased to in the // code So, this can't be decided by just looking at ELF. Hence acquire the // main symbol. const elf_symbol_sptr& main_symbol = corpus->lookup_variable_symbol("exported_variable")->get_main_symbol(); REQUIRE(main_symbol); // But since we know that 'exported_function' is the main symbol and this // can be discovered from DWARF CHECK(corpus->lookup_variable_symbol("exported_variable")->is_main_symbol()); CHECK(corpus->lookup_variable_symbol("exported_variable") ->get_number_of_aliases() == 4); CHECK(main_symbol->has_aliases()); CHECK(main_symbol->get_number_of_aliases() == 4); CHECK(main_symbol->get_main_symbol() == main_symbol); } static const char* kernel_versions[] = { "4.14", "4.19", "5.4", "5.6" }; static const size_t nr_kernel_versions = sizeof(kernel_versions) / sizeof(kernel_versions[0]); TEST_CASE("Symtab::SimpleKernelSymtabs", "[symtab, basic, kernel, ksymtab]") { for (size_t i = 0; i < nr_kernel_versions; ++i) { const std::string base_path = "kernel-" + std::string(kernel_versions[i]) + "/"; GIVEN("The binaries in " + base_path) { GIVEN("a kernel module with no exported symbols") { // TODO: should pass, but does currently not as empty tables are // treated // like the error case, but this is an edge case anyway. // assert_symbol_count(base_path + "empty.so"); } GIVEN("a kernel module with a single exported function") { const std::string binary = base_path + "single_function.ko"; const corpus_sptr& corpus = assert_symbol_count(binary, 1, 0); const elf_symbol_sptr& symbol = corpus->lookup_function_symbol("exported_function"); REQUIRE(symbol); CHECK(!corpus->lookup_variable_symbol("exported_function")); CHECK(symbol == corpus->lookup_function_symbol(*symbol)); CHECK(symbol != corpus->lookup_variable_symbol(*symbol)); } GIVEN("a kernel module with a single GPL exported function") { const std::string binary = base_path + "single_function_gpl.ko"; const corpus_sptr& corpus = assert_symbol_count(binary, 1, 0); const elf_symbol_sptr& symbol = corpus->lookup_function_symbol("exported_function_gpl"); REQUIRE(symbol); CHECK(!corpus->lookup_variable_symbol("exported_function_gpl")); CHECK(symbol == corpus->lookup_function_symbol(*symbol)); CHECK(symbol != corpus->lookup_variable_symbol(*symbol)); } GIVEN("a binary with a single exported variable") { const std::string binary = base_path + "single_variable.ko"; const corpus_sptr& corpus = assert_symbol_count(binary, 0, 1); const elf_symbol_sptr& symbol = corpus->lookup_variable_symbol("exported_variable"); REQUIRE(symbol); CHECK(!corpus->lookup_function_symbol("exported_variable")); CHECK(symbol == corpus->lookup_variable_symbol(*symbol)); CHECK(symbol != corpus->lookup_function_symbol(*symbol)); } GIVEN("a binary with a single GPL exported variable") { const std::string binary = base_path + "single_variable_gpl.ko"; const corpus_sptr& corpus = assert_symbol_count(binary, 0, 1); const elf_symbol_sptr& symbol = corpus->lookup_variable_symbol("exported_variable_gpl"); REQUIRE(symbol); CHECK(!corpus->lookup_function_symbol("exported_variable_gpl")); CHECK(symbol == corpus->lookup_variable_symbol(*symbol)); CHECK(symbol != corpus->lookup_function_symbol(*symbol)); } GIVEN("a binary with one function and one variable (GPL) exported") { const std::string binary = base_path + "one_of_each.ko"; const corpus_sptr& corpus = assert_symbol_count(binary, 2, 2); CHECK(corpus->lookup_function_symbol("exported_function")); CHECK(!corpus->lookup_variable_symbol("exported_function")); CHECK(corpus->lookup_function_symbol("exported_function_gpl")); CHECK(!corpus->lookup_variable_symbol("exported_function_gpl")); CHECK(corpus->lookup_variable_symbol("exported_variable")); CHECK(!corpus->lookup_function_symbol("exported_variable")); CHECK(corpus->lookup_variable_symbol("exported_variable_gpl")); CHECK(!corpus->lookup_function_symbol("exported_variable_gpl")); } } } } TEST_CASE("Symtab::KernelSymtabsWithCRC", "[symtab, crc, kernel, ksymtab]") { const std::string base_path = "kernel-modversions/"; GIVEN("a binary with one function and one variable (GPL) exported") { const std::string binary = base_path + "one_of_each.ko"; const corpus_sptr& corpus = assert_symbol_count(binary, 2, 2); CHECK(corpus->lookup_function_symbol("exported_function")->get_crc() != 0); CHECK(corpus->lookup_function_symbol("exported_function_gpl")->get_crc() != 0); CHECK(corpus->lookup_variable_symbol("exported_variable")->get_crc() != 0); CHECK(corpus->lookup_variable_symbol("exported_variable_gpl")->get_crc() != 0); } }