/* * Copyright (C) 2016 The Android Open Source Project * * Licensed under the Apache License, Version 2.0 (the "License"); * you may not use this file except in compliance with the License. * You may obtain a copy of the License at * * http://www.apache.org/licenses/LICENSE-2.0 * * Unless required by applicable law or agreed to in writing, software * distributed under the License is distributed on an "AS IS" BASIS, * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. * See the License for the specific language governing permissions and * limitations under the License. */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include "common/test_constants.h" #include "edify/expr.h" #include "otautil/SysUtil.h" #include "otautil/cache_location.h" #include "otautil/error_code.h" #include "otautil/print_sha1.h" #include "updater/blockimg.h" #include "updater/install.h" #include "updater/updater.h" struct selabel_handle *sehandle = nullptr; static void expect(const char* expected, const char* expr_str, CauseCode cause_code, UpdaterInfo* info = nullptr) { std::unique_ptr e; int error_count = 0; ASSERT_EQ(0, parse_string(expr_str, &e, &error_count)); ASSERT_EQ(0, error_count); State state(expr_str, info); std::string result; bool status = Evaluate(&state, e, &result); if (expected == nullptr) { ASSERT_FALSE(status); } else { ASSERT_TRUE(status); ASSERT_STREQ(expected, result.c_str()); } // Error code is set in updater/updater.cpp only, by parsing State.errmsg. ASSERT_EQ(kNoError, state.error_code); // Cause code should always be available. ASSERT_EQ(cause_code, state.cause_code); } static void BuildUpdatePackage(const std::unordered_map& entries, int fd) { FILE* zip_file_ptr = fdopen(fd, "wb"); ZipWriter zip_writer(zip_file_ptr); for (const auto& entry : entries) { ASSERT_EQ(0, zip_writer.StartEntry(entry.first.c_str(), 0)); if (!entry.second.empty()) { ASSERT_EQ(0, zip_writer.WriteBytes(entry.second.data(), entry.second.size())); } ASSERT_EQ(0, zip_writer.FinishEntry()); } ASSERT_EQ(0, zip_writer.Finish()); ASSERT_EQ(0, fclose(zip_file_ptr)); } static std::string get_sha1(const std::string& content) { uint8_t digest[SHA_DIGEST_LENGTH]; SHA1(reinterpret_cast(content.c_str()), content.size(), digest); return print_sha1(digest); } class UpdaterTest : public ::testing::Test { protected: virtual void SetUp() override { RegisterBuiltins(); RegisterInstallFunctions(); RegisterBlockImageFunctions(); // Mock the location of last_command_file. CacheLocation::location().set_cache_temp_source(temp_saved_source_.path); CacheLocation::location().set_last_command_file(temp_last_command_.path); CacheLocation::location().set_stash_directory_base(temp_stash_base_.path); } TemporaryFile temp_saved_source_; TemporaryFile temp_last_command_; TemporaryDir temp_stash_base_; }; TEST_F(UpdaterTest, getprop) { expect(android::base::GetProperty("ro.product.device", "").c_str(), "getprop(\"ro.product.device\")", kNoCause); expect(android::base::GetProperty("ro.build.fingerprint", "").c_str(), "getprop(\"ro.build.fingerprint\")", kNoCause); // getprop() accepts only one parameter. expect(nullptr, "getprop()", kArgsParsingFailure); expect(nullptr, "getprop(\"arg1\", \"arg2\")", kArgsParsingFailure); } TEST_F(UpdaterTest, sha1_check) { // sha1_check(data) returns the SHA-1 of the data. expect("81fe8bfe87576c3ecb22426f8e57847382917acf", "sha1_check(\"abcd\")", kNoCause); expect("da39a3ee5e6b4b0d3255bfef95601890afd80709", "sha1_check(\"\")", kNoCause); // sha1_check(data, sha1_hex, [sha1_hex, ...]) returns the matched SHA-1. expect("81fe8bfe87576c3ecb22426f8e57847382917acf", "sha1_check(\"abcd\", \"81fe8bfe87576c3ecb22426f8e57847382917acf\")", kNoCause); expect("81fe8bfe87576c3ecb22426f8e57847382917acf", "sha1_check(\"abcd\", \"wrong_sha1\", \"81fe8bfe87576c3ecb22426f8e57847382917acf\")", kNoCause); // Or "" if there's no match. expect("", "sha1_check(\"abcd\", \"wrong_sha1\")", kNoCause); expect("", "sha1_check(\"abcd\", \"wrong_sha1\", \"wrong_sha2\")", kNoCause); // sha1_check() expects at least one argument. expect(nullptr, "sha1_check()", kArgsParsingFailure); } TEST_F(UpdaterTest, apply_patch_check) { // Zero-argument is not valid. expect(nullptr, "apply_patch_check()", kArgsParsingFailure); // File not found. expect("", "apply_patch_check(\"/doesntexist\")", kNoCause); std::string src_file = from_testdata_base("old.file"); std::string src_content; ASSERT_TRUE(android::base::ReadFileToString(src_file, &src_content)); size_t src_size = src_content.size(); std::string src_hash = get_sha1(src_content); // One-argument with EMMC:file:size:sha1 should pass the check. std::string filename = android::base::Join( std::vector{ "EMMC", src_file, std::to_string(src_size), src_hash }, ":"); std::string cmd = "apply_patch_check(\"" + filename + "\")"; expect("t", cmd.c_str(), kNoCause); // EMMC:file:(size-1):sha1:(size+1):sha1 should fail the check. std::string filename_bad = android::base::Join( std::vector{ "EMMC", src_file, std::to_string(src_size - 1), src_hash, std::to_string(src_size + 1), src_hash }, ":"); cmd = "apply_patch_check(\"" + filename_bad + "\")"; expect("", cmd.c_str(), kNoCause); // EMMC:file:(size-1):sha1:size:sha1:(size+1):sha1 should pass the check. filename_bad = android::base::Join(std::vector{ "EMMC", src_file, std::to_string(src_size - 1), src_hash, std::to_string(src_size), src_hash, std::to_string(src_size + 1), src_hash }, ":"); cmd = "apply_patch_check(\"" + filename_bad + "\")"; expect("t", cmd.c_str(), kNoCause); // Multiple arguments. cmd = "apply_patch_check(\"" + filename + "\", \"wrong_sha1\", \"wrong_sha2\")"; expect("", cmd.c_str(), kNoCause); cmd = "apply_patch_check(\"" + filename + "\", \"wrong_sha1\", \"" + src_hash + "\", \"wrong_sha2\")"; expect("t", cmd.c_str(), kNoCause); cmd = "apply_patch_check(\"" + filename_bad + "\", \"wrong_sha1\", \"" + src_hash + "\", \"wrong_sha2\")"; expect("t", cmd.c_str(), kNoCause); } TEST_F(UpdaterTest, file_getprop) { // file_getprop() expects two arguments. expect(nullptr, "file_getprop()", kArgsParsingFailure); expect(nullptr, "file_getprop(\"arg1\")", kArgsParsingFailure); expect(nullptr, "file_getprop(\"arg1\", \"arg2\", \"arg3\")", kArgsParsingFailure); // File doesn't exist. expect(nullptr, "file_getprop(\"/doesntexist\", \"key1\")", kFileGetPropFailure); // Reject too large files (current limit = 65536). TemporaryFile temp_file1; std::string buffer(65540, '\0'); ASSERT_TRUE(android::base::WriteStringToFile(buffer, temp_file1.path)); // Read some keys. TemporaryFile temp_file2; std::string content("ro.product.name=tardis\n" "# comment\n\n\n" "ro.product.model\n" "ro.product.board = magic \n"); ASSERT_TRUE(android::base::WriteStringToFile(content, temp_file2.path)); std::string script1("file_getprop(\"" + std::string(temp_file2.path) + "\", \"ro.product.name\")"); expect("tardis", script1.c_str(), kNoCause); std::string script2("file_getprop(\"" + std::string(temp_file2.path) + "\", \"ro.product.board\")"); expect("magic", script2.c_str(), kNoCause); // No match. std::string script3("file_getprop(\"" + std::string(temp_file2.path) + "\", \"ro.product.wrong\")"); expect("", script3.c_str(), kNoCause); std::string script4("file_getprop(\"" + std::string(temp_file2.path) + "\", \"ro.product.name=\")"); expect("", script4.c_str(), kNoCause); std::string script5("file_getprop(\"" + std::string(temp_file2.path) + "\", \"ro.product.nam\")"); expect("", script5.c_str(), kNoCause); std::string script6("file_getprop(\"" + std::string(temp_file2.path) + "\", \"ro.product.model\")"); expect("", script6.c_str(), kNoCause); } // TODO: Test extracting to block device. TEST_F(UpdaterTest, package_extract_file) { // package_extract_file expects 1 or 2 arguments. expect(nullptr, "package_extract_file()", kArgsParsingFailure); expect(nullptr, "package_extract_file(\"arg1\", \"arg2\", \"arg3\")", kArgsParsingFailure); std::string zip_path = from_testdata_base("ziptest_valid.zip"); ZipArchiveHandle handle; ASSERT_EQ(0, OpenArchive(zip_path.c_str(), &handle)); // Need to set up the ziphandle. UpdaterInfo updater_info; updater_info.package_zip = handle; // Two-argument version. TemporaryFile temp_file1; std::string script("package_extract_file(\"a.txt\", \"" + std::string(temp_file1.path) + "\")"); expect("t", script.c_str(), kNoCause, &updater_info); // Verify the extracted entry. std::string data; ASSERT_TRUE(android::base::ReadFileToString(temp_file1.path, &data)); ASSERT_EQ(kATxtContents, data); // Now extract another entry to the same location, which should overwrite. script = "package_extract_file(\"b.txt\", \"" + std::string(temp_file1.path) + "\")"; expect("t", script.c_str(), kNoCause, &updater_info); ASSERT_TRUE(android::base::ReadFileToString(temp_file1.path, &data)); ASSERT_EQ(kBTxtContents, data); // Missing zip entry. The two-argument version doesn't abort. script = "package_extract_file(\"doesntexist\", \"" + std::string(temp_file1.path) + "\")"; expect("", script.c_str(), kNoCause, &updater_info); // Extract to /dev/full should fail. script = "package_extract_file(\"a.txt\", \"/dev/full\")"; expect("", script.c_str(), kNoCause, &updater_info); // One-argument version. script = "sha1_check(package_extract_file(\"a.txt\"))"; expect(kATxtSha1Sum.c_str(), script.c_str(), kNoCause, &updater_info); script = "sha1_check(package_extract_file(\"b.txt\"))"; expect(kBTxtSha1Sum.c_str(), script.c_str(), kNoCause, &updater_info); // Missing entry. The one-argument version aborts the evaluation. script = "package_extract_file(\"doesntexist\")"; expect(nullptr, script.c_str(), kPackageExtractFileFailure, &updater_info); CloseArchive(handle); } TEST_F(UpdaterTest, write_value) { // write_value() expects two arguments. expect(nullptr, "write_value()", kArgsParsingFailure); expect(nullptr, "write_value(\"arg1\")", kArgsParsingFailure); expect(nullptr, "write_value(\"arg1\", \"arg2\", \"arg3\")", kArgsParsingFailure); // filename cannot be empty. expect(nullptr, "write_value(\"value\", \"\")", kArgsParsingFailure); // Write some value to file. TemporaryFile temp_file; std::string value = "magicvalue"; std::string script("write_value(\"" + value + "\", \"" + std::string(temp_file.path) + "\")"); expect("t", script.c_str(), kNoCause); // Verify the content. std::string content; ASSERT_TRUE(android::base::ReadFileToString(temp_file.path, &content)); ASSERT_EQ(value, content); // Allow writing empty string. script = "write_value(\"\", \"" + std::string(temp_file.path) + "\")"; expect("t", script.c_str(), kNoCause); // Verify the content. ASSERT_TRUE(android::base::ReadFileToString(temp_file.path, &content)); ASSERT_EQ("", content); // It should fail gracefully when write fails. script = "write_value(\"value\", \"/proc/0/file1\")"; expect("", script.c_str(), kNoCause); } TEST_F(UpdaterTest, get_stage) { // get_stage() expects one argument. expect(nullptr, "get_stage()", kArgsParsingFailure); expect(nullptr, "get_stage(\"arg1\", \"arg2\")", kArgsParsingFailure); expect(nullptr, "get_stage(\"arg1\", \"arg2\", \"arg3\")", kArgsParsingFailure); // Set up a local file as BCB. TemporaryFile tf; std::string temp_file(tf.path); bootloader_message boot; strlcpy(boot.stage, "2/3", sizeof(boot.stage)); std::string err; ASSERT_TRUE(write_bootloader_message_to(boot, temp_file, &err)); // Can read the stage value. std::string script("get_stage(\"" + temp_file + "\")"); expect("2/3", script.c_str(), kNoCause); // Bad BCB path. script = "get_stage(\"doesntexist\")"; expect("", script.c_str(), kNoCause); } TEST_F(UpdaterTest, set_stage) { // set_stage() expects two arguments. expect(nullptr, "set_stage()", kArgsParsingFailure); expect(nullptr, "set_stage(\"arg1\")", kArgsParsingFailure); expect(nullptr, "set_stage(\"arg1\", \"arg2\", \"arg3\")", kArgsParsingFailure); // Set up a local file as BCB. TemporaryFile tf; std::string temp_file(tf.path); bootloader_message boot; strlcpy(boot.command, "command", sizeof(boot.command)); strlcpy(boot.stage, "2/3", sizeof(boot.stage)); std::string err; ASSERT_TRUE(write_bootloader_message_to(boot, temp_file, &err)); // Write with set_stage(). std::string script("set_stage(\"" + temp_file + "\", \"1/3\")"); expect(tf.path, script.c_str(), kNoCause); // Verify. bootloader_message boot_verify; ASSERT_TRUE(read_bootloader_message_from(&boot_verify, temp_file, &err)); // Stage should be updated, with command part untouched. ASSERT_STREQ("1/3", boot_verify.stage); ASSERT_STREQ(boot.command, boot_verify.command); // Bad BCB path. script = "set_stage(\"doesntexist\", \"1/3\")"; expect("", script.c_str(), kNoCause); script = "set_stage(\"/dev/full\", \"1/3\")"; expect("", script.c_str(), kNoCause); } TEST_F(UpdaterTest, set_progress) { // set_progress() expects one argument. expect(nullptr, "set_progress()", kArgsParsingFailure); expect(nullptr, "set_progress(\"arg1\", \"arg2\")", kArgsParsingFailure); // Invalid progress argument. expect(nullptr, "set_progress(\"arg1\")", kArgsParsingFailure); expect(nullptr, "set_progress(\"3x+5\")", kArgsParsingFailure); expect(nullptr, "set_progress(\".3.5\")", kArgsParsingFailure); TemporaryFile tf; UpdaterInfo updater_info; updater_info.cmd_pipe = fdopen(tf.release(), "w"); expect(".52", "set_progress(\".52\")", kNoCause, &updater_info); fflush(updater_info.cmd_pipe); std::string cmd; ASSERT_TRUE(android::base::ReadFileToString(tf.path, &cmd)); ASSERT_EQ(android::base::StringPrintf("set_progress %f\n", .52), cmd); // recovery-updater protocol expects 2 tokens ("set_progress "). ASSERT_EQ(2U, android::base::Split(cmd, " ").size()); ASSERT_EQ(0, fclose(updater_info.cmd_pipe)); } TEST_F(UpdaterTest, show_progress) { // show_progress() expects two arguments. expect(nullptr, "show_progress()", kArgsParsingFailure); expect(nullptr, "show_progress(\"arg1\")", kArgsParsingFailure); expect(nullptr, "show_progress(\"arg1\", \"arg2\", \"arg3\")", kArgsParsingFailure); // Invalid progress arguments. expect(nullptr, "show_progress(\"arg1\", \"arg2\")", kArgsParsingFailure); expect(nullptr, "show_progress(\"3x+5\", \"10\")", kArgsParsingFailure); expect(nullptr, "show_progress(\".3\", \"5a\")", kArgsParsingFailure); TemporaryFile tf; UpdaterInfo updater_info; updater_info.cmd_pipe = fdopen(tf.release(), "w"); expect(".52", "show_progress(\".52\", \"10\")", kNoCause, &updater_info); fflush(updater_info.cmd_pipe); std::string cmd; ASSERT_TRUE(android::base::ReadFileToString(tf.path, &cmd)); ASSERT_EQ(android::base::StringPrintf("progress %f %d\n", .52, 10), cmd); // recovery-updater protocol expects 3 tokens ("progress "). ASSERT_EQ(3U, android::base::Split(cmd, " ").size()); ASSERT_EQ(0, fclose(updater_info.cmd_pipe)); } TEST_F(UpdaterTest, block_image_update_patch_data) { std::string src_content = std::string(4096, 'a') + std::string(4096, 'c'); std::string tgt_content = std::string(4096, 'b') + std::string(4096, 'd'); // Generate the patch data. TemporaryFile patch_file; ASSERT_EQ(0, bsdiff::bsdiff(reinterpret_cast(src_content.data()), src_content.size(), reinterpret_cast(tgt_content.data()), tgt_content.size(), patch_file.path, nullptr)); std::string patch_content; ASSERT_TRUE(android::base::ReadFileToString(patch_file.path, &patch_content)); // Create the transfer list that contains a bsdiff. std::string src_hash = get_sha1(src_content); std::string tgt_hash = get_sha1(tgt_content); std::vector transfer_list = { "4", "2", "0", "2", "stash " + src_hash + " 2,0,2", android::base::StringPrintf("bsdiff 0 %zu %s %s 2,0,2 2 - %s:2,0,2", patch_content.size(), src_hash.c_str(), tgt_hash.c_str(), src_hash.c_str()), "free " + src_hash, }; std::unordered_map entries = { { "new_data", "" }, { "patch_data", patch_content }, { "transfer_list", android::base::Join(transfer_list, '\n') }, }; // Build the update package. TemporaryFile zip_file; BuildUpdatePackage(entries, zip_file.release()); MemMapping map; ASSERT_TRUE(map.MapFile(zip_file.path)); ZipArchiveHandle handle; ASSERT_EQ(0, OpenArchiveFromMemory(map.addr, map.length, zip_file.path, &handle)); // Set up the handler, command_pipe, patch offset & length. UpdaterInfo updater_info; updater_info.package_zip = handle; TemporaryFile temp_pipe; updater_info.cmd_pipe = fdopen(temp_pipe.release(), "wbe"); updater_info.package_zip_addr = map.addr; updater_info.package_zip_len = map.length; // Execute the commands in the transfer list. TemporaryFile update_file; ASSERT_TRUE(android::base::WriteStringToFile(src_content, update_file.path)); std::string script = "block_image_update(\"" + std::string(update_file.path) + R"(", package_extract_file("transfer_list"), "new_data", "patch_data"))"; expect("t", script.c_str(), kNoCause, &updater_info); // The update_file should be patched correctly. std::string updated_content; ASSERT_TRUE(android::base::ReadFileToString(update_file.path, &updated_content)); ASSERT_EQ(tgt_hash, get_sha1(updated_content)); ASSERT_EQ(0, fclose(updater_info.cmd_pipe)); CloseArchive(handle); } TEST_F(UpdaterTest, block_image_update_fail) { std::string src_content(4096 * 2, 'e'); std::string src_hash = get_sha1(src_content); // Stash and free some blocks, then fail the update intentionally. std::vector transfer_list = { "4", "2", "0", "2", "stash " + src_hash + " 2,0,2", "free " + src_hash, "fail", }; // Add a new data of 10 bytes to test the deadlock. std::unordered_map entries = { { "new_data", std::string(10, 0) }, { "patch_data", "" }, { "transfer_list", android::base::Join(transfer_list, '\n') }, }; // Build the update package. TemporaryFile zip_file; BuildUpdatePackage(entries, zip_file.release()); MemMapping map; ASSERT_TRUE(map.MapFile(zip_file.path)); ZipArchiveHandle handle; ASSERT_EQ(0, OpenArchiveFromMemory(map.addr, map.length, zip_file.path, &handle)); // Set up the handler, command_pipe, patch offset & length. UpdaterInfo updater_info; updater_info.package_zip = handle; TemporaryFile temp_pipe; updater_info.cmd_pipe = fdopen(temp_pipe.release(), "wbe"); updater_info.package_zip_addr = map.addr; updater_info.package_zip_len = map.length; TemporaryFile update_file; ASSERT_TRUE(android::base::WriteStringToFile(src_content, update_file.path)); // Expect the stashed blocks to be freed. std::string script = "block_image_update(\"" + std::string(update_file.path) + R"(", package_extract_file("transfer_list"), "new_data", "patch_data"))"; expect("", script.c_str(), kNoCause, &updater_info); // Updater generates the stash name based on the input file name. std::string name_digest = get_sha1(update_file.path); std::string stash_base = std::string(temp_stash_base_.path) + "/" + name_digest; ASSERT_EQ(0, access(stash_base.c_str(), F_OK)); ASSERT_EQ(-1, access((stash_base + src_hash).c_str(), F_OK)); ASSERT_EQ(0, rmdir(stash_base.c_str())); ASSERT_EQ(0, fclose(updater_info.cmd_pipe)); CloseArchive(handle); } TEST_F(UpdaterTest, new_data_over_write) { std::vector transfer_list = { "4", "1", "0", "0", "new 2,0,1", }; // Write 4096 + 100 bytes of new data. std::unordered_map entries = { { "new_data", std::string(4196, 0) }, { "patch_data", "" }, { "transfer_list", android::base::Join(transfer_list, '\n') }, }; // Build the update package. TemporaryFile zip_file; BuildUpdatePackage(entries, zip_file.release()); MemMapping map; ASSERT_TRUE(map.MapFile(zip_file.path)); ZipArchiveHandle handle; ASSERT_EQ(0, OpenArchiveFromMemory(map.addr, map.length, zip_file.path, &handle)); // Set up the handler, command_pipe, patch offset & length. UpdaterInfo updater_info; updater_info.package_zip = handle; TemporaryFile temp_pipe; updater_info.cmd_pipe = fdopen(temp_pipe.release(), "wbe"); updater_info.package_zip_addr = map.addr; updater_info.package_zip_len = map.length; TemporaryFile update_file; std::string script = "block_image_update(\"" + std::string(update_file.path) + R"(", package_extract_file("transfer_list"), "new_data", "patch_data"))"; expect("t", script.c_str(), kNoCause, &updater_info); ASSERT_EQ(0, fclose(updater_info.cmd_pipe)); CloseArchive(handle); } TEST_F(UpdaterTest, new_data_short_write) { std::vector transfer_list = { "4", "1", "0", "0", "new 2,0,1", }; std::unordered_map entries = { { "empty_new_data", "" }, { "short_new_data", std::string(10, 'a') }, { "exact_new_data", std::string(4096, 'a') }, { "patch_data", "" }, { "transfer_list", android::base::Join(transfer_list, '\n') }, }; TemporaryFile zip_file; BuildUpdatePackage(entries, zip_file.release()); MemMapping map; ASSERT_TRUE(map.MapFile(zip_file.path)); ZipArchiveHandle handle; ASSERT_EQ(0, OpenArchiveFromMemory(map.addr, map.length, zip_file.path, &handle)); // Set up the handler, command_pipe, patch offset & length. UpdaterInfo updater_info; updater_info.package_zip = handle; TemporaryFile temp_pipe; updater_info.cmd_pipe = fdopen(temp_pipe.release(), "wbe"); updater_info.package_zip_addr = map.addr; updater_info.package_zip_len = map.length; // Updater should report the failure gracefully rather than stuck in deadlock. TemporaryFile update_file; std::string script_empty_data = "block_image_update(\"" + std::string(update_file.path) + R"(", package_extract_file("transfer_list"), "empty_new_data", "patch_data"))"; expect("", script_empty_data.c_str(), kNoCause, &updater_info); std::string script_short_data = "block_image_update(\"" + std::string(update_file.path) + R"(", package_extract_file("transfer_list"), "short_new_data", "patch_data"))"; expect("", script_short_data.c_str(), kNoCause, &updater_info); // Expect to write 1 block of new data successfully. std::string script_exact_data = "block_image_update(\"" + std::string(update_file.path) + R"(", package_extract_file("transfer_list"), "exact_new_data", "patch_data"))"; expect("t", script_exact_data.c_str(), kNoCause, &updater_info); ASSERT_EQ(0, fclose(updater_info.cmd_pipe)); CloseArchive(handle); } TEST_F(UpdaterTest, brotli_new_data) { auto generator = []() { return rand() % 128; }; // Generate 100 blocks of random data. std::string brotli_new_data; brotli_new_data.reserve(4096 * 100); generate_n(back_inserter(brotli_new_data), 4096 * 100, generator); size_t encoded_size = BrotliEncoderMaxCompressedSize(brotli_new_data.size()); std::string encoded_data(encoded_size, 0); ASSERT_TRUE(BrotliEncoderCompress( BROTLI_DEFAULT_QUALITY, BROTLI_DEFAULT_WINDOW, BROTLI_DEFAULT_MODE, brotli_new_data.size(), reinterpret_cast(brotli_new_data.data()), &encoded_size, reinterpret_cast(const_cast(encoded_data.data())))); encoded_data.resize(encoded_size); // Write a few small chunks of new data, then a large chunk, and finally a few small chunks. // This helps us to catch potential short writes. std::vector transfer_list = { "4", "100", "0", "0", "new 2,0,1", "new 2,1,2", "new 4,2,50,50,97", "new 2,97,98", "new 2,98,99", "new 2,99,100", }; std::unordered_map entries = { { "new.dat.br", std::move(encoded_data) }, { "patch_data", "" }, { "transfer_list", android::base::Join(transfer_list, '\n') }, }; TemporaryFile zip_file; BuildUpdatePackage(entries, zip_file.release()); MemMapping map; ASSERT_TRUE(map.MapFile(zip_file.path)); ZipArchiveHandle handle; ASSERT_EQ(0, OpenArchiveFromMemory(map.addr, map.length, zip_file.path, &handle)); // Set up the handler, command_pipe, patch offset & length. UpdaterInfo updater_info; updater_info.package_zip = handle; TemporaryFile temp_pipe; updater_info.cmd_pipe = fdopen(temp_pipe.release(), "wb"); updater_info.package_zip_addr = map.addr; updater_info.package_zip_len = map.length; // Check if we can decompress the new data correctly. TemporaryFile update_file; std::string script_new_data = "block_image_update(\"" + std::string(update_file.path) + R"(", package_extract_file("transfer_list"), "new.dat.br", "patch_data"))"; expect("t", script_new_data.c_str(), kNoCause, &updater_info); std::string updated_content; ASSERT_TRUE(android::base::ReadFileToString(update_file.path, &updated_content)); ASSERT_EQ(brotli_new_data, updated_content); ASSERT_EQ(0, fclose(updater_info.cmd_pipe)); CloseArchive(handle); } TEST_F(UpdaterTest, last_command_update) { std::string last_command_file = CacheLocation::location().last_command_file(); std::string block1 = std::string(4096, '1'); std::string block2 = std::string(4096, '2'); std::string block3 = std::string(4096, '3'); std::string block1_hash = get_sha1(block1); std::string block2_hash = get_sha1(block2); std::string block3_hash = get_sha1(block3); // Compose the transfer list to fail the first update. std::vector transfer_list_fail = { "4", "2", "0", "2", "stash " + block1_hash + " 2,0,1", "move " + block1_hash + " 2,1,2 1 2,0,1", "stash " + block3_hash + " 2,2,3", "fail", }; // Mimic a resumed update with the same transfer commands. std::vector transfer_list_continue = { "4", "2", "0", "2", "stash " + block1_hash + " 2,0,1", "move " + block1_hash + " 2,1,2 1 2,0,1", "stash " + block3_hash + " 2,2,3", "move " + block1_hash + " 2,2,3 1 2,0,1", }; std::unordered_map entries = { { "new_data", "" }, { "patch_data", "" }, { "transfer_list_fail", android::base::Join(transfer_list_fail, '\n') }, { "transfer_list_continue", android::base::Join(transfer_list_continue, '\n') }, }; // Build the update package. TemporaryFile zip_file; BuildUpdatePackage(entries, zip_file.release()); MemMapping map; ASSERT_TRUE(map.MapFile(zip_file.path)); ZipArchiveHandle handle; ASSERT_EQ(0, OpenArchiveFromMemory(map.addr, map.length, zip_file.path, &handle)); // Set up the handler, command_pipe, patch offset & length. UpdaterInfo updater_info; updater_info.package_zip = handle; TemporaryFile temp_pipe; updater_info.cmd_pipe = fdopen(temp_pipe.release(), "wbe"); updater_info.package_zip_addr = map.addr; updater_info.package_zip_len = map.length; std::string src_content = block1 + block2 + block3; TemporaryFile update_file; ASSERT_TRUE(android::base::WriteStringToFile(src_content, update_file.path)); std::string script = "block_image_update(\"" + std::string(update_file.path) + R"(", package_extract_file("transfer_list_fail"), "new_data", "patch_data"))"; expect("", script.c_str(), kNoCause, &updater_info); // Expect last_command to contain the last stash command. std::string last_command_content; ASSERT_TRUE(android::base::ReadFileToString(last_command_file.c_str(), &last_command_content)); EXPECT_EQ("2\nstash " + block3_hash + " 2,2,3", last_command_content); std::string updated_contents; ASSERT_TRUE(android::base::ReadFileToString(update_file.path, &updated_contents)); ASSERT_EQ(block1 + block1 + block3, updated_contents); // Resume the update, expect the first 'move' to be skipped but the second 'move' to be executed. ASSERT_TRUE(android::base::WriteStringToFile(src_content, update_file.path)); std::string script_second_update = "block_image_update(\"" + std::string(update_file.path) + R"(", package_extract_file("transfer_list_continue"), "new_data", "patch_data"))"; expect("t", script_second_update.c_str(), kNoCause, &updater_info); ASSERT_TRUE(android::base::ReadFileToString(update_file.path, &updated_contents)); ASSERT_EQ(block1 + block2 + block1, updated_contents); ASSERT_EQ(0, fclose(updater_info.cmd_pipe)); CloseArchive(handle); } TEST_F(UpdaterTest, last_command_update_unresumable) { std::string last_command_file = CacheLocation::location().last_command_file(); std::string block1 = std::string(4096, '1'); std::string block2 = std::string(4096, '2'); std::string block1_hash = get_sha1(block1); std::string block2_hash = get_sha1(block2); // Construct an unresumable update with source blocks mismatch. std::vector transfer_list_unresumable = { "4", "2", "0", "2", "stash " + block1_hash + " 2,0,1", "move " + block2_hash + " 2,1,2 1 2,0,1", }; std::unordered_map entries = { { "new_data", "" }, { "patch_data", "" }, { "transfer_list_unresumable", android::base::Join(transfer_list_unresumable, '\n') }, }; // Build the update package. TemporaryFile zip_file; BuildUpdatePackage(entries, zip_file.release()); MemMapping map; ASSERT_TRUE(map.MapFile(zip_file.path)); ZipArchiveHandle handle; ASSERT_EQ(0, OpenArchiveFromMemory(map.addr, map.length, zip_file.path, &handle)); // Set up the handler, command_pipe, patch offset & length. UpdaterInfo updater_info; updater_info.package_zip = handle; TemporaryFile temp_pipe; updater_info.cmd_pipe = fdopen(temp_pipe.release(), "wbe"); updater_info.package_zip_addr = map.addr; updater_info.package_zip_len = map.length; // Set up the last_command_file ASSERT_TRUE( android::base::WriteStringToFile("0\nstash " + block1_hash + " 2,0,1", last_command_file)); // The last_command_file will be deleted if the update encounters an unresumable failure // later. std::string src_content = block1 + block1; TemporaryFile update_file; ASSERT_TRUE(android::base::WriteStringToFile(src_content, update_file.path)); std::string script = "block_image_update(\"" + std::string(update_file.path) + R"(", package_extract_file("transfer_list_unresumable"), "new_data", "patch_data"))"; expect("", script.c_str(), kNoCause, &updater_info); ASSERT_EQ(-1, access(last_command_file.c_str(), R_OK)); ASSERT_EQ(0, fclose(updater_info.cmd_pipe)); CloseArchive(handle); } TEST_F(UpdaterTest, last_command_verify) { std::string last_command_file = CacheLocation::location().last_command_file(); std::string block1 = std::string(4096, '1'); std::string block2 = std::string(4096, '2'); std::string block3 = std::string(4096, '3'); std::string block1_hash = get_sha1(block1); std::string block2_hash = get_sha1(block2); std::string block3_hash = get_sha1(block3); std::vector transfer_list_verify = { "4", "2", "0", "2", "stash " + block1_hash + " 2,0,1", "move " + block1_hash + " 2,0,1 1 2,0,1", "move " + block1_hash + " 2,1,2 1 2,0,1", "stash " + block3_hash + " 2,2,3", }; std::unordered_map entries = { { "new_data", "" }, { "patch_data", "" }, { "transfer_list_verify", android::base::Join(transfer_list_verify, '\n') }, }; // Build the update package. TemporaryFile zip_file; BuildUpdatePackage(entries, zip_file.release()); MemMapping map; ASSERT_TRUE(map.MapFile(zip_file.path)); ZipArchiveHandle handle; ASSERT_EQ(0, OpenArchiveFromMemory(map.addr, map.length, zip_file.path, &handle)); // Set up the handler, command_pipe, patch offset & length. UpdaterInfo updater_info; updater_info.package_zip = handle; TemporaryFile temp_pipe; updater_info.cmd_pipe = fdopen(temp_pipe.release(), "wbe"); updater_info.package_zip_addr = map.addr; updater_info.package_zip_len = map.length; std::string src_content = block1 + block1 + block3; TemporaryFile update_file; ASSERT_TRUE(android::base::WriteStringToFile(src_content, update_file.path)); ASSERT_TRUE( android::base::WriteStringToFile("2\nstash " + block3_hash + " 2,2,3", last_command_file)); // Expect the verification to succeed and the last_command_file is intact. std::string script_verify = "block_image_verify(\"" + std::string(update_file.path) + R"(", package_extract_file("transfer_list_verify"), "new_data","patch_data"))"; expect("t", script_verify.c_str(), kNoCause, &updater_info); std::string last_command_content; ASSERT_TRUE(android::base::ReadFileToString(last_command_file.c_str(), &last_command_content)); EXPECT_EQ("2\nstash " + block3_hash + " 2,2,3", last_command_content); // Expect the verification to succeed but last_command_file to be deleted; because the target // blocks don't have the expected contents for the second move command. src_content = block1 + block2 + block3; ASSERT_TRUE(android::base::WriteStringToFile(src_content, update_file.path)); expect("t", script_verify.c_str(), kNoCause, &updater_info); ASSERT_EQ(-1, access(last_command_file.c_str(), R_OK)); ASSERT_EQ(0, fclose(updater_info.cmd_pipe)); CloseArchive(handle); }