blob: e35870dc7127e99475d3c4148721b238a5441c14 [file] [log] [blame]
/*
* 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 <stdio.h>
#include <stdlib.h>
#include <sys/stat.h>
#include <sys/types.h>
#include <unistd.h>
#include <algorithm>
#include <memory>
#include <string>
#include <vector>
#include <android-base/file.h>
#include <android-base/properties.h>
#include <android-base/stringprintf.h>
#include <android-base/strings.h>
#include <android-base/test_utils.h>
#include <bootloader_message/bootloader_message.h>
#include <brotli/encode.h>
#include <bsdiff.h>
#include <gtest/gtest.h>
#include <ziparchive/zip_archive.h>
#include <ziparchive/zip_writer.h>
#include "common/test_constants.h"
#include "edify/expr.h"
#include "otautil/SysUtil.h"
#include "otautil/error_code.h"
#include "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<Expr> 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 std::string get_sha1(const std::string& content) {
uint8_t digest[SHA_DIGEST_LENGTH];
SHA1(reinterpret_cast<const uint8_t*>(content.c_str()), content.size(), digest);
return print_sha1(digest);
}
class UpdaterTest : public ::testing::Test {
protected:
virtual void SetUp() override {
RegisterBuiltins();
RegisterInstallFunctions();
RegisterBlockImageFunctions();
}
};
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<std::string>{ "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<std::string>{ "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<std::string>{ "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 <frac>").
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 <frac> <secs>").
ASSERT_EQ(3U, android::base::Split(cmd, " ").size());
ASSERT_EQ(0, fclose(updater_info.cmd_pipe));
}
TEST_F(UpdaterTest, block_image_update) {
// Create a zip file with new_data and patch_data.
TemporaryFile zip_file;
FILE* zip_file_ptr = fdopen(zip_file.release(), "wb");
ZipWriter zip_writer(zip_file_ptr);
// Add a dummy new data.
ASSERT_EQ(0, zip_writer.StartEntry("new_data", 0));
ASSERT_EQ(0, zip_writer.FinishEntry());
// Generate and add the 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');
TemporaryFile patch_file;
ASSERT_EQ(0, bsdiff::bsdiff(reinterpret_cast<const uint8_t*>(src_content.data()),
src_content.size(), reinterpret_cast<const uint8_t*>(tgt_content.data()),
tgt_content.size(), patch_file.path, nullptr));
std::string patch_content;
ASSERT_TRUE(android::base::ReadFileToString(patch_file.path, &patch_content));
ASSERT_EQ(0, zip_writer.StartEntry("patch_data", 0));
ASSERT_EQ(0, zip_writer.WriteBytes(patch_content.data(), patch_content.size()));
ASSERT_EQ(0, zip_writer.FinishEntry());
// Add two transfer lists. The first one contains a bsdiff; and we expect the update to succeed.
std::string src_hash = get_sha1(src_content);
std::string tgt_hash = get_sha1(tgt_content);
std::vector<std::string> 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,
};
ASSERT_EQ(0, zip_writer.StartEntry("transfer_list", 0));
std::string commands = android::base::Join(transfer_list, '\n');
ASSERT_EQ(0, zip_writer.WriteBytes(commands.data(), commands.size()));
ASSERT_EQ(0, zip_writer.FinishEntry());
// Stash and free some blocks, then fail the 2nd update intentionally.
std::vector<std::string> fail_transfer_list = {
"4",
"2",
"0",
"2",
"stash " + tgt_hash + " 2,0,2",
"free " + tgt_hash,
"fail",
};
ASSERT_EQ(0, zip_writer.StartEntry("fail_transfer_list", 0));
std::string fail_commands = android::base::Join(fail_transfer_list, '\n');
ASSERT_EQ(0, zip_writer.WriteBytes(fail_commands.data(), fail_commands.size()));
ASSERT_EQ(0, zip_writer.FinishEntry());
ASSERT_EQ(0, zip_writer.Finish());
ASSERT_EQ(0, fclose(zip_file_ptr));
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 1st 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));
// Expect the 2nd update to fail, but expect the stashed blocks to be freed.
script = "block_image_update(\"" + std::string(update_file.path) +
R"(", package_extract_file("fail_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 = "/cache/recovery/" + name_digest;
ASSERT_EQ(0, access(stash_base.c_str(), F_OK));
ASSERT_EQ(-1, access((stash_base + tgt_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_short_write) {
// Create a zip file with new_data.
TemporaryFile zip_file;
FILE* zip_file_ptr = fdopen(zip_file.release(), "wb");
ZipWriter zip_writer(zip_file_ptr);
// Add the empty new data.
ASSERT_EQ(0, zip_writer.StartEntry("empty_new_data", 0));
ASSERT_EQ(0, zip_writer.FinishEntry());
// Add the short written new data.
ASSERT_EQ(0, zip_writer.StartEntry("short_new_data", 0));
std::string new_data_short = std::string(10, 'a');
ASSERT_EQ(0, zip_writer.WriteBytes(new_data_short.data(), new_data_short.size()));
ASSERT_EQ(0, zip_writer.FinishEntry());
// Add the data of exactly one block.
ASSERT_EQ(0, zip_writer.StartEntry("exact_new_data", 0));
std::string new_data_exact = std::string(4096, 'a');
ASSERT_EQ(0, zip_writer.WriteBytes(new_data_exact.data(), new_data_exact.size()));
ASSERT_EQ(0, zip_writer.FinishEntry());
// Add a dummy patch data.
ASSERT_EQ(0, zip_writer.StartEntry("patch_data", 0));
ASSERT_EQ(0, zip_writer.FinishEntry());
std::vector<std::string> transfer_list = {
"4",
"1",
"0",
"0",
"new 2,0,1",
};
ASSERT_EQ(0, zip_writer.StartEntry("transfer_list", 0));
std::string commands = android::base::Join(transfer_list, '\n');
ASSERT_EQ(0, zip_writer.WriteBytes(commands.data(), commands.size()));
ASSERT_EQ(0, zip_writer.FinishEntry());
ASSERT_EQ(0, zip_writer.Finish());
ASSERT_EQ(0, fclose(zip_file_ptr));
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) {
// Create a zip file with new_data.
TemporaryFile zip_file;
FILE* zip_file_ptr = fdopen(zip_file.release(), "wb");
ZipWriter zip_writer(zip_file_ptr);
// Add a brotli compressed new data entry.
ASSERT_EQ(0, zip_writer.StartEntry("new.dat.br", 0));
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::vector<uint8_t> encoded_data(encoded_size);
ASSERT_TRUE(BrotliEncoderCompress(
BROTLI_DEFAULT_QUALITY, BROTLI_DEFAULT_WINDOW, BROTLI_DEFAULT_MODE, brotli_new_data.size(),
reinterpret_cast<const uint8_t*>(brotli_new_data.data()), &encoded_size, encoded_data.data()));
ASSERT_EQ(0, zip_writer.WriteBytes(encoded_data.data(), encoded_size));
ASSERT_EQ(0, zip_writer.FinishEntry());
// Add a dummy patch data.
ASSERT_EQ(0, zip_writer.StartEntry("patch_data", 0));
ASSERT_EQ(0, zip_writer.FinishEntry());
// 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<std::string> 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",
};
ASSERT_EQ(0, zip_writer.StartEntry("transfer_list", 0));
std::string commands = android::base::Join(transfer_list, '\n');
ASSERT_EQ(0, zip_writer.WriteBytes(commands.data(), commands.size()));
ASSERT_EQ(0, zip_writer.FinishEntry());
ASSERT_EQ(0, zip_writer.Finish());
ASSERT_EQ(0, fclose(zip_file_ptr));
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);
}