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/*
* Copyright (C) 2017 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 <errno.h>
#include <fcntl.h>
#include <inttypes.h>
#include <poll.h>
#include <signal.h>
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#include <unistd.h>
#include <atomic>
#include <memory>
#include <string>
#include <tuple>
#include <vector>
#include <gtest/gtest.h>
#include "Color.h"
#include "Isolate.h"
#include "Log.h"
#include "NanoTime.h"
#include "Test.h"
namespace android {
namespace gtest_extras {
static std::atomic_int g_signal;
static void SignalHandler(int sig) {
g_signal = sig;
}
static void RegisterSignalHandler() {
auto ret = signal(SIGINT, SignalHandler);
if (ret == SIG_ERR) {
FATAL_PLOG("Setting up SIGINT handler failed");
}
ret = signal(SIGQUIT, SignalHandler);
if (ret == SIG_ERR) {
FATAL_PLOG("Setting up SIGQUIT handler failed");
}
}
static void UnregisterSignalHandler() {
auto ret = signal(SIGINT, SIG_DFL);
if (ret == SIG_ERR) {
FATAL_PLOG("Disabling SIGINT handler failed");
}
ret = signal(SIGQUIT, SIG_DFL);
if (ret == SIG_ERR) {
FATAL_PLOG("Disabling SIGQUIT handler failed");
}
}
static std::string PluralizeString(size_t value, const char* name, bool uppercase = false) {
std::string string(std::to_string(value) + name);
if (value != 1) {
if (uppercase) {
string += 'S';
} else {
string += 's';
}
}
return string;
}
inline static bool StartsWithDisabled(const std::string& str) {
static constexpr char kDisabledStr[] = "DISABLED_";
static constexpr size_t kDisabledStrLen = sizeof(kDisabledStr) - 1;
return str.compare(0, kDisabledStrLen, kDisabledStr) == 0;
}
void Isolate::EnumerateTests() {
// Only apply --gtest_filter if present. This is the only option that changes
// what tests are listed.
std::string command(child_args_[0]);
if (!options_.filter().empty()) {
command += " --gtest_filter=" + options_.filter();
}
command += " --gtest_list_tests";
#if defined(__BIONIC__)
// Only bionic is guaranteed to support the 'e' option.
FILE* fp = popen(command.c_str(), "re");
#else
FILE* fp = popen(command.c_str(), "r");
#endif
if (fp == nullptr) {
FATAL_PLOG("Unexpected failure from popen");
}
size_t total_shards = options_.total_shards();
bool sharded = total_shards > 1;
size_t test_count = 0;
if (sharded) {
test_count = options_.shard_index() + 1;
}
bool skip_until_next_suite = false;
std::string suite_name;
char* buffer = nullptr;
size_t buffer_len = 0;
bool new_suite = false;
while (getline(&buffer, &buffer_len, fp) > 0) {
if (buffer[0] != ' ') {
// This is the case name.
suite_name = buffer;
auto space_index = suite_name.find(' ');
if (space_index != std::string::npos) {
suite_name.erase(space_index);
}
if (suite_name.back() == '\n') {
suite_name.resize(suite_name.size() - 1);
}
if (!options_.allow_disabled_tests() && StartsWithDisabled(suite_name)) {
// This whole set of tests have been disabled, skip them all.
skip_until_next_suite = true;
} else {
new_suite = true;
skip_until_next_suite = false;
}
} else if (buffer[0] == ' ' && buffer[1] == ' ') {
if (!skip_until_next_suite) {
std::string test_name = &buffer[2];
auto space_index = test_name.find(' ');
if (space_index != std::string::npos) {
test_name.erase(space_index);
}
if (test_name.back() == '\n') {
test_name.resize(test_name.size() - 1);
}
if (options_.allow_disabled_tests() || !StartsWithDisabled(test_name)) {
if (!sharded || --test_count == 0) {
tests_.push_back(std::make_tuple(suite_name, test_name));
total_tests_++;
if (new_suite) {
// Only increment the number of suites when we find at least one test
// for the suites.
total_suites_++;
new_suite = false;
}
if (sharded) {
test_count = total_shards;
}
}
} else {
total_disable_tests_++;
}
} else {
total_disable_tests_++;
}
} else {
printf("Unexpected output from test listing.\nCommand:\n%s\nLine:\n%s\n", command.c_str(),
buffer);
exit(1);
}
}
free(buffer);
if (pclose(fp) == -1) {
FATAL_PLOG("Unexpected failure from pclose");
}
}
int Isolate::ChildProcessFn(const std::tuple<std::string, std::string>& test) {
// Make sure the filter is only coming from our command-line option.
unsetenv("GTEST_FILTER");
// Add the filter argument.
std::vector<char*> args(child_args_);
std::string filter("--gtest_filter=" + GetTestName(test));
args.push_back(filter.data());
int argc = args.size();
// Add the null terminator.
args.push_back(nullptr);
::testing::InitGoogleTest(&argc, args.data());
return RUN_ALL_TESTS();
}
static bool Pipe(int* read_fd, int* write_fd) {
int pipefd[2];
#if defined(__linux__)
if (pipe2(pipefd, O_CLOEXEC) != 0) {
return false;
}
#else // defined(__APPLE__)
if (pipe(pipefd) != 0) {
return false;
}
if (fcntl(pipefd[0], F_SETFD, FD_CLOEXEC) != 0 || fcntl(pipefd[1], F_SETFD, FD_CLOEXEC)) {
close(pipefd[0]);
close(pipefd[1]);
return false;
}
#endif
*read_fd = pipefd[0];
*write_fd = pipefd[1];
return true;
}
void Isolate::LaunchTests() {
while (!running_indices_.empty() && cur_test_index_ < tests_.size()) {
int read_fd, write_fd;
if (!Pipe(&read_fd, &write_fd)) {
FATAL_PLOG("Unexpected failure from pipe");
}
if (fcntl(read_fd, F_SETFL, O_NONBLOCK) == -1) {
FATAL_PLOG("Unexpected failure from fcntl");
}
pid_t pid = fork();
if (pid == -1) {
FATAL_PLOG("Unexpected failure from fork");
}
if (pid == 0) {
close(read_fd);
close(STDOUT_FILENO);
close(STDERR_FILENO);
if (dup2(write_fd, STDOUT_FILENO) == -1) {
exit(1);
}
if (dup2(write_fd, STDERR_FILENO) == -1) {
exit(1);
}
close(write_fd);
UnregisterSignalHandler();
exit(ChildProcessFn(tests_[cur_test_index_]));
}
size_t run_index = running_indices_.back();
running_indices_.pop_back();
Test* test = new Test(tests_[cur_test_index_], cur_test_index_, run_index, read_fd);
running_by_pid_.emplace(pid, test);
running_[run_index] = test;
running_by_test_index_[cur_test_index_] = test;
pollfd* pollfd = &running_pollfds_[run_index];
pollfd->fd = test->fd();
pollfd->events = POLLIN;
cur_test_index_++;
close(write_fd);
}
}
void Isolate::ReadTestsOutput() {
int ready = poll(running_pollfds_.data(), running_pollfds_.size(), 0);
if (ready <= 0) {
return;
}
for (size_t i = 0; i < running_pollfds_.size(); i++) {
pollfd* pfd = &running_pollfds_[i];
if (pfd->revents & POLLIN) {
Test* test = running_[i];
if (!test->Read()) {
test->CloseFd();
pfd->fd = 0;
pfd->events = 0;
}
}
pfd->revents = 0;
}
}
size_t Isolate::CheckTestsFinished() {
size_t finished_tests = 0;
int status;
pid_t pid;
while ((pid = TEMP_FAILURE_RETRY(waitpid(-1, &status, WNOHANG))) > 0) {
if (pid == -1) {
FATAL_PLOG("Unexpected failure from waitpid");
}
auto entry = running_by_pid_.find(pid);
if (entry == running_by_pid_.end()) {
FATAL_LOG("Found process not spawned by the isolation framework");
}
std::unique_ptr<Test>& test_ptr = entry->second;
Test* test = test_ptr.get();
test->Stop();
// Read any leftover data.
test->ReadUntilClosed();
if (test->result() == TEST_NONE) {
if (WIFSIGNALED(status)) {
std::string output(test->name() + " terminated by signal: " + strsignal(WTERMSIG(status)) +
".\n");
test->AppendOutput(output);
test->set_result(TEST_FAIL);
} else {
int exit_code = WEXITSTATUS(status);
if (exit_code != 0) {
std::string output(test->name() + " exited with exitcode " + std::to_string(exit_code) +
".\n");
test->AppendOutput(output);
test->set_result(TEST_FAIL);
} else {
// Set the result based on the output, since skipped tests and
// passing tests have the same exit status.
test->SetResultFromOutput();
}
}
} else if (test->result() == TEST_TIMEOUT) {
uint64_t time_ms = options_.deadline_threshold_ms();
std::string timeout_str(test->name() + " killed because of timeout at " +
std::to_string(time_ms) + " ms.\n");
test->AppendOutput(timeout_str);
}
if (test->ExpectFail()) {
if (test->result() == TEST_FAIL) {
// The test is expected to fail, it failed.
test->set_result(TEST_XFAIL);
} else if (test->result() == TEST_PASS) {
// The test is expected to fail, it passed.
test->set_result(TEST_XPASS);
}
}
test->Print();
switch (test->result()) {
case TEST_PASS:
total_pass_tests_++;
if (test->slow()) {
total_slow_tests_++;
}
break;
case TEST_XPASS:
total_xpass_tests_++;
break;
case TEST_FAIL:
total_fail_tests_++;
break;
case TEST_TIMEOUT:
total_timeout_tests_++;
break;
case TEST_XFAIL:
total_xfail_tests_++;
break;
case TEST_SKIPPED:
total_skipped_tests_++;
break;
case TEST_NONE:
FATAL_LOG("Test result is TEST_NONE, this should not be possible");
}
finished_tests++;
size_t test_index = test->test_index();
finished_.emplace(test_index, test_ptr.release());
running_indices_.push_back(test->run_index());
// Remove it from all of the running indices.
size_t run_index = test->run_index();
if (running_by_pid_.erase(pid) != 1) {
printf("Internal error: Erasing pid %d from running_by_pid_ incorrect\n", pid);
}
if (running_by_test_index_.erase(test_index) == 0) {
printf("Internal error: Erasing test_index %zu from running_by_pid_ incorrect\n", test_index);
}
running_[run_index] = nullptr;
running_pollfds_[run_index] = {};
}
// The only valid error case is if ECHILD is returned because there are
// no more processes left running.
if (pid == -1 && errno != ECHILD) {
FATAL_PLOG("Unexpected failure from waitpid");
}
return finished_tests;
}
void Isolate::CheckTestsTimeout() {
for (auto& entry : running_by_pid_) {
Test* test = entry.second.get();
if (test->result() == TEST_TIMEOUT) {
continue;
}
if (NanoTime() > test->start_ns() + deadline_threshold_ns_) {
test->set_result(TEST_TIMEOUT);
// Do not mark this as slow and timed out.
test->set_slow(false);
// Test gets cleaned up in CheckTestsFinished.
kill(entry.first, SIGKILL);
} else if (!test->slow() && NanoTime() > test->start_ns() + slow_threshold_ns_) {
// Mark the test as running slow.
test->set_slow(true);
}
}
}
void Isolate::HandleSignals() {
int signal = g_signal.exchange(0);
if (signal == SIGINT) {
printf("Terminating due to signal...\n");
for (auto& entry : running_by_pid_) {
kill(entry.first, SIGKILL);
}
exit(1);
} else if (signal == SIGQUIT) {
printf("List of current running tests:\n");
for (const auto& entry : running_by_test_index_) {
const Test* test = entry.second;
uint64_t run_time_ms = (NanoTime() - test->start_ns()) / kNsPerMs;
printf(" %s (elapsed time %" PRId64 " ms)\n", test->name().c_str(), run_time_ms);
}
}
}
void Isolate::RunAllTests() {
total_pass_tests_ = 0;
total_xpass_tests_ = 0;
total_fail_tests_ = 0;
total_xfail_tests_ = 0;
total_timeout_tests_ = 0;
total_slow_tests_ = 0;
total_skipped_tests_ = 0;
running_by_test_index_.clear();
size_t job_count = options_.job_count();
running_.clear();
running_.resize(job_count);
running_pollfds_.resize(job_count);
memset(running_pollfds_.data(), 0, running_pollfds_.size() * sizeof(pollfd));
running_indices_.clear();
for (size_t i = 0; i < job_count; i++) {
running_indices_.push_back(i);
}
finished_.clear();
size_t finished = 0;
cur_test_index_ = 0;
while (finished < tests_.size()) {
LaunchTests();
ReadTestsOutput();
finished += CheckTestsFinished();
CheckTestsTimeout();
HandleSignals();
usleep(MIN_USECONDS_WAIT);
}
}
void Isolate::PrintResults(size_t total, const ResultsType& results, std::string* footer) {
ColoredPrintf(results.color, results.prefix);
if (results.list_desc != nullptr) {
printf(" %s %s, listed below:\n", PluralizeString(total, " test").c_str(), results.list_desc);
} else {
printf(" %s, listed below:\n", PluralizeString(total, " test").c_str());
}
for (const auto& entry : finished_) {
const Test* test = entry.second.get();
if (results.match_func(*test)) {
ColoredPrintf(results.color, results.prefix);
printf(" %s", test->name().c_str());
if (results.print_func != nullptr) {
results.print_func(options_, *test);
}
printf("\n");
}
}
if (results.title == nullptr) {
return;
}
if (total < 10) {
*footer += ' ';
}
*footer +=
PluralizeString(total, (std::string(" ") + results.title + " TEST").c_str(), true) + '\n';
}
Isolate::ResultsType Isolate::SlowResults = {
.color = COLOR_YELLOW,
.prefix = "[ SLOW ]",
.list_desc = nullptr,
.title = "SLOW",
.match_func = [](const Test& test) { return test.slow(); },
.print_func =
[](const Options& options, const Test& test) {
printf(" (%" PRIu64 " ms, exceeded %" PRIu64 " ms)", test.RunTimeNs() / kNsPerMs,
options.slow_threshold_ms());
},
};
Isolate::ResultsType Isolate::XpassFailResults = {
.color = COLOR_RED,
.prefix = "[ FAILED ]",
.list_desc = "should have failed",
.title = "SHOULD HAVE FAILED",
.match_func = [](const Test& test) { return test.result() == TEST_XPASS; },
.print_func = nullptr,
};
Isolate::ResultsType Isolate::FailResults = {
.color = COLOR_RED,
.prefix = "[ FAILED ]",
.list_desc = nullptr,
.title = "FAILED",
.match_func = [](const Test& test) { return test.result() == TEST_FAIL; },
.print_func = nullptr,
};
Isolate::ResultsType Isolate::TimeoutResults = {
.color = COLOR_RED,
.prefix = "[ TIMEOUT ]",
.list_desc = nullptr,
.title = "TIMEOUT",
.match_func = [](const Test& test) { return test.result() == TEST_TIMEOUT; },
.print_func =
[](const Options&, const Test& test) {
printf(" (stopped at %" PRIu64 " ms)", test.RunTimeNs() / kNsPerMs);
},
};
Isolate::ResultsType Isolate::SkippedResults = {
.color = COLOR_GREEN,
.prefix = "[ SKIPPED ]",
.list_desc = nullptr,
.title = nullptr,
.match_func = [](const Test& test) { return test.result() == TEST_SKIPPED; },
.print_func = nullptr,
};
void Isolate::PrintFooter(uint64_t elapsed_time_ns) {
ColoredPrintf(COLOR_GREEN, "[==========]");
printf(" %s from %s ran. (%" PRId64 " ms total)\n",
PluralizeString(total_tests_, " test").c_str(),
PluralizeString(total_suites_, " test suite").c_str(), elapsed_time_ns / kNsPerMs);
ColoredPrintf(COLOR_GREEN, "[ PASSED ]");
printf(" %s.", PluralizeString(total_pass_tests_ + total_xfail_tests_, " test").c_str());
if (total_xfail_tests_ != 0) {
printf(" (%s)", PluralizeString(total_xfail_tests_, " expected failure").c_str());
}
printf("\n");
std::string footer;
// Tests that were skipped.
if (total_skipped_tests_ != 0) {
PrintResults(total_skipped_tests_, SkippedResults, &footer);
}
// Tests that ran slow.
if (total_slow_tests_ != 0) {
PrintResults(total_slow_tests_, SlowResults, &footer);
}
// Tests that passed but should have failed.
if (total_xpass_tests_ != 0) {
PrintResults(total_xpass_tests_, XpassFailResults, &footer);
}
// Tests that timed out.
if (total_timeout_tests_ != 0) {
PrintResults(total_timeout_tests_, TimeoutResults, &footer);
}
// Tests that failed.
if (total_fail_tests_ != 0) {
PrintResults(total_fail_tests_, FailResults, &footer);
}
if (!footer.empty()) {
printf("\n%s", footer.c_str());
}
if (total_disable_tests_ != 0) {
if (footer.empty()) {
printf("\n");
}
ColoredPrintf(COLOR_YELLOW, " YOU HAVE %s\n\n",
PluralizeString(total_disable_tests_, " DISABLED TEST", true).c_str());
}
fflush(stdout);
}
std::string XmlEscape(const std::string& xml) {
std::string escaped;
escaped.reserve(xml.size());
for (auto c : xml) {
switch (c) {
case '<':
escaped.append("&lt;");
break;
case '>':
escaped.append("&gt;");
break;
case '&':
escaped.append("&amp;");
break;
case '\'':
escaped.append("&apos;");
break;
case '"':
escaped.append("&quot;");
break;
default:
escaped.append(1, c);
break;
}
}
return escaped;
}
class TestResultPrinter : public ::testing::EmptyTestEventListener {
public:
TestResultPrinter() : pinfo_(nullptr) {}
virtual void OnTestStart(const ::testing::TestInfo& test_info) {
pinfo_ = &test_info; // Record test_info for use in OnTestPartResult.
}
virtual void OnTestPartResult(const ::testing::TestPartResult& result);
private:
const ::testing::TestInfo* pinfo_;
};
// Called after an assertion failure.
void TestResultPrinter::OnTestPartResult(const ::testing::TestPartResult& result) {
// If the test part succeeded, we don't need to do anything.
if (result.type() == ::testing::TestPartResult::kSuccess) {
return;
}
if (result.type() == ::testing::TestPartResult::kSkip) {
printf("%s:(%d) Skipped\n", result.file_name(), result.line_number());
if (*result.message()) {
printf("%s\n", result.message());
}
} else {
// Print failure message from the assertion (e.g. expected this and got that).
printf("%s:(%d) Failure in test %s.%s\n%s\n", result.file_name(), result.line_number(),
pinfo_->test_suite_name(), pinfo_->name(), result.message());
}
fflush(stdout);
}
// Output xml file when --gtest_output is used, write this function as we can't reuse
// gtest.cc:XmlUnitTestResultPrinter. The reason is XmlUnitTestResultPrinter is totally
// defined in gtest.cc and not expose to outside. What's more, as we don't run gtest in
// the parent process, we don't have gtest classes which are needed by XmlUnitTestResultPrinter.
void Isolate::WriteXmlResults(uint64_t elapsed_time_ns, time_t start_time) {
FILE* fp = fopen(options_.xml_file().c_str(), "w");
if (fp == nullptr) {
printf("Cannot open xml file '%s': %s\n", options_.xml_file().c_str(), strerror(errno));
exit(1);
}
const tm* time_struct = localtime(&start_time);
if (time_struct == nullptr) {
FATAL_PLOG("Unexpected failure from localtime");
}
char timestamp[40];
snprintf(timestamp, sizeof(timestamp), "%4d-%02d-%02dT%02d:%02d:%02d",
time_struct->tm_year + 1900, time_struct->tm_mon + 1, time_struct->tm_mday,
time_struct->tm_hour, time_struct->tm_min, time_struct->tm_sec);
fputs("<?xml version=\"1.0\" encoding=\"UTF-8\"?>\n", fp);
fprintf(fp, "<testsuites tests=\"%zu\" failures=\"%zu\" disabled=\"0\" errors=\"0\"",
tests_.size(), total_fail_tests_ + total_timeout_tests_ + total_xpass_tests_);
fprintf(fp, " timestamp=\"%s\" time=\"%.3lf\" name=\"AllTests\">\n", timestamp,
double(elapsed_time_ns) / kNsPerMs);
// Construct the suite information.
struct SuiteInfo {
std::string suite_name;
size_t fails = 0;
double elapsed_ms = 0;
std::vector<const Test*> tests;
};
std::string last_suite_name;
std::vector<SuiteInfo> suites;
SuiteInfo* info = nullptr;
for (const auto& entry : finished_) {
const Test* test = entry.second.get();
const std::string& suite_name = test->suite_name();
if (test->result() == TEST_XFAIL) {
// Skip XFAIL tests.
continue;
}
if (last_suite_name != suite_name) {
SuiteInfo suite_info{.suite_name = suite_name.substr(0, suite_name.size() - 1)};
last_suite_name = suite_name;
suites.push_back(suite_info);
info = &suites.back();
}
info->tests.push_back(test);
info->elapsed_ms += double(test->RunTimeNs()) / kNsPerMs;
if (test->result() != TEST_PASS) {
info->fails++;
}
}
for (auto& suite_entry : suites) {
fprintf(fp,
" <testsuite name=\"%s\" tests=\"%zu\" failures=\"%zu\" disabled=\"0\" errors=\"0\"",
suite_entry.suite_name.c_str(), suite_entry.tests.size(), suite_entry.fails);
fprintf(fp, " time=\"%.3lf\">\n", suite_entry.elapsed_ms);
for (auto test : suite_entry.tests) {
fprintf(fp, " <testcase name=\"%s\" status=\"run\" time=\"%.3lf\" classname=\"%s\"",
test->test_name().c_str(), double(test->RunTimeNs()) / kNsPerMs,
suite_entry.suite_name.c_str());
if (test->result() == TEST_PASS) {
fputs(" />\n", fp);
} else {
fputs(">\n", fp);
const std::string escaped_output = XmlEscape(test->output());
fprintf(fp, " <failure message=\"%s\" type=\"\">\n", escaped_output.c_str());
fputs(" </failure>\n", fp);
fputs(" </testcase>\n", fp);
}
}
fputs(" </testsuite>\n", fp);
}
fputs("</testsuites>\n", fp);
fclose(fp);
}
int Isolate::Run() {
slow_threshold_ns_ = options_.slow_threshold_ms() * kNsPerMs;
deadline_threshold_ns_ = options_.deadline_threshold_ms() * kNsPerMs;
bool sharding_enabled = options_.total_shards() > 1;
if (sharding_enabled &&
(options_.shard_index() < 0 || options_.shard_index() >= options_.total_shards())) {
ColoredPrintf(COLOR_RED,
"Invalid environment variables: we require 0 <= GTEST_SHARD_INDEX < "
"GTEST_TOTAL_SHARDS, but you have GTEST_SHARD_INDEX=%" PRId64
", GTEST_TOTAL_SHARDS=%" PRId64,
options_.shard_index(), options_.total_shards());
printf("\n");
return 1;
}
if (!options_.filter().empty()) {
ColoredPrintf(COLOR_YELLOW, "Note: Google Test filter = %s", options_.filter().c_str());
printf("\n");
}
if (sharding_enabled) {
ColoredPrintf(COLOR_YELLOW, "Note: This is test shard %" PRId64 " of %" PRId64,
options_.shard_index() + 1, options_.total_shards());
printf("\n");
}
EnumerateTests();
// Stop default result printer to avoid environment setup/teardown information for each test.
delete ::testing::UnitTest::GetInstance()->listeners().Release(
::testing::UnitTest::GetInstance()->listeners().default_result_printer());
::testing::UnitTest::GetInstance()->listeners().Append(new TestResultPrinter);
RegisterSignalHandler();
std::string job_info("Running " + PluralizeString(total_tests_, " test") + " from " +
PluralizeString(total_suites_, " test suite") + " (" +
PluralizeString(options_.job_count(), " job") + ").");
int exit_code = 0;
for (int i = 0; options_.num_iterations() < 0 || i < options_.num_iterations(); i++) {
if (i > 0) {
printf("\nRepeating all tests (iteration %d) . . .\n\n", i + 1);
}
ColoredPrintf(COLOR_GREEN, "[==========]");
printf(" %s\n", job_info.c_str());
fflush(stdout);
time_t start_time = time(nullptr);
uint64_t time_ns = NanoTime();
RunAllTests();
time_ns = NanoTime() - time_ns;
PrintFooter(time_ns);
if (!options_.xml_file().empty()) {
WriteXmlResults(time_ns, start_time);
}
if (total_pass_tests_ + total_skipped_tests_ + total_xfail_tests_ != tests_.size()) {
exit_code = 1;
}
}
return exit_code;
}
} // namespace gtest_extras
} // namespace android