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/*
* Copyright (C) 2018 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 <bpf_timeinstate.h>
#include <sys/sysinfo.h>
#include <pthread.h>
#include <semaphore.h>
#include <numeric>
#include <unordered_map>
#include <vector>
#include <gtest/gtest.h>
#include <android-base/properties.h>
#include <android-base/unique_fd.h>
#include <bpf/BpfMap.h>
#include <cputimeinstate.h>
#include <cutils/android_filesystem_config.h>
#include <libbpf.h>
namespace android {
namespace bpf {
static constexpr uint64_t NSEC_PER_SEC = 1000000000;
static constexpr uint64_t NSEC_PER_YEAR = NSEC_PER_SEC * 60 * 60 * 24 * 365;
using std::vector;
class TimeInStateTest : public testing::Test {
protected:
TimeInStateTest() {};
void SetUp() {
if (!isTrackingUidTimesSupported() ||
!android::base::GetBoolProperty("sys.init.perf_lsm_hooks", false)) {
GTEST_SKIP();
}
}
};
TEST_F(TimeInStateTest, TotalTimeInState) {
auto times = getTotalCpuFreqTimes();
ASSERT_TRUE(times.has_value());
EXPECT_FALSE(times->empty());
}
TEST_F(TimeInStateTest, SingleUidTimeInState) {
auto times = getUidCpuFreqTimes(0);
ASSERT_TRUE(times.has_value());
EXPECT_FALSE(times->empty());
}
TEST_F(TimeInStateTest, SingleUidConcurrentTimes) {
auto concurrentTimes = getUidConcurrentTimes(0);
ASSERT_TRUE(concurrentTimes.has_value());
ASSERT_FALSE(concurrentTimes->active.empty());
ASSERT_FALSE(concurrentTimes->policy.empty());
uint64_t policyEntries = 0;
for (const auto &policyTimeVec : concurrentTimes->policy) policyEntries += policyTimeVec.size();
ASSERT_EQ(concurrentTimes->active.size(), policyEntries);
}
static void TestConcurrentTimesConsistent(const struct concurrent_time_t &concurrentTime) {
size_t maxPolicyCpus = 0;
for (const auto &vec : concurrentTime.policy) {
maxPolicyCpus = std::max(maxPolicyCpus, vec.size());
}
uint64_t policySum = 0;
for (size_t i = 0; i < maxPolicyCpus; ++i) {
for (const auto &vec : concurrentTime.policy) {
if (i < vec.size()) policySum += vec[i];
}
ASSERT_LE(concurrentTime.active[i], policySum);
policySum -= concurrentTime.active[i];
}
policySum = 0;
for (size_t i = 0; i < concurrentTime.active.size(); ++i) {
for (const auto &vec : concurrentTime.policy) {
if (i < vec.size()) policySum += vec[vec.size() - 1 - i];
}
auto activeSum = concurrentTime.active[concurrentTime.active.size() - 1 - i];
// This check is slightly flaky because we may read a map entry in the middle of an update
// when active times have been updated but policy times have not. This happens infrequently
// and can be distinguished from more serious bugs by re-running the test: if the underlying
// data itself is inconsistent, the test will fail every time.
ASSERT_LE(activeSum, policySum);
policySum -= activeSum;
}
}
static void TestUidTimesConsistent(const std::vector<std::vector<uint64_t>> &timeInState,
const struct concurrent_time_t &concurrentTime) {
ASSERT_NO_FATAL_FAILURE(TestConcurrentTimesConsistent(concurrentTime));
ASSERT_EQ(timeInState.size(), concurrentTime.policy.size());
uint64_t policySum = 0;
for (uint32_t i = 0; i < timeInState.size(); ++i) {
uint64_t tisSum =
std::accumulate(timeInState[i].begin(), timeInState[i].end(), (uint64_t)0);
uint64_t concurrentSum = std::accumulate(concurrentTime.policy[i].begin(),
concurrentTime.policy[i].end(), (uint64_t)0);
if (tisSum < concurrentSum)
ASSERT_LE(concurrentSum - tisSum, NSEC_PER_SEC);
else
ASSERT_LE(tisSum - concurrentSum, NSEC_PER_SEC);
policySum += concurrentSum;
}
uint64_t activeSum = std::accumulate(concurrentTime.active.begin(), concurrentTime.active.end(),
(uint64_t)0);
EXPECT_EQ(activeSum, policySum);
}
TEST_F(TimeInStateTest, SingleUidTimesConsistent) {
auto times = getUidCpuFreqTimes(0);
ASSERT_TRUE(times.has_value());
auto concurrentTimes = getUidConcurrentTimes(0);
ASSERT_TRUE(concurrentTimes.has_value());
ASSERT_NO_FATAL_FAILURE(TestUidTimesConsistent(*times, *concurrentTimes));
}
TEST_F(TimeInStateTest, AllUidTimeInState) {
uint64_t zero = 0;
auto maps = {getUidsCpuFreqTimes(), getUidsUpdatedCpuFreqTimes(&zero)};
for (const auto &map : maps) {
ASSERT_TRUE(map.has_value());
ASSERT_FALSE(map->empty());
vector<size_t> sizes;
auto firstEntry = map->begin()->second;
for (const auto &subEntry : firstEntry) sizes.emplace_back(subEntry.size());
for (const auto &vec : *map) {
ASSERT_EQ(vec.second.size(), sizes.size());
for (size_t i = 0; i < vec.second.size(); ++i) ASSERT_EQ(vec.second[i].size(), sizes[i]);
}
}
}
void TestCheckUpdate(const std::vector<std::vector<uint64_t>> &before,
const std::vector<std::vector<uint64_t>> &after) {
ASSERT_EQ(before.size(), after.size());
uint64_t sumBefore = 0, sumAfter = 0;
for (size_t i = 0; i < before.size(); ++i) {
ASSERT_EQ(before[i].size(), after[i].size());
for (size_t j = 0; j < before[i].size(); ++j) {
// Times should never decrease
ASSERT_LE(before[i][j], after[i][j]);
}
sumBefore += std::accumulate(before[i].begin(), before[i].end(), (uint64_t)0);
sumAfter += std::accumulate(after[i].begin(), after[i].end(), (uint64_t)0);
}
ASSERT_LE(sumBefore, sumAfter);
ASSERT_LE(sumAfter - sumBefore, NSEC_PER_SEC);
}
TEST_F(TimeInStateTest, AllUidUpdatedTimeInState) {
uint64_t lastUpdate = 0;
auto map1 = getUidsUpdatedCpuFreqTimes(&lastUpdate);
ASSERT_TRUE(map1.has_value());
ASSERT_FALSE(map1->empty());
ASSERT_NE(lastUpdate, (uint64_t)0);
uint64_t oldLastUpdate = lastUpdate;
// Sleep briefly to trigger a context switch, ensuring we see at least one update.
struct timespec ts;
ts.tv_sec = 0;
ts.tv_nsec = 1000000;
nanosleep (&ts, NULL);
auto map2 = getUidsUpdatedCpuFreqTimes(&lastUpdate);
ASSERT_TRUE(map2.has_value());
ASSERT_FALSE(map2->empty());
ASSERT_NE(lastUpdate, oldLastUpdate);
bool someUidsExcluded = false;
for (const auto &[uid, v] : *map1) {
if (map2->find(uid) == map2->end()) {
someUidsExcluded = true;
break;
}
}
ASSERT_TRUE(someUidsExcluded);
for (const auto &[uid, newTimes] : *map2) {
ASSERT_NE(map1->find(uid), map1->end());
ASSERT_NO_FATAL_FAILURE(TestCheckUpdate((*map1)[uid], newTimes));
}
}
TEST_F(TimeInStateTest, TotalAndAllUidTimeInStateConsistent) {
auto allUid = getUidsCpuFreqTimes();
auto total = getTotalCpuFreqTimes();
ASSERT_TRUE(allUid.has_value() && total.has_value());
// Check the number of policies.
ASSERT_EQ(allUid->at(0).size(), total->size());
for (uint32_t policyIdx = 0; policyIdx < total->size(); ++policyIdx) {
std::vector<uint64_t> totalTimes = total->at(policyIdx);
uint32_t totalFreqsCount = totalTimes.size();
std::vector<uint64_t> allUidTimes(totalFreqsCount, 0);
for (auto const &[uid, uidTimes]: *allUid) {
if (uid == AID_SDK_SANDBOX) continue;
for (uint32_t freqIdx = 0; freqIdx < uidTimes[policyIdx].size(); ++freqIdx) {
allUidTimes[std::min(freqIdx, totalFreqsCount - 1)] += uidTimes[policyIdx][freqIdx];
}
}
for (uint32_t freqIdx = 0; freqIdx < totalFreqsCount; ++freqIdx) {
ASSERT_LE(allUidTimes[freqIdx], totalTimes[freqIdx]);
}
}
}
TEST_F(TimeInStateTest, SingleAndAllUidTimeInStateConsistent) {
uint64_t zero = 0;
auto maps = {getUidsCpuFreqTimes(), getUidsUpdatedCpuFreqTimes(&zero)};
for (const auto &map : maps) {
ASSERT_TRUE(map.has_value());
ASSERT_FALSE(map->empty());
for (const auto &kv : *map) {
uint32_t uid = kv.first;
auto times1 = kv.second;
auto times2 = getUidCpuFreqTimes(uid);
ASSERT_TRUE(times2.has_value());
ASSERT_EQ(times1.size(), times2->size());
for (uint32_t i = 0; i < times1.size(); ++i) {
ASSERT_EQ(times1[i].size(), (*times2)[i].size());
for (uint32_t j = 0; j < times1[i].size(); ++j) {
ASSERT_LE((*times2)[i][j] - times1[i][j], NSEC_PER_SEC);
}
}
}
}
}
TEST_F(TimeInStateTest, AllUidConcurrentTimes) {
uint64_t zero = 0;
auto maps = {getUidsConcurrentTimes(), getUidsUpdatedConcurrentTimes(&zero)};
for (const auto &map : maps) {
ASSERT_TRUE(map.has_value());
ASSERT_FALSE(map->empty());
auto firstEntry = map->begin()->second;
for (const auto &kv : *map) {
ASSERT_EQ(kv.second.active.size(), firstEntry.active.size());
ASSERT_EQ(kv.second.policy.size(), firstEntry.policy.size());
for (size_t i = 0; i < kv.second.policy.size(); ++i) {
ASSERT_EQ(kv.second.policy[i].size(), firstEntry.policy[i].size());
}
}
}
}
TEST_F(TimeInStateTest, AllUidUpdatedConcurrentTimes) {
uint64_t lastUpdate = 0;
auto map1 = getUidsUpdatedConcurrentTimes(&lastUpdate);
ASSERT_TRUE(map1.has_value());
ASSERT_FALSE(map1->empty());
ASSERT_NE(lastUpdate, (uint64_t)0);
// Sleep briefly to trigger a context switch, ensuring we see at least one update.
struct timespec ts;
ts.tv_sec = 0;
ts.tv_nsec = 1000000;
nanosleep (&ts, NULL);
uint64_t oldLastUpdate = lastUpdate;
auto map2 = getUidsUpdatedConcurrentTimes(&lastUpdate);
ASSERT_TRUE(map2.has_value());
ASSERT_FALSE(map2->empty());
ASSERT_NE(lastUpdate, oldLastUpdate);
bool someUidsExcluded = false;
for (const auto &[uid, v] : *map1) {
if (map2->find(uid) == map2->end()) {
someUidsExcluded = true;
break;
}
}
ASSERT_TRUE(someUidsExcluded);
for (const auto &[uid, newTimes] : *map2) {
ASSERT_NE(map1->find(uid), map1->end());
ASSERT_NO_FATAL_FAILURE(TestCheckUpdate({(*map1)[uid].active},{newTimes.active}));
ASSERT_NO_FATAL_FAILURE(TestCheckUpdate((*map1)[uid].policy, newTimes.policy));
}
}
TEST_F(TimeInStateTest, SingleAndAllUidConcurrentTimesConsistent) {
uint64_t zero = 0;
auto maps = {getUidsConcurrentTimes(), getUidsUpdatedConcurrentTimes(&zero)};
for (const auto &map : maps) {
ASSERT_TRUE(map.has_value());
for (const auto &kv : *map) {
uint32_t uid = kv.first;
auto times1 = kv.second;
auto times2 = getUidConcurrentTimes(uid);
ASSERT_TRUE(times2.has_value());
for (uint32_t i = 0; i < times1.active.size(); ++i) {
ASSERT_LE(times2->active[i] - times1.active[i], NSEC_PER_SEC);
}
for (uint32_t i = 0; i < times1.policy.size(); ++i) {
for (uint32_t j = 0; j < times1.policy[i].size(); ++j) {
ASSERT_LE(times2->policy[i][j] - times1.policy[i][j], NSEC_PER_SEC);
}
}
}
}
}
void TestCheckDelta(uint64_t before, uint64_t after) {
// Times should never decrease
ASSERT_LE(before, after);
// UID can't have run for more than ~1s on each CPU
ASSERT_LE(after - before, NSEC_PER_SEC * 2 * get_nprocs_conf());
}
TEST_F(TimeInStateTest, TotalTimeInStateMonotonic) {
auto before = getTotalCpuFreqTimes();
ASSERT_TRUE(before.has_value());
sleep(1);
auto after = getTotalCpuFreqTimes();
ASSERT_TRUE(after.has_value());
for (uint32_t policyIdx = 0; policyIdx < after->size(); ++policyIdx) {
auto timesBefore = before->at(policyIdx);
auto timesAfter = after->at(policyIdx);
for (uint32_t freqIdx = 0; freqIdx < timesAfter.size(); ++freqIdx) {
ASSERT_NO_FATAL_FAILURE(TestCheckDelta(timesBefore[freqIdx], timesAfter[freqIdx]));
}
}
}
TEST_F(TimeInStateTest, AllUidTimeInStateMonotonic) {
auto map1 = getUidsCpuFreqTimes();
ASSERT_TRUE(map1.has_value());
sleep(1);
auto map2 = getUidsCpuFreqTimes();
ASSERT_TRUE(map2.has_value());
for (const auto &kv : *map1) {
uint32_t uid = kv.first;
auto times = kv.second;
ASSERT_NE(map2->find(uid), map2->end());
for (uint32_t policy = 0; policy < times.size(); ++policy) {
for (uint32_t freqIdx = 0; freqIdx < times[policy].size(); ++freqIdx) {
auto before = times[policy][freqIdx];
auto after = (*map2)[uid][policy][freqIdx];
ASSERT_NO_FATAL_FAILURE(TestCheckDelta(before, after));
}
}
}
}
TEST_F(TimeInStateTest, AllUidConcurrentTimesMonotonic) {
auto map1 = getUidsConcurrentTimes();
ASSERT_TRUE(map1.has_value());
ASSERT_FALSE(map1->empty());
sleep(1);
auto map2 = getUidsConcurrentTimes();
ASSERT_TRUE(map2.has_value());
ASSERT_FALSE(map2->empty());
for (const auto &kv : *map1) {
uint32_t uid = kv.first;
auto times = kv.second;
ASSERT_NE(map2->find(uid), map2->end());
for (uint32_t i = 0; i < times.active.size(); ++i) {
auto before = times.active[i];
auto after = (*map2)[uid].active[i];
ASSERT_NO_FATAL_FAILURE(TestCheckDelta(before, after));
}
for (uint32_t policy = 0; policy < times.policy.size(); ++policy) {
for (uint32_t idx = 0; idx < times.policy[policy].size(); ++idx) {
auto before = times.policy[policy][idx];
auto after = (*map2)[uid].policy[policy][idx];
ASSERT_NO_FATAL_FAILURE(TestCheckDelta(before, after));
}
}
}
}
TEST_F(TimeInStateTest, AllUidTimeInStateSanityCheck) {
uint64_t zero = 0;
auto maps = {getUidsCpuFreqTimes(), getUidsUpdatedCpuFreqTimes(&zero)};
for (const auto &map : maps) {
ASSERT_TRUE(map.has_value());
bool foundLargeValue = false;
for (const auto &kv : *map) {
for (const auto &timeVec : kv.second) {
for (const auto &time : timeVec) {
ASSERT_LE(time, NSEC_PER_YEAR);
if (time > UINT32_MAX) foundLargeValue = true;
}
}
}
// UINT32_MAX nanoseconds is less than 5 seconds, so if every part of our pipeline is using
// uint64_t as expected, we should have some times higher than that.
ASSERT_TRUE(foundLargeValue);
}
}
TEST_F(TimeInStateTest, AllUidConcurrentTimesSanityCheck) {
uint64_t zero = 0;
auto maps = {getUidsConcurrentTimes(), getUidsUpdatedConcurrentTimes(&zero)};
for (const auto &concurrentMap : maps) {
ASSERT_TRUE(concurrentMap);
bool activeFoundLargeValue = false;
bool policyFoundLargeValue = false;
for (const auto &kv : *concurrentMap) {
for (const auto &time : kv.second.active) {
ASSERT_LE(time, NSEC_PER_YEAR);
if (time > UINT32_MAX) activeFoundLargeValue = true;
}
for (const auto &policyTimeVec : kv.second.policy) {
for (const auto &time : policyTimeVec) {
ASSERT_LE(time, NSEC_PER_YEAR);
if (time > UINT32_MAX) policyFoundLargeValue = true;
}
}
}
// UINT32_MAX nanoseconds is less than 5 seconds, so if every part of our pipeline is using
// uint64_t as expected, we should have some times higher than that.
ASSERT_TRUE(activeFoundLargeValue);
ASSERT_TRUE(policyFoundLargeValue);
}
}
TEST_F(TimeInStateTest, AllUidConcurrentTimesFailsOnInvalidBucket) {
uint32_t uid = 0;
{
// Find an unused UID
auto map = getUidsConcurrentTimes();
ASSERT_TRUE(map.has_value());
ASSERT_FALSE(map->empty());
for (const auto &kv : *map) uid = std::max(uid, kv.first);
++uid;
}
android::base::unique_fd fd{
bpf_obj_get(BPF_FS_PATH "map_timeInState_uid_concurrent_times_map")};
ASSERT_GE(fd, 0);
uint32_t nCpus = get_nprocs_conf();
uint32_t maxBucket = (nCpus - 1) / CPUS_PER_ENTRY;
time_key_t key = {.uid = uid, .bucket = maxBucket + 1};
std::vector<concurrent_val_t> vals(nCpus);
ASSERT_FALSE(writeToMapEntry(fd, &key, vals.data(), BPF_NOEXIST));
EXPECT_FALSE(getUidsConcurrentTimes().has_value());
ASSERT_FALSE(deleteMapEntry(fd, &key));
}
TEST_F(TimeInStateTest, AllUidTimesConsistent) {
auto tisMap = getUidsCpuFreqTimes();
ASSERT_TRUE(tisMap.has_value());
auto concurrentMap = getUidsConcurrentTimes();
ASSERT_TRUE(concurrentMap.has_value());
ASSERT_EQ(tisMap->size(), concurrentMap->size());
for (const auto &kv : *tisMap) {
uint32_t uid = kv.first;
auto times = kv.second;
ASSERT_NE(concurrentMap->find(uid), concurrentMap->end());
auto concurrentTimes = (*concurrentMap)[uid];
ASSERT_NO_FATAL_FAILURE(TestUidTimesConsistent(times, concurrentTimes));
}
}
TEST_F(TimeInStateTest, RemoveUid) {
uint32_t uid = 0;
{
// Find an unused UID
auto times = getUidsCpuFreqTimes();
ASSERT_TRUE(times.has_value());
ASSERT_FALSE(times->empty());
for (const auto &kv : *times) uid = std::max(uid, kv.first);
++uid;
}
{
// Add a map entry for our fake UID by copying a real map entry
android::base::unique_fd fd{
bpf_obj_get(BPF_FS_PATH "map_timeInState_uid_time_in_state_map")};
ASSERT_GE(fd, 0);
time_key_t k;
ASSERT_FALSE(getFirstMapKey(fd, &k));
std::vector<tis_val_t> vals(get_nprocs_conf());
ASSERT_FALSE(findMapEntry(fd, &k, vals.data()));
uint32_t copiedUid = k.uid;
k.uid = uid;
ASSERT_FALSE(writeToMapEntry(fd, &k, vals.data(), BPF_NOEXIST));
android::base::unique_fd fd2{
bpf_obj_get(BPF_FS_PATH "map_timeInState_uid_concurrent_times_map")};
k.uid = copiedUid;
k.bucket = 0;
std::vector<concurrent_val_t> cvals(get_nprocs_conf());
ASSERT_FALSE(findMapEntry(fd2, &k, cvals.data()));
k.uid = uid;
ASSERT_FALSE(writeToMapEntry(fd2, &k, cvals.data(), BPF_NOEXIST));
}
auto times = getUidCpuFreqTimes(uid);
ASSERT_TRUE(times.has_value());
ASSERT_FALSE(times->empty());
auto concurrentTimes = getUidConcurrentTimes(0);
ASSERT_TRUE(concurrentTimes.has_value());
ASSERT_FALSE(concurrentTimes->active.empty());
ASSERT_FALSE(concurrentTimes->policy.empty());
uint64_t sum = 0;
for (size_t i = 0; i < times->size(); ++i) {
for (auto x : (*times)[i]) sum += x;
}
ASSERT_GT(sum, (uint64_t)0);
uint64_t activeSum = 0;
for (size_t i = 0; i < concurrentTimes->active.size(); ++i) {
activeSum += concurrentTimes->active[i];
}
ASSERT_GT(activeSum, (uint64_t)0);
ASSERT_TRUE(clearUidTimes(uid));
auto allTimes = getUidsCpuFreqTimes();
ASSERT_TRUE(allTimes.has_value());
ASSERT_FALSE(allTimes->empty());
ASSERT_EQ(allTimes->find(uid), allTimes->end());
auto allConcurrentTimes = getUidsConcurrentTimes();
ASSERT_TRUE(allConcurrentTimes.has_value());
ASSERT_FALSE(allConcurrentTimes->empty());
ASSERT_EQ(allConcurrentTimes->find(uid), allConcurrentTimes->end());
}
TEST_F(TimeInStateTest, GetCpuFreqs) {
auto freqs = getCpuFreqs();
ASSERT_TRUE(freqs.has_value());
auto times = getUidCpuFreqTimes(0);
ASSERT_TRUE(times.has_value());
ASSERT_EQ(freqs->size(), times->size());
for (size_t i = 0; i < freqs->size(); ++i) EXPECT_EQ((*freqs)[i].size(), (*times)[i].size());
}
uint64_t timeNanos() {
struct timespec spec;
clock_gettime(CLOCK_MONOTONIC, &spec);
return spec.tv_sec * 1000000000 + spec.tv_nsec;
}
// Keeps CPU busy with some number crunching
void useCpu() {
long sum = 0;
for (int i = 0; i < 100000; i++) {
sum *= i;
}
}
sem_t pingsem, pongsem;
void *testThread(void *) {
for (int i = 0; i < 10; i++) {
sem_wait(&pingsem);
useCpu();
sem_post(&pongsem);
}
return nullptr;
}
TEST_F(TimeInStateTest, GetAggregatedTaskCpuFreqTimes) {
uint64_t startTimeNs = timeNanos();
sem_init(&pingsem, 0, 1);
sem_init(&pongsem, 0, 0);
pthread_t thread;
ASSERT_EQ(pthread_create(&thread, NULL, &testThread, NULL), 0);
// This process may have been running for some time, so when we start tracking
// CPU time, the very first switch may include the accumulated time.
// Yield the remainder of this timeslice to the newly created thread.
sem_wait(&pongsem);
sem_post(&pingsem);
pid_t tgid = getpid();
startTrackingProcessCpuTimes(tgid);
pid_t tid = pthread_gettid_np(thread);
startAggregatingTaskCpuTimes(tid, 42);
// Play ping-pong with the other thread to ensure that both threads get
// some CPU time.
for (int i = 0; i < 9; i++) {
sem_wait(&pongsem);
useCpu();
sem_post(&pingsem);
}
pthread_join(thread, NULL);
std::optional<std::unordered_map<uint16_t, std::vector<std::vector<uint64_t>>>> optionalMap =
getAggregatedTaskCpuFreqTimes(tgid, {0, 42});
ASSERT_TRUE(optionalMap);
std::unordered_map<uint16_t, std::vector<std::vector<uint64_t>>> map = *optionalMap;
ASSERT_EQ(map.size(), 2u);
uint64_t testDurationNs = timeNanos() - startTimeNs;
for (auto pair : map) {
uint16_t aggregationKey = pair.first;
ASSERT_TRUE(aggregationKey == 0 || aggregationKey == 42);
std::vector<std::vector<uint64_t>> timesInState = pair.second;
uint64_t totalCpuTime = 0;
for (size_t i = 0; i < timesInState.size(); i++) {
for (size_t j = 0; j < timesInState[i].size(); j++) {
totalCpuTime += timesInState[i][j];
}
}
ASSERT_GT(totalCpuTime, 0ul);
ASSERT_LE(totalCpuTime, testDurationNs);
}
}
void *forceSwitchWithUid(void *uidPtr) {
if (!uidPtr) return nullptr;
setuid(*(uint32_t *)uidPtr);
// Sleep briefly to trigger a context switch, ensuring we see at least one update.
struct timespec ts;
ts.tv_sec = 0;
ts.tv_nsec = 1000000;
nanosleep(&ts, NULL);
return nullptr;
}
TEST_F(TimeInStateTest, SdkSandboxUid) {
// Find an unused app UID and its corresponding SDK sandbox uid.
uint32_t appUid = AID_APP_START, sandboxUid;
{
auto times = getUidsCpuFreqTimes();
ASSERT_TRUE(times.has_value());
ASSERT_FALSE(times->empty());
for (const auto &kv : *times) {
if (kv.first > AID_APP_END) break;
appUid = std::max(appUid, kv.first);
}
appUid++;
sandboxUid = appUid + (AID_SDK_SANDBOX_PROCESS_START - AID_APP_START);
}
// Create a thread to run with the fake sandbox uid.
pthread_t thread;
ASSERT_EQ(pthread_create(&thread, NULL, &forceSwitchWithUid, &sandboxUid), 0);
pthread_join(thread, NULL);
// Confirm we recorded stats for appUid and AID_SDK_SANDBOX but not sandboxUid
auto allTimes = getUidsCpuFreqTimes();
ASSERT_TRUE(allTimes.has_value());
ASSERT_FALSE(allTimes->empty());
ASSERT_NE(allTimes->find(appUid), allTimes->end());
ASSERT_NE(allTimes->find(AID_SDK_SANDBOX), allTimes->end());
ASSERT_EQ(allTimes->find(sandboxUid), allTimes->end());
auto allConcurrentTimes = getUidsConcurrentTimes();
ASSERT_TRUE(allConcurrentTimes.has_value());
ASSERT_FALSE(allConcurrentTimes->empty());
ASSERT_NE(allConcurrentTimes->find(appUid), allConcurrentTimes->end());
ASSERT_NE(allConcurrentTimes->find(AID_SDK_SANDBOX), allConcurrentTimes->end());
ASSERT_EQ(allConcurrentTimes->find(sandboxUid), allConcurrentTimes->end());
ASSERT_TRUE(clearUidTimes(appUid));
}
} // namespace bpf
} // namespace android