1 /*
2 * Copyright (c) 2022 Huawei Device Co., Ltd.
3 * Licensed under the Apache License, Version 2.0 (the "License");
4 * you may not use this file except in compliance with the License.
5 * You may obtain a copy of the License at
6 *
7 * http://www.apache.org/licenses/LICENSE-2.0
8 *
9 * Unless required by applicable law or agreed to in writing, software
10 * distributed under the License is distributed on an "AS IS" BASIS,
11 * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
12 * See the License for the specific language governing permissions and
13 * limitations under the License.
14 */
15 #include <hisysevent.h>
16 #include <ipc_skeleton.h>
17
18 #include "work_queue_manager.h"
19 #include "work_scheduler_service.h"
20 #include "work_sched_hilog.h"
21 #include "work_sched_utils.h"
22
23 using namespace std;
24
25 namespace OHOS {
26 namespace WorkScheduler {
27 const uint32_t TIME_CYCLE = 10 * 60 * 1000; // 10min
28 static int32_t g_timeRetrigger = INT32_MAX;
29
WorkQueueManager(const std::shared_ptr<WorkSchedulerService> & wss)30 WorkQueueManager::WorkQueueManager(const std::shared_ptr<WorkSchedulerService>& wss) : wss_(wss)
31 {
32 timeCycle_ = TIME_CYCLE;
33 }
34
Init()35 bool WorkQueueManager::Init()
36 {
37 return true;
38 }
39
AddListener(WorkCondition::Type type,shared_ptr<IConditionListener> listener)40 bool WorkQueueManager::AddListener(WorkCondition::Type type, shared_ptr<IConditionListener> listener)
41 {
42 std::lock_guard<ffrt::mutex> lock(mutex_);
43 if (listenerMap_.count(type) > 0) {
44 return false;
45 }
46 listenerMap_.emplace(type, listener);
47 return true;
48 }
49
AddWork(shared_ptr<WorkStatus> workStatus)50 bool WorkQueueManager::AddWork(shared_ptr<WorkStatus> workStatus)
51 {
52 if (!workStatus || !workStatus->workInfo_ || !workStatus->workInfo_->GetConditionMap()) {
53 return false;
54 }
55 WS_HILOGD("workStatus ID: %{public}s", workStatus->workId_.c_str());
56 std::lock_guard<ffrt::mutex> lock(mutex_);
57 auto map = workStatus->workInfo_->GetConditionMap();
58 for (auto it : *map) {
59 if (queueMap_.count(it.first) == 0) {
60 queueMap_.emplace(it.first, make_shared<WorkQueue>());
61 if (listenerMap_.count(it.first) != 0) {
62 listenerMap_.at(it.first)->Start();
63 }
64 }
65 queueMap_.at(it.first)->Push(workStatus);
66 }
67 if (WorkSchedUtils::IsSystemApp()) {
68 WS_HILOGI("Is system app, default group is active.");
69 workStatus->workInfo_->SetCallBySystemApp(true);
70 }
71 return true;
72 }
73
RemoveWork(shared_ptr<WorkStatus> workStatus)74 bool WorkQueueManager::RemoveWork(shared_ptr<WorkStatus> workStatus)
75 {
76 std::lock_guard<ffrt::mutex> lock(mutex_);
77 WS_HILOGD("workStatus ID: %{public}s", workStatus->workId_.c_str());
78 auto map = workStatus->workInfo_->GetConditionMap();
79 for (auto it : *map) {
80 if (queueMap_.count(it.first) > 0) {
81 queueMap_.at(it.first)->Remove(workStatus);
82 }
83 if (queueMap_.count(it.first) == 0) {
84 listenerMap_.at(it.first)->Stop();
85 }
86 }
87 return true;
88 }
89
CancelWork(shared_ptr<WorkStatus> workStatus)90 bool WorkQueueManager::CancelWork(shared_ptr<WorkStatus> workStatus)
91 {
92 std::lock_guard<ffrt::mutex> lock(mutex_);
93 WS_HILOGD("workStatus ID: %{public}s", workStatus->workId_.c_str());
94 for (auto it : queueMap_) {
95 it.second->CancelWork(workStatus);
96 if (queueMap_.count(it.first) == 0) {
97 listenerMap_.at(it.first)->Stop();
98 }
99 }
100 // Notify work remove event to battery statistics
101 int32_t pid = IPCSkeleton::GetCallingPid();
102 HiSysEventWrite(HiviewDFX::HiSysEvent::Domain::WORK_SCHEDULER,
103 "WORK_REMOVE", HiviewDFX::HiSysEvent::EventType::STATISTIC, "UID", workStatus->uid_,
104 "PID", pid, "NAME", workStatus->bundleName_, "WORKID", workStatus->workId_);
105 return true;
106 }
107
GetReayQueue(WorkCondition::Type conditionType,shared_ptr<DetectorValue> conditionVal)108 vector<shared_ptr<WorkStatus>> WorkQueueManager::GetReayQueue(WorkCondition::Type conditionType,
109 shared_ptr<DetectorValue> conditionVal)
110 {
111 vector<shared_ptr<WorkStatus>> result;
112 std::lock_guard<ffrt::mutex> lock(mutex_);
113 if (conditionType != WorkCondition::Type::GROUP && queueMap_.count(conditionType) > 0) {
114 shared_ptr<WorkQueue> workQueue = queueMap_.at(conditionType);
115 result = workQueue->OnConditionChanged(conditionType, conditionVal);
116 }
117 if (conditionType == WorkCondition::Type::GROUP || conditionType == WorkCondition::Type::STANDBY) {
118 for (auto it : queueMap_) {
119 shared_ptr<WorkQueue> workQueue = it.second;
120 auto works = workQueue->OnConditionChanged(conditionType, conditionVal);
121 PushWork(works, result);
122 }
123 }
124 bool hasStop = false;
125 auto it = result.begin();
126 while (it != result.end()) {
127 if (!(*it)->needRetrigger_) {
128 ++it;
129 continue;
130 }
131 if (conditionType != WorkCondition::Type::TIMER
132 && conditionType != WorkCondition::Type::GROUP) {
133 WS_HILOGI("Need retrigger, start group listener, bundleName:%{public}s, workId:%{public}s",
134 (*it)->bundleName_.c_str(), (*it)->workId_.c_str());
135 SetTimeRetrigger((*it)->timeRetrigger_);
136 if (!hasStop) {
137 listenerMap_.at(WorkCondition::Type::GROUP)->Stop();
138 hasStop = true;
139 }
140 listenerMap_.at(WorkCondition::Type::GROUP)->Start();
141 }
142 (*it)->needRetrigger_ = false;
143 (*it)->timeRetrigger_ = INT32_MAX;
144 it = result.erase(it);
145 }
146 PrintWorkStatus(conditionType);
147 return result;
148 }
149
PrintWorkStatus(WorkCondition::Type conditionType)150 void WorkQueueManager::PrintWorkStatus(WorkCondition::Type conditionType)
151 {
152 if (conditionType == WorkCondition::Type::GROUP || conditionType == WorkCondition::Type::STANDBY) {
153 PrintAllWorkStatus(conditionType);
154 return;
155 }
156 if (queueMap_.count(conditionType) > 0) {
157 shared_ptr<WorkQueue> workQueue = queueMap_.at(conditionType);
158 auto workList = workQueue->GetWorkList();
159 for (auto work : workList) {
160 work->ToString(conditionType);
161 }
162 }
163 }
164
PrintAllWorkStatus(WorkCondition::Type conditionType)165 void WorkQueueManager::PrintAllWorkStatus(WorkCondition::Type conditionType)
166 {
167 std::set<std::string> allWorkIds;
168 for (auto it : queueMap_) {
169 shared_ptr<WorkQueue> workQueue = it.second;
170 auto workList = workQueue->GetWorkList();
171 for (auto work : workList) {
172 if (allWorkIds.count(work->workId_) != 0) {
173 continue;
174 }
175 allWorkIds.insert(work->workId_);
176 work->ToString(conditionType);
177 }
178 }
179 }
180
PushWork(vector<shared_ptr<WorkStatus>> & works,vector<shared_ptr<WorkStatus>> & result)181 void WorkQueueManager::PushWork(vector<shared_ptr<WorkStatus>> &works, vector<shared_ptr<WorkStatus>> &result)
182 {
183 for (const auto &work : works) {
184 auto iter = std::find_if(result.begin(), result.end(),
185 [&](const auto &existingWork) {
186 return existingWork->workId_ == work->workId_;
187 });
188 if (iter != result.end()) {
189 WS_HILOGE("WorkId:%{public}s existing, bundleName:%{public}s",
190 work->workId_.c_str(), work->bundleName_.c_str());
191 continue;
192 }
193 result.push_back(work);
194 }
195 }
196
OnConditionChanged(WorkCondition::Type conditionType,shared_ptr<DetectorValue> conditionVal)197 void WorkQueueManager::OnConditionChanged(WorkCondition::Type conditionType,
198 shared_ptr<DetectorValue> conditionVal)
199 {
200 auto service = wss_.lock();
201 if (!service) {
202 WS_HILOGE("service is null");
203 return;
204 }
205 auto task = [weak = weak_from_this(), service, conditionType, conditionVal]() {
206 auto strong = weak.lock();
207 if (!strong) {
208 WS_HILOGE("strong is null");
209 return;
210 }
211 vector<shared_ptr<WorkStatus>> readyWorkVector = strong->GetReayQueue(conditionType, conditionVal);
212 if (readyWorkVector.size() == 0) {
213 return;
214 }
215 for (auto it : readyWorkVector) {
216 it->MarkStatus(WorkStatus::Status::CONDITION_READY);
217 }
218 service->OnConditionReady(make_shared<vector<shared_ptr<WorkStatus>>>(readyWorkVector));
219 };
220 auto handler = service->GetHandler();
221 if (!handler) {
222 WS_HILOGE("handler is null");
223 return;
224 }
225 handler->PostTask(task);
226 }
227
StopAndClearWorks(list<shared_ptr<WorkStatus>> workList)228 bool WorkQueueManager::StopAndClearWorks(list<shared_ptr<WorkStatus>> workList)
229 {
230 for (auto &it : workList) {
231 CancelWork(it);
232 }
233 return true;
234 }
235
Dump(string & result)236 void WorkQueueManager::Dump(string& result)
237 {
238 std::lock_guard<ffrt::mutex> lock(mutex_);
239 string conditionType[] = {"network", "charger", "battery_status", "battery_level",
240 "storage", "timer", "group", "deepIdle", "standby", "unknown"};
241 uint32_t size = sizeof(conditionType) / sizeof(conditionType[0]);
242 for (auto it : queueMap_) {
243 if (it.first < size) {
244 result.append(conditionType[it.first]);
245 } else {
246 result.append(conditionType[size - 1]);
247 }
248 result.append(" : ");
249 result.append("[");
250 string workIdStr;
251 it.second->GetWorkIdStr(workIdStr);
252 result.append(workIdStr);
253 result.append("]\n");
254 }
255 }
256
SetTimeCycle(uint32_t time)257 void WorkQueueManager::SetTimeCycle(uint32_t time)
258 {
259 timeCycle_ = time;
260 listenerMap_.at(WorkCondition::Type::TIMER)->Stop();
261 listenerMap_.at(WorkCondition::Type::TIMER)->Start();
262 }
263
GetTimeCycle()264 uint32_t WorkQueueManager::GetTimeCycle()
265 {
266 return timeCycle_;
267 }
268
SetTimeRetrigger(int32_t time)269 void WorkQueueManager::SetTimeRetrigger(int32_t time)
270 {
271 g_timeRetrigger = time;
272 }
273
GetTimeRetrigger()274 int32_t WorkQueueManager::GetTimeRetrigger()
275 {
276 return g_timeRetrigger;
277 }
278
SetMinIntervalByDump(int64_t interval)279 void WorkQueueManager::SetMinIntervalByDump(int64_t interval)
280 {
281 for (auto it : queueMap_) {
282 it.second->SetMinIntervalByDump(interval);
283 }
284 }
285 } // namespace WorkScheduler
286 } // namespace OHOS