services/java/com/android/server/ProcessStats.java - LeafOS-Project/android_frameworks_base - Gitiles

 /*
  * Copyright (C) 2007 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.
  */

 package com.android.server;

 import static android.os.Process.*;

 import android.os.Process;
 import android.os.SystemClock;
 import android.util.Config;
 import android.util.Slog;

 import java.io.File;
 import java.io.FileInputStream;
 import java.io.PrintWriter;
 import java.io.StringWriter;
 import java.util.ArrayList;
 import java.util.Collections;
 import java.util.Comparator;
 import java.util.StringTokenizer;

 public class ProcessStats {
     private static final String TAG = "ProcessStats";
     private static final boolean DEBUG = false;
     private static final boolean localLOGV = DEBUG || Config.LOGV;

     private static final int[] PROCESS_STATS_FORMAT = new int[] {
         PROC_SPACE_TERM,
         PROC_SPACE_TERM,
         PROC_SPACE_TERM,
         PROC_SPACE_TERM,
         PROC_SPACE_TERM,
         PROC_SPACE_TERM,
         PROC_SPACE_TERM,
         PROC_SPACE_TERM,
         PROC_SPACE_TERM,
         PROC_SPACE_TERM|PROC_OUT_LONG,                  // 9: minor faults
         PROC_SPACE_TERM,
         PROC_SPACE_TERM|PROC_OUT_LONG,                  // 11: major faults
         PROC_SPACE_TERM,
         PROC_SPACE_TERM|PROC_OUT_LONG,                  // 13: utime
         PROC_SPACE_TERM|PROC_OUT_LONG                   // 14: stime
     };

     static final int PROCESS_STAT_MINOR_FAULTS = 0;
     static final int PROCESS_STAT_MAJOR_FAULTS = 1;
     static final int PROCESS_STAT_UTIME = 2;
     static final int PROCESS_STAT_STIME = 3;

     /** Stores user time and system time in 100ths of a second. */
     private final long[] mProcessStatsData = new long[4];
     /** Stores user time and system time in 100ths of a second. */
     private final long[] mSinglePidStatsData = new long[4];

     private static final int[] PROCESS_FULL_STATS_FORMAT = new int[] {
         PROC_SPACE_TERM,
         PROC_SPACE_TERM|PROC_PARENS|PROC_OUT_STRING,    // 1: name
         PROC_SPACE_TERM,
         PROC_SPACE_TERM,
         PROC_SPACE_TERM,
         PROC_SPACE_TERM,
         PROC_SPACE_TERM,
         PROC_SPACE_TERM,
         PROC_SPACE_TERM,
         PROC_SPACE_TERM,
         PROC_SPACE_TERM,
         PROC_SPACE_TERM,
         PROC_SPACE_TERM,
         PROC_SPACE_TERM|PROC_OUT_LONG,                  // 13: utime
         PROC_SPACE_TERM|PROC_OUT_LONG                   // 14: stime
     };

     private final String[] mProcessFullStatsStringData = new String[3];
     private final long[] mProcessFullStatsData = new long[3];

     private static final int[] SYSTEM_CPU_FORMAT = new int[] {
         PROC_SPACE_TERM|PROC_COMBINE,
         PROC_SPACE_TERM|PROC_OUT_LONG,                  // 1: user time
         PROC_SPACE_TERM|PROC_OUT_LONG,                  // 2: nice time
         PROC_SPACE_TERM|PROC_OUT_LONG,                  // 3: sys time
         PROC_SPACE_TERM|PROC_OUT_LONG,                  // 4: idle time
         PROC_SPACE_TERM|PROC_OUT_LONG,                  // 5: iowait time
         PROC_SPACE_TERM|PROC_OUT_LONG,                  // 6: irq time
         PROC_SPACE_TERM|PROC_OUT_LONG                   // 7: softirq time
     };

     private final long[] mSystemCpuData = new long[7];

     private static final int[] LOAD_AVERAGE_FORMAT = new int[] {
         PROC_SPACE_TERM|PROC_OUT_FLOAT,                 // 0: 1 min
         PROC_SPACE_TERM|PROC_OUT_FLOAT,                 // 1: 5 mins
         PROC_SPACE_TERM|PROC_OUT_FLOAT                  // 2: 15 mins
     };

     private final float[] mLoadAverageData = new float[3];

     private final boolean mIncludeThreads;

     private float mLoad1 = 0;
     private float mLoad5 = 0;
     private float mLoad15 = 0;

     private long mCurrentSampleTime;
     private long mLastSampleTime;

     private long mBaseUserTime;
     private long mBaseSystemTime;
     private long mBaseIoWaitTime;
     private long mBaseIrqTime;
     private long mBaseSoftIrqTime;
     private long mBaseIdleTime;
     private int mRelUserTime;
     private int mRelSystemTime;
     private int mRelIoWaitTime;
     private int mRelIrqTime;
     private int mRelSoftIrqTime;
     private int mRelIdleTime;

     private int[] mCurPids;
     private int[] mCurThreadPids;

     private final ArrayList<Stats> mProcStats = new ArrayList<Stats>();
     private final ArrayList<Stats> mWorkingProcs = new ArrayList<Stats>();
     private boolean mWorkingProcsSorted;

     private boolean mFirst = true;

     private byte[] mBuffer = new byte[256];

     /**
      * The time in microseconds that the CPU has been running at each speed.
      */
     private long[] mCpuSpeedTimes;

     /**
      * The relative time in microseconds that the CPU has been running at each speed.
      */
     private long[] mRelCpuSpeedTimes;

     /**
      * The different speeds that the CPU can be running at.
      */
     private long[] mCpuSpeeds;

     public static class Stats {
         public final int pid;
         final String statFile;
         final String cmdlineFile;
         final String threadsDir;
         final ArrayList<Stats> threadStats;
         final ArrayList<Stats> workingThreads;

         public String baseName;
         public String name;
         int nameWidth;

         public long base_utime;
         public long base_stime;
         public int rel_utime;
         public int rel_stime;

         public long base_minfaults;
         public long base_majfaults;
         public int rel_minfaults;
         public int rel_majfaults;

         public boolean active;
         public boolean added;
         public boolean removed;

         Stats(int _pid, int parentPid, boolean includeThreads) {
             pid = _pid;
             if (parentPid < 0) {
                 final File procDir = new File("/proc", Integer.toString(pid));
                 statFile = new File(procDir, "stat").toString();
                 cmdlineFile = new File(procDir, "cmdline").toString();
                 threadsDir = (new File(procDir, "task")).toString();
                 if (includeThreads) {
                     threadStats = new ArrayList<Stats>();
                     workingThreads = new ArrayList<Stats>();
                 } else {
                     threadStats = null;
                     workingThreads = null;
                 }
             } else {
                 final File procDir = new File("/proc", Integer.toString(
                         parentPid));
                 final File taskDir = new File(
                         new File(procDir, "task"), Integer.toString(pid));
                 statFile = new File(taskDir, "stat").toString();
                 cmdlineFile = null;
                 threadsDir = null;
                 threadStats = null;
                 workingThreads = null;
             }
         }
     }

     private final static Comparator<Stats> sLoadComparator = new Comparator<Stats>() {
         public final int
         compare(Stats sta, Stats stb)
         {
             int ta = sta.rel_utime + sta.rel_stime;
             int tb = stb.rel_utime + stb.rel_stime;
             if (ta != tb) {
                 return ta > tb ? -1 : 1;
             }
             if (sta.added != stb.added) {
                 return sta.added ? -1 : 1;
             }
             if (sta.removed != stb.removed) {
                 return sta.added ? -1 : 1;
             }
             return 0;
         }
     };


     public ProcessStats(boolean includeThreads) {
         mIncludeThreads = includeThreads;
     }

     public void onLoadChanged(float load1, float load5, float load15) {
     }

     public int onMeasureProcessName(String name) {
         return 0;
     }

     public void init() {
         mFirst = true;
         update();
     }

     public void update() {
         mLastSampleTime = mCurrentSampleTime;
         mCurrentSampleTime = SystemClock.uptimeMillis();

         final float[] loadAverages = mLoadAverageData;
         if (Process.readProcFile("/proc/loadavg", LOAD_AVERAGE_FORMAT,
                 null, null, loadAverages)) {
             float load1 = loadAverages[0];
             float load5 = loadAverages[1];
             float load15 = loadAverages[2];
             if (load1 != mLoad1 || load5 != mLoad5 || load15 != mLoad15) {
                 mLoad1 = load1;
                 mLoad5 = load5;
                 mLoad15 = load15;
                 onLoadChanged(load1, load5, load15);
             }
         }

         mCurPids = collectStats("/proc", -1, mFirst, mCurPids,
                 mProcStats, mWorkingProcs);
         mFirst = false;

         final long[] sysCpu = mSystemCpuData;
         if (Process.readProcFile("/proc/stat", SYSTEM_CPU_FORMAT,
                 null, sysCpu, null)) {
             // Total user time is user + nice time.
             final long usertime = sysCpu[0]+sysCpu[1];
             // Total system time is simply system time.
             final long systemtime = sysCpu[2];
             // Total idle time is simply idle time.
             final long idletime = sysCpu[3];
             // Total irq time is iowait + irq + softirq time.
             final long iowaittime = sysCpu[4];
             final long irqtime = sysCpu[5];
             final long softirqtime = sysCpu[6];

             mRelUserTime = (int)(usertime - mBaseUserTime);
             mRelSystemTime = (int)(systemtime - mBaseSystemTime);
             mRelIoWaitTime = (int)(iowaittime - mBaseIoWaitTime);
             mRelIrqTime = (int)(irqtime - mBaseIrqTime);
             mRelSoftIrqTime = (int)(softirqtime - mBaseSoftIrqTime);
             mRelIdleTime = (int)(idletime - mBaseIdleTime);

             if (false) {
                 Slog.i("Load", "Total U:" + sysCpu[0] + " N:" + sysCpu[1]
                       + " S:" + sysCpu[2] + " I:" + sysCpu[3]
                       + " W:" + sysCpu[4] + " Q:" + sysCpu[5]
                       + " O:" + sysCpu[6]);
                 Slog.i("Load", "Rel U:" + mRelUserTime + " S:" + mRelSystemTime
                       + " I:" + mRelIdleTime + " Q:" + mRelIrqTime);
             }

             mBaseUserTime = usertime;
             mBaseSystemTime = systemtime;
             mBaseIoWaitTime = iowaittime;
             mBaseIrqTime = irqtime;
             mBaseSoftIrqTime = softirqtime;
             mBaseIdleTime = idletime;
         }

         mWorkingProcsSorted = false;
         mFirst = false;
     }

     private int[] collectStats(String statsFile, int parentPid, boolean first,
             int[] curPids, ArrayList<Stats> allProcs,
             ArrayList<Stats> workingProcs) {

         workingProcs.clear();

         int[] pids = Process.getPids(statsFile, curPids);
         int NP = (pids == null) ? 0 : pids.length;
         int NS = allProcs.size();
         int curStatsIndex = 0;
         for (int i=0; i<NP; i++) {
             int pid = pids[i];
             if (pid < 0) {
                 NP = pid;
                 break;
             }
             Stats st = curStatsIndex < NS ? allProcs.get(curStatsIndex) : null;

             if (st != null && st.pid == pid) {
                 // Update an existing process...
                 st.added = false;
                 curStatsIndex++;
                 if (localLOGV) Slog.v(TAG, "Existing pid " + pid + ": " + st);

                 final long[] procStats = mProcessStatsData;
                 if (!Process.readProcFile(st.statFile.toString(),
                         PROCESS_STATS_FORMAT, null, procStats, null)) {
                     continue;
                 }

                 final long minfaults = procStats[PROCESS_STAT_MINOR_FAULTS];
                 final long majfaults = procStats[PROCESS_STAT_MAJOR_FAULTS];
                 final long utime = procStats[PROCESS_STAT_UTIME];
                 final long stime = procStats[PROCESS_STAT_STIME];

                 if (utime == st.base_utime && stime == st.base_stime) {
                     st.rel_utime = 0;
                     st.rel_stime = 0;
                     st.rel_minfaults = 0;
                     st.rel_majfaults = 0;
                     if (st.active) {
                         st.active = false;
                     }
                     continue;
                 }

                 if (!st.active) {
                     st.active = true;
                 }

                 if (parentPid < 0) {
                     getName(st, st.cmdlineFile);
                     if (st.threadStats != null) {
                         mCurThreadPids = collectStats(st.threadsDir, pid, false,
                                 mCurThreadPids, st.threadStats,
                                 st.workingThreads);
                     }
                 }

                 st.rel_utime = (int)(utime - st.base_utime);
                 st.rel_stime = (int)(stime - st.base_stime);
                 st.base_utime = utime;
                 st.base_stime = stime;
                 st.rel_minfaults = (int)(minfaults - st.base_minfaults);
                 st.rel_majfaults = (int)(majfaults - st.base_majfaults);
                 st.base_minfaults = minfaults;
                 st.base_majfaults = majfaults;
                 //Slog.i("Load", "Stats changed " + name + " pid=" + st.pid
                 //      + " name=" + st.name + " utime=" + utime
                 //      + " stime=" + stime);
                 workingProcs.add(st);
                 continue;
             }

             if (st == null || st.pid > pid) {
                 // We have a new process!
                 st = new Stats(pid, parentPid, mIncludeThreads);
                 allProcs.add(curStatsIndex, st);
                 curStatsIndex++;
                 NS++;
                 if (localLOGV) Slog.v(TAG, "New pid " + pid + ": " + st);

                 final String[] procStatsString = mProcessFullStatsStringData;
                 final long[] procStats = mProcessFullStatsData;
                 if (Process.readProcFile(st.statFile.toString(),
                         PROCESS_FULL_STATS_FORMAT, procStatsString,
                         procStats, null)) {
                     st.baseName = parentPid < 0
                             ? procStatsString[0] : Integer.toString(pid);
                     st.base_utime = 0; //procStats[1];
                     st.base_stime = 0; //procStats[2];
                     st.base_minfaults = st.base_majfaults = 0;
                 } else {
                     st.baseName = "<unknown>";
                     st.base_utime = st.base_stime = 0;
                     st.base_minfaults = st.base_majfaults = 0;
                 }

                 if (parentPid < 0) {
                     getName(st, st.cmdlineFile);
                 } else {
                     st.name = st.baseName;
                     st.nameWidth = onMeasureProcessName(st.name);
                     if (st.threadStats != null) {
                         mCurThreadPids = collectStats(st.threadsDir, pid, true,
                                 mCurThreadPids, st.threadStats,
                                 st.workingThreads);
                     }
                 }

                 //Slog.i("Load", "New process: " + st.pid + " " + st.name);
                 st.rel_utime = 0;
                 st.rel_stime = 0;
                 st.rel_minfaults = 0;
                 st.rel_majfaults = 0;
                 st.added = true;
                 if (!first) {
                     workingProcs.add(st);
                 }
                 continue;
             }

             // This process has gone away!
             st.rel_utime = 0;
             st.rel_stime = 0;
             st.rel_minfaults = 0;
             st.rel_majfaults = 0;
             st.removed = true;
             workingProcs.add(st);
             allProcs.remove(curStatsIndex);
             NS--;
             if (localLOGV) Slog.v(TAG, "Removed pid " + st.pid + ": " + st);
             // Decrement the loop counter so that we process the current pid
             // again the next time through the loop.
             i--;
             continue;
         }

         while (curStatsIndex < NS) {
             // This process has gone away!
             final Stats st = allProcs.get(curStatsIndex);
             st.rel_utime = 0;
             st.rel_stime = 0;
             st.rel_minfaults = 0;
             st.rel_majfaults = 0;
             st.removed = true;
             workingProcs.add(st);
             allProcs.remove(curStatsIndex);
             NS--;
             if (localLOGV) Slog.v(TAG, "Removed pid " + st.pid + ": " + st);
         }

         return pids;
     }

     public long getCpuTimeForPid(int pid) {
         final String statFile = "/proc/" + pid + "/stat";
         final long[] statsData = mSinglePidStatsData;
         if (Process.readProcFile(statFile, PROCESS_STATS_FORMAT,
                 null, statsData, null)) {
             long time = statsData[PROCESS_STAT_UTIME]
                     + statsData[PROCESS_STAT_STIME];
             return time;
         }
         return 0;
     }

     /**
      * Returns the times spent at each CPU speed, since the last call to this method. If this
      * is the first time, it will return 1 for each value.
      * @return relative times spent at different speed steps.
      */
     public long[] getLastCpuSpeedTimes() {
         if (mCpuSpeedTimes == null) {
             mCpuSpeedTimes = getCpuSpeedTimes(null);
             mRelCpuSpeedTimes = new long[mCpuSpeedTimes.length];
             for (int i = 0; i < mCpuSpeedTimes.length; i++) {
                 mRelCpuSpeedTimes[i] = 1; // Initialize
             }
         } else {
             getCpuSpeedTimes(mRelCpuSpeedTimes);
             for (int i = 0; i < mCpuSpeedTimes.length; i++) {
                 long temp = mRelCpuSpeedTimes[i];
                 mRelCpuSpeedTimes[i] -= mCpuSpeedTimes[i];
                 mCpuSpeedTimes[i] = temp;
             }
         }
         return mRelCpuSpeedTimes;
     }

     private long[] getCpuSpeedTimes(long[] out) {
         long[] tempTimes = out;
         long[] tempSpeeds = mCpuSpeeds;
         final int MAX_SPEEDS = 20;
         if (out == null) {
             tempTimes = new long[MAX_SPEEDS]; // Hopefully no more than that
             tempSpeeds = new long[MAX_SPEEDS];
         }
         int speed = 0;
         String file = readFile("/sys/devices/system/cpu/cpu0/cpufreq/stats/time_in_state", '\0');
         // Note: file may be null on kernels without cpufreq (i.e. the emulator's)
         if (file != null) {
             StringTokenizer st = new StringTokenizer(file, "\n ");
             while (st.hasMoreElements()) {
                 String token = st.nextToken();
                 try {
                     long val = Long.parseLong(token);
                     tempSpeeds[speed] = val;
                     token = st.nextToken();
                     val = Long.parseLong(token);
                     tempTimes[speed] = val;
                     speed++;
                     if (speed == MAX_SPEEDS) break; // No more
                     if (localLOGV && out == null) {
                         Slog.v(TAG, "First time : Speed/Time = " + tempSpeeds[speed - 1]
                               + "\t" + tempTimes[speed - 1]);
                     }
                 } catch (NumberFormatException nfe) {
                     Slog.i(TAG, "Unable to parse time_in_state");
                 }
             }
         }
         if (out == null) {
             out = new long[speed];
             mCpuSpeeds = new long[speed];
             System.arraycopy(tempSpeeds, 0, mCpuSpeeds, 0, speed);
             System.arraycopy(tempTimes, 0, out, 0, speed);
         }
         return out;
     }

     final public int getLastUserTime() {
         return mRelUserTime;
     }

     final public int getLastSystemTime() {
         return mRelSystemTime;
     }

     final public int getLastIoWaitTime() {
         return mRelIoWaitTime;
     }

     final public int getLastIrqTime() {
         return mRelIrqTime;
     }

     final public int getLastSoftIrqTime() {
         return mRelSoftIrqTime;
     }

     final public int getLastIdleTime() {
         return mRelIdleTime;
     }

     final public float getTotalCpuPercent() {
         return ((float)(mRelUserTime+mRelSystemTime+mRelIrqTime)*100)
                 / (mRelUserTime+mRelSystemTime+mRelIrqTime+mRelIdleTime);
     }

     final public int countWorkingStats() {
         if (!mWorkingProcsSorted) {
             Collections.sort(mWorkingProcs, sLoadComparator);
             mWorkingProcsSorted = true;
         }
         return mWorkingProcs.size();
     }

     final public Stats getWorkingStats(int index) {
         return mWorkingProcs.get(index);
     }

     final public String printCurrentState() {
         if (!mWorkingProcsSorted) {
             Collections.sort(mWorkingProcs, sLoadComparator);
             mWorkingProcsSorted = true;
         }

         StringWriter sw = new StringWriter();
         PrintWriter pw = new PrintWriter(sw);
         pw.print("Load: ");
         pw.print(mLoad1);
         pw.print(" / ");
         pw.print(mLoad5);
         pw.print(" / ");
         pw.println(mLoad15);

         long now = SystemClock.uptimeMillis();

         pw.print("CPU usage from ");
         pw.print(now-mLastSampleTime);
         pw.print("ms to ");
         pw.print(now-mCurrentSampleTime);
         pw.println("ms ago:");

         final int totalTime = mRelUserTime + mRelSystemTime + mRelIoWaitTime
                 + mRelIrqTime + mRelSoftIrqTime + mRelIdleTime;

         int N = mWorkingProcs.size();
         for (int i=0; i<N; i++) {
             Stats st = mWorkingProcs.get(i);
             printProcessCPU(pw, st.added ? " +" : (st.removed ? " -": "  "),
                     st.name, totalTime, st.rel_utime, st.rel_stime, 0, 0, 0,
                     st.rel_minfaults, st.rel_majfaults);
             if (!st.removed && st.workingThreads != null) {
                 int M = st.workingThreads.size();
                 for (int j=0; j<M; j++) {
                     Stats tst = st.workingThreads.get(j);
                     printProcessCPU(pw,
                             tst.added ? "   +" : (tst.removed ? "   -": "    "),
                             tst.name, totalTime, tst.rel_utime, tst.rel_stime,
                             0, 0, 0, 0, 0);
                 }
             }
         }

         printProcessCPU(pw, "", "TOTAL", totalTime, mRelUserTime, mRelSystemTime,
                 mRelIoWaitTime, mRelIrqTime, mRelSoftIrqTime, 0, 0);

         return sw.toString();
     }

     private void printProcessCPU(PrintWriter pw, String prefix, String label, int totalTime,
             int user, int system, int iowait, int irq, int softIrq, int minFaults, int majFaults) {
         pw.print(prefix);
         pw.print(label);
         pw.print(": ");
         if (totalTime == 0) totalTime = 1;
         pw.print(((user+system+iowait+irq+softIrq)*100)/totalTime);
         pw.print("% = ");
         pw.print((user*100)/totalTime);
         pw.print("% user + ");
         pw.print((system*100)/totalTime);
         pw.print("% kernel");
         if (iowait > 0) {
             pw.print(" + ");
             pw.print((iowait*100)/totalTime);
             pw.print("% iowait");
         }
         if (irq > 0) {
             pw.print(" + ");
             pw.print((irq*100)/totalTime);
             pw.print("% irq");
         }
         if (softIrq > 0) {
             pw.print(" + ");
             pw.print((softIrq*100)/totalTime);
             pw.print("% softirq");
         }
         if (minFaults > 0 || majFaults > 0) {
             pw.print(" / faults:");
             if (minFaults > 0) {
                 pw.print(" ");
                 pw.print(minFaults);
                 pw.print(" minor");
             }
             if (majFaults > 0) {
                 pw.print(" ");
                 pw.print(majFaults);
                 pw.print(" major");
             }
         }
         pw.println();
     }

     private String readFile(String file, char endChar) {
         try {
             FileInputStream is = new FileInputStream(file);
             int len = is.read(mBuffer);
             is.close();

             if (len > 0) {
                 int i;
                 for (i=0; i<len; i++) {
                     if (mBuffer[i] == endChar) {
                         break;
                     }
                 }
                 return new String(mBuffer, 0, 0, i);
             }
         } catch (java.io.FileNotFoundException e) {
         } catch (java.io.IOException e) {
         }
         return null;
     }

     private void getName(Stats st, String cmdlineFile) {
         String newName = st.baseName;
         if (st.baseName == null || st.baseName.equals("app_process")) {
             String cmdName = readFile(cmdlineFile, '\0');
             if (cmdName != null && cmdName.length() > 1) {
                 newName = cmdName;
                 int i = newName.lastIndexOf("/");
                 if (i > 0 && i < newName.length()-1) {
                     newName = newName.substring(i+1);
                 }
             }
         }
         if (st.name == null || !newName.equals(st.name)) {
             st.name = newName;
             st.nameWidth = onMeasureProcessName(st.name);
         }
     }
 }
	/*
	* Copyright (C) 2007 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.
	*/

	package com.android.server;

	import static android.os.Process.*;

	import android.os.Process;
	import android.os.SystemClock;
	import android.util.Config;
	import android.util.Slog;

	import java.io.File;
	import java.io.FileInputStream;
	import java.io.PrintWriter;
	import java.io.StringWriter;
	import java.util.ArrayList;
	import java.util.Collections;
	import java.util.Comparator;
	import java.util.StringTokenizer;

	public class ProcessStats {
	private static final String TAG = "ProcessStats";
	private static final boolean DEBUG = false;
	private static final boolean localLOGV = DEBUG \|\| Config.LOGV;

	private static final int[] PROCESS_STATS_FORMAT = new int[] {
	PROC_SPACE_TERM,
	PROC_SPACE_TERM,
	PROC_SPACE_TERM,
	PROC_SPACE_TERM,
	PROC_SPACE_TERM,
	PROC_SPACE_TERM,
	PROC_SPACE_TERM,
	PROC_SPACE_TERM,
	PROC_SPACE_TERM,
	PROC_SPACE_TERM\|PROC_OUT_LONG, // 9: minor faults
	PROC_SPACE_TERM,
	PROC_SPACE_TERM\|PROC_OUT_LONG, // 11: major faults
	PROC_SPACE_TERM,
	PROC_SPACE_TERM\|PROC_OUT_LONG, // 13: utime
	PROC_SPACE_TERM\|PROC_OUT_LONG // 14: stime
	};

	static final int PROCESS_STAT_MINOR_FAULTS = 0;
	static final int PROCESS_STAT_MAJOR_FAULTS = 1;
	static final int PROCESS_STAT_UTIME = 2;
	static final int PROCESS_STAT_STIME = 3;

	/** Stores user time and system time in 100ths of a second. */
	private final long[] mProcessStatsData = new long[4];
	/** Stores user time and system time in 100ths of a second. */
	private final long[] mSinglePidStatsData = new long[4];

	private static final int[] PROCESS_FULL_STATS_FORMAT = new int[] {
	PROC_SPACE_TERM,
	PROC_SPACE_TERM\|PROC_PARENS\|PROC_OUT_STRING, // 1: name
	PROC_SPACE_TERM,
	PROC_SPACE_TERM,
	PROC_SPACE_TERM,
	PROC_SPACE_TERM,
	PROC_SPACE_TERM,
	PROC_SPACE_TERM,
	PROC_SPACE_TERM,
	PROC_SPACE_TERM,
	PROC_SPACE_TERM,
	PROC_SPACE_TERM,
	PROC_SPACE_TERM,
	PROC_SPACE_TERM\|PROC_OUT_LONG, // 13: utime
	PROC_SPACE_TERM\|PROC_OUT_LONG // 14: stime
	};

	private final String[] mProcessFullStatsStringData = new String[3];
	private final long[] mProcessFullStatsData = new long[3];

	private static final int[] SYSTEM_CPU_FORMAT = new int[] {
	PROC_SPACE_TERM\|PROC_COMBINE,
	PROC_SPACE_TERM\|PROC_OUT_LONG, // 1: user time
	PROC_SPACE_TERM\|PROC_OUT_LONG, // 2: nice time
	PROC_SPACE_TERM\|PROC_OUT_LONG, // 3: sys time
	PROC_SPACE_TERM\|PROC_OUT_LONG, // 4: idle time
	PROC_SPACE_TERM\|PROC_OUT_LONG, // 5: iowait time
	PROC_SPACE_TERM\|PROC_OUT_LONG, // 6: irq time
	PROC_SPACE_TERM\|PROC_OUT_LONG // 7: softirq time
	};

	private final long[] mSystemCpuData = new long[7];

	private static final int[] LOAD_AVERAGE_FORMAT = new int[] {
	PROC_SPACE_TERM\|PROC_OUT_FLOAT, // 0: 1 min
	PROC_SPACE_TERM\|PROC_OUT_FLOAT, // 1: 5 mins
	PROC_SPACE_TERM\|PROC_OUT_FLOAT // 2: 15 mins
	};

	private final float[] mLoadAverageData = new float[3];

	private final boolean mIncludeThreads;

	private float mLoad1 = 0;
	private float mLoad5 = 0;
	private float mLoad15 = 0;

	private long mCurrentSampleTime;
	private long mLastSampleTime;

	private long mBaseUserTime;
	private long mBaseSystemTime;
	private long mBaseIoWaitTime;
	private long mBaseIrqTime;
	private long mBaseSoftIrqTime;
	private long mBaseIdleTime;
	private int mRelUserTime;
	private int mRelSystemTime;
	private int mRelIoWaitTime;
	private int mRelIrqTime;
	private int mRelSoftIrqTime;
	private int mRelIdleTime;

	private int[] mCurPids;
	private int[] mCurThreadPids;

	private final ArrayList<Stats> mProcStats = new ArrayList<Stats>();
	private final ArrayList<Stats> mWorkingProcs = new ArrayList<Stats>();
	private boolean mWorkingProcsSorted;

	private boolean mFirst = true;

	private byte[] mBuffer = new byte[256];

	/**
	* The time in microseconds that the CPU has been running at each speed.
	*/
	private long[] mCpuSpeedTimes;

	/**
	* The relative time in microseconds that the CPU has been running at each speed.
	*/
	private long[] mRelCpuSpeedTimes;

	/**
	* The different speeds that the CPU can be running at.
	*/
	private long[] mCpuSpeeds;

	public static class Stats {
	public final int pid;
	final String statFile;
	final String cmdlineFile;
	final String threadsDir;
	final ArrayList<Stats> threadStats;
	final ArrayList<Stats> workingThreads;

	public String baseName;
	public String name;
	int nameWidth;

	public long base_utime;
	public long base_stime;
	public int rel_utime;
	public int rel_stime;

	public long base_minfaults;
	public long base_majfaults;
	public int rel_minfaults;
	public int rel_majfaults;

	public boolean active;
	public boolean added;
	public boolean removed;

	Stats(int _pid, int parentPid, boolean includeThreads) {
	pid = _pid;
	if (parentPid < 0) {
	final File procDir = new File("/proc", Integer.toString(pid));
	statFile = new File(procDir, "stat").toString();
	cmdlineFile = new File(procDir, "cmdline").toString();
	threadsDir = (new File(procDir, "task")).toString();
	if (includeThreads) {
	threadStats = new ArrayList<Stats>();
	workingThreads = new ArrayList<Stats>();
	} else {
	threadStats = null;
	workingThreads = null;
	}
	} else {
	final File procDir = new File("/proc", Integer.toString(
	parentPid));
	final File taskDir = new File(
	new File(procDir, "task"), Integer.toString(pid));
	statFile = new File(taskDir, "stat").toString();
	cmdlineFile = null;
	threadsDir = null;
	threadStats = null;
	workingThreads = null;
	}
	}
	}

	private final static Comparator<Stats> sLoadComparator = new Comparator<Stats>() {
	public final int
	compare(Stats sta, Stats stb)
	{
	int ta = sta.rel_utime + sta.rel_stime;
	int tb = stb.rel_utime + stb.rel_stime;
	if (ta != tb) {
	return ta > tb ? -1 : 1;
	}
	if (sta.added != stb.added) {
	return sta.added ? -1 : 1;
	}
	if (sta.removed != stb.removed) {
	return sta.added ? -1 : 1;
	}
	return 0;
	}
	};


	public ProcessStats(boolean includeThreads) {
	mIncludeThreads = includeThreads;
	}

	public void onLoadChanged(float load1, float load5, float load15) {
	}

	public int onMeasureProcessName(String name) {
	return 0;
	}

	public void init() {
	mFirst = true;
	update();
	}

	public void update() {
	mLastSampleTime = mCurrentSampleTime;
	mCurrentSampleTime = SystemClock.uptimeMillis();

	final float[] loadAverages = mLoadAverageData;
	if (Process.readProcFile("/proc/loadavg", LOAD_AVERAGE_FORMAT,
	null, null, loadAverages)) {
	float load1 = loadAverages[0];
	float load5 = loadAverages[1];
	float load15 = loadAverages[2];
	if (load1 != mLoad1 \|\| load5 != mLoad5 \|\| load15 != mLoad15) {
	mLoad1 = load1;
	mLoad5 = load5;
	mLoad15 = load15;
	onLoadChanged(load1, load5, load15);
	}
	}

	mCurPids = collectStats("/proc", -1, mFirst, mCurPids,
	mProcStats, mWorkingProcs);
	mFirst = false;

	final long[] sysCpu = mSystemCpuData;
	if (Process.readProcFile("/proc/stat", SYSTEM_CPU_FORMAT,
	null, sysCpu, null)) {
	// Total user time is user + nice time.
	final long usertime = sysCpu[0]+sysCpu[1];
	// Total system time is simply system time.
	final long systemtime = sysCpu[2];
	// Total idle time is simply idle time.
	final long idletime = sysCpu[3];
	// Total irq time is iowait + irq + softirq time.
	final long iowaittime = sysCpu[4];
	final long irqtime = sysCpu[5];
	final long softirqtime = sysCpu[6];

	mRelUserTime = (int)(usertime - mBaseUserTime);
	mRelSystemTime = (int)(systemtime - mBaseSystemTime);
	mRelIoWaitTime = (int)(iowaittime - mBaseIoWaitTime);
	mRelIrqTime = (int)(irqtime - mBaseIrqTime);
	mRelSoftIrqTime = (int)(softirqtime - mBaseSoftIrqTime);
	mRelIdleTime = (int)(idletime - mBaseIdleTime);

	if (false) {
	Slog.i("Load", "Total U:" + sysCpu[0] + " N:" + sysCpu[1]
	+ " S:" + sysCpu[2] + " I:" + sysCpu[3]
	+ " W:" + sysCpu[4] + " Q:" + sysCpu[5]
	+ " O:" + sysCpu[6]);
	Slog.i("Load", "Rel U:" + mRelUserTime + " S:" + mRelSystemTime
	+ " I:" + mRelIdleTime + " Q:" + mRelIrqTime);
	}

	mBaseUserTime = usertime;
	mBaseSystemTime = systemtime;
	mBaseIoWaitTime = iowaittime;
	mBaseIrqTime = irqtime;
	mBaseSoftIrqTime = softirqtime;
	mBaseIdleTime = idletime;
	}

	mWorkingProcsSorted = false;
	mFirst = false;
	}

	private int[] collectStats(String statsFile, int parentPid, boolean first,
	int[] curPids, ArrayList<Stats> allProcs,
	ArrayList<Stats> workingProcs) {

	workingProcs.clear();

	int[] pids = Process.getPids(statsFile, curPids);
	int NP = (pids == null) ? 0 : pids.length;
	int NS = allProcs.size();
	int curStatsIndex = 0;
	for (int i=0; i<NP; i++) {
	int pid = pids[i];
	if (pid < 0) {
	NP = pid;
	break;
	}
	Stats st = curStatsIndex < NS ? allProcs.get(curStatsIndex) : null;

	if (st != null && st.pid == pid) {
	// Update an existing process...
	st.added = false;
	curStatsIndex++;
	if (localLOGV) Slog.v(TAG, "Existing pid " + pid + ": " + st);

	final long[] procStats = mProcessStatsData;
	if (!Process.readProcFile(st.statFile.toString(),
	PROCESS_STATS_FORMAT, null, procStats, null)) {
	continue;
	}

	final long minfaults = procStats[PROCESS_STAT_MINOR_FAULTS];
	final long majfaults = procStats[PROCESS_STAT_MAJOR_FAULTS];
	final long utime = procStats[PROCESS_STAT_UTIME];
	final long stime = procStats[PROCESS_STAT_STIME];

	if (utime == st.base_utime && stime == st.base_stime) {
	st.rel_utime = 0;
	st.rel_stime = 0;
	st.rel_minfaults = 0;
	st.rel_majfaults = 0;
	if (st.active) {
	st.active = false;
	}
	continue;
	}

	if (!st.active) {
	st.active = true;
	}

	if (parentPid < 0) {
	getName(st, st.cmdlineFile);
	if (st.threadStats != null) {
	mCurThreadPids = collectStats(st.threadsDir, pid, false,
	mCurThreadPids, st.threadStats,
	st.workingThreads);
	}
	}

	st.rel_utime = (int)(utime - st.base_utime);
	st.rel_stime = (int)(stime - st.base_stime);
	st.base_utime = utime;
	st.base_stime = stime;
	st.rel_minfaults = (int)(minfaults - st.base_minfaults);
	st.rel_majfaults = (int)(majfaults - st.base_majfaults);
	st.base_minfaults = minfaults;
	st.base_majfaults = majfaults;
	//Slog.i("Load", "Stats changed " + name + " pid=" + st.pid
	// + " name=" + st.name + " utime=" + utime
	// + " stime=" + stime);
	workingProcs.add(st);
	continue;
	}

	if (st == null \|\| st.pid > pid) {
	// We have a new process!
	st = new Stats(pid, parentPid, mIncludeThreads);
	allProcs.add(curStatsIndex, st);
	curStatsIndex++;
	NS++;
	if (localLOGV) Slog.v(TAG, "New pid " + pid + ": " + st);

	final String[] procStatsString = mProcessFullStatsStringData;
	final long[] procStats = mProcessFullStatsData;
	if (Process.readProcFile(st.statFile.toString(),
	PROCESS_FULL_STATS_FORMAT, procStatsString,
	procStats, null)) {
	st.baseName = parentPid < 0
	? procStatsString[0] : Integer.toString(pid);
	st.base_utime = 0; //procStats[1];
	st.base_stime = 0; //procStats[2];
	st.base_minfaults = st.base_majfaults = 0;
	} else {
	st.baseName = "<unknown>";
	st.base_utime = st.base_stime = 0;
	st.base_minfaults = st.base_majfaults = 0;
	}

	if (parentPid < 0) {
	getName(st, st.cmdlineFile);
	} else {
	st.name = st.baseName;
	st.nameWidth = onMeasureProcessName(st.name);
	if (st.threadStats != null) {
	mCurThreadPids = collectStats(st.threadsDir, pid, true,
	mCurThreadPids, st.threadStats,
	st.workingThreads);
	}
	}

	//Slog.i("Load", "New process: " + st.pid + " " + st.name);
	st.rel_utime = 0;
	st.rel_stime = 0;
	st.rel_minfaults = 0;
	st.rel_majfaults = 0;
	st.added = true;
	if (!first) {
	workingProcs.add(st);
	}
	continue;
	}

	// This process has gone away!
	st.rel_utime = 0;
	st.rel_stime = 0;
	st.rel_minfaults = 0;
	st.rel_majfaults = 0;
	st.removed = true;
	workingProcs.add(st);
	allProcs.remove(curStatsIndex);
	NS--;
	if (localLOGV) Slog.v(TAG, "Removed pid " + st.pid + ": " + st);
	// Decrement the loop counter so that we process the current pid
	// again the next time through the loop.
	i--;
	continue;
	}

	while (curStatsIndex < NS) {
	// This process has gone away!
	final Stats st = allProcs.get(curStatsIndex);
	st.rel_utime = 0;
	st.rel_stime = 0;
	st.rel_minfaults = 0;
	st.rel_majfaults = 0;
	st.removed = true;
	workingProcs.add(st);
	allProcs.remove(curStatsIndex);
	NS--;
	if (localLOGV) Slog.v(TAG, "Removed pid " + st.pid + ": " + st);
	}

	return pids;
	}

	public long getCpuTimeForPid(int pid) {
	final String statFile = "/proc/" + pid + "/stat";
	final long[] statsData = mSinglePidStatsData;
	if (Process.readProcFile(statFile, PROCESS_STATS_FORMAT,
	null, statsData, null)) {
	long time = statsData[PROCESS_STAT_UTIME]
	+ statsData[PROCESS_STAT_STIME];
	return time;
	}
	return 0;
	}

	/**
	* Returns the times spent at each CPU speed, since the last call to this method. If this
	* is the first time, it will return 1 for each value.
	* @return relative times spent at different speed steps.
	*/
	public long[] getLastCpuSpeedTimes() {
	if (mCpuSpeedTimes == null) {
	mCpuSpeedTimes = getCpuSpeedTimes(null);
	mRelCpuSpeedTimes = new long[mCpuSpeedTimes.length];
	for (int i = 0; i < mCpuSpeedTimes.length; i++) {
	mRelCpuSpeedTimes[i] = 1; // Initialize
	}
	} else {
	getCpuSpeedTimes(mRelCpuSpeedTimes);
	for (int i = 0; i < mCpuSpeedTimes.length; i++) {
	long temp = mRelCpuSpeedTimes[i];
	mRelCpuSpeedTimes[i] -= mCpuSpeedTimes[i];
	mCpuSpeedTimes[i] = temp;
	}
	}
	return mRelCpuSpeedTimes;
	}

	private long[] getCpuSpeedTimes(long[] out) {
	long[] tempTimes = out;
	long[] tempSpeeds = mCpuSpeeds;
	final int MAX_SPEEDS = 20;
	if (out == null) {
	tempTimes = new long[MAX_SPEEDS]; // Hopefully no more than that
	tempSpeeds = new long[MAX_SPEEDS];
	}
	int speed = 0;
	String file = readFile("/sys/devices/system/cpu/cpu0/cpufreq/stats/time_in_state", '\0');
	// Note: file may be null on kernels without cpufreq (i.e. the emulator's)
	if (file != null) {
	StringTokenizer st = new StringTokenizer(file, "\n ");
	while (st.hasMoreElements()) {
	String token = st.nextToken();
	try {
	long val = Long.parseLong(token);
	tempSpeeds[speed] = val;
	token = st.nextToken();
	val = Long.parseLong(token);
	tempTimes[speed] = val;
	speed++;
	if (speed == MAX_SPEEDS) break; // No more
	if (localLOGV && out == null) {
	Slog.v(TAG, "First time : Speed/Time = " + tempSpeeds[speed - 1]
	+ "\t" + tempTimes[speed - 1]);
	}
	} catch (NumberFormatException nfe) {
	Slog.i(TAG, "Unable to parse time_in_state");
	}
	}
	}
	if (out == null) {
	out = new long[speed];
	mCpuSpeeds = new long[speed];
	System.arraycopy(tempSpeeds, 0, mCpuSpeeds, 0, speed);
	System.arraycopy(tempTimes, 0, out, 0, speed);
	}
	return out;
	}

	final public int getLastUserTime() {
	return mRelUserTime;
	}

	final public int getLastSystemTime() {
	return mRelSystemTime;
	}

	final public int getLastIoWaitTime() {
	return mRelIoWaitTime;
	}

	final public int getLastIrqTime() {
	return mRelIrqTime;
	}

	final public int getLastSoftIrqTime() {
	return mRelSoftIrqTime;
	}

	final public int getLastIdleTime() {
	return mRelIdleTime;
	}

	final public float getTotalCpuPercent() {
	return ((float)(mRelUserTime+mRelSystemTime+mRelIrqTime)*100)
	/ (mRelUserTime+mRelSystemTime+mRelIrqTime+mRelIdleTime);
	}

	final public int countWorkingStats() {
	if (!mWorkingProcsSorted) {
	Collections.sort(mWorkingProcs, sLoadComparator);
	mWorkingProcsSorted = true;
	}
	return mWorkingProcs.size();
	}

	final public Stats getWorkingStats(int index) {
	return mWorkingProcs.get(index);
	}

	final public String printCurrentState() {
	if (!mWorkingProcsSorted) {
	Collections.sort(mWorkingProcs, sLoadComparator);
	mWorkingProcsSorted = true;
	}

	StringWriter sw = new StringWriter();
	PrintWriter pw = new PrintWriter(sw);
	pw.print("Load: ");
	pw.print(mLoad1);
	pw.print(" / ");
	pw.print(mLoad5);
	pw.print(" / ");
	pw.println(mLoad15);

	long now = SystemClock.uptimeMillis();

	pw.print("CPU usage from ");
	pw.print(now-mLastSampleTime);
	pw.print("ms to ");
	pw.print(now-mCurrentSampleTime);
	pw.println("ms ago:");

	final int totalTime = mRelUserTime + mRelSystemTime + mRelIoWaitTime
	+ mRelIrqTime + mRelSoftIrqTime + mRelIdleTime;

	int N = mWorkingProcs.size();
	for (int i=0; i<N; i++) {
	Stats st = mWorkingProcs.get(i);
	printProcessCPU(pw, st.added ? " +" : (st.removed ? " -": " "),
	st.name, totalTime, st.rel_utime, st.rel_stime, 0, 0, 0,
	st.rel_minfaults, st.rel_majfaults);
	if (!st.removed && st.workingThreads != null) {
	int M = st.workingThreads.size();
	for (int j=0; j<M; j++) {
	Stats tst = st.workingThreads.get(j);
	printProcessCPU(pw,
	tst.added ? " +" : (tst.removed ? " -": " "),
	tst.name, totalTime, tst.rel_utime, tst.rel_stime,
	0, 0, 0, 0, 0);
	}
	}
	}

	printProcessCPU(pw, "", "TOTAL", totalTime, mRelUserTime, mRelSystemTime,
	mRelIoWaitTime, mRelIrqTime, mRelSoftIrqTime, 0, 0);

	return sw.toString();
	}

	private void printProcessCPU(PrintWriter pw, String prefix, String label, int totalTime,
	int user, int system, int iowait, int irq, int softIrq, int minFaults, int majFaults) {
	pw.print(prefix);
	pw.print(label);
	pw.print(": ");
	if (totalTime == 0) totalTime = 1;
	pw.print(((user+system+iowait+irq+softIrq)*100)/totalTime);
	pw.print("% = ");
	pw.print((user*100)/totalTime);
	pw.print("% user + ");
	pw.print((system*100)/totalTime);
	pw.print("% kernel");
	if (iowait > 0) {
	pw.print(" + ");
	pw.print((iowait*100)/totalTime);
	pw.print("% iowait");
	}
	if (irq > 0) {
	pw.print(" + ");
	pw.print((irq*100)/totalTime);
	pw.print("% irq");
	}
	if (softIrq > 0) {
	pw.print(" + ");
	pw.print((softIrq*100)/totalTime);
	pw.print("% softirq");
	}
	if (minFaults > 0 \|\| majFaults > 0) {
	pw.print(" / faults:");
	if (minFaults > 0) {
	pw.print(" ");
	pw.print(minFaults);
	pw.print(" minor");
	}
	if (majFaults > 0) {
	pw.print(" ");
	pw.print(majFaults);
	pw.print(" major");
	}
	}
	pw.println();
	}

	private String readFile(String file, char endChar) {
	try {
	FileInputStream is = new FileInputStream(file);
	int len = is.read(mBuffer);
	is.close();

	if (len > 0) {
	int i;
	for (i=0; i<len; i++) {
	if (mBuffer[i] == endChar) {
	break;
	}
	}
	return new String(mBuffer, 0, 0, i);
	}
	} catch (java.io.FileNotFoundException e) {
	} catch (java.io.IOException e) {
	}
	return null;
	}

	private void getName(Stats st, String cmdlineFile) {
	String newName = st.baseName;
	if (st.baseName == null \|\| st.baseName.equals("app_process")) {
	String cmdName = readFile(cmdlineFile, '\0');
	if (cmdName != null && cmdName.length() > 1) {
	newName = cmdName;
	int i = newName.lastIndexOf("/");
	if (i > 0 && i < newName.length()-1) {
	newName = newName.substring(i+1);
	}
	}
	}
	if (st.name == null \|\| !newName.equals(st.name)) {
	st.name = newName;
	st.nameWidth = onMeasureProcessName(st.name);
	}
	}
	}