com/android/internal/os/ProcTimeInStateReader.java - platform/prebuilts/fullsdk/sources/android-30 - Git at Google

 /*
  * 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.
  */

 package com.android.internal.os;

 import android.annotation.Nullable;
 import android.os.Process;

 import com.android.internal.util.ArrayUtils;

 import java.io.IOException;
 import java.nio.file.Files;
 import java.nio.file.Path;
 import java.util.ArrayList;
 import java.util.Arrays;
 import java.util.Collections;
 import java.util.List;

 /**
  * Reads and parses {@code time_in_state} files in the {@code proc} filesystem.
  *
  * Every line in a {@code time_in_state} file contains two numbers, separated by a single space
  * character. The first number is the frequency of the CPU used in kilohertz. The second number is
  * the time spent in this frequency. In the {@code time_in_state} file, this is given in 10s of
  * milliseconds, but this class returns in milliseconds. This can be per user, process, or thread
  * depending on which {@code time_in_state} file is used.
  *
  * For example, a {@code time_in_state} file would look like this:
  * <pre>
  *   300000 3
  *   364800 0
  *   ...
  *   1824000 0
  *   1900800 1
  * </pre>
  *
  * This file would indicate that the CPU has spent 30 milliseconds at frequency 300,000KHz (300Mhz)
  * and 10 milliseconds at frequency 1,900,800KHz (1.9GHz).
  *
  * <p>This class will also read {@code time_in_state} files with headers, such as:
  * <pre>
  *   cpu0
  *   300000 3
  *   364800 0
  *   ...
  *   cpu4
  *   300000 1
  *   364800 4
  * </pre>
  */
 public class ProcTimeInStateReader {
     private static final String TAG = "ProcTimeInStateReader";

     /**
      * The format of a single line of the {@code time_in_state} file that exports the frequency
      * values
      */
     private static final List<Integer> TIME_IN_STATE_LINE_FREQUENCY_FORMAT = Arrays.asList(
             Process.PROC_OUT_LONG | Process.PROC_SPACE_TERM,
             Process.PROC_NEWLINE_TERM
     );

     /**
      * The format of a single line of the {@code time_in_state} file that exports the time values
      */
     private static final List<Integer> TIME_IN_STATE_LINE_TIME_FORMAT = Arrays.asList(
             Process.PROC_SPACE_TERM,
             Process.PROC_OUT_LONG | Process.PROC_NEWLINE_TERM
     );

     /**
      * The format of a header line of the {@code time_in_state} file
      */
     private static final List<Integer> TIME_IN_STATE_HEADER_LINE_FORMAT =
             Collections.singletonList(Process.PROC_NEWLINE_TERM);

     /**
      * The format of the {@code time_in_state} file to extract times, defined using {@link
      * Process}'s {@code PROC_OUT_LONG} and related variables
      */
     private int[] mTimeInStateTimeFormat;

     /**
      * The frequencies reported in each {@code time_in_state} file
      *
      * Defined on first successful read of {@code time_in_state} file.
      */
     private long[] mFrequenciesKhz;

     /**
      * @param initialTimeInStateFile the file to base the format of the frequency files on, and to
      * read frequencies from. Expected to be in the same format as all other {@code time_in_state}
      * files, and contain the same frequencies.
      * @throws IOException if reading the initial {@code time_in_state} file failed
      */
     public ProcTimeInStateReader(Path initialTimeInStateFile) throws IOException {
         initializeTimeInStateFormat(initialTimeInStateFile);
     }

     /**
      * Read the CPU usages from a file
      *
      * @param timeInStatePath path where the CPU usages are read from
      * @return list of CPU usage times from the file. These correspond to the CPU frequencies given
      * by {@link ProcTimeInStateReader#getFrequenciesKhz}
      */
     @Nullable
     public long[] getUsageTimesMillis(final Path timeInStatePath) {
         // Read in the time_in_state file
         final long[] readLongs = new long[mFrequenciesKhz.length];
         final boolean readSuccess = Process.readProcFile(
                 timeInStatePath.toString(),
                 mTimeInStateTimeFormat,
                 null, readLongs, null);
         if (!readSuccess) {
             return null;
         }
         // Usage time is given in 10ms, so convert to ms
         for (int i = 0; i < readLongs.length; i++) {
             readLongs[i] *= 10;
         }
         return readLongs;
     }

     /**
      * Get the frequencies found in each {@code time_in_state} file
      *
      * @return list of CPU frequencies. These correspond to the CPU times given by {@link
      * ProcTimeInStateReader#getUsageTimesMillis(Path)}()}.
      */
     @Nullable
     public long[] getFrequenciesKhz() {
         return mFrequenciesKhz;
     }

     /**
      * Set the {@link #mTimeInStateTimeFormat} and {@link #mFrequenciesKhz} variables based on the
      * an input file. If the file is empty, these variables aren't set
      *
      * This needs to be run once on the first invocation of {@link #getUsageTimesMillis(Path)}. This
      * is because we need to know how many frequencies are available in order to parse time
      * {@code time_in_state} file using {@link Process#readProcFile}, which only accepts
      * fixed-length formats. Also, as the frequencies do not change between {@code time_in_state}
      * files, we read and store them here.
      *
      * @param timeInStatePath the input file to base the format off of
      */
     private void initializeTimeInStateFormat(final Path timeInStatePath) throws IOException {
         // Read the bytes of the `time_in_state` file
         byte[] timeInStateBytes = Files.readAllBytes(timeInStatePath);

         // Iterate over the lines of the time_in_state file, for each one adding a line to the
         // formats. These formats are used to extract either the frequencies or the times from a
         // time_in_state file
         // Also check if each line is a header, and handle this in the created format arrays
         ArrayList<Integer> timeInStateFrequencyFormat = new ArrayList<>();
         ArrayList<Integer> timeInStateTimeFormat = new ArrayList<>();
         int numFrequencies = 0;
         for (int i = 0; i < timeInStateBytes.length; i++) {
             // If the first character of the line is not a digit, we treat it as a header
             if (!Character.isDigit(timeInStateBytes[i])) {
                 timeInStateFrequencyFormat.addAll(TIME_IN_STATE_HEADER_LINE_FORMAT);
                 timeInStateTimeFormat.addAll(TIME_IN_STATE_HEADER_LINE_FORMAT);
             } else {
                 timeInStateFrequencyFormat.addAll(TIME_IN_STATE_LINE_FREQUENCY_FORMAT);
                 timeInStateTimeFormat.addAll(TIME_IN_STATE_LINE_TIME_FORMAT);
                 numFrequencies++;
             }
             // Go to the next line
             while (i < timeInStateBytes.length && timeInStateBytes[i] != '\n') {
                 i++;
             }
         }

         if (numFrequencies == 0) {
             throw new IOException("Empty time_in_state file");
         }

         // Read the frequencies from the `time_in_state` file and store them, as they will be the
         // same for every `time_in_state` file
         final long[] readLongs = new long[numFrequencies];
         final boolean readSuccess = Process.parseProcLine(
                 timeInStateBytes, 0, timeInStateBytes.length,
                 ArrayUtils.convertToIntArray(timeInStateFrequencyFormat), null, readLongs, null);
         if (!readSuccess) {
             throw new IOException("Failed to parse time_in_state file");
         }

         mTimeInStateTimeFormat = ArrayUtils.convertToIntArray(timeInStateTimeFormat);
         mFrequenciesKhz = readLongs;
     }
 }
	/*
	* 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.
	*/

	package com.android.internal.os;

	import android.annotation.Nullable;
	import android.os.Process;

	import com.android.internal.util.ArrayUtils;

	import java.io.IOException;
	import java.nio.file.Files;
	import java.nio.file.Path;
	import java.util.ArrayList;
	import java.util.Arrays;
	import java.util.Collections;
	import java.util.List;

	/**
	* Reads and parses {@code time_in_state} files in the {@code proc} filesystem.
	*
	* Every line in a {@code time_in_state} file contains two numbers, separated by a single space
	* character. The first number is the frequency of the CPU used in kilohertz. The second number is
	* the time spent in this frequency. In the {@code time_in_state} file, this is given in 10s of
	* milliseconds, but this class returns in milliseconds. This can be per user, process, or thread
	* depending on which {@code time_in_state} file is used.
	*
	* For example, a {@code time_in_state} file would look like this:
	* <pre>
	* 300000 3
	* 364800 0
	* ...
	* 1824000 0
	* 1900800 1
	* </pre>
	*
	* This file would indicate that the CPU has spent 30 milliseconds at frequency 300,000KHz (300Mhz)
	* and 10 milliseconds at frequency 1,900,800KHz (1.9GHz).
	*
	* <p>This class will also read {@code time_in_state} files with headers, such as:
	* <pre>
	* cpu0
	* 300000 3
	* 364800 0
	* ...
	* cpu4
	* 300000 1
	* 364800 4
	* </pre>
	*/
	public class ProcTimeInStateReader {
	private static final String TAG = "ProcTimeInStateReader";

	/**
	* The format of a single line of the {@code time_in_state} file that exports the frequency
	* values
	*/
	private static final List<Integer> TIME_IN_STATE_LINE_FREQUENCY_FORMAT = Arrays.asList(
	Process.PROC_OUT_LONG \| Process.PROC_SPACE_TERM,
	Process.PROC_NEWLINE_TERM
	);

	/**
	* The format of a single line of the {@code time_in_state} file that exports the time values
	*/
	private static final List<Integer> TIME_IN_STATE_LINE_TIME_FORMAT = Arrays.asList(
	Process.PROC_SPACE_TERM,
	Process.PROC_OUT_LONG \| Process.PROC_NEWLINE_TERM
	);

	/**
	* The format of a header line of the {@code time_in_state} file
	*/
	private static final List<Integer> TIME_IN_STATE_HEADER_LINE_FORMAT =
	Collections.singletonList(Process.PROC_NEWLINE_TERM);

	/**
	* The format of the {@code time_in_state} file to extract times, defined using {@link
	* Process}'s {@code PROC_OUT_LONG} and related variables
	*/
	private int[] mTimeInStateTimeFormat;

	/**
	* The frequencies reported in each {@code time_in_state} file
	*
	* Defined on first successful read of {@code time_in_state} file.
	*/
	private long[] mFrequenciesKhz;

	/**
	* @param initialTimeInStateFile the file to base the format of the frequency files on, and to
	* read frequencies from. Expected to be in the same format as all other {@code time_in_state}
	* files, and contain the same frequencies.
	* @throws IOException if reading the initial {@code time_in_state} file failed
	*/
	public ProcTimeInStateReader(Path initialTimeInStateFile) throws IOException {
	initializeTimeInStateFormat(initialTimeInStateFile);
	}

	/**
	* Read the CPU usages from a file
	*
	* @param timeInStatePath path where the CPU usages are read from
	* @return list of CPU usage times from the file. These correspond to the CPU frequencies given
	* by {@link ProcTimeInStateReader#getFrequenciesKhz}
	*/
	@Nullable
	public long[] getUsageTimesMillis(final Path timeInStatePath) {
	// Read in the time_in_state file
	final long[] readLongs = new long[mFrequenciesKhz.length];
	final boolean readSuccess = Process.readProcFile(
	timeInStatePath.toString(),
	mTimeInStateTimeFormat,
	null, readLongs, null);
	if (!readSuccess) {
	return null;
	}
	// Usage time is given in 10ms, so convert to ms
	for (int i = 0; i < readLongs.length; i++) {
	readLongs[i] *= 10;
	}
	return readLongs;
	}

	/**
	* Get the frequencies found in each {@code time_in_state} file
	*
	* @return list of CPU frequencies. These correspond to the CPU times given by {@link
	* ProcTimeInStateReader#getUsageTimesMillis(Path)}()}.
	*/
	@Nullable
	public long[] getFrequenciesKhz() {
	return mFrequenciesKhz;
	}

	/**
	* Set the {@link #mTimeInStateTimeFormat} and {@link #mFrequenciesKhz} variables based on the
	* an input file. If the file is empty, these variables aren't set
	*
	* This needs to be run once on the first invocation of {@link #getUsageTimesMillis(Path)}. This
	* is because we need to know how many frequencies are available in order to parse time
	* {@code time_in_state} file using {@link Process#readProcFile}, which only accepts
	* fixed-length formats. Also, as the frequencies do not change between {@code time_in_state}
	* files, we read and store them here.
	*
	* @param timeInStatePath the input file to base the format off of
	*/
	private void initializeTimeInStateFormat(final Path timeInStatePath) throws IOException {
	// Read the bytes of the `time_in_state` file
	byte[] timeInStateBytes = Files.readAllBytes(timeInStatePath);

	// Iterate over the lines of the time_in_state file, for each one adding a line to the
	// formats. These formats are used to extract either the frequencies or the times from a
	// time_in_state file
	// Also check if each line is a header, and handle this in the created format arrays
	ArrayList<Integer> timeInStateFrequencyFormat = new ArrayList<>();
	ArrayList<Integer> timeInStateTimeFormat = new ArrayList<>();
	int numFrequencies = 0;
	for (int i = 0; i < timeInStateBytes.length; i++) {
	// If the first character of the line is not a digit, we treat it as a header
	if (!Character.isDigit(timeInStateBytes[i])) {
	timeInStateFrequencyFormat.addAll(TIME_IN_STATE_HEADER_LINE_FORMAT);
	timeInStateTimeFormat.addAll(TIME_IN_STATE_HEADER_LINE_FORMAT);
	} else {
	timeInStateFrequencyFormat.addAll(TIME_IN_STATE_LINE_FREQUENCY_FORMAT);
	timeInStateTimeFormat.addAll(TIME_IN_STATE_LINE_TIME_FORMAT);
	numFrequencies++;
	}
	// Go to the next line
	while (i < timeInStateBytes.length && timeInStateBytes[i] != '\n') {
	i++;
	}
	}

	if (numFrequencies == 0) {
	throw new IOException("Empty time_in_state file");
	}

	// Read the frequencies from the `time_in_state` file and store them, as they will be the
	// same for every `time_in_state` file
	final long[] readLongs = new long[numFrequencies];
	final boolean readSuccess = Process.parseProcLine(
	timeInStateBytes, 0, timeInStateBytes.length,
	ArrayUtils.convertToIntArray(timeInStateFrequencyFormat), null, readLongs, null);
	if (!readSuccess) {
	throw new IOException("Failed to parse time_in_state file");
	}

	mTimeInStateTimeFormat = ArrayUtils.convertToIntArray(timeInStateTimeFormat);
	mFrequenciesKhz = readLongs;
	}
	}