/** * Copyright (C) 2009 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.telephony; import android.content.Context; import android.os.Build; import android.os.PersistableBundle; import android.os.SystemProperties; import android.telephony.CarrierConfigManager; import android.telephony.Rlog; import android.text.TextUtils; import android.util.Pair; import com.android.internal.telephony.dataconnection.ApnSetting; import java.io.FileDescriptor; import java.io.PrintWriter; import java.util.ArrayList; import java.util.Random; /** * Retry manager allows a simple way to declare a series of * retry timeouts. After creating a RetryManager the configure * method is used to define the sequence. A simple linear series * may be initialized using configure with three integer parameters * The other configure method allows a series to be declared using * a string. *

* The format of the configuration string is a series of parameters * separated by a comma. There are two name value pair parameters plus a series * of delay times. The units of of these delay times is unspecified. * The name value pairs which may be specified are: *

*

* max_retries is the number of times that incrementRetryCount * maybe called before isRetryNeeded will return false. if value * is infinite then isRetryNeeded will always return true. * * default_randomizationTime will be used as the randomizationTime * for delay times which have no supplied randomizationTime. If * default_randomizationTime is not defined it defaults to 0. *

* The other parameters define The series of delay times and each * may have an optional randomization value separated from the * delay time by a colon. *

* Examples: *

* * {@hide} */ public class RetryManager { public static final String LOG_TAG = "RetryManager"; public static final boolean DBG = true; public static final boolean VDBG = false; // STOPSHIP if true /** * The default retry configuration for default type APN. See above for the syntax. */ private static final String DEFAULT_DATA_RETRY_CONFIG = "default_randomization=2000," + "5000,10000,20000,40000,80000:5000,160000:5000," + "320000:5000,640000:5000,1280000:5000,1800000:5000"; /** * Retry configuration for networks other than default type, for example, mms. See above * for the syntax. */ private static final String OTHERS_DATA_RETRY_CONFIG = "max_retries=3, 5000, 5000, 5000"; /** * The default value (in milliseconds) for delay between APN trying (mInterApnDelay) * within the same round */ private static final long DEFAULT_INTER_APN_DELAY = 20000; /** * The default value (in milliseconds) for delay between APN trying (mFailFastInterApnDelay) * within the same round when we are in fail fast mode */ private static final long DEFAULT_INTER_APN_DELAY_FOR_PROVISIONING = 3000; /** * The value indicating no retry is needed */ public static final long NO_RETRY = -1; /** * The value indicating modem did not suggest any retry delay */ public static final long NO_SUGGESTED_RETRY_DELAY = -2; /** * If the modem suggests a retry delay in the data call setup response, we will retry * the current APN setting again. However, if the modem keeps suggesting retrying the same * APN setting, we'll fall into an infinite loop. Therefore adding a counter to retry up to * MAX_SAME_APN_RETRY times can avoid it. */ private static final int MAX_SAME_APN_RETRY = 3; /** * The delay (in milliseconds) between APN trying within the same round */ private long mInterApnDelay; /** * The delay (in milliseconds) between APN trying within the same round when we are in * fail fast mode */ private long mFailFastInterApnDelay; /** * Modem suggested delay for retrying the current APN */ private long mModemSuggestedDelay = NO_SUGGESTED_RETRY_DELAY; /** * The counter for same APN retrying. See MAX_SAME_APN_RETRY for the details. */ private int mSameApnRetryCount = 0; /** * Retry record with times in milli-seconds */ private static class RetryRec { RetryRec(int delayTime, int randomizationTime) { mDelayTime = delayTime; mRandomizationTime = randomizationTime; } int mDelayTime; int mRandomizationTime; } /** * The array of retry records */ private ArrayList mRetryArray = new ArrayList(); private Phone mPhone; /** * Flag indicating whether retrying forever regardless the maximum retry count mMaxRetryCount */ private boolean mRetryForever = false; /** * The maximum number of retries to attempt */ private int mMaxRetryCount; /** * The current number of retries */ private int mRetryCount = 0; /** * Random number generator. The random delay will be added into retry timer to avoid all devices * around retrying the APN at the same time. */ private Random mRng = new Random(); /** * Retry manager configuration string. See top of the detailed explanation. */ private String mConfig; /** * The list to store APN setting candidates for data call setup. Most of the carriers only have * one APN, but few carriers have more than one. */ private ArrayList mWaitingApns = null; /** * Index pointing to the current trying APN from mWaitingApns */ private int mCurrentApnIndex = -1; /** * Apn context type. Could be "default, "mms", "supl", etc... */ private String mApnType; /** * Retry manager constructor * @param phone Phone object * @param apnType APN type */ public RetryManager(Phone phone, String apnType) { mPhone = phone; mApnType = apnType; } /** * Configure for using string which allow arbitrary * sequences of times. See class comments for the * string format. * * @return true if successful */ private boolean configure(String configStr) { // Strip quotes if present. if ((configStr.startsWith("\"") && configStr.endsWith("\""))) { configStr = configStr.substring(1, configStr.length() - 1); } // Reset the retry manager since delay, max retry count, etc...will be reset. reset(); if (DBG) log("configure: '" + configStr + "'"); mConfig = configStr; if (!TextUtils.isEmpty(configStr)) { int defaultRandomization = 0; if (VDBG) log("configure: not empty"); String strArray[] = configStr.split(","); for (int i = 0; i < strArray.length; i++) { if (VDBG) log("configure: strArray[" + i + "]='" + strArray[i] + "'"); Pair value; String splitStr[] = strArray[i].split("=", 2); splitStr[0] = splitStr[0].trim(); if (VDBG) log("configure: splitStr[0]='" + splitStr[0] + "'"); if (splitStr.length > 1) { splitStr[1] = splitStr[1].trim(); if (VDBG) log("configure: splitStr[1]='" + splitStr[1] + "'"); if (TextUtils.equals(splitStr[0], "default_randomization")) { value = parseNonNegativeInt(splitStr[0], splitStr[1]); if (!value.first) return false; defaultRandomization = value.second; } else if (TextUtils.equals(splitStr[0], "max_retries")) { if (TextUtils.equals("infinite", splitStr[1])) { mRetryForever = true; } else { value = parseNonNegativeInt(splitStr[0], splitStr[1]); if (!value.first) return false; mMaxRetryCount = value.second; } } else { Rlog.e(LOG_TAG, "Unrecognized configuration name value pair: " + strArray[i]); return false; } } else { /** * Assume a retry time with an optional randomization value * following a ":" */ splitStr = strArray[i].split(":", 2); splitStr[0] = splitStr[0].trim(); RetryRec rr = new RetryRec(0, 0); value = parseNonNegativeInt("delayTime", splitStr[0]); if (!value.first) return false; rr.mDelayTime = value.second; // Check if optional randomization value present if (splitStr.length > 1) { splitStr[1] = splitStr[1].trim(); if (VDBG) log("configure: splitStr[1]='" + splitStr[1] + "'"); value = parseNonNegativeInt("randomizationTime", splitStr[1]); if (!value.first) return false; rr.mRandomizationTime = value.second; } else { rr.mRandomizationTime = defaultRandomization; } mRetryArray.add(rr); } } if (mRetryArray.size() > mMaxRetryCount) { mMaxRetryCount = mRetryArray.size(); if (VDBG) log("configure: setting mMaxRetryCount=" + mMaxRetryCount); } } else { log("configure: cleared"); } if (VDBG) log("configure: true"); return true; } /** * Configure the retry manager * @param forDefault True if the APN support default type */ private void configureRetry(boolean forDefault) { String configString = ""; try { if (Build.IS_DEBUGGABLE) { // Using system properties is easier for testing from command line. String config = SystemProperties.get("test.data_retry_config"); if (!TextUtils.isEmpty(config)) { configure(config); return; } } CarrierConfigManager configManager = (CarrierConfigManager) mPhone.getContext().getSystemService(Context.CARRIER_CONFIG_SERVICE); PersistableBundle b = configManager.getConfigForSubId(mPhone.getSubId()); mInterApnDelay = b.getLong( CarrierConfigManager.KEY_CARRIER_DATA_CALL_APN_DELAY_DEFAULT_LONG, DEFAULT_INTER_APN_DELAY); mFailFastInterApnDelay = b.getLong( CarrierConfigManager.KEY_CARRIER_DATA_CALL_APN_DELAY_FASTER_LONG, DEFAULT_INTER_APN_DELAY_FOR_PROVISIONING); if (forDefault) { configString = b.getString( CarrierConfigManager.KEY_CARRIER_DATA_CALL_RETRY_CONFIG_DEFAULT_STRING, DEFAULT_DATA_RETRY_CONFIG); } else { configString = b.getString( CarrierConfigManager.KEY_CARRIER_DATA_CALL_RETRY_CONFIG_OTHERS_STRING, OTHERS_DATA_RETRY_CONFIG); } } catch (NullPointerException ex) { log("Failed to read configuration! Use the hardcoded default value."); mInterApnDelay = DEFAULT_INTER_APN_DELAY; mFailFastInterApnDelay = DEFAULT_INTER_APN_DELAY_FOR_PROVISIONING; configString = (forDefault) ? DEFAULT_DATA_RETRY_CONFIG : OTHERS_DATA_RETRY_CONFIG; } if (VDBG) { log("mInterApnDelay = " + mInterApnDelay + ", mFailFastInterApnDelay = " + mFailFastInterApnDelay); } configure(configString); } /** * Return the timer that should be used to trigger the data reconnection */ private int getRetryTimer() { int index; if (mRetryCount < mRetryArray.size()) { index = mRetryCount; } else { index = mRetryArray.size() - 1; } int retVal; if ((index >= 0) && (index < mRetryArray.size())) { retVal = mRetryArray.get(index).mDelayTime + nextRandomizationTime(index); } else { retVal = 0; } if (DBG) log("getRetryTimer: " + retVal); return retVal; } /** * Parse an integer validating the value is not negative. * @param name Name * @param stringValue Value * @return Pair.first == true if stringValue an integer >= 0 */ private Pair parseNonNegativeInt(String name, String stringValue) { int value; Pair retVal; try { value = Integer.parseInt(stringValue); retVal = new Pair(validateNonNegativeInt(name, value), value); } catch (NumberFormatException e) { Rlog.e(LOG_TAG, name + " bad value: " + stringValue, e); retVal = new Pair(false, 0); } if (VDBG) { log("parseNonNetativeInt: " + name + ", " + stringValue + ", " + retVal.first + ", " + retVal.second); } return retVal; } /** * Validate an integer is >= 0 and logs an error if not * @param name Name * @param value Value * @return Pair.first */ private boolean validateNonNegativeInt(String name, int value) { boolean retVal; if (value < 0) { Rlog.e(LOG_TAG, name + " bad value: is < 0"); retVal = false; } else { retVal = true; } if (VDBG) log("validateNonNegative: " + name + ", " + value + ", " + retVal); return retVal; } /** * Return next random number for the index * @param index Retry index */ private int nextRandomizationTime(int index) { int randomTime = mRetryArray.get(index).mRandomizationTime; if (randomTime == 0) { return 0; } else { return mRng.nextInt(randomTime); } } /** * Get the next APN setting for data call setup. * @return APN setting to try */ public ApnSetting getNextApnSetting() { if (mWaitingApns == null || mWaitingApns.size() == 0) { log("Waiting APN list is null or empty."); return null; } // If the modem had suggested a retry delay, we should retry the current APN again // (up to MAX_SAME_APN_RETRY times) instead of getting the next APN setting from // our own list. if (mModemSuggestedDelay != NO_SUGGESTED_RETRY_DELAY && mSameApnRetryCount < MAX_SAME_APN_RETRY) { mSameApnRetryCount++; return mWaitingApns.get(mCurrentApnIndex); } mSameApnRetryCount = 0; int index = mCurrentApnIndex; // Loop through the APN list to find out the index of next non-permanent failed APN. while (true) { if (++index == mWaitingApns.size()) index = 0; // Stop if we find the non-failed APN. if (mWaitingApns.get(index).permanentFailed == false) break; // If we've already cycled through all the APNs, that means there is no APN we can try if (index == mCurrentApnIndex) return null; } mCurrentApnIndex = index; return mWaitingApns.get(mCurrentApnIndex); } /** * Get the delay for trying the next waiting APN from the list. * @param failFastEnabled True if fail fast mode enabled. In this case we'll use a shorter * delay. * @return delay in milliseconds */ public long getDelayForNextApn(boolean failFastEnabled) { if (mWaitingApns == null || mWaitingApns.size() == 0) { log("Waiting APN list is null or empty."); return NO_RETRY; } if (mModemSuggestedDelay == NO_RETRY) { log("Modem suggested not retrying."); return NO_RETRY; } if (mModemSuggestedDelay != NO_SUGGESTED_RETRY_DELAY && mSameApnRetryCount < MAX_SAME_APN_RETRY) { // If the modem explicitly suggests a retry delay, we should use it, even in fail fast // mode. log("Modem suggested retry in " + mModemSuggestedDelay + " ms."); return mModemSuggestedDelay; } // In order to determine the delay to try next APN, we need to peek the next available APN. // Case 1 - If we will start the next round of APN trying, // we use the exponential-growth delay. (e.g. 5s, 10s, 30s...etc.) // Case 2 - If we are still within the same round of APN trying, // we use the fixed standard delay between APNs. (e.g. 20s) int index = mCurrentApnIndex; while (true) { if (++index >= mWaitingApns.size()) index = 0; // Stop if we find the non-failed APN. if (mWaitingApns.get(index).permanentFailed == false) break; // If we've already cycled through all the APNs, that means all APNs have // permanently failed if (index == mCurrentApnIndex) { log("All APNs have permanently failed."); return NO_RETRY; } } long delay; if (index <= mCurrentApnIndex) { // Case 1, if the next APN is in the next round. if (!mRetryForever && mRetryCount + 1 > mMaxRetryCount) { log("Reached maximum retry count " + mMaxRetryCount + "."); return NO_RETRY; } delay = getRetryTimer(); ++mRetryCount; } else { // Case 2, if the next APN is still in the same round. delay = mInterApnDelay; } if (failFastEnabled && delay > mFailFastInterApnDelay) { // If we enable fail fast mode, and the delay we got is longer than // fail-fast delay (mFailFastInterApnDelay), use the fail-fast delay. // If the delay we calculated is already shorter than fail-fast delay, // then ignore fail-fast delay. delay = mFailFastInterApnDelay; } return delay; } /** * Mark the APN setting permanently failed. * @param apn APN setting to be marked as permanently failed * */ public void markApnPermanentFailed(ApnSetting apn) { if (apn != null) { apn.permanentFailed = true; } } /** * Reset the retry manager. */ private void reset() { mMaxRetryCount = 0; mRetryCount = 0; mCurrentApnIndex = -1; mSameApnRetryCount = 0; mModemSuggestedDelay = NO_SUGGESTED_RETRY_DELAY; mRetryArray.clear(); } /** * Set waiting APNs for retrying in case needed. * @param waitingApns Waiting APN list */ public void setWaitingApns(ArrayList waitingApns) { if (waitingApns == null) { log("No waiting APNs provided"); return; } mWaitingApns = waitingApns; // Since we replace the entire waiting APN list, we need to re-config this retry manager. configureRetry(mApnType.equals(PhoneConstants.APN_TYPE_DEFAULT)); for (ApnSetting apn : mWaitingApns) { apn.permanentFailed = false; } log("Setting " + mWaitingApns.size() + " waiting APNs."); if (VDBG) { for (int i = 0; i < mWaitingApns.size(); i++) { log(" [" + i + "]:" + mWaitingApns.get(i)); } } } /** * Get the list of waiting APNs. * @return the list of waiting APNs */ public ArrayList getWaitingApns() { return mWaitingApns; } /** * Save the modem suggested delay for retrying the current APN. * This method is called when we get the suggested delay from RIL. * @param delay The delay in milliseconds */ public void setModemSuggestedDelay(long delay) { mModemSuggestedDelay = delay; } /** * Get the delay between APN setting trying. This is the fixed delay used for APN setting trying * within the same round, comparing to the exponential delay used for different rounds. * @param failFastEnabled True if fail fast mode enabled, which a shorter delay will be used * @return The delay in milliseconds */ public long getInterApnDelay(boolean failFastEnabled) { return (failFastEnabled) ? mFailFastInterApnDelay : mInterApnDelay; } public String toString() { return "mApnType=" + mApnType + " mRetryCount=" + mRetryCount + " mMaxRetryCount=" + mMaxRetryCount + " mCurrentApnIndex=" + mCurrentApnIndex + " mSameApnRtryCount=" + mSameApnRetryCount + " mModemSuggestedDelay=" + mModemSuggestedDelay + " mRetryForever=" + mRetryForever + " mConfig={" + mConfig + "}"; } public void dump(FileDescriptor fd, PrintWriter pw, String[] args) { pw.println(" RetryManager"); pw.println("***************************************"); pw.println(" config = " + mConfig); pw.println(" mApnType = " + mApnType); pw.println(" mCurrentApnIndex = " + mCurrentApnIndex); pw.println(" mRetryCount = " + mRetryCount); pw.println(" mMaxRetryCount = " + mMaxRetryCount); pw.println(" mSameApnRetryCount = " + mSameApnRetryCount); pw.println(" mModemSuggestedDelay = " + mModemSuggestedDelay); if (mWaitingApns != null) { pw.println(" APN list: "); for (int i = 0; i < mWaitingApns.size(); i++) { pw.println(" [" + i + "]=" + mWaitingApns.get(i)); } } pw.println("***************************************"); pw.flush(); } private void log(String s) { Rlog.d(LOG_TAG, "[" + mApnType + "] " + s); } }