components/metrics/persisted_logs.cc - chromium/src - Git at Google

 // Copyright 2014 The Chromium Authors. All rights reserved.
 // Use of this source code is governed by a BSD-style license that can be
 // found in the LICENSE file.

 #include "components/metrics/persisted_logs.h"

 #include <memory>
 #include <string>
 #include <utility>

 #include "base/base64.h"
 #include "base/md5.h"
 #include "base/metrics/histogram_macros.h"
 #include "base/sha1.h"
 #include "base/strings/string_number_conversions.h"
 #include "base/timer/elapsed_timer.h"
 #include "components/metrics/persisted_logs_metrics.h"
 #include "components/prefs/pref_service.h"
 #include "components/prefs/scoped_user_pref_update.h"
 #include "third_party/zlib/google/compression_utils.h"

 namespace metrics {

 namespace {

 const char kLogHashKey[] = "hash";
 const char kLogTimestampKey[] = "timestamp";
 const char kLogDataKey[] = "data";

 std::string EncodeToBase64(const std::string& to_convert) {
   // CHECK to diagnose crbug.com/695433
   CHECK(to_convert.data());
   std::string base64_result;
   base::Base64Encode(to_convert, &base64_result);
   return base64_result;
 }

 std::string DecodeFromBase64(const std::string& to_convert) {
   std::string result;
   base::Base64Decode(to_convert, &result);
   return result;
 }

 }  // namespace

 void PersistedLogs::LogInfo::Init(PersistedLogsMetrics* metrics,
                                   const std::string& log_data,
                                   const std::string& log_timestamp) {
   DCHECK(!log_data.empty());

   if (!compression::GzipCompress(log_data, &compressed_log_data)) {
     NOTREACHED();
     return;
   }

   metrics->RecordCompressionRatio(compressed_log_data.size(), log_data.size());

   hash = base::SHA1HashString(log_data);
   timestamp = log_timestamp;
 }

 PersistedLogs::PersistedLogs(std::unique_ptr<PersistedLogsMetrics> metrics,
                              PrefService* local_state,
                              const char* pref_name,
                              size_t min_log_count,
                              size_t min_log_bytes,
                              size_t max_log_size)
     : metrics_(std::move(metrics)),
       local_state_(local_state),
       pref_name_(pref_name),
       min_log_count_(min_log_count),
       min_log_bytes_(min_log_bytes),
       max_log_size_(max_log_size != 0 ? max_log_size : static_cast<size_t>(-1)),
       staged_log_index_(-1) {
   DCHECK(local_state_);
   // One of the limit arguments must be non-zero.
   DCHECK(min_log_count_ > 0 || min_log_bytes_ > 0);
 }

 PersistedLogs::~PersistedLogs() {}

 bool PersistedLogs::has_unsent_logs() const {
   return !!size();
 }

 // True if a log has been staged.
 bool PersistedLogs::has_staged_log() const {
   return staged_log_index_ != -1;
 }

 // Returns the element in the front of the list.
 const std::string& PersistedLogs::staged_log() const {
   DCHECK(has_staged_log());
   return list_[staged_log_index_].compressed_log_data;
 }

 // Returns the element in the front of the list.
 const std::string& PersistedLogs::staged_log_hash() const {
   DCHECK(has_staged_log());
   return list_[staged_log_index_].hash;
 }

 // Returns the timestamp of the element in the front of the list.
 const std::string& PersistedLogs::staged_log_timestamp() const {
   DCHECK(has_staged_log());
   return list_[staged_log_index_].timestamp;
 }

 void PersistedLogs::StageNextLog() {
   // CHECK, rather than DCHECK, because swap()ing with an empty list causes
   // hard-to-identify crashes much later.
   CHECK(!list_.empty());
   DCHECK(!has_staged_log());
   staged_log_index_ = list_.size() - 1;
   DCHECK(has_staged_log());
 }

 void PersistedLogs::DiscardStagedLog() {
   // CHECK, rather than DCHECK, to diagnose cause of crashes from the field,
   // for crbug.com/695433.
   CHECK(has_staged_log());
   DCHECK_LT(static_cast<size_t>(staged_log_index_), list_.size());
   list_.erase(list_.begin() + staged_log_index_);
   staged_log_index_ = -1;
 }

 void PersistedLogs::PersistUnsentLogs() const {
   ListPrefUpdate update(local_state_, pref_name_);
   WriteLogsToPrefList(update.Get());
 }

 void PersistedLogs::LoadPersistedUnsentLogs() {
   ReadLogsFromPrefList(*local_state_->GetList(pref_name_));
 }

 void PersistedLogs::StoreLog(const std::string& log_data) {
   list_.push_back(LogInfo());
   list_.back().Init(metrics_.get(), log_data,
                     base::Int64ToString(base::Time::Now().ToTimeT()));
 }

 void PersistedLogs::Purge() {
   if (has_staged_log()) {
     DiscardStagedLog();
   }
   list_.clear();
   local_state_->ClearPref(pref_name_);
 }

 void PersistedLogs::ReadLogsFromPrefList(const base::ListValue& list_value) {
   if (list_value.empty()) {
     metrics_->RecordLogReadStatus(PersistedLogsMetrics::LIST_EMPTY);
     return;
   }

   const size_t log_count = list_value.GetSize();

   DCHECK(list_.empty());
   list_.resize(log_count);

   for (size_t i = 0; i < log_count; ++i) {
     const base::DictionaryValue* dict;
     if (!list_value.GetDictionary(i, &dict) ||
         !dict->GetString(kLogDataKey, &list_[i].compressed_log_data) ||
         !dict->GetString(kLogHashKey, &list_[i].hash)) {
       list_.clear();
       metrics_->RecordLogReadStatus(
           PersistedLogsMetrics::LOG_STRING_CORRUPTION);
       return;
     }

     list_[i].compressed_log_data =
         DecodeFromBase64(list_[i].compressed_log_data);
     list_[i].hash = DecodeFromBase64(list_[i].hash);
     // Ignoring the success of this step as timestamp might not be there for
     // older logs.
     // NOTE: Should be added to the check with other fields once migration is
     // over.
     dict->GetString(kLogTimestampKey, &list_[i].timestamp);
   }

   metrics_->RecordLogReadStatus(PersistedLogsMetrics::RECALL_SUCCESS);
 }

 void PersistedLogs::WriteLogsToPrefList(base::ListValue* list_value) const {
   list_value->Clear();

   // Keep the most recent logs which are smaller than |max_log_size_|.
   // We keep at least |min_log_bytes_| and |min_log_count_| of logs before
   // discarding older logs.
   size_t start = list_.size();
   size_t saved_log_count = 0;
   size_t bytes_used = 0;
   for (; start > 0; --start) {
     size_t log_size = list_[start - 1].compressed_log_data.length();
     if (bytes_used >= min_log_bytes_ &&
         saved_log_count >= min_log_count_) {
       break;
     }
     // Oversized logs won't be persisted, so don't count them.
     if (log_size > max_log_size_)
       continue;
     bytes_used += log_size;
     ++saved_log_count;
   }
   int dropped_logs_num = start - 1;

   for (size_t i = start; i < list_.size(); ++i) {
     size_t log_size = list_[i].compressed_log_data.length();
     if (log_size > max_log_size_) {
       metrics_->RecordDroppedLogSize(log_size);
       dropped_logs_num++;
       continue;
     }
     std::unique_ptr<base::DictionaryValue> dict_value(
         new base::DictionaryValue);
     dict_value->SetString(kLogHashKey, EncodeToBase64(list_[i].hash));
     dict_value->SetString(kLogDataKey,
                           EncodeToBase64(list_[i].compressed_log_data));
     dict_value->SetString(kLogTimestampKey, list_[i].timestamp);
     list_value->Append(std::move(dict_value));
   }
   if (dropped_logs_num > 0)
     metrics_->RecordDroppedLogsNum(dropped_logs_num);
 }

 }  // namespace metrics
	// Copyright 2014 The Chromium Authors. All rights reserved.
	// Use of this source code is governed by a BSD-style license that can be
	// found in the LICENSE file.

	#include "components/metrics/persisted_logs.h"

	#include <memory>
	#include <string>
	#include <utility>

	#include "base/base64.h"
	#include "base/md5.h"
	#include "base/metrics/histogram_macros.h"
	#include "base/sha1.h"
	#include "base/strings/string_number_conversions.h"
	#include "base/timer/elapsed_timer.h"
	#include "components/metrics/persisted_logs_metrics.h"
	#include "components/prefs/pref_service.h"
	#include "components/prefs/scoped_user_pref_update.h"
	#include "third_party/zlib/google/compression_utils.h"

	namespace metrics {

	namespace {

	const char kLogHashKey[] = "hash";
	const char kLogTimestampKey[] = "timestamp";
	const char kLogDataKey[] = "data";

	std::string EncodeToBase64(const std::string& to_convert) {
	// CHECK to diagnose crbug.com/695433
	CHECK(to_convert.data());
	std::string base64_result;
	base::Base64Encode(to_convert, &base64_result);
	return base64_result;
	}

	std::string DecodeFromBase64(const std::string& to_convert) {
	std::string result;
	base::Base64Decode(to_convert, &result);
	return result;
	}

	} // namespace

	void PersistedLogs::LogInfo::Init(PersistedLogsMetrics* metrics,
	const std::string& log_data,
	const std::string& log_timestamp) {
	DCHECK(!log_data.empty());

	if (!compression::GzipCompress(log_data, &compressed_log_data)) {
	NOTREACHED();
	return;
	}

	metrics->RecordCompressionRatio(compressed_log_data.size(), log_data.size());

	hash = base::SHA1HashString(log_data);
	timestamp = log_timestamp;
	}

	PersistedLogs::PersistedLogs(std::unique_ptr<PersistedLogsMetrics> metrics,
	PrefService* local_state,
	const char* pref_name,
	size_t min_log_count,
	size_t min_log_bytes,
	size_t max_log_size)
	: metrics_(std::move(metrics)),
	local_state_(local_state),
	pref_name_(pref_name),
	min_log_count_(min_log_count),
	min_log_bytes_(min_log_bytes),
	max_log_size_(max_log_size != 0 ? max_log_size : static_cast<size_t>(-1)),
	staged_log_index_(-1) {
	DCHECK(local_state_);
	// One of the limit arguments must be non-zero.
	DCHECK(min_log_count_ > 0 \|\| min_log_bytes_ > 0);
	}

	PersistedLogs::~PersistedLogs() {}

	bool PersistedLogs::has_unsent_logs() const {
	return !!size();
	}

	// True if a log has been staged.
	bool PersistedLogs::has_staged_log() const {
	return staged_log_index_ != -1;
	}

	// Returns the element in the front of the list.
	const std::string& PersistedLogs::staged_log() const {
	DCHECK(has_staged_log());
	return list_[staged_log_index_].compressed_log_data;
	}

	// Returns the element in the front of the list.
	const std::string& PersistedLogs::staged_log_hash() const {
	DCHECK(has_staged_log());
	return list_[staged_log_index_].hash;
	}

	// Returns the timestamp of the element in the front of the list.
	const std::string& PersistedLogs::staged_log_timestamp() const {
	DCHECK(has_staged_log());
	return list_[staged_log_index_].timestamp;
	}

	void PersistedLogs::StageNextLog() {
	// CHECK, rather than DCHECK, because swap()ing with an empty list causes
	// hard-to-identify crashes much later.
	CHECK(!list_.empty());
	DCHECK(!has_staged_log());
	staged_log_index_ = list_.size() - 1;
	DCHECK(has_staged_log());
	}

	void PersistedLogs::DiscardStagedLog() {
	// CHECK, rather than DCHECK, to diagnose cause of crashes from the field,
	// for crbug.com/695433.
	CHECK(has_staged_log());
	DCHECK_LT(static_cast<size_t>(staged_log_index_), list_.size());
	list_.erase(list_.begin() + staged_log_index_);
	staged_log_index_ = -1;
	}

	void PersistedLogs::PersistUnsentLogs() const {
	ListPrefUpdate update(local_state_, pref_name_);
	WriteLogsToPrefList(update.Get());
	}

	void PersistedLogs::LoadPersistedUnsentLogs() {
	ReadLogsFromPrefList(*local_state_->GetList(pref_name_));
	}

	void PersistedLogs::StoreLog(const std::string& log_data) {
	list_.push_back(LogInfo());
	list_.back().Init(metrics_.get(), log_data,
	base::Int64ToString(base::Time::Now().ToTimeT()));
	}

	void PersistedLogs::Purge() {
	if (has_staged_log()) {
	DiscardStagedLog();
	}
	list_.clear();
	local_state_->ClearPref(pref_name_);
	}

	void PersistedLogs::ReadLogsFromPrefList(const base::ListValue& list_value) {
	if (list_value.empty()) {
	metrics_->RecordLogReadStatus(PersistedLogsMetrics::LIST_EMPTY);
	return;
	}

	const size_t log_count = list_value.GetSize();

	DCHECK(list_.empty());
	list_.resize(log_count);

	for (size_t i = 0; i < log_count; ++i) {
	const base::DictionaryValue* dict;
	if (!list_value.GetDictionary(i, &dict) \|\|
	!dict->GetString(kLogDataKey, &list_[i].compressed_log_data) \|\|
	!dict->GetString(kLogHashKey, &list_[i].hash)) {
	list_.clear();
	metrics_->RecordLogReadStatus(
	PersistedLogsMetrics::LOG_STRING_CORRUPTION);
	return;
	}

	list_[i].compressed_log_data =
	DecodeFromBase64(list_[i].compressed_log_data);
	list_[i].hash = DecodeFromBase64(list_[i].hash);
	// Ignoring the success of this step as timestamp might not be there for
	// older logs.
	// NOTE: Should be added to the check with other fields once migration is
	// over.
	dict->GetString(kLogTimestampKey, &list_[i].timestamp);
	}

	metrics_->RecordLogReadStatus(PersistedLogsMetrics::RECALL_SUCCESS);
	}

	void PersistedLogs::WriteLogsToPrefList(base::ListValue* list_value) const {
	list_value->Clear();

	// Keep the most recent logs which are smaller than \|max_log_size_\|.
	// We keep at least \|min_log_bytes_\| and \|min_log_count_\| of logs before
	// discarding older logs.
	size_t start = list_.size();
	size_t saved_log_count = 0;
	size_t bytes_used = 0;
	for (; start > 0; --start) {
	size_t log_size = list_[start - 1].compressed_log_data.length();
	if (bytes_used >= min_log_bytes_ &&
	saved_log_count >= min_log_count_) {
	break;
	}
	// Oversized logs won't be persisted, so don't count them.
	if (log_size > max_log_size_)
	continue;
	bytes_used += log_size;
	++saved_log_count;
	}
	int dropped_logs_num = start - 1;

	for (size_t i = start; i < list_.size(); ++i) {
	size_t log_size = list_[i].compressed_log_data.length();
	if (log_size > max_log_size_) {
	metrics_->RecordDroppedLogSize(log_size);
	dropped_logs_num++;
	continue;
	}
	std::unique_ptr<base::DictionaryValue> dict_value(
	new base::DictionaryValue);
	dict_value->SetString(kLogHashKey, EncodeToBase64(list_[i].hash));
	dict_value->SetString(kLogDataKey,
	EncodeToBase64(list_[i].compressed_log_data));
	dict_value->SetString(kLogTimestampKey, list_[i].timestamp);
	list_value->Append(std::move(dict_value));
	}
	if (dropped_logs_num > 0)
	metrics_->RecordDroppedLogsNum(dropped_logs_num);
	}

	} // namespace metrics