// Copyright (c) 2012 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 "ipc/ipc_logging.h" #ifdef IPC_MESSAGE_LOG_ENABLED #define IPC_MESSAGE_MACROS_LOG_ENABLED #endif #include "base/bind.h" #include "base/bind_helpers.h" #include "base/command_line.h" #include "base/location.h" #include "base/logging.h" #include "base/message_loop/message_loop.h" #include "base/strings/string_number_conversions.h" #include "base/strings/string_util.h" #include "base/threading/thread.h" #include "base/time/time.h" #include "ipc/ipc_message_utils.h" #include "ipc/ipc_sender.h" #include "ipc/ipc_switches.h" #include "ipc/ipc_sync_message.h" #if defined(OS_POSIX) #include <unistd.h> #endif #ifdef IPC_MESSAGE_LOG_ENABLED using base::Time; namespace IPC { const int kLogSendDelayMs = 100; // We use a pointer to the function table to avoid any linker dependencies on // all the traits used as IPC message parameters. LogFunctionMap* Logging::log_function_map_; Logging::Logging() : enabled_(false), enabled_on_stderr_(false), enabled_color_(false), queue_invoke_later_pending_(false), sender_(NULL), main_thread_(base::MessageLoop::current()), consumer_(NULL) { #if defined(OS_WIN) // getenv triggers an unsafe warning. Simply check how big of a buffer // would be needed to fetch the value to see if the enviornment variable is // set. size_t requiredSize = 0; getenv_s(&requiredSize, NULL, 0, "CHROME_IPC_LOGGING"); bool logging_env_var_set = (requiredSize != 0); if (requiredSize <= 6) { char buffer[6]; getenv_s(&requiredSize, buffer, sizeof(buffer), "CHROME_IPC_LOGGING"); if (requiredSize && !strncmp("color", buffer, 6)) enabled_color_ = true; } #else // !defined(OS_WIN) const char* ipc_logging = getenv("CHROME_IPC_LOGGING"); bool logging_env_var_set = (ipc_logging != NULL); if (ipc_logging && !strcmp(ipc_logging, "color")) enabled_color_ = true; #endif //defined(OS_WIN) if (logging_env_var_set) { enabled_ = true; enabled_on_stderr_ = true; } } Logging::~Logging() { } Logging* Logging::GetInstance() { return Singleton<Logging>::get(); } void Logging::SetConsumer(Consumer* consumer) { consumer_ = consumer; } void Logging::Enable() { enabled_ = true; } void Logging::Disable() { enabled_ = false; } void Logging::OnSendLogs() { queue_invoke_later_pending_ = false; if (!sender_) return; Message* msg = new Message( MSG_ROUTING_CONTROL, IPC_LOGGING_ID, Message::PRIORITY_NORMAL); WriteParam(msg, queued_logs_); queued_logs_.clear(); sender_->Send(msg); } void Logging::SetIPCSender(IPC::Sender* sender) { sender_ = sender; } void Logging::OnReceivedLoggingMessage(const Message& message) { std::vector<LogData> data; PickleIterator iter(message); if (!ReadParam(&message, &iter, &data)) return; for (size_t i = 0; i < data.size(); ++i) { Log(data[i]); } } void Logging::OnSendMessage(Message* message, const std::string& channel_id) { if (!Enabled()) return; if (message->is_reply()) { LogData* data = message->sync_log_data(); if (!data) return; // This is actually the delayed reply to a sync message. Create a string // of the output parameters, add it to the LogData that was earlier stashed // with the reply, and log the result. GenerateLogData("", *message, data, true); data->channel = channel_id; Log(*data); delete data; message->set_sync_log_data(NULL); } else { // If the time has already been set (i.e. by ChannelProxy), keep that time // instead as it's more accurate. if (!message->sent_time()) message->set_sent_time(Time::Now().ToInternalValue()); } } void Logging::OnPreDispatchMessage(const Message& message) { message.set_received_time(Time::Now().ToInternalValue()); } void Logging::OnPostDispatchMessage(const Message& message, const std::string& channel_id) { if (!Enabled() || !message.sent_time() || !message.received_time() || message.dont_log()) return; LogData data; GenerateLogData(channel_id, message, &data, true); if (base::MessageLoop::current() == main_thread_) { Log(data); } else { main_thread_->PostTask( FROM_HERE, base::Bind(&Logging::Log, base::Unretained(this), data)); } } void Logging::GetMessageText(uint32 type, std::string* name, const Message* message, std::string* params) { if (!log_function_map_) return; LogFunctionMap::iterator it = log_function_map_->find(type); if (it == log_function_map_->end()) { if (name) { *name = "[UNKNOWN MSG "; *name += base::IntToString(type); *name += " ]"; } return; } (*it->second)(name, message, params); } const char* Logging::ANSIEscape(ANSIColor color) { if (!enabled_color_) return ""; switch (color) { case ANSI_COLOR_RESET: return "\033[m"; case ANSI_COLOR_BLACK: return "\033[0;30m"; case ANSI_COLOR_RED: return "\033[0;31m"; case ANSI_COLOR_GREEN: return "\033[0;32m"; case ANSI_COLOR_YELLOW: return "\033[0;33m"; case ANSI_COLOR_BLUE: return "\033[0;34m"; case ANSI_COLOR_MAGENTA: return "\033[0;35m"; case ANSI_COLOR_CYAN: return "\033[0;36m"; case ANSI_COLOR_WHITE: return "\033[0;37m"; } return ""; } Logging::ANSIColor Logging::DelayColor(double delay) { if (delay < 0.1) return ANSI_COLOR_GREEN; if (delay < 0.25) return ANSI_COLOR_BLACK; if (delay < 0.5) return ANSI_COLOR_YELLOW; return ANSI_COLOR_RED; } void Logging::Log(const LogData& data) { if (consumer_) { // We're in the browser process. consumer_->Log(data); } else { // We're in the renderer or plugin processes. if (sender_) { queued_logs_.push_back(data); if (!queue_invoke_later_pending_) { queue_invoke_later_pending_ = true; base::MessageLoop::current()->PostDelayedTask( FROM_HERE, base::Bind(&Logging::OnSendLogs, base::Unretained(this)), base::TimeDelta::FromMilliseconds(kLogSendDelayMs)); } } } if (enabled_on_stderr_) { std::string message_name; if (data.message_name.empty()) { message_name = base::StringPrintf("[unknown type %d]", data.type); } else { message_name = data.message_name; } double receive_delay = (Time::FromInternalValue(data.receive) - Time::FromInternalValue(data.sent)).InSecondsF(); double dispatch_delay = (Time::FromInternalValue(data.dispatch) - Time::FromInternalValue(data.sent)).InSecondsF(); fprintf(stderr, "ipc %s %d %s %s%s %s%s\n %18.5f %s%18.5f %s%18.5f%s\n", data.channel.c_str(), data.routing_id, data.flags.c_str(), ANSIEscape(sender_ ? ANSI_COLOR_BLUE : ANSI_COLOR_CYAN), message_name.c_str(), ANSIEscape(ANSI_COLOR_RESET), data.params.c_str(), Time::FromInternalValue(data.sent).ToDoubleT(), ANSIEscape(DelayColor(receive_delay)), Time::FromInternalValue(data.receive).ToDoubleT(), ANSIEscape(DelayColor(dispatch_delay)), Time::FromInternalValue(data.dispatch).ToDoubleT(), ANSIEscape(ANSI_COLOR_RESET) ); } } void GenerateLogData(const std::string& channel, const Message& message, LogData* data, bool get_params) { if (message.is_reply()) { // "data" should already be filled in. std::string params; Logging::GetMessageText(data->type, NULL, &message, ¶ms); if (!data->params.empty() && !params.empty()) data->params += ", "; data->flags += " DR"; data->params += params; } else { std::string flags; if (message.is_sync()) flags = "S"; if (message.is_reply()) flags += "R"; if (message.is_reply_error()) flags += "E"; std::string params, message_name; Logging::GetMessageText(message.type(), &message_name, &message, get_params ? ¶ms : NULL); data->channel = channel; data->routing_id = message.routing_id(); data->type = message.type(); data->flags = flags; data->sent = message.sent_time(); data->receive = message.received_time(); data->dispatch = Time::Now().ToInternalValue(); data->params = params; data->message_name = message_name; } } } #endif // IPC_MESSAGE_LOG_ENABLED