chrome/browser/memory_details.cc - platform/external/chromium - Git at Google

 // Copyright (c) 2009 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 "chrome/browser/memory_details.h"

 #include "base/file_version_info.h"
 #include "base/histogram.h"
 #include "base/process_util.h"
 #include "base/string_util.h"
 #include "base/utf_string_conversions.h"
 #include "chrome/browser/browser_child_process_host.h"
 #include "chrome/browser/chrome_thread.h"
 #include "chrome/browser/renderer_host/backing_store_manager.h"
 #include "chrome/browser/renderer_host/render_process_host.h"
 #include "chrome/browser/renderer_host/render_view_host.h"
 #include "chrome/browser/tab_contents/navigation_entry.h"
 #include "chrome/browser/tab_contents/tab_contents.h"
 #include "chrome/common/url_constants.h"
 #include "grit/chromium_strings.h"

 #if defined(OS_LINUX)
 #include "chrome/browser/zygote_host_linux.h"
 #include "chrome/browser/renderer_host/render_sandbox_host_linux.h"
 #endif

 // About threading:
 //
 // This operation will hit no fewer than 3 threads.
 //
 // The ChildProcessInfo::Iterator can only be accessed from the IO thread.
 //
 // The RenderProcessHostIterator can only be accessed from the UI thread.
 //
 // This operation can take 30-100ms to complete.  We never want to have
 // one task run for that long on the UI or IO threads.  So, we run the
 // expensive parts of this operation over on the file thread.
 //

 void MemoryDetails::StartFetch() {
   DCHECK(!ChromeThread::CurrentlyOn(ChromeThread::IO));
   DCHECK(!ChromeThread::CurrentlyOn(ChromeThread::FILE));

   // In order to process this request, we need to use the plugin information.
   // However, plugin process information is only available from the IO thread.
   ChromeThread::PostTask(
       ChromeThread::IO, FROM_HERE,
       NewRunnableMethod(this, &MemoryDetails::CollectChildInfoOnIOThread));
 }

 void MemoryDetails::CollectChildInfoOnIOThread() {
   DCHECK(ChromeThread::CurrentlyOn(ChromeThread::IO));

   std::vector<ProcessMemoryInformation> child_info;

   // Collect the list of child processes.
   for (BrowserChildProcessHost::Iterator iter; !iter.Done(); ++iter) {
     ProcessMemoryInformation info;
     info.pid = base::GetProcId(iter->handle());
     if (!info.pid)
       continue;

     info.type = iter->type();
     info.titles.push_back(iter->name());
     child_info.push_back(info);
   }

   // Now go do expensive memory lookups from the file thread.
   ChromeThread::PostTask(
       ChromeThread::FILE, FROM_HERE,
       NewRunnableMethod(this, &MemoryDetails::CollectProcessData, child_info));
 }

 void MemoryDetails::CollectChildInfoOnUIThread() {
   DCHECK(ChromeThread::CurrentlyOn(ChromeThread::UI));

 #if defined(OS_LINUX)
   const pid_t zygote_pid = Singleton<ZygoteHost>()->pid();
   const pid_t sandbox_helper_pid = Singleton<RenderSandboxHostLinux>()->pid();
 #endif

   ProcessData* const chrome_browser = ChromeBrowser();
   // Get more information about the process.
   for (size_t index = 0; index < chrome_browser->processes.size();
       index++) {
     // Check if it's a renderer, if so get the list of page titles in it and
     // check if it's a diagnostics-related process.  We skip all diagnostics
     // pages (e.g. "about:xxx" URLs).  Iterate the RenderProcessHosts to find
     // the tab contents.
     ProcessMemoryInformation& process =
         chrome_browser->processes[index];

     for (RenderProcessHost::iterator renderer_iter(
          RenderProcessHost::AllHostsIterator()); !renderer_iter.IsAtEnd();
          renderer_iter.Advance()) {
       DCHECK(renderer_iter.GetCurrentValue());
       // Ignore processes that don't have a connection, such as crashed tabs or
       // phantom tabs.
       if (!renderer_iter.GetCurrentValue()->HasConnection() || process.pid !=
               base::GetProcId(renderer_iter.GetCurrentValue()->GetHandle())) {
         continue;
       }
       process.type = ChildProcessInfo::RENDER_PROCESS;
       // The RenderProcessHost may host multiple TabContents.  Any
       // of them which contain diagnostics information make the whole
       // process be considered a diagnostics process.
       //
       // NOTE: This is a bit dangerous.  We know that for now, listeners
       //       are always RenderWidgetHosts.  But in theory, they don't
       //       have to be.
       RenderProcessHost::listeners_iterator iter(
           renderer_iter.GetCurrentValue()->ListenersIterator());
       for (; !iter.IsAtEnd(); iter.Advance()) {
         const RenderWidgetHost* widget =
             static_cast<const RenderWidgetHost*>(iter.GetCurrentValue());
         DCHECK(widget);
         if (!widget || !widget->IsRenderView())
           continue;

         const RenderViewHost* host = static_cast<const RenderViewHost*>(widget);
         TabContents* contents = NULL;
         if (host->delegate())
           contents = host->delegate()->GetAsTabContents();
         if (!contents)
           continue;
         std::wstring title = UTF16ToWideHack(contents->GetTitle());
         if (!title.length())
           title = L"Untitled";
         process.titles.push_back(title);

         // We need to check the pending entry as well as the virtual_url to
         // see if it's an about:memory URL (we don't want to count these in the
         // total memory usage of the browser).
         //
         // When we reach here, about:memory will be the pending entry since we
         // haven't responded with any data such that it would be committed. If
         // you have another about:memory tab open (which would be committed),
         // we don't want to count it either, so we also check the last committed
         // entry.
         //
         // Either the pending or last committed entries can be NULL.
         const NavigationEntry* pending_entry =
             contents->controller().pending_entry();
         const NavigationEntry* last_committed_entry =
             contents->controller().GetLastCommittedEntry();
         if ((last_committed_entry &&
              LowerCaseEqualsASCII(last_committed_entry->virtual_url().spec(),
                                   chrome::kAboutMemoryURL)) ||
             (pending_entry &&
              LowerCaseEqualsASCII(pending_entry->virtual_url().spec(),
                                   chrome::kAboutMemoryURL)))
           process.is_diagnostics = true;
       }
     }

 #if defined(OS_LINUX)
     if (process.pid == zygote_pid) {
       process.type = ChildProcessInfo::ZYGOTE_PROCESS;
     } else if (process.pid == sandbox_helper_pid) {
       process.type = ChildProcessInfo::SANDBOX_HELPER_PROCESS;
     }
 #endif
   }

   // Get rid of other Chrome processes that are from a different profile.
   for (size_t index = 0; index < chrome_browser->processes.size();
       index++) {
     if (chrome_browser->processes[index].type ==
         ChildProcessInfo::UNKNOWN_PROCESS) {
       chrome_browser->processes.erase(
           chrome_browser->processes.begin() + index);
       index--;
     }
   }

   UpdateHistograms();

   OnDetailsAvailable();
 }

 void MemoryDetails::UpdateHistograms() {
   // Reports a set of memory metrics to UMA.
   // Memory is measured in KB.

   const ProcessData& browser = *ChromeBrowser();
   size_t aggregate_memory = 0;
   int plugin_count = 0;
   int worker_count = 0;
   for (size_t index = 0; index < browser.processes.size(); index++) {
     int sample = static_cast<int>(browser.processes[index].working_set.priv);
     aggregate_memory += sample;
     switch (browser.processes[index].type) {
       case ChildProcessInfo::BROWSER_PROCESS:
         UMA_HISTOGRAM_MEMORY_KB("Memory.Browser", sample);
         break;
       case ChildProcessInfo::RENDER_PROCESS:
         UMA_HISTOGRAM_MEMORY_KB("Memory.Renderer", sample);
         break;
       case ChildProcessInfo::PLUGIN_PROCESS:
         UMA_HISTOGRAM_MEMORY_KB("Memory.Plugin", sample);
         plugin_count++;
         break;
       case ChildProcessInfo::WORKER_PROCESS:
         UMA_HISTOGRAM_MEMORY_KB("Memory.Worker", sample);
         worker_count++;
         break;
       case ChildProcessInfo::UTILITY_PROCESS:
         UMA_HISTOGRAM_MEMORY_KB("Memory.Utility", sample);
         break;
       case ChildProcessInfo::ZYGOTE_PROCESS:
         UMA_HISTOGRAM_MEMORY_KB("Memory.Zygote", sample);
         break;
       case ChildProcessInfo::SANDBOX_HELPER_PROCESS:
         UMA_HISTOGRAM_MEMORY_KB("Memory.SandboxHelper", sample);
         break;
       case ChildProcessInfo::NACL_LOADER_PROCESS:
         UMA_HISTOGRAM_MEMORY_KB("Memory.NativeClient", sample);
         break;
       case ChildProcessInfo::NACL_BROKER_PROCESS:
         UMA_HISTOGRAM_MEMORY_KB("Memory.NativeClientBroker", sample);
         break;
       case ChildProcessInfo::GPU_PROCESS:
         UMA_HISTOGRAM_MEMORY_KB("Memory.Gpu", sample);
         break;
       default:
         NOTREACHED();
     }
   }
   UMA_HISTOGRAM_MEMORY_KB("Memory.BackingStore",
                           BackingStoreManager::MemorySize() / 1024);

   UMA_HISTOGRAM_COUNTS_100("Memory.ProcessCount",
       static_cast<int>(browser.processes.size()));
   UMA_HISTOGRAM_COUNTS_100("Memory.PluginProcessCount", plugin_count);
   UMA_HISTOGRAM_COUNTS_100("Memory.WorkerProcessCount", worker_count);
   // TODO(viettrungluu): Do we want separate counts for the other
   // (platform-specific) process types?

   int total_sample = static_cast<int>(aggregate_memory / 1000);
   UMA_HISTOGRAM_MEMORY_MB("Memory.Total", total_sample);
 }
	// Copyright (c) 2009 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 "chrome/browser/memory_details.h"

	#include "base/file_version_info.h"
	#include "base/histogram.h"
	#include "base/process_util.h"
	#include "base/string_util.h"
	#include "base/utf_string_conversions.h"
	#include "chrome/browser/browser_child_process_host.h"
	#include "chrome/browser/chrome_thread.h"
	#include "chrome/browser/renderer_host/backing_store_manager.h"
	#include "chrome/browser/renderer_host/render_process_host.h"
	#include "chrome/browser/renderer_host/render_view_host.h"
	#include "chrome/browser/tab_contents/navigation_entry.h"
	#include "chrome/browser/tab_contents/tab_contents.h"
	#include "chrome/common/url_constants.h"
	#include "grit/chromium_strings.h"

	#if defined(OS_LINUX)
	#include "chrome/browser/zygote_host_linux.h"
	#include "chrome/browser/renderer_host/render_sandbox_host_linux.h"
	#endif

	// About threading:
	//
	// This operation will hit no fewer than 3 threads.
	//
	// The ChildProcessInfo::Iterator can only be accessed from the IO thread.
	//
	// The RenderProcessHostIterator can only be accessed from the UI thread.
	//
	// This operation can take 30-100ms to complete. We never want to have
	// one task run for that long on the UI or IO threads. So, we run the
	// expensive parts of this operation over on the file thread.
	//

	void MemoryDetails::StartFetch() {
	DCHECK(!ChromeThread::CurrentlyOn(ChromeThread::IO));
	DCHECK(!ChromeThread::CurrentlyOn(ChromeThread::FILE));

	// In order to process this request, we need to use the plugin information.
	// However, plugin process information is only available from the IO thread.
	ChromeThread::PostTask(
	ChromeThread::IO, FROM_HERE,
	NewRunnableMethod(this, &MemoryDetails::CollectChildInfoOnIOThread));
	}

	void MemoryDetails::CollectChildInfoOnIOThread() {
	DCHECK(ChromeThread::CurrentlyOn(ChromeThread::IO));

	std::vector<ProcessMemoryInformation> child_info;

	// Collect the list of child processes.
	for (BrowserChildProcessHost::Iterator iter; !iter.Done(); ++iter) {
	ProcessMemoryInformation info;
	info.pid = base::GetProcId(iter->handle());
	if (!info.pid)
	continue;

	info.type = iter->type();
	info.titles.push_back(iter->name());
	child_info.push_back(info);
	}

	// Now go do expensive memory lookups from the file thread.
	ChromeThread::PostTask(
	ChromeThread::FILE, FROM_HERE,
	NewRunnableMethod(this, &MemoryDetails::CollectProcessData, child_info));
	}

	void MemoryDetails::CollectChildInfoOnUIThread() {
	DCHECK(ChromeThread::CurrentlyOn(ChromeThread::UI));

	#if defined(OS_LINUX)
	const pid_t zygote_pid = Singleton<ZygoteHost>()->pid();
	const pid_t sandbox_helper_pid = Singleton<RenderSandboxHostLinux>()->pid();
	#endif

	ProcessData* const chrome_browser = ChromeBrowser();
	// Get more information about the process.
	for (size_t index = 0; index < chrome_browser->processes.size();
	index++) {
	// Check if it's a renderer, if so get the list of page titles in it and
	// check if it's a diagnostics-related process. We skip all diagnostics
	// pages (e.g. "about:xxx" URLs). Iterate the RenderProcessHosts to find
	// the tab contents.
	ProcessMemoryInformation& process =
	chrome_browser->processes[index];

	for (RenderProcessHost::iterator renderer_iter(
	RenderProcessHost::AllHostsIterator()); !renderer_iter.IsAtEnd();
	renderer_iter.Advance()) {
	DCHECK(renderer_iter.GetCurrentValue());
	// Ignore processes that don't have a connection, such as crashed tabs or
	// phantom tabs.
	if (!renderer_iter.GetCurrentValue()->HasConnection() \|\| process.pid !=
	base::GetProcId(renderer_iter.GetCurrentValue()->GetHandle())) {
	continue;
	}
	process.type = ChildProcessInfo::RENDER_PROCESS;
	// The RenderProcessHost may host multiple TabContents. Any
	// of them which contain diagnostics information make the whole
	// process be considered a diagnostics process.
	//
	// NOTE: This is a bit dangerous. We know that for now, listeners
	// are always RenderWidgetHosts. But in theory, they don't
	// have to be.
	RenderProcessHost::listeners_iterator iter(
	renderer_iter.GetCurrentValue()->ListenersIterator());
	for (; !iter.IsAtEnd(); iter.Advance()) {
	const RenderWidgetHost* widget =
	static_cast<const RenderWidgetHost*>(iter.GetCurrentValue());
	DCHECK(widget);
	if (!widget \|\| !widget->IsRenderView())
	continue;

	const RenderViewHost* host = static_cast<const RenderViewHost*>(widget);
	TabContents* contents = NULL;
	if (host->delegate())
	contents = host->delegate()->GetAsTabContents();
	if (!contents)
	continue;
	std::wstring title = UTF16ToWideHack(contents->GetTitle());
	if (!title.length())
	title = L"Untitled";
	process.titles.push_back(title);

	// We need to check the pending entry as well as the virtual_url to
	// see if it's an about:memory URL (we don't want to count these in the
	// total memory usage of the browser).
	//
	// When we reach here, about:memory will be the pending entry since we
	// haven't responded with any data such that it would be committed. If
	// you have another about:memory tab open (which would be committed),
	// we don't want to count it either, so we also check the last committed
	// entry.
	//
	// Either the pending or last committed entries can be NULL.
	const NavigationEntry* pending_entry =
	contents->controller().pending_entry();
	const NavigationEntry* last_committed_entry =
	contents->controller().GetLastCommittedEntry();
	if ((last_committed_entry &&
	LowerCaseEqualsASCII(last_committed_entry->virtual_url().spec(),
	chrome::kAboutMemoryURL)) \|\|
	(pending_entry &&
	LowerCaseEqualsASCII(pending_entry->virtual_url().spec(),
	chrome::kAboutMemoryURL)))
	process.is_diagnostics = true;
	}
	}

	#if defined(OS_LINUX)
	if (process.pid == zygote_pid) {
	process.type = ChildProcessInfo::ZYGOTE_PROCESS;
	} else if (process.pid == sandbox_helper_pid) {
	process.type = ChildProcessInfo::SANDBOX_HELPER_PROCESS;
	}
	#endif
	}

	// Get rid of other Chrome processes that are from a different profile.
	for (size_t index = 0; index < chrome_browser->processes.size();
	index++) {
	if (chrome_browser->processes[index].type ==
	ChildProcessInfo::UNKNOWN_PROCESS) {
	chrome_browser->processes.erase(
	chrome_browser->processes.begin() + index);
	index--;
	}
	}

	UpdateHistograms();

	OnDetailsAvailable();
	}

	void MemoryDetails::UpdateHistograms() {
	// Reports a set of memory metrics to UMA.
	// Memory is measured in KB.

	const ProcessData& browser = *ChromeBrowser();
	size_t aggregate_memory = 0;
	int plugin_count = 0;
	int worker_count = 0;
	for (size_t index = 0; index < browser.processes.size(); index++) {
	int sample = static_cast<int>(browser.processes[index].working_set.priv);
	aggregate_memory += sample;
	switch (browser.processes[index].type) {
	case ChildProcessInfo::BROWSER_PROCESS:
	UMA_HISTOGRAM_MEMORY_KB("Memory.Browser", sample);
	break;
	case ChildProcessInfo::RENDER_PROCESS:
	UMA_HISTOGRAM_MEMORY_KB("Memory.Renderer", sample);
	break;
	case ChildProcessInfo::PLUGIN_PROCESS:
	UMA_HISTOGRAM_MEMORY_KB("Memory.Plugin", sample);
	plugin_count++;
	break;
	case ChildProcessInfo::WORKER_PROCESS:
	UMA_HISTOGRAM_MEMORY_KB("Memory.Worker", sample);
	worker_count++;
	break;
	case ChildProcessInfo::UTILITY_PROCESS:
	UMA_HISTOGRAM_MEMORY_KB("Memory.Utility", sample);
	break;
	case ChildProcessInfo::ZYGOTE_PROCESS:
	UMA_HISTOGRAM_MEMORY_KB("Memory.Zygote", sample);
	break;
	case ChildProcessInfo::SANDBOX_HELPER_PROCESS:
	UMA_HISTOGRAM_MEMORY_KB("Memory.SandboxHelper", sample);
	break;
	case ChildProcessInfo::NACL_LOADER_PROCESS:
	UMA_HISTOGRAM_MEMORY_KB("Memory.NativeClient", sample);
	break;
	case ChildProcessInfo::NACL_BROKER_PROCESS:
	UMA_HISTOGRAM_MEMORY_KB("Memory.NativeClientBroker", sample);
	break;
	case ChildProcessInfo::GPU_PROCESS:
	UMA_HISTOGRAM_MEMORY_KB("Memory.Gpu", sample);
	break;
	default:
	NOTREACHED();
	}
	}
	UMA_HISTOGRAM_MEMORY_KB("Memory.BackingStore",
	BackingStoreManager::MemorySize() / 1024);

	UMA_HISTOGRAM_COUNTS_100("Memory.ProcessCount",
	static_cast<int>(browser.processes.size()));
	UMA_HISTOGRAM_COUNTS_100("Memory.PluginProcessCount", plugin_count);
	UMA_HISTOGRAM_COUNTS_100("Memory.WorkerProcessCount", worker_count);
	// TODO(viettrungluu): Do we want separate counts for the other
	// (platform-specific) process types?

	int total_sample = static_cast<int>(aggregate_memory / 1000);
	UMA_HISTOGRAM_MEMORY_MB("Memory.Total", total_sample);
	}