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/* -*- Mode: C++; tab-width: 8; indent-tabs-mode: nil; c-basic-offset: 2 -*- */
/* vim: set ts=8 sts=2 et sw=2 tw=80: */
/* This Source Code Form is subject to the terms of the Mozilla Public
* License, v. 2.0. If a copy of the MPL was not distributed with this
#include "GeckoChildProcessHost.h"
#include "base/command_line.h"
#include "base/process.h"
#include "base/process_util.h"
#include "base/string_util.h"
#include "base/task.h"
#include "chrome/common/chrome_switches.h"
#include "chrome/common/process_watcher.h"
#ifdef XP_DARWIN
# include <mach/mach_traps.h>
# include "SharedMemoryBasic.h"
# include "base/rand_util.h"
# include "chrome/common/mach_ipc_mac.h"
# include "mozilla/StaticPrefs_media.h"
#endif
#ifdef MOZ_WIDGET_COCOA
# include <bsm/libbsm.h>
# include <servers/bootstrap.h>
# include "nsILocalFileMac.h"
#endif
#include "GeckoProfiler.h"
#include "MainThreadUtils.h"
#include "mozilla/Preferences.h"
#include "mozilla/Sprintf.h"
#include "nsXPCOMPrivate.h"
#include "prenv.h"
#include "prerror.h"
#if defined(MOZ_SANDBOX)
# include "mozilla/SandboxSettings.h"
# include "nsAppDirectoryServiceDefs.h"
#endif
#include <sys/stat.h>
#include "ProtocolUtils.h"
#include "mozilla/LinkedList.h"
#include "mozilla/Logging.h"
#include "mozilla/Maybe.h"
#include "mozilla/GeckoArgs.h"
#include "mozilla/Omnijar.h"
#include "mozilla/RDDProcessHost.h"
#include "mozilla/Services.h"
#include "mozilla/SharedThreadPool.h"
#include "mozilla/StaticMutex.h"
#include "mozilla/TaskQueue.h"
#include "mozilla/Telemetry.h"
#include "mozilla/UniquePtrExtensions.h"
#include "mozilla/ipc/BrowserProcessSubThread.h"
#include "mozilla/ipc/EnvironmentMap.h"
#include "mozilla/ipc/NodeController.h"
#include "mozilla/net/SocketProcessHost.h"
#include "nsDirectoryService.h"
#include "nsDirectoryServiceDefs.h"
#include "nsExceptionHandler.h"
#include "nsIFile.h"
#include "nsIObserverService.h"
#include "nsPrintfCString.h"
#ifdef XP_WIN
# include <stdlib.h>
# include "mozilla/WindowsVersion.h"
# include "nsIWinTaskbar.h"
# define NS_TASKBAR_CONTRACTID "@mozilla.org/windows-taskbar;1"
# if defined(MOZ_SANDBOX)
# include "WinUtils.h"
# include "mozilla/Preferences.h"
# include "mozilla/sandboxing/sandboxLogging.h"
# if defined(_ARM64_)
# include "mozilla/remoteSandboxBroker.h"
# endif
# endif
# include "mozilla/NativeNt.h"
# include "mozilla/CacheNtDllThunk.h"
#endif
#if defined(XP_LINUX) && defined(MOZ_SANDBOX)
# include "mozilla/SandboxLaunch.h"
#endif
#if defined(XP_MACOSX) && defined(MOZ_SANDBOX)
# include "GMPProcessParent.h"
# include "nsMacUtilsImpl.h"
#endif
#include "mozilla/ipc/UtilityProcessHost.h"
#include "mozilla/ipc/UtilityProcessSandboxing.h"
#include "nsClassHashtable.h"
#include "nsHashKeys.h"
#include "nsNativeCharsetUtils.h"
#include "nsTArray.h"
#include "nscore.h" // for NS_FREE_PERMANENT_DATA
#include "nsIThread.h"
using mozilla::MonitorAutoLock;
using mozilla::Preferences;
using mozilla::StaticMutexAutoLock;
#ifdef MOZ_WIDGET_ANDROID
# include "AndroidBridge.h"
# include "mozilla/java/GeckoProcessManagerWrappers.h"
# include "mozilla/java/GeckoProcessTypeWrappers.h"
# include "mozilla/java/GeckoResultWrappers.h"
# include "mozilla/jni/Refs.h"
# include "mozilla/jni/Utils.h"
#endif
#ifdef MOZ_ENABLE_FORKSERVER
# include "mozilla/ipc/ForkServiceChild.h"
#endif
static bool ShouldHaveDirectoryService() {
return GeckoProcessType_Default == XRE_GetProcessType();
}
namespace mozilla {
namespace ipc {
struct LaunchResults {
base::ProcessHandle mHandle = 0;
#ifdef XP_DARWIN
task_t mChildTask = MACH_PORT_NULL;
#endif
#ifdef XP_IOS
Maybe<ExtensionKitProcess> mExtensionKitProcess;
DarwinObjectPtr<xpc_connection_t> mXPCConnection;
UniqueBEProcessCapabilityGrant mForegroundCapabilityGrant;
#endif
#if defined(XP_WIN) && defined(MOZ_SANDBOX)
RefPtr<AbstractSandboxBroker> mSandboxBroker;
#endif
};
typedef mozilla::MozPromise<LaunchResults, LaunchError, true>
ProcessLaunchPromise;
static Atomic<int32_t> gChildCounter;
static inline nsISerialEventTarget* IOThread() {
return XRE_GetIOMessageLoop()->SerialEventTarget();
}
class BaseProcessLauncher {
public:
BaseProcessLauncher(GeckoChildProcessHost* aHost,
std::vector<std::string>&& aExtraOpts)
: mProcessType(aHost->mProcessType),
mLaunchOptions(std::move(aHost->mLaunchOptions)),
mExtraOpts(std::move(aExtraOpts)),
#ifdef XP_WIN
mGroupId(aHost->mGroupId),
#endif
#if defined(XP_WIN) && defined(MOZ_SANDBOX)
mAllowedFilesRead(aHost->mAllowedFilesRead),
mSandboxLevel(aHost->mSandboxLevel),
mSandbox(aHost->mSandbox),
mIsFileContent(aHost->mIsFileContent),
mEnableSandboxLogging(aHost->mEnableSandboxLogging),
#endif
#if defined(XP_MACOSX) && defined(MOZ_SANDBOX)
mDisableOSActivityMode(aHost->mDisableOSActivityMode),
#endif
mTmpDirName(aHost->mTmpDirName),
mChildId(++gChildCounter) {
SprintfLiteral(mPidString, "%" PRIPID, base::GetCurrentProcId());
aHost->mInitialChannelId.ToProvidedString(mInitialChannelIdString);
// Compute the serial event target we'll use for launching.
nsCOMPtr<nsIEventTarget> threadOrPool = GetIPCLauncher();
mLaunchThread =
TaskQueue::Create(threadOrPool.forget(), "BaseProcessLauncher");
if (ShouldHaveDirectoryService()) {
// "Current process directory" means the app dir, not the current
// working dir or similar.
mozilla::Unused
<< nsDirectoryService::gService->GetCurrentProcessDirectory(
getter_AddRefs(mAppDir));
}
}
NS_INLINE_DECL_THREADSAFE_REFCOUNTING(BaseProcessLauncher);
#ifdef ALLOW_GECKO_CHILD_PROCESS_ARCH
void SetLaunchArchitecture(uint32_t aLaunchArch) {
mLaunchArch = aLaunchArch;
}
#endif
RefPtr<ProcessLaunchPromise> Launch(GeckoChildProcessHost*);
protected:
virtual ~BaseProcessLauncher() = default;
RefPtr<ProcessLaunchPromise> PerformAsyncLaunch();
RefPtr<ProcessLaunchPromise> FinishLaunch();
// Overrideable hooks. If superclass behavior is invoked, it's always at the
// top of the override.
virtual Result<Ok, LaunchError> DoSetup();
virtual RefPtr<ProcessHandlePromise> DoLaunch() = 0;
virtual Result<Ok, LaunchError> DoFinishLaunch();
void MapChildLogging();
static BinPathType GetPathToBinary(FilePath&, GeckoProcessType);
void GetChildLogName(const char* origLogName, nsACString& buffer);
const char* ChildProcessType() {
return XRE_GeckoProcessTypeToString(mProcessType);
}
nsCOMPtr<nsISerialEventTarget> mLaunchThread;
GeckoProcessType mProcessType;
UniquePtr<base::LaunchOptions> mLaunchOptions;
#ifdef ALLOW_GECKO_CHILD_PROCESS_ARCH
uint32_t mLaunchArch = base::PROCESS_ARCH_INVALID;
#endif
std::vector<std::string> mExtraOpts;
#ifdef XP_WIN
nsString mGroupId;
#endif
#if defined(XP_WIN) && defined(MOZ_SANDBOX)
std::vector<std::wstring> mAllowedFilesRead;
int32_t mSandboxLevel;
SandboxingKind mSandbox;
bool mIsFileContent;
bool mEnableSandboxLogging;
#endif
#if defined(XP_MACOSX) && defined(MOZ_SANDBOX)
// Controls whether or not the process will be launched with
// environment variable OS_ACTIVITY_MODE set to "disabled".
bool mDisableOSActivityMode;
#endif
nsCString mTmpDirName;
LaunchResults mResults = LaunchResults();
int32_t mChildId;
TimeStamp mStartTimeStamp = TimeStamp::Now();
char mPidString[32];
char mInitialChannelIdString[NSID_LENGTH];
// Set during launch.
IPC::Channel::ChannelHandle mClientChannelHandle;
nsCOMPtr<nsIFile> mAppDir;
};
#ifdef XP_WIN
class WindowsProcessLauncher final : public BaseProcessLauncher {
public:
WindowsProcessLauncher(GeckoChildProcessHost* aHost,
std::vector<std::string>&& aExtraOpts)
: BaseProcessLauncher(aHost, std::move(aExtraOpts)),
mCachedNtdllThunk(GetCachedNtDllThunk()) {}
protected:
virtual Result<Ok, LaunchError> DoSetup() override;
virtual RefPtr<ProcessHandlePromise> DoLaunch() override;
virtual Result<Ok, LaunchError> DoFinishLaunch() override;
private:
void AddApplicationPrefetchArgument();
mozilla::Maybe<CommandLine> mCmdLine;
# ifdef MOZ_SANDBOX
bool mUseSandbox = false;
# endif
const Buffer<IMAGE_THUNK_DATA>* mCachedNtdllThunk;
};
typedef WindowsProcessLauncher ProcessLauncher;
#endif // XP_WIN
#ifdef XP_UNIX
class PosixProcessLauncher : public BaseProcessLauncher {
public:
PosixProcessLauncher(GeckoChildProcessHost* aHost,
std::vector<std::string>&& aExtraOpts)
: BaseProcessLauncher(aHost, std::move(aExtraOpts)),
mProfileDir(aHost->mProfileDir),
mChannelDstFd(IPC::Channel::GetClientChannelHandle()) {}
protected:
virtual Result<Ok, LaunchError> DoSetup() override;
virtual RefPtr<ProcessHandlePromise> DoLaunch() override;
nsCOMPtr<nsIFile> mProfileDir;
std::vector<std::string> mChildArgv;
int mChannelDstFd;
};
# if defined(XP_MACOSX)
class MacProcessLauncher : public PosixProcessLauncher {
public:
MacProcessLauncher(GeckoChildProcessHost* aHost,
std::vector<std::string>&& aExtraOpts)
: PosixProcessLauncher(aHost, std::move(aExtraOpts)),
// Put a random number into the channel name, so that
// a compromised renderer can't pretend being the child
// that's forked off.
mMachConnectionName(
StringPrintf("org.mozilla.machname.%d",
base::RandInt(0, std::numeric_limits<int>::max()))) {
MOZ_ASSERT(mMachConnectionName.size() < BOOTSTRAP_MAX_NAME_LEN);
}
protected:
virtual Result<Ok, LaunchError> DoFinishLaunch() override;
std::string mMachConnectionName;
// We add a mach port to the command line so the child can communicate its
// 'task_t' back to the parent.
mozilla::UniqueMachReceiveRight mParentRecvPort;
friend class PosixProcessLauncher;
};
typedef MacProcessLauncher ProcessLauncher;
# elif defined(MOZ_WIDGET_ANDROID)
class AndroidProcessLauncher : public PosixProcessLauncher {
public:
AndroidProcessLauncher(GeckoChildProcessHost* aHost,
std::vector<std::string>&& aExtraOpts)
: PosixProcessLauncher(aHost, std::move(aExtraOpts)) {}
protected:
virtual RefPtr<ProcessHandlePromise> DoLaunch() override;
RefPtr<ProcessHandlePromise> LaunchAndroidService(
const GeckoProcessType aType, const std::vector<std::string>& argv,
const base::file_handle_mapping_vector& fds_to_remap);
};
typedef AndroidProcessLauncher ProcessLauncher;
// NB: Technically Android is linux (i.e. XP_LINUX is defined), but we want
// orthogonal IPC machinery there. Conversely, there are tier-3 non-Linux
// platforms (BSD and Solaris) where we want the "linux" IPC machinery. So
// we use MOZ_WIDGET_* to choose the platform backend.
# elif defined(MOZ_WIDGET_GTK)
class LinuxProcessLauncher : public PosixProcessLauncher {
public:
LinuxProcessLauncher(GeckoChildProcessHost* aHost,
std::vector<std::string>&& aExtraOpts)
: PosixProcessLauncher(aHost, std::move(aExtraOpts)) {}
protected:
virtual Result<Ok, LaunchError> DoSetup() override;
};
typedef LinuxProcessLauncher ProcessLauncher;
# elif defined(MOZ_WIDGET_UIKIT)
class IosProcessLauncher : public PosixProcessLauncher {
public:
IosProcessLauncher(GeckoChildProcessHost* aHost,
std::vector<std::string>&& aExtraOpts)
: PosixProcessLauncher(aHost, std::move(aExtraOpts)) {}
protected:
virtual RefPtr<ProcessHandlePromise> DoLaunch() override;
DarwinObjectPtr<xpc_object_t> mBootstrapMessage;
};
typedef IosProcessLauncher ProcessLauncher;
# else
# error "Unknown platform"
# endif
#endif // XP_UNIX
using base::ProcessHandle;
using mozilla::ipc::BaseProcessLauncher;
using mozilla::ipc::ProcessLauncher;
mozilla::StaticAutoPtr<mozilla::LinkedList<GeckoChildProcessHost>>
GeckoChildProcessHost::sGeckoChildProcessHosts;
mozilla::StaticMutex GeckoChildProcessHost::sMutex;
GeckoChildProcessHost::GeckoChildProcessHost(GeckoProcessType aProcessType,
bool aIsFileContent)
: mProcessType(aProcessType),
mIsFileContent(aIsFileContent),
mMonitor("mozilla.ipc.GeckoChildProcessHost.mMonitor"),
mLaunchOptions(MakeUnique<base::LaunchOptions>()),
mInitialChannelId(nsID::GenerateUUID()),
mProcessState(CREATING_CHANNEL),
#ifdef XP_WIN
mGroupId(u"-"),
#endif
#if defined(MOZ_SANDBOX) && defined(XP_WIN)
mEnableSandboxLogging(false),
mSandboxLevel(0),
#endif
mHandleLock("mozilla.ipc.GeckoChildProcessHost.mHandleLock"),
mChildProcessHandle(0),
#if defined(XP_DARWIN)
mChildTask(MACH_PORT_NULL),
#endif
#if defined(MOZ_SANDBOX) && defined(XP_MACOSX)
mDisableOSActivityMode(false),
#endif
mDestroying(false) {
MOZ_COUNT_CTOR(GeckoChildProcessHost);
StaticMutexAutoLock lock(sMutex);
if (!sGeckoChildProcessHosts) {
sGeckoChildProcessHosts = new mozilla::LinkedList<GeckoChildProcessHost>();
}
sGeckoChildProcessHosts->insertBack(this);
#if defined(MOZ_SANDBOX) && defined(XP_LINUX)
if (aProcessType == GeckoProcessType_Content) {
# if defined(MOZ_CONTENT_TEMP_DIR)
// The content process needs the content temp dir:
nsCOMPtr<nsIFile> contentTempDir;
nsresult rv = NS_GetSpecialDirectory(NS_APP_CONTENT_PROCESS_TEMP_DIR,
getter_AddRefs(contentTempDir));
if (NS_SUCCEEDED(rv)) {
contentTempDir->GetNativePath(mTmpDirName);
}
# endif
} else if (aProcessType == GeckoProcessType_RDD) {
// The RDD process makes limited use of EGL. If Mesa's shader
// cache is enabled and the directory isn't explicitly set, then
// it will try to getpwuid() the user which can cause problems
// with sandboxing. Because we shouldn't need shader caching in
// this process, we just disable the cache to prevent that.
mLaunchOptions->env_map["MESA_GLSL_CACHE_DISABLE"] = "true";
mLaunchOptions->env_map["MESA_SHADER_CACHE_DISABLE"] = "true";
// In case the nvidia driver is also loaded:
mLaunchOptions->env_map["__GL_SHADER_DISK_CACHE"] = "0";
}
#endif
#if defined(MOZ_ENABLE_FORKSERVER)
if (aProcessType != GeckoProcessType_ForkServer && ForkServiceChild::Get()) {
mLaunchOptions->use_forkserver = true;
}
#endif
}
GeckoChildProcessHost::~GeckoChildProcessHost()
{
AssertIOThread();
MOZ_RELEASE_ASSERT(mDestroying);
MOZ_COUNT_DTOR(GeckoChildProcessHost);
{
mozilla::AutoWriteLock hLock(mHandleLock);
#if defined(XP_DARWIN)
if (mChildTask != MACH_PORT_NULL) {
mach_port_deallocate(mach_task_self(), mChildTask);
}
#endif
#if defined(XP_IOS)
if (mForegroundCapabilityGrant) {
mForegroundCapabilityGrant.reset();
}
if (mExtensionKitProcess) {
mExtensionKitProcess->Invalidate();
}
if (mXPCConnection) {
xpc_connection_cancel(mXPCConnection.get());
}
#endif
if (mChildProcessHandle != 0) {
ProcessWatcher::EnsureProcessTerminated(
mChildProcessHandle
#ifdef NS_FREE_PERMANENT_DATA
// If we're doing leak logging, shutdown can be slow.
,
false // don't "force"
#endif
);
mChildProcessHandle = 0;
}
}
#if defined(MOZ_SANDBOX) && defined(XP_WIN)
if (mSandboxBroker) {
mSandboxBroker->Shutdown();
mSandboxBroker = nullptr;
}
#endif
}
base::ProcessHandle GeckoChildProcessHost::GetChildProcessHandle() {
mozilla::AutoReadLock handleLock(mHandleLock);
return mChildProcessHandle;
}
base::ProcessId GeckoChildProcessHost::GetChildProcessId() {
mozilla::AutoReadLock handleLock(mHandleLock);
if (!mChildProcessHandle) {
return 0;
}
return base::GetProcId(mChildProcessHandle);
}
#ifdef XP_DARWIN
task_t GeckoChildProcessHost::GetChildTask() {
mozilla::AutoReadLock handleLock(mHandleLock);
return mChildTask;
}
#endif
void GeckoChildProcessHost::RemoveFromProcessList() {
StaticMutexAutoLock lock(sMutex);
if (!sGeckoChildProcessHosts) {
return;
}
LinkedListElement<GeckoChildProcessHost>::removeFrom(
*sGeckoChildProcessHosts);
}
void GeckoChildProcessHost::Destroy() {
MOZ_RELEASE_ASSERT(!mDestroying);
// We can remove from the list before it's really destroyed
RemoveFromProcessList();
RefPtr<ProcessHandlePromise> whenReady = mHandlePromise;
if (!whenReady) {
// AsyncLaunch not called yet, so dispatch immediately.
whenReady = ProcessHandlePromise::CreateAndReject(
LaunchError("DestroyEarly"), __func__);
}
using Value = ProcessHandlePromise::ResolveOrRejectValue;
mDestroying = true;
whenReady->Then(XRE_GetIOMessageLoop()->SerialEventTarget(), __func__,
[this](const Value&) { delete this; });
}
// static
mozilla::BinPathType BaseProcessLauncher::GetPathToBinary(
FilePath& exePath, GeckoProcessType processType) {
BinPathType pathType = XRE_GetChildProcBinPathType(processType);
if (pathType == BinPathType::Self) {
#if defined(XP_WIN)
wchar_t exePathBuf[MAXPATHLEN];
if (!::GetModuleFileNameW(nullptr, exePathBuf, MAXPATHLEN)) {
MOZ_CRASH("GetModuleFileNameW failed (FIXME)");
}
exePath = FilePath::FromWStringHack(exePathBuf);
#else
exePath = FilePath(CommandLine::ForCurrentProcess()->argv()[0]);
#endif
return pathType;
}
#ifdef MOZ_WIDGET_COCOA
// The GMP child process runs via the Media Plugin Helper executable
// which is a clone of plugin-container allowing for GMP-specific
// codesigning entitlements.
nsCString bundleName;
std::string executableLeafName;
if (processType == GeckoProcessType_GMPlugin &&
mozilla::StaticPrefs::media_plugin_helper_process_enabled()) {
bundleName = MOZ_EME_PROCESS_BUNDLENAME;
executableLeafName = MOZ_EME_PROCESS_NAME_BRANDED;
} else {
bundleName = MOZ_CHILD_PROCESS_BUNDLENAME;
executableLeafName = MOZ_CHILD_PROCESS_NAME;
}
#endif
if (ShouldHaveDirectoryService()) {
MOZ_ASSERT(gGREBinPath);
#ifdef XP_WIN
exePath = FilePath(char16ptr_t(gGREBinPath));
#elif MOZ_WIDGET_COCOA
nsCOMPtr<nsIFile> childProcPath;
NS_NewLocalFile(nsDependentString(gGREBinPath), false,
getter_AddRefs(childProcPath));
// We need to use an App Bundle on OS X so that we can hide
childProcPath->AppendNative(bundleName);
childProcPath->AppendNative("Contents"_ns);
childProcPath->AppendNative("MacOS"_ns);
nsCString tempCPath;
childProcPath->GetNativePath(tempCPath);
exePath = FilePath(tempCPath.get());
#else
nsCString path;
NS_CopyUnicodeToNative(nsDependentString(gGREBinPath), path);
exePath = FilePath(path.get());
#endif
}
if (exePath.empty()) {
#ifdef XP_WIN
exePath =
FilePath::FromWStringHack(CommandLine::ForCurrentProcess()->program());
#else
exePath = FilePath(CommandLine::ForCurrentProcess()->argv()[0]);
#endif
exePath = exePath.DirName();
}
#ifdef MOZ_WIDGET_COCOA
exePath = exePath.Append(executableLeafName);
#else
exePath = exePath.AppendASCII(MOZ_CHILD_PROCESS_NAME);
#endif
return pathType;
}
#ifdef MOZ_WIDGET_COCOA
class AutoCFTypeObject {
public:
explicit AutoCFTypeObject(CFTypeRef object) { mObject = object; }
~AutoCFTypeObject() { ::CFRelease(mObject); }
private:
CFTypeRef mObject;
};
#endif
// We start the unique IDs at 1 so that 0 can be used to mean that
// a component has no unique ID assigned to it.
uint32_t GeckoChildProcessHost::sNextUniqueID = 1;
/* static */
uint32_t GeckoChildProcessHost::GetUniqueID() { return sNextUniqueID++; }
/* static */
void GeckoChildProcessHost::SetEnv(const char* aKey, const char* aValue) {
MOZ_ASSERT(mLaunchOptions);
mLaunchOptions->env_map[ENVIRONMENT_STRING(aKey)] =
ENVIRONMENT_STRING(aValue);
}
void GeckoChildProcessHost::PrepareLaunch() {
if (CrashReporter::GetEnabled()) {
CrashReporter::OOPInit();
}
#if defined(XP_LINUX) && defined(MOZ_SANDBOX)
SandboxLaunch::Configure(mProcessType, mSandbox, mLaunchOptions.get());
#endif
#ifdef XP_WIN
# if defined(MOZ_SANDBOX)
// We need to get the pref here as the process is launched off main thread.
if (mProcessType == GeckoProcessType_Content) {
// Win32k Lockdown state must be initialized on the main thread.
// This is our last chance to do it before it is read on the IPC Launch
// thread
GetWin32kLockdownState();
mSandboxLevel = GetEffectiveContentSandboxLevel();
mEnableSandboxLogging =
Preferences::GetBool("security.sandbox.logging.enabled");
// We currently have to whitelist certain paths for tests to work in some
// development configurations.
nsAutoString readPaths;
nsresult rv = Preferences::GetString(
"security.sandbox.content.read_path_whitelist", readPaths);
if (NS_SUCCEEDED(rv)) {
for (const nsAString& readPath : readPaths.Split(',')) {
nsString trimmedPath(readPath);
trimmedPath.Trim(" ", true, true);
std::wstring resolvedPath(trimmedPath.Data());
// Check if path ends with '\' as this indicates we want to give read
// access to a directory and so it needs a wildcard.
if (resolvedPath.back() == L'\\') {
resolvedPath.append(L"*");
}
mAllowedFilesRead.push_back(resolvedPath);
}
}
}
# endif
# if defined(MOZ_SANDBOX)
// For other process types we can't rely on them being launched on main
// thread and they may not have access to prefs in the child process, so allow
// them to turn on logging via an environment variable.
mEnableSandboxLogging =
mEnableSandboxLogging || !!PR_GetEnv("MOZ_SANDBOX_LOGGING");
# endif
#elif defined(XP_MACOSX)
# if defined(MOZ_SANDBOX)
if (ShouldHaveDirectoryService() &&
mProcessType != GeckoProcessType_GMPlugin) {
mozilla::Unused << NS_GetSpecialDirectory(NS_APP_USER_PROFILE_50_DIR,
getter_AddRefs(mProfileDir));
}
# endif
#endif
}
#ifdef XP_WIN
void GeckoChildProcessHost::InitWindowsGroupID() {
// On Win7+, pass the application user model to the child, so it can
// register with it. This insures windows created by the container
// properly group with the parent app on the Win7 taskbar.
nsCOMPtr<nsIWinTaskbar> taskbarInfo = do_GetService(NS_TASKBAR_CONTRACTID);
if (taskbarInfo) {
bool isSupported = false;
taskbarInfo->GetAvailable(&isSupported);
nsAutoString appId;
if (isSupported && NS_SUCCEEDED(taskbarInfo->GetDefaultGroupId(appId))) {
MOZ_ASSERT(mGroupId.EqualsLiteral("-"));
mGroupId.Assign(appId);
}
}
}
#endif
bool GeckoChildProcessHost::SyncLaunch(std::vector<std::string> aExtraOpts,
int aTimeoutMs) {
if (!AsyncLaunch(std::move(aExtraOpts))) {
return false;
}
return WaitUntilConnected(aTimeoutMs);
}
// Note: for most process types, we currently call AsyncLaunch, and therefore
// the *ProcessLauncher constructor, on the main thread, while the
// ProcessLauncher methods to actually execute the launch are called on the IO
// or IPC launcher thread. GMP processes are an exception - the GMP code
// invokes GeckoChildProcessHost from non-main-threads, and therefore we cannot
// rely on having access to mainthread-only services (like the directory
// service) from this code if we're launching that type of process.
bool GeckoChildProcessHost::AsyncLaunch(std::vector<std::string> aExtraOpts) {
PrepareLaunch();
#if defined(XP_MACOSX) && defined(MOZ_SANDBOX)
if (IsMacSandboxLaunchEnabled() && !AppendMacSandboxParams(aExtraOpts)) {
return false;
}
#endif
RefPtr<BaseProcessLauncher> launcher =
new ProcessLauncher(this, std::move(aExtraOpts));
#ifdef ALLOW_GECKO_CHILD_PROCESS_ARCH
launcher->SetLaunchArchitecture(mLaunchArch);
#endif
// Note: Destroy() waits on mHandlePromise to delete |this|. As such, we want
// to be sure that all of our post-launch processing on |this| happens before
// mHandlePromise notifies.
MOZ_ASSERT(mHandlePromise == nullptr);
mHandlePromise =
mozilla::InvokeAsync<GeckoChildProcessHost*>(
IOThread(), launcher.get(), __func__, &BaseProcessLauncher::Launch,
this)
->Then(
IOThread(), __func__,
[this](LaunchResults&& aResults) {
{
{
mozilla::AutoWriteLock handleLock(mHandleLock);
if (!OpenPrivilegedHandle(base::GetProcId(aResults.mHandle))
#ifdef XP_WIN
// If we failed in opening the process handle, try
// harder by duplicating one.
&& !::DuplicateHandle(
::GetCurrentProcess(), aResults.mHandle,
::GetCurrentProcess(), &mChildProcessHandle,
PROCESS_DUP_HANDLE | PROCESS_TERMINATE |
PROCESS_QUERY_INFORMATION | PROCESS_VM_READ |
SYNCHRONIZE,
FALSE, 0)
#endif // XP_WIN
) {
MOZ_CRASH("cannot open handle to child process");
}
// The original handle is no longer needed; it must
// be closed to prevent a resource leak.
base::CloseProcessHandle(aResults.mHandle);
// "safe" invalid value to use in places like this.
aResults.mHandle = 0;
#ifdef XP_DARWIN
this->mChildTask = aResults.mChildTask;
#endif
#ifdef XP_IOS
this->mExtensionKitProcess = aResults.mExtensionKitProcess;
this->mXPCConnection = aResults.mXPCConnection;
this->mForegroundCapabilityGrant =
std::move(aResults.mForegroundCapabilityGrant);
#endif
if (mNodeChannel) {
mNodeChannel->SetOtherPid(
base::GetProcId(this->mChildProcessHandle));
#ifdef XP_DARWIN
mNodeChannel->SetMachTaskPort(this->mChildTask);
#endif
}
}
#if defined(XP_WIN) && defined(MOZ_SANDBOX)
this->mSandboxBroker = std::move(aResults.mSandboxBroker);
#endif
MonitorAutoLock lock(mMonitor);
// The OnChannel{Connected,Error} may have already advanced
// the state.
if (mProcessState < PROCESS_CREATED) {
mProcessState = PROCESS_CREATED;
}
lock.Notify();
}
return ProcessHandlePromise::CreateAndResolve(
GetChildProcessHandle(), __func__);
},
[this](const LaunchError aError) {
// WaitUntilConnected might be waiting for us to signal.
// If something failed let's set the error state and notify.
CHROMIUM_LOG(ERROR)
<< "Failed to launch "
<< XRE_GeckoProcessTypeToString(mProcessType)
<< " subprocess @" << aError.FunctionName()
<< " (Error:" << aError.ErrorCode() << ")";
Telemetry::Accumulate(
Telemetry::SUBPROCESS_LAUNCH_FAILURE,
nsDependentCString(
XRE_GeckoProcessTypeToString(mProcessType)));
nsCString telemetryKey = nsPrintfCString(
#if defined(XP_WIN)
"%s,0x%lx,%s",
#else
"%s,%d,%s",
#endif
aError.FunctionName(), aError.ErrorCode(),
XRE_GeckoProcessTypeToString(mProcessType));
// Max telemetry key is 72 chars
if (telemetryKey.Length() > 72) {
NS_WARNING(nsPrintfCString("Truncating telemetry key: %s",
telemetryKey.get())
.get());
telemetryKey.Truncate(72);
}
Telemetry::ScalarAdd(
Telemetry::ScalarID::
DOM_PARENTPROCESS_PROCESS_LAUNCH_ERRORS,
NS_ConvertUTF8toUTF16(telemetryKey), 1);
{
MonitorAutoLock lock(mMonitor);
mProcessState = PROCESS_ERROR;
lock.Notify();
}
return ProcessHandlePromise::CreateAndReject(aError, __func__);
});
return true;
}
bool GeckoChildProcessHost::WaitUntilConnected(int32_t aTimeoutMs) {
AUTO_PROFILER_LABEL("GeckoChildProcessHost::WaitUntilConnected", OTHER);
// NB: this uses a different mechanism than the chromium parent
// class.
TimeDuration timeout = (aTimeoutMs > 0)
? TimeDuration::FromMilliseconds(aTimeoutMs)
: TimeDuration::Forever();
MonitorAutoLock lock(mMonitor);
TimeStamp waitStart = TimeStamp::Now();
TimeStamp current;
// We'll receive several notifications, we need to exit when we
// have either successfully launched or have timed out.
while (mProcessState != PROCESS_CONNECTED) {
// If there was an error then return it, don't wait out the timeout.
if (mProcessState == PROCESS_ERROR) {
break;
}
CVStatus status = lock.Wait(timeout);
if (status == CVStatus::Timeout) {
break;
}
if (timeout != TimeDuration::Forever()) {
current = TimeStamp::Now();
timeout -= current - waitStart;
waitStart = current;
}
}
return mProcessState == PROCESS_CONNECTED;
}
bool GeckoChildProcessHost::WaitForProcessHandle() {
MonitorAutoLock lock(mMonitor);
while (mProcessState < PROCESS_CREATED) {
lock.Wait();
}
MOZ_ASSERT(mProcessState == PROCESS_ERROR || GetChildProcessHandle());
return mProcessState < PROCESS_ERROR;
}
bool GeckoChildProcessHost::LaunchAndWaitForProcessHandle(
StringVector aExtraOpts) {
if (!AsyncLaunch(std::move(aExtraOpts))) {
return false;
}
return WaitForProcessHandle();
}
void GeckoChildProcessHost::InitializeChannel(
IPC::Channel::ChannelHandle&& aServerHandle) {
// Create the IPC channel which will be used for communication with this
// process.
mozilla::UniquePtr<IPC::Channel> channel = MakeUnique<IPC::Channel>(
std::move(aServerHandle), IPC::Channel::MODE_SERVER,
base::kInvalidProcessId);
#if defined(XP_WIN)
channel->StartAcceptingHandles(IPC::Channel::MODE_SERVER);
#elif defined(XP_DARWIN)
channel->StartAcceptingMachPorts(IPC::Channel::MODE_SERVER);
#endif
mNodeController = NodeController::GetSingleton();
std::tie(mInitialPort, mNodeChannel) =
mNodeController->InviteChildProcess(std::move(channel), this);
MonitorAutoLock lock(mMonitor);
mProcessState = CHANNEL_INITIALIZED;
lock.Notify();
}
void GeckoChildProcessHost::SetAlreadyDead() {
mozilla::AutoWriteLock handleLock(mHandleLock);
if (mChildProcessHandle &&
mChildProcessHandle != base::kInvalidProcessHandle) {
base::CloseProcessHandle(mChildProcessHandle);
}
mChildProcessHandle = 0;
}
void BaseProcessLauncher::GetChildLogName(const char* origLogName,
nsACString& buffer) {
#ifdef XP_WIN
// On Windows we must expand relative paths because sandboxing rules
// bound only to full paths. fopen fowards to NtCreateFile which checks
// the path against the sanboxing rules as passed to fopen (left relative).
char absPath[MAX_PATH + 2];
if (_fullpath(absPath, origLogName, sizeof(absPath))) {
buffer.Append(absPath);
} else
#endif
{
buffer.Append(origLogName);
}
// Remove .moz_log extension to avoid its duplication, it will be added
// automatically by the logging backend
static constexpr auto kMozLogExt = nsLiteralCString{MOZ_LOG_FILE_EXTENSION};
if (StringEndsWith(buffer, kMozLogExt)) {
buffer.Truncate(buffer.Length() - kMozLogExt.Length());
}
// Append child-specific postfix to name
buffer.AppendLiteral(".child-");
buffer.AppendInt(mChildId);
}
// Windows needs a single dedicated thread for process launching,
// because of thread-safety restrictions/assertions in the sandbox
// code.
//
// Android also needs a single dedicated thread to simplify thread
// safety in java.
//
// Fork server needs a dedicated thread for accessing
// |ForkServiceChild|.
#if defined(XP_WIN) || defined(MOZ_WIDGET_ANDROID) || \
defined(MOZ_ENABLE_FORKSERVER)
static mozilla::StaticMutex gIPCLaunchThreadMutex;
static mozilla::StaticRefPtr<nsIThread> gIPCLaunchThread
MOZ_GUARDED_BY(gIPCLaunchThreadMutex);
class IPCLaunchThreadObserver final : public nsIObserver {
public:
NS_DECL_ISUPPORTS
NS_DECL_NSIOBSERVER
protected:
virtual ~IPCLaunchThreadObserver() = default;
};
NS_IMPL_ISUPPORTS(IPCLaunchThreadObserver, nsIObserver, nsISupports)
NS_IMETHODIMP
IPCLaunchThreadObserver::Observe(nsISupports* aSubject, const char* aTopic,
const char16_t* aData) {
MOZ_RELEASE_ASSERT(strcmp(aTopic, "xpcom-shutdown-threads") == 0);
StaticMutexAutoLock lock(gIPCLaunchThreadMutex);
nsresult rv = NS_OK;
if (gIPCLaunchThread) {
rv = gIPCLaunchThread->Shutdown();
gIPCLaunchThread = nullptr;
}
mozilla::Unused << NS_WARN_IF(NS_FAILED(rv));
return rv;
}
nsCOMPtr<nsIEventTarget> GetIPCLauncher() {
StaticMutexAutoLock lock(gIPCLaunchThreadMutex);
if (!gIPCLaunchThread) {
nsCOMPtr<nsIThread> thread;
nsresult rv = NS_NewNamedThread("IPC Launch"_ns, getter_AddRefs(thread));
if (!NS_WARN_IF(NS_FAILED(rv))) {
NS_DispatchToMainThread(
NS_NewRunnableFunction("GeckoChildProcessHost::GetIPCLauncher", [] {
nsCOMPtr<nsIObserverService> obsService =
mozilla::services::GetObserverService();
nsCOMPtr<nsIObserver> obs = new IPCLaunchThreadObserver();
obsService->AddObserver(obs, "xpcom-shutdown-threads", false);
}));
gIPCLaunchThread = thread.forget();
}
}
nsCOMPtr<nsIEventTarget> thread = gIPCLaunchThread.get();
MOZ_DIAGNOSTIC_ASSERT(thread);
return thread;
}
#else // defined(XP_WIN) || defined(MOZ_WIDGET_ANDROID) ||
// defined(MOZ_ENABLE_FORKSERVER)
// Other platforms use an on-demand thread pool.
nsCOMPtr<nsIEventTarget> GetIPCLauncher() {
nsCOMPtr<nsIEventTarget> pool =
mozilla::SharedThreadPool::Get("IPC Launch"_ns);
MOZ_DIAGNOSTIC_ASSERT(pool);
return pool;
}
#endif // XP_WIN || MOZ_WIDGET_ANDROID || MOZ_ENABLE_FORKSERVER
void
#if defined(XP_WIN)
AddAppDirToCommandLine(CommandLine& aCmdLine, nsIFile* aAppDir)
#else
AddAppDirToCommandLine(std::vector<std::string>& aCmdLine, nsIFile* aAppDir,
nsIFile* aProfileDir)
#endif
{
// Content processes need access to application resources, so pass
// the full application directory path to the child process.
if (aAppDir) {
#if defined(XP_WIN)
nsString path;
MOZ_ALWAYS_SUCCEEDS(aAppDir->GetPath(path));
aCmdLine.AppendLooseValue(UTF8ToWide(geckoargs::sAppDir.Name()));
std::wstring wpath(path.get());
aCmdLine.AppendLooseValue(wpath);
#else
nsAutoCString path;
MOZ_ALWAYS_SUCCEEDS(aAppDir->GetNativePath(path));
geckoargs::sAppDir.Put(path.get(), aCmdLine);
#endif
#if defined(XP_MACOSX) && defined(MOZ_SANDBOX)
// Full path to the profile dir
if (aProfileDir) {
// If the profile doesn't exist, normalization will
// fail. But we don't return an error here because some
// tests require startup with a missing profile dir.
// For users, almost universally, the profile will be in
// the home directory and normalization isn't required.
mozilla::Unused << aProfileDir->Normalize();
nsAutoCString path;
MOZ_ALWAYS_SUCCEEDS(aProfileDir->GetNativePath(path));
geckoargs::sProfile.Put(path.get(), aCmdLine);
}
#endif
}
}
#if defined(XP_WIN) && (defined(MOZ_SANDBOX) || defined(_ARM64_))
static bool Contains(const std::vector<std::string>& aExtraOpts,
const char* aValue) {
return std::any_of(aExtraOpts.begin(), aExtraOpts.end(),
[&](const std::string arg) {
return arg.find(aValue) != std::string::npos;
});
}
#endif // defined(XP_WIN) && (defined(MOZ_SANDBOX) || defined(_ARM64_))
RefPtr<ProcessLaunchPromise> BaseProcessLauncher::PerformAsyncLaunch() {
Result<Ok, LaunchError> aError = DoSetup();
if (aError.isErr()) {
return ProcessLaunchPromise::CreateAndReject(aError.unwrapErr(), __func__);
}
RefPtr<BaseProcessLauncher> self = this;
return DoLaunch()->Then(
mLaunchThread, __func__,
[self](base::ProcessHandle aHandle) {
self->mResults.mHandle = aHandle;
return self->FinishLaunch();
},
[](LaunchError aError) {
return ProcessLaunchPromise::CreateAndReject(aError, __func__);
});
}
Result<Ok, LaunchError> BaseProcessLauncher::DoSetup() {
RefPtr<BaseProcessLauncher> self = this;
GetProfilerEnvVarsForChildProcess([self](const char* key, const char* value) {
self->mLaunchOptions->env_map[ENVIRONMENT_STRING(key)] =
ENVIRONMENT_STRING(value);
});
#ifdef MOZ_MEMORY
if (mProcessType == GeckoProcessType_Content) {
nsAutoCString mallocOpts(PR_GetEnv("MALLOC_OPTIONS"));
// Disable randomization of small arenas in content.
mallocOpts.Append("r");
self->mLaunchOptions->env_map[ENVIRONMENT_LITERAL("MALLOC_OPTIONS")] =
ENVIRONMENT_STRING(mallocOpts.get());
}
#endif
MapChildLogging();
return Ok();
}
void BaseProcessLauncher::MapChildLogging() {
const char* origNSPRLogName = PR_GetEnv("NSPR_LOG_FILE");
const char* origMozLogName = PR_GetEnv("MOZ_LOG_FILE");
if (origNSPRLogName) {
nsAutoCString nsprLogName;
GetChildLogName(origNSPRLogName, nsprLogName);
mLaunchOptions->env_map[ENVIRONMENT_LITERAL("NSPR_LOG_FILE")] =
ENVIRONMENT_STRING(nsprLogName.get());
}
if (origMozLogName) {
nsAutoCString mozLogName;
GetChildLogName(origMozLogName, mozLogName);
mLaunchOptions->env_map[ENVIRONMENT_LITERAL("MOZ_LOG_FILE")] =
ENVIRONMENT_STRING(mozLogName.get());
}
// `RUST_LOG_CHILD` is meant for logging child processes only.
nsAutoCString childRustLog(PR_GetEnv("RUST_LOG_CHILD"));
if (!childRustLog.IsEmpty()) {
mLaunchOptions->env_map[ENVIRONMENT_LITERAL("RUST_LOG")] =
ENVIRONMENT_STRING(childRustLog.get());
}
}
Result<Ok, LaunchError> BaseProcessLauncher::DoFinishLaunch() {
// We're in the parent and the child was launched. Close the child channel
// handle in the parent as soon as possible, which will allow the parent to
// detect when the child closes its handle (either due to normal exit or due
// to crash).
mClientChannelHandle = nullptr;
return Ok();
}
#if defined(MOZ_WIDGET_GTK)
Result<Ok, LaunchError> LinuxProcessLauncher::DoSetup() {
Result<Ok, LaunchError> aError = PosixProcessLauncher::DoSetup();
if (aError.isErr()) {
return aError;
}
if (mProcessType == GeckoProcessType_Content) {
// disable IM module to avoid sandbox violation
mLaunchOptions->env_map["GTK_IM_MODULE"] = "gtk-im-context-simple";
// Disable ATK accessibility code in content processes because it conflicts
// with the sandbox, and we proxy that information through the main process
// anyway.
mLaunchOptions->env_map["NO_AT_BRIDGE"] = "1";
}
# ifdef MOZ_SANDBOX
if (!mTmpDirName.IsEmpty()) {
// Point a bunch of things that might want to write from content to our
// shiny new content-process specific tmpdir
mLaunchOptions->env_map[ENVIRONMENT_LITERAL("TMPDIR")] =
ENVIRONMENT_STRING(mTmpDirName.get());
mLaunchOptions->env_map[ENVIRONMENT_LITERAL("MESA_GLSL_CACHE_DIR")] =
ENVIRONMENT_STRING(mTmpDirName.get());
}
# endif // MOZ_SANDBOX
return Ok();
}
#endif // MOZ_WIDGET_GTK
#ifdef XP_UNIX
Result<Ok, LaunchError> PosixProcessLauncher::DoSetup() {
Result<Ok, LaunchError> aError = BaseProcessLauncher::DoSetup();
if (aError.isErr()) {
return aError;
}
// XPCOM may not be initialized in some subprocesses. We don't want
// to initialize XPCOM just for the directory service, especially
// since LD_LIBRARY_PATH is already set correctly in subprocesses
// (meaning that we don't need to set that up in the environment).
if (ShouldHaveDirectoryService()) {
MOZ_ASSERT(gGREBinPath);
nsCString path;
NS_CopyUnicodeToNative(nsDependentString(gGREBinPath), path);
# if defined(XP_LINUX) || defined(__DragonFly__) || defined(XP_FREEBSD) || \
defined(XP_NETBSD) || defined(XP_OPENBSD)
const char* ld_library_path = PR_GetEnv("LD_LIBRARY_PATH");
nsCString new_ld_lib_path(path.get());
if (ld_library_path && *ld_library_path) {
new_ld_lib_path.Append(':');
new_ld_lib_path.Append(ld_library_path);
}
mLaunchOptions->env_map["LD_LIBRARY_PATH"] = new_ld_lib_path.get();
# elif XP_MACOSX
// With signed production Mac builds, the dynamic linker (dyld) will
// ignore dyld environment variables preventing the use of variables
// such as DYLD_LIBRARY_PATH and DYLD_INSERT_LIBRARIES.
// If we're running with gtests, add the gtest XUL ahead of normal XUL on
// the DYLD_LIBRARY_PATH so that plugin-container.app loads it instead.
nsCString new_dyld_lib_path(path.get());
if (PR_GetEnv("MOZ_RUN_GTEST")) {
new_dyld_lib_path = path + "/gtest:"_ns + new_dyld_lib_path;
mLaunchOptions->env_map["DYLD_LIBRARY_PATH"] = new_dyld_lib_path.get();
}
// DYLD_INSERT_LIBRARIES is currently unused by default but we allow
// it to be set by the external environment.
const char* interpose = PR_GetEnv("DYLD_INSERT_LIBRARIES");
if (interpose && strlen(interpose) > 0) {
mLaunchOptions->env_map["DYLD_INSERT_LIBRARIES"] = interpose;
}
// Prevent connection attempts to diagnosticd(8) to save cycles. Log
// messages can trigger these connection attempts, but access to
// diagnosticd is blocked in sandboxed child processes.
# if defined(MOZ_SANDBOX) && defined(XP_MACOSX)
if (mDisableOSActivityMode) {
mLaunchOptions->env_map["OS_ACTIVITY_MODE"] = "disable";
}
# endif // defined(MOZ_SANDBOX)
# endif
}
FilePath exePath;
BinPathType pathType = GetPathToBinary(exePath, mProcessType);
// remap the IPC socket fd to a well-known int, as the OS does for
// STDOUT_FILENO, for example
// The fork server doesn't use IPC::Channel, so can skip this step.
if (mProcessType != GeckoProcessType_ForkServer) {
# if !defined(MOZ_WIDGET_ANDROID) && !defined(MOZ_WIDGET_UIKIT)
// On Android/iOS, mChannelDstFd is initialised to -1 and the launching
// code uses only the first of each pair.
MOZ_ASSERT(mChannelDstFd >= 0);
# endif
mLaunchOptions->fds_to_remap.push_back(
std::pair<int, int>(mClientChannelHandle.get(), mChannelDstFd));
}
// no need for kProcessChannelID, the child process inherits the
// other end of the socketpair() from us
mChildArgv.push_back(exePath.value());
if (pathType == BinPathType::Self) {
mChildArgv.push_back("-contentproc");
}
mChildArgv.insert(mChildArgv.end(), mExtraOpts.begin(), mExtraOpts.end());
if ((mProcessType == GeckoProcessType_Content ||
mProcessType == GeckoProcessType_ForkServer) &&
Omnijar::IsInitialized()) {
// Make sure that child processes can find the omnijar, if they
// use full XPCOM. See Omnijar::ChildProcessInit and its callers.
nsAutoCString path;
nsCOMPtr<nsIFile> greFile = Omnijar::GetPath(Omnijar::GRE);
if (greFile && NS_SUCCEEDED(greFile->GetNativePath(path))) {
geckoargs::sGREOmni.Put(path.get(), mChildArgv);
}
nsCOMPtr<nsIFile> appFile = Omnijar::GetPath(Omnijar::APP);
if (appFile && NS_SUCCEEDED(appFile->GetNativePath(path))) {
geckoargs::sAppOmni.Put(path.get(), mChildArgv);
}
}
if (mProcessType != GeckoProcessType_GMPlugin) {
// Add the application directory path (-appdir path)
# ifdef XP_MACOSX
AddAppDirToCommandLine(mChildArgv, mAppDir, mProfileDir);
# else
AddAppDirToCommandLine(mChildArgv, mAppDir, nullptr);
# endif
}
mChildArgv.push_back(mInitialChannelIdString);
mChildArgv.push_back(mPidString);
if (!CrashReporter::IsDummy()) {
# if defined(MOZ_WIDGET_COCOA)
mChildArgv.push_back(CrashReporter::GetChildNotificationPipe());
# elif defined(XP_UNIX)
int childCrashFd, childCrashRemapFd;
if (NS_WARN_IF(!CrashReporter::CreateNotificationPipeForChild(
&childCrashFd, &childCrashRemapFd))) {
return Err(LaunchError("CR::CreateNotificationPipeForChild"));
}
if (0 <= childCrashFd) {
mLaunchOptions->fds_to_remap.push_back(
std::pair<int, int>(childCrashFd, childCrashRemapFd));
// "true" == crash reporting enabled
mChildArgv.push_back("true");
} else {
// "false" == crash reporting disabled
mChildArgv.push_back("false");
}
# endif
}
# ifdef MOZ_WIDGET_COCOA
{
auto* thisMac = static_cast<MacProcessLauncher*>(this);
kern_return_t kr =
bootstrap_check_in(bootstrap_port, thisMac->mMachConnectionName.c_str(),
getter_Transfers(thisMac->mParentRecvPort));
if (kr != KERN_SUCCESS) {
CHROMIUM_LOG(ERROR) << "parent bootstrap_check_in failed: "
<< mach_error_string(kr);
return Err(LaunchError("bootstrap_check_in", kr));
}
mChildArgv.push_back(thisMac->mMachConnectionName.c_str());
}
# endif // MOZ_WIDGET_COCOA
mChildArgv.push_back(ChildProcessType());
return Ok();
}
#endif // XP_UNIX
#if defined(MOZ_WIDGET_ANDROID)
RefPtr<ProcessHandlePromise> AndroidProcessLauncher::DoLaunch() {
return LaunchAndroidService(mProcessType, mChildArgv,
mLaunchOptions->fds_to_remap);
}
#endif // MOZ_WIDGET_ANDROID
#ifdef XP_UNIX
RefPtr<ProcessHandlePromise> PosixProcessLauncher::DoLaunch() {
ProcessHandle handle = 0;
Result<Ok, LaunchError> aError =
base::LaunchApp(mChildArgv, std::move(*mLaunchOptions), &handle);
if (aError.isErr()) {
return ProcessHandlePromise::CreateAndReject(aError.unwrapErr(), __func__);
}
return ProcessHandlePromise::CreateAndResolve(handle, __func__);
}
#endif // XP_UNIX
#ifdef XP_IOS
RefPtr<ProcessHandlePromise> IosProcessLauncher::DoLaunch() {
MOZ_RELEASE_ASSERT(mLaunchOptions->fds_to_remap.size() == 3,
"Unexpected fds_to_remap on iOS");
ExtensionKitProcess::Kind kind = ExtensionKitProcess::Kind::WebContent;
if (mProcessType == GeckoProcessType_GPU) {
kind = ExtensionKitProcess::Kind::Rendering;
} else if (mProcessType == GeckoProcessType_Socket) {
kind = ExtensionKitProcess::Kind::Networking;
}
DarwinObjectPtr<xpc_object_t> bootstrapMessage =
AdoptDarwinObject(xpc_dictionary_create_empty());
xpc_dictionary_set_string(bootstrapMessage.get(), "message-name",
"bootstrap");
DarwinObjectPtr<xpc_object_t> environDict =
AdoptDarwinObject(xpc_dictionary_create_empty());
for (auto& [envKey, envValue] : mLaunchOptions->env_map) {
xpc_dictionary_set_string(environDict.get(), envKey.c_str(),
envValue.c_str());
}
xpc_dictionary_set_value(bootstrapMessage.get(), "environ",
environDict.get());
// XXX: this processing depends entirely on the internals of
// ContentParent::LaunchSubprocess()
// GeckoChildProcessHost::PerformAsyncLaunch(), and the order in
// which they append to fds_to_remap. There must be a better way to do it.
int prefsFd = mLaunchOptions->fds_to_remap[0].first;
int prefMapFd = mLaunchOptions->fds_to_remap[1].first;
int ipcFd = mLaunchOptions->fds_to_remap[2].first;
xpc_dictionary_set_fd(bootstrapMessage.get(), "prefs", prefsFd);
xpc_dictionary_set_fd(bootstrapMessage.get(), "prefmap", prefMapFd);
xpc_dictionary_set_fd(bootstrapMessage.get(), "channel", ipcFd);
// Setup stdout and stderr to inherit.
xpc_dictionary_set_fd(bootstrapMessage.get(), "stdout", STDOUT_FILENO);
xpc_dictionary_set_fd(bootstrapMessage.get(), "stderr", STDERR_FILENO);
DarwinObjectPtr<xpc_object_t> argsArray =
AdoptDarwinObject(xpc_array_create_empty());
for (auto& argv : mChildArgv) {
xpc_array_set_string(argsArray.get(), XPC_ARRAY_APPEND, argv.c_str());
}
MOZ_ASSERT(xpc_array_get_count(argsArray.get()) == mChildArgv.size());
xpc_dictionary_set_value(bootstrapMessage.get(), "argv", argsArray.get());
auto promise = MakeRefPtr<ProcessHandlePromise::Private>(__func__);
ExtensionKitProcess::StartProcess(kind, [self = RefPtr{this}, promise,
bootstrapMessage =
std::move(bootstrapMessage)](
Result<ExtensionKitProcess,
LaunchError>&& result) {
if (result.isErr()) {
CHROMIUM_LOG(ERROR) << "ExtensionKitProcess::StartProcess failed";
promise->Reject(result.unwrapErr(), __func__);
return;
}
auto process = result.unwrap();
self->mResults.mForegroundCapabilityGrant =
process.GrantForegroundCapability();
self->mResults.mXPCConnection = process.MakeLibXPCConnection();
self->mResults.mExtensionKitProcess = Some(std::move(process));
// We don't actually use the event handler for anything other than
// watching for errors. Once the promise is resolved, this becomes a
// no-op.
xpc_connection_set_event_handler(self->mResults.mXPCConnection.get(), ^(
xpc_object_t event) {
if (!event || xpc_get_type(event) == XPC_TYPE_ERROR) {
CHROMIUM_LOG(WARNING) << "XPC connection received encountered an error";
promise->Reject(LaunchError("xpc_connection_event_handler"), __func__);
}
});
xpc_connection_resume(self->mResults.mXPCConnection.get());
// Send our bootstrap message to the content and wait for it to reply with
// the task port before resolving.
// FIXME: Should we have a time-out for if the child process doesn't respond
// in time? The main thread may be blocked while we're starting this
// process.
xpc_connection_send_message_with_reply(
self->mResults.mXPCConnection.get(), bootstrapMessage.get(), nullptr,
^(xpc_object_t reply) {
if (xpc_get_type(reply) == XPC_TYPE_ERROR) {
CHROMIUM_LOG(ERROR)
<< "Got error sending XPC bootstrap message to child";
promise->Reject(
LaunchError("xpc_connection_send_message_with_reply error"),
__func__);
return;
}
if (xpc_get_type(reply) != XPC_TYPE_DICTIONARY) {
CHROMIUM_LOG(ERROR)
<< "Unexpected reply type for bootstrap message from child";
promise->Reject(
LaunchError(
"xpc_connection_send_message_with_reply non-dictionary"),
__func__);
return;
}
// FIXME: We have to trust the child to tell us its pid & mach task.
// WebKit uses `xpc_connection_get_pid` to get the pid, however this
// is marked as unavailable on iOS.
//
// Given how the process is started, however, validating this
// information it sends us this early during startup may be
// unnecessary.
self->mResults.mChildTask =
xpc_dictionary_copy_mach_send(reply, "task");
pid_t pid =
static_cast<pid_t>(xpc_dictionary_get_int64(reply, "pid"));
CHROMIUM_LOG(INFO) << "ExtensionKit process started, task: "
<< self->mResults.mChildTask << ", pid: " << pid;
pid_t taskPid;
kern_return_t kr = pid_for_task(self->mResults.mChildTask, &taskPid);
if (kr != KERN_SUCCESS || pid != taskPid) {
CHROMIUM_LOG(ERROR) << "Could not validate child task matches pid";
promise->Reject(LaunchError("pid_for_task mismatch"), __func__);
return;
}
promise->Resolve(pid, __func__);
});
});
return promise;
}
#endif
#ifdef XP_MACOSX
Result<Ok, LaunchError> MacProcessLauncher::DoFinishLaunch() {
Result<Ok, LaunchError> aError = PosixProcessLauncher::DoFinishLaunch();
if (aError.isErr()) {
return aError;
}
MOZ_ASSERT(mParentRecvPort, "should have been configured during DoSetup()");
// Wait for the child process to send us its 'task_t' data.
const int kTimeoutMs = 10000;
mozilla::UniqueMachSendRight child_task;
audit_token_t audit_token{};
kern_return_t kr = MachReceivePortSendRight(
mParentRecvPort, mozilla::Some(kTimeoutMs), &child_task, &audit_token);
if (kr != KERN_SUCCESS) {
std::string errString = StringPrintf("0x%x %s", kr, mach_error_string(kr));
CHROMIUM_LOG(ERROR) << "parent MachReceivePortSendRight failed: "
<< errString;
return Err(LaunchError("MachReceivePortSendRight", kr));
}
// Ensure the message was sent by the newly spawned child process.
if (audit_token_to_pid(audit_token) != base::GetProcId(mResults.mHandle)) {
CHROMIUM_LOG(ERROR) << "task_t was not sent by child process";
return Err(LaunchError("audit_token_to_pid"));
}
// Ensure the task_t corresponds to the newly spawned child process.
pid_t task_pid = -1;
kr = pid_for_task(child_task.get(), &task_pid);
if (kr != KERN_SUCCESS) {
CHROMIUM_LOG(ERROR) << "pid_for_task failed: " << mach_error_string(kr);
return Err(LaunchError("pid_for_task", kr));
}
if (task_pid != base::GetProcId(mResults.mHandle)) {
CHROMIUM_LOG(ERROR) << "task_t is not for child process";
return Err(LaunchError("task_pid"));
}
mResults.mChildTask = child_task.release();
return Ok();
}
#endif // XP_MACOSX
#ifdef XP_WIN
void WindowsProcessLauncher::AddApplicationPrefetchArgument() {
// The Application Launch Prefetcher (ALPF) is an ill-documented Windows
// subsystem that's intended to speed up process launching, apparently mostly
// by assuming that a binary is going to want to load the same DLLs as it did
// the last time it launched, and getting those prepped for loading as well.
//
// For most applications, that's a good bet. For Firefox, it's less so, since
// we use the same binary with different arguments to do completely different
// things. Windows does allow applications to take up multiple slots in this
// cache, but the "which bucket does this invocation go in?" mechanism is
// highly unusual: the OS scans the command line and looks for a command-line
// switch of a particular form.
//
// (There is allegedly a way to do this without involving the command line,
// OVERRIDE_PREFETCH_PARAMETER, but it's even more poorly documented.)
// Applications' different prefetch-cache buckets are named with numbers from
// "1" to some OS-version-determined limit, with an additional implicit "0"
// cache bucket which is used when no valid prefetch cache slot is named.
//
// (The "0" bucket's existence and behavior is not documented, but has been
// confirmed by observing the creation and enumeration of cache files in the
// C:\Windows\Prefetch folder.)
static size_t const kMaxSlotNo = IsWin1122H2OrLater() ? 16 : 8;
// Determine the prefetch-slot number to be used for the process we're about
// to launch.
//
// This may be changed freely between Firefox versions, as a Firefox update
// will completely invalidate the prefetch cache anyway.
size_t const prefetchSlot = [&]() -> size_t {
switch (mProcessType) {
// This code path is not used when starting the main process...
case GeckoProcessType_Default:
// ...ForkServer is not used on Windows...
case GeckoProcessType_ForkServer:
// ..."End" isn't a process-type, just a limit...
case GeckoProcessType_End:
// ...and any new process-types should be considered explicitly here.
default:
MOZ_ASSERT_UNREACHABLE("Invalid process type");
return 0;
// We reserve 1 for the main process as started by the launcher process.
// (See LauncherProcessWin.cpp.) Otherwise, we mostly match the process-
// type enumeration.
case GeckoProcessType_Content:
return 2;
case GeckoProcessType_Socket:
return 3; // usurps IPDLUnitTest
case GeckoProcessType_GMPlugin:
return 4;
case GeckoProcessType_GPU:
return 5;
case GeckoProcessType_RemoteSandboxBroker:
return 6; // usurps VR
case GeckoProcessType_RDD:
return 7;
case GeckoProcessType_Utility: {
// Continue the enumeration, using the SandboxingKind as a
// probably-passably-precise proxy for the process's purpose.
//
// (On Win10 and earlier, or when sandboxing is not used, this will lump
// all utility processes into slot 8.)
# ifndef MOZ_SANDBOX
size_t const val = 0;
# else
size_t const val = static_cast<size_t>(mSandbox);
# endif
return std::min(kMaxSlotNo, 8 + val);
}
// These process types are started so rarely that we're not concerned
// about their interaction with the prefetch cache. Lump them together at
// the end (possibly alongside other process types).
case GeckoProcessType_IPDLUnitTest:
case GeckoProcessType_VR:
return kMaxSlotNo;
}
}();
MOZ_ASSERT(prefetchSlot <= kMaxSlotNo);
if (prefetchSlot == 0) {
// default; no explicit argument needed
return;
}
mCmdLine->AppendLooseValue(StringPrintf(L"/prefetch:%zu", prefetchSlot));
}
Result<Ok, LaunchError> WindowsProcessLauncher::DoSetup() {
Result<Ok, LaunchError> aError = BaseProcessLauncher::DoSetup();
if (aError.isErr()) {
return aError;
}
FilePath exePath;
BinPathType pathType = GetPathToBinary(exePath, mProcessType);
# if defined(MOZ_SANDBOX) || defined(_ARM64_)
const bool isGMP = mProcessType == GeckoProcessType_GMPlugin;
const bool isWidevine = isGMP && Contains(mExtraOpts, "gmp-widevinecdm");
# if defined(_ARM64_)
bool useRemoteSandboxBroker = false;
if (mLaunchArch & (base::PROCESS_ARCH_I386 | base::PROCESS_ARCH_X86_64)) {
// On Windows on ARM64 for ClearKey and Widevine, and for the sandbox
// launcher process, we want to run the x86 plugin-container.exe in
// the "i686" subdirectory, instead of the aarch64 plugin-container.exe.
// So insert "i686" into the exePath.
exePath = exePath.DirName().AppendASCII("i686").Append(exePath.BaseName());
useRemoteSandboxBroker =
mProcessType != GeckoProcessType_RemoteSandboxBroker;
}
# endif // if defined(_ARM64_)
# endif // defined(MOZ_SANDBOX) || defined(_ARM64_)
mCmdLine.emplace(exePath.ToWStringHack());
if (pathType == BinPathType::Self) {
mCmdLine->AppendLooseValue(UTF8ToWide("-contentproc"));
}
# ifdef HAS_DLL_BLOCKLIST
if (IsDynamicBlocklistDisabled(
gSafeMode,
CommandLine::ForCurrentProcess()->HasSwitch(UTF8ToWide(
mozilla::geckoargs::sDisableDynamicDllBlocklist.sMatch)))) {
mCmdLine->AppendLooseValue(
UTF8ToWide(mozilla::geckoargs::sDisableDynamicDllBlocklist.sMatch));
}
# endif // HAS_DLL_BLOCKLIST
// Inherit the initial client channel handle into the child process.
std::wstring processChannelID =
std::to_wstring(uint32_t(uintptr_t(mClientChannelHandle.get())));
mLaunchOptions->handles_to_inherit.push_back(mClientChannelHandle.get());
mCmdLine->AppendSwitchWithValue(switches::kProcessChannelID,
processChannelID);
for (std::vector<std::string>::iterator it = mExtraOpts.begin();
it != mExtraOpts.end(); ++it) {
mCmdLine->AppendLooseValue(UTF8ToWide(*it));
}
# if defined(MOZ_SANDBOX)
# if defined(_ARM64_)
if (useRemoteSandboxBroker)
mResults.mSandboxBroker = new RemoteSandboxBroker(mLaunchArch);
else
# endif // if defined(_ARM64_)
mResults.mSandboxBroker = new SandboxBroker();
// sandboxing in this class at some point. Unfortunately it will take a bit
// of reorganizing so I don't think this patch is the right time.
switch (mProcessType) {
case GeckoProcessType_Content:
if (mSandboxLevel > 0) {
// For now we treat every failure as fatal in
// SetSecurityLevelForContentProcess and just crash there right away.
// Should this change in the future then we should also handle the error
// here.
mResults.mSandboxBroker->SetSecurityLevelForContentProcess(
mSandboxLevel, mIsFileContent);
mUseSandbox = true;
}
break;
case GeckoProcessType_IPDLUnitTest:
// XXX: We don't sandbox this process type yet
break;
case GeckoProcessType_GMPlugin:
if (!PR_GetEnv("MOZ_DISABLE_GMP_SANDBOX")) {
// The Widevine CDM on Windows can only load at USER_RESTRICTED,
// not at USER_LOCKDOWN. So look in the command line arguments
// to see if we're loading the path to the Widevine CDM, and if
// so use sandbox level USER_RESTRICTED instead of USER_LOCKDOWN.
auto level =
isWidevine ? SandboxBroker::Restricted : SandboxBroker::LockDown;
if (NS_WARN_IF(
!mResults.mSandboxBroker->SetSecurityLevelForGMPlugin(level))) {
return Err(LaunchError("SetSecurityLevelForGMPlugin"));
}
mUseSandbox = true;
}
break;
case GeckoProcessType_GPU:
if (mSandboxLevel > 0 && !PR_GetEnv("MOZ_DISABLE_GPU_SANDBOX")) {
// For now we treat every failure as fatal in
// SetSecurityLevelForGPUProcess and just crash there right away. Should
// this change in the future then we should also handle the error here.
mResults.mSandboxBroker->SetSecurityLevelForGPUProcess(mSandboxLevel);
mUseSandbox = true;
}
break;
case GeckoProcessType_VR:
if (mSandboxLevel > 0 && !PR_GetEnv("MOZ_DISABLE_VR_SANDBOX")) {
}
break;
case GeckoProcessType_RDD:
if (!PR_GetEnv("MOZ_DISABLE_RDD_SANDBOX")) {
if (NS_WARN_IF(
!mResults.mSandboxBroker->SetSecurityLevelForRDDProcess())) {
return Err(LaunchError("SetSecurityLevelForRDDProcess"));
}
mUseSandbox = true;
}
break;
case GeckoProcessType_Socket:
if (!PR_GetEnv("MOZ_DISABLE_SOCKET_PROCESS_SANDBOX")) {
if (NS_WARN_IF(
!mResults.mSandboxBroker->SetSecurityLevelForSocketProcess())) {
return Err(LaunchError("SetSecurityLevelForSocketProcess"));
}
mUseSandbox = true;
}
break;
case GeckoProcessType_Utility:
if (IsUtilitySandboxEnabled(mSandbox)) {
if (!mResults.mSandboxBroker->SetSecurityLevelForUtilityProcess(
mSandbox)) {
return Err(LaunchError("SetSecurityLevelForUtilityProcess"));
}
mUseSandbox = true;
}
break;
case GeckoProcessType_RemoteSandboxBroker:
// We don't sandbox the sandbox launcher...
break;
case GeckoProcessType_Default:
default:
MOZ_CRASH("Bad process type in GeckoChildProcessHost");
break;
};
if (mUseSandbox) {
for (auto it = mAllowedFilesRead.begin(); it != mAllowedFilesRead.end();
++it) {
mResults.mSandboxBroker->AllowReadFile(it->c_str());
}
if (mResults.mSandboxBroker->IsWin32kLockedDown()) {
mCmdLine->AppendLooseValue(
UTF8ToWide(geckoargs::sWin32kLockedDown.Name()));
}
}
# endif // defined(MOZ_SANDBOX)
// Add the application directory path (-appdir path)
AddAppDirToCommandLine(mCmdLine.ref(), mAppDir);
// XXX Command line params past this point are expected to be at
// the end of the command line string, and in a specific order.
// See XRE_InitChildProcess in nsEmbedFunction.
// Win app model id
mCmdLine->AppendLooseValue(mGroupId.get());
// Initial MessageChannel id
mCmdLine->AppendLooseValue(UTF8ToWide(mInitialChannelIdString));
// Process id
mCmdLine->AppendLooseValue(UTF8ToWide(mPidString));
mCmdLine->AppendLooseValue(
UTF8ToWide(CrashReporter::GetChildNotificationPipe()));
// Process type
mCmdLine->AppendLooseValue(UTF8ToWide(ChildProcessType()));
// Prefetch cache hint
AddApplicationPrefetchArgument();
# ifdef MOZ_SANDBOX
if (mUseSandbox) {
// Mark the handles to inherit as inheritable.
for (HANDLE h : mLaunchOptions->handles_to_inherit) {
mResults.mSandboxBroker->AddHandleToShare(h);
}
}
# endif // MOZ_SANDBOX
return Ok();
}
RefPtr<ProcessHandlePromise> WindowsProcessLauncher::DoLaunch() {
ProcessHandle handle = 0;
# ifdef MOZ_SANDBOX
if (mUseSandbox) {
const IMAGE_THUNK_DATA* cachedNtdllThunk =
mCachedNtdllThunk ? mCachedNtdllThunk->begin() : nullptr;
Result<Ok, LaunchError> err = mResults.mSandboxBroker->LaunchApp(
mCmdLine->program().c_str(), mCmdLine->command_line_string().c_str(),
mLaunchOptions->env_map, mProcessType, mEnableSandboxLogging,
cachedNtdllThunk, &handle);
if (err.isOk()) {
EnvironmentLog("MOZ_PROCESS_LOG")
.print("==> process %d launched child process %d (%S)\n",
base::GetCurrentProcId(), base::GetProcId(handle),
mCmdLine->command_line_string().c_str());
return ProcessHandlePromise::CreateAndResolve(handle, __func__);
}
return ProcessHandlePromise::CreateAndReject(err.unwrapErr(), __func__);
}
# endif // defined(MOZ_SANDBOX)
Result<Ok, LaunchError> launchErr =
base::LaunchApp(mCmdLine.ref(), *mLaunchOptions, &handle);
if (launchErr.isErr()) {
return ProcessHandlePromise::CreateAndReject(launchErr.unwrapErr(),
__func__);
}
return ProcessHandlePromise::CreateAndResolve(handle, __func__);
}
Result<Ok, LaunchError> WindowsProcessLauncher::DoFinishLaunch() {
Result<Ok, LaunchError> err = BaseProcessLauncher::DoFinishLaunch();
if (err.isErr()) {
return err;
}
return Ok();
}
#endif // XP_WIN
RefPtr<ProcessLaunchPromise> BaseProcessLauncher::FinishLaunch() {
Result<Ok, LaunchError> aError = DoFinishLaunch();
if (aError.isErr()) {
return ProcessLaunchPromise::CreateAndReject(aError.unwrapErr(), __func__);
}
MOZ_DIAGNOSTIC_ASSERT(mResults.mHandle);
Telemetry::AccumulateTimeDelta(Telemetry::CHILD_PROCESS_LAUNCH_MS,
mStartTimeStamp);
return ProcessLaunchPromise::CreateAndResolve(std::move(mResults), __func__);
}
bool GeckoChildProcessHost::OpenPrivilegedHandle(base::ProcessId aPid) {
if (mChildProcessHandle) {
MOZ_ASSERT(aPid == base::GetProcId(mChildProcessHandle));
return true;
}
return base::OpenPrivilegedProcessHandle(aPid, &mChildProcessHandle);
}
void GeckoChildProcessHost::OnChannelConnected(base::ProcessId peer_pid) {
{
mozilla::AutoWriteLock hLock(mHandleLock);
if (!OpenPrivilegedHandle(peer_pid)) {
MOZ_CRASH("can't open handle to child process");
}
}
MonitorAutoLock lock(mMonitor);
mProcessState = PROCESS_CONNECTED;
lock.Notify();
}
RefPtr<ProcessHandlePromise> GeckoChildProcessHost::WhenProcessHandleReady() {
MOZ_ASSERT(mHandlePromise != nullptr);
return mHandlePromise;
}
#ifdef MOZ_WIDGET_ANDROID
RefPtr<ProcessHandlePromise> AndroidProcessLauncher::LaunchAndroidService(
const GeckoProcessType aType, const std::vector<std::string>& argv,
const base::file_handle_mapping_vector& fds_to_remap) {
MOZ_RELEASE_ASSERT((2 <= fds_to_remap.size()) && (fds_to_remap.size() <= 5));
JNIEnv* const env = mozilla::jni::GetEnvForThread();
MOZ_ASSERT(env);
const int argvSize = argv.size();
jni::ObjectArray::LocalRef jargs =
jni::ObjectArray::New<jni::String>(argvSize);
for (int ix = 0; ix < argvSize; ix++) {
jargs->SetElement(ix, jni::StringParam(argv[ix].c_str(), env));
}
// XXX: this processing depends entirely on the internals of
// ContentParent::LaunchSubprocess()
// GeckoChildProcessHost::PerformAsyncLaunch(), and the order in
// which they append to fds_to_remap. There must be a better way to do it.
int32_t prefsFd = fds_to_remap[0].first;
int32_t prefMapFd = fds_to_remap[1].first;
int32_t ipcFd = fds_to_remap[2].first;
int32_t crashFd = -1;
if (fds_to_remap.size() == 4) {
crashFd = fds_to_remap[3].first;
}
auto type = java::GeckoProcessType::FromInt(aType);
auto genericResult = java::GeckoProcessManager::Start(
type, jargs, prefsFd, prefMapFd, ipcFd, crashFd);
auto typedResult = java::GeckoResult::LocalRef(std::move(genericResult));
return ProcessHandlePromise::FromGeckoResult(typedResult);
}
#endif
#if defined(XP_MACOSX) && defined(MOZ_SANDBOX)
bool GeckoChildProcessHost::AppendMacSandboxParams(StringVector& aArgs) {
MacSandboxInfo info;
if (NS_WARN_IF(!FillMacSandboxInfo(info))) {
return false;
}
info.AppendAsParams(aArgs);
return true;
}
// Fill |aInfo| with the flags needed to launch the utility sandbox
bool GeckoChildProcessHost::FillMacSandboxInfo(MacSandboxInfo& aInfo) {
aInfo.type = GetDefaultMacSandboxType();
aInfo.shouldLog = Preferences::GetBool("security.sandbox.logging.enabled") ||
PR_GetEnv("MOZ_SANDBOX_LOGGING");
nsAutoCString appPath;
if (!nsMacUtilsImpl::GetAppPath(appPath)) {
MOZ_CRASH("Failed to get app path");
}
aInfo.appPath.assign(appPath.get());
return true;
}
void GeckoChildProcessHost::DisableOSActivityMode() {
mDisableOSActivityMode = true;
}
//
// If early sandbox startup is enabled for this process type, map the
// process type to the sandbox type and enable the sandbox. Returns true
// if no errors were encountered or if early sandbox startup is not
// enabled for this process. Returns false if an error was encountered.
//
/* static */
bool GeckoChildProcessHost::StartMacSandbox(int aArgc, char** aArgv,
std::string& aErrorMessage) {
MacSandboxType sandboxType = MacSandboxType_Invalid;
switch (XRE_GetProcessType()) {
// For now, only support early sandbox startup for content,
// RDD, and GMP processes. Add case statements for the additional
// process types once early sandbox startup is implemented for them.
case GeckoProcessType_Content:
// Content processes don't use GeckoChildProcessHost
// to configure sandboxing so hard code the sandbox type.
sandboxType = MacSandboxType_Content;
break;
case GeckoProcessType_RDD:
sandboxType = RDDProcessHost::GetMacSandboxType();
break;
case GeckoProcessType_Socket:
sandboxType = net::SocketProcessHost::GetMacSandboxType();
break;
case GeckoProcessType_GMPlugin:
sandboxType = gmp::GMPProcessParent::GetMacSandboxType();
break;
case GeckoProcessType_Utility:
sandboxType = ipc::UtilityProcessHost::GetMacSandboxType();
break;
default:
return true;
}
return mozilla::StartMacSandboxIfEnabled(sandboxType, aArgc, aArgv,
aErrorMessage);
}
#endif /* XP_MACOSX && MOZ_SANDBOX */
/* static */
void GeckoChildProcessHost::GetAll(const GeckoProcessCallback& aCallback) {
StaticMutexAutoLock lock(sMutex);
if (!sGeckoChildProcessHosts) {
return;
}
for (GeckoChildProcessHost* gp = sGeckoChildProcessHosts->getFirst(); gp;
gp = static_cast<mozilla::LinkedListElement<GeckoChildProcessHost>*>(gp)
->getNext()) {
aCallback(gp);
}
}
RefPtr<ProcessLaunchPromise> BaseProcessLauncher::Launch(
GeckoChildProcessHost* aHost) {
AssertIOThread();
// The ForkServer doesn't use IPC::Channel for communication, so we can skip
// initializing it.
if (mProcessType != GeckoProcessType_ForkServer) {
IPC::Channel::ChannelHandle serverHandle;
if (!IPC::Channel::CreateRawPipe(&serverHandle, &mClientChannelHandle)) {
return ProcessLaunchPromise::CreateAndReject(LaunchError("CreateRawPipe"),
__func__);
}
aHost->InitializeChannel(std::move(serverHandle));
}
return InvokeAsync(mLaunchThread, this, __func__,
&BaseProcessLauncher::PerformAsyncLaunch);
}
} // namespace ipc
} // namespace mozilla