gecko/toolkit/components/downloads/nsDownloadScanner.cpp
Jacek Caban 27a3029fcd Bug 944913 - Fixed char16_t/wchar_t mismatch in tollkit/. r=ehsan
--HG--
extra : rebase_source : c33427dd7c1c2db3d2741b8c2e0d1b4a0359a0a4
2013-12-03 16:07:22 +01:00

728 lines
23 KiB
C++

/* -*- Mode: C++; tab-width: 4; indent-tabs-mode: nil; c-basic-offset: 2 -*- */
/* vim: se cin sw=2 ts=2 et : */
/* 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
* file, You can obtain one at http://mozilla.org/MPL/2.0/. */
#include "nsDownloadScanner.h"
#include <comcat.h>
#include <process.h>
#include "nsDownloadManager.h"
#include "nsIXULAppInfo.h"
#include "nsXULAppAPI.h"
#include "nsIPrefService.h"
#include "nsNetUtil.h"
#include "nsDeque.h"
#include "nsIFileURL.h"
#include "nsIPrefBranch.h"
#include "nsXPCOMCIDInternal.h"
/**
* Code overview
*
* Download scanner attempts to make use of one of two different virus
* scanning interfaces available on Windows - IOfficeAntiVirus (Windows
* 95/NT 4 and IE 5) and IAttachmentExecute (XPSP2 and up). The latter
* interface supports calling IOfficeAntiVirus internally, while also
* adding support for XPSP2+ ADS forks which define security related
* prompting on downloaded content.
*
* Both interfaces are synchronous and can take a while, so it is not a
* good idea to call either from the main thread. Some antivirus scanners can
* take a long time to scan or the call might block while the scanner shows
* its UI so if the user were to download many files that finished around the
* same time, they would have to wait a while if the scanning were done on
* exactly one other thread. Since the overhead of creating a thread is
* relatively small compared to the time it takes to download a file and scan
* it, a new thread is spawned for each download that is to be scanned. Since
* most of the mozilla codebase is not threadsafe, all the information needed
* for the scanner is gathered in the main thread in nsDownloadScanner::Scan::Start.
* The only function of nsDownloadScanner::Scan which is invoked on another
* thread is DoScan.
*
* Watchdog overview
*
* The watchdog is used internally by the scanner. It maintains a queue of
* current download scans. In a separate thread, it dequeues the oldest scan
* and waits on that scan's thread with a timeout given by WATCHDOG_TIMEOUT
* (default is 30 seconds). If the wait times out, then the watchdog notifies
* the Scan that it has timed out. If the scan really has timed out, then the
* Scan object will dispatch its run method to the main thread; this will
* release the watchdog thread's addref on the Scan. If it has not timed out
* (i.e. the Scan just finished in time), then the watchdog dispatches a
* ReleaseDispatcher to release its ref of the Scan on the main thread.
*
* In order to minimize execution time, there are two events used to notify the
* watchdog thread of a non-empty queue and a quit event. Every blocking wait
* that the watchdog thread does waits on the quit event; this lets the thread
* quickly exit when shutting down. Also, the download scan queue will be empty
* most of the time; rather than use a spin loop, a simple event is triggered
* by the main thread when a new scan is added to an empty queue. When the
* watchdog thread knows that it has run out of elements in the queue, it will
* wait on the new item event.
*
* Memory/resource leaks due to timeout:
* In the event of a timeout, the thread must remain alive; terminating it may
* very well cause the antivirus scanner to crash or be put into an
* inconsistent state; COM resources may also not be cleaned up. The downside
* is that we need to leave the thread running; suspending it may lead to a
* deadlock. Because the scan call may be ongoing, it may be dependent on the
* memory referenced by the MSOAVINFO structure, so we cannot free mName, mPath
* or mOrigin; this means that we cannot free the Scan object since doing so
* will deallocate that memory. Note that mDownload is set to null upon timeout
* or completion, so the download itself is never leaked. If the scan does
* eventually complete, then the all the memory and resources will be freed.
* It is possible, however extremely rare, that in the event of a timeout, the
* mStateSync critical section will leak its event; this will happen only if
* the scanning thread, watchdog thread or main thread try to enter the
* critical section when one of the others is already in it.
*
* Reasoning for CheckAndSetState - there exists a race condition between the time when
* either the timeout or normal scan sets the state and when Scan::Run is
* executed on the main thread. Ex: mStatus could be set by Scan::DoScan* which
* then queues a dispatch on the main thread. Before that dispatch is executed,
* the timeout code fires and sets mStatus to AVSCAN_TIMEDOUT which then queues
* its dispatch to the main thread (the same function as DoScan*). Both
* dispatches run and both try to set the download state to AVSCAN_TIMEDOUT
* which is incorrect.
*
* There are 5 possible outcomes of the virus scan:
* AVSCAN_GOOD => the file is clean
* AVSCAN_BAD => the file has a virus
* AVSCAN_UGLY => the file had a virus, but it was cleaned
* AVSCAN_FAILED => something else went wrong with the virus scanner.
* AVSCAN_TIMEDOUT => the scan (thread setup + execution) took too long
*
* Both the good and ugly states leave the user with a benign file, so they
* transition to the finished state. Bad files are sent to the blocked state.
* The failed and timedout states transition to finished downloads.
*
* Possible Future enhancements:
* * Create an interface for scanning files in general
* * Make this a service
* * Get antivirus scanner status via WMI/registry
*/
// IAttachementExecute supports user definable settings for certain
// security related prompts. This defines a general GUID for use in
// all projects. Individual projects can define an individual guid
// if they want to.
#ifndef MOZ_VIRUS_SCANNER_PROMPT_GUID
#define MOZ_VIRUS_SCANNER_PROMPT_GUID \
{ 0xb50563d1, 0x16b6, 0x43c2, { 0xa6, 0x6a, 0xfa, 0xe6, 0xd2, 0x11, 0xf2, \
0xea } }
#endif
static const GUID GUID_MozillaVirusScannerPromptGeneric =
MOZ_VIRUS_SCANNER_PROMPT_GUID;
// Initial timeout is 30 seconds
#define WATCHDOG_TIMEOUT (30*PR_USEC_PER_SEC)
// Maximum length for URI's passed into IAE
#define MAX_IAEURILENGTH 1683
class nsDownloadScannerWatchdog
{
typedef nsDownloadScanner::Scan Scan;
public:
nsDownloadScannerWatchdog();
~nsDownloadScannerWatchdog();
nsresult Init();
nsresult Shutdown();
void Watch(Scan *scan);
private:
static unsigned int __stdcall WatchdogThread(void *p);
CRITICAL_SECTION mQueueSync;
nsDeque mScanQueue;
HANDLE mThread;
HANDLE mNewItemEvent;
HANDLE mQuitEvent;
};
nsDownloadScanner::nsDownloadScanner() :
mAESExists(false)
{
}
// This destructor appeases the compiler; it would otherwise complain about an
// incomplete type for nsDownloadWatchdog in the instantiation of
// nsAutoPtr::~nsAutoPtr
// Plus, it's a handy location to call nsDownloadScannerWatchdog::Shutdown from
nsDownloadScanner::~nsDownloadScanner() {
if (mWatchdog)
(void)mWatchdog->Shutdown();
}
nsresult
nsDownloadScanner::Init()
{
// This CoInitialize/CoUninitialize pattern seems to be common in the Mozilla
// codebase. All other COM calls/objects are made on different threads.
nsresult rv = NS_OK;
CoInitialize(nullptr);
if (!IsAESAvailable()) {
CoUninitialize();
return NS_ERROR_NOT_AVAILABLE;
}
mAESExists = true;
// Initialize scanning
mWatchdog = new nsDownloadScannerWatchdog();
if (mWatchdog) {
rv = mWatchdog->Init();
if (FAILED(rv))
mWatchdog = nullptr;
} else {
rv = NS_ERROR_OUT_OF_MEMORY;
}
if (NS_FAILED(rv))
return rv;
return rv;
}
bool
nsDownloadScanner::IsAESAvailable()
{
// Try to instantiate IAE to see if it's available.
nsRefPtr<IAttachmentExecute> ae;
HRESULT hr;
hr = CoCreateInstance(CLSID_AttachmentServices, nullptr, CLSCTX_INPROC,
IID_IAttachmentExecute, getter_AddRefs(ae));
if (FAILED(hr)) {
NS_WARNING("Could not instantiate attachment execution service\n");
return false;
}
return true;
}
// If IAttachementExecute is available, use the CheckPolicy call to find out
// if this download should be prevented due to Security Zone Policy settings.
AVCheckPolicyState
nsDownloadScanner::CheckPolicy(nsIURI *aSource, nsIURI *aTarget)
{
nsresult rv;
if (!mAESExists || !aSource || !aTarget)
return AVPOLICY_DOWNLOAD;
nsAutoCString source;
rv = aSource->GetSpec(source);
if (NS_FAILED(rv))
return AVPOLICY_DOWNLOAD;
nsCOMPtr<nsIFileURL> fileUrl(do_QueryInterface(aTarget));
if (!fileUrl)
return AVPOLICY_DOWNLOAD;
nsCOMPtr<nsIFile> theFile;
nsAutoString aFileName;
if (NS_FAILED(fileUrl->GetFile(getter_AddRefs(theFile))) ||
NS_FAILED(theFile->GetLeafName(aFileName)))
return AVPOLICY_DOWNLOAD;
// IAttachementExecute prohibits src data: schemes by default but we
// support them. If this is a data src, skip off doing a policy check.
// (The file will still be scanned once it lands on the local system.)
bool isDataScheme(false);
nsCOMPtr<nsIURI> innerURI = NS_GetInnermostURI(aSource);
if (innerURI)
(void)innerURI->SchemeIs("data", &isDataScheme);
if (isDataScheme)
return AVPOLICY_DOWNLOAD;
nsRefPtr<IAttachmentExecute> ae;
HRESULT hr;
hr = CoCreateInstance(CLSID_AttachmentServices, nullptr, CLSCTX_INPROC,
IID_IAttachmentExecute, getter_AddRefs(ae));
if (FAILED(hr))
return AVPOLICY_DOWNLOAD;
(void)ae->SetClientGuid(GUID_MozillaVirusScannerPromptGeneric);
(void)ae->SetSource(NS_ConvertUTF8toUTF16(source).get());
(void)ae->SetFileName(aFileName.get());
// Any failure means the file download/exec will be blocked by the system.
// S_OK or S_FALSE imply it's ok.
hr = ae->CheckPolicy();
if (hr == S_OK)
return AVPOLICY_DOWNLOAD;
if (hr == S_FALSE)
return AVPOLICY_PROMPT;
if (hr == E_INVALIDARG)
return AVPOLICY_PROMPT;
return AVPOLICY_BLOCKED;
}
#ifndef THREAD_MODE_BACKGROUND_BEGIN
#define THREAD_MODE_BACKGROUND_BEGIN 0x00010000
#endif
#ifndef THREAD_MODE_BACKGROUND_END
#define THREAD_MODE_BACKGROUND_END 0x00020000
#endif
unsigned int __stdcall
nsDownloadScanner::ScannerThreadFunction(void *p)
{
HANDLE currentThread = GetCurrentThread();
NS_ASSERTION(!NS_IsMainThread(), "Antivirus scan should not be run on the main thread");
nsDownloadScanner::Scan *scan = static_cast<nsDownloadScanner::Scan*>(p);
if (!SetThreadPriority(currentThread, THREAD_MODE_BACKGROUND_BEGIN))
(void)SetThreadPriority(currentThread, THREAD_PRIORITY_IDLE);
scan->DoScan();
(void)SetThreadPriority(currentThread, THREAD_MODE_BACKGROUND_END);
_endthreadex(0);
return 0;
}
// The sole purpose of this class is to release an object on the main thread
// It assumes that its creator will addref it and it will release itself on
// the main thread too
class ReleaseDispatcher : public nsRunnable {
public:
ReleaseDispatcher(nsISupports *ptr)
: mPtr(ptr) {}
NS_IMETHOD Run();
private:
nsISupports *mPtr;
};
nsresult ReleaseDispatcher::Run() {
NS_ASSERTION(NS_IsMainThread(), "Antivirus scan release dispatch should be run on the main thread");
NS_RELEASE(mPtr);
NS_RELEASE_THIS();
return NS_OK;
}
nsDownloadScanner::Scan::Scan(nsDownloadScanner *scanner, nsDownload *download)
: mDLScanner(scanner), mThread(nullptr),
mDownload(download), mStatus(AVSCAN_NOTSTARTED),
mSkipSource(false)
{
InitializeCriticalSection(&mStateSync);
}
nsDownloadScanner::Scan::~Scan() {
DeleteCriticalSection(&mStateSync);
}
nsresult
nsDownloadScanner::Scan::Start()
{
mStartTime = PR_Now();
mThread = (HANDLE)_beginthreadex(nullptr, 0, ScannerThreadFunction,
this, CREATE_SUSPENDED, nullptr);
if (!mThread)
return NS_ERROR_OUT_OF_MEMORY;
nsresult rv = NS_OK;
// Get the path to the file on disk
nsCOMPtr<nsIFile> file;
rv = mDownload->GetTargetFile(getter_AddRefs(file));
NS_ENSURE_SUCCESS(rv, rv);
rv = file->GetPath(mPath);
NS_ENSURE_SUCCESS(rv, rv);
// Grab the app name
nsCOMPtr<nsIXULAppInfo> appinfo =
do_GetService(XULAPPINFO_SERVICE_CONTRACTID, &rv);
NS_ENSURE_SUCCESS(rv, rv);
nsAutoCString name;
rv = appinfo->GetName(name);
NS_ENSURE_SUCCESS(rv, rv);
CopyUTF8toUTF16(name, mName);
// Get the origin
nsCOMPtr<nsIURI> uri;
rv = mDownload->GetSource(getter_AddRefs(uri));
NS_ENSURE_SUCCESS(rv, rv);
nsAutoCString origin;
rv = uri->GetSpec(origin);
NS_ENSURE_SUCCESS(rv, rv);
// Certain virus interfaces do not like extremely long uris.
// Chop off the path and cgi data and just pass the base domain.
if (origin.Length() > MAX_IAEURILENGTH) {
rv = uri->GetPrePath(origin);
NS_ENSURE_SUCCESS(rv, rv);
}
CopyUTF8toUTF16(origin, mOrigin);
// We count https/ftp/http as an http download
bool isHttp(false), isFtp(false), isHttps(false);
nsCOMPtr<nsIURI> innerURI = NS_GetInnermostURI(uri);
if (!innerURI) innerURI = uri;
(void)innerURI->SchemeIs("http", &isHttp);
(void)innerURI->SchemeIs("ftp", &isFtp);
(void)innerURI->SchemeIs("https", &isHttps);
mIsHttpDownload = isHttp || isFtp || isHttps;
// IAttachementExecute prohibits src data: schemes by default but we
// support them. Mark the download if it's a data scheme, so we
// can skip off supplying the src to IAttachementExecute when we scan
// the resulting file.
(void)innerURI->SchemeIs("data", &mSkipSource);
// ResumeThread returns the previous suspend count
if (1 != ::ResumeThread(mThread)) {
CloseHandle(mThread);
return NS_ERROR_UNEXPECTED;
}
return NS_OK;
}
nsresult
nsDownloadScanner::Scan::Run()
{
NS_ASSERTION(NS_IsMainThread(), "Antivirus scan dispatch should be run on the main thread");
// Cleanup our thread
if (mStatus != AVSCAN_TIMEDOUT)
WaitForSingleObject(mThread, INFINITE);
CloseHandle(mThread);
DownloadState downloadState = 0;
EnterCriticalSection(&mStateSync);
switch (mStatus) {
case AVSCAN_BAD:
downloadState = nsIDownloadManager::DOWNLOAD_DIRTY;
break;
default:
case AVSCAN_FAILED:
case AVSCAN_GOOD:
case AVSCAN_UGLY:
case AVSCAN_TIMEDOUT:
downloadState = nsIDownloadManager::DOWNLOAD_FINISHED;
break;
}
LeaveCriticalSection(&mStateSync);
// Download will be null if we already timed out
if (mDownload)
(void)mDownload->SetState(downloadState);
// Clean up some other variables
// In the event of a timeout, our destructor won't be called
mDownload = nullptr;
NS_RELEASE_THIS();
return NS_OK;
}
static DWORD
ExceptionFilterFunction(DWORD exceptionCode) {
switch(exceptionCode) {
case EXCEPTION_ACCESS_VIOLATION:
case EXCEPTION_ILLEGAL_INSTRUCTION:
case EXCEPTION_IN_PAGE_ERROR:
case EXCEPTION_PRIV_INSTRUCTION:
case EXCEPTION_STACK_OVERFLOW:
return EXCEPTION_EXECUTE_HANDLER;
default:
return EXCEPTION_CONTINUE_SEARCH;
}
}
bool
nsDownloadScanner::Scan::DoScanAES()
{
// This warning is for the destructor of ae which will not be invoked in the
// event of a win32 exception
#pragma warning(disable: 4509)
HRESULT hr;
nsRefPtr<IAttachmentExecute> ae;
MOZ_SEH_TRY {
hr = CoCreateInstance(CLSID_AttachmentServices, nullptr, CLSCTX_ALL,
IID_IAttachmentExecute, getter_AddRefs(ae));
} MOZ_SEH_EXCEPT(ExceptionFilterFunction(GetExceptionCode())) {
return CheckAndSetState(AVSCAN_NOTSTARTED,AVSCAN_FAILED);
}
// If we (somehow) already timed out, then don't bother scanning
if (CheckAndSetState(AVSCAN_SCANNING, AVSCAN_NOTSTARTED)) {
AVScanState newState;
if (SUCCEEDED(hr)) {
bool gotException = false;
MOZ_SEH_TRY {
(void)ae->SetClientGuid(GUID_MozillaVirusScannerPromptGeneric);
(void)ae->SetLocalPath(mPath.get());
// Provide the src for everything but data: schemes.
if (!mSkipSource)
(void)ae->SetSource(mOrigin.get());
// Save() will invoke the scanner
hr = ae->Save();
} MOZ_SEH_EXCEPT(ExceptionFilterFunction(GetExceptionCode())) {
gotException = true;
}
MOZ_SEH_TRY {
ae = nullptr;
} MOZ_SEH_EXCEPT(ExceptionFilterFunction(GetExceptionCode())) {
gotException = true;
}
if(gotException) {
newState = AVSCAN_FAILED;
}
else if (SUCCEEDED(hr)) { // Passed the scan
newState = AVSCAN_GOOD;
}
else if (HRESULT_CODE(hr) == ERROR_FILE_NOT_FOUND) {
NS_WARNING("Downloaded file disappeared before it could be scanned");
newState = AVSCAN_FAILED;
}
else if (hr == E_INVALIDARG) {
NS_WARNING("IAttachementExecute returned invalid argument error");
newState = AVSCAN_FAILED;
}
else {
newState = AVSCAN_UGLY;
}
}
else {
newState = AVSCAN_FAILED;
}
return CheckAndSetState(newState, AVSCAN_SCANNING);
}
return false;
}
#pragma warning(default: 4509)
void
nsDownloadScanner::Scan::DoScan()
{
CoInitialize(nullptr);
if (DoScanAES()) {
// We need to do a few more things on the main thread
NS_DispatchToMainThread(this);
} else {
// We timed out, so just release
ReleaseDispatcher* releaser = new ReleaseDispatcher(this);
if(releaser) {
NS_ADDREF(releaser);
NS_DispatchToMainThread(releaser);
}
}
MOZ_SEH_TRY {
CoUninitialize();
} MOZ_SEH_EXCEPT(ExceptionFilterFunction(GetExceptionCode())) {
// Not much we can do at this point...
}
}
HANDLE
nsDownloadScanner::Scan::GetWaitableThreadHandle() const
{
HANDLE targetHandle = INVALID_HANDLE_VALUE;
(void)DuplicateHandle(GetCurrentProcess(), mThread,
GetCurrentProcess(), &targetHandle,
SYNCHRONIZE, // Only allow clients to wait on this handle
FALSE, // cannot be inherited by child processes
0);
return targetHandle;
}
bool
nsDownloadScanner::Scan::NotifyTimeout()
{
bool didTimeout = CheckAndSetState(AVSCAN_TIMEDOUT, AVSCAN_SCANNING) ||
CheckAndSetState(AVSCAN_TIMEDOUT, AVSCAN_NOTSTARTED);
if (didTimeout) {
// We need to do a few more things on the main thread
NS_DispatchToMainThread(this);
}
return didTimeout;
}
bool
nsDownloadScanner::Scan::CheckAndSetState(AVScanState newState, AVScanState expectedState) {
bool gotExpectedState = false;
EnterCriticalSection(&mStateSync);
if(gotExpectedState = (mStatus == expectedState))
mStatus = newState;
LeaveCriticalSection(&mStateSync);
return gotExpectedState;
}
nsresult
nsDownloadScanner::ScanDownload(nsDownload *download)
{
if (!mAESExists)
return NS_ERROR_NOT_AVAILABLE;
// No ref ptr, see comment below
Scan *scan = new Scan(this, download);
if (!scan)
return NS_ERROR_OUT_OF_MEMORY;
NS_ADDREF(scan);
nsresult rv = scan->Start();
// Note that we only release upon error. On success, the scan is passed off
// to a new thread. It is eventually released in Scan::Run on the main thread.
if (NS_FAILED(rv))
NS_RELEASE(scan);
else
// Notify the watchdog
mWatchdog->Watch(scan);
return rv;
}
nsDownloadScannerWatchdog::nsDownloadScannerWatchdog()
: mNewItemEvent(nullptr), mQuitEvent(nullptr) {
InitializeCriticalSection(&mQueueSync);
}
nsDownloadScannerWatchdog::~nsDownloadScannerWatchdog() {
DeleteCriticalSection(&mQueueSync);
}
nsresult
nsDownloadScannerWatchdog::Init() {
// Both events are auto-reset
mNewItemEvent = CreateEvent(nullptr, FALSE, FALSE, nullptr);
if (INVALID_HANDLE_VALUE == mNewItemEvent)
return NS_ERROR_OUT_OF_MEMORY;
mQuitEvent = CreateEvent(nullptr, FALSE, FALSE, nullptr);
if (INVALID_HANDLE_VALUE == mQuitEvent) {
(void)CloseHandle(mNewItemEvent);
return NS_ERROR_OUT_OF_MEMORY;
}
// This thread is always running, however it will be asleep
// for most of the dlmgr's lifetime
mThread = (HANDLE)_beginthreadex(nullptr, 0, WatchdogThread,
this, 0, nullptr);
if (!mThread) {
(void)CloseHandle(mNewItemEvent);
(void)CloseHandle(mQuitEvent);
return NS_ERROR_OUT_OF_MEMORY;
}
return NS_OK;
}
nsresult
nsDownloadScannerWatchdog::Shutdown() {
// Tell the watchdog thread to quite
(void)SetEvent(mQuitEvent);
(void)WaitForSingleObject(mThread, INFINITE);
(void)CloseHandle(mThread);
// Manually clear and release the queued scans
while (mScanQueue.GetSize() != 0) {
Scan *scan = reinterpret_cast<Scan*>(mScanQueue.Pop());
NS_RELEASE(scan);
}
(void)CloseHandle(mNewItemEvent);
(void)CloseHandle(mQuitEvent);
return NS_OK;
}
void
nsDownloadScannerWatchdog::Watch(Scan *scan) {
bool wasEmpty;
// Note that there is no release in this method
// The scan will be released by the watchdog ALWAYS on the main thread
// when either the watchdog thread processes the scan or the watchdog
// is shut down
NS_ADDREF(scan);
EnterCriticalSection(&mQueueSync);
wasEmpty = mScanQueue.GetSize()==0;
mScanQueue.Push(scan);
LeaveCriticalSection(&mQueueSync);
// If the queue was empty, then the watchdog thread is/will be asleep
if (wasEmpty)
(void)SetEvent(mNewItemEvent);
}
unsigned int
__stdcall
nsDownloadScannerWatchdog::WatchdogThread(void *p) {
NS_ASSERTION(!NS_IsMainThread(), "Antivirus scan watchdog should not be run on the main thread");
nsDownloadScannerWatchdog *watchdog = (nsDownloadScannerWatchdog*)p;
HANDLE waitHandles[3] = {watchdog->mNewItemEvent, watchdog->mQuitEvent, INVALID_HANDLE_VALUE};
DWORD waitStatus;
DWORD queueItemsLeft = 0;
// Loop until quit event or error
while (0 != queueItemsLeft ||
(WAIT_OBJECT_0 + 1) !=
(waitStatus =
WaitForMultipleObjects(2, waitHandles, FALSE, INFINITE)) &&
waitStatus != WAIT_FAILED) {
Scan *scan = nullptr;
PRTime startTime, expectedEndTime, now;
DWORD waitTime;
// Pop scan from queue
EnterCriticalSection(&watchdog->mQueueSync);
scan = reinterpret_cast<Scan*>(watchdog->mScanQueue.Pop());
queueItemsLeft = watchdog->mScanQueue.GetSize();
LeaveCriticalSection(&watchdog->mQueueSync);
// Calculate expected end time
startTime = scan->GetStartTime();
expectedEndTime = WATCHDOG_TIMEOUT + startTime;
now = PR_Now();
// PRTime is not guaranteed to be a signed integral type (afaik), but
// currently it is
if (now > expectedEndTime) {
waitTime = 0;
} else {
// This is a positive value, and we know that it will not overflow
// (bounded by WATCHDOG_TIMEOUT)
// waitTime is in milliseconds, nspr uses microseconds
waitTime = static_cast<DWORD>((expectedEndTime - now)/PR_USEC_PER_MSEC);
}
HANDLE hThread = waitHandles[2] = scan->GetWaitableThreadHandle();
// Wait for the thread (obj 1) or quit event (obj 0)
waitStatus = WaitForMultipleObjects(2, (waitHandles+1), FALSE, waitTime);
CloseHandle(hThread);
ReleaseDispatcher* releaser = new ReleaseDispatcher(scan);
if(!releaser)
continue;
NS_ADDREF(releaser);
// Got quit event or error
if (waitStatus == WAIT_FAILED || waitStatus == WAIT_OBJECT_0) {
NS_DispatchToMainThread(releaser);
break;
// Thread exited normally
} else if (waitStatus == (WAIT_OBJECT_0+1)) {
NS_DispatchToMainThread(releaser);
continue;
// Timeout case
} else {
NS_ASSERTION(waitStatus == WAIT_TIMEOUT, "Unexpected wait status in dlmgr watchdog thread");
if (!scan->NotifyTimeout()) {
// If we didn't time out, then release the thread
NS_DispatchToMainThread(releaser);
} else {
// NotifyTimeout did a dispatch which will release the scan, so we
// don't need to release the scan
NS_RELEASE(releaser);
}
}
}
_endthreadex(0);
return 0;
}