gecko-dev/security/manager/ssl/nsNSSCallbacks.cpp

1285 строки
40 KiB
C++

/* -*- Mode: C++; tab-width: 2; indent-tabs-mode: nil; c-basic-offset: 2 -*-
*
* 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 "nsNSSCallbacks.h"
#include "pkix/pkixtypes.h"
#include "mozilla/Telemetry.h"
#include "mozilla/TimeStamp.h"
#include "nsNSSComponent.h"
#include "nsNSSIOLayer.h"
#include "nsIWebProgressListener.h"
#include "nsProtectedAuthThread.h"
#include "nsITokenDialogs.h"
#include "nsIUploadChannel.h"
#include "nsIPrompt.h"
#include "nsProxyRelease.h"
#include "PSMRunnable.h"
#include "nsContentUtils.h"
#include "nsIHttpChannelInternal.h"
#include "nsISupportsPriority.h"
#include "nsNetUtil.h"
#include "SharedSSLState.h"
#include "ssl.h"
#include "sslproto.h"
using namespace mozilla;
using namespace mozilla::psm;
extern PRLogModuleInfo* gPIPNSSLog;
static void AccumulateCipherSuite(Telemetry::ID probe,
const SSLChannelInfo& channelInfo);
namespace {
// Bits in bit mask for SSL_REASONS_FOR_NOT_FALSE_STARTING telemetry probe
// These bits are numbered so that the least subtle issues have higher values.
// This should make it easier for us to interpret the results.
const uint32_t NPN_NOT_NEGOTIATED = 64;
const uint32_t POSSIBLE_VERSION_DOWNGRADE = 4;
const uint32_t POSSIBLE_CIPHER_SUITE_DOWNGRADE = 2;
const uint32_t KEA_NOT_SUPPORTED = 1;
}
class nsHTTPDownloadEvent : public nsRunnable {
public:
nsHTTPDownloadEvent();
~nsHTTPDownloadEvent();
NS_IMETHOD Run();
nsNSSHttpRequestSession *mRequestSession;
nsRefPtr<nsHTTPListener> mListener;
bool mResponsibleForDoneSignal;
TimeStamp mStartTime;
};
nsHTTPDownloadEvent::nsHTTPDownloadEvent()
:mResponsibleForDoneSignal(true)
{
}
nsHTTPDownloadEvent::~nsHTTPDownloadEvent()
{
if (mResponsibleForDoneSignal && mListener)
mListener->send_done_signal();
mRequestSession->Release();
}
NS_IMETHODIMP
nsHTTPDownloadEvent::Run()
{
if (!mListener)
return NS_OK;
nsresult rv;
nsCOMPtr<nsIIOService> ios = do_GetIOService();
NS_ENSURE_STATE(ios);
nsCOMPtr<nsIChannel> chan;
ios->NewChannel2(mRequestSession->mURL,
nullptr,
nullptr,
nullptr, // aLoadingNode
nsContentUtils::GetSystemPrincipal(),
nullptr, // aTriggeringPrincipal
nsILoadInfo::SEC_NORMAL,
nsIContentPolicy::TYPE_OTHER,
getter_AddRefs(chan));
NS_ENSURE_STATE(chan);
// Security operations scheduled through normal HTTP channels are given
// high priority to accommodate real time OCSP transactions. Background CRL
// fetches happen through a different path (CRLDownloadEvent).
nsCOMPtr<nsISupportsPriority> priorityChannel = do_QueryInterface(chan);
if (priorityChannel)
priorityChannel->AdjustPriority(nsISupportsPriority::PRIORITY_HIGHEST);
chan->SetLoadFlags(nsIRequest::LOAD_ANONYMOUS);
// Create a loadgroup for this new channel. This way if the channel
// is redirected, we'll have a way to cancel the resulting channel.
nsCOMPtr<nsILoadGroup> lg = do_CreateInstance(NS_LOADGROUP_CONTRACTID);
chan->SetLoadGroup(lg);
if (mRequestSession->mHasPostData)
{
nsCOMPtr<nsIInputStream> uploadStream;
rv = NS_NewPostDataStream(getter_AddRefs(uploadStream),
false,
mRequestSession->mPostData);
NS_ENSURE_SUCCESS(rv, rv);
nsCOMPtr<nsIUploadChannel> uploadChannel(do_QueryInterface(chan));
NS_ENSURE_STATE(uploadChannel);
rv = uploadChannel->SetUploadStream(uploadStream,
mRequestSession->mPostContentType,
-1);
NS_ENSURE_SUCCESS(rv, rv);
}
// Do not use SPDY for internal security operations. It could result
// in the silent upgrade to ssl, which in turn could require an SSL
// operation to fufill something like a CRL fetch, which is an
// endless loop.
nsCOMPtr<nsIHttpChannelInternal> internalChannel = do_QueryInterface(chan);
if (internalChannel) {
rv = internalChannel->SetAllowSpdy(false);
NS_ENSURE_SUCCESS(rv, rv);
}
nsCOMPtr<nsIHttpChannel> hchan = do_QueryInterface(chan);
NS_ENSURE_STATE(hchan);
rv = hchan->SetAllowSTS(false);
NS_ENSURE_SUCCESS(rv, rv);
rv = hchan->SetRequestMethod(mRequestSession->mRequestMethod);
NS_ENSURE_SUCCESS(rv, rv);
mResponsibleForDoneSignal = false;
mListener->mResponsibleForDoneSignal = true;
mListener->mLoadGroup = lg.get();
NS_ADDREF(mListener->mLoadGroup);
mListener->mLoadGroupOwnerThread = PR_GetCurrentThread();
rv = NS_NewStreamLoader(getter_AddRefs(mListener->mLoader),
mListener);
if (NS_SUCCEEDED(rv)) {
mStartTime = TimeStamp::Now();
rv = hchan->AsyncOpen(mListener->mLoader, nullptr);
}
if (NS_FAILED(rv)) {
mListener->mResponsibleForDoneSignal = false;
mResponsibleForDoneSignal = true;
NS_RELEASE(mListener->mLoadGroup);
mListener->mLoadGroup = nullptr;
mListener->mLoadGroupOwnerThread = nullptr;
}
return NS_OK;
}
struct nsCancelHTTPDownloadEvent : nsRunnable {
nsRefPtr<nsHTTPListener> mListener;
NS_IMETHOD Run() {
mListener->FreeLoadGroup(true);
mListener = nullptr;
return NS_OK;
}
};
SECStatus nsNSSHttpServerSession::createSessionFcn(const char *host,
uint16_t portnum,
SEC_HTTP_SERVER_SESSION *pSession)
{
if (!host || !pSession)
return SECFailure;
nsNSSHttpServerSession *hss = new nsNSSHttpServerSession;
if (!hss)
return SECFailure;
hss->mHost = host;
hss->mPort = portnum;
*pSession = hss;
return SECSuccess;
}
SECStatus nsNSSHttpRequestSession::createFcn(SEC_HTTP_SERVER_SESSION session,
const char *http_protocol_variant,
const char *path_and_query_string,
const char *http_request_method,
const PRIntervalTime timeout,
SEC_HTTP_REQUEST_SESSION *pRequest)
{
if (!session || !http_protocol_variant || !path_and_query_string ||
!http_request_method || !pRequest)
return SECFailure;
nsNSSHttpServerSession* hss = static_cast<nsNSSHttpServerSession*>(session);
if (!hss)
return SECFailure;
nsNSSHttpRequestSession *rs = new nsNSSHttpRequestSession;
if (!rs)
return SECFailure;
rs->mTimeoutInterval = timeout;
// Use a maximum timeout value of 10 seconds because of bug 404059.
// FIXME: Use a better approach once 406120 is ready.
uint32_t maxBug404059Timeout = PR_TicksPerSecond() * 10;
if (timeout > maxBug404059Timeout) {
rs->mTimeoutInterval = maxBug404059Timeout;
}
rs->mURL.Assign(http_protocol_variant);
rs->mURL.AppendLiteral("://");
rs->mURL.Append(hss->mHost);
rs->mURL.Append(':');
rs->mURL.AppendInt(hss->mPort);
rs->mURL.Append(path_and_query_string);
rs->mRequestMethod = http_request_method;
*pRequest = (void*)rs;
return SECSuccess;
}
SECStatus nsNSSHttpRequestSession::setPostDataFcn(const char *http_data,
const uint32_t http_data_len,
const char *http_content_type)
{
mHasPostData = true;
mPostData.Assign(http_data, http_data_len);
mPostContentType.Assign(http_content_type);
return SECSuccess;
}
SECStatus nsNSSHttpRequestSession::addHeaderFcn(const char *http_header_name,
const char *http_header_value)
{
return SECFailure; // not yet implemented
// All http code needs to be postponed to the UI thread.
// Once this gets implemented, we need to add a string list member to
// nsNSSHttpRequestSession and queue up the headers,
// so they can be added in HandleHTTPDownloadPLEvent.
//
// The header will need to be set using
// mHttpChannel->SetRequestHeader(nsDependentCString(http_header_name),
// nsDependentCString(http_header_value),
// false)));
}
SECStatus nsNSSHttpRequestSession::trySendAndReceiveFcn(PRPollDesc **pPollDesc,
uint16_t *http_response_code,
const char **http_response_content_type,
const char **http_response_headers,
const char **http_response_data,
uint32_t *http_response_data_len)
{
MOZ_LOG(gPIPNSSLog, LogLevel::Debug,
("nsNSSHttpRequestSession::trySendAndReceiveFcn to %s\n", mURL.get()));
bool onSTSThread;
nsresult nrv;
nsCOMPtr<nsIEventTarget> sts
= do_GetService(NS_SOCKETTRANSPORTSERVICE_CONTRACTID, &nrv);
if (NS_FAILED(nrv)) {
NS_ERROR("Could not get STS service");
PR_SetError(PR_INVALID_STATE_ERROR, 0);
return SECFailure;
}
nrv = sts->IsOnCurrentThread(&onSTSThread);
if (NS_FAILED(nrv)) {
NS_ERROR("IsOnCurrentThread failed");
PR_SetError(PR_INVALID_STATE_ERROR, 0);
return SECFailure;
}
if (onSTSThread) {
NS_ERROR("nsNSSHttpRequestSession::trySendAndReceiveFcn called on socket "
"thread; this will not work.");
PR_SetError(PR_INVALID_STATE_ERROR, 0);
return SECFailure;
}
const int max_retries = 2;
int retry_count = 0;
bool retryable_error = false;
SECStatus result_sec_status = SECFailure;
do
{
if (retry_count > 0)
{
if (retryable_error)
{
MOZ_LOG(gPIPNSSLog, LogLevel::Debug,
("nsNSSHttpRequestSession::trySendAndReceiveFcn - sleeping and retrying: %d of %d\n",
retry_count, max_retries));
}
PR_Sleep( PR_MillisecondsToInterval(300) * retry_count );
}
++retry_count;
retryable_error = false;
result_sec_status =
internal_send_receive_attempt(retryable_error, pPollDesc, http_response_code,
http_response_content_type, http_response_headers,
http_response_data, http_response_data_len);
}
while (retryable_error &&
retry_count < max_retries);
if (retry_count > 1)
{
if (retryable_error)
MOZ_LOG(gPIPNSSLog, LogLevel::Debug,
("nsNSSHttpRequestSession::trySendAndReceiveFcn - still failing, giving up...\n"));
else
MOZ_LOG(gPIPNSSLog, LogLevel::Debug,
("nsNSSHttpRequestSession::trySendAndReceiveFcn - success at attempt %d\n",
retry_count));
}
return result_sec_status;
}
void
nsNSSHttpRequestSession::AddRef()
{
++mRefCount;
}
void
nsNSSHttpRequestSession::Release()
{
int32_t newRefCount = --mRefCount;
if (!newRefCount) {
delete this;
}
}
SECStatus
nsNSSHttpRequestSession::internal_send_receive_attempt(bool &retryable_error,
PRPollDesc **pPollDesc,
uint16_t *http_response_code,
const char **http_response_content_type,
const char **http_response_headers,
const char **http_response_data,
uint32_t *http_response_data_len)
{
if (pPollDesc) *pPollDesc = nullptr;
if (http_response_code) *http_response_code = 0;
if (http_response_content_type) *http_response_content_type = 0;
if (http_response_headers) *http_response_headers = 0;
if (http_response_data) *http_response_data = 0;
uint32_t acceptableResultSize = 0;
if (http_response_data_len)
{
acceptableResultSize = *http_response_data_len;
*http_response_data_len = 0;
}
if (!mListener)
return SECFailure;
Mutex& waitLock = mListener->mLock;
CondVar& waitCondition = mListener->mCondition;
volatile bool &waitFlag = mListener->mWaitFlag;
waitFlag = true;
RefPtr<nsHTTPDownloadEvent> event(new nsHTTPDownloadEvent);
if (!event)
return SECFailure;
event->mListener = mListener;
this->AddRef();
event->mRequestSession = this;
nsresult rv = NS_DispatchToMainThread(event);
if (NS_FAILED(rv))
{
event->mResponsibleForDoneSignal = false;
return SECFailure;
}
bool request_canceled = false;
{
MutexAutoLock locker(waitLock);
const PRIntervalTime start_time = PR_IntervalNow();
PRIntervalTime wait_interval;
bool running_on_main_thread = NS_IsMainThread();
if (running_on_main_thread)
{
// The result of running this on the main thread
// is a series of small timeouts mixed with spinning the
// event loop - this is always dangerous as there is so much main
// thread code that does not expect to be called re-entrantly. Your
// app really shouldn't do that.
NS_WARNING("Security network blocking I/O on Main Thread");
// let's process events quickly
wait_interval = PR_MicrosecondsToInterval(50);
}
else
{
// On a secondary thread, it's fine to wait some more for
// for the condition variable.
wait_interval = PR_MillisecondsToInterval(250);
}
while (waitFlag)
{
if (running_on_main_thread)
{
// Networking runs on the main thread, which we happen to block here.
// Processing events will allow the OCSP networking to run while we
// are waiting. Thanks a lot to Darin Fisher for rewriting the
// thread manager. Thanks a lot to Christian Biesinger who
// made me aware of this possibility. (kaie)
MutexAutoUnlock unlock(waitLock);
NS_ProcessNextEvent(nullptr);
}
waitCondition.Wait(wait_interval);
if (!waitFlag)
break;
if (!request_canceled)
{
bool timeout =
(PRIntervalTime)(PR_IntervalNow() - start_time) > mTimeoutInterval;
if (timeout)
{
request_canceled = true;
RefPtr<nsCancelHTTPDownloadEvent> cancelevent(
new nsCancelHTTPDownloadEvent);
cancelevent->mListener = mListener;
rv = NS_DispatchToMainThread(cancelevent);
if (NS_FAILED(rv)) {
NS_WARNING("cannot post cancel event");
}
break;
}
}
}
}
if (!event->mStartTime.IsNull()) {
if (request_canceled) {
Telemetry::Accumulate(Telemetry::CERT_VALIDATION_HTTP_REQUEST_RESULT, 0);
Telemetry::AccumulateTimeDelta(
Telemetry::CERT_VALIDATION_HTTP_REQUEST_CANCELED_TIME,
event->mStartTime, TimeStamp::Now());
}
else if (NS_SUCCEEDED(mListener->mResultCode) &&
mListener->mHttpResponseCode == 200) {
Telemetry::Accumulate(Telemetry::CERT_VALIDATION_HTTP_REQUEST_RESULT, 1);
Telemetry::AccumulateTimeDelta(
Telemetry::CERT_VALIDATION_HTTP_REQUEST_SUCCEEDED_TIME,
event->mStartTime, TimeStamp::Now());
}
else {
Telemetry::Accumulate(Telemetry::CERT_VALIDATION_HTTP_REQUEST_RESULT, 2);
Telemetry::AccumulateTimeDelta(
Telemetry::CERT_VALIDATION_HTTP_REQUEST_FAILED_TIME,
event->mStartTime, TimeStamp::Now());
}
}
else {
Telemetry::Accumulate(Telemetry::CERT_VALIDATION_HTTP_REQUEST_RESULT, 3);
}
if (request_canceled)
return SECFailure;
if (NS_FAILED(mListener->mResultCode))
{
if (mListener->mResultCode == NS_ERROR_CONNECTION_REFUSED
||
mListener->mResultCode == NS_ERROR_NET_RESET)
{
retryable_error = true;
}
return SECFailure;
}
if (http_response_code)
*http_response_code = mListener->mHttpResponseCode;
if (mListener->mHttpRequestSucceeded && http_response_data && http_response_data_len) {
*http_response_data_len = mListener->mResultLen;
// acceptableResultSize == 0 means: any size is acceptable
if (acceptableResultSize != 0
&&
acceptableResultSize < mListener->mResultLen)
{
return SECFailure;
}
// return data by reference, result data will be valid
// until "this" gets destroyed by NSS
*http_response_data = (const char*)mListener->mResultData;
}
if (mListener->mHttpRequestSucceeded && http_response_content_type) {
if (mListener->mHttpResponseContentType.Length()) {
*http_response_content_type = mListener->mHttpResponseContentType.get();
}
}
return SECSuccess;
}
SECStatus nsNSSHttpRequestSession::cancelFcn()
{
// As of today, only the blocking variant of the http interface
// has been implemented. Implementing cancelFcn will be necessary
// as soon as we implement the nonblocking variant.
return SECSuccess;
}
SECStatus nsNSSHttpRequestSession::freeFcn()
{
Release();
return SECSuccess;
}
nsNSSHttpRequestSession::nsNSSHttpRequestSession()
: mRefCount(1),
mHasPostData(false),
mTimeoutInterval(0),
mListener(new nsHTTPListener)
{
}
nsNSSHttpRequestSession::~nsNSSHttpRequestSession()
{
}
SEC_HttpClientFcn nsNSSHttpInterface::sNSSInterfaceTable;
void nsNSSHttpInterface::initTable()
{
sNSSInterfaceTable.version = 1;
SEC_HttpClientFcnV1 &v1 = sNSSInterfaceTable.fcnTable.ftable1;
v1.createSessionFcn = createSessionFcn;
v1.keepAliveSessionFcn = keepAliveFcn;
v1.freeSessionFcn = freeSessionFcn;
v1.createFcn = createFcn;
v1.setPostDataFcn = setPostDataFcn;
v1.addHeaderFcn = addHeaderFcn;
v1.trySendAndReceiveFcn = trySendAndReceiveFcn;
v1.cancelFcn = cancelFcn;
v1.freeFcn = freeFcn;
}
nsHTTPListener::nsHTTPListener()
: mResultData(nullptr),
mResultLen(0),
mLock("nsHTTPListener.mLock"),
mCondition(mLock, "nsHTTPListener.mCondition"),
mWaitFlag(true),
mResponsibleForDoneSignal(false),
mLoadGroup(nullptr),
mLoadGroupOwnerThread(nullptr)
{
}
nsHTTPListener::~nsHTTPListener()
{
if (mResponsibleForDoneSignal)
send_done_signal();
if (mResultData) {
free(const_cast<uint8_t *>(mResultData));
}
if (mLoader) {
nsCOMPtr<nsIThread> mainThread(do_GetMainThread());
NS_ProxyRelease(mainThread, mLoader);
}
}
NS_IMPL_ISUPPORTS(nsHTTPListener, nsIStreamLoaderObserver)
void
nsHTTPListener::FreeLoadGroup(bool aCancelLoad)
{
nsILoadGroup *lg = nullptr;
MutexAutoLock locker(mLock);
if (mLoadGroup) {
if (mLoadGroupOwnerThread != PR_GetCurrentThread()) {
NS_ASSERTION(false,
"attempt to access nsHTTPDownloadEvent::mLoadGroup on multiple threads, leaking it!");
}
else {
lg = mLoadGroup;
mLoadGroup = nullptr;
}
}
if (lg) {
if (aCancelLoad) {
lg->Cancel(NS_ERROR_ABORT);
}
NS_RELEASE(lg);
}
}
NS_IMETHODIMP
nsHTTPListener::OnStreamComplete(nsIStreamLoader* aLoader,
nsISupports* aContext,
nsresult aStatus,
uint32_t stringLen,
const uint8_t* string)
{
mResultCode = aStatus;
FreeLoadGroup(false);
nsCOMPtr<nsIRequest> req;
nsCOMPtr<nsIHttpChannel> hchan;
nsresult rv = aLoader->GetRequest(getter_AddRefs(req));
if (NS_FAILED(aStatus))
{
MOZ_LOG(gPIPNSSLog, LogLevel::Debug,
("nsHTTPListener::OnStreamComplete status failed %d", aStatus));
}
if (NS_SUCCEEDED(rv))
hchan = do_QueryInterface(req, &rv);
if (NS_SUCCEEDED(rv))
{
rv = hchan->GetRequestSucceeded(&mHttpRequestSucceeded);
if (NS_FAILED(rv))
mHttpRequestSucceeded = false;
mResultLen = stringLen;
mResultData = string; // take ownership of allocation
aStatus = NS_SUCCESS_ADOPTED_DATA;
unsigned int rcode;
rv = hchan->GetResponseStatus(&rcode);
if (NS_FAILED(rv))
mHttpResponseCode = 500;
else
mHttpResponseCode = rcode;
hchan->GetResponseHeader(NS_LITERAL_CSTRING("Content-Type"),
mHttpResponseContentType);
}
if (mResponsibleForDoneSignal)
send_done_signal();
return aStatus;
}
void nsHTTPListener::send_done_signal()
{
mResponsibleForDoneSignal = false;
{
MutexAutoLock locker(mLock);
mWaitFlag = false;
mCondition.NotifyAll();
}
}
static char*
ShowProtectedAuthPrompt(PK11SlotInfo* slot, nsIInterfaceRequestor *ir)
{
if (!NS_IsMainThread()) {
NS_ERROR("ShowProtectedAuthPrompt called off the main thread");
return nullptr;
}
char* protAuthRetVal = nullptr;
// Get protected auth dialogs
nsITokenDialogs* dialogs = 0;
nsresult nsrv = getNSSDialogs((void**)&dialogs,
NS_GET_IID(nsITokenDialogs),
NS_TOKENDIALOGS_CONTRACTID);
if (NS_SUCCEEDED(nsrv))
{
nsProtectedAuthThread* protectedAuthRunnable = new nsProtectedAuthThread();
if (protectedAuthRunnable)
{
NS_ADDREF(protectedAuthRunnable);
protectedAuthRunnable->SetParams(slot);
nsCOMPtr<nsIProtectedAuthThread> runnable = do_QueryInterface(protectedAuthRunnable);
if (runnable)
{
nsrv = dialogs->DisplayProtectedAuth(ir, runnable);
// We call join on the thread,
// so we can be sure that no simultaneous access will happen.
protectedAuthRunnable->Join();
if (NS_SUCCEEDED(nsrv))
{
SECStatus rv = protectedAuthRunnable->GetResult();
switch (rv)
{
case SECSuccess:
protAuthRetVal = ToNewCString(nsDependentCString(PK11_PW_AUTHENTICATED));
break;
case SECWouldBlock:
protAuthRetVal = ToNewCString(nsDependentCString(PK11_PW_RETRY));
break;
default:
protAuthRetVal = nullptr;
break;
}
}
}
NS_RELEASE(protectedAuthRunnable);
}
NS_RELEASE(dialogs);
}
return protAuthRetVal;
}
class PK11PasswordPromptRunnable : public SyncRunnableBase
{
public:
PK11PasswordPromptRunnable(PK11SlotInfo* slot,
nsIInterfaceRequestor* ir)
: mResult(nullptr),
mSlot(slot),
mIR(ir)
{
}
char * mResult; // out
virtual void RunOnTargetThread();
private:
PK11SlotInfo* const mSlot; // in
nsIInterfaceRequestor* const mIR; // in
};
void PK11PasswordPromptRunnable::RunOnTargetThread()
{
static NS_DEFINE_CID(kNSSComponentCID, NS_NSSCOMPONENT_CID);
nsNSSShutDownPreventionLock locker;
nsresult rv = NS_OK;
char16_t *password = nullptr;
bool value = false;
nsCOMPtr<nsIPrompt> prompt;
/* TODO: Retry should generate a different dialog message */
/*
if (retry)
return nullptr;
*/
if (!mIR)
{
nsNSSComponent::GetNewPrompter(getter_AddRefs(prompt));
}
else
{
prompt = do_GetInterface(mIR);
NS_ASSERTION(prompt, "callbacks does not implement nsIPrompt");
}
if (!prompt)
return;
if (PK11_ProtectedAuthenticationPath(mSlot)) {
mResult = ShowProtectedAuthPrompt(mSlot, mIR);
return;
}
nsAutoString promptString;
nsCOMPtr<nsINSSComponent> nssComponent(do_GetService(kNSSComponentCID, &rv));
if (NS_FAILED(rv))
return;
const char16_t* formatStrings[1] = {
ToNewUnicode(NS_ConvertUTF8toUTF16(PK11_GetTokenName(mSlot)))
};
rv = nssComponent->PIPBundleFormatStringFromName("CertPassPrompt",
formatStrings, 1,
promptString);
free(const_cast<char16_t*>(formatStrings[0]));
if (NS_FAILED(rv))
return;
{
nsPSMUITracker tracker;
if (tracker.isUIForbidden()) {
rv = NS_ERROR_NOT_AVAILABLE;
}
else {
// Although the exact value is ignored, we must not pass invalid
// bool values through XPConnect.
bool checkState = false;
rv = prompt->PromptPassword(nullptr, promptString.get(),
&password, nullptr, &checkState, &value);
}
}
if (NS_SUCCEEDED(rv) && value) {
mResult = ToNewUTF8String(nsDependentString(password));
free(password);
}
}
char*
PK11PasswordPrompt(PK11SlotInfo* slot, PRBool retry, void* arg)
{
RefPtr<PK11PasswordPromptRunnable> runnable(
new PK11PasswordPromptRunnable(slot,
static_cast<nsIInterfaceRequestor*>(arg)));
runnable->DispatchToMainThreadAndWait();
return runnable->mResult;
}
// call with shutdown prevention lock held
static void
PreliminaryHandshakeDone(PRFileDesc* fd)
{
nsNSSSocketInfo* infoObject = (nsNSSSocketInfo*) fd->higher->secret;
if (!infoObject)
return;
if (infoObject->IsPreliminaryHandshakeDone())
return;
infoObject->SetPreliminaryHandshakeDone();
SSLChannelInfo channelInfo;
if (SSL_GetChannelInfo(fd, &channelInfo, sizeof(channelInfo)) == SECSuccess) {
infoObject->SetSSLVersionUsed(channelInfo.protocolVersion);
SSLCipherSuiteInfo cipherInfo;
if (SSL_GetCipherSuiteInfo(channelInfo.cipherSuite, &cipherInfo,
sizeof cipherInfo) == SECSuccess) {
/* Set the SSL Status information */
RefPtr<nsSSLStatus> status(infoObject->SSLStatus());
if (!status) {
status = new nsSSLStatus();
infoObject->SetSSLStatus(status);
}
status->mHaveCipherSuiteAndProtocol = true;
status->mCipherSuite = channelInfo.cipherSuite;
status->mProtocolVersion = channelInfo.protocolVersion & 0xFF;
infoObject->SetKEAUsed(cipherInfo.keaType);
infoObject->SetKEAKeyBits(channelInfo.keaKeyBits);
infoObject->SetMACAlgorithmUsed(cipherInfo.macAlgorithm);
}
}
// Get the NPN value.
SSLNextProtoState state;
unsigned char npnbuf[256];
unsigned int npnlen;
if (SSL_GetNextProto(fd, &state, npnbuf, &npnlen, 256) == SECSuccess) {
if (state == SSL_NEXT_PROTO_NEGOTIATED ||
state == SSL_NEXT_PROTO_SELECTED) {
infoObject->SetNegotiatedNPN(reinterpret_cast<char *>(npnbuf), npnlen);
}
else {
infoObject->SetNegotiatedNPN(nullptr, 0);
}
mozilla::Telemetry::Accumulate(Telemetry::SSL_NPN_TYPE, state);
}
else {
infoObject->SetNegotiatedNPN(nullptr, 0);
}
}
SECStatus
CanFalseStartCallback(PRFileDesc* fd, void* client_data, PRBool *canFalseStart)
{
*canFalseStart = false;
nsNSSShutDownPreventionLock locker;
nsNSSSocketInfo* infoObject = (nsNSSSocketInfo*) fd->higher->secret;
if (!infoObject) {
PR_SetError(PR_INVALID_STATE_ERROR, 0);
return SECFailure;
}
infoObject->SetFalseStartCallbackCalled();
if (infoObject->isAlreadyShutDown()) {
MOZ_CRASH("SSL socket used after NSS shut down");
PR_SetError(PR_INVALID_STATE_ERROR, 0);
return SECFailure;
}
PreliminaryHandshakeDone(fd);
uint32_t reasonsForNotFalseStarting = 0;
SSLChannelInfo channelInfo;
if (SSL_GetChannelInfo(fd, &channelInfo, sizeof(channelInfo)) != SECSuccess) {
return SECSuccess;
}
SSLCipherSuiteInfo cipherInfo;
if (SSL_GetCipherSuiteInfo(channelInfo.cipherSuite, &cipherInfo,
sizeof (cipherInfo)) != SECSuccess) {
MOZ_LOG(gPIPNSSLog, LogLevel::Debug, ("CanFalseStartCallback [%p] failed - "
" KEA %d\n", fd,
static_cast<int32_t>(cipherInfo.keaType)));
return SECSuccess;
}
nsSSLIOLayerHelpers& helpers = infoObject->SharedState().IOLayerHelpers();
// Prevent version downgrade attacks from TLS 1.2, and avoid False Start for
// TLS 1.3 and later. See Bug 861310 for all the details as to why.
if (channelInfo.protocolVersion != SSL_LIBRARY_VERSION_TLS_1_2) {
MOZ_LOG(gPIPNSSLog, LogLevel::Debug, ("CanFalseStartCallback [%p] failed - "
"SSL Version must be TLS 1.2, was %x\n", fd,
static_cast<int32_t>(channelInfo.protocolVersion)));
reasonsForNotFalseStarting |= POSSIBLE_VERSION_DOWNGRADE;
}
// See bug 952863 for why ECDHE is allowed, but DHE (and RSA) are not.
if (cipherInfo.keaType != ssl_kea_ecdh) {
MOZ_LOG(gPIPNSSLog, LogLevel::Debug, ("CanFalseStartCallback [%p] failed - "
"unsupported KEA %d\n", fd,
static_cast<int32_t>(cipherInfo.keaType)));
reasonsForNotFalseStarting |= KEA_NOT_SUPPORTED;
}
// Prevent downgrade attacks on the symmetric cipher. We do not allow CBC
// mode due to BEAST, POODLE, and other attacks on the MAC-then-Encrypt
// design. See bug 1109766 for more details.
if (cipherInfo.symCipher != ssl_calg_aes_gcm) {
MOZ_LOG(gPIPNSSLog, LogLevel::Debug,
("CanFalseStartCallback [%p] failed - Symmetric cipher used, %d, "
"is not supported with False Start.\n", fd,
static_cast<int32_t>(cipherInfo.symCipher)));
reasonsForNotFalseStarting |= POSSIBLE_CIPHER_SUITE_DOWNGRADE;
}
// XXX: An attacker can choose which protocols are advertised in the
// NPN extension. TODO(Bug 861311): We should restrict the ability
// of an attacker leverage this capability by restricting false start
// to the same protocol we previously saw for the server, after the
// first successful connection to the server.
// Enforce NPN to do false start if policy requires it. Do this as an
// indicator if server compatibility.
if (helpers.mFalseStartRequireNPN) {
nsAutoCString negotiatedNPN;
if (NS_FAILED(infoObject->GetNegotiatedNPN(negotiatedNPN)) ||
!negotiatedNPN.Length()) {
MOZ_LOG(gPIPNSSLog, LogLevel::Debug, ("CanFalseStartCallback [%p] failed - "
"NPN cannot be verified\n", fd));
reasonsForNotFalseStarting |= NPN_NOT_NEGOTIATED;
}
}
Telemetry::Accumulate(Telemetry::SSL_REASONS_FOR_NOT_FALSE_STARTING,
reasonsForNotFalseStarting);
if (reasonsForNotFalseStarting == 0) {
*canFalseStart = PR_TRUE;
infoObject->SetFalseStarted();
infoObject->NoteTimeUntilReady();
MOZ_LOG(gPIPNSSLog, LogLevel::Debug, ("CanFalseStartCallback [%p] ok\n", fd));
}
return SECSuccess;
}
static void
AccumulateNonECCKeySize(Telemetry::ID probe, uint32_t bits)
{
unsigned int value = bits < 512 ? 1 : bits == 512 ? 2
: bits < 768 ? 3 : bits == 768 ? 4
: bits < 1024 ? 5 : bits == 1024 ? 6
: bits < 1280 ? 7 : bits == 1280 ? 8
: bits < 1536 ? 9 : bits == 1536 ? 10
: bits < 2048 ? 11 : bits == 2048 ? 12
: bits < 3072 ? 13 : bits == 3072 ? 14
: bits < 4096 ? 15 : bits == 4096 ? 16
: bits < 8192 ? 17 : bits == 8192 ? 18
: bits < 16384 ? 19 : bits == 16384 ? 20
: 0;
Telemetry::Accumulate(probe, value);
}
// XXX: This attempts to map a bit count to an ECC named curve identifier. In
// the vast majority of situations, we only have the Suite B curves available.
// In that case, this mapping works fine. If we were to have more curves
// available, the mapping would be ambiguous since there could be multiple
// named curves for a given size (e.g. secp256k1 vs. secp256r1). We punt on
// that for now. See also NSS bug 323674.
static void
AccumulateECCCurve(Telemetry::ID probe, uint32_t bits)
{
unsigned int value = bits == 256 ? 23 // P-256
: bits == 384 ? 24 // P-384
: bits == 521 ? 25 // P-521
: 0; // Unknown
Telemetry::Accumulate(probe, value);
}
static void
AccumulateCipherSuite(Telemetry::ID probe, const SSLChannelInfo& channelInfo)
{
uint32_t value;
switch (channelInfo.cipherSuite) {
// ECDHE key exchange
case TLS_ECDHE_RSA_WITH_AES_128_GCM_SHA256: value = 1; break;
case TLS_ECDHE_ECDSA_WITH_AES_128_GCM_SHA256: value = 2; break;
case TLS_ECDHE_RSA_WITH_AES_128_CBC_SHA: value = 3; break;
case TLS_ECDHE_ECDSA_WITH_AES_128_CBC_SHA: value = 4; break;
case TLS_ECDHE_RSA_WITH_AES_256_CBC_SHA: value = 5; break;
case TLS_ECDHE_ECDSA_WITH_AES_256_CBC_SHA: value = 6; break;
case TLS_ECDHE_RSA_WITH_3DES_EDE_CBC_SHA: value = 7; break;
case TLS_ECDHE_RSA_WITH_RC4_128_SHA: value = 8; break;
case TLS_ECDHE_ECDSA_WITH_RC4_128_SHA: value = 9; break;
case TLS_ECDHE_ECDSA_WITH_3DES_EDE_CBC_SHA: value = 10; break;
// DHE key exchange
case TLS_DHE_RSA_WITH_AES_128_CBC_SHA: value = 21; break;
case TLS_DHE_RSA_WITH_CAMELLIA_128_CBC_SHA: value = 22; break;
case TLS_DHE_RSA_WITH_AES_256_CBC_SHA: value = 23; break;
case TLS_DHE_RSA_WITH_CAMELLIA_256_CBC_SHA: value = 24; break;
case TLS_DHE_RSA_WITH_3DES_EDE_CBC_SHA: value = 25; break;
case TLS_DHE_DSS_WITH_AES_128_CBC_SHA: value = 26; break;
case TLS_DHE_DSS_WITH_CAMELLIA_128_CBC_SHA: value = 27; break;
case TLS_DHE_DSS_WITH_AES_256_CBC_SHA: value = 28; break;
case TLS_DHE_DSS_WITH_CAMELLIA_256_CBC_SHA: value = 29; break;
case TLS_DHE_DSS_WITH_3DES_EDE_CBC_SHA: value = 30; break;
// ECDH key exchange
case TLS_ECDH_ECDSA_WITH_AES_128_CBC_SHA: value = 41; break;
case TLS_ECDH_RSA_WITH_AES_128_CBC_SHA: value = 42; break;
case TLS_ECDH_ECDSA_WITH_AES_256_CBC_SHA: value = 43; break;
case TLS_ECDH_RSA_WITH_AES_256_CBC_SHA: value = 44; break;
case TLS_ECDH_ECDSA_WITH_3DES_EDE_CBC_SHA: value = 45; break;
case TLS_ECDH_RSA_WITH_3DES_EDE_CBC_SHA: value = 46; break;
case TLS_ECDH_ECDSA_WITH_RC4_128_SHA: value = 47; break;
case TLS_ECDH_RSA_WITH_RC4_128_SHA: value = 48; break;
// RSA key exchange
case TLS_RSA_WITH_AES_128_CBC_SHA: value = 61; break;
case TLS_RSA_WITH_CAMELLIA_128_CBC_SHA: value = 62; break;
case TLS_RSA_WITH_AES_256_CBC_SHA: value = 63; break;
case TLS_RSA_WITH_CAMELLIA_256_CBC_SHA: value = 64; break;
case SSL_RSA_FIPS_WITH_3DES_EDE_CBC_SHA: value = 65; break;
case TLS_RSA_WITH_3DES_EDE_CBC_SHA: value = 66; break;
case TLS_RSA_WITH_SEED_CBC_SHA: value = 67; break;
case TLS_RSA_WITH_RC4_128_SHA: value = 68; break;
case TLS_RSA_WITH_RC4_128_MD5: value = 69; break;
// unknown
default:
value = 0;
break;
}
MOZ_ASSERT(value != 0);
Telemetry::Accumulate(probe, value);
}
void HandshakeCallback(PRFileDesc* fd, void* client_data) {
nsNSSShutDownPreventionLock locker;
SECStatus rv;
nsNSSSocketInfo* infoObject = (nsNSSSocketInfo*) fd->higher->secret;
// Do the bookkeeping that needs to be done after the
// server's ServerHello...ServerHelloDone have been processed, but that doesn't
// need the handshake to be completed.
PreliminaryHandshakeDone(fd);
nsSSLIOLayerHelpers& ioLayerHelpers
= infoObject->SharedState().IOLayerHelpers();
SSLVersionRange versions(infoObject->GetTLSVersionRange());
MOZ_LOG(gPIPNSSLog, LogLevel::Debug,
("[%p] HandshakeCallback: succeeded using TLS version range (0x%04x,0x%04x)\n",
fd, static_cast<unsigned int>(versions.min),
static_cast<unsigned int>(versions.max)));
// If the handshake completed, then we know the site is TLS tolerant
ioLayerHelpers.rememberTolerantAtVersion(infoObject->GetHostName(),
infoObject->GetPort(),
versions.max);
bool usesWeakCipher = false;
SSLChannelInfo channelInfo;
rv = SSL_GetChannelInfo(fd, &channelInfo, sizeof(channelInfo));
MOZ_ASSERT(rv == SECSuccess);
if (rv == SECSuccess) {
// Get the protocol version for telemetry
// 1=tls1, 2=tls1.1, 3=tls1.2
unsigned int versionEnum = channelInfo.protocolVersion & 0xFF;
MOZ_ASSERT(versionEnum > 0);
Telemetry::Accumulate(Telemetry::SSL_HANDSHAKE_VERSION, versionEnum);
AccumulateCipherSuite(
infoObject->IsFullHandshake() ? Telemetry::SSL_CIPHER_SUITE_FULL
: Telemetry::SSL_CIPHER_SUITE_RESUMED,
channelInfo);
SSLCipherSuiteInfo cipherInfo;
rv = SSL_GetCipherSuiteInfo(channelInfo.cipherSuite, &cipherInfo,
sizeof cipherInfo);
MOZ_ASSERT(rv == SECSuccess);
if (rv == SECSuccess) {
usesWeakCipher = cipherInfo.symCipher == ssl_calg_rc4;
// keyExchange null=0, rsa=1, dh=2, fortezza=3, ecdh=4
Telemetry::Accumulate(
infoObject->IsFullHandshake()
? Telemetry::SSL_KEY_EXCHANGE_ALGORITHM_FULL
: Telemetry::SSL_KEY_EXCHANGE_ALGORITHM_RESUMED,
cipherInfo.keaType);
DebugOnly<int16_t> KEAUsed;
MOZ_ASSERT(NS_SUCCEEDED(infoObject->GetKEAUsed(&KEAUsed)) &&
(KEAUsed == cipherInfo.keaType));
if (infoObject->IsFullHandshake()) {
switch (cipherInfo.keaType) {
case ssl_kea_rsa:
AccumulateNonECCKeySize(Telemetry::SSL_KEA_RSA_KEY_SIZE_FULL,
channelInfo.keaKeyBits);
break;
case ssl_kea_dh:
AccumulateNonECCKeySize(Telemetry::SSL_KEA_DHE_KEY_SIZE_FULL,
channelInfo.keaKeyBits);
break;
case ssl_kea_ecdh:
AccumulateECCCurve(Telemetry::SSL_KEA_ECDHE_CURVE_FULL,
channelInfo.keaKeyBits);
break;
default:
MOZ_CRASH("impossible KEA");
break;
}
Telemetry::Accumulate(Telemetry::SSL_AUTH_ALGORITHM_FULL,
cipherInfo.authAlgorithm);
// RSA key exchange doesn't use a signature for auth.
if (cipherInfo.keaType != ssl_kea_rsa) {
switch (cipherInfo.authAlgorithm) {
case ssl_auth_rsa:
AccumulateNonECCKeySize(Telemetry::SSL_AUTH_RSA_KEY_SIZE_FULL,
channelInfo.authKeyBits);
break;
case ssl_auth_dsa:
AccumulateNonECCKeySize(Telemetry::SSL_AUTH_DSA_KEY_SIZE_FULL,
channelInfo.authKeyBits);
break;
case ssl_auth_ecdsa:
AccumulateECCCurve(Telemetry::SSL_AUTH_ECDSA_CURVE_FULL,
channelInfo.authKeyBits);
break;
default:
MOZ_CRASH("impossible auth algorithm");
break;
}
}
}
Telemetry::Accumulate(
infoObject->IsFullHandshake()
? Telemetry::SSL_SYMMETRIC_CIPHER_FULL
: Telemetry::SSL_SYMMETRIC_CIPHER_RESUMED,
cipherInfo.symCipher);
}
}
PRBool siteSupportsSafeRenego;
rv = SSL_HandshakeNegotiatedExtension(fd, ssl_renegotiation_info_xtn,
&siteSupportsSafeRenego);
MOZ_ASSERT(rv == SECSuccess);
if (rv != SECSuccess) {
siteSupportsSafeRenego = false;
}
bool renegotiationUnsafe = !siteSupportsSafeRenego &&
ioLayerHelpers.treatUnsafeNegotiationAsBroken();
uint32_t state;
if (usesWeakCipher || renegotiationUnsafe) {
state = nsIWebProgressListener::STATE_IS_BROKEN;
if (usesWeakCipher) {
state |= nsIWebProgressListener::STATE_USES_WEAK_CRYPTO;
}
} else {
state = nsIWebProgressListener::STATE_IS_SECURE |
nsIWebProgressListener::STATE_SECURE_HIGH;
}
infoObject->SetSecurityState(state);
// XXX Bug 883674: We shouldn't be formatting messages here in PSM; instead,
// we should set a flag on the channel that higher (UI) level code can check
// to log the warning. In particular, these warnings should go to the web
// console instead of to the error console. Also, the warning is not
// localized.
if (!siteSupportsSafeRenego &&
ioLayerHelpers.getWarnLevelMissingRFC5746() > 0) {
nsXPIDLCString hostName;
infoObject->GetHostName(getter_Copies(hostName));
nsAutoString msg;
msg.Append(NS_ConvertASCIItoUTF16(hostName));
msg.AppendLiteral(" : server does not support RFC 5746, see CVE-2009-3555");
nsContentUtils::LogSimpleConsoleError(msg, "SSL");
}
/* Set the SSL Status information */
RefPtr<nsSSLStatus> status(infoObject->SSLStatus());
if (!status) {
status = new nsSSLStatus();
infoObject->SetSSLStatus(status);
}
RememberCertErrorsTable::GetInstance().LookupCertErrorBits(infoObject,
status);
if (status->HasServerCert()) {
MOZ_LOG(gPIPNSSLog, LogLevel::Debug,
("HandshakeCallback KEEPING existing cert\n"));
} else {
ScopedCERTCertificate serverCert(SSL_PeerCertificate(fd));
RefPtr<nsNSSCertificate> nssc(nsNSSCertificate::Create(serverCert.get()));
MOZ_LOG(gPIPNSSLog, LogLevel::Debug,
("HandshakeCallback using NEW cert %p\n", nssc.get()));
status->SetServerCert(nssc, nsNSSCertificate::ev_status_unknown);
}
infoObject->NoteTimeUntilReady();
infoObject->SetHandshakeCompleted();
}