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tenfourfox/netwerk/protocol/http/Http2Session.cpp

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/* -*- Mode: C++; tab-width: 8; indent-tabs-mode: nil; c-basic-offset: 2 -*- */
/* vim: set sw=2 ts=8 et 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
* file, You can obtain one at http://mozilla.org/MPL/2.0/. */
// HttpLog.h should generally be included first
#include "HttpLog.h"
// Log on level :5, instead of default :4.
#undef LOG
#define LOG(args) LOG5(args)
#undef LOG_ENABLED
#define LOG_ENABLED() LOG5_ENABLED()
#include <algorithm>
#include "Http2Session.h"
#include "Http2Stream.h"
#include "Http2Push.h"
#include "mozilla/Endian.h"
#include "mozilla/Telemetry.h"
#include "mozilla/Preferences.h"
#include "nsHttp.h"
#include "nsHttpHandler.h"
#include "nsHttpConnection.h"
#include "nsISchedulingContext.h"
#include "nsISSLSocketControl.h"
#include "nsISSLStatus.h"
#include "nsISSLStatusProvider.h"
#include "nsISupportsPriority.h"
#include "nsStandardURL.h"
#include "nsURLHelper.h"
#include "prnetdb.h"
#include "sslt.h"
#include "mozilla/Snprintf.h"
#include "nsSocketTransportService2.h"
namespace mozilla {
namespace net {
// Http2Session has multiple inheritance of things that implement
// nsISupports, so this magic is taken from nsHttpPipeline that
// implements some of the same abstract classes.
NS_IMPL_ADDREF(Http2Session)
NS_IMPL_RELEASE(Http2Session)
NS_INTERFACE_MAP_BEGIN(Http2Session)
NS_INTERFACE_MAP_ENTRY_AMBIGUOUS(nsISupports, nsAHttpConnection)
NS_INTERFACE_MAP_END
// "magic" refers to the string that preceeds HTTP/2 on the wire
// to help find any intermediaries speaking an older version of HTTP
const uint8_t Http2Session::kMagicHello[] = {
0x50, 0x52, 0x49, 0x20, 0x2a, 0x20, 0x48, 0x54,
0x54, 0x50, 0x2f, 0x32, 0x2e, 0x30, 0x0d, 0x0a,
0x0d, 0x0a, 0x53, 0x4d, 0x0d, 0x0a, 0x0d, 0x0a
};
#define RETURN_SESSION_ERROR(o,x) \
do { \
(o)->mGoAwayReason = (x); \
return NS_ERROR_ILLEGAL_VALUE; \
} while (0)
Http2Session::Http2Session(nsISocketTransport *aSocketTransport, uint32_t version)
: mSocketTransport(aSocketTransport)
, mSegmentReader(nullptr)
, mSegmentWriter(nullptr)
, mNextStreamID(3) // 1 is reserved for Updgrade handshakes
, mConcurrentHighWater(0)
, mDownstreamState(BUFFERING_OPENING_SETTINGS)
, mInputFrameBufferSize(kDefaultBufferSize)
, mInputFrameBufferUsed(0)
, mInputFrameDataSize(0)
, mInputFrameDataRead(0)
, mInputFrameFinal(false)
, mInputFrameType(0)
, mInputFrameFlags(0)
, mInputFrameID(0)
, mPaddingLength(0)
, mInputFrameDataStream(nullptr)
, mNeedsCleanup(nullptr)
, mDownstreamRstReason(NO_HTTP_ERROR)
, mExpectedHeaderID(0)
, mExpectedPushPromiseID(0)
, mContinuedPromiseStream(0)
, mFlatHTTPResponseHeadersOut(0)
, mShouldGoAway(false)
, mClosed(false)
, mCleanShutdown(false)
, mTLSProfileConfirmed(false)
, mGoAwayReason(NO_HTTP_ERROR)
, mClientGoAwayReason(UNASSIGNED)
, mPeerGoAwayReason(UNASSIGNED)
, mGoAwayID(0)
, mOutgoingGoAwayID(0)
, mConcurrent(0)
, mServerPushedResources(0)
, mServerInitialStreamWindow(kDefaultRwin)
, mLocalSessionWindow(kDefaultRwin)
, mServerSessionWindow(kDefaultRwin)
, mInitialRwin(ASpdySession::kInitialRwin)
, mOutputQueueSize(kDefaultQueueSize)
, mOutputQueueUsed(0)
, mOutputQueueSent(0)
, mLastReadEpoch(PR_IntervalNow())
, mPingSentEpoch(0)
, mPreviousUsed(false)
, mWaitingForSettingsAck(false)
, mGoAwayOnPush(false)
, mUseH2Deps(false)
{
MOZ_ASSERT(PR_GetCurrentThread() == gSocketThread);
static uint64_t sSerial;
mSerial = ++sSerial;
LOG3(("Http2Session::Http2Session %p serial=0x%X\n", this, mSerial));
mInputFrameBuffer = MakeUnique<char[]>(mInputFrameBufferSize);
mOutputQueueBuffer = MakeUnique<char[]>(mOutputQueueSize);
mDecompressBuffer.SetCapacity(kDefaultBufferSize);
mDecompressor.SetCompressor(&mCompressor);
mPushAllowance = gHttpHandler->SpdyPushAllowance();
mInitialRwin = std::max(gHttpHandler->SpdyPullAllowance(), mPushAllowance);
mMaxConcurrent = gHttpHandler->DefaultSpdyConcurrent();
mSendingChunkSize = gHttpHandler->SpdySendingChunkSize();
SendHello();
mLastDataReadEpoch = mLastReadEpoch;
mPingThreshold = gHttpHandler->SpdyPingThreshold();
mPreviousPingThreshold = mPingThreshold;
}
PLDHashOperator
Http2Session::ShutdownEnumerator(nsAHttpTransaction *key,
nsAutoPtr<Http2Stream> &stream,
void *closure)
{
Http2Session *self = static_cast<Http2Session *>(closure);
nsresult result;
// On a clean server hangup the server sets the GoAwayID to be the ID of
// the last transaction it processed. If the ID of stream in the
// local stream is greater than that it can safely be restarted because the
// server guarantees it was not partially processed. Streams that have not
// registered an ID haven't actually been sent yet so they can always be
// restarted.
if (self->mCleanShutdown &&
(stream->StreamID() > self->mGoAwayID || !stream->HasRegisteredID())) {
result = NS_ERROR_NET_RESET; // can be restarted
} else if (stream->RecvdData()) {
result = NS_ERROR_NET_PARTIAL_TRANSFER;
} else {
result = NS_ERROR_ABORT;
}
self->CloseStream(stream, result);
return PL_DHASH_NEXT;
}
PLDHashOperator
Http2Session::GoAwayEnumerator(nsAHttpTransaction *key,
nsAutoPtr<Http2Stream> &stream,
void *closure)
{
Http2Session *self = static_cast<Http2Session *>(closure);
// these streams were not processed by the server and can be restarted.
// Do that after the enumerator completes to avoid the risk of
// a restart event re-entrantly modifying this hash. Be sure not to restart
// a pushed (even numbered) stream
if ((stream->StreamID() > self->mGoAwayID && (stream->StreamID() & 1)) ||
!stream->HasRegisteredID()) {
self->mGoAwayStreamsToRestart.Push(stream);
}
return PL_DHASH_NEXT;
}
Http2Session::~Http2Session()
{
LOG3(("Http2Session::~Http2Session %p mDownstreamState=%X",
this, mDownstreamState));
mStreamTransactionHash.Enumerate(ShutdownEnumerator, this);
Telemetry::Accumulate(Telemetry::SPDY_PARALLEL_STREAMS, mConcurrentHighWater);
Telemetry::Accumulate(Telemetry::SPDY_REQUEST_PER_CONN, (mNextStreamID - 1) / 2);
Telemetry::Accumulate(Telemetry::SPDY_SERVER_INITIATED_STREAMS,
mServerPushedResources);
Telemetry::Accumulate(Telemetry::SPDY_GOAWAY_LOCAL, mClientGoAwayReason);
Telemetry::Accumulate(Telemetry::SPDY_GOAWAY_PEER, mPeerGoAwayReason);
}
void
Http2Session::LogIO(Http2Session *self, Http2Stream *stream,
const char *label,
const char *data, uint32_t datalen)
{
if (!LOG5_ENABLED())
return;
LOG5(("Http2Session::LogIO %p stream=%p id=0x%X [%s]",
self, stream, stream ? stream->StreamID() : 0, label));
// Max line is (16 * 3) + 10(prefix) + newline + null
char linebuf[128];
uint32_t index;
char *line = linebuf;
linebuf[127] = 0;
for (index = 0; index < datalen; ++index) {
if (!(index % 16)) {
if (index) {
*line = 0;
LOG5(("%s", linebuf));
}
line = linebuf;
snprintf(line, 128, "%08X: ", index);
line += 10;
}
snprintf(line, 128 - (line - linebuf), "%02X ", (reinterpret_cast<const uint8_t *>(data))[index]);
line += 3;
}
if (index) {
*line = 0;
LOG5(("%s", linebuf));
}
}
typedef nsresult (*Http2ControlFx) (Http2Session *self);
static Http2ControlFx sControlFunctions[] = {
nullptr, // type 0 data is not a control function
Http2Session::RecvHeaders,
Http2Session::RecvPriority,
Http2Session::RecvRstStream,
Http2Session::RecvSettings,
Http2Session::RecvPushPromise,
Http2Session::RecvPing,
Http2Session::RecvGoAway,
Http2Session::RecvWindowUpdate,
Http2Session::RecvContinuation,
Http2Session::RecvAltSvc // extension for type 0x0A
};
bool
Http2Session::RoomForMoreConcurrent()
{
MOZ_ASSERT(PR_GetCurrentThread() == gSocketThread);
return (mConcurrent < mMaxConcurrent);
}
bool
Http2Session::RoomForMoreStreams()
{
if (mNextStreamID + mStreamTransactionHash.Count() * 2 > kMaxStreamID)
return false;
return !mShouldGoAway;
}
PRIntervalTime
Http2Session::IdleTime()
{
return PR_IntervalNow() - mLastDataReadEpoch;
}
uint32_t
Http2Session::ReadTimeoutTick(PRIntervalTime now)
{
MOZ_ASSERT(PR_GetCurrentThread() == gSocketThread);
LOG3(("Http2Session::ReadTimeoutTick %p delta since last read %ds\n",
this, PR_IntervalToSeconds(now - mLastReadEpoch)));
if (!mPingThreshold)
return UINT32_MAX;
if ((now - mLastReadEpoch) < mPingThreshold) {
// recent activity means ping is not an issue
if (mPingSentEpoch) {
mPingSentEpoch = 0;
if (mPreviousUsed) {
// restore the former value
mPingThreshold = mPreviousPingThreshold;
mPreviousUsed = false;
}
}
return PR_IntervalToSeconds(mPingThreshold) -
PR_IntervalToSeconds(now - mLastReadEpoch);
}
if (mPingSentEpoch) {
LOG3(("Http2Session::ReadTimeoutTick %p handle outstanding ping\n"));
if ((now - mPingSentEpoch) >= gHttpHandler->SpdyPingTimeout()) {
LOG3(("Http2Session::ReadTimeoutTick %p Ping Timer Exhaustion\n", this));
mPingSentEpoch = 0;
Close(NS_ERROR_NET_TIMEOUT);
return UINT32_MAX;
}
return 1; // run the tick aggressively while ping is outstanding
}
LOG3(("Http2Session::ReadTimeoutTick %p generating ping\n", this));
mPingSentEpoch = PR_IntervalNow();
if (!mPingSentEpoch) {
mPingSentEpoch = 1; // avoid the 0 sentinel value
}
GeneratePing(false);
ResumeRecv(); // read the ping reply
// Check for orphaned push streams. This looks expensive, but generally the
// list is empty.
Http2PushedStream *deleteMe;
TimeStamp timestampNow;
do {
deleteMe = nullptr;
for (uint32_t index = mPushedStreams.Length();
index > 0 ; --index) {
Http2PushedStream *pushedStream = mPushedStreams[index - 1];
if (timestampNow.IsNull())
timestampNow = TimeStamp::Now(); // lazy initializer
// if stream finished, but is not connected, and its been like that for
// long then cleanup the stream.
if (pushedStream->IsOrphaned(timestampNow))
{
LOG3(("Http2Session Timeout Pushed Stream %p 0x%X\n",
this, pushedStream->StreamID()));
deleteMe = pushedStream;
break; // don't CleanupStream() while iterating this vector
}
}
if (deleteMe)
CleanupStream(deleteMe, NS_ERROR_ABORT, CANCEL_ERROR);
} while (deleteMe);
return 1; // run the tick aggressively while ping is outstanding
}
uint32_t
Http2Session::RegisterStreamID(Http2Stream *stream, uint32_t aNewID)
{
MOZ_ASSERT(PR_GetCurrentThread() == gSocketThread);
MOZ_ASSERT(mNextStreamID < 0xfffffff0,
"should have stopped admitting streams");
MOZ_ASSERT(!(aNewID & 1),
"0 for autoassign pull, otherwise explicit even push assignment");
if (!aNewID) {
// auto generate a new pull stream ID
aNewID = mNextStreamID;
MOZ_ASSERT(aNewID & 1, "pull ID must be odd.");
mNextStreamID += 2;
}
LOG3(("Http2Session::RegisterStreamID session=%p stream=%p id=0x%X "
"concurrent=%d",this, stream, aNewID, mConcurrent));
// We've used up plenty of ID's on this session. Start
// moving to a new one before there is a crunch involving
// server push streams or concurrent non-registered submits
if (aNewID >= kMaxStreamID)
mShouldGoAway = true;
// integrity check
if (mStreamIDHash.Get(aNewID)) {
LOG3((" New ID already present\n"));
MOZ_ASSERT(false, "New ID already present in mStreamIDHash");
mShouldGoAway = true;
return kDeadStreamID;
}
mStreamIDHash.Put(aNewID, stream);
return aNewID;
}
bool
Http2Session::AddStream(nsAHttpTransaction *aHttpTransaction,
int32_t aPriority,
bool aUseTunnel,
nsIInterfaceRequestor *aCallbacks)
{
MOZ_ASSERT(PR_GetCurrentThread() == gSocketThread);
// integrity check
if (mStreamTransactionHash.Get(aHttpTransaction)) {
LOG3((" New transaction already present\n"));
MOZ_ASSERT(false, "AddStream duplicate transaction pointer");
return false;
}
if (!mConnection) {
mConnection = aHttpTransaction->Connection();
}
aHttpTransaction->SetConnection(this);
if (aUseTunnel) {
LOG3(("Http2Session::AddStream session=%p trans=%p OnTunnel",
this, aHttpTransaction));
DispatchOnTunnel(aHttpTransaction, aCallbacks);
return true;
}
Http2Stream *stream = new Http2Stream(aHttpTransaction, this, aPriority);
LOG3(("Http2Session::AddStream session=%p stream=%p serial=%u "
"NextID=0x%X (tentative)", this, stream, mSerial, mNextStreamID));
mStreamTransactionHash.Put(aHttpTransaction, stream);
mReadyForWrite.Push(stream);
SetWriteCallbacks();
// Kick off the SYN transmit without waiting for the poll loop
// This won't work for the first stream because there is no segment reader
// yet.
if (mSegmentReader) {
uint32_t countRead;
ReadSegments(nullptr, kDefaultBufferSize, &countRead);
}
if (!(aHttpTransaction->Caps() & NS_HTTP_ALLOW_KEEPALIVE) &&
!aHttpTransaction->IsNullTransaction()) {
LOG3(("Http2Session::AddStream %p transaction %p forces keep-alive off.\n",
this, aHttpTransaction));
DontReuse();
}
return true;
}
void
Http2Session::QueueStream(Http2Stream *stream)
{
// will be removed via processpending or a shutdown path
MOZ_ASSERT(PR_GetCurrentThread() == gSocketThread);
MOZ_ASSERT(!stream->CountAsActive());
MOZ_ASSERT(!stream->Queued());
LOG3(("Http2Session::QueueStream %p stream %p queued.", this, stream));
#ifdef DEBUG
int32_t qsize = mQueuedStreams.GetSize();
for (int32_t i = 0; i < qsize; i++) {
Http2Stream *qStream = static_cast<Http2Stream *>(mQueuedStreams.ObjectAt(i));
MOZ_ASSERT(qStream != stream);
MOZ_ASSERT(qStream->Queued());
}
#endif
stream->SetQueued(true);
mQueuedStreams.Push(stream);
}
void
Http2Session::ProcessPending()
{
MOZ_ASSERT(PR_GetCurrentThread() == gSocketThread);
Http2Stream*stream;
while (RoomForMoreConcurrent() &&
(stream = static_cast<Http2Stream *>(mQueuedStreams.PopFront()))) {
LOG3(("Http2Session::ProcessPending %p stream %p woken from queue.",
this, stream));
MOZ_ASSERT(!stream->CountAsActive());
MOZ_ASSERT(stream->Queued());
stream->SetQueued(false);
mReadyForWrite.Push(stream);
SetWriteCallbacks();
}
}
nsresult
Http2Session::NetworkRead(nsAHttpSegmentWriter *writer, char *buf,
uint32_t count, uint32_t *countWritten)
{
MOZ_ASSERT(PR_GetCurrentThread() == gSocketThread);
if (!count) {
*countWritten = 0;
return NS_OK;
}
nsresult rv = writer->OnWriteSegment(buf, count, countWritten);
if (NS_SUCCEEDED(rv) && *countWritten > 0)
mLastReadEpoch = PR_IntervalNow();
return rv;
}
void
Http2Session::SetWriteCallbacks()
{
if (mConnection && (GetWriteQueueSize() || mOutputQueueUsed))
mConnection->ResumeSend();
}
void
Http2Session::RealignOutputQueue()
{
mOutputQueueUsed -= mOutputQueueSent;
memmove(mOutputQueueBuffer.get(),
mOutputQueueBuffer.get() + mOutputQueueSent,
mOutputQueueUsed);
mOutputQueueSent = 0;
}
void
Http2Session::FlushOutputQueue()
{
if (!mSegmentReader || !mOutputQueueUsed)
return;
nsresult rv;
uint32_t countRead;
uint32_t avail = mOutputQueueUsed - mOutputQueueSent;
rv = mSegmentReader->
OnReadSegment(mOutputQueueBuffer.get() + mOutputQueueSent, avail,
&countRead);
LOG3(("Http2Session::FlushOutputQueue %p sz=%d rv=%x actual=%d",
this, avail, rv, countRead));
// Dont worry about errors on write, we will pick this up as a read error too
if (NS_FAILED(rv))
return;
if (countRead == avail) {
mOutputQueueUsed = 0;
mOutputQueueSent = 0;
return;
}
mOutputQueueSent += countRead;
// If the output queue is close to filling up and we have sent out a good
// chunk of data from the beginning then realign it.
if ((mOutputQueueSent >= kQueueMinimumCleanup) &&
((mOutputQueueSize - mOutputQueueUsed) < kQueueTailRoom)) {
RealignOutputQueue();
}
}
void
Http2Session::DontReuse()
{
mShouldGoAway = true;
if (!mStreamTransactionHash.Count())
Close(NS_OK);
}
uint32_t
Http2Session::GetWriteQueueSize()
{
MOZ_ASSERT(PR_GetCurrentThread() == gSocketThread);
return mReadyForWrite.GetSize();
}
void
Http2Session::ChangeDownstreamState(enum internalStateType newState)
{
MOZ_ASSERT(PR_GetCurrentThread() == gSocketThread);
LOG3(("Http2Session::ChangeDownstreamState() %p from %X to %X",
this, mDownstreamState, newState));
mDownstreamState = newState;
}
void
Http2Session::ResetDownstreamState()
{
MOZ_ASSERT(PR_GetCurrentThread() == gSocketThread);
LOG3(("Http2Session::ResetDownstreamState() %p", this));
ChangeDownstreamState(BUFFERING_FRAME_HEADER);
if (mInputFrameFinal && mInputFrameDataStream) {
mInputFrameFinal = false;
LOG3((" SetRecvdFin id=0x%x\n", mInputFrameDataStream->StreamID()));
mInputFrameDataStream->SetRecvdFin(true);
MaybeDecrementConcurrent(mInputFrameDataStream);
}
mInputFrameFinal = false;
mInputFrameBufferUsed = 0;
mInputFrameDataStream = nullptr;
}
// return true if activated (and counted against max)
// otherwise return false and queue
bool
Http2Session::TryToActivate(Http2Stream *aStream)
{
if (aStream->Queued()) {
LOG3(("Http2Session::TryToActivate %p stream=%p already queued.\n", this, aStream));
return false;
}
if (!RoomForMoreConcurrent()) {
LOG3(("Http2Session::TryToActivate %p stream=%p no room for more concurrent "
"streams %d\n", this, aStream));
QueueStream(aStream);
return false;
}
LOG3(("Http2Session::TryToActivate %p stream=%p\n", this, aStream));
IncrementConcurrent(aStream);
return true;
}
void
Http2Session::IncrementConcurrent(Http2Stream *stream)
{
MOZ_ASSERT(PR_GetCurrentThread() == gSocketThread);
MOZ_ASSERT(!stream->StreamID() || (stream->StreamID() & 1),
"Do not activate pushed streams");
nsAHttpTransaction *trans = stream->Transaction();
if (!trans || !trans->IsNullTransaction() || trans->QuerySpdyConnectTransaction()) {
MOZ_ASSERT(!stream->CountAsActive());
stream->SetCountAsActive(true);
++mConcurrent;
if (mConcurrent > mConcurrentHighWater) {
mConcurrentHighWater = mConcurrent;
}
LOG3(("Http2Session::IncrementCounter %p counting stream %p Currently %d "
"streams in session, high water mark is %d\n",
this, stream, mConcurrent, mConcurrentHighWater));
}
}
// call with data length (i.e. 0 for 0 data bytes - ignore 9 byte header)
// dest must have 9 bytes of allocated space
template<typename charType> void
Http2Session::CreateFrameHeader(charType dest, uint16_t frameLength,
uint8_t frameType, uint8_t frameFlags,
uint32_t streamID)
{
MOZ_ASSERT(frameLength <= kMaxFrameData, "framelength too large");
MOZ_ASSERT(!(streamID & 0x80000000));
dest[0] = 0x00;
NetworkEndian::writeUint16(dest + 1, frameLength);
dest[3] = frameType;
dest[4] = frameFlags;
NetworkEndian::writeUint32(dest + 5, streamID);
}
char *
Http2Session::EnsureOutputBuffer(uint32_t spaceNeeded)
{
// this is an infallible allocation (if an allocation is
// needed, which is probably isn't)
EnsureBuffer(mOutputQueueBuffer, mOutputQueueUsed + spaceNeeded,
mOutputQueueUsed, mOutputQueueSize);
return mOutputQueueBuffer.get() + mOutputQueueUsed;
}
template void
Http2Session::CreateFrameHeader(char *dest, uint16_t frameLength,
uint8_t frameType, uint8_t frameFlags,
uint32_t streamID);
template void
Http2Session::CreateFrameHeader(uint8_t *dest, uint16_t frameLength,
uint8_t frameType, uint8_t frameFlags,
uint32_t streamID);
void
Http2Session::MaybeDecrementConcurrent(Http2Stream *aStream)
{
MOZ_ASSERT(PR_GetCurrentThread() == gSocketThread);
LOG3(("MaybeDecrementConcurrent %p id=0x%X concurrent=%d active=%d\n",
this, aStream->StreamID(), mConcurrent, aStream->CountAsActive()));
if (!aStream->CountAsActive())
return;
MOZ_ASSERT(mConcurrent);
aStream->SetCountAsActive(false);
--mConcurrent;
ProcessPending();
}
// Need to decompress some data in order to keep the compression
// context correct, but we really don't care what the result is
nsresult
Http2Session::UncompressAndDiscard(bool isPush)
{
nsresult rv;
nsAutoCString trash;
rv = mDecompressor.DecodeHeaderBlock(reinterpret_cast<const uint8_t *>(mDecompressBuffer.BeginReading()),
mDecompressBuffer.Length(), trash, isPush);
mDecompressBuffer.Truncate();
if (NS_FAILED(rv)) {
LOG3(("Http2Session::UncompressAndDiscard %p Compression Error\n",
this));
mGoAwayReason = COMPRESSION_ERROR;
return rv;
}
return NS_OK;
}
void
Http2Session::GeneratePing(bool isAck)
{
MOZ_ASSERT(PR_GetCurrentThread() == gSocketThread);
LOG3(("Http2Session::GeneratePing %p isAck=%d\n", this, isAck));
char *packet = EnsureOutputBuffer(kFrameHeaderBytes + 8);
mOutputQueueUsed += kFrameHeaderBytes + 8;
if (isAck) {
CreateFrameHeader(packet, 8, FRAME_TYPE_PING, kFlag_ACK, 0);
memcpy(packet + kFrameHeaderBytes,
mInputFrameBuffer.get() + kFrameHeaderBytes, 8);
} else {
CreateFrameHeader(packet, 8, FRAME_TYPE_PING, 0, 0);
memset(packet + kFrameHeaderBytes, 0, 8);
}
LogIO(this, nullptr, "Generate Ping", packet, kFrameHeaderBytes + 8);
FlushOutputQueue();
}
void
Http2Session::GenerateSettingsAck()
{
// need to generate ack of this settings frame
MOZ_ASSERT(PR_GetCurrentThread() == gSocketThread);
LOG3(("Http2Session::GenerateSettingsAck %p\n", this));
char *packet = EnsureOutputBuffer(kFrameHeaderBytes);
mOutputQueueUsed += kFrameHeaderBytes;
CreateFrameHeader(packet, 0, FRAME_TYPE_SETTINGS, kFlag_ACK, 0);
LogIO(this, nullptr, "Generate Settings ACK", packet, kFrameHeaderBytes);
FlushOutputQueue();
}
void
Http2Session::GeneratePriority(uint32_t aID, uint8_t aPriorityWeight)
{
MOZ_ASSERT(PR_GetCurrentThread() == gSocketThread);
LOG3(("Http2Session::GeneratePriority %p %X %X\n",
this, aID, aPriorityWeight));
uint32_t frameSize = kFrameHeaderBytes + 5;
char *packet = EnsureOutputBuffer(frameSize);
mOutputQueueUsed += frameSize;
CreateFrameHeader(packet, 5, FRAME_TYPE_PRIORITY, 0, aID);
NetworkEndian::writeUint32(packet + kFrameHeaderBytes, 0);
memcpy(packet + frameSize - 1, &aPriorityWeight, 1);
LogIO(this, nullptr, "Generate Priority", packet, frameSize);
FlushOutputQueue();
}
void
Http2Session::GenerateRstStream(uint32_t aStatusCode, uint32_t aID)
{
MOZ_ASSERT(PR_GetCurrentThread() == gSocketThread);
// make sure we don't do this twice for the same stream (at least if we
// have a stream entry for it)
Http2Stream *stream = mStreamIDHash.Get(aID);
if (stream) {
if (stream->SentReset())
return;
stream->SetSentReset(true);
}
LOG3(("Http2Session::GenerateRst %p 0x%X %d\n", this, aID, aStatusCode));
uint32_t frameSize = kFrameHeaderBytes + 4;
char *packet = EnsureOutputBuffer(frameSize);
mOutputQueueUsed += frameSize;
CreateFrameHeader(packet, 4, FRAME_TYPE_RST_STREAM, 0, aID);
NetworkEndian::writeUint32(packet + kFrameHeaderBytes, aStatusCode);
LogIO(this, nullptr, "Generate Reset", packet, frameSize);
FlushOutputQueue();
}
void
Http2Session::GenerateGoAway(uint32_t aStatusCode)
{
MOZ_ASSERT(PR_GetCurrentThread() == gSocketThread);
LOG3(("Http2Session::GenerateGoAway %p code=%X\n", this, aStatusCode));
mClientGoAwayReason = aStatusCode;
uint32_t frameSize = kFrameHeaderBytes + 8;
char *packet = EnsureOutputBuffer(frameSize);
mOutputQueueUsed += frameSize;
CreateFrameHeader(packet, 8, FRAME_TYPE_GOAWAY, 0, 0);
// last-good-stream-id are bytes 9-12 reflecting pushes
NetworkEndian::writeUint32(packet + kFrameHeaderBytes, mOutgoingGoAwayID);
// bytes 13-16 are the status code.
NetworkEndian::writeUint32(packet + frameSize - 4, aStatusCode);
LogIO(this, nullptr, "Generate GoAway", packet, frameSize);
FlushOutputQueue();
}
// The Hello is comprised of
// 1] 24 octets of magic, which are designed to
// flush out silent but broken intermediaries
// 2] a settings frame which sets a small flow control window for pushes
// 3] a window update frame which creates a large session flow control window
// 4] 5 priority frames for streams which will never be opened with headers
// these streams (3, 5, 7, 9, b) build a dependency tree that all other
// streams will be direct leaves of.
void
Http2Session::SendHello()
{
MOZ_ASSERT(PR_GetCurrentThread() == gSocketThread);
LOG3(("Http2Session::SendHello %p\n", this));
// sized for magic + 4 settings and a session window update and 5 priority frames
// 24 magic, 33 for settings (9 header + 4 settings @6), 13 for window update,
// 5 priority frames at 14 (9 + 5) each
static const uint32_t maxSettings = 4;
static const uint32_t prioritySize = 5 * (kFrameHeaderBytes + 5);
static const uint32_t maxDataLen = 24 + kFrameHeaderBytes + maxSettings * 6 + 13 + prioritySize;
char *packet = EnsureOutputBuffer(maxDataLen);
memcpy(packet, kMagicHello, 24);
mOutputQueueUsed += 24;
LogIO(this, nullptr, "Magic Connection Header", packet, 24);
packet = mOutputQueueBuffer.get() + mOutputQueueUsed;
memset(packet, 0, maxDataLen - 24);
// frame header will be filled in after we know how long the frame is
uint8_t numberOfEntries = 0;
// entries need to be listed in order by ID
// 1st entry is bytes 9 to 14
// 2nd entry is bytes 15 to 20
// 3rd entry is bytes 21 to 26
// 4th entry is bytes 27 to 32
if (!gHttpHandler->AllowPush()) {
// If we don't support push then set MAX_CONCURRENT to 0 and also
// set ENABLE_PUSH to 0
NetworkEndian::writeUint16(packet + kFrameHeaderBytes + (6 * numberOfEntries), SETTINGS_TYPE_ENABLE_PUSH);
// The value portion of the setting pair is already initialized to 0
numberOfEntries++;
NetworkEndian::writeUint16(packet + kFrameHeaderBytes + (6 * numberOfEntries), SETTINGS_TYPE_MAX_CONCURRENT);
// The value portion of the setting pair is already initialized to 0
numberOfEntries++;
mWaitingForSettingsAck = true;
}
// Advertise the Push RWIN for the session, and on each new pull stream
// send a window update
NetworkEndian::writeUint16(packet + kFrameHeaderBytes + (6 * numberOfEntries), SETTINGS_TYPE_INITIAL_WINDOW);
NetworkEndian::writeUint32(packet + kFrameHeaderBytes + (6 * numberOfEntries) + 2, mPushAllowance);
numberOfEntries++;
// Make sure the other endpoint knows that we're sticking to the default max
// frame size
NetworkEndian::writeUint16(packet + kFrameHeaderBytes + (6 * numberOfEntries), SETTINGS_TYPE_MAX_FRAME_SIZE);
NetworkEndian::writeUint32(packet + kFrameHeaderBytes + (6 * numberOfEntries) + 2, kMaxFrameData);
numberOfEntries++;
MOZ_ASSERT(numberOfEntries <= maxSettings);
uint32_t dataLen = 6 * numberOfEntries;
CreateFrameHeader(packet, dataLen, FRAME_TYPE_SETTINGS, 0, 0);
mOutputQueueUsed += kFrameHeaderBytes + dataLen;
LogIO(this, nullptr, "Generate Settings", packet, kFrameHeaderBytes + dataLen);
// now bump the local session window from 64KB
uint32_t sessionWindowBump = mInitialRwin - kDefaultRwin;
if (kDefaultRwin < mInitialRwin) {
// send a window update for the session (Stream 0) for something large
mLocalSessionWindow = mInitialRwin;
packet = mOutputQueueBuffer.get() + mOutputQueueUsed;
CreateFrameHeader(packet, 4, FRAME_TYPE_WINDOW_UPDATE, 0, 0);
mOutputQueueUsed += kFrameHeaderBytes + 4;
NetworkEndian::writeUint32(packet + kFrameHeaderBytes, sessionWindowBump);
LOG3(("Session Window increase at start of session %p %u\n",
this, sessionWindowBump));
LogIO(this, nullptr, "Session Window Bump ", packet, kFrameHeaderBytes + 4);
}
if (gHttpHandler->UseH2Deps() && gHttpHandler->CriticalRequestPrioritization()) {
mUseH2Deps = true;
MOZ_ASSERT(mNextStreamID == kLeaderGroupID);
CreatePriorityNode(kLeaderGroupID, 0, 200, "leader");
mNextStreamID += 2;
MOZ_ASSERT(mNextStreamID == kOtherGroupID);
CreatePriorityNode(kOtherGroupID, 0, 100, "other");
mNextStreamID += 2;
MOZ_ASSERT(mNextStreamID == kBackgroundGroupID);
CreatePriorityNode(kBackgroundGroupID, 0, 0, "background");
mNextStreamID += 2;
MOZ_ASSERT(mNextStreamID == kSpeculativeGroupID);
CreatePriorityNode(kSpeculativeGroupID, kBackgroundGroupID, 0, "speculative");
mNextStreamID += 2;
MOZ_ASSERT(mNextStreamID == kFollowerGroupID);
CreatePriorityNode(kFollowerGroupID, kLeaderGroupID, 0, "follower");
mNextStreamID += 2;
}
FlushOutputQueue();
}
void
Http2Session::CreatePriorityNode(uint32_t streamID, uint32_t dependsOn, uint8_t weight,
const char *label)
{
char *packet = mOutputQueueBuffer.get() + mOutputQueueUsed;
CreateFrameHeader(packet, 5, FRAME_TYPE_PRIORITY, 0, streamID);
mOutputQueueUsed += kFrameHeaderBytes + 5;
NetworkEndian::writeUint32(packet + kFrameHeaderBytes, dependsOn); // depends on
packet[kFrameHeaderBytes + 4] = weight; // weight
LOG3(("Http2Session %p generate Priority Frame 0x%X depends on 0x%X "
"weight %d for %s class\n", this, streamID, dependsOn, weight, label));
LogIO(this, nullptr, "Priority dep node", packet, kFrameHeaderBytes + 5);
}
// perform a bunch of integrity checks on the stream.
// returns true if passed, false (plus LOG and ABORT) if failed.
bool
Http2Session::VerifyStream(Http2Stream *aStream, uint32_t aOptionalID = 0)
{
// This is annoying, but at least it is O(1)
MOZ_ASSERT(PR_GetCurrentThread() == gSocketThread);
#ifndef DEBUG
// Only do the real verification in debug builds
return true;
#endif
if (!aStream)
return true;
uint32_t test = 0;
do {
if (aStream->StreamID() == kDeadStreamID)
break;
nsAHttpTransaction *trans = aStream->Transaction();
test++;
if (!trans)
break;
test++;
if (mStreamTransactionHash.Get(trans) != aStream)
break;
if (aStream->StreamID()) {
Http2Stream *idStream = mStreamIDHash.Get(aStream->StreamID());
test++;
if (idStream != aStream)
break;
if (aOptionalID) {
test++;
if (idStream->StreamID() != aOptionalID)
break;
}
}
// tests passed
return true;
} while (0);
LOG3(("Http2Session %p VerifyStream Failure %p stream->id=0x%X "
"optionalID=0x%X trans=%p test=%d\n",
this, aStream, aStream->StreamID(),
aOptionalID, aStream->Transaction(), test));
MOZ_ASSERT(false, "VerifyStream");
return false;
}
void
Http2Session::CleanupStream(Http2Stream *aStream, nsresult aResult,
errorType aResetCode)
{
MOZ_ASSERT(PR_GetCurrentThread() == gSocketThread);
LOG3(("Http2Session::CleanupStream %p %p 0x%X %X\n",
this, aStream, aStream ? aStream->StreamID() : 0, aResult));
if (!aStream) {
return;
}
Http2PushedStream *pushSource = aStream->PushSource();
if (pushSource) {
// aStream is a synthetic attached to an even push
MOZ_ASSERT(pushSource->GetConsumerStream() == aStream);
MOZ_ASSERT(!aStream->StreamID());
MOZ_ASSERT(!(pushSource->StreamID() & 0x1));
aStream->ClearPushSource();
}
if (aStream->DeferCleanup(aResult)) {
LOG3(("Http2Session::CleanupStream 0x%X deferred\n", aStream->StreamID()));
return;
}
if (!VerifyStream(aStream)) {
LOG3(("Http2Session::CleanupStream failed to verify stream\n"));
return;
}
if (!aStream->RecvdFin() && !aStream->RecvdReset() && aStream->StreamID()) {
LOG3(("Stream had not processed recv FIN, sending RST code %X\n", aResetCode));
GenerateRstStream(aResetCode, aStream->StreamID());
}
CloseStream(aStream, aResult);
// Remove the stream from the ID hash table and, if an even id, the pushed
// table too.
uint32_t id = aStream->StreamID();
if (id > 0) {
mStreamIDHash.Remove(id);
if (!(id & 1)) {
mPushedStreams.RemoveElement(aStream);
Http2PushedStream *pushStream = static_cast<Http2PushedStream *>(aStream);
nsAutoCString hashKey;
pushStream->GetHashKey(hashKey);
nsISchedulingContext *schedulingContext = aStream->SchedulingContext();
if (schedulingContext) {
SpdyPushCache *cache = nullptr;
schedulingContext->GetSpdyPushCache(&cache);
if (cache) {
Http2PushedStream *trash = cache->RemovePushedStreamHttp2(hashKey);
LOG3(("Http2Session::CleanupStream %p aStream=%p pushStream=%p trash=%p",
this, aStream, pushStream, trash));
}
}
}
}
RemoveStreamFromQueues(aStream);
// removing from the stream transaction hash will
// delete the Http2Stream and drop the reference to
// its transaction
mStreamTransactionHash.Remove(aStream->Transaction());
if (mShouldGoAway && !mStreamTransactionHash.Count())
Close(NS_OK);
if (pushSource) {
pushSource->SetDeferCleanupOnSuccess(false);
CleanupStream(pushSource, aResult, aResetCode);
}
}
void
Http2Session::CleanupStream(uint32_t aID, nsresult aResult, errorType aResetCode)
{
MOZ_ASSERT(PR_GetCurrentThread() == gSocketThread);
Http2Stream *stream = mStreamIDHash.Get(aID);
LOG3(("Http2Session::CleanupStream %p by ID 0x%X to stream %p\n",
this, aID, stream));
if (!stream) {
return;
}
CleanupStream(stream, aResult, aResetCode);
}
static void RemoveStreamFromQueue(Http2Stream *aStream, nsDeque &queue)
{
size_t size = queue.GetSize();
for (size_t count = 0; count < size; ++count) {
Http2Stream *stream = static_cast<Http2Stream *>(queue.PopFront());
if (stream != aStream)
queue.Push(stream);
}
}
void
Http2Session::RemoveStreamFromQueues(Http2Stream *aStream)
{
RemoveStreamFromQueue(aStream, mReadyForWrite);
RemoveStreamFromQueue(aStream, mQueuedStreams);
RemoveStreamFromQueue(aStream, mPushesReadyForRead);
RemoveStreamFromQueue(aStream, mSlowConsumersReadyForRead);
}
void
Http2Session::CloseStream(Http2Stream *aStream, nsresult aResult)
{
MOZ_ASSERT(PR_GetCurrentThread() == gSocketThread);
LOG3(("Http2Session::CloseStream %p %p 0x%x %X\n",
this, aStream, aStream->StreamID(), aResult));
MaybeDecrementConcurrent(aStream);
// Check if partial frame reader
if (aStream == mInputFrameDataStream) {
LOG3(("Stream had active partial read frame on close"));
ChangeDownstreamState(DISCARDING_DATA_FRAME);
mInputFrameDataStream = nullptr;
}
RemoveStreamFromQueues(aStream);
if (aStream->IsTunnel()) {
UnRegisterTunnel(aStream);
}
// Send the stream the close() indication
aStream->Close(aResult);
}
nsresult
Http2Session::SetInputFrameDataStream(uint32_t streamID)
{
mInputFrameDataStream = mStreamIDHash.Get(streamID);
if (VerifyStream(mInputFrameDataStream, streamID))
return NS_OK;
LOG3(("Http2Session::SetInputFrameDataStream failed to verify 0x%X\n",
streamID));
mInputFrameDataStream = nullptr;
return NS_ERROR_UNEXPECTED;
}
nsresult
Http2Session::ParsePadding(uint8_t &paddingControlBytes, uint16_t &paddingLength)
{
if (mInputFrameFlags & kFlag_PADDED) {
paddingLength = *reinterpret_cast<uint8_t *>(&mInputFrameBuffer[kFrameHeaderBytes]);
paddingControlBytes = 1;
} else {
paddingLength = 0;
paddingControlBytes = 0;
}
if (static_cast<uint32_t>(paddingLength + paddingControlBytes) > mInputFrameDataSize) {
// This is fatal to the session
LOG3(("Http2Session::ParsePadding %p stream 0x%x PROTOCOL_ERROR "
"paddingLength %d > frame size %d\n",
this, mInputFrameID, paddingLength, mInputFrameDataSize));
RETURN_SESSION_ERROR(this, PROTOCOL_ERROR);
}
return NS_OK;
}
nsresult
Http2Session::RecvHeaders(Http2Session *self)
{
MOZ_ASSERT(self->mInputFrameType == FRAME_TYPE_HEADERS ||
self->mInputFrameType == FRAME_TYPE_CONTINUATION);
bool isContinuation = self->mExpectedHeaderID != 0;
// If this doesn't have END_HEADERS set on it then require the next
// frame to be HEADERS of the same ID
bool endHeadersFlag = self->mInputFrameFlags & kFlag_END_HEADERS;
if (endHeadersFlag)
self->mExpectedHeaderID = 0;
else
self->mExpectedHeaderID = self->mInputFrameID;
uint32_t priorityLen = 0;
if (self->mInputFrameFlags & kFlag_PRIORITY) {
priorityLen = 5;
}
self->SetInputFrameDataStream(self->mInputFrameID);
// Find out how much padding this frame has, so we can only extract the real
// header data from the frame.
uint16_t paddingLength = 0;
uint8_t paddingControlBytes = 0;
nsresult rv;
if (!isContinuation) {
self->mDecompressBuffer.Truncate();
rv = self->ParsePadding(paddingControlBytes, paddingLength);
if (NS_FAILED(rv)) {
return rv;
}
}
LOG3(("Http2Session::RecvHeaders %p stream 0x%X priorityLen=%d stream=%p "
"end_stream=%d end_headers=%d priority_group=%d "
"paddingLength=%d padded=%d\n",
self, self->mInputFrameID, priorityLen, self->mInputFrameDataStream,
self->mInputFrameFlags & kFlag_END_STREAM,
self->mInputFrameFlags & kFlag_END_HEADERS,
self->mInputFrameFlags & kFlag_PRIORITY,
paddingLength,
self->mInputFrameFlags & kFlag_PADDED));
if ((paddingControlBytes + priorityLen + paddingLength) > self->mInputFrameDataSize) {
// This is fatal to the session
RETURN_SESSION_ERROR(self, PROTOCOL_ERROR);
}
if (!self->mInputFrameDataStream) {
// Cannot find stream. We can continue the session, but we need to
// uncompress the header block to maintain the correct compression context
LOG3(("Http2Session::RecvHeaders %p lookup mInputFrameID stream "
"0x%X failed. NextStreamID = 0x%X\n",
self, self->mInputFrameID, self->mNextStreamID));
if (self->mInputFrameID >= self->mNextStreamID)
self->GenerateRstStream(PROTOCOL_ERROR, self->mInputFrameID);
self->mDecompressBuffer.Append(&self->mInputFrameBuffer[kFrameHeaderBytes + paddingControlBytes + priorityLen],
self->mInputFrameDataSize - paddingControlBytes - priorityLen - paddingLength);
if (self->mInputFrameFlags & kFlag_END_HEADERS) {
rv = self->UncompressAndDiscard(false);
if (NS_FAILED(rv)) {
LOG3(("Http2Session::RecvHeaders uncompress failed\n"));
// this is fatal to the session
self->mGoAwayReason = COMPRESSION_ERROR;
return rv;
}
}
self->ResetDownstreamState();
return NS_OK;
}
// make sure this is either the first headers or a trailer
if (self->mInputFrameDataStream->AllHeadersReceived() &&
!(self->mInputFrameFlags & kFlag_END_STREAM)) {
// Any header block after the first that does *not* end the stream is
// illegal.
LOG3(("Http2Session::Illegal Extra HeaderBlock %p 0x%X\n", self, self->mInputFrameID));
RETURN_SESSION_ERROR(self, PROTOCOL_ERROR);
}
// queue up any compression bytes
self->mDecompressBuffer.Append(&self->mInputFrameBuffer[kFrameHeaderBytes + paddingControlBytes + priorityLen],
self->mInputFrameDataSize - paddingControlBytes - priorityLen - paddingLength);
self->mInputFrameDataStream->UpdateTransportReadEvents(self->mInputFrameDataSize);
self->mLastDataReadEpoch = self->mLastReadEpoch;
if (!endHeadersFlag) { // more are coming - don't process yet
self->ResetDownstreamState();
return NS_OK;
}
rv = self->ResponseHeadersComplete();
if (rv == NS_ERROR_ILLEGAL_VALUE) {
LOG3(("Http2Session::RecvHeaders %p PROTOCOL_ERROR detected stream 0x%X\n",
self, self->mInputFrameID));
self->CleanupStream(self->mInputFrameDataStream, rv, PROTOCOL_ERROR);
self->ResetDownstreamState();
rv = NS_OK;
} else if (NS_FAILED(rv)) {
// This is fatal to the session.
self->mGoAwayReason = COMPRESSION_ERROR;
}
return rv;
}
// ResponseHeadersComplete() returns NS_ERROR_ILLEGAL_VALUE when the stream
// should be reset with a PROTOCOL_ERROR, NS_OK when the response headers were
// fine, and any other error is fatal to the session.
nsresult
Http2Session::ResponseHeadersComplete()
{
LOG3(("Http2Session::ResponseHeadersComplete %p for 0x%X fin=%d",
this, mInputFrameDataStream->StreamID(), mInputFrameFinal));
// only interpret headers once, afterwards ignore as trailers
if (mInputFrameDataStream->AllHeadersReceived()) {
LOG3(("Http2Session::ResponseHeadersComplete extra headers"));
MOZ_ASSERT(mInputFrameFlags & kFlag_END_STREAM);
nsresult rv = UncompressAndDiscard(false);
if (NS_FAILED(rv)) {
LOG3(("Http2Session::ResponseHeadersComplete extra uncompress failed\n"));
return rv;
}
mFlatHTTPResponseHeadersOut = 0;
mFlatHTTPResponseHeaders.Truncate();
if (mInputFrameFinal) {
// need to process the fin
ChangeDownstreamState(PROCESSING_COMPLETE_HEADERS);
} else {
ResetDownstreamState();
}
return NS_OK;
}
// if this turns out to be a 1xx response code we have to
// undo the headers received bit that we are setting here.
bool didFirstSetAllRecvd = !mInputFrameDataStream->AllHeadersReceived();
mInputFrameDataStream->SetAllHeadersReceived();
// The stream needs to see flattened http headers
// Uncompressed http/2 format headers currently live in
// Http2Stream::mDecompressBuffer - convert that to HTTP format in
// mFlatHTTPResponseHeaders via ConvertHeaders()
nsresult rv;
int32_t httpResponseCode; // out param to ConvertResponseHeaders
mFlatHTTPResponseHeadersOut = 0;
rv = mInputFrameDataStream->ConvertResponseHeaders(&mDecompressor,
mDecompressBuffer,
mFlatHTTPResponseHeaders,
httpResponseCode);
if (rv == NS_ERROR_ABORT) {
LOG(("Http2Session::ResponseHeadersComplete ConvertResponseHeaders aborted\n"));
if (mInputFrameDataStream->IsTunnel()) {
gHttpHandler->ConnMgr()->CancelTransactions(
mInputFrameDataStream->Transaction()->ConnectionInfo(),
NS_ERROR_CONNECTION_REFUSED);
}
CleanupStream(mInputFrameDataStream, rv, CANCEL_ERROR);
ResetDownstreamState();
return NS_OK;
} else if (NS_FAILED(rv)) {
return rv;
}
// allow more headers in the case of 1xx
if (((httpResponseCode / 100) == 1) && didFirstSetAllRecvd) {
mInputFrameDataStream->UnsetAllHeadersReceived();
}
ChangeDownstreamState(PROCESSING_COMPLETE_HEADERS);
return NS_OK;
}
nsresult
Http2Session::RecvPriority(Http2Session *self)
{
MOZ_ASSERT(self->mInputFrameType == FRAME_TYPE_PRIORITY);
if (self->mInputFrameDataSize != 5) {
LOG3(("Http2Session::RecvPriority %p wrong length data=%d\n",
self, self->mInputFrameDataSize));
RETURN_SESSION_ERROR(self, PROTOCOL_ERROR);
}
if (!self->mInputFrameID) {
LOG3(("Http2Session::RecvPriority %p stream ID of 0.\n", self));
RETURN_SESSION_ERROR(self, PROTOCOL_ERROR);
}
nsresult rv = self->SetInputFrameDataStream(self->mInputFrameID);
if (NS_FAILED(rv))
return rv;
uint32_t newPriorityDependency = NetworkEndian::readUint32(
self->mInputFrameBuffer.get() + kFrameHeaderBytes);
bool exclusive = !!(newPriorityDependency & 0x80000000);
newPriorityDependency &= 0x7fffffff;
uint8_t newPriorityWeight = *(self->mInputFrameBuffer.get() + kFrameHeaderBytes + 4);
if (self->mInputFrameDataStream) {
self->mInputFrameDataStream->SetPriorityDependency(newPriorityDependency,
newPriorityWeight,
exclusive);
}
self->ResetDownstreamState();
return NS_OK;
}
nsresult
Http2Session::RecvRstStream(Http2Session *self)
{
MOZ_ASSERT(self->mInputFrameType == FRAME_TYPE_RST_STREAM);
if (self->mInputFrameDataSize != 4) {
LOG3(("Http2Session::RecvRstStream %p RST_STREAM wrong length data=%d",
self, self->mInputFrameDataSize));
RETURN_SESSION_ERROR(self, PROTOCOL_ERROR);
}
if (!self->mInputFrameID) {
LOG3(("Http2Session::RecvRstStream %p stream ID of 0.\n", self));
RETURN_SESSION_ERROR(self, PROTOCOL_ERROR);
}
self->mDownstreamRstReason = NetworkEndian::readUint32(
self->mInputFrameBuffer.get() + kFrameHeaderBytes);
LOG3(("Http2Session::RecvRstStream %p RST_STREAM Reason Code %u ID %x\n",
self, self->mDownstreamRstReason, self->mInputFrameID));
self->SetInputFrameDataStream(self->mInputFrameID);
if (!self->mInputFrameDataStream) {
// if we can't find the stream just ignore it (4.2 closed)
self->ResetDownstreamState();
return NS_OK;
}
self->mInputFrameDataStream->SetRecvdReset(true);
self->MaybeDecrementConcurrent(self->mInputFrameDataStream);
self->ChangeDownstreamState(PROCESSING_CONTROL_RST_STREAM);
return NS_OK;
}
PLDHashOperator
Http2Session::UpdateServerRwinEnumerator(nsAHttpTransaction *key,
nsAutoPtr<Http2Stream> &stream,
void *closure)
{
int32_t delta = *(static_cast<int32_t *>(closure));
stream->UpdateServerReceiveWindow(delta);
return PL_DHASH_NEXT;
}
nsresult
Http2Session::RecvSettings(Http2Session *self)
{
MOZ_ASSERT(self->mInputFrameType == FRAME_TYPE_SETTINGS);
if (self->mInputFrameID) {
LOG3(("Http2Session::RecvSettings %p needs stream ID of 0. 0x%X\n",
self, self->mInputFrameID));
RETURN_SESSION_ERROR(self, PROTOCOL_ERROR);
}
if (self->mInputFrameDataSize % 6) {
// Number of Settings is determined by dividing by each 6 byte setting
// entry. So the payload must be a multiple of 6.
LOG3(("Http2Session::RecvSettings %p SETTINGS wrong length data=%d",
self, self->mInputFrameDataSize));
RETURN_SESSION_ERROR(self, PROTOCOL_ERROR);
}
uint32_t numEntries = self->mInputFrameDataSize / 6;
LOG3(("Http2Session::RecvSettings %p SETTINGS Control Frame "
"with %d entries ack=%X", self, numEntries,
self->mInputFrameFlags & kFlag_ACK));
if ((self->mInputFrameFlags & kFlag_ACK) && self->mInputFrameDataSize) {
LOG3(("Http2Session::RecvSettings %p ACK with non zero payload is err\n"));
RETURN_SESSION_ERROR(self, PROTOCOL_ERROR);
}
for (uint32_t index = 0; index < numEntries; ++index) {
uint8_t *setting = reinterpret_cast<uint8_t *>
(self->mInputFrameBuffer.get()) + kFrameHeaderBytes + index * 6;
uint16_t id = NetworkEndian::readUint16(setting);
uint32_t value = NetworkEndian::readUint32(setting + 2);
LOG3(("Settings ID %u, Value %u", id, value));
switch (id)
{
case SETTINGS_TYPE_HEADER_TABLE_SIZE:
LOG3(("Compression header table setting received: %d\n", value));
self->mCompressor.SetMaxBufferSize(value);
break;
case SETTINGS_TYPE_ENABLE_PUSH:
LOG3(("Client received an ENABLE Push SETTING. Odd.\n"));
// nop
break;
case SETTINGS_TYPE_MAX_CONCURRENT:
self->mMaxConcurrent = value;
Telemetry::Accumulate(Telemetry::SPDY_SETTINGS_MAX_STREAMS, value);
self->ProcessPending();
break;
case SETTINGS_TYPE_INITIAL_WINDOW:
{
Telemetry::Accumulate(Telemetry::SPDY_SETTINGS_IW, value >> 10);
int32_t delta = value - self->mServerInitialStreamWindow;
self->mServerInitialStreamWindow = value;
// SETTINGS only adjusts stream windows. Leave the sesison window alone.
// we need to add the delta to all open streams (delta can be negative)
self->mStreamTransactionHash.Enumerate(UpdateServerRwinEnumerator,
&delta);
}
break;
case SETTINGS_TYPE_MAX_FRAME_SIZE:
{
if ((value < kMaxFrameData) || (value >= 0x01000000)) {
LOG3(("Received invalid max frame size 0x%X", value));
RETURN_SESSION_ERROR(self, PROTOCOL_ERROR);
}
// We stick to the default for simplicity's sake, so nothing to change
}
break;
default:
break;
}
}
self->ResetDownstreamState();
if (!(self->mInputFrameFlags & kFlag_ACK)) {
self->GenerateSettingsAck();
} else if (self->mWaitingForSettingsAck) {
self->mGoAwayOnPush = true;
}
return NS_OK;
}
nsresult
Http2Session::RecvPushPromise(Http2Session *self)
{
MOZ_ASSERT(self->mInputFrameType == FRAME_TYPE_PUSH_PROMISE ||
self->mInputFrameType == FRAME_TYPE_CONTINUATION);
// Find out how much padding this frame has, so we can only extract the real
// header data from the frame.
uint16_t paddingLength = 0;
uint8_t paddingControlBytes = 0;
// If this doesn't have END_PUSH_PROMISE set on it then require the next
// frame to be PUSH_PROMISE of the same ID
uint32_t promiseLen;
uint32_t promisedID;
if (self->mExpectedPushPromiseID) {
promiseLen = 0; // really a continuation frame
promisedID = self->mContinuedPromiseStream;
} else {
self->mDecompressBuffer.Truncate();
nsresult rv = self->ParsePadding(paddingControlBytes, paddingLength);
if (NS_FAILED(rv)) {
return rv;
}
promiseLen = 4;
promisedID = NetworkEndian::readUint32(
self->mInputFrameBuffer.get() + kFrameHeaderBytes + paddingControlBytes);
promisedID &= 0x7fffffff;
}
uint32_t associatedID = self->mInputFrameID;
if (self->mInputFrameFlags & kFlag_END_PUSH_PROMISE) {
self->mExpectedPushPromiseID = 0;
self->mContinuedPromiseStream = 0;
} else {
self->mExpectedPushPromiseID = self->mInputFrameID;
self->mContinuedPromiseStream = promisedID;
}
if ((paddingControlBytes + promiseLen + paddingLength) > self->mInputFrameDataSize) {
// This is fatal to the session
LOG3(("Http2Session::RecvPushPromise %p ID 0x%X assoc ID 0x%X "
"PROTOCOL_ERROR extra %d > frame size %d\n",
self, promisedID, associatedID, (paddingControlBytes + promiseLen + paddingLength),
self->mInputFrameDataSize));
RETURN_SESSION_ERROR(self, PROTOCOL_ERROR);
}
LOG3(("Http2Session::RecvPushPromise %p ID 0x%X assoc ID 0x%X "
"paddingLength %d padded %d\n",
self, promisedID, associatedID, paddingLength,
self->mInputFrameFlags & kFlag_PADDED));
if (!associatedID || !promisedID || (promisedID & 1)) {
LOG3(("Http2Session::RecvPushPromise %p ID invalid.\n", self));
RETURN_SESSION_ERROR(self, PROTOCOL_ERROR);
}
// confirm associated-to
nsresult rv = self->SetInputFrameDataStream(associatedID);
if (NS_FAILED(rv))
return rv;
Http2Stream *associatedStream = self->mInputFrameDataStream;
++(self->mServerPushedResources);
// Anytime we start using the high bit of stream ID (either client or server)
// begin to migrate to a new session.
if (promisedID >= kMaxStreamID)
self->mShouldGoAway = true;
bool resetStream = true;
SpdyPushCache *cache = nullptr;
if (self->mShouldGoAway) {
LOG3(("Http2Session::RecvPushPromise %p push while in GoAway "
"mode refused.\n", self));
self->GenerateRstStream(REFUSED_STREAM_ERROR, promisedID);
} else if (!gHttpHandler->AllowPush()) {
// ENABLE_PUSH and MAX_CONCURRENT_STREAMS of 0 in settings disabled push
LOG3(("Http2Session::RecvPushPromise Push Recevied when Disabled\n"));
if (self->mGoAwayOnPush) {
LOG3(("Http2Session::RecvPushPromise sending GOAWAY"));
RETURN_SESSION_ERROR(self, PROTOCOL_ERROR);
}
self->GenerateRstStream(REFUSED_STREAM_ERROR, promisedID);
} else if (!associatedStream) {
LOG3(("Http2Session::RecvPushPromise %p lookup associated ID failed.\n", self));
self->GenerateRstStream(PROTOCOL_ERROR, promisedID);
} else {
nsISchedulingContext *schedulingContext = associatedStream->SchedulingContext();
if (schedulingContext) {
schedulingContext->GetSpdyPushCache(&cache);
if (!cache) {
cache = new SpdyPushCache();
if (!cache || NS_FAILED(schedulingContext->SetSpdyPushCache(cache))) {
delete cache;
cache = nullptr;
}
}
}
if (!cache) {
// this is unexpected, but we can handle it just by refusing the push
LOG3(("Http2Session::RecvPushPromise Push Recevied without push cache\n"));
self->GenerateRstStream(REFUSED_STREAM_ERROR, promisedID);
} else {
resetStream = false;
}
}
if (resetStream) {
// Need to decompress the headers even though we aren't using them yet in
// order to keep the compression context consistent for other frames
self->mDecompressBuffer.Append(&self->mInputFrameBuffer[kFrameHeaderBytes + paddingControlBytes + promiseLen],
self->mInputFrameDataSize - paddingControlBytes - promiseLen - paddingLength);
if (self->mInputFrameFlags & kFlag_END_PUSH_PROMISE) {
rv = self->UncompressAndDiscard(true);
if (NS_FAILED(rv)) {
LOG3(("Http2Session::RecvPushPromise uncompress failed\n"));
self->mGoAwayReason = COMPRESSION_ERROR;
return rv;
}
}
self->ResetDownstreamState();
return NS_OK;
}
self->mDecompressBuffer.Append(&self->mInputFrameBuffer[kFrameHeaderBytes + paddingControlBytes + promiseLen],
self->mInputFrameDataSize - paddingControlBytes - promiseLen - paddingLength);
if (!(self->mInputFrameFlags & kFlag_END_PUSH_PROMISE)) {
LOG3(("Http2Session::RecvPushPromise not finishing processing for multi-frame push\n"));
self->ResetDownstreamState();
return NS_OK;
}
// Create the buffering transaction and push stream
RefPtr<Http2PushTransactionBuffer> transactionBuffer =
new Http2PushTransactionBuffer();
transactionBuffer->SetConnection(self);
nsAutoPtr<Http2PushedStream> pushedStream(
new Http2PushedStream(transactionBuffer, self, associatedStream, promisedID)
);
rv = pushedStream->ConvertPushHeaders(&self->mDecompressor,
self->mDecompressBuffer,
pushedStream->GetRequestString());
if (rv == NS_ERROR_NOT_IMPLEMENTED) {
LOG3(("Http2Session::PushPromise Semantics not Implemented\n"));
self->GenerateRstStream(REFUSED_STREAM_ERROR, promisedID);
return NS_OK;
}
if (rv == NS_ERROR_ILLEGAL_VALUE) {
// This means the decompression completed ok, but there was a problem with
// the decoded headers. Reset the stream and go away.
self->GenerateRstStream(PROTOCOL_ERROR, promisedID);
return NS_OK;
} else if (NS_FAILED(rv)) {
// This is fatal to the session.
self->mGoAwayReason = COMPRESSION_ERROR;
return rv;
}
WeakPtr<Http2Stream> pushedWeak = pushedStream.forget();
// Ownership of the pushed stream is by the transaction hash, just as it
// is for a client initiated stream. Errors that aren't fatal to the
// whole session must call cleanupStream() after this point in order
// to remove the stream from that hash.
self->mStreamTransactionHash.Put(transactionBuffer, pushedWeak);
self->mPushedStreams.AppendElement(
static_cast<Http2PushedStream*>(pushedWeak.get()));
if (self->RegisterStreamID(pushedWeak, promisedID) == kDeadStreamID) {
LOG3(("Http2Session::RecvPushPromise registerstreamid failed\n"));
self->mGoAwayReason = INTERNAL_ERROR;
return NS_ERROR_FAILURE;
}
if (promisedID > self->mOutgoingGoAwayID)
self->mOutgoingGoAwayID = promisedID;
// Fake the request side of the pushed HTTP transaction. Sets up hash
// key and origin
uint32_t notUsed;
pushedWeak->ReadSegments(nullptr, 1, &notUsed);
nsAutoCString key;
if (!static_cast<Http2PushedStream*>(pushedWeak.get())->GetHashKey(key)) {
LOG3(("Http2Session::RecvPushPromise one of :authority :scheme :path missing from push\n"));
self->CleanupStream(pushedWeak, NS_ERROR_FAILURE, PROTOCOL_ERROR);
self->ResetDownstreamState();
return NS_OK;
}
// does the pushed origin belong on this connection?
RefPtr<nsStandardURL> associatedURL, pushedURL;
rv = Http2Stream::MakeOriginURL(associatedStream->Origin(), associatedURL);
if (NS_SUCCEEDED(rv)) {
rv = Http2Stream::MakeOriginURL(pushedWeak->Origin(), pushedURL);
}
LOG3(("Http2Session::RecvPushPromise %p checking %s == %s", self,
associatedStream->Origin().get(), pushedWeak->Origin().get()));
bool match = false;
if (NS_SUCCEEDED(rv)) {
rv = associatedURL->Equals(pushedURL, &match);
}
if (NS_FAILED(rv)) {
// Fallback to string equality of origins. This won't be guaranteed to be as
// liberal as we want it to be, but it will at least be safe
match = associatedStream->Origin().Equals(pushedWeak->Origin());
}
if (!match) {
LOG3(("Http2Session::RecvPushPromise %p pushed stream mismatched origin "
"associated origin %s .. pushed origin %s\n", self,
associatedStream->Origin().get(), pushedWeak->Origin().get()));
self->CleanupStream(pushedWeak, NS_ERROR_FAILURE, REFUSED_STREAM_ERROR);
self->ResetDownstreamState();
return NS_OK;
}
if (static_cast<Http2PushedStream*>(pushedWeak.get())->TryOnPush()) {
LOG3(("Http2Session::RecvPushPromise %p channel implements nsIHttpPushListener "
"stream %p will not be placed into session cache.\n", self, pushedWeak.get()));
} else {
LOG3(("Http2Session::RecvPushPromise %p place stream into session cache\n", self));
if (!cache->RegisterPushedStreamHttp2(
key, static_cast<Http2PushedStream*>(pushedWeak.get()))) {
// This only happens if they've already pushed us this item.
LOG3(("Http2Session::RecvPushPromise registerPushedStream Failed\n"));
self->CleanupStream(pushedWeak, NS_ERROR_FAILURE, INTERNAL_ERROR);
self->ResetDownstreamState();
return NS_OK;
}
}
pushedWeak->SetHTTPState(Http2Stream::RESERVED_BY_REMOTE);
static_assert(Http2Stream::kWorstPriority >= 0,
"kWorstPriority out of range");
uint8_t priorityWeight = (nsISupportsPriority::PRIORITY_LOWEST + 1) -
(Http2Stream::kWorstPriority - Http2Stream::kNormalPriority);
pushedWeak->SetPriority(Http2Stream::kWorstPriority);
self->GeneratePriority(promisedID, priorityWeight);
self->ResetDownstreamState();
return NS_OK;
}
nsresult
Http2Session::RecvPing(Http2Session *self)
{
MOZ_ASSERT(self->mInputFrameType == FRAME_TYPE_PING);
LOG3(("Http2Session::RecvPing %p PING Flags 0x%X.", self,
self->mInputFrameFlags));
if (self->mInputFrameDataSize != 8) {
LOG3(("Http2Session::RecvPing %p PING had wrong amount of data %d",
self, self->mInputFrameDataSize));
RETURN_SESSION_ERROR(self, FRAME_SIZE_ERROR);
}
if (self->mInputFrameID) {
LOG3(("Http2Session::RecvPing %p PING needs stream ID of 0. 0x%X\n",
self, self->mInputFrameID));
RETURN_SESSION_ERROR(self, PROTOCOL_ERROR);
}
if (self->mInputFrameFlags & kFlag_ACK) {
// presumably a reply to our timeout ping.. don't reply to it
self->mPingSentEpoch = 0;
} else {
// reply with a ack'd ping
self->GeneratePing(true);
}
self->ResetDownstreamState();
return NS_OK;
}
nsresult
Http2Session::RecvGoAway(Http2Session *self)
{
MOZ_ASSERT(self->mInputFrameType == FRAME_TYPE_GOAWAY);
if (self->mInputFrameDataSize < 8) {
// data > 8 is an opaque token that we can't interpret. NSPR Logs will
// have the hex of all packets so there is no point in separately logging.
LOG3(("Http2Session::RecvGoAway %p GOAWAY had wrong amount of data %d",
self, self->mInputFrameDataSize));
RETURN_SESSION_ERROR(self, PROTOCOL_ERROR);
}
if (self->mInputFrameID) {
LOG3(("Http2Session::RecvGoAway %p GOAWAY had non zero stream ID 0x%X\n",
self, self->mInputFrameID));
RETURN_SESSION_ERROR(self, PROTOCOL_ERROR);
}
self->mShouldGoAway = true;
self->mGoAwayID = NetworkEndian::readUint32(
self->mInputFrameBuffer.get() + kFrameHeaderBytes);
self->mGoAwayID &= 0x7fffffff;
self->mCleanShutdown = true;
self->mPeerGoAwayReason = NetworkEndian::readUint32(
self->mInputFrameBuffer.get() + kFrameHeaderBytes + 4);
// Find streams greater than the last-good ID and mark them for deletion
// in the mGoAwayStreamsToRestart queue with the GoAwayEnumerator. The
// underlying transaction can be restarted.
self->mStreamTransactionHash.Enumerate(GoAwayEnumerator, self);
// Process the streams marked for deletion and restart.
size_t size = self->mGoAwayStreamsToRestart.GetSize();
for (size_t count = 0; count < size; ++count) {
Http2Stream *stream =
static_cast<Http2Stream *>(self->mGoAwayStreamsToRestart.PopFront());
if (self->mPeerGoAwayReason == HTTP_1_1_REQUIRED) {
stream->Transaction()->DisableSpdy();
}
self->CloseStream(stream, NS_ERROR_NET_RESET);
if (stream->HasRegisteredID())
self->mStreamIDHash.Remove(stream->StreamID());
self->mStreamTransactionHash.Remove(stream->Transaction());
}
// Queued streams can also be deleted from this session and restarted
// in another one. (they were never sent on the network so they implicitly
// are not covered by the last-good id.
size = self->mQueuedStreams.GetSize();
for (size_t count = 0; count < size; ++count) {
Http2Stream *stream =
static_cast<Http2Stream *>(self->mQueuedStreams.PopFront());
MOZ_ASSERT(stream->Queued());
stream->SetQueued(false);
if (self->mPeerGoAwayReason == HTTP_1_1_REQUIRED) {
stream->Transaction()->DisableSpdy();
}
self->CloseStream(stream, NS_ERROR_NET_RESET);
self->mStreamTransactionHash.Remove(stream->Transaction());
}
LOG3(("Http2Session::RecvGoAway %p GOAWAY Last-Good-ID 0x%X status 0x%X "
"live streams=%d\n", self, self->mGoAwayID, self->mPeerGoAwayReason,
self->mStreamTransactionHash.Count()));
self->ResetDownstreamState();
return NS_OK;
}
PLDHashOperator
Http2Session::RestartBlockedOnRwinEnumerator(nsAHttpTransaction *key,
nsAutoPtr<Http2Stream> &stream,
void *closure)
{
Http2Session *self = static_cast<Http2Session *>(closure);
MOZ_ASSERT(self->mServerSessionWindow > 0);
if (!stream->BlockedOnRwin() || stream->ServerReceiveWindow() <= 0)
return PL_DHASH_NEXT;
self->mReadyForWrite.Push(stream);
self->SetWriteCallbacks();
return PL_DHASH_NEXT;
}
nsresult
Http2Session::RecvWindowUpdate(Http2Session *self)
{
MOZ_ASSERT(self->mInputFrameType == FRAME_TYPE_WINDOW_UPDATE);
if (self->mInputFrameDataSize != 4) {
LOG3(("Http2Session::RecvWindowUpdate %p Window Update wrong length %d\n",
self, self->mInputFrameDataSize));
RETURN_SESSION_ERROR(self, PROTOCOL_ERROR);
}
uint32_t delta = NetworkEndian::readUint32(
self->mInputFrameBuffer.get() + kFrameHeaderBytes);
delta &= 0x7fffffff;
LOG3(("Http2Session::RecvWindowUpdate %p len=%d Stream 0x%X.\n",
self, delta, self->mInputFrameID));
if (self->mInputFrameID) { // stream window
nsresult rv = self->SetInputFrameDataStream(self->mInputFrameID);
if (NS_FAILED(rv))
return rv;
if (!self->mInputFrameDataStream) {
LOG3(("Http2Session::RecvWindowUpdate %p lookup streamID 0x%X failed.\n",
self, self->mInputFrameID));
// only resest the session if the ID is one we haven't ever opened
if (self->mInputFrameID >= self->mNextStreamID)
self->GenerateRstStream(PROTOCOL_ERROR, self->mInputFrameID);
self->ResetDownstreamState();
return NS_OK;
}
if (delta == 0) {
LOG3(("Http2Session::RecvWindowUpdate %p received 0 stream window update",
self));
self->CleanupStream(self->mInputFrameDataStream, NS_ERROR_ILLEGAL_VALUE,
PROTOCOL_ERROR);
self->ResetDownstreamState();
return NS_OK;
}
int64_t oldRemoteWindow = self->mInputFrameDataStream->ServerReceiveWindow();
self->mInputFrameDataStream->UpdateServerReceiveWindow(delta);
if (self->mInputFrameDataStream->ServerReceiveWindow() >= 0x80000000) {
// a window cannot reach 2^31 and be in compliance. Our calculations
// are 64 bit safe though.
LOG3(("Http2Session::RecvWindowUpdate %p stream window "
"exceeds 2^31 - 1\n", self));
self->CleanupStream(self->mInputFrameDataStream, NS_ERROR_ILLEGAL_VALUE,
FLOW_CONTROL_ERROR);
self->ResetDownstreamState();
return NS_OK;
}
LOG3(("Http2Session::RecvWindowUpdate %p stream 0x%X window "
"%d increased by %d now %d.\n", self, self->mInputFrameID,
oldRemoteWindow, delta, oldRemoteWindow + delta));
} else { // session window update
if (delta == 0) {
LOG3(("Http2Session::RecvWindowUpdate %p received 0 session window update",
self));
RETURN_SESSION_ERROR(self, PROTOCOL_ERROR);
}
int64_t oldRemoteWindow = self->mServerSessionWindow;
self->mServerSessionWindow += delta;
if (self->mServerSessionWindow >= 0x80000000) {
// a window cannot reach 2^31 and be in compliance. Our calculations
// are 64 bit safe though.
LOG3(("Http2Session::RecvWindowUpdate %p session window "
"exceeds 2^31 - 1\n", self));
RETURN_SESSION_ERROR(self, FLOW_CONTROL_ERROR);
}
if ((oldRemoteWindow <= 0) && (self->mServerSessionWindow > 0)) {
LOG3(("Http2Session::RecvWindowUpdate %p restart session window\n",
self));
self->mStreamTransactionHash.Enumerate(RestartBlockedOnRwinEnumerator, self);
}
LOG3(("Http2Session::RecvWindowUpdate %p session window "
"%d increased by %d now %d.\n", self,
oldRemoteWindow, delta, oldRemoteWindow + delta));
}
self->ResetDownstreamState();
return NS_OK;
}
nsresult
Http2Session::RecvContinuation(Http2Session *self)
{
MOZ_ASSERT(self->mInputFrameType == FRAME_TYPE_CONTINUATION);
MOZ_ASSERT(self->mInputFrameID);
MOZ_ASSERT(self->mExpectedPushPromiseID || self->mExpectedHeaderID);
MOZ_ASSERT(!(self->mExpectedPushPromiseID && self->mExpectedHeaderID));
LOG3(("Http2Session::RecvContinuation %p Flags 0x%X id 0x%X "
"promise id 0x%X header id 0x%X\n",
self, self->mInputFrameFlags, self->mInputFrameID,
self->mExpectedPushPromiseID, self->mExpectedHeaderID));
self->SetInputFrameDataStream(self->mInputFrameID);
if (!self->mInputFrameDataStream) {
LOG3(("Http2Session::RecvContination stream ID 0x%X not found.",
self->mInputFrameID));
RETURN_SESSION_ERROR(self, PROTOCOL_ERROR);
}
// continued headers
if (self->mExpectedHeaderID) {
self->mInputFrameFlags &= ~kFlag_PRIORITY;
return RecvHeaders(self);
}
// continued push promise
if (self->mInputFrameFlags & kFlag_END_HEADERS) {
self->mInputFrameFlags &= ~kFlag_END_HEADERS;
self->mInputFrameFlags |= kFlag_END_PUSH_PROMISE;
}
return RecvPushPromise(self);
}
class UpdateAltSvcEvent : public nsRunnable
{
public:
UpdateAltSvcEvent(const nsCString &header,
const nsCString &aOrigin,
nsHttpConnectionInfo *aCI,
nsIInterfaceRequestor *callbacks)
: mHeader(header)
, mOrigin(aOrigin)
, mCI(aCI)
, mCallbacks(callbacks)
{
}
NS_IMETHOD Run() override
{
MOZ_ASSERT(NS_IsMainThread());
nsCString originScheme;
nsCString originHost;
int32_t originPort = -1;
nsCOMPtr<nsIURI> uri;
if (NS_FAILED(NS_NewURI(getter_AddRefs(uri), mOrigin))) {
LOG(("UpdateAltSvcEvent origin does not parse %s\n",
mOrigin.get()));
return NS_OK;
}
uri->GetScheme(originScheme);
uri->GetHost(originHost);
uri->GetPort(&originPort);
AltSvcMapping::ProcessHeader(mHeader, originScheme, originHost, originPort,
mCI->GetUsername(), mCI->GetPrivate(), mCallbacks,
mCI->ProxyInfo(), 0);
return NS_OK;
}
private:
nsCString mHeader;
nsCString mOrigin;
RefPtr<nsHttpConnectionInfo> mCI;
nsCOMPtr<nsIInterfaceRequestor> mCallbacks;
};
// defined as an http2 extension - alt-svc
// defines receipt of frame type 0x0A.. See AlternateSevices.h at least draft -06 sec 4
// as this is an extension, never generate protocol error - just ignore problems
nsresult
Http2Session::RecvAltSvc(Http2Session *self)
{
MOZ_ASSERT(self->mInputFrameType == FRAME_TYPE_ALTSVC);
LOG3(("Http2Session::RecvAltSvc %p Flags 0x%X id 0x%X\n", self,
self->mInputFrameFlags, self->mInputFrameID));
if (self->mInputFrameDataSize < 2) {
LOG3(("Http2Session::RecvAltSvc %p frame too small", self));
self->ResetDownstreamState();
return NS_OK;
}
uint16_t originLen = NetworkEndian::readUint16(
self->mInputFrameBuffer.get() + kFrameHeaderBytes);
if (originLen + 2U > self->mInputFrameDataSize) {
LOG3(("Http2Session::RecvAltSvc %p origin len too big for frame", self));
self->ResetDownstreamState();
return NS_OK;
}
if (!gHttpHandler->AllowAltSvc()) {
LOG3(("Http2Session::RecvAltSvc %p frame alt service pref'd off", self));
self->ResetDownstreamState();
return NS_OK;
}
uint16_t altSvcFieldValueLen = static_cast<uint16_t>(self->mInputFrameDataSize) - 2U - originLen;
LOG3(("Http2Session::RecvAltSvc %p frame originLen=%u altSvcFieldValueLen=%u\n",
self, originLen, altSvcFieldValueLen));
if (self->mInputFrameDataSize > 2000) {
LOG3(("Http2Session::RecvAltSvc %p frame too large to parse sensibly", self));
self->ResetDownstreamState();
return NS_OK;
}
nsAutoCString origin;
bool impliedOrigin = true;
if (originLen) {
origin.Assign(self->mInputFrameBuffer.get() + kFrameHeaderBytes + 2, originLen);
impliedOrigin = false;
}
nsAutoCString altSvcFieldValue;
if (altSvcFieldValueLen) {
altSvcFieldValue.Assign(self->mInputFrameBuffer.get() + kFrameHeaderBytes + 2 + originLen,
altSvcFieldValueLen);
}
if (altSvcFieldValue.IsEmpty() || !nsHttp::IsReasonableHeaderValue(altSvcFieldValue)) {
LOG(("Http2Session %p Alt-Svc Response Header seems unreasonable - skipping\n", self));
self->ResetDownstreamState();
return NS_OK;
}
if (self->mInputFrameID & 1) {
// pulled streams apply to the origin of the pulled stream.
// If the origin field is filled in the frame, the frame should be ignored
if (!origin.IsEmpty()) {
LOG(("Http2Session %p Alt-Svc pulled stream has non empty origin\n", self));
self->ResetDownstreamState();
return NS_OK;
}
if (NS_FAILED(self->SetInputFrameDataStream(self->mInputFrameID)) ||
!self->mInputFrameDataStream->Transaction() ||
!self->mInputFrameDataStream->Transaction()->RequestHead()) {
LOG3(("Http2Session::RecvAltSvc %p got frame w/o origin on invalid stream", self));
self->ResetDownstreamState();
return NS_OK;
}
origin.Assign(self->mInputFrameDataStream->Transaction()->RequestHead()->Origin());
} else if (!self->mInputFrameID) {
// ID 0 streams must supply their own origin
if (origin.IsEmpty()) {
LOG(("Http2Session %p Alt-Svc Stream 0 has empty origin\n", self));
self->ResetDownstreamState();
return NS_OK;
}
} else {
// handling of push streams is not defined. Let's ignore it
LOG(("Http2Session %p Alt-Svc Stream 0 has empty origin\n", self));
self->ResetDownstreamState();
return NS_OK;
}
RefPtr<nsHttpConnectionInfo> ci(self->ConnectionInfo());
if (!self->mConnection || !ci) {
LOG3(("Http2Session::RecvAltSvc %p no connection or conninfo for %d", self,
self->mInputFrameID));
self->ResetDownstreamState();
return NS_OK;
}
if (!impliedOrigin) {
bool okToReroute = true;
nsCOMPtr<nsISupports> securityInfo;
self->mConnection->GetSecurityInfo(getter_AddRefs(securityInfo));
nsCOMPtr<nsISSLSocketControl> ssl = do_QueryInterface(securityInfo);
if (!ssl) {
okToReroute = false;
}
// a little off main thread origin parser. This is a non critical function because
// any alternate route created has to be verified anyhow
nsAutoCString specifiedOriginHost;
if (origin.EqualsIgnoreCase("https://", 8)) {
specifiedOriginHost.Assign(origin.get() + 8, origin.Length() - 8);
if (ci->GetInsecureScheme()) {
// technically this is ok because it will still be confirmed before being used
// but let's not support it.
okToReroute = false;
}
} else if (origin.EqualsIgnoreCase("http://", 7)) {
specifiedOriginHost.Assign(origin.get() + 7, origin.Length() - 7);
}
int32_t colonOffset = specifiedOriginHost.FindCharInSet(":", 0);
if (colonOffset != kNotFound) {
specifiedOriginHost.Truncate(colonOffset);
}
if (okToReroute) {
ssl->IsAcceptableForHost(specifiedOriginHost, &okToReroute);
}
if (!okToReroute) {
LOG3(("Http2Session::RecvAltSvc %p can't reroute non-authoritative origin %s",
self, origin.BeginReading()));
self->ResetDownstreamState();
return NS_OK;
}
}
nsCOMPtr<nsISupports> callbacks;
self->mConnection->GetSecurityInfo(getter_AddRefs(callbacks));
nsCOMPtr<nsIInterfaceRequestor> irCallbacks = do_QueryInterface(callbacks);
RefPtr<UpdateAltSvcEvent> event =
new UpdateAltSvcEvent(altSvcFieldValue, origin, ci, irCallbacks);
NS_DispatchToMainThread(event);
self->ResetDownstreamState();
return NS_OK;
}
//-----------------------------------------------------------------------------
// nsAHttpTransaction. It is expected that nsHttpConnection is the caller
// of these methods
//-----------------------------------------------------------------------------
void
Http2Session::OnTransportStatus(nsITransport* aTransport,
nsresult aStatus, int64_t aProgress)
{
MOZ_ASSERT(PR_GetCurrentThread() == gSocketThread);
switch (aStatus) {
// These should appear only once, deliver to the first
// transaction on the session.
case NS_NET_STATUS_RESOLVING_HOST:
case NS_NET_STATUS_RESOLVED_HOST:
case NS_NET_STATUS_CONNECTING_TO:
case NS_NET_STATUS_CONNECTED_TO:
case NS_NET_STATUS_TLS_HANDSHAKE_STARTING:
case NS_NET_STATUS_TLS_HANDSHAKE_ENDED:
{
Http2Stream *target = mStreamIDHash.Get(1);
nsAHttpTransaction *transaction = target ? target->Transaction() : nullptr;
if (transaction)
transaction->OnTransportStatus(aTransport, aStatus, aProgress);
break;
}
default:
// The other transport events are ignored here because there is no good
// way to map them to the right transaction in http/2. Instead, the events
// are generated again from the http/2 code and passed directly to the
// correct transaction.
// NS_NET_STATUS_SENDING_TO:
// This is generated by the socket transport when (part) of
// a transaction is written out
//
// There is no good way to map it to the right transaction in http/2,
// so it is ignored here and generated separately when the request
// is sent from Http2Stream::TransmitFrame
// NS_NET_STATUS_WAITING_FOR:
// Created by nsHttpConnection when the request has been totally sent.
// There is no good way to map it to the right transaction in http/2,
// so it is ignored here and generated separately when the same
// condition is complete in Http2Stream when there is no more
// request body left to be transmitted.
// NS_NET_STATUS_RECEIVING_FROM
// Generated in session whenever we read a data frame or a HEADERS
// that can be attributed to a particular stream/transaction
break;
}
}
// ReadSegments() is used to write data to the network. Generally, HTTP
// request data is pulled from the approriate transaction and
// converted to http/2 data. Sometimes control data like window-update are
// generated instead.
nsresult
Http2Session::ReadSegmentsAgain(nsAHttpSegmentReader *reader,
uint32_t count, uint32_t *countRead, bool *again)
{
MOZ_ASSERT(PR_GetCurrentThread() == gSocketThread);
MOZ_ASSERT(!mSegmentReader || !reader || (mSegmentReader == reader),
"Inconsistent Write Function Callback");
nsresult rv = ConfirmTLSProfile();
if (NS_FAILED(rv))
return rv;
if (reader)
mSegmentReader = reader;
*countRead = 0;
LOG3(("Http2Session::ReadSegments %p", this));
Http2Stream *stream = static_cast<Http2Stream *>(mReadyForWrite.PopFront());
if (!stream) {
LOG3(("Http2Session %p could not identify a stream to write; suspending.",
this));
uint32_t availBeforeFlush = mOutputQueueUsed - mOutputQueueSent;
FlushOutputQueue();
uint32_t availAfterFlush = mOutputQueueUsed - mOutputQueueSent;
if (availBeforeFlush != availAfterFlush) {
LOG3(("Http2Session %p ResumeRecv After early flush in ReadSegments", this));
ResumeRecv();
}
SetWriteCallbacks();
return NS_BASE_STREAM_WOULD_BLOCK;
}
LOG3(("Http2Session %p will write from Http2Stream %p 0x%X "
"block-input=%d block-output=%d\n", this, stream, stream->StreamID(),
stream->RequestBlockedOnRead(), stream->BlockedOnRwin()));
rv = stream->ReadSegments(this, count, countRead);
// Not every permutation of stream->ReadSegents produces data (and therefore
// tries to flush the output queue) - SENDING_FIN_STREAM can be an example
// of that. But we might still have old data buffered that would be good
// to flush.
FlushOutputQueue();
// Allow new server reads - that might be data or control information
// (e.g. window updates or http replies) that are responses to these writes
ResumeRecv();
if (stream->RequestBlockedOnRead()) {
// We are blocked waiting for input - either more http headers or
// any request body data. When more data from the request stream
// becomes available the httptransaction will call conn->ResumeSend().
LOG3(("Http2Session::ReadSegments %p dealing with block on read", this));
// call readsegments again if there are other streams ready
// to run in this session
if (GetWriteQueueSize()) {
rv = NS_OK;
} else {
rv = NS_BASE_STREAM_WOULD_BLOCK;
}
SetWriteCallbacks();
return rv;
}
if (NS_FAILED(rv)) {
LOG3(("Http2Session::ReadSegments %p may return FAIL code %X",
this, rv));
if (rv == NS_BASE_STREAM_WOULD_BLOCK) {
return rv;
}
CleanupStream(stream, rv, CANCEL_ERROR);
if (SoftStreamError(rv)) {
LOG3(("Http2Session::ReadSegments %p soft error override\n", this));
*again = false;
SetWriteCallbacks();
rv = NS_OK;
}
return rv;
}
if (*countRead > 0) {
LOG3(("Http2Session::ReadSegments %p stream=%p countread=%d",
this, stream, *countRead));
mReadyForWrite.Push(stream);
SetWriteCallbacks();
return rv;
}
if (stream->BlockedOnRwin()) {
LOG3(("Http2Session %p will stream %p 0x%X suspended for flow control\n",
this, stream, stream->StreamID()));
return NS_BASE_STREAM_WOULD_BLOCK;
}
LOG3(("Http2Session::ReadSegments %p stream=%p stream send complete",
this, stream));
// call readsegments again if there are other streams ready
// to go in this session
SetWriteCallbacks();
return rv;
}
nsresult
Http2Session::ReadSegments(nsAHttpSegmentReader *reader,
uint32_t count, uint32_t *countRead)
{
bool again = false;
return ReadSegmentsAgain(reader, count, countRead, &again);
}
nsresult
Http2Session::ReadyToProcessDataFrame(enum internalStateType newState)
{
MOZ_ASSERT(newState == PROCESSING_DATA_FRAME ||
newState == DISCARDING_DATA_FRAME_PADDING);
ChangeDownstreamState(newState);
Telemetry::Accumulate(Telemetry::SPDY_CHUNK_RECVD,
mInputFrameDataSize >> 10);
mLastDataReadEpoch = mLastReadEpoch;
if (!mInputFrameID) {
LOG3(("Http2Session::ReadyToProcessDataFrame %p data frame stream 0\n",
this));
RETURN_SESSION_ERROR(this, PROTOCOL_ERROR);
}
nsresult rv = SetInputFrameDataStream(mInputFrameID);
if (NS_FAILED(rv)) {
LOG3(("Http2Session::ReadyToProcessDataFrame %p lookup streamID 0x%X "
"failed. probably due to verification.\n", this, mInputFrameID));
return rv;
}
if (!mInputFrameDataStream) {
LOG3(("Http2Session::ReadyToProcessDataFrame %p lookup streamID 0x%X "
"failed. Next = 0x%X", this, mInputFrameID, mNextStreamID));
if (mInputFrameID >= mNextStreamID)
GenerateRstStream(PROTOCOL_ERROR, mInputFrameID);
ChangeDownstreamState(DISCARDING_DATA_FRAME);
} else if (mInputFrameDataStream->RecvdFin() ||
mInputFrameDataStream->RecvdReset() ||
mInputFrameDataStream->SentReset()) {
LOG3(("Http2Session::ReadyToProcessDataFrame %p streamID 0x%X "
"Data arrived for already server closed stream.\n",
this, mInputFrameID));
if (mInputFrameDataStream->RecvdFin() || mInputFrameDataStream->RecvdReset())
GenerateRstStream(STREAM_CLOSED_ERROR, mInputFrameID);
ChangeDownstreamState(DISCARDING_DATA_FRAME);
}
LOG3(("Start Processing Data Frame. "
"Session=%p Stream ID 0x%X Stream Ptr %p Fin=%d Len=%d",
this, mInputFrameID, mInputFrameDataStream, mInputFrameFinal,
mInputFrameDataSize));
UpdateLocalRwin(mInputFrameDataStream, mInputFrameDataSize);
if (mInputFrameDataStream) {
mInputFrameDataStream->SetRecvdData(true);
}
return NS_OK;
}
// WriteSegments() is used to read data off the socket. Generally this is
// just the http2 frame header and from there the appropriate *Stream
// is identified from the Stream-ID. The http transaction associated with
// that read then pulls in the data directly, which it will feed to
// OnWriteSegment(). That function will gateway it into http and feed
// it to the appropriate transaction.
// we call writer->OnWriteSegment via NetworkRead() to get a http2 header..
// and decide if it is data or control.. if it is control, just deal with it.
// if it is data, identify the stream
// call stream->WriteSegments which can call this::OnWriteSegment to get the
// data. It always gets full frames if they are part of the stream
nsresult
Http2Session::WriteSegmentsAgain(nsAHttpSegmentWriter *writer,
uint32_t count, uint32_t *countWritten,
bool *again)
{
MOZ_ASSERT(PR_GetCurrentThread() == gSocketThread);
LOG3(("Http2Session::WriteSegments %p InternalState %X\n",
this, mDownstreamState));
*countWritten = 0;
if (mClosed)
return NS_ERROR_FAILURE;
nsresult rv = ConfirmTLSProfile();
if (NS_FAILED(rv))
return rv;
SetWriteCallbacks();
// If there are http transactions attached to a push stream with filled buffers
// trigger that data pump here. This only reads from buffers (not the network)
// so mDownstreamState doesn't matter.
Http2Stream *pushConnectedStream =
static_cast<Http2Stream *>(mPushesReadyForRead.PopFront());
if (pushConnectedStream) {
return ProcessConnectedPush(pushConnectedStream, writer, count, countWritten);
}
// feed gecko channels that previously stopped consuming data
// only take data from stored buffers
Http2Stream *slowConsumer =
static_cast<Http2Stream *>(mSlowConsumersReadyForRead.PopFront());
if (slowConsumer) {
internalStateType savedState = mDownstreamState;
mDownstreamState = NOT_USING_NETWORK;
rv = ProcessSlowConsumer(slowConsumer, writer, count, countWritten);
mDownstreamState = savedState;
return rv;
}
// The BUFFERING_OPENING_SETTINGS state is just like any BUFFERING_FRAME_HEADER
// except the only frame type it will allow is SETTINGS
// The session layer buffers the leading 8 byte header of every frame.
// Non-Data frames are then buffered for their full length, but data
// frames (type 0) are passed through to the http stack unprocessed
if (mDownstreamState == BUFFERING_OPENING_SETTINGS ||
mDownstreamState == BUFFERING_FRAME_HEADER) {
// The first 9 bytes of every frame is header information that
// we are going to want to strip before passing to http. That is
// true of both control and data packets.
MOZ_ASSERT(mInputFrameBufferUsed < kFrameHeaderBytes,
"Frame Buffer Used Too Large for State");
rv = NetworkRead(writer, &mInputFrameBuffer[mInputFrameBufferUsed],
kFrameHeaderBytes - mInputFrameBufferUsed, countWritten);
if (NS_FAILED(rv)) {
LOG3(("Http2Session %p buffering frame header read failure %x\n",
this, rv));
// maybe just blocked reading from network
if (rv == NS_BASE_STREAM_WOULD_BLOCK)
rv = NS_OK;
return rv;
}
LogIO(this, nullptr, "Reading Frame Header",
&mInputFrameBuffer[mInputFrameBufferUsed], *countWritten);
mInputFrameBufferUsed += *countWritten;
if (mInputFrameBufferUsed < kFrameHeaderBytes)
{
LOG3(("Http2Session::WriteSegments %p "
"BUFFERING FRAME HEADER incomplete size=%d",
this, mInputFrameBufferUsed));
return rv;
}
// 3 bytes of length, 1 type byte, 1 flag byte, 1 unused bit, 31 bits of ID
uint8_t totallyWastedByte = mInputFrameBuffer.get()[0];
mInputFrameDataSize = NetworkEndian::readUint16(
mInputFrameBuffer.get() + 1);
if (totallyWastedByte || (mInputFrameDataSize > kMaxFrameData)) {
LOG3(("Got frame too large 0x%02X%04X", totallyWastedByte, mInputFrameDataSize));
RETURN_SESSION_ERROR(this, PROTOCOL_ERROR);
}
mInputFrameType = *reinterpret_cast<uint8_t *>(mInputFrameBuffer.get() + kFrameLengthBytes);
mInputFrameFlags = *reinterpret_cast<uint8_t *>(mInputFrameBuffer.get() + kFrameLengthBytes + kFrameTypeBytes);
mInputFrameID = NetworkEndian::readUint32(
mInputFrameBuffer.get() + kFrameLengthBytes + kFrameTypeBytes + kFrameFlagBytes);
mInputFrameID &= 0x7fffffff;
mInputFrameDataRead = 0;
if (mInputFrameType == FRAME_TYPE_DATA || mInputFrameType == FRAME_TYPE_HEADERS) {
mInputFrameFinal = mInputFrameFlags & kFlag_END_STREAM;
} else {
mInputFrameFinal = 0;
}
mPaddingLength = 0;
LOG3(("Http2Session::WriteSegments[%p::%x] Frame Header Read "
"type %X data len %u flags %x id 0x%X",
this, mSerial, mInputFrameType, mInputFrameDataSize, mInputFrameFlags,
mInputFrameID));
// if mExpectedHeaderID is non 0, it means this frame must be a CONTINUATION of
// a HEADERS frame with a matching ID (section 6.2)
if (mExpectedHeaderID &&
((mInputFrameType != FRAME_TYPE_CONTINUATION) ||
(mExpectedHeaderID != mInputFrameID))) {
LOG3(("Expected CONINUATION OF HEADERS for ID 0x%X\n", mExpectedHeaderID));
RETURN_SESSION_ERROR(this, PROTOCOL_ERROR);
}
// if mExpectedPushPromiseID is non 0, it means this frame must be a
// CONTINUATION of a PUSH_PROMISE with a matching ID (section 6.2)
if (mExpectedPushPromiseID &&
((mInputFrameType != FRAME_TYPE_CONTINUATION) ||
(mExpectedPushPromiseID != mInputFrameID))) {
LOG3(("Expected CONTINUATION of PUSH PROMISE for ID 0x%X\n",
mExpectedPushPromiseID));
RETURN_SESSION_ERROR(this, PROTOCOL_ERROR);
}
if (mDownstreamState == BUFFERING_OPENING_SETTINGS &&
mInputFrameType != FRAME_TYPE_SETTINGS) {
LOG3(("First Frame Type Must Be Settings\n"));
RETURN_SESSION_ERROR(this, PROTOCOL_ERROR);
}
if (mInputFrameType != FRAME_TYPE_DATA) { // control frame
EnsureBuffer(mInputFrameBuffer, mInputFrameDataSize + kFrameHeaderBytes,
kFrameHeaderBytes, mInputFrameBufferSize);
ChangeDownstreamState(BUFFERING_CONTROL_FRAME);
} else if (mInputFrameFlags & kFlag_PADDED) {
ChangeDownstreamState(PROCESSING_DATA_FRAME_PADDING_CONTROL);
} else {
rv = ReadyToProcessDataFrame(PROCESSING_DATA_FRAME);
if (NS_FAILED(rv)) {
return rv;
}
}
}
if (mDownstreamState == PROCESSING_DATA_FRAME_PADDING_CONTROL) {
MOZ_ASSERT(mInputFrameFlags & kFlag_PADDED,
"Processing padding control on unpadded frame");
MOZ_ASSERT(mInputFrameBufferUsed < (kFrameHeaderBytes + 1),
"Frame buffer used too large for state");
rv = NetworkRead(writer, &mInputFrameBuffer[mInputFrameBufferUsed],
(kFrameHeaderBytes + 1) - mInputFrameBufferUsed,
countWritten);
if (NS_FAILED(rv)) {
LOG3(("Http2Session %p buffering data frame padding control read failure %x\n",
this, rv));
// maybe just blocked reading from network
if (rv == NS_BASE_STREAM_WOULD_BLOCK)
rv = NS_OK;
return rv;
}
LogIO(this, nullptr, "Reading Data Frame Padding Control",
&mInputFrameBuffer[mInputFrameBufferUsed], *countWritten);
mInputFrameBufferUsed += *countWritten;
if (mInputFrameBufferUsed - kFrameHeaderBytes < 1) {
LOG3(("Http2Session::WriteSegments %p "
"BUFFERING DATA FRAME CONTROL PADDING incomplete size=%d",
this, mInputFrameBufferUsed - 8));
return rv;
}
++mInputFrameDataRead;
char *control = &mInputFrameBuffer[kFrameHeaderBytes];
mPaddingLength = static_cast<uint8_t>(*control);
LOG3(("Http2Session::WriteSegments %p stream 0x%X mPaddingLength=%d", this,
mInputFrameID, mPaddingLength));
if (1U + mPaddingLength > mInputFrameDataSize) {
LOG3(("Http2Session::WriteSegments %p stream 0x%X padding too large for "
"frame", this, mInputFrameID));
RETURN_SESSION_ERROR(this, PROTOCOL_ERROR);
} else if (1U + mPaddingLength == mInputFrameDataSize) {
// This frame consists entirely of padding, we can just discard it
LOG3(("Http2Session::WriteSegments %p stream 0x%X frame with only padding",
this, mInputFrameID));
rv = ReadyToProcessDataFrame(DISCARDING_DATA_FRAME_PADDING);
if (NS_FAILED(rv)) {
return rv;
}
} else {
LOG3(("Http2Session::WriteSegments %p stream 0x%X ready to read HTTP data",
this, mInputFrameID));
rv = ReadyToProcessDataFrame(PROCESSING_DATA_FRAME);
if (NS_FAILED(rv)) {
return rv;
}
}
}
if (mDownstreamState == PROCESSING_CONTROL_RST_STREAM) {
nsresult streamCleanupCode;
// There is no bounds checking on the error code.. we provide special
// handling for a couple of cases and all others (including unknown) are
// equivalent to cancel.
if (mDownstreamRstReason == REFUSED_STREAM_ERROR) {
streamCleanupCode = NS_ERROR_NET_RESET; // can retry this 100% safely
mInputFrameDataStream->Transaction()->ReuseConnectionOnRestartOK(true);
} else if (mDownstreamRstReason == HTTP_1_1_REQUIRED) {
streamCleanupCode = NS_ERROR_NET_RESET;
mInputFrameDataStream->Transaction()->ReuseConnectionOnRestartOK(true);
mInputFrameDataStream->Transaction()->DisableSpdy();
} else {
streamCleanupCode = mInputFrameDataStream->RecvdData() ?
NS_ERROR_NET_PARTIAL_TRANSFER :
NS_ERROR_NET_INTERRUPT;
}
if (mDownstreamRstReason == COMPRESSION_ERROR) {
mShouldGoAway = true;
}
// mInputFrameDataStream is reset by ChangeDownstreamState
Http2Stream *stream = mInputFrameDataStream;
ResetDownstreamState();
LOG3(("Http2Session::WriteSegments cleanup stream on recv of rst "
"session=%p stream=%p 0x%X\n", this, stream,
stream ? stream->StreamID() : 0));
CleanupStream(stream, streamCleanupCode, CANCEL_ERROR);
return NS_OK;
}
if (mDownstreamState == PROCESSING_DATA_FRAME ||
mDownstreamState == PROCESSING_COMPLETE_HEADERS) {
// The cleanup stream should only be set while stream->WriteSegments is
// on the stack and then cleaned up in this code block afterwards.
MOZ_ASSERT(!mNeedsCleanup, "cleanup stream set unexpectedly");
mNeedsCleanup = nullptr; /* just in case */
uint32_t streamID = mInputFrameDataStream->StreamID();
mSegmentWriter = writer;
rv = mInputFrameDataStream->WriteSegments(this, count, countWritten);
mSegmentWriter = nullptr;
mLastDataReadEpoch = mLastReadEpoch;
if (SoftStreamError(rv)) {
// This will happen when the transaction figures out it is EOF, generally
// due to a content-length match being made. Return OK from this function
// otherwise the whole session would be torn down.
// if we were doing PROCESSING_COMPLETE_HEADERS need to pop the state
// back to PROCESSING_DATA_FRAME where we came from
mDownstreamState = PROCESSING_DATA_FRAME;
if (mInputFrameDataRead == mInputFrameDataSize)
ResetDownstreamState();
LOG3(("Http2Session::WriteSegments session=%p id 0x%X "
"needscleanup=%p. cleanup stream based on "
"stream->writeSegments returning code %x\n",
this, streamID, mNeedsCleanup, rv));
MOZ_ASSERT(!mNeedsCleanup || mNeedsCleanup->StreamID() == streamID);
CleanupStream(streamID, NS_OK, CANCEL_ERROR);
mNeedsCleanup = nullptr;
*again = false;
ResumeRecv();
return NS_OK;
}
if (mNeedsCleanup) {
LOG3(("Http2Session::WriteSegments session=%p stream=%p 0x%X "
"cleanup stream based on mNeedsCleanup.\n",
this, mNeedsCleanup, mNeedsCleanup ? mNeedsCleanup->StreamID() : 0));
CleanupStream(mNeedsCleanup, NS_OK, CANCEL_ERROR);
mNeedsCleanup = nullptr;
}
if (NS_FAILED(rv)) {
LOG3(("Http2Session %p data frame read failure %x\n", this, rv));
// maybe just blocked reading from network
if (rv == NS_BASE_STREAM_WOULD_BLOCK)
rv = NS_OK;
}
return rv;
}
if (mDownstreamState == DISCARDING_DATA_FRAME ||
mDownstreamState == DISCARDING_DATA_FRAME_PADDING) {
char trash[4096];
uint32_t count = std::min(4096U, mInputFrameDataSize - mInputFrameDataRead);
LOG3(("Http2Session::WriteSegments %p trying to discard %d bytes of data",
this, count));
if (!count && mDownstreamState == DISCARDING_DATA_FRAME) {
// Only do this short-cirtuit if we're not discarding a pure padding
// frame, as we need to potentially handle the stream FIN in those cases.
// See bug 1381016 comment 36 for more details.
ResetDownstreamState();
ResumeRecv();
return NS_BASE_STREAM_WOULD_BLOCK;
}
rv = NetworkRead(writer, trash, count, countWritten);
if (NS_FAILED(rv)) {
LOG3(("Http2Session %p discard frame read failure %x\n", this, rv));
// maybe just blocked reading from network
if (rv == NS_BASE_STREAM_WOULD_BLOCK)
rv = NS_OK;
return rv;
}
LogIO(this, nullptr, "Discarding Frame", trash, *countWritten);
mInputFrameDataRead += *countWritten;
if (mInputFrameDataRead == mInputFrameDataSize) {
Http2Stream *streamToCleanup = nullptr;
if (mInputFrameFinal) {
streamToCleanup = mInputFrameDataStream;
}
ResetDownstreamState();
if (streamToCleanup) {
CleanupStream(streamToCleanup, NS_OK, CANCEL_ERROR);
}
}
return rv;
}
if (mDownstreamState != BUFFERING_CONTROL_FRAME) {
MOZ_ASSERT(false); // this cannot happen
return NS_ERROR_UNEXPECTED;
}
MOZ_ASSERT(mInputFrameBufferUsed == kFrameHeaderBytes, "Frame Buffer Header Not Present");
MOZ_ASSERT(mInputFrameDataSize + kFrameHeaderBytes <= mInputFrameBufferSize,
"allocation for control frame insufficient");
rv = NetworkRead(writer, &mInputFrameBuffer[kFrameHeaderBytes + mInputFrameDataRead],
mInputFrameDataSize - mInputFrameDataRead, countWritten);
if (NS_FAILED(rv)) {
LOG3(("Http2Session %p buffering control frame read failure %x\n",
this, rv));
// maybe just blocked reading from network
if (rv == NS_BASE_STREAM_WOULD_BLOCK)
rv = NS_OK;
return rv;
}
LogIO(this, nullptr, "Reading Control Frame",
&mInputFrameBuffer[kFrameHeaderBytes + mInputFrameDataRead], *countWritten);
mInputFrameDataRead += *countWritten;
if (mInputFrameDataRead != mInputFrameDataSize)
return NS_OK;
MOZ_ASSERT(mInputFrameType != FRAME_TYPE_DATA);
if (mInputFrameType < FRAME_TYPE_LAST) {
rv = sControlFunctions[mInputFrameType](this);
} else {
// Section 4.1 requires this to be ignored; though protocol_error would
// be better
LOG3(("Http2Session %p unknown frame type %x ignored\n",
this, mInputFrameType));
ResetDownstreamState();
rv = NS_OK;
}
MOZ_ASSERT(NS_FAILED(rv) ||
mDownstreamState != BUFFERING_CONTROL_FRAME,
"Control Handler returned OK but did not change state");
if (mShouldGoAway && !mStreamTransactionHash.Count())
Close(NS_OK);
return rv;
}
nsresult
Http2Session::WriteSegments(nsAHttpSegmentWriter *writer,
uint32_t count, uint32_t *countWritten)
{
bool again = false;
return WriteSegmentsAgain(writer, count, countWritten, &again);
}
nsresult
Http2Session::ProcessConnectedPush(Http2Stream *pushConnectedStream,
nsAHttpSegmentWriter * writer,
uint32_t count, uint32_t *countWritten)
{
LOG3(("Http2Session::ProcessConnectedPush %p 0x%X\n",
this, pushConnectedStream->StreamID()));
mSegmentWriter = writer;
nsresult rv = pushConnectedStream->WriteSegments(this, count, countWritten);
mSegmentWriter = nullptr;
// The pipe in nsHttpTransaction rewrites CLOSED error codes into OK
// so we need this check to determine the truth.
if (NS_SUCCEEDED(rv) && !*countWritten &&
pushConnectedStream->PushSource() &&
pushConnectedStream->PushSource()->GetPushComplete()) {
rv = NS_BASE_STREAM_CLOSED;
}
if (rv == NS_BASE_STREAM_CLOSED) {
CleanupStream(pushConnectedStream, NS_OK, CANCEL_ERROR);
rv = NS_OK;
}
// if we return OK to nsHttpConnection it will use mSocketInCondition
// to determine whether to schedule more reads, incorrectly
// assuming that nsHttpConnection::OnSocketWrite() was called.
if (NS_SUCCEEDED(rv) || rv == NS_BASE_STREAM_WOULD_BLOCK) {
rv = NS_BASE_STREAM_WOULD_BLOCK;
ResumeRecv();
}
return rv;
}
nsresult
Http2Session::ProcessSlowConsumer(Http2Stream *slowConsumer,
nsAHttpSegmentWriter * writer,
uint32_t count, uint32_t *countWritten)
{
LOG3(("Http2Session::ProcessSlowConsumer %p 0x%X\n",
this, slowConsumer->StreamID()));
mSegmentWriter = writer;
nsresult rv = slowConsumer->WriteSegments(this, count, countWritten);
mSegmentWriter = nullptr;
LOG3(("Http2Session::ProcessSlowConsumer Writesegments %p 0x%X rv %X %d\n",
this, slowConsumer->StreamID(), rv, *countWritten));
if (NS_SUCCEEDED(rv) && !*countWritten && slowConsumer->RecvdFin()) {
rv = NS_BASE_STREAM_CLOSED;
}
if (NS_SUCCEEDED(rv) && (*countWritten > 0)) {
// There have been buffered bytes successfully fed into the
// formerly blocked consumer. Repeat until buffer empty or
// consumer is blocked again.
UpdateLocalRwin(slowConsumer, 0);
ConnectSlowConsumer(slowConsumer);
}
if (rv == NS_BASE_STREAM_CLOSED) {
CleanupStream(slowConsumer, NS_OK, CANCEL_ERROR);
rv = NS_OK;
}
return rv;
}
void
Http2Session::UpdateLocalStreamWindow(Http2Stream *stream, uint32_t bytes)
{
if (!stream) // this is ok - it means there was a data frame for a rst stream
return;
// If this data packet was not for a valid or live stream then there
// is no reason to mess with the flow control
if (!stream || stream->RecvdFin() || stream->RecvdReset() ||
mInputFrameFinal) {
return;
}
stream->DecrementClientReceiveWindow(bytes);
// Don't necessarily ack every data packet. Only do it
// after a significant amount of data.
uint64_t unacked = stream->LocalUnAcked();
int64_t localWindow = stream->ClientReceiveWindow();
LOG3(("Http2Session::UpdateLocalStreamWindow this=%p id=0x%X newbytes=%u "
"unacked=%llu localWindow=%lld\n",
this, stream->StreamID(), bytes, unacked, localWindow));
if (!unacked)
return;
if ((unacked < kMinimumToAck) && (localWindow > kEmergencyWindowThreshold))
return;
if (!stream->HasSink()) {
LOG3(("Http2Session::UpdateLocalStreamWindow %p 0x%X Pushed Stream Has No Sink\n",
this, stream->StreamID()));
return;
}
// Generate window updates directly out of session instead of the stream
// in order to avoid queue delays in getting the 'ACK' out.
uint32_t toack = (unacked <= 0x7fffffffU) ? unacked : 0x7fffffffU;
LOG3(("Http2Session::UpdateLocalStreamWindow Ack this=%p id=0x%X acksize=%d\n",
this, stream->StreamID(), toack));
stream->IncrementClientReceiveWindow(toack);
if (toack == 0) {
// Ensure we never send an illegal 0 window update
return;
}
// room for this packet needs to be ensured before calling this function
char *packet = mOutputQueueBuffer.get() + mOutputQueueUsed;
mOutputQueueUsed += kFrameHeaderBytes + 4;
MOZ_ASSERT(mOutputQueueUsed <= mOutputQueueSize);
CreateFrameHeader(packet, 4, FRAME_TYPE_WINDOW_UPDATE, 0, stream->StreamID());
NetworkEndian::writeUint32(packet + kFrameHeaderBytes, toack);
LogIO(this, stream, "Stream Window Update", packet, kFrameHeaderBytes + 4);
// dont flush here, this write can commonly be coalesced with a
// session window update to immediately follow.
}
void
Http2Session::UpdateLocalSessionWindow(uint32_t bytes)
{
if (!bytes)
return;
mLocalSessionWindow -= bytes;
LOG3(("Http2Session::UpdateLocalSessionWindow this=%p newbytes=%u "
"localWindow=%lld\n", this, bytes, mLocalSessionWindow));
// Don't necessarily ack every data packet. Only do it
// after a significant amount of data.
if ((mLocalSessionWindow > (mInitialRwin - kMinimumToAck)) &&
(mLocalSessionWindow > kEmergencyWindowThreshold))
return;
// Only send max bits of window updates at a time.
uint64_t toack64 = mInitialRwin - mLocalSessionWindow;
uint32_t toack = (toack64 <= 0x7fffffffU) ? toack64 : 0x7fffffffU;
LOG3(("Http2Session::UpdateLocalSessionWindow Ack this=%p acksize=%u\n",
this, toack));
mLocalSessionWindow += toack;
if (toack == 0) {
// Ensure we never send an illegal 0 window update
return;
}
// room for this packet needs to be ensured before calling this function
char *packet = mOutputQueueBuffer.get() + mOutputQueueUsed;
mOutputQueueUsed += kFrameHeaderBytes + 4;
MOZ_ASSERT(mOutputQueueUsed <= mOutputQueueSize);
CreateFrameHeader(packet, 4, FRAME_TYPE_WINDOW_UPDATE, 0, 0);
NetworkEndian::writeUint32(packet + kFrameHeaderBytes, toack);
LogIO(this, nullptr, "Session Window Update", packet, kFrameHeaderBytes + 4);
// dont flush here, this write can commonly be coalesced with others
}
void
Http2Session::UpdateLocalRwin(Http2Stream *stream, uint32_t bytes)
{
// make sure there is room for 2 window updates even though
// we may not generate any.
EnsureOutputBuffer(2 * (kFrameHeaderBytes + 4));
UpdateLocalStreamWindow(stream, bytes);
UpdateLocalSessionWindow(bytes);
FlushOutputQueue();
}
void
Http2Session::Close(nsresult aReason)
{
MOZ_ASSERT(PR_GetCurrentThread() == gSocketThread);
if (mClosed)
return;
LOG3(("Http2Session::Close %p %X", this, aReason));
mClosed = true;
mStreamTransactionHash.Enumerate(ShutdownEnumerator, this);
mStreamIDHash.Clear();
mStreamTransactionHash.Clear();
uint32_t goAwayReason;
if (mGoAwayReason != NO_HTTP_ERROR) {
goAwayReason = mGoAwayReason;
} else if (NS_SUCCEEDED(aReason)) {
goAwayReason = NO_HTTP_ERROR;
} else if (aReason == NS_ERROR_ILLEGAL_VALUE) {
goAwayReason = PROTOCOL_ERROR;
} else {
goAwayReason = INTERNAL_ERROR;
}
GenerateGoAway(goAwayReason);
mConnection = nullptr;
mSegmentReader = nullptr;
mSegmentWriter = nullptr;
}
nsHttpConnectionInfo *
Http2Session::ConnectionInfo()
{
RefPtr<nsHttpConnectionInfo> ci;
GetConnectionInfo(getter_AddRefs(ci));
return ci.get();
}
void
Http2Session::CloseTransaction(nsAHttpTransaction *aTransaction,
nsresult aResult)
{
MOZ_ASSERT(PR_GetCurrentThread() == gSocketThread);
LOG3(("Http2Session::CloseTransaction %p %p %x", this, aTransaction, aResult));
// Generally this arrives as a cancel event from the connection manager.
// need to find the stream and call CleanupStream() on it.
Http2Stream *stream = mStreamTransactionHash.Get(aTransaction);
if (!stream) {
LOG3(("Http2Session::CloseTransaction %p %p %x - not found.",
this, aTransaction, aResult));
return;
}
LOG3(("Http2Session::CloseTransaction probably a cancel. "
"this=%p, trans=%p, result=%x, streamID=0x%X stream=%p",
this, aTransaction, aResult, stream->StreamID(), stream));
CleanupStream(stream, aResult, CANCEL_ERROR);
ResumeRecv();
}
//-----------------------------------------------------------------------------
// nsAHttpSegmentReader
//-----------------------------------------------------------------------------
nsresult
Http2Session::OnReadSegment(const char *buf,
uint32_t count, uint32_t *countRead)
{
MOZ_ASSERT(PR_GetCurrentThread() == gSocketThread);
nsresult rv;
// If we can release old queued data then we can try and write the new
// data directly to the network without using the output queue at all
if (mOutputQueueUsed)
FlushOutputQueue();
if (!mOutputQueueUsed && mSegmentReader) {
// try and write directly without output queue
rv = mSegmentReader->OnReadSegment(buf, count, countRead);
if (rv == NS_BASE_STREAM_WOULD_BLOCK) {
*countRead = 0;
} else if (NS_FAILED(rv)) {
return rv;
}
if (*countRead < count) {
uint32_t required = count - *countRead;
// assuming a commitment() happened, this ensurebuffer is a nop
// but just in case the queuesize is too small for the required data
// call ensurebuffer().
EnsureBuffer(mOutputQueueBuffer, required, 0, mOutputQueueSize);
memcpy(mOutputQueueBuffer.get(), buf + *countRead, required);
mOutputQueueUsed = required;
}
*countRead = count;
return NS_OK;
}
// At this point we are going to buffer the new data in the output
// queue if it fits. By coalescing multiple small submissions into one larger
// buffer we can get larger writes out to the network later on.
// This routine should not be allowed to fill up the output queue
// all on its own - at least kQueueReserved bytes are always left
// for other routines to use - but this is an all-or-nothing function,
// so if it will not all fit just return WOULD_BLOCK
if ((mOutputQueueUsed + count) > (mOutputQueueSize - kQueueReserved))
return NS_BASE_STREAM_WOULD_BLOCK;
memcpy(mOutputQueueBuffer.get() + mOutputQueueUsed, buf, count);
mOutputQueueUsed += count;
*countRead = count;
FlushOutputQueue();
return NS_OK;
}
nsresult
Http2Session::CommitToSegmentSize(uint32_t count, bool forceCommitment)
{
if (mOutputQueueUsed)
FlushOutputQueue();
// would there be enough room to buffer this if needed?
if ((mOutputQueueUsed + count) <= (mOutputQueueSize - kQueueReserved))
return NS_OK;
// if we are using part of our buffers already, try again later unless
// forceCommitment is set.
if (mOutputQueueUsed && !forceCommitment)
return NS_BASE_STREAM_WOULD_BLOCK;
if (mOutputQueueUsed) {
// normally we avoid the memmove of RealignOutputQueue, but we'll try
// it if forceCommitment is set before growing the buffer.
RealignOutputQueue();
// is there enough room now?
if ((mOutputQueueUsed + count) <= (mOutputQueueSize - kQueueReserved))
return NS_OK;
}
// resize the buffers as needed
EnsureOutputBuffer(count + kQueueReserved);
MOZ_ASSERT((mOutputQueueUsed + count) <= (mOutputQueueSize - kQueueReserved),
"buffer not as large as expected");
return NS_OK;
}
//-----------------------------------------------------------------------------
// nsAHttpSegmentWriter
//-----------------------------------------------------------------------------
nsresult
Http2Session::OnWriteSegment(char *buf,
uint32_t count, uint32_t *countWritten)
{
MOZ_ASSERT(PR_GetCurrentThread() == gSocketThread);
nsresult rv;
if (!mSegmentWriter) {
// the only way this could happen would be if Close() were called on the
// stack with WriteSegments()
return NS_ERROR_FAILURE;
}
if (mDownstreamState == NOT_USING_NETWORK ||
mDownstreamState == BUFFERING_FRAME_HEADER ||
mDownstreamState == DISCARDING_DATA_FRAME_PADDING) {
return NS_BASE_STREAM_WOULD_BLOCK;
}
if (mDownstreamState == PROCESSING_DATA_FRAME) {
if (mInputFrameFinal &&
mInputFrameDataRead == mInputFrameDataSize) {
*countWritten = 0;
SetNeedsCleanup();
return NS_BASE_STREAM_CLOSED;
}
count = std::min(count, mInputFrameDataSize - mInputFrameDataRead);
rv = NetworkRead(mSegmentWriter, buf, count, countWritten);
if (NS_FAILED(rv))
return rv;
LogIO(this, mInputFrameDataStream, "Reading Data Frame",
buf, *countWritten);
mInputFrameDataRead += *countWritten;
if (mPaddingLength && (mInputFrameDataSize - mInputFrameDataRead <= mPaddingLength)) {
// We are crossing from real HTTP data into the realm of padding. If
// we've actually crossed the line, we need to munge countWritten for the
// sake of goodness and sanity. No matter what, any future calls to
// WriteSegments need to just discard data until we reach the end of this
// frame.
if (mInputFrameDataSize != mInputFrameDataRead) {
// Only change state if we still have padding to read. If we don't do
// this, we can end up hanging on frames that combine real data,
// padding, and END_STREAM (see bug 1019921)
ChangeDownstreamState(DISCARDING_DATA_FRAME_PADDING);
}
uint32_t paddingRead = mPaddingLength - (mInputFrameDataSize - mInputFrameDataRead);
LOG3(("Http2Session::OnWriteSegment %p stream 0x%X len=%d read=%d "
"crossed from HTTP data into padding (%d of %d) countWritten=%d",
this, mInputFrameID, mInputFrameDataSize, mInputFrameDataRead,
paddingRead, mPaddingLength, *countWritten));
*countWritten -= paddingRead;
LOG3(("Http2Session::OnWriteSegment %p stream 0x%X new countWritten=%d",
this, mInputFrameID, *countWritten));
}
mInputFrameDataStream->UpdateTransportReadEvents(*countWritten);
if ((mInputFrameDataRead == mInputFrameDataSize) && !mInputFrameFinal)
ResetDownstreamState();
return rv;
}
if (mDownstreamState == PROCESSING_COMPLETE_HEADERS) {
if (mFlatHTTPResponseHeaders.Length() == mFlatHTTPResponseHeadersOut &&
mInputFrameFinal) {
*countWritten = 0;
SetNeedsCleanup();
return NS_BASE_STREAM_CLOSED;
}
count = std::min(count,
mFlatHTTPResponseHeaders.Length() -
mFlatHTTPResponseHeadersOut);
memcpy(buf,
mFlatHTTPResponseHeaders.get() + mFlatHTTPResponseHeadersOut,
count);
mFlatHTTPResponseHeadersOut += count;
*countWritten = count;
if (mFlatHTTPResponseHeaders.Length() == mFlatHTTPResponseHeadersOut) {
if (!mInputFrameFinal) {
// If more frames are expected in this stream, then reset the state so they can be
// handled. Otherwise (e.g. a 0 length response with the fin on the incoming headers)
// stay in PROCESSING_COMPLETE_HEADERS state so the SetNeedsCleanup() code above can
// cleanup the stream.
ResetDownstreamState();
}
}
return NS_OK;
}
MOZ_ASSERT(false);
return NS_ERROR_UNEXPECTED;
}
void
Http2Session::SetNeedsCleanup()
{
LOG3(("Http2Session::SetNeedsCleanup %p - recorded downstream fin of "
"stream %p 0x%X", this, mInputFrameDataStream,
mInputFrameDataStream->StreamID()));
// This will result in Close() being called
MOZ_ASSERT(!mNeedsCleanup, "mNeedsCleanup unexpectedly set");
mNeedsCleanup = mInputFrameDataStream;
ResetDownstreamState();
}
void
Http2Session::ConnectPushedStream(Http2Stream *stream)
{
mPushesReadyForRead.Push(stream);
ForceRecv();
}
void
Http2Session::ConnectSlowConsumer(Http2Stream *stream)
{
LOG3(("Http2Session::ConnectSlowConsumer %p 0x%X\n",
this, stream->StreamID()));
mSlowConsumersReadyForRead.Push(stream);
ForceRecv();
}
uint32_t
Http2Session::FindTunnelCount(nsHttpConnectionInfo *aConnInfo)
{
MOZ_ASSERT(PR_GetCurrentThread() == gSocketThread);
uint32_t rv = 0;
mTunnelHash.Get(aConnInfo->HashKey(), &rv);
return rv;
}
void
Http2Session::RegisterTunnel(Http2Stream *aTunnel)
{
MOZ_ASSERT(PR_GetCurrentThread() == gSocketThread);
nsHttpConnectionInfo *ci = aTunnel->Transaction()->ConnectionInfo();
uint32_t newcount = FindTunnelCount(ci) + 1;
mTunnelHash.Remove(ci->HashKey());
mTunnelHash.Put(ci->HashKey(), newcount);
LOG3(("Http2Stream::RegisterTunnel %p stream=%p tunnels=%d [%s]",
this, aTunnel, newcount, ci->HashKey().get()));
}
void
Http2Session::UnRegisterTunnel(Http2Stream *aTunnel)
{
MOZ_ASSERT(PR_GetCurrentThread() == gSocketThread);
nsHttpConnectionInfo *ci = aTunnel->Transaction()->ConnectionInfo();
MOZ_ASSERT(FindTunnelCount(ci));
uint32_t newcount = FindTunnelCount(ci) - 1;
mTunnelHash.Remove(ci->HashKey());
if (newcount) {
mTunnelHash.Put(ci->HashKey(), newcount);
}
LOG3(("Http2Session::UnRegisterTunnel %p stream=%p tunnels=%d [%s]",
this, aTunnel, newcount, ci->HashKey().get()));
}
void
Http2Session::CreateTunnel(nsHttpTransaction *trans,
nsHttpConnectionInfo *ci,
nsIInterfaceRequestor *aCallbacks)
{
LOG(("Http2Session::CreateTunnel %p %p make new tunnel\n", this, trans));
// The connect transaction will hold onto the underlying http
// transaction so that an auth created by the connect can be mappped
// to the correct security callbacks
RefPtr<SpdyConnectTransaction> connectTrans =
new SpdyConnectTransaction(ci, aCallbacks, trans->Caps(), trans, this);
AddStream(connectTrans, nsISupportsPriority::PRIORITY_NORMAL, false, nullptr);
Http2Stream *tunnel = mStreamTransactionHash.Get(connectTrans);
MOZ_ASSERT(tunnel);
RegisterTunnel(tunnel);
}
void
Http2Session::DispatchOnTunnel(nsAHttpTransaction *aHttpTransaction,
nsIInterfaceRequestor *aCallbacks)
{
MOZ_ASSERT(PR_GetCurrentThread() == gSocketThread);
nsHttpTransaction *trans = aHttpTransaction->QueryHttpTransaction();
nsHttpConnectionInfo *ci = aHttpTransaction->ConnectionInfo();
MOZ_ASSERT(trans);
LOG3(("Http2Session::DispatchOnTunnel %p trans=%p", this, trans));
aHttpTransaction->SetConnection(nullptr);
// this transaction has done its work of setting up a tunnel, let
// the connection manager queue it if necessary
trans->SetTunnelProvider(this);
trans->EnableKeepAlive();
if (FindTunnelCount(ci) < gHttpHandler->MaxConnectionsPerOrigin()) {
LOG3(("Http2Session::DispatchOnTunnel %p create on new tunnel %s",
this, ci->HashKey().get()));
CreateTunnel(trans, ci, aCallbacks);
} else {
// requeue it. The connection manager is responsible for actually putting
// this on the tunnel connection with the specific ci. If that can't
// happen the cmgr checks with us via MaybeReTunnel() to see if it should
// make a new tunnel or just wait longer.
LOG3(("Http2Session::DispatchOnTunnel %p trans=%p queue in connection manager",
this, trans));
gHttpHandler->InitiateTransaction(trans, trans->Priority());
}
}
// From ASpdySession
bool
Http2Session::MaybeReTunnel(nsAHttpTransaction *aHttpTransaction)
{
MOZ_ASSERT(PR_GetCurrentThread() == gSocketThread);
nsHttpTransaction *trans = aHttpTransaction->QueryHttpTransaction();
LOG(("Http2Session::MaybeReTunnel %p trans=%p\n", this, trans));
if (!trans || trans->TunnelProvider() != this) {
// this isn't really one of our transactions.
return false;
}
if (mClosed || mShouldGoAway) {
LOG(("Http2Session::MaybeReTunnel %p %p session closed - requeue\n", this, trans));
trans->SetTunnelProvider(nullptr);
gHttpHandler->InitiateTransaction(trans, trans->Priority());
return true;
}
nsHttpConnectionInfo *ci = aHttpTransaction->ConnectionInfo();
LOG(("Http2Session:MaybeReTunnel %p %p count=%d limit %d\n",
this, trans, FindTunnelCount(ci), gHttpHandler->MaxConnectionsPerOrigin()));
if (FindTunnelCount(ci) >= gHttpHandler->MaxConnectionsPerOrigin()) {
// patience - a tunnel will open up.
return false;
}
LOG(("Http2Session::MaybeReTunnel %p %p make new tunnel\n", this, trans));
CreateTunnel(trans, ci, trans->SecurityCallbacks());
return true;
}
nsresult
Http2Session::BufferOutput(const char *buf,
uint32_t count,
uint32_t *countRead)
{
nsAHttpSegmentReader *old = mSegmentReader;
mSegmentReader = nullptr;
nsresult rv = OnReadSegment(buf, count, countRead);
mSegmentReader = old;
return rv;
}
bool // static
Http2Session::ALPNCallback(nsISupports *securityInfo)
{
if (!gHttpHandler->IsH2MandatorySuiteEnabled()) {
LOG3(("Http2Session::ALPNCallback Mandatory Cipher Suite Unavailable\n"));
return false;
}
nsCOMPtr<nsISSLSocketControl> ssl = do_QueryInterface(securityInfo);
LOG3(("Http2Session::ALPNCallback sslsocketcontrol=%p\n", ssl.get()));
if (ssl) {
int16_t version = ssl->GetSSLVersionOffered();
LOG3(("Http2Session::ALPNCallback version=%x\n", version));
if (version >= nsISSLSocketControl::TLS_VERSION_1_2) {
return true;
}
}
return false;
}
nsresult
Http2Session::ConfirmTLSProfile()
{
if (mTLSProfileConfirmed)
return NS_OK;
LOG3(("Http2Session::ConfirmTLSProfile %p mConnection=%p\n",
this, mConnection.get()));
if (!gHttpHandler->EnforceHttp2TlsProfile()) {
LOG3(("Http2Session::ConfirmTLSProfile %p passed due to configuration bypass\n", this));
mTLSProfileConfirmed = true;
return NS_OK;
}
if (!mConnection)
return NS_ERROR_FAILURE;
nsCOMPtr<nsISupports> securityInfo;
mConnection->GetSecurityInfo(getter_AddRefs(securityInfo));
nsCOMPtr<nsISSLSocketControl> ssl = do_QueryInterface(securityInfo);
LOG3(("Http2Session::ConfirmTLSProfile %p sslsocketcontrol=%p\n", this, ssl.get()));
if (!ssl)
return NS_ERROR_FAILURE;
int16_t version = ssl->GetSSLVersionUsed();
LOG3(("Http2Session::ConfirmTLSProfile %p version=%x\n", this, version));
if (version < nsISSLSocketControl::TLS_VERSION_1_2) {
LOG3(("Http2Session::ConfirmTLSProfile %p FAILED due to lack of TLS1.2\n", this));
RETURN_SESSION_ERROR(this, INADEQUATE_SECURITY);
}
uint16_t kea = ssl->GetKEAUsed();
if (kea != ssl_kea_dh && kea != ssl_kea_ecdh) {
LOG3(("Http2Session::ConfirmTLSProfile %p FAILED due to invalid KEA %d\n",
this, kea));
RETURN_SESSION_ERROR(this, INADEQUATE_SECURITY);
}
uint32_t keybits = ssl->GetKEAKeyBits();
if (kea == ssl_kea_dh && keybits < 2048) {
LOG3(("Http2Session::ConfirmTLSProfile %p FAILED due to DH %d < 2048\n",
this, keybits));
RETURN_SESSION_ERROR(this, INADEQUATE_SECURITY);
} else if (kea == ssl_kea_ecdh && keybits < 224) { // see rfc7540 9.2.1.
LOG3(("Http2Session::ConfirmTLSProfile %p FAILED due to ECDH %d < 224\n",
this, keybits));
RETURN_SESSION_ERROR(this, INADEQUATE_SECURITY);
}
int16_t macAlgorithm = ssl->GetMACAlgorithmUsed();
LOG3(("Http2Session::ConfirmTLSProfile %p MAC Algortihm (aead==6) %d\n",
this, macAlgorithm));
if (macAlgorithm != nsISSLSocketControl::SSL_MAC_AEAD) {
LOG3(("Http2Session::ConfirmTLSProfile %p FAILED due to lack of AEAD\n", this));
RETURN_SESSION_ERROR(this, INADEQUATE_SECURITY);
}
/* We are required to send SNI. We do that already, so no check is done
* here to make sure we did. */
/* We really should check to ensure TLS compression isn't enabled on
* this connection. However, we never enable TLS compression on our end,
* anyway, so it'll never be on. All the same, see https://bugzil.la/965881
* for the possibility for an interface to ensure it never gets turned on. */
mTLSProfileConfirmed = true;
return NS_OK;
}
//-----------------------------------------------------------------------------
// Modified methods of nsAHttpConnection
//-----------------------------------------------------------------------------
void
Http2Session::TransactionHasDataToWrite(nsAHttpTransaction *caller)
{
MOZ_ASSERT(PR_GetCurrentThread() == gSocketThread);
LOG3(("Http2Session::TransactionHasDataToWrite %p trans=%p", this, caller));
// a trapped signal from the http transaction to the connection that
// it is no longer blocked on read.
Http2Stream *stream = mStreamTransactionHash.Get(caller);
if (!stream || !VerifyStream(stream)) {
LOG3(("Http2Session::TransactionHasDataToWrite %p caller %p not found",
this, caller));
return;
}
LOG3(("Http2Session::TransactionHasDataToWrite %p ID is 0x%X\n",
this, stream->StreamID()));
if (!mClosed) {
mReadyForWrite.Push(stream);
SetWriteCallbacks();
} else {
LOG3(("Http2Session::TransactionHasDataToWrite %p closed so not setting Ready4Write\n",
this));
}
// NSPR poll will not poll the network if there are non system PR_FileDesc's
// that are ready - so we can get into a deadlock waiting for the system IO
// to come back here if we don't force the send loop manually.
ForceSend();
}
void
Http2Session::TransactionHasDataToRecv(nsAHttpTransaction *caller)
{
MOZ_ASSERT(PR_GetCurrentThread() == gSocketThread);
LOG3(("Http2Session::TransactionHasDataToRecv %p trans=%p", this, caller));
// a signal from the http transaction to the connection that it will consume more
Http2Stream *stream = mStreamTransactionHash.Get(caller);
if (!stream || !VerifyStream(stream)) {
LOG3(("Http2Session::TransactionHasDataToRecv %p caller %p not found",
this, caller));
return;
}
LOG3(("Http2Session::TransactionHasDataToRecv %p ID is 0x%X\n",
this, stream->StreamID()));
ConnectSlowConsumer(stream);
}
void
Http2Session::TransactionHasDataToWrite(Http2Stream *stream)
{
MOZ_ASSERT(PR_GetCurrentThread() == gSocketThread);
LOG3(("Http2Session::TransactionHasDataToWrite %p stream=%p ID=0x%x",
this, stream, stream->StreamID()));
mReadyForWrite.Push(stream);
SetWriteCallbacks();
ForceSend();
}
bool
Http2Session::IsPersistent()
{
return true;
}
nsresult
Http2Session::TakeTransport(nsISocketTransport **,
nsIAsyncInputStream **, nsIAsyncOutputStream **)
{
MOZ_ASSERT(false, "TakeTransport of Http2Session");
return NS_ERROR_UNEXPECTED;
}
nsHttpConnection *
Http2Session::TakeHttpConnection()
{
MOZ_ASSERT(false, "TakeHttpConnection of Http2Session");
return nullptr;
}
uint32_t
Http2Session::CancelPipeline(nsresult reason)
{
// we don't pipeline inside http/2, so this isn't an issue
return 0;
}
nsAHttpTransaction::Classifier
Http2Session::Classification()
{
if (!mConnection)
return nsAHttpTransaction::CLASS_GENERAL;
return mConnection->Classification();
}
void
Http2Session::GetSecurityCallbacks(nsIInterfaceRequestor **aOut)
{
*aOut = nullptr;
}
//-----------------------------------------------------------------------------
// unused methods of nsAHttpTransaction
// We can be sure of this because Http2Session is only constructed in
// nsHttpConnection and is never passed out of that object or a TLSFilterTransaction
// TLS tunnel
//-----------------------------------------------------------------------------
void
Http2Session::SetConnection(nsAHttpConnection *)
{
// This is unexpected
MOZ_ASSERT(false, "Http2Session::SetConnection()");
}
void
Http2Session::SetProxyConnectFailed()
{
MOZ_ASSERT(false, "Http2Session::SetProxyConnectFailed()");
}
bool
Http2Session::IsDone()
{
return !mStreamTransactionHash.Count();
}
nsresult
Http2Session::Status()
{
MOZ_ASSERT(false, "Http2Session::Status()");
return NS_ERROR_UNEXPECTED;
}
uint32_t
Http2Session::Caps()
{
MOZ_ASSERT(false, "Http2Session::Caps()");
return 0;
}
void
Http2Session::SetDNSWasRefreshed()
{
MOZ_ASSERT(false, "Http2Session::SetDNSWasRefreshed()");
}
uint64_t
Http2Session::Available()
{
MOZ_ASSERT(false, "Http2Session::Available()");
return 0;
}
nsHttpRequestHead *
Http2Session::RequestHead()
{
MOZ_ASSERT(PR_GetCurrentThread() == gSocketThread);
MOZ_ASSERT(false,
"Http2Session::RequestHead() "
"should not be called after http/2 is setup");
return NULL;
}
uint32_t
Http2Session::Http1xTransactionCount()
{
return 0;
}
// used as an enumerator by TakeSubTransactions()
static PLDHashOperator
TakeStream(nsAHttpTransaction *key,
nsAutoPtr<Http2Stream> &stream,
void *closure)
{
nsTArray<RefPtr<nsAHttpTransaction> > *list =
static_cast<nsTArray<RefPtr<nsAHttpTransaction> > *>(closure);
list->AppendElement(key);
// removing the stream from the hash will delete the stream
// and drop the transaction reference the hash held
return PL_DHASH_REMOVE;
}
nsresult
Http2Session::TakeSubTransactions(
nsTArray<RefPtr<nsAHttpTransaction> > &outTransactions)
{
// Generally this cannot be done with http/2 as transactions are
// started right away.
LOG3(("Http2Session::TakeSubTransactions %p\n", this));
if (mConcurrentHighWater > 0)
return NS_ERROR_ALREADY_OPENED;
LOG3((" taking %d\n", mStreamTransactionHash.Count()));
mStreamTransactionHash.Enumerate(TakeStream, &outTransactions);
return NS_OK;
}
nsresult
Http2Session::AddTransaction(nsAHttpTransaction *)
{
// This API is meant for pipelining, Http2Session's should be
// extended with AddStream()
MOZ_ASSERT(false,
"Http2Session::AddTransaction() should not be called");
return NS_ERROR_NOT_IMPLEMENTED;
}
uint32_t
Http2Session::PipelineDepth()
{
return IsDone() ? 0 : 1;
}
nsresult
Http2Session::SetPipelinePosition(int32_t position)
{
// This API is meant for pipelining, Http2Session's should be
// extended with AddStream()
MOZ_ASSERT(false,
"Http2Session::SetPipelinePosition() should not be called");
return NS_ERROR_NOT_IMPLEMENTED;
}
int32_t
Http2Session::PipelinePosition()
{
return 0;
}
//-----------------------------------------------------------------------------
// Pass through methods of nsAHttpConnection
//-----------------------------------------------------------------------------
nsAHttpConnection *
Http2Session::Connection()
{
MOZ_ASSERT(PR_GetCurrentThread() == gSocketThread);
return mConnection;
}
nsresult
Http2Session::OnHeadersAvailable(nsAHttpTransaction *transaction,
nsHttpRequestHead *requestHead,
nsHttpResponseHead *responseHead, bool *reset)
{
return mConnection->OnHeadersAvailable(transaction,
requestHead,
responseHead,
reset);
}
bool
Http2Session::IsReused()
{
return mConnection->IsReused();
}
nsresult
Http2Session::PushBack(const char *buf, uint32_t len)
{
return mConnection->PushBack(buf, len);
}
void
Http2Session::SendPing()
{
MOZ_ASSERT(PR_GetCurrentThread() == gSocketThread);
if (mPreviousUsed) {
// alredy in progress, get out
return;
}
mPingSentEpoch = PR_IntervalNow();
if (!mPingSentEpoch) {
mPingSentEpoch = 1; // avoid the 0 sentinel value
}
if (!mPingThreshold ||
(mPingThreshold > gHttpHandler->NetworkChangedTimeout())) {
mPreviousPingThreshold = mPingThreshold;
mPreviousUsed = true;
mPingThreshold = gHttpHandler->NetworkChangedTimeout();
}
GeneratePing(false);
ResumeRecv();
}
} // namespace net
} // namespace mozilla
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