/* -*- Mode: C++; tab-width: 2; indent-tabs-mode: nil; c-basic-offset: 2 -*- */ /* This Source Code Form is subject to the terms of the Mozilla Public * License, v. 2.0. If a copy of the MPL was not distributed with this * file, You can obtain one at http://mozilla.org/MPL/2.0/. */ #include "nsMultiMixedConv.h" #include "plstr.h" #include "nsIHttpChannel.h" #include "nsNetCID.h" #include "nsMimeTypes.h" #include "nsIStringStream.h" #include "nsCRT.h" #include "nsIHttpChannelInternal.h" #include "nsURLHelper.h" #include "nsIStreamConverterService.h" #include #include "nsContentSecurityManager.h" #include "nsHttp.h" #include "nsNetUtil.h" #include "nsIURI.h" #include "nsHttpHeaderArray.h" #include "mozilla/AutoRestore.h" #include "mozilla/Tokenizer.h" #include "nsComponentManagerUtils.h" using namespace mozilla; nsPartChannel::nsPartChannel(nsIChannel* aMultipartChannel, uint32_t aPartID, bool aIsFirstPart, nsIStreamListener* aListener) : mMultipartChannel(aMultipartChannel), mListener(aListener), mPartID(aPartID), mIsFirstPart(aIsFirstPart) { // Inherit the load flags from the original channel... mMultipartChannel->GetLoadFlags(&mLoadFlags); mMultipartChannel->GetLoadGroup(getter_AddRefs(mLoadGroup)); } void nsPartChannel::InitializeByteRange(int64_t aStart, int64_t aEnd) { mIsByteRangeRequest = true; mByteRangeStart = aStart; mByteRangeEnd = aEnd; } nsresult nsPartChannel::SendOnStartRequest(nsISupports* aContext) { return mListener->OnStartRequest(this); } nsresult nsPartChannel::SendOnDataAvailable(nsISupports* aContext, nsIInputStream* aStream, uint64_t aOffset, uint32_t aLen) { return mListener->OnDataAvailable(this, aStream, aOffset, aLen); } nsresult nsPartChannel::SendOnStopRequest(nsISupports* aContext, nsresult aStatus) { // Drop the listener nsCOMPtr listener; listener.swap(mListener); return listener->OnStopRequest(this, aStatus); } void nsPartChannel::SetContentDisposition( const nsACString& aContentDispositionHeader) { mContentDispositionHeader = aContentDispositionHeader; nsCOMPtr uri; GetURI(getter_AddRefs(uri)); NS_GetFilenameFromDisposition(mContentDispositionFilename, mContentDispositionHeader); mContentDisposition = NS_GetContentDispositionFromHeader(mContentDispositionHeader, this); } // // nsISupports implementation... // NS_IMPL_ADDREF(nsPartChannel) NS_IMPL_RELEASE(nsPartChannel) NS_INTERFACE_MAP_BEGIN(nsPartChannel) NS_INTERFACE_MAP_ENTRY_AMBIGUOUS(nsISupports, nsIChannel) NS_INTERFACE_MAP_ENTRY(nsIRequest) NS_INTERFACE_MAP_ENTRY(nsIChannel) NS_INTERFACE_MAP_ENTRY(nsIByteRangeRequest) NS_INTERFACE_MAP_ENTRY(nsIMultiPartChannel) NS_INTERFACE_MAP_END // // nsIRequest implementation... // NS_IMETHODIMP nsPartChannel::GetName(nsACString& aResult) { return mMultipartChannel->GetName(aResult); } NS_IMETHODIMP nsPartChannel::IsPending(bool* aResult) { // For now, consider the active lifetime of each part the same as // the underlying multipart channel... This is not exactly right, // but it is good enough :-) return mMultipartChannel->IsPending(aResult); } NS_IMETHODIMP nsPartChannel::GetStatus(nsresult* aResult) { nsresult rv = NS_OK; if (NS_FAILED(mStatus)) { *aResult = mStatus; } else { rv = mMultipartChannel->GetStatus(aResult); } return rv; } NS_IMETHODIMP nsPartChannel::SetCanceledReason(const nsACString& aReason) { return SetCanceledReasonImpl(aReason); } NS_IMETHODIMP nsPartChannel::GetCanceledReason(nsACString& aReason) { return GetCanceledReasonImpl(aReason); } NS_IMETHODIMP nsPartChannel::CancelWithReason(nsresult aStatus, const nsACString& aReason) { return CancelWithReasonImpl(aStatus, aReason); } NS_IMETHODIMP nsPartChannel::Cancel(nsresult aStatus) { // Cancelling an individual part must not cancel the underlying // multipart channel... // XXX but we should stop sending data for _this_ part channel! mStatus = aStatus; return NS_OK; } NS_IMETHODIMP nsPartChannel::GetCanceled(bool* aCanceled) { *aCanceled = NS_FAILED(mStatus); return NS_OK; } NS_IMETHODIMP nsPartChannel::Suspend(void) { // Suspending an individual part must not suspend the underlying // multipart channel... // XXX why not? return NS_OK; } NS_IMETHODIMP nsPartChannel::Resume(void) { // Resuming an individual part must not resume the underlying // multipart channel... // XXX why not? return NS_OK; } // // nsIChannel implementation // NS_IMETHODIMP nsPartChannel::GetOriginalURI(nsIURI** aURI) { return mMultipartChannel->GetOriginalURI(aURI); } NS_IMETHODIMP nsPartChannel::SetOriginalURI(nsIURI* aURI) { return mMultipartChannel->SetOriginalURI(aURI); } NS_IMETHODIMP nsPartChannel::GetURI(nsIURI** aURI) { return mMultipartChannel->GetURI(aURI); } NS_IMETHODIMP nsPartChannel::Open(nsIInputStream** aStream) { nsCOMPtr listener; nsresult rv = nsContentSecurityManager::doContentSecurityCheck(this, listener); NS_ENSURE_SUCCESS(rv, rv); // This channel cannot be opened! return NS_ERROR_FAILURE; } NS_IMETHODIMP nsPartChannel::AsyncOpen(nsIStreamListener* aListener) { nsCOMPtr listener = aListener; nsresult rv = nsContentSecurityManager::doContentSecurityCheck(this, listener); NS_ENSURE_SUCCESS(rv, rv); // This channel cannot be opened! return NS_ERROR_FAILURE; } NS_IMETHODIMP nsPartChannel::GetLoadFlags(nsLoadFlags* aLoadFlags) { *aLoadFlags = mLoadFlags; return NS_OK; } NS_IMETHODIMP nsPartChannel::SetLoadFlags(nsLoadFlags aLoadFlags) { mLoadFlags = aLoadFlags; return NS_OK; } NS_IMETHODIMP nsPartChannel::GetTRRMode(nsIRequest::TRRMode* aTRRMode) { return GetTRRModeImpl(aTRRMode); } NS_IMETHODIMP nsPartChannel::SetTRRMode(nsIRequest::TRRMode aTRRMode) { return SetTRRModeImpl(aTRRMode); } NS_IMETHODIMP nsPartChannel::GetIsDocument(bool* aIsDocument) { return NS_GetIsDocumentChannel(this, aIsDocument); } NS_IMETHODIMP nsPartChannel::GetLoadGroup(nsILoadGroup** aLoadGroup) { *aLoadGroup = do_AddRef(mLoadGroup).take(); return NS_OK; } NS_IMETHODIMP nsPartChannel::SetLoadGroup(nsILoadGroup* aLoadGroup) { mLoadGroup = aLoadGroup; return NS_OK; } NS_IMETHODIMP nsPartChannel::GetOwner(nsISupports** aOwner) { return mMultipartChannel->GetOwner(aOwner); } NS_IMETHODIMP nsPartChannel::SetOwner(nsISupports* aOwner) { return mMultipartChannel->SetOwner(aOwner); } NS_IMETHODIMP nsPartChannel::GetLoadInfo(nsILoadInfo** aLoadInfo) { return mMultipartChannel->GetLoadInfo(aLoadInfo); } NS_IMETHODIMP nsPartChannel::SetLoadInfo(nsILoadInfo* aLoadInfo) { MOZ_RELEASE_ASSERT(aLoadInfo, "loadinfo can't be null"); return mMultipartChannel->SetLoadInfo(aLoadInfo); } NS_IMETHODIMP nsPartChannel::GetNotificationCallbacks(nsIInterfaceRequestor** aCallbacks) { return mMultipartChannel->GetNotificationCallbacks(aCallbacks); } NS_IMETHODIMP nsPartChannel::SetNotificationCallbacks(nsIInterfaceRequestor* aCallbacks) { return mMultipartChannel->SetNotificationCallbacks(aCallbacks); } NS_IMETHODIMP nsPartChannel::GetSecurityInfo(nsITransportSecurityInfo** aSecurityInfo) { return mMultipartChannel->GetSecurityInfo(aSecurityInfo); } NS_IMETHODIMP nsPartChannel::GetContentType(nsACString& aContentType) { aContentType = mContentType; return NS_OK; } NS_IMETHODIMP nsPartChannel::SetContentType(const nsACString& aContentType) { bool dummy; net_ParseContentType(aContentType, mContentType, mContentCharset, &dummy); return NS_OK; } NS_IMETHODIMP nsPartChannel::GetContentCharset(nsACString& aContentCharset) { aContentCharset = mContentCharset; return NS_OK; } NS_IMETHODIMP nsPartChannel::SetContentCharset(const nsACString& aContentCharset) { mContentCharset = aContentCharset; return NS_OK; } NS_IMETHODIMP nsPartChannel::GetContentLength(int64_t* aContentLength) { *aContentLength = mContentLength; return NS_OK; } NS_IMETHODIMP nsPartChannel::SetContentLength(int64_t aContentLength) { mContentLength = aContentLength; return NS_OK; } NS_IMETHODIMP nsPartChannel::GetContentDisposition(uint32_t* aContentDisposition) { if (mContentDispositionHeader.IsEmpty()) return NS_ERROR_NOT_AVAILABLE; *aContentDisposition = mContentDisposition; return NS_OK; } NS_IMETHODIMP nsPartChannel::SetContentDisposition(uint32_t aContentDisposition) { return NS_ERROR_NOT_AVAILABLE; } NS_IMETHODIMP nsPartChannel::GetContentDispositionFilename( nsAString& aContentDispositionFilename) { if (mContentDispositionFilename.IsEmpty()) return NS_ERROR_NOT_AVAILABLE; aContentDispositionFilename = mContentDispositionFilename; return NS_OK; } NS_IMETHODIMP nsPartChannel::SetContentDispositionFilename( const nsAString& aContentDispositionFilename) { return NS_ERROR_NOT_AVAILABLE; } NS_IMETHODIMP nsPartChannel::GetContentDispositionHeader( nsACString& aContentDispositionHeader) { if (mContentDispositionHeader.IsEmpty()) return NS_ERROR_NOT_AVAILABLE; aContentDispositionHeader = mContentDispositionHeader; return NS_OK; } NS_IMETHODIMP nsPartChannel::GetPartID(uint32_t* aPartID) { *aPartID = mPartID; return NS_OK; } NS_IMETHODIMP nsPartChannel::GetIsFirstPart(bool* aIsFirstPart) { *aIsFirstPart = mIsFirstPart; return NS_OK; } NS_IMETHODIMP nsPartChannel::GetIsLastPart(bool* aIsLastPart) { *aIsLastPart = mIsLastPart; return NS_OK; } // // nsIByteRangeRequest implementation... // NS_IMETHODIMP nsPartChannel::GetIsByteRangeRequest(bool* aIsByteRangeRequest) { *aIsByteRangeRequest = mIsByteRangeRequest; return NS_OK; } NS_IMETHODIMP nsPartChannel::GetStartRange(int64_t* aStartRange) { *aStartRange = mByteRangeStart; return NS_OK; } NS_IMETHODIMP nsPartChannel::GetEndRange(int64_t* aEndRange) { *aEndRange = mByteRangeEnd; return NS_OK; } NS_IMETHODIMP nsPartChannel::GetBaseChannel(nsIChannel** aReturn) { NS_ENSURE_ARG_POINTER(aReturn); *aReturn = do_AddRef(mMultipartChannel).take(); return NS_OK; } // nsISupports implementation NS_IMPL_ISUPPORTS(nsMultiMixedConv, nsIStreamConverter, nsIStreamListener, nsIRequestObserver) // nsIStreamConverter implementation // No syncronous conversion at this time. NS_IMETHODIMP nsMultiMixedConv::Convert(nsIInputStream* aFromStream, const char* aFromType, const char* aToType, nsISupports* aCtxt, nsIInputStream** _retval) { return NS_ERROR_NOT_IMPLEMENTED; } // Stream converter service calls this to initialize the actual stream converter // (us). NS_IMETHODIMP nsMultiMixedConv::AsyncConvertData(const char* aFromType, const char* aToType, nsIStreamListener* aListener, nsISupports* aCtxt) { NS_ASSERTION(aListener && aFromType && aToType, "null pointer passed into multi mixed converter"); // hook up our final listener. this guy gets the various On*() calls we want // to throw at him. // // WARNING: this listener must be able to handle multiple OnStartRequest, // OnDataAvail() and OnStopRequest() call combinations. We call of series // of these for each sub-part in the raw stream. mFinalListener = aListener; return NS_OK; } NS_IMETHODIMP nsMultiMixedConv::GetConvertedType(const nsACString& aFromType, nsIChannel* aChannel, nsACString& aToType) { return NS_ERROR_NOT_IMPLEMENTED; } // nsIRequestObserver implementation NS_IMETHODIMP nsMultiMixedConv::OnStartRequest(nsIRequest* request) { // we're assuming the content-type is available at this stage NS_ASSERTION(mBoundary.IsEmpty(), "a second on start???"); nsresult rv; mTotalSent = 0; mChannel = do_QueryInterface(request, &rv); if (NS_FAILED(rv)) return rv; nsAutoCString contentType; // ask the HTTP channel for the content-type and extract the boundary from it. nsCOMPtr httpChannel = do_QueryInterface(mChannel, &rv); if (NS_SUCCEEDED(rv)) { rv = httpChannel->GetResponseHeader("content-type"_ns, contentType); if (NS_FAILED(rv)) { return rv; } nsCString csp; rv = httpChannel->GetResponseHeader("content-security-policy"_ns, csp); if (NS_SUCCEEDED(rv)) { mRootContentSecurityPolicy = csp; } } else { // try asking the channel directly rv = mChannel->GetContentType(contentType); if (NS_FAILED(rv)) { return NS_ERROR_FAILURE; } } Tokenizer p(contentType); p.SkipUntil(Token::Char(';')); if (!p.CheckChar(';')) { return NS_ERROR_CORRUPTED_CONTENT; } p.SkipWhites(); if (!p.CheckWord("boundary")) { return NS_ERROR_CORRUPTED_CONTENT; } p.SkipWhites(); if (!p.CheckChar('=')) { return NS_ERROR_CORRUPTED_CONTENT; } p.SkipWhites(); Unused << p.ReadUntil(Token::Char(';'), mBoundary); mBoundary.Trim( " \""); // ignoring potential quoted string formatting violations if (mBoundary.IsEmpty()) { return NS_ERROR_CORRUPTED_CONTENT; } mHeaderTokens[HEADER_CONTENT_TYPE] = mTokenizer.AddCustomToken( "content-type", mTokenizer.CASE_INSENSITIVE, false); mHeaderTokens[HEADER_CONTENT_LENGTH] = mTokenizer.AddCustomToken( "content-length", mTokenizer.CASE_INSENSITIVE, false); mHeaderTokens[HEADER_CONTENT_DISPOSITION] = mTokenizer.AddCustomToken( "content-disposition", mTokenizer.CASE_INSENSITIVE, false); mHeaderTokens[HEADER_SET_COOKIE] = mTokenizer.AddCustomToken( "set-cookie", mTokenizer.CASE_INSENSITIVE, false); mHeaderTokens[HEADER_CONTENT_RANGE] = mTokenizer.AddCustomToken( "content-range", mTokenizer.CASE_INSENSITIVE, false); mHeaderTokens[HEADER_RANGE] = mTokenizer.AddCustomToken("range", mTokenizer.CASE_INSENSITIVE, false); mHeaderTokens[HEADER_CONTENT_SECURITY_POLICY] = mTokenizer.AddCustomToken( "content-security-policy", mTokenizer.CASE_INSENSITIVE, false); mLFToken = mTokenizer.AddCustomToken("\n", mTokenizer.CASE_SENSITIVE, false); mCRLFToken = mTokenizer.AddCustomToken("\r\n", mTokenizer.CASE_SENSITIVE, false); SwitchToControlParsing(); mBoundaryToken = mTokenizer.AddCustomToken(mBoundary, mTokenizer.CASE_SENSITIVE); mBoundaryTokenWithDashes = mTokenizer.AddCustomToken("--"_ns + mBoundary, mTokenizer.CASE_SENSITIVE); return NS_OK; } // nsIStreamListener implementation NS_IMETHODIMP nsMultiMixedConv::OnDataAvailable(nsIRequest* request, nsIInputStream* inStr, uint64_t sourceOffset, uint32_t count) { // Failing these assertions may indicate that some of the target listeners of // this converter is looping the thead queue, which is harmful to how we // collect the raw (content) data. MOZ_DIAGNOSTIC_ASSERT(!mInOnDataAvailable, "nsMultiMixedConv::OnDataAvailable reentered!"); MOZ_DIAGNOSTIC_ASSERT( !mRawData, "There are unsent data from the previous tokenizer feed!"); if (mInOnDataAvailable) { // The multipart logic is incapable of being reentered. return NS_ERROR_UNEXPECTED; } mozilla::AutoRestore restore(mInOnDataAvailable); mInOnDataAvailable = true; nsresult rv_feed = mTokenizer.FeedInput(inStr, count); // We must do this every time. Regardless if something has failed during the // parsing process. Otherwise the raw data reference would not be thrown // away. nsresult rv_send = SendData(); return NS_FAILED(rv_send) ? rv_send : rv_feed; } NS_IMETHODIMP nsMultiMixedConv::OnStopRequest(nsIRequest* request, nsresult aStatus) { nsresult rv; if (mPartChannel) { mPartChannel->SetIsLastPart(); MOZ_DIAGNOSTIC_ASSERT( !mRawData, "There are unsent data from the previous tokenizer feed!"); rv = mTokenizer.FinishInput(); if (NS_SUCCEEDED(aStatus)) { aStatus = rv; } rv = SendData(); if (NS_SUCCEEDED(aStatus)) { aStatus = rv; } (void)SendStop(aStatus); } else if (NS_FAILED(aStatus) && !mRequestListenerNotified) { // underlying data production problem. we should not be in // the middle of sending data. if we were, mPartChannel, // above, would have been non-null. (void)mFinalListener->OnStartRequest(request); (void)mFinalListener->OnStopRequest(request, aStatus); } nsCOMPtr multiListener = do_QueryInterface(mFinalListener); if (multiListener) { multiListener->OnAfterLastPart(aStatus); } return NS_OK; } nsresult nsMultiMixedConv::ConsumeToken(Token const& token) { nsresult rv; switch (mParserState) { case PREAMBLE: if (token.Equals(mBoundaryTokenWithDashes)) { // The server first used boundary '--boundary'. Hence, we no longer // accept plain 'boundary' token as a delimiter. mTokenizer.RemoveCustomToken(mBoundaryToken); mParserState = BOUNDARY_CRLF; break; } if (token.Equals(mBoundaryToken)) { // And here the opposite from the just above block... mTokenizer.RemoveCustomToken(mBoundaryTokenWithDashes); mParserState = BOUNDARY_CRLF; break; } // This is a preamble, just ignore it and wait for the boundary. break; case BOUNDARY_CRLF: if (token.Equals(Token::NewLine())) { mParserState = HEADER_NAME; mResponseHeader = HEADER_UNKNOWN; HeadersToDefault(); SetHeaderTokensEnabled(true); break; } return NS_ERROR_CORRUPTED_CONTENT; case HEADER_NAME: SetHeaderTokensEnabled(false); if (token.Equals(Token::NewLine())) { mParserState = BODY_INIT; SwitchToBodyParsing(); break; } for (uint32_t h = HEADER_CONTENT_TYPE; h < HEADER_UNKNOWN; ++h) { if (token.Equals(mHeaderTokens[h])) { mResponseHeader = static_cast(h); break; } } mParserState = HEADER_SEP; break; case HEADER_SEP: if (token.Equals(Token::Char(':'))) { mParserState = HEADER_VALUE; mResponseHeaderValue.Truncate(); break; } if (mResponseHeader == HEADER_UNKNOWN) { // If the header is not of any we understand, just pass everything till // ':' break; } if (token.Equals(Token::Whitespace())) { // Accept only header-name traling whitespaces after known headers break; } return NS_ERROR_CORRUPTED_CONTENT; case HEADER_VALUE: if (token.Equals(Token::Whitespace()) && mResponseHeaderValue.IsEmpty()) { // Eat leading whitespaces break; } if (token.Equals(Token::NewLine())) { nsresult rv = ProcessHeader(); if (NS_FAILED(rv)) { return rv; } mParserState = HEADER_NAME; mResponseHeader = HEADER_UNKNOWN; SetHeaderTokensEnabled(true); } else { mResponseHeaderValue.Append(token.Fragment()); } break; case BODY_INIT: rv = SendStart(); if (NS_FAILED(rv)) { return rv; } mParserState = BODY; [[fallthrough]]; case BODY: { if (!token.Equals(mLFToken) && !token.Equals(mCRLFToken)) { if (token.Equals(mBoundaryTokenWithDashes) || token.Equals(mBoundaryToken)) { // Allow CRLF to NOT be part of the boundary as well SwitchToControlParsing(); mParserState = TRAIL_DASH1; break; } AccumulateData(token); break; } // After CRLF we must explicitly check for boundary. If found, // that CRLF is part of the boundary and must not be send to the // data listener. Token token2; if (!mTokenizer.Next(token2)) { // Note: this will give us the CRLF token again when more data // or OnStopRequest arrive. I.e. we will enter BODY case in // the very same state as we are now and start this block over. mTokenizer.NeedMoreInput(); break; } if (token2.Equals(mBoundaryTokenWithDashes) || token2.Equals(mBoundaryToken)) { SwitchToControlParsing(); mParserState = TRAIL_DASH1; break; } AccumulateData(token); AccumulateData(token2); break; } case TRAIL_DASH1: if (token.Equals(Token::NewLine())) { rv = SendStop(NS_OK); if (NS_FAILED(rv)) { return rv; } mParserState = BOUNDARY_CRLF; mTokenizer.Rollback(); break; } if (token.Equals(Token::Char('-'))) { mParserState = TRAIL_DASH2; break; } return NS_ERROR_CORRUPTED_CONTENT; case TRAIL_DASH2: if (token.Equals(Token::Char('-'))) { mPartChannel->SetIsLastPart(); // SendStop calls SendData first. rv = SendStop(NS_OK); if (NS_FAILED(rv)) { return rv; } mParserState = EPILOGUE; break; } return NS_ERROR_CORRUPTED_CONTENT; case EPILOGUE: // Just ignore break; default: MOZ_ASSERT(false, "Missing parser state handling branch"); break; } // switch return NS_OK; } void nsMultiMixedConv::SetHeaderTokensEnabled(bool aEnable) { for (uint32_t h = HEADER_FIRST; h < HEADER_UNKNOWN; ++h) { mTokenizer.EnableCustomToken(mHeaderTokens[h], aEnable); } } void nsMultiMixedConv::SwitchToBodyParsing() { mTokenizer.SetTokenizingMode(Tokenizer::Mode::CUSTOM_ONLY); mTokenizer.EnableCustomToken(mLFToken, true); mTokenizer.EnableCustomToken(mCRLFToken, true); mTokenizer.EnableCustomToken(mBoundaryTokenWithDashes, true); mTokenizer.EnableCustomToken(mBoundaryToken, true); } void nsMultiMixedConv::SwitchToControlParsing() { mTokenizer.SetTokenizingMode(Tokenizer::Mode::FULL); mTokenizer.EnableCustomToken(mLFToken, false); mTokenizer.EnableCustomToken(mCRLFToken, false); mTokenizer.EnableCustomToken(mBoundaryTokenWithDashes, false); mTokenizer.EnableCustomToken(mBoundaryToken, false); } // nsMultiMixedConv methods nsMultiMixedConv::nsMultiMixedConv() // XXX: This is a hack to bypass the raw pointer to refcounted object in // lambda analysis. It should be removed and replaced when the // IncrementalTokenizer API is improved to avoid the need for such // workarounds. // // This is safe because `mTokenizer` will not outlive `this`, meaning // that this std::bind object will be destroyed before `this` dies. : mTokenizer(std::bind(&nsMultiMixedConv::ConsumeToken, this, std::placeholders::_1)) {} nsresult nsMultiMixedConv::SendStart() { nsresult rv = NS_OK; nsCOMPtr partListener(mFinalListener); if (mContentType.IsEmpty()) { mContentType.AssignLiteral(UNKNOWN_CONTENT_TYPE); nsCOMPtr serv = do_GetService(NS_STREAMCONVERTERSERVICE_CONTRACTID, &rv); if (NS_SUCCEEDED(rv)) { nsCOMPtr converter; rv = serv->AsyncConvertData(UNKNOWN_CONTENT_TYPE, "*/*", mFinalListener, mContext, getter_AddRefs(converter)); if (NS_SUCCEEDED(rv)) { partListener = converter; } } } // if we already have an mPartChannel, that means we never sent a Stop() // before starting up another "part." that would be bad. MOZ_ASSERT(!mPartChannel, "tisk tisk, shouldn't be overwriting a channel"); nsPartChannel* newChannel; newChannel = new nsPartChannel(mChannel, mCurrentPartID, mCurrentPartID == 0, partListener); ++mCurrentPartID; if (mIsByteRangeRequest) { newChannel->InitializeByteRange(mByteRangeStart, mByteRangeEnd); } mTotalSent = 0; // Set up the new part channel... mPartChannel = newChannel; rv = mPartChannel->SetContentType(mContentType); if (NS_FAILED(rv)) return rv; rv = mPartChannel->SetContentLength(mContentLength); if (NS_FAILED(rv)) return rv; mPartChannel->SetContentDisposition(mContentDisposition); // Each part of a multipart/replace response can be used // for the top level document. We must inform upper layers // about this by setting the LOAD_REPLACE flag so that certain // state assertions are evaluated as positive. nsLoadFlags loadFlags = 0; mPartChannel->GetLoadFlags(&loadFlags); loadFlags |= nsIChannel::LOAD_REPLACE; mPartChannel->SetLoadFlags(loadFlags); nsCOMPtr loadGroup; (void)mPartChannel->GetLoadGroup(getter_AddRefs(loadGroup)); // Add the new channel to the load group (if any) if (loadGroup) { rv = loadGroup->AddRequest(mPartChannel, nullptr); if (NS_FAILED(rv)) return rv; } // This prevents artificial call to OnStart/StopRequest when the root // channel fails. Since now it's ensured to keep with the nsIStreamListener // contract every time. mRequestListenerNotified = true; // Let's start off the load. NOTE: we don't forward on the channel passed // into our OnDataAvailable() as it's the root channel for the raw stream. return mPartChannel->SendOnStartRequest(mContext); } nsresult nsMultiMixedConv::SendStop(nsresult aStatus) { // Make sure we send out all accumulcated data prior call to OnStopRequest. // If there is no data, this is a no-op. nsresult rv = SendData(); if (NS_SUCCEEDED(aStatus)) { aStatus = rv; } if (mPartChannel) { rv = mPartChannel->SendOnStopRequest(mContext, aStatus); // don't check for failure here, we need to remove the channel from // the loadgroup. // Remove the channel from its load group (if any) nsCOMPtr loadGroup; (void)mPartChannel->GetLoadGroup(getter_AddRefs(loadGroup)); if (loadGroup) { (void)loadGroup->RemoveRequest(mPartChannel, mContext, aStatus); } } mPartChannel = nullptr; return rv; } void nsMultiMixedConv::AccumulateData(Token const& aToken) { if (!mRawData) { // This is the first read of raw data during this FeedInput loop // of the incremental tokenizer. All 'raw' tokens are coming from // the same linear buffer, hence begining of this loop raw data // is begining of the first raw token. Length of this loop raw // data is just sum of all 'raw' tokens we collect during this loop. // // It's ensured we flush (send to to the listener via OnDataAvailable) // and nullify the collected raw data right after FeedInput call. // Hence, the reference can't outlive the actual buffer. mRawData = aToken.Fragment().BeginReading(); mRawDataLength = 0; } mRawDataLength += aToken.Fragment().Length(); } nsresult nsMultiMixedConv::SendData() { nsresult rv; if (!mRawData) { return NS_OK; } nsACString::const_char_iterator rawData = mRawData; mRawData = nullptr; if (!mPartChannel) { return NS_ERROR_FAILURE; // something went wrong w/ processing } if (mContentLength != UINT64_MAX) { // make sure that we don't send more than the mContentLength // XXX why? perhaps the Content-Length header was actually wrong!! if ((uint64_t(mRawDataLength) + mTotalSent) > mContentLength) { mRawDataLength = static_cast(mContentLength - mTotalSent); } if (mRawDataLength == 0) return NS_OK; } uint64_t offset = mTotalSent; mTotalSent += mRawDataLength; nsCOMPtr ss( do_CreateInstance("@mozilla.org/io/string-input-stream;1", &rv)); if (NS_FAILED(rv)) return rv; rv = ss->ShareData(rawData, mRawDataLength); mRawData = nullptr; if (NS_FAILED(rv)) return rv; return mPartChannel->SendOnDataAvailable(mContext, ss, offset, mRawDataLength); } void nsMultiMixedConv::HeadersToDefault() { mContentLength = UINT64_MAX; mContentType.Truncate(); mContentDisposition.Truncate(); mContentSecurityPolicy.Truncate(); mIsByteRangeRequest = false; } nsresult nsMultiMixedConv::ProcessHeader() { mozilla::Tokenizer p(mResponseHeaderValue); switch (mResponseHeader) { case HEADER_CONTENT_TYPE: mContentType = mResponseHeaderValue; mContentType.CompressWhitespace(); break; case HEADER_CONTENT_LENGTH: p.SkipWhites(); if (!p.ReadInteger(&mContentLength)) { return NS_ERROR_CORRUPTED_CONTENT; } break; case HEADER_CONTENT_DISPOSITION: mContentDisposition = mResponseHeaderValue; mContentDisposition.CompressWhitespace(); break; case HEADER_SET_COOKIE: { nsCOMPtr httpInternal = do_QueryInterface(mChannel); mResponseHeaderValue.CompressWhitespace(); if (httpInternal) { DebugOnly rv = httpInternal->SetCookie(mResponseHeaderValue); MOZ_ASSERT(NS_SUCCEEDED(rv)); } break; } case HEADER_RANGE: case HEADER_CONTENT_RANGE: { if (!p.CheckWord("bytes") || !p.CheckWhite()) { return NS_ERROR_CORRUPTED_CONTENT; } p.SkipWhites(); if (p.CheckChar('*')) { mByteRangeStart = mByteRangeEnd = 0; } else if (!p.ReadInteger(&mByteRangeStart) || !p.CheckChar('-') || !p.ReadInteger(&mByteRangeEnd)) { return NS_ERROR_CORRUPTED_CONTENT; } mIsByteRangeRequest = true; if (mContentLength == UINT64_MAX) { mContentLength = uint64_t(mByteRangeEnd - mByteRangeStart + 1); } break; } case HEADER_CONTENT_SECURITY_POLICY: { mContentSecurityPolicy = mResponseHeaderValue; mContentSecurityPolicy.CompressWhitespace(); nsCOMPtr httpChannel = do_QueryInterface(mChannel); if (httpChannel) { nsCString resultCSP = mRootContentSecurityPolicy; if (!mContentSecurityPolicy.IsEmpty()) { // We are updating the root channel CSP header respectively for // each part as: CSP-root + CSP-partN, where N is the part number. // Here we append current part's CSP to root CSP and reset CSP // header for each part. if (!resultCSP.IsEmpty()) { resultCSP.Append(";"); } resultCSP.Append(mContentSecurityPolicy); } nsresult rv = httpChannel->SetResponseHeader( "Content-Security-Policy"_ns, resultCSP, false); if (NS_FAILED(rv)) { return NS_ERROR_CORRUPTED_CONTENT; } } break; } case HEADER_UNKNOWN: // We ignore anything else... break; } return NS_OK; } nsresult NS_NewMultiMixedConv(nsMultiMixedConv** aMultiMixedConv) { MOZ_ASSERT(aMultiMixedConv != nullptr, "null ptr"); RefPtr conv = new nsMultiMixedConv(); conv.forget(aMultiMixedConv); return NS_OK; }