// Copyright Joyent, Inc. and other Node contributors. // // Permission is hereby granted, free of charge, to any person obtaining a // copy of this software and associated documentation files (the // "Software"), to deal in the Software without restriction, including // without limitation the rights to use, copy, modify, merge, publish, // distribute, sublicense, and/or sell copies of the Software, and to permit // persons to whom the Software is furnished to do so, subject to the // following conditions: // // The above copyright notice and this permission notice shall be included // in all copies or substantial portions of the Software. // // THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS // OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF // MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN // NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, // DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR // OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE // USE OR OTHER DEALINGS IN THE SOFTWARE. #include "tls_wrap.h" #include "async_wrap-inl.h" #include "node_buffer.h" // Buffer #include "node_crypto.h" // SecureContext #include "node_crypto_bio.h" // NodeBIO // ClientHelloParser #include "node_crypto_clienthello-inl.h" #include "stream_base-inl.h" #include "util-inl.h" namespace node { using crypto::SecureContext; using crypto::SSLWrap; using v8::Context; using v8::DontDelete; using v8::EscapableHandleScope; using v8::Exception; using v8::Function; using v8::FunctionCallbackInfo; using v8::FunctionTemplate; using v8::Isolate; using v8::Local; using v8::Object; using v8::ReadOnly; using v8::Signature; using v8::String; using v8::Value; TLSWrap::TLSWrap(Environment* env, Local obj, Kind kind, StreamBase* stream, SecureContext* sc) : AsyncWrap(env, obj, AsyncWrap::PROVIDER_TLSWRAP), SSLWrap(env, sc, kind), StreamBase(env), sc_(sc) { MakeWeak(); // sc comes from an Unwrap. Make sure it was assigned. CHECK_NOT_NULL(sc); // We've our own session callbacks SSL_CTX_sess_set_get_cb(sc_->ctx_.get(), SSLWrap::GetSessionCallback); SSL_CTX_sess_set_new_cb(sc_->ctx_.get(), SSLWrap::NewSessionCallback); stream->PushStreamListener(this); InitSSL(); } TLSWrap::~TLSWrap() { sc_ = nullptr; } bool TLSWrap::InvokeQueued(int status, const char* error_str) { if (!write_callback_scheduled_) return false; if (current_write_ != nullptr) { WriteWrap* w = current_write_; current_write_ = nullptr; w->Done(status, error_str); } return true; } void TLSWrap::NewSessionDoneCb() { Cycle(); } void TLSWrap::InitSSL() { // Initialize SSL – OpenSSL takes ownership of these. enc_in_ = crypto::NodeBIO::New(env()).release(); enc_out_ = crypto::NodeBIO::New(env()).release(); SSL_set_bio(ssl_.get(), enc_in_, enc_out_); // NOTE: This could be overridden in SetVerifyMode SSL_set_verify(ssl_.get(), SSL_VERIFY_NONE, crypto::VerifyCallback); #ifdef SSL_MODE_RELEASE_BUFFERS SSL_set_mode(ssl_.get(), SSL_MODE_RELEASE_BUFFERS); #endif // SSL_MODE_RELEASE_BUFFERS SSL_set_app_data(ssl_.get(), this); // Using InfoCallback isn't how we are supposed to check handshake progress: // https://github.com/openssl/openssl/issues/7199#issuecomment-420915993 // // Note on when this gets called on various openssl versions: // https://github.com/openssl/openssl/issues/7199#issuecomment-420670544 SSL_set_info_callback(ssl_.get(), SSLInfoCallback); if (is_server()) { SSL_CTX_set_tlsext_servername_callback(sc_->ctx_.get(), SelectSNIContextCallback); } ConfigureSecureContext(sc_); SSL_set_cert_cb(ssl_.get(), SSLWrap::SSLCertCallback, this); if (is_server()) { SSL_set_accept_state(ssl_.get()); } else if (is_client()) { // Enough space for server response (hello, cert) crypto::NodeBIO::FromBIO(enc_in_)->set_initial(kInitialClientBufferLength); SSL_set_connect_state(ssl_.get()); } else { // Unexpected ABORT(); } } void TLSWrap::Wrap(const FunctionCallbackInfo& args) { Environment* env = Environment::GetCurrent(args); CHECK_EQ(args.Length(), 3); CHECK(args[0]->IsObject()); CHECK(args[1]->IsObject()); CHECK(args[2]->IsBoolean()); Local stream_obj = args[0].As(); Local sc = args[1].As(); Kind kind = args[2]->IsTrue() ? SSLWrap::kServer : SSLWrap::kClient; StreamBase* stream = static_cast(stream_obj->Value()); CHECK_NOT_NULL(stream); Local obj; if (!env->tls_wrap_constructor_function() ->NewInstance(env->context()) .ToLocal(&obj)) { return; } TLSWrap* res = new TLSWrap(env, obj, kind, stream, Unwrap(sc)); args.GetReturnValue().Set(res->object()); } void TLSWrap::Receive(const FunctionCallbackInfo& args) { TLSWrap* wrap; ASSIGN_OR_RETURN_UNWRAP(&wrap, args.Holder()); CHECK(Buffer::HasInstance(args[0])); char* data = Buffer::Data(args[0]); size_t len = Buffer::Length(args[0]); // Copy given buffer entirely or partiall if handle becomes closed while (len > 0 && wrap->IsAlive() && !wrap->IsClosing()) { uv_buf_t buf = wrap->OnStreamAlloc(len); size_t copy = buf.len > len ? len : buf.len; memcpy(buf.base, data, copy); buf.len = copy; wrap->OnStreamRead(copy, buf); data += copy; len -= copy; } } void TLSWrap::Start(const FunctionCallbackInfo& args) { TLSWrap* wrap; ASSIGN_OR_RETURN_UNWRAP(&wrap, args.Holder()); CHECK(!wrap->started_); wrap->started_ = true; // Send ClientHello handshake CHECK(wrap->is_client()); // Seems odd to read when when we want to send, but SSL_read() triggers a // handshake if a session isn't established, and handshake will cause // encrypted data to become available for output. wrap->ClearOut(); wrap->EncOut(); } void TLSWrap::SSLInfoCallback(const SSL* ssl_, int where, int ret) { if (!(where & (SSL_CB_HANDSHAKE_START | SSL_CB_HANDSHAKE_DONE))) return; // SSL_renegotiate_pending() should take `const SSL*`, but it does not. SSL* ssl = const_cast(ssl_); TLSWrap* c = static_cast(SSL_get_app_data(ssl_)); Environment* env = c->env(); HandleScope handle_scope(env->isolate()); Context::Scope context_scope(env->context()); Local object = c->object(); if (where & SSL_CB_HANDSHAKE_START) { Local callback; if (object->Get(env->context(), env->onhandshakestart_string()) .ToLocal(&callback) && callback->IsFunction()) { Local argv[] = { env->GetNow() }; c->MakeCallback(callback.As(), arraysize(argv), argv); } } // SSL_CB_HANDSHAKE_START and SSL_CB_HANDSHAKE_DONE are called // sending HelloRequest in OpenSSL-1.1.1. // We need to check whether this is in a renegotiation state or not. if (where & SSL_CB_HANDSHAKE_DONE && !SSL_renegotiate_pending(ssl)) { Local callback; c->established_ = true; if (object->Get(env->context(), env->onhandshakedone_string()) .ToLocal(&callback) && callback->IsFunction()) { c->MakeCallback(callback.As(), 0, nullptr); } } } void TLSWrap::EncOut() { // Ignore cycling data if ClientHello wasn't yet parsed if (!hello_parser_.IsEnded()) return; // Write in progress if (write_size_ != 0) return; // Wait for `newSession` callback to be invoked if (is_awaiting_new_session()) return; // Split-off queue if (established_ && current_write_ != nullptr) write_callback_scheduled_ = true; if (ssl_ == nullptr) return; // No encrypted output ready to write to the underlying stream. if (BIO_pending(enc_out_) == 0) { if (pending_cleartext_input_.empty()) InvokeQueued(0); return; } char* data[kSimultaneousBufferCount]; size_t size[arraysize(data)]; size_t count = arraysize(data); write_size_ = crypto::NodeBIO::FromBIO(enc_out_)->PeekMultiple(data, size, &count); CHECK(write_size_ != 0 && count != 0); uv_buf_t buf[arraysize(data)]; uv_buf_t* bufs = buf; for (size_t i = 0; i < count; i++) buf[i] = uv_buf_init(data[i], size[i]); StreamWriteResult res = underlying_stream()->Write(bufs, count); if (res.err != 0) { InvokeQueued(res.err); return; } if (!res.async) { HandleScope handle_scope(env()->isolate()); // Simulate asynchronous finishing, TLS cannot handle this at the moment. env()->SetImmediate([](Environment* env, void* data) { static_cast(data)->OnStreamAfterWrite(nullptr, 0); }, this, object()); } } void TLSWrap::OnStreamAfterWrite(WriteWrap* req_wrap, int status) { if (current_empty_write_ != nullptr) { WriteWrap* finishing = current_empty_write_; current_empty_write_ = nullptr; finishing->Done(status); return; } if (ssl_ == nullptr) status = UV_ECANCELED; // Handle error if (status) { // Ignore errors after shutdown if (shutdown_) return; // Notify about error InvokeQueued(status); return; } // Commit crypto::NodeBIO::FromBIO(enc_out_)->Read(nullptr, write_size_); // Ensure that the progress will be made and `InvokeQueued` will be called. ClearIn(); // Try writing more data write_size_ = 0; EncOut(); } Local TLSWrap::GetSSLError(int status, int* err, std::string* msg) { EscapableHandleScope scope(env()->isolate()); // ssl_ is already destroyed in reading EOF by close notify alert. if (ssl_ == nullptr) return Local(); *err = SSL_get_error(ssl_.get(), status); switch (*err) { case SSL_ERROR_NONE: case SSL_ERROR_WANT_READ: case SSL_ERROR_WANT_WRITE: case SSL_ERROR_WANT_X509_LOOKUP: return Local(); case SSL_ERROR_ZERO_RETURN: return scope.Escape(env()->zero_return_string()); case SSL_ERROR_SSL: case SSL_ERROR_SYSCALL: { unsigned long ssl_err = ERR_peek_error(); // NOLINT(runtime/int) BIO* bio = BIO_new(BIO_s_mem()); ERR_print_errors(bio); BUF_MEM* mem; BIO_get_mem_ptr(bio, &mem); Isolate* isolate = env()->isolate(); Local context = isolate->GetCurrentContext(); Local message = OneByteString(isolate, mem->data, mem->length); Local exception = Exception::Error(message); Local obj = exception->ToObject(context).ToLocalChecked(); const char* ls = ERR_lib_error_string(ssl_err); const char* fs = ERR_func_error_string(ssl_err); const char* rs = ERR_reason_error_string(ssl_err); if (ls != nullptr) obj->Set(context, env()->library_string(), OneByteString(isolate, ls)).FromJust(); if (fs != nullptr) obj->Set(context, env()->function_string(), OneByteString(isolate, fs)).FromJust(); if (rs != nullptr) { obj->Set(context, env()->reason_string(), OneByteString(isolate, rs)).FromJust(); // SSL has no API to recover the error name from the number, so we // transform reason strings like "this error" to "ERR_SSL_THIS_ERROR", // which ends up being close to the original error macro name. std::string code(rs); for (auto& c : code) { if (c == ' ') c = '_'; else c = ::toupper(c); } obj->Set(context, env()->code_string(), OneByteString(isolate, ("ERR_SSL_" + code).c_str())) .FromJust(); } if (msg != nullptr) msg->assign(mem->data, mem->data + mem->length); BIO_free_all(bio); return scope.Escape(exception); } default: UNREACHABLE(); } UNREACHABLE(); } void TLSWrap::ClearOut() { // Ignore cycling data if ClientHello wasn't yet parsed if (!hello_parser_.IsEnded()) return; // No reads after EOF if (eof_) return; if (ssl_ == nullptr) return; crypto::MarkPopErrorOnReturn mark_pop_error_on_return; char out[kClearOutChunkSize]; int read; for (;;) { read = SSL_read(ssl_.get(), out, sizeof(out)); if (read <= 0) break; char* current = out; while (read > 0) { int avail = read; uv_buf_t buf = EmitAlloc(avail); if (static_cast(buf.len) < avail) avail = buf.len; memcpy(buf.base, current, avail); EmitRead(avail, buf); // Caveat emptor: OnRead() calls into JS land which can result in // the SSL context object being destroyed. We have to carefully // check that ssl_ != nullptr afterwards. if (ssl_ == nullptr) return; read -= avail; current += avail; } } int flags = SSL_get_shutdown(ssl_.get()); if (!eof_ && flags & SSL_RECEIVED_SHUTDOWN) { eof_ = true; EmitRead(UV_EOF); } // We need to check whether an error occurred or the connection was // shutdown cleanly (SSL_ERROR_ZERO_RETURN) even when read == 0. // See node#1642 and SSL_read(3SSL) for details. if (read <= 0) { HandleScope handle_scope(env()->isolate()); int err; Local arg = GetSSLError(read, &err, nullptr); // Ignore ZERO_RETURN after EOF, it is basically not a error if (err == SSL_ERROR_ZERO_RETURN && eof_) return; if (!arg.IsEmpty()) { // When TLS Alert are stored in wbio, // it should be flushed to socket before destroyed. if (BIO_pending(enc_out_) != 0) EncOut(); MakeCallback(env()->onerror_string(), 1, &arg); } } } void TLSWrap::ClearIn() { // Ignore cycling data if ClientHello wasn't yet parsed if (!hello_parser_.IsEnded()) return; if (ssl_ == nullptr) return; std::vector buffers; buffers.swap(pending_cleartext_input_); crypto::MarkPopErrorOnReturn mark_pop_error_on_return; size_t i; int written = 0; for (i = 0; i < buffers.size(); ++i) { size_t avail = buffers[i].len; char* data = buffers[i].base; written = SSL_write(ssl_.get(), data, avail); CHECK(written == -1 || written == static_cast(avail)); if (written == -1) break; } // All written if (i == buffers.size()) { // We wrote all the buffers, so no writes failed (written < 0 on failure). CHECK_GE(written, 0); return; } // Error or partial write HandleScope handle_scope(env()->isolate()); Context::Scope context_scope(env()->context()); int err; std::string error_str; Local arg = GetSSLError(written, &err, &error_str); if (!arg.IsEmpty()) { write_callback_scheduled_ = true; // XXX(sam) Should forward an error object with .code/.function/.etc, if // possible. InvokeQueued(UV_EPROTO, error_str.c_str()); } else { // Push back the not-yet-written pending buffers into their queue. // This can be skipped in the error case because no further writes // would succeed anyway. pending_cleartext_input_.insert(pending_cleartext_input_.end(), buffers.begin() + i, buffers.end()); } return; } AsyncWrap* TLSWrap::GetAsyncWrap() { return static_cast(this); } bool TLSWrap::IsIPCPipe() { return underlying_stream()->IsIPCPipe(); } int TLSWrap::GetFD() { return underlying_stream()->GetFD(); } bool TLSWrap::IsAlive() { return ssl_ != nullptr && stream_ != nullptr && underlying_stream()->IsAlive(); } bool TLSWrap::IsClosing() { return underlying_stream()->IsClosing(); } int TLSWrap::ReadStart() { if (stream_ != nullptr) return stream_->ReadStart(); return 0; } int TLSWrap::ReadStop() { if (stream_ != nullptr) return stream_->ReadStop(); return 0; } const char* TLSWrap::Error() const { return error_.empty() ? nullptr : error_.c_str(); } void TLSWrap::ClearError() { error_.clear(); } // Called by StreamBase::Write() to request async write of clear text into SSL. int TLSWrap::DoWrite(WriteWrap* w, uv_buf_t* bufs, size_t count, uv_stream_t* send_handle) { CHECK_NULL(send_handle); if (ssl_ == nullptr) { ClearError(); error_ = "Write after DestroySSL"; return UV_EPROTO; } bool empty = true; size_t i; for (i = 0; i < count; i++) { if (bufs[i].len > 0) { empty = false; break; } } // We want to trigger a Write() on the underlying stream to drive the stream // system, but don't want to encrypt empty buffers into a TLS frame, so see // if we can find something to Write(). // First, call ClearOut(). It does an SSL_read(), which might cause handshake // or other internal messages to be encrypted. If it does, write them later // with EncOut(). // If there is still no encrypted output, call Write(bufs) on the underlying // stream. Since the bufs are empty, it won't actually write non-TLS data // onto the socket, we just want the side-effects. After, make sure the // WriteWrap was accepted by the stream, or that we call Done() on it. if (empty) { ClearOut(); if (BIO_pending(enc_out_) == 0) { CHECK_NULL(current_empty_write_); current_empty_write_ = w; StreamWriteResult res = underlying_stream()->Write(bufs, count, send_handle); if (!res.async) { env()->SetImmediate([](Environment* env, void* data) { TLSWrap* self = static_cast(data); self->OnStreamAfterWrite(self->current_empty_write_, 0); }, this, object()); } return 0; } } // Store the current write wrap CHECK_NULL(current_write_); current_write_ = w; // Write encrypted data to underlying stream and call Done(). if (empty) { EncOut(); return 0; } crypto::MarkPopErrorOnReturn mark_pop_error_on_return; int written = 0; for (i = 0; i < count; i++) { written = SSL_write(ssl_.get(), bufs[i].base, bufs[i].len); CHECK(written == -1 || written == static_cast(bufs[i].len)); if (written == -1) break; } if (i != count) { int err; Local arg = GetSSLError(written, &err, &error_); // If we stopped writing because of an error, it's fatal, discard the data. if (!arg.IsEmpty()) { current_write_ = nullptr; return UV_EPROTO; } // Otherwise, save unwritten data so it can be written later by ClearIn(). pending_cleartext_input_.insert(pending_cleartext_input_.end(), &bufs[i], &bufs[count]); } // Write any encrypted/handshake output that may be ready. EncOut(); return 0; } uv_buf_t TLSWrap::OnStreamAlloc(size_t suggested_size) { CHECK_NOT_NULL(ssl_); size_t size = suggested_size; char* base = crypto::NodeBIO::FromBIO(enc_in_)->PeekWritable(&size); return uv_buf_init(base, size); } void TLSWrap::OnStreamRead(ssize_t nread, const uv_buf_t& buf) { if (nread < 0) { // Error should be emitted only after all data was read ClearOut(); // Ignore EOF if received close_notify if (nread == UV_EOF) { if (eof_) return; eof_ = true; } EmitRead(nread); return; } if (ssl_ == nullptr) { EmitRead(UV_EPROTO); return; } // Commit the amount of data actually read into the peeked/allocated buffer // from the underlying stream. crypto::NodeBIO* enc_in = crypto::NodeBIO::FromBIO(enc_in_); enc_in->Commit(nread); // Parse ClientHello first, if we need to. It's only parsed if session event // listeners are used on the server side. "ended" is the initial state, so // can mean parsing was never started, or that parsing is finished. Either // way, ended means we can give the buffered data to SSL. if (!hello_parser_.IsEnded()) { size_t avail = 0; uint8_t* data = reinterpret_cast(enc_in->Peek(&avail)); CHECK_IMPLIES(data == nullptr, avail == 0); return hello_parser_.Parse(data, avail); } // Cycle OpenSSL's state Cycle(); } ShutdownWrap* TLSWrap::CreateShutdownWrap(Local req_wrap_object) { return underlying_stream()->CreateShutdownWrap(req_wrap_object); } int TLSWrap::DoShutdown(ShutdownWrap* req_wrap) { crypto::MarkPopErrorOnReturn mark_pop_error_on_return; if (ssl_ && SSL_shutdown(ssl_.get()) == 0) SSL_shutdown(ssl_.get()); shutdown_ = true; EncOut(); return stream_->DoShutdown(req_wrap); } void TLSWrap::SetVerifyMode(const FunctionCallbackInfo& args) { TLSWrap* wrap; ASSIGN_OR_RETURN_UNWRAP(&wrap, args.Holder()); CHECK_EQ(args.Length(), 2); CHECK(args[0]->IsBoolean()); CHECK(args[1]->IsBoolean()); CHECK_NOT_NULL(wrap->ssl_); int verify_mode; if (wrap->is_server()) { bool request_cert = args[0]->IsTrue(); if (!request_cert) { // If no cert is requested, there will be none to reject as unauthorized. verify_mode = SSL_VERIFY_NONE; } else { bool reject_unauthorized = args[1]->IsTrue(); verify_mode = SSL_VERIFY_PEER; if (reject_unauthorized) verify_mode |= SSL_VERIFY_FAIL_IF_NO_PEER_CERT; } } else { // Servers always send a cert if the cipher is not anonymous (anon is // disabled by default), so use VERIFY_NONE and check the cert after the // handshake has completed. verify_mode = SSL_VERIFY_NONE; } // Always allow a connection. We'll reject in javascript. SSL_set_verify(wrap->ssl_.get(), verify_mode, crypto::VerifyCallback); } void TLSWrap::EnableSessionCallbacks( const FunctionCallbackInfo& args) { TLSWrap* wrap; ASSIGN_OR_RETURN_UNWRAP(&wrap, args.Holder()); CHECK_NOT_NULL(wrap->ssl_); wrap->enable_session_callbacks(); // Clients don't use the HelloParser. if (wrap->is_client()) return; crypto::NodeBIO::FromBIO(wrap->enc_in_)->set_initial(kMaxHelloLength); wrap->hello_parser_.Start(SSLWrap::OnClientHello, OnClientHelloParseEnd, wrap); } void TLSWrap::DestroySSL(const FunctionCallbackInfo& args) { TLSWrap* wrap; ASSIGN_OR_RETURN_UNWRAP(&wrap, args.Holder()); // If there is a write happening, mark it as finished. wrap->write_callback_scheduled_ = true; // And destroy wrap->InvokeQueued(UV_ECANCELED, "Canceled because of SSL destruction"); // Destroy the SSL structure and friends wrap->SSLWrap::DestroySSL(); wrap->enc_in_ = nullptr; wrap->enc_out_ = nullptr; if (wrap->stream_ != nullptr) wrap->stream_->RemoveStreamListener(wrap); } void TLSWrap::EnableCertCb(const FunctionCallbackInfo& args) { TLSWrap* wrap; ASSIGN_OR_RETURN_UNWRAP(&wrap, args.Holder()); wrap->WaitForCertCb(OnClientHelloParseEnd, wrap); } void TLSWrap::OnClientHelloParseEnd(void* arg) { TLSWrap* c = static_cast(arg); c->Cycle(); } void TLSWrap::GetServername(const FunctionCallbackInfo& args) { Environment* env = Environment::GetCurrent(args); TLSWrap* wrap; ASSIGN_OR_RETURN_UNWRAP(&wrap, args.Holder()); CHECK_NOT_NULL(wrap->ssl_); const char* servername = SSL_get_servername(wrap->ssl_.get(), TLSEXT_NAMETYPE_host_name); if (servername != nullptr) { args.GetReturnValue().Set(OneByteString(env->isolate(), servername)); } else { args.GetReturnValue().Set(false); } } void TLSWrap::SetServername(const FunctionCallbackInfo& args) { Environment* env = Environment::GetCurrent(args); TLSWrap* wrap; ASSIGN_OR_RETURN_UNWRAP(&wrap, args.Holder()); CHECK_EQ(args.Length(), 1); CHECK(args[0]->IsString()); CHECK(!wrap->started_); CHECK(wrap->is_client()); CHECK_NOT_NULL(wrap->ssl_); node::Utf8Value servername(env->isolate(), args[0].As()); SSL_set_tlsext_host_name(wrap->ssl_.get(), *servername); } int TLSWrap::SelectSNIContextCallback(SSL* s, int* ad, void* arg) { TLSWrap* p = static_cast(SSL_get_app_data(s)); Environment* env = p->env(); const char* servername = SSL_get_servername(s, TLSEXT_NAMETYPE_host_name); if (servername == nullptr) return SSL_TLSEXT_ERR_OK; HandleScope handle_scope(env->isolate()); Context::Scope context_scope(env->context()); // Call the SNI callback and use its return value as context Local object = p->object(); Local ctx; if (!object->Get(env->context(), env->sni_context_string()).ToLocal(&ctx)) return SSL_TLSEXT_ERR_NOACK; // Not an object, probably undefined or null if (!ctx->IsObject()) return SSL_TLSEXT_ERR_NOACK; Local cons = env->secure_context_constructor_template(); if (!cons->HasInstance(ctx)) { // Failure: incorrect SNI context object Local err = Exception::TypeError(env->sni_context_err_string()); p->MakeCallback(env->onerror_string(), 1, &err); return SSL_TLSEXT_ERR_NOACK; } p->sni_context_.Reset(env->isolate(), ctx); SecureContext* sc = Unwrap(ctx.As()); CHECK_NOT_NULL(sc); p->SetSNIContext(sc); return SSL_TLSEXT_ERR_OK; } void TLSWrap::GetWriteQueueSize(const FunctionCallbackInfo& info) { TLSWrap* wrap; ASSIGN_OR_RETURN_UNWRAP(&wrap, info.This()); if (wrap->ssl_ == nullptr) { info.GetReturnValue().Set(0); return; } uint32_t write_queue_size = BIO_pending(wrap->enc_out_); info.GetReturnValue().Set(write_queue_size); } void TLSWrap::MemoryInfo(MemoryTracker* tracker) const { tracker->TrackField("error", error_); tracker->TrackField("pending_cleartext_input", pending_cleartext_input_); if (enc_in_ != nullptr) tracker->TrackField("enc_in", crypto::NodeBIO::FromBIO(enc_in_)); if (enc_out_ != nullptr) tracker->TrackField("enc_out", crypto::NodeBIO::FromBIO(enc_out_)); } void TLSWrap::Initialize(Local target, Local unused, Local context, void* priv) { Environment* env = Environment::GetCurrent(context); env->SetMethod(target, "wrap", TLSWrap::Wrap); Local t = BaseObject::MakeLazilyInitializedJSTemplate(env); Local tlsWrapString = FIXED_ONE_BYTE_STRING(env->isolate(), "TLSWrap"); t->SetClassName(tlsWrapString); Local get_write_queue_size = FunctionTemplate::New(env->isolate(), GetWriteQueueSize, env->as_external(), Signature::New(env->isolate(), t)); t->PrototypeTemplate()->SetAccessorProperty( env->write_queue_size_string(), get_write_queue_size, Local(), static_cast(ReadOnly | DontDelete)); t->Inherit(AsyncWrap::GetConstructorTemplate(env)); env->SetProtoMethod(t, "receive", Receive); env->SetProtoMethod(t, "start", Start); env->SetProtoMethod(t, "setVerifyMode", SetVerifyMode); env->SetProtoMethod(t, "enableSessionCallbacks", EnableSessionCallbacks); env->SetProtoMethod(t, "destroySSL", DestroySSL); env->SetProtoMethod(t, "enableCertCb", EnableCertCb); StreamBase::AddMethods(env, t); SSLWrap::AddMethods(env, t); env->SetProtoMethod(t, "getServername", GetServername); env->SetProtoMethod(t, "setServername", SetServername); env->set_tls_wrap_constructor_function( t->GetFunction(env->context()).ToLocalChecked()); target->Set(env->context(), tlsWrapString, t->GetFunction(env->context()).ToLocalChecked()).FromJust(); } } // namespace node NODE_MODULE_CONTEXT_AWARE_INTERNAL(tls_wrap, node::TLSWrap::Initialize)