/* * Copyright (c) 2021 The WebRTC project authors. All Rights Reserved. * * Use of this source code is governed by a BSD-style license * that can be found in the LICENSE file in the root of the source * tree. An additional intellectual property rights grant can be found * in the file PATENTS. All contributing project authors may * be found in the AUTHORS file in the root of the source tree. */ #include "net/dcsctp/fuzzers/dcsctp_fuzzers.h" #include #include #include #include "net/dcsctp/common/math.h" #include "net/dcsctp/packet/chunk/cookie_ack_chunk.h" #include "net/dcsctp/packet/chunk/cookie_echo_chunk.h" #include "net/dcsctp/packet/chunk/data_chunk.h" #include "net/dcsctp/packet/chunk/forward_tsn_chunk.h" #include "net/dcsctp/packet/chunk/forward_tsn_common.h" #include "net/dcsctp/packet/chunk/shutdown_chunk.h" #include "net/dcsctp/packet/error_cause/protocol_violation_cause.h" #include "net/dcsctp/packet/error_cause/user_initiated_abort_cause.h" #include "net/dcsctp/packet/parameter/forward_tsn_supported_parameter.h" #include "net/dcsctp/packet/parameter/outgoing_ssn_reset_request_parameter.h" #include "net/dcsctp/packet/parameter/state_cookie_parameter.h" #include "net/dcsctp/public/dcsctp_message.h" #include "net/dcsctp/public/types.h" #include "net/dcsctp/socket/dcsctp_socket.h" #include "net/dcsctp/socket/state_cookie.h" #include "rtc_base/logging.h" namespace dcsctp { namespace dcsctp_fuzzers { namespace { static constexpr int kRandomValue = FuzzerCallbacks::kRandomValue; static constexpr size_t kMinInputLength = 5; static constexpr size_t kMaxInputLength = 1024; // A starting state for the socket, when fuzzing. enum class StartingState : int { kConnectNotCalled, // When socket initiating Connect kConnectCalled, kReceivedInitAck, kReceivedCookieAck, // When socket initiating Shutdown kShutdownCalled, kReceivedShutdownAck, // When peer socket initiated Connect kReceivedInit, kReceivedCookieEcho, // When peer initiated Shutdown kReceivedShutdown, kReceivedShutdownComplete, kNumberOfStates, }; // State about the current fuzzing iteration class FuzzState { public: explicit FuzzState(rtc::ArrayView data) : data_(data) {} uint8_t GetByte() { uint8_t value = 0; if (offset_ < data_.size()) { value = data_[offset_]; ++offset_; } return value; } TSN GetNextTSN() { return TSN(tsn_++); } MID GetNextMID() { return MID(mid_++); } bool empty() const { return offset_ >= data_.size(); } private: uint32_t tsn_ = kRandomValue; uint32_t mid_ = 0; rtc::ArrayView data_; size_t offset_ = 0; }; void SetSocketState(DcSctpSocketInterface& socket, FuzzerCallbacks& socket_cb, StartingState state) { // We'll use another temporary peer socket for the establishment. FuzzerCallbacks peer_cb; DcSctpSocket peer("peer", peer_cb, nullptr, {}); switch (state) { case StartingState::kConnectNotCalled: return; case StartingState::kConnectCalled: socket.Connect(); return; case StartingState::kReceivedInitAck: socket.Connect(); peer.ReceivePacket(socket_cb.ConsumeSentPacket()); // INIT socket.ReceivePacket(peer_cb.ConsumeSentPacket()); // INIT_ACK return; case StartingState::kReceivedCookieAck: socket.Connect(); peer.ReceivePacket(socket_cb.ConsumeSentPacket()); // INIT socket.ReceivePacket(peer_cb.ConsumeSentPacket()); // INIT_ACK peer.ReceivePacket(socket_cb.ConsumeSentPacket()); // COOKIE_ECHO socket.ReceivePacket(peer_cb.ConsumeSentPacket()); // COOKIE_ACK return; case StartingState::kShutdownCalled: socket.Connect(); peer.ReceivePacket(socket_cb.ConsumeSentPacket()); // INIT socket.ReceivePacket(peer_cb.ConsumeSentPacket()); // INIT_ACK peer.ReceivePacket(socket_cb.ConsumeSentPacket()); // COOKIE_ECHO socket.ReceivePacket(peer_cb.ConsumeSentPacket()); // COOKIE_ACK socket.Shutdown(); return; case StartingState::kReceivedShutdownAck: socket.Connect(); peer.ReceivePacket(socket_cb.ConsumeSentPacket()); // INIT socket.ReceivePacket(peer_cb.ConsumeSentPacket()); // INIT_ACK peer.ReceivePacket(socket_cb.ConsumeSentPacket()); // COOKIE_ECHO socket.ReceivePacket(peer_cb.ConsumeSentPacket()); // COOKIE_ACK socket.Shutdown(); peer.ReceivePacket(socket_cb.ConsumeSentPacket()); // SHUTDOWN socket.ReceivePacket(peer_cb.ConsumeSentPacket()); // SHUTDOWN_ACK return; case StartingState::kReceivedInit: peer.Connect(); socket.ReceivePacket(peer_cb.ConsumeSentPacket()); // INIT return; case StartingState::kReceivedCookieEcho: peer.Connect(); socket.ReceivePacket(peer_cb.ConsumeSentPacket()); // INIT peer.ReceivePacket(socket_cb.ConsumeSentPacket()); // INIT_ACK socket.ReceivePacket(peer_cb.ConsumeSentPacket()); // COOKIE_ECHO return; case StartingState::kReceivedShutdown: socket.Connect(); peer.ReceivePacket(socket_cb.ConsumeSentPacket()); // INIT socket.ReceivePacket(peer_cb.ConsumeSentPacket()); // INIT_ACK peer.ReceivePacket(socket_cb.ConsumeSentPacket()); // COOKIE_ECHO socket.ReceivePacket(peer_cb.ConsumeSentPacket()); // COOKIE_ACK peer.Shutdown(); socket.ReceivePacket(peer_cb.ConsumeSentPacket()); // SHUTDOWN return; case StartingState::kReceivedShutdownComplete: socket.Connect(); peer.ReceivePacket(socket_cb.ConsumeSentPacket()); // INIT socket.ReceivePacket(peer_cb.ConsumeSentPacket()); // INIT_ACK peer.ReceivePacket(socket_cb.ConsumeSentPacket()); // COOKIE_ECHO socket.ReceivePacket(peer_cb.ConsumeSentPacket()); // COOKIE_ACK peer.Shutdown(); socket.ReceivePacket(peer_cb.ConsumeSentPacket()); // SHUTDOWN peer.ReceivePacket(socket_cb.ConsumeSentPacket()); // SHUTDOWN_ACK socket.ReceivePacket(peer_cb.ConsumeSentPacket()); // SHUTDOWN_COMPLETE return; case StartingState::kNumberOfStates: RTC_CHECK(false); return; } } void MakeDataChunk(FuzzState& state, SctpPacket::Builder& b) { DataChunk::Options options; options.is_unordered = IsUnordered(state.GetByte() != 0); options.is_beginning = Data::IsBeginning(state.GetByte() != 0); options.is_end = Data::IsEnd(state.GetByte() != 0); b.Add(DataChunk(state.GetNextTSN(), StreamID(state.GetByte()), SSN(state.GetByte()), PPID(53), std::vector(10), options)); } void MakeInitChunk(FuzzState& state, SctpPacket::Builder& b) { Parameters::Builder builder; builder.Add(ForwardTsnSupportedParameter()); b.Add(InitChunk(VerificationTag(kRandomValue), 10000, 1000, 1000, TSN(kRandomValue), builder.Build())); } void MakeInitAckChunk(FuzzState& state, SctpPacket::Builder& b) { Parameters::Builder builder; builder.Add(ForwardTsnSupportedParameter()); uint8_t state_cookie[] = {1, 2, 3, 4, 5}; Parameters::Builder params_builder = Parameters::Builder().Add(StateCookieParameter(state_cookie)); b.Add(InitAckChunk(VerificationTag(kRandomValue), 10000, 1000, 1000, TSN(kRandomValue), builder.Build())); } void MakeSackChunk(FuzzState& state, SctpPacket::Builder& b) { std::vector gap_ack_blocks; uint16_t last_end = 0; while (gap_ack_blocks.size() < 20) { uint8_t delta_start = state.GetByte(); if (delta_start < 0x80) { break; } uint8_t delta_end = state.GetByte(); uint16_t start = last_end + delta_start; uint16_t end = start + delta_end; last_end = end; gap_ack_blocks.emplace_back(start, end); } TSN cum_ack_tsn(kRandomValue + state.GetByte()); b.Add(SackChunk(cum_ack_tsn, 10000, std::move(gap_ack_blocks), {})); } void MakeHeartbeatRequestChunk(FuzzState& state, SctpPacket::Builder& b) { uint8_t info[] = {1, 2, 3, 4, 5}; b.Add(HeartbeatRequestChunk( Parameters::Builder().Add(HeartbeatInfoParameter(info)).Build())); } void MakeHeartbeatAckChunk(FuzzState& state, SctpPacket::Builder& b) { std::vector info(8); b.Add(HeartbeatRequestChunk( Parameters::Builder().Add(HeartbeatInfoParameter(info)).Build())); } void MakeAbortChunk(FuzzState& state, SctpPacket::Builder& b) { b.Add(AbortChunk( /*filled_in_verification_tag=*/true, Parameters::Builder().Add(UserInitiatedAbortCause("Fuzzing")).Build())); } void MakeErrorChunk(FuzzState& state, SctpPacket::Builder& b) { b.Add(ErrorChunk( Parameters::Builder().Add(ProtocolViolationCause("Fuzzing")).Build())); } void MakeCookieEchoChunk(FuzzState& state, SctpPacket::Builder& b) { std::vector cookie(StateCookie::kCookieSize); b.Add(CookieEchoChunk(cookie)); } void MakeCookieAckChunk(FuzzState& state, SctpPacket::Builder& b) { b.Add(CookieAckChunk()); } void MakeShutdownChunk(FuzzState& state, SctpPacket::Builder& b) { b.Add(ShutdownChunk(state.GetNextTSN())); } void MakeShutdownAckChunk(FuzzState& state, SctpPacket::Builder& b) { b.Add(ShutdownAckChunk()); } void MakeShutdownCompleteChunk(FuzzState& state, SctpPacket::Builder& b) { b.Add(ShutdownCompleteChunk(false)); } void MakeReConfigChunk(FuzzState& state, SctpPacket::Builder& b) { std::vector streams = {StreamID(state.GetByte())}; Parameters::Builder params_builder = Parameters::Builder().Add(OutgoingSSNResetRequestParameter( ReconfigRequestSN(kRandomValue), ReconfigRequestSN(kRandomValue), state.GetNextTSN(), streams)); b.Add(ReConfigChunk(params_builder.Build())); } void MakeForwardTsnChunk(FuzzState& state, SctpPacket::Builder& b) { std::vector skipped_streams; for (;;) { uint8_t stream = state.GetByte(); if (skipped_streams.size() > 20 || stream < 0x80) { break; } skipped_streams.emplace_back(StreamID(stream), SSN(state.GetByte())); } b.Add(ForwardTsnChunk(state.GetNextTSN(), std::move(skipped_streams))); } void MakeIDataChunk(FuzzState& state, SctpPacket::Builder& b) { DataChunk::Options options; options.is_unordered = IsUnordered(state.GetByte() != 0); options.is_beginning = Data::IsBeginning(state.GetByte() != 0); options.is_end = Data::IsEnd(state.GetByte() != 0); b.Add(IDataChunk(state.GetNextTSN(), StreamID(state.GetByte()), state.GetNextMID(), PPID(53), FSN(0), std::vector(10), options)); } void MakeIForwardTsnChunk(FuzzState& state, SctpPacket::Builder& b) { std::vector skipped_streams; for (;;) { uint8_t stream = state.GetByte(); if (skipped_streams.size() > 20 || stream < 0x80) { break; } skipped_streams.emplace_back(StreamID(stream), SSN(state.GetByte())); } b.Add(IForwardTsnChunk(state.GetNextTSN(), std::move(skipped_streams))); } class RandomFuzzedChunk : public Chunk { public: explicit RandomFuzzedChunk(FuzzState& state) : state_(state) {} void SerializeTo(std::vector& out) const override { size_t bytes = state_.GetByte(); for (size_t i = 0; i < bytes; ++i) { out.push_back(state_.GetByte()); } } std::string ToString() const override { return std::string("RANDOM_FUZZED"); } private: FuzzState& state_; }; void MakeChunkWithRandomContent(FuzzState& state, SctpPacket::Builder& b) { b.Add(RandomFuzzedChunk(state)); } std::vector GeneratePacket(FuzzState& state) { DcSctpOptions options; // Setting a fixed limit to not be dependent on the defaults, which may // change. options.mtu = 2048; SctpPacket::Builder builder(VerificationTag(kRandomValue), options); // The largest expected serialized chunk, as created by fuzzers. static constexpr size_t kMaxChunkSize = 256; for (int i = 0; i < 5 && builder.bytes_remaining() > kMaxChunkSize; ++i) { switch (state.GetByte()) { case 1: MakeDataChunk(state, builder); break; case 2: MakeInitChunk(state, builder); break; case 3: MakeInitAckChunk(state, builder); break; case 4: MakeSackChunk(state, builder); break; case 5: MakeHeartbeatRequestChunk(state, builder); break; case 6: MakeHeartbeatAckChunk(state, builder); break; case 7: MakeAbortChunk(state, builder); break; case 8: MakeErrorChunk(state, builder); break; case 9: MakeCookieEchoChunk(state, builder); break; case 10: MakeCookieAckChunk(state, builder); break; case 11: MakeShutdownChunk(state, builder); break; case 12: MakeShutdownAckChunk(state, builder); break; case 13: MakeShutdownCompleteChunk(state, builder); break; case 14: MakeReConfigChunk(state, builder); break; case 15: MakeForwardTsnChunk(state, builder); break; case 16: MakeIDataChunk(state, builder); break; case 17: MakeIForwardTsnChunk(state, builder); break; case 18: MakeChunkWithRandomContent(state, builder); break; default: break; } } std::vector packet = builder.Build(); return packet; } } // namespace void FuzzSocket(DcSctpSocketInterface& socket, FuzzerCallbacks& cb, rtc::ArrayView data) { if (data.size() < kMinInputLength || data.size() > kMaxInputLength) { return; } if (data[0] >= static_cast(StartingState::kNumberOfStates)) { return; } // Set the socket in a specified valid starting state SetSocketState(socket, cb, static_cast(data[0])); FuzzState state(data.subview(1)); while (!state.empty()) { switch (state.GetByte()) { case 1: // Generate a valid SCTP packet (based on fuzz data) and "receive it". socket.ReceivePacket(GeneratePacket(state)); break; case 2: socket.Connect(); break; case 3: socket.Shutdown(); break; case 4: socket.Close(); break; case 5: { StreamID streams[] = {StreamID(state.GetByte())}; socket.ResetStreams(streams); } break; case 6: { uint8_t flags = state.GetByte(); SendOptions options; options.unordered = IsUnordered(flags & 0x01); options.max_retransmissions = (flags & 0x02) != 0 ? absl::make_optional(0) : absl::nullopt; options.lifecycle_id = LifecycleId(42); size_t payload_exponent = (flags >> 2) % 16; size_t payload_size = static_cast(1) << payload_exponent; socket.Send(DcSctpMessage(StreamID(state.GetByte()), PPID(53), std::vector(payload_size)), options); break; } case 7: { // Expire an active timeout/timer. uint8_t timeout_idx = state.GetByte(); absl::optional timeout_id = cb.ExpireTimeout(timeout_idx); if (timeout_id.has_value()) { socket.HandleTimeout(*timeout_id); } break; } default: break; } } } } // namespace dcsctp_fuzzers } // namespace dcsctp