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// Copyright (c) 2009-2022 The Bitcoin Core developers
// Distributed under the MIT software license, see the accompanying
// file COPYING or http://www.opensource.org/licenses/mit-license.php.
#include <test/fuzz/util/net.h>
#include <compat/compat.h>
#include <netaddress.h>
#include <node/protocol_version.h>
#include <protocol.h>
#include <test/fuzz/FuzzedDataProvider.h>
#include <test/fuzz/util.h>
#include <test/util/net.h>
#include <util/sock.h>
#include <util/time.h>
#include <array>
#include <cassert>
#include <cerrno>
#include <cstdint>
#include <cstdlib>
#include <cstring>
#include <thread>
#include <vector>
class CNode;
CNetAddr ConsumeNetAddr(FuzzedDataProvider& fuzzed_data_provider, FastRandomContext* rand) noexcept
{
struct NetAux {
Network net;
CNetAddr::BIP155Network bip155;
size_t len;
};
static constexpr std::array<NetAux, 6> nets{
NetAux{.net = Network::NET_IPV4, .bip155 = CNetAddr::BIP155Network::IPV4, .len = ADDR_IPV4_SIZE},
NetAux{.net = Network::NET_IPV6, .bip155 = CNetAddr::BIP155Network::IPV6, .len = ADDR_IPV6_SIZE},
NetAux{.net = Network::NET_ONION, .bip155 = CNetAddr::BIP155Network::TORV3, .len = ADDR_TORV3_SIZE},
NetAux{.net = Network::NET_I2P, .bip155 = CNetAddr::BIP155Network::I2P, .len = ADDR_I2P_SIZE},
NetAux{.net = Network::NET_CJDNS, .bip155 = CNetAddr::BIP155Network::CJDNS, .len = ADDR_CJDNS_SIZE},
NetAux{.net = Network::NET_INTERNAL, .bip155 = CNetAddr::BIP155Network{0}, .len = 0},
};
const size_t nets_index{rand == nullptr
? fuzzed_data_provider.ConsumeIntegralInRange<size_t>(0, nets.size() - 1)
: static_cast<size_t>(rand->randrange(nets.size()))};
const auto& aux = nets[nets_index];
CNetAddr addr;
if (aux.net == Network::NET_INTERNAL) {
if (rand == nullptr) {
addr.SetInternal(fuzzed_data_provider.ConsumeBytesAsString(32));
} else {
const auto v = rand->randbytes(32);
addr.SetInternal(std::string{v.begin(), v.end()});
}
return addr;
}
DataStream s;
s << static_cast<uint8_t>(aux.bip155);
std::vector<uint8_t> addr_bytes;
if (rand == nullptr) {
addr_bytes = fuzzed_data_provider.ConsumeBytes<uint8_t>(aux.len);
addr_bytes.resize(aux.len);
} else {
addr_bytes = rand->randbytes(aux.len);
}
if (aux.net == NET_IPV6 && addr_bytes[0] == CJDNS_PREFIX) { // Avoid generating IPv6 addresses that look like CJDNS.
addr_bytes[0] = 0x55; // Just an arbitrary number, anything != CJDNS_PREFIX would do.
}
if (aux.net == NET_CJDNS) { // Avoid generating CJDNS addresses that don't start with CJDNS_PREFIX because those are !IsValid().
addr_bytes[0] = CJDNS_PREFIX;
}
s << addr_bytes;
s >> CAddress::V2_NETWORK(addr);
return addr;
}
CAddress ConsumeAddress(FuzzedDataProvider& fuzzed_data_provider) noexcept
{
return {ConsumeService(fuzzed_data_provider), ConsumeWeakEnum(fuzzed_data_provider, ALL_SERVICE_FLAGS), NodeSeconds{std::chrono::seconds{fuzzed_data_provider.ConsumeIntegral<uint32_t>()}}};
}
template <typename P>
P ConsumeDeserializationParams(FuzzedDataProvider& fuzzed_data_provider) noexcept
{
constexpr std::array ADDR_ENCODINGS{
CNetAddr::Encoding::V1,
CNetAddr::Encoding::V2,
};
constexpr std::array ADDR_FORMATS{
CAddress::Format::Disk,
CAddress::Format::Network,
};
if constexpr (std::is_same_v<P, CNetAddr::SerParams>) {
return P{PickValue(fuzzed_data_provider, ADDR_ENCODINGS)};
}
if constexpr (std::is_same_v<P, CAddress::SerParams>) {
return P{{PickValue(fuzzed_data_provider, ADDR_ENCODINGS)}, PickValue(fuzzed_data_provider, ADDR_FORMATS)};
}
}
template CNetAddr::SerParams ConsumeDeserializationParams(FuzzedDataProvider&) noexcept;
template CAddress::SerParams ConsumeDeserializationParams(FuzzedDataProvider&) noexcept;
FuzzedSock::FuzzedSock(FuzzedDataProvider& fuzzed_data_provider)
: Sock{fuzzed_data_provider.ConsumeIntegralInRange<SOCKET>(INVALID_SOCKET - 1, INVALID_SOCKET)},
m_fuzzed_data_provider{fuzzed_data_provider},
m_selectable{fuzzed_data_provider.ConsumeBool()}
{
}
FuzzedSock::~FuzzedSock()
{
// Sock::~Sock() will be called after FuzzedSock::~FuzzedSock() and it will call
// close(m_socket) if m_socket is not INVALID_SOCKET.
// Avoid closing an arbitrary file descriptor (m_socket is just a random very high number which
// theoretically may concide with a real opened file descriptor).
m_socket = INVALID_SOCKET;
}
FuzzedSock& FuzzedSock::operator=(Sock&& other)
{
assert(false && "Move of Sock into FuzzedSock not allowed.");
return *this;
}
ssize_t FuzzedSock::Send(const void* data, size_t len, int flags) const
{
constexpr std::array send_errnos{
EACCES,
EAGAIN,
EALREADY,
EBADF,
ECONNRESET,
EDESTADDRREQ,
EFAULT,
EINTR,
EINVAL,
EISCONN,
EMSGSIZE,
ENOBUFS,
ENOMEM,
ENOTCONN,
ENOTSOCK,
EOPNOTSUPP,
EPIPE,
EWOULDBLOCK,
};
if (m_fuzzed_data_provider.ConsumeBool()) {
return len;
}
const ssize_t r = m_fuzzed_data_provider.ConsumeIntegralInRange<ssize_t>(-1, len);
if (r == -1) {
SetFuzzedErrNo(m_fuzzed_data_provider, send_errnos);
}
return r;
}
ssize_t FuzzedSock::Recv(void* buf, size_t len, int flags) const
{
// Have a permanent error at recv_errnos[0] because when the fuzzed data is exhausted
// SetFuzzedErrNo() will always return the first element and we want to avoid Recv()
// returning -1 and setting errno to EAGAIN repeatedly.
constexpr std::array recv_errnos{
ECONNREFUSED,
EAGAIN,
EBADF,
EFAULT,
EINTR,
EINVAL,
ENOMEM,
ENOTCONN,
ENOTSOCK,
EWOULDBLOCK,
};
assert(buf != nullptr || len == 0);
// Do the latency before any of the "return" statements.
if (m_fuzzed_data_provider.ConsumeBool() && std::getenv("FUZZED_SOCKET_FAKE_LATENCY") != nullptr) {
std::this_thread::sleep_for(std::chrono::milliseconds{2});
}
if (len == 0 || m_fuzzed_data_provider.ConsumeBool()) {
const ssize_t r = m_fuzzed_data_provider.ConsumeBool() ? 0 : -1;
if (r == -1) {
SetFuzzedErrNo(m_fuzzed_data_provider, recv_errnos);
}
return r;
}
size_t copied_so_far{0};
if (!m_peek_data.empty()) {
// `MSG_PEEK` was used in the preceding `Recv()` call, copy the first bytes from `m_peek_data`.
const size_t copy_len{std::min(len, m_peek_data.size())};
std::memcpy(buf, m_peek_data.data(), copy_len);
copied_so_far += copy_len;
if ((flags & MSG_PEEK) == 0) {
m_peek_data.erase(m_peek_data.begin(), m_peek_data.begin() + copy_len);
}
}
if (copied_so_far == len) {
return copied_so_far;
}
auto new_data = ConsumeRandomLengthByteVector(m_fuzzed_data_provider, len - copied_so_far);
if (new_data.empty()) return copied_so_far;
std::memcpy(reinterpret_cast<uint8_t*>(buf) + copied_so_far, new_data.data(), new_data.size());
copied_so_far += new_data.size();
if ((flags & MSG_PEEK) != 0) {
m_peek_data.insert(m_peek_data.end(), new_data.begin(), new_data.end());
}
if (copied_so_far == len || m_fuzzed_data_provider.ConsumeBool()) {
return copied_so_far;
}
// Pad to len bytes.
std::memset(reinterpret_cast<uint8_t*>(buf) + copied_so_far, 0x0, len - copied_so_far);
return len;
}
int FuzzedSock::Connect(const sockaddr*, socklen_t) const
{
// Have a permanent error at connect_errnos[0] because when the fuzzed data is exhausted
// SetFuzzedErrNo() will always return the first element and we want to avoid Connect()
// returning -1 and setting errno to EAGAIN repeatedly.
constexpr std::array connect_errnos{
ECONNREFUSED,
EAGAIN,
ECONNRESET,
EHOSTUNREACH,
EINPROGRESS,
EINTR,
ENETUNREACH,
ETIMEDOUT,
};
if (m_fuzzed_data_provider.ConsumeBool()) {
SetFuzzedErrNo(m_fuzzed_data_provider, connect_errnos);
return -1;
}
return 0;
}
int FuzzedSock::Bind(const sockaddr*, socklen_t) const
{
// Have a permanent error at bind_errnos[0] because when the fuzzed data is exhausted
// SetFuzzedErrNo() will always set the global errno to bind_errnos[0]. We want to
// avoid this method returning -1 and setting errno to a temporary error (like EAGAIN)
// repeatedly because proper code should retry on temporary errors, leading to an
// infinite loop.
constexpr std::array bind_errnos{
EACCES,
EADDRINUSE,
EADDRNOTAVAIL,
EAGAIN,
};
if (m_fuzzed_data_provider.ConsumeBool()) {
SetFuzzedErrNo(m_fuzzed_data_provider, bind_errnos);
return -1;
}
return 0;
}
int FuzzedSock::Listen(int) const
{
// Have a permanent error at listen_errnos[0] because when the fuzzed data is exhausted
// SetFuzzedErrNo() will always set the global errno to listen_errnos[0]. We want to
// avoid this method returning -1 and setting errno to a temporary error (like EAGAIN)
// repeatedly because proper code should retry on temporary errors, leading to an
// infinite loop.
constexpr std::array listen_errnos{
EADDRINUSE,
EINVAL,
EOPNOTSUPP,
};
if (m_fuzzed_data_provider.ConsumeBool()) {
SetFuzzedErrNo(m_fuzzed_data_provider, listen_errnos);
return -1;
}
return 0;
}
std::unique_ptr<Sock> FuzzedSock::Accept(sockaddr* addr, socklen_t* addr_len) const
{
constexpr std::array accept_errnos{
ECONNABORTED,
EINTR,
ENOMEM,
};
if (m_fuzzed_data_provider.ConsumeBool()) {
SetFuzzedErrNo(m_fuzzed_data_provider, accept_errnos);
return std::unique_ptr<FuzzedSock>();
}
return std::make_unique<FuzzedSock>(m_fuzzed_data_provider);
}
int FuzzedSock::GetSockOpt(int level, int opt_name, void* opt_val, socklen_t* opt_len) const
{
constexpr std::array getsockopt_errnos{
ENOMEM,
ENOBUFS,
};
if (m_fuzzed_data_provider.ConsumeBool()) {
SetFuzzedErrNo(m_fuzzed_data_provider, getsockopt_errnos);
return -1;
}
if (opt_val == nullptr) {
return 0;
}
std::memcpy(opt_val,
ConsumeFixedLengthByteVector(m_fuzzed_data_provider, *opt_len).data(),
*opt_len);
return 0;
}
int FuzzedSock::SetSockOpt(int, int, const void*, socklen_t) const
{
constexpr std::array setsockopt_errnos{
ENOMEM,
ENOBUFS,
};
if (m_fuzzed_data_provider.ConsumeBool()) {
SetFuzzedErrNo(m_fuzzed_data_provider, setsockopt_errnos);
return -1;
}
return 0;
}
int FuzzedSock::GetSockName(sockaddr* name, socklen_t* name_len) const
{
constexpr std::array getsockname_errnos{
ECONNRESET,
ENOBUFS,
};
if (m_fuzzed_data_provider.ConsumeBool()) {
SetFuzzedErrNo(m_fuzzed_data_provider, getsockname_errnos);
return -1;
}
*name_len = m_fuzzed_data_provider.ConsumeData(name, *name_len);
return 0;
}
bool FuzzedSock::SetNonBlocking() const
{
constexpr std::array setnonblocking_errnos{
EBADF,
EPERM,
};
if (m_fuzzed_data_provider.ConsumeBool()) {
SetFuzzedErrNo(m_fuzzed_data_provider, setnonblocking_errnos);
return false;
}
return true;
}
bool FuzzedSock::IsSelectable() const
{
return m_selectable;
}
bool FuzzedSock::Wait(std::chrono::milliseconds timeout, Event requested, Event* occurred) const
{
constexpr std::array wait_errnos{
EBADF,
EINTR,
EINVAL,
};
if (m_fuzzed_data_provider.ConsumeBool()) {
SetFuzzedErrNo(m_fuzzed_data_provider, wait_errnos);
return false;
}
if (occurred != nullptr) {
// We simulate the requested event as occurred when ConsumeBool()
// returns false. This avoids simulating endless waiting if the
// FuzzedDataProvider runs out of data.
*occurred = m_fuzzed_data_provider.ConsumeBool() ? 0 : requested;
}
return true;
}
bool FuzzedSock::WaitMany(std::chrono::milliseconds timeout, EventsPerSock& events_per_sock) const
{
for (auto& [sock, events] : events_per_sock) {
(void)sock;
// We simulate the requested event as occurred when ConsumeBool()
// returns false. This avoids simulating endless waiting if the
// FuzzedDataProvider runs out of data.
events.occurred = m_fuzzed_data_provider.ConsumeBool() ? 0 : events.requested;
}
return true;
}
bool FuzzedSock::IsConnected(std::string& errmsg) const
{
if (m_fuzzed_data_provider.ConsumeBool()) {
return true;
}
errmsg = "disconnected at random by the fuzzer";
return false;
}
void FillNode(FuzzedDataProvider& fuzzed_data_provider, ConnmanTestMsg& connman, CNode& node) noexcept
{
connman.Handshake(node,
/*successfully_connected=*/fuzzed_data_provider.ConsumeBool(),
/*remote_services=*/ConsumeWeakEnum(fuzzed_data_provider, ALL_SERVICE_FLAGS),
/*local_services=*/ConsumeWeakEnum(fuzzed_data_provider, ALL_SERVICE_FLAGS),
/*version=*/fuzzed_data_provider.ConsumeIntegralInRange<int32_t>(MIN_PEER_PROTO_VERSION, std::numeric_limits<int32_t>::max()),
/*relay_txs=*/fuzzed_data_provider.ConsumeBool());
}
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