// SPDX-FileCopyrightText: Copyright 2020 yuzu Emulator Project
// SPDX-License-Identifier: GPL-2.0-or-later
#include <algorithm>
#include <cstring>
#include <limits>
#include <utility>
#include <vector>
#include "common/error.h"
#ifdef _WIN32
#include <winsock2.h>
#include <ws2tcpip.h>
#elif YUZU_UNIX
#include <arpa/inet.h>
#include <errno.h>
#include <fcntl.h>
#include <netdb.h>
#include <netinet/in.h>
#include <poll.h>
#include <sys/socket.h>
#include <unistd.h>
#else
#error "Unimplemented platform"
#endif
#include "common/assert.h"
#include "common/common_types.h"
#include "common/expected.h"
#include "common/logging/log.h"
#include "common/settings.h"
#include "core/internal_network/network.h"
#include "core/internal_network/network_interface.h"
#include "core/internal_network/sockets.h"
#include "network/network.h"
namespace Network {
namespace {
enum class CallType {
Send,
Other,
};
#ifdef _WIN32
using socklen_t = int;
SOCKET interrupt_socket = static_cast<SOCKET>(-1);
void InterruptSocketOperations() {
closesocket(interrupt_socket);
}
void AcknowledgeInterrupt() {
interrupt_socket = socket(AF_INET, SOCK_DGRAM, IPPROTO_UDP);
}
void Initialize() {
WSADATA wsa_data;
(void)WSAStartup(MAKEWORD(2, 2), &wsa_data);
AcknowledgeInterrupt();
}
void Finalize() {
InterruptSocketOperations();
WSACleanup();
}
SOCKET GetInterruptSocket() {
return interrupt_socket;
}
sockaddr TranslateFromSockAddrIn(SockAddrIn input) {
sockaddr_in result;
#if YUZU_UNIX
result.sin_len = sizeof(result);
#endif
switch (static_cast<Domain>(input.family)) {
case Domain::INET:
result.sin_family = AF_INET;
break;
default:
UNIMPLEMENTED_MSG("Unhandled sockaddr family={}", input.family);
result.sin_family = AF_INET;
break;
}
result.sin_port = htons(input.portno);
auto& ip = result.sin_addr.S_un.S_un_b;
ip.s_b1 = input.ip[0];
ip.s_b2 = input.ip[1];
ip.s_b3 = input.ip[2];
ip.s_b4 = input.ip[3];
sockaddr addr;
std::memcpy(&addr, &result, sizeof(addr));
return addr;
}
LINGER MakeLinger(bool enable, u32 linger_value) {
ASSERT(linger_value <= std::numeric_limits<u_short>::max());
LINGER value;
value.l_onoff = enable ? 1 : 0;
value.l_linger = static_cast<u_short>(linger_value);
return value;
}
bool EnableNonBlock(SOCKET fd, bool enable) {
u_long value = enable ? 1 : 0;
return ioctlsocket(fd, FIONBIO, &value) != SOCKET_ERROR;
}
Errno TranslateNativeError(int e, CallType call_type = CallType::Other) {
switch (e) {
case 0:
return Errno::SUCCESS;
case WSAEBADF:
return Errno::BADF;
case WSAEINVAL:
return Errno::INVAL;
case WSAEMFILE:
return Errno::MFILE;
case WSAENOTCONN:
return Errno::NOTCONN;
case WSAEWOULDBLOCK:
return Errno::AGAIN;
case WSAECONNREFUSED:
return Errno::CONNREFUSED;
case WSAECONNABORTED:
if (call_type == CallType::Send) {
// Winsock yields WSAECONNABORTED from `send` in situations where Unix
// systems, and actual Switches, yield EPIPE.
return Errno::PIPE;
} else {
return Errno::CONNABORTED;
}
case WSAECONNRESET:
return Errno::CONNRESET;
case WSAEHOSTUNREACH:
return Errno::HOSTUNREACH;
case WSAENETDOWN:
return Errno::NETDOWN;
case WSAENETUNREACH:
return Errno::NETUNREACH;
case WSAEMSGSIZE:
return Errno::MSGSIZE;
case WSAETIMEDOUT:
return Errno::TIMEDOUT;
case WSAEINPROGRESS:
return Errno::INPROGRESS;
default:
UNIMPLEMENTED_MSG("Unimplemented errno={}", e);
return Errno::OTHER;
}
}
#elif YUZU_UNIX // ^ _WIN32 v YUZU_UNIX
using SOCKET = int;
using WSAPOLLFD = pollfd;
using ULONG = u64;
constexpr SOCKET SOCKET_ERROR = -1;
constexpr int SD_RECEIVE = SHUT_RD;
constexpr int SD_SEND = SHUT_WR;
constexpr int SD_BOTH = SHUT_RDWR;
int interrupt_pipe_fd[2] = {-1, -1};
void Initialize() {
if (pipe(interrupt_pipe_fd) != 0) {
LOG_ERROR(Network, "Failed to create interrupt pipe!");
}
int flags = fcntl(interrupt_pipe_fd[0], F_GETFL);
ASSERT_MSG(fcntl(interrupt_pipe_fd[0], F_SETFL, flags | O_NONBLOCK) == 0,
"Failed to set nonblocking state for interrupt pipe");
}
void Finalize() {
if (interrupt_pipe_fd[0] >= 0) {
close(interrupt_pipe_fd[0]);
}
if (interrupt_pipe_fd[1] >= 0) {
close(interrupt_pipe_fd[1]);
}
}
void InterruptSocketOperations() {
u8 value = 0;
ASSERT(write(interrupt_pipe_fd[1], &value, sizeof(value)) == 1);
}
void AcknowledgeInterrupt() {
u8 value = 0;
ssize_t ret = read(interrupt_pipe_fd[0], &value, sizeof(value));
if (ret != 1 && errno != EAGAIN && errno != EWOULDBLOCK) {
LOG_ERROR(Network, "Failed to acknowledge interrupt on shutdown");
}
}
SOCKET GetInterruptSocket() {
return interrupt_pipe_fd[0];
}
sockaddr TranslateFromSockAddrIn(SockAddrIn input) {
sockaddr_in result;
switch (static_cast<Domain>(input.family)) {
case Domain::INET:
result.sin_family = AF_INET;
break;
default:
UNIMPLEMENTED_MSG("Unhandled sockaddr family={}", input.family);
result.sin_family = AF_INET;
break;
}
result.sin_port = htons(input.portno);
result.sin_addr.s_addr = input.ip[0] | input.ip[1] << 8 | input.ip[2] << 16 | input.ip[3] << 24;
sockaddr addr;
std::memcpy(&addr, &result, sizeof(addr));
return addr;
}
int WSAPoll(WSAPOLLFD* fds, ULONG nfds, int timeout) {
return poll(fds, static_cast<nfds_t>(nfds), timeout);
}
int closesocket(SOCKET fd) {
return close(fd);
}
linger MakeLinger(bool enable, u32 linger_value) {
linger value;
value.l_onoff = enable ? 1 : 0;
value.l_linger = linger_value;
return value;
}
bool EnableNonBlock(int fd, bool enable) {
int flags = fcntl(fd, F_GETFL);
if (flags == -1) {
return false;
}
if (enable) {
flags |= O_NONBLOCK;
} else {
flags &= ~O_NONBLOCK;
}
return fcntl(fd, F_SETFL, flags) == 0;
}
Errno TranslateNativeError(int e, CallType call_type = CallType::Other) {
switch (e) {
case 0:
return Errno::SUCCESS;
case EBADF:
return Errno::BADF;
case EINVAL:
return Errno::INVAL;
case EMFILE:
return Errno::MFILE;
case EPIPE:
return Errno::PIPE;
case ECONNABORTED:
return Errno::CONNABORTED;
case ENOTCONN:
return Errno::NOTCONN;
case EAGAIN:
return Errno::AGAIN;
case ECONNREFUSED:
return Errno::CONNREFUSED;
case ECONNRESET:
return Errno::CONNRESET;
case EHOSTUNREACH:
return Errno::HOSTUNREACH;
case ENETDOWN:
return Errno::NETDOWN;
case ENETUNREACH:
return Errno::NETUNREACH;
case EMSGSIZE:
return Errno::MSGSIZE;
case ETIMEDOUT:
return Errno::TIMEDOUT;
case EINPROGRESS:
return Errno::INPROGRESS;
default:
UNIMPLEMENTED_MSG("Unimplemented errno={} ({})", e, strerror(e));
return Errno::OTHER;
}
}
#endif
Errno GetAndLogLastError(CallType call_type = CallType::Other) {
#ifdef _WIN32
int e = WSAGetLastError();
#else
int e = errno;
#endif
const Errno err = TranslateNativeError(e, call_type);
if (err == Errno::AGAIN || err == Errno::TIMEDOUT || err == Errno::INPROGRESS) {
// These happen during normal operation, so only log them at debug level.
LOG_DEBUG(Network, "Socket operation error: {}", Common::NativeErrorToString(e));
return err;
}
LOG_ERROR(Network, "Socket operation error: {}", Common::NativeErrorToString(e));
return err;
}
GetAddrInfoError TranslateGetAddrInfoErrorFromNative(int gai_err) {
switch (gai_err) {
case 0:
return GetAddrInfoError::SUCCESS;
#ifdef EAI_ADDRFAMILY
case EAI_ADDRFAMILY:
return GetAddrInfoError::ADDRFAMILY;
#endif
case EAI_AGAIN:
return GetAddrInfoError::AGAIN;
case EAI_BADFLAGS:
return GetAddrInfoError::BADFLAGS;
case EAI_FAIL:
return GetAddrInfoError::FAIL;
case EAI_FAMILY:
return GetAddrInfoError::FAMILY;
case EAI_MEMORY:
return GetAddrInfoError::MEMORY;
case EAI_NONAME:
return GetAddrInfoError::NONAME;
case EAI_SERVICE:
return GetAddrInfoError::SERVICE;
case EAI_SOCKTYPE:
return GetAddrInfoError::SOCKTYPE;
// These codes may not be defined on all systems:
#ifdef EAI_SYSTEM
case EAI_SYSTEM:
return GetAddrInfoError::SYSTEM;
#endif
#ifdef EAI_BADHINTS
case EAI_BADHINTS:
return GetAddrInfoError::BADHINTS;
#endif
#ifdef EAI_PROTOCOL
case EAI_PROTOCOL:
return GetAddrInfoError::PROTOCOL;
#endif
#ifdef EAI_OVERFLOW
case EAI_OVERFLOW:
return GetAddrInfoError::OVERFLOW_;
#endif
default:
#ifdef EAI_NODATA
// This can't be a case statement because it would create a duplicate
// case on Windows where EAI_NODATA is an alias for EAI_NONAME.
if (gai_err == EAI_NODATA) {
return GetAddrInfoError::NODATA;
}
#endif
return GetAddrInfoError::OTHER;
}
}
Domain TranslateDomainFromNative(int domain) {
switch (domain) {
case 0:
return Domain::Unspecified;
case AF_INET:
return Domain::INET;
default:
UNIMPLEMENTED_MSG("Unhandled domain={}", domain);
return Domain::INET;
}
}
int TranslateDomainToNative(Domain domain) {
switch (domain) {
case Domain::Unspecified:
return 0;
case Domain::INET:
return AF_INET;
default:
UNIMPLEMENTED_MSG("Unimplemented domain={}", domain);
return 0;
}
}
Type TranslateTypeFromNative(int type) {
switch (type) {
case 0:
return Type::Unspecified;
case SOCK_STREAM:
return Type::STREAM;
case SOCK_DGRAM:
return Type::DGRAM;
case SOCK_RAW:
return Type::RAW;
case SOCK_SEQPACKET:
return Type::SEQPACKET;
default:
UNIMPLEMENTED_MSG("Unimplemented type={}", type);
return Type::STREAM;
}
}
int TranslateTypeToNative(Type type) {
switch (type) {
case Type::Unspecified:
return 0;
case Type::STREAM:
return SOCK_STREAM;
case Type::DGRAM:
return SOCK_DGRAM;
case Type::RAW:
return SOCK_RAW;
default:
UNIMPLEMENTED_MSG("Unimplemented type={}", type);
return 0;
}
}
Protocol TranslateProtocolFromNative(int protocol) {
switch (protocol) {
case 0:
return Protocol::Unspecified;
case IPPROTO_TCP:
return Protocol::TCP;
case IPPROTO_UDP:
return Protocol::UDP;
default:
UNIMPLEMENTED_MSG("Unimplemented protocol={}", protocol);
return Protocol::Unspecified;
}
}
int TranslateProtocolToNative(Protocol protocol) {
switch (protocol) {
case Protocol::Unspecified:
return 0;
case Protocol::TCP:
return IPPROTO_TCP;
case Protocol::UDP:
return IPPROTO_UDP;
default:
UNIMPLEMENTED_MSG("Unimplemented protocol={}", protocol);
return 0;
}
}
SockAddrIn TranslateToSockAddrIn(sockaddr_in input, size_t input_len) {
SockAddrIn result;
result.family = TranslateDomainFromNative(input.sin_family);
result.portno = ntohs(input.sin_port);
result.ip = TranslateIPv4(input.sin_addr);
return result;
}
short TranslatePollEvents(PollEvents events) {
short result = 0;
const auto translate = [&result, &events](PollEvents guest, short host) {
if (True(events & guest)) {
events &= ~guest;
result |= host;
}
};
translate(PollEvents::In, POLLIN);
translate(PollEvents::Pri, POLLPRI);
translate(PollEvents::Out, POLLOUT);
translate(PollEvents::Err, POLLERR);
translate(PollEvents::Hup, POLLHUP);
translate(PollEvents::Nval, POLLNVAL);
translate(PollEvents::RdNorm, POLLRDNORM);
translate(PollEvents::RdBand, POLLRDBAND);
translate(PollEvents::WrBand, POLLWRBAND);
#ifdef _WIN32
short allowed_events = POLLRDBAND | POLLRDNORM | POLLWRNORM;
// Unlike poll on other OSes, WSAPoll will complain if any other flags are set on input.
if (result & ~allowed_events) {
LOG_DEBUG(Network,
"Removing WSAPoll input events 0x{:x} because Windows doesn't support them",
result & ~allowed_events);
}
result &= allowed_events;
#endif
UNIMPLEMENTED_IF_MSG((u16)events != 0, "Unhandled guest events=0x{:x}", (u16)events);
return result;
}
PollEvents TranslatePollRevents(short revents) {
PollEvents result{};
const auto translate = [&result, &revents](short host, PollEvents guest) {
if ((revents & host) != 0) {
revents &= static_cast<short>(~host);
result |= guest;
}
};
translate(POLLIN, PollEvents::In);
translate(POLLPRI, PollEvents::Pri);
translate(POLLOUT, PollEvents::Out);
translate(POLLERR, PollEvents::Err);
translate(POLLHUP, PollEvents::Hup);
translate(POLLNVAL, PollEvents::Nval);
translate(POLLRDNORM, PollEvents::RdNorm);
translate(POLLRDBAND, PollEvents::RdBand);
translate(POLLWRBAND, PollEvents::WrBand);
UNIMPLEMENTED_IF_MSG(revents != 0, "Unhandled host revents=0x{:x}", revents);
return result;
}
} // Anonymous namespace
NetworkInstance::NetworkInstance() {
Initialize();
}
NetworkInstance::~NetworkInstance() {
Finalize();
}
void CancelPendingSocketOperations() {
InterruptSocketOperations();
}
void RestartSocketOperations() {
AcknowledgeInterrupt();
}
std::optional<IPv4Address> GetHostIPv4Address() {
const auto network_interface = Network::GetSelectedNetworkInterface();
if (!network_interface.has_value()) {
// Only print the error once to avoid log spam
static bool print_error = true;
if (print_error) {
LOG_ERROR(Network, "GetSelectedNetworkInterface returned no interface");
print_error = false;
}
return {};
}
return TranslateIPv4(network_interface->ip_address);
}
std::string IPv4AddressToString(IPv4Address ip_addr) {
std::array<char, INET_ADDRSTRLEN> buf = {};
ASSERT(inet_ntop(AF_INET, &ip_addr, buf.data(), sizeof(buf)) == buf.data());
return std::string(buf.data());
}
u32 IPv4AddressToInteger(IPv4Address ip_addr) {
return static_cast<u32>(ip_addr[0]) << 24 | static_cast<u32>(ip_addr[1]) << 16 |
static_cast<u32>(ip_addr[2]) << 8 | static_cast<u32>(ip_addr[3]);
}
Common::Expected<std::vector<AddrInfo>, GetAddrInfoError> GetAddressInfo(
const std::string& host, const std::optional<std::string>& service) {
addrinfo hints{};
hints.ai_family = AF_INET; // Switch only supports IPv4.
addrinfo* addrinfo;
s32 gai_err = getaddrinfo(host.c_str(), service.has_value() ? service->c_str() : nullptr,
&hints, &addrinfo);
if (gai_err != 0) {
return Common::Unexpected(TranslateGetAddrInfoErrorFromNative(gai_err));
}
std::vector<AddrInfo> ret;
for (auto* current = addrinfo; current; current = current->ai_next) {
// We should only get AF_INET results due to the hints value.
ASSERT_OR_EXECUTE(addrinfo->ai_family == AF_INET &&
addrinfo->ai_addrlen == sizeof(sockaddr_in),
continue;);
AddrInfo& out = ret.emplace_back();
out.family = TranslateDomainFromNative(current->ai_family);
out.socket_type = TranslateTypeFromNative(current->ai_socktype);
out.protocol = TranslateProtocolFromNative(current->ai_protocol);
out.addr = TranslateToSockAddrIn(*reinterpret_cast<sockaddr_in*>(current->ai_addr),
current->ai_addrlen);
if (current->ai_canonname != nullptr) {
out.canon_name = current->ai_canonname;
}
}
freeaddrinfo(addrinfo);
return ret;
}
std::pair<s32, Errno> Poll(std::vector<PollFD>& pollfds, s32 timeout) {
const size_t num = pollfds.size();
std::vector<WSAPOLLFD> host_pollfds(pollfds.size());
std::transform(pollfds.begin(), pollfds.end(), host_pollfds.begin(), [](PollFD fd) {
WSAPOLLFD result;
result.fd = fd.socket->GetFD();
result.events = TranslatePollEvents(fd.events);
result.revents = 0;
return result;
});
host_pollfds.push_back(WSAPOLLFD{
.fd = GetInterruptSocket(),
.events = POLLIN,
.revents = 0,
});
const int result =
WSAPoll(host_pollfds.data(), static_cast<ULONG>(host_pollfds.size()), timeout);
if (result == 0) {
ASSERT(std::all_of(host_pollfds.begin(), host_pollfds.end(),
[](WSAPOLLFD fd) { return fd.revents == 0; }));
return {0, Errno::SUCCESS};
}
for (size_t i = 0; i < num; ++i) {
pollfds[i].revents = TranslatePollRevents(host_pollfds[i].revents);
}
if (result > 0) {
return {result, Errno::SUCCESS};
}
ASSERT(result == SOCKET_ERROR);
return {-1, GetAndLogLastError()};
}
Socket::~Socket() {
if (fd == INVALID_SOCKET) {
return;
}
(void)closesocket(fd);
fd = INVALID_SOCKET;
}
Socket::Socket(Socket&& rhs) noexcept {
fd = std::exchange(rhs.fd, INVALID_SOCKET);
}
template <typename T>
std::pair<T, Errno> Socket::GetSockOpt(SOCKET fd_so, int option) {
T value{};
socklen_t len = sizeof(value);
const int result = getsockopt(fd_so, SOL_SOCKET, option, reinterpret_cast<char*>(&value), &len);
if (result != SOCKET_ERROR) {
ASSERT(len == sizeof(value));
return {value, Errno::SUCCESS};
}
return {value, GetAndLogLastError()};
}
template <typename T>
Errno Socket::SetSockOpt(SOCKET fd_so, int option, T value) {
const int result =
setsockopt(fd_so, SOL_SOCKET, option, reinterpret_cast<const char*>(&value), sizeof(value));
if (result != SOCKET_ERROR) {
return Errno::SUCCESS;
}
return GetAndLogLastError();
}
Errno Socket::Initialize(Domain domain, Type type, Protocol protocol) {
fd = socket(TranslateDomainToNative(domain), TranslateTypeToNative(type),
TranslateProtocolToNative(protocol));
if (fd != INVALID_SOCKET) {
return Errno::SUCCESS;
}
return GetAndLogLastError();
}
std::pair<SocketBase::AcceptResult, Errno> Socket::Accept() {
sockaddr_in addr;
socklen_t addrlen = sizeof(addr);
const bool wait_for_accept = !is_non_blocking;
if (wait_for_accept) {
std::vector<WSAPOLLFD> host_pollfds{
WSAPOLLFD{fd, POLLIN, 0},
WSAPOLLFD{GetInterruptSocket(), POLLIN, 0},
};
while (true) {
const int pollres =
WSAPoll(host_pollfds.data(), static_cast<ULONG>(host_pollfds.size()), -1);
if (host_pollfds[1].revents != 0) {
// Interrupt signaled before a client could be accepted, break
return {AcceptResult{}, Errno::AGAIN};
}
if (pollres > 0) {
break;
}
}
}
const SOCKET new_socket = accept(fd, reinterpret_cast<sockaddr*>(&addr), &addrlen);
if (new_socket == INVALID_SOCKET) {
return {AcceptResult{}, GetAndLogLastError()};
}
AcceptResult result{
.socket = std::make_unique<Socket>(new_socket),
.sockaddr_in = TranslateToSockAddrIn(addr, addrlen),
};
return {std::move(result), Errno::SUCCESS};
}
Errno Socket::Connect(SockAddrIn addr_in) {
const sockaddr host_addr_in = TranslateFromSockAddrIn(addr_in);
if (connect(fd, &host_addr_in, sizeof(host_addr_in)) != SOCKET_ERROR) {
return Errno::SUCCESS;
}
return GetAndLogLastError();
}
std::pair<SockAddrIn, Errno> Socket::GetPeerName() {
sockaddr_in addr;
socklen_t addrlen = sizeof(addr);
if (getpeername(fd, reinterpret_cast<sockaddr*>(&addr), &addrlen) == SOCKET_ERROR) {
return {SockAddrIn{}, GetAndLogLastError()};
}
return {TranslateToSockAddrIn(addr, addrlen), Errno::SUCCESS};
}
std::pair<SockAddrIn, Errno> Socket::GetSockName() {
sockaddr_in addr;
socklen_t addrlen = sizeof(addr);
if (getsockname(fd, reinterpret_cast<sockaddr*>(&addr), &addrlen) == SOCKET_ERROR) {
return {SockAddrIn{}, GetAndLogLastError()};
}
return {TranslateToSockAddrIn(addr, addrlen), Errno::SUCCESS};
}
Errno Socket::Bind(SockAddrIn addr) {
const sockaddr addr_in = TranslateFromSockAddrIn(addr);
if (bind(fd, &addr_in, sizeof(addr_in)) != SOCKET_ERROR) {
return Errno::SUCCESS;
}
return GetAndLogLastError();
}
Errno Socket::Listen(s32 backlog) {
if (listen(fd, backlog) != SOCKET_ERROR) {
return Errno::SUCCESS;
}
return GetAndLogLastError();
}
Errno Socket::Shutdown(ShutdownHow how) {
int host_how = 0;
switch (how) {
case ShutdownHow::RD:
host_how = SD_RECEIVE;
break;
case ShutdownHow::WR:
host_how = SD_SEND;
break;
case ShutdownHow::RDWR:
host_how = SD_BOTH;
break;
default:
UNIMPLEMENTED_MSG("Unimplemented flag how={}", how);
return Errno::SUCCESS;
}
if (shutdown(fd, host_how) != SOCKET_ERROR) {
return Errno::SUCCESS;
}
return GetAndLogLastError();
}
std::pair<s32, Errno> Socket::Recv(int flags, std::span<u8> message) {
ASSERT(flags == 0);
ASSERT(message.size() < static_cast<size_t>(std::numeric_limits<int>::max()));
const auto result =
recv(fd, reinterpret_cast<char*>(message.data()), static_cast<int>(message.size()), 0);
if (result != SOCKET_ERROR) {
return {static_cast<s32>(result), Errno::SUCCESS};
}
return {-1, GetAndLogLastError()};
}
std::pair<s32, Errno> Socket::RecvFrom(int flags, std::span<u8> message, SockAddrIn* addr) {
ASSERT(flags == 0);
ASSERT(message.size() < static_cast<size_t>(std::numeric_limits<int>::max()));
sockaddr_in addr_in{};
socklen_t addrlen = sizeof(addr_in);
socklen_t* const p_addrlen = addr ? &addrlen : nullptr;
sockaddr* const p_addr_in = addr ? reinterpret_cast<sockaddr*>(&addr_in) : nullptr;
const auto result = recvfrom(fd, reinterpret_cast<char*>(message.data()),
static_cast<int>(message.size()), 0, p_addr_in, p_addrlen);
if (result != SOCKET_ERROR) {
if (addr) {
*addr = TranslateToSockAddrIn(addr_in, addrlen);
}
return {static_cast<s32>(result), Errno::SUCCESS};
}
return {-1, GetAndLogLastError()};
}
std::pair<s32, Errno> Socket::Send(std::span<const u8> message, int flags) {
ASSERT(message.size() < static_cast<size_t>(std::numeric_limits<int>::max()));
ASSERT(flags == 0);
int native_flags = 0;
#if YUZU_UNIX
native_flags |= MSG_NOSIGNAL; // do not send us SIGPIPE
#endif
const auto result = send(fd, reinterpret_cast<const char*>(message.data()),
static_cast<int>(message.size()), native_flags);
if (result != SOCKET_ERROR) {
return {static_cast<s32>(result), Errno::SUCCESS};
}
return {-1, GetAndLogLastError(CallType::Send)};
}
std::pair<s32, Errno> Socket::SendTo(u32 flags, std::span<const u8> message,
const SockAddrIn* addr) {
ASSERT(flags == 0);
const sockaddr* to = nullptr;
const int to_len = addr ? sizeof(sockaddr) : 0;
sockaddr host_addr_in;
if (addr) {
host_addr_in = TranslateFromSockAddrIn(*addr);
to = &host_addr_in;
}
const auto result = sendto(fd, reinterpret_cast<const char*>(message.data()),
static_cast<int>(message.size()), 0, to, to_len);
if (result != SOCKET_ERROR) {
return {static_cast<s32>(result), Errno::SUCCESS};
}
return {-1, GetAndLogLastError(CallType::Send)};
}
Errno Socket::Close() {
[[maybe_unused]] const int result = closesocket(fd);
ASSERT(result == 0);
fd = INVALID_SOCKET;
return Errno::SUCCESS;
}
std::pair<Errno, Errno> Socket::GetPendingError() {
auto [pending_err, getsockopt_err] = GetSockOpt<int>(fd, SO_ERROR);
return {TranslateNativeError(pending_err), getsockopt_err};
}
Errno Socket::SetLinger(bool enable, u32 linger) {
return SetSockOpt(fd, SO_LINGER, MakeLinger(enable, linger));
}
Errno Socket::SetReuseAddr(bool enable) {
return SetSockOpt<u32>(fd, SO_REUSEADDR, enable ? 1 : 0);
}
Errno Socket::SetKeepAlive(bool enable) {
return SetSockOpt<u32>(fd, SO_KEEPALIVE, enable ? 1 : 0);
}
Errno Socket::SetBroadcast(bool enable) {
return SetSockOpt<u32>(fd, SO_BROADCAST, enable ? 1 : 0);
}
Errno Socket::SetSndBuf(u32 value) {
return SetSockOpt(fd, SO_SNDBUF, value);
}
Errno Socket::SetRcvBuf(u32 value) {
return SetSockOpt(fd, SO_RCVBUF, value);
}
Errno Socket::SetSndTimeo(u32 value) {
return SetSockOpt(fd, SO_SNDTIMEO, value);
}
Errno Socket::SetRcvTimeo(u32 value) {
return SetSockOpt(fd, SO_RCVTIMEO, value);
}
Errno Socket::SetNonBlock(bool enable) {
if (EnableNonBlock(fd, enable)) {
is_non_blocking = enable;
return Errno::SUCCESS;
}
return GetAndLogLastError();
}
bool Socket::IsOpened() const {
return fd != INVALID_SOCKET;
}
void Socket::HandleProxyPacket(const ProxyPacket& packet) {
LOG_WARNING(Network, "ProxyPacket received, but not in Proxy mode!");
}
} // namespace Network