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Ipc.cpp
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Ipc.cpp
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// This file was developed by Thomas Müller <[email protected]>.
// It is published under the BSD 3-Clause License within the LICENSE file.
#ifdef _WIN32
# define NOMINMAX
# include <winsock2.h>
# include <Ws2tcpip.h>
# undef NOMINMAX
#endif
#include <tev/Common.h>
#include <tev/Ipc.h>
#include <tev/ThreadPool.h>
#ifdef _WIN32
using socklen_t = int;
#else
# include <arpa/inet.h>
# include <cstring>
# ifdef EMSCRIPTEN
# include <fcntl.h>
# endif
# include <netdb.h>
# include <netinet/in.h>
# include <signal.h>
# include <sys/file.h>
# include <sys/socket.h>
# include <unistd.h>
# define SOCKET_ERROR (-1)
# define INVALID_SOCKET (-1)
#endif
using namespace std;
namespace tev {
enum SocketError : int {
#ifdef _WIN32
Again = EAGAIN,
ConnRefused = WSAECONNREFUSED,
WouldBlock = WSAEWOULDBLOCK,
#else
Again = EAGAIN,
ConnRefused = ECONNREFUSED,
WouldBlock = EWOULDBLOCK,
#endif
};
IpcPacket::IpcPacket(const char* data, size_t length) {
if (length <= 0) {
throw runtime_error{"Cannot construct an IPC packet from no data."};
}
mPayload.assign(data, data+length);
}
void IpcPacket::setOpenImage(const string& imagePath, const string& channelSelector, bool grabFocus) {
OStream payload{mPayload};
payload << EType::OpenImageV2;
payload << grabFocus;
payload << imagePath;
payload << channelSelector;
}
void IpcPacket::setReloadImage(const string& imageName, bool grabFocus) {
OStream payload{mPayload};
payload << EType::ReloadImage;
payload << grabFocus;
payload << imageName;
}
void IpcPacket::setCloseImage(const string& imageName) {
OStream payload{mPayload};
payload << EType::CloseImage;
payload << imageName;
}
void IpcPacket::setUpdateImage(const string& imageName, bool grabFocus, const vector<IpcPacket::ChannelDesc>& channelDescs, int32_t x, int32_t y, int32_t width, int32_t height, const vector<float>& stridedImageData) {
if (channelDescs.empty()) {
throw runtime_error{"UpdateImage IPC packet must have a non-zero channel count."};
}
int32_t nChannels = (int32_t)channelDescs.size();
vector<string> channelNames(nChannels);
vector<int64_t> channelOffsets(nChannels);
vector<int64_t> channelStrides(nChannels);
for (int32_t i = 0; i < nChannels; ++i) {
channelNames[i] = channelDescs[i].name;
channelOffsets[i] = channelDescs[i].offset;
channelStrides[i] = channelDescs[i].stride;
}
OStream payload{mPayload};
payload << EType::UpdateImageV3;
payload << grabFocus;
payload << imageName;
payload << nChannels;
payload << channelNames;
payload << x << y << width << height;
payload << channelOffsets;
payload << channelStrides;
size_t nPixels = width * height;
size_t stridedImageDataSize = 0;
for (int32_t c = 0; c < nChannels; ++c) {
stridedImageDataSize = max(stridedImageDataSize, (size_t)(channelOffsets[c] + (nPixels-1) * channelStrides[c] + 1));
}
if (stridedImageData.size() != stridedImageDataSize) {
throw runtime_error{fmt::format("UpdateImage IPC packet's data size does not match specified dimensions, offset, and stride. (Expected: {})", stridedImageDataSize)};
}
payload << stridedImageData;
}
void IpcPacket::setCreateImage(const string& imageName, bool grabFocus, int32_t width, int32_t height, int32_t nChannels, const vector<string>& channelNames) {
if ((int32_t)channelNames.size() != nChannels) {
throw runtime_error{"CreateImage IPC packet's channel names size does not match number of channels."};
}
OStream payload{mPayload};
payload << EType::CreateImage;
payload << grabFocus;
payload << imageName;
payload << width << height;
payload << nChannels;
payload << channelNames;
}
void IpcPacket::setVectorGraphics(const string& imageName, bool grabFocus, bool append, const vector<VgCommand>& commands) {
OStream payload{mPayload};
payload << EType::VectorGraphics;
payload << grabFocus;
payload << imageName;
payload << append;
payload << (int32_t)commands.size();
for (const auto& command : commands) {
payload << command.type;
payload << command.data;
}
}
IpcPacketOpenImage IpcPacket::interpretAsOpenImage() const {
IpcPacketOpenImage result;
IStream payload{mPayload};
EType type;
payload >> type;
if (type != EType::OpenImage && type != EType::OpenImageV2) {
throw runtime_error{"Cannot interpret IPC packet as OpenImage."};
}
payload >> result.grabFocus;
string imageString;
payload >> imageString;
if (type >= EType::OpenImageV2) {
result.imagePath = imageString;
payload >> result.channelSelector;
return result;
}
size_t colonPos = imageString.find_last_of(":");
if (colonPos == string::npos ||
// windows path of the form X:/* or X:\*
(colonPos == 1 && imageString.length() >= 3 && (imageString[2] == '\\' || imageString[2] == '/'))
) {
result.imagePath = imageString;
result.channelSelector = "";
} else {
result.imagePath = imageString.substr(0, colonPos);
result.channelSelector = imageString.substr(colonPos + 1);
}
return result;
}
IpcPacketReloadImage IpcPacket::interpretAsReloadImage() const {
IpcPacketReloadImage result;
IStream payload{mPayload};
EType type;
payload >> type;
if (type != EType::ReloadImage) {
throw runtime_error{"Cannot interpret IPC packet as ReloadImage."};
}
payload >> result.grabFocus;
payload >> result.imageName;
return result;
}
IpcPacketCloseImage IpcPacket::interpretAsCloseImage() const {
IpcPacketCloseImage result;
IStream payload{mPayload};
EType type;
payload >> type;
if (type != EType::CloseImage) {
throw runtime_error{"Cannot interpret IPC packet as CloseImage."};
}
payload >> result.imageName;
return result;
}
IpcPacketUpdateImage IpcPacket::interpretAsUpdateImage() const {
IpcPacketUpdateImage result;
IStream payload{mPayload};
EType type;
payload >> type;
if (type != EType::UpdateImage && type != EType::UpdateImageV2 && type != EType::UpdateImageV3) {
throw runtime_error{"Cannot interpret IPC packet as UpdateImage."};
}
payload >> result.grabFocus;
payload >> result.imageName;
if (type >= EType::UpdateImageV2) {
// multi-channel support
payload >> result.nChannels;
} else {
result.nChannels = 1;
}
result.channelNames.resize(result.nChannels);
payload >> result.channelNames;
result.channelOffsets.resize(result.nChannels);
result.channelStrides.resize(result.nChannels, 1);
payload >> result.x >> result.y >> result.width >> result.height;
size_t nPixels = (size_t)result.width * result.height;
if (type >= EType::UpdateImageV3) {
// custom offset/stride support
payload >> result.channelOffsets;
payload >> result.channelStrides;
} else {
for (int32_t i = 0; i < result.nChannels; ++i) {
result.channelOffsets[i] = nPixels * i;
}
}
result.imageData.resize(result.nChannels);
for (int32_t i = 0; i < result.nChannels; ++i) {
result.imageData[i].resize(nPixels);
}
size_t stridedImageDataSize = 0;
for (int32_t c = 0; c < result.nChannels; ++c) {
stridedImageDataSize = max(stridedImageDataSize, (size_t)(result.channelOffsets[c] + (nPixels-1) * result.channelStrides[c] + 1));
}
if (payload.remainingBytes() < stridedImageDataSize * sizeof(float)) {
throw runtime_error{"UpdateImage: insufficient image data."};
}
const float* stridedImageData = (const float*)payload.get();
ThreadPool::global().parallelFor<size_t>(0, nPixels, [&](size_t px) {
for (int32_t c = 0; c < result.nChannels; ++c) {
result.imageData[c][px] = stridedImageData[result.channelOffsets[c] + px * result.channelStrides[c]];
}
}, numeric_limits<int>::max());
return result;
}
IpcPacketCreateImage IpcPacket::interpretAsCreateImage() const {
IpcPacketCreateImage result;
IStream payload{mPayload};
EType type;
payload >> type;
if (type != EType::CreateImage) {
throw runtime_error{"Cannot interpret IPC packet as CreateImage."};
}
payload >> result.grabFocus;
payload >> result.imageName;
payload >> result.width >> result.height;
payload >> result.nChannels;
result.channelNames.resize(result.nChannels);
payload >> result.channelNames;
return result;
}
IpcPacketVectorGraphics IpcPacket::interpretAsVectorGraphics() const {
IpcPacketVectorGraphics result;
IStream payload{mPayload};
EType type;
payload >> type;
if (type != EType::VectorGraphics) {
throw runtime_error{"Cannot interpret IPC packet as VectorGraphics."};
}
payload >> result.grabFocus;
payload >> result.imageName;
payload >> result.append;
payload >> result.nCommands;
result.commands.resize(result.nCommands);
for (int32_t i = 0; i < result.nCommands; ++i) {
auto& command = result.commands[i];
payload >> command.type;
command.data.resize(command.size());
payload >> command.data;
}
return result;
}
static void makeSocketNonBlocking(Ipc::socket_t socketFd) {
#ifdef _WIN32
u_long mode = 1;
int ioctlsocketResult = ioctlsocket(socketFd, FIONBIO, &mode);
if (ioctlsocketResult != NO_ERROR) {
throw runtime_error{fmt::format("ioctlsocket() to make socket non-blocking failed: {}", errorString(ioctlsocketResult))};
}
#else
if (fcntl(socketFd, F_SETFL, fcntl(socketFd, F_GETFL, 0) | O_NONBLOCK) == SOCKET_ERROR) {
throw runtime_error{fmt::format("fcntl() to make socket non-blocking failed: {}", errorString(lastSocketError()))};
}
#endif
}
static int closeSocket(Ipc::socket_t socket) {
#ifdef _WIN32
return closesocket(socket);
#else
return close(socket);
#endif
}
Ipc::Ipc(const string& hostname) : mSocketFd{INVALID_SOCKET} {
mLockName = ".tev-lock."s + hostname;
auto parts = split(hostname, ":");
mIp = parts.front();
mPort = parts.back();
try {
// Networking
#ifdef _WIN32
// FIXME: only do this once if multiple Ipc objects are created.
WSADATA wsaData;
int wsaStartupResult = WSAStartup(MAKEWORD(2, 2), &wsaData);
if (wsaStartupResult != NO_ERROR) {
throw runtime_error{fmt::format("Could not initialize WSA: {}", errorString(wsaStartupResult))};
}
#else
// We don't care about getting a SIGPIPE if the display server goes away...
signal(SIGPIPE, SIG_IGN);
#endif
if (attemptToBecomePrimaryInstance()) {
return;
}
// If we're not the primary instance, try to connect to it as a client
struct addrinfo hints = {}, *addrinfo;
hints.ai_family = PF_UNSPEC;
hints.ai_socktype = SOCK_STREAM;
int err = getaddrinfo(mIp.c_str(), mPort.c_str(), &hints, &addrinfo);
if (err != 0) {
throw runtime_error{fmt::format("getaddrinfo() failed: {}", gai_strerror(err))};
}
ScopeGuard addrinfoGuard{[addrinfo] { freeaddrinfo(addrinfo); }};
mSocketFd = INVALID_SOCKET;
for (struct addrinfo* ptr = addrinfo; ptr; ptr = ptr->ai_next) {
mSocketFd = socket(ptr->ai_family, ptr->ai_socktype, ptr->ai_protocol);
if (mSocketFd == INVALID_SOCKET) {
tlog::warning() << fmt::format("socket() failed: {}", errorString(lastSocketError()));
continue;
}
if (connect(mSocketFd, ptr->ai_addr, (int)ptr->ai_addrlen) == SOCKET_ERROR) {
int errorId = lastSocketError();
if (errorId == SocketError::ConnRefused) {
throw runtime_error{"Connection to primary instance refused"};
} else {
tlog::warning() << fmt::format("connect() failed: {}", errorString(errorId));
}
closeSocket(mSocketFd);
mSocketFd = INVALID_SOCKET;
continue;
}
tlog::success() << "Connected to primary instance " << mIp << ":" << mPort;
break; // success
}
if (mSocketFd == INVALID_SOCKET) {
throw runtime_error{"Unable to connect to primary instance."};
}
} catch (const runtime_error& e) {
tlog::warning() << "Could not initialize IPC. Assuming primary instance. " << e.what();
mIsPrimaryInstance = true;
}
}
Ipc::~Ipc() {
// Lock
#ifdef _WIN32
if (mIsPrimaryInstance && mInstanceMutex) {
ReleaseMutex(mInstanceMutex);
CloseHandle(mInstanceMutex);
}
#else
if (mIsPrimaryInstance) {
if (mLockFileDescriptor != -1) {
close(mLockFileDescriptor);
}
// Delete the lock file if it exists.
unlink(mLockFile.string().c_str());
}
#endif
// Networking
if (mSocketFd != INVALID_SOCKET) {
if (closeSocket(mSocketFd) == SOCKET_ERROR) {
tlog::warning() << "Error closing socket listen fd " << mSocketFd << ": " << errorString(lastSocketError());
}
}
#ifdef _WIN32
// FIXME: only do this when the last Ipc is destroyed
WSACleanup();
#endif
}
bool Ipc::attemptToBecomePrimaryInstance() {
#ifdef _WIN32
// Make sure at most one instance of tev is running
mInstanceMutex = CreateMutex(NULL, TRUE, mLockName.c_str());
if (!mInstanceMutex) {
throw runtime_error{fmt::format("Could not obtain global mutex: {}", errorString(lastError()))};
}
mIsPrimaryInstance = GetLastError() != ERROR_ALREADY_EXISTS;
if (!mIsPrimaryInstance) {
// No need to keep the handle to the existing mutex if we're not the primary instance.
ReleaseMutex(mInstanceMutex);
CloseHandle(mInstanceMutex);
}
#else
mLockFile = homeDirectory() / mLockName;
mLockFileDescriptor = open(mLockFile.string().c_str(), O_RDWR | O_CREAT, 0666);
if (mLockFileDescriptor == -1) {
throw runtime_error{fmt::format("Could not create lock file: {}", errorString(lastError()))};
}
mIsPrimaryInstance = !flock(mLockFileDescriptor, LOCK_EX | LOCK_NB);
if (!mIsPrimaryInstance) {
close(mLockFileDescriptor);
}
#endif
if (!mIsPrimaryInstance) {
return false;
}
// Managed to become primary instance
// If we were previously a secondary instance connected with the primary instance, disconnect
if (mSocketFd != INVALID_SOCKET) {
if (closeSocket(mSocketFd) == SOCKET_ERROR) {
tlog::warning() << "Error closing socket upon becoming primary instance " << mSocketFd << ": " << errorString(lastSocketError());
}
}
// Set up primary instance network server
mSocketFd = socket(AF_INET, SOCK_STREAM, 0);
if (mSocketFd == INVALID_SOCKET) {
throw runtime_error{fmt::format("socket() call failed: {}", errorString(lastSocketError()))};
}
makeSocketNonBlocking(mSocketFd);
// Avoid address in use error that occurs if we quit with a client connected.
int t = 1;
if (setsockopt(mSocketFd, SOL_SOCKET, SO_REUSEADDR, (const char*)&t, sizeof(int)) == SOCKET_ERROR) {
throw runtime_error{fmt::format("setsockopt() call failed: {}", errorString(lastSocketError()))};
}
struct sockaddr_in addr;
addr.sin_family = AF_INET;
addr.sin_port = htons((uint16_t)atoi(mPort.c_str()));
#ifdef _WIN32
InetPton(AF_INET, mIp.c_str(), &addr.sin_addr);
#else
inet_aton(mIp.c_str(), &addr.sin_addr);
#endif
if (::bind(mSocketFd, (struct sockaddr*)&addr, sizeof(addr)) == SOCKET_ERROR) {
throw runtime_error{fmt::format("bind() call failed: {}", errorString(lastSocketError()))};
}
if (listen(mSocketFd, 5) == SOCKET_ERROR) {
throw runtime_error{fmt::format("listen() call failed: {}", errorString(lastSocketError()))};
}
tlog::success() << "Initialized IPC, listening on " << mIp << ":" << mPort;
return true;
}
void Ipc::sendToPrimaryInstance(const IpcPacket& message) {
if (mIsPrimaryInstance) {
throw runtime_error{"Must be a secondary instance to send to the primary instance."};
}
int bytesSent = send(mSocketFd, message.data(), (int)message.size(), 0 /* flags */);
if (bytesSent != int(message.size())) {
throw runtime_error{fmt::format("send() failed: {}", errorString(lastSocketError()))};
}
}
void Ipc::receiveFromSecondaryInstance(function<void(const IpcPacket&)> callback) {
if (!mIsPrimaryInstance) {
throw runtime_error{"Must be the primary instance to receive from a secondary instance."};
}
// Check for new connections.
struct sockaddr_in client;
socklen_t addrlen = sizeof(client);
socket_t fd = accept(mSocketFd, (struct sockaddr*)&client, &addrlen);
if (fd == INVALID_SOCKET) {
int errorId = lastSocketError();
if (errorId == SocketError::WouldBlock) {
// no problem; no one is trying to connect
} else {
tlog::warning() << "accept() error: " << errorId << " " << errorString(errorId);
}
} else {
uint32_t ip = ntohl(client.sin_addr.s_addr);
uint16_t port = ntohs(client.sin_port);
auto name = fmt::format("{}.{}.{}.{}:{}", ip >> 24, (ip >> 16) & 0xff, (ip >> 8) & 0xff, ip & 0xff, port);
tlog::info() << fmt::format("Client {} (#{}) connected", name, fd);
mSocketConnections.push_back(SocketConnection{fd, name});
}
// Service existing connections.
for (auto iter = mSocketConnections.begin(); iter != mSocketConnections.end();) {
auto cur = iter++;
cur->service(callback);
// If the connection became closed, stop keeping track of it.
if (cur->isClosed()) {
mSocketConnections.erase(cur);
}
}
}
Ipc::SocketConnection::SocketConnection(Ipc::socket_t fd, const string& name)
: mSocketFd{fd}, mName{name}
{
TEV_ASSERT(mSocketFd != INVALID_SOCKET, "SocketConnection must receive a valid socket.");
makeSocketNonBlocking(mSocketFd);
// 1 MiB is a good default buffer size. If larger is required, it'll be automatizally resized.
mBuffer.resize(1024 * 1024);
}
void Ipc::SocketConnection::service(function<void(const IpcPacket&)> callback) {
if (isClosed()) {
// Client disconnected, so don't bother.
return;
}
while (true) {
// Receive as much data as we can, up to the capacity of 'mBuffer'.
size_t maxBytes = mBuffer.size() - mRecvOffset;
int bytesReceived = recv(mSocketFd, mBuffer.data() + mRecvOffset, (int)maxBytes, 0);
if (bytesReceived == SOCKET_ERROR) {
int errorId = lastSocketError();
// no more data; this is fine.
if (errorId == SocketError::Again || errorId == SocketError::WouldBlock) {
break;
} else {
tlog::warning() << "Error while reading from socket. " << errorString(errorId) << " Connection terminated.";
close();
return;
}
}
TEV_ASSERT(bytesReceived >= 0, "With no error, the number of bytes received should be positive.");
mRecvOffset += (size_t)bytesReceived;
// Since we aren't getting annoying SIGPIPE signals when a client
// disconnects, a zero-byte read here is how we know when that happens.
if (bytesReceived == 0) {
tlog::info() << "Client " << mName << " (#" << mSocketFd << ") disconnected";
close();
return;
}
// Go through the buffer and service as many complete messages as
// we can find.
size_t processedOffset = 0;
while (processedOffset + 4 <= mRecvOffset) {
// There's at least enough to figure out the next message's length.
const char* messagePtr = mBuffer.data() + processedOffset;
uint32_t messageLength = *((uint32_t*)messagePtr);
if (messageLength > mBuffer.size()) {
mBuffer.resize(messageLength);
break;
}
if (processedOffset + messageLength <= mRecvOffset) {
// We have a full message.
callback(IpcPacket{messagePtr, messageLength});
processedOffset += messageLength;
} else {
// It's a partial message; we'll need to recv() more.
break;
}
}
// TODO: we could save the memcpy by treating 'buffer' as a ring-buffer,
// but it's probably not worth the trouble. Revisit when someone throws around
// buffers with a size of gigabytes.
if (processedOffset > 0) {
// There's a partial message; copy it to the start of 'buffer'
// and update the offsets accordingly.
memmove(mBuffer.data(), mBuffer.data() + processedOffset, mRecvOffset - processedOffset);
mRecvOffset -= processedOffset;
}
}
}
void Ipc::SocketConnection::close() {
if (!isClosed()) {
closeSocket(mSocketFd);
mSocketFd = INVALID_SOCKET;
}
}
bool Ipc::SocketConnection::isClosed() const {
return mSocketFd == INVALID_SOCKET;
}
}