File: godot.cpp

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/*************************************************************************/
/*  godot.cpp                                                            */
/*************************************************************************/
/*                       This file is part of:                           */
/*                           GODOT ENGINE                                */
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/* Copyright (c) 2007-2020 Juan Linietsky, Ariel Manzur.                 */
/* Copyright (c) 2014-2020 Godot Engine contributors (cf. AUTHORS.md).   */
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/*************************************************************************/
/**
 @file  godot.cpp
 @brief ENet Godot specific functions
*/

#include "core/io/dtls_server.h"
#include "core/io/ip.h"
#include "core/io/net_socket.h"
#include "core/io/packet_peer_dtls.h"
#include "core/io/udp_server.h"
#include "core/os/os.h"

// This must be last for windows to compile (tested with MinGW)
#include "enet/enet.h"

/// Abstract ENet interface for UDP/DTLS.
class ENetGodotSocket {

public:
	virtual Error bind(IP_Address p_ip, uint16_t p_port) = 0;
	virtual Error sendto(const uint8_t *p_buffer, int p_len, int &r_sent, IP_Address p_ip, uint16_t p_port) = 0;
	virtual Error recvfrom(uint8_t *p_buffer, int p_len, int &r_read, IP_Address &r_ip, uint16_t &r_port) = 0;
	virtual int set_option(ENetSocketOption p_option, int p_value) = 0;
	virtual void close() = 0;
	virtual void set_refuse_new_connections(bool p_refuse) { /* Only used by dtls server */ }
	virtual ~ENetGodotSocket(){};
};

class ENetDTLSClient;
class ENetDTLSServer;

/// NetSocket interface
class ENetUDP : public ENetGodotSocket {

	friend class ENetDTLSClient;
	friend class ENetDTLSServer;

private:
	Ref<NetSocket> sock;
	IP_Address address;
	uint16_t port;
	bool bound;

public:
	ENetUDP() {
		sock = Ref<NetSocket>(NetSocket::create());
		IP::Type ip_type = IP::TYPE_ANY;
		bound = false;
		sock->open(NetSocket::TYPE_UDP, ip_type);
	}

	~ENetUDP() {
		sock->close();
	}

	Error bind(IP_Address p_ip, uint16_t p_port) {
		address = p_ip;
		port = p_port;
		bound = true;
		return sock->bind(address, port);
	}

	Error sendto(const uint8_t *p_buffer, int p_len, int &r_sent, IP_Address p_ip, uint16_t p_port) {
		return sock->sendto(p_buffer, p_len, r_sent, p_ip, p_port);
	}

	Error recvfrom(uint8_t *p_buffer, int p_len, int &r_read, IP_Address &r_ip, uint16_t &r_port) {
		Error err = sock->poll(NetSocket::POLL_TYPE_IN, 0);
		if (err != OK)
			return err;
		return sock->recvfrom(p_buffer, p_len, r_read, r_ip, r_port);
	}

	int set_option(ENetSocketOption p_option, int p_value) {
		switch (p_option) {
			case ENET_SOCKOPT_NONBLOCK: {
				sock->set_blocking_enabled(p_value ? false : true);
				return 0;
			} break;

			case ENET_SOCKOPT_BROADCAST: {
				sock->set_broadcasting_enabled(p_value ? true : false);
				return 0;
			} break;

			case ENET_SOCKOPT_REUSEADDR: {
				sock->set_reuse_address_enabled(p_value ? true : false);
				return 0;
			} break;

			case ENET_SOCKOPT_RCVBUF: {
				return -1;
			} break;

			case ENET_SOCKOPT_SNDBUF: {
				return -1;
			} break;

			case ENET_SOCKOPT_RCVTIMEO: {
				return -1;
			} break;

			case ENET_SOCKOPT_SNDTIMEO: {
				return -1;
			} break;

			case ENET_SOCKOPT_NODELAY: {
				sock->set_tcp_no_delay_enabled(p_value ? true : false);
				return 0;
			} break;
		}

		return -1;
	}

	void close() {
		sock->close();
	}
};

/// DTLS Client ENet interface
class ENetDTLSClient : public ENetGodotSocket {

	bool connected;
	Ref<PacketPeerUDP> udp;
	Ref<PacketPeerDTLS> dtls;
	bool verify;
	String for_hostname;
	Ref<X509Certificate> cert;

public:
	ENetDTLSClient(ENetUDP *p_base, Ref<X509Certificate> p_cert, bool p_verify, String p_for_hostname) {
		verify = p_verify;
		for_hostname = p_for_hostname;
		cert = p_cert;
		udp.instance();
		dtls = Ref<PacketPeerDTLS>(PacketPeerDTLS::create());
		p_base->close();
		if (p_base->bound) {
			bind(p_base->address, p_base->port);
		}
		connected = false;
	}

	~ENetDTLSClient() {
		close();
	}

	Error bind(IP_Address p_ip, uint16_t p_port) {
		return udp->listen(p_port, p_ip);
	}

	Error sendto(const uint8_t *p_buffer, int p_len, int &r_sent, IP_Address p_ip, uint16_t p_port) {
		if (!connected) {
			udp->connect_to_host(p_ip, p_port);
			dtls->connect_to_peer(udp, verify, for_hostname, cert);
			connected = true;
		}
		dtls->poll();
		if (dtls->get_status() == PacketPeerDTLS::STATUS_HANDSHAKING)
			return ERR_BUSY;
		else if (dtls->get_status() != PacketPeerDTLS::STATUS_CONNECTED)
			return FAILED;
		r_sent = p_len;
		return dtls->put_packet(p_buffer, p_len);
	}

	Error recvfrom(uint8_t *p_buffer, int p_len, int &r_read, IP_Address &r_ip, uint16_t &r_port) {
		dtls->poll();
		if (dtls->get_status() == PacketPeerDTLS::STATUS_HANDSHAKING)
			return ERR_BUSY;
		if (dtls->get_status() != PacketPeerDTLS::STATUS_CONNECTED)
			return FAILED;
		int pc = dtls->get_available_packet_count();
		if (pc == 0)
			return ERR_BUSY;
		else if (pc < 0)
			return FAILED;

		const uint8_t *buffer;
		Error err = dtls->get_packet(&buffer, r_read);
		ERR_FAIL_COND_V(err != OK, err);
		ERR_FAIL_COND_V(p_len < r_read, ERR_OUT_OF_MEMORY);

		copymem(p_buffer, buffer, r_read);
		r_ip = udp->get_packet_address();
		r_port = udp->get_packet_port();
		return err;
	}

	int set_option(ENetSocketOption p_option, int p_value) {
		return -1;
	}

	void close() {
		dtls->disconnect_from_peer();
		udp->close();
	}
};

/// DTLSServer - ENet interface
class ENetDTLSServer : public ENetGodotSocket {

	Ref<DTLSServer> server;
	Ref<UDPServer> udp_server;
	Map<String, Ref<PacketPeerDTLS> > peers;
	int last_service;

public:
	ENetDTLSServer(ENetUDP *p_base, Ref<CryptoKey> p_key, Ref<X509Certificate> p_cert) {
		last_service = 0;
		udp_server.instance();
		p_base->close();
		if (p_base->bound) {
			bind(p_base->address, p_base->port);
		}
		server = Ref<DTLSServer>(DTLSServer::create());
		server->setup(p_key, p_cert);
	}

	~ENetDTLSServer() {
		close();
	}

	void set_refuse_new_connections(bool p_refuse) {
		udp_server->set_max_pending_connections(p_refuse ? 0 : 16);
	}

	Error bind(IP_Address p_ip, uint16_t p_port) {
		return udp_server->listen(p_port, p_ip);
	}

	Error sendto(const uint8_t *p_buffer, int p_len, int &r_sent, IP_Address p_ip, uint16_t p_port) {
		String key = String(p_ip) + ":" + itos(p_port);
		ERR_FAIL_COND_V(!peers.has(key), ERR_UNAVAILABLE);
		Ref<PacketPeerDTLS> peer = peers[key];
		Error err = peer->put_packet(p_buffer, p_len);
		if (err == OK)
			r_sent = p_len;
		else if (err == ERR_BUSY)
			r_sent = 0;
		else
			r_sent = -1;
		return err;
	}

	Error recvfrom(uint8_t *p_buffer, int p_len, int &r_read, IP_Address &r_ip, uint16_t &r_port) {
		udp_server->poll();
		// TODO limits? Maybe we can better enforce allowed connections!
		if (udp_server->is_connection_available()) {
			Ref<PacketPeerUDP> udp = udp_server->take_connection();
			IP_Address peer_ip = udp->get_packet_address();
			int peer_port = udp->get_packet_port();
			Ref<PacketPeerDTLS> peer = server->take_connection(udp);
			PacketPeerDTLS::Status status = peer->get_status();
			if (status == PacketPeerDTLS::STATUS_HANDSHAKING || status == PacketPeerDTLS::STATUS_CONNECTED) {
				String key = String(peer_ip) + ":" + itos(peer_port);
				peers[key] = peer;
			}
		}

		List<String> remove;
		Error err = ERR_BUSY;
		// TODO this needs to be fair!
		for (Map<String, Ref<PacketPeerDTLS> >::Element *E = peers.front(); E; E = E->next()) {
			Ref<PacketPeerDTLS> peer = E->get();
			peer->poll();

			if (peer->get_status() == PacketPeerDTLS::STATUS_HANDSHAKING)
				continue;
			else if (peer->get_status() != PacketPeerDTLS::STATUS_CONNECTED) {
				// Peer disconnected, removing it.
				remove.push_back(E->key());
				continue;
			}

			if (peer->get_available_packet_count() > 0) {
				const uint8_t *buffer;
				err = peer->get_packet(&buffer, r_read);
				if (err != OK || p_len < r_read) {
					// Something wrong with this peer, removing it.
					remove.push_back(E->key());
					err = FAILED;
					continue;
				}

				Vector<String> s = E->key().rsplit(":", false, 1);
				ERR_CONTINUE(s.size() != 2); // BUG!

				copymem(p_buffer, buffer, r_read);
				r_ip = s[0];
				r_port = s[1].to_int();
				break; // err = OK
			}
		}

		// Remove disconnected peers from map.
		for (List<String>::Element *E = remove.front(); E; E = E->next()) {
			peers.erase(E->get());
		}

		return err; // OK, ERR_BUSY, or possibly an error.
	}

	int set_option(ENetSocketOption p_option, int p_value) {
		return -1;
	}

	void close() {
		for (Map<String, Ref<PacketPeerDTLS> >::Element *E = peers.front(); E; E = E->next()) {
			E->get()->disconnect_from_peer();
		}
		peers.clear();
		udp_server->stop();
		server->stop();
	}
};

static enet_uint32 timeBase = 0;

int enet_initialize(void) {

	return 0;
}

void enet_deinitialize(void) {
}

enet_uint32 enet_host_random_seed(void) {

	return (enet_uint32)OS::get_singleton()->get_unix_time();
}

enet_uint32 enet_time_get(void) {

	return OS::get_singleton()->get_ticks_msec() - timeBase;
}

void enet_time_set(enet_uint32 newTimeBase) {

	timeBase = OS::get_singleton()->get_ticks_msec() - newTimeBase;
}

int enet_address_set_host(ENetAddress *address, const char *name) {

	IP_Address ip = IP::get_singleton()->resolve_hostname(name);
	ERR_FAIL_COND_V(!ip.is_valid(), -1);

	enet_address_set_ip(address, ip.get_ipv6(), 16);
	return 0;
}

void enet_address_set_ip(ENetAddress *address, const uint8_t *ip, size_t size) {

	int len = size > 16 ? 16 : size;
	memset(address->host, 0, 16);
	memcpy(address->host, ip, len);
}

int enet_address_get_host_ip(const ENetAddress *address, char *name, size_t nameLength) {

	return -1;
}

int enet_address_get_host(const ENetAddress *address, char *name, size_t nameLength) {

	return -1;
}

ENetSocket enet_socket_create(ENetSocketType type) {

	ENetUDP *socket = memnew(ENetUDP);

	return socket;
}

void enet_host_dtls_server_setup(ENetHost *host, void *p_key, void *p_cert) {
	ENetUDP *sock = (ENetUDP *)host->socket;
	host->socket = memnew(ENetDTLSServer(sock, Ref<CryptoKey>((CryptoKey *)p_key), Ref<X509Certificate>((X509Certificate *)p_cert)));
	memdelete(sock);
}

void enet_host_dtls_client_setup(ENetHost *host, void *p_cert, uint8_t p_verify, const char *p_for_hostname) {
	ENetUDP *sock = (ENetUDP *)host->socket;
	host->socket = memnew(ENetDTLSClient(sock, Ref<X509Certificate>((X509Certificate *)p_cert), p_verify, String(p_for_hostname)));
	memdelete(sock);
}

void enet_host_refuse_new_connections(ENetHost *host, int p_refuse) {
	ERR_FAIL_COND(!host->socket);
	((ENetGodotSocket *)host->socket)->set_refuse_new_connections(p_refuse);
}

int enet_socket_bind(ENetSocket socket, const ENetAddress *address) {

	IP_Address ip;
	if (address->wildcard) {
		ip = IP_Address("*");
	} else {
		ip.set_ipv6(address->host);
	}

	ENetGodotSocket *sock = (ENetGodotSocket *)socket;
	if (sock->bind(ip, address->port) != OK) {
		return -1;
	}
	return 0;
}

void enet_socket_destroy(ENetSocket socket) {
	ENetGodotSocket *sock = (ENetGodotSocket *)socket;
	sock->close();
	memdelete(sock);
}

int enet_socket_send(ENetSocket socket, const ENetAddress *address, const ENetBuffer *buffers, size_t bufferCount) {

	ERR_FAIL_COND_V(address == NULL, -1);

	ENetGodotSocket *sock = (ENetGodotSocket *)socket;
	IP_Address dest;
	Error err;
	size_t i = 0;

	dest.set_ipv6(address->host);

	// Create a single packet.
	PoolVector<uint8_t> out;
	PoolVector<uint8_t>::Write w;
	int size = 0;
	int pos = 0;
	for (i = 0; i < bufferCount; i++) {
		size += buffers[i].dataLength;
	}

	out.resize(size);
	w = out.write();
	for (i = 0; i < bufferCount; i++) {
		memcpy(&w[pos], buffers[i].data, buffers[i].dataLength);
		pos += buffers[i].dataLength;
	}

	int sent = 0;
	err = sock->sendto((const uint8_t *)&w[0], size, sent, dest, address->port);
	if (err != OK) {

		if (err == ERR_BUSY) { // Blocking call
			return 0;
		}

		WARN_PRINT("Sending failed!");
		return -1;
	}

	return sent;
}

int enet_socket_receive(ENetSocket socket, ENetAddress *address, ENetBuffer *buffers, size_t bufferCount) {

	ERR_FAIL_COND_V(bufferCount != 1, -1);

	ENetGodotSocket *sock = (ENetGodotSocket *)socket;

	int read;
	IP_Address ip;

	Error err = sock->recvfrom((uint8_t *)buffers[0].data, buffers[0].dataLength, read, ip, address->port);
	if (err == ERR_BUSY)
		return 0;

	if (err != OK)
		return -1;

	enet_address_set_ip(address, ip.get_ipv6(), 16);

	return read;
}

// Not implemented
int enet_socket_wait(ENetSocket socket, enet_uint32 *condition, enet_uint32 timeout) {

	return 0; // do we need this function?
}

int enet_socket_get_address(ENetSocket socket, ENetAddress *address) {

	return -1; // do we need this function?
}

int enet_socketset_select(ENetSocket maxSocket, ENetSocketSet *readSet, ENetSocketSet *writeSet, enet_uint32 timeout) {

	return -1;
}

int enet_socket_listen(ENetSocket socket, int backlog) {

	return -1;
}

int enet_socket_set_option(ENetSocket socket, ENetSocketOption option, int value) {

	ENetGodotSocket *sock = (ENetGodotSocket *)socket;
	return sock->set_option(option, value);
}

int enet_socket_get_option(ENetSocket socket, ENetSocketOption option, int *value) {

	return -1;
}

int enet_socket_connect(ENetSocket socket, const ENetAddress *address) {

	return -1;
}

ENetSocket enet_socket_accept(ENetSocket socket, ENetAddress *address) {

	return NULL;
}

int enet_socket_shutdown(ENetSocket socket, ENetSocketShutdown how) {

	return -1;
}