#include "stdafx.h"
#include "Emu/Cell/lv2/sys_sync.h"
#include "Emu/Cell/Modules/sceNp.h" // for SCE_NP_PORT

#include "network_context.h"
#include "Emu/system_config.h"
#include "sys_net_helpers.h"

LOG_CHANNEL(sys_net);

// Used by RPCN to send signaling packets to RPCN server(for UDP hole punching)
s32 send_packet_from_p2p_port(const std::vector<u8>& data, const sockaddr_in& addr)
{
	s32 res{};
	auto& nc = g_fxo->get<network_context>();
	{
		std::lock_guard list_lock(nc.list_p2p_ports_mutex);
		if (nc.list_p2p_ports.contains(SCE_NP_PORT))
		{
			auto& def_port = ::at32(nc.list_p2p_ports, SCE_NP_PORT);
			res            = ::sendto(def_port.p2p_socket, reinterpret_cast<const char*>(data.data()), data.size(), 0, reinterpret_cast<const sockaddr*>(&addr), sizeof(sockaddr_in));
		}
		else
		{
			sys_net.error("send_packet_from_p2p_port: port %d not present", +SCE_NP_PORT);
		}
	}

	return res;
}

std::vector<std::vector<u8>> get_rpcn_msgs()
{
	std::vector<std::vector<u8>> msgs;
	auto& nc = g_fxo->get<network_context>();
	{
		std::lock_guard list_lock(nc.list_p2p_ports_mutex);
		if (nc.list_p2p_ports.contains(SCE_NP_PORT))
		{
			auto& def_port = ::at32(nc.list_p2p_ports, SCE_NP_PORT);
			{
				std::lock_guard lock(def_port.s_rpcn_mutex);
				msgs = std::move(def_port.rpcn_msgs);
				def_port.rpcn_msgs.clear();
			}
		}
		else
		{
			sys_net.error("get_rpcn_msgs: port %d not present", +SCE_NP_PORT);
		}
	}

	return msgs;
}

std::vector<signaling_message> get_sign_msgs()
{
	std::vector<signaling_message> msgs;
	auto& nc = g_fxo->get<network_context>();
	{
		std::lock_guard list_lock(nc.list_p2p_ports_mutex);
		if (nc.list_p2p_ports.contains(SCE_NP_PORT))
		{
			auto& def_port = ::at32(nc.list_p2p_ports, SCE_NP_PORT);
			{
				std::lock_guard lock(def_port.s_sign_mutex);
				msgs = std::move(def_port.sign_msgs);
				def_port.sign_msgs.clear();
			}
		}
		else
		{
			sys_net.error("get_sign_msgs: port %d not present", +SCE_NP_PORT);
		}
	}

	return msgs;
}

void need_network()
{
	g_fxo->need<network_context>();
	initialize_tcp_timeout_monitor();
}

void network_thread::bind_sce_np_port()
{
	std::lock_guard list_lock(list_p2p_ports_mutex);
	list_p2p_ports.emplace(std::piecewise_construct, std::forward_as_tuple(SCE_NP_PORT), std::forward_as_tuple(SCE_NP_PORT));
}

void network_thread::operator()()
{
	std::vector<std::shared_ptr<lv2_socket>> socklist;
	socklist.reserve(lv2_socket::id_count);

	s_to_awake.clear();

	::pollfd fds[lv2_socket::id_count]{};
#ifdef _WIN32
	bool connecting[lv2_socket::id_count]{};
	bool was_connecting[lv2_socket::id_count]{};
#endif

	::pollfd p2p_fd[lv2_socket::id_count]{};

	while (thread_ctrl::state() != thread_state::aborting)
	{
		// Wait with 1ms timeout
#ifdef _WIN32
		windows_poll(fds, ::size32(socklist), 1, connecting);
#else
		::poll(fds, socklist.size(), 1);
#endif

		// Check P2P sockets for incoming packets(timeout could probably be set at 0)
		{
			std::lock_guard lock(list_p2p_ports_mutex);
			std::memset(p2p_fd, 0, sizeof(p2p_fd));
			auto num_p2p_sockets = 0;
			for (const auto& p2p_port : list_p2p_ports)
			{
				p2p_fd[num_p2p_sockets].events  = POLLIN;
				p2p_fd[num_p2p_sockets].revents = 0;
				p2p_fd[num_p2p_sockets].fd      = p2p_port.second.p2p_socket;
				num_p2p_sockets++;
			}

			if (num_p2p_sockets)
			{
#ifdef _WIN32
				const auto ret_p2p = WSAPoll(p2p_fd, num_p2p_sockets, 1);
#else
				const auto ret_p2p = ::poll(p2p_fd, num_p2p_sockets, 1);
#endif
				if (ret_p2p > 0)
				{
					auto fd_index = 0;
					for (auto& p2p_port : list_p2p_ports)
					{
						if ((p2p_fd[fd_index].revents & POLLIN) == POLLIN || (p2p_fd[fd_index].revents & POLLRDNORM) == POLLRDNORM)
						{
							while (p2p_port.second.recv_data())
								;
						}
						fd_index++;
					}
				}
				else if (ret_p2p < 0)
				{
					sys_net.error("[P2P] Error poll on master P2P socket: %d", get_last_error(false));
				}
			}
		}

		std::lock_guard lock(s_nw_mutex);

		for (usz i = 0; i < socklist.size(); i++)
		{
#ifdef _WIN32
			socklist[i]->handle_events(fds[i], was_connecting[i] && !connecting[i]);
#else
			socklist[i]->handle_events(fds[i]);
#endif
		}

		s_to_awake.erase(std::unique(s_to_awake.begin(), s_to_awake.end()), s_to_awake.end());

		for (ppu_thread* ppu : s_to_awake)
		{
			network_clear_queue(*ppu);
			lv2_obj::append(ppu);
		}

		if (!s_to_awake.empty())
		{
			lv2_obj::awake_all();
		}

		s_to_awake.clear();
		socklist.clear();

		// Obtain all native active sockets
		idm::select<lv2_socket>([&](u32 id, lv2_socket& s)
			{
				if (s.get_type() == SYS_NET_SOCK_DGRAM || s.get_type() == SYS_NET_SOCK_STREAM)
				{
					socklist.emplace_back(idm::get_unlocked<lv2_socket>(id));
				}
			});

		for (usz i = 0; i < socklist.size(); i++)
		{
			auto events = socklist[i]->get_events();

			fds[i].fd = events ? socklist[i]->get_socket() : -1;
			fds[i].events =
				(events & lv2_socket::poll_t::read ? POLLIN : 0) |
				(events & lv2_socket::poll_t::write ? POLLOUT : 0) |
				0;
			fds[i].revents = 0;
#ifdef _WIN32
			const auto cur_connecting = socklist[i]->is_connecting();
			was_connecting[i] = cur_connecting;
			connecting[i] = cur_connecting;
#endif
		}
	}
}