#include "stdafx.h"
#include "sys_event.h"

#include "Emu/System.h"
#include "Emu/IdManager.h"
#include "Emu/IPC.h"

#include "Emu/Cell/ErrorCodes.h"
#include "Emu/Cell/PPUThread.h"
#include "Emu/Cell/SPUThread.h"
#include "sys_process.h"

LOG_CHANNEL(sys_event);

template<> DECLARE(ipc_manager<lv2_event_queue, u64>::g_ipc) {};

std::shared_ptr<lv2_event_queue> lv2_event_queue::find(u64 ipc_key)
{
	if (ipc_key == SYS_EVENT_QUEUE_LOCAL)
	{
		// Invalid IPC key
		return{};
	}

	return ipc_manager<lv2_event_queue, u64>::get(ipc_key);
}

bool lv2_event_queue::send(lv2_event event)
{
	std::lock_guard lock(mutex);

	if (sq.empty())
	{
		if (events.size() < this->size)
		{
			// Save event
			events.emplace_back(event);
			return true;
		}

		return false;
	}

	if (type == SYS_PPU_QUEUE)
	{
		// Store event in registers
		auto& ppu = static_cast<ppu_thread&>(*schedule<ppu_thread>(sq, protocol));

		std::tie(ppu.gpr[4], ppu.gpr[5], ppu.gpr[6], ppu.gpr[7]) = event;

		awake(&ppu);
	}
	else
	{
		// Store event in In_MBox
		auto& spu = static_cast<spu_thread&>(*sq.front());

		// TODO: use protocol?
		sq.pop_front();

		const u32 data1 = static_cast<u32>(std::get<1>(event));
		const u32 data2 = static_cast<u32>(std::get<2>(event));
		const u32 data3 = static_cast<u32>(std::get<3>(event));
		spu.ch_in_mbox.set_values(4, CELL_OK, data1, data2, data3);

		spu.state += cpu_flag::signal;
		spu.notify();
	}

	return true;
}

error_code sys_event_queue_create(vm::ptr<u32> equeue_id, vm::ptr<sys_event_queue_attribute_t> attr, u64 event_queue_key, s32 size)
{
	vm::temporary_unlock();

	sys_event.warning("sys_event_queue_create(equeue_id=*0x%x, attr=*0x%x, event_queue_key=0x%llx, size=%d)", equeue_id, attr, event_queue_key, size);

	if (size <= 0 || size > 127)
	{
		return CELL_EINVAL;
	}

	const u32 protocol = attr->protocol;

	if (protocol != SYS_SYNC_FIFO && protocol != SYS_SYNC_PRIORITY)
	{
		sys_event.error("sys_event_queue_create(): unknown protocol (0x%x)", protocol);
		return CELL_EINVAL;
	}

	const u32 type = attr->type;

	if (type != SYS_PPU_QUEUE && type != SYS_SPU_QUEUE)
	{
		sys_event.error("sys_event_queue_create(): unknown type (0x%x)", type);
		return CELL_EINVAL;
	}

	auto queue = std::make_shared<lv2_event_queue>(protocol, type, attr->name_u64, event_queue_key, size);

	if (event_queue_key == SYS_EVENT_QUEUE_LOCAL)
	{
		// Not an IPC queue
		if (const u32 _id = idm::import_existing<lv2_obj, lv2_event_queue>(std::move(queue)))
		{
			*equeue_id = _id;
			return CELL_OK;
		}

		return CELL_EAGAIN;
	}

	// Create IPC queue
	if (!ipc_manager<lv2_event_queue, u64>::add(event_queue_key, [&]() -> std::shared_ptr<lv2_event_queue>
	{
		if (const u32 _id = idm::import_existing<lv2_obj, lv2_event_queue>(queue))
		{
			*equeue_id = _id;
			return std::move(queue);
		}

		return nullptr;
	}))
	{
		return CELL_EEXIST;
	}

	if (queue)
	{
		return CELL_EAGAIN;
	}

	return CELL_OK;
}

error_code sys_event_queue_destroy(ppu_thread& ppu, u32 equeue_id, s32 mode)
{
	vm::temporary_unlock(ppu);

	sys_event.warning("sys_event_queue_destroy(equeue_id=0x%x, mode=%d)", equeue_id, mode);

	if (mode && mode != SYS_EVENT_QUEUE_DESTROY_FORCE)
	{
		return CELL_EINVAL;
	}

	const auto queue = idm::withdraw<lv2_obj, lv2_event_queue>(equeue_id, [&](lv2_event_queue& queue) -> CellError
	{
		std::lock_guard lock(queue.mutex);

		if (!mode && !queue.sq.empty())
		{
			return CELL_EBUSY;
		}

		return {};
	});

	if (!queue)
	{
		return CELL_ESRCH;
	}

	if (queue.ret)
	{
		return queue.ret;
	}

	if (mode == SYS_EVENT_QUEUE_DESTROY_FORCE)
	{
		std::lock_guard lock(queue->mutex);

		if (queue->type == SYS_PPU_QUEUE)
		{
			for (auto cpu : queue->sq)
			{
				static_cast<ppu_thread&>(*cpu).gpr[3] = CELL_ECANCELED;
				queue->append(cpu);
			}

			if (!queue->sq.empty())
			{
				lv2_obj::awake_all();
			}
		}
		else
		{
			for (auto cpu : queue->sq)
			{
				static_cast<spu_thread&>(*cpu).ch_in_mbox.set_values(1, CELL_ECANCELED);
				cpu->state += cpu_flag::signal;
				cpu->notify();
			}
		}
	}

	return CELL_OK;
}

error_code sys_event_queue_tryreceive(ppu_thread& ppu, u32 equeue_id, vm::ptr<sys_event_t> event_array, s32 size, vm::ptr<u32> number)
{
	vm::temporary_unlock(ppu);

	sys_event.trace("sys_event_queue_tryreceive(equeue_id=0x%x, event_array=*0x%x, size=%d, number=*0x%x)", equeue_id, event_array, size, number);

	const auto queue = idm::get<lv2_obj, lv2_event_queue>(equeue_id);

	if (!queue)
	{
		return CELL_ESRCH;
	}

	if (queue->type != SYS_PPU_QUEUE)
	{
		return CELL_EINVAL;
	}

	std::lock_guard lock(queue->mutex);

	s32 count = 0;

	while (queue->sq.empty() && count < size && !queue->events.empty())
	{
		auto& dest = event_array[count++];
		auto event = queue->events.front();
		queue->events.pop_front();

		std::tie(dest.source, dest.data1, dest.data2, dest.data3) = event;
	}

	*number = count;

	return CELL_OK;
}

error_code sys_event_queue_receive(ppu_thread& ppu, u32 equeue_id, vm::ptr<sys_event_t> dummy_event, u64 timeout)
{
	vm::temporary_unlock(ppu);

	sys_event.trace("sys_event_queue_receive(equeue_id=0x%x, *0x%x, timeout=0x%llx)", equeue_id, dummy_event, timeout);

	ppu.gpr[3] = CELL_OK;

	const auto queue = idm::get<lv2_obj, lv2_event_queue>(equeue_id, [&](lv2_event_queue& queue) -> CellError
	{
		if (queue.type != SYS_PPU_QUEUE)
		{
			return CELL_EINVAL;
		}

		std::lock_guard lock(queue.mutex);

		if (queue.events.empty())
		{
			queue.sq.emplace_back(&ppu);
			queue.sleep(ppu, timeout);
			return CELL_EBUSY;
		}

		std::tie(ppu.gpr[4], ppu.gpr[5], ppu.gpr[6], ppu.gpr[7]) = queue.events.front();
		queue.events.pop_front();
		return {};
	});

	if (!queue)
	{
		return CELL_ESRCH;
	}

	if (queue.ret)
	{
		if (queue.ret != CELL_EBUSY)
		{
			return queue.ret;
		}
	}
	else
	{
		return CELL_OK;
	}

	// If cancelled, gpr[3] will be non-zero. Other registers must contain event data.
	while (!ppu.state.test_and_reset(cpu_flag::signal))
	{
		if (ppu.is_stopped())
		{
			return 0;
		}

		if (timeout)
		{
			if (lv2_obj::wait_timeout(timeout, &ppu))
			{
				std::lock_guard lock(queue->mutex);

				if (!queue->unqueue(queue->sq, &ppu))
				{
					timeout = 0;
					continue;
				}

				ppu.gpr[3] = CELL_ETIMEDOUT;
				break;
			}
		}
		else
		{
			thread_ctrl::wait();
		}
	}

	return not_an_error(ppu.gpr[3]);
}

error_code sys_event_queue_drain(ppu_thread& ppu, u32 equeue_id)
{
	vm::temporary_unlock(ppu);

	sys_event.trace("sys_event_queue_drain(equeue_id=0x%x)", equeue_id);

	const auto queue = idm::check<lv2_obj, lv2_event_queue>(equeue_id, [&](lv2_event_queue& queue)
	{
		std::lock_guard lock(queue.mutex);

		queue.events.clear();
	});

	if (!queue)
	{
		return CELL_ESRCH;
	}

	return CELL_OK;
}

error_code sys_event_port_create(vm::ptr<u32> eport_id, s32 port_type, u64 name)
{
	vm::temporary_unlock();

	sys_event.warning("sys_event_port_create(eport_id=*0x%x, port_type=%d, name=0x%llx)", eport_id, port_type, name);

	if (port_type != SYS_EVENT_PORT_LOCAL && port_type != 3)
	{
		sys_event.error("sys_event_port_create(): unknown port type (%d)", port_type);
		return CELL_EINVAL;
	}

	if (const u32 id = idm::make<lv2_obj, lv2_event_port>(port_type, name))
	{
		*eport_id = id;
		return CELL_OK;
	}

	return CELL_EAGAIN;
}

error_code sys_event_port_destroy(ppu_thread& ppu, u32 eport_id)
{
	vm::temporary_unlock(ppu);

	sys_event.warning("sys_event_port_destroy(eport_id=0x%x)", eport_id);

	const auto port = idm::withdraw<lv2_obj, lv2_event_port>(eport_id, [](lv2_event_port& port) -> CellError
	{
		if (!port.queue.expired())
		{
			return CELL_EISCONN;
		}

		return {};
	});

	if (!port)
	{
		return CELL_ESRCH;
	}

	if (port.ret)
	{
		return port.ret;
	}

	return CELL_OK;
}

error_code sys_event_port_connect_local(u32 eport_id, u32 equeue_id)
{
	vm::temporary_unlock();

	sys_event.warning("sys_event_port_connect_local(eport_id=0x%x, equeue_id=0x%x)", eport_id, equeue_id);

	std::lock_guard lock(id_manager::g_mutex);

	const auto port = idm::check_unlocked<lv2_obj, lv2_event_port>(eport_id);

	if (!port || !idm::check_unlocked<lv2_obj, lv2_event_queue>(equeue_id))
	{
		return CELL_ESRCH;
	}

	if (port->type != SYS_EVENT_PORT_LOCAL)
	{
		return CELL_EINVAL;
	}

	if (!port->queue.expired())
	{
		return CELL_EISCONN;
	}

	port->queue = idm::get_unlocked<lv2_obj, lv2_event_queue>(equeue_id);

	return CELL_OK;
}

error_code sys_event_port_connect_ipc(ppu_thread& ppu, u32 eport_id, u64 ipc_key)
{
	vm::temporary_unlock(ppu);

	sys_event.warning("sys_event_port_connect_ipc(eport_id=0x%x, ipc_key=0x%x)", eport_id, ipc_key);

	if (ipc_key == 0)
	{
		return CELL_EINVAL;
	}

	auto queue = lv2_event_queue::find(ipc_key);

	std::lock_guard lock(id_manager::g_mutex);

	const auto port = idm::check_unlocked<lv2_obj, lv2_event_port>(eport_id);

	if (!port || !queue)
	{
		return CELL_ESRCH;
	}

	if (port->type != 3)
	{
		return CELL_EINVAL;
	}

	if (!port->queue.expired())
	{
		return CELL_EISCONN;
	}

	port->queue = std::move(queue);

	return CELL_OK;
}

error_code sys_event_port_disconnect(ppu_thread& ppu, u32 eport_id)
{
	vm::temporary_unlock(ppu);

	sys_event.warning("sys_event_port_disconnect(eport_id=0x%x)", eport_id);

	std::lock_guard lock(id_manager::g_mutex);

	const auto port = idm::check_unlocked<lv2_obj, lv2_event_port>(eport_id);

	if (!port)
	{
		return CELL_ESRCH;
	}

	if (port->queue.expired())
	{
		return CELL_ENOTCONN;
	}

	// TODO: return CELL_EBUSY if necessary (can't detect the condition)

	port->queue.reset();

	return CELL_OK;
}

error_code sys_event_port_send(u32 eport_id, u64 data1, u64 data2, u64 data3)
{
	vm::temporary_unlock();

	sys_event.trace("sys_event_port_send(eport_id=0x%x, data1=0x%llx, data2=0x%llx, data3=0x%llx)", eport_id, data1, data2, data3);

	const auto port = idm::get<lv2_obj, lv2_event_port>(eport_id, [&](lv2_event_port& port) -> CellError
	{
		if (const auto queue = port.queue.lock())
		{
			const u64 source = port.name ? port.name : (s64{process_getpid()} << 32) | u64{eport_id};

			if (queue->send(source, data1, data2, data3))
			{
				return {};
			}

			return CELL_EBUSY;
		}

		return CELL_ENOTCONN;
	});

	if (!port)
	{
		return CELL_ESRCH;
	}

	if (port.ret)
	{
		if (port.ret == CELL_EBUSY)
		{
			return not_an_error(CELL_EBUSY);
		}

		return port.ret;
	}

	return CELL_OK;
}