#include "stdafx.h" #include "Emu/System.h" #include "Emu/IdManager.h" #include "Emu/Cell/PPUModule.h" #include "pad_thread.h" #include "cellPad.h" extern logs::channel sys_io; s32 cellPadInit(u32 max_connect) { sys_io.warning("cellPadInit(max_connect=%d)", max_connect); const auto handler = fxm::import(Emu.GetCallbacks().get_pad_handler); if (!handler) return CELL_PAD_ERROR_ALREADY_INITIALIZED; handler->Init(std::min(max_connect, CELL_PAD_MAX_PORT_NUM)); return CELL_OK; } s32 cellPadEnd() { sys_io.notice("cellPadEnd()"); if (!fxm::remove()) return CELL_PAD_ERROR_UNINITIALIZED; return CELL_OK; } s32 cellPadClearBuf(u32 port_no) { sys_io.trace("cellPadClearBuf(port_no=%d)", port_no); const auto handler = fxm::get(); if (!handler) return CELL_PAD_ERROR_UNINITIALIZED; const PadInfo& rinfo = handler->GetInfo(); if (port_no >= rinfo.max_connect) return CELL_PAD_ERROR_INVALID_PARAMETER; //Set 'm_buffer_cleared' to force a resend of everything //might as well also reset everything in our pad 'buffer' to nothing as well const auto& pads = handler->GetPads(); const auto pad = pads[port_no]; if (!(pad->m_port_status & CELL_PAD_STATUS_CONNECTED)) return CELL_PAD_ERROR_NO_DEVICE; pad->m_buffer_cleared = true; pad->m_analog_left_x = pad->m_analog_left_y = pad->m_analog_right_x = pad->m_analog_right_y = 128; pad->m_digital_1 = pad->m_digital_2 = 0; pad->m_press_right = pad->m_press_left = pad->m_press_up = pad->m_press_down = 0; pad->m_press_triangle = pad->m_press_circle = pad->m_press_cross = pad->m_press_square = 0; pad->m_press_L1 = pad->m_press_L2 = pad->m_press_R1 = pad->m_press_R2 = 0; //~399 on sensor y is a level non moving controller pad->m_sensor_y = 399; pad->m_sensor_x = pad->m_sensor_z = pad->m_sensor_g = 512; return CELL_OK; } s32 cellPadGetData(u32 port_no, vm::ptr data) { sys_io.trace("cellPadGetData(port_no=%d, data=*0x%x)", port_no, data); const auto handler = fxm::get(); if (!handler) return CELL_PAD_ERROR_UNINITIALIZED; const PadInfo& rinfo = handler->GetInfo(); if (port_no >= rinfo.max_connect) return CELL_PAD_ERROR_INVALID_PARAMETER; const auto& pads = handler->GetPads(); const auto pad = pads[port_no]; //We have a choice here of NO_DEVICE or READ_FAILED...lets try no device for now if (!(pad->m_port_status & CELL_PAD_STATUS_CONNECTED)) return CELL_PAD_ERROR_NO_DEVICE; u16 d1Initial, d2Initial; d1Initial = pad->m_digital_1; d2Initial = pad->m_digital_2; bool btnChanged = false; for(Button& button : pad->m_buttons) { //here we check btns, and set pad accordingly, //if something changed, set btnChanged if (button.m_offset == CELL_PAD_BTN_OFFSET_DIGITAL1) { if (button.m_pressed) pad->m_digital_1 |= button.m_outKeyCode; else pad->m_digital_1 &= ~button.m_outKeyCode; switch (button.m_outKeyCode) { case CELL_PAD_CTRL_LEFT: if (pad->m_press_left != button.m_value) btnChanged = true; pad->m_press_left = button.m_value; break; case CELL_PAD_CTRL_DOWN: if (pad->m_press_down != button.m_value) btnChanged = true; pad->m_press_down = button.m_value; break; case CELL_PAD_CTRL_RIGHT: if (pad->m_press_right != button.m_value) btnChanged = true; pad->m_press_right = button.m_value; break; case CELL_PAD_CTRL_UP: if (pad->m_press_up != button.m_value) btnChanged = true; pad->m_press_up = button.m_value; break; //These arent pressure btns case CELL_PAD_CTRL_R3: case CELL_PAD_CTRL_L3: case CELL_PAD_CTRL_START: case CELL_PAD_CTRL_SELECT: default: break; } } else if (button.m_offset == CELL_PAD_BTN_OFFSET_DIGITAL2) { if (button.m_pressed) pad->m_digital_2 |= button.m_outKeyCode; else pad->m_digital_2 &= ~button.m_outKeyCode; switch (button.m_outKeyCode) { case CELL_PAD_CTRL_SQUARE: if (pad->m_press_square != button.m_value) btnChanged = true; pad->m_press_square = button.m_value; break; case CELL_PAD_CTRL_CROSS: if (pad->m_press_cross != button.m_value) btnChanged = true; pad->m_press_cross = button.m_value; break; case CELL_PAD_CTRL_CIRCLE: if (pad->m_press_circle != button.m_value) btnChanged = true; pad->m_press_circle = button.m_value; break; case CELL_PAD_CTRL_TRIANGLE: if (pad->m_press_triangle != button.m_value) btnChanged = true; pad->m_press_triangle = button.m_value; break; case CELL_PAD_CTRL_R1: if (pad->m_press_R1 != button.m_value) btnChanged = true; pad->m_press_R1 = button.m_value; break; case CELL_PAD_CTRL_L1: if (pad->m_press_L1 != button.m_value) btnChanged = true; pad->m_press_L1 = button.m_value; break; case CELL_PAD_CTRL_R2: if (pad->m_press_R2 != button.m_value) btnChanged = true; pad->m_press_R2 = button.m_value; break; case CELL_PAD_CTRL_L2: if (pad->m_press_L2 != button.m_value) btnChanged = true; pad->m_press_L2 = button.m_value; break; default: break; } } if(button.m_flush) { button.m_pressed = false; button.m_flush = false; button.m_value = 0; } } for (const AnalogStick& stick : pad->m_sticks) { switch (stick.m_offset) { case CELL_PAD_BTN_OFFSET_ANALOG_LEFT_X: if (pad->m_analog_left_x != stick.m_value) btnChanged = true; pad->m_analog_left_x = stick.m_value; break; case CELL_PAD_BTN_OFFSET_ANALOG_LEFT_Y: if (pad->m_analog_left_y != stick.m_value) btnChanged = true; pad->m_analog_left_y = stick.m_value; break; case CELL_PAD_BTN_OFFSET_ANALOG_RIGHT_X: if (pad->m_analog_right_x != stick.m_value) btnChanged = true; pad->m_analog_right_x = stick.m_value; break; case CELL_PAD_BTN_OFFSET_ANALOG_RIGHT_Y: if (pad->m_analog_right_y != stick.m_value) btnChanged = true; pad->m_analog_right_y = stick.m_value; break; default: break; } } for (const AnalogSensor& sensor : pad->m_sensors) { switch (sensor.m_offset) { case CELL_PAD_BTN_OFFSET_SENSOR_X: if (pad->m_sensor_x != sensor.m_value) btnChanged = true; pad->m_sensor_x = sensor.m_value; break; case CELL_PAD_BTN_OFFSET_SENSOR_Y: if (pad->m_sensor_y != sensor.m_value) btnChanged = true; pad->m_sensor_y = sensor.m_value; break; case CELL_PAD_BTN_OFFSET_SENSOR_Z: if (pad->m_sensor_z != sensor.m_value) btnChanged = true; pad->m_sensor_z = sensor.m_value; break; case CELL_PAD_BTN_OFFSET_SENSOR_G: if (pad->m_sensor_g != sensor.m_value) btnChanged = true; pad->m_sensor_g = sensor.m_value; break; default: break; } } if (d1Initial != pad->m_digital_1 || d2Initial != pad->m_digital_2) { btnChanged = true; } // the real hardware only fills the buffer up to "len" elements (16 bit each) if (pad->m_port_setting & CELL_PAD_SETTING_SENSOR_ON) { // report back new data every ~10 ms even if the input doesn't change // this is observed behaviour when using a Dualshock 3 controller static std::chrono::time_point last_update[CELL_PAD_MAX_PORT_NUM] = { }; const std::chrono::time_point now = steady_clock::now(); if (btnChanged || pad->m_buffer_cleared || (std::chrono::duration_cast(now - last_update[port_no]).count() >= 10)) { data->len = CELL_PAD_LEN_CHANGE_SENSOR_ON; last_update[port_no] = now; } else { data->len = CELL_PAD_LEN_NO_CHANGE; } } else if (btnChanged || pad->m_buffer_cleared) { // only give back valid data if a controller state changed data->len = (pad->m_port_setting & CELL_PAD_SETTING_PRESS_ON) ? CELL_PAD_LEN_CHANGE_PRESS_ON : CELL_PAD_LEN_CHANGE_DEFAULT; } else { // report no state changes data->len = CELL_PAD_LEN_NO_CHANGE; } pad->m_buffer_cleared = false; // only update parts of the output struct depending on the controller setting if (data->len > CELL_PAD_LEN_NO_CHANGE) { memset(data->button, 0, sizeof(data->button)); data->button[0] = 0x0; // always 0 // bits 15-8 reserved, 7-4 = 0x7, 3-0: data->len/2; data->button[1] = (0x7 << 4) | std::min(data->len / 2, 15); data->button[CELL_PAD_BTN_OFFSET_DIGITAL1] = pad->m_digital_1; data->button[CELL_PAD_BTN_OFFSET_DIGITAL2] = pad->m_digital_2; data->button[CELL_PAD_BTN_OFFSET_ANALOG_RIGHT_X] = pad->m_analog_right_x; data->button[CELL_PAD_BTN_OFFSET_ANALOG_RIGHT_Y] = pad->m_analog_right_y; data->button[CELL_PAD_BTN_OFFSET_ANALOG_LEFT_X] = pad->m_analog_left_x; data->button[CELL_PAD_BTN_OFFSET_ANALOG_LEFT_Y] = pad->m_analog_left_y; data->button[CELL_PAD_BTN_OFFSET_PRESS_RIGHT] = pad->m_press_right; data->button[CELL_PAD_BTN_OFFSET_PRESS_LEFT] = pad->m_press_left; data->button[CELL_PAD_BTN_OFFSET_PRESS_UP] = pad->m_press_up; data->button[CELL_PAD_BTN_OFFSET_PRESS_DOWN] = pad->m_press_down; } if (data->len >= CELL_PAD_LEN_CHANGE_PRESS_ON) { data->button[CELL_PAD_BTN_OFFSET_PRESS_TRIANGLE] = pad->m_press_triangle; data->button[CELL_PAD_BTN_OFFSET_PRESS_CIRCLE] = pad->m_press_circle; data->button[CELL_PAD_BTN_OFFSET_PRESS_CROSS] = pad->m_press_cross; data->button[CELL_PAD_BTN_OFFSET_PRESS_SQUARE] = pad->m_press_square; data->button[CELL_PAD_BTN_OFFSET_PRESS_L1] = pad->m_press_L1; data->button[CELL_PAD_BTN_OFFSET_PRESS_L2] = pad->m_press_L2; data->button[CELL_PAD_BTN_OFFSET_PRESS_R1] = pad->m_press_R1; data->button[CELL_PAD_BTN_OFFSET_PRESS_R2] = pad->m_press_R2; } if (data->len == CELL_PAD_LEN_CHANGE_SENSOR_ON) { data->button[CELL_PAD_BTN_OFFSET_SENSOR_X] = pad->m_sensor_x; data->button[CELL_PAD_BTN_OFFSET_SENSOR_Y] = pad->m_sensor_y; data->button[CELL_PAD_BTN_OFFSET_SENSOR_Z] = pad->m_sensor_z; data->button[CELL_PAD_BTN_OFFSET_SENSOR_G] = pad->m_sensor_g; } return CELL_OK; } s32 cellPadPeriphGetInfo(vm::ptr info) { sys_io.trace("cellPadPeriphGetInfo(info=*0x%x)", info); const auto handler = fxm::get(); if (!handler) return CELL_PAD_ERROR_UNINITIALIZED; const PadInfo& rinfo = handler->GetInfo(); std::memset(info.get_ptr(), 0, sizeof(CellPadPeriphInfo)); info->max_connect = rinfo.max_connect; info->now_connect = rinfo.now_connect; info->system_info = rinfo.system_info; const auto& pads = handler->GetPads(); // TODO: Support other types of controllers for (u32 i = 0; i < CELL_PAD_MAX_PORT_NUM; ++i) { if (i >= pads.size()) break; info->port_status[i] = pads[i]->m_port_status; pads[i]->m_port_status &= ~CELL_PAD_STATUS_ASSIGN_CHANGES; info->port_setting[i] = pads[i]->m_port_setting; info->device_capability[i] = pads[i]->m_device_capability; info->device_type[i] = pads[i]->m_device_type; info->pclass_type[i] = CELL_PAD_PCLASS_TYPE_STANDARD; info->pclass_profile[i] = 0x0; } return CELL_OK; } s32 cellPadPeriphGetData(u32 port_no, vm::ptr data) { sys_io.trace("cellPadPeriphGetData(port_no=%d, data=*0x%x)", port_no, data); const auto handler = fxm::get(); if (!handler) return CELL_PAD_ERROR_UNINITIALIZED; const PadInfo& rinfo = handler->GetInfo(); if (port_no >= rinfo.max_connect) return CELL_PAD_ERROR_INVALID_PARAMETER; const auto& pads = handler->GetPads(); const auto pad = pads[port_no]; if (!(pad->m_port_status & CELL_PAD_STATUS_CONNECTED)) return CELL_PAD_ERROR_NO_DEVICE; // todo: support for 'unique' controllers, which goes in offsets 24+ in padData data->pclass_type = CELL_PAD_PCLASS_TYPE_STANDARD; data->pclass_profile = 0x0; return cellPadGetData(port_no, vm::get_addr(&data->cellpad_data)); } s32 cellPadGetRawData(u32 port_no, vm::ptr data) { fmt::throw_exception("Unimplemented" HERE); } s32 cellPadGetDataExtra(u32 port_no, vm::ptr device_type, vm::ptr data) { sys_io.trace("cellPadGetDataExtra(port_no=%d, device_type=*0x%x, device_type=*0x%x)", port_no, device_type, data); const auto handler = fxm::get(); if (!handler) return CELL_PAD_ERROR_UNINITIALIZED; const PadInfo& rinfo = handler->GetInfo(); if (port_no >= rinfo.max_connect) return CELL_PAD_ERROR_INVALID_PARAMETER; const auto& pads = handler->GetPads(); const auto pad = pads[port_no]; if (!(pad->m_port_status & CELL_PAD_STATUS_CONNECTED)) return CELL_PAD_ERROR_NO_DEVICE; // TODO: This is used just to get data from a BD/CEC remote, // but if the port isnt a remote, device type is set to 0 and just regular cellPadGetData is returned *device_type = 0; // set BD data before just incase data->button[24] = 0x0; data->button[25] = 0x0; return cellPadGetData(port_no, data); } s32 cellPadSetActDirect(u32 port_no, vm::ptr param) { sys_io.trace("cellPadSetActDirect(port_no=%d, param=*0x%x)", port_no, param); const auto handler = fxm::get(); if (!handler) return CELL_PAD_ERROR_UNINITIALIZED; const PadInfo& rinfo = handler->GetInfo(); if (port_no >= rinfo.max_connect) return CELL_PAD_ERROR_INVALID_PARAMETER; const auto& pads = handler->GetPads(); const auto pad = pads[port_no]; if (!(pad->m_port_status & CELL_PAD_STATUS_CONNECTED)) return CELL_PAD_ERROR_NO_DEVICE; handler->SetRumble(port_no, param->motor[1], param->motor[0] > 0); return CELL_OK; } s32 cellPadGetInfo(vm::ptr info) { sys_io.trace("cellPadGetInfo(info=*0x%x)", info); const auto handler = fxm::get(); if (!handler) return CELL_PAD_ERROR_UNINITIALIZED; std::memset(info.get_ptr(), 0, sizeof(CellPadInfo)); const PadInfo& rinfo = handler->GetInfo(); info->max_connect = rinfo.max_connect; info->now_connect = rinfo.now_connect; info->system_info = rinfo.system_info; const auto& pads = handler->GetPads(); for (u32 i=0; i= pads.size()) break; info->status[i] = pads[i]->m_port_status; pads[i]->m_port_status &= ~CELL_PAD_STATUS_ASSIGN_CHANGES; info->product_id[i] = 0x0268; info->vendor_id[i] = 0x054C; } return CELL_OK; } s32 cellPadGetInfo2(vm::ptr info) { sys_io.trace("cellPadGetInfo2(info=*0x%x)", info); const auto handler = fxm::get(); if (!handler) return CELL_PAD_ERROR_UNINITIALIZED; std::memset(info.get_ptr(), 0, sizeof(CellPadInfo2)); const PadInfo& rinfo = handler->GetInfo(); info->max_connect = rinfo.max_connect; info->now_connect = rinfo.now_connect; info->system_info = rinfo.system_info; const auto& pads = handler->GetPads(); for (u32 i=0; i= pads.size()) break; info->port_status[i] = pads[i]->m_port_status; pads[i]->m_port_status &= ~CELL_PAD_STATUS_ASSIGN_CHANGES; info->port_setting[i] = pads[i]->m_port_setting; info->device_capability[i] = pads[i]->m_device_capability; info->device_type[i] = pads[i]->m_device_type; } return CELL_OK; } s32 cellPadGetCapabilityInfo(u32 port_no, vm::ptr info) { sys_io.trace("cellPadGetCapabilityInfo(port_no=%d, data_addr:=0x%x)", port_no, info.addr()); const auto handler = fxm::get(); if (!handler) return CELL_PAD_ERROR_UNINITIALIZED; const PadInfo& rinfo = handler->GetInfo(); if (port_no >= rinfo.max_connect) return CELL_PAD_ERROR_INVALID_PARAMETER; const auto& pads = handler->GetPads(); const auto pad = pads[port_no]; if (!(pad->m_port_status & CELL_PAD_STATUS_CONNECTED)) return CELL_PAD_ERROR_NO_DEVICE; //Should return the same as device capability mask, psl1ght has it backwards in pad->h info->info[0] = pad->m_device_capability; return CELL_OK; } s32 cellPadSetPortSetting(u32 port_no, u32 port_setting) { sys_io.trace("cellPadSetPortSetting(port_no=%d, port_setting=0x%x)", port_no, port_setting); const auto handler = fxm::get(); if (!handler) return CELL_PAD_ERROR_UNINITIALIZED; const PadInfo& rinfo = handler->GetInfo(); if (port_no >= rinfo.max_connect) return CELL_PAD_ERROR_INVALID_PARAMETER; const auto& pads = handler->GetPads(); const auto pad = pads[port_no]; pad->m_port_setting = port_setting; if (!(pad->m_port_status & CELL_PAD_STATUS_CONNECTED)) return CELL_PAD_ERROR_NO_DEVICE; return CELL_OK; } s32 cellPadInfoPressMode(u32 port_no) { sys_io.trace("cellPadInfoPressMode(port_no=%d)", port_no); const auto handler = fxm::get(); if (!handler) return CELL_PAD_ERROR_UNINITIALIZED; const PadInfo& rinfo = handler->GetInfo(); if (port_no >= rinfo.max_connect) return CELL_PAD_ERROR_INVALID_PARAMETER; const auto& pads = handler->GetPads(); const auto pad = pads[port_no]; if (!(pad->m_port_status & CELL_PAD_STATUS_CONNECTED)) return CELL_PAD_ERROR_NO_DEVICE; return (pad->m_device_capability & CELL_PAD_CAPABILITY_PRESS_MODE) > 0; } s32 cellPadInfoSensorMode(u32 port_no) { sys_io.trace("cellPadInfoSensorMode(port_no=%d)", port_no); const auto handler = fxm::get(); if (!handler) return CELL_PAD_ERROR_UNINITIALIZED; const PadInfo& rinfo = handler->GetInfo(); if (port_no >= rinfo.max_connect) return CELL_PAD_ERROR_INVALID_PARAMETER; const auto& pads = handler->GetPads(); const auto pad = pads[port_no]; if (!(pad->m_port_status & CELL_PAD_STATUS_CONNECTED)) return CELL_PAD_ERROR_NO_DEVICE; return (pad->m_device_capability & CELL_PAD_CAPABILITY_SENSOR_MODE) > 0; } s32 cellPadSetPressMode(u32 port_no, u32 mode) { sys_io.trace("cellPadSetPressMode(port_no=%d, mode=%d)", port_no, mode); const auto handler = fxm::get(); if (!handler) return CELL_PAD_ERROR_UNINITIALIZED; if (mode != 0 && mode != 1) return CELL_PAD_ERROR_INVALID_PARAMETER; const PadInfo& rinfo = handler->GetInfo(); if (port_no >= rinfo.max_connect) return CELL_PAD_ERROR_INVALID_PARAMETER; const auto& pads = handler->GetPads(); const auto pad = pads[port_no]; if (mode) pad->m_port_setting |= CELL_PAD_SETTING_PRESS_ON; else pad->m_port_setting &= ~CELL_PAD_SETTING_PRESS_ON; if (!(pad->m_port_status & CELL_PAD_STATUS_CONNECTED)) return CELL_PAD_ERROR_NO_DEVICE; return CELL_OK; } s32 cellPadSetSensorMode(u32 port_no, u32 mode) { sys_io.trace("cellPadSetSensorMode(port_no=%d, mode=%d)", port_no, mode); const auto handler = fxm::get(); if (!handler) return CELL_PAD_ERROR_UNINITIALIZED; if (mode != 0 && mode != 1) return CELL_PAD_ERROR_INVALID_PARAMETER; const PadInfo& rinfo = handler->GetInfo(); if (port_no >= rinfo.max_connect) return CELL_PAD_ERROR_INVALID_PARAMETER; const auto& pads = handler->GetPads(); const auto pad = pads[port_no]; if (mode) pad->m_port_setting |= CELL_PAD_SETTING_SENSOR_ON; else pad->m_port_setting &= ~CELL_PAD_SETTING_SENSOR_ON; if (!(pad->m_port_status & CELL_PAD_STATUS_CONNECTED)) return CELL_PAD_ERROR_NO_DEVICE; return CELL_OK; } s32 cellPadLddRegisterController() { sys_io.todo("cellPadLddRegisterController()"); const auto handler = fxm::get(); if (!handler) return CELL_PAD_ERROR_UNINITIALIZED; return CELL_OK; } s32 cellPadLddDataInsert(s32 handle, vm::ptr data) { sys_io.todo("cellPadLddDataInsert(handle=%d, data=*0x%x)", handle, data); const auto handler = fxm::get(); if (!handler) return CELL_PAD_ERROR_UNINITIALIZED; return CELL_OK; } s32 cellPadLddGetPortNo(s32 handle) { sys_io.todo("cellPadLddGetPortNo(handle=%d)", handle); if (handle < 0) return CELL_PAD_ERROR_INVALID_PARAMETER; const auto handler = fxm::get(); if (!handler) return CELL_PAD_ERROR_UNINITIALIZED; // CELL_OK would return port 0 (Nascar [BLUS30932] stopped looking for custom controllers after a few seconds, fixing normal input) return CELL_PAD_ERROR_EBUSY; } s32 cellPadLddUnregisterController(s32 handle) { sys_io.todo("cellPadLddUnregisterController(handle=%d)", handle); const auto handler = fxm::get(); if (!handler) return CELL_PAD_ERROR_UNINITIALIZED; return CELL_OK; } void cellPad_init() { REG_FUNC(sys_io, cellPadInit); REG_FUNC(sys_io, cellPadEnd); REG_FUNC(sys_io, cellPadClearBuf); REG_FUNC(sys_io, cellPadGetData); REG_FUNC(sys_io, cellPadGetRawData); // REG_FUNC(sys_io, cellPadGetDataExtra); REG_FUNC(sys_io, cellPadSetActDirect); REG_FUNC(sys_io, cellPadGetInfo); // REG_FUNC(sys_io, cellPadGetInfo2); REG_FUNC(sys_io, cellPadPeriphGetInfo); REG_FUNC(sys_io, cellPadPeriphGetData); REG_FUNC(sys_io, cellPadSetPortSetting); REG_FUNC(sys_io, cellPadInfoPressMode); // REG_FUNC(sys_io, cellPadInfoSensorMode); // REG_FUNC(sys_io, cellPadSetPressMode); // REG_FUNC(sys_io, cellPadSetSensorMode); // REG_FUNC(sys_io, cellPadGetCapabilityInfo); // REG_FUNC(sys_io, cellPadLddRegisterController); REG_FUNC(sys_io, cellPadLddDataInsert); REG_FUNC(sys_io, cellPadLddGetPortNo); REG_FUNC(sys_io, cellPadLddUnregisterController); }