#include "stdafx.h" #include "PadHandler.h" #include "Emu/system_utils.hpp" #include "Input/pad_thread.h" #include "Input/product_info.h" cfg_input g_cfg_input; LOG_CHANNEL(input_log, "Input"); PadHandlerBase::PadHandlerBase(pad_handler type) : m_type(type) { } // Search an unordered map for a string value and return found keycode int PadHandlerBase::FindKeyCode(const std::unordered_map& map, const cfg::string& name, bool fallback) { const std::string def = name.def; const std::string nam = name.to_string(); int def_code = -1; for (auto it = map.begin(); it != map.end(); ++it) { if (it->second == nam) return it->first; if (fallback && it->second == def) def_code = it->first; } if (fallback) { if (!nam.empty()) input_log.error("int FindKeyCode for [name = %s] returned with [def_code = %d] for [def = %s]", nam, def_code, def); if (def_code < 0) def_code = 0; } return def_code; } long PadHandlerBase::FindKeyCode(const std::unordered_map& map, const cfg::string& name, bool fallback) { const std::string def = name.def; const std::string nam = name.to_string(); long def_code = -1; for (auto it = map.begin(); it != map.end(); ++it) { if (it->second == nam) return static_cast(it->first); if (fallback && it->second == def) def_code = static_cast(it->first); } if (fallback) { if (!nam.empty()) input_log.error("long FindKeyCode for [name = %s] returned with [def_code = %d] for [def = %s]", nam, def_code, def); if (def_code < 0) def_code = 0; } return def_code; } // Search an unordered map for a string value and return found keycode int PadHandlerBase::FindKeyCodeByString(const std::unordered_map& map, const std::string& name, bool fallback) { for (auto it = map.begin(); it != map.end(); ++it) { if (it->second == name) return it->first; } if (fallback) { if (!name.empty()) input_log.error("long FindKeyCodeByString for [name = %s] returned with 0", name); return 0; } return -1; } // Search an unordered map for a string value and return found keycode long PadHandlerBase::FindKeyCodeByString(const std::unordered_map& map, const std::string& name, bool fallback) { for (auto it = map.begin(); it != map.end(); ++it) { if (it->second == name) return static_cast(it->first); } if (fallback) { if (!name.empty()) input_log.error("long FindKeyCodeByString for [name = %s] returned with 0", name); return 0; } return -1; } // Get new multiplied value based on the multiplier s32 PadHandlerBase::MultipliedInput(s32 raw_value, s32 multiplier) { return (multiplier * raw_value) / 100; } // Get new scaled value between 0 and 255 based on its minimum and maximum float PadHandlerBase::ScaledInput(s32 raw_value, int minimum, int maximum) { // value based on max range converted to [0, 1] const float val = static_cast(std::clamp(raw_value, minimum, maximum) - minimum) / (abs(maximum) + abs(minimum)); return 255.0f * val; } // Get new scaled value between -255 and 255 based on its minimum and maximum float PadHandlerBase::ScaledInput2(s32 raw_value, int minimum, int maximum) { // value based on max range converted to [0, 1] const float val = static_cast(std::clamp(raw_value, minimum, maximum) - minimum) / (abs(maximum) + abs(minimum)); return (510.0f * val) - 255.0f; } // Get normalized trigger value based on the range defined by a threshold u16 PadHandlerBase::NormalizeTriggerInput(u16 value, int threshold) const { if (value <= threshold || threshold >= trigger_max) { return static_cast(0); } else if (threshold <= trigger_min) { return static_cast(ScaledInput(value, trigger_min, trigger_max)); } else { const s32 val = static_cast(static_cast(trigger_max) * (value - threshold) / (trigger_max - threshold)); return static_cast(ScaledInput(val, trigger_min, trigger_max)); } } // normalizes a directed input, meaning it will correspond to a single "button" and not an axis with two directions // the input values must lie in 0+ u16 PadHandlerBase::NormalizeDirectedInput(s32 raw_value, s32 threshold, s32 maximum) const { if (threshold >= maximum || maximum <= 0) { return static_cast(0); } const float val = static_cast(std::clamp(raw_value, 0, maximum)) / maximum; // value based on max range converted to [0, 1] if (threshold <= 0) { return static_cast(255.0f * val); } else { const float thresh = static_cast(threshold) / maximum; // threshold converted to [0, 1] return static_cast(255.0f * std::min(1.0f, (val - thresh) / (1.0f - thresh))); } } u16 PadHandlerBase::NormalizeStickInput(u16 raw_value, int threshold, int multiplier, bool ignore_threshold) const { const s32 scaled_value = MultipliedInput(raw_value, multiplier); if (ignore_threshold) { return static_cast(ScaledInput(scaled_value, 0, thumb_max)); } else { return NormalizeDirectedInput(scaled_value, threshold, thumb_max); } } // This function normalizes stick deadzone based on the DS3's deadzone, which is ~13% // X and Y is expected to be in (-255) to 255 range, deadzone should be in terms of thumb stick range // return is new x and y values in 0-255 range std::tuple PadHandlerBase::NormalizeStickDeadzone(s32 inX, s32 inY, u32 deadzone) const { const float dz_range = deadzone / static_cast(std::abs(thumb_max)); // NOTE: thumb_max should be positive anyway float X = inX / 255.0f; float Y = inY / 255.0f; if (dz_range > 0.f) { const float mag = std::min(sqrtf(X * X + Y * Y), 1.f); if (mag <= 0) { return std::tuple(ConvertAxis(X), ConvertAxis(Y)); } if (mag > dz_range) { const float pos = std::lerp(0.13f, 1.f, (mag - dz_range) / (1 - dz_range)); const float scale = pos / mag; X = X * scale; Y = Y * scale; } else { const float pos = std::lerp(0.f, 0.13f, mag / dz_range); const float scale = pos / mag; X = X * scale; Y = Y * scale; } } return std::tuple(ConvertAxis(X), ConvertAxis(Y)); } // get clamped value between 0 and 255 u16 PadHandlerBase::Clamp0To255(f32 input) { return static_cast(std::clamp(input, 0.0f, 255.0f)); } // get clamped value between 0 and 1023 u16 PadHandlerBase::Clamp0To1023(f32 input) { return static_cast(std::clamp(input, 0.0f, 1023.0f)); } // input has to be [-1,1]. result will be [0,255] u16 PadHandlerBase::ConvertAxis(float value) { return static_cast((value + 1.0)*(255.0 / 2.0)); } // The DS3, (and i think xbox controllers) give a 'square-ish' type response, so that the corners will give (almost)max x/y instead of the ~30x30 from a perfect circle // using a simple scale/sensitivity increase would *work* although it eats a chunk of our usable range in exchange // this might be the best for now, in practice it seems to push the corners to max of 20x20, with a squircle_factor of 8000 // This function assumes inX and inY is already in 0-255 std::tuple PadHandlerBase::ConvertToSquirclePoint(u16 inX, u16 inY, int squircle_factor) { // convert inX and Y to a (-1, 1) vector; const f32 x = (inX - 127.5f) / 127.5f; const f32 y = (inY - 127.5f) / 127.5f; // compute angle and len of given point to be used for squircle radius const f32 angle = std::atan2(y, x); const f32 r = std::sqrt(std::pow(x, 2.f) + std::pow(y, 2.f)); // now find len/point on the given squircle from our current angle and radius in polar coords // https://thatsmaths.com/2016/07/14/squircles/ const f32 newLen = (1 + std::pow(std::sin(2 * angle), 2.f) / (squircle_factor / 1000.f)) * r; // we now have len and angle, convert to cartesian const int newX = Clamp0To255(((newLen * std::cos(angle)) + 1) * 127.5f); const int newY = Clamp0To255(((newLen * std::sin(angle)) + 1) * 127.5f); return std::tuple(newX, newY); } std::string PadHandlerBase::name_string() const { return m_name_string; } usz PadHandlerBase::max_devices() const { return m_max_devices; } bool PadHandlerBase::has_config() const { return b_has_config; } bool PadHandlerBase::has_rumble() const { return b_has_rumble; } bool PadHandlerBase::has_deadzones() const { return b_has_deadzones; } bool PadHandlerBase::has_led() const { return b_has_led; } bool PadHandlerBase::has_rgb() const { return b_has_rgb; } bool PadHandlerBase::has_battery() const { return b_has_battery; } bool PadHandlerBase::has_pressure_intensity_button() const { return b_has_pressure_intensity_button; } void PadHandlerBase::init_configs() { for (u32 i = 0; i < MAX_GAMEPADS; i++) { init_config(&m_pad_configs[i]); } } void PadHandlerBase::get_next_button_press(const std::string& pad_id, const pad_callback& callback, const pad_fail_callback& fail_callback, bool get_blacklist, const std::vector& /*buttons*/) { if (get_blacklist) blacklist.clear(); auto device = get_device(pad_id); const auto status = update_connection(device); if (status == connection::disconnected) { if (fail_callback) fail_callback(pad_id); return; } else if (status == connection::no_data) return; // Get the current button values auto data = get_button_values(device); // Check for each button in our list if its corresponding (maybe remapped) button or axis was pressed. // Return the new value if the button was pressed (aka. its value was bigger than 0 or the defined threshold) // Use a pair to get all the legally pressed buttons and use the one with highest value (prioritize first) std::pair pressed_button = { 0, "" }; for (const auto& button : button_list) { const u32 keycode = button.first; const u16 value = data[keycode]; if (!get_blacklist && std::find(blacklist.begin(), blacklist.end(), keycode) != blacklist.end()) continue; const bool is_trigger = get_is_left_trigger(keycode) || get_is_right_trigger(keycode); const bool is_stick = !is_trigger && (get_is_left_stick(keycode) || get_is_right_stick(keycode)); const bool is_button = !is_trigger && !is_stick; if ((is_trigger && (value > m_trigger_threshold)) || (is_stick && (value > m_thumb_threshold)) || (is_button && (value > 0))) { if (get_blacklist) { blacklist.emplace_back(keycode); input_log.error("%s Calibration: Added key [ %d = %s ] to blacklist. Value = %d", m_type, keycode, button.second, value); } else if (value > pressed_button.first) pressed_button = { value, button.second }; } } if (get_blacklist) { if (blacklist.empty()) input_log.success("%s Calibration: Blacklist is clear. No input spam detected", m_type); return; } const auto preview_values = get_preview_values(data); const auto battery_level = get_battery_level(pad_id); if (callback) { if (pressed_button.first > 0) return callback(pressed_button.first, pressed_button.second, pad_id, battery_level, preview_values); else return callback(0, "", pad_id, battery_level, preview_values); } return; } void PadHandlerBase::convert_stick_values(u16& x_out, u16& y_out, const s32& x_in, const s32& y_in, const s32& deadzone, const s32& padsquircling) const { // Normalize our stick axis based on the deadzone std::tie(x_out, y_out) = NormalizeStickDeadzone(x_in, y_in, deadzone); // Apply pad squircling if necessary if (padsquircling != 0) { std::tie(x_out, y_out) = ConvertToSquirclePoint(x_out, y_out, padsquircling); } } // Update the pad button values based on their type and thresholds. With this you can use axis or triggers as buttons or vice versa void PadHandlerBase::TranslateButtonPress(const std::shared_ptr& device, u64 keyCode, bool& pressed, u16& val, bool ignore_stick_threshold, bool ignore_trigger_threshold) { if (!device || !device->config) { return; } if (get_is_left_trigger(keyCode)) { pressed = val > (ignore_trigger_threshold ? 0 : device->config->ltriggerthreshold); val = pressed ? NormalizeTriggerInput(val, device->config->ltriggerthreshold) : 0; } else if (get_is_right_trigger(keyCode)) { pressed = val > (ignore_trigger_threshold ? 0 : device->config->rtriggerthreshold); val = pressed ? NormalizeTriggerInput(val, device->config->rtriggerthreshold) : 0; } else if (get_is_left_stick(keyCode)) { pressed = val > (ignore_stick_threshold ? 0 : device->config->lstickdeadzone); val = pressed ? NormalizeStickInput(val, device->config->lstickdeadzone, device->config->lstickmultiplier, ignore_stick_threshold) : 0; } else if (get_is_right_stick(keyCode)) { pressed = val > (ignore_stick_threshold ? 0 : device->config->rstickdeadzone); val = pressed ? NormalizeStickInput(val, device->config->rstickdeadzone, device->config->rstickmultiplier, ignore_stick_threshold) : 0; } else // normal button (should in theory also support sensitive buttons) { pressed = val > 0; val = pressed ? val : 0; } } bool PadHandlerBase::bindPadToDevice(std::shared_ptr pad, const std::string& device, u8 player_id) { if (!pad) { return false; } std::shared_ptr pad_device = get_device(device); if (!pad_device) { input_log.error("PadHandlerBase::bindPadToDevice: no PadDevice found for device '%s'", device); return false; } m_pad_configs[player_id].from_string(g_cfg_input.player[player_id]->config.to_string()); pad_device->config = &m_pad_configs[player_id]; pad_device->player_id = player_id; cfg_pad* config = pad_device->config; if (config == nullptr) { input_log.error("PadHandlerBase::bindPadToDevice: no profile found for device %d '%s'", bindings.size(), device); return false; } std::array mapping = get_mapped_key_codes(pad_device, config); u32 pclass_profile = 0x0; for (const auto& product : input::get_products_by_class(config->device_class_type)) { if (product.vendor_id == config->vendor_id && product.product_id == config->product_id) { pclass_profile = product.pclass_profile; } } pad->Init ( CELL_PAD_STATUS_DISCONNECTED, CELL_PAD_CAPABILITY_PS3_CONFORMITY | CELL_PAD_CAPABILITY_PRESS_MODE | CELL_PAD_CAPABILITY_HP_ANALOG_STICK | CELL_PAD_CAPABILITY_ACTUATOR | CELL_PAD_CAPABILITY_SENSOR_MODE, CELL_PAD_DEV_TYPE_STANDARD, config->device_class_type, pclass_profile, config->vendor_id, config->product_id, config->pressure_intensity ); pad->m_buttons.emplace_back(special_button_offset, mapping[button::pressure_intensity_button], special_button_value::pressure_intensity); pad->m_pressure_intensity_button_index = static_cast(pad->m_buttons.size()) - 1; pad->m_buttons.emplace_back(CELL_PAD_BTN_OFFSET_DIGITAL1, mapping[button::up], CELL_PAD_CTRL_UP); pad->m_buttons.emplace_back(CELL_PAD_BTN_OFFSET_DIGITAL1, mapping[button::down], CELL_PAD_CTRL_DOWN); pad->m_buttons.emplace_back(CELL_PAD_BTN_OFFSET_DIGITAL1, mapping[button::left], CELL_PAD_CTRL_LEFT); pad->m_buttons.emplace_back(CELL_PAD_BTN_OFFSET_DIGITAL1, mapping[button::right], CELL_PAD_CTRL_RIGHT); pad->m_buttons.emplace_back(CELL_PAD_BTN_OFFSET_DIGITAL2, mapping[button::cross], CELL_PAD_CTRL_CROSS); pad->m_buttons.emplace_back(CELL_PAD_BTN_OFFSET_DIGITAL2, mapping[button::square], CELL_PAD_CTRL_SQUARE); pad->m_buttons.emplace_back(CELL_PAD_BTN_OFFSET_DIGITAL2, mapping[button::circle], CELL_PAD_CTRL_CIRCLE); pad->m_buttons.emplace_back(CELL_PAD_BTN_OFFSET_DIGITAL2, mapping[button::triangle], CELL_PAD_CTRL_TRIANGLE); pad->m_buttons.emplace_back(CELL_PAD_BTN_OFFSET_DIGITAL2, mapping[button::l1], CELL_PAD_CTRL_L1); pad->m_buttons.emplace_back(CELL_PAD_BTN_OFFSET_DIGITAL2, mapping[button::l2], CELL_PAD_CTRL_L2); pad->m_buttons.emplace_back(CELL_PAD_BTN_OFFSET_DIGITAL1, mapping[button::l3], CELL_PAD_CTRL_L3); pad->m_buttons.emplace_back(CELL_PAD_BTN_OFFSET_DIGITAL2, mapping[button::r1], CELL_PAD_CTRL_R1); pad->m_buttons.emplace_back(CELL_PAD_BTN_OFFSET_DIGITAL2, mapping[button::r2], CELL_PAD_CTRL_R2); pad->m_buttons.emplace_back(CELL_PAD_BTN_OFFSET_DIGITAL1, mapping[button::r3], CELL_PAD_CTRL_R3); pad->m_buttons.emplace_back(CELL_PAD_BTN_OFFSET_DIGITAL1, mapping[button::start], CELL_PAD_CTRL_START); pad->m_buttons.emplace_back(CELL_PAD_BTN_OFFSET_DIGITAL1, mapping[button::select], CELL_PAD_CTRL_SELECT); pad->m_buttons.emplace_back(CELL_PAD_BTN_OFFSET_DIGITAL2, mapping[button::ps], CELL_PAD_CTRL_PS); pad->m_sticks.emplace_back(CELL_PAD_BTN_OFFSET_ANALOG_LEFT_X, mapping[button::ls_left], mapping[button::ls_right]); pad->m_sticks.emplace_back(CELL_PAD_BTN_OFFSET_ANALOG_LEFT_Y, mapping[button::ls_down], mapping[button::ls_up]); pad->m_sticks.emplace_back(CELL_PAD_BTN_OFFSET_ANALOG_RIGHT_X, mapping[button::rs_left], mapping[button::rs_right]); pad->m_sticks.emplace_back(CELL_PAD_BTN_OFFSET_ANALOG_RIGHT_Y, mapping[button::rs_down], mapping[button::rs_up]); pad->m_sensors.emplace_back(CELL_PAD_BTN_OFFSET_SENSOR_X, 512); pad->m_sensors.emplace_back(CELL_PAD_BTN_OFFSET_SENSOR_Y, 399); pad->m_sensors.emplace_back(CELL_PAD_BTN_OFFSET_SENSOR_Z, 512); pad->m_sensors.emplace_back(CELL_PAD_BTN_OFFSET_SENSOR_G, 512); pad->m_vibrateMotors.emplace_back(true, 0); pad->m_vibrateMotors.emplace_back(false, 0); bindings.emplace_back(pad_device, pad); return true; } std::array PadHandlerBase::get_mapped_key_codes(const std::shared_ptr& /*device*/, const cfg_pad* cfg) { std::array mapping{}; if (!cfg) return mapping; mapping[button::up] = FindKeyCode(button_list, cfg->up); mapping[button::down] = FindKeyCode(button_list, cfg->down); mapping[button::left] = FindKeyCode(button_list, cfg->left); mapping[button::right] = FindKeyCode(button_list, cfg->right); mapping[button::cross] = FindKeyCode(button_list, cfg->cross); mapping[button::square] = FindKeyCode(button_list, cfg->square); mapping[button::circle] = FindKeyCode(button_list, cfg->circle); mapping[button::triangle] = FindKeyCode(button_list, cfg->triangle); mapping[button::start] = FindKeyCode(button_list, cfg->start); mapping[button::select] = FindKeyCode(button_list, cfg->select); mapping[button::l1] = FindKeyCode(button_list, cfg->l1); mapping[button::l2] = FindKeyCode(button_list, cfg->l2); mapping[button::l3] = FindKeyCode(button_list, cfg->l3); mapping[button::r1] = FindKeyCode(button_list, cfg->r1); mapping[button::r2] = FindKeyCode(button_list, cfg->r2); mapping[button::r3] = FindKeyCode(button_list, cfg->r3); mapping[button::ls_left] = FindKeyCode(button_list, cfg->ls_left); mapping[button::ls_right] = FindKeyCode(button_list, cfg->ls_right); mapping[button::ls_down] = FindKeyCode(button_list, cfg->ls_down); mapping[button::ls_up] = FindKeyCode(button_list, cfg->ls_up); mapping[button::rs_left] = FindKeyCode(button_list, cfg->rs_left); mapping[button::rs_right] = FindKeyCode(button_list, cfg->rs_right); mapping[button::rs_down] = FindKeyCode(button_list, cfg->rs_down); mapping[button::rs_up] = FindKeyCode(button_list, cfg->rs_up); mapping[button::ps] = FindKeyCode(button_list, cfg->ps); mapping[button::pressure_intensity_button] = FindKeyCode(button_list, cfg->pressure_intensity_button); return mapping; } void PadHandlerBase::get_mapping(const std::shared_ptr& device, const std::shared_ptr& pad) { if (!device || !pad) return; auto cfg = device->config; auto button_values = get_button_values(device); // Find out if special buttons are pressed (introduced by RPCS3). // These buttons will have a delay of one cycle, but whatever. const bool adjust_pressure = pad->m_pressure_intensity_button_index >= 0 && pad->m_buttons[pad->m_pressure_intensity_button_index].m_pressed; // Translate any corresponding keycodes to our normal DS3 buttons and triggers for (auto& btn : pad->m_buttons) { // Using a temporary buffer because the values can change during translation Button tmp = btn; tmp.m_value = button_values[btn.m_keyCode]; TranslateButtonPress(device, tmp.m_keyCode, tmp.m_pressed, tmp.m_value); // Modify pressure if necessary if the button was pressed if (adjust_pressure && tmp.m_pressed) { tmp.m_value = pad->m_pressure_intensity; } btn = tmp; } // used to get the absolute value of an axis s32 stick_val[4]{ 0 }; // Translate any corresponding keycodes to our two sticks. (ignoring thresholds for now) for (int i = 0; i < static_cast(pad->m_sticks.size()); i++) { bool pressed; // m_keyCodeMin is the mapped key for left or down const u32 key_min = pad->m_sticks[i].m_keyCodeMin; u16 val_min = button_values[key_min]; TranslateButtonPress(device, key_min, pressed, val_min, true); // m_keyCodeMax is the mapped key for right or up const u32 key_max = pad->m_sticks[i].m_keyCodeMax; u16 val_max = button_values[key_max]; TranslateButtonPress(device, key_max, pressed, val_max, true); // cancel out opposing values and get the resulting difference stick_val[i] = val_max - val_min; } u16 lx, ly, rx, ry; // Normalize and apply pad squircling convert_stick_values(lx, ly, stick_val[0], stick_val[1], cfg->lstickdeadzone, cfg->lpadsquircling); convert_stick_values(rx, ry, stick_val[2], stick_val[3], cfg->rstickdeadzone, cfg->rpadsquircling); if (m_type == pad_handler::ds4) { ly = 255 - ly; ry = 255 - ry; // these are added with previous value and divided to 'smooth' out the readings // the ds4 seems to rapidly flicker sometimes between two values and this seems to stop that pad->m_sticks[0].m_value = (lx + pad->m_sticks[0].m_value) / 2; // LX pad->m_sticks[1].m_value = (ly + pad->m_sticks[1].m_value) / 2; // LY pad->m_sticks[2].m_value = (rx + pad->m_sticks[2].m_value) / 2; // RX pad->m_sticks[3].m_value = (ry + pad->m_sticks[3].m_value) / 2; // RY } else { pad->m_sticks[0].m_value = lx; pad->m_sticks[1].m_value = 255 - ly; pad->m_sticks[2].m_value = rx; pad->m_sticks[3].m_value = 255 - ry; } } void PadHandlerBase::ThreadProc() { for (usz i = 0; i < bindings.size(); ++i) { auto device = bindings[i].first; auto pad = bindings[i].second; if (!device || !pad) continue; const auto status = update_connection(device); switch (status) { case connection::no_data: case connection::connected: { if (!last_connection_status[i]) { input_log.success("%s device %d connected", m_type, i); pad->m_port_status |= CELL_PAD_STATUS_CONNECTED; pad->m_port_status |= CELL_PAD_STATUS_ASSIGN_CHANGES; last_connection_status[i] = true; connected_devices++; } if (status == connection::no_data) continue; break; } case connection::disconnected: { if (last_connection_status[i]) { input_log.error("%s device %d disconnected", m_type, i); pad->m_port_status &= ~CELL_PAD_STATUS_CONNECTED; pad->m_port_status |= CELL_PAD_STATUS_ASSIGN_CHANGES; last_connection_status[i] = false; connected_devices--; } continue; } default: break; } get_mapping(device, pad); get_extended_info(device, pad); apply_pad_data(device, pad); } }