aurora/lib/input.cpp

#include "input.hpp"
#include "internal.hpp"
#include "pad.hpp"

#include "magic_enum.hpp"

#include <SDL_haptic.h>
#include <SDL_version.h>

#include <absl/container/btree_map.h>
#include <absl/container/flat_hash_map.h>
#include <absl/strings/str_split.h>
#include <cmath>

using namespace std::string_view_literals;

namespace aurora::input {
static Module Log("aurora::input");

struct GameController {
  SDL_GameController* m_controller = nullptr;
  bool m_isGameCube = false;
  Sint32 m_index = -1;
  bool m_hasRumble = false;
  PADDeadZones m_deadZones{
      .emulateTriggers = true,
      .useDeadzones = true,
      .stickDeadZone = 8000,
      .substickDeadZone = 8000,
      .leftTriggerActivationZone = 31150,
      .rightTriggerActivationZone = 31150,
  };
  uint16_t m_vid = 0;
  uint16_t m_pid = 0;
  std::array<PADButtonMapping, 12> m_mapping{};
  bool m_mappingLoaded = false;
  constexpr bool operator==(const GameController& other) const {
    return m_controller == other.m_controller && m_index == other.m_index;
  }
};
absl::flat_hash_map<Uint32, GameController> g_GameControllers;

GameController* get_controller_for_player(uint32_t player) noexcept {
  for (auto& [which, controller] : g_GameControllers) {
    if (player_index(which) == player) {
      return &controller;
    }
  }

#if 0
  /* If we don't have a controller assigned to this port use the first unassigned controller */
  if (!g_GameControllers.empty()) {
    int32_t availIndex = -1;
    GameController* ct = nullptr;
    for (auto& controller : g_GameControllers) {
      if (player_index(controller.first) == -1) {
        availIndex = controller.first;
        ct = &controller.second;
        break;
      }
    }
    if (availIndex != -1) {
      set_player_index(availIndex, player);
      return ct;
    }
  }
#endif
  return nullptr;
}

Sint32 get_instance_for_player(uint32_t player) noexcept {
  for (const auto& [which, controller] : g_GameControllers) {
    if (player_index(which) == player) {
      return which;
    }
  }

  return {};
}

static std::optional<std::string> remap_controller_layout(std::string_view mapping) {
  std::string newMapping;
  newMapping.reserve(mapping.size());
  absl::btree_map<std::string_view, std::string_view> entries;
  for (size_t idx = 0; const auto value : absl::StrSplit(mapping, ',')) {
    if (idx < 2) {
      if (idx > 0) {
        newMapping.push_back(',');
      }
      newMapping.append(value);
    } else {
      const auto split = absl::StrSplit(value, absl::MaxSplits(':', 2));
      auto iter = split.begin();
      entries.emplace(*iter++, *iter);
    }
    idx++;
  }
  if (entries.contains("rightshoulder"sv) && !entries.contains("leftshoulder"sv)) {
    Log.report(LOG_INFO, FMT_STRING("Remapping GameCube controller layout"));
    entries.insert_or_assign("back"sv, entries["rightshoulder"sv]);
    // TODO trigger buttons may differ per platform
    entries.insert_or_assign("leftshoulder"sv, "b11"sv);
    entries.insert_or_assign("rightshoulder"sv, "b10"sv);
  } else if (entries.contains("leftshoulder"sv) && entries.contains("rightshoulder"sv) && entries.contains("back"sv)) {
    Log.report(LOG_INFO, FMT_STRING("Controller has standard layout"));
    auto a = entries["a"sv];
    entries.insert_or_assign("a"sv, entries["b"sv]);
    entries.insert_or_assign("b"sv, a);
    auto x = entries["x"sv];
    entries.insert_or_assign("x"sv, entries["y"sv]);
    entries.insert_or_assign("y"sv, x);
  } else {
    Log.report(LOG_ERROR, FMT_STRING("Controller has unsupported layout: {}"), mapping);
    return {};
  }
  for (auto [k, v] : entries) {
    newMapping.push_back(',');
    newMapping.append(k);
    newMapping.push_back(':');
    newMapping.append(v);
  }
  return newMapping;
}

Sint32 add_controller(Sint32 which) noexcept {
  auto* ctrl = SDL_GameControllerOpen(which);
  if (ctrl != nullptr) {
    {
      char* mapping = SDL_GameControllerMapping(ctrl);
      if (mapping != nullptr) {
        auto newMapping = remap_controller_layout(mapping);
        SDL_free(mapping);
        if (newMapping) {
          if (SDL_GameControllerAddMapping(newMapping->c_str()) == -1) {
            Log.report(LOG_ERROR, FMT_STRING("Failed to update controller mapping: {}"), SDL_GetError());
          }
        }
      } else {
        Log.report(LOG_ERROR, FMT_STRING("Failed to retrieve mapping for controller"));
      }
    }
    GameController controller;
    controller.m_controller = ctrl;
    controller.m_index = which;
    controller.m_vid = SDL_GameControllerGetVendor(ctrl);
    controller.m_pid = SDL_GameControllerGetProduct(ctrl);
    if (controller.m_vid == 0x05ac /* USB_VENDOR_APPLE */ && controller.m_pid == 3) {
      // Ignore Apple TV remote
      SDL_GameControllerClose(ctrl);
      return -1;
    }
    controller.m_isGameCube = controller.m_vid == 0x057E && controller.m_pid == 0x0337;
#if SDL_VERSION_ATLEAST(2, 0, 18)
    controller.m_hasRumble = (SDL_GameControllerHasRumble(ctrl) != 0u);
#else
    controller.m_hasRumble = true;
#endif
    Sint32 instance = SDL_JoystickInstanceID(SDL_GameControllerGetJoystick(ctrl));
    g_GameControllers[instance] = controller;
    return instance;
  }

  return -1;
}

void remove_controller(Uint32 instance) noexcept {
  if (g_GameControllers.find(instance) != g_GameControllers.end()) {
    SDL_GameControllerClose(g_GameControllers[instance].m_controller);
    g_GameControllers.erase(instance);
  }
}

bool is_gamecube(Uint32 instance) noexcept {
  if (g_GameControllers.find(instance) != g_GameControllers.end()) {
    return g_GameControllers[instance].m_isGameCube;
  }
  return false;
}

int32_t player_index(Uint32 instance) noexcept {
  if (g_GameControllers.find(instance) != g_GameControllers.end()) {
    return SDL_GameControllerGetPlayerIndex(g_GameControllers[instance].m_controller);
  }
  return -1;
}

void set_player_index(Uint32 instance, Sint32 index) noexcept {
  if (g_GameControllers.find(instance) != g_GameControllers.end()) {
    SDL_GameControllerSetPlayerIndex(g_GameControllers[instance].m_controller, index);
  }
}

std::string controller_name(Uint32 instance) noexcept {
  if (g_GameControllers.find(instance) != g_GameControllers.end()) {
    const auto* name = SDL_GameControllerName(g_GameControllers[instance].m_controller);
    if (name != nullptr) {
      return {name};
    }
  }
  return {};
}

bool controller_has_rumble(Uint32 instance) noexcept {
  if (g_GameControllers.find(instance) != g_GameControllers.end()) {
    return g_GameControllers[instance].m_hasRumble;
  }

  return false;
}

void controller_rumble(uint32_t instance, uint16_t low_freq_intensity, uint16_t high_freq_intensity,
                       uint16_t duration_ms) noexcept {

  if (g_GameControllers.find(instance) != g_GameControllers.end()) {
    SDL_GameControllerRumble(g_GameControllers[instance].m_controller, low_freq_intensity, high_freq_intensity,
                             duration_ms);
  }
}

uint32_t controller_count() noexcept { return g_GameControllers.size(); }

} // namespace aurora::input

static const std::array<PADButtonMapping, 12> mDefaultButtons{{
    {SDL_CONTROLLER_BUTTON_A, PAD_BUTTON_A},
    {SDL_CONTROLLER_BUTTON_B, PAD_BUTTON_B},
    {SDL_CONTROLLER_BUTTON_X, PAD_BUTTON_X},
    {SDL_CONTROLLER_BUTTON_Y, PAD_BUTTON_Y},
    {SDL_CONTROLLER_BUTTON_START, PAD_BUTTON_START},
    {SDL_CONTROLLER_BUTTON_BACK, PAD_TRIGGER_Z},
    {SDL_CONTROLLER_BUTTON_LEFTSHOULDER, PAD_TRIGGER_L},
    {SDL_CONTROLLER_BUTTON_RIGHTSHOULDER, PAD_TRIGGER_R},
    {SDL_CONTROLLER_BUTTON_DPAD_UP, PAD_BUTTON_UP},
    {SDL_CONTROLLER_BUTTON_DPAD_DOWN, PAD_BUTTON_DOWN},
    {SDL_CONTROLLER_BUTTON_DPAD_LEFT, PAD_BUTTON_LEFT},
    {SDL_CONTROLLER_BUTTON_DPAD_RIGHT, PAD_BUTTON_RIGHT},
}};

void PADSetSpec(u32 spec) {}
BOOL PADInit() { return true; }
BOOL PADRecalibrate(u32 mask) { return true; }
BOOL PADReset(u32 mask) { return true; }
void PADSetAnalogMode(u32 mode) {}

aurora::input::GameController* __PADGetControllerForIndex(uint32_t idx) {
  if (idx >= aurora::input::g_GameControllers.size()) {
    return nullptr;
  }

  uint32_t tmp = 0;
  auto iter = aurora::input::g_GameControllers.begin();
  while (tmp < idx) {
    ++iter;
    ++tmp;
  }
  if (iter == aurora::input::g_GameControllers.end()) {
    return nullptr;
  }

  return &iter->second;
}

uint32_t PADCount() { return aurora::input::g_GameControllers.size(); }

const char* PADGetNameForControllerIndex(uint32_t idx) {
  auto* ctrl = __PADGetControllerForIndex(idx);
  if (ctrl == nullptr) {
    return nullptr;
  }

  return SDL_GameControllerName(ctrl->m_controller);
}

void PADSetPortForIndex(uint32_t idx, int32_t port) {
  auto* ctrl = __PADGetControllerForIndex(idx);
  auto* dest = aurora::input::get_controller_for_player(port);
  if (ctrl == nullptr) {
    return;
  }
  if (dest != nullptr) {
    SDL_GameControllerSetPlayerIndex(dest->m_controller, -1);
  }
  SDL_GameControllerSetPlayerIndex(ctrl->m_controller, port);
}

int32_t PADGetIndexForPort(uint32_t port) {
  auto* ctrl = aurora::input::get_controller_for_player(port);
  if (ctrl == nullptr) {
    return -1;
  }
  int32_t index = 0;
  for (auto iter = aurora::input::g_GameControllers.begin(); iter != aurora::input::g_GameControllers.end();
       ++iter, ++index) {
    if (&iter->second == ctrl) {
      break;
    }
  }

  return index;
}

void PADClearPort(uint32_t port) {
  auto* ctrl = aurora::input::get_controller_for_player(port);
  if (ctrl == nullptr) {
    return;
  }
  SDL_GameControllerSetPlayerIndex(ctrl->m_controller, -1);
}

void __PADLoadMapping(aurora::input::GameController* controller) {
  int32_t playerIndex = SDL_GameControllerGetPlayerIndex(controller->m_controller);
  if (playerIndex == -1) {
    return;
  }

  std::string basePath{aurora::g_config.configPath};
  if (!controller->m_mappingLoaded) {
    controller->m_mapping = mDefaultButtons;
  }

  controller->m_mappingLoaded = true;

  auto path = fmt::format(FMT_STRING("{}/{}_{:04X}_{:04X}.controller"), basePath, PADGetName(playerIndex),
                          controller->m_vid, controller->m_pid);
  FILE* file = fopen(path.c_str(), "rb");
  if (file == nullptr) {
    return;
  }

  uint32_t magic = 0;
  fread(&magic, 1, sizeof(uint32_t), file);
  if (magic != SBIG('CTRL')) {
    fmt::print(FMT_STRING("Invalid controller mapping magic!\n"));
    return;
  }

  uint32_t version = 0;
  fread(&version, 1, sizeof(uint32_t), file);
  if (version != 1) {
    fmt::print(FMT_STRING("Invalid controller mapping version!\n"));
    return;
  }

  bool isGameCube = false;
  fread(&isGameCube, 1, 1, file);
  fseek(file, (ftell(file) + 31) & ~31, SEEK_SET);
  uint32_t dataStart = ftell(file);
  if (isGameCube) {
    fseek(file, dataStart + ((sizeof(PADDeadZones) + sizeof(PADButtonMapping)) * playerIndex), SEEK_SET);
  }

  fread(&controller->m_deadZones, 1, sizeof(PADDeadZones), file);
  fread(&controller->m_mapping, 1, sizeof(PADButtonMapping) * controller->m_mapping.size(), file);
  fclose(file);
}

bool gBlockPAD = false;
uint32_t PADRead(PADStatus* status) {
  if (gBlockPAD) {
    return 0;
  }

  uint32_t rumbleSupport = 0;
  for (uint32_t i = 0; i < 4; ++i) {
    memset(&status[i], 0, sizeof(PADStatus));
    auto controller = aurora::input::get_controller_for_player(i);
    if (controller == nullptr) {
      status[i].err = PAD_ERR_NO_CONTROLLER;
      continue;
    }

    if (!controller->m_mappingLoaded) {
      __PADLoadMapping(controller);
    }
    status[i].err = PAD_ERR_NONE;
    std::for_each(controller->m_mapping.begin(), controller->m_mapping.end(),
                  [&controller, &i, &status](const auto& mapping) {
                    if (SDL_GameControllerGetButton(controller->m_controller,
                                                    static_cast<SDL_GameControllerButton>(mapping.nativeButton))) {
                      status[i].button |= mapping.padButton;
                    }
                  });

    Sint16 x = SDL_GameControllerGetAxis(controller->m_controller, SDL_CONTROLLER_AXIS_LEFTX);
    Sint16 y = SDL_GameControllerGetAxis(controller->m_controller, SDL_CONTROLLER_AXIS_LEFTY);
    if (controller->m_deadZones.useDeadzones) {
      if (std::abs(x) > controller->m_deadZones.stickDeadZone) {
        x /= 256;
      } else {
        x = 0;
      }
      if (std::abs(y) > controller->m_deadZones.stickDeadZone) {
        y = (-(y + 1u)) / 256u;
      } else {
        y = 0;
      }
    } else {
      x /= 256;
      y = (-(y + 1u)) / 256u;
    }

    status[i].stickX = static_cast<int8_t>(x);
    status[i].stickY = static_cast<int8_t>(y);

    x = SDL_GameControllerGetAxis(controller->m_controller, SDL_CONTROLLER_AXIS_RIGHTX);
    y = SDL_GameControllerGetAxis(controller->m_controller, SDL_CONTROLLER_AXIS_RIGHTY);
    if (controller->m_deadZones.useDeadzones) {
      if (std::abs(x) > controller->m_deadZones.substickDeadZone) {
        x /= 256;
      } else {
        x = 0;
      }

      if (std::abs(y) > controller->m_deadZones.substickDeadZone) {
        y = (-(y + 1u)) / 256u;
      } else {
        y = 0;
      }
    } else {
      x /= 256;
      y = (-(y + 1u)) / 256u;
    }

    status[i].substickX = static_cast<int8_t>(x);
    status[i].substickY = static_cast<int8_t>(y);

    x = SDL_GameControllerGetAxis(controller->m_controller, SDL_CONTROLLER_AXIS_TRIGGERLEFT);
    y = SDL_GameControllerGetAxis(controller->m_controller, SDL_CONTROLLER_AXIS_TRIGGERRIGHT);
    if (/*!controller->m_isGameCube && */ controller->m_deadZones.emulateTriggers) {
      if (x > controller->m_deadZones.leftTriggerActivationZone) {
        status[i].button |= PAD_TRIGGER_L;
      }
      if (y > controller->m_deadZones.rightTriggerActivationZone) {
        status[i].button |= PAD_TRIGGER_R;
      }
    }
    x /= 128;
    y /= 128;

    status[i].triggerL = static_cast<int8_t>(x);
    status[i].triggerR = static_cast<int8_t>(y);

    if (controller->m_hasRumble) {
      rumbleSupport |= PAD_CHAN0_BIT >> i;
    }
  }
  return rumbleSupport;
}

void PADControlAllMotors(const uint32_t* commands) {
  for (uint32_t i = 0; i < 4; ++i) {
    auto controller = aurora::input::get_controller_for_player(i);
    auto instance = aurora::input::get_instance_for_player(i);
    if (controller == nullptr) {
      continue;
    }

    if (controller->m_isGameCube) {
      if (commands[i] == PAD_MOTOR_STOP) {
        aurora::input::controller_rumble(instance, 0, 1, 0);
      } else if (commands[i] == PAD_MOTOR_RUMBLE) {
        aurora::input::controller_rumble(instance, 1, 1, 0);
      } else if (commands[i] == PAD_MOTOR_STOP_HARD) {
        aurora::input::controller_rumble(instance, 0, 0, 0);
      }
    } else {
      if (commands[i] == PAD_MOTOR_STOP) {
        aurora::input::controller_rumble(instance, 0, 0, 1);
      } else if (commands[i] == PAD_MOTOR_RUMBLE) {
        aurora::input::controller_rumble(instance, 32767, 32767, 0);
      } else if (commands[i] == PAD_MOTOR_STOP_HARD) {
        aurora::input::controller_rumble(instance, 0, 0, 0);
      }
    }
  }
}

uint32_t SIProbe(int32_t chan) {
  auto* const controller = aurora::input::get_controller_for_player(chan);
  if (controller == nullptr) {
    return SI_ERROR_NO_RESPONSE;
  }

  if (controller->m_isGameCube) {
    auto level = SDL_JoystickCurrentPowerLevel(SDL_GameControllerGetJoystick(controller->m_controller));
    if (level == SDL_JOYSTICK_POWER_UNKNOWN) {
      return SI_GC_WAVEBIRD;
    }
  }

  return SI_GC_CONTROLLER;
}

struct PADCLampRegion {
  uint8_t minTrigger;
  uint8_t maxTrigger;
  int8_t minStick;
  int8_t maxStick;
  int8_t xyStick;
  int8_t minSubstick;
  int8_t maxSubstick;
  int8_t xySubstick;
  int8_t radStick;
  int8_t radSubstick;
};

static constexpr PADCLampRegion ClampRegion{
    // Triggers
    30,
    180,

    // Left stick
    15,
    72,
    40,

    // Right stick
    15,
    59,
    31,

    // Stick radii
    56,
    44,
};

void ClampTrigger(uint8_t* trigger, uint8_t min, uint8_t max) {
  if (*trigger <= min) {
    *trigger = 0;
  } else {
    if (*trigger > max) {
      *trigger = max;
    }
    *trigger -= min;
  }
}

void ClampCircle(int8_t* px, int8_t* py, int8_t radius, int8_t min) {
  int x = *px;
  int y = *py;

  if (-min < x && x < min) {
    x = 0;
  } else if (0 < x) {
    x -= min;
  } else {
    x += min;
  }

  if (-min < y && y < min) {
    y = 0;
  } else if (0 < y) {
    y -= min;
  } else {
    y += min;
  }

  int squared = x * x + y * y;
  if (radius * radius < squared) {
    int32_t length = static_cast<int32_t>(std::sqrt(squared));
    x = (x * radius) / length;
    y = (y * radius) / length;
  }

  *px = static_cast<int8_t>(x);
  *py = static_cast<int8_t>(y);
}

void ClampStick(int8_t* px, int8_t* py, int8_t max, int8_t xy, int8_t min) {
  int32_t x = *px;
  int32_t y = *py;

  int32_t signX = 0;
  if (0 <= x) {
    signX = 1;
  } else {
    signX = -1;
    x = -x;
  }

  int8_t signY = 0;
  if (0 <= y) {
    signY = 1;
  } else {
    signY = -1;
    y = -y;
  }

  if (x <= min) {
    x = 0;
  } else {
    x -= min;
  }
  if (y <= min) {
    y = 0;
  } else {
    y -= min;
  }

  if (x == 0 && y == 0) {
    *px = *py = 0;
    return;
  }

  if (xy * y <= xy * x) {
    int32_t d = xy * x + (max - xy) * y;
    if (xy * max < d) {
      x = (xy * max * x / d);
      y = (xy * max * y / d);
    }
  } else {
    int32_t d = xy * y + (max - xy) * x;
    if (xy * max < d) {
      x = (xy * max * x / d);
      y = (xy * max * y / d);
    }
  }

  *px = (signX * x);
  *py = (signY * y);
}

void PADClamp(PADStatus* status) {
  for (uint32_t i = 0; i < 4; ++i) {
    if (status[i].err != PAD_ERR_NONE) {
      continue;
    }

    ClampStick(&status[i].stickX, &status[i].stickY, ClampRegion.maxStick, ClampRegion.xyStick, ClampRegion.minStick);
    ClampStick(&status[i].substickX, &status[i].substickY, ClampRegion.maxSubstick, ClampRegion.xySubstick,
               ClampRegion.minSubstick);
    ClampTrigger(&status[i].triggerL, ClampRegion.minTrigger, ClampRegion.maxTrigger);
    ClampTrigger(&status[i].triggerR, ClampRegion.minTrigger, ClampRegion.maxTrigger);
  }
}

void PADClampCircle(PADStatus* status) {
  for (uint32_t i = 0; i < 4; ++i) {
    if (status[i].err != PAD_ERR_NONE) {
      continue;
    }

    ClampCircle(&status[i].stickX, &status[i].stickY, ClampRegion.radStick, ClampRegion.minStick);
    ClampCircle(&status[i].substickX, &status[i].substickY, ClampRegion.radSubstick, ClampRegion.minSubstick);
    ClampTrigger(&status[i].triggerL, ClampRegion.minTrigger, ClampRegion.maxTrigger);
    ClampTrigger(&status[i].triggerR, ClampRegion.minTrigger, ClampRegion.maxTrigger);
  }
}

void PADGetVidPid(uint32_t port, uint32_t* vid, uint32_t* pid) {
  *vid = 0;
  *pid = 0;
  auto* controller = aurora::input::get_controller_for_player(port);
  if (controller == nullptr) {
    return;
  }

  *vid = controller->m_vid;
  *pid = controller->m_pid;
}

const char* PADGetName(uint32_t port) {
  auto* controller = aurora::input::get_controller_for_player(port);
  if (controller == nullptr) {
    return nullptr;
  }

  return SDL_GameControllerName(controller->m_controller);
}

void PADSetButtonMapping(uint32_t port, PADButtonMapping mapping) {
  auto* controller = aurora::input::get_controller_for_player(port);
  if (controller == nullptr) {
    return;
  }

  auto iter = std::find_if(controller->m_mapping.begin(), controller->m_mapping.end(),
                           [mapping](const auto& pair) { return mapping.padButton == pair.padButton; });
  if (iter == controller->m_mapping.end()) {
    return;
  }

  *iter = mapping;
}

void PADSetAllButtonMappings(uint32_t port, PADButtonMapping buttons[12]) {
  for (uint32_t i = 0; i < 12; ++i) {
    PADSetButtonMapping(port, buttons[i]);
  }
}

PADButtonMapping* PADGetButtonMappings(uint32_t port, uint32_t* buttonCount) {
  auto* controller = aurora::input::get_controller_for_player(port);
  if (controller == nullptr) {
    *buttonCount = 0;
    return nullptr;
  }

  *buttonCount = controller->m_mapping.size();
  return controller->m_mapping.data();
}

void __PADWriteDeadZones(FILE* file, aurora::input::GameController& controller) {
  fwrite(&controller.m_deadZones, 1, sizeof(PADDeadZones), file);
}

void PADSerializeMappings() {
  std::string basePath{aurora::g_config.configPath};

  bool wroteGameCubeAlready = false;
  for (auto& controller : aurora::input::g_GameControllers) {
    if (!controller.second.m_mappingLoaded) {
      __PADLoadMapping(&controller.second);
    }
    FILE* file = fopen(fmt::format(FMT_STRING("{}/{}_{:04X}_{:04X}.controller"), basePath,
                                   aurora::input::controller_name(controller.second.m_index), controller.second.m_vid,
                                   controller.second.m_pid)
                           .c_str(),
                       "wbe");
    if (file == nullptr) {
      return;
    }

    uint32_t magic = SBIG('CTRL');
    uint32_t version = 1;
    fwrite(&magic, 1, sizeof(magic), file);
    fwrite(&version, 1, sizeof(magic), file);
    fwrite(&controller.second.m_isGameCube, 1, 1, file);
    fseek(file, (ftell(file) + 31) & ~31, SEEK_SET);
    int32_t dataStart = ftell(file);
    if (!controller.second.m_isGameCube) {
      __PADWriteDeadZones(file, controller.second);
      fwrite(controller.second.m_mapping.data(), 1, sizeof(PADButtonMapping) * controller.second.m_mapping.size(),
             file);
    } else {
      if (!wroteGameCubeAlready) {
        for (uint32_t i = 0; i < 4; ++i) {
          /* Just use the current controller's configs for this */
          __PADWriteDeadZones(file, controller.second);
          fwrite(mDefaultButtons.data(), 1, sizeof(PADButtonMapping) * mDefaultButtons.size(), file);
        }
        fflush(file);
        wroteGameCubeAlready = true;
      }
      uint32_t port = aurora::input::player_index(controller.second.m_index);
      fseek(file, dataStart + ((sizeof(PADDeadZones) + sizeof(PADButtonMapping)) * port), SEEK_SET);
      __PADWriteDeadZones(file, controller.second);
      fwrite(controller.second.m_mapping.data(), 1, sizeof(PADButtonMapping) * controller.second.m_mapping.size(),
             file);
    }
    fclose(file);
  }
}

PADDeadZones* PADGetDeadZones(uint32_t port) {
  auto* controller = aurora::input::get_controller_for_player(port);
  if (controller == nullptr) {
    return nullptr;
  }
  return &controller->m_deadZones;
}

static constexpr std::array<std::pair<PADButton, std::string_view>, 12> skButtonNames = {{
    {PAD_BUTTON_LEFT, "Left"sv},
    {PAD_BUTTON_RIGHT, "Right"sv},
    {PAD_BUTTON_DOWN, "Down"sv},
    {PAD_BUTTON_UP, "Up"sv},
    {PAD_TRIGGER_Z, "Z"sv},
    {PAD_TRIGGER_R, "R"sv},
    {PAD_TRIGGER_L, "L"sv},
    {PAD_BUTTON_A, "A"sv},
    {PAD_BUTTON_B, "B"sv},
    {PAD_BUTTON_X, "X"sv},
    {PAD_BUTTON_Y, "Y"sv},
    {PAD_BUTTON_START, "Start"sv},
}};

const char* PADGetButtonName(PADButton button) {
  auto it = std::find_if(skButtonNames.begin(), skButtonNames.end(),
                         [&button](const auto& pair) { return button == pair.first; });

  if (it != skButtonNames.end()) {
    return it->second.data();
  }

  return nullptr;
}

const char* PADGetNativeButtonName(uint32_t button) {
  return SDL_GameControllerGetStringForButton(static_cast<SDL_GameControllerButton>(button));
}

int32_t PADGetNativeButtonPressed(uint32_t port) {
  auto* controller = aurora::input::get_controller_for_player(port);
  if (controller == nullptr) {
    return -1;
  }

  for (uint32_t i = 0; i < SDL_CONTROLLER_BUTTON_MAX; ++i) {
    if (SDL_GameControllerGetButton(controller->m_controller, static_cast<SDL_GameControllerButton>(i)) != 0u) {
      return i;
    }
  }
  return -1;
}

void PADRestoreDefaultMapping(uint32_t port) {
  auto* controller = aurora::input::get_controller_for_player(port);
  if (controller == nullptr) {
    return;
  }
  controller->m_mapping = mDefaultButtons;
}

void PADBlockInput(bool block) { gBlockPAD = block; }