ppsspp/Windows/XinputDevice.cpp

341 lines
9.7 KiB
C++

#include "ppsspp_config.h"
#include <climits>
#include <algorithm>
#include "base/NativeApp.h"
#include "Core/Config.h"
#include "Common/CommonWindows.h"
#include "Common/KeyMap.h"
#include "Common/Log.h"
#include "input/input_state.h"
#include "input/keycodes.h"
#include "XinputDevice.h"
// Utilities to dynamically load XInput. Adapted from SDL.
#if !PPSSPP_PLATFORM(UWP)
typedef DWORD (WINAPI *XInputGetState_t) (DWORD dwUserIndex, XINPUT_STATE* pState);
static XInputGetState_t PPSSPP_XInputGetState = NULL;
static DWORD PPSSPP_XInputVersion = 0;
static HMODULE s_pXInputDLL = 0;
static int s_XInputDLLRefCount = 0;
static void UnloadXInputDLL();
static int LoadXInputDLL() {
DWORD version = 0;
if (s_pXInputDLL) {
s_XInputDLLRefCount++;
return 0; /* already loaded */
}
version = (1 << 16) | 4;
s_pXInputDLL = LoadLibrary( L"XInput1_4.dll" ); // 1.4 Ships with Windows 8.
if (!s_pXInputDLL) {
version = (1 << 16) | 3;
s_pXInputDLL = LoadLibrary( L"XInput1_3.dll" ); // 1.3 Ships with Vista and Win7, can be installed as a restributable component.
if (!s_pXInputDLL) {
version = (1 << 16) | 0;
s_pXInputDLL = LoadLibrary( L"XInput9_1_0.dll" ); // 1.0 ships with any Windows since WinXP
}
}
if (!s_pXInputDLL) {
return -1;
}
PPSSPP_XInputVersion = version;
s_XInputDLLRefCount = 1;
/* 100 is the ordinal for _XInputGetStateEx, which returns the same struct as XinputGetState, but with extra data in wButtons for the guide button, we think...
Let's try the name first, though - then fall back to ordinal, then to a non-Ex version (xinput9_1_0.dll doesn't have Ex) */
PPSSPP_XInputGetState = (XInputGetState_t)GetProcAddress( (HMODULE)s_pXInputDLL, "XInputGetStateEx" );
if ( !PPSSPP_XInputGetState ) {
PPSSPP_XInputGetState = (XInputGetState_t)GetProcAddress( (HMODULE)s_pXInputDLL, (LPCSTR)100 );
if ( !PPSSPP_XInputGetState ) {
PPSSPP_XInputGetState = (XInputGetState_t)GetProcAddress( (HMODULE)s_pXInputDLL, "XInputGetState" );
}
}
if ( !PPSSPP_XInputGetState ) {
UnloadXInputDLL();
return -1;
}
return 0;
}
static void UnloadXInputDLL() {
if ( s_pXInputDLL ) {
if (--s_XInputDLLRefCount == 0) {
FreeLibrary( s_pXInputDLL );
s_pXInputDLL = NULL;
}
}
}
#else
static int LoadXInputDLL() { return 0; }
static void UnloadXInputDLL() {}
#define PPSSPP_XInputGetState XInputGetState
#endif
#ifndef XUSER_MAX_COUNT
#define XUSER_MAX_COUNT 4
#endif
// Undocumented. Steam annoyingly grabs this button though....
#define XINPUT_GUIDE_BUTTON 0x400
// Permanent map. Actual mapping happens elsewhere.
static const struct {int from, to;} xinput_ctrl_map[] = {
{XINPUT_GAMEPAD_A, NKCODE_BUTTON_A},
{XINPUT_GAMEPAD_B, NKCODE_BUTTON_B},
{XINPUT_GAMEPAD_X, NKCODE_BUTTON_X},
{XINPUT_GAMEPAD_Y, NKCODE_BUTTON_Y},
{XINPUT_GAMEPAD_BACK, NKCODE_BUTTON_SELECT},
{XINPUT_GAMEPAD_START, NKCODE_BUTTON_START},
{XINPUT_GAMEPAD_LEFT_SHOULDER, NKCODE_BUTTON_L1},
{XINPUT_GAMEPAD_RIGHT_SHOULDER, NKCODE_BUTTON_R1},
{XINPUT_GAMEPAD_LEFT_THUMB, NKCODE_BUTTON_THUMBL},
{XINPUT_GAMEPAD_RIGHT_THUMB, NKCODE_BUTTON_THUMBR},
{XINPUT_GAMEPAD_DPAD_UP, NKCODE_DPAD_UP},
{XINPUT_GAMEPAD_DPAD_DOWN, NKCODE_DPAD_DOWN},
{XINPUT_GAMEPAD_DPAD_LEFT, NKCODE_DPAD_LEFT},
{XINPUT_GAMEPAD_DPAD_RIGHT, NKCODE_DPAD_RIGHT},
{XINPUT_GUIDE_BUTTON, NKCODE_HOME},
};
static const unsigned int xinput_ctrl_map_size = sizeof(xinput_ctrl_map) / sizeof(xinput_ctrl_map[0]);
XinputDevice::XinputDevice() {
if (LoadXInputDLL() != 0) {
WARN_LOG(SCECTRL, "Failed to load XInput! DLL missing");
}
for (size_t i = 0; i < ARRAY_SIZE(check_delay); ++i) {
check_delay[i] = (int)i;
}
}
XinputDevice::~XinputDevice() {
UnloadXInputDLL();
}
struct Stick {
Stick (float x_, float y_, float scale) : x(x_ * scale), y(y_ * scale) {}
float x;
float y;
};
inline float Clampf(float val, float min, float max) {
if (val < min) return min;
if (val > max) return max;
return val;
}
inline float Signf(float val) {
return (0.0f < val) - (val < 0.0f);
}
inline float LinearMapf(float val, float a0, float a1, float b0, float b1) {
return b0 + (((val - a0) * (b1 - b0)) / (a1 - a0));
}
static Stick NormalizedDeadzoneFilter(short x, short y, float dz, int idzm, float idz, float st) {
Stick s(x, y, 1.0f / 32767.0f);
float magnitude = sqrtf(s.x * s.x + s.y * s.y);
if (magnitude > dz) {
// Circle to square mapping (the PSP stick outputs the full -1..1 square of values)
#if 1
// Looks way better than the old one, below, in the axis tester.
float sx = s.x;
float sy = s.y;
float scaleFactor = sqrtf((sx * sx + sy * sy) / std::max(sx * sx, sy * sy));
s.x = sx * scaleFactor;
s.y = sy * scaleFactor;
#else
if (magnitude > 1.0f) {
s.x *= 1.41421f;
s.y *= 1.41421f;
}
#endif
// Linear range mapping (used to invert deadzones)
float md = std::max(dz, idz);
if (idzm == 1)
{
float xSign = Signf(s.x);
if (xSign != 0.0f) {
s.x = LinearMapf(s.x, xSign * dz, xSign, xSign * md, xSign * st);
}
}
else if (idzm == 2)
{
float ySign = Signf(s.y);
if (ySign != 0.0f) {
s.y = LinearMapf(s.y, ySign * dz, ySign, ySign * md, ySign * st);
}
}
else if (idzm == 3)
{
float xNorm = s.x / magnitude;
float yNorm = s.y / magnitude;
float mapMag = LinearMapf(magnitude, dz, 1.0f, md, st);
s.x = xNorm * mapMag;
s.y = yNorm * mapMag;
}
s.x = Clampf(s.x, -1.0f, 1.0f);
s.y = Clampf(s.y, -1.0f, 1.0f);
} else {
s.x = 0.0f;
s.y = 0.0f;
}
return s;
}
bool NormalizedDeadzoneDiffers(short x1, short y1, short x2, short y2, const float dz) {
Stick s1(x1, y1, 1.0f / 32767.0f);
Stick s2(x2, y2, 1.0f / 32767.0f);
float magnitude1 = sqrtf(s1.x * s1.x + s1.y * s1.y);
float magnitude2 = sqrtf(s2.x * s2.x + s2.y * s2.y);
if (magnitude1 > dz || magnitude2 > dz) {
return x1 != x2 || y1 != y2;
}
return false;
}
bool NormalizedDeadzoneDiffers(u8 x1, u8 x2, const u8 thresh) {
if (x1 > thresh || x2 > thresh) {
return x1 != x2;
}
return false;
}
int XinputDevice::UpdateState() {
#if !PPSSPP_PLATFORM(UWP)
if (!s_pXInputDLL)
return 0;
#endif
bool anySuccess = false;
for (int i = 0; i < XUSER_MAX_COUNT; i++) {
XINPUT_STATE state;
ZeroMemory(&state, sizeof(XINPUT_STATE));
if (check_delay[i]-- > 0)
continue;
DWORD dwResult = PPSSPP_XInputGetState(i, &state);
if (dwResult == ERROR_SUCCESS) {
UpdatePad(i, state);
anySuccess = true;
} else {
check_delay[i] = 30;
}
}
// If we get XInput, skip the others. This might not actually be a good idea,
// and was done to avoid conflicts between DirectInput and XInput.
return anySuccess ? UPDATESTATE_SKIP_PAD : 0;
}
void XinputDevice::UpdatePad(int pad, const XINPUT_STATE &state) {
static bool notified = false;
if (!notified) {
notified = true;
KeyMap::NotifyPadConnected("Xbox 360 Pad");
}
ApplyButtons(pad, state);
const float STICK_DEADZONE = g_Config.fXInputAnalogDeadzone;
const int STICK_INV_MODE = g_Config.iXInputAnalogInverseMode;
const float STICK_INV_DEADZONE = g_Config.fXInputAnalogInverseDeadzone;
const float STICK_SENSITIVITY = g_Config.fXInputAnalogSensitivity;
if (NormalizedDeadzoneDiffers(prevState[pad].Gamepad.sThumbLX, prevState[pad].Gamepad.sThumbLY, state.Gamepad.sThumbLX, state.Gamepad.sThumbLY, STICK_DEADZONE)) {
Stick left = NormalizedDeadzoneFilter(state.Gamepad.sThumbLX, state.Gamepad.sThumbLY, STICK_DEADZONE, STICK_INV_MODE, STICK_INV_DEADZONE, STICK_SENSITIVITY);
AxisInput axis;
axis.deviceId = DEVICE_ID_X360_0 + pad;
axis.axisId = JOYSTICK_AXIS_X;
axis.value = left.x;
if (prevState[pad].Gamepad.sThumbLX != state.Gamepad.sThumbLX) {
NativeAxis(axis);
}
axis.axisId = JOYSTICK_AXIS_Y;
axis.value = left.y;
if (prevState[pad].Gamepad.sThumbLY != state.Gamepad.sThumbLY) {
NativeAxis(axis);
}
}
if (NormalizedDeadzoneDiffers(prevState[pad].Gamepad.sThumbRX, prevState[pad].Gamepad.sThumbRY, state.Gamepad.sThumbRX, state.Gamepad.sThumbRY, STICK_DEADZONE)) {
Stick right = NormalizedDeadzoneFilter(state.Gamepad.sThumbRX, state.Gamepad.sThumbRY, STICK_DEADZONE, STICK_INV_MODE, STICK_INV_DEADZONE, STICK_SENSITIVITY);
AxisInput axis;
axis.deviceId = DEVICE_ID_X360_0 + pad;
axis.axisId = JOYSTICK_AXIS_Z;
axis.value = right.x;
if (prevState[pad].Gamepad.sThumbRX != state.Gamepad.sThumbRX) {
NativeAxis(axis);
}
axis.axisId = JOYSTICK_AXIS_RZ;
axis.value = right.y;
if (prevState[pad].Gamepad.sThumbRY != state.Gamepad.sThumbRY) {
NativeAxis(axis);
}
}
if (NormalizedDeadzoneDiffers(prevState[pad].Gamepad.bLeftTrigger, state.Gamepad.bLeftTrigger, XINPUT_GAMEPAD_TRIGGER_THRESHOLD)) {
AxisInput axis;
axis.deviceId = DEVICE_ID_X360_0 + pad;
axis.axisId = JOYSTICK_AXIS_LTRIGGER;
axis.value = (float)state.Gamepad.bLeftTrigger / 255.0f;
NativeAxis(axis);
}
if (NormalizedDeadzoneDiffers(prevState[pad].Gamepad.bRightTrigger, state.Gamepad.bRightTrigger, XINPUT_GAMEPAD_TRIGGER_THRESHOLD)) {
AxisInput axis;
axis.deviceId = DEVICE_ID_X360_0 + pad;
axis.axisId = JOYSTICK_AXIS_RTRIGGER;
axis.value = (float)state.Gamepad.bRightTrigger / 255.0f;
NativeAxis(axis);
}
prevState[pad] = state;
check_delay[pad] = 0;
}
void XinputDevice::ApplyButtons(int pad, const XINPUT_STATE &state) {
u32 buttons = state.Gamepad.wButtons;
u32 downMask = buttons & (~prevButtons[pad]);
u32 upMask = (~buttons) & prevButtons[pad];
prevButtons[pad] = buttons;
for (int i = 0; i < xinput_ctrl_map_size; i++) {
if (downMask & xinput_ctrl_map[i].from) {
KeyInput key;
key.deviceId = DEVICE_ID_X360_0 + pad;
key.flags = KEY_DOWN;
key.keyCode = xinput_ctrl_map[i].to;
NativeKey(key);
}
if (upMask & xinput_ctrl_map[i].from) {
KeyInput key;
key.deviceId = DEVICE_ID_X360_0 + pad;
key.flags = KEY_UP;
key.keyCode = xinput_ctrl_map[i].to;
NativeKey(key);
}
}
}