#define WINVER 0x0500 #define _WIN32_WINNT WINVER #define DIRECTINPUT_VERSION 0x0800 #include #include #include #include #include "PadSSSPSX.h" static const char* LibraryName = "SSSPSX PAD Plugin Pressure Mod"; static const unsigned char version = 0x0002; static const unsigned char revision = 1; static const unsigned char build = 6; HMODULE hInstance; HWND hTargetWnd; static struct { Config config; int devcnt; LPDIRECTINPUT8 pDInput; LPDIRECTINPUTDEVICE8 pDKeyboard; LPDIRECTINPUTDEVICE8 pDDevice[4]; LPDIRECTINPUTEFFECT pDEffect[4][2]; /* for Small & Big Motor */ DIJOYSTATE JoyState[4]; u16 padStat[2]; int padID[2]; int padMode1[2]; int padMode2[2]; int padModeE[2]; int padModeC[2]; int padModeF[2]; int padVib0[2]; int padVib1[2]; int padVibF[2][4]; int padVibC[2]; DWORD padPress[2][16]; int curPad; int curByte; int curCmd; int cmdLen; } global; static BOOL CALLBACK EnumAxesCallback (LPCDIDEVICEOBJECTINSTANCE lpddoi, LPVOID pvRef) { LPDIRECTINPUTDEVICE8 pDDevice = (LPDIRECTINPUTDEVICE8)pvRef; DIPROPRANGE diprg; diprg.diph.dwSize = sizeof (diprg); diprg.diph.dwHeaderSize = sizeof (diprg.diph); diprg.diph.dwObj = lpddoi->dwType; diprg.diph.dwHow = DIPH_BYID; diprg.lMin = -128; diprg.lMax = 127; pDDevice->SetProperty (DIPROP_RANGE, &diprg.diph); return DIENUM_CONTINUE; } static BOOL CALLBACK EnumJoysticksCallback (const DIDEVICEINSTANCE* instance, VOID* pContext) { const int devno = global.devcnt; if (devno >= 4) return DIENUM_STOP; HRESULT result = global.pDInput->CreateDevice (instance->guidInstance, &global.pDDevice[devno], NULL); if (FAILED (result)) return DIENUM_CONTINUE; global.devcnt++; return DIENUM_CONTINUE; } static bool ReleaseDirectInput (void) { int index = 4; while (index--) { if (global.pDEffect[index][0]) { global.pDEffect[index][0]->Unload(); global.pDEffect[index][0]->Release(); global.pDEffect[index][0] = NULL; } if (global.pDEffect[index][1]) { global.pDEffect[index][1]->Unload(); global.pDEffect[index][1]->Release(); global.pDEffect[index][1] = NULL; } if (global.pDDevice[index]) { global.pDDevice[index]->Unacquire(); global.pDDevice[index]->Release(); global.pDDevice[index] = NULL; } } if (global.pDKeyboard) { global.pDKeyboard->Unacquire(); global.pDKeyboard->Release(); global.pDKeyboard = NULL; } if (global.pDInput) { global.pDInput->Release(); global.pDInput = NULL; } global.devcnt = 0; return FALSE; } static bool InitDirectInput (void) { if (global.pDInput) return TRUE; HRESULT result = DirectInput8Create (hInstance, DIRECTINPUT_VERSION, IID_IDirectInput8, (void**)&global.pDInput, NULL); if (FAILED (result)) return ReleaseDirectInput(); result = global.pDInput->CreateDevice (GUID_SysKeyboard, &global.pDKeyboard, NULL); if (FAILED (result)) return ReleaseDirectInput(); result = global.pDInput->EnumDevices (DI8DEVCLASS_GAMECTRL, EnumJoysticksCallback, NULL, DIEDFL_ATTACHEDONLY); if (FAILED (result)) return ReleaseDirectInput(); result = global.pDKeyboard->SetDataFormat (&c_dfDIKeyboard); if (FAILED (result)) return ReleaseDirectInput(); if (hTargetWnd) { global.pDKeyboard->Unacquire(); result = global.pDKeyboard->SetCooperativeLevel (hTargetWnd, DISCL_FOREGROUND | DISCL_NONEXCLUSIVE); if (FAILED (result)) return ReleaseDirectInput(); } int index = global.devcnt; while (index--) { const LPDIRECTINPUTDEVICE8 pDDevice = global.pDDevice[index]; result = pDDevice->SetDataFormat (&c_dfDIJoystick); if (FAILED (result)) return ReleaseDirectInput(); if (hTargetWnd) { pDDevice->Unacquire(); result = pDDevice->SetCooperativeLevel (hTargetWnd, DISCL_FOREGROUND | DISCL_EXCLUSIVE); if (FAILED (result)) return ReleaseDirectInput(); } struct { DIPROPDWORD dipdw; DWORD rgdwAxes[2]; LONG rglDirection[2]; DIPERIODIC per; DICONSTANTFORCE cf; DIEFFECT eff; } local; memset (&local, 0, sizeof (local)); local.dipdw.diph.dwSize = sizeof (DIPROPDWORD); local.dipdw.diph.dwHeaderSize = sizeof (DIPROPHEADER); local.dipdw.diph.dwHow = DIPH_DEVICE; local.dipdw.dwData = DIPROPAUTOCENTER_OFF; pDDevice->SetProperty (DIPROP_AUTOCENTER, &local.dipdw.diph); result = pDDevice->EnumObjects (EnumAxesCallback, pDDevice, DIDFT_AXIS); if (FAILED (result)) return ReleaseDirectInput(); local.rgdwAxes[0] = DIJOFS_X; local.rgdwAxes[1] = DIJOFS_Y; local.eff.dwSize = sizeof (DIEFFECT); local.eff.dwFlags = DIEFF_CARTESIAN | DIEFF_OBJECTOFFSETS; local.eff.dwDuration = INFINITE; local.eff.dwGain = DI_FFNOMINALMAX; local.eff.dwTriggerButton = DIEB_NOTRIGGER; local.eff.cAxes = 2; local.eff.rgdwAxes = local.rgdwAxes; local.eff.rglDirection = local.rglDirection; /* Small Motor */ local.eff.cbTypeSpecificParams = sizeof (DIPERIODIC); local.eff.lpvTypeSpecificParams = &local.per; result = pDDevice->CreateEffect (GUID_Square , &local.eff, &global.pDEffect[index][0], NULL); if (FAILED (result)) global.pDEffect[index][0] = NULL; /* Big Motor */ local.eff.cbTypeSpecificParams = sizeof (DICONSTANTFORCE); local.eff.lpvTypeSpecificParams = &local.cf; result = pDDevice->CreateEffect (GUID_ConstantForce , &local.eff, &global.pDEffect[index][1], NULL); if (FAILED (result)) global.pDEffect[index][1] = NULL; } return TRUE; } static bool AcquireDevice (LPDIRECTINPUTDEVICE8 lpDirectInputDevice) { if (FAILED (lpDirectInputDevice->Acquire())) { HRESULT result = lpDirectInputDevice->Acquire(); if (result == DIERR_OTHERAPPHASPRIO) return FALSE; if (FAILED (result)) return ReleaseDirectInput(); } return TRUE; } /* Small Motor */ static bool SetDeviceForceS (int pad, DWORD force) { InitDirectInput(); if (global.pDEffect[pad][0]) { if ( force == 0) { if (FAILED (global.pDEffect[pad][0]->Stop())) { AcquireDevice (global.pDDevice[pad]); if (FAILED (global.pDEffect[pad][0]->Stop())) return ReleaseDirectInput(); } return TRUE; } LONG rglDirection[2] = { 0, 0 }; DIPERIODIC per; rglDirection[0] = force; rglDirection[1] = force; per.dwMagnitude = force; per.dwPeriod = (DWORD) (0.01 * DI_SECONDS); per.lOffset = 0; per.dwPhase = 0; DIEFFECT eff; eff.dwSize = sizeof (DIEFFECT); eff.dwFlags = DIEFF_CARTESIAN | DIEFF_OBJECTOFFSETS; eff.cAxes = 2; eff.rglDirection = rglDirection; eff.lpEnvelope = 0; eff.cbTypeSpecificParams = sizeof (DIPERIODIC); eff.lpvTypeSpecificParams = &per; if (FAILED (global.pDEffect[pad][0]->SetParameters (&eff, DIEP_DIRECTION | DIEP_TYPESPECIFICPARAMS | DIEP_START))) return ReleaseDirectInput(); if (FAILED (global.pDEffect[pad][0]->Start (1, 0))) { AcquireDevice (global.pDDevice[pad]); if (FAILED (global.pDEffect[pad][0]->Start (1, 0))) return ReleaseDirectInput(); } } return TRUE; } /* Big Motor */ static bool SetDeviceForceB (int pad, DWORD force) { InitDirectInput(); if (global.pDEffect[pad][1]) { if ( force == 0) { if (FAILED (global.pDEffect[pad][1]->Stop())) { AcquireDevice (global.pDDevice[pad]); if (FAILED (global.pDEffect[pad][1]->Stop())) return ReleaseDirectInput(); } return TRUE; } LONG rglDirection[2] = { 0, 0 }; DICONSTANTFORCE cf; rglDirection[0] = force; rglDirection[1] = force; cf.lMagnitude = force; DIEFFECT eff; eff.dwSize = sizeof (DIEFFECT); eff.dwFlags = DIEFF_CARTESIAN | DIEFF_OBJECTOFFSETS; eff.cAxes = 2; eff.rglDirection = rglDirection; eff.lpEnvelope = 0; eff.cbTypeSpecificParams = sizeof (DICONSTANTFORCE); eff.lpvTypeSpecificParams = &cf; if (FAILED (global.pDEffect[pad][1]->SetParameters (&eff, DIEP_DIRECTION | DIEP_TYPESPECIFICPARAMS | DIEP_START))) return ReleaseDirectInput(); if (FAILED (global.pDEffect[pad][1]->Start (1, 0))) { AcquireDevice (global.pDDevice[pad]); if (FAILED (global.pDEffect[pad][1]->Start (1, 0))) return ReleaseDirectInput(); } } return TRUE; } static bool GetJoyState (const int devno) { InitDirectInput(); if (global.pDDevice[devno] == NULL) return FALSE; global.pDDevice[devno]->Poll(); if (FAILED (global.pDDevice[devno]->GetDeviceState (sizeof (DIJOYSTATE), &global.JoyState[devno]))) { AcquireDevice (global.pDDevice[devno]); return FALSE; } return TRUE; } static bool GetKeyState (u8* keyboard) { InitDirectInput(); if (global.pDKeyboard == NULL) return FALSE; global.pDKeyboard->Poll(); if (FAILED (global.pDKeyboard->GetDeviceState (256, keyboard))) { AcquireDevice (global.pDKeyboard); return FALSE; } return TRUE; } static void MakeConfigFileName (char* fname) { GetModuleFileName (hInstance, fname, 256); strcpy (fname + strlen (fname) - 3, "cfg"); } static void SaveConfig (void) { char fname[256]; MakeConfigFileName (fname); HANDLE hFile = CreateFile (fname, GENERIC_WRITE, FILE_SHARE_READ, NULL, CREATE_ALWAYS, FILE_FLAG_SEQUENTIAL_SCAN, NULL); if (hFile != INVALID_HANDLE_VALUE) { DWORD number_of_bytes; WriteFile (hFile, &global.config, sizeof (global.config), &number_of_bytes, NULL); CloseHandle (hFile); } } static void LoadConfig (void) { char fname[256]; MakeConfigFileName (fname); HANDLE hFile = CreateFile (fname, GENERIC_READ, FILE_SHARE_READ, NULL, OPEN_EXISTING, FILE_FLAG_SEQUENTIAL_SCAN, NULL); if (hFile != INVALID_HANDLE_VALUE) { DWORD number_of_bytes; ReadFile (hFile, &global.config, sizeof (global.config), &number_of_bytes, NULL); CloseHandle (hFile); } global.padVibC[0] = global.padVibC[1] = -1; for (int cnt = 21; cnt--; ) { const int key0 = global.config.keys[0][cnt]; if (key0 >= 0x1000) global.padVibC[0] = (key0 & 0xfff) / 0x100; const int key1 = global.config.keys[1][cnt]; if (key1 >= 0x1000) global.padVibC[1] = (key1 & 0xfff) / 0x100; } } static void PADsetMode (const int pad, const int mode) { static const u8 padID[] = { 0x41, 0x73, 0x41, 0x79 }; global.padMode1[pad] = mode; global.padVib0[pad] = 0; global.padVib1[pad] = 0; global.padVibF[pad][0] = 0; global.padVibF[pad][1] = 0; global.padID[pad] = padID[global.padMode2[pad] * 2 + mode]; } static void KeyPress (const int pad, const int index, const bool press) { if (index < 16) { if (press) { global.padStat[pad] &= ~(1 << index); if (global.padPress[pad][index] == 0) global.padPress[pad][index] = GetTickCount(); } else { global.padStat[pad] |= 1 << index; global.padPress[pad][index] = 0; } } else { static bool prev[2] = { FALSE, FALSE }; if ((prev[pad] != press) && (global.padModeF[pad] == 0)) { prev[pad] = press; if (press) PADsetMode (pad, !global.padMode1[pad]); } } } static void UpdateState (const int pad) { static int flag_keyboard; static int flag_joypad[4]; if (pad == 0) { flag_keyboard = 0; flag_joypad[0] = 0; flag_joypad[1] = 0; flag_joypad[2] = 0; flag_joypad[3] = 0; } static u8 keystate[256]; for (int index = 17; index--; ) { const int key = global.config.keys[pad][index]; if (key == 0) continue; else if (key < 0x100) { if (flag_keyboard == FALSE) { flag_keyboard = TRUE; if (GetKeyState (keystate) == FALSE) return; } KeyPress (pad, index, keystate[key] & 0x80); } else { const int joypad = ((key & 0xfff) / 100); if (flag_joypad[joypad] == FALSE) { flag_joypad[joypad] = TRUE; if (GetJoyState (joypad) == FALSE) return; } if (key < 0x2000) { KeyPress (pad, index, global.JoyState[joypad].rgbButtons[key & 0xff]); } else if (key < 0x3000) { const int state = ((int*)&global.JoyState[joypad].lX)[(key & 0xff) /2]; switch (key & 1) { case 0: KeyPress (pad, index, state < -64); break; case 1: KeyPress (pad, index, state >= 64); break; } } else { const u32 state = global.JoyState[joypad].rgdwPOV[(key & 0xff) /4]; switch (key & 3) { case 0: KeyPress (pad, index, (state >= 0 && state <= 4500) || (state >= 31500 && state <= 36000)); break; case 1: KeyPress (pad, index, state >= 4500 && state <= 13500); break; case 2: KeyPress (pad, index, state >= 13500 && state <= 22500); break; case 3: KeyPress (pad, index, state >= 22500 && state <= 31500); break; } } } } /* Small Motor */ const int vib0 = global.padVibF[pad][0] ? 10000 : 0; if ((global.padVibF[pad][2] != vib0) && (global.padVibC[pad] >= 0)) { global.padVibF[pad][2] = vib0; SetDeviceForceS (global.padVibC[pad], vib0); } /* Big Motor */ const int vib1 = global.padVibF[pad][1] ? 500 + 37*global.padVibF[pad][1] : 0; if ((global.padVibF[pad][3] != vib1) && (global.padVibC[pad] >= 0)) { global.padVibF[pad][3] = vib1; SetDeviceForceB (global.padVibC[pad], vib1); } } static void set_label (const HWND hWnd, const int pad, const int index) { const int key = global.config.keys[pad][index]; char buff[64]; if (key < 0x100) { if (key == 0) strcpy (buff, "NONE"); else if (GetKeyNameText (key << 16, buff, sizeof (buff)) == 0) wsprintf (buff, "Keyboard 0x%02X", key); } else if (key >= 0x1000 && key < 0x2000) { wsprintf (buff, "J%d_%d", (key & 0xfff) / 0x100, (key & 0xff) + 1); } else if (key >= 0x2000 && key < 0x3000) { static const char name[][4] = { "MIN", "MAX" }; const int axis = (key & 0xff); wsprintf (buff, "J%d_AXIS%d_%s", (key & 0xfff) / 0x100, axis / 2, name[axis % 2]); if (index >= 17 && index <= 20) buff[strlen (buff) -4] = '\0'; } else if (key >= 0x3000 && key < 0x4000) { static const char name[][7] = { "FOWARD", "RIGHT", "BACK", "LEFT" }; const int pov = (key & 0xff); wsprintf (buff, "J%d_POV%d_%s", (key & 0xfff) / 0x100, pov /4, name[pov % 4]); } Button_SetText (GetDlgItem (hWnd, IDC_ESELECT + index), buff); } static BOOL CALLBACK ConfigureDlgProc (const HWND hWnd, const UINT msg, const WPARAM wParam, const LPARAM lParam) { static BYTE keymaps[2][256]; static DWORD countdown; static int disabled; static HWND hTabWnd; static int pad; int cnt1; int cnt2; int key; switch (msg) { case WM_INITDIALOG: hTargetWnd = hWnd; pad = disabled = 0; LoadConfig(); for (cnt1 = 21; cnt1--; ) set_label (hWnd, pad, cnt1); hTabWnd = GetDlgItem (hWnd, IDC_TABC); TCITEM tcI; tcI.mask = TCIF_TEXT; tcI.pszText = "PAD1"; TabCtrl_InsertItem (hTabWnd, 0, &tcI); tcI.mask = TCIF_TEXT; tcI.pszText = "PAD2"; TabCtrl_InsertItem (hTabWnd, 1, &tcI); SetTimer (hWnd, 0x80, 50, NULL); return TRUE; case WM_DESTROY: break; case WM_NOTIFY: if (wParam == IDC_TABC) { if (disabled) EnableWindow (GetDlgItem (hWnd, disabled), TRUE); disabled = 0; pad = TabCtrl_GetCurSel (hTabWnd); for (cnt1 = 21; cnt1--; ) set_label (hWnd, pad, cnt1); } break; case WM_COMMAND: for (cnt1 = 21; cnt1--; ) { if (LOWORD (wParam) == IDC_BSELECT + cnt1) { if (disabled) EnableWindow (GetDlgItem (hWnd, disabled), TRUE); EnableWindow (GetDlgItem (hWnd, disabled = wParam), FALSE); countdown = GetTickCount(); GetKeyState (keymaps[0]); return TRUE; } } if (LOWORD (wParam) == IDOK) EndDialog (hWnd, IDOK); else if (LOWORD (wParam) == IDCANCEL) EndDialog (hWnd, IDCANCEL); break; case WM_TIMER: if (disabled) { const int index = disabled - IDC_BSELECT; int analog = FALSE; if ((GetTickCount() - countdown) / 1000 != 10) { char buff[64]; wsprintf (buff, "Timeout: %d", 10 - (GetTickCount() - countdown) / 1000); SetWindowText (GetDlgItem (hWnd, IDC_ESELECT + index), buff); } else { global.config.keys[pad][index] = 0; set_label (hWnd, pad, index); EnableWindow (GetDlgItem (hWnd, disabled), TRUE); disabled = 0; break; } if (GetKeyState (keymaps[1]) == FALSE) break; for (key = 0x100; key--; ) { if (~keymaps[0][key] & keymaps[1][key] & 0x80) break; } for (cnt1 = global.devcnt; cnt1--;) { if (GetJoyState (cnt1) == FALSE) break; for (cnt2 = 32; cnt2--; ) { if (global.JoyState[cnt1].rgbButtons[cnt2]) key = 0x1000 + 0x100 * cnt1 + cnt2; } for (cnt2 = 8; cnt2--; ) { const int now = ((u32*)&global.JoyState[cnt1].lX)[cnt2]; if (now < -64) { key = 0x2000 + 0x100 * cnt1 + cnt2 * 2 +0; analog = TRUE; } else if (now >= 64) { key = 0x2000 + 0x100 * cnt1 + cnt2 * 2 +1; analog = TRUE; } } for (cnt2 = 4; cnt2--; ) { const u32 now = global.JoyState[cnt1].rgdwPOV[cnt2]; if ((now >= 0 && now < 4500) || (now >= 31500 && now < 36000)) key = 0x3000 + 0x100 * cnt1 + cnt2 * 4 +0; if (now >= 4500 && now < 13500) key = 0x3000 + 0x100 * cnt1 + cnt2 * 4 +1; if (now >= 13500 && now < 22500) key = 0x3000 + 0x100 * cnt1 + cnt2 * 4 +2; if (now >= 22500 && now < 31500) key = 0x3000 + 0x100 * cnt1 + cnt2 * 4 +3; } } if (index >= 17 && index <= 20 && analog == 0) key = 0; else if (key > 0) { if (key != 1) global.config.keys[pad][index] = key; set_label (hWnd, pad, index); EnableWindow (GetDlgItem (hWnd, disabled), TRUE); disabled = 0; } } } return FALSE; } u32 CALLBACK PS2EgetLibType (void) { return 0x02; } const char* CALLBACK PS2EgetLibName (void) { return LibraryName; } u32 CALLBACK PS2EgetLibVersion2 (u32 type) { return (version << 16) | (revision << 8) | build; } u32 CALLBACK PSEgetLibType (void) { return 8; } const char* CALLBACK PSEgetLibName (void) { return LibraryName; } u32 CALLBACK PSEgetLibVersion (void) { return (version << 16) | (revision << 8) | build; } s32 CALLBACK PADinit (u32 flags) { return 0; } void CALLBACK PADshutdown (void) { } static int n_open = 0; s32 CALLBACK PADopen (HWND hWnd) { if (!IsWindow (hWnd) && !IsBadReadPtr ((u32*)hWnd, 4)) hWnd = *(HWND*)hWnd; if (!IsWindow (hWnd)) hWnd = NULL; else { while (GetWindowLong (hWnd, GWL_STYLE) & WS_CHILD) hWnd = GetParent (hWnd); } hTargetWnd = hWnd; if (n_open++ == FALSE) { memset (&global, 0, sizeof (global)); global.padStat[0] = 0xffff; global.padStat[1] = 0xffff; LoadConfig(); PADsetMode (0, 0); PADsetMode (1, 0); } return 0; } void CALLBACK PADclose (void) { if (--n_open == 0) ReleaseDirectInput(); } u32 CALLBACK PADquery (void) { return 3; } u8 CALLBACK PADstartPoll (int pad) { global.curPad = pad -1; global.curByte = 0; return 0xff; } static const u8 cmd40[8] = { 0xff, 0x5a, 0x00, 0x00, 0x02, 0x00, 0x00, 0x5a }; static const u8 cmd41[8] = { 0xff, 0x5a, 0xff, 0xff, 0x03, 0x00, 0x00, 0x5a, }; static const u8 cmd44[8] = { 0xff, 0x5a, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, }; static const u8 cmd45[8] = { 0xff, 0x5a, 0x03, 0x02, 0x01, 0x02, 0x01, 0x00, }; static const u8 cmd46[8] = { 0xff, 0x5a, 0x00, 0x00, 0x01, 0x02, 0x00, 0x0a, }; static const u8 cmd47[8] = { 0xff, 0x5a, 0x00, 0x00, 0x02, 0x00, 0x01, 0x00, }; static const u8 cmd4c[8] = { 0xff, 0x5a, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, }; static const u8 cmd4d[8] = { 0xff, 0x5a, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff, }; static const u8 cmd4f[8] = { 0xff, 0x5a, 0x00, 0x00, 0x00, 0x00, 0x00, 0x5a, }; static u8 get_analog (const int key) { const int pad = ((key & 0xf00) / 0x100); const int pos = ((key & 0x0ff) /2); return (u8)(((int*)&global.JoyState[pad].lX)[pos] + 128); } static u8 get_pressure (const DWORD now, const DWORD press) { /*if (press == 0) return 0; return (u8)((now - press > 2550) ? 255 : (now - press) / 10);*/ return 255; } u8 CALLBACK PADpoll (const u8 value) { const int pad = global.curPad; const int cur = global.curByte; static u8 buf[20]; if (cur == 0) { global.curByte++; global.curCmd = value; switch (value) { case 0x40: global.cmdLen = sizeof (cmd40); memcpy (buf, cmd40, sizeof (cmd40)); return 0xf3; case 0x41: global.cmdLen = sizeof (cmd41); memcpy (buf, cmd41, sizeof (cmd41)); return 0xf3; case 0x42: case 0x43: if (value == 0x42) UpdateState (pad); global.cmdLen = 2 + 2 * (global.padID[pad] & 0x0f); buf[1] = global.padModeC[pad] ? 0x00 : 0x5a; *(u16*)&buf[2] = global.padStat[pad]; if (value == 0x43 && global.padModeE[pad]) { buf[4] = 0; buf[5] = 0; buf[6] = 0; buf[7] = 0; return 0xf3; } else { buf[ 4] = get_analog (global.config.keys[pad][19]); buf[ 5] = get_analog (global.config.keys[pad][20]); buf[ 6] = get_analog (global.config.keys[pad][17]); buf[ 7] = get_analog (global.config.keys[pad][18]); if (global.padID[pad] == 0x79) { const DWORD now = GetTickCount(); buf[ 8] = get_pressure (now, global.padPress[pad][2]); buf[ 9] = get_pressure (now, global.padPress[pad][0]); buf[10] = get_pressure (now, global.padPress[pad][3]); buf[11] = get_pressure (now, global.padPress[pad][1]); buf[12] = get_pressure (now, global.padPress[pad][11]); buf[13] = get_pressure (now, global.padPress[pad][10]); buf[14] = get_pressure (now, global.padPress[pad][9]); buf[15] = get_pressure (now, global.padPress[pad][8]); buf[16] = get_pressure (now, global.padPress[pad][13]); buf[17] = get_pressure (now, global.padPress[pad][12]); buf[18] = get_pressure (now, global.padPress[pad][15]); buf[19] = get_pressure (now, global.padPress[pad][14]); } return (u8)global.padID[pad]; } break; case 0x44: global.cmdLen = sizeof (cmd44); memcpy (buf, cmd44, sizeof (cmd44)); return 0xf3; case 0x45: global.cmdLen = sizeof (cmd45); memcpy (buf, cmd45, sizeof (cmd45)); buf[4] = (u8)global.padMode1[pad]; return 0xf3; case 0x46: global.cmdLen = sizeof (cmd46); memcpy (buf, cmd46, sizeof (cmd46)); return 0xf3; case 0x47: global.cmdLen = sizeof (cmd47); memcpy (buf, cmd47, sizeof (cmd47)); return 0xf3; case 0x4c: global.cmdLen = sizeof (cmd4c); memcpy (buf, cmd4c, sizeof (cmd4c)); return 0xf3; case 0x4d: global.cmdLen = sizeof (cmd4d); memcpy (buf, cmd4d, sizeof (cmd4d)); return 0xf3; case 0x4f: global.padID[pad] = 0x79; global.padMode2[pad] = 1; global.cmdLen = sizeof (cmd4f); memcpy (buf, cmd4f, sizeof (cmd4f)); return 0xf3; } } switch (global.curCmd) { case 0x42: if (cur == global.padVib0[pad]) global.padVibF[pad][0] = value; if (cur == global.padVib1[pad]) global.padVibF[pad][1] = value; break; case 0x43: if (cur == 2) { global.padModeE[pad] = value; global.padModeC[pad] = 0; } break; case 0x44: if (cur == 2) PADsetMode (pad, value); if (cur == 3) global.padModeF[pad] = (value == 3); break; case 0x46: if (cur == 2) { switch(value) { case 0: buf[5] = 0x02; buf[6] = 0x00; buf[7] = 0x0A; break; case 1: buf[5] = 0x01; buf[6] = 0x01; buf[7] = 0x14; break; } } break; case 0x4c: if (cur == 2) { static const u8 buf5[] = { 0x04, 0x07, 0x02, 0x05 }; buf[5] = buf5[value & 3]; } break; case 0x4d: if (cur >= 2) { if (cur == global.padVib0[pad]) buf[cur] = 0x00; if (cur == global.padVib1[pad]) buf[cur] = 0x01; if (value == 0x00) { global.padVib0[pad] = cur; if ((global.padID[pad] & 0x0f) < (cur - 1) / 2) global.padID[pad] = (global.padID[pad] & 0xf0) + (cur - 1) / 2; } else if (value == 0x01) { global.padVib1[pad] = cur; if ((global.padID[pad] & 0x0f) < (cur - 1) / 2) global.padID[pad] = (global.padID[pad] & 0xf0) + (cur - 1) / 2; } } break; } if (cur >= global.cmdLen) return 0; return buf[global.curByte++]; } typedef struct { unsigned char controllerType; unsigned short buttonStatus; unsigned char rightJoyX, rightJoyY, leftJoyX, leftJoyY; unsigned char moveX, moveY; unsigned char reserved[91]; } PadDataS; long PADreadPort1 (PadDataS* pads) { memset (pads, 0, sizeof (PadDataS)); if ((global.padID[0] & 0xf0) == 0x40) pads->controllerType = 4; else pads->controllerType = 7; pads->buttonStatus = global.padStat[0]; pads->leftJoyX = get_analog (global.config.keys[0][17]); pads->leftJoyY = get_analog (global.config.keys[0][18]); pads->rightJoyX = get_analog (global.config.keys[0][19]); pads->rightJoyY = get_analog (global.config.keys[0][20]); pads->moveX = 0; pads->moveY = 0; return 0; } long PADreadPort2 (PadDataS* pads) { memset (pads, 0, sizeof (PadDataS)); if ((global.padID[1] & 0xf0) == 0x40) pads->controllerType = 4; else pads->controllerType = 7; pads->buttonStatus = global.padStat[1]; pads->leftJoyX = get_analog (global.config.keys[1][17]); pads->leftJoyY = get_analog (global.config.keys[1][18]); pads->rightJoyX = get_analog (global.config.keys[1][19]); pads->rightJoyY = get_analog (global.config.keys[1][20]); pads->moveX = 0; pads->moveY = 0; return 0; } keyEvent* CALLBACK PADkeyEvent (void) { static keyEvent ev; static u8 state[2][256]; if (n_open) { memcpy (state[0], state[1], sizeof (state[0])); GetKeyState (state[1]); for (int cnt = 0; cnt < 256; cnt++) { if (~state[0][cnt] & state[1][cnt] & 0x80) { ev.event = (state[1][cnt] & 0x80) ? 1 : 2; ev.key = MapVirtualKey (cnt, 1); return &ev; } } } return NULL; } void CALLBACK PADconfigure (void) { if (n_open == 0) { memset (&global, 0, sizeof (global)); if (DialogBox (hInstance, MAKEINTRESOURCE (IDD_DIALOG1), GetActiveWindow(), (DLGPROC)ConfigureDlgProc) == IDOK) SaveConfig(); ReleaseDirectInput(); } } void CALLBACK PADabout (void) { MessageBox (0, "Copyright (C) 2004-2005 Nagisa", "SSSPSX PAD plugin", 0); } s32 CALLBACK PADtest (void) { return 0; } //#ifdef _WIN64 BOOL APIENTRY DllMain(HMODULE hInst, DWORD dwReason, LPVOID lpReserved) { hInstance = hInst; return TRUE; } //#else BOOL APIENTRY EntryPoint (HMODULE hInst, DWORD dwReason, LPVOID lpReserved) { hInstance = hInst; return TRUE; } //#endif