/* * Copyright (c) 2009, Wei Mingzhi . * All Rights Reserved. * * This program is free software; you can redistribute it and/or modify * it under the terms of the GNU General Public License as published by * the Free Software Foundation; either version 2 of the License, or * (at your option) any later version. * * This program is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. * * You should have received a copy of the GNU General Public License * along with this program; if not, see . */ #include "pad.h" void InitAnalog() { g.PadState[0].AnalogStatus[ANALOG_LEFT][0] = 127; g.PadState[0].AnalogStatus[ANALOG_LEFT][1] = 127; g.PadState[0].AnalogStatus[ANALOG_RIGHT][0] = 127; g.PadState[0].AnalogStatus[ANALOG_RIGHT][1] = 127; g.PadState[1].AnalogStatus[ANALOG_LEFT][0] = 127; g.PadState[1].AnalogStatus[ANALOG_LEFT][1] = 127; g.PadState[1].AnalogStatus[ANALOG_RIGHT][0] = 127; g.PadState[1].AnalogStatus[ANALOG_RIGHT][1] = 127; memset(g.PadState[0].AnalogKeyStatus, 0, sizeof(g.PadState[0].AnalogKeyStatus)); memset(g.PadState[1].AnalogKeyStatus, 0, sizeof(g.PadState[1].AnalogKeyStatus)); } void CheckAnalog() { int i, j, k, val; uint8_t n; for (i = 0; i < 2; i++) { if (g.cfg.PadDef[i].Type != PSE_PAD_TYPE_ANALOGPAD) { continue; } for (j = 0; j < ANALOG_TOTAL; j++) { for (k = 0; k < 4; k++) { if (g.PadState[i].AnalogKeyStatus[j][k]) { switch (k) { case ANALOG_XP: g.PadState[i].AnalogStatus[j][0] = 255; k++; break; case ANALOG_XM: g.PadState[i].AnalogStatus[j][0] = 0; break; case ANALOG_YP: g.PadState[i].AnalogStatus[j][1] = 255; k++; break; case ANALOG_YM: g.PadState[i].AnalogStatus[j][1] = 0; break; } continue; } switch (g.cfg.PadDef[i].AnalogDef[j][k].JoyEvType) { case AXIS: n = abs(g.cfg.PadDef[i].AnalogDef[j][k].J.Axis) - 1; if (g.cfg.PadDef[i].AnalogDef[j][k].J.Axis > 0) { val = SDL_JoystickGetAxis(g.PadState[i].JoyDev, n); if (val >= 0) { val += 32640; val /= 256; switch (k) { case ANALOG_XP: g.PadState[i].AnalogStatus[j][0] = val; break; case ANALOG_XM: g.PadState[i].AnalogStatus[j][0] = 255 - val; break; case ANALOG_YP: g.PadState[i].AnalogStatus[j][1] = val; break; case ANALOG_YM: g.PadState[i].AnalogStatus[j][1] = 255 - val; break; } } } else if (g.cfg.PadDef[i].AnalogDef[j][k].J.Axis < 0) { val = SDL_JoystickGetAxis(g.PadState[i].JoyDev, n); if (val <= 0) { val += 32640; val /= 256; switch (k) { case ANALOG_XP: g.PadState[i].AnalogStatus[j][0] = 255 - val; break; case ANALOG_XM: g.PadState[i].AnalogStatus[j][0] = val; break; case ANALOG_YP: g.PadState[i].AnalogStatus[j][1] = 255 - val; break; case ANALOG_YM: g.PadState[i].AnalogStatus[j][1] = val; break; } } } break; case HAT: n = (g.cfg.PadDef[i].AnalogDef[j][k].J.Hat >> 8); g.PadState[i].AnalogStatus[j][0] = 0; if (SDL_JoystickGetHat(g.PadState[i].JoyDev, n) & (g.cfg.PadDef[i].AnalogDef[j][k].J.Hat & 0xFF)) { switch (k) { case ANALOG_XP: g.PadState[i].AnalogStatus[j][0] = 255; k++; break; case ANALOG_XM: g.PadState[i].AnalogStatus[j][0] = 0; break; case ANALOG_YP: g.PadState[i].AnalogStatus[j][1] = 255; k++; break; case ANALOG_YM: g.PadState[i].AnalogStatus[j][1] = 0; break; } } else { switch (k) { case ANALOG_XP: g.PadState[i].AnalogStatus[j][0] = 127; break; case ANALOG_XM: g.PadState[i].AnalogStatus[j][0] = 127; break; case ANALOG_YP: g.PadState[i].AnalogStatus[j][1] = 127; break; case ANALOG_YM: g.PadState[i].AnalogStatus[j][1] = 127; break; } } break; case BUTTON: if (SDL_JoystickGetButton(g.PadState[i].JoyDev, g.cfg.PadDef[i].AnalogDef[j][k].J.Button)) { switch (k) { case ANALOG_XP: g.PadState[i].AnalogStatus[j][0] = 255; k++; break; case ANALOG_XM: g.PadState[i].AnalogStatus[j][0] = 0; break; case ANALOG_YP: g.PadState[i].AnalogStatus[j][1] = 255; k++; break; case ANALOG_YM: g.PadState[i].AnalogStatus[j][1] = 0; break; } } else { switch (k) { case ANALOG_XP: g.PadState[i].AnalogStatus[j][0] = 127; break; case ANALOG_XM: g.PadState[i].AnalogStatus[j][0] = 127; break; case ANALOG_YP: g.PadState[i].AnalogStatus[j][1] = 127; break; case ANALOG_YM: g.PadState[i].AnalogStatus[j][1] = 127; break; } } break; default: switch (k) { case ANALOG_XP: g.PadState[i].AnalogStatus[j][0] = 127; break; case ANALOG_XM: g.PadState[i].AnalogStatus[j][0] = 127; break; case ANALOG_YP: g.PadState[i].AnalogStatus[j][1] = 127; break; case ANALOG_YM: g.PadState[i].AnalogStatus[j][1] = 127; break; } break; } } } } } int AnalogKeyPressed(uint16_t Key) { int i, j, k; for (i = 0; i < 2; i++) { if (g.cfg.PadDef[i].Type != PSE_PAD_TYPE_ANALOGPAD) { continue; } for (j = 0; j < ANALOG_TOTAL; j++) { for (k = 0; k < 4; k++) { if (g.cfg.PadDef[i].AnalogDef[j][k].Key == Key) { g.PadState[i].AnalogKeyStatus[j][k] = 1; return 1; } } } } return 0; } int AnalogKeyReleased(uint16_t Key) { int i, j, k; for (i = 0; i < 2; i++) { if (g.cfg.PadDef[i].Type != PSE_PAD_TYPE_ANALOGPAD) { continue; } for (j = 0; j < ANALOG_TOTAL; j++) { for (k = 0; k < 4; k++) { if (g.cfg.PadDef[i].AnalogDef[j][k].Key == Key) { g.PadState[i].AnalogKeyStatus[j][k] = 0; return 1; } } } } return 0; }