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|
/***************************************************************************
* Copyright (C) 2007 Ryan Schultz, PCSX-df Team, PCSX team *
* *
* 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, write to the *
* Free Software Foundation, Inc., *
* 51 Franklin Street, Fifth Floor, Boston, MA 02111-1307 USA. *
***************************************************************************/
/*
* Plugin library callback/access functions.
*/
#include "plugins.h"
#include "cdriso.h"
#include "../plugins/dfinput/externals.h"
static char IsoFile[MAXPATHLEN] = "";
static s64 cdOpenCaseTime = 0;
GPUupdateLace GPU_updateLace;
GPUinit GPU_init;
GPUshutdown GPU_shutdown;
GPUconfigure GPU_configure;
GPUtest GPU_test;
GPUabout GPU_about;
GPUopen GPU_open;
GPUclose GPU_close;
GPUreadStatus GPU_readStatus;
GPUreadData GPU_readData;
GPUreadDataMem GPU_readDataMem;
GPUwriteStatus GPU_writeStatus;
GPUwriteData GPU_writeData;
GPUwriteDataMem GPU_writeDataMem;
GPUdmaChain GPU_dmaChain;
GPUkeypressed GPU_keypressed;
GPUdisplayText GPU_displayText;
GPUmakeSnapshot GPU_makeSnapshot;
GPUfreeze GPU_freeze;
GPUgetScreenPic GPU_getScreenPic;
GPUshowScreenPic GPU_showScreenPic;
GPUclearDynarec GPU_clearDynarec;
GPUvBlank GPU_vBlank;
CDRinit CDR_init;
CDRshutdown CDR_shutdown;
CDRopen CDR_open;
CDRclose CDR_close;
CDRtest CDR_test;
CDRgetTN CDR_getTN;
CDRgetTD CDR_getTD;
CDRreadTrack CDR_readTrack;
CDRgetBuffer CDR_getBuffer;
CDRplay CDR_play;
CDRstop CDR_stop;
CDRgetStatus CDR_getStatus;
CDRgetDriveLetter CDR_getDriveLetter;
CDRgetBufferSub CDR_getBufferSub;
CDRconfigure CDR_configure;
CDRabout CDR_about;
CDRsetfilename CDR_setfilename;
CDRreadCDDA CDR_readCDDA;
CDRgetTE CDR_getTE;
SPUconfigure SPU_configure;
SPUabout SPU_about;
SPUinit SPU_init;
SPUshutdown SPU_shutdown;
SPUtest SPU_test;
SPUopen SPU_open;
SPUclose SPU_close;
SPUplaySample SPU_playSample;
SPUwriteRegister SPU_writeRegister;
SPUreadRegister SPU_readRegister;
SPUwriteDMA SPU_writeDMA;
SPUreadDMA SPU_readDMA;
SPUwriteDMAMem SPU_writeDMAMem;
SPUreadDMAMem SPU_readDMAMem;
SPUplayADPCMchannel SPU_playADPCMchannel;
SPUfreeze SPU_freeze;
SPUregisterCallback SPU_registerCallback;
SPUregisterScheduleCb SPU_registerScheduleCb;
SPUasync SPU_async;
SPUplayCDDAchannel SPU_playCDDAchannel;
PADconfigure PAD1_configure;
PADabout PAD1_about;
PADinit PAD1_init;
PADshutdown PAD1_shutdown;
PADtest PAD1_test;
PADopen PAD1_open;
PADclose PAD1_close;
PADquery PAD1_query;
PADreadPort1 PAD1_readPort1;
PADkeypressed PAD1_keypressed;
PADstartPoll PAD1_startPoll;
PADpoll PAD1_poll;
PADsetSensitive PAD1_setSensitive;
PADconfigure PAD2_configure;
PADabout PAD2_about;
PADinit PAD2_init;
PADshutdown PAD2_shutdown;
PADtest PAD2_test;
PADopen PAD2_open;
PADclose PAD2_close;
PADquery PAD2_query;
PADreadPort2 PAD2_readPort2;
PADkeypressed PAD2_keypressed;
PADstartPoll PAD2_startPoll;
PADpoll PAD2_poll;
PADsetSensitive PAD2_setSensitive;
NETinit NET_init;
NETshutdown NET_shutdown;
NETopen NET_open;
NETclose NET_close;
NETtest NET_test;
NETconfigure NET_configure;
NETabout NET_about;
NETpause NET_pause;
NETresume NET_resume;
NETqueryPlayer NET_queryPlayer;
NETsendData NET_sendData;
NETrecvData NET_recvData;
NETsendPadData NET_sendPadData;
NETrecvPadData NET_recvPadData;
NETsetInfo NET_setInfo;
NETkeypressed NET_keypressed;
#ifdef ENABLE_SIO1API
SIO1init SIO1_init;
SIO1shutdown SIO1_shutdown;
SIO1open SIO1_open;
SIO1close SIO1_close;
SIO1test SIO1_test;
SIO1configure SIO1_configure;
SIO1about SIO1_about;
SIO1pause SIO1_pause;
SIO1resume SIO1_resume;
SIO1keypressed SIO1_keypressed;
SIO1writeData8 SIO1_writeData8;
SIO1writeData16 SIO1_writeData16;
SIO1writeData32 SIO1_writeData32;
SIO1writeStat16 SIO1_writeStat16;
SIO1writeStat32 SIO1_writeStat32;
SIO1writeMode16 SIO1_writeMode16;
SIO1writeMode32 SIO1_writeMode32;
SIO1writeCtrl16 SIO1_writeCtrl16;
SIO1writeCtrl32 SIO1_writeCtrl32;
SIO1writeBaud16 SIO1_writeBaud16;
SIO1writeBaud32 SIO1_writeBaud32;
SIO1readData8 SIO1_readData8;
SIO1readData16 SIO1_readData16;
SIO1readData32 SIO1_readData32;
SIO1readStat16 SIO1_readStat16;
SIO1readStat32 SIO1_readStat32;
SIO1readMode16 SIO1_readMode16;
SIO1readMode32 SIO1_readMode32;
SIO1readCtrl16 SIO1_readCtrl16;
SIO1readCtrl32 SIO1_readCtrl32;
SIO1readBaud16 SIO1_readBaud16;
SIO1readBaud32 SIO1_readBaud32;
SIO1registerCallback SIO1_registerCallback;
#endif
static const char *err;
#define CheckErr(func) { \
err = SysLibError(); \
if (err != NULL) { SysMessage(_("Error loading %s: %s"), func, err); return -1; } \
}
#define LoadSym(dest, src, name, checkerr) { \
dest = (src)SysLoadSym(drv, name); \
if (checkerr) { CheckErr(name); } else SysLibError(); \
}
void *hGPUDriver = NULL;
void CALLBACK GPU__displayText(char *pText) {
SysPrintf("%s\n", pText);
}
long CALLBACK GPU__configure(void) { return 0; }
long CALLBACK GPU__test(void) { return 0; }
void CALLBACK GPU__about(void) {}
void CALLBACK GPU__makeSnapshot(void) {}
void CALLBACK GPU__keypressed(int key) {}
long CALLBACK GPU__getScreenPic(unsigned char *pMem) { return -1; }
long CALLBACK GPU__showScreenPic(unsigned char *pMem) { return -1; }
void CALLBACK GPU__clearDynarec(void (CALLBACK *callback)(void)) {}
void CALLBACK GPU__vBlank(int val) {}
#define LoadGpuSym1(dest, name) \
LoadSym(GPU_##dest, GPU##dest, name, TRUE);
#define LoadGpuSym0(dest, name) \
LoadSym(GPU_##dest, GPU##dest, name, FALSE); \
if (GPU_##dest == NULL) GPU_##dest = (GPU##dest) GPU__##dest;
#define LoadGpuSymN(dest, name) \
LoadSym(GPU_##dest, GPU##dest, name, FALSE);
static int LoadGPUplugin(const char *GPUdll) {
void *drv;
hGPUDriver = SysLoadLibrary(GPUdll);
if (hGPUDriver == NULL) {
GPU_configure = NULL;
SysMessage (_("Could not load GPU plugin %s!"), GPUdll); return -1;
}
drv = hGPUDriver;
LoadGpuSym1(init, "GPUinit");
LoadGpuSym1(shutdown, "GPUshutdown");
LoadGpuSym1(open, "GPUopen");
LoadGpuSym1(close, "GPUclose");
LoadGpuSym1(readData, "GPUreadData");
LoadGpuSym1(readDataMem, "GPUreadDataMem");
LoadGpuSym1(readStatus, "GPUreadStatus");
LoadGpuSym1(writeData, "GPUwriteData");
LoadGpuSym1(writeDataMem, "GPUwriteDataMem");
LoadGpuSym1(writeStatus, "GPUwriteStatus");
LoadGpuSym1(dmaChain, "GPUdmaChain");
LoadGpuSym1(updateLace, "GPUupdateLace");
LoadGpuSym0(keypressed, "GPUkeypressed");
LoadGpuSym0(displayText, "GPUdisplayText");
LoadGpuSym0(makeSnapshot, "GPUmakeSnapshot");
LoadGpuSym1(freeze, "GPUfreeze");
LoadGpuSym0(getScreenPic, "GPUgetScreenPic");
LoadGpuSym0(showScreenPic, "GPUshowScreenPic");
LoadGpuSym0(clearDynarec, "GPUclearDynarec");
LoadGpuSym0(vBlank, "GPUvBlank");
LoadGpuSym0(configure, "GPUconfigure");
LoadGpuSym0(test, "GPUtest");
LoadGpuSym0(about, "GPUabout");
return 0;
}
void *hCDRDriver = NULL;
long CALLBACK CDR__play(unsigned char *sector) { return 0; }
long CALLBACK CDR__stop(void) { return 0; }
long CALLBACK CDR__getStatus(struct CdrStat *stat) {
if (cdOpenCaseTime < 0 || cdOpenCaseTime > (s64)time(NULL))
stat->Status = 0x10;
else
stat->Status = 0;
return 0;
}
char* CALLBACK CDR__getDriveLetter(void) { return NULL; }
long CALLBACK CDR__configure(void) { return 0; }
long CALLBACK CDR__test(void) { return 0; }
void CALLBACK CDR__about(void) {}
long CALLBACK CDR__setfilename(char*filename) { return 0; }
#define LoadCdrSym1(dest, name) \
LoadSym(CDR_##dest, CDR##dest, name, TRUE);
#define LoadCdrSym0(dest, name) \
LoadSym(CDR_##dest, CDR##dest, name, FALSE); \
if (CDR_##dest == NULL) CDR_##dest = (CDR##dest) CDR__##dest;
#define LoadCdrSymN(dest, name) \
LoadSym(CDR_##dest, CDR##dest, name, FALSE);
static int LoadCDRplugin(const char *CDRdll) {
void *drv;
if (CDRdll == NULL) {
cdrIsoInit();
return 0;
}
hCDRDriver = SysLoadLibrary(CDRdll);
if (hCDRDriver == NULL) {
CDR_configure = NULL;
SysMessage (_("Could not load CD-ROM plugin %s!"), CDRdll); return -1;
}
drv = hCDRDriver;
LoadCdrSym1(init, "CDRinit");
LoadCdrSym1(shutdown, "CDRshutdown");
LoadCdrSym1(open, "CDRopen");
LoadCdrSym1(close, "CDRclose");
LoadCdrSym1(getTN, "CDRgetTN");
LoadCdrSym1(getTD, "CDRgetTD");
LoadCdrSym1(readTrack, "CDRreadTrack");
LoadCdrSym1(getBuffer, "CDRgetBuffer");
LoadCdrSym1(getBufferSub, "CDRgetBufferSub");
LoadCdrSym0(play, "CDRplay");
LoadCdrSym0(stop, "CDRstop");
LoadCdrSym0(getStatus, "CDRgetStatus");
LoadCdrSym0(getDriveLetter, "CDRgetDriveLetter");
LoadCdrSym0(configure, "CDRconfigure");
LoadCdrSym0(test, "CDRtest");
LoadCdrSym0(about, "CDRabout");
LoadCdrSym0(setfilename, "CDRsetfilename");
LoadCdrSymN(readCDDA, "CDRreadCDDA");
LoadCdrSymN(getTE, "CDRgetTE");
return 0;
}
void *hSPUDriver = NULL;
long CALLBACK SPU__configure(void) { return 0; }
void CALLBACK SPU__about(void) {}
long CALLBACK SPU__test(void) { return 0; }
void CALLBACK SPU__registerScheduleCb(void (CALLBACK *cb)(unsigned int)) {}
#define LoadSpuSym1(dest, name) \
LoadSym(SPU_##dest, SPU##dest, name, TRUE);
#define LoadSpuSym0(dest, name) \
LoadSym(SPU_##dest, SPU##dest, name, FALSE); \
if (SPU_##dest == NULL) SPU_##dest = (SPU##dest) SPU__##dest;
#define LoadSpuSymN(dest, name) \
LoadSym(SPU_##dest, SPU##dest, name, FALSE);
static int LoadSPUplugin(const char *SPUdll) {
void *drv;
hSPUDriver = SysLoadLibrary(SPUdll);
if (hSPUDriver == NULL) {
SPU_configure = NULL;
SysMessage (_("Could not load SPU plugin %s!"), SPUdll); return -1;
}
drv = hSPUDriver;
LoadSpuSym1(init, "SPUinit");
LoadSpuSym1(shutdown, "SPUshutdown");
LoadSpuSym1(open, "SPUopen");
LoadSpuSym1(close, "SPUclose");
LoadSpuSym0(configure, "SPUconfigure");
LoadSpuSym0(about, "SPUabout");
LoadSpuSym0(test, "SPUtest");
LoadSpuSym1(writeRegister, "SPUwriteRegister");
LoadSpuSym1(readRegister, "SPUreadRegister");
LoadSpuSym1(writeDMA, "SPUwriteDMA");
LoadSpuSym1(readDMA, "SPUreadDMA");
LoadSpuSym1(writeDMAMem, "SPUwriteDMAMem");
LoadSpuSym1(readDMAMem, "SPUreadDMAMem");
LoadSpuSym1(playADPCMchannel, "SPUplayADPCMchannel");
LoadSpuSym1(freeze, "SPUfreeze");
LoadSpuSym1(registerCallback, "SPUregisterCallback");
LoadSpuSym0(registerScheduleCb, "SPUregisterScheduleCb");
LoadSpuSymN(async, "SPUasync");
LoadSpuSymN(playCDDAchannel, "SPUplayCDDAchannel");
return 0;
}
extern int in_type[8];
void *hPAD1Driver = NULL;
void *hPAD2Driver = NULL;
static int multitap1 = -1;
static int multitap2 = -1;
//Pad information, keystate, mode, config mode, vibration
static PadDataS pad[8];
static int reqPos, respSize, req;
static int ledStateReq44[8];
static int PadMode[8]; /* 0 : digital 1: analog */
static unsigned char buf[256];
static unsigned char bufMulti[34] = { 0x80, 0x5a,
0x41, 0x5a, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff,
0x41, 0x5a, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff,
0x41, 0x5a, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff,
0x41, 0x5a, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff};
unsigned char stdpar[8] = { 0x41, 0x5a, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff};
unsigned char multitappar[34] = { 0x80, 0x5a,
0x41, 0x5a, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff,
0x41, 0x5a, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff,
0x41, 0x5a, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff,
0x41, 0x5a, 0xff, 0xff, 0xff, 0xff, 0xff, 0xff};
//response for request 44, 45, 46, 47, 4C, 4D
static unsigned char resp45[8] = {0xF3, 0x5A, 0x01, 0x02, 0x00, 0x02, 0x01, 0x00};
static unsigned char resp46_00[8] = {0xF3, 0x5A, 0x00, 0x00, 0x01, 0x02, 0x00, 0x0A};
static unsigned char resp46_01[8] = {0xF3, 0x5A, 0x00, 0x00, 0x01, 0x01, 0x01, 0x14};
static unsigned char resp47[8] = {0xF3, 0x5A, 0x00, 0x00, 0x02, 0x00, 0x01, 0x00};
static unsigned char resp4C_00[8] = {0xF3, 0x5A, 0x00, 0x00, 0x00, 0x04, 0x00, 0x00};
static unsigned char resp4C_01[8] = {0xF3, 0x5A, 0x00, 0x00, 0x00, 0x07, 0x00, 0x00};
static unsigned char resp4D[8] = {0xF3, 0x5A, 0x00, 0x01, 0xFF, 0xFF, 0xFF, 0xFF};
//fixed reponse of request number 41, 48, 49, 4A, 4B, 4E, 4F
static unsigned char resp40[8] = {0xF3, 0x5A, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00};
static unsigned char resp41[8] = {0xF3, 0x5A, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00};
static unsigned char resp43[8] = {0xF3, 0x5A, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00};
static unsigned char resp44[8] = {0xF3, 0x5A, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00};
static unsigned char resp49[8] = {0xF3, 0x5A, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00};
static unsigned char resp4A[8] = {0xF3, 0x5A, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00};
static unsigned char resp4B[8] = {0xF3, 0x5A, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00};
static unsigned char resp4E[8] = {0xF3, 0x5A, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00};
static unsigned char resp4F[8] = {0xF3, 0x5A, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00};
// Resquest of psx core
enum {
// REQUEST
// first call of this request for the pad, the pad is configured as an digital pad.
// 0x0X, 0x42, 0x0Y, 0xZZ, 0xAA, 0x00, 0x00, 0x00, 0x00
// X pad number (used for the multitap, first request response 0x00, 0x80, 0x5A, (8 bytes pad A), (8 bytes pad B), (8 bytes pad C), (8 bytes pad D)
// Y if 1 : psx request the full length response for the multitap, 3 bytes header and 4 block of 8 bytes per pad
// Y if 0 : psx request a pad key state
// ZZ rumble small motor 00-> OFF, 01 -> ON
// AA rumble large motor speed 0x00 -> 0xFF
// RESPONSE
// header 3 Bytes
// 0x00
// PadId -> 0x41 for digital pas, 0x73 for analog pad
// 0x5A mode has not change (no press on analog button on the center of pad), 0x00 the analog button have been pressed and the mode switch
// 6 Bytes for keystates
CMD_READ_DATA_AND_VIBRATE = 0x42,
// REQUEST
// Header
// 0x0N, 0x43, 0x00, XX, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00
// XX = 00 -> Normal mode : Seconde bytes of response = padId
// XX = 01 -> Configuration mode : Seconde bytes of response = 0xF3
// RESPONSE
// enter in config mode example :
// req : 01 43 00 01 00 00 00 00 00 00
// res : 00 41 5A buttons state, analog states
// exit config mode :
// req : 01 43 00 00 00 00 00 00 00 00
// res : 00 F3 5A buttons state, analog states
CMD_CONFIG_MODE = 0x43,
// Set led State
// REQUEST
// 0x0N, 0x44, 0x00, VAL, SEL, 0x00, 0x00, 0x00, 0x00
// If sel = 2 then
// VAL = 00 -> OFF
// VAL = 01 -> ON
// RESPONSE
// 0x00, 0xF3, 0x5A, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00
CMD_SET_MODE_AND_LOCK = 0x44,
// Get Analog Led state
// REQUEST
// 0x0N, 0x45, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00
// RESPONSE
// 0x00, 0xF3, 0x5A, 0x01, 0x02, VAL, 0x02, 0x01, 0x00
// VAL = 00 Led OFF
// VAL = 01 Led ON
CMD_QUERY_MODEL_AND_MODE = 0x45,
//Get Variable A
// REQUEST
// 0x0N, 0x46, 0x00, 0xXX, 0x00, 0x00, 0x00, 0x00, 0x00
// RESPONSE
// XX=00
// 0x00, 0xF3, 0x5A, 0x00, 0x00, 0x01, 0x02, 0x00, 0x0A
// XX=01
// 0x00, 0xF3, 0x5A, 0x00, 0x00, 0x01, 0x01, 0x01, 0x14
CMD_QUERY_ACT = 0x46,
// REQUEST
// 0x0N, 0x47, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00
// RESPONSE
// 0x00, 0xF3, 0x5A, 0x00, 0x00, 0x02, 0x00, 0x01, 0x00
CMD_QUERY_COMB = 0x47,
// REQUEST
// 0x0N, 0x4C, 0x00, 0xXX, 0x00, 0x00, 0x00, 0x00, 0x00
// RESPONSE
// XX = 0
// 0x00, 0xF3, 0x5A, 0x00, 0x00, 0x00, 0x04, 0x00, 0x00
// XX = 1
// 0x00, 0xF3, 0x5A, 0x00, 0x00, 0x00, 0x07, 0x00, 0x00
CMD_QUERY_MODE = 0x4C,
// REQUEST
// 0x0N, 0x4D, 0x00, 0xAA, 0xBB, 0xCC, 0xDD, 0xEE, 0xFF
// RESPONSE
// 0x00, 0xF3, 0x5A, old value or
// AA = 01 unlock large motor (and swap VAL1 and VAL2)
// BB = 01 unlock large motor (default)
// CC, DD, EE, FF = all FF -> unlock small motor
//
// default repsonse for analog pad with 2 motor : 0x00 0xF3 0x5A 0x00 0x01 0xFF 0xFF 0xFF 0xFF
//
CMD_VIBRATION_TOGGLE = 0x4D,
REQ40 = 0x40,
REQ41 = 0x41,
REQ49 = 0x49,
REQ4A = 0x4A,
REQ4B = 0x4B,
REQ4E = 0x4E,
REQ4F = 0x4F
};
//NO MULTITAP
void initBufForRequest(int padIndex, char value){
switch (value){
//Pad keystate already in buffer
//case CMD_READ_DATA_AND_VIBRATE :
// break;
case CMD_CONFIG_MODE :
if (pad[padIndex].configMode == 1) {
memcpy(buf, resp43, 8);
break;
}
//else, not in config mode, pad keystate return (already in the buffer)
break;
case CMD_SET_MODE_AND_LOCK :
memcpy(buf, resp44, 8);
break;
case CMD_QUERY_MODEL_AND_MODE :
memcpy(buf, resp45, 8);
buf[4] = PadMode[padIndex];
break;
case CMD_QUERY_ACT :
memcpy(buf, resp46_00, 8);
break;
case CMD_QUERY_COMB :
memcpy(buf, resp47, 8);
break;
case CMD_QUERY_MODE :
memcpy(buf, resp4C_00, 8);
break;
case CMD_VIBRATION_TOGGLE :
memcpy(buf, resp4D, 8);
break;
case REQ40 :
memcpy(buf, resp40, 8);
break;
case REQ41 :
memcpy(buf, resp41, 8);
break;
case REQ49 :
memcpy(buf, resp49, 8);
break;
case REQ4A :
memcpy(buf, resp4A, 8);
break;
case REQ4B :
memcpy(buf, resp4B, 8);
break;
case REQ4E :
memcpy(buf, resp4E, 8);
break;
case REQ4F :
memcpy(buf, resp4F, 8);
break;
}
}
void reqIndex2Treatment(int padIndex, char value){
switch (req){
case CMD_CONFIG_MODE :
//0x43
if (value == 0) {
pad[padIndex].configMode = 0;
} else {
pad[padIndex].configMode = 1;
}
break;
case CMD_SET_MODE_AND_LOCK :
//0x44 store the led state for change mode if the next value = 0x02
//0x01 analog ON
//0x00 analog OFF
ledStateReq44[padIndex] = value;
PadMode[padIndex] = value;
break;
case CMD_QUERY_ACT :
//0x46
if (value == 1) {
memcpy(buf, resp46_01, 8);
}
break;
case CMD_QUERY_MODE :
if (value == 1) {
memcpy(buf, resp4C_01, 8);
}
break;
case CMD_VIBRATION_TOGGLE :
//0x4D
memcpy(buf, resp4D, 8);
break;
case CMD_READ_DATA_AND_VIBRATE:
//mem the vibration value for small motor;
pad[padIndex].Vib[0] = value;
break;
}
}
void vibrate(int padIndex){
if (pad[padIndex].Vib[0] != pad[padIndex].VibF[0] || pad[padIndex].Vib[1] != pad[padIndex].VibF[1]) {
//value is different update Value and call libretro for vibration
pad[padIndex].VibF[0] = pad[padIndex].Vib[0];
pad[padIndex].VibF[1] = pad[padIndex].Vib[1];
plat_trigger_vibrate(padIndex, pad[padIndex].VibF[0], pad[padIndex].VibF[1]);
//printf("vibration pad %i", padIndex);
}
}
//Build response for 0x42 request Pad in port
void _PADstartPoll(PadDataS *pad) {
switch (pad->controllerType) {
case PSE_PAD_TYPE_MOUSE:
stdpar[0] = 0x12;
stdpar[2] = pad->buttonStatus & 0xff;
stdpar[3] = pad->buttonStatus >> 8;
stdpar[4] = pad->moveX;
stdpar[5] = pad->moveY;
memcpy(buf, stdpar, 6);
respSize = 6;
break;
case PSE_PAD_TYPE_NEGCON: // npc101/npc104(slph00001/slph00069)
stdpar[0] = 0x23;
stdpar[2] = pad->buttonStatus & 0xff;
stdpar[3] = pad->buttonStatus >> 8;
stdpar[4] = pad->rightJoyX;
stdpar[5] = pad->rightJoyY;
stdpar[6] = pad->leftJoyX;
stdpar[7] = pad->leftJoyY;
memcpy(buf, stdpar, 8);
respSize = 8;
break;
case PSE_PAD_TYPE_GUNCON: // GUNCON - gun controller SLPH-00034 from Namco
stdpar[0] = 0x63;
stdpar[1] = 0x5a;
stdpar[2] = pad->buttonStatus & 0xff;
stdpar[3] = pad->buttonStatus >> 8;
//This code assumes an X resolution of 256 and a Y resolution of 240
int xres = 256;
int yres = 240;
//The code wants an input range for x and y of 0-1023 we passed in -32767 -> 32767
int absX = (pad->absoluteX / 64) + 512;
int absY = (pad->absoluteY / 64) + 512;
//Keep within limits
if (absX > 1023) absX = 1023;
if (absX < 0) absX = 0;
if (absY > 1023) absY = 1023;
if (absY < 0) absY = 0;
stdpar[4] = 0x5a - (xres - 256) / 3 + (((xres - 256) / 3 + 356) * absX >> 10);
stdpar[5] = (0x5a - (xres - 256) / 3 + (((xres - 256) / 3 + 356) * absX >> 10)) >> 8;
stdpar[6] = 0x20 + (yres * absY >> 10);
stdpar[7] = (0x20 + (yres * absY >> 10)) >> 8;
//Offscreen - Point at the side of the screen so PSX thinks you are pointing offscreen
//Required as a mouse can't be offscreen
//Coordinates X=0001h, Y=000Ah indicates "no light"
//This will mean you cannot shoot the very each of the screen
//ToDo read offscreen range from settings if useful to change
int OffscreenRange = 2;
if (absX < (OffscreenRange) || absX > (1023 - OffscreenRange) || absY < (OffscreenRange) || absY > (1023 - OffscreenRange)) {
stdpar[4] = 0x01;
stdpar[5] = 0x00;
stdpar[6] = 0x0A;
stdpar[7] = 0x00;
}
memcpy(buf, stdpar, 8);
respSize = 8;
break;
case PSE_PAD_TYPE_ANALOGPAD: // scph1150
stdpar[0] = 0x73;
stdpar[2] = pad->buttonStatus & 0xff;
stdpar[3] = pad->buttonStatus >> 8;
stdpar[4] = pad->rightJoyX;
stdpar[5] = pad->rightJoyY;
stdpar[6] = pad->leftJoyX;
stdpar[7] = pad->leftJoyY;
memcpy(buf, stdpar, 8);
respSize = 8;
break;
case PSE_PAD_TYPE_ANALOGJOY: // scph1110
stdpar[0] = 0x53;
stdpar[2] = pad->buttonStatus & 0xff;
stdpar[3] = pad->buttonStatus >> 8;
stdpar[4] = pad->rightJoyX;
stdpar[5] = pad->rightJoyY;
stdpar[6] = pad->leftJoyX;
stdpar[7] = pad->leftJoyY;
memcpy(buf, stdpar, 8);
respSize = 8;
break;
case PSE_PAD_TYPE_STANDARD:
default:
stdpar[0] = 0x41;
stdpar[2] = pad->buttonStatus & 0xff;
stdpar[3] = pad->buttonStatus >> 8;
//avoid analog value in multitap mode if change pad type in game.
stdpar[4] = 0xff;
stdpar[5] = 0xff;
stdpar[6] = 0xff;
stdpar[7] = 0xff;
memcpy(buf, stdpar, 8);
respSize = 8;
}
}
//Build response for 0x42 request Multitap in port
//Response header for multitap : 0x80, 0x5A, (Pad information port 1-2A), (Pad information port 1-2B), (Pad information port 1-2C), (Pad information port 1-2D)
void _PADstartPollMultitap(PadDataS* padd) {
int i, offset;
for(i = 0; i < 4; i++) {
offset = 2 + (i * 8);
_PADstartPoll(&padd[i]);
memcpy(multitappar+offset, stdpar, 8);
}
memcpy(bufMulti, multitappar, 34);
respSize = 34;
}
unsigned char _PADpoll(int port, unsigned char value) {
if (reqPos == 0) {
//mem the request number
req = value;
// Don't enable Analog/Vibration for a standard pad
if (in_type[port] == PSE_PAD_TYPE_STANDARD ||
in_type[port] == PSE_PAD_TYPE_NEGCON) {
; // Pad keystate already in buffer
}
else
{
//copy the default value of request response in buffer instead of the keystate
initBufForRequest(port, value);
}
}
//if no new request the pad return 0xff, for signaling connected
if (reqPos >= respSize) return 0xff;
switch(reqPos){
case 2:
reqIndex2Treatment(port, value);
break;
case 3:
switch(req) {
case CMD_SET_MODE_AND_LOCK :
//change mode on pad
break;
case CMD_READ_DATA_AND_VIBRATE:
//mem the vibration value for Large motor;
pad[port].Vib[1] = value;
if (in_type[port] == PSE_PAD_TYPE_STANDARD &&
in_type[port] == PSE_PAD_TYPE_NEGCON)
break;
//vibration
vibrate(port);
break;
}
break;
}
return buf[reqPos++];
}
unsigned char _PADpollMultitap(int port, unsigned char value) {
if (reqPos >= respSize) return 0xff;
return bufMulti[reqPos++];
}
// refresh the button state on port 1.
// int pad is not needed.
unsigned char CALLBACK PAD1__startPoll(int pad) {
reqPos = 0;
// first call the pad provide if a multitap is connected between the psx and himself
if (multitap1 == -1) {
PadDataS padd;
padd.requestPadIndex = 0;
PAD1_readPort1(&padd);
multitap1 = padd.portMultitap;
}
// just one pad is on port 1 : NO MULTITAP
if (multitap1 == 0) {
PadDataS padd;
padd.requestPadIndex = 0;
PAD1_readPort1(&padd);
_PADstartPoll(&padd);
} else {
// a multitap is plugged : refresh all pad.
int i;
PadDataS padd[4];
for(i = 0; i < 4; i++) {
padd[i].requestPadIndex = i;
PAD1_readPort1(&padd[i]);
}
_PADstartPollMultitap(padd);
}
//printf("\npad 1 : ");
return 0x00;
}
unsigned char CALLBACK PAD1__poll(unsigned char value) {
char tmp;
if (multitap1 == 1) {
tmp = _PADpollMultitap(0, value);
} else {
tmp = _PADpoll(0, value);
}
//printf("%2x:%2x, ",value,tmp);
return tmp;
}
long CALLBACK PAD1__configure(void) { return 0; }
void CALLBACK PAD1__about(void) {}
long CALLBACK PAD1__test(void) { return 0; }
long CALLBACK PAD1__query(void) { return 3; }
long CALLBACK PAD1__keypressed() { return 0; }
#define LoadPad1Sym1(dest, name) \
LoadSym(PAD1_##dest, PAD##dest, name, TRUE);
#define LoadPad1SymN(dest, name) \
LoadSym(PAD1_##dest, PAD##dest, name, FALSE);
#define LoadPad1Sym0(dest, name) \
LoadSym(PAD1_##dest, PAD##dest, name, FALSE); \
if (PAD1_##dest == NULL) PAD1_##dest = (PAD##dest) PAD1__##dest;
static int LoadPAD1plugin(const char *PAD1dll) {
void *drv;
hPAD1Driver = SysLoadLibrary(PAD1dll);
if (hPAD1Driver == NULL) {
PAD1_configure = NULL;
SysMessage (_("Could not load Controller 1 plugin %s!"), PAD1dll); return -1;
}
drv = hPAD1Driver;
LoadPad1Sym1(init, "PADinit");
LoadPad1Sym1(shutdown, "PADshutdown");
LoadPad1Sym1(open, "PADopen");
LoadPad1Sym1(close, "PADclose");
LoadPad1Sym0(query, "PADquery");
LoadPad1Sym1(readPort1, "PADreadPort1");
LoadPad1Sym0(configure, "PADconfigure");
LoadPad1Sym0(test, "PADtest");
LoadPad1Sym0(about, "PADabout");
LoadPad1Sym0(keypressed, "PADkeypressed");
LoadPad1Sym0(startPoll, "PADstartPoll");
LoadPad1Sym0(poll, "PADpoll");
LoadPad1SymN(setSensitive, "PADsetSensitive");
return 0;
}
unsigned char CALLBACK PAD2__startPoll(int pad) {
int pad_index;
reqPos = 0;
if (multitap1 == 0 && (multitap2 == 0 || multitap2 == 2)) {
pad_index = 1;
} else if(multitap1 == 1 && (multitap2 == 0 || multitap2 == 2)) {
pad_index = 4;
} else {
pad_index = 0;
}
//first call the pad provide if a multitap is connected between the psx and himself
if (multitap2 == -1) {
PadDataS padd;
padd.requestPadIndex = pad_index;
PAD2_readPort2(&padd);
multitap2 = padd.portMultitap;
}
// just one pad is on port 1 : NO MULTITAP
if (multitap2 == 0) {
PadDataS padd;
padd.requestPadIndex = pad_index;
PAD2_readPort2(&padd);
_PADstartPoll(&padd);
} else {
// a multitap is plugged : refresh all pad.
int i;
PadDataS padd[4];
for(i = 0; i < 4; i++) {
padd[i].requestPadIndex = i+pad_index;
PAD2_readPort2(&padd[i]);
}
_PADstartPollMultitap(padd);
}
//printf("\npad 2 : ");
return 0x00;
}
unsigned char CALLBACK PAD2__poll(unsigned char value) {
char tmp;
if (multitap2 == 2) {
tmp = _PADpollMultitap(1, value);
} else {
tmp = _PADpoll(1, value);
}
//printf("%2x:%2x, ",value,tmp);
return tmp;
}
long CALLBACK PAD2__configure(void) { return 0; }
void CALLBACK PAD2__about(void) {}
long CALLBACK PAD2__test(void) { return 0; }
long CALLBACK PAD2__query(void) { return PSE_PAD_USE_PORT1 | PSE_PAD_USE_PORT2; }
long CALLBACK PAD2__keypressed() { return 0; }
#define LoadPad2Sym1(dest, name) \
LoadSym(PAD2_##dest, PAD##dest, name, TRUE);
#define LoadPad2Sym0(dest, name) \
LoadSym(PAD2_##dest, PAD##dest, name, FALSE); \
if (PAD2_##dest == NULL) PAD2_##dest = (PAD##dest) PAD2__##dest;
#define LoadPad2SymN(dest, name) \
LoadSym(PAD2_##dest, PAD##dest, name, FALSE);
static int LoadPAD2plugin(const char *PAD2dll) {
void *drv;
hPAD2Driver = SysLoadLibrary(PAD2dll);
if (hPAD2Driver == NULL) {
PAD2_configure = NULL;
SysMessage (_("Could not load Controller 2 plugin %s!"), PAD2dll); return -1;
}
drv = hPAD2Driver;
LoadPad2Sym1(init, "PADinit");
LoadPad2Sym1(shutdown, "PADshutdown");
LoadPad2Sym1(open, "PADopen");
LoadPad2Sym1(close, "PADclose");
LoadPad2Sym0(query, "PADquery");
LoadPad2Sym1(readPort2, "PADreadPort2");
LoadPad2Sym0(configure, "PADconfigure");
LoadPad2Sym0(test, "PADtest");
LoadPad2Sym0(about, "PADabout");
LoadPad2Sym0(keypressed, "PADkeypressed");
LoadPad2Sym0(startPoll, "PADstartPoll");
LoadPad2Sym0(poll, "PADpoll");
LoadPad2SymN(setSensitive, "PADsetSensitive");
return 0;
}
void *hNETDriver = NULL;
void CALLBACK NET__setInfo(netInfo *info) {}
void CALLBACK NET__keypressed(int key) {}
long CALLBACK NET__configure(void) { return 0; }
long CALLBACK NET__test(void) { return 0; }
void CALLBACK NET__about(void) {}
#define LoadNetSym1(dest, name) \
LoadSym(NET_##dest, NET##dest, name, TRUE);
#define LoadNetSymN(dest, name) \
LoadSym(NET_##dest, NET##dest, name, FALSE);
#define LoadNetSym0(dest, name) \
LoadSym(NET_##dest, NET##dest, name, FALSE); \
if (NET_##dest == NULL) NET_##dest = (NET##dest) NET__##dest;
static int LoadNETplugin(const char *NETdll) {
void *drv;
hNETDriver = SysLoadLibrary(NETdll);
if (hNETDriver == NULL) {
SysMessage (_("Could not load NetPlay plugin %s!"), NETdll); return -1;
}
drv = hNETDriver;
LoadNetSym1(init, "NETinit");
LoadNetSym1(shutdown, "NETshutdown");
LoadNetSym1(open, "NETopen");
LoadNetSym1(close, "NETclose");
LoadNetSymN(sendData, "NETsendData");
LoadNetSymN(recvData, "NETrecvData");
LoadNetSym1(sendPadData, "NETsendPadData");
LoadNetSym1(recvPadData, "NETrecvPadData");
LoadNetSym1(queryPlayer, "NETqueryPlayer");
LoadNetSym1(pause, "NETpause");
LoadNetSym1(resume, "NETresume");
LoadNetSym0(setInfo, "NETsetInfo");
LoadNetSym0(keypressed, "NETkeypressed");
LoadNetSym0(configure, "NETconfigure");
LoadNetSym0(test, "NETtest");
LoadNetSym0(about, "NETabout");
return 0;
}
#ifdef ENABLE_SIO1API
void *hSIO1Driver = NULL;
long CALLBACK SIO1__init(void) { return 0; }
long CALLBACK SIO1__shutdown(void) { return 0; }
long CALLBACK SIO1__open(void) { return 0; }
long CALLBACK SIO1__close(void) { return 0; }
long CALLBACK SIO1__configure(void) { return 0; }
long CALLBACK SIO1__test(void) { return 0; }
void CALLBACK SIO1__about(void) {}
void CALLBACK SIO1__pause(void) {}
void CALLBACK SIO1__resume(void) {}
long CALLBACK SIO1__keypressed(int key) { return 0; }
void CALLBACK SIO1__writeData8(unsigned char val) {}
void CALLBACK SIO1__writeData16(unsigned short val) {}
void CALLBACK SIO1__writeData32(unsigned long val) {}
void CALLBACK SIO1__writeStat16(unsigned short val) {}
void CALLBACK SIO1__writeStat32(unsigned long val) {}
void CALLBACK SIO1__writeMode16(unsigned short val) {}
void CALLBACK SIO1__writeMode32(unsigned long val) {}
void CALLBACK SIO1__writeCtrl16(unsigned short val) {}
void CALLBACK SIO1__writeCtrl32(unsigned long val) {}
void CALLBACK SIO1__writeBaud16(unsigned short val) {}
void CALLBACK SIO1__writeBaud32(unsigned long val) {}
unsigned char CALLBACK SIO1__readData8(void) { return 0; }
unsigned short CALLBACK SIO1__readData16(void) { return 0; }
unsigned long CALLBACK SIO1__readData32(void) { return 0; }
unsigned short CALLBACK SIO1__readStat16(void) { return 0; }
unsigned long CALLBACK SIO1__readStat32(void) { return 0; }
unsigned short CALLBACK SIO1__readMode16(void) { return 0; }
unsigned long CALLBACK SIO1__readMode32(void) { return 0; }
unsigned short CALLBACK SIO1__readCtrl16(void) { return 0; }
unsigned long CALLBACK SIO1__readCtrl32(void) { return 0; }
unsigned short CALLBACK SIO1__readBaud16(void) { return 0; }
unsigned long CALLBACK SIO1__readBaud32(void) { return 0; }
void CALLBACK SIO1__registerCallback(void (CALLBACK *callback)(void)) {};
void CALLBACK SIO1irq(void) {
psxHu32ref(0x1070) |= SWAPu32(0x100);
}
#define LoadSio1Sym1(dest, name) \
LoadSym(SIO1_##dest, SIO1##dest, name, TRUE);
#define LoadSio1SymN(dest, name) \
LoadSym(SIO1_##dest, SIO1##dest, name, FALSE);
#define LoadSio1Sym0(dest, name) \
LoadSym(SIO1_##dest, SIO1##dest, name, FALSE); \
if (SIO1_##dest == NULL) SIO1_##dest = (SIO1##dest) SIO1__##dest;
static int LoadSIO1plugin(const char *SIO1dll) {
void *drv;
hSIO1Driver = SysLoadLibrary(SIO1dll);
if (hSIO1Driver == NULL) {
SysMessage (_("Could not load SIO1 plugin %s!"), SIO1dll); return -1;
}
drv = hSIO1Driver;
LoadSio1Sym0(init, "SIO1init");
LoadSio1Sym0(shutdown, "SIO1shutdown");
LoadSio1Sym0(open, "SIO1open");
LoadSio1Sym0(close, "SIO1close");
LoadSio1Sym0(pause, "SIO1pause");
LoadSio1Sym0(resume, "SIO1resume");
LoadSio1Sym0(keypressed, "SIO1keypressed");
LoadSio1Sym0(configure, "SIO1configure");
LoadSio1Sym0(test, "SIO1test");
LoadSio1Sym0(about, "SIO1about");
LoadSio1Sym0(writeData8, "SIO1writeData8");
LoadSio1Sym0(writeData16, "SIO1writeData16");
LoadSio1Sym0(writeData32, "SIO1writeData32");
LoadSio1Sym0(writeStat16, "SIO1writeStat16");
LoadSio1Sym0(writeStat32, "SIO1writeStat32");
LoadSio1Sym0(writeMode16, "SIO1writeMode16");
LoadSio1Sym0(writeMode32, "SIO1writeMode32");
LoadSio1Sym0(writeCtrl16, "SIO1writeCtrl16");
LoadSio1Sym0(writeCtrl32, "SIO1writeCtrl32");
LoadSio1Sym0(writeBaud16, "SIO1writeBaud16");
LoadSio1Sym0(writeBaud32, "SIO1writeBaud32");
LoadSio1Sym0(readData16, "SIO1readData16");
LoadSio1Sym0(readData32, "SIO1readData32");
LoadSio1Sym0(readStat16, "SIO1readStat16");
LoadSio1Sym0(readStat32, "SIO1readStat32");
LoadSio1Sym0(readMode16, "SIO1readMode16");
LoadSio1Sym0(readMode32, "SIO1readMode32");
LoadSio1Sym0(readCtrl16, "SIO1readCtrl16");
LoadSio1Sym0(readCtrl32, "SIO1readCtrl32");
LoadSio1Sym0(readBaud16, "SIO1readBaud16");
LoadSio1Sym0(readBaud32, "SIO1readBaud32");
LoadSio1Sym0(registerCallback, "SIO1registerCallback");
return 0;
}
#endif
void CALLBACK clearDynarec(void) {
psxCpu->Reset();
}
int LoadPlugins() {
int ret;
char Plugin[MAXPATHLEN * 2];
ReleasePlugins();
SysLibError();
if (UsingIso()) {
LoadCDRplugin(NULL);
} else {
sprintf(Plugin, "%s/%s", Config.PluginsDir, Config.Cdr);
if (LoadCDRplugin(Plugin) == -1) return -1;
}
sprintf(Plugin, "%s/%s", Config.PluginsDir, Config.Gpu);
if (LoadGPUplugin(Plugin) == -1) return -1;
sprintf(Plugin, "%s/%s", Config.PluginsDir, Config.Spu);
if (LoadSPUplugin(Plugin) == -1) return -1;
sprintf(Plugin, "%s/%s", Config.PluginsDir, Config.Pad1);
if (LoadPAD1plugin(Plugin) == -1) return -1;
sprintf(Plugin, "%s/%s", Config.PluginsDir, Config.Pad2);
if (LoadPAD2plugin(Plugin) == -1) return -1;
if (strcmp("Disabled", Config.Net) == 0 || strcmp("", Config.Net) == 0)
Config.UseNet = FALSE;
else {
Config.UseNet = TRUE;
sprintf(Plugin, "%s/%s", Config.PluginsDir, Config.Net);
if (LoadNETplugin(Plugin) == -1) Config.UseNet = FALSE;
}
#ifdef ENABLE_SIO1API
sprintf(Plugin, "%s/%s", Config.PluginsDir, Config.Sio1);
if (LoadSIO1plugin(Plugin) == -1) return -1;
#endif
ret = CDR_init();
if (ret < 0) { SysMessage (_("Error initializing CD-ROM plugin: %d"), ret); return -1; }
ret = GPU_init();
if (ret < 0) { SysMessage (_("Error initializing GPU plugin: %d"), ret); return -1; }
ret = SPU_init();
if (ret < 0) { SysMessage (_("Error initializing SPU plugin: %d"), ret); return -1; }
ret = PAD1_init(1);
if (ret < 0) { SysMessage (_("Error initializing Controller 1 plugin: %d"), ret); return -1; }
ret = PAD2_init(2);
if (ret < 0) { SysMessage (_("Error initializing Controller 2 plugin: %d"), ret); return -1; }
if (Config.UseNet) {
ret = NET_init();
if (ret < 0) { SysMessage (_("Error initializing NetPlay plugin: %d"), ret); return -1; }
}
#ifdef ENABLE_SIO1API
ret = SIO1_init();
if (ret < 0) { SysMessage (_("Error initializing SIO1 plugin: %d"), ret); return -1; }
#endif
SysPrintf(_("Plugins loaded.\n"));
return 0;
}
void ReleasePlugins() {
if (Config.UseNet) {
int ret = NET_close();
if (ret < 0) Config.UseNet = FALSE;
}
NetOpened = FALSE;
if (hCDRDriver != NULL || cdrIsoActive()) CDR_shutdown();
if (hGPUDriver != NULL) GPU_shutdown();
if (hSPUDriver != NULL) SPU_shutdown();
if (hPAD1Driver != NULL) PAD1_shutdown();
if (hPAD2Driver != NULL) PAD2_shutdown();
if (Config.UseNet && hNETDriver != NULL) NET_shutdown();
if (hCDRDriver != NULL) { SysCloseLibrary(hCDRDriver); hCDRDriver = NULL; }
if (hGPUDriver != NULL) { SysCloseLibrary(hGPUDriver); hGPUDriver = NULL; }
if (hSPUDriver != NULL) { SysCloseLibrary(hSPUDriver); hSPUDriver = NULL; }
if (hPAD1Driver != NULL) { SysCloseLibrary(hPAD1Driver); hPAD1Driver = NULL; }
if (hPAD2Driver != NULL) { SysCloseLibrary(hPAD2Driver); hPAD2Driver = NULL; }
if (Config.UseNet && hNETDriver != NULL) {
SysCloseLibrary(hNETDriver); hNETDriver = NULL;
}
#ifdef ENABLE_SIO1API
if (hSIO1Driver != NULL) {
SIO1_shutdown();
SysCloseLibrary(hSIO1Driver);
hSIO1Driver = NULL;
}
#endif
}
// for CD swap
int ReloadCdromPlugin()
{
if (hCDRDriver != NULL || cdrIsoActive()) CDR_shutdown();
if (hCDRDriver != NULL) { SysCloseLibrary(hCDRDriver); hCDRDriver = NULL; }
if (UsingIso()) {
LoadCDRplugin(NULL);
} else {
char Plugin[MAXPATHLEN * 2];
sprintf(Plugin, "%s/%s", Config.PluginsDir, Config.Cdr);
if (LoadCDRplugin(Plugin) == -1) return -1;
}
return CDR_init();
}
void SetIsoFile(const char *filename) {
if (filename == NULL) {
IsoFile[0] = '\0';
return;
}
strncpy(IsoFile, filename, MAXPATHLEN - 1);
}
const char *GetIsoFile(void) {
return IsoFile;
}
boolean UsingIso(void) {
return (IsoFile[0] != '\0');
}
void SetCdOpenCaseTime(s64 time) {
cdOpenCaseTime = time;
}
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