/* ScummVM - Scumm Interpreter * Copyright (C) 2005-2006 The ScummVM project * * 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 02110-1301, USA. * * $Header$ * */ #include "common/stdafx.h" #include #include #include #include #include #include #include #include #include #include #include #include "common/scummsys.h" #include "../intern.h" #include "base/engine.h" #include "backends/ps2/systemps2.h" #include "backends/ps2/Gs2dScreen.h" #include "backends/ps2/ps2input.h" #include #include #include "backends/ps2/savefile.h" #include "common/file.h" #include "backends/ps2/sysdefs.h" #include #include #include "backends/ps2/cd.h" #include #include #include "graphics/surface.h" #include "graphics/font.h" #define TIMER_STACK_SIZE (1024 * 32) #define SOUND_STACK_SIZE (1024 * 32) #define SMP_PER_BLOCK 800 #define FROM_BCD(a) ((a >> 4) * 10 + (a & 0xF)) #define BUS_CLOCK 147456000 // bus clock, a little less than 150 mhz #define CLK_DIVIS 5760 // the timer IRQ handler gets called (BUS_CLOCK / 256) / CLK_DIVIS times per second (100 times) #ifdef USE_PS2LINK #define IRX_PREFIX "host:" #define IRX_SUFFIX #else #define IRX_PREFIX "cdrom0:\\" #define IRX_SUFFIX ";1" #endif static int g_TimerThreadSema = -1, g_SoundThreadSema = -1; static int g_MainWaitSema = -1, g_TimerWaitSema = -1; static volatile int32 g_MainWakeUp = 0, g_TimerWakeUp = 0; static volatile uint32 msecCount = 0; OSystem_PS2 *g_systemPs2 = NULL; int gBitFormat = 555; #define FOREVER 2147483647 namespace Graphics { extern const NewFont g_sysfont; }; void sioprintf(const char *zFormat, ...) { va_list ap; char resStr[2048]; va_start(ap,zFormat); vsnprintf(resStr, 2048, zFormat, ap); va_end(ap); sio_puts(resStr); } OSystem *OSystem_PS2_create(void) { if (!g_systemPs2) g_systemPs2 = new OSystem_PS2(); return g_systemPs2; } extern "C" int scummvm_main(int argc, char *argv[]); extern "C" int main(int argc, char *argv[]) { SifInitRpc(0); #ifndef USE_PS2LINK // reset the IOP if this is a CD build cdvdInit(CDVD_EXIT); cdvdExit(); SifExitIopHeap(); SifLoadFileExit(); SifExitRpc(); sio_puts("Resetting IOP."); SifIopReset("rom0:UDNL rom0:EELOADCNF",0); while (!SifIopSync()) ; sio_puts("IOP synced."); SifInitRpc(0); SifLoadFileInit(); cdvdInit(CDVD_INIT_NOWAIT); #endif ee_thread_t thisThread; int tid = GetThreadId(); ReferThreadStatus(tid, &thisThread); sioprintf("Thread Start Priority = %d\n", thisThread.current_priority); if ((thisThread.current_priority < 5) || (thisThread.current_priority > 80)) { /* Depending on the way ScummVM is run, we may get here with different thread priorities. The PS2 BIOS executes it with priority = 0, ps2link uses priority 64. Don't know about NapLink, etc. The priority doesn't matter too much, but we need to be at least at prio 3, so we can have the timer thread run at prio 2 and the sound thread at prio 1 */ sioprintf("Changing thread priority"); int res = ChangeThreadPriority(tid, 20); sioprintf("Result = %d", res); } sioprintf("Creating system"); /* The OSystem has to be created before we enter ScummVM's main. It sets up the memory card, etc. */ OSystem_PS2_create(); sioprintf("init done. starting ScummVM."); return scummvm_main(argc, argv); } s32 timerInterruptHandler(s32 cause) { T0_MODE = 0xDC2; // same value as in initialization. msecCount += 10; iSignalSema(g_SoundThreadSema); iSignalSema(g_TimerThreadSema); if (g_MainWakeUp) { g_MainWakeUp -= 10; if (g_MainWakeUp <= 0) { iSignalSema(g_MainWaitSema); g_MainWakeUp = 0; } } if (g_TimerWakeUp) { g_TimerWakeUp -= 10; if (g_TimerWakeUp <= 0) { iSignalSema(g_TimerWaitSema); g_TimerWakeUp = 0; } } return 0; } void systemTimerThread(OSystem_PS2 *system) { system->timerThread(); } void systemSoundThread(OSystem_PS2 *system) { system->soundThread(); } OSystem_PS2::OSystem_PS2(void) { _soundStack = _timerStack = NULL; _scummTimerProc = NULL; _scummSoundProc = NULL; _scummSoundParam = NULL; _printY = 0; _msgClearTime = 0; _systemQuit = false; _screen = new Gs2dScreen(320, 200, TV_DONT_CARE); sioprintf("Initializing system..."); initTimer(); _screen->wantAnim(true); sioprintf("Loading IOP modules..."); loadModules(); int res; if ((res = SjPCM_Init(0)) < 0) { msgPrintf(FOREVER, "SjPCM Bind failed: %d", res); quit(); } if ((res = CDVD_Init()) != 0) { msgPrintf(FOREVER, "CDVD Init failed: %d", res); quit(); } if ((res = fileXioInit()) < 0) { msgPrintf(FOREVER, "FXIO Init failed: %d", res); quit(); } fileXioSetBlockMode(FXIO_NOWAIT); _mouseVisible = false; sioprintf("reading RTC"); readRtcTime(); sioprintf("Starting SavefileManager"); _saveManager = new Ps2SaveFileManager(this, _screen); sioprintf("Initializing ps2Input"); _input = new Ps2Input(this, _useMouse, _useKbd); #ifdef _REC_MUTEX_ _mutex = new Ps2Mutex[MAX_MUTEXES]; ee_sema_t newSema; newSema.init_count = 1; newSema.max_count = 1; _mutexSema = CreateSema(&newSema); for (int i = 0; i < MAX_MUTEXES; i++) { _mutex[i].sema = -1; _mutex[i].count = _mutex[i].owner = 0; } #endif _screen->wantAnim(false); _screen->clearScreen(); } OSystem_PS2::~OSystem_PS2(void) { } void OSystem_PS2::initTimer(void) { // first setup the two threads that get activated by the timer: // the timerthread and the soundthread ee_sema_t threadSema; threadSema.init_count = 0; threadSema.max_count = 255; g_TimerThreadSema = CreateSema(&threadSema); g_SoundThreadSema = CreateSema(&threadSema); assert((g_TimerThreadSema >= 0) && (g_SoundThreadSema >= 0)); ee_thread_t timerThread, soundThread, thisThread; ReferThreadStatus(GetThreadId(), &thisThread); _timerStack = (uint8*)malloc(TIMER_STACK_SIZE); _soundStack = (uint8*)malloc(SOUND_STACK_SIZE); // give timer thread a higher priority than main thread timerThread.initial_priority = thisThread.current_priority - 1; timerThread.stack = _timerStack; timerThread.stack_size = TIMER_STACK_SIZE; timerThread.func = (void *)systemTimerThread; //timerThread.gp_reg = _gp; // _gp is always NULL.. broken linkfile? asm("move %0, $gp\n": "=r"(timerThread.gp_reg)); // soundthread's priority is higher than main- and timerthread soundThread.initial_priority = thisThread.current_priority - 2; soundThread.stack = _soundStack; soundThread.stack_size = SOUND_STACK_SIZE; soundThread.func = (void *)systemSoundThread; asm("move %0, $gp\n": "=r"(soundThread.gp_reg)); _timerTid = CreateThread(&timerThread); _soundTid = CreateThread(&soundThread); assert((_timerTid >= 0) && (_soundTid >= 0)); StartThread(_timerTid, this); StartThread(_soundTid, this); // these semaphores are used for OSystem::delayMillis() threadSema.init_count = 0; threadSema.max_count = 1; g_MainWaitSema = CreateSema(&threadSema); g_TimerWaitSema = CreateSema(&threadSema); assert((g_MainWaitSema >= 0) && (g_TimerWaitSema >= 0)); // threads done, start the interrupt handler _intrId = AddIntcHandler( INT_TIMER0, timerInterruptHandler, 0); // 0=first handler assert(_intrId >= 0); EnableIntc(INT_TIMER0); T0_HOLD = 0; T0_COUNT = 0; T0_COMP = CLK_DIVIS; // (BUS_CLOCK / 256) / CLK_DIVIS = 100 T0_MODE = TIMER_MODE( 2, 0, 0, 0, 1, 1, 1, 0, 1, 1); } void OSystem_PS2::timerThread(void) { while (!_systemQuit) { WaitSema(g_TimerThreadSema); if (_scummTimerProc) _scummTimerProc(0); } ExitThread(); } void OSystem_PS2::soundThread(void) { ee_sema_t soundSema; soundSema.init_count = 1; soundSema.max_count = 1; _soundSema = CreateSema(&soundSema); assert(_soundSema >= 0); int16 *soundBufL = (int16*)memalign(64, SMP_PER_BLOCK * sizeof(int16) * 2); int16 *soundBufR = soundBufL + SMP_PER_BLOCK; int bufferedSamples = 0; int cycles = 0; while (!_systemQuit) { WaitSema(g_SoundThreadSema); if (!(cycles & 31)) bufferedSamples = SjPCM_Buffered(); else bufferedSamples -= 480; cycles++; WaitSema(_soundSema); if (_scummSoundProc) { if (bufferedSamples <= 4 * SMP_PER_BLOCK) { // we have to produce more samples, call sound mixer // the scratchpad at 0x70000000 is used as temporary soundbuffer _scummSoundProc(_scummSoundParam, (uint8*)0x70000000, SMP_PER_BLOCK * 2 * sizeof(int16)); // demux data into 2 buffers, L and R __asm__ ( "move $t2, %1\n\t" // dest buffer right "move $t3, %0\n\t" // dest buffer left "lui $t8, 0x7000\n\t" // muxed buffer, fixed at 0x70000000 "addiu $t9, $0, 100\n\t" // number of loops "mtsab $0, 2\n\t" // set qword shift = 2 byte "loop:\n\t" " lq $t4, 0($t8)\n\t" // load 8 muxed samples " lq $t5, 16($t8)\n\t" // load 8 more muxed samples " qfsrv $t6, $0, $t4\n\t" // shift right for second " qfsrv $t7, $0, $t5\n\t" // packing step (right channel) " ppach $t4, $t5, $t4\n\t" // combine left channel data " ppach $t6, $t7, $t6\n\t" // right channel data " sq $t4, 0($t3)\n\t" // write back " sq $t6, 0($t2)\n\t" // " addiu $t9, -1\n\t" // decrement loop counter " addiu $t2, 16\n\t" // increment pointers " addiu $t3, 16\n\t" " addiu $t8, 32\n\t" " bnez $t9, loop\n\t" // loop : // outputs : "r"(soundBufL), "r"(soundBufR) // inputs // : "$t2", "$t3", "$t4", "$t5", "$t6", "$t7", "$t8", "$t9" // destroyed : "$10", "$11", "$12", "$13", "$14", "$15", "$24", "$25" // destroyed ); // and feed it into the SPU // non-blocking call, the function will return before the buffer's content // was transferred. SjPCM_Enqueue((short int*)soundBufL, (short int*)soundBufR, SMP_PER_BLOCK, 0); bufferedSamples += SMP_PER_BLOCK; } } SignalSema(_soundSema); } free(soundBufL); DeleteSema(_soundSema); ExitThread(); } const char *irxModules[] = { "rom0:SIO2MAN", "rom0:MCMAN", "rom0:MCSERV", "rom0:PADMAN", "rom0:LIBSD", #ifndef USE_PS2LINK IRX_PREFIX "IOMANX.IRX" IRX_SUFFIX, #endif IRX_PREFIX "FILEXIO.IRX" IRX_SUFFIX, IRX_PREFIX "CDVD.IRX" IRX_SUFFIX, IRX_PREFIX "SJPCM.IRX" IRX_SUFFIX }; void OSystem_PS2::loadModules(void) { _useMouse = _useKbd = false; int res; for (int i = 0; i < ARRAYSIZE(irxModules); i++) { if ((res = SifLoadModule(irxModules[i], 0, NULL)) < 0) { msgPrintf(FOREVER, "Unable to load module %s, Error %d", irxModules[i], res); _screen->wantAnim(false); updateScreen(); SleepThread(); } } // now try to load optional IRXs if ((res = SifLoadModule(IRX_PREFIX "USBD.IRX" IRX_SUFFIX, 0, NULL)) >= 0) { if ((res = SifLoadModule(IRX_PREFIX "PS2MOUSE.IRX" IRX_SUFFIX, 0, NULL)) < 0) sioprintf("Cannot load module: PS2MOUSE.IRX (%d)", res); else _useMouse = true; if ((res = SifLoadModule(IRX_PREFIX "RPCKBD.IRX" IRX_SUFFIX, 0, NULL)) < 0) sioprintf("Cannot load module: RPCKBD.IRX (%d)", res); else _useKbd = true; } sioprintf("Modules: UsbMouse %sloaded, UsbKbd %sloaded.", _useMouse ? "" : "not ", _useKbd ? "" : "not "); } void OSystem_PS2::initSize(uint width, uint height, int overscale) { printf("initializing new size: (%d/%d)...", width, height); _screen->newScreenSize(width, height); _screen->setMouseXy(width / 2, height / 2); _input->newRange(0, 0, width - 1, height - 1); _input->warpTo(width / 2, height / 2); _oldMouseX = width / 2; _oldMouseY = height / 2; printf("done\n"); } void OSystem_PS2::setPalette(const byte *colors, uint start, uint num) { _screen->setPalette((const uint32*)colors, (uint8)start, (uint16)num); } void OSystem_PS2::grabPalette(byte *colors, uint start, uint num) { _screen->grabPalette((uint32*)colors, (uint8)start, (uint16)num); } void OSystem_PS2::copyRectToScreen(const byte *buf, int pitch, int x, int y, int w, int h) { _screen->copyScreenRect((const uint8*)buf, pitch, x, y, w, h); } bool OSystem_PS2::grabRawScreen(Graphics::Surface *surf) { _screen->grabScreen(surf); return true; } void OSystem_PS2::updateScreen(void) { if (_msgClearTime && (_msgClearTime < getMillis())) { _screen->clearPrintfOverlay(); _msgClearTime = 0; } _screen->updateScreen(); } uint32 OSystem_PS2::getMillis(void) { return msecCount; } void OSystem_PS2::delayMillis(uint msecs) { if (msecs == 0) return; int tid = GetThreadId(); if (tid == _soundTid) { sioprintf("ERROR: delayMillis() from sound thread!"); return; } if (tid == _timerTid) { g_TimerWakeUp = (int32)msecs; WaitSema(g_TimerWaitSema); } else { g_MainWakeUp = (int32)msecs; WaitSema(g_MainWaitSema); } } void OSystem_PS2::setTimerCallback(OSystem::TimerProc callback, int interval) { if (callback && (interval != 10)) sioprintf("unhandled timer interval: %d\n", interval); _scummTimerProc = callback; } int OSystem_PS2::getOutputSampleRate(void) const { return 48000; } bool OSystem_PS2::setSoundCallback(SoundProc proc, void *param) { assert(proc != NULL); WaitSema(_soundSema); _scummSoundProc = proc; _scummSoundParam = param; SjPCM_Play(); SignalSema(_soundSema); return true; } void OSystem_PS2::clearSoundCallback(void) { WaitSema(_soundSema); _scummSoundProc = NULL; _scummSoundParam = NULL; SjPCM_Pause(); SignalSema(_soundSema); } Common::SaveFileManager *OSystem_PS2::getSavefileManager(void) { return _saveManager; } #ifndef _REC_MUTEX_ OSystem::MutexRef OSystem_PS2::createMutex(void) { ee_sema_t newSema; newSema.init_count = 1; newSema.max_count = 1; int resSema = CreateSema(&newSema); if (resSema < 0) printf("createMutex: unable to create Semaphore.\n"); return (MutexRef)resSema; } void OSystem_PS2::lockMutex(MutexRef mutex) { WaitSema((int)mutex); } void OSystem_PS2::unlockMutex(MutexRef mutex) { SignalSema((int)mutex); } void OSystem_PS2::deleteMutex(MutexRef mutex) { DeleteSema((int)mutex); } #else OSystem::MutexRef OSystem_PS2::createMutex(void) { WaitSema(_mutexSema); Ps2Mutex *mutex = NULL; for (int i = 0; i < MAX_MUTEXES; i++) if (_mutex[i].sema < 0) { mutex = _mutex + i; break; } if (mutex) { ee_sema_t newSema; newSema.init_count = 1; newSema.max_count = 1; mutex->sema = CreateSema(&newSema); mutex->owner = mutex->count = 0; } else printf("OSystem_PS2::createMutex: ran out of Mutex slots!\n"); SignalSema(_mutexSema); return (OSystem::MutexRef)mutex; } void OSystem_PS2::lockMutex(MutexRef mutex) { WaitSema(_mutexSema); Ps2Mutex *sysMutex = (Ps2Mutex*)mutex; int tid = GetThreadId(); assert(tid != 0); if (sysMutex->owner && (sysMutex->owner == tid)) sysMutex->count++; else { SignalSema(_mutexSema); WaitSema(sysMutex->sema); WaitSema(_mutexSema); sysMutex->owner = tid; sysMutex->count = 0; } SignalSema(_mutexSema); } void OSystem_PS2::unlockMutex(MutexRef mutex) { WaitSema(_mutexSema); Ps2Mutex *sysMutex = (Ps2Mutex*)mutex; int tid = GetThreadId(); if (sysMutex->owner && sysMutex->count && (sysMutex->owner == tid)) sysMutex->count--; else { assert(sysMutex->count == 0); SignalSema(sysMutex->sema); sysMutex->owner = 0; } SignalSema(_mutexSema); } void OSystem_PS2::deleteMutex(MutexRef mutex) { WaitSema(_mutexSema); Ps2Mutex *sysMutex = (Ps2Mutex*)mutex; if (sysMutex->owner || sysMutex->count) printf("WARNING: Deleting LOCKED mutex!\n"); DeleteSema(sysMutex->sema); sysMutex->sema = -1; SignalSema(_mutexSema); } #endif void OSystem_PS2::setShakePos(int shakeOffset) { _screen->setShakePos(shakeOffset); } bool OSystem_PS2::showMouse(bool visible) { bool retVal = _mouseVisible; _screen->showMouse(visible); _mouseVisible = visible; return retVal; } void OSystem_PS2::warpMouse(int x, int y) { _input->warpTo((uint16)x, (uint16)y); _screen->setMouseXy(x, y); } void OSystem_PS2::setMouseCursor(const byte *buf, uint w, uint h, int hotspot_x, int hotspot_y, byte keycolor, int cursorTargetScale) { _screen->setMouseOverlay(buf, w, h, hotspot_x, hotspot_y, keycolor); } bool OSystem_PS2::openCD(int drive) { return false; } bool OSystem_PS2::pollCD(void) { return false; } void OSystem_PS2::playCD(int track, int num_loops, int start_frame, int duration) { } void OSystem_PS2::stopCD(void) { } void OSystem_PS2::updateCD(void) { } void OSystem_PS2::showOverlay(void) { _screen->showOverlay(); } void OSystem_PS2::hideOverlay(void) { _screen->hideOverlay(); } void OSystem_PS2::clearOverlay(void) { _screen->clearOverlay(); } void OSystem_PS2::grabOverlay(OverlayColor *buf, int pitch) { _screen->grabOverlay((uint16*)buf, (uint16)pitch); } void OSystem_PS2::copyRectToOverlay(const OverlayColor *buf, int pitch, int x, int y, int w, int h) { _screen->copyOverlayRect((uint16*)buf, (uint16)pitch, (uint16)x, (uint16)y, (uint16)w, (uint16)h); } const OSystem::GraphicsMode OSystem_PS2::_graphicsMode = { NULL, NULL, 0 }; const OSystem::GraphicsMode *OSystem_PS2::getSupportedGraphicsModes(void) const { return &_graphicsMode; } bool OSystem_PS2::setGraphicsMode(int mode) { return (mode == 0); } int OSystem_PS2::getGraphicsMode(void) const { return 0; } int OSystem_PS2::getDefaultGraphicsMode(void) const { return 0; } bool OSystem_PS2::pollEvent(Event &event) { bool res = _input->pollEvent(&event); if (res && (event.type == EVENT_MOUSEMOVE)) _screen->setMouseXy(event.mouse.x, event.mouse.y); return res; } OverlayColor OSystem_PS2::RGBToColor(uint8 r, uint8 g, uint8 b) { return (r >> 3) | ((g >> 3) << 5) | ((b >> 3) << 10); } void OSystem_PS2::colorToRGB(OverlayColor color, uint8 &r, uint8 &g, uint8 &b) { r = (color & 0x1F) << 3; g = ((color >> 5) & 0x1F) << 3; b = ((color >> 10) & 0x1F) << 3; } int16 OSystem_PS2::getHeight(void) { return _screen->getHeight(); } int16 OSystem_PS2::getWidth(void) { return _screen->getWidth(); } void OSystem_PS2::msgPrintf(int millis, char *format, ...) { va_list ap; char resStr[1024]; memset(resStr, 0, 1024); va_start(ap, format); vsnprintf(resStr, 1023, format, ap); va_end(ap); uint16 posY = 2; int maxWidth = 0; Graphics::Surface surf; surf.create(300, 200, 1); char *lnSta = resStr; while (*lnSta && (posY < 180)) { char *lnEnd = lnSta; while ((*lnEnd) && (*lnEnd != '\n')) lnEnd++; *lnEnd = '\0'; Common::String str(lnSta); int width = Graphics::g_sysfont.getStringWidth(str); if (width > maxWidth) maxWidth = width; int posX = (300 - width) / 2; Graphics::g_sysfont.drawString(&surf, str, posX, posY, 300 - posX, 1); posY += 14; lnSta = lnEnd + 1; } uint8 *scrBuf = (uint8*)memalign(64, 320 * 200); memset(scrBuf, 4, 320 * 200); uint8 *dstPos = scrBuf + ((200 - posY) >> 1) * 320 + (320 - maxWidth) / 2; for (int y = 0; y < posY; y++) { uint8 *srcPos = (uint8*)surf.getBasePtr((300 - maxWidth) / 2, y); for (int x = 0; x < maxWidth; x++) dstPos[x] = srcPos[x] + 5; dstPos += 320; } surf.free(); _screen->copyPrintfOverlay(scrBuf); free(scrBuf); _msgClearTime = millis + getMillis(); } void OSystem_PS2::quit(void) { sioprintf("OSystem_PS2::quit"); clearSoundCallback(); setTimerCallback(NULL, 0); _screen->wantAnim(false); _systemQuit = true; ee_thread_t statSound, statTimer; do { // wait until both threads called ExitThread() ReferThreadStatus(_timerTid, &statTimer); ReferThreadStatus(_soundTid, &statSound); } while ((statSound.status != 0x10) || (statTimer.status != 0x10)); DeleteThread(_timerTid); DeleteThread(_soundTid); free(_timerStack); free(_soundStack); DisableIntc(INT_TIMER0); RemoveIntcHandler(INT_TIMER0, _intrId); _saveManager->quit(); _screen->quit(); padEnd(); // stop pad library cdvdInit(CDVD_EXIT); cdvdExit(); SifExitIopHeap(); SifLoadFileExit(); SifExitRpc(); LoadExecPS2("cdrom0:\\SCUMMVM.ELF", 0, NULL); // resets the console and executes the ELF } static uint32 g_timeSecs; static int g_day, g_month, g_year; static uint32 g_lastTimeCheck; void buildNewDate(int dayDiff) { static int daysPerMonth[12] = { 31, 28, 31, 30, 31, 30, 31, 31, 30, 31, 30, 31 }; if (((g_year % 4) == 0) && (((g_year % 100) != 0) || ((g_year % 1000) == 0))) daysPerMonth[1] = 29; else daysPerMonth[1] = 28; if (dayDiff == -1) { g_day--; if (g_day == 0) { g_month--; if (g_month == 0) { g_year--; g_month = 12; } g_day = daysPerMonth[g_month - 1]; } } else if (dayDiff == 1) { g_day++; if (g_day > daysPerMonth[g_month - 1]) { g_day = 1; g_month++; if (g_month > 12) { g_month = 1; g_year++; } } } } #define SECONDS_PER_DAY (24 * 60 * 60) void OSystem_PS2::readRtcTime(void) { struct CdClock cdClock; CDVD_ReadClock(&cdClock); g_lastTimeCheck = msecCount; if (cdClock.stat) { msgPrintf(5000, "Unable to read RTC time, EC: %d\n", cdClock.stat); g_day = g_month = 1; g_year = 0; g_timeSecs = 0; } else { int gmtOfs = configGetTimezone(); if (configIsDaylightSavingEnabled()) gmtOfs += 60; int timeSecs = (FROM_BCD(cdClock.hour) * 60 + FROM_BCD(cdClock.minute)) * 60 + FROM_BCD(cdClock.second); timeSecs -= 9 * 60 * 60; // minus 9 hours, JST -> GMT conversion timeSecs += gmtOfs * 60; // GMT -> timezone the user selected g_day = FROM_BCD(cdClock.day); g_month = FROM_BCD(cdClock.month); g_year = FROM_BCD(cdClock.year); if (timeSecs < 0) { buildNewDate(-1); timeSecs += SECONDS_PER_DAY; } else if (timeSecs >= SECONDS_PER_DAY) { buildNewDate(+1); timeSecs -= SECONDS_PER_DAY; } g_timeSecs = (uint32)timeSecs; } sioprintf("Time: %d:%02d:%02d - %d.%d.%4d", g_timeSecs / (60 * 60), (g_timeSecs / 60) % 60, g_timeSecs % 60, g_day, g_month, g_year + 2000); } extern time_t time(time_t *p) { return (time_t)g_timeSecs; } extern struct tm *localtime(const time_t *p) { uint32 currentSecs = g_timeSecs + (msecCount - g_lastTimeCheck) / 1000; if (currentSecs >= SECONDS_PER_DAY) { buildNewDate(+1); g_lastTimeCheck += SECONDS_PER_DAY * 1000; currentSecs = g_timeSecs + (msecCount - g_lastTimeCheck) / 1000; } static struct tm retStruct; memset(&retStruct, 0, sizeof(retStruct)); retStruct.tm_hour = currentSecs / (60 * 60); retStruct.tm_min = (currentSecs / 60) % 60; retStruct.tm_sec = currentSecs % 60; retStruct.tm_year = g_year + 100; retStruct.tm_mday = g_day; retStruct.tm_mon = g_month - 1; // tm_wday, tm_yday and tm_isdst are zero for now return &retStruct; }