/*************************************************************************** * 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. * ***************************************************************************/ /* * Handles all CD-ROM registers and functions. */ #include "cdrom.h" #include "ppf.h" cdrStruct cdr; /* CD-ROM magic numbers */ #define CdlSync 0 #define CdlNop 1 #define CdlSetloc 2 #define CdlPlay 3 #define CdlForward 4 #define CdlBackward 5 #define CdlReadN 6 #define CdlStandby 7 #define CdlStop 8 #define CdlPause 9 #define CdlInit 10 #define CdlMute 11 #define CdlDemute 12 #define CdlSetfilter 13 #define CdlSetmode 14 #define CdlGetmode 15 #define CdlGetlocL 16 #define CdlGetlocP 17 #define CdlReadT 18 #define CdlGetTN 19 #define CdlGetTD 20 #define CdlSeekL 21 #define CdlSeekP 22 #define CdlSetclock 23 #define CdlGetclock 24 #define CdlTest 25 #define CdlID 26 #define CdlReadS 27 #define CdlReset 28 #define CdlReadToc 30 #define AUTOPAUSE 249 #define READ_ACK 250 #define READ 251 #define REPPLAY_ACK 252 #define REPPLAY 253 #define ASYNC 254 /* don't set 255, it's reserved */ char *CmdName[0x100]= { "CdlSync", "CdlNop", "CdlSetloc", "CdlPlay", "CdlForward", "CdlBackward", "CdlReadN", "CdlStandby", "CdlStop", "CdlPause", "CdlInit", "CdlMute", "CdlDemute", "CdlSetfilter", "CdlSetmode", "CdlGetmode", "CdlGetlocL", "CdlGetlocP", "CdlReadT", "CdlGetTN", "CdlGetTD", "CdlSeekL", "CdlSeekP", "CdlSetclock", "CdlGetclock", "CdlTest", "CdlID", "CdlReadS", "CdlReset", NULL, "CDlReadToc", NULL }; unsigned char Test04[] = { 0 }; unsigned char Test05[] = { 0 }; unsigned char Test20[] = { 0x98, 0x06, 0x10, 0xC3 }; unsigned char Test22[] = { 0x66, 0x6F, 0x72, 0x20, 0x45, 0x75, 0x72, 0x6F }; unsigned char Test23[] = { 0x43, 0x58, 0x44, 0x32, 0x39 ,0x34, 0x30, 0x51 }; // 1x = 75 sectors per second // PSXCLK = 1 sec in the ps // so (PSXCLK / 75) = cdr read time (linuzappz) #define cdReadTime (PSXCLK / 75) static struct CdrStat stat; static struct SubQ *subq; #define CDR_INT(eCycle) { \ psxRegs.interrupt |= 0x4; \ psxRegs.intCycle[2 + 1] = eCycle; \ psxRegs.intCycle[2] = psxRegs.cycle; \ new_dyna_set_event(0, psxRegs.cycle + eCycle); \ } #define CDREAD_INT(eCycle) { \ psxRegs.interrupt |= 0x40000; \ psxRegs.intCycle[2 + 16 + 1] = eCycle; \ psxRegs.intCycle[2 + 16] = psxRegs.cycle; \ new_dyna_set_event(2, psxRegs.cycle + eCycle); \ } #define StartReading(type, eCycle) { \ cdr.Reading = type; \ cdr.FirstSector = 1; \ cdr.Readed = 0xff; \ AddIrqQueue(READ_ACK, eCycle); \ } #define StopReading() { \ if (cdr.Reading) { \ cdr.Reading = 0; \ psxRegs.interrupt &= ~0x40000; \ } \ cdr.StatP &= ~0x20;\ } #define StopCdda() { \ if (cdr.Play) { \ if (!Config.Cdda) CDR_stop(); \ cdr.StatP &= ~0x80; \ cdr.Play = FALSE; \ } \ } #define SetResultSize(size) { \ cdr.ResultP = 0; \ cdr.ResultC = size; \ cdr.ResultReady = 1; \ } static void ReadTrack() { cdr.Prev[0] = itob(cdr.SetSector[0]); cdr.Prev[1] = itob(cdr.SetSector[1]); cdr.Prev[2] = itob(cdr.SetSector[2]); #ifdef CDR_LOG CDR_LOG("ReadTrack() Log: KEY *** %x:%x:%x\n", cdr.Prev[0], cdr.Prev[1], cdr.Prev[2]); #endif cdr.RErr = CDR_readTrack(cdr.Prev); } // cdr.Stat: #define NoIntr 0 #define DataReady 1 #define Complete 2 #define Acknowledge 3 #define DataEnd 4 #define DiskError 5 void AddIrqQueue(unsigned char irq, unsigned long ecycle) { cdr.Irq = irq; if (cdr.Stat) { cdr.eCycle = ecycle; } else { CDR_INT(ecycle); } } void cdrInterrupt() { int i; unsigned char Irq = cdr.Irq; if (cdr.Stat) { CDR_INT(0x1000); return; } cdr.Irq = 0xff; cdr.Ctrl &= ~0x80; switch (Irq) { case CdlSync: SetResultSize(1); cdr.StatP |= 0x2; cdr.Result[0] = cdr.StatP; cdr.Stat = Acknowledge; break; case CdlNop: SetResultSize(1); cdr.Result[0] = cdr.StatP; cdr.Stat = Acknowledge; i = stat.Status; if (CDR_getStatus(&stat) != -1) { if (stat.Type == 0xff) cdr.Stat = DiskError; if (stat.Status & 0x10) { cdr.Stat = DiskError; cdr.Result[0] |= 0x11; cdr.Result[0] &= ~0x02; } else if (i & 0x10) { cdr.StatP |= 0x2; cdr.Result[0] |= 0x2; CheckCdrom(); } } break; case CdlSetloc: cdr.CmdProcess = 0; SetResultSize(1); cdr.StatP |= 0x2; cdr.Result[0] = cdr.StatP; cdr.Stat = Acknowledge; break; case CdlPlay: cdr.CmdProcess = 0; SetResultSize(1); cdr.StatP |= 0x2; cdr.Result[0] = cdr.StatP; cdr.Stat = Acknowledge; cdr.StatP |= 0x80; // if ((cdr.Mode & 0x5) == 0x5) AddIrqQueue(REPPLAY, cdReadTime); break; case CdlForward: cdr.CmdProcess = 0; SetResultSize(1); cdr.StatP |= 0x2; cdr.Result[0] = cdr.StatP; cdr.Stat = Complete; break; case CdlBackward: cdr.CmdProcess = 0; SetResultSize(1); cdr.StatP |= 0x2; cdr.Result[0] = cdr.StatP; cdr.Stat = Complete; break; case CdlStandby: cdr.CmdProcess = 0; SetResultSize(1); cdr.StatP |= 0x2; cdr.Result[0] = cdr.StatP; cdr.Stat = Complete; break; case CdlStop: cdr.CmdProcess = 0; SetResultSize(1); cdr.StatP &= ~0x2; cdr.Result[0] = cdr.StatP; cdr.Stat = Complete; // cdr.Stat = Acknowledge; // check case open/close -shalma i = stat.Status; if (CDR_getStatus(&stat) != -1) { if (stat.Type == 0xff) cdr.Stat = DiskError; if (stat.Status & 0x10) { cdr.Stat = DiskError; cdr.Result[0] |= 0x11; cdr.Result[0] &= ~0x02; } else if (i & 0x10) { cdr.StatP |= 0x2; cdr.Result[0] |= 0x2; CheckCdrom(); } } break; case CdlPause: SetResultSize(1); cdr.Result[0] = cdr.StatP; cdr.Stat = Acknowledge; AddIrqQueue(CdlPause + 0x20, 0x1000); cdr.Ctrl |= 0x80; break; case CdlPause + 0x20: SetResultSize(1); cdr.StatP &= ~0x20; cdr.StatP |= 0x2; cdr.Result[0] = cdr.StatP; cdr.Stat = Complete; break; case CdlInit: SetResultSize(1); cdr.StatP = 0x2; cdr.Result[0] = cdr.StatP; cdr.Stat = Acknowledge; // if (!cdr.Init) { AddIrqQueue(CdlInit + 0x20, 0x1000); // } break; case CdlInit + 0x20: SetResultSize(1); cdr.Result[0] = cdr.StatP; cdr.Stat = Complete; cdr.Init = 1; break; case CdlMute: SetResultSize(1); cdr.StatP |= 0x2; cdr.Result[0] = cdr.StatP; cdr.Stat = Acknowledge; break; case CdlDemute: SetResultSize(1); cdr.StatP |= 0x2; cdr.Result[0] = cdr.StatP; cdr.Stat = Acknowledge; break; case CdlSetfilter: SetResultSize(1); cdr.StatP |= 0x2; cdr.Result[0] = cdr.StatP; cdr.Stat = Acknowledge; break; case CdlSetmode: SetResultSize(1); cdr.StatP |= 0x2; cdr.Result[0] = cdr.StatP; cdr.Stat = Acknowledge; break; case CdlGetmode: SetResultSize(6); cdr.StatP |= 0x2; cdr.Result[0] = cdr.StatP; cdr.Result[1] = cdr.Mode; cdr.Result[2] = cdr.File; cdr.Result[3] = cdr.Channel; cdr.Result[4] = 0; cdr.Result[5] = 0; cdr.Stat = Acknowledge; break; case CdlGetlocL: SetResultSize(8); // for (i = 0; i < 8; i++) // cdr.Result[i] = itob(cdr.Transfer[i]); for (i = 0; i < 8; i++) cdr.Result[i] = cdr.Transfer[i]; cdr.Stat = Acknowledge; break; case CdlGetlocP: SetResultSize(8); subq = (struct SubQ *)CDR_getBufferSub(); if (subq != NULL) { cdr.Result[0] = subq->TrackNumber; cdr.Result[1] = subq->IndexNumber; memcpy(cdr.Result + 2, subq->TrackRelativeAddress, 3); memcpy(cdr.Result + 5, subq->AbsoluteAddress, 3); // subQ integrity check if (calcCrc((u8 *)subq + 12, 10) != (((u16)subq->CRC[0] << 8) | subq->CRC[1])) { memset(cdr.Result + 2, 0, 3 + 3); // CRC wrong, wipe out time data } } else { cdr.Result[0] = 1; cdr.Result[1] = 1; cdr.Result[2] = btoi(cdr.Prev[0]); cdr.Result[3] = btoi(cdr.Prev[1]) - 2; cdr.Result[4] = cdr.Prev[2]; // m:s adjustment if ((s8)cdr.Result[3] < 0) { cdr.Result[3] += 60; cdr.Result[2] -= 1; } cdr.Result[2] = itob(cdr.Result[2]); cdr.Result[3] = itob(cdr.Result[3]); memcpy(cdr.Result + 5, cdr.Prev, 3); } cdr.Stat = Acknowledge; break; case CdlGetTN: cdr.CmdProcess = 0; SetResultSize(3); cdr.StatP |= 0x2; cdr.Result[0] = cdr.StatP; if (CDR_getTN(cdr.ResultTN) == -1) { cdr.Stat = DiskError; cdr.Result[0] |= 0x01; } else { cdr.Stat = Acknowledge; cdr.Result[1] = itob(cdr.ResultTN[0]); cdr.Result[2] = itob(cdr.ResultTN[1]); } break; case CdlGetTD: cdr.CmdProcess = 0; cdr.Track = btoi(cdr.Param[0]); SetResultSize(4); cdr.StatP |= 0x2; if (CDR_getTD(cdr.Track, cdr.ResultTD) == -1) { cdr.Stat = DiskError; cdr.Result[0] |= 0x01; } else { cdr.Stat = Acknowledge; cdr.Result[0] = cdr.StatP; cdr.Result[1] = itob(cdr.ResultTD[2]); cdr.Result[2] = itob(cdr.ResultTD[1]); cdr.Result[3] = itob(cdr.ResultTD[0]); } break; case CdlSeekL: SetResultSize(1); cdr.StatP |= 0x2; cdr.Result[0] = cdr.StatP; cdr.StatP |= 0x40; cdr.Stat = Acknowledge; cdr.Seeked = TRUE; AddIrqQueue(CdlSeekL + 0x20, 0x1000); break; case CdlSeekL + 0x20: SetResultSize(1); cdr.StatP |= 0x2; cdr.StatP &= ~0x40; cdr.Result[0] = cdr.StatP; cdr.Stat = Complete; break; case CdlSeekP: SetResultSize(1); cdr.StatP |= 0x2; cdr.Result[0] = cdr.StatP; cdr.StatP |= 0x40; cdr.Stat = Acknowledge; AddIrqQueue(CdlSeekP + 0x20, 0x1000); break; case CdlSeekP + 0x20: SetResultSize(1); cdr.StatP |= 0x2; cdr.StatP &= ~0x40; cdr.Result[0] = cdr.StatP; cdr.Stat = Complete; break; case CdlTest: cdr.Stat = Acknowledge; switch (cdr.Param[0]) { case 0x20: // System Controller ROM Version SetResultSize(4); memcpy(cdr.Result, Test20, 4); break; case 0x22: SetResultSize(8); memcpy(cdr.Result, Test22, 4); break; case 0x23: case 0x24: SetResultSize(8); memcpy(cdr.Result, Test23, 4); break; } break; case CdlID: SetResultSize(1); cdr.StatP |= 0x2; cdr.Result[0] = cdr.StatP; cdr.Stat = Acknowledge; AddIrqQueue(CdlID + 0x20, 0x1000); break; case CdlID + 0x20: SetResultSize(8); if (CDR_getStatus(&stat) == -1) { cdr.Result[0] = 0x00; // 0x08 and cdr.Result[1]|0x10 : audio cd, enters cd player cdr.Result[1] = 0x00; // 0x80 leads to the menu in the bios, else loads CD } else { if (stat.Type == 2) { cdr.Result[0] = 0x08; cdr.Result[1] = 0x10; } else { cdr.Result[0] = 0x00; cdr.Result[1] = 0x00; } } cdr.Result[1] |= 0x80; cdr.Result[2] = 0x00; cdr.Result[3] = 0x00; strncpy((char *)&cdr.Result[4], "PCSX", 4); cdr.Stat = Complete; break; case CdlReset: SetResultSize(1); cdr.StatP = 0x2; cdr.Result[0] = cdr.StatP; cdr.Stat = Acknowledge; break; case CdlReadToc: SetResultSize(1); cdr.StatP |= 0x2; cdr.Result[0] = cdr.StatP; cdr.Stat = Acknowledge; AddIrqQueue(CdlReadToc + 0x20, 0x1000); break; case CdlReadToc + 0x20: SetResultSize(1); cdr.StatP |= 0x2; cdr.Result[0] = cdr.StatP; cdr.Stat = Complete; break; case AUTOPAUSE: cdr.OCUP = 0; /* SetResultSize(1); StopCdda(); StopReading(); cdr.OCUP = 0; cdr.StatP&=~0x20; cdr.StatP|= 0x2; cdr.Result[0] = cdr.StatP; cdr.Stat = DataEnd; */ AddIrqQueue(CdlPause, 0x800); break; case READ_ACK: if (!cdr.Reading) return; SetResultSize(1); cdr.StatP |= 0x2; cdr.Result[0] = cdr.StatP; if (!cdr.Seeked) { cdr.Seeked = TRUE; cdr.StatP |= 0x40; } cdr.StatP |= 0x20; cdr.Stat = Acknowledge; // CDREAD_INT((cdr.Mode & 0x80) ? (cdReadTime / 2) : cdReadTime); CDREAD_INT(0x80000); break; case REPPLAY_ACK: cdr.Stat = Acknowledge; cdr.Result[0] = cdr.StatP; SetResultSize(1); AddIrqQueue(REPPLAY, cdReadTime); break; case REPPLAY: if ((cdr.Mode & 5) != 5) break; /* if (CDR_getStatus(&stat) == -1) { cdr.Result[0] = 0; cdr.Result[1] = 0; cdr.Result[2] = 0; cdr.Result[3] = 0; cdr.Result[4] = 0; cdr.Result[5] = 0; cdr.Result[6] = 0; cdr.Result[7] = 0; } else memcpy(cdr.Result, &stat.Track, 8); cdr.Stat = 1; SetResultSize(8); AddIrqQueue(REPPLAY_ACK, cdReadTime); */ break; case 0xff: return; default: cdr.Stat = Complete; break; } if (cdr.Stat != NoIntr && cdr.Reg2 != 0x18) { psxHu32ref(0x1070) |= SWAP32((u32)0x4); } #ifdef CDR_LOG CDR_LOG("cdrInterrupt() Log: CDR Interrupt IRQ %x\n", Irq); #endif } void cdrReadInterrupt() { u8 *buf; if (!cdr.Reading) return; if (cdr.Stat) { CDREAD_INT(0x1000); return; } #ifdef CDR_LOG CDR_LOG("cdrReadInterrupt() Log: KEY END"); #endif cdr.OCUP = 1; SetResultSize(1); cdr.StatP |= 0x22; cdr.StatP &= ~0x40; cdr.Result[0] = cdr.StatP; ReadTrack(); buf = CDR_getBuffer(); if (buf == NULL) cdr.RErr = -1; if (cdr.RErr == -1) { #ifdef CDR_LOG fprintf(emuLog, "cdrReadInterrupt() Log: err\n"); #endif memset(cdr.Transfer, 0, DATA_SIZE); cdr.Stat = DiskError; cdr.Result[0] |= 0x01; CDREAD_INT((cdr.Mode & 0x80) ? (cdReadTime / 2) : cdReadTime); return; } memcpy(cdr.Transfer, buf, DATA_SIZE); CheckPPFCache(cdr.Transfer, cdr.Prev[0], cdr.Prev[1], cdr.Prev[2]); cdr.Stat = DataReady; #ifdef CDR_LOG fprintf(emuLog, "cdrReadInterrupt() Log: cdr.Transfer %x:%x:%x\n", cdr.Transfer[0], cdr.Transfer[1], cdr.Transfer[2]); #endif if ((!cdr.Muted) && (cdr.Mode & 0x40) && (!Config.Xa) && (cdr.FirstSector != -1)) { // CD-XA if ((cdr.Transfer[4 + 2] & 0x4) && ((cdr.Mode & 0x8) ? (cdr.Transfer[4 + 1] == cdr.Channel) : 1) && (cdr.Transfer[4 + 0] == cdr.File)) { int ret = xa_decode_sector(&cdr.Xa, cdr.Transfer+4, cdr.FirstSector); if (!ret) { SPU_playADPCMchannel(&cdr.Xa); cdr.FirstSector = 0; } else cdr.FirstSector = -1; } } cdr.SetSector[2]++; if (cdr.SetSector[2] == 75) { cdr.SetSector[2] = 0; cdr.SetSector[1]++; if (cdr.SetSector[1] == 60) { cdr.SetSector[1] = 0; cdr.SetSector[0]++; } } cdr.Readed = 0; if ((cdr.Transfer[4 + 2] & 0x80) && (cdr.Mode & 0x2)) { // EOF #ifdef CDR_LOG CDR_LOG("cdrReadInterrupt() Log: Autopausing read\n"); #endif // AddIrqQueue(AUTOPAUSE, 0x1000); AddIrqQueue(CdlPause, 0x1000); } else { CDREAD_INT((cdr.Mode & 0x80) ? (cdReadTime / 2) : cdReadTime); } psxHu32ref(0x1070) |= SWAP32((u32)0x4); } /* cdrRead0: bit 0 - 0 REG1 command send / 1 REG1 data read bit 1 - 0 data transfer finish / 1 data transfer ready/in progress bit 2 - unknown bit 3 - unknown bit 4 - unknown bit 5 - 1 result ready bit 6 - 1 dma ready bit 7 - 1 command being processed */ unsigned char cdrRead0(void) { if (cdr.ResultReady) cdr.Ctrl |= 0x20; else cdr.Ctrl &= ~0x20; if (cdr.OCUP) cdr.Ctrl |= 0x40; // else // cdr.Ctrl &= ~0x40; // What means the 0x10 and the 0x08 bits? I only saw it used by the bios cdr.Ctrl |= 0x18; #ifdef CDR_LOG CDR_LOG("cdrRead0() Log: CD0 Read: %x\n", cdr.Ctrl); #endif return psxHu8(0x1800) = cdr.Ctrl; } /* cdrWrite0: 0 - to send a command / 1 - to get the result */ void cdrWrite0(unsigned char rt) { #ifdef CDR_LOG CDR_LOG("cdrWrite0() Log: CD0 write: %x\n", rt); #endif cdr.Ctrl = rt | (cdr.Ctrl & ~0x3); if (rt == 0) { cdr.ParamP = 0; cdr.ParamC = 0; cdr.ResultReady = 0; } } unsigned char cdrRead1(void) { if (cdr.ResultReady) { // && cdr.Ctrl & 0x1) { psxHu8(0x1801) = cdr.Result[cdr.ResultP++]; if (cdr.ResultP == cdr.ResultC) cdr.ResultReady = 0; } else { psxHu8(0x1801) = 0; } #ifdef CDR_LOG CDR_LOG("cdrRead1() Log: CD1 Read: %x\n", psxHu8(0x1801)); #endif return psxHu8(0x1801); } void cdrWrite1(unsigned char rt) { int i; #ifdef CDR_LOG CDR_LOG("cdrWrite1() Log: CD1 write: %x (%s)\n", rt, CmdName[rt]); #endif // psxHu8(0x1801) = rt; cdr.Cmd = rt; cdr.OCUP = 0; #ifdef CDRCMD_DEBUG SysPrintf("cdrWrite1() Log: CD1 write: %x (%s)", rt, CmdName[rt]); if (cdr.ParamC) { SysPrintf(" Param[%d] = {", cdr.ParamC); for (i = 0; i < cdr.ParamC; i++) SysPrintf(" %x,", cdr.Param[i]); SysPrintf("}\n"); } else { SysPrintf("\n"); } #endif if (cdr.Ctrl & 0x1) return; switch (cdr.Cmd) { case CdlSync: cdr.Ctrl |= 0x80; cdr.Stat = NoIntr; AddIrqQueue(cdr.Cmd, 0x1000); break; case CdlNop: cdr.Ctrl |= 0x80; cdr.Stat = NoIntr; AddIrqQueue(cdr.Cmd, 0x1000); break; case CdlSetloc: StopReading(); cdr.Seeked = FALSE; for (i = 0; i < 3; i++) cdr.SetSector[i] = btoi(cdr.Param[i]); cdr.SetSector[3] = 0; /* if ((cdr.SetSector[0] | cdr.SetSector[1] | cdr.SetSector[2]) == 0) { *(u32 *)cdr.SetSector = *(u32 *)cdr.SetSectorSeek; }*/ cdr.Ctrl |= 0x80; cdr.Stat = NoIntr; AddIrqQueue(cdr.Cmd, 0x1000); break; case CdlPlay: if (!cdr.SetSector[0] & !cdr.SetSector[1] & !cdr.SetSector[2]) { if (CDR_getTN(cdr.ResultTN) != -1) { if (cdr.CurTrack > cdr.ResultTN[1]) cdr.CurTrack = cdr.ResultTN[1]; if (CDR_getTD((unsigned char)(cdr.CurTrack), cdr.ResultTD) != -1) { int tmp = cdr.ResultTD[2]; cdr.ResultTD[2] = cdr.ResultTD[0]; cdr.ResultTD[0] = tmp; if (!Config.Cdda) CDR_play(cdr.ResultTD); } } } else if (!Config.Cdda) { CDR_play(cdr.SetSector); } cdr.Play = TRUE; cdr.Ctrl |= 0x80; cdr.Stat = NoIntr; AddIrqQueue(cdr.Cmd, 0x1000); break; case CdlForward: if (cdr.CurTrack < 0xaa) cdr.CurTrack++; cdr.Ctrl |= 0x80; cdr.Stat = NoIntr; AddIrqQueue(cdr.Cmd, 0x1000); break; case CdlBackward: if (cdr.CurTrack > 1) cdr.CurTrack--; cdr.Ctrl |= 0x80; cdr.Stat = NoIntr; AddIrqQueue(cdr.Cmd, 0x1000); break; case CdlReadN: cdr.Irq = 0; StopReading(); cdr.Ctrl|= 0x80; cdr.Stat = NoIntr; StartReading(1, 0x1000); break; case CdlStandby: StopCdda(); StopReading(); cdr.Ctrl |= 0x80; cdr.Stat = NoIntr; AddIrqQueue(cdr.Cmd, 0x1000); break; case CdlStop: StopCdda(); StopReading(); cdr.Ctrl |= 0x80; cdr.Stat = NoIntr; AddIrqQueue(cdr.Cmd, 0x1000); break; case CdlPause: StopCdda(); StopReading(); cdr.Ctrl |= 0x80; cdr.Stat = NoIntr; AddIrqQueue(cdr.Cmd, 0x80000); break; case CdlReset: case CdlInit: StopCdda(); StopReading(); cdr.Ctrl |= 0x80; cdr.Stat = NoIntr; AddIrqQueue(cdr.Cmd, 0x1000); break; case CdlMute: cdr.Muted = TRUE; cdr.Ctrl |= 0x80; cdr.Stat = NoIntr; AddIrqQueue(cdr.Cmd, 0x1000); break; case CdlDemute: cdr.Muted = FALSE; cdr.Ctrl |= 0x80; cdr.Stat = NoIntr; AddIrqQueue(cdr.Cmd, 0x1000); break; case CdlSetfilter: cdr.File = cdr.Param[0]; cdr.Channel = cdr.Param[1]; cdr.Ctrl |= 0x80; cdr.Stat = NoIntr; AddIrqQueue(cdr.Cmd, 0x1000); break; case CdlSetmode: #ifdef CDR_LOG CDR_LOG("cdrWrite1() Log: Setmode %x\n", cdr.Param[0]); #endif cdr.Mode = cdr.Param[0]; cdr.Ctrl |= 0x80; cdr.Stat = NoIntr; AddIrqQueue(cdr.Cmd, 0x1000); break; case CdlGetmode: cdr.Ctrl |= 0x80; cdr.Stat = NoIntr; AddIrqQueue(cdr.Cmd, 0x1000); break; case CdlGetlocL: cdr.Ctrl |= 0x80; cdr.Stat = NoIntr; AddIrqQueue(cdr.Cmd, 0x1000); break; case CdlGetlocP: cdr.Ctrl |= 0x80; cdr.Stat = NoIntr; AddIrqQueue(cdr.Cmd, 0x1000); break; case CdlGetTN: cdr.Ctrl |= 0x80; cdr.Stat = NoIntr; AddIrqQueue(cdr.Cmd, 0x1000); break; case CdlGetTD: cdr.Ctrl |= 0x80; cdr.Stat = NoIntr; AddIrqQueue(cdr.Cmd, 0x1000); break; case CdlSeekL: // ((u32 *)cdr.SetSectorSeek)[0] = ((u32 *)cdr.SetSector)[0]; cdr.Ctrl |= 0x80; cdr.Stat = NoIntr; AddIrqQueue(cdr.Cmd, 0x1000); break; case CdlSeekP: // ((u32 *)cdr.SetSectorSeek)[0] = ((u32 *)cdr.SetSector)[0]; cdr.Ctrl |= 0x80; cdr.Stat = NoIntr; AddIrqQueue(cdr.Cmd, 0x1000); break; case CdlTest: cdr.Ctrl |= 0x80; cdr.Stat = NoIntr; AddIrqQueue(cdr.Cmd, 0x1000); break; case CdlID: cdr.Ctrl |= 0x80; cdr.Stat = NoIntr; AddIrqQueue(cdr.Cmd, 0x1000); break; case CdlReadS: cdr.Irq = 0; StopReading(); cdr.Ctrl |= 0x80; cdr.Stat = NoIntr; StartReading(2, 0x1000); break; case CdlReadToc: cdr.Ctrl |= 0x80; cdr.Stat = NoIntr; AddIrqQueue(cdr.Cmd, 0x1000); break; default: #ifdef CDR_LOG CDR_LOG("cdrWrite1() Log: Unknown command: %x\n", cdr.Cmd); #endif return; } if (cdr.Stat != NoIntr) { psxHu32ref(0x1070) |= SWAP32((u32)0x4); } } unsigned char cdrRead2(void) { unsigned char ret; if (cdr.Readed == 0) { ret = 0; } else { ret = *cdr.pTransfer++; } #ifdef CDR_LOG CDR_LOG("cdrRead2() Log: CD2 Read: %x\n", ret); #endif return ret; } void cdrWrite2(unsigned char rt) { #ifdef CDR_LOG CDR_LOG("cdrWrite2() Log: CD2 write: %x\n", rt); #endif if (cdr.Ctrl & 0x1) { switch (rt) { case 0x07: cdr.ParamP = 0; cdr.ParamC = 0; cdr.ResultReady = 1; //0; cdr.Ctrl &= ~3; //cdr.Ctrl = 0; break; default: cdr.Reg2 = rt; break; } } else if (!(cdr.Ctrl & 0x1) && cdr.ParamP < 8) { cdr.Param[cdr.ParamP++] = rt; cdr.ParamC++; } } unsigned char cdrRead3(void) { if (cdr.Stat) { if (cdr.Ctrl & 0x1) psxHu8(0x1803) = cdr.Stat | 0xE0; else psxHu8(0x1803) = 0xff; } else { psxHu8(0x1803) = 0; } #ifdef CDR_LOG CDR_LOG("cdrRead3() Log: CD3 Read: %x\n", psxHu8(0x1803)); #endif return psxHu8(0x1803); } void cdrWrite3(unsigned char rt) { #ifdef CDR_LOG CDR_LOG("cdrWrite3() Log: CD3 write: %x\n", rt); #endif if (rt == 0x07 && cdr.Ctrl & 0x1) { cdr.Stat = 0; if (cdr.Irq == 0xff) { cdr.Irq = 0; return; } if (cdr.Irq) CDR_INT(cdr.eCycle); if (cdr.Reading && !cdr.ResultReady) CDREAD_INT((cdr.Mode & 0x80) ? (cdReadTime / 2) : cdReadTime); return; } if (rt == 0x80 && !(cdr.Ctrl & 0x1) && cdr.Readed == 0) { cdr.Readed = 1; cdr.pTransfer = cdr.Transfer; switch (cdr.Mode & 0x30) { case 0x10: case 0x00: cdr.pTransfer += 12; break; default: break; } } } void psxDma3(u32 madr, u32 bcr, u32 chcr) { u32 cdsize; u8 *ptr; #ifdef CDR_LOG CDR_LOG("psxDma3() Log: *** DMA 3 *** %x addr = %x size = %x\n", chcr, madr, bcr); #endif switch (chcr) { case 0x11000000: case 0x11400100: if (cdr.Readed == 0) { #ifdef CDR_LOG CDR_LOG("psxDma3() Log: *** DMA 3 *** NOT READY\n"); #endif break; } cdsize = (bcr & 0xffff) * 4; ptr = (u8 *)PSXM(madr); if (ptr == NULL) { #ifdef CPU_LOG CDR_LOG("psxDma3() Log: *** DMA 3 *** NULL Pointer!\n"); #endif break; } memcpy(ptr, cdr.pTransfer, cdsize); psxCpu->Clear(madr, cdsize / 4); cdr.pTransfer += cdsize; break; default: #ifdef CDR_LOG CDR_LOG("psxDma3() Log: Unknown cddma %x\n", chcr); #endif break; } HW_DMA3_CHCR &= SWAP32(~0x01000000); DMA_INTERRUPT(3); } void cdrReset() { memset(&cdr, 0, sizeof(cdr)); cdr.CurTrack = 1; cdr.File = 1; cdr.Channel = 1; } int cdrFreeze(gzFile f, int Mode) { uintptr_t tmp; gzfreeze(&cdr, sizeof(cdr)); if (Mode == 1) tmp = cdr.pTransfer - cdr.Transfer; gzfreeze(&tmp, sizeof(tmp)); if (Mode == 0) cdr.pTransfer = cdr.Transfer + tmp; return 0; }