#include #include #include #include #include #include #include #include "rdisk.h" // Decode keyboard/PRAM settings static void RDDecodeSettings(Ptr unmountEN, Ptr mountEN, Ptr ramEN, Ptr dbgEN, Ptr cdrEN) { // Read PRAM char legacy_startup, legacy_ram; RDiskReadXPRAM(1, 4, &legacy_startup); RDiskReadXPRAM(1, 5, &legacy_ram); // Decode settings: unmount (don't boot), mount (after boot), RAM disk if (RDiskIsRPressed()) { // R boots from ROM disk *unmountEN = 0; // Don't unmount so we boot from this drive *mountEN = 0; // No need to mount later since we are boot disk *ramEN = RDiskIsAPressed(); // A enables RAM disk } else { if (legacy_startup & 0x01) { // Boot from ROM disk *unmountEN = 0; // Don't unmount so we boot from this drive *mountEN = 0; // No need to mount later since we are boot disk *ramEN = legacy_ram & 0x01; } else if (legacy_startup & 0x02) { // Mount ROM disk *unmountEN = 1; // Unmount to not boot from our disk *mountEN = 1; // Mount in accRun *ramEN = legacy_ram & 0x01; } else { *unmountEN = 1; // Unmount *mountEN = 0; // Don't mount again *ramEN = 0; // Don't allocate RAM disk } } // MacsBug enabled if bit 2 == 1 or not boot *dbgEN = *unmountEN || (legacy_startup & 0x04); // CD-ROM enabled if bit 3 == 0 or not boot *cdrEN = *unmountEN || !(legacy_startup & 0x08); } // Switch to 32-bit mode and copy #pragma parameter C24(__A0, __A1, __D0) void C24(Ptr sourcePtr, Ptr destPtr, unsigned long byteCount) { signed char mode = true32b; SwapMMUMode(&mode); BlockMove(sourcePtr, destPtr, byteCount); SwapMMUMode(&mode); } // Switch to 32-bit mode and patch void P24(Ptr romdisk, long index, char patch) { //if (index < 0) { return; } // Don't patch if index < 0 signed char mode = true32b; SwapMMUMode(&mode); romdisk[index] = patch; // Patch byte SwapMMUMode(&mode); } typedef void (*RDiskPatch_t)(Ptr, char, char); static void patch24(Ptr romdisk, char dbgEN, char cdrEN) { RDiskPatch_t fun = (RDiskPatch_t)P24; /*if (!dbgEN)*/ { fun(romdisk, 0x00000031UL, 0x44); } /*if (!cdrEN)*/ { fun(romdisk, 0x00012CAFUL, 0x44); } } // Figure out the first available drive number >= 5 static int RDFindDrvNum() { DrvQElPtr dq; int drvNum = 5; for (dq = (DrvQElPtr)(GetDrvQHdr())->qHead; dq; dq = (DrvQElPtr)dq->qLink) { if (dq->dQDrive >= drvNum) { drvNum = dq->dQDrive + 1; } } return drvNum; } #pragma parameter __D0 RDOpen(__A0, __A1) OSErr RDOpen(IOParamPtr p, DCtlPtr d) { int drvNum; RDiskStorage_t *c; char legacy_startup; // Do nothing if already opened if (d->dCtlStorage) { return noErr; } // Do nothing if inhibited RDiskReadXPRAM(1, 4, &legacy_startup); if (legacy_startup & 0x80) { return noErr; } // Allocate storage struct d->dCtlStorage = NewHandleSysClear(sizeof(RDiskStorage_t)); if (!d->dCtlStorage) { return openErr; } // Lock our storage struct and get master pointer HLock(d->dCtlStorage); c = *(RDiskStorage_t**)d->dCtlStorage; // Find first available drive number drvNum = RDFindDrvNum(); // Set drive status //c->status.track = 0; c->status.writeProt = -1; // nonzero is write protected c->status.diskInPlace = 8; // 8 is nonejectable disk c->status.installed = 1; // drive installed //c->status.sides = 0; //c->status.qType = 1; c->status.dQDrive = drvNum; //c->status.dQFSID = 0; c->status.dQRefNum = d->dCtlRefNum; c->status.driveSize = RDiskSize / 512; //c->status.driveS1 = (RDiskSize / 512) >> 16; // Decompress icon #ifdef RDISK_COMPRESS_ICON_ENABLE char *src = &RDiskIconCompressed[0]; char *dst = &c->icon[0]; UnpackBits(&src, &dst, RDISK_ICON_SIZE); #endif // Add drive to drive queue and return RDiskAddDrive(c->status.dQRefNum, drvNum, (DrvQElPtr)&c->status.qLink); return noErr; } // Init is called at beginning of first prime (read/write) call static void RDInit(IOParamPtr p, DCtlPtr d, RDiskStorage_t *c) { char unmountEN, mountEN, ramEN, dbgEN, cdrEN; // Mark init done c->initialized = 1; // Decode settings RDDecodeSettings(&unmountEN, &mountEN, &ramEN, &dbgEN, &cdrEN); // Set debug and CD-ROM enable flags in storage struct c->dbgEN = dbgEN; c->cdrEN = cdrEN; // If RAM disk enabled, try to allocate RAM disk buffer if not already if (ramEN & !c->ramdisk) { if (*MMU32bit) { // 32-bit mode unsigned long minBufPtr, newBufPtr; // Compute if there is enough high memory minBufPtr = ((unsigned long)*MemTop / 2) + 1024; newBufPtr = (unsigned long)*BufPtr - RDiskSize; if (newBufPtr > minBufPtr && (unsigned long)*BufPtr > newBufPtr) { // Allocate RAM disk buffer by lowering BufPtr *BufPtr = (Ptr)newBufPtr; // Set RAM disk buffer pointer. c->ramdisk = *BufPtr; // Copy ROM disk image to RAM disk BlockMove(RDiskBuf, c->ramdisk, RDiskSize); // Clearing write protect marks RAM disk enabled c->status.writeProt = 0; // Patch debug and CD-ROM enable bytes patch24(c->ramdisk, dbgEN, cdrEN); } } else { // 24-bit mode // Put RAM disk just past 8MB c->ramdisk = (Ptr)(8 * 1024 * 1024); // Copy ROM disk image to RAM disk //FIXME: what if we don't have enough RAM? // Will this wrap around and overwrite low memory? // That's not the worst, since the system would just crash, // but it would be better to switch to read-only status copy24(RDiskBuf, c->ramdisk, RDiskSize); // Clearing write protect marks RAM disk enabled c->status.writeProt = 0; // Patch debug and CD-ROM enable bytes patch24(c->ramdisk, dbgEN, cdrEN); } } // Unmount if not booting from ROM disk if (unmountEN) { c->status.diskInPlace = 0; } // If mount enabled, enable accRun to post disk inserted event later if (mountEN) { d->dCtlDelay = 150; // Set accRun delay (150 ticks is 2.5 sec.) d->dCtlFlags |= dNeedTimeMask; // Enable accRun } } #pragma parameter __D0 RDPrime(__A0, __A1) OSErr RDPrime(IOParamPtr p, DCtlPtr d) { RDiskStorage_t *c; char cmd; Ptr disk; // Return disk offline error if dCtlStorage null if (!d->dCtlStorage) { return notOpenErr; } // Dereference dCtlStorage to get pointer to our context c = *(RDiskStorage_t**)d->dCtlStorage; // Initialize if this is the first prime call if (!c->initialized) { RDInit(p, d, c); } // Return disk offline error if virtual disk not inserted if (!c->status.diskInPlace) { return offLinErr; } // Get pointer to RAM or ROM disk buffer disk = (c->ramdisk ? c->ramdisk : RDiskBuf) + d->dCtlPosition; // Bounds checking if (d->dCtlPosition >= RDiskSize || p->ioReqCount >= RDiskSize || d->dCtlPosition + p->ioReqCount >= RDiskSize) { return paramErr; } // Service read or write request cmd = p->ioTrap & 0x00FF; if (cmd == aRdCmd) { // Read // Read from disk into buffer. if (*MMU32bit) { BlockMove(disk, p->ioBuffer, p->ioReqCount); } else { copy24(disk, StripAddress(p->ioBuffer), p->ioReqCount); } } else if (cmd == aWrCmd) { // Write // Fail if write protected or RAM disk buffer not set up if (c->status.writeProt || !c->ramdisk) { return wPrErr; } // Write from buffer into disk. if (*MMU32bit) { BlockMove(p->ioBuffer, disk, p->ioReqCount); } else { copy24(StripAddress(p->ioBuffer), disk, p->ioReqCount); } } else { return noErr; } //FIXME: Fail if cmd isn't read or write? // Update count and position/offset, then return d->dCtlPosition += p->ioReqCount; p->ioActCount = p->ioReqCount; return noErr; } #pragma parameter __D0 RDCtl(__A0, __A1) OSErr RDCtl(CntrlParamPtr p, DCtlPtr d) { RDiskStorage_t *c; // Fail if dCtlStorage null if (!d->dCtlStorage) { return notOpenErr; } // Dereference dCtlStorage to get pointer to our context c = *(RDiskStorage_t**)d->dCtlStorage; // Handle control request based on csCode switch (p->csCode) { case killCode: return noErr; /*case kFormat: if (!c->status.diskInPlace || c->status.writeProt || !c->ramdisk) { return controlErr; } long zero[32]; for (int i = 0; i < 32; i++) { zero[i] = 0; } for (int i = 0; i < 32; i++) { copy24((Ptr)zero, c->ramdisk + i * sizeof(zero), sizeof(zero)); } return noErr;*/ case kVerify: if (!c->status.diskInPlace) { return controlErr; } return noErr; case kEject: // "Reinsert" disk if ejected illegally if (c->status.diskInPlace) { PostEvent(diskEvt, c->status.dQDrive); } return controlErr; // Eject not allowed so return error case accRun: d->dCtlFlags &= ~dNeedTimeMask; // Disable accRun c->status.diskInPlace = 8; // 8 is nonejectable disk PostEvent(diskEvt, c->status.dQDrive); // Post disk inserted event return noErr; case kDriveIcon: case kMediaIcon: // Get icon #ifdef RDISK_COMPRESS_ICON_ENABLE *(Ptr*)p->csParam = (Ptr)c->icon; #else *(Ptr*)p->csParam = (Ptr)RDiskIcon; #endif return noErr; case kDriveInfo: // high word (bytes 2 & 3) clear // byte 1 = primary + fixed media + internal // byte 0 = drive type (0x10 is RAM disk) / (0x11 is ROM disk) if (c->status.writeProt) { *(long*)p->csParam = 0x00000411; } else { *(long*)p->csParam = 0x00000410; } return noErr; case 24: // Return SCSI partition size *(long*)p->csParam = RDiskSize / 512; return noErr; case 2351: // Post-boot c->initialized = 1; // Skip initialization d->dCtlDelay = 30; // Set accRun delay (30 ticks is 0.5 sec.) d->dCtlFlags |= dNeedTimeMask; // Enable accRun return noErr; default: return controlErr; } } #pragma parameter __D0 RDStat(__A0, __A1) OSErr RDStat(CntrlParamPtr p, DCtlPtr d) { //RDiskStorage_t *c; // Fail if dCtlStorage null if (!d->dCtlStorage) { return notOpenErr; } // Dereference dCtlStorage to get pointer to our context //c = *(RDiskStorage_t**)d->dCtlStorage; // Handle status request based on csCode switch (p->csCode) { case kDriveStatus: BlockMove(*d->dCtlStorage, &p->csParam, sizeof(DrvSts2)); return noErr; default: return statusErr; } } #pragma parameter __D0 RDClose(__A0, __A1) OSErr RDClose(IOParamPtr p, DCtlPtr d) { // If dCtlStorage not null, dispose of it if (!d->dCtlStorage) { return noErr; } //RDiskStorage_t *c = *(RDiskStorage_t**)d->dCtlStorage; HUnlock(d->dCtlStorage); DisposeHandle(d->dCtlStorage); d->dCtlStorage = NULL; return noErr; }