// Copyright (C) 2001 MandrakeSoft S.A. // // MandrakeSoft S.A. // 43, rue d'Aboukir // 75002 Paris - France // http://www.linux-mandrake.com/ // http://www.mandrakesoft.com/ // // This library is free software; you can redistribute it and/or // modify it under the terms of the GNU Lesser General Public // License as published by the Free Software Foundation; either // version 2 of the License, or (at your option) any later version. // // This library 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 // Lesser General Public License for more details. // // You should have received a copy of the GNU Lesser General Public // License along with this library; if not, write to the Free Software // Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA // Useful docs: // AT Attachment with Packet Interface // working draft by T13 at www.t13.org #include "bochs.h" #define LOG_THIS bx_hard_drive. #define INDEX_PULSE_CYCLE 10 #define PACKET_SIZE 12 bx_hard_drive_c bx_hard_drive; #if BX_USE_HD_SMF #define this (&bx_hard_drive) #endif static unsigned char model_no[41] = "Generic 1234 "; static unsigned max_multiple_sectors = 0; // was 0x3f static unsigned curr_multiple_sectors = 0; // was 0x3f // some packet handling macros #define EXTRACT_FIELD(arr,byte,start,num_bits) (((arr)[(byte)] >> (start)) & ((1 << (num_bits)) - 1)) #define get_packet_field(b,s,n) (EXTRACT_FIELD((BX_SELECTED_CONTROLLER.buffer),(b),(s),(n))) #define get_packet_byte(b) (BX_SELECTED_CONTROLLER.buffer[(b)]) #define get_packet_word(b) (((uint16)BX_SELECTED_CONTROLLER.buffer[(b)] << 8) | BX_SELECTED_CONTROLLER.buffer[(b)+1]) #define BX_CONTROLLER(a) (BX_HD_THIS s[(a)]).controller #define BX_SELECTED_CONTROLLER (BX_CONTROLLER(BX_HD_THIS drive_select)) #define WRITE_FEATURES(a) do { uint8 _a = a; BX_CONTROLLER(0).features = _a; BX_CONTROLLER(1).features = _a; } while(0) #define WRITE_SECTOR_COUNT(a) do { uint8 _a = a; BX_CONTROLLER(0).sector_count = _a; BX_CONTROLLER(1).sector_count = _a; } while(0) #define WRITE_SECTOR_NUMBER(a) do { uint8 _a = a; BX_CONTROLLER(0).sector_no = _a; BX_CONTROLLER(1).sector_no = _a; } while(0) #define WRITE_CYLINDER_LOW(a) do { uint8 _a = a; BX_CONTROLLER(0).cylinder_no = (BX_CONTROLLER(0).cylinder_no & 0xff00) | _a; BX_CONTROLLER(1).cylinder_no = (BX_CONTROLLER(1).cylinder_no & 0xff00) | _a; } while(0) #define WRITE_CYLINDER_HIGH(a) do { uint16 _a = a; BX_CONTROLLER(0).cylinder_no = (_a << 8) | (BX_CONTROLLER(0).cylinder_no & 0xff); BX_CONTROLLER(1).cylinder_no = (_a << 8) | (BX_CONTROLLER(1).cylinder_no & 0xff); } while(0) #define WRITE_HEAD_NO(a) do { uint8 _a = a; BX_CONTROLLER(0).head_no = _a; BX_CONTROLLER(1).head_no = _a; } while(0) #define WRITE_LBA_MODE(a) do { uint8 _a = a; BX_CONTROLLER(0).lba_mode = _a; BX_CONTROLLER(1).lba_mode = _a; } while(0) //static unsigned im_here = 0; bx_hard_drive_c::bx_hard_drive_c(void) { put("HD"); settype(HDLOG); #if EXTERNAL_DISK_SIMULATOR s[0].hard_drive = new EXTERNAL_DISK_SIMULATOR_CLASS(); s[1].hard_drive = new EXTERNAL_DISK_SIMULATOR_CLASS(); #else #if BX_SPLIT_HD_SUPPORT // use new concatenated image object s[0].hard_drive = new concat_image_t(); s[1].hard_drive = new concat_image_t(); #else s[0].hard_drive = new default_image_t(); s[1].hard_drive = new default_image_t(); #endif #endif } bx_hard_drive_c::~bx_hard_drive_c(void) { // nothing for now BX_DEBUG(("Exit.")); } void bx_hard_drive_c::init(bx_devices_c *d, bx_cmos_c *cmos) { BX_HD_THIS devices = d; BX_DEBUG(("Init $Id: harddrv.cc,v 1.33 2001-09-28 07:14:50 bdenney Exp $")); /* HARD DRIVE 0 */ BX_HD_THIS devices->register_irq(14, "Hard Drive 0"); for (unsigned addr=0x01F0; addr<=0x01F7; addr++) { BX_HD_THIS devices->register_io_read_handler(this, read_handler, addr, "Hard Drive 0"); BX_HD_THIS devices->register_io_write_handler(this, write_handler, addr, "Hard Drive 0"); } #if 0 // this would be necessary to make the second HD master on the // second controller, using 0x170-0x177 and irq15. But it currently // works as second disk on the first IDE controller, so this code // is not needed. BX_HD_THIS devices->register_irq(15, "Hard Drive 1"); for (unsigned addr=0x0170; addr<=0x0177; addr++) { BX_HD_THIS devices->register_io_read_handler(this, read_handler, addr, "Hard Drive 1"); BX_HD_THIS devices->register_io_write_handler(this, write_handler, addr, "Hard Drive 1"); } #endif BX_HD_THIS drive_select = 0; BX_HD_THIS s[0].hard_drive->cylinders = bx_options.diskc.Ocylinders->get (); BX_HD_THIS s[0].hard_drive->heads = bx_options.diskc.Oheads->get (); BX_HD_THIS s[0].hard_drive->sectors = bx_options.diskc.Ospt->get (); BX_HD_THIS s[0].device_type = IDE_DISK; BX_HD_THIS s[1].hard_drive->cylinders = bx_options.diskd.Ocylinders->get (); BX_HD_THIS s[1].hard_drive->heads = bx_options.diskd.Oheads->get (); BX_HD_THIS s[1].hard_drive->sectors = bx_options.diskd.Ospt->get (); BX_HD_THIS s[1].device_type = IDE_DISK; if (bx_options.cdromd.Opresent->get ()) { bx_options.diskd.Opresent->set (1); BX_DEBUG(( "Experimental CDROM on target 1" )); BX_HD_THIS s[1].device_type = IDE_CDROM; BX_HD_THIS s[1].cdrom.locked = 0; BX_HD_THIS s[1].sense.sense_key = SENSE_NONE; BX_HD_THIS s[1].sense.asc = 0; BX_HD_THIS s[1].sense.ascq = 0; // Check bit fields BX_CONTROLLER(1).sector_count = 0; BX_CONTROLLER(1).interrupt_reason.c_d = 1; if (BX_CONTROLLER(1).sector_count != 0x01) BX_PANIC(("interrupt reason bit field error")); BX_CONTROLLER(1).sector_count = 0; BX_CONTROLLER(1).interrupt_reason.i_o = 1; if (BX_CONTROLLER(1).sector_count != 0x02) BX_PANIC(("interrupt reason bit field error")); BX_CONTROLLER(1).sector_count = 0; BX_CONTROLLER(1).interrupt_reason.rel = 1; if (BX_CONTROLLER(1).sector_count != 0x04) BX_PANIC(("interrupt reason bit field error")); BX_CONTROLLER(1).sector_count = 0; BX_CONTROLLER(1).interrupt_reason.tag = 3; if (BX_CONTROLLER(1).sector_count != 0x18) BX_PANIC(("interrupt reason bit field error")); BX_CONTROLLER(1).sector_count = 0; // allocate low level driver #ifdef LOWLEVEL_CDROM BX_HD_THIS s[1].cdrom.cd = new LOWLEVEL_CDROM(bx_options.cdromd.Opath->getptr ()); #endif #ifdef LOWLEVEL_CDROM if (bx_options.cdromd.Oinserted->get () == BX_INSERTED) { if (BX_HD_THIS s[1].cdrom.cd->insert_cdrom()) { BX_INFO(( "Media present in CD-ROM drive")); BX_HD_THIS s[1].cdrom.ready = 1; BX_HD_THIS s[1].cdrom.capacity = BX_HD_THIS s[1].cdrom.cd->capacity(); } else { BX_INFO(( "Could not locate CD-ROM, continuing with media not present")); BX_HD_THIS s[1].cdrom.ready = 0; } } else { #endif BX_INFO(( "Media not present in CD-ROM drive" )); BX_HD_THIS s[1].cdrom.ready = 0; #ifdef LOWLEVEL_CDROM } #endif } /* open hard drive image file */ if (bx_options.diskc.Opresent->get ()) { if ((BX_HD_THIS s[0].hard_drive->open(bx_options.diskc.Opath->getptr ())) < 0) { BX_PANIC(("could not open hard drive image file '%s'", bx_options.diskc.Opath->getptr ())); } BX_INFO(("hd0: '%s'",bx_options.diskc.Opath->getptr ())); } if (bx_options.diskd.Opresent->get () && !bx_options.cdromd.Opresent->get ()) { if ((BX_HD_THIS s[1].hard_drive->open(bx_options.diskd.Opath->getptr ())) < 0) { BX_PANIC(("could not open hard drive image file '%s'", bx_options.diskd.Opath->getptr ())); } BX_INFO(("hd1: '%s'",bx_options.diskd.Opath->getptr())); } // generate CMOS values for hard drive if not using a CMOS image if (!bx_options.cmos.OcmosImage->get ()) { cmos->s.reg[0x12] = 0x00; // start out with: no drive 0, no drive 1 if (bx_options.diskc.Opresent->get ()) { // Flag drive type as Fh, use extended CMOS location as real type cmos->s.reg[0x12] = (cmos->s.reg[0x12] & 0x0f) | 0xf0; cmos->s.reg[0x19] = 47; // user definable type // AMI BIOS: 1st hard disk #cyl low byte cmos->s.reg[0x1b] = (bx_options.diskc.Ocylinders->get () & 0x00ff); // AMI BIOS: 1st hard disk #cyl high byte cmos->s.reg[0x1c] = (bx_options.diskc.Ocylinders->get () & 0xff00) >> 8; // AMI BIOS: 1st hard disk #heads cmos->s.reg[0x1d] = (bx_options.diskc.Oheads->get ()); // AMI BIOS: 1st hard disk write precompensation cylinder, low byte cmos->s.reg[0x1e] = 0xff; // -1 // AMI BIOS: 1st hard disk write precompensation cylinder, high byte cmos->s.reg[0x1f] = 0xff; // -1 // AMI BIOS: 1st hard disk control byte cmos->s.reg[0x20] = 0xc0 | ((bx_options.diskc.Oheads->get () > 8) << 3); // AMI BIOS: 1st hard disk landing zone, low byte cmos->s.reg[0x21] = cmos->s.reg[0x1b]; // AMI BIOS: 1st hard disk landing zone, high byte cmos->s.reg[0x22] = cmos->s.reg[0x1c]; // AMI BIOS: 1st hard disk sectors/track cmos->s.reg[0x23] = bx_options.diskc.Ospt->get (); } //set up cmos for second hard drive if (bx_options.diskd.Opresent->get () && !bx_options.cdromd.Opresent->get ()) { BX_DEBUG(("1: I will put 0xf into the second hard disk field")); // fill in lower 4 bits of 0x12 for second HD cmos->s.reg[0x12] = (cmos->s.reg[0x12] & 0xf0) | 0x0f; cmos->s.reg[0x1a] = 47; // user definable type // AMI BIOS: 2nd hard disk #cyl low byte cmos->s.reg[0x24] = (bx_options.diskd.Ocylinders->get () & 0x00ff); // AMI BIOS: 2nd hard disk #cyl high byte cmos->s.reg[0x25] = (bx_options.diskd.Ocylinders->get () & 0xff00) >> 8; // AMI BIOS: 2nd hard disk #heads cmos->s.reg[0x26] = (bx_options.diskd.Oheads->get ()); // AMI BIOS: 2nd hard disk write precompensation cylinder, low byte cmos->s.reg[0x27] = 0xff; // -1 // AMI BIOS: 2nd hard disk write precompensation cylinder, high byte cmos->s.reg[0x28] = 0xff; // -1 // AMI BIOS: 2nd hard disk, 0x80 if heads>8 cmos->s.reg[0x29] = (bx_options.diskd.Oheads->get () > 8) ? 0x80 : 0x00; // AMI BIOS: 2nd hard disk landing zone, low byte cmos->s.reg[0x2a] = cmos->s.reg[0x1b]; // AMI BIOS: 2nd hard disk landing zone, high byte cmos->s.reg[0x2b] = cmos->s.reg[0x1c]; // AMI BIOS: 2nd hard disk sectors/track cmos->s.reg[0x2c] = bx_options.diskd.Ospt->get (); } if ( bx_options.Obootdrive->get () == BX_BOOT_DISKC) { // system boot sequence C:, A: cmos->s.reg[0x2d] &= 0xdf; } else { // 'a' // system boot sequence A:, C: cmos->s.reg[0x2d] |= 0x20; } } //switch (stat_buf.st_size) { // } for (int id = 0; id < 2; id++) { BX_CONTROLLER(id).status.busy = 0; BX_CONTROLLER(id).status.drive_ready = 1; BX_CONTROLLER(id).status.write_fault = 0; BX_CONTROLLER(id).status.seek_complete = 1; BX_CONTROLLER(id).status.drq = 0; BX_CONTROLLER(id).status.corrected_data = 0; BX_CONTROLLER(id).status.index_pulse = 0; BX_CONTROLLER(id).status.index_pulse_count = 0; BX_CONTROLLER(id).status.err = 0; BX_CONTROLLER(id).error_register = 0x01; // diagnostic code: no error BX_CONTROLLER(id).head_no = 0; BX_CONTROLLER(id).sector_count = 1; BX_CONTROLLER(id).sector_no = 1; BX_CONTROLLER(id).cylinder_no = 0; BX_CONTROLLER(id).current_command = 0x00; BX_CONTROLLER(id).buffer_index = 0; BX_CONTROLLER(id).control.reset = 0; BX_CONTROLLER(id).control.disable_irq = 0; BX_CONTROLLER(id).reset_in_progress = 0; BX_CONTROLLER(id).sectors_per_block = 0x80; BX_CONTROLLER(id).lba_mode = 0; BX_CONTROLLER(id).features = 0; } } // static IO port read callback handler // redirects to non-static class handler to avoid virtual functions Bit32u bx_hard_drive_c::read_handler(void *this_ptr, Bit32u address, unsigned io_len) { #if !BX_USE_HD_SMF bx_hard_drive_c *class_ptr = (bx_hard_drive_c *) this_ptr; return( class_ptr->read(address, io_len) ); } Bit32u bx_hard_drive_c::read(Bit32u address, unsigned io_len) { #else UNUSED(this_ptr); #endif // !BX_USE_HD_SMF Bit8u value8; Bit16u value16; Bit32u value32; if (io_len==2 && address!=0x1f0) { BX_PANIC(("non-byte IO read to %04x", (unsigned) address)); } switch (address) { case 0x1f0: // hard disk data (16bit) if (BX_SELECTED_CONTROLLER.status.drq == 0) { BX_PANIC(("IO read(1f0h) with drq == 0: last command was %02xh", (unsigned) BX_SELECTED_CONTROLLER.current_command)); } BX_DEBUG(("IO read(1f0h): current command is %02xh", (unsigned) BX_SELECTED_CONTROLLER.current_command)); switch (BX_SELECTED_CONTROLLER.current_command) { case 0x20: // READ SECTORS, with retries case 0x21: // READ SECTORS, without retries if (io_len != 2) { BX_PANIC(("non-word IO read from %04x", (unsigned) address)); } if (BX_SELECTED_CONTROLLER.buffer_index >= 512) BX_PANIC(("IO read(1f0): buffer_index >= 512")); value16 = BX_SELECTED_CONTROLLER.buffer[BX_SELECTED_CONTROLLER.buffer_index]; value16 |= (BX_SELECTED_CONTROLLER.buffer[BX_SELECTED_CONTROLLER.buffer_index+1] << 8); BX_SELECTED_CONTROLLER.buffer_index += 2; // if buffer completely read if (BX_SELECTED_CONTROLLER.buffer_index >= 512) { // update sector count, sector number, cylinder, // drive, head, status // if there are more sectors, read next one in... // BX_SELECTED_CONTROLLER.buffer_index = 0; increment_address(); BX_SELECTED_CONTROLLER.status.busy = 0; BX_SELECTED_CONTROLLER.status.drive_ready = 1; BX_SELECTED_CONTROLLER.status.write_fault = 0; if (bx_options.OnewHardDriveSupport->get ()) BX_SELECTED_CONTROLLER.status.seek_complete = 1; else BX_SELECTED_CONTROLLER.status.seek_complete = 0; BX_SELECTED_CONTROLLER.status.corrected_data = 0; BX_SELECTED_CONTROLLER.status.err = 0; if (BX_SELECTED_CONTROLLER.sector_count==0) { BX_SELECTED_CONTROLLER.status.drq = 0; } else { /* read next one into controller buffer */ unsigned long logical_sector; int ret; BX_SELECTED_CONTROLLER.status.drq = 1; BX_SELECTED_CONTROLLER.status.seek_complete = 1; logical_sector = calculate_logical_address(); ret = BX_SELECTED_HD.hard_drive->lseek(logical_sector * 512, SEEK_SET); if (ret < 0) BX_PANIC(("could lseek() hard drive image file")); ret = BX_SELECTED_HD.hard_drive->read((bx_ptr_t) BX_SELECTED_CONTROLLER.buffer, 512); if (ret < 512) { BX_INFO(("logical sector was %u", (unsigned) logical_sector)); BX_PANIC(("could not read() hard drive image file at byte %d", logical_sector*512)); } BX_SELECTED_CONTROLLER.buffer_index = 0; raise_interrupt(); } } goto return_value16; break; case 0xec: // IDENTIFY DEVICE case 0xa1: if (bx_options.OnewHardDriveSupport->get ()) { unsigned index; BX_SELECTED_CONTROLLER.status.busy = 0; BX_SELECTED_CONTROLLER.status.drive_ready = 1; BX_SELECTED_CONTROLLER.status.write_fault = 0; BX_SELECTED_CONTROLLER.status.seek_complete = 1; BX_SELECTED_CONTROLLER.status.corrected_data = 0; BX_SELECTED_CONTROLLER.status.err = 0; index = BX_SELECTED_CONTROLLER.buffer_index; value32 = BX_SELECTED_CONTROLLER.buffer[index]; index++; if (io_len >= 2) { value32 |= (BX_SELECTED_CONTROLLER.buffer[index] << 8); index++; } if (io_len == 4) { value32 |= (BX_SELECTED_CONTROLLER.buffer[index] << 16); value32 |= (BX_SELECTED_CONTROLLER.buffer[index+1] << 24); index += 2; } BX_SELECTED_CONTROLLER.buffer_index = index; if (BX_SELECTED_CONTROLLER.buffer_index >= 512) { BX_SELECTED_CONTROLLER.status.drq = 0; if (bx_dbg.disk || (CDROM_SELECTED && bx_dbg.cdrom)) BX_INFO(("Read all drive ID Bytes ...")); } if (io_len == 1) { value8 = (Bit8u)value32; goto return_value8; } else if (io_len == 2) { value16 = (Bit16u)value32; goto return_value16; } else { goto return_value32; } } else BX_PANIC(("IO read(1f0h): current command is %02xh", (unsigned) BX_SELECTED_CONTROLLER.current_command)); case 0xa0: { unsigned index = BX_SELECTED_CONTROLLER.buffer_index; // Load block if necessary if (index >= 2048) { if (index > 2048) BX_PANIC(("index > 2048")); switch (BX_SELECTED_HD.atapi.command) { case 0x28: // read (10) case 0xa8: // read (12) #ifdef LOWLEVEL_CDROM BX_SELECTED_HD.cdrom.cd->read_block(BX_SELECTED_CONTROLLER.buffer, BX_SELECTED_HD.cdrom.next_lba); BX_SELECTED_HD.cdrom.next_lba++; BX_SELECTED_HD.cdrom.remaining_blocks--; if (bx_dbg.disk || (CDROM_SELECTED && bx_dbg.cdrom)) if (!BX_SELECTED_HD.cdrom.remaining_blocks) BX_INFO(("Last READ block loaded {CDROM}")); else BX_INFO(("READ block loaded (%d remaining) {CDROM}", BX_SELECTED_HD.cdrom.remaining_blocks)); // one block transfered BX_SELECTED_HD.atapi.drq_bytes -= 2048; BX_SELECTED_HD.atapi.total_bytes_remaining -= 2048; index = 0; #else BX_PANIC(("Read with no LOWLEVEL_CDROM")); #endif break; default: // no need to load a new block break; } } value32 = BX_SELECTED_CONTROLLER.buffer[index]; index++; if (io_len >= 2) { value32 |= (BX_SELECTED_CONTROLLER.buffer[index] << 8); index++; } if (io_len == 4) { value32 |= (BX_SELECTED_CONTROLLER.buffer[index] << 16); value32 |= (BX_SELECTED_CONTROLLER.buffer[index+1] << 24); index += 2; } BX_SELECTED_CONTROLLER.buffer_index = index; if (BX_SELECTED_CONTROLLER.buffer_index >= (unsigned)BX_SELECTED_HD.atapi.drq_bytes) { BX_SELECTED_CONTROLLER.status.drq = 0; BX_SELECTED_HD.atapi.total_bytes_remaining -= BX_SELECTED_HD.atapi.drq_bytes; if (BX_SELECTED_HD.atapi.total_bytes_remaining > 0) { // one or more blocks remaining (works only for single block commands) if (bx_dbg.disk || (CDROM_SELECTED && bx_dbg.cdrom)) BX_INFO(("PACKET drq bytes read")); BX_SELECTED_CONTROLLER.interrupt_reason.i_o = 1; BX_SELECTED_CONTROLLER.status.busy = 0; BX_SELECTED_CONTROLLER.status.drq = 1; BX_SELECTED_CONTROLLER.interrupt_reason.c_d = 0; // set new byte count if last block if (BX_SELECTED_HD.atapi.total_bytes_remaining < BX_SELECTED_CONTROLLER.byte_count) { BX_SELECTED_CONTROLLER.byte_count = BX_SELECTED_HD.atapi.total_bytes_remaining; } BX_SELECTED_HD.atapi.drq_bytes += BX_SELECTED_CONTROLLER.byte_count; raise_interrupt(); } else { // all bytes read if (bx_dbg.disk || (CDROM_SELECTED && bx_dbg.cdrom)) BX_INFO(("PACKET all bytes read")); BX_SELECTED_CONTROLLER.interrupt_reason.i_o = 1; BX_SELECTED_CONTROLLER.interrupt_reason.c_d = 1; BX_SELECTED_CONTROLLER.status.drive_ready = 1; BX_SELECTED_CONTROLLER.interrupt_reason.rel = 0; BX_SELECTED_CONTROLLER.status.busy = 0; BX_SELECTED_CONTROLLER.status.drq = 0; BX_SELECTED_CONTROLLER.status.err = 0; raise_interrupt(); } } if (io_len == 1) { value8 = (Bit8u)value32; goto return_value8; } else if (io_len == 2) { value16 = (Bit16u)value32; goto return_value16; } else { goto return_value32; } break; } default: BX_PANIC(("IO read(1f0h): current command is %02xh", (unsigned) BX_SELECTED_CONTROLLER.current_command)); } break; case 0x1f1: // hard disk error register BX_SELECTED_CONTROLLER.status.err = 0; value8 = BX_SELECTED_CONTROLLER.error_register; goto return_value8; break; case 0x1f2: // hard disk sector count / interrupt reason value8 = BX_SELECTED_CONTROLLER.sector_count; goto return_value8; break; case 0x1f3: // sector number value8 = BX_SELECTED_CONTROLLER.sector_no; goto return_value8; case 0x1f4: // cylinder low value8 = (BX_SELECTED_CONTROLLER.cylinder_no & 0x00ff); goto return_value8; case 0x1f5: // cylinder high value8 = BX_SELECTED_CONTROLLER.cylinder_no >> 8; goto return_value8; case 0x1f6: // hard disk drive and head register // b7 Extended data field for ECC // b6/b5: Used to be sector size. 00=256,01=512,10=1024,11=128 // Since 512 was always used, bit 6 was taken to mean LBA mode: // b6 1=LBA mode, 0=CHS mode // b5 1 // b4: DRV // b3..0 HD3..HD0 value8 = (1 << 7) | ((BX_SELECTED_CONTROLLER.lba_mode>0) << 6) | (1 << 5) | // 01b = 512 sector size (BX_HD_THIS drive_select << 4) | (BX_SELECTED_CONTROLLER.head_no << 0); goto return_value8; break; //BX_CONTROLLER(0).lba_mode case 0x1f7: // Hard Disk Status case 0x3f6: // Hard Disk Alternate Status if (BX_HD_THIS drive_select && !bx_options.diskd.Opresent->get ()) { // (mch) Just return zero for these registers value8 = 0; } else { value8 = ( (BX_SELECTED_CONTROLLER.status.busy << 7) | (BX_SELECTED_CONTROLLER.status.drive_ready << 6) | (BX_SELECTED_CONTROLLER.status.write_fault << 5) | (BX_SELECTED_CONTROLLER.status.seek_complete << 4) | (BX_SELECTED_CONTROLLER.status.drq << 3) | (BX_SELECTED_CONTROLLER.status.corrected_data << 2) | (BX_SELECTED_CONTROLLER.status.index_pulse << 1) | (BX_SELECTED_CONTROLLER.status.err) ); BX_SELECTED_CONTROLLER.status.index_pulse_count++; BX_SELECTED_CONTROLLER.status.index_pulse = 0; if (BX_SELECTED_CONTROLLER.status.index_pulse_count >= INDEX_PULSE_CYCLE) { BX_SELECTED_CONTROLLER.status.index_pulse = 1; BX_SELECTED_CONTROLLER.status.index_pulse_count = 0; } } goto return_value8; break; case 0x3f7: // Hard Disk Address Register // Obsolete and unsupported register. Not driven by hard // disk controller. Report all 1's. If floppy controller // is handling this address, it will call this function // set/clear D7 (the only bit it handles), then return // the combined value value8 = 0xff; goto return_value8; break; #if 0 // you'll need these to support second IDE controller, not needed yet. case 0x170: case 0x171: case 0x172: case 0x173: case 0x174: case 0x175: case 0x176: case 0x177: BX_INFO(("[disk] ignoring read from 0x%04x", address)); break; #endif default: BX_PANIC(("hard drive: io read to address %x unsupported", (unsigned) address)); } BX_PANIC(("hard drive: shouldnt get here!")); return(0); return_value32: BX_DEBUG(("32-bit read from %04x = %08x {%s}", (unsigned) address, value32, DEVICE_TYPE_STRING)); return value32; return_value16: BX_DEBUG(("16-bit read from %04x = %04x {%s}", (unsigned) address, value16, DEVICE_TYPE_STRING)); return value16; return_value8: BX_DEBUG(("8-bit read from %04x = %02x {%s}", (unsigned) address, value8, DEVICE_TYPE_STRING)); return value8; } // static IO port write callback handler // redirects to non-static class handler to avoid virtual functions void bx_hard_drive_c::write_handler(void *this_ptr, Bit32u address, Bit32u value, unsigned io_len) { #if !BX_USE_HD_SMF bx_hard_drive_c *class_ptr = (bx_hard_drive_c *) this_ptr; class_ptr->write(address, value, io_len); } void bx_hard_drive_c::write(Bit32u address, Bit32u value, unsigned io_len) { #else UNUSED(this_ptr); #endif // !BX_USE_HD_SMF unsigned long logical_sector; int ret; Boolean prev_control_reset; if (io_len==2 && address!=0x1f0) { BX_PANIC(("non-byte IO write to %04x", (unsigned) address)); } if (bx_dbg.disk || (CDROM_SELECTED && bx_dbg.cdrom)) { switch (io_len) { case 1: BX_INFO(("8-bit write to %04x = %02x {%s}", (unsigned) address, (unsigned) value, DEVICE_TYPE_STRING)); break; case 2: BX_INFO(("16-bit write to %04x = %04x {%s}", (unsigned) address, (unsigned) value, DEVICE_TYPE_STRING)); break; case 4: BX_INFO(("32-bit write to %04x = %08x {%s}", (unsigned) address, (unsigned) value, DEVICE_TYPE_STRING)); break; default: BX_INFO(("unknown-size write to %04x = %08x {%s}", (unsigned) address, (unsigned) value, DEVICE_TYPE_STRING)); break; } } BX_DEBUG(("IO write to %04x = %02x", (unsigned) address, (unsigned) value)); switch (address) { case 0x1f0: if (io_len != 2) { BX_PANIC(("non-word IO read from %04x", (unsigned) address)); } switch (BX_SELECTED_CONTROLLER.current_command) { case 0x30: // WRITE SECTORS if (BX_SELECTED_CONTROLLER.buffer_index >= 512) BX_PANIC(("IO write(1f0): buffer_index >= 512")); BX_SELECTED_CONTROLLER.buffer[BX_SELECTED_CONTROLLER.buffer_index] = value; BX_SELECTED_CONTROLLER.buffer[BX_SELECTED_CONTROLLER.buffer_index+1] = (value >> 8); BX_SELECTED_CONTROLLER.buffer_index += 2; /* if buffer completely writtten */ if (BX_SELECTED_CONTROLLER.buffer_index >= 512) { unsigned long logical_sector; int ret; logical_sector = calculate_logical_address(); ret = BX_SELECTED_HD.hard_drive->lseek(logical_sector * 512, SEEK_SET); if (ret < 0) BX_PANIC(("could lseek() hard drive image file")); ret = BX_SELECTED_HD.hard_drive->write((bx_ptr_t) BX_SELECTED_CONTROLLER.buffer, 512); if (ret < 512) BX_PANIC(("could not write() hard drive image file at byte %d", logical_sector*512)); BX_SELECTED_CONTROLLER.buffer_index = 0; /* update sector count, sector number, cylinder, * drive, head, status * if there are more sectors, read next one in... */ increment_address(); /* When the write is complete, controller clears the DRQ bit and * sets the BSY bit. * If at least one more sector is to be written, controller sets DRQ bit, * clears BSY bit, and issues IRQ 14 */ if (BX_SELECTED_CONTROLLER.sector_count!=0) { BX_SELECTED_CONTROLLER.status.busy = 0; BX_SELECTED_CONTROLLER.status.drive_ready = 1; BX_SELECTED_CONTROLLER.status.drq = 1; BX_SELECTED_CONTROLLER.status.corrected_data = 0; BX_SELECTED_CONTROLLER.status.err = 0; } else { /* no more sectors to write */ BX_SELECTED_CONTROLLER.status.busy = 0; BX_SELECTED_CONTROLLER.status.drive_ready = 1; BX_SELECTED_CONTROLLER.status.drq = 0; BX_SELECTED_CONTROLLER.status.err = 0; BX_SELECTED_CONTROLLER.status.corrected_data = 0; } raise_interrupt(); } break; case 0xa0: // PACKET if (BX_SELECTED_CONTROLLER.buffer_index >= PACKET_SIZE) BX_PANIC(("IO write(1f0): buffer_index >= PACKET_SIZE")); BX_SELECTED_CONTROLLER.buffer[BX_SELECTED_CONTROLLER.buffer_index] = value; BX_SELECTED_CONTROLLER.buffer[BX_SELECTED_CONTROLLER.buffer_index+1] = (value >> 8); BX_SELECTED_CONTROLLER.buffer_index += 2; /* if packet completely writtten */ if (BX_SELECTED_CONTROLLER.buffer_index >= PACKET_SIZE) { // complete command received Bit8u atapi_command = BX_SELECTED_CONTROLLER.buffer[0]; int alloc_length; if (bx_dbg.cdrom) BX_INFO(("cdrom: ATAPI command 0x%x started", atapi_command)); switch (atapi_command) { case 0x00: // test unit ready if (BX_SELECTED_HD.cdrom.ready) { atapi_cmd_nop(); } else { atapi_cmd_error(SENSE_NOT_READY, ASC_MEDIUM_NOT_PRESENT); } raise_interrupt(); break; case 0x03: { // request sense int alloc_length = BX_SELECTED_CONTROLLER.buffer[4]; init_send_atapi_command(atapi_command, 18, alloc_length); // sense data BX_SELECTED_CONTROLLER.buffer[0] = 0x70 | (1 << 7); BX_SELECTED_CONTROLLER.buffer[1] = 0; BX_SELECTED_CONTROLLER.buffer[2] = BX_SELECTED_HD.sense.sense_key; BX_SELECTED_CONTROLLER.buffer[3] = BX_SELECTED_HD.sense.information.arr[0]; BX_SELECTED_CONTROLLER.buffer[4] = BX_SELECTED_HD.sense.information.arr[1]; BX_SELECTED_CONTROLLER.buffer[5] = BX_SELECTED_HD.sense.information.arr[2]; BX_SELECTED_CONTROLLER.buffer[6] = BX_SELECTED_HD.sense.information.arr[3]; BX_SELECTED_CONTROLLER.buffer[7] = 17-7; BX_SELECTED_CONTROLLER.buffer[8] = BX_SELECTED_HD.sense.specific_inf.arr[0]; BX_SELECTED_CONTROLLER.buffer[9] = BX_SELECTED_HD.sense.specific_inf.arr[1]; BX_SELECTED_CONTROLLER.buffer[10] = BX_SELECTED_HD.sense.specific_inf.arr[2]; BX_SELECTED_CONTROLLER.buffer[11] = BX_SELECTED_HD.sense.specific_inf.arr[3]; BX_SELECTED_CONTROLLER.buffer[12] = BX_SELECTED_HD.sense.asc; BX_SELECTED_CONTROLLER.buffer[13] = BX_SELECTED_HD.sense.ascq; BX_SELECTED_CONTROLLER.buffer[14] = BX_SELECTED_HD.sense.fruc; BX_SELECTED_CONTROLLER.buffer[15] = BX_SELECTED_HD.sense.key_spec.arr[0]; BX_SELECTED_CONTROLLER.buffer[16] = BX_SELECTED_HD.sense.key_spec.arr[1]; BX_SELECTED_CONTROLLER.buffer[17] = BX_SELECTED_HD.sense.key_spec.arr[2]; ready_to_send_atapi(); } break; case 0x1b: { // start stop unit //Boolean Immed = (BX_SELECTED_CONTROLLER.buffer[1] >> 0) & 1; Boolean LoEj = (BX_SELECTED_CONTROLLER.buffer[4] >> 1) & 1; Boolean Start = (BX_SELECTED_CONTROLLER.buffer[4] >> 0) & 1; if (!LoEj && !Start) { // stop the disc BX_PANIC(("Stop disc not implemented")); } else if (!LoEj && Start) { // start the disc and read the TOC BX_PANIC(("Start disc not implemented")); } else if (LoEj && !Start) { // Eject the disc BX_PANIC(("Eject the disc not implemented")); } else { // Load the disc // My guess is that this command only closes the tray, that's a no-op for us atapi_cmd_nop(); raise_interrupt(); } } break; case 0xbd: { // mechanism status uint16 alloc_length = read_16bit(BX_SELECTED_CONTROLLER.buffer + 8); if (alloc_length == 0) BX_PANIC(("Zero allocation length to MECHANISM STATUS not impl.")); init_send_atapi_command(atapi_command, 8, alloc_length); BX_SELECTED_CONTROLLER.buffer[0] = 0; // reserved for non changers BX_SELECTED_CONTROLLER.buffer[1] = 0; // reserved for non changers BX_SELECTED_CONTROLLER.buffer[2] = 0; // Current LBA (TODO!) BX_SELECTED_CONTROLLER.buffer[3] = 0; // Current LBA (TODO!) BX_SELECTED_CONTROLLER.buffer[4] = 0; // Current LBA (TODO!) BX_SELECTED_CONTROLLER.buffer[5] = 1; // one slot BX_SELECTED_CONTROLLER.buffer[6] = 0; // slot table length BX_SELECTED_CONTROLLER.buffer[7] = 0; // slot table length ready_to_send_atapi(); } break; case 0x5a: { // mode sense uint16 alloc_length = read_16bit(BX_SELECTED_CONTROLLER.buffer + 7); Bit8u PC = BX_SELECTED_CONTROLLER.buffer[2] >> 6; Bit8u PageCode = BX_SELECTED_CONTROLLER.buffer[2] & 0x3f; switch (PC) { case 0x0: // current values switch (PageCode) { case 0x01: // error recovery init_send_atapi_command(atapi_command, sizeof(error_recovery_t) + 8, alloc_length); init_mode_sense_single(&BX_SELECTED_HD.cdrom.current.error_recovery, sizeof(error_recovery_t)); ready_to_send_atapi(); break; case 0x2a: // CD-ROM capabilities & mech. status init_send_atapi_command(atapi_command, 28, alloc_length); init_mode_sense_single(&BX_SELECTED_CONTROLLER.buffer[8], 28); BX_SELECTED_CONTROLLER.buffer[8] = 0x2a; BX_SELECTED_CONTROLLER.buffer[9] = 0x12; BX_SELECTED_CONTROLLER.buffer[10] = 0x00; BX_SELECTED_CONTROLLER.buffer[11] = 0x00; BX_SELECTED_CONTROLLER.buffer[12] = 0x00; BX_SELECTED_CONTROLLER.buffer[13] = (3 << 5); BX_SELECTED_CONTROLLER.buffer[14] = (unsigned char) (1 | (BX_SELECTED_HD.cdrom.locked ? (1 << 1) : 0) | (1 << 3) | (1 << 5)); BX_SELECTED_CONTROLLER.buffer[15] = 0x00; BX_SELECTED_CONTROLLER.buffer[16] = (706 >> 8) & 0xff; BX_SELECTED_CONTROLLER.buffer[17] = 706 & 0xff; BX_SELECTED_CONTROLLER.buffer[18] = 0; BX_SELECTED_CONTROLLER.buffer[19] = 2; BX_SELECTED_CONTROLLER.buffer[20] = (512 >> 8) & 0xff; BX_SELECTED_CONTROLLER.buffer[21] = 512 & 0xff; BX_SELECTED_CONTROLLER.buffer[22] = (706 >> 8) & 0xff; BX_SELECTED_CONTROLLER.buffer[23] = 706 & 0xff; BX_SELECTED_CONTROLLER.buffer[24] = 0; BX_SELECTED_CONTROLLER.buffer[25] = 0; BX_SELECTED_CONTROLLER.buffer[26] = 0; BX_SELECTED_CONTROLLER.buffer[27] = 0; ready_to_send_atapi(); break; case 0x0d: // CD-ROM case 0x0e: // CD-ROM audio control case 0x3f: // all BX_PANIC(("cdrom: MODE SENSE (curr), code=%x", PageCode)); break; default: // not implemeted by this device BX_INFO(("cdrom: MODE SENSE PC=%x, PageCode=%x," " not implemented by device", PC, PageCode)); atapi_cmd_error(SENSE_ILLEGAL_REQUEST, ASC_INV_FIELD_IN_CMD_PACKET); raise_interrupt(); break; } break; case 0x1: // changeable values switch (PageCode) { case 0x01: // error recovery case 0x0d: // CD-ROM case 0x0e: // CD-ROM audio control case 0x2a: // CD-ROM capabilities & mech. status case 0x3f: // all BX_PANIC(("cdrom: MODE SENSE (chg), code=%x", PageCode)); break; default: // not implemeted by this device BX_INFO(("cdrom: MODE SENSE PC=%x, PageCode=%x," " not implemented by device", PC, PageCode)); atapi_cmd_error(SENSE_ILLEGAL_REQUEST, ASC_INV_FIELD_IN_CMD_PACKET); raise_interrupt(); break; } break; case 0x2: // default values switch (PageCode) { case 0x01: // error recovery case 0x0d: // CD-ROM case 0x0e: // CD-ROM audio control case 0x2a: // CD-ROM capabilities & mech. status case 0x3f: // all BX_PANIC(("cdrom: MODE SENSE (dflt), code=%x", PageCode)); break; default: // not implemeted by this device BX_INFO(("cdrom: MODE SENSE PC=%x, PageCode=%x," " not implemented by device", PC, PageCode)); atapi_cmd_error(SENSE_ILLEGAL_REQUEST, ASC_INV_FIELD_IN_CMD_PACKET); raise_interrupt(); break; } break; case 0x3: // saved values not implemented atapi_cmd_error(SENSE_ILLEGAL_REQUEST, ASC_SAVING_PARAMETERS_NOT_SUPPORTED); raise_interrupt(); break; default: BX_PANIC(("Should not get here!")); break; } } break; case 0x12: { // inquiry uint8 alloc_length = BX_SELECTED_CONTROLLER.buffer[4]; init_send_atapi_command(atapi_command, 36, alloc_length); BX_SELECTED_CONTROLLER.buffer[0] = 0x05; // CD-ROM BX_SELECTED_CONTROLLER.buffer[1] = 0x80; // Removable BX_SELECTED_CONTROLLER.buffer[2] = 0x00; // ISO, ECMA, ANSI version BX_SELECTED_CONTROLLER.buffer[3] = 0x21; // ATAPI-2, as specified BX_SELECTED_CONTROLLER.buffer[4] = 31; // additional length (total 36) BX_SELECTED_CONTROLLER.buffer[5] = 0x00; // reserved BX_SELECTED_CONTROLLER.buffer[6] = 0x00; // reserved BX_SELECTED_CONTROLLER.buffer[7] = 0x00; // reserved // Vendor ID const char* vendor_id = "VTAB\0\0\0\0"; int i; for (i = 0; i < 8; i++) BX_SELECTED_CONTROLLER.buffer[8+i] = vendor_id[i]; // Product ID const char* product_id = "Turbo CD-ROM\0\0\0\0"; for (i = 0; i < 16; i++) BX_SELECTED_CONTROLLER.buffer[16+i] = product_id[i]; // Product Revision level const char* rev_level = "R0\0\0"; for (i = 0; i < 4; i++) BX_SELECTED_CONTROLLER.buffer[32+i] = rev_level[i]; ready_to_send_atapi(); } break; case 0x25: { // read cd-rom capacity // no allocation length??? init_send_atapi_command(atapi_command, 8, 8); if (BX_SELECTED_HD.cdrom.ready) { uint32 capacity = BX_SELECTED_HD.cdrom.capacity; BX_INFO(("Capacity is %d sectors (%d bytes)", capacity, capacity * 2048)); BX_SELECTED_CONTROLLER.buffer[0] = (capacity >> 24) & 0xff; BX_SELECTED_CONTROLLER.buffer[1] = (capacity >> 16) & 0xff; BX_SELECTED_CONTROLLER.buffer[2] = (capacity >> 8) & 0xff; BX_SELECTED_CONTROLLER.buffer[3] = (capacity >> 0) & 0xff; BX_SELECTED_CONTROLLER.buffer[4] = (2048 >> 24) & 0xff; BX_SELECTED_CONTROLLER.buffer[5] = (2048 >> 16) & 0xff; BX_SELECTED_CONTROLLER.buffer[6] = (2048 >> 8) & 0xff; BX_SELECTED_CONTROLLER.buffer[7] = (2048 >> 0) & 0xff; ready_to_send_atapi(); } else { atapi_cmd_error(SENSE_NOT_READY, ASC_MEDIUM_NOT_PRESENT); raise_interrupt(); } } break; case 0xbe: { // read cd if (BX_SELECTED_HD.cdrom.ready) { BX_PANIC(("Read CD with CD present not implemented")); } else { atapi_cmd_error(SENSE_NOT_READY, ASC_MEDIUM_NOT_PRESENT); raise_interrupt(); } } break; case 0x43: { // read toc if (BX_SELECTED_HD.cdrom.ready) { #ifdef LOWLEVEL_CDROM bool msf = (BX_SELECTED_CONTROLLER.buffer[1] >> 1) & 1; uint8 starting_track = BX_SELECTED_CONTROLLER.buffer[6]; #endif uint16 alloc_length = read_16bit(BX_SELECTED_CONTROLLER.buffer + 7); uint8 format = (BX_SELECTED_CONTROLLER.buffer[9] >> 6); int i; switch (format) { case 0: #ifdef LOWLEVEL_CDROM int toc_length; if (!BX_SELECTED_HD.cdrom.cd->read_toc(BX_SELECTED_CONTROLLER.buffer, &toc_length, msf, starting_track)) { atapi_cmd_error(SENSE_ILLEGAL_REQUEST, ASC_INV_FIELD_IN_CMD_PACKET); raise_interrupt(); } else { init_send_atapi_command(atapi_command, toc_length, alloc_length); ready_to_send_atapi(); } #else BX_PANIC(("LOWLEVEL_CDROM not defined")); #endif break; case 1: // multi session stuff. we ignore this and emulate a single session only init_send_atapi_command(atapi_command, 12, alloc_length); BX_SELECTED_CONTROLLER.buffer[0] = 0; BX_SELECTED_CONTROLLER.buffer[1] = 0x0a; BX_SELECTED_CONTROLLER.buffer[2] = 1; BX_SELECTED_CONTROLLER.buffer[3] = 1; for (i = 0; i < 8; i++) BX_SELECTED_CONTROLLER.buffer[4+i] = 0; ready_to_send_atapi(); break; case 2: default: BX_PANIC(("(READ TOC) Format %d not supported", format)); break; } } else { atapi_cmd_error(SENSE_NOT_READY, ASC_MEDIUM_NOT_PRESENT); raise_interrupt(); } } break; case 0x28: { // read (10) uint32 transfer_length = read_16bit(BX_SELECTED_CONTROLLER.buffer + 7); uint32 lba = read_32bit(BX_SELECTED_CONTROLLER.buffer + 2); if (!BX_SELECTED_HD.cdrom.ready) { atapi_cmd_error(SENSE_NOT_READY, ASC_MEDIUM_NOT_PRESENT); raise_interrupt(); break; } if (transfer_length == 0) { atapi_cmd_nop(); raise_interrupt(); BX_INFO(("READ(10) with transfer length 0, ok")); break; } if (lba + transfer_length > BX_SELECTED_HD.cdrom.capacity) { atapi_cmd_error(SENSE_ILLEGAL_REQUEST, ASC_LOGICAL_BLOCK_OOR); raise_interrupt(); break; } //BX_INFO(("cdrom: READ LBA=%d LEN=%d", lba, transfer_length)); // handle command init_send_atapi_command(atapi_command, transfer_length * 2048, transfer_length * 2048, true); BX_SELECTED_HD.cdrom.remaining_blocks = transfer_length; BX_SELECTED_HD.cdrom.next_lba = lba; ready_to_send_atapi(); } break; case 0x2b: { // seek uint32 lba = read_32bit(BX_SELECTED_CONTROLLER.buffer + 2); if (!BX_SELECTED_HD.cdrom.ready) { atapi_cmd_error(SENSE_NOT_READY, ASC_MEDIUM_NOT_PRESENT); raise_interrupt(); break; } if (lba > BX_SELECTED_HD.cdrom.capacity) { atapi_cmd_error(SENSE_ILLEGAL_REQUEST, ASC_LOGICAL_BLOCK_OOR); raise_interrupt(); break; } BX_INFO(("cdrom: SEEK (ignored)")); atapi_cmd_nop(); raise_interrupt(); } break; case 0x1e: { // prevent/allow medium removal if (BX_SELECTED_HD.cdrom.ready) { BX_SELECTED_HD.cdrom.locked = BX_SELECTED_CONTROLLER.buffer[4] & 1; atapi_cmd_nop(); } else { atapi_cmd_error(SENSE_NOT_READY, ASC_MEDIUM_NOT_PRESENT); } raise_interrupt(); } break; case 0x42: { // read sub-channel bool msf = get_packet_field(1, 1, 1); bool sub_q = get_packet_field(2, 6, 1); uint8 data_format = get_packet_byte(3); uint8 track_number = get_packet_byte(6); uint16 alloc_length = get_packet_word(7); UNUSED(msf); UNUSED(data_format); UNUSED(track_number); if (BX_SELECTED_HD.cdrom.ready) { atapi_cmd_error(SENSE_NOT_READY, ASC_MEDIUM_NOT_PRESENT); raise_interrupt(); } else { BX_SELECTED_CONTROLLER.buffer[0] = 0; BX_SELECTED_CONTROLLER.buffer[1] = 0; // audio not supported BX_SELECTED_CONTROLLER.buffer[2] = 0; BX_SELECTED_CONTROLLER.buffer[3] = 0; int ret_len = 4; // header size if (sub_q) { // !sub_q == header only BX_PANIC(("Read sub-channel with SubQ not implemented")); } init_send_atapi_command(atapi_command, ret_len, alloc_length); ready_to_send_atapi(); } } break; case 0x51: { // read disc info // no-op to keep the Linux CD-ROM driver happy atapi_cmd_error(SENSE_ILLEGAL_REQUEST, ASC_INV_FIELD_IN_CMD_PACKET); raise_interrupt(); } break; case 0xa8: // read (12) case 0x55: // mode select case 0xa6: // load/unload cd case 0x4b: // pause/resume case 0x45: // play audio case 0x47: // play audio msf case 0xbc: // play cd case 0xb9: // read cd msf case 0x44: // read header case 0xba: // scan case 0xbb: // set cd speed case 0x4e: // stop play/scan default: BX_PANIC(("Unknown ATAPI command 0x%x (%d)", atapi_command, atapi_command)); break; } } break; default: BX_PANIC(("IO write(1f0h): current command is %02xh", (unsigned) BX_SELECTED_CONTROLLER.current_command)); } break; case 0x1f1: /* hard disk write precompensation */ WRITE_FEATURES(value); if (bx_dbg.disk || (CDROM_SELECTED && bx_dbg.cdrom)) { if (value == 0xff) BX_INFO(("no precompensation {%s}", DEVICE_TYPE_STRING)); else BX_INFO(("precompensation value %02x {%s}", (unsigned) value, DEVICE_TYPE_STRING)); } break; case 0x1f2: /* hard disk sector count */ WRITE_SECTOR_COUNT(value); if (bx_dbg.disk || (CDROM_SELECTED && bx_dbg.cdrom)) BX_INFO(("sector count = %u {%s}", (unsigned) value, DEVICE_TYPE_STRING)); break; case 0x1f3: /* hard disk sector number */ WRITE_SECTOR_NUMBER(value); if (bx_dbg.disk || (CDROM_SELECTED && bx_dbg.cdrom)) BX_INFO(("sector number = %u {%s}", (unsigned) value, DEVICE_TYPE_STRING)); break; case 0x1f4: /* hard disk cylinder low */ WRITE_CYLINDER_LOW(value); if (bx_dbg.disk || (CDROM_SELECTED && bx_dbg.cdrom)) BX_INFO(("cylinder low = %02xh {%s}", (unsigned) value, DEVICE_TYPE_STRING)); break; case 0x1f5: /* hard disk cylinder high */ WRITE_CYLINDER_HIGH(value); if (bx_dbg.disk || (CDROM_SELECTED && bx_dbg.cdrom)) BX_INFO(("cylinder high = %02xh {%s}", (unsigned) value, DEVICE_TYPE_STRING)); break; case 0x1f6: // hard disk drive and head register // b7 Extended data field for ECC // b6/b5: Used to be sector size. 00=256,01=512,10=1024,11=128 // Since 512 was always used, bit 6 was taken to mean LBA mode: // b6 1=LBA mode, 0=CHS mode // b5 1 // b4: DRV // b3..0 HD3..HD0 if ( (value & 0xa0) != 0xa0 ) // 1x1xxxxx BX_INFO(("IO write 1f6 (%02x): not 1x1xxxxxb", (unsigned) value)); BX_HD_THIS drive_select = (value >> 4) & 0x01; WRITE_HEAD_NO(value & 0xf); if (BX_SELECTED_CONTROLLER.lba_mode == 0 && ((value >> 6) & 1) == 1) BX_INFO(("enabling LBA mode")); WRITE_LBA_MODE((value >> 6) & 1); break; case 0x1f7: // hard disk command // (mch) Writes to the command register with drive_select != 0 // are ignored if no secondary device is present if (BX_HD_THIS drive_select != 0 && value != 0x90 && !bx_options.diskd.Opresent->get ()) break; if (BX_SELECTED_CONTROLLER.status.busy) BX_PANIC(("hard disk: command sent, controller BUSY")); if ( (value & 0xf0) == 0x10 ) value = 0x10; switch (value) { case 0x10: // CALIBRATE DRIVE if (BX_SELECTED_HD.device_type != IDE_DISK) BX_PANIC(("calibrate drive issued to non-disk")); if (BX_HD_THIS drive_select != 0 && !bx_options.diskd.Opresent->get ()) { BX_SELECTED_CONTROLLER.error_register = 0x02; // Track 0 not found BX_SELECTED_CONTROLLER.status.busy = 0; BX_SELECTED_CONTROLLER.status.drive_ready = 1; BX_SELECTED_CONTROLLER.status.seek_complete = 0; BX_SELECTED_CONTROLLER.status.drq = 0; BX_SELECTED_CONTROLLER.status.err = 1; raise_interrupt(); BX_INFO(("calibrate drive != 0, with diskd not present")); break; } /* move head to cylinder 0, issue IRQ 14 */ BX_SELECTED_CONTROLLER.error_register = 0; BX_SELECTED_CONTROLLER.cylinder_no = 0; BX_SELECTED_CONTROLLER.status.busy = 0; BX_SELECTED_CONTROLLER.status.drive_ready = 1; BX_SELECTED_CONTROLLER.status.seek_complete = 1; BX_SELECTED_CONTROLLER.status.drq = 0; BX_SELECTED_CONTROLLER.status.err = 0; raise_interrupt(); break; case 0x20: // READ MULTIPLE SECTORS, with retries case 0x21: // READ MULTIPLE SECTORS, without retries /* update sector_no, always points to current sector * after each sector is read to buffer, DRQ bit set and issue IRQ 14 * if interrupt handler transfers all data words into main memory, * and more sectors to read, then set BSY bit again, clear DRQ and * read next sector into buffer * sector count of 0 means 256 sectors */ if (BX_SELECTED_HD.device_type != IDE_DISK) BX_PANIC(("read multiple issued to non-disk")); BX_SELECTED_CONTROLLER.current_command = value; // Lose98 accesses 0/0/0 in CHS mode if (!BX_SELECTED_CONTROLLER.lba_mode && !BX_SELECTED_CONTROLLER.head_no && !BX_SELECTED_CONTROLLER.cylinder_no && !BX_SELECTED_CONTROLLER.sector_no) { BX_INFO(("Read from 0/0/0, aborting command")); command_aborted(value); break; } logical_sector = calculate_logical_address(); ret = BX_SELECTED_HD.hard_drive->lseek(logical_sector * 512, SEEK_SET); if (ret < 0) { BX_PANIC(("could not lseek() hard drive image file")); } ret = BX_SELECTED_HD.hard_drive->read((bx_ptr_t) BX_SELECTED_CONTROLLER.buffer, 512); if (ret < 512) { BX_INFO(("logical sector was %u", (unsigned) logical_sector)); BX_PANIC(("could not read() hard drive image file at byte %d", logical_sector*512)); } BX_SELECTED_CONTROLLER.error_register = 0; BX_SELECTED_CONTROLLER.status.busy = 0; BX_SELECTED_CONTROLLER.status.drive_ready = 1; BX_SELECTED_CONTROLLER.status.seek_complete = 1; BX_SELECTED_CONTROLLER.status.drq = 1; BX_SELECTED_CONTROLLER.status.corrected_data = 0; BX_SELECTED_CONTROLLER.status.err = 0; BX_SELECTED_CONTROLLER.buffer_index = 0; raise_interrupt(); break; case 0x30: /* WRITE SECTORS, with retries */ /* update sector_no, always points to current sector * after each sector is read to buffer, DRQ bit set and issue IRQ 14 * if interrupt handler transfers all data words into main memory, * and more sectors to read, then set BSY bit again, clear DRQ and * read next sector into buffer * sector count of 0 means 256 sectors */ if (BX_SELECTED_HD.device_type != IDE_DISK) BX_PANIC(("write multiple issued to non-disk")); if (BX_SELECTED_CONTROLLER.status.busy) { BX_PANIC(("write command: BSY bit set")); } BX_SELECTED_CONTROLLER.current_command = value; // implicit seek done :^) BX_SELECTED_CONTROLLER.error_register = 0; BX_SELECTED_CONTROLLER.status.busy = 0; // BX_SELECTED_CONTROLLER.status.drive_ready = 1; BX_SELECTED_CONTROLLER.status.seek_complete = 1; BX_SELECTED_CONTROLLER.status.drq = 1; BX_SELECTED_CONTROLLER.status.err = 0; BX_SELECTED_CONTROLLER.buffer_index = 0; break; case 0x90: // EXECUTE DEVICE DIAGNOSTIC if (BX_SELECTED_CONTROLLER.status.busy) { BX_PANIC(("diagnostic command: BSY bit set")); } if (BX_SELECTED_HD.device_type != IDE_DISK) BX_PANIC(("drive diagnostics issued to non-disk")); BX_SELECTED_CONTROLLER.error_register = 0x81; // Drive 1 failed, no error on drive 0 // BX_SELECTED_CONTROLLER.status.busy = 0; // not needed BX_SELECTED_CONTROLLER.status.drq = 0; BX_SELECTED_CONTROLLER.status.err = 0; break; case 0x91: // INITIALIZE DRIVE PARAMETERS if (BX_SELECTED_CONTROLLER.status.busy) { BX_PANIC(("init drive parameters command: BSY bit set")); } if (BX_SELECTED_HD.device_type != IDE_DISK) BX_PANIC(("initialize drive parameters issued to non-disk")); // sets logical geometry of specified drive BX_DEBUG(("init drive params: sec=%u, drive sel=%u, head=%u", (unsigned) BX_SELECTED_CONTROLLER.sector_count, (unsigned) BX_HD_THIS drive_select, (unsigned) BX_SELECTED_CONTROLLER.head_no)); if (BX_HD_THIS drive_select != 0 && !bx_options.diskd.Opresent->get ()) { BX_PANIC(("init drive params: drive != 0")); //BX_SELECTED_CONTROLLER.error_register = 0x12; BX_SELECTED_CONTROLLER.status.busy = 0; BX_SELECTED_CONTROLLER.status.drive_ready = 1; BX_SELECTED_CONTROLLER.status.drq = 0; BX_SELECTED_CONTROLLER.status.err = 0; raise_interrupt(); break; } if (BX_SELECTED_CONTROLLER.sector_count != BX_SELECTED_HD.hard_drive->sectors) BX_PANIC(("init drive params: sector count doesnt match")); if ( BX_SELECTED_CONTROLLER.head_no != (BX_SELECTED_HD.hard_drive->heads-1) ) BX_PANIC(("init drive params: head number doesn't match")); BX_SELECTED_CONTROLLER.status.busy = 0; BX_SELECTED_CONTROLLER.status.drive_ready = 1; BX_SELECTED_CONTROLLER.status.drq = 0; BX_SELECTED_CONTROLLER.status.err = 0; raise_interrupt(); break; case 0xec: // IDENTIFY DEVICE if (bx_options.OnewHardDriveSupport->get ()) { if (bx_dbg.disk || (CDROM_SELECTED && bx_dbg.cdrom)) BX_INFO(("Drive ID Command issued : 0xec ")); if (BX_HD_THIS drive_select && !bx_options.diskd.Opresent->get ()) { BX_INFO(("2nd drive not present, aborting")); command_aborted(value); break; } if (BX_SELECTED_HD.device_type == IDE_CDROM) { BX_SELECTED_CONTROLLER.head_no = 0; BX_SELECTED_CONTROLLER.sector_count = 1; BX_SELECTED_CONTROLLER.sector_no = 1; BX_SELECTED_CONTROLLER.cylinder_no = 0xeb14; command_aborted(0xec); } else { BX_SELECTED_CONTROLLER.current_command = value; BX_SELECTED_CONTROLLER.error_register = 0; // See ATA/ATAPI-4, 8.12 BX_SELECTED_CONTROLLER.status.busy = 0; BX_SELECTED_CONTROLLER.status.drive_ready = 1; BX_SELECTED_CONTROLLER.status.write_fault = 0; BX_SELECTED_CONTROLLER.status.drq = 1; BX_SELECTED_CONTROLLER.status.err = 0; BX_SELECTED_CONTROLLER.status.seek_complete = 1; BX_SELECTED_CONTROLLER.status.corrected_data = 0; BX_SELECTED_CONTROLLER.buffer_index = 0; raise_interrupt(); identify_drive(BX_HD_THIS drive_select); } } else { BX_INFO(("old hard drive")); command_aborted(value); } break; case 0xef: // SET FEATURES switch(BX_SELECTED_CONTROLLER.features) { case 0x02: // Enable and case 0x82: // Disable write cache. case 0xAA: // Enable and case 0x55: // Disable look-ahead cache. BX_INFO(("SET FEATURES subcommand not supported by disk.")); command_aborted(value); break; default: BX_PANIC(("SET FEATURES with unknown subcommand: 0x%02x", (unsigned) BX_SELECTED_CONTROLLER.features )); } break; case 0x40: // READ VERIFY SECTORS if (bx_options.OnewHardDriveSupport->get ()) { if (BX_SELECTED_HD.device_type != IDE_DISK) BX_PANIC(("read verify issued to non-disk")); BX_INFO(("Verify Command : 0x40 ! ")); BX_SELECTED_CONTROLLER.status.busy = 0; BX_SELECTED_CONTROLLER.status.drive_ready = 1; BX_SELECTED_CONTROLLER.status.drq = 0; BX_SELECTED_CONTROLLER.status.err = 0; raise_interrupt(); } else { BX_INFO(("old hard drive")); command_aborted(value); } break; case 0xc6: // SET MULTIPLE MODE (mch) if (BX_SELECTED_CONTROLLER.sector_count != 128 && BX_SELECTED_CONTROLLER.sector_count != 64 && BX_SELECTED_CONTROLLER.sector_count != 32 && BX_SELECTED_CONTROLLER.sector_count != 16 && BX_SELECTED_CONTROLLER.sector_count != 8 && BX_SELECTED_CONTROLLER.sector_count != 4 && BX_SELECTED_CONTROLLER.sector_count != 2) command_aborted(value); if (BX_SELECTED_HD.device_type != IDE_DISK) BX_PANIC(("set multiple mode issued to non-disk")); BX_SELECTED_CONTROLLER.sectors_per_block = BX_SELECTED_CONTROLLER.sector_count; BX_SELECTED_CONTROLLER.status.busy = 0; BX_SELECTED_CONTROLLER.status.drive_ready = 1; BX_SELECTED_CONTROLLER.status.write_fault = 0; BX_SELECTED_CONTROLLER.status.drq = 0; BX_SELECTED_CONTROLLER.status.err = 0; break; // ATAPI commands case 0xa1: // IDENTIFY PACKET DEVICE if (BX_SELECTED_HD.device_type == IDE_CDROM) { BX_SELECTED_CONTROLLER.current_command = value; BX_SELECTED_CONTROLLER.error_register = 0; BX_SELECTED_CONTROLLER.status.busy = 0; BX_SELECTED_CONTROLLER.status.drive_ready = 1; BX_SELECTED_CONTROLLER.status.write_fault = 0; BX_SELECTED_CONTROLLER.status.drq = 1; BX_SELECTED_CONTROLLER.status.err = 0; BX_SELECTED_CONTROLLER.status.seek_complete = 1; BX_SELECTED_CONTROLLER.status.corrected_data = 0; BX_SELECTED_CONTROLLER.buffer_index = 0; raise_interrupt(); identify_ATAPI_drive(BX_HD_THIS drive_select); } else { command_aborted(0xa1); } break; case 0x08: // DEVICE RESET (atapi) if (BX_SELECTED_HD.device_type == IDE_CDROM) { BX_SELECTED_CONTROLLER.status.busy = 1; BX_SELECTED_CONTROLLER.error_register &= ~(1 << 7); // device signature BX_SELECTED_CONTROLLER.head_no = 0; BX_SELECTED_CONTROLLER.sector_count = 1; BX_SELECTED_CONTROLLER.sector_no = 1; BX_SELECTED_CONTROLLER.cylinder_no = 0xeb14; BX_SELECTED_CONTROLLER.status.write_fault = 0; BX_SELECTED_CONTROLLER.status.drq = 0; BX_SELECTED_CONTROLLER.status.corrected_data = 0; BX_SELECTED_CONTROLLER.status.err = 0; BX_SELECTED_CONTROLLER.status.busy = 0; } else { command_aborted(0x08); } break; case 0xa0: // SEND PACKET (atapi) if (BX_SELECTED_HD.device_type == IDE_CDROM) { // PACKET if (BX_SELECTED_CONTROLLER.features & (1 << 0)) BX_PANIC(("PACKET-DMA not supported")); if (BX_SELECTED_CONTROLLER.features & (1 << 1)) BX_PANIC(("PACKET-overlapped not supported")); // We're already ready! BX_SELECTED_CONTROLLER.sector_count = 1; BX_SELECTED_CONTROLLER.status.busy = 0; BX_SELECTED_CONTROLLER.status.write_fault = 0; // serv bit?? BX_SELECTED_CONTROLLER.status.drq = 1; BX_SELECTED_CONTROLLER.status.err = 0; // NOTE: no interrupt here BX_SELECTED_CONTROLLER.current_command = value; BX_SELECTED_CONTROLLER.buffer_index = 0; break; } case 0xa2: // SERVICE (atapi), optional if (BX_SELECTED_HD.device_type == IDE_CDROM) { BX_PANIC(("ATAPI SERVICE not implemented")); } // non-standard commands case 0xf0: // Exabyte enable nest command BX_INFO(("Not implemented command 0xf0: exabyte enable nest")); command_aborted(value); break; case 0xe1: // IDLE IMMEDIATE BX_INFO (("IO write(1f7h): idle immediate ignored")); command_aborted(value); break; // power management case 0xe5: // CHECK POWER MODE BX_SELECTED_CONTROLLER.status.busy = 0; BX_SELECTED_CONTROLLER.status.drive_ready = 1; BX_SELECTED_CONTROLLER.status.write_fault = 0; BX_SELECTED_CONTROLLER.status.drq = 0; BX_SELECTED_CONTROLLER.status.err = 0; BX_SELECTED_CONTROLLER.sector_count = 0xff; // Active or Idle mode raise_interrupt(); break; case 0xe7: // FLUSH CACHE // We don't have a cache! This is showing up in win2000 and freebsd. BX_INFO(("IO write(1f7h): flush cache ignored")); command_aborted(value); break; default: BX_PANIC(("IO write(1f7h): command 0x%02x", (unsigned) value)); // if user foolishly decides to continue, abort the command // so that the software knows the drive didn't understand it. command_aborted(value); } break; case 0x3f6: // hard disk adapter control // (mch) Even if device 1 was selected, a write to this register // goes to device 0 (if device 1 is absent) prev_control_reset = BX_SELECTED_CONTROLLER.control.reset; BX_HD_THIS s[0].controller.control.reset = value & 0x04; BX_HD_THIS s[1].controller.control.reset = value & 0x04; BX_SELECTED_CONTROLLER.control.disable_irq = value & 0x02; //BX_DEBUG(( "adpater control reg: reset controller = %d", // (unsigned) (BX_SELECTED_CONTROLLER.control.reset) ? 1 : 0 )); //BX_DEBUG(( "adpater control reg: disable_irq(14) = %d", // (unsigned) (BX_SELECTED_CONTROLLER.control.disable_irq) ? 1 : 0 )); if (!prev_control_reset && BX_SELECTED_CONTROLLER.control.reset) { // transition from 0 to 1 causes all drives to reset BX_DEBUG(("hard drive: RESET")); // (mch) Set BSY, drive not ready for (int id = 0; id < 2; id++) { BX_CONTROLLER(id).status.busy = 1; BX_CONTROLLER(id).status.drive_ready = 0; BX_CONTROLLER(id).reset_in_progress = 1; BX_CONTROLLER(id).status.write_fault = 0; BX_CONTROLLER(id).status.seek_complete = 1; BX_CONTROLLER(id).status.drq = 0; BX_CONTROLLER(id).status.corrected_data = 0; BX_CONTROLLER(id).status.err = 0; BX_CONTROLLER(id).error_register = 0x01; // diagnostic code: no error BX_CONTROLLER(id).current_command = 0x00; BX_CONTROLLER(id).buffer_index = 0; BX_CONTROLLER(id).sectors_per_block = 0x80; BX_CONTROLLER(id).lba_mode = 0; BX_CONTROLLER(id).control.disable_irq = 0; } } else if (BX_SELECTED_CONTROLLER.reset_in_progress && !BX_SELECTED_CONTROLLER.control.reset) { // Clear BSY and DRDY BX_DEBUG(("Reset complete {%s}", DEVICE_TYPE_STRING)); for (int id = 0; id < 2; id++) { BX_CONTROLLER(id).status.busy = 0; BX_CONTROLLER(id).status.drive_ready = 1; BX_CONTROLLER(id).reset_in_progress = 0; // Device signature if (BX_HD_THIS s[id].device_type == IDE_DISK) { BX_CONTROLLER(id).head_no = 0; BX_CONTROLLER(id).sector_count = 1; BX_CONTROLLER(id).sector_no = 1; BX_CONTROLLER(id).cylinder_no = 0; } else { BX_CONTROLLER(id).head_no = 0; BX_CONTROLLER(id).sector_count = 1; BX_CONTROLLER(id).sector_no = 1; BX_CONTROLLER(id).cylinder_no = 0xeb14; } } } break; #if 0 // you'll need these to support second IDE controller, not needed yet. case 0x170: case 0x171: case 0x172: case 0x173: case 0x174: case 0x175: case 0x176: case 0x177: BX_DEBUG(("ignoring write to 0x%04x", address)); break; #endif default: BX_PANIC(("hard drive: io write to address %x = %02x", (unsigned) address, (unsigned) value)); } } void bx_hard_drive_c::close_harddrive(void) { BX_HD_THIS s[0].hard_drive->close(); BX_HD_THIS s[1].hard_drive->close(); } Bit32u bx_hard_drive_c::calculate_logical_address() { Bit32u logical_sector; if (BX_SELECTED_CONTROLLER.lba_mode) { //bx_printf ("disk: calculate: %d %d %d\n", ((Bit32u)BX_SELECTED_CONTROLLER.head_no), ((Bit32u)BX_SELECTED_CONTROLLER.cylinder_no), (Bit32u)BX_SELECTED_CONTROLLER.sector_no); logical_sector = ((Bit32u)BX_SELECTED_CONTROLLER.head_no) << 24 | ((Bit32u)BX_SELECTED_CONTROLLER.cylinder_no) << 8 | (Bit32u)BX_SELECTED_CONTROLLER.sector_no; //bx_printf ("disk: result: %u\n", logical_sector); } else logical_sector = (BX_SELECTED_CONTROLLER.cylinder_no * BX_SELECTED_HD.hard_drive->heads * BX_SELECTED_HD.hard_drive->sectors) + (BX_SELECTED_CONTROLLER.head_no * BX_SELECTED_HD.hard_drive->sectors) + (BX_SELECTED_CONTROLLER.sector_no - 1); if (logical_sector >= (BX_SELECTED_HD.hard_drive->cylinders * BX_SELECTED_HD.hard_drive->heads * BX_SELECTED_HD.hard_drive->sectors)) { BX_PANIC(("read sectors: out of bounds")); } return logical_sector; } void bx_hard_drive_c::increment_address() { BX_SELECTED_CONTROLLER.sector_count--; if (BX_SELECTED_CONTROLLER.lba_mode) { Bit32u current_address = calculate_logical_address(); current_address++; BX_SELECTED_CONTROLLER.head_no = (current_address >> 24) & 0xf; BX_SELECTED_CONTROLLER.cylinder_no = (current_address >> 8) & 0xffff; BX_SELECTED_CONTROLLER.sector_no = (current_address) & 0xff; } else { BX_SELECTED_CONTROLLER.sector_no++; if (BX_SELECTED_CONTROLLER.sector_no > BX_SELECTED_HD.hard_drive->sectors) { BX_SELECTED_CONTROLLER.sector_no = 1; BX_SELECTED_CONTROLLER.head_no++; if (BX_SELECTED_CONTROLLER.head_no >= BX_SELECTED_HD.hard_drive->heads) { BX_SELECTED_CONTROLLER.head_no = 0; BX_SELECTED_CONTROLLER.cylinder_no++; if (BX_SELECTED_CONTROLLER.cylinder_no >= BX_SELECTED_HD.hard_drive->cylinders) BX_SELECTED_CONTROLLER.cylinder_no = BX_SELECTED_HD.hard_drive->cylinders - 1; } } } } void bx_hard_drive_c::identify_ATAPI_drive(unsigned drive) { unsigned i; if (drive != (unsigned)BX_HD_THIS drive_select) { BX_PANIC(("identify_drive panic (drive != drive_select)")); } BX_SELECTED_HD.id_drive[0] = (2 << 14) | (5 << 8) | (1 << 7) | (2 << 5) | (0 << 0); // Removable CDROM, 50us response, 12 byte packets for (i = 1; i <= 9; i++) BX_SELECTED_HD.id_drive[i] = 0; char* serial_number = " VT00001\0\0\0\0\0\0\0\0\0\0\0\0"; for (i = 0; i < 10; i++) { BX_SELECTED_HD.id_drive[10+i] = (serial_number[i*2] << 8) | serial_number[i*2 + 1]; } for (i = 20; i <= 22; i++) BX_SELECTED_HD.id_drive[i] = 0; char* firmware = "ALPHA1 "; for (i = 0; i < strlen(firmware)/2; i++) { BX_SELECTED_HD.id_drive[23+i] = (firmware[i*2] << 8) | firmware[i*2 + 1]; } BX_ASSERT((23+i) == 27); for (i = 0; i < strlen((char *) model_no)/2; i++) { BX_SELECTED_HD.id_drive[27+i] = (model_no[i*2] << 8) | model_no[i*2 + 1]; } BX_ASSERT((27+i) == 47); BX_SELECTED_HD.id_drive[47] = 0; BX_SELECTED_HD.id_drive[48] = 0; BX_SELECTED_HD.id_drive[49] = (1 << 9); // LBA supported BX_SELECTED_HD.id_drive[50] = 0; BX_SELECTED_HD.id_drive[51] = 0; BX_SELECTED_HD.id_drive[52] = 0; BX_SELECTED_HD.id_drive[53] = 3; // words 64-70, 54-58 valid for (i = 54; i <= 62; i++) BX_SELECTED_HD.id_drive[i] = 0; // copied from CFA540A BX_SELECTED_HD.id_drive[63] = 0x0103; // variable (DMA stuff) BX_SELECTED_HD.id_drive[64] = 0x0001; // PIO BX_SELECTED_HD.id_drive[65] = 0x00b4; BX_SELECTED_HD.id_drive[66] = 0x00b4; BX_SELECTED_HD.id_drive[67] = 0x012c; BX_SELECTED_HD.id_drive[68] = 0x00b4; BX_SELECTED_HD.id_drive[69] = 0; BX_SELECTED_HD.id_drive[70] = 0; BX_SELECTED_HD.id_drive[71] = 30; // faked BX_SELECTED_HD.id_drive[72] = 30; // faked BX_SELECTED_HD.id_drive[73] = 0; BX_SELECTED_HD.id_drive[74] = 0; BX_SELECTED_HD.id_drive[75] = 0; for (i = 76; i <= 79; i++) BX_SELECTED_HD.id_drive[i] = 0; BX_SELECTED_HD.id_drive[80] = 0x1e; // supports up to ATA/ATAPI-4 BX_SELECTED_HD.id_drive[81] = 0; BX_SELECTED_HD.id_drive[82] = 0; BX_SELECTED_HD.id_drive[83] = 0; BX_SELECTED_HD.id_drive[84] = 0; BX_SELECTED_HD.id_drive[85] = 0; BX_SELECTED_HD.id_drive[86] = 0; BX_SELECTED_HD.id_drive[87] = 0; BX_SELECTED_HD.id_drive[88] = 0; for (i = 89; i <= 126; i++) BX_SELECTED_HD.id_drive[i] = 0; BX_SELECTED_HD.id_drive[127] = 0; BX_SELECTED_HD.id_drive[128] = 0; for (i = 129; i <= 159; i++) BX_SELECTED_HD.id_drive[i] = 0; for (i = 160; i <= 255; i++) BX_SELECTED_HD.id_drive[i] = 0; // now convert the id_drive array (native 256 word format) to // the controller buffer (512 bytes) Bit16u temp16; for (i = 0; i <= 255; i++) { temp16 = BX_SELECTED_HD.id_drive[i]; BX_SELECTED_CONTROLLER.buffer[i*2] = temp16 & 0x00ff; BX_SELECTED_CONTROLLER.buffer[i*2+1] = temp16 >> 8; } } void bx_hard_drive_c::identify_drive(unsigned drive) { unsigned i; Bit32u temp32; Bit16u temp16; if (drive != BX_HD_THIS drive_select) { BX_PANIC(("identify_drive panic (drive != drive_select)")); } #if defined(CONNER_CFA540A) BX_SELECTED_HD.id_drive[0] = 0x0c5a; BX_SELECTED_HD.id_drive[1] = 0x0418; BX_SELECTED_HD.id_drive[2] = 0; BX_SELECTED_HD.id_drive[3] = BX_SELECTED_HD.hard_drive->heads; BX_SELECTED_HD.id_drive[4] = 0x9fb7; BX_SELECTED_HD.id_drive[5] = 0x0289; BX_SELECTED_HD.id_drive[6] = BX_SELECTED_HD.hard_drive->sectors; BX_SELECTED_HD.id_drive[7] = 0x0030; BX_SELECTED_HD.id_drive[8] = 0x000a; BX_SELECTED_HD.id_drive[9] = 0x0000; char* serial_number = " CA00GSQ\0\0\0\0\0\0\0\0\0\0\0\0"; for (i = 0; i < 10; i++) { BX_SELECTED_HD.id_drive[10+i] = (serial_number[i*2] << 8) | serial_number[i*2 + 1]; } BX_SELECTED_HD.id_drive[20] = 3; BX_SELECTED_HD.id_drive[21] = 512; // 512 Sectors = 256kB cache BX_SELECTED_HD.id_drive[22] = 4; char* firmware = "8FT054 "; for (i = 0; i < strlen(firmware)/2; i++) { BX_SELECTED_HD.id_drive[23+i] = (firmware[i*2] << 8) | firmware[i*2 + 1]; } BX_ASSERT((23+i) == 27); char* model = "Conner Peripherals 540MB - CFA540A "; for (i = 0; i < strlen(model)/2; i++) { BX_SELECTED_HD.id_drive[27+i] = (model[i*2] << 8) | model[i*2 + 1]; } BX_ASSERT((27+i) == 47); BX_SELECTED_HD.id_drive[47] = 0x8080; // multiple mode identification BX_SELECTED_HD.id_drive[48] = 0; BX_SELECTED_HD.id_drive[49] = 0x0f01; BX_SELECTED_HD.id_drive[50] = 0; BX_SELECTED_HD.id_drive[51] = 0; BX_SELECTED_HD.id_drive[52] = 0x0002; BX_SELECTED_HD.id_drive[53] = 0x0003; BX_SELECTED_HD.id_drive[54] = 0x0418; BX_SELECTED_HD.id_drive[55] = BX_SELECTED_HD.hard_drive->heads; BX_SELECTED_HD.id_drive[56] = BX_SELECTED_HD.hard_drive->sectors; BX_SELECTED_HD.id_drive[57] = 0x1e80; BX_SELECTED_HD.id_drive[58] = 0x0010; BX_SELECTED_HD.id_drive[59] = 0x0100 | BX_SELECTED_CONTROLLER.sectors_per_block; BX_SELECTED_HD.id_drive[60] = 0x20e0; BX_SELECTED_HD.id_drive[61] = 0x0010; BX_SELECTED_HD.id_drive[62] = 0; BX_SELECTED_HD.id_drive[63] = 0x0103; // variable (DMA stuff) BX_SELECTED_HD.id_drive[64] = 0x0001; // PIO BX_SELECTED_HD.id_drive[65] = 0x00b4; BX_SELECTED_HD.id_drive[66] = 0x00b4; BX_SELECTED_HD.id_drive[67] = 0x012c; BX_SELECTED_HD.id_drive[68] = 0x00b4; for (i = 69; i <= 79; i++) BX_SELECTED_HD.id_drive[i] = 0; BX_SELECTED_HD.id_drive[80] = 0; BX_SELECTED_HD.id_drive[81] = 0; BX_SELECTED_HD.id_drive[82] = 0; BX_SELECTED_HD.id_drive[83] = 0; BX_SELECTED_HD.id_drive[84] = 0; BX_SELECTED_HD.id_drive[85] = 0; BX_SELECTED_HD.id_drive[86] = 0; BX_SELECTED_HD.id_drive[87] = 0; for (i = 88; i <= 127; i++) BX_SELECTED_HD.id_drive[i] = 0; BX_SELECTED_HD.id_drive[128] = 0x0418; BX_SELECTED_HD.id_drive[129] = 0x103f; BX_SELECTED_HD.id_drive[130] = 0x0418; BX_SELECTED_HD.id_drive[131] = 0x103f; BX_SELECTED_HD.id_drive[132] = 0x0004; BX_SELECTED_HD.id_drive[133] = 0xffff; BX_SELECTED_HD.id_drive[134] = 0; BX_SELECTED_HD.id_drive[135] = 0x5050; for (i = 136; i <= 144; i++) BX_SELECTED_HD.id_drive[i] = 0; BX_SELECTED_HD.id_drive[145] = 0x302e; BX_SELECTED_HD.id_drive[146] = 0x3245; BX_SELECTED_HD.id_drive[147] = 0x2020; BX_SELECTED_HD.id_drive[148] = 0x2020; for (i = 149; i <= 255; i++) BX_SELECTED_HD.id_drive[i] = 0; #else // Identify Drive command return values definition // // This code is rehashed from some that was donated. // I'm using ANSI X3.221-1994, AT Attachment Interface for Disk Drives // and X3T10 2008D Working Draft for ATA-3 // Word 0: general config bit-significant info // Note: bits 1-5 and 8-14 are now "Vendor specific (obsolete)" // bit 15: 0=ATA device // 1=ATAPI device // bit 14: 1=format speed tolerance gap required // bit 13: 1=track offset option available // bit 12: 1=data strobe offset option available // bit 11: 1=rotational speed tolerance is > 0,5% (typo?) // bit 10: 1=disk transfer rate > 10Mbs // bit 9: 1=disk transfer rate > 5Mbs but <= 10Mbs // bit 8: 1=disk transfer rate <= 5Mbs // bit 7: 1=removable cartridge drive // bit 6: 1=fixed drive // bit 5: 1=spindle motor control option implemented // bit 4: 1=head switch time > 15 usec // bit 3: 1=not MFM encoded // bit 2: 1=soft sectored // bit 1: 1=hard sectored // bit 0: 0=reserved BX_SELECTED_HD.id_drive[0] = 0x0040; // Word 1: number of user-addressable cylinders in // default translation mode. If the value in words 60-61 // exceed 16,515,072, this word shall contain 16,383. BX_SELECTED_HD.id_drive[1] = BX_SELECTED_HD.hard_drive->cylinders; // Word 2: reserved BX_SELECTED_HD.id_drive[2] = 0; // Word 3: number of user-addressable heads in default // translation mode BX_SELECTED_HD.id_drive[3] = BX_SELECTED_HD.hard_drive->heads; // Word 4: # unformatted bytes per translated track in default xlate mode // Word 5: # unformatted bytes per sector in default xlated mode // Word 6: # user-addressable sectors per track in default xlate mode // Note: words 4,5 are now "Vendor specific (obsolete)" BX_SELECTED_HD.id_drive[4] = (512 * BX_SELECTED_HD.hard_drive->sectors); BX_SELECTED_HD.id_drive[5] = 512; BX_SELECTED_HD.id_drive[6] = BX_SELECTED_HD.hard_drive->sectors; // Word 7-9: Vendor specific for (i=7; i<=9; i++) BX_SELECTED_HD.id_drive[i] = 0; // Word 10-19: Serial number (20 ASCII characters, 0000h=not specified) // This field is right justified and padded with spaces (20h). for (i=10; i<=19; i++) BX_SELECTED_HD.id_drive[i] = 0; // Word 20: buffer type // 0000h = not specified // 0001h = single ported single sector buffer which is // not capable of simulataneous data xfers to/from // the host and the disk. // 0002h = dual ported multi-sector buffer capable of // simulatenous data xfers to/from the host and disk. // 0003h = dual ported mutli-sector buffer capable of // simulatenous data xfers with a read caching // capability. // 0004h-ffffh = reserved BX_SELECTED_HD.id_drive[20] = 3; // Word 21: buffer size in 512 byte increments, 0000h = not specified BX_SELECTED_HD.id_drive[21] = 512; // 512 Sectors = 256kB cache // Word 22: # of ECC bytes available on read/write long cmds // 0000h = not specified BX_SELECTED_HD.id_drive[22] = 4; // Word 23..26: Firmware revision (8 ascii chars, 0000h=not specified) // This field is left justified and padded with spaces (20h) for (i=23; i<=26; i++) BX_SELECTED_HD.id_drive[i] = 0; // Word 27..46: Model number (40 ascii chars, 0000h=not specified) // This field is left justified and padded with spaces (20h) // for (i=27; i<=46; i++) // BX_SELECTED_HD.id_drive[i] = 0; for (i=0; i<20; i++) { BX_SELECTED_HD.id_drive[27+i] = (model_no[i*2] << 8) | model_no[i*2 + 1]; } // Word 47: 15-8 Vendor unique // 7-0 00h= read/write multiple commands not implemented // xxh= maximum # of sectors that can be transferred // per interrupt on read and write multiple commands BX_SELECTED_HD.id_drive[47] = max_multiple_sectors; // Word 48: 0000h = cannot perform dword IO // 0001h = can perform dword IO BX_SELECTED_HD.id_drive[48] = 0; // Word 49: Capabilities // 15-10: 0 = reserved // 9: 1 = LBA supported // 8: 1 = DMA supported // 7-0: Vendor unique BX_SELECTED_HD.id_drive[49] = 0; // Word 50: Reserved BX_SELECTED_HD.id_drive[50] = 0; // Word 51: 15-8 PIO data transfer cycle timing mode // 7-0 Vendor unique BX_SELECTED_HD.id_drive[51] = 0x200; // Word 52: 15-8 DMA data transfer cycle timing mode // 7-0 Vendor unique BX_SELECTED_HD.id_drive[52] = 0x200; // Word 53: 15-1 Reserved // 0 1=the fields reported in words 54-58 are valid // 0=the fields reported in words 54-58 may be valid BX_SELECTED_HD.id_drive[53] = 0; // Word 54: # of user-addressable cylinders in curr xlate mode // Word 55: # of user-addressable heads in curr xlate mode // Word 56: # of user-addressable sectors/track in curr xlate mode BX_SELECTED_HD.id_drive[54] = BX_SELECTED_HD.hard_drive->cylinders; BX_SELECTED_HD.id_drive[55] = BX_SELECTED_HD.hard_drive->heads; BX_SELECTED_HD.id_drive[56] = BX_SELECTED_HD.hard_drive->sectors; // Word 57-58: Current capacity in sectors // Excludes all sectors used for device specific purposes. temp32 = BX_SELECTED_HD.hard_drive->cylinders * BX_SELECTED_HD.hard_drive->heads * BX_SELECTED_HD.hard_drive->sectors; BX_SELECTED_HD.id_drive[57] = (temp32 & 0xffff); // LSW BX_SELECTED_HD.id_drive[58] = (temp32 >> 16); // MSW // Word 59: 15-9 Reserved // 8 1=multiple sector setting is valid // 7-0 current setting for number of sectors that can be // transferred per interrupt on R/W multiple commands BX_SELECTED_HD.id_drive[59] = 0x0000 | curr_multiple_sectors; // Word 60-61: // If drive supports LBA Mode, these words reflect total # of user // addressable sectors. This value does not depend on the current // drive geometry. If the drive does not support LBA mode, these // words shall be set to 0. Bit32u num_sects = BX_SELECTED_HD.hard_drive->cylinders * BX_SELECTED_HD.hard_drive->heads * BX_SELECTED_HD.hard_drive->sectors; BX_SELECTED_HD.id_drive[60] = num_sects & 0xffff; // LSW BX_SELECTED_HD.id_drive[61] = num_sects >> 16; // MSW // Word 62: 15-8 single word DMA transfer mode active // 7-0 single word DMA transfer modes supported // The low order byte identifies by bit, all the Modes which are // supported e.g., if Mode 0 is supported bit 0 is set. // The high order byte contains a single bit set to indiciate // which mode is active. BX_SELECTED_HD.id_drive[62] = 0x0; // Word 63: 15-8 multiword DMA transfer mode active // 7-0 multiword DMA transfer modes supported // The low order byte identifies by bit, all the Modes which are // supported e.g., if Mode 0 is supported bit 0 is set. // The high order byte contains a single bit set to indiciate // which mode is active. BX_SELECTED_HD.id_drive[63] = 0x0; // Word 64-79 Reserved for (i=64; i<=79; i++) BX_SELECTED_HD.id_drive[i] = 0; // Word 80: 15-5 reserved // 4 supports ATA/ATAPI-4 // 3 supports ATA-3 // 2 supports ATA-2 // 1 supports ATA-1 // 0 reserved BX_SELECTED_HD.id_drive[80] = (1 << 2) | (1 << 1); // Word 81: Minor version number BX_SELECTED_HD.id_drive[81] = 0; // Word 82: 15 obsolete // 14 NOP command supported // 13 READ BUFFER command supported // 12 WRITE BUFFER command supported // 11 obsolete // 10 Host protected area feature set supported // 9 DEVICE RESET command supported // 8 SERVICE interrupt supported // 7 release interrupt supported // 6 look-ahead supported // 5 write cache supported // 4 supports PACKET command feature set // 3 supports power management feature set // 2 supports removable media feature set // 1 supports securite mode feature set // 0 support SMART feature set BX_SELECTED_HD.id_drive[82] = 1 << 14; BX_SELECTED_HD.id_drive[83] = 1 << 14; BX_SELECTED_HD.id_drive[84] = 1 << 14; BX_SELECTED_HD.id_drive[85] = 1 << 14; BX_SELECTED_HD.id_drive[86] = 0; BX_SELECTED_HD.id_drive[87] = 1 << 14; for (i=88; i<=127; i++) BX_SELECTED_HD.id_drive[i] = 0; // Word 128-159 Vendor unique for (i=128; i<=159; i++) BX_SELECTED_HD.id_drive[i] = 0; // Word 160-255 Reserved for (i=160; i<=255; i++) BX_SELECTED_HD.id_drive[i] = 0; #endif BX_DEBUG(("Drive ID Info. initialized : %04d {%s}", 512, DEVICE_TYPE_STRING)); // now convert the id_drive array (native 256 word format) to // the controller buffer (512 bytes) for (i=0; i<=255; i++) { temp16 = BX_SELECTED_HD.id_drive[i]; BX_SELECTED_CONTROLLER.buffer[i*2] = temp16 & 0x00ff; BX_SELECTED_CONTROLLER.buffer[i*2+1] = temp16 >> 8; } } void bx_hard_drive_c::init_send_atapi_command(Bit8u command, int req_length, int alloc_length, bool lazy) { if (BX_SELECTED_CONTROLLER.byte_count == 0) BX_PANIC(("ATAPI command with zero byte count")); if (BX_SELECTED_CONTROLLER.byte_count & 1) BX_PANIC(("Odd byte count to ATAPI command")); if (alloc_length <= 0) BX_PANIC(("Allocation length <= 0")); BX_SELECTED_CONTROLLER.interrupt_reason.i_o = 1; BX_SELECTED_CONTROLLER.interrupt_reason.c_d = 0; BX_SELECTED_CONTROLLER.status.busy = 0; BX_SELECTED_CONTROLLER.status.drq = 1; BX_SELECTED_CONTROLLER.status.err = 0; // no bytes transfered yet if (lazy) BX_SELECTED_CONTROLLER.buffer_index = 2048; else BX_SELECTED_CONTROLLER.buffer_index = 0; if (BX_SELECTED_CONTROLLER.byte_count > req_length) BX_SELECTED_CONTROLLER.byte_count = req_length; if (BX_SELECTED_CONTROLLER.byte_count > alloc_length) BX_SELECTED_CONTROLLER.byte_count = alloc_length; BX_SELECTED_HD.atapi.command = command; BX_SELECTED_HD.atapi.drq_bytes = BX_SELECTED_CONTROLLER.byte_count; BX_SELECTED_HD.atapi.total_bytes_remaining = (req_length < alloc_length) ? req_length : alloc_length; if (lazy) { // bias drq_bytes and total_bytes_remaining BX_SELECTED_HD.atapi.drq_bytes += 2048; BX_SELECTED_HD.atapi.total_bytes_remaining += 2048; } } void bx_hard_drive_c::atapi_cmd_error(sense_t sense_key, asc_t asc) { BX_SELECTED_CONTROLLER.error_register = sense_key << 4; BX_SELECTED_CONTROLLER.interrupt_reason.i_o = 1; BX_SELECTED_CONTROLLER.interrupt_reason.c_d = 1; BX_SELECTED_CONTROLLER.interrupt_reason.rel = 0; BX_SELECTED_CONTROLLER.status.busy = 0; BX_SELECTED_CONTROLLER.status.drive_ready = 1; BX_SELECTED_CONTROLLER.status.write_fault = 0; BX_SELECTED_CONTROLLER.status.drq = 0; BX_SELECTED_CONTROLLER.status.err = 1; BX_SELECTED_HD.sense.sense_key = sense_key; BX_SELECTED_HD.sense.asc = asc; BX_SELECTED_HD.sense.ascq = 0; } void bx_hard_drive_c::atapi_cmd_nop() { BX_SELECTED_CONTROLLER.interrupt_reason.i_o = 1; BX_SELECTED_CONTROLLER.interrupt_reason.c_d = 1; BX_SELECTED_CONTROLLER.interrupt_reason.rel = 0; BX_SELECTED_CONTROLLER.status.busy = 0; BX_SELECTED_CONTROLLER.status.drive_ready = 1; BX_SELECTED_CONTROLLER.status.drq = 0; BX_SELECTED_CONTROLLER.status.err = 0; } void bx_hard_drive_c::init_mode_sense_single(const void* src, int size) { // Header BX_SELECTED_CONTROLLER.buffer[0] = (size+6) >> 8; BX_SELECTED_CONTROLLER.buffer[1] = (size+6) & 0xff; BX_SELECTED_CONTROLLER.buffer[2] = 0x70; // no media present BX_SELECTED_CONTROLLER.buffer[3] = 0; // reserved BX_SELECTED_CONTROLLER.buffer[4] = 0; // reserved BX_SELECTED_CONTROLLER.buffer[5] = 0; // reserved BX_SELECTED_CONTROLLER.buffer[6] = 0; // reserved BX_SELECTED_CONTROLLER.buffer[7] = 0; // reserved // Data memcpy(BX_SELECTED_CONTROLLER.buffer + 8, src, size); } void bx_hard_drive_c::ready_to_send_atapi() { raise_interrupt(); } void bx_hard_drive_c::raise_interrupt() { if (!BX_SELECTED_CONTROLLER.control.disable_irq) { Bit32u irq = 14; // always 1st IDE controller // for second controller, you would want irq 15 BX_DEBUG(("Raising interrupt %d {%s}", irq, DEVICE_TYPE_STRING)); BX_HD_THIS devices->pic->trigger_irq(irq); } else { if (bx_dbg.disk || (CDROM_SELECTED && bx_dbg.cdrom)) BX_INFO(("Interrupt masked {%s}", DEVICE_TYPE_STRING)); } } void bx_hard_drive_c::command_aborted(unsigned value) { BX_DEBUG(("aborting on command 0x%02x {%s}", value, DEVICE_TYPE_STRING)); BX_SELECTED_CONTROLLER.current_command = 0; BX_SELECTED_CONTROLLER.status.busy = 0; BX_SELECTED_CONTROLLER.status.drive_ready = 1; BX_SELECTED_CONTROLLER.status.err = 1; BX_SELECTED_CONTROLLER.error_register = 0x04; // command ABORTED BX_SELECTED_CONTROLLER.status.drq = 0; BX_SELECTED_CONTROLLER.status.seek_complete = 0; BX_SELECTED_CONTROLLER.status.corrected_data = 0; BX_SELECTED_CONTROLLER.buffer_index = 0; raise_interrupt(); } /*** default_image_t function definitions ***/ int default_image_t::open (const char* pathname) { fd = ::open(pathname, O_RDWR #ifdef O_BINARY | O_BINARY #endif ); if (fd < 0) { return fd; } /* look at size of image file to calculate disk geometry */ struct stat stat_buf; int ret = fstat(fd, &stat_buf); if (ret) { BX_PANIC(("fstat() returns error!")); } return fd; } void default_image_t::close () { if (fd > -1) { ::close(fd); } } off_t default_image_t::lseek (off_t offset, int whence) { return ::lseek(fd, offset, whence); } ssize_t default_image_t::read (void* buf, size_t count) { return ::read(fd, buf, count); } ssize_t default_image_t::write (const void* buf, size_t count) { return ::write(fd, buf, count); } #if BX_SPLIT_HD_SUPPORT /*** concat_image_t function definitions ***/ void concat_image_t::increment_string (char *str) { // find the last character of the string, and increment it. char *p = str; while (*p != 0) p++; BX_ASSERT (p>str); // choke on zero length strings p--; // point to last character of the string ++(*p); // increment to next ascii code. BX_DEBUG(("concat_image.increment string returning '%s'", str)); } int concat_image_t::open (const char* pathname0) { char *pathname = strdup (pathname0); BX_DEBUG(("concat_image_t.open")); ssize_t start_offset = 0; for (int i=0; i -1) { ::close(fd); } } off_t concat_image_t::lseek (off_t offset, int whence) { if ((offset % 512) != 0) BX_PANIC( ("lseek HD with offset not multiple of 512")); BX_DEBUG(("concat_image_t.lseek(%d)", whence)); // is this offset in this disk image? if (offset < thismin) { // no, look at previous images for (int i=index-1; i>=0; i--) { if (offset >= start_offset_table[i]) { index = i; fd = fd_table[i]; thismin = start_offset_table[i]; thismax = thismin + length_table[i] - 1; BX_DEBUG(("concat_image_t.lseek to earlier image, index=%d", index)); break; } } } else if (offset > thismax) { // no, look at later images for (int i=index+1; i= length_table[index]) BX_PANIC(("concat_image_t.lseek to byte %ld failed", (long)offset)); seek_was_last_op = 1; return ::lseek(fd, offset, whence); } ssize_t concat_image_t::read (void* buf, size_t count) { if (bx_dbg.disk) BX_DEBUG(("concat_image_t.read %ld bytes", (long)count)); // notice if anyone does sequential read or write without seek in between. // This can be supported pretty easily, but needs additional checks for // end of a partial image. if (!seek_was_last_op) BX_PANIC( ("no seek before read")); return ::read(fd, buf, count); } ssize_t concat_image_t::write (const void* buf, size_t count) { BX_DEBUG(("concat_image_t.write %ld bytes", (long)count)); // notice if anyone does sequential read or write without seek in between. // This can be supported pretty easily, but needs additional checks for // end of a partial image. if (!seek_was_last_op) BX_PANIC( ("no seek before write")); return ::write(fd, buf, count); } #endif /* BX_SPLIT_HD_SUPPORT */ error_recovery_t::error_recovery_t () { if (sizeof(error_recovery_t) != 8) { BX_PANIC(("error_recovery_t has size != 8")); } data[0] = 0x01; data[1] = 0x06; data[2] = 0x00; data[3] = 0x05; // Try to recover 5 times data[4] = 0x00; data[5] = 0x00; data[6] = 0x00; data[7] = 0x00; } uint16 read_16bit(const uint8* buf) { return (buf[0] << 8) | buf[1]; } uint32 read_32bit(const uint8* buf) { return (buf[0] << 24) | (buf[1] << 16) | (buf[2] << 8) | buf[3]; }