/************************************************************************* * * * $Id: vfdhd.c 1995 2008-07-15 03:59:13Z hharte $ * * * * Copyright (c) 2007-2008 Howard M. Harte. * * http://www.hartetec.com * * * * Permission is hereby granted, free of charge, to any person obtaining * * a copy of this software and associated documentation files (the * * "Software"), to deal in the Software without restriction, including * * without limitation the rights to use, copy, modify, merge, publish, * * distribute, sublicense, and/or sell copies of the Software, and to * * permit persons to whom the Software is furnished to do so, subject to * * the following conditions: * * * * The above copyright notice and this permission notice shall be * * included in all copies or substantial portions of the Software. * * * * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, * * EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF * * MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND * * NONINFRINGEMENT. IN NO EVENT SHALL HOWARD M. HARTE BE LIABLE FOR ANY * * CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, * * TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION WITH THE * * SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE. * * * * Except as contained in this notice, the name of Howard M. Harte shall * * not be used in advertising or otherwise to promote the sale, use or * * other dealings in this Software without prior written authorization * * Howard M. Harte. * * * * SIMH Interface based on altairz80_hdsk.c, by Peter Schorn. * * * * Module Description: * * Micropolis FDC module for SIMH * * * * Environment: * * User mode only * * * *************************************************************************/ /*#define DBG_MSG */ #define USE_VGI /* Use 275-byte VGI-format sectors (includes all metadata) */ #include "altairz80_defs.h" #if defined (_WIN32) #include #endif #include "sim_imd.h" /* #define DBG_MSG */ #ifdef DBG_MSG #define DBG_PRINT(args) sim_printf args #else #define DBG_PRINT(args) #endif /* Debug flags */ #define ERROR_MSG (1 << 0) #define SEEK_MSG (1 << 1) #define CMD_MSG (1 << 2) #define RD_DATA_MSG (1 << 3) #define WR_DATA_MSG (1 << 4) #define STATUS_MSG (1 << 5) #define VERBOSE_MSG (1 << 6) static void VFDHD_Command(void); #define VFDHD_MAX_DRIVES 4 #define VFDHD_SECTOR_LEN 275 #define VFDHD_RAW_LEN (40 + VFDHD_SECTOR_LEN + 128) typedef union { struct { uint8 preamble[40]; /* Hard disk uses 30 bytes of preamble, floppy uses 40. */ uint8 sync; uint8 header[2]; uint8 unused[10]; uint8 data[256]; uint8 checksum; uint8 ecc[4]; uint8 ecc_valid; /* 0xAA indicates ECC is being used. */ uint8 postamble[128]; } u; uint8 raw[VFDHD_RAW_LEN]; } SECTOR_FORMAT; typedef struct { UNIT *uptr; DISK_INFO *imd; uint16 ntracks; /* number of tracks */ uint8 nheads; /* number of heads */ uint8 nspt; /* number of sectors per track */ uint8 npre_len; /* preamble length */ uint32 sectsize; /* sector size, not including pre/postamble */ uint16 track; uint8 wp; /* Disk write protected */ uint8 ready; /* Drive is ready */ uint8 write_fault; uint8 seek_complete; uint8 sync_lost; uint32 sector_wait_count; } VFDHD_DRIVE_INFO; typedef struct { PNP_INFO pnp; /* Plug and Play */ uint8 xfr_flag; /* Indicates controller is ready to send/receive data */ uint8 sel_drive; /* Currently selected drive */ uint8 selected; /* 1 if drive is selected */ uint8 track0; /* Set it selected drive is on track 0 */ uint8 head; /* Currently selected head */ uint8 wr_latch; /* Write enable latch */ uint8 int_enable; /* Interrupt Enable */ uint32 datacount; /* Number of data bytes transferred from controller for current sector */ uint8 step; uint8 direction; uint8 rwc; uint8 sector; uint8 read; uint8 ecc_enable; uint8 precomp; uint8 floppy_sel; uint8 controller_busy; uint8 motor_on; uint8 hdsk_type; VFDHD_DRIVE_INFO drive[VFDHD_MAX_DRIVES]; } VFDHD_INFO; static VFDHD_INFO vfdhd_info_data = { { 0x0, 0, 0xC0, 4 } }; static VFDHD_INFO *vfdhd_info = &vfdhd_info_data; static SECTOR_FORMAT sdata; extern uint32 PCX; extern t_stat set_iobase(UNIT *uptr, int32 val, char *cptr, void *desc); extern t_stat show_iobase(FILE *st, UNIT *uptr, int32 val, void *desc); extern uint32 sim_map_resource(uint32 baseaddr, uint32 size, uint32 resource_type, int32 (*routine)(const int32, const int32, const int32), uint8 unmap); #define UNIT_V_VFDHD_VERBOSE (UNIT_V_UF + 1) /* verbose mode, i.e. show error messages */ #define UNIT_VFDHD_VERBOSE (1 << UNIT_V_VFDHD_VERBOSE) #define VFDHD_CAPACITY (77*2*16*256) /* Default Micropolis Disk Capacity */ static t_stat vfdhd_reset(DEVICE *vfdhd_dev); static t_stat vfdhd_attach(UNIT *uptr, char *cptr); static t_stat vfdhd_detach(UNIT *uptr); static int32 vfdhddev(const int32 port, const int32 io, const int32 data); static uint8 VFDHD_Read(const uint32 Addr); static uint8 VFDHD_Write(const uint32 Addr, uint8 cData); static int32 hdSize = 5; static UNIT vfdhd_unit[] = { { UDATA (NULL, UNIT_FIX + UNIT_ATTABLE + UNIT_DISABLE + UNIT_ROABLE, VFDHD_CAPACITY) }, { UDATA (NULL, UNIT_FIX + UNIT_ATTABLE + UNIT_DISABLE + UNIT_ROABLE, VFDHD_CAPACITY) }, { UDATA (NULL, UNIT_FIX + UNIT_ATTABLE + UNIT_DISABLE + UNIT_ROABLE, VFDHD_CAPACITY) }, { UDATA (NULL, UNIT_FIX + UNIT_ATTABLE + UNIT_DISABLE + UNIT_ROABLE, VFDHD_CAPACITY) } }; static REG vfdhd_reg[] = { { DRDATAD (HDSIZE, hdSize, 10, "Size register"), }, { NULL } }; #define VFDHD_NAME "Vector Graphic FD-HD Controller VFDHD" static MTAB vfdhd_mod[] = { { MTAB_XTD|MTAB_VDV, 0, "IOBASE", "IOBASE", &set_iobase, &show_iobase, NULL, "Sets disk controller I/O base address" }, /* quiet, no warning messages */ { UNIT_VFDHD_VERBOSE, 0, "QUIET", "QUIET", NULL, NULL, NULL, "No verbose messages for unit " VFDHD_NAME "n" }, /* verbose, show warning messages */ { UNIT_VFDHD_VERBOSE, UNIT_VFDHD_VERBOSE, "VERBOSE", "VERBOSE", NULL, NULL, NULL, "Verbose messages for unit " VFDHD_NAME "n" }, { 0 } }; /* Debug Flags */ static DEBTAB vfdhd_dt[] = { { "ERROR", ERROR_MSG, "Error messages" }, { "SEEK", SEEK_MSG, "Seek messages" }, { "CMD", CMD_MSG, "Command messages" }, { "READ", RD_DATA_MSG, "Read messages" }, { "WRITE", WR_DATA_MSG, "Write messages" }, { "STATUS", STATUS_MSG, "Status messages" }, { "VERBOSE", VERBOSE_MSG, "Verbose messages" }, { NULL, 0 } }; DEVICE vfdhd_dev = { "VFDHD", vfdhd_unit, vfdhd_reg, vfdhd_mod, VFDHD_MAX_DRIVES, 10, 31, 1, VFDHD_MAX_DRIVES, VFDHD_MAX_DRIVES, NULL, NULL, &vfdhd_reset, NULL, &vfdhd_attach, &vfdhd_detach, &vfdhd_info_data, (DEV_DISABLE | DEV_DIS | DEV_DEBUG), ERROR_MSG, vfdhd_dt, NULL, VFDHD_NAME }; /* Reset routine */ static t_stat vfdhd_reset(DEVICE *dptr) { PNP_INFO *pnp = (PNP_INFO *)dptr->ctxt; if(dptr->flags & DEV_DIS) { sim_map_resource(pnp->io_base, pnp->io_size, RESOURCE_TYPE_IO, &vfdhddev, TRUE); } else { /* Connect MFDC at base address */ if(sim_map_resource(pnp->io_base, pnp->io_size, RESOURCE_TYPE_IO, &vfdhddev, FALSE) != 0) { sim_printf("%s: error mapping I/O resource at 0x%04x\n", __FUNCTION__, pnp->io_base); return SCPE_ARG; } } return SCPE_OK; } /* Attach routine */ static t_stat vfdhd_attach(UNIT *uptr, char *cptr) { t_stat r; unsigned int i = 0; r = attach_unit(uptr, cptr); /* attach unit */ if ( r != SCPE_OK) /* error? */ return r; /* Determine length of this disk */ uptr->capac = sim_fsize(uptr->fileref); for(i = 0; i < VFDHD_MAX_DRIVES; i++) { vfdhd_info->drive[i].uptr = &vfdhd_dev.units[i]; } for(i = 0; i < VFDHD_MAX_DRIVES; i++) { if(vfdhd_dev.units[i].fileref == uptr->fileref) { break; } } if(uptr->capac > 0) { r = assignDiskType(uptr); if (r != SCPE_OK) { vfdhd_detach(uptr); return r; } } else { /* creating file, must be DSK format. */ uptr->u3 = IMAGE_TYPE_DSK; } if (uptr->flags & UNIT_VFDHD_VERBOSE) sim_printf("VFDHD%d: attached to '%s', type=%s, len=%d\n", i, cptr, uptr->u3 == IMAGE_TYPE_IMD ? "IMD" : uptr->u3 == IMAGE_TYPE_CPT ? "CPT" : "DSK", uptr->capac); if(uptr->u3 == IMAGE_TYPE_IMD) { if(uptr->capac < 318000) { sim_printf("Cannot create IMD files with SIMH.\nCopy an existing file and format it with CP/M.\n"); vfdhd_detach(uptr); return SCPE_OPENERR; } if (uptr->flags & UNIT_VFDHD_VERBOSE) sim_printf("--------------------------------------------------------\n"); vfdhd_info->drive[i].imd = diskOpenEx((uptr->fileref), (uptr->flags & UNIT_VFDHD_VERBOSE), &vfdhd_dev, VERBOSE_MSG, VERBOSE_MSG); if (uptr->flags & UNIT_VFDHD_VERBOSE) sim_printf("\n"); } else { vfdhd_info->drive[i].imd = NULL; } if(i>0) { /* Floppy Disk, Unit 1-3 */ vfdhd_info->drive[i].ntracks = 77; /* number of tracks */ vfdhd_info->drive[i].nheads = 2; /* number of heads */ vfdhd_info->drive[i].nspt = 16; /* number of sectors per track */ vfdhd_info->drive[i].npre_len = 40; /* preamble length */ vfdhd_info->drive[i].sectsize = VFDHD_SECTOR_LEN; /* sector size, not including pre/postamble */ } else { /* Hard Disk, Unit 0 */ if(hdSize == 10) { vfdhd_info->drive[i].ntracks = 153; /* number of tracks */ vfdhd_info->drive[i].nheads = 6; /* number of heads */ vfdhd_info->hdsk_type = 1; sim_printf("10MB\n"); } else if (hdSize == 5) { vfdhd_info->drive[i].ntracks = 153; /* number of tracks */ vfdhd_info->drive[i].nheads = 4; /* number of heads */ vfdhd_info->hdsk_type = 0; sim_printf("5MB\n"); } else { vfdhd_info->drive[i].ntracks = 512; /* number of tracks */ vfdhd_info->drive[i].nheads = 8; /* number of heads */ vfdhd_info->hdsk_type = 1; sim_printf("32MB\n"); } vfdhd_info->drive[i].nheads = 4; /* number of heads */ vfdhd_info->drive[i].nspt = 32; /* number of sectors per track */ vfdhd_info->drive[i].npre_len = 30; /* preamble length */ vfdhd_info->drive[i].sectsize = VFDHD_SECTOR_LEN; /* sector size, not including pre/postamble */ vfdhd_info->drive[i].ready = 1; vfdhd_info->drive[i].seek_complete = 1; vfdhd_info->drive[i].sync_lost = 1; /* Active LOW */ } vfdhd_info->motor_on = 1; return SCPE_OK; } /* Detach routine */ static t_stat vfdhd_detach(UNIT *uptr) { t_stat r; int8 i; for(i = 0; i < VFDHD_MAX_DRIVES; i++) { if(vfdhd_dev.units[i].fileref == uptr->fileref) { break; } } DBG_PRINT(("Detach VFDHD%d\n", i)); r = diskClose(&vfdhd_info->drive[i].imd); if (r != SCPE_OK) return r; r = detach_unit(uptr); /* detach unit */ if (r != SCPE_OK) return r; return SCPE_OK; } static uint8 cy; static uint8 adc(uint8 sum, uint8 a1) { uint32 total; total = sum + a1 + cy; if(total > 0xFF) { cy = 1; } else { cy = 0; } return(total & 0xFF); } static int32 vfdhddev(const int32 port, const int32 io, const int32 data) { DBG_PRINT(("VFDHD: " ADDRESS_FORMAT " IO %s, Port %02x" NLP, PCX, io ? "WR" : "RD", port)); if(io) { VFDHD_Write(port, data); return 0; } else { return(VFDHD_Read(port)); } } #define FDHD_CTRL_STATUS0 0 /* R=Status Port 0, W=Control Port 0 */ #define FDHD_CTRL_STATUS1 1 /* R=Status Port 1, W=Control Port 0 */ #define FDHD_DATA 2 /* R/W=Data Port */ #define FDHD_RESET_START 3 /* R=RESET, W=START */ static uint8 VFDHD_Read(const uint32 Addr) { uint8 cData; VFDHD_DRIVE_INFO *pDrive; pDrive = &vfdhd_info->drive[vfdhd_info->sel_drive]; cData = 0x00; switch(Addr & 0x3) { case FDHD_CTRL_STATUS0: cData = (pDrive->wp & 1); /* [0] Write Protect (FD) */ cData |= (pDrive->ready & 1) << 1; /* [1] Drive ready (HD) */ cData |= (pDrive->track == 0) ? 0x04 : 0; /* [2] TK0 (FD/HD) */ cData |= (pDrive->write_fault & 1) << 3; /* [3] Write Fault (HD) */ cData |= (pDrive->seek_complete & 1) << 4; /* [4] Seek Complete (HD) */ cData |= (pDrive->sync_lost & 1) << 5; /* [5] Loss of Sync (HD) */ cData |= 0xC0; /* [7:6] Reserved (pulled up) */ sim_debug(STATUS_MSG, &vfdhd_dev, "VFDHD: " ADDRESS_FORMAT " RD S0 = 0x%02x\n", PCX, cData); break; case FDHD_CTRL_STATUS1: vfdhd_info->floppy_sel = (vfdhd_info->sel_drive == 0) ? 0 : 1; cData = (vfdhd_info->floppy_sel & 0x1); /* [0] Floppy Selected */ cData |= (vfdhd_info->controller_busy & 0x1) << 1; /* [1] Controller busy */ cData |= (vfdhd_info->motor_on & 0x1) << 2; /* [2] Motor On (FD) */ cData |= (vfdhd_info->hdsk_type & 0x1) << 3; /* [3] Hard Disk Type (0=5MB, 1=10MB) */ cData |= 0xF0; /* [7:4] Reserved (pulled up) */ if(vfdhd_info->sel_drive == 0) { /* cData &= 0xF0; */ } vfdhd_info->controller_busy = 0; sim_debug(STATUS_MSG, &vfdhd_dev, "VFDHD: " ADDRESS_FORMAT " RD S1 = 0x%02x\n", PCX, cData); break; case FDHD_DATA: /* DBG_PRINT(("VFDHD: " ADDRESS_FORMAT " RD Data" NLP, PCX)); */ if(vfdhd_info->datacount+40 >= VFDHD_RAW_LEN) { sim_debug(ERROR_MSG, &vfdhd_dev, "VFDHD: " ADDRESS_FORMAT " Illegal data count %d.\n", PCX, vfdhd_info->datacount); vfdhd_info->datacount = 0; } cData = sdata.raw[vfdhd_info->datacount+40]; vfdhd_info->datacount++; /* DBG_PRINT(("VFDHD: " ADDRESS_FORMAT " RD Data Sector %d[%03d]: 0x%02x" NLP, PCX, pDrive->sector, vfdhd_info->datacount, cData)); */ break; case FDHD_RESET_START: /* Reset */ sim_debug(CMD_MSG, &vfdhd_dev, "VFDHD: " ADDRESS_FORMAT " Reset\n", PCX); vfdhd_info->datacount = 0; cData = 0xFF; /* Return High-Z data */ break; } return (cData); } static uint8 VFDHD_Write(const uint32 Addr, uint8 cData) { VFDHD_DRIVE_INFO *pDrive; pDrive = &vfdhd_info->drive[vfdhd_info->sel_drive]; switch(Addr & 0x3) { case FDHD_CTRL_STATUS0: vfdhd_info->sel_drive = cData & 0x03; vfdhd_info->head = (cData >> 2) & 0x7; vfdhd_info->step = (cData >> 5) & 1; vfdhd_info->direction = (cData >> 6) & 1; vfdhd_info->rwc = (cData >> 7) & 1; sim_debug(WR_DATA_MSG, &vfdhd_dev, "VFDHD: " ADDRESS_FORMAT " WR C0=%02x: sel_drive=%d, head=%d, step=%d, dir=%d, rwc=%d\n", PCX, cData, vfdhd_info->sel_drive, vfdhd_info->head, vfdhd_info->step, vfdhd_info->direction, vfdhd_info->rwc); if(vfdhd_info->step == 1) { if(vfdhd_info->direction == 1) { /* Step IN */ pDrive->track++; } else { /* Step OUT */ if(pDrive->track != 0) { pDrive->track--; } } sim_debug(SEEK_MSG, &vfdhd_dev, "VFDHD: " ADDRESS_FORMAT " Drive %d on track %d\n", PCX, vfdhd_info->sel_drive, pDrive->track); } break; case FDHD_CTRL_STATUS1: vfdhd_info->sector = (cData & 0x1f); vfdhd_info->read = (cData >> 5) & 1; vfdhd_info->ecc_enable = (cData >> 6) & 1; vfdhd_info->precomp = (cData >> 7) & 1; if(cData == 0xFF) { sim_debug(SEEK_MSG, &vfdhd_dev, "VFDHD: " ADDRESS_FORMAT " Home Disk %d\n", PCX, vfdhd_info->sel_drive); pDrive->track = 0; } DBG_PRINT(("VFDHD: " ADDRESS_FORMAT " WR C1=%02x: sector=%d, read=%d, ecc_en=%d, precomp=%d" NLP, PCX, cData, vfdhd_info->sector, vfdhd_info->read, vfdhd_info->ecc_enable, vfdhd_info->precomp)); break; case FDHD_DATA: /* Data Port */ DBG_PRINT(("VFDHD: " ADDRESS_FORMAT " WR Data" NLP, PCX)); #ifdef USE_VGI if(vfdhd_info->sel_drive > 0) { /* Floppy */ if(vfdhd_info->datacount >= VFDHD_RAW_LEN) { sim_debug(ERROR_MSG, &vfdhd_dev, "VFDHD: " ADDRESS_FORMAT " Illegal data count %d.\n", PCX, vfdhd_info->datacount); vfdhd_info->datacount = 0; } sdata.raw[vfdhd_info->datacount] = cData; } else { /* Hard */ if(vfdhd_info->datacount+10 >= VFDHD_RAW_LEN) { sim_debug(ERROR_MSG, &vfdhd_dev, "VFDHD: " ADDRESS_FORMAT " Illegal data count %d.\n", PCX, vfdhd_info->datacount); vfdhd_info->datacount = 0; } sdata.raw[vfdhd_info->datacount+10] = cData; } #else if((vfdhd_info->datacount-13 >= VFDHD_RAW_LEN) || (vfdhd_info->datacount < 13)) { sim_debug(ERROR_MSG, &vfdhd_dev, "VFDHD: " ADDRESS_FORMAT " Illegal data count %d.\n", PCX, vfdhd_info->datacount); vfdhd_info->datacount = 13; } sdata.u.data[vfdhd_info->datacount-13] = cData; #endif /* USE_VGI */ vfdhd_info->datacount ++; break; case FDHD_RESET_START: sim_debug(CMD_MSG, &vfdhd_dev, "VFDHD: " ADDRESS_FORMAT " Start Command\n", PCX); VFDHD_Command(); break; } cData = 0x00; return (cData); } static void VFDHD_Command(void) { VFDHD_DRIVE_INFO *pDrive; uint32 bytesPerTrack; uint32 bytesPerHead; uint32 sec_offset; uint32 flags; int32 rtn; pDrive = &(vfdhd_info->drive[vfdhd_info->sel_drive]); bytesPerTrack = pDrive->sectsize * pDrive->nspt; bytesPerHead = bytesPerTrack * pDrive->ntracks; sec_offset = (pDrive->track * bytesPerTrack) + \ (vfdhd_info->head * bytesPerHead) + \ (vfdhd_info->sector * pDrive->sectsize); vfdhd_info->controller_busy = 1; if(vfdhd_info->read == 1) { /* Perform a Read operation */ unsigned int i, checksum; uint32 readlen; sim_debug(RD_DATA_MSG, &vfdhd_dev, "VFDHD: " ADDRESS_FORMAT " RD: Drive=%d, Track=%d, Head=%d, Sector=%d\n", PCX, vfdhd_info->sel_drive, pDrive->track, vfdhd_info->head, vfdhd_info->sector); /* Clear out unused portion of sector. */ memset(&sdata.u.unused[0], 0x00, 10); sdata.u.sync = 0xFF; sdata.u.header[0] = pDrive->track & 0xFF; sdata.u.header[1] = vfdhd_info->sector; switch((pDrive->uptr)->u3) { case IMAGE_TYPE_IMD: if(pDrive->imd == NULL) { sim_printf(".imd is NULL!" NLP); } sim_printf("%s: Read: imd=%p" NLP, __FUNCTION__, pDrive->imd); sectRead(pDrive->imd, pDrive->track, vfdhd_info->head, vfdhd_info->sector, sdata.u.data, 256, &flags, &readlen); adc(0,0); /* clear Carry bit */ checksum = 0; /* Checksum everything except the sync byte */ for(i=1;i<269;i++) { checksum = adc(checksum, sdata.raw[i+40]); } sdata.u.checksum = checksum & 0xFF; sdata.u.ecc_valid = 0xAA; break; case IMAGE_TYPE_DSK: if(pDrive->uptr->fileref == NULL) { sim_printf(".fileref is NULL!" NLP); } else { sim_fseek((pDrive->uptr)->fileref, sec_offset, SEEK_SET); rtn = sim_fread(&sdata.u.sync, 1, 274, /*VFDHD_SECTOR_LEN,*/ (pDrive->uptr)->fileref); if (rtn != 274) { sim_debug(ERROR_MSG, &vfdhd_dev, "VFDHD: " ADDRESS_FORMAT " READ: sim_fread error.\n", PCX); } memset(&sdata.u.preamble, 0, 40); memset(&sdata.u.ecc, 0, 4); /* Clear out the ECC bytes */ sdata.u.ecc_valid = 0xAA; /* Set the ECC Valid byte */ for(vfdhd_info->datacount = 0; sdata.raw[vfdhd_info->datacount] == 0x00; vfdhd_info->datacount++) { } DBG_PRINT(("VFDHD: " ADDRESS_FORMAT " READ: Sync found at offset %d" NLP, PCX, vfdhd_info->datacount)); } break; case IMAGE_TYPE_CPT: sim_printf("%s: CPT Format not supported" NLP, __FUNCTION__); break; default: sim_printf("%s: Unknown image Format" NLP, __FUNCTION__); break; } } else { /* Perform a Write operation */ uint32 writelen; sim_debug(WR_DATA_MSG, &vfdhd_dev, "VFDHD: " ADDRESS_FORMAT " WR: Drive=%d, Track=%d, Head=%d, Sector=%d\n", PCX, vfdhd_info->sel_drive, pDrive->track, vfdhd_info->head, vfdhd_info->sector); #ifdef USE_VGI #else int data_index = vfdhd_info->datacount - 13; sec_offset = (pDrive->track * 4096) + \ (vfdhd_info->head * 315392) + \ (vfdhd_info->sector * 256); #endif /* USE_VGI */ switch((pDrive->uptr)->u3) { case IMAGE_TYPE_IMD: if(pDrive->imd == NULL) { sim_printf(".imd is NULL!" NLP); } sectWrite(pDrive->imd, pDrive->track, vfdhd_info->head, vfdhd_info->sector, sdata.u.data, 256, &flags, &writelen); break; case IMAGE_TYPE_DSK: if(pDrive->uptr->fileref == NULL) { sim_printf(".fileref is NULL!" NLP); } else { DBG_PRINT(("VFDHD: " ADDRESS_FORMAT " WR drive=%d, track=%d, head=%d, sector=%d" NLP, PCX, vfdhd_info->sel_drive, pDrive->track, vfdhd_info->head, vfdhd_info->sector)); sim_fseek((pDrive->uptr)->fileref, sec_offset, SEEK_SET); #ifdef USE_VGI sim_fwrite(&sdata.u.sync, 1, VFDHD_SECTOR_LEN, (pDrive->uptr)->fileref); #else sim_fwrite(sdata.u.data, 1, 256, (pDrive->uptr)->fileref); #endif /* USE_VGI */ } break; case IMAGE_TYPE_CPT: sim_printf("%s: CPT Format not supported" NLP, __FUNCTION__); break; default: sim_printf("%s: Unknown image Format" NLP, __FUNCTION__); break; } } }