/* * 86Box A hypervisor and IBM PC system emulator that specializes in * running old operating systems and software designed for IBM * PC systems and compatibles from 1981 through fairly recent * system designs based on the PCI bus. * * This file is part of the 86Box distribution. * * Implementation of the HxC MFM image format. * * * * Authors: Miran Grca, * * Copyright 2018-2019 Miran Grca. */ #include #include #include #include #include #include #include #define HAVE_STDARG_H #include <86box/86box.h> #include <86box/timer.h> #include <86box/plat.h> #include <86box/fdd.h> #include <86box/fdd_86f.h> #include <86box/fdd_img.h> #include <86box/fdd_mfm.h> #include <86box/fdc.h> #pragma pack(push, 1) typedef struct { uint8_t hdr_name[7]; uint16_t tracks_no; uint8_t sides_no; uint16_t rpm; uint16_t bit_rate; uint8_t if_type; uint32_t track_list_offset; } mfm_header_t; typedef struct { uint16_t track_no; uint8_t side_no; uint32_t track_size; uint32_t track_offset; } mfm_track_t; typedef struct { uint16_t track_no; uint8_t side_no; uint16_t rpm; uint16_t bit_rate; uint32_t track_size; uint32_t track_offset; } mfm_adv_track_t; #pragma pack(pop) typedef struct { FILE *f; mfm_header_t hdr; mfm_track_t *tracks; mfm_adv_track_t *adv_tracks; uint16_t disk_flags, pad; uint16_t side_flags[2]; int br_rounded, rpm_rounded, total_tracks, cur_track; uint8_t track_data[2][256 * 1024]; } mfm_t; static mfm_t *mfm[FDD_NUM]; static fdc_t *mfm_fdc; #ifdef ENABLE_MFM_LOG int mfm_do_log = ENABLE_MFM_LOG; static void mfm_log(const char *fmt, ...) { va_list ap; if (mfm_do_log) { va_start(ap, fmt); pclog_ex(fmt, ap); va_end(ap); } } #else # define mfm_log(fmt, ...) #endif static int get_track_index(int drive, int side, int track) { mfm_t *dev = mfm[drive]; int i, ret = -1; for (i = 0; i < dev->total_tracks; i++) { if ((dev->tracks[i].track_no == track) && (dev->tracks[i].side_no == side)) { ret = i; break; } } return ret; } static int get_adv_track_index(int drive, int side, int track) { mfm_t *dev = mfm[drive]; int i, ret = -1; for (i = 0; i < dev->total_tracks; i++) { if ((dev->adv_tracks[i].track_no == track) && (dev->adv_tracks[i].side_no == side)) { ret = i; break; } } return ret; } static void get_adv_track_bitrate(int drive, int side, int track, int *br, int *rpm) { mfm_t *dev = mfm[drive]; int track_index; double dbr; track_index = get_adv_track_index(drive, side, track); if (track_index == -1) { *br = 250; *rpm = 300; } else { dbr = round(((double) dev->adv_tracks[track_index].bit_rate) / 50.0) * 50.0; *br = ((int) dbr); dbr = round(((double) dev->adv_tracks[track_index].rpm) / 60.0) * 60.0; *rpm = ((int) dbr); } } static void set_disk_flags(int drive) { int br = 250, rpm = 300; mfm_t *dev = mfm[drive]; uint16_t temp_disk_flags = 0x1080; /* We ALWAYS claim to have extra bit cells, even if the actual amount is 0; Bit 12 = 1, bits 6, 5 = 0 - extra bit cells field specifies the entire amount of bit cells per track. */ /* If this is the modified MFM format, get bit rate (and RPM) from track 0 instead. */ if (dev->hdr.if_type & 0x80) get_adv_track_bitrate(drive, 0, 0, &br, &rpm); else { br = dev->br_rounded; rpm = dev->rpm_rounded; } switch (br) { case 500: temp_disk_flags |= 2; break; case 300: case 250: default: temp_disk_flags |= 0; break; case 1000: temp_disk_flags |= 4; break; } if (dev->hdr.sides_no == 2) temp_disk_flags |= 8; dev->disk_flags = temp_disk_flags; } static uint16_t disk_flags(int drive) { mfm_t *dev = mfm[drive]; return dev->disk_flags; } static void set_side_flags(int drive, int side) { mfm_t *dev = mfm[drive]; uint16_t temp_side_flags = 0; int br = 250, rpm = 300; if (dev->hdr.if_type & 0x80) get_adv_track_bitrate(drive, side, dev->cur_track, &br, &rpm); else { br = dev->br_rounded; rpm = dev->rpm_rounded; } /* 300 kbps @ 360 rpm = 250 kbps @ 200 rpm */ if ((br == 300) && (rpm == 360)) { br = 250; rpm = 300; } switch (br) { case 500: temp_side_flags = 0; break; case 300: temp_side_flags = 1; break; case 250: default: temp_side_flags = 2; break; case 1000: temp_side_flags = 3; break; } if (rpm == 360) temp_side_flags |= 0x20; /* * Set the encoding value to match that provided by the FDC. * Then if it's wrong, it will sector not found anyway. */ temp_side_flags |= 0x08; dev->side_flags[side] = temp_side_flags; } static uint16_t side_flags(int drive) { mfm_t *dev = mfm[drive]; int side; side = fdd_get_head(drive); return dev->side_flags[side]; } static uint32_t get_raw_size(int drive, int side) { mfm_t *dev = mfm[drive]; int track_index, is_300_rpm; int br = 250, rpm = 300; if (dev->hdr.if_type & 0x80) { track_index = get_adv_track_index(drive, side, dev->cur_track); get_adv_track_bitrate(drive, 0, 0, &br, &rpm); } else { track_index = get_track_index(drive, side, dev->cur_track); br = dev->br_rounded; rpm = dev->rpm_rounded; } is_300_rpm = (rpm == 300); if (track_index == -1) { mfm_log("MFM: Unable to find track (%i, %i)\n", dev->cur_track, side); switch (br) { case 250: default: return is_300_rpm ? 100000 : 83333; case 300: return is_300_rpm ? 120000 : 100000; case 500: return is_300_rpm ? 200000 : 166666; case 1000: return is_300_rpm ? 400000 : 333333; } } /* Bit 7 on - my extension of the HxC MFM format to output exact bitcell counts for each track instead of rounded byte counts. */ if (dev->hdr.if_type & 0x80) return dev->adv_tracks[track_index].track_size; else return dev->tracks[track_index].track_size * 8; } static int32_t extra_bit_cells(int drive, int side) { return (int32_t) get_raw_size(drive, side); } static uint16_t * encoded_data(int drive, int side) { mfm_t *dev = mfm[drive]; return ((uint16_t *) dev->track_data[side]); } void mfm_read_side(int drive, int side) { mfm_t *dev = mfm[drive]; int track_index, track_size; int track_bytes, ret; if (dev->hdr.if_type & 0x80) track_index = get_adv_track_index(drive, side, dev->cur_track); else track_index = get_track_index(drive, side, dev->cur_track); track_size = get_raw_size(drive, side); track_bytes = track_size >> 3; if (track_size & 0x07) track_bytes++; if (track_index == -1) memset(dev->track_data[side], 0x00, track_bytes); else { if (dev->hdr.if_type & 0x80) ret = fseek(dev->f, dev->adv_tracks[track_index].track_offset, SEEK_SET); else ret = fseek(dev->f, dev->tracks[track_index].track_offset, SEEK_SET); if (ret == -1) fatal("mfm_read_side(): Error seeking to the beginning of the file\n"); if (fread(dev->track_data[side], 1, track_bytes, dev->f) != track_bytes) fatal("mfm_read_side(): Error reading track bytes\n"); } mfm_log("drive = %i, side = %i, dev->cur_track = %i, track_index = %i, track_size = %i\n", drive, side, dev->cur_track, track_index, track_size); } void mfm_seek(int drive, int track) { mfm_t *dev = mfm[drive]; mfm_log("mfm_seek(%i, %i)\n", drive, track); if (fdd_doublestep_40(drive)) { if (dev->hdr.tracks_no <= 43) track /= 2; } dev->cur_track = track; d86f_set_cur_track(drive, track); if (dev->f == NULL) return; if (track < 0) track = 0; mfm_read_side(drive, 0); mfm_read_side(drive, 1); set_side_flags(drive, 0); set_side_flags(drive, 1); } void mfm_load(int drive, char *fn) { mfm_t *dev; double dbr; int i, size; writeprot[drive] = fwriteprot[drive] = 1; /* Allocate a drive block. */ dev = (mfm_t *) malloc(sizeof(mfm_t)); memset(dev, 0x00, sizeof(mfm_t)); dev->f = plat_fopen(fn, "rb"); if (dev->f == NULL) { free(dev); memset(floppyfns[drive], 0, sizeof(floppyfns[drive])); return; } d86f_unregister(drive); /* Read the header. */ size = sizeof(mfm_header_t); if (fread(&dev->hdr, 1, size, dev->f) != size) fatal("mfm_load(): Error reading header\n"); /* Calculate tracks * sides, allocate the tracks array, and read it. */ dev->total_tracks = dev->hdr.tracks_no * dev->hdr.sides_no; if (dev->hdr.if_type & 0x80) { dev->adv_tracks = (mfm_adv_track_t *) malloc(dev->total_tracks * sizeof(mfm_adv_track_t)); size = dev->total_tracks * sizeof(mfm_adv_track_t); if (fread(dev->adv_tracks, 1, size, dev->f) != size) fatal("mfm_load(): Error reading advanced tracks\n"); } else { dev->tracks = (mfm_track_t *) malloc(dev->total_tracks * sizeof(mfm_track_t)); size = dev->total_tracks * sizeof(mfm_track_t); if (fread(dev->tracks, 1, size, dev->f) != size) fatal("mfm_load(): Error reading tracks\n"); } /* The chances of finding a HxC MFM image of a single-sided thin track disk are much smaller than the chances of finding a HxC MFM image incorrectly converted from a SCP image, erroneously indicating 1 side and 80+ tracks instead of 2 sides and <= 43 tracks, so if we have detected such an image, convert the track numbers. */ if ((dev->hdr.tracks_no > 43) && (dev->hdr.sides_no == 1)) { dev->hdr.tracks_no >>= 1; dev->hdr.sides_no <<= 1; for (i = 0; i < dev->total_tracks; i++) { if (dev->hdr.if_type & 0x80) { dev->adv_tracks[i].side_no <<= 1; dev->adv_tracks[i].side_no |= (dev->adv_tracks[i].track_no & 1); dev->adv_tracks[i].track_no >>= 1; } else { dev->tracks[i].side_no <<= 1; dev->tracks[i].side_no |= (dev->tracks[i].track_no & 1); dev->tracks[i].track_no >>= 1; } } } if (!(dev->hdr.if_type & 0x80)) { dbr = round(((double) dev->hdr.bit_rate) / 50.0) * 50.0; dev->br_rounded = (int) dbr; mfm_log("Rounded bit rate: %i kbps\n", dev->br_rounded); dbr = round(((double) dev->hdr.rpm) / 60.0) * 60.0; dev->rpm_rounded = (int) dbr; mfm_log("Rounded RPM: %i kbps\n", dev->rpm_rounded); } /* Set up the drive unit. */ mfm[drive] = dev; set_disk_flags(drive); /* Attach this format to the D86F engine. */ d86f_handler[drive].disk_flags = disk_flags; d86f_handler[drive].side_flags = side_flags; d86f_handler[drive].writeback = null_writeback; d86f_handler[drive].set_sector = null_set_sector; d86f_handler[drive].write_data = null_write_data; d86f_handler[drive].format_conditions = null_format_conditions; d86f_handler[drive].extra_bit_cells = extra_bit_cells; d86f_handler[drive].encoded_data = encoded_data; d86f_handler[drive].read_revolution = common_read_revolution; d86f_handler[drive].index_hole_pos = null_index_hole_pos; d86f_handler[drive].get_raw_size = get_raw_size; d86f_handler[drive].check_crc = 1; d86f_set_version(drive, D86FVER); d86f_common_handlers(drive); drives[drive].seek = mfm_seek; mfm_log("Loaded as MFM\n"); } void mfm_close(int drive) { mfm_t *dev = mfm[drive]; if (dev == NULL) return; d86f_unregister(drive); drives[drive].seek = NULL; if (dev->tracks) free(dev->tracks); if (dev->adv_tracks) free(dev->adv_tracks); if (dev->f) fclose(dev->f); /* Release the memory. */ free(dev); mfm[drive] = NULL; } void mfm_set_fdc(void *fdc) { mfm_fdc = (fdc_t *) fdc; }