/* _______ ____ __ ___ ___ * \ _ \ \ / \ / \ \ / / ' ' ' * | | \ \ | | || | \/ | . . * | | | | | | || ||\ /| | * | | | | | | || || \/ | | ' ' ' * | | | | | | || || | | . . * | |_/ / \ \__// || | | * /_______/ynamic \____/niversal /__\ /____\usic /| . . ibliotheque * / \ * / . \ * reads3m.c - Code to read a ScreamTracker 3 / / \ \ * module from an open file. | < / \_ * | \/ /\ / * By entheh. \_ / > / * | \ / / * | ' / * \__/ */ // IT_STEREO... :o #include #include #include "dumb.h" #include "internal/it.h" //#define S3M_BROKEN_OVERLAPPED_SAMPLES /** WARNING: this is duplicated in itread.c */ static int it_seek(DUMBFILE *f, long offset) { long pos = dumbfile_pos(f); if (pos > offset) { return -1; } if (pos < offset) if (dumbfile_skip(f, offset - pos)) return -1; return 0; } static int it_s3m_read_sample_header(IT_SAMPLE *sample, long *offset, unsigned char *pack, int cwtv, DUMBFILE *f) { unsigned char type; int flags; type = dumbfile_getc(f); dumbfile_getnc(sample->filename, 12, f); sample->filename[12] = 0; if (type > 1) { /** WARNING: no adlib support */ dumbfile_skip(f, 3 + 12 + 1 + 1 + 2 + 2 + 2 + 12); dumbfile_getnc(sample->name, 28, f); sample->name[28] = 0; dumbfile_skip(f, 4); sample->flags &= ~IT_SAMPLE_EXISTS; return -1; // return error so that another plugin could pick that file up } *offset = dumbfile_getc(f) << 20; *offset += dumbfile_igetw(f) << 4; sample->length = dumbfile_igetl(f); sample->loop_start = dumbfile_igetl(f); sample->loop_end = dumbfile_igetl(f); sample->default_volume = dumbfile_getc(f); dumbfile_skip(f, 1); flags = dumbfile_getc(f); if (flags < 0 || (flags != 0 && flags != 4)) /* Sample is packed apparently (or error reading from file). We don't * know how to read packed samples. */ return -1; *pack = flags; flags = dumbfile_getc(f); sample->C5_speed = dumbfile_igetl(f) << 1; /* Skip four unused bytes and three internal variables. */ dumbfile_skip(f, 4+2+2+4); dumbfile_getnc(sample->name, 28, f); sample->name[28] = 0; if (type == 0 || sample->length <= 0) { /* Looks like no-existy. Anyway, there's for sure no 'SCRS' ... */ sample->flags &= ~IT_SAMPLE_EXISTS; return dumbfile_error(f); } if (dumbfile_mgetl(f) != DUMB_ID('S','C','R','S')) return -1; sample->global_volume = 64; sample->flags = IT_SAMPLE_EXISTS; if (flags & 1) sample->flags |= IT_SAMPLE_LOOP; /* The ST3 TECH.DOC is unclear on this, but IMAGO Orpheus is not. Piece of crap. */ if (flags & 2) { sample->flags |= IT_SAMPLE_STEREO; if ((cwtv & 0xF000) == 0x2000) { sample->length >>= 1; sample->loop_start >>= 1; sample->loop_end >>= 1; } } if (flags & 4) { sample->flags |= IT_SAMPLE_16BIT; if ((cwtv & 0xF000) == 0x2000) { sample->length >>= 1; sample->loop_start >>= 1; sample->loop_end >>= 1; } } sample->default_pan = 0; // 0 = don't use, or 160 = centre? if (sample->flags & IT_SAMPLE_LOOP) { if ((unsigned int)sample->loop_end > (unsigned int)sample->length) /*sample->flags &= ~IT_SAMPLE_LOOP;*/ sample->loop_end = sample->length; else if ((unsigned int)sample->loop_start >= (unsigned int)sample->loop_end) sample->flags &= ~IT_SAMPLE_LOOP; else /* ScreamTracker seems not to save what comes after the loop end * point, but rather to assume it is a duplicate of what comes at * the loop start point. I am not completely sure of this though. * It is easy to evade; simply truncate the sample. */ sample->length = sample->loop_end; } //Do we need to set all these? sample->vibrato_speed = 0; sample->vibrato_depth = 0; sample->vibrato_rate = 0; sample->vibrato_waveform = IT_VIBRATO_SINE; sample->finetune = 0; sample->max_resampling_quality = -1; return dumbfile_error(f); } static int it_s3m_read_sample_data(IT_SAMPLE *sample, int ffi, unsigned char pack, DUMBFILE *f) { long n; long datasize = sample->length; if (sample->flags & IT_SAMPLE_STEREO) datasize <<= 1; sample->data = malloc(datasize * (sample->flags & IT_SAMPLE_16BIT ? 2 : 1)); if (!sample->data) return -1; if (pack == 4) { if (_dumb_it_read_sample_data_adpcm4(sample, f) < 0) return -1; } else if (sample->flags & IT_SAMPLE_STEREO) { if (sample->flags & IT_SAMPLE_16BIT) { for (n = 0; n < datasize; n += 2) ((short *)sample->data)[n] = dumbfile_igetw(f); for (n = 1; n < datasize; n += 2) ((short *)sample->data)[n] = dumbfile_igetw(f); } else { for (n = 0; n < datasize; n += 2) ((signed char *)sample->data)[n] = dumbfile_getc(f); for (n = 1; n < datasize; n += 2) ((signed char *)sample->data)[n] = dumbfile_getc(f); } } else if (sample->flags & IT_SAMPLE_16BIT) for (n = 0; n < sample->length; n++) ((short *)sample->data)[n] = dumbfile_igetw(f); else for (n = 0; n < sample->length; n++) ((signed char *)sample->data)[n] = dumbfile_getc(f); if (dumbfile_error(f)) return -1; if (ffi != 1) { /* Convert to signed. */ if (sample->flags & IT_SAMPLE_16BIT) for (n = 0; n < datasize; n++) ((short *)sample->data)[n] ^= 0x8000; else for (n = 0; n < datasize; n++) ((signed char *)sample->data)[n] ^= 0x80; } return 0; } static int it_s3m_read_pattern(IT_PATTERN *pattern, DUMBFILE *f, unsigned char *buffer, int maxlen) { int length; int buflen = 0; int bufpos = 0; IT_ENTRY *entry; unsigned char channel; /* Haha, this is hilarious! * * Well, after some experimentation, it seems that different S3M writers * define the format in different ways. The S3M docs say that the first * two bytes hold the "length of [the] packed pattern", and the packed * pattern data follow. Judging by the contents of ARMANI.S3M, packaged * with ScreamTracker itself, the measure of length _includes_ the two * bytes used to store the length; in other words, we should read * (length - 2) more bytes. However, aryx.s3m, packaged with ModPlug * Tracker, excludes these two bytes, so (length) more bytes must be * read. * * Call me crazy, but I just find it insanely funny that the format was * misunderstood in this way :D * * Now we can't just risk reading two extra bytes, because then we * overshoot, and DUMBFILEs don't support backward seeking (for a good * reason). Luckily, there is a way. We can read the data little by * little, and stop when we have 64 rows in memory. Provided we protect * against buffer overflow, this method should work with all sensibly * written S3M files. If you find one for which it does not work, please * let me know at entheh@users.sf.net so I can look at it. */ /* Discard the length. */ /* read at most length bytes, in case of retarded crap */ length = dumbfile_igetw(f); if (maxlen) { maxlen -= 2; if (length > maxlen) length = maxlen; } if (dumbfile_error(f) || !length) return -1; pattern->n_rows = 0; pattern->n_entries = 0; /* Read in the pattern data, little by little, and work out how many * entries we need room for. Sorry, but this is just so funny... */ for (;;) { unsigned char b = buffer[buflen++] = dumbfile_getc(f); #if 1 static const unsigned char used[8] = {0, 2, 1, 3, 2, 4, 3, 5}; channel = b & 31; b >>= 5; pattern->n_entries++; if (b) { if (buflen + used[b] >= 65536) return -1; if (buflen + used[b] <= length) dumbfile_getnc(buffer + buflen, used[b], f); else memset(buffer + buflen, 0, used[b]); buflen += used[b]; } else { /* End of row */ if (++pattern->n_rows == 64) break; if (buflen >= 65536) return -1; } #else if (b == 0) { /* End of row */ pattern->n_entries++; if (++pattern->n_rows == 64) break; if (buflen >= 65536) return -1; } else { static const unsigned char used[8] = {0, 2, 1, 3, 2, 4, 3, 5}; channel = b & 31; b >>= 5; if (b) { pattern->n_entries++; if (buflen + used[b] >= 65536) return -1; dumbfile_getnc(buffer + buflen, used[b], f); buflen += used[b]; } } #endif /* We have ensured that buflen < 65536 at this point, so it is safe * to iterate and read at least one more byte without checking. * However, now would be a good time to check for errors reading from * the file. */ if (dumbfile_error(f)) return -1; /* Great. We ran out of data, but there should be data for more rows. * Fill the rest with null data... */ if (buflen >= length && pattern->n_rows < 64) { while (pattern->n_rows < 64) { if (buflen >= 65536) return -1; buffer[buflen++] = 0; pattern->n_entries++; pattern->n_rows++; } break; } } pattern->entry = malloc(pattern->n_entries * sizeof(*pattern->entry)); if (!pattern->entry) return -1; entry = pattern->entry; while (bufpos < buflen) { unsigned char b = buffer[bufpos++]; #if 1 if (!(b & ~31)) #else if (b == 0) #endif { /* End of row */ IT_SET_END_ROW(entry); entry++; continue; } channel = b & 31; if (b & 224) { entry->mask = 0; entry->channel = channel; if (b & 32) { unsigned char n = buffer[bufpos++]; if (n != 255) { if (n == 254) entry->note = IT_NOTE_CUT; else entry->note = (n >> 4) * 12 + (n & 15); entry->mask |= IT_ENTRY_NOTE; } entry->instrument = buffer[bufpos++]; if (entry->instrument) entry->mask |= IT_ENTRY_INSTRUMENT; } if (b & 64) { entry->volpan = buffer[bufpos++]; if (entry->volpan != 255) entry->mask |= IT_ENTRY_VOLPAN; } if (b & 128) { entry->effect = buffer[bufpos++]; entry->effectvalue = buffer[bufpos++]; // XXX woot if (entry->effect && entry->effect < IT_MIDI_MACRO /*!= 255*/) { entry->mask |= IT_ENTRY_EFFECT; switch (entry->effect) { case IT_BREAK_TO_ROW: entry->effectvalue -= (entry->effectvalue >> 4) * 6; break; case IT_SET_CHANNEL_VOLUME: case IT_CHANNEL_VOLUME_SLIDE: case IT_PANNING_SLIDE: case IT_GLOBAL_VOLUME_SLIDE: case IT_PANBRELLO: case IT_MIDI_MACRO: entry->mask &= ~IT_ENTRY_EFFECT; break; case IT_S: switch (entry->effectvalue >> 4) { case IT_S_SET_PANBRELLO_WAVEFORM: case IT_S_FINE_PATTERN_DELAY: case IT_S7: case IT_S_SET_SURROUND_SOUND: case IT_S_SET_MIDI_MACRO: entry->mask &= ~IT_ENTRY_EFFECT; break; } break; } } /** WARNING: ARGH! CONVERT TEH EFFECTS!@~ */ } entry++; } } ASSERT(entry == pattern->entry + pattern->n_entries); return 0; } /** WARNING: this is duplicated in itread.c - also bad practice to use the same struct name unless they are unified in a header */ /* Currently we assume the sample data are stored after the sample headers in * module files. This assumption may be unjustified; let me know if you have * trouble. */ #define S3M_COMPONENT_INSTRUMENT 1 #define S3M_COMPONENT_PATTERN 2 #define S3M_COMPONENT_SAMPLE 3 typedef struct S3M_COMPONENT { unsigned char type; unsigned char n; long offset; short sampfirst; /* component[sampfirst] = first sample data after this */ short sampnext; /* sampnext is used to create linked lists of sample data */ } S3M_COMPONENT; static int s3m_component_compare(const void *e1, const void *e2) { return ((const S3M_COMPONENT *)e1)->offset - ((const S3M_COMPONENT *)e2)->offset; } static DUMB_IT_SIGDATA *it_s3m_load_sigdata(DUMBFILE *f, int * cwtv) { DUMB_IT_SIGDATA *sigdata; int flags, ffi; int default_pan_present; int master_volume; unsigned char sample_pack[256]; S3M_COMPONENT *component; int n_components = 0; int n; unsigned char *buffer; sigdata = malloc(sizeof(*sigdata)); if (!sigdata) return NULL; dumbfile_getnc(sigdata->name, 28, f); sigdata->name[28] = 0; n = dumbfile_getc(f); if (n != 0x1A && n != 0) { free(sigdata); return NULL; } if (dumbfile_getc(f) != 16) { free(sigdata); return NULL; } dumbfile_skip(f, 2); sigdata->song_message = NULL; sigdata->order = NULL; sigdata->instrument = NULL; sigdata->sample = NULL; sigdata->pattern = NULL; sigdata->midi = NULL; sigdata->checkpoint = NULL; sigdata->n_orders = dumbfile_igetw(f); sigdata->n_instruments = 0; sigdata->n_samples = dumbfile_igetw(f); sigdata->n_patterns = dumbfile_igetw(f); if (dumbfile_error(f) || sigdata->n_orders <= 0 || sigdata->n_samples > 256 || sigdata->n_patterns > 256) { _dumb_it_unload_sigdata(sigdata); return NULL; } sigdata->order = malloc(sigdata->n_orders); if (!sigdata->order) { _dumb_it_unload_sigdata(sigdata); return NULL; } if (sigdata->n_samples) { sigdata->sample = malloc(sigdata->n_samples * sizeof(*sigdata->sample)); if (!sigdata->sample) { _dumb_it_unload_sigdata(sigdata); return NULL; } for (n = 0; n < sigdata->n_samples; n++) sigdata->sample[n].data = NULL; } if (sigdata->n_patterns) { sigdata->pattern = malloc(sigdata->n_patterns * sizeof(*sigdata->pattern)); if (!sigdata->pattern) { _dumb_it_unload_sigdata(sigdata); return NULL; } for (n = 0; n < sigdata->n_patterns; n++) sigdata->pattern[n].entry = NULL; } flags = dumbfile_igetw(f); *cwtv = dumbfile_igetw(f); if (*cwtv == 0x1300) { /** WARNING: volume slides on every frame */ } ffi = dumbfile_igetw(f); /** WARNING: which ones? */ sigdata->flags = IT_OLD_EFFECTS | IT_COMPATIBLE_GXX | IT_WAS_AN_S3M; if (dumbfile_mgetl(f) != DUMB_ID('S','C','R','M')) { _dumb_it_unload_sigdata(sigdata); return NULL; } sigdata->global_volume = dumbfile_getc(f) << 1; if ( !sigdata->global_volume || sigdata->global_volume > 128 ) sigdata->global_volume = 128; sigdata->speed = dumbfile_getc(f); if (sigdata->speed == 0) sigdata->speed = 6; // Should we? What about tempo? sigdata->tempo = dumbfile_getc(f); master_volume = dumbfile_getc(f); // 7 bits; +128 for stereo //what do we do with master_volume? it's not the same as mixing volume... sigdata->mixing_volume = 48; if (master_volume & 128) sigdata->flags |= IT_STEREO; /* Skip GUS Ultra Click Removal byte. */ dumbfile_getc(f); default_pan_present = dumbfile_getc(f); dumbfile_skip(f, 8); /* Skip Special Custom Data Pointer. */ /** WARNING: investigate this? */ dumbfile_igetw(f); sigdata->n_pchannels = 0; /* Channel settings for 32 channels, 255=unused, +128=disabled */ { int i; for (i = 0; i < 32; i++) { int c = dumbfile_getc(f); if (!(c & (128 | 16))) { /* +128=disabled, +16=Adlib */ if (sigdata->n_pchannels < i + 1) sigdata->n_pchannels = i + 1; sigdata->channel_volume[i] = 64; sigdata->channel_pan[i] = c & 8 ? 12 : 3; /** WARNING: ah, but it should be 7 for mono... */ } else { /** WARNING: this could be improved if we support channel muting... */ sigdata->channel_volume[i] = 0; sigdata->channel_pan[i] = 7; } } } /* Orders, byte each, length = sigdata->n_orders (should be even) */ dumbfile_getnc(sigdata->order, sigdata->n_orders, f); sigdata->restart_position = 0; component = malloc(768*sizeof(*component)); if (!component) { _dumb_it_unload_sigdata(sigdata); return NULL; } for (n = 0; n < sigdata->n_samples; n++) { component[n_components].type = S3M_COMPONENT_SAMPLE; component[n_components].n = n; component[n_components].offset = dumbfile_igetw(f) << 4; component[n_components].sampfirst = -1; n_components++; } for (n = 0; n < sigdata->n_patterns; n++) { long offset = dumbfile_igetw(f) << 4; if (offset) { component[n_components].type = S3M_COMPONENT_PATTERN; component[n_components].n = n; component[n_components].offset = offset; component[n_components].sampfirst = -1; n_components++; } else { /** WARNING: Empty 64-row pattern ... ? (this does happen!) */ sigdata->pattern[n].n_rows = 64; sigdata->pattern[n].n_entries = 0; } } qsort(component, n_components, sizeof(S3M_COMPONENT), &s3m_component_compare); /* I found a really dumb S3M file that claimed to contain default pan * data but didn't contain any. Programs would load it by reading part of * the first instrument header, assuming the data to be default pan * positions, and then rereading the instrument module. We cannot do this * without obfuscating the file input model, so we insert an extra check * here that we won't overrun the start of the first component. */ if (default_pan_present == 252 && component[0].offset >= dumbfile_pos(f) + 32) { /* Channel default pan positions */ int i; for (i = 0; i < 32; i++) { int c = dumbfile_getc(f); if (c & 32) sigdata->channel_pan[i] = c & 15; } } { int i; for (i = 0; i < 32; i++) { sigdata->channel_pan[i] -= (sigdata->channel_pan[i] & 8) >> 3; sigdata->channel_pan[i] = ((int)sigdata->channel_pan[i] << 5) / 7; } } sigdata->pan_separation = 128; if (dumbfile_error(f)) { free(component); _dumb_it_unload_sigdata(sigdata); return NULL; } buffer = malloc(65536); if (!buffer) { free(component); _dumb_it_unload_sigdata(sigdata); return NULL; } /* Voila, I must deal with a very dumb S3M myself. This file refers to the same file offset twice * for two different patterns. Solution: Eliminate it. */ for (n = 0; n < n_components; n++) { if (component[n].type == S3M_COMPONENT_PATTERN) { int m; for (m = n + 1; m < n_components; m++) { if (component[m].type == S3M_COMPONENT_PATTERN) { if (component[n].offset == component[m].offset) { int o, pattern; pattern = component[m].n; n_components--; for (o = m; o < n_components; o++) { component[o] = component[o + 1]; } for (o = 0; o < sigdata->n_orders; o++) { if (sigdata->order[o] == pattern) { sigdata->order[o] = component[n].n; } } sigdata->pattern[pattern].n_rows = 64; sigdata->pattern[pattern].n_entries = 0; m--; } else break; } } } } for (n = 0; n < n_components; n++) { long offset; int m; #ifdef S3M_BROKEN_OVERLAPPED_SAMPLES int last; #endif if (it_seek(f, component[n].offset)) { free(buffer); free(component); _dumb_it_unload_sigdata(sigdata); return NULL; } switch (component[n].type) { case S3M_COMPONENT_PATTERN: if (it_s3m_read_pattern(&sigdata->pattern[component[n].n], f, buffer, (n + 1 < n_components) ? (component[n+1].offset - component[n].offset) : 0)) { free(buffer); free(component); _dumb_it_unload_sigdata(sigdata); return NULL; } break; case S3M_COMPONENT_SAMPLE: { int err = it_s3m_read_sample_header(&sigdata->sample[component[n].n], &offset, &sample_pack[component[n].n], *cwtv, f); if (err) { free(buffer); free(component); _dumb_it_unload_sigdata(sigdata); return NULL; } } if (sigdata->sample[component[n].n].flags & IT_SAMPLE_EXISTS) { short *sample; for (m = n + 1; m < n_components; m++) if (component[m].offset > offset) break; m--; sample = &component[m].sampfirst; while (*sample >= 0 && component[*sample].offset <= offset) sample = &component[*sample].sampnext; component[n].sampnext = *sample; *sample = n; component[n].offset = offset; } } m = component[n].sampfirst; #ifdef S3M_BROKEN_OVERLAPPED_SAMPLES last = -1; #endif while (m >= 0) { // XXX #ifdef S3M_BROKEN_OVERLAPPED_SAMPLES if ( last >= 0 ) { if ( dumbfile_pos( f ) > component[m].offset ) { IT_SAMPLE * s1 = &sigdata->sample[component[last].n]; IT_SAMPLE * s2 = &sigdata->sample[component[m].n]; if ( ( s1->flags | s2->flags ) & ( IT_SAMPLE_16BIT | IT_SAMPLE_STEREO ) ) { free(buffer); free(component); _dumb_it_unload_sigdata(sigdata); return NULL; } if ( component[m].offset >= component[last].offset && component[m].offset + s2->length <= component[last].offset + s1->length ) { s2->left = malloc( s2->length ); if ( ! s2->left ) { free(buffer); free(component); _dumb_it_unload_sigdata(sigdata); return NULL; } memcpy( s2->left, ( const char * ) s1->left + component[m].offset - component[last].offset, s2->length ); last = -1; } } } else last = 0; if ( last >= 0 ) { #endif if (it_seek(f, component[m].offset)) { free(buffer); free(component); _dumb_it_unload_sigdata(sigdata); return NULL; } if (it_s3m_read_sample_data(&sigdata->sample[component[m].n], ffi, sample_pack[component[m].n], f)) { free(buffer); free(component); _dumb_it_unload_sigdata(sigdata); return NULL; } #ifdef S3M_BROKEN_OVERLAPPED_SAMPLES last = m; } #endif m = component[m].sampnext; } } free(buffer); free(component); _dumb_it_fix_invalid_orders(sigdata); return sigdata; } static char hexdigit(int in) { if (in < 10) return in + '0'; else return in + 'A' - 10; } DUH *dumb_read_s3m_quick(DUMBFILE *f) { sigdata_t *sigdata; int cwtv; DUH_SIGTYPE_DESC *descptr = &_dumb_sigtype_it; sigdata = it_s3m_load_sigdata(f, &cwtv); if (!sigdata) return NULL; { char version[8]; const char *tag[3][2]; tag[0][0] = "TITLE"; tag[0][1] = ((DUMB_IT_SIGDATA *)sigdata)->name; tag[1][0] = "FORMAT"; tag[1][1] = "S3M"; tag[2][0] = "TRACKERVERSION"; version[0] = hexdigit((cwtv >> 8) & 15); version[1] = '.'; version[2] = hexdigit((cwtv >> 4) & 15); version[3] = hexdigit(cwtv & 15); version[4] = 0; tag[2][1] = (const char *) &version; return make_duh(-1, 3, (const char *const (*)[2])tag, 1, &descptr, &sigdata); } }