ref: 74414b91d904eb3c7c9fa084695178c1387cd7d0
dir: /src/it/itread.c/
/* _______ ____ __ ___ ___ * \ _ \ \ / \ / \ \ / / ' ' ' * | | \ \ | | || | \/ | . . * | | | | | | || ||\ /| | * | | | | | | || || \/ | | ' ' ' * | | | | | | || || | | . . * | |_/ / \ \__// || | | * /_______/ynamic \____/niversal /__\ /____\usic /| . . ibliotheque * / \ * / . \ * itread.c - Code to read an Impulse Tracker / / \ \ * module from an open file. | < / \_ * | \/ /\ / * Based on the loader from an IT player by Bob. \_ / > / * Adapted for DUMB by entheh. | \ / / * | ' / * \__/ */ #include <stdlib.h> #include <string.h> //might not be necessary later; required for memset #include "dumb.h" #include "internal/it.h" #ifndef min #define min(a, b) (((a) < (b)) ? (a) : (b)) #endif //#define INVESTIGATE_OLD_INSTRUMENTS typedef unsigned char byte; typedef unsigned short word; typedef unsigned long dword; typedef struct readblock_crap readblock_crap; struct readblock_crap { unsigned char *sourcebuf; unsigned char *sourcepos; unsigned char *sourceend; int rembits; }; static int readblock(DUMBFILE *f, readblock_crap *crap) { long size; int c; size = dumbfile_igetw(f); if (size < 0) return (int)size; crap->sourcebuf = malloc(size); if (!crap->sourcebuf) return -1; c = (int)dumbfile_getnc((char *)crap->sourcebuf, size, f); if (c < size) { free(crap->sourcebuf); crap->sourcebuf = NULL; return -1; } crap->sourcepos = crap->sourcebuf; crap->sourceend = crap->sourcebuf + size; crap->rembits = 8; return 0; } static void freeblock(readblock_crap *crap) { free(crap->sourcebuf); crap->sourcebuf = NULL; } static int readbits(int bitwidth, readblock_crap *crap) { int val = 0; int b = 0; if (crap->sourcepos >= crap->sourceend) return val; while (bitwidth > crap->rembits) { val |= *crap->sourcepos++ << b; if (crap->sourcepos >= crap->sourceend) return val; b += crap->rembits; bitwidth -= crap->rembits; crap->rembits = 8; } val |= (*crap->sourcepos & ((1 << bitwidth) - 1)) << b; *crap->sourcepos >>= bitwidth; crap->rembits -= bitwidth; return val; } /** WARNING - do we even need to pass `right`? */ /** WARNING - why bother memsetting at all? The whole array is written... */ // if we do memset, dumb_silence() would be neater... static int decompress8(DUMBFILE *f, signed char *data, int len, int it215, int stereo) { int blocklen, blockpos; byte bitwidth; word val; signed char d1, d2; readblock_crap crap; memset(&crap, 0, sizeof(crap)); for (blocklen = 0, blockpos = 0; blocklen < len; blocklen++, blockpos += 1 + stereo) data[blockpos] = 0; while (len > 0) { // Read a block of compressed data: if (readblock(f, &crap)) return -1; // Set up a few variables blocklen = (len < 0x8000) ? len : 0x8000; // Max block length is 0x8000 bytes blockpos = 0; bitwidth = 9; d1 = d2 = 0; // Start the decompression: while (blockpos < blocklen) { // Read a value: val = (word)readbits(bitwidth, &crap); // Check for bit width change: if (bitwidth < 7) { // Method 1: if (val == (1 << (bitwidth - 1))) { val = (word)readbits(3, &crap) + 1; bitwidth = (val < bitwidth) ? val : val + 1; continue; } } else if (bitwidth < 9) { // Method 2 byte border = (0xFF >> (9 - bitwidth)) - 4; if (val > border && val <= (border + 8)) { val -= border; bitwidth = (val < bitwidth) ? val : val + 1; continue; } } else if (bitwidth == 9) { // Method 3 if (val & 0x100) { bitwidth = (val + 1) & 0xFF; continue; } } else { // Illegal width, abort ? freeblock(&crap); return -1; } // Expand the value to signed byte: { signed char v; // The sample value: if (bitwidth < 8) { byte shift = 8 - bitwidth; v = (val << shift); v >>= shift; } else v = (signed char)val; // And integrate the sample value //(It always has to end with integration doesn't it ? ;-) d1 += v; d2 += d1; } // Store ! /* Version 2.15 was an unofficial version with hacked compression * code. Yay, better compression :D */ *data++ = it215 ? d2 : d1; data += stereo; len--; blockpos++; } freeblock(&crap); } return 0; } static int decompress16(DUMBFILE *f, short *data, int len, int it215, int stereo) { int blocklen, blockpos; byte bitwidth; long val; signed short d1, d2; readblock_crap crap; memset(&crap, 0, sizeof(crap)); for (blocklen = 0, blockpos = 0; blocklen < len; blocklen++, blockpos += 1 + stereo) data[blockpos] = 0; while (len > 0) { // Read a block of compressed data: if (readblock(f, &crap)) return -1; // Set up a few variables blocklen = (len < 0x4000) ? len : 0x4000; // Max block length is 0x4000 bytes blockpos = 0; bitwidth = 17; d1 = d2 = 0; // Start the decompression: while (blockpos < blocklen) { val = readbits(bitwidth, &crap); // Check for bit width change: if (bitwidth < 7) { // Method 1: if (val == (1 << (bitwidth - 1))) { val = readbits(4, &crap) + 1; bitwidth = (val < bitwidth) ? val : val + 1; continue; } } else if (bitwidth < 17) { // Method 2 word border = (0xFFFF >> (17 - bitwidth)) - 8; if (val > border && val <= (border + 16)) { val -= border; bitwidth = val < bitwidth ? val : val + 1; continue; } } else if (bitwidth == 17) { // Method 3 if (val & 0x10000) { bitwidth = (val + 1) & 0xFF; continue; } } else { // Illegal width, abort ? freeblock(&crap); return -1; } // Expand the value to signed byte: { short v; // The sample value: if (bitwidth < 16) { byte shift = 16 - bitwidth; v = (short)(val << shift); v >>= shift; } else v = (short)val; // And integrate the sample value //(It always has to end with integration doesn't it ? ;-) d1 += v; d2 += d1; } // Store ! /* Version 2.15 was an unofficial version with hacked compression * code. Yay, better compression :D */ *data++ = it215 ? d2 : d1; data += stereo; len--; blockpos++; } freeblock(&crap); } return 0; } static int it_read_envelope(IT_ENVELOPE *envelope, DUMBFILE *f) { int n; envelope->flags = dumbfile_getc(f); envelope->n_nodes = dumbfile_getc(f); if (envelope->n_nodes > 25) { TRACE("IT error: wrong number of envelope nodes (%d)\n", envelope->n_nodes); envelope->n_nodes = 0; return -1; } envelope->loop_start = dumbfile_getc(f); envelope->loop_end = dumbfile_getc(f); envelope->sus_loop_start = dumbfile_getc(f); envelope->sus_loop_end = dumbfile_getc(f); for (n = 0; n < envelope->n_nodes; n++) { envelope->node_y[n] = dumbfile_getc(f); envelope->node_t[n] = dumbfile_igetw(f); } dumbfile_skip(f, 75 - envelope->n_nodes * 3 + 1); if (envelope->n_nodes <= 0) envelope->flags &= ~IT_ENVELOPE_ON; else { if (envelope->loop_end >= envelope->n_nodes || envelope->loop_start > envelope->loop_end) envelope->flags &= ~IT_ENVELOPE_LOOP_ON; if (envelope->sus_loop_end >= envelope->n_nodes || envelope->sus_loop_start > envelope->sus_loop_end) envelope->flags &= ~IT_ENVELOPE_SUSTAIN_LOOP; } return dumbfile_error(f); } static int it_read_old_instrument(IT_INSTRUMENT *instrument, DUMBFILE *f) { int n; /*if (dumbfile_mgetl(f) != IT_INSTRUMENT_SIGNATURE) return -1;*/ // XXX dumbfile_skip(f, 4); dumbfile_getnc((char *)instrument->filename, 13, f); instrument->filename[13] = 0; instrument->volume_envelope.flags = dumbfile_getc(f); instrument->volume_envelope.loop_start = dumbfile_getc(f); instrument->volume_envelope.loop_end = dumbfile_getc(f); instrument->volume_envelope.sus_loop_start = dumbfile_getc(f); instrument->volume_envelope.sus_loop_end = dumbfile_getc(f); /* Skip two unused bytes. */ dumbfile_skip(f, 2); /* In the old instrument format, fadeout ranges from 0 to 64, and is * subtracted at intervals from a value starting at 512. In the new * format, all these values are doubled. Therefore we double when loading * from the old instrument format - that way we don't have to think about * it later. */ instrument->fadeout = dumbfile_igetw(f) << 1; instrument->new_note_action = dumbfile_getc(f); instrument->dup_check_type = dumbfile_getc(f); instrument->dup_check_action = DCA_NOTE_CUT; // This might be wrong! /** WARNING - what is the duplicate check action for old-style instruments? */ /* Skip Tracker Version and Number of Samples. These are only used in * separate instrument files. Also skip unused byte. */ dumbfile_skip(f, 4); dumbfile_getnc((char *)instrument->name, 26, f); instrument->name[26] = 0; /* Skip unused bytes following the Instrument Name. */ dumbfile_skip(f, 6); instrument->pp_separation = 0; instrument->pp_centre = 60; instrument->global_volume = 128; /** WARNING - should global_volume be 64 or something? */ instrument->default_pan = 32; /** WARNING - should default_pan be 128, meaning don`t use? */ instrument->random_volume = 0; instrument->random_pan = 0; for (n = 0; n < 120; n++) { instrument->map_note[n] = dumbfile_getc(f); instrument->map_sample[n] = dumbfile_getc(f); } /* Skip "Volume envelope (200 bytes)". */ // - need to know better what this is for though. dumbfile_skip(f, 200); #ifdef INVESTIGATE_OLD_INSTRUMENTS fprintf(stderr, "Inst %02d Env:", n); #endif for (n = 0; n < 25; n++) { instrument->volume_envelope.node_t[n] = dumbfile_getc(f); instrument->volume_envelope.node_y[n] = dumbfile_getc(f); #ifdef INVESTIGATE_OLD_INSTRUMENTS fprintf(stderr, " %d,%d", instrument->volume_envelope.node_t[n], instrument->volume_envelope.node_y[n]); #endif // This loop is unfinished, as we can probably escape from it before // the end if we want to. Hence the otherwise useless dumbfile_skip() // call below. } dumbfile_skip(f, 50 - (n << 1)); instrument->volume_envelope.n_nodes = n; #ifdef INVESTIGATE_OLD_INSTRUMENTS fprintf(stderr, "\n"); #endif if (dumbfile_error(f)) return -1; { IT_ENVELOPE *envelope = &instrument->volume_envelope; if (envelope->n_nodes <= 0) envelope->flags &= ~IT_ENVELOPE_ON; else { if (envelope->loop_end >= envelope->n_nodes || envelope->loop_start > envelope->loop_end) envelope->flags &= ~IT_ENVELOPE_LOOP_ON; if (envelope->sus_loop_end >= envelope->n_nodes || envelope->sus_loop_start > envelope->sus_loop_end) envelope->flags &= ~IT_ENVELOPE_SUSTAIN_LOOP; } } instrument->filter_cutoff = 127; instrument->filter_resonance = 0; instrument->pan_envelope.flags = 0; instrument->pitch_envelope.flags = 0; return 0; } static int it_read_instrument(IT_INSTRUMENT *instrument, DUMBFILE *f, int maxlen) { int n; long len; /*if (dumbfile_mgetl(f) != IT_INSTRUMENT_SIGNATURE) return -1;*/ // XXX if (maxlen) len = dumbfile_pos(f); else len = 0; dumbfile_skip(f, 4); dumbfile_getnc((char *)instrument->filename, 13, f); instrument->filename[13] = 0; instrument->new_note_action = dumbfile_getc(f); instrument->dup_check_type = dumbfile_getc(f); instrument->dup_check_action = dumbfile_getc(f); instrument->fadeout = dumbfile_igetw(f); instrument->pp_separation = dumbfile_getc(f); instrument->pp_centre = dumbfile_getc(f); instrument->global_volume = dumbfile_getc(f); instrument->default_pan = dumbfile_getc(f); instrument->random_volume = dumbfile_getc(f); instrument->random_pan = dumbfile_getc(f); /* Skip Tracker Version and Number of Samples. These are only used in * separate instrument files. Also skip unused byte. */ dumbfile_skip(f, 4); dumbfile_getnc((char *)instrument->name, 26, f); instrument->name[26] = 0; instrument->filter_cutoff = dumbfile_getc(f); instrument->filter_resonance = dumbfile_getc(f); /* Skip MIDI Channel, Program and Bank. */ // dumbfile_skip(f, 4); /*instrument->output = dumbfile_getc(f); if ( instrument->output > 16 ) { instrument->output -= 128; } else { instrument->output = 0; } dumbfile_skip(f, 3);*/ dumbfile_skip(f, 4); for (n = 0; n < 120; n++) { instrument->map_note[n] = dumbfile_getc(f); instrument->map_sample[n] = dumbfile_getc(f); } if (dumbfile_error(f)) return -1; if (it_read_envelope(&instrument->volume_envelope, f)) return -1; if (it_read_envelope(&instrument->pan_envelope, f)) return -1; if (it_read_envelope(&instrument->pitch_envelope, f)) return -1; if (maxlen) { len = dumbfile_pos(f) - len; if (maxlen - len < 124) return 0; } if (dumbfile_mgetl(f) == IT_MPTX_SIGNATURE) { for (n = 0; n < 120; n++) { instrument->map_sample[n] += dumbfile_getc(f) << 8; } if (dumbfile_error(f)) return -1; } /*if ( dumbfile_mgetl(f) == IT_INSM_SIGNATURE ) { long end = dumbfile_igetl(f); end += dumbfile_pos(f); while ( dumbfile_pos(f) < end ) { int chunkid = dumbfile_igetl(f); switch ( chunkid ) { case DUMB_ID('P','L','U','G'): instrument->output = dumbfile_getc(f); break; default: chunkid = chunkid / 0x100 + dumbfile_getc(f) * 0x1000000; break; } } if (dumbfile_error(f)) return -1; }*/ return 0; } static int it_read_sample_header(IT_SAMPLE *sample, unsigned char *convert, long *offset, DUMBFILE *f) { /* XXX if (dumbfile_mgetl(f) != IT_SAMPLE_SIGNATURE) return -1;*/ int hax = 0; long s = dumbfile_mgetl(f); if (s != IT_SAMPLE_SIGNATURE) { if (s == (IT_SAMPLE_SIGNATURE >> 16)) { s <<= 16; s |= dumbfile_mgetw(f); if (s != IT_SAMPLE_SIGNATURE) return -1; hax = 1; } } dumbfile_getnc((char *)sample->filename, 13, f); sample->filename[13] = 0; sample->global_volume = dumbfile_getc(f); sample->flags = dumbfile_getc(f); sample->default_volume = dumbfile_getc(f); dumbfile_getnc((char *)sample->name, 26, f); sample->name[26] = 0; *convert = dumbfile_getc(f); sample->default_pan = dumbfile_getc(f); sample->length = dumbfile_igetl(f); sample->loop_start = dumbfile_igetl(f); sample->loop_end = dumbfile_igetl(f); sample->C5_speed = dumbfile_igetl(f); sample->sus_loop_start = dumbfile_igetl(f); sample->sus_loop_end = dumbfile_igetl(f); #ifdef STEREO_SAMPLES_COUNT_AS_TWO if (sample->flags & IT_SAMPLE_STEREO) { sample->length >>= 1; sample->loop_start >>= 1; sample->loop_end >>= 1; sample->C5_speed >>= 1; sample->sus_loop_start >>= 1; sample->sus_loop_end >>= 1; } #endif if (sample->flags & IT_SAMPLE_EXISTS) { if (sample->length <= 0) sample->flags &= ~IT_SAMPLE_EXISTS; else { if ((unsigned int)sample->loop_end > (unsigned int)sample->length) sample->flags &= ~IT_SAMPLE_LOOP; else if ((unsigned int)sample->loop_start >= (unsigned int)sample->loop_end) sample->flags &= ~IT_SAMPLE_LOOP; if ((unsigned int)sample->sus_loop_end > (unsigned int)sample->length) sample->flags &= ~IT_SAMPLE_SUS_LOOP; else if ((unsigned int)sample->sus_loop_start >= (unsigned int)sample->sus_loop_end) sample->flags &= ~IT_SAMPLE_SUS_LOOP; /* We may be able to truncate the sample to save memory. */ if (sample->flags & IT_SAMPLE_LOOP && *convert != 0xFF) { /* not truncating compressed samples, for now... */ if ((sample->flags & IT_SAMPLE_SUS_LOOP) && sample->sus_loop_end >= sample->loop_end) sample->length = sample->sus_loop_end; else sample->length = sample->loop_end; } } } *offset = dumbfile_igetl(f); sample->vibrato_speed = dumbfile_getc(f); sample->vibrato_depth = dumbfile_getc(f); if (!hax) { sample->vibrato_rate = dumbfile_getc(f); sample->vibrato_waveform = dumbfile_getc(f); } else { sample->vibrato_rate = 0; sample->vibrato_waveform = 0; } sample->finetune = 0; sample->max_resampling_quality = -1; return dumbfile_error(f); } long _dumb_it_read_sample_data_adpcm4(IT_SAMPLE *sample, DUMBFILE *f) { long n, len, delta; signed char *ptr, *end; signed char compression_table[16]; if (dumbfile_getnc((char *)compression_table, 16, f) != 16) return -1; ptr = (signed char *)sample->data; delta = 0; end = ptr + sample->length; len = (sample->length + 1) / 2; for (n = 0; n < len; n++) { int b = dumbfile_getc(f); if (b < 0) return -1; delta += compression_table[b & 0x0F]; *ptr++ = delta; if (ptr >= end) break; delta += compression_table[b >> 4]; *ptr++ = delta; } return 0; } static long it_read_sample_data(IT_SAMPLE *sample, unsigned char convert, 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 (!(sample->flags & IT_SAMPLE_16BIT) && (convert == 0xFF)) { if (_dumb_it_read_sample_data_adpcm4(sample, f) < 0) return -1; } else if (sample->flags & 8) { /* If the sample is packed, then we must unpack it. */ /* Behavior as defined by greasemonkey's munch.py and observed by XMPlay * and OpenMPT */ if (sample->flags & IT_SAMPLE_STEREO) { if (sample->flags & IT_SAMPLE_16BIT) { decompress16(f, (short *)sample->data, (int)(datasize >> 1), convert & 4, 1); decompress16(f, (short *)sample->data + 1, (int)(datasize >> 1), convert & 4, 1); } else { decompress8(f, (signed char *)sample->data, (int)(datasize >> 1), convert & 4, 1); decompress8(f, (signed char *)sample->data + 1, (int)(datasize >> 1), convert & 4, 1); } } else { if (sample->flags & IT_SAMPLE_16BIT) decompress16(f, (short *)sample->data, (int)datasize, convert & 4, 0); else decompress8(f, (signed char *)sample->data, (int)datasize, convert & 4, 0); } } else if (sample->flags & IT_SAMPLE_16BIT) { if (sample->flags & IT_SAMPLE_STEREO) { if (convert & 2) { for (n = 0; n < datasize; n += 2) ((short *)sample->data)[n] = dumbfile_mgetw(f); for (n = 1; n < datasize; n += 2) ((short *)sample->data)[n] = dumbfile_mgetw(f); } else { 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 { if (convert & 2) for (n = 0; n < datasize; n++) ((short *)sample->data)[n] = dumbfile_mgetw(f); else for (n = 0; n < datasize; n++) ((short *)sample->data)[n] = dumbfile_igetw(f); } } else { if (sample->flags & IT_SAMPLE_STEREO) { 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 for (n = 0; n < datasize; n++) ((signed char *)sample->data)[n] = dumbfile_getc(f); } if (dumbfile_error(f)) return -1; if (!(convert & 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; } /* NOT SUPPORTED: * * convert & 4 - Samples stored as delta values * convert & 16 - Samples stored as TX-Wave 12-bit values * convert & 32 - Left/Right/All Stereo prompt */ return 0; } //#define DETECT_DUPLICATE_CHANNELS #ifdef DETECT_DUPLICATE_CHANNELS #include <stdio.h> #endif static int it_read_pattern(IT_PATTERN *pattern, DUMBFILE *f, unsigned char *buffer) { unsigned char cmask[DUMB_IT_N_CHANNELS]; unsigned char cnote[DUMB_IT_N_CHANNELS]; unsigned char cinstrument[DUMB_IT_N_CHANNELS]; unsigned char cvolpan[DUMB_IT_N_CHANNELS]; unsigned char ceffect[DUMB_IT_N_CHANNELS]; unsigned char ceffectvalue[DUMB_IT_N_CHANNELS]; #ifdef DETECT_DUPLICATE_CHANNELS IT_ENTRY *dupentry[DUMB_IT_N_CHANNELS]; #endif int n_entries = 0; int buflen; int bufpos = 0; IT_ENTRY *entry; unsigned char channel; unsigned char mask; memset(cmask, 0, sizeof(cmask)); memset(cnote, 0, sizeof(cnote)); memset(cinstrument, 0, sizeof(cinstrument)); memset(cvolpan, 0, sizeof(cvolpan)); memset(ceffect, 0, sizeof(ceffect)); memset(ceffectvalue, 0, sizeof(ceffectvalue)); #ifdef DETECT_DUPLICATE_CHANNELS { int i; for (i = 0; i < DUMB_IT_N_CHANNELS; i++) dupentry[i] = NULL; } #endif buflen = dumbfile_igetw(f); pattern->n_rows = dumbfile_igetw(f); /* Skip four unused bytes. */ dumbfile_skip(f, 4); if (dumbfile_error(f)) return -1; /* Read in the pattern data. */ dumbfile_getnc((char *)buffer, buflen, f); if (dumbfile_error(f)) return -1; /* Scan the pattern data, and work out how many entries we need room for. */ while (bufpos < buflen) { unsigned char b = buffer[bufpos++]; if (b == 0) { /* End of row */ n_entries++; continue; } channel = (b - 1) & 63; if (b & 128) cmask[channel] = mask = buffer[bufpos++]; else mask = cmask[channel]; { static const unsigned char used[16] = {0, 1, 1, 2, 1, 2, 2, 3, 2, 3, 3, 4, 3, 4, 4, 5}; n_entries += (mask != 0); bufpos += used[mask & 15]; } } pattern->n_entries = n_entries; pattern->entry = malloc(n_entries * sizeof(*pattern->entry)); if (!pattern->entry) return -1; bufpos = 0; memset(cmask, 0, sizeof(cmask)); entry = pattern->entry; while (bufpos < buflen) { unsigned char b = buffer[bufpos++]; if (b == 0) { /* End of row */ IT_SET_END_ROW(entry); entry++; #ifdef DETECT_DUPLICATE_CHANNELS { int i; for (i = 0; i < DUMB_IT_N_CHANNELS; i++) dupentry[i] = NULL; } #endif continue; } channel = (b - 1) & 63; if (b & 128) { if (bufpos >= buflen) return -1; cmask[channel] = mask = buffer[bufpos++]; } else mask = cmask[channel]; if (mask) { entry->mask = (mask & 15) | (mask >> 4); entry->channel = channel; if (mask & IT_ENTRY_NOTE) { if (bufpos >= buflen) return -1; cnote[channel] = entry->note = buffer[bufpos++]; } else if (mask & (IT_ENTRY_NOTE << 4)) entry->note = cnote[channel]; if (mask & IT_ENTRY_INSTRUMENT) { if (bufpos >= buflen) return -1; cinstrument[channel] = entry->instrument = buffer[bufpos++]; } else if (mask & (IT_ENTRY_INSTRUMENT << 4)) entry->instrument = cinstrument[channel]; if (mask & IT_ENTRY_VOLPAN) { if (bufpos >= buflen) return -1; cvolpan[channel] = entry->volpan = buffer[bufpos++]; } else if (mask & (IT_ENTRY_VOLPAN << 4)) entry->volpan = cvolpan[channel]; if (mask & IT_ENTRY_EFFECT) { if (bufpos + 1 >= buflen) return -1; ceffect[channel] = entry->effect = buffer[bufpos++]; ceffectvalue[channel] = entry->effectvalue = buffer[bufpos++]; } else { entry->effect = ceffect[channel]; entry->effectvalue = ceffectvalue[channel]; } #ifdef DETECT_DUPLICATE_CHANNELS if (dupentry[channel]) { FILE *f = fopen("dupentry.txt", "a"); if (!f) abort(); fprintf(f, "Two events on channel %d:", channel); fprintf(f, " Event #1:"); if (dupentry[channel]->mask & IT_ENTRY_NOTE) fprintf(f, " %03d", dupentry[channel]->note); else fprintf(f, " ..."); if (dupentry[channel]->mask & IT_ENTRY_INSTRUMENT) fprintf(f, " %03d", dupentry[channel]->instrument); else fprintf(f, " ..."); if (dupentry[channel]->mask & IT_ENTRY_VOLPAN) fprintf(f, " %03d", dupentry[channel]->volpan); else fprintf(f, " ..."); if (dupentry[channel]->mask & IT_ENTRY_EFFECT) fprintf(f, " %c%02X\n", 'A' - 1 + dupentry[channel]->effect, dupentry[channel]->effectvalue); else fprintf(f, " ...\n"); fprintf(f, " Event #2:"); if (entry->mask & IT_ENTRY_NOTE) fprintf(f, " %03d", entry->note); else fprintf(f, " ..."); if (entry->mask & IT_ENTRY_INSTRUMENT) fprintf(f, " %03d", entry->instrument); else fprintf(f, " ..."); if (entry->mask & IT_ENTRY_VOLPAN) fprintf(f, " %03d", entry->volpan); else fprintf(f, " ..."); if (entry->mask & IT_ENTRY_EFFECT) fprintf(f, " %c%02X\n", 'A' - 1 + entry->effect, entry->effectvalue); else fprintf(f, " ...\n"); fclose(f); } dupentry[channel] = entry; #endif entry++; } } ASSERT(entry == pattern->entry + n_entries); return 0; } /* 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 IT_COMPONENT_SONG_MESSAGE 1 #define IT_COMPONENT_INSTRUMENT 2 #define IT_COMPONENT_PATTERN 3 #define IT_COMPONENT_SAMPLE 4 typedef struct IT_COMPONENT { unsigned char type; unsigned short n; long offset; short sampfirst; /* component[sampfirst] = first sample data after this */ short sampnext; /* sampnext is used to create linked lists of sample data */ } IT_COMPONENT; static int it_component_compare(const void *e1, const void *e2) { return (int)(((const IT_COMPONENT *)e1)->offset - ((const IT_COMPONENT *)e2)->offset); } static sigdata_t *it_load_sigdata(DUMBFILE *f) { DUMB_IT_SIGDATA *sigdata; int cwt, cmwt; int special; int message_length, message_offset; IT_COMPONENT *component; int min_components; int n_components = 0; unsigned char sample_convert[4096]; int n; unsigned char *buffer; if (dumbfile_mgetl(f) != IT_SIGNATURE) { return NULL; } sigdata = malloc(sizeof(*sigdata)); if (!sigdata) { return NULL; } sigdata->song_message = NULL; sigdata->order = NULL; sigdata->instrument = NULL; sigdata->sample = NULL; sigdata->pattern = NULL; sigdata->midi = NULL; sigdata->checkpoint = NULL; dumbfile_getnc((char *)sigdata->name, 26, f); sigdata->name[26] = 0; /* Skip pattern row highlight info. */ dumbfile_skip(f, 2); sigdata->n_orders = dumbfile_igetw(f); sigdata->n_instruments = dumbfile_igetw(f); sigdata->n_samples = dumbfile_igetw(f); sigdata->n_patterns = dumbfile_igetw(f); cwt = dumbfile_igetw(f); cmwt = dumbfile_igetw(f); sigdata->flags = dumbfile_igetw(f); special = dumbfile_igetw(f); sigdata->global_volume = dumbfile_getc(f); sigdata->mixing_volume = dumbfile_getc(f); sigdata->speed = dumbfile_getc(f); if (sigdata->speed == 0) sigdata->speed = 6; // Should we? What about tempo? sigdata->tempo = dumbfile_getc(f); sigdata->pan_separation = dumbfile_getc(f); /** WARNING: use this */ /* Skip Pitch Wheel Depth */ dumbfile_skip(f, 1); message_length = dumbfile_igetw(f); message_offset = (int)dumbfile_igetl(f); /* Skip Reserved. */ dumbfile_skip(f, 4); dumbfile_getnc((char *)sigdata->channel_pan, DUMB_IT_N_CHANNELS, f); dumbfile_getnc((char *)sigdata->channel_volume, DUMB_IT_N_CHANNELS, f); // XXX sample count if (dumbfile_error(f) || sigdata->n_orders <= 0 || sigdata->n_orders > 1024 || // Whoa, nelly. sigdata->n_instruments > 256 || sigdata->n_samples > 4000 || 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_instruments) { sigdata->instrument = malloc(sigdata->n_instruments * sizeof(*sigdata->instrument)); if (!sigdata->instrument) { _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; } if (dumbfile_getnc((char *)sigdata->order, sigdata->n_orders, f) < sigdata->n_orders) { _dumb_it_unload_sigdata(sigdata); return NULL; } sigdata->restart_position = 0; min_components = (special & 1) + sigdata->n_instruments + sigdata->n_samples + sigdata->n_patterns; component = malloc(min_components * sizeof(*component)); if (!component) { _dumb_it_unload_sigdata(sigdata); return NULL; } if (special & 1) { component[n_components].type = IT_COMPONENT_SONG_MESSAGE; component[n_components].offset = message_offset; component[n_components].sampfirst = -1; n_components++; } for (n = 0; n < sigdata->n_instruments; n++) { component[n_components].type = IT_COMPONENT_INSTRUMENT; component[n_components].n = n; component[n_components].offset = dumbfile_igetl(f); component[n_components].sampfirst = -1; n_components++; } for (n = 0; n < sigdata->n_samples; n++) { component[n_components].type = IT_COMPONENT_SAMPLE; component[n_components].n = n; component[n_components].offset = dumbfile_igetl(f); component[n_components].sampfirst = -1; n_components++; } for (n = 0; n < sigdata->n_patterns; n++) { long offset = dumbfile_igetl(f); if (offset) { component[n_components].type = IT_COMPONENT_PATTERN; component[n_components].n = n; component[n_components].offset = offset; component[n_components].sampfirst = -1; n_components++; } else { /* Empty 64-row pattern */ sigdata->pattern[n].n_rows = 64; sigdata->pattern[n].n_entries = 0; } } if (dumbfile_error(f)) { free(component); _dumb_it_unload_sigdata(sigdata); return NULL; } /* if (!(sigdata->flags & 128) != !(special & 8)) { fprintf(stderr, "Flags Bit 7 (\"Request embedded MIDI configuration\"): %s\n", sigdata->flags & 128 ? "=SET=" : "clear"); fprintf(stderr, "Special Bit 3 (\"MIDI configuration embedded\") : %s\n", special & 8 ? "=SET=" : "clear"); fprintf(stderr, "entheh would like to investigate this IT file.\n"); fprintf(stderr, "Please contact him! entheh@users.sf.net\n"); } */ if (special & 8) { /* MIDI configuration is embedded. */ unsigned char mididata[32]; int i; sigdata->midi = malloc(sizeof(*sigdata->midi)); if (!sigdata->midi) { free(component); _dumb_it_unload_sigdata(sigdata); return NULL; // Should we be happy with this outcome in some situations? } // What are we skipping? i = dumbfile_igetw(f); if (dumbfile_error(f) || dumbfile_skip(f, 8 * i)) { free(component); _dumb_it_unload_sigdata(sigdata); return NULL; } /* Read embedded MIDI configuration */ // What are the first 9 commands for? if (dumbfile_skip(f, 32 * 9)) { free(component); _dumb_it_unload_sigdata(sigdata); return NULL; } for (i = 0; i < 16; i++) { unsigned char len = 0; int j, leftdigit = -1; if (dumbfile_getnc((char *)mididata, 32, f) < 32) { free(component); _dumb_it_unload_sigdata(sigdata); return NULL; } sigdata->midi->SFmacroz[i] = 0; for (j = 0; j < 32; j++) { if (leftdigit >= 0) { if (mididata[j] == 0) { sigdata->midi->SFmacro[i][len++] = leftdigit; break; } else if (mididata[j] == ' ') sigdata->midi->SFmacro[i][len++] = leftdigit; else if (mididata[j] >= '0' && mididata[j] <= '9') sigdata->midi->SFmacro[i][len++] = (leftdigit << 4) | (mididata[j] - '0'); else if (mididata[j] >= 'A' && mididata[j] <= 'F') sigdata->midi->SFmacro[i][len++] = (leftdigit << 4) | (mididata[j] - 'A' + 0xA); leftdigit = -1; } else if (mididata[j] == 0) break; else if (mididata[j] == 'z') sigdata->midi->SFmacroz[i] |= 1 << len++; else if (mididata[j] >= '0' && mididata[j] <= '9') leftdigit = mididata[j] - '0'; else if (mididata[j] >= 'A' && mididata[j] <= 'F') leftdigit = mididata[j] - 'A' + 0xA; } sigdata->midi->SFmacrolen[i] = len; } for (i = 0; i < 128; i++) { unsigned char len = 0; int j, leftdigit = -1; dumbfile_getnc((char *)mididata, 32, f); for (j = 0; j < 32; j++) { if (leftdigit >= 0) { if (mididata[j] == 0) { sigdata->midi->Zmacro[i][len++] = leftdigit; break; } else if (mididata[j] == ' ') sigdata->midi->Zmacro[i][len++] = leftdigit; else if (mididata[j] >= '0' && mididata[j] <= '9') sigdata->midi->Zmacro[i][len++] = (leftdigit << 4) | (mididata[j] - '0'); else if (mididata[j] >= 'A' && mididata[j] <= 'F') sigdata->midi->Zmacro[i][len++] = (leftdigit << 4) | (mididata[j] - 'A' + 0xA); leftdigit = -1; } else if (mididata[j] == 0) break; else if (mididata[j] >= '0' && mididata[j] <= '9') leftdigit = mididata[j] - '0'; else if (mididata[j] >= 'A' && mididata[j] <= 'F') leftdigit = mididata[j] - 'A' + 0xA; } sigdata->midi->Zmacrolen[i] = len; } } sigdata->flags &= IT_REAL_FLAGS; qsort(component, n_components, sizeof(IT_COMPONENT), &it_component_compare); buffer = malloc(65536); if (!buffer) { free(component); _dumb_it_unload_sigdata(sigdata); return NULL; } for (n = 0; n < n_components; n++) { long offset; int m; /* XXX */ if (component[n].offset == 0) { switch (component[n].type) { case IT_COMPONENT_INSTRUMENT: memset(&sigdata->instrument[component[n].n], 0, sizeof(IT_INSTRUMENT)); break; case IT_COMPONENT_SAMPLE: memset(&sigdata->sample[component[n].n], 0, sizeof(IT_SAMPLE)); break; case IT_COMPONENT_PATTERN: { IT_PATTERN *p = &sigdata->pattern[component[n].n]; p->entry = 0; p->n_rows = 64; p->n_entries = 0; } break; } continue; } if (dumbfile_seek(f, component[n].offset, DFS_SEEK_SET)) { free(buffer); free(component); _dumb_it_unload_sigdata(sigdata); return NULL; } switch (component[n].type) { case IT_COMPONENT_SONG_MESSAGE: if (n + 1 < n_components) { message_length = min(message_length, (int)(component[n + 1].offset - component[n].offset)); } sigdata->song_message = malloc(message_length + 1); if (sigdata->song_message) { if (dumbfile_getnc((char *)sigdata->song_message, message_length, f) < message_length) { free(buffer); free(component); _dumb_it_unload_sigdata(sigdata); return NULL; } sigdata->song_message[message_length] = 0; } break; case IT_COMPONENT_INSTRUMENT: if (cmwt < 0x200) m = it_read_old_instrument(&sigdata->instrument[component[n].n], f); else m = it_read_instrument( &sigdata->instrument[component[n].n], f, (n + 1 < n_components) ? (int)(component[n + 1].offset - component[n].offset) : 0); if (m) { free(buffer); free(component); _dumb_it_unload_sigdata(sigdata); return NULL; } break; case IT_COMPONENT_PATTERN: if (it_read_pattern(&sigdata->pattern[component[n].n], f, buffer)) { free(buffer); free(component); _dumb_it_unload_sigdata(sigdata); return NULL; } break; case IT_COMPONENT_SAMPLE: if (it_read_sample_header(&sigdata->sample[component[n].n], &sample_convert[component[n].n], &offset, f)) { 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; while (m >= 0) { if (dumbfile_seek(f, component[m].offset, DFS_SEEK_SET)) { free(buffer); free(component); _dumb_it_unload_sigdata(sigdata); return NULL; } if (it_read_sample_data(&sigdata->sample[component[m].n], sample_convert[component[m].n], f)) { free(buffer); free(component); _dumb_it_unload_sigdata(sigdata); return NULL; } m = component[m].sampnext; } } for (n = 0; n < 10; n++) { if (dumbfile_getc(f) == 'X') { if (dumbfile_getc(f) == 'T') { if (dumbfile_getc(f) == 'P') { if (dumbfile_getc(f) == 'M') { break; } } } } } if (!dumbfile_error(f) && n < 10) { unsigned int mptx_id = (unsigned int)dumbfile_igetl(f); while (!dumbfile_error(f) && mptx_id != DUMB_ID('M', 'P', 'T', 'S')) { unsigned int size = dumbfile_igetw(f); switch (mptx_id) { /* TODO: Add instrument extension readers */ default: dumbfile_skip(f, size * sigdata->n_instruments); break; } mptx_id = (unsigned int)dumbfile_igetl(f); } mptx_id = (unsigned int)dumbfile_igetl(f); while (!dumbfile_error(f) && dumbfile_pos(f) < dumbfile_get_size(f)) { unsigned int size = dumbfile_igetw(f); switch (mptx_id) { /* TODO: Add more song extension readers */ case DUMB_ID('D', 'T', '.', '.'): if (size == 2) sigdata->tempo = dumbfile_igetw(f); else if (size == 4) sigdata->tempo = (int)dumbfile_igetl(f); break; default: dumbfile_skip(f, size); break; } mptx_id = (unsigned int)dumbfile_igetl(f); } } free(buffer); free(component); if (_dumb_it_fix_invalid_orders(sigdata) < 0) { _dumb_it_unload_sigdata(sigdata); return NULL; } return sigdata; } DUH *dumb_read_it_quick(DUMBFILE *f) { sigdata_t *sigdata; DUH_SIGTYPE_DESC *descptr = &_dumb_sigtype_it; sigdata = it_load_sigdata(f); if (!sigdata) return NULL; { const char *tag[2][2]; tag[0][0] = "TITLE"; tag[0][1] = (const char *)(((DUMB_IT_SIGDATA *)sigdata)->name); tag[1][0] = "FORMAT"; tag[1][1] = "IT"; return make_duh(-1, 2, (const char *const(*)[2])tag, 1, &descptr, &sigdata); } }