ref: 6080f4c2a1b74d3536232d7a63533446b24f083b
dir: /src/it/readamf.c/
/* _______ ____ __ ___ ___ * \ _ \ \ / \ / \ \ / / ' ' ' * | | \ \ | | || | \/ | . . * | | | | | | || ||\ /| | * | | | | | | || || \/ | | ' ' ' * | | | | | | || || | | . . * | |_/ / \ \__// || | | * /_______/ynamic \____/niversal /__\ /____\usic /| . . ibliotheque * / \ * / . \ * readamf.c - Code to read a DSMI AMF module from / / \ \ * an open file. | < / \_ * | \/ /\ / * By Chris Moeller. \_ / > / * | \ / / * | ' / * \__/ */ #include <stdlib.h> #include <string.h> #include <math.h> #include "dumb.h" #include "internal/it.h" static void it_amf_process_track(IT_ENTRY *entry_table, unsigned char *track, int rows, int channels) { int last_instrument = 0; int tracksize = track[0] + (track[1] << 8) + (track[2] << 16); track += 3; while (tracksize--) { unsigned int row = track[0]; unsigned int command = track[1]; unsigned int argument = track[2]; IT_ENTRY *entry = entry_table + row * channels; if (row >= (unsigned int)rows) break; if (command < 0x7F) { entry->mask |= IT_ENTRY_NOTE | IT_ENTRY_INSTRUMENT | IT_ENTRY_VOLPAN; entry->note = command; if (!entry->instrument) entry->instrument = last_instrument; entry->volpan = argument; } else if (command == 0x7F) { signed char row_delta = (signed char)argument; int row_source = (int)row + (int)row_delta; if (row_source >= 0 && row_source < (int)rows) { *entry = entry_table[row_source * channels]; } } else if (command == 0x80) { entry->mask |= IT_ENTRY_INSTRUMENT; last_instrument = argument + 1; entry->instrument = last_instrument; } else if (command == 0x83) { entry->mask |= IT_ENTRY_VOLPAN; entry->volpan = argument; } else { unsigned int effect = command & 0x7F; unsigned int effectvalue = argument; switch (effect) { case 0x01: effect = IT_SET_SPEED; break; case 0x02: effect = IT_VOLUME_SLIDE; case 0x0A: if (effect == 0x0A) effect = IT_VOLSLIDE_TONEPORTA; case 0x0B: if (effect == 0x0B) effect = IT_VOLSLIDE_VIBRATO; if (effectvalue & 0x80) effectvalue = (-(signed char)effectvalue) & 0x0F; else effectvalue = (effectvalue & 0x0F) << 4; break; case 0x04: if (effectvalue & 0x80) { effect = IT_PORTAMENTO_UP; effectvalue = (-(signed char)effectvalue) & 0x7F; } else { effect = IT_PORTAMENTO_DOWN; } break; case 0x06: effect = IT_TONE_PORTAMENTO; break; case 0x07: effect = IT_TREMOR; break; case 0x08: effect = IT_ARPEGGIO; break; case 0x09: effect = IT_VIBRATO; break; case 0x0C: effect = IT_BREAK_TO_ROW; break; case 0x0D: effect = IT_JUMP_TO_ORDER; break; case 0x0F: effect = IT_RETRIGGER_NOTE; break; case 0x10: effect = IT_SET_SAMPLE_OFFSET; break; case 0x11: if (effectvalue) { effect = IT_VOLUME_SLIDE; if (effectvalue & 0x80) effectvalue = 0xF0 | ((-(signed char)effectvalue) & 0x0F); else effectvalue = 0x0F | ((effectvalue & 0x0F) << 4); } else effect = 0; break; case 0x12: case 0x16: if (effectvalue) { int mask = (effect == 0x16) ? 0xE0 : 0xF0; effect = (effectvalue & 0x80) ? IT_PORTAMENTO_UP : IT_PORTAMENTO_DOWN; if (effectvalue & 0x80) effectvalue = mask | ((-(signed char)effectvalue) & 0x0F); else effectvalue = mask | (effectvalue & 0x0F); } else effect = 0; break; case 0x13: effect = IT_S; effectvalue = EFFECT_VALUE(IT_S_NOTE_DELAY, effectvalue & 0x0F); break; case 0x14: effect = IT_S; effectvalue = EFFECT_VALUE(IT_S_DELAYED_NOTE_CUT, effectvalue & 0x0F); break; case 0x15: effect = IT_SET_SONG_TEMPO; break; case 0x17: effectvalue = (effectvalue + 64) & 0x7F; if (entry->mask & IT_ENTRY_EFFECT) { if (!(entry->mask & IT_ENTRY_VOLPAN)) { entry->mask |= IT_ENTRY_VOLPAN; entry->volpan = (effectvalue / 2) + 128; } effect = 0; } else { effect = IT_SET_PANNING; } break; default: effect = effectvalue = 0; } if (effect) { entry->mask |= IT_ENTRY_EFFECT; entry->effect = effect; entry->effectvalue = effectvalue; } } track += 3; } } static int it_amf_process_pattern(IT_PATTERN *pattern, IT_ENTRY *entry_table, int rows, int channels) { int i, j; int n_entries = rows; IT_ENTRY *entry; pattern->n_rows = rows; for (i = 0, j = channels * rows; i < j; i++) { if (entry_table[i].mask) { n_entries++; } } pattern->n_entries = n_entries; pattern->entry = entry = malloc(n_entries * sizeof(IT_ENTRY)); if (!entry) { return -1; } for (i = 0; i < rows; i++) { for (j = 0; j < channels; j++) { if (entry_table[i * channels + j].mask) { *entry = entry_table[i * channels + j]; entry->channel = j; entry++; } } IT_SET_END_ROW(entry); entry++; } return 0; } static int it_amf_read_sample_header(IT_SAMPLE *sample, DUMBFILE *f, int *offset, int ver) { int exists; exists = dumbfile_getc(f); dumbfile_getnc((char *)sample->name, 32, f); sample->name[32] = 0; dumbfile_getnc((char *)sample->filename, 13, f); sample->filename[13] = 0; *offset = (int)dumbfile_igetl(f); sample->length = dumbfile_igetl(f); sample->C5_speed = dumbfile_igetw(f); sample->default_volume = dumbfile_getc(f); sample->global_volume = 64; if (sample->default_volume > 64) sample->default_volume = 64; if (ver >= 11) { sample->loop_start = dumbfile_igetl(f); sample->loop_end = dumbfile_igetl(f); } else { sample->loop_start = dumbfile_igetw(f); sample->loop_end = sample->length; } if (sample->length <= 0) { sample->flags = 0; return 0; } sample->flags = exists == 1 ? IT_SAMPLE_EXISTS : 0; sample->default_pan = 0; sample->finetune = 0; if (sample->loop_end > sample->loop_start + 2 && sample->loop_end <= sample->length) sample->flags |= IT_SAMPLE_LOOP; sample->vibrato_speed = 0; sample->vibrato_depth = 0; sample->vibrato_rate = 0; sample->vibrato_waveform = 0; // do we have to set _all_ these? sample->max_resampling_quality = -1; return dumbfile_error(f); } static int it_amf_read_sample_data(IT_SAMPLE *sample, DUMBFILE *f) { int i, read_length = 0; sample->data = malloc(sample->length); if (!sample->data) return -1; if (sample->length) read_length = (int)dumbfile_getnc(sample->data, sample->length, f); if (read_length < 0) read_length = 0; for (i = 0; i < read_length; i++) { ((signed char *)sample->data)[i] ^= 0x80; } for (i = read_length; i < sample->length; i++) { ((signed char *)sample->data)[i] = 0; } return 0; /* Sometimes the last sample is truncated :( */ } static DUMB_IT_SIGDATA *it_amf_load_sigdata(DUMBFILE *f, int *version) { DUMB_IT_SIGDATA *sigdata; int i, j, ver, ntracks, realntracks, nchannels; int maxsampleseekpos = 0; int sampleseekpos[256]; unsigned short *orderstotracks; unsigned short *trackmap; unsigned int tracksize[256]; unsigned char **track; static const char sig[] = "AMF"; char signature[3]; if (dumbfile_getnc(signature, 3, f) != 3 || memcmp(signature, sig, 3)) { return NULL; } *version = ver = dumbfile_getc(f); if (ver < 10 || ver > 14) { return NULL; } sigdata = malloc(sizeof(*sigdata)); if (!sigdata) { return NULL; } dumbfile_getnc((char *)sigdata->name, 32, f); sigdata->name[32] = 0; sigdata->n_samples = dumbfile_getc(f); sigdata->n_orders = dumbfile_getc(f); ntracks = dumbfile_igetw(f); nchannels = dumbfile_getc(f); if (dumbfile_error(f) || sigdata->n_samples < 1 || sigdata->n_samples > 255 || sigdata->n_orders < 1 || sigdata->n_orders > 255 || !ntracks || nchannels < 1 || nchannels > 32) { free(sigdata); return NULL; } sigdata->n_pchannels = nchannels; memset(sigdata->channel_volume, 64, DUMB_IT_N_CHANNELS); if (ver >= 11) { int nchannels = (ver >= 13) ? 32 : 16; for (i = 0; i < nchannels; i++) { signed char panpos = dumbfile_getc(f); int pan = (panpos + 64) / 2; if (pan < 0) pan = 0; else if (pan > 64) pan = IT_SURROUND; sigdata->channel_pan[i] = pan; } } else { int sep = 32 * dumb_it_default_panning_separation / 100; for (i = 0; i < 16; i++) { sigdata->channel_pan[i] = (dumbfile_getc(f) & 1) ? 32 - sep : 32 + sep; } } sigdata->tempo = 125; sigdata->speed = 6; if (ver >= 13) { i = dumbfile_getc(f); if (i >= 32) sigdata->tempo = i; i = dumbfile_getc(f); if (i <= 32) sigdata->speed = i; } sigdata->order = malloc(sigdata->n_orders); if (!sigdata->order) { free(sigdata); return NULL; } orderstotracks = malloc(sigdata->n_orders * nchannels * sizeof(unsigned short)); if (!orderstotracks) { free(sigdata->order); free(sigdata); return NULL; } for (i = 0; i < sigdata->n_orders; i++) { sigdata->order[i] = i; tracksize[i] = 64; if (ver >= 14) { tracksize[i] = dumbfile_igetw(f); } for (j = 0; j < nchannels; j++) { orderstotracks[i * nchannels + j] = dumbfile_igetw(f); } } if (dumbfile_error(f)) { free(orderstotracks); free(sigdata->order); free(sigdata); return NULL; } sigdata->sample = malloc(sigdata->n_samples * sizeof(*sigdata->sample)); if (!sigdata->sample) { free(orderstotracks); free(sigdata->order); free(sigdata); return NULL; } sigdata->restart_position = 0; sigdata->song_message = NULL; sigdata->instrument = NULL; sigdata->pattern = NULL; sigdata->midi = NULL; sigdata->checkpoint = NULL; sigdata->n_instruments = 0; for (i = 0; i < sigdata->n_samples; ++i) sigdata->sample[i].data = NULL; for (i = 0; i < sigdata->n_samples; ++i) { int offset; if (it_amf_read_sample_header(&sigdata->sample[i], f, &offset, ver)) { goto error_ott; } sampleseekpos[i] = offset; if (offset > maxsampleseekpos) maxsampleseekpos = offset; } sigdata->n_patterns = sigdata->n_orders; sigdata->pattern = malloc(sigdata->n_patterns * sizeof(*sigdata->pattern)); if (!sigdata->pattern) { goto error_ott; } for (i = 0; i < sigdata->n_patterns; ++i) sigdata->pattern[i].entry = NULL; trackmap = malloc(ntracks * sizeof(unsigned short)); if (!trackmap) { goto error_ott; } if (dumbfile_getnc((char *)trackmap, ntracks * sizeof(unsigned short), f) != (long)(ntracks * sizeof(unsigned short))) { goto error_tm; } realntracks = 0; for (i = 0; i < ntracks; i++) { if (trackmap[i] > realntracks) realntracks = trackmap[i]; } track = calloc(realntracks, sizeof(unsigned char *)); if (!track) { goto error_tm; } for (i = 0; i < realntracks; i++) { int tracksize = dumbfile_igetw(f); tracksize += dumbfile_getc(f) << 16; track[i] = malloc(tracksize * 3 + 3); if (!track[i]) { goto error_all; } track[i][0] = tracksize & 255; track[i][1] = (tracksize >> 8) & 255; track[i][2] = (tracksize >> 16) & 255; if (dumbfile_getnc((char *)track[i] + 3, tracksize * 3, f) != tracksize * 3) { goto error_all; } } for (i = 1; i <= maxsampleseekpos; i++) { for (j = 0; j < sigdata->n_samples; j++) { if (sampleseekpos[j] == i) { if (it_amf_read_sample_data(&sigdata->sample[j], f)) { goto error_all; } break; } } } /* Process tracks into patterns */ for (i = 0; i < sigdata->n_patterns; i++) { IT_ENTRY *entry_table = calloc(tracksize[i] * nchannels, sizeof(IT_ENTRY)); if (!entry_table) { goto error_all; } for (j = 0; j < nchannels; j++) { int ntrack = orderstotracks[i * nchannels + j]; if (ntrack && ntrack <= ntracks) { int realtrack = trackmap[ntrack - 1]; if (realtrack) { realtrack--; if (realtrack < realntracks && track[realtrack]) { it_amf_process_track(entry_table + j, track[realtrack], tracksize[i], nchannels); } } } } if (it_amf_process_pattern(&sigdata->pattern[i], entry_table, tracksize[i], nchannels)) { free(entry_table); goto error_all; } free(entry_table); } /* Now let's initialise the remaining variables, and we're done! */ sigdata->flags = IT_OLD_EFFECTS | IT_COMPATIBLE_GXX | IT_STEREO | IT_WAS_AN_S3M; sigdata->global_volume = 128; sigdata->mixing_volume = 48; sigdata->pan_separation = 128; _dumb_it_fix_invalid_orders(sigdata); for (i = 0; i < realntracks; i++) { if (track[i]) { free(track[i]); } } free(track); free(trackmap); free(orderstotracks); return sigdata; error_all: for (i = 0; i < realntracks; i++) { if (track[i]) { free(track[i]); } } free(track); error_tm: free(trackmap); error_ott: free(orderstotracks); _dumb_it_unload_sigdata(sigdata); return NULL; } DUH *dumb_read_amf_quick(DUMBFILE *f) { sigdata_t *sigdata; DUH_SIGTYPE_DESC *descptr = &_dumb_sigtype_it; int version; sigdata = it_amf_load_sigdata(f, &version); if (!sigdata) return NULL; { const char *tag[2][2]; char ver_string[14]; tag[0][0] = "TITLE"; tag[0][1] = (const char *)(((DUMB_IT_SIGDATA *)sigdata)->name); tag[1][0] = "FORMAT"; memcpy(ver_string, "DSMI AMF v", 10); ver_string[10] = '0' + version / 10; ver_string[11] = '.'; ver_string[12] = '0' + version % 10; ver_string[13] = 0; tag[1][1] = ver_string; return make_duh(-1, 2, (const char *const(*)[2])tag, 1, &descptr, &sigdata); } }