double Alg_reader::parse_after_dur(double dur, string &field, int n, double base) { if ((int) field.length() == n) { return dur; } if (toupper(field[n]) == 'T') { return parse_after_dur(dur * 2/3, field, n + 1, base); } if (field[n] == '.') { return parse_after_dur(dur * 1.5, field, n + 1, base); } if (isdigit(field[n])) { int last = find_real_in(field, n); string a_string = field.substr(n, last - n); double f = atof(a_string.c_str()); return parse_after_dur(dur * f, field, last, base); } if (field[n] == '+') { string a_string = field.substr(n + 1); return dur + parse_dur( a_string, seq->get_time_map()->beat_to_time( seq->get_time_map()->time_to_beat(base) + dur)); } parse_error(field, n, "Unexpected character in duration"); return dur; }
double Alg_reader::parse_dur(string &field, double base) { char *msg = "Duration expected"; char *durs = "SIQHW"; char *p; int last; double dur; if (field.length() < 2) { // fall through to error message return -1; } else if (isdigit(field[1])) { last = find_real_in(field, 1); string real_string = field.substr(1, last - 1); dur = atof(real_string.c_str()); // convert dur from seconds to beats dur = seq->get_time_map()->time_to_beat(base + dur) - seq->get_time_map()->time_to_beat(base); } else if (p = strchr(durs, toupper(field[1]))) { dur = duration_lookup[p - durs]; last = 2; } else { parse_error(field, 1, msg); return 0; } dur = parse_after_dur(dur, field, last, base); dur = seq->get_time_map()->beat_to_time( seq->get_time_map()->time_to_beat(base) + dur) - base; return dur; }
Alg_parameters_ptr Alg_reader::process_attributes( Alg_parameters_ptr attributes, double time) { // print "process_attributes:", attributes bool ts_flag = false; if (attributes) { Alg_parameters_ptr a; bool in_seconds = seq->get_units_are_seconds(); if (a = Alg_parameters::remove_key(&attributes, "tempor")) { double tempo = a->parm.r; seq->insert_tempo(tempo, seq->get_time_map()->time_to_beat(time)); } if (a = Alg_parameters::remove_key(&attributes, "beatr")) { double beat = a->parm.r; seq->insert_beat(time, beat); } if (a = Alg_parameters::remove_key(&attributes, "timesig_numr")) { tsnum = a->parm.r; ts_flag = true; } if (a = Alg_parameters::remove_key(&attributes, "timesig_denr")) { tsden = a->parm.r; ts_flag = true; } if (ts_flag) { seq->set_time_sig(seq->get_time_map()->time_to_beat(time), tsnum, tsden); } if (in_seconds) seq->convert_to_seconds(); } return attributes; // in case it was modified }
#include "assert.h" #include "stdlib.h" #include "stdio.h" #include "allegro.h" #include "string.h" #include "ctype.h" //#include "memory.h" #include "trace.h" #include "strparse.h" #ifndef EXPERIMENTAL_NOTE_TRACK #include "allegrord.h" #endif /* EXPERIMENTAL_NOTE_TRACK */ #define streql(s1, s2) (strcmp(s1, s2) == 0) #define field_max 80 //Note that this is an #ifdef, not an #ifndef #ifdef EXPERIMENTAL_NOTE_TRACK class Alg_reader { public: FILE *file; int line_no; String_parse line_parser; bool line_parser_flag; char field[field_max]; bool error_flag; Alg_seq_ptr seq; double tsnum; double tsden; Alg_reader(FILE *a_file, Alg_seq_ptr new_seq); void readline(); Alg_parameters_ptr process_attributes(Alg_parameters_ptr attributes, double time); bool parse(); long parse_chan(char *field); long parse_int(char *field); int find_real_in(char *field, int n); double parse_real(char *field); void parse_error(char *field, long offset, char *message); double parse_dur(char *field, double base); double parse_after_dur(double dur, char *field, int n, double base); double parse_loud(char *field); long parse_key(char *field); double parse_pitch(char *field); long parse_after_key(int key, char *field, int n); long find_int_in(char *field, int n); bool parse_attribute(char *field, Alg_parameter_ptr parm); bool parse_val(Alg_parameter_ptr param, char *s, int i); bool check_type(char type_char, Alg_parameter_ptr param); }; #endif /* EXPERIMENTAL_NOTE_TRACK */ void subseq(char *result, char *source, int from, int to) { memcpy(result, source + from, to - from); result[to - from] = 0; } #ifndef EXPERIMENTAL_NOTE_TRACK double Allegro_reader::parse_pitch(char *field) #else /* EXPERIMENTAL_NOTE_TRACK */ double Alg_reader::parse_pitch(char *field) #endif /* EXPERIMENTAL_NOTE_TRACK */ { if (isdigit(field[1])) { char real_string[80]; int last = find_real_in(field, 1); subseq(real_string, field, 1, last); return atof(real_string); } else { return (double) parse_key(field); } } #ifndef EXPERIMENTAL_NOTE_TRACK Allegro_reader::Allegro_reader(FILE *a_file) { file = a_file; // save the file line_parser_flag = false; line_no = 0; seq = Seq(); tsnum = 4; // default time signature tsden = 4; } #else /* EXPERIMENTAL_NOTE_TRACK */ // it is the responsibility of the caller to delete // the seq Alg_reader::Alg_reader(FILE *a_file, Alg_seq_ptr new_seq) { file = a_file; // save the file line_parser_flag = false; line_no = 0; tsnum = 4; // default time signature tsden = 4; seq = new_seq; } #endif /* EXPERIMENTAL_NOTE_TRACK */ //Note that this is an #ifdef, not an #ifndef #ifdef EXPERIMENTAL_NOTE_TRACK Alg_seq_ptr alg_read(FILE *file, Alg_seq_ptr new_seq) // read a sequence from allegro file { if (!new_seq) new_seq = new Alg_seq(); Alg_reader alg_reader(file, new_seq); alg_reader.parse(); return alg_reader.seq; } #endif /* EXPERIMENTAL_NOTE_TRACK */ #ifndef EXPERIMENTAL_NOTE_TRACK void Allegro_reader::readline() #else /* EXPERIMENTAL_NOTE_TRACK */ void Alg_reader::readline() #endif /* EXPERIMENTAL_NOTE_TRACK */ { char line[256]; char *line_flag = fgets(line, 256, file); line_parser_flag = false; if (line_flag) { line_parser.init(line); line_parser_flag = true; error_flag = false; } } #ifndef EXPERIMENTAL_NOTE_TRACK void Allegro_reader::process_attributes(Parameters_ptr attributes, double time) { // print "process_attributes:", attributes bool ts_flag; if (attributes) { Parameters_ptr a; if (a = Parameters::remove_key(&attributes, "tempor")) { double tempo = a->parm.r; seq.insert_tempo(tempo, seq.map.time_to_beat(time)); } if (a = Parameters::remove_key(&attributes, "beatr")) { double beat = a->parm.r; seq.insert_beat(time, beat); } if (a = Parameters::remove_key(&attributes, "tsnumr")) { tsnum = a->parm.r; ts_flag = true; } if (a = Parameters::remove_key(&attributes, "tsdenr")) { tsden = a->parm.r; ts_flag = true; } if (ts_flag) { seq.set_time_sig(seq.map.time_to_beat(time), tsnum, tsden); } } } #else /* EXPERIMENTAL_NOTE_TRACK */ Alg_parameters_ptr Alg_reader::process_attributes( Alg_parameters_ptr attributes, double time) { // print "process_attributes:", attributes bool ts_flag = false; if (attributes) { Alg_parameters_ptr a; bool in_seconds = seq->get_units_are_seconds(); if (a = Alg_parameters::remove_key(&attributes, "tempor")) { double tempo = a->parm.r; seq->insert_tempo(tempo, seq->get_time_map()->time_to_beat(time)); } if (a = Alg_parameters::remove_key(&attributes, "beatr")) { double beat = a->parm.r; seq->insert_beat(time, beat); } if (a = Alg_parameters::remove_key(&attributes, "timesig_numr")) { tsnum = a->parm.r; ts_flag = true; } if (a = Alg_parameters::remove_key(&attributes, "timesig_denr")) { tsden = a->parm.r; ts_flag = true; } if (ts_flag) { seq->set_time_sig(seq->get_time_map()->time_to_beat(time), tsnum, tsden); } if (in_seconds) seq->convert_to_seconds(); } return attributes; // in case it was modified } #endif /* EXPERIMENTAL_NOTE_TRACK */ #ifndef EXPERIMENTAL_NOTE_TRACK bool Allegro_reader::parse() { int voice = 0; int key = 60; double loud = 100.0; double pitch = 60.0; double dur = 1.0; double time = 0.0; readline(); bool valid = false; // ignore blank lines while (line_parser_flag) { bool time_flag = false; bool next_flag = false; double next; bool voice_flag = false; bool loud_flag = false; bool dur_flag = false; bool new_pitch_flag = false; // "P" syntax double new_pitch = 0.0; bool new_key_flag = false; // "K" syntax int new_key = 0; bool new_note_flag = false; // "A"-"G" syntax int new_note = 0; Parameters_ptr attributes = NULL; line_parser.get_nonspace_quoted(field); char pk = line_parser.peek(); if (pk && !isspace(pk)) { line_parser.get_nonspace_quoted(field + strlen(field)); } while (field[0]) { // print "field", "|";field;"|", "|";line_parser.string;"|", line_parser.pos char first = toupper(field[0]); if (strchr("ABCDEFGKLPUSIQHW-", first)) { valid = true; // it's a note or event } if (first == 'V') { if (voice_flag) { parse_error(field, 0, "Voice specified twice"); } else { voice = parse_int(field); } voice_flag = true; } else if (first == 'T') { if (time_flag) { parse_error(field, 0, "Time specified twice"); } else { time = parse_dur(field, 0.0); } time_flag = true; } else if (first == 'N') { if (next_flag) { parse_error(field, 0, "Next specified twice"); } else { next = parse_dur(field, time); } next_flag = true; } else if (first == 'K') { if (new_key_flag) { parse_error(field, 0, "Key specified twice"); } else { new_key = parse_key(field); new_key_flag = true; } } else if (first == 'L') { if (loud_flag) { parse_error(field, 0, "Loudness specified twice"); } else { loud = parse_loud(field); } loud_flag = true; } else if (first == 'P') { if (new_note_flag || new_pitch_flag) { parse_error(field, 0, "Pitch specified twice"); } else { new_pitch = parse_pitch(field); new_pitch_flag = true; } } else if (first == 'U') { if (dur_flag) { parse_error(field, 0, "Dur specified twice"); } else { dur = parse_dur(field, time); dur_flag = true; } } else if (strchr("SIQHW", first)) { if (dur_flag) { parse_error(field, 0, "Dur specified twice"); } else { // prepend 'U' to field, copy EOS too memmove(field + 1, field, strlen(field) + 1); field[0] = 'U'; dur = parse_dur(field, time); dur_flag = true; } } else if (strchr("ABCDEFG", first)) { if (new_note_flag || new_pitch_flag) { parse_error(field, 0, "Pitch specified twice"); } else { // prepend 'K' to field, copy EOS too memmove(field + 1, field, strlen(field) + 1); field[0] = 'K'; new_note = parse_key(field); new_note_flag = true; } } else if (first == '-') { Parameter parm; if (parse_attribute(field, &parm)) { // enter attribute-value pair attributes = new Parameters(attributes); attributes->parm = parm; parm.s = NULL; // protect string from deletion by destructor } } else { parse_error(field, 0, "Unknown field"); } if (error_flag) { field[0] = 0; // exit the loop } else { line_parser.get_nonspace_quoted(field); pk = line_parser.peek(); if (pk && !isspace(pk)) { line_parser.get_nonspace_quoted(field + strlen(field)); } } } // a case analysis: // Key < 128 counts as both key and pitch // A-G implies pitch AND key unless key given too // K60 P60 -- both are specified, use 'em // K60 P60 C4 -- overconstrained, an error // K60 C4 -- overconstrained // K60 -- OK, pitch is 60 // C4 P60 -- over constrained // P60 -- OK, key is from before, pitch is 60 // C4 -- OK, key is 60, pitch is 60 // <nothing> -- OK, key and pitch from before // K200 with P60 ok, pitch is 60 // K200 with neither P60 nor C4 uses // pitch from before // figure out what the key/instance is: if (new_key_flag) { // it was directly specified key = new_key; if (key < 128 && new_note_flag) { parse_error("", 0, "Pitch specified twice"); } } else if (new_note_flag) { // "A"-"G" used key = new_note; } if (new_pitch_flag) { pitch = new_pitch; } else if (key < 128) { pitch = key; } // now we've acquired new parameters // if (it is a note, then enter the note if (valid) { // change tempo or beat process_attributes(attributes, time); // if there's a duration or pitch, make a note: if (new_pitch_flag || dur_flag || new_note_flag) { new_key_flag = false; new_pitch_flag = false; Allegro_note_ptr note_ptr = new Allegro_note; note_ptr->chan = voice; note_ptr->time = time; note_ptr->dur = dur; note_ptr->key = key; note_ptr->pitch = pitch; note_ptr->loud = loud; note_ptr->parameters = attributes; seq.add_event(note_ptr); // sort later } else { int update_key = -1; // key or pitch must appear explicitly; otherwise // update applies to channel if (new_key_flag || new_pitch_flag) { update_key = key; } if (loud_flag) { Allegro_update_ptr new_upd = new Allegro_update; new_upd->chan = voice; new_upd->time = time; new_upd->key = update_key; new_upd->parameter.set_attr(symbol_table.insert_string("loudr")); new_upd->parameter.r = pitch; seq.add_event(new_upd); } if (attributes) { while (attributes) { Allegro_update_ptr new_upd = new Allegro_update; new_upd->chan = voice; new_upd->time = time; new_upd->key = update_key; new_upd->parameter = attributes->parm; seq.add_event(new_upd); Parameters_ptr p = attributes; attributes = attributes->next; delete p; } } } if (next_flag) { time = time + next; } else if (dur_flag) { time = time + dur; } } readline(); } //print "Finished reading score" if (!error_flag) { seq.convert_to_seconds(); // make sure format is correct // seq.notes.sort('event_greater_than'); } // print "parse returns error_flag", error_flag return error_flag; } #else /* EXPERIMENTAL_NOTE_TRACK */ bool Alg_reader::parse() { int voice = 0; int key = 60; double loud = 100.0; double pitch = 60.0; double dur = 1.0; double time = 0.0; int track_num = 0; seq->convert_to_seconds(); //seq->set_real_dur(0.0); // just in case it's not initialized already readline(); bool valid = false; // ignore blank lines while (line_parser_flag) { bool time_flag = false; bool next_flag = false; double next; bool voice_flag = false; bool loud_flag = false; bool dur_flag = false; bool new_pitch_flag = false; // "P" syntax double new_pitch = 0.0; bool new_key_flag = false; // "K" syntax int new_key = 0; bool new_note_flag = false; // "A"-"G" syntax int new_note = 0; Alg_parameters_ptr attributes = NULL; if (line_parser.peek() == '#') { // look for #track line_parser.get_nonspace_quoted(field); if (streql(field, "#track")) { line_parser.get_nonspace_quoted(field); // number track_num = parse_int(field - 1); seq->add_track(track_num); } // maybe we have a comment } else { // we must have a track to insert into if (seq->tracks() == 0) seq->add_track(0); line_parser.get_nonspace_quoted(field); char pk = line_parser.peek(); // attributes are parsed as two adjacent nonspace_quoted tokens // so we have to conditionally call get_nonspace_quoted() again if (pk && !isspace(pk)) { line_parser.get_nonspace_quoted(field + strlen(field)); } while (field[0]) { char first = toupper(field[0]); if (strchr("ABCDEFGKLPUSIQHW-", first)) { valid = true; // it's a note or event } if (first == 'V') { if (voice_flag) { parse_error(field, 0, "Voice specified twice"); } else { voice = parse_chan(field); } voice_flag = true; } else if (first == 'T') { if (time_flag) { parse_error(field, 0, "Time specified twice"); } else { time = parse_dur(field, 0.0); } time_flag = true; } else if (first == 'N') { if (next_flag) { parse_error(field, 0, "Next specified twice"); } else { next = parse_dur(field, time); } next_flag = true; } else if (first == 'K') { if (new_key_flag) { parse_error(field, 0, "Key specified twice"); } else { new_key = parse_key(field); new_key_flag = true; } } else if (first == 'L') { if (loud_flag) { parse_error(field, 0, "Loudness specified twice"); } else { loud = parse_loud(field); } loud_flag = true; } else if (first == 'P') { if (new_note_flag || new_pitch_flag) { parse_error(field, 0, "Pitch specified twice"); } else { new_pitch = parse_pitch(field); new_pitch_flag = true; } } else if (first == 'U') { if (dur_flag) { parse_error(field, 0, "Dur specified twice"); } else { dur = parse_dur(field, time); dur_flag = true; } } else if (strchr("SIQHW", first)) { if (dur_flag) { parse_error(field, 0, "Dur specified twice"); } else { // prepend 'U' to field, copy EOS too memmove(field + 1, field, strlen(field) + 1); field[0] = 'U'; dur = parse_dur(field, time); dur_flag = true; } } else if (strchr("ABCDEFG", first)) { if (new_note_flag || new_pitch_flag) { parse_error(field, 0, "Pitch specified twice"); } else { // prepend 'K' to field, copy EOS too memmove(field + 1, field, strlen(field) + 1); field[0] = 'K'; new_note = parse_key(field); new_note_flag = true; } } else if (first == '-') { Alg_parameter parm; if (parse_attribute(field, &parm)) { // enter attribute-value pair attributes = new Alg_parameters(attributes); attributes->parm = parm; parm.s = NULL; // protect string from deletion by destructor } } else { parse_error(field, 0, "Unknown field"); } if (error_flag) { field[0] = 0; // exit the loop } else { line_parser.get_nonspace_quoted(field); pk = line_parser.peek(); // attributes are parsed as two adjacent nonspace_quoted // tokens so we have to conditionally call // get_nonspace_quoted() again if (pk && !isspace(pk)) { line_parser.get_nonspace_quoted(field + strlen(field)); } } } // a case analysis: // Key < 128 counts as both key and pitch // A-G implies pitch AND key unless key given too // K60 P60 -- both are specified, use 'em // K60 P60 C4 -- overconstrained, an error // K60 C4 -- overconstrained // K60 -- OK, pitch is 60 // C4 P60 -- over constrained // P60 -- OK, key is from before, pitch is 60 // C4 -- OK, key is 60, pitch is 60 // <nothing> -- OK, key and pitch from before // K200 with P60 ok, pitch is 60 // K200 with neither P60 nor C4 uses // pitch from before // figure out what the key/instance is: if (new_key_flag) { // it was directly specified key = new_key; if (key < 128 && new_note_flag) { parse_error("", 0, "Pitch specified twice"); } } else if (new_note_flag) { // "A"-"G" used key = new_note; } if (new_pitch_flag) { pitch = new_pitch; } else if (key < 128) { pitch = key; } // now we've acquired new parameters // if (it is a note, then enter the note if (valid) { // change tempo or beat attributes = process_attributes(attributes, time); // if there's a duration or pitch, make a note: if (new_pitch_flag || dur_flag || new_note_flag) { new_key_flag = false; new_pitch_flag = false; Alg_note_ptr note_ptr = new Alg_note; note_ptr->chan = voice; note_ptr->time = time; note_ptr->dur = dur; note_ptr->set_identifier(key); note_ptr->pitch = pitch; note_ptr->loud = loud; note_ptr->parameters = attributes; seq->add_event(note_ptr, track_num); // sort later if (seq->get_real_dur() < (time + dur)) seq->set_real_dur(time + dur); } else { int update_key = -1; // key or pitch must appear explicitly; otherwise // update applies to channel if (new_key_flag || new_pitch_flag) { update_key = key; } if (loud_flag) { Alg_update_ptr new_upd = new Alg_update; new_upd->chan = voice; new_upd->time = time; new_upd->set_identifier(update_key); new_upd->parameter.set_attr(symbol_table.insert_string("loudr")); new_upd->parameter.r = pitch; seq->add_event(new_upd, track_num); if (seq->get_real_dur() < time) seq->set_real_dur(time); } if (attributes) { while (attributes) { Alg_update_ptr new_upd = new Alg_update; new_upd->chan = voice; new_upd->time = time; new_upd->set_identifier(update_key); new_upd->parameter = attributes->parm; seq->add_event(new_upd, track_num); Alg_parameters_ptr p = attributes; attributes = attributes->next; p->parm.s = NULL; // so we don't delete the string delete p; } } } if (next_flag) { time = time + next; } else if (dur_flag) { time = time + dur; } } } readline(); } //print "Finished reading score" if (!error_flag) { seq->convert_to_seconds(); // make sure format is correct // seq->notes.sort('event_greater_than'); } // real_dur is valid, translate to beat_dur seq->set_beat_dur((seq->get_time_map())->time_to_beat(seq->get_real_dur())); // print "parse returns error_flag", error_flag return error_flag; } #endif /* EXPERIMENTAL_NOTE_TRACK */ //Note that this is an #ifdef, not an #ifndef #ifdef EXPERIMENTAL_NOTE_TRACK long Alg_reader::parse_chan(char *field) { char *int_string = field + 1; char *msg = "Integer or - expected"; char *p = int_string; char c; // check that all chars in int_string are digits or '-': while (c = *p++) { if (!isdigit(c) && c != '-') { parse_error(field, p - field - 1, msg); return 0; } } p--; // p now points to end-of-string character if (p - int_string == 0) { // bad: string length is zero parse_error(field, 1, msg); return 0; } if (p - int_string == 1 && int_string[0] == '-') { // special case: entire string is "-", interpret as -1 return -1; } return atoi(int_string); } #endif /* EXPERIMENTAL_NOTE_TRACK */ #ifndef EXPERIMENTAL_NOTE_TRACK long Allegro_reader::parse_int(char *field) { char int_string[field_max]; strcpy(int_string, field + 1); char *msg = "Integer expected"; char *p = int_string; char c; while (c = *p++) { if (!isdigit(c)) { parse_error(field, 1, msg); return 0; } } if (strlen(int_string) < 1) { parse_error(field, 1, msg); return 0; } return atoi(int_string); } #else /* EXPERIMENTAL_NOTE_TRACK */ long Alg_reader::parse_int(char *field) { char *int_string = field + 1; char *msg = "Integer expected"; char *p = int_string; char c; // check that all chars in int_string are digits: while (c = *p++) { if (!isdigit(c)) { parse_error(field, p - field - 1, msg); return 0; } } p--; // p now points to end-of-string character if (p - int_string == 0) { // bad: string length is zero parse_error(field, 1, msg); return 0; } return atoi(int_string); } #endif /* EXPERIMENTAL_NOTE_TRACK */ #ifndef EXPERIMENTAL_NOTE_TRACK int Allegro_reader::find_real_in(char *field, int n) #else /* EXPERIMENTAL_NOTE_TRACK */ int Alg_reader::find_real_in(char *field, int n) #endif /* EXPERIMENTAL_NOTE_TRACK */ { // scans from offset n to the end of a real constant bool decimal = false; int len = strlen(field); for (int i = n; i < len; i++) { char c = field[i]; if (!isdigit(c)) { if (c == '.' && !decimal) { decimal = true; } else { return i; } } } return strlen(field); } #ifndef EXPERIMENTAL_NOTE_TRACK double Allegro_reader::parse_real(char *field) #else /* EXPERIMENTAL_NOTE_TRACK */ double Alg_reader::parse_real(char *field) #endif /* EXPERIMENTAL_NOTE_TRACK */ { char real_string[80]; char *msg = "Real expected"; bool decimal = false; int last = find_real_in(field, 1); subseq(real_string, field, 1, last); if (last <= 1 || last < (int) strlen(field)) { parse_error(field, 1, msg); return 0; } return atof(real_string); } #ifndef EXPERIMENTAL_NOTE_TRACK void Allegro_reader::parse_error(char *field, long offset, char *message) #else /* EXPERIMENTAL_NOTE_TRACK */ void Alg_reader::parse_error(char *field, long offset, char *message) #endif /* EXPERIMENTAL_NOTE_TRACK */ { int position = line_parser.pos - strlen(field) + offset; error_flag = true; puts(line_parser.string); for (int i = 0; i < position; i++) { putc(' ', stdout); } putc('^', stdout); printf(" %s\n", message); } double duration_lookup[] = { 0.25, 0.5, 1.0, 2.0, 4.0 }; #ifndef EXPERIMENTAL_NOTE_TRACK double Allegro_reader::parse_dur(char *field, double base) { char *msg = "Duration expected"; char real_string[80]; char *durs = "SIQHW"; char *p; int last; double dur; if (strlen(field) < 2) { // fall through to error message return -1; } else if (isdigit(field[1])) { last = find_real_in(field, 1); subseq(real_string, field, 1, last); dur = atof(real_string); // convert dur from seconds to beats dur = seq.map.time_to_beat(base + dur) - seq.map.time_to_beat(base); } else if (p = strchr(durs, field[1])) { dur = duration_lookup[p - durs]; last = 2; } else { parse_error(field, 1, msg); return 0; } dur = parse_after_dur(dur, field, last, base); dur = seq.map.beat_to_time(seq.map.time_to_beat(base) + dur) - base; return dur; } #else /* EXPERIMENTAL_NOTE_TRACK */ double Alg_reader::parse_dur(char *field, double base) { char *msg = "Duration expected"; char real_string[80]; char *durs = "SIQHW"; char *p; int last; double dur; if (strlen(field) < 2) { // fall through to error message return -1; } else if (isdigit(field[1])) { last = find_real_in(field, 1); subseq(real_string, field, 1, last); dur = atof(real_string); // convert dur from seconds to beats dur = seq->get_time_map()->time_to_beat(base + dur) - seq->get_time_map()->time_to_beat(base); } else if (p = strchr(durs, field[1])) { dur = duration_lookup[p - durs]; last = 2; } else { parse_error(field, 1, msg); return 0; } dur = parse_after_dur(dur, field, last, base); dur = seq->get_time_map()->beat_to_time( seq->get_time_map()->time_to_beat(base) + dur) - base; return dur; } #endif /* EXPERIMENTAL_NOTE_TRACK */ #ifndef EXPERIMENTAL_NOTE_TRACK double Allegro_reader::parse_after_dur(double dur, char *field, int n, double base) { char a_string[80]; if ((int) strlen(field) == n) { return dur; } if (field[n] == 'T') { return parse_after_dur(dur * 2/3, field, n + 1, base); } if (field[n] == '.') { return parse_after_dur(dur * 1.5, field, n + 1, base); } if (isdigit(field[n])) { int last = find_real_in(field, n); subseq(a_string, field, n, last); double f = atof(a_string); return parse_after_dur(dur * f, field, last, base); } if (field[n] == '+') { subseq(a_string, field, n + 1, -1); return dur + parse_dur(a_string, seq.map.beat_to_time( seq.map.time_to_beat(base) + dur)); } parse_error(field, n, "Unexpected character in duration"); return dur; } #else /* EXPERIMENTAL_NOTE_TRACK */ double Alg_reader::parse_after_dur(double dur, char *field, int n, double base) { char a_string[80]; if ((int) strlen(field) == n) { return dur; } if (field[n] == 'T') { return parse_after_dur(dur * 2/3, field, n + 1, base); } if (field[n] == '.') { return parse_after_dur(dur * 1.5, field, n + 1, base); } if (isdigit(field[n])) { int last = find_real_in(field, n); subseq(a_string, field, n, last); double f = atof(a_string); return parse_after_dur(dur * f, field, last, base); } if (field[n] == '+') { subseq(a_string, field, n + 1, -1); return dur + parse_dur( a_string, seq->get_time_map()->beat_to_time( seq->get_time_map()->time_to_beat(base) + dur)); } parse_error(field, n, "Unexpected character in duration"); return dur; }
bool Alg_midifile_reader::parse() { channel_offset = 0; seq->convert_to_beats(); midifile(); seq->set_real_dur(seq->get_time_map()->beat_to_time(seq->get_beat_dur())); return midifile_error != 0; }
Alg_seq_ptr NoteTrack::MakeExportableSeq() { double offset = GetOffset(); if (offset == 0) return mSeq; // make a copy, deleting events that are shifted before time 0 double start = -offset; if (start < 0) start = 0; // notes that begin before "start" are not included even if they // extend past "start" (because "all" parameter is set to false) Alg_seq_ptr seq = mSeq->copy(start, mSeq->get_dur() - start, false); if (offset > 0) { // swap seq and mSeq so that Shift operates on the new copy Alg_seq_ptr old_seq = mSeq; mSeq = seq; Shift(offset); seq = mSeq; // undo the swap mSeq = old_seq; #ifdef OLD_CODE // now shift events by offset. This must be done with an integer // number of measures, so first, find the beats-per-measure double beats_per_measure = 4.0; Alg_time_sig_ptr tsp = NULL; if (seq->time_sig.length() > 0 && seq->time_sig[0].beat < ALG_EPS) { // there is an initial time signature tsp = &(seq->time_sig[0]); beats_per_measure = (tsp->num * 4) / tsp->den; } // also need the initial tempo double bps = ALG_DEFAULT_BPM / 60; Alg_time_map_ptr map = seq->get_time_map(); Alg_beat_ptr bp = &(map->beats[0]); if (bp->time < ALG_EPS) { // tempo change at time 0 if (map->beats.len > 1) { // compute slope to get tempo bps = (map->beats[1].beat - map->beats[0].beat) / (map->beats[1].time - map->beats[0].time); } else if (seq->get_time_map()->last_tempo_flag) { bps = seq->get_time_map()->last_tempo; } } // find closest number of measures to fit in the gap // number of measures is offset / measure_time double measure_time = beats_per_measure / bps; // seconds per measure int n = ROUND(offset / measure_time); if (n == 0) n = 1; // we will insert n measures. Compute the desired duration of each. measure_time = offset / n; bps = beats_per_measure / measure_time; // insert integer multiple of measures at beginning seq->convert_to_beats(); seq->insert_silence(0, beats_per_measure * n); // make sure time signature at 0 is correct if (tsp) { seq->set_time_sig(0, tsp->num, tsp->den); } // adjust tempo to match offset seq->set_tempo(bps * 60.0, 0, beats_per_measure * n); #endif } else { // if offset is negative, it might not be a multiple of beats, but // we want to preserve the relative positions of measures. I.e. we // should shift barlines and time signatures as well as notes. // Insert a time signature at the first bar-line if necessary. // Translate start from seconds to beats and call it beat: double beat = mSeq->get_time_map()->time_to_beat(start); // Find the time signature in mSeq in effect at start (beat): int i = mSeq->time_sig.find_beat(beat); // i is where you would insert a new time sig at beat, // Case 1: beat coincides with a time sig at i. Time signature // at beat means that there is a barline at beat, so when beat // is shifted to 0, the relative barline positions are preserved if (mSeq->time_sig.length() > 0 && within(beat, mSeq->time_sig[i].beat, ALG_EPS)) { // beat coincides with time signature change, so offset must // be a multiple of beats /* do nothing */ ; // Case 2: there is no time signature before beat. } else if (i == 0 && (mSeq->time_sig.length() == 0 || mSeq->time_sig[i].beat > beat)) { // If beat does not fall on an implied barline, we need to // insert a time signature. double measures = beat / 4.0; double imeasures = ROUND(measures); if (!within(measures, imeasures, ALG_EPS)) { double bar_offset = (int(measures) + 1) * 4.0 - beat; seq->set_time_sig(bar_offset, 4, 4); } // This case should never be true because if i == 0, either there // are no time signatures before beat (Case 2), // or there is one time signature at beat (Case 1) } else if (i == 0) { /* do nothing (might be good to assert(false)) */ ; // Case 3: i-1 must be the effective time sig position } else { i -= 1; // index the time signature in effect at beat Alg_time_sig_ptr tsp = &(mSeq->time_sig[i]); double beats_per_measure = (tsp->num * 4) / tsp->den; double measures = (beat - tsp->beat) / beats_per_measure; int imeasures = ROUND(measures); if (!within(measures, imeasures, ALG_EPS)) { // beat is not on a measure, so we need to insert a time sig // to force a bar line at the first measure location after // beat double bar = tsp->beat + beats_per_measure * (int(measures) + 1); double bar_offset = bar - beat; // insert new time signature at bar_offset in new sequence // It will have the same time signature, but the position will // force a barline to match the barlines in mSeq seq->set_time_sig(bar_offset, tsp->num, tsp->den); } // else beat coincides with a barline, so no need for an extra // time signature to force barline alignment } } return seq; }
bool MidiImport::readSMF( TrackContainer* tc ) { QString filename = file().fileName(); closeFile(); const int preTrackSteps = 2; QProgressDialog pd( TrackContainer::tr( "Importing MIDI-file..." ), TrackContainer::tr( "Cancel" ), 0, preTrackSteps, gui->mainWindow() ); pd.setWindowTitle( TrackContainer::tr( "Please wait..." ) ); pd.setWindowModality(Qt::WindowModal); pd.setMinimumDuration( 0 ); pd.setValue( 0 ); Alg_seq_ptr seq = new Alg_seq(filename.toLocal8Bit(), true); seq->convert_to_beats(); pd.setMaximum( seq->tracks() + preTrackSteps ); pd.setValue( 1 ); // 128 CC + Pitch Bend smfMidiCC ccs[129]; smfMidiChannel chs[256]; MeterModel & timeSigMM = Engine::getSong()->getTimeSigModel(); AutomationPattern * timeSigNumeratorPat = AutomationPattern::globalAutomationPattern( &timeSigMM.numeratorModel() ); AutomationPattern * timeSigDenominatorPat = AutomationPattern::globalAutomationPattern( &timeSigMM.denominatorModel() ); // TODO: adjust these to Time.Sig changes double beatsPerTact = 4; double ticksPerBeat = DefaultTicksPerTact / beatsPerTact; // Time-sig changes Alg_time_sigs * timeSigs = &seq->time_sig; for( int s = 0; s < timeSigs->length(); ++s ) { Alg_time_sig timeSig = (*timeSigs)[s]; // Initial timeSig, set song-default value if(/* timeSig.beat == 0*/ true ) { // TODO set song-global default value printf("Another timesig at %f\n", timeSig.beat); timeSigNumeratorPat->putValue( timeSig.beat*ticksPerBeat, timeSig.num ); timeSigDenominatorPat->putValue( timeSig.beat*ticksPerBeat, timeSig.den ); } else { } } pd.setValue( 2 ); // Tempo stuff AutomationPattern * tap = tc->tempoAutomationPattern(); if( tap ) { tap->clear(); Alg_time_map * timeMap = seq->get_time_map(); Alg_beats & beats = timeMap->beats; for( int i = 0; i < beats.len - 1; i++ ) { Alg_beat_ptr b = &(beats[i]); double tempo = ( beats[i + 1].beat - b->beat ) / ( beats[i + 1].time - beats[i].time ); tap->putValue( b->beat * ticksPerBeat, tempo * 60.0 ); } if( timeMap->last_tempo_flag ) { Alg_beat_ptr b = &( beats[beats.len - 1] ); tap->putValue( b->beat * ticksPerBeat, timeMap->last_tempo * 60.0 ); } } // Song events for( int e = 0; e < seq->length(); ++e ) { Alg_event_ptr evt = (*seq)[e]; if( evt->is_update() ) { printf("Unhandled SONG update: %d %f %s\n", evt->get_type_code(), evt->time, evt->get_attribute() ); } } // Tracks for( int t = 0; t < seq->tracks(); ++t ) { QString trackName = QString( tr( "Track" ) + " %1" ).arg( t ); Alg_track_ptr trk = seq->track( t ); pd.setValue( t + preTrackSteps ); for( int c = 0; c < 129; c++ ) { ccs[c].clear(); } // Now look at events for( int e = 0; e < trk->length(); ++e ) { Alg_event_ptr evt = (*trk)[e]; if( evt->chan == -1 ) { bool handled = false; if( evt->is_update() ) { QString attr = evt->get_attribute(); if( attr == "tracknames" && evt->get_update_type() == 's' ) { trackName = evt->get_string_value(); handled = true; } } if( !handled ) { // Write debug output printf("MISSING GLOBAL HANDLER\n"); printf(" Chn: %d, Type Code: %d, Time: %f", (int) evt->chan, evt->get_type_code(), evt->time ); if ( evt->is_update() ) { printf( ", Update Type: %s", evt->get_attribute() ); if ( evt->get_update_type() == 'a' ) { printf( ", Atom: %s", evt->get_atom_value() ); } } printf( "\n" ); } } else if( evt->is_note() && evt->chan < 256 ) { smfMidiChannel * ch = chs[evt->chan].create( tc, trackName ); Alg_note_ptr noteEvt = dynamic_cast<Alg_note_ptr>( evt ); int ticks = noteEvt->get_duration() * ticksPerBeat; Note n( (ticks < 1 ? 1 : ticks ), noteEvt->get_start_time() * ticksPerBeat, noteEvt->get_identifier() - 12, noteEvt->get_loud()); ch->addNote( n ); } else if( evt->is_update() ) { smfMidiChannel * ch = chs[evt->chan].create( tc, trackName ); double time = evt->time*ticksPerBeat; QString update( evt->get_attribute() ); if( update == "programi" ) { long prog = evt->get_integer_value(); if( ch->isSF2 ) { ch->it_inst->childModel( "bank" )->setValue( 0 ); ch->it_inst->childModel( "patch" )->setValue( prog ); } else { const QString num = QString::number( prog ); const QString filter = QString().fill( '0', 3 - num.length() ) + num + "*.pat"; const QString dir = "/usr/share/midi/" "freepats/Tone_000/"; const QStringList files = QDir( dir ). entryList( QStringList( filter ) ); if( ch->it_inst && !files.empty() ) { ch->it_inst->loadFile( dir+files.front() ); } } } else if( update.startsWith( "control" ) || update == "bendr" ) { int ccid = update.mid( 7, update.length()-8 ).toInt(); if( update == "bendr" ) { ccid = 128; } if( ccid <= 128 ) { double cc = evt->get_real_value(); AutomatableModel * objModel = NULL; switch( ccid ) { case 0: if( ch->isSF2 && ch->it_inst ) { objModel = ch->it_inst->childModel( "bank" ); printf("BANK SELECT %f %d\n", cc, (int)(cc*127.0)); cc *= 127.0f; } break; case 7: objModel = ch->it->volumeModel(); cc *= 100.0f; break; case 10: objModel = ch->it->panningModel(); cc = cc * 200.f - 100.0f; break; case 128: objModel = ch->it->pitchModel(); cc = cc * 100.0f; break; default: //TODO: something useful for other CCs break; } if( objModel ) { if( time == 0 && objModel ) { objModel->setInitValue( cc ); } else { if( ccs[ccid].at == NULL ) { ccs[ccid].create( tc, trackName + " > " + ( objModel != NULL ? objModel->displayName() : QString("CC %1").arg(ccid) ) ); } ccs[ccid].putValue( time, objModel, cc ); } } } } else { printf("Unhandled update: %d %d %f %s\n", (int) evt->chan, evt->get_type_code(), evt->time, evt->get_attribute() ); } } } } delete seq; for( int c=0; c < 256; ++c ) { if( !chs[c].hasNotes && chs[c].it ) { printf(" Should remove empty track\n"); // must delete trackView first - but where is it? //tc->removeTrack( chs[c].it ); //it->deleteLater(); } } // Set channel 10 to drums as per General MIDI's orders if( chs[9].hasNotes && chs[9].it_inst && chs[9].isSF2 ) { // AFAIK, 128 should be the standard bank for drums in SF2. // If not, this has to be made configurable. chs[9].it_inst->childModel( "bank" )->setValue( 128 ); chs[9].it_inst->childModel( "patch" )->setValue( 0 ); } return true; }
bool Alg_reader::parse() { int voice = 0; int key = 60; double loud = 100.0; double pitch = 60.0; double dur = 1.0; double time = 0.0; int track_num = 0; seq->convert_to_seconds(); //seq->set_real_dur(0.0); // just in case it's not initialized already readline(); bool valid = false; // ignore blank lines while (line_parser_flag) { bool time_flag = false; bool next_flag = false; double next; bool voice_flag = false; bool loud_flag = false; bool dur_flag = false; bool new_pitch_flag = false; // "P" syntax or "A"-"G" syntax double new_pitch = 0.0; bool new_key_flag = false; // "K" syntax int new_key = 0; Alg_parameters_ptr attributes = NULL; if (line_parser.peek() == '#') { // look for #track line_parser.get_nonspace_quoted(field); if (streql(field.c_str(), "#track")) { line_parser.get_nonspace_quoted(field); // number field.insert(0, " "); // need char at beginning because // parse_int ignores the first character of the argument track_num = parse_int(field); seq->add_track(track_num); // maybe we have a sequence or track name line_parser.get_remainder(field); // if there is a non-space character after #track n then // use it as sequence or track name. Note that because we // skip over spaces, a sequence or track name cannot begin // with leading blanks. Another decision is that the name // must be at time zero if (field.length() > 0) { // insert the field as sequence name or track name Alg_update_ptr update = new Alg_update; update->chan = -1; update->time = 0; update->set_identifier(-1); // sequence name is whatever is on track 0 // other tracks have track names const char *attr = (track_num == 0 ? "seqnames" : "tracknames"); update->parameter.set_attr( symbol_table.insert_string(attr)); update->parameter.s = heapify(field.c_str()); seq->add_event(update, track_num); } } else if (streql(field.c_str(), "#offset")) { if (offset_found) { parse_error(field, 0, "#offset specified twice"); } offset_found = true; line_parser.get_nonspace_quoted(field); // number field.insert(0, " "); // need char at beginning because // parse_real ignores first character in the argument offset = parse_real(field); } } else { // we must have a track to insert into if (seq->tracks() == 0) seq->add_track(0); line_parser.get_nonspace_quoted(field); char pk = line_parser.peek(); // attributes are parsed as two adjacent nonspace_quoted tokens // so we have to conditionally call get_nonspace_quoted() again if (pk && !isspace(pk)) { string field2; line_parser.get_nonspace_quoted(field2); field.append(field2); } while (field[0]) { char first = toupper(field[0]); if (strchr("ABCDEFGKLPUSIQHW-", first)) { valid = true; // it's a note or event } if (first == 'V') { if (voice_flag) { parse_error(field, 0, "Voice specified twice"); } else { voice = parse_chan(field); } voice_flag = true; } else if (first == 'T') { if (time_flag) { parse_error(field, 0, "Time specified twice"); } else { time = parse_dur(field, 0.0); } time_flag = true; } else if (first == 'N') { if (next_flag) { parse_error(field, 0, "Next specified twice"); } else { next = parse_dur(field, time); } next_flag = true; } else if (first == 'K') { if (new_key_flag) { parse_error(field, 0, "Key specified twice"); } else { new_key = parse_key(field); new_key_flag = true; } } else if (first == 'L') { if (loud_flag) { parse_error(field, 0, "Loudness specified twice"); } else { loud = parse_loud(field); } loud_flag = true; } else if (first == 'P') { if (new_pitch_flag) { parse_error(field, 0, "Pitch specified twice"); } else { new_pitch = parse_pitch(field); new_pitch_flag = true; } } else if (first == 'U') { if (dur_flag) { parse_error(field, 0, "Dur specified twice"); } else { dur = parse_dur(field, time); dur_flag = true; } } else if (strchr("SIQHW", first)) { if (dur_flag) { parse_error(field, 0, "Dur specified twice"); } else { // prepend 'U' to field, copy EOS too field.insert((unsigned int) 0, 1, 'U'); dur = parse_dur(field, time); dur_flag = true; } } else if (strchr("ABCDEFG", first)) { if (new_pitch_flag) { parse_error(field, 0, "Pitch specified twice"); } else { // prepend 'P' to field field.insert((unsigned int) 0, 1, 'P'); new_pitch = parse_pitch(field); new_pitch_flag = true; } } else if (first == '-') { Alg_parameter parm; if (parse_attribute(field, &parm)) { // enter attribute-value pair attributes = new Alg_parameters(attributes); attributes->parm = parm; parm.s = NULL; // protect string from deletion by destructor } } else { parse_error(field, 0, "Unknown field"); } if (error_flag) { field[0] = 0; // exit the loop } else { line_parser.get_nonspace_quoted(field); pk = line_parser.peek(); // attributes are parsed as two adjacent nonspace_quoted // tokens so we have to conditionally call // get_nonspace_quoted() again if (pk && !isspace(pk)) { string field2; line_parser.get_nonspace_quoted(field2); field.append(field2); } } } // a case analysis: // Key < 128 implies pitch unless pitch is explicitly given // Pitch implies Key unless key is explicitly given, // Pitch is rounded to nearest integer to determine the Key // if necessary, so MIDI files will lose the pitch fraction // A-G is a Pitch specification (therefore it implies Key) // K60 P60 -- both are specified, use 'em // K60 P60 C4 -- overconstrained, an error // K60 C4 -- OK, but K60 is already implied by C4 // K60 -- OK, pitch is 60 // C4 P60 -- over constrained // P60 -- OK, key is 60 // P60.1 -- OK, key is 60 // C4 -- OK, key is 60, pitch is 60 // <nothing> -- OK, key and pitch from before // K200 P60 -- ok, pitch is 60 // K200 with neither P60 nor C4 uses // pitch from before // figure out what the key/instance is: if (new_key_flag) { // it was directly specified key = new_key; } else if (new_pitch_flag) { // pitch was specified, but key was not; get key from pitch key = (int) (new_pitch + 0.5); // round to integer key number } if (new_pitch_flag) { pitch = new_pitch; } else if (key < 128 && new_key_flag) { // no explicit pitch, but key < 128, so it implies pitch pitch = key; new_pitch_flag = true; } // now we've acquired new parameters // if (it is a note, then enter the note if (valid) { // change tempo or beat attributes = process_attributes(attributes, time); // if there's a duration or pitch, make a note: if (new_pitch_flag || dur_flag) { Alg_note_ptr note_ptr = new Alg_note; note_ptr->chan = voice; note_ptr->time = time; note_ptr->dur = dur; note_ptr->set_identifier(key); note_ptr->pitch = (float) pitch; note_ptr->loud = (float) loud; note_ptr->parameters = attributes; seq->add_event(note_ptr, track_num); // sort later if (seq->get_real_dur() < (time + dur)) seq->set_real_dur(time + dur); } else { int update_key = -1; // key must appear explicitly; otherwise // update applies to channel if (new_key_flag) { update_key = key; } if (loud_flag) { Alg_update_ptr new_upd = new Alg_update; new_upd->chan = voice; new_upd->time = time; new_upd->set_identifier(update_key); new_upd->parameter.set_attr(symbol_table.insert_string("loudr")); new_upd->parameter.r = pitch; seq->add_event(new_upd, track_num); if (seq->get_real_dur() < time) seq->set_real_dur(time); } if (attributes) { while (attributes) { Alg_update_ptr new_upd = new Alg_update; new_upd->chan = voice; new_upd->time = time; new_upd->set_identifier(update_key); new_upd->parameter = attributes->parm; seq->add_event(new_upd, track_num); Alg_parameters_ptr p = attributes; attributes = attributes->next; p->parm.s = NULL; // so we don't delete the string delete p; } } } if (next_flag) { time = time + next; } else if (dur_flag || new_pitch_flag) { // a note: incr by dur time = time + dur; } } } readline(); } if (!error_flag) { // why not convert even if there was an error? -RBD seq->convert_to_seconds(); // make sure format is correct } // real_dur is valid, translate to beat_dur seq->set_beat_dur((seq->get_time_map())->time_to_beat(seq->get_real_dur())); return error_flag; }
#include "assert.h" #include "stdlib.h" #include "stdio.h" #include "allegro.h" #include "string.h" #include "ctype.h" //#include "memory.h" #include "trace.h" #include "strparse.h" #ifndef EXPERIMENTAL_NOTE_TRACK #include "allegrord.h" #endif /* EXPERIMENTAL_NOTE_TRACK */ #define streql(s1, s2) (strcmp(s1, s2) == 0) #define field_max 80 //Note that this is an #ifdef, not an #ifndef #ifdef EXPERIMENTAL_NOTE_TRACK class Alg_reader { public: FILE *file; int line_no; String_parse line_parser; bool line_parser_flag; char field[field_max]; bool error_flag; Alg_seq_ptr seq; double tsnum; double tsden; Alg_reader(FILE *a_file, Alg_seq_ptr new_seq); void readline(); Alg_parameters_ptr process_attributes(Alg_parameters_ptr attributes, double time); bool parse(); long parse_chan(char *field); long parse_int(char *field); int find_real_in(char *field, int n); double parse_real(char *field); void parse_error(char *field, long offset, char *message); double parse_dur(char *field, double base); double parse_after_dur(double dur, char *field, int n, double base); double parse_loud(char *field); long parse_key(char *field); double parse_pitch(char *field); long parse_after_key(int key, char *field, int n); long find_int_in(char *field, int n); bool parse_attribute(char *field, Alg_parameter_ptr parm); bool parse_val(Alg_parameter_ptr param, char *s, int i); bool check_type(char type_char, Alg_parameter_ptr param); }; #endif /* EXPERIMENTAL_NOTE_TRACK */ void subseq(char *result, char *source, int from, int to) { memcpy(result, source + from, to - from); result[to - from] = 0; } #ifndef EXPERIMENTAL_NOTE_TRACK double Allegro_reader::parse_pitch(char *field) #else /* EXPERIMENTAL_NOTE_TRACK */ double Alg_reader::parse_pitch(char *field) #endif /* EXPERIMENTAL_NOTE_TRACK */ { if (isdigit(field[1])) { char real_string[80]; int last = find_real_in(field, 1); subseq(real_string, field, 1, last); return atof(real_string); } else { return (double) parse_key(field); } } #ifndef EXPERIMENTAL_NOTE_TRACK Allegro_reader::Allegro_reader(FILE *a_file) { file = a_file; // save the file line_parser_flag = false; line_no = 0; seq = Seq(); tsnum = 4; // default time signature tsden = 4; } #else /* EXPERIMENTAL_NOTE_TRACK */ // it is the responsibility of the caller to delete // the seq Alg_reader::Alg_reader(FILE *a_file, Alg_seq_ptr new_seq) { file = a_file; // save the file line_parser_flag = false; line_no = 0; tsnum = 4; // default time signature tsden = 4; seq = new_seq; } #endif /* EXPERIMENTAL_NOTE_TRACK */ //Note that this is an #ifdef, not an #ifndef #ifdef EXPERIMENTAL_NOTE_TRACK Alg_seq_ptr alg_read(FILE *file, Alg_seq_ptr new_seq) // read a sequence from allegro file { if (!new_seq) new_seq = new Alg_seq(); Alg_reader alg_reader(file, new_seq); alg_reader.parse(); return alg_reader.seq; } #endif /* EXPERIMENTAL_NOTE_TRACK */ #ifndef EXPERIMENTAL_NOTE_TRACK void Allegro_reader::readline() #else /* EXPERIMENTAL_NOTE_TRACK */ void Alg_reader::readline() #endif /* EXPERIMENTAL_NOTE_TRACK */ { char line[256]; char *line_flag = fgets(line, 256, file); line_parser_flag = false; if (line_flag) { line_parser.init(line); line_parser_flag = true; error_flag = false; } } #ifndef EXPERIMENTAL_NOTE_TRACK void Allegro_reader::process_attributes(Parameters_ptr attributes, double time) { // print "process_attributes:", attributes bool ts_flag; if (attributes) { Parameters_ptr a; if (a = Parameters::remove_key(&attributes, "tempor")) { double tempo = a->parm.r; seq.insert_tempo(tempo, seq.map.time_to_beat(time)); } if (a = Parameters::remove_key(&attributes, "beatr")) { double beat = a->parm.r; seq.insert_beat(time, beat); } if (a = Parameters::remove_key(&attributes, "tsnumr")) { tsnum = a->parm.r; ts_flag = true; } if (a = Parameters::remove_key(&attributes, "tsdenr")) { tsden = a->parm.r; ts_flag = true; } if (ts_flag) { seq.set_time_sig(seq.map.time_to_beat(time), tsnum, tsden); } } } #else /* EXPERIMENTAL_NOTE_TRACK */ Alg_parameters_ptr Alg_reader::process_attributes( Alg_parameters_ptr attributes, double time) { // print "process_attributes:", attributes bool ts_flag = false; if (attributes) { Alg_parameters_ptr a; bool in_seconds = seq->get_units_are_seconds(); if (a = Alg_parameters::remove_key(&attributes, "tempor")) { double tempo = a->parm.r; seq->insert_tempo(tempo, seq->get_time_map()->time_to_beat(time)); } if (a = Alg_parameters::remove_key(&attributes, "beatr")) { double beat = a->parm.r; seq->insert_beat(time, beat); } if (a = Alg_parameters::remove_key(&attributes, "timesig_numr")) { tsnum = a->parm.r; ts_flag = true; } if (a = Alg_parameters::remove_key(&attributes, "timesig_denr")) { tsden = a->parm.r; ts_flag = true; } if (ts_flag) { seq->set_time_sig(seq->get_time_map()->time_to_beat(time), tsnum, tsden); } if (in_seconds) seq->convert_to_seconds(); } return attributes; // in case it was modified } #endif /* EXPERIMENTAL_NOTE_TRACK */ #ifndef EXPERIMENTAL_NOTE_TRACK bool Allegro_reader::parse() { int voice = 0; int key = 60; double loud = 100.0; double pitch = 60.0; double dur = 1.0; double time = 0.0; readline(); bool valid = false; // ignore blank lines while (line_parser_flag) { bool time_flag = false; bool next_flag = false; double next; bool voice_flag = false; bool loud_flag = false; bool dur_flag = false; bool new_pitch_flag = false; // "P" syntax double new_pitch = 0.0; bool new_key_flag = false; // "K" syntax int new_key = 0; bool new_note_flag = false; // "A"-"G" syntax int new_note = 0; Parameters_ptr attributes = NULL; line_parser.get_nonspace_quoted(field); char pk = line_parser.peek(); if (pk && !isspace(pk)) { line_parser.get_nonspace_quoted(field + strlen(field)); } while (field[0]) { // print "field", "|";field;"|", "|";line_parser.string;"|", line_parser.pos char first = toupper(field[0]); if (strchr("ABCDEFGKLPUSIQHW-", first)) { valid = true; // it's a note or event } if (first == 'V') { if (voice_flag) { parse_error(field, 0, "Voice specified twice"); } else { voice = parse_int(field); } voice_flag = true; } else if (first == 'T') { if (time_flag) { parse_error(field, 0, "Time specified twice"); } else { time = parse_dur(field, 0.0); } time_flag = true; } else if (first == 'N') { if (next_flag) { parse_error(field, 0, "Next specified twice"); } else { next = parse_dur(field, time); } next_flag = true; } else if (first == 'K') { if (new_key_flag) { parse_error(field, 0, "Key specified twice"); } else { new_key = parse_key(field); new_key_flag = true; } } else if (first == 'L') { if (loud_flag) { parse_error(field, 0, "Loudness specified twice"); } else { loud = parse_loud(field); } loud_flag = true; } else if (first == 'P') { if (new_note_flag || new_pitch_flag) { parse_error(field, 0, "Pitch specified twice"); } else { new_pitch = parse_pitch(field); new_pitch_flag = true; } } else if (first == 'U') { if (dur_flag) { parse_error(field, 0, "Dur specified twice"); } else { dur = parse_dur(field, time); dur_flag = true; } } else if (strchr("SIQHW", first)) { if (dur_flag) { parse_error(field, 0, "Dur specified twice"); } else { // prepend 'U' to field, copy EOS too memmove(field + 1, field, strlen(field) + 1); field[0] = 'U'; dur = parse_dur(field, time); dur_flag = true; } } else if (strchr("ABCDEFG", first)) { if (new_note_flag || new_pitch_flag) { parse_error(field, 0, "Pitch specified twice"); } else { // prepend 'K' to field, copy EOS too memmove(field + 1, field, strlen(field) + 1); field[0] = 'K'; new_note = parse_key(field); new_note_flag = true; } } else if (first == '-') { Parameter parm; if (parse_attribute(field, &parm)) { // enter attribute-value pair attributes = new Parameters(attributes); attributes->parm = parm; parm.s = NULL; // protect string from deletion by destructor } } else { parse_error(field, 0, "Unknown field"); } if (error_flag) { field[0] = 0; // exit the loop } else { line_parser.get_nonspace_quoted(field); pk = line_parser.peek(); if (pk && !isspace(pk)) { line_parser.get_nonspace_quoted(field + strlen(field)); } } } // a case analysis: // Key < 128 counts as both key and pitch // A-G implies pitch AND key unless key given too // K60 P60 -- both are specified, use 'em // K60 P60 C4 -- overconstrained, an error // K60 C4 -- overconstrained // K60 -- OK, pitch is 60 // C4 P60 -- over constrained // P60 -- OK, key is from before, pitch is 60 // C4 -- OK, key is 60, pitch is 60 // <nothing> -- OK, key and pitch from before // K200 with P60 ok, pitch is 60 // K200 with neither P60 nor C4 uses // pitch from before // figure out what the key/instance is: if (new_key_flag) { // it was directly specified key = new_key; if (key < 128 && new_note_flag) { parse_error("", 0, "Pitch specified twice"); } } else if (new_note_flag) { // "A"-"G" used key = new_note; } if (new_pitch_flag) { pitch = new_pitch; } else if (key < 128) { pitch = key; } // now we've acquired new parameters // if (it is a note, then enter the note if (valid) { // change tempo or beat process_attributes(attributes, time); // if there's a duration or pitch, make a note: if (new_pitch_flag || dur_flag || new_note_flag) { new_key_flag = false; new_pitch_flag = false; Allegro_note_ptr note_ptr = new Allegro_note; note_ptr->chan = voice; note_ptr->time = time; note_ptr->dur = dur; note_ptr->key = key; note_ptr->pitch = pitch; note_ptr->loud = loud; note_ptr->parameters = attributes; seq.add_event(note_ptr); // sort later } else { int update_key = -1; // key or pitch must appear explicitly; otherwise // update applies to channel if (new_key_flag || new_pitch_flag) { update_key = key; } if (loud_flag) { Allegro_update_ptr new_upd = new Allegro_update; new_upd->chan = voice; new_upd->time = time; new_upd->key = update_key; new_upd->parameter.set_attr(symbol_table.insert_string("loudr")); new_upd->parameter.r = pitch; seq.add_event(new_upd); } if (attributes) { while (attributes) { Allegro_update_ptr new_upd = new Allegro_update; new_upd->chan = voice; new_upd->time = time; new_upd->key = update_key; new_upd->parameter = attributes->parm; seq.add_event(new_upd); Parameters_ptr p = attributes; attributes = attributes->next; delete p; } } } if (next_flag) { time = time + next; } else if (dur_flag) { time = time + dur; } } readline(); } //print "Finished reading score" if (!error_flag) { seq.convert_to_seconds(); // make sure format is correct // seq.notes.sort('event_greater_than'); } // print "parse returns error_flag", error_flag return error_flag; } #else /* EXPERIMENTAL_NOTE_TRACK */ bool Alg_reader::parse() { int voice = 0; int key = 60; double loud = 100.0; double pitch = 60.0; double dur = 1.0; double time = 0.0; int track_num = 0; seq->convert_to_seconds(); //seq->set_real_dur(0.0); // just in case it's not initialized already readline(); bool valid = false; // ignore blank lines while (line_parser_flag) { bool time_flag = false; bool next_flag = false; double next; bool voice_flag = false; bool loud_flag = false; bool dur_flag = false; bool new_pitch_flag = false; // "P" syntax double new_pitch = 0.0; bool new_key_flag = false; // "K" syntax int new_key = 0; bool new_note_flag = false; // "A"-"G" syntax int new_note = 0; Alg_parameters_ptr attributes = NULL; if (line_parser.peek() == '#') { // look for #track line_parser.get_nonspace_quoted(field); if (streql(field, "#track")) { line_parser.get_nonspace_quoted(field); // number track_num = parse_int(field - 1); seq->add_track(track_num); } // maybe we have a comment } else { // we must have a track to insert into if (seq->tracks() == 0) seq->add_track(0); line_parser.get_nonspace_quoted(field); char pk = line_parser.peek(); // attributes are parsed as two adjacent nonspace_quoted tokens // so we have to conditionally call get_nonspace_quoted() again if (pk && !isspace(pk)) { line_parser.get_nonspace_quoted(field + strlen(field)); } while (field[0]) { char first = toupper(field[0]); if (strchr("ABCDEFGKLPUSIQHW-", first)) { valid = true; // it's a note or event } if (first == 'V') { if (voice_flag) { parse_error(field, 0, "Voice specified twice"); } else { voice = parse_chan(field); } voice_flag = true; } else if (first == 'T') { if (time_flag) { parse_error(field, 0, "Time specified twice"); } else { time = parse_dur(field, 0.0); } time_flag = true; } else if (first == 'N') { if (next_flag) { parse_error(field, 0, "Next specified twice"); } else { next = parse_dur(field, time); } next_flag = true; } else if (first == 'K') { if (new_key_flag) { parse_error(field, 0, "Key specified twice"); } else { new_key = parse_key(field); new_key_flag = true; } } else if (first == 'L') { if (loud_flag) { parse_error(field, 0, "Loudness specified twice"); } else { loud = parse_loud(field); } loud_flag = true; } else if (first == 'P') { if (new_note_flag || new_pitch_flag) { parse_error(field, 0, "Pitch specified twice"); } else { new_pitch = parse_pitch(field); new_pitch_flag = true; } } else if (first == 'U') { if (dur_flag) { parse_error(field, 0, "Dur specified twice"); } else { dur = parse_dur(field, time); dur_flag = true; } } else if (strchr("SIQHW", first)) { if (dur_flag) { parse_error(field, 0, "Dur specified twice"); } else { // prepend 'U' to field, copy EOS too memmove(field + 1, field, strlen(field) + 1); field[0] = 'U'; dur = parse_dur(field, time); dur_flag = true; } } else if (strchr("ABCDEFG", first)) { if (new_note_flag || new_pitch_flag) { parse_error(field, 0, "Pitch specified twice"); } else { // prepend 'K' to field, copy EOS too memmove(field + 1, field, strlen(field) + 1); field[0] = 'K'; new_note = parse_key(field); new_note_flag = true; } } else if (first == '-') { Alg_parameter parm; if (parse_attribute(field, &parm)) { // enter attribute-value pair attributes = new Alg_parameters(attributes); attributes->parm = parm; parm.s = NULL; // protect string from deletion by destructor } } else { parse_error(field, 0, "Unknown field"); } if (error_flag) { field[0] = 0; // exit the loop } else { line_parser.get_nonspace_quoted(field); pk = line_parser.peek(); // attributes are parsed as two adjacent nonspace_quoted // tokens so we have to conditionally call // get_nonspace_quoted() again if (pk && !isspace(pk)) { line_parser.get_nonspace_quoted(field + strlen(field)); } } } // a case analysis: // Key < 128 counts as both key and pitch // A-G implies pitch AND key unless key given too // K60 P60 -- both are specified, use 'em // K60 P60 C4 -- overconstrained, an error // K60 C4 -- overconstrained // K60 -- OK, pitch is 60 // C4 P60 -- over constrained // P60 -- OK, key is from before, pitch is 60 // C4 -- OK, key is 60, pitch is 60 // <nothing> -- OK, key and pitch from before // K200 with P60 ok, pitch is 60 // K200 with neither P60 nor C4 uses // pitch from before // figure out what the key/instance is: if (new_key_flag) { // it was directly specified key = new_key; if (key < 128 && new_note_flag) { parse_error("", 0, "Pitch specified twice"); } } else if (new_note_flag) { // "A"-"G" used key = new_note; } if (new_pitch_flag) { pitch = new_pitch; } else if (key < 128) { pitch = key; } // now we've acquired new parameters // if (it is a note, then enter the note if (valid) { // change tempo or beat attributes = process_attributes(attributes, time); // if there's a duration or pitch, make a note: if (new_pitch_flag || dur_flag || new_note_flag) { new_key_flag = false; new_pitch_flag = false; Alg_note_ptr note_ptr = new Alg_note; note_ptr->chan = voice; note_ptr->time = time; note_ptr->dur = dur; note_ptr->set_identifier(key); note_ptr->pitch = pitch; note_ptr->loud = loud; note_ptr->parameters = attributes; seq->add_event(note_ptr, track_num); // sort later if (seq->get_real_dur() < (time + dur)) seq->set_real_dur(time + dur); } else { int update_key = -1; // key or pitch must appear explicitly; otherwise // update applies to channel if (new_key_flag || new_pitch_flag) { update_key = key; } if (loud_flag) { Alg_update_ptr new_upd = new Alg_update; new_upd->chan = voice; new_upd->time = time; new_upd->set_identifier(update_key); new_upd->parameter.set_attr(symbol_table.insert_string("loudr")); new_upd->parameter.r = pitch; seq->add_event(new_upd, track_num); if (seq->get_real_dur() < time) seq->set_real_dur(time); } if (attributes) { while (attributes) { Alg_update_ptr new_upd = new Alg_update; new_upd->chan = voice; new_upd->time = time; new_upd->set_identifier(update_key); new_upd->parameter = attributes->parm; seq->add_event(new_upd, track_num); Alg_parameters_ptr p = attributes; attributes = attributes->next; p->parm.s = NULL; // so we don't delete the string delete p; } } } if (next_flag) { time = time + next; } else if (dur_flag) { time = time + dur; } } } readline(); } //print "Finished reading score" if (!error_flag) { seq->convert_to_seconds(); // make sure format is correct // seq->notes.sort('event_greater_than'); } // real_dur is valid, translate to beat_dur seq->set_beat_dur((seq->get_time_map())->time_to_beat(seq->get_real_dur())); // print "parse returns error_flag", error_flag return error_flag; }