/**
*
- * \mainpage libsmf - general usage instructions
+ * \page libsmf libsmf - general usage instructions
*
* An smf_t structure represents a "song". Every valid smf contains one or more tracks.
* Tracks contain zero or more events. Libsmf doesn't care about actual MIDI data, as long
* of these types, i.e. never do something like this: "smf_t smf;". Always use
* "smf_t *smf = smf_new();". The same applies to smf_track_t and smf_event_t.
*
- * Say you want to load a Standard MIDI File (.mid) file and play it back somehow. This is (roughly)
- * how you do this:
+ * Say you want to load a Standard MIDI File (.mid) file and play it back somehow.
+ * This is (roughly) how you do this:
*
* \code
* smf_t *smf;
*
* \endcode
*
- * There are two basic ways of getting MIDI data out of smf - sequential or by track/event number. You may
- * mix them if you need to. First one is used in the example above - seek to the point from which you want
- * the playback to start (using smf_seek_to_seconds(), smf_seek_to_pulses() or smf_seek_to_event()) and then
- * do smf_get_next_event() in loop, until it returns NULL. Calling smf_load() causes the smf to be rewound
- * to the start of the song.
+ * There are two basic ways of getting MIDI data out of smf - sequential or by track/event number.
+ * You may mix them if you need to. First one is used in the example above - seek to the point
+ * from which you want the playback to start (using smf_seek_to_seconds(), smf_seek_to_pulses()
+ * or smf_seek_to_event()) and then do smf_get_next_event() in loop, until it returns NULL.
+ * Calling smf_load() causes the smf to be rewound to the start of the song.
*
* Getting events by number works like this:
*
*
* \endcode
*
- * To create new event, use smf_event_new(), smf_event_new_from_pointer() or smf_event_new_from_bytes().
- * First one creates an empty event - you need to manually allocate (using malloc(3)) buffer for
- * MIDI data, write MIDI data into it, put the address of that buffer into event->midi_buffer,
- * and the length of MIDI data into event->midi_buffer_length. Note that deleting the event
- * (using smf_event_delete()) will free the buffer.
+ * To create new event, use smf_event_new(), smf_event_new_from_pointer() or
+ * smf_event_new_from_bytes(). First one creates an empty event - you need to manually allocate
+ * (using malloc(3)) buffer for MIDI data, write MIDI data into it, put the address of that
+ * buffer into event->midi_buffer, and the length of MIDI data into event->midi_buffer_length.
+ * Note that deleting the event (using smf_event_delete()) will free the buffer.
*
* Second form does most of this for you: it takes an address of the buffer containing MIDI data,
* allocates storage and copies MIDI data into it.
*
* Third form is useful for manually creating short events, up to three bytes in length, for
- * example Note On or Note Off events. It simply takes three bytes and creates MIDI event containing
- * them. If you need to create MIDI message that takes only two bytes, pass -1 as the third byte.
- * For one byte message (System Realtime), pass -1 as second and third byte.
+ * example Note On or Note Off events. It simply takes three bytes and creates MIDI event
+ * containing them. If you need to create MIDI message that takes only two bytes, pass -1 as
+ * the third byte. For one byte message (System Realtime), pass -1 as second and third byte.
*
* To free an event, use smf_event_delete().
*
* To add event to the track, use smf_track_add_event_delta_pulses(), smf_track_add_event_pulses(),
- * or smf_track_add_event_seconds(). The difference between them is in the way you specify the time of
- * the event - with the first one, you specify it as an interval, in pulses, from the previous event
- * in this track; with the second one, you specify it as pulses from the start of the song, and with the
- * last one, you specify it as seconds from the start of the song. Obviously, the first version can
- * only append events at the end of the track.
+ * or smf_track_add_event_seconds(). The difference between them is in the way you specify the
+ * time of the event - with the first one, you specify it as an interval, in pulses, from the
+ * previous event in this track; with the second one, you specify it as pulses from the start
+ * of the song, and with the last one, you specify it as seconds from the start of the song.
+ * Obviously, the first version can only append events at the end of the track.
*
- * To remove an event from the track it's attached to, use smf_event_remove_from_track(). You may
- * want to free the event (using smf_event_delete()) afterwards.
+ * To remove an event from the track it's attached to, use smf_event_remove_from_track().
+ * You may want to free the event (using smf_event_delete()) afterwards.
*
* To create new track, use smf_track_new(). To add track to the smf, use smf_add_track().
* To remove track from its smf, use smf_track_remove_from_smf(). To free the track structure,
* use smf_track_delete().
*
- * Note that libsmf keeps things consistent. If you free (using smf_track_delete()) a track that
- * is attached to an smf and contains events, libsmf will detach the events, free them, detach
- * the track, free it etc.
- *
- * Tracks and events are numbered consecutively, starting from one. If you remove a track or event,
- * the rest of tracks/events will get renumbered. To get the number of a given event in its track, use event->event_number.
- * To get the number of track in its smf, use track->track_number. To get the number of events in the track,
- * use track->number_of_events. To get the number of tracks in the smf, use smf->number_of_tracks.
- *
- * In SMF File Format, each track has to end with End Of Track metaevent. If you load SMF file using smf_load(),
- * that will be the case. If you want to create or edit an SMF, you don't need to worry about EOT events;
- * libsmf automatically takes care of them for you. If you try to save an SMF with tracks that do not end
- * with EOTs, smf_save() will append them. If you try to add event that happens after EOT metaevent, libsmf
- * will remove the EOT. If you want to add EOT manually, you can, of course, using smf_track_add_eot_seconds()
+ * Note that libsmf keeps things consistent. If you free (using smf_track_delete()) a track
+ * that is attached to an smf and contains events, libsmf will detach the events, free them,
+ * detach the track, free it etc.
+ *
+ * Tracks and events are numbered consecutively, starting from one. If you remove a track
+ * or event, the rest of tracks/events will get renumbered. To get the number of a given
+ * event in its track, use event->event_number. To get the number of track in its smf, use
+ * track->track_number. To get the number of events in the track, use track->number_of_events.
+ * To get the number of tracks in the smf, use smf->number_of_tracks.
+ *
+ * In SMF File Format, each track has to end with End Of Track metaevent. If you load SMF file
+ * using smf_load(), that will be the case. If you want to create or edit an SMF, you don't
+ * need to worry about EOT events; libsmf automatically takes care of them for you. If you
+ * try to save an SMF with tracks that do not end with EOTs, smf_save() will append them.
+ * If you try to add event that happens after EOT metaevent, libsmf will remove the EOT.
+ * If you want to add EOT manually, you can, of course, using smf_track_add_eot_seconds()
* or smf_track_add_eot_pulses().
*
- * Each event carries three time values - event->time_seconds, which is seconds since the start of the song,
- * event->time_pulses, which is PPQN clocks since the start of the song, and event->delta_pulses, which is PPQN clocks
- * since the previous event in that track. These values are invalid if the event is not attached to the track.
- * If event is attached, all three values are valid. Time of the event is specified when adding the event
- * (using smf_track_add_event_seconds(), smf_track_add_event_pulses() or smf_track_add_event_delta_pulses()); the remaining
- * two values are computed from that.
- *
- * Tempo related stuff happens automatically - when you add a metaevent that
- * is Tempo Change or Time Signature, libsmf adds that event to the tempo map. If you remove
- * Tempo Change event that is in the middle of the song, the rest of the events will have their
- * event->time_seconds recomputed from event->time_pulses before smf_event_remove_from_track() function returns.
- * Adding Tempo Change in the middle of the song works in a similar way.
- *
- * MIDI data (event->midi_buffer) is always kept in normalized form - it always begins with status byte
- * (no running status), there are no System Realtime events embedded in them etc. Events like SysExes
- * are in "on the wire" form, without embedded length that is used in SMF file format. Obviously
- * libsmf "normalizes" MIDI data during loading and "denormalizes" (adding length to SysExes, escaping
- * System Common and System Realtime messages etc) during writing.
+ * Each event carries three time values - event->time_seconds, which is seconds since
+ * the start of the song, event->time_pulses, which is PPQN clocks since the start of
+ * the song, and event->delta_pulses, which is PPQN clocks since the previous event
+ * in that track. These values are invalid if the event is not attached to the track.
+ * If event is attached, all three values are valid. Time of the event is specified when
+ * adding the event (using smf_track_add_event_seconds(), smf_track_add_event_pulses() or
+ * smf_track_add_event_delta_pulses()); the remaining two values are computed from that.
+ *
+ * Tempo related stuff happens automatically - when you add a metaevent that is Tempo PropertyChange or
+ * Time Signature, libsmf adds that event to the tempo map. If you remove Tempo PropertyChange event
+ * that is in the middle of the song, the rest of the events will have their event->time_seconds
+ * recomputed from event->time_pulses before smf_event_remove_from_track() function returns.
+ * Adding Tempo PropertyChange in the middle of the song works in a similar way.
+ *
+ * MIDI data (event->midi_buffer) is always kept in normalized form - it always begins with
+ * status byte (no running status), there are no System Realtime events embedded in them etc.
+ * Events like SysExes are in "on the wire" form, without embedded length that is used in SMF
+ * file format. Obviously libsmf "normalizes" MIDI data during loading and "denormalizes" (adding
+ * length to SysExes, escaping System Common and System Realtime messages etc) during writing.
*
* Note that you always have to first add the track to smf, and then add events to the track.
- * Doing it the other way around will trip asserts. Also, try to add events at the end of the track and remove
- * them from the end of the track, that's much more efficient.
- *
- * All the libsmf functions have prefix "smf_". First argument for routines whose names start with
- * "smf_event_" is "smf_event_t *", for routines whose names start with "smf_track_" - "smf_track_t *",
- * and for plain "smf_" - "smf_t *". The only exception are smf_whatever_new routines.
- * Library does not use any global variables and is thread-safe,
- * as long as you don't try to work on the same SMF (smf_t and its descendant tracks and events) from several
- * threads at once without protecting it with mutex. Library depends on glib and nothing else. License is
- * BSD, two clause, which basically means you can use it freely in your software, both Open Source (including
- * GPL) and closed source.
+ * Doing it the other way around will trip asserts. Also, try to add events at the end of the
+ * track and remove them from the end of the track, that's much more efficient.
+ *
+ * All the libsmf functions have prefix "smf_". First argument for routines whose names start
+ * with "smf_event_" is "smf_event_t *", for routines whose names start with "smf_track_" -
+ * "smf_track_t *", and for plain "smf_" - "smf_t *". The only exception are smf_whatever_new
+ * routines. Library does not use any global variables and is thread-safe, as long as you
+ * don't try to work on the same SMF (smf_t and its descendant tracks and events) from several
+ * threads at once without protecting it with mutex. Library depends on glib and nothing else.
+ * License is BSD, two clause, which basically means you can use it freely in your software,
+ * both Open Source (including GPL) and closed source.
*
*/
/** Represents a "song", that is, collection of one or more tracks. */
struct smf_struct {
- int format;
+ int format;
- /** These fields are extracted from "division" field of MThd header. Valid is _either_ ppqn or frames_per_second/resolution. */
- uint16_t ppqn;
- int frames_per_second;
- int resolution;
- int number_of_tracks;
+ /** These fields are extracted from "division" field of MThd header.
+ * Valid is _either_ ppqn or frames_per_second/resolution. */
+ uint16_t ppqn;
+ int frames_per_second;
+ int resolution;
+ int number_of_tracks;
/** These are private fields using only by loading and saving routines. */
- FILE *stream;
- void *file_buffer;
- size_t file_buffer_length;
- size_t next_chunk_offset;
- int expected_number_of_tracks;
+ FILE *stream;
+ void *file_buffer;
+ size_t file_buffer_length;
+ size_t next_chunk_offset;
+ int expected_number_of_tracks;
/** Private, used by smf.c. */
- GPtrArray *tracks_array;
- double last_seek_position;
+ GPtrArray *tracks_array;
+ double last_seek_position;
/** Private, used by smf_tempo.c. */
/** Array of pointers to smf_tempo_struct. */
- GPtrArray *tempo_array;
+ GPtrArray *tempo_array;
};
typedef struct smf_struct smf_t;
struct smf_tempo_struct {
size_t time_pulses;
double time_seconds;
- int microseconds_per_quarter_note;
- int numerator;
- int denominator;
- int clocks_per_click;
- int notes_per_note;
+ int microseconds_per_quarter_note;
+ int numerator;
+ int denominator;
+ int clocks_per_click;
+ int notes_per_note;
};
typedef struct smf_tempo_struct smf_tempo_t;
/** Represents a single track. */
struct smf_track_struct {
- smf_t *smf;
+ smf_t *smf;
- int track_number;
- size_t number_of_events;
+ int track_number;
+ size_t number_of_events;
/** These are private fields using only by loading and saving routines. */
- void *file_buffer;
- size_t file_buffer_length;
- int last_status; /* Used for "running status". */
+ void *file_buffer;
+ size_t file_buffer_length;
+ int last_status; /* Used for "running status". */
/** Private, used by smf.c. */
/** Offset into buffer, used in parse_next_event(). */
- size_t next_event_offset;
- size_t next_event_number;
+ size_t next_event_offset;
+ size_t next_event_number;
/** Absolute time of next event on events_queue. */
- size_t time_of_next_event;
- GPtrArray *events_array;
+ size_t time_of_next_event;
+ GPtrArray *events_array;
};
typedef struct smf_track_struct smf_track_t;
/** Represents a single MIDI event or metaevent. */
struct smf_event_struct {
/** Pointer to the track, or NULL if event is not attached. */
- smf_track_t *track;
+ smf_track_t *track;
- /** Number of this event in the track. Events are numbered consecutively, starting from one. */
- size_t event_number;
+ /** Number of this event in the track. Events are numbered consecutively, starting from 1. */
+ size_t event_number;
/** Note that the time fields are invalid, if event is not attached to a track. */
/** Time, in pulses, since the previous event on this track. */
- int32_t delta_time_pulses;
+ int32_t delta_time_pulses;
/** Time, in pulses, since the start of the song. */
- size_t time_pulses;
+ size_t time_pulses;
/** Time, in seconds, since the start of the song. */
- double time_seconds;
+ double time_seconds;
/** Tracks are numbered consecutively, starting from 1. */
- int track_number;
+ int track_number;
/** Pointer to the buffer containing MIDI message. This is freed by smf_event_delete. */
- uint8_t *midi_buffer;
+ uint8_t *midi_buffer;
/** Length of the MIDI message in the buffer, in bytes. */
- size_t midi_buffer_length;
+ size_t midi_buffer_length;
};
typedef struct smf_event_struct smf_event_t;
/* Routines for manipulating smf_t. */
smf_t *smf_new(void) WARN_UNUSED_RESULT;
-void smf_delete(smf_t *smf);
+void smf_delete(smf_t *smf);
int smf_set_format(smf_t *smf, int format) WARN_UNUSED_RESULT;
int smf_set_ppqn(smf_t *smf, uint16_t ppqn) WARN_UNUSED_RESULT;
smf_event_t *smf_peek_next_event(smf_t *smf) WARN_UNUSED_RESULT;
smf_event_t *smf_get_next_event(smf_t *smf) WARN_UNUSED_RESULT;
-void smf_skip_next_event(smf_t *smf);
+void smf_skip_next_event(smf_t *smf);
void smf_rewind(smf_t *smf);
-int smf_seek_to_seconds(smf_t *smf, double seconds) WARN_UNUSED_RESULT;
-int smf_seek_to_pulses(smf_t *smf, size_t pulses) WARN_UNUSED_RESULT;
-int smf_seek_to_event(smf_t *smf, const smf_event_t *event) WARN_UNUSED_RESULT;
+int smf_seek_to_seconds(smf_t *smf, double seconds) WARN_UNUSED_RESULT;
+int smf_seek_to_pulses(smf_t *smf, size_t pulses) WARN_UNUSED_RESULT;
+int smf_seek_to_event(smf_t *smf, const smf_event_t *event) WARN_UNUSED_RESULT;
size_t smf_get_length_pulses(const smf_t *smf) WARN_UNUSED_RESULT;
double smf_get_length_seconds(const smf_t *smf) WARN_UNUSED_RESULT;
-int smf_event_is_last(const smf_event_t *event) WARN_UNUSED_RESULT;
+int smf_event_is_last(const smf_event_t *event) WARN_UNUSED_RESULT;
void smf_add_track(smf_t *smf, smf_track_t *track);
void smf_track_remove_from_smf(smf_track_t *track);
/* Routines for manipulating smf_track_t. */
smf_track_t *smf_track_new(void) WARN_UNUSED_RESULT;
-void smf_track_delete(smf_track_t *track);
+void smf_track_delete(smf_track_t *track);
smf_event_t *smf_track_get_next_event(smf_track_t *track) WARN_UNUSED_RESULT;
-smf_event_t *smf_track_get_event_by_number(const smf_track_t *track, size_t event_number) WARN_UNUSED_RESULT;
+smf_event_t *smf_track_get_event_by_number(const smf_track_t *track, size_t num) WARN_UNUSED_RESULT;
smf_event_t *smf_track_get_last_event(const smf_track_t *track) WARN_UNUSED_RESULT;
void smf_track_add_event_delta_pulses(smf_track_t *track, smf_event_t *event, uint32_t delta);
void smf_track_add_event_pulses(smf_track_t *track, smf_event_t *event, size_t pulses);
void smf_track_add_event_seconds(smf_track_t *track, smf_event_t *event, double seconds);
-int smf_track_add_eot_delta_pulses(smf_track_t *track, uint32_t delta) WARN_UNUSED_RESULT;
-int smf_track_add_eot_pulses(smf_track_t *track, size_t pulses) WARN_UNUSED_RESULT;
-int smf_track_add_eot_seconds(smf_track_t *track, double seconds) WARN_UNUSED_RESULT;
+int smf_track_add_eot_delta_pulses(smf_track_t *track, uint32_t delta) WARN_UNUSED_RESULT;
+int smf_track_add_eot_pulses(smf_track_t *track, size_t pulses) WARN_UNUSED_RESULT;
+int smf_track_add_eot_seconds(smf_track_t *track, double seconds) WARN_UNUSED_RESULT;
void smf_event_remove_from_track(smf_event_t *event);
/* Routines for manipulating smf_event_t. */
smf_event_t *smf_event_new(void) WARN_UNUSED_RESULT;
-smf_event_t *smf_event_new_from_pointer(void *midi_data, size_t len) WARN_UNUSED_RESULT;
-smf_event_t *smf_event_new_from_bytes(int first_byte, int second_byte, int third_byte) WARN_UNUSED_RESULT;
+smf_event_t *smf_event_new_from_pointer(const void *midi_data, size_t len) WARN_UNUSED_RESULT;
+smf_event_t *smf_event_new_from_bytes(int byte1, int byte2, int byte3) WARN_UNUSED_RESULT;
smf_event_t *smf_event_new_textual(int type, const char *text);
-void smf_event_delete(smf_event_t *event);
-
-int smf_event_is_valid(const smf_event_t *event) WARN_UNUSED_RESULT;
-int smf_event_is_metadata(const smf_event_t *event) WARN_UNUSED_RESULT;
-int smf_event_is_system_realtime(const smf_event_t *event) WARN_UNUSED_RESULT;
-int smf_event_is_system_common(const smf_event_t *event) WARN_UNUSED_RESULT;
-int smf_event_is_sysex(const smf_event_t *event) WARN_UNUSED_RESULT;
-int smf_event_is_eot(const smf_event_t *event) WARN_UNUSED_RESULT;
-int smf_event_is_textual(const smf_event_t *event) WARN_UNUSED_RESULT;
+void smf_event_delete(smf_event_t *event);
+
+int smf_event_is_valid(const smf_event_t *event) WARN_UNUSED_RESULT;
+int smf_event_is_metadata(const smf_event_t *event) WARN_UNUSED_RESULT;
+int smf_event_is_system_realtime(const smf_event_t *event) WARN_UNUSED_RESULT;
+int smf_event_is_system_common(const smf_event_t *event) WARN_UNUSED_RESULT;
+int smf_event_is_sysex(const smf_event_t *event) WARN_UNUSED_RESULT;
+int smf_event_is_eot(const smf_event_t *event) WARN_UNUSED_RESULT;
+int smf_event_is_textual(const smf_event_t *event) WARN_UNUSED_RESULT;
char *smf_event_decode(const smf_event_t *event) WARN_UNUSED_RESULT;
char *smf_event_extract_text(const smf_event_t *event) WARN_UNUSED_RESULT;
+/* Routines for dealing with Variable Length Quantities (VLQ's).
+ Slightly odd names reflect original static names within libsmf
+ */
+int smf_format_vlq (unsigned char *buf, int length, unsigned long value);
+int smf_extract_vlq(const unsigned char *buf, const size_t buffer_length, uint32_t *value, uint32_t *len);
+
/* Routines for loading SMF files. */
-smf_t *smf_load(const char *file_name) WARN_UNUSED_RESULT;
+smf_t *smf_load(FILE *) WARN_UNUSED_RESULT;
smf_t *smf_load_from_memory(const void *buffer, const size_t buffer_length) WARN_UNUSED_RESULT;
/* Routine for writing SMF files. */
-int smf_save(smf_t *smf, const char *file_name) WARN_UNUSED_RESULT;
+int smf_save(smf_t *smf, FILE *file) WARN_UNUSED_RESULT;
/* Routines for manipulating smf_tempo_t. */
smf_tempo_t *smf_get_tempo_by_pulses(const smf_t *smf, size_t pulses) WARN_UNUSED_RESULT;