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/**
@ file ltc . h
@ brief libltc - en + decode linear timecode
Linear ( or Longitudinal ) Timecode ( LTC ) is an encoding of
timecode data as a Manchester - Biphase encoded audio signal .
The audio signal is commonly recorded on a VTR track or other
storage media .
libltc facilitates decoding and encoding of LTC from / to
timecode , including SMPTE date support .
@ author Robin Gareus < robin @ gareus . org >
@ copyright
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Copyright ( C ) 2006 - 2014 Robin Gareus < robin @ gareus . org >
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Copyright ( C ) 2008 - 2009 Jan Weiß < jan @ geheimwerk . de >
Inspired by SMPTE Decoder - Maarten de Boer < mdeboer @ iua . upf . es >
This program is free software ; you can redistribute it and / or modify
it under the terms of the GNU Lesser General Public License as
published by the Free Software Foundation , either version 3 of the
License , or ( at your option ) any later version .
This program is distributed in the hope that it will be useful ,
but WITHOUT ANY WARRANTY ; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE . See the
GNU Lesser General Public License for more details .
You should have received a copy of the GNU Lesser General Public
License along with this library .
If not , see < http : //www.gnu.org/licenses/>.
*/
# ifndef LTC_H
# define LTC_H 1
# ifdef __cplusplus
extern " C " {
# endif
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# if defined _WIN32 && !defined(__LITTLE_ENDIAN__)
# define __LITTLE_ENDIAN__
# endif
# ifdef __BIG_ENDIAN__
# define LTC_BIG_ENDIAN
# elif defined _BIG_ENDIAN
# define LTC_BIG_ENDIAN
# elif defined __BYTE_ORDER__
# if __BYTE_ORDER__ == __ORDER_BIG_ENDIAN__
# define LTC_BIG_ENDIAN
# endif
# elif !defined __LITTLE_ENDIAN__
# include <endian.h> // machine/endian.h
# if (defined __BYTE_ORDER__ && defined __ORDER_BIG_ENDIAN__ && __BYTE_ORDER__ == __ORDER_BIG_ENDIAN__)
# define LTC_BIG_ENDIAN
# endif
# endif
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# include <stddef.h> /* size_t */
# ifndef DOXYGEN_IGNORE
/* libltc version */
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# define LIBLTC_VERSION "1.3.0"
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# define LIBLTC_VERSION_MAJOR 1
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# define LIBLTC_VERSION_MINOR 3
# define LIBLTC_VERSION_MICRO 0
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/* interface revision number
* http : //www.gnu.org/software/libtool/manual/html_node/Updating-version-info.html
*/
# define LIBLTC_CUR 11
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# define LIBLTC_REV 5
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# define LIBLTC_AGE 0
# endif /* end DOXYGEN_IGNORE */
/**
* default audio sample type : 8 bit unsigned ( mono )
*/
typedef unsigned char ltcsnd_sample_t ;
/**
* sample - count offset - 64 bit wide
*/
typedef long long int ltc_off_t ;
# define LTC_FRAME_BIT_COUNT 80
/**
* Raw 80 bit LTC frame
*
* The datastream for each video frame of Longitudinal Timecode consists of eighty bit - periods .
*
* At a frame - rate of 30 fps , the bit - rate corresponds to 30 [ fps ] * 80 [ bits / f ] = 2400 bits per second .
* The frequency for a stream of zeros would be 1.2 kHz and for a stream of ones it would be 2.4 kHz .
* \ image html smptefmt . png
* With all commonly used video - frame - rates and audio - sample - rates , LTC timecode can be recorded
* easily into a audio - track .
*
* In each frame , 26 of the eighty bits carry the SMPTE time in binary coded decimal ( BCD ) .
*
* These Bits are FRAME - UNITS , FRAME - TENS , SECS - UNITS , SECS - TENS , MINS - UNITS , MINS - TENS , HOURS - UNITS and HOURS - TENS .
* The BCD digits are loaded ' least significant bit first ' ( libltc takes care of the architecture specific alignment ) .
*
* 32 bits are assigned as eight groups of four USER - BITS ( also sometimes called the " Binary Groups " ) .
* This capacity is generally used to carry extra info such as reel number and / or date .
* The User Bits may be allocated howsoever one wishes as long as both Binary Group Flag Bits are cleared .
*
* The function \ ref ltc_frame_to_time can interpret the user - bits as SMPTE Date + Timezone according to SMPTE 309 M - 1999.
* similarly \ ref ltc_time_to_frame will do the reverse .
*
* The last 16 Bits make up the SYNC WORD . These bits indicate the frame boundary , the tape direction , and the bit - rate of the sync tone .
* The values of these Bits are fixed as 0011 1111 1111 1101
*
* The Bi - Phase Mark Phase Correction Bit ( Bit 27 or 59 ) may be set or cleared so that that every 80 - bit word
* contains an even number of zeroes . This means that the phase of the pulse train in every Sync Word will be the same .
*
* Bit 10 indicates drop - frame timecode .
* The Colour Frame Flag col . frm is Bit 11 ; if the timecode intentionally synchronized to a colour TV field sequence , this bit is set .
*
* Bit 58 is not required for the BCD count for HOURS - TENS ( which has a maximum value of two )
* and has not been given any other special purpose so remains unassigned .
* This Bit has been RESERVED for future assignment .
*
* The Binary Group Flag Bits ( bits 43 and 59 ) are two bits indicate the format of the User Bits data .
* SMPTE 12 M - 1999 defines the previously reserved bit 58 to signals that the time is locked to wall - clock
* within a tolerance of ± 0.5 seconds .
*
* SMPTE 12 M - 1999 also changes the numbering schema of the BGF . ( BGF1 was renamed to BGF2 and bit 58 becomes BGFB1 )
*
* To further complicate matters , the BGFB assignment as well as the biphase_mark_phase_correction ( aka parity )
* bit depends on the timecode - format used .
*
* < pre >
* 25 fps 24 , 30 fps
* BGF0 27 43
* BGF1 58 58
* BGF2 43 59
* Parity 59 27
* < / pre >
*
* The variable naming chosen for the LTCFrame struct is based on the 24 , 30 fps standard .
*
* The Binary Group Flag Bits should be used only as shown in the truth table below .
* The Unassigned entries in the table should not be used , as they may be allocated specific meanings in the future .
*
* < pre >
* BGF0 BGF1 BGF2
* user - bits timecode Bit 43 Bit 58 Bit 59 ( 30f ps , 24 fps )
* | | Bit 27 Bit 58 Bit 43 ( 25f ps )
* No User Bits format specified | ? | 0 0 0
* Eight - bit character set ( 1 ) | ? | 1 0 0
* Date and Timezone set | ? | 0 0 1
* Page / Line multiplex ( 2 ) | ? | 1 0 1
* Character set not specified | clk | 0 1 0
* Reserved | ? | 1 1 0
* Date and Timezone set | clk | 0 1 1
* Page / Line multiplex ( 2 ) | clk | 1 1 1
*
* < / pre >
*
* ( 1 ) ISO / IEC 646 or ISO / IEC 2022 character set .
* If the seven - bit ISO codes are being used , they shall be converted to
* eight - bit codes by setting the eighth bit to zero . 4 ISO codes can be encoded ,
* user7 and user8 are to be used for the first code with LSB 7 and MSB in 8.
* the remaining ISO codes are to be distributed in the same manner to
* user5 / 6 user3 / 4 and user1 / 2 accordingly .
*
* ( 2 ) The Page / Line indicates ANSI / SMPTE - 262 M is used for the user - bits . It is multiplex system that
* can be used to encode large amounts of data in the binary groups through the use of time multiplexing .
*
* libltc does not use any of the BGF - except for the Parity bit which can be calculated and set with
* \ ref ltc_frame_set_parity . Setting and interpreting the BGF is left to the application using libltc .
* However libltc provides functionality to parse or set date and timezoe according to SMPTE 309 M - 1999.
*
* further information : http : //www.philrees.co.uk/articles/timecode.htm
* and http : //www.barney-wol.net/time/timecode.html
*/
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# if (defined LTC_BIG_ENDIAN && !defined DOXYGEN_IGNORE)
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// Big Endian version, bytes are "upside down"
struct LTCFrame {
unsigned int user1 : 4 ;
unsigned int frame_units : 4 ;
unsigned int user2 : 4 ;
unsigned int col_frame : 1 ;
unsigned int dfbit : 1 ;
unsigned int frame_tens : 2 ;
unsigned int user3 : 4 ;
unsigned int secs_units : 4 ;
unsigned int user4 : 4 ;
unsigned int biphase_mark_phase_correction : 1 ;
unsigned int secs_tens : 3 ;
unsigned int user5 : 4 ;
unsigned int mins_units : 4 ;
unsigned int user6 : 4 ;
unsigned int binary_group_flag_bit0 : 1 ;
unsigned int mins_tens : 3 ;
unsigned int user7 : 4 ;
unsigned int hours_units : 4 ;
unsigned int user8 : 4 ;
unsigned int binary_group_flag_bit2 : 1 ;
unsigned int binary_group_flag_bit1 : 1 ;
unsigned int hours_tens : 2 ;
unsigned int sync_word : 16 ;
} ;
# else
/* Little Endian version -- and doxygen doc */
struct LTCFrame {
unsigned int frame_units : 4 ; ///< SMPTE framenumber BCD unit 0..9
unsigned int user1 : 4 ;
unsigned int frame_tens : 2 ; ///< SMPTE framenumber BCD tens 0..3
unsigned int dfbit : 1 ; ///< indicated drop-frame timecode
unsigned int col_frame : 1 ; ///< colour-frame: timecode intentionally synchronized to a colour TV field sequence
unsigned int user2 : 4 ;
unsigned int secs_units : 4 ; ///< SMPTE seconds BCD unit 0..9
unsigned int user3 : 4 ;
unsigned int secs_tens : 3 ; ///< SMPTE seconds BCD tens 0..6
unsigned int biphase_mark_phase_correction : 1 ; ///< see note on Bit 27 in description and \ref ltc_frame_set_parity .
unsigned int user4 : 4 ;
unsigned int mins_units : 4 ; ///< SMPTE minutes BCD unit 0..9
unsigned int user5 : 4 ;
unsigned int mins_tens : 3 ; ///< SMPTE minutes BCD tens 0..6
unsigned int binary_group_flag_bit0 : 1 ; ///< indicate user-data char encoding, see table above - bit 43
unsigned int user6 : 4 ;
unsigned int hours_units : 4 ; ///< SMPTE hours BCD unit 0..9
unsigned int user7 : 4 ;
unsigned int hours_tens : 2 ; ///< SMPTE hours BCD tens 0..2
unsigned int binary_group_flag_bit1 : 1 ; ///< indicate timecode is local time wall-clock, see table above - bit 58
unsigned int binary_group_flag_bit2 : 1 ; ///< indicate user-data char encoding (or parity with 25fps), see table above - bit 59
unsigned int user8 : 4 ;
unsigned int sync_word : 16 ;
} ;
# endif
/** the standard defines the assignment of the binary-group-flag bits
* basically only 25f ps is different , but other standards defined in
* the SMPTE spec have been included for completeness .
*/
enum LTC_TV_STANDARD {
LTC_TV_525_60 , ///< 30fps
LTC_TV_625_50 , ///< 25fps
LTC_TV_1125_60 , ///< 30fps
LTC_TV_FILM_24 ///< 24fps
} ;
/** encoder and LTCframe <> timecode operation flags */
enum LTC_BG_FLAGS {
LTC_USE_DATE = 1 , ///< LTCFrame <> SMPTETimecode converter and LTCFrame increment/decrement use date, also set BGF2 to '1' when encoder is initialized or re-initialized (unless LTC_BGF_DONT_TOUCH is given)
LTC_TC_CLOCK = 2 , ///< the Timecode is wall-clock aka freerun. This also sets BGF1 (unless LTC_BGF_DONT_TOUCH is given)
LTC_BGF_DONT_TOUCH = 4 , ///< encoder init or re-init does not touch the BGF bits (initial values after initialization is zero)
LTC_NO_PARITY = 8 ///< parity bit is left untouched when setting or in/decrementing the encoder frame-number
} ;
/**
* see LTCFrame
*/
typedef struct LTCFrame LTCFrame ;
/**
* Extended LTC frame - includes audio - sample position offsets , volume , etc
*
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* Note : For TV systems , the sample in the LTC audio data stream where the LTC Frame starts is not necessarily at the same time
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* as the video - frame which is described by the LTC Frame .
*
* \ ref off_start denotes the time of the first transition of bit 0 in the LTC frame .
*
* For 525 / 60 Television systems , the first transition shall occur at the beginning of line 5 of the frame with which it is
* associated . The tolerance is ± 1.5 lines .
*
* For 625 / 50 systems , the first transition shall occur at the beginning of line 2 ± 1.5 lines of the frame with which it is associated .
*
* Only for 1125 / 60 systems , the first transition occurs exactly at the vertical sync timing reference of the frame . ± 1 line .
*
*/
struct LTCFrameExt {
LTCFrame ltc ; ///< the actual LTC frame. see \ref LTCFrame
ltc_off_t off_start ; ///< \anchor off_start the approximate sample in the stream corresponding to the start of the LTC frame.
ltc_off_t off_end ; ///< \anchor off_end the sample in the stream corresponding to the end of the LTC frame.
int reverse ; ///< if non-zero, a reverse played LTC frame was detected. Since the frame was reversed, it started at off_end and finishes as off_start (off_end > off_start). (Note: in reverse playback the (reversed) sync-word of the next/previous frame is detected, this offset is corrected).
float biphase_tics [ LTC_FRAME_BIT_COUNT ] ; ///< detailed timing info: phase of the LTC signal; the time between each bit in the LTC-frame in audio-frames. Summing all 80 values in the array will yield audio-frames/LTC-frame = (\ref off_end - \ref off_start + 1).
ltcsnd_sample_t sample_min ; ///< the minimum input sample signal for this frame (0..255)
ltcsnd_sample_t sample_max ; ///< the maximum input sample signal for this frame (0..255)
double volume ; ///< the volume of the input signal in dbFS
} ;
/**
* see \ ref LTCFrameExt
*/
typedef struct LTCFrameExt LTCFrameExt ;
/**
* Human readable time representation , decimal values .
*/
struct SMPTETimecode {
char timezone [ 6 ] ; ///< the timezone 6bytes: "+HHMM" textual representation
unsigned char years ; ///< LTC-date uses 2-digit year 00.99
unsigned char months ; ///< valid months are 1..12
unsigned char days ; ///< day of month 1..31
unsigned char hours ; ///< hour 0..23
unsigned char mins ; ///< minute 0..60
unsigned char secs ; ///< second 0..60
unsigned char frame ; ///< sub-second frame 0..(FPS - 1)
} ;
/**
* see \ ref SMPTETimecode
*/
typedef struct SMPTETimecode SMPTETimecode ;
/**
* Opaque structure
* see : \ ref ltc_decoder_create , \ ref ltc_decoder_free
*/
typedef struct LTCDecoder LTCDecoder ;
/**
* Opaque structure
* see : \ ref ltc_encoder_create , \ ref ltc_encoder_free
*/
typedef struct LTCEncoder LTCEncoder ;
/**
* Convert binary LTCFrame into SMPTETimecode struct
*
* @ param stime output
* @ param frame input
* @ param flags binary combination of \ ref LTC_BG_FLAGS - here only LTC_USE_DATE is relevant .
* if LTC_USE_DATE is set , the user - fields in LTCFrame will be parsed into the date variable of SMPTETimecode .
* otherwise the date information in the SMPTETimecode is set to zero .
*/
void ltc_frame_to_time ( SMPTETimecode * stime , LTCFrame * frame , int flags ) ;
/**
* Translate SMPTETimecode struct into its binary LTC representation
* and set the LTC frame ' s parity bit accordingly ( see \ ref ltc_frame_set_parity )
*
* @ param frame output - the frame to be set
* @ param stime input - timecode input
* @ param standard the TV standard to use for parity bit assignment
* @ param flags binary combination of \ ref LTC_BG_FLAGS - here only LTC_USE_DATE and LTC_NO_PARITY are relevant .
* if LTC_USE_DATE is given , user - fields in LTCFrame will be set from the date in SMPTETimecode ,
* otherwise the user - bits are not modified . All non - timecode fields remain untouched - except for the parity bit
* unless LTC_NO_PARITY is given .
*/
void ltc_time_to_frame ( LTCFrame * frame , SMPTETimecode * stime , enum LTC_TV_STANDARD standard , int flags ) ;
/**
* Reset all values of a LTC FRAME to zero , except for the sync - word ( 0x3FFD ) at the end .
* The sync word is set according to architecture ( big / little endian ) .
* Also set the Frame ' s parity bit accordingly ( see \ ref ltc_frame_set_parity )
* @ param frame the LTCFrame to reset
*/
void ltc_frame_reset ( LTCFrame * frame ) ;
/**
* Increment the timecode by one Frame ( 1 / framerate seconds )
* and set the Frame ' s parity bit accordingly ( see \ ref ltc_frame_set_parity )
*
* @ param frame the LTC - timecode to increment
* @ param fps integer framerate ( for drop - frame - timecode set frame - > dfbit and round - up the fps ) .
* @ param standard the TV standard to use for parity bit assignment
* if set to 1 the 25f ps standard is enabled and LTC Frame bit 59 instead of 27 is used for the parity . It only has only has effect flag bit 4 ( LTC_NO_PARITY ) is cleared .
* @ param flags binary combination of \ ref LTC_BG_FLAGS - here only LTC_USE_DATE and LTC_NO_PARITY are relevant .
* If the bit 0 ( 1 ) is set ( 1 ) interpret user - data as date and increment date if timecode wraps after 24 h .
* ( Note : leap - years are taken into account , but since the year is two - digit only , the 100 , 400 yr rules are ignored .
* " 00 " is assumed to be year 2000 which was a leap year . )
* @ return 1 if timecode was wrapped around after 23 : 59 : 59 : ff , 0 otherwise
*/
int ltc_frame_increment ( LTCFrame * frame , int fps , enum LTC_TV_STANDARD standard , int flags ) ;
/**
* Decrement the timecode by one Frame ( 1 / framerate seconds )
* and set the Frame ' s parity bit accordingly ( see \ ref ltc_frame_set_parity )
*
* @ param frame the LTC - timecode to decrement
* @ param fps integer framerate ( for drop - frame - timecode set frame - > dfbit and round - up the fps ) .
* @ param standard the TV standard to use for parity bit assignment
* if set to 1 the 25f ps standard is enabled and LTC Frame bit 59 instead of 27 is used for the parity . It only has only has effect flag bit 4 ( LTC_NO_PARITY ) is cleared .
* @ param flags binary combination of \ ref LTC_BG_FLAGS - here only LTC_USE_DATE and LTC_NO_PARITY are relevant .
* if the bit 0 is set ( 1 ) interpret user - data as date and decrement date if timecode wraps at 24 h .
* ( Note : leap - years are taken into account , but since the year is two - digit only , the 100 , 400 yr rules are ignored .
* " 00 " is assumed to be year 2000 which was a leap year . )
* bit 3 ( 8 ) indicates that the parity bit should not be touched
* @ return 1 if timecode was wrapped around at 23 : 59 : 59 : ff , 0 otherwise
*/
int ltc_frame_decrement ( LTCFrame * frame , int fps , enum LTC_TV_STANDARD standard , int flags ) ;
/**
* Create a new LTC decoder .
*
* @ param apv audio - frames per video frame . This is just used for initial settings , the speed is tracked dynamically . setting this in the right ballpark is needed to properly decode the first LTC frame in a sequence .
* @ param queue_size length of the internal queue to store decoded frames
* to SMPTEDecoderWrite .
* @ return decoder handle or NULL if out - of - memory
*/
LTCDecoder * ltc_decoder_create ( int apv , int queue_size ) ;
/**
* Release memory of decoder .
* @ param d decoder handle
*/
int ltc_decoder_free ( LTCDecoder * d ) ;
/**
* Feed the LTC decoder with new audio samples .
*
* Parse raw audio for LTC timestamps . Once a complete LTC frame has been
* decoded it is pushed into a queue ( \ ref ltc_decoder_read )
*
* @ param d decoder handle
* @ param buf pointer to ltcsnd_sample_t - unsigned 8 bit mono audio data
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* @ param size size number of samples to parse
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* @ param posinfo ( optional , recommended ) sample - offset in the audio - stream . It is added to \ ref off_start , \ ref off_end in \ ref LTCFrameExt and should be monotonic ( ie incremented by \ p size for every call to ltc_decoder_write )
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*/
void ltc_decoder_write ( LTCDecoder * d ,
ltcsnd_sample_t * buf , size_t size ,
ltc_off_t posinfo ) ;
/**
* Wrapper around \ ref ltc_decoder_write that accepts floating point
* audio samples . Note : internally libltc uses 8 bit only .
*
* @ param d decoder handle
* @ param buf pointer to audio sample data
* @ param size number of samples to parse
* @ param posinfo ( optional , recommended ) sample - offset in the audio - stream .
*/
void ltc_decoder_write_float ( LTCDecoder * d , float * buf , size_t size , ltc_off_t posinfo ) ;
/**
* Wrapper around \ ref ltc_decoder_write that accepts signed 16 bit
* audio samples . Note : internally libltc uses 8 bit only .
*
* @ param d decoder handle
* @ param buf pointer to audio sample data
* @ param size number of samples to parse
* @ param posinfo ( optional , recommended ) sample - offset in the audio - stream .
*/
void ltc_decoder_write_s16 ( LTCDecoder * d , short * buf , size_t size , ltc_off_t posinfo ) ;
/**
* Wrapper around \ ref ltc_decoder_write that accepts unsigned 16 bit
* audio samples . Note : internally libltc uses 8 bit only .
*
* @ param d decoder handle
* @ param buf pointer to audio sample data
* @ param size number of samples to parse
* @ param posinfo ( optional , recommended ) sample - offset in the audio - stream .
*/
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void ltc_decoder_write_u16 ( LTCDecoder * d , unsigned short * buf , size_t size , ltc_off_t posinfo ) ;
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/**
* Decoded LTC frames are placed in a queue . This function retrieves
* a frame from the queue , and stores it at LTCFrameExt *
*
* @ param d decoder handle
* @ param frame the decoded LTC frame is copied there
* @ return 1 on success or 0 when no frames queued .
*/
int ltc_decoder_read ( LTCDecoder * d , LTCFrameExt * frame ) ;
/**
* Remove all LTC frames from the internal queue .
* @ param d decoder handle
*/
void ltc_decoder_queue_flush ( LTCDecoder * d ) ;
/**
* Count number of LTC frames currently in the queue .
* @ param d decoder handle
* @ return number of queued frames
*/
int ltc_decoder_queue_length ( LTCDecoder * d ) ;
/**
* Allocate and initialize LTC audio encoder .
*
* calls \ ref ltc_encoder_reinit internally see , see notes there .
*
* @ param sample_rate audio sample rate ( eg . 48000 )
* @ param fps video - frames per second ( e . g . 25.0 )
* @ param standard the TV standard to use for Binary Group Flag bit position
* @ param flags binary combination of \ ref LTC_BG_FLAGS
*/
LTCEncoder * ltc_encoder_create ( double sample_rate , double fps , enum LTC_TV_STANDARD standard , int flags ) ;
/**
* Release memory of the encoder .
* @ param e encoder handle
*/
void ltc_encoder_free ( LTCEncoder * e ) ;
/**
* Set the encoder LTC - frame to the given SMPTETimecode .
* The next call to \ ref ltc_encoder_encode_byte or
* \ ref ltc_encoder_encode_frame will encode this time to LTC audio - samples .
*
* Internally this call uses \ ref ltc_time_to_frame because
* the LTCEncoder operates on LTCframes only .
* see als \ ref ltc_encoder_set_frame
*
* @ param e encoder handle
* @ param t timecode to set .
*/
void ltc_encoder_set_timecode ( LTCEncoder * e , SMPTETimecode * t ) ;
/**
* Query the current encoder timecode .
*
* Note : the decoder stores its internal state in an LTC - frame ,
* this function converts that LTC - Frame into SMPTETimecode on demand .
* see also \ ref ltc_encoder_get_frame .
*
* @ param e encoder handle
* @ param t is set to current timecode
*/
void ltc_encoder_get_timecode ( LTCEncoder * e , SMPTETimecode * t ) ;
/**
* Move the encoder to the next timecode frame .
* uses \ ref ltc_frame_increment ( ) internally .
*/
int ltc_encoder_inc_timecode ( LTCEncoder * e ) ;
/**
* Move the encoder to the previous timecode frame .
* This is useful for encoding reverse LTC .
* uses \ ref ltc_frame_decrement ( ) internally .
*/
int ltc_encoder_dec_timecode ( LTCEncoder * e ) ;
/**
* Low - level access to the internal LTCFrame data .
*
* Note : be careful to about f - > dfbit , the encoder sets this [ only ] upon
* initialization .
*
* @ param e encoder handle
* @ param f LTC frame data to use
*/
void ltc_encoder_set_frame ( LTCEncoder * e , LTCFrame * f ) ;
/**
* Low - level access to the encoder internal LTCFrame data
*
* @ param e encoder handle
* @ param f return LTC frame data
*/
void ltc_encoder_get_frame ( LTCEncoder * e , LTCFrame * f ) ;
/**
* Copy the accumulated encoded audio to the given
* sample - buffer and flush the internal buffer .
*
* @ param e encoder handle
* @ param buf place to store the audio - samples , needs to be large enough
* to hold \ ref ltc_encoder_get_buffersize bytes
* @ return the number of bytes written to the memory area
* pointed to by buf .
*/
int ltc_encoder_get_buffer ( LTCEncoder * e , ltcsnd_sample_t * buf ) ;
/**
* Retrieve a pointer to the accumulated encoded audio - data .
*
* @ param e encoder handle
* @ param size if set , the number of valid bytes in the buffer is stored there
* @ param flush call \ ref ltc_encoder_buffer_flush - reset the buffer write - pointer
* @ return pointer to encoder - buffer
*/
ltcsnd_sample_t * ltc_encoder_get_bufptr ( LTCEncoder * e , int * size , int flush ) ;
/**
* reset the write - pointer of the encoder - buffer
* @ param e encoder handle
*/
void ltc_encoder_buffer_flush ( LTCEncoder * e ) ;
/**
* Query the length of the internal buffer . It is allocated
* to hold audio - frames for exactly one LTC frame for the given
* sample - rate and frame - rate . ie . ( 1 + sample - rate / fps ) bytes
*
* Note this returns the total size of the buffer , not the used / free
* part . See also \ ref ltc_encoder_get_bufptr
*
* @ param e encoder handle
* @ return size of the allocated internal buffer .
*/
size_t ltc_encoder_get_buffersize ( LTCEncoder * e ) ;
/**
* Change the encoder settings without re - allocating any
* library internal data structure ( realtime safe ) .
* changing the fps and or sample - rate implies a buffer flush ,
* and biphase state reset .
*
* This call will fail if the internal buffer is too small
* to hold one full LTC frame . Use \ ref ltc_encoder_set_bufsize to
* prepare an internal buffer large enough to accommodate all
* sample_rate , fps combinations that you would like to re - init to .
*
* The LTC frame payload data is not modified by this call , however ,
* the flag - bits of the LTC - Frame are updated :
* If fps equals to 29.97 or 30000.0 / 1001.0 , the LTCFrame ' s ' dfbit ' bit is set to 1
* to indicate drop - frame timecode .
*
* Unless the LTC_BGF_DONT_TOUCH flag is set the BGF1 is set or cleared depending
* on LTC_TC_CLOCK and BGF0 , 2 according to LTC_USE_DATE and the given standard .
* col_frame is cleared and the parity recomputed ( unless LTC_NO_PARITY is given ) .
*
* @ param e encoder handle
* @ param sample_rate audio sample rate ( eg . 48000 )
* @ param fps video - frames per second ( e . g . 25.0 )
* @ param standard the TV standard to use for Binary Group Flag bit position
* @ param flags binary combination of \ ref LTC_BG_FLAGS
*/
int ltc_encoder_reinit ( LTCEncoder * e , double sample_rate , double fps , enum LTC_TV_STANDARD standard , int flags ) ;
/**
* reset ecoder state .
* flushes buffer , reset biphase state
*
* @ param e encoder handle
*/
void ltc_encoder_reset ( LTCEncoder * e ) ;
/**
* Configure a custom size for the internal buffer .
*
* This is needed if you are planning to call \ ref ltc_encoder_reinit ( )
* or if you want to keep more than one LTC frame ' s worth of data in
* the library ' s internal buffer .
*
* The buffer - size is ( 1 + sample_rate / fps ) bytes .
* resizing the internal buffer will flush all existing data
* in it - alike \ ref ltc_encoder_buffer_flush .
*
* @ param e encoder handle
* @ param sample_rate audio sample rate ( eg . 48000 )
* @ param fps video - frames per second ( e . g . 25.0 )
* @ return 0 on success , - 1 if allocation fails ( which makes the
* encoder unusable , call \ ref ltc_encoder_free or realloc the buffer )
*/
int ltc_encoder_set_bufsize ( LTCEncoder * e , double sample_rate , double fps ) ;
/**
* Set the volume of the generated LTC signal
*
* typically LTC is sent at 0 dBu ; in EBU callibrated systems that
* corresponds to - 18 dBFS . - by default libltc creates - 3 dBFS
*
2017-07-26 16:23:50 -04:00
* since libltc generated 8 bit audio - data , the minimum dBFS
2012-12-14 11:18:47 -05:00
* is about - 42 dB which corresponds to 1 bit .
*
* 0 dB corresponds to a signal range of 127
* 1. .255 with 128 at the center .
*
* @ param e encoder handle
* @ param dBFS the volume in dB full - scale ( < = 0.0 )
* @ return 0 on success , - 1 if the value was out of range
*/
int ltc_encoder_set_volume ( LTCEncoder * e , double dBFS ) ;
/**
* Set encoder signal rise - time / signal filtering
*
* LTC signal should have a rise time of 40u s + / - 10 us .
* by default the encoder honors this and low - pass filters
* the output depending on the sample - rate .
*
* If you want a perfect square wave , set ' rise_time ' to 0.
*
* Note \ ref ltc_encoder_reinit resets the filter - time - constant to use
* the default 40u s for the given sample - rate , overriding any value
* previously set with \ ref ltc_encoder_set_filter
*
* @ param e encoder handle
* @ param rise_time the signal rise - time in us ( 10 ^ ( - 6 ) sec ) , set to 0 for perfect square wave , default 40.0
*/
void ltc_encoder_set_filter ( LTCEncoder * e , double rise_time ) ;
/**
* Generate LTC audio for given byte of the LTC - frame and
* place it into the internal buffer .
*
* see \ ref ltc_encoder_get_buffer and \ ref ltc_encoder_get_bufptr
*
* LTC has 10 bytes per frame : 0 < = bytecnt < 10
* use SMPTESetTime ( . . ) to set the current frame before Encoding .
* see tests / encoder . c for an example .
*
* The default output signal is @ - 3 dBFS ( 38. .218 at 8 bit unsigned ) .
* see also \ ref ltc_encoder_set_volume
*
* if speed is < 0 , the bits are encoded in reverse .
* slowdown > 10.0 requires custom buffer sizes ; see \ ref ltc_encoder_set_bufsize
*
* @ param e encoder handle
* @ param byte byte of the LTC - frame to encode 0. .9
* @ param speed vari - speed , < 1.0 faster , > 1.0 slower ; must be ! = 0
*
* @ return 0 on success , - 1 if byte is invalid or buffer overflow ( speed > 10.0 )
*/
int ltc_encoder_encode_byte ( LTCEncoder * e , int byte , double speed ) ;
/**
* Encode a full LTC frame at fixed speed .
* This is equivalent to calling \ ref ltc_encoder_encode_byte 10 times for
* bytes 0. .9 with speed 1.0 .
*
* Note : The internal buffer must be empty before calling this function .
* Otherwise it may overflow . This is usually the case if it is read with
* \ ref ltc_encoder_get_buffer after calling this function .
*
* The default internal buffersize is exactly one full LTC frame at speed 1.0 .
*
* @ param e encoder handle
*/
void ltc_encoder_encode_frame ( LTCEncoder * e ) ;
/**
* Set the parity of the LTC frame .
*
* Bi - Phase Mark Phase Correction bit ( bit 27 - or 59 ) may be set or cleared so that
* that every 80 - bit word contains an even number of zeroes .
* This means that the phase in every Sync Word will be the same .
*
* This is merely cosmetic ; the motivation to keep the polarity of the waveform
* constant is to make finding the Sync Word visibly ( on a scope ) easier .
*
* There is usually no need to call this function directly . The encoder utility
* functions \ ref ltc_time_to_frame , \ ref ltc_frame_increment and
* \ ref ltc_frame_decrement include a call to it .
*
* @ param frame the LTC to analyze and set or clear the biphase_mark_phase_correction bit .
* @ param standard If 1 ( aka LTC_TV_625_50 ) , the 25f ps mode ( bit 59 - aka binary_group_flag_bit2 ) is used , otherwise the 30f ps , 24f ps mode ( bit 27 - - biphase_mark_phase_correction ) is set or cleared .
*/
void ltc_frame_set_parity ( LTCFrame * frame , enum LTC_TV_STANDARD standard ) ;
/**
* Parse Binary Group Flags into standard independent format :
* bit 0 ( 1 ) - BGF 0 ,
* bit 1 ( 2 ) - BGF 1 ,
* bit 2 ( 4 ) - BGF 2
*
* @ param f LTC frame data analyze
* @ param standard the TV standard to use - - see \ ref LTCFrame for BGF assignment
* @ return LTC Binary Group Flags
*/
int parse_bcg_flags ( LTCFrame * f , enum LTC_TV_STANDARD standard ) ;
/**
* LTCFrame sample alignment offset .
*
* There is a relative offset of the LTC - Frame start and the TV - frame .
* The first bit of a LTC frame corresponds to a specific line in the actual video
* frame . When decoding this offset needs to be subtracted from the LTC - frame ' s
* audio - sample - time to match the TV - frame ' s start position .
*
* For film frames or HDV the offset is zero .
*
* @ param samples_per_frame audio - samples per timecode - frame ( eg . 1920 = 48000 / 25 )
* @ param standard the TV standard
* @ return offset in samples
*/
ltc_off_t ltc_frame_alignment ( double samples_per_frame , enum LTC_TV_STANDARD standard ) ;
# ifdef __cplusplus
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# endif
# endif