970 lines
28 KiB
C
970 lines
28 KiB
C
/*
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* refclock_irig - audio IRIG-B/E demodulator/decoder
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*/
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#ifdef HAVE_CONFIG_H
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#include <config.h>
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#endif
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#if defined(REFCLOCK) && defined(CLOCK_IRIG)
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#include <stdio.h>
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#include <ctype.h>
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#include <sys/time.h>
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#include <math.h>
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#ifdef HAVE_SYS_IOCTL_H
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#include <sys/ioctl.h>
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#endif /* HAVE_SYS_IOCTL_H */
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#include "ntpd.h"
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#include "ntp_io.h"
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#include "ntp_refclock.h"
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#include "ntp_calendar.h"
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#include "ntp_stdlib.h"
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#include "audio.h"
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/*
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* Audio IRIG-B/E demodulator/decoder
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*
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* This driver receives, demodulates and decodes IRIG-B/E signals when
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* connected to the audio codec /dev/audio. The IRIG signal format is an
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* amplitude-modulated carrier with pulse-width modulated data bits. For
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* IRIG-B, the carrier frequency is 1000 Hz and bit rate 100 b/s; for
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* IRIG-E, the carrier frequenchy is 100 Hz and bit rate 10 b/s. The
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* driver automatically recognizes which format is in use.
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*
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* The program processes 8000-Hz mu-law companded samples using separate
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* signal filters for IRIG-B and IRIG-E, a comb filter, envelope
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* detector and automatic threshold corrector. Cycle crossings relative
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* to the corrected slice level determine the width of each pulse and
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* its value - zero, one or position identifier. The data encode 20 BCD
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* digits which determine the second, minute, hour and day of the year
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* and sometimes the year and synchronization condition. The comb filter
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* exponentially averages the corresponding samples of successive baud
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* intervals in order to reliably identify the reference carrier cycle.
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* A type-II phase-lock loop (PLL) performs additional integration and
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* interpolation to accurately determine the zero crossing of that
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* cycle, which determines the reference timestamp. A pulse-width
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* discriminator demodulates the data pulses, which are then encoded as
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* the BCD digits of the timecode.
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*
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* The timecode and reference timestamp are updated once each second
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* with IRIG-B (ten seconds with IRIG-E) and local clock offset samples
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* saved for later processing. At poll intervals of 64 s, the saved
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* samples are processed by a trimmed-mean filter and used to update the
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* system clock.
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*
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* An automatic gain control feature provides protection against
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* overdriven or underdriven input signal amplitudes. It is designed to
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* maintain adequate demodulator signal amplitude while avoiding
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* occasional noise spikes. In order to assure reliable capture, the
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* decompanded input signal amplitude must be greater than 100 units and
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* the codec sample frequency error less than 250 PPM (.025 percent).
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*
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* The program performs a number of error checks to protect against
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* overdriven or underdriven input signal levels, incorrect signal
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* format or improper hardware configuration. Specifically, if any of
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* the following errors occur for a time measurement, the data are
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* rejected.
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*
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* o The peak carrier amplitude is less than DRPOUT (100). This usually
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* means dead IRIG signal source, broken cable or wrong input port.
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*
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* o The frequency error is greater than MAXFREQ +-250 PPM (.025%). This
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* usually means broken codec hardware or wrong codec configuration.
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*
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* o The modulation index is less than MODMIN (0.5). This usually means
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* overdriven IRIG signal or wrong IRIG format.
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*
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* o A frame synchronization error has occurred. This usually means wrong
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* IRIG signal format or the IRIG signal source has lost
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* synchronization (signature control).
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*
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* o A data decoding error has occurred. This usually means wrong IRIG
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* signal format.
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*
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* o The current second of the day is not exactly one greater than the
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* previous one. This usually means a very noisy IRIG signal or
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* insufficient CPU resources.
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*
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* o An audio codec error (overrun) occurred. This usually means
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* insufficient CPU resources, as sometimes happens with Sun SPARC
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* IPCs when doing something useful.
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*
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* Note that additional checks are done elsewhere in the reference clock
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* interface routines.
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*
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* Debugging aids
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*
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* The timecode format used for debugging and data recording includes
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* data helpful in diagnosing problems with the IRIG signal and codec
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* connections. With debugging enabled (-d -d -d on the ntpd command
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* line), the driver produces one line for each timecode in the
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* following format:
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*
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* 00 1 98 23 19:26:52 721 143 0.694 47 20 0.083 66.5 3094572411.00027
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*
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* The most recent line is also written to the clockstats file at 64-s
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* intervals.
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*
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* The first field contains the error flags in hex, where the hex bits
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* are interpreted as below. This is followed by the IRIG status
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* indicator, year of century, day of year and time of day. The status
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* indicator and year are not produced by some IRIG devices. Following
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* these fields are the signal amplitude (0-8100), codec gain (0-255),
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* field phase (0-79), time constant (2-20), modulation index (0-1),
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* carrier phase error (0+-0.5) and carrier frequency error (PPM). The
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* last field is the on-time timestamp in NTP format.
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*
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* The fraction part of the on-time timestamp is a good indicator of how
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* well the driver is doing. With an UltrSPARC 30, this thing can keep
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* the clock within a few tens of microseconds relative to the IRIG-B
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* signal. Accuracy with IRIG-E is about ten times worse.
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*
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* Unlike other drivers, which can have multiple instantiations, this
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* one supports only one. It does not seem likely that more than one
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* audio codec would be useful in a single machine. More than one would
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* probably chew up too much CPU time anyway.
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*
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* Fudge factors
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*
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* Fudge flag2 selects the audio input port, where 0 is the mike port
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* (default) and 1 is the line-in port. It does not seem useful to
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* select the compact disc player port. Fudge flag3 enables audio
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* monitoring of the input signal. For this purpose, the speaker volume
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* must be set before the driver is started. Fudge flag4 causes the
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* debugging output described above to be recorded in the clockstats
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* file. Any of these flags can be changed during operation with the
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* ntpdc program.
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*/
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/*
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* Interface definitions
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*/
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#define PRECISION (-17) /* precision assumed (about 10 us) */
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#define REFID "IRIG" /* reference ID */
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#define DESCRIPTION "Generic IRIG Audio Driver" /* WRU */
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#define SECOND 8000 /* nominal sample rate (Hz) */
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#define BAUD 80 /* samples per baud interval */
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#define OFFSET 128 /* companded sample offset */
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#define SIZE 256 /* decompanding table size */
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#define CYCLE 8 /* samples per carrier cycle */
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#define SUBFLD 10 /* bits per subfield */
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#define FIELD 10 /* subfields per field */
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#define MINTC 2 /* min PLL time constant */
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#define MAXTC 20 /* max PLL time constant max */
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#define MAXSIG 6000. /* maximum signal level */
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#define DRPOUT 100. /* dropout signal level */
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#define MODMIN 0.5 /* minimum modulation index */
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#define MAXFREQ (250e-6 * SECOND) /* freq tolerance (.025%) */
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#define PI 3.1415926535 /* the real thing */
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/*
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* Experimentally determined fudge factors
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*/
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#define IRIG_B .0019 /* IRIG-B phase delay */
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#define IRIG_E .0019 /* IRIG-E phase delay */
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/*
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* Data bit definitions
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*/
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#define BIT0 0 /* zero */
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#define BIT1 1 /* one */
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#define BITP 2 /* position identifier */
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/*
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* Error flags (up->errflg)
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*/
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#define IRIG_ERR_AMP 0x01 /* low carrier amplitude */
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#define IRIG_ERR_FREQ 0x02 /* frequency tolerance exceeded */
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#define IRIG_ERR_MOD 0x04 /* low modulation index */
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#define IRIG_ERR_SYNCH 0x08 /* frame synch error */
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#define IRIG_ERR_DECODE 0x10 /* frame decoding error */
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#define IRIG_ERR_CHECK 0x20 /* second numbering discrepancy */
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#define IRIG_ERR_ERROR 0x40 /* codec error (overrun) */
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/*
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* IRIG unit control structure
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*/
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struct irigunit {
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u_char timecode[21]; /* timecode string */
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l_fp timestamp; /* audio sample timestamp */
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l_fp tick; /* audio sample increment */
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double comp[SIZE]; /* decompanding table */
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double integ[BAUD]; /* baud integrator */
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double phase, freq; /* logical clock phase and frequency */
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double zxing; /* phase detector integrator */
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double yxing; /* phase detector display */
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double modndx; /* modulation index */
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double irig_b; /* IRIG-B signal amplitude */
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double irig_e; /* IRIG-E signal amplitude */
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int errflg; /* error flags */
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int bufcnt; /* samples in buffer */
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int bufptr; /* buffer index pointer */
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int pollcnt; /* poll counter */
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int port; /* codec port */
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int gain; /* codec gain */
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int clipcnt; /* sample clipped count */
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int seccnt; /* second interval counter */
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int decim; /* sample decimation factor */
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/*
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* RF variables
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*/
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double hpf[5]; /* IRIG-B filter shift register */
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double lpf[5]; /* IRIG-E filter shift register */
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double intmin, intmax; /* integrated envelope min and max */
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double envmax; /* peak amplitude */
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double envmin; /* noise amplitude */
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double maxsignal; /* integrated peak amplitude */
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double noise; /* integrated noise amplitude */
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double lastenv[CYCLE]; /* last cycle amplitudes */
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double lastint[CYCLE]; /* last integrated cycle amplitudes */
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double lastsig; /* last carrier sample */
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double xxing; /* phase detector interpolated output */
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double fdelay; /* filter delay */
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int envphase; /* envelope phase */
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int envptr; /* envelope phase pointer */
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int carphase; /* carrier phase */
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int envsw; /* envelope state */
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int envxing; /* envelope slice crossing */
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int tc; /* time constant */
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int tcount; /* time constant counter */
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int badcnt; /* decimation interval counter */
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/*
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* Decoder variables
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*/
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l_fp montime; /* reference timestamp for eyeball */
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int timecnt; /* timecode counter */
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int pulse; /* cycle counter */
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int cycles; /* carrier cycles */
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int dcycles; /* data cycles */
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int xptr; /* translate table pointer */
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int lastbit; /* last code element length */
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int second; /* previous second */
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int fieldcnt; /* subfield count in field */
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int bits; /* demodulated bits */
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int bitcnt; /* bit count in subfield */
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};
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/*
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* Function prototypes
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*/
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static int irig_start P((int, struct peer *));
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static void irig_shutdown P((int, struct peer *));
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static void irig_receive P((struct recvbuf *));
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static void irig_poll P((int, struct peer *));
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/*
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* More function prototypes
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*/
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static void irig_base P((struct peer *, double));
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static void irig_rf P((struct peer *, double));
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static void irig_decode P((struct peer *, int));
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static void irig_gain P((struct peer *));
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/*
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* Transfer vector
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*/
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struct refclock refclock_irig = {
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irig_start, /* start up driver */
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irig_shutdown, /* shut down driver */
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irig_poll, /* transmit poll message */
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noentry, /* not used (old irig_control) */
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noentry, /* initialize driver (not used) */
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noentry, /* not used (old irig_buginfo) */
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NOFLAGS /* not used */
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};
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/*
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* Global variables
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*/
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static char hexchar[] = { /* really quick decoding table */
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'0', '8', '4', 'c', /* 0000 0001 0010 0011 */
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'2', 'a', '6', 'e', /* 0100 0101 0110 0111 */
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'1', '9', '5', 'd', /* 1000 1001 1010 1011 */
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'3', 'b', '7', 'f' /* 1100 1101 1110 1111 */
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};
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/*
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* irig_start - open the devices and initialize data for processing
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*/
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static int
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irig_start(
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int unit, /* instance number (not used) */
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struct peer *peer /* peer structure pointer */
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)
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{
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struct refclockproc *pp;
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struct irigunit *up;
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/*
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* Local variables
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*/
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int fd; /* file descriptor */
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int i; /* index */
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double step; /* codec adjustment */
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/*
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* Open audio device
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*/
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fd = audio_init();
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if (fd < 0)
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return (0);
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#ifdef DEBUG
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if (debug)
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audio_show();
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#endif
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/*
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* Allocate and initialize unit structure
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*/
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if (!(up = (struct irigunit *)
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emalloc(sizeof(struct irigunit)))) {
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(void) close(fd);
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return (0);
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}
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memset((char *)up, 0, sizeof(struct irigunit));
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pp = peer->procptr;
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pp->unitptr = (caddr_t)up;
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pp->io.clock_recv = irig_receive;
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pp->io.srcclock = (caddr_t)peer;
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pp->io.datalen = 0;
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pp->io.fd = fd;
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if (!io_addclock(&pp->io)) {
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(void)close(fd);
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free(up);
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return (0);
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}
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/*
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* Initialize miscellaneous variables
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*/
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peer->precision = PRECISION;
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pp->clockdesc = DESCRIPTION;
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memcpy((char *)&pp->refid, REFID, 4);
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up->tc = MINTC;
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up->decim = 1;
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up->fdelay = IRIG_B;
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up->gain = 127;
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up->pollcnt = 2;
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/*
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* The companded samples are encoded sign-magnitude. The table
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* contains all the 256 values in the interest of speed.
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*/
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up->comp[0] = up->comp[OFFSET] = 0.;
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up->comp[1] = 1; up->comp[OFFSET + 1] = -1.;
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up->comp[2] = 3; up->comp[OFFSET + 2] = -3.;
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step = 2.;
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for (i = 3; i < OFFSET; i++) {
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up->comp[i] = up->comp[i - 1] + step;
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up->comp[OFFSET + i] = -up->comp[i];
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if (i % 16 == 0)
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step *= 2.;
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}
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DTOLFP(1. / SECOND, &up->tick);
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return (1);
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}
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/*
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* irig_shutdown - shut down the clock
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*/
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static void
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irig_shutdown(
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int unit, /* instance number (not used) */
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struct peer *peer /* peer structure pointer */
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)
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{
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struct refclockproc *pp;
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struct irigunit *up;
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pp = peer->procptr;
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up = (struct irigunit *)pp->unitptr;
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io_closeclock(&pp->io);
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free(up);
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}
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/*
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* irig_receive - receive data from the audio device
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*
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* This routine reads input samples and adjusts the logical clock to
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* track the irig clock by dropping or duplicating codec samples.
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*/
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static void
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irig_receive(
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struct recvbuf *rbufp /* receive buffer structure pointer */
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)
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{
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struct peer *peer;
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struct refclockproc *pp;
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struct irigunit *up;
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/*
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* Local variables
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*/
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double sample; /* codec sample */
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u_char *dpt; /* buffer pointer */
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l_fp ltemp; /* l_fp temp */
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peer = (struct peer *)rbufp->recv_srcclock;
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pp = peer->procptr;
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up = (struct irigunit *)pp->unitptr;
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/*
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* Main loop - read until there ain't no more. Note codec
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* samples are bit-inverted.
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*/
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up->timestamp = rbufp->recv_time;
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up->bufcnt = rbufp->recv_length;
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DTOLFP((double)up->bufcnt / SECOND, <emp);
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L_SUB(&up->timestamp, <emp);
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dpt = rbufp->recv_buffer;
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for (up->bufptr = 0; up->bufptr < up->bufcnt; up->bufptr++) {
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sample = up->comp[~*dpt++ & 0xff];
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/*
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* Clip noise spikes greater than MAXSIG. If no clips,
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* increase the gain a tad; if the clips are too high,
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* decrease a tad. Choose either IRIG-B or IRIG-E
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* according to the energy at the respective filter
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* output.
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*/
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if (sample > MAXSIG) {
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sample = MAXSIG;
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up->clipcnt++;
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} else if (sample < -MAXSIG) {
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sample = -MAXSIG;
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up->clipcnt++;
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}
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/*
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* Variable frequency oscillator. A phase change of one
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* unit produces a change of 360 degrees; a frequency
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* change of one unit produces a change of 1 Hz.
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*/
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up->phase += up->freq / SECOND;
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if (up->phase >= .5) {
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up->phase -= 1.;
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} else if (up->phase < -.5) {
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up->phase += 1.;
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irig_rf(peer, sample);
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irig_rf(peer, sample);
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} else {
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irig_rf(peer, sample);
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}
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L_ADD(&up->timestamp, &up->tick);
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/*
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* Once each second, determine the IRIG format, codec
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* port and gain.
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*/
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up->seccnt = (up->seccnt + 1) % SECOND;
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if (up->seccnt == 0) {
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if (up->irig_b > up->irig_e) {
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up->decim = 1;
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up->fdelay = IRIG_B;
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} else {
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up->decim = 10;
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up->fdelay = IRIG_E;
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}
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if (pp->sloppyclockflag & CLK_FLAG2)
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up->port = 2;
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else
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up->port = 1;
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irig_gain(peer);
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up->irig_b = up->irig_e = 0;
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}
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}
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/*
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* Squawk to the monitor speaker if enabled.
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*/
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if (pp->sloppyclockflag & CLK_FLAG3)
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if (write(pp->io.fd, (u_char *)&rbufp->recv_space,
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(u_int)up->bufcnt) < 0)
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perror("irig:");
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}
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/*
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* irig_rf - RF processing
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*
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* This routine filters the RF signal using a highpass filter for IRIG-B
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* and a lowpass filter for IRIG-E. In case of IRIG-E, the samples are
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* decimated by a factor of ten. The lowpass filter functions also as a
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* decimation filter in this case. Note that the codec filters function
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* as roofing filters to attenuate both the high and low ends of the
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* passband. IIR filter coefficients were determined using Matlab Signal
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* Processing Toolkit.
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*/
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static void
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irig_rf(
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struct peer *peer, /* peer structure pointer */
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double sample /* current signal sample */
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|
)
|
|
{
|
|
struct refclockproc *pp;
|
|
struct irigunit *up;
|
|
|
|
/*
|
|
* Local variables
|
|
*/
|
|
double irig_b, irig_e; /* irig filter outputs */
|
|
|
|
pp = peer->procptr;
|
|
up = (struct irigunit *)pp->unitptr;
|
|
|
|
/*
|
|
* IRIG-B filter. 4th-order elliptic, 800-Hz highpass, 0.3 dB
|
|
* passband ripple, -50 dB stopband ripple, phase delay -.0022
|
|
* s)
|
|
*/
|
|
irig_b = (up->hpf[4] = up->hpf[3]) * 2.322484e-01;
|
|
irig_b += (up->hpf[3] = up->hpf[2]) * -1.103929e+00;
|
|
irig_b += (up->hpf[2] = up->hpf[1]) * 2.351081e+00;
|
|
irig_b += (up->hpf[1] = up->hpf[0]) * -2.335036e+00;
|
|
up->hpf[0] = sample - irig_b;
|
|
irig_b = up->hpf[0] * 4.335855e-01
|
|
+ up->hpf[1] * -1.695859e+00
|
|
+ up->hpf[2] * 2.525004e+00
|
|
+ up->hpf[3] * -1.695859e+00
|
|
+ up->hpf[4] * 4.335855e-01;
|
|
up->irig_b += irig_b * irig_b;
|
|
|
|
/*
|
|
* IRIG-E filter. 4th-order elliptic, 130-Hz lowpass, 0.3 dB
|
|
* passband ripple, -50 dB stopband ripple, phase delay .0219 s.
|
|
*/
|
|
irig_e = (up->lpf[4] = up->lpf[3]) * 8.694604e-01;
|
|
irig_e += (up->lpf[3] = up->lpf[2]) * -3.589893e+00;
|
|
irig_e += (up->lpf[2] = up->lpf[1]) * 5.570154e+00;
|
|
irig_e += (up->lpf[1] = up->lpf[0]) * -3.849667e+00;
|
|
up->lpf[0] = sample - irig_e;
|
|
irig_e = up->lpf[0] * 3.215696e-03
|
|
+ up->lpf[1] * -1.174951e-02
|
|
+ up->lpf[2] * 1.712074e-02
|
|
+ up->lpf[3] * -1.174951e-02
|
|
+ up->lpf[4] * 3.215696e-03;
|
|
up->irig_e += irig_e * irig_e;
|
|
|
|
/*
|
|
* Decimate by a factor of either 1 (IRIG-B) or 10 (IRIG-E).
|
|
*/
|
|
up->badcnt = (up->badcnt + 1) % up->decim;
|
|
if (up->badcnt == 0) {
|
|
if (up->decim == 1)
|
|
irig_base(peer, irig_b);
|
|
else
|
|
irig_base(peer, irig_e);
|
|
}
|
|
}
|
|
|
|
/*
|
|
* irig_base - baseband processing
|
|
*
|
|
* This routine processes the baseband signal and demodulates the AM
|
|
* carrier using a synchronous detector. It then synchronizes to the
|
|
* data frame at the baud rate and decodes the data pulses.
|
|
*/
|
|
static void
|
|
irig_base(
|
|
struct peer *peer, /* peer structure pointer */
|
|
double sample /* current signal sample */
|
|
)
|
|
{
|
|
struct refclockproc *pp;
|
|
struct irigunit *up;
|
|
|
|
/*
|
|
* Local variables
|
|
*/
|
|
double lope; /* integrator output */
|
|
double env; /* envelope detector output */
|
|
double dtemp; /* double temp */
|
|
int i; /* index temp */
|
|
|
|
pp = peer->procptr;
|
|
up = (struct irigunit *)pp->unitptr;
|
|
|
|
/*
|
|
* Synchronous baud integrator. Corresponding samples of current
|
|
* and past baud intervals are integrated to refine the envelope
|
|
* amplitude and phase estimate. We keep one cycle of both the
|
|
* raw and integrated data for later use.
|
|
*/
|
|
up->envphase = (up->envphase + 1) % BAUD;
|
|
up->carphase = (up->carphase + 1) % CYCLE;
|
|
up->integ[up->envphase] += (sample - up->integ[up->envphase]) /
|
|
(5 * up->tc);
|
|
lope = up->integ[up->envphase];
|
|
up->lastenv[up->carphase] = sample;
|
|
up->lastint[up->carphase] = lope;
|
|
|
|
/*
|
|
* Phase detector. Sample amplitudes are integrated over the
|
|
* baud interval. Cycle phase is determined from these
|
|
* amplitudes using an eight-sample cyclic buffer. A phase
|
|
* change of 360 degrees produces an output change of one unit.
|
|
*/
|
|
if (up->lastsig > 0 && lope <= 0) {
|
|
up->xxing = lope / (up->lastsig - lope);
|
|
up->zxing += (up->carphase - 4 + up->xxing) / 8.;
|
|
}
|
|
up->lastsig = lope;
|
|
|
|
/*
|
|
* Update signal/noise estimates and PLL phase/frequency.
|
|
*/
|
|
if (up->envphase == 0) {
|
|
|
|
/*
|
|
* Update envelope signal and noise estimates and mess
|
|
* with error bits.
|
|
*/
|
|
up->maxsignal = up->intmax;
|
|
up->noise = up->intmin;
|
|
if (up->maxsignal < DRPOUT)
|
|
up->errflg |= IRIG_ERR_AMP;
|
|
if (up->intmax > 0)
|
|
up->modndx = (up->intmax - up->intmin) / up->intmax;
|
|
else
|
|
up->modndx = 0;
|
|
if (up->modndx < MODMIN)
|
|
up->errflg |= IRIG_ERR_MOD;
|
|
up->intmin = 1e6; up->intmax = 0;
|
|
if (up->errflg & (IRIG_ERR_AMP | IRIG_ERR_FREQ |
|
|
IRIG_ERR_MOD | IRIG_ERR_SYNCH)) {
|
|
up->tc = MINTC;
|
|
up->tcount = 0;
|
|
}
|
|
|
|
/*
|
|
* Update PLL phase and frequency. The PLL time constant
|
|
* is set initially to stabilize the frequency within a
|
|
* minute or two, then increases to the maximum. The
|
|
* frequency is clamped so that the PLL capture range
|
|
* cannot be exceeded.
|
|
*/
|
|
dtemp = up->zxing * up->decim / BAUD;
|
|
up->yxing = dtemp;
|
|
up->zxing = 0.;
|
|
up->phase += dtemp / up->tc;
|
|
up->freq += dtemp / (4. * up->tc * up->tc);
|
|
if (up->freq > MAXFREQ) {
|
|
up->freq = MAXFREQ;
|
|
up->errflg |= IRIG_ERR_FREQ;
|
|
} else if (up->freq < -MAXFREQ) {
|
|
up->freq = -MAXFREQ;
|
|
up->errflg |= IRIG_ERR_FREQ;
|
|
}
|
|
}
|
|
|
|
/*
|
|
* Synchronous demodulator. There are eight samples in the cycle
|
|
* and ten cycles in the baud interval. The amplitude of each
|
|
* cycle is determined at the last sample in the cycle. The
|
|
* beginning of the data pulse is determined from the integrated
|
|
* samples, while the end of the pulse is determined from the
|
|
* raw samples. The raw data bits are demodulated relative to
|
|
* the slice level and left-shifted in the decoding register.
|
|
*/
|
|
if (up->carphase != 7)
|
|
return;
|
|
env = (up->lastenv[2] - up->lastenv[6]) / 2.;
|
|
lope = (up->lastint[2] - up->lastint[6]) / 2.;
|
|
if (lope > up->intmax)
|
|
up->intmax = lope;
|
|
if (lope < up->intmin)
|
|
up->intmin = lope;
|
|
|
|
/*
|
|
* Pulse code demodulator and reference timestamp. The decoder
|
|
* looks for a sequence of ten bits; the first two bits must be
|
|
* one, the last two bits must be zero. Frame synch is asserted
|
|
* when three correct frames have been found.
|
|
*/
|
|
up->pulse = (up->pulse + 1) % 10;
|
|
if (up->pulse == 1)
|
|
up->envmax = env;
|
|
else if (up->pulse == 9)
|
|
up->envmin = env;
|
|
up->dcycles <<= 1;
|
|
if (env >= (up->envmax + up->envmin) / 2.)
|
|
up->dcycles |= 1;
|
|
up->cycles <<= 1;
|
|
if (lope >= (up->maxsignal + up->noise) / 2.)
|
|
up->cycles |= 1;
|
|
if ((up->cycles & 0x303c0f03) == 0x300c0300) {
|
|
l_fp ltemp;
|
|
int bitz;
|
|
|
|
/*
|
|
* The PLL time constant starts out small, in order to
|
|
* sustain a frequency tolerance of 250 PPM. It
|
|
* gradually increases as the loop settles down. Note
|
|
* that small wiggles are not believed, unless they
|
|
* persist for lots of samples.
|
|
*/
|
|
if (up->pulse != 9)
|
|
up->errflg |= IRIG_ERR_SYNCH;
|
|
up->pulse = 9;
|
|
dtemp = BAUD - up->zxing;
|
|
i = up->envxing - up->envphase;
|
|
if (i < 0)
|
|
i -= i;
|
|
if (i <= 1) {
|
|
up->tcount++;
|
|
if (up->tcount > 50 * up->tc) {
|
|
up->tc++;
|
|
if (up->tc > MAXTC)
|
|
up->tc = MAXTC;
|
|
up->tcount = 0;
|
|
up->envxing = up->envphase;
|
|
} else {
|
|
dtemp -= up->envxing - up->envphase;
|
|
}
|
|
} else {
|
|
up->tcount = 0;
|
|
up->envxing = up->envphase;
|
|
}
|
|
|
|
/*
|
|
* Determine a reference timestamp, accounting for the
|
|
* codec delay and filter delay. Note the timestamp is
|
|
* for the previous frame, so we have to backtrack for
|
|
* this plus the delay since the last carrier positive
|
|
* zero crossing.
|
|
*/
|
|
DTOLFP(up->decim * (dtemp / SECOND + 1.) + up->fdelay,
|
|
<emp);
|
|
pp->lastrec = up->timestamp;
|
|
L_SUB(&pp->lastrec, <emp);
|
|
|
|
/*
|
|
* The data bits are collected in ten-bit frames. The
|
|
* first two and last two bits are determined by frame
|
|
* sync and ignored here; the resulting patterns
|
|
* represent zero (0-1 bits), one (2-4 bits) and
|
|
* position identifier (5-6 bits). The remaining
|
|
* patterns represent errors and are treated as zeros.
|
|
*/
|
|
bitz = up->dcycles & 0xfc;
|
|
switch(bitz) {
|
|
|
|
case 0x00:
|
|
case 0x80:
|
|
irig_decode(peer, BIT0);
|
|
break;
|
|
|
|
case 0xc0:
|
|
case 0xe0:
|
|
case 0xf0:
|
|
irig_decode(peer, BIT1);
|
|
break;
|
|
|
|
case 0xf8:
|
|
case 0xfc:
|
|
irig_decode(peer, BITP);
|
|
break;
|
|
|
|
default:
|
|
irig_decode(peer, 0);
|
|
up->errflg |= IRIG_ERR_DECODE;
|
|
}
|
|
}
|
|
}
|
|
|
|
|
|
/*
|
|
* irig_decode - decode the data
|
|
*
|
|
* This routine assembles bits into digits, digits into subfields and
|
|
* subfields into the timecode field. Bits can have values of zero, one
|
|
* or position identifier. There are four bits per digit, two digits per
|
|
* subfield and ten subfields per field. The last bit in every subfield
|
|
* and the first bit in the first subfield are position identifiers.
|
|
*/
|
|
static void
|
|
irig_decode(
|
|
struct peer *peer, /* peer structure pointer */
|
|
int bit /* data bit (0, 1 or 2) */
|
|
)
|
|
{
|
|
struct refclockproc *pp;
|
|
struct irigunit *up;
|
|
|
|
/*
|
|
* Local variables
|
|
*/
|
|
char syncchar; /* sync character (Spectracom only) */
|
|
char sbs[6]; /* binary seconds since 0h */
|
|
char spare[2]; /* mulligan digits */
|
|
|
|
pp = peer->procptr;
|
|
up = (struct irigunit *)pp->unitptr;
|
|
|
|
/*
|
|
* Assemble subfield bits.
|
|
*/
|
|
up->bits <<= 1;
|
|
if (bit == BIT1) {
|
|
up->bits |= 1;
|
|
} else if (bit == BITP && up->lastbit == BITP) {
|
|
|
|
/*
|
|
* Frame sync - two adjacent position identifiers.
|
|
* Monitor the reference timestamp and wiggle the
|
|
* clock, but only if no errors have occurred.
|
|
*/
|
|
up->bitcnt = 1;
|
|
up->fieldcnt = 0;
|
|
up->lastbit = 0;
|
|
up->montime = pp->lastrec;
|
|
if (up->errflg == 0) {
|
|
up->timecnt++;
|
|
refclock_process(pp);
|
|
}
|
|
if (up->timecnt >= MAXSTAGE) {
|
|
refclock_receive(peer);
|
|
up->timecnt = 0;
|
|
up->pollcnt = 2;
|
|
}
|
|
up->errflg = 0;
|
|
}
|
|
up->bitcnt = (up->bitcnt + 1) % SUBFLD;
|
|
if (up->bitcnt == 0) {
|
|
|
|
/*
|
|
* End of subfield. Encode two hexadecimal digits in
|
|
* little-endian timecode field.
|
|
*/
|
|
if (up->fieldcnt == 0)
|
|
up->bits <<= 1;
|
|
if (up->xptr < 2)
|
|
up->xptr = 2 * FIELD;
|
|
up->timecode[--up->xptr] = hexchar[(up->bits >> 5) &
|
|
0xf];
|
|
up->timecode[--up->xptr] = hexchar[up->bits & 0xf];
|
|
up->fieldcnt = (up->fieldcnt + 1) % FIELD;
|
|
if (up->fieldcnt == 0) {
|
|
|
|
/*
|
|
* End of field. Decode the timecode, adjust the
|
|
* gain and set the input port. Set the port
|
|
* here on the assumption somebody might even
|
|
* change it on-wing.
|
|
*/
|
|
up->xptr = 2 * FIELD;
|
|
if (sscanf((char *)up->timecode,
|
|
"%6s%2d%c%2s%3d%2d%2d%2d",
|
|
sbs, &pp->year, &syncchar, spare, &pp->day,
|
|
&pp->hour, &pp->minute, &pp->second) != 8)
|
|
pp->leap = LEAP_NOTINSYNC;
|
|
else
|
|
pp->leap = LEAP_NOWARNING;
|
|
up->second = (up->second + up->decim) % 60;
|
|
if (pp->second != up->second)
|
|
up->errflg |= IRIG_ERR_CHECK;
|
|
up->second = pp->second;
|
|
sprintf(pp->a_lastcode,
|
|
"%02x %c %2d %3d %02d:%02d:%02d %4.0f %3d %6.3f %2d %2d %6.3f %6.1f %s",
|
|
up->errflg, syncchar, pp->year, pp->day,
|
|
pp->hour, pp->minute, pp->second,
|
|
up->maxsignal, up->gain, up->modndx,
|
|
up->envxing, up->tc, up->yxing, up->freq *
|
|
1e6 / SECOND, ulfptoa(&up->montime, 6));
|
|
pp->lencode = strlen(pp->a_lastcode);
|
|
if (up->timecnt == 0 || pp->sloppyclockflag &
|
|
CLK_FLAG4)
|
|
record_clock_stats(&peer->srcadr,
|
|
pp->a_lastcode);
|
|
#ifdef DEBUG
|
|
if (debug > 2)
|
|
printf("irig: %s\n", pp->a_lastcode);
|
|
#endif /* DEBUG */
|
|
}
|
|
}
|
|
up->lastbit = bit;
|
|
}
|
|
|
|
|
|
/*
|
|
* irig_poll - called by the transmit procedure
|
|
*
|
|
* This routine keeps track of status. If nothing is heard for two
|
|
* successive poll intervals, a timeout event is declared and any
|
|
* orphaned timecode updates are sent to foster care.
|
|
*/
|
|
static void
|
|
irig_poll(
|
|
int unit, /* instance number (not used) */
|
|
struct peer *peer /* peer structure pointer */
|
|
)
|
|
{
|
|
struct refclockproc *pp;
|
|
struct irigunit *up;
|
|
|
|
pp = peer->procptr;
|
|
up = (struct irigunit *)pp->unitptr;
|
|
|
|
/*
|
|
* Keep book for tattletales
|
|
*/
|
|
if (up->pollcnt == 0) {
|
|
refclock_report(peer, CEVNT_TIMEOUT);
|
|
up->timecnt = 0;
|
|
return;
|
|
}
|
|
up->pollcnt--;
|
|
pp->polls++;
|
|
|
|
}
|
|
|
|
|
|
/*
|
|
* irig_gain - adjust codec gain
|
|
*
|
|
* This routine is called once each second. If the signal envelope
|
|
* amplitude is too low, the codec gain is bumped up by four units; if
|
|
* too high, it is bumped down. The decoder is relatively insensitive to
|
|
* amplitude, so this crudity works just fine. The input port is set and
|
|
* the error flag is cleared, mostly to be ornery.
|
|
*/
|
|
static void
|
|
irig_gain(
|
|
struct peer *peer /* peer structure pointer */
|
|
)
|
|
{
|
|
struct refclockproc *pp;
|
|
struct irigunit *up;
|
|
|
|
pp = peer->procptr;
|
|
up = (struct irigunit *)pp->unitptr;
|
|
|
|
/*
|
|
* Apparently, the codec uses only the high order bits of the
|
|
* gain control field. Thus, it may take awhile for changes to
|
|
* wiggle the hardware bits.
|
|
*/
|
|
if (up->clipcnt == 0) {
|
|
up->gain += 4;
|
|
if (up->gain > 255)
|
|
up->gain = 255;
|
|
} else if (up->clipcnt > SECOND / 100) {
|
|
up->gain -= 4;
|
|
if (up->gain < 0)
|
|
up->gain = 0;
|
|
}
|
|
audio_gain(up->gain, up->port);
|
|
up->clipcnt = 0;
|
|
}
|
|
|
|
|
|
#else
|
|
int refclock_irig_bs;
|
|
#endif /* REFCLOCK */
|