direwolf/multi_modem.c

734 lines
21 KiB
C

//
// This file is part of Dire Wolf, an amateur radio packet TNC.
//
// Copyright (C) 2013, 2014, 2015, 2016 John Langner, WB2OSZ
//
// This program is free software: you can redistribute it and/or modify
// it under the terms of the GNU General Public License as published by
// the Free Software Foundation, either version 2 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 General Public License for more details.
//
// You should have received a copy of the GNU General Public License
// along with this program. If not, see <http://www.gnu.org/licenses/>.
//
/*------------------------------------------------------------------
*
* Name: multi_modem.c
*
* Purpose: Use multiple modems in parallel to increase chances
* of decoding less than ideal signals.
*
* Description: The initial motivation was for HF SSB where mistuning
* causes a shift in the audio frequencies. Here, we can
* have multiple modems tuned to staggered pairs of tones
* in hopes that one will be close enough.
*
* The overall structure opens the door to other approaches
* as well. For VHF FM, the tones should always have the
* right frequencies but we might want to tinker with other
* modem parameters instead of using a single compromise.
*
* Originally: The the interface application is in 3 places:
*
* (a) Main program (direwolf.c or atest.c) calls
* demod_init to set up modem properties and
* hdlc_rec_init for the HDLC decoders.
*
* (b) demod_process_sample is called for each audio sample
* from the input audio stream.
*
* (c) When a valid AX.25 frame is found, process_rec_frame,
* provided by the application, in direwolf.c or atest.c,
* is called. Normally this comes from hdlc_rec.c but
* there are a couple other special cases to consider.
* It can be called from hdlc_rec2.c if it took a long
* time to "fix" corrupted bits. aprs_tt.c constructs
* a fake packet when a touch tone message is received.
*
* New in version 0.9:
*
* Put an extra layer in between which potentially uses
* multiple modems & HDLC decoders per channel. The tricky
* part is picking the best one when there is more than one
* success and discarding the rest.
*
* New in version 1.1:
*
* Several enhancements provided by Fabrice FAURE:
*
* Additional types of attempts to fix a bad CRC.
* Optimized code to reduce execution time.
* Improved detection of duplicate packets from
* different fixup attempts.
* Set limit on number of packets in fix up later queue.
*
*------------------------------------------------------------------*/
//#define DEBUG 1
#define DIGIPEATER_C
#include "direwolf.h"
#include <stdlib.h>
#include <string.h>
#include <assert.h>
#include <stdio.h>
#include <sys/unistd.h>
#include "ax25_pad.h"
#include "textcolor.h"
#include "multi_modem.h"
#include "demod.h"
#include "hdlc_rec.h"
#include "hdlc_rec2.h"
#include "dlq.h"
// Properties of the radio channels.
static struct audio_s *save_audio_config_p;
// Candidates for further processing.
static struct {
packet_t packet_p;
alevel_t alevel;
retry_t retries;
int age;
unsigned int crc;
int score;
} candidate[MAX_CHANS][MAX_SUBCHANS][MAX_SLICERS];
//#define PROCESS_AFTER_BITS 2 // version 1.4. Was a little short for skew of PSK with different modem types, optional pre-filter
#define PROCESS_AFTER_BITS 3
static int process_age[MAX_CHANS];
static void pick_best_candidate (int chan);
/*------------------------------------------------------------------------------
*
* Name: multi_modem_init
*
* Purpose: Called at application start up to initialize appropriate
* modems and HDLC decoders.
*
* Input: Modem properties structure as filled in from the configuration file.
*
* Outputs:
*
* Description: Called once at application startup time.
*
*------------------------------------------------------------------------------*/
void multi_modem_init (struct audio_s *pa)
{
int chan;
/*
* Save audio configuration for later use.
*/
save_audio_config_p = pa;
memset (candidate, 0, sizeof(candidate));
demod_init (save_audio_config_p);
hdlc_rec_init (save_audio_config_p);
for (chan=0; chan<MAX_CHANS; chan++) {
if (save_audio_config_p->achan[chan].valid) {
if (save_audio_config_p->achan[chan].baud <= 0) {
text_color_set(DW_COLOR_ERROR);
dw_printf("Internal error, chan=%d, %s, %d\n", chan, __FILE__, __LINE__);
save_audio_config_p->achan[chan].baud = DEFAULT_BAUD;
}
int real_baud = save_audio_config_p->achan[chan].baud;
if (save_audio_config_p->achan[chan].modem_type == MODEM_QPSK) real_baud = save_audio_config_p->achan[chan].baud / 2;
if (save_audio_config_p->achan[chan].modem_type == MODEM_8PSK) real_baud = save_audio_config_p->achan[chan].baud / 3;
process_age[chan] = PROCESS_AFTER_BITS * save_audio_config_p->adev[ACHAN2ADEV(chan)].samples_per_sec / real_baud ;
//crc_queue_of_last_to_app[chan] = NULL;
}
}
}
#if 0
//Add a crc to the end of the queue and returns the numbers of CRC stored in the queue
int crc_queue_append (unsigned int crc, unsigned int chan) {
crc_t plast;
// crc_t plast1;
crc_t pnext;
crc_t new_crc;
unsigned int nb_crc = 1;
if (chan>=MAX_CHANS) {
return -1;
}
new_crc = (crc_t) malloc (10*sizeof(struct crc_s));
if (!new_crc)
return -1;
new_crc->crc = crc;
new_crc->nextp = NULL;
if (crc_queue_of_last_to_app[chan] == NULL) {
crc_queue_of_last_to_app[chan] = new_crc;
nb_crc = 1;
}
else {
nb_crc = 2;
plast = crc_queue_of_last_to_app[chan];
pnext = plast->nextp;
while (pnext != NULL) {
nb_crc++;
plast = pnext;
pnext = pnext->nextp;
}
plast->nextp = new_crc;
}
#if DEBUG
text_color_set(DW_COLOR_DEBUG);
dw_printf("Out crc_queue_append nb_crc = %d\n", nb_crc);
#endif
return nb_crc;
}
//Remove the crc from the top of the queue
unsigned int crc_queue_remove (unsigned int chan) {
unsigned int res;
// crc_t plast;
// crc_t pnext;
#if DEBUG
text_color_set(DW_COLOR_DEBUG);
dw_printf("In crc_queue_remove\n");
#endif
crc_t removed_crc;
if (chan>=MAX_CHANS) {
return 0;
}
removed_crc = crc_queue_of_last_to_app[chan];
if (removed_crc == NULL) {
return 0;
}
else {
crc_queue_of_last_to_app[chan] = removed_crc->nextp;
res = removed_crc->crc;
free(removed_crc);
}
return res;
}
unsigned char is_crc_in_queue(unsigned int chan, unsigned int crc) {
crc_t plast;
crc_t pnext;
if (crc_queue_of_last_to_app[chan] == NULL) {
return 0;
}
else {
plast = crc_queue_of_last_to_app[chan];
do {
pnext = plast->nextp;
if (plast->crc == crc) {
return 1;
}
plast = pnext;
} while (pnext != NULL);
}
return 0;
}
#endif /* if 0 */
/*------------------------------------------------------------------------------
*
* Name: multi_modem_process_sample
*
* Purpose: Feed the sample into the proper modem(s) for the channel.
*
* Inputs: chan - Radio channel number
*
* audio_sample
*
* Description: In earlier versions we always had a one-to-one mapping with
* demodulators and HDLC decoders.
* This was added so we could have multiple modems running in
* parallel with different mark/space tones to compensate for
* mistuning of HF SSB signals.
* It was also possible to run multiple filters, for the same
* tones, in parallel (e.g. ABC).
*
* Version 1.2: Let's try something new for an experiment.
* We will have a single mark/space demodulator but multiple
* slicers, using different levels, each with its own HDLC decoder.
* We now have a separate variable, num_demod, which could be 1
* while num_subchan is larger.
*
* Version 1.3: Go back to num_subchan with single meaning of number of demodulators.
* We now have separate independent variable, num_slicers, for the
* mark/space imbalance compensation.
* num_demod, while probably more descriptive, should not exist anymore.
*
*------------------------------------------------------------------------------*/
static float dc_average[MAX_CHANS];
int multi_modem_get_dc_average (int chan)
{
// Scale to +- 200 so it will like the deviation measurement.
return ( (int) ((float)(dc_average[chan]) * (200.0f / 32767.0f) ) );
}
__attribute__((hot))
void multi_modem_process_sample (int chan, int audio_sample)
{
int d;
int subchan;
static int i = 0; /* for interleaving among multiple demodulators. */
// Accumulate an average DC bias level.
// Shouldn't happen with a soundcard but could with mistuned SDR.
dc_average[chan] = dc_average[chan] * 0.999f + (float)audio_sample * 0.001f;
// Issue 128. Someone ran into this.
//assert (save_audio_config_p->achan[chan].num_subchan > 0 && save_audio_config_p->achan[chan].num_subchan <= MAX_SUBCHANS);
//assert (save_audio_config_p->achan[chan].num_slicers > 0 && save_audio_config_p->achan[chan].num_slicers <= MAX_SLICERS);
if (save_audio_config_p->achan[chan].num_subchan <= 0 || save_audio_config_p->achan[chan].num_subchan > MAX_SUBCHANS ||
save_audio_config_p->achan[chan].num_slicers <= 0 || save_audio_config_p->achan[chan].num_slicers > MAX_SLICERS) {
text_color_set(DW_COLOR_ERROR);
dw_printf ("ERROR! Something is seriously wrong in %s %s.\n", __FILE__, __func__);
dw_printf ("chan = %d, num_subchan = %d [max %d], num_slicers = %d [max %d]\n", chan,
save_audio_config_p->achan[chan].num_subchan, MAX_SUBCHANS,
save_audio_config_p->achan[chan].num_slicers, MAX_SLICERS);
dw_printf ("Please report this message and include a copy of your configuration file.\n");
exit (EXIT_FAILURE);
}
/* Formerly one loop. */
/* 1.2: We can feed one demodulator but end up with multiple outputs. */
if (save_audio_config_p->achan[chan].interleave > 1) {
// TODO: temp debug, remove this.
assert (save_audio_config_p->achan[chan].interleave == save_audio_config_p->achan[chan].num_subchan);
demod_process_sample(chan, i, audio_sample);
i++;
if (i >= save_audio_config_p->achan[chan].interleave) i = 0;
}
else {
/* Send same thing to all. */
for (d = 0; d < save_audio_config_p->achan[chan].num_subchan; d++) {
demod_process_sample(chan, d, audio_sample);
}
}
for (subchan = 0; subchan < save_audio_config_p->achan[chan].num_subchan; subchan++) {
int slice;
for (slice = 0; slice < save_audio_config_p->achan[chan].num_slicers; slice++) {
if (candidate[chan][subchan][slice].packet_p != NULL) {
candidate[chan][subchan][slice].age++;
if (candidate[chan][subchan][slice].age > process_age[chan]) {
pick_best_candidate (chan);
}
}
}
}
}
/*-------------------------------------------------------------------
*
* Name: multi_modem_process_rec_frame
*
* Purpose: This is called when we receive a frame with a valid
* FCS and acceptable size.
*
* Inputs: chan - Audio channel number, 0 or 1.
* subchan - Which modem found it.
* slice - Which slice found it.
* fbuf - Pointer to first byte in HDLC frame.
* flen - Number of bytes excluding the FCS.
* alevel - Audio level, range of 0 - 100.
* (Special case, use negative to skip
* display of audio level line.
* Use -2 to indicate DTMF message.)
* retries - Level of bit correction used.
*
*
* Description: Add to list of candidates. Best one will be picked later.
*
*--------------------------------------------------------------------*/
/*
It gets a little more complicated when we try fixing frames
with imperfect CRCs.
Changing of adjacent bits is quick and done immediately. These
all come in at nearly the same time. The processing of two
separated bits can take a long time and is handled in the
background by another thread. These could come in seconds later.
We need a way to remove duplicates. I think these are the
two cases we need to consider.
(1) Same result as earlier no error or adjacent bit errors.
____||||_
0.0: ptr=00000000
0.1: ptr=00000000
0.2: ptr=00000000
0.3: ptr=00000000
0.4: ptr=009E5540, retry=0, age=295, crc=9458, score=5024
0.5: ptr=0082F008, retry=0, age=294, crc=9458, score=5026 ***
0.6: ptr=009CE560, retry=0, age=293, crc=9458, score=5026
0.7: ptr=009CEE08, retry=0, age=293, crc=9458, score=5024
0.8: ptr=00000000
___._____
0.0: ptr=00000000
0.1: ptr=00000000
0.2: ptr=00000000
0.3: ptr=009E5540, retry=4, age=295, crc=9458, score=1000 ***
0.4: ptr=00000000
0.5: ptr=00000000
0.6: ptr=00000000
0.7: ptr=00000000
0.8: ptr=00000000
(2) Only results from adjusting two non-adjacent bits.
||||||||_
0.0: ptr=022EBA08, retry=0, age=289, crc=5acd, score=5042
0.1: ptr=022EA8B8, retry=0, age=290, crc=5acd, score=5048
0.2: ptr=022EB160, retry=0, age=290, crc=5acd, score=5052
0.3: ptr=05BD0048, retry=0, age=291, crc=5acd, score=5054 ***
0.4: ptr=04FE0048, retry=0, age=292, crc=5acd, score=5054
0.5: ptr=05E10048, retry=0, age=294, crc=5acd, score=5052
0.6: ptr=053D0048, retry=0, age=294, crc=5acd, score=5048
0.7: ptr=02375558, retry=0, age=295, crc=5acd, score=5042
0.8: ptr=00000000
_______._
0.0: ptr=00000000
0.1: ptr=00000000
0.2: ptr=00000000
0.3: ptr=00000000
0.4: ptr=00000000
0.5: ptr=00000000
0.6: ptr=00000000
0.7: ptr=02375558, retry=4, age=295, crc=5fc5, score=1000 ***
0.8: ptr=00000000
________.
0.0: ptr=00000000
0.1: ptr=00000000
0.2: ptr=00000000
0.3: ptr=00000000
0.4: ptr=00000000
0.5: ptr=00000000
0.6: ptr=00000000
0.7: ptr=00000000
0.8: ptr=02375558, retry=4, age=295, crc=5fc5, score=1000 ***
These can both be covered by keepin the last CRC and dropping
duplicates. In theory we could get another frame in between with
a slow computer so the complete solution would be to remember more
than one.
*/
void multi_modem_process_rec_frame (int chan, int subchan, int slice, unsigned char *fbuf, int flen, alevel_t alevel, retry_t retries)
{
packet_t pp;
assert (chan >= 0 && chan < MAX_CHANS);
assert (subchan >= 0 && subchan < MAX_SUBCHANS);
assert (slice >= 0 && slice < MAX_SUBCHANS);
pp = ax25_from_frame (fbuf, flen, alevel);
if (pp == NULL) {
text_color_set(DW_COLOR_ERROR);
dw_printf ("Unexpected internal problem, %s %d\n", __FILE__, __LINE__);
return; /* oops! why would it fail? */
}
/*
* If only one demodulator/slicer, push it thru and forget about all this foolishness.
*/
if (save_audio_config_p->achan[chan].num_subchan == 1 &&
save_audio_config_p->achan[chan].num_slicers == 1) {
int drop_it = 0;
if (save_audio_config_p->recv_error_rate != 0) {
float r = (float)(rand()) / (float)RAND_MAX; // Random, 0.0 to 1.0
//text_color_set(DW_COLOR_INFO);
//dw_printf ("TEMP DEBUG. recv error rate = %d\n", save_audio_config_p->recv_error_rate);
if (save_audio_config_p->recv_error_rate / 100.0 > r) {
drop_it = 1;
text_color_set(DW_COLOR_INFO);
dw_printf ("Intentionally dropping incoming frame. Recv Error rate = %d per cent.\n", save_audio_config_p->recv_error_rate);
}
}
if (drop_it ) {
ax25_delete (pp);
}
else {
dlq_rec_frame (chan, subchan, slice, pp, alevel, retries, "");
}
return;
}
/*
* Otherwise, save them up for a few bit times so we can pick the best.
*/
if (candidate[chan][subchan][slice].packet_p != NULL) {
/* Oops! Didn't expect it to be there. */
ax25_delete (candidate[chan][subchan][slice].packet_p);
candidate[chan][subchan][slice].packet_p = NULL;
}
candidate[chan][subchan][slice].packet_p = pp;
candidate[chan][subchan][slice].alevel = alevel;
candidate[chan][subchan][slice].retries = retries;
candidate[chan][subchan][slice].age = 0;
candidate[chan][subchan][slice].crc = ax25_m_m_crc(pp);
}
/*-------------------------------------------------------------------
*
* Name: pick_best_candidate
*
* Purpose: This is called when we have one or more candidates
* available for a certain amount of time.
*
* Description: Pick the best one and send it up to the application.
* Discard the others.
*
* Rules: We prefer one received perfectly but will settle for
* one where some bits had to be flipped to get a good CRC.
*
*--------------------------------------------------------------------*/
/* This is a suitable order for interleaved "G" demodulators. */
/* Opposite order would be suitable for multi-frequency although */
/* multiple slicers are of questionable value for HF SSB. */
#define subchan_from_n(x) ((x) % save_audio_config_p->achan[chan].num_subchan)
#define slice_from_n(x) ((x) / save_audio_config_p->achan[chan].num_subchan)
static void pick_best_candidate (int chan)
{
int best_n, best_score;
char spectrum[MAX_SUBCHANS*MAX_SLICERS+1];
int n, j, k;
int num_bars = save_audio_config_p->achan[chan].num_slicers * save_audio_config_p->achan[chan].num_subchan;
memset (spectrum, 0, sizeof(spectrum));
for (n = 0; n < num_bars; n++) {
j = subchan_from_n(n);
k = slice_from_n(n);
/* Build the spectrum display. */
if (candidate[chan][j][k].packet_p == NULL) {
spectrum[n] = '_';
}
else if (candidate[chan][j][k].retries == RETRY_NONE) {
spectrum[n] = '|';
}
else if (candidate[chan][j][k].retries == RETRY_INVERT_SINGLE) {
spectrum[n] = ':';
}
else {
spectrum[n] = '.';
}
/* Begining score depends on effort to get a valid frame CRC. */
if (candidate[chan][j][k].packet_p == NULL) {
candidate[chan][j][k].score = 0;
}
else {
/* Originally, this produced 0 for the PASSALL case. */
/* This didn't work so well when looking for the best score. */
/* Around 1.3 dev H, we add an extra 1 in here so the minimum */
/* score should now be 1 for anything received. */
candidate[chan][j][k].score = RETRY_MAX * 1000 - ((int)candidate[chan][j][k].retries * 1000) + 1;
}
}
/* Bump it up slightly if others nearby have the same CRC. */
for (n = 0; n < num_bars; n++) {
int m;
j = subchan_from_n(n);
k = slice_from_n(n);
if (candidate[chan][j][k].packet_p != NULL) {
for (m = 0; m < num_bars; m++) {
int mj = subchan_from_n(m);
int mk = slice_from_n(m);
if (m != n && candidate[chan][mj][mk].packet_p != NULL) {
if (candidate[chan][j][k].crc == candidate[chan][mj][mk].crc) {
candidate[chan][j][k].score += (num_bars+1) - abs(m-n);
}
}
}
}
}
best_n = 0;
best_score = 0;
for (n = 0; n < num_bars; n++) {
j = subchan_from_n(n);
k = slice_from_n(n);
if (candidate[chan][j][k].packet_p != NULL) {
if (candidate[chan][j][k].score > best_score) {
best_score = candidate[chan][j][k].score;
best_n = n;
}
}
}
#if DEBUG
text_color_set(DW_COLOR_DEBUG);
dw_printf ("\n%s\n", spectrum);
for (n = 0; n < num_bars; n++) {
j = subchan_from_n(n);
k = slice_from_n(n);
if (candidate[chan][j][k].packet_p == NULL) {
dw_printf ("%d.%d.%d: ptr=%p\n", chan, j, k,
candidate[chan][j][k].packet_p);
}
else {
dw_printf ("%d.%d.%d: ptr=%p, retry=%d, age=%3d, crc=%04x, score=%d %s\n", chan, j, k,
candidate[chan][j][k].packet_p,
(int)(candidate[chan][j][k].retries),
candidate[chan][j][k].age,
candidate[chan][j][k].crc,
candidate[chan][j][k].score,
(n == best_n) ? "***" : "");
}
}
#endif
if (best_score == 0) {
text_color_set(DW_COLOR_ERROR);
dw_printf ("Unexpected internal problem, %s %d. How can best score be zero?\n", __FILE__, __LINE__);
}
/*
* send the best one along.
*/
/* Delete those not chosen. */
for (n = 0; n < num_bars; n++) {
j = subchan_from_n(n);
k = slice_from_n(n);
if (n != best_n && candidate[chan][j][k].packet_p != NULL) {
ax25_delete (candidate[chan][j][k].packet_p);
candidate[chan][j][k].packet_p = NULL;
}
}
/* Pass along one. */
j = subchan_from_n(best_n);
k = slice_from_n(best_n);
int drop_it = 0;
if (save_audio_config_p->recv_error_rate != 0) {
float r = (float)(rand()) / (float)RAND_MAX; // Random, 0.0 to 1.0
//text_color_set(DW_COLOR_INFO);
//dw_printf ("TEMP DEBUG. recv error rate = %d\n", save_audio_config_p->recv_error_rate);
if (save_audio_config_p->recv_error_rate / 100.0 > r) {
drop_it = 1;
text_color_set(DW_COLOR_INFO);
dw_printf ("Intentionally dropping incoming frame. Recv Error rate = %d per cent.\n", save_audio_config_p->recv_error_rate);
}
}
if ( drop_it ) {
ax25_delete (candidate[chan][j][k].packet_p);
candidate[chan][j][k].packet_p = NULL;
}
else {
dlq_rec_frame (chan, j, k,
candidate[chan][j][k].packet_p,
candidate[chan][j][k].alevel,
(int)(candidate[chan][j][k].retries),
spectrum);
/* Someone else owns it now and will delete it later. */
candidate[chan][j][k].packet_p = NULL;
}
/* Clear in preparation for next time. */
memset (candidate[chan], 0, sizeof(candidate[chan]));
} /* end pick_best_candidate */
/* end multi_modem.c */