dump1090/dump1090.c
Malcolm Robb 39cb96f24b Fix several bugs in input/output fromat
Thanks to vk1et for these.

1) Correct for additional timestamp langth in raw output buffer when
using mlat mode

2) Don't output a timestamp when the message has been received from a
remote site (the internet). This is to avoid upsetting MLAT because
there is an indeterminate delay between reception at the remote site and
subsequent message arrival in the local dump1090 instance.

3) Allow @ character for raw data input with timestamp, and correctly
calculate the length.
2013-04-20 11:29:27 +01:00

2907 lines
111 KiB
C

/* Mode1090, a Mode S messages decoder for RTLSDR devices.
*
* Copyright (C) 2012 by Salvatore Sanfilippo <antirez@gmail.com>
*
* All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions are
* met:
*
* * Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
*
* * Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in the
* documentation and/or other materials provided with the distribution.
*
* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
* "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
* LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR
* A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT
* HOLDER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
* SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT
* LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
* DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
* THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
* (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
* OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
*/
#ifndef _WIN32
#include <stdio.h>
#include <string.h>
#include <stdlib.h>
#include <pthread.h>
#include <stdint.h>
#include <errno.h>
#include <unistd.h>
#include <math.h>
#include <sys/time.h>
#include <sys/timeb.h>
#include <signal.h>
#include <fcntl.h>
#include <ctype.h>
#include <sys/stat.h>
#include "rtl-sdr.h"
#include "anet.h"
#else
#include "dump1090.h" //Put everything Windows specific in here
#include "rtl-sdr.h"
#endif
// File Version number
// ====================
// Format is : MajorVer.MinorVer.DayMonth.Year"
// MajorVer changes only with significant changes
// MinorVer changes when additional features are added, but not for bug fixes (range 00-99)
// DayDate & Year changes for all changes, including for bug fixes. It represent the release date of the update
//
#define MODES_DUMP1090_VERSION "1.01.2004.13"
#define MODES_DEFAULT_RATE 2000000
#define MODES_DEFAULT_FREQ 1090000000
#define MODES_DEFAULT_WIDTH 1000
#define MODES_DEFAULT_HEIGHT 700
#define MODES_ASYNC_BUF_NUMBER 12
#define MODES_ASYNC_BUF_SIZE (16*16384) /* 256k */
#define MODES_ASYNC_BUF_SAMPLES (MODES_ASYNC_BUF_SIZE / 2) /* Each sample is 2 bytes */
#define MODES_AUTO_GAIN -100 /* Use automatic gain. */
#define MODES_MAX_GAIN 999999 /* Use max available gain. */
#define MODES_MSG_SQUELCH_LEVEL 0x02FF /* Average signal strength limit */
#define MODES_MSG_ENCODER_ERRS 3 /* Maximum number of encoding errors */
#define MODEA_MSG_BYTES 2
#define MODES_PREAMBLE_US 8 /* microseconds = bits */
#define MODES_PREAMBLE_SAMPLES (MODES_PREAMBLE_US * 2)
#define MODES_PREAMBLE_SIZE (MODES_PREAMBLE_SAMPLES * sizeof(uint16_t))
#define MODES_LONG_MSG_BYTES 14
#define MODES_SHORT_MSG_BYTES 7
#define MODES_LONG_MSG_BITS (MODES_LONG_MSG_BYTES * 8)
#define MODES_SHORT_MSG_BITS (MODES_SHORT_MSG_BYTES * 8)
#define MODES_LONG_MSG_SAMPLES (MODES_LONG_MSG_BITS * 2)
#define MODES_SHORT_MSG_SAMPLES (MODES_SHORT_MSG_BITS * 2)
#define MODES_LONG_MSG_SIZE (MODES_LONG_MSG_SAMPLES * sizeof(uint16_t))
#define MODES_SHORT_MSG_SIZE (MODES_SHORT_MSG_SAMPLES * sizeof(uint16_t))
#define MODES_RAWOUT_BUF_SIZE (1500)
#define MODES_RAWOUT_BUF_FLUSH (MODES_RAWOUT_BUF_SIZE - 200)
#define MODES_RAWOUT_BUF_RATE (1000) // 1000 * 64mS = 1 Min approx
#define MODES_ICAO_CACHE_LEN 1024 /* Power of two required. */
#define MODES_ICAO_CACHE_TTL 60 /* Time to live of cached addresses. */
#define MODES_UNIT_FEET 0
#define MODES_UNIT_METERS 1
#define MODES_SBS_LAT_LONG_FRESH (1<<0)
#define MODES_DEBUG_DEMOD (1<<0)
#define MODES_DEBUG_DEMODERR (1<<1)
#define MODES_DEBUG_BADCRC (1<<2)
#define MODES_DEBUG_GOODCRC (1<<3)
#define MODES_DEBUG_NOPREAMBLE (1<<4)
#define MODES_DEBUG_NET (1<<5)
#define MODES_DEBUG_JS (1<<6)
/* When debug is set to MODES_DEBUG_NOPREAMBLE, the first sample must be
* at least greater than a given level for us to dump the signal. */
#define MODES_DEBUG_NOPREAMBLE_LEVEL 25
#define MODES_INTERACTIVE_REFRESH_TIME 250 /* Milliseconds */
#define MODES_INTERACTIVE_ROWS 15 /* Rows on screen */
#define MODES_INTERACTIVE_TTL 60 /* TTL before being removed */
#define MODES_NET_MAX_FD 1024
#define MODES_NET_OUTPUT_SBS_PORT 30003
#define MODES_NET_OUTPUT_RAW_PORT 30002
#define MODES_NET_INPUT_RAW_PORT 30001
#define MODES_NET_HTTP_PORT 8080
#define MODES_CLIENT_BUF_SIZE 1024
#define MODES_NET_SNDBUF_SIZE (1024*64)
#define MODES_NOTUSED(V) ((void) V)
/* Structure used to describe a networking client. */
struct client {
int fd; /* File descriptor. */
int service; /* TCP port the client is connected to. */
char buf[MODES_CLIENT_BUF_SIZE+1]; /* Read buffer. */
int buflen; /* Amount of data on buffer. */
};
/* Structure used to describe an aircraft in iteractive mode. */
struct aircraft {
uint32_t addr; /* ICAO address */
char hexaddr[7]; /* Printable ICAO address */
char flight[9]; /* Flight number */
int altitude; /* Altitude */
int speed; /* Velocity computed from EW and NS components. */
int track; /* Angle of flight. */
time_t seen; /* Time at which the last packet was received. */
long messages; /* Number of Mode S messages received. */
/* Encoded latitude and longitude as extracted by odd and even
* CPR encoded messages. */
int odd_cprlat;
int odd_cprlon;
int even_cprlat;
int even_cprlon;
double lat, lon; /* Coordinated obtained from CPR encoded data. */
int sbsflags;
uint64_t odd_cprtime, even_cprtime;
int squawk;
struct aircraft *next; /* Next aircraft in our linked list. */
};
/* Program global state. */
struct {
/* Internal state */
pthread_t reader_thread;
pthread_mutex_t data_mutex; /* Mutex to synchronize buffer access. */
pthread_cond_t data_cond; /* Conditional variable associated. */
uint16_t *data; /* Raw IQ samples buffer */
uint16_t *magnitude; /* Magnitude vector */
struct timeb stSystemTimeRTL; /* System time when RTL passed us the Latest block */
uint64_t timestampBlk; /* Timestamp of the start of the current block */
struct timeb stSystemTimeBlk; /* System time when RTL passed us currently processing this block */
int fd; /* --ifile option file descriptor. */
int data_ready; /* Data ready to be processed. */
uint32_t *icao_cache; /* Recently seen ICAO addresses cache. */
uint16_t *maglut; /* I/Q -> Magnitude lookup table. */
int exit; /* Exit from the main loop when true. */
/* RTLSDR */
int dev_index;
int gain;
int enable_agc;
rtlsdr_dev_t *dev;
int freq;
int ppm_error;
/* Networking */
char aneterr[ANET_ERR_LEN];
struct client *clients[MODES_NET_MAX_FD]; /* Our clients. */
int maxfd; /* Greatest fd currently active. */
int sbsos; /* SBS output listening socket. */
int ros; /* Raw output listening socket. */
int ris; /* Raw input listening socket. */
int https; /* HTTP listening socket. */
char * rawOut; /* Buffer for building raw output data */
int rawOutUsed; /* How much if the buffer is currently used */
/* Configuration */
char *filename; /* Input form file, --ifile option. */
int fix_errors; /* Single bit error correction if true. */
int check_crc; /* Only display messages with good CRC. */
int raw; /* Raw output format. */
int beast; /* Beast binary format output. */
int debug; /* Debugging mode. */
int net; /* Enable networking. */
int net_only; /* Enable just networking. */
int net_output_sbs_port; /* SBS output TCP port. */
int net_output_raw_size; /* Minimum Size of the output raw data */
int net_output_raw_rate; /* Rate (in 64mS increments) of output raw data */
int net_output_raw_rate_count; /* Rate (in 64mS increments) of output raw data */
int net_output_raw_port; /* Raw output TCP port. */
int net_input_raw_port; /* Raw input TCP port. */
int net_http_port; /* HTTP port. */
int quiet; /* Suppress stdout */
int interactive; /* Interactive mode */
int interactive_rows; /* Interactive mode: max number of rows. */
int interactive_ttl; /* Interactive mode: TTL before deletion. */
int stats; /* Print stats at exit in --ifile mode. */
int onlyaddr; /* Print only ICAO addresses. */
int metric; /* Use metric units. */
int aggressive; /* Aggressive detection algorithm. */
int mlat; /* Use Beast ascii format for raw data output, i.e. @...; iso *...; */
int interactive_rtl1090; /* flight table in interactive mode is formatted like RTL1090 */
/* Interactive mode */
struct aircraft *aircrafts;
uint64_t interactive_last_update; /* Last screen update in milliseconds */
/* Statistics */
unsigned int stat_valid_preamble;
unsigned int stat_demodulated;
unsigned int stat_goodcrc;
unsigned int stat_badcrc;
unsigned int stat_fixed;
unsigned int stat_single_bit_fix;
unsigned int stat_two_bits_fix;
unsigned int stat_http_requests;
unsigned int stat_sbs_connections;
unsigned int stat_out_of_phase;
unsigned int stat_DF_Corrected;
} Modes;
/* The struct we use to store information about a decoded message. */
struct modesMessage {
/* Generic fields */
unsigned char msg[MODES_LONG_MSG_BYTES]; /* Binary message. */
int msgbits; /* Number of bits in message */
int msgtype; /* Downlink format # */
int crcok; /* True if CRC was valid */
uint32_t crc; /* Message CRC */
int errorbit; /* Bit corrected. -1 if no bit corrected. */
int aa1, aa2, aa3; /* ICAO Address bytes 1 2 and 3 */
int phase_corrected; /* True if phase correction was applied. */
uint64_t timestampMsg; /* Timestamp of the message. */
unsigned char signalLevel; /* Signal Amplitude */
/* DF 11 */
int ca; /* Responder capabilities. */
int iid;
/* DF 17 */
int metype; /* Extended squitter message type. */
int mesub; /* Extended squitter message subtype. */
int heading_is_valid;
int heading;
int aircraft_type;
int fflag; /* 1 = Odd, 0 = Even CPR message. */
int tflag; /* UTC synchronized? */
int raw_latitude; /* Non decoded latitude */
int raw_longitude; /* Non decoded longitude */
char flight[9]; /* 8 chars flight number. */
int ew_dir; /* 0 = East, 1 = West. */
int ew_velocity; /* E/W velocity. */
int ns_dir; /* 0 = North, 1 = South. */
int ns_velocity; /* N/S velocity. */
int vert_rate_source; /* Vertical rate source. */
int vert_rate_sign; /* Vertical rate sign. */
int vert_rate; /* Vertical rate. */
int velocity; /* Computed from EW and NS velocity. */
/* DF4, DF5, DF20, DF21 */
int fs; /* Flight status for DF4,5,20,21 */
int dr; /* Request extraction of downlink request. */
int um; /* Request extraction of downlink request. */
int identity; /* 13 bits identity (Squawk). */
/* Fields used by multiple message types. */
int altitude, unit;
};
void interactiveShowData(void);
struct aircraft* interactiveReceiveData(struct modesMessage *mm);
void modesSendAllClients(int service, void *msg, int len);
void modesSendRawOutput(struct modesMessage *mm);
void modesSendBeastOutput(struct modesMessage *mm);
void modesSendSBSOutput(struct modesMessage *mm, struct aircraft *a);
void useModesMessage(struct modesMessage *mm);
int fixSingleBitErrors(unsigned char *msg, int bits, struct modesMessage *mm);
int fixTwoBitsErrors(unsigned char *msg, int bits, struct modesMessage *mm);
int modesMessageLenByType(int type);
/* ============================= Utility functions ========================== */
static uint64_t mstime(void) {
struct timeval tv;
uint64_t mst;
gettimeofday(&tv, NULL);
mst = ((uint64_t)tv.tv_sec)*1000;
mst += tv.tv_usec/1000;
return mst;
}
/* =============================== Initialization =========================== */
void modesInitConfig(void) {
Modes.gain = MODES_MAX_GAIN;
Modes.dev_index = 0;
Modes.enable_agc = 0;
Modes.ppm_error = 0;
Modes.freq = MODES_DEFAULT_FREQ;
Modes.filename = NULL;
Modes.fix_errors = 1;
Modes.check_crc = 1;
Modes.raw = 0;
Modes.beast = 0;
Modes.net = 0;
Modes.net_only = 0;
Modes.net_output_sbs_port = MODES_NET_OUTPUT_SBS_PORT;
Modes.net_output_raw_size = 0;
Modes.net_output_raw_rate = 0;
Modes.net_output_raw_port = MODES_NET_OUTPUT_RAW_PORT;
Modes.net_input_raw_port = MODES_NET_INPUT_RAW_PORT;
Modes.net_http_port = MODES_NET_HTTP_PORT;
Modes.onlyaddr = 0;
Modes.debug = 0;
Modes.interactive = 0;
Modes.interactive_rows = MODES_INTERACTIVE_ROWS;
Modes.interactive_ttl = MODES_INTERACTIVE_TTL;
Modes.quiet = 0;
Modes.aggressive = 0;
Modes.mlat = 0;
Modes.interactive_rtl1090 = 0;
}
void modesInit(void) {
int i, q;
pthread_mutex_init(&Modes.data_mutex,NULL);
pthread_cond_init(&Modes.data_cond,NULL);
// Allocate the various buffers used by Modes
if ( ((Modes.icao_cache = (uint32_t *) malloc(sizeof(uint32_t) * MODES_ICAO_CACHE_LEN * 2) ) == NULL) ||
((Modes.data = (uint16_t *) malloc(MODES_ASYNC_BUF_SIZE) ) == NULL) ||
((Modes.magnitude = (uint16_t *) malloc(MODES_ASYNC_BUF_SIZE+MODES_PREAMBLE_SIZE+MODES_LONG_MSG_SIZE) ) == NULL) ||
((Modes.maglut = (uint16_t *) malloc(sizeof(uint16_t) * 256 * 256) ) == NULL) ||
((Modes.rawOut = (char *) malloc(MODES_RAWOUT_BUF_SIZE) ) == NULL) )
{
fprintf(stderr, "Out of memory allocating data buffer.\n");
exit(1);
}
// Limit the maximum requested raw output size to less than one Ethernet Block
Modes.net_output_raw_rate_count = 0;
if (Modes.net_output_raw_size > (MODES_RAWOUT_BUF_FLUSH))
{Modes.net_output_raw_size = MODES_RAWOUT_BUF_FLUSH;}
if (Modes.net_output_raw_rate > (MODES_RAWOUT_BUF_RATE))
{Modes.net_output_raw_rate = MODES_RAWOUT_BUF_RATE;}
// Clear the buffers that have just been allocated, just in-case
memset(Modes.icao_cache, 0, sizeof(uint32_t) * MODES_ICAO_CACHE_LEN * 2);
memset(Modes.data, 127, MODES_ASYNC_BUF_SIZE);
memset(Modes.magnitude, 0, MODES_ASYNC_BUF_SIZE+MODES_PREAMBLE_SIZE+MODES_LONG_MSG_SIZE);
// The ICAO address cache. We use two uint32_t for every
// entry because it's a addr / timestamp pair for every entry.
Modes.timestampBlk = 0;
Modes.data_ready = 0;
Modes.aircrafts = NULL;
Modes.interactive_last_update = 0;
Modes.rawOutUsed = 0;
ftime(&Modes.stSystemTimeRTL);
Modes.stSystemTimeBlk = Modes.stSystemTimeRTL;
/* Populate the I/Q -> Magnitude lookup table. It is used because
* sqrt or round may be expensive and may vary a lot depending on
* the libc used.
*
* We scale to 0-255 range multiplying by 1.4 in order to ensure that
* every different I/Q pair will result in a different magnitude value,
* not losing any resolution. */
/*
for (i = 0; i <= 255; i++) {
for (q = 0; q <= 255; q++) {
int mag_i = i - 127;
int mag_q = q - 127;
int mag = 0;
mag = (int) round(sqrt((mag_i*mag_i)+(mag_q*mag_q)) * 360);
Modes.maglut[(i*256)+q] = (uint16_t) min(mag,65535);
}
}
*/
// Each I and Q value varies from 0 to 255, which represents a range from -1 to +1. To get from the
// unsigned (0-255) range you therefore subtract 127 (or 128 or 127.5) from each I and Q, giving you
// a range from -127 to +128 (or -128 to +127, or -127.5 to +127.5)..
//
// To decode the AM signal, you need the magnitude of the waveform, which is given by sqrt((I^2)+(Q^2))
// The most this could be is if I&Q are both 128 (or 127 or 127.5), so you could end up with a magnitude
// of 181.019 (or 179.605, or 180.312)
//
// However, in reality the magnitude of the signal should never exceed the range -1 to +1, because the
// values are I = rCos(w) and Q = rSin(w). Therefore the integer computed magnitude should (can?) never
// exceed 128 (or 127, or 127.5 or whatever)
//
// If we scale up the results so that they range from 0 to 65535 (16 bits) then we need to multiply
// by 511.99, (or 516.02 or 514). antirez's original code multiplies by 360, presumably because he's
// assuming the maximim calculated amplitude is 181.019, and (181.019 * 360) = 65166.
//
// So lets see if we can improve things by subtracting 127.5, Well in integer arithmatic we can't
// subtract half, so, we'll double everything up and subtract one, and then compensate for the doubling
// in the multiplier at the end.
//
// If we do this we can never have I or Q equal to 0 - they can only be as small as +/- 1.
// This gives us a minimum magnitude of root 2 (0.707), so the dynamic range becomes (1.414-255). This
// also affects our scaling value, which is now 65535/(255 - 1.414), or 258.433254
//
// The sums then become mag = 258.433254 * (sqrt((I*2-255)^2 + (Q*2-255)^2) - 1.414)
// or mag = (258.433254 * sqrt((I*2-255)^2 + (Q*2-255)^2)) - 365.4798
//
// We also need to clip mag just incaes any rogue I/Q values somehow do have a magnitude greater than 255.
//
for (i = 0; i <= 255; i++) {
for (q = 0; q <= 255; q++) {
int mag, mag_i, mag_q;
mag_i = (i * 2) - 255;
mag_q = (q * 2) - 255;
mag = (int) round((sqrt((mag_i*mag_i)+(mag_q*mag_q)) * 258.433254) - 365.4798);
Modes.maglut[(i*256)+q] = (uint16_t) ((mag < 65535) ? mag : 65535);
}
}
/* Statistics */
Modes.stat_valid_preamble = 0;
Modes.stat_demodulated = 0;
Modes.stat_goodcrc = 0;
Modes.stat_badcrc = 0;
Modes.stat_fixed = 0;
Modes.stat_single_bit_fix = 0;
Modes.stat_two_bits_fix = 0;
Modes.stat_http_requests = 0;
Modes.stat_sbs_connections = 0;
Modes.stat_out_of_phase = 0;
Modes.stat_DF_Corrected = 0;
Modes.exit = 0;
}
/* =============================== RTLSDR handling ========================== */
void modesInitRTLSDR(void) {
int j;
int device_count;
char vendor[256], product[256], serial[256];
device_count = rtlsdr_get_device_count();
if (!device_count) {
fprintf(stderr, "No supported RTLSDR devices found.\n");
exit(1);
}
fprintf(stderr, "Found %d device(s):\n", device_count);
for (j = 0; j < device_count; j++) {
rtlsdr_get_device_usb_strings(j, vendor, product, serial);
fprintf(stderr, "%d: %s, %s, SN: %s %s\n", j, vendor, product, serial,
(j == Modes.dev_index) ? "(currently selected)" : "");
}
if (rtlsdr_open(&Modes.dev, Modes.dev_index) < 0) {
fprintf(stderr, "Error opening the RTLSDR device: %s\n",
strerror(errno));
exit(1);
}
/* Set gain, frequency, sample rate, and reset the device. */
rtlsdr_set_tuner_gain_mode(Modes.dev,
(Modes.gain == MODES_AUTO_GAIN) ? 0 : 1);
if (Modes.gain != MODES_AUTO_GAIN) {
if (Modes.gain == MODES_MAX_GAIN) {
/* Find the maximum gain available. */
int numgains;
int gains[100];
numgains = rtlsdr_get_tuner_gains(Modes.dev, gains);
Modes.gain = gains[numgains-1];
fprintf(stderr, "Max available gain is: %.2f\n", Modes.gain/10.0);
}
rtlsdr_set_tuner_gain(Modes.dev, Modes.gain);
fprintf(stderr, "Setting gain to: %.2f\n", Modes.gain/10.0);
} else {
fprintf(stderr, "Using automatic gain control.\n");
}
rtlsdr_set_freq_correction(Modes.dev, Modes.ppm_error);
if (Modes.enable_agc) rtlsdr_set_agc_mode(Modes.dev, 1);
rtlsdr_set_center_freq(Modes.dev, Modes.freq);
rtlsdr_set_sample_rate(Modes.dev, MODES_DEFAULT_RATE);
rtlsdr_reset_buffer(Modes.dev);
fprintf(stderr, "Gain reported by device: %.2f\n",
rtlsdr_get_tuner_gain(Modes.dev)/10.0);
}
/* We use a thread reading data in background, while the main thread
* handles decoding and visualization of data to the user.
*
* The reading thread calls the RTLSDR API to read data asynchronously, and
* uses a callback to populate the data buffer.
* A Mutex is used to avoid races with the decoding thread. */
void rtlsdrCallback(unsigned char *buf, uint32_t len, void *ctx) {
MODES_NOTUSED(ctx);
pthread_mutex_lock(&Modes.data_mutex);
ftime(&Modes.stSystemTimeRTL);
if (len > MODES_ASYNC_BUF_SIZE) len = MODES_ASYNC_BUF_SIZE;
/* Read the new data. */
memcpy(Modes.data, buf, len);
Modes.data_ready = 1;
/* Signal to the other thread that new data is ready */
pthread_cond_signal(&Modes.data_cond);
pthread_mutex_unlock(&Modes.data_mutex);
}
/* This is used when --ifile is specified in order to read data from file
* instead of using an RTLSDR device. */
void readDataFromFile(void) {
pthread_mutex_lock(&Modes.data_mutex);
while(1) {
ssize_t nread, toread;
unsigned char *p;
if (Modes.data_ready) {
pthread_cond_wait(&Modes.data_cond,&Modes.data_mutex);
continue;
}
if (Modes.interactive) {
/* When --ifile and --interactive are used together, slow down
* playing at the natural rate of the RTLSDR received. */
pthread_mutex_unlock(&Modes.data_mutex);
usleep(5000);
pthread_mutex_lock(&Modes.data_mutex);
}
toread = MODES_ASYNC_BUF_SIZE;
p = (unsigned char *) Modes.data;
while(toread) {
nread = read(Modes.fd, p, toread);
if (nread <= 0) {
Modes.exit = 1; /* Signal the other thread to exit. */
break;
}
p += nread;
toread -= nread;
}
if (toread) {
/* Not enough data on file to fill the buffer? Pad with
* no signal. */
memset(p,127,toread);
}
Modes.data_ready = 1;
/* Signal to the other thread that new data is ready */
pthread_cond_signal(&Modes.data_cond);
}
}
/* We read data using a thread, so the main thread only handles decoding
* without caring about data acquisition. */
void *readerThreadEntryPoint(void *arg) {
MODES_NOTUSED(arg);
if (Modes.filename == NULL) {
rtlsdr_read_async(Modes.dev, rtlsdrCallback, NULL,
MODES_ASYNC_BUF_NUMBER,
MODES_ASYNC_BUF_SIZE);
} else {
readDataFromFile();
}
return NULL;
}
/* ============================== Debugging ================================= */
/* Helper function for dumpMagnitudeVector().
* It prints a single bar used to display raw signals.
*
* Since every magnitude sample is between 0-255, the function uses
* up to 63 characters for every bar. Every character represents
* a length of 4, 3, 2, 1, specifically:
*
* "O" is 4
* "o" is 3
* "-" is 2
* "." is 1
*/
void dumpMagnitudeBar(int index, int magnitude) {
char *set = " .-o";
char buf[256];
int div = magnitude / 256 / 4;
int rem = magnitude / 256 % 4;
memset(buf,'O',div);
buf[div] = set[rem];
buf[div+1] = '\0';
if (index >= 0)
printf("[%.3d] |%-66s %d\n", index, buf, magnitude);
else
printf("[%.2d] |%-66s %d\n", index, buf, magnitude);
}
/* Display an ASCII-art alike graphical representation of the undecoded
* message as a magnitude signal.
*
* The message starts at the specified offset in the "m" buffer.
* The function will display enough data to cover a short 56 bit message.
*
* If possible a few samples before the start of the messsage are included
* for context. */
void dumpMagnitudeVector(uint16_t *m, uint32_t offset) {
uint32_t padding = 5; /* Show a few samples before the actual start. */
uint32_t start = (offset < padding) ? 0 : offset-padding;
uint32_t end = offset + (MODES_PREAMBLE_SAMPLES)+(MODES_SHORT_MSG_SAMPLES) - 1;
uint32_t j;
for (j = start; j <= end; j++) {
dumpMagnitudeBar(j-offset, m[j]);
}
}
/* Produce a raw representation of the message as a Javascript file
* loadable by debug.html. */
void dumpRawMessageJS(char *descr, unsigned char *msg,
uint16_t *m, uint32_t offset, int fixable)
{
int padding = 5; /* Show a few samples before the actual start. */
int start = offset - padding;
int end = offset + (MODES_PREAMBLE_SAMPLES)+(MODES_LONG_MSG_SAMPLES) - 1;
FILE *fp;
int j, fix1 = -1, fix2 = -1;
if (fixable != -1) {
fix1 = fixable & 0xff;
if (fixable > 255) fix2 = fixable >> 8;
}
if ((fp = fopen("frames.js","a")) == NULL) {
fprintf(stderr, "Error opening frames.js: %s\n", strerror(errno));
exit(1);
}
fprintf(fp,"frames.push({\"descr\": \"%s\", \"mag\": [", descr);
for (j = start; j <= end; j++) {
fprintf(fp,"%d", j < 0 ? 0 : m[j]);
if (j != end) fprintf(fp,",");
}
fprintf(fp,"], \"fix1\": %d, \"fix2\": %d, \"bits\": %d, \"hex\": \"",
fix1, fix2, modesMessageLenByType(msg[0]>>3));
for (j = 0; j < MODES_LONG_MSG_BYTES; j++)
fprintf(fp,"\\x%02x",msg[j]);
fprintf(fp,"\"});\n");
fclose(fp);
}
/* This is a wrapper for dumpMagnitudeVector() that also show the message
* in hex format with an additional description.
*
* descr is the additional message to show to describe the dump.
* msg points to the decoded message
* m is the original magnitude vector
* offset is the offset where the message starts
*
* The function also produces the Javascript file used by debug.html to
* display packets in a graphical format if the Javascript output was
* enabled.
*/
void dumpRawMessage(char *descr, unsigned char *msg,
uint16_t *m, uint32_t offset)
{
int j;
int msgtype = msg[0]>>3;
int fixable = -1;
if (msgtype == 11 || msgtype == 17) {
int msgbits = (msgtype == 11) ? MODES_SHORT_MSG_BITS :
MODES_LONG_MSG_BITS;
fixable = fixSingleBitErrors(msg, msgbits, NULL);
if (fixable == -1)
fixable = fixTwoBitsErrors(msg, msgbits, NULL);
}
if (Modes.debug & MODES_DEBUG_JS) {
dumpRawMessageJS(descr, msg, m, offset, fixable);
return;
}
printf("\n--- %s\n ", descr);
for (j = 0; j < MODES_LONG_MSG_BYTES; j++) {
printf("%02x",msg[j]);
if (j == MODES_SHORT_MSG_BYTES-1) printf(" ... ");
}
printf(" (DF %d, Fixable: %d)\n", msgtype, fixable);
dumpMagnitudeVector(m,offset);
printf("---\n\n");
}
/* ===================== Mode S detection and decoding ===================== */
/* Parity table for MODE S Messages.
* The table contains 112 elements, every element corresponds to a bit set
* in the message, starting from the first bit of actual data after the
* preamble.
*
* For messages of 112 bit, the whole table is used.
* For messages of 56 bits only the last 56 elements are used.
*
* The algorithm is as simple as xoring all the elements in this table
* for which the corresponding bit on the message is set to 1.
*
* The latest 24 elements in this table are set to 0 as the checksum at the
* end of the message should not affect the computation.
*
* Note: this function can be used with DF11 and DF17, other modes have
* the CRC xored with the sender address as they are reply to interrogations,
* but a casual listener can't split the address from the checksum.
*/
uint32_t modes_checksum_table[112] = {
0x3935ea, 0x1c9af5, 0xf1b77e, 0x78dbbf, 0xc397db, 0x9e31e9, 0xb0e2f0, 0x587178,
0x2c38bc, 0x161c5e, 0x0b0e2f, 0xfa7d13, 0x82c48d, 0xbe9842, 0x5f4c21, 0xd05c14,
0x682e0a, 0x341705, 0xe5f186, 0x72f8c3, 0xc68665, 0x9cb936, 0x4e5c9b, 0xd8d449,
0x939020, 0x49c810, 0x24e408, 0x127204, 0x093902, 0x049c81, 0xfdb444, 0x7eda22,
0x3f6d11, 0xe04c8c, 0x702646, 0x381323, 0xe3f395, 0x8e03ce, 0x4701e7, 0xdc7af7,
0x91c77f, 0xb719bb, 0xa476d9, 0xadc168, 0x56e0b4, 0x2b705a, 0x15b82d, 0xf52612,
0x7a9309, 0xc2b380, 0x6159c0, 0x30ace0, 0x185670, 0x0c2b38, 0x06159c, 0x030ace,
0x018567, 0xff38b7, 0x80665f, 0xbfc92b, 0xa01e91, 0xaff54c, 0x57faa6, 0x2bfd53,
0xea04ad, 0x8af852, 0x457c29, 0xdd4410, 0x6ea208, 0x375104, 0x1ba882, 0x0dd441,
0xf91024, 0x7c8812, 0x3e4409, 0xe0d800, 0x706c00, 0x383600, 0x1c1b00, 0x0e0d80,
0x0706c0, 0x038360, 0x01c1b0, 0x00e0d8, 0x00706c, 0x003836, 0x001c1b, 0xfff409,
0x000000, 0x000000, 0x000000, 0x000000, 0x000000, 0x000000, 0x000000, 0x000000,
0x000000, 0x000000, 0x000000, 0x000000, 0x000000, 0x000000, 0x000000, 0x000000,
0x000000, 0x000000, 0x000000, 0x000000, 0x000000, 0x000000, 0x000000, 0x000000
};
uint32_t modesChecksum(unsigned char *msg, int bits) {
uint32_t crc = 0;
int offset = (bits == 112) ? 0 : (112-56);
uint8_t theByte = *msg;
uint32_t * pCRCTable = &modes_checksum_table[offset];
int j;
for(j = 0; j < bits; j++) {
if ((j & 7) == 0)
{theByte = *msg++;}
// If bit is set, xor with corresponding table entry.
if (theByte & 0x80) {crc ^= *pCRCTable;}
pCRCTable++;
theByte = theByte << 1;
}
return crc; // 24 bit checksum.
}
/* Given the Downlink Format (DF) of the message, return the message length
* in bits. */
int modesMessageLenByType(int type) {
if (type == 16 || type == 17 ||
type == 19 || type == 20 ||
type == 21)
return MODES_LONG_MSG_BITS;
else
return MODES_SHORT_MSG_BITS;
}
/* Try to fix single bit errors using the checksum. On success modifies
* the original buffer with the fixed version, and returns the position
* of the error bit. Otherwise if fixing failed -1 is returned. */
int fixSingleBitErrors(unsigned char *msg, int bits, struct modesMessage *mm) {
int j;
unsigned char aux[MODES_LONG_MSG_BYTES];
memcpy(aux, msg,bits/8);
for (j = 0; j < bits; j++) {
int byte = j/8;
int bitmask = 1 << (7-(j%8));
uint32_t crc1, crc2;
aux[byte] ^= bitmask; /* Flip j-th bit. */
crc1 = ((uint32_t)aux[(bits/8)-3] << 16) |
((uint32_t)aux[(bits/8)-2] << 8) |
(uint32_t)aux[(bits/8)-1];
crc2 = modesChecksum(aux,bits);
if (crc1 == crc2) {
/* The error is fixed. Overwrite the original buffer with
* the corrected sequence, and returns the error bit
* position. */
memcpy(msg,aux,bits/8);
if (mm)
{
mm->crc = crc2;
mm->iid = 0;
mm->crcok = 1;
}
return j;
}
aux[byte] ^= bitmask; /* Flip j-th bit back again. */
}
return -1;
}
/* Similar to fixSingleBitErrors() but try every possible two bit combination.
* This is very slow and should be tried only against DF17 messages that
* don't pass the checksum, and only in Aggressive Mode. */
int fixTwoBitsErrors(unsigned char *msg, int bits, struct modesMessage *mm) {
int j, i;
unsigned char aux[MODES_LONG_MSG_BYTES];
memcpy(aux,msg, bits/8);
for (j = 0; j < bits; j++) {
int byte1 = j/8;
int bitmask1 = 1 << (7-(j%8));
aux[byte1] ^= bitmask1; /* Flip j-th bit. */
/* Don't check the same pairs multiple times, so i starts from j+1 */
for (i = j+1; i < bits; i++) {
int byte2 = i/8;
int bitmask2 = 1 << (7-(i%8));
uint32_t crc1, crc2;
aux[byte2] ^= bitmask2; /* Flip i-th bit. */
crc1 = ((uint32_t)aux[(bits/8)-3] << 16) |
((uint32_t)aux[(bits/8)-2] << 8) |
(uint32_t)aux[(bits/8)-1];
crc2 = modesChecksum(aux,bits);
if (crc1 == crc2) {
/* The error is fixed. Overwrite the original buffer with
* the corrected sequence, and returns the error bit
* position. */
memcpy(msg,aux,bits/8);
if (mm)
{
mm->crc = crc2;
mm->iid = 0;
mm->crcok = 1;
}
/* We return the two bits as a 16 bit integer by shifting
* 'i' on the left. This is possible since 'i' will always
* be non-zero because i starts from j+1. */
return j | (i<<8);
aux[byte2] ^= bitmask2; /* Flip i-th bit back. */
}
aux[byte1] ^= bitmask1; /* Flip j-th bit back. */
}
}
return -1;
}
/* Hash the ICAO address to index our cache of MODES_ICAO_CACHE_LEN
* elements, that is assumed to be a power of two. */
uint32_t ICAOCacheHashAddress(uint32_t a) {
/* The following three rounds wil make sure that every bit affects
* every output bit with ~ 50% of probability. */
a = ((a >> 16) ^ a) * 0x45d9f3b;
a = ((a >> 16) ^ a) * 0x45d9f3b;
a = ((a >> 16) ^ a);
return a & (MODES_ICAO_CACHE_LEN-1);
}
/* Add the specified entry to the cache of recently seen ICAO addresses.
* Note that we also add a timestamp so that we can make sure that the
* entry is only valid for MODES_ICAO_CACHE_TTL seconds. */
void addRecentlySeenICAOAddr(uint32_t addr) {
uint32_t h = ICAOCacheHashAddress(addr);
Modes.icao_cache[h*2] = addr;
Modes.icao_cache[h*2+1] = (uint32_t) time(NULL);
}
/* Returns 1 if the specified ICAO address was seen in a DF format with
* proper checksum (not xored with address) no more than * MODES_ICAO_CACHE_TTL
* seconds ago. Otherwise returns 0. */
int ICAOAddressWasRecentlySeen(uint32_t addr) {
uint32_t h = ICAOCacheHashAddress(addr);
uint32_t a = Modes.icao_cache[h*2];
uint32_t t = Modes.icao_cache[h*2+1];
return a && a == addr && time(NULL)-t <= MODES_ICAO_CACHE_TTL;
}
/* If the message type has the checksum xored with the ICAO address, try to
* brute force it using a list of recently seen ICAO addresses.
*
* Do this in a brute-force fashion by xoring the predicted CRC with
* the address XOR checksum field in the message. This will recover the
* address: if we found it in our cache, we can assume the message is ok.
*
* This function expects mm->msgtype and mm->msgbits to be correctly
* populated by the caller.
*
* On success the correct ICAO address is stored in the modesMessage
* structure in the aa3, aa2, and aa1 fiedls.
*
* If the function successfully recovers a message with a correct checksum
* it returns 1. Otherwise 0 is returned. */
int bruteForceAP(unsigned char *msg, struct modesMessage *mm) {
unsigned char aux[MODES_LONG_MSG_BYTES];
int msgtype = mm->msgtype;
int msgbits = mm->msgbits;
if (msgtype == 0 || /* Short air surveillance */
msgtype == 4 || /* Surveillance, altitude reply */
msgtype == 5 || /* Surveillance, identity reply */
msgtype == 16 || /* Long Air-Air survillance */
msgtype == 20 || /* Comm-A, altitude request */
msgtype == 21 || /* Comm-A, identity request */
msgtype == 24) /* Comm-C ELM */
{
uint32_t addr;
uint32_t crc;
int lastbyte = (msgbits/8)-1;
/* Work on a copy. */
memcpy(aux,msg,msgbits/8);
/* Compute the CRC of the message and XOR it with the AP field
* so that we recover the address, because:
*
* (ADDR xor CRC) xor CRC = ADDR. */
crc = modesChecksum(aux,msgbits);
aux[lastbyte] ^= crc & 0xff;
aux[lastbyte-1] ^= (crc >> 8) & 0xff;
aux[lastbyte-2] ^= (crc >> 16) & 0xff;
/* If the obtained address exists in our cache we consider
* the message valid. */
addr = aux[lastbyte] | (aux[lastbyte-1] << 8) | (aux[lastbyte-2] << 16);
if (ICAOAddressWasRecentlySeen(addr)) {
mm->aa1 = aux[lastbyte-2];
mm->aa2 = aux[lastbyte-1];
mm->aa3 = aux[lastbyte];
return 1;
}
}
return 0;
}
/* Decode the 13 bit AC altitude field (in DF 20 and others).
* Returns the altitude, and set 'unit' to either MODES_UNIT_METERS
* or MDOES_UNIT_FEETS. */
int decodeAC13Field(unsigned char *msg, int *unit) {
int m_bit = msg[3] & (1<<6);
int q_bit = msg[3] & (1<<4);
if (!m_bit) {
*unit = MODES_UNIT_FEET;
if (q_bit) {
/* N is the 11 bit integer resulting from the removal of bit
* Q and M */
int n = ((msg[2]&31)<<6) |
((msg[3]&0x80)>>2) |
((msg[3]&0x20)>>1) |
(msg[3]&15);
/* The final altitude is due to the resulting number multiplied
* by 25, minus 1000. */
return n*25-1000;
} else {
/* TODO: Implement altitude where Q=0 and M=0 */
}
} else {
*unit = MODES_UNIT_METERS;
/* TODO: Implement altitude when meter unit is selected. */
}
return 0;
}
/* Decode the 12 bit AC altitude field (in DF 17 and others).
* Returns the altitude or 0 if it can't be decoded. */
int decodeAC12Field(unsigned char *msg, int *unit) {
int q_bit = msg[5] & 1;
if (q_bit) {
/* N is the 11 bit integer resulting from the removal of bit
* Q */
int n = ((msg[5]>>1)<<4) | ((msg[6]&0xF0) >> 4);
*unit = MODES_UNIT_FEET;
/* The final altitude is due to the resulting number multiplied
* by 25, minus 1000. */
return n*25-1000;
} else {
return 0;
}
}
/* Capability table. */
char *ca_str[8] = {
/* 0 */ "Level 1 (Survillance Only)",
/* 1 */ "Level 2 (DF0,4,5,11)",
/* 2 */ "Level 3 (DF0,4,5,11,20,21)",
/* 3 */ "Level 4 (DF0,4,5,11,20,21,24)",
/* 4 */ "Level 2+3+4 (DF0,4,5,11,20,21,24,code7 - is on ground)",
/* 5 */ "Level 2+3+4 (DF0,4,5,11,20,21,24,code7 - is on airborne)",
/* 6 */ "Level 2+3+4 (DF0,4,5,11,20,21,24,code7)",
/* 7 */ "Level 7 ???"
};
/* Flight status table. */
char *fs_str[8] = {
/* 0 */ "Normal, Airborne",
/* 1 */ "Normal, On the ground",
/* 2 */ "ALERT, Airborne",
/* 3 */ "ALERT, On the ground",
/* 4 */ "ALERT & Special Position Identification. Airborne or Ground",
/* 5 */ "Special Position Identification. Airborne or Ground",
/* 6 */ "Value 6 is not assigned",
/* 7 */ "Value 7 is not assigned"
};
char *getMEDescription(int metype, int mesub) {
char *mename = "Unknown";
if (metype >= 1 && metype <= 4)
mename = "Aircraft Identification and Category";
else if (metype >= 5 && metype <= 8)
mename = "Surface Position";
else if (metype >= 9 && metype <= 18)
mename = "Airborne Position (Baro Altitude)";
else if (metype == 19 && mesub >=1 && mesub <= 4)
mename = "Airborne Velocity";
else if (metype >= 20 && metype <= 22)
mename = "Airborne Position (GNSS Height)";
else if (metype == 23 && mesub == 0)
mename = "Test Message";
else if (metype == 24 && mesub == 1)
mename = "Surface System Status";
else if (metype == 28 && mesub == 1)
mename = "Extended Squitter Aircraft Status (Emergency)";
else if (metype == 28 && mesub == 2)
mename = "Extended Squitter Aircraft Status (1090ES TCAS RA)";
else if (metype == 29 && (mesub == 0 || mesub == 1))
mename = "Target State and Status Message";
else if (metype == 31 && (mesub == 0 || mesub == 1))
mename = "Aircraft Operational Status Message";
return mename;
}
/* Decode a raw Mode S message demodulated as a stream of bytes by
* detectModeS(), and split it into fields populating a modesMessage
* structure. */
void decodeModesMessage(struct modesMessage *mm, unsigned char *msg) {
uint32_t crc2; /* Computed CRC, used to verify the message CRC. */
char *ais_charset = "?ABCDEFGHIJKLMNOPQRSTUVWXYZ????? ???????????????0123456789??????";
/* Work on our local copy */
memcpy(mm->msg, msg, MODES_LONG_MSG_BYTES);
msg = mm->msg;
/* Get the message type ASAP as other operations depend on this */
mm->msgtype = msg[0] >> 3; /* Downlink Format */
mm->msgbits = modesMessageLenByType(mm->msgtype);
/* CRC is always the last three bytes. */
mm->crc = ((uint32_t)msg[(mm->msgbits/8)-3] << 16) |
((uint32_t)msg[(mm->msgbits/8)-2] << 8) |
(uint32_t)msg[(mm->msgbits/8)-1];
crc2 = modesChecksum(msg, mm->msgbits);
mm->iid = (mm->crc ^ crc2);
/* Check CRC and fix single bit errors using the CRC when
* possible (DF 11 and 17). */
mm->errorbit = -1; /* No error */
if (mm->msgtype == 11)
{mm->crcok = (mm->iid < 80);}
else
{mm->crcok = (mm->iid == 0);}
if (!mm->crcok && Modes.fix_errors && (mm->msgtype == 17)){
mm->errorbit = fixSingleBitErrors(msg, mm->msgbits, mm);
if ((mm->errorbit == -1) && (Modes.aggressive)) {
mm->errorbit = fixTwoBitsErrors(msg, mm->msgbits, mm);
}
}
/* Note that most of the other computation happens *after* we fix
* the single bit errors, otherwise we would need to recompute the
* fields again. */
mm->ca = msg[0] & 7; /* Responder capabilities. */
/* ICAO address */
mm->aa1 = msg[1];
mm->aa2 = msg[2];
mm->aa3 = msg[3];
/* DF 17 type (assuming this is a DF17, otherwise not used) */
mm->metype = msg[4] >> 3; /* Extended squitter message type. */
mm->mesub = msg[4] & 7; /* Extended squitter message subtype. */
/* Fields for DF4,5,20,21 */
mm->fs = msg[0] & 7; /* Flight status for DF4,5,20,21 */
mm->dr = msg[1] >> 3 & 31; /* Request extraction of downlink request. */
mm->um = ((msg[1] & 7)<<3)| /* Request extraction of downlink request. */
msg[2]>>5;
/* In the squawk (identity) field bits are interleaved like that
* (message bit 20 to bit 32):
*
* C1-A1-C2-A2-C4-A4-ZERO-B1-D1-B2-D2-B4-D4
*
* So every group of three bits A, B, C, D represent an integer
* from 0 to 7.
*
* The actual meaning is just 4 octal numbers, but we convert it
* into a base ten number tha happens to represent the four
* octal numbers.
*
* For more info: http://en.wikipedia.org/wiki/Gillham_code */
{
int decIdentity = 0;
unsigned char rawIdentity;
rawIdentity = msg[2];
if (rawIdentity & 0x01) {decIdentity += 40;} // C4
if (rawIdentity & 0x02) {decIdentity += 2000;} // A2
if (rawIdentity & 0x04) {decIdentity += 20;} // C2
if (rawIdentity & 0x08) {decIdentity += 1000;} // A1
if (rawIdentity & 0x10) {decIdentity += 10;} // C1
rawIdentity = msg[3];
if (rawIdentity & 0x01) {decIdentity += 4;} // D4
if (rawIdentity & 0x02) {decIdentity += 400;} // B4
if (rawIdentity & 0x04) {decIdentity += 2;} // D2
if (rawIdentity & 0x08) {decIdentity += 200;} // B2
if (rawIdentity & 0x10) {decIdentity += 1;} // D1
if (rawIdentity & 0x20) {decIdentity += 100;} // B1
if (rawIdentity & 0x80) {decIdentity += 4000;} // A4
mm->identity = decIdentity;
}
/* DF 11 & 17: try to populate our ICAO addresses whitelist.
* DFs with an AP field (xored addr and crc), try to decode it. */
if (mm->msgtype != 11 && mm->msgtype != 17) {
/* Check if we can check the checksum for the Downlink Formats where
* the checksum is xored with the aircraft ICAO address. We try to
* brute force it using a list of recently seen aircraft addresses. */
if (bruteForceAP(msg,mm)) {
/* We recovered the message, mark the checksum as valid. */
mm->crcok = 1;
} else {
mm->crcok = 0;
}
} else {
/* If this is DF 11 or DF 17 and the checksum was ok,
* we can add this address to the list of recently seen
* addresses. */
if (mm->crcok && mm->errorbit == -1) {
uint32_t addr = (mm->aa1 << 16) | (mm->aa2 << 8) | mm->aa3;
addRecentlySeenICAOAddr(addr);
}
}
/* Decode 13 bit altitude for DF0, DF4, DF16, DF20 */
if (mm->msgtype == 0 || mm->msgtype == 4 ||
mm->msgtype == 16 || mm->msgtype == 20) {
mm->altitude = decodeAC13Field(msg, &mm->unit);
}
/* Decode extended squitter specific stuff. */
if (mm->msgtype == 17) {
/* Decode the extended squitter message. */
if (mm->metype >= 1 && mm->metype <= 4) {
/* Aircraft Identification and Category */
mm->aircraft_type = mm->metype-1;
mm->flight[0] = ais_charset[msg[5]>>2];
mm->flight[1] = ais_charset[((msg[5]&3)<<4)|(msg[6]>>4)];
mm->flight[2] = ais_charset[((msg[6]&15)<<2)|(msg[7]>>6)];
mm->flight[3] = ais_charset[msg[7]&63];
mm->flight[4] = ais_charset[msg[8]>>2];
mm->flight[5] = ais_charset[((msg[8]&3)<<4)|(msg[9]>>4)];
mm->flight[6] = ais_charset[((msg[9]&15)<<2)|(msg[10]>>6)];
mm->flight[7] = ais_charset[msg[10]&63];
mm->flight[8] = '\0';
} else if (mm->metype >= 9 && mm->metype <= 18) {
/* Airborne position Message */
mm->fflag = msg[6] & (1<<2);
mm->tflag = msg[6] & (1<<3);
mm->altitude = decodeAC12Field(msg,&mm->unit);
mm->raw_latitude = ((msg[6] & 3) << 15) |
(msg[7] << 7) |
(msg[8] >> 1);
mm->raw_longitude = ((msg[8]&1) << 16) |
(msg[9] << 8) |
msg[10];
} else if (mm->metype == 19 && mm->mesub >= 1 && mm->mesub <= 4) {
/* Airborne Velocity Message */
if (mm->mesub == 1 || mm->mesub == 2) {
mm->ew_dir = (msg[5]&4) >> 2;
mm->ew_velocity = ((msg[5]&3) << 8) | msg[6];
mm->ns_dir = (msg[7]&0x80) >> 7;
mm->ns_velocity = ((msg[7]&0x7f) << 3) | ((msg[8]&0xe0) >> 5);
mm->vert_rate_source = (msg[8]&0x10) >> 4;
mm->vert_rate_sign = (msg[8]&0x8) >> 3;
mm->vert_rate = ((msg[8]&7) << 6) | ((msg[9]&0xfc) >> 2);
/* Compute velocity and angle from the two speed
* components. */
mm->velocity = (int) sqrt(mm->ns_velocity*mm->ns_velocity+
mm->ew_velocity*mm->ew_velocity);
if (mm->velocity) {
int ewv = mm->ew_velocity;
int nsv = mm->ns_velocity;
double heading;
if (mm->ew_dir) ewv *= -1;
if (mm->ns_dir) nsv *= -1;
heading = atan2(ewv,nsv);
/* Convert to degrees. */
mm->heading = (int) (heading * 360 / (M_PI*2));
/* We don't want negative values but a 0-360 scale. */
if (mm->heading < 0) mm->heading += 360;
} else {
mm->heading = 0;
}
} else if (mm->mesub == 3 || mm->mesub == 4) {
mm->heading_is_valid = msg[5] & (1<<2);
mm->heading = (int) (360.0/128) * (((msg[5] & 3) << 5) |
(msg[6] >> 3));
}
}
}
mm->phase_corrected = 0; /* Set to 1 by the caller if needed. */
}
/* This function gets a decoded Mode S Message and prints it on the screen
* in a human readable format. */
void displayModesMessage(struct modesMessage *mm) {
int j;
char * pTimeStamp;
/* Handle only addresses mode first. */
if (Modes.onlyaddr) {
printf("%02x%02x%02x\n", mm->aa1, mm->aa2, mm->aa3);
return;
}
/* Show the raw message. */
if (Modes.mlat) {
printf("@"); //&&&
pTimeStamp = (char *) &mm->timestampMsg;
for (j=5; j>=0;j--) {
printf("%02X",pTimeStamp[j]);
}
} else
printf("*");
for (j = 0; j < mm->msgbits/8; j++) printf("%02x", mm->msg[j]);
printf(";\n");
if (Modes.raw) {
fflush(stdout); /* Provide data to the reader ASAP. */
return; /* Enough for --raw mode */
}
printf("CRC: %06x (%s)\n", (int)mm->crc, mm->crcok ? "ok" : "wrong");
if (mm->errorbit != -1)
printf("Single bit error fixed, bit %d\n", mm->errorbit);
if (mm->msgtype == 0) {
/* DF 0 */
printf("DF 0: Short Air-Air Surveillance.\n");
printf(" Altitude : %d %s\n", mm->altitude,
(mm->unit == MODES_UNIT_METERS) ? "meters" : "feet");
printf(" ICAO Address : %02x%02x%02x\n", mm->aa1, mm->aa2, mm->aa3);
} else if (mm->msgtype == 4 || mm->msgtype == 20) {
printf("DF %d: %s, Altitude Reply.\n", mm->msgtype,
(mm->msgtype == 4) ? "Surveillance" : "Comm-B");
printf(" Flight Status : %s\n", fs_str[mm->fs]);
printf(" DR : %d\n", mm->dr);
printf(" UM : %d\n", mm->um);
printf(" Altitude : %d %s\n", mm->altitude,
(mm->unit == MODES_UNIT_METERS) ? "meters" : "feet");
printf(" ICAO Address : %02x%02x%02x\n", mm->aa1, mm->aa2, mm->aa3);
if (mm->msgtype == 20) {
/* TODO: 56 bits DF20 MB additional field. */
}
} else if (mm->msgtype == 5 || mm->msgtype == 21) {
printf("DF %d: %s, Identity Reply.\n", mm->msgtype,
(mm->msgtype == 5) ? "Surveillance" : "Comm-B");
printf(" Flight Status : %s\n", fs_str[mm->fs]);
printf(" DR : %d\n", mm->dr);
printf(" UM : %d\n", mm->um);
printf(" Squawk : %d\n", mm->identity);
printf(" ICAO Address : %02x%02x%02x\n", mm->aa1, mm->aa2, mm->aa3);
if (mm->msgtype == 21) {
/* TODO: 56 bits DF21 MB additional field. */
}
} else if (mm->msgtype == 11) {
/* DF 11 */
printf("DF 11: All Call Reply.\n");
printf(" Capability : %s\n", ca_str[mm->ca]);
printf(" ICAO Address: %02x%02x%02x\n", mm->aa1, mm->aa2, mm->aa3);
if (mm->iid > 16)
{printf(" IID : SI-%02d\n", mm->iid-16);}
else
{printf(" IID : II-%02d\n", mm->iid);}
} else if (mm->msgtype == 17) {
/* DF 17 */
printf("DF 17: ADS-B message.\n");
printf(" Capability : %d (%s)\n", mm->ca, ca_str[mm->ca]);
printf(" ICAO Address : %02x%02x%02x\n", mm->aa1, mm->aa2, mm->aa3);
printf(" Extended Squitter Type: %d\n", mm->metype);
printf(" Extended Squitter Sub : %d\n", mm->mesub);
printf(" Extended Squitter Name: %s\n",
getMEDescription(mm->metype,mm->mesub));
/* Decode the extended squitter message. */
if (mm->metype >= 1 && mm->metype <= 4) {
/* Aircraft identification. */
char *ac_type_str[4] = {
"Aircraft Type D",
"Aircraft Type C",
"Aircraft Type B",
"Aircraft Type A"
};
printf(" Aircraft Type : %s\n", ac_type_str[mm->aircraft_type]);
printf(" Identification : %s\n", mm->flight);
} else if (mm->metype >= 9 && mm->metype <= 18) {
printf(" F flag : %s\n", mm->fflag ? "odd" : "even");
printf(" T flag : %s\n", mm->tflag ? "UTC" : "non-UTC");
printf(" Altitude : %d feet\n", mm->altitude);
printf(" Latitude : %d (not decoded)\n", mm->raw_latitude);
printf(" Longitude: %d (not decoded)\n", mm->raw_longitude);
} else if (mm->metype == 19 && mm->mesub >= 1 && mm->mesub <= 4) {
if (mm->mesub == 1 || mm->mesub == 2) {
/* Velocity */
printf(" EW direction : %d\n", mm->ew_dir);
printf(" EW velocity : %d\n", mm->ew_velocity);
printf(" NS direction : %d\n", mm->ns_dir);
printf(" NS velocity : %d\n", mm->ns_velocity);
printf(" Vertical rate src : %d\n", mm->vert_rate_source);
printf(" Vertical rate sign: %d\n", mm->vert_rate_sign);
printf(" Vertical rate : %d\n", mm->vert_rate);
} else if (mm->mesub == 3 || mm->mesub == 4) {
printf(" Heading status: %d", mm->heading_is_valid);
printf(" Heading: %d", mm->heading);
}
} else {
printf(" Unrecognized ME type: %d subtype: %d\n",
mm->metype, mm->mesub);
}
} else {
if (Modes.check_crc)
printf("DF %d with good CRC received "
"(decoding still not implemented).\n",
mm->msgtype);
}
}
/* Turn I/Q samples pointed by Modes.data into the magnitude vector
* pointed by Modes.magnitude. */
void computeMagnitudeVector(void) {
uint16_t *m = &Modes.magnitude[MODES_PREAMBLE_SAMPLES+MODES_LONG_MSG_SAMPLES];
uint16_t *p = Modes.data;
uint32_t j;
memcpy(Modes.magnitude,&Modes.magnitude[MODES_ASYNC_BUF_SAMPLES], MODES_PREAMBLE_SIZE+MODES_LONG_MSG_SIZE);
/* Compute the magnitudo vector. It's just SQRT(I^2 + Q^2), but
* we rescale to the 0-255 range to exploit the full resolution. */
for (j = 0; j < MODES_ASYNC_BUF_SAMPLES; j ++) {
*m++ = Modes.maglut[*p++];
}
}
/* Return -1 if the message is out of fase left-side
* Return 1 if the message is out of fase right-size
* Return 0 if the message is not particularly out of phase.
*
* Note: this function will access pPreamble[-1], so the caller should make sure to
* call it only if we are not at the start of the current buffer. */
int detectOutOfPhase(uint16_t *pPreamble) {
if (pPreamble[ 3] > pPreamble[2]/3) return 1;
if (pPreamble[10] > pPreamble[9]/3) return 1;
if (pPreamble[ 6] > pPreamble[7]/3) return -1;
if (pPreamble[-1] > pPreamble[1]/3) return -1;
return 0;
}
/* This function does not really correct the phase of the message, it just
* applies a transformation to the first sample representing a given bit:
*
* If the previous bit was one, we amplify it a bit.
* If the previous bit was zero, we decrease it a bit.
*
* This simple transformation makes the message a bit more likely to be
* correctly decoded for out of phase messages:
*
* When messages are out of phase there is more uncertainty in
* sequences of the same bit multiple times, since 11111 will be
* transmitted as continuously altering magnitude (high, low, high, low...)
*
* However because the message is out of phase some part of the high
* is mixed in the low part, so that it is hard to distinguish if it is
* a zero or a one.
*
* However when the message is out of phase passing from 0 to 1 or from
* 1 to 0 happens in a very recognizable way, for instance in the 0 -> 1
* transition, magnitude goes low, high, high, low, and one of of the
* two middle samples the high will be *very* high as part of the previous
* or next high signal will be mixed there.
*
* Applying our simple transformation we make more likely if the current
* bit is a zero, to detect another zero. Symmetrically if it is a one
* it will be more likely to detect a one because of the transformation.
* In this way similar levels will be interpreted more likely in the
* correct way. */
void applyPhaseCorrection(uint16_t *pPayload) {
int j;
for (j = 0; j < MODES_LONG_MSG_SAMPLES; j += 2, pPayload += 2) {
if (pPayload[0] > pPayload[1]) { /* One */
pPayload[2] = (pPayload[2] * 5) / 4;
} else { /* Zero */
pPayload[2] = (pPayload[2] * 4) / 5;
}
}
}
/* Detect a Mode S messages inside the magnitude buffer pointed by 'm' and of
* size 'mlen' bytes. Every detected Mode S message is convert it into a
* stream of bits and passed to the function to display it. */
void detectModeS(uint16_t *m, uint32_t mlen) {
unsigned char msg[MODES_LONG_MSG_BYTES], *pMsg;
uint16_t aux[MODES_LONG_MSG_SAMPLES];
uint32_t j;
int use_correction = 0;
/* The Mode S preamble is made of impulses of 0.5 microseconds at
* the following time offsets:
*
* 0 - 0.5 usec: first impulse.
* 1.0 - 1.5 usec: second impulse.
* 3.5 - 4 usec: third impulse.
* 4.5 - 5 usec: last impulse.
*
* Since we are sampling at 2 Mhz every sample in our magnitude vector
* is 0.5 usec, so the preamble will look like this, assuming there is
* an impulse at offset 0 in the array:
*
* 0 -----------------
* 1 -
* 2 ------------------
* 3 --
* 4 -
* 5 --
* 6 -
* 7 ------------------
* 8 --
* 9 -------------------
*/
for (j = 0; j < mlen; j++) {
int high, i, errors, errors56, errorsTy;
int good_message = 0;
uint16_t *pPreamble, *pPayload, *pPtr;
uint8_t theByte, theErrs;
int msglen, sigStrength;
pPreamble = &m[j];
pPayload = &m[j+MODES_PREAMBLE_SAMPLES];
if (!use_correction) // This is not a re-try with phase correction
{ // so try to find a new preamble
/* First check of relations between the first 10 samples
* representing a valid preamble. We don't even investigate further
* if this simple test is not passed. */
if (!(pPreamble[0] > pPreamble[1] &&
pPreamble[1] < pPreamble[2] &&
pPreamble[2] > pPreamble[3] &&
pPreamble[3] < pPreamble[0] &&
pPreamble[4] < pPreamble[0] &&
pPreamble[5] < pPreamble[0] &&
pPreamble[6] < pPreamble[0] &&
pPreamble[7] > pPreamble[8] &&
pPreamble[8] < pPreamble[9] &&
pPreamble[9] > pPreamble[6]))
{
if (Modes.debug & MODES_DEBUG_NOPREAMBLE &&
*pPreamble > MODES_DEBUG_NOPREAMBLE_LEVEL)
dumpRawMessage("Unexpected ratio among first 10 samples", msg, m, j);
continue;
}
/* The samples between the two spikes must be < than the average
* of the high spikes level. We don't test bits too near to
* the high levels as signals can be out of phase so part of the
* energy can be in the near samples. */
high = (pPreamble[0] + pPreamble[2] + pPreamble[7] + pPreamble[9]) / 6;
if (pPreamble[4] >= high ||
pPreamble[5] >= high)
{
if (Modes.debug & MODES_DEBUG_NOPREAMBLE &&
*pPreamble > MODES_DEBUG_NOPREAMBLE_LEVEL)
dumpRawMessage("Too high level in samples between 3 and 6", msg, m, j);
continue;
}
/* Similarly samples in the range 11-14 must be low, as it is the
* space between the preamble and real data. Again we don't test
* bits too near to high levels, see above. */
if (pPreamble[11] >= high ||
pPreamble[12] >= high ||
pPreamble[13] >= high ||
pPreamble[14] >= high)
{
if (Modes.debug & MODES_DEBUG_NOPREAMBLE &&
*pPreamble > MODES_DEBUG_NOPREAMBLE_LEVEL)
dumpRawMessage("Too high level in samples between 10 and 15", msg, m, j);
continue;
}
Modes.stat_valid_preamble++;
}
else {
/* If the previous attempt with this message failed, retry using
* magnitude correction. */
// Make a copy of the Payload, and phase correct the copy
memcpy(aux, pPayload, sizeof(aux));
applyPhaseCorrection(aux);
Modes.stat_out_of_phase++;
pPayload = aux;
/* TODO ... apply other kind of corrections. */
}
/* Decode all the next 112 bits, regardless of the actual message
* size. We'll check the actual message type later. */
pMsg = &msg[0];
pPtr = pPayload;
theByte = 0;
theErrs = 0; errorsTy = 0;
errors = 0; errors56 = 0;
// We should have 4 'bits' of 0/1 and 1/0 samples in the preamble,
// so include these in the signal strength
sigStrength = (pPreamble[0]-pPreamble[1])
+ (pPreamble[2]-pPreamble[3])
+ (pPreamble[7]-pPreamble[6])
+ (pPreamble[9]-pPreamble[8]);
msglen = MODES_LONG_MSG_BITS;
for (i = 0; i < msglen; i++) {
uint32_t a = *pPtr++;
uint32_t b = *pPtr++;
if (a > b)
{sigStrength += (a-b); theByte |= 1;}
else if (a < b)
{sigStrength += (b-a); /*theByte |= 0;*/}
else if (i >= MODES_SHORT_MSG_BITS) //(a == b), and we're in the long part of a frame
{errors++; /*theByte |= 0;*/}
else if (i >= 5) //(a == b), and we're in the short part of a frame
{errors56 = ++errors;/*theByte |= 0;*/}
else //(a == b), and we're in the message type part of a frame
{errorsTy = errors56 = ++errors; theErrs |= 1; /*theByte |= 0;*/}
if ((i & 7) == 7)
{*pMsg++ = theByte;}
else if ((i == 4) && (errors == 0))
{msglen = modesMessageLenByType(theByte);}
theByte = theByte << 1;
if (i < 8)
{theErrs = theErrs << 1;}
// If we've exceeded the permissible number of encoding errors, abandon ship now
if (errors > MODES_MSG_ENCODER_ERRS)
{
// If we're in the long frame when it went to pot, but it was still ok-ish when we
// were in the short part of the frame, then try for a mis-identified short frame
// we must believe that this should've been a long frame to get this far.
if (i >= MODES_SHORT_MSG_BITS)
{
// If we did see some errors in the first byte of the frame, then it's possible
// we guessed wrongly about the value of the bit. If we only saw one error, we may
// be able to correct it by guessing the other way.
if (errorsTy == 1)
{
// See if inverting the bit we guessed at would change the message type from a
// long to a short. If it would, invert the bit, cross your fingers and carry on.
theByte = pMsg[0] ^ theErrs;
if (MODES_SHORT_MSG_BITS == modesMessageLenByType(theByte))
{
pMsg[0] = theByte; // write the modified type back to the msg buffer
errors = errors56; // revert to the number of errors prior to bit 56
msglen = MODES_SHORT_MSG_BITS;
i--; // this latest sample was zero, so we can ignore it.
Modes.stat_DF_Corrected++;
}
}
}
break;
}
}
// Don't forget to add 4 for the preamble samples. This also removes any risk of dividing by zero.
sigStrength /= (msglen+4);
/* If we reached this point, and error is zero, we are very likely
* with a Mode S message in our hands, but it may still be broken
* and CRC may not be correct. This is handled by the next layer. */
if ( (sigStrength > MODES_MSG_SQUELCH_LEVEL) && (errors <= MODES_MSG_ENCODER_ERRS) )
{
struct modesMessage mm;
/* Decode the received message and update statistics */
mm.timestampMsg = Modes.timestampBlk + (j*6);
sigStrength = (sigStrength + 0x7F) >> 8;
mm.signalLevel = ((sigStrength < 255) ? sigStrength : 255);
decodeModesMessage(&mm,msg);
/* Update statistics. */
if (mm.crcok || use_correction) {
if (errors == 0) Modes.stat_demodulated++;
if (mm.errorbit == -1) {
if (mm.crcok)
Modes.stat_goodcrc++;
else
Modes.stat_badcrc++;
} else {
Modes.stat_badcrc++;
Modes.stat_fixed++;
if (mm.errorbit < MODES_LONG_MSG_BITS)
Modes.stat_single_bit_fix++;
else
Modes.stat_two_bits_fix++;
}
}
/* Output debug mode info if needed. */
if (use_correction) {
if (Modes.debug & MODES_DEBUG_DEMOD)
dumpRawMessage("Demodulated with 0 errors", msg, m, j);
else if (Modes.debug & MODES_DEBUG_BADCRC &&
mm.msgtype == 17 &&
(!mm.crcok || mm.errorbit != -1))
dumpRawMessage("Decoded with bad CRC", msg, m, j);
else if (Modes.debug & MODES_DEBUG_GOODCRC && mm.crcok &&
mm.errorbit == -1)
dumpRawMessage("Decoded with good CRC", msg, m, j);
}
/* Skip this message if we are sure it's fine. */
if (mm.crcok) {
j += (MODES_PREAMBLE_US+msglen)*2;
good_message = 1;
if (use_correction)
mm.phase_corrected = 1;
}
/* Pass data to the next layer */
useModesMessage(&mm);
} else {
if (Modes.debug & MODES_DEBUG_DEMODERR && use_correction) {
printf("The following message has %d demod errors\n", errors);
dumpRawMessage("Demodulated with errors", msg, m, j);
}
}
// Retry with phase correction if possible.
if (!good_message && !use_correction && j && detectOutOfPhase(pPreamble)) {
use_correction = 1; j--;
} else {
use_correction = 0;
}
}
//Send any remaining partial raw buffers now
if (Modes.rawOutUsed)
{
Modes.net_output_raw_rate_count++;
if (Modes.net_output_raw_rate_count > Modes.net_output_raw_rate)
{
modesSendAllClients(Modes.ros, Modes.rawOut, Modes.rawOutUsed);
Modes.rawOutUsed = 0;
Modes.net_output_raw_rate_count = 0;
}
}
}
/* When a new message is available, because it was decoded from the
* RTL device, file, or received in the TCP input port, or any other
* way we can receive a decoded message, we call this function in order
* to use the message.
*
* Basically this function passes a raw message to the upper layers for
* further processing and visualization. */
void useModesMessage(struct modesMessage *mm) {
if (!Modes.stats && (Modes.check_crc == 0 || mm->crcok)) {
/* Track aircrafts in interactive mode or if the HTTP
* interface is enabled. */
if (Modes.interactive || Modes.stat_http_requests > 0 || Modes.stat_sbs_connections > 0) {
struct aircraft *a = interactiveReceiveData(mm);
if (a && Modes.stat_sbs_connections > 0) modesSendSBSOutput(mm, a); /* Feed SBS output clients. */
}
/* In non-interactive way, display messages on standard output. */
if (!Modes.interactive && !Modes.quiet) {
displayModesMessage(mm);
if (!Modes.raw && !Modes.onlyaddr) printf("\n");
}
/* Send data to connected clients. */
if (Modes.net) { /* Feed raw output clients. */
if (Modes.beast)
modesSendBeastOutput(mm);
else
modesSendRawOutput(mm);
}
}
}
/* ========================= Interactive mode =============================== */
/* Return a new aircraft structure for the interactive mode linked list
* of aircrafts. */
struct aircraft *interactiveCreateAircraft(uint32_t addr) {
struct aircraft *a = (struct aircraft *) malloc(sizeof(*a));
a->addr = addr;
snprintf(a->hexaddr,sizeof(a->hexaddr),"%06x",(int)addr);
a->flight[0] = '\0';
a->altitude = 0;
a->speed = 0;
a->track = 0;
a->odd_cprlat = 0;
a->odd_cprlon = 0;
a->odd_cprtime = 0;
a->even_cprlat = 0;
a->even_cprlon = 0;
a->even_cprtime = 0;
a->lat = 0;
a->lon = 0;
a->sbsflags = 0;
a->seen = time(NULL);
a->messages = 0;
a->squawk = 0;
a->next = NULL;
return a;
}
/* Return the aircraft with the specified address, or NULL if no aircraft
* exists with this address. */
struct aircraft *interactiveFindAircraft(uint32_t addr) {
struct aircraft *a = Modes.aircrafts;
while(a) {
if (a->addr == addr) return a;
a = a->next;
}
return NULL;
}
/* Always positive MOD operation, used for CPR decoding. */
int cprModFunction(int a, int b) {
int res = a % b;
if (res < 0) res += b;
return res;
}
/* The NL function uses the precomputed table from 1090-WP-9-14 */
int cprNLFunction(double lat) {
if (lat < 0) lat = -lat; /* Table is simmetric about the equator. */
if (lat < 10.47047130) return 59;
if (lat < 14.82817437) return 58;
if (lat < 18.18626357) return 57;
if (lat < 21.02939493) return 56;
if (lat < 23.54504487) return 55;
if (lat < 25.82924707) return 54;
if (lat < 27.93898710) return 53;
if (lat < 29.91135686) return 52;
if (lat < 31.77209708) return 51;
if (lat < 33.53993436) return 50;
if (lat < 35.22899598) return 49;
if (lat < 36.85025108) return 48;
if (lat < 38.41241892) return 47;
if (lat < 39.92256684) return 46;
if (lat < 41.38651832) return 45;
if (lat < 42.80914012) return 44;
if (lat < 44.19454951) return 43;
if (lat < 45.54626723) return 42;
if (lat < 46.86733252) return 41;
if (lat < 48.16039128) return 40;
if (lat < 49.42776439) return 39;
if (lat < 50.67150166) return 38;
if (lat < 51.89342469) return 37;
if (lat < 53.09516153) return 36;
if (lat < 54.27817472) return 35;
if (lat < 55.44378444) return 34;
if (lat < 56.59318756) return 33;
if (lat < 57.72747354) return 32;
if (lat < 58.84763776) return 31;
if (lat < 59.95459277) return 30;
if (lat < 61.04917774) return 29;
if (lat < 62.13216659) return 28;
if (lat < 63.20427479) return 27;
if (lat < 64.26616523) return 26;
if (lat < 65.31845310) return 25;
if (lat < 66.36171008) return 24;
if (lat < 67.39646774) return 23;
if (lat < 68.42322022) return 22;
if (lat < 69.44242631) return 21;
if (lat < 70.45451075) return 20;
if (lat < 71.45986473) return 19;
if (lat < 72.45884545) return 18;
if (lat < 73.45177442) return 17;
if (lat < 74.43893416) return 16;
if (lat < 75.42056257) return 15;
if (lat < 76.39684391) return 14;
if (lat < 77.36789461) return 13;
if (lat < 78.33374083) return 12;
if (lat < 79.29428225) return 11;
if (lat < 80.24923213) return 10;
if (lat < 81.19801349) return 9;
if (lat < 82.13956981) return 8;
if (lat < 83.07199445) return 7;
if (lat < 83.99173563) return 6;
if (lat < 84.89166191) return 5;
if (lat < 85.75541621) return 4;
if (lat < 86.53536998) return 3;
if (lat < 87.00000000) return 2;
else return 1;
}
int cprNFunction(double lat, int isodd) {
int nl = cprNLFunction(lat) - isodd;
if (nl < 1) nl = 1;
return nl;
}
double cprDlonFunction(double lat, int isodd) {
return 360.0 / cprNFunction(lat, isodd);
}
/* This algorithm comes from:
* http://www.lll.lu/~edward/edward/adsb/DecodingADSBposition.html.
*
*
* A few remarks:
* 1) 131072 is 2^17 since CPR latitude and longitude are encoded in 17 bits.
* 2) We assume that we always received the odd packet as last packet for
* simplicity. This may provide a position that is less fresh of a few
* seconds.
*/
void decodeCPR(struct aircraft *a) {
const double AirDlat0 = 360.0 / 60;
const double AirDlat1 = 360.0 / 59;
double lat0 = a->even_cprlat;
double lat1 = a->odd_cprlat;
double lon0 = a->even_cprlon;
double lon1 = a->odd_cprlon;
/* Compute the Latitude Index "j" */
int j = (int) floor(((59*lat0 - 60*lat1) / 131072) + 0.5);
double rlat0 = AirDlat0 * (cprModFunction(j,60) + lat0 / 131072);
double rlat1 = AirDlat1 * (cprModFunction(j,59) + lat1 / 131072);
if (rlat0 >= 270) rlat0 -= 360;
if (rlat1 >= 270) rlat1 -= 360;
/* Check that both are in the same latitude zone, or abort. */
if (cprNLFunction(rlat0) != cprNLFunction(rlat1)) return;
/* Compute ni and the longitude index m */
if (a->even_cprtime > a->odd_cprtime) {
/* Use even packet. */
int ni = cprNFunction(rlat0,0);
int m = (int) floor((((lon0 * (cprNLFunction(rlat0)-1)) -
(lon1 * cprNLFunction(rlat0))) / 131072) + 0.5);
a->lon = cprDlonFunction(rlat0,0) * (cprModFunction(m,ni)+lon0/131072);
a->lat = rlat0;
} else {
/* Use odd packet. */
int ni = cprNFunction(rlat1,1);
int m = (int) floor((((lon0 * (cprNLFunction(rlat1)-1)) -
(lon1 * cprNLFunction(rlat1))) / 131072.0) + 0.5);
a->lon = cprDlonFunction(rlat1,1) * (cprModFunction(m,ni)+lon1/131072);
a->lat = rlat1;
}
if (a->lon > 180) a->lon -= 360;
a->sbsflags |= MODES_SBS_LAT_LONG_FRESH;
}
/* Receive new messages and populate the interactive mode with more info. */
struct aircraft *interactiveReceiveData(struct modesMessage *mm) {
uint32_t addr;
struct aircraft *a, *aux;
if (Modes.check_crc && mm->crcok == 0) return NULL;
addr = (mm->aa1 << 16) | (mm->aa2 << 8) | mm->aa3;
/* Loookup our aircraft or create a new one. */
a = interactiveFindAircraft(addr);
if (!a) {
a = interactiveCreateAircraft(addr);
a->next = Modes.aircrafts;
Modes.aircrafts = a;
} else {
/* If it is an already known aircraft, move it on head
* so we keep aircrafts ordered by received message time.
*
* However move it on head only if at least one second elapsed
* since the aircraft that is currently on head sent a message,
* othewise with multiple aircrafts at the same time we have an
* useless shuffle of positions on the screen. */
if (0 && Modes.aircrafts != a && (time(NULL) - a->seen) >= 1) {
aux = Modes.aircrafts;
while(aux->next != a) aux = aux->next;
/* Now we are a node before the aircraft to remove. */
aux->next = aux->next->next; /* removed. */
/* Add on head */
a->next = Modes.aircrafts;
Modes.aircrafts = a;
}
}
a->seen = time(NULL);
a->messages++;
if (mm->msgtype == 0 || mm->msgtype == 4 || mm->msgtype == 20) {
a->altitude = mm->altitude;
} else if(mm->msgtype == 5 || mm->msgtype == 21) {
a->squawk = mm->identity;
} else if (mm->msgtype == 17) {
if (mm->metype >= 1 && mm->metype <= 4) {
memcpy(a->flight, mm->flight, sizeof(a->flight));
} else if (mm->metype >= 9 && mm->metype <= 18) {
a->altitude = mm->altitude;
if (mm->fflag) {
a->odd_cprlat = mm->raw_latitude;
a->odd_cprlon = mm->raw_longitude;
a->odd_cprtime = mstime();
} else {
a->even_cprlat = mm->raw_latitude;
a->even_cprlon = mm->raw_longitude;
a->even_cprtime = mstime();
}
/* If the two data is less than 10 seconds apart, compute
* the position. */
if (abs((int)(a->even_cprtime - a->odd_cprtime)) <= 10000) {
decodeCPR(a);
}
} else if (mm->metype == 19) {
if (mm->mesub == 1 || mm->mesub == 2) {
a->speed = mm->velocity;
a->track = mm->heading;
}
}
}
return a;
}
/* Show the currently captured interactive data on screen. */
void interactiveShowData(void) {
struct aircraft *a = Modes.aircrafts;
time_t now = time(NULL);
int count = 0;
char progress;
char spinner[4] = "|/-\\";
progress = spinner[time(NULL)%4];
printf("\x1b[H\x1b[2J"); /* Clear the screen */
if (Modes.interactive_rtl1090 ==0) {
printf (
"Hex ModeA Flight Alt Speed Lat Lon Track Msgs Seen %c\n", progress);
} else {
printf (
"Hex Flight Alt V/S GS TT SSR G*456^ Msgs Seen %c\n", progress);
}
printf(
"--------------------------------------------------------------------------------\n");
while(a && count < Modes.interactive_rows) {
int altitude = a->altitude, speed = a->speed, msgs = a->messages;
char squawk[5] = " ";
char fl[5] = " ";
char tt[5] = " ";
char gs[5] = " ";
char spacer = '\0';
/* Convert units to metric if --metric was specified. */
if (Modes.metric) {
altitude = (int) (altitude / 3.2828);
speed = (int) (speed * 1.852);
}
if (altitude > 99999) {
altitude = 99999;
} else if (altitude < -9999) {
altitude = -9999;
}
if (a->squawk > 0 && a->squawk <= 7777) {
sprintf(squawk, "%04d", a->squawk);
}
if (a->messages > 99999) {
msgs = 99999;
}
if ((int)(now - a->seen) < 10) {
spacer = ' ';
}
if (Modes.interactive_rtl1090 != 0) {
if (altitude>0) {
altitude=altitude/100;
sprintf(fl,"F%03d",altitude);
}
if (speed > 0) {
sprintf (gs,"%3d",speed);
}
if (a->track > 0) {
sprintf (tt,"%03d",a->track);
}
printf("%-6s %-8s %-4s %-3s %-3s %4s %-6d %d %c \n",
a->hexaddr, a->flight, fl, gs, tt, squawk, msgs, (int)(now - a->seen), spacer);
} else {
printf("%-6s %-4s %-8s %-7d %-7d %-7.03f %-7.03f %-3d %-6d %d%c sec\n",
a->hexaddr, squawk, a->flight, altitude, speed,
a->lat, a->lon, a->track, msgs, (int)(now - a->seen), spacer);
}
a = a->next;
count++;
}
}
/* When in interactive mode If we don't receive new nessages within
* MODES_INTERACTIVE_TTL seconds we remove the aircraft from the list. */
void interactiveRemoveStaleAircrafts(void) {
struct aircraft *a = Modes.aircrafts;
struct aircraft *prev = NULL;
time_t now = time(NULL);
while(a) {
if ((now - a->seen) > Modes.interactive_ttl) {
struct aircraft *next = a->next;
/* Remove the element from the linked list, with care
* if we are removing the first element. */
free(a);
if (!prev)
Modes.aircrafts = next;
else
prev->next = next;
a = next;
} else {
prev = a;
a = a->next;
}
}
}
/* ============================== Snip mode ================================= */
/* Get raw IQ samples and filter everything is < than the specified level
* for more than 256 samples in order to reduce example file size. */
void snipMode(int level) {
int i, q;
uint64_t c = 0;
while ((i = getchar()) != EOF && (q = getchar()) != EOF) {
if (abs(i-127) < level && abs(q-127) < level) {
c++;
if (c > MODES_PREAMBLE_SIZE) continue;
} else {
c = 0;
}
putchar(i);
putchar(q);
}
}
/* ============================= Networking =================================
* Note: here we risregard any kind of good coding practice in favor of
* extreme simplicity, that is:
*
* 1) We only rely on the kernel buffers for our I/O without any kind of
* user space buffering.
* 2) We don't register any kind of event handler, from time to time a
* function gets called and we accept new connections. All the rest is
* handled via non-blocking I/O and manually pullign clients to see if
* they have something new to share with us when reading is needed.
*/
/* Networking "stack" initialization. */
void modesInitNet(void) {
struct {
char *descr;
int *socket;
int port;
} services[4] = {
{"Raw TCP output", &Modes.ros, Modes.net_output_raw_port},
{"Raw TCP input", &Modes.ris, Modes.net_input_raw_port},
{"HTTP server", &Modes.https, Modes.net_http_port},
{"Basestation TCP output", &Modes.sbsos, Modes.net_output_sbs_port}
};
int j;
memset(Modes.clients,0,sizeof(Modes.clients));
Modes.maxfd = -1;
for (j = 0; j < 4; j++) {
int s = anetTcpServer(Modes.aneterr, services[j].port, NULL);
if (s == -1) {
fprintf(stderr, "Error opening the listening port %d (%s): %s\n",
services[j].port, services[j].descr, strerror(errno));
exit(1);
}
anetNonBlock(Modes.aneterr, s);
*services[j].socket = s;
}
signal(SIGPIPE, SIG_IGN);
}
/* This function gets called from time to time when the decoding thread is
* awakened by new data arriving. This usually happens a few times every
* second. */
void modesAcceptClients(void) {
int fd, port;
unsigned int j;
struct client *c;
int services[4];
services[0] = Modes.ros;
services[1] = Modes.ris;
services[2] = Modes.https;
services[3] = Modes.sbsos;
for (j = 0; j < sizeof(services)/sizeof(int); j++) {
fd = anetTcpAccept(Modes.aneterr, services[j], NULL, &port);
if (fd == -1) continue;
if (fd >= MODES_NET_MAX_FD) {
close(fd);
return; /* Max number of clients reached. */
}
anetNonBlock(Modes.aneterr, fd);
c = (struct client *) malloc(sizeof(*c));
c->service = services[j];
c->fd = fd;
c->buflen = 0;
Modes.clients[fd] = c;
anetSetSendBuffer(Modes.aneterr,fd,MODES_NET_SNDBUF_SIZE);
if (Modes.maxfd < fd) Modes.maxfd = fd;
if (services[j] == Modes.sbsos) Modes.stat_sbs_connections++;
j--; /* Try again with the same listening port. */
if (Modes.debug & MODES_DEBUG_NET)
printf("Created new client %d\n", fd);
}
}
/* On error free the client, collect the structure, adjust maxfd if needed. */
void modesFreeClient(int fd) {
close(fd);
free(Modes.clients[fd]);
Modes.clients[fd] = NULL;
if (Modes.debug & MODES_DEBUG_NET)
printf("Closing client %d\n", fd);
/* If this was our maxfd, rescan the full clients array to check what's
* the new max. */
if (Modes.maxfd == fd) {
int j;
Modes.maxfd = -1;
for (j = 0; j < MODES_NET_MAX_FD; j++) {
if (Modes.clients[j]) Modes.maxfd = j;
}
}
}
/* Send the specified message to all clients listening for a given service. */
void modesSendAllClients(int service, void *msg, int len) {
int j;
struct client *c;
for (j = 0; j <= Modes.maxfd; j++) {
c = Modes.clients[j];
if (c && c->service == service) {
int nwritten = write(j, msg, len);
if (nwritten != len) {
modesFreeClient(j);
}
}
}
}
/* Write raw output in Beast Binary format with Timestamp to TCP clients */
void modesSendBeastOutput(struct modesMessage *mm) {
char *p = &Modes.rawOut[Modes.rawOutUsed];
int msgLen = mm->msgbits / 8;
char * pTimeStamp;
int j;
*p++ = 0x1a;
if (msgLen == MODES_SHORT_MSG_BYTES)
{*p++ = '2';}
else if (msgLen == MODES_LONG_MSG_BYTES)
{*p++ = '3';}
else if (msgLen == MODEA_MSG_BYTES)
{*p++ = '1';}
else
{return;}
pTimeStamp = (char *) &mm->timestampMsg;
for (j = 5; j >= 0; j--) {
*p++ = pTimeStamp[j];
}
*p++ = mm->signalLevel;
memcpy(p, mm->msg, msgLen);
Modes.rawOutUsed += (msgLen + 9);
if (Modes.rawOutUsed >= Modes.net_output_raw_size)
{
modesSendAllClients(Modes.ros, Modes.rawOut, Modes.rawOutUsed);
Modes.rawOutUsed = 0;
Modes.net_output_raw_rate_count = 0;
}
}
/* Write raw output to TCP clients. */
void modesSendRawOutput(struct modesMessage *mm) {
char *p = &Modes.rawOut[Modes.rawOutUsed];
int msgLen = mm->msgbits / 8;
int j;
char * pTimeStamp;
if (Modes.mlat) {
*p++ = '@';
pTimeStamp = (char *) &mm->timestampMsg;
for (j = 5; j >= 0; j--) {
sprintf(p, "%02X", pTimeStamp[j]);
p += 2;
}
Modes.rawOutUsed += 12; // additional 12 characters for timestamp
} else
*p++ = '*';
for (j = 0; j < msgLen; j++) {
sprintf(p, "%02X", mm->msg[j]);
p += 2;
}
*p++ = ';';
*p++ = '\n';
Modes.rawOutUsed += ((msgLen*2) + 3);
if (Modes.rawOutUsed >= Modes.net_output_raw_size)
{
modesSendAllClients(Modes.ros, Modes.rawOut, Modes.rawOutUsed);
Modes.rawOutUsed = 0;
Modes.net_output_raw_rate_count = 0;
}
}
/* Write SBS output to TCP clients. */
void modesSendSBSOutput(struct modesMessage *mm, struct aircraft *a) {
char msg[256], *p = msg;
char strCommon[128], *pCommon = strCommon;
int emergency = 0, ground = 0, alert = 0, spi = 0;
uint32_t offset;
struct timeb epocTime;
struct tm stTime;
if (mm->msgtype == 4 || mm->msgtype == 5 || mm->msgtype == 21) {
/* Node: identity is calculated/kept in base10 but is actually
* octal (07500 is represented as 7500) */
if (mm->identity == 7500 || mm->identity == 7600 ||
mm->identity == 7700) emergency = -1;
if (mm->fs == 1 || mm->fs == 3) ground = -1;
if (mm->fs == 2 || mm->fs == 3 || mm->fs == 4) alert = -1;
if (mm->fs == 4 || mm->fs == 5) spi = -1;
}
// ICAO address of the aircraft
pCommon += sprintf(pCommon, "111,11111,%02X%02X%02X,111111,", mm->aa1, mm->aa2, mm->aa3);
// Make sure the records' timestamp is valid before outputing it
if (mm->timestampMsg != (uint64_t)(-1)) {
// Do the records' time and date now
epocTime = Modes.stSystemTimeBlk; // This is the time of the start of the Block we're processing
offset = (int) (mm->timestampMsg - Modes.timestampBlk); // This is the time (in 12Mhz ticks) into the Block
offset = offset / 12000; // convert to milliseconds
epocTime.millitm += offset; // add on the offset time to the Block start time
if (epocTime.millitm > 999) // if we've caused an overflow into the next second...
{epocTime.millitm -= 1000; epocTime.time ++;} // ..correct the overflow
stTime = *localtime(&epocTime.time); // convert the time to year, month day, hours, min, sec
pCommon += sprintf(pCommon, "%04d/%02d/%02d,", (stTime.tm_year+1900),(stTime.tm_mon+1), stTime.tm_mday);
pCommon += sprintf(pCommon, "%02d:%02d:%02d.%03d,", stTime.tm_hour, stTime.tm_min, stTime.tm_sec, epocTime.millitm);
} else {
pCommon += sprintf(pCommon, ",,");
}
// Do the current time and date now
ftime(&epocTime); // get the current system time & date
stTime = *localtime(&epocTime.time); // convert the time to year, month day, hours, min, sec
pCommon += sprintf(pCommon, "%04d/%02d/%02d,", (stTime.tm_year+1900),(stTime.tm_mon+1), stTime.tm_mday);
pCommon += sprintf(pCommon, "%02d:%02d:%02d.%03d", stTime.tm_hour, stTime.tm_min, stTime.tm_sec, epocTime.millitm);
if (mm->msgtype == 0) {
p += sprintf(p, "MSG,5,%s,,%d,,,,,,,,,,", strCommon, mm->altitude);
} else if (mm->msgtype == 4) {
p += sprintf(p, "MSG,5,%s,,%d,,,,,,,%d,%d,%d,%d", strCommon, mm->altitude, alert, emergency, spi, ground);
} else if (mm->msgtype == 5) {
p += sprintf(p, "MSG,6,%s,,,,,,,,%d,%d,%d,%d,%d", strCommon, mm->identity, alert, emergency, spi, ground);
} else if (mm->msgtype == 11) {
p += sprintf(p, "MSG,8,%s,,,,,,,,,,,,", strCommon);
} else if (mm->msgtype == 17 && mm->metype == 4) {
p += sprintf(p, "MSG,1,%s,%s,,,,,,,,0,0,0,0", strCommon, mm->flight);
} else if (mm->msgtype == 17 && mm->metype >= 9 && mm->metype <= 18) {
if ( ((a->lat == 0) && (a->lon == 0)) || ((a->sbsflags & MODES_SBS_LAT_LONG_FRESH) == 0) ){
p += sprintf(p, "MSG,3,%s,,%d,,,,,,,0,0,0,0", strCommon, mm->altitude);
} else {
p += sprintf(p, "MSG,3,%s,,%d,,,%1.5f,%1.5f,,,0,0,0,0", strCommon, mm->altitude, a->lat, a->lon);
a->sbsflags &= ~MODES_SBS_LAT_LONG_FRESH;
}
} else if (mm->msgtype == 17 && mm->metype == 19 && mm->mesub == 1) {
int vr = (mm->vert_rate_sign==0?1:-1) * (mm->vert_rate-1) * 64;
p += sprintf(p, "MSG,4,%s,,,%d,%d,,,%i,,0,0,0,0", strCommon, mm->velocity, mm->heading, vr);
} else if (mm->msgtype == 21) {
p += sprintf(p, "MSG,6,%s,,,,,,,,%d,%d,%d,%d,%d", strCommon, mm->identity, alert, emergency, spi, ground);
} else {
return;
}
*p++ = '\r'; *p++ = '\n'; // <CRLF> or just <LF> ??
modesSendAllClients(Modes.sbsos, msg, p-msg);
}
/* Turn an hex digit into its 4 bit decimal value.
* Returns -1 if the digit is not in the 0-F range. */
int hexDigitVal(int c) {
c = tolower(c);
if (c >= '0' && c <= '9') return c-'0';
else if (c >= 'a' && c <= 'f') return c-'a'+10;
else return -1;
}
/* This function decodes a string representing a Mode S message in
* raw hex format like: *8D4B969699155600E87406F5B69F;
* The string is supposed to be at the start of the client buffer
* and null-terminated.
*
* The message is passed to the higher level layers, so it feeds
* the selected screen output, the network output and so forth.
*
* If the message looks invalid is silently discarded.
*
* The function always returns 0 (success) to the caller as there is
* no case where we want broken messages here to close the client
* connection. */
int decodeHexMessage(struct client *c) {
char *hex = c->buf;
int l = strlen(hex), j;
unsigned char msg[MODES_LONG_MSG_BYTES];
struct modesMessage mm;
/* Remove spaces on the left and on the right. */
while(l && isspace(hex[l-1])) {
hex[l-1] = '\0';
l--;
}
while(isspace(*hex)) {
hex++;
l--;
}
/* Turn the message into binary. */
if (l < 2 || (hex[0] != '*' && hex[0] != '@') || hex[l-1] != ';') return 0;
if (hex[0] == '@') {
hex += 13; l -= 15; // Skip @, and timestamp, and ;
} else {
hex++; l-=2; // Skip * and ;
}
if (l > MODES_LONG_MSG_BYTES*2) return 0; /* Too long message... broken. */
for (j = 0; j < l; j += 2) {
int high = hexDigitVal(hex[j]);
int low = hexDigitVal(hex[j+1]);
if (high == -1 || low == -1) return 0;
msg[j/2] = (high<<4) | low;
}
// Always mark the timestamp as invalid for packets received over the internet
// Mixing of data from two or more different receivers and publishing
// as coming from one would lead to corrupt mlat data
// Non timemarked internet data has indeterminate delay
mm.timestampMsg = -1;
mm.signalLevel = -1;
decodeModesMessage(&mm,msg);
useModesMessage(&mm);
return 0;
}
/* Return a description of planes in json. */
char *aircraftsToJson(int *len) {
struct aircraft *a = Modes.aircrafts;
int buflen = 1024; /* The initial buffer is incremented as needed. */
char *buf = (char *) malloc(buflen), *p = buf;
int l;
l = snprintf(p,buflen,"[\n");
p += l; buflen -= l;
while(a) {
int altitude = a->altitude, speed = a->speed;
/* Convert units to metric if --metric was specified. */
if (Modes.metric) {
altitude = (int) (altitude / 3.2828);
speed = (int) (speed * 1.852);
}
if (a->lat != 0 && a->lon != 0) {
l = snprintf(p,buflen,
"{\"hex\":\"%s\", \"flight\":\"%s\", \"lat\":%f, "
"\"lon\":%f, \"altitude\":%d, \"track\":%d, "
"\"speed\":%d},\n",
a->hexaddr, a->flight, a->lat, a->lon, a->altitude, a->track,
a->speed);
p += l; buflen -= l;
/* Resize if needed. */
if (buflen < 256) {
int used = p-buf;
buflen += 1024; /* Our increment. */
buf = (char *) realloc(buf,used+buflen);
p = buf+used;
}
}
a = a->next;
}
/* Remove the final comma if any, and closes the json array. */
if (*(p-2) == ',') {
*(p-2) = '\n';
p--;
buflen++;
}
l = snprintf(p,buflen,"]\n");
p += l; buflen -= l;
*len = p-buf;
return buf;
}
#define MODES_CONTENT_TYPE_HTML "text/html;charset=utf-8"
#define MODES_CONTENT_TYPE_JSON "application/json;charset=utf-8"
/* Get an HTTP request header and write the response to the client.
* Again here we assume that the socket buffer is enough without doing
* any kind of userspace buffering.
*
* Returns 1 on error to signal the caller the client connection should
* be closed. */
int handleHTTPRequest(struct client *c) {
char hdr[512];
int clen, hdrlen;
int httpver, keepalive;
char *p, *url, *content;
char *ctype;
if (Modes.debug & MODES_DEBUG_NET)
printf("\nHTTP request: %s\n", c->buf);
/* Minimally parse the request. */
httpver = (strstr(c->buf, "HTTP/1.1") != NULL) ? 11 : 10;
if (httpver == 10) {
/* HTTP 1.0 defaults to close, unless otherwise specified. */
keepalive = strstr(c->buf, "Connection: keep-alive") != NULL;
} else if (httpver == 11) {
/* HTTP 1.1 defaults to keep-alive, unless close is specified. */
keepalive = strstr(c->buf, "Connection: close") == NULL;
}
/* Identify he URL. */
p = strchr(c->buf,' ');
if (!p) return 1; /* There should be the method and a space... */
url = ++p; /* Now this should point to the requested URL. */
p = strchr(p, ' ');
if (!p) return 1; /* There should be a space before HTTP/... */
*p = '\0';
if (Modes.debug & MODES_DEBUG_NET) {
printf("\nHTTP keep alive: %d\n", keepalive);
printf("HTTP requested URL: %s\n\n", url);
}
/* Select the content to send, we have just two so far:
* "/" -> Our google map application.
* "/data.json" -> Our ajax request to update planes. */
if (strstr(url, "/data.json")) {
content = aircraftsToJson(&clen);
ctype = MODES_CONTENT_TYPE_JSON;
} else {
struct stat sbuf;
int fd = -1;
if (stat("gmap.html",&sbuf) != -1 &&
(fd = open("gmap.html",O_RDONLY)) != -1)
{
content = (char *) malloc(sbuf.st_size);
if (read(fd,content,sbuf.st_size) == -1) {
snprintf(content,sbuf.st_size,"Error reading from file: %s",
strerror(errno));
}
clen = sbuf.st_size;
} else {
char buf[128];
clen = snprintf(buf,sizeof(buf),"Error opening HTML file: %s",
strerror(errno));
content = strdup(buf);
}
if (fd != -1) close(fd);
ctype = MODES_CONTENT_TYPE_HTML;
}
/* Create the header and send the reply. */
hdrlen = snprintf(hdr, sizeof(hdr),
"HTTP/1.1 200 OK\r\n"
"Server: Dump1090\r\n"
"Content-Type: %s\r\n"
"Connection: %s\r\n"
"Content-Length: %d\r\n"
"\r\n",
ctype,
keepalive ? "keep-alive" : "close",
clen);
if (Modes.debug & MODES_DEBUG_NET)
printf("HTTP Reply header:\n%s", hdr);
/* Send header and content. */
if (write(c->fd, hdr, hdrlen) == -1 ||
write(c->fd, content, clen) == -1)
{
free(content);
return 1;
}
free(content);
Modes.stat_http_requests++;
return !keepalive;
}
/* This function polls the clients using read() in order to receive new
* messages from the net.
*
* The message is supposed to be separated by the next message by the
* separator 'sep', that is a null-terminated C string.
*
* Every full message received is decoded and passed to the higher layers
* calling the function 'handler'.
*
* The handelr returns 0 on success, or 1 to signal this function we
* should close the connection with the client in case of non-recoverable
* errors. */
void modesReadFromClient(struct client *c, char *sep,
int(*handler)(struct client *))
{
while(1) {
int left = MODES_CLIENT_BUF_SIZE - c->buflen;
int nread = read(c->fd, c->buf+c->buflen, left);
int fullmsg = 0;
int i;
char *p;
if (nread <= 0) {
if (nread == 0 || errno != EAGAIN) {
/* Error, or end of file. */
modesFreeClient(c->fd);
}
break; /* Serve next client. */
}
c->buflen += nread;
/* Always null-term so we are free to use strstr() */
c->buf[c->buflen] = '\0';
/* If there is a complete message there must be the separator 'sep'
* in the buffer, note that we full-scan the buffer at every read
* for simplicity. */
while ((p = strstr(c->buf, sep)) != NULL) {
i = p - c->buf; /* Turn it as an index inside the buffer. */
c->buf[i] = '\0'; /* Te handler expects null terminated strings. */
/* Call the function to process the message. It returns 1
* on error to signal we should close the client connection. */
if (handler(c)) {
modesFreeClient(c->fd);
return;
}
/* Move what's left at the start of the buffer. */
i += strlen(sep); /* The separator is part of the previous msg. */
memmove(c->buf,c->buf+i,c->buflen-i);
c->buflen -= i;
c->buf[c->buflen] = '\0';
/* Maybe there are more messages inside the buffer.
* Start looping from the start again. */
fullmsg = 1;
}
/* If our buffer is full discard it, this is some badly
* formatted shit. */
if (c->buflen == MODES_CLIENT_BUF_SIZE) {
c->buflen = 0;
/* If there is garbage, read more to discard it ASAP. */
continue;
}
/* If no message was decoded process the next client, otherwise
* read more data from the same client. */
if (!fullmsg) break;
}
}
/* Read data from clients. This function actually delegates a lower-level
* function that depends on the kind of service (raw, http, ...). */
void modesReadFromClients(void) {
int j;
struct client *c;
for (j = 0; j <= Modes.maxfd; j++) {
if ((c = Modes.clients[j]) == NULL) continue;
if (c->service == Modes.ris)
modesReadFromClient(c,"\n",decodeHexMessage);
else if (c->service == Modes.https)
modesReadFromClient(c,"\r\n\r\n",handleHTTPRequest);
}
}
/* ================================ Main ==================================== */
void showHelp(void) {
printf(
"-----------------------------------------------------------------------------\n"
"| dump1090 ModeS Receiver Ver : " MODES_DUMP1090_VERSION " |\n"
"-----------------------------------------------------------------------------\n"
"--device-index <index> Select RTL device (default: 0)\n"
"--gain <db> Set gain (default: max gain. Use -100 for auto-gain)\n"
"--enable-agc Enable the Automatic Gain Control (default: off)\n"
"--freq <hz> Set frequency (default: 1090 Mhz)\n"
"--ifile <filename> Read data from file (use '-' for stdin)\n"
"--interactive Interactive mode refreshing data on screen\n"
"--interactive-rows <num> Max number of rows in interactive mode (default: 15)\n"
"--interactive-ttl <sec> Remove from list if idle for <sec> (default: 60)\n"
"--interactive-rtl1090 Display flight table in RTL1090 format\n"
"--raw Show only messages hex values\n"
"--net Enable networking\n"
"--net-beast TCP raw output in Beast binary format\n"
"--net-only Enable just networking, no RTL device or file used\n"
"--net-ro-size <size> TCP raw output minimum size (default: 0)\n"
"--net-ro-rate <rate> TCP raw output memory flush rate (default: 0)\n"
"--net-ro-port <port> TCP raw output listen port (default: 30002)\n"
"--net-ri-port <port> TCP raw input listen port (default: 30001)\n"
"--net-http-port <port> HTTP server port (default: 8080)\n"
"--net-sbs-port <port> TCP BaseStation output listen port (default: 30003)\n"
"--no-fix Disable single-bits error correction using CRC\n"
"--no-crc-check Disable messages with broken CRC (discouraged)\n"
"--aggressive More CPU for more messages (two bits fixes, ...)\n"
"--mlat display raw messages in Beast ascii mode\n"
"--stats With --ifile print stats at exit. No other output\n"
"--onlyaddr Show only ICAO addresses (testing purposes)\n"
"--metric Use metric units (meters, km/h, ...)\n"
"--snip <level> Strip IQ file removing samples < level\n"
"--debug <flags> Debug mode (verbose), see README for details\n"
"--quiet Disable output to stdout. Use for daemon applications\n"
"--ppm <error> Set receiver error in parts per million (default 0)\n"
"--help Show this help\n"
"\n"
"Debug mode flags: d = Log frames decoded with errors\n"
" D = Log frames decoded with zero errors\n"
" c = Log frames with bad CRC\n"
" C = Log frames with good CRC\n"
" p = Log frames with bad preamble\n"
" n = Log network debugging info\n"
" j = Log frames to frames.js, loadable by debug.html\n"
);
}
/* This function is called a few times every second by main in order to
* perform tasks we need to do continuously, like accepting new clients
* from the net, refreshing the screen in interactive mode, and so forth. */
void backgroundTasks(void) {
if (Modes.net) {
modesAcceptClients();
modesReadFromClients();
interactiveRemoveStaleAircrafts();
}
/* Refresh screen when in interactive mode. */
if (Modes.interactive &&
(mstime() - Modes.interactive_last_update) >
MODES_INTERACTIVE_REFRESH_TIME)
{
interactiveRemoveStaleAircrafts();
interactiveShowData();
Modes.interactive_last_update = mstime();
}
}
int main(int argc, char **argv) {
int j;
/* Set sane defaults. */
modesInitConfig();
/* Parse the command line options */
for (j = 1; j < argc; j++) {
int more = j+1 < argc; /* There are more arguments. */
if (!strcmp(argv[j],"--device-index") && more) {
Modes.dev_index = atoi(argv[++j]);
} else if (!strcmp(argv[j],"--gain") && more) {
Modes.gain = (int) atof(argv[++j])*10; /* Gain is in tens of DBs */
} else if (!strcmp(argv[j],"--enable-agc")) {
Modes.enable_agc++;
} else if (!strcmp(argv[j],"--freq") && more) {
Modes.freq = (int) strtoll(argv[++j],NULL,10);
} else if (!strcmp(argv[j],"--ifile") && more) {
Modes.filename = strdup(argv[++j]);
} else if (!strcmp(argv[j],"--no-fix")) {
Modes.fix_errors = 0;
} else if (!strcmp(argv[j],"--no-crc-check")) {
Modes.check_crc = 0;
} else if (!strcmp(argv[j],"--raw")) {
Modes.raw = 1;
} else if (!strcmp(argv[j],"--net")) {
Modes.net = 1;
} else if (!strcmp(argv[j],"--net-beast")) {
Modes.beast = 1;
} else if (!strcmp(argv[j],"--net-only")) {
Modes.net = 1;
Modes.net_only = 1;
} else if (!strcmp(argv[j],"--net-ro-size") && more) {
Modes.net_output_raw_size = atoi(argv[++j]);
} else if (!strcmp(argv[j],"--net-ro-rate") && more) {
Modes.net_output_raw_rate = atoi(argv[++j]);
} else if (!strcmp(argv[j],"--net-ro-port") && more) {
Modes.net_output_raw_port = atoi(argv[++j]);
} else if (!strcmp(argv[j],"--net-ri-port") && more) {
Modes.net_input_raw_port = atoi(argv[++j]);
} else if (!strcmp(argv[j],"--net-http-port") && more) {
Modes.net_http_port = atoi(argv[++j]);
} else if (!strcmp(argv[j],"--net-sbs-port") && more) {
Modes.net_output_sbs_port = atoi(argv[++j]);
} else if (!strcmp(argv[j],"--onlyaddr")) {
Modes.onlyaddr = 1;
} else if (!strcmp(argv[j],"--metric")) {
Modes.metric = 1;
} else if (!strcmp(argv[j],"--aggressive")) {
Modes.aggressive++;
} else if (!strcmp(argv[j],"--interactive")) {
Modes.interactive = 1;
} else if (!strcmp(argv[j],"--interactive-rows")) {
Modes.interactive_rows = atoi(argv[++j]);
} else if (!strcmp(argv[j],"--interactive-ttl")) {
Modes.interactive_ttl = atoi(argv[++j]);
} else if (!strcmp(argv[j],"--debug") && more) {
char *f = argv[++j];
while(*f) {
switch(*f) {
case 'D': Modes.debug |= MODES_DEBUG_DEMOD; break;
case 'd': Modes.debug |= MODES_DEBUG_DEMODERR; break;
case 'C': Modes.debug |= MODES_DEBUG_GOODCRC; break;
case 'c': Modes.debug |= MODES_DEBUG_BADCRC; break;
case 'p': Modes.debug |= MODES_DEBUG_NOPREAMBLE; break;
case 'n': Modes.debug |= MODES_DEBUG_NET; break;
case 'j': Modes.debug |= MODES_DEBUG_JS; break;
default:
fprintf(stderr, "Unknown debugging flag: %c\n", *f);
exit(1);
break;
}
f++;
}
} else if (!strcmp(argv[j],"--stats")) {
Modes.stats = 1;
} else if (!strcmp(argv[j],"--snip") && more) {
snipMode(atoi(argv[++j]));
exit(0);
} else if (!strcmp(argv[j],"--help")) {
showHelp();
exit(0);
} else if (!strcmp(argv[j],"--ppm") && more) {
Modes.ppm_error = atoi(argv[++j]);
} else if (!strcmp(argv[j],"--quiet")) {
Modes.quiet = 1;
} else if (!strcmp(argv[j],"--mlat")) {
Modes.mlat = 1;
} else if (!strcmp(argv[j],"--interactive-rtl1090")) {
Modes.interactive = 1;
Modes.interactive_rtl1090 = 1;
} else {
fprintf(stderr,
"Unknown or not enough arguments for option '%s'.\n\n",
argv[j]);
showHelp();
exit(1);
}
}
/* Initialization */
modesInit();
if (Modes.net_only) {
fprintf(stderr,"Net-only mode, no RTL device or file open.\n");
} else if (Modes.filename == NULL) {
modesInitRTLSDR();
} else {
if (Modes.filename[0] == '-' && Modes.filename[1] == '\0') {
Modes.fd = STDIN_FILENO;
} else if ((Modes.fd = open(Modes.filename,O_RDONLY)) == -1) {
perror("Opening data file");
exit(1);
}
}
if (Modes.net) modesInitNet();
/* If the user specifies --net-only, just run in order to serve network
* clients without reading data from the RTL device. */
while (Modes.net_only) {
backgroundTasks();
usleep(100000);
}
/* Create the thread that will read the data from the device. */
pthread_create(&Modes.reader_thread, NULL, readerThreadEntryPoint, NULL);
pthread_mutex_lock(&Modes.data_mutex);
while(1) {
if (!Modes.data_ready) {
pthread_cond_wait(&Modes.data_cond,&Modes.data_mutex);
continue;
}
computeMagnitudeVector();
Modes.stSystemTimeBlk = Modes.stSystemTimeRTL;
/* Signal to the other thread that we processed the available data
* and we want more (useful for --ifile). */
Modes.data_ready = 0;
pthread_cond_signal(&Modes.data_cond);
/* Process data after releasing the lock, so that the capturing
* thread can read data while we perform computationally expensive
* stuff * at the same time. (This should only be useful with very
* slow processors). */
pthread_mutex_unlock(&Modes.data_mutex);
detectModeS(Modes.magnitude, MODES_ASYNC_BUF_SAMPLES);
Modes.timestampBlk += (MODES_ASYNC_BUF_SAMPLES*6);
backgroundTasks();
pthread_mutex_lock(&Modes.data_mutex);
if (Modes.exit) break;
}
/* If --ifile and --stats were given, print statistics. */
if (Modes.stats && Modes.filename) {
printf("%d valid preambles\n", Modes.stat_valid_preamble);
printf("%d DF-?? fields corrected for length\n", Modes.stat_DF_Corrected);
printf("%d demodulated again after phase correction\n", Modes.stat_out_of_phase);
printf("%d demodulated with zero errors\n", Modes.stat_demodulated);
printf("%d with good crc\n", Modes.stat_goodcrc);
printf("%d with bad crc\n", Modes.stat_badcrc);
printf("%d errors corrected\n", Modes.stat_fixed);
printf("%d single bit errors\n", Modes.stat_single_bit_fix);
printf("%d two bits errors\n", Modes.stat_two_bits_fix);
printf("%d total usable messages\n", Modes.stat_goodcrc + Modes.stat_fixed);
}
rtlsdr_close(Modes.dev);
return 0;
}