subsurface/libdivecomputer.c
Claudiu Olteanu 198cc41959 Implement the custom Bluetooth serial communication and use it
Create a custom Bluetooth serial communication using the QTBluetooth
API and use it when the Bluetooth download mode is enabled.
First try to connect on RFCOMM channel 1 because this is the default
RFCOMM channel of SPP service for most devices. If this doesn't work
try again on RFCOMM channel number 5 because it could be a Petrel2 device.

Add a fake open function for the custom implementation. This is
used when the selected device is HW OSTC 2N and the Bluetooth
mode is activated, then fake the open call of the serial device.

Signed-off-by: Claudiu Olteanu <olteanu.claudiu@ymail.com>
Signed-off-by: Dirk Hohndel <dirk@hohndel.org>
2015-07-06 08:37:42 -07:00

1022 lines
30 KiB
C

#include <stdio.h>
#include <unistd.h>
#include <inttypes.h>
#include <string.h>
#include "gettext.h"
#include "dive.h"
#include "device.h"
#include "divelist.h"
#include "display.h"
#include "libdivecomputer.h"
#include <libdivecomputer/uwatec.h>
#include <libdivecomputer/hw.h>
/* Christ. Libdivecomputer has the worst configuration system ever. */
#ifdef HW_FROG_H
#define NOT_FROG , 0
#define LIBDIVECOMPUTER_SUPPORTS_FROG
#else
#define NOT_FROG
#endif
char *dumpfile_name;
char *logfile_name;
const char *progress_bar_text = "";
double progress_bar_fraction = 0.0;
static int stoptime, stopdepth, ndl, po2, cns;
static bool in_deco, first_temp_is_air;
/*
* Directly taken from libdivecomputer's examples/common.c to improve
* the error messages resulting from libdc's return codes
*/
const char *errmsg (dc_status_t rc)
{
switch (rc) {
case DC_STATUS_SUCCESS:
return "Success";
case DC_STATUS_UNSUPPORTED:
return "Unsupported operation";
case DC_STATUS_INVALIDARGS:
return "Invalid arguments";
case DC_STATUS_NOMEMORY:
return "Out of memory";
case DC_STATUS_NODEVICE:
return "No device found";
case DC_STATUS_NOACCESS:
return "Access denied";
case DC_STATUS_IO:
return "Input/output error";
case DC_STATUS_TIMEOUT:
return "Timeout";
case DC_STATUS_PROTOCOL:
return "Protocol error";
case DC_STATUS_DATAFORMAT:
return "Data format error";
case DC_STATUS_CANCELLED:
return "Cancelled";
default:
return "Unknown error";
}
}
static dc_status_t create_parser(device_data_t *devdata, dc_parser_t **parser)
{
return dc_parser_new(parser, devdata->device);
}
static int parse_gasmixes(device_data_t *devdata, struct dive *dive, dc_parser_t *parser, int ngases)
{
static bool shown_warning = false;
int i, rc;
#if DC_VERSION_CHECK(0, 5, 0) && defined(DC_GASMIX_UNKNOWN)
int ntanks = 0;
rc = dc_parser_get_field(parser, DC_FIELD_TANK_COUNT, 0, &ntanks);
if (rc == DC_STATUS_SUCCESS) {
if (ntanks != ngases) {
shown_warning = true;
report_error("different number of gases (%d) and tanks (%d)", ngases, ntanks);
}
}
dc_tank_t tank = { 0 };
#endif
for (i = 0; i < ngases; i++) {
dc_gasmix_t gasmix = { 0 };
int o2, he;
bool no_volume = true;
rc = dc_parser_get_field(parser, DC_FIELD_GASMIX, i, &gasmix);
if (rc != DC_STATUS_SUCCESS && rc != DC_STATUS_UNSUPPORTED)
return rc;
if (i >= MAX_CYLINDERS)
continue;
o2 = rint(gasmix.oxygen * 1000);
he = rint(gasmix.helium * 1000);
/* Ignore bogus data - libdivecomputer does some crazy stuff */
if (o2 + he <= O2_IN_AIR || o2 > 1000) {
if (!shown_warning) {
shown_warning = true;
report_error("unlikely dive gas data from libdivecomputer: o2 = %d he = %d", o2, he);
}
o2 = 0;
}
if (he < 0 || o2 + he > 1000) {
if (!shown_warning) {
shown_warning = true;
report_error("unlikely dive gas data from libdivecomputer: o2 = %d he = %d", o2, he);
}
he = 0;
}
dive->cylinder[i].gasmix.o2.permille = o2;
dive->cylinder[i].gasmix.he.permille = he;
#if DC_VERSION_CHECK(0, 5, 0) && defined(DC_GASMIX_UNKNOWN)
tank.volume = 0.0;
if (i < ntanks) {
rc = dc_parser_get_field(parser, DC_FIELD_TANK, i, &tank);
if (rc == DC_STATUS_SUCCESS) {
if (tank.type == DC_TANKVOLUME_IMPERIAL) {
dive->cylinder[i].type.size.mliter = rint(tank.volume * 1000);
dive->cylinder[i].type.workingpressure.mbar = rint(tank.workpressure * 1000);
} else if (tank.type == DC_TANKVOLUME_METRIC) {
dive->cylinder[i].type.size.mliter = rint(tank.volume * 1000);
}
if (tank.gasmix != i) { // we don't handle this, yet
shown_warning = true;
report_error("gasmix %d for tank %d doesn't match", tank.gasmix, i);
}
}
}
if (!IS_FP_SAME(tank.volume, 0.0))
no_volume = false;
// this new API also gives us the beginning and end pressure for the tank
if (!IS_FP_SAME(tank.beginpressure, 0.0) && !IS_FP_SAME(tank.endpressure, 0.0)) {
dive->cylinder[i].start.mbar = tank.beginpressure * 1000;
dive->cylinder[i].end.mbar = tank.endpressure * 1000;
}
#endif
if (no_volume) {
/* for the first tank, if there is no tanksize available from the
* dive computer, fill in the default tank information (if set) */
fill_default_cylinder(&dive->cylinder[i]);
}
/* whatever happens, make sure there is a name for the cylinder */
if (same_string(dive->cylinder[i].type.description, ""))
dive->cylinder[i].type.description = strdup(translate("gettextFromC", "unknown"));
}
return DC_STATUS_SUCCESS;
}
static void handle_event(struct divecomputer *dc, struct sample *sample, dc_sample_value_t value)
{
int type, time;
/* we mark these for translation here, but we store the untranslated strings
* and only translate them when they are displayed on screen */
static const char *events[] = {
QT_TRANSLATE_NOOP("gettextFromC", "none"), QT_TRANSLATE_NOOP("gettextFromC", "deco stop"), QT_TRANSLATE_NOOP("gettextFromC", "rbt"), QT_TRANSLATE_NOOP("gettextFromC", "ascent"), QT_TRANSLATE_NOOP("gettextFromC", "ceiling"), QT_TRANSLATE_NOOP("gettextFromC", "workload"),
QT_TRANSLATE_NOOP("gettextFromC", "transmitter"), QT_TRANSLATE_NOOP("gettextFromC", "violation"), QT_TRANSLATE_NOOP("gettextFromC", "bookmark"), QT_TRANSLATE_NOOP("gettextFromC", "surface"), QT_TRANSLATE_NOOP("gettextFromC", "safety stop"),
QT_TRANSLATE_NOOP("gettextFromC", "gaschange"), QT_TRANSLATE_NOOP("gettextFromC", "safety stop (voluntary)"), QT_TRANSLATE_NOOP("gettextFromC", "safety stop (mandatory)"),
QT_TRANSLATE_NOOP("gettextFromC", "deepstop"), QT_TRANSLATE_NOOP("gettextFromC", "ceiling (safety stop)"), QT_TRANSLATE_NOOP3("gettextFromC", "below floor", "event showing dive is below deco floor and adding deco time"), QT_TRANSLATE_NOOP("gettextFromC", "divetime"),
QT_TRANSLATE_NOOP("gettextFromC", "maxdepth"), QT_TRANSLATE_NOOP("gettextFromC", "OLF"), QT_TRANSLATE_NOOP("gettextFromC", "pO₂"), QT_TRANSLATE_NOOP("gettextFromC", "airtime"), QT_TRANSLATE_NOOP("gettextFromC", "rgbm"), QT_TRANSLATE_NOOP("gettextFromC", "heading"),
QT_TRANSLATE_NOOP("gettextFromC", "tissue level warning"), QT_TRANSLATE_NOOP("gettextFromC", "gaschange"), QT_TRANSLATE_NOOP("gettextFromC", "non stop time")
};
const int nr_events = sizeof(events) / sizeof(const char *);
const char *name;
/*
* Just ignore surface events. They are pointless. What "surface"
* means depends on the dive computer (and possibly even settings
* in the dive computer). It does *not* necessarily mean "depth 0",
* so don't even turn it into that.
*/
if (value.event.type == SAMPLE_EVENT_SURFACE)
return;
/*
* Other evens might be more interesting, but for now we just print them out.
*/
type = value.event.type;
name = QT_TRANSLATE_NOOP("gettextFromC", "invalid event number");
if (type < nr_events)
name = events[type];
time = value.event.time;
if (sample)
time += sample->time.seconds;
add_event(dc, time, type, value.event.flags, value.event.value, name);
}
void
sample_cb(dc_sample_type_t type, dc_sample_value_t value, void *userdata)
{
unsigned int mm;
struct divecomputer *dc = userdata;
struct sample *sample;
/*
* We fill in the "previous" sample - except for DC_SAMPLE_TIME,
* which creates a new one.
*/
sample = dc->samples ? dc->sample + dc->samples - 1 : NULL;
/*
* Ok, sanity check.
* If first sample is not a DC_SAMPLE_TIME, Allocate a sample for us
*/
if (sample == NULL && type != DC_SAMPLE_TIME)
sample = prepare_sample(dc);
switch (type) {
case DC_SAMPLE_TIME:
mm = 0;
if (sample) {
sample->in_deco = in_deco;
sample->ndl.seconds = ndl;
sample->stoptime.seconds = stoptime;
sample->stopdepth.mm = stopdepth;
sample->setpoint.mbar = po2;
sample->cns = cns;
mm = sample->depth.mm;
}
sample = prepare_sample(dc);
sample->time.seconds = value.time;
sample->depth.mm = mm;
finish_sample(dc);
break;
case DC_SAMPLE_DEPTH:
sample->depth.mm = rint(value.depth * 1000);
break;
case DC_SAMPLE_PRESSURE:
sample->sensor = value.pressure.tank;
sample->cylinderpressure.mbar = rint(value.pressure.value * 1000);
break;
case DC_SAMPLE_TEMPERATURE:
sample->temperature.mkelvin = C_to_mkelvin(value.temperature);
break;
case DC_SAMPLE_EVENT:
handle_event(dc, sample, value);
break;
case DC_SAMPLE_RBT:
printf(" <rbt>%u</rbt>\n", value.rbt);
break;
case DC_SAMPLE_HEARTBEAT:
sample->heartbeat = value.heartbeat;
break;
case DC_SAMPLE_BEARING:
sample->bearing.degrees = value.bearing;
break;
#ifdef DEBUG_DC_VENDOR
case DC_SAMPLE_VENDOR:
printf(" <vendor time='%u:%02u' type=\"%u\" size=\"%u\">", FRACTION(sample->time.seconds, 60),
value.vendor.type, value.vendor.size);
for (int i = 0; i < value.vendor.size; ++i)
printf("%02X", ((unsigned char *)value.vendor.data)[i]);
printf("</vendor>\n");
break;
#endif
#if DC_VERSION_CHECK(0, 3, 0)
case DC_SAMPLE_SETPOINT:
/* for us a setpoint means constant pO2 from here */
sample->setpoint.mbar = po2 = rint(value.setpoint * 1000);
break;
case DC_SAMPLE_PPO2:
sample->setpoint.mbar = po2 = rint(value.ppo2 * 1000);
break;
case DC_SAMPLE_CNS:
sample->cns = cns = rint(value.cns * 100);
break;
case DC_SAMPLE_DECO:
if (value.deco.type == DC_DECO_NDL) {
sample->ndl.seconds = ndl = value.deco.time;
sample->stopdepth.mm = stopdepth = rint(value.deco.depth * 1000.0);
sample->in_deco = in_deco = false;
} else if (value.deco.type == DC_DECO_DECOSTOP ||
value.deco.type == DC_DECO_DEEPSTOP) {
sample->in_deco = in_deco = true;
sample->stopdepth.mm = stopdepth = rint(value.deco.depth * 1000.0);
sample->stoptime.seconds = stoptime = value.deco.time;
ndl = 0;
} else if (value.deco.type == DC_DECO_SAFETYSTOP) {
sample->in_deco = in_deco = false;
sample->stopdepth.mm = stopdepth = rint(value.deco.depth * 1000.0);
sample->stoptime.seconds = stoptime = value.deco.time;
}
#endif
default:
break;
}
}
static void dev_info(device_data_t *devdata, const char *fmt, ...)
{
static char buffer[1024];
va_list ap;
va_start(ap, fmt);
vsnprintf(buffer, sizeof(buffer), fmt, ap);
va_end(ap);
progress_bar_text = buffer;
}
static int import_dive_number = 0;
static int parse_samples(device_data_t *devdata, struct divecomputer *dc, dc_parser_t *parser)
{
// Parse the sample data.
return dc_parser_samples_foreach(parser, sample_cb, dc);
}
static int might_be_same_dc(struct divecomputer *a, struct divecomputer *b)
{
if (!a->model || !b->model)
return 1;
if (strcasecmp(a->model, b->model))
return 0;
if (!a->deviceid || !b->deviceid)
return 1;
return a->deviceid == b->deviceid;
}
static int match_one_dive(struct divecomputer *a, struct dive *dive)
{
struct divecomputer *b = &dive->dc;
/*
* Walk the existing dive computer data,
* see if we have a match (or an anti-match:
* the same dive computer but a different
* dive ID).
*/
do {
int match = match_one_dc(a, b);
if (match)
return match > 0;
b = b->next;
} while (b);
/* Ok, no exact dive computer match. Does the date match? */
b = &dive->dc;
do {
if (a->when == b->when && might_be_same_dc(a, b))
return 1;
b = b->next;
} while (b);
return 0;
}
/*
* Check if this dive already existed before the import
*/
static int find_dive(struct divecomputer *match)
{
int i;
for (i = 0; i < dive_table.preexisting; i++) {
struct dive *old = dive_table.dives[i];
if (match_one_dive(match, old))
return 1;
}
return 0;
}
static inline int year(int year)
{
if (year < 70)
return year + 2000;
if (year < 100)
return year + 1900;
return year;
}
/*
* Like g_strdup_printf(), but without the stupid g_malloc/g_free confusion.
* And we limit the string to some arbitrary size.
*/
static char *str_printf(const char *fmt, ...)
{
va_list args;
char buf[1024];
va_start(args, fmt);
vsnprintf(buf, sizeof(buf) - 1, fmt, args);
va_end(args);
buf[sizeof(buf) - 1] = 0;
return strdup(buf);
}
/*
* The dive ID for libdivecomputer dives is the first word of the
* SHA1 of the fingerprint, if it exists.
*
* NOTE! This is byte-order dependent, and I don't care.
*/
static uint32_t calculate_diveid(const unsigned char *fingerprint, unsigned int fsize)
{
uint32_t csum[5];
if (!fingerprint || !fsize)
return 0;
SHA1(fingerprint, fsize, (unsigned char *)csum);
return csum[0];
}
#ifdef DC_FIELD_STRING
static uint32_t calculate_string_hash(const char *str)
{
return calculate_diveid((const unsigned char *)str, strlen(str));
}
static void parse_string_field(struct dive *dive, dc_field_string_t *str)
{
// Our dive ID is the string hash of the "Dive ID" string
if (!strcmp(str->desc, "Dive ID")) {
if (!dive->dc.diveid)
dive->dc.diveid = calculate_string_hash(str->value);
return;
}
add_extra_data(&dive->dc, str->desc, str->value);
if (!strcmp(str->desc, "Serial")) {
dive->dc.serial = strdup(str->value);
/* should we just overwrite this whenever we have the "Serial" field?
* It's a much better deviceid then what we have so far... for now I'm leaving it as is */
if (!dive->dc.deviceid)
dive->dc.deviceid = calculate_string_hash(str->value);
return;
}
if (!strcmp(str->desc, "FW Version")) {
dive->dc.fw_version = strdup(str->value);
return;
}
}
#endif
static dc_status_t libdc_header_parser(dc_parser_t *parser, struct device_data_t *devdata, struct dive *dive)
{
dc_status_t rc = 0;
dc_datetime_t dt = { 0 };
struct tm tm;
rc = dc_parser_get_datetime(parser, &dt);
if (rc != DC_STATUS_SUCCESS && rc != DC_STATUS_UNSUPPORTED) {
dev_info(devdata, translate("gettextFromC", "Error parsing the datetime"));
return rc;
}
dive->dc.deviceid = devdata->deviceid;
if (rc == DC_STATUS_SUCCESS) {
tm.tm_year = dt.year;
tm.tm_mon = dt.month - 1;
tm.tm_mday = dt.day;
tm.tm_hour = dt.hour;
tm.tm_min = dt.minute;
tm.tm_sec = dt.second;
dive->when = dive->dc.when = utc_mktime(&tm);
}
// Parse the divetime.
const char *date_string = get_dive_date_c_string(dive->when);
dev_info(devdata, translate("gettextFromC", "Dive %d: %s"), import_dive_number, date_string);
free((void *)date_string);
unsigned int divetime = 0;
rc = dc_parser_get_field(parser, DC_FIELD_DIVETIME, 0, &divetime);
if (rc != DC_STATUS_SUCCESS && rc != DC_STATUS_UNSUPPORTED) {
dev_info(devdata, translate("gettextFromC", "Error parsing the divetime"));
return rc;
}
if (rc == DC_STATUS_SUCCESS)
dive->dc.duration.seconds = divetime;
// Parse the maxdepth.
double maxdepth = 0.0;
rc = dc_parser_get_field(parser, DC_FIELD_MAXDEPTH, 0, &maxdepth);
if (rc != DC_STATUS_SUCCESS && rc != DC_STATUS_UNSUPPORTED) {
dev_info(devdata, translate("gettextFromC", "Error parsing the maxdepth"));
return rc;
}
if (rc == DC_STATUS_SUCCESS)
dive->dc.maxdepth.mm = rint(maxdepth * 1000);
#if DC_VERSION_CHECK(0, 5, 0) && defined(DC_GASMIX_UNKNOWN)
// if this is defined then we have a fairly late version of libdivecomputer
// from the 0.5 development cylcle - most likely temperatures and tank sizes
// are supported
// Parse temperatures
double temperature;
dc_field_type_t temp_fields[] = {DC_FIELD_TEMPERATURE_SURFACE,
DC_FIELD_TEMPERATURE_MAXIMUM,
DC_FIELD_TEMPERATURE_MINIMUM};
for (int i = 0; i < 3; i++) {
rc = dc_parser_get_field(parser, temp_fields[i], 0, &temperature);
if (rc != DC_STATUS_SUCCESS && rc != DC_STATUS_UNSUPPORTED) {
dev_info(devdata, translate("gettextFromC", "Error parsing temperature"));
return rc;
}
if (rc == DC_STATUS_SUCCESS)
switch(i) {
case 0:
dive->dc.airtemp.mkelvin = C_to_mkelvin(temperature);
break;
case 1: // we don't distinguish min and max water temp here, so take min if given, max otherwise
case 2:
dive->dc.watertemp.mkelvin = C_to_mkelvin(temperature);
break;
}
}
#endif
// Parse the gas mixes.
unsigned int ngases = 0;
rc = dc_parser_get_field(parser, DC_FIELD_GASMIX_COUNT, 0, &ngases);
if (rc != DC_STATUS_SUCCESS && rc != DC_STATUS_UNSUPPORTED) {
dev_info(devdata, translate("gettextFromC", "Error parsing the gas mix count"));
return rc;
}
#if DC_VERSION_CHECK(0, 3, 0)
// Check if the libdivecomputer version already supports salinity & atmospheric
dc_salinity_t salinity = {
.type = DC_WATER_SALT,
.density = SEAWATER_SALINITY / 10.0
};
rc = dc_parser_get_field(parser, DC_FIELD_SALINITY, 0, &salinity);
if (rc != DC_STATUS_SUCCESS && rc != DC_STATUS_UNSUPPORTED) {
dev_info(devdata, translate("gettextFromC", "Error obtaining water salinity"));
return rc;
}
if (rc == DC_STATUS_SUCCESS)
dive->dc.salinity = rint(salinity.density * 10.0);
double surface_pressure = 0;
rc = dc_parser_get_field(parser, DC_FIELD_ATMOSPHERIC, 0, &surface_pressure);
if (rc != DC_STATUS_SUCCESS && rc != DC_STATUS_UNSUPPORTED) {
dev_info(devdata, translate("gettextFromC", "Error obtaining surface pressure"));
return rc;
}
if (rc == DC_STATUS_SUCCESS)
dive->dc.surface_pressure.mbar = rint(surface_pressure * 1000.0);
#endif
#ifdef DC_FIELD_STRING
// The dive parsing may give us more device information
int idx;
for (idx = 0; idx < 100; idx++) {
dc_field_string_t str = { NULL };
rc = dc_parser_get_field(parser, DC_FIELD_STRING, idx, &str);
if (rc != DC_STATUS_SUCCESS)
break;
if (!str.desc || !str.value)
break;
parse_string_field(dive, &str);
}
#endif
#if DC_VERSION_CHECK(0, 5, 0) && defined(DC_GASMIX_UNKNOWN)
dc_divemode_t divemode;
rc = dc_parser_get_field(parser, DC_FIELD_DIVEMODE, 0, &divemode);
if (rc != DC_STATUS_SUCCESS && rc != DC_STATUS_UNSUPPORTED) {
dev_info(devdata, translate("gettextFromC", "Error obtaining divemode"));
return rc;
}
if (rc == DC_STATUS_SUCCESS)
switch(divemode) {
case DC_DIVEMODE_FREEDIVE:
dive->dc.divemode = FREEDIVE;
break;
case DC_DIVEMODE_GAUGE:
case DC_DIVEMODE_OC: /* Open circuit */
dive->dc.divemode = OC;
break;
case DC_DIVEMODE_CC: /* Closed circuit */
dive->dc.divemode = CCR;
break;
}
#endif
rc = parse_gasmixes(devdata, dive, parser, ngases);
if (rc != DC_STATUS_SUCCESS && rc != DC_STATUS_UNSUPPORTED) {
dev_info(devdata, translate("gettextFromC", "Error parsing the gas mix"));
return rc;
}
return DC_STATUS_SUCCESS;
}
/* returns true if we want libdivecomputer's dc_device_foreach() to continue,
* false otherwise */
static int dive_cb(const unsigned char *data, unsigned int size,
const unsigned char *fingerprint, unsigned int fsize,
void *userdata)
{
int rc;
dc_parser_t *parser = NULL;
device_data_t *devdata = userdata;
dc_datetime_t dt = { 0 };
struct tm tm;
struct dive *dive = NULL;
/* reset the deco / ndl data */
ndl = stoptime = stopdepth = 0;
in_deco = false;
rc = create_parser(devdata, &parser);
if (rc != DC_STATUS_SUCCESS) {
dev_info(devdata, translate("gettextFromC", "Unable to create parser for %s %s"), devdata->vendor, devdata->product);
return false;
}
rc = dc_parser_set_data(parser, data, size);
if (rc != DC_STATUS_SUCCESS) {
dev_info(devdata, translate("gettextFromC", "Error registering the data"));
goto error_exit;
}
import_dive_number++;
dive = alloc_dive();
// Parse the dive's header data
rc = libdc_header_parser (parser, devdata, dive);
if (rc != DC_STATUS_SUCCESS) {
dev_info(devdata, translate("getextFromC", "Error parsing the header"));
goto error_exit;
}
dive->dc.model = strdup(devdata->model);
dive->dc.diveid = calculate_diveid(fingerprint, fsize);
// Initialize the sample data.
rc = parse_samples(devdata, &dive->dc, parser);
if (rc != DC_STATUS_SUCCESS) {
dev_info(devdata, translate("gettextFromC", "Error parsing the samples"));
goto error_exit;
}
/* If we already saw this dive, abort. */
if (!devdata->force_download && find_dive(&dive->dc))
goto error_exit;
dc_parser_destroy(parser);
/* Various libdivecomputer interface fixups */
if (first_temp_is_air && dive->dc.samples) {
dive->dc.airtemp = dive->dc.sample[0].temperature;
dive->dc.sample[0].temperature.mkelvin = 0;
}
if (devdata->create_new_trip) {
if (!devdata->trip)
devdata->trip = create_and_hookup_trip_from_dive(dive);
else
add_dive_to_trip(dive, devdata->trip);
}
dive->downloaded = true;
record_dive_to_table(dive, devdata->download_table);
mark_divelist_changed(true);
return true;
error_exit:
dc_parser_destroy(parser);
free(dive);
return false;
}
/*
* The device ID for libdivecomputer devices is the first 32-bit word
* of the SHA1 hash of the model/firmware/serial numbers.
*
* NOTE! This is byte-order-dependent. And I can't find it in myself to
* care.
*/
static uint32_t calculate_sha1(unsigned int model, unsigned int firmware, unsigned int serial)
{
SHA_CTX ctx;
uint32_t csum[5];
SHA1_Init(&ctx);
SHA1_Update(&ctx, &model, sizeof(model));
SHA1_Update(&ctx, &firmware, sizeof(firmware));
SHA1_Update(&ctx, &serial, sizeof(serial));
SHA1_Final((unsigned char *)csum, &ctx);
return csum[0];
}
/*
* libdivecomputer has returned two different serial numbers for the
* same device in different versions. First it used to just do the four
* bytes as one 32-bit number, then it turned it into a decimal number
* with each byte giving two digits (0-99).
*
* The only way we can tell is by looking at the format of the number,
* so we'll just fix it to the first format.
*/
static unsigned int undo_libdivecomputer_suunto_nr_changes(unsigned int serial)
{
unsigned char b0, b1, b2, b3;
/*
* The second format will never have more than 8 decimal
* digits, so do a cheap check first
*/
if (serial >= 100000000)
return serial;
/* The original format seems to be four bytes of values 00-99 */
b0 = (serial >> 0) & 0xff;
b1 = (serial >> 8) & 0xff;
b2 = (serial >> 16) & 0xff;
b3 = (serial >> 24) & 0xff;
/* Looks like an old-style libdivecomputer serial number */
if ((b0 < 100) && (b1 < 100) && (b2 < 100) && (b3 < 100))
return serial;
/* Nope, it was converted. */
b0 = serial % 100;
serial /= 100;
b1 = serial % 100;
serial /= 100;
b2 = serial % 100;
serial /= 100;
b3 = serial % 100;
serial = b0 + (b1 << 8) + (b2 << 16) + (b3 << 24);
return serial;
}
static unsigned int fixup_suunto_versions(device_data_t *devdata, const dc_event_devinfo_t *devinfo)
{
unsigned int serial = devinfo->serial;
char serial_nr[13] = "";
char firmware[13] = "";
first_temp_is_air = 1;
serial = undo_libdivecomputer_suunto_nr_changes(serial);
if (serial) {
snprintf(serial_nr, sizeof(serial_nr), "%02d%02d%02d%02d",
(devinfo->serial >> 24) & 0xff,
(devinfo->serial >> 16) & 0xff,
(devinfo->serial >> 8) & 0xff,
(devinfo->serial >> 0) & 0xff);
}
if (devinfo->firmware) {
snprintf(firmware, sizeof(firmware), "%d.%d.%d",
(devinfo->firmware >> 16) & 0xff,
(devinfo->firmware >> 8) & 0xff,
(devinfo->firmware >> 0) & 0xff);
}
create_device_node(devdata->model, devdata->deviceid, serial_nr, firmware, "");
return serial;
}
static void event_cb(dc_device_t *device, dc_event_type_t event, const void *data, void *userdata)
{
const dc_event_progress_t *progress = data;
const dc_event_devinfo_t *devinfo = data;
const dc_event_clock_t *clock = data;
const dc_event_vendor_t *vendor = data;
device_data_t *devdata = userdata;
unsigned int serial;
switch (event) {
case DC_EVENT_WAITING:
dev_info(devdata, translate("gettextFromC", "Event: waiting for user action"));
break;
case DC_EVENT_PROGRESS:
if (!progress->maximum)
break;
progress_bar_fraction = (double)progress->current / (double)progress->maximum;
break;
case DC_EVENT_DEVINFO:
dev_info(devdata, translate("gettextFromC", "model=%u (0x%08x), firmware=%u (0x%08x), serial=%u (0x%08x)"),
devinfo->model, devinfo->model,
devinfo->firmware, devinfo->firmware,
devinfo->serial, devinfo->serial);
if (devdata->libdc_logfile) {
fprintf(devdata->libdc_logfile, "Event: model=%u (0x%08x), firmware=%u (0x%08x), serial=%u (0x%08x)\n",
devinfo->model, devinfo->model,
devinfo->firmware, devinfo->firmware,
devinfo->serial, devinfo->serial);
}
/*
* libdivecomputer doesn't give serial numbers in the proper string form,
* so we have to see if we can do some vendor-specific munging.
*/
serial = devinfo->serial;
if (!strcmp(devdata->vendor, "Suunto"))
serial = fixup_suunto_versions(devdata, devinfo);
devdata->deviceid = calculate_sha1(devinfo->model, devinfo->firmware, serial);
/* really, serial and firmware version are NOT numbers. We'll try to save them here
* in something that might work, but this really needs to be handled with the
* DC_FIELD_STRING interface instead */
devdata->libdc_serial = devinfo->serial;
devdata->libdc_firmware = devinfo->firmware;
break;
case DC_EVENT_CLOCK:
dev_info(devdata, translate("gettextFromC", "Event: systime=%" PRId64 ", devtime=%u\n"),
(uint64_t)clock->systime, clock->devtime);
if (devdata->libdc_logfile) {
fprintf(devdata->libdc_logfile, "Event: systime=%" PRId64 ", devtime=%u\n",
(uint64_t)clock->systime, clock->devtime);
}
break;
case DC_EVENT_VENDOR:
if (devdata->libdc_logfile) {
fprintf(devdata->libdc_logfile, "Event: vendor=");
for (unsigned int i = 0; i < vendor->size; ++i)
fprintf(devdata->libdc_logfile, "%02X", vendor->data[i]);
fprintf(devdata->libdc_logfile, "\n");
}
break;
default:
break;
}
}
int import_thread_cancelled;
static int
cancel_cb(void *userdata)
{
return import_thread_cancelled;
}
static const char *do_device_import(device_data_t *data)
{
dc_status_t rc;
dc_device_t *device = data->device;
data->model = str_printf("%s %s", data->vendor, data->product);
// Register the event handler.
int events = DC_EVENT_WAITING | DC_EVENT_PROGRESS | DC_EVENT_DEVINFO | DC_EVENT_CLOCK | DC_EVENT_VENDOR;
rc = dc_device_set_events(device, events, event_cb, data);
if (rc != DC_STATUS_SUCCESS)
return translate("gettextFromC", "Error registering the event handler.");
// Register the cancellation handler.
rc = dc_device_set_cancel(device, cancel_cb, data);
if (rc != DC_STATUS_SUCCESS)
return translate("gettextFromC", "Error registering the cancellation handler.");
if (data->libdc_dump) {
dc_buffer_t *buffer = dc_buffer_new(0);
rc = dc_device_dump(device, buffer);
if (rc == DC_STATUS_SUCCESS && dumpfile_name) {
FILE *fp = subsurface_fopen(dumpfile_name, "wb");
if (fp != NULL) {
fwrite(dc_buffer_get_data(buffer), 1, dc_buffer_get_size(buffer), fp);
fclose(fp);
}
}
dc_buffer_free(buffer);
} else {
rc = dc_device_foreach(device, dive_cb, data);
}
if (rc != DC_STATUS_SUCCESS) {
progress_bar_fraction = 0.0;
return translate("gettextFromC", "Dive data import error");
}
/* All good */
return NULL;
}
void
logfunc(dc_context_t *context, dc_loglevel_t loglevel, const char *file, unsigned int line, const char *function, const char *msg, void *userdata)
{
const char *loglevels[] = { "NONE", "ERROR", "WARNING", "INFO", "DEBUG", "ALL" };
FILE *fp = (FILE *)userdata;
if (loglevel == DC_LOGLEVEL_ERROR || loglevel == DC_LOGLEVEL_WARNING) {
fprintf(fp, "%s: %s [in %s:%d (%s)]\n", loglevels[loglevel], msg, file, line, function);
} else {
fprintf(fp, "%s: %s\n", loglevels[loglevel], msg);
}
}
const char *do_libdivecomputer_import(device_data_t *data)
{
dc_status_t rc;
const char *err;
FILE *fp = NULL;
import_dive_number = 0;
first_temp_is_air = 0;
data->device = NULL;
data->context = NULL;
if (data->libdc_log && logfile_name)
fp = subsurface_fopen(logfile_name, "w");
data->libdc_logfile = fp;
rc = dc_context_new(&data->context);
if (rc != DC_STATUS_SUCCESS)
return translate("gettextFromC", "Unable to create libdivecomputer context");
if (fp) {
dc_context_set_loglevel(data->context, DC_LOGLEVEL_ALL);
dc_context_set_logfunc(data->context, logfunc, fp);
}
err = translate("gettextFromC", "Unable to open %s %s (%s)");
if (data->bluetooth_mode) {
dc_serial_t *serial_device;
rc = dc_serial_qt_open(&serial_device, data->context, data->devname);
if (rc == DC_STATUS_SUCCESS) {
rc = dc_device_custom_open(&data->device, data->context, data->descriptor, serial_device);
} else {
report_error(errmsg(rc));
}
} else {
rc = dc_device_open(&data->device, data->context, data->descriptor, data->devname);
if (rc != DC_STATUS_SUCCESS && subsurface_access(data->devname, R_OK | W_OK) != 0)
err = translate("gettextFromC", "Insufficient privileges to open the device %s %s (%s)");
}
if (rc == DC_STATUS_SUCCESS) {
err = do_device_import(data);
/* TODO: Show the logfile to the user on error. */
dc_device_close(data->device);
data->device = NULL;
}
dc_context_free(data->context);
data->context = NULL;
if (fp) {
fclose(fp);
}
return err;
}
/*
* Parse data buffers instead of dc devices downloaded data.
* Intended to be used to parse profile data from binary files during import tasks.
* Actually included Uwatec families because of works on datatrak and smartrak logs
* and OSTC families for OSTCTools logs import.
* For others, simply include them in the switch (check parameters).
* Note that dc_descriptor_t in data *must* have been filled using dc_descriptor_iterator()
* calls.
*/
dc_status_t libdc_buffer_parser(struct dive *dive, device_data_t *data, unsigned char *buffer, int size)
{
dc_status_t rc;
dc_parser_t *parser = NULL;
switch (data->descriptor->type) {
case DC_FAMILY_UWATEC_ALADIN:
case DC_FAMILY_UWATEC_MEMOMOUSE:
rc = uwatec_memomouse_parser_create(&parser, data->context, 0, 0);
break;
case DC_FAMILY_UWATEC_SMART:
case DC_FAMILY_UWATEC_MERIDIAN:
rc = uwatec_smart_parser_create (&parser, data->context, data->descriptor->model, 0, 0);
break;
case DC_FAMILY_HW_OSTC:
rc = hw_ostc_parser_create (&parser, data->context, data->deviceid, 0);
break;
case DC_FAMILY_HW_FROG:
case DC_FAMILY_HW_OSTC3:
rc = hw_ostc_parser_create (&parser, data->context, data->deviceid, 1);
break;
default:
report_error("Device type not handled!");
return DC_STATUS_UNSUPPORTED;
}
if (rc != DC_STATUS_SUCCESS) {
report_error("Error creating parser.");
dc_parser_destroy (parser);
return rc;
}
rc = dc_parser_set_data(parser, buffer, size);
if (rc != DC_STATUS_SUCCESS) {
report_error("Error registering the data.");
dc_parser_destroy (parser);
return rc;
}
// Do not parse Aladin/Memomouse headers as they are fakes
// Do not return on error, we can still parse the samples
if (data->descriptor->type != DC_FAMILY_UWATEC_ALADIN && data->descriptor->type != DC_FAMILY_UWATEC_MEMOMOUSE) {
rc = libdc_header_parser (parser, data, dive);
if (rc != DC_STATUS_SUCCESS) {
report_error("Error parsing the dive header data. Dive # %d\nStatus = %s", dive->number, errmsg(rc));
}
}
rc = dc_parser_samples_foreach (parser, sample_cb, &dive->dc);
if (rc != DC_STATUS_SUCCESS) {
report_error("Error parsing the sample data. Dive # %d\nStatus = %s", dive->number, errmsg(rc));
dc_parser_destroy (parser);
return rc;
}
dc_parser_destroy(parser);
return(DC_STATUS_SUCCESS);
}