#include #include #include #include #include #include #include #define __USE_XOPEN #include #include #include #include #include #include #include "gettext.h" #include "dive.h" #include "divelist.h" #include "device.h" #include "membuffer.h" int verbose, quit; int metric = 1; int last_xml_version = -1; int diveid = -1; static xmlDoc *test_xslt_transforms(xmlDoc *doc, const char **params); /* the dive table holds the overall dive list; target table points at * the table we are currently filling */ struct dive_table dive_table; struct dive_table *target_table = NULL; /* Trim a character string by removing leading and trailing white space characters. * Parameter: a pointer to a null-terminated character string (buffer); * Return value: length of the trimmed string, excluding the terminal 0x0 byte * The original pointer (buffer) remains valid after this function has been called * and points to the trimmed string */ int trimspace(char *buffer) { int i, size, start, end; size = strlen(buffer); for(start = 0; isspace(buffer[start]); start++) if (start >= size) return 0; // Find 1st character following leading whitespace for(end = size - 1; isspace(buffer[end]); end--) // Find last character before trailing whitespace if (end <= 0) return 0; for(i = start; i <= end; i++) // Move the nonspace characters to the start of the string buffer[i-start] = buffer[i]; size = end - start + 1; buffer[size] = 0x0; // then terminate the string return size; // return string length } /* * Clear a dive_table */ void clear_table(struct dive_table *table) { for (int i = 0; i < table->nr; i++) free(table->dives[i]); table->nr = 0; } /* * Add a dive into the dive_table array */ void record_dive_to_table(struct dive *dive, struct dive_table *table) { assert(table != NULL); struct dive **dives = grow_dive_table(table); int nr = table->nr; dives[nr] = fixup_dive(dive); table->nr = nr + 1; } void record_dive(struct dive *dive) { record_dive_to_table(dive, &dive_table); } static void start_match(const char *type, const char *name, char *buffer) { if (verbose > 2) printf("Matching %s '%s' (%s)\n", type, name, buffer); } static void nonmatch(const char *type, const char *name, char *buffer) { if (verbose > 1) printf("Unable to match %s '%s' (%s)\n", type, name, buffer); } typedef void (*matchfn_t)(char *buffer, void *); static int match(const char *pattern, int plen, const char *name, matchfn_t fn, char *buf, void *data) { switch (name[plen]) { case '\0': case '.': break; default: return 0; } if (memcmp(pattern, name, plen)) return 0; fn(buf, data); return 1; } struct units xml_parsing_units; const struct units SI_units = SI_UNITS; const struct units IMPERIAL_units = IMPERIAL_UNITS; /* * Dive info as it is being built up.. */ #define MAX_EVENT_NAME 128 static struct divecomputer *cur_dc; static struct dive *cur_dive; static struct dive_site *cur_dive_site; degrees_t cur_latitude, cur_longitude; static dive_trip_t *cur_trip = NULL; static struct sample *cur_sample; static struct picture *cur_picture; static union { struct event event; char allocation[sizeof(struct event)+MAX_EVENT_NAME]; } event_allocation = { .event.deleted = 1 }; #define cur_event event_allocation.event static struct { struct { const char *model; uint32_t deviceid; const char *nickname, *serial_nr, *firmware; } dc; } cur_settings; static bool in_settings = false; static bool in_userid = false; static struct tm cur_tm; static int cur_cylinder_index, cur_ws_index; static int lastndl, laststoptime, laststopdepth, lastcns, lastpo2, lastindeco; static int lastcylinderindex, lastsensor, next_o2_sensor; static struct extra_data cur_extra_data; /* * If we don't have an explicit dive computer, * we use the implicit one that every dive has.. */ static struct divecomputer *get_dc(void) { return cur_dc ?: &cur_dive->dc; } static enum import_source { UNKNOWN, LIBDIVECOMPUTER, DIVINGLOG, UDDF, SSRF_WS, } import_source; static void divedate(const char *buffer, timestamp_t *when) { int d, m, y; int hh, mm, ss; hh = 0; mm = 0; ss = 0; if (sscanf(buffer, "%d.%d.%d %d:%d:%d", &d, &m, &y, &hh, &mm, &ss) >= 3) { /* This is ok, and we got at least the date */ } else if (sscanf(buffer, "%d-%d-%d %d:%d:%d", &y, &m, &d, &hh, &mm, &ss) >= 3) { /* This is also ok */ } else { fprintf(stderr, "Unable to parse date '%s'\n", buffer); return; } cur_tm.tm_year = y; cur_tm.tm_mon = m - 1; cur_tm.tm_mday = d; cur_tm.tm_hour = hh; cur_tm.tm_min = mm; cur_tm.tm_sec = ss; *when = utc_mktime(&cur_tm); } static void divetime(const char *buffer, timestamp_t *when) { int h, m, s = 0; if (sscanf(buffer, "%d:%d:%d", &h, &m, &s) >= 2) { cur_tm.tm_hour = h; cur_tm.tm_min = m; cur_tm.tm_sec = s; *when = utc_mktime(&cur_tm); } } /* Libdivecomputer: "2011-03-20 10:22:38" */ static void divedatetime(char *buffer, timestamp_t *when) { int y, m, d; int hr, min, sec; if (sscanf(buffer, "%d-%d-%d %d:%d:%d", &y, &m, &d, &hr, &min, &sec) == 6) { cur_tm.tm_year = y; cur_tm.tm_mon = m - 1; cur_tm.tm_mday = d; cur_tm.tm_hour = hr; cur_tm.tm_min = min; cur_tm.tm_sec = sec; *when = utc_mktime(&cur_tm); } } enum ParseState { FINDSTART, FINDEND }; static void divetags(char *buffer, struct tag_entry **tags) { int i = 0, start = 0, end = 0; enum ParseState state = FINDEND; int len = buffer ? strlen(buffer) : 0; while (i < len) { if (buffer[i] == ',') { if (state == FINDSTART) { /* Detect empty tags */ } else if (state == FINDEND) { /* Found end of tag */ if (i > 0 && buffer[i - 1] != '\\') { buffer[i] = '\0'; state = FINDSTART; taglist_add_tag(tags, buffer + start); } else { state = FINDSTART; } } } else if (buffer[i] == ' ') { /* Handled */ } else { /* Found start of tag */ if (state == FINDSTART) { state = FINDEND; start = i; } else if (state == FINDEND) { end = i; } } i++; } if (state == FINDEND) { if (end < start) end = len - 1; if (len > 0) { buffer[end + 1] = '\0'; taglist_add_tag(tags, buffer + start); } } } enum number_type { NEITHER, FLOAT }; static enum number_type parse_float(const char *buffer, double *res, const char **endp) { double val; static bool first_time = true; errno = 0; val = ascii_strtod(buffer, endp); if (errno || *endp == buffer) return NEITHER; if (**endp == ',') { if (IS_FP_SAME(val, rint(val))) { /* we really want to send an error if this is a Subsurface native file * as this is likely indication of a bug - but right now we don't have * that information available */ if (first_time) { fprintf(stderr, "Floating point value with decimal comma (%s)?\n", buffer); first_time = false; } /* Try again in permissive mode*/ val = strtod_flags(buffer, endp, 0); } } *res = val; return FLOAT; } union int_or_float { double fp; }; static enum number_type integer_or_float(char *buffer, union int_or_float *res) { const char *end; return parse_float(buffer, &res->fp, &end); } static void pressure(char *buffer, pressure_t *pressure) { double mbar = 0.0; union int_or_float val; switch (integer_or_float(buffer, &val)) { case FLOAT: /* Just ignore zero values */ if (!val.fp) break; switch (xml_parsing_units.pressure) { case PASCAL: mbar = val.fp / 100; break; case BAR: /* Assume mbar, but if it's really small, it's bar */ mbar = val.fp; if (fabs(mbar) < 5000) mbar = mbar * 1000; break; case PSI: mbar = psi_to_mbar(val.fp); break; } if (fabs(mbar) > 5 && fabs(mbar) < 5000000) { pressure->mbar = rint(mbar); break; } /* fallthrough */ default: printf("Strange pressure reading %s\n", buffer); } } static void cylinder_use(char *buffer, enum cylinderuse *cyl_use) { if (trimspace(buffer)) *cyl_use = cylinderuse_from_text(buffer); } static void salinity(char *buffer, int *salinity) { union int_or_float val; switch (integer_or_float(buffer, &val)) { case FLOAT: *salinity = rint(val.fp * 10.0); break; default: printf("Strange salinity reading %s\n", buffer); } } static void depth(char *buffer, depth_t *depth) { union int_or_float val; switch (integer_or_float(buffer, &val)) { case FLOAT: switch (xml_parsing_units.length) { case METERS: depth->mm = rint(val.fp * 1000); break; case FEET: depth->mm = feet_to_mm(val.fp); break; } break; default: printf("Strange depth reading %s\n", buffer); } } static void extra_data_start(void) { memset(&cur_extra_data, 0, sizeof(struct extra_data)); } static void extra_data_end(void) { // don't save partial structures - we must have both key and value if (cur_extra_data.key && cur_extra_data.value) add_extra_data(cur_dc, cur_extra_data.key, cur_extra_data.value); } static void weight(char *buffer, weight_t *weight) { union int_or_float val; switch (integer_or_float(buffer, &val)) { case FLOAT: switch (xml_parsing_units.weight) { case KG: weight->grams = rint(val.fp * 1000); break; case LBS: weight->grams = lbs_to_grams(val.fp); break; } break; default: printf("Strange weight reading %s\n", buffer); } } static void temperature(char *buffer, temperature_t *temperature) { union int_or_float val; switch (integer_or_float(buffer, &val)) { case FLOAT: switch (xml_parsing_units.temperature) { case KELVIN: temperature->mkelvin = val.fp * 1000; break; case CELSIUS: temperature->mkelvin = C_to_mkelvin(val.fp); break; case FAHRENHEIT: temperature->mkelvin = F_to_mkelvin(val.fp); break; } break; default: printf("Strange temperature reading %s\n", buffer); } /* temperatures outside -40C .. +70C should be ignored */ if (temperature->mkelvin < ZERO_C_IN_MKELVIN - 40000 || temperature->mkelvin > ZERO_C_IN_MKELVIN + 70000) temperature->mkelvin = 0; } static void sampletime(char *buffer, duration_t *time) { int i; int min, sec; i = sscanf(buffer, "%d:%d", &min, &sec); switch (i) { case 1: sec = min; min = 0; /* fallthrough */ case 2: time->seconds = sec + min * 60; break; default: printf("Strange sample time reading %s\n", buffer); } } static void offsettime(char *buffer, offset_t *time) { duration_t uoffset; int sign = 1; if (*buffer == '-') { sign = -1; buffer++; } /* yes, this could indeed fail if we have an offset > 34yrs * - too bad */ sampletime(buffer, &uoffset); time->seconds = sign * uoffset.seconds; } static void duration(char *buffer, duration_t *time) { /* DivingLog 5.08 (and maybe other versions) appear to sometimes * store the dive time as 44.00 instead of 44:00; * This attempts to parse this in a fairly robust way */ if (!strchr(buffer, ':') && strchr(buffer, '.')) { char *mybuffer = strdup(buffer); char *dot = strchr(mybuffer, '.'); *dot = ':'; sampletime(mybuffer, time); free(mybuffer); } else { sampletime(buffer, time); } } static void percent(char *buffer, fraction_t *fraction) { double val; const char *end; switch (parse_float(buffer, &val, &end)) { case FLOAT: /* Turn fractions into percent unless explicit.. */ if (val <= 1.0) { while (isspace(*end)) end++; if (*end != '%') val *= 100; } /* Then turn percent into our integer permille format */ if (val >= 0 && val <= 100.0) { fraction->permille = rint(val * 10); break; } default: printf(translate("gettextFromC", "Strange percentage reading %s\n"), buffer); break; } } static void gasmix(char *buffer, fraction_t *fraction) { /* libdivecomputer does negative percentages. */ if (*buffer == '-') return; if (cur_cylinder_index < MAX_CYLINDERS) percent(buffer, fraction); } static void gasmix_nitrogen(char *buffer, struct gasmix *gasmix) { /* Ignore n2 percentages. There's no value in them. */ } static void cylindersize(char *buffer, volume_t *volume) { union int_or_float val; switch (integer_or_float(buffer, &val)) { case FLOAT: volume->mliter = rint(val.fp * 1000); break; default: printf("Strange volume reading %s\n", buffer); break; } } static void utf8_string(char *buffer, void *_res) { char **res = _res; int size; size = trimspace(buffer); if(size) *res = strdup(buffer); } static void event_name(char *buffer, char *name) { int size = trimspace(buffer); if (size >= MAX_EVENT_NAME) size = MAX_EVENT_NAME-1; memcpy(name, buffer, size); name[size] = 0; } // We don't use gauge as a mode, and pscr doesn't exist as a libdc divemode const char *libdc_divemode_text[] = { "oc", "cc", "pscr", "freedive", "gauge"}; /* Extract the dive computer type from the xml text buffer */ static void get_dc_type(char *buffer, enum dive_comp_type *dct) { if (trimspace(buffer)) { for (enum dive_comp_type i = 0; i < NUM_DC_TYPE; i++) { if (strcmp(buffer, divemode_text[i]) == 0) *dct = i; else if (strcmp(buffer, libdc_divemode_text[i]) == 0) *dct = i; } } } #define MATCH(pattern, fn, dest) ({ \ /* Silly type compatibility test */ \ if (0) (fn)("test", dest); \ match(pattern, strlen(pattern), name, (matchfn_t) (fn), buf, dest); }) static void get_index(char *buffer, int *i) { *i = atoi(buffer); } static void get_uint8(char *buffer, uint8_t *i) { *i = atoi(buffer); } static void get_bearing(char *buffer, bearing_t *bearing) { bearing->degrees = atoi(buffer); } static void get_rating(char *buffer, int *i) { int j = atoi(buffer); if (j >= 0 && j <= 5) { *i = j; } } static void double_to_o2pressure(char *buffer, o2pressure_t *i) { i->mbar = rint(ascii_strtod(buffer, NULL) * 1000.0); } static void hex_value(char *buffer, uint32_t *i) { *i = strtoul(buffer, NULL, 16); } static void get_tripflag(char *buffer, tripflag_t *tf) { *tf = strcmp(buffer, "NOTRIP") ? TF_NONE : NO_TRIP; } /* * Divinglog is crazy. The temperatures are in celsius. EXCEPT * for the sample temperatures, that are in Fahrenheit. * WTF? * * Oh, and I think Diving Log *internally* probably kept them * in celsius, because I'm seeing entries like * * 32.0 * * in there. Which is freezing, aka 0 degC. I bet the "0" is * what Diving Log uses for "no temperature". * * So throw away crap like that. * * It gets worse. Sometimes the sample temperatures are in * Celsius, which apparently happens if you are in a SI * locale. So we now do: * * - temperatures < 32.0 == Celsius * - temperature == 32.0 -> garbage, it's a missing temperature (zero converted from C to F) * - temperatures > 32.0 == Fahrenheit */ static void fahrenheit(char *buffer, temperature_t *temperature) { union int_or_float val; switch (integer_or_float(buffer, &val)) { case FLOAT: if (IS_FP_SAME(val.fp, 32.0)) break; if (val.fp < 32.0) temperature->mkelvin = C_to_mkelvin(val.fp); else temperature->mkelvin = F_to_mkelvin(val.fp); break; default: fprintf(stderr, "Crazy Diving Log temperature reading %s\n", buffer); } } /* * Did I mention how bat-shit crazy divinglog is? The sample * pressures are in PSI. But the tank working pressure is in * bar. WTF^2? * * Crazy stuff like this is why subsurface has everything in * these inconvenient typed structures, and you have to say * "pressure->mbar" to get the actual value. Exactly so that * you can never have unit confusion. * * It gets worse: sometimes apparently the pressures are in * bar, sometimes in psi. Dirk suspects that this may be a * DivingLog Uemis importer bug, and that they are always * supposed to be in bar, but that the importer got the * sample importing wrong. * * Sadly, there's no way to really tell. So I think we just * have to have some arbitrary cut-off point where we assume * that smaller values mean bar.. Not good. */ static void psi_or_bar(char *buffer, pressure_t *pressure) { union int_or_float val; switch (integer_or_float(buffer, &val)) { case FLOAT: if (val.fp > 400) pressure->mbar = psi_to_mbar(val.fp); else pressure->mbar = rint(val.fp * 1000); break; default: fprintf(stderr, "Crazy Diving Log PSI reading %s\n", buffer); } } static int divinglog_fill_sample(struct sample *sample, const char *name, char *buf) { return MATCH("time.p", sampletime, &sample->time) || MATCH("depth.p", depth, &sample->depth) || MATCH("temp.p", fahrenheit, &sample->temperature) || MATCH("press1.p", psi_or_bar, &sample->cylinderpressure) || 0; } static void uddf_gasswitch(char *buffer, struct sample *sample) { int idx = atoi(buffer); int seconds = sample->time.seconds; struct dive *dive = cur_dive; struct divecomputer *dc = get_dc(); add_gas_switch_event(dive, dc, seconds, idx); } static int uddf_fill_sample(struct sample *sample, const char *name, char *buf) { return MATCH("divetime", sampletime, &sample->time) || MATCH("depth", depth, &sample->depth) || MATCH("temperature", temperature, &sample->temperature) || MATCH("tankpressure", pressure, &sample->cylinderpressure) || MATCH("ref.switchmix", uddf_gasswitch, sample) || 0; } static void eventtime(char *buffer, duration_t *duration) { sampletime(buffer, duration); if (cur_sample) duration->seconds += cur_sample->time.seconds; } static void try_to_match_autogroup(const char *name, char *buf) { int autogroupvalue; start_match("autogroup", name, buf); if (MATCH("state.autogroup", get_index, &autogroupvalue)) { set_autogroup(autogroupvalue); return; } nonmatch("autogroup", name, buf); } void add_gas_switch_event(struct dive *dive, struct divecomputer *dc, int seconds, int idx) { /* sanity check so we don't crash */ if (idx < 0 || idx >= MAX_CYLINDERS) return; /* The gas switch event format is insane for historical reasons */ struct gasmix *mix = &dive->cylinder[idx].gasmix; int o2 = get_o2(mix); int he = get_he(mix); struct event *ev; int value; o2 = (o2 + 5) / 10; he = (he + 5) / 10; value = o2 + (he << 16); ev = add_event(dc, seconds, he ? SAMPLE_EVENT_GASCHANGE2 : SAMPLE_EVENT_GASCHANGE, 0, value, "gaschange"); if (ev) { ev->gas.index = idx; ev->gas.mix = *mix; } } static void get_cylinderindex(char *buffer, uint8_t *i) { *i = atoi(buffer); if (lastcylinderindex != *i) { add_gas_switch_event(cur_dive, get_dc(), cur_sample->time.seconds, *i); lastcylinderindex = *i; } } static void get_sensor(char *buffer, uint8_t *i) { *i = atoi(buffer); lastsensor = *i; } static void parse_libdc_deco(char *buffer, struct sample *s) { if (strcmp(buffer, "deco") == 0) { s->in_deco = true; } else if (strcmp(buffer, "ndl") == 0) { s->in_deco = false; // The time wasn't stoptime, it was ndl s->ndl = s->stoptime; s->stoptime.seconds = 0; } } static void try_to_fill_dc_settings(const char *name, char *buf) { start_match("divecomputerid", name, buf); if (MATCH("model.divecomputerid", utf8_string, &cur_settings.dc.model)) return; if (MATCH("deviceid.divecomputerid", hex_value, &cur_settings.dc.deviceid)) return; if (MATCH("nickname.divecomputerid", utf8_string, &cur_settings.dc.nickname)) return; if (MATCH("serial.divecomputerid", utf8_string, &cur_settings.dc.serial_nr)) return; if (MATCH("firmware.divecomputerid", utf8_string, &cur_settings.dc.firmware)) return; nonmatch("divecomputerid", name, buf); } static void try_to_fill_event(const char *name, char *buf) { start_match("event", name, buf); if (MATCH("event", event_name, cur_event.name)) return; if (MATCH("name", event_name, cur_event.name)) return; if (MATCH("time", eventtime, &cur_event.time)) return; if (MATCH("type", get_index, &cur_event.type)) return; if (MATCH("flags", get_index, &cur_event.flags)) return; if (MATCH("value", get_index, &cur_event.value)) return; if (MATCH("cylinder", get_index, &cur_event.gas.index)) { /* We add one to indicate that we got an actual cylinder index value */ cur_event.gas.index++; return; } if (MATCH("o2", percent, &cur_event.gas.mix.o2)) return; if (MATCH("he", percent, &cur_event.gas.mix.he)) return; nonmatch("event", name, buf); } static int match_dc_data_fields(struct divecomputer *dc, const char *name, char *buf) { if (MATCH("maxdepth", depth, &dc->maxdepth)) return 1; if (MATCH("meandepth", depth, &dc->meandepth)) return 1; if (MATCH("max.depth", depth, &dc->maxdepth)) return 1; if (MATCH("mean.depth", depth, &dc->meandepth)) return 1; if (MATCH("duration", duration, &dc->duration)) return 1; if (MATCH("divetime", duration, &dc->duration)) return 1; if (MATCH("divetimesec", duration, &dc->duration)) return 1; if (MATCH("surfacetime", duration, &dc->surfacetime)) return 1; if (MATCH("airtemp", temperature, &dc->airtemp)) return 1; if (MATCH("watertemp", temperature, &dc->watertemp)) return 1; if (MATCH("air.temperature", temperature, &dc->airtemp)) return 1; if (MATCH("water.temperature", temperature, &dc->watertemp)) return 1; if (MATCH("pressure.surface", pressure, &dc->surface_pressure)) return 1; if (MATCH("salinity.water", salinity, &dc->salinity)) return 1; if (MATCH("key.extradata", utf8_string, &cur_extra_data.key)) return 1; if (MATCH("value.extradata", utf8_string, &cur_extra_data.value)) return 1; if (MATCH("divemode", get_dc_type, &dc->divemode)) return 1; if (MATCH("salinity", salinity, &dc->salinity)) return 1; if (MATCH("atmospheric", pressure, &dc->surface_pressure)) return 1; return 0; } /* We're in the top-level dive xml. Try to convert whatever value to a dive value */ static void try_to_fill_dc(struct divecomputer *dc, const char *name, char *buf) { start_match("divecomputer", name, buf); if (MATCH("date", divedate, &dc->when)) return; if (MATCH("time", divetime, &dc->when)) return; if (MATCH("model", utf8_string, &dc->model)) return; if (MATCH("deviceid", hex_value, &dc->deviceid)) return; if (MATCH("diveid", hex_value, &dc->diveid)) return; if (MATCH("dctype", get_dc_type, &dc->divemode)) return; if (MATCH("no_o2sensors", get_sensor, &dc->no_o2sensors)) return; if (match_dc_data_fields(dc, name, buf)) return; nonmatch("divecomputer", name, buf); } /* We're in samples - try to convert the random xml value to something useful */ static void try_to_fill_sample(struct sample *sample, const char *name, char *buf) { int in_deco; start_match("sample", name, buf); if (MATCH("pressure.sample", pressure, &sample->cylinderpressure)) return; if (MATCH("cylpress.sample", pressure, &sample->cylinderpressure)) return; if (MATCH("pdiluent.sample", pressure, &sample->cylinderpressure)) return; if (MATCH("o2pressure.sample", pressure, &sample->o2cylinderpressure)) return; if (MATCH("cylinderindex.sample", get_cylinderindex, &sample->sensor)) return; if (MATCH("sensor.sample", get_sensor, &sample->sensor)) return; if (MATCH("depth.sample", depth, &sample->depth)) return; if (MATCH("temp.sample", temperature, &sample->temperature)) return; if (MATCH("temperature.sample", temperature, &sample->temperature)) return; if (MATCH("sampletime.sample", sampletime, &sample->time)) return; if (MATCH("time.sample", sampletime, &sample->time)) return; if (MATCH("ndl.sample", sampletime, &sample->ndl)) return; if (MATCH("tts.sample", sampletime, &sample->tts)) return; if (MATCH("in_deco.sample", get_index, &in_deco)) { sample->in_deco = (in_deco == 1); return; } if (MATCH("stoptime.sample", sampletime, &sample->stoptime)) return; if (MATCH("stopdepth.sample", depth, &sample->stopdepth)) return; if (MATCH("cns.sample", get_uint8, &sample->cns)) return; if (MATCH("rbt.sample", sampletime, &sample->rbt)) return; if (MATCH("sensor1.sample", double_to_o2pressure, &sample->o2sensor[0])) // CCR O2 sensor data return; if (MATCH("sensor2.sample", double_to_o2pressure, &sample->o2sensor[1])) return; if (MATCH("sensor3.sample", double_to_o2pressure, &sample->o2sensor[2])) // up to 3 CCR sensors return; if (MATCH("po2.sample", double_to_o2pressure, &sample->setpoint)) return; if (MATCH("heartbeat", get_uint8, &sample->heartbeat)) return; if (MATCH("bearing", get_bearing, &sample->bearing)) return; if (MATCH("setpoint.sample", double_to_o2pressure, &sample->setpoint)) return; if (MATCH("ppo2.sample", double_to_o2pressure, &sample->o2sensor[next_o2_sensor])) { next_o2_sensor++; return; } if (MATCH("deco.sample", parse_libdc_deco, sample)) return; if (MATCH("time.deco", sampletime, &sample->stoptime)) return; if (MATCH("depth.deco", depth, &sample->stopdepth)) return; switch (import_source) { case DIVINGLOG: if (divinglog_fill_sample(sample, name, buf)) return; break; case UDDF: if (uddf_fill_sample(sample, name, buf)) return; break; default: break; } nonmatch("sample", name, buf); } void try_to_fill_userid(const char *name, char *buf) { if (prefs.save_userid_local) set_userid(buf); } static const char *country, *city; static void divinglog_place(char *place, uint32_t *uuid) { char buffer[1024]; snprintf(buffer, sizeof(buffer), "%s%s%s%s%s", place, city ? ", " : "", city ? city : "", country ? ", " : "", country ? country : ""); *uuid = get_dive_site_uuid_by_name(buffer, NULL); if (*uuid == 0) *uuid = create_dive_site(buffer, cur_dive->when); city = NULL; country = NULL; } static int divinglog_dive_match(struct dive *dive, const char *name, char *buf) { return MATCH("divedate", divedate, &dive->when) || MATCH("entrytime", divetime, &dive->when) || MATCH("divetime", duration, &dive->dc.duration) || MATCH("depth", depth, &dive->dc.maxdepth) || MATCH("depthavg", depth, &dive->dc.meandepth) || MATCH("tanktype", utf8_string, &dive->cylinder[0].type.description) || MATCH("tanksize", cylindersize, &dive->cylinder[0].type.size) || MATCH("presw", pressure, &dive->cylinder[0].type.workingpressure) || MATCH("press", pressure, &dive->cylinder[0].start) || MATCH("prese", pressure, &dive->cylinder[0].end) || MATCH("comments", utf8_string, &dive->notes) || MATCH("names.buddy", utf8_string, &dive->buddy) || MATCH("name.country", utf8_string, &country) || MATCH("name.city", utf8_string, &city) || MATCH("name.place", divinglog_place, &dive->dive_site_uuid) || 0; } /* * Uddf specifies ISO 8601 time format. * * There are many variations on that. This handles the useful cases. */ static void uddf_datetime(char *buffer, timestamp_t *when) { char c; int y, m, d, hh, mm, ss; struct tm tm = { 0 }; int i; i = sscanf(buffer, "%d-%d-%d%c%d:%d:%d", &y, &m, &d, &c, &hh, &mm, &ss); if (i == 7) goto success; ss = 0; if (i == 6) goto success; i = sscanf(buffer, "%04d%02d%02d%c%02d%02d%02d", &y, &m, &d, &c, &hh, &mm, &ss); if (i == 7) goto success; ss = 0; if (i == 6) goto success; bad_date: printf("Bad date time %s\n", buffer); return; success: if (c != 'T' && c != ' ') goto bad_date; tm.tm_year = y; tm.tm_mon = m - 1; tm.tm_mday = d; tm.tm_hour = hh; tm.tm_min = mm; tm.tm_sec = ss; *when = utc_mktime(&tm); } #define uddf_datedata(name, offset) \ static void uddf_##name(char *buffer, timestamp_t *when) \ { \ cur_tm.tm_##name = atoi(buffer) + offset; \ *when = utc_mktime(&cur_tm); \ } uddf_datedata(year, 0) uddf_datedata(mon, -1) uddf_datedata(mday, 0) uddf_datedata(hour, 0) uddf_datedata(min, 0) static int uddf_dive_match(struct dive *dive, const char *name, char *buf) { return MATCH("datetime", uddf_datetime, &dive->when) || MATCH("diveduration", duration, &dive->dc.duration) || MATCH("greatestdepth", depth, &dive->dc.maxdepth) || MATCH("year.date", uddf_year, &dive->when) || MATCH("month.date", uddf_mon, &dive->when) || MATCH("day.date", uddf_mday, &dive->when) || MATCH("hour.time", uddf_hour, &dive->when) || MATCH("minute.time", uddf_min, &dive->when) || 0; } /* * This parses "floating point" into micro-degrees. * We don't do exponentials etc, if somebody does * GPS locations in that format, they are insane. */ degrees_t parse_degrees(char *buf, char **end) { int sign = 1, decimals = 6, value = 0; degrees_t ret; while (isspace(*buf)) buf++; switch (*buf) { case '-': sign = -1; /* fallthrough */ case '+': buf++; } while (isdigit(*buf)) { value = 10 * value + *buf - '0'; buf++; } /* Get the first six decimals if they exist */ if (*buf == '.') buf++; do { value *= 10; if (isdigit(*buf)) { value += *buf - '0'; buf++; } } while (--decimals); /* Rounding */ switch (*buf) { case '5' ... '9': value++; } while (isdigit(*buf)) buf++; *end = buf; ret.udeg = value * sign; return ret; } static void gps_lat(char *buffer, struct dive *dive) { char *end; degrees_t latitude = parse_degrees(buffer, &end); struct dive_site *ds = get_dive_site_for_dive(dive); if (!ds) { dive->dive_site_uuid = create_dive_site_with_gps(NULL, latitude, (degrees_t){0}, dive->when); } else { if (ds->latitude.udeg && ds->latitude.udeg != latitude.udeg) fprintf(stderr, "Oops, changing the latitude of existing dive site id %8x name %s; not good\n", ds->uuid, ds->name ?: "(unknown)"); ds->latitude = latitude; } } static void gps_long(char *buffer, struct dive *dive) { char *end; degrees_t longitude = parse_degrees(buffer, &end); struct dive_site *ds = get_dive_site_for_dive(dive); if (!ds) { dive->dive_site_uuid = create_dive_site_with_gps(NULL, (degrees_t){0}, longitude, dive->when); } else { if (ds->longitude.udeg && ds->longitude.udeg != longitude.udeg) fprintf(stderr, "Oops, changing the longitude of existing dive site id %8x name %s; not good\n", ds->uuid, ds->name ?: "(unknown)"); ds->longitude = longitude; } } static void gps_location(char *buffer, struct dive_site *ds) { char *end; ds->latitude = parse_degrees(buffer, &end); ds->longitude = parse_degrees(end, &end); } /* this is in qthelper.cpp, so including the .h file is a pain */ extern const char *printGPSCoords(int lat, int lon); static void gps_in_dive(char *buffer, struct dive *dive) { char *end; struct dive_site *ds = NULL; degrees_t latitude = parse_degrees(buffer, &end); degrees_t longitude = parse_degrees(end, &end); uint32_t uuid = dive->dive_site_uuid; if (uuid == 0) { // check if we have a dive site within 20 meters of that gps fix uuid = get_dive_site_uuid_by_gps_proximity(latitude, longitude, 20, &ds); if (ds) { // found a site nearby; in case it turns out this one had a different name let's // remember the original coordinates so we can create the correct dive site later cur_latitude = latitude; cur_longitude = longitude; dive->dive_site_uuid = uuid; } else { dive->dive_site_uuid = create_dive_site_with_gps("", latitude, longitude, dive->when); ds = get_dive_site_by_uuid(dive->dive_site_uuid); } } else { ds = get_dive_site_by_uuid(uuid); if (dive_site_has_gps_location(ds) && (latitude.udeg != 0 || longitude.udeg != 0) && (ds->latitude.udeg != latitude.udeg || ds->longitude.udeg != longitude.udeg)) { // Houston, we have a problem fprintf(stderr, "dive site uuid in dive, but gps location (%10.6f/%10.6f) different from dive location (%10.6f/%10.6f)\n", ds->latitude.udeg / 1000000.0, ds->longitude.udeg / 1000000.0, latitude.udeg / 1000000.0, longitude.udeg / 1000000.0); const char *coords = printGPSCoords(latitude.udeg, longitude.udeg); ds->notes = add_to_string(ds->notes, translate("gettextFromC", "multiple GPS locations for this dive site; also %s\n"), coords); free((void *)coords); } else { ds->latitude = latitude; ds->longitude = longitude; } } } static void add_dive_site(char *ds_name, struct dive *dive) { static int suffix = 1; char *buffer = ds_name; char *to_free = NULL; int size = trimspace(buffer); if(size) { uint32_t uuid = dive->dive_site_uuid; struct dive_site *ds = get_dive_site_by_uuid(uuid); if (uuid && !ds) { // that's strange - we have a uuid but it doesn't exist - let's just ignore it fprintf(stderr, "dive contains a non-existing dive site uuid %x\n", dive->dive_site_uuid); uuid = 0; } if (!uuid) { // if the dive doesn't have a uuid, check if there's already a dive site by this name uuid = get_dive_site_uuid_by_name(buffer, &ds); if (uuid && import_source == SSRF_WS) { // when downloading GPS fixes from the Subsurface webservice we will often // get a lot of dives with identical names (the autogenerated fixes). // So in this case modify the name to make it unique int name_size = strlen(buffer) + 10; // 8 digits - enough for 100 million sites to_free = buffer = malloc(name_size); do { suffix++; snprintf(buffer, name_size, "%s %8d", ds_name, suffix); } while (get_dive_site_uuid_by_name(buffer, NULL) != 0); ds = NULL; } } if (ds) { // we have a uuid, let's hope there isn't a different name if (same_string(ds->name, "")) { ds->name = copy_string(buffer); } else if (!same_string(ds->name, buffer)) { // if it's not the same name, it's not the same dive site // but wait, we could have gotten this one based on GPS coords and could // have had two different names for the same site... so let's search the other // way around uint32_t exact_match_uuid = get_dive_site_uuid_by_gps_and_name(buffer, ds->latitude, ds->longitude); if (exact_match_uuid) { dive->dive_site_uuid = exact_match_uuid; } else { dive->dive_site_uuid = create_dive_site(buffer, dive->when); struct dive_site *newds = get_dive_site_by_uuid(dive->dive_site_uuid); if (cur_latitude.udeg || cur_longitude.udeg) { // we started this uuid with GPS data, so lets use those newds->latitude = cur_latitude; newds->longitude = cur_longitude; } else { newds->latitude = ds->latitude; newds->longitude = ds->longitude; } newds->notes = add_to_string(newds->notes, translate("gettextFromC", "additional name for site: %s\n"), ds->name); } } else { // add the existing dive site to the current dive dive->dive_site_uuid = uuid; } } else { dive->dive_site_uuid = create_dive_site(buffer, dive->when); } } free(to_free); } static void gps_picture_location(char *buffer, struct picture *pic) { char *end; pic->latitude = parse_degrees(buffer, &end); pic->longitude = parse_degrees(end, &end); } /* We're in the top-level dive xml. Try to convert whatever value to a dive value */ static void try_to_fill_dive(struct dive *dive, const char *name, char *buf) { start_match("dive", name, buf); switch (import_source) { case DIVINGLOG: if (divinglog_dive_match(dive, name, buf)) return; break; case UDDF: if (uddf_dive_match(dive, name, buf)) return; break; default: break; } if (MATCH("divesiteid", hex_value, &dive->dive_site_uuid)) return; if (MATCH("number", get_index, &dive->number)) return; if (MATCH("tags", divetags, &dive->tag_list)) return; if (MATCH("tripflag", get_tripflag, &dive->tripflag)) return; if (MATCH("date", divedate, &dive->when)) return; if (MATCH("time", divetime, &dive->when)) return; if (MATCH("datetime", divedatetime, &dive->when)) return; /* * Legacy format note: per-dive depths and duration get saved * in the first dive computer entry */ if (match_dc_data_fields(&dive->dc, name, buf)) return; if (MATCH("filename.picture", utf8_string, &cur_picture->filename)) return; if (MATCH("offset.picture", offsettime, &cur_picture->offset)) return; if (MATCH("gps.picture", gps_picture_location, cur_picture)) return; if (MATCH("hash.picture", utf8_string, &cur_picture->hash)) return; if (MATCH("cylinderstartpressure", pressure, &dive->cylinder[0].start)) return; if (MATCH("cylinderendpressure", pressure, &dive->cylinder[0].end)) return; if (MATCH("gps", gps_in_dive, dive)) return; if (MATCH("Place", gps_in_dive, dive)) return; if (MATCH("latitude", gps_lat, dive)) return; if (MATCH("sitelat", gps_lat, dive)) return; if (MATCH("lat", gps_lat, dive)) return; if (MATCH("longitude", gps_long, dive)) return; if (MATCH("sitelon", gps_long, dive)) return; if (MATCH("lon", gps_long, dive)) return; if (MATCH("location", add_dive_site, dive)) return; if (MATCH("name.dive", add_dive_site, dive)) return; if (MATCH("suit", utf8_string, &dive->suit)) return; if (MATCH("divesuit", utf8_string, &dive->suit)) return; if (MATCH("notes", utf8_string, &dive->notes)) return; if (MATCH("divemaster", utf8_string, &dive->divemaster)) return; if (MATCH("buddy", utf8_string, &dive->buddy)) return; if (MATCH("rating.dive", get_rating, &dive->rating)) return; if (MATCH("visibility.dive", get_rating, &dive->visibility)) return; if (MATCH("size.cylinder", cylindersize, &dive->cylinder[cur_cylinder_index].type.size)) return; if (MATCH("workpressure.cylinder", pressure, &dive->cylinder[cur_cylinder_index].type.workingpressure)) return; if (MATCH("description.cylinder", utf8_string, &dive->cylinder[cur_cylinder_index].type.description)) return; if (MATCH("start.cylinder", pressure, &dive->cylinder[cur_cylinder_index].start)) return; if (MATCH("end.cylinder", pressure, &dive->cylinder[cur_cylinder_index].end)) return; if (MATCH("use.cylinder", cylinder_use, &dive->cylinder[cur_cylinder_index].cylinder_use)) return; if (MATCH("description.weightsystem", utf8_string, &dive->weightsystem[cur_ws_index].description)) return; if (MATCH("weight.weightsystem", weight, &dive->weightsystem[cur_ws_index].weight)) return; if (MATCH("weight", weight, &dive->weightsystem[cur_ws_index].weight)) return; if (MATCH("o2", gasmix, &dive->cylinder[cur_cylinder_index].gasmix.o2)) return; if (MATCH("o2percent", gasmix, &dive->cylinder[cur_cylinder_index].gasmix.o2)) return; if (MATCH("n2", gasmix_nitrogen, &dive->cylinder[cur_cylinder_index].gasmix)) return; if (MATCH("he", gasmix, &dive->cylinder[cur_cylinder_index].gasmix.he)) return; if (MATCH("air.divetemperature", temperature, &dive->airtemp)) return; if (MATCH("water.divetemperature", temperature, &dive->watertemp)) return; nonmatch("dive", name, buf); } /* We're in the top-level trip xml. Try to convert whatever value to a trip value */ static void try_to_fill_trip(dive_trip_t **dive_trip_p, const char *name, char *buf) { start_match("trip", name, buf); dive_trip_t *dive_trip = *dive_trip_p; if (MATCH("date", divedate, &dive_trip->when)) return; if (MATCH("time", divetime, &dive_trip->when)) return; if (MATCH("location", utf8_string, &dive_trip->location)) return; if (MATCH("notes", utf8_string, &dive_trip->notes)) return; nonmatch("trip", name, buf); } /* We're processing a divesite entry - try to fill the components */ static void try_to_fill_dive_site(struct dive_site **ds_p, const char *name, char *buf) { start_match("divesite", name, buf); struct dive_site *ds = *ds_p; if (ds->taxonomy.category == NULL) ds->taxonomy.category = alloc_taxonomy(); if (MATCH("uuid", hex_value, &ds->uuid)) return; if (MATCH("name", utf8_string, &ds->name)) return; if (MATCH("description", utf8_string, &ds->description)) return; if (MATCH("notes", utf8_string, &ds->notes)) return; if (MATCH("gps", gps_location, ds)) return; if (MATCH("cat.geo", get_index, (int *)&ds->taxonomy.category[ds->taxonomy.nr].category)) return; if (MATCH("origin.geo", get_index, (int *)&ds->taxonomy.category[ds->taxonomy.nr].origin)) return; if (MATCH("value.geo", utf8_string, &ds->taxonomy.category[ds->taxonomy.nr].value)) { if (ds->taxonomy.nr < TC_NR_CATEGORIES) ds->taxonomy.nr++; return; } nonmatch("divesite", name, buf); } /* * While in some formats file boundaries are dive boundaries, in many * others (as for example in our native format) there are * multiple dives per file, so there can be other events too that * trigger a "new dive" marker and you may get some nesting due * to that. Just ignore nesting levels. * On the flipside it is possible that we start an XML file that ends * up having no dives in it at all - don't create a bogus empty dive * for those. It's not entirely clear what is the minimum set of data * to make a dive valid, but if it has no location, no date and no * samples I'm pretty sure it's useless. */ static bool is_dive(void) { return (cur_dive && (cur_dive->dive_site_uuid || cur_dive->when || cur_dive->dc.samples)); } static void reset_dc_info(struct divecomputer *dc) { lastcns = lastpo2 = lastndl = laststoptime = laststopdepth = lastindeco = 0; lastsensor = lastcylinderindex = 0; } static void reset_dc_settings(void) { free((void *)cur_settings.dc.model); free((void *)cur_settings.dc.nickname); free((void *)cur_settings.dc.serial_nr); free((void *)cur_settings.dc.firmware); cur_settings.dc.model = NULL; cur_settings.dc.nickname = NULL; cur_settings.dc.serial_nr = NULL; cur_settings.dc.firmware = NULL; cur_settings.dc.deviceid = 0; } static void settings_start(void) { in_settings = true; } static void settings_end(void) { in_settings = false; } static void dc_settings_start(void) { reset_dc_settings(); } static void dc_settings_end(void) { create_device_node(cur_settings.dc.model, cur_settings.dc.deviceid, cur_settings.dc.serial_nr, cur_settings.dc.firmware, cur_settings.dc.nickname); reset_dc_settings(); } static void dive_site_start(void) { if (cur_dive_site) return; cur_dive_site = calloc(1, sizeof(struct dive_site)); } static void dive_site_end(void) { if (!cur_dive_site) return; if (cur_dive_site->uuid) { // we intentionally call this with '0' to ensure we get // a new structure and then copy things into that new // structure a few lines below (which sets the correct // uuid) struct dive_site *ds = alloc_or_get_dive_site(0); if (cur_dive_site->taxonomy.nr == 0) { free(cur_dive_site->taxonomy.category); cur_dive_site->taxonomy.category = NULL; } copy_dive_site(cur_dive_site, ds); if (verbose > 3) printf("completed dive site uuid %x8 name {%s}\n", ds->uuid, ds->name); } free_taxonomy(&cur_dive_site->taxonomy); free(cur_dive_site); cur_dive_site = NULL; } // now we need to add the code to parse the parts of the divesite enry static void dive_start(void) { if (cur_dive) return; cur_dive = alloc_dive(); reset_dc_info(&cur_dive->dc); memset(&cur_tm, 0, sizeof(cur_tm)); if (cur_trip) { add_dive_to_trip(cur_dive, cur_trip); cur_dive->tripflag = IN_TRIP; } } static void dive_end(void) { if (!cur_dive) return; if (!is_dive()) free(cur_dive); else record_dive_to_table(cur_dive, target_table); cur_dive = NULL; cur_dc = NULL; cur_latitude.udeg = 0; cur_longitude.udeg = 0; cur_cylinder_index = 0; cur_ws_index = 0; } static void trip_start(void) { if (cur_trip) return; dive_end(); cur_trip = calloc(1, sizeof(dive_trip_t)); memset(&cur_tm, 0, sizeof(cur_tm)); } static void trip_end(void) { if (!cur_trip) return; insert_trip(&cur_trip); cur_trip = NULL; } static void event_start(void) { memset(&cur_event, 0, sizeof(cur_event)); cur_event.deleted = 0; /* Active */ } static void event_end(void) { struct divecomputer *dc = get_dc(); if (strcmp(cur_event.name, "surface") != 0) { /* 123 is a magic event that we used for a while to encode images in dives */ if (cur_event.type == 123) { struct picture *pic = alloc_picture(); pic->filename = strdup(cur_event.name); /* theoretically this could fail - but we didn't support multi year offsets */ pic->offset.seconds = cur_event.time.seconds; dive_add_picture(cur_dive, pic); } else { struct event *ev; /* At some point gas change events did not have any type. Thus we need to add * one on import, if we encounter the type one missing. */ if (cur_event.type == 0 && strcmp(cur_event.name, "gaschange") == 0) cur_event.type = cur_event.value >> 16 > 0 ? SAMPLE_EVENT_GASCHANGE2 : SAMPLE_EVENT_GASCHANGE; ev = add_event(dc, cur_event.time.seconds, cur_event.type, cur_event.flags, cur_event.value, cur_event.name); if (ev && event_is_gaschange(ev)) { /* See try_to_fill_event() on why the filled-in index is one too big */ ev->gas.index = cur_event.gas.index-1; if (cur_event.gas.mix.o2.permille || cur_event.gas.mix.he.permille) ev->gas.mix = cur_event.gas.mix; } } } cur_event.deleted = 1; /* No longer active */ } static void picture_start(void) { cur_picture = alloc_picture(); } static void picture_end(void) { dive_add_picture(cur_dive, cur_picture); cur_picture = NULL; } static void cylinder_start(void) { } static void cylinder_end(void) { cur_cylinder_index++; } static void ws_start(void) { } static void ws_end(void) { cur_ws_index++; } static void sample_start(void) { cur_sample = prepare_sample(get_dc()); cur_sample->ndl.seconds = lastndl; cur_sample->in_deco = lastindeco; cur_sample->stoptime.seconds = laststoptime; cur_sample->stopdepth.mm = laststopdepth; cur_sample->cns = lastcns; cur_sample->setpoint.mbar = lastpo2; cur_sample->sensor = lastsensor; next_o2_sensor = 0; } static void sample_end(void) { if (!cur_dive) return; finish_sample(get_dc()); lastndl = cur_sample->ndl.seconds; lastindeco = cur_sample->in_deco; laststoptime = cur_sample->stoptime.seconds; laststopdepth = cur_sample->stopdepth.mm; lastcns = cur_sample->cns; lastpo2 = cur_sample->setpoint.mbar; cur_sample = NULL; } static void divecomputer_start(void) { struct divecomputer *dc; /* Start from the previous dive computer */ dc = &cur_dive->dc; while (dc->next) dc = dc->next; /* Did we already fill that in? */ if (dc->samples || dc->model || dc->when) { struct divecomputer *newdc = calloc(1, sizeof(*newdc)); if (newdc) { dc->next = newdc; dc = newdc; } } /* .. this is the one we'll use */ cur_dc = dc; reset_dc_info(dc); } static void divecomputer_end(void) { if (!cur_dc->when) cur_dc->when = cur_dive->when; cur_dc = NULL; } static void userid_start(void) { in_userid = true; set_save_userid_local(true); //if the xml contains userid, keep saving it. } static void userid_stop(void) { in_userid = false; } static bool entry(const char *name, char *buf) { if (!strncmp(name, "version.program", sizeof("version.program") - 1) || !strncmp(name, "version.divelog", sizeof("version.divelog") - 1)) { last_xml_version = atoi(buf); report_datafile_version(last_xml_version); } if (in_userid) { try_to_fill_userid(name, buf); return true; } if (in_settings) { try_to_fill_dc_settings(name, buf); try_to_match_autogroup(name, buf); return true; } if (cur_dive_site) { try_to_fill_dive_site(&cur_dive_site, name, buf); return true; } if (!cur_event.deleted) { try_to_fill_event(name, buf); return true; } if (cur_sample) { try_to_fill_sample(cur_sample, name, buf); return true; } if (cur_dc) { try_to_fill_dc(cur_dc, name, buf); return true; } if (cur_dive) { try_to_fill_dive(cur_dive, name, buf); return true; } if (cur_trip) { try_to_fill_trip(&cur_trip, name, buf); return true; } return true; } static const char *nodename(xmlNode *node, char *buf, int len) { int levels = 2; char *p = buf; if (!node || (node->type != XML_CDATA_SECTION_NODE && !node->name)) { return "root"; } if (node->type == XML_CDATA_SECTION_NODE || (node->parent && !strcmp((const char *)node->name, "text"))) node = node->parent; /* Make sure it's always NUL-terminated */ p[--len] = 0; for (;;) { const char *name = (const char *)node->name; char c; while ((c = *name++) != 0) { /* Cheaper 'tolower()' for ASCII */ c = (c >= 'A' && c <= 'Z') ? c - 'A' + 'a' : c; *p++ = c; if (!--len) return buf; } *p = 0; node = node->parent; if (!node || !node->name) return buf; *p++ = '.'; if (!--len) return buf; if (!--levels) return buf; } } #define MAXNAME 32 static bool visit_one_node(xmlNode *node) { xmlChar *content; static char buffer[MAXNAME]; const char *name; content = node->content; if (!content || xmlIsBlankNode(node)) return true; name = nodename(node, buffer, sizeof(buffer)); return entry(name, (char *)content); } static bool traverse(xmlNode *root); static bool traverse_properties(xmlNode *node) { xmlAttr *p; bool ret = true; for (p = node->properties; p; p = p->next) if ((ret = traverse(p->children)) == false) break; return ret; } static bool visit(xmlNode *n) { return visit_one_node(n) && traverse_properties(n) && traverse(n->children); } static void DivingLog_importer(void) { import_source = DIVINGLOG; /* * Diving Log units are really strange. * * Temperatures are in C, except in samples, * when they are in Fahrenheit. Depths are in * meters, an dpressure is in PSI in the samples, * but in bar when it comes to working pressure. * * Crazy f*%^ morons. */ xml_parsing_units = SI_units; } static void uddf_importer(void) { import_source = UDDF; xml_parsing_units = SI_units; xml_parsing_units.pressure = PASCAL; xml_parsing_units.temperature = KELVIN; } static void subsurface_webservice(void) { import_source = SSRF_WS; } /* * I'm sure this could be done as some fancy DTD rules. * It's just not worth the headache. */ static struct nesting { const char *name; void (*start)(void), (*end)(void); } nesting[] = { { "divecomputerid", dc_settings_start, dc_settings_end }, { "settings", settings_start, settings_end }, { "site", dive_site_start, dive_site_end }, { "dive", dive_start, dive_end }, { "Dive", dive_start, dive_end }, { "trip", trip_start, trip_end }, { "sample", sample_start, sample_end }, { "waypoint", sample_start, sample_end }, { "SAMPLE", sample_start, sample_end }, { "reading", sample_start, sample_end }, { "event", event_start, event_end }, { "mix", cylinder_start, cylinder_end }, { "gasmix", cylinder_start, cylinder_end }, { "cylinder", cylinder_start, cylinder_end }, { "weightsystem", ws_start, ws_end }, { "divecomputer", divecomputer_start, divecomputer_end }, { "P", sample_start, sample_end }, { "userid", userid_start, userid_stop}, { "picture", picture_start, picture_end }, { "extradata", extra_data_start, extra_data_end }, /* Import type recognition */ { "Divinglog", DivingLog_importer }, { "uddf", uddf_importer }, { "output", subsurface_webservice }, { NULL, } }; static bool traverse(xmlNode *root) { xmlNode *n; bool ret = true; for (n = root; n; n = n->next) { struct nesting *rule = nesting; if (!n->name) { if ((ret = visit(n)) == false) break; continue; } do { if (!strcmp(rule->name, (const char *)n->name)) break; rule++; } while (rule->name); if (rule->start) rule->start(); if ((ret = visit(n)) == false) break; if (rule->end) rule->end(); } return ret; } /* Per-file reset */ static void reset_all(void) { /* * We reset the units for each file. You'd think it was * a per-dive property, but I'm not going to trust people * to do per-dive setup. If the xml does have per-dive * data within one file, we might have to reset it per * dive for that format. */ xml_parsing_units = SI_units; import_source = UNKNOWN; } /* divelog.de sends us xml files that claim to be iso-8859-1 * but once we decode the HTML encoded characters they turn * into UTF-8 instead. So skip the incorrect encoding * declaration and decode the HTML encoded characters */ const char *preprocess_divelog_de(const char *buffer) { char *ret = strstr(buffer, ""); if (ret) { xmlParserCtxtPtr ctx; char buf[] = ""; int i; for (i = 0; i < strlen(ret); ++i) if (!isascii(ret[i])) return buffer; ctx = xmlCreateMemoryParserCtxt(buf, sizeof(buf)); ret = (char *)xmlStringLenDecodeEntities(ctx, (xmlChar *)ret, strlen(ret), XML_SUBSTITUTE_REF, 0, 0, 0); return ret; } return buffer; } int parse_xml_buffer(const char *url, const char *buffer, int size, struct dive_table *table, const char **params) { xmlDoc *doc; const char *res = preprocess_divelog_de(buffer); int ret = 0; target_table = table; doc = xmlReadMemory(res, strlen(res), url, NULL, 0); if (res != buffer) free((char *)res); if (!doc) return report_error(translate("gettextFromC", "Failed to parse '%s'"), url); set_save_userid_local(false); set_userid(""); reset_all(); dive_start(); doc = test_xslt_transforms(doc, params); if (!traverse(xmlDocGetRootElement(doc))) { // we decided to give up on parsing... why? ret = -1; } dive_end(); xmlFreeDoc(doc); return ret; } void parse_mkvi_buffer(struct membuffer *txt, struct membuffer *csv, const char *starttime) { dive_start(); divedate(starttime, &cur_dive->when); dive_end(); } extern int dm4_events(void *handle, int columns, char **data, char **column) { event_start(); if (data[1]) cur_event.time.seconds = atoi(data[1]); if (data[2]) { switch (atoi(data[2])) { case 1: /* 1 Mandatory Safety Stop */ strcpy(cur_event.name, "safety stop (mandatory)"); break; case 3: /* 3 Deco */ /* What is Subsurface's term for going to * deco? */ strcpy(cur_event.name, "deco"); break; case 4: /* 4 Ascent warning */ strcpy(cur_event.name, "ascent"); break; case 5: /* 5 Ceiling broken */ strcpy(cur_event.name, "violation"); break; case 6: /* 6 Mandatory safety stop ceiling error */ strcpy(cur_event.name, "violation"); break; case 7: /* 7 Below deco floor */ strcpy(cur_event.name, "below floor"); break; case 8: /* 8 Dive time alarm */ strcpy(cur_event.name, "divetime"); break; case 9: /* 9 Depth alarm */ strcpy(cur_event.name, "maxdepth"); break; case 10: /* 10 OLF 80% */ case 11: /* 11 OLF 100% */ strcpy(cur_event.name, "OLF"); break; case 12: /* 12 High pO₂ */ strcpy(cur_event.name, "PO2"); break; case 13: /* 13 Air time */ strcpy(cur_event.name, "airtime"); break; case 17: /* 17 Ascent warning */ strcpy(cur_event.name, "ascent"); break; case 18: /* 18 Ceiling error */ strcpy(cur_event.name, "ceiling"); break; case 19: /* 19 Surfaced */ strcpy(cur_event.name, "surface"); break; case 20: /* 20 Deco */ strcpy(cur_event.name, "deco"); break; case 22: case 32: /* 22 Mandatory safety stop violation */ /* 32 Deep stop violation */ strcpy(cur_event.name, "violation"); break; case 30: /* Tissue level warning */ strcpy(cur_event.name, "tissue warning"); break; case 37: /* Tank pressure alarm */ strcpy(cur_event.name, "tank pressure"); break; case 257: /* 257 Dive active */ /* This seems to be given after surface when * descending again. */ strcpy(cur_event.name, "surface"); break; case 258: /* 258 Bookmark */ if (data[3]) { strcpy(cur_event.name, "heading"); cur_event.value = atoi(data[3]); } else { strcpy(cur_event.name, "bookmark"); } break; case 259: /* Deep stop */ strcpy(cur_event.name, "Deep stop"); break; case 260: /* Deep stop */ strcpy(cur_event.name, "Deep stop cleared"); break; case 266: /* Mandatory safety stop activated */ strcpy(cur_event.name, "safety stop (mandatory)"); break; case 267: /* Mandatory safety stop deactivated */ /* DM5 shows this only on event list, not on the * profile so skipping as well for now */ break; default: strcpy(cur_event.name, "unknown"); cur_event.value = atoi(data[2]); break; } } event_end(); return 0; } extern int dm5_cylinders(void *handle, int columns, char **data, char **column) { cylinder_start(); if (data[7] && atoi(data[7]) > 0 && atoi(data[7]) < 350000) cur_dive->cylinder[cur_cylinder_index].start.mbar = atoi(data[7]); if (data[8] && atoi(data[8]) > 0 && atoi(data[8]) < 350000) cur_dive->cylinder[cur_cylinder_index].end.mbar = (atoi(data[8])); if (data[6]) { /* DM5 shows tank size of 12 liters when the actual * value is 0 (and using metric units). So we just use * the same 12 liters when size is not available */ if (atof(data[6]) == 0.0 && cur_dive->cylinder[cur_cylinder_index].start.mbar) cur_dive->cylinder[cur_cylinder_index].type.size.mliter = 12000; else cur_dive->cylinder[cur_cylinder_index].type.size.mliter = (atof(data[6])) * 1000; } if (data[2]) cur_dive->cylinder[cur_cylinder_index].gasmix.o2.permille = atoi(data[2]) * 10; if (data[3]) cur_dive->cylinder[cur_cylinder_index].gasmix.he.permille = atoi(data[3]) * 10; cylinder_end(); return 0; } extern int dm5_gaschange(void *handle, int columns, char **data, char **column) { event_start(); if (data[0]) cur_event.time.seconds = atoi(data[0]); if (data[1]) { strcpy(cur_event.name, "gaschange"); cur_event.value = atof(data[1]); } event_end(); return 0; } extern int dm4_tags(void *handle, int columns, char **data, char **column) { if (data[0]) taglist_add_tag(&cur_dive->tag_list, data[0]); return 0; } extern int dm4_dive(void *param, int columns, char **data, char **column) { int i, interval, retval = 0; sqlite3 *handle = (sqlite3 *)param; float *profileBlob; unsigned char *tempBlob; int *pressureBlob; char *err = NULL; char get_events_template[] = "select * from Mark where DiveId = %d"; char get_tags_template[] = "select Text from DiveTag where DiveId = %d"; char get_events[64]; dive_start(); cur_dive->number = atoi(data[0]); cur_dive->when = (time_t)(atol(data[1])); if (data[2]) utf8_string(data[2], &cur_dive->notes); /* * DM4 stores Duration and DiveTime. It looks like DiveTime is * 10 to 60 seconds shorter than Duration. However, I have no * idea what is the difference and which one should be used. * Duration = data[3] * DiveTime = data[15] */ if (data[3]) cur_dive->duration.seconds = atoi(data[3]); if (data[15]) cur_dive->dc.duration.seconds = atoi(data[15]); /* * TODO: the deviceid hash should be calculated here. */ settings_start(); dc_settings_start(); if (data[4]) utf8_string(data[4], &cur_settings.dc.serial_nr); if (data[5]) utf8_string(data[5], &cur_settings.dc.model); cur_settings.dc.deviceid = 0xffffffff; dc_settings_end(); settings_end(); if (data[6]) cur_dive->dc.maxdepth.mm = atof(data[6]) * 1000; if (data[8]) cur_dive->dc.airtemp.mkelvin = C_to_mkelvin(atoi(data[8])); if (data[9]) cur_dive->dc.watertemp.mkelvin = C_to_mkelvin(atoi(data[9])); /* * TODO: handle multiple cylinders */ cylinder_start(); if (data[22] && atoi(data[22]) > 0) cur_dive->cylinder[cur_cylinder_index].start.mbar = atoi(data[22]); else if (data[10] && atoi(data[10]) > 0) cur_dive->cylinder[cur_cylinder_index].start.mbar = atoi(data[10]); if (data[23] && atoi(data[23]) > 0) cur_dive->cylinder[cur_cylinder_index].end.mbar = (atoi(data[23])); if (data[11] && atoi(data[11]) > 0) cur_dive->cylinder[cur_cylinder_index].end.mbar = (atoi(data[11])); if (data[12]) cur_dive->cylinder[cur_cylinder_index].type.size.mliter = (atof(data[12])) * 1000; if (data[13]) cur_dive->cylinder[cur_cylinder_index].type.workingpressure.mbar = (atoi(data[13])); if (data[20]) cur_dive->cylinder[cur_cylinder_index].gasmix.o2.permille = atoi(data[20]) * 10; if (data[21]) cur_dive->cylinder[cur_cylinder_index].gasmix.he.permille = atoi(data[21]) * 10; cylinder_end(); if (data[14]) cur_dive->dc.surface_pressure.mbar = (atoi(data[14]) * 1000); interval = data[16] ? atoi(data[16]) : 0; profileBlob = (float *)data[17]; tempBlob = (unsigned char *)data[18]; pressureBlob = (int *)data[19]; for (i = 0; interval && i * interval < cur_dive->duration.seconds; i++) { sample_start(); cur_sample->time.seconds = i * interval; if (profileBlob) cur_sample->depth.mm = profileBlob[i] * 1000; else cur_sample->depth.mm = cur_dive->dc.maxdepth.mm; if (data[18] && data[18][0]) cur_sample->temperature.mkelvin = C_to_mkelvin(tempBlob[i]); if (data[19] && data[19][0]) cur_sample->cylinderpressure.mbar = pressureBlob[i]; sample_end(); } snprintf(get_events, sizeof(get_events) - 1, get_events_template, cur_dive->number); retval = sqlite3_exec(handle, get_events, &dm4_events, 0, &err); if (retval != SQLITE_OK) { fprintf(stderr, "%s", "Database query dm4_events failed.\n"); return 1; } snprintf(get_events, sizeof(get_events) - 1, get_tags_template, cur_dive->number); retval = sqlite3_exec(handle, get_events, &dm4_tags, 0, &err); if (retval != SQLITE_OK) { fprintf(stderr, "%s", "Database query dm4_tags failed.\n"); return 1; } dive_end(); /* for (i=0; inumber = atoi(data[0]); cur_dive->when = (time_t)(atol(data[1])); if (data[2]) utf8_string(data[2], &cur_dive->notes); if (data[3]) cur_dive->duration.seconds = atoi(data[3]); if (data[15]) cur_dive->dc.duration.seconds = atoi(data[15]); /* * TODO: the deviceid hash should be calculated here. */ settings_start(); dc_settings_start(); if (data[4]) { utf8_string(data[4], &cur_settings.dc.serial_nr); cur_settings.dc.deviceid = atoi(data[4]); } if (data[5]) utf8_string(data[5], &cur_settings.dc.model); dc_settings_end(); settings_end(); if (data[6]) cur_dive->dc.maxdepth.mm = atof(data[6]) * 1000; if (data[8]) cur_dive->dc.airtemp.mkelvin = C_to_mkelvin(atoi(data[8])); if (data[9]) cur_dive->dc.watertemp.mkelvin = C_to_mkelvin(atoi(data[9])); if (data[4]) { cur_dive->dc.deviceid = atoi(data[4]); } if (data[5]) utf8_string(data[5], &cur_dive->dc.model); snprintf(get_events, sizeof(get_events) - 1, get_cylinders_template, cur_dive->number); retval = sqlite3_exec(handle, get_events, &dm5_cylinders, 0, &err); if (retval != SQLITE_OK) { fprintf(stderr, "%s", "Database query dm5_cylinders failed.\n"); return 1; } if (data[14]) cur_dive->dc.surface_pressure.mbar = (atoi(data[14]) / 100); interval = data[16] ? atoi(data[16]) : 0; sampleBlob = (unsigned const char *)data[24]; if (sampleBlob) { switch (sampleBlob[0]) { case 2: block_size = 19; break; case 3: block_size = 23; break; default: block_size = 16; break; } } for (i = 0; interval && sampleBlob && i * interval < cur_dive->duration.seconds; i++) { float *depth = (float *)&sampleBlob[i * block_size + 3]; int32_t temp = (sampleBlob[i * block_size + 10] << 8) + sampleBlob[i * block_size + 11]; int32_t pressure = (sampleBlob[i * block_size + 9] << 16) + (sampleBlob[i * block_size + 8] << 8) + sampleBlob[i * block_size + 7]; sample_start(); cur_sample->time.seconds = i * interval; cur_sample->depth.mm = depth[0] * 1000; /* * Limit temperatures and cylinder pressures to somewhat * sensible values */ if (temp >= -10 && temp < 50) cur_sample->temperature.mkelvin = C_to_mkelvin(temp); if (pressure >= 0 && pressure < 350000) cur_sample->cylinderpressure.mbar = pressure; sample_end(); } /* * Log was converted from DM4, thus we need to parse the profile * from DM4 format */ if (i == 0) { float *profileBlob; unsigned char *tempBlob; int *pressureBlob; profileBlob = (float *)data[17]; tempBlob = (unsigned char *)data[18]; pressureBlob = (int *)data[19]; for (i = 0; interval && i * interval < cur_dive->duration.seconds; i++) { sample_start(); cur_sample->time.seconds = i * interval; if (profileBlob) cur_sample->depth.mm = profileBlob[i] * 1000; else cur_sample->depth.mm = cur_dive->dc.maxdepth.mm; if (data[18] && data[18][0]) cur_sample->temperature.mkelvin = C_to_mkelvin(tempBlob[i]); if (data[19] && data[19][0]) cur_sample->cylinderpressure.mbar = pressureBlob[i]; sample_end(); } } snprintf(get_events, sizeof(get_events) - 1, get_gaschange_template, cur_dive->number); retval = sqlite3_exec(handle, get_events, &dm5_gaschange, 0, &err); if (retval != SQLITE_OK) { fprintf(stderr, "%s", "Database query dm5_gaschange failed.\n"); return 1; } snprintf(get_events, sizeof(get_events) - 1, get_events_template, cur_dive->number); retval = sqlite3_exec(handle, get_events, &dm4_events, 0, &err); if (retval != SQLITE_OK) { fprintf(stderr, "%s", "Database query dm4_events failed.\n"); return 1; } snprintf(get_events, sizeof(get_events) - 1, get_tags_template, cur_dive->number); retval = sqlite3_exec(handle, get_events, &dm4_tags, 0, &err); if (retval != SQLITE_OK) { fprintf(stderr, "%s", "Database query dm4_tags failed.\n"); return 1; } dive_end(); return SQLITE_OK; } int parse_dm4_buffer(sqlite3 *handle, const char *url, const char *buffer, int size, struct dive_table *table) { int retval; char *err = NULL; target_table = table; /* StartTime is converted from Suunto's nano seconds to standard * time. We also need epoch, not seconds since year 1. */ char get_dives[] = "select D.DiveId,StartTime/10000000-62135596800,Note,Duration,SourceSerialNumber,Source,MaxDepth,SampleInterval,StartTemperature,BottomTemperature,D.StartPressure,D.EndPressure,Size,CylinderWorkPressure,SurfacePressure,DiveTime,SampleInterval,ProfileBlob,TemperatureBlob,PressureBlob,Oxygen,Helium,MIX.StartPressure,MIX.EndPressure FROM Dive AS D JOIN DiveMixture AS MIX ON D.DiveId=MIX.DiveId"; retval = sqlite3_exec(handle, get_dives, &dm4_dive, handle, &err); if (retval != SQLITE_OK) { fprintf(stderr, "Database query failed '%s'.\n", url); return 1; } return 0; } int parse_dm5_buffer(sqlite3 *handle, const char *url, const char *buffer, int size, struct dive_table *table) { int retval; char *err = NULL; target_table = table; /* StartTime is converted from Suunto's nano seconds to standard * time. We also need epoch, not seconds since year 1. */ char get_dives[] = "select DiveId,StartTime/10000000-62135596800,Note,Duration,coalesce(SourceSerialNumber,SerialNumber),Source,MaxDepth,SampleInterval,StartTemperature,BottomTemperature,StartPressure,EndPressure,'','',SurfacePressure,DiveTime,SampleInterval,ProfileBlob,TemperatureBlob,PressureBlob,'','','','',SampleBlob FROM Dive where Deleted is null"; retval = sqlite3_exec(handle, get_dives, &dm5_dive, handle, &err); if (retval != SQLITE_OK) { fprintf(stderr, "Database query failed '%s'.\n", url); return 1; } return 0; } extern int shearwater_cylinders(void *handle, int columns, char **data, char **column) { cylinder_start(); if (data[0]) cur_dive->cylinder[cur_cylinder_index].gasmix.o2.permille = atof(data[0]) * 1000; if (data[1]) cur_dive->cylinder[cur_cylinder_index].gasmix.he.permille = atof(data[1]) * 1000; cylinder_end(); return 0; } extern int shearwater_changes(void *handle, int columns, char **data, char **column) { event_start(); if (data[0]) cur_event.time.seconds = atoi(data[0]); if (data[1]) { strcpy(cur_event.name, "gaschange"); cur_event.value = atof(data[1]) * 100; } event_end(); return 0; } extern int cobalt_profile_sample(void *handle, int columns, char **data, char **column) { sample_start(); if (data[0]) cur_sample->time.seconds = atoi(data[0]); if (data[1]) cur_sample->depth.mm = atoi(data[1]); if (data[2]) cur_sample->temperature.mkelvin = metric ? C_to_mkelvin(atof(data[2])) : F_to_mkelvin(atof(data[2])); sample_end(); return 0; } extern int shearwater_profile_sample(void *handle, int columns, char **data, char **column) { sample_start(); if (data[0]) cur_sample->time.seconds = atoi(data[0]); if (data[1]) cur_sample->depth.mm = metric ? atof(data[1]) * 1000 : feet_to_mm(atof(data[1])); if (data[2]) cur_sample->temperature.mkelvin = metric ? C_to_mkelvin(atof(data[2])) : F_to_mkelvin(atof(data[2])); if (data[3]) { cur_sample->setpoint.mbar = atof(data[3]) * 1000; cur_dive->dc.divemode = CCR; } if (data[4]) cur_sample->ndl.seconds = atoi(data[4]) * 60; if (data[5]) cur_sample->cns = atoi(data[5]); if (data[6]) cur_sample->stopdepth.mm = metric ? atoi(data[6]) * 1000 : feet_to_mm(atoi(data[6])); /* We don't actually have data[3], but it should appear in the * SQL query at some point. if (data[3]) cur_sample->cylinderpressure.mbar = metric ? atoi(data[3]) * 1000 : psi_to_mbar(atoi(data[3])); */ sample_end(); return 0; } extern int shearwater_dive(void *param, int columns, char **data, char **column) { int retval = 0; sqlite3 *handle = (sqlite3 *)param; char *err = NULL; char get_profile_template[] = "select currentTime,currentDepth,waterTemp,averagePPO2,currentNdl,CNSPercent,decoCeiling from dive_log_records where diveLogId = %d"; char get_cylinder_template[] = "select fractionO2,fractionHe from dive_log_records where diveLogId = %d group by fractionO2,fractionHe"; char get_changes_template[] = "select a.currentTime,a.fractionO2,a.fractionHe from dive_log_records as a,dive_log_records as b where a.diveLogId = %d and b.diveLogId = %d and (a.id - 1) = b.id and (a.fractionO2 != b.fractionO2 or a.fractionHe != b.fractionHe) union select min(currentTime),fractionO2,fractionHe from dive_log_records"; char get_buffer[1024]; dive_start(); cur_dive->number = atoi(data[0]); cur_dive->when = (time_t)(atol(data[1])); if (data[2]) add_dive_site(data[2], cur_dive); if (data[3]) utf8_string(data[3], &cur_dive->buddy); if (data[4]) utf8_string(data[4], &cur_dive->notes); metric = atoi(data[5]) == 1 ? 0 : 1; /* TODO: verify that metric calculation is correct */ if (data[6]) cur_dive->dc.maxdepth.mm = metric ? atof(data[6]) * 1000 : feet_to_mm(atof(data[6])); if (data[7]) cur_dive->dc.duration.seconds = atoi(data[7]) * 60; if (data[8]) cur_dive->dc.surface_pressure.mbar = atoi(data[8]); /* * TODO: the deviceid hash should be calculated here. */ settings_start(); dc_settings_start(); if (data[9]) utf8_string(data[9], &cur_settings.dc.serial_nr); if (data[10]) utf8_string(data[10], &cur_settings.dc.model); cur_settings.dc.deviceid = 0xffffffff; dc_settings_end(); settings_end(); snprintf(get_buffer, sizeof(get_buffer) - 1, get_cylinder_template, cur_dive->number); retval = sqlite3_exec(handle, get_buffer, &shearwater_cylinders, 0, &err); if (retval != SQLITE_OK) { fprintf(stderr, "%s", "Database query shearwater_cylinders failed.\n"); return 1; } snprintf(get_buffer, sizeof(get_buffer) - 1, get_changes_template, cur_dive->number, cur_dive->number); retval = sqlite3_exec(handle, get_buffer, &shearwater_changes, 0, &err); if (retval != SQLITE_OK) { fprintf(stderr, "%s", "Database query shearwater_changes failed.\n"); return 1; } snprintf(get_buffer, sizeof(get_buffer) - 1, get_profile_template, cur_dive->number); retval = sqlite3_exec(handle, get_buffer, &shearwater_profile_sample, 0, &err); if (retval != SQLITE_OK) { fprintf(stderr, "%s", "Database query shearwater_profile_sample failed.\n"); return 1; } dive_end(); return SQLITE_OK; } extern int cobalt_cylinders(void *handle, int columns, char **data, char **column) { cylinder_start(); if (data[0]) cur_dive->cylinder[cur_cylinder_index].gasmix.o2.permille = atoi(data[0]) * 10; if (data[1]) cur_dive->cylinder[cur_cylinder_index].gasmix.he.permille = atoi(data[1]) * 10; if (data[2]) cur_dive->cylinder[cur_cylinder_index].start.mbar = psi_to_mbar(atoi(data[2])); if (data[3]) cur_dive->cylinder[cur_cylinder_index].end.mbar = psi_to_mbar(atoi(data[3])); if (data[4]) cur_dive->cylinder[cur_cylinder_index].type.size.mliter = atoi(data[4]) * 100; if (data[5]) cur_dive->cylinder[cur_cylinder_index].gas_used.mliter = atoi(data[5]) * 1000; cylinder_end(); return 0; } extern int cobalt_buddies(void *handle, int columns, char **data, char **column) { if (data[0]) utf8_string(data[0], &cur_dive->buddy); return 0; } /* * We still need to figure out how to map free text visibility to * Subsurface star rating. */ extern int cobalt_visibility(void *handle, int columns, char **data, char **column) { return 0; } extern int cobalt_location(void *handle, int columns, char **data, char **column) { static char *location = NULL; if (data[0]) { if (location) { char *tmp = malloc(strlen(location) + strlen(data[0]) + 4); if (!tmp) return -1; sprintf(tmp, "%s / %s", location, data[0]); free(location); location = NULL; cur_dive->dive_site_uuid = find_or_create_dive_site_with_name(tmp, cur_dive->when); free(tmp); } else { location = strdup(data[0]); } } return 0; } extern int cobalt_dive(void *param, int columns, char **data, char **column) { int retval = 0; sqlite3 *handle = (sqlite3 *)param; char *err = NULL; char get_profile_template[] = "select runtime*60,(DepthPressure*10000/SurfacePressure)-10000,p.Temperature from Dive AS d JOIN TrackPoints AS p ON d.Id=p.DiveId where d.Id=%d"; char get_cylinder_template[] = "select FO2,FHe,StartingPressure,EndingPressure,TankSize,TankPressure,TotalConsumption from GasMixes where DiveID=%d and StartingPressure>0 group by FO2,FHe"; char get_buddy_template[] = "select l.Data from Items AS i, List AS l ON i.Value1=l.Id where i.DiveId=%d and l.Type=4"; char get_visibility_template[] = "select l.Data from Items AS i, List AS l ON i.Value1=l.Id where i.DiveId=%d and l.Type=3"; char get_location_template[] = "select l.Data from Items AS i, List AS l ON i.Value1=l.Id where i.DiveId=%d and l.Type=0"; char get_site_template[] = "select l.Data from Items AS i, List AS l ON i.Value1=l.Id where i.DiveId=%d and l.Type=1"; char get_buffer[1024]; dive_start(); cur_dive->number = atoi(data[0]); cur_dive->when = (time_t)(atol(data[1])); if (data[4]) utf8_string(data[4], &cur_dive->notes); /* data[5] should have information on Units used, but I cannot * parse it at all based on the sample log I have received. The * temperatures in the samples are all Imperial, so let's go by * that. */ metric = 0; /* Cobalt stores the pressures, not the depth */ if (data[6]) cur_dive->dc.maxdepth.mm = atoi(data[6]); if (data[7]) cur_dive->dc.duration.seconds = atoi(data[7]); if (data[8]) cur_dive->dc.surface_pressure.mbar = atoi(data[8]); /* * TODO: the deviceid hash should be calculated here. */ settings_start(); dc_settings_start(); if (data[9]) { utf8_string(data[9], &cur_settings.dc.serial_nr); cur_settings.dc.deviceid = atoi(data[9]); cur_settings.dc.model = strdup("Cobalt import"); } dc_settings_end(); settings_end(); if (data[9]) { cur_dive->dc.deviceid = atoi(data[9]); cur_dive->dc.model = strdup("Cobalt import"); } snprintf(get_buffer, sizeof(get_buffer) - 1, get_cylinder_template, cur_dive->number); retval = sqlite3_exec(handle, get_buffer, &cobalt_cylinders, 0, &err); if (retval != SQLITE_OK) { fprintf(stderr, "%s", "Database query cobalt_cylinders failed.\n"); return 1; } snprintf(get_buffer, sizeof(get_buffer) - 1, get_buddy_template, cur_dive->number); retval = sqlite3_exec(handle, get_buffer, &cobalt_buddies, 0, &err); if (retval != SQLITE_OK) { fprintf(stderr, "%s", "Database query cobalt_buddies failed.\n"); return 1; } snprintf(get_buffer, sizeof(get_buffer) - 1, get_visibility_template, cur_dive->number); retval = sqlite3_exec(handle, get_buffer, &cobalt_visibility, 0, &err); if (retval != SQLITE_OK) { fprintf(stderr, "%s", "Database query cobalt_visibility failed.\n"); return 1; } snprintf(get_buffer, sizeof(get_buffer) - 1, get_location_template, cur_dive->number); retval = sqlite3_exec(handle, get_buffer, &cobalt_location, 0, &err); if (retval != SQLITE_OK) { fprintf(stderr, "%s", "Database query cobalt_location failed.\n"); return 1; } snprintf(get_buffer, sizeof(get_buffer) - 1, get_site_template, cur_dive->number); retval = sqlite3_exec(handle, get_buffer, &cobalt_location, 0, &err); if (retval != SQLITE_OK) { fprintf(stderr, "%s", "Database query cobalt_location (site) failed.\n"); return 1; } snprintf(get_buffer, sizeof(get_buffer) - 1, get_profile_template, cur_dive->number); retval = sqlite3_exec(handle, get_buffer, &cobalt_profile_sample, 0, &err); if (retval != SQLITE_OK) { fprintf(stderr, "%s", "Database query cobalt_profile_sample failed.\n"); return 1; } dive_end(); return SQLITE_OK; } int parse_shearwater_buffer(sqlite3 *handle, const char *url, const char *buffer, int size, struct dive_table *table) { int retval; char *err = NULL; target_table = table; char get_dives[] = "select i.diveId,timestamp,location||' / '||site,buddy,notes,imperialUnits,maxDepth,maxTime,startSurfacePressure,computerSerial,computerModel FROM dive_info AS i JOIN dive_logs AS l ON i.diveId=l.diveId"; retval = sqlite3_exec(handle, get_dives, &shearwater_dive, handle, &err); if (retval != SQLITE_OK) { fprintf(stderr, "Database query failed '%s'.\n", url); return 1; } return 0; } int parse_cobalt_buffer(sqlite3 *handle, const char *url, const char *buffer, int size, struct dive_table *table) { int retval; char *err = NULL; target_table = table; char get_dives[] = "select Id,strftime('%s',DiveStartTime),LocationId,'buddy','notes',Units,(MaxDepthPressure*10000/SurfacePressure)-10000,DiveMinutes,SurfacePressure,SerialNumber,'model' from Dive where IsViewDeleted = 0"; retval = sqlite3_exec(handle, get_dives, &cobalt_dive, handle, &err); if (retval != SQLITE_OK) { fprintf(stderr, "Database query failed '%s'.\n", url); return 1; } return 0; } extern int divinglog_cylinder(void *handle, int columns, char **data, char **column) { short dbl = 1; //char get_cylinder_template[] = "select TankID,TankSize,PresS,PresE,PresW,O2,He,DblTank from Tank where LogID = %d"; /* * Divinglog might have more cylinders than what we support. So * better to ignore those. */ if (cur_cylinder_index >= MAX_CYLINDERS) return 0; if (data[7] && atoi(data[7]) > 0) dbl = 2; cylinder_start(); /* * Assuming that we have to double the cylinder size, if double * is set */ if (data[1] && atoi(data[1]) > 0) cur_dive->cylinder[cur_cylinder_index].type.size.mliter = atol(data[1]) * 1000 * dbl; if (data[2] && atoi(data[2]) > 0) cur_dive->cylinder[cur_cylinder_index].start.mbar = atol(data[2]) * 1000; if (data[3] && atoi(data[3]) > 0) cur_dive->cylinder[cur_cylinder_index].end.mbar = atol(data[3]) * 1000; if (data[4] && atoi(data[4]) > 0) cur_dive->cylinder[cur_cylinder_index].type.workingpressure.mbar = atol(data[4]) * 1000; if (data[5] && atoi(data[5]) > 0) cur_dive->cylinder[cur_cylinder_index].gasmix.o2.permille = atol(data[5]) * 10; if (data[6] && atoi(data[6]) > 0) cur_dive->cylinder[cur_cylinder_index].gasmix.he.permille = atol(data[6]) * 10; cylinder_end(); return 0; } extern int divinglog_profile(void *handle, int columns, char **data, char **column) { int sinterval = 0; unsigned long i, len, lenprofile2 = 0; char *ptr, temp[4], pres[5], hbeat[4], stop[4], stime[4], ndl[4], ppo2_1[4], ppo2_2[4], ppo2_3[4], cns[5], setpoint[3]; short oldcyl = -1; /* We do not have samples */ if (!data[1]) return 0; if (data[0]) sinterval = atoi(data[0]); /* * Profile * * DDDDDCRASWEE * D: Depth (in meter with two decimals) * C: Deco (1 = yes, 0 = no) * R: RBT (Remaining Bottom Time warning) * A: Ascent warning * S: Decostop ignored * W: Work warning * E: Extra info (different for every computer) * * Example: 004500010000 * 4.5 m, no deco, no RBT warning, ascanding too fast, no decostop ignored, no work, no extra info * * * Profile2 * * TTTFFFFIRRR * * T: Temperature (in °C with one decimal) * F: Tank pressure 1 (in bar with one decimal) * I: Tank ID (0, 1, 2 ... 9) * R: RBT (in min) * * Example: 25518051099 * 25.5 °C, 180.5 bar, Tank 1, 99 min RBT * */ len = strlen(data[1]); if (data[2]) lenprofile2 = strlen(data[2]); for (i = 0, ptr = data[1]; i * 12 < len; ++i) { sample_start(); cur_sample->time.seconds = sinterval * i; cur_sample->in_deco = ptr[5] - '0' ? true : false; ptr[5] = 0; cur_sample->depth.mm = atoi(ptr) * 10; if (i * 11 < lenprofile2) { memcpy(temp, &data[2][i * 11], 3); cur_sample->temperature.mkelvin = C_to_mkelvin(atoi(temp) / 10); } if (data[2]) { memcpy(pres, &data[2][i * 11 + 3], 4); cur_sample->cylinderpressure.mbar = atoi(pres) * 100; } if (data[3] && strlen(data[3])) { memcpy(hbeat, &data[3][i * 14 + 8], 3); cur_sample->heartbeat = atoi(hbeat); } if (data[4] && strlen(data[4])) { memcpy(stop, &data[4][i * 9 + 6], 3); cur_sample->stopdepth.mm = atoi(stop) * 1000; memcpy(stime, &data[4][i * 9 + 3], 3); cur_sample->stoptime.seconds = atoi(stime) * 60; /* * Following value is NDL when not in deco, and * either 0 or TTS when in deco. */ memcpy(ndl, &data[4][i * 9 + 0], 3); if (cur_sample->in_deco == false) cur_sample->ndl.seconds = atoi(ndl) * 60; else if (atoi(ndl)) cur_sample->tts.seconds = atoi(ndl) * 60; if (cur_sample->in_deco == true) cur_sample->ndl.seconds = 0; } /* * AAABBBCCCOOOONNNNSS * * A = ppO2 cell 1 (measured) * B = ppO2 cell 2 (measured) * C = ppO2 cell 3 (measured) * O = OTU * N = CNS * S = Setpoint * * Example: 1121131141548026411 * 1.12 bar, 1.13 bar, 1.14 bar, OTU = 154.8, CNS = 26.4, Setpoint = 1.1 */ if (data[5] && strlen(data[5])) { memcpy(ppo2_1, &data[5][i * 19 + 0], 3); memcpy(ppo2_2, &data[5][i * 19 + 3], 3); memcpy(ppo2_3, &data[5][i * 19 + 6], 3); memcpy(cns, &data[5][i * 19 + 13], 4); memcpy(setpoint, &data[5][i * 19 + 17], 2); if (atoi(ppo2_1) > 0) cur_sample->o2sensor[0].mbar = atoi(ppo2_1) * 100; if (atoi(ppo2_2) > 0) cur_sample->o2sensor[1].mbar = atoi(ppo2_2) * 100; if (atoi(ppo2_3) > 0) cur_sample->o2sensor[2].mbar = atoi(ppo2_3) * 100; if (atoi(cns) > 0) cur_sample->cns = rint(atoi(cns) / 10); if (atoi(setpoint) > 0) cur_sample->setpoint.mbar = atoi(setpoint) * 100; } /* * My best guess is that if we have o2sensors, then it * is either CCR or PSCR dive. And the first time we * have O2 sensor readings, we can count them to get * the amount O2 sensors. */ if (!cur_dive->dc.no_o2sensors) { cur_dive->dc.no_o2sensors = cur_sample->o2sensor[0].mbar ? 1 : 0 + cur_sample->o2sensor[1].mbar ? 1 : 0 + cur_sample->o2sensor[2].mbar ? 1 : 0; cur_dive->dc.divemode = CCR; } ptr += 12; sample_end(); } for (i = 0, ptr = data[1]; i * 12 < len; ++i) { /* Remaining bottom time warning */ if (ptr[6] - '0') { event_start(); cur_event.time.seconds = sinterval * i; strcpy(cur_event.name, "rbt"); event_end(); } /* Ascent warning */ if (ptr[7] - '0') { event_start(); cur_event.time.seconds = sinterval * i; strcpy(cur_event.name, "ascent"); event_end(); } /* Deco stop ignored */ if (ptr[8] - '0') { event_start(); cur_event.time.seconds = sinterval * i; strcpy(cur_event.name, "violation"); event_end(); } /* Workload warning */ if (ptr[9] - '0') { event_start(); cur_event.time.seconds = sinterval * i; strcpy(cur_event.name, "workload"); event_end(); } ptr += 12; } for (i = 0; i * 11 < lenprofile2; ++i) { short tank = data[2][i * 11 + 7] - '0'; if (oldcyl != tank) { struct gasmix *mix = &cur_dive->cylinder[tank].gasmix; int o2 = get_o2(mix); int he = get_he(mix); event_start(); cur_event.time.seconds = sinterval * i; strcpy(cur_event.name, "gaschange"); o2 = (o2 + 5) / 10; he = (he + 5) / 10; cur_event.value = o2 + (he << 16); event_end(); oldcyl = tank; } } return 0; } extern int divinglog_dive(void *param, int columns, char **data, char **column) { int retval = 0; sqlite3 *handle = (sqlite3 *)param; char *err = NULL; char get_profile_template[] = "select ProfileInt,Profile,Profile2,Profile3,Profile4,Profile5 from Logbook where ID = %d"; char get_cylinder0_template[] = "select 0,TankSize,PresS,PresE,PresW,O2,He,DblTank from Logbook where ID = %d"; char get_cylinder_template[] = "select TankID,TankSize,PresS,PresE,PresW,O2,He,DblTank from Tank where LogID = %d order by TankID"; char get_buffer[1024]; dive_start(); diveid = atoi(data[13]); cur_dive->number = atoi(data[0]); cur_dive->when = (time_t)(atol(data[1])); if (data[2]) cur_dive->dive_site_uuid = find_or_create_dive_site_with_name(data[2], cur_dive->when); if (data[3]) utf8_string(data[3], &cur_dive->buddy); if (data[4]) utf8_string(data[4], &cur_dive->notes); if (data[5]) cur_dive->dc.maxdepth.mm = atof(data[5]) * 1000; if (data[6]) cur_dive->dc.duration.seconds = atoi(data[6]) * 60; if (data[7]) utf8_string(data[7], &cur_dive->divemaster); if (data[8]) cur_dive->airtemp.mkelvin = C_to_mkelvin(atol(data[8])); if (data[9]) cur_dive->watertemp.mkelvin = C_to_mkelvin(atol(data[9])); if (data[10]) { cur_dive->weightsystem[0].weight.grams = atol(data[10]) * 1000; cur_dive->weightsystem[0].description = strdup(translate("gettextFromC", "unknown")); } if (data[11]) cur_dive->suit = strdup(data[11]); settings_start(); dc_settings_start(); if (data[12]) { cur_dive->dc.model = strdup(data[12]); } else { cur_settings.dc.model = strdup("Divinglog import"); } snprintf(get_buffer, sizeof(get_buffer) - 1, get_cylinder0_template, diveid); retval = sqlite3_exec(handle, get_buffer, &divinglog_cylinder, 0, &err); if (retval != SQLITE_OK) { fprintf(stderr, "%s", "Database query divinglog_cylinder0 failed.\n"); return 1; } snprintf(get_buffer, sizeof(get_buffer) - 1, get_cylinder_template, diveid); retval = sqlite3_exec(handle, get_buffer, &divinglog_cylinder, 0, &err); if (retval != SQLITE_OK) { fprintf(stderr, "%s", "Database query divinglog_cylinder failed.\n"); return 1; } dc_settings_end(); settings_end(); if (data[12]) { cur_dive->dc.model = strdup(data[12]); } else { cur_dive->dc.model = strdup("Divinglog import"); } snprintf(get_buffer, sizeof(get_buffer) - 1, get_profile_template, diveid); retval = sqlite3_exec(handle, get_buffer, &divinglog_profile, 0, &err); if (retval != SQLITE_OK) { fprintf(stderr, "%s", "Database query divinglog_profile failed.\n"); return 1; } dive_end(); return SQLITE_OK; } int parse_divinglog_buffer(sqlite3 *handle, const char *url, const char *buffer, int size, struct dive_table *table) { int retval; char *err = NULL; target_table = table; char get_dives[] = "select Number,strftime('%s',Divedate || ' ' || ifnull(Entrytime,'00:00')),Country || ' - ' || City || ' - ' || Place,Buddy,Comments,Depth,Divetime,Divemaster,Airtemp,Watertemp,Weight,Divesuit,Computer,ID from Logbook where UUID not in (select UUID from DeletedRecords)"; retval = sqlite3_exec(handle, get_dives, &divinglog_dive, handle, &err); if (retval != SQLITE_OK) { fprintf(stderr, "Database query failed '%s'.\n", url); return 1; } return 0; } /* * Parse a signed 32-bit integer in little-endian mode, * that is seconds since Jan 1, 2000. */ static timestamp_t parse_dlf_timestamp(unsigned char *buffer) { timestamp_t offset; offset = (signed char) buffer[3]; offset = (offset << 8) + buffer[2]; offset = (offset << 8) + buffer[1]; offset = (offset << 8) + buffer[0]; // Jan 1, 2000 is 946684800 seconds after Jan 1, 1970, which is // the Unix epoch date that "timestamp_t" uses. return offset + 946684800; } int parse_dlf_buffer(unsigned char *buffer, size_t size) { unsigned char *ptr = buffer; unsigned char event; bool found; unsigned int time = 0; int i; char serial[6]; target_table = &dive_table; // Check for the correct file magic if (ptr[0] != 'D' || ptr[1] != 'i' || ptr[2] != 'v' || ptr[3] != 'E') return -1; dive_start(); divecomputer_start(); cur_dc->model = strdup("DLF import"); // (ptr[7] << 8) + ptr[6] Is "Serial" snprintf(serial, sizeof(serial), "%d", (ptr[7] << 8) + ptr[6]); cur_dc->serial = strdup(serial); cur_dc->when = parse_dlf_timestamp(ptr + 8); cur_dive->when = cur_dc->when; cur_dc->duration.seconds = ((ptr[14] & 0xFE) << 16) + (ptr[13] << 8) + ptr[12]; // ptr[14] >> 1 is scrubber used in % // 3 bit dive type switch((ptr[15] & 0x30) >> 3) { case 0: // unknown case 1: cur_dc->divemode = OC; break; case 2: cur_dc->divemode = CCR; break; case 3: cur_dc->divemode = CCR; // mCCR break; case 4: cur_dc->divemode = FREEDIVE; break; case 5: cur_dc->divemode = OC; // Gauge break; case 6: cur_dc->divemode = PSCR; // ASCR break; case 7: cur_dc->divemode = PSCR; break; } cur_dc->maxdepth.mm = ((ptr[21] << 8) + ptr[20]) * 10; cur_dc->surface_pressure.mbar = ((ptr[25] << 8) + ptr[24]) / 10; /* Done with parsing what we know about the dive header */ ptr += 32; // We're going to interpret ppO2 saved as a sensor value in these modes. if (cur_dc->divemode == CCR || cur_dc->divemode == PSCR) cur_dc->no_o2sensors = 1; while (ptr < buffer + size) { time = ((ptr[0] >> 4) & 0x0f) + ((ptr[1] << 4) & 0xff0) + (ptr[2] & 0x0f) * 3600; /* hours */ event = ptr[0] & 0x0f; switch (event) { case 0: /* Regular sample */ sample_start(); cur_sample->time.seconds = time; cur_sample->depth.mm = ((ptr[5] << 8) + ptr[4]) * 10; // Crazy precision on these stored values... // Only store value if we're in CCR/PSCR mode, // because we rather calculate ppo2 our selfs. if (cur_dc->divemode == CCR || cur_dc->divemode == PSCR) cur_sample->o2sensor[0].mbar = ((ptr[7] << 8) + ptr[6]) / 10; // NDL in minutes, 10 bit cur_sample->ndl.seconds = (((ptr[9] & 0x03) << 8) + ptr[8]) * 60; // TTS in minutes, 10 bit cur_sample->tts.seconds = (((ptr[10] & 0x0F) << 6) + (ptr[9] >> 2)) * 60; // Temperature in 1/10 C, 10 bit signed cur_sample->temperature.mkelvin = ((ptr[11] & 0x20) ? -1 : 1) * (((ptr[11] & 0x1F) << 4) + (ptr[10] >> 4)) * 100 + ZERO_C_IN_MKELVIN; // ptr[11] & 0xF0 is unknown, and always 0xC in all checked files cur_sample->stopdepth.mm = ((ptr[13] << 8) + ptr[12]) * 10; if (cur_sample->stopdepth.mm) cur_sample->in_deco = true; //ptr[14] is helium content, always zero? //ptr[15] is setpoint, always zero? sample_end(); break; case 1: /* dive event */ case 2: /* automatic parameter change */ case 3: /* diver error */ case 4: /* internal error */ case 5: /* device activity log */ event_start(); cur_event.time.seconds = time; switch (ptr[4]) { case 1: strcpy(cur_event.name, "Setpoint Manual"); // There is a setpoint value somewhere... break; case 2: strcpy(cur_event.name, "Setpoint Auto"); // There is a setpoint value somewhere... switch (ptr[7]) { case 0: strcat(cur_event.name, " Manual"); break; case 1: strcat(cur_event.name, " Auto Start"); break; case 2: strcat(cur_event.name, " Auto Hypox"); break; case 3: strcat(cur_event.name, " Auto Timeout"); break; case 4: strcat(cur_event.name, " Auto Ascent"); break; case 5: strcat(cur_event.name, " Auto Stall"); break; case 6: strcat(cur_event.name, " Auto SP Low"); break; default: break; } break; case 3: // obsolete strcpy(cur_event.name, "OC"); break; case 4: // obsolete strcpy(cur_event.name, "CCR"); break; case 5: strcpy(cur_event.name, "gaschange"); cur_event.type = SAMPLE_EVENT_GASCHANGE2; cur_event.value = ptr[7] << 8 ^ ptr[6]; found = false; for (i = 0; i < cur_cylinder_index; ++i) { if (cur_dive->cylinder[i].gasmix.o2.permille == ptr[6] * 10 && cur_dive->cylinder[i].gasmix.he.permille == ptr[7] * 10) { found = true; break; } } if (!found) { cylinder_start(); cur_dive->cylinder[cur_cylinder_index].gasmix.o2.permille = ptr[6] * 10; cur_dive->cylinder[cur_cylinder_index].gasmix.he.permille = ptr[7] * 10; cylinder_end(); cur_event.gas.index = cur_cylinder_index; } else { cur_event.gas.index = i; } break; case 6: strcpy(cur_event.name, "Start"); break; case 7: strcpy(cur_event.name, "Too Fast"); break; case 8: strcpy(cur_event.name, "Above Ceiling"); break; case 9: strcpy(cur_event.name, "Toxic"); break; case 10: strcpy(cur_event.name, "Hypox"); break; case 11: strcpy(cur_event.name, "Critical"); break; case 12: strcpy(cur_event.name, "Sensor Disabled"); break; case 13: strcpy(cur_event.name, "Sensor Enabled"); break; case 14: strcpy(cur_event.name, "O2 Backup"); break; case 15: strcpy(cur_event.name, "Peer Down"); break; case 16: strcpy(cur_event.name, "HS Down"); break; case 17: strcpy(cur_event.name, "Inconsistent"); break; case 18: // key pressed - probably not // interesting to view on profile break; case 19: // obsolete strcpy(cur_event.name, "SCR"); break; case 20: strcpy(cur_event.name, "Above Stop"); break; case 21: strcpy(cur_event.name, "Safety Miss"); break; case 22: strcpy(cur_event.name, "Fatal"); break; case 23: strcpy(cur_event.name, "Diluent"); break; case 24: strcpy(cur_event.name, "gaschange"); cur_event.type = SAMPLE_EVENT_GASCHANGE2; cur_event.value = ptr[7] << 8 ^ ptr[6]; event_end(); // This is both a mode change and a gas change event // so we encode it as two separate events. event_start(); strcpy(cur_event.name, "Change Mode"); switch (ptr[8]) { case 1: strcat(cur_event.name, ": OC"); break; case 2: strcat(cur_event.name, ": CCR"); break; case 3: strcat(cur_event.name, ": mCCR"); break; case 4: strcat(cur_event.name, ": Free"); break; case 5: strcat(cur_event.name, ": Gauge"); break; case 6: strcat(cur_event.name, ": ASCR"); break; case 7: strcat(cur_event.name, ": PSCR"); break; default: break; } event_end(); break; case 25: strcpy(cur_event.name, "CCR O2 solenoid opened/closed"); break; case 26: strcpy(cur_event.name, "User mark"); break; case 27: snprintf(cur_event.name, MAX_EVENT_NAME, "%sGF Switch (%d/%d)", ptr[6] ? "Bailout, ": "", ptr[7], ptr[8]); break; case 28: strcpy(cur_event.name, "Peer Up"); break; case 29: strcpy(cur_event.name, "HS Up"); break; case 30: snprintf(cur_event.name, MAX_EVENT_NAME, "CNS %d%%", ptr[6]); break; default: // No values above 30 had any description break; } event_end(); break; case 6: /* device configuration */ break; case 7: /* measure record */ /* Po2 sample? Solenoid inject? */ //fprintf(stderr, "%02X %02X%02X %02X%02X\n", ptr[5], ptr[6], ptr[7], ptr[8], ptr[9]); break; default: /* Unknown... */ break; } ptr += 16; } divecomputer_end(); dive_end(); return 0; } void parse_xml_init(void) { LIBXML_TEST_VERSION } void parse_xml_exit(void) { xmlCleanupParser(); } static struct xslt_files { const char *root; const char *file; const char *attribute; } xslt_files[] = { { "SUUNTO", "SuuntoSDM.xslt", NULL }, { "Dive", "SuuntoDM4.xslt", "xmlns" }, { "Dive", "shearwater.xslt", "version" }, { "JDiveLog", "jdivelog2subsurface.xslt", NULL }, { "dives", "MacDive.xslt", NULL }, { "DIVELOGSDATA", "divelogs.xslt", NULL }, { "uddf", "uddf.xslt", NULL }, { "UDDF", "uddf.xslt", NULL }, { "profile", "udcf.xslt", NULL }, { "Divinglog", "DivingLog.xslt", NULL }, { "csv", "csv2xml.xslt", NULL }, { "sensuscsv", "sensuscsv.xslt", NULL }, { "SubsurfaceCSV", "subsurfacecsv.xslt", NULL }, { "manualcsv", "manualcsv2xml.xslt", NULL }, { "logbook", "DiveLog.xslt", NULL }, { NULL, } }; static xmlDoc *test_xslt_transforms(xmlDoc *doc, const char **params) { struct xslt_files *info = xslt_files; xmlDoc *transformed; xsltStylesheetPtr xslt = NULL; xmlNode *root_element = xmlDocGetRootElement(doc); char *attribute; while (info->root) { if ((strcasecmp((const char *)root_element->name, info->root) == 0)) { if (info->attribute == NULL) break; else if (xmlGetProp(root_element, (const xmlChar *)info->attribute) != NULL) break; } info++; } if (info->root) { attribute = (char *)xmlGetProp(xmlFirstElementChild(root_element), (const xmlChar *)"name"); if (attribute) { if (strcasecmp(attribute, "subsurface") == 0) { free((void *)attribute); return doc; } free((void *)attribute); } xmlSubstituteEntitiesDefault(1); xslt = get_stylesheet(info->file); if (xslt == NULL) { report_error(translate("gettextFromC", "Can't open stylesheet %s"), info->file); return doc; } transformed = xsltApplyStylesheet(xslt, doc, params); xmlFreeDoc(doc); xsltFreeStylesheet(xslt); return transformed; } return doc; }