// SPDX-License-Identifier: GPL-2.0 /* dive.c */ /* maintains the internal dive list structure */ #include #include #include #include #include "gettext.h" #include "subsurface-string.h" #include "libdivecomputer.h" #include "device.h" #include "divelist.h" #include "divesite.h" #include "errorhelper.h" #include "qthelper.h" #include "metadata.h" #include "membuffer.h" #include "picture.h" #include "tag.h" #include "trip.h" #include "structured_list.h" #include "fulltext.h" /* one could argue about the best place to have this variable - * it's used in the UI, but it seems to make the most sense to have it * here */ struct dive displayed_dive; // For user visible text but still not translated const char *divemode_text_ui[] = { QT_TRANSLATE_NOOP("gettextFromC", "Open circuit"), QT_TRANSLATE_NOOP("gettextFromC", "CCR"), QT_TRANSLATE_NOOP("gettextFromC", "pSCR"), QT_TRANSLATE_NOOP("gettextFromC", "Freedive") }; // For writing/reading files. const char *divemode_text[] = {"OC", "CCR", "PSCR", "Freedive"}; /* * Adding a cylinder pressure sample field is not quite as trivial as it * perhaps should be. * * We try to keep the same sensor index for the same sensor, so that even * if the dive computer doesn't give pressure information for every sample, * we don't move pressure information around between the different sensor * indices. * * The "prepare_sample()" function will always copy the sensor indices * from the previous sample, so the indices are pre-populated (but the * pressures obviously are not) */ void add_sample_pressure(struct sample *sample, int sensor, int mbar) { int idx; if (!mbar) return; /* Do we already have a slot for this sensor */ for (idx = 0; idx < MAX_SENSORS; idx++) { if (sensor != sample->sensor[idx]) continue; sample->pressure[idx].mbar = mbar; return; } /* Pick the first unused index if we couldn't reuse one */ for (idx = 0; idx < MAX_SENSORS; idx++) { if (sample->pressure[idx].mbar) continue; sample->sensor[idx] = sensor; sample->pressure[idx].mbar = mbar; return; } /* We do not have enough slots for the pressure samples. */ /* Should we warn the user about dropping pressure data? */ } /* * The legacy format for sample pressures has a single pressure * for each sample that can have any sensor, plus a possible * "o2pressure" that is fixed to the Oxygen sensor for a CCR dive. * * For more complex pressure data, we have to use explicit * cylinder indices for each sample. * * This function returns a negative number for "no legacy mode", * or a non-negative number that indicates the o2 sensor index. */ int legacy_format_o2pressures(const struct dive *dive, const struct divecomputer *dc) { int i, o2sensor; o2sensor = (dc->divemode == CCR) ? get_cylinder_idx_by_use(dive, OXYGEN) : -1; for (i = 0; i < dc->samples; i++) { const struct sample *s = dc->sample + i; int seen_pressure = 0, idx; for (idx = 0; idx < MAX_SENSORS; idx++) { int sensor = s->sensor[idx]; pressure_t p = s->pressure[idx]; if (!p.mbar) continue; if (sensor == o2sensor) continue; if (seen_pressure) return -1; seen_pressure = 1; } } /* * Use legacy mode: if we have no O2 sensor we return a * positive sensor index that is guaranmteed to not match * any sensor (we encode it as 8 bits). */ return o2sensor < 0 ? 256 : o2sensor; } int event_is_gaschange(const struct event *ev) { return ev->type == SAMPLE_EVENT_GASCHANGE || ev->type == SAMPLE_EVENT_GASCHANGE2; } bool event_is_divemodechange(const struct event *ev) { return same_string(ev->name, "modechange"); } struct event *create_event(unsigned int time, int type, int flags, int value, const char *name) { int gas_index = -1; struct event *ev; unsigned int size, len = strlen(name); size = sizeof(*ev) + len + 1; ev = malloc(size); if (!ev) return NULL; memset(ev, 0, size); memcpy(ev->name, name, len); ev->time.seconds = time; ev->type = type; ev->flags = flags; ev->value = value; /* * Expand the events into a sane format. Currently * just gas switches */ switch (type) { case SAMPLE_EVENT_GASCHANGE2: /* High 16 bits are He percentage */ ev->gas.mix.he.permille = (value >> 16) * 10; /* Extension to the GASCHANGE2 format: cylinder index in 'flags' */ /* TODO: verify that gas_index < num_cylinders. */ if (flags > 0) gas_index = flags-1; /* Fallthrough */ case SAMPLE_EVENT_GASCHANGE: /* Low 16 bits are O2 percentage */ ev->gas.mix.o2.permille = (value & 0xffff) * 10; ev->gas.index = gas_index; break; } return ev; } /* warning: does not test idx for validity */ struct event *create_gas_switch_event(struct dive *dive, struct divecomputer *dc, int seconds, int idx) { /* The gas switch event format is insane for historical reasons */ struct gasmix mix = get_cylinder(dive, 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 = create_event(seconds, he ? SAMPLE_EVENT_GASCHANGE2 : SAMPLE_EVENT_GASCHANGE, 0, value, "gaschange"); ev->gas.index = idx; ev->gas.mix = mix; return ev; } struct event *clone_event_rename(const struct event *ev, const char *name) { return create_event(ev->time.seconds, ev->type, ev->flags, ev->value, name); } void add_event_to_dc(struct divecomputer *dc, struct event *ev) { struct event **p; p = &dc->events; /* insert in the sorted list of events */ while (*p && (*p)->time.seconds <= ev->time.seconds) p = &(*p)->next; ev->next = *p; *p = ev; } struct event *add_event(struct divecomputer *dc, unsigned int time, int type, int flags, int value, const char *name) { struct event *ev = create_event(time, type, flags, value, name); if (!ev) return NULL; add_event_to_dc(dc, ev); remember_event(name); return ev; } 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 >= dive->cylinders.nr) { report_error("Unknown cylinder index: %d", idx); return; } struct event *ev = create_gas_switch_event(dive, dc, seconds, idx); add_event_to_dc(dc, ev); } /* Substitutes an event in a divecomputer for another. No reordering is performed! */ void swap_event(struct divecomputer *dc, struct event *from, struct event *to) { for (struct event **ep = &dc->events; *ep; ep = &(*ep)->next) { if (*ep == from) { to->next = from->next; *ep = to; from->next = NULL; // For good measure. break; } } } bool same_event(const struct event *a, const struct event *b) { if (a->time.seconds != b->time.seconds) return 0; if (a->type != b->type) return 0; if (a->flags != b->flags) return 0; if (a->value != b->value) return 0; return !strcmp(a->name, b->name); } /* Remove given event from dive computer. Does *not* free the event. */ void remove_event_from_dc(struct divecomputer *dc, struct event *event) { for (struct event **ep = &dc->events; *ep; ep = &(*ep)->next) { if (*ep == event) { *ep = event->next; event->next = NULL; // For good measure. break; } } } /* since the name is an array as part of the structure (how silly is that?) we * have to actually remove the existing event and replace it with a new one. * WARNING, WARNING... this may end up freeing event in case that event is indeed * WARNING, WARNING... part of this divecomputer on this dive! */ void update_event_name(struct dive *d, struct event *event, const char *name) { if (!d || !event) return; struct divecomputer *dc = get_dive_dc(d, dc_number); if (!dc) return; struct event **removep = &dc->events; struct event *remove; while ((*removep)->next && !same_event(*removep, event)) removep = &(*removep)->next; if (!same_event(*removep, event)) return; remove = *removep; *removep = (*removep)->next; add_event(dc, event->time.seconds, event->type, event->flags, event->value, name); free(remove); invalidate_dive_cache(d); } void add_extra_data(struct divecomputer *dc, const char *key, const char *value) { struct extra_data **ed = &dc->extra_data; while (*ed) ed = &(*ed)->next; *ed = malloc(sizeof(struct extra_data)); if (*ed) { (*ed)->key = strdup(key); (*ed)->value = strdup(value); (*ed)->next = NULL; } } /* Find the divemode at time 'time' (in seconds) into the dive. Sequentially step through the divemode-change events, * saving the dive mode for each event. When the events occur AFTER 'time' seconds, the last stored divemode * is returned. This function is self-tracking, relying on setting the event pointer 'evp' so that, in each iteration * that calls this function, the search does not have to begin at the first event of the dive */ enum divemode_t get_current_divemode(const struct divecomputer *dc, int time, const struct event **evp, enum divemode_t *divemode) { const struct event *ev = *evp; if (dc) { if (*divemode == UNDEF_COMP_TYPE) { *divemode = dc->divemode; ev = get_next_event(dc->events, "modechange"); } } else { ev = NULL; } while (ev && ev->time.seconds < time) { *divemode = (enum divemode_t) ev->value; ev = get_next_event(ev->next, "modechange"); } *evp = ev; return *divemode; } struct gasmix get_gasmix_from_event(const struct dive *dive, const struct event *ev) { struct gasmix dummy = gasmix_air; if (ev && event_is_gaschange(ev)) { int index = ev->gas.index; if (index >= 0 && index < dive->cylinders.nr) return get_cylinder(dive, index)->gasmix; return ev->gas.mix; } return dummy; } // we need this to be uniq. oh, and it has no meaning whatsoever // - that's why we have the silly initial number and increment by 3 :-) int dive_getUniqID() { static int maxId = 83529; maxId += 3; return maxId; } struct dive *alloc_dive(void) { struct dive *dive; dive = malloc(sizeof(*dive)); if (!dive) exit(1); memset(dive, 0, sizeof(*dive)); dive->id = dive_getUniqID(); return dive; } static void free_dc(struct divecomputer *dc); static void free_dc_contents(struct divecomputer *dc); /* copy an element in a list of dive computer extra data */ static void copy_extra_data(struct extra_data *sed, struct extra_data *ded) { ded->key = copy_string(sed->key); ded->value = copy_string(sed->value); } /* this is very different from the copy_divecomputer later in this file; * this function actually makes full copies of the content */ static void copy_dc(const struct divecomputer *sdc, struct divecomputer *ddc) { *ddc = *sdc; ddc->model = copy_string(sdc->model); ddc->serial = copy_string(sdc->serial); ddc->fw_version = copy_string(sdc->fw_version); copy_samples(sdc, ddc); copy_events(sdc, ddc); STRUCTURED_LIST_COPY(struct extra_data, sdc->extra_data, ddc->extra_data, copy_extra_data); } static void dc_cylinder_renumber(struct dive *dive, struct divecomputer *dc, const int mapping[]); /* copy dive computer list and renumber the cylinders * space for the first divecomputer is provided by the * caller, the remainder is allocated */ static void copy_dc_renumber(struct dive *d, const struct divecomputer *sdc, struct divecomputer *ddc, const int cylinders_map[]) { for (;;) { copy_dc(sdc, ddc); dc_cylinder_renumber(d, ddc, cylinders_map); if (!sdc->next) break; sdc = sdc->next; ddc->next = calloc(1, sizeof(struct divecomputer)); ddc = ddc->next; } ddc->next = NULL; } /* copy an element in a list of pictures */ static void copy_pl(struct picture *sp, struct picture *dp) { *dp = *sp; dp->filename = copy_string(sp->filename); } /* The first divecomputer is embedded in the dive structure. Free its data but not * the structure itself. For all remainding dcs in the list, free data *and* structures. */ void free_dive_dcs(struct divecomputer *dc) { free_dc_contents(dc); STRUCTURED_LIST_FREE(struct divecomputer, dc->next, free_dc); } static void free_dive_structures(struct dive *d) { if (!d) return; fulltext_unregister(d); /* free the strings */ free(d->buddy); free(d->divemaster); free(d->notes); free(d->suit); /* free tags, additional dive computers, and pictures */ taglist_free(d->tag_list); free_dive_dcs(&d->dc); STRUCTURED_LIST_FREE(struct picture, d->picture_list, free_picture); clear_cylinder_table(&d->cylinders); free(d->cylinders.cylinders); clear_weightsystem_table(&d->weightsystems); free(d->weightsystems.weightsystems); } void free_dive(struct dive *d) { free_dive_structures(d); free(d); } /* copy_dive makes duplicates of many components of a dive; * in order not to leak memory, we need to free those . * copy_dive doesn't play with the divetrip and forward/backward pointers * so we can ignore those */ void clear_dive(struct dive *d) { if (!d) return; free_dive_structures(d); memset(d, 0, sizeof(struct dive)); } /* make a true copy that is independent of the source dive; * all data structures are duplicated, so the copy can be modified without * any impact on the source */ static void copy_dive_nodc(const struct dive *s, struct dive *d) { clear_dive(d); /* simply copy things over, but then make actual copies of the * relevant components that are referenced through pointers, * so all the strings and the structured lists */ *d = *s; memset(&d->cylinders, 0, sizeof(d->cylinders)); memset(&d->weightsystems, 0, sizeof(d->weightsystems)); d->full_text = NULL; invalidate_dive_cache(d); d->buddy = copy_string(s->buddy); d->divemaster = copy_string(s->divemaster); d->notes = copy_string(s->notes); d->suit = copy_string(s->suit); copy_cylinders(&s->cylinders, &d->cylinders); copy_weights(&s->weightsystems, &d->weightsystems); STRUCTURED_LIST_COPY(struct picture, s->picture_list, d->picture_list, copy_pl); d->tag_list = taglist_copy(s->tag_list); } void copy_dive(const struct dive *s, struct dive *d) { copy_dive_nodc(s, d); // Copy the first dc explicitly, then the list of subsequent dc's copy_dc(&s->dc, &d->dc); STRUCTURED_LIST_COPY(struct divecomputer, s->dc.next, d->dc.next, copy_dc); } static void copy_dive_onedc(const struct dive *s, const struct divecomputer *sdc, struct dive *d) { copy_dive_nodc(s, d); copy_dc(sdc, &d->dc); d->dc.next = NULL; } /* make a clone of the source dive and clean out the source dive; * this is specifically so we can create a dive in the displayed_dive and then * add it to the divelist. * Note the difference to copy_dive() / clean_dive() */ struct dive *move_dive(struct dive *s) { struct dive *dive = alloc_dive(); *dive = *s; // so all the pointers in dive point to the things s pointed to memset(s, 0, sizeof(struct dive)); // and now the pointers in s are gone return dive; } #define CONDITIONAL_COPY_STRING(_component) \ if (what._component) \ d->_component = copy_string(s->_component) // copy elements, depending on bits in what that are set void selective_copy_dive(const struct dive *s, struct dive *d, struct dive_components what, bool clear) { if (clear) clear_dive(d); CONDITIONAL_COPY_STRING(notes); CONDITIONAL_COPY_STRING(divemaster); CONDITIONAL_COPY_STRING(buddy); CONDITIONAL_COPY_STRING(suit); if (what.rating) d->rating = s->rating; if (what.visibility) d->visibility = s->visibility; if (what.divesite) { unregister_dive_from_dive_site(d); add_dive_to_dive_site(d, s->dive_site); } if (what.tags) d->tag_list = taglist_copy(s->tag_list); if (what.cylinders) copy_cylinder_types(s, d); if (what.weights) copy_weights(&s->weightsystems, &d->weightsystems); } #undef CONDITIONAL_COPY_STRING struct event *clone_event(const struct event *src_ev) { struct event *ev; if (!src_ev) return NULL; size_t size = sizeof(*src_ev) + strlen(src_ev->name) + 1; ev = (struct event*) malloc(size); if (!ev) exit(1); memcpy(ev, src_ev, size); ev->next = NULL; return ev; } /* copies all events in this dive computer */ void copy_events(const struct divecomputer *s, struct divecomputer *d) { const struct event *ev; struct event **pev; if (!s || !d) return; ev = s->events; pev = &d->events; while (ev != NULL) { struct event *new_ev = clone_event(ev); *pev = new_ev; pev = &new_ev->next; ev = ev->next; } *pev = NULL; } /* copies all events from all dive computers before a given time this is used when editing a dive in the planner to preserve the events of the old dive */ void copy_events_until(const struct dive *sd, struct dive *dd, int time) { if (!sd || !dd) return; const struct divecomputer *s = &sd->dc; struct divecomputer *d = &dd->dc; while (s && d) { const struct event *ev; ev = s->events; while (ev != NULL) { // Don't add events the planner knows about if (ev->time.seconds < time && !event_is_gaschange(ev) && !event_is_divemodechange(ev)) add_event(d, ev->time.seconds, ev->type, ev->flags, ev->value, ev->name); ev = ev->next; } s = s->next; d = d->next; } } int nr_cylinders(const struct dive *dive) { return dive->cylinders.nr; } int nr_weightsystems(const struct dive *dive) { return dive->weightsystems.nr; } void copy_cylinders(const struct cylinder_table *s, struct cylinder_table *d) { int i; clear_cylinder_table(d); for (i = 0; i < s->nr; i++) add_cloned_cylinder(d, s->cylinders[i]); } void copy_used_cylinders(const struct dive *s, struct dive *d, bool used_only) { int i; if (!s || !d) return; clear_cylinder_table(&d->cylinders); for (i = 0; i < s->cylinders.nr; i++) { if (!used_only || is_cylinder_used(s, i) || get_cylinder(s, i)->cylinder_use == NOT_USED) add_cloned_cylinder(&d->cylinders, *get_cylinder(s, i)); } } void copy_samples(const struct divecomputer *s, struct divecomputer *d) { /* instead of carefully copying them one by one and calling add_sample * over and over again, let's just copy the whole blob */ if (!s || !d) return; int nr = s->samples; d->samples = nr; d->alloc_samples = nr; // We expect to be able to read the memory in the other end of the pointer // if its a valid pointer, so don't expect malloc() to return NULL for // zero-sized malloc, do it ourselves. d->sample = NULL; if(!nr) return; d->sample = malloc(nr * sizeof(struct sample)); if (d->sample) memcpy(d->sample, s->sample, nr * sizeof(struct sample)); } /* make room for num samples; if not enough space is available, the sample * array is reallocated and the existing samples are copied. */ void alloc_samples(struct divecomputer *dc, int num) { if (num > dc->alloc_samples) { dc->alloc_samples = (num * 3) / 2 + 10; dc->sample = realloc(dc->sample, dc->alloc_samples * sizeof(struct sample)); if (!dc->sample) dc->samples = dc->alloc_samples = 0; } } void free_samples(struct divecomputer *dc) { if (dc) { free(dc->sample); dc->sample = 0; dc->samples = 0; dc->alloc_samples = 0; } } struct sample *prepare_sample(struct divecomputer *dc) { if (dc) { int nr = dc->samples; struct sample *sample; alloc_samples(dc, nr + 1); if (!dc->sample) return NULL; sample = dc->sample + nr; memset(sample, 0, sizeof(*sample)); // Copy the sensor numbers - but not the pressure values // from the previous sample if any. if (nr) { for (int idx = 0; idx < MAX_SENSORS; idx++) sample->sensor[idx] = sample[-1].sensor[idx]; } // Init some values with -1 sample->bearing.degrees = -1; sample->ndl.seconds = -1; return sample; } return NULL; } void finish_sample(struct divecomputer *dc) { dc->samples++; } /* * So when we re-calculate maxdepth and meandepth, we will * not override the old numbers if they are close to the * new ones. * * Why? Because a dive computer may well actually track the * max. depth and mean depth at finer granularity than the * samples it stores. So it's possible that the max and mean * have been reported more correctly originally. * * Only if the values calculated from the samples are clearly * different do we override the normal depth values. * * This considers 1m to be "clearly different". That's * a totally random number. */ static void update_depth(depth_t *depth, int new) { if (new) { int old = depth->mm; if (abs(old - new) > 1000) depth->mm = new; } } static void update_temperature(temperature_t *temperature, int new) { if (new) { int old = temperature->mkelvin; if (abs(old - new) > 1000) temperature->mkelvin = new; } } /* * Calculate how long we were actually under water, and the average * depth while under water. * * This ignores any surface time in the middle of the dive. */ void fixup_dc_duration(struct divecomputer *dc) { int duration, i; int lasttime, lastdepth, depthtime; duration = 0; lasttime = 0; lastdepth = 0; depthtime = 0; for (i = 0; i < dc->samples; i++) { struct sample *sample = dc->sample + i; int time = sample->time.seconds; int depth = sample->depth.mm; /* We ignore segments at the surface */ if (depth > SURFACE_THRESHOLD || lastdepth > SURFACE_THRESHOLD) { duration += time - lasttime; depthtime += (time - lasttime) * (depth + lastdepth) / 2; } lastdepth = depth; lasttime = time; } if (duration) { dc->duration.seconds = duration; dc->meandepth.mm = (depthtime + duration / 2) / duration; } } /* Which cylinders had gas used? */ #define SOME_GAS 5000 static bool cylinder_used(const cylinder_t *cyl) { int start_mbar, end_mbar; start_mbar = cyl->start.mbar ?: cyl->sample_start.mbar; end_mbar = cyl->end.mbar ?: cyl->sample_end.mbar; // More than 5 bar used? This matches statistics.c // heuristics return start_mbar > end_mbar + SOME_GAS; } /* Get list of used cylinders. Returns the number of used cylinders. */ static int get_cylinder_used(const struct dive *dive, bool used[]) { int i, num = 0; for (i = 0; i < dive->cylinders.nr; i++) { used[i] = cylinder_used(get_cylinder(dive, i)); if (used[i]) num++; } return num; } /* Are there any used cylinders which we do not know usage about? */ static bool has_unknown_used_cylinders(const struct dive *dive, const struct divecomputer *dc, const bool used_cylinders[], int num) { int idx; const struct event *ev; bool *used_and_unknown = malloc(dive->cylinders.nr * sizeof(bool)); memcpy(used_and_unknown, used_cylinders, dive->cylinders.nr * sizeof(bool)); /* We know about using the O2 cylinder in a CCR dive */ if (dc->divemode == CCR) { int o2_cyl = get_cylinder_idx_by_use(dive, OXYGEN); if (o2_cyl >= 0 && used_and_unknown[o2_cyl]) { used_and_unknown[o2_cyl] = false; num--; } } /* We know about the explicit first cylinder (or first) */ idx = explicit_first_cylinder(dive, dc); if (used_and_unknown[idx]) { used_and_unknown[idx] = false; num--; } /* And we have possible switches to other gases */ ev = get_next_event(dc->events, "gaschange"); while (ev && num > 0) { idx = get_cylinder_index(dive, ev); if (idx >= 0 && used_and_unknown[idx]) { used_and_unknown[idx] = false; num--; } ev = get_next_event(ev->next, "gaschange"); } free(used_and_unknown); return num > 0; } void per_cylinder_mean_depth(const struct dive *dive, struct divecomputer *dc, int *mean, int *duration) { int i; int *depthtime; uint32_t lasttime = 0; int lastdepth = 0; int idx = 0; bool *used_cylinders; int num_used_cylinders; if (dive->cylinders.nr <= 0) return; for (i = 0; i < dive->cylinders.nr; i++) mean[i] = duration[i] = 0; if (!dc) return; /* * There is no point in doing per-cylinder information * if we don't actually know about the usage of all the * used cylinders. */ used_cylinders = malloc(dive->cylinders.nr * sizeof(bool)); num_used_cylinders = get_cylinder_used(dive, used_cylinders); if (has_unknown_used_cylinders(dive, dc, used_cylinders, num_used_cylinders)) { /* * If we had more than one used cylinder, but * do not know usage of them, we simply cannot * account mean depth to them. */ if (num_used_cylinders > 1) { free(used_cylinders); return; } /* * For a single cylinder, use the overall mean * and duration */ for (i = 0; i < dive->cylinders.nr; i++) { if (used_cylinders[i]) { mean[i] = dc->meandepth.mm; duration[i] = dc->duration.seconds; } } free(used_cylinders); return; } free(used_cylinders); if (!dc->samples) fake_dc(dc); const struct event *ev = get_next_event(dc->events, "gaschange"); depthtime = malloc(dive->cylinders.nr * sizeof(*depthtime)); memset(depthtime, 0, dive->cylinders.nr * sizeof(*depthtime)); for (i = 0; i < dc->samples; i++) { struct sample *sample = dc->sample + i; uint32_t time = sample->time.seconds; int depth = sample->depth.mm; /* Make sure to move the event past 'lasttime' */ while (ev && lasttime >= ev->time.seconds) { idx = get_cylinder_index(dive, ev); ev = get_next_event(ev->next, "gaschange"); } /* Do we need to fake a midway sample at an event? */ if (ev && time > ev->time.seconds) { int newtime = ev->time.seconds; int newdepth = interpolate(lastdepth, depth, newtime - lasttime, time - lasttime); time = newtime; depth = newdepth; i--; } /* We ignore segments at the surface */ if (depth > SURFACE_THRESHOLD || lastdepth > SURFACE_THRESHOLD) { duration[idx] += time - lasttime; depthtime[idx] += (time - lasttime) * (depth + lastdepth) / 2; } lastdepth = depth; lasttime = time; } for (i = 0; i < dive->cylinders.nr; i++) { if (duration[i]) mean[i] = (depthtime[i] + duration[i] / 2) / duration[i]; } free(depthtime); } static void update_min_max_temperatures(struct dive *dive, temperature_t temperature) { if (temperature.mkelvin) { if (!dive->maxtemp.mkelvin || temperature.mkelvin > dive->maxtemp.mkelvin) dive->maxtemp = temperature; if (!dive->mintemp.mkelvin || temperature.mkelvin < dive->mintemp.mkelvin) dive->mintemp = temperature; } } /* * If the cylinder tank pressures are within half a bar * (about 8 PSI) of the sample pressures, we consider it * to be a rounding error, and throw them away as redundant. */ static int same_rounded_pressure(pressure_t a, pressure_t b) { return abs(a.mbar - b.mbar) <= 500; } /* Some dive computers (Cobalt) don't start the dive with cylinder 0 but explicitly * tell us what the first gas is with a gas change event in the first sample. * Sneakily we'll use a return value of 0 (or FALSE) when there is no explicit * first cylinder - in which case cylinder 0 is indeed the first cylinder. * We likewise return 0 if the event concerns a cylinder that doesn't exist. * If the dive has no cylinders, -1 is returned. */ int explicit_first_cylinder(const struct dive *dive, const struct divecomputer *dc) { int res = 0; if (!dive->cylinders.nr) return -1; if (dc) { const struct event *ev = get_next_event(dc->events, "gaschange"); if (ev && ((dc->sample && ev->time.seconds == dc->sample[0].time.seconds) || ev->time.seconds <= 1)) res = get_cylinder_index(dive, ev); else if (dc->divemode == CCR) res = MAX(get_cylinder_idx_by_use(dive, DILUENT), 0); } return res < dive->cylinders.nr ? res : 0; } /* this gets called when the dive mode has changed (so OC vs. CC) * there are two places we might have setpoints... events or in the samples */ void update_setpoint_events(const struct dive *dive, struct divecomputer *dc) { struct event *ev; int new_setpoint = 0; if (dc->divemode == CCR) new_setpoint = prefs.defaultsetpoint; if (dc->divemode == OC && (same_string(dc->model, "Shearwater Predator") || same_string(dc->model, "Shearwater Petrel") || same_string(dc->model, "Shearwater Nerd"))) { // make sure there's no setpoint in the samples // this is an irreversible change - so switching a dive to OC // by mistake when it's actually CCR is _bad_ // So we make sure, this comes from a Predator or Petrel and we only remove // pO2 values we would have computed anyway. const struct event *ev = get_next_event(dc->events, "gaschange"); struct gasmix gasmix = get_gasmix_from_event(dive, ev); const struct event *next = get_next_event(ev, "gaschange"); for (int i = 0; i < dc->samples; i++) { struct gas_pressures pressures; if (next && dc->sample[i].time.seconds >= next->time.seconds) { ev = next; gasmix = get_gasmix_from_event(dive, ev); next = get_next_event(ev, "gaschange"); } fill_pressures(&pressures, calculate_depth_to_mbar(dc->sample[i].depth.mm, dc->surface_pressure, 0), gasmix ,0, dc->divemode); if (abs(dc->sample[i].setpoint.mbar - (int)(1000 * pressures.o2)) <= 50) dc->sample[i].setpoint.mbar = 0; } } // an "SP change" event at t=0 is currently our marker for OC vs CCR // this will need to change to a saner setup, but for now we can just // check if such an event is there and adjust it, or add that event ev = get_next_event_mutable(dc->events, "SP change"); if (ev && ev->time.seconds == 0) { ev->value = new_setpoint; } else { if (!add_event(dc, 0, SAMPLE_EVENT_PO2, 0, new_setpoint, "SP change")) fprintf(stderr, "Could not add setpoint change event\n"); } } /* * See if the size/workingpressure looks like some standard cylinder * size, eg "AL80". * * NOTE! We don't take compressibility into account when naming * cylinders. That makes a certain amount of sense, since the * cylinder name is independent from the gasmix, and different * gasmixes have different compressibility. */ static void match_standard_cylinder(cylinder_type_t *type) { double cuft, bar; int psi, len; const char *fmt; char buffer[40], *p; /* Do we already have a cylinder description? */ if (type->description) return; bar = type->workingpressure.mbar / 1000.0; cuft = ml_to_cuft(type->size.mliter); cuft *= bar_to_atm(bar); psi = to_PSI(type->workingpressure); switch (psi) { case 2300 ... 2500: /* 2400 psi: LP tank */ fmt = "LP%d"; break; case 2600 ... 2700: /* 2640 psi: LP+10% */ fmt = "LP%d"; break; case 2900 ... 3100: /* 3000 psi: ALx tank */ fmt = "AL%d"; break; case 3400 ... 3500: /* 3442 psi: HP tank */ fmt = "HP%d"; break; case 3700 ... 3850: /* HP+10% */ fmt = "HP%d+"; break; default: return; } len = snprintf(buffer, sizeof(buffer), fmt, (int)lrint(cuft)); p = malloc(len + 1); if (!p) return; memcpy(p, buffer, len + 1); type->description = p; } /* * There are two ways to give cylinder size information: * - total amount of gas in cuft (depends on working pressure and physical size) * - physical size * * where "physical size" is the one that actually matters and is sane. * * We internally use physical size only. But we save the workingpressure * so that we can do the conversion if required. */ static void sanitize_cylinder_type(cylinder_type_t *type) { /* If we have no working pressure, it had *better* be just a physical size! */ if (!type->workingpressure.mbar) return; /* No size either? Nothing to go on */ if (!type->size.mliter) return; /* Ok, we have both size and pressure: try to match a description */ match_standard_cylinder(type); } static void sanitize_cylinder_info(struct dive *dive) { int i; for (i = 0; i < dive->cylinders.nr; i++) { sanitize_gasmix(&get_cylinder(dive, i)->gasmix); sanitize_cylinder_type(&get_cylinder(dive, i)->type); } } /* some events should never be thrown away */ static bool is_potentially_redundant(const struct event *event) { if (!strcmp(event->name, "gaschange")) return false; if (!strcmp(event->name, "bookmark")) return false; if (!strcmp(event->name, "heading")) return false; return true; } /* match just by name - we compare the details in the code that uses this helper */ static struct event *find_previous_event(struct divecomputer *dc, struct event *event) { struct event *ev = dc->events; struct event *previous = NULL; if (empty_string(event->name)) return NULL; while (ev && ev != event) { if (same_string(ev->name, event->name)) previous = ev; ev = ev->next; } return previous; } pressure_t calculate_surface_pressure(const struct dive *dive) { const struct divecomputer *dc; pressure_t res; int sum = 0, nr = 0; for_each_dc (dive, dc) { if (dc->surface_pressure.mbar) { sum += dc->surface_pressure.mbar; nr++; } } res.mbar = nr ? (sum + nr / 2) / nr : 0; return res; } static void fixup_surface_pressure(struct dive *dive) { dive->surface_pressure = calculate_surface_pressure(dive); } /* if the surface pressure in the dive data is redundant to the calculated * value (i.e., it was added by running fixup on the dive) return 0, * otherwise return the surface pressure given in the dive */ pressure_t un_fixup_surface_pressure(const struct dive *d) { pressure_t res = d->surface_pressure; if (res.mbar && res.mbar == calculate_surface_pressure(d).mbar) res.mbar = 0; return res; } static void fixup_water_salinity(struct dive *dive) { struct divecomputer *dc; int sum = 0, nr = 0; for_each_dc (dive, dc) { if (dc->salinity) { if (dc->salinity < 500) dc->salinity += FRESHWATER_SALINITY; sum += dc->salinity; nr++; } } if (nr) dive->salinity = (sum + nr / 2) / nr; } static void fixup_meandepth(struct dive *dive) { struct divecomputer *dc; int sum = 0, nr = 0; for_each_dc (dive, dc) { if (dc->meandepth.mm) { sum += dc->meandepth.mm; nr++; } } if (nr) dive->meandepth.mm = (sum + nr / 2) / nr; } static void fixup_duration(struct dive *dive) { struct divecomputer *dc; duration_t duration = { }; for_each_dc (dive, dc) duration.seconds = MAX(duration.seconds, dc->duration.seconds); dive->duration.seconds = duration.seconds; } /* * What do the dive computers say the water temperature is? * (not in the samples, but as dc property for dcs that support that) */ unsigned int dc_watertemp(const struct divecomputer *dc) { int sum = 0, nr = 0; do { if (dc->watertemp.mkelvin) { sum += dc->watertemp.mkelvin; nr++; } } while ((dc = dc->next) != NULL); if (!nr) return 0; return (sum + nr / 2) / nr; } static void fixup_watertemp(struct dive *dive) { if (!dive->watertemp.mkelvin) dive->watertemp.mkelvin = dc_watertemp(&dive->dc); } /* * What do the dive computers say the air temperature is? */ unsigned int dc_airtemp(const struct divecomputer *dc) { int sum = 0, nr = 0; do { if (dc->airtemp.mkelvin) { sum += dc->airtemp.mkelvin; nr++; } } while ((dc = dc->next) != NULL); if (!nr) return 0; return (sum + nr / 2) / nr; } static void fixup_airtemp(struct dive *dive) { if (!dive->airtemp.mkelvin) dive->airtemp.mkelvin = dc_airtemp(&dive->dc); } /* if the air temperature in the dive data is redundant to the one in its * first divecomputer (i.e., it was added by running fixup on the dive) * return 0, otherwise return the air temperature given in the dive */ static temperature_t un_fixup_airtemp(const struct dive *a) { temperature_t res = a->airtemp; if (a->airtemp.mkelvin && a->airtemp.mkelvin == dc_airtemp(&a->dc)) res.mkelvin = 0; return res; } /* * events are stored as a linked list, so the concept of * "consecutive, identical events" is somewhat hard to * implement correctly (especially given that on some dive * computers events are asynchronous, so they can come in * between what would be the non-constant sample rate). * * So what we do is that we throw away clearly redundant * events that are fewer than 61 seconds apart (assuming there * is no dive computer with a sample rate of more than 60 * seconds... that would be pretty pointless to plot the * profile with) * * We first only mark the events for deletion so that we * still know when the previous event happened. */ static void fixup_dc_events(struct divecomputer *dc) { struct event *event; event = dc->events; while (event) { struct event *prev; if (is_potentially_redundant(event)) { prev = find_previous_event(dc, event); if (prev && prev->value == event->value && prev->flags == event->flags && event->time.seconds - prev->time.seconds < 61) event->deleted = true; } event = event->next; } event = dc->events; while (event) { if (event->next && event->next->deleted) { struct event *nextnext = event->next->next; free(event->next); event->next = nextnext; } else { event = event->next; } } } static int interpolate_depth(struct divecomputer *dc, int idx, int lastdepth, int lasttime, int now) { int i; int nextdepth = lastdepth; int nexttime = now; for (i = idx+1; i < dc->samples; i++) { struct sample *sample = dc->sample + i; if (sample->depth.mm < 0) continue; nextdepth = sample->depth.mm; nexttime = sample->time.seconds; break; } return interpolate(lastdepth, nextdepth, now-lasttime, nexttime-lasttime); } static void fixup_dc_depths(struct dive *dive, struct divecomputer *dc) { int i; int maxdepth = dc->maxdepth.mm; int lasttime = 0, lastdepth = 0; for (i = 0; i < dc->samples; i++) { struct sample *sample = dc->sample + i; int time = sample->time.seconds; int depth = sample->depth.mm; if (depth < 0) { depth = interpolate_depth(dc, i, lastdepth, lasttime, time); sample->depth.mm = depth; } if (depth > SURFACE_THRESHOLD) { if (depth > maxdepth) maxdepth = depth; } lastdepth = depth; lasttime = time; if (sample->cns > dive->maxcns) dive->maxcns = sample->cns; } update_depth(&dc->maxdepth, maxdepth); if (maxdepth > dive->maxdepth.mm) dive->maxdepth.mm = maxdepth; } static void fixup_dc_ndl(struct divecomputer *dc) { int i; for (i = 0; i < dc->samples; i++) { struct sample *sample = dc->sample + i; if (sample->ndl.seconds != 0) break; if (sample->ndl.seconds == 0) sample->ndl.seconds = -1; } } static void fixup_dc_temp(struct dive *dive, struct divecomputer *dc) { int i; int mintemp = 0, lasttemp = 0; for (i = 0; i < dc->samples; i++) { struct sample *sample = dc->sample + i; int temp = sample->temperature.mkelvin; if (temp) { /* * If we have consecutive identical * temperature readings, throw away * the redundant ones. */ if (lasttemp == temp) sample->temperature.mkelvin = 0; else lasttemp = temp; if (!mintemp || temp < mintemp) mintemp = temp; } update_min_max_temperatures(dive, sample->temperature); } update_temperature(&dc->watertemp, mintemp); update_min_max_temperatures(dive, dc->watertemp); } /* Remove redundant pressure information */ static void simplify_dc_pressures(struct divecomputer *dc) { int i; int lastindex[2] = { -1, -1 }; int lastpressure[2] = { 0 }; for (i = 0; i < dc->samples; i++) { int j; struct sample *sample = dc->sample + i; for (j = 0; j < MAX_SENSORS; j++) { int pressure = sample->pressure[j].mbar; int index = sample->sensor[j]; if (index == lastindex[j]) { /* Remove duplicate redundant pressure information */ if (pressure == lastpressure[j]) sample->pressure[j].mbar = 0; } lastindex[j] = index; lastpressure[j] = pressure; } } } /* Do we need a sensor -> cylinder mapping? */ static void fixup_start_pressure(struct dive *dive, int idx, pressure_t p) { if (idx >= 0 && idx < dive->cylinders.nr) { cylinder_t *cyl = get_cylinder(dive, idx); if (p.mbar && !cyl->sample_start.mbar) cyl->sample_start = p; } } static void fixup_end_pressure(struct dive *dive, int idx, pressure_t p) { if (idx >= 0 && idx < dive->cylinders.nr) { cylinder_t *cyl = get_cylinder(dive, idx); if (p.mbar && !cyl->sample_end.mbar) cyl->sample_end = p; } } /* * Check the cylinder pressure sample information and fill in the * overall cylinder pressures from those. * * We ignore surface samples for tank pressure information. * * At the beginning of the dive, let the cylinder cool down * if the diver starts off at the surface. And at the end * of the dive, there may be surface pressures where the * diver has already turned off the air supply (especially * for computers like the Uemis Zurich that end up saving * quite a bit of samples after the dive has ended). */ static void fixup_dive_pressures(struct dive *dive, struct divecomputer *dc) { int i; /* Walk the samples from the beginning to find starting pressures.. */ for (i = 0; i < dc->samples; i++) { int idx; struct sample *sample = dc->sample + i; if (sample->depth.mm < SURFACE_THRESHOLD) continue; for (idx = 0; idx < MAX_SENSORS; idx++) fixup_start_pressure(dive, sample->sensor[idx], sample->pressure[idx]); } /* ..and from the end for ending pressures */ for (i = dc->samples; --i >= 0; ) { int idx; struct sample *sample = dc->sample + i; if (sample->depth.mm < SURFACE_THRESHOLD) continue; for (idx = 0; idx < MAX_SENSORS; idx++) fixup_end_pressure(dive, sample->sensor[idx], sample->pressure[idx]); } simplify_dc_pressures(dc); } /* * Match a gas change event against the cylinders we have */ static bool validate_gaschange(struct dive *dive, struct event *event) { int index; int o2, he, value; /* We'll get rid of the per-event gasmix, but for now sanitize it */ if (gasmix_is_air(event->gas.mix)) event->gas.mix.o2.permille = 0; /* Do we already have a cylinder index for this gasmix? */ if (event->gas.index >= 0) return true; index = find_best_gasmix_match(event->gas.mix, &dive->cylinders); if (index < 0 || index >= dive->cylinders.nr) return false; /* Fix up the event to have the right information */ event->gas.index = index; event->gas.mix = get_cylinder(dive, index)->gasmix; /* Convert to odd libdivecomputer format */ o2 = get_o2(event->gas.mix); he = get_he(event->gas.mix); o2 = (o2 + 5) / 10; he = (he + 5) / 10; value = o2 + (he << 16); event->value = value; if (he) event->type = SAMPLE_EVENT_GASCHANGE2; return true; } /* Clean up event, return true if event is ok, false if it should be dropped as bogus */ static bool validate_event(struct dive *dive, struct event *event) { if (event_is_gaschange(event)) return validate_gaschange(dive, event); return true; } static void fixup_dc_gasswitch(struct dive *dive, struct divecomputer *dc) { struct event **evp, *event; evp = &dc->events; while ((event = *evp) != NULL) { if (validate_event(dive, event)) { evp = &event->next; continue; } /* Delete this event and try the next one */ *evp = event->next; } } static void fixup_no_o2sensors(struct divecomputer *dc) { // Its only relevant to look for sensor values on CCR and PSCR dives without any no_o2sensors recorded. if (dc->no_o2sensors != 0 || !(dc->divemode == CCR || dc->divemode == PSCR)) return; for (int i = 0; i < dc->samples; i++) { int nsensor = 0; struct sample *s = dc->sample + i; // How many o2 sensors can we find in this sample? if (s->o2sensor[0].mbar) nsensor++; if (s->o2sensor[1].mbar) nsensor++; if (s->o2sensor[2].mbar) nsensor++; // If we fond more than the previous found max, record it. if (nsensor > dc->no_o2sensors) dc->no_o2sensors = nsensor; // Already found the maximum posible amount. if (nsensor == 3) return; } } static void fixup_dive_dc(struct dive *dive, struct divecomputer *dc) { /* Add device information to table */ if (dc->deviceid && (dc->serial || dc->fw_version)) create_device_node(dc->model, dc->deviceid, dc->serial, dc->fw_version, ""); /* Fixup duration and mean depth */ fixup_dc_duration(dc); /* Fix up sample depth data */ fixup_dc_depths(dive, dc); /* Fix up first sample ndl data */ fixup_dc_ndl(dc); /* Fix up dive temperatures based on dive computer samples */ fixup_dc_temp(dive, dc); /* Fix up gas switch events */ fixup_dc_gasswitch(dive, dc); /* Fix up cylinder pressures based on DC info */ fixup_dive_pressures(dive, dc); fixup_dc_events(dc); /* Fixup CCR / PSCR dives with o2sensor values, but without no_o2sensors */ fixup_no_o2sensors(dc); } struct dive *fixup_dive(struct dive *dive) { int i; struct divecomputer *dc; sanitize_cylinder_info(dive); dive->maxcns = dive->cns; /* * Use the dive's temperatures for minimum and maximum in case * we do not have temperatures recorded by DC. */ update_min_max_temperatures(dive, dive->watertemp); for_each_dc (dive, dc) fixup_dive_dc(dive, dc); fixup_water_salinity(dive); if (!dive->surface_pressure.mbar) fixup_surface_pressure(dive); fixup_meandepth(dive); fixup_duration(dive); fixup_watertemp(dive); fixup_airtemp(dive); for (i = 0; i < dive->cylinders.nr; i++) { cylinder_t *cyl = get_cylinder(dive, i); add_cylinder_description(&cyl->type); if (same_rounded_pressure(cyl->sample_start, cyl->start)) cyl->start.mbar = 0; if (same_rounded_pressure(cyl->sample_end, cyl->end)) cyl->end.mbar = 0; } update_cylinder_related_info(dive); for (i = 0; i < dive->weightsystems.nr; i++) { weightsystem_t *ws = &dive->weightsystems.weightsystems[i]; add_weightsystem_description(ws); } /* we should always have a uniq ID as that gets assigned during alloc_dive(), * but we want to make sure... */ if (!dive->id) dive->id = dive_getUniqID(); return dive; } /* Don't pick a zero for MERGE_MIN() */ #define MERGE_MAX(res, a, b, n) res->n = MAX(a->n, b->n) #define MERGE_MIN(res, a, b, n) res->n = (a->n) ? (b->n) ? MIN(a->n, b->n) : (a->n) : (b->n) #define MERGE_TXT(res, a, b, n, sep) res->n = merge_text(a->n, b->n, sep) #define MERGE_NONZERO(res, a, b, n) res->n = a->n ? a->n : b->n struct sample *add_sample(const struct sample *sample, int time, struct divecomputer *dc) { struct sample *p = prepare_sample(dc); if (p) { *p = *sample; p->time.seconds = time; finish_sample(dc); } return p; } /* * This is like add_sample(), but if the distance from the last sample * is excessive, we add two surface samples in between. * * This is so that if you merge two non-overlapping dives, we make sure * that the time in between the dives is at the surface, not some "last * sample that happened to be at a depth of 1.2m". */ static void merge_one_sample(const struct sample *sample, int time, struct divecomputer *dc) { int last = dc->samples - 1; if (last >= 0) { struct sample *prev = dc->sample + last; int last_time = prev->time.seconds; int last_depth = prev->depth.mm; /* * Only do surface events if the samples are more than * a minute apart, and shallower than 5m */ if (time > last_time + 60 && last_depth < 5000) { struct sample surface = { 0 }; /* Init a few values from prev sample to avoid useless info in XML */ surface.bearing.degrees = prev->bearing.degrees; surface.ndl.seconds = prev->ndl.seconds; add_sample(&surface, last_time + 20, dc); add_sample(&surface, time - 20, dc); } } add_sample(sample, time, dc); } static void renumber_last_sample(struct divecomputer *dc, const int mapping[]); static void sample_renumber(struct sample *s, int i, const int mapping[]); /* * Merge samples. Dive 'a' is "offset" seconds before Dive 'b' */ static void merge_samples(struct divecomputer *res, const struct divecomputer *a, const struct divecomputer *b, const int *cylinders_map_a, const int *cylinders_map_b, int offset) { int asamples = a->samples; int bsamples = b->samples; struct sample *as = a->sample; struct sample *bs = b->sample; /* * We want a positive sample offset, so that sample * times are always positive. So if the samples for * 'b' are before the samples for 'a' (so the offset * is negative), we switch a and b around, and use * the reverse offset. */ if (offset < 0) { const int *cylinders_map_tmp; offset = -offset; asamples = bsamples; bsamples = a->samples; as = bs; bs = a->sample; cylinders_map_tmp = cylinders_map_a; cylinders_map_a = cylinders_map_b; cylinders_map_b = cylinders_map_tmp; } for (;;) { int j; int at, bt; struct sample sample = { .bearing.degrees = -1, .ndl.seconds = -1 }; if (!res) return; at = asamples ? as->time.seconds : -1; bt = bsamples ? bs->time.seconds + offset : -1; /* No samples? All done! */ if (at < 0 && bt < 0) return; /* Only samples from a? */ if (bt < 0) { add_sample_a: merge_one_sample(as, at, res); renumber_last_sample(res, cylinders_map_a); as++; asamples--; continue; } /* Only samples from b? */ if (at < 0) { add_sample_b: merge_one_sample(bs, bt, res); renumber_last_sample(res, cylinders_map_b); bs++; bsamples--; continue; } if (at < bt) goto add_sample_a; if (at > bt) goto add_sample_b; /* same-time sample: add a merged sample. Take the non-zero ones */ sample = *bs; sample_renumber(&sample, 0, cylinders_map_b); if (as->depth.mm) sample.depth = as->depth; if (as->temperature.mkelvin) sample.temperature = as->temperature; for (j = 0; j < MAX_SENSORS; ++j) { int sensor_id; sensor_id = cylinders_map_a[as->sensor[j]]; if (sensor_id < 0) continue; if (as->pressure[j].mbar) sample.pressure[j] = as->pressure[j]; if (as->sensor[j]) sample.sensor[j] = sensor_id; } if (as->cns) sample.cns = as->cns; if (as->setpoint.mbar) sample.setpoint = as->setpoint; if (as->ndl.seconds) sample.ndl = as->ndl; if (as->stoptime.seconds) sample.stoptime = as->stoptime; if (as->stopdepth.mm) sample.stopdepth = as->stopdepth; if (as->in_deco) sample.in_deco = true; merge_one_sample(&sample, at, res); as++; bs++; asamples--; bsamples--; } } /* * Does the extradata key/value pair already exist in the * supplied dive computer data? * * This is not hugely efficient (with the whole "do this for * every value you merge" it's O(n**2)) but it's not like we * have very many extra_data entries per dive computer anyway. */ static bool extra_data_exists(const struct extra_data *ed, const struct divecomputer *dc) { const struct extra_data *p; for (p = dc->extra_data; p; p = p->next) { if (strcmp(p->key, ed->key)) continue; if (strcmp(p->value, ed->value)) continue; return true; } return false; } /* * Merge extra_data. * * The extra data from 'a' has already been copied into 'res'. So * we really should just copy over the data from 'b' too. */ static void merge_extra_data(struct divecomputer *res, const struct divecomputer *a, const struct divecomputer *b) { struct extra_data **ed, *src; // Find the place to add things in the result ed = &res->extra_data; while (*ed) ed = &(*ed)->next; for (src = b->extra_data; src; src = src->next) { if (extra_data_exists(src, a)) continue; *ed = malloc(sizeof(struct extra_data)); if (!*ed) break; copy_extra_data(src, *ed); ed = &(*ed)->next; } // Terminate the result list *ed = NULL; } static char *merge_text(const char *a, const char *b, const char *sep) { char *res; if (!a && !b) return NULL; if (!a || !*a) return copy_string(b); if (!b || !*b) return strdup(a); if (!strcmp(a, b)) return copy_string(a); res = malloc(strlen(a) + strlen(b) + 32); if (!res) return (char *)a; sprintf(res, "%s%s%s", a, sep, b); return res; } #define SORT(a, b) \ if (a != b) \ return a < b ? -1 : 1 #define SORT_FIELD(a, b, field) SORT(a->field, b->field) static int sort_event(const struct event *a, const struct event *b, int time_a, int time_b) { SORT(time_a, time_b); SORT_FIELD(a, b, type); SORT_FIELD(a, b, flags); SORT_FIELD(a, b, value); return strcmp(a->name, b->name); } static int same_gas(const struct event *a, const struct event *b) { if (a->type == b->type && a->flags == b->flags && a->value == b->value && !strcmp(a->name, b->name) && same_gasmix(a->gas.mix, b->gas.mix)) { return true; } return false; } static void event_renumber(struct event *ev, const int mapping[]); static void add_initial_gaschange(struct dive *dive, struct divecomputer *dc, int offset, int idx); static void merge_events(struct dive *d, struct divecomputer *res, const struct divecomputer *src1, const struct divecomputer *src2, const int *cylinders_map1, const int *cylinders_map2, int offset) { const struct event *a, *b; struct event **p = &res->events; const struct event *last_gas = NULL; /* Always use positive offsets */ if (offset < 0) { const struct divecomputer *tmp; const int *cylinders_map_tmp; offset = -offset; tmp = src1; src1 = src2; src2 = tmp; cylinders_map_tmp = cylinders_map1; cylinders_map1 = cylinders_map2; cylinders_map2 = cylinders_map_tmp; } a = src1->events; b = src2->events; while (a || b) { int s; const struct event *pick; const int *cylinders_map; int event_offset; if (!b) { *p = clone_event(a); event_renumber(*p, cylinders_map1); break; } if (!a) { *p = clone_event(b); (*p)->time.seconds += offset; event_renumber(*p, cylinders_map2); break; } s = sort_event(a, b, a->time.seconds, b->time.seconds + offset); /* Identical events? Just skip one of them (we pick a) */ if (!s) { a = a->next; continue; } /* Otherwise, pick the one that sorts first */ if (s < 0) { pick = a; a = a->next; event_offset = 0; cylinders_map = cylinders_map1; } else { pick = b; b = b->next; event_offset = offset; cylinders_map = cylinders_map2; } /* * If that's a gas-change that matches the previous * gas change, we'll just skip it */ if (event_is_gaschange(pick)) { if (last_gas && same_gas(pick, last_gas)) continue; last_gas = pick; } /* Add it to the target list */ *p = clone_event(pick); (*p)->time.seconds += event_offset; event_renumber(*p, cylinders_map); p = &(*p)->next; } /* If the initial cylinder of a divecomputer was remapped, add a gas change event to that cylinder */ if (cylinders_map1[0] > 0) add_initial_gaschange(d, res, 0, cylinders_map1[0]); if (cylinders_map2[0] > 0) add_initial_gaschange(d, res, offset, cylinders_map2[0]); } /* get_cylinder_idx_by_use(): Find the index of the first cylinder with a particular CCR use type. * The index returned corresponds to that of the first cylinder with a cylinder_use that * equals the appropriate enum value [oxygen, diluent, bailout] given by cylinder_use_type. * A negative number returned indicates that a match could not be found. * Call parameters: dive = the dive being processed * cylinder_use_type = an enum, one of {oxygen, diluent, bailout} */ extern int get_cylinder_idx_by_use(const struct dive *dive, enum cylinderuse cylinder_use_type) { int cylinder_index; for (cylinder_index = 0; cylinder_index < dive->cylinders.nr; cylinder_index++) { if (get_cylinder(dive, cylinder_index)->cylinder_use == cylinder_use_type) return cylinder_index; // return the index of the cylinder with that cylinder use type } return -1; // negative number means cylinder_use_type not found in list of cylinders } /* fill_pressures(): Compute partial gas pressures in bar from gasmix and ambient pressures, possibly for OC or CCR, to be * extended to PSCT. This function does the calculations of gas pressures applicable to a single point on the dive profile. * The structure "pressures" is used to return calculated gas pressures to the calling software. * Call parameters: po2 = po2 value applicable to the record in calling function * amb_pressure = ambient pressure applicable to the record in calling function * *pressures = structure for communicating o2 sensor values from and gas pressures to the calling function. * *mix = structure containing cylinder gas mixture information. * divemode = the dive mode pertaining to this point in the dive profile. * This function called by: calculate_gas_information_new() in profile.c; add_segment() in deco.c. */ void fill_pressures(struct gas_pressures *pressures, const double amb_pressure, struct gasmix mix, double po2, enum divemode_t divemode) { if ((divemode != OC) && po2) { // This is a rebreather dive where pressures->o2 is defined if (po2 >= amb_pressure) { pressures->o2 = amb_pressure; pressures->n2 = pressures->he = 0.0; } else { pressures->o2 = po2; if (get_o2(mix) == 1000) { pressures->he = pressures->n2 = 0; } else { pressures->he = (amb_pressure - pressures->o2) * (double)get_he(mix) / (1000 - get_o2(mix)); pressures->n2 = amb_pressure - pressures->o2 - pressures->he; } } } else { if (divemode == PSCR) { /* The steady state approximation should be good enough */ pressures->o2 = get_o2(mix) / 1000.0 * amb_pressure - (1.0 - get_o2(mix) / 1000.0) * prefs.o2consumption / (prefs.bottomsac * prefs.pscr_ratio / 1000.0); if (pressures->o2 < 0) // He's dead, Jim. pressures->o2 = 0; if (get_o2(mix) != 1000) { pressures->he = (amb_pressure - pressures->o2) * get_he(mix) / (1000.0 - get_o2(mix)); pressures->n2 = (amb_pressure - pressures->o2) * (1000 - get_o2(mix) - get_he(mix)) / (1000.0 - get_o2(mix)); } else { pressures->he = pressures->n2 = 0; } } else { // Open circuit dives: no gas pressure values available, they need to be calculated pressures->o2 = get_o2(mix) / 1000.0 * amb_pressure; // These calculations are also used if the CCR calculation above.. pressures->he = get_he(mix) / 1000.0 * amb_pressure; // ..returned a po2 of zero (i.e. o2 sensor data not resolvable) pressures->n2 = (1000 - get_o2(mix) - get_he(mix)) / 1000.0 * amb_pressure; } } } /* Force an initial gaschange event to the (old) gas #0 */ static void add_initial_gaschange(struct dive *dive, struct divecomputer *dc, int offset, int idx) { /* if there is a gaschange event up to 30 sec after the initial event, * refrain from adding the initial event */ const struct event *ev = dc->events; while(ev && (ev = get_next_event(ev, "gaschange")) != NULL) { if (ev->time.seconds > offset + 30) break; else if (ev->time.seconds > offset) return; ev = ev->next; } /* Old starting gas mix */ add_gas_switch_event(dive, dc, offset, idx); } static void sample_renumber(struct sample *s, int i, const int mapping[]) { int j; for (j = 0; j < MAX_SENSORS; j++) { int sensor; sensor = mapping[s->sensor[j]]; if (sensor == -1) { // Remove sensor and gas pressure info if (i == 0) { s->sensor[j] = 0; s->pressure[j].mbar = 0; } else { s->sensor[j] = s[-1].sensor[j]; s->pressure[j].mbar = s[-1].pressure[j].mbar; } } else { s->sensor[j] = sensor; } } } static void renumber_last_sample(struct divecomputer *dc, const int mapping[]) { int idx; if (dc->samples <= 0) return; idx = dc->samples - 1; sample_renumber(dc->sample + idx, idx, mapping); } static void event_renumber(struct event *ev, const int mapping[]) { if (!event_is_gaschange(ev)) return; if (ev->gas.index < 0) return; ev->gas.index = mapping[ev->gas.index]; } static void dc_cylinder_renumber(struct dive *dive, struct divecomputer *dc, const int mapping[]) { int i; struct event *ev; /* Remap or delete the sensor indices */ for (i = 0; i < dc->samples; i++) sample_renumber(dc->sample + i, i, mapping); /* Remap the gas change indices */ for (ev = dc->events; ev; ev = ev->next) event_renumber(ev, mapping); /* If the initial cylinder of a dive was remapped, add a gas change event to that cylinder */ if (mapping[0] > 0) add_initial_gaschange(dive, dc, 0, mapping[0]); } /* * If the cylinder indices change (due to merging dives or deleting * cylinders in the middle), we need to change the indices in the * dive computer data for this dive. * * Also note that we assume that the initial cylinder is cylinder 0, * so if that got renamed, we need to create a fake gas change event */ void cylinder_renumber(struct dive *dive, int mapping[]) { struct divecomputer *dc; for_each_dc (dive, dc) dc_cylinder_renumber(dive, dc, mapping); } int same_gasmix_cylinder(const cylinder_t *cyl, int cylid, const struct dive *dive, bool check_unused) { struct gasmix mygas = cyl->gasmix; for (int i = 0; i < dive->cylinders.nr; i++) { if (i == cylid) continue; struct gasmix gas2 = get_cylinder(dive, i)->gasmix; if (gasmix_distance(mygas, gas2) == 0 && (is_cylinder_used(dive, i) || check_unused)) return i; } return -1; } static int pdiff(pressure_t a, pressure_t b) { return a.mbar && b.mbar && a.mbar != b.mbar; } static int different_manual_pressures(const cylinder_t *a, const cylinder_t *b) { return pdiff(a->start, b->start) || pdiff(a->end, b->end); } /* * Can we find an exact match for a cylinder in another dive? * Take the "already matched" map into account, so that we * don't match multiple similar cylinders to one target. * * To match, the cylinders have to have the same gasmix and the * same cylinder use (ie OC/Diluent/Oxygen), and if pressures * have been added manually they need to match. */ static int match_cylinder(const cylinder_t *cyl, const struct dive *dive, const bool *used) { int i; for (i = 0; i < dive->cylinders.nr; i++) { const cylinder_t *target; if (!used[i]) continue; target = get_cylinder(dive, i); if (!same_gasmix(cyl->gasmix, target->gasmix)) continue; if (cyl->cylinder_use != target->cylinder_use) continue; if (different_manual_pressures(cyl, target)) continue; /* open question: Should we check sizes too? */ return i; } return -1; } /* * We matched things up so that they have the same gasmix and * use, but we might want to fill in any missing cylinder details * in 'a' if we had it from 'b'. */ static void merge_one_cylinder(struct cylinder_table *t, const cylinder_t *a, const cylinder_t *b) { cylinder_t *res = add_empty_cylinder(t); res->type.size.mliter = a->type.size.mliter ? a->type.size.mliter : b->type.size.mliter; res->type.workingpressure.mbar = a->type.workingpressure.mbar ? a->type.workingpressure.mbar : b->type.workingpressure.mbar; res->type.description = !empty_string(a->type.description) ? copy_string(a->type.description) : copy_string(b->type.description); res->gasmix = a->gasmix; res->start.mbar = a->start.mbar ? a->start.mbar : b->start.mbar; res->end.mbar = a->end.mbar ? a->end.mbar : b->end.mbar; if (a->sample_start.mbar && b->sample_start.mbar) res->sample_start.mbar = a->sample_start.mbar > b->sample_start.mbar ? a->sample_start.mbar : b->sample_start.mbar; else res->sample_start.mbar = 0; if (a->sample_end.mbar && b->sample_end.mbar) res->sample_end.mbar = a->sample_end.mbar < b->sample_end.mbar ? a->sample_end.mbar : b->sample_end.mbar; else res->sample_end.mbar = 0; res->depth = a->depth; res->manually_added = a->manually_added; res->gas_used.mliter = a->gas_used.mliter + b->gas_used.mliter; res->deco_gas_used.mliter = a->deco_gas_used.mliter + b->deco_gas_used.mliter; res->bestmix_o2 = a->bestmix_o2 && b->bestmix_o2; res->bestmix_he = a->bestmix_he && b->bestmix_he; } /* * Merging cylinder information is non-trivial, because the two dive computers * may have different ideas of what the different cylinder indexing is. * * Logic: take all the cylinder information from the preferred dive ('a'), and * then try to match each of the cylinders in the other dive by the gasmix that * is the best match and hasn't been used yet. * * For each dive, a cylinder-renumbering table is returned. */ static void merge_cylinders(struct dive *res, const struct dive *a, const struct dive *b, int mapping_a[], int mapping_b[]) { int i; bool *used_in_a = malloc(a->cylinders.nr * sizeof(bool)); bool *used_in_b = malloc(b->cylinders.nr * sizeof(bool)); /* First, clear all cylinders in destination */ clear_cylinder_table(&res->cylinders); /* Calculate usage map of cylinders */ for (i = 0; i < a->cylinders.nr; i++) { used_in_a[i] = is_cylinder_used(a, i); mapping_a[i] = -1; } for (i = 0; i < b->cylinders.nr; i++) { used_in_b[i] = is_cylinder_used(b, i); mapping_b[i] = -1; } /* For each cylinder in 'b', try to match up things */ for (i = 0; i < b->cylinders.nr; i++) { int j; if (!used_in_b[i]) continue; j = match_cylinder(get_cylinder(b, i), a, used_in_a); if (j < 0) continue; /* * If we had a successful match, we: * * - try to merge individual cylinder data from both cases * * - save that in the mapping table * * - remove it from the used array so that it will not be used later * * - mark as needing renumbering if the index changed */ mapping_b[i] = res->cylinders.nr; mapping_a[j] = res->cylinders.nr; used_in_a[i] = false; used_in_b[j] = false; merge_one_cylinder(&res->cylinders, get_cylinder(a, j), get_cylinder(b, i)); } /* Now copy all the used cylinders from 'a' that are used but have not been matched */ for (i = 0; i < a->cylinders.nr; i++) { if (used_in_a[i]) { mapping_a[i] = res->weightsystems.nr; add_cloned_cylinder(&res->cylinders, *get_cylinder(a, i)); } } /* Finally, copy all the used cylinders from 'b' that are used but have not been matched */ for (i = 0; i < b->cylinders.nr; i++) { if (used_in_b[i]) { mapping_b[i] = res->weightsystems.nr; add_cloned_cylinder(&res->cylinders, *get_cylinder(b, i)); } } free(used_in_a); free(used_in_b); } /* Check whether a weightsystem table contains a given weightsystem */ static bool has_weightsystem(const struct weightsystem_table *t, const weightsystem_t w) { int i; for (i = 0; i < t->nr; i++) { if (same_weightsystem(w, t->weightsystems[i])) return true; } return false; } static void merge_equipment(struct dive *res, const struct dive *a, const struct dive *b) { int i; for (i = 0; i < a->weightsystems.nr; i++) { if (!has_weightsystem(&res->weightsystems, a->weightsystems.weightsystems[i])) add_cloned_weightsystem(&res->weightsystems, a->weightsystems.weightsystems[i]); } for (i = 0; i < b->weightsystems.nr; i++) { if (!has_weightsystem(&res->weightsystems, b->weightsystems.weightsystems[i])) add_cloned_weightsystem(&res->weightsystems, b->weightsystems.weightsystems[i]); } } static void merge_temperatures(struct dive *res, const struct dive *a, const struct dive *b) { temperature_t airtemp_a = un_fixup_airtemp(a); temperature_t airtemp_b = un_fixup_airtemp(b); res->airtemp = airtemp_a.mkelvin ? airtemp_a : airtemp_b; MERGE_NONZERO(res, a, b, watertemp.mkelvin); } /* * Pick a trip for a dive */ static struct dive_trip *get_preferred_trip(const struct dive *a, const struct dive *b) { dive_trip_t *atrip, *btrip; /* If only one dive has a trip, choose that */ atrip = a->divetrip; btrip = b->divetrip; if (!atrip) return btrip; if (!btrip) return atrip; /* Both dives have a trip - prefer the non-autogenerated one */ if (atrip->autogen && !btrip->autogen) return btrip; if (!atrip->autogen && btrip->autogen) return atrip; /* Otherwise, look at the trip data and pick the "better" one */ if (!atrip->location) return btrip; if (!btrip->location) return atrip; if (!atrip->notes) return btrip; if (!btrip->notes) return atrip; /* * Ok, so both have location and notes. * Pick the earlier one. */ if (a->when < b->when) return atrip; return btrip; } #if CURRENTLY_NOT_USED /* * Sample 's' is between samples 'a' and 'b'. It is 'offset' seconds before 'b'. * * If 's' and 'a' are at the same time, offset is 0, and b is NULL. */ static int compare_sample(struct sample *s, struct sample *a, struct sample *b, int offset) { unsigned int depth = a->depth.mm; int diff; if (offset) { unsigned int interval = b->time.seconds - a->time.seconds; unsigned int depth_a = a->depth.mm; unsigned int depth_b = b->depth.mm; if (offset > interval) return -1; /* pick the average depth, scaled by the offset from 'b' */ depth = (depth_a * offset) + (depth_b * (interval - offset)); depth /= interval; } diff = s->depth.mm - depth; if (diff < 0) diff = -diff; /* cut off at one meter difference */ if (diff > 1000) diff = 1000; return diff * diff; } /* * Calculate a "difference" in samples between the two dives, given * the offset in seconds between them. Use this to find the best * match of samples between two different dive computers. */ static unsigned long sample_difference(struct divecomputer *a, struct divecomputer *b, int offset) { int asamples = a->samples; int bsamples = b->samples; struct sample *as = a->sample; struct sample *bs = b->sample; unsigned long error = 0; int start = -1; if (!asamples || !bsamples) return 0; /* * skip the first sample - this way we know can always look at * as/bs[-1] to look at the samples around it in the loop. */ as++; bs++; asamples--; bsamples--; for (;;) { int at, bt, diff; /* If we run out of samples, punt */ if (!asamples) return INT_MAX; if (!bsamples) return INT_MAX; at = as->time.seconds; bt = bs->time.seconds + offset; /* b hasn't started yet? Ignore it */ if (bt < 0) { bs++; bsamples--; continue; } if (at < bt) { diff = compare_sample(as, bs - 1, bs, bt - at); as++; asamples--; } else if (at > bt) { diff = compare_sample(bs, as - 1, as, at - bt); bs++; bsamples--; } else { diff = compare_sample(as, bs, NULL, 0); as++; bs++; asamples--; bsamples--; } /* Invalid comparison point? */ if (diff < 0) continue; if (start < 0) start = at; error += diff; if (at - start > 120) break; } return error; } /* * Dive 'a' is 'offset' seconds before dive 'b' * * This is *not* because the dive computers clocks aren't in sync, * it is because the dive computers may "start" the dive at different * points in the dive, so the sample at time X in dive 'a' is the * same as the sample at time X+offset in dive 'b'. * * For example, some dive computers take longer to "wake up" when * they sense that you are under water (ie Uemis Zurich if it was off * when the dive started). And other dive computers have different * depths that they activate at, etc etc. * * If we cannot find a shared offset, don't try to merge. */ static int find_sample_offset(struct divecomputer *a, struct divecomputer *b) { int offset, best; unsigned long max; /* No samples? Merge at any time (0 offset) */ if (!a->samples) return 0; if (!b->samples) return 0; /* * Common special-case: merging a dive that came from * the same dive computer, so the samples are identical. * Check this first, without wasting time trying to find * some minimal offset case. */ best = 0; max = sample_difference(a, b, 0); if (!max) return 0; /* * Otherwise, look if we can find anything better within * a thirty second window.. */ for (offset = -30; offset <= 30; offset++) { unsigned long diff; diff = sample_difference(a, b, offset); if (diff > max) continue; best = offset; max = diff; } return best; } #endif /* * Are a and b "similar" values, when given a reasonable lower end expected * difference? * * So for example, we'd expect different dive computers to give different * max. depth readings. You might have them on different arms, and they * have different pressure sensors and possibly different ideas about * water salinity etc. * * So have an expected minimum difference, but also allow a larger relative * error value. */ static int similar(unsigned long a, unsigned long b, unsigned long expected) { if (!a && !b) return 1; if (a && b) { unsigned long min, max, diff; min = a; max = b; if (a > b) { min = b; max = a; } diff = max - min; /* Smaller than expected difference? */ if (diff < expected) return 1; /* Error less than 10% or the maximum */ if (diff * 10 < max) return 1; } return 0; } /* * Match two dive computer entries against each other, and * tell if it's the same dive. Return 0 if "don't know", * positive for "same dive" and negative for "definitely * not the same dive" */ int match_one_dc(const struct divecomputer *a, const struct divecomputer *b) { /* Not same model? Don't know if matching.. */ if (!a->model || !b->model) return 0; if (strcasecmp(a->model, b->model)) return 0; /* Different device ID's? Don't know */ if (a->deviceid != b->deviceid) return 0; /* Do we have dive IDs? */ if (!a->diveid || !b->diveid) return 0; /* * If they have different dive ID's on the same * dive computer, that's a definite "same or not" */ return a->diveid == b->diveid && a->when == b->when ? 1 : -1; } /* * Match every dive computer against each other to see if * we have a matching dive. * * Return values: * -1 for "is definitely *NOT* the same dive" * 0 for "don't know" * 1 for "is definitely the same dive" */ static int match_dc_dive(const struct divecomputer *a, const struct divecomputer *b) { do { const struct divecomputer *tmp = b; do { int match = match_one_dc(a, tmp); if (match) return match; tmp = tmp->next; } while (tmp); a = a->next; } while (a); return 0; } /* * Do we want to automatically try to merge two dives that * look like they are the same dive? * * This happens quite commonly because you download a dive * that you already had, or perhaps because you maintained * multiple dive logs and want to load them all together * (possibly one of them was imported from another dive log * application entirely). * * NOTE! We mainly look at the dive time, but it can differ * between two dives due to a few issues: * * - rounding the dive date to the nearest minute in other dive * applications * * - dive computers with "relative datestamps" (ie the dive * computer doesn't actually record an absolute date at all, * but instead at download-time synchronizes its internal * time with real-time on the downloading computer) * * - using multiple dive computers with different real time on * the same dive * * We do not merge dives that look radically different, and if * the dates are *too* far off the user will have to join two * dives together manually. But this tries to handle the sane * cases. */ static int likely_same_dive(const struct dive *a, const struct dive *b) { int match, fuzz = 20 * 60; /* don't merge manually added dives with anything */ if (same_string(a->dc.model, "manually added dive") || same_string(b->dc.model, "manually added dive")) return 0; /* * Do some basic sanity testing of the values we * have filled in during 'fixup_dive()' */ if (!similar(a->maxdepth.mm, b->maxdepth.mm, 1000) || (a->meandepth.mm && b->meandepth.mm && !similar(a->meandepth.mm, b->meandepth.mm, 1000)) || !a->duration.seconds || !b->duration.seconds || !similar(a->duration.seconds, b->duration.seconds, 5 * 60)) return 0; /* See if we can get an exact match on the dive computer */ match = match_dc_dive(&a->dc, &b->dc); if (match) return match > 0; /* * Allow a time difference due to dive computer time * setting etc. Check if they overlap. */ fuzz = MAX(a->duration.seconds, b->duration.seconds) / 2; if (fuzz < 60) fuzz = 60; return (a->when <= b->when + fuzz) && (a->when >= b->when - fuzz); } /* * This could do a lot more merging. Right now it really only * merges almost exact duplicates - something that happens easily * with overlapping dive downloads. * * If new dives are merged into the dive table, dive a is supposed to * be the old dive and dive b is supposed to be the newly imported * dive. If the flag "prefer_downloaded" is set, data of the latter * will take priority over the former. * * Attn: The dive_site parameter of the dive will be set, but the caller * still has to register the dive in the dive site! */ struct dive *try_to_merge(struct dive *a, struct dive *b, bool prefer_downloaded) { struct dive *res; struct dive_site *site; if (!likely_same_dive(a, b)) return NULL; res = merge_dives(a, b, 0, prefer_downloaded, NULL, &site); res->dive_site = site; /* Caller has to call add_dive_to_dive_site()! */ return res; } void free_events(struct event *ev) { while (ev) { struct event *next = ev->next; free(ev); ev = next; } } static void free_extra_data(struct extra_data *ed) { free((void *)ed->key); free((void *)ed->value); } static void free_dc_contents(struct divecomputer *dc) { free(dc->sample); free((void *)dc->model); free((void *)dc->serial); free((void *)dc->fw_version); free_events(dc->events); STRUCTURED_LIST_FREE(struct extra_data, dc->extra_data, free_extra_data); } static void free_dc(struct divecomputer *dc) { free_dc_contents(dc); free(dc); } static int same_sample(struct sample *a, struct sample *b) { if (a->time.seconds != b->time.seconds) return 0; if (a->depth.mm != b->depth.mm) return 0; if (a->temperature.mkelvin != b->temperature.mkelvin) return 0; if (a->pressure[0].mbar != b->pressure[0].mbar) return 0; return a->sensor[0] == b->sensor[0]; } static int same_dc(struct divecomputer *a, struct divecomputer *b) { int i; const struct event *eva, *evb; i = match_one_dc(a, b); if (i) return i > 0; if (a->when && b->when && a->when != b->when) return 0; if (a->samples != b->samples) return 0; for (i = 0; i < a->samples; i++) if (!same_sample(a->sample + i, b->sample + i)) return 0; eva = a->events; evb = b->events; while (eva && evb) { if (!same_event(eva, evb)) return 0; eva = eva->next; evb = evb->next; } return eva == evb; } static int might_be_same_device(const struct divecomputer *a, const struct divecomputer *b) { /* No dive computer model? That matches anything */ if (!a->model || !b->model) return 1; /* Otherwise at least the model names have to match */ if (strcasecmp(a->model, b->model)) return 0; /* No device ID? Match */ if (!a->deviceid || !b->deviceid) return 1; return a->deviceid == b->deviceid; } static void remove_redundant_dc(struct divecomputer *dc, int prefer_downloaded) { do { struct divecomputer **p = &dc->next; /* Check this dc against all the following ones.. */ while (*p) { struct divecomputer *check = *p; if (same_dc(dc, check) || (prefer_downloaded && might_be_same_device(dc, check))) { *p = check->next; check->next = NULL; free_dc(check); continue; } p = &check->next; } /* .. and then continue down the chain, but we */ prefer_downloaded = 0; dc = dc->next; } while (dc); } static const struct divecomputer *find_matching_computer(const struct divecomputer *match, const struct divecomputer *list) { const struct divecomputer *p; while ((p = list) != NULL) { list = list->next; if (might_be_same_device(match, p)) break; } return p; } static void copy_dive_computer(struct divecomputer *res, const struct divecomputer *a) { *res = *a; res->model = copy_string(a->model); res->serial = copy_string(a->serial); res->fw_version = copy_string(a->fw_version); STRUCTURED_LIST_COPY(struct extra_data, a->extra_data, res->extra_data, copy_extra_data); res->samples = res->alloc_samples = 0; res->sample = NULL; res->events = NULL; res->next = NULL; } /* * Join dive computers with a specific time offset between * them. * * Use the dive computer ID's (or names, if ID's are missing) * to match them up. If we find a matching dive computer, we * merge them. If not, we just take the data from 'a'. */ static void interleave_dive_computers(struct dive *d, struct divecomputer *res, const struct divecomputer *a, const struct divecomputer *b, const int cylinders_map_a[], const int cylinders_map_b[], int offset) { do { const struct divecomputer *match; copy_dive_computer(res, a); match = find_matching_computer(a, b); if (match) { merge_events(d, res, a, match, cylinders_map_a, cylinders_map_b, offset); merge_samples(res, a, match, cylinders_map_a, cylinders_map_b, offset); merge_extra_data(res, a, match); /* Use the diveid of the later dive! */ if (offset > 0) res->diveid = match->diveid; } else { copy_dc_renumber(d, a, res, cylinders_map_a); } a = a->next; if (!a) break; res->next = calloc(1, sizeof(struct divecomputer)); res = res->next; } while (res); } /* * Join dive computer information. * * If we have old-style dive computer information (no model * name etc), we will prefer a new-style one and just throw * away the old. We're assuming it's a re-download. * * Otherwise, we'll just try to keep all the information, * unless the user has specified that they prefer the * downloaded computer, in which case we'll aggressively * try to throw out old information that *might* be from * that one. */ static void join_dive_computers(struct dive *d, struct divecomputer *res, const struct divecomputer *a, const struct divecomputer *b, const int cylinders_map_a[], const int cylinders_map_b[], int prefer_downloaded) { struct divecomputer *tmp; if (a->model && !b->model) { copy_dc_renumber(d, a, res, cylinders_map_a); return; } if (b->model && !a->model) { copy_dc_renumber(d, b, res, cylinders_map_b); return; } copy_dc_renumber(d, a, res, cylinders_map_a); tmp = res; while (tmp->next) tmp = tmp->next; tmp->next = calloc(1, sizeof(*tmp)); copy_dc_renumber(d, b, tmp->next, cylinders_map_b); remove_redundant_dc(res, prefer_downloaded); } bool is_dc_planner(const struct divecomputer *dc) { return same_string(dc->model, "planned dive"); } // Does this dive have a dive computer for which is_dc_planner has value planned bool has_planned(const struct dive *dive, bool planned) { const struct divecomputer *dc = &dive->dc; while (dc) { if (is_dc_planner(&dive->dc) == planned) return true; dc = dc->next; } return false; } /* * Merging two dives can be subtle, because there's two different ways * of merging: * * (a) two distinctly _different_ dives that have the same dive computer * are merged into one longer dive, because the user asked for it * in the divelist. * * Because this case is with the same dive computer, we *know* the * two must have a different start time, and "offset" is the relative * time difference between the two. * * (b) two different dive computers that we might want to merge into * one single dive with multiple dive computers. * * This is the "try_to_merge()" case, which will have offset == 0, * even if the dive times might be different. * * If new dives are merged into the dive table, dive a is supposed to * be the old dive and dive b is supposed to be the newly imported * dive. If the flag "prefer_downloaded" is set, data of the latter * will take priority over the former. * * The trip the new dive should be associated with (if any) is returned * in the "trip" output parameter. * * The dive site the new dive should be added to (if any) is returned * in the "dive_site" output parameter. */ struct dive *merge_dives(const struct dive *a, const struct dive *b, int offset, bool prefer_downloaded, struct dive_trip **trip, struct dive_site **site) { struct dive *res = alloc_dive(); int *cylinders_map_a, *cylinders_map_b; if (offset) { /* * If "likely_same_dive()" returns true, that means that * it is *not* the same dive computer, and we do not want * to try to turn it into a single longer dive. So we'd * join them as two separate dive computers at zero offset. */ if (likely_same_dive(a, b)) offset = 0; } if (is_dc_planner(&a->dc)) { const struct dive *tmp = a; a = b; b = tmp; } res->when = prefer_downloaded ? b->when : a->when; res->selected = a->selected || b->selected; if (trip) *trip = get_preferred_trip(a, b); MERGE_TXT(res, a, b, notes, "\n--\n"); MERGE_TXT(res, a, b, buddy, ", "); MERGE_TXT(res, a, b, divemaster, ", "); MERGE_MAX(res, a, b, rating); MERGE_TXT(res, a, b, suit, ", "); MERGE_MAX(res, a, b, number); MERGE_NONZERO(res, a, b, cns); MERGE_NONZERO(res, a, b, visibility); STRUCTURED_LIST_COPY(struct picture, a->picture_list ? a->picture_list : b->picture_list, res->picture_list, copy_pl); taglist_merge(&res->tag_list, a->tag_list, b->tag_list); cylinders_map_a = malloc(a->cylinders.nr * sizeof(*cylinders_map_a)); cylinders_map_b = malloc(b->cylinders.nr * sizeof(*cylinders_map_b)); merge_cylinders(res, a, b, cylinders_map_a, cylinders_map_b); merge_equipment(res, a, b); merge_temperatures(res, a, b); if (prefer_downloaded) { /* If we prefer downloaded, do those first, and get rid of "might be same" computers */ join_dive_computers(res, &res->dc, &b->dc, &a->dc, cylinders_map_b, cylinders_map_a, 1); } else if (offset && might_be_same_device(&a->dc, &b->dc)) interleave_dive_computers(res, &res->dc, &a->dc, &b->dc, cylinders_map_a, cylinders_map_b, offset); else join_dive_computers(res, &res->dc, &a->dc, &b->dc, cylinders_map_a, cylinders_map_b, 0); /* we take the first dive site, unless it's empty */ *site = a->dive_site && !dive_site_is_empty(a->dive_site) ? a->dive_site : b->dive_site; fixup_dive(res); free(cylinders_map_a); free(cylinders_map_b); return res; } // copy_dive(), but retaining the new ID for the copied dive static struct dive *create_new_copy(const struct dive *from) { struct dive *to = alloc_dive(); int id; // alloc_dive() gave us a new ID, we just need to // make sure it's not overwritten. id = to->id; copy_dive(from, to); to->id = id; return to; } struct start_end_pressure { pressure_t start; pressure_t end; }; static void force_fixup_dive(struct dive *d) { struct divecomputer *dc = &d->dc; int old_temp = dc->watertemp.mkelvin; int old_mintemp = d->mintemp.mkelvin; int old_maxtemp = d->maxtemp.mkelvin; duration_t old_duration = d->duration; struct start_end_pressure *old_pressures = malloc(d->cylinders.nr * sizeof(*old_pressures)); d->maxdepth.mm = 0; dc->maxdepth.mm = 0; d->watertemp.mkelvin = 0; dc->watertemp.mkelvin = 0; d->duration.seconds = 0; d->maxtemp.mkelvin = 0; d->mintemp.mkelvin = 0; for (int i = 0; i < d->cylinders.nr; i++) { cylinder_t *cyl = get_cylinder(d, i); old_pressures[i].start = cyl->start; old_pressures[i].end = cyl->end; cyl->start.mbar = 0; cyl->end.mbar = 0; } fixup_dive(d); if (!d->watertemp.mkelvin) d->watertemp.mkelvin = old_temp; if (!dc->watertemp.mkelvin) dc->watertemp.mkelvin = old_temp; if (!d->maxtemp.mkelvin) d->maxtemp.mkelvin = old_maxtemp; if (!d->mintemp.mkelvin) d->mintemp.mkelvin = old_mintemp; if (!d->duration.seconds) d->duration = old_duration; for (int i = 0; i < d->cylinders.nr; i++) { if (!get_cylinder(d, i)->start.mbar) get_cylinder(d, i)->start = old_pressures[i].start; if (!get_cylinder(d, i)->end.mbar) get_cylinder(d, i)->end = old_pressures[i].end; } free(old_pressures); } /* * Split a dive that has a surface interval from samples 'a' to 'b' * into two dives, but don't add them to the log yet. * Returns the nr of the old dive or <0 on failure. * Moreover, on failure both output dives are set to NULL. * On success, the newly allocated dives are returned in out1 and out2. */ static int split_dive_at(const struct dive *dive, int a, int b, struct dive **out1, struct dive **out2) { int i, nr; uint32_t t; struct dive *d1, *d2; struct divecomputer *dc1, *dc2; struct event *event, **evp; /* if we can't find the dive in the dive list, don't bother */ if ((nr = get_divenr(dive)) < 0) return -1; /* Splitting should leave at least 3 samples per dive */ if (a < 3 || b > dive->dc.samples - 4) return -1; /* We're not trying to be efficient here.. */ d1 = create_new_copy(dive); d2 = create_new_copy(dive); d1->divetrip = d2->divetrip = 0; /* now unselect the first first segment so we don't keep all * dives selected by mistake. But do keep the second one selected * so the algorithm keeps splitting the dive further */ d1->selected = false; dc1 = &d1->dc; dc2 = &d2->dc; /* * Cut off the samples of d1 at the beginning * of the interval. */ dc1->samples = a; /* And get rid of the 'b' first samples of d2 */ dc2->samples -= b; memmove(dc2->sample, dc2->sample+b, dc2->samples * sizeof(struct sample)); /* Now the secondary dive computers */ t = dc2->sample[0].time.seconds; while ((dc1 = dc1->next)) { i = 0; while (dc1->samples < i && dc1->sample[i].time.seconds <= t) ++i; dc1->samples = i; } while ((dc2 = dc2->next)) { i = 0; while (dc2->samples < i && dc2->sample[i].time.seconds < t) ++i; dc2->samples -= i; memmove(dc2->sample, dc2->sample + i, dc2->samples * sizeof(struct sample)); } dc1 = &d1->dc; dc2 = &d2->dc; /* * This is where we cut off events from d1, * and shift everything in d2 */ d2->when += t; while (dc1 && dc2) { dc2->when += t; for (i = 0; i < dc2->samples; i++) dc2->sample[i].time.seconds -= t; /* Remove the events past 't' from d1 */ evp = &dc1->events; while ((event = *evp) != NULL && event->time.seconds < t) evp = &event->next; *evp = NULL; while (event) { struct event *next = event->next; free(event); event = next; } /* Remove the events before 't' from d2, and shift the rest */ evp = &dc2->events; while ((event = *evp) != NULL) { if (event->time.seconds < t) { *evp = event->next; free(event); } else { event->time.seconds -= t; } } dc1 = dc1->next; dc2 = dc2->next; } force_fixup_dive(d1); force_fixup_dive(d2); /* * Was the dive numbered? If it was the last dive, then we'll * increment the dive number for the tail part that we split off. * Otherwise the tail is unnumbered. */ if (d2->number) { if (dive_table.nr == nr + 1) d2->number++; else d2->number = 0; } *out1 = d1; *out2 = d2; return nr; } /* in freedive mode we split for as little as 10 seconds on the surface, * otherwise we use a minute */ static bool should_split(const struct divecomputer *dc, int t1, int t2) { int threshold = dc->divemode == FREEDIVE ? 10 : 60; return t2 - t1 >= threshold; } /* * Try to split a dive into multiple dives at a surface interval point. * * NOTE! We will split when there is at least one surface event that has * non-surface events on both sides. * * The surface interval points are determined using the first dive computer. * * In other words, this is a (simplified) reversal of the dive merging. */ int split_dive(const struct dive *dive, struct dive **new1, struct dive **new2) { int i; int at_surface, surface_start; const struct divecomputer *dc; *new1 = *new2 = NULL; if (!dive) return -1; dc = &dive->dc; surface_start = 0; at_surface = 1; for (i = 1; i < dc->samples; i++) { struct sample *sample = dc->sample+i; int surface_sample = sample->depth.mm < SURFACE_THRESHOLD; /* * We care about the transition from and to depth 0, * not about the depth staying similar. */ if (at_surface == surface_sample) continue; at_surface = surface_sample; // Did it become surface after having been non-surface? We found the start if (at_surface) { surface_start = i; continue; } // Going down again? We want at least a minute from // the surface start. if (!surface_start) continue; if (!should_split(dc, dc->sample[surface_start].time.seconds, sample[-1].time.seconds)) continue; return split_dive_at(dive, surface_start, i-1, new1, new2); } return -1; } int split_dive_at_time(const struct dive *dive, duration_t time, struct dive **new1, struct dive **new2) { int i = 0; if (!dive) return -1; struct sample *sample = dive->dc.sample; *new1 = *new2 = NULL; while(sample->time.seconds < time.seconds) { ++sample; ++i; if (dive->dc.samples == i) return -1; } return split_dive_at(dive, i, i - 1, new1, new2); } /* * "dc_maxtime()" is how much total time this dive computer * has for this dive. Note that it can differ from "duration" * if there are surface events in the middle. * * Still, we do ignore all but the last surface samples from the * end, because some divecomputers just generate lots of them. */ static inline int dc_totaltime(const struct divecomputer *dc) { int time = dc->duration.seconds; int nr = dc->samples; while (nr--) { struct sample *s = dc->sample + nr; time = s->time.seconds; if (s->depth.mm >= SURFACE_THRESHOLD) break; } return time; } /* * The end of a dive is actually not trivial, because "duration" * is not the duration until the end, but the time we spend under * water, which can be very different if there are surface events * during the dive. * * So walk the dive computers, looking for the longest actual * time in the samples (and just default to the dive duration if * there are no samples). */ static inline int dive_totaltime(const struct dive *dive) { int time = dive->duration.seconds; const struct divecomputer *dc; for_each_dc(dive, dc) { int dc_time = dc_totaltime(dc); if (dc_time > time) time = dc_time; } return time; } timestamp_t dive_endtime(const struct dive *dive) { return dive->when + dive_totaltime(dive); } bool time_during_dive_with_offset(struct dive *dive, timestamp_t when, timestamp_t offset) { timestamp_t start = dive->when; timestamp_t end = dive_endtime(dive); return start - offset <= when && when <= end + offset; } bool dive_within_time_range(struct dive *dive, timestamp_t when, timestamp_t offset) { timestamp_t start = dive->when; timestamp_t end = dive_endtime(dive); return when - offset <= start && end <= when + offset; } /* find the n-th dive that is part of a group of dives within the offset around 'when'. * How is that for a vague definition of what this function should do... */ struct dive *find_dive_n_near(timestamp_t when, int n, timestamp_t offset) { int i, j = 0; struct dive *dive; for_each_dive (i, dive) { if (dive_within_time_range(dive, when, offset)) if (++j == n) return dive; } return NULL; } timestamp_t get_times() { int i; struct dive *dive; for_each_dive (i, dive) { if (dive->selected) break; } return dive->when; } /* this sets a usually unused copy of the preferences with the units * that were active the last time the dive list was saved to git storage * (this isn't used in XML files); storing the unit preferences in the * data file is usually pointless (that's a setting of the software, * not a property of the data), but it's a great hint of what the user * might expect to see when creating a backend service that visualizes * the dive list without Subsurface running - so this is basically a * functionality for the core library that Subsurface itself doesn't * use but that another consumer of the library (like an HTML exporter) * will need */ void set_informational_units(const char *units) { if (strstr(units, "METRIC")) { git_prefs.unit_system = METRIC; } else if (strstr(units, "IMPERIAL")) { git_prefs.unit_system = IMPERIAL; } else if (strstr(units, "PERSONALIZE")) { git_prefs.unit_system = PERSONALIZE; if (strstr(units, "METERS")) git_prefs.units.length = METERS; if (strstr(units, "FEET")) git_prefs.units.length = FEET; if (strstr(units, "LITER")) git_prefs.units.volume = LITER; if (strstr(units, "CUFT")) git_prefs.units.volume = CUFT; if (strstr(units, "BAR")) git_prefs.units.pressure = BAR; if (strstr(units, "PSI")) git_prefs.units.pressure = PSI; if (strstr(units, "PASCAL")) git_prefs.units.pressure = PASCALS; if (strstr(units, "CELSIUS")) git_prefs.units.temperature = CELSIUS; if (strstr(units, "FAHRENHEIT")) git_prefs.units.temperature = FAHRENHEIT; if (strstr(units, "KG")) git_prefs.units.weight = KG; if (strstr(units, "LBS")) git_prefs.units.weight = LBS; if (strstr(units, "SECONDS")) git_prefs.units.vertical_speed_time = SECONDS; if (strstr(units, "MINUTES")) git_prefs.units.vertical_speed_time = MINUTES; } } void set_git_prefs(const char *prefs) { if (strstr(prefs, "TANKBAR")) git_prefs.tankbar = 1; if (strstr(prefs, "DCCEILING")) git_prefs.dcceiling = 1; if (strstr(prefs, "SHOW_SETPOINT")) git_prefs.show_ccr_setpoint = 1; if (strstr(prefs, "SHOW_SENSORS")) git_prefs.show_ccr_sensors = 1; if (strstr(prefs, "PO2_GRAPH")) git_prefs.pp_graphs.po2 = 1; } static bool new_picture_for_dive(struct dive *d, const char *filename) { FOR_EACH_PICTURE (d) { if (same_string(picture->filename, filename)) return false; } return true; } /* Return distance of timestamp to time of dive. Result is always positive, 0 means during dive. */ static timestamp_t time_from_dive(const struct dive *d, timestamp_t timestamp) { timestamp_t end_time = dive_endtime(d); if (timestamp < d->when) return d->when - timestamp; else if (timestamp > end_time) return timestamp - end_time; else return 0; } // only add pictures that have timestamps between 30 minutes before the dive and // 30 minutes after the dive ends #define D30MIN (30 * 60) static bool dive_check_picture_time(const struct dive *d, timestamp_t timestamp) { return time_from_dive(d, timestamp) < D30MIN; } /* Return dive closest selected dive to given timestamp or NULL if no dives are selected. */ static struct dive *nearest_selected_dive(timestamp_t timestamp) { struct dive *d, *res = NULL; int i; timestamp_t offset, min = 0; for_each_dive(i, d) { if (!d->selected) continue; offset = time_from_dive(d, timestamp); if (!res || offset < min) { res = d; min = offset; } /* We suppose that dives are sorted chronologically. Thus * if the offset starts to increase, we can end. This ignores * pathological cases such as overlapping dives. In such a * case the user will have to add pictures manually. */ if (offset == 0 || offset > min) break; } return res; } bool picture_check_valid_time(timestamp_t timestamp, int shift_time) { int i; struct dive *dive; for_each_dive (i, dive) if (dive->selected && dive_check_picture_time(dive, timestamp + shift_time)) return true; return false; } static void dive_set_geodata_from_picture(struct dive *dive, struct picture *picture, struct dive_site_table *table) { struct dive_site *ds = dive->dive_site; if (!dive_site_has_gps_location(ds) && has_location(&picture->location)) { if (ds) { ds->location = picture->location; } else { ds = create_dive_site_with_gps("", &picture->location, table); add_dive_to_dive_site(dive, ds); invalidate_dive_cache(dive); } } } void create_picture(const char *filename, int shift_time, bool match_all) { struct metadata metadata; struct dive *dive; timestamp_t timestamp; get_metadata(filename, &metadata); timestamp = metadata.timestamp + shift_time; dive = nearest_selected_dive(timestamp); if (!dive) return; if (!new_picture_for_dive(dive, filename)) return; if (!match_all && !dive_check_picture_time(dive, timestamp)) return; struct picture *picture = alloc_picture(); picture->filename = strdup(filename); picture->offset.seconds = metadata.timestamp - dive->when + shift_time; picture->location = metadata.location; dive_add_picture(dive, picture); dive_set_geodata_from_picture(dive, picture, &dive_site_table); invalidate_dive_cache(dive); } void dive_add_picture(struct dive *dive, struct picture *newpic) { struct picture **pic_ptr = &dive->picture_list; /* let's keep the list sorted by time */ while (*pic_ptr && (*pic_ptr)->offset.seconds <= newpic->offset.seconds) pic_ptr = &(*pic_ptr)->next; newpic->next = *pic_ptr; *pic_ptr = newpic; return; } // Return true if picture was found and deleted bool dive_remove_picture(struct dive *d, const char *filename) { struct picture **picture = &d->picture_list; while (*picture && !same_string((*picture)->filename, filename)) picture = &(*picture)->next; if (*picture) { struct picture *temp = (*picture)->next; free_picture(*picture); *picture = temp; invalidate_dive_cache(d); return true; } return false; } /* clones a dive and moves given dive computer to front */ struct dive *make_first_dc(const struct dive *d, int dc_number) { struct dive *res; struct divecomputer *dc, *newdc, *old_dc; /* copy the dive */ res = alloc_dive(); copy_dive(d, res); /* make a new unique id, since we still can't handle two equal ids */ res->id = dive_getUniqID(); invalidate_dive_cache(res); if (dc_number == 0) return res; dc = &res->dc; newdc = malloc(sizeof(*newdc)); old_dc = get_dive_dc(res, dc_number); /* skip the current DC in the linked list */ for (dc = &res->dc; dc && dc->next != old_dc; dc = dc->next) ; if (!dc) { free(newdc); fprintf(stderr, "data inconsistent: can't find the current DC"); return res; } dc->next = old_dc->next; *newdc = res->dc; res->dc = *old_dc; res->dc.next = newdc; free(old_dc); return res; } int count_divecomputers(const struct dive *d) { int ret = 1; struct divecomputer *dc = d->dc.next; while (dc) { ret++; dc = dc->next; } return ret; } static void delete_divecomputer(struct dive *d, int num) { int i; /* Refuse to delete the last dive computer */ if (!d->dc.next) return; if (num == 0) { /* remove the first one, so copy the second one in place of the first and free the second one * be careful about freeing the no longer needed structures - since we copy things around we can't use free_dc()*/ struct divecomputer *fdc = d->dc.next; free_dc_contents(&d->dc); memcpy(&d->dc, fdc, sizeof(struct divecomputer)); free(fdc); } else { struct divecomputer *pdc = &d->dc; for (i = 0; i < num - 1 && pdc; i++) pdc = pdc->next; if (pdc && pdc->next) { struct divecomputer *dc = pdc->next; pdc->next = dc->next; free_dc(dc); } } /* If this is the currently displayed dive, we might have to adjust * the currently displayed dive computer. */ if (d == current_dive && dc_number >= count_divecomputers(d)) dc_number--; invalidate_dive_cache(d); } /* Clone a dive and delete goven dive computer */ struct dive *clone_delete_divecomputer(const struct dive *d, int dc_number) { struct dive *res; /* copy the dive */ res = alloc_dive(); copy_dive(d, res); /* make a new unique id, since we still can't handle two equal ids */ res->id = dive_getUniqID(); invalidate_dive_cache(res); delete_divecomputer(res, dc_number); return res; } /* * This splits the dive src by dive computer. The first output dive has all * dive computers except num, the second only dive computer num. * The dives will not be associated with a trip. * On error, both output parameters are set to NULL. */ void split_divecomputer(const struct dive *src, int num, struct dive **out1, struct dive **out2) { struct divecomputer *srcdc = get_dive_dc(current_dive, dc_number); if (src && srcdc) { // Copy the dive, but only using the selected dive computer *out2 = alloc_dive(); copy_dive_onedc(src, srcdc, *out2); // This will also make fixup_dive() to allocate a new dive id... (*out2)->id = 0; fixup_dive(*out2); // Copy the dive with all dive computers *out1 = create_new_copy(src); // .. and then delete the split-out dive computer delete_divecomputer(*out1, num); (*out1)->divetrip = (*out2)->divetrip = NULL; } else { *out1 = *out2 = NULL; } } /* helper function to make it easier to work with our structures * we don't interpolate here, just use the value from the last sample up to that time */ int get_depth_at_time(const struct divecomputer *dc, unsigned int time) { int depth = 0; if (dc && dc->sample) for (int i = 0; i < dc->samples; i++) { if (dc->sample[i].time.seconds > time) break; depth = dc->sample[i].depth.mm; } return depth; } //Calculate O2 in best mix fraction_t best_o2(depth_t depth, const struct dive *dive) { fraction_t fo2; fo2.permille = (prefs.bottompo2 * 100 / depth_to_mbar(depth.mm, dive)) * 10; //use integer arithmetic to round down to nearest percent // Don't permit >100% O2 if (fo2.permille > 1000) fo2.permille = 1000; return fo2; } //Calculate He in best mix. O2 is considered narcopic fraction_t best_he(depth_t depth, const struct dive *dive, bool o2narcotic, fraction_t fo2) { fraction_t fhe; int pnarcotic, ambient; pnarcotic = depth_to_mbar(prefs.bestmixend.mm, dive); ambient = depth_to_mbar(depth.mm, dive); if (o2narcotic) { fhe.permille = (100 - 100 * pnarcotic / ambient) * 10; //use integer arithmetic to round up to nearest percent } else { fhe.permille = 1000 - fo2.permille - N2_IN_AIR * pnarcotic / ambient; } if (fhe.permille < 0) fhe.permille = 0; return fhe; } void invalidate_dive_cache(struct dive *dive) { memset(dive->git_id, 0, 20); } bool dive_cache_is_valid(const struct dive *dive) { static const unsigned char null_id[20] = { 0, }; return !!memcmp(dive->git_id, null_id, 20); } int get_surface_pressure_in_mbar(const struct dive *dive, bool non_null) { int mbar = dive->surface_pressure.mbar; if (!mbar && non_null) mbar = SURFACE_PRESSURE; return mbar; } /* Pa = N/m^2 - so we determine the weight (in N) of the mass of 10m * of water (and use standard salt water at 1.03kg per liter if we don't know salinity) * and add that to the surface pressure (or to 1013 if that's unknown) */ int calculate_depth_to_mbar(int depth, pressure_t surface_pressure, int salinity) { double specific_weight; int mbar = surface_pressure.mbar; if (!mbar) mbar = SURFACE_PRESSURE; if (!salinity) salinity = SEAWATER_SALINITY; if (salinity < 500) salinity += FRESHWATER_SALINITY; specific_weight = salinity / 10000.0 * 0.981; mbar += lrint(depth / 10.0 * specific_weight); return mbar; } int depth_to_mbar(int depth, const struct dive *dive) { return calculate_depth_to_mbar(depth, dive->surface_pressure, dive->salinity); } double depth_to_bar(int depth, const struct dive *dive) { return depth_to_mbar(depth, dive) / 1000.0; } double depth_to_atm(int depth, const struct dive *dive) { return mbar_to_atm(depth_to_mbar(depth, dive)); } /* for the inverse calculation we use just the relative pressure * (that's the one that some dive computers like the Uemis Zurich * provide - for the other models that do this libdivecomputer has to * take care of this, but the Uemis we support natively */ int rel_mbar_to_depth(int mbar, const struct dive *dive) { int cm; double specific_weight = 1.03 * 0.981; if (dive->dc.salinity) specific_weight = dive->dc.salinity / 10000.0 * 0.981; /* whole mbar gives us cm precision */ cm = (int)lrint(mbar / specific_weight); return cm * 10; } int mbar_to_depth(int mbar, const struct dive *dive) { pressure_t surface_pressure; if (dive->surface_pressure.mbar) surface_pressure = dive->surface_pressure; else surface_pressure.mbar = SURFACE_PRESSURE; return rel_mbar_to_depth(mbar - surface_pressure.mbar, dive); } /* MOD rounded to multiples of roundto mm */ depth_t gas_mod(struct gasmix mix, pressure_t po2_limit, const struct dive *dive, int roundto) { depth_t rounded_depth; double depth = (double) mbar_to_depth(po2_limit.mbar * 1000 / get_o2(mix), dive); rounded_depth.mm = (int)lrint(depth / roundto) * roundto; return rounded_depth; } /* Maximum narcotic depth rounded to multiples of roundto mm */ depth_t gas_mnd(struct gasmix mix, depth_t end, const struct dive *dive, int roundto) { depth_t rounded_depth; pressure_t ppo2n2; ppo2n2.mbar = depth_to_mbar(end.mm, dive); int maxambient = (int)lrint(ppo2n2.mbar / (1 - get_he(mix) / 1000.0)); rounded_depth.mm = (int)lrint(((double)mbar_to_depth(maxambient, dive)) / roundto) * roundto; return rounded_depth; } struct dive *get_dive(int nr) { if (nr >= dive_table.nr || nr < 0) return NULL; return dive_table.dives[nr]; } struct dive *get_dive_from_table(int nr, const struct dive_table *dt) { if (nr >= dt->nr || nr < 0) return NULL; return dt->dives[nr]; } struct dive_site *get_dive_site_for_dive(const struct dive *dive) { return dive->dive_site; } const char *get_dive_country(const struct dive *dive) { struct dive_site *ds = dive->dive_site; if (ds) { int idx = taxonomy_index_for_category(&ds->taxonomy, TC_COUNTRY); if (idx >= 0) return ds->taxonomy.category[idx].value; } return NULL; } const char *get_dive_location(const struct dive *dive) { const struct dive_site *ds = dive->dive_site; if (ds && ds->name) return ds->name; return NULL; } unsigned int number_of_computers(const struct dive *dive) { unsigned int total_number = 0; const struct divecomputer *dc = &dive->dc; if (!dive) return 1; do { total_number++; dc = dc->next; } while (dc); return total_number; } struct divecomputer *get_dive_dc(struct dive *dive, int nr) { struct divecomputer *dc; if (!dive) return NULL; dc = &dive->dc; while (nr-- > 0) { dc = dc->next; if (!dc) return &dive->dc; } return dc; } struct dive *get_dive_by_uniq_id(int id) { int i; struct dive *dive = NULL; for_each_dive (i, dive) { if (dive->id == id) break; } #ifdef DEBUG if (dive == NULL) { fprintf(stderr, "Invalid id %x passed to get_dive_by_diveid, try to fix the code\n", id); exit(1); } #endif return dive; } int get_idx_by_uniq_id(int id) { int i; struct dive *dive = NULL; for_each_dive (i, dive) { if (dive->id == id) break; } #ifdef DEBUG if (dive == NULL) { fprintf(stderr, "Invalid id %x passed to get_dive_by_diveid, try to fix the code\n", id); exit(1); } #endif return i; } bool dive_site_has_gps_location(const struct dive_site *ds) { return ds && has_location(&ds->location); } int dive_has_gps_location(const struct dive *dive) { if (!dive) return false; return dive_site_has_gps_location(dive->dive_site); } /* Extract GPS location of a dive computer stored in the GPS1 * or GPS2 extra data fields */ static location_t dc_get_gps_location(const struct divecomputer *dc) { location_t res = { }; for (struct extra_data *data = dc->extra_data; data; data = data->next) { if (!strcmp(data->key, "GPS1")) { parse_location(data->value, &res); /* If we found a valid GPS1 field exit early since * it has priority over GPS2 */ if (has_location(&res)) break; } else if (!strcmp(data->key, "GPS2")) { /* For GPS2 fields continue searching, as we might * still find a GPS1 field */ parse_location(data->value, &res); } } return res; } /* Get GPS location for a dive. Highest priority is given to the GPS1 * extra data written by libdivecomputer, as this comes from a real GPS * device. If that doesn't exits, use the currently set dive site. * This function is potentially slow, therefore only call sparingly * and remember the result. */ location_t dive_get_gps_location(const struct dive *d) { location_t res = { }; for (const struct divecomputer *dc = &d->dc; dc; dc = dc->next) { res = dc_get_gps_location(dc); if (has_location(&res)) return res; } /* No libdivecomputer generated GPS data found. * Let's use the location of the current dive site. */ if (d->dive_site) res = d->dive_site->location; return res; } /* When evaluated at the time of a gasswitch, this returns the new gas */ struct gasmix get_gasmix(const struct dive *dive, const struct divecomputer *dc, int time, const struct event **evp, struct gasmix gasmix) { const struct event *ev = *evp; struct gasmix res; /* if there is no cylinder, return air */ if (dive->cylinders.nr <= 0) return gasmix_air; if (!ev) { /* on first invocation, get initial gas mix and first event (if any) */ int cyl = explicit_first_cylinder(dive, dc); res = get_cylinder(dive, cyl)->gasmix; ev = dc ? get_next_event(dc->events, "gaschange") : NULL; } else { res = gasmix; } while (ev && ev->time.seconds <= time) { res = get_gasmix_from_event(dive, ev); ev = get_next_event(ev->next, "gaschange"); } *evp = ev; return res; } /* get the gas at a certain time during the dive */ /* If there is a gasswitch at that time, it returns the new gasmix */ struct gasmix get_gasmix_at_time(const struct dive *d, const struct divecomputer *dc, duration_t time) { const struct event *ev = NULL; struct gasmix gasmix = gasmix_air; return get_gasmix(d, dc, time.seconds, &ev, gasmix); }