subsurface/core/statistics.c
Michael Keller 8f0380fd05 Equipment: Fix 'used' Gas Selection for CCR Dives.
Fix how gases are marked as 'used' and kept from being deleted in the
equipment tab for CCR dives.
It does not make sense to treat the (arbitrary) first gas in the list
with a usage type of 'diluent' or 'oxygen' as 'used' and prevent the
user from deleting it. Dive computers report the initial diluent and
any other diluents used through a 'gaschange' event, so the actually
used diluents are already picked up as part of gaschange event based
logic.
Also clarify the selection of the first diluent used as a default if no
gaschange events exist.
Also fixed the test data - gases that have a pressure change should be
included in the profile if they do not have a gas change recorded
against them by other dive computers, even if they are oxygen.
A secondary problem shown by this is that the pressure change is not
applied to the profile - the pressure is currently shown as constant on
the start pressure. But this is for another pull request.

Signed-off-by: Michael Keller <github@ike.ch>
2023-07-25 12:05:51 +12:00

415 lines
13 KiB
C

// SPDX-License-Identifier: GPL-2.0
/* statistics.c
*
* core logic for the Info & Stats page -
* void calculate_stats_summary(struct stats_summary *out, bool selected_only);
* void calculate_stats_selected(stats_t *stats_selection);
*/
#include "statistics.h"
#include "dive.h"
#include "divelog.h"
#include "event.h"
#include "gettext.h"
#include "sample.h"
#include "subsurface-time.h"
#include "trip.h"
#include "units.h"
#include <stdlib.h>
#include <string.h>
#include <ctype.h>
static void process_temperatures(struct dive *dp, stats_t *stats)
{
temperature_t min_temp, mean_temp, max_temp = {.mkelvin = 0};
max_temp.mkelvin = dp->maxtemp.mkelvin;
if (max_temp.mkelvin && (!stats->max_temp.mkelvin || max_temp.mkelvin > stats->max_temp.mkelvin))
stats->max_temp.mkelvin = max_temp.mkelvin;
min_temp.mkelvin = dp->mintemp.mkelvin;
if (min_temp.mkelvin && (!stats->min_temp.mkelvin || min_temp.mkelvin < stats->min_temp.mkelvin))
stats->min_temp.mkelvin = min_temp.mkelvin;
if (min_temp.mkelvin || max_temp.mkelvin) {
mean_temp.mkelvin = min_temp.mkelvin;
if (mean_temp.mkelvin)
mean_temp.mkelvin = (mean_temp.mkelvin + max_temp.mkelvin) / 2;
else
mean_temp.mkelvin = max_temp.mkelvin;
stats->combined_temp.mkelvin += mean_temp.mkelvin;
stats->combined_count++;
}
}
static void process_dive(struct dive *dive, stats_t *stats)
{
int old_tadt, sac_time = 0;
int32_t duration = dive->duration.seconds;
old_tadt = stats->total_average_depth_time.seconds;
stats->total_time.seconds += duration;
if (duration > stats->longest_time.seconds)
stats->longest_time.seconds = duration;
if (stats->shortest_time.seconds == 0 || duration < stats->shortest_time.seconds)
stats->shortest_time.seconds = duration;
if (dive->maxdepth.mm > stats->max_depth.mm)
stats->max_depth.mm = dive->maxdepth.mm;
if (stats->min_depth.mm == 0 || dive->maxdepth.mm < stats->min_depth.mm)
stats->min_depth.mm = dive->maxdepth.mm;
stats->combined_max_depth.mm += dive->maxdepth.mm;
process_temperatures(dive, stats);
/* Maybe we should drop zero-duration dives */
if (!duration)
return;
if (dive->meandepth.mm) {
stats->total_average_depth_time.seconds += duration;
stats->avg_depth.mm = lrint((1.0 * old_tadt * stats->avg_depth.mm +
duration * dive->meandepth.mm) /
stats->total_average_depth_time.seconds);
}
if (dive->sac > 100) { /* less than .1 l/min is bogus, even with a pSCR */
sac_time = stats->total_sac_time.seconds + duration;
stats->avg_sac.mliter = lrint((1.0 * stats->total_sac_time.seconds * stats->avg_sac.mliter +
duration * dive->sac) /
sac_time);
if (dive->sac > stats->max_sac.mliter)
stats->max_sac.mliter = dive->sac;
if (stats->min_sac.mliter == 0 || dive->sac < stats->min_sac.mliter)
stats->min_sac.mliter = dive->sac;
stats->total_sac_time.seconds = sac_time;
}
}
/*
* Calculate a summary of the statistics and put in the stats_summary
* structure provided in the first parameter.
* Before first use, it should be initialized with init_stats_summary().
* After use, memory must be released with free_stats_summary().
*/
void calculate_stats_summary(struct stats_summary *out, bool selected_only)
{
int idx;
int t_idx, d_idx, r;
struct dive *dp;
struct tm tm;
int current_year = 0;
int current_month = 0;
int year_iter = 0;
int month_iter = 0;
int prev_month = 0, prev_year = 0;
int trip_iter = 0;
dive_trip_t *trip_ptr = 0;
size_t size, tsize, dsize, tmsize;
stats_t stats = { 0 };
if (divelog.dives->nr > 0) {
stats.shortest_time.seconds = divelog.dives->dives[0]->duration.seconds;
stats.min_depth.mm = divelog.dives->dives[0]->maxdepth.mm;
stats.selection_size = divelog.dives->nr;
}
/* allocate sufficient space to hold the worst
* case (one dive per year or all dives during
* one month) for yearly and monthly statistics*/
size = sizeof(stats_t) * (divelog.dives->nr + 1);
tsize = sizeof(stats_t) * (NUM_DIVEMODE + 1);
dsize = sizeof(stats_t) * ((STATS_MAX_DEPTH / STATS_DEPTH_BUCKET) + 1);
tmsize = sizeof(stats_t) * ((STATS_MAX_TEMP / STATS_TEMP_BUCKET) + 1);
free_stats_summary(out);
out->stats_yearly = malloc(size);
out->stats_monthly = malloc(size);
out->stats_by_trip = malloc(size);
out->stats_by_type = malloc(tsize);
out->stats_by_depth = malloc(dsize);
out->stats_by_temp = malloc(tmsize);
if (!out->stats_yearly || !out->stats_monthly || !out->stats_by_trip ||
!out->stats_by_type || !out->stats_by_depth || !out->stats_by_temp)
return;
memset(out->stats_yearly, 0, size);
memset(out->stats_monthly, 0, size);
memset(out->stats_by_trip, 0, size);
memset(out->stats_by_type, 0, tsize);
memset(out->stats_by_depth, 0, dsize);
memset(out->stats_by_temp, 0, tmsize);
out->stats_yearly[0].is_year = true;
/* Setting the is_trip to true to show the location as first
* field in the statistics window */
out->stats_by_type[0].location = strdup(translate("gettextFromC", "All (by type stats)"));
out->stats_by_type[0].is_trip = true;
out->stats_by_type[1].location = strdup(translate("gettextFromC", divemode_text_ui[OC]));
out->stats_by_type[1].is_trip = true;
out->stats_by_type[2].location = strdup(translate("gettextFromC", divemode_text_ui[CCR]));
out->stats_by_type[2].is_trip = true;
out->stats_by_type[3].location = strdup(translate("gettextFromC", divemode_text_ui[PSCR]));
out->stats_by_type[3].is_trip = true;
out->stats_by_type[4].location = strdup(translate("gettextFromC", divemode_text_ui[FREEDIVE]));
out->stats_by_type[4].is_trip = true;
out->stats_by_depth[0].location = strdup(translate("gettextFromC", "All (by max depth stats)"));
out->stats_by_depth[0].is_trip = true;
out->stats_by_temp[0].location = strdup(translate("gettextFromC", "All (by min. temp stats)"));
out->stats_by_temp[0].is_trip = true;
/* this relies on the fact that the dives in the dive_table
* are in chronological order */
for_each_dive (idx, dp) {
if (selected_only && !dp->selected)
continue;
if (dp->invalid)
continue;
process_dive(dp, &stats);
/* yearly statistics */
utc_mkdate(dp->when, &tm);
if (current_year == 0)
current_year = tm.tm_year;
if (current_year != tm.tm_year) {
current_year = tm.tm_year;
process_dive(dp, &(out->stats_yearly[++year_iter]));
out->stats_yearly[year_iter].is_year = true;
} else {
process_dive(dp, &(out->stats_yearly[year_iter]));
}
out->stats_yearly[year_iter].selection_size++;
out->stats_yearly[year_iter].period = current_year;
/* stats_by_type[0] is all the dives combined */
out->stats_by_type[0].selection_size++;
process_dive(dp, &(out->stats_by_type[0]));
process_dive(dp, &(out->stats_by_type[dp->dc.divemode + 1]));
out->stats_by_type[dp->dc.divemode + 1].selection_size++;
/* stats_by_depth[0] is all the dives combined */
out->stats_by_depth[0].selection_size++;
process_dive(dp, &(out->stats_by_depth[0]));
d_idx = dp->maxdepth.mm / (STATS_DEPTH_BUCKET * 1000);
if (d_idx < 0)
d_idx = 0;
if (d_idx >= STATS_MAX_DEPTH / STATS_DEPTH_BUCKET)
d_idx = STATS_MAX_DEPTH / STATS_DEPTH_BUCKET - 1;
process_dive(dp, &(out->stats_by_depth[d_idx + 1]));
out->stats_by_depth[d_idx + 1].selection_size++;
/* stats_by_temp[0] is all the dives combined */
out->stats_by_temp[0].selection_size++;
process_dive(dp, &(out->stats_by_temp[0]));
t_idx = ((int)mkelvin_to_C(dp->mintemp.mkelvin)) / STATS_TEMP_BUCKET;
if (t_idx < 0)
t_idx = 0;
if (t_idx >= STATS_MAX_TEMP / STATS_TEMP_BUCKET)
t_idx = STATS_MAX_TEMP / STATS_TEMP_BUCKET - 1;
process_dive(dp, &(out->stats_by_temp[t_idx + 1]));
out->stats_by_temp[t_idx + 1].selection_size++;
if (dp->divetrip != NULL) {
if (trip_ptr != dp->divetrip) {
trip_ptr = dp->divetrip;
trip_iter++;
}
/* stats_by_trip[0] is all the dives combined */
out->stats_by_trip[0].selection_size++;
process_dive(dp, &(out->stats_by_trip[0]));
out->stats_by_trip[0].is_trip = true;
out->stats_by_trip[0].location = strdup(translate("gettextFromC", "All (by trip stats)"));
process_dive(dp, &(out->stats_by_trip[trip_iter]));
out->stats_by_trip[trip_iter].selection_size++;
out->stats_by_trip[trip_iter].is_trip = true;
out->stats_by_trip[trip_iter].location = dp->divetrip->location;
}
/* monthly statistics */
if (current_month == 0) {
current_month = tm.tm_mon + 1;
} else {
if (current_month != tm.tm_mon + 1)
current_month = tm.tm_mon + 1;
if (prev_month != current_month || prev_year != current_year)
month_iter++;
}
process_dive(dp, &(out->stats_monthly[month_iter]));
out->stats_monthly[month_iter].selection_size++;
out->stats_monthly[month_iter].period = current_month;
prev_month = current_month;
prev_year = current_year;
}
/* add labels for depth ranges up to maximum depth seen */
if (out->stats_by_depth[0].selection_size) {
d_idx = out->stats_by_depth[0].max_depth.mm;
if (d_idx > STATS_MAX_DEPTH * 1000)
d_idx = STATS_MAX_DEPTH * 1000;
for (r = 0; r * (STATS_DEPTH_BUCKET * 1000) < d_idx; ++r)
out->stats_by_depth[r+1].is_trip = true;
}
/* add labels for depth ranges up to maximum temperature seen */
if (out->stats_by_temp[0].selection_size) {
t_idx = (int)mkelvin_to_C(out->stats_by_temp[0].max_temp.mkelvin);
if (t_idx > STATS_MAX_TEMP)
t_idx = STATS_MAX_TEMP;
for (r = 0; r * STATS_TEMP_BUCKET < t_idx; ++r)
out->stats_by_temp[r+1].is_trip = true;
}
}
void free_stats_summary(struct stats_summary *stats)
{
free(stats->stats_yearly);
free(stats->stats_monthly);
free(stats->stats_by_trip);
free(stats->stats_by_type);
free(stats->stats_by_depth);
free(stats->stats_by_temp);
}
void init_stats_summary(struct stats_summary *stats)
{
stats->stats_yearly = NULL;
stats->stats_monthly = NULL;
stats->stats_by_trip = NULL;
stats->stats_by_type = NULL;
stats->stats_by_depth = NULL;
stats->stats_by_temp = NULL;
}
/* make sure we skip the selected summary entries */
void calculate_stats_selected(stats_t *stats_selection)
{
struct dive *dive;
unsigned int i, nr;
memset(stats_selection, 0, sizeof(*stats_selection));
nr = 0;
for_each_dive(i, dive) {
if (dive->selected && !dive->invalid) {
process_dive(dive, stats_selection);
nr++;
}
}
stats_selection->selection_size = nr;
}
#define SOME_GAS 5000 // 5bar drop in cylinder pressure makes cylinder used
bool has_gaschange_event(const struct dive *dive, const struct divecomputer *dc, int idx)
{
bool first_gas_explicit = false;
const struct event *event = get_next_event(dc->events, "gaschange");
while (event) {
if (dc->sample && (event->time.seconds == 0 ||
(dc->samples && dc->sample[0].time.seconds == event->time.seconds)))
first_gas_explicit = true;
if (get_cylinder_index(dive, event) == idx)
return true;
event = get_next_event(event->next, "gaschange");
}
return !first_gas_explicit && idx == 0;
}
bool is_cylinder_used(const struct dive *dive, int idx)
{
const struct divecomputer *dc;
cylinder_t *cyl;
if (idx < 0 || idx >= dive->cylinders.nr)
return false;
cyl = get_cylinder(dive, idx);
if ((cyl->start.mbar - cyl->end.mbar) > SOME_GAS)
return true;
if ((cyl->sample_start.mbar - cyl->sample_end.mbar) > SOME_GAS)
return true;
for_each_dc(dive, dc) {
if (has_gaschange_event(dive, dc, idx))
return true;
else if (dc->divemode == CCR && idx == get_cylinder_idx_by_use(dive, OXYGEN))
return true;
}
return false;
}
bool is_cylinder_prot(const struct dive *dive, int idx)
{
const struct divecomputer *dc;
if (idx < 0 || idx >= dive->cylinders.nr)
return false;
for_each_dc(dive, dc) {
if (has_gaschange_event(dive, dc, idx))
return true;
}
return false;
}
/* Returns a dynamically allocated array with dive->cylinders.nr entries,
* which has to be freed by the caller */
volume_t *get_gas_used(struct dive *dive)
{
int idx;
volume_t *gases = malloc(dive->cylinders.nr * sizeof(volume_t));
for (idx = 0; idx < dive->cylinders.nr; idx++) {
cylinder_t *cyl = get_cylinder(dive, idx);
pressure_t start, end;
start = cyl->start.mbar ? cyl->start : cyl->sample_start;
end = cyl->end.mbar ? cyl->end : cyl->sample_end;
if (end.mbar && start.mbar > end.mbar)
gases[idx].mliter = gas_volume(cyl, start) - gas_volume(cyl, end);
else
gases[idx].mliter = 0;
}
return gases;
}
/* Quite crude reverse-blender-function, but it produces a approx result */
static void get_gas_parts(struct gasmix mix, volume_t vol, int o2_in_topup, volume_t *o2, volume_t *he)
{
volume_t air = {};
if (gasmix_is_air(mix)) {
o2->mliter = 0;
he->mliter = 0;
return;
}
air.mliter = lrint(((double)vol.mliter * get_n2(mix)) / (1000 - o2_in_topup));
he->mliter = lrint(((double)vol.mliter * get_he(mix)) / 1000.0);
o2->mliter += vol.mliter - he->mliter - air.mliter;
}
void selected_dives_gas_parts(volume_t *o2_tot, volume_t *he_tot)
{
int i, j;
struct dive *d;
for_each_dive (i, d) {
if (!d->selected || d->invalid)
continue;
volume_t *diveGases = get_gas_used(d);
for (j = 0; j < d->cylinders.nr; j++) {
if (diveGases[j].mliter) {
volume_t o2 = {}, he = {};
get_gas_parts(get_cylinder(d, j)->gasmix, diveGases[j], O2_IN_AIR, &o2, &he);
o2_tot->mliter += o2.mliter;
he_tot->mliter += he.mliter;
}
}
free(diveGases);
}
}