mirror of
https://github.com/subsurface/subsurface.git
synced 2024-11-30 22:20:21 +00:00
9c253ee6c5
The parser API was very annoying, as a number of tables to-be-filled were passed in as pointers. The goal of this commit is to collect all these tables in a single struct. This should make it (more or less) clear what is actually written into the divelog files. Moreover, it should now be rather easy to search for instances, where the global logfile is accessed (and it turns out that there are many!). The divelog struct does not contain the tables as substructs, but only collects pointers. The idea is that the "divelog.h" file can be included without all the other files describing the numerous tables. To make it easier to use from C++ parts of the code, the struct implements a constructor and a destructor. Sadly, we can't use smart pointers, since the pointers are accessed from C code. Therfore the constructor and destructor are quite complex. The whole commit is large, but was mostly an automatic conversion. One oddity of note: the divelog structure also contains the "autogroup" flag, since that is saved in the divelog. This actually fixes a bug: Before, when importing dives from a different log, the autogroup flag was overwritten. This was probably not intended and does not happen anymore. Signed-off-by: Berthold Stoeger <bstoeger@mail.tuwien.ac.at>
419 lines
13 KiB
C
419 lines
13 KiB
C
// SPDX-License-Identifier: GPL-2.0
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/* statistics.c
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*
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* core logic for the Info & Stats page -
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* void calculate_stats_summary(struct stats_summary *out, bool selected_only);
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* void calculate_stats_selected(stats_t *stats_selection);
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*/
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#include "statistics.h"
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#include "dive.h"
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#include "divelog.h"
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#include "event.h"
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#include "gettext.h"
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#include "sample.h"
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#include "subsurface-time.h"
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#include "trip.h"
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#include "units.h"
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#include <stdlib.h>
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#include <string.h>
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#include <ctype.h>
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static void process_temperatures(struct dive *dp, stats_t *stats)
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{
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temperature_t min_temp, mean_temp, max_temp = {.mkelvin = 0};
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max_temp.mkelvin = dp->maxtemp.mkelvin;
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if (max_temp.mkelvin && (!stats->max_temp.mkelvin || max_temp.mkelvin > stats->max_temp.mkelvin))
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stats->max_temp.mkelvin = max_temp.mkelvin;
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min_temp.mkelvin = dp->mintemp.mkelvin;
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if (min_temp.mkelvin && (!stats->min_temp.mkelvin || min_temp.mkelvin < stats->min_temp.mkelvin))
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stats->min_temp.mkelvin = min_temp.mkelvin;
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if (min_temp.mkelvin || max_temp.mkelvin) {
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mean_temp.mkelvin = min_temp.mkelvin;
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if (mean_temp.mkelvin)
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mean_temp.mkelvin = (mean_temp.mkelvin + max_temp.mkelvin) / 2;
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else
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mean_temp.mkelvin = max_temp.mkelvin;
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stats->combined_temp.mkelvin += mean_temp.mkelvin;
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stats->combined_count++;
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}
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}
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static void process_dive(struct dive *dive, stats_t *stats)
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{
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int old_tadt, sac_time = 0;
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int32_t duration = dive->duration.seconds;
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old_tadt = stats->total_average_depth_time.seconds;
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stats->total_time.seconds += duration;
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if (duration > stats->longest_time.seconds)
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stats->longest_time.seconds = duration;
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if (stats->shortest_time.seconds == 0 || duration < stats->shortest_time.seconds)
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stats->shortest_time.seconds = duration;
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if (dive->maxdepth.mm > stats->max_depth.mm)
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stats->max_depth.mm = dive->maxdepth.mm;
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if (stats->min_depth.mm == 0 || dive->maxdepth.mm < stats->min_depth.mm)
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stats->min_depth.mm = dive->maxdepth.mm;
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stats->combined_max_depth.mm += dive->maxdepth.mm;
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process_temperatures(dive, stats);
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/* Maybe we should drop zero-duration dives */
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if (!duration)
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return;
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if (dive->meandepth.mm) {
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stats->total_average_depth_time.seconds += duration;
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stats->avg_depth.mm = lrint((1.0 * old_tadt * stats->avg_depth.mm +
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duration * dive->meandepth.mm) /
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stats->total_average_depth_time.seconds);
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}
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if (dive->sac > 100) { /* less than .1 l/min is bogus, even with a pSCR */
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sac_time = stats->total_sac_time.seconds + duration;
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stats->avg_sac.mliter = lrint((1.0 * stats->total_sac_time.seconds * stats->avg_sac.mliter +
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duration * dive->sac) /
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sac_time);
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if (dive->sac > stats->max_sac.mliter)
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stats->max_sac.mliter = dive->sac;
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if (stats->min_sac.mliter == 0 || dive->sac < stats->min_sac.mliter)
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stats->min_sac.mliter = dive->sac;
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stats->total_sac_time.seconds = sac_time;
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}
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}
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/*
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* Calculate a summary of the statistics and put in the stats_summary
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* structure provided in the first parameter.
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* Before first use, it should be initialized with init_stats_summary().
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* After use, memory must be released with free_stats_summary().
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*/
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void calculate_stats_summary(struct stats_summary *out, bool selected_only)
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{
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int idx;
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int t_idx, d_idx, r;
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struct dive *dp;
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struct tm tm;
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int current_year = 0;
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int current_month = 0;
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int year_iter = 0;
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int month_iter = 0;
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int prev_month = 0, prev_year = 0;
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int trip_iter = 0;
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dive_trip_t *trip_ptr = 0;
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size_t size, tsize, dsize, tmsize;
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stats_t stats = { 0 };
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if (divelog.dives->nr > 0) {
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stats.shortest_time.seconds = divelog.dives->dives[0]->duration.seconds;
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stats.min_depth.mm = divelog.dives->dives[0]->maxdepth.mm;
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stats.selection_size = divelog.dives->nr;
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}
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/* allocate sufficient space to hold the worst
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* case (one dive per year or all dives during
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* one month) for yearly and monthly statistics*/
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size = sizeof(stats_t) * (divelog.dives->nr + 1);
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tsize = sizeof(stats_t) * (NUM_DIVEMODE + 1);
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dsize = sizeof(stats_t) * ((STATS_MAX_DEPTH / STATS_DEPTH_BUCKET) + 1);
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tmsize = sizeof(stats_t) * ((STATS_MAX_TEMP / STATS_TEMP_BUCKET) + 1);
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free_stats_summary(out);
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out->stats_yearly = malloc(size);
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out->stats_monthly = malloc(size);
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out->stats_by_trip = malloc(size);
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out->stats_by_type = malloc(tsize);
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out->stats_by_depth = malloc(dsize);
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out->stats_by_temp = malloc(tmsize);
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if (!out->stats_yearly || !out->stats_monthly || !out->stats_by_trip ||
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!out->stats_by_type || !out->stats_by_depth || !out->stats_by_temp)
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return;
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memset(out->stats_yearly, 0, size);
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memset(out->stats_monthly, 0, size);
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memset(out->stats_by_trip, 0, size);
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memset(out->stats_by_type, 0, tsize);
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memset(out->stats_by_depth, 0, dsize);
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memset(out->stats_by_temp, 0, tmsize);
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out->stats_yearly[0].is_year = true;
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/* Setting the is_trip to true to show the location as first
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* field in the statistics window */
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out->stats_by_type[0].location = strdup(translate("gettextFromC", "All (by type stats)"));
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out->stats_by_type[0].is_trip = true;
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out->stats_by_type[1].location = strdup(translate("gettextFromC", divemode_text_ui[OC]));
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out->stats_by_type[1].is_trip = true;
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out->stats_by_type[2].location = strdup(translate("gettextFromC", divemode_text_ui[CCR]));
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out->stats_by_type[2].is_trip = true;
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out->stats_by_type[3].location = strdup(translate("gettextFromC", divemode_text_ui[PSCR]));
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out->stats_by_type[3].is_trip = true;
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out->stats_by_type[4].location = strdup(translate("gettextFromC", divemode_text_ui[FREEDIVE]));
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out->stats_by_type[4].is_trip = true;
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out->stats_by_depth[0].location = strdup(translate("gettextFromC", "All (by max depth stats)"));
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out->stats_by_depth[0].is_trip = true;
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out->stats_by_temp[0].location = strdup(translate("gettextFromC", "All (by min. temp stats)"));
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out->stats_by_temp[0].is_trip = true;
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/* this relies on the fact that the dives in the dive_table
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* are in chronological order */
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for_each_dive (idx, dp) {
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if (selected_only && !dp->selected)
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continue;
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if (dp->invalid)
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continue;
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process_dive(dp, &stats);
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/* yearly statistics */
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utc_mkdate(dp->when, &tm);
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if (current_year == 0)
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current_year = tm.tm_year;
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if (current_year != tm.tm_year) {
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current_year = tm.tm_year;
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process_dive(dp, &(out->stats_yearly[++year_iter]));
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out->stats_yearly[year_iter].is_year = true;
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} else {
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process_dive(dp, &(out->stats_yearly[year_iter]));
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}
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out->stats_yearly[year_iter].selection_size++;
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out->stats_yearly[year_iter].period = current_year;
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/* stats_by_type[0] is all the dives combined */
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out->stats_by_type[0].selection_size++;
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process_dive(dp, &(out->stats_by_type[0]));
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process_dive(dp, &(out->stats_by_type[dp->dc.divemode + 1]));
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out->stats_by_type[dp->dc.divemode + 1].selection_size++;
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/* stats_by_depth[0] is all the dives combined */
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out->stats_by_depth[0].selection_size++;
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process_dive(dp, &(out->stats_by_depth[0]));
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d_idx = dp->maxdepth.mm / (STATS_DEPTH_BUCKET * 1000);
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if (d_idx < 0)
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d_idx = 0;
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if (d_idx >= STATS_MAX_DEPTH / STATS_DEPTH_BUCKET)
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d_idx = STATS_MAX_DEPTH / STATS_DEPTH_BUCKET - 1;
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process_dive(dp, &(out->stats_by_depth[d_idx + 1]));
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out->stats_by_depth[d_idx + 1].selection_size++;
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/* stats_by_temp[0] is all the dives combined */
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out->stats_by_temp[0].selection_size++;
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process_dive(dp, &(out->stats_by_temp[0]));
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t_idx = ((int)mkelvin_to_C(dp->mintemp.mkelvin)) / STATS_TEMP_BUCKET;
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if (t_idx < 0)
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t_idx = 0;
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if (t_idx >= STATS_MAX_TEMP / STATS_TEMP_BUCKET)
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t_idx = STATS_MAX_TEMP / STATS_TEMP_BUCKET - 1;
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process_dive(dp, &(out->stats_by_temp[t_idx + 1]));
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out->stats_by_temp[t_idx + 1].selection_size++;
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if (dp->divetrip != NULL) {
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if (trip_ptr != dp->divetrip) {
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trip_ptr = dp->divetrip;
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trip_iter++;
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}
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/* stats_by_trip[0] is all the dives combined */
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out->stats_by_trip[0].selection_size++;
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process_dive(dp, &(out->stats_by_trip[0]));
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out->stats_by_trip[0].is_trip = true;
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out->stats_by_trip[0].location = strdup(translate("gettextFromC", "All (by trip stats)"));
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process_dive(dp, &(out->stats_by_trip[trip_iter]));
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out->stats_by_trip[trip_iter].selection_size++;
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out->stats_by_trip[trip_iter].is_trip = true;
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out->stats_by_trip[trip_iter].location = dp->divetrip->location;
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}
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/* monthly statistics */
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if (current_month == 0) {
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current_month = tm.tm_mon + 1;
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} else {
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if (current_month != tm.tm_mon + 1)
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current_month = tm.tm_mon + 1;
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if (prev_month != current_month || prev_year != current_year)
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month_iter++;
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}
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process_dive(dp, &(out->stats_monthly[month_iter]));
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out->stats_monthly[month_iter].selection_size++;
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out->stats_monthly[month_iter].period = current_month;
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prev_month = current_month;
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prev_year = current_year;
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}
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/* add labels for depth ranges up to maximum depth seen */
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if (out->stats_by_depth[0].selection_size) {
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d_idx = out->stats_by_depth[0].max_depth.mm;
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if (d_idx > STATS_MAX_DEPTH * 1000)
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d_idx = STATS_MAX_DEPTH * 1000;
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for (r = 0; r * (STATS_DEPTH_BUCKET * 1000) < d_idx; ++r)
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out->stats_by_depth[r+1].is_trip = true;
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}
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/* add labels for depth ranges up to maximum temperature seen */
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if (out->stats_by_temp[0].selection_size) {
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t_idx = (int)mkelvin_to_C(out->stats_by_temp[0].max_temp.mkelvin);
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if (t_idx > STATS_MAX_TEMP)
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t_idx = STATS_MAX_TEMP;
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for (r = 0; r * STATS_TEMP_BUCKET < t_idx; ++r)
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out->stats_by_temp[r+1].is_trip = true;
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}
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}
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void free_stats_summary(struct stats_summary *stats)
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{
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free(stats->stats_yearly);
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free(stats->stats_monthly);
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free(stats->stats_by_trip);
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free(stats->stats_by_type);
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free(stats->stats_by_depth);
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free(stats->stats_by_temp);
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}
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void init_stats_summary(struct stats_summary *stats)
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{
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stats->stats_yearly = NULL;
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stats->stats_monthly = NULL;
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stats->stats_by_trip = NULL;
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stats->stats_by_type = NULL;
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stats->stats_by_depth = NULL;
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stats->stats_by_temp = NULL;
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}
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/* make sure we skip the selected summary entries */
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void calculate_stats_selected(stats_t *stats_selection)
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{
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struct dive *dive;
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unsigned int i, nr;
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memset(stats_selection, 0, sizeof(*stats_selection));
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nr = 0;
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for_each_dive(i, dive) {
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if (dive->selected && !dive->invalid) {
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process_dive(dive, stats_selection);
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nr++;
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}
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}
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stats_selection->selection_size = nr;
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}
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#define SOME_GAS 5000 // 5bar drop in cylinder pressure makes cylinder used
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bool has_gaschange_event(const struct dive *dive, const struct divecomputer *dc, int idx)
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{
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bool first_gas_explicit = false;
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const struct event *event = get_next_event(dc->events, "gaschange");
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while (event) {
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if (dc->sample && (event->time.seconds == 0 ||
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(dc->samples && dc->sample[0].time.seconds == event->time.seconds)))
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first_gas_explicit = true;
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if (get_cylinder_index(dive, event) == idx)
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return true;
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event = get_next_event(event->next, "gaschange");
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}
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if (dc->divemode == CCR) {
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if (idx == get_cylinder_idx_by_use(dive, DILUENT))
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return true;
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if (idx == get_cylinder_idx_by_use(dive, OXYGEN))
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return true;
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}
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return !first_gas_explicit && idx == 0;
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}
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bool is_cylinder_used(const struct dive *dive, int idx)
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{
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const struct divecomputer *dc;
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cylinder_t *cyl;
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if (idx < 0 || idx >= dive->cylinders.nr)
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return false;
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cyl = get_cylinder(dive, idx);
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if ((cyl->start.mbar - cyl->end.mbar) > SOME_GAS)
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return true;
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if ((cyl->sample_start.mbar - cyl->sample_end.mbar) > SOME_GAS)
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return true;
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for_each_dc(dive, dc) {
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if (has_gaschange_event(dive, dc, idx))
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return true;
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}
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return false;
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}
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bool is_cylinder_prot(const struct dive *dive, int idx)
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{
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const struct divecomputer *dc;
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if (idx < 0 || idx >= dive->cylinders.nr)
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return false;
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for_each_dc(dive, dc) {
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if (has_gaschange_event(dive, dc, idx))
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return true;
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}
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return false;
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}
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/* Returns a dynamically allocated array with dive->cylinders.nr entries,
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* which has to be freed by the caller */
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volume_t *get_gas_used(struct dive *dive)
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{
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int idx;
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volume_t *gases = malloc(dive->cylinders.nr * sizeof(volume_t));
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for (idx = 0; idx < dive->cylinders.nr; idx++) {
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cylinder_t *cyl = get_cylinder(dive, idx);
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pressure_t start, end;
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start = cyl->start.mbar ? cyl->start : cyl->sample_start;
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end = cyl->end.mbar ? cyl->end : cyl->sample_end;
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if (end.mbar && start.mbar > end.mbar)
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gases[idx].mliter = gas_volume(cyl, start) - gas_volume(cyl, end);
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else
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gases[idx].mliter = 0;
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}
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return gases;
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}
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/* Quite crude reverse-blender-function, but it produces a approx result */
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static void get_gas_parts(struct gasmix mix, volume_t vol, int o2_in_topup, volume_t *o2, volume_t *he)
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{
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volume_t air = {};
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if (gasmix_is_air(mix)) {
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o2->mliter = 0;
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he->mliter = 0;
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return;
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}
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air.mliter = lrint(((double)vol.mliter * get_n2(mix)) / (1000 - o2_in_topup));
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he->mliter = lrint(((double)vol.mliter * get_he(mix)) / 1000.0);
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o2->mliter += vol.mliter - he->mliter - air.mliter;
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}
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void selected_dives_gas_parts(volume_t *o2_tot, volume_t *he_tot)
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{
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int i, j;
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struct dive *d;
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for_each_dive (i, d) {
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if (!d->selected || d->invalid)
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continue;
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volume_t *diveGases = get_gas_used(d);
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for (j = 0; j < d->cylinders.nr; j++) {
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if (diveGases[j].mliter) {
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volume_t o2 = {}, he = {};
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get_gas_parts(get_cylinder(d, j)->gasmix, diveGases[j], O2_IN_AIR, &o2, &he);
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o2_tot->mliter += o2.mliter;
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he_tot->mliter += he.mliter;
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}
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}
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|
free(diveGases);
|
|
}
|
|
}
|