Exemplo n.º 1
0
static struct gaschanges *analyze_gaslist(struct diveplan *diveplan, int *gaschangenr, int depth, int *asc_cylinder)
{
	struct gasmix gas;
	int nr = 0;
	struct gaschanges *gaschanges = NULL;
	struct divedatapoint *dp = diveplan->dp;
	int best_depth = displayed_dive.cylinder[*asc_cylinder].depth.mm;
	while (dp) {
		if (dp->time == 0) {
			gas = dp->gasmix;
			if (dp->depth <= depth) {
				int i = 0;
				nr++;
				gaschanges = realloc(gaschanges, nr * sizeof(struct gaschanges));
				while (i < nr - 1) {
					if (dp->depth < gaschanges[i].depth) {
						memmove(gaschanges + i + 1, gaschanges + i, (nr - i - 1) * sizeof(struct gaschanges));
						break;
					}
					i++;
				}
				gaschanges[i].depth = dp->depth;
				gaschanges[i].gasidx = get_gasidx(&displayed_dive, &gas);
				assert(gaschanges[i].gasidx != -1);
			} else {
				/* is there a better mix to start deco? */
				if (dp->depth < best_depth) {
					best_depth = dp->depth;
					*asc_cylinder = get_gasidx(&displayed_dive, &gas);
				}
			}
		}
		dp = dp->next;
	}
	*gaschangenr = nr;
#if DEBUG_PLAN & 16
	for (nr = 0; nr < *gaschangenr; nr++) {
		int idx = gaschanges[nr].gasidx;
		printf("gaschange nr %d: @ %5.2lfm gasidx %d (%s)\n", nr, gaschanges[nr].depth / 1000.0,
		       idx, gasname(&displayed_dive.cylinder[idx].gasmix));
	}
#endif
	return gaschanges;
}
Exemplo n.º 2
0
/* returns the tissue tolerance at the end of this (partial) dive */
double tissue_at_end(struct dive *dive, char **cached_datap)
{
	struct divecomputer *dc;
	struct sample *sample, *psample;
	int i, t0, t1, gasidx, lastdepth;
	double tissue_tolerance;
	struct gasmix gas;

	if (!dive)
		return 0.0;
	if (*cached_datap) {
		tissue_tolerance = restore_deco_state(*cached_datap);
	} else {
		tissue_tolerance = init_decompression(dive);
		cache_deco_state(tissue_tolerance, cached_datap);
	}
	dc = &dive->dc;
	if (!dc->samples)
		return tissue_tolerance;
	psample = sample = dc->sample;
	lastdepth = t0 = 0;
	/* we always start with gas 0 (unless an event tells us otherwise) */
	gas = dive->cylinder[0].gasmix;
	for (i = 0; i < dc->samples; i++, sample++) {
		t1 = sample->time.seconds;
		get_gas_from_events(&dive->dc, t0, &gas);
		if ((gasidx = get_gasidx(dive, &gas)) == -1) {
			report_error(translate("gettextFromC", "Can't find gas %s"), gasname(&gas));
			gasidx = 0;
		}
		if (i > 0)
			lastdepth = psample->depth.mm;
		tissue_tolerance = interpolate_transition(dive, t0, t1, lastdepth, sample->depth.mm, &dive->cylinder[gasidx].gasmix, sample->po2.mbar);
		psample = sample;
		t0 = t1;
	}
	return tissue_tolerance;
}
Exemplo n.º 3
0
void plan(struct diveplan *diveplan, char **cached_datap, bool is_planner, bool show_disclaimer)
{
	struct sample *sample;
	int po2;
	int transitiontime, gi;
	int current_cylinder;
	unsigned int stopidx;
	int depth;
	double tissue_tolerance = 0.0;
	struct gaschanges *gaschanges = NULL;
	int gaschangenr;
	int *stoplevels = NULL;
	char *trial_cache = NULL;
	bool stopping = false;
	bool clear_to_ascend;
	int clock, previous_point_time;
	int avg_depth, bottom_time = 0;
	int last_ascend_rate;
	int best_first_ascend_cylinder;
	struct gasmix gas;
	int o2time = 0;
	int breaktime = -1;
	int breakcylinder;

	set_gf(diveplan->gflow, diveplan->gfhigh, prefs.gf_low_at_maxdepth);
	if (!diveplan->surface_pressure)
		diveplan->surface_pressure = SURFACE_PRESSURE;
	create_dive_from_plan(diveplan, is_planner);

	/* Let's start at the last 'sample', i.e. the last manually entered waypoint. */
	sample = &displayed_dive.dc.sample[displayed_dive.dc.samples - 1];

	get_gas_at_time(&displayed_dive, &displayed_dive.dc, sample->time, &gas);

	po2 = displayed_dive.dc.sample[displayed_dive.dc.samples - 1].po2.mbar;
	if ((current_cylinder = get_gasidx(&displayed_dive, &gas)) == -1) {
		report_error(translate("gettextFromC", "Can't find gas %s"), gasname(&gas));
		current_cylinder = 0;
	}
	depth = displayed_dive.dc.sample[displayed_dive.dc.samples - 1].depth.mm;
	avg_depth = average_depth(diveplan);
	last_ascend_rate = ascend_velocity(depth, avg_depth, bottom_time);

	/* if all we wanted was the dive just get us back to the surface */
	if (!is_planner) {
		transitiontime = depth / 75; /* this still needs to be made configurable */
		plan_add_segment(diveplan, transitiontime, 0, gas, po2, false);
		create_dive_from_plan(diveplan, is_planner);
		return;
	}

	tissue_tolerance = tissue_at_end(&displayed_dive, cached_datap);

#if DEBUG_PLAN & 4
	printf("gas %s\n", gasname(&gas));
	printf("depth %5.2lfm \n", depth / 1000.0);
#endif

	best_first_ascend_cylinder = current_cylinder;
	/* Find the gases available for deco */
	gaschanges = analyze_gaslist(diveplan, &gaschangenr, depth, &best_first_ascend_cylinder);
	/* Find the first potential decostopdepth above current depth */
	for (stopidx = 0; stopidx < sizeof(decostoplevels) / sizeof(int); stopidx++)
		if (decostoplevels[stopidx] >= depth)
			break;
	if (stopidx > 0)
		stopidx--;
	/* Stoplevels are either depths of gas changes or potential deco stop depths. */
	stoplevels = sort_stops(decostoplevels, stopidx + 1, gaschanges, gaschangenr);
	stopidx += gaschangenr;

	/* Keep time during the ascend */
	bottom_time = clock = previous_point_time = displayed_dive.dc.sample[displayed_dive.dc.samples - 1].time.seconds;
	gi = gaschangenr - 1;

	if (best_first_ascend_cylinder != current_cylinder) {
		stopping = true;

		current_cylinder = best_first_ascend_cylinder;
		gas = displayed_dive.cylinder[current_cylinder].gasmix;
#if DEBUG_PLAN & 16
		printf("switch to gas %d (%d/%d) @ %5.2lfm\n", best_first_ascend_cylinder,
		       (get_o2(&gas) + 5) / 10, (get_he(&gas) + 5) / 10, gaschanges[best_first_ascend_cylinder].depth / 1000.0);
#endif
	}
	while (1) {
		/* We will break out when we hit the surface */
		do {
			/* Ascend to next stop depth */
			int deltad = ascend_velocity(depth, avg_depth, bottom_time) * TIMESTEP;
			if (ascend_velocity(depth, avg_depth, bottom_time) != last_ascend_rate) {
				plan_add_segment(diveplan, clock - previous_point_time, depth, gas, po2, false);
				previous_point_time = clock;
				stopping = false;
				last_ascend_rate = ascend_velocity(depth, avg_depth, bottom_time);
			}
			if (depth - deltad < stoplevels[stopidx])
				deltad = depth - stoplevels[stopidx];

			tissue_tolerance = add_segment(depth_to_mbar(depth, &displayed_dive) / 1000.0,
						       &displayed_dive.cylinder[current_cylinder].gasmix,
						       TIMESTEP, po2, &displayed_dive);
			clock += TIMESTEP;
			depth -= deltad;
		} while (depth > stoplevels[stopidx]);

		if (depth <= 0)
			break; /* We are at the surface */

		if (gi >= 0 && stoplevels[stopidx] == gaschanges[gi].depth) {
			/* We have reached a gas change.
			 * Record this in the dive plan */
			plan_add_segment(diveplan, clock - previous_point_time, depth, gas, po2, false);
			previous_point_time = clock;
			stopping = true;

			current_cylinder = gaschanges[gi].gasidx;
			gas = displayed_dive.cylinder[current_cylinder].gasmix;
#if DEBUG_PLAN & 16
			printf("switch to gas %d (%d/%d) @ %5.2lfm\n", gaschanges[gi].gasidx,
			       (get_o2(&gas) + 5) / 10, (get_he(&gas) + 5) / 10, gaschanges[gi].depth / 1000.0);
#endif
			gi--;
		}

		--stopidx;

		/* Save the current state and try to ascend to the next stopdepth */
		int trial_depth = depth;
		cache_deco_state(tissue_tolerance, &trial_cache);
		while (1) {
			/* Check if ascending to next stop is clear, go back and wait if we hit the ceiling on the way */
			clear_to_ascend = true;
			while (trial_depth > stoplevels[stopidx]) {
				int deltad = ascend_velocity(trial_depth, avg_depth, bottom_time) * TIMESTEP;
				if (deltad > trial_depth) /* don't test against depth above surface */
					deltad = trial_depth;
				tissue_tolerance = add_segment(depth_to_mbar(trial_depth, &displayed_dive) / 1000.0,
							       &displayed_dive.cylinder[current_cylinder].gasmix,
							       TIMESTEP, po2, &displayed_dive);
				if (deco_allowed_depth(tissue_tolerance, diveplan->surface_pressure / 1000.0, &displayed_dive, 1) > trial_depth - deltad) {
					/* We should have stopped */
					clear_to_ascend = false;
					break;
				}
				trial_depth -= deltad;
			}
			restore_deco_state(trial_cache);

			if (clear_to_ascend)
				break; /* We did not hit the ceiling */

			/* Add a minute of deco time and then try again */
			if (!stopping) {
				/* The last segment was an ascend segment.
				 * Add a waypoint for start of this deco stop */
				plan_add_segment(diveplan, clock - previous_point_time, depth, gas, po2, false);
				previous_point_time = clock;
				stopping = true;
			}
			tissue_tolerance = add_segment(depth_to_mbar(depth, &displayed_dive) / 1000.0,
						       &displayed_dive.cylinder[current_cylinder].gasmix,
						       DECOTIMESTEP, po2, &displayed_dive);
			cache_deco_state(tissue_tolerance, &trial_cache);
			clock += DECOTIMESTEP;
			if (prefs.doo2breaks) {
				if (get_o2(&displayed_dive.cylinder[current_cylinder].gasmix) == 1000) {
					o2time += DECOTIMESTEP;
					if (o2time >= 12 * 60) {
						breaktime = 0;
						breakcylinder = current_cylinder;
						plan_add_segment(diveplan, clock - previous_point_time, depth, gas, po2, false);
						previous_point_time = clock;
						current_cylinder = 0;
						gas = displayed_dive.cylinder[current_cylinder].gasmix;
					}
				} else {
					if (breaktime >= 0) {
						breaktime += DECOTIMESTEP;
						if (breaktime >= 6 * 60) {
							o2time = 0;
							plan_add_segment(diveplan, clock - previous_point_time, depth, gas, po2, false);
							previous_point_time = clock;
							current_cylinder = breakcylinder;
							gas = displayed_dive.cylinder[current_cylinder].gasmix;
							breaktime = -1;
						}
					}
				}
			}
			trial_depth = depth;
		}
		if (stopping) {
			/* Next we will ascend again. Add a waypoint if we have spend deco time */
			plan_add_segment(diveplan, clock - previous_point_time, depth, gas, po2, false);
			previous_point_time = clock;
			stopping = false;
		}
	}

	/* We made it to the surface */
	plan_add_segment(diveplan, clock - previous_point_time, 0, gas, po2, false);
	create_dive_from_plan(diveplan, is_planner);
	add_plan_to_notes(diveplan, &displayed_dive, show_disclaimer);

	free(stoplevels);
	free(gaschanges);
}
Exemplo n.º 4
0
static void add_plan_to_notes(struct diveplan *diveplan, struct dive *dive, bool show_disclaimer)
{
	char buffer[20000], temp[1000];
	int len, gasidx, lastdepth = 0, lasttime = 0;
	struct divedatapoint *dp = diveplan->dp;
	bool gaschange = !plan_verbatim;
	struct divedatapoint *nextdp = NULL;

	disclaimer =  translate("gettextFromC", "DISCLAIMER / WARNING: THIS IS A NEW IMPLEMENTATION OF THE BUHLMANN "
				"ALGORITHM AND A DIVE PLANNER IMPLEMENTION BASED ON THAT WHICH HAS "
				"RECEIVED ONLY A LIMITED AMOUNT OF TESTING. WE STRONGLY RECOMMEND NOT TO "
				"PLAN DIVES SIMPLY BASED ON THE RESULTS GIVEN HERE.");

	if (!dp)
		return;

	len = show_disclaimer ? snprintf(buffer, sizeof(buffer), "<div><b>%s<b></div><br>", disclaimer) : 0;
	snprintf(temp, sizeof(temp), translate("gettextFromC", "based on GFlow = %d and GFhigh = %d"),
		 diveplan->gflow, diveplan->gfhigh);
	len += snprintf(buffer + len, sizeof(buffer) - len, "<div><b>%s</b><br>%s</div><br>",
			translate("gettextFromC", "Subsurface dive plan"), temp);

	if (!plan_verbatim) {
		len += snprintf(buffer + len, sizeof(buffer) - len, "<div><table><thead><tr><th>%s</th>",
				translate("gettextFromC", "depth"));
		if (plan_display_runtime)
			len += snprintf(buffer + len, sizeof(buffer) - len, "<th style='padding-left: 10px;'>%s</th>",
					translate("gettextFromC", "runtime"));
		if (plan_display_duration)
			len += snprintf(buffer + len, sizeof(buffer) - len, "<th style='padding-left: 10px;'>%s</th>",
					translate("gettextFromC", "duration"));
		len += snprintf(buffer + len, sizeof(buffer) - len,
				"<th style='padding-left: 10px; float: left;'>%s</th></tr></thead><tbody style='float: left;'>",
				translate("gettextFromC", "gas"));
	}
	do {
		struct gasmix gasmix, newgasmix;
		const char *depth_unit;
		double depthvalue;
		int decimals;

		if (dp->time == 0)
			continue;
		gasmix = dp->gasmix;
		depthvalue = get_depth_units(dp->depth, &decimals, &depth_unit);
		/* analyze the dive points ahead */
		nextdp = dp->next;
		while (nextdp && nextdp->time == 0)
			nextdp = nextdp->next;
		if (nextdp) {
			newgasmix = nextdp->gasmix;
			if (gasmix_is_null(&newgasmix))
				newgasmix = gasmix;
		}
		/* do we want to skip this leg as it is devoid of anything useful? */
		if (!dp->entered &&
		    gasmix_distance(&gasmix, &newgasmix) == 0 &&
		    nextdp &&
		    dp->depth != lastdepth &&
		    nextdp->depth != dp->depth)
			continue;
		if (dp->time - lasttime < 10 && !(gaschange && dp->next && dp->depth != dp->next->depth))
			continue;
		gasidx = get_gasidx(dive, &gasmix);
		len = strlen(buffer);
		if (nextdp && gasmix_distance(&gasmix, &newgasmix))
			gaschange = true;
		if (plan_verbatim) {
			if (dp->depth != lastdepth) {
				if (plan_display_transitions || dp->entered || !dp->next || (gaschange && dp->next && dp->depth != nextdp->depth)) {
					snprintf(temp, sizeof(temp), translate("gettextFromC", "Transition to %.*f %s in %d:%02d min - runtime %d:%02u on %s"),
						 decimals, depthvalue, depth_unit,
						 FRACTION(dp->time - lasttime, 60),
						 FRACTION(dp->time, 60),
						 gasname(&gasmix));
					len += snprintf(buffer + len, sizeof(buffer) - len, "%s<br>", temp);
					lasttime = dp->time;
				}
			} else {
				if (dp->depth != nextdp->depth) {
					snprintf(temp, sizeof(temp), translate("gettextFromC", "Stay at %.*f %s for %d:%02d min - runtime %d:%02u on %s"),
							decimals, depthvalue, depth_unit,
							FRACTION(dp->time - lasttime, 60),
							FRACTION(dp->time, 60),
							gasname(&gasmix));
					len += snprintf(buffer + len, sizeof(buffer) - len, "%s<br>", temp);
					lasttime = dp->time;
				}
			}
		} else {
			if ((dp->depth == lastdepth && dp->depth != nextdp->depth) || plan_display_transitions || dp->entered || !dp->next || (gaschange && dp->next && dp->depth != nextdp->depth)) {
				snprintf(temp, sizeof(temp), translate("gettextFromC", "%3.0f%s"), depthvalue, depth_unit);
				len += snprintf(buffer + len, sizeof(buffer) - len, "<tr><td style='padding-left: 10px; float: right;'>%s</td>", temp);
				if (plan_display_runtime) {
					snprintf(temp, sizeof(temp), translate("gettextFromC", "%3dmin"), (dp->time + 30) / 60);
					len += snprintf(buffer + len, sizeof(buffer) - len, "<td style='padding-left: 10px; float: right;'>%s</td>", temp);
				}
				if (plan_display_duration) {
					snprintf(temp, sizeof(temp), translate("gettextFromC", "%3dmin"), (dp->time - lasttime + 30) / 60);
					len += snprintf(buffer + len, sizeof(buffer) - len, "<td style='padding-left: 10px; float: right;'>%s</td>", temp);
				}
				if (gaschange) {
					len += snprintf(buffer + len, sizeof(buffer) - len, "<td style='padding-left: 10px; color: red; float: left;'><b>%s</b></td>", gasname(&newgasmix));
					gaschange = false;
				} else {
					len += snprintf(buffer + len, sizeof(buffer) - len, "<td>&nbsp;</td>");
				}
				len += snprintf(buffer + len, sizeof(buffer) - len, "</tr>");
				lasttime = dp->time;
			}
		}
		if (gaschange) {
			// gas switch at this waypoint
			if (plan_verbatim) {
				snprintf(temp, sizeof(temp), translate("gettextFromC", "Switch gas to %s"), gasname(&newgasmix));
				len += snprintf(buffer + len, sizeof(buffer) - len, "%s<br>", temp);
				gaschange = false;
			}
			gasmix = newgasmix;
		}
		lastdepth = dp->depth;
	} while ((dp = nextdp) != NULL);

	snprintf(temp, sizeof(temp), "%s", translate("gettextFromC", "Gas consumption:"));
	len += snprintf(buffer + len, sizeof(buffer) - len, "</tbody></table></div><div><br>%s<br>", temp);
	for (gasidx = 0; gasidx < MAX_CYLINDERS; gasidx++) {
		double volume, deco_volume, deco_pressure;
		const char *unit, *pressure_unit;
		char warning[1000] = "";
		cylinder_t *cyl = &dive->cylinder[gasidx];
		if (cylinder_none(cyl))
			break;

		volume = get_volume_units(cyl->gas_used.mliter, NULL, &unit);
		deco_volume = get_volume_units(cyl->deco_gas_used.mliter, NULL, &unit);
		if (cyl->type.size.mliter) {
			deco_pressure = get_pressure_units(1000.0 * cyl->deco_gas_used.mliter / cyl->type.size.mliter, &pressure_unit);
			/* Warn if the plan uses more gas than is available in a cylinder
			 * This only works if we have working pressure for the cylinder
			 * 10bar is a made up number - but it seemed silly to pretend you could breathe cylinder down to 0 */
			if (cyl->end.mbar < 10000)
				snprintf(warning, sizeof(warning), " &mdash; <span style='color: red;'>%s </span> %s",
					translate("gettextFromC", "Warning:"),
					translate("gettextFromC", "this is more gas than available in the specified cylinder!"));
			snprintf(temp, sizeof(temp), translate("gettextFromC", "%.0f%s (%.0f%s/%.0f%s in planned ascent) of %s"), volume, unit, deco_volume, unit, deco_pressure, pressure_unit, gasname(&cyl->gasmix));
		} else {
			snprintf(temp, sizeof(temp), translate("gettextFromC", "%.0f%s (%.0f%s during planned ascent) of %s"), volume, unit, deco_volume, unit, gasname(&cyl->gasmix));
		}
		len += snprintf(buffer + len, sizeof(buffer) - len, "%s%s<br>", temp, warning);
	}
	dp = diveplan->dp;
	while (dp) {
		if (dp->time != 0) {
			int pO2 = depth_to_atm(dp->depth, dive) * dp->gasmix.o2.permille;

			if (pO2 > 1600) {
				const char *depth_unit;
				int decimals;
				double depth_value = get_depth_units(dp->depth, &decimals, &depth_unit);
				len = strlen(buffer);
				snprintf(temp, sizeof(temp),
					 translate("gettextFromC", "high pO₂ value %.2f at %d:%02u with gas %s at depth %.*f %s"),
					 pO2 / 1000.0, FRACTION(dp->time, 60), gasname(&dp->gasmix), decimals, depth_value, depth_unit);
				len += snprintf(buffer + len, sizeof(buffer) - len, "<span style='color: red;'>%s </span> %s<br>",
						translate("gettextFromC", "Warning:"), temp);
			}
		}
		dp = dp->next;
	}
	snprintf(buffer + len, sizeof(buffer) - len, "</div>");
	dive->notes = strdup(buffer);
}
Exemplo n.º 5
0
bool plan(struct diveplan *diveplan, char **cached_datap, bool is_planner, bool show_disclaimer)
{
	struct sample *sample;
	int po2;
	int transitiontime, gi;
	int current_cylinder;
	unsigned int stopidx;
	int depth;
	double tissue_tolerance = 0.0;
	struct gaschanges *gaschanges = NULL;
	int gaschangenr;
	unsigned int *stoplevels = NULL;
	bool stopping = false;
	bool clear_to_ascend;
	int clock, previous_point_time;
	int avg_depth, max_depth, bottom_time = 0;
	int last_ascend_rate;
	int best_first_ascend_cylinder;
	struct gasmix gas;
	int o2time = 0;
	int breaktime = -1;
	int breakcylinder = 0;
	int error = 0;
	bool decodive = false;

	set_gf(diveplan->gflow, diveplan->gfhigh, prefs.gf_low_at_maxdepth);
	if (!diveplan->surface_pressure)
		diveplan->surface_pressure = SURFACE_PRESSURE;
	create_dive_from_plan(diveplan, is_planner);

	if (prefs.verbatim_plan)
		plan_verbatim = true;
	if (prefs.display_runtime)
		plan_display_runtime = true;
	if (prefs.display_duration)
		plan_display_duration = true;
	if (prefs.display_transitions)
		plan_display_transitions = true;
	if (prefs.last_stop)
		decostoplevels[1] = 6000;

	/* Let's start at the last 'sample', i.e. the last manually entered waypoint. */
	sample = &displayed_dive.dc.sample[displayed_dive.dc.samples - 1];

	get_gas_at_time(&displayed_dive, &displayed_dive.dc, sample->time, &gas);

	po2 = sample->setpoint.mbar;
	if ((current_cylinder = get_gasidx(&displayed_dive, &gas)) == -1) {
		report_error(translate("gettextFromC", "Can't find gas %s"), gasname(&gas));
		current_cylinder = 0;
	}
	depth = displayed_dive.dc.sample[displayed_dive.dc.samples - 1].depth.mm;
	average_max_depth(diveplan, &avg_depth, &max_depth);
	last_ascend_rate = ascent_velocity(depth, avg_depth, bottom_time);

	/* if all we wanted was the dive just get us back to the surface */
	if (!is_planner) {
		transitiontime = depth / 75; /* this still needs to be made configurable */
		plan_add_segment(diveplan, transitiontime, 0, gas, po2, false);
		create_dive_from_plan(diveplan, is_planner);
		return(false);
	}
	tissue_tolerance = tissue_at_end(&displayed_dive, cached_datap);

#if DEBUG_PLAN & 4
	printf("gas %s\n", gasname(&gas));
	printf("depth %5.2lfm \n", depth / 1000.0);
#endif

	best_first_ascend_cylinder = current_cylinder;
	/* Find the gases available for deco */

	if (po2) {	// Don't change gas in CCR mode
		gaschanges = NULL;
		gaschangenr = 0;
	} else {
		gaschanges = analyze_gaslist(diveplan, &gaschangenr, depth, &best_first_ascend_cylinder);
	}
	/* Find the first potential decostopdepth above current depth */
	for (stopidx = 0; stopidx < sizeof(decostoplevels) / sizeof(int); stopidx++)
		if (decostoplevels[stopidx] >= depth)
			break;
	if (stopidx > 0)
		stopidx--;
	/* Stoplevels are either depths of gas changes or potential deco stop depths. */
	stoplevels = sort_stops(decostoplevels, stopidx + 1, gaschanges, gaschangenr);
	stopidx += gaschangenr;

	/* Keep time during the ascend */
	bottom_time = clock = previous_point_time = displayed_dive.dc.sample[displayed_dive.dc.samples - 1].time.seconds;
	gi = gaschangenr - 1;
	if(prefs.recreational_mode) {
		bool safety_stop = prefs.safetystop && max_depth >= 10000;
		track_ascent_gas(depth, &displayed_dive.cylinder[current_cylinder], avg_depth, bottom_time, safety_stop);
		// How long can we stay at the current depth and still directly ascent to the surface?
		while (trial_ascent(depth, 0, avg_depth, bottom_time, tissue_tolerance, &displayed_dive.cylinder[current_cylinder].gasmix,
				  po2, diveplan->surface_pressure / 1000.0) &&
		       enough_gas(current_cylinder)) {
			tissue_tolerance = add_segment(depth_to_mbar(depth, &displayed_dive) / 1000.0,
						       &displayed_dive.cylinder[current_cylinder].gasmix,
						       DECOTIMESTEP, po2, &displayed_dive, prefs.bottomsac);
			update_cylinder_pressure(&displayed_dive, depth, depth, DECOTIMESTEP, prefs.bottomsac, &displayed_dive.cylinder[current_cylinder], false);
			clock += DECOTIMESTEP;
		}
		clock -= DECOTIMESTEP;
		plan_add_segment(diveplan, clock - previous_point_time, depth, gas, po2, true);
		previous_point_time = clock;
		do {
			/* Ascend to surface */
			int deltad = ascent_velocity(depth, avg_depth, bottom_time) * TIMESTEP;
			if (ascent_velocity(depth, avg_depth, bottom_time) != last_ascend_rate) {
				plan_add_segment(diveplan, clock - previous_point_time, depth, gas, po2, false);
				previous_point_time = clock;
				last_ascend_rate = ascent_velocity(depth, avg_depth, bottom_time);
			}
			if (depth - deltad < 0)
				deltad = depth;

			tissue_tolerance = add_segment(depth_to_mbar(depth, &displayed_dive) / 1000.0,
						       &displayed_dive.cylinder[current_cylinder].gasmix,
						       TIMESTEP, po2, &displayed_dive, prefs.decosac);
			clock += TIMESTEP;
			depth -= deltad;
			if (depth <= 5000 && depth >= (5000 - deltad) && safety_stop) {
				plan_add_segment(diveplan, clock - previous_point_time, 5000, gas, po2, false);
				previous_point_time = clock;
				clock += 180;
				plan_add_segment(diveplan, clock - previous_point_time, 5000, gas, po2, false);
				previous_point_time = clock;
				safety_stop = false;
			}
		} while (depth > 0);
		plan_add_segment(diveplan, clock - previous_point_time, 0, gas, po2, false);
		create_dive_from_plan(diveplan, is_planner);
		add_plan_to_notes(diveplan, &displayed_dive, show_disclaimer, error);
		fixup_dc_duration(&displayed_dive.dc);

		free(stoplevels);
		free(gaschanges);

		return(false);
	}

	if (best_first_ascend_cylinder != current_cylinder) {
		stopping = true;

		current_cylinder = best_first_ascend_cylinder;
		gas = displayed_dive.cylinder[current_cylinder].gasmix;

#if DEBUG_PLAN & 16
		printf("switch to gas %d (%d/%d) @ %5.2lfm\n", best_first_ascend_cylinder,
		       (get_o2(&gas) + 5) / 10, (get_he(&gas) + 5) / 10, gaschanges[best_first_ascend_cylinder].depth / 1000.0);
#endif
	}
	while (1) {
		/* We will break out when we hit the surface */
		do {
			/* Ascend to next stop depth */
			int deltad = ascent_velocity(depth, avg_depth, bottom_time) * TIMESTEP;
			if (ascent_velocity(depth, avg_depth, bottom_time) != last_ascend_rate) {
				plan_add_segment(diveplan, clock - previous_point_time, depth, gas, po2, false);
				previous_point_time = clock;
				stopping = false;
				last_ascend_rate = ascent_velocity(depth, avg_depth, bottom_time);
			}
			if (depth - deltad < stoplevels[stopidx])
				deltad = depth - stoplevels[stopidx];

			tissue_tolerance = add_segment(depth_to_mbar(depth, &displayed_dive) / 1000.0,
						       &displayed_dive.cylinder[current_cylinder].gasmix,
						       TIMESTEP, po2, &displayed_dive, prefs.decosac);
			clock += TIMESTEP;
			depth -= deltad;
		} while (depth > 0 && depth > stoplevels[stopidx]);

		if (depth <= 0)
			break; /* We are at the surface */

		if (gi >= 0 && stoplevels[stopidx] == gaschanges[gi].depth) {
			/* We have reached a gas change.
			 * Record this in the dive plan */
			plan_add_segment(diveplan, clock - previous_point_time, depth, gas, po2, false);
			previous_point_time = clock;
			stopping = true;

			/* Check we need to change cylinder.
			 * We might not if the cylinder was chosen by the user */
			if (current_cylinder != gaschanges[gi].gasidx) {
				current_cylinder = gaschanges[gi].gasidx;
				gas = displayed_dive.cylinder[current_cylinder].gasmix;
#if DEBUG_PLAN & 16
				printf("switch to gas %d (%d/%d) @ %5.2lfm\n", gaschanges[gi].gasidx,
					(get_o2(&gas) + 5) / 10, (get_he(&gas) + 5) / 10, gaschanges[gi].depth / 1000.0);
#endif
				/* Stop for the minimum duration to switch gas */
				tissue_tolerance = add_segment(depth_to_mbar(depth, &displayed_dive) / 1000.0,
					&displayed_dive.cylinder[current_cylinder].gasmix,
					prefs.min_switch_duration, po2, &displayed_dive, prefs.decosac);
				clock += prefs.min_switch_duration;
			}
			gi--;
		}

		--stopidx;

		/* Save the current state and try to ascend to the next stopdepth */
		while (1) {
			/* Check if ascending to next stop is clear, go back and wait if we hit the ceiling on the way */
			if (trial_ascent(depth, stoplevels[stopidx], avg_depth, bottom_time, tissue_tolerance,
					 &displayed_dive.cylinder[current_cylinder].gasmix, po2, diveplan->surface_pressure / 1000.0))
				break; /* We did not hit the ceiling */

			/* Add a minute of deco time and then try again */
			decodive = true;
			if (!stopping) {
				/* The last segment was an ascend segment.
				 * Add a waypoint for start of this deco stop */
				plan_add_segment(diveplan, clock - previous_point_time, depth, gas, po2, false);
				previous_point_time = clock;
				stopping = true;
			}

			/* Deco stop should end when runtime is at a whole minute */
			int this_decotimestep;
			this_decotimestep = DECOTIMESTEP - clock % DECOTIMESTEP;

			tissue_tolerance = add_segment(depth_to_mbar(depth, &displayed_dive) / 1000.0,
						       &displayed_dive.cylinder[current_cylinder].gasmix,
						       this_decotimestep, po2, &displayed_dive, prefs.decosac);
			clock += this_decotimestep;
			/* Finish infinite deco */
			if(clock >= 48 * 3600 && depth >= 6000) {
				error = LONGDECO;
				break;
			}
			if (prefs.doo2breaks) {
				if (get_o2(&displayed_dive.cylinder[current_cylinder].gasmix) == 1000) {
					o2time += DECOTIMESTEP;
					if (o2time >= 12 * 60) {
						breaktime = 0;
						breakcylinder = current_cylinder;
						plan_add_segment(diveplan, clock - previous_point_time, depth, gas, po2, false);
						previous_point_time = clock;
						current_cylinder = 0;
						gas = displayed_dive.cylinder[current_cylinder].gasmix;
					}
				} else {
					if (breaktime >= 0) {
						breaktime += DECOTIMESTEP;
						if (breaktime >= 6 * 60) {
							o2time = 0;
							plan_add_segment(diveplan, clock - previous_point_time, depth, gas, po2, false);
							previous_point_time = clock;
							current_cylinder = breakcylinder;
							gas = displayed_dive.cylinder[current_cylinder].gasmix;
							breaktime = -1;
						}
					}
				}
			}
		}
		if (stopping) {
			/* Next we will ascend again. Add a waypoint if we have spend deco time */
			plan_add_segment(diveplan, clock - previous_point_time, depth, gas, po2, false);
			previous_point_time = clock;
			stopping = false;
		}
	}

	/* We made it to the surface
	 * Create the final dive, add the plan to the notes and fixup some internal
	 * data that we need to be there when plotting the dive */
	plan_add_segment(diveplan, clock - previous_point_time, 0, gas, po2, false);
	create_dive_from_plan(diveplan, is_planner);
	add_plan_to_notes(diveplan, &displayed_dive, show_disclaimer, error);
	fixup_dc_duration(&displayed_dive.dc);

	free(stoplevels);
	free(gaschanges);
	return decodive;
}
Exemplo n.º 6
0
bool plan(struct diveplan *diveplan, char **cached_datap, bool is_planner, bool show_disclaimer)
{
	int bottom_depth;
	int bottom_gi;
	int bottom_stopidx;
	bool is_final_plan = true;
	int deco_time;
	int previous_deco_time;
	char *bottom_cache = NULL;
	struct sample *sample;
	int po2;
	int transitiontime, gi;
	int current_cylinder;
	unsigned int stopidx;
	int depth;
	double tissue_tolerance = 0.0;
	struct gaschanges *gaschanges = NULL;
	int gaschangenr;
	int *decostoplevels;
	int decostoplevelcount;
	unsigned int *stoplevels = NULL;
	int vpmb_first_stop;
	bool stopping = false;
	bool pendinggaschange = false;
	bool clear_to_ascend;
	int clock, previous_point_time;
	int avg_depth, max_depth, bottom_time = 0;
	int last_ascend_rate;
	int best_first_ascend_cylinder;
	struct gasmix gas, bottom_gas;
	int o2time = 0;
	int breaktime = -1;
	int breakcylinder = 0;
	int error = 0;
	bool decodive = false;

	set_gf(diveplan->gflow, diveplan->gfhigh, prefs.gf_low_at_maxdepth);
	if (!diveplan->surface_pressure)
		diveplan->surface_pressure = SURFACE_PRESSURE;
	create_dive_from_plan(diveplan, is_planner);

	// Do we want deco stop array in metres or feet?
	if (prefs.units.length == METERS ) {
		decostoplevels = decostoplevels_metric;
		decostoplevelcount = sizeof(decostoplevels_metric) / sizeof(int);
	} else {
		decostoplevels = decostoplevels_imperial;
		decostoplevelcount = sizeof(decostoplevels_imperial) / sizeof(int);
	}

	/* If the user has selected last stop to be at 6m/20', we need to get rid of the 3m/10' stop.
	 * Otherwise reinstate the last stop 3m/10' stop.
	 */
	if (prefs.last_stop)
		*(decostoplevels + 1) = 0;
	else
		*(decostoplevels + 1) = M_OR_FT(3,10);

	/* Let's start at the last 'sample', i.e. the last manually entered waypoint. */
	sample = &displayed_dive.dc.sample[displayed_dive.dc.samples - 1];

	get_gas_at_time(&displayed_dive, &displayed_dive.dc, sample->time, &gas);

	po2 = sample->setpoint.mbar;
	if ((current_cylinder = get_gasidx(&displayed_dive, &gas)) == -1) {
		report_error(translate("gettextFromC", "Can't find gas %s"), gasname(&gas));
		current_cylinder = 0;
	}
	depth = displayed_dive.dc.sample[displayed_dive.dc.samples - 1].depth.mm;
	average_max_depth(diveplan, &avg_depth, &max_depth);
	last_ascend_rate = ascent_velocity(depth, avg_depth, bottom_time);

	/* if all we wanted was the dive just get us back to the surface */
	if (!is_planner) {
		transitiontime = depth / 75; /* this still needs to be made configurable */
		plan_add_segment(diveplan, transitiontime, 0, gas, po2, false);
		create_dive_from_plan(diveplan, is_planner);
		return(false);
	}
	calc_crushing_pressure(depth_to_mbar(depth, &displayed_dive) / 1000.0);
	nuclear_regeneration(clock);
	clear_deco(displayed_dive.surface_pressure.mbar / 1000.0);
	vpmb_start_gradient();
	previous_deco_time = 100000000;
	deco_time = 10000000;

	tissue_tolerance = tissue_at_end(&displayed_dive, cached_datap);
	displayed_dive.surface_pressure.mbar = diveplan->surface_pressure;

#if DEBUG_PLAN & 4
	printf("gas %s\n", gasname(&gas));
	printf("depth %5.2lfm \n", depth / 1000.0);
#endif

	best_first_ascend_cylinder = current_cylinder;
	/* Find the gases available for deco */

	if (po2) {	// Don't change gas in CCR mode
		gaschanges = NULL;
		gaschangenr = 0;
	} else {
		gaschanges = analyze_gaslist(diveplan, &gaschangenr, depth, &best_first_ascend_cylinder);
	}
	/* Find the first potential decostopdepth above current depth */
	for (stopidx = 0; stopidx < decostoplevelcount; stopidx++)
		if (*(decostoplevels + stopidx) >= depth)
			break;
	if (stopidx > 0)
		stopidx--;
	/* Stoplevels are either depths of gas changes or potential deco stop depths. */
	stoplevels = sort_stops(decostoplevels, stopidx + 1, gaschanges, gaschangenr);
	stopidx += gaschangenr;

	/* Keep time during the ascend */
	bottom_time = clock = previous_point_time = displayed_dive.dc.sample[displayed_dive.dc.samples - 1].time.seconds;
	gi = gaschangenr - 1;

	if(prefs.deco_mode == RECREATIONAL) {
		bool safety_stop = prefs.safetystop && max_depth >= 10000;
		track_ascent_gas(depth, &displayed_dive.cylinder[current_cylinder], avg_depth, bottom_time, safety_stop);
		// How long can we stay at the current depth and still directly ascent to the surface?
		while (trial_ascent(depth, 0, avg_depth, bottom_time, tissue_tolerance, &displayed_dive.cylinder[current_cylinder].gasmix,
				  po2, diveplan->surface_pressure / 1000.0) &&
		       enough_gas(current_cylinder)) {
			tissue_tolerance = add_segment(depth_to_mbar(depth, &displayed_dive) / 1000.0,
						       &displayed_dive.cylinder[current_cylinder].gasmix,
						       DECOTIMESTEP, po2, &displayed_dive, prefs.bottomsac);
			update_cylinder_pressure(&displayed_dive, depth, depth, DECOTIMESTEP, prefs.bottomsac, &displayed_dive.cylinder[current_cylinder], false);
			clock += DECOTIMESTEP;
		}
		clock -= DECOTIMESTEP;
		plan_add_segment(diveplan, clock - previous_point_time, depth, gas, po2, true);
		previous_point_time = clock;
		do {
			/* Ascend to surface */
			int deltad = ascent_velocity(depth, avg_depth, bottom_time) * TIMESTEP;
			if (ascent_velocity(depth, avg_depth, bottom_time) != last_ascend_rate) {
				plan_add_segment(diveplan, clock - previous_point_time, depth, gas, po2, false);
				previous_point_time = clock;
				last_ascend_rate = ascent_velocity(depth, avg_depth, bottom_time);
			}
			if (depth - deltad < 0)
				deltad = depth;

			tissue_tolerance = add_segment(depth_to_mbar(depth, &displayed_dive) / 1000.0,
						       &displayed_dive.cylinder[current_cylinder].gasmix,
						       TIMESTEP, po2, &displayed_dive, prefs.decosac);
			clock += TIMESTEP;
			depth -= deltad;
			if (depth <= 5000 && depth >= (5000 - deltad) && safety_stop) {
				plan_add_segment(diveplan, clock - previous_point_time, 5000, gas, po2, false);
				previous_point_time = clock;
				clock += 180;
				plan_add_segment(diveplan, clock - previous_point_time, 5000, gas, po2, false);
				previous_point_time = clock;
				safety_stop = false;
			}
		} while (depth > 0);
		plan_add_segment(diveplan, clock - previous_point_time, 0, gas, po2, false);
		create_dive_from_plan(diveplan, is_planner);
		add_plan_to_notes(diveplan, &displayed_dive, show_disclaimer, error);
		fixup_dc_duration(&displayed_dive.dc);

		free(stoplevels);
		free(gaschanges);
		return(false);
	}

	if (best_first_ascend_cylinder != current_cylinder) {
		stopping = true;

		current_cylinder = best_first_ascend_cylinder;
		gas = displayed_dive.cylinder[current_cylinder].gasmix;

#if DEBUG_PLAN & 16
		printf("switch to gas %d (%d/%d) @ %5.2lfm\n", best_first_ascend_cylinder,
		       (get_o2(&gas) + 5) / 10, (get_he(&gas) + 5) / 10, gaschanges[best_first_ascend_cylinder].depth / 1000.0);
#endif
	}

	// VPM-B or Buehlmann Deco
	nuclear_regeneration(clock);
	vpmb_start_gradient();
	previous_deco_time = 100000000;
	deco_time = 10000000;
	cache_deco_state(tissue_tolerance, &bottom_cache);  // Lets us make several iterations
	bottom_depth = depth;
	bottom_gi = gi;
	bottom_gas = gas;
	bottom_stopidx = stopidx;

	// Find first stop used for VPM-B Boyle's law compensation
	if (prefs.deco_mode == VPMB) {
		vpmb_first_stop = deco_allowed_depth(tissue_tolerance, diveplan->surface_pressure / 1000, &displayed_dive, 1);
		if (vpmb_first_stop > 0) {
			while (stoplevels[stopidx] > vpmb_first_stop) {
				stopidx--;
			}
			stopidx++;
			vpmb_first_stop = stoplevels[stopidx];
		}
		first_stop_pressure.mbar = depth_to_mbar(vpmb_first_stop, &displayed_dive);
	} else {
		first_stop_pressure.mbar = 0;
	}

	//CVA
	do {
		is_final_plan = (prefs.deco_mode == BUEHLMANN) || (previous_deco_time - deco_time < 10);  // CVA time converges
		if (deco_time != 10000000)
			vpmb_next_gradient(deco_time, diveplan->surface_pressure / 1000.0);

		previous_deco_time = deco_time;
		tissue_tolerance = restore_deco_state(bottom_cache);

		depth = bottom_depth;
		gi = bottom_gi;
		clock = previous_point_time = bottom_time;
		gas = bottom_gas;
		stopping = false;
		decodive = false;
		stopidx = bottom_stopidx;
		breaktime = -1;
		breakcylinder = 0;
		o2time = 0;
		last_ascend_rate = ascent_velocity(depth, avg_depth, bottom_time);
		if ((current_cylinder = get_gasidx(&displayed_dive, &gas)) == -1) {
			report_error(translate("gettextFromC", "Can't find gas %s"), gasname(&gas));
			current_cylinder = 0;
		}

		while (1) {
			/* We will break out when we hit the surface */
			do {
				/* Ascend to next stop depth */
				int deltad = ascent_velocity(depth, avg_depth, bottom_time) * TIMESTEP;
				if (ascent_velocity(depth, avg_depth, bottom_time) != last_ascend_rate) {
					if (is_final_plan)
						plan_add_segment(diveplan, clock - previous_point_time, depth, gas, po2, false);
					previous_point_time = clock;
					stopping = false;
					last_ascend_rate = ascent_velocity(depth, avg_depth, bottom_time);
				}
				if (depth - deltad < stoplevels[stopidx])
					deltad = depth - stoplevels[stopidx];

				tissue_tolerance = add_segment(depth_to_mbar(depth, &displayed_dive) / 1000.0,
								&displayed_dive.cylinder[current_cylinder].gasmix,
								TIMESTEP, po2, &displayed_dive, prefs.decosac);
				clock += TIMESTEP;
				depth -= deltad;
			} while (depth > 0 && depth > stoplevels[stopidx]);

			if (depth <= 0)
				break; /* We are at the surface */

			if (gi >= 0 && stoplevels[stopidx] <= gaschanges[gi].depth) {
				/* We have reached a gas change.
				 * Record this in the dive plan */
				if (is_final_plan)
					plan_add_segment(diveplan, clock - previous_point_time, depth, gas, po2, false);
				previous_point_time = clock;
				stopping = true;

				// Boyles Law compensation
				boyles_law(depth_to_mbar(stoplevels[stopidx], &displayed_dive) / 1000.0);

				/* Check we need to change cylinder.
				 * We might not if the cylinder was chosen by the user
				 * or user has selected only to switch only at required stops.
				 * If current gas is hypoxic, we want to switch asap */

				if (current_cylinder != gaschanges[gi].gasidx) {
					if (!prefs.switch_at_req_stop ||
							!trial_ascent(depth, stoplevels[stopidx - 1], avg_depth, bottom_time, tissue_tolerance,
							&displayed_dive.cylinder[current_cylinder].gasmix, po2, diveplan->surface_pressure / 1000.0) || get_o2(&displayed_dive.cylinder[current_cylinder].gasmix) < 160) {
						current_cylinder = gaschanges[gi].gasidx;
						gas = displayed_dive.cylinder[current_cylinder].gasmix;
#if DEBUG_PLAN & 16
						printf("switch to gas %d (%d/%d) @ %5.2lfm\n", gaschanges[gi].gasidx,
							(get_o2(&gas) + 5) / 10, (get_he(&gas) + 5) / 10, gaschanges[gi].depth / 1000.0);
#endif
						/* Stop for the minimum duration to switch gas */
						tissue_tolerance = add_segment(depth_to_mbar(depth, &displayed_dive) / 1000.0,
							&displayed_dive.cylinder[current_cylinder].gasmix,
							prefs.min_switch_duration, po2, &displayed_dive, prefs.decosac);
						clock += prefs.min_switch_duration;
						if (prefs.doo2breaks && get_o2(&displayed_dive.cylinder[current_cylinder].gasmix) == 1000)
							o2time += prefs.min_switch_duration;
					} else {
						/* The user has selected the option to switch gas only at required stops.
						 * Remember that we are waiting to switch gas
						 */
						pendinggaschange = true;
					}
				}
				gi--;
			}
			--stopidx;

			/* Save the current state and try to ascend to the next stopdepth */
			while (1) {
				/* Check if ascending to next stop is clear, go back and wait if we hit the ceiling on the way */
				if (trial_ascent(depth, stoplevels[stopidx], avg_depth, bottom_time, tissue_tolerance,
						&displayed_dive.cylinder[current_cylinder].gasmix, po2, diveplan->surface_pressure / 1000.0))
					break; /* We did not hit the ceiling */

				/* Add a minute of deco time and then try again */
				decodive = true;
				if (!stopping) {
					/* The last segment was an ascend segment.
					 * Add a waypoint for start of this deco stop */
					if (is_final_plan)
						plan_add_segment(diveplan, clock - previous_point_time, depth, gas, po2, false);
					previous_point_time = clock;
					stopping = true;

					// Boyles Law compensation
					boyles_law(depth_to_mbar(stoplevels[stopidx], &displayed_dive) / 1000.0);
				}

				/* Are we waiting to switch gas?
				 * Occurs when the user has selected the option to switch only at required stops
				 */
				if (pendinggaschange) {
					current_cylinder = gaschanges[gi + 1].gasidx;
					gas = displayed_dive.cylinder[current_cylinder].gasmix;
#if DEBUG_PLAN & 16
					printf("switch to gas %d (%d/%d) @ %5.2lfm\n", gaschanges[gi + 1].gasidx,
						(get_o2(&gas) + 5) / 10, (get_he(&gas) + 5) / 10, gaschanges[gi + 1].depth / 1000.0);
#endif
					/* Stop for the minimum duration to switch gas */
					tissue_tolerance = add_segment(depth_to_mbar(depth, &displayed_dive) / 1000.0,
						&displayed_dive.cylinder[current_cylinder].gasmix,
						prefs.min_switch_duration, po2, &displayed_dive, prefs.decosac);
					clock += prefs.min_switch_duration;
					if (prefs.doo2breaks && get_o2(&displayed_dive.cylinder[current_cylinder].gasmix) == 1000)
						o2time += prefs.min_switch_duration;
					pendinggaschange = false;
				}

				/* Deco stop should end when runtime is at a whole minute */
				int this_decotimestep;
				this_decotimestep = DECOTIMESTEP - clock % DECOTIMESTEP;

				tissue_tolerance = add_segment(depth_to_mbar(depth, &displayed_dive) / 1000.0,
								&displayed_dive.cylinder[current_cylinder].gasmix,
								this_decotimestep, po2, &displayed_dive, prefs.decosac);
				clock += this_decotimestep;
				/* Finish infinite deco */
				if(clock >= 48 * 3600 && depth >= 6000) {
					error = LONGDECO;
					break;
				}
				if (prefs.doo2breaks) {
					/* The backgas breaks option limits time on oxygen to 12 minutes, followed by 6 minutes on
					 * backgas (first defined gas).  This could be customized if there were demand.
					 */
					if (get_o2(&displayed_dive.cylinder[current_cylinder].gasmix) == 1000) {
						o2time += DECOTIMESTEP;
						if (o2time >= 12 * 60) {
							breaktime = 0;
							breakcylinder = current_cylinder;
							if (is_final_plan)
								plan_add_segment(diveplan, clock - previous_point_time, depth, gas, po2, false);
							previous_point_time = clock;
							current_cylinder = 0;
							gas = displayed_dive.cylinder[current_cylinder].gasmix;
						}
					} else {
						if (breaktime >= 0) {
							breaktime += DECOTIMESTEP;
							if (breaktime >= 6 * 60) {
								o2time = 0;
								if (is_final_plan)
									plan_add_segment(diveplan, clock - previous_point_time, depth, gas, po2, false);
								previous_point_time = clock;
								current_cylinder = breakcylinder;
								gas = displayed_dive.cylinder[current_cylinder].gasmix;
								breaktime = -1;
							}
						}
					}
				}
			}
			if (stopping) {
				/* Next we will ascend again. Add a waypoint if we have spend deco time */
				if (is_final_plan)
					plan_add_segment(diveplan, clock - previous_point_time, depth, gas, po2, false);
				previous_point_time = clock;
				stopping = false;
			}
		}

		deco_time = clock - bottom_time;
	} while (!is_final_plan);

	plan_add_segment(diveplan, clock - previous_point_time, 0, gas, po2, false);
	create_dive_from_plan(diveplan, is_planner);
	add_plan_to_notes(diveplan, &displayed_dive, show_disclaimer, error);
	fixup_dc_duration(&displayed_dive.dc);

	free(stoplevels);
	free(gaschanges);
	return decodive;
}