subsurface/core/liquivision.c

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C
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#include <string.h>
#include "dive.h"
#include "divelist.h"
#include "file.h"
#include "strndup.h"
// Convert bytes into an INT
#define array_uint16_le(p) ((unsigned int) (p)[0] \
+ ((p)[1]<<8) )
#define array_uint32_le(p) ((unsigned int) (p)[0] \
+ ((p)[1]<<8) + ((p)[2]<<16) \
+ ((p)[3]<<24))
struct lv_event {
time_t time;
struct pressure {
int sensor;
int mbar;
} pressure;
};
uint16_t primary_sensor;
static int handle_event_ver2(int code, const unsigned char *ps, unsigned int ps_ptr, struct lv_event *event)
{
(void) code;
(void) ps;
(void) ps_ptr;
(void) event;
// Skip 4 bytes
return 4;
}
static int handle_event_ver3(int code, const unsigned char *ps, unsigned int ps_ptr, struct lv_event *event)
{
int skip = 4;
uint16_t current_sensor;
switch (code) {
case 0x0002: // Unknown
case 0x0004: // Unknown
skip = 4;
break;
case 0x0005: // Unknown
skip = 6;
break;
case 0x0007: // Gas
// 4 byte time
// 1 byte O2, 1 bye He
skip = 6;
break;
case 0x0008:
// 4 byte time
// 2 byte gas setpoint 2
skip = 6;
break;
case 0x000f:
// Tank pressure
event->time = array_uint32_le(ps + ps_ptr);
/* As far as I know, Liquivision supports 2 sensors, own and buddie's. This is my
* best guess how it is represented. */
current_sensor = array_uint16_le(ps + ps_ptr + 4);
if (primary_sensor == 0) {
primary_sensor = current_sensor;
}
if (current_sensor == primary_sensor) {
event->pressure.sensor = 0;
event->pressure.mbar = array_uint16_le(ps + ps_ptr + 6) * 10; // cb->mb
} else {
/* Ignoring the buddy sensor for no as we cannot draw it on the profile.
event->pressure.sensor = 1;
event->pressure.mbar = array_uint16_le(ps + ps_ptr + 6) * 10; // cb->mb
*/
}
// 1 byte PSR
// 1 byte ST
skip = 10;
break;
case 0x0010:
skip = 26;
break;
case 0x0015: // Unknown
skip = 2;
break;
default:
skip = 4;
break;
}
return skip;
}
static void parse_dives (int log_version, const unsigned char *buf, unsigned int buf_size)
{
unsigned int ptr = 0;
unsigned char model;
struct dive *dive;
struct divecomputer *dc;
struct sample *sample;
while (ptr < buf_size) {
int i;
bool found_divesite = false;
dive = alloc_dive();
primary_sensor = 0;
dc = &dive->dc;
/* Just the main cylinder until we can handle the buddy cylinder porperly */
for (i = 0; i < 1; i++)
fill_default_cylinder(&dive->cylinder[i]);
// Model 0=Xen, 1,2=Xeo, 4=Lynx, other=Liquivision
model = *(buf + ptr);
switch (model) {
case 0:
dc->model = strdup("Xen");
break;
case 1:
case 2:
dc->model = strdup("Xeo");
break;
case 4:
dc->model = strdup("Lynx");
break;
default:
dc->model = strdup("Liquivision");
break;
}
ptr++;
// Dive location, assemble Location and Place
unsigned int len, place_len;
char *location;
len = array_uint32_le(buf + ptr);
ptr += 4;
place_len = array_uint32_le(buf + ptr + len);
if (len && place_len) {
location = malloc(len + place_len + 4);
memset(location, 0, len + place_len + 4);
memcpy(location, buf + ptr, len);
memcpy(location + len, ", ", 2);
memcpy(location + len + 2, buf + ptr + len + 4, place_len);
} else if (len) {
location = strndup((char *)buf + ptr, len);
} else if (place_len) {
location = strndup((char *)buf + ptr + len + 4, place_len);
}
/* Store the location only if we have one */
if (len || place_len)
found_divesite = true;
ptr += len + 4 + place_len;
// Dive comment
len = array_uint32_le(buf + ptr);
ptr += 4;
// Blank notes are better than the default text
if (len && strncmp((char *)buf + ptr, "Comment ...", 11)) {
dive->notes = strndup((char *)buf + ptr, len);
}
ptr += len;
dive->id = array_uint32_le(buf + ptr);
ptr += 4;
dive->number = array_uint16_le(buf + ptr) + 1;
ptr += 2;
dive->duration.seconds = array_uint32_le(buf + ptr); // seconds
ptr += 4;
dive->maxdepth.mm = array_uint16_le(buf + ptr) * 10; // cm->mm
ptr += 2;
dive->meandepth.mm = array_uint16_le(buf + ptr) * 10; // cm->mm
ptr += 2;
dive->when = array_uint32_le(buf + ptr);
ptr += 4;
// now that we have the dive time we can store the divesite
// (we need the dive time to create deterministic uuids)
if (found_divesite) {
dive->dive_site_uuid = find_or_create_dive_site_with_name(location, dive->when);
free(location);
}
//unsigned int end_time = array_uint32_le(buf + ptr);
ptr += 4;
//unsigned int sit = array_uint32_le(buf + ptr);
ptr += 4;
//if (sit == 0xffffffff) {
//}
dive->surface_pressure.mbar = array_uint16_le(buf + ptr); // ???
ptr += 2;
//unsigned int rep_dive = array_uint16_le(buf + ptr);
ptr += 2;
dive->mintemp.mkelvin = C_to_mkelvin((float)array_uint16_le(buf + ptr)/10);// C->mK
ptr += 2;
dive->maxtemp.mkelvin = C_to_mkelvin((float)array_uint16_le(buf + ptr)/10);// C->mK
ptr += 2;
dive->salinity = *(buf + ptr); // ???
ptr += 1;
unsigned int sample_count = array_uint32_le(buf + ptr);
ptr += 4;
// Sample interval
unsigned char sample_interval;
sample_interval = 1;
unsigned char intervals[6] = {1,2,5,10,30,60};
if (*(buf + ptr) < 6)
sample_interval = intervals[*(buf + ptr)];
ptr += 1;
float start_cns = 0;
unsigned char dive_mode = 0, algorithm = 0;
if (array_uint32_le(buf + ptr) != sample_count) {
// Xeo, with CNS and OTU
start_cns = *(float *) (buf + ptr);
ptr += 4;
dive->cns = lrintf(*(float *) (buf + ptr)); // end cns
ptr += 4;
dive->otu = lrintf(*(float *) (buf + ptr));
ptr += 4;
dive_mode = *(buf + ptr++); // 0=Deco, 1=Gauge, 2=None
algorithm = *(buf + ptr++); // 0=ZH-L16C+GF
sample_count = array_uint32_le(buf + ptr);
}
// we aren't using the start_cns, dive_mode, and algorithm, yet
(void)start_cns;
(void)dive_mode;
(void)algorithm;
ptr += 4;
// Parse dive samples
const unsigned char *ds = buf + ptr;
const unsigned char *ts = buf + ptr + sample_count * 2 + 4;
const unsigned char *ps = buf + ptr + sample_count * 4 + 4;
unsigned int ps_count = array_uint32_le(ps);
ps += 4;
// Bump ptr
ptr += sample_count * 4 + 4;
// Handle events
unsigned int ps_ptr;
ps_ptr = 0;
unsigned int event_code, d = 0, e;
struct lv_event event;
// Loop through events
for (e = 0; e < ps_count; e++) {
// Get event
event_code = array_uint16_le(ps + ps_ptr);
ps_ptr += 2;
if (log_version == 3) {
ps_ptr += handle_event_ver3(event_code, ps, ps_ptr, &event);
if (event_code != 0xf)
continue; // ignore all by pressure sensor event
} else { // version 2
ps_ptr += handle_event_ver2(event_code, ps, ps_ptr, &event);
continue; // ignore all events
}
int sample_time, last_time;
int depth_mm, last_depth, temp_mk, last_temp;
while (true) {
sample = prepare_sample(dc);
// Get sample times
sample_time = d * sample_interval;
depth_mm = array_uint16_le(ds + d * 2) * 10; // cm->mm
temp_mk = C_to_mkelvin((float)array_uint16_le(ts + d * 2) / 10); // dC->mK
last_time = (d ? (d - 1) * sample_interval : 0);
if (d == sample_count) {
// We still have events to record
sample->time.seconds = event.time;
sample->depth.mm = array_uint16_le(ds + (d - 1) * 2) * 10; // cm->mm
sample->temperature.mkelvin = C_to_mkelvin((float) array_uint16_le(ts + (d - 1) * 2) / 10); // dC->mK
sample->sensor = event.pressure.sensor;
sample->cylinderpressure.mbar = event.pressure.mbar;
finish_sample(dc);
break;
} else if (event.time > sample_time) {
// Record sample and loop
sample->time.seconds = sample_time;
sample->depth.mm = depth_mm;
sample->temperature.mkelvin = temp_mk;
finish_sample(dc);
d++;
continue;
} else if (event.time == sample_time) {
sample->time.seconds = sample_time;
sample->depth.mm = depth_mm;
sample->temperature.mkelvin = temp_mk;
sample->sensor = event.pressure.sensor;
sample->cylinderpressure.mbar = event.pressure.mbar;
finish_sample(dc);
break;
} else { // Event is prior to sample
sample->time.seconds = event.time;
sample->sensor = event.pressure.sensor;
sample->cylinderpressure.mbar = event.pressure.mbar;
if (last_time == sample_time) {
sample->depth.mm = depth_mm;
sample->temperature.mkelvin = temp_mk;
} else {
// Extrapolate
last_depth = array_uint16_le(ds + (d - 1) * 2) * 10; // cm->mm
last_temp = C_to_mkelvin((float) array_uint16_le(ts + (d - 1) * 2) / 10); // dC->mK
sample->depth.mm = last_depth + (depth_mm - last_depth)
* (event.time - last_time) / sample_interval;
sample->temperature.mkelvin = last_temp + (temp_mk - last_temp)
* (event.time - last_time) / sample_interval;
}
finish_sample(dc);
break;
}
} // while (true);
} // for each event sample
// record trailing depth samples
for ( ;d < sample_count; d++) {
sample = prepare_sample(dc);
sample->time.seconds = d * sample_interval;
sample->depth.mm = array_uint16_le(ds + d * 2) * 10; // cm->mm
sample->temperature.mkelvin =
C_to_mkelvin((float)array_uint16_le(ts + d * 2) / 10);
finish_sample(dc);
}
if (log_version == 3 && model == 4) {
// Advance to begin of next dive
switch (array_uint16_le(ps + ps_ptr)) {
case 0x0000:
ps_ptr += 5;
break;
case 0x0100:
ps_ptr += 7;
break;
case 0x0200:
ps_ptr += 9;
break;
case 0x0300:
ps_ptr += 11;
break;
case 0x0b0b:
ps_ptr += 27;
break;
}
while (*(ps + ps_ptr) != 0x04)
ps_ptr++;
}
// End dive
dive->downloaded = true;
record_dive(dive);
mark_divelist_changed(true);
// Advance ptr for next dive
ptr += ps_ptr + 4;
} // while
//DEBUG save_dives("/tmp/test.xml");
}
int try_to_open_liquivision(const char *filename, struct memblock *mem)
{
(void) filename;
const unsigned char *buf = mem->buffer;
unsigned int buf_size = mem->size;
unsigned int ptr;
int log_version;
// Get name length
unsigned int len = array_uint32_le(buf);
// Ignore length field and the name
ptr = 4 + len;
unsigned int dive_count = array_uint32_le(buf + ptr);
if (dive_count == 0xffffffff) {
// File version 3.0
log_version = 3;
ptr += 6;
dive_count = array_uint32_le(buf + ptr);
} else {
log_version = 2;
}
ptr += 4;
parse_dives(log_version, buf + ptr, buf_size - ptr);
return 1;
}