subsurface/file.c
Anton Lundin 36b6045460 Document more about fields in Poseidon MkVI logs
This is based on the great work done by Søren Reinke's on his MKVI Logfile
Analyzer.

Signed-off-by: Anton Lundin <glance@acc.umu.se>
Signed-off-by: Dirk Hohndel <dirk@hohndel.org>
2014-11-19 17:50:33 -08:00

1039 lines
29 KiB
C

#include <unistd.h>
#include <fcntl.h>
#include <sys/stat.h>
#include <stdlib.h>
#include <string.h>
#include <errno.h>
#include "gettext.h"
#include <zip.h>
#include <time.h>
#include "dive.h"
#include "file.h"
/* For SAMPLE_* */
#include <libdivecomputer/parser.h>
/* Crazy windows sh*t */
#ifndef O_BINARY
#define O_BINARY 0
#endif
int readfile(const char *filename, struct memblock *mem)
{
int ret, fd;
struct stat st;
char *buf;
mem->buffer = NULL;
mem->size = 0;
fd = subsurface_open(filename, O_RDONLY | O_BINARY, 0);
if (fd < 0)
return fd;
ret = fstat(fd, &st);
if (ret < 0)
goto out;
ret = -EINVAL;
if (!S_ISREG(st.st_mode))
goto out;
ret = 0;
if (!st.st_size)
goto out;
buf = malloc(st.st_size + 1);
ret = -1;
errno = ENOMEM;
if (!buf)
goto out;
mem->buffer = buf;
mem->size = st.st_size;
ret = read(fd, buf, mem->size);
if (ret < 0)
goto free;
buf[ret] = 0;
if (ret == mem->size)
goto out;
errno = EIO;
ret = -1;
free:
free(mem->buffer);
mem->buffer = NULL;
mem->size = 0;
out:
close(fd);
return ret;
}
static void zip_read(struct zip_file *file, const char *filename)
{
int size = 1024, n, read = 0;
char *mem = malloc(size);
while ((n = zip_fread(file, mem + read, size - read)) > 0) {
read += n;
size = read * 3 / 2;
mem = realloc(mem, size);
}
mem[read] = 0;
parse_xml_buffer(filename, mem, read, &dive_table, NULL);
free(mem);
}
static int try_to_open_zip(const char *filename, struct memblock *mem)
{
int success = 0;
/* Grr. libzip needs to re-open the file, it can't take a buffer */
struct zip *zip = subsurface_zip_open_readonly(filename, ZIP_CHECKCONS, NULL);
if (zip) {
int index;
for (index = 0;; index++) {
struct zip_file *file = zip_fopen_index(zip, index, 0);
if (!file)
break;
/* skip parsing the divelogs.de pictures */
if (strstr(zip_get_name(zip, index, 0), "pictures/"))
continue;
zip_read(file, filename);
zip_fclose(file);
success++;
}
subsurface_zip_close(zip);
}
return success;
}
static int try_to_xslt_open_csv(const char *filename, struct memblock *mem, const char *tag)
{
char *buf;
if (mem->size == 0 && readfile(filename, mem) < 0)
return report_error(translate("gettextFromC", "Failed to read '%s'"), filename);
/* Surround the CSV file content with XML tags to enable XSLT
* parsing
*
* Tag markers take: strlen("<></>") = 5
*/
buf = realloc(mem->buffer, mem->size + 5 + strlen(tag) * 2);
if (buf != NULL) {
char *starttag = NULL;
char *endtag = NULL;
starttag = malloc(3 + strlen(tag));
endtag = malloc(4 + strlen(tag));
if (starttag == NULL || endtag == NULL) {
/* this is fairly silly - so the malloc fails, but we strdup the error?
* let's complete the silliness by freeing the two pointers in case one malloc succeeded
* and the other one failed - this will make static analysis tools happy */
free(starttag);
free(endtag);
free(buf);
return report_error("Memory allocation failed in %s", __func__);
}
sprintf(starttag, "<%s>", tag);
sprintf(endtag, "</%s>", tag);
memmove(buf + 2 + strlen(tag), buf, mem->size);
memcpy(buf, starttag, 2 + strlen(tag));
memcpy(buf + mem->size + 2 + strlen(tag), endtag, 4 + strlen(tag));
mem->size += (5 + 2 * strlen(tag));
mem->buffer = buf;
free(starttag);
free(endtag);
} else {
free(mem->buffer);
return report_error("realloc failed in %s", __func__);
}
return 0;
}
int db_test_func(void *param, int columns, char **data, char **column)
{
return *data[0] == '0';
}
static int try_to_open_db(const char *filename, struct memblock *mem)
{
sqlite3 *handle;
char dm4_test[] = "select count(*) from sqlite_master where type='table' and name='Dive' and sql like '%ProfileBlob%'";
char dm5_test[] = "select count(*) from sqlite_master where type='table' and name='Dive' and sql like '%SampleBlob%'";
char shearwater_test[] = "select count(*) from sqlite_master where type='table' and name='system' and sql like '%dbVersion%'";
int retval;
retval = sqlite3_open(filename, &handle);
if (retval) {
fprintf(stderr, translate("gettextFromC", "Database connection failed '%s'.\n"), filename);
return 1;
}
/* Testing if DB schema resembles Suunto DM5 database format */
retval = sqlite3_exec(handle, dm5_test, &db_test_func, 0, NULL);
if (!retval) {
retval = parse_dm5_buffer(handle, filename, mem->buffer, mem->size, &dive_table);
sqlite3_close(handle);
return retval;
}
/* Testing if DB schema resembles Suunto DM4 database format */
retval = sqlite3_exec(handle, dm4_test, &db_test_func, 0, NULL);
if (!retval) {
retval = parse_dm4_buffer(handle, filename, mem->buffer, mem->size, &dive_table);
sqlite3_close(handle);
return retval;
}
/* Testing if DB schema resembles Shearwater database format */
retval = sqlite3_exec(handle, shearwater_test, &db_test_func, 0, NULL);
if (!retval) {
retval = parse_shearwater_buffer(handle, filename, mem->buffer, mem->size, &dive_table);
sqlite3_close(handle);
return retval;
}
sqlite3_close(handle);
return retval;
}
timestamp_t parse_date(const char *date)
{
int hour, min, sec;
struct tm tm;
char *p;
memset(&tm, 0, sizeof(tm));
tm.tm_mday = strtol(date, &p, 10);
if (tm.tm_mday < 1 || tm.tm_mday > 31)
return 0;
for (tm.tm_mon = 0; tm.tm_mon < 12; tm.tm_mon++) {
if (!memcmp(p, monthname(tm.tm_mon), 3))
break;
}
if (tm.tm_mon > 11)
return 0;
date = p + 3;
tm.tm_year = strtol(date, &p, 10);
if (date == p)
return 0;
if (tm.tm_year < 70)
tm.tm_year += 2000;
if (tm.tm_year < 100)
tm.tm_year += 1900;
if (sscanf(p, "%d:%d:%d", &hour, &min, &sec) != 3)
return 0;
tm.tm_hour = hour;
tm.tm_min = min;
tm.tm_sec = sec;
return utc_mktime(&tm);
}
enum csv_format {
CSV_DEPTH,
CSV_TEMP,
CSV_PRESSURE,
POSEIDON_DEPTH,
POSEIDON_TEMP,
POSEIDON_SETPOINT,
POSEIDON_SENSOR1,
POSEIDON_SENSOR2,
POSEIDON_PRESSURE,
POSEIDON_O2CYLINDER,
POSEIDON_NDL,
POSEIDON_CEILING
};
static void add_sample_data(struct sample *sample, enum csv_format type, double val)
{
switch (type) {
case CSV_DEPTH:
sample->depth.mm = feet_to_mm(val);
break;
case CSV_TEMP:
sample->temperature.mkelvin = F_to_mkelvin(val);
break;
case CSV_PRESSURE:
sample->cylinderpressure.mbar = psi_to_mbar(val * 4);
break;
case POSEIDON_DEPTH:
sample->depth.mm = val * 0.5 *1000;
break;
case POSEIDON_TEMP:
sample->temperature.mkelvin = C_to_mkelvin(val * 0.2);
break;
case POSEIDON_SETPOINT:
sample->setpoint.mbar = val * 10;
break;
case POSEIDON_SENSOR1:
sample->o2sensor[0].mbar = val * 10;
break;
case POSEIDON_SENSOR2:
sample->o2sensor[1].mbar = val * 10;
break;
case POSEIDON_PRESSURE:
sample->cylinderpressure.mbar = val * 1000;
break;
case POSEIDON_O2CYLINDER:
sample->o2cylinderpressure.mbar = val * 1000;
break;
case POSEIDON_NDL:
sample->ndl.seconds = val * 60;
break;
case POSEIDON_CEILING:
sample->stopdepth.mm = val * 1000;
break;
}
}
/*
* Cochran comma-separated values: depth in feet, temperature in F, pressure in psi.
*
* They start with eight comma-separated fields like:
*
* filename: {C:\Analyst4\can\T036785.can},{C:\Analyst4\can\K031892.can}
* divenr: %d
* datetime: {03Sep11 16:37:22},{15Dec11 18:27:02}
* ??: 1
* serialnr??: {CCI134},{CCI207}
* computer??: {GeminiII},{CommanderIII}
* computer??: {GeminiII},{CommanderIII}
* ??: 1
*
* Followed by the data values (all comma-separated, all one long line).
*/
static int try_to_open_csv(const char *filename, struct memblock *mem, enum csv_format type)
{
char *p = mem->buffer;
char *header[8];
int i, time;
timestamp_t date;
struct dive *dive;
struct divecomputer *dc;
for (i = 0; i < 8; i++) {
header[i] = p;
p = strchr(p, ',');
if (!p)
return 0;
p++;
}
date = parse_date(header[2]);
if (!date)
return 0;
dive = alloc_dive();
dive->when = date;
dive->number = atoi(header[1]);
dc = &dive->dc;
time = 0;
for (;;) {
char *end;
double val;
struct sample *sample;
errno = 0;
val = strtod(p, &end); // FIXME == localization issue
if (end == p)
break;
if (errno)
break;
sample = prepare_sample(dc);
sample->time.seconds = time;
add_sample_data(sample, type, val);
finish_sample(dc);
time++;
dc->duration.seconds = time;
if (*end != ',')
break;
p = end + 1;
}
record_dive(dive);
return 1;
}
static int open_by_filename(const char *filename, const char *fmt, struct memblock *mem)
{
/* Suunto Dive Manager files: SDE, ZIP; divelogs.de files: DLD */
if (!strcasecmp(fmt, "SDE") || !strcasecmp(fmt, "ZIP") || !strcasecmp(fmt, "DLD"))
return try_to_open_zip(filename, mem);
/* CSV files */
if (!strcasecmp(fmt, "CSV"))
return 1;
/* Truly nasty intentionally obfuscated Cochran Anal software */
if (!strcasecmp(fmt, "CAN"))
return try_to_open_cochran(filename, mem);
/* Cochran export comma-separated-value files */
if (!strcasecmp(fmt, "DPT"))
return try_to_open_csv(filename, mem, CSV_DEPTH);
if (!strcasecmp(fmt, "LVD"))
return try_to_open_liquivision(filename, mem);
if (!strcasecmp(fmt, "TMP"))
return try_to_open_csv(filename, mem, CSV_TEMP);
if (!strcasecmp(fmt, "HP1"))
return try_to_open_csv(filename, mem, CSV_PRESSURE);
return 0;
}
static void parse_file_buffer(const char *filename, struct memblock *mem)
{
char *fmt = strrchr(filename, '.');
if (fmt && open_by_filename(filename, fmt + 1, mem))
return;
if (!mem->size || !mem->buffer)
return;
parse_xml_buffer(filename, mem->buffer, mem->size, &dive_table, NULL);
}
int parse_file(const char *filename)
{
struct git_repository *git;
const char *branch;
struct memblock mem;
char *fmt;
git = is_git_repository(filename, &branch);
if (git && !git_load_dives(git, branch))
return 0;
if (readfile(filename, &mem) < 0) {
/* we don't want to display an error if this was the default file */
if (prefs.default_filename && !strcmp(filename, prefs.default_filename))
return 0;
return report_error(translate("gettextFromC", "Failed to read '%s'"), filename);
}
fmt = strrchr(filename, '.');
if (fmt && (!strcasecmp(fmt + 1, "DB") || !strcasecmp(fmt + 1, "BAK"))) {
if (!try_to_open_db(filename, &mem)) {
free(mem.buffer);
return 0;
}
}
parse_file_buffer(filename, &mem);
free(mem.buffer);
return 0;
}
#define MATCH(buffer, pattern) \
memcmp(buffer, pattern, strlen(pattern))
char *parse_mkvi_value(const char *haystack, const char *needle)
{
char *lineptr, *valueptr, *endptr, *ret = NULL;
if ((lineptr = strstr(haystack, needle)) != NULL) {
if ((valueptr = strstr(lineptr, ": ")) != NULL) {
valueptr += 2;
}
if ((endptr = strstr(lineptr, "\n")) != NULL) {
char terminator = '\n';
if (*(endptr - 1) == '\r') {
--endptr;
terminator = '\r';
}
*endptr = 0;
ret = strdup(valueptr);
*endptr = terminator;
}
}
return ret;
}
char *next_mkvi_key(const char *haystack)
{
char *valueptr, *endptr, *ret = NULL;
if ((valueptr = strstr(haystack, "\n")) != NULL) {
valueptr += 1;
}
if ((endptr = strstr(valueptr, ": ")) != NULL) {
*endptr = 0;
ret = strdup(valueptr);
*endptr = ':';
}
return ret;
}
int parse_txt_file(const char *filename, const char *csv)
{
struct memblock memtxt, memcsv;
if (readfile(filename, &memtxt) < 0) {
return report_error(translate("gettextFromC", "Failed to read '%s'"), filename);
}
/*
* MkVI stores some information in .txt file but the whole profile and events are stored in .csv file. First
* make sure the input .txt looks like proper MkVI file, then start parsing the .csv.
*/
if (MATCH(memtxt.buffer, "MkVI_Config") == 0) {
int d, m, y, he;
int hh = 0, mm = 0, ss = 0;
int prev_depth = 0, cur_sampletime = 0, prev_setpoint = -1, prev_ndl = -1;
bool has_depth = false, has_setpoint = false, has_ndl = false;
char *lineptr, *key, *value;
int o2cylinder_pressure = 0, cylinder_pressure = 0, cur_cylinder_index = 0;
struct dive *dive;
struct divecomputer *dc;
struct tm cur_tm;
if (sscanf(parse_mkvi_value(memtxt.buffer, "Dive started at"), "%d-%d-%d %d:%d:%d",
&y, &m, &d, &hh, &mm, &ss) != 6) {
return -1;
}
cur_tm.tm_year = y;
cur_tm.tm_mon = m - 1;
cur_tm.tm_mday = d;
cur_tm.tm_hour = hh;
cur_tm.tm_min = mm;
cur_tm.tm_sec = ss;
dive = alloc_dive();
dive->when = utc_mktime(&cur_tm);;
dive->dc.model = strdup("Poseidon MkVI Discovery");
value = parse_mkvi_value(memtxt.buffer, "Rig Serial number");
dive->dc.deviceid = atoi(value);
free(value);
dive->dc.dctype = CCR;
dive->dc.no_o2sensors = 2;
dive->cylinder[cur_cylinder_index].cylinder_use = OXYGEN;
dive->cylinder[cur_cylinder_index].type.size.mliter = 3000;
dive->cylinder[cur_cylinder_index].type.workingpressure.mbar = 200000;
dive->cylinder[cur_cylinder_index].type.description = strdup("3l Mk6");
dive->cylinder[cur_cylinder_index].gasmix.o2.permille = 1000;
cur_cylinder_index++;
dive->cylinder[cur_cylinder_index].cylinder_use = DILUENT;
dive->cylinder[cur_cylinder_index].type.size.mliter = 3000;
dive->cylinder[cur_cylinder_index].type.workingpressure.mbar = 200000;
dive->cylinder[cur_cylinder_index].type.description = strdup("3l Mk6");
value = parse_mkvi_value(memtxt.buffer, "Helium percentage");
he = atoi(value);
free(value);
value = parse_mkvi_value(memtxt.buffer, "Nitrogen percentage");
dive->cylinder[cur_cylinder_index].gasmix.o2.permille = (100 - atoi(value) - he) * 10;
free(value);
dive->cylinder[cur_cylinder_index].gasmix.he.permille = he * 10;
cur_cylinder_index++;
lineptr = strstr(memtxt.buffer, "Dive started at");
while (lineptr && *lineptr && (lineptr = strchr(lineptr, '\n')) && ++lineptr) {
key = next_mkvi_key(lineptr);
if (!key)
break;
value = parse_mkvi_value(lineptr, key);
if (!value) {
free(key);
break;
}
add_extra_data(&dive->dc, key, value);
free(key);
free(value);
}
dc = &dive->dc;
/*
* Read samples from the CSV file. A sample contains all the lines with same timestamp. The CSV file has
* the following format:
*
* timestamp, type, value
*
* And following fields are of interest to us:
*
* 6 sensor1
* 7 sensor2
* 8 depth
* 13 o2 tank pressure
* 14 diluent tank pressure
* 20 o2 setpoint
* 39 water temp
*/
if (readfile(csv, &memcsv) < 0) {
return report_error(translate("gettextFromC", "Poseidon import failed: unable to read '%s'"), csv);
}
lineptr = memcsv.buffer;
for (;;) {
struct sample *sample;
int type;
int value;
int sampletime;
int gaschange = 0;
/* Collect all the information for one sample */
sscanf(lineptr, "%d,%d,%d", &cur_sampletime, &type, &value);
has_depth = false;
has_setpoint = false;
has_ndl = false;
sample = prepare_sample(dc);
sample->time.seconds = cur_sampletime;
do {
int i = sscanf(lineptr, "%d,%d,%d", &sampletime, &type, &value);
switch (i) {
case 3:
switch (type) {
case 0:
//MouthPiece position event: 0=OC, 1=CC, 2=UN, 3=NC
switch (value) {
case 0:
add_event(dc, cur_sampletime, 0, 0, 0,
QT_TRANSLATE_NOOP("gettextFromC", "MouthPiece position OC"));
break;
case 1:
add_event(dc, cur_sampletime, 0, 0, 0,
QT_TRANSLATE_NOOP("gettextFromC", "MouthPiece position CC"));
break;
case 2:
add_event(dc, cur_sampletime, 0, 0, 0,
QT_TRANSLATE_NOOP("gettextFromC", "MouthPiece position UN"));
break;
case 3:
add_event(dc, cur_sampletime, 0, 0, 0,
QT_TRANSLATE_NOOP("gettextFromC", "MouthPiece position NC"));
break;
}
case 3:
//Power Off event
add_event(dc, cur_sampletime, 0, 0, 0,
QT_TRANSLATE_NOOP("gettextFromC", "Power off"));
break;
case 4:
//Battery State of Charge in %
#ifdef SAMPLE_EVENT_BATTERY
add_event(dc, cur_sampletime, SAMPLE_EVENT_BATTERY, 0,
value, QT_TRANSLATE_NOOP("gettextFromC", "battery"));
#endif
break;
case 6:
//PO2 Cell 1 Average
add_sample_data(sample, POSEIDON_SENSOR1, value);
break;
case 7:
//PO2 Cell 2 Average
add_sample_data(sample, POSEIDON_SENSOR2, value);
break;
case 8:
//Depth * 2
has_depth = true;
prev_depth = value;
add_sample_data(sample, POSEIDON_DEPTH, value);
break;
//9 Max Depth * 2
//10 Ascent/Descent Rate * 2
case 11:
//Ascent Rate Alert >10 m/s
add_event(dc, cur_sampletime, SAMPLE_EVENT_ASCENT, 0, 0,
QT_TRANSLATE_NOOP("gettextFromC", "ascent"));
break;
case 13:
//O2 Tank Pressure
add_sample_data(sample, POSEIDON_O2CYLINDER, value);
if (!o2cylinder_pressure) {
dive->cylinder[0].sample_start.mbar = value * 1000;
o2cylinder_pressure = value;
} else
o2cylinder_pressure = value;
break;
case 14:
//Diluent Tank Pressure
add_sample_data(sample, POSEIDON_PRESSURE, value);
if (!cylinder_pressure) {
dive->cylinder[1].sample_start.mbar = value * 1000;
cylinder_pressure = value;
} else
cylinder_pressure = value;
break;
//16 Remaining dive time #1?
//17 related to O2 injection
case 20:
//PO2 Setpoint
has_setpoint = true;
prev_setpoint = value;
add_sample_data(sample, POSEIDON_SETPOINT, value);
break;
case 22:
//End of O2 calibration Event: 0 = OK, 2 = Failed, rest of dive setpoint 1.0
if (value == 2)
add_event(dc, cur_sampletime, 0, SAMPLE_FLAGS_END, 0,
QT_TRANSLATE_NOOP("gettextFromC", "O2 calibration failed"));
add_event(dc, cur_sampletime, 0, SAMPLE_FLAGS_END, 0,
QT_TRANSLATE_NOOP("gettextFromC", "O2 calibration"));
break;
case 25:
//25 Max Ascent depth
add_sample_data(sample, POSEIDON_CEILING, value);
break;
case 31:
//Start of O2 calibration Event
add_event(dc, cur_sampletime, 0, SAMPLE_FLAGS_BEGIN, 0,
QT_TRANSLATE_NOOP("gettextFromC", "O2 calibration"));
break;
case 37:
//Remaining dive time #2?
has_ndl = true;
prev_ndl = value;
add_sample_data(sample, POSEIDON_NDL, value);
break;
case 39:
// Water Temperature in Celcius
add_sample_data(sample, POSEIDON_TEMP, value);
break;
case 85:
//He diluent part in %
gaschange ^= value << 16;
break;
case 86:
//O2 diluent part in %
gaschange ^= value;
break;
//239 Unknown, maybe PO2 at sensor validation?
//240 Unknown, maybe PO2 at sensor validation?
//247 Unknown, maybe PO2 Cell 1 during pressure test
//248 Unknown, maybe PO2 Cell 2 during pressure test
//250 PO2 Cell 1
//251 PO2 Cell 2
default:
printf("Ignoring %d = %d\n", type, value);
break;
} /* sample types */
break;
case EOF:
break;
default:
printf("Unable to parse input: %s\n", lineptr);
break;
}
lineptr = strchr(lineptr, '\n');
if (!lineptr || !*lineptr)
break;
lineptr++;
/* Grabbing next sample time */
sscanf(lineptr, "%d,%d,%d", &cur_sampletime, &type, &value);
} while (sampletime == cur_sampletime);
if (gaschange)
add_event(dc, cur_sampletime, SAMPLE_EVENT_GASCHANGE2, 0, gaschange,
QT_TRANSLATE_NOOP("gettextFromC", "gaschange"));
if (!has_depth)
add_sample_data(sample, POSEIDON_DEPTH, prev_depth);
if (!has_setpoint)
add_sample_data(sample, POSEIDON_SETPOINT, prev_setpoint);
if (!has_ndl)
add_sample_data(sample, POSEIDON_NDL, prev_ndl);
if (cylinder_pressure)
dive->cylinder[1].sample_end.mbar = cylinder_pressure * 1000;
if (o2cylinder_pressure)
dive->cylinder[0].sample_end.mbar = o2cylinder_pressure * 1000;
finish_sample(dc);
if (!lineptr || !*lineptr)
break;
}
record_dive(dive);
return 1;
} else {
return report_error(translate("gettextFromC", "No matching DC found for file '%s'"), csv);
}
return 0;
}
#define MAXCOLDIGITS 3
#define MAXCOLS 100
#define DATESTR 9
#define TIMESTR 6
void init_csv_file_parsing(char **params, char *timebuf, char *depthbuf, char *tempbuf, char *po2buf, char *cnsbuf, char *ndlbuf, char *ttsbuf, char *stopdepthbuf, char *pressurebuf, char *unitbuf, char *separator_index, time_t *now, struct tm *timep, char *curdate, char *curtime, int timef, int depthf, int tempf, int po2f, int cnsf, int ndlf, int ttsf, int stopdepthf, int pressuref, int sepidx, const char *csvtemplate, int unitidx)
{
int pnr = 0;
snprintf(timebuf, MAXCOLDIGITS, "%d", timef);
snprintf(depthbuf, MAXCOLDIGITS, "%d", depthf);
snprintf(tempbuf, MAXCOLDIGITS, "%d", tempf);
snprintf(po2buf, MAXCOLDIGITS, "%d", po2f);
snprintf(cnsbuf, MAXCOLDIGITS, "%d", cnsf);
snprintf(ndlbuf, MAXCOLDIGITS, "%d", ndlf);
snprintf(ttsbuf, MAXCOLDIGITS, "%d", ttsf);
snprintf(stopdepthbuf, MAXCOLDIGITS, "%d", stopdepthf);
snprintf(pressurebuf, MAXCOLDIGITS, "%d", pressuref);
snprintf(separator_index, MAXCOLDIGITS, "%d", sepidx);
snprintf(unitbuf, MAXCOLDIGITS, "%d", unitidx);
time(now);
timep = localtime(now);
strftime(curdate, DATESTR, "%Y%m%d", timep);
/* As the parameter is numeric, we need to ensure that the leading zero
* is not discarded during the transform, thus prepend time with 1 */
strftime(curtime, TIMESTR, "1%H%M", timep);
params[pnr++] = "timeField";
params[pnr++] = timebuf;
params[pnr++] = "depthField";
params[pnr++] = depthbuf;
params[pnr++] = "tempField";
params[pnr++] = tempbuf;
params[pnr++] = "po2Field";
params[pnr++] = po2buf;
params[pnr++] = "cnsField";
params[pnr++] = cnsbuf;
params[pnr++] = "ndlField";
params[pnr++] = ndlbuf;
params[pnr++] = "ttsField";
params[pnr++] = ttsbuf;
params[pnr++] = "stopdepthField";
params[pnr++] = stopdepthbuf;
params[pnr++] = "pressureField";
params[pnr++] = pressurebuf;
params[pnr++] = "date";
params[pnr++] = curdate;
params[pnr++] = "time";
params[pnr++] = curtime;
params[pnr++] = "units";
params[pnr++] = unitbuf;
params[pnr++] = "separatorIndex";
params[pnr++] = separator_index;
params[pnr++] = NULL;
}
int parse_csv_file(const char *filename, int timef, int depthf, int tempf, int po2f, int cnsf, int ndlf, int ttsf, int stopdepthf, int pressuref, int sepidx, const char *csvtemplate, int unitidx)
{
struct memblock mem;
char *params[27];
char timebuf[MAXCOLDIGITS];
char depthbuf[MAXCOLDIGITS];
char tempbuf[MAXCOLDIGITS];
char po2buf[MAXCOLDIGITS];
char cnsbuf[MAXCOLDIGITS];
char ndlbuf[MAXCOLDIGITS];
char ttsbuf[MAXCOLDIGITS];
char stopdepthbuf[MAXCOLDIGITS];
char pressurebuf[MAXCOLDIGITS];
char unitbuf[MAXCOLDIGITS];
char separator_index[MAXCOLDIGITS];
time_t now;
struct tm *timep;
char curdate[DATESTR];
char curtime[TIMESTR];
if (timef >= MAXCOLS || depthf >= MAXCOLS || tempf >= MAXCOLS || po2f >= MAXCOLS || cnsf >= MAXCOLS || ndlf >= MAXCOLS || cnsf >= MAXCOLS || stopdepthf >= MAXCOLS || pressuref >= MAXCOLS)
return report_error(translate("gettextFromC", "Maximum number of supported columns on CSV import is %d"), MAXCOLS);
init_csv_file_parsing(params, timebuf, depthbuf, tempbuf, po2buf, cnsbuf,ndlbuf, ttsbuf, stopdepthbuf, pressurebuf, unitbuf, separator_index, &now, timep, curdate, curtime, timef, depthf, tempf, po2f, cnsf, ndlf, ttsf, stopdepthf, pressuref, sepidx, csvtemplate, unitidx);
if (filename == NULL)
return report_error("No CSV filename");
mem.size = 0;
if (try_to_xslt_open_csv(filename, &mem, csvtemplate))
return -1;
parse_xml_buffer(filename, mem.buffer, mem.size, &dive_table, (const char **)params);
free(mem.buffer);
return 0;
}
int parse_seabear_csv_file(const char *filename, int timef, int depthf, int tempf, int po2f, int cnsf, int ndlf, int ttsf, int stopdepthf, int pressuref, int sepidx, const char *csvtemplate, int unitidx)
{
struct memblock mem;
char *params[27];
char timebuf[MAXCOLDIGITS];
char depthbuf[MAXCOLDIGITS];
char tempbuf[MAXCOLDIGITS];
char po2buf[MAXCOLDIGITS];
char cnsbuf[MAXCOLDIGITS];
char ndlbuf[MAXCOLDIGITS];
char ttsbuf[MAXCOLDIGITS];
char stopdepthbuf[MAXCOLDIGITS];
char pressurebuf[MAXCOLDIGITS];
char unitbuf[MAXCOLDIGITS];
char separator_index[MAXCOLDIGITS];
time_t now;
struct tm *timep;
char curdate[DATESTR];
char curtime[TIMESTR];
char *ptr, *ptr_old = NULL;
char *NL;
if (timef >= MAXCOLS || depthf >= MAXCOLS || tempf >= MAXCOLS || po2f >= MAXCOLS || cnsf >= MAXCOLS || ndlf >= MAXCOLS || cnsf >= MAXCOLS || stopdepthf >= MAXCOLS || pressuref >= MAXCOLS)
return report_error(translate("gettextFromC", "Maximum number of supported columns on CSV import is %d"), MAXCOLS);
init_csv_file_parsing(params, timebuf, depthbuf, tempbuf, po2buf, cnsbuf,ndlbuf, ttsbuf, stopdepthbuf, pressurebuf, unitbuf, separator_index, &now, timep, curdate, curtime, timef, depthf, tempf, po2f, cnsf, ndlf, ttsf, stopdepthf, pressuref, sepidx, csvtemplate, unitidx);
if (filename == NULL)
return report_error("No CSV filename");
if (readfile(filename, &mem) < 0)
return report_error(translate("gettextFromC", "Failed to read '%s'"), filename);
/* Determine NL (new line) character and the start of CSV data */
ptr = mem.buffer;
while ((ptr = strstr(ptr, "\r\n\r\n")) != NULL) {
ptr_old = ptr;
ptr += 1;
NL = "\r\n";
}
if (!ptr_old) {
while ((ptr = strstr(ptr, "\n\n")) != NULL) {
ptr_old = ptr;
ptr += 1;
}
ptr_old += 2;
NL = "\n";
} else
ptr_old += 4;
/*
* On my current sample of Seabear DC log file, the date is
* without any identifier. Thus we must search for the previous
* line and step through from there.
*/
ptr = strstr(mem.buffer, "Serial number:");
if (ptr)
ptr = strstr(ptr, NL);
/* Write date and time values to params array */
if (ptr) {
ptr += strlen(NL) + 2;
memcpy(params[19], ptr, 4);
memcpy(params[19] + 4, ptr + 5, 2);
memcpy(params[19] + 6, ptr + 8, 2);
params[19][8] = 0;
params[21][0] = '1';
memcpy(params[21] + 1, ptr + 11, 2);
memcpy(params[21] + 3, ptr + 14, 2);
params[21][5] = 0;
}
/* Move the CSV data to the start of mem buffer */
memmove(mem.buffer, ptr_old, mem.size - (ptr_old - (char*)mem.buffer));
mem.size = (int)mem.size - (ptr_old - (char*)mem.buffer);
if (try_to_xslt_open_csv(filename, &mem, csvtemplate))
return -1;
parse_xml_buffer(filename, mem.buffer, mem.size, &dive_table, (const char **)params);
free(mem.buffer);
return 0;
}
int parse_manual_file(const char *filename, int sepidx, int units, int numberf, int datef, int timef, int durationf, int locationf, int gpsf, int maxdepthf, int meandepthf, int buddyf, int notesf, int weightf, int tagsf)
{
struct memblock mem;
int pnr = 0;
char *params[33];
char numberbuf[MAXCOLDIGITS];
char datebuf[MAXCOLDIGITS];
char timebuf[MAXCOLDIGITS];
char durationbuf[MAXCOLDIGITS];
char locationbuf[MAXCOLDIGITS];
char gpsbuf[MAXCOLDIGITS];
char maxdepthbuf[MAXCOLDIGITS];
char meandepthbuf[MAXCOLDIGITS];
char buddybuf[MAXCOLDIGITS];
char notesbuf[MAXCOLDIGITS];
char weightbuf[MAXCOLDIGITS];
char tagsbuf[MAXCOLDIGITS];
char separator_index[MAXCOLDIGITS];
char unit[MAXCOLDIGITS];
time_t now;
struct tm *timep;
char curdate[9];
char curtime[6];
if (numberf >= MAXCOLS || datef >= MAXCOLS || timef >= MAXCOLS || durationf >= MAXCOLS || locationf >= MAXCOLS || gpsf >= MAXCOLS || maxdepthf >= MAXCOLS || meandepthf >= MAXCOLS || buddyf >= MAXCOLS || notesf >= MAXCOLS || weightf >= MAXCOLS || tagsf >= MAXCOLS)
return report_error(translate("gettextFromC", "Maximum number of supported columns on CSV import is %d"), MAXCOLS);
snprintf(numberbuf, MAXCOLDIGITS, "%d", numberf);
snprintf(datebuf, MAXCOLDIGITS, "%d", datef);
snprintf(timebuf, MAXCOLDIGITS, "%d", timef);
snprintf(durationbuf, MAXCOLDIGITS, "%d", durationf);
snprintf(locationbuf, MAXCOLDIGITS, "%d", locationf);
snprintf(gpsbuf, MAXCOLDIGITS, "%d", gpsf);
snprintf(maxdepthbuf, MAXCOLDIGITS, "%d", maxdepthf);
snprintf(meandepthbuf, MAXCOLDIGITS, "%d", meandepthf);
snprintf(buddybuf, MAXCOLDIGITS, "%d", buddyf);
snprintf(notesbuf, MAXCOLDIGITS, "%d", notesf);
snprintf(weightbuf, MAXCOLDIGITS, "%d", weightf);
snprintf(tagsbuf, MAXCOLDIGITS, "%d", tagsf);
snprintf(separator_index, MAXCOLDIGITS, "%d", sepidx);
snprintf(unit, MAXCOLDIGITS, "%d", units);
time(&now);
timep = localtime(&now);
strftime(curdate, DATESTR, "%Y%m%d", timep);
/* As the parameter is numeric, we need to ensure that the leading zero
* is not discarded during the transform, thus prepend time with 1 */
strftime(curtime, TIMESTR, "1%H%M", timep);
params[pnr++] = "numberField";
params[pnr++] = numberbuf;
params[pnr++] = "dateField";
params[pnr++] = datebuf;
params[pnr++] = "timeField";
params[pnr++] = timebuf;
params[pnr++] = "durationField";
params[pnr++] = durationbuf;
params[pnr++] = "locationField";
params[pnr++] = locationbuf;
params[pnr++] = "gpsField";
params[pnr++] = gpsbuf;
params[pnr++] = "maxDepthField";
params[pnr++] = maxdepthbuf;
params[pnr++] = "meanDepthField";
params[pnr++] = meandepthbuf;
params[pnr++] = "buddyField";
params[pnr++] = buddybuf;
params[pnr++] = "notesField";
params[pnr++] = notesbuf;
params[pnr++] = "weightField";
params[pnr++] = weightbuf;
params[pnr++] = "tagsField";
params[pnr++] = tagsbuf;
params[pnr++] = "date";
params[pnr++] = curdate;
params[pnr++] = "time";
params[pnr++] = curtime;
params[pnr++] = "separatorIndex";
params[pnr++] = separator_index;
params[pnr++] = "units";
params[pnr++] = unit;
params[pnr++] = NULL;
if (filename == NULL)
return report_error("No manual CSV filename");
mem.size = 0;
if (try_to_xslt_open_csv(filename, &mem, "manualCSV"))
return -1;
parse_xml_buffer(filename, mem.buffer, mem.size, &dive_table, (const char **)params);
free(mem.buffer);
return 0;
}