#include #include #include #include #include "dive.h" #include "errorhelper.h" #include "subsurface-string.h" #include "divelist.h" #include "divelog.h" #include "file.h" #include "format.h" #include "parse.h" #include "sample.h" #include "divelist.h" #include "gettext.h" #include "import-csv.h" #include "qthelper.h" #include "xmlparams.h" #define MATCH(buffer, pattern) \ memcmp(buffer, pattern, strlen(pattern)) static 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); } 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->pressure[0].mbar = psi_to_mbar(val * 4); break; case POSEIDON_DEPTH: sample->depth.mm = lrint(val * 0.5 * 1000); break; case POSEIDON_TEMP: sample->temperature.mkelvin = C_to_mkelvin(val * 0.2); break; case POSEIDON_SETPOINT: sample->setpoint.mbar = lrint(val * 10); break; case POSEIDON_SENSOR1: sample->o2sensor[0].mbar = lrint(val * 10); break; case POSEIDON_SENSOR2: sample->o2sensor[1].mbar = lrint(val * 10); break; case POSEIDON_NDL: sample->ndl.seconds = lrint(val * 60); break; case POSEIDON_CEILING: sample->stopdepth.mm = lrint(val * 1000); break; } } static char *parse_dan_new_line(char *buf, const char *NL) { char *iter = buf; if (!iter) return NULL; iter = strstr(iter, NL); if (iter) { iter += strlen(NL); } else { report_info("DEBUG: No new line found"); return NULL; } return iter; } static int try_to_xslt_open_csv(const char *filename, std::string &mem, const char *tag); static int parse_dan_format(const char *filename, struct xml_params *params, struct divelog *log) { int ret = 0, i; size_t end_ptr = 0; char tmpbuf[MAXCOLDIGITS]; int params_orig_size = xml_params_count(params); char *ptr = NULL; const char *NL = NULL; char *iter = NULL; auto [mem, err] = readfile(filename); if (err < 0) return report_error(translate("gettextFromC", "Failed to read '%s'"), filename); /* Determine NL (new line) character and the start of CSV data */ if ((ptr = strstr(mem.data(), "\r\n")) != NULL) { NL = "\r\n"; } else if ((ptr = strstr(mem.data(), "\n")) != NULL) { NL = "\n"; } else { report_info("DEBUG: failed to detect NL"); return -1; } while ((end_ptr < mem.size()) && (ptr = strstr(mem.data() + end_ptr, "ZDH"))) { xml_params_resize(params, params_orig_size); // restart with original parameter block char *iter_end = NULL; iter = ptr + 4; iter = strchr(iter, '|'); if (iter) { memcpy(tmpbuf, ptr + 4, iter - ptr - 4); tmpbuf[iter - ptr - 4] = 0; xml_params_add(params, "diveNro", tmpbuf); } //report_info("DEBUG: BEGIN end_ptr %d round %d <%s>", end_ptr, j++, ptr); iter = ptr + 1; for (i = 0; i <= 4 && iter; ++i) { iter = strchr(iter, '|'); if (iter) ++iter; } if (!iter) { report_info("DEBUG: Data corrupt"); return -1; } /* Setting date */ memcpy(tmpbuf, iter, 8); tmpbuf[8] = 0; xml_params_add(params, "date", tmpbuf); /* Setting time, gotta prepend it with 1 to * avoid octal parsing (this is stripped out in * XSLT */ tmpbuf[0] = '1'; memcpy(tmpbuf + 1, iter + 8, 6); tmpbuf[7] = 0; xml_params_add(params, "time", tmpbuf); /* Air temperature */ memset(tmpbuf, 0, sizeof(tmpbuf)); iter = strchr(iter, '|'); if (iter) { iter = iter + 1; iter_end = strchr(iter, '|'); if (iter_end) { memcpy(tmpbuf, iter, iter_end - iter); xml_params_add(params, "airTemp", tmpbuf); } } /* Search for the next line */ if (iter) iter = parse_dan_new_line(iter, NL); if (!iter) return -1; /* We got a trailer, no samples on this dive */ if (strncmp(iter, "ZDT", 3) == 0) { end_ptr = iter - mem.data(); /* Water temperature */ memset(tmpbuf, 0, sizeof(tmpbuf)); for (i = 0; i < 5 && iter; ++i) iter = strchr(iter + 1, '|'); if (iter) { iter = iter + 1; iter_end = strchr(iter, '|'); if (iter_end) { memcpy(tmpbuf, iter, iter_end - iter); xml_params_add(params, "waterTemp", tmpbuf); } } ret |= parse_xml_buffer(filename, "", 11, log, params); continue; } /* After ZDH we should get either ZDT (above) or ZDP */ if (strncmp(iter, "ZDP{", 4) != 0) { report_info("DEBUG: Input appears to violate DL7 specification"); end_ptr = iter - mem.data(); continue; } if (ptr && ptr[4] == '}') return report_error(translate("gettextFromC", "No dive profile found from '%s'"), filename); if (ptr) ptr = parse_dan_new_line(ptr, NL); if (!ptr) return -1; end_ptr = ptr - mem.data(); /* Copy the current dive data to start of mem_csv buffer */ std::string mem_csv(ptr, mem.size() - (ptr - mem.data())); ptr = strstr(mem_csv.data(), "ZDP}"); if (ptr) { *ptr = 0; } else { report_info("DEBUG: failed to find end ZDP"); return -1; } mem_csv.resize(ptr - mem_csv.data()); end_ptr += ptr - mem_csv.data(); iter = parse_dan_new_line(ptr + 1, NL); if (iter && strncmp(iter, "ZDT", 3) == 0) { /* Water temperature */ memset(tmpbuf, 0, sizeof(tmpbuf)); for (i = 0; i < 5 && iter; ++i) iter = strchr(iter + 1, '|'); if (iter) { iter = iter + 1; iter_end = strchr(iter, '|'); if (iter_end) { memcpy(tmpbuf, iter, iter_end - iter); xml_params_add(params, "waterTemp", tmpbuf); } } } if (try_to_xslt_open_csv(filename, mem_csv, "csv")) return -1; ret |= parse_xml_buffer(filename, mem_csv.data(), mem_csv.size(), log, params); } return ret; } int parse_csv_file(const char *filename, struct xml_params *params, const char *csvtemplate, struct divelog *log) { int ret; std::string mem; time_t now; struct tm *timep = NULL; char tmpbuf[MAXCOLDIGITS]; /* Increase the limits for recursion and variables on XSLT * parsing */ xsltMaxDepth = 30000; #if LIBXSLT_VERSION > 10126 xsltMaxVars = 150000; #endif if (filename == NULL) return report_error("No CSV filename"); if (!strcmp("DL7", csvtemplate)) { return parse_dan_format(filename, params, log); } else if (strcmp(xml_params_get_key(params, 0), "date")) { time(&now); timep = localtime(&now); strftime(tmpbuf, MAXCOLDIGITS, "%Y%m%d", timep); xml_params_add(params, "date", tmpbuf); /* 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(tmpbuf, MAXCOLDIGITS, "1%H%M", timep); xml_params_add(params, "time", tmpbuf); } if (try_to_xslt_open_csv(filename, mem, csvtemplate)) return -1; /* * Lets print command line for manual testing with xsltproc if * verbosity level is high enough. The printed line needs the * input file added as last parameter. */ #ifndef SUBSURFACE_MOBILE if (verbose >= 2) { std::string info = format_string_std("(echo ''; cat %s;echo '') | xsltproc ", filename); for (int i = 0; i < xml_params_count(params); i++) info += format_string_std("--stringparam %s %s ", xml_params_get_key(params, i), xml_params_get_value(params, i)); info += format_string_std("%s/xslt/%s -", SUBSURFACE_SOURCE, csvtemplate); report_info("%s", info.c_str()); } #endif ret = parse_xml_buffer(filename, mem.data(), mem.size(), log, params); return ret; } static int try_to_xslt_open_csv(const char *filename, std::string &mem, const char *tag) { size_t amp = 0; if (mem.empty()) { auto [mem2, err] = readfile(filename); if (err < 0) return report_error(translate("gettextFromC", "Failed to read '%s'"), filename); if (mem2.empty()) return 0; // Empty file - nothing to do. Guess that's a "success". mem = std::move(mem2); } /* Count ampersand characters */ for (size_t i = 0; i < mem.size(); ++i) { if (mem[i] == '&') { ++amp; } } /* Surround the CSV file content with XML tags to enable XSLT * parsing * * Tag markers take: strlen("<>") = 5 * Reserve also room for encoding ampersands "&" => "&" * * Attention: This code is quite subtle, because we reserve one * more byte than we use and put a '\0' there. */ size_t tag_name_size = strlen(tag); size_t old_size = mem.size(); mem.resize(mem.size() + tag_name_size * 2 + 5 + amp * 4); const char *ptr_in = mem.data() + old_size; char *ptr_out = mem.data() + mem.size(); /* Add end tag */ *--ptr_out = '>'; ptr_out -= tag_name_size; memcpy(ptr_out, tag, tag_name_size); *--ptr_out = '/'; *--ptr_out = '<'; while (--ptr_in >= mem.data()) { if (*ptr_in == '&') { *--ptr_out = ';'; *--ptr_out = 'p'; *--ptr_out = 'm'; *--ptr_out = 'a'; } *--ptr_out = *ptr_in; } /* Add start tag */ *--ptr_out = '>'; ptr_out -= tag_name_size; memcpy(ptr_out, tag, tag_name_size); *--ptr_out = '<'; // On Windows, ptrdiff_t is long long int, on Linux it is long int. // Windows doesn't support the ptrdiff_t format specifier "%td", so // let's cast to long int. if (ptr_out != mem.data()) report_info("try_to_xslt_open_csv(): ptr_out off by %ld. This shouldn't happen", static_cast(ptr_out - mem.data())); return 0; } int try_to_open_csv(std::string &mem, enum csv_format type, struct divelog *log) { char *p = mem.data(); char *header[8]; int i, time; timestamp_t date; 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; auto dive = std::make_unique(); dive->when = date; dive->number = atoi(header[1]); dc = &dive->dcs[0]; 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); time++; dc->duration.seconds = time; if (*end != ',') break; p = end + 1; } record_dive_to_table(dive.release(), log->dives.get()); return 1; } static std::string parse_mkvi_value(const char *haystack, const char *needle) { const char *lineptr, *valueptr, *endptr; if ((lineptr = strstr(haystack, needle)) != NULL) { if ((valueptr = strstr(lineptr, ": ")) != NULL) { valueptr += 2; if ((endptr = strstr(lineptr, "\n")) != NULL) { if (*(endptr - 1) == '\r') --endptr; return std::string(valueptr, endptr - valueptr); } } } return std::string(); } static std::string next_mkvi_key(const char *haystack) { const char *valueptr, *endptr; if ((valueptr = strstr(haystack, "\n")) != NULL) { valueptr += 1; if ((endptr = strstr(valueptr, ": ")) != NULL) return std::string(valueptr, endptr - valueptr); } return std::string(); } int parse_txt_file(const char *filename, const char *csv, struct divelog *log) { auto [memtxt, err] = readfile(filename); if (err < 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.data(), "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; int prev_time = 0; cylinder_t cyl; struct divecomputer *dc; struct tm cur_tm; std::string value = parse_mkvi_value(memtxt.data(), "Dive started at"); if (sscanf(value.c_str(), "%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; auto dive = std::make_unique(); dive->when = utc_mktime(&cur_tm);; dive->dcs[0].model = "Poseidon MkVI Discovery"; value = parse_mkvi_value(memtxt.data(), "Rig Serial number"); dive->dcs[0].deviceid = atoi(value.c_str()); dive->dcs[0].divemode = CCR; dive->dcs[0].no_o2sensors = 2; cyl.cylinder_use = OXYGEN; cyl.type.size.mliter = 3000; cyl.type.workingpressure.mbar = 200000; cyl.type.description = "3l Mk6"; cyl.gasmix.o2.permille = 1000; cyl.manually_added = true; cyl.bestmix_o2 = 0; cyl.bestmix_he = 0; add_cloned_cylinder(&dive->cylinders, cyl); cyl.cylinder_use = DILUENT; cyl.type.size.mliter = 3000; cyl.type.workingpressure.mbar = 200000; cyl.type.description = "3l Mk6"; value = parse_mkvi_value(memtxt.data(), "Helium percentage"); he = atoi(value.c_str()); value = parse_mkvi_value(memtxt.data(), "Nitrogen percentage"); cyl.gasmix.o2.permille = (100 - atoi(value.c_str()) - he) * 10; cyl.gasmix.he.permille = he * 10; add_cloned_cylinder(&dive->cylinders, cyl); lineptr = strstr(memtxt.data(), "Dive started at"); while (!empty_string(lineptr) && (lineptr = strchr(lineptr, '\n'))) { ++lineptr; // Skip over '\n' std::string key = next_mkvi_key(lineptr); if (key.empty()) break; std::string value = parse_mkvi_value(lineptr, key.c_str()); if (value.empty()) break; add_extra_data(&dive->dcs[0], key, value); } dc = &dive->dcs[0]; /* * 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 */ auto [memcsv, err] = readfile(csv); if (err < 0) return report_error(translate("gettextFromC", "Poseidon import failed: unable to read '%s'"), csv); lineptr = memcsv.data(); 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); /* * There was a bug in MKVI download tool that resulted in erroneous sample * times. This fix should work similarly as the vendor's own. */ sample->time.seconds = cur_sampletime < 0xFFFF * 3 / 4 ? cur_sampletime : prev_time; prev_time = sample->time.seconds; do { int i = sscanf(lineptr, "%d,%d,%d", &sampletime, &type, &value); switch (i) { case 3: switch (type) { case 0: //Mouth piece 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", "Mouth piece position OC")); break; case 1: add_event(dc, cur_sampletime, 0, 0, 0, QT_TRANSLATE_NOOP("gettextFromC", "Mouth piece position CC")); break; case 2: add_event(dc, cur_sampletime, 0, 0, 0, QT_TRANSLATE_NOOP("gettextFromC", "Mouth piece position unknown")); break; case 3: add_event(dc, cur_sampletime, 0, 0, 0, QT_TRANSLATE_NOOP("gettextFromC", "Mouth piece position not connected")); break; } 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_pressure(sample, 0, lrint(value * 1000)); break; case 14: //Diluent Tank Pressure add_sample_pressure(sample, 1, lrint(value * 1000)); 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 Celsius 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: break; } /* sample types */ break; case EOF: break; default: report_info("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 && prev_setpoint >= 0) add_sample_data(sample, POSEIDON_SETPOINT, prev_setpoint); if (!has_ndl && prev_ndl >= 0) add_sample_data(sample, POSEIDON_NDL, prev_ndl); if (!lineptr || !*lineptr) break; } record_dive_to_table(dive.release(), log->dives.get()); return 1; } else { return 0; } return 0; } #define DATESTR 9 #define TIMESTR 6 #define SBPARAMS 40 static int parse_seabear_csv_file(const char *filename, struct xml_params *params, const char *csvtemplate, struct divelog *log); int parse_seabear_log(const char *filename, struct divelog *log) { struct xml_params *params = alloc_xml_params(); int ret; parse_seabear_header(filename, params); ret = parse_seabear_csv_file(filename, params, "csv", log) < 0 ? -1 : 0; free_xml_params(params); return ret; } static int parse_seabear_csv_file(const char *filename, struct xml_params *params, const char *csvtemplate, struct divelog *log) { int ret, i; time_t now; struct tm *timep = NULL; char *ptr, *ptr_old = NULL; const char *NL = NULL; char tmpbuf[MAXCOLDIGITS]; /* Increase the limits for recursion and variables on XSLT * parsing */ xsltMaxDepth = 30000; #if LIBXSLT_VERSION > 10126 xsltMaxVars = 150000; #endif time(&now); timep = localtime(&now); strftime(tmpbuf, MAXCOLDIGITS, "%Y%m%d", timep); xml_params_add(params, "date", tmpbuf); /* 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(tmpbuf, MAXCOLDIGITS, "1%H%M", timep); xml_params_add(params, "time", tmpbuf); if (filename == NULL) return report_error("No CSV filename"); auto [mem, err] = readfile(filename); if (err < 0) return report_error(translate("gettextFromC", "Failed to read '%s'"), filename); /* Determine NL (new line) character and the start of CSV data */ ptr = (char *)mem.data(); while ((ptr = strstr(ptr, "\r\n\r\n")) != NULL) { ptr_old = ptr; ptr += 1; NL = "\r\n"; } if (!ptr_old) { ptr = (char *)mem.data(); while ((ptr = strstr(ptr, "\n\n")) != NULL) { ptr_old = ptr; ptr += 1; NL = "\n"; } ptr_old += 2; } else { ptr_old += 4; } /* * If file does not contain empty lines, it is not a valid * Seabear CSV file. */ if (NL == NULL) return -1; /* * 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. That is the line after * Serial number. */ ptr = strstr((char *)mem.data(), "Serial number:"); if (ptr) ptr = strstr(ptr, NL); /* * Write date and time values to params array, if available in * the CSV header */ if (ptr) { /* * The two last entries should be date and time. * Here we overwrite them with the data from the * CSV header. */ char buf[10]; ptr += strlen(NL) + 2; memcpy(buf, ptr, 4); memcpy(buf + 4, ptr + 5, 2); memcpy(buf + 6, ptr + 8, 2); buf[8] = 0; xml_params_set_value(params, xml_params_count(params) - 2, buf); buf[0] = xml_params_get_value(params, xml_params_count(params) - 1)[0]; memcpy(buf + 1, ptr + 11, 2); memcpy(buf + 3, ptr + 14, 2); buf[5] = 0; xml_params_set_value(params, xml_params_count(params) - 1, buf); } /* Move the CSV data to the start of mem buffer */ memmove(mem.data(), ptr_old, mem.size() - (ptr_old - mem.data())); mem.resize(mem.size() - (ptr_old - mem.data())); if (try_to_xslt_open_csv(filename, mem, csvtemplate)) return -1; /* * Lets print command line for manual testing with xsltproc if * verbosity level is high enough. The printed line needs the * input file added as last parameter. */ if (verbose >= 2) { std::string info = "xsltproc "; for (i = 0; i < xml_params_count(params); i++) info += format_string_std("--stringparam %s %s ", xml_params_get_key(params, i), xml_params_get_value(params, i)); info += "xslt/csv2xml.xslt"; report_info("%s", info.c_str()); } ret = parse_xml_buffer(filename, mem.data(), mem.size(), log, params); return ret; } int parse_manual_file(const char *filename, struct xml_params *params, struct divelog *log) { std::string mem; time_t now; struct tm *timep; char curdate[9]; char curtime[6]; int ret; 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); xml_params_add(params, "date", curdate); xml_params_add(params, "time", curtime); if (filename == NULL) return report_error("No manual CSV filename"); if (try_to_xslt_open_csv(filename, mem, "manualCSV")) return -1; #ifndef SUBSURFACE_MOBILE if (verbose >= 2) { std::string info = format_string_std("(echo ''; cat %s;echo '') | xsltproc ", filename); for (int i = 0; i < xml_params_count(params); i++) info += format_string_std("--stringparam %s %s ", xml_params_get_key(params, i), xml_params_get_value(params, i)); info += format_string_std("%s/xslt/manualcsv2xml.xslt -", SUBSURFACE_SOURCE); report_info("%s", info.c_str()); } #endif ret = parse_xml_buffer(filename, mem.data(), mem.size(), log, params); return ret; }