/* * uemis-downloader.c * * Copyright (c) Dirk Hohndel * released under GPL2 * * very (VERY) loosely based on the algorithms found in Java code by Fabian Gast * which was released under the BSD-STYLE BEER WARE LICENSE * I believe that I only used the information about HOW to do this (download data from the Uemis * Zurich) but did not actually use any of his copyrighted code, therefore the license under which * he released his code does not apply to this new implementation in C */ #include #include #include #include #include #include #include #include #include "uemis.h" #include "dive.h" #include "divelist.h" #include "display.h" #include "display-gtk.h" #define ERR_FS_ALMOST_FULL N_("Uemis Zurich: File System is almost full\nDisconnect/reconnect the dive computer\nand try again") #define ERR_FS_FULL N_("Uemis Zurich: File System is full\nDisconnect/reconnect the dive computer\nand try again") #define ERR_FS_SHORT_WRITE N_("Short write to req.txt file\nIs the Uemis Zurich plugged in correctly?") #define BUFLEN 2048 #define NUM_PARAM_BUFS 10 #define UEMIS_TIMEOUT 100000 static char *param_buff[NUM_PARAM_BUFS]; static char *reqtxt_path; static int reqtxt_file; static int filenr; static int number_of_files; static char *mbuf = NULL; static int mbuf_size = 0; struct argument_block { const char *mountpath; char **max_dive_data; char **xml_buffer; progressbar_t *progress; }; static int import_thread_done = 0, import_thread_cancelled; static const char *progress_bar_text = ""; static double progress_bar_fraction = 0.0; static GError *error(const char *fmt, ...) { va_list args; GError *error; va_start(args, fmt); error = g_error_new_valist( g_quark_from_string("subsurface"), DIVE_ERROR_PARSE, fmt, args); va_end(args); return error; } /* send text to the importer progress bar */ static void uemis_info(const char *fmt, ...) { static char buffer[32]; va_list ap; va_start(ap, fmt); vsnprintf(buffer, sizeof(buffer), fmt, ap); va_end(ap); progress_bar_text = buffer; } static long bytes_available(int file) { long result; long now = lseek(file, 0, SEEK_CUR); result = lseek(file, 0, SEEK_END); lseek(file, now, SEEK_SET); return result; } static int number_of_file(char *path) { int count = 0; GDir *dir = g_dir_open(path, 0, NULL); while (g_dir_read_name(dir)) count++; g_dir_close(dir); return count; } /* Check if there's a req.txt file and get the starting filenr from it. * Test for the maximum number of ANS files (I believe this is always * 4000 but in case there are differences depending on firmware, this * code is easy enough */ static gboolean uemis_init(const char *path) { char *ans_path; int i; if (!path) return FALSE; /* let's check if this is indeed a Uemis DC */ reqtxt_path = g_build_filename(path, "/req.txt", NULL); reqtxt_file = g_open(reqtxt_path, O_RDONLY, 0666); if (!reqtxt_file) return FALSE; if (bytes_available(reqtxt_file) > 5) { char tmp[6]; read(reqtxt_file, tmp, 5); tmp[5] = '\0'; #if UEMIS_DEBUG > 2 fprintf(debugfile, "::r req.txt \"%s\"\n", tmp); #endif if (sscanf(tmp + 1, "%d", &filenr) != 1) return FALSE; } #if UEMIS_DEBUG > 2 else { fprintf(debugfile, "::r req.txt skipped as there were fewer than 5 bytes\n"); } #endif close (reqtxt_file); /* It would be nice if we could simply go back to the first set of * ANS files. Something like the below - unfortunately this is known * to fail - more information from Uemis is needed here. * Without code like this it is very easy when downloading large amounts * of dives to run out of space on the dive computer - which can only * be fixed by unmounting and rebooting the DC * reqtxt_file = g_open(reqtxt_path, O_RDWR | O_CREAT | O_TRUNC, 0666); * write(reqtxt_file, "n0001", 5); * close(reqtxt_file); * filenr = 1; */ ans_path = g_build_filename(path, "ANS", NULL); number_of_files = number_of_file(ans_path); g_free(ans_path); /* initialize the array in which we collect the answers */ for (i = 0; i < NUM_PARAM_BUFS; i++) param_buff[i] = ""; return TRUE; } static void str_append_with_delim(char *s, char *t) { int len = strlen(s); snprintf(s + len, BUFLEN - len, "%s{", t); } /* The communication protocoll with the DC is truly funky. * After you write your request to the req.txt file you call this function. * It writes the number of the next ANS file at the beginning of the req.txt * file (prefixed by 'n' or 'r') and then again at the very end of it, after * the full request (this time without the prefix). * Then it syncs (not needed on Windows) and closes the file. */ static void trigger_response(int file, char *command, int nr, long tailpos) { char fl[10]; snprintf(fl, 8, "%s%04d", command, nr); #if UEMIS_DEBUG > 2 fprintf(debugfile,"::: %s (after seeks)\n", fl); #endif lseek(file, 0, SEEK_SET); write(file, fl, strlen(fl)); lseek(file, tailpos, SEEK_SET); write(file, fl + 1, strlen(fl + 1)); #ifndef WIN32 fsync(file); #endif close(file); } static char *next_token(char **buf) { char *q, *p = strchr(*buf, '{'); if (p) *p = '\0'; else p = *buf + strlen(*buf) - 1; q = *buf; *buf = p + 1; return q; } /* poor man's tokenizer that understands a quoted delimter ('{') */ static char *next_segment(char *buf, int *offset, int size) { int i = *offset; int seg_size; gboolean done = FALSE; char *segment; while (!done) { if (i < size) { if (buf[i] == '\\' && i < size - 1 && (buf[i+1] == '\\' || buf[i+1] == '{')) memcpy(buf + i, buf + i + 1, size - i - 1); else if (buf[i] == '{') done = TRUE; i++; } else { done = TRUE; } } seg_size = i - *offset - 1; if (seg_size < 0) seg_size = 0; segment = malloc(seg_size + 1); memcpy(segment, buf + *offset, seg_size); segment[seg_size] = '\0'; *offset = i; return segment; } /* a dynamically growing buffer to store the potentially massive responses. * The binary data block can be more than 100k in size (base64 encoded) */ static void buffer_add(char **buffer, int *buffer_size, char *buf) { if (!buf) return; if (! *buffer) { *buffer = strdup(buf); *buffer_size = strlen(*buffer) + 1; } else { *buffer_size += strlen(buf); *buffer = realloc(*buffer, *buffer_size); strcat(*buffer, buf); } #if UEMIS_DEBUG > 5 fprintf(debugfile,"added \"%s\" to buffer - new length %d\n", buf, *buffer_size); #endif } #define PATTERN1 "%s" #define PATTERN2 "\n%d" static gboolean get_tag_int_value(char *buffer, char *tag, int *value, char **next_ptr) { char *ptr = buffer; int len; char *format; if (!ptr || !value) return FALSE; len = strlen(PATTERN1) + strlen(PATTERN2) + strlen(tag); format = malloc(len); snprintf(format, len, PATTERN1, tag, ""); ptr = strstr(ptr, format); if (!ptr) return FALSE; snprintf(format, len, PATTERN1, tag, PATTERN2); if (sscanf(ptr, format, value) != 1) return FALSE; if (next_ptr) *next_ptr = ptr + 1; return TRUE; } static gboolean get_tag_string_value(char *buffer, char *tag, char **value) { char *eptr, *ptr = buffer; int len; char *format; if (!ptr || !value) return FALSE; len = strlen(PATTERN1) + strlen(tag); format = malloc(len); snprintf(format, len, PATTERN1, tag, ""); ptr = strstr(ptr, format); if (!ptr) return FALSE; eptr = strstr(ptr, ""); if (!eptr) return FALSE; *eptr = '\0'; *value = strdup(ptr + strlen(format) + 9); *eptr = '<'; return TRUE; } #define PATTERN4 "\n%lf" static gboolean get_tag_double_value(char *buffer, char *tag, double *value, char **next_ptr) { char *ptr = buffer; int len; char *format; if (!ptr || !value) return FALSE; len = strlen(PATTERN1) + strlen(PATTERN4) + strlen(tag); format = malloc(len); snprintf(format, len, PATTERN1, tag, ""); ptr = strstr(ptr, format); if (!ptr) return FALSE; snprintf(format, len, PATTERN1, tag, PATTERN4); if (sscanf(ptr, format, value) != 1) return FALSE; if (next_ptr) *next_ptr = ptr + 1; return TRUE; } static char *get_xml_for_int(char *buf, char *tag) { int value; char *xml; if (get_tag_int_value(buf, tag, &value, NULL)) { int len = 20 + 2 * strlen(tag); xml = malloc(len); snprintf(xml, len, "<%s>%d\n", tag, value, tag); } return xml; } static const char *suit[] = { "", "wetsuit", "semidry", "drysuit" }; static const char *suit_type[] = { "", "shorty", "vest", "long john", "jacket", "full suit", "2 pcs full suit" }; static const char *suit_thickness[] = { "", "0.5-2mm", "2-3mm", "3-5mm", "5-7mm", "8mm+", "membrane" }; static char *convert_dive_details(char *buf, uint8_t *hdr) { char *conv_buffer = NULL; int conv_size = 0; char *ptr, *eptr; double doublevalue; double weight; char *stringvalue; char textbuf[200]; int suit_idx, suit_type_idx, suit_thickness_idx; /* we want to throw away what is duplicate and clean up and * parse the userful entries */ ptr = strstr(buf, ""); if (!ptr) return NULL; eptr = strstr(ptr + 1, "\n", weight); buffer_add(&conv_buffer, &conv_size, textbuf); } if (get_tag_string_value(eptr, "notes", &stringvalue)) { buffer_add(&conv_buffer, &conv_size, ""); buffer_add(&conv_buffer, &conv_size, stringvalue); buffer_add(&conv_buffer, &conv_size, "\n"); } if (get_tag_int_value(eptr, "u8DiveSuit", &suit_idx, NULL) && get_tag_int_value(eptr, "u8DiveSuitType", &suit_type_idx, NULL) && get_tag_int_value(eptr, "u8SuitThickness", &suit_thickness_idx, NULL) && suit_idx >= 0 && suit_idx < sizeof(suit) && suit_type_idx >= 0 && suit_type_idx < sizeof(suit_type) && suit_thickness_idx >= 0 && suit_thickness_idx < sizeof(suit_thickness)) { snprintf(textbuf, sizeof(textbuf), "%s %s %s\n", suit[suit_idx], suit_type[suit_type_idx], suit_thickness[suit_thickness_idx]); buffer_add(&conv_buffer, &conv_size, textbuf); } return conv_buffer; } /* this is more interesting - insert the additional data in the dive * it belongs to - no idea why Uemis splits out the dive data in this * odd way, but we have to re-assemble it here */ static void buffer_insert(char **buffer, int *buffer_size, char *buf) { char *ptr, *endptr, *b64, *cbuf; int obj_dive; int obj_log; int offset, len; uint8_t hdr[24]; /* since we want to insert into the buffer... if there's * nothing there, this makes absolutely no sense so just * bail */ if (!buf || !*buffer) return; endptr = *buffer + strlen(*buffer); /* now figure out the object_id of buf and find the matching * spot in buffer */ if (!get_tag_int_value(buf, "logfilenr", &obj_dive, NULL)) return; ptr = *buffer; while (ptr < endptr) { if (!get_tag_int_value(ptr, "object_id", &obj_log, &ptr)) return; if (obj_dive == obj_log) break; } ptr = strstr(ptr, ""); if (!ptr) return; /* this is where the base64 data starts; we need to extract * some info from that in order to make sense of the data in * the dive info */ b64 = strstr(ptr, "") + 5; decode(b64, hdr, 32); cbuf = convert_dive_details(buf, hdr); offset = ptr - *buffer; len = strlen(cbuf); *buffer_size += len; *buffer = realloc(*buffer, *buffer_size); ptr = *buffer + offset; memmove(ptr + len, ptr, strlen(*buffer) - offset); memmove(ptr, cbuf, len); } /* are there more ANS files we can check? */ static gboolean next_file(int max) { if (filenr >= max) return FALSE; filenr++; return TRUE; } /* ultra-simplistic; it doesn't deal with the case when the object_id is * split across two chunks. It also doesn't deal with the discrepancy between * object_id and dive number as understood by the dive computer */ static void show_progress(char *buf) { char *object; object = strstr(buf, "object_id"); if (object) { /* let the user know which dive we are working on */ char tmp[10]; char *p = object + 14; char *t = tmp; if (p < buf + strlen(buf)) { while (*p != '{' && t < tmp + 9) *t++ = *p++; *t = '\0'; uemis_info(_("Reading dive %s"), tmp); } } } /* send a request to the dive computer and collect the answer */ static gboolean uemis_get_answer(const char *path, char *request, int n_param_in, int n_param_out, char **error_text) { int i = 0, file_length; char sb[BUFLEN]; char fl[13]; char tmp[101]; gboolean searching = TRUE; gboolean assembling_mbuf = FALSE; gboolean ismulti = FALSE; gboolean found_answer = FALSE; gboolean more_files = TRUE; gboolean answer_in_mbuf = FALSE; char *ans_path; int ans_file; reqtxt_file = g_open(reqtxt_path, O_RDWR | O_CREAT, 0666); snprintf(sb, BUFLEN, "n%04d12345678", filenr); str_append_with_delim(sb, request); for (i = 0; i < n_param_in; i++) str_append_with_delim(sb, param_buff[i]); if (! strcmp(request, "getDivelogs") || ! strcmp(request, "getDeviceData") || ! strcmp(request, "getDirectory")) { answer_in_mbuf = TRUE; str_append_with_delim(sb, ""); } str_append_with_delim(sb, ""); file_length = strlen(sb); snprintf(fl, 10, "%08d", file_length - 13); memcpy(sb + 5, fl, strlen(fl)); #ifdef UEMIS_DEBUG fprintf(debugfile,"::w req.txt \"%s\"\n", sb); #endif if (write(reqtxt_file, sb, strlen(sb)) != strlen(sb)) { *error_text = _(ERR_FS_SHORT_WRITE); return FALSE; } if (! next_file(number_of_files)) { *error_text = _(ERR_FS_FULL); more_files = FALSE; } trigger_response(reqtxt_file, "n", filenr, file_length); usleep(UEMIS_TIMEOUT); mbuf = NULL; mbuf_size = 0; while (searching || assembling_mbuf) { progress_bar_fraction = filenr / 4000.0; snprintf(fl, 13, "ANS%d.TXT", filenr - 1); ans_path = g_build_filename(path, "ANS", fl, NULL); ans_file = g_open(ans_path, O_RDONLY, 0666); read(ans_file, tmp, 100); close(ans_file); #if UEMIS_DEBUG > 3 tmp[100]='\0'; fprintf(debugfile, "::t %s \"%s\"\n", ans_path, tmp); #endif g_free(ans_path); if (tmp[0] == '1') { searching = FALSE; if (tmp[1] == 'm') { assembling_mbuf = TRUE; ismulti = TRUE; } if (tmp[2] == 'e') assembling_mbuf = FALSE; if (assembling_mbuf) { if (! next_file(number_of_files)) { *error_text = _(ERR_FS_FULL); more_files = FALSE; assembling_mbuf = FALSE; } reqtxt_file = g_open(reqtxt_path, O_RDWR | O_CREAT, 0666); trigger_response(reqtxt_file, "n", filenr, file_length); } } else { if (! next_file(number_of_files - 1)) { *error_text = _(ERR_FS_FULL); more_files = FALSE; assembling_mbuf = FALSE; searching = FALSE; } reqtxt_file = g_open(reqtxt_path, O_RDWR | O_CREAT, 0666); trigger_response(reqtxt_file, "r", filenr, file_length); usleep(UEMIS_TIMEOUT); } if (ismulti && more_files && tmp[0] == '1') { int size; snprintf(fl, 13, "ANS%d.TXT", assembling_mbuf ? filenr - 2 : filenr - 1); ans_path = g_build_filename(path, "ANS", fl, NULL); ans_file = g_open(ans_path, O_RDONLY, 0666); size = bytes_available(ans_file); if (size > 3) { char *buf = malloc(size - 2); lseek(ans_file, 3, SEEK_CUR); read(ans_file, buf, size - 3); buf[size -3 ] = '\0'; buffer_add(&mbuf, &mbuf_size, buf); show_progress(buf); free(buf); param_buff[3]++; } close(ans_file); usleep(UEMIS_TIMEOUT); } } if (more_files) { int size = 0, j = 0; char *buf = NULL; if (!ismulti) { snprintf(fl, 13, "ANS%d.TXT", filenr - 1); ans_path = g_build_filename(path, "ANS", fl, NULL); ans_file = g_open(ans_path, O_RDONLY, 0666); size = bytes_available(ans_file); if (size > 3) { buf = malloc(size - 2); lseek(ans_file, 3, SEEK_CUR); read(ans_file, buf, size - 3); buf[size - 3] = '\0'; #if UEMIS_DEBUG > 2 fprintf(debugfile, "::r %s \"%s\"\n", ans_path, buf); #endif } size -= 3; close(ans_file); free(ans_path); } else { ismulti = FALSE; } #if UEMIS_DEBUG > 1 fprintf(debugfile,":r: %s\n", buf); #endif if (!answer_in_mbuf) for (i = 0; i < n_param_out && j < size; i++) param_buff[i] = next_segment(buf, &j, size); found_answer = TRUE; free(buf); } #if UEMIS_DEBUG for (i = 0; i < n_param_out; i++) fprintf(debugfile,"::: %d: %s\n", i, param_buff[i]); #endif return found_answer; } /* Turn what we get from the dive computer into something that we can * pass to the parse_xml function. If this is a divelog, then the * last 'object_id' that we see is returned as our current * approximation of a last dive number */ static char *process_raw_buffer(char *inbuf, char **max_divenr) { char *buf = strdup(inbuf); char *tp, *bp, *tag, *type, *val; gboolean done = FALSE; int inbuflen = strlen(inbuf); char *endptr = buf + inbuflen; char *conv_buffer = NULL; int conv_buffer_size = 0; gboolean log = FALSE; char *sections[10]; int s, nr_sections = 0; bp = buf + 1; tp = next_token(&bp); if (strcmp(tp, "divelog") == 0) { /* this is a divelog */ log = TRUE; tp = next_token(&bp); if (strcmp(tp,"1.0") != 0) return NULL; } else if (strcmp(tp, "dive") == 0) { /* this is dive detail */ tp = next_token(&bp); if (strcmp(tp,"1.0") != 0) return NULL; } else { /* don't understand the buffer */ return NULL; } if (log) buffer_add(&conv_buffer, &conv_buffer_size, "\n"); while (!done) { char *tmp; int tmp_size; /* the valid buffer ends with a series of delimiters */ if (bp >= endptr - 2 || !strcmp(bp, "{{")) break; tag = next_token(&bp); /* we also end if we get an empty tag */ if (*tag == '\0') break; for (s = 0; s < nr_sections; s++) if (!strcmp(tag, sections[s])) { tag = next_token(&bp); break; } type = next_token(&bp); if (!strcmp(type, "1.0")) { /* this tells us the sections that will follow; the tag here * is of the format dive-
*/ sections[nr_sections] = strchr(tag, '-') + 1; #if UEMIS_DEBUG > 2 fprintf(debugfile, "Expect to find section %s\n", sections[nr_sections]); #endif if (nr_sections < sizeof(sections) - 1) nr_sections++; continue; } val = next_token(&bp); if (log && ! strcmp(tag, "object_id")) { free(*max_divenr); *max_divenr = strdup(val); } if (! strcmp(tag, "file_content")) { tmp_size = 45 + strlen(tag) + strlen(val); done = TRUE; } else { tmp_size = 28 + strlen(tag) + 2 * strlen(type) + strlen(val); } tmp = malloc(tmp_size); snprintf(tmp, tmp_size, "\n<%s>%s\n\n", tag, type, val, type); buffer_add(&conv_buffer, &conv_buffer_size, tmp); free(tmp); /* done with one dive (got the file_content tag), but there could be more: * a '{' indicates the end of the record - but we need to see another "{{" * later in the buffer to know that the next record is complete (it could * be a short read because of some error */ if (done && ++bp < endptr && *bp != '{' && strstr(bp, "{{")) { done = FALSE; buffer_add(&conv_buffer, &conv_buffer_size, "\n\n"); } } if (log) { buffer_add(&conv_buffer, &conv_buffer_size, "\n"); } free(buf); #if UEMIS_DEBUG > 2 fprintf(debugfile,"converted to \"%s\"\n", conv_buffer); #endif return strdup(conv_buffer); } /* to keep track of multiple computers we simply encode the last dive read in tuples "{deviceid,nr},{deviceid,nr}..." no spaces to make parsing easier */ static char *find_deviceid(char *max_dive_data, char *deviceid) { char *pattern; char *result; if (! deviceid || *deviceid == '\0') return NULL; pattern = malloc(3 + strlen(deviceid)); sprintf(pattern, "{%s,", deviceid); result = strstr(max_dive_data, pattern); free(pattern); return result; } static char *get_divenr(char *max_dive_data, char *deviceid) { char *q, *p = max_dive_data; char *result = NULL; if (!p || !deviceid) return strdup("0"); p = find_deviceid(max_dive_data, deviceid); if (p) { p += strlen(deviceid) + 2; q = strchr(p, '}'); if (!q) return result; result = malloc(q - p + 1); strncpy(result, p, q - p); result[q - p] = '\0'; } if (!result) result = strdup("0"); return result; } static char *update_max_dive_data(char *max_dive_data, char *deviceid, char *newmax) { char *p; char *result; int len; if (! newmax || *newmax == '\0') return max_dive_data; p = find_deviceid(max_dive_data, deviceid); if (p) { /* if there are more entries after this one, copy them, otherwise just remove the existing entry for this device */ char *q = strstr(p, "},{"); if (q) { memcpy(p + 1, q + 3, strlen(q + 3) + 1); } else { if (p > max_dive_data) *(p-1) = '\0'; else *p = '\0'; } } /* now add the new one at the end */ len = strlen(max_dive_data) + strlen(deviceid) + strlen(newmax) + 4 + (strlen(max_dive_data) ? 1 : 0); result = malloc(len); snprintf(result, len, "%s%s{%s,%s}", max_dive_data, strlen(max_dive_data) ? "," : "", deviceid, newmax); free(max_dive_data); return result; } static char *do_uemis_download(struct argument_block *args) { const char *mountpath = args->mountpath; char **max_dive_data = args->max_dive_data; char **xml_buffer = args->xml_buffer; int xml_buffer_size; char *newmax = NULL; int start, end, i; char objectid[10]; char *deviceid = NULL; char *result = NULL; char *endptr; gboolean success; buffer_add(xml_buffer, &xml_buffer_size, "\n\n"); uemis_info("Init Communication"); if (! uemis_init(mountpath)) return _("Uemis init failed"); if (! uemis_get_answer(mountpath, "getDeviceId", 0, 1, &result)) goto bail; deviceid = strdup(param_buff[0]); /* the answer from the DeviceId call becomes the input parameter for getDeviceData */ if (! uemis_get_answer(mountpath, "getDeviceData", 1, 0, &result)) goto bail; /* param_buff[0] is still valid */ if (! uemis_get_answer(mountpath, "initSession", 1, 6, &result)) goto bail; uemis_info("Start download"); if (! uemis_get_answer(mountpath, "processSync", 0, 2, &result)) goto bail; param_buff[1] = "notempty"; newmax = get_divenr(*max_dive_data, deviceid); if (sscanf(newmax, "%d", &start) != 1) start = 0; for (;;) { param_buff[2] = newmax; param_buff[3] = 0; success = uemis_get_answer(mountpath, "getDivelogs", 3, 0, &result); /* process the buffer we have assembled */ if (mbuf) { char *next_seg = process_raw_buffer(mbuf, &newmax); buffer_add(xml_buffer, &xml_buffer_size, next_seg); free(next_seg); } /* if we got an error, deal with it */ if (!success) break; /* also, if we got nothing back, we should stop trying */ if (!param_buff[3]) break; /* finally, if the memory is getting too full, maybe we better stop, too */ if (progress_bar_fraction > 0.85) { result = _(ERR_FS_ALMOST_FULL); break; } /* clean up mbuf */ endptr = strstr(mbuf, "{{{"); if (endptr) *(endptr + 2) = '\0'; } *args->max_dive_data = update_max_dive_data(*max_dive_data, deviceid, newmax); if (sscanf(newmax, "%d", &end) != 1) end = start; #if UEMIS_DEBUG > 2 fprintf(debugfile, "done: read from object_id %d to %d\n", start, end); #endif free(newmax); for (i = start; i < end; i++) { snprintf(objectid, sizeof(objectid), "%d", i); param_buff[2] = objectid; param_buff[3] = 0; success = uemis_get_answer(mountpath, "getDive", 3, 0, &result); if (mbuf) { char *next_detail = process_raw_buffer(mbuf, &newmax); buffer_insert(xml_buffer, &xml_buffer_size, next_detail); free(next_detail); } if (!success) break; } if (! uemis_get_answer(mountpath, "terminateSync", 0, 3, &result)) goto bail; if (! strcmp(param_buff[0], "error")) { if (! strcmp(param_buff[2],"Out of Memory")) result = _(ERR_FS_FULL); else result = param_buff[2]; } buffer_add(xml_buffer, &xml_buffer_size, ""); #if UEMIS_DEBUG > 5 fprintf(debugfile, "XML buffer \"%s\"", *xml_buffer); #endif bail: free(deviceid); return result; } static void *pthread_wrapper(void *_data) { struct argument_block *args = _data; const char *err_string = do_uemis_download(args); import_thread_done = 1; return (void *)err_string; } GError *uemis_download(const char *mountpath, char **max_dive_data, char **xml_buffer, progressbar_t *progress) { pthread_t pthread; void *retval; struct argument_block args = {mountpath, max_dive_data, xml_buffer, progress}; /* I'm sure there is some better interface for waiting on a thread in a UI main loop */ import_thread_done = 0; progress_bar_text = ""; progress_bar_fraction = 0.0; pthread_create(&pthread, NULL, pthread_wrapper, &args); while (!import_thread_done) { import_thread_cancelled = process_ui_events(); update_progressbar(args.progress, progress_bar_fraction); update_progressbar_text(args.progress, progress_bar_text); usleep(100000); } if (pthread_join(pthread, &retval) < 0) return error("Pthread return with error"); if (retval) return error(retval); return NULL; }