/* * DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS HEADER. * * Copyright 2019 Olaf Wintermann. All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions are met: * * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" * AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE * ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDER OR CONTRIBUTORS BE * LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR * CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF * SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS * INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN * CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) * ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE * POSSIBILITY OF SUCH DAMAGE. */ #include #include #include #include #include #include #include #include #include #include #include #ifdef _WIN32 #include #define getpasswordchar() getch() #define IS_PATH_SEPARATOR(c) (c == '/' || c == '\\') #define PATH_SEPARATOR '\\' #else #include #define getpasswordchar() getchar() #define IS_PATH_SEPARATOR(c) (c == '/') #define PATH_SEPARATOR '/' #endif #include "webdav.h" #include "utils.h" #include "crypto.h" #include "session.h" /* #include #include #include #include #include */ static size_t extractval(sstr_t str, char *result, char delim) { size_t n = 0; for(size_t i = 0; i < str.length ; i++) { if(isdigit(str.ptr[i])) { result[n++] = str.ptr[i]; } else if(str.ptr[i] != delim) { return 0; } } result[n] = '\0'; return n; } static time_t parse_iso8601(char *iso8601str) { // safety if(!iso8601str) { return 0; } // local vars struct tm tparts; memset(&tparts, 0, sizeof(struct tm)); long val; char conv[16]; // work on the trimmed string sstr_t date = sstrtrim(sstr(iso8601str)); sstr_t time = sstrchr(date, 'T'); if(time.length == 0) { return 0; } date.length = time.ptr - date.ptr; time.ptr++; time.length--; sstr_t tzinfo; if((tzinfo = sstrchr(time, 'Z')).length > 0 || (tzinfo = sstrchr(time, '+')).length > 0 || (tzinfo = sstrchr(time, '-')).length > 0) { time.length = tzinfo.ptr - time.ptr; } // parse date if((date.length != 8 && date.length != 10) || extractval(date, conv , '-') != 8) { return 0; } val = atol(conv); if(val < 19000000L) { return 0; } tparts.tm_mday = val % 100; tparts.tm_mon = (val % 10000) / 100 - 1; tparts.tm_year = val / 10000 - 1900; // parse time and skip possible fractional seconds sstr_t frac; if((frac = sstrchr(time, '.')).length > 0 || (frac = sstrchr(time, ',')).length > 0) { time.length = frac.ptr - time.ptr; } if((time.length != 6 && time.length != 8) || extractval(time, conv , ':') != 6) { return 0; } val = atol(conv); tparts.tm_sec = val % 100; tparts.tm_min = (val % 10000) / 100; tparts.tm_hour = val / 10000; // parse time zone (if any) if(tzinfo.length == 0) { // local time tparts.tm_isdst = -1; return mktime(&tparts); } else if(!sstrcmp(tzinfo, S("Z"))) { #ifdef __FreeBSD__ return timegm(&tparts); #else return mktime(&tparts) - timezone; #endif } else if(tzinfo.ptr[0] == '+' || tzinfo.ptr[0] == '-') { int sign = (tzinfo.ptr[0] == '+') ? -1 : 1; if(tzinfo.length > 6) { return 0; } else { tzinfo.ptr++; tzinfo.length--; extractval(tzinfo, conv, ':'); val = atol(conv); val = 60 * (val / 100) + (val % 100); #ifdef __FreeBSD__ return timegm(&tparts) + (time_t) (60 * val * sign); #else return mktime(&tparts) - timezone + (time_t) (60 * val * sign); #endif } } else { return 0; } } time_t util_parse_creationdate(char *str) { // parse a ISO-8601 date (rfc-3339) // example: 2012-11-29T21:35:35Z if(!str) { return 0; } return parse_iso8601(str); } time_t util_parse_lastmodified(char *str) { // parse a rfc-1123 date // example: Thu, 29 Nov 2012 21:35:35 GMT if(!str) { return 0; } else { time_t result = curl_getdate(str, NULL); if(result == -1) { // fall back to the ISO-8601 format (e.g. Microsoft Sharepoint // illegally uses this format for lastmodified, but also some // users might want to give an ISO-8601 date) return util_parse_creationdate(str); } else { return result; } } } int util_getboolean(const char *v) { if(v[0] == 'T' || v[0] == 't') { return 1; } return 0; } int util_strtouint(const char *str, uint64_t *value) { char *end; errno = 0; uint64_t val = strtoull(str, &end, 0); if(errno == 0) { *value = val; return 1; } else { return 0; } } int util_strtoint(const char *str, int64_t *value) { char *end; errno = 0; int64_t val = strtoll(str, &end, 0); if(errno == 0) { *value = val; return 1; } else { return 0; } } int util_szstrtouint(const char *str, uint64_t *value) { char *end; errno = 0; size_t len = strlen(str); uint64_t val = strtoull(str, &end, 0); if(end == str+len) { *value = val; return 1; } else if(end == str+len-1) { uint64_t mul = 1; switch(end[0]) { case 'k': case 'K': mul = 1024; break; case 'm': case 'M': mul = 1024*1024; break; case 'g': case 'G': mul = 1024*1024*1024; break; default: return 0; } uint64_t result = 0; if(util_uint_mul(val, mul, &result)) { return 0; } *value = result; return 1; } return 0; } int util_uint_mul(uint64_t a, uint64_t b, uint64_t *result) { if(a == 0 || b == 0) { *result = 0; return 0; } uint64_t r = a * b; if(r / b == a) { *result = r; return 0; } else { *result = 0; return 1; } } char* util_url_base_s(sstr_t url) { size_t i = 0; if(url.length > 0) { int slmax; if(sstrprefix(url, SC("http://"))) { slmax = 3; } else if(sstrprefix(url, SC("https://"))) { slmax = 3; } else { slmax = 1; } int slashcount = 0; for(i=0;i 7 && !strncasecmp(url, "http://", 7)) { slmax = 3; } else if(len > 8 && !strncasecmp(url, "https://", 8)) { slmax = 3; } else { slmax = 1; } char c; for(int i=0;ihandle, url, strlen(url), NULL); char *ret = strdup(unesc); curl_free(unesc); return ret; } static size_t util_header_callback(char *buffer, size_t size, size_t nitems, void *data) { sstr_t sbuffer = sstrn(buffer, size*nitems); UcxMap *map = (UcxMap*) data; // if we get a status line, clear the map and exit if(sstrprefix(sbuffer, S("HTTP/"))) { ucx_map_free_content(map, free); ucx_map_clear(map); return size*nitems; } // if we get the terminating CRLF, just exit if(!sstrcmp(sbuffer, S("\r\n"))) { return 2; } sstr_t key = sbuffer; sstr_t value = sstrchr(sbuffer, ':'); if(value.length == 0) { return 0; // invalid header line } key.length = value.ptr - key.ptr; value.ptr++; value.length--; key = sstrlower(sstrtrim(key)); value = sstrdup(sstrtrim(value)); ucx_map_sstr_put(map, key, value.ptr); free(key.ptr); return sbuffer.length; } int util_path_isrelated(const char *path1, const char *path2) { scstr_t p1 = scstr(path1); scstr_t p2 = scstr(path2); if(IS_PATH_SEPARATOR(p1.ptr[p1.length-1])) { p1.length--; } if(IS_PATH_SEPARATOR(p2.ptr[p2.length-1])) { p2.length--; } if(p2.length < p1.length) { return 0; } if(!sstrcmp(p1, p2)) { return 1; } if(sstrprefix(p2, p1)) { if(IS_PATH_SEPARATOR(p2.ptr[p1.length])) { return 1; } } return 0; } #ifdef _WIN32 int util_path_isabsolut(const char *path) { if(strlen(path) < 3) { return 0; } // check if first char is A-Z or a-z char c = path[0]; if(!((c >= 65 && c <= 90) || (c >= 97 && c <= 122))) { return 0; } if(path[1] == ':' && path[2] == '\\') { return 1; } return 0; } #else int util_path_isabsolut(const char *path) { return path[0] == '/'; } #endif char* util_path_normalize(const char *path) { size_t len = strlen(path); UcxBuffer *buf = ucx_buffer_new(NULL, len+1, UCX_BUFFER_AUTOEXTEND); if(path[0] == '/') { ucx_buffer_putc(buf, '/'); } int add_separator = 0; int seg_start = 0; for(int i=0;i<=len;i++) { char c = path[i]; if(IS_PATH_SEPARATOR(c) || c == '\0') { const char *seg_ptr = path+seg_start; int seg_len = i - seg_start; if(IS_PATH_SEPARATOR(seg_ptr[0])) { seg_ptr++; seg_len--; } if(seg_len > 0) { scstr_t seg = scstrn(seg_ptr, seg_len); if(!sstrcmp(seg, SC(".."))) { for(int j=buf->pos;j>=0;j--) { char t = buf->space[j]; if(IS_PATH_SEPARATOR(t) || j == 0) { buf->pos = j; buf->size = j; buf->space[j] = 0; add_separator = IS_PATH_SEPARATOR(t) ? 1 : 0; break; } } } else if(!sstrcmp(seg, SC("."))) { // ignore } else { if(add_separator) { ucx_buffer_putc(buf, PATH_SEPARATOR); } ucx_buffer_write(seg_ptr, 1, seg_len, buf); add_separator = 1; } } seg_start = i; } } ucx_buffer_putc(buf, 0); char *space = buf->space; buf->flags = 0; // disable autofree ucx_buffer_free(buf); return space; } static char* create_relative_path(const char *abspath, const char *base) { size_t path_len = strlen(abspath); size_t base_len = strlen(base); if(IS_PATH_SEPARATOR(abspath[path_len-1])) { path_len--; } if(IS_PATH_SEPARATOR(base[base_len-1])) { base_len--; } // get base parent for(int i=base_len-1;i>=0;i--) { if(IS_PATH_SEPARATOR(base[i])) { base_len = i+1; break; } } size_t max = path_len > base_len ? base_len : path_len; // get prefix of abspath and base // this dir is the root of the link size_t i; size_t last_dir = 0; for(i=0;iflags = 0; ret = out->space; ucx_buffer_free(out); return ret; } #ifdef _WIN32 char* util_create_relative_path(const char *abspath, const char *base) { char *abspath_converted = strdup(abspath); char *base_converted = strdup(base); size_t abs_len = strlen(abspath_converted); size_t base_len = strlen(base_converted); for(int i=0;i 1) { return resname.ptr+1; } else { return url; } } int util_mkdir(char *path, mode_t mode) { #ifdef _WIN32 return mkdir(path); #else return mkdir(path, mode); #endif } char* util_concat_path(const char *url_base, const char *p) { sstr_t base = sstr((char*)url_base); sstr_t path; if(p) { path = sstr((char*)p); } else { path = sstrn("", 0); } int add_separator = 0; if(base.length != 0 && base.ptr[base.length-1] == '/') { if(path.ptr[0] == '/') { base.length--; } } else { if(path.length == 0 || path.ptr[0] != '/') { add_separator = 1; } } sstr_t url; if(add_separator) { url = sstrcat(3, base, sstr("/"), path); } else { url = sstrcat(2, base, path); } return url.ptr; } char* util_get_url(DavSession *sn, const char *href) { scstr_t base = scstr(sn->base_url); scstr_t href_str = scstr(href); char *base_path = util_url_path(sn->base_url); base.length -= strlen(base_path); sstr_t url = sstrcat(2, base, href_str); return url.ptr; } void util_set_url(DavSession *sn, const char *href) { char *url = util_get_url(sn, href); curl_easy_setopt(sn->handle, CURLOPT_URL, url); free(url); } char* util_path_to_url(DavSession *sn, char *path) { char *space = malloc(256); UcxBuffer *url = ucx_buffer_new(space, 256, UCX_BUFFER_AUTOEXTEND); // add base url ucx_buffer_write(sn->base_url, 1, strlen(sn->base_url), url); // remove trailing slash ucx_buffer_seek(url, -1, SEEK_CUR); sstr_t p = sstr(path); ssize_t ntk = 0; sstr_t *tks = sstrsplit(p, S("/"), &ntk); for(int i=0;i 0) { char *esc = curl_easy_escape(sn->handle, node.ptr, node.length); ucx_buffer_putc(url, '/'); ucx_buffer_write(esc, 1, strlen(esc), url); curl_free(esc); } free(node.ptr); } free(tks); if(path[p.length-1] == '/') { ucx_buffer_putc(url, '/'); } ucx_buffer_putc(url, 0); space = url->space; ucx_buffer_free(url); return space; } char* util_parent_path(const char *path) { char *name = util_resource_name((char*)path); size_t namelen = strlen(name); size_t pathlen = strlen(path); size_t parentlen = pathlen - namelen; char *parent = malloc(parentlen + 1); memcpy(parent, path, parentlen); parent[parentlen] = '\0'; return parent; } char* util_size_str(DavBool iscollection, uint64_t contentlength) { char *str = malloc(16); uint64_t size = contentlength; if(iscollection) { str[0] = '\0'; // currently no information for collections } else if(size < 0x400) { snprintf(str, 16, "%" PRIu64 " bytes", size); } else if(size < 0x100000) { float s = (float)size/0x400; int diff = (s*100 - (int)s*100); if(diff > 90) { diff = 0; s += 0.10f; } if(size < 0x2800 && diff != 0) { // size < 10 KiB snprintf(str, 16, "%.1f KiB", s); } else { snprintf(str, 16, "%.0f KiB", s); } } else if(size < 0x40000000) { float s = (float)size/0x100000; int diff = (s*100 - (int)s*100); if(diff > 90) { diff = 0; s += 0.10f; } if(size < 0xa00000 && diff != 0) { // size < 10 MiB snprintf(str, 16, "%.1f MiB", s); } else { size /= 0x100000; snprintf(str, 16, "%.0f MiB", s); } } else if(size < 0x1000000000ULL) { float s = (float)size/0x40000000; int diff = (s*100 - (int)s*100); if(diff > 90) { diff = 0; s += 0.10f; } if(size < 0x280000000 && diff != 0) { // size < 10 GiB snprintf(str, 16, "%.1f GiB", s); } else { size /= 0x40000000; snprintf(str, 16, "%.0f GiB", s); } } else { size /= 1024; float s = (float)size/0x40000000; int diff = (s*100 - (int)s*100); if(diff > 90) { diff = 0; s += 0.10f; } if(size < 0x280000000 && diff != 0) { // size < 10 TiB snprintf(str, 16, "%.1f TiB", s); } else { size /= 0x40000000; snprintf(str, 16, "%.0f TiB", s); } } return str; } char* util_date_str(time_t tm) { struct tm t; struct tm n; time_t now = time(NULL); #ifdef _WIN32 memcpy(&t, localtime(&tm), sizeof(struct tm)); memcpy(&n, localtime(&now), sizeof(struct tm)); #else localtime_r(&tm, &t); localtime_r(&now, &n); #endif /* _WIN32 */ char *str = malloc(16); if(t.tm_year == n.tm_year) { strftime(str, 16, "%b %d %H:%M", &t); } else { strftime(str, 16, "%b %d %Y", &t); } return str; } char* util_xml_get_text(const xmlNode *elm) { xmlNode *node = elm->children; while(node) { if(node->type == XML_TEXT_NODE) { return (char*)node->content; } node = node->next; } return NULL; } char* util_base64decode(const char *in) { int len = 0; return util_base64decode_len(in, &len); } #define WHITESPACE 64 #define EQUALS 65 #define INVALID 66 static char b64dectable[] = { 66,66,66,66,66,66,66,66,66,66,64,66,66,66,66,66,66,66,66,66,66,66,66,66,66, 66,66,66,66,66,66,66,66,66,66,66,66,66,66,66,66,66,66,62,66,66,66,63,52,53, 54,55,56,57,58,59,60,61,66,66,66,65,66,66,66, 0, 1, 2, 3, 4, 5, 6, 7, 8, 9, 10,11,12,13,14,15,16,17,18,19,20,21,22,23,24,25,66,66,66,66,66,66,26,27,28, 29,30,31,32,33,34,35,36,37,38,39,40,41,42,43,44,45,46,47,48,49,50,51,66,66, 66,66,66,66,66,66,66,66,66,66,66,66,66,66,66,66,66,66,66,66,66,66,66,66,66, 66,66,66,66,66,66,66,66,66,66,66,66,66,66,66,66,66,66,66,66,66,66,66,66,66, 66,66,66,66,66,66,66,66,66,66,66,66,66,66,66,66,66,66,66,66,66,66,66,66,66, 66,66,66,66,66,66,66,66,66,66,66,66,66,66,66,66,66,66,66,66,66,66,66,66,66, 66,66,66,66,66,66,66,66,66,66,66,66,66,66,66,66,66,66,66,66,66,66,66,66,66, 66,66,66,66,66,66 }; char* util_base64decode_len(const char* in, int *outlen) { /* code is mostly from wikibooks */ if(!in) { *outlen = 0; return NULL; } size_t inlen = strlen(in); size_t bufsize = (inlen*3) / 4; char *outbuf = malloc(bufsize+1); *outlen = -1; unsigned char *out = (unsigned char*)outbuf; const char *end = in + inlen; char iter = 0; uint32_t buf = 0; size_t len = 0; while (in < end) { unsigned char c = b64dectable[*in++]; switch (c) { case WHITESPACE: continue; /* skip whitespace */ case INVALID: { /* invalid input */ outbuf[0] = 0; return outbuf; } case EQUALS: { /* pad character, end of data */ in = end; continue; } default: { buf = buf << 6 | c; iter++; // increment the number of iteration /* If the buffer is full, split it into bytes */ if (iter == 4) { if ((len += 3) > bufsize) { /* buffer overflow */ outbuf[0] = 0; return outbuf; } *(out++) = (buf >> 16) & 255; *(out++) = (buf >> 8) & 255; *(out++) = buf & 255; buf = 0; iter = 0; } } } } if (iter == 3) { if ((len += 2) > bufsize) { /* buffer overflow */ outbuf[0] = 0; return outbuf; } *(out++) = (buf >> 10) & 255; *(out++) = (buf >> 2) & 255; } else if (iter == 2) { if (++len > bufsize) { /* buffer overflow */ outbuf[0] = 0; return outbuf; } *(out++) = (buf >> 4) & 255; } *outlen = len; /* modify to reflect the actual output size */ outbuf[len] = 0; return outbuf; } static char* b64enctable = "ABCDEFGHIJKLMNOPQRSTUVWXYZabcdefghijklmnopqrstuvwxyz0123456789+/"; char* util_base64encode(const char *in, size_t len) { // calculate length of base64 output and create buffer size_t outlen = 4 * ((len + 2) / 3); int pad = len % 3; char *out = malloc(outlen + 1); out[outlen] = 0; size_t pos = 0; // encode blocks of 3 bytes size_t i; size_t blockend = len - pad; for(i=0;i> 18) & 63]; out[pos++] = b64enctable[(inb >> 12) & 63]; out[pos++] = b64enctable[(inb >> 6) & 63]; out[pos++] = b64enctable[(inb) & 63]; } // encode last bytes if(pad > 0) { char p[3] = {0, 0, 0}; for(int j=0;i> 18) & 63]; out[pos++] = b64enctable[(inb >> 12) & 63]; out[pos++] = b64enctable[(inb >> 6) & 63]; out[pos++] = b64enctable[(inb) & 63]; for(int k=outlen-1;k>=outlen-(3-pad);k--) { out[k] = '='; } } return out; } char* util_encrypt_str(DavSession *sn, char *str, char *key) { DavKey *k = dav_context_get_key(sn->context, key); if(!k) { sn->error = DAV_ERROR; sstr_t err = ucx_sprintf("Key %s not found", key); dav_session_set_errstr(sn, err.ptr); free(err.ptr); return NULL; } return util_encrypt_str_k(sn, str, k); } char* util_encrypt_str_k(DavSession *sn, char *str, DavKey *key) { char *enc_str = aes_encrypt(str, strlen(str), key); char *ret_str = dav_session_strdup(sn, enc_str); free(enc_str); return ret_str; } char* util_decrypt_str(DavSession *sn, char *str, char *key) { DavKey *k = dav_context_get_key(sn->context, key); if(!k) { sn->error = DAV_ERROR; sstr_t err = ucx_sprintf("Key %s not found", key); dav_session_set_errstr(sn, err.ptr); free(err.ptr); return NULL; } return util_decrypt_str_k(sn, str, k); } char* util_decrypt_str_k(DavSession *sn, char *str, DavKey *key) { size_t len = 0; char *dec_str = aes_decrypt(str, &len, key); char *ret_str = dav_session_strdup(sn, dec_str); free(dec_str); return ret_str; } char* util_random_str() { unsigned char *str = malloc(25); str[24] = '\0'; sstr_t t = S( "01234567890" "abcdefghijklmnopqrstuvwxyz" "ABCDEFGHIJKLMNOPQRSTUVWXYZ"); const unsigned char *table = (const unsigned char*)t.ptr; #ifdef DAV_USE_OPENSSL RAND_bytes(str, 24); #else dav_rand_bytes(str, 24); #endif for(int i=0;i<24;i++) { int c = str[i] % t.length; str[i] = table[c]; } return (char*)str; } /* * gets a substring from 0 to the appearance of the token * tokens are separated by space * sets sub to the substring and returns the remaining string */ sstr_t util_getsubstr_until_token(sstr_t str, sstr_t token, sstr_t *sub) { int i; int token_start = -1; int token_end = -1; for(i=0;i<=str.length;i++) { int c; if(i == str.length) { c = ' '; } else { c = str.ptr[i]; } if(c < 33) { if(token_start != -1) { token_end = i; size_t len = token_end - token_start; sstr_t tk = sstrsubsl(str, token_start, len); //printf("token: {%.*s}\n", token.length, token.ptr); if(!sstrcmp(tk, token)) { *sub = sstrtrim(sstrsubsl(str, 0, token_start)); break; } token_start = -1; token_end = -1; } } else { if(token_start == -1) { token_start = i; } } } if(i < str.length) { return sstrtrim(sstrsubs(str, i)); } else { str.ptr = NULL; str.length = 0; return str; } } sstr_t util_readline(FILE *stream) { UcxBuffer *buf = ucx_buffer_new(NULL, 128, UCX_BUFFER_AUTOEXTEND); int c; while((c = fgetc(stream)) != EOF) { if(c == '\n') { break; } ucx_buffer_putc(buf, c); } sstr_t str = sstrdup(sstrtrim(sstrn(buf->space, buf->size))); ucx_buffer_free(buf); return str; } char* util_password_input(char *prompt) { fprintf(stderr, "%s", prompt); fflush(stderr); #ifndef _WIN32 // hide terminal input struct termios oflags, nflags; tcgetattr(fileno(stdin), &oflags); nflags = oflags; nflags.c_lflag &= ~ECHO; nflags.c_lflag |= ECHONL; if (tcsetattr(fileno(stdin), TCSANOW, &nflags) != 0) { perror("tcsetattr"); } #endif // read password input UcxBuffer *buf = ucx_buffer_new(NULL, 128, UCX_BUFFER_AUTOEXTEND); int c = 0; while((c = getpasswordchar()) != EOF) { if(c == '\n' || c == '\r') { break; } ucx_buffer_putc(buf, c); } ucx_buffer_putc(buf, 0); fflush(stdin); #ifndef _WIN32 // restore terminal settings if (tcsetattr(fileno(stdin), TCSANOW, &oflags) != 0) { perror("tcsetattr"); } #endif char *str = buf->space; free(buf); // only free the UcxBuffer struct return str; } char* util_hexstr(const unsigned char *data, size_t len) { size_t buflen = 2*len + 4; UcxBuffer *buf = ucx_buffer_new(malloc(buflen), buflen + 1, 0); for(int i=0;ispace; ucx_buffer_free(buf); return str; } void util_remove_trailing_pathseparator(char *path) { size_t len = strlen(path); if(len < 2) { return; } if(path[len-1] == '/') { path[len-1] = '\0'; } } char* util_file_hash(const char *path) { FILE *in = fopen(path, "r"); if(!in) { return NULL; } DAV_SHA_CTX *sha = dav_hash_init(); char *buf = malloc(16384); size_t r; while((r = fread(buf, 1, 16384, in)) > 0) { dav_hash_update(sha, buf, r); } unsigned char hash[DAV_SHA256_DIGEST_LENGTH]; dav_hash_final(sha, hash); free(buf); fclose(in); return util_hexstr(hash, DAV_SHA256_DIGEST_LENGTH); }