v4k-git-backup/engine/split/fwk_data.c

352 lines
13 KiB
C

static
array(char) base64__decode(const char *in_, unsigned inlen) {
// from libtomcrypt
#define BASE64_ENCODE_OUT_SIZE(s) (((s) + 2) / 3 * 4)
#define BASE64_DECODE_OUT_SIZE(s) (((s)) / 4 * 3)
#if 1
unsigned long outlen = BASE64_DECODE_OUT_SIZE(inlen);
array(char) out_ = 0; array_resize(out_, outlen);
if( base64_decode((const unsigned char *)in_, (unsigned long)inlen, (unsigned char *)out_, &outlen) != CRYPT_OK ) {
array_free(out_);
return 0;
}
array_resize(out_, outlen);
return out_;
#else
unsigned outlen = BASE64_DECODE_OUT_SIZE(inlen);
array(char) out_ = 0; array_resize(out_, outlen);
// based on code by Jon Mayo - November 13, 2003 (PUBLIC DOMAIN)
uint_least32_t v;
unsigned ii, io, rem;
char *out = (char *)out_;
const unsigned char *in = (const unsigned char *)in_;
const uint8_t base64dec_tab[256]= {
255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,
255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,
255,255,255,255,255,255,255,255,255,255,255,255,255, 62,255,255,
52, 53, 54, 55, 56, 57, 58, 59, 60, 61,255,255,255, 0,255,255,
255, 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, 25,255,255,255,255, 63,
255, 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, 51,255,255,255,255,255,
255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,
255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,
255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,
255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,
255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,
255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,
255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,
255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,255,
};
for (io = 0, ii = 0,v = 0, rem = 0; ii < inlen; ii ++) {
unsigned char ch;
if (isspace(in[ii]))
continue;
if ((in[ii]=='=') || (!in[ii]))
break; /* stop at = or null character*/
ch = base64dec_tab[(unsigned char)in[ii]];
if (ch == 255)
break; /* stop at a parse error */
v = (v<<6) | ch;
rem += 6;
if (rem >= 8) {
rem -= 8;
if (io >= outlen)
return (array_free(out_), NULL); /* truncation is failure */
out[io ++] = (v >> rem) & 255;
}
}
if (rem >= 8) {
rem -= 8;
if (io >= outlen)
return (array_free(out_), NULL); /* truncation is failure */
out[io ++] = (v >> rem) & 255;
}
return (array_resize(out_, io), out_);
#endif
}
static array(json5) roots;
static array(char*) sources;
bool json_push(const char *source) {
char *source_rw = STRDUP(source);
json5 root = {0};
char *error = json5_parse(&root, source_rw, 0);
if( error ) {
FREE(source_rw);
return false;
} else {
array_push(sources, source_rw);
array_push(roots, root);
return true;
}
}
bool json_pop() {
if( array_count(roots) > 0 ) {
FREE(*array_back(sources));
array_pop(sources);
json5_free(array_back(roots));
array_pop(roots);
return true;
}
return false;
}
json5* json_node(const char *keypath) {
json5 *j = array_back(roots), *r = j;
for each_substring( keypath, "/[.]", key ) {
r = 0;
/**/ if( j->type == JSON5_ARRAY ) r = j = &j->array[atoi(key)];
else if( j->type == JSON5_OBJECT && isdigit(key[0]) )
for( int i = 0, seq = atoi(key); !r && i < j->count; ++i ) {
if( i == seq ) {
r = j = &j->nodes[i];
break;
}
}
else if( j->type == JSON5_OBJECT )
for( int i = 0; !r && i < j->count; ++i ) {
if( j->nodes[i].name && !strcmp(j->nodes[i].name, key) ) {
r = j = &j->nodes[i];
break;
}
}
if( !j ) break;
}
return r;
}
int (json_count)(const char *keypath) {
json5* j = json_node(keypath);
return j ? j->count : 0;
}
json_t *json_find(const char *type_keypath) {
char type = type_keypath[0];
const char *key = type_keypath+1;
json5 *j = json_node(key);
if( !j ) return NULL;
static __thread int slot = 0;
static __thread json_t buf[128] = {0};
slot = (slot+1) % 128;
json_t *v = &buf[slot];
v->i = j ? j->integer : 0;
if(type == 's' && (!v->p || j->type == JSON5_NULL)) v->s = ""; // if_null_string
if(type == 'f' && j && j->type == JSON5_INTEGER) v->f = j->integer;
return v;
}
json_t json_get(const char *type_keypath) {
char type = type_keypath[0];
const char *key = type_keypath+1;
json5 *j = json_node(key);
json_t v = {0};
v.i = j ? j->integer : 0;
if(type == 's' && (!v.p || j->type == JSON5_NULL)) v.s = ""; // if_null_string
if(type == 'f' && j && j->type == JSON5_INTEGER) v.f = j->integer;
return v;
}
const char *(json_key)(const char *keypath) {
json5 *j = json_node(keypath);
if( !j ) return "";
return j->name;
}
// xml impl
static __thread array(char *) xml_sources;
static __thread array(struct xml *) xml_docs;
int xml_push(const char *xml_source) {
if( xml_source ) {
char *src = STRDUP(xml_source), *error = 0;
for( struct xml *doc = xml_parse(src, 0, &error); doc && !error; ) {
array_push(xml_docs, doc);
array_push(xml_sources, src);
return 1;
}
if( error ) PRINTF("%s\n", error);
FREE(src);
}
return 0;
}
void xml_pop() {
if( array_count(xml_docs) ) {
xml_free( *array_back(xml_docs) );
array_pop(xml_docs);
FREE( *array_back(xml_sources) );
array_pop(xml_sources);
}
}
static void *xml_path(struct xml *node, char *path, int down) {
if( !path || !path[0] ) return node;
if( node ) {
char type = path[0];
if( type == '/' ) {
int sep = strcspn(++path, "/[@$");
if( !sep ) type = path[0];
else
if( 1 ) { // path[ sep ] ) {
char tag[32]; snprintf(tag, 32, "%.*s", sep, path);
// Find the first sibling with the given tag name (may be the same node)
struct xml *next = down ? xml_find_down(node, tag) : xml_find(node, tag);
return xml_path(next, &path[ sep ], 1);
}
}
if( type == '$' ) {
return (void*)( node->down ? xml_text( node->down ) : xml_tag( node ) );
}
if( type == '@' ) {
return (void*)xml_att(node, ++path);
}
if( type == '[' ) {
for( int i = 0, end = atoi(++path); i < end; ++i ) { node = xml_find_next(node, xml_tag(node)); if(!node) return NULL; }
while( isdigit(path[0]) ) ++path;
return xml_path(node, ++path, 1);
}
}
return NULL;
}
const char *(xml_string)(char *key) {
struct xml *node = xml_path(*array_back(xml_docs), key, 0);
if( !node ) return "(null)";
if( strchr(key, '@') ) return (const char *)node;
if( strchr(key, '$') ) return (const char *)node;
return "";
}
unsigned (xml_count)(char *key) {
struct xml *node = xml_path(*array_back(xml_docs), key, 0);
if( !node ) return 0;
const char *tag = xml_tag(node);
unsigned count = 1;
while( (node = xml_find_next(node, tag)) != 0) ++count;
return count;
}
array(char) (xml_blob)(char *key) { // base64 blob
struct xml *node = xml_path(*array_back(xml_docs), key, 0);
if( !node ) return 0;
if( !strchr(key, '$') ) return 0;
const char *data = (const char*)node;
array(char) out = base64__decode(data, strlen(data)); // either array of chars (ok) or null (error)
return out;
}
bool data_tests() {
// data tests (json5)
const char json5[] =
" /* json5 */ // comment\n"
" abc: 42.67, def: true, integer:0x100 \n"
" huge: 2.2239333e5, \n"
" hello: 'world /*comment in string*/ //again', \n"
" children : { a: 1, b: 2, c: 3 },\n"
" array: [+1,2,-3,4,5], \n"
" invalids : [ nan, NaN, -nan, -NaN, inf, Infinity, -inf, -Infinity ],";
if( json_push(json5) ) {
assert( json_float("/abc") == 42.67 );
assert( json_int("/def") == 1 );
assert( json_int("/integer") == 0x100 );
assert( json_float("/huge") > 2.22e5 );
assert( strlen(json_string("/hello")) == 35 );
assert( json_int("/children/a") == 1 );
assert( json_int("/children.b") == 2 );
assert( json_int("/children[c]") == 3 );
assert( json_int("/array[%d]", 2) == -3 );
assert( json_count("/invalids") == 8 );
assert( isnan(json_float("/invalids[0]")) );
assert( !json_find("/non_existing") );
assert( PRINTF("json5 tests OK\n") );
json_pop();
}
// data tests (xml)
const char *xml = // vfs_read("test1.xml");
"<!-- XML representation of a person record -->"
"<person created=\"2006-11-11T19:23\" modified=\"2006-12-31T23:59\">"
" <firstName>Robert</firstName>"
" <lastName>Smith</lastName>"
" <address type=\"home\">"
" <street>12345 Sixth Ave</street>"
" <city>Anytown</city>"
" <state>CA</state>"
" <postalCode>98765-4321</postalCode>"
" </address>"
"</person>";
if( xml_push(xml) ) {
assert( !strcmp("Robert", xml_string("/person/firstName/$")) );
assert( !strcmp("Smith", xml_string("/person/lastName/$")) );
assert( !strcmp("home", xml_string("/person/address/@type")) );
assert( PRINTF("xml tests OK\n") );
xml_pop();
}
return true;
}
// compression api
static struct zcompressor {
// id of compressor
unsigned enumerator;
// name of compressor
const char name1, *name4, *name;
// returns worst case compression estimation for selected flags
unsigned (*bounds)(unsigned bytes, unsigned flags);
// returns number of bytes written. 0 if error.
unsigned (*encode)(const void *in, unsigned inlen, void *out, unsigned outcap, unsigned flags);
// returns number of excess bytes that will be overwritten when decoding.
unsigned (*excess)(unsigned flags);
// returns number of bytes written. 0 if error.
unsigned (*decode)(const void *in, unsigned inlen, void *out, unsigned outcap);
} zlist[] = {
{ COMPRESS_RAW, '0', "raw", "raw", raw_bounds, raw_encode, raw_excess, raw_decode },
{ COMPRESS_PPP, 'p', "ppp", "ppp", ppp_bounds, ppp_encode, ppp_excess, ppp_decode },
{ COMPRESS_ULZ, 'u', "ulz", "ulz", ulz_bounds, ulz_encode, ulz_excess, ulz_decode },
{ COMPRESS_LZ4, '4', "lz4x", "lz4x", lz4x_bounds, lz4x_encode, lz4x_excess, lz4x_decode },
{ COMPRESS_CRUSH, 'c', "crsh", "crush", crush_bounds, crush_encode, crush_excess, crush_decode },
{ COMPRESS_DEFLATE, 'd', "defl", "deflate", deflate_bounds, deflate_encode, deflate_excess, deflate_decode },
{ COMPRESS_LZP1, '1', "lzp1", "lzp1", lzp1_bounds, lzp1_encode, lzp1_excess, lzp1_decode },
{ COMPRESS_LZMA, 'm', "lzma", "lzma", lzma_bounds, lzma_encode, lzma_excess, lzma_decode },
{ COMPRESS_BALZ, 'b', "balz", "balz", balz_bounds, balz_encode, balz_excess, balz_decode },
{ COMPRESS_LZW3, 'w', "lzw3", "lzrw3a", lzrw3a_bounds, lzrw3a_encode, lzrw3a_excess, lzrw3a_decode },
{ COMPRESS_LZSS, 's', "lzss", "lzss", lzss_bounds, lzss_encode, lzss_excess, lzss_decode },
{ COMPRESS_BCM, 'B', "bcm", "bcm", bcm_bounds, bcm_encode, bcm_excess, bcm_decode },
{ COMPRESS_ZLIB, 'z', "zlib", "zlib", deflate_bounds, deflatez_encode, deflate_excess, deflatez_decode },
};
enum { COMPRESS_NUM = 14 };
static char *znameof(unsigned flags) {
static __thread char buf[16];
snprintf(buf, 16, "%4s.%c", zlist[(flags>>4)&0x0F].name4, "0123456789ABCDEF"[flags&0xF]);
return buf;
}
unsigned zencode(void *out, unsigned outlen, const void *in, unsigned inlen, unsigned flags) {
return zlist[(flags >> 4) % COMPRESS_NUM].encode(in, inlen, (uint8_t*)out, outlen, flags & 0x0F);
}
unsigned zdecode(void *out, unsigned outlen, const void *in, unsigned inlen, unsigned flags) {
return zlist[(flags >> 4) % COMPRESS_NUM].decode((uint8_t*)in, inlen, out, outlen);
}
unsigned zbounds(unsigned inlen, unsigned flags) {
return zlist[(flags >> 4) % COMPRESS_NUM].bounds(inlen, flags & 0x0F);
}
unsigned zexcess(unsigned flags) {
return zlist[(flags >> 4) % COMPRESS_NUM].excess(flags & 0x0F);
}