/* * This file Copyright (C) 2008 Charles Kerr * * This file is licensed by the GPL version 2. Works owned by the * Transmission project are granted a special exemption to clause 2(b) * so that the bulk of its code can remain under the MIT license. * This exemption does not extend to derived works not owned by * the Transmission project. * * $Id$ */ #include #include /* isdigit, isprint, isspace */ #include #include #include #include #include #include /* evbuffer */ #include "ConvertUTF.h" #include "transmission.h" #include "bencode.h" #include "json.h" #include "list.h" #include "ptrarray.h" #include "utils.h" /* tr_new(), tr_free() */ /** *** **/ tr_bool tr_bencIsType( const tr_benc * val, int type ) { return ( val ) && ( val->type == type ); } static tr_bool isContainer( const tr_benc * val ) { return tr_bencIsList( val ) || tr_bencIsDict( val ); } static tr_bool isSomething( const tr_benc * val ) { return isContainer( val ) || tr_bencIsInt( val ) || tr_bencIsString( val ); } static void tr_bencInit( tr_benc * val, int type ) { memset( val, 0, sizeof( *val ) ); val->type = type; } /*** **** tr_bencParse() **** tr_bencLoad() ***/ /** * The initial i and trailing e are beginning and ending delimiters. * You can have negative numbers such as i-3e. You cannot prefix the * number with a zero such as i04e. However, i0e is valid. * Example: i3e represents the integer "3" * NOTE: The maximum number of bit of this integer is unspecified, * but to handle it as a signed 64bit integer is mandatory to handle * "large files" aka .torrent for more that 4Gbyte */ int tr_bencParseInt( const uint8_t * buf, const uint8_t * bufend, const uint8_t ** setme_end, int64_t * setme_val ) { int err = 0; char * endptr; const void * begin; const void * end; int64_t val; if( buf >= bufend ) return EILSEQ; if( *buf != 'i' ) return EILSEQ; begin = buf + 1; end = memchr( begin, 'e', ( bufend - buf ) - 1 ); if( end == NULL ) return EILSEQ; errno = 0; val = evutil_strtoll( begin, &endptr, 10 ); if( errno || ( endptr != end ) ) /* incomplete parse */ err = EILSEQ; else if( val && *(const char*)begin == '0' ) /* no leading zeroes! */ err = EILSEQ; else { *setme_end = (const uint8_t*)end + 1; *setme_val = val; } return err; } /** * Byte strings are encoded as follows: * : * Note that there is no constant beginning delimiter, and no ending delimiter. * Example: 4:spam represents the string "spam" */ int tr_bencParseStr( const uint8_t * buf, const uint8_t * bufend, const uint8_t ** setme_end, const uint8_t ** setme_str, size_t * setme_strlen ) { size_t len; const void * end; char * endptr; if( buf >= bufend ) return EILSEQ; if( !isdigit( *buf ) ) return EILSEQ; end = memchr( buf, ':', bufend - buf ); if( end == NULL ) return EILSEQ; errno = 0; len = strtoul( (const char*)buf, &endptr, 10 ); if( errno || endptr != end ) return EILSEQ; if( (const uint8_t*)end + 1 + len > bufend ) return EILSEQ; *setme_end = (const uint8_t*)end + 1 + len; *setme_str = (const uint8_t*)end + 1; *setme_strlen = len; return 0; } /* set to 1 to help expose bugs with tr_bencListAdd and tr_bencDictAdd */ #define LIST_SIZE 8 /* number of items to increment list/dict buffer by */ static int makeroom( tr_benc * val, size_t count ) { assert( TYPE_LIST == val->type || TYPE_DICT == val->type ); if( val->val.l.count + count > val->val.l.alloc ) { /* We need a bigger boat */ const int len = val->val.l.alloc + count + ( count % LIST_SIZE ? LIST_SIZE - ( count % LIST_SIZE ) : 0 ); void * new = realloc( val->val.l.vals, len * sizeof( tr_benc ) ); if( NULL == new ) return 1; val->val.l.alloc = len; val->val.l.vals = new; } return 0; } static tr_benc* getNode( tr_benc * top, tr_ptrArray * parentStack, int type ) { tr_benc * parent; assert( top ); assert( parentStack ); if( tr_ptrArrayEmpty( parentStack ) ) return top; parent = tr_ptrArrayBack( parentStack ); assert( parent ); /* dictionary keys must be strings */ if( ( parent->type == TYPE_DICT ) && ( type != TYPE_STR ) && ( !( parent->val.l.count % 2 ) ) ) return NULL; makeroom( parent, 1 ); return parent->val.l.vals + parent->val.l.count++; } /** * This function's previous recursive implementation was * easier to read, but was vulnerable to a smash-stacking * attack via maliciously-crafted bencoded data. (#667) */ static int tr_bencParseImpl( const void * buf_in, const void * bufend_in, tr_benc * top, tr_ptrArray * parentStack, const uint8_t ** setme_end ) { int err; const uint8_t * buf = buf_in; const uint8_t * bufend = bufend_in; tr_bencInit( top, 0 ); while( buf != bufend ) { if( buf > bufend ) /* no more text to parse... */ return 1; if( *buf == 'i' ) /* int */ { int64_t val; const uint8_t * end; tr_benc * node; if( ( err = tr_bencParseInt( buf, bufend, &end, &val ) ) ) return err; node = getNode( top, parentStack, TYPE_INT ); if( !node ) return EILSEQ; tr_bencInitInt( node, val ); buf = end; if( tr_ptrArrayEmpty( parentStack ) ) break; } else if( *buf == 'l' ) /* list */ { tr_benc * node = getNode( top, parentStack, TYPE_LIST ); if( !node ) return EILSEQ; tr_bencInit( node, TYPE_LIST ); tr_ptrArrayAppend( parentStack, node ); ++buf; } else if( *buf == 'd' ) /* dict */ { tr_benc * node = getNode( top, parentStack, TYPE_DICT ); if( !node ) return EILSEQ; tr_bencInit( node, TYPE_DICT ); tr_ptrArrayAppend( parentStack, node ); ++buf; } else if( *buf == 'e' ) /* end of list or dict */ { tr_benc * node; ++buf; if( tr_ptrArrayEmpty( parentStack ) ) return EILSEQ; node = tr_ptrArrayBack( parentStack ); if( tr_bencIsDict( node ) && ( node->val.l.count % 2 ) ) { /* odd # of children in dict */ tr_bencFree( &node->val.l.vals[--node->val.l.count] ); return EILSEQ; } tr_ptrArrayPop( parentStack ); if( tr_ptrArrayEmpty( parentStack ) ) break; } else if( isdigit( *buf ) ) /* string? */ { const uint8_t * end; const uint8_t * str; size_t str_len; tr_benc * node; if( ( err = tr_bencParseStr( buf, bufend, &end, &str, &str_len ) ) ) return err; node = getNode( top, parentStack, TYPE_STR ); if( !node ) return EILSEQ; tr_bencInitStr( node, str, str_len ); buf = end; if( tr_ptrArrayEmpty( parentStack ) ) break; } else /* invalid bencoded text... march past it */ { ++buf; } } err = !isSomething( top ) || !tr_ptrArrayEmpty( parentStack ); if( !err && setme_end ) *setme_end = buf; return err; } int tr_bencParse( const void * buf, const void * end, tr_benc * top, const uint8_t ** setme_end ) { int err; tr_ptrArray parentStack = TR_PTR_ARRAY_INIT; top->type = 0; /* set to `uninitialized' */ err = tr_bencParseImpl( buf, end, top, &parentStack, setme_end ); if( err ) tr_bencFree( top ); tr_ptrArrayDestruct( &parentStack, NULL ); return err; } int tr_bencLoad( const void * buf_in, size_t buflen, tr_benc * setme_benc, char ** setme_end ) { const uint8_t * buf = buf_in; const uint8_t * end; const int ret = tr_bencParse( buf, buf + buflen, setme_benc, &end ); if( !ret && setme_end ) *setme_end = (char*) end; return ret; } /*** **** ***/ static int dictIndexOf( const tr_benc * val, const char * key ) { if( tr_bencIsDict( val ) ) { size_t i; const size_t len = strlen( key ); for( i = 0; ( i + 1 ) < val->val.l.count; i += 2 ) { const tr_benc * child = val->val.l.vals + i; if( ( child->type == TYPE_STR ) && ( child->val.s.i == len ) && !memcmp( child->val.s.s, key, len ) ) return i; } } return -1; } tr_benc * tr_bencDictFind( tr_benc * val, const char * key ) { const int i = dictIndexOf( val, key ); return i < 0 ? NULL : &val->val.l.vals[i + 1]; } static tr_benc* tr_bencDictFindType( tr_benc * val, const char * key, int type ) { tr_benc * ret = tr_bencDictFind( val, key ); return ( ret && ( ret->type == type ) ) ? ret : NULL; } size_t tr_bencListSize( const tr_benc * list ) { return tr_bencIsList( list ) ? list->val.l.count : 0; } tr_benc* tr_bencListChild( tr_benc * val, size_t i ) { tr_benc * ret = NULL; if( tr_bencIsList( val ) && ( i < val->val.l.count ) ) ret = val->val.l.vals + i; return ret; } tr_bool tr_bencGetInt( const tr_benc * val, int64_t * setme ) { const int success = tr_bencIsInt( val ); if( success && setme ) *setme = val->val.i; return success; } tr_bool tr_bencGetStr( const tr_benc * val, const char ** setme ) { const int success = tr_bencIsString( val ); if( success ) *setme = val->val.s.s; return success; } tr_bool tr_bencDictFindInt( tr_benc * dict, const char * key, int64_t * setme ) { tr_bool found = FALSE; tr_benc * child = tr_bencDictFindType( dict, key, TYPE_INT ); if( child ) found = tr_bencGetInt( child, setme ); return found; } tr_bool tr_bencDictFindDouble( tr_benc * dict, const char * key, double * setme ) { const char * str; const tr_bool success = tr_bencDictFindStr( dict, key, &str ); if( success && setme ) *setme = strtod( str, NULL ); return success; } tr_bool tr_bencDictFindList( tr_benc * dict, const char * key, tr_benc ** setme ) { tr_bool found = FALSE; tr_benc * child = tr_bencDictFindType( dict, key, TYPE_LIST ); if( child ) { if( setme != NULL ) *setme = child; found = TRUE; } return found; } tr_bool tr_bencDictFindDict( tr_benc * dict, const char * key, tr_benc ** setme ) { tr_bool found = FALSE; tr_benc * child = tr_bencDictFindType( dict, key, TYPE_DICT ); if( child ) { if( setme != NULL ) *setme = child; found = TRUE; } return found; } tr_bool tr_bencDictFindStr( tr_benc * dict, const char * key, const char ** setme ) { tr_bool found = FALSE; tr_benc * child = tr_bencDictFindType( dict, key, TYPE_STR ); if( child ) { if( setme ) *setme = child->val.s.s; found = TRUE; } return found; } tr_bool tr_bencDictFindRaw( tr_benc * dict, const char * key, const uint8_t ** setme_raw, size_t * setme_len ) { tr_bool found = FALSE; tr_benc * child = tr_bencDictFindType( dict, key, TYPE_STR ); if( child ) { *setme_raw = (uint8_t*) child->val.s.s; *setme_len = child->val.s.i; found = TRUE; } return found; } /*** **** ***/ void tr_bencInitRaw( tr_benc * val, const void * src, size_t byteCount ) { tr_bencInit( val, TYPE_STR ); val->val.s.i = byteCount; val->val.s.s = tr_memdup( src, byteCount ); } void tr_bencInitStr( tr_benc * val, const void * str, int len ) { tr_bencInit( val, TYPE_STR ); val->val.s.s = tr_strndup( str, len ); if( val->val.s.s == NULL ) val->val.s.i = 0; else if( len < 0 ) val->val.s.i = strlen( val->val.s.s ); else val->val.s.i = len; } void tr_bencInitInt( tr_benc * val, int64_t num ) { tr_bencInit( val, TYPE_INT ); val->val.i = num; } int tr_bencInitList( tr_benc * val, size_t reserveCount ) { tr_bencInit( val, TYPE_LIST ); return tr_bencListReserve( val, reserveCount ); } int tr_bencListReserve( tr_benc * val, size_t count ) { assert( tr_bencIsList( val ) ); return makeroom( val, count ); } int tr_bencInitDict( tr_benc * val, size_t reserveCount ) { tr_bencInit( val, TYPE_DICT ); return tr_bencDictReserve( val, reserveCount ); } int tr_bencDictReserve( tr_benc * val, size_t reserveCount ) { assert( tr_bencIsDict( val ) ); return makeroom( val, reserveCount * 2 ); } tr_benc * tr_bencListAdd( tr_benc * list ) { tr_benc * item; assert( tr_bencIsList( list ) ); if( list->val.l.count == list->val.l.alloc ) tr_bencListReserve( list, LIST_SIZE ); assert( list->val.l.count < list->val.l.alloc ); item = &list->val.l.vals[list->val.l.count]; list->val.l.count++; tr_bencInit( item, TYPE_INT ); return item; } tr_benc * tr_bencListAddInt( tr_benc * list, int64_t val ) { tr_benc * node = tr_bencListAdd( list ); tr_bencInitInt( node, val ); return node; } tr_benc * tr_bencListAddStr( tr_benc * list, const char * val ) { tr_benc * node = tr_bencListAdd( list ); tr_bencInitStr( node, val, -1 ); return node; } tr_benc* tr_bencListAddList( tr_benc * list, size_t reserveCount ) { tr_benc * child = tr_bencListAdd( list ); tr_bencInitList( child, reserveCount ); return child; } tr_benc* tr_bencListAddDict( tr_benc * list, size_t reserveCount ) { tr_benc * child = tr_bencListAdd( list ); tr_bencInitDict( child, reserveCount ); return child; } tr_benc * tr_bencDictAdd( tr_benc * dict, const char * key ) { tr_benc * keyval, * itemval; assert( tr_bencIsDict( dict ) ); if( dict->val.l.count + 2 > dict->val.l.alloc ) makeroom( dict, 2 ); assert( dict->val.l.count + 2 <= dict->val.l.alloc ); keyval = dict->val.l.vals + dict->val.l.count++; tr_bencInitStr( keyval, key, -1 ); itemval = dict->val.l.vals + dict->val.l.count++; tr_bencInit( itemval, TYPE_INT ); return itemval; } tr_benc* tr_bencDictAddInt( tr_benc * dict, const char * key, int64_t val ) { tr_benc * child; /* see if it already exists, and if so, try to reuse it */ if(( child = tr_bencDictFind( dict, key ))) { if( !tr_bencIsInt( child ) ) { tr_bencDictRemove( dict, key ); child = NULL; } } /* if it doesn't exist, create it */ if( child == NULL ) child = tr_bencDictAdd( dict, key ); /* set it */ tr_bencInitInt( child, val ); return child; } tr_benc* tr_bencDictAddStr( tr_benc * dict, const char * key, const char * val ) { tr_benc * child; /* see if it already exists, and if so, try to reuse it */ if(( child = tr_bencDictFind( dict, key ))) { if( tr_bencIsString( child ) ) tr_free( child->val.s.s ); else { tr_bencDictRemove( dict, key ); child = NULL; } } /* if it doesn't exist, create it */ if( child == NULL ) child = tr_bencDictAdd( dict, key ); /* set it */ tr_bencInitStr( child, val, -1 ); return child; } tr_benc* tr_bencDictAddDouble( tr_benc * dict, const char * key, double d ) { char buf[128]; char * locale; /* the json spec requires a '.' decimal point regardless of locale */ locale = tr_strdup( setlocale ( LC_NUMERIC, NULL ) ); setlocale( LC_NUMERIC, "POSIX" ); tr_snprintf( buf, sizeof( buf ), "%f", d ); setlocale( LC_NUMERIC, locale ); tr_free( locale ); return tr_bencDictAddStr( dict, key, buf ); } tr_benc* tr_bencDictAddList( tr_benc * dict, const char * key, size_t reserveCount ) { tr_benc * child = tr_bencDictAdd( dict, key ); tr_bencInitList( child, reserveCount ); return child; } tr_benc* tr_bencDictAddDict( tr_benc * dict, const char * key, size_t reserveCount ) { tr_benc * child = tr_bencDictAdd( dict, key ); tr_bencInitDict( child, reserveCount ); return child; } tr_benc* tr_bencDictAddRaw( tr_benc * dict, const char * key, const void * src, size_t len ) { tr_benc * child = tr_bencDictAdd( dict, key ); tr_bencInitRaw( child, src, len ); return child; } int tr_bencDictRemove( tr_benc * dict, const char * key ) { int i = dictIndexOf( dict, key ); if( i >= 0 ) { const int n = dict->val.l.count; tr_bencFree( &dict->val.l.vals[i] ); tr_bencFree( &dict->val.l.vals[i + 1] ); if( i + 2 < n ) { dict->val.l.vals[i] = dict->val.l.vals[n - 2]; dict->val.l.vals[i + 1] = dict->val.l.vals[n - 1]; } dict->val.l.count -= 2; } return i >= 0; /* return true if found */ } /*** **** BENC WALKING ***/ struct KeyIndex { const char * key; int index; }; static int compareKeyIndex( const void * va, const void * vb ) { const struct KeyIndex * a = va; const struct KeyIndex * b = vb; return strcmp( a->key, b->key ); } struct SaveNode { const tr_benc * val; int valIsVisited; int childCount; int childIndex; int * children; }; static struct SaveNode* nodeNewDict( const tr_benc * val ) { int i, j; int nKeys; struct SaveNode * node; struct KeyIndex * indices; assert( tr_bencIsDict( val ) ); nKeys = val->val.l.count / 2; node = tr_new0( struct SaveNode, 1 ); node->val = val; node->children = tr_new0( int, nKeys * 2 ); /* ugh, a dictionary's children have to be sorted by key... */ indices = tr_new( struct KeyIndex, nKeys ); for( i = j = 0; i < ( nKeys * 2 ); i += 2, ++j ) { indices[j].key = val->val.l.vals[i].val.s.s; indices[j].index = i; } qsort( indices, j, sizeof( struct KeyIndex ), compareKeyIndex ); for( i = 0; i < j; ++i ) { const int index = indices[i].index; node->children[node->childCount++] = index; node->children[node->childCount++] = index + 1; } assert( node->childCount == nKeys * 2 ); tr_free( indices ); return node; } static struct SaveNode* nodeNewList( const tr_benc * val ) { int i, n; struct SaveNode * node; assert( tr_bencIsList( val ) ); n = val->val.l.count; node = tr_new0( struct SaveNode, 1 ); node->val = val; node->childCount = n; node->children = tr_new0( int, n ); for( i = 0; i < n; ++i ) /* a list's children don't need to be reordered */ node->children[i] = i; return node; } static struct SaveNode* nodeNewLeaf( const tr_benc * val ) { struct SaveNode * node; assert( !isContainer( val ) ); node = tr_new0( struct SaveNode, 1 ); node->val = val; return node; } static struct SaveNode* nodeNew( const tr_benc * val ) { struct SaveNode * node; if( tr_bencIsList( val ) ) node = nodeNewList( val ); else if( tr_bencIsDict( val ) ) node = nodeNewDict( val ); else node = nodeNewLeaf( val ); return node; } typedef void ( *BencWalkFunc )( const tr_benc * val, void * user_data ); struct WalkFuncs { BencWalkFunc intFunc; BencWalkFunc stringFunc; BencWalkFunc dictBeginFunc; BencWalkFunc listBeginFunc; BencWalkFunc containerEndFunc; }; /** * This function's previous recursive implementation was * easier to read, but was vulnerable to a smash-stacking * attack via maliciously-crafted bencoded data. (#667) */ static void bencWalk( const tr_benc * top, struct WalkFuncs * walkFuncs, void * user_data ) { tr_ptrArray stack = TR_PTR_ARRAY_INIT; tr_ptrArrayAppend( &stack, nodeNew( top ) ); while( !tr_ptrArrayEmpty( &stack ) ) { struct SaveNode * node = tr_ptrArrayBack( &stack ); const tr_benc * val; if( !node->valIsVisited ) { val = node->val; node->valIsVisited = TRUE; } else if( node->childIndex < node->childCount ) { const int index = node->children[node->childIndex++]; val = node->val->val.l.vals + index; } else /* done with this node */ { if( isContainer( node->val ) ) walkFuncs->containerEndFunc( node->val, user_data ); tr_ptrArrayPop( &stack ); tr_free( node->children ); tr_free( node ); continue; } if( val ) switch( val->type ) { case TYPE_INT: walkFuncs->intFunc( val, user_data ); break; case TYPE_STR: walkFuncs->stringFunc( val, user_data ); break; case TYPE_LIST: if( val != node->val ) tr_ptrArrayAppend( &stack, nodeNew( val ) ); else walkFuncs->listBeginFunc( val, user_data ); break; case TYPE_DICT: if( val != node->val ) tr_ptrArrayAppend( &stack, nodeNew( val ) ); else walkFuncs->dictBeginFunc( val, user_data ); break; default: /* did caller give us an uninitialized val? */ tr_err( _( "Invalid metadata" ) ); break; } } tr_ptrArrayDestruct( &stack, NULL ); } /**** ***** ****/ static void saveIntFunc( const tr_benc * val, void * evbuf ) { evbuffer_add_printf( evbuf, "i%" PRId64 "e", val->val.i ); } static void saveStringFunc( const tr_benc * val, void * vevbuf ) { struct evbuffer * evbuf = vevbuf; evbuffer_add_printf( evbuf, "%lu:", (unsigned long)val->val.s.i ); evbuffer_add( evbuf, val->val.s.s, val->val.s.i ); } static void saveDictBeginFunc( const tr_benc * val UNUSED, void * evbuf ) { evbuffer_add_printf( evbuf, "d" ); } static void saveListBeginFunc( const tr_benc * val UNUSED, void * evbuf ) { evbuffer_add_printf( evbuf, "l" ); } static void saveContainerEndFunc( const tr_benc * val UNUSED, void * evbuf ) { evbuffer_add_printf( evbuf, "e" ); } char* tr_bencSave( const tr_benc * top, int * len ) { char * ret; struct WalkFuncs walkFuncs; struct evbuffer * out = tr_getBuffer( ); walkFuncs.intFunc = saveIntFunc; walkFuncs.stringFunc = saveStringFunc; walkFuncs.dictBeginFunc = saveDictBeginFunc; walkFuncs.listBeginFunc = saveListBeginFunc; walkFuncs.containerEndFunc = saveContainerEndFunc; bencWalk( top, &walkFuncs, out ); if( len ) *len = EVBUFFER_LENGTH( out ); ret = tr_strndup( EVBUFFER_DATA( out ), EVBUFFER_LENGTH( out ) ); tr_releaseBuffer( out ); return ret; } /*** **** ***/ static void freeDummyFunc( const tr_benc * val UNUSED, void * buf UNUSED ) {} static void freeStringFunc( const tr_benc * val, void * freeme ) { tr_ptrArrayAppend( freeme, val->val.s.s ); } static void freeContainerBeginFunc( const tr_benc * val, void * freeme ) { tr_ptrArrayAppend( freeme, val->val.l.vals ); } void tr_bencFree( tr_benc * val ) { if( val && val->type ) { tr_ptrArray a = TR_PTR_ARRAY_INIT; struct WalkFuncs walkFuncs; walkFuncs.intFunc = freeDummyFunc; walkFuncs.stringFunc = freeStringFunc; walkFuncs.dictBeginFunc = freeContainerBeginFunc; walkFuncs.listBeginFunc = freeContainerBeginFunc; walkFuncs.containerEndFunc = freeDummyFunc; bencWalk( val, &walkFuncs, &a ); tr_ptrArrayDestruct( &a, tr_free ); } } /*** **** ***/ struct ParentState { int bencType; int childIndex; int childCount; }; struct jsonWalk { tr_list * parents; struct evbuffer * out; }; static void jsonIndent( struct jsonWalk * data ) { const int width = tr_list_size( data->parents ) * 4; evbuffer_add_printf( data->out, "\n%*.*s", width, width, " " ); } static void jsonChildFunc( struct jsonWalk * data ) { if( data->parents ) { struct ParentState * parentState = data->parents->data; switch( parentState->bencType ) { case TYPE_DICT: { const int i = parentState->childIndex++; if( !( i % 2 ) ) evbuffer_add_printf( data->out, ": " ); else { evbuffer_add_printf( data->out, ", " ); jsonIndent( data ); } break; } case TYPE_LIST: { ++parentState->childIndex; evbuffer_add_printf( data->out, ", " ); jsonIndent( data ); break; } default: break; } } } static void jsonPushParent( struct jsonWalk * data, const tr_benc * benc ) { struct ParentState * parentState = tr_new( struct ParentState, 1 ); parentState->bencType = benc->type; parentState->childIndex = 0; parentState->childCount = benc->val.l.count; tr_list_prepend( &data->parents, parentState ); } static void jsonPopParent( struct jsonWalk * data ) { tr_free( tr_list_pop_front( &data->parents ) ); } static void jsonIntFunc( const tr_benc * val, void * vdata ) { struct jsonWalk * data = vdata; evbuffer_add_printf( data->out, "%" PRId64, val->val.i ); jsonChildFunc( data ); } static void jsonStringFunc( const tr_benc * val, void * vdata ) { struct jsonWalk * data = vdata; const unsigned char *it, *end; evbuffer_add_printf( data->out, "\"" ); for( it = (const unsigned char*)val->val.s.s, end = it + val->val.s.i; it != end; ++it ) { switch( *it ) { case '/': evbuffer_add_printf( data->out, "\\/" ); break; case '\b': evbuffer_add_printf( data->out, "\\b" ); break; case '\f': evbuffer_add_printf( data->out, "\\f" ); break; case '\n': evbuffer_add_printf( data->out, "\\n" ); break; case '\r': evbuffer_add_printf( data->out, "\\r" ); break; case '\t': evbuffer_add_printf( data->out, "\\t" ); break; case '"': evbuffer_add_printf( data->out, "\\\"" ); break; case '\\': evbuffer_add_printf( data->out, "\\\\" ); break; default: if( isascii( *it ) ) { /*fprintf( stderr, "[%c]\n", *it );*/ evbuffer_add_printf( data->out, "%c", *it ); } else { const UTF8 * tmp = it; UTF32 buf = 0; UTF32 * u32 = &buf; ConversionResult result = ConvertUTF8toUTF32( &tmp, end, &u32, &buf + 1, 0 ); if( ( result != conversionOK ) && ( tmp == it ) ) ++it; /* it's beyond help; skip it */ else { evbuffer_add_printf( data->out, "\\u%04x", buf ); it = tmp - 1; } /*fprintf( stderr, "[\\u%04x]\n", buf );*/ } } } evbuffer_add_printf( data->out, "\"" ); jsonChildFunc( data ); } static void jsonDictBeginFunc( const tr_benc * val, void * vdata ) { struct jsonWalk * data = vdata; jsonPushParent( data, val ); evbuffer_add_printf( data->out, "{" ); if( val->val.l.count ) jsonIndent( data ); } static void jsonListBeginFunc( const tr_benc * val, void * vdata ) { const size_t nChildren = tr_bencListSize( val ); struct jsonWalk * data = vdata; jsonPushParent( data, val ); evbuffer_add_printf( data->out, "[" ); if( nChildren ) jsonIndent( data ); } static void jsonContainerEndFunc( const tr_benc * val, void * vdata ) { size_t i; struct jsonWalk * data = vdata; char * str; int emptyContainer = FALSE; /* trim out the trailing comma, if any */ str = (char*) EVBUFFER_DATA( data->out ); for( i = EVBUFFER_LENGTH( data->out ) - 1; i > 0; --i ) { if( isspace( str[i] ) ) continue; if( str[i] == ',' ) EVBUFFER_LENGTH( data->out ) = i; if( str[i] == '{' || str[i] == '[' ) emptyContainer = TRUE; break; } jsonPopParent( data ); if( !emptyContainer ) jsonIndent( data ); if( tr_bencIsDict( val ) ) evbuffer_add_printf( data->out, "}" ); else /* list */ evbuffer_add_printf( data->out, "]" ); jsonChildFunc( data ); } char* tr_bencSaveAsJSON( const tr_benc * top, struct evbuffer * out ) { struct WalkFuncs walkFuncs; struct jsonWalk data; evbuffer_drain( out, EVBUFFER_LENGTH( out ) ); data.out = out; data.parents = NULL; walkFuncs.intFunc = jsonIntFunc; walkFuncs.stringFunc = jsonStringFunc; walkFuncs.dictBeginFunc = jsonDictBeginFunc; walkFuncs.listBeginFunc = jsonListBeginFunc; walkFuncs.containerEndFunc = jsonContainerEndFunc; bencWalk( top, &walkFuncs, &data ); if( EVBUFFER_LENGTH( out ) ) evbuffer_add_printf( out, "\n" ); return (char*) EVBUFFER_DATA( out ); } /*** **** ***/ static size_t tr_bencDictSize( const tr_benc * dict ) { size_t count = 0; if( tr_bencIsDict( dict ) ) count = dict->val.l.count / 2; return count; } static tr_bool tr_bencDictChild( const tr_benc * dict, size_t n, const char ** key, const tr_benc ** val ) { tr_bool success = 0; assert( tr_bencIsDict( dict ) ); if( tr_bencIsDict( dict ) && (n*2)+1 <= dict->val.l.count ) { tr_benc * k = dict->val.l.vals + (n*2); tr_benc * v = dict->val.l.vals + (n*2) + 1; if(( success = tr_bencGetStr( k, key ) && isSomething( v ))) *val = v; } return success; } void tr_bencMergeDicts( tr_benc * target, const tr_benc * source ) { size_t i; const size_t sourceCount = tr_bencDictSize( source ); assert( tr_bencIsDict( target ) ); assert( tr_bencIsDict( source ) ); for( i=0; i