// This file is part of OpenCV project. // It is subject to the license terms in the LICENSE file found in the top-level directory // of this distribution and at http://opencv.org/license.html #include "precomp.hpp" #include "persistence.hpp" #include "persistence_impl.hpp" #include "persistence_base64_encoding.hpp" #include #include #include namespace cv { namespace fs { int strcasecmp(const char* s1, const char* s2) { const char* dummy=""; if(!s1) s1=dummy; if(!s2) s2=dummy; size_t len1 = strlen(s1); size_t len2 = strlen(s2); size_t i, len = std::min(len1, len2); for( i = 0; i < len; i++ ) { int d = tolower((int)s1[i]) - tolower((int)s2[i]); if( d != 0 ) return d; } return len1 < len2 ? -1 : len1 > len2 ? 1 : 0; } char* itoa( int _val, char* buffer, int /*radix*/ ) { const int radix = 10; char* ptr=buffer + 23 /* enough even for 64-bit integers */; unsigned val = abs(_val); *ptr = '\0'; do { unsigned r = val / radix; *--ptr = (char)(val - (r*radix) + '0'); val = r; } while( val != 0 ); if( _val < 0 ) *--ptr = '-'; return ptr; } char* doubleToString( char* buf, double value, bool explicitZero ) { Cv64suf val; unsigned ieee754_hi; val.f = value; ieee754_hi = (unsigned)(val.u >> 32); if( (ieee754_hi & 0x7ff00000) != 0x7ff00000 ) { int ivalue = cvRound(value); if( ivalue == value ) { if( explicitZero ) sprintf( buf, "%d.0", ivalue ); else sprintf( buf, "%d.", ivalue ); } else { static const char* fmt = "%.16e"; char* ptr = buf; sprintf( buf, fmt, value ); if( *ptr == '+' || *ptr == '-' ) ptr++; for( ; cv_isdigit(*ptr); ptr++ ) ; if( *ptr == ',' ) *ptr = '.'; } } else { unsigned ieee754_lo = (unsigned)val.u; if( (ieee754_hi & 0x7fffffff) + (ieee754_lo != 0) > 0x7ff00000 ) strcpy( buf, ".Nan" ); else strcpy( buf, (int)ieee754_hi < 0 ? "-.Inf" : ".Inf" ); } return buf; } char* floatToString( char* buf, float value, bool halfprecision, bool explicitZero ) { Cv32suf val; unsigned ieee754; val.f = value; ieee754 = val.u; if( (ieee754 & 0x7f800000) != 0x7f800000 ) { int ivalue = cvRound(value); if( ivalue == value ) { if( explicitZero ) sprintf( buf, "%d.0", ivalue ); else sprintf( buf, "%d.", ivalue ); } else { char* ptr = buf; if (halfprecision) sprintf(buf, "%.4e", value); else sprintf(buf, "%.8e", value); if( *ptr == '+' || *ptr == '-' ) ptr++; for( ; cv_isdigit(*ptr); ptr++ ) ; if( *ptr == ',' ) *ptr = '.'; } } else { if( (ieee754 & 0x7fffffff) != 0x7f800000 ) strcpy( buf, ".Nan" ); else strcpy( buf, (int)ieee754 < 0 ? "-.Inf" : ".Inf" ); } return buf; } static const char symbols[9] = "ucwsifdh"; static char typeSymbol(int depth) { CV_StaticAssert(CV_64F == 6, ""); CV_CheckDepth(depth, depth >=0 && depth <= CV_16F, ""); return symbols[depth]; } static int symbolToType(char c) { if (c == 'r') return CV_SEQ_ELTYPE_PTR; const char* pos = strchr( symbols, c ); if( !pos ) CV_Error( cv::Error::StsBadArg, "Invalid data type specification" ); return static_cast(pos - symbols); } char* encodeFormat(int elem_type, char* dt) { int cn = (elem_type == CV_SEQ_ELTYPE_PTR/*CV_USRTYPE1*/) ? 1 : CV_MAT_CN(elem_type); char symbol = (elem_type == CV_SEQ_ELTYPE_PTR/*CV_USRTYPE1*/) ? 'r' : typeSymbol(CV_MAT_DEPTH(elem_type)); sprintf(dt, "%d%c", cn, symbol); return dt + (cn == 1 ? 1 : 0); } int decodeFormat( const char* dt, int* fmt_pairs, int max_len ) { int fmt_pair_count = 0; int i = 0, k = 0, len = dt ? (int)strlen(dt) : 0; if( !dt || !len ) return 0; CV_Assert( fmt_pairs != 0 && max_len > 0 ); fmt_pairs[0] = 0; max_len *= 2; for( ; k < len; k++ ) { char c = dt[k]; if( cv_isdigit(c) ) { int count = c - '0'; if( cv_isdigit(dt[k+1]) ) { char* endptr = 0; count = (int)strtol( dt+k, &endptr, 10 ); k = (int)(endptr - dt) - 1; } if( count <= 0 ) CV_Error( cv::Error::StsBadArg, "Invalid data type specification" ); fmt_pairs[i] = count; } else { int depth = symbolToType(c); if( fmt_pairs[i] == 0 ) fmt_pairs[i] = 1; fmt_pairs[i+1] = depth; if( i > 0 && fmt_pairs[i+1] == fmt_pairs[i-1] ) fmt_pairs[i-2] += fmt_pairs[i]; else { i += 2; if( i >= max_len ) CV_Error( cv::Error::StsBadArg, "Too long data type specification" ); } fmt_pairs[i] = 0; } } fmt_pair_count = i/2; return fmt_pair_count; } int calcElemSize( const char* dt, int initial_size ) { int size = 0; int fmt_pairs[CV_FS_MAX_FMT_PAIRS], i, fmt_pair_count; int comp_size; fmt_pair_count = decodeFormat( dt, fmt_pairs, CV_FS_MAX_FMT_PAIRS ); fmt_pair_count *= 2; for( i = 0, size = initial_size; i < fmt_pair_count; i += 2 ) { comp_size = CV_ELEM_SIZE(fmt_pairs[i+1]); size = cvAlign( size, comp_size ); size += comp_size * fmt_pairs[i]; } if( initial_size == 0 ) { comp_size = CV_ELEM_SIZE(fmt_pairs[1]); size = cvAlign( size, comp_size ); } return size; } int calcStructSize( const char* dt, int initial_size ) { int size = calcElemSize( dt, initial_size ); size_t elem_max_size = 0; for ( const char * type = dt; *type != '\0'; type++ ) { char v = *type; if (v >= '0' && v <= '9') continue; // skip vector size switch (v) { case 'u': { elem_max_size = std::max( elem_max_size, sizeof(uchar ) ); break; } case 'c': { elem_max_size = std::max( elem_max_size, sizeof(schar ) ); break; } case 'w': { elem_max_size = std::max( elem_max_size, sizeof(ushort) ); break; } case 's': { elem_max_size = std::max( elem_max_size, sizeof(short ) ); break; } case 'i': { elem_max_size = std::max( elem_max_size, sizeof(int ) ); break; } case 'f': { elem_max_size = std::max( elem_max_size, sizeof(float ) ); break; } case 'd': { elem_max_size = std::max( elem_max_size, sizeof(double) ); break; } case 'h': { elem_max_size = std::max(elem_max_size, sizeof(float16_t)); break; } default: CV_Error_(Error::StsNotImplemented, ("Unknown type identifier: '%c' in '%s'", (char)(*type), dt)); } } size = cvAlign( size, static_cast(elem_max_size) ); return size; } int decodeSimpleFormat( const char* dt ) { int elem_type = -1; int fmt_pairs[CV_FS_MAX_FMT_PAIRS], fmt_pair_count; fmt_pair_count = decodeFormat( dt, fmt_pairs, CV_FS_MAX_FMT_PAIRS ); if( fmt_pair_count != 1 || fmt_pairs[0] >= CV_CN_MAX) CV_Error( cv::Error::StsError, "Too complex format for the matrix" ); elem_type = CV_MAKETYPE( fmt_pairs[1], fmt_pairs[0] ); return elem_type; } } #if defined __i386__ || defined(_M_IX86) || defined __x86_64__ || defined(_M_X64) #define CV_UNALIGNED_LITTLE_ENDIAN_MEM_ACCESS 1 #else #define CV_UNALIGNED_LITTLE_ENDIAN_MEM_ACCESS 0 #endif static inline int readInt(const uchar* p) { #if CV_UNALIGNED_LITTLE_ENDIAN_MEM_ACCESS return *(const int*)p; #else int val = (int)(p[0] | (p[1] << 8) | (p[2] << 16) | (p[3] << 24)); return val; #endif } static inline double readReal(const uchar* p) { #if CV_UNALIGNED_LITTLE_ENDIAN_MEM_ACCESS return *(const double*)p; #else unsigned val0 = (unsigned)(p[0] | (p[1] << 8) | (p[2] << 16) | (p[3] << 24)); unsigned val1 = (unsigned)(p[4] | (p[5] << 8) | (p[6] << 16) | (p[7] << 24)); Cv64suf val; val.u = val0 | ((uint64)val1 << 32); return val.f; #endif } static inline void writeInt(uchar* p, int ival) { #if CV_UNALIGNED_LITTLE_ENDIAN_MEM_ACCESS int* ip = (int*)p; *ip = ival; #else p[0] = (uchar)ival; p[1] = (uchar)(ival >> 8); p[2] = (uchar)(ival >> 16); p[3] = (uchar)(ival >> 24); #endif } static inline void writeReal(uchar* p, double fval) { #if CV_UNALIGNED_LITTLE_ENDIAN_MEM_ACCESS double* fp = (double*)p; *fp = fval; #else Cv64suf v; v.f = fval; p[0] = (uchar)v.u; p[1] = (uchar)(v.u >> 8); p[2] = (uchar)(v.u >> 16); p[3] = (uchar)(v.u >> 24); p[4] = (uchar)(v.u >> 32); p[5] = (uchar)(v.u >> 40); p[6] = (uchar)(v.u >> 48); p[7] = (uchar)(v.u >> 56); #endif } void FileStorage::Impl::init() { flags = 0; buffer.clear(); bufofs = 0; state = UNDEFINED; is_using_base64 = false; state_of_writing_base64 = FileStorage_API::Base64State::Uncertain; is_write_struct_delayed = false; delayed_struct_key = nullptr; delayed_struct_flags = 0; delayed_type_name = nullptr; base64_writer = nullptr; is_opened = false; dummy_eof = false; write_mode = false; mem_mode = false; space = 0; wrap_margin = 71; fmt = 0; file = 0; gzfile = 0; empty_stream = true; strbufv.clear(); strbuf = 0; strbufsize = strbufpos = 0; roots.clear(); fs_data.clear(); fs_data_ptrs.clear(); fs_data_blksz.clear(); freeSpaceOfs = 0; str_hash.clear(); str_hash_data.clear(); str_hash_data.resize(1); str_hash_data[0] = '\0'; filename.clear(); lineno = 0; } FileStorage::Impl::Impl(FileStorage *_fs) { fs_ext = _fs; init(); } FileStorage::Impl::~Impl() { release(); } void FileStorage::Impl::release(String *out) { if (is_opened) { if (out) out->clear(); if (write_mode) { while (write_stack.size() > 1) { endWriteStruct(); } flush(); if (fmt == FileStorage::FORMAT_XML) puts("\n"); else if (fmt == FileStorage::FORMAT_JSON) puts("}\n"); } if (mem_mode && out) { *out = cv::String(outbuf.begin(), outbuf.end()); } } closeFile(); init(); } void FileStorage::Impl::analyze_file_name(const std::string &file_name, std::vector ¶ms) { params.clear(); static const char not_file_name = '\n'; static const char parameter_begin = '?'; static const char parameter_separator = '&'; if (file_name.find(not_file_name, (size_t) 0) != std::string::npos) return; size_t beg = file_name.find_last_of(parameter_begin); params.push_back(file_name.substr((size_t) 0, beg)); if (beg != std::string::npos) { size_t end = file_name.size(); beg++; for (size_t param_beg = beg, param_end = beg; param_end < end; param_beg = param_end + 1) { param_end = file_name.find_first_of(parameter_separator, param_beg); if ((param_end == std::string::npos || param_end != param_beg) && param_beg + 1 < end) { params.push_back(file_name.substr(param_beg, param_end - param_beg)); } } } } bool FileStorage::Impl::open(const char *filename_or_buf, int _flags, const char *encoding) { bool ok = true; release(); bool append = (_flags & 3) == FileStorage::APPEND; mem_mode = (_flags & FileStorage::MEMORY) != 0; write_mode = (_flags & 3) != 0; bool write_base64 = (write_mode || append) && (_flags & FileStorage::BASE64) != 0; bool isGZ = false; size_t fnamelen = 0; std::vector params; //if ( !mem_mode ) { analyze_file_name(filename_or_buf, params); if (!params.empty()) filename = params[0]; if (!write_base64 && params.size() >= 2 && std::find(params.begin() + 1, params.end(), std::string("base64")) != params.end()) write_base64 = (write_mode || append); } if (filename.size() == 0 && !mem_mode && !write_mode) CV_Error(cv::Error::StsNullPtr, "NULL or empty filename"); if (mem_mode && append) CV_Error(cv::Error::StsBadFlag, "FileStorage::APPEND and FileStorage::MEMORY are not currently compatible"); flags = _flags; if (!mem_mode) { char *dot_pos = strrchr((char *) filename.c_str(), '.'); char compression = '\0'; if (dot_pos && dot_pos[1] == 'g' && dot_pos[2] == 'z' && (dot_pos[3] == '\0' || (cv_isdigit(dot_pos[3]) && dot_pos[4] == '\0'))) { if (append) { CV_Error(cv::Error::StsNotImplemented, "Appending data to compressed file is not implemented"); } isGZ = true; compression = dot_pos[3]; if (compression) dot_pos[3] = '\0', fnamelen--; } if (!isGZ) { file = fopen(filename.c_str(), !write_mode ? "rt" : !append ? "wt" : "a+t"); if (!file) { CV_LOG_ERROR(NULL, "Can't open file: '" << filename << "' in " << (!write_mode ? "read" : !append ? "write" : "append") << " mode"); return false; } } else { #if USE_ZLIB char mode[] = {write_mode ? 'w' : 'r', 'b', compression ? compression : '3', '\0'}; gzfile = gzopen(filename.c_str(), mode); if (!gzfile) { CV_LOG_ERROR(NULL, "Can't open archive: '" << filename << "' mode=" << mode); return false; } #else CV_Error(cv::Error::StsNotImplemented, "There is no compressed file storage support in this configuration"); #endif } } // FIXIT release() must do that, use CV_Assert() here instead roots.clear(); fs_data.clear(); wrap_margin = 71; fmt = FileStorage::FORMAT_AUTO; if (write_mode) { fmt = flags & FileStorage::FORMAT_MASK; if (mem_mode) outbuf.clear(); if (fmt == FileStorage::FORMAT_AUTO && !filename.empty()) { const char *dot_pos = NULL; const char *dot_pos2 = NULL; // like strrchr() implementation, but save two last positions simultaneously for (const char *pos = &filename[0]; pos[0] != 0; pos++) { if (pos[0] == '.') { dot_pos2 = dot_pos; dot_pos = pos; } } if (fs::strcasecmp(dot_pos, ".gz") == 0 && dot_pos2 != NULL) { dot_pos = dot_pos2; } fmt = (fs::strcasecmp(dot_pos, ".xml") == 0 || fs::strcasecmp(dot_pos, ".xml.gz") == 0) ? FileStorage::FORMAT_XML : (fs::strcasecmp(dot_pos, ".json") == 0 || fs::strcasecmp(dot_pos, ".json.gz") == 0) ? FileStorage::FORMAT_JSON : FileStorage::FORMAT_YAML; } else if (fmt == FileStorage::FORMAT_AUTO) { fmt = FileStorage::FORMAT_XML; } // we use factor=6 for XML (the longest characters (' and ") are encoded with 6 bytes (' and ") // and factor=4 for YAML ( as we use 4 bytes for non ASCII characters (e.g. \xAB)) int buf_size = CV_FS_MAX_LEN * (fmt == FileStorage::FORMAT_XML ? 6 : 4) + 1024; if (append) { fseek(file, 0, SEEK_END); if (ftell(file) == 0) append = false; } write_stack.clear(); empty_stream = true; write_stack.push_back(FStructData("", FileNode::MAP | FileNode::EMPTY, 0)); buffer.reserve(buf_size + 1024); buffer.resize(buf_size); bufofs = 0; is_using_base64 = write_base64; state_of_writing_base64 = FileStorage_API::Base64State::Uncertain; if (fmt == FileStorage::FORMAT_XML) { size_t file_size = file ? (size_t) ftell(file) : (size_t) 0; if (!append || file_size == 0) { if (encoding && *encoding != '\0') { if (fs::strcasecmp(encoding, "UTF-16") == 0) { release(); CV_Error(cv::Error::StsBadArg, "UTF-16 XML encoding is not supported! Use 8-bit encoding\n"); } CV_Assert(strlen(encoding) < 1000); char buf[1100]; sprintf(buf, "\n", encoding); puts(buf); } else puts("\n"); puts("\n"); } else { int xml_buf_size = 1 << 10; char substr[] = ""; int last_occurrence = -1; xml_buf_size = MIN(xml_buf_size, int(file_size)); fseek(file, -xml_buf_size, SEEK_END); // find the last occurrence of for (;;) { int line_offset = (int) ftell(file); const char *ptr0 = this->gets(xml_buf_size); const char *ptr = NULL; if (!ptr0) break; ptr = ptr0; for (;;) { ptr = strstr(ptr, substr); if (!ptr) break; last_occurrence = line_offset + (int) (ptr - ptr0); ptr += strlen(substr); } } if (last_occurrence < 0) { release(); CV_Error(cv::Error::StsError, "Could not find in the end of file.\n"); } closeFile(); file = fopen(filename.c_str(), "r+t"); CV_Assert(file != 0); fseek(file, last_occurrence, SEEK_SET); // replace the last "" with " ", which has the same length puts(" "); fseek(file, 0, SEEK_END); puts("\n"); } emitter_do_not_use_direct_dereference = createXMLEmitter(this); } else if (fmt == FileStorage::FORMAT_YAML) { if (!append) puts("%YAML:1.0\n---\n"); else puts("...\n---\n"); emitter_do_not_use_direct_dereference = createYAMLEmitter(this); } else { CV_Assert(fmt == FileStorage::FORMAT_JSON); if (!append) puts("{\n"); else { bool valid = false; long roffset = 0; for (; fseek(file, roffset, SEEK_END) == 0; roffset -= 1) { const char end_mark = '}'; if (fgetc(file) == end_mark) { fseek(file, roffset, SEEK_END); valid = true; break; } } if (valid) { closeFile(); file = fopen(filename.c_str(), "r+t"); CV_Assert(file != 0); fseek(file, roffset, SEEK_END); fputs(",", file); } else { CV_Error(cv::Error::StsError, "Could not find '}' in the end of file.\n"); } } write_stack.back().indent = 4; emitter_do_not_use_direct_dereference = createJSONEmitter(this); } is_opened = true; } else { const size_t buf_size0 = 40; buffer.resize(buf_size0); if (mem_mode) { strbuf = (char *) filename_or_buf; strbufsize = strlen(strbuf); } const char *yaml_signature = "%YAML"; const char *json_signature = "{"; const char *xml_signature = "gets(16); CV_Assert(buf); char *bufPtr = cv_skip_BOM(buf); size_t bufOffset = bufPtr - buf; if (strncmp(bufPtr, yaml_signature, strlen(yaml_signature)) == 0) fmt = FileStorage::FORMAT_YAML; else if (strncmp(bufPtr, json_signature, strlen(json_signature)) == 0) fmt = FileStorage::FORMAT_JSON; else if (strncmp(bufPtr, xml_signature, strlen(xml_signature)) == 0) fmt = FileStorage::FORMAT_XML; else if (strbufsize == bufOffset) CV_Error(cv::Error::StsBadArg, "Input file is invalid"); else CV_Error(cv::Error::StsBadArg, "Unsupported file storage format"); rewind(); strbufpos = bufOffset; bufofs = 0; try { char *ptr = bufferStart(); ptr[0] = ptr[1] = ptr[2] = '\0'; FileNode root_nodes(fs_ext, 0, 0); uchar *rptr = reserveNodeSpace(root_nodes, 9); *rptr = FileNode::SEQ; writeInt(rptr + 1, 4); writeInt(rptr + 5, 0); roots.clear(); switch (fmt) { case FileStorage::FORMAT_XML: parser_do_not_use_direct_dereference = createXMLParser(this); break; case FileStorage::FORMAT_YAML: parser_do_not_use_direct_dereference = createYAMLParser(this); break; case FileStorage::FORMAT_JSON: parser_do_not_use_direct_dereference = createJSONParser(this); break; default: parser_do_not_use_direct_dereference = Ptr(); } if (!parser_do_not_use_direct_dereference.empty()) { ok = getParser().parse(ptr); if (ok) { finalizeCollection(root_nodes); CV_Assert(!fs_data_ptrs.empty()); FileNode roots_node(fs_ext, 0, 0); size_t i, nroots = roots_node.size(); FileNodeIterator it = roots_node.begin(); for (i = 0; i < nroots; i++, ++it) roots.push_back(*it); } } } catch (...) { // FIXIT log error message is_opened = true; release(); throw; } // release resources that we do not need anymore closeFile(); is_opened = true; std::vector tmpbuf; std::swap(buffer, tmpbuf); bufofs = 0; } return ok; } void FileStorage::Impl::puts(const char *str) { CV_Assert(write_mode); if (mem_mode) std::copy(str, str + strlen(str), std::back_inserter(outbuf)); else if (file) fputs(str, file); #if USE_ZLIB else if (gzfile) gzputs(gzfile, str); #endif else CV_Error(cv::Error::StsError, "The storage is not opened"); } char *FileStorage::Impl::getsFromFile(char *buf, int count) { if (file) return fgets(buf, count, file); #if USE_ZLIB if (gzfile) return gzgets(gzfile, buf, count); #endif CV_Error(cv::Error::StsError, "The storage is not opened"); } char *FileStorage::Impl::gets(size_t maxCount) { if (strbuf) { size_t i = strbufpos, len = strbufsize; const char *instr = strbuf; for (; i < len; i++) { char c = instr[i]; if (c == '\0' || c == '\n') { if (c == '\n') i++; break; } } size_t count = i - strbufpos; if (maxCount == 0 || maxCount > count) maxCount = count; buffer.resize(std::max(buffer.size(), maxCount + 8)); memcpy(&buffer[0], instr + strbufpos, maxCount); buffer[maxCount] = '\0'; strbufpos = i; return maxCount > 0 ? &buffer[0] : 0; } const size_t MAX_BLOCK_SIZE = INT_MAX / 2; // hopefully, that will be enough if (maxCount == 0) maxCount = MAX_BLOCK_SIZE; else CV_Assert(maxCount < MAX_BLOCK_SIZE); size_t ofs = 0; for (;;) { int count = (int) std::min(buffer.size() - ofs - 16, maxCount); char *ptr = getsFromFile(&buffer[ofs], count + 1); if (!ptr) break; int delta = (int) strlen(ptr); ofs += delta; maxCount -= delta; if (ptr[delta - 1] == '\n' || maxCount == 0) break; if (delta == count) buffer.resize((size_t) (buffer.size() * 1.5)); } return ofs > 0 ? &buffer[0] : 0; } char *FileStorage::Impl::gets() { char *ptr = this->gets(0); if (!ptr) { ptr = bufferStart(); // FIXIT Why do we need this hack? What is about other parsers JSON/YAML? *ptr = '\0'; setEof(); return 0; } else { size_t l = strlen(ptr); if (l > 0 && ptr[l - 1] != '\n' && ptr[l - 1] != '\r' && !eof()) { ptr[l] = '\n'; ptr[l + 1] = '\0'; } } lineno++; return ptr; } bool FileStorage::Impl::eof() { if (dummy_eof) return true; if (strbuf) return strbufpos >= strbufsize; if (file) return feof(file) != 0; #if USE_ZLIB if (gzfile) return gzeof(gzfile) != 0; #endif return false; } void FileStorage::Impl::setEof() { dummy_eof = true; } void FileStorage::Impl::closeFile() { if (file) fclose(file); #if USE_ZLIB else if (gzfile) gzclose(gzfile); #endif file = 0; gzfile = 0; strbuf = 0; strbufpos = 0; is_opened = false; } void FileStorage::Impl::rewind() { if (file) ::rewind(file); #if USE_ZLIB else if (gzfile) gzrewind(gzfile); #endif strbufpos = 0; } char *FileStorage::Impl::resizeWriteBuffer(char *ptr, int len) { const char *buffer_end = &buffer[0] + buffer.size(); if (ptr + len < buffer_end) return ptr; const char *buffer_start = &buffer[0]; int written_len = (int) (ptr - buffer_start); CV_Assert(written_len <= (int) buffer.size()); int new_size = (int) ((buffer_end - buffer_start) * 3 / 2); new_size = MAX(written_len + len, new_size); buffer.reserve(new_size + 256); buffer.resize(new_size); bufofs = written_len; return &buffer[0] + bufofs; } char *FileStorage::Impl::flush() { char *buffer_start = &buffer[0]; char *ptr = buffer_start + bufofs; if (ptr > buffer_start + space) { ptr[0] = '\n'; ptr[1] = '\0'; puts(buffer_start); bufofs = 0; } int indent = write_stack.back().indent; if (space != indent) { memset(buffer_start, ' ', indent); space = indent; } bufofs = space; ptr = buffer_start + bufofs; return ptr; } void FileStorage::Impl::endWriteStruct() { CV_Assert(write_mode); check_if_write_struct_is_delayed(false); if (state_of_writing_base64 != FileStorage_API::Uncertain) switch_to_Base64_state(FileStorage_API::Uncertain); CV_Assert(!write_stack.empty()); FStructData ¤t_struct = write_stack.back(); if (fmt == FileStorage::FORMAT_JSON && !FileNode::isFlow(current_struct.flags) && write_stack.size() > 1) current_struct.indent = write_stack[write_stack.size() - 2].indent; getEmitter().endWriteStruct(current_struct); write_stack.pop_back(); if (!write_stack.empty()) write_stack.back().flags &= ~FileNode::EMPTY; } void FileStorage::Impl::startWriteStruct_helper(const char *key, int struct_flags, const char *type_name) { CV_Assert(write_mode); struct_flags = (struct_flags & (FileNode::TYPE_MASK | FileNode::FLOW)) | FileNode::EMPTY; if (!FileNode::isCollection(struct_flags)) CV_Error(cv::Error::StsBadArg, "Some collection type: FileNode::SEQ or FileNode::MAP must be specified"); if (type_name && type_name[0] == '\0') type_name = 0; FStructData s = getEmitter().startWriteStruct(write_stack.back(), key, struct_flags, type_name); write_stack.push_back(s); size_t write_stack_size = write_stack.size(); if (write_stack_size > 1) write_stack[write_stack_size - 2].flags &= ~FileNode::EMPTY; if (fmt != FileStorage::FORMAT_JSON && !FileNode::isFlow(s.flags)) flush(); if (fmt == FileStorage::FORMAT_JSON && type_name && type_name[0] && FileNode::isMap(struct_flags)) { getEmitter().write("type_id", type_name, false); } } void FileStorage::Impl::startWriteStruct(const char *key, int struct_flags, const char *type_name) { check_if_write_struct_is_delayed(false); if (state_of_writing_base64 == FileStorage_API::NotUse) switch_to_Base64_state(FileStorage_API::Uncertain); if (state_of_writing_base64 == FileStorage_API::Uncertain && FileNode::isSeq(struct_flags) && is_using_base64 && type_name == 0) { /* Uncertain whether output Base64 data */ make_write_struct_delayed(key, struct_flags, type_name); } else if (type_name && memcmp(type_name, "binary", 6) == 0) { /* Must output Base64 data */ if ((FileNode::TYPE_MASK & struct_flags) != FileNode::SEQ) CV_Error(cv::Error::StsBadArg, "must set 'struct_flags |= CV_NODE_SEQ' if using Base64."); else if (state_of_writing_base64 != FileStorage_API::Uncertain) CV_Error(cv::Error::StsError, "function \'cvStartWriteStruct\' calls cannot be nested if using Base64."); startWriteStruct_helper(key, struct_flags, "binary"); if (state_of_writing_base64 != FileStorage_API::Uncertain) switch_to_Base64_state(FileStorage_API::Uncertain); switch_to_Base64_state(FileStorage_API::InUse); } else { /* Won't output Base64 data */ if (state_of_writing_base64 == FileStorage_API::InUse) CV_Error(cv::Error::StsError, "At the end of the output Base64, `cvEndWriteStruct` is needed."); startWriteStruct_helper(key, struct_flags, type_name); if (state_of_writing_base64 != FileStorage_API::Uncertain) switch_to_Base64_state(FileStorage_API::Uncertain); switch_to_Base64_state(FileStorage_API::NotUse); } } void FileStorage::Impl::writeComment(const char *comment, bool eol_comment) { CV_Assert(write_mode); getEmitter().writeComment(comment, eol_comment); } void FileStorage::Impl::startNextStream() { CV_Assert(write_mode); if (!empty_stream) { while (!write_stack.empty()) endWriteStruct(); flush(); getEmitter().startNextStream(); empty_stream = true; write_stack.push_back(FStructData("", FileNode::EMPTY, 0)); bufofs = 0; } } void FileStorage::Impl::write(const String &key, int value) { CV_Assert(write_mode); getEmitter().write(key.c_str(), value); } void FileStorage::Impl::write(const String &key, double value) { CV_Assert(write_mode); getEmitter().write(key.c_str(), value); } void FileStorage::Impl::write(const String &key, const String &value) { CV_Assert(write_mode); getEmitter().write(key.c_str(), value.c_str(), false); } void FileStorage::Impl::writeRawData(const std::string &dt, const void *_data, size_t len) { CV_Assert(write_mode); if (is_using_base64 || state_of_writing_base64 == FileStorage_API::Base64State::InUse) { writeRawDataBase64(_data, len, dt.c_str()); return; } else if (state_of_writing_base64 == FileStorage_API::Base64State::Uncertain) { switch_to_Base64_state(FileStorage_API::Base64State::NotUse); } size_t elemSize = fs::calcStructSize(dt.c_str(), 0); CV_Assert(elemSize); CV_Assert(len % elemSize == 0); len /= elemSize; bool explicitZero = fmt == FileStorage::FORMAT_JSON; const uchar *data0 = (const uchar *) _data; int fmt_pairs[CV_FS_MAX_FMT_PAIRS * 2], k, fmt_pair_count; char buf[256] = ""; fmt_pair_count = fs::decodeFormat(dt.c_str(), fmt_pairs, CV_FS_MAX_FMT_PAIRS); if (!len) return; if (!data0) CV_Error(cv::Error::StsNullPtr, "Null data pointer"); if (fmt_pair_count == 1) { fmt_pairs[0] *= (int) len; len = 1; } for (; len--; data0 += elemSize) { int offset = 0; for (k = 0; k < fmt_pair_count; k++) { int i, count = fmt_pairs[k * 2]; int elem_type = fmt_pairs[k * 2 + 1]; int elem_size = CV_ELEM_SIZE(elem_type); const char *ptr; offset = cvAlign(offset, elem_size); const uchar *data = data0 + offset; for (i = 0; i < count; i++) { switch (elem_type) { case CV_8U: ptr = fs::itoa(*(uchar *) data, buf, 10); data++; break; case CV_8S: ptr = fs::itoa(*(char *) data, buf, 10); data++; break; case CV_16U: ptr = fs::itoa(*(ushort *) data, buf, 10); data += sizeof(ushort); break; case CV_16S: ptr = fs::itoa(*(short *) data, buf, 10); data += sizeof(short); break; case CV_32S: ptr = fs::itoa(*(int *) data, buf, 10); data += sizeof(int); break; case CV_32F: ptr = fs::floatToString(buf, *(float *) data, false, explicitZero); data += sizeof(float); break; case CV_64F: ptr = fs::doubleToString(buf, *(double *) data, explicitZero); data += sizeof(double); break; case CV_16F: /* reference */ ptr = fs::floatToString(buf, (float) *(float16_t *) data, true, explicitZero); data += sizeof(float16_t); break; default: CV_Error(cv::Error::StsUnsupportedFormat, "Unsupported type"); return; } getEmitter().writeScalar(0, ptr); } offset = (int) (data - data0); } } } void FileStorage::Impl::workaround() { check_if_write_struct_is_delayed(false); if (state_of_writing_base64 != FileStorage_API::Base64State::Uncertain) switch_to_Base64_state(FileStorage_API::Base64State::Uncertain); } void FileStorage::Impl::switch_to_Base64_state(FileStorage_API::Base64State new_state) { const char *err_unkonwn_state = "Unexpected error, unable to determine the Base64 state."; const char *err_unable_to_switch = "Unexpected error, unable to switch to this state."; /* like a finite state machine */ switch (state_of_writing_base64) { case FileStorage_API::Base64State::Uncertain: switch (new_state) { case FileStorage_API::Base64State::InUse: { CV_DbgAssert(base64_writer == 0); bool can_indent = (fmt != cv::FileStorage::Mode::FORMAT_JSON); base64_writer = new base64::Base64Writer(*this, can_indent); if (!can_indent) { char *ptr = bufferPtr(); *ptr++ = '\0'; puts(bufferStart()); setBufferPtr(bufferStart()); memset(bufferStart(), 0, static_cast(space)); puts("\"$base64$"); } break; } case FileStorage_API::Base64State::Uncertain: break; case FileStorage_API::Base64State::NotUse: break; default: CV_Error(cv::Error::StsError, err_unkonwn_state); break; } break; case FileStorage_API::Base64State::InUse: switch (new_state) { case FileStorage_API::Base64State::InUse: case FileStorage_API::Base64State::NotUse: CV_Error(cv::Error::StsError, err_unable_to_switch); break; case FileStorage_API::Base64State::Uncertain: delete base64_writer; base64_writer = 0; if ( fmt == cv::FileStorage::FORMAT_JSON ) { puts("\""); setBufferPtr(bufferStart()); flush(); memset(bufferStart(), 0, static_cast(space) ); setBufferPtr(bufferStart()); } break; default: CV_Error(cv::Error::StsError, err_unkonwn_state); break; } break; case FileStorage_API::Base64State::NotUse: switch (new_state) { case FileStorage_API::Base64State::InUse: case FileStorage_API::Base64State::NotUse: CV_Error(cv::Error::StsError, err_unable_to_switch); break; case FileStorage_API::Base64State::Uncertain: break; default: CV_Error(cv::Error::StsError, err_unkonwn_state); break; } break; default: CV_Error(cv::Error::StsError, err_unkonwn_state); break; } state_of_writing_base64 = new_state; } void FileStorage::Impl::make_write_struct_delayed(const char *key, int struct_flags, const char *type_name) { CV_Assert(is_write_struct_delayed == false); CV_DbgAssert(delayed_struct_key == nullptr); CV_DbgAssert(delayed_struct_flags == 0); CV_DbgAssert(delayed_type_name == nullptr); delayed_struct_flags = struct_flags; if (key != nullptr) { delayed_struct_key = new char[strlen(key) + 1U]; strcpy(delayed_struct_key, key); } if (type_name != nullptr) { delayed_type_name = new char[strlen(type_name) + 1U]; strcpy(delayed_type_name, type_name); } is_write_struct_delayed = true; } void FileStorage::Impl::check_if_write_struct_is_delayed(bool change_type_to_base64) { if (is_write_struct_delayed) { /* save data to prevent recursive call errors */ std::string struct_key; std::string type_name; int struct_flags = delayed_struct_flags; if (delayed_struct_key != nullptr && *delayed_struct_key != '\0') { struct_key.assign(delayed_struct_key); } if (delayed_type_name != nullptr && *delayed_type_name != '\0') { type_name.assign(delayed_type_name); } /* reset */ delete[] delayed_struct_key; delete[] delayed_type_name; delayed_struct_key = nullptr; delayed_struct_flags = 0; delayed_type_name = nullptr; is_write_struct_delayed = false; /* call */ if (change_type_to_base64) { startWriteStruct_helper(struct_key.c_str(), struct_flags, "binary"); if (state_of_writing_base64 != FileStorage_API::Uncertain) switch_to_Base64_state(FileStorage_API::Uncertain); switch_to_Base64_state(FileStorage_API::InUse); } else { startWriteStruct_helper(struct_key.c_str(), struct_flags, type_name.c_str()); if (state_of_writing_base64 != FileStorage_API::Uncertain) switch_to_Base64_state(FileStorage_API::Uncertain); switch_to_Base64_state(FileStorage_API::NotUse); } } } void FileStorage::Impl::writeRawDataBase64(const void *_data, size_t len, const char *dt) { CV_Assert(write_mode); check_if_write_struct_is_delayed(true); if (state_of_writing_base64 == FileStorage_API::Base64State::Uncertain) { switch_to_Base64_state(FileStorage_API::Base64State::InUse); } else if (state_of_writing_base64 != FileStorage_API::Base64State::InUse) { CV_Error(cv::Error::StsError, "Base64 should not be used at present."); } base64_writer->write(_data, len, dt); } FileNode FileStorage::Impl::getFirstTopLevelNode() const { return roots.empty() ? FileNode() : roots[0]; } FileNode FileStorage::Impl::root(int streamIdx) const { return streamIdx >= 0 && streamIdx < (int) roots.size() ? roots[streamIdx] : FileNode(); } FileNode FileStorage::Impl::operator[](const String &nodename) const { return this->operator[](nodename.c_str()); } FileNode FileStorage::Impl::operator[](const char * /*nodename*/) const { return FileNode(); } int FileStorage::Impl::getFormat() const { return fmt; } char *FileStorage::Impl::bufferPtr() const { return (char *) (&buffer[0] + bufofs); } char *FileStorage::Impl::bufferStart() const { return (char *) &buffer[0]; } char *FileStorage::Impl::bufferEnd() const { return (char *) (&buffer[0] + buffer.size()); } void FileStorage::Impl::setBufferPtr(char *ptr) { char *bufferstart = bufferStart(); CV_Assert(ptr >= bufferstart && ptr <= bufferEnd()); bufofs = ptr - bufferstart; } int FileStorage::Impl::wrapMargin() const { return wrap_margin; } FStructData &FileStorage::Impl::getCurrentStruct() { CV_Assert(!write_stack.empty()); return write_stack.back(); } void FileStorage::Impl::setNonEmpty() { empty_stream = false; } void FileStorage::Impl::processSpecialDouble(char *buf, double *value, char **endptr) { FileStorage_API *fs = this; char c = buf[0]; int inf_hi = 0x7ff00000; if (c == '-' || c == '+') { inf_hi = c == '-' ? 0xfff00000 : 0x7ff00000; c = *++buf; } if (c != '.') CV_PARSE_ERROR_CPP("Bad format of floating-point constant"); Cv64suf v; v.f = 0.; if (toupper(buf[1]) == 'I' && toupper(buf[2]) == 'N' && toupper(buf[3]) == 'F') v.u = (uint64) inf_hi << 32; else if (toupper(buf[1]) == 'N' && toupper(buf[2]) == 'A' && toupper(buf[3]) == 'N') v.u = (uint64) -1; else CV_PARSE_ERROR_CPP("Bad format of floating-point constant"); *value = v.f; *endptr = buf + 4; } double FileStorage::Impl::strtod(char *ptr, char **endptr) { double fval = ::strtod(ptr, endptr); if (**endptr == '.') { char *dot_pos = *endptr; *dot_pos = ','; double fval2 = ::strtod(ptr, endptr); *dot_pos = '.'; if (*endptr > dot_pos) fval = fval2; else *endptr = dot_pos; } if (*endptr == ptr || cv_isalpha(**endptr)) processSpecialDouble(ptr, &fval, endptr); return fval; } void FileStorage::Impl::convertToCollection(int type, FileNode &node) { CV_Assert(type == FileNode::SEQ || type == FileNode::MAP); int node_type = node.type(); if (node_type == type) return; bool named = node.isNamed(); uchar *ptr = node.ptr() + 1 + (named ? 4 : 0); int ival = 0; double fval = 0; std::string sval; bool add_first_scalar = false; if (node_type != FileNode::NONE) { // scalar nodes can only be converted to sequences, e.g. in XML: // 5[parser_position]... => create 5 with name "a" // 5 6[parser_position]... => 5 is converted to [5] and then 6 is added to it // // otherwise we don't know where to get the element names from CV_Assert(type == FileNode::SEQ); if (node_type == FileNode::INT) { ival = readInt(ptr); add_first_scalar = true; } else if (node_type == FileNode::REAL) { fval = readReal(ptr); add_first_scalar = true; } else if (node_type == FileNode::STRING) { sval = std::string(node); add_first_scalar = true; } else CV_Error_(Error::StsError, ("The node of type %d cannot be converted to collection", node_type)); } ptr = reserveNodeSpace(node, 1 + (named ? 4 : 0) + 4 + 4); *ptr++ = (uchar) (type | (named ? FileNode::NAMED : 0)); // name has been copied automatically if (named) ptr += 4; // set raw_size(collection)==4, nelems(collection)==1 writeInt(ptr, 4); writeInt(ptr + 4, 0); if (add_first_scalar) addNode(node, std::string(), node_type, node_type == FileNode::INT ? (const void *) &ival : node_type == FileNode::REAL ? (const void *) &fval : node_type == FileNode::STRING ? (const void *) sval.c_str() : 0, -1); } // a) allocates new FileNode (for that just set blockIdx to the last block and ofs to freeSpaceOfs) or // b) reallocates just created new node (blockIdx and ofs must be taken from FileNode). // If there is no enough space in the current block (it should be the last block added so far), // the last block is shrunk so that it ends immediately before the reallocated node. Then, // a new block of sufficient size is allocated and the FileNode is placed in the beginning of it. // The case (a) can be used to allocate the very first node by setting blockIdx == ofs == 0. // In the case (b) the existing tag and the name are copied automatically. uchar *FileStorage::Impl::reserveNodeSpace(FileNode &node, size_t sz) { bool shrinkBlock = false; size_t shrinkBlockIdx = 0, shrinkSize = 0; uchar *ptr = 0, *blockEnd = 0; if (!fs_data_ptrs.empty()) { size_t blockIdx = node.blockIdx; size_t ofs = node.ofs; CV_Assert(blockIdx == fs_data_ptrs.size() - 1); CV_Assert(ofs <= fs_data_blksz[blockIdx]); CV_Assert(freeSpaceOfs <= fs_data_blksz[blockIdx]); //CV_Assert( freeSpaceOfs <= ofs + sz ); ptr = fs_data_ptrs[blockIdx] + ofs; blockEnd = fs_data_ptrs[blockIdx] + fs_data_blksz[blockIdx]; CV_Assert(ptr >= fs_data_ptrs[blockIdx] && ptr <= blockEnd); if (ptr + sz <= blockEnd) { freeSpaceOfs = ofs + sz; return ptr; } if (ofs == 0) // FileNode is a first component of this block. Resize current block instead of allocation of new one. { fs_data[blockIdx]->resize(sz); ptr = &fs_data[blockIdx]->at(0); fs_data_ptrs[blockIdx] = ptr; fs_data_blksz[blockIdx] = sz; freeSpaceOfs = sz; return ptr; } shrinkBlock = true; shrinkBlockIdx = blockIdx; shrinkSize = ofs; } size_t blockSize = std::max((size_t) CV_FS_MAX_LEN * 4 - 256, sz) + 256; Ptr > pv = makePtr >(blockSize); fs_data.push_back(pv); uchar *new_ptr = &pv->at(0); fs_data_ptrs.push_back(new_ptr); fs_data_blksz.push_back(blockSize); node.blockIdx = fs_data_ptrs.size() - 1; node.ofs = 0; freeSpaceOfs = sz; if (ptr && ptr + 5 <= blockEnd) { new_ptr[0] = ptr[0]; if (ptr[0] & FileNode::NAMED) { new_ptr[1] = ptr[1]; new_ptr[2] = ptr[2]; new_ptr[3] = ptr[3]; new_ptr[4] = ptr[4]; } } if (shrinkBlock) { fs_data[shrinkBlockIdx]->resize(shrinkSize); fs_data_blksz[shrinkBlockIdx] = shrinkSize; } return new_ptr; } unsigned FileStorage::Impl::getStringOfs(const std::string &key) const { str_hash_t::const_iterator it = str_hash.find(key); return it != str_hash.end() ? it->second : 0; } FileNode FileStorage::Impl::addNode(FileNode &collection, const std::string &key, int elem_type, const void *value, int len) { FileStorage_API *fs = this; bool noname = key.empty() || (fmt == FileStorage::FORMAT_XML && strcmp(key.c_str(), "_") == 0); convertToCollection(noname ? FileNode::SEQ : FileNode::MAP, collection); bool isseq = collection.empty() ? false : collection.isSeq(); if (noname != isseq) CV_PARSE_ERROR_CPP(noname ? "Map element should have a name" : "Sequence element should not have name (use <_>)"); unsigned strofs = 0; if (!noname) { strofs = getStringOfs(key); if (!strofs) { strofs = (unsigned) str_hash_data.size(); size_t keysize = key.size() + 1; str_hash_data.resize(strofs + keysize); memcpy(&str_hash_data[0] + strofs, &key[0], keysize); str_hash.insert(std::make_pair(key, strofs)); } } uchar *cp = collection.ptr(); size_t blockIdx = fs_data_ptrs.size() - 1; size_t ofs = freeSpaceOfs; FileNode node(fs_ext, blockIdx, ofs); size_t sz0 = 1 + (noname ? 0 : 4) + 8; uchar *ptr = reserveNodeSpace(node, sz0); *ptr++ = (uchar) (elem_type | (noname ? 0 : FileNode::NAMED)); if (elem_type == FileNode::NONE) freeSpaceOfs -= 8; if (!noname) { writeInt(ptr, (int) strofs); ptr += 4; } if (elem_type == FileNode::SEQ || elem_type == FileNode::MAP) { writeInt(ptr, 4); writeInt(ptr, 0); } if (value) node.setValue(elem_type, value, len); if (collection.isNamed()) cp += 4; int nelems = readInt(cp + 5); writeInt(cp + 5, nelems + 1); return node; } void FileStorage::Impl::finalizeCollection(FileNode &collection) { if (!collection.isSeq() && !collection.isMap()) return; uchar *ptr0 = collection.ptr(), *ptr = ptr0 + 1; if (*ptr0 & FileNode::NAMED) ptr += 4; size_t blockIdx = collection.blockIdx; size_t ofs = collection.ofs + (size_t) (ptr + 8 - ptr0); size_t rawSize = 4; unsigned sz = (unsigned) readInt(ptr + 4); if (sz > 0) { size_t lastBlockIdx = fs_data_ptrs.size() - 1; for (; blockIdx < lastBlockIdx; blockIdx++) { rawSize += fs_data_blksz[blockIdx] - ofs; ofs = 0; } } rawSize += freeSpaceOfs - ofs; writeInt(ptr, (int) rawSize); } void FileStorage::Impl::normalizeNodeOfs(size_t &blockIdx, size_t &ofs) const { while (ofs >= fs_data_blksz[blockIdx]) { if (blockIdx == fs_data_blksz.size() - 1) { CV_Assert(ofs == fs_data_blksz[blockIdx]); break; } ofs -= fs_data_blksz[blockIdx]; blockIdx++; } } FileStorage::Impl::Base64State FileStorage::Impl::get_state_of_writing_base64() { return state_of_writing_base64; } int FileStorage::Impl::get_space() { return space; } FileStorage::Impl::Base64Decoder::Base64Decoder() { ofs = 0; ptr = 0; indent = 0; totalchars = 0; eos = true; } void FileStorage::Impl::Base64Decoder::init(const Ptr &_parser, char *_ptr, int _indent) { parser_do_not_use_direct_dereference = _parser; ptr = _ptr; indent = _indent; encoded.clear(); decoded.clear(); ofs = 0; totalchars = 0; eos = false; } bool FileStorage::Impl::Base64Decoder::readMore(int needed) { static const uchar base64tab[] = { 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 62, 0, 0, 0, 63, 52, 53, 54, 55, 56, 57, 58, 59, 60, 61, 0, 0, 0, 0, 0, 0, 0, 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, 0, 0, 0, 0, 0, 0, 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, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0 }; if (eos) return false; size_t sz = decoded.size(); CV_Assert(ofs <= sz); sz -= ofs; for (size_t i = 0; i < sz; i++) decoded[i] = decoded[ofs + i]; decoded.resize(sz); ofs = 0; CV_Assert(ptr); char *beg = 0, *end = 0; bool ok = getParser().getBase64Row(ptr, indent, beg, end); ptr = end; std::copy(beg, end, std::back_inserter(encoded)); totalchars += end - beg; if (!ok || beg == end) { // in the end of base64 sequence pad it with '=' characters so that // its total length is multiple of eos = true; size_t tc = totalchars; for (; tc % 4 != 0; tc++) encoded.push_back('='); } int i = 0, j, n = (int) encoded.size(); if (n > 0) { const uchar *tab = base64tab; char *src = &encoded[0]; for (; i <= n - 4; i += 4) { // dddddd cccccc bbbbbb aaaaaa => ddddddcc ccccbbbb bbaaaaaa uchar d = tab[(int) (uchar) src[i]], c = tab[(int) (uchar) src[i + 1]]; uchar b = tab[(int) (uchar) src[i + 2]], a = tab[(int) (uchar) src[i + 3]]; decoded.push_back((uchar) ((d << 2) | (c >> 4))); decoded.push_back((uchar) ((c << 4) | (b >> 2))); decoded.push_back((uchar) ((b << 6) | a)); } } if (i > 0 && encoded[i - 1] == '=') { if (i > 1 && encoded[i - 2] == '=' && !decoded.empty()) decoded.pop_back(); if (!decoded.empty()) decoded.pop_back(); } n -= i; for (j = 0; j < n; j++) encoded[j] = encoded[i + j]; encoded.resize(n); return (int) decoded.size() >= needed; } uchar FileStorage::Impl::Base64Decoder::getUInt8() { size_t sz = decoded.size(); if (ofs >= sz && !readMore(1)) return (uchar) 0; return decoded[ofs++]; } ushort FileStorage::Impl::Base64Decoder::getUInt16() { size_t sz = decoded.size(); if (ofs + 2 > sz && !readMore(2)) return (ushort) 0; ushort val = (decoded[ofs] + (decoded[ofs + 1] << 8)); ofs += 2; return val; } int FileStorage::Impl::Base64Decoder::getInt32() { size_t sz = decoded.size(); if (ofs + 4 > sz && !readMore(4)) return 0; int ival = readInt(&decoded[ofs]); ofs += 4; return ival; } double FileStorage::Impl::Base64Decoder::getFloat64() { size_t sz = decoded.size(); if (ofs + 8 > sz && !readMore(8)) return 0; double fval = readReal(&decoded[ofs]); ofs += 8; return fval; } bool FileStorage::Impl::Base64Decoder::endOfStream() const { return eos; } char *FileStorage::Impl::Base64Decoder::getPtr() const { return ptr; } char *FileStorage::Impl::parseBase64(char *ptr, int indent, FileNode &collection) { const int BASE64_HDR_SIZE = 24; char dt[BASE64_HDR_SIZE + 1] = {0}; base64decoder.init(parser_do_not_use_direct_dereference, ptr, indent); int i, k; for (i = 0; i < BASE64_HDR_SIZE; i++) dt[i] = (char) base64decoder.getUInt8(); for (i = 0; i < BASE64_HDR_SIZE; i++) if (isspace(dt[i])) break; dt[i] = '\0'; CV_Assert(!base64decoder.endOfStream()); int fmt_pairs[CV_FS_MAX_FMT_PAIRS * 2]; int fmt_pair_count = fs::decodeFormat(dt, fmt_pairs, CV_FS_MAX_FMT_PAIRS); int ival = 0; double fval = 0; for (;;) { for (k = 0; k < fmt_pair_count; k++) { int elem_type = fmt_pairs[k * 2 + 1]; int count = fmt_pairs[k * 2]; for (i = 0; i < count; i++) { int node_type = FileNode::INT; switch (elem_type) { case CV_8U: ival = base64decoder.getUInt8(); break; case CV_8S: ival = (char) base64decoder.getUInt8(); break; case CV_16U: ival = base64decoder.getUInt16(); break; case CV_16S: ival = (short) base64decoder.getUInt16(); break; case CV_32S: ival = base64decoder.getInt32(); break; case CV_32F: { Cv32suf v; v.i = base64decoder.getInt32(); fval = v.f; node_type = FileNode::REAL; } break; case CV_64F: fval = base64decoder.getFloat64(); node_type = FileNode::REAL; break; case CV_16F: fval = (float) float16_t::fromBits(base64decoder.getUInt16()); node_type = FileNode::REAL; break; default: CV_Error(Error::StsUnsupportedFormat, "Unsupported type"); } if (base64decoder.endOfStream()) break; addNode(collection, std::string(), node_type, node_type == FileNode::INT ? (void *) &ival : (void *) &fval, -1); } } if (base64decoder.endOfStream()) break; } finalizeCollection(collection); return base64decoder.getPtr(); } void FileStorage::Impl::parseError(const char *func_name, const std::string &err_msg, const char *source_file, int source_line) { std::string msg = format("%s(%d): %s", filename.c_str(), lineno, err_msg.c_str()); error(Error::StsParseError, func_name, msg.c_str(), source_file, source_line); } const uchar *FileStorage::Impl::getNodePtr(size_t blockIdx, size_t ofs) const { CV_Assert(blockIdx < fs_data_ptrs.size()); CV_Assert(ofs < fs_data_blksz[blockIdx]); return fs_data_ptrs[blockIdx] + ofs; } std::string FileStorage::Impl::getName(size_t nameofs) const { CV_Assert(nameofs < str_hash_data.size()); return std::string(&str_hash_data[nameofs]); } FileStorage *FileStorage::Impl::getFS() { return fs_ext; } FileStorage::FileStorage() : state(0) { p = makePtr(this); } FileStorage::FileStorage(const String& filename, int flags, const String& encoding) : state(0) { p = makePtr(this); bool ok = p->open(filename.c_str(), flags, encoding.c_str()); if(ok) state = FileStorage::NAME_EXPECTED + FileStorage::INSIDE_MAP; } void FileStorage::startWriteStruct(const String& name, int struct_flags, const String& typeName) { p->startWriteStruct(name.size() ? name.c_str() : 0, struct_flags, typeName.size() ? typeName.c_str() : 0); elname = String(); if ((struct_flags & FileNode::TYPE_MASK) == FileNode::SEQ) state = FileStorage::VALUE_EXPECTED; else state = FileStorage::NAME_EXPECTED + FileStorage::INSIDE_MAP; } void FileStorage::endWriteStruct() { p->endWriteStruct(); state = p->write_stack.empty() || FileNode::isMap(p->write_stack.back().flags) ? FileStorage::NAME_EXPECTED + FileStorage::INSIDE_MAP : FileStorage::VALUE_EXPECTED; elname = String(); } FileStorage::~FileStorage() { } bool FileStorage::open(const String& filename, int flags, const String& encoding) { try { bool ok = p->open(filename.c_str(), flags, encoding.c_str()); if(ok) state = FileStorage::NAME_EXPECTED + FileStorage::INSIDE_MAP; return ok; } catch (...) { release(); throw; // re-throw } } bool FileStorage::isOpened() const { return p->is_opened; } void FileStorage::release() { p->release(); } FileNode FileStorage::root(int i) const { if( p.empty() || p->roots.empty() || i < 0 || i >= (int)p->roots.size() ) return FileNode(); return p->roots[i]; } FileNode FileStorage::getFirstTopLevelNode() const { FileNode r = root(); FileNodeIterator it = r.begin(); return it != r.end() ? *it : FileNode(); } std::string FileStorage::getDefaultObjectName(const std::string& _filename) { static const char* stubname = "unnamed"; const char* filename = _filename.c_str(); const char* ptr2 = filename + _filename.size(); const char* ptr = ptr2 - 1; cv::AutoBuffer name_buf(_filename.size()+1); while( ptr >= filename && *ptr != '\\' && *ptr != '/' && *ptr != ':' ) { if( *ptr == '.' && (!*ptr2 || strncmp(ptr2, ".gz", 3) == 0) ) ptr2 = ptr; ptr--; } ptr++; if( ptr == ptr2 ) CV_Error( cv::Error::StsBadArg, "Invalid filename" ); char* name = name_buf.data(); // name must start with letter or '_' if( !cv_isalpha(*ptr) && *ptr!= '_' ){ *name++ = '_'; } while( ptr < ptr2 ) { char c = *ptr++; if( !cv_isalnum(c) && c != '-' && c != '_' ) c = '_'; *name++ = c; } *name = '\0'; name = name_buf.data(); if( strcmp( name, "_" ) == 0 ) strcpy( name, stubname ); return name; } int FileStorage::getFormat() const { return p->fmt; } FileNode FileStorage::operator [](const char* key) const { return this->operator[](std::string(key)); } FileNode FileStorage::operator [](const std::string& key) const { FileNode res; for (size_t i = 0; i < p->roots.size(); i++) { res = p->roots[i][key]; if (!res.empty()) break; } return res; } String FileStorage::releaseAndGetString() { String buf; p->release(&buf); return buf; } void FileStorage::writeRaw( const String& fmt, const void* vec, size_t len ) { p->writeRawData(fmt, (const uchar*)vec, len); } void FileStorage::writeComment( const String& comment, bool eol_comment ) { p->writeComment(comment.c_str(), eol_comment); } void writeScalar( FileStorage& fs, int value ) { fs.p->write(String(), value); } void writeScalar( FileStorage& fs, float value ) { fs.p->write(String(), (double)value); } void writeScalar( FileStorage& fs, double value ) { fs.p->write(String(), value); } void writeScalar( FileStorage& fs, const String& value ) { fs.p->write(String(), value); } void write( FileStorage& fs, const String& name, int value ) { fs.p->write(name, value); } void write( FileStorage& fs, const String& name, float value ) { fs.p->write(name, (double)value); } void write( FileStorage& fs, const String& name, double value ) { fs.p->write(name, value); } void write( FileStorage& fs, const String& name, const String& value ) { fs.p->write(name, value); } void FileStorage::write(const String& name, int val) { p->write(name, val); } void FileStorage::write(const String& name, double val) { p->write(name, val); } void FileStorage::write(const String& name, const String& val) { p->write(name, val); } void FileStorage::write(const String& name, const Mat& val) { cv::write(*this, name, val); } void FileStorage::write(const String& name, const std::vector& val) { cv::write(*this, name, val); } FileStorage& operator << (FileStorage& fs, const String& str) { enum { NAME_EXPECTED = FileStorage::NAME_EXPECTED, VALUE_EXPECTED = FileStorage::VALUE_EXPECTED, INSIDE_MAP = FileStorage::INSIDE_MAP }; const char* _str = str.c_str(); if( !fs.isOpened() || !_str ) return fs; Ptr& fs_impl = fs.p; char c = *_str; if( c == '}' || c == ']' ) { if( fs_impl->write_stack.empty() ) CV_Error_( cv::Error::StsError, ("Extra closing '%c'", *_str) ); fs_impl->workaround(); int struct_flags = fs_impl->write_stack.back().flags; char expected_bracket = FileNode::isMap(struct_flags) ? '}' : ']'; if( c != expected_bracket ) CV_Error_( cv::Error::StsError, ("The closing '%c' does not match the opening '%c'", c, expected_bracket)); fs_impl->endWriteStruct(); CV_Assert(!fs_impl->write_stack.empty()); struct_flags = fs_impl->write_stack.back().flags; fs.state = FileNode::isMap(struct_flags) ? INSIDE_MAP + NAME_EXPECTED : VALUE_EXPECTED; fs.elname = String(); } else if( fs.state == NAME_EXPECTED + INSIDE_MAP ) { if (!cv_isalpha(c) && c != '_') CV_Error_( cv::Error::StsError, ("Incorrect element name %s; should start with a letter or '_'", _str) ); fs.elname = str; fs.state = VALUE_EXPECTED + INSIDE_MAP; } else if( (fs.state & 3) == VALUE_EXPECTED ) { if( c == '{' || c == '[' ) { int struct_flags = c == '{' ? FileNode::MAP : FileNode::SEQ; fs.state = struct_flags == FileNode::MAP ? INSIDE_MAP + NAME_EXPECTED : VALUE_EXPECTED; _str++; if( *_str == ':' ) { _str++; if( !*_str ) struct_flags |= FileNode::FLOW; } fs_impl->startWriteStruct(!fs.elname.empty() ? fs.elname.c_str() : 0, struct_flags, *_str ? _str : 0 ); fs.elname = String(); } else { write( fs, fs.elname, (c == '\\' && (_str[1] == '{' || _str[1] == '}' || _str[1] == '[' || _str[1] == ']')) ? String(_str+1) : str ); if( fs.state == INSIDE_MAP + VALUE_EXPECTED ) fs.state = INSIDE_MAP + NAME_EXPECTED; } } else CV_Error( cv::Error::StsError, "Invalid fs.state" ); return fs; } FileNode::FileNode() : fs(NULL) { blockIdx = ofs = 0; } FileNode::FileNode(FileStorage::Impl* _fs, size_t _blockIdx, size_t _ofs) : fs(_fs) { blockIdx = _blockIdx; ofs = _ofs; } FileNode::FileNode(const FileStorage* _fs, size_t _blockIdx, size_t _ofs) : FileNode(_fs->p.get(), _blockIdx, _ofs) { // nothing } FileNode::FileNode(const FileNode& node) { fs = node.fs; blockIdx = node.blockIdx; ofs = node.ofs; } FileNode& FileNode::operator=(const FileNode& node) { fs = node.fs; blockIdx = node.blockIdx; ofs = node.ofs; return *this; } FileNode FileNode::operator[](const std::string& nodename) const { if(!fs) return FileNode(); CV_Assert( isMap() ); unsigned key = fs->getStringOfs(nodename); size_t i, sz = size(); FileNodeIterator it = begin(); for( i = 0; i < sz; i++, ++it ) { FileNode n = *it; const uchar* p = n.ptr(); unsigned key2 = (unsigned)readInt(p + 1); CV_Assert( key2 < fs->str_hash_data.size() ); if( key == key2 ) return n; } return FileNode(); } FileNode FileNode::operator[](const char* nodename) const { return this->operator[](std::string(nodename)); } FileNode FileNode::operator[](int i) const { if(!fs) return FileNode(); CV_Assert( isSeq() ); int sz = (int)size(); CV_Assert( 0 <= i && i < sz ); FileNodeIterator it = begin(); it += i; return *it; } std::vector FileNode::keys() const { CV_Assert(isMap()); std::vector res; res.reserve(size()); for (FileNodeIterator it = begin(); it != end(); ++it) { res.push_back((*it).name()); } return res; } int FileNode::type() const { const uchar* p = ptr(); if(!p) return NONE; return (*p & TYPE_MASK); } bool FileNode::isMap(int flags) { return (flags & TYPE_MASK) == MAP; } bool FileNode::isSeq(int flags) { return (flags & TYPE_MASK) == SEQ; } bool FileNode::isCollection(int flags) { return isMap(flags) || isSeq(flags); } bool FileNode::isFlow(int flags) { return (flags & FLOW) != 0; } bool FileNode::isEmptyCollection(int flags) { return (flags & EMPTY) != 0; } bool FileNode::empty() const { return fs == 0; } bool FileNode::isNone() const { return type() == NONE; } bool FileNode::isSeq() const { return type() == SEQ; } bool FileNode::isMap() const { return type() == MAP; } bool FileNode::isInt() const { return type() == INT; } bool FileNode::isReal() const { return type() == REAL; } bool FileNode::isString() const { return type() == STRING; } bool FileNode::isNamed() const { const uchar* p = ptr(); if(!p) return false; return (*p & NAMED) != 0; } std::string FileNode::name() const { const uchar* p = ptr(); if(!p) return std::string(); size_t nameofs = p[1] | (p[2]<<8) | (p[3]<<16) | (p[4]<<24); return fs->getName(nameofs); } FileNode::operator int() const { const uchar* p = ptr(); if(!p) return 0; int tag = *p; int type = (tag & TYPE_MASK); p += (tag & NAMED) ? 5 : 1; if( type == INT ) { return readInt(p); } else if( type == REAL ) { return cvRound(readReal(p)); } else return 0x7fffffff; } FileNode::operator float() const { const uchar* p = ptr(); if(!p) return 0.f; int tag = *p; int type = (tag & TYPE_MASK); p += (tag & NAMED) ? 5 : 1; if( type == INT ) { return (float)readInt(p); } else if( type == REAL ) { return (float)readReal(p); } else return FLT_MAX; } FileNode::operator double() const { const uchar* p = ptr(); if(!p) return 0.f; int tag = *p; int type = (tag & TYPE_MASK); p += (tag & NAMED) ? 5 : 1; if( type == INT ) { return (double)readInt(p); } else if( type == REAL ) { return readReal(p); } else return DBL_MAX; } double FileNode::real() const { return double(*this); } std::string FileNode::string() const { const uchar* p = ptr(); if( !p || (*p & TYPE_MASK) != STRING ) return std::string(); p += (*p & NAMED) ? 5 : 1; size_t sz = (size_t)(unsigned)readInt(p); return std::string((const char*)(p + 4), sz - 1); } Mat FileNode::mat() const { Mat value; read(*this, value, Mat()); return value; } FileNodeIterator FileNode::begin() const { return FileNodeIterator(*this, false); } FileNodeIterator FileNode::end() const { return FileNodeIterator(*this, true); } void FileNode::readRaw( const std::string& fmt, void* vec, size_t len ) const { FileNodeIterator it = begin(); it.readRaw( fmt, vec, len ); } size_t FileNode::size() const { const uchar* p = ptr(); if( !p ) return 0; int tag = *p; int tp = tag & TYPE_MASK; if( tp == MAP || tp == SEQ ) { if( tag & NAMED ) p += 4; return (size_t)(unsigned)readInt(p + 5); } return tp != NONE; } size_t FileNode::rawSize() const { const uchar* p0 = ptr(), *p = p0; if( !p ) return 0; int tag = *p++; int tp = tag & TYPE_MASK; if( tag & NAMED ) p += 4; size_t sz0 = (size_t)(p - p0); if( tp == INT ) return sz0 + 4; if( tp == REAL ) return sz0 + 8; if( tp == NONE ) return sz0; CV_Assert( tp == STRING || tp == SEQ || tp == MAP ); return sz0 + 4 + readInt(p); } uchar* FileNode::ptr() { return !fs ? 0 : (uchar*)fs->getNodePtr(blockIdx, ofs); } const uchar* FileNode::ptr() const { return !fs ? 0 : fs->getNodePtr(blockIdx, ofs); } void FileNode::setValue( int type, const void* value, int len ) { uchar *p = ptr(); CV_Assert(p != 0); int tag = *p; int current_type = tag & TYPE_MASK; CV_Assert( current_type == NONE || current_type == type ); int sz = 1; if( tag & NAMED ) sz += 4; if( type == INT ) sz += 4; else if( type == REAL ) sz += 8; else if( type == STRING ) { if( len < 0 ) len = (int)strlen((const char*)value); sz += 4 + len + 1; // besides the string content, // take the size (4 bytes) and the final '\0' into account } else CV_Error(Error::StsNotImplemented, "Only scalar types can be dynamically assigned to a file node"); p = fs->reserveNodeSpace(*this, sz); *p++ = (uchar)(type | (tag & NAMED)); if( tag & NAMED ) p += 4; if( type == INT ) { int ival = *(const int*)value; writeInt(p, ival); } else if( type == REAL ) { double dbval = *(const double*)value; writeReal(p, dbval); } else if( type == STRING ) { const char* str = (const char*)value; writeInt(p, len + 1); memcpy(p + 4, str, len); p[4 + len] = (uchar)'\0'; } } FileNodeIterator::FileNodeIterator() { fs = 0; blockIdx = 0; ofs = 0; blockSize = 0; nodeNElems = 0; idx = 0; } FileNodeIterator::FileNodeIterator( const FileNode& node, bool seekEnd ) { fs = node.fs; idx = 0; if( !fs ) blockIdx = ofs = blockSize = nodeNElems = 0; else { blockIdx = node.blockIdx; ofs = node.ofs; bool collection = node.isSeq() || node.isMap(); if( node.isNone() ) { nodeNElems = 0; } else if( !collection ) { nodeNElems = 1; if( seekEnd ) { idx = 1; ofs += node.rawSize(); } } else { nodeNElems = node.size(); const uchar* p0 = node.ptr(), *p = p0 + 1; if(*p0 & FileNode::NAMED ) p += 4; if( !seekEnd ) ofs += (p - p0) + 8; else { size_t rawsz = (size_t)(unsigned)readInt(p); ofs += (p - p0) + 4 + rawsz; idx = nodeNElems; } } fs->normalizeNodeOfs(blockIdx, ofs); blockSize = fs->fs_data_blksz[blockIdx]; } } FileNodeIterator::FileNodeIterator(const FileNodeIterator& it) { fs = it.fs; blockIdx = it.blockIdx; ofs = it.ofs; blockSize = it.blockSize; nodeNElems = it.nodeNElems; idx = it.idx; } FileNodeIterator& FileNodeIterator::operator=(const FileNodeIterator& it) { fs = it.fs; blockIdx = it.blockIdx; ofs = it.ofs; blockSize = it.blockSize; nodeNElems = it.nodeNElems; idx = it.idx; return *this; } FileNode FileNodeIterator::operator *() const { return FileNode(idx < nodeNElems ? fs : NULL, blockIdx, ofs); } FileNodeIterator& FileNodeIterator::operator ++ () { if( idx == nodeNElems || !fs ) return *this; idx++; FileNode n(fs, blockIdx, ofs); ofs += n.rawSize(); if( ofs >= blockSize ) { fs->normalizeNodeOfs(blockIdx, ofs); blockSize = fs->fs_data_blksz[blockIdx]; } return *this; } FileNodeIterator FileNodeIterator::operator ++ (int) { FileNodeIterator it = *this; ++(*this); return it; } FileNodeIterator& FileNodeIterator::operator += (int _ofs) { CV_Assert( _ofs >= 0 ); for( ; _ofs > 0; _ofs-- ) this->operator ++(); return *this; } FileNodeIterator& FileNodeIterator::readRaw( const String& fmt, void* _data0, size_t maxsz) { if( fs && idx < nodeNElems ) { uchar* data0 = (uchar*)_data0; int fmt_pairs[CV_FS_MAX_FMT_PAIRS*2]; int fmt_pair_count = fs::decodeFormat( fmt.c_str(), fmt_pairs, CV_FS_MAX_FMT_PAIRS ); size_t esz = fs::calcStructSize( fmt.c_str(), 0 ); CV_Assert( maxsz % esz == 0 ); maxsz /= esz; for( ; maxsz > 0; maxsz--, data0 += esz ) { size_t offset = 0; for( int k = 0; k < fmt_pair_count; k++ ) { int elem_type = fmt_pairs[k*2+1]; int elem_size = CV_ELEM_SIZE(elem_type); int count = fmt_pairs[k*2]; offset = alignSize( offset, elem_size ); uchar* data = data0 + offset; for( int i = 0; i < count; i++, ++(*this) ) { FileNode node = *(*this); if( node.isInt() ) { int ival = (int)node; switch( elem_type ) { case CV_8U: *(uchar*)data = saturate_cast(ival); data++; break; case CV_8S: *(char*)data = saturate_cast(ival); data++; break; case CV_16U: *(ushort*)data = saturate_cast(ival); data += sizeof(ushort); break; case CV_16S: *(short*)data = saturate_cast(ival); data += sizeof(short); break; case CV_32S: *(int*)data = ival; data += sizeof(int); break; case CV_32F: *(float*)data = (float)ival; data += sizeof(float); break; case CV_64F: *(double*)data = (double)ival; data += sizeof(double); break; case CV_16F: *(float16_t*)data = float16_t((float)ival); data += sizeof(float16_t); break; default: CV_Error( Error::StsUnsupportedFormat, "Unsupported type" ); } } else if( node.isReal() ) { double fval = (double)node; switch( elem_type ) { case CV_8U: *(uchar*)data = saturate_cast(fval); data++; break; case CV_8S: *(char*)data = saturate_cast(fval); data++; break; case CV_16U: *(ushort*)data = saturate_cast(fval); data += sizeof(ushort); break; case CV_16S: *(short*)data = saturate_cast(fval); data += sizeof(short); break; case CV_32S: *(int*)data = saturate_cast(fval); data += sizeof(int); break; case CV_32F: *(float*)data = (float)fval; data += sizeof(float); break; case CV_64F: *(double*)data = fval; data += sizeof(double); break; case CV_16F: *(float16_t*)data = float16_t((float)fval); data += sizeof(float16_t); break; default: CV_Error( Error::StsUnsupportedFormat, "Unsupported type" ); } } else CV_Error( Error::StsError, "readRawData can only be used to read plain sequences of numbers" ); } offset = (int)(data - data0); } } } return *this; } bool FileNodeIterator::equalTo(const FileNodeIterator& it) const { return fs == it.fs && blockIdx == it.blockIdx && ofs == it.ofs && idx == it.idx && nodeNElems == it.nodeNElems; } size_t FileNodeIterator::remaining() const { return nodeNElems - idx; } bool operator == ( const FileNodeIterator& it1, const FileNodeIterator& it2 ) { return it1.equalTo(it2); } bool operator != ( const FileNodeIterator& it1, const FileNodeIterator& it2 ) { return !it1.equalTo(it2); } void read(const FileNode& node, int& val, int default_val) { val = default_val; if( !node.empty() ) { val = (int)node; } } void read(const FileNode& node, double& val, double default_val) { val = default_val; if( !node.empty() ) { val = (double)node; } } void read(const FileNode& node, float& val, float default_val) { val = default_val; if( !node.empty() ) { val = (float)node; } } void read(const FileNode& node, std::string& val, const std::string& default_val) { val = default_val; if( !node.empty() ) { val = (std::string)node; } } FileStorage_API::~FileStorage_API() {} namespace internal { WriteStructContext::WriteStructContext(FileStorage& _fs, const std::string& name, int flags, const std::string& typeName) { fs = &_fs; fs->startWriteStruct(name, flags, typeName); } WriteStructContext::~WriteStructContext() { fs->endWriteStruct(); } } }