void sd_object::test<2>() { const std::string decoded("random"); //const std::string encoded("cmFuZG9t\n"); const std::string streamed("b(6)\"random\""); typedef std::vector<U8> buf_t; buf_t buf; std::copy( decoded.begin(), decoded.end(), std::back_insert_iterator<buf_t>(buf)); LLSD sd; sd = buf; std::stringstream str; S32 count = LLSDSerialize::toNotation(sd, str); ensure_equals("output count", count, 1); std::string actual(str.str()); ensure_equals("formatted binary encoding", actual, streamed); sd.clear(); LLSDSerialize::fromNotation(sd, str); std::vector<U8> after; after = sd.asBinary(); ensure_equals("binary decoded size", after.size(), decoded.size()); ensure("binary decoding", (0 == memcmp( &after[0], decoded.c_str(), decoded.size()))); }
void sd_object::test<5>() { for(S32 i = 0; i < 100; ++i) { // gen up a starting point typedef std::vector<U8> buf_t; buf_t source; srand(666 + i); /* Flawfinder: ignore */ S32 size = rand() % 1000 + 10; std::generate_n( std::back_insert_iterator<buf_t>(source), size, rand); std::stringstream str; str << "b(" << size << ")\""; str.write((const char*)&source[0], size); str << "\""; LLSD sd; S32 count = LLSDSerialize::fromNotation(sd, str); ensure_equals("binary parse", count, 1); buf_t actual = sd.asBinary(); ensure_equals("binary size", actual.size(), (size_t)size); ensure("binary data", (0 == memcmp(&source[0], &actual[0], size))); } }
// Converts an LLSD binary to an LLSD string LLSD ll_string_from_binary(const LLSD& sd) { std::vector<U8> value = sd.asBinary(); std::string str; str.resize(value.size()); memcpy(&str[0], &value[0], value.size()); return str; }
const std::string LLSavedLoginEntry::decryptPassword(const LLSD& pwdata) { std::string pw = ""; if (pwdata.isBinary() && pwdata.asBinary().size() == PASSWORD_HASH_LENGTH+1) { LLSD::Binary buffer = pwdata.asBinary(); LLXORCipher cipher(gMACAddress, 6); cipher.decrypt(&buffer[0], PASSWORD_HASH_LENGTH); buffer[PASSWORD_HASH_LENGTH] = '\0'; if (LLStringOps::isHexString(std::string(reinterpret_cast<const char*>(&buffer[0]), PASSWORD_HASH_LENGTH))) { pw.assign(reinterpret_cast<char*>(&buffer[0])); } } return pw; }
U32 ll_ipaddr_from_sd(const LLSD& sd) { U32 ret; std::vector<U8> v = sd.asBinary(); if (v.size() < 4) { return 0; } memcpy(&ret, &(v[0]), 4); /* Flawfinder: ignore */ return ret; }
U64 ll_U64_from_sd(const LLSD& sd) { U32 high, low; std::vector<U8> v = sd.asBinary(); if (v.size() < 8) { return 0; } memcpy(&high, &(v[0]), 4); /* Flawfinder: ignore */ memcpy(&low, &(v[4]), 4); /* Flawfinder: ignore */ high = ntohl(high); low = ntohl(low); return ((U64)high) << 32 | low; }
S32 LLSDXMLFormatter::format_impl(const LLSD& data, std::ostream& ostr, U32 options, U32 level) const { S32 format_count = 1; std::string pre; std::string post; if (options & LLSDFormatter::OPTIONS_PRETTY) { for (U32 i = 0; i < level; i++) { pre += " "; } post = "\n"; } switch(data.type()) { case LLSD::TypeMap: if(0 == data.size()) { ostr << pre << "<map />" << post; } else { ostr << pre << "<map>" << post; LLSD::map_const_iterator iter = data.beginMap(); LLSD::map_const_iterator end = data.endMap(); for(; iter != end; ++iter) { ostr << pre << "<key>" << escapeString((*iter).first) << "</key>" << post; format_count += format_impl((*iter).second, ostr, options, level + 1); } ostr << pre << "</map>" << post; } break; case LLSD::TypeArray: if(0 == data.size()) { ostr << pre << "<array />" << post; } else { ostr << pre << "<array>" << post; LLSD::array_const_iterator iter = data.beginArray(); LLSD::array_const_iterator end = data.endArray(); for(; iter != end; ++iter) { format_count += format_impl(*iter, ostr, options, level + 1); } ostr << pre << "</array>" << post; } break; case LLSD::TypeUndefined: ostr << pre << "<undef />" << post; break; case LLSD::TypeBoolean: ostr << pre << "<boolean>"; if(mBoolAlpha || (ostr.flags() & std::ios::boolalpha) ) { ostr << (data.asBoolean() ? "true" : "false"); } else { ostr << (data.asBoolean() ? 1 : 0); } ostr << "</boolean>" << post; break; case LLSD::TypeInteger: ostr << pre << "<integer>" << data.asInteger() << "</integer>" << post; break; case LLSD::TypeReal: ostr << pre << "<real>"; if(mRealFormat.empty()) { ostr << data.asReal(); } else { formatReal(data.asReal(), ostr); } ostr << "</real>" << post; break; case LLSD::TypeUUID: if(data.asUUID().isNull()) ostr << pre << "<uuid />" << post; else ostr << pre << "<uuid>" << data.asUUID() << "</uuid>" << post; break; case LLSD::TypeString: if(data.asStringRef().empty()) ostr << pre << "<string />" << post; else ostr << pre << "<string>" << escapeString(data.asStringRef()) <<"</string>" << post; break; case LLSD::TypeDate: ostr << pre << "<date>" << data.asDate() << "</date>" << post; break; case LLSD::TypeURI: ostr << pre << "<uri>" << escapeString(data.asString()) << "</uri>" << post; break; case LLSD::TypeBinary: { const LLSD::Binary& buffer = data.asBinary(); if(buffer.empty()) { ostr << pre << "<binary />" << post; } else { ostr << pre << "<binary encoding=\"base64\">"; ostr << LLBase64::encode(&buffer[0], buffer.size()); ostr << "</binary>" << post; } break; } default: // *NOTE: This should never happen. ostr << pre << "<undef />" << post; break; } return format_count; }
void ensure_equals(const std::string& msg, const LLSD& actual, const LLSD& expected) { ensure_equals(msg + " type", actual.type(), expected.type()); switch (actual.type()) { case LLSD::TypeUndefined: return; case LLSD::TypeBoolean: ensure_equals(msg + " boolean", actual.asBoolean(), expected.asBoolean()); return; case LLSD::TypeInteger: ensure_equals(msg + " integer", actual.asInteger(), expected.asInteger()); return; case LLSD::TypeReal: ensure_equals(msg + " real", actual.asReal(), expected.asReal()); return; case LLSD::TypeString: ensure_equals(msg + " string", actual.asString(), expected.asString()); return; case LLSD::TypeUUID: ensure_equals(msg + " uuid", actual.asUUID(), expected.asUUID()); return; case LLSD::TypeDate: ensure_equals(msg + " date", actual.asDate(), expected.asDate()); return; case LLSD::TypeURI: ensure_equals(msg + " uri", actual.asURI(), expected.asURI()); return; case LLSD::TypeBinary: ensure_equals(msg + " binary", actual.asBinary(), expected.asBinary()); return; case LLSD::TypeMap: { ensure_equals(msg + " map size", actual.size(), expected.size()); LLSD::map_const_iterator actual_iter = actual.beginMap(); LLSD::map_const_iterator expected_iter = expected.beginMap(); while(actual_iter != actual.endMap()) { ensure_equals(msg + " map keys", actual_iter->first, expected_iter->first); ensure_equals(msg + "[" + actual_iter->first + "]", actual_iter->second, expected_iter->second); ++actual_iter; ++expected_iter; } return; } case LLSD::TypeArray: { ensure_equals(msg + " array size", actual.size(), expected.size()); for(int i = 0; i < actual.size(); ++i) { ensure_equals(msg + llformat("[%d]", i), actual[i], expected[i]); } return; } default: // should never get here, but compiler produces warning if we // don't cover this case, and at Linden warnings are fatal. throw failure(STRINGIZE("invalid type field " << actual.type())); } }
void LLFilterSD2XMLRPC::streamOut(std::ostream& ostr, const LLSD& sd) { ostr << "<value>"; switch(sd.type()) { case LLSD::TypeMap: { #if LL_SPEW_STREAM_OUT_DEBUGGING llinfos << "streamOut(map) BEGIN" << llendl; #endif ostr << "<struct>"; if(ostr.fail()) { llinfos << "STREAM FAILURE writing struct" << llendl; } LLSD::map_const_iterator it = sd.beginMap(); LLSD::map_const_iterator end = sd.endMap(); for(; it != end; ++it) { ostr << "<member><name>" << xml_escape_string((*it).first) << "</name>"; streamOut(ostr, (*it).second); if(ostr.fail()) { llinfos << "STREAM FAILURE writing '" << (*it).first << "' with sd type " << (*it).second.type() << llendl; } ostr << "</member>"; } ostr << "</struct>"; #if LL_SPEW_STREAM_OUT_DEBUGGING llinfos << "streamOut(map) END" << llendl; #endif break; } case LLSD::TypeArray: { #if LL_SPEW_STREAM_OUT_DEBUGGING llinfos << "streamOut(array) BEGIN" << llendl; #endif ostr << "<array><data>"; LLSD::array_const_iterator it = sd.beginArray(); LLSD::array_const_iterator end = sd.endArray(); for(; it != end; ++it) { streamOut(ostr, *it); if(ostr.fail()) { llinfos << "STREAM FAILURE writing array element sd type " << (*it).type() << llendl; } } #if LL_SPEW_STREAM_OUT_DEBUGGING llinfos << "streamOut(array) END" << llendl; #endif ostr << "</data></array>"; break; } case LLSD::TypeUndefined: // treat undefined as a bool with a false value. case LLSD::TypeBoolean: #if LL_SPEW_STREAM_OUT_DEBUGGING llinfos << "streamOut(bool)" << llendl; #endif ostr << "<boolean>" << (sd.asBoolean() ? "1" : "0") << "</boolean>"; break; case LLSD::TypeInteger: #if LL_SPEW_STREAM_OUT_DEBUGGING llinfos << "streamOut(int)" << llendl; #endif ostr << "<i4>" << sd.asInteger() << "</i4>"; break; case LLSD::TypeReal: #if LL_SPEW_STREAM_OUT_DEBUGGING llinfos << "streamOut(real)" << llendl; #endif ostr << "<double>" << sd.asReal() << "</double>"; break; case LLSD::TypeString: #if LL_SPEW_STREAM_OUT_DEBUGGING llinfos << "streamOut(string)" << llendl; #endif ostr << "<string>" << xml_escape_string(sd.asString()) << "</string>"; break; case LLSD::TypeUUID: #if LL_SPEW_STREAM_OUT_DEBUGGING llinfos << "streamOut(uuid)" << llendl; #endif // serialize it as a string ostr << "<string>" << sd.asString() << "</string>"; break; case LLSD::TypeURI: { #if LL_SPEW_STREAM_OUT_DEBUGGING llinfos << "streamOut(uri)" << llendl; #endif // serialize it as a string ostr << "<string>" << xml_escape_string(sd.asString()) << "</string>"; break; } case LLSD::TypeBinary: { #if LL_SPEW_STREAM_OUT_DEBUGGING llinfos << "streamOut(binary)" << llendl; #endif // this is pretty inefficient, but we'll deal with that // problem when it becomes one. ostr << "<base64>"; LLSD::Binary buffer = sd.asBinary(); if(!buffer.empty()) { // *TODO: convert to LLBase64 int b64_buffer_length = apr_base64_encode_len(buffer.size()); char* b64_buffer = new char[b64_buffer_length]; b64_buffer_length = apr_base64_encode_binary( b64_buffer, &buffer[0], buffer.size()); ostr.write(b64_buffer, b64_buffer_length - 1); delete[] b64_buffer; } ostr << "</base64>"; break; } case LLSD::TypeDate: #if LL_SPEW_STREAM_OUT_DEBUGGING llinfos << "streamOut(date)" << llendl; #endif // no need to escape this since it will be alpha-numeric. ostr << "<dateTime.iso8601>" << sd.asString() << "</dateTime.iso8601>"; break; default: // unhandled type llwarns << "Unhandled structured data type: " << sd.type() << llendl; break; } ostr << "</value>"; }
LLMaterialID::LLMaterialID(const LLSD& pMaterialID) { llassert(pMaterialID.isBinary()); parseFromBinary(pMaterialID.asBinary()); }
// virtual S32 LLSDBinaryFormatter::format(const LLSD& data, std::ostream& ostr, U32 options) const { S32 format_count = 1; switch(data.type()) { case LLSD::TypeMap: { ostr.put('{'); U32 size_nbo = htonl(data.size()); ostr.write((const char*)(&size_nbo), sizeof(U32)); LLSD::map_const_iterator iter = data.beginMap(); LLSD::map_const_iterator end = data.endMap(); for(; iter != end; ++iter) { ostr.put('k'); formatString((*iter).first, ostr); format_count += format((*iter).second, ostr); } ostr.put('}'); break; } case LLSD::TypeArray: { ostr.put('['); U32 size_nbo = htonl(data.size()); ostr.write((const char*)(&size_nbo), sizeof(U32)); LLSD::array_const_iterator iter = data.beginArray(); LLSD::array_const_iterator end = data.endArray(); for(; iter != end; ++iter) { format_count += format(*iter, ostr); } ostr.put(']'); break; } case LLSD::TypeUndefined: ostr.put('!'); break; case LLSD::TypeBoolean: if(data.asBoolean()) ostr.put(BINARY_TRUE_SERIAL); else ostr.put(BINARY_FALSE_SERIAL); break; case LLSD::TypeInteger: { ostr.put('i'); U32 value_nbo = htonl(data.asInteger()); ostr.write((const char*)(&value_nbo), sizeof(U32)); break; } case LLSD::TypeReal: { ostr.put('r'); F64 value_nbo = ll_htond(data.asReal()); ostr.write((const char*)(&value_nbo), sizeof(F64)); break; } case LLSD::TypeUUID: ostr.put('u'); ostr.write((const char*)(&(data.asUUID().mData)), UUID_BYTES); break; case LLSD::TypeString: ostr.put('s'); formatString(data.asString(), ostr); break; case LLSD::TypeDate: { ostr.put('d'); F64 value = data.asReal(); ostr.write((const char*)(&value), sizeof(F64)); break; } case LLSD::TypeURI: ostr.put('l'); formatString(data.asString(), ostr); break; case LLSD::TypeBinary: { // *FIX: memory inefficient. ostr.put('b'); std::vector<U8> buffer = data.asBinary(); U32 size_nbo = htonl(buffer.size()); ostr.write((const char*)(&size_nbo), sizeof(U32)); if(buffer.size()) ostr.write((const char*)&buffer[0], buffer.size()); break; } default: // *NOTE: This should never happen. ostr.put('!'); break; } return format_count; }
// virtual S32 LLSDNotationFormatter::format(const LLSD& data, std::ostream& ostr, U32 options) const { S32 format_count = 1; switch(data.type()) { case LLSD::TypeMap: { ostr << "{"; bool need_comma = false; LLSD::map_const_iterator iter = data.beginMap(); LLSD::map_const_iterator end = data.endMap(); for(; iter != end; ++iter) { if(need_comma) ostr << ","; need_comma = true; ostr << '\''; serialize_string((*iter).first, ostr); ostr << "':"; format_count += format((*iter).second, ostr); } ostr << "}"; break; } case LLSD::TypeArray: { ostr << "["; bool need_comma = false; LLSD::array_const_iterator iter = data.beginArray(); LLSD::array_const_iterator end = data.endArray(); for(; iter != end; ++iter) { if(need_comma) ostr << ","; need_comma = true; format_count += format(*iter, ostr); } ostr << "]"; break; } case LLSD::TypeUndefined: ostr << "!"; break; case LLSD::TypeBoolean: if(mBoolAlpha || #if( LL_WINDOWS || LL_MINGW32 || __GNUC__ > 2) (ostr.flags() & std::ios::boolalpha) #else (ostr.flags() & 0x0100) #endif ) { ostr << (data.asBoolean() ? NOTATION_TRUE_SERIAL : NOTATION_FALSE_SERIAL); } else { ostr << (data.asBoolean() ? 1 : 0); } break; case LLSD::TypeInteger: ostr << "i" << data.asInteger(); break; case LLSD::TypeReal: ostr << "r"; if(mRealFormat.empty()) { ostr << data.asReal(); } else { formatReal(data.asReal(), ostr); } break; case LLSD::TypeUUID: ostr << "u" << data.asUUID(); break; case LLSD::TypeString: ostr << '\''; serialize_string(data.asString(), ostr); ostr << '\''; break; case LLSD::TypeDate: ostr << "d\"" << data.asDate() << "\""; break; case LLSD::TypeURI: ostr << "l\""; serialize_string(data.asString(), ostr); ostr << "\""; break; case LLSD::TypeBinary: { // *FIX: memory inefficient. std::vector<U8> buffer = data.asBinary(); ostr << "b(" << buffer.size() << ")\""; if(buffer.size()) ostr.write((const char*)&buffer[0], buffer.size()); ostr << "\""; break; } default: // *NOTE: This should never happen. ostr << "!"; break; } return format_count; }
void DOHexEditor::setValue(const LLSD& value) { mValue = value.asBinary(); changedLength(); }
S32 LLSDXMLFormatter::format_impl(const LLSD& data, std::ostream& ostr, U32 options, U32 level) const { S32 format_count = 1; std::string pre; std::string post; if (options & LLSDFormatter::OPTIONS_PRETTY) { for (U32 i = 0; i < level; i++) { pre += " "; } post = "\n"; } switch(data.type()) { case LLSD::TypeMap: if(0 == data.size()) { ostr << pre << "<map />" << post; } else { ostr << pre << "<map>" << post; LLSD::map_const_iterator iter = data.beginMap(); LLSD::map_const_iterator end = data.endMap(); for(; iter != end; ++iter) { ostr << pre << "<key>" << escapeString((*iter).first) << "</key>" << post; format_count += format_impl((*iter).second, ostr, options, level + 1); } ostr << pre << "</map>" << post; } break; case LLSD::TypeArray: if(0 == data.size()) { ostr << pre << "<array />" << post; } else { ostr << pre << "<array>" << post; LLSD::array_const_iterator iter = data.beginArray(); LLSD::array_const_iterator end = data.endArray(); for(; iter != end; ++iter) { format_count += format_impl(*iter, ostr, options, level + 1); } ostr << pre << "</array>" << post; } break; case LLSD::TypeUndefined: ostr << pre << "<undef />" << post; break; case LLSD::TypeBoolean: ostr << pre << "<boolean>"; if(mBoolAlpha || #if( LL_WINDOWS || __GNUC__ > 2) (ostr.flags() & std::ios::boolalpha) #else (ostr.flags() & 0x0100) #endif ) { ostr << (data.asBoolean() ? "true" : "false"); } else { ostr << (data.asBoolean() ? 1 : 0); } ostr << "</boolean>" << post; break; case LLSD::TypeInteger: ostr << pre << "<integer>" << data.asInteger() << "</integer>" << post; break; case LLSD::TypeReal: ostr << pre << "<real>"; if(mRealFormat.empty()) { ostr << data.asReal(); } else { formatReal(data.asReal(), ostr); } ostr << "</real>" << post; break; case LLSD::TypeUUID: if(data.asUUID().isNull()) ostr << pre << "<uuid />" << post; else ostr << pre << "<uuid>" << data.asUUID() << "</uuid>" << post; break; case LLSD::TypeString: if(data.asString().empty()) ostr << pre << "<string />" << post; else ostr << pre << "<string>" << escapeString(data.asString()) <<"</string>" << post; break; case LLSD::TypeDate: ostr << pre << "<date>" << data.asDate() << "</date>" << post; break; case LLSD::TypeURI: ostr << pre << "<uri>" << escapeString(data.asString()) << "</uri>" << post; break; case LLSD::TypeBinary: { LLSD::Binary buffer = data.asBinary(); if(buffer.empty()) { ostr << pre << "<binary />" << post; } else { // *FIX: memory inefficient. // *TODO: convert to use LLBase64 ostr << pre << "<binary encoding=\"base64\">"; int b64_buffer_length = apr_base64_encode_len(buffer.size()); char* b64_buffer = new char[b64_buffer_length]; b64_buffer_length = apr_base64_encode_binary( b64_buffer, &buffer[0], buffer.size()); ostr.write(b64_buffer, b64_buffer_length - 1); delete[] b64_buffer; ostr << "</binary>" << post; } break; } default: // *NOTE: This should never happen. ostr << pre << "<undef />" << post; break; } return format_count; }
S32 LLSDNotationFormatter::format_impl(const LLSD& data, std::ostream& ostr, U32 options, U32 level) const { S32 format_count = 1; std::string pre; std::string post; if (options & LLSDFormatter::OPTIONS_PRETTY) { for (U32 i = 0; i < level; i++) { pre += " "; } post = "\n"; } switch(data.type()) { case LLSD::TypeMap: { if (0 != level) ostr << post << pre; ostr << "{"; std::string inner_pre; if (options & LLSDFormatter::OPTIONS_PRETTY) { inner_pre = pre + " "; } bool need_comma = false; LLSD::map_const_iterator iter = data.beginMap(); LLSD::map_const_iterator end = data.endMap(); for(; iter != end; ++iter) { if(need_comma) ostr << ","; need_comma = true; ostr << post << inner_pre << '\''; serialize_string((*iter).first, ostr); ostr << "':"; format_count += format_impl((*iter).second, ostr, options, level + 2); } ostr << post << pre << "}"; break; } case LLSD::TypeArray: { ostr << post << pre << "["; bool need_comma = false; LLSD::array_const_iterator iter = data.beginArray(); LLSD::array_const_iterator end = data.endArray(); for(; iter != end; ++iter) { if(need_comma) ostr << ","; need_comma = true; format_count += format_impl(*iter, ostr, options, level + 1); } ostr << "]"; break; } case LLSD::TypeUndefined: ostr << "!"; break; case LLSD::TypeBoolean: if(mBoolAlpha || #if( LL_WINDOWS || __GNUC__ > 2) (ostr.flags() & std::ios::boolalpha) #else (ostr.flags() & 0x0100) #endif ) { ostr << (data.asBoolean() ? NOTATION_TRUE_SERIAL : NOTATION_FALSE_SERIAL); } else { ostr << (data.asBoolean() ? 1 : 0); } break; case LLSD::TypeInteger: ostr << "i" << data.asInteger(); break; case LLSD::TypeReal: ostr << "r"; if(mRealFormat.empty()) { ostr << data.asReal(); } else { formatReal(data.asReal(), ostr); } break; case LLSD::TypeUUID: ostr << "u" << data.asUUID(); break; case LLSD::TypeString: ostr << '\''; serialize_string(data.asStringRef(), ostr); ostr << '\''; break; case LLSD::TypeDate: ostr << "d\"" << data.asDate() << "\""; break; case LLSD::TypeURI: ostr << "l\""; serialize_string(data.asString(), ostr); ostr << "\""; break; case LLSD::TypeBinary: { // *FIX: memory inefficient. const std::vector<U8>& buffer = data.asBinary(); ostr << "b(" << buffer.size() << ")\""; if(buffer.size()) { if (options & LLSDFormatter::OPTIONS_PRETTY_BINARY) { std::ios_base::fmtflags old_flags = ostr.flags(); ostr.setf( std::ios::hex, std::ios::basefield ); ostr << "0x"; for (size_t i = 0; i < buffer.size(); i++) { ostr << (int) buffer[i]; } ostr.flags(old_flags); } else { ostr.write((const char*)&buffer[0], buffer.size()); } } ostr << "\""; break; } default: // *NOTE: This should never happen. ostr << "!"; break; } return format_count; }