// STATIC ProtocolUtilities::BuddyListPtr BuddyListParser::ExtractBuddyListFromXMLRPCReply(XmlRpcEpi &call) { XmlRpcCall *xmlrpcCall = call.GetXMLRPCCall(); if (!xmlrpcCall) throw XmlRpcException("Failed to read buddy list, no XMLRPC Reply to read!"); XMLRPC_REQUEST request = xmlrpcCall->GetReply(); if (!request) throw XmlRpcException("Failed to read buddy list, no XMLRPC Reply to read!"); XMLRPC_VALUE result = XMLRPC_RequestGetData(request); if (!result) throw XmlRpcException("Failed to read buddy list, the XMLRPC Reply did not contain any data!"); XMLRPC_VALUE buddy_list_node = XMLRPC_VectorGetValueWithID(result, "buddy-list"); if (!buddy_list_node || XMLRPC_GetValueType(buddy_list_node) != xmlrpc_vector) throw XmlRpcException("Failed to read buddy list, buddy-list in the reply was not properly formed!"); ProtocolUtilities::BuddyListPtr buddy_list = ProtocolUtilities::BuddyListPtr(new ProtocolUtilities::BuddyList()); XMLRPC_VALUE item = XMLRPC_VectorRewind(buddy_list_node); while(item) { XMLRPC_VALUE_TYPE type = XMLRPC_GetValueType(item); if (type == xmlrpc_vector) // xmlrpc-epi handles structs as arrays. { RexUUID id; int rights_given = 0; int rights_has = 0; XMLRPC_VALUE val = XMLRPC_VectorGetValueWithID(item, "buddy_id"); if (val && XMLRPC_GetValueType(val) == xmlrpc_string) id.FromString( XMLRPC_GetValueString(val) ); val = XMLRPC_VectorGetValueWithID(item, "buddy_rights_given"); if (val && XMLRPC_GetValueType(val) == xmlrpc_type_int) rights_given = XMLRPC_GetValueInt(val); val = XMLRPC_VectorGetValueWithID(item, "buddy_rights_has"); if (val && XMLRPC_GetValueType(val) == xmlrpc_type_int) rights_has = XMLRPC_GetValueInt(val); ProtocolUtilities::Buddy *buddy = new ProtocolUtilities::Buddy(id, rights_given, rights_has); buddy_list->AddBuddy(buddy); } item = XMLRPC_VectorNext(buddy_list_node); } return buddy_list; }
/* input: an XMLRPC_VALUE representing a fault struct in xml-rpc style. * output: an XMLRPC_VALUE representing a fault struct in soap style, * with xmlrpc codes mapped to soap codes, and all other values preserved. * note that the returned value is a completely new value, and must be freed. * the input value is untouched. */ static XMLRPC_VALUE gen_fault_xmlrpc(XMLRPC_VALUE node, xml_element* el_target) { XMLRPC_VALUE xDup = XMLRPC_DupValueNew(node); XMLRPC_VALUE xCode = XMLRPC_VectorGetValueWithID(xDup, TOKEN_XMLRPC_FAULTCODE); XMLRPC_VALUE xStr = XMLRPC_VectorGetValueWithID(xDup, TOKEN_XMLRPC_FAULTSTRING); XMLRPC_SetValueID(xCode, TOKEN_SOAP_FAULTCODE, 0); XMLRPC_SetValueID(xStr, TOKEN_SOAP_FAULTSTRING, 0); /* rough mapping of xmlrpc fault codes to soap codes */ switch (XMLRPC_GetValueInt(xCode)) { case -32700: /* "parse error. not well formed", */ case -32701: /* "parse error. unsupported encoding" */ case -32702: /* "parse error. invalid character for encoding" */ case -32600: /* "server error. invalid xml-rpc. not conforming to spec." */ case -32601: /* "server error. requested method not found" */ case -32602: /* "server error. invalid method parameters" */ XMLRPC_SetValueString(xCode, "SOAP-ENV:Client", 0); break; case -32603: /* "server error. internal xml-rpc error" */ case -32500: /* "application error" */ case -32400: /* "system error" */ case -32300: /* "transport error */ XMLRPC_SetValueString(xCode, "SOAP-ENV:Server", 0); break; } return xDup; }
/* * This handler takes one parameter, and returns a struct containing three * elements, times10, times100 and times1000, the result of multiplying the * number by 10, 100 and 1000. */ XMLRPC_VALUE validator1_simpleStructReturnTest (XMLRPC_SERVER server, XMLRPC_REQUEST xRequest, void* userData) { XMLRPC_VALUE xStruct = XMLRPC_CreateVector(0, xmlrpc_vector_struct); int iIncoming = XMLRPC_GetValueInt(XMLRPC_VectorRewind(XMLRPC_RequestGetData(xRequest))); XMLRPC_AddValuesToVector(xStruct, XMLRPC_CreateValueInt("times10", iIncoming * 10), XMLRPC_CreateValueInt("times100", iIncoming * 100), XMLRPC_CreateValueInt("times1000", iIncoming * 1000), NULL); return xStruct; }
t_int XMLRPC::genericSDTDeserialize(destinationType *_destination) { destinationType d; XMLRPC_VALUE v=getNextValue(); if(XMLRPC_GetValueType(v) != xmlrpc_int) { return 0; } d = XMLRPC_GetValueInt(v); (*_destination) = d; return sizeof(d); }
bool XMLRPC::getByte(t_byte & _byte) { XMLRPC_VALUE v = getNextValue(); if(XMLRPC_GetValueType(v) != xmlrpc_int) { return 0; } int res = XMLRPC_GetValueInt(v); _byte = static_cast<t_byte>(res); success(); return true; }
static void parseOptionInto( const std::string& id, XMLRPC_VALUE option, LLUserAuth::options_t& options) { std::string key; std::string val; XMLRPC_VALUE_TYPE_EASY type; XMLRPC_VALUE row = XMLRPC_VectorRewind(option); while(row) { XMLRPC_VALUE opt = XMLRPC_VectorRewind(row); LLUserAuth::response_t responses; while(opt) { key.assign(XMLRPC_GetValueID(opt)); //llinfos << "option key: " << key << llendl; type = XMLRPC_GetValueTypeEasy(opt); if(xmlrpc_type_string == type) { val.assign(XMLRPC_GetValueString(opt)); //llinfos << "string val: " << val << llendl; } else if(xmlrpc_type_int == type) { val = llformat("%d", XMLRPC_GetValueInt(opt)); //llinfos << "int val: " << val << llendl; } else if(xmlrpc_type_double == type) { val = llformat("%g", XMLRPC_GetValueDouble(opt)); //llinfos << "double val: " << val << llendl; } else { // Can't understand the type val = "???"; //llinfos << "unknown value type: " << type << llendl; } responses.insert(LLUserAuth::response_t::value_type(key, val)); opt = XMLRPC_VectorNext(row); } options.push_back(responses); row = XMLRPC_VectorNext(option); } }
// this is a c function here since it's really an implementation // detail that requires a header file just get the definition of the // parameters. LLIOPipe::EStatus stream_out(std::ostream& ostr, XMLRPC_VALUE value) { XMLRPC_VALUE_TYPE_EASY type = XMLRPC_GetValueTypeEasy(value); LLIOPipe::EStatus status = LLIOPipe::STATUS_OK; switch(type) { case xmlrpc_type_base64: { S32 len = XMLRPC_GetValueStringLen(value); const char* buf = XMLRPC_GetValueBase64(value); ostr << " b("; if((len > 0) && buf) { ostr << len << ")\""; ostr.write(buf, len); ostr << "\""; } else { ostr << "0)\"\""; } break; } case xmlrpc_type_boolean: //lldebugs << "stream_out() bool" << llendl; ostr << " " << (XMLRPC_GetValueBoolean(value) ? "true" : "false"); break; case xmlrpc_type_datetime: ostr << " d\"" << XMLRPC_GetValueDateTime_ISO8601(value) << "\""; break; case xmlrpc_type_double: ostr << " r" << XMLRPC_GetValueDouble(value); //lldebugs << "stream_out() double" << XMLRPC_GetValueDouble(value) // << llendl; break; case xmlrpc_type_int: ostr << " i" << XMLRPC_GetValueInt(value); //lldebugs << "stream_out() integer:" << XMLRPC_GetValueInt(value) // << llendl; break; case xmlrpc_type_string: //lldebugs << "stream_out() string: " << str << llendl; ostr << " s(" << XMLRPC_GetValueStringLen(value) << ")'" << XMLRPC_GetValueString(value) << "'"; break; case xmlrpc_type_array: // vector case xmlrpc_type_mixed: // vector { //lldebugs << "stream_out() array" << llendl; ostr << " ["; U32 needs_comma = 0; XMLRPC_VALUE current = XMLRPC_VectorRewind(value); while(current && (LLIOPipe::STATUS_OK == status)) { if(needs_comma++) ostr << ","; status = stream_out(ostr, current); current = XMLRPC_VectorNext(value); } ostr << "]"; break; } case xmlrpc_type_struct: // still vector { //lldebugs << "stream_out() struct" << llendl; ostr << " {"; std::string name; U32 needs_comma = 0; XMLRPC_VALUE current = XMLRPC_VectorRewind(value); while(current && (LLIOPipe::STATUS_OK == status)) { if(needs_comma++) ostr << ","; name.assign(XMLRPC_GetValueID(current)); ostr << "'" << LLSDNotationFormatter::escapeString(name) << "':"; status = stream_out(ostr, current); current = XMLRPC_VectorNext(value); } ostr << "}"; break; } case xmlrpc_type_empty: case xmlrpc_type_none: default: status = LLIOPipe::STATUS_ERROR; llwarns << "Found an empty xmlrpc type.." << llendl; // not much we can do here... break; }; return status; }
int LLXMLRPCValue::asInt() const { return XMLRPC_GetValueInt(mV); }
LLSD LLUserAuth::parseValues(UserAuthcode &auth_code, const std::string& key_pfx, XMLRPC_VALUE param) { auth_code = E_OK; LLSD responses; for(XMLRPC_VALUE current = XMLRPC_VectorRewind(param); current; current = XMLRPC_VectorNext(param)) { std::string key(XMLRPC_GetValueID(current)); lldebugs << "key: " << key_pfx << key << llendl; XMLRPC_VALUE_TYPE_EASY type = XMLRPC_GetValueTypeEasy(current); if(xmlrpc_type_string == type) { LLSD::String val(XMLRPC_GetValueString(current)); lldebugs << "val: " << val << llendl; responses.insert(key,val); } else if(xmlrpc_type_int == type) { LLSD::Integer val(XMLRPC_GetValueInt(current)); lldebugs << "val: " << val << llendl; responses.insert(key,val); } else if (xmlrpc_type_double == type) { LLSD::Real val(XMLRPC_GetValueDouble(current)); lldebugs << "val: " << val << llendl; responses.insert(key,val); } else if(xmlrpc_type_array == type) { // We expect this to be an array of submaps. Walk the array, // recursively parsing each submap and collecting them. LLSD array; int i = 0; // for descriptive purposes for (XMLRPC_VALUE row = XMLRPC_VectorRewind(current); row; row = XMLRPC_VectorNext(current), ++i) { // Recursive call. For the lower-level key_pfx, if 'key' // is "foo", pass "foo[0]:", then "foo[1]:", etc. In the // nested call, a subkey "bar" will then be logged as // "foo[0]:bar", and so forth. // Parse the scalar subkey/value pairs from this array // entry into a temp submap. Collect such submaps in 'array'. std::string key_prefix = key_pfx; array.append(parseValues(auth_code, STRINGIZE(key_pfx << key << '[' << i << "]:"), row)); } // Having collected an 'array' of 'submap's, insert that whole // 'array' as the value of this 'key'. responses.insert(key, array); } else if (xmlrpc_type_struct == type) { LLSD submap = parseValues(auth_code, STRINGIZE(key_pfx << key << ':'), current); responses.insert(key, submap); } else { // whoops - unrecognized type llwarns << "Unhandled xmlrpc type " << type << " for key " << key_pfx << key << LL_ENDL; responses.insert(key, STRINGIZE("<bad XMLRPC type " << type << '>')); auth_code = E_UNHANDLED_ERROR; } } return responses; }
xml_element* XMLRPC_to_xml_element_worker(XMLRPC_VALUE current_vector, XMLRPC_VALUE node, XMLRPC_REQUEST_TYPE request_type, int depth) { #define BUF_SIZE 512 xml_element* root = NULL; if (node) { char buf[BUF_SIZE]; XMLRPC_VALUE_TYPE type = XMLRPC_GetValueType(node); XMLRPC_VECTOR_TYPE vtype = XMLRPC_GetVectorType(node); xml_element* elem_val = xml_elem_new(); /* special case for when root element is not an array */ if (depth == 0 && !(type == xmlrpc_vector && vtype == xmlrpc_vector_array && request_type == xmlrpc_request_call) ) { int bIsFault = (vtype == xmlrpc_vector_struct && XMLRPC_VectorGetValueWithID(node, ELEM_FAULTCODE)); xml_element* next_el = XMLRPC_to_xml_element_worker(NULL, node, request_type, depth + 1); if (next_el) { Q_PushTail(&elem_val->children, next_el); } elem_val->name = strdup(bIsFault ? ELEM_FAULT : ELEM_PARAMS); } else { switch (type) { case xmlrpc_empty: /* treat null value as empty string in xmlrpc. */ case xmlrpc_string: elem_val->name = strdup(ELEM_STRING); simplestring_addn(&elem_val->text, XMLRPC_GetValueString(node), XMLRPC_GetValueStringLen(node)); break; case xmlrpc_int: elem_val->name = strdup(ELEM_INT); snprintf(buf, BUF_SIZE, "%i", XMLRPC_GetValueInt(node)); simplestring_add(&elem_val->text, buf); break; case xmlrpc_boolean: elem_val->name = strdup(ELEM_BOOLEAN); snprintf(buf, BUF_SIZE, "%i", XMLRPC_GetValueBoolean(node)); simplestring_add(&elem_val->text, buf); break; case xmlrpc_double: elem_val->name = strdup(ELEM_DOUBLE); snprintf(buf, BUF_SIZE, "%f", XMLRPC_GetValueDouble(node)); simplestring_add(&elem_val->text, buf); break; case xmlrpc_datetime: elem_val->name = strdup(ELEM_DATETIME); simplestring_add(&elem_val->text, XMLRPC_GetValueDateTime_ISO8601(node)); break; case xmlrpc_base64: { struct buffer_st buf; elem_val->name = strdup(ELEM_BASE64); base64_encode(&buf, XMLRPC_GetValueBase64(node), XMLRPC_GetValueStringLen(node)); simplestring_addn(&elem_val->text, buf.data, buf.offset ); buffer_delete(&buf); } break; case xmlrpc_vector: { XMLRPC_VECTOR_TYPE my_type = XMLRPC_GetVectorType(node); XMLRPC_VALUE xIter = XMLRPC_VectorRewind(node); xml_element* root_vector_elem = elem_val; switch (my_type) { case xmlrpc_vector_array: { if(depth == 0) { elem_val->name = strdup(ELEM_PARAMS); } else { /* Hi my name is Dave and I like to make things as confusing * as possible, thus I will throw in this 'data' element * where it absolutely does not belong just so that people * cannot code arrays and structs in a similar and straight * forward manner. Have a good day. * * GRRRRRRRRR! */ xml_element* data = xml_elem_new(); data->name = strdup(ELEM_DATA); elem_val->name = strdup(ELEM_ARRAY); Q_PushTail(&elem_val->children, data); root_vector_elem = data; } } break; case xmlrpc_vector_mixed: /* not officially supported */ case xmlrpc_vector_struct: elem_val->name = strdup(ELEM_STRUCT); break; default: break; } /* recurse through sub-elements */ while ( xIter ) { xml_element* next_el = XMLRPC_to_xml_element_worker(node, xIter, request_type, depth + 1); if (next_el) { Q_PushTail(&root_vector_elem->children, next_el); } xIter = XMLRPC_VectorNext(node); } } break; default: break; } } { XMLRPC_VECTOR_TYPE vtype = XMLRPC_GetVectorType(current_vector); if (depth == 1) { xml_element* value = xml_elem_new(); value->name = strdup(ELEM_VALUE); /* yet another hack for the "fault" crap */ if (XMLRPC_VectorGetValueWithID(node, ELEM_FAULTCODE)) { root = value; } else { xml_element* param = xml_elem_new(); param->name = strdup(ELEM_PARAM); Q_PushTail(¶m->children, value); root = param; } Q_PushTail(&value->children, elem_val); } else if (vtype == xmlrpc_vector_struct || vtype == xmlrpc_vector_mixed) { xml_element* member = xml_elem_new(); xml_element* name = xml_elem_new(); xml_element* value = xml_elem_new(); member->name = strdup(ELEM_MEMBER); name->name = strdup(ELEM_NAME); value->name = strdup(ELEM_VALUE); simplestring_add(&name->text, XMLRPC_GetValueID(node)); Q_PushTail(&member->children, name); Q_PushTail(&member->children, value); Q_PushTail(&value->children, elem_val); root = member; } else if (vtype == xmlrpc_vector_array) { xml_element* value = xml_elem_new(); value->name = strdup(ELEM_VALUE); Q_PushTail(&value->children, elem_val); root = value; } else if (vtype == xmlrpc_vector_none) { /* no parent. non-op */ root = elem_val; } else { xml_element* value = xml_elem_new(); value->name = strdup(ELEM_VALUE); Q_PushTail(&value->children, elem_val); root = value; } } } return root; }
LLUserAuth::UserAuthcode LLUserAuth::parseResponse() { // The job of this function is to parse sCurlDownloadArea and // extract every member into either the mResponses or // mOptions. For now, we will only be looking at mResponses, which // will all be string => string pairs. UserAuthcode rv = E_UNHANDLED_ERROR; XMLRPC_REQUEST response = mTransaction->response(); if(!response) return rv; // clear out any old parsing mResponses.clear(); mOptions.clear(); // Now, parse everything std::string key; std::string val; XMLRPC_VALUE param = NULL; XMLRPC_VALUE current = NULL; XMLRPC_VALUE_TYPE_EASY type; param = XMLRPC_RequestGetData(response); if(!param) goto exit; current = XMLRPC_VectorRewind(param); while(current) { key.assign(XMLRPC_GetValueID(current)); lldebugs << "key: " << key << llendl; type = XMLRPC_GetValueTypeEasy(current); if(xmlrpc_type_string == type) { val.assign(XMLRPC_GetValueString(current)); lldebugs << "val: " << val << llendl; mResponses.insert(response_t::value_type(key, val)); } else if(xmlrpc_type_int == type) { val = llformat( "%d", XMLRPC_GetValueInt(current)); lldebugs << "val: " << val << llendl; mResponses.insert(response_t::value_type(key, val)); } else if(xmlrpc_type_array == type) { options_t options; parseOptionInto(key, current, options); mOptions.insert(all_options_t::value_type(key, options)); } else { // whoops - bad response llwarns << "Unhandled xmlrpc type, key, value: " << type << " " << key << " " << val << "." << llendl; rv = E_UNHANDLED_ERROR; break; } current = XMLRPC_VectorNext(param); rv = E_OK; } exit: return rv; }
xml_element* DANDARPC_to_xml_element_worker(XMLRPC_REQUEST request, XMLRPC_VALUE node) { #define BUF_SIZE 512 xml_element* root = NULL; if(node) { char buf[BUF_SIZE]; const char* id = XMLRPC_GetValueID(node); XMLRPC_VALUE_TYPE type = XMLRPC_GetValueType(node); XMLRPC_REQUEST_OUTPUT_OPTIONS output = XMLRPC_RequestGetOutputOptions(request); int bNoAddType = (type == xmlrpc_string && request && output && output->xml_elem_opts.verbosity == xml_elem_no_white_space); xml_element* elem_val = xml_elem_new(); const char* pAttrType = NULL; xml_element_attr* attr_type = bNoAddType ? NULL : emalloc(sizeof(xml_element_attr)); if(attr_type) { attr_type->key = estrdup(ATTR_TYPE); attr_type->val = 0; Q_PushTail(&elem_val->attrs, attr_type); } elem_val->name = (type == xmlrpc_vector) ? estrdup(ATTR_VECTOR) : estrdup(ATTR_SCALAR); if(id && *id) { xml_element_attr* attr_id = emalloc(sizeof(xml_element_attr)); if(attr_id) { attr_id->key = estrdup(ATTR_ID); attr_id->val = estrdup(id); Q_PushTail(&elem_val->attrs, attr_id); } } switch(type) { case xmlrpc_string: pAttrType = ATTR_STRING; simplestring_addn(&elem_val->text, XMLRPC_GetValueString(node), XMLRPC_GetValueStringLen(node)); break; case xmlrpc_int: pAttrType = ATTR_INT; snprintf(buf, BUF_SIZE, "%i", XMLRPC_GetValueInt(node)); simplestring_add(&elem_val->text, buf); break; case xmlrpc_boolean: pAttrType = ATTR_BOOLEAN; snprintf(buf, BUF_SIZE, "%i", XMLRPC_GetValueBoolean(node)); simplestring_add(&elem_val->text, buf); break; case xmlrpc_double: pAttrType = ATTR_DOUBLE; snprintf(buf, BUF_SIZE, "%f", XMLRPC_GetValueDouble(node)); simplestring_add(&elem_val->text, buf); break; case xmlrpc_datetime: pAttrType = ATTR_DATETIME; simplestring_add(&elem_val->text, XMLRPC_GetValueDateTime_ISO8601(node)); break; case xmlrpc_base64: { struct buffer_st buf; pAttrType = ATTR_BASE64; base64_encode_xmlrpc(&buf, XMLRPC_GetValueBase64(node), XMLRPC_GetValueStringLen(node)); simplestring_addn(&elem_val->text, buf.data, buf.offset ); buffer_delete(&buf); } break; case xmlrpc_vector: { XMLRPC_VECTOR_TYPE my_type = XMLRPC_GetVectorType(node); XMLRPC_VALUE xIter = XMLRPC_VectorRewind(node); switch(my_type) { case xmlrpc_vector_array: pAttrType = ATTR_ARRAY; break; case xmlrpc_vector_mixed: pAttrType = ATTR_MIXED; break; case xmlrpc_vector_struct: pAttrType = ATTR_STRUCT; break; default: break; } /* recurse through sub-elements */ while( xIter ) { xml_element* next_el = DANDARPC_to_xml_element_worker(request, xIter); if(next_el) { Q_PushTail(&elem_val->children, next_el); } xIter = XMLRPC_VectorNext(node); } } break; default: break; } if(pAttrType && attr_type && !bNoAddType) { attr_type->val = estrdup(pAttrType); } root = elem_val; } return root; }
/* translates data structures to soap/xml. recursive */ xml_element* SOAP_to_xml_element_worker(XMLRPC_REQUEST request, XMLRPC_VALUE node) { #define BUF_SIZE 128 xml_element* elem_val = NULL; if (node) { int bFreeNode = 0; /* sometimes we may need to free 'node' variable */ char buf[BUF_SIZE]; XMLRPC_VALUE_TYPE_EASY type = XMLRPC_GetValueTypeEasy(node); char* pName = NULL, *pAttrType = NULL; /* create our return value element */ elem_val = xml_elem_new(); switch (type) { case xmlrpc_type_struct: case xmlrpc_type_mixed: case xmlrpc_type_array: if (type == xmlrpc_type_array) { /* array's are _very_ special in soap. TODO: Should handle sparse/partial arrays here. */ /* determine soap array type. */ const char* type = get_array_soap_type(node); xml_element_attr* attr_array_type = NULL; /* specify array kids type and array size. */ snprintf(buf, sizeof(buf), "%s[%i]", type, XMLRPC_VectorSize(node)); attr_array_type = new_attr(TOKEN_ARRAY_TYPE, buf); Q_PushTail(&elem_val->attrs, attr_array_type); pAttrType = TOKEN_ARRAY; } /* check for fault, which is a rather special case. (can't these people design anything consistent/simple/elegant?) */ else if (type == xmlrpc_type_struct) { int fault_type = get_fault_type(node); if (fault_type) { if (fault_type == 1) { /* gen fault from xmlrpc style fault codes notice that we get a new node, which must be freed herein. */ node = gen_fault_xmlrpc(node, elem_val); bFreeNode = 1; } pName = TOKEN_FAULT; } } { /* recurse through sub-elements */ XMLRPC_VALUE xIter = XMLRPC_VectorRewind(node); while ( xIter ) { xml_element* next_el = SOAP_to_xml_element_worker(request, xIter); if (next_el) { Q_PushTail(&elem_val->children, next_el); } xIter = XMLRPC_VectorNext(node); } } break; /* handle scalar types */ case xmlrpc_type_empty: pAttrType = TOKEN_NULL; break; case xmlrpc_type_string: pAttrType = TOKEN_STRING; simplestring_addn(&elem_val->text, XMLRPC_GetValueString(node), XMLRPC_GetValueStringLen(node)); break; case xmlrpc_type_int: pAttrType = TOKEN_INT; snprintf(buf, BUF_SIZE, "%i", XMLRPC_GetValueInt(node)); simplestring_add(&elem_val->text, buf); break; case xmlrpc_type_boolean: pAttrType = TOKEN_BOOLEAN; snprintf(buf, BUF_SIZE, "%i", XMLRPC_GetValueBoolean(node)); simplestring_add(&elem_val->text, buf); break; case xmlrpc_type_double: pAttrType = TOKEN_DOUBLE; snprintf(buf, BUF_SIZE, "%f", XMLRPC_GetValueDouble(node)); simplestring_add(&elem_val->text, buf); break; case xmlrpc_type_datetime: { time_t tt = XMLRPC_GetValueDateTime(node); struct tm *tm = localtime (&tt); pAttrType = TOKEN_DATETIME; if(strftime (buf, BUF_SIZE, "%Y-%m-%dT%H:%M:%SZ", tm)) { simplestring_add(&elem_val->text, buf); } } break; case xmlrpc_type_base64: { struct buffer_st buf; pAttrType = TOKEN_BASE64; base64_encode_xmlrpc(&buf, XMLRPC_GetValueBase64(node), XMLRPC_GetValueStringLen(node)); simplestring_addn(&elem_val->text, buf.data, buf.offset ); buffer_delete(&buf); } break; break; default: break; } /* determining element's name is a bit tricky, due to soap semantics. */ if (!pName) { /* if the value's type is known... */ if (pAttrType) { /* see if it has an id (key). If so, use that as name, and type as an attribute. */ pName = (char*)XMLRPC_GetValueID(node); if (pName) { Q_PushTail(&elem_val->attrs, new_attr(TOKEN_TYPE, pAttrType)); } /* otherwise, use the type as the name. */ else { pName = pAttrType; } } /* if the value's type is not known... (a rare case?) */ else { /* see if it has an id (key). otherwise, default to generic "item" */ pName = (char*)XMLRPC_GetValueID(node); if (!pName) { pName = "item"; } } } elem_val->name = strdup(pName); /* cleanup */ if (bFreeNode) { XMLRPC_CleanupValue(node); } } return elem_val; }