XMLRPC_VALUE xsm_system_multicall_cb(XMLRPC_SERVER server, XMLRPC_REQUEST input, void* userData) {
XMLRPC_VALUE xArray = XMLRPC_VectorRewind(XMLRPC_RequestGetData(input));
XMLRPC_VALUE xReturn = XMLRPC_CreateVector(0, xmlrpc_vector_array);
if (xArray) {
XMLRPC_VALUE xMethodIter = XMLRPC_VectorRewind(xArray);
while (xMethodIter) {
XMLRPC_REQUEST request = XMLRPC_RequestNew();
if(request) {
const char* methodName = XMLRPC_VectorGetStringWithID(xMethodIter, "methodName");
XMLRPC_VALUE params = XMLRPC_VectorGetValueWithID(xMethodIter, "params");
if(methodName && params) {
XMLRPC_VALUE xRandomArray = XMLRPC_CreateVector(0, xmlrpc_vector_array);
XMLRPC_RequestSetMethodName(request, methodName);
XMLRPC_RequestSetData(request, params);
XMLRPC_RequestSetRequestType(request, xmlrpc_request_call);
XMLRPC_AddValueToVector(xRandomArray,
XMLRPC_ServerCallMethod(server, request, userData));
XMLRPC_AddValueToVector(xReturn, xRandomArray);
}
XMLRPC_RequestFree(request, 1);
}
xMethodIter = XMLRPC_VectorNext(xArray);
}
}
return xReturn;
}
/*
* This handler takes a single parameter, which is an array containing
* between 100 and 200 elements. Each of the items is a string, your handler
* must return a string containing the concatenated text of the first and
* last elements.
*/
XMLRPC_VALUE validator1_moderateSizeArrayCheck (XMLRPC_SERVER server, XMLRPC_REQUEST xRequest, void* userData) {
XMLRPC_VALUE xReturn = NULL;
simplestring buf;
simplestring_init(&buf);
if(xRequest) {
XMLRPC_VALUE xArray = XMLRPC_VectorRewind(XMLRPC_RequestGetData(xRequest));
if(xArray) {
XMLRPC_VALUE xIter = XMLRPC_VectorRewind(xArray), xPrev = 0;
simplestring_add(&buf, XMLRPC_GetValueString(xIter));
/* TODO: Should add XMLRPC_VectorLast() call. Much more efficient */
while(xIter) {
xPrev = xIter;
xIter = XMLRPC_VectorNext(xArray);
}
simplestring_add(&buf, XMLRPC_GetValueString(xPrev));
}
}
xReturn = XMLRPC_CreateValueString(0, buf.str, buf.len);
return xReturn;
}
/* this complies with system.methodSignature as defined at
* http://xmlrpc.usefulinc.com/doc/sysmethodsig.html
*/
static XMLRPC_VALUE xi_system_method_signature_cb(XMLRPC_SERVER server, XMLRPC_REQUEST input, void* userData) {
const char* method = XMLRPC_GetValueString(XMLRPC_VectorRewind(XMLRPC_RequestGetData(input)));
XMLRPC_VALUE xResponse = NULL;
/* lazy loading of introspection data */
check_docs_loaded(server, userData);
if(method) {
server_method* sm = find_method(server, method);
if(sm && sm->desc) {
XMLRPC_VALUE xTypesArray = XMLRPC_CreateVector(NULL, xmlrpc_vector_array);
XMLRPC_VALUE xIter, xParams, xSig, xSigIter;
const char* type;
/* array of possible signatures. */
xResponse = XMLRPC_CreateVector(NULL, xmlrpc_vector_array);
/* find first signature */
xSig = XMLRPC_VectorGetValueWithID(sm->desc, xi_token_signatures);
xSigIter = XMLRPC_VectorRewind( xSig );
/* iterate through sigs */
while(xSigIter) {
/* first type is the return value */
type = XMLRPC_VectorGetStringWithID(XMLRPC_VectorRewind(
XMLRPC_VectorGetValueWithID(xSigIter, xi_token_returns)),
xi_token_type);
XMLRPC_AddValueToVector(xTypesArray,
XMLRPC_CreateValueString(NULL,
type ? type : type_to_str(xmlrpc_none, 0),
0));
/* the rest are parameters */
xParams = XMLRPC_VectorGetValueWithID(xSigIter, xi_token_params);
xIter = XMLRPC_VectorRewind(xParams);
/* iter through params, adding to types array */
while(xIter) {
XMLRPC_AddValueToVector(xTypesArray,
XMLRPC_CreateValueString(NULL,
XMLRPC_VectorGetStringWithID(xIter, xi_token_type),
0));
xIter = XMLRPC_VectorNext(xParams);
}
/* add types for this signature */
XMLRPC_AddValueToVector(xResponse, xTypesArray);
xSigIter = XMLRPC_VectorNext( xSig );
}
}
}
return xResponse;
}
/****f* SERVER/XMLRPC_ServerAddIntrospectionData
* NAME
* XMLRPC_ServerAddIntrospectionData
* SYNOPSIS
* int XMLRPC_ServerAddIntrospectionData(XMLRPC_SERVER server, XMLRPC_VALUE desc)
* FUNCTION
* updates server with additional introspection data
* INPUTS
* server - target server
* desc - introspection data, should be a struct generated by
* XMLRPC_IntrospectionCreateDescription ()
* RESULT
* int - 1 if success, else 0
* NOTES
* - function will fail if neither typeList nor methodList key is present in struct.
* - if method or type already exists, it will be replaced.
* - desc is never freed by the server. caller is responsible for cleanup.
* BUGS
* - horribly slow lookups. prime candidate for hash improvements.
* - uglier and more complex than I like to see for API functions.
* SEE ALSO
* XMLRPC_ServerAddIntrospectionData ()
* XMLRPC_ServerRegisterIntrospectionCallback ()
* XMLRPC_CleanupValue ()
* SOURCE
*/
int XMLRPC_ServerAddIntrospectionData(XMLRPC_SERVER server, XMLRPC_VALUE desc) {
int bSuccess = 0;
if(server && desc) {
XMLRPC_VALUE xNewTypes = XMLRPC_VectorGetValueWithID(desc, "typeList");
XMLRPC_VALUE xNewMethods = XMLRPC_VectorGetValueWithID(desc, "methodList");
XMLRPC_VALUE xServerTypes = XMLRPC_VectorGetValueWithID(server->xIntrospection, "typeList");
if(xNewMethods) {
XMLRPC_VALUE xMethod = XMLRPC_VectorRewind(xNewMethods);
while(xMethod) {
const char* name = XMLRPC_VectorGetStringWithID(xMethod, xi_token_name);
server_method* sm = find_method(server, name);
if(sm) {
if(sm->desc) {
XMLRPC_CleanupValue(sm->desc);
}
sm->desc = XMLRPC_CopyValue(xMethod);
bSuccess = 1;
}
xMethod = XMLRPC_VectorNext(xNewMethods);
}
}
if(xNewTypes) {
if(!xServerTypes) {
if(!server->xIntrospection) {
server->xIntrospection = XMLRPC_CreateVector(NULL, xmlrpc_vector_struct);
}
XMLRPC_AddValueToVector(server->xIntrospection, xNewTypes);
bSuccess = 1;
}
else {
XMLRPC_VALUE xIter = XMLRPC_VectorRewind(xNewTypes);
while(xIter) {
/* get rid of old values */
XMLRPC_VALUE xPrev = find_named_value(xServerTypes, XMLRPC_VectorGetStringWithID(xIter, xi_token_name));
if(xPrev) {
XMLRPC_VectorRemoveValue(xServerTypes, xPrev);
}
XMLRPC_AddValueToVector(xServerTypes, xIter);
bSuccess = 1;
xIter = XMLRPC_VectorNext(xNewTypes);
}
}
}
}
return bSuccess;
}
/* typically, most developer time will be spent writing these types of functions. */
XMLRPC_VALUE hello_callback(XMLRPC_SERVER server, XMLRPC_REQUEST request, void* userData)
{
char buf[1024];
#ifdef VERBOSE
XMLRPC_VALUE xParams = XMLRPC_RequestGetData(request); // obtain method params from request
XMLRPC_VALUE xFirstParam = XMLRPC_VectorRewind(xParams); // obtain first parameter
const char * name = XMLRPC_GetValueString(xFirstParam); // get string value
#else
const char* name = XMLRPC_GetValueString(XMLRPC_VectorRewind(XMLRPC_RequestGetData(request)));
#endif
snprintf(buf, sizeof(buf), "hello %s", name ? name : "stranger");
return XMLRPC_CreateValueString(NULL, buf, 0);
}
/* system.describeMethods() callback */
static XMLRPC_VALUE xi_system_describe_methods_cb(XMLRPC_SERVER server, XMLRPC_REQUEST input, void* userData) {
XMLRPC_VALUE xParams = XMLRPC_VectorRewind(XMLRPC_RequestGetData(input));
XMLRPC_VALUE xResponse = XMLRPC_CreateVector(NULL, xmlrpc_vector_struct);
XMLRPC_VALUE xMethodList = XMLRPC_CreateVector("methodList", xmlrpc_vector_array);
XMLRPC_VALUE xTypeList = NULL;
int bAll = 1;
/* lazy loading of introspection data */
check_docs_loaded(server, userData);
xTypeList = XMLRPC_VectorGetValueWithID(server->xIntrospection, "typeList");
XMLRPC_AddValueToVector(xResponse, xTypeList);
XMLRPC_AddValueToVector(xResponse, xMethodList);
/* check if we have any param */
if(xParams) {
/* check if string or vector (1 or n) */
XMLRPC_VALUE_TYPE type = XMLRPC_GetValueType(xParams);
if(type == xmlrpc_string) {
/* just one. spit it out. */
describe_method(server, xMethodList, XMLRPC_GetValueString(xParams));
bAll = 0;
}
else if(type == xmlrpc_vector) {
/* multiple. spit all out */
XMLRPC_VALUE xIter = XMLRPC_VectorRewind(xParams);
while(xIter) {
describe_method(server, xMethodList, XMLRPC_GetValueString(xIter));
xIter = XMLRPC_VectorNext(xParams);
}
bAll = 0;
}
}
/* otherwise, default to sending all methods */
if(bAll) {
q_iter qi = Q_Iter_Head_F(&server->methodlist);
while( qi ) {
server_method* sm = Q_Iter_Get_F(qi);
if(sm) {
XMLRPC_AddValueToVector(xMethodList, sm->desc);
}
qi = Q_Iter_Next_F(qi);
}
}
return xResponse;
}
/*
* This handler takes a single parameter, a string, that contains any number
* of predefined entities, namely <, >, &, ' and ".
*
* Your handler must return a struct that contains five fields, all numbers:
* ctLeftAngleBrackets, ctRightAngleBrackets, ctAmpersands, ctApostrophes,
* ctQuotes.
*
* To validate, the numbers must be correct.
*/
XMLRPC_VALUE validator1_countTheEntities (XMLRPC_SERVER server, XMLRPC_REQUEST xRequest, void* userData) {
XMLRPC_VALUE xStruct = XMLRPC_CreateVector(0, xmlrpc_vector_struct);
int counts[256] = {0};
//returns struct
if(xRequest) {
XMLRPC_VALUE xString = XMLRPC_VectorRewind(XMLRPC_RequestGetData(xRequest));
const char* pString = XMLRPC_GetValueString(xString);
if(pString) {
const unsigned char* p = (const unsigned char*)pString;
while(p && *p != 0) {
counts[*p] ++;
p++;
}
}
}
XMLRPC_VectorAppendInt(xStruct, "ctLeftAngleBrackets", counts['<']);
XMLRPC_VectorAppendInt(xStruct, "ctRightAngleBrackets", counts['>']);
XMLRPC_VectorAppendInt(xStruct, "ctAmpersands", counts['&']);
XMLRPC_VectorAppendInt(xStruct, "ctApostrophes", counts['\'']);
XMLRPC_VectorAppendInt(xStruct, "ctQuotes", counts['"']);
return xStruct;
}
/* performs heuristics on an xmlrpc_vector_array to determine
* appropriate soap arrayType string.
*/
static const char* get_array_soap_type(XMLRPC_VALUE node) {
XMLRPC_VALUE_TYPE_EASY type = xmlrpc_type_none;
XMLRPC_VALUE xIter = XMLRPC_VectorRewind(node);
int loopCount = 0;
const char* soapType = TOKEN_ANY;
type = XMLRPC_GetValueTypeEasy(xIter);
xIter = XMLRPC_VectorNext(node);
while (xIter) {
/* 50 seems like a decent # of loops. That will likely
* cover most cases. Any more and we start to sacrifice
* performance.
*/
if ( (XMLRPC_GetValueTypeEasy(xIter) != type) || loopCount >= 50) {
type = xmlrpc_type_none;
break;
}
loopCount ++;
xIter = XMLRPC_VectorNext(node);
}
switch (type) {
case xmlrpc_type_none:
soapType = TOKEN_ANY;
break;
case xmlrpc_type_empty:
soapType = TOKEN_NULL;
break;
case xmlrpc_type_int:
soapType = TOKEN_INT;
break;
case xmlrpc_type_double:
soapType = TOKEN_DOUBLE;
break;
case xmlrpc_type_boolean:
soapType = TOKEN_BOOLEAN;
break;
case xmlrpc_type_string:
soapType = TOKEN_STRING;
break;
case xmlrpc_type_base64:
soapType = TOKEN_BASE64;
break;
case xmlrpc_type_datetime:
soapType = TOKEN_DATETIME;
break;
case xmlrpc_type_struct:
soapType = TOKEN_STRUCT;
break;
case xmlrpc_type_array:
soapType = TOKEN_ARRAY;
break;
case xmlrpc_type_mixed:
soapType = TOKEN_STRUCT;
break;
}
return soapType;
}
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);
}
}
/* iterates through a list of structs and finds the one with key "name" matching
* needle. slow, would benefit from a struct key hash.
*/
static inline XMLRPC_VALUE find_named_value(XMLRPC_VALUE list, const char* needle) {
XMLRPC_VALUE xIter = XMLRPC_VectorRewind(list);
while(xIter) {
const char* name = XMLRPC_VectorGetStringWithID(xIter, xi_token_name);
if(name && !strcmp(name, needle)) {
return xIter;
}
xIter = XMLRPC_VectorNext(list);
}
return NULL;
}
/*
* 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;
}
/*
* This handler takes a single parameter, an array of structs, each of which
* contains at least three elements named moe, larry and curly, all <i4>s.
* Your handler must add all the struct elements named curly and return the
* result.
*/
XMLRPC_VALUE validator1_arrayOfStructsTest (XMLRPC_SERVER server, XMLRPC_REQUEST xRequest, void* userData) {
XMLRPC_VALUE xReturn = NULL;
int iCurly = 0;
if(xRequest) {
XMLRPC_VALUE xArray = XMLRPC_VectorRewind(XMLRPC_RequestGetData(xRequest));
if(xArray) {
XMLRPC_VALUE xIter = XMLRPC_VectorRewind(xArray);
while(xIter) {
iCurly += XMLRPC_VectorGetIntWithID(xIter, "curly");
xIter = XMLRPC_VectorNext(xArray);
}
}
}
xReturn = XMLRPC_CreateValueInt(0, iCurly);
return xReturn;
}
// 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;
}
/*
* This handler takes six parameters, and returns an array containing all the
* parameters.
*/
XMLRPC_VALUE validator1_manyTypesTest (XMLRPC_SERVER server, XMLRPC_REQUEST xRequest, void* userData) {
XMLRPC_VALUE xArray = XMLRPC_CreateVector(0, xmlrpc_vector_array);
if(xRequest && xArray) {
XMLRPC_VALUE xParams = XMLRPC_RequestGetData(xRequest);
XMLRPC_VALUE xIter = XMLRPC_VectorRewind(xParams);
while(xIter) {
XMLRPC_AddValueToVector(xArray, XMLRPC_CopyValue(xIter));
xIter = XMLRPC_VectorNext(xParams);
}
}
return xArray;
}
XMLRPC_VALUE XMLRPC::getNextValue()
{
XMLRPC_VALUE params = XMLRPC_RequestGetData(xmlrpc_request);
XMLRPC_VALUE param;
if(doRewind)
{
doRewind = false;
param = XMLRPC_VectorRewind(params);
}else
param = XMLRPC_VectorNext(params);
#if BTG_EXTERNALIZATION_DEBUG
BTG_NOTICE(logWrapper(), "XMLRPC::getNextValue() retrieved param of type " << XMLRPC_GetValueType(param));
#endif
return param;
}
/*
* This handler takes a single parameter, a struct, containing at least three
* elements named moe, larry and curly, all <i4>s. Your handler must add the
* three numbers and return the result.
*/
XMLRPC_VALUE validator1_easyStructTest (XMLRPC_SERVER server, XMLRPC_REQUEST xRequest, void* userData) {
XMLRPC_VALUE xReturn = NULL;
int iSum = 0;
if(xRequest) {
XMLRPC_VALUE xStruct = XMLRPC_VectorRewind(XMLRPC_RequestGetData(xRequest));
if(xStruct) {
iSum += XMLRPC_VectorGetIntWithID(xStruct, "curly");
iSum += XMLRPC_VectorGetIntWithID(xStruct, "moe");
iSum += XMLRPC_VectorGetIntWithID(xStruct, "larry");
}
}
xReturn = XMLRPC_CreateValueInt(0, iSum);
return xReturn;
}
/* this complies with system.methodHelp as defined at
* http://xmlrpc.usefulinc.com/doc/sysmethhelp.html
*/
static XMLRPC_VALUE xi_system_method_help_cb(XMLRPC_SERVER server, XMLRPC_REQUEST input, void* userData) {
const char* method = XMLRPC_GetValueString(XMLRPC_VectorRewind(XMLRPC_RequestGetData(input)));
XMLRPC_VALUE xResponse = NULL;
/* lazy loading of introspection data */
check_docs_loaded(server, userData);
if(method) {
server_method* sm = find_method(server, method);
if(sm && sm->desc) {
const char* help = XMLRPC_VectorGetStringWithID(sm->desc, xi_token_purpose);
/* returns a documentation string, or empty string */
xResponse = XMLRPC_CreateValueString(NULL, help ? help : xi_token_empty, 0);
}
}
return xResponse;
}
/*
* This handler takes a single parameter, a struct, that models a daily
* calendar. At the top level, there is one struct for each year. Each year
* is broken down into months, and months into days. Most of the days are
* empty in the struct you receive, but the entry for April 1, 2000 contains
* a least three elements named moe, larry and curly, all <i4>s. Your
* handler must add the three numbers and return the result.
*
* Ken MacLeod: "This description isn't clear, I expected '2000.April.1' when
* in fact it's '2000.04.01'. Adding a note saying that month and day are
* two-digits with leading 0s, and January is 01 would help." Done.
*/
XMLRPC_VALUE validator1_nestedStructTest (XMLRPC_SERVER server, XMLRPC_REQUEST xRequest, void* userData) {
XMLRPC_VALUE xReturn = NULL;
XMLRPC_VALUE xParams = XMLRPC_RequestGetData(xRequest);
int iSum = 0;
XMLRPC_VALUE xStruct = XMLRPC_VectorRewind(xParams);
XMLRPC_VALUE xYear = XMLRPC_VectorGetValueWithID(xStruct, "2000");
XMLRPC_VALUE xMonth = XMLRPC_VectorGetValueWithID(xYear, "04");
XMLRPC_VALUE xDay = XMLRPC_VectorGetValueWithID(xMonth, "01");
iSum += XMLRPC_VectorGetIntWithID(xDay, "larry");
iSum += XMLRPC_VectorGetIntWithID(xDay, "curly");
iSum += XMLRPC_VectorGetIntWithID(xDay, "moe");
xReturn = XMLRPC_CreateValueInt(0, iSum);
return xReturn;
}
LLIOPipe::EStatus LLFilterXMLRPCRequest2LLSD::process_impl(
const LLChannelDescriptors& channels,
buffer_ptr_t& buffer,
bool& eos,
LLSD& context,
LLPumpIO* pump)
{
LLFastTimer t(FTM_PROCESS_XMLRPC2LLSD_REQUEST);
PUMP_DEBUG;
if(!eos) return STATUS_BREAK;
if(!buffer) return STATUS_ERROR;
PUMP_DEBUG;
// *FIX: This technique for reading data is far from optimal. We
// need to have some kind of istream interface into the xml
// parser...
S32 bytes = buffer->countAfter(channels.in(), NULL);
if(!bytes) return STATUS_ERROR;
char* buf = new char[bytes + 1];
buf[bytes] = '\0';
buffer->readAfter(channels.in(), NULL, (U8*)buf, bytes);
//lldebugs << "xmlrpc request: " << buf << llendl;
// Check the value in the buffer. XMLRPC_REQUEST_FromXML will report a error code 4 if
// values that are less than 0x20 are passed to it, except
// 0x09: Horizontal tab; 0x0a: New Line; 0x0d: Carriage
U8* cur_pBuf = (U8*)buf;
U8 cur_char;
for (S32 i=0; i<bytes; i++)
{
cur_char = *cur_pBuf;
if ( cur_char < 0x20
&& 0x09 != cur_char
&& 0x0a != cur_char
&& 0x0d != cur_char )
{
*cur_pBuf = '?';
}
++cur_pBuf;
}
PUMP_DEBUG;
XMLRPC_REQUEST request = XMLRPC_REQUEST_FromXML(
buf,
bytes,
NULL);
if(!request)
{
llwarns << "XML -> SD Request process parse error." << llendl;
delete[] buf;
return STATUS_ERROR;
}
PUMP_DEBUG;
LLBufferStream stream(channels, buffer.get());
stream.precision(DEFAULT_PRECISION);
const char* name = XMLRPC_RequestGetMethodName(request);
stream << LLSDRPC_REQUEST_HEADER_1 << (name ? name : "")
<< LLSDRPC_REQUEST_HEADER_2;
XMLRPC_VALUE param = XMLRPC_RequestGetData(request);
if(param)
{
PUMP_DEBUG;
S32 size = XMLRPC_VectorSize(param);
if(size > 1)
{
// if there are multiple parameters, stuff the values into
// an array so that the next step in the chain can read them.
stream << "[";
}
XMLRPC_VALUE current = XMLRPC_VectorRewind(param);
bool needs_comma = false;
while(current)
{
if(needs_comma)
{
stream << ",";
}
needs_comma = true;
stream_out(stream, current);
current = XMLRPC_VectorNext(param);
}
if(size > 1)
{
// close the array
stream << "]";
}
}
stream << LLSDRPC_REQUEST_FOOTER << std::flush;
XMLRPC_RequestFree(request, 1);
delete[] buf;
PUMP_DEBUG;
return STATUS_DONE;
}
// 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;
}
LLXMLRPCValue LLXMLRPCValue::rewind()
{
return LLXMLRPCValue(XMLRPC_VectorRewind(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;
}
/*
* This handler takes a single parameter, a struct. Your handler must return
* the struct.
*/
XMLRPC_VALUE validator1_echoStructTest (XMLRPC_SERVER server, XMLRPC_REQUEST xRequest, void* userData) {
XMLRPC_VALUE xReturn = XMLRPC_CopyValue(XMLRPC_VectorRewind(XMLRPC_RequestGetData(xRequest)));
return xReturn;
}
/* 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;
}
