void UDPEchoClient::onReadyRead () {
{
LockGuard guard (mMutex);
if (mState != WAIT) return; // ignoring; timeout.
// Check protocol
String from;
int fromPort;
ByteArrayPtr data = mSocket.recvFrom(&from,&fromPort);
if (!data) {
Log (LogWarning) << LOGID << "Could not read any data tough readyRead() signal" << std::endl;
return; // ?
}
String toParse (data->const_c_array(), data->size());
ArgumentList list;
sf::argSplit (toParse, &list);
// Format: TOKEN IP-Address Port
if (list.size() != 4 || list[0] != "condataReply") {
Log (LogInfo) << LOGID << "Invalid protocol in answer " << *data << ", token=" << list.size() << std::endl;
return; // invalid protocol
}
if (list[1] != mToken){
Log (LogInfo) << LOGID << "Token mismatch in answer " << *data << std::endl;
return; // invalid token
}
mState = READY;
mAddress = list[2];
mPort = atoi (list[3].c_str());
Log (LogInfo) << LOGID << "Successfully decoded echo answer: " << mAddress << ":" << mPort << " coming from " << from << ":" << fromPort << std::endl;
sf::cancelTimer(mTimeoutHandle);
}
mResultDelegate (NoError);
}
void InsertMacro(CMacro* Macro, std::wstring& Args)
{
tTextData Text;
ArgumentList Arguments;
splitArguments(Arguments,Args);
if ((int)Arguments.size() != Macro->getArgumentCount())
{
Logger::printError(Logger::Error,L"%s macro arguments (%d vs %d)",
(int)Arguments.size() > Macro->getArgumentCount() ? L"Too many" : L"Not enough",
Arguments.size(),Macro->getArgumentCount());
return;
}
Global.MacroNestingLevel++;
if (Global.MacroNestingLevel == ASSEMBLER_MACRO_NESTING_LEVEL)
{
Logger::printError(Logger::Error,L"Maximum macro nesting level reached");
return;
}
int MacroCounter = Macro->getIncreaseCounter();
for (int i = 0; i < Macro->getLineCount(); i++)
{
Text.buffer = Macro->getLine(i,Arguments,MacroCounter);
Text.buffer = Global.symbolTable.insertEquations(Text.buffer,Global.FileInfo.FileNum,Global.Section);
if (CheckEquLabel(Text.buffer) == false)
{
Text.buffer = checkLabel(Text.buffer,false);
splitLine(Text.buffer,Text.name,Text.params);
if (Text.name.size() == 0) continue;
bool macro = false;
for (size_t i = 0; i < Global.Macros.size(); i++)
{
if (Text.name.compare(Global.Macros[i]->getName()) == 0)
{
InsertMacro(Global.Macros[i],Text.params);
macro = true;
}
}
if (macro == true) continue;
if (Arch->AssembleDirective(Text.name,Text.params) == false)
{
Arch->AssembleOpcode(Text.name,Text.params);
}
}
}
Global.MacroNestingLevel--;
}
Variant Invoke(Variant &obj, const ArgumentList &arguments) override
{
UAssert( arguments.size( ) == THIS_ARG_COUNT,
"Invalid method arguments.\nExpected %i args but got %i.",
THIS_ARG_COUNT,
arguments.size( )
);
invoke<void, ArgTypes...>( obj, arguments );
return { };
}
CDirectiveIncbin::CDirectiveIncbin(ArgumentList& args)
{
fileName = getFullPathName(args[0].text);
if (fileExists(fileName) == false)
{
Logger::printError(Logger::FatalError,L"File %s not found",fileName);
return;
}
int inputFileSize = fileSize(fileName);
if (args.size() >= 2)
{
// load start address
if (ConvertExpression(args[1].text,startAddress) == false)
{
Logger::printError(Logger::FatalError,L"Invalid start address %s",args[1].text);
return;
}
if (startAddress >= inputFileSize)
{
Logger::printError(Logger::Error,L"Start address 0x%08X after end of file",startAddress);
return;
}
if (args.size() >= 3)
{
// load size too
if (ConvertExpression(args[2].text,loadSize) == false)
{
Logger::printError(Logger::FatalError,L"Invalid size %s",args[1].text);
return;
}
if (startAddress+loadSize > inputFileSize)
{
Logger::printError(Logger::Warning,L"Loading beyond file end, truncating");
loadSize = inputFileSize-startAddress;
}
} else {
loadSize = inputFileSize-startAddress;
}
} else {
startAddress = 0;
loadSize = inputFileSize;
}
g_fileManager->advanceMemory(loadSize);
}
bool measured_response_time(
const char* name,
ArgumentList const& arguments,
EvalState &state,
Value& result)
{
result.SetErrorValue();
std::string queue_id;
int mode = 0, seconds = 0;
// we check to make sure that we are passed at least one argument
if (arguments.size() <= 1) {
return false;
} else {
Value arg[3];
if (!(arguments[0]->Evaluate(state, arg[0]) && arg[0].IsStringValue(queue_id))) {
return false;
}
if (!(arguments[1]->Evaluate(state, arg[1]) && arg[1].IsIntegerValue(mode))) {
return false;
}
if (!(arguments[2]->Evaluate(state, arg[2]) && arg[2].IsIntegerValue(seconds))) {
return false;
}
}
if (mode) {
result.SetRealValue(lb_statistics(queue_id, avg, seconds));
} else {
result.SetRealValue(lb_statistics(queue_id, std_dev, seconds));
}
return true;
}
bool DirectiveData(ArgumentList& List, int flags)
{
bool ascii = false;
if (flags & DIRECTIVE_DATA_ASCII)
{
ascii = true;
flags &= ~DIRECTIVE_DATA_ASCII;
}
bool hasNonAscii = false;
for (size_t i = 0; i < List.size(); i++)
{
if (List[i].isString)
{
for (size_t k = 0; k < List[i].text.size(); k++)
{
if (List[i].text[k] >= 0x80)
hasNonAscii = true;
}
}
}
if (hasNonAscii)
Logger::printError(Logger::Warning,L"Non-ASCII character in data directive. Use .string instead");
CDirectiveData* Data = new CDirectiveData(List,flags,ascii);
AddAssemblerCommand(Data);
return true;
}
void Action::clearOutputAgumentValues() {
ArgumentList *outArgList = getOutputArgumentList();
int nArgs = outArgList->size();
for (int n = 0; n < nArgs; n++) {
Argument *arg = outArgList->getArgument(n);
arg->setValue("");
}
}
double Calculator::call(Lexer& lexer, string name)
{
SymEntry* sym = symbols.Get(name);
if(!sym)
{
throw Error::SyntaxError("undefined function "+name);
}
ArgumentList args = arguments(lexer);
switch(sym->type)
{
case SymEntry::SYS_FUNC:
{
SymSysFunc* sFunc = static_cast<SymSysFunc*>(sym);
if(args.size() != 1)
throw Error::SyntaxError("incorrect number of arguments");
return sFunc->func(args[0]);
}
case SymEntry::USR_FUNC:
{
SymUsrFunc* uFunc = static_cast<SymUsrFunc*>(sym);
if(args.size() != uFunc->params.size())
throw Error::SyntaxError("incorrect number of arguments");
map<string,double> argMap;
for(unsigned int i = 0; i < uFunc->params.size(); i++)
{
argMap[uFunc->params[i]] = args[i];
}
for(TokenList::const_iterator i = uFunc->func.begin(); i != uFunc->func.end(); i++)
{
Token tok = *i;
if(tok.Type == Token::NAME && argMap.count(tok.StringValue) > 0)
{
Token val(Token::NUMBER, argMap[tok.StringValue]);
lexer.push(val);
}
else
lexer.push(*i);
}
return expr(lexer);
}
default:
throw Error::SyntaxError("not a function: "+name);
}
}
void CMacro::loadArguments(ArgumentList& argumentList)
{
name = argumentList[0].text;
for (size_t i = 1; i < argumentList.size(); i++)
{
arguments.push_back(argumentList[i].text);
}
}
DirectiveObjImport::DirectiveObjImport(ArgumentList& args)
{
if (rel.init(args[0].text))
{
rel.exportSymbols();
if (args.size() == 2)
rel.writeCtor(args[1].text);
}
}
CDirectiveData::CDirectiveData(ArgumentList& Args, int SizePerUnit, bool asc)
{
TotalAmount = Args.size();
StrAmount = 0;
ExpAmount = 0;
for (int i = 0; i < TotalAmount; i++)
{
if (Args[i].isString == true)
{
StrAmount++;
} else {
ExpAmount++;
}
}
Entries = (tDirectiveDataEntry*) malloc(TotalAmount*sizeof(tDirectiveDataEntry));
ExpData = new CExpressionCommandList[ExpAmount];
switch (SizePerUnit)
{
case 1: case 2: case 4:
UnitSize = SizePerUnit;
ascii = asc;
break;
default:
Logger::printError(Logger::Error,L"Invalid data unit size %d",SizePerUnit);
return;
}
int ExpNum = 0;
SpaceNeeded = 0;
for (int i = 0; i < TotalAmount; i++)
{
if (Args[i].isString == true)
{
std::string tt = convertWStringToUtf8(Args[i].text);
char* t = (char*) tt.c_str();
int len = strlen(t);
Entries[i].String = true;
Entries[i].num = StrData.GetCount();
StrData.AddEntry((unsigned char*)t,len);
SpaceNeeded += len*UnitSize;
} else {
Entries[i].String = false;
Entries[i].num = ExpNum;
if (initExpression(ExpData[ExpNum++],Args[i].text) == false)
return;
SpaceNeeded += UnitSize;
}
}
g_fileManager->advanceMemory(SpaceNeeded);
}
static bool triple(
const char *,
const ArgumentList &arguments,
EvalState &state,
Value &result)
{
Value arg;
// takes exactly one argument
if( arguments.size() > 1 ) {
result.SetErrorValue( );
return true;
}
if( !arguments[0]->Evaluate( state, arg ) ) {
result.SetErrorValue( );
return false;
}
switch( arg.GetType( ) ) {
case Value::UNDEFINED_VALUE:
result.SetUndefinedValue( );
return true;
case Value::ERROR_VALUE:
case Value::CLASSAD_VALUE:
case Value::LIST_VALUE:
case Value::SLIST_VALUE:
case Value::STRING_VALUE:
case Value::ABSOLUTE_TIME_VALUE:
case Value::RELATIVE_TIME_VALUE:
case Value::BOOLEAN_VALUE:
result.SetErrorValue( );
return true;
case Value::INTEGER_VALUE:
int int_value;
arg.IsIntegerValue(int_value);
result.SetIntegerValue(3 * int_value);
return true;
case Value::REAL_VALUE:
{
double real_value;
arg.IsRealValue( real_value );
result.SetRealValue(3 * real_value);
return true;
}
default:
return false;
}
return false;
}
Argument *Action::getArgument(const std::string &name) {
ArgumentList *argList = getArgumentList();
int nArgs = argList->size();
for (int n = 0; n < nArgs; n++) {
Argument *arg = argList->getArgument(n);
const char *argName = arg->getName();
if (argName == NULL)
continue;
string argNameStr = argName;
if (argNameStr.compare(name) == 0)
return arg;
}
return NULL;
}
bool DirectiveOpen(ArgumentList& list, int flags)
{
if (list.size() == 2)
{
// open
CDirectiveFile* command = new CDirectiveFile(CDirectiveFile::Open,list);
AddAssemblerCommand(command);
} else {
// copy
CDirectiveFile* command = new CDirectiveFile(CDirectiveFile::Copy,list);
AddAssemblerCommand(command);
}
return true;
}
bool listAttrRegEx(const char *name,
const ArgumentList &arguments,
EvalState &state,
Value &result)
{
bool eval_successful = false;
result.SetErrorValue();
// We check to make sure that we passed exactly two arguments...
if (arguments.size() == 2) {
Value arg1;
std::string pattern;
// ...the first argument should evaluate to a string value...
if (arguments[0] -> Evaluate(state, arg1) &&
arg1.IsStringValue(pattern)) {
// ...the second argument should be an attribute reference
if (arguments[1] -> GetKind() == ExprTree::ATTRREF_NODE) {
// Now we compile the pattern...
regex_t re;
if( !regcomp( &re, pattern.c_str(), REG_EXTENDED|REG_NOSUB ) ) {
std::vector<std::string> attrs;
deep_find_attribute_if(&attrs, arguments[1], match_pattern(&re));
// if there is no matching attribute then the undefined
// value should be returned as result. Otherwise we have
// to create an exprlist containing the quoted names of
// the attributes matching the regex...
eval_successful = !attrs.empty();
if (!eval_successful) result.SetUndefinedValue();
else {
std::vector<ExprTree*> attrsList;
for(std::vector<std::string>::const_iterator a=attrs.begin();
a != attrs.end(); a++) {
Value value;
value.SetStringValue(*a);
attrsList.push_back( Literal::MakeLiteral(value) );
}
ExprList* e = ExprList::MakeExprList(attrsList);
e->SetParentScope(state.curAd);
result.SetListValue(e);
}
// dispose memory created by regcomp()
regfree( &re );
}
}
}
}
return eval_successful;
}
BOOST_FOREACH(ArgumentList argList, argLists)
{
proxyFile.oss << " % " << name << "(";
unsigned int i = 0;
BOOST_FOREACH(const Argument& arg, argList)
{
if(i != argList.size()-1)
proxyFile.oss << arg.type << " " << arg.name << ", ";
else
proxyFile.oss << arg.type << " " << arg.name;
i++;
}
proxyFile.oss << ")" << endl;
}
bool CDirectiveArea::LoadStart(ArgumentList &Args)
{
if (initExpression(SizeExpression,Args[0].text) == false)
return false;
Start = true;
if (Args.size() == 2)
{
if (initExpression(FillExpression,Args[1].text) == false)
return false;
}
return true;
}
void PrintDeviceInfo(Device *dev, int indent)
{
string indentStr;
GetIndentString(indent, indentStr);
const char *devName = dev->getFriendlyName();
cout << indentStr << devName << endl;
int i, n, j;
ServiceList *serviceList = dev->getServiceList();
int serviceCnt = serviceList->size();
for (n=0; n<serviceCnt; n++) {
Service *service = serviceList->getService(n);
cout << indentStr << " service[" << n << "] = "<< service->getServiceType() << endl;
ActionList *actionList = service->getActionList();
int actionCnt = actionList->size();
for (i=0; i<actionCnt; i++) {
Action *action = actionList->getAction(i);
cout << indentStr << " action[" << i << "] = "<< action->getName() << endl;
ArgumentList *argList = action->getArgumentList();
int argCnt = argList->size();
for (j=0; j<argCnt; j++) {
Argument *arg = argList->getArgument(j);
cout << indentStr << " arg[" << j << "] = " << arg->getName() << "(" << arg->getDirection() << ")";
StateVariable *stateVar = arg->getRelatedStateVariable();
if (stateVar != NULL)
cout << " - " << stateVar->getName();
cout << endl;
}
}
ServiceStateTable *stateTable = service->getServiceStateTable();
int varCnt = stateTable->size();
for (i=0; i<varCnt; i++) {
StateVariable *stateVar = stateTable->getStateVariable(i);
cout << indentStr << " stateVar[" << i << "] = " << stateVar->getName() << endl;
AllowedValueList *valueList = stateVar->getAllowedValueList();
int valueListCnt = valueList->size();
if (0 < valueListCnt) {
for (j=0; j<valueListCnt; j++)
cout << indentStr << " AllowedValueList[" << j << "] = " << valueList->getAllowedValue(j) << endl;
}
AllowedValueRange *valueRange = stateVar->getAllowedValueRange();
if (valueRange != NULL) {
cout << indentStr << " AllowedRange[minimum] = " << valueRange->getMinimum() << endl;
cout << indentStr << " AllowedRange[maximum] = " << valueRange->getMaximum() << endl;
cout << indentStr << " AllowedRange[step] = " << valueRange->getStep() << endl;
}
}
}
}
bool DirectiveString(ArgumentList& List, int flags)
{
ArgumentList NewList;
if (Global.Table.isLoaded() == false)
{
Logger::printError(Logger::Error,L"No table opened");
return false;
}
for (size_t i = 0; i < List.size(); i++)
{
if (List[i].isString)
{
ByteArray data = Global.Table.encodeString(List[i].text,false);
if (data.size() == 0 && List[i].text.size() != 0)
{
Logger::printError(Logger::Error,L"Failed to encode string");
return false;
}
for (int i = 0; i < data.size(); i++)
{
wchar_t str[32];
swprintf(str,32,L"0x%02X",data[i]);
NewList.add(str,false);
}
} else {
NewList.add(List[i].text,false);
}
}
if ((flags & DIRECTIVE_STR_NOTERMINATION) == 0)
{
ByteArray data = Global.Table.encodeTermination();
for (int i = 0; i < data.size(); i++)
{
wchar_t str[32];
swprintf(str,32,L"0x%02X",data[i]);
NewList.add(str,false);
}
}
CDirectiveData* Data = new CDirectiveData(NewList,1,false);
AddAssemblerCommand(Data);
return true;
}
CDirectiveAlign::CDirectiveAlign(ArgumentList& args)
{
if (args.size() >= 1)
{
if (ConvertExpression(args[0].text,alignment) == false)
{
Logger::printError(Logger::FatalError,L"Invalid alignment %s",args[0].text);
}
if (isPowerOfTwo(alignment) == false)
{
Logger::printError(Logger::Error,L"Invalid alignment %d",alignment);
}
} else {
alignment = Arch->GetWordSize();
}
int num = computePadding();
}
bool DirectiveInclude(ArgumentList& List, int flags)
{
std::wstring fileName = getFullPathName(List[0].text);
TextFile::Encoding encoding = TextFile::GUESS;
if (List.size() == 2)
encoding = getEncodingFromString(List[1].text);
int FileNum = Global.FileInfo.FileNum;
int LineNum = Global.FileInfo.LineNumber;
if (fileExists(fileName) == false)
{
Logger::printError(Logger::Error,L"Included file \"%s\" does not exist",fileName.c_str());
return false;
}
LoadAssemblyFile(fileName,encoding);
Global.FileInfo.FileNum = FileNum;
Global.FileInfo.LineNumber = LineNum;
return true;
}
//==============================================================================
int main (int argc, char **argv)
{
ConsoleLogger logger;
Logger::setCurrentLogger (&logger);
ConsoleUnitTestRunner runner;
ArgumentList args (argc, argv);
if (args.size() == 0)
{
runner.runAllTests();
}
else
{
if (args.containsOption ("--help|-h"))
{
std::cout << argv[0] << " [--help|-h] [--category category] [--list-categories]" << std::endl;
return 0;
}
if (args.containsOption ("--list-categories"))
{
for (auto& category : UnitTest::getAllCategories())
std::cout << category << std::endl;
return 0;
}
if (args.containsOption ("--category"))
runner.runTestsInCategory (args.getValueForOption ("--category"));
}
Logger::setCurrentLogger (nullptr);
for (int i = 0; i < runner.getNumResults(); ++i)
if (runner.getResult(i)->failures > 0)
return 1;
return 0;
}
bool DirectiveLoadTable(ArgumentList& List, int flags)
{
std::wstring fileName = getFullPathName(List[0].text);
if (fileExists(fileName) == false)
{
Logger::printError(Logger::Error,L"Table file \"%s\" does not exist",fileName.c_str());
return false;
}
TextFile::Encoding encoding = TextFile::GUESS;
if (List.size() == 2)
encoding = getEncodingFromString(List[1].text);
if (Global.Table.load(fileName,encoding) == false)
{
Logger::printError(Logger::Error,L"Invalid table file \"%s\"",fileName.c_str());
return false;
}
return true;
}
void processMacro(istream* input, Define define)
{
Token tok = get_token(input, true, false);
ArgumentList args;
if(tok.token == TOK_LPAREN)
{
args = arguments(input);
}
if (args.size() != define.params.size())
{
cerr << "Macro argument mismatch, expected " << define.params.size() << ", got " << args.size() << endl;
return;
}
map<string,TokenList> argLookup;
for(int i = 0; i < define.params.size(); i++)
{
if(argLookup.count(define.params[i]) > 0)
cerr << "Warning: duplicate parameter name in macro" << endl;
else
argLookup[define.params[i]] = args[i];
}
for(TokenList::const_iterator i = define.tokens.begin(); i != define.tokens.end(); i++)
{
Token paramTok = *i;
if(paramTok.token == TOK_ID && argLookup.count(paramTok.value) > 0)
{
TokenList argToks = argLookup[paramTok.value];
for(TokenList::const_iterator j = argToks.begin(); j != argToks.end(); j++)
{
cout << (*j).value;
}
}
else cout << paramTok.value;
}
if(tok.token != TOK_LPAREN)
cout << tok.value;
}
/* ************************************************************************* */
string Method::wrapper_call(FileWriter& wrapperFile, Str cppClassName,
Str matlabUniqueName, const ArgumentList& args) const {
// check arguments
// extra argument obj -> nargin-1 is passed !
// example: checkArguments("equals",nargout,nargin-1,2);
wrapperFile.oss << " checkArguments(\"" << matlabName()
<< "\",nargout,nargin-1," << args.size() << ");\n";
// get class pointer
// example: shared_ptr<Test> = unwrap_shared_ptr< Test >(in[0], "Test");
wrapperFile.oss << " Shared obj = unwrap_shared_ptr<" << cppClassName
<< ">(in[0], \"ptr_" << matlabUniqueName << "\");" << endl;
// unwrap arguments, see Argument.cpp, we start at 1 as first is obj
args.matlab_unwrap(wrapperFile, 1);
// call method and wrap result
// example: out[0]=wrap<bool>(obj->return_field(t));
string expanded = "obj->" + name_;
if (templateArgValue_)
expanded += ("<" + templateArgValue_->qualifiedName("::") + ">");
return expanded;
}
double Parser::call(istream* input, string name)
{
if (functions.count(name) < 1)
throw Error::SyntaxError("undefined function "+name);
ArgumentList args = arguments(input);
Function func = functions[name];
if(func.params.size() != args.size())
throw Error::SyntaxError("incorrect number of arguments");
if(func.type == FUNC_BUILTIN)
{
return func.ptr(args[0]);
}
map<string,double> argMap;
for(unsigned int i = 0; i < func.params.size(); i++)
{
argMap[func.params[i]] = args[i];
}
for(TokenList::const_iterator i = func.tokens.begin(); i != func.tokens.end(); i++)
{
Token tok = *i;
if(tok.curr_tok == Lexer::NAME && argMap.count(tok.string_value) > 0)
{
Token val;
val.curr_tok = Lexer::NUMBER;
val.number_value = argMap[tok.string_value];
Lexer::token_queue.push(val);
}
else
Lexer::token_queue.push(*i);
}
return expr(input, true);
}
/****************************************************************************
*
* Query an xrootd server and translate filenames to locations
* To use:
* files_to_sites("xrootd.example.com", ["file1", "file2", "file3"])
*
* This function will aggressively cache the results (matchmaking will call
* it many times over a short period); it is also guaranteed to return within
* 50ms.
*
* Returns the list of xrootd endpoints which claim to have the file. Any not
* responding or not in the cache after 50ms will be left off the list. It is
* not possible to distinguish, in this function, the difference between
* timeouts, failures, and empty responses.
*
****************************************************************************/
static bool files_to_sites(
const char *, // name
const ArgumentList &arguments,
EvalState & state,
Value &result)
{
Value xrootd_host_arg, filenames_arg;
// We check to make sure that we are passed exactly one argument,
// then we have to evaluate that argument.
if (arguments.size() != 2) {
result.SetErrorValue();
CondorErrMsg = "Invalid number of arguments passed to files_to_sites; 2 required.";
return false;
}
std::string xrootd_host;
if (!arguments[0]->Evaluate(state, xrootd_host_arg) || (!xrootd_host_arg.IsStringValue(xrootd_host))) {
result.SetErrorValue();
CondorErrMsg = "Could not evaluate the first argument (Xrootd hostname) of files_to_sites to a string.";
return false;
}
if (!arguments[1]->Evaluate(state, filenames_arg)) {
result.SetErrorValue();
CondorErrMsg = "Could not evaluate the second argument (list of filenames) of files_to_sites.";
return false;
}
std::vector<std::string> filenames;
std::string single_filename;
if (filenames_arg.IsStringValue(single_filename))
{
filenames.push_back(single_filename);
}
else if (!convert_to_vector_string(state, filenames_arg, filenames))
{
result.SetErrorValue();
CondorErrMsg = "Could not evaluate the second argument (list of filenames) of files_to_sites to a list of strings.";
return false;
}
std::vector<std::string> files_to_query;
ResponseCache &cache = ResponseCache::getInstance();
classad_shared_ptr<ExprList> result_list = cache.query(filenames, files_to_query);
if (files_to_query.size() > 0)
{
FileMappingClient &client = FileMappingClient::getClient(xrootd_host);
if (!client.is_connected()) {
result.SetErrorValue();
CondorErrMsg = "Could not connect to specified xrootd host: " + xrootd_host;
return false;
}
std::set<std::string> hosts;
if (!client.map(filenames, hosts)) {
result.SetErrorValue();
CondorErrMsg = "Error while mapping the files to hosts.";
return false;
}
if (hosts.size() > 0)
{
classad_shared_ptr<ExprList> new_list = cache.addToList(result_list, hosts);
result_list = new_list;
}
}
result.SetListValue(result_list.get());
return true;
}
bool
doMatch(const char *name, const ArgumentList &arguments, EvalState &state, Value &result)
{
bool eval_successful = false;
result.SetErrorValue();
// We check to make sure that we passed exactly two arguments...
if (arguments.size() == 2) {
Value arg1;
const ExprList *adList;
// ...the first argument should evaluate to a list...
if (arguments[0] -> Evaluate(state, arg1) &&
arg1.IsListValue(adList)) {
// ...the second argument should be either an expression
// operand node or a function call node...
if (arguments[1] -> GetKind() == ExprTree::OP_NODE ||
arguments[1] -> GetKind() == ExprTree::FN_CALL_NODE) {
// Now we prepare the match context used while looking for
// any matching ad in the adList.In order to evaluate correctly
// any attribute reference involved in the second argument we
// should use the same classad containing the anyMatch statement
// while matching. Moreover we should make a copy of the requirements
// expression passed as second argument and set the parent scope by
// inserting it into the just copied classad. Finally, we set the left
// context which will be constant for any further match.
MatchClassAd match;
ClassAd* al = static_cast<classad::ClassAd*>(arguments[1]->GetParentScope()->Copy());
al->Insert("requirements", arguments[1]->Copy());
match.ReplaceLeftAd(al);
std::vector<ExprTree*> ads, matching;
adList->GetComponents(ads);
for(std::vector<ExprTree*>::const_iterator it = ads.begin();
it != ads.end(); it++) {
// Each expression in the list should be a classad...
if (!utils::is_classad(*it)) {
result.SetErrorValue();
eval_successful = false;
break;
}
ClassAd* ar = static_cast<ClassAd*>((*it)->Copy());
match.ReplaceRightAd(ar);
// If requirements does not evaluate to a boolean there is
// something seriously wrong and exit...
if (!match.EvaluateAttrBool("rightMatchesLeft", eval_successful)) {
result.SetErrorValue();
eval_successful = false;
break;
}
// ...otherwise we have to set the result and exit depending
// on which function was called.
if ( (!strcasecmp(name, "anyMatch") && eval_successful) ||
(!strcasecmp(name, "allMatch") && !eval_successful)) {
result.SetBooleanValue(eval_successful);
break;
}
if (!strcasecmp(name, "whichMatch") && eval_successful) {
matching.push_back(dynamic_cast<ClassAd*>(*it));
}
}
// if the whichMatch was called we have to set the result to
// the classad which matched...
if (!strcasecmp(name, "whichMatch")) {
eval_successful = !matching.empty();
// if there is no matching ad then the evaluation was successful
// and we have to set the result to undefined...
// ...otherwise we have to set the result to the matching ad(s)
if (!eval_successful) result.SetUndefinedValue();
else result.SetListValue(ExprList::MakeExprList(matching));
}
}
}
}
return eval_successful;
}
void Process::setupChild(const std::string& _exe, const ArgumentList& _args, const Environment& _env, const std::string& _workdir)
{
// restore signal handler(s)
::signal(SIGPIPE, SIG_DFL);
// setup environment
int k = 0;
std::vector<char *> env(_env.size() + 1);
for (Environment::const_iterator i = _env.cbegin(), e = _env.cend(); i != e; ++i)
{
char *buf = new char[i->first.size() + i->second.size() + 2];
::memcpy(buf, i->first.c_str(), i->first.size());
buf[i->first.size()] = '=';
::memcpy(buf + i->first.size() + 1, i->second.c_str(), i->second.size() + 1);
//::fprintf(stderr, "proc[%d]: setting env[%d]: %s\n", getpid(), k, buf);
//::fflush(stderr);
env[k++] = buf;
}
env[_env.size()] = 0;
// setup args
std::vector<char *> args(_args.size() + 2);
args[0] = const_cast<char *>(_exe.c_str());
//::fprintf(stderr, "args[%d] = %s\n", 0, args[0]);
for (int i = 0, e = _args.size(); i != e; ++i)
{
args[i + 1] = const_cast<char *>(_args[i].c_str());
//::fprintf(stderr, "args[%d] = %s\n", i + 1, args[i + 1]);
}
args[args.size() - 1] = 0;
// chdir
if (!_workdir.empty())
{
::chdir(_workdir.c_str());
}
// setup I/O
EINTR_LOOP(::close(STDIN_FILENO));
EINTR_LOOP(::close(STDOUT_FILENO));
EINTR_LOOP(::close(STDERR_FILENO));
EINTR_LOOP(::dup2(input_.remote(), STDIN_FILENO));
EINTR_LOOP(::dup2(output_.remote(), STDOUT_FILENO));
EINTR_LOOP(::dup2(error_.remote(), STDERR_FILENO));
#if 0 // this is basically working but a very bad idea for high performance (XXX better get O_CLOEXEC working)
for (int i = 3; i < 1024; ++i)
::close(i);
#endif
// input_.close();
// output_.close();
// error_.close();
// finally execute
::execve(args[0], &args[0], &env[0]);
// OOPS
::fprintf(stderr, "proc[%d]: execve(%s) error: %s\n", getpid(), args[0], strerror(errno));
::fflush(stderr);
::_exit(1);
}