int findMatch(node* head, int passedData)
{
if(head == NULL)
{
return 0;
}
if(head->data == passedData)
{
return 1 + findMatch(head->next, passedData);
}
else
{
return 0 + findMatch(head->next, passedData);
}
}
void ParenCat( void ) {
//==========================
// Check if ) matches ( as opposed to [.
// called on ) // sequence
itnode *cit;
bool ok_to_axe;
bool all_const_opns;
cit = findMatch( &ok_to_axe, &all_const_opns );
if( cit != NULL ) {
// consider: a(1)(2:3)//c
if( ( cit->opr == OPR_LBR ) && ok_to_axe ) {
ReqNOpn();
cit->is_catparen = 1;
cit = CITNode;
AdvanceITPtr();
FreeOneNode( cit );
// check for CHAR(73) - CHAR is allowed in constant expressions
} else if( (cit->opr != OPR_FBR) || !all_const_opns ||
((cit->link->flags & SY_CLASS ) != SY_SUBPROGRAM) ||
(!(cit->link->flags & SY_INTRINSIC)) ||
(cit->link->sym_ptr->ns.si.fi.index != IF_CHAR) ) {
ChkConstCatOpn( CITNode->link );
}
}
BackTrack();
}
void ShtServer::onMatchFinished(const QString &uuid)
{
qWarning() << "OnMatchFinished, uuid: " << uuid;
Match *m = findMatch(uuid);
matches.removeOne(m);
m->deleteLater();
}
void MainWindow::work()
{
QString fileName=pathE->text();
for(int i=0;i<fileName.length();i++)
if(fileName[i]=='\\')
fileName[i]='/';
int picNum=numE->text().toInt();
wd=new ImageWidget(NULL,fileName,picNum);
matchFBtn->setVisible(wd->tp.linev.size()==Hei);
findMBtn->setVisible(true);
findSBtn->setVisible(true);
preBtn->setVisible(true);
addBtn->setVisible(true);
delBtn->setVisible(true);
redoBtn->setVisible(true);
nextBtn->setVisible(true);
zinBtn->setVisible(true);
zoutBtn->setVisible(true);
// listSBtn->setVisible(true);
connect(listSBtn,SIGNAL(clicked()),this,SLOT(listSameLine()));
connect(findMBtn,SIGNAL(clicked()),this,SLOT(findMatch()));
connect(findSBtn,SIGNAL(clicked()),this,SLOT(findSameLine()));
connect(preBtn,SIGNAL(clicked()),this,SLOT(getPre()));
connect(nextBtn,SIGNAL(clicked()),this,SLOT(getNext()));
connect(addBtn,SIGNAL(clicked()),this,SLOT(addEdge()));
connect(delBtn,SIGNAL(clicked()),this,SLOT(delEdge()));
connect(redoBtn,SIGNAL(clicked()),this,SLOT(redo()));
connect(dispBtn,SIGNAL(clicked()),this,SLOT(disp()));
connect(matchFBtn,SIGNAL(clicked()),this,SLOT(matchFinall()));
connect(zinBtn,SIGNAL(clicked()),this,SLOT(zoomin()));
connect(zoutBtn,SIGNAL(clicked()),this,SLOT(zoomout()));
updateLayout();
wd->show();
}
void ChkCatOpn( void ) {
//===========================
// Check if ) is the start of a concatenation operand.
// Called on ) rel sequence since only relational operators are allowed with
// character arguments.
// Consider:
// if( a(1)//a(2) .eq. 'ab' )then
// We want to evaluate 'ab' first. Otherwise, a(2) would get evaluated,
// followed by 'ab' and finally a(1) -- which is incorrect.
itnode *cit;
bool ok_to_axe;
cit = findMatch( &ok_to_axe, NULL );
if( cit != NULL ) {
if( cit->opr == OPR_FBR ) {
if( cit->link->opr == OPR_CAT ) {
CatOpn();
return;
}
}
}
BackTrack();
}
std::string UserList::completeUserName(std::string const& text, std::string const& ignore)
{
std::string fullUserName;
if (text.empty())
{
LOG(DEBUG)<< "ignored trying to complete empty string";
return fullUserName;
}
std::vector<std::string> userNames;
for (int i=0; i<rows(); ++i)
{
StringTableRow const & row = getRow(static_cast<std::size_t>(i));
try
{
User const & user = model_.getUser(row.data_[0]);
userNames.push_back(row.data_[0]);
}
catch (std::invalid_argument const & e)
{
LOG(WARNING)<< "unexpected exception: "<< e.what();
}
}
auto const match = findMatch(userNames, text, ignore);
if (!match.empty())
{
fullUserName = match;
}
return fullUserName;
}
int RandOp::getOneUnique(int min, int max)
{
int val;
bool isMatch;
do {
val = pRand->IRandomX(min, max);
// If val returned is a zero or one, bump the corresponding
// counters and check to see if we've exceeded the maximum
// allowable number for those conditions.
//
if(val == 0) {
m_zeroCount++;
if(m_zeroCount > m_maxZeros)
continue;
}
if(val == 1) {
m_onesCount++;
if(m_onesCount > m_maxOnes)
continue;
}
isMatch = findMatch(val, m_qlLopRepeats);
} while (isMatch);
return val;
}
int main() {
puts("\n\n ----- Lab 2: Unicode Blocks ----- ");
puts(" ----- Author: Matt Hixon -----\n\n");
int size = readFile();
if(size != 0){
int codepoint;
puts("Enter a Codepoint Value (integer)\n");
scanf("%d", &codepoint);
do{
puts("--------------- ");
int blockIndex = findMatch(codepoint, size);
if(blockIndex == -1){
puts("No matching block found.");
} else {
printf("%s", blocks[blockIndex].name);
}
puts("\n\n\nTry another number (-1 to exit):\n");
scanf("%d", &codepoint);
} while (codepoint != -1);
}
}
bool win(){
int begin=0;
for(int i=0;seq[i]!='\0';i++){
int pos=findMatch(seq[i],begin);
if(pos==-1)
return false;
begin=pos+1;
}
return true;
}
// Main function
int main(int argc, char *argv[]){
char *line;
char *address;
char pattern[] = "GCAG";
getString(&line);
address = findMatch(line, pattern);
printIt(address);
if (address != NULL)
getIndex(line, address);
}
void GLUTAPIENTRY
glutGameModeString(const char *string)
{
Criterion *criteria;
int ncriteria;
initGameModeSupport();
criteria = parseDisplayString(string, &ncriteria);
currentDm = findMatch(dmodes, ndmodes, criteria, ncriteria);
free(criteria);
}
int main(int argc, char *argv[]){
char *line;
char *result;
char *c;
getString3(&line);
printString(line);
result = findMatch(line);
if (result == NULL){
printf("Too bad no match\n");
} else {
printf("Yippee a match is found\n");
}
}
int main(int argc,char* argv[]) {
if (argc < 5) {
printf("%s ratio target id_start id_end\n",argv[0]);
return 1;
}
float ratio = atof(argv[1]);
int id_start = atoi(argv[3]);
int id_end = atoi(argv[4]);
Desc targetDesc = parseKeyFile(argv[2]);
printf("Loaded %d (dim %d) keypoints from %s\n",targetDesc.n,targetDesc.dimension,argv[2]);
int newDimension = 64;
float* pca_basis = new float[newDimension * targetDesc.dimension];
pca(targetDesc,newDimension,pca_basis);
changeBasis(&targetDesc,newDimension,pca_basis);
char buffer[128];
struct timespec tic,toc;
clock_gettime(CLOCK_MONOTONIC,&tic);
for (int i=id_start;i<=id_end;i++) {
sprintf(buffer,"%d.key",i);
Desc sourceDesc = parseKeyFile(buffer);
changeBasis(&sourceDesc,newDimension,pca_basis);
std::vector<Match> match = findMatch(sourceDesc,targetDesc,ratio);
sprintf(buffer,"%d.site.match",i);
FILE* output = fopen(buffer,"w");
for (size_t i=0;i<match.size();i++) {
fprintf(output,"0 %f %f 1 %f %f\n",
sourceDesc.x[match[i].id1],sourceDesc.y[match[i].id1],
targetDesc.x[match[i].id2],targetDesc.y[match[i].id2]);
}
printf("Wrote %lu matches to %s\n",match.size(),buffer);
fclose(output);
delete[] sourceDesc.x;
delete[] sourceDesc.y;
delete[] sourceDesc.data;
}
clock_gettime(CLOCK_MONOTONIC,&toc);
printf("Profiling: %fs for %d images\n",toc.tv_sec - tic.tv_sec + 0.000000001 * toc.tv_nsec - 0.000000001 * tic.tv_nsec,id_end-id_start+1);
delete[] targetDesc.x;
delete[] targetDesc.y;
delete[] targetDesc.data;
delete[] pca_basis;
}
void LZ::myEncode(char n , char l , char s )
{
cout << "encoding..."<<endl;
N = n;
L = l;
S = s;
//default values: N = 11, L = 4, S = 3
if (ifile.is_open()) {
cout << "file is opened..." << endl;
W = pow(2, N);
F = pow(2, L)-1;
char* buffer = new char[F];
window = "";
lookahead = "";
//while there is input to process
//(i.e. there is unread data or unprocessed data in the lookahead)
while (!ifile.eof()|| lookahead!="") {
//if there is unread data
if (!ifile.eof())
{//read enough chars(at most F) to make lookahead contain F chars
ifile.read(buffer, F - lookahead.length());
//only append the number of chars that were read in the previous step to the
//lookahead(otherwise the rest of the data will be junk data) if you dont use
//gcount, at the end of the file you will try to append more chars than you have
lookahead.append(buffer, ifile.gcount());
}
//make sure the size of window is correct
if (window.length() + lookahead.length() > W) {
//resize window so that len(window) + len(lookahead)<=W
int window_start= window.length() - (W - lookahead.length());
int window_end = W - lookahead.length();
window = window.substr(window_start,window_end);
}
findMatch();
}
ifile.close();
}
//now we need to encode the completed tokens to a file and output the reuslt
//cleanTokens();
writeTokens();
}
/**
* Removes all rules which are not descendants of simulated DAG rooted at targets.
*
* @param rules Queue of rules which is read and modified.
* @param targets List of targets which act as roots.
* @return Void.
*/
static void filterOnTargets(queue_t **rules, char **targets){
queue_t *validRules = malloc(sizeof(queue_t));
queue_init(validRules);
int idx;
//initialize validRules with targets
for(idx=0; idx < queue_size(*rules);idx++){
rule_t *curRule = queue_at(*rules, idx);
int tarIdx;
for(tarIdx=0; targets[tarIdx] != NULL; tarIdx++){
if(strcmp(curRule->target, targets[tarIdx]) == 0){
queue_enqueue(validRules, curRule);
queue_remove_at(*rules, idx);
idx--;
break;
}
}
}
//repeated linear search for new valid targets
int prevSize = 0;
while(prevSize != queue_size(validRules)){
prevSize = queue_size(validRules);
for(idx=0; idx < queue_size(*rules); idx++){
rule_t *curRule = queue_at(*rules, idx);
if(findMatch(curRule, validRules)){
queue_enqueue(validRules, curRule);
queue_remove_at(*rules, idx);
idx--;
}
}
}
//cleanup old rules
queue_iterate(*rules, rule_free_adapter, 0);
queue_destroy(*rules);
free(*rules);
//assign new queue
*rules = validRules;
}
virtual size_t match(const char* data, size_t size)
{
__m128i firstLetter = _mm_loadu_si128(reinterpret_cast<const __m128i*>(this->firstLetter));
__m128i patternData = _mm_loadu_si128(reinterpret_cast<const __m128i*>(this->patternData));
__m128i patternMask = _mm_loadu_si128(reinterpret_cast<const __m128i*>(this->patternMask));
size_t offset = firstLetterPos;
while (offset + 32 <= size)
{
__m128i value = _mm_loadu_si128(reinterpret_cast<const __m128i*>(data + offset));
unsigned int mask = _mm_movemask_epi8(_mm_cmpeq_epi8(value, firstLetter));
// advance offset regardless of match results to reduce number of live values
offset += 16;
while (mask != 0)
{
unsigned int pos = re2::countTrailingZeros(mask);
size_t dataOffset = offset - 16 + pos - firstLetterOffset;
mask &= ~(1 << pos);
// check if we have a match
__m128i patternMatch = _mm_loadu_si128(reinterpret_cast<const __m128i*>(data + dataOffset));
__m128i matchMask = _mm_or_si128(patternMask, _mm_cmpeq_epi8(patternMatch, patternData));
if (_mm_movemask_epi8(matchMask) == 0xffff)
{
size_t matchOffset = dataOffset + firstLetterOffset - firstLetterPos;
// final check for full pattern
if (matchOffset + pattern.size() < size && memcmp(data + matchOffset, pattern.c_str(), pattern.size()) == 0)
{
return matchOffset;
}
}
}
}
return findMatch(pattern.c_str(), pattern.size(), data, size, offset - firstLetterPos);
}
void recognizeAlphabet(int size){
//recognize alphabet
char line[2048];
unsigned char *c;
int lenptr;
unsigned int codepoint;
int blockIndex = 0;
while(fgets(line, 2048, stdin) != NULL){
c = line;
while(*c != '\0' && *c != '\n'){
codepoint = utf8_to_codepoint(c, &lenptr);
if(codepoint > 0){
int blockIndex = findMatch(codepoint, size);
if(blockIndex != -1){ blocks[blockIndex].counter += 1; }
c = c + lenptr;
}
if(codepoint == 0){c++;}
}
}
}
virtual size_t match(const char* data, size_t size)
{
__m128i firstLetter = _mm_loadu_si128(reinterpret_cast<const __m128i*>(this->firstLetter));
__m128i patternData = _mm_loadu_si128(reinterpret_cast<const __m128i*>(this->patternData));
__m128i patternMask = _mm_loadu_si128(reinterpret_cast<const __m128i*>(this->patternMask));
size_t offset = firstLetterPos;
while (offset + 32 <= size)
{
__m128i value = _mm_loadu_si128(reinterpret_cast<const __m128i*>(data + offset));
int mask = _mm_movemask_epi8(_mm_cmpeq_epi8(value, firstLetter));
if (mask == 0)
offset += 16;
else
{
offset += re2::countTrailingZeros(mask);
// check if we have a match
__m128i patternMatch = _mm_loadu_si128(reinterpret_cast<const __m128i*>(data + offset - firstLetterOffset));
__m128i matchMask = _mm_or_si128(patternMask, _mm_cmpeq_epi8(patternMatch, patternData));
if (_mm_movemask_epi8(matchMask) == 0xffff)
{
// final check for full pattern
if (memcmp(data + offset - firstLetterPos, pattern.c_str(), pattern.size()) == 0)
{
return offset - firstLetterPos;
}
}
offset += 1;
}
}
return findMatch(pattern.c_str(), pattern.size(), data, size, offset - firstLetterPos);
}
bool Parser::parse(QString pattern)
{
if(!pattern.isEmpty())
setExpression(pattern);
for(std::vector<Token *>::iterator iter = _tokens.begin(); iter != _tokens.end(); ++iter)
delete *iter;
_tokens.clear();
int previousPositon = 0;
while(_pos < pattern.length())
{
handleToken(findMatch());
// In the case where no progress is being made, exit returning false
if(previousPositon == _pos)
return false;
previousPositon = _pos;
}
return true;
}
int main (int argc, char** argv) {
int my_rank, p;
long int n = atoi(argv[1]);
long int q=1;
long int *qlist;
mpz_t l;
mpz_init(l);
MPI_Init(&argc, &argv);
MPI_Comm_size(MPI_COMM_WORLD, &p);
MPI_Comm_rank(MPI_COMM_WORLD, &my_rank);
qlist = (long int*)malloc(sizeof(long int)*(n/p));
int i = 0;
int u = 0;
while(q <= sqrt(n)){
if (i == p) i = 0;
if (my_rank == i) {
qlist[u] = q;
u++;
}
mpz_nextprime(l, l);
q = mpz_get_si(l);
i++;
}
for (int a=0; a<u; a++){
if(findMatch(qlist[a], n)){
printf("Answer: %u and %u\n", qlist[a], n/(qlist[a]));
}
}
free(qlist);
MPI_Finalize();
return 0;
}
void CatParen( void ) {
//==========================
// Check if ) matches ( as opposed to [.
// called on // ) sequence
itnode *cit;
bool ok_to_axe;
cit = findMatch( &ok_to_axe, NULL );
if( cit != NULL ) {
if( ( cit->opr == OPR_LBR ) && ok_to_axe ) {
cit->is_catparen = 1;
cit = CITNode;
AdvanceITPtr();
ReqNOpn();
cit->link = CITNode->link;
FreeOneNode( CITNode );
CITNode = cit;
} else {
CatOpn();
}
}
}
void main(int argc, char *argv[])
{
unsigned char buf[100];
unsigned char notice[100];
unsigned char fullName[100];
unsigned char familyName[100];
unsigned char weigth[100];
unsigned char italic[100];
unsigned char fixed[100];
unsigned char foundry[100] = "";
unsigned char slant[100] = "r";
unsigned char width[100] = "normal";
for (;;) {
getWord( buf, 99 );
if (stricmp( buf, "/Notice" )==0)
getString( notice, 99 ); else if (stricmp( buf, "/FullName" )==0)
getString( fullName, 99 );
else if (stricmp( buf, "/FamilyName" )==0)
getString( familyName, 99 );
else if (stricmp( buf, "/Weight" )==0)
getString( weigth, 99 );
else if (stricmp( buf, "/ItalicAngle" )==0)
getWord( italic, 99 );
else if (stricmp( buf, "/isFixedPitch" )==0)
getWord( fixed, 99 );
else if (stricmp( buf, "eexec" )==0)
break;
else {
// if (buf[0]=='/')
// printf( "%s\n", buf );
}
}
lower( weigth );
ConvertBuf( weigth, mapWeight );
lower( fixed );
ConvertBuf( fixed, mapFixed );
if (atoi(italic)!=0)
strcpy( slant, "i" );
if (argc>1) {
strcpy( buf, argv[1] );
lower( buf );
} else
strcpy( buf, "" );
lower( notice );
findMatch( notice, foundry, mapFoundry );
// Lets dig out as much as possible from fullName
lower( fullName );
findMatch( fullName, slant, mapSlant );
findMatch( fullName, width, mapWidth );
lower( familyName );
printf( "%s -%s-%s-%s-%s-%s--0-0-0-0-%s-0-iso8859-1\n",
buf, foundry, familyName, weigth, slant, width, fixed );
}
void PcreParser::handleToken(RegexpToken token)
{
QRegExp rx;
QRegExp characterClass;
QRegExp bracketExpressionLiteral("[^\\\\[\\]\\.]|\\\\[^a-zA-Z0-9]");
QRegExp bracketExpressionRange(_syntax[T_BRACKET_EXPRESSION_RANGE]);
QRegExp flagClose;
Token *openingToken;
QString character;
QString tmp;
switch(token)
{
case T_LITERAL:
case T_ALTERNATION:
case T_ANY_CHARACTER:
case T_STARTING_POSITION:
case T_ENDING_POSITION:
case T_BACKREFERENCE:
case T_WORD:
case T_NOT_WORD:
case T_DIGIT:
case T_NOT_DIGIT:
case T_SPACE:
case T_NOT_SPACE:
case T_WORD_BOUNDARY:
case T_NOT_WORD_BOUNDARY:
case T_OCTAL_CHAR:
case T_NAMED_BACKREFERENCE:
case T_FIRST_MATCHING_POSITION:
case T_START_OF_STRING:
case T_END_OF_STRING:
case T_END_OF_STRING_WITH_CLOSING_EOL:
case T_ALNUM:
case T_ALPHA:
case T_BLANK:
case T_CNTRL:
case T_GRAPH:
case T_LOWER:
case T_PRINT:
case T_PUNCT:
case T_UPPER:
case T_XDIGIT:
case T_HORIZONTAL_WHITESPACE:
case T_NOT_HORIZONTAL_WHITESPACE:
case T_VERTICAL_WHITESPACE:
case T_NOT_VERTICAL_WHITESPACE:
case T_BELL:
case T_BACKSPACE:
case T_ESCAPE:
case T_FORM_FEED:
case T_LINE_FEED:
case T_HORIZONTAL_TAB:
case T_HEXADECIMAL_CHAR:
_tokens.push_back(new Token(token, _expression.mid(_pos, _matchLength)));
_pos += _matchLength;
break;
case T_GROUPING_OPEN:
case T_REVERSED_CAPTURING_GROUPING_OPEN:
case T_NAMED_GROUPING_OPEN:
openingToken = new Token(token, _expression.mid(_pos, _matchLength));
_tokens.push_back(openingToken);
_pos += _matchLength;
rx.setPattern(_syntax[T_GROUPING_CLOSE]);
while(rx.indexIn(_expression, _pos) != _pos && _pos < _expression.length())
handleToken(findMatch());
if(rx.indexIn(_expression, _pos) == _pos)
{
_tokens.push_back(new Token(T_GROUPING_CLOSE, _expression.mid(_pos, 1)));
_pos += 1;
}
else
openingToken->setType(T_ERROR);
break;
case T_BRACKET_EXPRESSION_OPEN:
case T_NEGATED_BRACKET_EXPRESSION_OPEN:
openingToken = new Token(token, _expression.mid(_pos, _matchLength));
_tokens.push_back(openingToken);
_pos += _matchLength;
rx.setPattern(_syntax[T_BRACKET_EXPRESSION_CLOSE]);
// Look for a "[]...]" or "[^]...]" including a literal close bracket in
// the first position of the bracket expression
if(rx.indexIn(_expression, _pos) == _pos)
{
_tokens.push_back(new Token(T_LITERAL, _expression.mid(_pos, rx.matchedLength())));
_pos += rx.matchedLength();
}
while(rx.indexIn(_expression, _pos) != _pos && _pos < _expression.length())
{
bool matched = false;
if(matched == false && bracketExpressionRange.indexIn(_expression, _pos) == _pos)
{
matched = true;
_tokens.push_back(new Token(T_BRACKET_EXPRESSION_RANGE, _expression.mid(_pos, bracketExpressionRange.matchedLength())));
_pos += bracketExpressionRange.matchedLength();
}
if(matched == false && bracketExpressionLiteral.indexIn(_expression, _pos) == _pos)
{
matched = true;
_tokens.push_back(new Token(T_LITERAL, _expression.mid(_pos, bracketExpressionLiteral.matchedLength())));
_pos += bracketExpressionLiteral.matchedLength();
}
characterClass.setPattern(_syntax[T_WORD]);
if(matched == false && characterClass.indexIn(_expression, _pos) == _pos)
{
matched = true;
_tokens.push_back(new Token(T_WORD, _expression.mid(_pos, characterClass.matchedLength())));
_pos += characterClass.matchedLength();
}
characterClass.setPattern(_syntax[T_NOT_WORD]);
if(matched == false && characterClass.indexIn(_expression, _pos) == _pos)
{
matched = true;
_tokens.push_back(new Token(T_NOT_WORD, _expression.mid(_pos, characterClass.matchedLength())));
_pos += characterClass.matchedLength();
}
characterClass.setPattern(_syntax[T_DIGIT]);
if(matched == false && characterClass.indexIn(_expression, _pos) == _pos)
{
matched = true;
_tokens.push_back(new Token(T_DIGIT, _expression.mid(_pos, characterClass.matchedLength())));
_pos += characterClass.matchedLength();
}
characterClass.setPattern(_syntax[T_NOT_DIGIT]);
if(matched == false && characterClass.indexIn(_expression, _pos) == _pos)
{
matched = true;
_tokens.push_back(new Token(T_NOT_DIGIT, _expression.mid(_pos, characterClass.matchedLength())));
_pos += characterClass.matchedLength();
}
characterClass.setPattern(_syntax[T_SPACE]);
if(matched == false && characterClass.indexIn(_expression, _pos) == _pos)
{
matched = true;
_tokens.push_back(new Token(T_SPACE, _expression.mid(_pos, characterClass.matchedLength())));
_pos += characterClass.matchedLength();
}
characterClass.setPattern(_syntax[T_NOT_SPACE]);
if(matched == false && characterClass.indexIn(_expression, _pos) == _pos)
{
matched = true;
_tokens.push_back(new Token(T_NOT_SPACE, _expression.mid(_pos, characterClass.matchedLength())));
_pos += characterClass.matchedLength();
}
characterClass.setPattern(_syntax[T_WORD_BOUNDARY]);
if(matched == false && characterClass.indexIn(_expression, _pos) == _pos)
{
matched = true;
_tokens.push_back(new Token(T_WORD_BOUNDARY, _expression.mid(_pos, characterClass.matchedLength())));
_pos += characterClass.matchedLength();
}
characterClass.setPattern(_syntax[T_NOT_WORD_BOUNDARY]);
if(matched == false && characterClass.indexIn(_expression, _pos) == _pos)
{
matched = true;
_tokens.push_back(new Token(T_NOT_WORD_BOUNDARY, _expression.mid(_pos, characterClass.matchedLength())));
_pos += characterClass.matchedLength();
}
characterClass.setPattern(_syntax[T_BELL]);
if(matched == false && characterClass.indexIn(_expression, _pos) == _pos)
{
matched = true;
_tokens.push_back(new Token(T_BELL, _expression.mid(_pos, characterClass.matchedLength())));
_pos += characterClass.matchedLength();
}
characterClass.setPattern(_syntax[T_ESCAPE]);
if(matched == false && characterClass.indexIn(_expression, _pos) == _pos)
{
matched = true;
_tokens.push_back(new Token(T_ESCAPE, _expression.mid(_pos, characterClass.matchedLength())));
_pos += characterClass.matchedLength();
}
characterClass.setPattern(_syntax[T_FORM_FEED]);
if(matched == false && characterClass.indexIn(_expression, _pos) == _pos)
{
matched = true;
_tokens.push_back(new Token(T_FORM_FEED, _expression.mid(_pos, characterClass.matchedLength())));
_pos += characterClass.matchedLength();
}
characterClass.setPattern(_syntax[T_LINE_FEED]);
if(matched == false && characterClass.indexIn(_expression, _pos) == _pos)
{
matched = true;
_tokens.push_back(new Token(T_LINE_FEED, _expression.mid(_pos, characterClass.matchedLength())));
_pos += characterClass.matchedLength();
}
characterClass.setPattern(_syntax[T_HORIZONTAL_TAB]);
if(matched == false && characterClass.indexIn(_expression, _pos) == _pos)
{
matched = true;
_tokens.push_back(new Token(T_HORIZONTAL_TAB, _expression.mid(_pos, characterClass.matchedLength())));
_pos += characterClass.matchedLength();
}
characterClass.setPattern(_syntax[T_OCTAL_CHAR]);
if(matched == false && characterClass.indexIn(_expression, _pos) == _pos)
{
matched = true;
_tokens.push_back(new Token(T_OCTAL_CHAR, _expression.mid(_pos, characterClass.matchedLength())));
_pos += characterClass.matchedLength();
}
if(!matched)
{
_tokens.push_back(new Token(T_ERROR, _expression.mid(_pos, 1)));
++_pos;
}
}
if(rx.indexIn(_expression, _pos) == _pos)
{
_tokens.push_back(new Token(T_BRACKET_EXPRESSION_CLOSE,
_expression.mid(_pos, rx.matchedLength()))
);
_pos += rx.matchedLength();
}
else
openingToken->setType(T_ERROR);
break;
case T_POSITIVE_LOOKAHEAD_ASSERTION_OPEN:
case T_NEGATIVE_LOOKAHEAD_ASSERTION_OPEN:
case T_POSITIVE_LOOKBEHIND_ASSERTION_OPEN:
case T_NEGATIVE_LOOKBEHIND_ASSERTION_OPEN:
openingToken = new Token(token, _expression.mid(_pos, _matchLength));
_tokens.push_back(openingToken);
_pos += _matchLength;
rx.setPattern(_syntax[T_ASSERTION_CLOSE]);
while(rx.indexIn(_expression, _pos) != _pos && _pos < _expression.length())
handleToken(findMatch());
if(rx.indexIn(_expression, _pos) == _pos)
{
_tokens.push_back(new Token(T_ASSERTION_CLOSE, _expression.mid(_pos, 1)));
_pos += 1;
}
else
openingToken->setType(T_ERROR);
break;
case T_REPEAT_ZERO_OR_ONE:
case T_REPEAT_ANY_NUMBER:
case T_REPEAT_ONE_OR_MORE:
case T_REPEAT_SPECIFIED:
case T_REPEAT_ZERO_OR_ONE_NONGREEDY:
case T_REPEAT_ANY_NUMBER_NONGREEDY:
case T_REPEAT_ONE_OR_MORE_NONGREEDY:
case T_REPEAT_SPECIFIED_NONGREEDY:
case T_REPEAT_ZERO_OR_ONE_POSSESSIVE:
case T_REPEAT_ANY_NUMBER_POSSESSIVE:
case T_REPEAT_ONE_OR_MORE_POSSESSIVE:
case T_REPEAT_SPECIFIED_POSSESSIVE:
switch(_tokens[_tokens.size()-1]->type())
{
case T_POSITIVE_LOOKAHEAD_ASSERTION_OPEN:
case T_NEGATIVE_LOOKAHEAD_ASSERTION_OPEN:
case T_POSITIVE_LOOKBEHIND_ASSERTION_OPEN:
case T_NEGATIVE_LOOKBEHIND_ASSERTION_OPEN:
case T_REPEAT_ZERO_OR_ONE:
case T_REPEAT_ANY_NUMBER:
case T_REPEAT_ONE_OR_MORE:
case T_REPEAT_SPECIFIED:
case T_REPEAT_ZERO_OR_ONE_NONGREEDY:
case T_REPEAT_ANY_NUMBER_NONGREEDY:
case T_REPEAT_ONE_OR_MORE_NONGREEDY:
case T_REPEAT_SPECIFIED_NONGREEDY:
case T_REPEAT_ZERO_OR_ONE_POSSESSIVE:
case T_REPEAT_ANY_NUMBER_POSSESSIVE:
case T_REPEAT_ONE_OR_MORE_POSSESSIVE:
case T_REPEAT_SPECIFIED_POSSESSIVE:
case T_GROUPING_OPEN:
case T_REVERSED_CAPTURING_GROUPING_OPEN:
case T_NAMED_GROUPING_OPEN:
_tokens.push_back(new Token(T_ERROR, _expression.mid(_pos, _matchLength)));
_pos += _matchLength;
break;
case T_LITERAL:
// Requires a bit of extra work to separate the last character from
// the literal
character = _tokens[_tokens.size()-1]->value().right(1);
tmp = _tokens[_tokens.size()-1]->value();
if(tmp.size() > 1)
{
tmp.truncate(tmp.length() - 1);
_tokens[_tokens.size()-1]->setValue(tmp);
_tokens.push_back(new Token(T_LITERAL, character));
}
default:
_tokens.push_back(new Token(token, _expression.mid(_pos, _matchLength)));
_pos += _matchLength;
}
break;
case T_COMMENT_OPEN:
openingToken = new Token(token, _expression.mid(_pos, _matchLength));
_tokens.push_back(openingToken);
_pos += _matchLength;
// Comments contain one literal comment message lasting up until the
// next closing paren
rx.setMinimal(true);
rx.setPattern(QString(".*(?=") + _syntax[T_COMMENT_CLOSE] + ")");
if(rx.indexIn(_expression, _pos) == _pos)
{
_tokens.push_back(new Token(T_LITERAL, _expression.mid(_pos, rx.matchedLength())));
_pos += rx.matchedLength();
}
rx.setPattern(_syntax[T_COMMENT_CLOSE]);
if(rx.indexIn(_expression, _pos) != _pos)
openingToken->setType(T_ERROR);
else
{
_tokens.push_back(new Token(T_COMMENT_CLOSE, _expression.mid(_pos, rx.matchedLength())));
_pos += rx.matchedLength();
}
break;
case T_QUOTE_SEQUENCE_OPEN:
openingToken = new Token(token, _expression.mid(_pos, _matchLength));
_tokens.push_back(openingToken);
_pos += _matchLength;
// Quote sequences are literal up until a closing \E
rx.setMinimal(true);
rx.setPattern(QString(".*(?=") + _syntax[T_QUOTE_SEQUENCE_CLOSE] + ")");
if(rx.indexIn(_expression, _pos) == _pos)
{
_tokens.push_back(new Token(T_LITERAL, _expression.mid(_pos, rx.matchedLength())));
_pos += rx.matchedLength();
}
rx.setPattern(_syntax[T_QUOTE_SEQUENCE_CLOSE]);
if(rx.indexIn(_expression, _pos) != _pos)
openingToken->setType(T_ERROR);
else
{
_tokens.push_back(new Token(T_QUOTE_SEQUENCE_CLOSE, _expression.mid(_pos, rx.matchedLength())));
_pos += rx.matchedLength();
}
break;
case T_FLAGS_OPEN:
openingToken = new Token(token, _expression.mid(_pos, _matchLength));
_tokens.push_back(openingToken);
_pos += _matchLength;
// Flag sections can contain a-zA-Z- characters and end with a close
// paren, if we encounter anything else then we'll stop trying to match
// it as a flag and mark the opening as an error
rx.setMinimal(true);
rx.setPattern(QString("[a-zA-Z-]*") + _syntax[T_FLAGS_CLOSE]);
if(rx.indexIn(_expression, _pos) != _pos)
openingToken->setType(T_ERROR);
else
{
flagClose.setPattern(_syntax[T_FLAGS_CLOSE]);
while(flagClose.indexIn(_expression, _pos) != _pos)
{
bool matched = false;
rx.setPattern(_syntax[T_FLAGS_NEGATION]);
if(!matched && rx.indexIn(_expression, _pos) == _pos)
{
_tokens.push_back(new Token(T_FLAGS_NEGATION, _expression.mid(_pos, rx.matchedLength())));
_pos += rx.matchedLength();
matched = true;
}
rx.setPattern(_syntax[T_FLAG_CASELESS]);
if(!matched && rx.indexIn(_expression, _pos) == _pos)
{
_tokens.push_back(new Token(T_FLAG_CASELESS, _expression.mid(_pos, rx.matchedLength())));
_pos += rx.matchedLength();
matched = true;
}
rx.setPattern(_syntax[T_FLAG_DOTALL]);
if(!matched && rx.indexIn(_expression, _pos) == _pos)
{
_tokens.push_back(new Token(T_FLAG_DOTALL, _expression.mid(_pos, rx.matchedLength())));
_pos += rx.matchedLength();
matched = true;
}
rx.setPattern(_syntax[T_FLAG_MULTILINE]);
if(!matched && rx.indexIn(_expression, _pos) == _pos)
{
_tokens.push_back(new Token(T_FLAG_MULTILINE, _expression.mid(_pos, rx.matchedLength())));
_pos += rx.matchedLength();
matched = true;
}
rx.setPattern(_syntax[T_FLAG_EXTENDED]);
if(!matched && rx.indexIn(_expression, _pos) == _pos)
{
_tokens.push_back(new Token(T_FLAG_EXTENDED, _expression.mid(_pos, rx.matchedLength())));
_pos += rx.matchedLength();
matched = true;
}
rx.setPattern(_syntax[T_FLAG_PCRE_EXTRA]);
if(!matched && rx.indexIn(_expression, _pos) == _pos)
{
_tokens.push_back(new Token(T_FLAG_PCRE_EXTRA, _expression.mid(_pos, rx.matchedLength())));
_pos += rx.matchedLength();
matched = true;
}
rx.setPattern(_syntax[T_FLAG_ANCHORED]);
if(!matched && rx.indexIn(_expression, _pos) == _pos)
{
_tokens.push_back(new Token(T_FLAG_ANCHORED, _expression.mid(_pos, rx.matchedLength())));
_pos += rx.matchedLength();
matched = true;
}
rx.setPattern(_syntax[T_FLAG_UNGREEDY]);
if(!matched && rx.indexIn(_expression, _pos) == _pos)
{
_tokens.push_back(new Token(T_FLAG_UNGREEDY, _expression.mid(_pos, rx.matchedLength())));
_pos += rx.matchedLength();
matched = true;
}
if(!matched)
{
_tokens.push_back(new Token(T_ERROR, _expression.mid(_pos, 1)));
++_pos;
}
}
_tokens.push_back(new Token(T_FLAGS_CLOSE, _expression.mid(_pos, flagClose.matchedLength())));
_pos += flagClose.matchedLength();
}
break;
default:
qDebug() << "Unknown token at position " << _pos << ": " << token;
qDebug() << "Value: " << _expression.mid(_pos, _matchLength);
_tokens.push_back(new Token(T_ERROR, _expression.mid(_pos, _matchLength)));
_pos += _matchLength;
}
}
GHOST_TSuccess GHOST_DisplayManagerWin32::setCurrentDisplaySetting(GHOST_TUns8 display, const GHOST_DisplaySetting& setting)
{
GHOST_ASSERT((display==kMainDisplay), "GHOST_DisplayManagerWin32::setCurrentDisplaySetting(): only main display is supported");
GHOST_DisplaySetting match;
findMatch(display, setting, match);
DEVMODE dm;
int i = 0;
while (::EnumDisplaySettings(NULL, i++, &dm)) {
if ((dm.dmBitsPerPel == match.bpp) &&
(dm.dmPelsWidth == match.xPixels) &&
(dm.dmPelsHeight == match.yPixels) &&
(dm.dmDisplayFrequency == match.frequency)) {
break;
}
}
/*
dm.dmBitsPerPel = match.bpp;
dm.dmPelsWidth = match.xPixels;
dm.dmPelsHeight = match.yPixels;
dm.dmDisplayFrequency = match.frequency;
dm.dmFields = DM_BITSPERPEL | DM_PELSWIDTH | DM_PELSHEIGHT | DM_DISPLAYFREQUENCY;
dm.dmSize = sizeof(DEVMODE);
dm.dmDriverExtra = 0;
*/
#ifdef GHOST_DEBUG
printf("display change: Requested settings:\n");
printf(" dmBitsPerPel=%d\n", dm.dmBitsPerPel);
printf(" dmPelsWidth=%d\n", dm.dmPelsWidth);
printf(" dmPelsHeight=%d\n", dm.dmPelsHeight);
printf(" dmDisplayFrequency=%d\n", dm.dmDisplayFrequency);
#endif // GHOST_DEBUG
LONG status = ::ChangeDisplaySettings(&dm, CDS_FULLSCREEN);
#ifdef GHOST_DEBUG
switch (status)
{
case DISP_CHANGE_SUCCESSFUL:
printf("display change: The settings change was successful.\n");
break;
case DISP_CHANGE_RESTART:
printf("display change: The computer must be restarted in order for the graphics mode to work.\n");
break;
case DISP_CHANGE_BADFLAGS:
printf("display change: An invalid set of flags was passed in.\n");
break;
case DISP_CHANGE_BADPARAM:
printf("display change: An invalid parameter was passed in. This can include an invalid flag or combination of flags.\n");
break;
case DISP_CHANGE_FAILED:
printf("display change: The display driver failed the specified graphics mode.\n");
break;
case DISP_CHANGE_BADMODE:
printf("display change: The graphics mode is not supported.\n");
break;
case DISP_CHANGE_NOTUPDATED:
printf("display change: Windows NT: Unable to write settings to the registry.\n");
break;
default:
printf("display change: Return value invalid\n");
break;
}
#endif // GHOST_DEBUG
return status == DISP_CHANGE_SUCCESSFUL? GHOST_kSuccess : GHOST_kFailure;
}
void GLUTAPIENTRY
glutGameModeString(const char *string)
{
Criterion *criteria;
int ncriteria[4], requestedMask, queries = 1;
#if _WIN32
int bpp, width, height, hertz, n;
#endif
initGameModeSupport();
#if _WIN32
XHDC = GetDC(GetDesktopWindow());
bpp = GetDeviceCaps(XHDC, BITSPIXEL);
/* Note that Windows 95 and 98 systems always return zero
for VREFRESH so be prepared to ignore values of hertz
that are too low. */
hertz = GetDeviceCaps(XHDC, VREFRESH);
width = GetSystemMetrics(SM_CXSCREEN);
height = GetSystemMetrics(SM_CYSCREEN);
#endif
criteria = parseGameModeString(string, &ncriteria[0], &requestedMask);
#if _WIN32
/* Build an extra set of default queries. If no pixel depth is
explicitly specified, prefer a display mode that doesn't change
the display mode. Likewise for the width and height. Likewise for
the display frequency. */
n = ncriteria[0];
if (!(requestedMask & (1 << DM_PIXEL_DEPTH))) {
criteria[n].capability = DM_PIXEL_DEPTH;
criteria[n].comparison = EQ;
criteria[n].value = bpp;
n += 1;
ncriteria[queries] = n;
queries++;
}
if (!(requestedMask & ((1<<DM_WIDTH) | (1<<DM_HEIGHT)) )) {
criteria[n].capability = DM_WIDTH;
criteria[n].comparison = EQ;
criteria[n].value = width;
criteria[n].capability = DM_HEIGHT;
criteria[n].comparison = EQ;
criteria[n].value = height;
n += 2;
ncriteria[queries] = n;
queries++;
}
/* Assume a display frequency of less than 50 is to be ignored. */
if (hertz >= 50) {
if (!(requestedMask & (1 << DM_HERTZ))) {
criteria[n].capability = DM_HERTZ;
criteria[n].comparison = EQ;
criteria[n].value = hertz;
n += 1;
ncriteria[queries] = n;
queries++;
}
}
#endif
/* Perform multiple queries until one succeeds or no more queries. */
do {
queries--;
currentDm = findMatch(dmodes, ndmodes, criteria, ncriteria[queries]);
} while((currentDm == NULL) && (queries > 0));
free(criteria);
}
bool isMatch(char* s, char* p) {
int length = 0,posp = 0,hasStar = 0, poss = 0;//当前s 已经匹配到的位置
int plen = strlen(p), slen = strlen(s);
for (posp = 0; p[posp] != '\0'; posp++) {
if (p[posp] == '*') {
break;
}
buf[length++] = p[posp];
}
if (length > slen || (plen == length && slen > plen)) {
return false;
}
for (int i = 0;i < length;i++) {
if (buf[i] != '?' && buf[i] != s[i]) {
return false;
}
}
//检查前排
poss = length;
length = 0;
for (posp = posp + 1; p[posp] != '\0' && posp < plen ;posp++) {
if (p[posp] == '*') {
hasStar = 1;
if (length > 0) {
poss = findMatch(s, poss,length) ;
length = 0;
if (poss == -1) {
return false;
}
}
} else {
// 或者是 * 前面没有匹配上
buf[length++] = p[posp];
//return false;
}
}
if (length > 0) {
/*
if (hasStar == 0 && slen != strlen(p)) {
return false;
}
*/
//检验末尾的行,是不是正好
slen = slen - length;
if (slen < poss) {
return false;
}
for (int j = 0;s[slen] != '\0' && j < length;slen++,j++) {
if (buf[j] != '?' && buf[j] != s[slen]) {
return false;
}
}
/*
poss = findMatch(s, poss,length);
if (poss == -1 ) {
//没有匹配就是错的
return false;
}
//匹配完了,就是对的
if (s[poss] == '\0') {
return true;
}
//没有匹配完,但是最后的都是?,可以随意放置
for (int i = 0;i < length;i++) {
if (buf[i] != '?') {
return false;
}
}
*/
}
return true;
//return check(s, p, 0, 0);
}
void ShtServer::onTextMessage(QString msg)
{
QElapsedTimer totalTime;
totalTime.start();
QWebSocket *socket = qobject_cast<QWebSocket *>(sender());
qWarning() << "received: " << msg << "from " << socket->peerName();
//Json
QJsonDocument doc = QJsonDocument::fromJson(msg.toUtf8());
if(!doc.isObject()){
socket->sendTextMessage("json or gtfo");
return;
}
QJsonObject docObj = doc.object();
int r = docObj["request"].toInt();
switch(r){
case 0: //LOGIN
{
QString uuid = docObj["uuid"].toString();
User* u = dbManager->findUserByUuid(uuid);
if(!u){
//DEFAULTS FOR NEW USERS
u = new User();
u->setUuid(QUuid::createUuid().toString());
u->setName("anonimo");
u->setEmail("");
u->setMatches(0);
u->setKilos(0);
u->setState(User::AVAILABLE);
u->setAvatar("263a");
dbManager->addUser(u);
u->setSocket(socket);
}
usersBySocket.insert(socket, u);
QJsonObject obj = u->getJsonObject();
QJsonDocument doc;
doc.setObject(obj);
QByteArray msg = doc.toJson(QJsonDocument::Compact);
socket->sendTextMessage(msg);
}break;
case 1: //GET MATCHES
{
User *u = usersBySocket.value(socket);
if(!u){
qWarning() << "WARNING: getMatches from unknown user";
break;
}
QJsonArray matchesList;
for(Match* m: matches){
QJsonObject matchObj = m->getJsonObject();
matchesList.append(matchObj);
}
QJsonObject obj;
obj["request"] = 1;
obj["matchesList"] = matchesList;
QJsonDocument doc;
doc.setObject(obj);
QByteArray msg = doc.toJson(QJsonDocument::Compact);
socket->sendTextMessage(msg);
}break;
case 2: //CREATE MATCH
{
User* u = usersBySocket.value(socket);
if(!u){
qWarning() << "ERROR: createMatch() user not found";
break;
}
if(u->getPendingMatch() != NULL){
qWarning() << "SKIPPING: user already has a match pending";
break;
}
Match *m = new Match(this);
m->init(u);
m->addPlayer(u);
matches.append(m);
u->setPendingMatch(m);
QJsonObject obj;
obj["request"] = 2;
obj["result"] = "ok";
QJsonDocument doc;
doc.setObject(obj);
QByteArray msg = doc.toJson(QJsonDocument::Compact);
socket->sendTextMessage(msg);
connect(m, &Match::finished, this, &ShtServer::onMatchFinished);
}break;
case 3: //JOIN MATCH
{
User* u = usersBySocket.value(socket);
if(!u){
qWarning() << "ERROR: joinMatch() user not found";
break;
}
Match* m = findMatch(docObj["uuid"].toString());
if(!m){
qWarning() << "ERROR: match not found";
break;
}
m->addPlayer(u);
u->setPendingMatch(m);
}break;
case 4: //LEAVE MATCH
{
User* u = usersBySocket.value(socket);
if(!u){
qWarning() << "ERROR: leaveMatch() user not found";
break;
}
Match* m = findMatch(docObj["uuid"].toString());
if(!m){
qWarning() << "ERROR: match not found";
break;
}
m->leavePlayer(u);
}break;
case 5: //PASS CARD
{
User* u = usersBySocket.value(socket);
if(!u){
qWarning() << "ERROR: passCard user not found";
break;
}
Match* m = findMatch(docObj["uuid"].toString());
if(!m){
qWarning() << "ERROR: match not found";
break;
}
m->passCard(u, docObj["card"].toString());
}break;
case 6: //START MATCH
{
User* u = usersBySocket.value(socket);
if(!u){
qWarning() << "ERROR: matchStart user not found";
break;
}
Match* m = findMatch(docObj["uuid"].toString());
if(!m){
qWarning() << "ERROR: match not found";
break;
}
//Only match creator can start the match
if(m->state()==Match::INIT && m->getOwner() == u){
m->start();
} else {
u->sendMessage("match_server", "start_game", "denied", "");
}
}break;
default:
break;
}
qWarning() << "Request " << r << " evaded in " << totalTime.elapsed() << "ms";
}
int main( const int argc, const char const *argv[] )
{
static nst_save_state_s empty_save_state = { 0 };
const char *rom_filename = NULL;
const char *ss_filename = NULL;
tsbrom_s *rom = NULL;
nst_save_state_s *save_state = NULL;
nst_matchup_s *match = NULL;
unsigned char *state_file = NULL;
organization_s *organization = NULL;
team_s *road_team = NULL;
team_s *home_team = NULL;
int save_state_len = 0;
if ( argc != 3 )
{
printf( "Usage: %s <rom_file> <save_state_file>\n", argv[0] );
return EXIT_SUCCESS;
}
rom_filename = argv[1];
ss_filename = argv[2];
if ( (rom = readTsbRom( rom_filename )) == NULL )
{
printf( "Error reading rom: %s\n", getFileUtilsError() );
return EXIT_FAILURE;
}
if ( (state_file = readNstSaveState( ss_filename, &save_state_len )) == NULL )
{
printf( "Error reading Save State: %s\n", getFileUtilsError() );
free( rom );
return EXIT_FAILURE;
}
if ( (save_state = getSaveStateStats( state_file, save_state_len )) == NULL )
{
printf( "Error retrieving stats from Save State: %s\n", getFileUtilsError() );
free( rom );
free( state_file );
return EXIT_FAILURE;
}
if ( (organization = convertOrganization( rom, &empty_save_state, rom, &empty_save_state, 0, bg_None )) == NULL )
{
printf( "Error converting rom and save state data: %s\n", getConvertOrganizationError() );
free( rom );
free( state_file );
return EXIT_FAILURE;
}
if ( (match = findMatch( save_state )) == NULL )
{
printf( "Unable to retrieve match\n" );
free( rom );
free( state_file );
free_organization( organization );
return EXIT_FAILURE;
}
if ( (road_team = findTeam( organization, match->road[0] )) == NULL )
{
printf( "Road team <%d> not found in rom\n", match->road[0] );
free( rom );
free( state_file );
free_organization( organization );
return EXIT_FAILURE;
}
if ( (home_team = findTeam( organization, match->home[0] )) == NULL )
{
printf( "Home team <%d> not found in rom\n", match->home[0] );
free( rom );
free( state_file );
free_organization( organization );
return EXIT_FAILURE;
}
loadGameStats( road_team, home_team, save_state, state_file );
printBoxscore( road_team, home_team, save_state );
free( rom );
free( state_file );
free_organization( organization );
return EXIT_SUCCESS;
}
const LCDbTankMap * LCDbTankMaps::findCurrent( int pTankCID ) const
{
return findMatch( Matcher( pTankCID ) );
}
