void main(){
char username[50];
char password[50];
char form[200];
//getting length of form
int n = atoi(getenv("CONTENT_LENGTH"));
//1 is go back to login page, 0 is continue onto topics page
int goback = 1;
//identifiers for form parameters
char *user = "******";
char *pass = "******";
//get the form
fgets(form,n+1,stdin);
//get the parameters corresponding to the identifiers
getSubstring(user, form, username);
getSubstring(pass, form, password);
//was getting errors with an extra char on the username, to this just deletes the last char from the username
int i;
for (i = 0; i < 50; i++) {
if (username[i] == '\0') {
username[i-1] = '\0';
break;
}
}
//for printing html
printf("Content-Type:text/html \n\n");
//open members.csv and read line by line
FILE *fp;
fp = fopen("members.csv","r");
char line[1024];
while (fgets(line, 1024, fp)) {
//checks if the username and passwords match on the form and members.csv
goback = login(line, username, password);
if (goback == 0) break;
}
//If no match
if (goback == 1) {
printf("Login failed... Click to go back to Login page.");
//Button that redirects to login page
printf("<form action=\"http://cs.mcgill.ca/~hkoivu/web/comp206/welcome.html\" method=\"POST\"><input type=\"submit\" value=\"Continue\"></form>");
}
}
SvgBoundingBox& SvgPolygon::getBoundingBox() {
if (NULL == this->boundingBoxPtr) {
//i metodi chiamati possono lanciare runtime_error, che viene propagata.
string points = getSubstring(getSubstring(this->toString(), Svg::polygonTopDelimiter, Svg::polygonBottomDelimiter), Svg::pointListTopDelimiter,
Svg::pointListBottomDelimiter);
SvgBoundingBox& bb = SvgBoundingBox::getBoundingBox(getCoords(points));
this->boundingBoxPtr = &bb;
}
return *(this->boundingBoxPtr);
}
/** Retornar el indice de la cadena, si no existe retornar 0*/
unsigned int Trie::getIndice( string cadena ){
//Obtener el nodo raiz del primer caracter de la cadena
Nodo * nodo = this->getInicio(cadena[0]);
//Obtener el substring de la cadena
string subCadena = getSubstring(cadena);
//Recorrer toda la cadena, hasta que no haya hijos o se acabe
while(nodo != NULL && subCadena.length() > 0){
nodo = nodo->getNodoHijoByCaracter(subCadena[0]);
subCadena = getSubstring(subCadena);
}
//Si termino con un nodo, y recorrio toda la cadena retornar el indice
if (nodo != NULL && subCadena.length() == 0)
return nodo->getIndice();
return 0;
}
vector<SvgPoint> SvgPolygon::getCoords(string pointString) {
vector<SvgPoint> coords = vector<SvgPoint>();
string tmp, x, y;
pointString = boost::trim_copy(pointString).append("\n");
int lfpos = pointString.find("\n");
while (lfpos >= 0) {
tmp = boost::trim_copy(pointString.substr(0, lfpos));
pointString.erase(0, lfpos + 1);
try {
x = getSubstring(tmp, "", ","); //can throw a runtime_error
y = tmp.substr(tmp.find(",") + 1);
if (y.empty()) {
throw runtime_error("");
}
} catch (runtime_error& e) {
throw runtime_error("SvgPolygon::getCoords: cannot read coords.");
}
coords.push_back(SvgPoint(strtol(x.c_str(), NULL, 0), strtol(y.c_str(), NULL, 0)));
lfpos = pointString.find("\n");
}
return coords;
}
/** Eliminar la subcadena del nodo, si debe eliminar retornar true, sino false*/
bool Trie::deleteSubCadena(Nodo * nodo, string subCadena ){
bool eliminar = false;
//Obtener el nodo hijo correspondiente al primer caracter de la subcadena
Nodo * nodoHijo = nodo->getNodoHijoByCaracter(subCadena[0]);
//Si existe hijo y la cadena no termino, eliminar la subcadena
if (nodoHijo != NULL && subCadena.length() > 0){
subCadena = getSubstring(subCadena);
eliminar = deleteSubCadena(nodoHijo,subCadena);
}
if (eliminar ){
//Elimino hijo del nodo
nodo->deleteNodoHijo(nodoHijo);
if (nodo->cantHijos() == 0 ){
return true;
}
return false;
}
//Si llego al final de la subCadena, y tiene indice mayor a 0 retornar true
if (subCadena.length() == 0 && nodo->getIndice() > 0){
//Si la cantidad de hijos es 0 eliminar el nodo, si no setear el indice en 0
if (nodo->cantHijos() == 0){
return true;
}else{
nodo->setIndice(0);
}
}
return false;
}
/** Eliminar la cadena del Trie si existe retornar true, sino false*/
bool Trie::deleteCadena( string cadena ){
//Obtener el nodo raiz del primer caracter de la cadena
Nodo * nodo = this->getInicio(cadena[0]);
//Obtener el substring de la cadena
string subCadena = getSubstring(cadena);
return deleteSubCadena(nodo,subCadena);
}
int main(void){
char prompt[100];
char *initialprompt = "Yo bitch.";
//copy the initial prompt into prompt array for changing
memcpy(prompt, initialprompt, strlen(initialprompt)+1);
printf("%s %s", prompt, " ");
char userinput[100];
// printf("%s", userinput);
// printf("%d", isQuit(userinput));
// printf("%d", isSetPrompt(userinput));
while(gets(userinput) != NULL){
//the user inputs valid things
if(isSetPrompt(userinput) == 1){
//we want to set the prompt
//get subString also sets the prompt
getSubstring(prompt, userinput);
}
if(isQuit(userinput) == 1){
//we want to quit
exit(0);
}
else{
system(userinput);
}
printf("%s %s", prompt, " ");
}
}
const char *RegEx::GetSubstring(size_t start, char buffer[], size_t max, size_t *outlen)
{
if (start >= mSubStrings.length())
{
return NULL;
}
RegExSub sub = mSubStrings.at(start);
return getSubstring(subject, sub.start, sub.end, buffer, max, outlen);
}
int verifySubstring(char* str, State* state)
{
int i,j, size = strlen(str), ok=0;
for(i=0;i<size;i++)
{
for(j=0;j<size;j++)
{
ok = ok || runNFA(state,getSubstring(str,i,j),state->last);
}
}
return ok;
}
/** Insertar una cadena al Trie, y retornar si tuvo exito*/
bool Trie::insertCadenaSubLevel(Nodo* nodo, string cadena , unsigned int indice ){
string subCadena = getSubstring(cadena);
/* Insertar caracter en el nodo correspondiente y actualizar el parametro
* nodo con el hijo donde se hizo la insersecion */
bool inserto = this->insertCaracterInHijo(&nodo,subCadena[0]);
//Si no inserto, es el final de la cadena, y el indice no es 0 entonces ya estaba el termino
if (!inserto && subCadena.length() == 0 && nodo->getIndice() > 0)
return false;
else
if (subCadena.length() > 1){
return insertCadenaSubLevel(nodo, subCadena, indice);
}else{
nodo->setIndice(indice);
return true;
}
}
bool MessageFormatter::processNamedTypes() {
#ifdef HAS_MESSAGE_PATTERN
auto formatter = formatterObj();
auto pat = MessageFormatAdapter::getMessagePattern(formatter);
auto parts_count = pat.countParts();
// See MessageFormat::cacheExplicitFormats()
/*
* Looking through the pattern, go to each arg_start part type.
* The arg-typeof that tells us the argument type (simple, complicated)
* then the next part is either the arg_name or arg number
* and then if it's simple after that there could be a part-type=arg-type
* while substring will tell us number, spellout, etc.
* If the next thing isn't an arg-type then assume string.
*
* The last two "parts" can at most be ARG_LIMIT and MSG_LIMIT
* which we need not examine.
*/
clearError();
MessageFormatter::NamedPartsMap namedParts;
MessageFormatter::NumericPartsMap numericParts;
for (int32_t i = 0; i < parts_count - 2; i++) {
auto p = pat.getPart(i);
if (p.getType() != UMSGPAT_PART_TYPE_ARG_START) {
continue;
}
auto name_part = pat.getPart(++i);
icu::Formattable::Type type = icu::Formattable::kObject;
switch (p.getArgType()) {
case UMSGPAT_ARG_TYPE_SIMPLE: {
auto type_part = pat.getPart(++i);
if (type_part.getType() != UMSGPAT_PART_TYPE_ARG_TYPE) {
setError(U_PARSE_ERROR,
"Expected UMSGPAT_PART_TYPE_ARG_TYPE part following "
"UMSGPAT_ARG_TYPE_SIMPLE part");
return false;
}
auto type_string = pat.getSubstring(type_part);
if (type_string == "number") {
type = icu::Formattable::kDouble;
auto style_part = pat.getPart(i + 1);
if (style_part.getType() == UMSGPAT_PART_TYPE_ARG_STYLE) {
auto style_string = pat.getSubstring(style_part);
if (style_string == "integer") {
type = icu::Formattable::kInt64;
}
}
} else if ((type_string == "date") || (type_string == "time")) {
m_usesDate = true;
type = icu::Formattable::kDate;
} else if ((type_string == "spellout") || (type_string == "ordinal") ||
(type_string == "duration")) {
type = icu::Formattable::kDouble;
}
break;
}
case UMSGPAT_ARG_TYPE_PLURAL:
case UMSGPAT_ARG_TYPE_CHOICE:
type = icu::Formattable::kDouble;
break;
case UMSGPAT_ARG_TYPE_NONE:
case UMSGPAT_ARG_TYPE_SELECT:
default:
type = icu::Formattable::kString;
break;
}
if (name_part.getType() == UMSGPAT_PART_TYPE_ARG_NAME) {
auto argName = pat.getSubstring(name_part);
auto it = namedParts.find(argName);
if (it != namedParts.end()) {
if (it->second != type) {
setError(U_ARGUMENT_TYPE_MISMATCH,
"Inconsistent types declared for an argument");
return false;
}
} else {
namedParts[argName] = type;
}
} else if (name_part.getType() == UMSGPAT_PART_TYPE_ARG_NUMBER) {
auto argNumber = name_part.getValue();
if (argNumber < 0) {
setError(U_INVALID_FORMAT_ERROR, "Found part with negative number");
return false;
}
auto it = numericParts.find(argNumber);
if (it != numericParts.end()) {
if (it->second != type) {
setError(U_ARGUMENT_TYPE_MISMATCH,
"Inconsistent types declared for an argument");
return false;
}
} else {
numericParts[argNumber] = type;
}
} else {
setError(U_INVALID_FORMAT_ERROR, "Invalid part type encountered");
}
}
m_namedParts = namedParts;
m_numericParts = numericParts;
return true;
#else
return false;
#endif
}
istringstream bufferStream(buffer);
aux = buffer.substr(0,2);
if (aux == "v ")
{
bufferStream >> id >> dato1 >> dato2 >> dato3;
_mesh->addVertex(dato1, dato2, dato3);
center.x += dato1;
center.y += dato2;
center.z += dato3;
} else if (aux == "f ")
{
bufferStream >> id >> ind1 >> ind2 >> ind3;
temp = getSubstring(ind1, "/", 1);
bufferStream.str(temp);
bufferStream.clear();
bufferStream >> dato1;
bufferStream.ignore(1);
temp = getSubstring(ind2, "/", 1);
bufferStream.str(temp);
bufferStream.clear();
bufferStream >> dato2;
bufferStream.ignore(1);
temp = getSubstring(ind3, "/", 1);
bufferStream.str(temp);
//
// Makes a copy of a Genome, but with only one of the sex chromosomes.
//
// The fate of the mitochondrion is that of the X chromosome.
//
Genome *
Genome::copy(bool copyX, bool copyY, bool copyM) const
{
Genome *newCopy = new Genome(getCountOfBases(),getCountOfBases(), chromosomePadding);
if (NULL == newCopy) {
WriteErrorMessage("Genome::copy: failed to allocate space for copy.\n");
return NULL;
}
const Genome::Contig *currentContig = NULL;
const Genome::Contig *nextContig = getContigAtLocation(0);
unsigned offsetInReference = 0;
while (offsetInReference < getCountOfBases()) {
if (NULL != nextContig && offsetInReference >= nextContig->beginningOffset) {
//
// Start of a new contig. See if we want to skip it.
//
currentContig = nextContig;
nextContig = getNextContigAfterLocation(offsetInReference + 1);
if ((!copyX && !strcmp(currentContig->name,"chrX")) ||
(!copyY && !strcmp(currentContig->name,"chrY")) ||
(!copyM && !strcmp(currentContig->name,"chrM"))) {
//
// Yes, skip over this contig.
//
nextContig = getNextContigAfterLocation(offsetInReference + 1);
if (NULL == nextContig) {
//
// The chromosome that we're skipping was the last one, so we're done.
//
break;
} else {
offsetInReference = nextContig->beginningOffset;
continue;
}
} // If skipping this chromosome
newCopy->startContig(currentContig->name);
} // If new contig beginning
const size_t maxCopySize = 10000;
char dataBuffer[maxCopySize + 1];
unsigned amountToCopy = maxCopySize;
if (nextContig && nextContig->beginningOffset < offsetInReference + amountToCopy) {
amountToCopy = nextContig->beginningOffset - offsetInReference;
}
if (getCountOfBases() < offsetInReference + amountToCopy) {
amountToCopy = getCountOfBases() - offsetInReference;
}
memcpy(dataBuffer,getSubstring(offsetInReference,amountToCopy), amountToCopy);
dataBuffer[amountToCopy] = '\0';
newCopy->addData(dataBuffer);
offsetInReference += amountToCopy;
}
newCopy->fillInContigLengths();
newCopy->sortContigsByName();
return newCopy;
}
/**
* This method reads in the records.txt file, forms records out of them,
* and inserts them into the linked list.
**/
int readfile(char name[], char address[], int *yob, char telno[], char filename[], struct record **start)
{
/* Initialize variables */
char line[100];
line[0] = '\0';
int colCount = 0;
int intchar = 0;
char nextchar[2];
char yearofbirth[15];
int counter = 0;
/* Open records.txt */
filein = fopen(filename, "r");
/* The file does not exist */
if(!filein)
return 1;
/* Load contents into struct account */
while(intchar != -1)
{
/* Each column represents a field. End the entry after the last column. */
while(colCount < 4)
{
/* Read in the data as an int */
intchar = fgetc(filein);
/* checks for EOF */
if(intchar == -1)
{
break;
}
/* Copies each character 1 at a time */
else
{
/* Convert the int to a char and store it */
nextchar[0] = (char)intchar;
nextchar[1] = '\0';
/* If a column is encountered increment the counter */
if(nextchar[0] == '|')
colCount++;
/* If the character is a newline skip it */
if(intchar == 10)
continue;
/* If not add it to the string line */
else
strcat(line, nextchar);
}
/* EOF has been reached */
if(intchar == -1)
break;
}
/* Reset the column counter for the next record */
colCount = 0;
/* EOF has been reached */
if(intchar == -1)
break;
/* Gets the field for name */
getSubstring(name, line);
/* Gets the field for address */
getSubstring(address, line);
/* Gets the field for yob */
getSubstring(yearofbirth, line);
*yob = atoi(yearofbirth);
memset(yearofbirth, 0, 15);
/* Gets the field for telno */
line[strlen(line)-1] = 0;
/* Copy the rest of the line to the phone number */
strcpy(telno, line);
/* Add the record to the linked list */
addRecord(start, name, address, *yob, telno);
counter++;
/* Clears line */
memset(line, 0, 100);
}
/* Print the number of records retrieved */
printf("\n%d%s\n", counter, " records retrieved.");
/* Success! */
fclose(filein);
return 0;
}
//
// Makes a copy of a Genome, but with only one of the sex chromosomes.
//
// The fate of the mitochondrion is that of the X chromosome.
//
Genome *
Genome::copy(bool copyX, bool copyY, bool copyM) const
{
Genome *newCopy = new Genome(getCountOfBases(),getCountOfBases());
if (NULL == newCopy) {
fprintf(stderr,"Genome::copy: failed to allocate space for copy.\n");
return NULL;
}
const Genome::Piece *currentPiece = NULL;
const Genome::Piece *nextPiece = getPieceAtLocation(0);
unsigned offsetInReference = 0;
while (offsetInReference < getCountOfBases()) {
if (NULL != nextPiece && offsetInReference >= nextPiece->beginningOffset) {
//
// Start of a new piece. See if we want to skip it.
//
currentPiece = nextPiece;
nextPiece = getNextPieceAfterLocation(offsetInReference + 1);
if ((!copyX && !strcmp(currentPiece->name,"chrX")) ||
(!copyY && !strcmp(currentPiece->name,"chrY")) ||
(!copyM && !strcmp(currentPiece->name,"chrM"))) {
//
// Yes, skip over this piece.
//
nextPiece = getNextPieceAfterLocation(offsetInReference + 1);
if (NULL == nextPiece) {
//
// The chromosome that we're skipping was the last one, so we're done.
//
break;
} else {
offsetInReference = nextPiece->beginningOffset;
continue;
}
} // If skipping this chromosome
newCopy->startPiece(currentPiece->name);
} // If new piece beginning
const size_t maxCopySize = 10000;
char dataBuffer[maxCopySize + 1];
unsigned amountToCopy = maxCopySize;
if (nextPiece && nextPiece->beginningOffset < offsetInReference + amountToCopy) {
amountToCopy = nextPiece->beginningOffset - offsetInReference;
}
if (getCountOfBases() < offsetInReference + amountToCopy) {
amountToCopy = getCountOfBases() - offsetInReference;
}
memcpy(dataBuffer,getSubstring(offsetInReference,amountToCopy), amountToCopy);
dataBuffer[amountToCopy] = '\0';
newCopy->addData(dataBuffer);
offsetInReference += amountToCopy;
}
return newCopy;
}
