void finalPass(FILE *file, Rule *rules, int rules_number)
{
char buffer[BUFFER_LENGTH];
int i, j, c;
fseek(file, 0, SEEK_SET);
c = extractLine(file, BUFFER_LENGTH, buffer);
for(i=0; i<rules_number;i++)
{
while(c!='[')
c = extractLine(file, BUFFER_LENGTH, buffer);
c = extractLine(file, BUFFER_LENGTH, buffer);
for(j=0; j<rules[i].connections_number; j++)
{
setConnection(buffer, rules, rules_number, i, j);
c = extractLine(file, BUFFER_LENGTH, buffer);
}
for(j=0; j<rules[i].symbols_number; j++)
{
setSymbol(buffer, &rules[i], j);
c = extractLine(file, BUFFER_LENGTH, buffer);
}
rules[i].connections_total_weight = 0;
for(j=0;j<rules[i].connections_number;j++)
rules[i].connections_total_weight+=rules[i].connections_weight[j];
rules[i].symbols_total_weight = 0;
for(j=0;j<rules[i].symbols_number;j++)
rules[i].symbols_total_weight+=rules[i].symbols_weight[j];
}
}
void Config::extractArray(const std::string& section, const std::string& line, std::ifstream& file, int& lineNb)
{
std::string array = line;
std::string lineTmp;
while(std::getline(file, lineTmp)) {
lineNb++;
if(isSection(lineTmp)) {
lineNb--;
putbackIntoStream(file, lineTmp);
break; //end of section
}
//skip comments & empty lines
else if(isComment(lineTmp) ||
isEmpty(lineTmp)) {
continue;
}
//parse array
else {
array += ":" + lineTmp;
}
}
std::string key = section.substr(1, section.length()-2) + "=" + array;
extractLine(section, key, file, lineNb);
}
void GeoJson::extractPoly(const rapidjson::Value& _in, Polygon& _out, const MapTile& _tile) {
for (auto itr = _in.Begin(); itr != _in.End(); ++itr) {
_out.emplace_back();
extractLine(*itr, _out.back(), _tile);
}
}
int
BrepHandler::extractLine(const Pointer& ptr)
{
DirectoryEntry* de = _iges->getDirectoryEntry(ptr);
ParameterData params;
_iges->getParameter(de->paramData(), params);
return extractLine(de, params);
}
LexerException *Lexer::lexerException(QString message) const {
int column, line;
computeColumnAndLineForPosition(source(), _position, column, line);
QString text = extractLine(source(), line);
if(!text.isEmpty()) {
QString cursor = QString(" ").repeated(column - 1).append("^");
message += "\n" + text + "\n" + cursor;
}
return LexerException::make(message, resourceName(), line);
}
void wrapText (
std::vector <std::string>& lines,
const std::string& text,
const int width,
bool hyphenate)
{
std::string line;
unsigned int offset = 0;
while (extractLine (line, text, width, hyphenate, offset))
lines.push_back (line);
}
bool Config::parseLine(const std::string& section, const std::string& line, std::ifstream& file, int& lineNb)
{
if(isKey(line, lineNb)) { //key = value
extractLine(section, line, file, lineNb);
}
else if(isArray(line)) { //array
extractArray(section, line, file, lineNb);
}
else { //else crap
return false;
}
return true;
}
int countRules(FILE *file)
{
char buffer[BUFFER_LENGTH];
int c;
int rules_number = 0;
fseek(file, 0, SEEK_SET);
do
{
c = extractLine(file, BUFFER_LENGTH, buffer);
if(c=='[')
rules_number++;
}while(c!=0);
return rules_number;
}
int
BrepHandler::extractSurfaceOfRevolution(const ParameterData& params) {
Pointer linePtr = params.getPointer(1);
Pointer curvePtr = params.getPointer(2);
double startAngle = params.getReal(3);
double endAngle = params.getReal(4);
// load the line (axis of revolution)
int line = extractLine(linePtr);
// load the curve (generatrix)
int curve = extractCurve(_iges->getDirectoryEntry(curvePtr), false);
return handleSurfaceOfRevolution(line, curve, startAngle, endAngle);
}
void initPass(FILE *file, Rule *rules, int rules_number)
{
char buffer[BUFFER_LENGTH];
int i, c;
int count;
fseek(file, 0, SEEK_SET);
c = extractLine(file, BUFFER_LENGTH, buffer);
for(i=0; i<rules_number;i++)
{
while(c!='[')
c = extractLine(file, BUFFER_LENGTH, buffer);
rules[i].name = malloc(strlen(buffer)+1);
strcpy(rules[i].name, buffer);
count = 0;
c = extractLine(file, BUFFER_LENGTH, buffer);
while(c=='-')
{
count++;
c = extractLine(file, BUFFER_LENGTH, buffer);
}
rules[i].connections_number = count;
rules[i].connections = (int*) malloc(sizeof(int)*count);
rules[i].connections_weight = (int*) malloc(sizeof(int)*count);
count = 0;
while(c=='*')
{
count++;
c=extractLine(file, BUFFER_LENGTH, buffer);
}
rules[i].symbols_number = count;
rules[i].symbols_weight = (int*) malloc(sizeof(int)*count);
rules[i].symbols = (char**) malloc(sizeof(char*)*count);
}
}
void wrapText (
std::vector <std::string>& lines,
const std::string& text,
const int width,
bool hyphenate)
{
std::string copy = text;
std::string line;
int modified_width = width > 0 ? width : 1;
while (copy.length ()) // Used as Boolean, therefore UTF8 safe.
{
extractLine (copy, line, modified_width, hyphenate);
lines.push_back (line);
}
}
int
BrepHandler::extractCurve(const DirectoryEntry* de, bool isISO) {
debug("########################## E X T R A C T C U R V E");
ParameterData params;
_iges->getParameter(de->paramData(), params);
switch (de->type()) {
case CircularArc:
debug("\tcircular arc");
return extractCircularArc(de, params);
case CompositeCurve:
debug("\tcomposite curve");
break;
case ConicArc:
debug("\tconic arc");
break;
case CopiousData:
debug("\tcopious data");
// 11: 2d path
// 12: 3d path
// 63: simple closed planar curve
break;
case Line:
debug("\tline");
return extractLine(de, params);
case ParametricSplineCurve:
debug("\tparametric spline curve");
break;
case RationalBSplineCurve:
debug("\trational b-spline curve");
return extractRationalBSplineCurve(de, params);
case OffsetCurve:
debug("\toffset curve");
break;
}
return 0;
}
void HttpConnect::sock_readyRead()
{
QByteArray block = d->sock.read();
if(!d->active) {
ByteStream::appendArray(&d->recvBuf, block);
if(d->inHeader) {
// grab available lines
while(1) {
bool found;
QString line = extractLine(&d->recvBuf, &found);
if(!found)
break;
if(line.isEmpty()) {
d->inHeader = false;
break;
}
d->headerLines += line;
}
// done with grabbing the header?
if(!d->inHeader) {
QString str = d->headerLines.first();
d->headerLines.takeFirst();
QString proto;
int code;
QString msg;
if(!extractMainHeader(str, &proto, &code, &msg)) {
#ifdef PROX_DEBUG
fprintf(stderr, "HttpConnect: invalid header!\n");
#endif
reset(true);
error(ErrProxyNeg);
return;
}
else {
#ifdef PROX_DEBUG
fprintf(stderr, "HttpConnect: header proto=[%s] code=[%d] msg=[%s]\n", qPrintable(proto), code, qPrintable(msg));
for(QStringList::ConstIterator it = d->headerLines.begin(); it != d->headerLines.end(); ++it)
fprintf(stderr, "HttpConnect: * [%s]\n", qPrintable(*it));
#endif
}
if(code == 200) { // OK
#ifdef PROX_DEBUG
fprintf(stderr, "HttpConnect: << Success >>\n");
#endif
d->active = true;
connected();
if(!d->recvBuf.isEmpty()) {
appendRead(d->recvBuf);
d->recvBuf.resize(0);
readyRead();
return;
}
}
else {
int err;
QString errStr;
if(code == 407) { // Authentication failed
err = ErrProxyAuth;
errStr = tr("Authentication failed");
}
else if(code == 404) { // Host not found
err = ErrHostNotFound;
errStr = tr("Host not found");
}
else if(code == 403) { // Access denied
err = ErrProxyNeg;
errStr = tr("Access denied");
}
else if(code == 503) { // Connection refused
err = ErrConnectionRefused;
errStr = tr("Connection refused");
}
else { // invalid reply
err = ErrProxyNeg;
errStr = tr("Invalid reply");
}
#ifdef PROX_DEBUG
fprintf(stderr, "HttpConnect: << Error >> [%s]\n", qPrintable(errStr));
#endif
reset(true);
error(err);
return;
}
}
}
}
else {
appendRead(block);
readyRead();
return;
}
}
void HttpProxyPost::processData(const QByteArray &block)
{
d->recvBuf += block;
if(d->inHeader) {
// grab available lines
while(1) {
bool found;
QString line = extractLine(&d->recvBuf, &found);
if(!found)
break;
if(line.isEmpty()) {
d->inHeader = false;
break;
}
d->headerLines += line;
}
// done with grabbing the header?
if(!d->inHeader) {
QString str = d->headerLines.first();
d->headerLines.takeFirst();
QString proto;
int code;
QString msg;
if(!extractMainHeader(str, &proto, &code, &msg)) {
#ifdef PROX_DEBUG
fprintf(stderr, "HttpProxyPost: invalid header!\n");
#endif
resetConnection(true);
error(ErrProxyNeg);
return;
}
else {
#ifdef PROX_DEBUG
fprintf(stderr, "HttpProxyPost: header proto=[%s] code=[%d] msg=[%s]\n", proto.latin1(), code, msg.latin1());
foreach (const QString &s, d->headerLines)
fprintf(stderr, "HttpProxyPost: * [%s]\n", qPrintable(s));
#endif
}
if(code == 200) { // OK
#ifdef PROX_DEBUG
fprintf(stderr, "HttpProxyPost: << Success >>\n");
#endif
}
else {
int err;
QString errStr;
if(code == 407) { // Authentication failed
err = ErrProxyAuth;
errStr = tr("Authentication failed");
}
else if(code == 404) { // Host not found
err = ErrHostNotFound;
errStr = tr("Host not found");
}
else if(code == 403) { // Access denied
err = ErrProxyNeg;
errStr = tr("Access denied");
}
else if(code == 503) { // Connection refused
err = ErrConnectionRefused;
errStr = tr("Connection refused");
}
else { // invalid reply
err = ErrProxyNeg;
errStr = tr("Invalid reply");
}
#ifdef PROX_DEBUG
fprintf(stderr, "HttpProxyPost: << Error >> [%s]\n", errStr.latin1());
#endif
resetConnection(true);
error(err);
return;
}
}
}
int main (int argc, char** argv)
{
UnitTest t (264);
// void wrapText (std::vector <std::string>& lines, const std::string& text, const int width, bool hyphenate)
std::string text = "This is a test of the line wrapping code.";
std::vector <std::string> lines;
wrapText (lines, text, 10, true);
t.is (lines.size (), (size_t) 5, "wrapText 'This is a test of the line wrapping code.' -> total 5 lines");
t.is (lines[0], "This is a", "wrapText line 0 -> 'This is a'");
t.is (lines[1], "test of", "wrapText line 1 -> 'test of'");
t.is (lines[2], "the line", "wrapText line 2 -> 'the line'");
t.is (lines[3], "wrapping", "wrapText line 3 -> 'wrapping'");
t.is (lines[4], "code.", "wrapText line 4 -> 'code.'");
text = "This ☺ is a test of utf8 line extraction.";
lines.clear ();
wrapText (lines, text, 7, true);
t.is (lines.size (), (size_t) 7, "wrapText 'This ☺ is a test of utf8 line extraction.' -> total 7 lines");
t.is (lines[0], "This ☺", "wrapText line 0 -> 'This ☺'");
t.is (lines[1], "is a", "wrapText line 1 -> 'is a'");
t.is (lines[2], "test of", "wrapText line 2 -> 'test of'");
t.is (lines[3], "utf8", "wrapText line 3 -> 'utf8'");
t.is (lines[4], "line", "wrapText line 4 -> 'line'");
t.is (lines[5], "extrac-", "wrapText line 5 -> 'extrac-'");
t.is (lines[6], "tion.", "wrapText line 6 -> 'tion.'");
text = "one two three\n four";
lines.clear ();
wrapText (lines, text, 13, true);
t.is (lines.size (), (size_t) 2, "wrapText 'one two three\\n four' -> 2 lines");
t.is (lines[0], "one two three", "wrapText line 0 -> 'one two three'");
t.is (lines[1], " four", "wrapText line 1 -> ' four'");
// void extractLine (std::string& text, std::string& line, int length, bool hyphenate, unsigned int& offset)
text = "This ☺ is a test of utf8 line extraction.";
unsigned int offset = 0;
std::string line;
extractLine (line, text, 7, true, offset);
t.is (line, "This ☺", "extractLine 7 'This ☺ is a test of utf8 line extraction.' -> 'This ☺'");
// void extractLine (std::string& text, std::string& line, int length, bool hyphenate, unsigned int& offset)
text = "line 1\nlengthy second line that exceeds width";
offset = 0;
extractLine (line, text, 10, true, offset);
t.is (line, "line 1", "extractLine 10 'line 1\\nlengthy second line that exceeds width' -> 'line 1'");
extractLine (line, text, 10, true, offset);
t.is (line, "lengthy", "extractLine 10 'lengthy second line that exceeds width' -> 'lengthy'");
extractLine (line, text, 10, true, offset);
t.is (line, "second", "extractLine 10 'second line that exceeds width' -> 'second'");
extractLine (line, text, 10, true, offset);
t.is (line, "line that", "extractLine 10 'line that exceeds width' -> 'line that'");
extractLine (line, text, 10, true, offset);
t.is (line, "exceeds", "extractLine 10 'exceeds width' -> 'exceeds'");
extractLine (line, text, 10, true, offset);
t.is (line, "width", "extractLine 10 'width' -> 'width'");
t.notok (extractLine (line, text, 10, true, offset), "extractLine 10 '' -> ''");
// void split (std::vector<std::string>& results, const std::string& input, const char delimiter)
std::vector <std::string> items;
std::string unsplit = "";
split (items, unsplit, '-');
t.is (items.size (), (size_t) 0, "split '' '-' -> 0 items");
unsplit = "a";
split (items, unsplit, '-');
t.is (items.size (), (size_t) 1, "split 'a' '-' -> 1 item");
t.is (items[0], "a", "split 'a' '-' -> 'a'");
split (items, unsplit, '-');
t.is (items.size (), (size_t) 1, "split 'a' '-' -> 1 item");
t.is (items[0], "a", "split 'a' '-' -> 'a'");
unsplit = "-";
split (items, unsplit, '-');
t.is (items.size (), (size_t) 2, "split '-' '-' -> '' ''");
t.is (items[0], "", "split '-' '-' -> [0] ''");
t.is (items[1], "", "split '-' '-' -> [1] ''");
split_minimal (items, unsplit, '-');
t.is (items.size (), (size_t) 0, "split '-' '-' ->");
unsplit = "-a-bc-def";
split (items, unsplit, '-');
t.is (items.size (), (size_t) 4, "split '-a-bc-def' '-' -> '' 'a' 'bc' 'def'");
t.is (items[0], "", "split '-a-bc-def' '-' -> [0] ''");
t.is (items[1], "a", "split '-a-bc-def' '-' -> [1] 'a'");
t.is (items[2], "bc", "split '-a-bc-def' '-' -> [2] 'bc'");
t.is (items[3], "def", "split '-a-bc-def' '-' -> [3] 'def'");
split_minimal (items, unsplit, '-');
t.is (items.size (), (size_t) 3, "split '-a-bc-def' '-' -> 'a' 'bc' 'def'");
t.is (items[0], "a", "split '-a-bc-def' '-' -> [1] 'a'");
t.is (items[1], "bc", "split '-a-bc-def' '-' -> [2] 'bc'");
t.is (items[2], "def", "split '-a-bc-def' '-' -> [3] 'def'");
// void split (std::vector<std::string>& results, const std::string& input, const std::string& delimiter)
unsplit = "";
split (items, unsplit, "--");
t.is (items.size (), (size_t) 0, "split '' '--' -> 0 items");
unsplit = "a";
split (items, unsplit, "--");
t.is (items.size (), (size_t) 1, "split 'a' '--' -> 1 item");
t.is (items[0], "a", "split 'a' '-' -> 'a'");
unsplit = "--";
split (items, unsplit, "--");
t.is (items.size (), (size_t) 2, "split '-' '--' -> '' ''");
t.is (items[0], "", "split '-' '-' -> [0] ''");
t.is (items[1], "", "split '-' '-' -> [1] ''");
unsplit = "--a--bc--def";
split (items, unsplit, "--");
t.is (items.size (), (size_t) 4, "split '-a-bc-def' '--' -> '' 'a' 'bc' 'def'");
t.is (items[0], "", "split '-a-bc-def' '--' -> [0] ''");
t.is (items[1], "a", "split '-a-bc-def' '--' -> [1] 'a'");
t.is (items[2], "bc", "split '-a-bc-def' '--' -> [2] 'bc'");
t.is (items[3], "def", "split '-a-bc-def' '--' -> [3] 'def'");
unsplit = "one\ntwo\nthree";
split (items, unsplit, "\n");
t.is (items.size (), (size_t) 3, "split 'one\\ntwo\\nthree' -> 'one', 'two', 'three'");
t.is (items[0], "one", "split 'one\\ntwo\\nthree' -> [0] 'one'");
t.is (items[1], "two", "split 'one\\ntwo\\nthree' -> [1] 'two'");
t.is (items[2], "three", "split 'one\\ntwo\\nthree' -> [2] 'three'");
// void splitq (std::vector<std::string>&, const std::string&, const char);
unsplit = "one 'two' '' 'three four' \"five six seven\" eight'nine ten'";
splitq (items, unsplit, ' ');
t.is (items.size () , (size_t) 6, "splitq 'one \\'two\\' \\'\\' \\'three four\\' \"five six seven\" eight'nine ten'");
t.is (items[0], "one", "splitq 'one \\'two\\' \\'\\' \\'three four\\' \"five six seven\" eight'nine ten' -> [0] 'one'");
t.is (items[1], "two", "splitq 'one \\'two\\' \\'\\' \\'three four\\' \"five six seven\" eight'nine ten' -> [1] 'two'");
t.is (items[2], "", "splitq 'one \\'two\\' \\'\\' \\'three four\\' \"five six seven\" eight'nine ten' -> [2] ''");
t.is (items[3], "three four", "splitq 'one \\'two\\' \\'\\' \\'three four\\' \"five six seven\" eight'nine ten' -> [3] 'three four'");
t.is (items[4], "five six seven", "splitq 'one \\'two\\' \\'\\' \\'three four\\' \"five six seven\" eight'nine ten' -> [4] 'five six seven'");
t.is (items[5], "eight'nine ten'", "splitq 'one \\'two\\' \\'\\' \\'three four\\' \"five six seven\" eight'nine ten' -> [4] 'eight\\'nine ten\\''");
// void join (std::string& result, const std::string& separator, const std::vector<std::string>& items)
std::vector <std::string> unjoined;
std::string joined;
join (joined, "", unjoined);
t.is (joined.length (), (size_t) 0, "join -> length 0");
t.is (joined, "", "join -> ''");
unjoined.push_back ("");
unjoined.push_back ("a");
unjoined.push_back ("bc");
unjoined.push_back ("def");
join (joined, "", unjoined);
t.is (joined.length (), (size_t) 6, "join '' 'a' 'bc' 'def' -> length 6");
t.is (joined, "abcdef", "join '' 'a' 'bc' 'def' -> 'abcdef'");
join (joined, "-", unjoined);
t.is (joined.length (), (size_t) 9, "join '' - 'a' - 'bc' - 'def' -> length 9");
t.is (joined, "-a-bc-def", "join '' - 'a' - 'bc' - 'def' -> '-a-bc-def'");
// void join (std::string& result, const std::string& separator, const std::vector<int>& items)
std::vector <int> unjoined2;
join (joined, "", unjoined2);
t.is (joined.length (), (size_t) 0, "join -> length 0");
t.is (joined, "", "join -> ''");
unjoined2.push_back (0);
unjoined2.push_back (1);
unjoined2.push_back (2);
join (joined, "", unjoined2);
t.is (joined.length (), (size_t) 3, "join 0 1 2 -> length 3");
t.is (joined, "012", "join 0 1 2 -> '012'");
join (joined, "-", unjoined2);
t.is (joined.length (), (size_t) 5, "join 0 1 2 -> length 5");
t.is (joined, "0-1-2", "join 0 1 2 -> '0-1-2'");
// std::string trimLeft (const std::string& in, const std::string& t /*= " "*/)
t.is (trimLeft (""), "", "trimLeft '' -> ''");
t.is (trimLeft (" "), "", "trimLeft ' ' -> ''");
t.is (trimLeft ("", " \t"), "", "trimLeft '' -> ''");
t.is (trimLeft ("xxx"), "xxx", "trimLeft 'xxx' -> 'xxx'");
t.is (trimLeft ("xxx", " \t"), "xxx", "trimLeft 'xxx' -> 'xxx'");
t.is (trimLeft (" \t xxx \t "), "\t xxx \t ", "trimLeft ' \\t xxx \\t ' -> '\\t xxx \\t '");
t.is (trimLeft (" \t xxx \t ", " \t"), "xxx \t ", "trimLeft ' \\t xxx \\t ' -> 'xxx \\t '");
// std::string trimRight (const std::string& in, const std::string& t /*= " "*/)
t.is (trimRight (""), "", "trimRight '' -> ''");
t.is (trimRight (" "), "", "trimRight ' ' -> ''");
t.is (trimRight ("", " \t"), "", "trimRight '' -> ''");
t.is (trimRight ("xxx"), "xxx", "trimRight 'xxx' -> 'xxx'");
t.is (trimRight ("xxx", " \t"), "xxx", "trimRight 'xxx' -> 'xxx'");
t.is (trimRight (" \t xxx \t "), " \t xxx \t", "trimRight ' \\t xxx \\t ' -> ' \\t xxx \\t'");
t.is (trimRight (" \t xxx \t ", " \t"), " \t xxx", "trimRight ' \\t xxx \\t ' -> ' \\t xxx'");
// std::string trim (const std::string& in, const std::string& t /*= " "*/)
t.is (trim (""), "", "trim '' -> ''");
t.is (trim (" "), "", "trim ' ' -> ''");
t.is (trim ("", " \t"), "", "trim '' -> ''");
t.is (trim ("xxx"), "xxx", "trim 'xxx' -> 'xxx'");
t.is (trim ("xxx", " \t"), "xxx", "trim 'xxx' -> 'xxx'");
t.is (trim (" \t xxx \t "), "\t xxx \t", "trim ' \\t xxx \\t ' -> '\\t xxx \\t'");
t.is (trim (" \t xxx \t ", " \t"), "xxx", "trim ' \\t xxx \\t ' -> 'xxx'");
// std::string unquoteText (const std::string& text)
t.is (unquoteText (""), "", "unquoteText '' -> ''");
t.is (unquoteText ("x"), "x", "unquoteText 'x' -> 'x'");
t.is (unquoteText ("'x"), "'x", "unquoteText ''x' -> ''x'");
t.is (unquoteText ("x'"), "x'", "unquoteText 'x'' -> 'x''");
t.is (unquoteText ("\"x"), "\"x", "unquoteText '\"x' -> '\"x'");
t.is (unquoteText ("x\""), "x\"", "unquoteText 'x\"' -> 'x\"'");
t.is (unquoteText ("''"), "", "unquoteText '''' -> ''");
t.is (unquoteText ("'''"), "'", "unquoteText ''''' -> '''");
t.is (unquoteText ("\"\""), "", "unquoteText '\"\"' -> ''");
t.is (unquoteText ("\"\"\""), "\"", "unquoteText '\"\"\"' -> '\"'");
t.is (unquoteText ("''''"), "''", "unquoteText '''''' -> ''''");
t.is (unquoteText ("\"\"\"\""), "\"\"", "unquoteText '\"\"\"\"' -> '\"\"'");
t.is (unquoteText ("'\"\"'"), "\"\"", "unquoteText '''\"\"' -> '\"\"'");
t.is (unquoteText ("\"''\""), "''", "unquoteText '\"''\"' -> ''''");
t.is (unquoteText ("'x'"), "x", "unquoteText ''x'' -> 'x'");
t.is (unquoteText ("\"x\""), "x", "unquoteText '\"x\"' -> 'x'");
// int longestWord (const std::string&)
t.is (longestWord (" "), 0, "longestWord ( ) --> 0");
t.is (longestWord ("this is a test"), 4, "longestWord (this is a test) --> 4");
t.is (longestWord ("this is a better test"), 6, "longestWord (this is a better test) --> 6");
t.is (longestWord ("house Çirçös clown"), 6, "longestWord (Çirçös) --> 6");
// int longestLine (const std::string&)
t.is (longestLine ("one two three four"), 18, "longestLine (one two three four) --> 18");
t.is (longestLine ("one\ntwo three four"), 14, "longestLine (one\\ntwo three four) --> 14");
t.is (longestLine ("one\ntwo\nthree\nfour"), 5, "longestLine (one\\ntwo\\nthree\\nfour) --> 5");
// std::string commify (const std::string& data)
t.is (commify (""), "", "commify '' -> ''");
t.is (commify ("1"), "1", "commify '1' -> '1'");
t.is (commify ("12"), "12", "commify '12' -> '12'");
t.is (commify ("123"), "123", "commify '123' -> '123'");
t.is (commify ("1234"), "1,234", "commify '1234' -> '1,234'");
t.is (commify ("12345"), "12,345", "commify '12345' -> '12,345'");
t.is (commify ("123456"), "123,456", "commify '123456' -> '123,456'");
t.is (commify ("1234567"), "1,234,567", "commify '1234567' -> '1,234,567'");
t.is (commify ("12345678"), "12,345,678", "commify '12345678' -> '12,345,678'");
t.is (commify ("123456789"), "123,456,789", "commify '123456789' -> '123,456,789'");
t.is (commify ("1234567890"), "1,234,567,890", "commify '1234567890' -> '1,234,567,890'");
t.is (commify ("pre"), "pre", "commify 'pre' -> 'pre'");
t.is (commify ("pre1234"), "pre1,234", "commify 'pre1234' -> 'pre1,234'");
t.is (commify ("1234post"), "1,234post", "commify '1234post' -> '1,234post'");
t.is (commify ("pre1234post"), "pre1,234post", "commify 'pre1234post' -> 'pre1,234post'");
// std::string lowerCase (const std::string& input)
t.is (lowerCase (""), "", "lowerCase '' -> ''");
t.is (lowerCase ("pre01_:POST"), "pre01_:post", "lowerCase 'pre01_:POST' -> 'pre01_:post'");
// std::string upperCase (const std::string& input)
t.is (upperCase (""), "", "upperCase '' -> ''");
t.is (upperCase ("pre01_:POST"), "PRE01_:POST", "upperCase 'pre01_:POST' -> 'PRE01_:POST'");
// bool nontrivial (const std::string&);
t.notok (nontrivial (""), "nontrivial '' -> false");
t.notok (nontrivial (" "), "nontrivial ' ' -> false");
t.notok (nontrivial ("\t\t"), "nontrivial '\\t\\t' -> false");
t.notok (nontrivial (" \t \t"), "nontrivial ' \\t \\t' -> false");
t.ok (nontrivial ("a"), "nontrivial 'a' -> true");
t.ok (nontrivial (" a"), "nontrivial ' a' -> true");
t.ok (nontrivial ("a "), "nontrivial 'a ' -> true");
t.ok (nontrivial (" \t\ta"), "nontrivial ' \\t\\ta' -> true");
t.ok (nontrivial ("a\t\t "), "nontrivial 'a\\t\\t ' -> true");
// bool digitsOnly (const std::string&);
t.ok (digitsOnly (""), "digitsOnly '' -> true");
t.ok (digitsOnly ("0"), "digitsOnly '0' -> true");
t.ok (digitsOnly ("123"), "digitsOnly '123' -> true");
t.notok (digitsOnly ("12fa"), "digitsOnly '12fa' -> false");
// bool noSpaces (const std::string&);
t.ok (noSpaces (""), "noSpaces '' -> true");
t.ok (noSpaces ("a"), "noSpaces 'a' -> true");
t.ok (noSpaces ("abc"), "noSpaces 'abc' -> true");
t.notok (noSpaces (" "), "noSpaces ' ' -> false");
t.notok (noSpaces ("ab cd"), "noSpaces 'ab cd' -> false");
// bool noVerticalSpace (const std::string&);
t.ok (noVerticalSpace (""), "noVerticalSpace '' -> true");
t.ok (noVerticalSpace ("a"), "noVerticalSpace 'a' -> true");
t.ok (noVerticalSpace ("abc"), "noVerticalSpace 'abc' -> true");
t.notok (noVerticalSpace ("a\nb"), "noVerticalSpace 'a\\nb' -> false");
t.notok (noVerticalSpace ("a\rb"), "noVerticalSpace 'a\\rb' -> false");
t.notok (noVerticalSpace ("a\fb"), "noVerticalSpace 'a\\fb' -> false");
text = "Hello, world.";
// 0123456789012
// s e s e
// bool isWordStart (const std::string&, std::string::size_type);
t.notok (isWordStart ("", 0), "isWordStart (\"\", 0) -> false");
t.ok (isWordStart ("foo", 0), "isWordStart (\"foo\", 0) -> true");
t.ok (isWordStart (text, 0), "isWordStart (\"Hello, world.\", 0) -> true");
t.notok (isWordStart (text, 1), "isWordStart (\"Hello, world.\", 1) -> false");
t.notok (isWordStart (text, 2), "isWordStart (\"Hello, world.\", 2) -> false");
t.notok (isWordStart (text, 3), "isWordStart (\"Hello, world.\", 3) -> false");
t.notok (isWordStart (text, 4), "isWordStart (\"Hello, world.\", 4) -> false");
t.notok (isWordStart (text, 5), "isWordStart (\"Hello, world.\", 5) -> false");
t.notok (isWordStart (text, 6), "isWordStart (\"Hello, world.\", 6) -> false");
t.ok (isWordStart (text, 7), "isWordStart (\"Hello, world.\", 7) -> true");
t.notok (isWordStart (text, 8), "isWordStart (\"Hello, world.\", 8) -> false");
t.notok (isWordStart (text, 9), "isWordStart (\"Hello, world.\", 9) -> false");
t.notok (isWordStart (text, 10), "isWordStart (\"Hello, world.\", 10) -> false");
t.notok (isWordStart (text, 11), "isWordStart (\"Hello, world.\", 11) -> false");
t.notok (isWordStart (text, 12), "isWordStart (\"Hello, world.\", 12) -> false");
// bool isWordEnd (const std::string&, std::string::size_type);
t.notok (isWordEnd ("", 0), "isWordEnd (\"\", 0) -> false");
t.ok (isWordEnd ("foo", 2), "isWordEnd (\"foo\", 2) -> true");
t.notok (isWordEnd (text, 0), "isWordEnd (\"Hello, world.\", 0) -> false");
t.notok (isWordEnd (text, 1), "isWordEnd (\"Hello, world.\", 1) -> false");
t.notok (isWordEnd (text, 2), "isWordEnd (\"Hello, world.\", 2) -> false");
t.notok (isWordEnd (text, 3), "isWordEnd (\"Hello, world.\", 3) -> false");
t.ok (isWordEnd (text, 4), "isWordEnd (\"Hello, world.\", 4) -> true");
t.notok (isWordEnd (text, 5), "isWordEnd (\"Hello, world.\", 5) -> false");
t.notok (isWordEnd (text, 6), "isWordEnd (\"Hello, world.\", 6) -> false");
t.notok (isWordEnd (text, 7), "isWordEnd (\"Hello, world.\", 7) -> false");
t.notok (isWordEnd (text, 8), "isWordEnd (\"Hello, world.\", 8) -> false");
t.notok (isWordEnd (text, 9), "isWordEnd (\"Hello, world.\", 9) -> false");
t.notok (isWordEnd (text, 10), "isWordEnd (\"Hello, world.\", 10) -> false");
t.ok (isWordEnd (text, 11), "isWordEnd (\"Hello, world.\", 11) -> true");
t.notok (isWordEnd (text, 12), "isWordEnd (\"Hello, world.\", 12) -> false");
// bool compare (const std::string&, const std::string&, bool caseless = false);
// Make sure degenerate cases are handled.
t.ok (compare ("", ""), "'' == ''");
t.notok (compare ("foo", ""), "foo != ''");
t.notok (compare ("", "foo"), "'' != foo");
// Make sure the default is case-sensitive.
t.ok (compare ("foo", "foo"), "foo == foo");
t.notok (compare ("foo", "FOO"), "foo != foo");
// Test case-sensitive.
t.notok (compare ("foo", "xx", true), "foo != xx");
t.ok (compare ("foo", "foo", true), "foo == foo");
t.notok (compare ("foo", "FOO", true), "foo != FOO");
t.notok (compare ("FOO", "foo", true), "FOO != foo");
t.ok (compare ("FOO", "FOO", true), "FOO == FOO");
// Test case-insensitive.
t.notok (compare ("foo", "xx", false), "foo != foo (caseless)");
t.ok (compare ("foo", "foo", false), "foo == foo (caseless)");
t.ok (compare ("foo", "FOO", false), "foo == FOO (caseless)");
t.ok (compare ("FOO", "foo", false), "FOO == foo (caseless)");
t.ok (compare ("FOO", "FOO", false), "FOO == FOO (caseless)");
// std::string::size_type find (const std::string&, const std::string&, bool caseless = false);
// Make sure degenerate cases are handled.
t.is ((int) find ("foo", ""), (int) 0, "foo !contains ''");
t.is ((int) find ("", "foo"), (int) std::string::npos, "'' !contains foo");
// Make sure the default is case-sensitive.
t.is ((int) find ("foo", "fo"), 0, "foo contains fo");
t.is ((int) find ("foo", "FO"), (int) std::string::npos, "foo !contains fo");
// Test case-sensitive.
t.is ((int) find ("foo", "xx", true), (int) std::string::npos, "foo !contains xx");
t.is ((int) find ("foo", "oo", true), 1, "foo contains oo");
t.is ((int) find ("foo", "fo", true), 0, "foo contains fo");
t.is ((int) find ("foo", "FO", true), (int) std::string::npos, "foo !contains fo");
t.is ((int) find ("FOO", "fo", true), (int) std::string::npos, "foo !contains fo");
t.is ((int) find ("FOO", "FO", true), 0, "foo contains fo");
// Test case-insensitive.
t.is ((int) find ("foo", "xx", false), (int) std::string::npos, "foo !contains xx (caseless)");
t.is ((int) find ("foo", "oo", false), 1, "foo contains oo (caseless)");
t.is ((int) find ("foo", "fo", false), 0, "foo contains fo (caseless)");
t.is ((int) find ("foo", "FO", false), 0, "foo contains FO (caseless)");
t.is ((int) find ("FOO", "fo", false), 0, "FOO contains fo (caseless)");
t.is ((int) find ("FOO", "FO", false), 0, "FOO contains FO (caseless)");
// Test start offset.
t.is ((int) find ("one two three", "e", 3, true), (int) 11, "offset obeyed");
t.is ((int) find ("one two three", "e", 11, true), (int) 11, "offset obeyed");
// int strippedLength (const std::string&);
t.is (strippedLength (std::string ("")), 0, "strippedLength -> 0");
t.is (strippedLength (std::string ("abc")), 3, "strippedLength abc -> 3");
t.is (strippedLength (std::string ("one\033[5;38;255mtwo\033[0mthree")), 11, "strippedLength one^[[5;38;255mtwo^[[0mthree -> 11");
t.is (strippedLength (std::string ("\033[0m")), 0, "strippedLength ^[[0m -> 0");
t.is (strippedLength (std::string ("\033[1m\033[0m")), 0, "strippedLength ^[[1m^[[0m -> 0");
// std::string format (char);
t.is (format ('A'), "A", "format ('A') -> A");
// std::string format (int);
t.is (format (0), "0", "format (0) -> 0");
t.is (format (-1), "-1", "format (-1) -> -1");
// std::string formatHex (int);
t.is (formatHex (0), "0", "formatHex (0) -> 0");
t.is (formatHex (10), "a", "formatHex (10) -> a");
t.is (formatHex (123), "7b", "formatHex (123) -> 7b");
// std::string format (float, int, int);
t.is (format (1.23456789, 8, 1), " 1", "format (1.23456789, 8, 1) -> _______1");
t.is (format (1.23456789, 8, 2), " 1.2", "format (1.23456789, 8, 2) -> _____1.2");
t.is (format (1.23456789, 8, 3), " 1.23", "format (1.23456789, 8, 3) -> ____1.23");
t.is (format (1.23456789, 8, 4), " 1.235", "format (1.23456789, 8, 4) -> ___1.235");
t.is (format (1.23456789, 8, 5), " 1.2346", "format (1.23456789, 8, 5) -> __1.2346");
t.is (format (1.23456789, 8, 6), " 1.23457", "format (1.23456789, 8, 6) -> 1.23457");
t.is (format (1.23456789, 8, 7), "1.234568", "format (1.23456789, 8, 7) -> 1.234568");
t.is (format (1.23456789, 8, 8), "1.2345679", "format (1.23456789, 8, 8) -> 1.2345679");
t.is (format (2444238.56789, 12, 11), "2444238.5679", "format (2444238.56789, 12, 11) -> 2444238.5679");
// std::string format (double, int, int);
// std::string leftJustify (const std::string&, const int);
t.is (leftJustify (123, 3), "123", "leftJustify 123,3 -> '123'");
t.is (leftJustify (123, 4), "123 ", "leftJustify 123,4 -> '123 '");
t.is (leftJustify (123, 5), "123 ", "leftJustify 123,5 -> '123 '");
// std::string leftJustify (const std::string&, const int);
t.is (leftJustify ("foo", 3), "foo", "leftJustify foo,3 -> 'foo'");
t.is (leftJustify ("foo", 4), "foo ", "leftJustify foo,4 -> 'foo '");
t.is (leftJustify ("foo", 5), "foo ", "leftJustify foo,5 -> 'foo '");
t.is (leftJustify ("föo", 5), "föo ", "leftJustify föo,5 -> 'föo '");
// std::string rightJustify (const std::string&, const int);
t.is (rightJustify (123, 3), "123", "rightJustify 123,3 -> '123'");
t.is (rightJustify (123, 4), " 123", "rightJustify 123,4 -> ' 123'");
t.is (rightJustify (123, 5), " 123", "rightJustify 123,5 -> ' 123'");
// std::string rightJustify (const std::string&, const int);
t.is (rightJustify ("foo", 3), "foo", "rightJustify foo,3 -> 'foo'");
t.is (rightJustify ("foo", 4), " foo", "rightJustify foo,4 -> ' foo'");
t.is (rightJustify ("foo", 5), " foo", "rightJustify foo,5 -> ' foo'");
t.is (rightJustify ("föo", 5), " föo", "rightJustify föo,5 -> ' föo'");
// int utf8_length (const std::string&);
t.is ((int) utf8_length ("Çirçös"), 6, "utf8_length (Çirçös) == 6");
t.is ((int) utf8_length ("ツネナラム"), 5, "utf8_length (ツネナラム) == 5");
t.is ((int) utf8_length ("Zwölf Boxkämpfer"), 16, "utf8_length (Zwölf Boxkämpfer) == 16");
return 0;
}
void HttpProxyGetStream::processData(const QByteArray &block)
{
printf("processData: %d bytes\n", block.size());
if(!d->inHeader) {
emit dataReady(block);
return;
}
ByteStream::appendArray(&d->recvBuf, block);
if(d->inHeader) {
// grab available lines
while(1) {
bool found;
QString line = extractLine(&d->recvBuf, &found);
if(!found)
break;
if(line.isEmpty()) {
printf("empty line\n");
d->inHeader = false;
break;
}
d->headerLines += line;
printf("headerLine: [%s]\n", qPrintable(line));
}
// done with grabbing the header?
if(!d->inHeader) {
QString str = d->headerLines.first();
d->headerLines.takeFirst();
QString proto;
int code;
QString msg;
if(!extractMainHeader(str, &proto, &code, &msg)) {
#ifdef PROX_DEBUG
fprintf(stderr, "HttpProxyGetStream: invalid header!\n");
#endif
reset(true);
error(ErrProxyNeg);
return;
}
else {
#ifdef PROX_DEBUG
fprintf(stderr, "HttpProxyGetStream: header proto=[%s] code=[%d] msg=[%s]\n", proto.latin1(), code, msg.latin1());
for(QStringList::ConstIterator it = d->headerLines.begin(); it != d->headerLines.end(); ++it)
fprintf(stderr, "HttpProxyGetStream: * [%s]\n", (*it).latin1());
#endif
}
if(code == 200) { // OK
#ifdef PROX_DEBUG
fprintf(stderr, "HttpProxyGetStream: << Success >>\n");
#endif
bool ok;
int x = getHeader("Content-Length").toInt(&ok);
if(ok)
d->length = x;
QPointer<QObject> self = this;
emit handshaken();
if(!self)
return;
}
else {
int err;
QString errStr;
if(code == 407) { // Authentication failed
err = ErrProxyAuth;
errStr = tr("Authentication failed");
}
else if(code == 404) { // Host not found
err = ErrHostNotFound;
errStr = tr("Host not found");
}
else if(code == 403) { // Access denied
err = ErrProxyNeg;
errStr = tr("Access denied");
}
else if(code == 503) { // Connection refused
err = ErrConnectionRefused;
errStr = tr("Connection refused");
}
else { // invalid reply
err = ErrProxyNeg;
errStr = tr("Invalid reply");
}
#ifdef PROX_DEBUG
fprintf(stderr, "HttpProxyGetStream: << Error >> [%s]\n", errStr.latin1());
#endif
reset(true);
error(err);
return;
}
if(!d->recvBuf.isEmpty()) {
QByteArray a = d->recvBuf;
d->recvBuf.clear();
emit dataReady(a);
}
}
}
}
void GeoJson::extractFeature(const rapidjson::Value& _in, Feature& _out, const MapTile& _tile) {
// Copy properties into tile data
const rapidjson::Value& properties = _in["properties"];
for (auto itr = properties.MemberBegin(); itr != properties.MemberEnd(); ++itr) {
const auto& member = itr->name.GetString();
const rapidjson::Value& prop = properties[member];
// height and minheight need to be handled separately so that their dimensions are normalized
if (strcmp(member, "height") == 0) {
_out.props.numericProps[member] = prop.GetDouble() * _tile.getInverseScale();
continue;
}
if (strcmp(member, "min_height") == 0) {
_out.props.numericProps[member] = prop.GetDouble() * _tile.getInverseScale();
continue;
}
if (prop.IsNumber()) {
_out.props.numericProps[member] = prop.GetDouble();
} else if (prop.IsString()) {
_out.props.stringProps[member] = prop.GetString();
}
}
// Copy geometry into tile data
const rapidjson::Value& geometry = _in["geometry"];
const rapidjson::Value& coords = geometry["coordinates"];
const std::string& geometryType = geometry["type"].GetString();
if (geometryType.compare("Point") == 0) {
_out.geometryType = GeometryType::POINTS;
_out.points.emplace_back();
extractPoint(coords, _out.points.back(), _tile);
} else if (geometryType.compare("MultiPoint") == 0) {
_out.geometryType= GeometryType::POINTS;
for (auto pointCoords = coords.Begin(); pointCoords != coords.End(); ++pointCoords) {
_out.points.emplace_back();
extractPoint(*pointCoords, _out.points.back(), _tile);
}
} else if (geometryType.compare("LineString") == 0) {
_out.geometryType = GeometryType::LINES;
_out.lines.emplace_back();
extractLine(coords, _out.lines.back(), _tile);
} else if (geometryType.compare("MultiLineString") == 0) {
_out.geometryType = GeometryType::LINES;
for (auto lineCoords = coords.Begin(); lineCoords != coords.End(); ++lineCoords) {
_out.lines.emplace_back();
extractLine(*lineCoords, _out.lines.back(), _tile);
}
} else if (geometryType.compare("Polygon") == 0) {
_out.geometryType = GeometryType::POLYGONS;
_out.polygons.emplace_back();
extractPoly(coords, _out.polygons.back(), _tile);
} else if (geometryType.compare("MultiPolygon") == 0) {
_out.geometryType = GeometryType::POLYGONS;
for (auto polyCoords = coords.Begin(); polyCoords != coords.End(); ++polyCoords) {
_out.polygons.emplace_back();
extractPoly(*polyCoords, _out.polygons.back(), _tile);
}
}
}
Line& Line::operator<<(const std::string& line)
{
bool setType = text_.empty();
extractLine(line, setType);
return *this;
}
