I'm sorting strings that are comprised of text and numbers.
I want the sort to sort the number parts as numbers, not alphanumeric.
For example I want: abc1def, ..., abc9def, abc10def
instead of: abc10def, abc1def, ..., abc9def
Does anyone know an algorithm for this (in particular in c++)
Thanks
I asked this exact question (although in Java) and got pointed to http://www.davekoelle.com/alphanum.html which has an algorithm and implementations of it in many languages.
Update 14 years later: Dave Koelle’s blog has gone off line and I can’t find his actual algorithm, but here’s an implementation.
https://github.com/cblanc/koelle-sort
Several natural sort implementations for C++ are available. A brief review:
natural_sort<> - based on Boost.Regex.
In my tests, it's roughly 20 times slower than other options.
Dirk Jagdmann's alnum.hpp, based on Dave Koelle's alphanum algorithm
Potential integer overlow issues for values over MAXINT
Martin Pool's natsort - written in C, but trivially usable from C++.
The only C/C++ implementation I've seen to offer a case insensitive version, which would seem to be a high priority for a "natural" sort.
Like the other implementations, it doesn't actually parse decimal points, but it does special case leading zeroes (anything with a leading 0 is assumed to be a fraction), which is a little weird but potentially useful.
PHP uses this algorithm.
This is known as natural sorting. There's an algorithm here that looks promising.
Be careful of problems with non-ASCII characters (see Jeff's blog entry on the subject).
Partially reposting my another answer:
bool compareNat(const std::string& a, const std::string& b){
if (a.empty())
return true;
if (b.empty())
return false;
if (std::isdigit(a[0]) && !std::isdigit(b[0]))
return true;
if (!std::isdigit(a[0]) && std::isdigit(b[0]))
return false;
if (!std::isdigit(a[0]) && !std::isdigit(b[0]))
{
if (a[0] == b[0])
return compareNat(a.substr(1), b.substr(1));
return (toUpper(a) < toUpper(b));
//toUpper() is a function to convert a std::string to uppercase.
}
// Both strings begin with digit --> parse both numbers
std::istringstream issa(a);
std::istringstream issb(b);
int ia, ib;
issa >> ia;
issb >> ib;
if (ia != ib)
return ia < ib;
// Numbers are the same --> remove numbers and recurse
std::string anew, bnew;
std::getline(issa, anew);
std::getline(issb, bnew);
return (compareNat(anew, bnew));
}
toUpper() function:
std::string toUpper(std::string s){
for(int i=0;i<(int)s.length();i++){s[i]=toupper(s[i]);}
return s;
}
Usage:
std::vector<std::string> str;
str.push_back("abc1def");
str.push_back("abc10def");
...
std::sort(str.begin(), str.end(), compareNat);
To solve what is essentially a parsing problem a state machine (aka finite state automaton) is the way to go. Dissatisfied with the above solutions i wrote a simple one-pass early bail-out algorithm that beats C/C++ variants suggested above in terms of performance, does not suffer from numerical datatype overflow errors, and is easy to modify to add case insensitivity if required.
sources can be found here
For those that arrive here and are already using Qt in their project, you can use the QCollator class. See this question for details.
Avalanchesort is a recursive variation of naturall sort, whiche merge runs, while exploring the stack of sorting-datas. The algorithim will sort stable, even if you add datas to your sorting-heap, while the algorithm is running/sorting.
The search-principle is simple. Only merge runs with the same rank.
After finding the first two naturell runs (rank 0), avalanchesort merge them to a run with rank 1. Then it call avalanchesort, to generate a second run with rank 1 and merge the two runs to a run with rank 2. Then it call the avalancheSort to generate a run with rank 2 on the unsorted datas....
My Implementation porthd/avalanchesort divide the sorting from the handling of the data using interface injection. You can use the algorithmn for datastructures like array, associative arrays or lists.
/**
* #param DataListAvalancheSortInterface $dataList
* #param DataRangeInterface $beginRange
* #param int $avalancheIndex
* #return bool
*/
public function startAvalancheSort(DataListAvalancheSortInterface $dataList)
{
$avalancheIndex = 0;
$rangeResult = $this->avalancheSort($dataList, $dataList->getFirstIdent(), $avalancheIndex);
if (!$dataList->isLastIdent($rangeResult->getStop())) {
do {
$avalancheIndex++;
$lastIdent = $rangeResult->getStop();
if ($dataList->isLastIdent($lastIdent)) {
$rangeResult = new $this->rangeClass();
$rangeResult->setStart($dataList->getFirstIdent());
$rangeResult->setStop($dataList->getLastIdent());
break;
}
$nextIdent = $dataList->getNextIdent($lastIdent);
$rangeFollow = $this->avalancheSort($dataList, $nextIdent, $avalancheIndex);
$rangeResult = $this->mergeAvalanche($dataList, $rangeResult, $rangeFollow);
} while (true);
}
return $rangeResult;
}
/**
* #param DataListAvalancheSortInterface $dataList
* #param DataRangeInterface $range
* #return DataRangeInterface
*/
protected function findRun(DataListAvalancheSortInterface $dataList,
$startIdent)
{
$result = new $this->rangeClass();
$result->setStart($startIdent);
$result->setStop($startIdent);
do {
if ($dataList->isLastIdent($result->getStop())) {
break;
}
$nextIdent = $dataList->getNextIdent($result->getStop());
if ($dataList->oddLowerEqualThanEven(
$dataList->getDataItem($result->getStop()),
$dataList->getDataItem($nextIdent)
)) {
$result->setStop($nextIdent);
} else {
break;
}
} while (true);
return $result;
}
/**
* #param DataListAvalancheSortInterface $dataList
* #param $beginIdent
* #param int $avalancheIndex
* #return DataRangeInterface|mixed
*/
protected function avalancheSort(DataListAvalancheSortInterface $dataList,
$beginIdent,
int $avalancheIndex = 0)
{
if ($avalancheIndex === 0) {
$rangeFirst = $this->findRun($dataList, $beginIdent);
if ($dataList->isLastIdent($rangeFirst->getStop())) {
// it is the last run
$rangeResult = $rangeFirst;
} else {
$nextIdent = $dataList->getNextIdent($rangeFirst->getStop());
$rangeSecond = $this->findRun($dataList, $nextIdent);
$rangeResult = $this->mergeAvalanche($dataList, $rangeFirst, $rangeSecond);
}
} else {
$rangeFirst = $this->avalancheSort($dataList,
$beginIdent,
($avalancheIndex - 1)
);
if ($dataList->isLastIdent($rangeFirst->getStop())) {
$rangeResult = $rangeFirst;
} else {
$nextIdent = $dataList->getNextIdent($rangeFirst->getStop());
$rangeSecond = $this->avalancheSort($dataList,
$nextIdent,
($avalancheIndex - 1)
);
$rangeResult = $this->mergeAvalanche($dataList, $rangeFirst, $rangeSecond);
}
}
return $rangeResult;
}
protected function mergeAvalanche(DataListAvalancheSortInterface $dataList, $oddListRange, $evenListRange)
{
$resultRange = new $this->rangeClass();
$oddNextIdent = $oddListRange->getStart();
$oddStopIdent = $oddListRange->getStop();
$evenNextIdent = $evenListRange->getStart();
$evenStopIdent = $evenListRange->getStop();
$dataList->initNewListPart($oddListRange, $evenListRange);
do {
if ($dataList->oddLowerEqualThanEven(
$dataList->getDataItem($oddNextIdent),
$dataList->getDataItem($evenNextIdent)
)) {
$dataList->addListPart($oddNextIdent);
if ($oddNextIdent === $oddStopIdent) {
$restTail = $evenNextIdent;
$stopTail = $evenStopIdent;
break;
}
$oddNextIdent = $dataList->getNextIdent($oddNextIdent);
} else {
$dataList->addListPart($evenNextIdent);
if ($evenNextIdent === $evenStopIdent) {
$restTail = $oddNextIdent;
$stopTail = $oddStopIdent;
break;
}
$evenNextIdent = $dataList->getNextIdent($evenNextIdent);
}
} while (true);
while ($stopTail !== $restTail) {
$dataList->addListPart($restTail);
$restTail = $dataList->getNextIdent($restTail);
}
$dataList->addListPart($restTail);
$dataList->cascadeDataListChange($resultRange);
return $resultRange;
}
}
My algorithm with test code of java version. If you want to use it in your project you can define a comparator yourself.
import java.io.File;
import java.io.IOException;
import java.util.ArrayList;
import java.util.Arrays;
import java.util.Comparator;
import java.util.List;
import java.util.function.Consumer;
public class FileNameSortTest {
private static List<String> names = Arrays.asList(
"A__01__02",
"A__2__02",
"A__1__23",
"A__11__23",
"A__3++++",
"B__1__02",
"B__22_13",
"1_22_2222",
"12_222_222",
"2222222222",
"1.sadasdsadsa",
"11.asdasdasdasdasd",
"2.sadsadasdsad",
"22.sadasdasdsadsa",
"3.asdasdsadsadsa",
"adsadsadsasd1",
"adsadsadsasd10",
"adsadsadsasd3",
"adsadsadsasd02"
);
public static void main(String...args) {
List<File> files = new ArrayList<>();
names.forEach(s -> {
File f = new File(s);
try {
if (!f.exists()) {
f.createNewFile();
}
files.add(f);
} catch (IOException e) {
e.printStackTrace();
}
});
files.sort(Comparator.comparing(File::getName));
files.forEach(f -> System.out.print(f.getName() + " "));
System.out.println();
files.sort(new Comparator<File>() {
boolean caseSensitive = false;
int SPAN_OF_CASES = 'a' - 'A';
#Override
public int compare(File left, File right) {
char[] csLeft = left.getName().toCharArray(), csRight = right.getName().toCharArray();
boolean isNumberRegion = false;
int diff=0, i=0, j=0, lenLeft=csLeft.length, lenRight=csRight.length;
char cLeft = 0, cRight = 0;
for (; i<lenLeft && j<lenRight; i++, j++) {
cLeft = getCharByCaseSensitive(csLeft[i]);
cRight = getCharByCaseSensitive(csRight[j]);
boolean isNumericLeft = isNumeric(cLeft), isNumericRight = isNumeric(cRight);
if (isNumericLeft && isNumericRight) {
// Number start!
if (!isNumberRegion) {
isNumberRegion = true;
// Remove prefix '0'
while (i < lenLeft && cLeft == '0') i++;
while (j < lenRight && cRight == '0') j++;
if (i == lenLeft || j == lenRight) break;
}
// Diff start: calculate the diff value.
if (cLeft != cRight && diff == 0)
diff = cLeft - cRight;
} else {
if (isNumericLeft != isNumericRight) {
// One numeric and one char.
if (isNumberRegion)
return isNumericLeft ? 1 : -1;
return cLeft - cRight;
} else {
// Two chars: if (number) diff don't equal 0 return it.
if (diff != 0)
return diff;
// Calculate chars diff.
diff = cLeft - cRight;
if (diff != 0)
return diff;
// Reset!
isNumberRegion = false;
diff = 0;
}
}
}
// The longer one will be put backwards.
return (i == lenLeft && j == lenRight) ? cLeft - cRight : (i == lenLeft ? -1 : 1) ;
}
private boolean isNumeric(char c) {
return c >= '0' && c <= '9';
}
private char getCharByCaseSensitive(char c) {
return caseSensitive ? c : (c >= 'A' && c <= 'Z' ? (char) (c + SPAN_OF_CASES) : c);
}
});
files.forEach(f -> System.out.print(f.getName() + " "));
}
}
The output is,
1.sadasdsadsa 11.asdasdasdasdasd 12_222_222 1_22_2222 2.sadsadasdsad 22.sadasdasdsadsa 2222222222 3.asdasdsadsadsa A__01__02 A__11__23 A__1__23 A__2__02 A__3++++ B__1__02 B__22_13 adsadsadsasd02 adsadsadsasd1 adsadsadsasd10 adsadsadsasd3
1.sadasdsadsa 1_22_2222 2.sadsadasdsad 3.asdasdsadsadsa 11.asdasdasdasdasd 12_222_222 22.sadasdasdsadsa 2222222222 A__01__02 A__1__23 A__2__02 A__3++++ A__11__23 adsadsadsasd02 adsadsadsasd1 adsadsadsasd3 adsadsadsasd10 B__1__02 B__22_13
Process finished with exit code 0
// -1: s0 < s1; 0: s0 == s1; 1: s0 > s1
static int numericCompare(const string &s0, const string &s1) {
size_t i = 0, j = 0;
for (; i < s0.size() && j < s1.size();) {
string t0(1, s0[i++]);
while (i < s0.size() && !(isdigit(t0[0]) ^ isdigit(s0[i]))) {
t0.push_back(s0[i++]);
}
string t1(1, s1[j++]);
while (j < s1.size() && !(isdigit(t1[0]) ^ isdigit(s1[j]))) {
t1.push_back(s1[j++]);
}
if (isdigit(t0[0]) && isdigit(t1[0])) {
size_t p0 = t0.find_first_not_of('0');
size_t p1 = t1.find_first_not_of('0');
t0 = p0 == string::npos ? "" : t0.substr(p0);
t1 = p1 == string::npos ? "" : t1.substr(p1);
if (t0.size() != t1.size()) {
return t0.size() < t1.size() ? -1 : 1;
}
}
if (t0 != t1) {
return t0 < t1 ? -1 : 1;
}
}
return i == s0.size() && j == s1.size() ? 0 : i != s0.size() ? 1 : -1;
}
I am not very sure if it is you want, anyway, you can have a try:-)
Related
I have a problem when I'm trying to find a way to check if a trade was made on the current bar or not to stop the EA for making multiple entries on the same bar.
When I don't do a multi Currency EA I usually just use
static datetime lastTradeBar;
and
if(lastTradeBar!=Time[0])
{
if(PFTP_BuySignal > 0 && PFTP_BuySignal_Prev == 0 && PFTP_Rate > PFTP_Rate_Value)
{
myTP = PFTP_TP1;
mySL = PFTP_BuySL;
return (1);
}
if(PFTP_SellSignal > 0 && PFTP_SellSignal_Prev == 0 && PFTP_Rate > PFTP_Rate_Value)
{
myTP = PFTP_TP1;
mySL = PFTP_SellSL;
return (-1);
}
else
return (0);
lastTradeBar=Time[0];
};
return (0);
}
but this doesn't work when using it as I do now.
I'm thinking I need to make a myArray[sym,period,lastTradeBar] or myArray [sym][period][lastTradeBar]
but I can't wrap my head around how or where to put it.
this is the flow
int OnInit() ->
void OnTimer() ->
void LoopThruSym(stringlistOfSym) ->
void LoopThruPeriod(string sym, string listOfPeriods, int listOfSym) ->
void Trade(string sym, int period) ->
int Signal(string sym, int period)
This is how the flow is now.
int OnInit()
{
EventSetTimer(5);
return(INIT_SUCCEEDED);
}
....
void OnTimer()
{
LoopThruSym(symbols);
}
....
void LoopThruSym(string listOfSym)
{
if(Mode == All)
{
int i;
int numSymbolmarketWatch=SymbolsTotal(false);
numSymbols=numSymbolmarketWatch;
ArrayResize(symbolListFinal,numSymbolmarketWatch);
for(i=0; i<numSymbolmarketWatch; i++)
{
symbolListFinal[i]=SymbolName(i,false);
}
}
else
if(Mode == Selected)
{
string sep=",";
ushort u_sep;
int i;
u_sep=StringGetCharacter(sep,0);
StringSplit(listOfSym,u_sep,symbolList);
numSymbols=ArraySize(symbolList);
ArrayResize(symbolListFinal,numSymbols);
for(i=0; i<numSymbols; i++)
{
symbolListFinal[i]=symbolPrefix+symbolList[i]+symbolSuffix;
LoopThruPeriod(symbolListFinal[i],periods, numSymbols);
}
}
else
if(Mode == Current)
{
LoopThruPeriod(Symbol(),periods,numSymbols);
}
return;
}
....
void LoopThruPeriod(string sym, string listOfPeriods, int listOfSym)
{
if(ModePeriod == All_Period)
{
string periodsALL = "1,5,15,30,60,240,1440,10080,43200";
string sep=",";
ushort u_sep;
int i;
int lastTradeBarArrayCount;
u_sep=StringGetCharacter(sep,0);
StringSplit(periodsALL,u_sep,periodList);
numPeriods=ArraySize(periodList);
ArrayResize(periodListFinal,numPeriods);
lastTradeBarArrayCount = listOfSym+numPeriods;
ArrayResize(lastTradeBarArray,lastTradeBarArrayCount);
for(i=0; i<numPeriods; i++)
{
periodListFinal[i]=symbolPrefix+periodList[i]+symbolSuffix;
Trade(sym,StrToInteger(periodListFinal[i]));
Comment("lastTradeBarArrayCount = "+lastTradeBarArrayCount);
}
}
else
if(ModePeriod == Selected_Period)
{
string sep=",";
ushort u_sep;
int i;
int lastTradeBarArrayCount;
u_sep=StringGetCharacter(sep,0);
StringSplit(listOfPeriods,u_sep,periodList);
numPeriods=ArraySize(periodList);
ArrayResize(periodListFinal,numPeriods);
lastTradeBarArrayCount = listOfSym*numPeriods;
ArrayResize(lastTradeBarArray,lastTradeBarArrayCount);
for(i=0; i<numPeriods; i++)
{
periodListFinal[i]=symbolPrefix+periodList[i]+symbolSuffix;
Trade(sym,StrToInteger(periodListFinal[i]));
Comment("lastTradeBarArrayCount = "+lastTradeBarArrayCount);
}
}
if(ModePeriod == Current_Period)
{
Trade(sym,Period());
}
}
...
void Trade(string sym, int period)
{
//Print("Symbole = " + sym + " : " + period);
if(OrderMethod == BuyandSell)
{
if(Signal(sym,period) == 1 && CheckMoneyForTrade(sym,Lots,OP_BUY) && CheckVolumeValue(sym,Lots))
LimitBuy(sym,period);
else
if(Signal(sym,period) == -1 && CheckMoneyForTrade(sym,Lots,OP_SELL) && CheckVolumeValue(sym,Lots))
LimitSell(sym,period);
}
else
if(OrderMethod == BuyOnly)
{
if(Signal(sym,period) == 1 && CheckMoneyForTrade(sym,Lots,OP_BUY) && CheckVolumeValue(sym,Lots))
LimitBuy(sym,period);
}
else
if(OrderMethod == SellOnly)
{
if(Signal(sym,period) == -1 && CheckMoneyForTrade(sym,Lots,OP_SELL) && CheckVolumeValue(sym,Lots))
LimitSell(sym,period);
}
//Trail(sym);
return;
}
...
int Signal(string sym, int period)
{
if(lastTradeBar!=Time[0])
{
if(PFTP_BuySignal > 0 && PFTP_BuySignal_Prev == 0 && PFTP_Rate > PFTP_Rate_Value)
{
myTP = PFTP_TP1;
mySL = PFTP_BuySL;
return (1);
}
if(PFTP_SellSignal > 0 && PFTP_SellSignal_Prev == 0 && PFTP_Rate > PFTP_Rate_Value)
{
myTP = PFTP_TP1;
mySL = PFTP_SellSL;
return (-1);
}
else
return (0);
lastTradeBar=Time[0];
};
return (0);
}
Code a function on the "void OnTick()" like this:
void OnTick()
{
//---
CheckForSignal();
}
And then code the function "CheckForSignal()"
//+------------------------------------------------------------------+
//| Function "CheckForSignal()" |
//+------------------------------------------------------------------+
void CheckForSignal(){
//check here a bar until a Signal given Signal given then initialize it to Time[]
static datetime candletime=0;
if(candletime!=Time[0]){
double upArrow=iCustom(your Custom indicator or whatever parameters);
if(upArrow != EMPTY_VALUE){
EnterTrade(OP_BUY);
}
double downArrow=iCustom(your Custom indicator or whatever parameters);
if(downArrow != EMPTY_VALUE){
EnterTrade(OP_SELL);
}
// if we have a Signal we will initialize candle time to Time[0] to avoid multiple Orders
candletime=Time[0];
}
}
//+------------------------------------------------------------------+
Then Send Signal to Open or Close or whatever you need in my example we will open Trades
//+------------------------------------------------------------------+
//| Function "EnterTrade()" |
//+------------------------------------------------------------------+
void EnterTrade(int type){
int err=0;
double price=0;
double sl=0;
double tp=0;
if(type == OP_BUY){
price=Ask;
}else{
price=Bid;
}
//steppoin8-step15: replace function "OrderSend" parameter
// ->variablename "name" (magic)
//steppoint8-step16: end ";"
int ticket=OrderSend(Symbol(),type,LotSize,price,slippage,0,0,"EA Trade",magic,0,clrMagenta);
if(ticket>0){
if(OrderSelect(ticket,SELECT_BY_TICKET)){
if(OrderType()==OP_BUY){
sl=OrderOpenPrice()-(stopLoss*pips);
tp=OrderOpenPrice()+(takeProfit*pips);
}else if(OrderType()==OP_SELL){
sl= OrderOpenPrice()+(stopLoss*pips);
tp= OrderOpenPrice()-(takeProfit*pips);
}
if(!OrderModify(ticket,price,sl,tp,0,clrMagenta)){
err=GetLastError();
Print("Encountered an error during modification!"+(string)err+" "+ErrorDescription(err));
}
}else{
Print("Failed to Select Order",ticket);
err=GetLastError();
Print("Encountered an error while selecting order"+(string)ticket+" error number"+(string)err+" "+ErrorDescription(err));
}
}
else{
err=GetLastError();
Print("Encountered an error during order placement"+(string)err+" "+ErrorDescription(err));
}
}
//+------------------------------------------------------------------+
This is not an answer more of like progress.
So what i'm doing not instead of checking for candletime=Time[0] I check then the last trade close time is for that sym/magic nr and comment. and then runing it thru if(iBarShift(sym,period,OrderCloseTime()) > 1)
this kinda works but I'm getting problems down the road if I'm trying to use symbols with different miniLots. But that will come on another post.
bool getLastOrderClose(string sym, int period)
{
if(OrdersHistoryTotal() == 0)
return true;
string comment = "Multi Currency "+sym+":"+IntegerToString(period);
int count = 0;
int tradesPerSymbole =0;
for(int i=OrdersHistoryTotal()-1; i >= 0; i--)
if(OrderSelect(i, SELECT_BY_POS, MODE_HISTORY))
{
if(OrderSymbol() == sym)
{
if(OrderMagicNumber() == Magic)
{
tradesPerSymbole++;
if(StringFind(comment,OrderComment())<0)
{
if(iBarShift(sym,period,OrderCloseTime()) > 1)
{
return true;
}
}
}
}
}
else
{
Print(sym +" : "+"OrderSend() - getLastOrderClose - error - ", ErrorDescription(GetLastError()));
}
if(tradesPerSymbole == 0)
return true;
return false;
};
//OrderSend('EURUSD',blablabla Parameter)
//OrderSend('GBPUSD',blablabla Parameter)
//OrderSend('USDJPY',blablabla Parameter)
//OrderSend('EURCHF',blablabla Parameter)
int ticket=OrderSend('EURUSD',type,LotSize,price,slippage,0,0,"EA Trade",magic,0,clrMagenta);
for(int I=ticket;ticket<Orderstotal();i++){
if(OrderSelect(ticket,SELECT_BY_TICKET)){
if(OrderType()==OP_BUY){
sl=OrderOpenPrice()-(stopLoss*pips);
tp=OrderOpenPrice()+(takeProfit*pips);
}else if(OrderType()==OP_SELL){
sl= OrderOpenPrice()+(stopLoss*pips);
tp= OrderOpenPrice()-(takeProfit*pips);
}
if(!OrderModify(ticket,price,sl,tp,0,clrMagenta)){
err=GetLastError();
Print("Encountered an error during modification!"+(string)err+" "+ErrorDescription(err));
}
}else{
Print("Failed to Select Order",ticket);
err=GetLastError();
Print("Encountered an error while selecting order"+(string)ticket+" error number"+(string)err+" "+ErrorDescription(err));
}
}
else{
err=GetLastError();
Print("Encountered an error during order placement"+(string)err+" "+ErrorDescription(err));
}
}
//+------------------------------------------------------------------+
I think its not the pro solution but I would declare a Ordersend function for all the pairs where u want to open the order (I need not to say that the order send function should be declared in a conditional so only the the real ordersend be placed)
but the part where I want your attention is you can do it the hardware by declaring the Ordersend(not with Symbol() instead of that with "YourPairname");
hope this help you a little bit to reach your goal gl
My code below places sell pending orders when certain candle patterns are met on the H_1 chart. But duplicate pending orders are created when I change the chart timeframe and return to H_1. Also old orders that should have hit stop loss or take profit seem to still be open.
I need to have multiple pending orders, but the duplicates and orders that should have closed are not wanted. How can I solve this?
string prefix = "HG";
const int N_bars = 1;
int numBars = 1;
int numBarsArray[];
int tempVal = 0;
int NumOfDisplayBars = 300;
int count = 0;
extern double lotSize = 0.01;
int magicnumber = 1337;
void showRectangles()
{
for (int i=NumOfDisplayBars;i>=1;i--)
{
if(isBearishEngulfing(i))
{
drawBearRectangle(i + 1,iHigh(_Symbol,0,i + 1),iOpen(_Symbol,0,i + 1));
}
}
}
bool isBearishEngulfing(int current)
{
if( (iClose(_Symbol,0,current ) < iOpen( _Symbol,0,current ))
&& (iClose(_Symbol,0,current + 1) > iOpen( _Symbol,0,current + 1))
&& (iOpen( _Symbol,0,current ) > iClose(_Symbol,0,current + 1))
&& (iClose(_Symbol,0,current ) < iOpen( _Symbol,0,current + 1))
)
return true;
return false;
}
bool drawBearRectangle(int candleInt,const double top,const double bottom)
{
const datetime starts = iTime(_Symbol,0,candleInt);
const datetime ends = starts+PeriodSeconds()*N_bars;
const string name = prefix+"_"+(candleInt>0?"DEMAND":"SUPPLY")+"_"+TimeToString(starts);
if(!ObjectCreate(0,name,OBJ_RECTANGLE,0,0,0,0,0))
{
printf("%i %s: failed to create %s. error=%d",__LINE__,__FILE__,name,_LastError);
return false;
}
ObjectSetInteger(0,name,OBJPROP_TIME1, starts);
ObjectSetInteger(0,name,OBJPROP_TIME2, ends);
ObjectSetDouble( 0,name,OBJPROP_PRICE1,bottom);
ObjectSetDouble( 0,name,OBJPROP_PRICE2,top);
ObjectSetInteger(0,name,OBJPROP_COLOR, clrChocolate);
ObjectSetInteger(0,name,OBJPROP_STYLE, STYLE_DASHDOT);
ObjectSetInteger(0,name,OBJPROP_WIDTH, 1);
ObjectSetInteger(0,name,OBJPROP_FILL, false);
if(_Period == 60){
double entryPrice=bottom-3*_Point;
double stopLoss=top;
double slDist=fabs(entryPrice-stopLoss);
double dTakeProfit=entryPrice-2*slDist;
int ticketSell = OrderSend(Symbol(),OP_SELLLIMIT,lotSize, entryPrice,0,stopLoss,dTakeProfit,"SellOrder",magicnumber,0,Red);
}
return true;
}
void OnDeinit(const int reason){ObjectsDeleteAll(0,prefix);}
void OnTick()
{
if(!isNewBar())
return; // not necessary but waste of time to check every second
showRectangles();
}
bool isNewBar()
{
static datetime lastbar;
datetime curbar = (datetime)SeriesInfoInteger(_Symbol,_Period,SERIES_LASTBAR_DATE);
if(lastbar != curbar)
{
lastbar = curbar;
return true;
}
return false;
}
Q : How can I solve the duplicates of pending order issues?... when I change the chart timeframe and return to H_1.
Well, this is rather a feature of the MQL4/5 code-execution ecosystem.
Solution:
Configure a preventive checkmark, setup in MT4-Terminal in Tools > Options > Expert Advisor-tab so as to become:
[x] Disable automated trading when the chart symbol or period has been changed
Let's consider a simple grid, where any point is connected with at most 4 other points (North-East-West-South neighborhood).
I have to write program, that computes minimal route from selected initial point to any of goal points, which are connected (there is route consisting of goal points between any two goals). Of course there can be obstacles on grid.
My solution is quite simple: I'm using A* algorithm with variable heuristic function h(x) - manhattan distance from x to nearest goal point. To find nearest goal point I have to do linear search (in O(n), where n - number of goal points). Here is my question: is there any more efficient solution (heuristic function) to dynamically find nearest goal point (where time < O(n))?
Or maybe A* is not good way to solve that problem?
How many goals, tens or thousands? If tens your way will work fine, if thousands then nearest neighbor search will give you ideas on setting up your data to search quickly.
The tradeoffs are obvious, spatially organizing your data to search will take time and on small sets brute force will be simpler to maintain. Since you're constantly evaluating I think that structuring the data will be worthwhile at very low numbers of points.
An alternate way to do this would be a modified flood fill algorithm that stops once it reaches a destination point during the flood.
First, decide whether you need to optimize, because any optimization is going to complicate your code, and for a small number of goals, your current solution is probably fine for a simple heuristic like Manhattan distance.
Before taking the first step, compute the heuristic for each goal. Remember the nearest goal as the currently selected goal, and move toward it, but subtract the maximum possible progress toward any goal from all the other distances. You can consider this second value a "meta-heuristic"; it is an optimistic estimate of the heuristic for other goals.
On subsequent steps, compute the heuristic for the current goal, and any goals with a "meta-heuristic" that is less than or equal to the heuristic. The other goals can't possibly have a better heuristic, so you don't need to compute them. The nearest goal becomes the new current goal; move toward it, subtracting the maximum possible progress from the others. Repeat until you arrive at a goal.
Use Dijkstra's algorithm, which has as it's output the minimal cost to all reachable points. Then you just select the goal points from the output.
you may consider this article If your goals not too much and want simple ways
If you want to search for any of several goals, construct a heuristic
h'(x) that is the minimum of h1(x), h2(x), h3(x), ... where h1, h2, h3
are heuristics to each of the nearby spots.
One way to think about this is that we can add a new zero-cost edge
from each of the goals to a new graph node. A path to that new node
will necessarily go through one of the goal nodes.
If you want to search for paths to all of several goals, your best
option may be Dijkstra’s Algorithm with early exit when you find all
the goals. There may be a variant of A* that can calculate these
paths; I don’t know.
If you want to search for spot near a single goal, ask A* search to
find a path to the center of the goal area. While processing nodes
from the OPEN set, exit when you pull a node that is near enough.
You can calculate the f score using the nearest target. As others said, for naive approach, you can directly calculate all target distance from current node and pick the minimum, if you only have few targets to search. For more than 100 targets, you can probably find the nearest by KDTree to speed up the process.
Here is a sample code in dart.
Iterable<Vector2> getPath(Vector2 from, Iterable<Vector2> targets,
{double? maxDistance, bool useAStar = false}) {
targets = targets.asSet();
clearPoints();
var projectedTargets = addPoints(targets).toSet();
var tree = useAStar ? IKDTree(targets) : null;
var q = PriorityQueue<Node>(_priorityQueueComparor);
Map<Vector2, Node> visited = {};
var node = Node(from);
visited[from] = node;
q.add(node);
while (q.isNotEmpty) {
var current = q.removeFirst();
// developer.log(
// '${current.point}#${current.distance}: ${getEdges(current.point).map((e) => e.dest)}');
for (var edge in getEdges(current.point)) {
if (visited.containsKey(edge.dest)) continue;
var distance = current.distance + edge.distance;
// too far
if (maxDistance != null && distance > maxDistance) continue;
// it is a target
if (projectedTargets.contains(edge.dest)) {
return reconstructPath(visited, current, edge.dest);
}
// we only interested in exploring polygon node.
if (!_polygonPoints.contains(edge.dest)) continue;
var f = 0.0;
if (tree != null) {
var nearest = tree
.nearest(edge.dest, maxDistance: maxDistance ?? double.infinity)
.firstOrNull;
f = nearest != null ? edge.dest.distanceToSquared(nearest) : 0.0;
}
node = Node(edge.dest, distance, current.count + 1, current.point, f);
visited[edge.dest] = node;
q.add(node);
}
}
return [];
}
Iterable<Vector2> reconstructPath(
Map<Vector2, Node> visited, Node prev, Vector2 point) {
var path = <Vector2>[point];
Node? currentNode = prev;
while (currentNode != null) {
path.add(currentNode.point);
currentNode = visited[currentNode.prev];
}
return path.reversed;
}
int _priorityQueueComparor(Node p0, Node p1) {
int r;
if (p0.f > 0 && p1.f > 0) {
r = ((p0.distance * p0.distance) + p0.f)
.compareTo((p1.distance * p1.distance) + p1.f);
if (r != 0) return r;
}
r = p0.distance.compareTo(p1.distance);
if (r != 0) return r;
return p0.count.compareTo(p1.count);
}
and the implementation of KDTree
class IKDTree {
final int _dimensions = 2;
late Node? _root;
IKDTree(Iterable<Vector2> points) {
_root = _buildTree(points, null);
}
Node? _buildTree(Iterable<Vector2> points, Node? parent) {
var list = points.asList();
if (list.isEmpty) return null;
var median = (list.length / 2).floor();
// Select the longest dimension as division axis
var axis = 0;
var aabb = AABB.fromPoints(list);
for (var i = 1; i < _dimensions; i++) {
if (aabb.range[i] > aabb.range[axis]) {
axis = i;
}
}
// Divide by the division axis and recursively build.
// var list = list.orderBy((e) => _selector(e)[axis]).asList();
list.sort(((a, b) => a[axis].compareTo(b[axis])));
var point = list[median];
var node = Node(point.clone());
node.parent = parent;
node.left = _buildTree(list.sublist(0, median), node);
node.right = _buildTree(list.sublist(median + 1), node);
update(node);
return node;
}
void addPoint(Vector2 point, [bool allowRebuild = true]) {
_root = _addByPoint(_root, point, allowRebuild, 0);
}
// void removePoint(Vector2 point, [bool allowRebuild = true]) {
// if (node == null) return;
// _removeNode(node, allowRebuild);
// }
Node? _addByPoint(
Node? node, Vector2 point, bool allowRebuild, int parentDim) {
if (node == null) {
node = Node(point.clone());
node.dimension = (parentDim + 1) % _dimensions;
update(node);
return node;
}
_pushDown(node);
if (point[node.dimension] < node.point[node.dimension]) {
node.left = _addByPoint(node.left, point, allowRebuild, node.dimension);
} else {
node.right = _addByPoint(node.right, point, allowRebuild, node.dimension);
}
update(node);
bool needRebuild = allowRebuild && criterionCheck(node);
if (needRebuild) node = rebuild(node);
return node;
}
// checked
void _pushDown(Node? node) {
if (node == null) return;
if (node.needPushDownToLeft && node.left != null) {
node.left!.treeDownsampleDeleted |= node.treeDownsampleDeleted;
node.left!.pointDownsampleDeleted |= node.treeDownsampleDeleted;
node.left!.treeDeleted =
node.treeDeleted || node.left!.treeDownsampleDeleted;
node.left!.deleted =
node.left!.treeDeleted || node.left!.pointDownsampleDeleted;
if (node.treeDownsampleDeleted) {
node.left!.downDeletedNum = node.left!.treeSize;
}
if (node.treeDeleted) {
node.left!.invalidNum = node.left!.treeSize;
} else {
node.left!.invalidNum = node.left!.downDeletedNum;
}
node.left!.needPushDownToLeft = true;
node.left!.needPushDownToRight = true;
node.needPushDownToLeft = false;
}
if (node.needPushDownToRight && node.right != null) {
node.right!.treeDownsampleDeleted |= node.treeDownsampleDeleted;
node.right!.pointDownsampleDeleted |= node.treeDownsampleDeleted;
node.right!.treeDeleted =
node.treeDeleted || node.right!.treeDownsampleDeleted;
node.right!.deleted =
node.right!.treeDeleted || node.right!.pointDownsampleDeleted;
if (node.treeDownsampleDeleted) {
node.right!.downDeletedNum = node.right!.treeSize;
}
if (node.treeDeleted) {
node.right!.invalidNum = node.right!.treeSize;
} else {
node.right!.invalidNum = node.right!.downDeletedNum;
}
node.right!.needPushDownToLeft = true;
node.right!.needPushDownToRight = true;
node.needPushDownToRight = false;
}
}
void _removeNode(Node? node, bool allowRebuild) {
if (node == null || node.deleted) return;
_pushDown(node);
node.deleted = true;
node.invalidNum++;
if (node.invalidNum == node.treeSize) {
node.treeDeleted = true;
}
// update and rebuild parent
var parent = node.parent;
if (parent != null) {
updateAncestors(parent);
bool needRebuild = allowRebuild && criterionCheck(parent);
if (needRebuild) parent = rebuild(parent);
}
}
void updateAncestors(Node? node) {
if (node == null) return;
update(node);
updateAncestors(node.parent);
}
void _removeByPoint(Node? node, Vector2 point, bool allowRebuild) {
if (node == null || node.treeDeleted) return;
_pushDown(node);
if (node.point == point && !node.deleted) {
node.deleted = true;
node.invalidNum++;
if (node.invalidNum == node.treeSize) {
node.treeDeleted = true;
}
return;
}
if (point[node.dimension] < node.point[node.dimension]) {
_removeByPoint(node.left, point, false);
} else {
_removeByPoint(node.right, point, false);
}
update(node);
bool needRebuild = allowRebuild && criterionCheck(node);
if (needRebuild) rebuild(node);
}
// checked
void update(Node node) {
var left = node.left;
var right = node.right;
node.treeSize = (left != null ? left.treeSize : 0) +
(right != null ? right.treeSize : 0) +
1;
node.invalidNum = (left != null ? left.invalidNum : 0) +
(right != null ? right.invalidNum : 0) +
(node.deleted ? 1 : 0);
node.downDeletedNum = (left != null ? left.downDeletedNum : 0) +
(right != null ? right.downDeletedNum : 0) +
(node.pointDownsampleDeleted ? 1 : 0);
node.treeDownsampleDeleted = (left == null || left.treeDownsampleDeleted) &&
(right == null || right.treeDownsampleDeleted) &&
node.pointDownsampleDeleted;
node.treeDeleted = (left == null || left.treeDeleted) &&
(right == null || right.treeDeleted) &&
node.deleted;
var minList = <Vector2>[];
var maxList = <Vector2>[];
if (left != null && !left.treeDeleted) {
minList.add(left.aabb.min);
maxList.add(left.aabb.max);
}
if (right != null && !right.treeDeleted) {
minList.add(right.aabb.min);
maxList.add(right.aabb.max);
}
if (!node.deleted) {
minList.add(node.point);
maxList.add(node.point);
}
if (minList.isNotEmpty && maxList.isNotEmpty) {
node.aabb = AABB()
..min = minList.min()
..max = maxList.max();
}
// TODO: Radius data for search: https://github.com/hku-mars/ikd-Tree/blob/main/ikd-Tree/ikd_Tree.cpp#L1312
if (left != null) left.parent = node;
if (right != null) right.parent = node;
// TODO: root alpha value for multithread
}
// checked
final minimalUnbalancedTreeSize = 10;
final deleteCriterionParam = 0.3;
final balanceCriterionParam = 0.6;
bool criterionCheck(Node node) {
if (node.treeSize <= minimalUnbalancedTreeSize) return false;
double balanceEvaluation = 0.0;
double deleteEvaluation = 0.0;
var child = node.left ?? node.right!;
deleteEvaluation = node.invalidNum / node.treeSize;
balanceEvaluation = child.treeSize / (node.treeSize - 1);
if (deleteEvaluation > deleteCriterionParam) return true;
if (balanceEvaluation > balanceCriterionParam ||
balanceEvaluation < 1 - balanceCriterionParam) return true;
return false;
}
void rebuildAll() {
_root = rebuild(_root);
}
// checked
Node? rebuild(Node? node) {
if (node == null) return null;
var parent = node.parent;
var points = flatten(node).toList();
// log('rebuilding: $node objects: ${objects.length}');
deleteTreeNodes(node);
return _buildTree(points, parent);
// if (parent == null) {
// _root = newNode;
// } else if (parent.left == node) {
// parent.left = newNode;
// } else if (parent.right == node) {
// parent.right = newNode;
// }
}
// checked
Iterable<Vector2> flatten(Node? node) sync* {
if (node == null) return;
_pushDown(node);
if (!node.deleted) yield node.point;
yield* flatten(node.left);
yield* flatten(node.right);
}
void deleteTreeNodes(Node? node) {
if (node == null) return;
_pushDown(node);
deleteTreeNodes(node.left);
deleteTreeNodes(node.right);
}
double _calcDist(Vector2 a, Vector2 b) {
double dist = 0;
for (var dim = 0; dim < _dimensions; dim++) {
dist += math.pow(a[dim] - b[dim], 2);
}
return dist;
}
// checked
double _calcBoxDist(Node? node, Vector2 point) {
if (node == null) return double.infinity;
double minDist = 0;
for (var dim = 0; dim < _dimensions; dim++) {
if (point[dim] < node.aabb.min[dim]) {
minDist += math.pow(point[dim] - node.aabb.min[dim], 2);
}
if (point[dim] > node.aabb.max[dim]) {
minDist += math.pow(point[dim] - node.aabb.max[dim], 2);
}
}
return minDist;
}
void _search(Node? node, int maxNodes, Vector2 point, BinaryHeap<Result> heap,
double maxDist) {
if (node == null || node.treeDeleted) return;
double curDist = _calcBoxDist(node, point);
double maxDistSqr = maxDist * maxDist;
if (curDist > maxDistSqr) return;
if (node.needPushDownToLeft || node.needPushDownToRight) {
_pushDown(node);
}
if (!node.deleted) {
double dist = _calcDist(point, node.point);
if (dist <= maxDistSqr &&
(heap.size() < maxNodes || dist < heap.peek().distance)) {
if (heap.size() >= maxNodes) heap.pop();
heap.push(Result(node, dist));
}
}
double distLeftNode = _calcBoxDist(node.left, point);
double distRightNode = _calcBoxDist(node.right, point);
if (heap.size() < maxNodes ||
distLeftNode < heap.peek().distance &&
distRightNode < heap.peek().distance) {
if (distLeftNode <= distRightNode) {
_search(node.left, maxNodes, point, heap, maxDist);
if (heap.size() < maxNodes || distRightNode < heap.peek().distance) {
_search(node.right, maxNodes, point, heap, maxDist);
}
} else {
_search(node.right, maxNodes, point, heap, maxDist);
if (heap.size() < maxNodes || distLeftNode < heap.peek().distance) {
_search(node.left, maxNodes, point, heap, maxDist);
}
}
} else {
if (distLeftNode < heap.peek().distance) {
_search(node.left, maxNodes, point, heap, maxDist);
}
if (distRightNode < heap.peek().distance) {
_search(node.right, maxNodes, point, heap, maxDist);
}
}
}
/// Find the [maxNodes] of nearest Nodes.
/// Distance is calculated via Metric function.
/// Max distance can be set with [maxDistance] param
Iterable<Vector2> nearest(Vector2 point,
{int maxNodes = 1, double maxDistance = double.infinity}) sync* {
var heap = BinaryHeap<Result>((e) => -e.distance);
_search(_root, maxNodes, point, heap, maxDistance);
var found = math.min(maxNodes, heap.content.length);
for (var i = 0; i < found; i++) {
yield heap.content[i].node.point;
}
}
int get length => _root?.length ?? 0;
int get height => _root?.height ?? 0;
}
class Result {
final Node node;
final double distance;
const Result(this.node, this.distance);
}
class Node {
Vector2 point;
int dimension = 0;
Node? parent;
Node? left;
Node? right;
int treeSize = 0;
int invalidNum = 0;
int downDeletedNum = 0;
bool deleted = false;
bool treeDeleted = false;
bool needPushDownToLeft = false;
bool needPushDownToRight = false;
bool treeDownsampleDeleted = false;
bool pointDownsampleDeleted = false;
AABB aabb = AABB();
Node(this.point);
int get length {
return 1 +
(left == null ? 0 : left!.length) +
(right == null ? 0 : right!.length);
}
int get height {
return 1 +
math.max(
left == null ? 0 : left!.height,
right == null ? 0 : right!.height,
);
}
int get depth {
return 1 + (parent == null ? 0 : parent!.depth);
}
}
Here is my code for a cellular automaton I am working on:
UPDATE:
public class Lif1ID {
private Rule rule;
private int stepCount;
public static void main (String [ ] args) {
Lif1ID simulation = new Lif1ID ( );
simulation.processArgs (args);
simulation.producePBM ( ); LINE 9
}
// Print, in Portable Bitmap format, the image corresponding to the rule and step count
// specified on the command line.
public void producePBM ( ) {
int width = (stepCount*2+1);
System.out.println("P1 " + width + " " + (stepCount+1));
String prev_string = "";
// constructs dummy first line of rule
for (int i = 0; i < width; i++){
if (i == stepCount+1){
prev_string += "1";
} else {
prev_string += "0";
}
}
// contructs and prints out all lines prescribed by the rule, including the first
for (int i = 0; i < stepCount; i++) {
String next_string = "";
for (int j = 0; j < width; j++) {
// prints next line, one character at a time
System.out.print(prev_string.charAt(j) + " ");
// specifies cases for the edges as well as for normal inputs to Rule
if (j == 0) {
next_string += rule.output(0, Character.getNumericValue(prev_string.charAt(0)), Character.getNumericValue(prev_string.charAt(1)));
} else if (j == width-1) {
next_string += rule.output(Character.getNumericValue(prev_string.charAt(width-2)), Character.getNumericValue(prev_string.charAt(width-1)), 0);
} else {
String rule_input = prev_string.substring(j-1, j+2);
int first = Character.getNumericValue(rule_input.charAt(0));
int second = Character.getNumericValue(rule_input.charAt(1));
int third = Character.getNumericValue(rule_input.charAt(2));
next_string += rule.output(first, second, third); LINE 43
}
}
// sets prev_string to next_string so that string will be the next string in line to be printed
prev_string = next_string;
System.out.println();
}
}
// Retrieve the command-line arguments, and convert them to values for the rule number
// and the timestep count.
private void processArgs (String [ ] args) {
if (args.length != 2) {
System.err.println ("Usage: java Life1D rule# rowcount");
System.exit (1);
}
try {
rule = new Rule (Integer.parseInt(args[0]));
} catch (Exception ex) {
System.err.println ("The first argument must specify a rule number.");
System.exit (1);
}
try {
stepCount = Integer.parseInt (args[1]);
} catch (Exception ex) {
System.err.println ("The second argument must specify the number of lines in the output.");
System.exit (1);
}
if (stepCount < 1) {
System.err.println ("The number of output lines must be a positive number.");
System.exit (1);
}
}
}
class Rule {
private int a, b, c;
private String rulebin;
public Rule (int ruleNum) {
rulebin = convertToBinary(ruleNum);
}
private String convertToBinary(int input) // get the binary presentation as you want
{ // if the input is 2 you'll get "00000010"
String binary = "";
for (int i = 0; i < 8; i++){
if ((1 << i & input) != 0)
binary += "1";
else
binary+= "0";
}
binary = new StringBuffer(binary).reverse().toString();
return binary;
}
// Return the output that this rule prescribes for the given input.
// a, b, and c are each either 1 or 0; 4*a+2*b+c is the input for the rule.
public char output (int a, int b, int c) {
return rulebin.charAt(7 - 4*a + 2*b + c); LINE 106
}
}
Here is the error message I get when I type in rule 30 with 3 timesteps:
java Life1D 30 3
UPDATED error message:
P1 7 4
0 0 0 0Exception in thread "main" java.lang.StringIndexOutOfBoundsException: String index out of range: 151
at java.lang.String.charAt(String.java:686)
at Rule.output(Life1D.java:106)
at Life1D.producePBM(Life1D.java:43)
at Life1D.main(Life1D.java:9)
The corresponding lines are noted in the code. Why am I getting this error, and how can I fix it? I've been trying to find the error for hours, and it'll a blessing if I could be helped.
The problem is that Rule.output() expects three int parameters, but what you're calling it with on the line
next_string += rule.output(0, prev_string.charAt(0), prev_string.charAt(1));
is actually an int and then 2 chars. Now, the actual character is '0', but due to the implicit conversion the language does for you, you get the ASCII code of '0', which is 48 and that's what's passed to the function Rule.output().
Now, to fix this problem you need to use the method Character.getNumericValue() like so:
next_string += rule.output(0, Character.getNumericValue(prev_string.charAt(0)), Character.getNumericValue(prev_string.charAt(1)));
Don't forget to change the other two invocations of Rule.output()
However, note that this is not the only problem in your code, as I'm still getting String index out of range: 7, because the parameters with which the Rule.output() method is called with are now all 0, but I've answered your original question. If you need more help, let me know.
Here is my code for a cellular automaton I am working on:
public class Life1D {
private Rule rule;
private int stepCount;
public static void main (String [ ] args) {
Life1D simulation = new Life1D ( );
simulation.processArgs (args);
simulation.producePBM ( );
}
// Print, in Portable Bitmap format, the image corresponding to the rule and step count
// specified on the command line.
public void producePBM ( ) {
int width = (stepCount*2+1);
System.out.println("P1 " + width + " " + (stepCount+1));
String prev_string = "";
// constructs dummy first line of rule
for (int i = 0; i < width; i++){
if (i == stepCount+1){
prev_string += "1";
} else {
prev_string += "0";
}
}
// contructs and prints out all lines prescribed by the rule, including the first
for (int i = 0; i < stepCount; i++) {
String next_string = "";
for (int j = 0; j < width; j++) {
// prints next line, one character at a time
System.out.print(prev_string.charAt(j) + " ");
// specifies cases for the edges as well as for normal inputs to Rule
if (j == 0) {
next_string += rule.output(0, prev_string.charAt(0), prev_string.charAt(1));
} else if (j == width-1) {
next_string += rule.output(prev_string.charAt(width-2), prev_string.charAt(width-1), 0);
} else {
String rule_input = prev_string.substring(j-1, j+2);
int first = rule_input.charAt(0);
int second = rule_input.charAt(1);
int third = rule_input.charAt(2);
next_string += rule.output(first, second, third);
}
}
// sets prev_string to next_string so that string will be the next string in line to be printed
prev_string = next_string;
System.out.println();
}
}
// Retrieve the command-line arguments, and convert them to values for the rule number
// and the timestep count.
private void processArgs (String [ ] args) {
if (args.length != 2) {
System.err.println ("Usage: java Life1D rule# rowcount");
System.exit (1);
}
try {
rule = new Rule (Integer.parseInt (args[0]));
} catch (Exception ex) {
System.err.println ("The first argument must specify a rule number.");
System.exit (1);
}
try {
stepCount = Integer.parseInt (args[1]);
} catch (Exception ex) {
System.err.println ("The second argument must specify the number of lines in the output.");
System.exit (1);
}
if (stepCount < 1) {
System.err.println ("The number of output lines must be a positive number.");
System.exit (1);
}
}
}
class Rule {
private int a, b, c;
private String rulebin;
public Rule (int ruleNum) {
rulebin = Integer.toBinaryString(ruleNum);
}
// Return the output that this rule prescribes for the given input.
// a, b, and c are each either 1 or 0; 4*a+2*b+c is the input for the rule.
public int output (int a, int b, int c) {
return rulebin.charAt(7 - 4*a + 2*b + c);
}
}
Here is the error message when I run it:
P1 7 4
0 Exception in thread "main" java.lang.StringIndexOutOfBoundsException: String index out of range: 151
at java.lang.String.charAt(String.java:686)
at Rule.output(Life1D.java:90)
at Life1D.producePBM(Life1D.java:35)
at Life1D.main(Life1D.java:9)
What the heck? Why am I getting this error, and how can I fix it? I've been trying to find the error for hours, and it'll a blessing if I could be helped.
In this particular part you are converting integer to binary string:
rulebin = Integer.toBinaryString(ruleNum);
Now let suppose your parameters are:
first parameter = 12
second parameter = any number
Now when this code will convert this number into binary string then you will get:
rulebin = "1100" (length 4)
Now in this function:
public int output (int a, int b, int c) {
return rulebin.charAt(7 - 4*a + 2*b + c);
}
When a = b = c = 0 then this function will try to access your "rulebin's character 8" but length of your rulebin is 4. That's why you are getting String Index out of bound exception.
Note: I am not sure if you have put any restrictions on your input parameters but this can be a potential problem.
No! the problem is that you're passing char instead of int to
public int output (int a, int b, int c) {
return rulebin.charAt(7 - 4*a + 2*b + c);
}
I tried it and when the prevString.charAt(0) and prevString.charAt(1) were 0 it send to the output method those parameters (0,48,48) (try to debug it and you'll)
this cause the index out of range!
and also the convertion to binary string doesn't return 7 digits format..
UPDATE:
public class Lif1ID {
private Rule rule;
private int stepCount;
public static void main (String [ ] args) {
Lif1ID simulation = new Lif1ID ( );
simulation.processArgs (args);
simulation.producePBM ( );
}
// Print, in Portable Bitmap format, the image corresponding to the rule and step count
// specified on the command line.
public void producePBM ( ) {
int width = (stepCount*2+1);
System.out.println("P1 " + width + " " + (stepCount+1));
String prev_string = "";
// constructs dummy first line of rule
for (int i = 0; i < width; i++){
if (i == stepCount+1){
prev_string += "1";
} else {
prev_string += "0";
}
}
// contructs and prints out all lines prescribed by the rule, including the first
for (int i = 0; i < stepCount; i++) {
String next_string = "";
for (int j = 0; j < width; j++) {
// prints next line, one character at a time
System.out.print(prev_string.charAt(j) + " ");
// specifies cases for the edges as well as for normal inputs to Rule
if (j == 0) {
// take a look at the 'getNumericValue' Method.. in your version it didn't pass 0 or 1, now it does..
next_string += rule.output(0, Character.getNumericValue(prev_string.charAt(0)), Character.getNumericValue(prev_string.charAt(1)));
} else if (j == width-1) {
next_string += rule.output(prev_string.charAt(width-2), prev_string.charAt(width-1), 0);
} else {
String rule_input = prev_string.substring(j-1, j+2);
int first = Character.getNumericValue(rule_input.charAt(0));
int second = Character.getNumericValue(rule_input.charAt(1));
int third = Character.getNumericValue(rule_input.charAt(2));
next_string += rule.output(first, second, third);
}
}
// sets prev_string to next_string so that string will be the next string in line to be printed
prev_string = next_string;
System.out.println();
}
}
// Retrieve the command-line arguments, and convert them to values for the rule number
// and the timestep count.
private void processArgs (String [ ] args) {
if (args.length != 2) {
System.err.println ("Usage: java Life1D rule# rowcount");
System.exit (1);
}
try {
rule = new Rule (Integer.parseInt(args[0]));
} catch (Exception ex) {
System.err.println ("The first argument must specify a rule number.");
System.exit (1);
}
try {
stepCount = Integer.parseInt (args[1]);
} catch (Exception ex) {
System.err.println ("The second argument must specify the number of lines in the output.");
System.exit (1);
}
if (stepCount < 1) {
System.err.println ("The number of output lines must be a positive number.");
System.exit (1);
}
}
}
class Rule {
private int a, b, c;
private String rulebin;
public Rule (int ruleNum) {
rulebin = convertToBinary(ruleNum);
}
private String convertToBinary(int input) // get the binary presentation as you want
{ // if the input is 2 you'll get "00000010"
String binary = "";
for (int i = 0; i < 8; i++){
if ((1 << i & input) != 0)
binary += "1";
else
binary+= "0";
}
binary = new StringBuffer(binary).reverse().toString();
return binary;
}
// Return the output that this rule prescribes for the given input.
// a, b, and c are each either 1 or 0; 4*a+2*b+c is the input for the rule.
public char output (int a, int b, int c) { // here you want to return a char, no?
return rulebin.charAt(7 - 4*a + 2*b + c); // there is a problem with your formula
}
}