mobinzkr/mql-for-begginers
1
0
Fork 0
Code Issues Pull requests Projects Releases Packages Wiki Activity Actions
mql-for-begginers/Include/Math/Stat/Geometric.mqh
Mobin Zarekar 3a4dea3f15 init
2025-07-22 18:30:17 +03:00

567 lines
24 KiB
MQL5
Raw Permalink Blame History

//+------------------------------------------------------------------+
//| Geometric.mqh |
//| Copyright 2000-2025, MetaQuotes Ltd. |
//| https://www.mql5.com |
//+------------------------------------------------------------------+
#include "Math.mqh"
//+------------------------------------------------------------------+
//| Geometric mass function (PDF) |
//+------------------------------------------------------------------+
//| The function returns the probability mass function of the |
//| Geometric distribution with parameter p. |
//| |
//| Arguments: |
//| x : Random variable |
//| p : Probability parameter |
//| log_mode : Logarithm mode flag, if true it returns Log values |
//| error_code : Variable for error code |
//| |
//| Return value: |
//| The probability mass evaluated at x. |
//+------------------------------------------------------------------+
double MathProbabilityDensityGeometric(const double x,const double p,const bool log_mode,int &error_code)
{
//--- check NaN
if(!MathIsValidNumber(x) || !MathIsValidNumber(p))
{
error_code=ERR_ARGUMENTS_NAN;
return QNaN;
}
//--- check probability
if(p<=0.0 || p>1.0)
{
error_code=ERR_ARGUMENTS_INVALID;
return QNaN;
}
//--- check x
if(x!=MathRound(x))
{
error_code=ERR_ARGUMENTS_INVALID;
return QNaN;
}
error_code=ERR_OK;
if(x<0)
return TailLog0(true,log_mode);
if(p==1.0)
{
if(x==0.0)
return TailLog1(true,log_mode);
else
return TailLog0(true,log_mode);
}
//--- return geometric density
return TailLogValue(p*MathPow(1.0-p,x),true,log_mode);
}
//+------------------------------------------------------------------+
//| Geometric mass function (PDF) |
//+------------------------------------------------------------------+
//| The function returns the probability mass function of |
//| the Geometric distribution with parameter p. |
//| |
//| Arguments: |
//| x : Random variable |
//| p : Probability parameter |
//| log_mode : Logarithm mode flag, if true it returns Log values |
//| error_code : Variable for error code |
//| |
//| Return value: |
//| The probability mass evaluated at x. |
//+------------------------------------------------------------------+
double MathProbabilityDensityGeometric(const double x,const double p,int &error_code)
{
return MathProbabilityDensityGeometric(x,p,false,error_code);
}
//+------------------------------------------------------------------+
//| Geometric mass function (PDF) |
//+------------------------------------------------------------------+
//| The function calculates the probability mass function of |
//| the Geometric distribution with parameter p for values in x[]. |
//| |
//| Arguments: |
//| x : Array with random variables |
//| p : Probability parameter |
//| log_mode : Logarithm mode, if true it calculates Log values |
//| result : Array with calculated values |
//| |
//| Return value: |
//| true if successful, otherwise false. |
//+------------------------------------------------------------------+
bool MathProbabilityDensityGeometric(const double &x[],const double p,const bool log_mode,double &result[])
{
//--- check NaN
if(!MathIsValidNumber(p))
return false;
//--- check probability
if(p<=0.0 || p>1.0)
return false;
int data_count=ArraySize(x);
if(data_count==0)
return false;
int error_code=0;
ArrayResize(result,data_count);
//--- special case p==1.0
if(p==1.0)
{
for(int i=0; i<data_count; i++)
{
if(x[i]==0.0)
result[i]=TailLog1(true,log_mode);
else
result[i]=TailLog0(true,log_mode);
}
return true;
}
for(int i=0; i<data_count; i++)
{
double x_arg=x[i];
if(!MathIsValidNumber(x_arg))
return false;
if(x_arg!=MathRound(x_arg))
return false;
if(x_arg<0)
result[i]=TailLog0(true,log_mode);
else
{
double pdf=p*MathPow(1.0-p,x_arg);
result[i]=TailLogValue(pdf,true,log_mode);
}
}
return true;
}
//+------------------------------------------------------------------+
//| Geometric mass function (PDF) |
//+------------------------------------------------------------------+
//| The function calculates the probability mass function of |
//| the Geometric distribution with parameter p for values in x[]. |
//| |
//| Arguments: |
//| x : Array with random variables |
//| p : Probability parameter |
//| result : Array with calculated values |
//| |
//| Return value: |
//| true if successful, otherwise false. |
//+------------------------------------------------------------------+
bool MathProbabilityDensityGeometric(const double &x[],const double p,double &result[])
{
return MathProbabilityDensityGeometric(x,p,false,result);
}
//+------------------------------------------------------------------+
//| Geometric cumulative distribution function (CDF) |
//+------------------------------------------------------------------+
//| The function returns the cumulative distribution function of |
//| the Geometric distribution with parameter p. |
//| |
//| Arguments: |
//| x : The desired quantile |
//| p : Probability parameter |
//| tail : Flag to calculate lower tail |
//| log_mode : Logarithm mode,if true it calculates Log values |
//| error_code : Variable for error code |
//| |
//| Return value: |
//| The value of the Geometric cumulative distribution function |
//| with parameter p, evaluated at x. |
//+------------------------------------------------------------------+
double MathCumulativeDistributionGeometric(const double x,const double p,const bool tail,const bool log_mode,int &error_code)
{
//--- check NaN
if(!MathIsValidNumber(x) || !MathIsValidNumber(p))
{
error_code=ERR_ARGUMENTS_NAN;
return QNaN;
}
//--- check probability range
if(p<=0.0 || p>1.0)
{
error_code=ERR_ARGUMENTS_INVALID;
return QNaN;
}
error_code=ERR_OK;
//--- check x
if(x<0)
return TailLog0(true,log_mode);
//--- check p
if(p==1.0)
{
if(x==0.0)
return TailLog1(true,log_mode);
else
return TailLog0(true,log_mode);
}
//--- calculate cdf and take into account round-off errors for probability
double cdf=1.0-MathPow(1.0-p,x+1.0);
return TailLogValue(MathMin(cdf,1.0),tail,log_mode);
}
//+------------------------------------------------------------------+
//| Geometric cumulative distribution function (CDF) |
//+------------------------------------------------------------------+
//| The function returns the cumulative distribution function of |
//| the Geometric distribution with parameter p. |
//| |
//| Arguments: |
//| x : The desired quantile |
//| p : Probability parameter |
//| error_code : Variable for error code |
//| |
//| Return value: |
//| The value of the Geometric cumulative distribution function |
//| with parameter p, evaluated at x. |
//+------------------------------------------------------------------+
double MathCumulativeDistributionGeometric(const double x,const double p,int &error_code)
{
return MathCumulativeDistributionGeometric(x,p,true,false,error_code);
}
//+------------------------------------------------------------------+
//| Geometric cumulative distribution function (CDF) |
//+------------------------------------------------------------------+
//| The function calculates the cumulative distribution function of |
//| the Geometric distribution with parameter p for values in x[]. |
//| |
//| Arguments: |
//| x : Array with random variables |
//| p : Probability parameter |
//| tail : Flag to calculate lower tail |
//| log_mode : Logarithm mode,if true it calculates Log values |
//| result : Array with calculated values |
//| |
//| Return value: |
//| true if successful, otherwise false. |
//+------------------------------------------------------------------+
bool MathCumulativeDistributionGeometric(const double &x[],const double p,const bool tail,const bool log_mode,double &result[])
{
//--- check NaN
if(!MathIsValidNumber(p))
return false;
//--- check probability range
if(p<=0.0 || p>1.0)
return false;
int data_count=ArraySize(x);
if(data_count==0)
return false;
int error_code=0;
ArrayResize(result,data_count);
//--- special case p==1.0
if(p==1.0)
{
for(int i=0; i<data_count; i++)
{
if(x[i]==0.0)
result[i]=TailLog1(true,log_mode);
else
result[i]=TailLog0(true,log_mode);
}
return true;
}
for(int i=0; i<data_count; i++)
{
double x_arg=x[i];
if(!MathIsValidNumber(x_arg))
return false;
if(x_arg<0)
result[i]=TailLog0(true,log_mode);
else
result[i]=TailLogValue(MathMin(1.0-MathPow(1.0-p,x_arg+1.0),1.0),tail,log_mode);
}
return true;
}
//+------------------------------------------------------------------+
//| Geometric cumulative distribution function (CDF) |
//+------------------------------------------------------------------+
//| The function calculates the cumulative distribution function of |
//| the Geometric distribution with parameter p for values in x[]. |
//| |
//| Arguments: |
//| x : Array with random variables |
//| p : Probability parameter |
//| result : Array with calculated values |
//| |
//| Return value: |
//| true if successful, otherwise false. |
//+------------------------------------------------------------------+
bool MathCumulativeDistributionGeometric(const double &x[],const double p,double &result[])
{
return MathCumulativeDistributionGeometric(x,p,true,false,result);
}
//+------------------------------------------------------------------+
//| Geometric distribution quantile function (inverse CDF) |
//+------------------------------------------------------------------+
//| The function returns the inverse cumulative distribution |
//| function of Geometric distribution with parameter p for the |
//| desired probability. |
//| |
//| Arguments: |
//| probability : The desired probability |
//| p : Probability parameter |
//| tail : Flag to calculate lower tail |
//| log_mode : Logarithm mode,if true it calculates for Log values|
//| error_code : Variable for error code |
//| |
//| Return value: |
//| The value of the Geometric inverse cumulative distribution |
//| function with parameter p, evaluated at probability. |
//+------------------------------------------------------------------+
double MathQuantileGeometric(const double probability,const double p,const bool tail,const bool log_mode,int &error_code)
{
//--- check parameters
if(!MathIsValidNumber(p))
{
error_code=ERR_ARGUMENTS_NAN;
return QNaN;
}
//--- check p range
if(p<=0.0 || p>=1.0)
{
error_code=ERR_ARGUMENTS_INVALID;
return QNaN;
}
//--- calculate real probability
double prob=TailLogProbability(probability,tail,log_mode);
//--- check probability range
if(prob<0.0 || prob>1.0)
{
error_code=ERR_ARGUMENTS_INVALID;
return QNaN;
}
error_code=ERR_OK;
//--- +infinity
if(prob==1.0)
return QPOSINF;
if(prob==0.0)
return 0.0;
double res=MathCeil(-1.0+MathLog(1.0-prob)/MathLog(1.0-p)-1e-12);
if(res<0)
res=0;
//--- return quantile
return res;
}
//+------------------------------------------------------------------+
//| Geometric distribution quantile function (inverse CDF) |
//+------------------------------------------------------------------+
//| The function returns the inverse cumulative distribution |
//| function of the Geometric distribution with parameter p |
//| for the desired probability. |
//| |
//| Arguments: |
//| probability : The desired probability |
//| p : Probability parameter |
//| error_code : Variable for error code |
//| |
//| Return value: |
//| The value of the Geometric quantile function for probability. |
//+------------------------------------------------------------------+
double MathQuantileGeometric(const double probability,const double p,int &error_code)
{
return MathQuantileGeometric(probability,p,true,false,error_code);
}
//+------------------------------------------------------------------+
//| Geometric distribution quantile function (inverse CDF) |
//+------------------------------------------------------------------+
//| The function calculates the inverse cumulative distribution |
//| function of the Geometric distribution with parameter p |
//| for values form the probability[] array. |
//| |
//| Arguments: |
//| probability : Array with probabilities |
//| p : Probability parameter |
//| tail : Flag to calculate lower tail |
//| log_mode : Logarithm mode, if true it calculates Log values |
//| result : Array with calculated values |
//| |
//| Return value: |
//| true if successful, otherwise false. |
//+------------------------------------------------------------------+
bool MathQuantileGeometric(const double &probability[],const double p,const bool tail,const bool log_mode,double &result[])
{
//--- check parameters
if(!MathIsValidNumber(p))
return false;
//--- check p range
if(p<=0.0 || p>=1.0)
return false;
int data_count=ArraySize(probability);
if(data_count==0)
return false;
int error_code=0;
ArrayResize(result,data_count);
for(int i=0; i<data_count; i++)
{
//--- calculate real probability
double prob=TailLogProbability(probability[i],tail,log_mode);
//--- check probability range
if(prob<0.0 || prob>1.0)
return false;
//--- +infinity
if(prob==1.0)
result[i]=QPOSINF;
if(prob==0.0)
result[i]=0.0;
else
{
double res=MathCeil(-1.0+MathLog(1.0-prob)/MathLog(1.0-p)-1e-12);
if(res<0)
res=0;
result[i]=res;
}
}
return true;
}
//+------------------------------------------------------------------+
//| Geometric distribution quantile function (inverse CDF) |
//+------------------------------------------------------------------+
//| The function calculates the inverse cumulative distribution |
//| function of the Geometric distribution with parameter p |
//| for values from the probability[] array. |
//| |
//| Arguments: |
//| probability : Array with probabilities |
//| p : Probability parameter |
//| result : Array with calculated values |
//| |
//| Return value: |
//| true if successful, otherwise false. |
//+------------------------------------------------------------------+
bool MathQuantileGeometric(const double &probability[],const double p,double &result[])
{
return MathQuantileGeometric(probability,p,true,false,result);
}
//+------------------------------------------------------------------+
//| Random variate from the Geometric distribution |
//+------------------------------------------------------------------+
//| Computes the random variable from the Geometric distribution |
//| with parameter p. |
//| |
//| Arguments: |
//| p : Probability parameter |
//| error_code : Variable for error code |
//| |
//| Return value: |
//| The random value with Geometric distribution. |
//+------------------------------------------------------------------+
double MathRandomGeometric(const double p,int &error_code)
{
//--- check parameters
if(!MathIsValidNumber(p))
{
error_code=ERR_ARGUMENTS_NAN;
return QNaN;
}
//--- check probability range
if(p<0.0 || p>1.0)
{
error_code=ERR_ARGUMENTS_INVALID;
return QNaN;
}
error_code=ERR_OK;
//--- generate random number
double rnd=MathRandomNonZero();
double res=MathCeil(-1.0+MathLog(rnd)/MathLog(1.0-p)-1e-12);
if(res<0)
res=0;
return res;
}
//+------------------------------------------------------------------+
//| Random variate from the Geometric distribution |
//+------------------------------------------------------------------+
//| Generates random variables from the Geometric distribution with |
//| parameter p. |
//| |
//| Arguments: |
//| p : Probability parameter |
//| data_count : Number of values needed |
//| result : Output array with random values |
//| |
//| Return value: |
//| true if successful, otherwise false. |
//+------------------------------------------------------------------+
bool MathRandomGeometric(const double p,const int data_count,double &result[])
{
//--- check parameters
if(!MathIsValidNumber(p))
return false;
//--- check probability range
if(p<0.0 || p>1.0)
return false;
//--- prepare output array and calculate random values
ArrayResize(result,data_count);
for(int i=0; i<data_count; i++)
{
//--- generate random number
double rnd=MathRandomNonZero();
double res=MathCeil(-1.0+MathLog(rnd)/MathLog(1.0-p)-1e-12);
if(res<0)
res=0;
result[i]=res;
}
return true;
}
//+------------------------------------------------------------------+
//| Geometric distribution moments |
//+------------------------------------------------------------------+
//| The function calculates 4 first moments of Geometric |
//| distribution with parameter p. |
//| |
//| Arguments: |
//| p : Probability parameter |
//| mean : Variable for mean value (1st moment) |
//| variance : Variable for variance value (2nd moment) |
//| skewness : Variable for skewness value (3rd moment) |
//| kurtosis : Variable for kurtosis value (4th moment) |
//| error_code : Variable for error code |
//| |
//| Return value: |
//| true if moments calculated successfully, otherwise false. |
//+------------------------------------------------------------------+
bool MathMomentsGeometric(const double p,double &mean,double &variance,double &skewness,double &kurtosis,int &error_code)
{
//--- default values
mean =QNaN;
variance=QNaN;
skewness=QNaN;
kurtosis=QNaN;
//--- check NaN
if(!MathIsValidNumber(p))
{
error_code=ERR_ARGUMENTS_NAN;
return false;
}
//--- check probability range
if(p<=0.0 || p>=1.0)
{
error_code=ERR_ARGUMENTS_INVALID;
return(false);
}
error_code=ERR_OK;
//--- calculate moments
mean =(1.0/p)-1;
variance=(1.0-p)/(p*p);
skewness=(2.0-p)/MathSqrt(1.0-p);
kurtosis=(p*p-6*p+6)/(1-p);
//--- successful
return true;
}
//+------------------------------------------------------------------+
Reference in a new issue View git blame Copy permalink