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Generator.h
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Generator.h
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// -*- c++ -*-
// 1. implement "fixed" generator
// 2. implement discrete generator
// 3. implement combine generator?
#ifndef GENERATOR_H
#define GENERATOR_H
#define MAX(a,b) ((a) > (b) ? (a) : (b))
#include "config.h"
#include <string>
#include <vector>
#include <utility>
#include <assert.h>
#include <inttypes.h>
#include <limits.h>
#include <math.h>
#include <stdint.h>
#include <stdlib.h>
#include <string.h>
#include "log.h"
#include "util.h"
// Generator syntax:
//
// \d+ == fixed
// n[ormal]:mean,sd
// e[xponential]:lambda
// p[areto]:scale,shape
// g[ev]:loc,scale,shape
// fb_value, fb_key, fb_rate
class Generator {
public:
Generator() {}
// Generator(const Generator &g) = delete;
// virtual Generator& operator=(const Generator &g) = delete;
virtual ~Generator() {}
virtual double generate(double U = -1.0) = 0;
virtual void set_lambda(double lambda) {DIE("set_lambda() not implemented");}
protected:
std::string type;
};
class Fixed : public Generator {
public:
Fixed(double _value = 1.0) : value(_value) { D("Fixed(%f)", value); }
virtual double generate(double U = -1.0) { return value; }
virtual void set_lambda(double lambda) {
if (lambda > 0.0) value = 1.0 / lambda;
else value = 0.0;
}
private:
double value;
};
class Uniform : public Generator {
public:
Uniform(double _scale) : scale(_scale) { D("Uniform(%f)", scale); }
virtual double generate(double U = -1.0) {
if (U < 0.0) U = drand48();
return scale * U;
}
virtual void set_lambda(double lambda) {
if (lambda > 0.0) scale = 2.0 / lambda;
else scale = 0.0;
}
private:
double scale;
};
class Normal : public Generator {
public:
Normal(double _mean = 1.0, double _sd = 1.0) : mean(_mean), sd(_sd) {
D("Normal(mean=%f, sd=%f)", mean, sd);
}
virtual double generate(double U = -1.0) {
if (U < 0.0) U = drand48();
double V = U; // drand48();
double N = sqrt(-2 * log(U)) * cos(2 * M_PI * V);
return mean + sd * N;
}
virtual void set_lambda(double lambda) {
if (lambda > 0.0) mean = 1.0 / lambda;
else mean = 0.0;
}
private:
double mean, sd;
};
class Exponential : public Generator {
public:
Exponential(double _lambda = 1.0) : lambda(_lambda) {
D("Exponential(lambda=%f)", lambda);
}
virtual double generate(double U = -1.0) {
if (lambda <= 0.0) return 0.0;
if (U < 0.0) U = drand48();
return -log(U) / lambda;
}
virtual void set_lambda(double lambda) { this->lambda = lambda; }
private:
double lambda;
};
class GPareto : public Generator {
public:
GPareto(double _loc = 0.0, double _scale = 1.0, double _shape = 1.0) :
loc(_loc), scale(_scale), shape(_shape) {
assert(shape != 0.0);
D("GPareto(loc=%f, scale=%f, shape=%f)", loc, scale, shape);
}
virtual double generate(double U = -1.0) {
if (U < 0.0) U = drand48();
return loc + scale * (pow(U, -shape) - 1) / shape;
}
virtual void set_lambda(double lambda) {
if (lambda <= 0.0) scale = 0.0;
else scale = (1 - shape) / lambda - (1 - shape) * loc;
}
private:
double loc /* mu */;
double scale /* sigma */, shape /* k */;
};
class GEV : public Generator {
public:
GEV(double _loc = 0.0, double _scale = 1.0, double _shape = 1.0) :
e(1.0), loc(_loc), scale(_scale), shape(_shape) {
assert(shape != 0.0);
D("GEV(loc=%f, scale=%f, shape=%f)", loc, scale, shape);
}
virtual double generate(double U = -1.0) {
return loc + scale * (pow(e.generate(U), -shape) - 1) / shape;
}
private:
Exponential e;
double loc /* mu */, scale /* sigma */, shape /* k */;
};
class Discrete : public Generator {
public:
~Discrete() { delete def; }
Discrete(Generator* _def = NULL) : def(_def) {
if (def == NULL) def = new Fixed(0.0);
}
virtual double generate(double U = -1.0) {
double Uc = U;
if (pv.size() > 0 && U < 0.0) U = drand48();
double sum = 0;
for (auto p: pv) {
sum += p.first;
if (U < sum) return p.second;
}
return def->generate(Uc);
}
void add(double p, double v) {
pv.push_back(std::pair<double,double>(p, v));
}
private:
Generator *def;
std::vector< std::pair<double,double> > pv;
};
class KeyGenerator {
public:
KeyGenerator(Generator* _g, double _max = 10000) : g(_g), max(_max) {}
std::string generate(uint64_t ind) {
uint64_t h = fnv_64(ind);
double U = (double) h / ULLONG_MAX;
double G = g->generate(U);
int keylen = MAX(round(G), floor(log10(max)) + 1);
char key[256];
snprintf(key, 256, "%0*" PRIu64, keylen, ind);
// D("%d = %s", ind, key);
return std::string(key);
}
private:
Generator* g;
double max;
};
Generator* createGenerator(std::string str);
Generator* createFacebookKey();
Generator* createFacebookValue();
Generator* createFacebookIA();
#endif // GENERATOR_H