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#ifndef _pyp_hh
#define _pyp_hh
#include <math.h>
#include <map>
#include <tr1/unordered_map>
#include "log_add.h"
#include "gammadist.h"
#include "slice-sampler.h"
#include "mt19937ar.h"
//
// Pitman-Yor process with customer and table tracking
//
template <typename Dish, typename Hash=std::tr1::hash<Dish> >
class PYP : protected std::tr1::unordered_map<Dish, int, Hash>
{
public:
using std::tr1::unordered_map<Dish,int>::const_iterator;
using std::tr1::unordered_map<Dish,int>::iterator;
using std::tr1::unordered_map<Dish,int>::begin;
using std::tr1::unordered_map<Dish,int>::end;
PYP(long double a, long double b, Hash hash=Hash());
int increment(Dish d, long double p0);
int decrement(Dish d);
// lookup functions
int count(Dish d) const;
long double prob(Dish dish, long double p0) const;
long double prob(Dish dish, long double dcd, long double dca,
long double dtd, long double dta, long double p0) const;
int num_customers() const { return _total_customers; }
int num_types() const { return std::tr1::unordered_map<Dish,int>::size(); }
bool empty() const { return _total_customers == 0; }
long double log_prob(Dish dish, long double log_p0) const;
// nb. d* are NOT logs
long double log_prob(Dish dish, long double dcd, long double dca,
long double dtd, long double dta, long double log_p0) const;
int num_tables(Dish dish) const;
int num_tables() const;
long double a() const { return _a; }
void set_a(long double a) { _a = a; }
long double b() const { return _b; }
void set_b(long double b) { _b = b; }
void clear();
std::ostream& debug_info(std::ostream& os) const;
long double log_restaurant_prob() const;
long double log_prior() const;
static long double log_prior_a(long double a, long double beta_a, long double beta_b);
static long double log_prior_b(long double b, long double gamma_c, long double gamma_s);
void resample_prior();
void resample_prior_a();
void resample_prior_b();
private:
long double _a, _b; // parameters of the Pitman-Yor distribution
long double _a_beta_a, _a_beta_b; // parameters of Beta prior on a
long double _b_gamma_s, _b_gamma_c; // parameters of Gamma prior on b
struct TableCounter
{
TableCounter() : tables(0) {};
int tables;
std::map<int, int> table_histogram; // num customers at table -> number tables
};
typedef std::tr1::unordered_map<Dish, TableCounter, Hash> DishTableType;
DishTableType _dish_tables;
int _total_customers, _total_tables;
// Function objects for calculating the parts of the log_prob for
// the parameters a and b
struct resample_a_type {
int n, m; long double b, a_beta_a, a_beta_b;
const DishTableType& dish_tables;
resample_a_type(int n, int m, long double b, long double a_beta_a,
long double a_beta_b, const DishTableType& dish_tables)
: n(n), m(m), b(b), a_beta_a(a_beta_a), a_beta_b(a_beta_b), dish_tables(dish_tables) {}
long double operator() (long double proposed_a) const {
long double log_prior = log_prior_a(proposed_a, a_beta_a, a_beta_b);
long double log_prob = 0.0;
long double lgamma1a = lgamma(1.0 - proposed_a);
for (typename DishTableType::const_iterator dish_it=dish_tables.begin(); dish_it != dish_tables.end(); ++dish_it)
for (std::map<int, int>::const_iterator table_it=dish_it->second.table_histogram.begin();
table_it !=dish_it->second.table_histogram.end(); ++table_it)
log_prob += (table_it->second * (lgamma(table_it->first - proposed_a) - lgamma1a));
log_prob += (proposed_a == 0.0 ? (m-1.0)*log(b)
: ((m-1.0)*log(proposed_a) + lgamma((m-1.0) + b/proposed_a) - lgamma(b/proposed_a)));
assert(std::isfinite(log_prob));
return log_prob + log_prior;
}
};
struct resample_b_type {
int n, m; long double a, b_gamma_c, b_gamma_s;
resample_b_type(int n, int m, long double a, long double b_gamma_c, long double b_gamma_s)
: n(n), m(m), a(a), b_gamma_c(b_gamma_c), b_gamma_s(b_gamma_s) {}
long double operator() (long double proposed_b) const {
long double log_prior = log_prior_b(proposed_b, b_gamma_c, b_gamma_s);
long double log_prob = 0.0;
log_prob += (a == 0.0 ? (m-1.0)*log(proposed_b)
: ((m-1.0)*log(a) + lgamma((m-1.0) + proposed_b/a) - lgamma(proposed_b/a)));
log_prob += (lgamma(1.0+proposed_b) - lgamma(n+proposed_b));
return log_prob + log_prior;
}
};
};
template <typename Dish, typename Hash>
PYP<Dish,Hash>::PYP(long double a, long double b, Hash cmp)
: std::tr1::unordered_map<Dish, int, Hash>(), _a(a), _b(b),
_a_beta_a(1), _a_beta_b(1), _b_gamma_s(1), _b_gamma_c(1),
//_a_beta_a(1), _a_beta_b(1), _b_gamma_s(10), _b_gamma_c(0.1),
_total_customers(0), _total_tables(0)
{
// std::cerr << "\t##PYP<Dish,Hash>::PYP(a=" << _a << ",b=" << _b << ")" << std::endl;
}
template <typename Dish, typename Hash>
long double
PYP<Dish,Hash>::prob(Dish dish, long double p0) const
{
int c = count(dish), t = num_tables(dish);
long double r = num_tables() * _a + _b;
//std::cerr << "\t\t\t\tPYP<Dish,Hash>::prob(" << dish << "," << p0 << ") c=" << c << " r=" << r << std::endl;
if (c > 0)
return (c - _a * t + r * p0) / (num_customers() + _b);
else
return r * p0 / (num_customers() + _b);
}
template <typename Dish, typename Hash>
long double
PYP<Dish,Hash>::prob(Dish dish, long double dcd, long double dca,
long double dtd, long double dta, long double p0)
const
{
int c = count(dish) + dcd, t = num_tables(dish) + dtd;
long double r = (num_tables() + dta) * _a + _b;
if (c > 0)
return (c - _a * t + r * p0) / (num_customers() + dca + _b);
else
return r * p0 / (num_customers() + dca + _b);
}
template <typename Dish, typename Hash>
long double
PYP<Dish,Hash>::log_prob(Dish dish, long double log_p0) const
{
using std::log;
int c = count(dish), t = num_tables(dish);
long double r = log(num_tables() * _a + b);
if (c > 0)
return Log<double>::add(log(c - _a * t), r + log_p0)
- log(num_customers() + _b);
else
return r + log_p0 - log(num_customers() + b);
}
template <typename Dish, typename Hash>
long double
PYP<Dish,Hash>::log_prob(Dish dish, long double dcd, long double dca,
long double dtd, long double dta, long double log_p0)
const
{
using std::log;
int c = count(dish) + dcd, t = num_tables(dish) + dtd;
long double r = log((num_tables() + dta) * _a + b);
if (c > 0)
return Log<double>::add(log(c - _a * t), r + log_p0)
- log(num_customers() + dca + _b);
else
return r + log_p0 - log(num_customers() + dca + b);
}
template <typename Dish, typename Hash>
int
PYP<Dish,Hash>::increment(Dish dish, long double p0) {
int delta = 0;
TableCounter &tc = _dish_tables[dish];
// seated on a new or existing table?
int c = count(dish), t = num_tables(dish), T = num_tables();
long double pshare = (c > 0) ? (c - _a*t) : 0.0;
long double pnew = (_b + _a*T) * p0;
assert (pshare >= 0.0);
//assert (pnew > 0.0);
if (mt_genrand_res53() < pnew / (pshare + pnew)) {
// assign to a new table
tc.tables += 1;
tc.table_histogram[1] += 1;
_total_tables += 1;
delta = 1;
}
else {
// randomly assign to an existing table
// remove constant denominator from inner loop
long double r = mt_genrand_res53() * (c - _a*t);
for (std::map<int,int>::iterator
hit = tc.table_histogram.begin();
hit != tc.table_histogram.end(); ++hit) {
r -= ((hit->first - _a) * hit->second);
if (r <= 0) {
tc.table_histogram[hit->first+1] += 1;
hit->second -= 1;
if (hit->second == 0)
tc.table_histogram.erase(hit);
break;
}
}
if (r > 0) {
std::cerr << r << " " << c << " " << _a << " " << t << std::endl;
assert(false);
}
delta = 0;
}
std::tr1::unordered_map<Dish,int,Hash>::operator[](dish) += 1;
_total_customers += 1;
return delta;
}
template <typename Dish, typename Hash>
int
PYP<Dish,Hash>::count(Dish dish) const
{
typename std::tr1::unordered_map<Dish, int>::const_iterator
dcit = find(dish);
if (dcit != end())
return dcit->second;
else
return 0;
}
template <typename Dish, typename Hash>
int
PYP<Dish,Hash>::decrement(Dish dish)
{
typename std::tr1::unordered_map<Dish, int>::iterator dcit = find(dish);
if (dcit == end()) {
std::cerr << dish << std::endl;
assert(false);
}
int delta = 0;
typename std::tr1::unordered_map<Dish, TableCounter>::iterator dtit = _dish_tables.find(dish);
if (dtit == _dish_tables.end()) {
std::cerr << dish << std::endl;
assert(false);
}
TableCounter &tc = dtit->second;
//std::cerr << "\tdecrement for " << dish << "\n";
//std::cerr << "\tBEFORE histogram: " << tc.table_histogram << " ";
//std::cerr << "count: " << count(dish) << " ";
//std::cerr << "tables: " << tc.tables << "\n";
long double r = mt_genrand_res53() * count(dish);
for (std::map<int,int>::iterator hit = tc.table_histogram.begin();
hit != tc.table_histogram.end(); ++hit)
{
//r -= (hit->first - _a) * hit->second;
r -= (hit->first) * hit->second;
if (r <= 0)
{
if (hit->first > 1)
tc.table_histogram[hit->first-1] += 1;
else
{
delta = -1;
tc.tables -= 1;
_total_tables -= 1;
}
hit->second -= 1;
if (hit->second == 0) tc.table_histogram.erase(hit);
break;
}
}
if (r > 0) {
std::cerr << r << " " << count(dish) << " " << _a << " " << num_tables(dish) << std::endl;
assert(false);
}
// remove the customer
dcit->second -= 1;
_total_customers -= 1;
assert(dcit->second >= 0);
if (dcit->second == 0) {
erase(dcit);
_dish_tables.erase(dtit);
//std::cerr << "\tAFTER histogram: Empty\n";
}
else {
//std::cerr << "\tAFTER histogram: " << _dish_tables[dish].table_histogram << " ";
//std::cerr << "count: " << count(dish) << " ";
//std::cerr << "tables: " << _dish_tables[dish].tables << "\n";
}
return delta;
}
template <typename Dish, typename Hash>
int
PYP<Dish,Hash>::num_tables(Dish dish) const
{
typename std::tr1::unordered_map<Dish, TableCounter, Hash>::const_iterator
dtit = _dish_tables.find(dish);
//assert(dtit != _dish_tables.end());
if (dtit == _dish_tables.end())
return 0;
return dtit->second.tables;
}
template <typename Dish, typename Hash>
int
PYP<Dish,Hash>::num_tables() const
{
return _total_tables;
}
template <typename Dish, typename Hash>
std::ostream&
PYP<Dish,Hash>::debug_info(std::ostream& os) const
{
int hists = 0, tables = 0;
for (typename std::tr1::unordered_map<Dish, TableCounter, Hash>::const_iterator
dtit = _dish_tables.begin(); dtit != _dish_tables.end(); ++dtit)
{
hists += dtit->second.table_histogram.size();
tables += dtit->second.tables;
assert(dtit->second.tables > 0);
assert(!dtit->second.table_histogram.empty());
for (std::map<int,int>::const_iterator
hit = dtit->second.table_histogram.begin();
hit != dtit->second.table_histogram.end(); ++hit)
assert(hit->second > 0);
}
os << "restaurant has "
<< _total_customers << " customers; "
<< _total_tables << " tables; "
<< tables << " tables'; "
<< num_types() << " dishes; "
<< _dish_tables.size() << " dishes'; and "
<< hists << " histogram entries\n";
return os;
}
template <typename Dish, typename Hash>
void
PYP<Dish,Hash>::clear()
{
this->std::tr1::unordered_map<Dish,int,Hash>::clear();
_dish_tables.clear();
_total_tables = _total_customers = 0;
}
// log_restaurant_prob returns the log probability of the PYP table configuration.
// Excludes Hierarchical P0 term which must be calculated separately.
template <typename Dish, typename Hash>
long double
PYP<Dish,Hash>::log_restaurant_prob() const {
if (_total_customers < 1)
return (long double)0.0;
long double log_prob = 0.0;
long double lgamma1a = lgamma(1.0-_a);
//std::cerr << "-------------------\n" << std::endl;
for (typename DishTableType::const_iterator dish_it=_dish_tables.begin();
dish_it != _dish_tables.end(); ++dish_it) {
for (std::map<int, int>::const_iterator table_it=dish_it->second.table_histogram.begin();
table_it !=dish_it->second.table_histogram.end(); ++table_it) {
log_prob += (table_it->second * (lgamma(table_it->first - _a) - lgamma1a));
//std::cerr << "|" << dish_it->first->parent << " --> " << dish_it->first->rhs << " " << table_it->first << " " << table_it->second << " " << log_prob;
}
}
//std::cerr << std::endl;
log_prob += (_a == (long double)0.0 ? (_total_tables-1.0)*log(_b) : (_total_tables-1.0)*log(_a) + lgamma((_total_tables-1.0) + _b/_a) - lgamma(_b/_a));
//std::cerr << "\t\t" << log_prob << std::endl;
log_prob += (lgamma(1.0 + _b) - lgamma(_total_customers + _b));
//std::cerr << _total_customers << " " << _total_tables << " " << log_prob << " " << log_prior() << std::endl;
//std::cerr << _a << " " << _b << std::endl;
if (!std::isfinite(log_prob)) {
assert(false);
}
//return log_prob;
return log_prob + log_prior();
}
template <typename Dish, typename Hash>
long double
PYP<Dish,Hash>::log_prior() const {
long double prior = 0.0;
if (_a_beta_a > 0.0 && _a_beta_b > 0.0 && _a > 0.0)
prior += log_prior_a(_a, _a_beta_a, _a_beta_b);
if (_b_gamma_s > 0.0 && _b_gamma_c > 0.0)
prior += log_prior_b(_b, _b_gamma_c, _b_gamma_s);
return prior;
}
template <typename Dish, typename Hash>
long double
PYP<Dish,Hash>::log_prior_a(long double a, long double beta_a, long double beta_b) {
return lbetadist(a, beta_a, beta_b);
}
template <typename Dish, typename Hash>
long double
PYP<Dish,Hash>::log_prior_b(long double b, long double gamma_c, long double gamma_s) {
return lgammadist(b, gamma_c, gamma_s);
}
template <typename Dish, typename Hash>
void
PYP<Dish,Hash>::resample_prior() {
for (int num_its=5; num_its >= 0; --num_its) {
resample_prior_b();
resample_prior_a();
}
resample_prior_b();
}
template <typename Dish, typename Hash>
void
PYP<Dish,Hash>::resample_prior_b() {
if (_total_tables == 0)
return;
int niterations = 10; // number of resampling iterations
//std::cerr << "\n## resample_prior_b(), initial a = " << _a << ", b = " << _b << std::endl;
resample_b_type b_log_prob(_total_customers, _total_tables, _a, _b_gamma_c, _b_gamma_s);
_b = slice_sampler1d(b_log_prob, _b, mt_genrand_res53, (long double) 0.0, std::numeric_limits<long double>::infinity(),
(long double) 0.0, niterations, 100*niterations);
//std::cerr << "\n## resample_prior_b(), final a = " << _a << ", b = " << _b << std::endl;
}
template <typename Dish, typename Hash>
void
PYP<Dish,Hash>::resample_prior_a() {
if (_total_tables == 0)
return;
int niterations = 10;
//std::cerr << "\n## Initial a = " << _a << ", b = " << _b << std::endl;
resample_a_type a_log_prob(_total_customers, _total_tables, _b, _a_beta_a, _a_beta_b, _dish_tables);
_a = slice_sampler1d(a_log_prob, _a, mt_genrand_res53, std::numeric_limits<long double>::min(),
(long double) 1.0, (long double) 0.0, niterations, 100*niterations);
}
#endif
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