Datasets:

benzlxs
/

temp_backup

	/** @internal
	** @file aib.c
	** @author Brian Fulkerson
	** @author Andrea Vedaldi
	** @brief Agglomerative Information Bottleneck (AIB) - Definition
	**/

	/* AUTORIGHTS
	Copyright (C) 2007-09 Andrea Vedaldi and Brian Fulkerson

	This file is part of VLFeat, available in the terms of the GNU
	General Public License version 2.
	*/

	/** @file aib.h
	** @brief Agglomerative Information Bottleneck (AIB)

	This provides an implementation of Agglomerative Information
	Bottleneck (AIB) as first described in:

	[Slonim] <em>N. Slonim and N. Tishby. Agglomerative information
	bottleneck. In Proc. NIPS, 1999</em>

	AIB takes a discrete valued feature \f$x\f$ and a label \f$c\f$ and
	gradually compresses \f$x\f$ by iteratively merging values which
	minimize the loss in mutual information \f$I(x,c)\f$.

	While the algorithm is equivalent to the one described in [Slonim],
	it has some speedups that enable handling much larger datasets. Let
	<em>N</em> be the number of feature values and <em>C</em> the number
	of labels. The algorithm of [Slonim] is \f$O(N^2)\f$ in space and \f$O(C
	N^3)\f$ in time. This algorithm is \f$O(N)\f$ space and \f$O(C N^2)\f$
	time in common cases (\f$O(C N^3)\f$ in the worst case).

	@section aib-overview Overview

	Given a discrete feature @f$x \in \mathcal{X} = \{x_1,\dots,x_N\}@f$
	and a category label @f$c = 1,\dots,C@f$ with joint probability
	@f$p(x,c)@f$, AIB computes a compressed feature @f$[x]_{ij}@f$ by
	merging two values @f$x_i@f$ and @f$x_j@f$. Among all the pairs
	@f$ij@f$, AIB chooses the one that yields the smallest loss in the
	mutual information

	@f[
	D_{ij} = I(x,c) - I([x]_{ij},c) =
	\sum_c p(x_i) \log \frac{p(x_i,c)}{p(x_i)p(c)} +
	\sum_c p(x_i) \log \frac{p(x_i,c)}{p(x_i)p(c)} -
	\sum_c (p(x_i)+p(x_j)) \log \frac {p(x_i,c)+p(x_i,c)}{(p(x_i)+p(x_j))p(c)}
	@f]

	AIB iterates this procedure until the desired level of
	compression is achieved.

	@section aib-algorithm Algorithm details

	Computing \f$D_{ij}\f$ requires \f$O(C)\f$ operations. For example,
	in standard AIB we need to calculate
	@f[
	D_{ij} = I(x,c) - I([x]_{ij},c) =
	\sum_c p(x_i) \log \frac{p(x_i,c)}{p(x_i)p(c)} +
	\sum_c p(x_i) \log \frac{p(x_i,c)}{p(x_i)p(c)} -
	\sum_c (p(x_i)+p(x_j)) \log \frac {p(x_i,c)+p(x_i,c)}{(p(x_i)+p(x_j))p(c)}
	@f]

	Thus in a basic implementation of AIB, finding the optimal pair
	\f$ij\f$ of feature values requires \f$O(CN^2)\f$ operations in
	total. In order to join all the \f$N\f$ values, we repeat this
	procedure \f$O(N)\f$ times, yielding \f$O(N^3 C)\f$ time and
	\f$O(1)\f$ space complexity (this does not account for the space need
	to store the input).

	The complexity can be improved by reusing computations. For instance,
	we can store the matrix \f$D = [ D_{ij} ]\f$ (which requires
	\f$O(N^2)\f$ space). Then, after joining \f$ij\f$, all of the matrix
	<em>D</em> except the rows and columns (the matrix is symmetric) of
	indexes <em>i</em> and <em>j</em> is unchanged. These two rows and
	columns are deleted and a new row and column, whose computation
	requires \f$O(NC)\f$ operations, are added for the merged value
	\f$x_{ij}\f$. Finding the minimal element of the matrix still requires
	\f$O(N^2)\f$ operations, so the complexity of this algorithm is
	\f$O(N^2C + N^3)\f$ time and \f$O(N^2)\f$ space.

	We can obtain a much better expected complexity as follows. First,
	instead of storing the whole matrix <em>D</em>, we store the smallest
	element (index and value) of each row as \f$(q_i, D_i)\f$ (notice
	that this is also the best element of each column since <em>D</em>
	is symmetric). This requires \f$O(N)\f$ space and finding the
	minimal element of the matrix requires \f$O(N)\f$ operations.
	After joining \f$ij\f$, we have to efficiently update this
	representation. This is done as follows:

	- The entries \f$(q_i,D_i)\f$ and \f$(q_j,D_j)\f$ are deleted.
	- A new entry \f$(q_{ij},D_{ij})\f$ for the joint value \f$x_{ij}\f$
	is added. This requires \f$O(CN)\f$ operations.
	- We test which other entries \f$(q_{k},D_{k})\f$ need to
	be updated. Recall that \f$(q_{k},D_{k})\f$ means that, before the
	merge, the value
	closest to \f$x_k\f$ was \f$x_{q_k}\f$ at a distance \f$D_k\f$. Then
	- If \f$q_k \not = i\f$, \f$q_k \not = j\f$ and \f$D_{k,ij} \geq D_k\f$, then
	\f$q_k\f$ is still the closest element and we do not do anything.
	- If \f$q_k \not = i\f$, \f$q_k \not = j\f$ and \f$D_{k,ij} <
	D_k\f$, then the closest element is \f$ij\f$ and we update the
	entry in constant time.
	- If \f$q_k = i\f$ or \f$q_k = j\f$, then we need to re-compute
	the closest element in \f$O(CN)\f$ operations.

	This algorithm requires only \f$O(N)\f$ space and \f$O(\gamma(N) C
	N^2)\f$ time, where \f$\gamma(N)\f$ is the expected number of times
	we fall in the last case. In common cases one has \f$\gamma(N)
	\approx \mathrm{const.}\f$, so the time saving is significant.

	**/

	#include "aib.h"

	#include <stdio.h>
	#include <stdlib.h>
	#include <float.h> /* DBL_MAX */
	#include <math.h>

	/** @internal @brief The maximum value which beta may take */
	#define BETA_MAX DBL_MAX

	/** ------------------------------------------------------------------
	** @internal
	** @brief Normalizes an array of probabilities to sum to 1
	**
	** @param P The array of probabilities
	** @param nelem The number of elements in the array
	**
	** @return Modifies P to contain values which sum to 1
	**/

	void vl_aib_normalize_P (double * P, vl_uint nelem)
	{
	vl_uint i;
	double sum = 0;
	for(i=0; i<nelem; i++)
	sum += P[i];
	for(i=0; i<nelem; i++)
	P[i] /= sum;
	}

	/** ------------------------------------------------------------------
	** @internal
	** @brief Allocates and creates a list of nodes
	**
	** @param nentries The size of the list which will be created
	**
	** @return an array containing elements 0...nentries
	**/

	vl_uint *vl_aib_new_nodelist (vl_uint nentries)
	{
	vl_uint * nodelist = vl_malloc(sizeof(vl_uint)*nentries);
	vl_uint n;
	for(n=0; n<nentries; n++)
	nodelist[n] = n;

	return nodelist;
	}

	/** ------------------------------------------------------------------
	** @internal
	** @brief Allocates and creates the marginal distribution Px
	**
	** @param Pcx A two-dimensional array of probabilities
	** @param nvalues The number of rows in Pcx
	** @param nlabels The number of columns in Pcx
	**
	** @return an array of size @a nvalues which contains the marginal
	** distribution over the rows.
	**/

	double * vl_aib_new_Px(double * Pcx, vl_uint nvalues, vl_uint nlabels)
	{
	double * Px = vl_malloc(sizeof(double)*nvalues);
	vl_uint r,c;
	for(r=0; r<nvalues; r++)
	{
	double sum = 0;
	for(c=0; c<nlabels; c++)
	sum += Pcx[r*nlabels+c];
	Px[r] = sum;
	}
	return Px;
	}

	/** ------------------------------------------------------------------
	** @internal @brief Allocates and creates the marginal distribution Pc
	**
	** @param Pcx A two-dimensional array of probabilities
	** @param nvalues The number of rows in Pcx
	** @param nlabels The number of columns in Pcx
	**
	** @return an array of size @a nlabels which contains the marginal distribution
	** over the columns
	**/

	double * vl_aib_new_Pc(double * Pcx, vl_uint nvalues, vl_uint nlabels)
	{
	double * Pc = vl_malloc(sizeof(double)*nlabels);
	vl_uint r, c;
	for(c=0; c<nlabels; c++)
	{
	double sum = 0;
	for(r=0; r<nvalues; r++)
	sum += Pcx[r*nlabels+c];
	Pc[c] = sum;
	}
	return Pc;
	}

	/** ------------------------------------------------------------------
	** @internal @brief Find the two nodes which have minimum beta.
	**
	** @param aib A pointer to the internal data structure
	** @param besti The index of one member of the pair which has mininum beta
	** @param bestj The index of the other member of the pair which
	** minimizes beta
	** @param minbeta The minimum beta value corresponding to (@a i, @a j)
	**
	** Searches @a aib->beta to find the minimum value and fills @a minbeta and
	** @a besti and @a bestj with this information.
	**/

	void vl_aib_min_beta
	(VlAIB * aib, vl_uint * besti, vl_uint * bestj, double * minbeta)
	{
	vl_uint i;
	*minbeta = aib->beta[0];
	*besti = 0;
	*bestj = aib->bidx[0];

	for(i=0; i<aib->nentries; i++)
	{
	if(aib->beta[i] < *minbeta)
	{
	*minbeta = aib->beta[i];
	*besti = i;
	*bestj = aib->bidx[i];
	}
	}
	}

	/** ------------------------------------------------------------------
	** @internal
	** @brief Merges two nodes i,j in the internal datastructure
	**
	** @param aib A pointer to the internal data structure
	** @param i The index of one member of the pair to merge
	** @param j The index of the other member of the pair to merge
	** @param new The index of the new node which corresponds to the union of
	** (@a i, @a j).
	**
	** Nodes are merged by replacing the entry @a i with the union of @c
	** ij, moving the node stored in last position (called @c lastnode)
	** back to jth position and the entry at the end.
	**
	** After the nodes have been merged, it updates which nodes should be
	** considered on the next iteration based on which beta values could
	** potentially change. The merged node will always be part of this
	** list.
	**/

	void
	vl_aib_merge_nodes (VlAIB * aib, vl_uint i, vl_uint j, vl_uint new)
	{
	vl_uint last_entry = aib->nentries - 1 ;
	vl_uint c, n ;

	/* clear the list of nodes to update */
	aib->nwhich = 0;

	/* make sure that i is smaller than j */
	if(i > j) { vl_uint tmp = j; j = i; i = tmp; }

	/* -----------------------------------------------------------------
	* Merge entries i and j, storing the result in i
	* -------------------------------------------------------------- */

	aib-> Px [i] += aib->Px[j] ;
	aib-> beta [i] = BETA_MAX ;
	aib-> nodes[i] = new ;

	for (c = 0; c < aib->nlabels; c++)
	aib-> Pcx [iaib->nlabels + c] += aib-> Pcx [jaib->nlabels + c] ;

	/* -----------------------------------------------------------------
	* Move last entry to j
	* -------------------------------------------------------------- */

	aib-> Px [j] = aib-> Px [last_entry];
	aib-> beta [j] = aib-> beta [last_entry];
	aib-> bidx [j] = aib-> bidx [last_entry];
	aib-> nodes [j] = aib-> nodes [last_entry];

	for (c = 0 ; c < aib->nlabels ; c++)
	aib-> Pcx[jaib->nlabels + c] = aib-> Pcx [last_entryaib->nlabels + c] ;

	/* delete last entry */
	aib-> nentries -- ;

	/* -----------------------------------------------------------------
	* Scan for entries to update
	* -------------------------------------------------------------- */

	/*
	* After mergin entries i and j, we need to update all other entries
	* that had one of these two as closest match. We also need to
	* update the renewend entry i. This is added by the loop below
	* since bidx [i] = j exactly because i was merged.
	*
	* Additionaly, since we moved the last entry back to the entry j,
	* we need to adjust the valeus of bidx to reflect this.
	*/

	for (n = 0 ; n < aib->nentries; n++) {
	if(aib->bidx[n] == i \|\| aib->bidx[n] == j) {
	aib->bidx [n] = 0;
	aib->beta [n] = BETA_MAX;
	aib->which [aib->nwhich++] = n ;
	}
	else if(aib->bidx[n] == last_entry) {
	aib->bidx[n] = j ;
	}
	}
	}

	/** ------------------------------------------------------------------
	** @internal
	** @brief Updates @c aib->beta and @c aib->bidx according to @c aib->which
	**
	** @param aib AIB data structure.
	**
	** The function calculates @c beta[i] and @c bidx[i] for the nodes @c
	** i listed in @c aib->which. @c beta[i] is the minimal variation of mutual
	** information (or other score) caused by merging entry @c i with another entry
	** and @c bidx[i] is the index of this best matching entry.
	**
	** Notice that for each entry @c i that we need to update, a full
	** scan of all the other entries must be performed.
	**/

	void
	vl_aib_update_beta (VlAIB * aib)
	{

	#define PLOGP(x) ((x)*log((x)))

	vl_uint i;
	double * Px = aib->Px;
	double * Pcx = aib->Pcx;
	double * tmp = vl_malloc(sizeof(double)*aib->nentries);
	vl_uint a, b, c ;

	/*
	* T1 = I(x,c) - I([x]_ij) = A + B - C
	*
	* A = \sum_c p(xa,c) \log ( p(xa,c) / p(xa) )
	* B = \sum_c p(xb,c) \log ( p(xb,c) / p(xb) )
	* C = \sum_c (p(xa,c)+p(xb,c)) \log ((p(xa,c)+p(xb,c)) / (p(xa)+p(xb)))
	*
	* C = C1 + C2
	* C1 = \sum_c (p(xa,c)+p(xb,c)) \log (p(xa,c)+p(xb,c))
	* C2 = - (p(xa)+p(xb) \log (p(xa)+p(xb))
	*/

	/* precalculate A and B */
	for (a = 0; a < aib->nentries; a++) {
	tmp[a] = 0;
	for (c = 0; c < aib->nlabels; c++) {
	double Pac = Pcx [a*aib->nlabels + c] ;
	if(Pac != 0) tmp[a] += Pac * log (Pac / Px[a]) ;
	}
	}

	/* for each entry listed in which */
	for (i = 0 ; i < aib->nwhich; i++) {
	a = aib->which[i];

	/* for each other entry */
	for(b = 0 ; b < aib->nentries ; b++) {
	double T1 = 0 ;

	if (a == b \|\| Px [a] == 0 \|\| Px [b] == 0) continue ;


	T1 = PLOGP ((Px[a] + Px[b])) ; /* - C2 */
	T1 += tmp[a] + tmp[b] ; /* + A + B */

	for (c = 0 ; c < aib->nlabels; ++ c) {
	double Pac = Pcx [a*aib->nlabels + c] ;
	double Pbc = Pcx [b*aib->nlabels + c] ;
	if (Pac == 0 && Pbc == 0) continue;
	T1 += - PLOGP ((Pac + Pbc)) ; /* - C1 */
	}

	/*
	* Now we have beta(a,b). We check wether this is the best beta
	* for entries a and b.
	*/
	{
	double beta = T1 ;

	if (beta < aib->beta[a])
	{
	aib->beta[a] = beta;
	aib->bidx[a] = b;
	}
	if (beta < aib->beta[b])
	{
	aib->beta[b] = beta;
	aib->bidx[b] = a;
	}
	}
	}
	}
	vl_free(tmp);
	}

	/** ------------------------------------------------------------------
	** @internal @brief Calculates the current information and entropy
	**
	** @param aib A pointer to the internal data structure
	** @param I The current mutual information (out).
	** @param H The current entropy (out).
	**
	** Calculates the current mutual information and entropy of Pcx and sets
	** @a I and @a H to these new values.
	**/
	void vl_aib_calculate_information(VlAIB * aib, double * I, double * H)
	{
	vl_uint r, c;
	*H = 0;
	*I = 0;

	/*
	* H(x) = - sum_x p(x) \ log p(x)
	* I(x,c) = sum_xc p(x,c) \ log (p(x,c) / p(x)p(c))
	*/

	/* for each entry */
	for(r = 0 ; r< aib->nentries ; r++) {

	if (aib->Px[r] == 0) continue ;
	H += -log(aib->Px[r]) aib->Px[r] ;

	for(c=0; c<aib->nlabels; c++) {
	if (aib->Pcx[r*aib->nlabels+c] == 0) continue;
	I += aib->Pcx[raib->nlabels+c] *
	log (aib->Pcx[raib->nlabels+c] / (aib->Px[r]aib->Pc[c])) ;
	}
	}
	}

	/** ------------------------------------------------------------------
	** @brief Allocates and initializes the internal data structure
	**
	** @param Pcx A pointer to a 2D array of probabilities
	** @param nvalues The number of rows in the array
	** @param nlabels The number of columns in the array
	**
	** Creates a new @a VlAIB struct containing pointers to all the data that
	** will be used during the AIB process.
	**
	** Allocates memory for the following:
	** - Px (nvalues*sizeof(double))
	** - Pc (nlabels*sizeof(double))
	** - nodelist (nvalues*sizeof(vl_uint))
	** - which (nvalues*sizeof(vl_uint))
	** - beta (nvalues*sizeof(double))
	** - bidx (nvalues*sizeof(vl_uint))
	** - parents ((2nvalues-1)sizeof(vl_uint))
	** - costs (nvalues*sizeof(double))
	**
	** Since it simply copies to pointer to Pcx, the total additional memory
	** requirement is:
	**
	** (3nvalues+nlabels)sizeof(double) + 4nvaluessizeof(vl_uint)
	**
	** @returns An allocated and initialized @a VlAIB pointer
	**/
	VlAIB * vl_aib_new(double * Pcx, vl_uint nvalues, vl_uint nlabels)
	{
	VlAIB * aib = vl_malloc(sizeof(VlAIB));
	vl_uint i ;

	aib->Pcx = Pcx ;
	aib->nvalues = nvalues ;
	aib->nlabels = nlabels ;

	vl_aib_normalize_P (aib->Pcx, aib->nvalues * aib->nlabels) ;

	aib->Px = vl_aib_new_Px (aib->Pcx, aib->nvalues, aib->nlabels) ;
	aib->Pc = vl_aib_new_Pc (aib->Pcx, aib->nvalues, aib->nlabels) ;

	aib->nentries = aib->nvalues ;
	aib->nodes = vl_aib_new_nodelist(aib->nentries) ;
	aib->beta = vl_malloc(sizeof(double) * aib->nentries) ;
	aib->bidx = vl_malloc(sizeof(vl_uint) * aib->nentries) ;

	for(i = 0 ; i < aib->nentries ; i++)
	aib->beta [i] = BETA_MAX ;

	/* Initially we must consider all nodes */
	aib->nwhich = aib->nvalues;
	aib->which = vl_aib_new_nodelist (aib->nwhich) ;

	aib->parents = vl_malloc(sizeof(vl_uint)(aib->nvalues2-1));
	/* Initially, all parents point to a nonexistent node */
	for (i = 0 ; i < 2 * aib->nvalues - 1 ; i++)
	aib->parents [i] = 2 * aib->nvalues ;

	/* Allocate cost output vector */
	aib->costs = vl_malloc (sizeof(double) * (aib->nvalues - 1 + 1)) ;


	return aib ;
	}

	/** ------------------------------------------------------------------
	** @brief Deletes AIB data structure
	** @param aib data structure to delete.
	**/

	void
	vl_aib_delete (VlAIB * aib)
	{
	if (aib) {
	if (aib-> nodes) vl_free (aib-> nodes);
	if (aib-> beta) vl_free (aib-> beta);
	if (aib-> bidx) vl_free (aib-> bidx);
	if (aib-> which) vl_free (aib-> which);
	if (aib-> Px) vl_free (aib-> Px);
	if (aib-> Pc) vl_free (aib-> Pc);
	if (aib-> parents) vl_free (aib-> parents);
	if (aib-> costs) vl_free (aib-> costs);

	vl_free (aib) ;
	}
	}

	/** ------------------------------------------------------------------
	** @brief Runs AIB on Pcx
	**
	** @param aib AIB object to process
	**
	** The function runs Agglomerative Information Bottleneck (AIB) on
	** the joint probability table @a aib->Pcx which has labels along the
	** columns and feature values along the rows. AIB iteratively merges
	** the two values of the feature @c x that causes the smallest
	** decrease in mutual information between the random variables @c x
	** and @c c.
	**
	** Merge operations are arranged in a binary tree. The nodes of the
	** tree correspond to the original feature values and any other value
	** obtained as a result of a merge operation. The nodes are indexed
	** in breadth-first order, starting from the leaves. The first index
	** is zero. In this way, the leaves correspond directly to the
	** original feature values. In total there are @c 2*nvalues-1 nodes.
	**
	** The results may be accessed through vl_aib_get_parents which
	** returns an array with one element per tree node. Each
	** element is the index the parent node. The root parent is equal to
	** zero. The array has @c 2*nvalues-1 elements.
	**
	** Feature values with null probability are ignored by the algorithm
	** and their nodes have parents indexing a non-existent tree node (a
	** value bigger than @c 2*nvalues-1).
	**
	** Then the function will also compute the information level after each
	** merge. vl_get_costs will return a vector with the information level
	** after each merge. @a
	** cost has @c nvalues entries: The first is the value of the cost
	** functional before any merge, and the others are the cost after the
	** @c nvalues-1 merges.
	**
	**/

	VL_EXPORT
	void vl_aib_process(VlAIB *aib)
	{
	vl_uint i, besti, bestj, newnode, nodei, nodej;
	double I, H;
	double minbeta;

	/* Calculate initial value of cost function */
	vl_aib_calculate_information (aib, &I, &H) ;
	aib->costs[0] = I;

	/* Initially which = all */

	/* For each merge */
	for(i = 0 ; i < aib->nvalues - 1 ; i++) {

	/* update entries in aib-> which */
	vl_aib_update_beta(aib);

	/* find best pair of nodes to merge */
	vl_aib_min_beta (aib, &besti, &bestj, &minbeta);

	if(minbeta == BETA_MAX)
	/* only null-probability entries remain */
	break;

	/* Add the parent pointers for the new node */
	newnode = aib->nvalues + i ;
	nodei = aib->nodes[besti];
	nodej = aib->nodes[bestj];

	aib->parents [nodei] = newnode ;
	aib->parents [nodej] = newnode ;
	aib->parents [newnode] = 0 ;

	/* Merge the nodes which produced the minimum beta */
	vl_aib_merge_nodes (aib, besti, bestj, newnode) ;
	vl_aib_calculate_information (aib, &I, &H) ;

	aib->costs[i+1] = I;

	VL_PRINTF ("aib: (%5d,%5d)=%5d dE: %10.3g I: %6.4g H: %6.4g updt: %5d\n",
	nodei,
	nodej,
	newnode,
	minbeta,
	I,
	H,
	aib->nwhich) ;
	}

	/* fill ignored entries with NaNs */
	for(; i < aib->nvalues - 1 ; i++)
	aib->costs[i+1] = VL_NAN_D ;
	}