[valse.git] / src / sources / constructionModelesLassoMLE.c

#include "EMGLLF.h"
#include "utils.h"
#include <stdlib.h>
#include <gsl/gsl_linalg.h>
#include <omp.h>

// TODO: comment on constructionModelesLassoMLE purpose
void constructionModelesLassoMLE_core(
	// IN parameters
	const Real* phiInit, // parametre initial de moyenne renormalisé
	const Real* rhoInit, // parametre initial de variance renormalisé
	const Real* piInit,// parametre initial des proportions
	const Real* gamInit, // paramètre initial des probabilités a posteriori de chaque échantillon
	int mini,// nombre minimal d'itérations dans l'algorithme EM
	int maxi,// nombre maximal d'itérations dans l'algorithme EM
	Real gamma,// valeur de gamma : puissance des proportions dans la pénalisation pour un Lasso adaptatif
	const Real* glambda, // valeur des paramètres de régularisation du Lasso
	const Real* X, // régresseurs
	const Real* Y, // réponse
	Real seuil,// seuil pour prendre en compte une variable
	Real tau,// seuil pour accepter la convergence
	const int* A1, // matrice des coefficients des parametres selectionnes
	const int* A2, // matrice des coefficients des parametres non selectionnes
	// OUT parameters
	Real* phi,// estimateur ainsi calculé par le Lasso
	Real* rho,// estimateur ainsi calculé par le Lasso
	Real* pi, // estimateur ainsi calculé par le Lasso
	Real* llh, // estimateur ainsi calculé par le Lasso
	// additional size parameters
	int n, // taille de l'echantillon
	int p, // nombre de covariables
	int m, // taille de Y (multivarié)
	int k, // nombre de composantes
	int L) // taille de glambda
{
	//preparation: phi = 0
	for (int u=0; u<p*m*k*L; u++)
		phi[u] = 0.0;

	//initiate parallel section
	int lambdaIndex;
	omp_set_num_threads(OMP_NUM_THREADS);
	#pragma omp parallel default(shared) private(lambdaIndex)
	{
	#pragma omp for schedule(dynamic,CHUNK_SIZE) nowait
	for (lambdaIndex=0; lambdaIndex<L; lambdaIndex++)
	{
		//~ a = A1(:,1,lambdaIndex);
		//~ a(a==0) = [];
		int* a = (int*)malloc(p*sizeof(int));
		int lengthA = 0;
		for (int j=0; j<p; j++)
		{
			if (A1[ai(j,0,lambdaIndex,p,m+1,L)] != 0)
				a[lengthA++] = A1[ai(j,0,lambdaIndex,p,m+1,L)] - 1;
		}
		if (lengthA == 0)
			continue;

		//Xa = X(:,a)
		Real* Xa = (Real*)malloc(n*lengthA*sizeof(Real));
		for (int i=0; i<n; i++)
		{
			for (int j=0; j<lengthA; j++)
				Xa[mi(i,j,n,lengthA)] = X[mi(i,a[j],n,p)];
		}

		//phia = phiInit(a,:,:)
		Real* phia = (Real*)malloc(lengthA*m*k*sizeof(Real));
		for (int j=0; j<lengthA; j++)
		{
			for (int mm=0; mm<m; mm++)
			{
				for (int r=0; r<k; r++)
					phia[ai(j,mm,r,lengthA,m,k)] = phiInit[ai(a[j],mm,r,p,m,k)];
			}
		}

		//[phiLambda,rhoLambda,piLambda,~,~] = EMGLLF(...
		//	phiInit(a,:,:),rhoInit,piInit,gamInit,mini,maxi,gamma,0,X(:,a),Y,tau);
		Real* phiLambda = (Real*)malloc(lengthA*m*k*sizeof(Real));
		Real* rhoLambda = (Real*)malloc(m*m*k*sizeof(Real));
		Real* piLambda = (Real*)malloc(k*sizeof(Real));
		Real* LLF = (Real*)malloc((maxi+1)*sizeof(Real));
		Real* S = (Real*)malloc(lengthA*m*k*sizeof(Real));
		EMGLLF_core(phia,rhoInit,piInit,gamInit,mini,maxi,gamma,0.0,Xa,Y,tau,
			phiLambda,rhoLambda,piLambda,LLF,S,
			n,lengthA,m,k);
		free(Xa);
		free(phia);
		free(LLF);
		free(S);

		//~ for j=1:length(a)
			//~ phi(a(j),:,:,lambdaIndex) = phiLambda(j,:,:);
		//~ end
		for (int j=0; j<lengthA; j++)
		{
			for (int mm=0; mm<m; mm++)
			{
				for (int r=0; r<k; r++)
					phi[ai4(a[j],mm,r,lambdaIndex,p,m,k,L)] = phiLambda[ai(j,mm,r,p,m,k)];
			}
		}
		free(phiLambda);
		//~ rho(:,:,:,lambdaIndex) = rhoLambda;
		for (int u=0; u<m; u++)
		{
			for (int v=0; v<m; v++)
			{
				for (int r=0; r<k; r++)
					rho[ai4(u,v,r,lambdaIndex,m,m,k,L)] = rhoLambda[ai(u,v,r,m,m,k)];
			}
		}
		free(rhoLambda);
		//~ pi(:,lambdaIndex) = piLambda;
		for (int r=0; r<k; r++)
			pi[mi(r,lambdaIndex,k,L)] = piLambda[r];
		free(piLambda);

		int dimension = 0;
		int* b = (int*)malloc(m*sizeof(int));
		for (int j=0; j<p; j++)
		{
			//~ b = A2(j,2:end,lambdaIndex);
			//~ b(b==0) = [];
			int lengthB = 0;
			for (int mm=0; mm<m; mm++)
			{
				if (A2[ai(j,mm+1,lambdaIndex,p,m+1,L)] != 0)
					b[lengthB++] = A2[ai(j,mm+1,lambdaIndex,p,m+1,L)] - 1;
			}
			//~ if length(b) > 0
				//~ phi(A2(j,1,lambdaIndex),b,:,lambdaIndex) = 0.0;
			//~ end
			if (lengthB > 0)
			{
				for (int mm=0; mm<lengthB; mm++)
				{
					for (int r=0; r<k; r++)
						phi[ai4( A2[ai(j,0,lambdaIndex,p,m+1,L)]-1, b[mm], r, lambdaIndex, p, m, k, L)] = 0.;
				}
			}

			//~ c = A1(j,2:end,lambdaIndex);
			//~ c(c==0) = [];
			//~ dimension = dimension + length(c);
			for (int mm=0; mm<m; mm++)
			{
				if (A1[ai(j,mm+1,lambdaIndex,p,m+1,L)] != 0)
					dimension++;
			}
		}
		free(b);

		int signum;
		Real* densite = (Real*)calloc(L*n,sizeof(Real));
		Real sumLogDensit = 0.0;
		gsl_matrix* matrix = gsl_matrix_alloc(m, m);
		gsl_permutation* permutation = gsl_permutation_alloc(m);
		Real* YiRhoR = (Real*)malloc(m*sizeof(Real));
		Real* XiPhiR = (Real*)malloc(m*sizeof(Real));
		for (int i=0; i<n; i++)
		{
			//~ for r=1:k
				//~ delta = Y(i,:)*rho(:,:,r,lambdaIndex) - (X(i,a)*(phi(a,:,r,lambdaIndex)));
				//~ densite(i,lambdaIndex) = densite(i,lambdaIndex) +...
					//~ pi(r,lambdaIndex)*det(rho(:,:,r,lambdaIndex))/(sqrt(2*PI))^m*exp(-dot(delta,delta)/2.0);
			//~ end
			for (int r=0; r<k; r++)
			{
				//compute det(rho(:,:,r,lambdaIndex)) [TODO: avoid re-computations]
				for (int u=0; u<m; u++)
				{
					for (int v=0; v<m; v++)
						matrix->data[u*m+v] = rho[ai4(u,v,r,lambdaIndex,m,m,k,L)];
				}
				gsl_linalg_LU_decomp(matrix, permutation, &signum);
				Real detRhoR = gsl_linalg_LU_det(matrix, signum);

				//compute Y(i,:)*rho(:,:,r,lambdaIndex)
				for (int u=0; u<m; u++)
				{
					YiRhoR[u] = 0.0;
					for (int v=0; v<m; v++)
						YiRhoR[u] += Y[mi(i,v,n,m)] * rho[ai4(v,u,r,lambdaIndex,m,m,k,L)];
				}

				//compute X(i,a)*phi(a,:,r,lambdaIndex)
				for (int u=0; u<m; u++)
				{
					XiPhiR[u] = 0.0;
					for (int v=0; v<lengthA; v++)
						XiPhiR[u] += X[mi(i,a[v],n,p)] * phi[ai4(a[v],u,r,lambdaIndex,p,m,k,L)];
				}
				// On peut remplacer X par Xa dans ce dernier calcul, mais je ne sais pas si c'est intéressant ...

				// compute dotProduct < delta . delta >
				Real dotProduct = 0.0;
				for (int u=0; u<m; u++)
					dotProduct += (YiRhoR[u]-XiPhiR[u]) * (YiRhoR[u]-XiPhiR[u]);

				densite[mi(lambdaIndex,i,L,n)] += (pi[mi(r,lambdaIndex,k,L)]*detRhoR/pow(sqrt(2.0*M_PI),m))*exp(-dotProduct/2.0);
			}
			sumLogDensit += log(densite[lambdaIndex*n+i]);
		}
		llh[mi(lambdaIndex,0,L,2)] = sumLogDensit;
		llh[mi(lambdaIndex,1,L,2)] = (dimension+m+1)*k-1;

		free(a);
		free(YiRhoR);
		free(XiPhiR);
		free(densite);
		gsl_matrix_free(matrix);
		gsl_permutation_free(permutation);
	}
	}
}
Commit	Line	Data
1d3c1faa	1	#include "EMGLLF.h"
8e92c49c BA	2	#include "utils.h"
8e92c49c BA	3	#include <stdlib.h>
1d3c1faa BA	4	#include <gsl/gsl_linalg.h>
1d3c1faa BA	5	#include <omp.h>
1d3c1faa BA	6
1d3c1faa BA	7	// TODO: comment on constructionModelesLassoMLE purpose
09ab3c16	8	void constructionModelesLassoMLE_core(
3ec579a0	9	// IN parameters
9ff729fb BA	10	const Real* phiInit, // parametre initial de moyenne renormalisé
	11	const Real* rhoInit, // parametre initial de variance renormalisé
	12	const Real* piInit,// parametre initial des proportions
	13	const Real* gamInit, // paramètre initial des probabilités a posteriori de chaque échantillon
3ec579a0 BA	14	int mini,// nombre minimal d'itérations dans l'algorithme EM
3ec579a0 BA	15	int maxi,// nombre maximal d'itérations dans l'algorithme EM
9ff729fb BA	16	Real gamma,// valeur de gamma : puissance des proportions dans la pénalisation pour un Lasso adaptatif
	17	const Real* glambda, // valeur des paramètres de régularisation du Lasso
	18	const Real* X, // régresseurs
	19	const Real* Y, // réponse
	20	Real seuil,// seuil pour prendre en compte une variable
	21	Real tau,// seuil pour accepter la convergence
3ec579a0 BA	22	const int* A1, // matrice des coefficients des parametres selectionnes
3ec579a0 BA	23	const int* A2, // matrice des coefficients des parametres non selectionnes
1d3c1faa	24	// OUT parameters
9ff729fb BA	25	Real* phi,// estimateur ainsi calculé par le Lasso
	26	Real* rho,// estimateur ainsi calculé par le Lasso
	27	Real* pi, // estimateur ainsi calculé par le Lasso
c3bc4705	28	Real* llh, // estimateur ainsi calculé par le Lasso
1d3c1faa	29	// additional size parameters
3ec579a0 BA	30	int n, // taille de l'echantillon
	31	int p, // nombre de covariables
	32	int m, // taille de Y (multivarié)
	33	int k, // nombre de composantes
	34	int L) // taille de glambda
1d3c1faa BA	35	{
1d3c1faa BA	36	//preparation: phi = 0
3ec579a0	37	for (int u=0; u<pmk*L; u++)
1d3c1faa	38	phi[u] = 0.0;
3ec579a0	39
1d3c1faa	40	//initiate parallel section
3ec579a0	41	int lambdaIndex;
1d3c1faa BA	42	omp_set_num_threads(OMP_NUM_THREADS);
	43	#pragma omp parallel default(shared) private(lambdaIndex)
	44	{
	45	#pragma omp for schedule(dynamic,CHUNK_SIZE) nowait
	46	for (lambdaIndex=0; lambdaIndex<L; lambdaIndex++)
	47	{
	48	//~ a = A1(:,1,lambdaIndex);
	49	//~ a(a==0) = [];
3ec579a0 BA	50	int* a = (int)malloc(psizeof(int));
	51	int lengthA = 0;
	52	for (int j=0; j<p; j++)
1d3c1faa	53	{
3ec579a0 BA	54	if (A1[ai(j,0,lambdaIndex,p,m+1,L)] != 0)
3ec579a0 BA	55	a[lengthA++] = A1[ai(j,0,lambdaIndex,p,m+1,L)] - 1;
1d3c1faa BA	56	}
	57	if (lengthA == 0)
	58	continue;
3ec579a0	59
1d3c1faa	60	//Xa = X(:,a)
9ff729fb	61	Real* Xa = (Real)malloc(nlengthA*sizeof(Real));
3ec579a0	62	for (int i=0; i<n; i++)
1d3c1faa	63	{
3ec579a0 BA	64	for (int j=0; j<lengthA; j++)
3ec579a0 BA	65	Xa[mi(i,j,n,lengthA)] = X[mi(i,a[j],n,p)];
1d3c1faa	66	}
3ec579a0	67
1d3c1faa	68	//phia = phiInit(a,:,:)
9ff729fb	69	Real* phia = (Real)malloc(lengthAmksizeof(Real));
3ec579a0	70	for (int j=0; j<lengthA; j++)
1d3c1faa	71	{
3ec579a0	72	for (int mm=0; mm<m; mm++)
1d3c1faa	73	{
3ec579a0 BA	74	for (int r=0; r<k; r++)
3ec579a0 BA	75	phia[ai(j,mm,r,lengthA,m,k)] = phiInit[ai(a[j],mm,r,p,m,k)];
1d3c1faa BA	76	}
1d3c1faa BA	77	}
3ec579a0	78
1d3c1faa BA	79	//[phiLambda,rhoLambda,piLambda,~,~] = EMGLLF(...
1d3c1faa BA	80	// phiInit(a,:,:),rhoInit,piInit,gamInit,mini,maxi,gamma,0,X(:,a),Y,tau);
9ff729fb BA	81	Real* phiLambda = (Real)malloc(lengthAmksizeof(Real));
	82	Real* rhoLambda = (Real)malloc(mmksizeof(Real));
	83	Real* piLambda = (Real)malloc(ksizeof(Real));
	84	Real* LLF = (Real)malloc((maxi+1)sizeof(Real));
	85	Real* S = (Real)malloc(lengthAmksizeof(Real));
09ab3c16	86	EMGLLF_core(phia,rhoInit,piInit,gamInit,mini,maxi,gamma,0.0,Xa,Y,tau,
1d3c1faa BA	87	phiLambda,rhoLambda,piLambda,LLF,S,
	88	n,lengthA,m,k);
	89	free(Xa);
	90	free(phia);
	91	free(LLF);
	92	free(S);
3ec579a0	93
1d3c1faa BA	94	//~ for j=1:length(a)
	95	//~ phi(a(j),:,:,lambdaIndex) = phiLambda(j,:,:);
	96	//~ end
3ec579a0	97	for (int j=0; j<lengthA; j++)
1d3c1faa	98	{
3ec579a0	99	for (int mm=0; mm<m; mm++)
1d3c1faa	100	{
3ec579a0 BA	101	for (int r=0; r<k; r++)
3ec579a0 BA	102	phi[ai4(a[j],mm,r,lambdaIndex,p,m,k,L)] = phiLambda[ai(j,mm,r,p,m,k)];
1d3c1faa BA	103	}
	104	}
	105	free(phiLambda);
	106	//~ rho(:,:,:,lambdaIndex) = rhoLambda;
3ec579a0	107	for (int u=0; u<m; u++)
1d3c1faa	108	{
3ec579a0	109	for (int v=0; v<m; v++)
1d3c1faa	110	{
3ec579a0 BA	111	for (int r=0; r<k; r++)
3ec579a0 BA	112	rho[ai4(u,v,r,lambdaIndex,m,m,k,L)] = rhoLambda[ai(u,v,r,m,m,k)];
1d3c1faa BA	113	}
	114	}
	115	free(rhoLambda);
	116	//~ pi(:,lambdaIndex) = piLambda;
3ec579a0 BA	117	for (int r=0; r<k; r++)
3ec579a0 BA	118	pi[mi(r,lambdaIndex,k,L)] = piLambda[r];
1d3c1faa	119	free(piLambda);
3ec579a0 BA	120
	121	int dimension = 0;
	122	int* b = (int)malloc(msizeof(int));
	123	for (int j=0; j<p; j++)
1d3c1faa BA	124	{
	125	//~ b = A2(j,2:end,lambdaIndex);
	126	//~ b(b==0) = [];
3ec579a0 BA	127	int lengthB = 0;
3ec579a0 BA	128	for (int mm=0; mm<m; mm++)
1d3c1faa	129	{
3ec579a0 BA	130	if (A2[ai(j,mm+1,lambdaIndex,p,m+1,L)] != 0)
3ec579a0 BA	131	b[lengthB++] = A2[ai(j,mm+1,lambdaIndex,p,m+1,L)] - 1;
1d3c1faa BA	132	}
	133	//~ if length(b) > 0
	134	//~ phi(A2(j,1,lambdaIndex),b,:,lambdaIndex) = 0.0;
	135	//~ end
	136	if (lengthB > 0)
	137	{
3ec579a0	138	for (int mm=0; mm<lengthB; mm++)
1d3c1faa	139	{
3ec579a0	140	for (int r=0; r<k; r++)
09ab3c16	141	phi[ai4( A2[ai(j,0,lambdaIndex,p,m+1,L)]-1, b[mm], r, lambdaIndex, p, m, k, L)] = 0.;
1d3c1faa BA	142	}
1d3c1faa BA	143	}
3ec579a0	144
1d3c1faa BA	145	//~ c = A1(j,2:end,lambdaIndex);
	146	//~ c(c==0) = [];
	147	//~ dimension = dimension + length(c);
3ec579a0	148	for (int mm=0; mm<m; mm++)
1d3c1faa	149	{
3ec579a0	150	if (A1[ai(j,mm+1,lambdaIndex,p,m+1,L)] != 0)
1d3c1faa BA	151	dimension++;
	152	}
	153	}
	154	free(b);
3ec579a0	155
1d3c1faa	156	int signum;
9ff729fb BA	157	Real* densite = (Real)calloc(Ln,sizeof(Real));
9ff729fb BA	158	Real sumLogDensit = 0.0;
1d3c1faa BA	159	gsl_matrix* matrix = gsl_matrix_alloc(m, m);
1d3c1faa BA	160	gsl_permutation* permutation = gsl_permutation_alloc(m);
9ff729fb BA	161	Real* YiRhoR = (Real)malloc(msizeof(Real));
9ff729fb BA	162	Real* XiPhiR = (Real)malloc(msizeof(Real));
3ec579a0	163	for (int i=0; i<n; i++)
1d3c1faa BA	164	{
	165	//~ for r=1:k
	166	//~ delta = Y(i,:)rho(:,:,r,lambdaIndex) - (X(i,a)(phi(a,:,r,lambdaIndex)));
	167	//~ densite(i,lambdaIndex) = densite(i,lambdaIndex) +...
	168	//~ pi(r,lambdaIndex)det(rho(:,:,r,lambdaIndex))/(sqrt(2PI))^m*exp(-dot(delta,delta)/2.0);
	169	//~ end
3ec579a0	170	for (int r=0; r<k; r++)
1d3c1faa BA	171	{
1d3c1faa BA	172	//compute det(rho(:,:,r,lambdaIndex)) [TODO: avoid re-computations]
3ec579a0	173	for (int u=0; u<m; u++)
1d3c1faa	174	{
3ec579a0 BA	175	for (int v=0; v<m; v++)
3ec579a0 BA	176	matrix->data[u*m+v] = rho[ai4(u,v,r,lambdaIndex,m,m,k,L)];
1d3c1faa BA	177	}
1d3c1faa BA	178	gsl_linalg_LU_decomp(matrix, permutation, &signum);
9ff729fb	179	Real detRhoR = gsl_linalg_LU_det(matrix, signum);
3ec579a0	180
1d3c1faa	181	//compute Y(i,:)*rho(:,:,r,lambdaIndex)
3ec579a0	182	for (int u=0; u<m; u++)
1d3c1faa BA	183	{
1d3c1faa BA	184	YiRhoR[u] = 0.0;
3ec579a0 BA	185	for (int v=0; v<m; v++)
3ec579a0 BA	186	YiRhoR[u] += Y[mi(i,v,n,m)] * rho[ai4(v,u,r,lambdaIndex,m,m,k,L)];
1d3c1faa	187	}
3ec579a0	188
1d3c1faa	189	//compute X(i,a)*phi(a,:,r,lambdaIndex)
3ec579a0	190	for (int u=0; u<m; u++)
1d3c1faa BA	191	{
1d3c1faa BA	192	XiPhiR[u] = 0.0;
3ec579a0 BA	193	for (int v=0; v<lengthA; v++)
3ec579a0 BA	194	XiPhiR[u] += X[mi(i,a[v],n,p)] * phi[ai4(a[v],u,r,lambdaIndex,p,m,k,L)];
1d3c1faa	195	}
3ec579a0 BA	196	// On peut remplacer X par Xa dans ce dernier calcul, mais je ne sais pas si c'est intéressant ...
3ec579a0 BA	197
1d3c1faa	198	// compute dotProduct < delta . delta >
9ff729fb	199	Real dotProduct = 0.0;
3ec579a0	200	for (int u=0; u<m; u++)
1d3c1faa	201	dotProduct += (YiRhoR[u]-XiPhiR[u]) * (YiRhoR[u]-XiPhiR[u]);
3ec579a0 BA	202
	203	densite[mi(lambdaIndex,i,L,n)] += (pi[mi(r,lambdaIndex,k,L)]detRhoR/pow(sqrt(2.0M_PI),m))*exp(-dotProduct/2.0);
	204	}
1d3c1faa BA	205	sumLogDensit += log(densite[lambdaIndex*n+i]);
1d3c1faa BA	206	}
c3bc4705 BA	207	llh[mi(lambdaIndex,0,L,2)] = sumLogDensit;
c3bc4705 BA	208	llh[mi(lambdaIndex,1,L,2)] = (dimension+m+1)*k-1;
3ec579a0	209
1d3c1faa BA	210	free(a);
	211	free(YiRhoR);
	212	free(XiPhiR);
	213	free(densite);
	214	gsl_matrix_free(matrix);
	215	gsl_permutation_free(permutation);
	216	}
	217	}
	218	}