getfem_assembling.h

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/* -*- c++ -*- (enables emacs c++ mode) */
/*===========================================================================
 
 Copyright (C) 2000-2020 Yves Renard, Julien Pommier
 
 This file is a part of GetFEM
 
 GetFEM  is  free software;  you  can  redistribute  it  and/or modify it
 under  the  terms  of the  GNU  Lesser General Public License as published
 by  the  Free Software Foundation;  either version 3 of the License,  or
 (at your option) any later version along with the GCC Runtime Library
 Exception either version 3.1 or (at your option) any later version.
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 software  library  without  restriction.  Specifically,  if   other  files
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===========================================================================*/
 
/** @file getfem_assembling.h
    @author  Yves Renard <Yves.Renard@insa-lyon.fr>
    @author  Julien Pommier <Julien.Pommier@insa-toulouse.fr>
    @date November 17, 2000.
    @brief Miscelleanous assembly routines for common terms. Use the low-level
           generic assembly. Prefer the high-level one.
 */
 
/** @defgroup asm Assembly routines */
 
#ifndef GETFEM_ASSEMBLING_H__
#define GETFEM_ASSEMBLING_H__
 
#include "getfem_assembling_tensors.h"
#include "getfem_generic_assembly.h"
 
namespace getfem {
 
  /**
     compute @f$ \|U\|_2 @f$, U might be real or complex
     @ingroup asm
   */
  template<typename VEC>
  inline scalar_type asm_L2_norm
  (const mesh_im &mim, const mesh_fem &mf, const VEC &U,
   const mesh_region &rg=mesh_region::all_convexes())
  { return sqrt(asm_L2_norm_sqr(mim, mf, U, rg)); }
 
  template<typename VEC>
  scalar_type asm_L2_norm_sqr
  (const mesh_im &mim, const mesh_fem &mf, const VEC &U,
   const mesh_region &rg=mesh_region::all_convexes()) {
    return asm_L2_norm_sqr(mim, mf, U, rg,
                           typename gmm::linalg_traits<VEC>::value_type());
  }
  
  template<typename VEC, typename T>
  inline scalar_type asm_L2_norm_sqr(const mesh_im &mim, const mesh_fem &mf,
                              const VEC &U, const mesh_region &rg_, T) {
    ga_workspace workspace;
    model_real_plain_vector UU(mf.nb_dof());
    gmm::copy(U, UU);
    gmm::sub_interval Iu(0, mf.nb_dof());
    workspace.add_fem_variable("u", mf, Iu, UU);
    workspace.add_expression("u.u", mim, rg_);
    workspace.assembly(0);
    return workspace.assembled_potential();
  }
 
  inline scalar_type asm_L2_norm_sqr(const mesh_im &mim, const mesh_fem &mf,
                              const model_real_plain_vector &U,
                              const mesh_region &rg_, scalar_type) {
    ga_workspace workspace;
    gmm::sub_interval Iu(0, mf.nb_dof());
    workspace.add_fem_variable("u", mf, Iu, U);
    workspace.add_expression("u.u", mim, rg_);
    workspace.assembly(0);
    return workspace.assembled_potential();
  }
 
  template<typename VEC, typename T>
  inline scalar_type asm_L2_norm_sqr(const mesh_im &mim, const mesh_fem &mf,
                              const VEC &U,
                              const mesh_region &rg, std::complex<T>) {
    ga_workspace workspace;
    model_real_plain_vector UUR(mf.nb_dof()), UUI(mf.nb_dof());
    gmm::copy(gmm::real_part(U), UUR);
    gmm::copy(gmm::imag_part(U), UUI);
    gmm::sub_interval Iur(0, mf.nb_dof()), Iui(mf.nb_dof(), mf.nb_dof());
    workspace.add_fem_variable("u", mf, Iur, UUR);
    workspace.add_fem_variable("v", mf, Iui, UUI);
    workspace.add_expression("u.u + v.v", mim, rg);
    workspace.assembly(0);
    return workspace.assembled_potential();
  }
  
  /**
     Compute the distance between U1 and U2, defined on two different
     mesh_fems (but sharing the same mesh), without interpolating U1 on mf2.
     
     @ingroup asm
  */
  template<typename VEC1, typename VEC2>
  inline scalar_type asm_L2_dist
  (const mesh_im &mim, const mesh_fem &mf1, const VEC1 &U1,
   const mesh_fem &mf2, const VEC2 &U2,
   mesh_region rg = mesh_region::all_convexes()) {
    return sqrt(asm_L2_dist_sqr(mim, mf1, U1, mf2, U2, rg,
                           typename gmm::linalg_traits<VEC1>::value_type()));
  }
 
  template<typename VEC1, typename VEC2, typename T>
  inline scalar_type asm_L2_dist_sqr
  (const mesh_im &mim, const mesh_fem &mf1, const VEC1 &U1,
   const mesh_fem &mf2, const VEC2 &U2, mesh_region rg, T) {
    ga_workspace workspace;
    model_real_plain_vector UU1(mf1.nb_dof()), UU2(mf2.nb_dof());
    gmm::copy(U1, UU1); gmm::copy(U2, UU2);
    gmm::sub_interval Iu1(0, mf1.nb_dof()), Iu2(mf1.nb_dof(), mf2.nb_dof());
    workspace.add_fem_variable("u1", mf1, Iu1, UU1);
    workspace.add_fem_variable("u2", mf2, Iu2, UU2);
    workspace.add_expression("(u2-u1).(u2-u1)", mim, rg);
    workspace.assembly(0);
    return workspace.assembled_potential();
  }
 
  inline scalar_type asm_L2_dist_sqr
  (const mesh_im &mim, const mesh_fem &mf1, const  model_real_plain_vector &U1,
   const mesh_fem &mf2, const  model_real_plain_vector &U2, 
   mesh_region rg, scalar_type) {
    ga_workspace workspace;
    gmm::sub_interval Iu1(0, mf1.nb_dof()), Iu2(mf1.nb_dof(), mf2.nb_dof());
    workspace.add_fem_variable("u1", mf1, Iu1, U1);
    workspace.add_fem_variable("u2", mf2, Iu2, U2);
    workspace.add_expression("(u2-u1).(u2-u1)", mim, rg);
    workspace.assembly(0);
    return workspace.assembled_potential();
  }
 
  template<typename VEC1, typename VEC2, typename T>
  inline scalar_type asm_L2_dist_sqr
  (const mesh_im &mim, const mesh_fem &mf1, const VEC1 &U1,
   const mesh_fem &mf2, const VEC2 &U2, mesh_region rg, std::complex<T>) {
    ga_workspace workspace;
    model_real_plain_vector UU1R(mf1.nb_dof()), UU2R(mf2.nb_dof());
    model_real_plain_vector UU1I(mf1.nb_dof()), UU2I(mf2.nb_dof());
    gmm::copy(gmm::real_part(U1), UU1R); gmm::copy(gmm::imag_part(U1), UU1I);
    gmm::copy(gmm::real_part(U2), UU2R); gmm::copy(gmm::imag_part(U2), UU2I);
    gmm::sub_interval Iu1r(0, mf1.nb_dof()), Iu2r(mf1.nb_dof(), mf2.nb_dof());
    gmm::sub_interval Iu1i(Iu2r.last(), mf1.nb_dof());
    gmm::sub_interval Iu2i(Iu1i.last(), mf2.nb_dof());
    workspace.add_fem_variable("u1", mf1, Iu1r, UU1R);
    workspace.add_fem_variable("u2", mf2, Iu2r, UU2R);
    workspace.add_fem_variable("v1", mf1, Iu1i, UU1I);
    workspace.add_fem_variable("v2", mf2, Iu2i, UU2I);
    workspace.add_expression("(u2-u1).(u2-u1) + (v2-v1).(v2-v1)", mim, rg);
    workspace.assembly(0);
    return workspace.assembled_potential();
  }
 
  
  /**
     compute @f$\|\nabla U\|_2@f$, U might be real or complex
     @ingroup asm
   */
  template<typename VEC>
  scalar_type asm_H1_semi_norm
  (const mesh_im &mim, const mesh_fem &mf, const VEC &U,
   const mesh_region &rg = mesh_region::all_convexes()) {
    typedef typename gmm::linalg_traits<VEC>::value_type T;
    return sqrt(asm_H1_semi_norm_sqr(mim, mf, U, rg, T()));
  }
 
  template<typename VEC, typename T>
  inline scalar_type asm_H1_semi_norm_sqr
  (const mesh_im &mim, const mesh_fem &mf, const VEC &U,
   const mesh_region &rg_, T) {
    ga_workspace workspace;
    model_real_plain_vector UU(mf.nb_dof()); gmm::copy(U, UU);
    gmm::sub_interval Iu(0, mf.nb_dof());
    workspace.add_fem_variable("u", mf, Iu, UU);
    workspace.add_expression("Grad_u:Grad_u", mim, rg_);
    workspace.assembly(0);
    return workspace.assembled_potential();
  }
 
  inline scalar_type asm_H1_semi_norm_sqr
  (const mesh_im &mim, const mesh_fem &mf, const model_real_plain_vector &U,
   const mesh_region &rg_, scalar_type) {
    ga_workspace workspace;
    gmm::sub_interval Iu(0, mf.nb_dof());
    workspace.add_fem_variable("u", mf, Iu, U);
    workspace.add_expression("Grad_u:Grad_u", mim, rg_);
    workspace.assembly(0);
    return workspace.assembled_potential();
  }
  
 
  template<typename VEC, typename T>
  inline scalar_type asm_H1_semi_norm_sqr
  (const mesh_im &mim, const mesh_fem &mf, const VEC &U,
   const mesh_region &rg, std::complex<T>) {
    ga_workspace workspace;
    model_real_plain_vector UUR(mf.nb_dof()), UUI(mf.nb_dof());
    gmm::copy(gmm::real_part(U), UUR);
    gmm::copy(gmm::imag_part(U), UUI);
    gmm::sub_interval Iur(0, mf.nb_dof()), Iui(mf.nb_dof(), mf.nb_dof());
    workspace.add_fem_variable("u", mf, Iur, UUR);
    workspace.add_fem_variable("v", mf, Iui, UUI);
    workspace.add_expression("Grad_u:Grad_u + Grad_v:Grad_v", mim, rg);
    workspace.assembly(0);
    return workspace.assembled_potential();
  }
  
  /**
     Compute the H1 semi-distance between U1 and U2, defined on two different
     mesh_fems (but sharing the same mesh), without interpolating U1 on mf2.
     
     @ingroup asm
  */
  template<typename VEC1, typename VEC2>
  inline scalar_type asm_H1_semi_dist
  (const mesh_im &mim, const mesh_fem &mf1, const VEC1 &U1,
   const mesh_fem &mf2, const VEC2 &U2,
   mesh_region rg = mesh_region::all_convexes()) {
    return sqrt(asm_H1_semi_dist_sqr(mim, mf1, U1, mf2, U2, rg,
                           typename gmm::linalg_traits<VEC1>::value_type()));
  }
 
  template<typename VEC1, typename VEC2, typename T>
  inline scalar_type asm_H1_semi_dist_sqr
  (const mesh_im &mim, const mesh_fem &mf1, const VEC1 &U1,
   const mesh_fem &mf2, const VEC2 &U2, mesh_region rg, T) {
    ga_workspace workspace;
    model_real_plain_vector UU1(mf1.nb_dof()), UU2(mf2.nb_dof());
    gmm::copy(U1, UU1); gmm::copy(U2, UU2);
    gmm::sub_interval Iu1(0, mf1.nb_dof()), Iu2(mf1.nb_dof(), mf2.nb_dof());
    workspace.add_fem_variable("u1", mf1, Iu1, UU1);
    workspace.add_fem_variable("u2", mf2, Iu2, UU2);
    workspace.add_expression("(Grad_u2-Grad_u1):(Grad_u2-Grad_u1)", mim, rg);
    workspace.assembly(0);
    return workspace.assembled_potential();
  }
 
  inline scalar_type asm_H1_semi_dist_sqr
  (const mesh_im &mim, const mesh_fem &mf1, const  model_real_plain_vector &U1,
   const mesh_fem &mf2, const  model_real_plain_vector &U2, 
   mesh_region rg, scalar_type) {
    ga_workspace workspace;
    gmm::sub_interval Iu1(0, mf1.nb_dof()), Iu2(mf1.nb_dof(), mf2.nb_dof());
    workspace.add_fem_variable("u1", mf1, Iu1, U1);
    workspace.add_fem_variable("u2", mf2, Iu2, U2);
    workspace.add_expression("(Grad_u2-Grad_u1):(Grad_u2-Grad_u1)", mim, rg);
    workspace.assembly(0);
    return workspace.assembled_potential();
  }
 
  template<typename VEC1, typename VEC2, typename T>
  inline scalar_type asm_H1_semi_dist_sqr
  (const mesh_im &mim, const mesh_fem &mf1, const VEC1 &U1,
   const mesh_fem &mf2, const VEC2 &U2, mesh_region rg, std::complex<T>) {
    ga_workspace workspace;
    model_real_plain_vector UU1R(mf1.nb_dof()), UU2R(mf2.nb_dof());
    model_real_plain_vector UU1I(mf1.nb_dof()), UU2I(mf2.nb_dof());
    gmm::copy(gmm::real_part(U1), UU1R); gmm::copy(gmm::imag_part(U1), UU1I);
    gmm::copy(gmm::real_part(U2), UU2R); gmm::copy(gmm::imag_part(U2), UU2I);
    gmm::sub_interval Iu1r(0, mf1.nb_dof()), Iu2r(mf1.nb_dof(), mf2.nb_dof());
    gmm::sub_interval Iu1i(Iu2r.last(), mf1.nb_dof());
    gmm::sub_interval Iu2i(Iu1i.last(), mf2.nb_dof());
    workspace.add_fem_variable("u1", mf1, Iu1r, UU1R);
    workspace.add_fem_variable("u2", mf2, Iu2r, UU2R);
    workspace.add_fem_variable("v1", mf1, Iu1i, UU1I);
    workspace.add_fem_variable("v2", mf2, Iu2i, UU2I);
    workspace.add_expression("(Grad_u2-Grad_u1):(Grad_u2-Grad_u1)"
                             "+ (Grad_v2-Grad_v1):(Grad_v2-Grad_v1)", mim, rg);
    workspace.assembly(0);
    return workspace.assembled_potential();
  }
 
  /** 
      compute the H1 norm of U.
      @ingroup asm
  */
 
  /**
     compute @f$\|\nabla U\|_2@f$, U might be real or complex
     @ingroup asm
   */
  template<typename VEC>
  scalar_type asm_H1_norm
  (const mesh_im &mim, const mesh_fem &mf, const VEC &U,
   const mesh_region &rg = mesh_region::all_convexes()) {
    typedef typename gmm::linalg_traits<VEC>::value_type T;
    return sqrt(asm_H1_norm_sqr(mim, mf, U, rg, T()));
  }
 
  template<typename VEC, typename T>
  inline scalar_type asm_H1_norm_sqr
  (const mesh_im &mim, const mesh_fem &mf, const VEC &U,
   const mesh_region &rg_, T) {
    ga_workspace workspace;
    model_real_plain_vector UU(mf.nb_dof()); gmm::copy(U, UU);
    gmm::sub_interval Iu(0, mf.nb_dof());
    workspace.add_fem_variable("u", mf, Iu, UU);
    workspace.add_expression("u.u + Grad_u:Grad_u", mim, rg_);
    workspace.assembly(0);
    return workspace.assembled_potential();
  }
 
  inline scalar_type asm_H1_norm_sqr
  (const mesh_im &mim, const mesh_fem &mf, const model_real_plain_vector &U,
   const mesh_region &rg_, scalar_type) {
    ga_workspace workspace;
    gmm::sub_interval Iu(0, mf.nb_dof());
    workspace.add_fem_variable("u", mf, Iu, U);
    workspace.add_expression("u.u + Grad_u:Grad_u", mim, rg_);
    workspace.assembly(0);
    return workspace.assembled_potential();
  }
  
 
  template<typename VEC, typename T>
  inline scalar_type asm_H1_norm_sqr
  (const mesh_im &mim, const mesh_fem &mf, const VEC &U,
   const mesh_region &rg, std::complex<T>) {
    ga_workspace workspace;
    model_real_plain_vector UUR(mf.nb_dof()), UUI(mf.nb_dof());
    gmm::copy(gmm::real_part(U), UUR);
    gmm::copy(gmm::imag_part(U), UUI);
    gmm::sub_interval Iur(0, mf.nb_dof()), Iui(mf.nb_dof(), mf.nb_dof());
    workspace.add_fem_variable("u", mf, Iur, UUR);
    workspace.add_fem_variable("v", mf, Iui, UUI);
    workspace.add_expression("u.u+v.v + Grad_u:Grad_u+Grad_v:Grad_v", mim, rg);
    workspace.assembly(0);
    return workspace.assembled_potential();
  }
  
  /**
     Compute the H1 distance between U1 and U2
     @ingroup asm
   */
  template<typename VEC1, typename VEC2>
  inline scalar_type asm_H1_dist
  (const mesh_im &mim, const mesh_fem &mf1, const VEC1 &U1,
   const mesh_fem &mf2, const VEC2 &U2,
   mesh_region rg = mesh_region::all_convexes()) {
    return sqrt(asm_H1_dist_sqr(mim, mf1, U1, mf2, U2, rg,
                             typename gmm::linalg_traits<VEC1>::value_type()));
  }
 
  template<typename VEC1, typename VEC2, typename T>
  inline scalar_type asm_H1_dist_sqr
  (const mesh_im &mim, const mesh_fem &mf1, const VEC1 &U1,
   const mesh_fem &mf2, const VEC2 &U2, mesh_region rg, T) {
    ga_workspace workspace;
    model_real_plain_vector UU1(mf1.nb_dof()), UU2(mf2.nb_dof());
    gmm::copy(U1, UU1); gmm::copy(U2, UU2);
    gmm::sub_interval Iu1(0, mf1.nb_dof()), Iu2(mf1.nb_dof(), mf2.nb_dof());
    workspace.add_fem_variable("u1", mf1, Iu1, UU1);
    workspace.add_fem_variable("u2", mf2, Iu2, UU2);
    workspace.add_expression("(u2-u1).(u2-u1)"
                             "+ (Grad_u2-Grad_u1):(Grad_u2-Grad_u1)", mim, rg);
    workspace.assembly(0);
    return workspace.assembled_potential();
  }
 
  inline scalar_type asm_H1_dist_sqr
  (const mesh_im &mim, const mesh_fem &mf1, const  model_real_plain_vector &U1,
   const mesh_fem &mf2, const  model_real_plain_vector &U2, 
   mesh_region rg, scalar_type) {
    ga_workspace workspace;
    gmm::sub_interval Iu1(0, mf1.nb_dof()), Iu2(mf1.nb_dof(), mf2.nb_dof());
    workspace.add_fem_variable("u1", mf1, Iu1, U1);
    workspace.add_fem_variable("u2", mf2, Iu2, U2);
    workspace.add_expression("(u2-u1).(u2-u1)"
                             "+ (Grad_u2-Grad_u1):(Grad_u2-Grad_u1)", mim, rg);
    workspace.assembly(0);
    return workspace.assembled_potential();
  }
 
  template<typename VEC1, typename VEC2, typename T>
  inline scalar_type asm_H1_dist_sqr
  (const mesh_im &mim, const mesh_fem &mf1, const VEC1 &U1,
   const mesh_fem &mf2, const VEC2 &U2, mesh_region rg, std::complex<T>) {
    ga_workspace workspace;
    model_real_plain_vector UU1R(mf1.nb_dof()), UU2R(mf2.nb_dof());
    model_real_plain_vector UU1I(mf1.nb_dof()), UU2I(mf2.nb_dof());
    gmm::copy(gmm::real_part(U1), UU1R); gmm::copy(gmm::imag_part(U1), UU1I);
    gmm::copy(gmm::real_part(U2), UU2R); gmm::copy(gmm::imag_part(U2), UU2I);
    gmm::sub_interval Iu1r(0, mf1.nb_dof()), Iu2r(mf1.nb_dof(), mf2.nb_dof());
    gmm::sub_interval Iu1i(Iu2r.last(), mf1.nb_dof());
    gmm::sub_interval Iu2i(Iu1i.last(), mf2.nb_dof());
    workspace.add_fem_variable("u1", mf1, Iu1r, UU1R);
    workspace.add_fem_variable("u2", mf2, Iu2r, UU2R);
    workspace.add_fem_variable("v1", mf1, Iu1i, UU1I);
    workspace.add_fem_variable("v2", mf2, Iu2i, UU2I);
    workspace.add_expression("(u2-u1).(u2-u1) + (v2-v1).(v2-v1)"
                             "+ (Grad_u2-Grad_u1):(Grad_u2-Grad_u1)"
                             "+ (Grad_v2-Grad_v1):(Grad_v2-Grad_v1)", mim, rg);
    workspace.assembly(0);
    return workspace.assembled_potential();
  }
 
  /**
     compute @f$\|Hess U\|_2@f$, U might be real or complex. For C^1 elements
     @ingroup asm
  */
  
  template<typename VEC>
  scalar_type asm_H2_semi_norm
  (const mesh_im &mim, const mesh_fem &mf, const VEC &U,
   const mesh_region &rg = mesh_region::all_convexes()) {
    typedef typename gmm::linalg_traits<VEC>::value_type T;
    return sqrt(asm_H2_semi_norm_sqr(mim, mf, U, rg, T()));
  }
 
  template<typename VEC, typename T>
  inline scalar_type asm_H2_semi_norm_sqr
  (const mesh_im &mim, const mesh_fem &mf, const VEC &U,
   const mesh_region &rg_, T) {
    ga_workspace workspace;
    model_real_plain_vector UU(mf.nb_dof()); gmm::copy(U, UU);
    gmm::sub_interval Iu(0, mf.nb_dof());
    workspace.add_fem_variable("u", mf, Iu, UU);
    workspace.add_expression("Hess_u:Hess_u", mim, rg_);
    workspace.assembly(0);
    return workspace.assembled_potential();
  }
 
  inline scalar_type asm_H2_semi_norm_sqr
  (const mesh_im &mim, const mesh_fem &mf, const model_real_plain_vector &U,
   const mesh_region &rg_, scalar_type) {
    ga_workspace workspace;
    gmm::sub_interval Iu(0, mf.nb_dof());
    workspace.add_fem_variable("u", mf, Iu, U);
    workspace.add_expression("Hess_u:Hess_u", mim, rg_);
    workspace.assembly(0);
    return workspace.assembled_potential();
  }
  
 
  template<typename VEC, typename T>
  inline scalar_type asm_H2_semi_norm_sqr
  (const mesh_im &mim, const mesh_fem &mf, const VEC &U,
   const mesh_region &rg, std::complex<T>) {
    ga_workspace workspace;
    model_real_plain_vector UUR(mf.nb_dof()), UUI(mf.nb_dof());
    gmm::copy(gmm::real_part(U), UUR);
    gmm::copy(gmm::imag_part(U), UUI);
    gmm::sub_interval Iur(0, mf.nb_dof()), Iui(mf.nb_dof(), mf.nb_dof());
    workspace.add_fem_variable("u", mf, Iur, UUR);
    workspace.add_fem_variable("v", mf, Iui, UUI);
    workspace.add_expression("Hess_u:Hess_u + Hess_v:Hess_v", mim, rg);
    workspace.assembly(0);
    return workspace.assembled_potential();
  }
 
 
  template<typename VEC1, typename VEC2>
  inline scalar_type asm_H2_semi_dist
  (const mesh_im &mim, const mesh_fem &mf1, const VEC1 &U1,
   const mesh_fem &mf2, const VEC2 &U2,
   mesh_region rg = mesh_region::all_convexes()) {
    return sqrt(asm_H2_semi_dist_sqr(mim, mf1, U1, mf2, U2, rg,
                           typename gmm::linalg_traits<VEC1>::value_type()));
  }
 
  template<typename VEC1, typename VEC2, typename T>
  inline scalar_type asm_H2_semi_dist_sqr
  (const mesh_im &mim, const mesh_fem &mf1, const VEC1 &U1,
   const mesh_fem &mf2, const VEC2 &U2, mesh_region rg, T) {
    ga_workspace workspace;
    model_real_plain_vector UU1(mf1.nb_dof()), UU2(mf2.nb_dof());
    gmm::copy(U1, UU1); gmm::copy(U2, UU2);
    gmm::sub_interval Iu1(0, mf1.nb_dof()), Iu2(mf1.nb_dof(), mf2.nb_dof());
    workspace.add_fem_variable("u1", mf1, Iu1, UU1);
    workspace.add_fem_variable("u2", mf2, Iu2, UU2);
    workspace.add_expression("(Hess_u2-Hess_u1):(Hess_u2-Hess_u1)", mim, rg);
    workspace.assembly(0);
    return workspace.assembled_potential();
  }
 
  inline scalar_type asm_H2_semi_dist_sqr
  (const mesh_im &mim, const mesh_fem &mf1, const  model_real_plain_vector &U1,
   const mesh_fem &mf2, const model_real_plain_vector &U2, 
   mesh_region rg, scalar_type) {
    ga_workspace workspace;
    gmm::sub_interval Iu1(0, mf1.nb_dof()), Iu2(mf1.nb_dof(), mf2.nb_dof());
    workspace.add_fem_variable("u1", mf1, Iu1, U1);
    workspace.add_fem_variable("u2", mf2, Iu2, U2);
    workspace.add_expression("(Hess_u2-Hess_u1):(Hess_u2-Hess_u1)", mim, rg);
    workspace.assembly(0);
    return workspace.assembled_potential();
  }
 
  template<typename VEC1, typename VEC2, typename T>
  inline scalar_type asm_H2_semi_dist_sqr
  (const mesh_im &mim, const mesh_fem &mf1, const VEC1 &U1,
   const mesh_fem &mf2, const VEC2 &U2, mesh_region rg, std::complex<T>) {
    ga_workspace workspace;
    model_real_plain_vector UU1R(mf1.nb_dof()), UU2R(mf2.nb_dof());
    model_real_plain_vector UU1I(mf1.nb_dof()), UU2I(mf2.nb_dof());
    gmm::copy(gmm::real_part(U1), UU1R); gmm::copy(gmm::imag_part(U1), UU1I);
    gmm::copy(gmm::real_part(U2), UU2R); gmm::copy(gmm::imag_part(U2), UU2I);
    gmm::sub_interval Iu1r(0, mf1.nb_dof()), Iu2r(mf1.nb_dof(), mf2.nb_dof());
    gmm::sub_interval Iu1i(Iu2r.last(), mf1.nb_dof());
    gmm::sub_interval Iu2i(Iu1i.last(), mf2.nb_dof());
    workspace.add_fem_variable("u1", mf1, Iu1r, UU1R);
    workspace.add_fem_variable("u2", mf2, Iu2r, UU2R);
    workspace.add_fem_variable("v1", mf1, Iu1i, UU1I);
    workspace.add_fem_variable("v2", mf2, Iu2i, UU2I);
    workspace.add_expression("(Hess_u2-Hess_u1):(Hess_u2-Hess_u1)"
                             "+ (Hess_v2-Hess_v1):(Hess_v2-Hess_v1)", mim, rg);
    workspace.assembly(0);
    return workspace.assembled_potential();
  }
 
  /** 
      compute the H2 norm of U (for C^1 elements).
      @ingroup asm
  */
  template<typename VEC>
  scalar_type asm_H2_norm(const mesh_im &mim, const mesh_fem &mf,
                          const VEC &U,
                          const mesh_region &rg
                          = mesh_region::all_convexes()) {
    typedef typename gmm::linalg_traits<VEC>::value_type T;
    return sqrt(asm_H1_norm_sqr(mim, mf, U, rg, T())
                + asm_H2_semi_norm_sqr(mim, mf, U, rg, T()));
  }
  
  /**
     Compute the H2 distance between U1 and U2
     @ingroup asm
   */
  template<typename VEC1, typename VEC2>
  scalar_type asm_H2_dist(const mesh_im &mim, 
                          const mesh_fem &mf1, const VEC1 &U1,
                          const mesh_fem &mf2, const VEC2 &U2,
                          const mesh_region &rg
                          = mesh_region::all_convexes()) {
    typedef typename gmm::linalg_traits<VEC1>::value_type T;
    return sqrt(asm_H1_dist_sqr(mim,mf1,U1,mf2,U2,rg,T()) +
                asm_H2_semi_dist_sqr(mim,mf1,U1,mf2,U2,rg,T()));
  }
 
  /*
    assembly of a matrix with 1 parameter (real or complex)
    (the most common here for the assembly routines below)
  */
  template <typename MAT, typename VECT>
  inline void asm_real_or_complex_1_param_mat
  (MAT &M, const mesh_im &mim, const mesh_fem &mf_u, const mesh_fem *mf_data,
   const VECT &A, const mesh_region &rg, const char *assembly_description) {
    asm_real_or_complex_1_param_mat_
      (M, mim, mf_u, mf_data, A, rg, assembly_description,
       typename gmm::linalg_traits<VECT>::value_type());
  }
 
  /* real version */
  template<typename MAT, typename VECT, typename T>
  inline void asm_real_or_complex_1_param_mat_
  (const MAT &M, const mesh_im &mim,  const mesh_fem &mf_u,
   const mesh_fem *mf_data, const VECT &A,  const mesh_region &rg,
   const char *assembly_description, T) {
    ga_workspace workspace;
    gmm::sub_interval Iu(0, mf_u.nb_dof());
    base_vector u(mf_u.nb_dof()), AA(gmm::vect_size(A));
    gmm::copy(A, AA);
    workspace.add_fem_variable("u", mf_u, Iu, u);
    if (mf_data)
      workspace.add_fem_constant("A", *mf_data, AA);
    else
      workspace.add_fixed_size_constant("A", AA);
    workspace.add_expression(assembly_description, mim, rg);
    workspace.assembly(2);
    if (gmm::mat_nrows(workspace.assembled_matrix()))
        gmm::add(workspace.assembled_matrix(), const_cast<MAT &>(M));
  }
 
  inline void asm_real_or_complex_1_param_mat_
  (model_real_sparse_matrix &M, const mesh_im &mim,  const mesh_fem &mf_u,
   const mesh_fem *mf_data, const model_real_plain_vector &A,
   const mesh_region &rg,
   const char *assembly_description, scalar_type) {
    ga_workspace workspace;
    gmm::sub_interval Iu(0, mf_u.nb_dof());
    base_vector u(mf_u.nb_dof());
    workspace.add_fem_variable("u", mf_u, Iu, u);
    if (mf_data)
      workspace.add_fem_constant("A", *mf_data, A);
    else
      workspace.add_fixed_size_constant("A", A);
    workspace.add_expression(assembly_description, mim, rg);
    workspace.set_assembled_matrix(M);
    workspace.assembly(2);
  }
 
  /* complex version */
  template<typename MAT, typename VECT, typename T>
  inline void asm_real_or_complex_1_param_mat_
  (MAT &M, const mesh_im &mim, const mesh_fem &mf_u, const mesh_fem *mf_data,
   const VECT &A, const mesh_region &rg, const char *assembly_description,
   std::complex<T>) {
    asm_real_or_complex_1_param_mat_(gmm::real_part(M),mim,mf_u,mf_data,
                                     gmm::real_part(A),rg,
                                     assembly_description, T());
    asm_real_or_complex_1_param_mat_(gmm::imag_part(M),mim,mf_u,mf_data,
                                     gmm::imag_part(A),rg,
                                     assembly_description, T());
  }
 
  /*
    assembly of a vector with 1 parameter (real or complex)
    (the most common here for the assembly routines below)
  */
  template <typename MAT, typename VECT>
  inline void asm_real_or_complex_1_param_vec
  (MAT &M, const mesh_im &mim, const mesh_fem &mf_u, const mesh_fem *mf_data,
   const VECT &A, const mesh_region &rg, const char *assembly_description) {
    asm_real_or_complex_1_param_vec_
      (M, mim, mf_u, mf_data, A, rg, assembly_description,
       typename gmm::linalg_traits<VECT>::value_type());
  }
 
  /* real version */
  template<typename VECTA, typename VECT, typename T>
  inline void asm_real_or_complex_1_param_vec_
  (const VECTA &V, const mesh_im &mim,  const mesh_fem &mf_u,
   const mesh_fem *mf_data, const VECT &A,  const mesh_region &rg,
   const char *assembly_description, T) {
    ga_workspace workspace;
    gmm::sub_interval Iu(0, mf_u.nb_dof());
    base_vector u(mf_u.nb_dof()), AA(gmm::vect_size(A));
    gmm::copy(A, AA);
    workspace.add_fem_variable("u", mf_u, Iu, u);
    if (mf_data)
      workspace.add_fem_constant("A", *mf_data, AA);
    else
      workspace.add_fixed_size_constant("A", AA);
    workspace.add_expression(assembly_description, mim, rg);
    workspace.assembly(1);
    if (gmm::vect_size(workspace.assembled_vector()))
        gmm::add(workspace.assembled_vector(), const_cast<VECTA &>(V));
  }
 
  inline void asm_real_or_complex_1_param_vec_
  (model_real_plain_vector &V, const mesh_im &mim,  const mesh_fem &mf_u,
   const mesh_fem *mf_data, const model_real_plain_vector &A,
   const mesh_region &rg,
   const char *assembly_description, scalar_type) {
    ga_workspace workspace;
    gmm::sub_interval Iu(0, mf_u.nb_dof());
    base_vector u(mf_u.nb_dof());
    workspace.add_fem_variable("u", mf_u, Iu, u);
    if (mf_data)
      workspace.add_fem_constant("A", *mf_data, A);
    else
      workspace.add_fixed_size_constant("A", A);
    workspace.add_expression(assembly_description, mim, rg);
    workspace.set_assembled_vector(V);
    workspace.assembly(1);
  }
 
  /* complex version */
  template<typename MAT, typename VECT, typename T>
  inline void asm_real_or_complex_1_param_vec_
  (MAT &M, const mesh_im &mim, const mesh_fem &mf_u, const mesh_fem *mf_data,
   const VECT &A, const mesh_region &rg,const char *assembly_description,
   std::complex<T>) {
    asm_real_or_complex_1_param_vec_(gmm::real_part(M),mim,mf_u,mf_data,
                                     gmm::real_part(A),rg,
                                     assembly_description, T());
    asm_real_or_complex_1_param_vec_(gmm::imag_part(M),mim,mf_u,mf_data,
                                     gmm::imag_part(A),rg,
                                     assembly_description, T());
  }
 
  /** 
      generic mass matrix assembly (on the whole mesh or on the specified
      convex set or boundary) 
      @ingroup asm
  */
  template<typename MAT>
  inline void asm_mass_matrix
  (const MAT &M, const mesh_im &mim, const mesh_fem &mf1,
   const mesh_region &rg = mesh_region::all_convexes()) {
 
    ga_workspace workspace;
    gmm::sub_interval Iu1(0, mf1.nb_dof());
    base_vector u1(mf1.nb_dof());
    workspace.add_fem_variable("u1", mf1, Iu1, u1);
    workspace.add_expression("Test_u1:Test2_u1", mim, rg);
    workspace.assembly(2);
    if (gmm::mat_nrows(workspace.assembled_matrix()))
        gmm::add(workspace.assembled_matrix(), const_cast<MAT &>(M));
  }
 
  inline void asm_mass_matrix
  (model_real_sparse_matrix &M, const mesh_im &mim,
   const mesh_fem &mf1,
   const mesh_region &rg = mesh_region::all_convexes()) {
    ga_workspace workspace;
    gmm::sub_interval Iu1(0, mf1.nb_dof());
    base_vector u1(mf1.nb_dof());
    workspace.add_fem_variable("u1", mf1, Iu1, u1);
    workspace.add_expression("Test_u1:Test2_u1", mim, rg);
    workspace.set_assembled_matrix(M);
    workspace.assembly(2);
  }
 
  /** 
   *  generic mass matrix assembly (on the whole mesh or on the specified
   *  boundary) 
   */
 
  template<typename MAT>
  inline void asm_mass_matrix
  (const MAT &M, const mesh_im &mim, const mesh_fem &mf1, const mesh_fem &mf2,
   const mesh_region &rg = mesh_region::all_convexes()) {
    ga_workspace workspace;
    gmm::sub_interval Iu1(0, mf1.nb_dof()), Iu2(Iu1.last(), mf2.nb_dof());
    base_vector u1(mf1.nb_dof()), u2(mf2.nb_dof());
    workspace.add_fem_variable("u1", mf1, Iu1, u1);
    workspace.add_fem_variable("u2", mf2, Iu2, u2);
    workspace.add_expression("Test_u1:Test2_u2", mim, rg);
    workspace.assembly(2);
    if (gmm::mat_nrows(workspace.assembled_matrix()))
        gmm::add(gmm::sub_matrix(workspace.assembled_matrix(), Iu1, Iu2),
                 const_cast<MAT &>(M));
  }
  
  inline void asm_mass_matrix
  (model_real_sparse_matrix &M, const mesh_im &mim,
   const mesh_fem &mf1, const mesh_fem &mf2,
   const mesh_region &rg = mesh_region::all_convexes()) {
    ga_workspace workspace;
    gmm::sub_interval Iu1(0, mf1.nb_dof()), Iu2(0, mf2.nb_dof());
    base_vector u1(mf1.nb_dof()), u2(mf2.nb_dof());
    workspace.add_fem_variable("u1", mf1, Iu1, u1);
    workspace.add_fem_variable("u2", mf2, Iu2, u2);
    workspace.add_expression("Test_u1:Test2_u2", mim, rg);
    workspace.set_assembled_matrix(M);
    workspace.assembly(2);
  }
 
  /**
     generic mass matrix assembly with an additional parameter
     (on the whole mesh or on the specified boundary) 
     @ingroup asm
  */
  template<typename MAT, typename VECT>
  inline void asm_mass_matrix_param
  (const MAT &M, const mesh_im &mim, const mesh_fem &mf1, const mesh_fem &mf2,
   const mesh_fem &mf_data, const VECT &A,
   const mesh_region &rg = mesh_region::all_convexes()) {
 
    ga_workspace workspace;
    gmm::sub_interval Iu1(0, mf1.nb_dof()), Iu2(Iu1.last(), mf2.nb_dof());
    base_vector u1(mf1.nb_dof()), u2(mf2.nb_dof()), AA(mf_data.nb_dof());
    gmm::copy(A, AA);
    workspace.add_fem_variable("u1", mf1, Iu1, u1);
    workspace.add_fem_variable("u2", mf2, Iu2, u2);
    workspace.add_fem_constant("A", mf_data, AA);
    workspace.add_expression("(A*Test_u1).Test2_u2", mim, rg);
    workspace.assembly(2);
    if (gmm::mat_nrows(workspace.assembled_matrix()))
        gmm::add(gmm::sub_matrix(workspace.assembled_matrix(), Iu1, Iu2),
                 const_cast<MAT &>(M));
  }
 
  inline void asm_mass_matrix_param
  (model_real_sparse_matrix &M, const mesh_im &mim,
   const mesh_fem &mf1, const mesh_fem &mf2,
   const mesh_fem &mf_data, const model_real_plain_vector &A,
   const mesh_region &rg = mesh_region::all_convexes()) {
 
    ga_workspace workspace;
    gmm::sub_interval Iu1(0, mf1.nb_dof()), Iu2(0, mf2.nb_dof());
    base_vector u1(mf1.nb_dof()), u2(mf2.nb_dof());
    workspace.add_fem_variable("u1", mf1, Iu1, u1);
    workspace.add_fem_variable("u2", mf2, Iu2, u2);
    workspace.add_fem_constant("A", mf_data, A);
    workspace.add_expression("(A*Test_u1).Test2_u2", mim, rg);
    workspace.set_assembled_matrix(M);
    workspace.assembly(2);
  }
    
 
 
  /** 
     generic mass matrix assembly with an additional parameter
     (on the whole mesh or on the specified boundary) 
     @ingroup asm
   */
  template<typename MAT, typename VECT>
  void asm_mass_matrix_param
  (MAT &M, const mesh_im &mim, const mesh_fem &mf_u, const mesh_fem &mf_data,
   const VECT &F, const mesh_region &rg = mesh_region::all_convexes()) {
    asm_real_or_complex_1_param_mat
      (M, mim, mf_u, &mf_data, F, rg, "(A*Test_u):Test2_u");
  }
    
  /** 
     generic mass matrix assembly with an additional constant parameter
     (on the whole mesh or on the specified boundary) 
     @ingroup asm
   */
  template<typename MAT, typename VECT>
  void asm_mass_matrix_homogeneous_param
  (MAT &M, const mesh_im &mim, const mesh_fem &mf_u,
   const VECT &F, const mesh_region &rg = mesh_region::all_convexes()) {
    asm_real_or_complex_1_param_mat
      (M, mim, mf_u, 0, F, rg, "(A*Test_u):Test2_u");
  }
 
  /**
     lumped mass matrix assembly from consistent mass matrix
   */
  template<typename MAT>
  inline void asm_lumped_mass_matrix_for_first_order_from_consistent
  (const MAT &M) {
    size_type nbd = gmm::mat_ncols(M), nbr = gmm::mat_nrows(M);
    GMM_ASSERT1(nbd == nbr, "mass matrix is not square");
    typedef typename gmm::linalg_traits<MAT>::value_type T;
    std::vector<T> V(nbd), W(nbr);
    gmm::fill(V, T(1));
    gmm::mult(M, V, W);
    gmm::clear(const_cast<MAT &>(M));
    for (size_type i =0; i < nbd; ++i) {
      (const_cast<MAT &>(M))(i, i) = W[i];
    }
  }
 
  /**
     lumped mass matrix assembly (on the whole mesh or on the specified
     boundary)
     @ingroup asm
   */
  template<typename MAT>
  inline void asm_lumped_mass_matrix_for_first_order
  (const MAT &M, const mesh_im &mim, const mesh_fem &mf1,
   const mesh_region &rg = mesh_region::all_convexes()) {
    asm_mass_matrix(M, mim, mf1, rg);
    asm_lumped_mass_matrix_for_first_order_from_consistent(M);
  }
 
  /**
     lumped mass matrix assembly with an additional parameter
     (on the whole mesh or on the specified boundary)
     @ingroup asm
   */
  template<typename MAT, typename VECT>
  inline void asm_lumped_mass_matrix_for_first_order_param
  (MAT &M, const mesh_im &mim, const mesh_fem &mf_u, const mesh_fem &mf_data,
   const VECT &F, const mesh_region &rg = mesh_region::all_convexes()) {
    asm_mass_matrix_param(M, mim, mf_u, mf_data, F, rg);
    asm_lumped_mass_matrix_for_first_order_from_consistent(M);
  }
 
  /** 
      source term (for both volumic sources and boundary (Neumann) sources).
      @ingroup asm
   */
  template<typename VECT1, typename VECT2>
  void asm_source_term(const VECT1 &B, const mesh_im &mim, const mesh_fem &mf,
                       const mesh_fem &mf_data, const VECT2 &F,
                       const mesh_region &rg = mesh_region::all_convexes()) {
    GMM_ASSERT1(mf_data.get_qdim() == 1 ||
                mf_data.get_qdim() == mf.get_qdim(),
                "invalid data mesh fem (same Qdim or Qdim=1 required)");
    asm_real_or_complex_1_param_vec
      (const_cast<VECT1 &>(B), mim, mf, &mf_data, F, rg, "A:Test_u");
  }
 
  /** 
      source term (for both volumic sources and boundary (Neumann) sources).
      For an homogeneous term.
      @ingroup asm
   */
  template<typename VECT1, typename VECT2>
  void asm_homogeneous_source_term(const VECT1 &B, const mesh_im &mim,
                                   const mesh_fem &mf, const VECT2 &F,
                       const mesh_region &rg = mesh_region::all_convexes()) {
    asm_real_or_complex_1_param_vec
      (const_cast<VECT1 &>(B), mim, mf, 0, F, rg, "A:Test_u");
  }
 
  /** 
      Normal source term (for boundary (Neumann) condition).
      @ingroup asm
   */
  template<typename VECT1, typename VECT2>
  void asm_normal_source_term(VECT1 &B, const mesh_im &mim,
                              const mesh_fem &mf,
                              const mesh_fem &mf_data, const VECT2 &F,
                              const mesh_region &rg) {
    asm_real_or_complex_1_param_vec(B, mim, mf, &mf_data, F, rg,
                          "(Reshape(A, qdim(u), meshdim).Normal):Test_u");
  }
 
  /** 
      Homogeneous normal source term (for boundary (Neumann) condition).
      @ingroup asm
   */
  template<typename VECT1, typename VECT2>
  void asm_homogeneous_normal_source_term
  (VECT1 &B, const mesh_im &mim, const mesh_fem &mf, const VECT2 &F,
   const mesh_region &rg)
  { asm_real_or_complex_1_param_vec(B, mim, mf, 0,F,rg,
                         "(Reshape(A, qdim(u), meshdim).Normal):Test_u"); }
 
  /**
     assembly of @f$\int{qu.v}@f$
 
     (if @f$u@f$ is a vector field of size @f$N@f$, @f$q@f$ is a square
     matrix @f$N\times N@f$ used by assem_general_boundary_conditions
 
     convention: Q is of the form 
     Q1_11 Q2_11 ..... Qn_11
     Q1_21 Q2_21 ..... Qn_21
     Q1_12 Q2_12 ..... Qn_12
     Q1_22 Q2_22 ..... Qn_22
     if  N = 2, and mf_d has n/N degree of freedom
 
     Q is a vector, so the matrix is assumed to be stored by columns
     (fortran style)
 
     Works for both volumic assembly and boundary assembly
     @ingroup asm
  */
  template<typename MAT, typename VECT>
  void asm_qu_term(MAT &M, const mesh_im &mim, const mesh_fem &mf_u, 
                   const mesh_fem &mf_d, const VECT &Q, 
                   const mesh_region &rg) {
    if (mf_d.get_qdim() == 1 && gmm::vect_size(Q) > mf_d.nb_dof())
      asm_real_or_complex_1_param_mat
        (M, mim,mf_u,&mf_d,Q,rg,"(Reshape(A,qdim(u),qdim(u)).Test_u):Test2_u");
    else if (mf_d.get_qdim() == mf_u.get_qdim())
      asm_real_or_complex_1_param_mat
        (M, mim, mf_u, &mf_d, Q, rg, "(A*Test_u):Test2_u");
    else GMM_ASSERT1(false, "invalid data mesh fem");
  }
 
  template<typename MAT, typename VECT>
  void asm_homogeneous_qu_term(MAT &M, const mesh_im &mim,
                               const mesh_fem &mf_u, const VECT &Q, 
                               const mesh_region &rg) {
    if (gmm::vect_size(Q) == 1)
      asm_real_or_complex_1_param_mat
        (M, mim,mf_u,0,Q,rg,"(A*Test_u):Test2_u");
    else
      asm_real_or_complex_1_param_mat
        (M, mim,mf_u,0,Q,rg,"(Reshape(A,qdim(u),qdim(u)).Test_u):Test2_u");
  }
  
  /** 
      Stiffness matrix for linear elasticity, with Lamé coefficients
      @ingroup asm
  */
  template<class MAT, class VECT>
  inline void asm_stiffness_matrix_for_linear_elasticity
  (const MAT &M, const mesh_im &mim, const mesh_fem &mf,
   const mesh_fem &mf_data, const VECT &LAMBDA, const VECT &MU,
   const mesh_region &rg = mesh_region::all_convexes()) {
    ga_workspace workspace;
    gmm::sub_interval Iu(0, mf.nb_dof());
    base_vector u(mf.nb_dof()), lambda(gmm::vect_size(LAMBDA));
    base_vector mu(gmm::vect_size(MU));
    gmm::copy(LAMBDA, lambda); gmm::copy(MU, mu); 
    workspace.add_fem_variable("u", mf, Iu, u);
    workspace.add_fem_constant("lambda", mf_data, lambda);
    workspace.add_fem_constant("mu", mf_data, mu);
    workspace.add_expression("((lambda*Div_Test_u)*Id(meshdim)"
                             "+(2*mu)*Sym(Grad_Test_u)):Grad_Test2_u", mim, rg);
    workspace.assembly(2);
    if (gmm::mat_nrows(workspace.assembled_matrix()))
       gmm::add(workspace.assembled_matrix(), const_cast<MAT &>(M));
  }
 
  inline void asm_stiffness_matrix_for_linear_elasticity
  (model_real_sparse_matrix &M, const mesh_im &mim, const mesh_fem &mf,
   const mesh_fem &mf_data, const model_real_plain_vector &LAMBDA,
   const model_real_plain_vector &MU,
   const mesh_region &rg = mesh_region::all_convexes()) {
    ga_workspace workspace;
    gmm::sub_interval Iu(0, mf.nb_dof());
    base_vector u(mf.nb_dof());
    workspace.add_fem_variable("u", mf, Iu, u);
    workspace.add_fem_constant("lambda", mf_data, LAMBDA);
    workspace.add_fem_constant("mu", mf_data, MU);
    workspace.add_expression("((lambda*Div_Test_u)*Id(meshdim)"
                             "+(2*mu)*Sym(Grad_Test_u)):Grad_Test2_u", mim, rg);
    workspace.set_assembled_matrix(M);
    workspace.assembly(2);
  }
 
 
  /** 
      Stiffness matrix for linear elasticity, with constant Lamé coefficients
      @ingroup asm
  */
  template<class MAT, class VECT>
  inline void asm_stiffness_matrix_for_homogeneous_linear_elasticity
  (const MAT &M, const mesh_im &mim, const mesh_fem &mf,
   const VECT &LAMBDA, const VECT &MU,
   const mesh_region &rg = mesh_region::all_convexes()) {
    ga_workspace workspace;
    gmm::sub_interval Iu(0, mf.nb_dof());
    base_vector u(mf.nb_dof()), lambda(gmm::vect_size(LAMBDA));
    base_vector mu(gmm::vect_size(MU));
    gmm::copy(LAMBDA, lambda); gmm::copy(MU, mu);
    workspace.add_fem_variable("u", mf, Iu, u);
    workspace.add_fixed_size_constant("lambda", lambda);
    workspace.add_fixed_size_constant("mu", mu);
    workspace.add_expression("((lambda*Div_Test_u)*Id(meshdim)"
                             "+(2*mu)*Sym(Grad_Test_u)):Grad_Test2_u", mim, rg);
    workspace.assembly(2);
    if (gmm::mat_nrows(workspace.assembled_matrix()))
      gmm::add(workspace.assembled_matrix(), const_cast<MAT &>(M));
  }
 
  
  inline void asm_stiffness_matrix_for_homogeneous_linear_elasticity
  (model_real_sparse_matrix &M, const mesh_im &mim, const mesh_fem &mf,
   const model_real_plain_vector &LAMBDA, const model_real_plain_vector &MU,
   const mesh_region &rg = mesh_region::all_convexes()) {
    ga_workspace workspace;
    gmm::sub_interval Iu(0, mf.nb_dof());
    base_vector u(mf.nb_dof());
    workspace.add_fem_variable("u", mf, Iu, u);
    workspace.add_fixed_size_constant("lambda", LAMBDA);
    workspace.add_fixed_size_constant("mu", MU);
    workspace.add_expression("((lambda*Div_Test_u)*Id(meshdim)"
                             "+(2*mu)*Sym(Grad_Test_u)):Grad_Test2_u", mim, rg);
    workspace.set_assembled_matrix(M);
    workspace.assembly(2);
  }
 
  /** 
      Stiffness matrix for linear elasticity, with a general Hooke
      tensor. This is more a demonstration of generic assembly than
      something useful !  
 
      Note that this function is just an alias for
      asm_stiffness_matrix_for_vector_elliptic.
 
      @ingroup asm
  */
  template<typename MAT, typename VECT> void
  asm_stiffness_matrix_for_linear_elasticity_Hooke
  (MAT &RM, const mesh_im &mim, const mesh_fem &mf, const mesh_fem &mf_data, 
   const VECT &H, const mesh_region &rg = mesh_region::all_convexes()) {
    asm_stiffness_matrix_for_vector_elliptic(RM, mim, mf, mf_data, H, rg);
  }
 
  /**
     Build the mixed pressure term @f$ B = - \int p.div u @f$
 
     @ingroup asm
  */
  template<typename MAT>
  inline void asm_stokes_B(const MAT &B, const mesh_im &mim,
                           const mesh_fem &mf_u, const mesh_fem &mf_p, 
                           const mesh_region &rg=mesh_region::all_convexes()) {
    ga_workspace workspace;
    gmm::sub_interval Iu(0, mf_u.nb_dof()), Ip(Iu.last(), mf_p.nb_dof());
    base_vector u(mf_u.nb_dof()), p(mf_p.nb_dof());
    workspace.add_fem_variable("u", mf_u, Iu, u);
    workspace.add_fem_variable("p", mf_p, Ip, p);
    workspace.add_expression("Test_p*Div_Test2_u", mim, rg);
    workspace.assembly(2);
    if (gmm::mat_nrows(workspace.assembled_matrix()))
        gmm::add(gmm::sub_matrix(workspace.assembled_matrix(), Ip, Iu),
                 const_cast<MAT &>(B));
  }
 
  inline void asm_stokes_B(model_real_sparse_matrix &B, const mesh_im &mim,
                           const mesh_fem &mf_u, const mesh_fem &mf_p, 
                           const mesh_region &rg=mesh_region::all_convexes()) {
    ga_workspace workspace;
    gmm::sub_interval Iu(0, mf_u.nb_dof()), Ip(0, mf_p.nb_dof());
    base_vector u(mf_u.nb_dof()), p(mf_p.nb_dof());
    workspace.add_fem_variable("u", mf_u, Iu, u);
    workspace.add_fem_variable("p", mf_p, Ip, p);
    workspace.add_expression("Test_p*Div_Test2_u", mim, rg);
    workspace.set_assembled_matrix(B);
    workspace.assembly(2);
  }
  
 
  /**
     assembly of @f$\int_\Omega \nabla u.\nabla v@f$.
 
     @ingroup asm
   */
  template<typename MAT>
  inline void asm_stiffness_matrix_for_homogeneous_laplacian
  (const MAT &M, const mesh_im &mim, const mesh_fem &mf,
   const mesh_region &rg = mesh_region::all_convexes()) {
    ga_workspace workspace;
    gmm::sub_interval Iu(0, mf.nb_dof());
    base_vector u(mf.nb_dof());
    workspace.add_fem_variable("u", mf, Iu, u);
    workspace.add_expression("Grad_Test_u:Grad_Test2_u", mim, rg);
    workspace.assembly(2);
    if (gmm::mat_nrows(workspace.assembled_matrix()))
        gmm::add(workspace.assembled_matrix(), const_cast<MAT &>(M));
  }
 
  inline void asm_stiffness_matrix_for_homogeneous_laplacian
  (model_real_sparse_matrix &M, const mesh_im &mim, const mesh_fem &mf,
   const mesh_region &rg = mesh_region::all_convexes()) {
    ga_workspace workspace;
    gmm::sub_interval Iu(0, mf.nb_dof());
    base_vector u(mf.nb_dof());
    workspace.add_fem_variable("u", mf, Iu, u);
    workspace.add_expression("Grad_Test_u:Grad_Test2_u", mim, rg);
    workspace.set_assembled_matrix(M);
    workspace.assembly(2);
  }
 
  /**
     assembly of @f$\int_\Omega \nabla u.\nabla v@f$.
     @ingroup asm
   */
  template<typename MAT>
  inline void asm_stiffness_matrix_for_homogeneous_laplacian_componentwise
  (const MAT &M, const mesh_im &mim, const mesh_fem &mf, 
   const mesh_region &rg = mesh_region::all_convexes()) {
    return asm_stiffness_matrix_for_homogeneous_laplacian(M, mim, mf, rg);
  }
 
  /**
     assembly of @f$\int_\Omega a(x)\nabla u.\nabla v@f$ , where @f$a(x)@f$
     is scalar.
     @ingroup asm
  */
  template<typename MAT, typename VECT>
  inline void asm_stiffness_matrix_for_laplacian
  (MAT &M, const mesh_im &mim, const mesh_fem &mf, const mesh_fem &mf_data,
   const VECT &A, const mesh_region &rg = mesh_region::all_convexes()) {
    GMM_ASSERT1(mf_data.get_qdim() == 1
                && gmm::vect_size(A) == mf_data.nb_dof(), "invalid data");
    asm_real_or_complex_1_param_mat
      (M, mim, mf, &mf_data, A, rg, "(A*Grad_Test_u):Grad_Test2_u");
  }
 
  /** The same as getfem::asm_stiffness_matrix_for_laplacian , but on
      each component of mf when mf has a qdim > 1
  */
  template<typename MAT, typename VECT>
  inline void asm_stiffness_matrix_for_laplacian_componentwise
  (MAT &M, const mesh_im &mim, const mesh_fem &mf, const mesh_fem &mf_data,
   const VECT &A, const mesh_region &rg = mesh_region::all_convexes()) {
    asm_stiffness_matrix_for_laplacian(M, mim, mf, mf_data, A, rg);
  }
 
  /**
     assembly of @f$\int_\Omega A(x)\nabla u.\nabla v@f$, where @f$A(x)@f$
     is a (symmetric positive definite) NxN matrix.
     Arguments:
     @param M a sparse matrix of dimensions mf.nb_dof() x mf.nb_dof()
 
     @param mim the mesh_im.
 
     @param mf : the mesh_fem that describes the solution, with
     @c mf.get_qdim() == @c N.
 
     @param mf_data the mesh_fem that describes the coefficients of @c A
     (@c mf_data.get_qdim() == 1).
 
     @param A a (very large) vector, which is a flattened (n x n x
     mf_data.nb_dof()) 3D array. For each dof of mf_data, it contains
     the n x n coefficients of @f$A@f$. As usual, the order is the
     "fortran-order", i.e. @c A = [A_11(dof1) A_21(dof1) A_31(dof1)
     A_12(dof1) A_22(dof1) ... A_33(dof) A_11(dof2)
     .... A_33(lastdof)]
 
     @ingroup asm
  */
  template<typename MAT, typename VECT>
  void asm_stiffness_matrix_for_scalar_elliptic
  (MAT &M, const mesh_im &mim, const mesh_fem &mf, const mesh_fem &mf_data,
   const VECT &A, const mesh_region &rg = mesh_region::all_convexes()) {
    asm_real_or_complex_1_param_mat
      (M, mim, mf, &mf_data, A, rg,
       "(Reshape(A,meshdim,meshdim)*Grad_Test_u):Grad_Test2_u");
  }
 
  /** The same but with a constant matrix
   */
  template<typename MAT, typename VECT>
  void asm_stiffness_matrix_for_homogeneous_scalar_elliptic
  (MAT &M, const mesh_im &mim, const mesh_fem &mf,
   const VECT &A, const mesh_region &rg = mesh_region::all_convexes()) {
    asm_real_or_complex_1_param_mat
      (M, mim, mf, 0, A, rg,
       "(Reshape(A,meshdim,meshdim)*Grad_Test_u):Grad_Test2_u");
  }
 
  /** The same but on each component of mf when mf has a qdim > 1 
   */
  template<typename MAT, typename VECT>
  void asm_stiffness_matrix_for_scalar_elliptic_componentwise
  (MAT &M, const mesh_im &mim, const mesh_fem &mf,
   const mesh_fem &mf_data, const VECT &A, 
   const mesh_region &rg = mesh_region::all_convexes()) {
    asm_real_or_complex_1_param_mat
      (M, mim, mf, &mf_data, A, rg,
       "(Grad_Test_u*(Reshape(A,meshdim,meshdim)')):Grad_Test2_u");
  }
 
  /** The same but with a constant matrix 
   */
  template<typename MAT, typename VECT>
  void asm_stiffness_matrix_for_homogeneous_scalar_elliptic_componentwise
  (MAT &M, const mesh_im &mim, const mesh_fem &mf, const VECT &A, 
   const mesh_region &rg = mesh_region::all_convexes()) {
    asm_real_or_complex_1_param_mat
      (M, mim, mf, 0, A, rg,
       "(Grad_Test_u*(Reshape(A,meshdim,meshdim)')):Grad_Test2_u");
  }
 
 
  /**
     Assembly of @f$\int_\Omega A(x)\nabla u.\nabla v@f$, where @f$A(x)@f$
     is a NxNxQxQ (symmetric positive definite) tensor defined on mf_data.
  */
  template<typename MAT, typename VECT> void
  asm_stiffness_matrix_for_vector_elliptic
  (MAT &M, const mesh_im &mim, const mesh_fem &mf, const mesh_fem &mf_data, 
   const VECT &A, const mesh_region &rg = mesh_region::all_convexes()) {
   /* M = a_{i,j,k,l}D_{i,j}(u)D_{k,l}(v) */
    asm_real_or_complex_1_param_mat
      (M, mim, mf, &mf_data, A, rg,
       "(Reshape(A,qdim(u),meshdim,qdim(u),meshdim):Grad_Test_u):Grad_Test2_u");
  }
 
  /**
     Assembly of @f$\int_\Omega A(x)\nabla u.\nabla v@f$, where @f$A(x)@f$
     is a NxNxQxQ (symmetric positive definite) constant tensor.
  */
  template<typename MAT, typename VECT> void
  asm_stiffness_matrix_for_homogeneous_vector_elliptic
  (MAT &M, const mesh_im &mim, const mesh_fem &mf,
   const VECT &A, const mesh_region &rg = mesh_region::all_convexes()) {
    /* M = a_{i,j,k,l}D_{i,j}(u)D_{k,l}(v) */
    asm_real_or_complex_1_param_mat
      (M, mim, mf, 0, A, rg,
       "(Reshape(A,qdim(u),meshdim,qdim(u),meshdim):Grad_Test_u):Grad_Test2_u");
  }
 
  /** 
      assembly of the term @f$\int_\Omega Kuv - \nabla u.\nabla v@f$, 
      for the helmholtz equation (@f$\Delta u + k^2u = 0@f$, with @f$K=k^2@f$).
 
      The argument K_squared may be a real or a complex-valued vector.
 
     @ingroup asm
  */
  template<typename MAT, typename VECT>
  void asm_Helmholtz(MAT &M, const mesh_im &mim, const mesh_fem &mf_u,
                     const mesh_fem &mf_data, const VECT &K_squared, 
                     const mesh_region &rg = mesh_region::all_convexes()) {
    typedef typename gmm::linalg_traits<MAT>::value_type T;
    asm_Helmholtz_(M, mim, mf_u, &mf_data, K_squared, rg, T());
  }
 
  template<typename MAT, typename VECT, typename T>
  void asm_Helmholtz_(MAT &M, const mesh_im &mim, const mesh_fem &mf_u,
                      const mesh_fem *mf_data, const VECT &K_squared, 
                      const mesh_region &rg, T) {
    asm_real_or_complex_1_param_mat
      (M, mim, mf_u, mf_data, K_squared, rg,
       "(A*Test_u).Test2_u - Grad_Test_u:Grad_Test2_u");
  }
 
  template<typename MAT, typename VECT, typename T>
  void asm_Helmholtz_(MAT &M, const mesh_im &mim, const mesh_fem &mf_u,
                     const mesh_fem *mf_data, const VECT &K_squared, 
                      const mesh_region &rg, std::complex<T>) {
    // asm_real_or_complex_1_param_mat
    //   (M, mim, mf_u, &mf_data, gmm::real_part(K_squared), rg,
    //    "(A*Test_u).Test2_u - Grad_Test_u:Grad_Test2_u");
    // asm_real_or_complex_1_param_mat
    //   (M, mim, mf_u, &mf_data, gmm::imag_part(K_squared), rg,
    //    "(A*Test_u).Test2_u");
 
 
    ga_workspace workspace;
    gmm::sub_interval Iur(0, mf_u.nb_dof()), Iui(Iur.last(), mf_u.nb_dof());
    base_vector u(mf_u.nb_dof());
    base_vector AR(gmm::vect_size(K_squared)), AI(gmm::vect_size(K_squared));
    gmm::copy(gmm::real_part(K_squared), AR);
    gmm::copy(gmm::imag_part(K_squared), AI);
    workspace.add_fem_variable("u", mf_u, Iur, u);
    workspace.add_fem_variable("ui", mf_u, Iui, u);
 
    if (mf_data) {
      workspace.add_fem_constant("A",  *mf_data, AR);
      workspace.add_fem_constant("AI", *mf_data, AI);
    } else {
      workspace.add_fixed_size_constant("A",  AR);
      workspace.add_fixed_size_constant("AI", AI);
    }
    workspace.add_expression("(A*Test_u).Test2_u - Grad_Test_u:Grad_Test2_u",
                             mim, rg);
    workspace.add_expression("(AI*Test_ui).Test2_ui", mim, rg);
    workspace.assembly(2);
    
    if (gmm::mat_nrows(workspace.assembled_matrix()))
      gmm::add(gmm::sub_matrix(workspace.assembled_matrix(),Iur,Iur),
               const_cast<MAT &>(M));
    if (gmm::mat_nrows(workspace.assembled_matrix()) > mf_u.nb_dof())
      gmm::add(gmm::sub_matrix(workspace.assembled_matrix(),Iui,Iui),
               gmm::imag_part(const_cast<MAT &>(M)));
      
 
 
  }
 
  /** 
      assembly of the term @f$\int_\Omega Kuv - \nabla u.\nabla v@f$, 
      for the helmholtz equation (@f$\Delta u + k^2u = 0@f$, with @f$K=k^2@f$).
 
      The argument K_squared may be a real or a complex-valued scalar.
 
     @ingroup asm
  */
  template<typename MAT, typename VECT>
  void asm_homogeneous_Helmholtz
  (MAT &M, const mesh_im &mim, const mesh_fem &mf_u, const VECT &K_squared, 
   const mesh_region &rg = mesh_region::all_convexes()) {
    typedef typename gmm::linalg_traits<MAT>::value_type T;
    asm_Helmholtz_(M, mim, mf_u, 0, K_squared, rg, T());
  }
 
  enum { ASMDIR_BUILDH = 1, ASMDIR_BUILDR = 2, ASMDIR_SIMPLIFY = 4,
         ASMDIR_BUILDALL = 7 };
 
  /**
     Assembly of Dirichlet constraints @f$ u(x) = r(x) @f$ in a weak form
     @f[ \int_{\Gamma} u(x)v(x) = \int_{\Gamma} r(x)v(x) \forall v@f],
     where @f$ v @f$ is in
     the space of multipliers corresponding to mf_mult.
 
     size(r_data) = Q   * nb_dof(mf_rh);
 
     A simplification can be done when the fem for u and r are the same and
     when the fem for the multipliers is of same dimension as the one for u.
     version = |ASMDIR_BUILDH : build H
     |ASMDIR_BUILDR : build R
     |ASMDIR_SIMPLIFY : simplify
     |ASMDIR_BUILDALL : do everything.
 
     @ingroup asm
  */
 
  template<typename MAT, typename VECT1, typename VECT2>
  void asm_dirichlet_constraints
  (MAT &H, VECT1 &R, const mesh_im &mim, const mesh_fem &mf_u,
   const mesh_fem &mf_mult, const mesh_fem &mf_r,
   const VECT2 &r_data, const mesh_region &region,
   int version =  ASMDIR_BUILDALL) {
    typedef typename gmm::linalg_traits<VECT1>::value_type value_type;
    typedef typename gmm::number_traits<value_type>::magnitude_type magn_type;
 
    if ((version & ASMDIR_SIMPLIFY) &&
        (mf_u.is_reduced() || mf_mult.is_reduced() || mf_r.is_reduced())) {
      GMM_WARNING1("Sorry, no simplification for reduced fems");
      version = (version & (ASMDIR_BUILDR | ASMDIR_BUILDH));
    }      
    
    region.from_mesh(mim.linked_mesh()).error_if_not_faces();
    GMM_ASSERT1(mf_r.get_qdim() == 1,
                "invalid data mesh fem (Qdim=1 required)");
    if (version & ASMDIR_BUILDH) {
      asm_mass_matrix(H, mim, mf_mult, mf_u, region);
      gmm::clean(H, gmm::default_tol(magn_type())
                 * gmm::mat_maxnorm(H) * magn_type(1000));
    }
    if (version & ASMDIR_BUILDR)
      asm_source_term(R, mim, mf_mult, mf_r, r_data, region);
 
    // Verifications and simplifications
 
    pfem pf_u, pf_r, pf_m;
    bool warning_msg1 = false, warning_msg2 = false;
    dal::bit_vector simplifiable_dofs, nonsimplifiable_dofs;
    std::vector<size_type> simplifiable_indices(mf_mult.nb_basic_dof());
    std::vector<value_type> simplifiable_values(mf_mult.nb_basic_dof());
    std::vector<value_type> v1, v2, v3;
 
    for (mr_visitor v(region); !v.finished(); v.next()) {
      GMM_ASSERT1(v.is_face(), "attempt to impose a dirichlet "
                  "on the interior of the domain!");
      size_type cv = v.cv(); short_type f = v.f();
 
      GMM_ASSERT1(mf_u.convex_index().is_in(cv) &&
                  mf_r.convex_index().is_in(cv) &&
                  mf_mult.convex_index().is_in(cv), 
                  "attempt to impose a dirichlet "
                  "condition on a convex with no FEM!");
      pf_u = mf_u.fem_of_element(cv); 
      pf_r = mf_r.fem_of_element(cv);
      pf_m = mf_mult.fem_of_element(cv);
 
      if (!pf_m->is_lagrange() && !warning_msg1) {
        GMM_WARNING3("Dirichlet condition with non-lagrange multiplier fem. "
                     "see the documentation about Dirichlet conditions.");
        warning_msg1 = true;
      }
      
      if (!(version & ASMDIR_SIMPLIFY)) continue;
      
      mesh_fem::ind_dof_face_ct pf_u_ct
        = mf_u.ind_basic_dof_of_face_of_element(cv, f);
      mesh_fem::ind_dof_face_ct pf_r_ct
        = mf_r.ind_basic_dof_of_face_of_element(cv, f);
      mesh_fem::ind_dof_face_ct pf_m_ct
        = mf_mult.ind_basic_dof_of_face_of_element(cv, f);
      
      size_type pf_u_nbdf = pf_u_ct.size();
      size_type pf_m_nbdf = pf_m_ct.size();
      size_type pf_u_nbdf_loc = pf_u->structure(cv)->nb_points_of_face(f);
      size_type pf_m_nbdf_loc = pf_m->structure(cv)->nb_points_of_face(f);
      // size_type pf_r_nbdf_loc = pf_r->structure(cv)->nb_points_of_face(f);
 
      if (pf_u_nbdf < pf_m_nbdf && !warning_msg2) {
        GMM_WARNING2("Dirichlet condition with a too rich multiplier fem. "
                     "see the documentation about Dirichlet conditions.");
        warning_msg2 = true;
      }
      
      if (pf_u != pf_r || pf_u_nbdf != pf_m_nbdf || 
          ((pf_u != pf_r) && (pf_u_nbdf_loc != pf_m_nbdf_loc))) { 
        for (size_type i = 0; i < pf_m_nbdf; ++i)
          nonsimplifiable_dofs.add(pf_m_ct[i]);
        continue;
      }
      
      for (size_type i = 0; i < pf_m_nbdf; ++i) {
        simplifiable_dofs.add(pf_m_ct[i]);
        simplifiable_indices[pf_m_ct[i]] = pf_u_ct[i];
      }
 
      if (!(version & ASMDIR_BUILDR)) continue;
 
      if (pf_u == pf_r) { // simplest simplification.
        size_type Qratio = mf_u.get_qdim() / mf_r.get_qdim();
        for (size_type i = 0; i < pf_m_nbdf; ++i) {
          simplifiable_values[pf_m_ct[i]]
            = r_data[pf_r_ct[i/Qratio]*Qratio+(i%Qratio)];
        }
      }
    }
    
    if (version & ASMDIR_SIMPLIFY) {
      if (simplifiable_dofs.card() > 0)
        { GMM_TRACE3("Simplification of the Dirichlet condition"); }
      else
        GMM_TRACE3("Sorry, no simplification of the Dirichlet condition");
      if (nonsimplifiable_dofs.card() > 0 && simplifiable_dofs.card() > 0)
        GMM_WARNING3("Partial simplification of the Dirichlet condition");
 
      for (dal::bv_visitor i(simplifiable_dofs); !i.finished(); ++i)
        if (!(nonsimplifiable_dofs[i])) {
          if (version & ASMDIR_BUILDH) {  /* "erase" the row i */
            const mesh::ind_cv_ct &cv_ct = mf_mult.convex_to_basic_dof(i);
            for (size_type j = 0; j < cv_ct.size(); ++j) {
              size_type cv = cv_ct[j];
              for (size_type k=0; k < mf_u.nb_basic_dof_of_element(cv); ++k)
                H(i, mf_u.ind_basic_dof_of_element(cv)[k]) = value_type(0);
            }
            H(i, simplifiable_indices[i]) = value_type(1);
          }
          if (version & ASMDIR_BUILDR) R[i] = simplifiable_values[i];
        }
    }
  }
 
  template<typename MATRM, typename VECT1, typename VECT2>
  void assembling_Dirichlet_condition
  (MATRM &RM, VECT1 &B, const getfem::mesh_fem &mf, size_type boundary,
   const VECT2 &F) {
    // Works only for Lagrange dofs.
    size_type Q=mf.get_qdim();
    GMM_ASSERT1(!(mf.is_reduced()), "This function is not adapted to "
                "reduced finite element methods"); 
    dal::bit_vector nndof = mf.basic_dof_on_region(boundary);
    getfem::pfem pf1;
    for (dal::bv_visitor cv(mf.convex_index()); !cv.finished(); ++cv) {
      pf1 = mf.fem_of_element(cv);
      getfem::pdof_description ldof = getfem::lagrange_dof(pf1->dim());
      size_type nbd = pf1->nb_dof(cv);
      for (size_type i = 0; i < nbd; i++) {
        size_type dof1 = mf.ind_basic_dof_of_element(cv)[i*Q];
        if (nndof.is_in(dof1) && pf1->dof_types()[i] == ldof) {
          // cout << "dof : " << i << endl;
          for (size_type j = 0; j < nbd; j++) {
            size_type dof2 = mf.ind_basic_dof_of_element(cv)[j*Q];
            for (size_type k = 0; k < Q; ++k)
              for (size_type l = 0; l < Q; ++l) {
                if (!(nndof.is_in(dof2)) &&
                    getfem::dof_compatibility(pf1->dof_types()[j],
                                              getfem::lagrange_dof(pf1->dim())))
                  B[dof2+k] -= RM(dof2+k, dof1+l) * F[dof1+l];
                RM(dof2+k, dof1+l) = RM(dof1+l, dof2+k) = 0;
              }
          }
          for (size_type k = 0; k < Q; ++k)
            { RM(dof1+k, dof1+k) = 1; B[dof1+k] = F[dof1+k]; }
        }
      }
    }
  }
  
  /**
     Assembly of generalized Dirichlet constraints h(x)u(x) = r(x),
     where h is a QxQ matrix field (Q == mf_u.get_qdim()), outputs a
     (under-determined) linear system HU=R.
 
     size(h_data) = Q^2 * nb_dof(mf_rh);
     size(r_data) = Q   * nb_dof(mf_rh);
 
     This function tries hard to make H diagonal or mostly diagonal:
     this function is able to "simplify" the dirichlet constraints (see below)
     version = |ASMDIR_BUILDH : build H
     |ASMDIR_BUILDR : build R
     |ASMDIR_SIMPLIFY : simplify
     |ASMDIR_BUILDALL : do everything.
 
     @ingroup asm
  */
 
  template<typename MAT, typename VECT1, typename VECT2, typename VECT3>
  void asm_generalized_dirichlet_constraints
  (MAT &H, VECT1 &R, const mesh_im &mim, const mesh_fem &mf_u,
   const mesh_fem &mf_h, const mesh_fem &mf_r, const VECT2 &h_data,
   const VECT3 &r_data, const mesh_region &region,
   int version =  ASMDIR_BUILDALL) {
    pfem pf_u, pf_rh;
 
    if ((version & ASMDIR_SIMPLIFY) &&
        (mf_u.is_reduced() || mf_h.is_reduced() || mf_r.is_reduced())) {
      GMM_WARNING1("Sorry, no simplification for reduced fems");
      version = (version & ASMDIR_BUILDR);
    }
 
    region.from_mesh(mim.linked_mesh()).error_if_not_faces();
    GMM_ASSERT1(mf_h.get_qdim() == 1 && mf_r.get_qdim() == 1,
                "invalid data mesh fem (Qdim=1 required)");
    if (version & ASMDIR_BUILDH) {
      asm_qu_term(H, mim, mf_u, mf_h, h_data, region);
      std::vector<size_type> ind(0);
      dal::bit_vector bdof = mf_u.basic_dof_on_region(region);
      // gmm::clean(H, 1E-15 * gmm::mat_maxnorm(H));
      for (size_type i = 0; i < mf_u.nb_dof(); ++i)
        if (!(bdof[i])) ind.push_back(i);
      gmm::clear(gmm::sub_matrix(H, gmm::sub_index(ind)));
    }
    if (version & ASMDIR_BUILDR)
      asm_source_term(R, mim, mf_u, mf_r, r_data, region);
    if (!(version & ASMDIR_SIMPLIFY)) return;
 
    /* step 2 : simplification of simple dirichlet conditions */
    if (&mf_r == &mf_h) {
      for (mr_visitor v(region); !v.finished(); v.next()) {
        size_type cv = v.cv();
        short_type f = v.f();
 
        GMM_ASSERT1(mf_u.convex_index().is_in(cv) &&
                    mf_r.convex_index().is_in(cv), 
                    "attempt to impose a dirichlet "
                    "condition on a convex with no FEM!");
 
        if (f >= mf_u.linked_mesh().structure_of_convex(cv)->nb_faces())
          continue;
        pf_u = mf_u.fem_of_element(cv); 
        pf_rh = mf_r.fem_of_element(cv);
        /* don't try anything with vector elements */
        if (mf_u.fem_of_element(cv)->target_dim() != 1) continue;
        bgeot::pconvex_structure cvs_u = pf_u->structure(cv);
        bgeot::pconvex_structure cvs_rh = pf_rh->structure(cv);
        for (size_type i = 0; i < cvs_u->nb_points_of_face(f); ++i) {
          
          size_type Q = mf_u.get_qdim();  // pf_u->target_dim() (==1)
          
          size_type ind_u = cvs_u->ind_points_of_face(f)[i];
          pdof_description tdof_u = pf_u->dof_types()[ind_u];
          
          for (size_type j = 0; j < cvs_rh->nb_points_of_face(f); ++j) {
            size_type ind_rh = cvs_rh->ind_points_of_face(f)[j];
            pdof_description tdof_rh = pf_rh->dof_types()[ind_rh];
            /*
              same kind of dof and same location of dof ? 
              => then the previous was not useful for this dofs (introducing
              a mass matrix which is not diagonal in the constraints matrix)
              -> the constraint is simplified:
              we replace \int{(H_j.psi_j)*phi_i}=\int{R_j.psi_j} (sum over j)
              with             H_j*phi_i = R_j     
              --> Le principe peut être faux : non identique à la projection
              L^2 et peut entrer en conccurence avec les autres ddl -> a revoir
            */
            if (tdof_u == tdof_rh &&
                gmm::vect_dist2_sqr((*(pf_u->node_tab(cv)))[ind_u], 
                                    (*(pf_rh->node_tab(cv)))[ind_rh])
                < 1.0E-14) {
              /* the dof might be "duplicated" */
              for (size_type q = 0; q < Q; ++q) {
                size_type dof_u = mf_u.ind_basic_dof_of_element(cv)[ind_u*Q+q];
                
                /* "erase" the row */
                if (version & ASMDIR_BUILDH)
                  for (size_type k=0; k < mf_u.nb_basic_dof_of_element(cv); ++k)
                    H(dof_u, mf_u.ind_basic_dof_of_element(cv)[k]) = 0.0;
                
                size_type dof_rh = mf_r.ind_basic_dof_of_element(cv)[ind_rh];
                /* set the "simplified" row */
                if (version & ASMDIR_BUILDH)
                  for (unsigned jj=0; jj < Q; jj++) {
                    size_type dof_u2
                      = mf_u.ind_basic_dof_of_element(cv)[ind_u*Q+jj];
                    H(dof_u, dof_u2) = h_data[(jj*Q+q) + Q*Q*(dof_rh)];
                  }
                if (version & ASMDIR_BUILDR) R[dof_u] = r_data[dof_rh*Q+q];
              }
            }
          }
        }
      }
    }
  }
 
  /** 
      Build an orthogonal basis of the kernel of H in NS, gives the
      solution of minimal norm of H*U = R in U0 and return the
      dimension of the kernel. The function is based on a
      Gramm-Schmidt algorithm.
 
      @ingroup asm
  */
  template<typename MAT1, typename MAT2, typename VECT1, typename VECT2>
  size_type Dirichlet_nullspace(const MAT1 &H, MAT2 &NS,
                                const VECT1 &R, VECT2 &U0) {
 
    typedef typename gmm::linalg_traits<MAT1>::value_type T;
    typedef typename gmm::number_traits<T>::magnitude_type MAGT;
    typedef typename gmm::temporary_vector<MAT1>::vector_type TEMP_VECT;
    MAGT tol = gmm::default_tol(MAGT());
    MAGT norminfH = gmm::mat_maxnorm(H);
    size_type nbd = gmm::mat_ncols(H), nbase = 0, nbr = gmm::mat_nrows(H);
    TEMP_VECT aux(nbr), e(nbd), f(nbd);
    dal::dynamic_array<TEMP_VECT> base_img;
    dal::dynamic_array<TEMP_VECT> base_img_inv;
    size_type nb_bimg = 0;
    gmm::clear(NS);
 
    if (!(gmm::is_col_matrix(H)))
      GMM_WARNING2("Dirichlet_nullspace inefficient for a row matrix H");
    // First, detection of null columns of H, and already orthogonals 
    // vectors of the image of H.
    dal::bit_vector nn;
    for (size_type i = 0; i < nbd; ++i) {
      gmm::clear(e); e[i] = T(1);
      gmm::mult(H, e, aux);
      MAGT n = gmm::vect_norm2(aux);
 
      if (n < norminfH*tol*1000) {
        NS(i, nbase++) = T(1); nn[i] = true;
      }
      else {
        bool good = true;
        for (size_type j = 0; j < nb_bimg; ++j)
          if (gmm::abs(gmm::vect_sp(aux, base_img[j])) > MAGT(0))
            { good = false; break; }
        if (good) {
          gmm::copy(e, f);
          gmm::scale(f, T(MAGT(1)/n)); gmm::scale(aux, T(MAGT(1)/n));
          base_img_inv[nb_bimg] = TEMP_VECT(nbd);
          gmm::copy(f, base_img_inv[nb_bimg]);
          gmm::clean(aux, gmm::vect_norminf(aux)*tol);
          base_img[nb_bimg] = TEMP_VECT(nbr);
          gmm::copy(aux, base_img[nb_bimg++]);
          nn[i] = true;
        }
      }
    }
    size_type nb_triv_base = nbase;
 
    for (size_type i = 0; i < nbd; ++i) {
      if (!(nn[i])) {
        gmm::clear(e); e[i] = T(1); gmm::clear(f); f[i] = T(1);
        gmm::mult(H, e, aux);
        for (size_type j = 0; j < nb_bimg; ++j) { 
          T c = gmm::vect_sp(aux, base_img[j]);
          // if (gmm::abs(c > 1.0E-6) { // à scaler sur l'ensemble de H ...
          if (c != T(0)) {
            gmm::add(gmm::scaled(base_img[j], -c), aux);
            gmm::add(gmm::scaled(base_img_inv[j], -c), f);
          }
        }
        if (gmm::vect_norm2(aux) < norminfH*tol*MAGT(10000)) {
          gmm::copy(f, gmm::mat_col(NS, nbase++));
        }
        else {
          MAGT n = gmm::vect_norm2(aux);
          gmm::scale(f, T(MAGT(1)/n)); gmm::scale(aux, T(MAGT(1)/n));
          gmm::clean(f, tol*gmm::vect_norminf(f));
          gmm::clean(aux, tol*gmm::vect_norminf(aux));
          base_img_inv[nb_bimg] = TEMP_VECT(nbd);
          gmm::copy(f, base_img_inv[nb_bimg]);
          base_img[nb_bimg] = TEMP_VECT(nbr);
          gmm::copy(aux, base_img[nb_bimg++]);
        }
      }
    }
    // Compute a solution in U0
    gmm::clear(U0);
    for (size_type i = 0; i < nb_bimg; ++i) {
      T c = gmm::vect_sp(base_img[i], R);
      gmm::add(gmm::scaled(base_img_inv[i], c), U0);
    }
    // Orthogonalisation of the basis of the kernel of H.
    for (size_type i = nb_triv_base; i < nbase; ++i) {
      for (size_type j = nb_triv_base; j < i; ++j) {
        T c = gmm::vect_sp(gmm::mat_col(NS,i), gmm::mat_col(NS,j));
        if (c != T(0))
          gmm::add(gmm::scaled(gmm::mat_col(NS,j), -c), gmm::mat_col(NS,i));
      }
      gmm::scale(gmm::mat_col(NS,i),
                 T(1) / gmm::vect_norm2(gmm::mat_col(NS,i)));
    }
    // projection of U0 on the orthogonal to the kernel.
    for (size_type j = nb_triv_base; j < nbase; ++j) {
      T c = gmm::vect_sp(gmm::mat_col(NS,j), U0);
      if (c != T(0))
        gmm::add(gmm::scaled(gmm::mat_col(NS,j), -c), U0);
    }
    // Test ...
    gmm::mult(H, U0, gmm::scaled(R, T(-1)), aux);
    if (gmm::vect_norm2(aux) > gmm::vect_norm2(U0)*tol*MAGT(10000))
      GMM_WARNING2("Dirichlet condition not well inverted: residu="
                  << gmm::vect_norm2(aux));
    
    return nbase;
  }
 
}  /* end of namespace getfem.                                             */
 
 
#endif /* GETFEM_ASSEMBLING_H__  */