Add Doxygen-style documentation to all interfaces.

opm/core/pressure/mimetic/mimetic.h

@@ -20,78 +20,250 @@
 #ifndef OPM_MIMETIC_HEADER_INCLUDED
 #define OPM_MIMETIC_HEADER_INCLUDED
 
+/**
+ * \file
+ * Routines to assist mimetic discretisations of the flow equation.
+ */
+
 #ifdef __cplusplus
 extern "C" {
 #endif
 
-void mim_ip_span_nullspace(int nf, int nconn, int d,
-                           double *C,
-                           double *A,
-                           double *X,
-                           double *work, int lwork);
-
-void mim_ip_linpress_exact(int nf, int nconn, int d,
-                           double vol, double *K,
-                           double *N,
-                           double *Binv,
-                           double *work, int lwork);
-
-void mim_ip_simple(int nf, int nconn, int d,
-                   double v, double *K, double *C,
-                   double *A, double *N,
-                   double *Binv,
-                   double *work, int lwork);
-
-
-/** Compute the mimetic inner products given a grid and cellwise
- *  permeability tensors.
+/**
+ * Form linear operator to span the null space of the normal vectors
+ * of a grid cell.
  *
- * @param ncells Number of cells in grid.
- * @param d Number of space dimensions.
- * @param max_ncf Maximum number of faces per cell.
- * @param pconn Start indices in conn for each cell, plus end
- *              marker. The size of pconn is (ncells + 1), and for a
- *              cell i, [conn[pconn[i]], conn[pconn[i+1]]) is a
- *              half-open interval containing the indices of faces
- *              adjacent to i.
- * @param conn Cell to face mapping. Size shall be equal to the sum of
- *             ncf. See pconn for explanation.
- * @param fneighbour Face to cell mapping. Its size shall be equal to
- *                   the number of faces times 2. For each face, the
- *                   two entries are either a cell number or -1
- *                   (signifying the outer boundary). The face normal
- *                   points out of the first cell and into the second.
- * @param fcentroid Face centroids. Size shall be equal to the number
- *                  of faces times d.
- * @param fnormal Face normale. Size shall be equal to the number
- *                of faces times d.
- * @param farea Face areas.
- * @param ccentroid Cell centroids. Size shall be ncells*d.
- * @param cvol Cell volumes.
- * @param perm Permeability. Size shall be ncells*d*d, storing a
- *             d-by-d positive definite tensor per cell.
- * @param[out] Binv This is where the inner product will be
- *                  stored. Its size shall be equal to \f$\sum_i
- * n_i^2\f$.
+ * Specifically,
+ * \f[
+ * \begin{aligned}
+ * X &= \operatorname{diag}(A) (I - QQ^\mathsf{T})
+ *      \operatorname{diag}(A), \\
+ * Q &= \operatorname{orth}(\operatorname{diag}(A) C)
+ * \end{aligned}
+ * \f]
+ * in which \f$\operatorname{orth}(M)\f$ denotes an orthonormal
+ * basis for the colum space (range) of the matrix \f$M\f$,
+ * represented as a matrix.
+ *
+ * @param[in]     nf    Number of faces connected to single grid cell.
+ * @param[in]     nconn Total number of grid cell connections.
+ *                      Typically equal to @c nf.
+ * @param[in]     d     Number of physical dimensions.
+ *                      Assumed less than four.
+ * @param[in,out] C     Centroid vectors.  Specifically,
+ *                      \f$c_{ij} = \Bar{x}_{ij} - \Bar{x}_{cj}\f$.
+ *                      Array of size \f$\mathit{nf}\times d\f$
+ *                      in column major (Fortran) order.
+ *                      Contents destroyed on output.
+ * @param[in]     A     Interface areas.
+ * @param[out]    X     Null space linear operator.  Array of size
+ *                      \f$\mathit{nconn}\times\mathit{nconn}\f$
+ *                      in column major (Fortran) order.  On output,
+ *                      the upper left \f$\mathit{nf}\times\mathit{nf}\f$
+ *                      sub-matrix contains the required null space
+ *                      linear operator.
+ * @param[out]    work  Scratch array of size at least @c nconn.
+ * @param[in]     lwork Actual size of scratch array.
  */
-void mim_ip_simple_all(int ncells, int d, int max_ncf,
-                       int *pconn, int *conn,
-                       int *fneighbour, double *fcentroid, double *fnormal,
-                       double *farea, double *ccentroid, double *cvol,
-                       double *perm, double *Binv);
+void
+mim_ip_span_nullspace(int nf, int nconn, int d,
+                      double *C,
+                      double *A,
+                      double *X,
+                      double *work, int lwork);
 
+/**
+ * Form (inverse) mimetic inner product that reproduces linear
+ * pressure drops (constant velocity) on general polyhedral cells.
+ *
+ * Specifically
+ * \f[
+ * B^{-1} = \frac{1}{v} \big(NKN^\mathsf{T} + \frac{6t}{d}\,X\big)
+ * \f]
+ * in which \f$t = \operatorname{tr}(K)\f$ is the trace of \f$K\f$
+ * and \f$X\f$ is the result of function mim_ip_span_nullspace().
+ *
+ * @param[in]     nf    Number of faces connected to single grid cell.
+ * @param[in]     nconn Total number of grid cell connections.
+ *                      Typically equal to @c nf.
+ * @param[in]     d     Number of physical dimensions.
+ *                      Assumed less than four.
+ * @param[in]     vol   Cell volume.
+ * @param[in]     K     Permeability.  A \f$d\times d\f$ matrix in
+ *                      column major (Fortran) order.
+ * @param[in]     N     Normal vectors.  An \f$\mathit{nf}\times d\f$
+ *                      matrix in column major (Fortran) order.
+ * @param[in,out] Binv  Inverse inner product result.  An
+ *                      \f$\mathit{nconn}\times\mathit{nconn}\f$
+ *                      matrix in column major format.  On input,
+ *                      the result of mim_ip_span_nullspace().  On
+ *                      output, the upper left
+ *                      \f$\mathit{nf}\times\mathit{nf}\f$ sub-matrix
+ *                      will be overwritten with \f$B^{-1}\f$.
+ * @param[in,out] work  Scratch array of size at least <CODE>nf * d</CODE>.
+ * @param[in]     lwork Actual size of scratch array.
+ */
+void
+mim_ip_linpress_exact(int nf, int nconn, int d,
+                      double vol, double *K,
+                      double *N,
+                      double *Binv,
+                      double *work, int lwork);
+
+
+/**
+ * Convenience wrapper around the function pair mim_ip_span_nullspace()
+ * and mim_ip_linpress_exact().
+ *
+ * @param[in]     nf    Number of faces connected to single grid cell.
+ * @param[in]     nconn Total number of grid cell connections.
+ *                      Typically equal to @c nf.
+ * @param[in]     d     Number of physical dimensions.
+ *                      Assumed less than four.
+ * @param[in]     v     Cell volume.
+ * @param[in]     K     Permeability.  A \f$d\times d\f$ matrix in
+ *                      column major (Fortran) order.
+ * @param[in,out] C     Centroid vectors.  Specifically,
+ *                      \f$c_{ij} = \Bar{x}_{ij} - \Bar{x}_{cj}\f$.
+ *                      Array of size \f$\mathit{nf}\times d\f$
+ *                      in column major (Fortran) order.
+ *                      Contents destroyed on output.
+ * @param[in]     A     Interface areas.
+ * @param[in]     N     Outward normal vectors.
+ *                      An \f$\mathit{nf}\times d\f$ matrix in
+ *                      column major (Fortran) order.
+ * @param[out]    Binv  Inverse inner product result.  An
+ *                      \f$\mathit{nconn}\times\mathit{nconn}\f$
+ *                      matrix in column major format.  On
+ *                      output, the upper left
+ *                      \f$\mathit{nf}\times\mathit{nf}\f$ sub-matrix
+ *                      will be overwritten with \f$B^{-1}\f$
+ *                      defined by function mim_ip_linpress_exact().
+ * @param[in,out] work  Scratch array of size at least <CODE>nf * d</CODE>.
+ * @param[in]     lwork Actual size of scratch array.
+ */
+void
+mim_ip_simple(int nf, int nconn, int d,
+              double v, double *K, double *C,
+              double *A, double *N,
+              double *Binv,
+              double *work, int lwork);
+
+
+/**
+ * Compute the mimetic inner products given a grid and cell-wise
+ * permeability tensors.
+ *
+ * This function applies mim_ip_simple() to all specified cells.
+ *
+ * @param[in]  ncells       Number of cells.
+ * @param[in]  d            Number of physical dimensions.
+ * @param[in]  max_ncf      Maximum number of connections (faces)
+ *                          of any individual cell.
+ * @param[in]  pconn        Start pointers of cell-to-face topology
+ *                          mapping.
+ * @param[in]  conn         Actual cell-to-face topology mapping.
+ * @param[in]  fneighbour   Face-to-cell mapping.
+ * @param[in]  fcentroid    Face centroids.
+ * @param[in]  fnormal      Face normals.
+ * @param[in]  farea        Face areas.
+ * @param[in]  ccentroid    Cell centroids.
+ * @param[in]  cvol         Cell volumes.
+ * @param[in]  perm         Cell permeability.
+ * @param[out] Binv         Inverse inner product result.  Must point
+ *                          to an array of size at least
+ *                          \f$\sum_c n_c^2\f$ when \f$n_c\f$ denotes
+ *                          the number of connections (faces) of
+ *                          cell \f$c\f$.
+ */
+void
+mim_ip_simple_all(int ncells, int d, int max_ncf,
+                  int *pconn, int *conn,
+                  int *fneighbour, double *fcentroid, double *fnormal,
+                  double *farea, double *ccentroid, double *cvol,
+                  double *perm, double *Binv);
+
+/**
+ * Compute local, static gravity pressure contributions to Darcy
+ * flow equation discretised using a mimetic finite-difference method.
+ *
+ * The pressure contribution of local face \f$i\f$ in cell \f$c\f$ is
+ * \f[
+ * \mathit{gpress}_{\mathit{pconn}_c + i} =
+ * \vec{g}\cdot (\Bar{x}_{\mathit{conn}_{\mathit{pconn}_c + i}}
+ * - \Bar{x}_c)
+ * \f]
+ *
+ * @param[in]  nc        Number of cells.
+ * @param[in]  d         Number of physcial dimensions.
+ * @param[in]  grav      Gravity vector.  Array of size @c d.
+ * @param[in]  pconn     Start pointers of cell-to-face topology
+ *                       mapping.
+ * @param[in]  conn      Actual cell-to-face topology mapping.
+ * @param[in]  fcentroid Face centroids.
+ * @param[in]  ccentroid Cell centroids.
+ * @param[out] gpress    Gravity pressure result.  Array of size
+ *                       at least <CODE>pconn[nc]</CODE>.
+ */
 void
 mim_ip_compute_gpress(int nc, int d, const double *grav,
                       const int *pconn, const int *conn,
                       const double *fcentroid, const double *ccentroid,
                       double *gpress);
 
-/* inv(B) <- \lambda_t(s)*inv(B)_0 */
+
+/**
+ * Incorporate effects of multiple phases in mimetic discretisation of
+ * flow equations.
+ *
+ * Specifically, update the (inverse) inner products \f$B^{-1}\f$
+ * previously computed using function mim_ip_linpress_exact() according
+ * to the rule
+ * \f[
+ * \Tilde{B}_c^{-1} = \frac{1}{\lambda_{T,c}} B_c^{-1},
+ * \quad i=0,\dots,\mathit{nc}-1
+ * \f]
+ * in which \f$B_c^{-1}\f$ denotes the result of mim_ip_linpress_exact()
+ * for cell \f$c\f$ and \f$\lambda_{T,c}\f$ denotes the total mobility
+ * of cell \f$c\f$.
+ *
+ * @param[in]  nc     Number of cells.
+ * @param[in]  pconn  Start pointers of cell-to-face topology
+ *                    mapping.
+ * @param[in]  totmob Total mobility for all cells.  Array of size @c nc.
+ * @param[in]  Binv0  Inverse inner product results for all cells.
+ * @param[out] Binv   Inverse inner product results incorporating
+ *                    effects of multiple fluid phases.
+ */
 void
 mim_ip_mobility_update(int nc, const int *pconn, const double *totmob,
                        const double *Binv0, double *Binv);
 
-/* G <- \sum_i \rho_i f_i(s) * G_0 */
+
+/**
+ * Incorporate effects of multiple fluid phases into existing, local,
+ * static mimetic discretisations of gravity pressure.
+ *
+ * Specifically, update the result of mim_ip_compute_gpress()
+ * according to the rule
+ * \f[
+ * \Tilde{G}_{\mathit{pconn}_c + i} = \omega_c\cdot
+ * G_{\mathit{pconn}_c + i}, \quad i=\mathit{pconn}_c, \dots,
+ * \mathit{pconn}_{c+1}-1, \quad c=0,\dots,\mathit{nc}-1
+ * \f]
+ * in which \f$\omega_c = (\sum_\alpha \lambda_{\alpha,c}
+ * \rho_\alpha)/\lambda_{T,c}\f$ and \f$\Tilde{G}\f$ denotes the result
+ * of function mim_ip_compute_gpress().
+ *
+ * @param[in]  nc      Number of cells.
+ * @param[in]  pconn   Start pointers of cell-to-face topology
+ *                     mapping.
+ * @param[in]  omega   Sum of phase densities weighted by
+ *                     fractional flow.
+ * @param[in]  gpress0 Result of mim_ip_compute_gpress().
+ * @param[out] gpress  Gravity pressure incorporating effects
+ *                     of multiple fluid phases.
+ */
 void
 mim_ip_density_update(int nc, const int *pconn, const double *omega,
                       const double *gpress0, double *gpress);