Add new functions to define subcase orderings.

[pspp-builds.git] / src / language / stats / roc.c

/* PSPP - a program for statistical analysis.
   Copyright (C) 2009 Free Software Foundation, Inc.

   This program is free software: you can redistribute it and/or modify
   it under the terms of the GNU General Public License as published by
   the Free Software Foundation, either version 3 of the License, or
   (at your option) any later version.

   This program is distributed in the hope that it will be useful,
   but WITHOUT ANY WARRANTY; without even the implied warranty of
   MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
   GNU General Public License for more details.

   You should have received a copy of the GNU General Public License
   along with this program.  If not, see <http://www.gnu.org/licenses/>. */

#include <config.h>

#include "roc.h"
#include <data/procedure.h>
#include <language/lexer/variable-parser.h>
#include <language/lexer/value-parser.h>
#include <language/lexer/lexer.h>

#include <data/casegrouper.h>
#include <data/casereader.h>
#include <data/casewriter.h>
#include <data/dictionary.h>
#include <data/format.h>
#include <math/sort.h>
#include <data/subcase.h>


#include <libpspp/misc.h>

#include <gsl/gsl_cdf.h>
#include <output/table.h>

#include <output/charts/plot-chart.h>
#include <output/charts/cartesian.h>

#include "gettext.h"
#define _(msgid) gettext (msgid)
#define N_(msgid) msgid

struct cmd_roc
{
  size_t n_vars;
  const struct variable **vars;

  struct variable *state_var ;
  union value state_value;

  /* Plot the roc curve */
  bool curve;
  /* Plot the reference line */
  bool reference;

  double ci;

  bool print_coords;
  bool print_se;
  bool bi_neg_exp; /* True iff the bi-negative exponential critieria
                      should be used */
  enum mv_class exclude;

  bool invert ; /* True iff a smaller test result variable indicates
                   a positive result */
};

static int run_roc (struct dataset *ds, struct cmd_roc *roc);

int
cmd_roc (struct lexer *lexer, struct dataset *ds)
{
  struct cmd_roc roc ;
  const struct dictionary *dict = dataset_dict (ds);

  roc.vars = NULL;
  roc.n_vars = 0;
  roc.print_se = false;
  roc.print_coords = false;
  roc.exclude = MV_ANY;
  roc.curve = true;
  roc.reference = false;
  roc.ci = 95;
  roc.bi_neg_exp = false;
  roc.invert = false;

  if (!parse_variables_const (lexer, dict, &roc.vars, &roc.n_vars,
                              PV_APPEND | PV_NO_DUPLICATE | PV_NUMERIC))
    return 2;

  if ( ! lex_force_match (lexer, T_BY))
    {
      return 2;
    }

  roc.state_var = parse_variable (lexer, dict);

  if ( !lex_force_match (lexer, '('))
    {
      return 2;
    }

  parse_value (lexer, &roc.state_value, var_get_width (roc.state_var));


  if ( !lex_force_match (lexer, ')'))
    {
      return 2;
    }


  while (lex_token (lexer) != '.')
    {
      lex_match (lexer, '/');
      if (lex_match_id (lexer, "MISSING"))
        {
          lex_match (lexer, '=');
          while (lex_token (lexer) != '.' && lex_token (lexer) != '/')
            {
              if (lex_match_id (lexer, "INCLUDE"))
                {
                  roc.exclude = MV_SYSTEM;
                }
              else if (lex_match_id (lexer, "EXCLUDE"))
                {
                  roc.exclude = MV_ANY;
                }
              else
                {
                  lex_error (lexer, NULL);
                  return 2;
                }
            }
        }
      else if (lex_match_id (lexer, "PLOT"))
        {
          lex_match (lexer, '=');
          if (lex_match_id (lexer, "CURVE"))
            {
              roc.curve = true;
              if (lex_match (lexer, '('))
                {
                  roc.reference = true;
                  lex_force_match_id (lexer, "REFERENCE");
                  lex_force_match (lexer, ')');
                }
            }
          else if (lex_match_id (lexer, "NONE"))
            {
              roc.curve = false;
            }
          else
            {
              lex_error (lexer, NULL);
              return 2;
            }
        }
      else if (lex_match_id (lexer, "PRINT"))
        {
          lex_match (lexer, '=');
          while (lex_token (lexer) != '.' && lex_token (lexer) != '/')
            {
              if (lex_match_id (lexer, "SE"))
                {
                  roc.print_se = true;
                }
              else if (lex_match_id (lexer, "COORDINATES"))
                {
                  roc.print_coords = true;
                }
              else
                {
                  lex_error (lexer, NULL);
                  return 2;
                }
            }
        }
      else if (lex_match_id (lexer, "CRITERIA"))
        {
          lex_match (lexer, '=');
          while (lex_token (lexer) != '.' && lex_token (lexer) != '/')
            {
              if (lex_match_id (lexer, "CUTOFF"))
                {
                  lex_force_match (lexer, '(');
                  if (lex_match_id (lexer, "INCLUDE"))
                    {
                      roc.exclude = MV_SYSTEM;
                    }
                  else if (lex_match_id (lexer, "EXCLUDE"))
                    {
                      roc.exclude = MV_USER | MV_SYSTEM;
                    }
                  else
                    {
                      lex_error (lexer, NULL);
                      return 2;
                    }
                  lex_force_match (lexer, ')');
                }
              else if (lex_match_id (lexer, "TESTPOS"))
                {
                  lex_force_match (lexer, '(');
                  if (lex_match_id (lexer, "LARGE"))
                    {
                      roc.invert = false;
                    }
                  else if (lex_match_id (lexer, "SMALL"))
                    {
                      roc.invert = true;
                    }
                  else
                    {
                      lex_error (lexer, NULL);
                      return 2;
                    }
                  lex_force_match (lexer, ')');
                }
              else if (lex_match_id (lexer, "CI"))
                {
                  lex_force_match (lexer, '(');
                  lex_force_num (lexer);
                  roc.ci = lex_number (lexer);
                  lex_get (lexer);
                  lex_force_match (lexer, ')');
                }
              else if (lex_match_id (lexer, "DISTRIBUTION"))
                {
                  lex_force_match (lexer, '(');
                  if (lex_match_id (lexer, "FREE"))
                    {
                      roc.bi_neg_exp = false;
                    }
                  else if (lex_match_id (lexer, "NEGEXPO"))
                    {
                      roc.bi_neg_exp = true;
                    }
                  else
                    {
                      lex_error (lexer, NULL);
                      return 2;
                    }
                  lex_force_match (lexer, ')');
                }
              else
                {
                  lex_error (lexer, NULL);
                  return 2;
                }
            }
        }
      else
        {
          lex_error (lexer, NULL);
          break;
        }
    }

  run_roc (ds, &roc);

  return 1;
}




static void
do_roc (struct cmd_roc *roc, struct casereader *group, struct dictionary *dict);


static int
run_roc (struct dataset *ds, struct cmd_roc *roc)
{
  struct dictionary *dict = dataset_dict (ds);
  bool ok;
  struct casereader *group;

  struct casegrouper *grouper = casegrouper_create_splits (proc_open (ds), dict);
  while (casegrouper_get_next_group (grouper, &group))
    {
      do_roc (roc, group, dataset_dict (ds));
    }
  ok = casegrouper_destroy (grouper);
  ok = proc_commit (ds) && ok;

  return ok;
}


static void
dump_casereader (struct casereader *reader)
{
  struct ccase *c;
  struct casereader *r = casereader_clone (reader);

  for ( ; (c = casereader_read (r) ); case_unref (c))
    {
      int i;
      for (i = 0 ; i < case_get_value_cnt (c); ++i)
        {
          printf ("%g ", case_data_idx (c, i)->f);
        }
      printf ("\n");
    }

  casereader_destroy (r);
}

static bool
match_positives (const struct ccase *c, void *aux)
{
  struct cmd_roc *roc = aux;

  return 0 == value_compare_3way (case_data (c, roc->state_var),
                                 &roc->state_value,
                                 var_get_width (roc->state_var));
}


#define VALUE  0
#define N_EQ   1
#define N_PRED 2

struct roc_state
{
  double auc;

  double n1;
  double n2;

  double q1hat;
  double q2hat;

  struct casewriter *cutpoint_wtr;
  struct casereader *cutpoint_rdr;
  double prev_result;
  double min;
  double max;
};



#define CUTPOINT 0
#define TP 1
#define FN 2
#define TN 3
#define FP 4


static struct casereader *
accumulate_counts (struct casereader *cutpoint_rdr, 
                   double result, double weight, 
                   bool (*pos_cond) (double, double),
                   int true_index, int false_index)
{
  const struct caseproto *proto = casereader_get_proto (cutpoint_rdr);
  struct casewriter *w =
    autopaging_writer_create (proto);
  struct casereader *r = casereader_clone (cutpoint_rdr);
  struct ccase *cpc;
  double prev_cp = SYSMIS;


  for ( ; (cpc = casereader_read (r) ); case_unref (cpc))
    {
      struct ccase *new_case;
      const double cp = case_data_idx (cpc, CUTPOINT)->f;

      /* We don't want duplicates here */
      if ( cp == prev_cp )
        continue;

      new_case = case_clone (cpc);

      if ( pos_cond (result, cp))
        {
          case_data_rw_idx (new_case, true_index)->f += weight;
        }
      else
        {
          case_data_rw_idx (new_case, false_index)->f += weight;
        }

      prev_cp = cp;

      casewriter_write (w, new_case);
    }
  casereader_destroy (r);

  return casewriter_make_reader (w);
}



static void output_roc (struct roc_state *rs, const struct cmd_roc *roc);


static struct casereader *
process_group (const struct variable *var, struct casereader *reader,
               bool (*pred) (double, double),
               const struct dictionary *dict,
               double *cc,
               struct casereader **cutpoint_rdr, 
               bool (*pos_cond) (double, double),
               int true_index,
               int false_index
               )
{
  const struct variable *w = dict_get_weight (dict);
  struct casereader *r1 =
    casereader_create_distinct (sort_execute_1var (reader, var), var, w);

  const int weight_idx  = w ? var_get_case_index (w) :
    caseproto_get_n_widths (casereader_get_proto (r1)) - 1;
  
  struct ccase *c1;

  struct casereader *rclone = casereader_clone (r1);
  struct casewriter *wtr;
  struct caseproto *proto = caseproto_create ();

  proto = caseproto_add_width (proto, 0);
  proto = caseproto_add_width (proto, 0);
  proto = caseproto_add_width (proto, 0);

  wtr = autopaging_writer_create (proto);  

  *cc = 0;

  for ( ; (c1 = casereader_read (r1) ); case_unref (c1))
    {
      struct ccase *c2;
      struct casereader *r2 = casereader_clone (rclone);

      const double weight1 = case_data_idx (c1, weight_idx)->f;
      const double d1 = case_data (c1, var)->f;
      double n_eq = 0.0;
      double n_pred = 0.0;

      *cutpoint_rdr = accumulate_counts (*cutpoint_rdr, d1, weight1,
                                        pos_cond,
                                        true_index, false_index);

      struct ccase *new_case = case_create (proto);

      *cc += weight1;

      for ( ; (c2 = casereader_read (r2) ); case_unref (c2))
        {
          const double d2 = case_data (c2, var)->f;
          const double weight2 = case_data_idx (c2, weight_idx)->f;

          if ( d1 == d2 )
            {
              n_eq += weight2;
              continue;
            }
          else  if ( pred (d2, d1))
            {
              n_pred += weight2;
            }
        }

      case_data_rw_idx (new_case, VALUE)->f = d1;
      case_data_rw_idx (new_case, N_EQ)->f = n_eq;
      case_data_rw_idx (new_case, N_PRED)->f = n_pred;

      casewriter_write (wtr, new_case);

      casereader_destroy (r2);
    }

  casereader_destroy (r1);
  casereader_destroy (rclone);

  return casewriter_make_reader (wtr);
}

static bool
gt (double d1, double d2)
{
  return d1 > d2;
}


static bool
ge (double d1, double d2)
{
  return d1 > d2;
}

static bool
lt (double d1, double d2)
{
  return d1 < d2;
}

static struct casereader *
process_positive_group (const struct variable *var, struct casereader *reader,
                        const struct dictionary *dict,
                        struct roc_state *rs)
{
  return process_group (var, reader, gt, dict, &rs->n1,
                        &rs->cutpoint_rdr,
                        ge,
                        TP, FN);
}


static struct casereader *
process_negative_group (const struct variable *var, struct casereader *reader,
                        const struct dictionary *dict,
                        struct roc_state *rs)
{
  return process_group (var, reader, lt, dict, &rs->n2,
                        &rs->cutpoint_rdr,
                        lt,
                        TN, FP);
}




static void
append_cutpoint (struct casewriter *writer, double cutpoint)
{
  struct ccase *cc = case_create (casewriter_get_proto (writer));

  case_data_rw_idx (cc, CUTPOINT)->f = cutpoint;
  case_data_rw_idx (cc, TP)->f = 0;
  case_data_rw_idx (cc, FN)->f = 0;
  case_data_rw_idx (cc, TN)->f = 0;
  case_data_rw_idx (cc, FP)->f = 0;


  casewriter_write (writer, cc);
}


static void
do_roc (struct cmd_roc *roc, struct casereader *input, struct dictionary *dict)
{
  int i;

  struct roc_state *rs = xcalloc (roc->n_vars, sizeof *rs);

  struct casewriter *neg_wtr = autopaging_writer_create (casereader_get_proto (input));

  struct casereader *negatives = NULL;
  struct casereader *positives = NULL;


  /* Prepare the cutpoints */
  {
    struct casereader *r = casereader_clone (input);
    struct ccase *c;
    struct caseproto *proto = caseproto_create ();

    struct subcase ordering;
    subcase_init (&ordering, CUTPOINT, 0, SC_ASCEND);


    proto = caseproto_add_width (proto, 0); /* cutpoint */
    proto = caseproto_add_width (proto, 0); /* TP */
    proto = caseproto_add_width (proto, 0); /* FN */
    proto = caseproto_add_width (proto, 0); /* TN */
    proto = caseproto_add_width (proto, 0); /* FP */


    for (i = 0 ; i < roc->n_vars; ++i)
      {
        rs[i].cutpoint_wtr = sort_create_writer (&ordering, proto);
        rs[i].prev_result = SYSMIS;
        rs[i].max = -DBL_MAX;
        rs[i].min = DBL_MAX;
      }

    for (; (c = casereader_read (r)) != NULL; case_unref (c))
      {
        const double weight = dict_get_case_weight (dict, c, NULL);
        for (i = 0 ; i < roc->n_vars; ++i)
          {
            const double result = case_data (c, roc->vars[i])->f;

            minimize (&rs[i].min, result);
            maximize (&rs[i].max, result);

            if ( rs[i].prev_result != SYSMIS && rs[i].prev_result != result )
              {
                const double mean = (result + rs[i].prev_result ) / 2.0;
                append_cutpoint (rs[i].cutpoint_wtr, mean);
              }

            rs[i].prev_result = result;
          }
      }
    casereader_destroy (r);


    /* Append the min and max cutpoints */
    for (i = 0 ; i < roc->n_vars; ++i)
      {
        append_cutpoint (rs[i].cutpoint_wtr, rs[i].min - 1);
        append_cutpoint (rs[i].cutpoint_wtr, rs[i].max + 1);

        rs[i].cutpoint_rdr = casewriter_make_reader (rs[i].cutpoint_wtr);
      }
  }

 positives = 
    casereader_create_filter_func (input,
                                   match_positives,
                                   NULL,
                                   roc,
                                   neg_wtr);


  for (i = 0 ; i < roc->n_vars; ++i)
    {
      struct ccase *cpos;
      struct casereader *n_neg ;
      const struct variable *var = roc->vars[i];

      struct casereader *neg ;
      struct casereader *pos = casereader_clone (positives);

      struct casereader *n_pos =
        process_positive_group (var, pos, dict, &rs[i]);

      if ( negatives == NULL)
        {
          negatives = casewriter_make_reader (neg_wtr);
        }

      neg = casereader_clone (negatives);

      n_neg = process_negative_group (var, neg, dict, &rs[i]);


      /* Simple join on VALUE */
      for ( ; (cpos = casereader_read (n_pos) ); case_unref (cpos))
        {
          struct ccase *cneg = NULL;
          double dneg = -DBL_MAX;
          const double dpos = case_data_idx (cpos, VALUE)->f;
          while (dneg < dpos)
            {
              if ( cneg )
                case_unref (cneg);

              cneg = casereader_read (n_neg);
              if ( ! cneg )
                break;
              dneg = case_data_idx (cneg, VALUE)->f;
            }
        
          if ( dpos == dneg )
            {
              double n_pos_eq = case_data_idx (cpos, N_EQ)->f;
              double n_neg_eq = case_data_idx (cneg, N_EQ)->f;
              double n_pos_gt = case_data_idx (cpos, N_PRED)->f;
              double n_neg_lt = case_data_idx (cneg, N_PRED)->f;

              rs[i].auc += n_pos_gt * n_neg_eq + (n_pos_eq * n_neg_eq) / 2.0;
              rs[i].q1hat +=
                n_neg_eq * ( pow2 (n_pos_gt) + n_pos_gt * n_pos_eq + pow2 (n_pos_eq) / 3.0);
              rs[i].q2hat +=
                n_pos_eq * ( pow2 (n_neg_lt) + n_neg_lt * n_neg_eq + pow2 (n_neg_eq) / 3.0);
            }

          if ( cneg )
            case_unref (cneg);
        }

      rs[i].auc /=  rs[i].n1 * rs[i].n2; 
      if ( roc->invert ) 
        rs[i].auc = 1 - rs[i].auc;

      if ( roc->bi_neg_exp )
        {
          rs[i].q1hat = rs[i].auc / ( 2 - rs[i].auc);
          rs[i].q2hat = 2 * pow2 (rs[i].auc) / ( 1 + rs[i].auc);
        }
      else
        {
          rs[i].q1hat /= rs[i].n2 * pow2 (rs[i].n1);
          rs[i].q2hat /= rs[i].n1 * pow2 (rs[i].n2);
        }
    }

  casereader_destroy (positives);
  casereader_destroy (negatives);

  output_roc (rs, roc);

  free (rs);
}




static void
show_auc  (struct roc_state *rs, const struct cmd_roc *roc)
{
  int i;
  const int n_fields = roc->print_se ? 5 : 1;
  const int n_cols = roc->n_vars > 1 ? n_fields + 1: n_fields;
  const int n_rows = 2 + roc->n_vars;
  struct tab_table *tbl = tab_create (n_cols, n_rows, 0);

  if ( roc->n_vars > 1)
    tab_title (tbl, _("Area Under the Curve"));
  else
    tab_title (tbl, _("Area Under the Curve (%s)"), var_to_string (roc->vars[0]));

  tab_headers (tbl, n_cols - n_fields, 0, 1, 0);

  tab_dim (tbl, tab_natural_dimensions, NULL);

  tab_text (tbl, n_cols - n_fields, 1, TAT_TITLE, _("Area"));

  tab_hline (tbl, TAL_2, 0, n_cols - 1, 2);

  tab_box (tbl,
           TAL_2, TAL_2,
           -1, TAL_1,
           0, 0,
           n_cols - 1,
           n_rows - 1);

  if ( roc->print_se )
    {
      tab_text (tbl, n_cols - 4, 1, TAT_TITLE, _("Std. Error"));
      tab_text (tbl, n_cols - 3, 1, TAT_TITLE, _("Asymptotic Sig."));

      tab_text (tbl, n_cols - 2, 1, TAT_TITLE, _("Lower Bound"));
      tab_text (tbl, n_cols - 1, 1, TAT_TITLE, _("Upper Bound"));

      tab_joint_text (tbl, n_cols - 2, 0, 4, 0,
                      TAT_TITLE | TAB_CENTER | TAT_PRINTF,
                      _("Asymp. %g%% Confidence Interval"), roc->ci);
      tab_vline (tbl, 0, n_cols - 1, 0, 0);
      tab_hline (tbl, TAL_1, n_cols - 2, n_cols - 1, 1);
    }

  if ( roc->n_vars > 1)
    tab_text (tbl, 0, 1, TAT_TITLE, _("Variable under test"));

  if ( roc->n_vars > 1)
    tab_vline (tbl, TAL_2, 1, 0, n_rows - 1);


  for ( i = 0 ; i < roc->n_vars ; ++i )
    {
      tab_text (tbl, 0, 2 + i, TAT_TITLE, var_to_string (roc->vars[i]));

      tab_double (tbl, n_cols - n_fields, 2 + i, 0, rs[i].auc, NULL);

      if ( roc->print_se )
        {
          double se ;
          const double sd_0_5 = sqrt ((rs[i].n1 + rs[i].n2 + 1) /
                                      (12 * rs[i].n1 * rs[i].n2));
          double ci ;
          double yy ;

          se = rs[i].auc * (1 - rs[i].auc) + (rs[i].n1 - 1) * (rs[i].q1hat - pow2 (rs[i].auc)) +
            (rs[i].n2 - 1) * (rs[i].q2hat - pow2 (rs[i].auc));

          se /= rs[i].n1 * rs[i].n2;

          se = sqrt (se);

          tab_double (tbl, n_cols - 4, 2 + i, 0,
                      se,
                      NULL);

          ci = 1 - roc->ci / 100.0;
          yy = gsl_cdf_gaussian_Qinv (ci, se) ;

          tab_double (tbl, n_cols - 2, 2 + i, 0,
                      rs[i].auc - yy,
                      NULL);

          tab_double (tbl, n_cols - 1, 2 + i, 0,
                      rs[i].auc + yy,
                      NULL);

          tab_double (tbl, n_cols - 3, 2 + i, 0,
                      2.0 * gsl_cdf_ugaussian_Q (fabs ((rs[i].auc - 0.5 ) / sd_0_5)),
                      NULL);
        }
    }

  tab_submit (tbl);
}


static void
show_summary (const struct cmd_roc *roc)
{
  const int n_cols = 3;
  const int n_rows = 4;
  struct tab_table *tbl = tab_create (n_cols, n_rows, 0);

  tab_title (tbl, _("Case Summary"));

  tab_headers (tbl, 1, 0, 2, 0);

  tab_dim (tbl, tab_natural_dimensions, NULL);

  tab_box (tbl,
           TAL_2, TAL_2,
           -1, -1,
           0, 0,
           n_cols - 1,
           n_rows - 1);

  tab_hline (tbl, TAL_2, 0, n_cols - 1, 2);
  tab_vline (tbl, TAL_2, 1, 0, n_rows - 1);


  tab_hline (tbl, TAL_2, 1, n_cols - 1, 1);
  tab_vline (tbl, TAL_1, 2, 1, n_rows - 1);


  tab_text (tbl, 0, 1, TAT_TITLE | TAB_LEFT, var_to_string (roc->state_var));
  tab_text (tbl, 1, 1, TAT_TITLE, _("Unweighted"));
  tab_text (tbl, 2, 1, TAT_TITLE, _("Weighted"));

  tab_joint_text (tbl, 1, 0, 2, 0,
                  TAT_TITLE | TAB_CENTER,
                  _("Valid N (listwise)"));


  tab_text (tbl, 0, 2, TAB_LEFT, _("Positive"));
  tab_text (tbl, 0, 3, TAB_LEFT, _("Negative"));


#if 0
  tab_double (tbl, 1, 2, 0, roc->pos, &F_8_0);
  tab_double (tbl, 1, 3, 0, roc->neg, &F_8_0);

  tab_double (tbl, 2, 2, 0, roc->pos_weighted, 0);
  tab_double (tbl, 2, 3, 0, roc->neg_weighted, 0);
#endif

  tab_submit (tbl);
}


static void
show_coords (struct roc_state *rs, const struct cmd_roc *roc)
{
  int x = 1;
  int i;
  const int n_cols = roc->n_vars > 1 ? 4 : 3;
  int n_rows = 1;
  struct tab_table *tbl ;

  for (i = 0; i < roc->n_vars; ++i)
    n_rows += casereader_count_cases (rs[i].cutpoint_rdr);

  tbl = tab_create (n_cols, n_rows, 0);

  if ( roc->n_vars > 1)
    tab_title (tbl, _("Coordinates of the Curve"));
  else
    tab_title (tbl, _("Coordinates of the Curve (%s)"), var_to_string (roc->vars[0]));


  tab_headers (tbl, 1, 0, 1, 0);

  tab_dim (tbl, tab_natural_dimensions, NULL);

  tab_hline (tbl, TAL_2, 0, n_cols - 1, 1);

  if ( roc->n_vars > 1)
    tab_text (tbl, 0, 0, TAT_TITLE, _("Test variable"));

  tab_text (tbl, n_cols - 3, 0, TAT_TITLE, _("Positive if greater than or equal to"));
  tab_text (tbl, n_cols - 2, 0, TAT_TITLE, _("Sensitivity"));
  tab_text (tbl, n_cols - 1, 0, TAT_TITLE, _("1 - Specificity"));

  tab_box (tbl,
           TAL_2, TAL_2,
           -1, TAL_1,
           0, 0,
           n_cols - 1,
           n_rows - 1);

  if ( roc->n_vars > 1)
    tab_vline (tbl, TAL_2, 1, 0, n_rows - 1);

  for (i = 0; i < roc->n_vars; ++i)
    {
      struct ccase *cc;
      struct casereader *r = casereader_clone (rs[i].cutpoint_rdr);

      if ( roc->n_vars > 1)
        tab_text (tbl, 0, x, TAT_TITLE, var_to_string (roc->vars[i]));

      if ( i > 0)
        tab_hline (tbl, TAL_1, 0, n_cols - 1, x);


      for (; (cc = casereader_read (r)) != NULL;
           case_unref (cc), x++)
        {
          const double se = case_data_idx (cc, TP)->f /
            (
             case_data_idx (cc, TP)->f
             +
             case_data_idx (cc, FN)->f
             );

          const double sp = case_data_idx (cc, TN)->f /
            (
             case_data_idx (cc, TN)->f
             +
             case_data_idx (cc, FP)->f
             );

          tab_double (tbl, n_cols - 3, x, 0, case_data_idx (cc, CUTPOINT)->f,
                      var_get_print_format (roc->vars[i]));

          tab_double (tbl, n_cols - 2, x, 0, se, NULL);
          tab_double (tbl, n_cols - 1, x, 0, 1 - sp, NULL);
        }

      casereader_destroy (r);
    }

  tab_submit (tbl);
}


static void
draw_roc (struct roc_state *rs, const struct cmd_roc *roc)
{
  int i;

  struct chart *roc_chart = chart_create ();

  chart_write_title (roc_chart, _("ROC Curve"));
  chart_write_xlabel (roc_chart, _("1 - Specificity"));
  chart_write_ylabel (roc_chart, _("Sensitivity"));

  chart_write_xscale (roc_chart, 0, 1, 5);
  chart_write_yscale (roc_chart, 0, 1, 5);

  if ( roc->reference )
    {
      chart_line (roc_chart, 1.0, 0,
                  0.0, 1.0,
                  CHART_DIM_X);
    }

  for (i = 0; i < roc->n_vars; ++i)
    {
      struct ccase *cc;
      struct casereader *r = casereader_clone (rs[i].cutpoint_rdr);

      chart_vector_start (roc_chart, var_get_name (roc->vars[i]));
      for (; (cc = casereader_read (r)) != NULL;
           case_unref (cc))
        {
          double se = case_data_idx (cc, TP)->f;
          double sp = case_data_idx (cc, TN)->f;

          se /= case_data_idx (cc, FN)->f +
            case_data_idx (cc, TP)->f ;

          sp /= case_data_idx (cc, TN)->f +
            case_data_idx (cc, FP)->f ;

          chart_vector (roc_chart, 1 - sp, se);
        }
      chart_vector_end (roc_chart);
      casereader_destroy (r);
    }

  chart_write_legend (roc_chart);

  chart_submit (roc_chart);
}


static void
output_roc (struct roc_state *rs, const struct cmd_roc *roc)
{
  show_summary (roc);

  if ( roc->curve )
    draw_roc (rs, roc);

  show_auc (rs, roc);


  if ( roc->print_coords )
    show_coords (rs, roc);
}