You should have received a copy of the GNU General Public License
along with this program; if not, write to the Free Software
- Foundation, Inc., 59 Temple Place - Suite 330, Boston, MA
- 02111-1307, USA. */
+ Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA
+ 02110-1301, USA. */
#include <config.h>
-#include <assert.h>
+#include "error.h"
#include <stdlib.h>
#include <ctype.h>
#include <float.h>
#include "algorithm.h"
#include "alloc.h"
+#include "case.h"
#include "command.h"
#include "data-in.h"
-#include "dfm.h"
+#include "dfm-read.h"
+#include "dictionary.h"
#include "error.h"
#include "file-handle.h"
#include "lexer.h"
#include "var.h"
#include "vfm.h"
+#include "gettext.h"
+#define _(msgid) gettext (msgid)
+
#include "debug-print.h"
/* FIXME: /N subcommand not implemented. It should be pretty simple,
too. */
+/* Different types of variables for MATRIX DATA procedure. Order is
+ important: these are used for sort keys. */
+enum
+ {
+ MXD_SPLIT, /* SPLIT FILE variables. */
+ MXD_ROWTYPE, /* ROWTYPE_. */
+ MXD_FACTOR, /* Factor variables. */
+ MXD_VARNAME, /* VARNAME_. */
+ MXD_CONTINUOUS, /* Continuous variables. */
+
+ MXD_COUNT
+ };
+
/* Format type enums. */
enum format_type
{
struct matrix_data_pgm
{
struct pool *container; /* Arena used for all allocations. */
- struct file_handle *data_file; /* The data file to be read. */
+ struct dfm_reader *reader; /* Data file to read. */
/* Format. */
enum format_type fmt; /* LIST or FREE. */
struct variable *single_split; /* Single SPLIT FILE variable. */
/* Factor variables. */
- int n_factors; /* Number of factor variables. */
+ size_t n_factors; /* Number of factor variables. */
struct variable **factors; /* Factor variables. */
int is_per_factor[PROX + 1]; /* Is there per-factor data? */
first continuous variable. */
};
+/* Auxiliary data attached to MATRIX DATA variables. */
+struct mxd_var
+ {
+ int var_type; /* Variable type. */
+ int sub_type; /* Subtype. */
+ };
+
static const struct case_source_class matrix_data_with_rowtype_source_class;
static const struct case_source_class matrix_data_without_rowtype_source_class;
-static int compare_variables_by_mxd_vartype (const void *pa,
+static int compare_variables_by_mxd_var_type (const void *pa,
const void *pb);
static void read_matrices_without_rowtype (struct matrix_data_pgm *);
static void read_matrices_with_rowtype (struct matrix_data_pgm *);
static int string_to_content_type (char *, int *);
-
-#if DEBUGGING
-static void debug_print (void);
-#endif
+static void attach_mxd_aux (struct variable *, int var_type, int sub_type);
int
cmd_matrix_data (void)
{
struct pool *pool;
struct matrix_data_pgm *mx;
-
+ struct file_handle *fh = NULL;
+
unsigned seen = 0;
- lex_match_id ("MATRIX");
- lex_match_id ("DATA");
-
discard_variables ();
pool = pool_create ();
mx = pool_alloc (pool, sizeof *mx);
mx->container = pool;
- mx->data_file = inline_file;
+ mx->reader = NULL;
mx->fmt = LIST;
mx->section = LOWER;
mx->diag = DIAGONAL;
if (lex_match_id ("VARIABLES"))
{
char **v;
- int nv;
+ size_t nv;
if (seen & 1)
{
goto lossage;
{
- int i;
+ size_t i;
for (i = 0; i < nv; i++)
- if (!strcmp (v[i], "VARNAME_"))
+ if (!strcasecmp (v[i], "VARNAME_"))
{
msg (SE, _("VARNAME_ cannot be explicitly specified on "
"VARIABLES."));
}
{
- int i;
+ size_t i;
for (i = 0; i < nv; i++)
{
struct variable *new_var;
- if (strcmp (v[i], "ROWTYPE_"))
+ if (strcasecmp (v[i], "ROWTYPE_"))
{
new_var = dict_create_var_assert (default_dict, v[i], 0);
- new_var->p.mxd.vartype = MXD_CONTINUOUS;
- new_var->p.mxd.subtype = i;
- }
+ attach_mxd_aux (new_var, MXD_CONTINUOUS, i);
+ }
else
mx->explicit_rowtype = 1;
free (v[i]);
free (v);
}
- {
- mx->rowtype_ = dict_create_var_assert (default_dict,
- "ROWTYPE_", 8);
- mx->rowtype_->p.mxd.vartype = MXD_ROWTYPE;
- mx->rowtype_->p.mxd.subtype = 0;
- }
+ mx->rowtype_ = dict_create_var_assert (default_dict,
+ "ROWTYPE_", 8);
+ attach_mxd_aux (mx->rowtype_, MXD_ROWTYPE, 0);
}
else if (lex_match_id ("FILE"))
{
lex_match ('=');
- mx->data_file = fh_parse_file_handle ();
- if (mx->data_file == NULL)
+ fh = fh_parse ();
+ if (fh == NULL)
goto lossage;
}
else if (lex_match_id ("FORMAT"))
if (dict_lookup_var (default_dict, tokid) == NULL
&& (lex_look_ahead () == '.' || lex_look_ahead () == '/'))
{
- if (!strcmp (tokid, "ROWTYPE_") || !strcmp (tokid, "VARNAME_"))
+ if (!strcasecmp (tokid, "ROWTYPE_")
+ || !strcasecmp (tokid, "VARNAME_"))
{
msg (SE, _("Split variable may not be named ROWTYPE_ "
"or VARNAME_."));
mx->single_split = dict_create_var_assert (default_dict,
tokid, 0);
+ attach_mxd_aux (mx->single_split, MXD_CONTINUOUS, 0);
lex_get ();
- mx->single_split->p.mxd.vartype = MXD_CONTINUOUS;
-
dict_set_split_vars (default_dict, &mx->single_split, 1);
}
else
{
struct variable **split;
- int n;
+ size_t n;
if (!parse_variables (default_dict, &split, &n, PV_NO_DUPLICATE))
goto lossage;
for (i = 0; i < split_cnt; i++)
{
- if (split[i]->p.mxd.vartype != MXD_CONTINUOUS)
+ struct mxd_var *mv = split[i]->aux;
+ assert (mv != NULL);
+ if (mv->var_type != MXD_CONTINUOUS)
{
msg (SE, _("Split variable %s is already another type."),
tokid);
goto lossage;
}
- split[i]->p.mxd.vartype = MXD_SPLIT;
- split[i]->p.mxd.subtype = i;
+ var_clear_aux (split[i]);
+ attach_mxd_aux (split[i], MXD_SPLIT, i);
}
}
}
}
seen |= 4;
- if (!parse_variables (default_dict, &mx->factors, &mx->n_factors, PV_NONE))
+ if (!parse_variables (default_dict, &mx->factors, &mx->n_factors,
+ PV_NONE))
goto lossage;
{
- int i;
+ size_t i;
for (i = 0; i < mx->n_factors; i++)
{
- if (mx->factors[i]->p.mxd.vartype != MXD_CONTINUOUS)
+ struct variable *v = mx->factors[i];
+ struct mxd_var *mv = v->aux;
+ assert (mv != NULL);
+ if (mv->var_type != MXD_CONTINUOUS)
{
msg (SE, _("Factor variable %s is already another type."),
tokid);
goto lossage;
}
- mx->factors[i]->p.mxd.vartype = MXD_FACTOR;
- mx->factors[i]->p.mxd.subtype = i;
+ var_clear_aux (v);
+ attach_mxd_aux (v, MXD_FACTOR, i);
}
}
}
goto lossage;
}
- if (!lex_integer_p () || lex_integer () < 1)
+ if (!lex_is_integer () || lex_integer () < 1)
{
lex_error (_("expecting positive integer"));
goto lossage;
goto lossage;
}
- if (!lex_integer_p () || lex_integer () < 1)
+ if (!lex_is_integer () || lex_integer () < 1)
{
lex_error (_("expecting positive integer"));
goto lossage;
}
/* Create VARNAME_. */
- {
- mx->varname_ = dict_create_var_assert (default_dict, "VARNAME_", 8);
- mx->varname_->p.mxd.vartype = MXD_VARNAME;
- mx->varname_->p.mxd.subtype = 0;
- }
+ mx->varname_ = dict_create_var_assert (default_dict, "VARNAME_", 8);
+ attach_mxd_aux (mx->varname_, MXD_VARNAME, 0);
/* Sort the dictionary variables into the desired order for the
system file output. */
size_t nv;
dict_get_vars (default_dict, &v, &nv, 0);
- qsort (v, nv, sizeof *v, compare_variables_by_mxd_vartype);
+ qsort (v, nv, sizeof *v, compare_variables_by_mxd_var_type);
dict_reorder_vars (default_dict, v, nv);
free (v);
}
for (i = 0; i < dict_get_var_cnt (default_dict); i++)
{
struct variable *v = dict_get_var (default_dict, i);
- int type = v->p.mxd.vartype;
+ struct mxd_var *mv = v->aux;
+ int type = mv->var_type;
assert (type >= 0 && type < MXD_COUNT);
v->print = v->write = fmt_tab[type];
goto lossage;
}
-#if DEBUGGING
- debug_print ();
-#endif
+ mx->reader = dfm_open_reader (fh);
+ if (mx->reader == NULL)
+ goto lossage;
if (mx->explicit_rowtype)
read_matrices_with_rowtype (mx);
else
read_matrices_without_rowtype (mx);
+ dfm_close_reader (mx->reader);
+
pool_destroy (mx->container);
return CMD_SUCCESS;
};
for (tp = tab; tp->value != -1; tp++)
- if (!strcmp (s, tp->string))
+ if (!strcasecmp (s, tp->string))
{
if (collide)
*collide = tp->collide;
return -1;
}
-/* Compare two variables using p.mxd.vartype and p.mxd.subtype
+/* Compare two variables using p.mxd.var_type and p.mxd.sub_type
fields. */
static int
-compare_variables_by_mxd_vartype (const void *a_, const void *b_)
+compare_variables_by_mxd_var_type (const void *a_, const void *b_)
{
struct variable *const *pa = a_;
struct variable *const *pb = b_;
- const struct matrix_data_proc *a = &(*pa)->p.mxd;
- const struct matrix_data_proc *b = &(*pb)->p.mxd;
-
- if (a->vartype != b->vartype)
- return a->vartype > b->vartype ? 1 : -1;
+ const struct mxd_var *a = (*pa)->aux;
+ const struct mxd_var *b = (*pb)->aux;
+
+ if (a->var_type != b->var_type)
+ return a->var_type > b->var_type ? 1 : -1;
else
- return a->subtype < b->subtype ? -1 : a->subtype > b->subtype;
+ return a->sub_type < b->sub_type ? -1 : a->sub_type > b->sub_type;
}
-#if DEBUGGING
-/* Print out the command as input. */
+/* Attaches a struct mxd_var with the specific member values to
+ V. */
static void
-debug_print (void)
+attach_mxd_aux (struct variable *v, int var_type, int sub_type)
{
- printf ("MATRIX DATA\n\t/VARIABLES=");
+ struct mxd_var *mv;
- {
- int i;
-
- for (i = 0; i < default_dict.nvar; i++)
- printf ("%s ", default_dict.var[i]->name);
- }
- printf ("\n");
-
- printf ("\t/FORMAT=");
- if (fmt == LIST)
- printf ("LIST");
- else if (fmt == FREE)
- printf ("FREE");
- else
- assert (0);
- if (section == LOWER)
- printf (" LOWER");
- else if (section == UPPER)
- printf (" UPPER");
- else if (section == FULL)
- printf (" FULL");
- else
- assert (0);
- if (diag == DIAGONAL)
- printf (" DIAGONAL\n");
- else if (diag == NODIAGONAL)
- printf (" NODIAGONAL\n");
- else
- assert (0);
-
- if (dict_get_split_cnt (default_dict) != 0)
- {
- int i;
-
- printf ("\t/SPLIT=");
- for (i = 0; i < dict_get_split_cnt (default_dict); i++)
- printf ("%s ", dict_get_split_vars (default_dict)[i]->name);
- if (single_split)
- printf ("\t/* single split");
- printf ("\n");
- }
-
- if (n_factors)
- {
- int i;
-
- printf ("\t/FACTORS=");
- for (i = 0; i < n_factors; i++)
- printf ("%s ", factors[i]->name);
- printf ("\n");
- }
-
- if (cells != -1)
- printf ("\t/CELLS=%d\n", cells);
-
- if (mx->pop_n != -1)
- printf ("\t/N=%d\n", mx->pop_n);
-
- if (mx->n_contents)
- {
- int i;
- int space = 0;
-
- printf ("\t/CONTENTS=");
- for (i = 0; i < mx->n_contents; i++)
- {
- if (mx->contents[i] == LPAREN)
- {
- if (space)
- printf (" ");
- printf ("(");
- space = 0;
- }
- else if (mx->contents[i] == RPAREN)
- {
- printf (")");
- space = 1;
- }
- else
- {
-
- assert (mx->contents[i] >= 0 && mx->contents[i] <= PROX);
- if (space)
- printf (" ");
- printf ("%s", content_names[mx->contents[i]]);
- space = 1;
- }
- }
- printf ("\n");
- }
+ assert (v->aux == NULL);
+ mv = xmalloc (sizeof *mv);
+ mv->var_type = var_type;
+ mv->sub_type = sub_type;
+ var_attach_aux (v, mv, var_dtor_free);
}
-#endif /* DEBUGGING */
\f
/* Matrix tokenizer. */
int length; /* MSTR: tokstr length. */
};
-static int mget_token (struct matrix_token *, struct file_handle *);
+static int mget_token (struct matrix_token *, struct dfm_reader *);
#if DEBUGGING
-#define mget_token(TOKEN, HANDLE) mget_token_dump(TOKEN, HANDLE)
+#define mget_token(TOKEN, READER) mget_token_dump(TOKEN, READER)
static void
mdump_token (const struct matrix_token *token)
}
static int
-mget_token_dump (struct matrix_token *token, struct file_handle *data_file)
+mget_token_dump (struct matrix_token *token, struct dfm_reader *reader)
{
- int result = (mget_token) (token, data_file);
+ int result = (mget_token) (token, reader);
mdump_token (token);
return result;
}
#endif
-/* Return the current position in DATA_FILE. */
+/* Return the current position in READER. */
static const char *
-context (struct file_handle *data_file)
+context (struct dfm_reader *reader)
{
static char buf[32];
- int len;
- char *p = dfm_get_record (data_file, &len);
-
- if (!p || !len)
- strcpy (buf, "at end of line");
- else
+
+ if (dfm_eof (reader))
+ strcpy (buf, "at end of file");
+ else
{
- char *cp = buf;
- int n_copy = min (10, len);
- cp = stpcpy (buf, "before `");
- while (n_copy && isspace ((unsigned char) *p))
- p++, n_copy++;
- while (n_copy && !isspace ((unsigned char) *p))
- *cp++ = *p++, n_copy--;
- *cp++ = '\'';
- *cp = 0;
+ struct fixed_string line;
+ const char *sp;
+
+ dfm_get_record (reader, &line);
+ sp = ls_c_str (&line);
+ while (sp < ls_end (&line) && isspace ((unsigned char) *sp))
+ sp++;
+ if (sp >= ls_end (&line))
+ strcpy (buf, "at end of line");
+ else
+ {
+ char *dp;
+ size_t copy_cnt = 0;
+
+ dp = stpcpy (buf, "before `");
+ while (sp < ls_end (&line) && !isspace ((unsigned char) *sp)
+ && copy_cnt < 10)
+ {
+ *dp++ = *sp++;
+ copy_cnt++;
+ }
+ strcpy (dp, "'");
+ }
}
return buf;
/* Is there at least one token left in the data file? */
static int
-another_token (struct file_handle *data_file)
+another_token (struct dfm_reader *reader)
{
- char *cp, *ep;
- int len;
-
for (;;)
{
- cp = dfm_get_record (data_file, &len);
- if (!cp)
- return 0;
+ struct fixed_string line;
+ const char *cp;
+
+ if (dfm_eof (reader))
+ return 0;
+ dfm_get_record (reader, &line);
- ep = cp + len;
- while (isspace ((unsigned char) *cp) && cp < ep)
+ cp = ls_c_str (&line);
+ while (isspace ((unsigned char) *cp) && cp < ls_end (&line))
cp++;
- if (cp < ep)
- break;
+ if (cp < ls_end (&line))
+ {
+ dfm_forward_columns (reader, cp - ls_c_str (&line));
+ return 1;
+ }
- dfm_fwd_record (data_file);
+ dfm_forward_record (reader);
}
-
- dfm_set_record (data_file, cp);
-
- return 1;
}
-/* Parse a MATRIX DATA token from mx->data_file into TOKEN. */
+/* Parse a MATRIX DATA token from READER into TOKEN. */
static int
-(mget_token) (struct matrix_token *token, struct file_handle *data_file)
+(mget_token) (struct matrix_token *token, struct dfm_reader *reader)
{
- char *cp, *ep;
- int len;
+ struct fixed_string line;
int first_column;
-
- for (;;)
- {
- cp = dfm_get_record (data_file, &len);
- if (!cp)
- return 0;
-
- ep = cp + len;
- while (isspace ((unsigned char) *cp) && cp < ep)
- cp++;
+ char *cp;
- if (cp < ep)
- break;
+ if (!another_token (reader))
+ return 0;
- dfm_fwd_record (data_file);
- }
-
- dfm_set_record (data_file, cp);
- first_column = dfm_get_cur_col (data_file) + 1;
+ dfm_get_record (reader, &line);
+ first_column = dfm_column_start (reader);
/* Three types of fields: quoted with ', quoted with ", unquoted. */
+ cp = ls_c_str (&line);
if (*cp == '\'' || *cp == '"')
{
int quote = *cp;
token->type = MSTR;
token->string = ++cp;
- while (cp < ep && *cp != quote)
+ while (cp < ls_end (&line) && *cp != quote)
cp++;
token->length = cp - token->string;
- if (cp < ep)
+ if (cp < ls_end (&line))
cp++;
else
msg (SW, _("Scope of string exceeds line."));
int is_num = isdigit ((unsigned char) *cp) || *cp == '.';
token->string = cp++;
- while (cp < ep && !isspace ((unsigned char) *cp) && *cp != ','
+ while (cp < ls_end (&line)
+ && !isspace ((unsigned char) *cp) && *cp != ','
&& *cp != '-' && *cp != '+')
{
if (isdigit ((unsigned char) *cp))
di.e = token->string + token->length;
di.v = (union value *) &token->number;
di.f1 = first_column;
- di.format.type = FMT_F;
- di.format.w = token->length;
- di.format.d = 0;
+ di.format = make_output_format (FMT_F, token->length, 0);
if (!data_in (&di))
return 0;
token->type = MSTR;
}
- dfm_set_record (data_file, cp);
+ dfm_forward_columns (reader, cp - ls_c_str (&line));
return 1;
}
/* Forcibly skip the end of a line for content type CONTENT in
- DATA_FILE. */
+ READER. */
static int
-force_eol (struct file_handle *data_file, const char *content)
+force_eol (struct dfm_reader *reader, const char *content)
{
- char *cp;
- int len;
-
- cp = dfm_get_record (data_file, &len);
- if (!cp)
+ struct fixed_string line;
+ const char *cp;
+
+ if (dfm_eof (reader))
return 0;
- while (len && isspace (*cp))
- cp++, len--;
+ dfm_get_record (reader, &line);
+
+ cp = ls_c_str (&line);
+ while (isspace ((unsigned char) *cp) && cp < ls_end (&line))
+ cp++;
- if (len)
+ if (cp < ls_end (&line))
{
msg (SE, _("End of line expected %s while reading %s."),
- context (data_file), content);
+ context (reader), content);
return 0;
}
- dfm_fwd_record (data_file);
-
+ dfm_forward_record (reader);
return 1;
}
\f
/* Back end, omitting ROWTYPE_. */
-/* MATRIX DATA data. */
-static double ***nr_data;
-
-/* Factor values. */
-static double *nr_factor_values;
-
-/* Largest-numbered cell that we have read in thus far, plus one. */
-static int max_cell_index;
-
-/* SPLIT FILE variable values. */
-static double *split_values;
+struct nr_aux_data
+ {
+ struct matrix_data_pgm *mx; /* MATRIX DATA program. */
+ double ***data; /* MATRIX DATA data. */
+ double *factor_values; /* Factor values. */
+ int max_cell_idx; /* Max-numbered cell that we have
+ read so far, plus one. */
+ double *split_values; /* SPLIT FILE variable values. */
+ };
-static int nr_read_splits (struct matrix_data_pgm *, int compare);
-static int nr_read_factors (struct matrix_data_pgm *, int cell);
-static void nr_output_data (struct matrix_data_pgm *, struct ccase *,
+static int nr_read_splits (struct nr_aux_data *, int compare);
+static int nr_read_factors (struct nr_aux_data *, int cell);
+static void nr_output_data (struct nr_aux_data *, struct ccase *,
write_case_func *, write_case_data);
static void matrix_data_read_without_rowtype (struct case_source *source,
struct ccase *,
static void
read_matrices_without_rowtype (struct matrix_data_pgm *mx)
{
+ struct nr_aux_data nr;
+
if (mx->cells == -1)
mx->cells = 1;
-
- split_values = xmalloc (sizeof *split_values
- * dict_get_split_cnt (default_dict));
- nr_factor_values = xmalloc (sizeof *nr_factor_values * mx->n_factors * mx->cells);
- max_cell_index = 0;
- vfm_source = create_case_source (&matrix_data_without_rowtype_source_class,
- default_dict, mx);
+ nr.mx = mx;
+ nr.data = NULL;
+ nr.factor_values = xnmalloc (mx->n_factors * mx->cells,
+ sizeof *nr.factor_values);
+ nr.max_cell_idx = 0;
+ nr.split_values = xnmalloc (dict_get_split_cnt (default_dict),
+ sizeof *nr.split_values);
+
+ vfm_source = create_case_source (&matrix_data_without_rowtype_source_class, &nr);
procedure (NULL, NULL);
- free (split_values);
- free (nr_factor_values);
-
- fh_close_handle (mx->data_file);
+ free (nr.split_values);
+ free (nr.factor_values);
}
/* Mirror data across the diagonal of matrix CP which contains
If PER_FACTOR is nonzero, then factor information is read from
the data file. Data is for cell number CELL. */
static int
-nr_read_data_lines (struct matrix_data_pgm *mx,
+nr_read_data_lines (struct nr_aux_data *nr,
int per_factor, int cell, int content, int compare)
{
- /* Content type. */
- const int type = content_type[content];
-
- /* Number of lines that must be parsed from the data file for this
- content type. */
- int n_lines;
-
- /* Current position in vector or matrix. */
- double *cp;
-
- /* Counter. */
+ struct matrix_data_pgm *mx = nr->mx;
+ const int type = content_type[content]; /* Content type. */
+ int n_lines; /* Number of lines to parse from data file for this type. */
+ double *cp; /* Current position in vector or matrix. */
int i;
if (type != 1)
n_lines--;
}
- cp = nr_data[content][cell];
+ cp = nr->data[content][cell];
if (type == 1 && mx->section == LOWER && mx->diag == NODIAGONAL)
cp += mx->n_continuous;
{
int n_cols;
- if (!nr_read_splits (mx, 1))
+ if (!nr_read_splits (nr, 1))
return 0;
- if (per_factor && !nr_read_factors (mx, cell))
+ if (per_factor && !nr_read_factors (nr, cell))
return 0;
compare = 1;
break;
default:
assert (0);
+ abort ();
}
break;
case 2:
break;
default:
assert (0);
+ abort ();
}
{
for (j = 0; j < n_cols; j++)
{
struct matrix_token token;
- if (!mget_token (&token, mx->data_file))
+ if (!mget_token (&token, mx->reader))
return 0;
if (token.type != MNUM)
{
msg (SE, _("expecting value for %s %s"),
dict_get_var (default_dict, j)->name,
- context (mx->data_file));
+ context (mx->reader));
return 0;
}
*cp++ = token.number;
}
if (mx->fmt != FREE
- && !force_eol (mx->data_file, content_names[content]))
+ && !force_eol (mx->reader, content_names[content]))
return 0;
debug_printf (("\n"));
}
cp += mx->n_continuous - n_cols;
}
- fill_matrix (mx, content, nr_data[content][cell]);
+ fill_matrix (mx, content, nr->data[content][cell]);
return 1;
}
write_case_func *write_case,
write_case_data wc_data)
{
- struct matrix_data_pgm *mx = source->aux;
+ struct nr_aux_data *nr = source->aux;
+ struct matrix_data_pgm *mx = nr->mx;
{
int *cp;
- nr_data = pool_alloc (mx->container, (PROX + 1) * sizeof *nr_data);
+ nr->data = pool_nalloc (mx->container, PROX + 1, sizeof *nr->data);
{
int i;
for (i = 0; i <= PROX; i++)
- nr_data[i] = NULL;
+ nr->data[i] = NULL;
}
for (cp = mx->contents; *cp != EOC; cp++)
int n_vectors = per_factor ? mx->cells : 1;
int i;
- nr_data[*cp] = pool_alloc (mx->container,
- n_vectors * sizeof **nr_data);
+ nr->data[*cp] = pool_nalloc (mx->container,
+ n_vectors, sizeof **nr->data);
for (i = 0; i < n_vectors; i++)
- nr_data[*cp][i] = pool_alloc (mx->container,
- n_entries * sizeof ***nr_data);
+ nr->data[*cp][i] = pool_nalloc (mx->container,
+ n_entries, sizeof ***nr->data);
}
}
}
{
int *bp, *ep, *np;
- if (!nr_read_splits (mx, 0))
+ if (!nr_read_splits (nr, 0))
return;
for (bp = mx->contents; *bp != EOC; bp = np)
int *cp;
for (cp = bp; cp < ep; cp++)
- if (!nr_read_data_lines (mx, per_factor, i, *cp, cp != bp))
+ if (!nr_read_data_lines (nr, per_factor, i, *cp, cp != bp))
return;
}
}
}
- nr_output_data (mx, c, write_case, wc_data);
+ nr_output_data (nr, c, write_case, wc_data);
if (dict_get_split_cnt (default_dict) == 0
- || !another_token (mx->data_file))
+ || !another_token (mx->reader))
return;
}
}
values read to the last values read and returns 1 if they're equal,
0 otherwise. */
static int
-nr_read_splits (struct matrix_data_pgm *mx, int compare)
+nr_read_splits (struct nr_aux_data *nr, int compare)
{
- static int just_read = 0;
+ struct matrix_data_pgm *mx = nr->mx;
+ static int just_read = 0; /* FIXME: WTF? */
size_t split_cnt;
size_t i;
if (mx->single_split)
{
- if (!compare)
- split_values[0]
- = ++dict_get_split_vars (default_dict)[0]->p.mxd.subtype;
+ if (!compare)
+ {
+ struct mxd_var *mv = dict_get_split_vars (default_dict)[0]->aux;
+ nr->split_values[0] = ++mv->sub_type;
+ }
return 1;
}
for (i = 0; i < split_cnt; i++)
{
struct matrix_token token;
- if (!mget_token (&token, mx->data_file))
+ if (!mget_token (&token, mx->reader))
return 0;
if (token.type != MNUM)
{
msg (SE, _("Syntax error expecting SPLIT FILE value %s."),
- context (mx->data_file));
+ context (mx->reader));
return 0;
}
if (!compare)
- split_values[i] = token.number;
- else if (split_values[i] != token.number)
+ nr->split_values[i] = token.number;
+ else if (nr->split_values[i] != token.number)
{
msg (SE, _("Expecting value %g for %s."),
- split_values[i], dict_get_split_vars (default_dict)[i]->name);
+ nr->split_values[i],
+ dict_get_split_vars (default_dict)[i]->name);
return 0;
}
}
values read to the last values read and returns 1 if they're equal,
0 otherwise. */
static int
-nr_read_factors (struct matrix_data_pgm *mx, int cell)
+nr_read_factors (struct nr_aux_data *nr, int cell)
{
+ struct matrix_data_pgm *mx = nr->mx;
int compare;
if (mx->n_factors == 0)
return 1;
- assert (max_cell_index >= cell);
- if (cell != max_cell_index)
+ assert (nr->max_cell_idx >= cell);
+ if (cell != nr->max_cell_idx)
compare = 1;
else
{
compare = 0;
- max_cell_index++;
+ nr->max_cell_idx++;
}
{
- int i;
+ size_t i;
for (i = 0; i < mx->n_factors; i++)
{
struct matrix_token token;
- if (!mget_token (&token, mx->data_file))
+ if (!mget_token (&token, mx->reader))
return 0;
if (token.type != MNUM)
{
msg (SE, _("Syntax error expecting factor value %s."),
- context (mx->data_file));
+ context (mx->reader));
return 0;
}
if (!compare)
- nr_factor_values[i + mx->n_factors * cell] = token.number;
- else if (nr_factor_values[i + mx->n_factors * cell] != token.number)
+ nr->factor_values[i + mx->n_factors * cell] = token.number;
+ else if (nr->factor_values[i + mx->n_factors * cell] != token.number)
{
msg (SE, _("Syntax error expecting value %g for %s %s."),
- nr_factor_values[i + mx->n_factors * cell],
- mx->factors[i]->name, context (mx->data_file));
+ nr->factor_values[i + mx->n_factors * cell],
+ mx->factors[i]->name, context (mx->reader));
return 0;
}
}
int type = content_type[content];
{
- st_bare_pad_copy (c->data[mx->rowtype_->fv].s,
- content_names[content], 8);
+ buf_copy_str_rpad (case_data_rw (c, mx->rowtype_->fv)->s, 8,
+ content_names[content]);
if (type != 1)
- memset (&c->data[mx->varname_->fv].s, ' ', 8);
+ memset (case_data_rw (c, mx->varname_->fv)->s, ' ', 8);
}
{
for (j = 0; j < mx->n_continuous; j++)
{
int fv = dict_get_var (default_dict, mx->first_continuous + j)->fv;
- c->data[fv].f = *cp;
+ case_data_rw (c, fv)->f = *cp;
cp++;
}
if (type == 1)
- st_bare_pad_copy (c->data[mx->varname_->fv].s,
- dict_get_var (default_dict,
- mx->first_continuous + i)->name,
- 8);
+ buf_copy_str_rpad (case_data_rw (c, mx->varname_->fv)->s, 8,
+ dict_get_var (default_dict,
+ mx->first_continuous + i)->name);
write_case (wc_data);
}
}
/* Finally dump out everything from nr_data[] to the output file. */
static void
-nr_output_data (struct matrix_data_pgm *mx, struct ccase *c,
+nr_output_data (struct nr_aux_data *nr, struct ccase *c,
write_case_func *write_case, write_case_data wc_data)
{
+ struct matrix_data_pgm *mx = nr->mx;
+
{
struct variable *const *split;
size_t split_cnt;
split_cnt = dict_get_split_cnt (default_dict);
split = dict_get_split_vars (default_dict);
for (i = 0; i < split_cnt; i++)
- c->data[split[i]->fv].f = split_values[i];
+ case_data_rw (c, split[i]->fv)->f = nr->split_values[i];
}
if (mx->n_factors)
for (cell = 0; cell < mx->cells; cell++)
{
{
- int factor;
+ size_t factor;
for (factor = 0; factor < mx->n_factors; factor++)
{
- c->data[mx->factors[factor]->fv].f
- = nr_factor_values[factor + cell * mx->n_factors];
+ case_data_rw (c, mx->factors[factor]->fv)->f
+ = nr->factor_values[factor + cell * mx->n_factors];
debug_printf (("f:%s ", mx->factors[factor]->name));
}
}
for (content = 0; content <= PROX; content++)
if (mx->is_per_factor[content])
{
- assert (nr_data[content] != NULL
- && nr_data[content][cell] != NULL);
+ assert (nr->data[content] != NULL
+ && nr->data[content][cell] != NULL);
- dump_cell_content (mx, content, nr_data[content][cell],
+ dump_cell_content (mx, content, nr->data[content][cell],
c, write_case, wc_data);
}
}
int content;
{
- int factor;
+ size_t factor;
for (factor = 0; factor < mx->n_factors; factor++)
- c->data[mx->factors[factor]->fv].f = SYSMIS;
+ case_data_rw (c, mx->factors[factor]->fv)->f = SYSMIS;
}
for (content = 0; content <= PROX; content++)
- if (!mx->is_per_factor[content] && nr_data[content] != NULL)
- dump_cell_content (mx, content, nr_data[content][0],
+ if (!mx->is_per_factor[content] && nr->data[content] != NULL)
+ dump_cell_content (mx, content, nr->data[content][0],
c, write_case, wc_data);
}
}
\f
/* Back end, with ROWTYPE_. */
-/* Type of current row. */
-static int wr_content;
-
/* All the data for one set of factor values. */
struct factor_data
{
struct factor_data *next;
};
-/* All the data, period. */
-struct factor_data *wr_data;
-
-/* Current factor. */
-struct factor_data *wr_current;
+/* With ROWTYPE_ auxiliary data. */
+struct wr_aux_data
+ {
+ struct matrix_data_pgm *mx; /* MATRIX DATA program. */
+ int content; /* Type of current row. */
+ double *split_values; /* SPLIT FILE variable values. */
+ struct factor_data *data; /* All the data. */
+ struct factor_data *current; /* Current factor. */
+ };
-static int wr_read_splits (struct matrix_data_pgm *,
- struct ccase *,
+static int wr_read_splits (struct wr_aux_data *, struct ccase *,
+ write_case_func *, write_case_data);
+static int wr_output_data (struct wr_aux_data *, struct ccase *,
write_case_func *, write_case_data);
-static int wr_output_data (struct matrix_data_pgm *,
- struct ccase *, write_case_func *, write_case_data);
-static int wr_read_rowtype (const struct matrix_token *, struct file_handle *);
-static int wr_read_factors (struct matrix_data_pgm *);
-static int wr_read_indeps (struct matrix_data_pgm *);
+static int wr_read_rowtype (struct wr_aux_data *,
+ const struct matrix_token *, struct dfm_reader *);
+static int wr_read_factors (struct wr_aux_data *);
+static int wr_read_indeps (struct wr_aux_data *);
static void matrix_data_read_with_rowtype (struct case_source *,
struct ccase *,
write_case_func *,
static void
read_matrices_with_rowtype (struct matrix_data_pgm *mx)
{
- wr_data = wr_current = NULL;
- split_values = NULL;
+ struct wr_aux_data wr;
+
+ wr.mx = mx;
+ wr.content = -1;
+ wr.split_values = NULL;
+ wr.data = NULL;
+ wr.current = NULL;
mx->cells = 0;
vfm_source = create_case_source (&matrix_data_with_rowtype_source_class,
- default_dict, mx);
-
+ &wr);
procedure (NULL, NULL);
- free (split_values);
- fh_close_handle (mx->data_file);
+ free (wr.split_values);
}
/* Read from the data file and write it to the active file. */
write_case_func *write_case,
write_case_data wc_data)
{
- struct matrix_data_pgm *mx = source->aux;
+ struct wr_aux_data *wr = source->aux;
+ struct matrix_data_pgm *mx = wr->mx;
do
{
- if (!wr_read_splits (mx, c, write_case, wc_data))
+ if (!wr_read_splits (wr, c, write_case, wc_data))
return;
- if (!wr_read_factors (mx))
+ if (!wr_read_factors (wr))
return;
- if (!wr_read_indeps (mx))
+ if (!wr_read_indeps (wr))
return;
}
- while (another_token (mx->data_file));
+ while (another_token (mx->reader));
- wr_output_data (mx, c, write_case, wc_data);
+ wr_output_data (wr, c, write_case, wc_data);
}
/* Read the split file variables. If they differ from the previous
set of split variables then output the data. Returns success. */
static int
-wr_read_splits (struct matrix_data_pgm *mx,
+wr_read_splits (struct wr_aux_data *wr,
struct ccase *c,
write_case_func *write_case, write_case_data wc_data)
{
+ struct matrix_data_pgm *mx = wr->mx;
int compare;
size_t split_cnt;
if (split_cnt == 0)
return 1;
- if (split_values)
+ if (wr->split_values)
compare = 1;
else
{
compare = 0;
- split_values = xmalloc (split_cnt * sizeof *split_values);
+ wr->split_values = xnmalloc (split_cnt, sizeof *wr->split_values);
}
{
for (i = 0; i < split_cnt; i++)
{
struct matrix_token token;
- if (!mget_token (&token, mx->data_file))
+ if (!mget_token (&token, mx->reader))
return 0;
if (token.type != MNUM)
{
msg (SE, _("Syntax error %s expecting SPLIT FILE value."),
- context (mx->data_file));
+ context (mx->reader));
return 0;
}
- if (compare && split_values[i] != token.number && !different)
+ if (compare && wr->split_values[i] != token.number && !different)
{
- if (!wr_output_data (mx, c, write_case, wc_data))
+ if (!wr_output_data (wr, c, write_case, wc_data))
return 0;
different = 1;
mx->cells = 0;
}
- split_values[i] = token.number;
+ wr->split_values[i] = token.number;
}
}
/* Write out the data for the current split file to the active
file. */
static int
-wr_output_data (struct matrix_data_pgm *mx,
+wr_output_data (struct wr_aux_data *wr,
struct ccase *c,
write_case_func *write_case, write_case_data wc_data)
{
+ struct matrix_data_pgm *mx = wr->mx;
+
{
struct variable *const *split;
size_t split_cnt;
split_cnt = dict_get_split_cnt (default_dict);
split = dict_get_split_vars (default_dict);
for (i = 0; i < split_cnt; i++)
- c->data[split[i]->fv].f = split_values[i];
+ case_data_rw (c, split[i]->fv)->f = wr->split_values[i];
}
- /* Sort the wr_data list. */
+ /* Sort the wr->data list. */
{
struct factor_data **factors;
struct factor_data *iter;
int i;
- factors = xmalloc (sizeof *factors * mx->cells);
+ factors = xnmalloc (mx->cells, sizeof *factors);
- for (i = 0, iter = wr_data; iter; iter = iter->next, i++)
+ for (i = 0, iter = wr->data; iter; iter = iter->next, i++)
factors[i] = iter;
sort (factors, mx->cells, sizeof *factors, compare_factors, mx);
- wr_data = factors[0];
+ wr->data = factors[0];
for (i = 0; i < mx->cells - 1; i++)
factors[i]->next = factors[i + 1];
factors[mx->cells - 1]->next = NULL;
{
struct factor_data *iter;
- for (iter = wr_data; iter; iter = iter->next)
+ for (iter = wr->data; iter; iter = iter->next)
{
{
- int factor;
+ size_t factor;
for (factor = 0; factor < mx->n_factors; factor++)
- {
- c->data[mx->factors[factor]->fv].f
- = iter->factors[factor];
- debug_printf (("f:%s ", factors[factor]->name));
- }
+ case_data_rw (c, mx->factors[factor]->fv)->f
+ = iter->factors[factor];
}
{
pool_destroy (mx->container);
mx->container = pool_create ();
- wr_data = wr_current = NULL;
+ wr->data = wr->current = NULL;
return 1;
}
-/* Sets ROWTYPE_ based on the given TOKEN read from DATA_FILE.
+/* Sets ROWTYPE_ based on the given TOKEN read from READER.
Return success. */
static int
-wr_read_rowtype (const struct matrix_token *token,
- struct file_handle *data_file)
+wr_read_rowtype (struct wr_aux_data *wr,
+ const struct matrix_token *token,
+ struct dfm_reader *reader)
{
- if (wr_content != -1)
+ if (wr->content != -1)
{
- msg (SE, _("Multiply specified ROWTYPE_ %s."), context (data_file));
+ msg (SE, _("Multiply specified ROWTYPE_ %s."), context (reader));
return 0;
}
if (token->type != MSTR)
{
msg (SE, _("Syntax error %s expecting ROWTYPE_ string."),
- context (data_file));
+ context (reader));
return 0;
}
for (cp = s; *cp; cp++)
*cp = toupper ((unsigned char) *cp);
- wr_content = string_to_content_type (s, NULL);
+ wr->content = string_to_content_type (s, NULL);
}
- if (wr_content == -1)
+ if (wr->content == -1)
{
- msg (SE, _("Syntax error %s."), context (data_file));
+ msg (SE, _("Syntax error %s."), context (reader));
return 0;
}
/* Read the factors for the current row. Select a set of factors and
point wr_current to it. */
static int
-wr_read_factors (struct matrix_data_pgm *mx)
+wr_read_factors (struct wr_aux_data *wr)
{
+ struct matrix_data_pgm *mx = wr->mx;
double *factor_values = local_alloc (sizeof *factor_values * mx->n_factors);
- wr_content = -1;
+ wr->content = -1;
{
- int i;
+ size_t i;
for (i = 0; i < mx->n_factors; i++)
{
struct matrix_token token;
- if (!mget_token (&token, mx->data_file))
+ if (!mget_token (&token, mx->reader))
goto lossage;
if (token.type == MSTR)
{
- if (!wr_read_rowtype (&token, mx->data_file))
+ if (!wr_read_rowtype (wr, &token, mx->reader))
goto lossage;
- if (!mget_token (&token, mx->data_file))
+ if (!mget_token (&token, mx->reader))
goto lossage;
}
if (token.type != MNUM)
{
msg (SE, _("Syntax error expecting factor value %s."),
- context (mx->data_file));
+ context (mx->reader));
goto lossage;
}
factor_values[i] = token.number;
}
}
- if (wr_content == -1)
+ if (wr->content == -1)
{
struct matrix_token token;
- if (!mget_token (&token, mx->data_file))
+ if (!mget_token (&token, mx->reader))
goto lossage;
- if (!wr_read_rowtype (&token, mx->data_file))
+ if (!wr_read_rowtype (wr, &token, mx->reader))
goto lossage;
}
/* Try the most recent factor first as a simple caching
mechanism. */
- if (wr_current)
+ if (wr->current)
{
- int i;
+ size_t i;
for (i = 0; i < mx->n_factors; i++)
- if (factor_values[i] != wr_current->factors[i])
+ if (factor_values[i] != wr->current->factors[i])
goto cache_miss;
goto winnage;
}
{
struct factor_data *iter;
- for (iter = wr_data; iter; iter = iter->next)
+ for (iter = wr->data; iter; iter = iter->next)
{
- int i;
+ size_t i;
for (i = 0; i < mx->n_factors; i++)
if (factor_values[i] != iter->factors[i])
goto next_item;
- wr_current = iter;
+ wr->current = iter;
goto winnage;
next_item: ;
{
struct factor_data *new = pool_alloc (mx->container, sizeof *new);
- new->factors = pool_alloc (mx->container, sizeof *new->factors * mx->n_factors);
+ new->factors = pool_nalloc (mx->container,
+ mx->n_factors, sizeof *new->factors);
{
- int i;
+ size_t i;
for (i = 0; i < mx->n_factors; i++)
new->factors[i] = factor_values[i];
}
}
- new->next = wr_data;
- wr_data = wr_current = new;
+ new->next = wr->data;
+ wr->data = wr->current = new;
mx->cells++;
}
return 0;
}
-/* Read the independent variables into wr_current. */
+/* Read the independent variables into wr->current. */
static int
-wr_read_indeps (struct matrix_data_pgm *mx)
+wr_read_indeps (struct wr_aux_data *wr)
{
- struct factor_data *c = wr_current;
- const int type = content_type[wr_content];
- const int n_rows = c->n_rows[wr_content];
+ struct matrix_data_pgm *mx = wr->mx;
+ struct factor_data *c = wr->current;
+ const int type = content_type[wr->content];
+ const int n_rows = c->n_rows[wr->content];
double *cp;
int n_cols;
/* Allocate room for data if necessary. */
- if (c->data[wr_content] == NULL)
+ if (c->data[wr->content] == NULL)
{
int n_items = mx->n_continuous;
if (type == 1)
n_items *= mx->n_continuous;
- c->data[wr_content] = pool_alloc (mx->container,
- sizeof **c->data * n_items);
+ c->data[wr->content] = pool_nalloc (mx->container,
+ n_items, sizeof **c->data);
}
- cp = &c->data[wr_content][n_rows * mx->n_continuous];
+ cp = &c->data[wr->content][n_rows * mx->n_continuous];
/* Figure out how much to read from this line. */
switch (type)
if (n_rows > 0)
{
msg (SE, _("Duplicate specification for %s."),
- content_names[wr_content]);
+ content_names[wr->content]);
return 0;
}
if (type == 0)
if (n_rows >= mx->n_continuous - (mx->section != FULL && mx->diag == NODIAGONAL))
{
msg (SE, _("Too many rows of matrix data for %s."),
- content_names[wr_content]);
+ content_names[wr->content]);
return 0;
}
break;
default:
assert (0);
+ abort ();
}
break;
default:
assert (0);
+ abort ();
}
- c->n_rows[wr_content]++;
+ c->n_rows[wr->content]++;
debug_printf ((" (c=%p,r=%d,n=%d)", c, n_rows + 1, n_cols));
for (j = 0; j < n_cols; j++)
{
struct matrix_token token;
- if (!mget_token (&token, mx->data_file))
+ if (!mget_token (&token, mx->reader))
return 0;
if (token.type != MNUM)
{
msg (SE, _("Syntax error expecting value for %s %s."),
dict_get_var (default_dict, mx->first_continuous + j)->name,
- context (mx->data_file));
+ context (mx->reader));
return 0;
}
*cp++ = token.number;
}
if (mx->fmt != FREE
- && !force_eol (mx->data_file, content_names[wr_content]))
+ && !force_eol (mx->reader, content_names[wr->content]))
return 0;
debug_printf (("\n"));
}
matrix_data_read_without_rowtype,
NULL,
};
+