-/* Copyright (C) 2002, 2003, 2004, 2005, 2006, 2007
- Free Software Foundation, Inc.
+/* Copyright (C) 2002-2017 Free Software Foundation, Inc.
Contributed by Andy Vaught
+ F2003 I/O support contributed by Jerry DeLisle
-This file is part of the GNU Fortran 95 runtime library (libgfortran).
+This file is part of the GNU Fortran runtime library (libgfortran).
Libgfortran 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 2, or (at your option)
+the Free Software Foundation; either version 3, or (at your option)
any later version.
-In addition to the permissions in the GNU General Public License, the
-Free Software Foundation gives you unlimited permission to link the
-compiled version of this file into combinations with other programs,
-and to distribute those combinations without any restriction coming
-from the use of this file. (The General Public License restrictions
-do apply in other respects; for example, they cover modification of
-the file, and distribution when not linked into a combine
-executable.)
-
Libgfortran 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 Libgfortran; see the file COPYING. If not, write to
-the Free Software Foundation, 51 Franklin Street, Fifth Floor,
-Boston, MA 02110-1301, USA. */
+Under Section 7 of GPL version 3, you are granted additional
+permissions described in the GCC Runtime Library Exception, version
+3.1, as published by the Free Software Foundation.
+
+You should have received a copy of the GNU General Public License and
+a copy of the GCC Runtime Library Exception along with this program;
+see the files COPYING3 and COPYING.RUNTIME respectively. If not, see
+<http://www.gnu.org/licenses/>. */
/* format.c-- parse a FORMAT string into a binary format suitable for
* interpretation during I/O statements */
#include "io.h"
+#include "format.h"
#include <ctype.h>
#include <string.h>
-#define FARRAY_SIZE 64
-
-typedef struct fnode_array
-{
- struct fnode_array *next;
- fnode array[FARRAY_SIZE];
-}
-fnode_array;
-
-typedef struct format_data
-{
- char *format_string, *string;
- const char *error;
- format_token saved_token;
- int value, format_string_len, reversion_ok;
- fnode *avail;
- const fnode *saved_format;
- fnode_array *last;
- fnode_array array;
-}
-format_data;
static const fnode colon_node = { FMT_COLON, 0, NULL, NULL, {{ 0, 0, 0 }}, 0,
NULL };
-/* Error messages */
+/* Error messages. */
static const char posint_required[] = "Positive width required in format",
period_required[] = "Period required in format",
nonneg_required[] = "Nonnegative width required in format",
- unexpected_element[] = "Unexpected element in format",
+ unexpected_element[] = "Unexpected element '%c' in format\n",
unexpected_end[] = "Unexpected end of format string",
bad_string[] = "Unterminated character constant in format",
bad_hollerith[] = "Hollerith constant extends past the end of the format",
- reversion_error[] = "Exhausted data descriptors in format";
+ reversion_error[] = "Exhausted data descriptors in format",
+ zero_width[] = "Zero width in format descriptor";
+
+/* The following routines support caching format data from parsed format strings
+ into a hash table. This avoids repeatedly parsing duplicate format strings
+ or format strings in I/O statements that are repeated in loops. */
+
+
+/* Traverse the table and free all data. */
+
+void
+free_format_hash_table (gfc_unit *u)
+{
+ size_t i;
+
+ /* free_format_data handles any NULL pointers. */
+ for (i = 0; i < FORMAT_HASH_SIZE; i++)
+ {
+ if (u->format_hash_table[i].hashed_fmt != NULL)
+ {
+ free_format_data (u->format_hash_table[i].hashed_fmt);
+ free (u->format_hash_table[i].key);
+ }
+ u->format_hash_table[i].key = NULL;
+ u->format_hash_table[i].key_len = 0;
+ u->format_hash_table[i].hashed_fmt = NULL;
+ }
+}
+
+/* Traverse the format_data structure and reset the fnode counters. */
+
+static void
+reset_node (fnode *fn)
+{
+ fnode *f;
+
+ fn->count = 0;
+ fn->current = NULL;
+
+ if (fn->format != FMT_LPAREN)
+ return;
+
+ for (f = fn->u.child; f; f = f->next)
+ {
+ if (f->format == FMT_RPAREN)
+ break;
+ reset_node (f);
+ }
+}
+
+static void
+reset_fnode_counters (st_parameter_dt *dtp)
+{
+ fnode *f;
+ format_data *fmt;
+
+ fmt = dtp->u.p.fmt;
+
+ /* Clear this pointer at the head so things start at the right place. */
+ fmt->array.array[0].current = NULL;
+
+ for (f = fmt->array.array[0].u.child; f; f = f->next)
+ reset_node (f);
+}
+
+
+/* A simple hashing function to generate an index into the hash table. */
+
+static uint32_t
+format_hash (st_parameter_dt *dtp)
+{
+ char *key;
+ gfc_charlen_type key_len;
+ uint32_t hash = 0;
+ gfc_charlen_type i;
+
+ /* Hash the format string. Super simple, but what the heck! */
+ key = dtp->format;
+ key_len = dtp->format_len;
+ for (i = 0; i < key_len; i++)
+ hash ^= key[i];
+ hash &= (FORMAT_HASH_SIZE - 1);
+ return hash;
+}
+
+
+static void
+save_parsed_format (st_parameter_dt *dtp)
+{
+ uint32_t hash;
+ gfc_unit *u;
+
+ hash = format_hash (dtp);
+ u = dtp->u.p.current_unit;
+
+ /* Index into the hash table. We are simply replacing whatever is there
+ relying on probability. */
+ if (u->format_hash_table[hash].hashed_fmt != NULL)
+ free_format_data (u->format_hash_table[hash].hashed_fmt);
+ u->format_hash_table[hash].hashed_fmt = NULL;
+
+ free (u->format_hash_table[hash].key);
+ u->format_hash_table[hash].key = dtp->format;
+
+ u->format_hash_table[hash].key_len = dtp->format_len;
+ u->format_hash_table[hash].hashed_fmt = dtp->u.p.fmt;
+}
+
+
+static format_data *
+find_parsed_format (st_parameter_dt *dtp)
+{
+ uint32_t hash;
+ gfc_unit *u;
+
+ hash = format_hash (dtp);
+ u = dtp->u.p.current_unit;
+
+ if (u->format_hash_table[hash].key != NULL)
+ {
+ /* See if it matches. */
+ if (u->format_hash_table[hash].key_len == dtp->format_len)
+ {
+ /* So far so good. */
+ if (strncmp (u->format_hash_table[hash].key,
+ dtp->format, dtp->format_len) == 0)
+ return u->format_hash_table[hash].hashed_fmt;
+ }
+ }
+ return NULL;
+}
/* next_char()-- Return the next character in the format string.
fmt->format_string_len--;
c = toupper (*fmt->format_string++);
+ fmt->error_element = c;
}
while ((c == ' ' || c == '\t') && !literal);
if (fmt->avail == &fmt->last->array[FARRAY_SIZE])
{
- fmt->last->next = get_mem (sizeof (fnode_array));
+ fmt->last->next = xmalloc (sizeof (fnode_array));
fmt->last = fmt->last->next;
fmt->last->next = NULL;
fmt->avail = &fmt->last->array[0];
}
+/* free_format()-- Free allocated format string. */
+void
+free_format (st_parameter_dt *dtp)
+{
+ if ((dtp->common.flags & IOPARM_DT_HAS_FORMAT) && dtp->format)
+ {
+ free (dtp->format);
+ dtp->format = NULL;
+ }
+}
+
+
/* free_format_data()-- Free all allocated format data. */
void
-free_format_data (st_parameter_dt *dtp)
+free_format_data (format_data *fmt)
{
fnode_array *fa, *fa_next;
- format_data *fmt = dtp->u.p.fmt;
+ fnode *fnp;
if (fmt == NULL)
return;
+ /* Free vlist descriptors in the fnode_array if one was allocated. */
+ for (fnp = fmt->array.array; fnp->format != FMT_NONE; fnp++)
+ if (fnp->format == FMT_DT)
+ {
+ if (GFC_DESCRIPTOR_DATA(fnp->u.udf.vlist))
+ free (GFC_DESCRIPTOR_DATA(fnp->u.udf.vlist));
+ free (fnp->u.udf.vlist);
+ }
+
for (fa = fmt->array.next; fa; fa = fa_next)
{
fa_next = fa->next;
- free_mem (fa);
+ free (fa);
}
- free_mem (fmt);
- dtp->u.p.fmt = NULL;
+ free (fmt);
+ fmt = NULL;
}
switch (c)
{
+ case '*':
+ token = FMT_STAR;
+ break;
+
+ case '(':
+ token = FMT_LPAREN;
+ break;
+
+ case ')':
+ token = FMT_RPAREN;
+ break;
+
case '-':
negative_flag = 1;
/* Fall Through */
break;
- case '(':
- token = FMT_LPAREN;
- break;
-
- case ')':
- token = FMT_RPAREN;
- break;
-
case 'X':
token = FMT_X;
break;
unget_char (fmt);
break;
}
-
break;
case 'G':
break;
case 'D':
- token = FMT_D;
+ switch (next_char (fmt, 0))
+ {
+ case 'P':
+ token = FMT_DP;
+ break;
+ case 'C':
+ token = FMT_DC;
+ break;
+ case 'T':
+ token = FMT_DT;
+ break;
+ default:
+ token = FMT_D;
+ unget_char (fmt);
+ break;
+ }
+ break;
+
+ case 'R':
+ switch (next_char (fmt, 0))
+ {
+ case 'C':
+ token = FMT_RC;
+ break;
+ case 'D':
+ token = FMT_RD;
+ break;
+ case 'N':
+ token = FMT_RN;
+ break;
+ case 'P':
+ token = FMT_RP;
+ break;
+ case 'U':
+ token = FMT_RU;
+ break;
+ case 'Z':
+ token = FMT_RZ;
+ break;
+ default:
+ unget_char (fmt);
+ token = FMT_UNKNOWN;
+ break;
+ }
break;
case -1:
* parenthesis node which contains the rest of the list. */
static fnode *
-parse_format_list (st_parameter_dt *dtp)
+parse_format_list (st_parameter_dt *dtp, bool *seen_dd)
{
fnode *head, *tail;
format_token t, u, t2;
int repeat;
format_data *fmt = dtp->u.p.fmt;
+ bool seen_data_desc = false;
head = tail = NULL;
format_item_1:
switch (t)
{
+ case FMT_STAR:
+ t = format_lex (fmt);
+ if (t != FMT_LPAREN)
+ {
+ fmt->error = "Left parenthesis required after '*'";
+ goto finished;
+ }
+ get_fnode (fmt, &head, &tail, FMT_LPAREN);
+ tail->repeat = -2; /* Signifies unlimited format. */
+ tail->u.child = parse_format_list (dtp, &seen_data_desc);
+ *seen_dd = seen_data_desc;
+ if (fmt->error != NULL)
+ goto finished;
+ if (!seen_data_desc)
+ {
+ fmt->error = "'*' requires at least one associated data descriptor";
+ goto finished;
+ }
+ goto between_desc;
+
case FMT_POSINT:
repeat = fmt->value;
case FMT_LPAREN:
get_fnode (fmt, &head, &tail, FMT_LPAREN);
tail->repeat = repeat;
- tail->u.child = parse_format_list (dtp);
+ tail->u.child = parse_format_list (dtp, &seen_data_desc);
+ *seen_dd = seen_data_desc;
if (fmt->error != NULL)
goto finished;
case FMT_LPAREN:
get_fnode (fmt, &head, &tail, FMT_LPAREN);
tail->repeat = 1;
- tail->u.child = parse_format_list (dtp);
+ tail->u.child = parse_format_list (dtp, &seen_data_desc);
+ *seen_dd = seen_data_desc;
if (fmt->error != NULL)
goto finished;
goto data_desc;
}
+ if (t != FMT_COMMA && t != FMT_RPAREN && t != FMT_SLASH
+ && t != FMT_POSINT)
+ {
+ fmt->error = "Comma required after P descriptor";
+ goto finished;
+ }
+
fmt->saved_token = t;
goto optional_comma;
case FMT_STRING:
get_fnode (fmt, &head, &tail, FMT_STRING);
-
tail->u.string.p = fmt->string;
tail->u.string.length = fmt->value;
tail->repeat = 1;
goto optional_comma;
+ case FMT_RC:
+ case FMT_RD:
+ case FMT_RN:
+ case FMT_RP:
+ case FMT_RU:
+ case FMT_RZ:
+ notify_std (&dtp->common, GFC_STD_F2003, "Fortran 2003: Round "
+ "descriptor not allowed");
+ get_fnode (fmt, &head, &tail, t);
+ tail->repeat = 1;
+ goto between_desc;
+
+ case FMT_DC:
+ case FMT_DP:
+ notify_std (&dtp->common, GFC_STD_F2003, "Fortran 2003: DC or DP "
+ "descriptor not allowed");
+ /* Fall through. */
case FMT_S:
case FMT_SS:
case FMT_SP:
case FMT_EN:
case FMT_ES:
case FMT_D:
+ case FMT_DT:
case FMT_L:
case FMT_A:
case FMT_F:
case FMT_G:
repeat = 1;
+ *seen_dd = true;
goto data_desc;
case FMT_H:
get_fnode (fmt, &head, &tail, FMT_STRING);
-
if (fmt->format_string_len < 1)
{
fmt->error = bad_hollerith;
/* In this state, t must currently be a data descriptor. Deal with
things that can/must follow the descriptor */
data_desc:
+
switch (t)
{
- case FMT_P:
- t = format_lex (fmt);
- if (t == FMT_POSINT)
- {
- fmt->error = "Repeat count cannot follow P descriptor";
- goto finished;
- }
-
- fmt->saved_token = t;
- get_fnode (fmt, &head, &tail, FMT_P);
-
- goto optional_comma;
-
case FMT_L:
+ *seen_dd = true;
t = format_lex (fmt);
if (t != FMT_POSINT)
{
- if (notification_std(GFC_STD_GNU) == ERROR)
+ if (t == FMT_ZERO)
{
- fmt->error = posint_required;
- goto finished;
+ if (notification_std(GFC_STD_GNU) == NOTIFICATION_ERROR)
+ {
+ fmt->error = "Extension: Zero width after L descriptor";
+ goto finished;
+ }
+ else
+ notify_std (&dtp->common, GFC_STD_GNU,
+ "Zero width after L descriptor");
}
else
{
fmt->saved_token = t;
- fmt->value = 1; /* Default width */
- notify_std (&dtp->common, GFC_STD_GNU, posint_required);
+ notify_std (&dtp->common, GFC_STD_GNU,
+ "Positive width required with L descriptor");
}
+ fmt->value = 1; /* Default width */
}
-
get_fnode (fmt, &head, &tail, FMT_L);
tail->u.n = fmt->value;
tail->repeat = repeat;
break;
case FMT_A:
+ *seen_dd = true;
t = format_lex (fmt);
+ if (t == FMT_ZERO)
+ {
+ fmt->error = zero_width;
+ goto finished;
+ }
+
if (t != FMT_POSINT)
{
fmt->saved_token = t;
case FMT_G:
case FMT_EN:
case FMT_ES:
+ *seen_dd = true;
get_fnode (fmt, &head, &tail, t);
tail->repeat = repeat;
u = format_lex (fmt);
- if (t == FMT_F || dtp->u.p.mode == WRITING)
+ if (t == FMT_G && u == FMT_ZERO)
{
- if (u != FMT_POSINT && u != FMT_ZERO)
+ *seen_dd = true;
+ if (notification_std (GFC_STD_F2008) == NOTIFICATION_ERROR
+ || dtp->u.p.mode == READING)
{
- fmt->error = nonneg_required;
+ fmt->error = zero_width;
goto finished;
}
- }
- else
- {
+ tail->u.real.w = 0;
+ u = format_lex (fmt);
+ if (u != FMT_PERIOD)
+ {
+ fmt->saved_token = u;
+ break;
+ }
+
+ u = format_lex (fmt);
if (u != FMT_POSINT)
{
fmt->error = posint_required;
goto finished;
}
+ tail->u.real.d = fmt->value;
+ break;
+ }
+ if (t == FMT_F && dtp->u.p.mode == WRITING)
+ {
+ *seen_dd = true;
+ if (u != FMT_POSINT && u != FMT_ZERO)
+ {
+ fmt->error = nonneg_required;
+ goto finished;
+ }
+ }
+ else if (u != FMT_POSINT)
+ {
+ fmt->error = posint_required;
+ goto finished;
}
tail->u.real.w = fmt->value;
}
fmt->saved_token = t;
tail->u.real.d = 0;
+ tail->u.real.e = -1;
break;
}
}
tail->u.real.d = fmt->value;
-
- if (t == FMT_D || t == FMT_F)
- break;
-
tail->u.real.e = -1;
+ if (t2 == FMT_D || t2 == FMT_F)
+ {
+ *seen_dd = true;
+ break;
+ }
+
/* Look for optional exponent */
t = format_lex (fmt);
if (t != FMT_E)
}
break;
+ case FMT_DT:
+ *seen_dd = true;
+ get_fnode (fmt, &head, &tail, t);
+ tail->repeat = repeat;
+ t = format_lex (fmt);
+
+ /* Initialize the vlist to a zero size array. */
+ tail->u.udf.vlist= xmalloc (sizeof(gfc_array_i4));
+ GFC_DESCRIPTOR_DATA(tail->u.udf.vlist) = NULL;
+ GFC_DIMENSION_SET(tail->u.udf.vlist->dim[0],1, 0, 0);
+
+ if (t == FMT_STRING)
+ {
+ /* Get pointer to the optional format string. */
+ tail->u.udf.string = fmt->string;
+ tail->u.udf.string_len = fmt->value;
+ t = format_lex (fmt);
+ }
+ if (t == FMT_LPAREN)
+ {
+ /* Temporary buffer to hold the vlist values. */
+ GFC_INTEGER_4 temp[FARRAY_SIZE];
+ int i = 0;
+ loop:
+ t = format_lex (fmt);
+ if (t != FMT_POSINT)
+ {
+ fmt->error = posint_required;
+ goto finished;
+ }
+ /* Save the positive integer value. */
+ temp[i++] = fmt->value;
+ t = format_lex (fmt);
+ if (t == FMT_COMMA)
+ goto loop;
+ if (t == FMT_RPAREN)
+ {
+ /* We have parsed the complete vlist so initialize the
+ array descriptor and save it in the format node. */
+ gfc_array_i4 *vp = tail->u.udf.vlist;
+ GFC_DESCRIPTOR_DATA(vp) = xmalloc (i * sizeof(GFC_INTEGER_4));
+ GFC_DIMENSION_SET(vp->dim[0],1, i, 1);
+ memcpy (GFC_DESCRIPTOR_DATA(vp), temp, i * sizeof(GFC_INTEGER_4));
+ break;
+ }
+ fmt->error = unexpected_element;
+ goto finished;
+ }
+ fmt->saved_token = t;
+ break;
case FMT_H:
if (repeat > fmt->format_string_len)
{
}
get_fnode (fmt, &head, &tail, FMT_STRING);
-
tail->u.string.p = fmt->format_string;
tail->u.string.length = repeat;
tail->repeat = 1;
case FMT_B:
case FMT_O:
case FMT_Z:
+ *seen_dd = true;
get_fnode (fmt, &head, &tail, t);
tail->repeat = repeat;
goto format_item;
finished:
+
return head;
}
void
format_error (st_parameter_dt *dtp, const fnode *f, const char *message)
{
- int width, i, j, offset;
- char *p, buffer[300];
+ int width, i, offset;
+#define BUFLEN 300
+ char *p, buffer[BUFLEN];
format_data *fmt = dtp->u.p.fmt;
if (f != NULL)
- fmt->format_string = f->source;
-
- sprintf (buffer, "%s\n", message);
+ p = f->source;
+ else /* This should not happen. */
+ p = dtp->format;
- j = fmt->format_string - dtp->format;
+ if (message == unexpected_element)
+ snprintf (buffer, BUFLEN, message, fmt->error_element);
+ else
+ snprintf (buffer, BUFLEN, "%s\n", message);
- offset = (j > 60) ? j - 40 : 0;
+ /* Get the offset into the format string where the error occurred. */
+ offset = dtp->format_len - (fmt->reversion_ok ?
+ (int) strlen(p) : fmt->format_string_len);
- j -= offset;
- width = dtp->format_len - offset;
+ width = dtp->format_len;
if (width > 80)
width = 80;
p = strchr (buffer, '\0');
- memcpy (p, dtp->format + offset, width);
+ if (dtp->format)
+ memcpy (p, dtp->format, width);
p += width;
*p++ = '\n';
/* Show where the problem is */
- for (i = 1; i < j; i++)
+ for (i = 1; i < offset; i++)
*p++ = ' ';
*p++ = '^';
}
+/* revert()-- Do reversion of the format. Control reverts to the left
+ * parenthesis that matches the rightmost right parenthesis. From our
+ * tree structure, we are looking for the rightmost parenthesis node
+ * at the second level, the first level always being a single
+ * parenthesis node. If this node doesn't exit, we use the top
+ * level. */
+
+static void
+revert (st_parameter_dt *dtp)
+{
+ fnode *f, *r;
+ format_data *fmt = dtp->u.p.fmt;
+
+ dtp->u.p.reversion_flag = 1;
+
+ r = NULL;
+
+ for (f = fmt->array.array[0].u.child; f; f = f->next)
+ if (f->format == FMT_LPAREN)
+ r = f;
+
+ /* If r is NULL because no node was found, the whole tree will be used */
+
+ fmt->array.array[0].current = r;
+ fmt->array.array[0].count = 0;
+}
+
/* parse_format()-- Parse a format string. */
void
parse_format (st_parameter_dt *dtp)
{
format_data *fmt;
+ bool format_cache_ok, seen_data_desc = false;
+
+ /* Don't cache for internal units and set an arbitrary limit on the
+ size of format strings we will cache. (Avoids memory issues.)
+ Also, the format_hash_table resides in the current_unit, so
+ child_dtio procedures would overwrite the parent table */
+ format_cache_ok = !is_internal_unit (dtp)
+ && (dtp->u.p.current_unit->child_dtio == 0);
+
+ /* Lookup format string to see if it has already been parsed. */
+ if (format_cache_ok)
+ {
+ dtp->u.p.fmt = find_parsed_format (dtp);
+
+ if (dtp->u.p.fmt != NULL)
+ {
+ dtp->u.p.fmt->reversion_ok = 0;
+ dtp->u.p.fmt->saved_token = FMT_NONE;
+ dtp->u.p.fmt->saved_format = NULL;
+ reset_fnode_counters (dtp);
+ return;
+ }
+ }
- dtp->u.p.fmt = fmt = get_mem (sizeof (format_data));
+ /* Not found so proceed as follows. */
+
+ char *fmt_string = fc_strdup_notrim (dtp->format, dtp->format_len);
+ dtp->format = fmt_string;
+
+ dtp->u.p.fmt = fmt = xmalloc (sizeof (format_data));
fmt->format_string = dtp->format;
fmt->format_string_len = dtp->format_len;
fmt->error = NULL;
fmt->value = 0;
- /* Initialize variables used during traversal of the tree */
+ /* Initialize variables used during traversal of the tree. */
fmt->reversion_ok = 0;
fmt->saved_format = NULL;
- /* Allocate the first format node as the root of the tree */
+ /* Initialize the fnode_array. */
+
+ memset (&(fmt->array), 0, sizeof(fmt->array));
+
+ /* Allocate the first format node as the root of the tree. */
fmt->last = &fmt->array;
fmt->last->next = NULL;
fmt->avail++;
if (format_lex (fmt) == FMT_LPAREN)
- fmt->array.array[0].u.child = parse_format_list (dtp);
+ fmt->array.array[0].u.child = parse_format_list (dtp, &seen_data_desc);
else
fmt->error = "Missing initial left parenthesis in format";
+ if (format_cache_ok)
+ save_parsed_format (dtp);
+ else
+ dtp->u.p.format_not_saved = 1;
+
if (fmt->error)
format_error (dtp, NULL, fmt->error);
}
-/* revert()-- Do reversion of the format. Control reverts to the left
- * parenthesis that matches the rightmost right parenthesis. From our
- * tree structure, we are looking for the rightmost parenthesis node
- * at the second level, the first level always being a single
- * parenthesis node. If this node doesn't exit, we use the top
- * level. */
-
-static void
-revert (st_parameter_dt *dtp)
-{
- fnode *f, *r;
- format_data *fmt = dtp->u.p.fmt;
-
- dtp->u.p.reversion_flag = 1;
-
- r = NULL;
-
- for (f = fmt->array.array[0].u.child; f; f = f->next)
- if (f->format == FMT_LPAREN)
- r = f;
-
- /* If r is NULL because no node was found, the whole tree will be used */
-
- fmt->array.array[0].current = r;
- fmt->array.array[0].count = 0;
-}
-
-
/* next_format0()-- Get the next format node without worrying about
* reversion. Returns NULL when we hit the end of the list.
* Parenthesis nodes are incremented after the list has been
return NULL;
}
- /* Deal with a parenthesis node */
+ /* Deal with a parenthesis node with unlimited format. */
+
+ if (f->repeat == -2) /* -2 signifies unlimited. */
+ for (;;)
+ {
+ if (f->current == NULL)
+ f->current = f->u.child;
+
+ for (; f->current != NULL; f->current = f->current->next)
+ {
+ r = next_format0 (f->current);
+ if (r != NULL)
+ return r;
+ }
+ }
+ /* Deal with a parenthesis node with specific repeat count. */
for (; f->count < f->repeat; f->count++)
{
if (f->current == NULL)
/* next_format()-- Return the next format node. If the format list
* ends up being exhausted, we do reversion. Reversion is only
- * allowed if the we've seen a data descriptor since the
+ * allowed if we've seen a data descriptor since the
* initialization or the last reversion. We return NULL if there
* are no more data descriptors to return (which is an error
* condition). */
if (!fmt->reversion_ok &&
(t == FMT_I || t == FMT_B || t == FMT_O || t == FMT_Z || t == FMT_F ||
t == FMT_E || t == FMT_EN || t == FMT_ES || t == FMT_G || t == FMT_L ||
- t == FMT_A || t == FMT_D))
+ t == FMT_A || t == FMT_D || t == FMT_DT))
fmt->reversion_ok = 1;
return f;
}