gcc/libgfortran/io/io.h

1017 lines
26 KiB
C++

/* Copyright (C) 2002, 2003, 2004, 2005, 2006, 2007, 2008
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).
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)
any later version.
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. */
/* As a special exception, if you link this library with other files,
some of which are compiled with GCC, to produce an executable,
this library does not by itself cause the resulting executable
to be covered by the GNU General Public License.
This exception does not however invalidate any other reasons why
the executable file might be covered by the GNU General Public License. */
#ifndef GFOR_IO_H
#define GFOR_IO_H
/* IO library include. */
#include "libgfortran.h"
#include <setjmp.h>
#include <gthr.h>
/* Basic types used in data transfers. */
typedef enum
{ BT_NULL, BT_INTEGER, BT_LOGICAL, BT_CHARACTER, BT_REAL,
BT_COMPLEX
}
bt;
struct st_parameter_dt;
typedef struct stream
{
char *(*alloc_w_at) (struct stream *, int *);
try (*sfree) (struct stream *);
try (*close) (struct stream *);
try (*seek) (struct stream *, gfc_offset);
try (*trunc) (struct stream *);
int (*read) (struct stream *, void *, size_t *);
int (*write) (struct stream *, const void *, size_t *);
try (*set) (struct stream *, int, size_t);
}
stream;
typedef enum
{ SYNC_BUFFERED, SYNC_UNBUFFERED, ASYNC }
io_mode;
/* Macros for doing file I/O given a stream. */
#define sfree(s) ((s)->sfree)(s)
#define sclose(s) ((s)->close)(s)
#define salloc_w(s, len) ((s)->alloc_w_at)(s, len)
#define sseek(s, pos) ((s)->seek)(s, pos)
#define struncate(s) ((s)->trunc)(s)
#define sread(s, buf, nbytes) ((s)->read)(s, buf, nbytes)
#define swrite(s, buf, nbytes) ((s)->write)(s, buf, nbytes)
#define sset(s, c, n) ((s)->set)(s, c, n)
/* Macros for testing what kinds of I/O we are doing. */
#define is_array_io(dtp) ((dtp)->internal_unit_desc)
#define is_internal_unit(dtp) ((dtp)->u.p.unit_is_internal)
#define is_stream_io(dtp) ((dtp)->u.p.current_unit->flags.access == ACCESS_STREAM)
/* The array_loop_spec contains the variables for the loops over index ranges
that are encountered. Since the variables can be negative, ssize_t
is used. */
typedef struct array_loop_spec
{
/* Index counter for this dimension. */
ssize_t idx;
/* Start for the index counter. */
ssize_t start;
/* End for the index counter. */
ssize_t end;
/* Step for the index counter. */
ssize_t step;
}
array_loop_spec;
/* Representation of a namelist object in libgfortran
Namelist Records
&GROUPNAME OBJECT=value[s] [,OBJECT=value[s]].../
or
&GROUPNAME OBJECT=value[s] [,OBJECT=value[s]]...&END
The object can be a fully qualified, compound name for an intrinsic
type, derived types or derived type components. So, a substring
a(:)%b(4)%ch(2:4)(1:7) has to be treated correctly in namelist
read. Hence full information about the structure of the object has
to be available to list_read.c and write.
These requirements are met by the following data structures.
namelist_info type contains all the scalar information about the
object and arrays of descriptor_dimension and array_loop_spec types for
arrays. */
typedef struct namelist_type
{
/* Object type, stored as GFC_DTYPE_xxxx. */
bt type;
/* Object name. */
char * var_name;
/* Address for the start of the object's data. */
void * mem_pos;
/* Flag to show that a read is to be attempted for this node. */
int touched;
/* Length of intrinsic type in bytes. */
int len;
/* Rank of the object. */
int var_rank;
/* Overall size of the object in bytes. */
index_type size;
/* Length of character string. */
index_type string_length;
descriptor_dimension * dim;
array_loop_spec * ls;
struct namelist_type * next;
}
namelist_info;
/* Options for the OPEN statement. */
typedef enum
{ ACCESS_SEQUENTIAL, ACCESS_DIRECT, ACCESS_APPEND, ACCESS_STREAM,
ACCESS_UNSPECIFIED
}
unit_access;
typedef enum
{ ACTION_READ, ACTION_WRITE, ACTION_READWRITE,
ACTION_UNSPECIFIED
}
unit_action;
typedef enum
{ BLANK_NULL, BLANK_ZERO, BLANK_UNSPECIFIED }
unit_blank;
typedef enum
{ DELIM_NONE, DELIM_APOSTROPHE, DELIM_QUOTE,
DELIM_UNSPECIFIED
}
unit_delim;
typedef enum
{ FORM_FORMATTED, FORM_UNFORMATTED, FORM_UNSPECIFIED }
unit_form;
typedef enum
{ POSITION_ASIS, POSITION_REWIND, POSITION_APPEND,
POSITION_UNSPECIFIED
}
unit_position;
typedef enum
{ STATUS_UNKNOWN, STATUS_OLD, STATUS_NEW, STATUS_SCRATCH,
STATUS_REPLACE, STATUS_UNSPECIFIED
}
unit_status;
typedef enum
{ PAD_YES, PAD_NO, PAD_UNSPECIFIED }
unit_pad;
typedef enum
{ DECIMAL_POINT, DECIMAL_COMMA, DECIMAL_UNSPECIFIED }
unit_decimal;
typedef enum
{ ENCODING_UTF8, ENCODING_DEFAULT, ENCODING_UNSPECIFIED }
unit_encoding;
typedef enum
{ ROUND_UP, ROUND_DOWN, ROUND_ZERO, ROUND_NEAREST, ROUND_COMPATIBLE,
ROUND_PROCDEFINED, ROUND_UNSPECIFIED }
unit_round;
/* NOTE: unit_sign must correspond with the sign_status enumerator in
st_parameter_dt to not break the ABI. */
typedef enum
{ SIGN_PROCDEFINED, SIGN_SUPPRESS, SIGN_PLUS, SIGN_UNSPECIFIED }
unit_sign;
typedef enum
{ ADVANCE_YES, ADVANCE_NO, ADVANCE_UNSPECIFIED }
unit_advance;
typedef enum
{READING, WRITING}
unit_mode;
typedef enum
{ ASYNC_YES, ASYNC_NO, ASYNC_UNSPECIFIED }
unit_async;
#define CHARACTER1(name) \
char * name; \
gfc_charlen_type name ## _len
#define CHARACTER2(name) \
gfc_charlen_type name ## _len; \
char * name
typedef struct
{
st_parameter_common common;
GFC_INTEGER_4 recl_in;
CHARACTER2 (file);
CHARACTER1 (status);
CHARACTER2 (access);
CHARACTER1 (form);
CHARACTER2 (blank);
CHARACTER1 (position);
CHARACTER2 (action);
CHARACTER1 (delim);
CHARACTER2 (pad);
CHARACTER1 (convert);
CHARACTER2 (decimal);
CHARACTER1 (encoding);
CHARACTER2 (round);
CHARACTER1 (sign);
CHARACTER2 (asynchronous);
}
st_parameter_open;
#define IOPARM_CLOSE_HAS_STATUS (1 << 7)
typedef struct
{
st_parameter_common common;
CHARACTER1 (status);
}
st_parameter_close;
typedef struct
{
st_parameter_common common;
}
st_parameter_filepos;
#define IOPARM_INQUIRE_HAS_EXIST (1 << 7)
#define IOPARM_INQUIRE_HAS_OPENED (1 << 8)
#define IOPARM_INQUIRE_HAS_NUMBER (1 << 9)
#define IOPARM_INQUIRE_HAS_NAMED (1 << 10)
#define IOPARM_INQUIRE_HAS_NEXTREC (1 << 11)
#define IOPARM_INQUIRE_HAS_RECL_OUT (1 << 12)
#define IOPARM_INQUIRE_HAS_STRM_POS_OUT (1 << 13)
#define IOPARM_INQUIRE_HAS_FILE (1 << 14)
#define IOPARM_INQUIRE_HAS_ACCESS (1 << 15)
#define IOPARM_INQUIRE_HAS_FORM (1 << 16)
#define IOPARM_INQUIRE_HAS_BLANK (1 << 17)
#define IOPARM_INQUIRE_HAS_POSITION (1 << 18)
#define IOPARM_INQUIRE_HAS_ACTION (1 << 19)
#define IOPARM_INQUIRE_HAS_DELIM (1 << 20)
#define IOPARM_INQUIRE_HAS_PAD (1 << 21)
#define IOPARM_INQUIRE_HAS_NAME (1 << 22)
#define IOPARM_INQUIRE_HAS_SEQUENTIAL (1 << 23)
#define IOPARM_INQUIRE_HAS_DIRECT (1 << 24)
#define IOPARM_INQUIRE_HAS_FORMATTED (1 << 25)
#define IOPARM_INQUIRE_HAS_UNFORMATTED (1 << 26)
#define IOPARM_INQUIRE_HAS_READ (1 << 27)
#define IOPARM_INQUIRE_HAS_WRITE (1 << 28)
#define IOPARM_INQUIRE_HAS_READWRITE (1 << 29)
#define IOPARM_INQUIRE_HAS_CONVERT (1 << 30)
#define IOPARM_INQUIRE_HAS_FLAGS2 (1 << 31)
#define IOPARM_INQUIRE_HAS_ASYNCHRONOUS (1 << 0)
#define IOPARM_INQUIRE_HAS_DECIMAL (1 << 1)
#define IOPARM_INQUIRE_HAS_ENCODING (1 << 2)
#define IOPARM_INQUIRE_HAS_PENDING (1 << 3)
#define IOPARM_INQUIRE_HAS_ROUND (1 << 4)
#define IOPARM_INQUIRE_HAS_SIGN (1 << 5)
#define IOPARM_INQUIRE_HAS_SIZE (1 << 6)
#define IOPARM_INQUIRE_HAS_ID (1 << 7)
typedef struct
{
st_parameter_common common;
GFC_INTEGER_4 *exist, *opened, *number, *named;
GFC_INTEGER_4 *nextrec, *recl_out;
GFC_IO_INT *strm_pos_out;
CHARACTER1 (file);
CHARACTER2 (access);
CHARACTER1 (form);
CHARACTER2 (blank);
CHARACTER1 (position);
CHARACTER2 (action);
CHARACTER1 (delim);
CHARACTER2 (pad);
CHARACTER1 (name);
CHARACTER2 (sequential);
CHARACTER1 (direct);
CHARACTER2 (formatted);
CHARACTER1 (unformatted);
CHARACTER2 (read);
CHARACTER1 (write);
CHARACTER2 (readwrite);
CHARACTER1 (convert);
GFC_INTEGER_4 flags2;
CHARACTER1 (asynchronous);
CHARACTER2 (decimal);
CHARACTER1 (encoding);
CHARACTER2 (pending);
CHARACTER1 (round);
CHARACTER2 (sign);
GFC_INTEGER_4 *size;
GFC_INTEGER_4 *id;
}
st_parameter_inquire;
struct gfc_unit;
struct format_data;
#define IOPARM_DT_LIST_FORMAT (1 << 7)
#define IOPARM_DT_NAMELIST_READ_MODE (1 << 8)
#define IOPARM_DT_HAS_REC (1 << 9)
#define IOPARM_DT_HAS_SIZE (1 << 10)
#define IOPARM_DT_HAS_IOLENGTH (1 << 11)
#define IOPARM_DT_HAS_FORMAT (1 << 12)
#define IOPARM_DT_HAS_ADVANCE (1 << 13)
#define IOPARM_DT_HAS_INTERNAL_UNIT (1 << 14)
#define IOPARM_DT_HAS_NAMELIST_NAME (1 << 15)
#define IOPARM_DT_HAS_ID (1 << 16)
#define IOPARM_DT_HAS_POS (1 << 17)
#define IOPARM_DT_HAS_ASYNCHRONOUS (1 << 18)
#define IOPARM_DT_HAS_BLANK (1 << 19)
#define IOPARM_DT_HAS_DECIMAL (1 << 20)
#define IOPARM_DT_HAS_DELIM (1 << 21)
#define IOPARM_DT_HAS_PAD (1 << 22)
#define IOPARM_DT_HAS_ROUND (1 << 23)
#define IOPARM_DT_HAS_SIGN (1 << 24)
/* Internal use bit. */
#define IOPARM_DT_IONML_SET (1 << 31)
typedef struct st_parameter_dt
{
st_parameter_common common;
GFC_IO_INT rec;
GFC_IO_INT *size, *iolength;
gfc_array_char *internal_unit_desc;
CHARACTER1 (format);
CHARACTER2 (advance);
CHARACTER1 (internal_unit);
CHARACTER2 (namelist_name);
GFC_IO_INT *id;
GFC_IO_INT pos;
CHARACTER1 (asynchronous);
CHARACTER2 (blank);
CHARACTER1 (decimal);
CHARACTER2 (delim);
CHARACTER1 (pad);
CHARACTER2 (round);
CHARACTER1 (sign);
/* Private part of the structure. The compiler just needs
to reserve enough space. */
union
{
struct
{
void (*transfer) (struct st_parameter_dt *, bt, void *, int,
size_t, size_t);
struct gfc_unit *current_unit;
/* Item number in a formatted data transfer. Also used in namelist
read_logical as an index into line_buffer. */
int item_count;
unit_mode mode;
unit_blank blank_status;
unit_pad pad_status;
enum { SIGN_S, SIGN_SS, SIGN_SP } sign_status;
int scale_factor;
int max_pos; /* Maximum righthand column written to. */
/* Number of skips + spaces to be done for T and X-editing. */
int skips;
/* Number of spaces to be done for T and X-editing. */
int pending_spaces;
/* Whether an EOR condition was encountered. Value is:
0 if no EOR was encountered
1 if an EOR was encountered due to a 1-byte marker (LF)
2 if an EOR was encountered due to a 2-bytes marker (CRLF) */
int sf_seen_eor;
unit_advance advance_status;
unit_decimal decimal_status;
unit_delim delim_status;
unsigned reversion_flag : 1; /* Format reversion has occurred. */
unsigned first_item : 1;
unsigned seen_dollar : 1;
unsigned eor_condition : 1;
unsigned no_leading_blank : 1;
unsigned char_flag : 1;
unsigned input_complete : 1;
unsigned at_eol : 1;
unsigned comma_flag : 1;
/* A namelist specific flag used in the list directed library
to flag that calls are being made from namelist read (eg. to
ignore comments or to treat '/' as a terminator) */
unsigned namelist_mode : 1;
/* A namelist specific flag used in the list directed library
to flag read errors and return, so that an attempt can be
made to read a new object name. */
unsigned nml_read_error : 1;
/* A sequential formatted read specific flag used to signal that a
character string is being read so don't use commas to shorten a
formatted field width. */
unsigned sf_read_comma : 1;
/* A namelist specific flag used to enable reading input from
line_buffer for logical reads. */
unsigned line_buffer_enabled : 1;
/* An internal unit specific flag used to identify that the associated
unit is internal. */
unsigned unit_is_internal : 1;
/* An internal unit specific flag to signify an EOF condition for list
directed read. */
unsigned at_eof : 1;
/* 16 unused bits. */
char last_char;
char nml_delim;
int repeat_count;
int saved_length;
int saved_used;
bt saved_type;
char *saved_string;
char *scratch;
char *line_buffer;
struct format_data *fmt;
jmp_buf *eof_jump;
namelist_info *ionml;
/* A flag used to identify when a non-standard expanded namelist read
has occurred. */
int expanded_read;
/* Storage area for values except for strings. Must be large
enough to hold a complex value (two reals) of the largest
kind. */
char value[32];
gfc_offset size_used;
} p;
/* This pad size must be equal to the pad_size declared in
trans-io.c (gfc_build_io_library_fndecls). The above structure
must be smaller or equal to this array. */
char pad[16 * sizeof (char *) + 32 * sizeof (int)];
} u;
}
st_parameter_dt;
/* Ensure st_parameter_dt's u.pad is bigger or equal to u.p. */
extern char check_st_parameter_dt[sizeof (((st_parameter_dt *) 0)->u.pad)
>= sizeof (((st_parameter_dt *) 0)->u.p)
? 1 : -1];
#define IOPARM_WAIT_HAS_ID (1 << 7)
typedef struct
{
st_parameter_common common;
CHARACTER1 (id);
}
st_parameter_wait;
#undef CHARACTER1
#undef CHARACTER2
typedef struct
{
unit_access access;
unit_action action;
unit_blank blank;
unit_delim delim;
unit_form form;
int is_notpadded;
unit_position position;
unit_status status;
unit_pad pad;
unit_decimal decimal;
unit_encoding encoding;
unit_round round;
unit_sign sign;
unit_convert convert;
int has_recl;
unit_async async;
}
unit_flags;
/* Formatting buffer. This is a temporary scratch buffer. Currently used only
by formatted writes. After every
formatted write statement, this buffer is flushed. This buffer is needed since
not all devices are seekable, and T or TL edit descriptors require
moving backwards in the record. However, advance='no' complicates the
situation, so the buffer must only be partially flushed from the end of the
last flush until the current position in the record. */
typedef struct fbuf
{
char *buf; /* Start of buffer. */
size_t len; /* Length of buffer. */
size_t act; /* Active bytes in buffer. */
size_t flushed; /* Flushed bytes from beginning of buffer. */
size_t pos; /* Current position in buffer. */
}
fbuf;
typedef struct gfc_unit
{
int unit_number;
stream *s;
/* Treap links. */
struct gfc_unit *left, *right;
int priority;
int read_bad, current_record, saved_pos, previous_nonadvancing_write;
enum
{ NO_ENDFILE, AT_ENDFILE, AFTER_ENDFILE }
endfile;
unit_mode mode;
unit_flags flags;
/* recl -- Record length of the file.
last_record -- Last record number read or written
maxrec -- Maximum record number in a direct access file
bytes_left -- Bytes left in current record.
strm_pos -- Current position in file for STREAM I/O.
recl_subrecord -- Maximum length for subrecord.
bytes_left_subrecord -- Bytes left in current subrecord. */
gfc_offset recl, last_record, maxrec, bytes_left, strm_pos,
recl_subrecord, bytes_left_subrecord;
/* Set to 1 if we have read a subrecord. */
int continued;
__gthread_mutex_t lock;
/* Number of threads waiting to acquire this unit's lock.
When non-zero, close_unit doesn't only removes the unit
from the UNIT_ROOT tree, but doesn't free it and the
last of the waiting threads will do that.
This must be either atomically increased/decreased, or
always guarded by UNIT_LOCK. */
int waiting;
/* Flag set by close_unit if the unit as been closed.
Must be manipulated under unit's lock. */
int closed;
/* For traversing arrays */
array_loop_spec *ls;
int rank;
int file_len;
char *file;
/* Formatting buffer. */
struct fbuf *fbuf;
}
gfc_unit;
/* Format tokens. Only about half of these can be stored in the
format nodes. */
typedef enum
{
FMT_NONE = 0, FMT_UNKNOWN, FMT_SIGNED_INT, FMT_ZERO, FMT_POSINT, FMT_PERIOD,
FMT_COMMA, FMT_COLON, FMT_SLASH, FMT_DOLLAR, FMT_T, FMT_TR, FMT_TL,
FMT_LPAREN, FMT_RPAREN, FMT_X, FMT_S, FMT_SS, FMT_SP, FMT_STRING,
FMT_BADSTRING, FMT_P, FMT_I, FMT_B, FMT_BN, FMT_BZ, FMT_O, FMT_Z, FMT_F,
FMT_E, FMT_EN, FMT_ES, FMT_G, FMT_L, FMT_A, FMT_D, FMT_H, FMT_END, FMT_DC,
FMT_DP
}
format_token;
/* Format nodes. A format string is converted into a tree of these
structures, which is traversed as part of a data transfer statement. */
typedef struct fnode
{
format_token format;
int repeat;
struct fnode *next;
char *source;
union
{
struct
{
int w, d, e;
}
real;
struct
{
int length;
char *p;
}
string;
struct
{
int w, m;
}
integer;
int w;
int k;
int r;
int n;
struct fnode *child;
}
u;
/* Members for traversing the tree during data transfer. */
int count;
struct fnode *current;
}
fnode;
/* unix.c */
extern int move_pos_offset (stream *, int);
internal_proto(move_pos_offset);
extern int compare_files (stream *, stream *);
internal_proto(compare_files);
extern stream *open_external (st_parameter_open *, unit_flags *);
internal_proto(open_external);
extern stream *open_internal (char *, int, gfc_offset);
internal_proto(open_internal);
extern stream *input_stream (void);
internal_proto(input_stream);
extern stream *output_stream (void);
internal_proto(output_stream);
extern stream *error_stream (void);
internal_proto(error_stream);
extern int compare_file_filename (gfc_unit *, const char *, int);
internal_proto(compare_file_filename);
extern gfc_unit *find_file (const char *file, gfc_charlen_type file_len);
internal_proto(find_file);
extern int stream_at_bof (stream *);
internal_proto(stream_at_bof);
extern int stream_at_eof (stream *);
internal_proto(stream_at_eof);
extern int delete_file (gfc_unit *);
internal_proto(delete_file);
extern int file_exists (const char *file, gfc_charlen_type file_len);
internal_proto(file_exists);
extern const char *inquire_sequential (const char *, int);
internal_proto(inquire_sequential);
extern const char *inquire_direct (const char *, int);
internal_proto(inquire_direct);
extern const char *inquire_formatted (const char *, int);
internal_proto(inquire_formatted);
extern const char *inquire_unformatted (const char *, int);
internal_proto(inquire_unformatted);
extern const char *inquire_read (const char *, int);
internal_proto(inquire_read);
extern const char *inquire_write (const char *, int);
internal_proto(inquire_write);
extern const char *inquire_readwrite (const char *, int);
internal_proto(inquire_readwrite);
extern gfc_offset file_length (stream *);
internal_proto(file_length);
extern gfc_offset file_position (stream *);
internal_proto(file_position);
extern int is_seekable (stream *);
internal_proto(is_seekable);
extern int is_special (stream *);
internal_proto(is_special);
extern int is_preconnected (stream *);
internal_proto(is_preconnected);
extern void flush_if_preconnected (stream *);
internal_proto(flush_if_preconnected);
extern void empty_internal_buffer(stream *);
internal_proto(empty_internal_buffer);
extern try flush (stream *);
internal_proto(flush);
extern int stream_isatty (stream *);
internal_proto(stream_isatty);
extern char * stream_ttyname (stream *);
internal_proto(stream_ttyname);
extern gfc_offset stream_offset (stream *s);
internal_proto(stream_offset);
extern int unpack_filename (char *, const char *, int);
internal_proto(unpack_filename);
/* unit.c */
/* Maximum file offset, computed at library initialization time. */
extern gfc_offset max_offset;
internal_proto(max_offset);
/* Unit tree root. */
extern gfc_unit *unit_root;
internal_proto(unit_root);
extern __gthread_mutex_t unit_lock;
internal_proto(unit_lock);
extern int close_unit (gfc_unit *);
internal_proto(close_unit);
extern gfc_unit *get_internal_unit (st_parameter_dt *);
internal_proto(get_internal_unit);
extern void free_internal_unit (st_parameter_dt *);
internal_proto(free_internal_unit);
extern gfc_unit *find_unit (int);
internal_proto(find_unit);
extern gfc_unit *find_or_create_unit (int);
internal_proto(find_or_create_unit);
extern gfc_unit *get_unit (st_parameter_dt *, int);
internal_proto(get_unit);
extern void unlock_unit (gfc_unit *);
internal_proto(unlock_unit);
extern void update_position (gfc_unit *);
internal_proto(update_position);
extern void finish_last_advance_record (gfc_unit *u);
internal_proto (finish_last_advance_record);
/* open.c */
extern gfc_unit *new_unit (st_parameter_open *, gfc_unit *, unit_flags *);
internal_proto(new_unit);
/* format.c */
extern void parse_format (st_parameter_dt *);
internal_proto(parse_format);
extern const fnode *next_format (st_parameter_dt *);
internal_proto(next_format);
extern void unget_format (st_parameter_dt *, const fnode *);
internal_proto(unget_format);
extern void format_error (st_parameter_dt *, const fnode *, const char *);
internal_proto(format_error);
extern void free_format_data (st_parameter_dt *);
internal_proto(free_format_data);
/* transfer.c */
#define SCRATCH_SIZE 300
extern const char *type_name (bt);
internal_proto(type_name);
extern try read_block_form (st_parameter_dt *, void *, size_t *);
internal_proto(read_block_form);
extern char *read_sf (st_parameter_dt *, int *, int);
internal_proto(read_sf);
extern void *write_block (st_parameter_dt *, int);
internal_proto(write_block);
extern gfc_offset next_array_record (st_parameter_dt *, array_loop_spec *,
int*);
internal_proto(next_array_record);
extern gfc_offset init_loop_spec (gfc_array_char *, array_loop_spec *,
gfc_offset *);
internal_proto(init_loop_spec);
extern void next_record (st_parameter_dt *, int);
internal_proto(next_record);
extern void reverse_memcpy (void *, const void *, size_t);
internal_proto (reverse_memcpy);
extern void st_wait (st_parameter_wait *);
export_proto(st_wait);
/* read.c */
extern void set_integer (void *, GFC_INTEGER_LARGEST, int);
internal_proto(set_integer);
extern GFC_UINTEGER_LARGEST max_value (int, int);
internal_proto(max_value);
extern int convert_real (st_parameter_dt *, void *, const char *, int);
internal_proto(convert_real);
extern void read_a (st_parameter_dt *, const fnode *, char *, int);
internal_proto(read_a);
extern void read_a_char4 (st_parameter_dt *, const fnode *, char *, int);
internal_proto(read_a);
extern void read_f (st_parameter_dt *, const fnode *, char *, int);
internal_proto(read_f);
extern void read_l (st_parameter_dt *, const fnode *, char *, int);
internal_proto(read_l);
extern void read_x (st_parameter_dt *, int);
internal_proto(read_x);
extern void read_radix (st_parameter_dt *, const fnode *, char *, int, int);
internal_proto(read_radix);
extern void read_decimal (st_parameter_dt *, const fnode *, char *, int);
internal_proto(read_decimal);
/* list_read.c */
extern void list_formatted_read (st_parameter_dt *, bt, void *, int, size_t,
size_t);
internal_proto(list_formatted_read);
extern void finish_list_read (st_parameter_dt *);
internal_proto(finish_list_read);
extern void namelist_read (st_parameter_dt *);
internal_proto(namelist_read);
extern void namelist_write (st_parameter_dt *);
internal_proto(namelist_write);
/* write.c */
extern void write_a (st_parameter_dt *, const fnode *, const char *, int);
internal_proto(write_a);
extern void write_a_char4 (st_parameter_dt *, const fnode *, const char *, int);
internal_proto(write_a_char4);
extern void write_b (st_parameter_dt *, const fnode *, const char *, int);
internal_proto(write_b);
extern void write_d (st_parameter_dt *, const fnode *, const char *, int);
internal_proto(write_d);
extern void write_e (st_parameter_dt *, const fnode *, const char *, int);
internal_proto(write_e);
extern void write_en (st_parameter_dt *, const fnode *, const char *, int);
internal_proto(write_en);
extern void write_es (st_parameter_dt *, const fnode *, const char *, int);
internal_proto(write_es);
extern void write_f (st_parameter_dt *, const fnode *, const char *, int);
internal_proto(write_f);
extern void write_i (st_parameter_dt *, const fnode *, const char *, int);
internal_proto(write_i);
extern void write_l (st_parameter_dt *, const fnode *, char *, int);
internal_proto(write_l);
extern void write_o (st_parameter_dt *, const fnode *, const char *, int);
internal_proto(write_o);
extern void write_real (st_parameter_dt *, const char *, int);
internal_proto(write_real);
extern void write_x (st_parameter_dt *, int, int);
internal_proto(write_x);
extern void write_z (st_parameter_dt *, const fnode *, const char *, int);
internal_proto(write_z);
extern void list_formatted_write (st_parameter_dt *, bt, void *, int, size_t,
size_t);
internal_proto(list_formatted_write);
/* size_from_kind.c */
extern size_t size_from_real_kind (int);
internal_proto(size_from_real_kind);
extern size_t size_from_complex_kind (int);
internal_proto(size_from_complex_kind);
/* fbuf.c */
extern void fbuf_init (gfc_unit *, size_t);
internal_proto(fbuf_init);
extern void fbuf_destroy (gfc_unit *);
internal_proto(fbuf_destroy);
extern void fbuf_reset (gfc_unit *);
internal_proto(fbuf_reset);
extern char * fbuf_alloc (gfc_unit *, size_t);
internal_proto(fbuf_alloc);
extern int fbuf_flush (gfc_unit *, int);
internal_proto(fbuf_flush);
extern int fbuf_seek (gfc_unit *, gfc_offset);
internal_proto(fbuf_seek);
/* lock.c */
extern void free_ionml (st_parameter_dt *);
internal_proto(free_ionml);
static inline void
inc_waiting_locked (gfc_unit *u)
{
#ifdef HAVE_SYNC_FETCH_AND_ADD
(void) __sync_fetch_and_add (&u->waiting, 1);
#else
u->waiting++;
#endif
}
static inline int
predec_waiting_locked (gfc_unit *u)
{
#ifdef HAVE_SYNC_FETCH_AND_ADD
return __sync_add_and_fetch (&u->waiting, -1);
#else
return --u->waiting;
#endif
}
static inline void
dec_waiting_unlocked (gfc_unit *u)
{
#ifdef HAVE_SYNC_FETCH_AND_ADD
(void) __sync_fetch_and_add (&u->waiting, -1);
#else
__gthread_mutex_lock (&unit_lock);
u->waiting--;
__gthread_mutex_unlock (&unit_lock);
#endif
}
#endif