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 /* st.c -- Implementation File (module.c template V1.0)
    Copyright (C) 1995 Free Software Foundation, Inc.
    Contributed by James Craig Burley.

 This file is part of GNU Fortran.

 GNU Fortran 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.

 GNU Fortran 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 GNU Fortran; see the file COPYING.  If not, write to
 the Free Software Foundation, 59 Temple Place - Suite 330, Boston, MA
 02111-1307, USA.

    Related Modules:
       None

    Description:
       The high-level input level to statement handling for the rest of the
       FFE.  ffest_first is the first state for the lexer to invoke to start
       a statement.  A statement normally starts with a NUMBER token (to indicate
       a label def) followed by a NAME token (to indicate what kind of statement
       it is), though of course the NUMBER token may be omitted.	 ffest_first
       gathers the first NAME token and returns a state of ffest_second_,
       where the trailing underscore means "internal to ffest" and thus outside
       users should not depend on this.	ffest_second_ then looks at the second
       token in conjunction with the first, decides what possible statements are
       meant, and tries each possible statement in turn, from most likely to
       least likely.  A successful attempt currently is recorded, and further
       successful attempts by other possibilities raise an assertion error in
       ffest_confirmed (this is to detect ambiguities).	A failure in an
       attempt is signaled by calling ffest_ffebad_start; this results in the
       next token sent by ffest_save_ (the intermediary when more than one
       possible statement exists) being EOS to shut down processing and the next
       possibility tried.

       When all possibilities have been tried, the successful one is retried with
       inhibition turned off (FALSE) as reported by ffest_is_inhibited().  If
       there is no successful one, the first one is retried so the user gets to
       see the error messages.

       In the future, after syntactic bugs have been reasonably shaken out and
       ambiguities thus detected, the first successful possibility will be
       enabled (inhibited goes FALSE) as soon as it confirms success by calling
       ffest_confirmed, thus retrying the possibility will not be necessary.

       The only complication in all this is that expression handling is
       happening while possibilities are inhibited.  It is up to the expression
       handler, conceptually, to not make any changes to its knowledge base for
       variable names and so on when inhibited that cannot be undone if
       the current possibility fails (shuts down via ffest_ffebad_start).  In
       fact, this business is handled not be ffeexpr, but by lower levels.

       ffesta functions serve only to provide information used in syntactic
       processing of possible statements, and thus may not make changes to the
       knowledge base for variables and such.

       ffestb functions perform the syntactic analysis for possible statements,
       and thus again may not make changes to the knowledge base except under the
       auspices of ffeexpr and its subordinates, changes which can be undone when
       necessary.

       ffestc functions perform the semantic analysis for the chosen statement,
       and thus may change the knowledge base as necessary since they are invoked
       by ffestb functions only after a given statement is confirmed and
       enabled.	Note, however, that a few ffestc functions (identified by
       their statement names rather than grammar numbers) indicate valid forms
       that are, outside of any context, ambiguous, such as ELSE WHERE and
       PRIVATE; these functions should make a quick decision as to what is
       intended and dispatch to the appropriate specific ffestc function.

       ffestd functions actually implement statements.  When called, the
       statement is considered valid and is either an executable statement or
       a nonexecutable statement with direct-output results.  For example, CALL,
       GOTO, and assignment statements pass through ffestd because they are
       executable; DATA statements pass through because they map directly to the
       output file (or at least might so map); ENTRY statements also pass through
       because they essentially affect code generation in an immediate way;
       whereas INTEGER, SAVE, and SUBROUTINE statements do not go through
       ffestd functions because they merely update the knowledge base.

    Modifications:
 */

 /* Include files. */

 #include "proj.h"
 #include "st.h"
 #include "bad.h"
 #include "lex.h"
 #include "sta.h"
 #include "stb.h"
 #include "stc.h"
 #include "std.h"
 #include "ste.h"
 #include "stp.h"
 #include "str.h"
 #include "sts.h"
 #include "stt.h"
 #include "stu.h"
 #include "stv.h"
 #include "stw.h"

 /* Externals defined here. */


 /* Simple definitions and enumerations. */


 /* Internal typedefs. */


 /* Private include files. */


 /* Internal structure definitions. */


 /* Static objects accessed by functions in this module. */


 /* Static functions (internal). */


 /* Internal macros. */


 /* ffest_confirmed -- Confirm current possibility as only one

    ffest_confirmed();

    Sets the confirmation flag.	During debugging for ambiguous constructs,
    asserts that the confirmation flag for a previous possibility has not
    yet been set.  */

 void
 ffest_confirmed ()
 {
   ffesta_confirmed ();
 }

 /* ffest_eof -- End of (non-INCLUDEd) source file

    ffest_eof();

    Call after piping tokens through ffest_first, where the most recent
    token sent through must be EOS.

    20-Feb-91  JCB  1.1
       Put new EOF token in ffesta_tokens[0], not NULL, because too much
       code expects something there for error reporting and the like.  Also,
       do basically the same things ffest_second and ffesta_zero do for
       processing a statement (make and destroy pools, et cetera).  */

 void
 ffest_eof ()
 {
   ffesta_eof ();
 }

 /* ffest_ffebad_here_current_stmt -- ffebad_here with ptr to current stmt

    ffest_ffebad_here_current_stmt(0);

    Outsiders can call this fn if they have no more convenient place to
    point to (via a token or pair of ffewhere objects) and they know a
    current, useful statement is being evaluted by ffest (i.e. they are
    being called from ffestb, ffestc, ffestd, ... functions).  */

 void
 ffest_ffebad_here_current_stmt (ffebadIndex i)
 {
   ffesta_ffebad_here_current_stmt (i);
 }

 /* ffest_ffebad_here_doiter -- Calls ffebad_here with ptr to DO iter var

    ffesymbol s;
    // call ffebad_start first, of course.
    ffest_ffebad_here_doiter(0,s);
    // call ffebad_finish afterwards, naturally.

    Searches the stack of blocks backwards for a DO loop that has s
    as its iteration variable, then calls ffebad_here with pointers to
    that particular reference to the variable.  Crashes if the DO loop
    can't be found.  */

 void
 ffest_ffebad_here_doiter (ffebadIndex i, ffesymbol s)
 {
   ffestc_ffebad_here_doiter (i, s);
 }

 /* ffest_ffebad_start -- Start a possibly inhibited error report

    if (ffest_ffebad_start(FFEBAD_SOME_ERROR))
        {
        ffebad_here, ffebad_string ...;
        ffebad_finish();
        }

    Call if the error might indicate that ffest is evaluating the wrong
    statement form, instead of calling ffebad_start directly.  If ffest
    is choosing between forms, it will return FALSE, send an EOS/SEMICOLON
    token through as the next token (if the current one isn't already one
    of those), and try another possible form.  Otherwise, ffebad_start is
    called with the argument and TRUE returned.	*/

 bool
 ffest_ffebad_start (ffebad errnum)
 {
   return ffesta_ffebad_start (errnum);
 }

 /* ffest_first -- Parse the first token in a statement

    return ffest_first;	// to lexer.  */

 ffelexHandler
 ffest_first (ffelexToken t)
 {
   return ffesta_first (t);
 }

 /* ffest_init_0 -- Initialize for entire image invocation

    ffest_init_0();

    Call just once per invocation of the compiler (not once per invocation
    of the front end).

    Gets memory for the list of possibles once and for all, since this
    list never gets larger than a certain size (FFEST_maxPOSSIBLES_)
    and is not particularly large.  Initializes the array of pointers to
    this list.  Initializes the executable and nonexecutable lists.  */

 void
 ffest_init_0 ()
 {
   ffesta_init_0 ();
   ffestb_init_0 ();
   ffestc_init_0 ();
   ffestd_init_0 ();
   ffeste_init_0 ();
   ffestp_init_0 ();
   ffestr_init_0 ();
   ffests_init_0 ();
   ffestt_init_0 ();
   ffestu_init_0 ();
   ffestv_init_0 ();
   ffestw_init_0 ();
 }

 /* ffest_init_1 -- Initialize for entire image invocation

    ffest_init_1();

    Call just once per invocation of the compiler (not once per invocation
    of the front end).

    Gets memory for the list of possibles once and for all, since this
    list never gets larger than a certain size (FFEST_maxPOSSIBLES_)
    and is not particularly large.  Initializes the array of pointers to
    this list.  Initializes the executable and nonexecutable lists.  */

 void
 ffest_init_1 ()
 {
   ffesta_init_1 ();
   ffestb_init_1 ();
   ffestc_init_1 ();
   ffestd_init_1 ();
   ffeste_init_1 ();
   ffestp_init_1 ();
   ffestr_init_1 ();
   ffests_init_1 ();
   ffestt_init_1 ();
   ffestu_init_1 ();
   ffestv_init_1 ();
   ffestw_init_1 ();
 }

 /* ffest_init_2 -- Initialize for entire image invocation

    ffest_init_2();

    Call just once per invocation of the compiler (not once per invocation
    of the front end).

    Gets memory for the list of possibles once and for all, since this
    list never gets larger than a certain size (FFEST_maxPOSSIBLES_)
    and is not particularly large.  Initializes the array of pointers to
    this list.  Initializes the executable and nonexecutable lists.  */

 void
 ffest_init_2 ()
 {
   ffesta_init_2 ();
   ffestb_init_2 ();
   ffestc_init_2 ();
   ffestd_init_2 ();
   ffeste_init_2 ();
   ffestp_init_2 ();
   ffestr_init_2 ();
   ffests_init_2 ();
   ffestt_init_2 ();
   ffestu_init_2 ();
   ffestv_init_2 ();
   ffestw_init_2 ();
 }

 /* ffest_init_3 -- Initialize for any program unit

    ffest_init_3();  */

 void
 ffest_init_3 ()
 {
   ffesta_init_3 ();
   ffestb_init_3 ();
   ffestc_init_3 ();
   ffestd_init_3 ();
   ffeste_init_3 ();
   ffestp_init_3 ();
   ffestr_init_3 ();
   ffests_init_3 ();
   ffestt_init_3 ();
   ffestu_init_3 ();
   ffestv_init_3 ();
   ffestw_init_3 ();

   ffestw_display_state ();
 }

 /* ffest_init_4 -- Initialize for statement functions

    ffest_init_4();  */

 void
 ffest_init_4 ()
 {
   ffesta_init_4 ();
   ffestb_init_4 ();
   ffestc_init_4 ();
   ffestd_init_4 ();
   ffeste_init_4 ();
   ffestp_init_4 ();
   ffestr_init_4 ();
   ffests_init_4 ();
   ffestt_init_4 ();
   ffestu_init_4 ();
   ffestv_init_4 ();
   ffestw_init_4 ();
 }

 /* Test whether ENTRY statement is valid.

    Returns TRUE if current program unit is known to be FUNCTION or SUBROUTINE.
    Else returns FALSE.  */

 bool
 ffest_is_entry_valid ()
 {
   return ffesta_is_entry_valid;
 }

 /* ffest_is_inhibited -- Test whether the current possibility is inhibited

    if (!ffest_is_inhibited())
        // implement the statement.

    Just make sure the current possibility has been confirmed.  If anyone
    really needs to test whether the current possibility is inhibited prior
    to confirming it, that indicates a need to begin statement processing
    before it is certain that the given possibility is indeed the statement
    to be processed.  As of this writing, there does not appear to be such
    a need.  If there is, then when confirming a statement would normally
    immediately disable the inhibition (whereas currently we leave the
    confirmed statement disabled until we've tried the other possibilities,
    to check for ambiguities), we must check to see if the possibility has
    already tested for inhibition prior to confirmation and, if so, maintain
    inhibition until the end of the statement (which may be forced right
    away) and then rerun the entire statement from the beginning.  Otherwise,
    initial calls to ffestb functions won't have been made, but subsequent
    calls (after confirmation) will, which is wrong.  Of course, this all
    applies only to those statements implemented via multiple calls to
    ffestb, although if a statement requiring only a single ffestb call
    tested for inhibition prior to confirmation, it would likely mean that
    the ffestb call would be completely dropped without this mechanism.	*/

 bool
 ffest_is_inhibited ()
 {
   return ffesta_is_inhibited ();
 }

 /* ffest_seen_first_exec -- Test whether first executable stmt has been seen

    if (ffest_seen_first_exec())
        // No more spec stmts can be seen.

    In a case where, say, the first statement is PARAMETER(A)=B, FALSE
    will be returned while the PARAMETER statement is being run, and TRUE
    will be returned if it doesn't confirm and the assignment statement
    is being run.  */

 bool
 ffest_seen_first_exec ()
 {
   return ffesta_seen_first_exec;
 }

 /* Shut down current parsing possibility, but without bothering the
    user with a diagnostic if we're not inhibited.  */

 void
 ffest_shutdown ()
 {
   ffesta_shutdown ();
 }

 /* ffest_sym_end_transition -- Update symbol info just before end of unit

    ffesymbol s;
    ffest_sym_end_transition(s);	 */

 ffesymbol
 ffest_sym_end_transition (ffesymbol s)
 {
   return ffestu_sym_end_transition (s);
 }

 /* ffest_sym_exec_transition -- Update symbol just before first exec stmt

    ffesymbol s;
    ffest_sym_exec_transition(s);  */

 ffesymbol
 ffest_sym_exec_transition (ffesymbol s)
 {
   return ffestu_sym_exec_transition (s);
 }

 /* ffest_terminate_0 -- Terminate for entire image invocation

    ffest_terminate_0();	 */

 void
 ffest_terminate_0 ()
 {
   ffesta_terminate_0 ();
   ffestb_terminate_0 ();
   ffestc_terminate_0 ();
   ffestd_terminate_0 ();
   ffeste_terminate_0 ();
   ffestp_terminate_0 ();
   ffestr_terminate_0 ();
   ffests_terminate_0 ();
   ffestt_terminate_0 ();
   ffestu_terminate_0 ();
   ffestv_terminate_0 ();
   ffestw_terminate_0 ();
 }

 /* ffest_terminate_1 -- Terminate for source file

    ffest_terminate_1();	 */

 void
 ffest_terminate_1 ()
 {
   ffesta_terminate_1 ();
   ffestb_terminate_1 ();
   ffestc_terminate_1 ();
   ffestd_terminate_1 ();
   ffeste_terminate_1 ();
   ffestp_terminate_1 ();
   ffestr_terminate_1 ();
   ffests_terminate_1 ();
   ffestt_terminate_1 ();
   ffestu_terminate_1 ();
   ffestv_terminate_1 ();
   ffestw_terminate_1 ();
 }

 /* ffest_terminate_2 -- Terminate for outer program unit

    ffest_terminate_2();	 */

 void
 ffest_terminate_2 ()
 {
   ffesta_terminate_2 ();
   ffestb_terminate_2 ();
   ffestc_terminate_2 ();
   ffestd_terminate_2 ();
   ffeste_terminate_2 ();
   ffestp_terminate_2 ();
   ffestr_terminate_2 ();
   ffests_terminate_2 ();
   ffestt_terminate_2 ();
   ffestu_terminate_2 ();
   ffestv_terminate_2 ();
   ffestw_terminate_2 ();
 }

 /* ffest_terminate_3 -- Terminate for any program unit

    ffest_terminate_3();	 */

 void
 ffest_terminate_3 ()
 {
   ffesta_terminate_3 ();
   ffestb_terminate_3 ();
   ffestc_terminate_3 ();
   ffestd_terminate_3 ();
   ffeste_terminate_3 ();
   ffestp_terminate_3 ();
   ffestr_terminate_3 ();
   ffests_terminate_3 ();
   ffestt_terminate_3 ();
   ffestu_terminate_3 ();
   ffestv_terminate_3 ();
   ffestw_terminate_3 ();
 }

 /* ffest_terminate_4 -- Terminate for statement functions

    ffest_terminate_4();	 */

 void
 ffest_terminate_4 ()
 {
   ffesta_terminate_4 ();
   ffestb_terminate_4 ();
   ffestc_terminate_4 ();
   ffestd_terminate_4 ();
   ffeste_terminate_4 ();
   ffestp_terminate_4 ();
   ffestr_terminate_4 ();
   ffests_terminate_4 ();
   ffestt_terminate_4 ();
   ffestu_terminate_4 ();
   ffestv_terminate_4 ();
   ffestw_terminate_4 ();
 }
	/* st.c -- Implementation File (module.c template V1.0)
	Copyright (C) 1995 Free Software Foundation, Inc.
	Contributed by James Craig Burley.

	This file is part of GNU Fortran.

	GNU Fortran 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.

	GNU Fortran 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 GNU Fortran; see the file COPYING. If not, write to
	the Free Software Foundation, 59 Temple Place - Suite 330, Boston, MA
	02111-1307, USA.

	Related Modules:
	None

	Description:
	The high-level input level to statement handling for the rest of the
	FFE. ffest_first is the first state for the lexer to invoke to start
	a statement. A statement normally starts with a NUMBER token (to indicate
	a label def) followed by a NAME token (to indicate what kind of statement
	it is), though of course the NUMBER token may be omitted. ffest_first
	gathers the first NAME token and returns a state of ffest_second_,
	where the trailing underscore means "internal to ffest" and thus outside
	users should not depend on this. ffest_second_ then looks at the second
	token in conjunction with the first, decides what possible statements are
	meant, and tries each possible statement in turn, from most likely to
	least likely. A successful attempt currently is recorded, and further
	successful attempts by other possibilities raise an assertion error in
	ffest_confirmed (this is to detect ambiguities). A failure in an
	attempt is signaled by calling ffest_ffebad_start; this results in the
	next token sent by ffest_save_ (the intermediary when more than one
	possible statement exists) being EOS to shut down processing and the next
	possibility tried.

	When all possibilities have been tried, the successful one is retried with
	inhibition turned off (FALSE) as reported by ffest_is_inhibited(). If
	there is no successful one, the first one is retried so the user gets to
	see the error messages.

	In the future, after syntactic bugs have been reasonably shaken out and
	ambiguities thus detected, the first successful possibility will be
	enabled (inhibited goes FALSE) as soon as it confirms success by calling
	ffest_confirmed, thus retrying the possibility will not be necessary.

	The only complication in all this is that expression handling is
	happening while possibilities are inhibited. It is up to the expression
	handler, conceptually, to not make any changes to its knowledge base for
	variable names and so on when inhibited that cannot be undone if
	the current possibility fails (shuts down via ffest_ffebad_start). In
	fact, this business is handled not be ffeexpr, but by lower levels.

	ffesta functions serve only to provide information used in syntactic
	processing of possible statements, and thus may not make changes to the
	knowledge base for variables and such.

	ffestb functions perform the syntactic analysis for possible statements,
	and thus again may not make changes to the knowledge base except under the
	auspices of ffeexpr and its subordinates, changes which can be undone when
	necessary.

	ffestc functions perform the semantic analysis for the chosen statement,
	and thus may change the knowledge base as necessary since they are invoked
	by ffestb functions only after a given statement is confirmed and
	enabled. Note, however, that a few ffestc functions (identified by
	their statement names rather than grammar numbers) indicate valid forms
	that are, outside of any context, ambiguous, such as ELSE WHERE and
	PRIVATE; these functions should make a quick decision as to what is
	intended and dispatch to the appropriate specific ffestc function.

	ffestd functions actually implement statements. When called, the
	statement is considered valid and is either an executable statement or
	a nonexecutable statement with direct-output results. For example, CALL,
	GOTO, and assignment statements pass through ffestd because they are
	executable; DATA statements pass through because they map directly to the
	output file (or at least might so map); ENTRY statements also pass through
	because they essentially affect code generation in an immediate way;
	whereas INTEGER, SAVE, and SUBROUTINE statements do not go through
	ffestd functions because they merely update the knowledge base.

	Modifications:
	*/

	/* Include files. */

	#include "proj.h"
	#include "st.h"
	#include "bad.h"
	#include "lex.h"
	#include "sta.h"
	#include "stb.h"
	#include "stc.h"
	#include "std.h"
	#include "ste.h"
	#include "stp.h"
	#include "str.h"
	#include "sts.h"
	#include "stt.h"
	#include "stu.h"
	#include "stv.h"
	#include "stw.h"

	/* Externals defined here. */


	/* Simple definitions and enumerations. */


	/* Internal typedefs. */


	/* Private include files. */


	/* Internal structure definitions. */


	/* Static objects accessed by functions in this module. */


	/* Static functions (internal). */


	/* Internal macros. */


	/* ffest_confirmed -- Confirm current possibility as only one

	ffest_confirmed();

	Sets the confirmation flag. During debugging for ambiguous constructs,
	asserts that the confirmation flag for a previous possibility has not
	yet been set. */

	void
	ffest_confirmed ()
	{
	ffesta_confirmed ();
	}

	/* ffest_eof -- End of (non-INCLUDEd) source file

	ffest_eof();

	Call after piping tokens through ffest_first, where the most recent
	token sent through must be EOS.

	20-Feb-91 JCB 1.1
	Put new EOF token in ffesta_tokens[0], not NULL, because too much
	code expects something there for error reporting and the like. Also,
	do basically the same things ffest_second and ffesta_zero do for
	processing a statement (make and destroy pools, et cetera). */

	void
	ffest_eof ()
	{
	ffesta_eof ();
	}

	/* ffest_ffebad_here_current_stmt -- ffebad_here with ptr to current stmt

	ffest_ffebad_here_current_stmt(0);

	Outsiders can call this fn if they have no more convenient place to
	point to (via a token or pair of ffewhere objects) and they know a
	current, useful statement is being evaluted by ffest (i.e. they are
	being called from ffestb, ffestc, ffestd, ... functions). */

	void
	ffest_ffebad_here_current_stmt (ffebadIndex i)
	{
	ffesta_ffebad_here_current_stmt (i);
	}

	/* ffest_ffebad_here_doiter -- Calls ffebad_here with ptr to DO iter var

	ffesymbol s;
	// call ffebad_start first, of course.
	ffest_ffebad_here_doiter(0,s);
	// call ffebad_finish afterwards, naturally.

	Searches the stack of blocks backwards for a DO loop that has s
	as its iteration variable, then calls ffebad_here with pointers to
	that particular reference to the variable. Crashes if the DO loop
	can't be found. */

	void
	ffest_ffebad_here_doiter (ffebadIndex i, ffesymbol s)
	{
	ffestc_ffebad_here_doiter (i, s);
	}

	/* ffest_ffebad_start -- Start a possibly inhibited error report

	if (ffest_ffebad_start(FFEBAD_SOME_ERROR))
	{
	ffebad_here, ffebad_string ...;
	ffebad_finish();
	}

	Call if the error might indicate that ffest is evaluating the wrong
	statement form, instead of calling ffebad_start directly. If ffest
	is choosing between forms, it will return FALSE, send an EOS/SEMICOLON
	token through as the next token (if the current one isn't already one
	of those), and try another possible form. Otherwise, ffebad_start is
	called with the argument and TRUE returned. */

	bool
	ffest_ffebad_start (ffebad errnum)
	{
	return ffesta_ffebad_start (errnum);
	}

	/* ffest_first -- Parse the first token in a statement

	return ffest_first; // to lexer. */

	ffelexHandler
	ffest_first (ffelexToken t)
	{
	return ffesta_first (t);
	}

	/* ffest_init_0 -- Initialize for entire image invocation

	ffest_init_0();

	Call just once per invocation of the compiler (not once per invocation
	of the front end).

	Gets memory for the list of possibles once and for all, since this
	list never gets larger than a certain size (FFEST_maxPOSSIBLES_)
	and is not particularly large. Initializes the array of pointers to
	this list. Initializes the executable and nonexecutable lists. */

	void
	ffest_init_0 ()
	{
	ffesta_init_0 ();
	ffestb_init_0 ();
	ffestc_init_0 ();
	ffestd_init_0 ();
	ffeste_init_0 ();
	ffestp_init_0 ();
	ffestr_init_0 ();
	ffests_init_0 ();
	ffestt_init_0 ();
	ffestu_init_0 ();
	ffestv_init_0 ();
	ffestw_init_0 ();
	}

	/* ffest_init_1 -- Initialize for entire image invocation

	ffest_init_1();

	Call just once per invocation of the compiler (not once per invocation
	of the front end).

	Gets memory for the list of possibles once and for all, since this
	list never gets larger than a certain size (FFEST_maxPOSSIBLES_)
	and is not particularly large. Initializes the array of pointers to
	this list. Initializes the executable and nonexecutable lists. */

	void
	ffest_init_1 ()
	{
	ffesta_init_1 ();
	ffestb_init_1 ();
	ffestc_init_1 ();
	ffestd_init_1 ();
	ffeste_init_1 ();
	ffestp_init_1 ();
	ffestr_init_1 ();
	ffests_init_1 ();
	ffestt_init_1 ();
	ffestu_init_1 ();
	ffestv_init_1 ();
	ffestw_init_1 ();
	}

	/* ffest_init_2 -- Initialize for entire image invocation

	ffest_init_2();

	Call just once per invocation of the compiler (not once per invocation
	of the front end).

	Gets memory for the list of possibles once and for all, since this
	list never gets larger than a certain size (FFEST_maxPOSSIBLES_)
	and is not particularly large. Initializes the array of pointers to
	this list. Initializes the executable and nonexecutable lists. */

	void
	ffest_init_2 ()
	{
	ffesta_init_2 ();
	ffestb_init_2 ();
	ffestc_init_2 ();
	ffestd_init_2 ();
	ffeste_init_2 ();
	ffestp_init_2 ();
	ffestr_init_2 ();
	ffests_init_2 ();
	ffestt_init_2 ();
	ffestu_init_2 ();
	ffestv_init_2 ();
	ffestw_init_2 ();
	}

	/* ffest_init_3 -- Initialize for any program unit

	ffest_init_3(); */

	void
	ffest_init_3 ()
	{
	ffesta_init_3 ();
	ffestb_init_3 ();
	ffestc_init_3 ();
	ffestd_init_3 ();
	ffeste_init_3 ();
	ffestp_init_3 ();
	ffestr_init_3 ();
	ffests_init_3 ();
	ffestt_init_3 ();
	ffestu_init_3 ();
	ffestv_init_3 ();
	ffestw_init_3 ();

	ffestw_display_state ();
	}

	/* ffest_init_4 -- Initialize for statement functions

	ffest_init_4(); */

	void
	ffest_init_4 ()
	{
	ffesta_init_4 ();
	ffestb_init_4 ();
	ffestc_init_4 ();
	ffestd_init_4 ();
	ffeste_init_4 ();
	ffestp_init_4 ();
	ffestr_init_4 ();
	ffests_init_4 ();
	ffestt_init_4 ();
	ffestu_init_4 ();
	ffestv_init_4 ();
	ffestw_init_4 ();
	}

	/* Test whether ENTRY statement is valid.

	Returns TRUE if current program unit is known to be FUNCTION or SUBROUTINE.
	Else returns FALSE. */

	bool
	ffest_is_entry_valid ()
	{
	return ffesta_is_entry_valid;
	}

	/* ffest_is_inhibited -- Test whether the current possibility is inhibited

	if (!ffest_is_inhibited())
	// implement the statement.

	Just make sure the current possibility has been confirmed. If anyone
	really needs to test whether the current possibility is inhibited prior
	to confirming it, that indicates a need to begin statement processing
	before it is certain that the given possibility is indeed the statement
	to be processed. As of this writing, there does not appear to be such
	a need. If there is, then when confirming a statement would normally
	immediately disable the inhibition (whereas currently we leave the
	confirmed statement disabled until we've tried the other possibilities,
	to check for ambiguities), we must check to see if the possibility has
	already tested for inhibition prior to confirmation and, if so, maintain
	inhibition until the end of the statement (which may be forced right
	away) and then rerun the entire statement from the beginning. Otherwise,
	initial calls to ffestb functions won't have been made, but subsequent
	calls (after confirmation) will, which is wrong. Of course, this all
	applies only to those statements implemented via multiple calls to
	ffestb, although if a statement requiring only a single ffestb call
	tested for inhibition prior to confirmation, it would likely mean that
	the ffestb call would be completely dropped without this mechanism. */

	bool
	ffest_is_inhibited ()
	{
	return ffesta_is_inhibited ();
	}

	/* ffest_seen_first_exec -- Test whether first executable stmt has been seen

	if (ffest_seen_first_exec())
	// No more spec stmts can be seen.

	In a case where, say, the first statement is PARAMETER(A)=B, FALSE
	will be returned while the PARAMETER statement is being run, and TRUE
	will be returned if it doesn't confirm and the assignment statement
	is being run. */

	bool
	ffest_seen_first_exec ()
	{
	return ffesta_seen_first_exec;
	}

	/* Shut down current parsing possibility, but without bothering the
	user with a diagnostic if we're not inhibited. */

	void
	ffest_shutdown ()
	{
	ffesta_shutdown ();
	}

	/* ffest_sym_end_transition -- Update symbol info just before end of unit

	ffesymbol s;
	ffest_sym_end_transition(s); */

	ffesymbol
	ffest_sym_end_transition (ffesymbol s)
	{
	return ffestu_sym_end_transition (s);
	}

	/* ffest_sym_exec_transition -- Update symbol just before first exec stmt

	ffesymbol s;
	ffest_sym_exec_transition(s); */

	ffesymbol
	ffest_sym_exec_transition (ffesymbol s)
	{
	return ffestu_sym_exec_transition (s);
	}

	/* ffest_terminate_0 -- Terminate for entire image invocation

	ffest_terminate_0(); */

	void
	ffest_terminate_0 ()
	{
	ffesta_terminate_0 ();
	ffestb_terminate_0 ();
	ffestc_terminate_0 ();
	ffestd_terminate_0 ();
	ffeste_terminate_0 ();
	ffestp_terminate_0 ();
	ffestr_terminate_0 ();
	ffests_terminate_0 ();
	ffestt_terminate_0 ();
	ffestu_terminate_0 ();
	ffestv_terminate_0 ();
	ffestw_terminate_0 ();
	}

	/* ffest_terminate_1 -- Terminate for source file

	ffest_terminate_1(); */

	void
	ffest_terminate_1 ()
	{
	ffesta_terminate_1 ();
	ffestb_terminate_1 ();
	ffestc_terminate_1 ();
	ffestd_terminate_1 ();
	ffeste_terminate_1 ();
	ffestp_terminate_1 ();
	ffestr_terminate_1 ();
	ffests_terminate_1 ();
	ffestt_terminate_1 ();
	ffestu_terminate_1 ();
	ffestv_terminate_1 ();
	ffestw_terminate_1 ();
	}

	/* ffest_terminate_2 -- Terminate for outer program unit

	ffest_terminate_2(); */

	void
	ffest_terminate_2 ()
	{
	ffesta_terminate_2 ();
	ffestb_terminate_2 ();
	ffestc_terminate_2 ();
	ffestd_terminate_2 ();
	ffeste_terminate_2 ();
	ffestp_terminate_2 ();
	ffestr_terminate_2 ();
	ffests_terminate_2 ();
	ffestt_terminate_2 ();
	ffestu_terminate_2 ();
	ffestv_terminate_2 ();
	ffestw_terminate_2 ();
	}

	/* ffest_terminate_3 -- Terminate for any program unit

	ffest_terminate_3(); */

	void
	ffest_terminate_3 ()
	{
	ffesta_terminate_3 ();
	ffestb_terminate_3 ();
	ffestc_terminate_3 ();
	ffestd_terminate_3 ();
	ffeste_terminate_3 ();
	ffestp_terminate_3 ();
	ffestr_terminate_3 ();
	ffests_terminate_3 ();
	ffestt_terminate_3 ();
	ffestu_terminate_3 ();
	ffestv_terminate_3 ();
	ffestw_terminate_3 ();
	}

	/* ffest_terminate_4 -- Terminate for statement functions

	ffest_terminate_4(); */

	void
	ffest_terminate_4 ()
	{
	ffesta_terminate_4 ();
	ffestb_terminate_4 ();
	ffestc_terminate_4 ();
	ffestd_terminate_4 ();
	ffeste_terminate_4 ();
	ffestp_terminate_4 ();
	ffestr_terminate_4 ();
	ffests_terminate_4 ();
	ffestt_terminate_4 ();
	ffestu_terminate_4 ();
	ffestv_terminate_4 ();
	ffestw_terminate_4 ();
	}