[bison.git] / src / state.h

/* Type definitions for nondeterministic finite state machine for bison,
   Copyright 1984, 1989, 2000 Free Software Foundation, Inc.

   This file is part of Bison, the GNU Compiler Compiler.

   Bison 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.

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


/* These type definitions are used to represent a nondeterministic
   finite state machine that parses the specified grammar.  This
   information is generated by the function generate_states in the
   file LR0.

   Each state of the machine is described by a set of items --
   particular positions in particular rules -- that are the possible
   places where parsing could continue when the machine is in this
   state.  These symbols at these items are the allowable inputs that
   can follow now.

   A core represents one state.  States are numbered in the number
   field.  When generate_states is finished, the starting state is
   state 0 and nstates is the number of states.  (A transition to a
   state whose state number is nstates indicates termination.)  All
   the cores are chained together and first_state points to the first
   one (state 0).

   For each state there is a particular symbol which must have been
   the last thing accepted to reach that state.  It is the
   accessing_symbol of the core.

   Each core contains a vector of nitems items which are the indices
   in the ritems vector of the items that are selected in this state.

   The link field is used for chaining buckets that hash states by
   their itemsets.  This is for recognizing equivalent states and
   combining them when the states are generated.

   The two types of transitions are shifts (push the lookahead token
   and read another) and reductions (combine the last n things on the
   stack via a rule, replace them with the symbol that the rule
   derives, and leave the lookahead token alone).  When the states are
   generated, these transitions are represented in two other lists.

   Each shifts structure describes the possible shift transitions out
   of one state, the state whose number is in the number field.  The
   shifts structures are linked through next and first_shift points to
   them.  Each contains a vector of numbers of the states that shift
   transitions can go to.  The accessing_symbol fields of those
   states' cores say what kind of input leads to them.

   A shift to state zero should be ignored.  Conflict resolution
   deletes shifts by changing them to zero.

   Each reductions structure describes the possible reductions at the
   state whose number is in the number field.  The data is a list of
   nreds rules, represented by their rule numbers.  first_reduction
   points to the list of these structures.

   Conflict resolution can decide that certain tokens in certain
   states should explicitly be errors (for implementing %nonassoc).
   For each state, the tokens that are errors for this reason are
   recorded in an errs structure, which has the state number in its
   number field.  The rest of the errs structure is full of token
   numbers.

   There is at least one shift transition present in state zero.  It
   leads to a next-to-final state whose accessing_symbol is the
   grammar's start symbol.  The next-to-final state has one shift to
   the final state, whose accessing_symbol is zero (end of input).
   The final state has one shift, which goes to the termination state
   (whose number is nstates-1).  The reason for the extra state at the
   end is to placate the parser's strategy of making all decisions one
   token ahead of its actions.  */

#ifndef STATE_H_
# define STATE_H_


/*-------.
| Core.  |
`-------*/

typedef struct core
{
  struct core *next;
  struct core *link;
  short number;
  short accessing_symbol;
  short nitems;
  short items[1];
} core;

#define CORE_ALLOC(Nitems)						\
  (core *) xcalloc ((unsigned) (sizeof (core)	 			\
                                + (Nitems - 1) * sizeof (short)), 1)

/*---------.
| Shifts.  |
`---------*/

typedef struct shifts
{
  struct shifts *next;
  short number;
  short nshifts;
  short shifts[1];
} shifts;


#define SHIFTS_ALLOC(Nshifts)						\
  (shifts *) xcalloc ((unsigned) (sizeof (shifts) 			\
                                  + (Nshifts - 1) * sizeof (short)), 1)

/* What is the symbol which is shifted by SHIFTS->shifts[Shift]?  Can
   be a token (amongst which the error token), or non terminals in
   case of gotos.  */

#define SHIFT_SYMBOL(Shifts, Shift) \
  (state_table[Shifts->shifts[Shift]].accessing_symbol)

/* Is the SHIFTS->shifts[Shift] a real shift? (as opposed to gotos.) */

#define SHIFT_IS_SHIFT(Shifts, Shift) \
  (ISTOKEN (SHIFT_SYMBOL (Shifts, Shift)))

/* Is the SHIFTS->shifts[Shift] a goto?. */

#define SHIFT_IS_GOTO(Shifts, Shift) \
  (!SHIFT_IS_SHIFT (Shifts, Shift))

/* Is the SHIFTS->shifts[Shift] then handling of the error token?. */

#define SHIFT_IS_ERROR(Shifts, Shift) \
  (SHIFT_SYMBOL (Shifts, Shift) == error_token_number)

/* When resolving a SR conflicts, if the reduction wins, the shift is
   disabled.  */

#define SHIFT_DISABLE(Shifts, Shift) \
  (Shifts->shifts[Shift] = 0)

#define SHIFT_IS_DISABLED(Shifts, Shift) \
  (Shifts->shifts[Shift] == 0)


/*-------.
| Errs.  |
`-------*/

typedef struct errs
{
  short nerrs;
  short errs[1];
} errs;

#define ERRS_ALLOC(Nerrs)						\
  (errs *) xcalloc ((unsigned) (sizeof (errs) 				\
                                  + (Nerrs - 1) * sizeof (short)), 1)


/*-------------.
| Reductions.  |
`-------------*/

typedef struct reductions
{
  struct reductions *next;
  short number;
  short nreds;
  short rules[1];
} reductions;

#define REDUCTIONS_ALLOC(Nreductions)					\
  (reductions *) xcalloc ((unsigned) (sizeof (reductions)		\
                                  + (Nreductions - 1) * sizeof (short)), 1)

#endif /* !STATE_H_ */
Commit	Line	Data
d0fb370f	1	/* Type definitions for nondeterministic finite state machine for bison,
aa7815f5	2	Copyright 1984, 1989, 2000 Free Software Foundation, Inc.
d0fb370f	3
a70083a3	4	This file is part of Bison, the GNU Compiler Compiler.
d0fb370f	5
a70083a3 AD	6	Bison is free software; you can redistribute it and/or modify
	7	it under the terms of the GNU General Public License as published by
	8	the Free Software Foundation; either version 2, or (at your option)
	9	any later version.
d0fb370f	10
a70083a3 AD	11	Bison is distributed in the hope that it will be useful,
	12	but WITHOUT ANY WARRANTY; without even the implied warranty of
	13	MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
	14	GNU General Public License for more details.
d0fb370f	15
a70083a3 AD	16	You should have received a copy of the GNU General Public License
	17	along with Bison; see the file COPYING. If not, write to
	18	the Free Software Foundation, Inc., 59 Temple Place - Suite 330,
	19	Boston, MA 02111-1307, USA. */
d0fb370f RS	20
	21
	22	/* These type definitions are used to represent a nondeterministic
a70083a3 AD	23	finite state machine that parses the specified grammar. This
	24	information is generated by the function generate_states in the
	25	file LR0.
	26
	27	Each state of the machine is described by a set of items --
	28	particular positions in particular rules -- that are the possible
	29	places where parsing could continue when the machine is in this
	30	state. These symbols at these items are the allowable inputs that
	31	can follow now.
	32
	33	A core represents one state. States are numbered in the number
	34	field. When generate_states is finished, the starting state is
	35	state 0 and nstates is the number of states. (A transition to a
	36	state whose state number is nstates indicates termination.) All
	37	the cores are chained together and first_state points to the first
	38	one (state 0).
	39
	40	For each state there is a particular symbol which must have been
	41	the last thing accepted to reach that state. It is the
	42	accessing_symbol of the core.
	43
	44	Each core contains a vector of nitems items which are the indices
	45	in the ritems vector of the items that are selected in this state.
	46
	47	The link field is used for chaining buckets that hash states by
	48	their itemsets. This is for recognizing equivalent states and
	49	combining them when the states are generated.
	50
	51	The two types of transitions are shifts (push the lookahead token
	52	and read another) and reductions (combine the last n things on the
	53	stack via a rule, replace them with the symbol that the rule
	54	derives, and leave the lookahead token alone). When the states are
	55	generated, these transitions are represented in two other lists.
	56
	57	Each shifts structure describes the possible shift transitions out
	58	of one state, the state whose number is in the number field. The
	59	shifts structures are linked through next and first_shift points to
	60	them. Each contains a vector of numbers of the states that shift
	61	transitions can go to. The accessing_symbol fields of those
	62	states' cores say what kind of input leads to them.
	63
	64	A shift to state zero should be ignored. Conflict resolution
	65	deletes shifts by changing them to zero.
	66
	67	Each reductions structure describes the possible reductions at the
	68	state whose number is in the number field. The data is a list of
	69	nreds rules, represented by their rule numbers. first_reduction
	70	points to the list of these structures.
	71
	72	Conflict resolution can decide that certain tokens in certain
	73	states should explicitly be errors (for implementing %nonassoc).
	74	For each state, the tokens that are errors for this reason are
	75	recorded in an errs structure, which has the state number in its
	76	number field. The rest of the errs structure is full of token
	77	numbers.
	78
	79	There is at least one shift transition present in state zero. It
	80	leads to a next-to-final state whose accessing_symbol is the
	81	grammar's start symbol. The next-to-final state has one shift to
	82	the final state, whose accessing_symbol is zero (end of input).
	83	The final state has one shift, which goes to the termination state
	84	(whose number is nstates-1). The reason for the extra state at the
	85	end is to placate the parser's strategy of making all decisions one
	86	token ahead of its actions. */
87
88	#ifndef STATE_H_
89	# define STATE_H_
90
aa2aab3c AD	91
	92	/*-------.
	93	\| Core. \|
	94	`-------*/
	95
a70083a3 AD	96	typedef struct core
	97	{
	98	struct core *next;
	99	struct core *link;
	100	short number;
	101	short accessing_symbol;
	102	short nitems;
	103	short items[1];
aa2aab3c	104	} core;
a70083a3	105
f59c437a AD	106	#define CORE_ALLOC(Nitems) \
	107	(core *) xcalloc ((unsigned) (sizeof (core) \
	108	+ (Nitems - 1) * sizeof (short)), 1)
a70083a3	109
aa2aab3c AD	110	/*---------.
	111	\| Shifts. \|
	112	`---------*/
	113
a70083a3 AD	114	typedef struct shifts
	115	{
	116	struct shifts *next;
	117	short number;
	118	short nshifts;
	119	short shifts[1];
aa2aab3c AD	120	} shifts;
aa2aab3c AD	121
a70083a3	122
f59c437a AD	123	#define SHIFTS_ALLOC(Nshifts) \
	124	(shifts *) xcalloc ((unsigned) (sizeof (shifts) \
	125	+ (Nshifts - 1) * sizeof (short)), 1)
a70083a3	126
b608206e AD	127	/* What is the symbol which is shifted by SHIFTS->shifts[Shift]? Can
	128	be a token (amongst which the error token), or non terminals in
	129	case of gotos. */
	130
	131	#define SHIFT_SYMBOL(Shifts, Shift) \
	132	(state_table[Shifts->shifts[Shift]].accessing_symbol)
	133
aa2aab3c AD	134	/* Is the SHIFTS->shifts[Shift] a real shift? (as opposed to gotos.) */
	135
	136	#define SHIFT_IS_SHIFT(Shifts, Shift) \
b608206e	137	(ISTOKEN (SHIFT_SYMBOL (Shifts, Shift)))
aa2aab3c AD	138
	139	/* Is the SHIFTS->shifts[Shift] a goto?. */
	140
	141	#define SHIFT_IS_GOTO(Shifts, Shift) \
	142	(!SHIFT_IS_SHIFT (Shifts, Shift))
	143
	144	/* Is the SHIFTS->shifts[Shift] then handling of the error token?. */
	145
	146	#define SHIFT_IS_ERROR(Shifts, Shift) \
b608206e	147	(SHIFT_SYMBOL (Shifts, Shift) == error_token_number)
aa2aab3c	148
9839bbe5 AD	149	/* When resolving a SR conflicts, if the reduction wins, the shift is
	150	disabled. */
	151
	152	#define SHIFT_DISABLE(Shifts, Shift) \
	153	(Shifts->shifts[Shift] = 0)
	154
	155	#define SHIFT_IS_DISABLED(Shifts, Shift) \
	156	(Shifts->shifts[Shift] == 0)
	157
aa2aab3c AD	158
	159	/*-------.
	160	\| Errs. \|
	161	`-------*/
a70083a3 AD	162
	163	typedef struct errs
	164	{
	165	short nerrs;
	166	short errs[1];
aa2aab3c	167	} errs;
a70083a3	168
f59c437a AD	169	#define ERRS_ALLOC(Nerrs) \
	170	(errs *) xcalloc ((unsigned) (sizeof (errs) \
	171	+ (Nerrs - 1) * sizeof (short)), 1)
	172
a70083a3	173
aa2aab3c AD	174	/*-------------.
	175	\| Reductions. \|
	176	`-------------*/
a70083a3 AD	177
	178	typedef struct reductions
	179	{
	180	struct reductions *next;
	181	short number;
	182	short nreds;
	183	short rules[1];
aa2aab3c	184	} reductions;
d0fb370f	185
f59c437a AD	186	#define REDUCTIONS_ALLOC(Nreductions) \
	187	(reductions *) xcalloc ((unsigned) (sizeof (reductions) \
	188	+ (Nreductions - 1) * sizeof (short)), 1)
	189
a70083a3	190	#endif /* !STATE_H_ */