/* Compute lookahead criteria for Bison.
Copyright (C) 1984, 1986, 1989, 2000-2015, 2018-2019 Free Software
Foundation, Inc.
This file is part of Bison, the GNU Compiler Compiler.
This program 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 3 of the License, or
(at your option) any later version.
This program 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 this program. If not, see . */
/* Find which rules need lookahead in each state, and which lookahead
tokens they accept. */
#include
#include "system.h"
#include
#include
#include "complain.h"
#include "derives.h"
#include "getargs.h"
#include "gram.h"
#include "lalr.h"
#include "lr0.h"
#include "muscle-tab.h"
#include "nullable.h"
#include "reader.h"
#include "relation.h"
#include "symtab.h"
/* goto_map[nterm - NTOKENS] -> number of gotos. */
goto_number *goto_map = NULL;
goto_number ngotos = 0;
state_number *from_state = NULL;
state_number *to_state = NULL;
bitsetv goto_follows = NULL;
/* Linked list of goto numbers. */
typedef struct goto_list
{
struct goto_list *next;
goto_number value;
} goto_list;
static goto_list *
goto_list_new (goto_number value, struct goto_list *next)
{
goto_list *res = xmalloc (sizeof *res);
res->next = next;
res->value = value;
return res;
}
/* LA is an nLA by NTOKENS matrix of bits. LA[l, i] is 1 if the rule
LArule[l] is applicable in the appropriate state when the next
token is symbol i. If LA[l, i] and LA[l, j] are both 1 for i != j,
it is a conflict. */
static bitsetv LA = NULL;
size_t nLA;
static goto_number **includes;
static goto_list **lookback;
static void
goto_print (goto_number i, FILE *out)
{
const state_number src = from_state[i];
const state_number dst = to_state[i];
symbol_number var = states[dst]->accessing_symbol;
fprintf (out,
"goto[%ld] = (%d, %s, %d)", i, src, symbols[var]->tag, dst);
}
void
set_goto_map (void)
{
/* Count the number of gotos (ngotos) per nterm (goto_map). */
goto_map = xcalloc (nvars + 1, sizeof *goto_map);
ngotos = 0;
for (state_number s = 0; s < nstates; ++s)
{
transitions *trans = states[s]->transitions;
for (int i = trans->num - 1; 0 <= i && TRANSITION_IS_GOTO (trans, i); --i)
{
ngotos++;
/* Abort if (ngotos + 1) would overflow. */
aver (ngotos != GOTO_NUMBER_MAXIMUM);
goto_map[TRANSITION_SYMBOL (trans, i) - ntokens]++;
}
}
goto_number *temp_map = xnmalloc (nvars + 1, sizeof *temp_map);
{
goto_number k = 0;
for (symbol_number i = ntokens; i < nsyms; ++i)
{
temp_map[i - ntokens] = k;
k += goto_map[i - ntokens];
}
for (symbol_number i = ntokens; i < nsyms; ++i)
goto_map[i - ntokens] = temp_map[i - ntokens];
goto_map[nsyms - ntokens] = ngotos;
temp_map[nsyms - ntokens] = ngotos;
}
from_state = xcalloc (ngotos, sizeof *from_state);
to_state = xcalloc (ngotos, sizeof *to_state);
for (state_number s = 0; s < nstates; ++s)
{
const transitions *trans = states[s]->transitions;
for (int i = trans->num - 1; 0 <= i && TRANSITION_IS_GOTO (trans, i); --i)
{
goto_number k = temp_map[TRANSITION_SYMBOL (trans, i) - ntokens]++;
from_state[k] = s;
to_state[k] = trans->states[i]->number;
}
}
free (temp_map);
if (trace_flag & trace_automaton)
for (int i = 0; i < ngotos; ++i)
{
goto_print (i, stderr);
fputc ('\n', stderr);
}
}
goto_number
map_goto (state_number src, symbol_number sym)
{
goto_number low = goto_map[sym - ntokens];
goto_number high = goto_map[sym - ntokens + 1] - 1;
for (;;)
{
aver (low <= high);
goto_number middle = (low + high) / 2;
state_number s = from_state[middle];
if (s == src)
return middle;
else if (s < src)
low = middle + 1;
else
high = middle - 1;
}
}
/* Print FOLLOWS for debugging. */
static void
follows_print (const char* title, FILE *out)
{
fprintf (out, "%s:\n", title);
for (goto_number i = 0; i < ngotos; ++i)
{
fputs (" FOLLOWS[", out);
goto_print (i, out);
fputs ("] =", out);
bitset_iterator iter;
symbol_number sym;
BITSET_FOR_EACH (iter, goto_follows[i], sym, 0)
fprintf (out, " %s", symbols[sym]->tag);
fputc ('\n', out);
}
fputc ('\n', out);
}
/* Build goto_follows. */
static void
initialize_goto_follows (void)
{
goto_number **reads = xnmalloc (ngotos, sizeof *reads);
goto_number *edge = xnmalloc (ngotos + 1, sizeof *edge);
goto_number nedges = 0;
goto_follows = bitsetv_create (ngotos, ntokens, BITSET_FIXED);
for (goto_number i = 0; i < ngotos; ++i)
{
state_number dst = to_state[i];
const transitions *trans = states[dst]->transitions;
int j;
FOR_EACH_SHIFT (trans, j)
bitset_set (goto_follows[i], TRANSITION_SYMBOL (trans, j));
for (; j < trans->num; ++j)
{
symbol_number sym = TRANSITION_SYMBOL (trans, j);
if (nullable[sym - ntokens])
{
assert (nedges < ngotos + 1);
edge[nedges++] = map_goto (dst, sym);
}
}
if (nedges == 0)
reads[i] = NULL;
else
{
reads[i] = xnmalloc (nedges + 1, sizeof reads[i][0]);
memcpy (reads[i], edge, nedges * sizeof edge[0]);
reads[i][nedges] = END_NODE;
nedges = 0;
}
}
if (trace_flag & trace_automaton)
{
follows_print ("follows after shifts", stderr);
relation_print ("reads", reads, ngotos, goto_print, stderr);
}
relation_digraph (reads, ngotos, goto_follows);
if (trace_flag & trace_automaton)
follows_print ("follows after read", stderr);
for (goto_number i = 0; i < ngotos; ++i)
free (reads[i]);
free (reads);
free (edge);
}
static void
add_lookback_edge (state *s, rule const *r, goto_number gotono)
{
int ri = state_reduction_find (s, r);
int idx = (s->reductions->lookahead_tokens - LA) + ri;
lookback[idx] = goto_list_new (gotono, lookback[idx]);
}
/* Compute INCLUDES and LOOKBACK. Corresponds to step E in Sec. 6 of
[DeRemer 1982]. */
static void
build_relations (void)
{
goto_number *edge = xnmalloc (ngotos + 1, sizeof *edge);
state_number *path = xnmalloc (ritem_longest_rhs () + 1, sizeof *path);
includes = xnmalloc (ngotos, sizeof *includes);
/* For each goto (from SRC to DST labeled by nterm VAR), iterate
over each rule with VAR as LHS, and find the path PATH from SRC
labeled with the RHS of the rule. */
for (goto_number i = 0; i < ngotos; ++i)
{
const state_number src = from_state[i];
const state_number dst = to_state[i];
symbol_number var = states[dst]->accessing_symbol;
/* Size of EDGE. */
int nedges = 0;
for (rule **rulep = derives[var - ntokens]; *rulep; ++rulep)
{
rule const *r = *rulep;
state *s = states[src];
path[0] = s->number;
/* Length of PATH. */
int length = 1;
for (item_number const *rp = r->rhs; 0 <= *rp; rp++)
{
symbol_number sym = item_number_as_symbol_number (*rp);
s = transitions_to (s, sym);
path[length++] = s->number;
}
if (!s->consistent)
add_lookback_edge (s, r, i);
/* Walk back PATH from penultimate to beginning.
The "0 <= p" part is actually useless: each rhs ends in a
rule number (for which ISVAR(...) is false), and there is
a sentinel (ritem[-1]=0) before the first rhs. */
for (int p = length - 2; 0 <= p && ISVAR (r->rhs[p]); --p)
{
symbol_number sym = item_number_as_symbol_number (r->rhs[p]);
goto_number g = map_goto (path[p], sym);
/* Insert G if not already in EDGE.
FIXME: linear search. A bitset instead? */
{
bool found = false;
for (int j = 0; !found && j < nedges; ++j)
found = edge[j] == g;
if (!found)
{
assert (nedges < ngotos + 1);
edge[nedges++] = map_goto (path[p], sym);
}
}
if (!nullable[sym - ntokens])
break;
}
}
if (nedges == 0)
includes[i] = NULL;
else
{
includes[i] = xnmalloc (nedges + 1, sizeof includes[i][0]);
for (int j = 0; j < nedges; ++j)
includes[i][j] = edge[j];
includes[i][nedges] = END_NODE;
}
}
free (edge);
free (path);
relation_transpose (&includes, ngotos);
if (trace_flag & trace_automaton)
relation_print ("includes", includes, ngotos, goto_print, stderr);
}
/* Compute FOLLOWS from INCLUDES, and free INCLUDES. */
static void
compute_follows (void)
{
relation_digraph (includes, ngotos, goto_follows);
if (trace_flag & trace_sets)
follows_print ("follows after includes", stderr);
for (goto_number i = 0; i < ngotos; ++i)
free (includes[i]);
free (includes);
}
static void
compute_lookahead_tokens (void)
{
for (size_t i = 0; i < nLA; ++i)
for (goto_list *sp = lookback[i]; sp; sp = sp->next)
bitset_or (LA[i], LA[i], goto_follows[sp->value]);
/* Free LOOKBACK. */
for (size_t i = 0; i < nLA; ++i)
LIST_FREE (goto_list, lookback[i]);
free (lookback);
}
/*----------------------------------------------------.
| Count the number of lookahead tokens required for S |
| (N_LOOKAHEAD_TOKENS member). |
`----------------------------------------------------*/
static int
state_lookahead_tokens_count (state *s, bool default_reduction_only_for_accept)
{
const reductions *reds = s->reductions;
const transitions *trans = s->transitions;
/* Transitions are only disabled during conflict resolution, and that
hasn't happened yet, so there should be no need to check that
transition 0 hasn't been disabled before checking if it is a shift.
However, this check was performed at one time, so we leave it as an
aver. */
aver (trans->num == 0 || !TRANSITION_IS_DISABLED (trans, 0));
/* We need a lookahead either to distinguish different reductions
(i.e., there are two or more), or to distinguish a reduction from a
shift. Otherwise, it is straightforward, and the state is
'consistent'. However, do not treat a state with any reductions as
consistent unless it is the accepting state (because there is never
a lookahead token that makes sense there, and so no lookahead token
should be read) if the user has otherwise disabled default
reductions. */
s->consistent =
!(reds->num > 1
|| (reds->num == 1 && trans->num && TRANSITION_IS_SHIFT (trans, 0))
|| (reds->num == 1 && reds->rules[0]->number != 0
&& default_reduction_only_for_accept));
return s->consistent ? 0 : reds->num;
}
/*----------------------------------------------------.
| Compute LA, NLA, and the lookahead_tokens members. |
`----------------------------------------------------*/
void
initialize_LA (void)
{
bool default_reduction_only_for_accept;
{
char *default_reductions =
muscle_percent_define_get ("lr.default-reduction");
default_reduction_only_for_accept = STREQ (default_reductions, "accepting");
free (default_reductions);
}
/* Compute the total number of reductions requiring a lookahead. */
nLA = 0;
for (state_number i = 0; i < nstates; ++i)
nLA +=
state_lookahead_tokens_count (states[i],
default_reduction_only_for_accept);
/* Avoid having to special case 0. */
if (!nLA)
nLA = 1;
bitsetv pLA = LA = bitsetv_create (nLA, ntokens, BITSET_FIXED);
/* Initialize the members LOOKAHEAD_TOKENS for each state whose reductions
require lookahead tokens. */
for (state_number i = 0; i < nstates; ++i)
{
int count =
state_lookahead_tokens_count (states[i],
default_reduction_only_for_accept);
if (count)
{
states[i]->reductions->lookahead_tokens = pLA;
pLA += count;
}
}
}
/*---------------------------------------------.
| Output the lookahead tokens for each state. |
`---------------------------------------------*/
static void
lookahead_tokens_print (FILE *out)
{
fputs ("Lookaheads:\n", out);
for (state_number i = 0; i < nstates; ++i)
{
const reductions *reds = states[i]->reductions;
if (reds->num)
{
fprintf (out, " State %d:\n", i);
for (int j = 0; j < reds->num; ++j)
{
fprintf (out, " rule %d:", reds->rules[j]->number);
if (reds->lookahead_tokens)
{
bitset_iterator iter;
int k;
BITSET_FOR_EACH (iter, reds->lookahead_tokens[j], k, 0)
fprintf (out, " %s", symbols[k]->tag);
}
fputc ('\n', out);
}
}
}
fputc ('\n', out);
}
void
lalr (void)
{
initialize_LA ();
set_goto_map ();
initialize_goto_follows ();
lookback = xcalloc (nLA, sizeof *lookback);
build_relations ();
compute_follows ();
compute_lookahead_tokens ();
if (trace_flag & trace_sets)
lookahead_tokens_print (stderr);
}
void
lalr_update_state_numbers (state_number old_to_new[], state_number nstates_old)
{
goto_number ngotos_reachable = 0;
symbol_number nonterminal = 0;
aver (nsyms == nvars + ntokens);
for (goto_number i = 0; i < ngotos; ++i)
{
while (i == goto_map[nonterminal])
goto_map[nonterminal++] = ngotos_reachable;
/* If old_to_new[from_state[i]] = nstates_old, remove this goto
entry. */
if (old_to_new[from_state[i]] != nstates_old)
{
/* from_state[i] is not removed, so it and thus to_state[i] are
reachable, so to_state[i] != nstates_old. */
aver (old_to_new[to_state[i]] != nstates_old);
from_state[ngotos_reachable] = old_to_new[from_state[i]];
to_state[ngotos_reachable] = old_to_new[to_state[i]];
++ngotos_reachable;
}
}
while (nonterminal <= nvars)
{
aver (ngotos == goto_map[nonterminal]);
goto_map[nonterminal++] = ngotos_reachable;
}
ngotos = ngotos_reachable;
}
void
lalr_free (void)
{
for (state_number s = 0; s < nstates; ++s)
states[s]->reductions->lookahead_tokens = NULL;
bitsetv_free (LA);
}