/* Thread edges through blocks and update the control flow and SSA graphs.
Copyright (C) 2004-2014 Free Software Foundation, Inc.
This file is part of GCC.
GCC 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, or (at your option)
any later version.
GCC 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 GCC; see the file COPYING3. If not see
. */
#include "config.h"
#include "system.h"
#include "coretypes.h"
#include "tree.h"
#include "flags.h"
#include "predict.h"
#include "vec.h"
#include "hashtab.h"
#include "hash-set.h"
#include "machmode.h"
#include "tm.h"
#include "hard-reg-set.h"
#include "input.h"
#include "function.h"
#include "dominance.h"
#include "cfg.h"
#include "cfganal.h"
#include "basic-block.h"
#include "hash-table.h"
#include "tree-ssa-alias.h"
#include "internal-fn.h"
#include "gimple-expr.h"
#include "is-a.h"
#include "gimple.h"
#include "gimple-iterator.h"
#include "gimple-ssa.h"
#include "tree-phinodes.h"
#include "tree-ssa.h"
#include "tree-ssa-threadupdate.h"
#include "ssa-iterators.h"
#include "dumpfile.h"
#include "cfgloop.h"
#include "dbgcnt.h"
#include "tree-cfg.h"
#include "tree-pass.h"
/* Given a block B, update the CFG and SSA graph to reflect redirecting
one or more in-edges to B to instead reach the destination of an
out-edge from B while preserving any side effects in B.
i.e., given A->B and B->C, change A->B to be A->C yet still preserve the
side effects of executing B.
1. Make a copy of B (including its outgoing edges and statements). Call
the copy B'. Note B' has no incoming edges or PHIs at this time.
2. Remove the control statement at the end of B' and all outgoing edges
except B'->C.
3. Add a new argument to each PHI in C with the same value as the existing
argument associated with edge B->C. Associate the new PHI arguments
with the edge B'->C.
4. For each PHI in B, find or create a PHI in B' with an identical
PHI_RESULT. Add an argument to the PHI in B' which has the same
value as the PHI in B associated with the edge A->B. Associate
the new argument in the PHI in B' with the edge A->B.
5. Change the edge A->B to A->B'.
5a. This automatically deletes any PHI arguments associated with the
edge A->B in B.
5b. This automatically associates each new argument added in step 4
with the edge A->B'.
6. Repeat for other incoming edges into B.
7. Put the duplicated resources in B and all the B' blocks into SSA form.
Note that block duplication can be minimized by first collecting the
set of unique destination blocks that the incoming edges should
be threaded to.
We reduce the number of edges and statements we create by not copying all
the outgoing edges and the control statement in step #1. We instead create
a template block without the outgoing edges and duplicate the template.
Another case this code handles is threading through a "joiner" block. In
this case, we do not know the destination of the joiner block, but one
of the outgoing edges from the joiner block leads to a threadable path. This
case largely works as outlined above, except the duplicate of the joiner
block still contains a full set of outgoing edges and its control statement.
We just redirect one of its outgoing edges to our jump threading path. */
/* Steps #5 and #6 of the above algorithm are best implemented by walking
all the incoming edges which thread to the same destination edge at
the same time. That avoids lots of table lookups to get information
for the destination edge.
To realize that implementation we create a list of incoming edges
which thread to the same outgoing edge. Thus to implement steps
#5 and #6 we traverse our hash table of outgoing edge information.
For each entry we walk the list of incoming edges which thread to
the current outgoing edge. */
struct el
{
edge e;
struct el *next;
};
/* Main data structure recording information regarding B's duplicate
blocks. */
/* We need to efficiently record the unique thread destinations of this
block and specific information associated with those destinations. We
may have many incoming edges threaded to the same outgoing edge. This
can be naturally implemented with a hash table. */
struct redirection_data : typed_free_remove
{
/* We support wiring up two block duplicates in a jump threading path.
One is a normal block copy where we remove the control statement
and wire up its single remaining outgoing edge to the thread path.
The other is a joiner block where we leave the control statement
in place, but wire one of the outgoing edges to a thread path.
In theory we could have multiple block duplicates in a jump
threading path, but I haven't tried that.
The duplicate blocks appear in this array in the same order in
which they appear in the jump thread path. */
basic_block dup_blocks[2];
/* The jump threading path. */
vec *path;
/* A list of incoming edges which we want to thread to the
same path. */
struct el *incoming_edges;
/* hash_table support. */
typedef redirection_data value_type;
typedef redirection_data compare_type;
static inline hashval_t hash (const value_type *);
static inline int equal (const value_type *, const compare_type *);
};
/* Dump a jump threading path, including annotations about each
edge in the path. */
static void
dump_jump_thread_path (FILE *dump_file, vec path,
bool registering)
{
fprintf (dump_file,
" %s jump thread: (%d, %d) incoming edge; ",
(registering ? "Registering" : "Cancelling"),
path[0]->e->src->index, path[0]->e->dest->index);
for (unsigned int i = 1; i < path.length (); i++)
{
/* We can get paths with a NULL edge when the final destination
of a jump thread turns out to be a constant address. We dump
those paths when debugging, so we have to be prepared for that
possibility here. */
if (path[i]->e == NULL)
continue;
if (path[i]->type == EDGE_COPY_SRC_JOINER_BLOCK)
fprintf (dump_file, " (%d, %d) joiner; ",
path[i]->e->src->index, path[i]->e->dest->index);
if (path[i]->type == EDGE_COPY_SRC_BLOCK)
fprintf (dump_file, " (%d, %d) normal;",
path[i]->e->src->index, path[i]->e->dest->index);
if (path[i]->type == EDGE_NO_COPY_SRC_BLOCK)
fprintf (dump_file, " (%d, %d) nocopy;",
path[i]->e->src->index, path[i]->e->dest->index);
}
fputc ('\n', dump_file);
}
/* Simple hashing function. For any given incoming edge E, we're going
to be most concerned with the final destination of its jump thread
path. So hash on the block index of the final edge in the path. */
inline hashval_t
redirection_data::hash (const value_type *p)
{
vec *path = p->path;
return path->last ()->e->dest->index;
}
/* Given two hash table entries, return true if they have the same
jump threading path. */
inline int
redirection_data::equal (const value_type *p1, const compare_type *p2)
{
vec *path1 = p1->path;
vec *path2 = p2->path;
if (path1->length () != path2->length ())
return false;
for (unsigned int i = 1; i < path1->length (); i++)
{
if ((*path1)[i]->type != (*path2)[i]->type
|| (*path1)[i]->e != (*path2)[i]->e)
return false;
}
return true;
}
/* Data structure of information to pass to hash table traversal routines. */
struct ssa_local_info_t
{
/* The current block we are working on. */
basic_block bb;
/* We only create a template block for the first duplicated block in a
jump threading path as we may need many duplicates of that block.
The second duplicate block in a path is specific to that path. Creating
and sharing a template for that block is considerably more difficult. */
basic_block template_block;
/* TRUE if we thread one or more jumps, FALSE otherwise. */
bool jumps_threaded;
/* Blocks duplicated for the thread. */
bitmap duplicate_blocks;
};
/* Passes which use the jump threading code register jump threading
opportunities as they are discovered. We keep the registered
jump threading opportunities in this vector as edge pairs
(original_edge, target_edge). */
static vec *> paths;
/* When we start updating the CFG for threading, data necessary for jump
threading is attached to the AUX field for the incoming edge. Use these
macros to access the underlying structure attached to the AUX field. */
#define THREAD_PATH(E) ((vec *)(E)->aux)
/* Jump threading statistics. */
struct thread_stats_d
{
unsigned long num_threaded_edges;
};
struct thread_stats_d thread_stats;
/* Remove the last statement in block BB if it is a control statement
Also remove all outgoing edges except the edge which reaches DEST_BB.
If DEST_BB is NULL, then remove all outgoing edges. */
static void
remove_ctrl_stmt_and_useless_edges (basic_block bb, basic_block dest_bb)
{
gimple_stmt_iterator gsi;
edge e;
edge_iterator ei;
gsi = gsi_last_bb (bb);
/* If the duplicate ends with a control statement, then remove it.
Note that if we are duplicating the template block rather than the
original basic block, then the duplicate might not have any real
statements in it. */
if (!gsi_end_p (gsi)
&& gsi_stmt (gsi)
&& (gimple_code (gsi_stmt (gsi)) == GIMPLE_COND
|| gimple_code (gsi_stmt (gsi)) == GIMPLE_GOTO
|| gimple_code (gsi_stmt (gsi)) == GIMPLE_SWITCH))
gsi_remove (&gsi, true);
for (ei = ei_start (bb->succs); (e = ei_safe_edge (ei)); )
{
if (e->dest != dest_bb)
remove_edge (e);
else
ei_next (&ei);
}
}
/* Create a duplicate of BB. Record the duplicate block in an array
indexed by COUNT stored in RD. */
static void
create_block_for_threading (basic_block bb,
struct redirection_data *rd,
unsigned int count,
bitmap *duplicate_blocks)
{
edge_iterator ei;
edge e;
/* We can use the generic block duplication code and simply remove
the stuff we do not need. */
rd->dup_blocks[count] = duplicate_block (bb, NULL, NULL);
FOR_EACH_EDGE (e, ei, rd->dup_blocks[count]->succs)
e->aux = NULL;
/* Zero out the profile, since the block is unreachable for now. */
rd->dup_blocks[count]->frequency = 0;
rd->dup_blocks[count]->count = 0;
if (duplicate_blocks)
bitmap_set_bit (*duplicate_blocks, rd->dup_blocks[count]->index);
}
/* Main data structure to hold information for duplicates of BB. */
static hash_table *redirection_data;
/* Given an outgoing edge E lookup and return its entry in our hash table.
If INSERT is true, then we insert the entry into the hash table if
it is not already present. INCOMING_EDGE is added to the list of incoming
edges associated with E in the hash table. */
static struct redirection_data *
lookup_redirection_data (edge e, enum insert_option insert)
{
struct redirection_data **slot;
struct redirection_data *elt;
vec *path = THREAD_PATH (e);
/* Build a hash table element so we can see if E is already
in the table. */
elt = XNEW (struct redirection_data);
elt->path = path;
elt->dup_blocks[0] = NULL;
elt->dup_blocks[1] = NULL;
elt->incoming_edges = NULL;
slot = redirection_data->find_slot (elt, insert);
/* This will only happen if INSERT is false and the entry is not
in the hash table. */
if (slot == NULL)
{
free (elt);
return NULL;
}
/* This will only happen if E was not in the hash table and
INSERT is true. */
if (*slot == NULL)
{
*slot = elt;
elt->incoming_edges = XNEW (struct el);
elt->incoming_edges->e = e;
elt->incoming_edges->next = NULL;
return elt;
}
/* E was in the hash table. */
else
{
/* Free ELT as we do not need it anymore, we will extract the
relevant entry from the hash table itself. */
free (elt);
/* Get the entry stored in the hash table. */
elt = *slot;
/* If insertion was requested, then we need to add INCOMING_EDGE
to the list of incoming edges associated with E. */
if (insert)
{
struct el *el = XNEW (struct el);
el->next = elt->incoming_edges;
el->e = e;
elt->incoming_edges = el;
}
return elt;
}
}
/* Similar to copy_phi_args, except that the PHI arg exists, it just
does not have a value associated with it. */
static void
copy_phi_arg_into_existing_phi (edge src_e, edge tgt_e)
{
int src_idx = src_e->dest_idx;
int tgt_idx = tgt_e->dest_idx;
/* Iterate over each PHI in e->dest. */
for (gimple_stmt_iterator gsi = gsi_start_phis (src_e->dest),
gsi2 = gsi_start_phis (tgt_e->dest);
!gsi_end_p (gsi);
gsi_next (&gsi), gsi_next (&gsi2))
{
gimple src_phi = gsi_stmt (gsi);
gimple dest_phi = gsi_stmt (gsi2);
tree val = gimple_phi_arg_def (src_phi, src_idx);
source_location locus = gimple_phi_arg_location (src_phi, src_idx);
SET_PHI_ARG_DEF (dest_phi, tgt_idx, val);
gimple_phi_arg_set_location (dest_phi, tgt_idx, locus);
}
}
/* Given ssa_name DEF, backtrack jump threading PATH from node IDX
to see if it has constant value in a flow sensitive manner. Set
LOCUS to location of the constant phi arg and return the value.
Return DEF directly if either PATH or idx is ZERO. */
static tree
get_value_locus_in_path (tree def, vec *path,
basic_block bb, int idx, source_location *locus)
{
tree arg;
gimple def_phi;
basic_block def_bb;
if (path == NULL || idx == 0)
return def;
def_phi = SSA_NAME_DEF_STMT (def);
if (gimple_code (def_phi) != GIMPLE_PHI)
return def;
def_bb = gimple_bb (def_phi);
/* Don't propagate loop invariants into deeper loops. */
if (!def_bb || bb_loop_depth (def_bb) < bb_loop_depth (bb))
return def;
/* Backtrack jump threading path from IDX to see if def has constant
value. */
for (int j = idx - 1; j >= 0; j--)
{
edge e = (*path)[j]->e;
if (e->dest == def_bb)
{
arg = gimple_phi_arg_def (def_phi, e->dest_idx);
if (is_gimple_min_invariant (arg))
{
*locus = gimple_phi_arg_location (def_phi, e->dest_idx);
return arg;
}
break;
}
}
return def;
}
/* For each PHI in BB, copy the argument associated with SRC_E to TGT_E.
Try to backtrack jump threading PATH from node IDX to see if the arg
has constant value, copy constant value instead of argument itself
if yes. */
static void
copy_phi_args (basic_block bb, edge src_e, edge tgt_e,
vec *path, int idx)
{
gimple_stmt_iterator gsi;
int src_indx = src_e->dest_idx;
for (gsi = gsi_start_phis (bb); !gsi_end_p (gsi); gsi_next (&gsi))
{
gimple phi = gsi_stmt (gsi);
tree def = gimple_phi_arg_def (phi, src_indx);
source_location locus = gimple_phi_arg_location (phi, src_indx);
if (TREE_CODE (def) == SSA_NAME
&& !virtual_operand_p (gimple_phi_result (phi)))
def = get_value_locus_in_path (def, path, bb, idx, &locus);
add_phi_arg (phi, def, tgt_e, locus);
}
}
/* We have recently made a copy of ORIG_BB, including its outgoing
edges. The copy is NEW_BB. Every PHI node in every direct successor of
ORIG_BB has a new argument associated with edge from NEW_BB to the
successor. Initialize the PHI argument so that it is equal to the PHI
argument associated with the edge from ORIG_BB to the successor.
PATH and IDX are used to check if the new PHI argument has constant
value in a flow sensitive manner. */
static void
update_destination_phis (basic_block orig_bb, basic_block new_bb,
vec *path, int idx)
{
edge_iterator ei;
edge e;
FOR_EACH_EDGE (e, ei, orig_bb->succs)
{
edge e2 = find_edge (new_bb, e->dest);
copy_phi_args (e->dest, e, e2, path, idx);
}
}
/* Given a duplicate block and its single destination (both stored
in RD). Create an edge between the duplicate and its single
destination.
Add an additional argument to any PHI nodes at the single
destination. IDX is the start node in jump threading path
we start to check to see if the new PHI argument has constant
value along the jump threading path. */
static void
create_edge_and_update_destination_phis (struct redirection_data *rd,
basic_block bb, int idx)
{
edge e = make_edge (bb, rd->path->last ()->e->dest, EDGE_FALLTHRU);
rescan_loop_exit (e, true, false);
e->probability = REG_BR_PROB_BASE;
e->count = bb->count;
/* We used to copy the thread path here. That was added in 2007
and dutifully updated through the representation changes in 2013.
In 2013 we added code to thread from an interior node through
the backedge to another interior node. That runs after the code
to thread through loop headers from outside the loop.
The latter may delete edges in the CFG, including those
which appeared in the jump threading path we copied here. Thus
we'd end up using a dangling pointer.
After reviewing the 2007/2011 code, I can't see how anything
depended on copying the AUX field and clearly copying the jump
threading path is problematical due to embedded edge pointers.
It has been removed. */
e->aux = NULL;
/* If there are any PHI nodes at the destination of the outgoing edge
from the duplicate block, then we will need to add a new argument
to them. The argument should have the same value as the argument
associated with the outgoing edge stored in RD. */
copy_phi_args (e->dest, rd->path->last ()->e, e, rd->path, idx);
}
/* Look through PATH beginning at START and return TRUE if there are
any additional blocks that need to be duplicated. Otherwise,
return FALSE. */
static bool
any_remaining_duplicated_blocks (vec *path,
unsigned int start)
{
for (unsigned int i = start + 1; i < path->length (); i++)
{
if ((*path)[i]->type == EDGE_COPY_SRC_JOINER_BLOCK
|| (*path)[i]->type == EDGE_COPY_SRC_BLOCK)
return true;
}
return false;
}
/* Compute the amount of profile count/frequency coming into the jump threading
path stored in RD that we are duplicating, returned in PATH_IN_COUNT_PTR and
PATH_IN_FREQ_PTR, as well as the amount of counts flowing out of the
duplicated path, returned in PATH_OUT_COUNT_PTR. LOCAL_INFO is used to
identify blocks duplicated for jump threading, which have duplicated
edges that need to be ignored in the analysis. Return true if path contains
a joiner, false otherwise.
In the non-joiner case, this is straightforward - all the counts/frequency
flowing into the jump threading path should flow through the duplicated
block and out of the duplicated path.
In the joiner case, it is very tricky. Some of the counts flowing into
the original path go offpath at the joiner. The problem is that while
we know how much total count goes off-path in the original control flow,
we don't know how many of the counts corresponding to just the jump
threading path go offpath at the joiner.
For example, assume we have the following control flow and identified
jump threading paths:
A B C
\ | /
Ea \ |Eb / Ec
\ | /
v v v
J <-- Joiner
/ \
Eoff/ \Eon
/ \
v v
Soff Son <--- Normal
/\
Ed/ \ Ee
/ \
v v
D E
Jump threading paths: A -> J -> Son -> D (path 1)
C -> J -> Son -> E (path 2)
Note that the control flow could be more complicated:
- Each jump threading path may have more than one incoming edge. I.e. A and
Ea could represent multiple incoming blocks/edges that are included in
path 1.
- There could be EDGE_NO_COPY_SRC_BLOCK edges after the joiner (either
before or after the "normal" copy block). These are not duplicated onto
the jump threading path, as they are single-successor.
- Any of the blocks along the path may have other incoming edges that
are not part of any jump threading path, but add profile counts along
the path.
In the aboe example, after all jump threading is complete, we will
end up with the following control flow:
A B C
| | |
Ea| |Eb |Ec
| | |
v v v
Ja J Jc
/ \ / \Eon' / \
Eona/ \ ---/---\-------- \Eonc
/ \ / / \ \
v v v v v
Sona Soff Son Sonc
\ /\ /
\___________ / \ _____/
\ / \/
vv v
D E
The main issue to notice here is that when we are processing path 1
(A->J->Son->D) we need to figure out the outgoing edge weights to
the duplicated edges Ja->Sona and Ja->Soff, while ensuring that the
sum of the incoming weights to D remain Ed. The problem with simply
assuming that Ja (and Jc when processing path 2) has the same outgoing
probabilities to its successors as the original block J, is that after
all paths are processed and other edges/counts removed (e.g. none
of Ec will reach D after processing path 2), we may end up with not
enough count flowing along duplicated edge Sona->D.
Therefore, in the case of a joiner, we keep track of all counts
coming in along the current path, as well as from predecessors not
on any jump threading path (Eb in the above example). While we
first assume that the duplicated Eona for Ja->Sona has the same
probability as the original, we later compensate for other jump
threading paths that may eliminate edges. We do that by keep track
of all counts coming into the original path that are not in a jump
thread (Eb in the above example, but as noted earlier, there could
be other predecessors incoming to the path at various points, such
as at Son). Call this cumulative non-path count coming into the path
before D as Enonpath. We then ensure that the count from Sona->D is as at
least as big as (Ed - Enonpath), but no bigger than the minimum
weight along the jump threading path. The probabilities of both the
original and duplicated joiner block J and Ja will be adjusted
accordingly after the updates. */
static bool
compute_path_counts (struct redirection_data *rd,
ssa_local_info_t *local_info,
gcov_type *path_in_count_ptr,
gcov_type *path_out_count_ptr,
int *path_in_freq_ptr)
{
edge e = rd->incoming_edges->e;
vec *path = THREAD_PATH (e);
edge elast = path->last ()->e;
gcov_type nonpath_count = 0;
bool has_joiner = false;
gcov_type path_in_count = 0;
int path_in_freq = 0;
/* Start by accumulating incoming edge counts to the path's first bb
into a couple buckets:
path_in_count: total count of incoming edges that flow into the
current path.
nonpath_count: total count of incoming edges that are not
flowing along *any* path. These are the counts
that will still flow along the original path after
all path duplication is done by potentially multiple
calls to this routine.
(any other incoming edge counts are for a different jump threading
path that will be handled by a later call to this routine.)
To make this easier, start by recording all incoming edges that flow into
the current path in a bitmap. We could add up the path's incoming edge
counts here, but we still need to walk all the first bb's incoming edges
below to add up the counts of the other edges not included in this jump
threading path. */
struct el *next, *el;
bitmap in_edge_srcs = BITMAP_ALLOC (NULL);
for (el = rd->incoming_edges; el; el = next)
{
next = el->next;
bitmap_set_bit (in_edge_srcs, el->e->src->index);
}
edge ein;
edge_iterator ei;
FOR_EACH_EDGE (ein, ei, e->dest->preds)
{
vec *ein_path = THREAD_PATH (ein);
/* Simply check the incoming edge src against the set captured above. */
if (ein_path
&& bitmap_bit_p (in_edge_srcs, (*ein_path)[0]->e->src->index))
{
/* It is necessary but not sufficient that the last path edges
are identical. There may be different paths that share the
same last path edge in the case where the last edge has a nocopy
source block. */
gcc_assert (ein_path->last ()->e == elast);
path_in_count += ein->count;
path_in_freq += EDGE_FREQUENCY (ein);
}
else if (!ein_path)
{
/* Keep track of the incoming edges that are not on any jump-threading
path. These counts will still flow out of original path after all
jump threading is complete. */
nonpath_count += ein->count;
}
}
BITMAP_FREE (in_edge_srcs);
/* Now compute the fraction of the total count coming into the first
path bb that is from the current threading path. */
gcov_type total_count = e->dest->count;
/* Handle incoming profile insanities. */
if (total_count < path_in_count)
path_in_count = total_count;
int onpath_scale = GCOV_COMPUTE_SCALE (path_in_count, total_count);
/* Walk the entire path to do some more computation in order to estimate
how much of the path_in_count will flow out of the duplicated threading
path. In the non-joiner case this is straightforward (it should be
the same as path_in_count, although we will handle incoming profile
insanities by setting it equal to the minimum count along the path).
In the joiner case, we need to estimate how much of the path_in_count
will stay on the threading path after the joiner's conditional branch.
We don't really know for sure how much of the counts
associated with this path go to each successor of the joiner, but we'll
estimate based on the fraction of the total count coming into the path
bb was from the threading paths (computed above in onpath_scale).
Afterwards, we will need to do some fixup to account for other threading
paths and possible profile insanities.
In order to estimate the joiner case's counts we also need to update
nonpath_count with any additional counts coming into the path. Other
blocks along the path may have additional predecessors from outside
the path. */
gcov_type path_out_count = path_in_count;
gcov_type min_path_count = path_in_count;
for (unsigned int i = 1; i < path->length (); i++)
{
edge epath = (*path)[i]->e;
gcov_type cur_count = epath->count;
if ((*path)[i]->type == EDGE_COPY_SRC_JOINER_BLOCK)
{
has_joiner = true;
cur_count = apply_probability (cur_count, onpath_scale);
}
/* In the joiner case we need to update nonpath_count for any edges
coming into the path that will contribute to the count flowing
into the path successor. */
if (has_joiner && epath != elast)
{
/* Look for other incoming edges after joiner. */
FOR_EACH_EDGE (ein, ei, epath->dest->preds)
{
if (ein != epath
/* Ignore in edges from blocks we have duplicated for a
threading path, which have duplicated edge counts until
they are redirected by an invocation of this routine. */
&& !bitmap_bit_p (local_info->duplicate_blocks,
ein->src->index))
nonpath_count += ein->count;
}
}
if (cur_count < path_out_count)
path_out_count = cur_count;
if (epath->count < min_path_count)
min_path_count = epath->count;
}
/* We computed path_out_count above assuming that this path targeted
the joiner's on-path successor with the same likelihood as it
reached the joiner. However, other thread paths through the joiner
may take a different path through the normal copy source block
(i.e. they have a different elast), meaning that they do not
contribute any counts to this path's elast. As a result, it may
turn out that this path must have more count flowing to the on-path
successor of the joiner. Essentially, all of this path's elast
count must be contributed by this path and any nonpath counts
(since any path through the joiner with a different elast will not
include a copy of this elast in its duplicated path).
So ensure that this path's path_out_count is at least the
difference between elast->count and nonpath_count. Otherwise the edge
counts after threading will not be sane. */
if (has_joiner && path_out_count < elast->count - nonpath_count)
{
path_out_count = elast->count - nonpath_count;
/* But neither can we go above the minimum count along the path
we are duplicating. This can be an issue due to profile
insanities coming in to this pass. */
if (path_out_count > min_path_count)
path_out_count = min_path_count;
}
*path_in_count_ptr = path_in_count;
*path_out_count_ptr = path_out_count;
*path_in_freq_ptr = path_in_freq;
return has_joiner;
}
/* Update the counts and frequencies for both an original path
edge EPATH and its duplicate EDUP. The duplicate source block
will get a count/frequency of PATH_IN_COUNT and PATH_IN_FREQ,
and the duplicate edge EDUP will have a count of PATH_OUT_COUNT. */
static void
update_profile (edge epath, edge edup, gcov_type path_in_count,
gcov_type path_out_count, int path_in_freq)
{
/* First update the duplicated block's count / frequency. */
if (edup)
{
basic_block dup_block = edup->src;
gcc_assert (dup_block->count == 0);
gcc_assert (dup_block->frequency == 0);
dup_block->count = path_in_count;
dup_block->frequency = path_in_freq;
}
/* Now update the original block's count and frequency in the
opposite manner - remove the counts/freq that will flow
into the duplicated block. Handle underflow due to precision/
rounding issues. */
epath->src->count -= path_in_count;
if (epath->src->count < 0)
epath->src->count = 0;
epath->src->frequency -= path_in_freq;
if (epath->src->frequency < 0)
epath->src->frequency = 0;
/* Next update this path edge's original and duplicated counts. We know
that the duplicated path will have path_out_count flowing
out of it (in the joiner case this is the count along the duplicated path
out of the duplicated joiner). This count can then be removed from the
original path edge. */
if (edup)
edup->count = path_out_count;
epath->count -= path_out_count;
gcc_assert (epath->count >= 0);
}
/* The duplicate and original joiner blocks may end up with different
probabilities (different from both the original and from each other).
Recompute the probabilities here once we have updated the edge
counts and frequencies. */
static void
recompute_probabilities (basic_block bb)
{
edge esucc;
edge_iterator ei;
FOR_EACH_EDGE (esucc, ei, bb->succs)
{
if (!bb->count)
continue;
/* Prevent overflow computation due to insane profiles. */
if (esucc->count < bb->count)
esucc->probability = GCOV_COMPUTE_SCALE (esucc->count,
bb->count);
else
/* Can happen with missing/guessed probabilities, since we
may determine that more is flowing along duplicated
path than joiner succ probabilities allowed.
Counts and freqs will be insane after jump threading,
at least make sure probability is sane or we will
get a flow verification error.
Not much we can do to make counts/freqs sane without
redoing the profile estimation. */
esucc->probability = REG_BR_PROB_BASE;
}
}
/* Update the counts of the original and duplicated edges from a joiner
that go off path, given that we have already determined that the
duplicate joiner DUP_BB has incoming count PATH_IN_COUNT and
outgoing count along the path PATH_OUT_COUNT. The original (on-)path
edge from joiner is EPATH. */
static void
update_joiner_offpath_counts (edge epath, basic_block dup_bb,
gcov_type path_in_count,
gcov_type path_out_count)
{
/* Compute the count that currently flows off path from the joiner.
In other words, the total count of joiner's out edges other than
epath. Compute this by walking the successors instead of
subtracting epath's count from the joiner bb count, since there
are sometimes slight insanities where the total out edge count is
larger than the bb count (possibly due to rounding/truncation
errors). */
gcov_type total_orig_off_path_count = 0;
edge enonpath;
edge_iterator ei;
FOR_EACH_EDGE (enonpath, ei, epath->src->succs)
{
if (enonpath == epath)
continue;
total_orig_off_path_count += enonpath->count;
}
/* For the path that we are duplicating, the amount that will flow
off path from the duplicated joiner is the delta between the
path's cumulative in count and the portion of that count we
estimated above as flowing from the joiner along the duplicated
path. */
gcov_type total_dup_off_path_count = path_in_count - path_out_count;
/* Now do the actual updates of the off-path edges. */
FOR_EACH_EDGE (enonpath, ei, epath->src->succs)
{
/* Look for edges going off of the threading path. */
if (enonpath == epath)
continue;
/* Find the corresponding edge out of the duplicated joiner. */
edge enonpathdup = find_edge (dup_bb, enonpath->dest);
gcc_assert (enonpathdup);
/* We can't use the original probability of the joiner's out
edges, since the probabilities of the original branch
and the duplicated branches may vary after all threading is
complete. But apportion the duplicated joiner's off-path
total edge count computed earlier (total_dup_off_path_count)
among the duplicated off-path edges based on their original
ratio to the full off-path count (total_orig_off_path_count).
*/
int scale = GCOV_COMPUTE_SCALE (enonpath->count,
total_orig_off_path_count);
/* Give the duplicated offpath edge a portion of the duplicated
total. */
enonpathdup->count = apply_scale (scale,
total_dup_off_path_count);
/* Now update the original offpath edge count, handling underflow
due to rounding errors. */
enonpath->count -= enonpathdup->count;
if (enonpath->count < 0)
enonpath->count = 0;
}
}
/* Check if the paths through RD all have estimated frequencies but zero
profile counts. This is more accurate than checking the entry block
for a zero profile count, since profile insanities sometimes creep in. */
static bool
estimated_freqs_path (struct redirection_data *rd)
{
edge e = rd->incoming_edges->e;
vec *path = THREAD_PATH (e);
edge ein;
edge_iterator ei;
bool non_zero_freq = false;
FOR_EACH_EDGE (ein, ei, e->dest->preds)
{
if (ein->count)
return false;
non_zero_freq |= ein->src->frequency != 0;
}
for (unsigned int i = 1; i < path->length (); i++)
{
edge epath = (*path)[i]->e;
if (epath->src->count)
return false;
non_zero_freq |= epath->src->frequency != 0;
edge esucc;
FOR_EACH_EDGE (esucc, ei, epath->src->succs)
{
if (esucc->count)
return false;
non_zero_freq |= esucc->src->frequency != 0;
}
}
return non_zero_freq;
}
/* Invoked for routines that have guessed frequencies and no profile
counts to record the block and edge frequencies for paths through RD
in the profile count fields of those blocks and edges. This is because
ssa_fix_duplicate_block_edges incrementally updates the block and
edge counts as edges are redirected, and it is difficult to do that
for edge frequencies which are computed on the fly from the source
block frequency and probability. When a block frequency is updated
its outgoing edge frequencies are affected and become difficult to
adjust. */
static void
freqs_to_counts_path (struct redirection_data *rd)
{
edge e = rd->incoming_edges->e;
vec *path = THREAD_PATH (e);
edge ein;
edge_iterator ei;
FOR_EACH_EDGE (ein, ei, e->dest->preds)
{
/* Scale up the frequency by REG_BR_PROB_BASE, to avoid rounding
errors applying the probability when the frequencies are very
small. */
ein->count = apply_probability (ein->src->frequency * REG_BR_PROB_BASE,
ein->probability);
}
for (unsigned int i = 1; i < path->length (); i++)
{
edge epath = (*path)[i]->e;
edge esucc;
/* Scale up the frequency by REG_BR_PROB_BASE, to avoid rounding
errors applying the edge probability when the frequencies are very
small. */
epath->src->count = epath->src->frequency * REG_BR_PROB_BASE;
FOR_EACH_EDGE (esucc, ei, epath->src->succs)
esucc->count = apply_probability (esucc->src->count,
esucc->probability);
}
}
/* For routines that have guessed frequencies and no profile counts, where we
used freqs_to_counts_path to record block and edge frequencies for paths
through RD, we clear the counts after completing all updates for RD.
The updates in ssa_fix_duplicate_block_edges are based off the count fields,
but the block frequencies and edge probabilities were updated as well,
so we can simply clear the count fields. */
static void
clear_counts_path (struct redirection_data *rd)
{
edge e = rd->incoming_edges->e;
vec *path = THREAD_PATH (e);
edge ein, esucc;
edge_iterator ei;
FOR_EACH_EDGE (ein, ei, e->dest->preds)
ein->count = 0;
/* First clear counts along original path. */
for (unsigned int i = 1; i < path->length (); i++)
{
edge epath = (*path)[i]->e;
FOR_EACH_EDGE (esucc, ei, epath->src->succs)
esucc->count = 0;
epath->src->count = 0;
}
/* Also need to clear the counts along duplicated path. */
for (unsigned int i = 0; i < 2; i++)
{
basic_block dup = rd->dup_blocks[i];
if (!dup)
continue;
FOR_EACH_EDGE (esucc, ei, dup->succs)
esucc->count = 0;
dup->count = 0;
}
}
/* Wire up the outgoing edges from the duplicate blocks and
update any PHIs as needed. Also update the profile counts
on the original and duplicate blocks and edges. */
void
ssa_fix_duplicate_block_edges (struct redirection_data *rd,
ssa_local_info_t *local_info)
{
bool multi_incomings = (rd->incoming_edges->next != NULL);
edge e = rd->incoming_edges->e;
vec *path = THREAD_PATH (e);
edge elast = path->last ()->e;
gcov_type path_in_count = 0;
gcov_type path_out_count = 0;
int path_in_freq = 0;
/* This routine updates profile counts, frequencies, and probabilities
incrementally. Since it is difficult to do the incremental updates
using frequencies/probabilities alone, for routines without profile
data we first take a snapshot of the existing block and edge frequencies
by copying them into the empty profile count fields. These counts are
then used to do the incremental updates, and cleared at the end of this
routine. If the function is marked as having a profile, we still check
to see if the paths through RD are using estimated frequencies because
the routine had zero profile counts. */
bool do_freqs_to_counts = (profile_status_for_fn (cfun) != PROFILE_READ
|| estimated_freqs_path (rd));
if (do_freqs_to_counts)
freqs_to_counts_path (rd);
/* First determine how much profile count to move from original
path to the duplicate path. This is tricky in the presence of
a joiner (see comments for compute_path_counts), where some portion
of the path's counts will flow off-path from the joiner. In the
non-joiner case the path_in_count and path_out_count should be the
same. */
bool has_joiner = compute_path_counts (rd, local_info,
&path_in_count, &path_out_count,
&path_in_freq);
int cur_path_freq = path_in_freq;
for (unsigned int count = 0, i = 1; i < path->length (); i++)
{
edge epath = (*path)[i]->e;
/* If we were threading through an joiner block, then we want
to keep its control statement and redirect an outgoing edge.
Else we want to remove the control statement & edges, then create
a new outgoing edge. In both cases we may need to update PHIs. */
if ((*path)[i]->type == EDGE_COPY_SRC_JOINER_BLOCK)
{
edge victim;
edge e2;
gcc_assert (has_joiner);
/* This updates the PHIs at the destination of the duplicate
block. Pass 0 instead of i if we are threading a path which
has multiple incoming edges. */
update_destination_phis (local_info->bb, rd->dup_blocks[count],
path, multi_incomings ? 0 : i);
/* Find the edge from the duplicate block to the block we're
threading through. That's the edge we want to redirect. */
victim = find_edge (rd->dup_blocks[count], (*path)[i]->e->dest);
/* If there are no remaining blocks on the path to duplicate,
then redirect VICTIM to the final destination of the jump
threading path. */
if (!any_remaining_duplicated_blocks (path, i))
{
e2 = redirect_edge_and_branch (victim, elast->dest);
/* If we redirected the edge, then we need to copy PHI arguments
at the target. If the edge already existed (e2 != victim
case), then the PHIs in the target already have the correct
arguments. */
if (e2 == victim)
copy_phi_args (e2->dest, elast, e2,
path, multi_incomings ? 0 : i);
}
else
{
/* Redirect VICTIM to the next duplicated block in the path. */
e2 = redirect_edge_and_branch (victim, rd->dup_blocks[count + 1]);
/* We need to update the PHIs in the next duplicated block. We
want the new PHI args to have the same value as they had
in the source of the next duplicate block.
Thus, we need to know which edge we traversed into the
source of the duplicate. Furthermore, we may have
traversed many edges to reach the source of the duplicate.
Walk through the path starting at element I until we
hit an edge marked with EDGE_COPY_SRC_BLOCK. We want
the edge from the prior element. */
for (unsigned int j = i + 1; j < path->length (); j++)
{
if ((*path)[j]->type == EDGE_COPY_SRC_BLOCK)
{
copy_phi_arg_into_existing_phi ((*path)[j - 1]->e, e2);
break;
}
}
}
/* Update the counts and frequency of both the original block
and path edge, and the duplicates. The path duplicate's
incoming count and frequency are the totals for all edges
incoming to this jump threading path computed earlier.
And we know that the duplicated path will have path_out_count
flowing out of it (i.e. along the duplicated path out of the
duplicated joiner). */
update_profile (epath, e2, path_in_count, path_out_count,
path_in_freq);
/* Next we need to update the counts of the original and duplicated
edges from the joiner that go off path. */
update_joiner_offpath_counts (epath, e2->src, path_in_count,
path_out_count);
/* Finally, we need to set the probabilities on the duplicated
edges out of the duplicated joiner (e2->src). The probabilities
along the original path will all be updated below after we finish
processing the whole path. */
recompute_probabilities (e2->src);
/* Record the frequency flowing to the downstream duplicated
path blocks. */
cur_path_freq = EDGE_FREQUENCY (e2);
}
else if ((*path)[i]->type == EDGE_COPY_SRC_BLOCK)
{
remove_ctrl_stmt_and_useless_edges (rd->dup_blocks[count], NULL);
create_edge_and_update_destination_phis (rd, rd->dup_blocks[count],
multi_incomings ? 0 : i);
if (count == 1)
single_succ_edge (rd->dup_blocks[1])->aux = NULL;
/* Update the counts and frequency of both the original block
and path edge, and the duplicates. Since we are now after
any joiner that may have existed on the path, the count
flowing along the duplicated threaded path is path_out_count.
If we didn't have a joiner, then cur_path_freq was the sum
of the total frequencies along all incoming edges to the
thread path (path_in_freq). If we had a joiner, it would have
been updated at the end of that handling to the edge frequency
along the duplicated joiner path edge. */
update_profile (epath, EDGE_SUCC (rd->dup_blocks[count], 0),
path_out_count, path_out_count,
cur_path_freq);
}
else
{
/* No copy case. In this case we don't have an equivalent block
on the duplicated thread path to update, but we do need
to remove the portion of the counts/freqs that were moved
to the duplicated path from the counts/freqs flowing through
this block on the original path. Since all the no-copy edges
are after any joiner, the removed count is the same as
path_out_count.
If we didn't have a joiner, then cur_path_freq was the sum
of the total frequencies along all incoming edges to the
thread path (path_in_freq). If we had a joiner, it would have
been updated at the end of that handling to the edge frequency
along the duplicated joiner path edge. */
update_profile (epath, NULL, path_out_count, path_out_count,
cur_path_freq);
}
/* Increment the index into the duplicated path when we processed
a duplicated block. */
if ((*path)[i]->type == EDGE_COPY_SRC_JOINER_BLOCK
|| (*path)[i]->type == EDGE_COPY_SRC_BLOCK)
{
count++;
}
}
/* Now walk orig blocks and update their probabilities, since the
counts and freqs should be updated properly by above loop. */
for (unsigned int i = 1; i < path->length (); i++)
{
edge epath = (*path)[i]->e;
recompute_probabilities (epath->src);
}
/* Done with all profile and frequency updates, clear counts if they
were copied. */
if (do_freqs_to_counts)
clear_counts_path (rd);
}
/* Hash table traversal callback routine to create duplicate blocks. */
int
ssa_create_duplicates (struct redirection_data **slot,
ssa_local_info_t *local_info)
{
struct redirection_data *rd = *slot;
/* The second duplicated block in a jump threading path is specific
to the path. So it gets stored in RD rather than in LOCAL_DATA.
Each time we're called, we have to look through the path and see
if a second block needs to be duplicated.
Note the search starts with the third edge on the path. The first
edge is the incoming edge, the second edge always has its source
duplicated. Thus we start our search with the third edge. */
vec *path = rd->path;
for (unsigned int i = 2; i < path->length (); i++)
{
if ((*path)[i]->type == EDGE_COPY_SRC_BLOCK
|| (*path)[i]->type == EDGE_COPY_SRC_JOINER_BLOCK)
{
create_block_for_threading ((*path)[i]->e->src, rd, 1,
&local_info->duplicate_blocks);
break;
}
}
/* Create a template block if we have not done so already. Otherwise
use the template to create a new block. */
if (local_info->template_block == NULL)
{
create_block_for_threading ((*path)[1]->e->src, rd, 0,
&local_info->duplicate_blocks);
local_info->template_block = rd->dup_blocks[0];
/* We do not create any outgoing edges for the template. We will
take care of that in a later traversal. That way we do not
create edges that are going to just be deleted. */
}
else
{
create_block_for_threading (local_info->template_block, rd, 0,
&local_info->duplicate_blocks);
/* Go ahead and wire up outgoing edges and update PHIs for the duplicate
block. */
ssa_fix_duplicate_block_edges (rd, local_info);
}
/* Keep walking the hash table. */
return 1;
}
/* We did not create any outgoing edges for the template block during
block creation. This hash table traversal callback creates the
outgoing edge for the template block. */
inline int
ssa_fixup_template_block (struct redirection_data **slot,
ssa_local_info_t *local_info)
{
struct redirection_data *rd = *slot;
/* If this is the template block halt the traversal after updating
it appropriately.
If we were threading through an joiner block, then we want
to keep its control statement and redirect an outgoing edge.
Else we want to remove the control statement & edges, then create
a new outgoing edge. In both cases we may need to update PHIs. */
if (rd->dup_blocks[0] && rd->dup_blocks[0] == local_info->template_block)
{
ssa_fix_duplicate_block_edges (rd, local_info);
return 0;
}
return 1;
}
/* Hash table traversal callback to redirect each incoming edge
associated with this hash table element to its new destination. */
int
ssa_redirect_edges (struct redirection_data **slot,
ssa_local_info_t *local_info)
{
struct redirection_data *rd = *slot;
struct el *next, *el;
/* Walk over all the incoming edges associated associated with this
hash table entry. */
for (el = rd->incoming_edges; el; el = next)
{
edge e = el->e;
vec *path = THREAD_PATH (e);
/* Go ahead and free this element from the list. Doing this now
avoids the need for another list walk when we destroy the hash
table. */
next = el->next;
free (el);
thread_stats.num_threaded_edges++;
if (rd->dup_blocks[0])
{
edge e2;
if (dump_file && (dump_flags & TDF_DETAILS))
fprintf (dump_file, " Threaded jump %d --> %d to %d\n",
e->src->index, e->dest->index, rd->dup_blocks[0]->index);
/* If we redirect a loop latch edge cancel its loop. */
if (e->src == e->src->loop_father->latch)
mark_loop_for_removal (e->src->loop_father);
/* Redirect the incoming edge (possibly to the joiner block) to the
appropriate duplicate block. */
e2 = redirect_edge_and_branch (e, rd->dup_blocks[0]);
gcc_assert (e == e2);
flush_pending_stmts (e2);
}
/* Go ahead and clear E->aux. It's not needed anymore and failure
to clear it will cause all kinds of unpleasant problems later. */
delete_jump_thread_path (path);
e->aux = NULL;
}
/* Indicate that we actually threaded one or more jumps. */
if (rd->incoming_edges)
local_info->jumps_threaded = true;
return 1;
}
/* Return true if this block has no executable statements other than
a simple ctrl flow instruction. When the number of outgoing edges
is one, this is equivalent to a "forwarder" block. */
static bool
redirection_block_p (basic_block bb)
{
gimple_stmt_iterator gsi;
/* Advance to the first executable statement. */
gsi = gsi_start_bb (bb);
while (!gsi_end_p (gsi)
&& (gimple_code (gsi_stmt (gsi)) == GIMPLE_LABEL
|| is_gimple_debug (gsi_stmt (gsi))
|| gimple_nop_p (gsi_stmt (gsi))))
gsi_next (&gsi);
/* Check if this is an empty block. */
if (gsi_end_p (gsi))
return true;
/* Test that we've reached the terminating control statement. */
return gsi_stmt (gsi)
&& (gimple_code (gsi_stmt (gsi)) == GIMPLE_COND
|| gimple_code (gsi_stmt (gsi)) == GIMPLE_GOTO
|| gimple_code (gsi_stmt (gsi)) == GIMPLE_SWITCH);
}
/* BB is a block which ends with a COND_EXPR or SWITCH_EXPR and when BB
is reached via one or more specific incoming edges, we know which
outgoing edge from BB will be traversed.
We want to redirect those incoming edges to the target of the
appropriate outgoing edge. Doing so avoids a conditional branch
and may expose new optimization opportunities. Note that we have
to update dominator tree and SSA graph after such changes.
The key to keeping the SSA graph update manageable is to duplicate
the side effects occurring in BB so that those side effects still
occur on the paths which bypass BB after redirecting edges.
We accomplish this by creating duplicates of BB and arranging for
the duplicates to unconditionally pass control to one specific
successor of BB. We then revector the incoming edges into BB to
the appropriate duplicate of BB.
If NOLOOP_ONLY is true, we only perform the threading as long as it
does not affect the structure of the loops in a nontrivial way.
If JOINERS is true, then thread through joiner blocks as well. */
static bool
thread_block_1 (basic_block bb, bool noloop_only, bool joiners)
{
/* E is an incoming edge into BB that we may or may not want to
redirect to a duplicate of BB. */
edge e, e2;
edge_iterator ei;
ssa_local_info_t local_info;
local_info.duplicate_blocks = BITMAP_ALLOC (NULL);
/* To avoid scanning a linear array for the element we need we instead
use a hash table. For normal code there should be no noticeable
difference. However, if we have a block with a large number of
incoming and outgoing edges such linear searches can get expensive. */
redirection_data
= new hash_table (EDGE_COUNT (bb->succs));
/* Record each unique threaded destination into a hash table for
efficient lookups. */
FOR_EACH_EDGE (e, ei, bb->preds)
{
if (e->aux == NULL)
continue;
vec *path = THREAD_PATH (e);
if (((*path)[1]->type == EDGE_COPY_SRC_JOINER_BLOCK && !joiners)
|| ((*path)[1]->type == EDGE_COPY_SRC_BLOCK && joiners))
continue;
e2 = path->last ()->e;
if (!e2 || noloop_only)
{
/* If NOLOOP_ONLY is true, we only allow threading through the
header of a loop to exit edges. */
/* One case occurs when there was loop header buried in a jump
threading path that crosses loop boundaries. We do not try
and thread this elsewhere, so just cancel the jump threading
request by clearing the AUX field now. */
if ((bb->loop_father != e2->src->loop_father
&& !loop_exit_edge_p (e2->src->loop_father, e2))
|| (e2->src->loop_father != e2->dest->loop_father
&& !loop_exit_edge_p (e2->src->loop_father, e2)))
{
/* Since this case is not handled by our special code
to thread through a loop header, we must explicitly
cancel the threading request here. */
delete_jump_thread_path (path);
e->aux = NULL;
continue;
}
/* Another case occurs when trying to thread through our
own loop header, possibly from inside the loop. We will
thread these later. */
unsigned int i;
for (i = 1; i < path->length (); i++)
{
if ((*path)[i]->e->src == bb->loop_father->header
&& (!loop_exit_edge_p (bb->loop_father, e2)
|| (*path)[1]->type == EDGE_COPY_SRC_JOINER_BLOCK))
break;
}
if (i != path->length ())
continue;
}
/* Insert the outgoing edge into the hash table if it is not
already in the hash table. */
lookup_redirection_data (e, INSERT);
}
/* We do not update dominance info. */
free_dominance_info (CDI_DOMINATORS);
/* We know we only thread through the loop header to loop exits.
Let the basic block duplication hook know we are not creating
a multiple entry loop. */
if (noloop_only
&& bb == bb->loop_father->header)
set_loop_copy (bb->loop_father, loop_outer (bb->loop_father));
/* Now create duplicates of BB.
Note that for a block with a high outgoing degree we can waste
a lot of time and memory creating and destroying useless edges.
So we first duplicate BB and remove the control structure at the
tail of the duplicate as well as all outgoing edges from the
duplicate. We then use that duplicate block as a template for
the rest of the duplicates. */
local_info.template_block = NULL;
local_info.bb = bb;
local_info.jumps_threaded = false;
redirection_data->traverse
(&local_info);
/* The template does not have an outgoing edge. Create that outgoing
edge and update PHI nodes as the edge's target as necessary.
We do this after creating all the duplicates to avoid creating
unnecessary edges. */
redirection_data->traverse
(&local_info);
/* The hash table traversals above created the duplicate blocks (and the
statements within the duplicate blocks). This loop creates PHI nodes for
the duplicated blocks and redirects the incoming edges into BB to reach
the duplicates of BB. */
redirection_data->traverse
(&local_info);
/* Done with this block. Clear REDIRECTION_DATA. */
delete redirection_data;
redirection_data = NULL;
if (noloop_only
&& bb == bb->loop_father->header)
set_loop_copy (bb->loop_father, NULL);
BITMAP_FREE (local_info.duplicate_blocks);
local_info.duplicate_blocks = NULL;
/* Indicate to our caller whether or not any jumps were threaded. */
return local_info.jumps_threaded;
}
/* Wrapper for thread_block_1 so that we can first handle jump
thread paths which do not involve copying joiner blocks, then
handle jump thread paths which have joiner blocks.
By doing things this way we can be as aggressive as possible and
not worry that copying a joiner block will create a jump threading
opportunity. */
static bool
thread_block (basic_block bb, bool noloop_only)
{
bool retval;
retval = thread_block_1 (bb, noloop_only, false);
retval |= thread_block_1 (bb, noloop_only, true);
return retval;
}
/* Threads edge E through E->dest to the edge THREAD_TARGET (E). Returns the
copy of E->dest created during threading, or E->dest if it was not necessary
to copy it (E is its single predecessor). */
static basic_block
thread_single_edge (edge e)
{
basic_block bb = e->dest;
struct redirection_data rd;
vec *path = THREAD_PATH (e);
edge eto = (*path)[1]->e;
for (unsigned int i = 0; i < path->length (); i++)
delete (*path)[i];
delete path;
e->aux = NULL;
thread_stats.num_threaded_edges++;
if (single_pred_p (bb))
{
/* If BB has just a single predecessor, we should only remove the
control statements at its end, and successors except for ETO. */
remove_ctrl_stmt_and_useless_edges (bb, eto->dest);
/* And fixup the flags on the single remaining edge. */
eto->flags &= ~(EDGE_TRUE_VALUE | EDGE_FALSE_VALUE | EDGE_ABNORMAL);
eto->flags |= EDGE_FALLTHRU;
return bb;
}
/* Otherwise, we need to create a copy. */
if (e->dest == eto->src)
update_bb_profile_for_threading (bb, EDGE_FREQUENCY (e), e->count, eto);
vec *npath = new vec ();
jump_thread_edge *x = new jump_thread_edge (e, EDGE_START_JUMP_THREAD);
npath->safe_push (x);
x = new jump_thread_edge (eto, EDGE_COPY_SRC_BLOCK);
npath->safe_push (x);
rd.path = npath;
create_block_for_threading (bb, &rd, 0, NULL);
remove_ctrl_stmt_and_useless_edges (rd.dup_blocks[0], NULL);
create_edge_and_update_destination_phis (&rd, rd.dup_blocks[0], 0);
if (dump_file && (dump_flags & TDF_DETAILS))
fprintf (dump_file, " Threaded jump %d --> %d to %d\n",
e->src->index, e->dest->index, rd.dup_blocks[0]->index);
rd.dup_blocks[0]->count = e->count;
rd.dup_blocks[0]->frequency = EDGE_FREQUENCY (e);
single_succ_edge (rd.dup_blocks[0])->count = e->count;
redirect_edge_and_branch (e, rd.dup_blocks[0]);
flush_pending_stmts (e);
return rd.dup_blocks[0];
}
/* Callback for dfs_enumerate_from. Returns true if BB is different
from STOP and DBDS_CE_STOP. */
static basic_block dbds_ce_stop;
static bool
dbds_continue_enumeration_p (const_basic_block bb, const void *stop)
{
return (bb != (const_basic_block) stop
&& bb != dbds_ce_stop);
}
/* Evaluates the dominance relationship of latch of the LOOP and BB, and
returns the state. */
enum bb_dom_status
{
/* BB does not dominate latch of the LOOP. */
DOMST_NONDOMINATING,
/* The LOOP is broken (there is no path from the header to its latch. */
DOMST_LOOP_BROKEN,
/* BB dominates the latch of the LOOP. */
DOMST_DOMINATING
};
static enum bb_dom_status
determine_bb_domination_status (struct loop *loop, basic_block bb)
{
basic_block *bblocks;
unsigned nblocks, i;
bool bb_reachable = false;
edge_iterator ei;
edge e;
/* This function assumes BB is a successor of LOOP->header.
If that is not the case return DOMST_NONDOMINATING which
is always safe. */
{
bool ok = false;
FOR_EACH_EDGE (e, ei, bb->preds)
{
if (e->src == loop->header)
{
ok = true;
break;
}
}
if (!ok)
return DOMST_NONDOMINATING;
}
if (bb == loop->latch)
return DOMST_DOMINATING;
/* Check that BB dominates LOOP->latch, and that it is back-reachable
from it. */
bblocks = XCNEWVEC (basic_block, loop->num_nodes);
dbds_ce_stop = loop->header;
nblocks = dfs_enumerate_from (loop->latch, 1, dbds_continue_enumeration_p,
bblocks, loop->num_nodes, bb);
for (i = 0; i < nblocks; i++)
FOR_EACH_EDGE (e, ei, bblocks[i]->preds)
{
if (e->src == loop->header)
{
free (bblocks);
return DOMST_NONDOMINATING;
}
if (e->src == bb)
bb_reachable = true;
}
free (bblocks);
return (bb_reachable ? DOMST_DOMINATING : DOMST_LOOP_BROKEN);
}
/* Return true if BB is part of the new pre-header that is created
when threading the latch to DATA. */
static bool
def_split_header_continue_p (const_basic_block bb, const void *data)
{
const_basic_block new_header = (const_basic_block) data;
const struct loop *l;
if (bb == new_header
|| loop_depth (bb->loop_father) < loop_depth (new_header->loop_father))
return false;
for (l = bb->loop_father; l; l = loop_outer (l))
if (l == new_header->loop_father)
return true;
return false;
}
/* Thread jumps through the header of LOOP. Returns true if cfg changes.
If MAY_PEEL_LOOP_HEADERS is false, we avoid threading from entry edges
to the inside of the loop. */
static bool
thread_through_loop_header (struct loop *loop, bool may_peel_loop_headers)
{
basic_block header = loop->header;
edge e, tgt_edge, latch = loop_latch_edge (loop);
edge_iterator ei;
basic_block tgt_bb, atgt_bb;
enum bb_dom_status domst;
/* We have already threaded through headers to exits, so all the threading
requests now are to the inside of the loop. We need to avoid creating
irreducible regions (i.e., loops with more than one entry block), and
also loop with several latch edges, or new subloops of the loop (although
there are cases where it might be appropriate, it is difficult to decide,
and doing it wrongly may confuse other optimizers).
We could handle more general cases here. However, the intention is to
preserve some information about the loop, which is impossible if its
structure changes significantly, in a way that is not well understood.
Thus we only handle few important special cases, in which also updating
of the loop-carried information should be feasible:
1) Propagation of latch edge to a block that dominates the latch block
of a loop. This aims to handle the following idiom:
first = 1;
while (1)
{
if (first)
initialize;
first = 0;
body;
}
After threading the latch edge, this becomes
first = 1;
if (first)
initialize;
while (1)
{
first = 0;
body;
}
The original header of the loop is moved out of it, and we may thread
the remaining edges through it without further constraints.
2) All entry edges are propagated to a single basic block that dominates
the latch block of the loop. This aims to handle the following idiom
(normally created for "for" loops):
i = 0;
while (1)
{
if (i >= 100)
break;
body;
i++;
}
This becomes
i = 0;
while (1)
{
body;
i++;
if (i >= 100)
break;
}
*/
/* Threading through the header won't improve the code if the header has just
one successor. */
if (single_succ_p (header))
goto fail;
/* If we threaded the latch using a joiner block, we cancel the
threading opportunity out of an abundance of caution. However,
still allow threading from outside to inside the loop. */
if (latch->aux)
{
vec *path = THREAD_PATH (latch);
if ((*path)[1]->type == EDGE_COPY_SRC_JOINER_BLOCK)
{
delete_jump_thread_path (path);
latch->aux = NULL;
}
}
if (latch->aux)
{
vec *path = THREAD_PATH (latch);
tgt_edge = (*path)[1]->e;
tgt_bb = tgt_edge->dest;
}
else if (!may_peel_loop_headers
&& !redirection_block_p (loop->header))
goto fail;
else
{
tgt_bb = NULL;
tgt_edge = NULL;
FOR_EACH_EDGE (e, ei, header->preds)
{
if (!e->aux)
{
if (e == latch)
continue;
/* If latch is not threaded, and there is a header
edge that is not threaded, we would create loop
with multiple entries. */
goto fail;
}
vec *path = THREAD_PATH (e);
if ((*path)[1]->type == EDGE_COPY_SRC_JOINER_BLOCK)
goto fail;
tgt_edge = (*path)[1]->e;
atgt_bb = tgt_edge->dest;
if (!tgt_bb)
tgt_bb = atgt_bb;
/* Two targets of threading would make us create loop
with multiple entries. */
else if (tgt_bb != atgt_bb)
goto fail;
}
if (!tgt_bb)
{
/* There are no threading requests. */
return false;
}
/* Redirecting to empty loop latch is useless. */
if (tgt_bb == loop->latch
&& empty_block_p (loop->latch))
goto fail;
}
/* The target block must dominate the loop latch, otherwise we would be
creating a subloop. */
domst = determine_bb_domination_status (loop, tgt_bb);
if (domst == DOMST_NONDOMINATING)
goto fail;
if (domst == DOMST_LOOP_BROKEN)
{
/* If the loop ceased to exist, mark it as such, and thread through its
original header. */
mark_loop_for_removal (loop);
return thread_block (header, false);
}
if (tgt_bb->loop_father->header == tgt_bb)
{
/* If the target of the threading is a header of a subloop, we need
to create a preheader for it, so that the headers of the two loops
do not merge. */
if (EDGE_COUNT (tgt_bb->preds) > 2)
{
tgt_bb = create_preheader (tgt_bb->loop_father, 0);
gcc_assert (tgt_bb != NULL);
}
else
tgt_bb = split_edge (tgt_edge);
}
if (latch->aux)
{
basic_block *bblocks;
unsigned nblocks, i;
/* First handle the case latch edge is redirected. We are copying
the loop header but not creating a multiple entry loop. Make the
cfg manipulation code aware of that fact. */
set_loop_copy (loop, loop);
loop->latch = thread_single_edge (latch);
set_loop_copy (loop, NULL);
gcc_assert (single_succ (loop->latch) == tgt_bb);
loop->header = tgt_bb;
/* Remove the new pre-header blocks from our loop. */
bblocks = XCNEWVEC (basic_block, loop->num_nodes);
nblocks = dfs_enumerate_from (header, 0, def_split_header_continue_p,
bblocks, loop->num_nodes, tgt_bb);
for (i = 0; i < nblocks; i++)
if (bblocks[i]->loop_father == loop)
{
remove_bb_from_loops (bblocks[i]);
add_bb_to_loop (bblocks[i], loop_outer (loop));
}
free (bblocks);
/* If the new header has multiple latches mark it so. */
FOR_EACH_EDGE (e, ei, loop->header->preds)
if (e->src->loop_father == loop
&& e->src != loop->latch)
{
loop->latch = NULL;
loops_state_set (LOOPS_MAY_HAVE_MULTIPLE_LATCHES);
}
/* Cancel remaining threading requests that would make the
loop a multiple entry loop. */
FOR_EACH_EDGE (e, ei, header->preds)
{
edge e2;
if (e->aux == NULL)
continue;
vec *path = THREAD_PATH (e);
e2 = path->last ()->e;
if (e->src->loop_father != e2->dest->loop_father
&& e2->dest != loop->header)
{
delete_jump_thread_path (path);
e->aux = NULL;
}
}
/* Thread the remaining edges through the former header. */
thread_block (header, false);
}
else
{
basic_block new_preheader;
/* Now consider the case entry edges are redirected to the new entry
block. Remember one entry edge, so that we can find the new
preheader (its destination after threading). */
FOR_EACH_EDGE (e, ei, header->preds)
{
if (e->aux)
break;
}
/* The duplicate of the header is the new preheader of the loop. Ensure
that it is placed correctly in the loop hierarchy. */
set_loop_copy (loop, loop_outer (loop));
thread_block (header, false);
set_loop_copy (loop, NULL);
new_preheader = e->dest;
/* Create the new latch block. This is always necessary, as the latch
must have only a single successor, but the original header had at
least two successors. */
loop->latch = NULL;
mfb_kj_edge = single_succ_edge (new_preheader);
loop->header = mfb_kj_edge->dest;
latch = make_forwarder_block (tgt_bb, mfb_keep_just, NULL);
loop->header = latch->dest;
loop->latch = latch->src;
}
return true;
fail:
/* We failed to thread anything. Cancel the requests. */
FOR_EACH_EDGE (e, ei, header->preds)
{
vec *path = THREAD_PATH (e);
if (path)
{
delete_jump_thread_path (path);
e->aux = NULL;
}
}
return false;
}
/* E1 and E2 are edges into the same basic block. Return TRUE if the
PHI arguments associated with those edges are equal or there are no
PHI arguments, otherwise return FALSE. */
static bool
phi_args_equal_on_edges (edge e1, edge e2)
{
gimple_stmt_iterator gsi;
int indx1 = e1->dest_idx;
int indx2 = e2->dest_idx;
for (gsi = gsi_start_phis (e1->dest); !gsi_end_p (gsi); gsi_next (&gsi))
{
gimple phi = gsi_stmt (gsi);
if (!operand_equal_p (gimple_phi_arg_def (phi, indx1),
gimple_phi_arg_def (phi, indx2), 0))
return false;
}
return true;
}
/* Walk through the registered jump threads and convert them into a
form convenient for this pass.
Any block which has incoming edges threaded to outgoing edges
will have its entry in THREADED_BLOCK set.
Any threaded edge will have its new outgoing edge stored in the
original edge's AUX field.
This form avoids the need to walk all the edges in the CFG to
discover blocks which need processing and avoids unnecessary
hash table lookups to map from threaded edge to new target. */
static void
mark_threaded_blocks (bitmap threaded_blocks)
{
unsigned int i;
bitmap_iterator bi;
bitmap tmp = BITMAP_ALLOC (NULL);
basic_block bb;
edge e;
edge_iterator ei;
/* It is possible to have jump threads in which one is a subpath
of the other. ie, (A, B), (B, C), (C, D) where B is a joiner
block and (B, C), (C, D) where no joiner block exists.
When this occurs ignore the jump thread request with the joiner
block. It's totally subsumed by the simpler jump thread request.
This results in less block copying, simpler CFGs. More importantly,
when we duplicate the joiner block, B, in this case we will create
a new threading opportunity that we wouldn't be able to optimize
until the next jump threading iteration.
So first convert the jump thread requests which do not require a
joiner block. */
for (i = 0; i < paths.length (); i++)
{
vec *path = paths[i];
if ((*path)[1]->type != EDGE_COPY_SRC_JOINER_BLOCK)
{
edge e = (*path)[0]->e;
e->aux = (void *)path;
bitmap_set_bit (tmp, e->dest->index);
}
}
/* Now iterate again, converting cases where we want to thread
through a joiner block, but only if no other edge on the path
already has a jump thread attached to it. We do this in two passes,
to avoid situations where the order in the paths vec can hide overlapping
threads (the path is recorded on the incoming edge, so we would miss
cases where the second path starts at a downstream edge on the same
path). First record all joiner paths, deleting any in the unexpected
case where there is already a path for that incoming edge. */
for (i = 0; i < paths.length (); i++)
{
vec *path = paths[i];
if ((*path)[1]->type == EDGE_COPY_SRC_JOINER_BLOCK)
{
/* Attach the path to the starting edge if none is yet recorded. */
if ((*path)[0]->e->aux == NULL)
(*path)[0]->e->aux = path;
else if (dump_file && (dump_flags & TDF_DETAILS))
dump_jump_thread_path (dump_file, *path, false);
}
}
/* Second, look for paths that have any other jump thread attached to
them, and either finish converting them or cancel them. */
for (i = 0; i < paths.length (); i++)
{
vec *path = paths[i];
edge e = (*path)[0]->e;
if ((*path)[1]->type == EDGE_COPY_SRC_JOINER_BLOCK && e->aux == path)
{
unsigned int j;
for (j = 1; j < path->length (); j++)
if ((*path)[j]->e->aux != NULL)
break;
/* If we iterated through the entire path without exiting the loop,
then we are good to go, record it. */
if (j == path->length ())
bitmap_set_bit (tmp, e->dest->index);
else
{
e->aux = NULL;
if (dump_file && (dump_flags & TDF_DETAILS))
dump_jump_thread_path (dump_file, *path, false);
}
}
}
/* If optimizing for size, only thread through block if we don't have
to duplicate it or it's an otherwise empty redirection block. */
if (optimize_function_for_size_p (cfun))
{
EXECUTE_IF_SET_IN_BITMAP (tmp, 0, i, bi)
{
bb = BASIC_BLOCK_FOR_FN (cfun, i);
if (EDGE_COUNT (bb->preds) > 1
&& !redirection_block_p (bb))
{
FOR_EACH_EDGE (e, ei, bb->preds)
{
if (e->aux)
{
vec *path = THREAD_PATH (e);
delete_jump_thread_path (path);
e->aux = NULL;
}
}
}
else
bitmap_set_bit (threaded_blocks, i);
}
}
else
bitmap_copy (threaded_blocks, tmp);
/* Look for jump threading paths which cross multiple loop headers.
The code to thread through loop headers will change the CFG in ways
that break assumptions made by the loop optimization code.
We don't want to blindly cancel the requests. We can instead do better
by trimming off the end of the jump thread path. */
EXECUTE_IF_SET_IN_BITMAP (tmp, 0, i, bi)
{
basic_block bb = BASIC_BLOCK_FOR_FN (cfun, i);
FOR_EACH_EDGE (e, ei, bb->preds)
{
if (e->aux)
{
vec *path = THREAD_PATH (e);
for (unsigned int i = 0, crossed_headers = 0;
i < path->length ();
i++)
{
basic_block dest = (*path)[i]->e->dest;
crossed_headers += (dest == dest->loop_father->header);
if (crossed_headers > 1)
{
/* Trim from entry I onwards. */
for (unsigned int j = i; j < path->length (); j++)
delete (*path)[j];
path->truncate (i);
/* Now that we've truncated the path, make sure
what's left is still valid. We need at least
two edges on the path and the last edge can not
be a joiner. This should never happen, but let's
be safe. */
if (path->length () < 2
|| (path->last ()->type
== EDGE_COPY_SRC_JOINER_BLOCK))
{
delete_jump_thread_path (path);
e->aux = NULL;
}
break;
}
}
}
}
}
/* If we have a joiner block (J) which has two successors S1 and S2 and
we are threading though S1 and the final destination of the thread
is S2, then we must verify that any PHI nodes in S2 have the same
PHI arguments for the edge J->S2 and J->S1->...->S2.
We used to detect this prior to registering the jump thread, but
that prohibits propagation of edge equivalences into non-dominated
PHI nodes as the equivalency test might occur before propagation.
This must also occur after we truncate any jump threading paths
as this scenario may only show up after truncation.
This works for now, but will need improvement as part of the FSA
optimization.
Note since we've moved the thread request data to the edges,
we have to iterate on those rather than the threaded_edges vector. */
EXECUTE_IF_SET_IN_BITMAP (tmp, 0, i, bi)
{
bb = BASIC_BLOCK_FOR_FN (cfun, i);
FOR_EACH_EDGE (e, ei, bb->preds)
{
if (e->aux)
{
vec *path = THREAD_PATH (e);
bool have_joiner = ((*path)[1]->type == EDGE_COPY_SRC_JOINER_BLOCK);
if (have_joiner)
{
basic_block joiner = e->dest;
edge final_edge = path->last ()->e;
basic_block final_dest = final_edge->dest;
edge e2 = find_edge (joiner, final_dest);
if (e2 && !phi_args_equal_on_edges (e2, final_edge))
{
delete_jump_thread_path (path);
e->aux = NULL;
}
}
}
}
}
BITMAP_FREE (tmp);
}
/* Return TRUE if BB ends with a switch statement or a computed goto.
Otherwise return false. */
static bool
bb_ends_with_multiway_branch (basic_block bb ATTRIBUTE_UNUSED)
{
gimple stmt = last_stmt (bb);
if (stmt && gimple_code (stmt) == GIMPLE_SWITCH)
return true;
if (stmt && gimple_code (stmt) == GIMPLE_GOTO
&& TREE_CODE (gimple_goto_dest (stmt)) == SSA_NAME)
return true;
return false;
}
/* Walk through all blocks and thread incoming edges to the appropriate
outgoing edge for each edge pair recorded in THREADED_EDGES.
It is the caller's responsibility to fix the dominance information
and rewrite duplicated SSA_NAMEs back into SSA form.
If MAY_PEEL_LOOP_HEADERS is false, we avoid threading edges through
loop headers if it does not simplify the loop.
Returns true if one or more edges were threaded, false otherwise. */
bool
thread_through_all_blocks (bool may_peel_loop_headers)
{
bool retval = false;
unsigned int i;
bitmap_iterator bi;
bitmap threaded_blocks;
struct loop *loop;
if (!paths.exists ())
return false;
threaded_blocks = BITMAP_ALLOC (NULL);
memset (&thread_stats, 0, sizeof (thread_stats));
mark_threaded_blocks (threaded_blocks);
initialize_original_copy_tables ();
/* First perform the threading requests that do not affect
loop structure. */
EXECUTE_IF_SET_IN_BITMAP (threaded_blocks, 0, i, bi)
{
basic_block bb = BASIC_BLOCK_FOR_FN (cfun, i);
if (EDGE_COUNT (bb->preds) > 0)
retval |= thread_block (bb, true);
}
/* Then perform the threading through loop headers. We start with the
innermost loop, so that the changes in cfg we perform won't affect
further threading. */
FOR_EACH_LOOP (loop, LI_FROM_INNERMOST)
{
if (!loop->header
|| !bitmap_bit_p (threaded_blocks, loop->header->index))
continue;
retval |= thread_through_loop_header (loop, may_peel_loop_headers);
}
/* Any jump threading paths that are still attached to edges at this
point must be one of two cases.
First, we could have a jump threading path which went from outside
a loop to inside a loop that was ignored because a prior jump thread
across a backedge was realized (which indirectly causes the loop
above to ignore the latter thread). We can detect these because the
loop structures will be different and we do not currently try to
optimize this case.
Second, we could be threading across a backedge to a point within the
same loop. This occurrs for the FSA/FSM optimization and we would
like to optimize it. However, we have to be very careful as this
may completely scramble the loop structures, with the result being
irreducible loops causing us to throw away our loop structure.
As a compromise for the latter case, if the thread path ends in
a block where the last statement is a multiway branch, then go
ahead and thread it, else ignore it. */
basic_block bb;
edge e;
FOR_EACH_BB_FN (bb, cfun)
{
/* If we do end up threading here, we can remove elements from
BB->preds. Thus we can not use the FOR_EACH_EDGE iterator. */
for (edge_iterator ei = ei_start (bb->preds);
(e = ei_safe_edge (ei));)
if (e->aux)
{
vec *path = THREAD_PATH (e);
/* Case 1, threading from outside to inside the loop
after we'd already threaded through the header. */
if ((*path)[0]->e->dest->loop_father
!= path->last ()->e->src->loop_father)
{
delete_jump_thread_path (path);
e->aux = NULL;
ei_next (&ei);
}
else if (bb_ends_with_multiway_branch (path->last ()->e->src))
{
/* The code to thread through loop headers may have
split a block with jump threads attached to it.
We can identify this with a disjoint jump threading
path. If found, just remove it. */
for (unsigned int i = 0; i < path->length () - 1; i++)
if ((*path)[i]->e->dest != (*path)[i + 1]->e->src)
{
delete_jump_thread_path (path);
e->aux = NULL;
ei_next (&ei);
break;
}
/* Our path is still valid, thread it. */
if (e->aux)
{
struct loop *loop = (*path)[0]->e->dest->loop_father;
if (thread_block ((*path)[0]->e->dest, false))
{
/* This jump thread likely totally scrambled this loop.
So arrange for it to be fixed up. */
loop->header = NULL;
loop->latch = NULL;
e->aux = NULL;
}
else
{
delete_jump_thread_path (path);
e->aux = NULL;
ei_next (&ei);
}
}
}
else
{
delete_jump_thread_path (path);
e->aux = NULL;
ei_next (&ei);
}
}
else
ei_next (&ei);
}
statistics_counter_event (cfun, "Jumps threaded",
thread_stats.num_threaded_edges);
free_original_copy_tables ();
BITMAP_FREE (threaded_blocks);
threaded_blocks = NULL;
paths.release ();
if (retval)
loops_state_set (LOOPS_NEED_FIXUP);
return retval;
}
/* Delete the jump threading path PATH. We have to explcitly delete
each entry in the vector, then the container. */
void
delete_jump_thread_path (vec *path)
{
for (unsigned int i = 0; i < path->length (); i++)
delete (*path)[i];
path->release();
}
/* Register a jump threading opportunity. We queue up all the jump
threading opportunities discovered by a pass and update the CFG
and SSA form all at once.
E is the edge we can thread, E2 is the new target edge, i.e., we
are effectively recording that E->dest can be changed to E2->dest
after fixing the SSA graph. */
void
register_jump_thread (vec *path)
{
if (!dbg_cnt (registered_jump_thread))
{
delete_jump_thread_path (path);
return;
}
/* First make sure there are no NULL outgoing edges on the jump threading
path. That can happen for jumping to a constant address. */
for (unsigned int i = 0; i < path->length (); i++)
if ((*path)[i]->e == NULL)
{
if (dump_file && (dump_flags & TDF_DETAILS))
{
fprintf (dump_file,
"Found NULL edge in jump threading path. Cancelling jump thread:\n");
dump_jump_thread_path (dump_file, *path, false);
}
delete_jump_thread_path (path);
return;
}
if (dump_file && (dump_flags & TDF_DETAILS))
dump_jump_thread_path (dump_file, *path, true);
if (!paths.exists ())
paths.create (5);
paths.safe_push (path);
}