/* LTO partitioning logic routines.
Copyright (C) 2009-2020 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 "target.h"
#include "function.h"
#include "basic-block.h"
#include "tree.h"
#include "gimple.h"
#include "alloc-pool.h"
#include "stringpool.h"
#include "cgraph.h"
#include "lto-streamer.h"
#include "symbol-summary.h"
#include "tree-vrp.h"
#include "ipa-prop.h"
#include "ipa-fnsummary.h"
#include "lto-partition.h"
#include "sreal.h"
vec ltrans_partitions;
static void add_symbol_to_partition (ltrans_partition part, symtab_node *node);
/* Helper for qsort; compare partitions and return one with smaller order. */
static int
cmp_partitions_order (const void *a, const void *b)
{
const struct ltrans_partition_def *pa
= *(struct ltrans_partition_def *const *)a;
const struct ltrans_partition_def *pb
= *(struct ltrans_partition_def *const *)b;
int ordera = -1, orderb = -1;
if (lto_symtab_encoder_size (pa->encoder))
ordera = lto_symtab_encoder_deref (pa->encoder, 0)->order;
if (lto_symtab_encoder_size (pb->encoder))
orderb = lto_symtab_encoder_deref (pb->encoder, 0)->order;
return orderb - ordera;
}
/* Create new partition with name NAME. */
static ltrans_partition
new_partition (const char *name)
{
ltrans_partition part = XCNEW (struct ltrans_partition_def);
part->encoder = lto_symtab_encoder_new (false);
part->name = name;
part->insns = 0;
part->symbols = 0;
ltrans_partitions.safe_push (part);
return part;
}
/* Free memory used by ltrans datastructures. */
void
free_ltrans_partitions (void)
{
unsigned int idx;
ltrans_partition part;
for (idx = 0; ltrans_partitions.iterate (idx, &part); idx++)
{
if (part->initializers_visited)
delete part->initializers_visited;
/* Symtab encoder is freed after streaming. */
free (part);
}
ltrans_partitions.release ();
}
/* Return true if symbol is already in some partition. */
static inline bool
symbol_partitioned_p (symtab_node *node)
{
return node->aux;
}
/* Add references into the partition. */
static void
add_references_to_partition (ltrans_partition part, symtab_node *node)
{
int i;
struct ipa_ref *ref = NULL;
/* Add all duplicated references to the partition. */
for (i = 0; node->iterate_reference (i, ref); i++)
if (ref->referred->get_partitioning_class () == SYMBOL_DUPLICATE)
add_symbol_to_partition (part, ref->referred);
/* References to a readonly variable may be constant foled into its value.
Recursively look into the initializers of the constant variable and add
references, too. */
else if (is_a (ref->referred)
&& (dyn_cast (ref->referred)
->ctor_useable_for_folding_p ())
&& !lto_symtab_encoder_in_partition_p (part->encoder, ref->referred))
{
if (!part->initializers_visited)
part->initializers_visited = new hash_set;
if (!part->initializers_visited->add (ref->referred))
add_references_to_partition (part, ref->referred);
}
}
/* Helper function for add_symbol_to_partition doing the actual dirty work
of adding NODE to PART. */
static bool
add_symbol_to_partition_1 (ltrans_partition part, symtab_node *node)
{
enum symbol_partitioning_class c = node->get_partitioning_class ();
struct ipa_ref *ref;
symtab_node *node1;
/* If NODE is already there, we have nothing to do. */
if (lto_symtab_encoder_in_partition_p (part->encoder, node))
return true;
/* non-duplicated aliases or tunks of a duplicated symbol needs to be output
just once.
Be lax about comdats; they may or may not be duplicated and we may
end up in need to duplicate keyed comdat because it has unkeyed alias. */
if (c == SYMBOL_PARTITION && !DECL_COMDAT (node->decl)
&& symbol_partitioned_p (node))
return false;
/* Be sure that we never try to duplicate partitioned symbol
or add external symbol. */
gcc_assert (c != SYMBOL_EXTERNAL
&& (c == SYMBOL_DUPLICATE || !symbol_partitioned_p (node)));
part->symbols++;
lto_set_symtab_encoder_in_partition (part->encoder, node);
if (symbol_partitioned_p (node))
{
node->in_other_partition = 1;
if (dump_file)
fprintf (dump_file,
"Symbol node %s now used in multiple partitions\n",
node->dump_name ());
}
node->aux = (void *)((size_t)node->aux + 1);
if (cgraph_node *cnode = dyn_cast (node))
{
struct cgraph_edge *e;
if (!node->alias && c == SYMBOL_PARTITION)
part->insns += ipa_size_summaries->get (cnode)->size;
/* Add all inline clones and callees that are duplicated. */
for (e = cnode->callees; e; e = e->next_callee)
if (!e->inline_failed)
add_symbol_to_partition_1 (part, e->callee);
else if (e->callee->get_partitioning_class () == SYMBOL_DUPLICATE)
add_symbol_to_partition (part, e->callee);
/* Add all thunks associated with the function. */
for (e = cnode->callers; e; e = e->next_caller)
if (e->caller->thunk.thunk_p && !e->caller->inlined_to)
add_symbol_to_partition_1 (part, e->caller);
}
add_references_to_partition (part, node);
/* Add all aliases associated with the symbol. */
FOR_EACH_ALIAS (node, ref)
if (!ref->referring->transparent_alias)
add_symbol_to_partition_1 (part, ref->referring);
else
{
struct ipa_ref *ref2;
/* We do not need to add transparent aliases if they are not used.
However we must add aliases of transparent aliases if they exist. */
FOR_EACH_ALIAS (ref->referring, ref2)
{
/* Nested transparent aliases are not permitted. */
gcc_checking_assert (!ref2->referring->transparent_alias);
add_symbol_to_partition_1 (part, ref2->referring);
}
}
/* Ensure that SAME_COMDAT_GROUP lists all allways added in a group. */
if (node->same_comdat_group)
for (node1 = node->same_comdat_group;
node1 != node; node1 = node1->same_comdat_group)
if (!node->alias)
{
bool added = add_symbol_to_partition_1 (part, node1);
gcc_assert (added);
}
return true;
}
/* If symbol NODE is really part of other symbol's definition (i.e. it is
internal label, thunk, alias or so), return the outer symbol.
When add_symbol_to_partition_1 is called on the outer symbol it must
eventually add NODE, too. */
static symtab_node *
contained_in_symbol (symtab_node *node)
{
/* There is no need to consider transparent aliases to be part of the
definition: they are only useful insite the partition they are output
and thus we will always see an explicit reference to it. */
if (node->transparent_alias)
return node;
if (cgraph_node *cnode = dyn_cast (node))
{
cnode = cnode->function_symbol ();
if (cnode->inlined_to)
cnode = cnode->inlined_to;
return cnode;
}
else if (varpool_node *vnode = dyn_cast (node))
return vnode->ultimate_alias_target ();
return node;
}
/* Add symbol NODE to partition. When definition of NODE is part
of other symbol definition, add the other symbol, too. */
static void
add_symbol_to_partition (ltrans_partition part, symtab_node *node)
{
symtab_node *node1;
/* Verify that we do not try to duplicate something that cannot be. */
gcc_checking_assert (node->get_partitioning_class () == SYMBOL_DUPLICATE
|| !symbol_partitioned_p (node));
while ((node1 = contained_in_symbol (node)) != node)
node = node1;
/* If we have duplicated symbol contained in something we cannot duplicate,
we are very badly screwed. The other way is possible, so we do not
assert this in add_symbol_to_partition_1.
Be lax about comdats; they may or may not be duplicated and we may
end up in need to duplicate keyed comdat because it has unkeyed alias. */
gcc_assert (node->get_partitioning_class () == SYMBOL_DUPLICATE
|| DECL_COMDAT (node->decl)
|| !symbol_partitioned_p (node));
add_symbol_to_partition_1 (part, node);
}
/* Undo all additions until number of cgraph nodes in PARITION is N_CGRAPH_NODES
and number of varpool nodes is N_VARPOOL_NODES. */
static void
undo_partition (ltrans_partition partition, unsigned int n_nodes)
{
while (lto_symtab_encoder_size (partition->encoder) > (int)n_nodes)
{
symtab_node *node = lto_symtab_encoder_deref (partition->encoder,
n_nodes);
partition->symbols--;
cgraph_node *cnode;
/* After UNDO we no longer know what was visited. */
if (partition->initializers_visited)
delete partition->initializers_visited;
partition->initializers_visited = NULL;
if (!node->alias && (cnode = dyn_cast (node))
&& node->get_partitioning_class () == SYMBOL_PARTITION)
partition->insns -= ipa_size_summaries->get (cnode)->size;
lto_symtab_encoder_delete_node (partition->encoder, node);
node->aux = (void *)((size_t)node->aux - 1);
}
}
/* Group cgrah nodes by input files. This is used mainly for testing
right now. */
void
lto_1_to_1_map (void)
{
symtab_node *node;
struct lto_file_decl_data *file_data;
hash_map pmap;
ltrans_partition partition;
int npartitions = 0;
FOR_EACH_SYMBOL (node)
{
if (node->get_partitioning_class () != SYMBOL_PARTITION
|| symbol_partitioned_p (node))
continue;
file_data = node->lto_file_data;
if (file_data)
{
ltrans_partition *slot = &pmap.get_or_insert (file_data);
if (*slot)
partition = *slot;
else
{
partition = new_partition (file_data->file_name);
*slot = partition;
npartitions++;
}
}
else if (!file_data && ltrans_partitions.length ())
partition = ltrans_partitions[0];
else
{
partition = new_partition ("");
pmap.put (NULL, partition);
npartitions++;
}
add_symbol_to_partition (partition, node);
}
/* If the cgraph is empty, create one cgraph node set so that there is still
an output file for any variables that need to be exported in a DSO. */
if (!npartitions)
new_partition ("empty");
/* Order partitions by order of symbols because they are linked into binary
that way. */
ltrans_partitions.qsort (cmp_partitions_order);
}
/* Maximal partitioning. Put every new symbol into new partition if possible. */
void
lto_max_map (void)
{
symtab_node *node;
ltrans_partition partition;
int npartitions = 0;
FOR_EACH_SYMBOL (node)
{
if (node->get_partitioning_class () != SYMBOL_PARTITION
|| symbol_partitioned_p (node))
continue;
partition = new_partition (node->asm_name ());
add_symbol_to_partition (partition, node);
npartitions++;
}
if (!npartitions)
new_partition ("empty");
}
/* Helper function for qsort; sort nodes by order. */
static int
node_cmp (const void *pa, const void *pb)
{
const symtab_node *a = *static_cast (pa);
const symtab_node *b = *static_cast (pb);
return b->order - a->order;
}
/* Add all symtab nodes from NEXT_NODE to PARTITION in order. */
static void
add_sorted_nodes (vec &next_nodes, ltrans_partition partition)
{
unsigned i;
symtab_node *node;
next_nodes.qsort (node_cmp);
FOR_EACH_VEC_ELT (next_nodes, i, node)
if (!symbol_partitioned_p (node))
add_symbol_to_partition (partition, node);
}
/* Return true if we should account reference from N1 to N2 in cost
of partition boundary. */
bool
account_reference_p (symtab_node *n1, symtab_node *n2)
{
if (cgraph_node *cnode = dyn_cast (n1))
n1 = cnode;
/* Do not account references from aliases - they are never split across
partitions. */
if (n1->alias)
return false;
/* Do not account recursion - the code below will handle it incorrectly
otherwise. Do not account references to external symbols: they will
never become local. Finally do not account references to duplicated
symbols: they will be always local. */
if (n1 == n2
|| !n2->definition
|| n2->get_partitioning_class () != SYMBOL_PARTITION)
return false;
/* If referring node is external symbol do not account it to boundary
cost. Those are added into units only to enable possible constant
folding and devirtulization.
Here we do not know if it will ever be added to some partition
(this is decided by compute_ltrans_boundary) and second it is not
that likely that constant folding will actually use the reference. */
if (contained_in_symbol (n1)
->get_partitioning_class () == SYMBOL_EXTERNAL)
return false;
return true;
}
/* Group cgraph nodes into equally-sized partitions.
The partitioning algorithm is simple: nodes are taken in predefined order.
The order corresponds to the order we want functions to have in the final
output. In the future this will be given by function reordering pass, but
at the moment we use the topological order, which is a good approximation.
The goal is to partition this linear order into intervals (partitions) so
that all the partitions have approximately the same size and the number of
callgraph or IPA reference edges crossing boundaries is minimal.
This is a lot faster (O(n) in size of callgraph) than algorithms doing
priority-based graph clustering that are generally O(n^2) and, since
WHOPR is designed to make things go well across partitions, it leads
to good results.
We compute the expected size of a partition as:
max (total_size / lto_partitions, min_partition_size)
We use dynamic expected size of partition so small programs are partitioned
into enough partitions to allow use of multiple CPUs, while large programs
are not partitioned too much. Creating too many partitions significantly
increases the streaming overhead.
In the future, we would like to bound the maximal size of partitions so as
to prevent the LTRANS stage from consuming too much memory. At the moment,
however, the WPA stage is the most memory intensive for large benchmarks,
since too many types and declarations are read into memory.
The function implements a simple greedy algorithm. Nodes are being added
to the current partition until after 3/4 of the expected partition size is
reached. Past this threshold, we keep track of boundary size (number of
edges going to other partitions) and continue adding functions until after
the current partition has grown to twice the expected partition size. Then
the process is undone to the point where the minimal ratio of boundary size
and in-partition calls was reached. */
void
lto_balanced_map (int n_lto_partitions, int max_partition_size)
{
int n_varpool_nodes = 0, varpool_pos = 0, best_varpool_pos = 0;
int best_noreorder_pos = 0;
auto_vec order (symtab->cgraph_count);
auto_vec noreorder;
auto_vec varpool_order;
struct cgraph_node *node;
int64_t original_total_size, total_size = 0;
int64_t partition_size;
ltrans_partition partition;
int last_visited_node = 0;
varpool_node *vnode;
int64_t cost = 0, internal = 0;
unsigned int best_n_nodes = 0, best_i = 0;
int64_t best_cost = -1, best_internal = 0, best_size = 0;
int npartitions;
int current_order = -1;
int noreorder_pos = 0;
FOR_EACH_VARIABLE (vnode)
gcc_assert (!vnode->aux);
FOR_EACH_DEFINED_FUNCTION (node)
if (node->get_partitioning_class () == SYMBOL_PARTITION)
{
if (node->no_reorder)
noreorder.safe_push (node);
else
order.safe_push (node);
if (!node->alias)
total_size += ipa_size_summaries->get (node)->size;
}
original_total_size = total_size;
/* Streaming works best when the source units do not cross partition
boundaries much. This is because importing function from a source
unit tends to import a lot of global trees defined there. We should
get better about minimizing the function bounday, but until that
things works smoother if we order in source order. */
order.qsort (tp_first_run_node_cmp);
noreorder.qsort (node_cmp);
if (dump_file)
{
for (unsigned i = 0; i < order.length (); i++)
fprintf (dump_file, "Balanced map symbol order:%s:%u\n",
order[i]->dump_name (), order[i]->tp_first_run);
for (unsigned i = 0; i < noreorder.length (); i++)
fprintf (dump_file, "Balanced map symbol no_reorder:%s:%u\n",
noreorder[i]->dump_name (), noreorder[i]->tp_first_run);
}
/* Collect all variables that should not be reordered. */
FOR_EACH_VARIABLE (vnode)
if (vnode->get_partitioning_class () == SYMBOL_PARTITION
&& vnode->no_reorder)
varpool_order.safe_push (vnode);
n_varpool_nodes = varpool_order.length ();
varpool_order.qsort (node_cmp);
/* Compute partition size and create the first partition. */
if (param_min_partition_size > max_partition_size)
fatal_error (input_location, "min partition size cannot be greater "
"than max partition size");
partition_size = total_size / n_lto_partitions;
if (partition_size < param_min_partition_size)
partition_size = param_min_partition_size;
npartitions = 1;
partition = new_partition ("");
if (dump_file)
fprintf (dump_file, "Total unit size: %" PRId64 ", partition size: %" PRId64 "\n",
total_size, partition_size);
auto_vec next_nodes;
for (unsigned i = 0; i < order.length (); i++)
{
if (symbol_partitioned_p (order[i]))
continue;
current_order = order[i]->order;
/* Output noreorder and varpool in program order first. */
next_nodes.truncate (0);
while (varpool_pos < n_varpool_nodes
&& varpool_order[varpool_pos]->order < current_order)
next_nodes.safe_push (varpool_order[varpool_pos++]);
while (noreorder_pos < (int)noreorder.length ()
&& noreorder[noreorder_pos]->order < current_order)
next_nodes.safe_push (noreorder[noreorder_pos++]);
add_sorted_nodes (next_nodes, partition);
if (!symbol_partitioned_p (order[i]))
add_symbol_to_partition (partition, order[i]);
/* Once we added a new node to the partition, we also want to add
all referenced variables unless they was already added into some
earlier partition.
add_symbol_to_partition adds possibly multiple nodes and
variables that are needed to satisfy needs of ORDER[i].
We remember last visited cgraph and varpool node from last iteration
of outer loop that allows us to process every new addition.
At the same time we compute size of the boundary into COST. Every
callgraph or IPA reference edge leaving the partition contributes into
COST. Every edge inside partition was earlier computed as one leaving
it and thus we need to subtract it from COST. */
while (last_visited_node < lto_symtab_encoder_size (partition->encoder))
{
int j;
struct ipa_ref *ref = NULL;
symtab_node *snode = lto_symtab_encoder_deref (partition->encoder,
last_visited_node);
if (cgraph_node *node = dyn_cast (snode))
{
struct cgraph_edge *edge;
last_visited_node++;
gcc_assert (node->definition || node->weakref);
/* Compute boundary cost of callgraph edges. */
for (edge = node->callees; edge; edge = edge->next_callee)
/* Inline edges will always end up local. */
if (edge->inline_failed
&& account_reference_p (node, edge->callee))
{
int edge_cost = edge->frequency ();
int index;
if (!edge_cost)
edge_cost = 1;
gcc_assert (edge_cost > 0);
index = lto_symtab_encoder_lookup (partition->encoder,
edge->callee);
if (index != LCC_NOT_FOUND
&& index < last_visited_node - 1)
cost -= edge_cost, internal += edge_cost;
else
cost += edge_cost;
}
for (edge = node->callers; edge; edge = edge->next_caller)
if (edge->inline_failed
&& account_reference_p (edge->caller, node))
{
int edge_cost = edge->frequency ();
int index;
gcc_assert (edge->caller->definition);
if (!edge_cost)
edge_cost = 1;
gcc_assert (edge_cost > 0);
index = lto_symtab_encoder_lookup (partition->encoder,
edge->caller);
if (index != LCC_NOT_FOUND
&& index < last_visited_node - 1)
cost -= edge_cost, internal += edge_cost;
else
cost += edge_cost;
}
}
else
last_visited_node++;
/* Compute boundary cost of IPA REF edges and at the same time look into
variables referenced from current partition and try to add them. */
for (j = 0; snode->iterate_reference (j, ref); j++)
if (!account_reference_p (snode, ref->referred))
;
else if (is_a (ref->referred))
{
int index;
vnode = dyn_cast (ref->referred);
if (!symbol_partitioned_p (vnode)
&& !vnode->no_reorder
&& vnode->get_partitioning_class () == SYMBOL_PARTITION)
add_symbol_to_partition (partition, vnode);
index = lto_symtab_encoder_lookup (partition->encoder,
vnode);
if (index != LCC_NOT_FOUND
&& index < last_visited_node - 1)
cost--, internal++;
else
cost++;
}
else
{
int index;
node = dyn_cast (ref->referred);
index = lto_symtab_encoder_lookup (partition->encoder,
node);
if (index != LCC_NOT_FOUND
&& index < last_visited_node - 1)
cost--, internal++;
else
cost++;
}
for (j = 0; snode->iterate_referring (j, ref); j++)
if (!account_reference_p (ref->referring, snode))
;
else if (is_a (ref->referring))
{
int index;
vnode = dyn_cast (ref->referring);
gcc_assert (vnode->definition);
/* It is better to couple variables with their users,
because it allows them to be removed. Coupling
with objects they refer to only helps to reduce
number of symbols promoted to hidden. */
if (!symbol_partitioned_p (vnode)
&& !vnode->no_reorder
&& !vnode->can_remove_if_no_refs_p ()
&& vnode->get_partitioning_class () == SYMBOL_PARTITION)
add_symbol_to_partition (partition, vnode);
index = lto_symtab_encoder_lookup (partition->encoder,
vnode);
if (index != LCC_NOT_FOUND
&& index < last_visited_node - 1)
cost--, internal++;
else
cost++;
}
else
{
int index;
node = dyn_cast (ref->referring);
gcc_assert (node->definition);
index = lto_symtab_encoder_lookup (partition->encoder,
node);
if (index != LCC_NOT_FOUND
&& index < last_visited_node - 1)
cost--, internal++;
else
cost++;
}
}
gcc_assert (cost >= 0 && internal >= 0);
/* If the partition is large enough, start looking for smallest boundary cost.
If partition still seems too small (less than 7/8 of target weight) accept
any cost. If partition has right size, optimize for highest internal/cost.
Later we stop building partition if its size is 9/8 of the target wight. */
if (partition->insns < partition_size * 7 / 8
|| best_cost == -1
|| (!cost
|| ((sreal)best_internal * (sreal) cost
< ((sreal) internal * (sreal)best_cost))))
{
best_cost = cost;
best_internal = internal;
best_size = partition->insns;
best_i = i;
best_n_nodes = lto_symtab_encoder_size (partition->encoder);
best_varpool_pos = varpool_pos;
best_noreorder_pos = noreorder_pos;
}
if (dump_file)
fprintf (dump_file, "Step %i: added %s, size %i, "
"cost %" PRId64 "/%" PRId64 " "
"best %" PRId64 "/%" PRId64", step %i\n", i,
order[i]->dump_name (),
partition->insns, cost, internal,
best_cost, best_internal, best_i);
/* Partition is too large, unwind into step when best cost was reached and
start new partition. */
if (partition->insns > 9 * partition_size / 8
|| partition->insns > max_partition_size)
{
if (best_i != i)
{
if (dump_file)
fprintf (dump_file, "Unwinding %i insertions to step %i\n",
i - best_i, best_i);
undo_partition (partition, best_n_nodes);
varpool_pos = best_varpool_pos;
noreorder_pos = best_noreorder_pos;
}
gcc_assert (best_size == partition->insns);
i = best_i;
if (dump_file)
fprintf (dump_file,
"Partition insns: %i (want %" PRId64 ")\n",
partition->insns, partition_size);
/* When we are finished, avoid creating empty partition. */
while (i < order.length () - 1 && symbol_partitioned_p (order[i + 1]))
i++;
if (i == order.length () - 1)
break;
total_size -= partition->insns;
partition = new_partition ("");
last_visited_node = 0;
cost = 0;
if (dump_file)
fprintf (dump_file, "New partition\n");
best_n_nodes = 0;
best_cost = -1;
/* Since the size of partitions is just approximate, update the size after
we finished current one. */
if (npartitions < n_lto_partitions)
partition_size = total_size / (n_lto_partitions - npartitions);
else
/* Watch for overflow. */
partition_size = INT_MAX / 16;
if (dump_file)
fprintf (dump_file,
"Total size: %" PRId64 " partition_size: %" PRId64 "\n",
total_size, partition_size);
if (partition_size < param_min_partition_size)
partition_size = param_min_partition_size;
npartitions ++;
}
}
next_nodes.truncate (0);
/* Varables that are not reachable from the code go into last partition. */
FOR_EACH_VARIABLE (vnode)
if (vnode->get_partitioning_class () == SYMBOL_PARTITION
&& !symbol_partitioned_p (vnode))
next_nodes.safe_push (vnode);
/* Output remaining ordered symbols. */
while (varpool_pos < n_varpool_nodes)
next_nodes.safe_push (varpool_order[varpool_pos++]);
while (noreorder_pos < (int)noreorder.length ())
next_nodes.safe_push (noreorder[noreorder_pos++]);
/* For one partition the cost of boundary should be 0 unless we added final
symbols here (these are not accounted) or we have accounting bug. */
gcc_assert (next_nodes.length () || npartitions != 1 || !best_cost || best_cost == -1);
add_sorted_nodes (next_nodes, partition);
if (dump_file)
{
fprintf (dump_file, "\nPartition sizes:\n");
unsigned partitions = ltrans_partitions.length ();
for (unsigned i = 0; i < partitions ; i++)
{
ltrans_partition p = ltrans_partitions[i];
fprintf (dump_file, "partition %d contains %d (%2.2f%%)"
" symbols and %d (%2.2f%%) insns\n", i, p->symbols,
100.0 * p->symbols / order.length (), p->insns,
100.0 * p->insns / original_total_size);
}
fprintf (dump_file, "\n");
}
}
/* Return true if we must not change the name of the NODE. The name as
extracted from the corresponding decl should be passed in NAME. */
static bool
must_not_rename (symtab_node *node, const char *name)
{
/* Our renaming machinery do not handle more than one change of assembler name.
We should not need more than one anyway. */
if (node->lto_file_data
&& lto_get_decl_name_mapping (node->lto_file_data, name) != name)
{
if (dump_file)
fprintf (dump_file,
"Not privatizing symbol name: %s. It privatized already.\n",
name);
return true;
}
/* Avoid mangling of already mangled clones.
??? should have a flag whether a symbol has a 'private' name already,
since we produce some symbols like that i.e. for global constructors
that are not really clones. */
if (node->unique_name)
{
if (dump_file)
fprintf (dump_file,
"Not privatizing symbol name: %s. Has unique name.\n",
name);
return true;
}
return false;
}
/* If we are an offload compiler, we may have to rewrite symbols to be
valid on this target. Return either PTR or a modified version of it. */
static const char *
maybe_rewrite_identifier (const char *ptr)
{
#if defined ACCEL_COMPILER && (defined NO_DOT_IN_LABEL || defined NO_DOLLAR_IN_LABEL)
#ifndef NO_DOT_IN_LABEL
char valid = '.';
const char reject[] = "$";
#elif !defined NO_DOLLAR_IN_LABEL
char valid = '$';
const char reject[] = ".";
#else
char valid = '_';
const char reject[] = ".$";
#endif
char *copy = NULL;
const char *match = ptr;
for (;;)
{
size_t off = strcspn (match, reject);
if (match[off] == '\0')
break;
if (copy == NULL)
{
copy = xstrdup (ptr);
match = copy;
}
copy[off] = valid;
}
return match;
#else
return ptr;
#endif
}
/* Ensure that the symbol in NODE is valid for the target, and if not,
rewrite it. */
static void
validize_symbol_for_target (symtab_node *node)
{
tree decl = node->decl;
const char *name = IDENTIFIER_POINTER (DECL_ASSEMBLER_NAME (decl));
if (must_not_rename (node, name))
return;
const char *name2 = maybe_rewrite_identifier (name);
if (name2 != name)
{
symtab->change_decl_assembler_name (decl, get_identifier (name2));
if (node->lto_file_data)
lto_record_renamed_decl (node->lto_file_data, name,
IDENTIFIER_POINTER
(DECL_ASSEMBLER_NAME (decl)));
}
}
/* Maps symbol names to unique lto clone counters. */
static hash_map *lto_clone_numbers;
/* Helper for privatize_symbol_name. Mangle NODE symbol name
represented by DECL. */
static bool
privatize_symbol_name_1 (symtab_node *node, tree decl)
{
const char *name = IDENTIFIER_POINTER (DECL_ASSEMBLER_NAME (decl));
if (must_not_rename (node, name))
return false;
name = maybe_rewrite_identifier (name);
unsigned &clone_number = lto_clone_numbers->get_or_insert (name);
symtab->change_decl_assembler_name (decl,
clone_function_name (
name, "lto_priv", clone_number));
clone_number++;
if (node->lto_file_data)
lto_record_renamed_decl (node->lto_file_data, name,
IDENTIFIER_POINTER
(DECL_ASSEMBLER_NAME (decl)));
if (dump_file)
fprintf (dump_file,
"Privatizing symbol name: %s -> %s\n",
name, IDENTIFIER_POINTER (DECL_ASSEMBLER_NAME (decl)));
return true;
}
/* Mangle NODE symbol name into a local name.
This is necessary to do
1) if two or more static vars of same assembler name
are merged into single ltrans unit.
2) if previously static var was promoted hidden to avoid possible conflict
with symbols defined out of the LTO world. */
static bool
privatize_symbol_name (symtab_node *node)
{
if (!privatize_symbol_name_1 (node, node->decl))
return false;
return true;
}
/* Promote variable VNODE to be static. */
static void
promote_symbol (symtab_node *node)
{
/* We already promoted ... */
if (DECL_VISIBILITY (node->decl) == VISIBILITY_HIDDEN
&& DECL_VISIBILITY_SPECIFIED (node->decl)
&& TREE_PUBLIC (node->decl))
{
validize_symbol_for_target (node);
return;
}
gcc_checking_assert (!TREE_PUBLIC (node->decl)
&& !DECL_EXTERNAL (node->decl));
/* Be sure that newly public symbol does not conflict with anything already
defined by the non-LTO part. */
privatize_symbol_name (node);
TREE_PUBLIC (node->decl) = 1;
DECL_VISIBILITY (node->decl) = VISIBILITY_HIDDEN;
DECL_VISIBILITY_SPECIFIED (node->decl) = true;
if (dump_file)
fprintf (dump_file,
"Promoting as hidden: %s (%s)\n", node->dump_name (),
IDENTIFIER_POINTER (DECL_ASSEMBLER_NAME (node->decl)));
/* Promoting a symbol also promotes all transparent aliases with exception
of weakref where the visibility flags are always wrong and set to
!PUBLIC. */
ipa_ref *ref;
for (unsigned i = 0; node->iterate_direct_aliases (i, ref); i++)
{
struct symtab_node *alias = ref->referring;
if (alias->transparent_alias && !alias->weakref)
{
TREE_PUBLIC (alias->decl) = 1;
DECL_VISIBILITY (alias->decl) = VISIBILITY_HIDDEN;
DECL_VISIBILITY_SPECIFIED (alias->decl) = true;
if (dump_file)
fprintf (dump_file,
"Promoting alias as hidden: %s\n",
IDENTIFIER_POINTER (DECL_ASSEMBLER_NAME (node->decl)));
}
gcc_assert (!alias->weakref || TREE_PUBLIC (alias->decl));
}
}
/* Return true if NODE needs named section even if it won't land in
the partition symbol table.
FIXME: we should really not use named sections for inline clones
and master clones. */
static bool
may_need_named_section_p (lto_symtab_encoder_t encoder, symtab_node *node)
{
struct cgraph_node *cnode = dyn_cast (node);
if (!cnode)
return false;
if (node->real_symbol_p ())
return false;
return (!encoder
|| (lto_symtab_encoder_lookup (encoder, node) != LCC_NOT_FOUND
&& lto_symtab_encoder_encode_body_p (encoder,
cnode)));
}
/* If NODE represents a static variable. See if there are other variables
of the same name in partition ENCODER (or in whole compilation unit if
ENCODER is NULL) and if so, mangle the statics. Always mangle all
conflicting statics, so we reduce changes of silently miscompiling
asm statements referring to them by symbol name. */
static void
rename_statics (lto_symtab_encoder_t encoder, symtab_node *node)
{
tree decl = node->decl;
symtab_node *s;
tree name = DECL_ASSEMBLER_NAME (decl);
/* See if this is static symbol. */
if (((node->externally_visible && !node->weakref)
/* FIXME: externally_visible is somewhat illogically not set for
external symbols (i.e. those not defined). Remove this test
once this is fixed. */
|| DECL_EXTERNAL (node->decl)
|| !node->real_symbol_p ())
&& !may_need_named_section_p (encoder, node))
return;
/* Now walk symbols sharing the same name and see if there are any conflicts.
(all types of symbols counts here, since we cannot have static of the
same name as external or public symbol.) */
for (s = symtab_node::get_for_asmname (name);
s; s = s->next_sharing_asm_name)
if ((s->real_symbol_p () || may_need_named_section_p (encoder, s))
&& s->decl != node->decl
&& (!encoder
|| lto_symtab_encoder_lookup (encoder, s) != LCC_NOT_FOUND))
break;
/* OK, no confict, so we have nothing to do. */
if (!s)
return;
if (dump_file)
fprintf (dump_file,
"Renaming statics with asm name: %s\n", node->dump_name ());
/* Assign every symbol in the set that shares the same ASM name an unique
mangled name. */
for (s = symtab_node::get_for_asmname (name); s;)
if ((!s->externally_visible || s->weakref)
/* Transparent aliases having same name as target are renamed at a
time their target gets new name. Transparent aliases that use
separate assembler name require the name to be unique. */
&& (!s->transparent_alias || !s->definition || s->weakref
|| !symbol_table::assembler_names_equal_p
(IDENTIFIER_POINTER (DECL_ASSEMBLER_NAME (s->decl)),
IDENTIFIER_POINTER
(DECL_ASSEMBLER_NAME (s->get_alias_target()->decl))))
&& ((s->real_symbol_p ()
&& !DECL_EXTERNAL (s->decl)
&& !TREE_PUBLIC (s->decl))
|| may_need_named_section_p (encoder, s))
&& (!encoder
|| lto_symtab_encoder_lookup (encoder, s) != LCC_NOT_FOUND))
{
if (privatize_symbol_name (s))
/* Re-start from beginning since we do not know how many
symbols changed a name. */
s = symtab_node::get_for_asmname (name);
else s = s->next_sharing_asm_name;
}
else s = s->next_sharing_asm_name;
}
/* Find out all static decls that need to be promoted to global because
of cross file sharing. This function must be run in the WPA mode after
all inlinees are added. */
void
lto_promote_cross_file_statics (void)
{
unsigned i, n_sets;
gcc_assert (flag_wpa);
lto_stream_offload_p = false;
select_what_to_stream ();
/* First compute boundaries. */
n_sets = ltrans_partitions.length ();
for (i = 0; i < n_sets; i++)
{
ltrans_partition part
= ltrans_partitions[i];
part->encoder = compute_ltrans_boundary (part->encoder);
}
lto_clone_numbers = new hash_map;
/* Look at boundaries and promote symbols as needed. */
for (i = 0; i < n_sets; i++)
{
lto_symtab_encoder_iterator lsei;
lto_symtab_encoder_t encoder = ltrans_partitions[i]->encoder;
for (lsei = lsei_start (encoder); !lsei_end_p (lsei);
lsei_next (&lsei))
{
symtab_node *node = lsei_node (lsei);
/* If symbol is static, rename it if its assembler name
clashes with anything else in this unit. */
rename_statics (encoder, node);
/* No need to promote if symbol already is externally visible ... */
if (node->externally_visible
/* ... or if it is part of current partition ... */
|| lto_symtab_encoder_in_partition_p (encoder, node)
/* ... or if we do not partition it. This mean that it will
appear in every partition referencing it. */
|| node->get_partitioning_class () != SYMBOL_PARTITION)
{
validize_symbol_for_target (node);
continue;
}
promote_symbol (node);
}
}
delete lto_clone_numbers;
}
/* Rename statics in the whole unit in the case that
we do -flto-partition=none. */
void
lto_promote_statics_nonwpa (void)
{
symtab_node *node;
lto_clone_numbers = new hash_map;
FOR_EACH_SYMBOL (node)
{
rename_statics (NULL, node);
validize_symbol_for_target (node);
}
delete lto_clone_numbers;
}