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8sa1-gcc/gcc/analyzer/engine.cc
David Malcolm e4bb1bd60a analyzer: avoid printing '<unknown>' for SSA names [PR99771] 
We don't want to print '<unknown>' in our diagnostics, but
PR analyzer/99771 lists various cases where -fanalyzer does, due to
using the SSA_NAME for a temporary when determining the best tree to
use.

This can happen in two ways:

(a) ...when a better expression than the SSA_NAME could be built, but
finding it requires traversing the relationships in the region_model
in a graph-like way, rather than by considering individual svalues and
regions.

(b) ...when the only remaining user of the underlying svalue is the
SSA_NAME, typically due to the diagnostic referring to a temporary.

I've been experimenting with fixing (a), but don't have a good fix yet.
In the meantime, this patch addresses (b) by detecting if we have
the SSA_NAME for a temporary, and, for the cases where it's possible,
reconstructing a tree by walking the def-stmts.  This fixes various
cases of (b) and ameliorates some cases of (a).

gcc/analyzer/ChangeLog:
	PR analyzer/99771
	* analyzer.cc (maybe_reconstruct_from_def_stmt): New.
	(fixup_tree_for_diagnostic_1): New.
	(fixup_tree_for_diagnostic): New.
	* analyzer.h (fixup_tree_for_diagnostic): New decl.
	* checker-path.cc (call_event::get_desc): Call
	fixup_tree_for_diagnostic and use it for the call_with_state call.
	(warning_event::get_desc): Likewise for the final_event and
	make_label_text calls.
	* engine.cc (impl_region_model_context::on_state_leak): Likewise
	for the on_leak and add_diagnostic calls.
	* region-model.cc (region_model::get_representative_tree):
	Likewise for the result.

gcc/testsuite/ChangeLog:
	PR analyzer/99771
	* gcc.dg/analyzer/data-model-10.c: Update expected output.
	* gcc.dg/analyzer/malloc-ipa-13.c: Likewise.
	* gcc.dg/analyzer/malloc-ipa-13a.c: New test.
	* gcc.dg/analyzer/pr99771-1.c: New test.
2021-03-31 19:16:48 -04:00

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/* The analysis "engine".
Copyright (C) 2019-2021 Free Software Foundation, Inc.
Contributed by David Malcolm <dmalcolm@redhat.com>.
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
<http://www.gnu.org/licenses/>. */
#include "config.h"
#include "system.h"
#include "coretypes.h"
#include "tree.h"
#include "fold-const.h"
#include "gcc-rich-location.h"
#include "alloc-pool.h"
#include "fibonacci_heap.h"
#include "shortest-paths.h"
#include "diagnostic-core.h"
#include "diagnostic-event-id.h"
#include "diagnostic-path.h"
#include "function.h"
#include "pretty-print.h"
#include "sbitmap.h"
#include "bitmap.h"
#include "tristate.h"
#include "ordered-hash-map.h"
#include "selftest.h"
#include "json.h"
#include "analyzer/analyzer.h"
#include "analyzer/analyzer-logging.h"
#include "analyzer/call-string.h"
#include "analyzer/program-point.h"
#include "analyzer/store.h"
#include "analyzer/region-model.h"
#include "analyzer/constraint-manager.h"
#include "analyzer/sm.h"
#include "analyzer/pending-diagnostic.h"
#include "analyzer/diagnostic-manager.h"
#include "cfg.h"
#include "basic-block.h"
#include "gimple.h"
#include "gimple-iterator.h"
#include "gimple-pretty-print.h"
#include "cgraph.h"
#include "digraph.h"
#include "analyzer/supergraph.h"
#include "analyzer/program-state.h"
#include "analyzer/exploded-graph.h"
#include "analyzer/analysis-plan.h"
#include "analyzer/checker-path.h"
#include "analyzer/state-purge.h"
#include "analyzer/bar-chart.h"
#include <zlib.h>
#include "plugin.h"
/* For an overview, see gcc/doc/analyzer.texi. */
#if ENABLE_ANALYZER
namespace ana {
/* class impl_region_model_context : public region_model_context. */
impl_region_model_context::
impl_region_model_context (exploded_graph &eg,
const exploded_node *enode_for_diag,
const program_state *old_state,
program_state *new_state,
const gimple *stmt,
stmt_finder *stmt_finder)
: m_eg (&eg), m_logger (eg.get_logger ()),
m_enode_for_diag (enode_for_diag),
m_old_state (old_state),
m_new_state (new_state),
m_stmt (stmt),
m_stmt_finder (stmt_finder),
m_ext_state (eg.get_ext_state ())
{
}
impl_region_model_context::
impl_region_model_context (program_state *state,
const extrinsic_state &ext_state,
logger *logger)
: m_eg (NULL), m_logger (logger), m_enode_for_diag (NULL),
m_old_state (NULL),
m_new_state (state),
m_stmt (NULL),
m_stmt_finder (NULL),
m_ext_state (ext_state)
{
}
void
impl_region_model_context::warn (pending_diagnostic *d)
{
LOG_FUNC (get_logger ());
if (m_eg)
m_eg->get_diagnostic_manager ().add_diagnostic
(m_enode_for_diag, m_enode_for_diag->get_supernode (),
m_stmt, m_stmt_finder, d);
}
void
impl_region_model_context::on_svalue_leak (const svalue *sval)
{
int sm_idx;
sm_state_map *smap;
FOR_EACH_VEC_ELT (m_new_state->m_checker_states, sm_idx, smap)
smap->on_svalue_leak (sval, this);
}
void
impl_region_model_context::
on_liveness_change (const svalue_set &live_svalues,
const region_model *model)
{
int sm_idx;
sm_state_map *smap;
FOR_EACH_VEC_ELT (m_new_state->m_checker_states, sm_idx, smap)
smap->on_liveness_change (live_svalues, model, this);
}
void
impl_region_model_context::on_unknown_change (const svalue *sval,
bool is_mutable)
{
int sm_idx;
sm_state_map *smap;
FOR_EACH_VEC_ELT (m_new_state->m_checker_states, sm_idx, smap)
smap->on_unknown_change (sval, is_mutable, m_ext_state);
}
void
impl_region_model_context::on_escaped_function (tree fndecl)
{
m_eg->on_escaped_function (fndecl);
}
/* struct setjmp_record. */
int
setjmp_record::cmp (const setjmp_record &rec1, const setjmp_record &rec2)
{
if (int cmp_enode = rec1.m_enode->m_index - rec2.m_enode->m_index)
return cmp_enode;
gcc_assert (&rec1 == &rec2);
return 0;
}
/* class setjmp_svalue : public svalue. */
/* Implementation of svalue::accept vfunc for setjmp_svalue. */
void
setjmp_svalue::accept (visitor *v) const
{
v->visit_setjmp_svalue (this);
}
/* Implementation of svalue::dump_to_pp vfunc for setjmp_svalue. */
void
setjmp_svalue::dump_to_pp (pretty_printer *pp, bool simple) const
{
if (simple)
pp_printf (pp, "SETJMP(EN: %i)", get_enode_index ());
else
pp_printf (pp, "setjmp_svalue(EN%i)", get_enode_index ());
}
/* Get the index of the stored exploded_node. */
int
setjmp_svalue::get_enode_index () const
{
return m_setjmp_record.m_enode->m_index;
}
/* Concrete implementation of sm_context, wiring it up to the rest of this
file. */
class impl_sm_context : public sm_context
{
public:
impl_sm_context (exploded_graph &eg,
int sm_idx,
const state_machine &sm,
const exploded_node *enode_for_diag,
const program_state *old_state,
program_state *new_state,
const sm_state_map *old_smap,
sm_state_map *new_smap,
stmt_finder *stmt_finder = NULL)
: sm_context (sm_idx, sm),
m_logger (eg.get_logger ()),
m_eg (eg), m_enode_for_diag (enode_for_diag),
m_old_state (old_state), m_new_state (new_state),
m_old_smap (old_smap), m_new_smap (new_smap),
m_stmt_finder (stmt_finder)
{
}
logger *get_logger () const { return m_logger.get_logger (); }
tree get_fndecl_for_call (const gcall *call) FINAL OVERRIDE
{
impl_region_model_context old_ctxt
(m_eg, m_enode_for_diag, NULL, NULL/*m_enode->get_state ()*/,
call);
region_model *model = m_new_state->m_region_model;
return model->get_fndecl_for_call (call, &old_ctxt);
}
state_machine::state_t get_state (const gimple *stmt,
tree var)
{
logger * const logger = get_logger ();
LOG_FUNC (logger);
impl_region_model_context old_ctxt
(m_eg, m_enode_for_diag, NULL, NULL/*m_enode->get_state ()*/,
stmt);
const svalue *var_old_sval
= m_old_state->m_region_model->get_rvalue (var, &old_ctxt);
state_machine::state_t current
= m_old_smap->get_state (var_old_sval, m_eg.get_ext_state ());
return current;
}
void set_next_state (const gimple *stmt,
tree var,
state_machine::state_t to,
tree origin)
{
logger * const logger = get_logger ();
LOG_FUNC (logger);
impl_region_model_context old_ctxt
(m_eg, m_enode_for_diag, NULL, NULL/*m_enode->get_state ()*/,
stmt);
const svalue *var_old_sval
= m_old_state->m_region_model->get_rvalue (var, &old_ctxt);
impl_region_model_context new_ctxt (m_eg, m_enode_for_diag,
m_old_state, m_new_state,
stmt);
const svalue *var_new_sval
= m_new_state->m_region_model->get_rvalue (var, &new_ctxt);
const svalue *origin_new_sval
= m_new_state->m_region_model->get_rvalue (origin, &new_ctxt);
state_machine::state_t current
= m_old_smap->get_state (var_old_sval, m_eg.get_ext_state ());
if (logger)
logger->log ("%s: state transition of %qE: %s -> %s",
m_sm.get_name (),
var,
current->get_name (),
to->get_name ());
m_new_smap->set_state (m_new_state->m_region_model, var_new_sval,
to, origin_new_sval, m_eg.get_ext_state ());
}
void warn (const supernode *snode, const gimple *stmt,
tree var, pending_diagnostic *d) FINAL OVERRIDE
{
LOG_FUNC (get_logger ());
gcc_assert (d); // take ownership
impl_region_model_context old_ctxt
(m_eg, m_enode_for_diag, m_old_state, m_new_state, NULL);
const svalue *var_old_sval
= m_old_state->m_region_model->get_rvalue (var, &old_ctxt);
state_machine::state_t current
= (var
? m_old_smap->get_state (var_old_sval, m_eg.get_ext_state ())
: m_old_smap->get_global_state ());
m_eg.get_diagnostic_manager ().add_diagnostic
(&m_sm, m_enode_for_diag, snode, stmt, m_stmt_finder,
var, var_old_sval, current, d);
}
/* Hook for picking more readable trees for SSA names of temporaries,
so that rather than e.g.
"double-free of '<unknown>'"
we can print:
"double-free of 'inbuf.data'". */
tree get_diagnostic_tree (tree expr) FINAL OVERRIDE
{
/* Only for SSA_NAMEs of temporaries; otherwise, return EXPR, as it's
likely to be the least surprising tree to report. */
if (TREE_CODE (expr) != SSA_NAME)
return expr;
if (SSA_NAME_VAR (expr) != NULL)
return expr;
gcc_assert (m_new_state);
const svalue *sval = m_new_state->m_region_model->get_rvalue (expr, NULL);
/* Find trees for all regions storing the value. */
if (tree t = m_new_state->m_region_model->get_representative_tree (sval))
return t;
else
return expr;
}
state_machine::state_t get_global_state () const FINAL OVERRIDE
{
return m_old_state->m_checker_states[m_sm_idx]->get_global_state ();
}
void set_global_state (state_machine::state_t state) FINAL OVERRIDE
{
m_new_state->m_checker_states[m_sm_idx]->set_global_state (state);
}
void on_custom_transition (custom_transition *transition) FINAL OVERRIDE
{
transition->impl_transition (&m_eg,
const_cast<exploded_node *> (m_enode_for_diag),
m_sm_idx);
}
tree is_zero_assignment (const gimple *stmt) FINAL OVERRIDE
{
const gassign *assign_stmt = dyn_cast <const gassign *> (stmt);
if (!assign_stmt)
return NULL_TREE;
impl_region_model_context old_ctxt
(m_eg, m_enode_for_diag, m_old_state, m_new_state, stmt);
if (const svalue *sval
= m_new_state->m_region_model->get_gassign_result (assign_stmt,
&old_ctxt))
if (tree cst = sval->maybe_get_constant ())
if (::zerop(cst))
return gimple_assign_lhs (assign_stmt);
return NULL_TREE;
}
log_user m_logger;
exploded_graph &m_eg;
const exploded_node *m_enode_for_diag;
const program_state *m_old_state;
program_state *m_new_state;
const sm_state_map *m_old_smap;
sm_state_map *m_new_smap;
stmt_finder *m_stmt_finder;
};
/* Subclass of stmt_finder for finding the best stmt to report the leak at,
given the emission path. */
class leak_stmt_finder : public stmt_finder
{
public:
leak_stmt_finder (const exploded_graph &eg, tree var)
: m_eg (eg), m_var (var) {}
stmt_finder *clone () const FINAL OVERRIDE
{
return new leak_stmt_finder (m_eg, m_var);
}
const gimple *find_stmt (const exploded_path &epath)
FINAL OVERRIDE
{
logger * const logger = m_eg.get_logger ();
LOG_FUNC (logger);
if (m_var && TREE_CODE (m_var) == SSA_NAME)
{
/* Locate the final write to this SSA name in the path. */
const gimple *def_stmt = SSA_NAME_DEF_STMT (m_var);
int idx_of_def_stmt;
bool found = epath.find_stmt_backwards (def_stmt, &idx_of_def_stmt);
if (!found)
goto not_found;
/* What was the next write to the underlying var
after the SSA name was set? (if any). */
for (unsigned idx = idx_of_def_stmt + 1;
idx < epath.m_edges.length ();
++idx)
{
const exploded_edge *eedge = epath.m_edges[idx];
if (logger)
logger->log ("eedge[%i]: EN %i -> EN %i",
idx,
eedge->m_src->m_index,
eedge->m_dest->m_index);
const exploded_node *dst_node = eedge->m_dest;
const program_point &dst_point = dst_node->get_point ();
const gimple *stmt = dst_point.get_stmt ();
if (!stmt)
continue;
if (const gassign *assign = dyn_cast <const gassign *> (stmt))
{
tree lhs = gimple_assign_lhs (assign);
if (TREE_CODE (lhs) == SSA_NAME
&& SSA_NAME_VAR (lhs) == SSA_NAME_VAR (m_var))
return assign;
}
}
}
not_found:
/* Look backwards for the first statement with a location. */
int i;
const exploded_edge *eedge;
FOR_EACH_VEC_ELT_REVERSE (epath.m_edges, i, eedge)
{
if (logger)
logger->log ("eedge[%i]: EN %i -> EN %i",
i,
eedge->m_src->m_index,
eedge->m_dest->m_index);
const exploded_node *dst_node = eedge->m_dest;
const program_point &dst_point = dst_node->get_point ();
const gimple *stmt = dst_point.get_stmt ();
if (stmt)
if (get_pure_location (stmt->location) != UNKNOWN_LOCATION)
return stmt;
}
gcc_unreachable ();
return NULL;
}
private:
const exploded_graph &m_eg;
tree m_var;
};
/* A measurement of how good EXPR is for presenting to the user, so
that e.g. we can say prefer printing
"leak of 'tmp.m_ptr'"
over:
"leak of '<unknown>'". */
static int
readability (const_tree expr)
{
/* Arbitrarily-chosen "high readability" value. */
const int HIGH_READABILITY = 65536;
gcc_assert (expr);
switch (TREE_CODE (expr))
{
case COMPONENT_REF:
case MEM_REF:
/* Impose a slight readability penalty relative to that of
operand 0. */
return readability (TREE_OPERAND (expr, 0)) - 16;
case SSA_NAME:
{
if (tree var = SSA_NAME_VAR (expr))
/* Slightly favor the underlying var over the SSA name to
avoid having them compare equal. */
return readability (var) - 1;
/* Avoid printing '<unknown>' for SSA names for temporaries. */
return -1;
}
break;
case PARM_DECL:
case VAR_DECL:
if (DECL_NAME (expr))
return HIGH_READABILITY;
else
/* We don't want to print temporaries. For example, the C FE
prints them as e.g. "<Uxxxx>" where "xxxx" is the low 16 bits
of the tree pointer (see pp_c_tree_decl_identifier). */
return -1;
case RESULT_DECL:
/* Printing "<return-value>" isn't ideal, but is less awful than
trying to print a temporary. */
return HIGH_READABILITY / 2;
case NOP_EXPR:
{
/* Impose a moderate readability penalty for casts. */
const int CAST_PENALTY = 32;
return readability (TREE_OPERAND (expr, 0)) - CAST_PENALTY;
}
case INTEGER_CST:
return HIGH_READABILITY;
default:
return 0;
}
return 0;
}
/* A qsort comparator for trees to sort them into most user-readable to
least user-readable. */
int
readability_comparator (const void *p1, const void *p2)
{
path_var pv1 = *(path_var const *)p1;
path_var pv2 = *(path_var const *)p2;
const int tree_r1 = readability (pv1.m_tree);
const int tree_r2 = readability (pv2.m_tree);
/* Favor items that are deeper on the stack and hence more recent;
this also favors locals over globals. */
const int COST_PER_FRAME = 64;
const int depth_r1 = pv1.m_stack_depth * COST_PER_FRAME;
const int depth_r2 = pv2.m_stack_depth * COST_PER_FRAME;
/* Combine the scores from the tree and from the stack depth.
This e.g. lets us have a slightly penalized cast in the most
recent stack frame "beat" an uncast value in an older stack frame. */
const int sum_r1 = tree_r1 + depth_r1;
const int sum_r2 = tree_r2 + depth_r2;
if (int cmp = sum_r2 - sum_r1)
return cmp;
/* Otherwise, more readable trees win. */
if (int cmp = tree_r2 - tree_r1)
return cmp;
/* Otherwise, if they have the same readability, then impose an
arbitrary deterministic ordering on them. */
if (int cmp = TREE_CODE (pv1.m_tree) - TREE_CODE (pv2.m_tree))
return cmp;
switch (TREE_CODE (pv1.m_tree))
{
default:
break;
case SSA_NAME:
if (int cmp = (SSA_NAME_VERSION (pv1.m_tree)
- SSA_NAME_VERSION (pv2.m_tree)))
return cmp;
break;
case PARM_DECL:
case VAR_DECL:
case RESULT_DECL:
if (int cmp = DECL_UID (pv1.m_tree) - DECL_UID (pv2.m_tree))
return cmp;
break;
}
/* TODO: We ought to find ways of sorting such cases. */
return 0;
}
/* Find the best tree for SVAL and call SM's on_leak vfunc with it.
If on_leak returns a pending_diagnostic, queue it up to be reported,
so that we potentially complain about a leak of SVAL in the given STATE. */
void
impl_region_model_context::on_state_leak (const state_machine &sm,
const svalue *sval,
state_machine::state_t state)
{
logger * const logger = get_logger ();
LOG_SCOPE (logger);
if (logger)
{
logger->start_log_line ();
logger->log_partial ("considering leak of ");
sval->dump_to_pp (logger->get_printer (), true);
logger->end_log_line ();
}
if (!m_eg)
return;
/* m_old_state also needs to be non-NULL so that the sm_ctxt can look
up the old state of SVAL. */
gcc_assert (m_old_state);
/* SVAL has leaked within the new state: it is not used by any reachable
regions.
We need to convert it back to a tree, but since it's likely no regions
use it, we have to find the "best" tree for it in the old_state. */
svalue_set visited;
path_var leaked_pv
= m_old_state->m_region_model->get_representative_path_var (sval,
&visited);
/* Strip off top-level casts */
if (leaked_pv.m_tree && TREE_CODE (leaked_pv.m_tree) == NOP_EXPR)
leaked_pv.m_tree = TREE_OPERAND (leaked_pv.m_tree, 0);
/* This might be NULL; the pending_diagnostic subclasses need to cope
with this. */
tree leaked_tree = leaked_pv.m_tree;
if (logger)
{
if (leaked_tree)
logger->log ("best leaked_tree: %qE", leaked_tree);
else
logger->log ("best leaked_tree: NULL");
}
leak_stmt_finder stmt_finder (*m_eg, leaked_tree);
gcc_assert (m_enode_for_diag);
/* Don't complain about leaks when returning from "main". */
if (m_enode_for_diag->get_supernode ()
&& m_enode_for_diag->get_supernode ()->return_p ())
{
tree fndecl = m_enode_for_diag->get_function ()->decl;
if (id_equal (DECL_NAME (fndecl), "main"))
{
if (logger)
logger->log ("not reporting leak from main");
return;
}
}
tree leaked_tree_for_diag = fixup_tree_for_diagnostic (leaked_tree);
pending_diagnostic *pd = sm.on_leak (leaked_tree_for_diag);
if (pd)
m_eg->get_diagnostic_manager ().add_diagnostic
(&sm, m_enode_for_diag, m_enode_for_diag->get_supernode (),
m_stmt, &stmt_finder,
leaked_tree_for_diag, sval, state, pd);
}
/* Implementation of region_model_context::on_condition vfunc.
Notify all state machines about the condition, which could lead to
state transitions. */
void
impl_region_model_context::on_condition (tree lhs, enum tree_code op, tree rhs)
{
int sm_idx;
sm_state_map *smap;
FOR_EACH_VEC_ELT (m_new_state->m_checker_states, sm_idx, smap)
{
const state_machine &sm = m_ext_state.get_sm (sm_idx);
impl_sm_context sm_ctxt (*m_eg, sm_idx, sm, m_enode_for_diag,
m_old_state, m_new_state,
m_old_state->m_checker_states[sm_idx],
m_new_state->m_checker_states[sm_idx]);
sm.on_condition (&sm_ctxt,
m_enode_for_diag->get_supernode (), m_stmt,
lhs, op, rhs);
}
}
/* Implementation of region_model_context::on_phi vfunc.
Notify all state machines about the phi, which could lead to
state transitions. */
void
impl_region_model_context::on_phi (const gphi *phi, tree rhs)
{
int sm_idx;
sm_state_map *smap;
FOR_EACH_VEC_ELT (m_new_state->m_checker_states, sm_idx, smap)
{
const state_machine &sm = m_ext_state.get_sm (sm_idx);
impl_sm_context sm_ctxt (*m_eg, sm_idx, sm, m_enode_for_diag,
m_old_state, m_new_state,
m_old_state->m_checker_states[sm_idx],
m_new_state->m_checker_states[sm_idx]);
sm.on_phi (&sm_ctxt, m_enode_for_diag->get_supernode (), phi, rhs);
}
}
/* Implementation of region_model_context::on_unexpected_tree_code vfunc.
Mark the new state as being invalid for further exploration.
TODO(stage1): introduce a warning for when this occurs. */
void
impl_region_model_context::on_unexpected_tree_code (tree t,
const dump_location_t &loc)
{
logger * const logger = get_logger ();
if (logger)
logger->log ("unhandled tree code: %qs in %qs at %s:%i",
get_tree_code_name (TREE_CODE (t)),
loc.get_impl_location ().m_function,
loc.get_impl_location ().m_file,
loc.get_impl_location ().m_line);
if (m_new_state)
m_new_state->m_valid = false;
}
/* struct point_and_state. */
/* Assert that this object is sane. */
void
point_and_state::validate (const extrinsic_state &ext_state) const
{
/* Skip this in a release build. */
#if !CHECKING_P
return;
#endif
m_point.validate ();
m_state.validate (ext_state);
/* Verify that the callstring's model of the stack corresponds to that
of the region_model. */
/* They should have the same depth. */
gcc_assert (m_point.get_stack_depth ()
== m_state.m_region_model->get_stack_depth ());
/* Check the functions in the callstring vs those in the frames
at each depth. */
for (const frame_region *iter_frame
= m_state.m_region_model->get_current_frame ();
iter_frame; iter_frame = iter_frame->get_calling_frame ())
{
int index = iter_frame->get_index ();
gcc_assert (m_point.get_function_at_depth (index)
== iter_frame->get_function ());
}
}
/* Subroutine of print_enode_indices: print a run of indices from START_IDX
to END_IDX to PP, using and updating *FIRST_RUN. */
static void
print_run (pretty_printer *pp, int start_idx, int end_idx,
bool *first_run)
{
if (!(*first_run))
pp_string (pp, ", ");
*first_run = false;
if (start_idx == end_idx)
pp_printf (pp, "EN: %i", start_idx);
else
pp_printf (pp, "EN: %i-%i", start_idx, end_idx);
}
/* Print the indices within ENODES to PP, collecting them as
runs/singletons e.g. "EN: 4-7, EN: 20-23, EN: 42". */
static void
print_enode_indices (pretty_printer *pp,
const auto_vec<exploded_node *> &enodes)
{
int cur_start_idx = -1;
int cur_finish_idx = -1;
bool first_run = true;
unsigned i;
exploded_node *enode;
FOR_EACH_VEC_ELT (enodes, i, enode)
{
if (cur_start_idx == -1)
{
gcc_assert (cur_finish_idx == -1);
cur_start_idx = cur_finish_idx = enode->m_index;
}
else
{
if (enode->m_index == cur_finish_idx + 1)
/* Continuation of a run. */
cur_finish_idx = enode->m_index;
else
{
/* Finish existing run, start a new one. */
gcc_assert (cur_start_idx >= 0);
gcc_assert (cur_finish_idx >= 0);
print_run (pp, cur_start_idx, cur_finish_idx,
&first_run);
cur_start_idx = cur_finish_idx = enode->m_index;
}
}
}
/* Finish any existing run. */
if (cur_start_idx >= 0)
{
gcc_assert (cur_finish_idx >= 0);
print_run (pp, cur_start_idx, cur_finish_idx,
&first_run);
}
}
/* struct eg_traits::dump_args_t. */
/* The <FILENAME>.eg.dot output can quickly become unwieldy if we show
full details for all enodes (both in terms of CPU time to render it,
and in terms of being meaningful to a human viewing it).
If we show just the IDs then the resulting graph is usually viewable,
but then we have to keep switching back and forth between the .dot
view and other dumps.
This function implements a heuristic for showing detail at the enodes
that (we hope) matter, and just the ID at other enodes, fixing the CPU
usage of the .dot viewer, and drawing the attention of the viewer
to these enodes.
Return true if ENODE should be shown in detail in .dot output.
Return false if no detail should be shown for ENODE. */
bool
eg_traits::dump_args_t::show_enode_details_p (const exploded_node &enode) const
{
/* If the number of exploded nodes isn't too large, we may as well show
all enodes in full detail in the .dot output. */
if (m_eg.m_nodes.length ()
<= (unsigned) param_analyzer_max_enodes_for_full_dump)
return true;
/* Otherwise, assume that what's most interesting are state explosions,
and thus the places where this happened.
Expand enodes at program points where we hit the per-enode limit, so we
can investigate what exploded. */
const per_program_point_data *per_point_data
= m_eg.get_per_program_point_data (enode.get_point ());
return per_point_data->m_excess_enodes > 0;
}
/* class exploded_node : public dnode<eg_traits>. */
const char *
exploded_node::status_to_str (enum status s)
{
switch (s)
{
default: gcc_unreachable ();
case STATUS_WORKLIST: return "WORKLIST";
case STATUS_PROCESSED: return "PROCESSED";
case STATUS_MERGER: return "MERGER";
case STATUS_BULK_MERGED: return "BULK_MERGED";
}
}
/* exploded_node's ctor. */
exploded_node::exploded_node (const point_and_state &ps,
int index)
: m_ps (ps), m_status (STATUS_WORKLIST), m_index (index),
m_num_processed_stmts (0)
{
gcc_checking_assert (ps.get_state ().m_region_model->canonicalized_p ());
}
/* Get the stmt that was processed in this enode at index IDX.
IDX is an index within the stmts processed at this enode, rather
than within those of the supernode. */
const gimple *
exploded_node::get_processed_stmt (unsigned idx) const
{
gcc_assert (idx < m_num_processed_stmts);
const program_point &point = get_point ();
gcc_assert (point.get_kind () == PK_BEFORE_STMT);
const supernode *snode = get_supernode ();
const unsigned int point_stmt_idx = point.get_stmt_idx ();
const unsigned int idx_within_snode = point_stmt_idx + idx;
const gimple *stmt = snode->m_stmts[idx_within_snode];
return stmt;
}
/* For use by dump_dot, get a value for the .dot "fillcolor" attribute.
Colorize by sm-state, to make it easier to see how sm-state propagates
through the exploded_graph. */
const char *
exploded_node::get_dot_fillcolor () const
{
const program_state &state = get_state ();
/* We want to be able to easily distinguish the no-sm-state case,
and to be able to distinguish cases where there's a single state
from each other.
Sum the sm_states, and use the result to choose from a table,
modulo table-size, special-casing the "no sm-state" case. */
int total_sm_state = 0;
int i;
sm_state_map *smap;
FOR_EACH_VEC_ELT (state.m_checker_states, i, smap)
{
for (sm_state_map::iterator_t iter = smap->begin ();
iter != smap->end ();
++iter)
total_sm_state += (*iter).second.m_state->get_id ();
total_sm_state += smap->get_global_state ()->get_id ();
}
if (total_sm_state > 0)
{
/* An arbitrarily-picked collection of light colors. */
const char * const colors[]
= {"azure", "coral", "cornsilk", "lightblue", "yellow",
"honeydew", "lightpink", "lightsalmon", "palegreen1",
"wheat", "seashell"};
const int num_colors = sizeof (colors) / sizeof (colors[0]);
return colors[total_sm_state % num_colors];
}
else
/* No sm-state. */
return "lightgrey";
}
/* Implementation of dnode::dump_dot vfunc for exploded_node. */
void
exploded_node::dump_dot (graphviz_out *gv, const dump_args_t &args) const
{
pretty_printer *pp = gv->get_pp ();
dump_dot_id (pp);
pp_printf (pp, " [shape=none,margin=0,style=filled,fillcolor=%s,label=\"",
get_dot_fillcolor ());
pp_write_text_to_stream (pp);
pp_printf (pp, "EN: %i", m_index);
if (m_status == STATUS_MERGER)
pp_string (pp, " (merger)");
else if (m_status == STATUS_BULK_MERGED)
pp_string (pp, " (bulk merged)");
pp_newline (pp);
if (args.show_enode_details_p (*this))
{
format f (true);
m_ps.get_point ().print (pp, f);
pp_newline (pp);
const extrinsic_state &ext_state = args.m_eg.get_ext_state ();
const program_state &state = m_ps.get_state ();
state.dump_to_pp (ext_state, false, true, pp);
pp_newline (pp);
dump_processed_stmts (pp);
}
dump_saved_diagnostics (pp, args.m_eg.get_diagnostic_manager ());
args.dump_extra_info (this, pp);
pp_write_text_as_dot_label_to_stream (pp, /*for_record=*/true);
pp_string (pp, "\"];\n\n");
pp_flush (pp);
}
/* Show any stmts that were processed within this enode,
and their index within the supernode. */
void
exploded_node::dump_processed_stmts (pretty_printer *pp) const
{
if (m_num_processed_stmts > 0)
{
const program_point &point = get_point ();
gcc_assert (point.get_kind () == PK_BEFORE_STMT);
const supernode *snode = get_supernode ();
const unsigned int point_stmt_idx = point.get_stmt_idx ();
pp_printf (pp, "stmts: %i", m_num_processed_stmts);
pp_newline (pp);
for (unsigned i = 0; i < m_num_processed_stmts; i++)
{
const unsigned int idx_within_snode = point_stmt_idx + i;
const gimple *stmt = snode->m_stmts[idx_within_snode];
pp_printf (pp, " %i: ", idx_within_snode);
pp_gimple_stmt_1 (pp, stmt, 0, (dump_flags_t)0);
pp_newline (pp);
}
}
}
/* Dump any saved_diagnostics at this enode to PP. */
void
exploded_node::dump_saved_diagnostics (pretty_printer *pp,
const diagnostic_manager &dm) const
{
for (unsigned i = 0; i < dm.get_num_diagnostics (); i++)
{
const saved_diagnostic *sd = dm.get_saved_diagnostic (i);
if (sd->m_enode == this)
{
pp_printf (pp, "DIAGNOSTIC: %s (sd: %i)",
sd->m_d->get_kind (), sd->get_index ());
pp_newline (pp);
}
}
}
/* Dump this to PP in a form suitable for use as an id in .dot output. */
void
exploded_node::dump_dot_id (pretty_printer *pp) const
{
pp_printf (pp, "exploded_node_%i", m_index);
}
/* Dump a multiline representation of this node to PP. */
void
exploded_node::dump_to_pp (pretty_printer *pp,
const extrinsic_state &ext_state) const
{
pp_printf (pp, "EN: %i", m_index);
pp_newline (pp);
format f (true);
m_ps.get_point ().print (pp, f);
pp_newline (pp);
m_ps.get_state ().dump_to_pp (ext_state, false, true, pp);
pp_newline (pp);
}
/* Dump a multiline representation of this node to FILE. */
void
exploded_node::dump (FILE *fp,
const extrinsic_state &ext_state) const
{
pretty_printer pp;
pp_format_decoder (&pp) = default_tree_printer;
pp_show_color (&pp) = pp_show_color (global_dc->printer);
pp.buffer->stream = fp;
dump_to_pp (&pp, ext_state);
pp_flush (&pp);
}
/* Dump a multiline representation of this node to stderr. */
DEBUG_FUNCTION void
exploded_node::dump (const extrinsic_state &ext_state) const
{
dump (stderr, ext_state);
}
/* Return a new json::object of the form
{"point" : object for program_point,
"state" : object for program_state,
"status" : str,
"idx" : int,
"processed_stmts" : int}. */
json::object *
exploded_node::to_json (const extrinsic_state &ext_state) const
{
json::object *enode_obj = new json::object ();
enode_obj->set ("point", get_point ().to_json ());
enode_obj->set ("state", get_state ().to_json (ext_state));
enode_obj->set ("status", new json::string (status_to_str (m_status)));
enode_obj->set ("idx", new json::integer_number (m_index));
enode_obj->set ("processed_stmts",
new json::integer_number (m_num_processed_stmts));
return enode_obj;
}
} // namespace ana
/* Return true if FNDECL has a gimple body. */
// TODO: is there a pre-canned way to do this?
bool
fndecl_has_gimple_body_p (tree fndecl)
{
if (fndecl == NULL_TREE)
return false;
cgraph_node *n = cgraph_node::get (fndecl);
if (!n)
return false;
return n->has_gimple_body_p ();
}
namespace ana {
/* A pending_diagnostic subclass for implementing "__analyzer_dump_path". */
class dump_path_diagnostic
: public pending_diagnostic_subclass<dump_path_diagnostic>
{
public:
bool emit (rich_location *richloc) FINAL OVERRIDE
{
inform (richloc, "path");
return true;
}
const char *get_kind () const FINAL OVERRIDE { return "dump_path_diagnostic"; }
bool operator== (const dump_path_diagnostic &) const
{
return true;
}
};
/* Modify STATE in place, applying the effects of the stmt at this node's
point. */
exploded_node::on_stmt_flags
exploded_node::on_stmt (exploded_graph &eg,
const supernode *snode,
const gimple *stmt,
program_state *state) const
{
logger *logger = eg.get_logger ();
LOG_SCOPE (logger);
if (logger)
{
logger->start_log_line ();
pp_gimple_stmt_1 (logger->get_printer (), stmt, 0, (dump_flags_t)0);
logger->end_log_line ();
}
/* Update input_location in case of ICE: make it easier to track down which
source construct we're failing to handle. */
input_location = stmt->location;
gcc_assert (state->m_region_model);
/* Preserve the old state. It is used here for looking
up old checker states, for determining state transitions, and
also within impl_region_model_context and impl_sm_context for
going from tree to svalue_id. */
const program_state old_state (*state);
impl_region_model_context ctxt (eg, this,
&old_state, state,
stmt);
bool unknown_side_effects = false;
bool terminate_path = false;
switch (gimple_code (stmt))
{
default:
/* No-op for now. */
break;
case GIMPLE_ASSIGN:
{
const gassign *assign = as_a <const gassign *> (stmt);
state->m_region_model->on_assignment (assign, &ctxt);
}
break;
case GIMPLE_ASM:
/* No-op for now. */
break;
case GIMPLE_CALL:
{
/* Track whether we have a gcall to a function that's not recognized by
anything, for which we don't have a function body, or for which we
don't know the fndecl. */
const gcall *call = as_a <const gcall *> (stmt);
/* Debugging/test support. */
if (is_special_named_call_p (call, "__analyzer_describe", 2))
state->m_region_model->impl_call_analyzer_describe (call, &ctxt);
else if (is_special_named_call_p (call, "__analyzer_dump", 0))
{
/* Handle the builtin "__analyzer_dump" by dumping state
to stderr. */
state->dump (eg.get_ext_state (), true);
}
else if (is_special_named_call_p (call, "__analyzer_dump_path", 0))
{
/* Handle the builtin "__analyzer_dump_path" by queuing a
diagnostic at this exploded_node. */
ctxt.warn (new dump_path_diagnostic ());
}
else if (is_special_named_call_p (call, "__analyzer_dump_region_model",
0))
{
/* Handle the builtin "__analyzer_dump_region_model" by dumping
the region model's state to stderr. */
state->m_region_model->dump (false);
}
else if (is_special_named_call_p (call, "__analyzer_eval", 1))
state->m_region_model->impl_call_analyzer_eval (call, &ctxt);
else if (is_special_named_call_p (call, "__analyzer_break", 0))
{
/* Handle the builtin "__analyzer_break" by triggering a
breakpoint. */
/* TODO: is there a good cross-platform way to do this? */
raise (SIGINT);
}
else if (is_special_named_call_p (call,
"__analyzer_dump_exploded_nodes",
1))
{
/* This is handled elsewhere. */
}
else if (is_setjmp_call_p (call))
state->m_region_model->on_setjmp (call, this, &ctxt);
else if (is_longjmp_call_p (call))
{
on_longjmp (eg, call, state, &ctxt);
return on_stmt_flags::terminate_path ();
}
else
unknown_side_effects
= state->m_region_model->on_call_pre (call, &ctxt, &terminate_path);
}
break;
case GIMPLE_RETURN:
{
const greturn *return_ = as_a <const greturn *> (stmt);
state->m_region_model->on_return (return_, &ctxt);
}
break;
}
if (terminate_path)
return on_stmt_flags::terminate_path ();
bool any_sm_changes = false;
int sm_idx;
sm_state_map *smap;
FOR_EACH_VEC_ELT (old_state.m_checker_states, sm_idx, smap)
{
const state_machine &sm = eg.get_ext_state ().get_sm (sm_idx);
const sm_state_map *old_smap
= old_state.m_checker_states[sm_idx];
sm_state_map *new_smap = state->m_checker_states[sm_idx];
impl_sm_context sm_ctxt (eg, sm_idx, sm, this, &old_state, state,
old_smap, new_smap);
/* If we're at the def-stmt of an SSA name, then potentially purge
any sm-state for svalues that involve that SSA name. This avoids
false positives in loops, since a symbolic value referring to the
SSA name will be referring to the previous value of that SSA name.
For example, in:
while ((e = hashmap_iter_next(&iter))) {
struct oid2strbuf *e_strbuf = (struct oid2strbuf *)e;
free (e_strbuf->value);
}
at the def-stmt of e_8:
e_8 = hashmap_iter_next (&iter);
we should purge the "freed" state of:
INIT_VAL(CAST_REG(struct oid2strbuf, (*INIT_VAL(e_8))).value)
which is the "e_strbuf->value" value from the previous iteration,
or we will erroneously report a double-free - the "e_8" within it
refers to the previous value. */
if (tree lhs = gimple_get_lhs (stmt))
if (TREE_CODE (lhs) == SSA_NAME)
{
const svalue *sval
= old_state.m_region_model->get_rvalue (lhs, &ctxt);
new_smap->purge_state_involving (sval, eg.get_ext_state ());
}
/* Allow the state_machine to handle the stmt. */
if (sm.on_stmt (&sm_ctxt, snode, stmt))
unknown_side_effects = false;
if (*old_smap != *new_smap)
any_sm_changes = true;
}
if (const gcall *call = dyn_cast <const gcall *> (stmt))
state->m_region_model->on_call_post (call, unknown_side_effects, &ctxt);
return on_stmt_flags (any_sm_changes);
}
/* Consider the effect of following superedge SUCC from this node.
Return true if it's feasible to follow the edge, or false
if it's infeasible.
Examples: if it's the "true" branch within
a CFG and we know the conditional is false, we know it's infeasible.
If it's one of multiple interprocedual "return" edges, then only
the edge back to the most recent callsite is feasible.
Update NEXT_STATE accordingly (e.g. to record that a condition was
true or false, or that the NULL-ness of a pointer has been checked,
pushing/popping stack frames, etc).
Update NEXT_POINT accordingly (updating the call string). */
bool
exploded_node::on_edge (exploded_graph &eg,
const superedge *succ,
program_point *next_point,
program_state *next_state) const
{
LOG_FUNC (eg.get_logger ());
if (!next_point->on_edge (eg, succ))
return false;
if (!next_state->on_edge (eg, *this, succ))
return false;
return true;
}
/* Verify that the stack at LONGJMP_POINT is still valid, given a call
to "setjmp" at SETJMP_POINT - the stack frame that "setjmp" was
called in must still be valid.
Caveat: this merely checks the call_strings in the points; it doesn't
detect the case where a frame returns and is then called again. */
static bool
valid_longjmp_stack_p (const program_point &longjmp_point,
const program_point &setjmp_point)
{
const call_string &cs_at_longjmp = longjmp_point.get_call_string ();
const call_string &cs_at_setjmp = setjmp_point.get_call_string ();
if (cs_at_longjmp.length () < cs_at_setjmp.length ())
return false;
/* Check that the call strings match, up to the depth of the
setjmp point. */
for (unsigned depth = 0; depth < cs_at_setjmp.length (); depth++)
if (cs_at_longjmp[depth] != cs_at_setjmp[depth])
return false;
return true;
}
/* A pending_diagnostic subclass for complaining about bad longjmps,
where the enclosing function of the "setjmp" has returned (and thus
the stack frame no longer exists). */
class stale_jmp_buf : public pending_diagnostic_subclass<dump_path_diagnostic>
{
public:
stale_jmp_buf (const gcall *setjmp_call, const gcall *longjmp_call,
const program_point &setjmp_point)
: m_setjmp_call (setjmp_call), m_longjmp_call (longjmp_call),
m_setjmp_point (setjmp_point), m_stack_pop_event (NULL)
{}
bool emit (rich_location *richloc) FINAL OVERRIDE
{
return warning_at
(richloc, OPT_Wanalyzer_stale_setjmp_buffer,
"%qs called after enclosing function of %qs has returned",
get_user_facing_name (m_longjmp_call),
get_user_facing_name (m_setjmp_call));
}
const char *get_kind () const FINAL OVERRIDE
{ return "stale_jmp_buf"; }
bool operator== (const stale_jmp_buf &other) const
{
return (m_setjmp_call == other.m_setjmp_call
&& m_longjmp_call == other.m_longjmp_call);
}
bool
maybe_add_custom_events_for_superedge (const exploded_edge &eedge,
checker_path *emission_path)
FINAL OVERRIDE
{
/* Detect exactly when the stack first becomes invalid,
and issue an event then. */
if (m_stack_pop_event)
return false;
const exploded_node *src_node = eedge.m_src;
const program_point &src_point = src_node->get_point ();
const exploded_node *dst_node = eedge.m_dest;
const program_point &dst_point = dst_node->get_point ();
if (valid_longjmp_stack_p (src_point, m_setjmp_point)
&& !valid_longjmp_stack_p (dst_point, m_setjmp_point))
{
/* Compare with diagnostic_manager::add_events_for_superedge. */
const int src_stack_depth = src_point.get_stack_depth ();
m_stack_pop_event = new custom_event
(src_point.get_location (),
src_point.get_fndecl (),
src_stack_depth,
"stack frame is popped here, invalidating saved environment");
emission_path->add_event (m_stack_pop_event);
return false;
}
return false;
}
label_text describe_final_event (const evdesc::final_event &ev)
{
if (m_stack_pop_event)
return ev.formatted_print
("%qs called after enclosing function of %qs returned at %@",
get_user_facing_name (m_longjmp_call),
get_user_facing_name (m_setjmp_call),
m_stack_pop_event->get_id_ptr ());
else
return ev.formatted_print
("%qs called after enclosing function of %qs has returned",
get_user_facing_name (m_longjmp_call),
get_user_facing_name (m_setjmp_call));;
}
private:
const gcall *m_setjmp_call;
const gcall *m_longjmp_call;
program_point m_setjmp_point;
custom_event *m_stack_pop_event;
};
/* Handle LONGJMP_CALL, a call to longjmp or siglongjmp.
Attempt to locate where setjmp/sigsetjmp was called on the jmp_buf and build
an exploded_node and exploded_edge to it representing a rewind to that frame,
handling the various kinds of failure that can occur. */
void
exploded_node::on_longjmp (exploded_graph &eg,
const gcall *longjmp_call,
program_state *new_state,
region_model_context *ctxt) const
{
tree buf_ptr = gimple_call_arg (longjmp_call, 0);
gcc_assert (POINTER_TYPE_P (TREE_TYPE (buf_ptr)));
region_model *new_region_model = new_state->m_region_model;
const svalue *buf_ptr_sval = new_region_model->get_rvalue (buf_ptr, ctxt);
const region *buf = new_region_model->deref_rvalue (buf_ptr_sval, buf_ptr,
ctxt);
const svalue *buf_content_sval = new_region_model->get_store_value (buf);
const setjmp_svalue *setjmp_sval
= buf_content_sval->dyn_cast_setjmp_svalue ();
if (!setjmp_sval)
return;
const setjmp_record tmp_setjmp_record = setjmp_sval->get_setjmp_record ();
/* Build a custom enode and eedge for rewinding from the longjmp/siglongjmp
call back to the setjmp/sigsetjmp. */
rewind_info_t rewind_info (tmp_setjmp_record, longjmp_call);
const gcall *setjmp_call = rewind_info.get_setjmp_call ();
const program_point &setjmp_point = rewind_info.get_setjmp_point ();
const program_point &longjmp_point = get_point ();
/* Verify that the setjmp's call_stack hasn't been popped. */
if (!valid_longjmp_stack_p (longjmp_point, setjmp_point))
{
ctxt->warn (new stale_jmp_buf (setjmp_call, longjmp_call, setjmp_point));
return;
}
gcc_assert (longjmp_point.get_stack_depth ()
>= setjmp_point.get_stack_depth ());
/* Update the state for use by the destination node. */
/* Stash the current number of diagnostics so that we can update
any that this adds to show where the longjmp is rewinding to. */
diagnostic_manager *dm = &eg.get_diagnostic_manager ();
unsigned prev_num_diagnostics = dm->get_num_diagnostics ();
new_region_model->on_longjmp (longjmp_call, setjmp_call,
setjmp_point.get_stack_depth (), ctxt);
/* Detect leaks in the new state relative to the old state. */
program_state::detect_leaks (get_state (), *new_state, NULL,
eg.get_ext_state (), ctxt);
program_point next_point
= program_point::after_supernode (setjmp_point.get_supernode (),
setjmp_point.get_call_string ());
exploded_node *next
= eg.get_or_create_node (next_point, *new_state, this);
/* Create custom exploded_edge for a longjmp. */
if (next)
{
exploded_edge *eedge
= eg.add_edge (const_cast<exploded_node *> (this), next, NULL,
new rewind_info_t (tmp_setjmp_record, longjmp_call));
/* For any diagnostics that were queued here (such as leaks) we want
the checker_path to show the rewinding events after the "final event"
so that the user sees where the longjmp is rewinding to (otherwise the
path is meaningless).
For example, we want to emit something like:
| NN | {
| NN | longjmp (env, 1);
| | ~~~~~~~~~~~~~~~~
| | |
| | (10) 'ptr' leaks here; was allocated at (7)
| | (11) rewinding from 'longjmp' in 'inner'...
|
<-------------+
|
'outer': event 12
|
| NN | i = setjmp(env);
| | ^~~~~~
| | |
| | (12) ...to 'setjmp' in 'outer' (saved at (2))
where the "final" event above is event (10), but we want to append
events (11) and (12) afterwards.
Do this by setting m_trailing_eedge on any diagnostics that were
just saved. */
unsigned num_diagnostics = dm->get_num_diagnostics ();
for (unsigned i = prev_num_diagnostics; i < num_diagnostics; i++)
{
saved_diagnostic *sd = dm->get_saved_diagnostic (i);
sd->m_trailing_eedge = eedge;
}
}
}
/* Subroutine of exploded_graph::process_node for finding the successors
of the supernode for a function exit basic block.
Ensure that pop_frame is called, potentially queuing diagnostics about
leaks. */
void
exploded_node::detect_leaks (exploded_graph &eg) const
{
LOG_FUNC_1 (eg.get_logger (), "EN: %i", m_index);
gcc_assert (get_point ().get_supernode ()->return_p ());
/* If we're not a "top-level" function, do nothing; pop_frame
will be called when handling the return superedge. */
if (get_point ().get_stack_depth () > 1)
return;
/* We have a "top-level" function. */
gcc_assert (get_point ().get_stack_depth () == 1);
const program_state &old_state = get_state ();
/* Work with a temporary copy of the state: pop the frame, and see
what leaks (via purge_unused_svalues). */
program_state new_state (old_state);
gcc_assert (new_state.m_region_model);
impl_region_model_context ctxt (eg, this,
&old_state, &new_state,
get_stmt ());
const svalue *result = NULL;
new_state.m_region_model->pop_frame (NULL, &result, &ctxt);
program_state::detect_leaks (old_state, new_state, result,
eg.get_ext_state (), &ctxt);
}
/* Dump the successors and predecessors of this enode to OUTF. */
void
exploded_node::dump_succs_and_preds (FILE *outf) const
{
unsigned i;
exploded_edge *e;
{
auto_vec<exploded_node *> preds (m_preds.length ());
FOR_EACH_VEC_ELT (m_preds, i, e)
preds.quick_push (e->m_src);
pretty_printer pp;
print_enode_indices (&pp, preds);
fprintf (outf, "preds: %s\n",
pp_formatted_text (&pp));
}
{
auto_vec<exploded_node *> succs (m_succs.length ());
FOR_EACH_VEC_ELT (m_succs, i, e)
succs.quick_push (e->m_dest);
pretty_printer pp;
print_enode_indices (&pp, succs);
fprintf (outf, "succs: %s\n",
pp_formatted_text (&pp));
}
}
/* class rewind_info_t : public exploded_edge::custom_info_t. */
/* Implementation of exploded_edge::custom_info_t::update_model vfunc
for rewind_info_t.
Update state for the special-case of a rewind of a longjmp
to a setjmp (which doesn't have a superedge, but does affect
state). */
void
rewind_info_t::update_model (region_model *model,
const exploded_edge &eedge)
{
const program_point &longjmp_point = eedge.m_src->get_point ();
const program_point &setjmp_point = eedge.m_dest->get_point ();
gcc_assert (longjmp_point.get_stack_depth ()
>= setjmp_point.get_stack_depth ());
model->on_longjmp (get_longjmp_call (),
get_setjmp_call (),
setjmp_point.get_stack_depth (), NULL);
}
/* Implementation of exploded_edge::custom_info_t::add_events_to_path vfunc
for rewind_info_t. */
void
rewind_info_t::add_events_to_path (checker_path *emission_path,
const exploded_edge &eedge)
{
const exploded_node *src_node = eedge.m_src;
const program_point &src_point = src_node->get_point ();
const int src_stack_depth = src_point.get_stack_depth ();
const exploded_node *dst_node = eedge.m_dest;
const program_point &dst_point = dst_node->get_point ();
const int dst_stack_depth = dst_point.get_stack_depth ();
emission_path->add_event
(new rewind_from_longjmp_event
(&eedge, get_longjmp_call ()->location,
src_point.get_fndecl (),
src_stack_depth, this));
emission_path->add_event
(new rewind_to_setjmp_event
(&eedge, get_setjmp_call ()->location,
dst_point.get_fndecl (),
dst_stack_depth, this));
}
/* class exploded_edge : public dedge<eg_traits>. */
/* exploded_edge's ctor. */
exploded_edge::exploded_edge (exploded_node *src, exploded_node *dest,
const superedge *sedge,
custom_info_t *custom_info)
: dedge<eg_traits> (src, dest), m_sedge (sedge),
m_custom_info (custom_info)
{
}
/* exploded_edge's dtor. */
exploded_edge::~exploded_edge ()
{
delete m_custom_info;
}
/* Implementation of dedge::dump_dot vfunc for exploded_edge.
Use the label of the underlying superedge, if any. */
void
exploded_edge::dump_dot (graphviz_out *gv, const dump_args_t &) const
{
pretty_printer *pp = gv->get_pp ();
m_src->dump_dot_id (pp);
pp_string (pp, " -> ");
m_dest->dump_dot_id (pp);
dump_dot_label (pp);
}
/* Second half of exploded_edge::dump_dot. This is split out
for use by trimmed_graph::dump_dot and base_feasible_edge::dump_dot. */
void
exploded_edge::dump_dot_label (pretty_printer *pp) const
{
const char *style = "\"solid,bold\"";
const char *color = "black";
int weight = 10;
const char *constraint = "true";
if (m_sedge)
switch (m_sedge->m_kind)
{
default:
gcc_unreachable ();
case SUPEREDGE_CFG_EDGE:
break;
case SUPEREDGE_CALL:
color = "red";
//constraint = "false";
break;
case SUPEREDGE_RETURN:
color = "green";
//constraint = "false";
break;
case SUPEREDGE_INTRAPROCEDURAL_CALL:
style = "\"dotted\"";
break;
}
if (m_custom_info)
{
color = "red";
style = "\"dotted\"";
}
pp_printf (pp,
(" [style=%s, color=%s, weight=%d, constraint=%s,"
" headlabel=\""),
style, color, weight, constraint);
if (m_sedge)
m_sedge->dump_label_to_pp (pp, false);
else if (m_custom_info)
m_custom_info->print (pp);
//pp_write_text_as_dot_label_to_stream (pp, /*for_record=*/false);
pp_printf (pp, "\"];\n");
}
/* Return a new json::object of the form
{"src_idx": int, the index of the source exploded edge,
"dst_idx": int, the index of the destination exploded edge,
"sedge": (optional) object for the superedge, if any,
"custom": (optional) str, a description, if this is a custom edge}. */
json::object *
exploded_edge::to_json () const
{
json::object *eedge_obj = new json::object ();
eedge_obj->set ("src_idx", new json::integer_number (m_src->m_index));
eedge_obj->set ("dst_idx", new json::integer_number (m_dest->m_index));
if (m_sedge)
eedge_obj->set ("sedge", m_sedge->to_json ());
if (m_custom_info)
{
pretty_printer pp;
pp_format_decoder (&pp) = default_tree_printer;
m_custom_info->print (&pp);
eedge_obj->set ("custom", new json::string (pp_formatted_text (&pp)));
}
return eedge_obj;
}
/* struct stats. */
/* stats' ctor. */
stats::stats (int num_supernodes)
: m_node_reuse_count (0),
m_node_reuse_after_merge_count (0),
m_num_supernodes (num_supernodes)
{
for (int i = 0; i < NUM_POINT_KINDS; i++)
m_num_nodes[i] = 0;
}
/* Log these stats in multiline form to LOGGER. */
void
stats::log (logger *logger) const
{
gcc_assert (logger);
for (int i = 0; i < NUM_POINT_KINDS; i++)
if (m_num_nodes[i] > 0)
logger->log ("m_num_nodes[%s]: %i",
point_kind_to_string (static_cast <enum point_kind> (i)),
m_num_nodes[i]);
logger->log ("m_node_reuse_count: %i", m_node_reuse_count);
logger->log ("m_node_reuse_after_merge_count: %i",
m_node_reuse_after_merge_count);
}
/* Dump these stats in multiline form to OUT. */
void
stats::dump (FILE *out) const
{
for (int i = 0; i < NUM_POINT_KINDS; i++)
if (m_num_nodes[i] > 0)
fprintf (out, "m_num_nodes[%s]: %i\n",
point_kind_to_string (static_cast <enum point_kind> (i)),
m_num_nodes[i]);
fprintf (out, "m_node_reuse_count: %i\n", m_node_reuse_count);
fprintf (out, "m_node_reuse_after_merge_count: %i\n",
m_node_reuse_after_merge_count);
if (m_num_supernodes > 0)
fprintf (out, "PK_AFTER_SUPERNODE nodes per supernode: %.2f\n",
(float)m_num_nodes[PK_AFTER_SUPERNODE] / (float)m_num_supernodes);
}
/* Return the total number of enodes recorded within this object. */
int
stats::get_total_enodes () const
{
int result = 0;
for (int i = 0; i < NUM_POINT_KINDS; i++)
result += m_num_nodes[i];
return result;
}
/* strongly_connected_components's ctor. Tarjan's SCC algorithm. */
strongly_connected_components::
strongly_connected_components (const supergraph &sg, logger *logger)
: m_sg (sg), m_per_node (m_sg.num_nodes ())
{
LOG_SCOPE (logger);
auto_timevar tv (TV_ANALYZER_SCC);
for (int i = 0; i < m_sg.num_nodes (); i++)
m_per_node.quick_push (per_node_data ());
for (int i = 0; i < m_sg.num_nodes (); i++)
if (m_per_node[i].m_index == -1)
strong_connect (i);
if (0)
dump ();
}
/* Dump this object to stderr. */
DEBUG_FUNCTION void
strongly_connected_components::dump () const
{
for (int i = 0; i < m_sg.num_nodes (); i++)
{
const per_node_data &v = m_per_node[i];
fprintf (stderr, "SN %i: index: %i lowlink: %i on_stack: %i\n",
i, v.m_index, v.m_lowlink, v.m_on_stack);
}
}
/* Return a new json::array of per-snode SCC ids. */
json::array *
strongly_connected_components::to_json () const
{
json::array *scc_arr = new json::array ();
for (int i = 0; i < m_sg.num_nodes (); i++)
scc_arr->append (new json::integer_number (get_scc_id (i)));
return scc_arr;
}
/* Subroutine of strongly_connected_components's ctor, part of Tarjan's
SCC algorithm. */
void
strongly_connected_components::strong_connect (unsigned index)
{
supernode *v_snode = m_sg.get_node_by_index (index);
/* Set the depth index for v to the smallest unused index. */
per_node_data *v = &m_per_node[index];
v->m_index = index;
v->m_lowlink = index;
m_stack.safe_push (index);
v->m_on_stack = true;
index++;
/* Consider successors of v. */
unsigned i;
superedge *sedge;
FOR_EACH_VEC_ELT (v_snode->m_succs, i, sedge)
{
if (sedge->get_kind () != SUPEREDGE_CFG_EDGE
&& sedge->get_kind () != SUPEREDGE_INTRAPROCEDURAL_CALL)
continue;
supernode *w_snode = sedge->m_dest;
per_node_data *w = &m_per_node[w_snode->m_index];
if (w->m_index == -1)
{
/* Successor w has not yet been visited; recurse on it. */
strong_connect (w_snode->m_index);
v->m_lowlink = MIN (v->m_lowlink, w->m_lowlink);
}
else if (w->m_on_stack)
{
/* Successor w is in stack S and hence in the current SCC
If w is not on stack, then (v, w) is a cross-edge in the DFS
tree and must be ignored. */
v->m_lowlink = MIN (v->m_lowlink, w->m_index);
}
}
/* If v is a root node, pop the stack and generate an SCC. */
if (v->m_lowlink == v->m_index)
{
per_node_data *w;
do {
int idx = m_stack.pop ();
w = &m_per_node[idx];
w->m_on_stack = false;
} while (w != v);
}
}
/* worklist's ctor. */
worklist::worklist (const exploded_graph &eg, const analysis_plan &plan)
: m_scc (eg.get_supergraph (), eg.get_logger ()),
m_plan (plan),
m_queue (key_t (*this, NULL))
{
}
/* Return the number of nodes in the worklist. */
unsigned
worklist::length () const
{
return m_queue.nodes ();
}
/* Return the next node in the worklist, removing it. */
exploded_node *
worklist::take_next ()
{
return m_queue.extract_min ();
}
/* Return the next node in the worklist without removing it. */
exploded_node *
worklist::peek_next ()
{
return m_queue.min ();
}
/* Add ENODE to the worklist. */
void
worklist::add_node (exploded_node *enode)
{
gcc_assert (enode->get_status () == exploded_node::STATUS_WORKLIST);
m_queue.insert (key_t (*this, enode), enode);
}
/* Comparator for implementing worklist::key_t comparison operators.
Return negative if KA is before KB
Return positive if KA is after KB
Return 0 if they are equal.
The ordering of the worklist is critical for performance and for
avoiding node explosions. Ideally we want all enodes at a CFG join-point
with the same callstring to be sorted next to each other in the worklist
so that a run of consecutive enodes can be merged and processed "in bulk"
rather than individually or pairwise, minimizing the number of new enodes
created. */
int
worklist::key_t::cmp (const worklist::key_t &ka, const worklist::key_t &kb)
{
const program_point &point_a = ka.m_enode->get_point ();
const program_point &point_b = kb.m_enode->get_point ();
const call_string &call_string_a = point_a.get_call_string ();
const call_string &call_string_b = point_b.get_call_string ();
/* Order empty-callstring points with different functions based on the
analysis_plan, so that we generate summaries before they are used. */
if (flag_analyzer_call_summaries
&& call_string_a.empty_p ()
&& call_string_b.empty_p ()
&& point_a.get_function () != NULL
&& point_b.get_function () != NULL
&& point_a.get_function () != point_b.get_function ())
{
if (int cmp = ka.m_worklist.m_plan.cmp_function (point_a.get_function (),
point_b.get_function ()))
return cmp;
}
/* First, order by SCC. */
int scc_id_a = ka.get_scc_id (ka.m_enode);
int scc_id_b = kb.get_scc_id (kb.m_enode);
if (scc_id_a != scc_id_b)
return scc_id_a - scc_id_b;
/* If in same SCC, order by supernode index (an arbitrary but stable
ordering). */
const supernode *snode_a = ka.m_enode->get_supernode ();
const supernode *snode_b = kb.m_enode->get_supernode ();
if (snode_a == NULL)
{
if (snode_b != NULL)
/* One is NULL. */
return -1;
else
/* Both are NULL. */
return 0;
}
if (snode_b == NULL)
/* One is NULL. */
return 1;
/* Neither are NULL. */
gcc_assert (snode_a && snode_b);
if (snode_a->m_index != snode_b->m_index)
return snode_a->m_index - snode_b->m_index;
gcc_assert (snode_a == snode_b);
/* The points might vary by callstring; try sorting by callstring. */
int cs_cmp = call_string::cmp (call_string_a, call_string_b);
if (cs_cmp)
return cs_cmp;
/* Order within supernode via program point. */
int within_snode_cmp
= function_point::cmp_within_supernode (point_a.get_function_point (),
point_b.get_function_point ());
if (within_snode_cmp)
return within_snode_cmp;
/* Otherwise, we ought to have the same program_point. */
gcc_assert (point_a == point_b);
const program_state &state_a = ka.m_enode->get_state ();
const program_state &state_b = kb.m_enode->get_state ();
/* Sort by sm-state, so that identical sm-states are grouped
together in the worklist. */
for (unsigned sm_idx = 0; sm_idx < state_a.m_checker_states.length ();
++sm_idx)
{
sm_state_map *smap_a = state_a.m_checker_states[sm_idx];
sm_state_map *smap_b = state_b.m_checker_states[sm_idx];
if (int smap_cmp = sm_state_map::cmp (*smap_a, *smap_b))
return smap_cmp;
}
/* Otherwise, we have two enodes at the same program point but with
different states. We don't have a good total ordering on states,
so order them by enode index, so that we have at least have a
stable sort. */
return ka.m_enode->m_index - kb.m_enode->m_index;
}
/* Return a new json::object of the form
{"scc" : [per-snode-IDs]}, */
json::object *
worklist::to_json () const
{
json::object *worklist_obj = new json::object ();
worklist_obj->set ("scc", m_scc.to_json ());
/* The following field isn't yet being JSONified:
queue_t m_queue; */
return worklist_obj;
}
/* exploded_graph's ctor. */
exploded_graph::exploded_graph (const supergraph &sg, logger *logger,
const extrinsic_state &ext_state,
const state_purge_map *purge_map,
const analysis_plan &plan,
int verbosity)
: m_sg (sg), m_logger (logger),
m_worklist (*this, plan),
m_ext_state (ext_state),
m_purge_map (purge_map),
m_plan (plan),
m_diagnostic_manager (logger, ext_state.get_engine (), verbosity),
m_global_stats (m_sg.num_nodes ()),
m_functionless_stats (m_sg.num_nodes ()),
m_PK_AFTER_SUPERNODE_per_snode (m_sg.num_nodes ())
{
m_origin = get_or_create_node (program_point::origin (),
program_state (ext_state), NULL);
for (int i = 0; i < m_sg.num_nodes (); i++)
m_PK_AFTER_SUPERNODE_per_snode.quick_push (i);
}
/* exploded_graph's dtor. */
exploded_graph::~exploded_graph ()
{
for (function_stat_map_t::iterator iter = m_per_function_stats.begin ();
iter != m_per_function_stats.end ();
++iter)
delete (*iter).second;
for (point_map_t::iterator iter = m_per_point_data.begin ();
iter != m_per_point_data.end ();
++iter)
delete (*iter).second;
}
/* Ensure that there is an exploded_node representing an external call to
FUN, adding it to the worklist if creating it.
Add an edge from the origin exploded_node to the function entrypoint
exploded_node.
Return the exploded_node for the entrypoint to the function. */
exploded_node *
exploded_graph::add_function_entry (function *fun)
{
gcc_assert (gimple_has_body_p (fun->decl));
/* Be idempotent. */
if (m_functions_with_enodes.contains (fun))
{
logger * const logger = get_logger ();
if (logger)
logger->log ("entrypoint for %qE already exists", fun->decl);
return NULL;
}
program_point point = program_point::from_function_entry (m_sg, fun);
program_state state (m_ext_state);
state.push_frame (m_ext_state, fun);
if (!state.m_valid)
return NULL;
exploded_node *enode = get_or_create_node (point, state, NULL);
if (!enode)
return NULL;
add_edge (m_origin, enode, NULL);
m_functions_with_enodes.add (fun);
return enode;
}
/* Get or create an exploded_node for (POINT, STATE).
If a new node is created, it is added to the worklist.
Use ENODE_FOR_DIAG, a pre-existing enode, for any diagnostics
that need to be emitted (e.g. when purging state *before* we have
a new enode). */
exploded_node *
exploded_graph::get_or_create_node (const program_point &point,
const program_state &state,
const exploded_node *enode_for_diag)
{
logger * const logger = get_logger ();
LOG_FUNC (logger);
if (logger)
{
format f (false);
pretty_printer *pp = logger->get_printer ();
logger->start_log_line ();
pp_string (pp, "point: ");
point.print (pp, f);
logger->end_log_line ();
logger->start_log_line ();
pp_string (pp, "state: ");
state.dump_to_pp (m_ext_state, true, false, pp);
logger->end_log_line ();
}
/* Stop exploring paths for which we don't know how to effectively
model the state. */
if (!state.m_valid)
{
if (logger)
logger->log ("invalid state; not creating node");
return NULL;
}
auto_cfun sentinel (point.get_function ());
state.validate (get_ext_state ());
//state.dump (get_ext_state ());
/* Prune state to try to improve the chances of a cache hit,
avoiding generating redundant nodes. */
program_state pruned_state
= state.prune_for_point (*this, point, enode_for_diag);
pruned_state.validate (get_ext_state ());
//pruned_state.dump (get_ext_state ());
if (logger)
{
pretty_printer *pp = logger->get_printer ();
logger->start_log_line ();
pp_string (pp, "pruned_state: ");
pruned_state.dump_to_pp (m_ext_state, true, false, pp);
logger->end_log_line ();
pruned_state.m_region_model->dump_to_pp (logger->get_printer (), true,
false);
}
stats *per_fn_stats = get_or_create_function_stats (point.get_function ());
stats *per_cs_stats
= &get_or_create_per_call_string_data (point.get_call_string ())->m_stats;
point_and_state ps (point, pruned_state);
ps.validate (m_ext_state);
if (exploded_node **slot = m_point_and_state_to_node.get (&ps))
{
/* An exploded_node for PS already exists. */
if (logger)
logger->log ("reused EN: %i", (*slot)->m_index);
m_global_stats.m_node_reuse_count++;
per_fn_stats->m_node_reuse_count++;
per_cs_stats->m_node_reuse_count++;
return *slot;
}
per_program_point_data *per_point_data
= get_or_create_per_program_point_data (point);
/* Consider merging state with another enode at this program_point. */
if (flag_analyzer_state_merge)
{
exploded_node *existing_enode;
unsigned i;
FOR_EACH_VEC_ELT (per_point_data->m_enodes, i, existing_enode)
{
if (logger)
logger->log ("considering merging with existing EN: %i for point",
existing_enode->m_index);
gcc_assert (existing_enode->get_point () == point);
const program_state &existing_state = existing_enode->get_state ();
/* This merges successfully within the loop. */
program_state merged_state (m_ext_state);
if (pruned_state.can_merge_with_p (existing_state, point,
&merged_state))
{
if (logger)
logger->log ("merging new state with that of EN: %i",
existing_enode->m_index);
/* Try again for a cache hit.
Whether we get one or not, merged_state's value_ids have no
relationship to those of the input state, and thus to those
of CHANGE, so we must purge any svalue_ids from *CHANGE. */
ps.set_state (merged_state);
if (exploded_node **slot = m_point_and_state_to_node.get (&ps))
{
/* An exploded_node for PS already exists. */
if (logger)
logger->log ("reused EN: %i", (*slot)->m_index);
m_global_stats.m_node_reuse_after_merge_count++;
per_fn_stats->m_node_reuse_after_merge_count++;
per_cs_stats->m_node_reuse_after_merge_count++;
return *slot;
}
}
else
if (logger)
logger->log ("not merging new state with that of EN: %i",
existing_enode->m_index);
}
}
/* Impose a limit on the number of enodes per program point, and
simply stop if we exceed it. */
if ((int)per_point_data->m_enodes.length ()
>= param_analyzer_max_enodes_per_program_point)
{
pretty_printer pp;
point.print (&pp, format (false));
print_enode_indices (&pp, per_point_data->m_enodes);
if (logger)
logger->log ("not creating enode; too many at program point: %s",
pp_formatted_text (&pp));
warning_at (point.get_location (), OPT_Wanalyzer_too_complex,
"terminating analysis for this program point: %s",
pp_formatted_text (&pp));
per_point_data->m_excess_enodes++;
return NULL;
}
ps.validate (m_ext_state);
/* An exploded_node for "ps" doesn't already exist; create one. */
exploded_node *node = new exploded_node (ps, m_nodes.length ());
add_node (node);
m_point_and_state_to_node.put (node->get_ps_key (), node);
/* Update per-program_point data. */
per_point_data->m_enodes.safe_push (node);
const enum point_kind node_pk = node->get_point ().get_kind ();
m_global_stats.m_num_nodes[node_pk]++;
per_fn_stats->m_num_nodes[node_pk]++;
per_cs_stats->m_num_nodes[node_pk]++;
if (node_pk == PK_AFTER_SUPERNODE)
m_PK_AFTER_SUPERNODE_per_snode[point.get_supernode ()->m_index]++;
if (logger)
{
format f (false);
pretty_printer *pp = logger->get_printer ();
logger->log ("created EN: %i", node->m_index);
logger->start_log_line ();
pp_string (pp, "point: ");
point.print (pp, f);
logger->end_log_line ();
logger->start_log_line ();
pp_string (pp, "pruned_state: ");
pruned_state.dump_to_pp (m_ext_state, true, false, pp);
logger->end_log_line ();
}
/* Add the new node to the worlist. */
m_worklist.add_node (node);
return node;
}
/* Add an exploded_edge from SRC to DEST, recording its association
with SEDGE (which may be NULL), and, if non-NULL, taking ownership
of REWIND_INFO.
Return the newly-created eedge. */
exploded_edge *
exploded_graph::add_edge (exploded_node *src, exploded_node *dest,
const superedge *sedge,
exploded_edge::custom_info_t *custom_info)
{
if (get_logger ())
get_logger ()->log ("creating edge EN: %i -> EN: %i",
src->m_index, dest->m_index);
exploded_edge *e = new exploded_edge (src, dest, sedge, custom_info);
digraph<eg_traits>::add_edge (e);
return e;
}
/* Ensure that this graph has per-program_point-data for POINT;
borrow a pointer to it. */
per_program_point_data *
exploded_graph::
get_or_create_per_program_point_data (const program_point &point)
{
if (per_program_point_data **slot = m_per_point_data.get (&point))
return *slot;
per_program_point_data *per_point_data = new per_program_point_data (point);
m_per_point_data.put (&per_point_data->m_key, per_point_data);
return per_point_data;
}
/* Get this graph's per-program-point-data for POINT if there is any,
otherwise NULL. */
per_program_point_data *
exploded_graph::get_per_program_point_data (const program_point &point) const
{
if (per_program_point_data **slot
= const_cast <point_map_t &> (m_per_point_data).get (&point))
return *slot;
return NULL;
}
/* Ensure that this graph has per-call_string-data for CS;
borrow a pointer to it. */
per_call_string_data *
exploded_graph::get_or_create_per_call_string_data (const call_string &cs)
{
if (per_call_string_data **slot = m_per_call_string_data.get (&cs))
return *slot;
per_call_string_data *data = new per_call_string_data (cs, m_sg.num_nodes ());
m_per_call_string_data.put (&data->m_key,
data);
return data;
}
/* Ensure that this graph has per-function-data for FUN;
borrow a pointer to it. */
per_function_data *
exploded_graph::get_or_create_per_function_data (function *fun)
{
if (per_function_data **slot = m_per_function_data.get (fun))
return *slot;
per_function_data *data = new per_function_data ();
m_per_function_data.put (fun, data);
return data;
}
/* Get this graph's per-function-data for FUN if there is any,
otherwise NULL. */
per_function_data *
exploded_graph::get_per_function_data (function *fun) const
{
if (per_function_data **slot
= const_cast <per_function_data_t &> (m_per_function_data).get (fun))
return *slot;
return NULL;
}
/* Return true if FUN should be traversed directly, rather than only as
called via other functions. */
static bool
toplevel_function_p (function *fun, logger *logger)
{
/* Don't directly traverse into functions that have an "__analyzer_"
prefix. Doing so is useful for the analyzer test suite, allowing
us to have functions that are called in traversals, but not directly
explored, thus testing how the analyzer handles calls and returns.
With this, we can have DejaGnu directives that cover just the case
of where a function is called by another function, without generating
excess messages from the case of the first function being traversed
directly. */
#define ANALYZER_PREFIX "__analyzer_"
if (!strncmp (IDENTIFIER_POINTER (DECL_NAME (fun->decl)), ANALYZER_PREFIX,
strlen (ANALYZER_PREFIX)))
{
if (logger)
logger->log ("not traversing %qE (starts with %qs)",
fun->decl, ANALYZER_PREFIX);
return false;
}
if (logger)
logger->log ("traversing %qE (all checks passed)", fun->decl);
return true;
}
/* Add initial nodes to EG, with entrypoints for externally-callable
functions. */
void
exploded_graph::build_initial_worklist ()
{
logger * const logger = get_logger ();
LOG_SCOPE (logger);
cgraph_node *node;
FOR_EACH_FUNCTION_WITH_GIMPLE_BODY (node)
{
function *fun = node->get_fun ();
if (!toplevel_function_p (fun, logger))
continue;
exploded_node *enode = add_function_entry (fun);
if (logger)
{
if (enode)
logger->log ("created EN %i for %qE entrypoint",
enode->m_index, fun->decl);
else
logger->log ("did not create enode for %qE entrypoint", fun->decl);
}
}
}
/* The main loop of the analysis.
Take freshly-created exploded_nodes from the worklist, calling
process_node on them to explore the <point, state> graph.
Add edges to their successors, potentially creating new successors
(which are also added to the worklist). */
void
exploded_graph::process_worklist ()
{
logger * const logger = get_logger ();
LOG_SCOPE (logger);
auto_timevar tv (TV_ANALYZER_WORKLIST);
while (m_worklist.length () > 0)
{
exploded_node *node = m_worklist.take_next ();
gcc_assert (node->get_status () == exploded_node::STATUS_WORKLIST);
gcc_assert (node->m_succs.length () == 0
|| node == m_origin);
if (logger)
logger->log ("next to process: EN: %i", node->m_index);
/* If we have a run of nodes that are before-supernode, try merging and
processing them together, rather than pairwise or individually. */
if (flag_analyzer_state_merge && node != m_origin)
if (maybe_process_run_of_before_supernode_enodes (node))
goto handle_limit;
/* Avoid exponential explosions of nodes by attempting to merge
nodes that are at the same program point and which have
sufficiently similar state. */
if (flag_analyzer_state_merge && node != m_origin)
if (exploded_node *node_2 = m_worklist.peek_next ())
{
gcc_assert (node_2->get_status ()
== exploded_node::STATUS_WORKLIST);
gcc_assert (node->m_succs.length () == 0);
gcc_assert (node_2->m_succs.length () == 0);
gcc_assert (node != node_2);
if (logger)
logger->log ("peek worklist: EN: %i", node_2->m_index);
if (node->get_point () == node_2->get_point ())
{
const program_point &point = node->get_point ();
if (logger)
{
format f (false);
pretty_printer *pp = logger->get_printer ();
logger->start_log_line ();
logger->log_partial
("got potential merge EN: %i and EN: %i at ",
node->m_index, node_2->m_index);
point.print (pp, f);
logger->end_log_line ();
}
const program_state &state = node->get_state ();
const program_state &state_2 = node_2->get_state ();
/* They shouldn't be equal, or we wouldn't have two
separate nodes. */
gcc_assert (state != state_2);
program_state merged_state (m_ext_state);
if (state.can_merge_with_p (state_2, point, &merged_state))
{
if (logger)
logger->log ("merging EN: %i and EN: %i",
node->m_index, node_2->m_index);
if (merged_state == state)
{
/* Then merge node_2 into node by adding an edge. */
add_edge (node_2, node, NULL);
/* Remove node_2 from the worklist. */
m_worklist.take_next ();
node_2->set_status (exploded_node::STATUS_MERGER);
/* Continue processing "node" below. */
}
else if (merged_state == state_2)
{
/* Then merge node into node_2, and leave node_2
in the worklist, to be processed on the next
iteration. */
add_edge (node, node_2, NULL);
node->set_status (exploded_node::STATUS_MERGER);
continue;
}
else
{
/* We have a merged state that differs from
both state and state_2. */
/* Remove node_2 from the worklist. */
m_worklist.take_next ();
/* Create (or get) an exploded node for the merged
states, adding to the worklist. */
exploded_node *merged_enode
= get_or_create_node (node->get_point (),
merged_state, node);
if (merged_enode == NULL)
continue;
if (logger)
logger->log ("merged EN: %i and EN: %i into EN: %i",
node->m_index, node_2->m_index,
merged_enode->m_index);
/* "node" and "node_2" have both now been removed
from the worklist; we should not process them.
"merged_enode" may be a new node; if so it will be
processed in a subsequent iteration.
Alternatively, "merged_enode" could be an existing
node; one way the latter can
happen is if we end up merging a succession of
similar nodes into one. */
/* If merged_node is one of the two we were merging,
add it back to the worklist to ensure it gets
processed.
Add edges from the merged nodes to it (but not a
self-edge). */
if (merged_enode == node)
m_worklist.add_node (merged_enode);
else
{
add_edge (node, merged_enode, NULL);
node->set_status (exploded_node::STATUS_MERGER);
}
if (merged_enode == node_2)
m_worklist.add_node (merged_enode);
else
{
add_edge (node_2, merged_enode, NULL);
node_2->set_status (exploded_node::STATUS_MERGER);
}
continue;
}
}
/* TODO: should we attempt more than two nodes,
or just do pairs of nodes? (and hope that we get
a cascade of mergers). */
}
}
process_node (node);
handle_limit:
/* Impose a hard limit on the number of exploded nodes, to ensure
that the analysis terminates in the face of pathological state
explosion (or bugs).
Specifically, the limit is on the number of PK_AFTER_SUPERNODE
exploded nodes, looking at supernode exit events.
We use exit rather than entry since there can be multiple
entry ENs, one per phi; the number of PK_AFTER_SUPERNODE ought
to be equivalent to the number of supernodes multiplied by the
number of states. */
const int limit = m_sg.num_nodes () * param_analyzer_bb_explosion_factor;
if (m_global_stats.m_num_nodes[PK_AFTER_SUPERNODE] > limit)
{
if (logger)
logger->log ("bailing out; too many nodes");
warning_at (node->get_point ().get_location (),
OPT_Wanalyzer_too_complex,
"analysis bailed out early"
" (%i 'after-snode' enodes; %i enodes)",
m_global_stats.m_num_nodes[PK_AFTER_SUPERNODE],
m_nodes.length ());
return;
}
}
}
/* Attempt to process a consecutive run of sufficiently-similar nodes in
the worklist at a CFG join-point (having already popped ENODE from the
head of the worklist).
If ENODE's point is of the form (before-supernode, SNODE) and the next
nodes in the worklist are a consecutive run of enodes of the same form,
for the same supernode as ENODE (but potentially from different in-edges),
process them all together, setting their status to STATUS_BULK_MERGED,
and return true.
Otherwise, return false, in which case ENODE must be processed in the
normal way.
When processing them all together, generate successor states based
on phi nodes for the appropriate CFG edges, and then attempt to merge
these states into a minimal set of merged successor states, partitioning
the inputs by merged successor state.
Create new exploded nodes for all of the merged states, and add edges
connecting the input enodes to the corresponding merger exploded nodes.
We hope we have a much smaller number of merged successor states
compared to the number of input enodes - ideally just one,
if all successor states can be merged.
Processing and merging many together as one operation rather than as
pairs avoids scaling issues where per-pair mergers could bloat the
graph with merger nodes (especially so after switch statements). */
bool
exploded_graph::
maybe_process_run_of_before_supernode_enodes (exploded_node *enode)
{
/* A struct for tracking per-input state. */
struct item
{
item (exploded_node *input_enode)
: m_input_enode (input_enode),
m_processed_state (input_enode->get_state ()),
m_merger_idx (-1)
{}
exploded_node *m_input_enode;
program_state m_processed_state;
int m_merger_idx;
};
gcc_assert (enode->get_status () == exploded_node::STATUS_WORKLIST);
gcc_assert (enode->m_succs.length () == 0);
const program_point &point = enode->get_point ();
if (point.get_kind () != PK_BEFORE_SUPERNODE)
return false;
const supernode *snode = point.get_supernode ();
logger * const logger = get_logger ();
LOG_SCOPE (logger);
/* Find a run of enodes in the worklist that are before the same supernode,
but potentially from different in-edges. */
auto_vec <exploded_node *> enodes;
enodes.safe_push (enode);
while (exploded_node *enode_2 = m_worklist.peek_next ())
{
gcc_assert (enode_2->get_status ()
== exploded_node::STATUS_WORKLIST);
gcc_assert (enode_2->m_succs.length () == 0);
const program_point &point_2 = enode_2->get_point ();
if (point_2.get_kind () == PK_BEFORE_SUPERNODE
&& point_2.get_supernode () == snode
&& point_2.get_call_string () == point.get_call_string ())
{
enodes.safe_push (enode_2);
m_worklist.take_next ();
}
else
break;
}
/* If the only node is ENODE, then give up. */
if (enodes.length () == 1)
return false;
if (logger)
logger->log ("got run of %i enodes for SN: %i",
enodes.length (), snode->m_index);
/* All of these enodes have a shared successor point (even if they
were for different in-edges). */
program_point next_point (point.get_next ());
/* Calculate the successor state for each enode in enodes. */
auto_delete_vec<item> items (enodes.length ());
unsigned i;
exploded_node *iter_enode;
FOR_EACH_VEC_ELT (enodes, i, iter_enode)
{
item *it = new item (iter_enode);
items.quick_push (it);
const program_state &state = iter_enode->get_state ();
program_state *next_state = &it->m_processed_state;
const program_point &iter_point = iter_enode->get_point ();
if (const superedge *iter_sedge = iter_point.get_from_edge ())
{
impl_region_model_context ctxt (*this, iter_enode,
&state, next_state, NULL);
const cfg_superedge *last_cfg_superedge
= iter_sedge->dyn_cast_cfg_superedge ();
if (last_cfg_superedge)
next_state->m_region_model->update_for_phis
(snode, last_cfg_superedge, &ctxt);
}
}
/* Attempt to partition the items into a set of merged states.
We hope we have a much smaller number of merged states
compared to the number of input enodes - ideally just one,
if all can be merged. */
auto_delete_vec <program_state> merged_states;
auto_vec<item *> first_item_for_each_merged_state;
item *it;
FOR_EACH_VEC_ELT (items, i, it)
{
const program_state &it_state = it->m_processed_state;
program_state *merged_state;
unsigned iter_merger_idx;
FOR_EACH_VEC_ELT (merged_states, iter_merger_idx, merged_state)
{
program_state merge (m_ext_state);
if (it_state.can_merge_with_p (*merged_state, next_point, &merge))
{
*merged_state = merge;
it->m_merger_idx = iter_merger_idx;
if (logger)
logger->log ("reusing merger state %i for item %i (EN: %i)",
it->m_merger_idx, i, it->m_input_enode->m_index);
goto got_merger;
}
}
/* If it couldn't be merged with any existing merged_states,
create a new one. */
if (it->m_merger_idx == -1)
{
it->m_merger_idx = merged_states.length ();
merged_states.safe_push (new program_state (it_state));
first_item_for_each_merged_state.safe_push (it);
if (logger)
logger->log ("using new merger state %i for item %i (EN: %i)",
it->m_merger_idx, i, it->m_input_enode->m_index);
}
got_merger:
gcc_assert (it->m_merger_idx >= 0);
gcc_assert ((unsigned)it->m_merger_idx < merged_states.length ());
}
/* Create merger nodes. */
auto_vec<exploded_node *> next_enodes (merged_states.length ());
program_state *merged_state;
FOR_EACH_VEC_ELT (merged_states, i, merged_state)
{
exploded_node *src_enode
= first_item_for_each_merged_state[i]->m_input_enode;
exploded_node *next
= get_or_create_node (next_point, *merged_state, src_enode);
/* "next" could be NULL; we handle that when adding the edges below. */
next_enodes.quick_push (next);
if (logger)
{
if (next)
logger->log ("using EN: %i for merger state %i", next->m_index, i);
else
logger->log ("using NULL enode for merger state %i", i);
}
}
/* Create edges from each input enode to the appropriate successor enode.
Update the status of the now-processed input enodes. */
FOR_EACH_VEC_ELT (items, i, it)
{
exploded_node *next = next_enodes[it->m_merger_idx];
if (next)
add_edge (it->m_input_enode, next, NULL);
it->m_input_enode->set_status (exploded_node::STATUS_BULK_MERGED);
}
if (logger)
logger->log ("merged %i in-enodes into %i out-enode(s) at SN: %i",
items.length (), merged_states.length (), snode->m_index);
return true;
}
/* Return true if STMT must appear at the start of its exploded node, and
thus we can't consolidate its effects within a run of other statements,
where PREV_STMT was the previous statement. */
static bool
stmt_requires_new_enode_p (const gimple *stmt,
const gimple *prev_stmt)
{
if (const gcall *call = dyn_cast <const gcall *> (stmt))
{
/* Stop consolidating at calls to
"__analyzer_dump_exploded_nodes", so they always appear at the
start of an exploded_node. */
if (is_special_named_call_p (call, "__analyzer_dump_exploded_nodes",
1))
return true;
/* sm-signal.cc injects an additional custom eedge at "signal" calls
from the registration enode to the handler enode, separate from the
regular next state, which defeats the "detect state change" logic
in process_node. Work around this via special-casing, to ensure
we split the enode immediately before any "signal" call. */
if (is_special_named_call_p (call, "signal", 2))
return true;
}
/* If we had a PREV_STMT with an unknown location, and this stmt
has a known location, then if a state change happens here, it
could be consolidated into PREV_STMT, giving us an event with
no location. Ensure that STMT gets its own exploded_node to
avoid this. */
if (get_pure_location (prev_stmt->location) == UNKNOWN_LOCATION
&& get_pure_location (stmt->location) != UNKNOWN_LOCATION)
return true;
return false;
}
/* The core of exploded_graph::process_worklist (the main analysis loop),
handling one node in the worklist.
Get successor <point, state> pairs for NODE, calling get_or_create on
them, and adding an exploded_edge to each successors.
Freshly-created nodes will be added to the worklist. */
void
exploded_graph::process_node (exploded_node *node)
{
logger * const logger = get_logger ();
LOG_FUNC_1 (logger, "EN: %i", node->m_index);
node->set_status (exploded_node::STATUS_PROCESSED);
const program_point &point = node->get_point ();
/* Update cfun and input_location in case of an ICE: make it easier to
track down which source construct we're failing to handle. */
auto_cfun sentinel (node->get_function ());
const gimple *stmt = point.get_stmt ();
if (stmt)
input_location = stmt->location;
const program_state &state = node->get_state ();
if (logger)
{
pretty_printer *pp = logger->get_printer ();
logger->start_log_line ();
pp_string (pp, "point: ");
point.print (pp, format (false));
pp_string (pp, ", state: ");
state.dump_to_pp (m_ext_state, true, false, pp);
logger->end_log_line ();
}
switch (point.get_kind ())
{
default:
gcc_unreachable ();
case PK_ORIGIN:
/* This node exists to simplify finding the shortest path
to an exploded_node. */
break;
case PK_BEFORE_SUPERNODE:
{
program_state next_state (state);
if (point.get_from_edge ())
{
impl_region_model_context ctxt (*this, node,
&state, &next_state, NULL);
const cfg_superedge *last_cfg_superedge
= point.get_from_edge ()->dyn_cast_cfg_superedge ();
if (last_cfg_superedge)
next_state.m_region_model->update_for_phis
(node->get_supernode (),
last_cfg_superedge,
&ctxt);
}
program_point next_point (point.get_next ());
exploded_node *next = get_or_create_node (next_point, next_state, node);
if (next)
add_edge (node, next, NULL);
}
break;
case PK_BEFORE_STMT:
{
/* Determine the effect of a run of one or more statements
within one supernode, generating an edge to the program_point
after the last statement that's processed.
Stop iterating statements and thus consolidating into one enode
when:
- reaching the end of the statements in the supernode
- if an sm-state-change occurs (so that it gets its own
exploded_node)
- if "-fanalyzer-fine-grained" is active
- encountering certain statements must appear at the start of
their enode (for which stmt_requires_new_enode_p returns true)
Update next_state in-place, to get the result of the one
or more stmts that are processed.
Split the node in-place if an sm-state-change occurs, so that
the sm-state-change occurs on an edge where the src enode has
exactly one stmt, the one that caused the change. */
program_state next_state (state);
const supernode *snode = point.get_supernode ();
unsigned stmt_idx;
const gimple *prev_stmt = NULL;
for (stmt_idx = point.get_stmt_idx ();
stmt_idx < snode->m_stmts.length ();
stmt_idx++)
{
const gimple *stmt = snode->m_stmts[stmt_idx];
if (stmt_idx > point.get_stmt_idx ())
if (stmt_requires_new_enode_p (stmt, prev_stmt))
{
stmt_idx--;
break;
}
prev_stmt = stmt;
program_state old_state (next_state);
/* Process the stmt. */
exploded_node::on_stmt_flags flags
= node->on_stmt (*this, snode, stmt, &next_state);
node->m_num_processed_stmts++;
/* If flags.m_terminate_path, stop analyzing; any nodes/edges
will have been added by on_stmt (e.g. for handling longjmp). */
if (flags.m_terminate_path)
return;
if (next_state.m_region_model)
{
impl_region_model_context ctxt (*this, node,
&old_state, &next_state, stmt);
program_state::detect_leaks (old_state, next_state, NULL,
get_ext_state (), &ctxt);
}
unsigned next_idx = stmt_idx + 1;
program_point next_point
= (next_idx < point.get_supernode ()->m_stmts.length ()
? program_point::before_stmt (point.get_supernode (), next_idx,
point.get_call_string ())
: program_point::after_supernode (point.get_supernode (),
point.get_call_string ()));
next_state = next_state.prune_for_point (*this, next_point, node);
if (flags.m_sm_changes || flag_analyzer_fine_grained)
{
program_point split_point
= program_point::before_stmt (point.get_supernode (),
stmt_idx,
point.get_call_string ());
if (split_point != node->get_point ())
{
/* If we're not at the start of NODE, split the enode at
this stmt, so we have:
node -> split_enode
so that when split_enode is processed the next edge
we add will be:
split_enode -> next
and any state change will effectively occur on that
latter edge, and split_enode will contain just stmt. */
if (logger)
logger->log ("getting split_enode");
exploded_node *split_enode
= get_or_create_node (split_point, old_state, node);
if (!split_enode)
return;
/* "stmt" will be reprocessed when split_enode is
processed. */
node->m_num_processed_stmts--;
if (logger)
logger->log ("creating edge to split_enode");
add_edge (node, split_enode, NULL);
return;
}
else
/* If we're at the start of NODE, stop iterating,
so that an edge will be created from NODE to
(next_point, next_state) below. */
break;
}
}
unsigned next_idx = stmt_idx + 1;
program_point next_point
= (next_idx < point.get_supernode ()->m_stmts.length ()
? program_point::before_stmt (point.get_supernode (), next_idx,
point.get_call_string ())
: program_point::after_supernode (point.get_supernode (),
point.get_call_string ()));
exploded_node *next = get_or_create_node (next_point, next_state, node);
if (next)
add_edge (node, next, NULL);
}
break;
case PK_AFTER_SUPERNODE:
{
/* If this is an EXIT BB, detect leaks, and potentially
create a function summary. */
if (point.get_supernode ()->return_p ())
{
node->detect_leaks (*this);
if (flag_analyzer_call_summaries
&& point.get_call_string ().empty_p ())
{
/* TODO: create function summary
There can be more than one; each corresponds to a different
final enode in the function. */
if (logger)
{
pretty_printer *pp = logger->get_printer ();
logger->start_log_line ();
logger->log_partial
("would create function summary for %qE; state: ",
point.get_fndecl ());
state.dump_to_pp (m_ext_state, true, false, pp);
logger->end_log_line ();
}
per_function_data *per_fn_data
= get_or_create_per_function_data (point.get_function ());
per_fn_data->add_call_summary (node);
}
}
/* Traverse into successors of the supernode. */
int i;
superedge *succ;
FOR_EACH_VEC_ELT (point.get_supernode ()->m_succs, i, succ)
{
if (logger)
logger->log ("considering SN: %i -> SN: %i",
succ->m_src->m_index, succ->m_dest->m_index);
program_point next_point
= program_point::before_supernode (succ->m_dest, succ,
point.get_call_string ());
program_state next_state (state);
if (!node->on_edge (*this, succ, &next_point, &next_state))
{
if (logger)
logger->log ("skipping impossible edge to SN: %i",
succ->m_dest->m_index);
continue;
}
exploded_node *next = get_or_create_node (next_point, next_state,
node);
if (next)
add_edge (node, next, succ);
}
}
break;
}
}
/* Ensure that this graph has a stats instance for FN, return it.
FN can be NULL, in which case a stats instances is returned covering
"functionless" parts of the graph (the origin node). */
stats *
exploded_graph::get_or_create_function_stats (function *fn)
{
if (!fn)
return &m_functionless_stats;
if (stats **slot = m_per_function_stats.get (fn))
return *slot;
else
{
int num_supernodes = fn ? n_basic_blocks_for_fn (fn) : 0;
/* not quite the num supernodes, but nearly. */
stats *new_stats = new stats (num_supernodes);
m_per_function_stats.put (fn, new_stats);
return new_stats;
}
}
/* Print bar charts to PP showing:
- the number of enodes per function, and
- for each function:
- the number of enodes per supernode/BB
- the number of excess enodes per supernode/BB beyond the
per-program-point limit, if there were any. */
void
exploded_graph::print_bar_charts (pretty_printer *pp) const
{
cgraph_node *cgnode;
pp_string (pp, "enodes per function:");
pp_newline (pp);
bar_chart enodes_per_function;
FOR_EACH_FUNCTION_WITH_GIMPLE_BODY (cgnode)
{
function *fn = cgnode->get_fun ();
const stats * const *s_ptr
= const_cast <function_stat_map_t &> (m_per_function_stats).get (fn);
enodes_per_function.add_item (function_name (fn),
s_ptr ? (*s_ptr)->get_total_enodes () : 0);
}
enodes_per_function.print (pp);
/* Accumulate number of enodes per supernode. */
auto_vec<unsigned> enodes_per_supernode (m_sg.num_nodes ());
for (int i = 0; i < m_sg.num_nodes (); i++)
enodes_per_supernode.quick_push (0);
int i;
exploded_node *enode;
FOR_EACH_VEC_ELT (m_nodes, i, enode)
{
const supernode *iter_snode = enode->get_supernode ();
if (!iter_snode)
continue;
enodes_per_supernode[iter_snode->m_index]++;
}
/* Accumulate excess enodes per supernode. */
auto_vec<unsigned> excess_enodes_per_supernode (m_sg.num_nodes ());
for (int i = 0; i < m_sg.num_nodes (); i++)
excess_enodes_per_supernode.quick_push (0);
for (point_map_t::iterator iter = m_per_point_data.begin ();
iter != m_per_point_data.end (); ++iter)
{
const program_point *point = (*iter).first;
const supernode *iter_snode = point->get_supernode ();
if (!iter_snode)
continue;
const per_program_point_data *point_data = (*iter).second;
excess_enodes_per_supernode[iter_snode->m_index]
+= point_data->m_excess_enodes;
}
/* Show per-function bar_charts of enodes per supernode/BB. */
pp_string (pp, "per-function enodes per supernode/BB:");
pp_newline (pp);
FOR_EACH_FUNCTION_WITH_GIMPLE_BODY (cgnode)
{
function *fn = cgnode->get_fun ();
pp_printf (pp, "function: %qs", function_name (fn));
pp_newline (pp);
bar_chart enodes_per_snode;
bar_chart excess_enodes_per_snode;
bool have_excess_enodes = false;
for (int i = 0; i < m_sg.num_nodes (); i++)
{
const supernode *iter_snode = m_sg.get_node_by_index (i);
if (iter_snode->get_function () != fn)
continue;
pretty_printer tmp_pp;
pp_printf (&tmp_pp, "sn %i (bb %i)",
iter_snode->m_index, iter_snode->m_bb->index);
enodes_per_snode.add_item (pp_formatted_text (&tmp_pp),
enodes_per_supernode[iter_snode->m_index]);
const int num_excess
= excess_enodes_per_supernode[iter_snode->m_index];
excess_enodes_per_snode.add_item (pp_formatted_text (&tmp_pp),
num_excess);
if (num_excess)
have_excess_enodes = true;
}
enodes_per_snode.print (pp);
if (have_excess_enodes)
{
pp_printf (pp, "EXCESS ENODES:");
pp_newline (pp);
excess_enodes_per_snode.print (pp);
}
}
}
/* Write all stats information to this graph's logger, if any. */
void
exploded_graph::log_stats () const
{
logger * const logger = get_logger ();
if (!logger)
return;
LOG_SCOPE (logger);
m_ext_state.get_engine ()->log_stats (logger);
logger->log ("m_sg.num_nodes (): %i", m_sg.num_nodes ());
logger->log ("m_nodes.length (): %i", m_nodes.length ());
logger->log ("m_edges.length (): %i", m_edges.length ());
logger->log ("remaining enodes in worklist: %i", m_worklist.length ());
logger->log ("global stats:");
m_global_stats.log (logger);
for (function_stat_map_t::iterator iter = m_per_function_stats.begin ();
iter != m_per_function_stats.end ();
++iter)
{
function *fn = (*iter).first;
log_scope s (logger, function_name (fn));
(*iter).second->log (logger);
}
print_bar_charts (logger->get_printer ());
}
/* Dump all stats information to OUT. */
void
exploded_graph::dump_stats (FILE *out) const
{
fprintf (out, "m_sg.num_nodes (): %i\n", m_sg.num_nodes ());
fprintf (out, "m_nodes.length (): %i\n", m_nodes.length ());
fprintf (out, "m_edges.length (): %i\n", m_edges.length ());
fprintf (out, "remaining enodes in worklist: %i", m_worklist.length ());
fprintf (out, "global stats:\n");
m_global_stats.dump (out);
for (function_stat_map_t::iterator iter = m_per_function_stats.begin ();
iter != m_per_function_stats.end ();
++iter)
{
function *fn = (*iter).first;
fprintf (out, "function: %s\n", function_name (fn));
(*iter).second->dump (out);
}
fprintf (out, "PK_AFTER_SUPERNODE per supernode:\n");
for (unsigned i = 0; i < m_PK_AFTER_SUPERNODE_per_snode.length (); i++)
fprintf (out, " SN %i: %3i\n", i, m_PK_AFTER_SUPERNODE_per_snode[i]);
}
void
exploded_graph::dump_states_for_supernode (FILE *out,
const supernode *snode) const
{
fprintf (out, "PK_AFTER_SUPERNODE nodes for SN: %i\n", snode->m_index);
int i;
exploded_node *enode;
int state_idx = 0;
FOR_EACH_VEC_ELT (m_nodes, i, enode)
{
const supernode *iter_snode = enode->get_supernode ();
if (enode->get_point ().get_kind () == PK_AFTER_SUPERNODE
&& iter_snode == snode)
{
pretty_printer pp;
pp_format_decoder (&pp) = default_tree_printer;
enode->get_state ().dump_to_pp (m_ext_state, true, false, &pp);
fprintf (out, "state %i: EN: %i\n %s\n",
state_idx++, enode->m_index,
pp_formatted_text (&pp));
}
}
fprintf (out, "#exploded_node for PK_AFTER_SUPERNODE for SN: %i = %i\n",
snode->m_index, state_idx);
}
/* Return a new json::object of the form
{"nodes" : [objs for enodes],
"edges" : [objs for eedges],
"ext_state": object for extrinsic_state,
"diagnostic_manager": object for diagnostic_manager}. */
json::object *
exploded_graph::to_json () const
{
json::object *egraph_obj = new json::object ();
/* Nodes. */
{
json::array *nodes_arr = new json::array ();
unsigned i;
exploded_node *n;
FOR_EACH_VEC_ELT (m_nodes, i, n)
nodes_arr->append (n->to_json (m_ext_state));
egraph_obj->set ("nodes", nodes_arr);
}
/* Edges. */
{
json::array *edges_arr = new json::array ();
unsigned i;
exploded_edge *n;
FOR_EACH_VEC_ELT (m_edges, i, n)
edges_arr->append (n->to_json ());
egraph_obj->set ("edges", edges_arr);
}
/* m_sg is JSONified at the top-level. */
egraph_obj->set ("ext_state", m_ext_state.to_json ());
egraph_obj->set ("worklist", m_worklist.to_json ());
egraph_obj->set ("diagnostic_manager", m_diagnostic_manager.to_json ());
/* The following fields aren't yet being JSONified:
const state_purge_map *const m_purge_map;
const analysis_plan &m_plan;
stats m_global_stats;
function_stat_map_t m_per_function_stats;
stats m_functionless_stats;
call_string_data_map_t m_per_call_string_data;
auto_vec<int> m_PK_AFTER_SUPERNODE_per_snode; */
return egraph_obj;
}
/* class exploded_path. */
/* Copy ctor. */
exploded_path::exploded_path (const exploded_path &other)
: m_edges (other.m_edges.length ())
{
int i;
const exploded_edge *eedge;
FOR_EACH_VEC_ELT (other.m_edges, i, eedge)
m_edges.quick_push (eedge);
}
/* Look for the last use of SEARCH_STMT within this path.
If found write the edge's index to *OUT_IDX and return true, otherwise
return false. */
bool
exploded_path::find_stmt_backwards (const gimple *search_stmt,
int *out_idx) const
{
int i;
const exploded_edge *eedge;
FOR_EACH_VEC_ELT_REVERSE (m_edges, i, eedge)
{
const exploded_node *dst_node = eedge->m_dest;
const program_point &dst_point = dst_node->get_point ();
const gimple *stmt = dst_point.get_stmt ();
if (stmt == search_stmt)
{
*out_idx = i;
return true;
}
}
return false;
}
/* Get the final exploded_node in this path, which must be non-empty. */
exploded_node *
exploded_path::get_final_enode () const
{
gcc_assert (m_edges.length () > 0);
return m_edges[m_edges.length () - 1]->m_dest;
}
/* Check state along this path, returning true if it is feasible.
If OUT is non-NULL, and the path is infeasible, write a new
feasibility_problem to *OUT. */
bool
exploded_path::feasible_p (logger *logger, feasibility_problem **out,
engine *eng, const exploded_graph *eg) const
{
LOG_SCOPE (logger);
feasibility_state state (eng->get_model_manager (),
eg->get_supergraph ());
/* Traverse the path, updating this state. */
for (unsigned edge_idx = 0; edge_idx < m_edges.length (); edge_idx++)
{
const exploded_edge *eedge = m_edges[edge_idx];
if (logger)
logger->log ("considering edge %i: EN:%i -> EN:%i",
edge_idx,
eedge->m_src->m_index,
eedge->m_dest->m_index);
rejected_constraint *rc = NULL;
if (!state.maybe_update_for_edge (logger, eedge, &rc))
{
gcc_assert (rc);
if (out)
{
const exploded_node &src_enode = *eedge->m_src;
const program_point &src_point = src_enode.get_point ();
const gimple *last_stmt
= src_point.get_supernode ()->get_last_stmt ();
*out = new feasibility_problem (edge_idx, *eedge,
last_stmt, rc);
}
else
delete rc;
return false;
}
if (logger)
{
logger->log ("state after edge %i: EN:%i -> EN:%i",
edge_idx,
eedge->m_src->m_index,
eedge->m_dest->m_index);
logger->start_log_line ();
state.get_model ().dump_to_pp (logger->get_printer (), true, false);
logger->end_log_line ();
}
}
return true;
}
/* Dump this path in multiline form to PP. */
void
exploded_path::dump_to_pp (pretty_printer *pp) const
{
for (unsigned i = 0; i < m_edges.length (); i++)
{
const exploded_edge *eedge = m_edges[i];
pp_printf (pp, "m_edges[%i]: EN %i -> EN %i",
i,
eedge->m_src->m_index,
eedge->m_dest->m_index);
pp_newline (pp);
}
}
/* Dump this path in multiline form to FP. */
void
exploded_path::dump (FILE *fp) const
{
pretty_printer pp;
pp_format_decoder (&pp) = default_tree_printer;
pp_show_color (&pp) = pp_show_color (global_dc->printer);
pp.buffer->stream = fp;
dump_to_pp (&pp);
pp_flush (&pp);
}
/* Dump this path in multiline form to stderr. */
DEBUG_FUNCTION void
exploded_path::dump () const
{
dump (stderr);
}
/* class feasibility_problem. */
void
feasibility_problem::dump_to_pp (pretty_printer *pp) const
{
pp_printf (pp, "edge from EN: %i to EN: %i",
m_eedge.m_src->m_index, m_eedge.m_dest->m_index);
if (m_rc)
{
pp_string (pp, "; rejected constraint: ");
m_rc->dump_to_pp (pp);
pp_string (pp, "; rmodel: ");
m_rc->m_model.dump_to_pp (pp, true, false);
}
}
/* class feasibility_state. */
/* Ctor for feasibility_state, at the beginning of a path. */
feasibility_state::feasibility_state (region_model_manager *manager,
const supergraph &sg)
: m_model (manager),
m_snodes_visited (sg.m_nodes.length ())
{
bitmap_clear (m_snodes_visited);
}
/* Copy ctor for feasibility_state, for extending a path. */
feasibility_state::feasibility_state (const feasibility_state &other)
: m_model (other.m_model),
m_snodes_visited (const_sbitmap (other.m_snodes_visited)->n_bits)
{
bitmap_copy (m_snodes_visited, other.m_snodes_visited);
}
/* The heart of feasibility-checking.
Attempt to update this state in-place based on traversing EEDGE
in a path.
Update the model for the stmts in the src enode.
Attempt to add constraints for EEDGE.
If feasible, return true.
Otherwise, return false and write to *OUT_RC. */
bool
feasibility_state::maybe_update_for_edge (logger *logger,
const exploded_edge *eedge,
rejected_constraint **out_rc)
{
const exploded_node &src_enode = *eedge->m_src;
const program_point &src_point = src_enode.get_point ();
if (logger)
{
logger->start_log_line ();
src_point.print (logger->get_printer (), format (false));
logger->end_log_line ();
}
/* Update state for the stmts that were processed in each enode. */
for (unsigned stmt_idx = 0; stmt_idx < src_enode.m_num_processed_stmts;
stmt_idx++)
{
const gimple *stmt = src_enode.get_processed_stmt (stmt_idx);
/* Update cfun and input_location in case of ICE: make it easier to
track down which source construct we're failing to handle. */
auto_cfun sentinel (src_point.get_function ());
input_location = stmt->location;
if (const gassign *assign = dyn_cast <const gassign *> (stmt))
m_model.on_assignment (assign, NULL);
else if (const greturn *return_ = dyn_cast <const greturn *> (stmt))
m_model.on_return (return_, NULL);
}
const superedge *sedge = eedge->m_sedge;
if (sedge)
{
if (logger)
logger->log (" sedge: SN:%i -> SN:%i %s",
sedge->m_src->m_index,
sedge->m_dest->m_index,
sedge->get_description (false));
const gimple *last_stmt = src_point.get_supernode ()->get_last_stmt ();
if (!m_model.maybe_update_for_edge (*sedge, last_stmt, NULL, out_rc))
{
if (logger)
{
logger->log ("rejecting due to region model");
m_model.dump_to_pp (logger->get_printer (), true, false);
}
return false;
}
}
else
{
/* Special-case the initial eedge from the origin node to the
initial function by pushing a frame for it. */
if (src_point.get_kind () == PK_ORIGIN)
{
gcc_assert (eedge->m_src->m_index == 0);
gcc_assert (eedge->m_dest->get_point ().get_kind ()
== PK_BEFORE_SUPERNODE);
function *fun = eedge->m_dest->get_function ();
gcc_assert (fun);
m_model.push_frame (fun, NULL, NULL);
if (logger)
logger->log (" pushing frame for %qD", fun->decl);
}
else if (eedge->m_custom_info)
{
eedge->m_custom_info->update_model (&m_model, *eedge);
}
}
/* Handle phi nodes on an edge leaving a PK_BEFORE_SUPERNODE (to
a PK_BEFORE_STMT, or a PK_AFTER_SUPERNODE if no stmts).
This will typically not be associated with a superedge. */
if (src_point.get_from_edge ())
{
const cfg_superedge *last_cfg_superedge
= src_point.get_from_edge ()->dyn_cast_cfg_superedge ();
const exploded_node &dst_enode = *eedge->m_dest;
const unsigned dst_snode_idx = dst_enode.get_supernode ()->m_index;
if (last_cfg_superedge)
{
if (logger)
logger->log (" update for phis");
m_model.update_for_phis (src_enode.get_supernode (),
last_cfg_superedge,
NULL);
/* If we've entering an snode that we've already visited on this
epath, then we need do fix things up for loops; see the
comment for store::loop_replay_fixup.
Perhaps we should probably also verify the callstring,
and track program_points, but hopefully doing it by supernode
is good enough. */
if (bitmap_bit_p (m_snodes_visited, dst_snode_idx))
m_model.loop_replay_fixup (dst_enode.get_state ().m_region_model);
}
bitmap_set_bit (m_snodes_visited, dst_snode_idx);
}
return true;
}
/* A family of cluster subclasses for use when generating .dot output for
exploded graphs (-fdump-analyzer-exploded-graph), for grouping the
enodes into hierarchical boxes.
All functionless enodes appear in the top-level graph.
Every (function, call_string) pair gets its own cluster. Within that
cluster, each supernode gets its own cluster.
Hence all enodes relating to a particular function with a particular
callstring will be in a cluster together; all enodes for the same
function but with a different callstring will be in a different
cluster. */
/* Base class of cluster for clustering exploded_node instances in .dot
output, based on various subclass-specific criteria. */
class exploded_cluster : public cluster<eg_traits>
{
};
/* Cluster containing all exploded_node instances for one supernode. */
class supernode_cluster : public exploded_cluster
{
public:
supernode_cluster (const supernode *supernode) : m_supernode (supernode) {}
// TODO: dtor?
void dump_dot (graphviz_out *gv, const dump_args_t &args) const FINAL OVERRIDE
{
gv->println ("subgraph \"cluster_supernode_%i\" {", m_supernode->m_index);
gv->indent ();
gv->println ("style=\"dashed\";");
gv->println ("label=\"SN: %i (bb: %i; scc: %i)\";",
m_supernode->m_index, m_supernode->m_bb->index,
args.m_eg.get_scc_id (*m_supernode));
int i;
exploded_node *enode;
FOR_EACH_VEC_ELT (m_enodes, i, enode)
enode->dump_dot (gv, args);
/* Terminate subgraph. */
gv->outdent ();
gv->println ("}");
}
void add_node (exploded_node *en) FINAL OVERRIDE
{
m_enodes.safe_push (en);
}
/* Comparator for use by auto_vec<supernode_cluster *>::qsort. */
static int cmp_ptr_ptr (const void *p1, const void *p2)
{
const supernode_cluster *c1
= *(const supernode_cluster * const *)p1;
const supernode_cluster *c2
= *(const supernode_cluster * const *)p2;
return c1->m_supernode->m_index - c2->m_supernode->m_index;
}
private:
const supernode *m_supernode;
auto_vec <exploded_node *> m_enodes;
};
/* Cluster containing all supernode_cluster instances for one
(function, call_string) pair. */
class function_call_string_cluster : public exploded_cluster
{
public:
function_call_string_cluster (function *fun, call_string cs)
: m_fun (fun), m_cs (cs) {}
~function_call_string_cluster ()
{
for (map_t::iterator iter = m_map.begin ();
iter != m_map.end ();
++iter)
delete (*iter).second;
}
void dump_dot (graphviz_out *gv, const dump_args_t &args) const FINAL OVERRIDE
{
const char *funcname = function_name (m_fun);
gv->println ("subgraph \"cluster_function_%s\" {",
IDENTIFIER_POINTER (DECL_ASSEMBLER_NAME (m_fun->decl)));
gv->indent ();
gv->write_indent ();
gv->print ("label=\"call string: ");
m_cs.print (gv->get_pp ());
gv->print (" function: %s \";", funcname);
gv->print ("\n");
/* Dump m_map, sorting it to avoid churn when comparing dumps. */
auto_vec<supernode_cluster *> child_clusters (m_map.elements ());
for (map_t::iterator iter = m_map.begin ();
iter != m_map.end ();
++iter)
child_clusters.quick_push ((*iter).second);
child_clusters.qsort (supernode_cluster::cmp_ptr_ptr);
unsigned i;
supernode_cluster *child_cluster;
FOR_EACH_VEC_ELT (child_clusters, i, child_cluster)
child_cluster->dump_dot (gv, args);
/* Terminate subgraph. */
gv->outdent ();
gv->println ("}");
}
void add_node (exploded_node *en) FINAL OVERRIDE
{
const supernode *supernode = en->get_supernode ();
gcc_assert (supernode);
supernode_cluster **slot = m_map.get (supernode);
if (slot)
(*slot)->add_node (en);
else
{
supernode_cluster *child = new supernode_cluster (supernode);
m_map.put (supernode, child);
child->add_node (en);
}
}
/* Comparator for use by auto_vec<function_call_string_cluster *>. */
static int cmp_ptr_ptr (const void *p1, const void *p2)
{
const function_call_string_cluster *c1
= *(const function_call_string_cluster * const *)p1;
const function_call_string_cluster *c2
= *(const function_call_string_cluster * const *)p2;
if (int cmp_names
= strcmp (IDENTIFIER_POINTER (DECL_ASSEMBLER_NAME (c1->m_fun->decl)),
IDENTIFIER_POINTER (DECL_ASSEMBLER_NAME (c2->m_fun->decl))))
return cmp_names;
return call_string::cmp (c1->m_cs, c2->m_cs);
}
private:
function *m_fun;
call_string m_cs;
typedef ordered_hash_map<const supernode *, supernode_cluster *> map_t;
map_t m_map;
};
/* Keys for root_cluster. */
struct function_call_string
{
function_call_string (function *fun, call_string cs)
: m_fun (fun), m_cs (cs)
{
gcc_assert (fun);
}
function *m_fun;
call_string m_cs;
};
} // namespace ana
template <> struct default_hash_traits<function_call_string>
: public pod_hash_traits<function_call_string>
{
static const bool empty_zero_p = false;
};
template <>
inline hashval_t
pod_hash_traits<function_call_string>::hash (value_type v)
{
return pointer_hash <function>::hash (v.m_fun) ^ v.m_cs.hash ();
}
template <>
inline bool
pod_hash_traits<function_call_string>::equal (const value_type &existing,
const value_type &candidate)
{
return existing.m_fun == candidate.m_fun && existing.m_cs == candidate.m_cs;
}
template <>
inline void
pod_hash_traits<function_call_string>::mark_deleted (value_type &v)
{
v.m_fun = reinterpret_cast<function *> (1);
}
template <>
inline void
pod_hash_traits<function_call_string>::mark_empty (value_type &v)
{
v.m_fun = NULL;
}
template <>
inline bool
pod_hash_traits<function_call_string>::is_deleted (value_type v)
{
return v.m_fun == reinterpret_cast<function *> (1);
}
template <>
inline bool
pod_hash_traits<function_call_string>::is_empty (value_type v)
{
return v.m_fun == NULL;
}
namespace ana {
/* Top-level cluster for generating .dot output for exploded graphs,
handling the functionless nodes, and grouping the remaining nodes by
callstring. */
class root_cluster : public exploded_cluster
{
public:
~root_cluster ()
{
for (map_t::iterator iter = m_map.begin ();
iter != m_map.end ();
++iter)
delete (*iter).second;
}
void dump_dot (graphviz_out *gv, const dump_args_t &args) const FINAL OVERRIDE
{
int i;
exploded_node *enode;
FOR_EACH_VEC_ELT (m_functionless_enodes, i, enode)
enode->dump_dot (gv, args);
/* Dump m_map, sorting it to avoid churn when comparing dumps. */
auto_vec<function_call_string_cluster *> child_clusters (m_map.elements ());
for (map_t::iterator iter = m_map.begin ();
iter != m_map.end ();
++iter)
child_clusters.quick_push ((*iter).second);
child_clusters.qsort (function_call_string_cluster::cmp_ptr_ptr);
function_call_string_cluster *child_cluster;
FOR_EACH_VEC_ELT (child_clusters, i, child_cluster)
child_cluster->dump_dot (gv, args);
}
void add_node (exploded_node *en) FINAL OVERRIDE
{
function *fun = en->get_function ();
if (!fun)
{
m_functionless_enodes.safe_push (en);
return;
}
const call_string &cs = en->get_point ().get_call_string ();
function_call_string key (fun, cs);
function_call_string_cluster **slot = m_map.get (key);
if (slot)
(*slot)->add_node (en);
else
{
function_call_string_cluster *child
= new function_call_string_cluster (fun, cs);
m_map.put (key, child);
child->add_node (en);
}
}
private:
/* This can't be an ordered_hash_map, as we can't store vec<call_string>,
since it's not a POD; vec<>::quick_push has:
*slot = obj;
and the slot isn't initialized, so the assignment op dies when cleaning up
un-inited *slot (within the truncate call). */
typedef hash_map<function_call_string, function_call_string_cluster *> map_t;
map_t m_map;
/* This should just be the origin exploded_node. */
auto_vec <exploded_node *> m_functionless_enodes;
};
/* Subclass of range_label for use within
exploded_graph::dump_exploded_nodes for implementing
-fdump-analyzer-exploded-nodes: a label for a specific
exploded_node. */
class enode_label : public range_label
{
public:
enode_label (const extrinsic_state &ext_state,
exploded_node *enode)
: m_ext_state (ext_state), m_enode (enode) {}
label_text get_text (unsigned) const FINAL OVERRIDE
{
pretty_printer pp;
pp_format_decoder (&pp) = default_tree_printer;
m_enode->get_state ().dump_to_pp (m_ext_state, true, false, &pp);
return make_label_text (false, "EN: %i: %s",
m_enode->m_index, pp_formatted_text (&pp));
}
private:
const extrinsic_state &m_ext_state;
exploded_node *m_enode;
};
/* Postprocessing support for dumping the exploded nodes.
Handle -fdump-analyzer-exploded-nodes,
-fdump-analyzer-exploded-nodes-2, and the
"__analyzer_dump_exploded_nodes" builtin. */
void
exploded_graph::dump_exploded_nodes () const
{
// TODO
/* Locate calls to __analyzer_dump_exploded_nodes. */
// Print how many egs there are for them?
/* Better: log them as we go, and record the exploded nodes
in question. */
/* Show every enode. */
/* Gather them by stmt, so that we can more clearly see the
"hotspots" requiring numerous exploded nodes. */
/* Alternatively, simply throw them all into one big rich_location
and see if the label-printing will sort it out...
This requires them all to be in the same source file. */
if (flag_dump_analyzer_exploded_nodes)
{
auto_timevar tv (TV_ANALYZER_DUMP);
gcc_rich_location richloc (UNKNOWN_LOCATION);
unsigned i;
exploded_node *enode;
FOR_EACH_VEC_ELT (m_nodes, i, enode)
{
if (const gimple *stmt = enode->get_stmt ())
{
if (get_pure_location (richloc.get_loc ()) == UNKNOWN_LOCATION)
richloc.set_range (0, stmt->location, SHOW_RANGE_WITH_CARET);
else
richloc.add_range (stmt->location,
SHOW_RANGE_WITHOUT_CARET,
new enode_label (m_ext_state, enode));
}
}
warning_at (&richloc, 0, "%i exploded nodes", m_nodes.length ());
/* Repeat the warning without all the labels, so that message is visible
(the other one may well have scrolled past the terminal limit). */
warning_at (richloc.get_loc (), 0,
"%i exploded nodes", m_nodes.length ());
if (m_worklist.length () > 0)
warning_at (richloc.get_loc (), 0,
"worklist still contains %i nodes", m_worklist.length ());
}
/* Dump the egraph in textual form to a dump file. */
if (flag_dump_analyzer_exploded_nodes_2)
{
auto_timevar tv (TV_ANALYZER_DUMP);
char *filename
= concat (dump_base_name, ".eg.txt", NULL);
FILE *outf = fopen (filename, "w");
if (!outf)
error_at (UNKNOWN_LOCATION, "unable to open %qs for writing", filename);
free (filename);
fprintf (outf, "exploded graph for %s\n", dump_base_name);
fprintf (outf, " nodes: %i\n", m_nodes.length ());
fprintf (outf, " edges: %i\n", m_edges.length ());
unsigned i;
exploded_node *enode;
FOR_EACH_VEC_ELT (m_nodes, i, enode)
{
fprintf (outf, "\nEN %i:\n", enode->m_index);
enode->dump_succs_and_preds (outf);
pretty_printer pp;
enode->get_point ().print (&pp, format (true));
fprintf (outf, "%s\n", pp_formatted_text (&pp));
enode->get_state ().dump_to_file (m_ext_state, false, true, outf);
}
fclose (outf);
}
/* Dump the egraph in textual form to multiple dump files, one per enode. */
if (flag_dump_analyzer_exploded_nodes_3)
{
auto_timevar tv (TV_ANALYZER_DUMP);
unsigned i;
exploded_node *enode;
FOR_EACH_VEC_ELT (m_nodes, i, enode)
{
char *filename
= xasprintf ("%s.en-%i.txt", dump_base_name, i);
FILE *outf = fopen (filename, "w");
if (!outf)
error_at (UNKNOWN_LOCATION, "unable to open %qs for writing", filename);
free (filename);
fprintf (outf, "EN %i:\n", enode->m_index);
enode->dump_succs_and_preds (outf);
pretty_printer pp;
enode->get_point ().print (&pp, format (true));
fprintf (outf, "%s\n", pp_formatted_text (&pp));
enode->get_state ().dump_to_file (m_ext_state, false, true, outf);
fclose (outf);
}
}
/* Emit a warning at any call to "__analyzer_dump_exploded_nodes",
giving the number of processed exploded nodes for "before-stmt",
and the IDs of processed, merger, and worklist enodes.
We highlight the count of *processed* enodes since this is of most
interest in DejaGnu tests for ensuring that state merger has
happened.
We don't show the count of merger and worklist enodes, as this is
more of an implementation detail of the merging/worklist that we
don't want to bake into our expected DejaGnu messages. */
unsigned i;
exploded_node *enode;
hash_set<const gimple *> seen;
FOR_EACH_VEC_ELT (m_nodes, i, enode)
{
if (enode->get_point ().get_kind () != PK_BEFORE_STMT)
continue;
if (const gimple *stmt = enode->get_stmt ())
if (const gcall *call = dyn_cast <const gcall *> (stmt))
if (is_special_named_call_p (call, "__analyzer_dump_exploded_nodes",
1))
{
if (seen.contains (stmt))
continue;
auto_vec<exploded_node *> processed_enodes;
auto_vec<exploded_node *> merger_enodes;
auto_vec<exploded_node *> worklist_enodes;
/* This is O(N^2). */
unsigned j;
exploded_node *other_enode;
FOR_EACH_VEC_ELT (m_nodes, j, other_enode)
{
if (other_enode->get_point ().get_kind () != PK_BEFORE_STMT)
continue;
if (other_enode->get_stmt () == stmt)
switch (other_enode->get_status ())
{
default:
gcc_unreachable ();
case exploded_node::STATUS_WORKLIST:
worklist_enodes.safe_push (other_enode);
break;
case exploded_node::STATUS_PROCESSED:
processed_enodes.safe_push (other_enode);
break;
case exploded_node::STATUS_MERGER:
merger_enodes.safe_push (other_enode);
break;
}
}
pretty_printer pp;
pp_character (&pp, '[');
print_enode_indices (&pp, processed_enodes);
if (merger_enodes.length () > 0)
{
pp_string (&pp, "] merger(s): [");
print_enode_indices (&pp, merger_enodes);
}
if (worklist_enodes.length () > 0)
{
pp_string (&pp, "] worklist: [");
print_enode_indices (&pp, worklist_enodes);
}
pp_character (&pp, ']');
warning_n (stmt->location, 0, processed_enodes.length (),
"%i processed enode: %s",
"%i processed enodes: %s",
processed_enodes.length (), pp_formatted_text (&pp));
seen.add (stmt);
/* If the argument is non-zero, then print all of the states
of the various enodes. */
tree t_arg = fold (gimple_call_arg (call, 0));
if (TREE_CODE (t_arg) != INTEGER_CST)
{
error_at (call->location,
"integer constant required for arg 1");
return;
}
int i_arg = TREE_INT_CST_LOW (t_arg);
if (i_arg)
{
exploded_node *other_enode;
FOR_EACH_VEC_ELT (processed_enodes, j, other_enode)
{
fprintf (stderr, "%i of %i: EN %i:\n",
j + 1, processed_enodes.length (),
other_enode->m_index);
other_enode->dump_succs_and_preds (stderr);
/* Dump state. */
other_enode->get_state ().dump (m_ext_state, false);
}
}
}
}
}
DEBUG_FUNCTION exploded_node *
exploded_graph::get_node_by_index (int idx) const
{
exploded_node *enode = m_nodes[idx];
gcc_assert (enode->m_index == idx);
return enode;
}
/* Ensure that there is an exploded_node for a top-level call to FNDECL. */
void
exploded_graph::on_escaped_function (tree fndecl)
{
logger * const logger = get_logger ();
LOG_FUNC_1 (logger, "%qE", fndecl);
cgraph_node *cgnode = cgraph_node::get (fndecl);
if (!cgnode)
return;
function *fun = cgnode->get_fun ();
if (!fun)
return;
if (!gimple_has_body_p (fndecl))
return;
exploded_node *enode = add_function_entry (fun);
if (logger)
{
if (enode)
logger->log ("created EN %i for %qE entrypoint",
enode->m_index, fun->decl);
else
logger->log ("did not create enode for %qE entrypoint", fun->decl);
}
}
/* A collection of classes for visualizing the callgraph in .dot form
(as represented in the supergraph). */
/* Forward decls. */
class viz_callgraph_node;
class viz_callgraph_edge;
class viz_callgraph;
class viz_callgraph_cluster;
/* Traits for using "digraph.h" to visualize the callgraph. */
struct viz_callgraph_traits
{
typedef viz_callgraph_node node_t;
typedef viz_callgraph_edge edge_t;
typedef viz_callgraph graph_t;
struct dump_args_t
{
dump_args_t (const exploded_graph *eg) : m_eg (eg) {}
const exploded_graph *m_eg;
};
typedef viz_callgraph_cluster cluster_t;
};
/* Subclass of dnode representing a function within the callgraph. */
class viz_callgraph_node : public dnode<viz_callgraph_traits>
{
friend class viz_callgraph;
public:
viz_callgraph_node (function *fun, int index)
: m_fun (fun), m_index (index), m_num_supernodes (0), m_num_superedges (0)
{
gcc_assert (fun);
}
void dump_dot (graphviz_out *gv, const dump_args_t &args) const FINAL OVERRIDE
{
pretty_printer *pp = gv->get_pp ();
dump_dot_id (pp);
pp_printf (pp, " [shape=none,margin=0,style=filled,fillcolor=%s,label=<",
"lightgrey");
pp_string (pp, "<TABLE BORDER=\"0\">");
pp_write_text_to_stream (pp);
gv->begin_trtd ();
pp_printf (pp, "VCG: %i: %s", m_index, function_name (m_fun));
gv->end_tdtr ();
pp_newline (pp);
gv->begin_trtd ();
pp_printf (pp, "supernodes: %i\n", m_num_supernodes);
gv->end_tdtr ();
pp_newline (pp);
gv->begin_trtd ();
pp_printf (pp, "superedges: %i\n", m_num_superedges);
gv->end_tdtr ();
pp_newline (pp);
if (args.m_eg)
{
unsigned i;
exploded_node *enode;
unsigned num_enodes = 0;
FOR_EACH_VEC_ELT (args.m_eg->m_nodes, i, enode)
{
if (enode->get_point ().get_function () == m_fun)
num_enodes++;
}
gv->begin_trtd ();
pp_printf (pp, "enodes: %i\n", num_enodes);
gv->end_tdtr ();
pp_newline (pp);
// TODO: also show the per-callstring breakdown
const exploded_graph::call_string_data_map_t *per_cs_data
= args.m_eg->get_per_call_string_data ();
for (exploded_graph::call_string_data_map_t::iterator iter
= per_cs_data->begin ();
iter != per_cs_data->end ();
++iter)
{
const call_string *cs = (*iter).first;
//per_call_string_data *data = (*iter).second;
num_enodes = 0;
FOR_EACH_VEC_ELT (args.m_eg->m_nodes, i, enode)
{
if (enode->get_point ().get_function () == m_fun
&& enode->get_point ().get_call_string () == *cs)
num_enodes++;
}
if (num_enodes > 0)
{
gv->begin_trtd ();
cs->print (pp);
pp_printf (pp, ": %i\n", num_enodes);
pp_write_text_as_html_like_dot_to_stream (pp);
gv->end_tdtr ();
}
}
/* Show any summaries. */
per_function_data *data = args.m_eg->get_per_function_data (m_fun);
if (data)
{
pp_newline (pp);
gv->begin_trtd ();
pp_printf (pp, "summaries: %i\n", data->m_summaries.length ());
pp_write_text_as_html_like_dot_to_stream (pp);
gv->end_tdtr ();
}
}
pp_string (pp, "</TABLE>>];\n\n");
pp_flush (pp);
}
void dump_dot_id (pretty_printer *pp) const
{
pp_printf (pp, "vcg_%i", m_index);
}
private:
function *m_fun;
int m_index;
int m_num_supernodes;
int m_num_superedges;
};
/* Subclass of dedge representing a callgraph edge. */
class viz_callgraph_edge : public dedge<viz_callgraph_traits>
{
public:
viz_callgraph_edge (viz_callgraph_node *src, viz_callgraph_node *dest)
: dedge<viz_callgraph_traits> (src, dest)
{}
void dump_dot (graphviz_out *gv, const dump_args_t &) const
FINAL OVERRIDE
{
pretty_printer *pp = gv->get_pp ();
const char *style = "\"solid,bold\"";
const char *color = "black";
int weight = 10;
const char *constraint = "true";
m_src->dump_dot_id (pp);
pp_string (pp, " -> ");
m_dest->dump_dot_id (pp);
pp_printf (pp,
(" [style=%s, color=%s, weight=%d, constraint=%s,"
" headlabel=\""),
style, color, weight, constraint);
pp_printf (pp, "\"];\n");
}
};
/* Subclass of digraph representing the callgraph. */
class viz_callgraph : public digraph<viz_callgraph_traits>
{
public:
viz_callgraph (const supergraph &sg);
viz_callgraph_node *get_vcg_node_for_function (function *fun)
{
return *m_map.get (fun);
}
viz_callgraph_node *get_vcg_node_for_snode (supernode *snode)
{
return get_vcg_node_for_function (snode->m_fun);
}
private:
hash_map<function *, viz_callgraph_node *> m_map;
};
/* Placeholder subclass of cluster. */
class viz_callgraph_cluster : public cluster<viz_callgraph_traits>
{
};
/* viz_callgraph's ctor. */
viz_callgraph::viz_callgraph (const supergraph &sg)
{
cgraph_node *node;
FOR_EACH_FUNCTION_WITH_GIMPLE_BODY (node)
{
function *fun = node->get_fun ();
viz_callgraph_node *vcg_node
= new viz_callgraph_node (fun, m_nodes.length ());
m_map.put (fun, vcg_node);
add_node (vcg_node);
}
unsigned i;
superedge *sedge;
FOR_EACH_VEC_ELT (sg.m_edges, i, sedge)
{
viz_callgraph_node *vcg_src = get_vcg_node_for_snode (sedge->m_src);
if (vcg_src->m_fun)
get_vcg_node_for_function (vcg_src->m_fun)->m_num_superedges++;
if (sedge->dyn_cast_call_superedge ())
{
viz_callgraph_node *vcg_dest = get_vcg_node_for_snode (sedge->m_dest);
viz_callgraph_edge *vcg_edge
= new viz_callgraph_edge (vcg_src, vcg_dest);
add_edge (vcg_edge);
}
}
supernode *snode;
FOR_EACH_VEC_ELT (sg.m_nodes, i, snode)
{
if (snode->m_fun)
get_vcg_node_for_function (snode->m_fun)->m_num_supernodes++;
}
}
/* Dump the callgraph to FILENAME. */
static void
dump_callgraph (const supergraph &sg, const char *filename,
const exploded_graph *eg)
{
FILE *outf = fopen (filename, "w");
if (!outf)
return;
// TODO
viz_callgraph vcg (sg);
vcg.dump_dot (filename, NULL, viz_callgraph_traits::dump_args_t (eg));
fclose (outf);
}
/* Dump the callgraph to "<srcfile>.callgraph.dot". */
static void
dump_callgraph (const supergraph &sg, const exploded_graph *eg)
{
auto_timevar tv (TV_ANALYZER_DUMP);
char *filename = concat (dump_base_name, ".callgraph.dot", NULL);
dump_callgraph (sg, filename, eg);
free (filename);
}
/* Subclass of dot_annotator for implementing
DUMP_BASE_NAME.supergraph-eg.dot, a post-analysis dump of the supergraph.
Annotate the supergraph nodes by printing the exploded nodes in concise
form within them, next to their pertinent statements where appropriate,
colorizing the exploded nodes based on sm-state.
Also show saved diagnostics within the exploded nodes, giving information
on whether they were feasible, and, if infeasible, where the problem
was. */
class exploded_graph_annotator : public dot_annotator
{
public:
exploded_graph_annotator (const exploded_graph &eg)
: m_eg (eg)
{
/* Avoid O(N^2) by prepopulating m_enodes_per_snodes. */
unsigned i;
supernode *snode;
FOR_EACH_VEC_ELT (eg.get_supergraph ().m_nodes, i, snode)
m_enodes_per_snodes.safe_push (new auto_vec <exploded_node *> ());
exploded_node *enode;
FOR_EACH_VEC_ELT (m_eg.m_nodes, i, enode)
if (enode->get_supernode ())
m_enodes_per_snodes[enode->get_supernode ()->m_index]->safe_push (enode);
}
/* Show exploded nodes for BEFORE_SUPERNODE points before N. */
bool add_node_annotations (graphviz_out *gv, const supernode &n,
bool within_table)
const FINAL OVERRIDE
{
if (!within_table)
return false;
gv->begin_tr ();
pretty_printer *pp = gv->get_pp ();
gv->begin_td ();
pp_string (pp, "BEFORE");
pp_printf (pp, " (scc: %i)", m_eg.get_scc_id (n));
gv->end_td ();
unsigned i;
exploded_node *enode;
bool had_enode = false;
FOR_EACH_VEC_ELT (*m_enodes_per_snodes[n.m_index], i, enode)
{
gcc_assert (enode->get_supernode () == &n);
const program_point &point = enode->get_point ();
if (point.get_kind () != PK_BEFORE_SUPERNODE)
continue;
print_enode (gv, enode);
had_enode = true;
}
if (!had_enode)
pp_string (pp, "<TD BGCOLOR=\"red\">UNREACHED</TD>");
pp_flush (pp);
gv->end_tr ();
return true;
}
/* Show exploded nodes for STMT. */
void add_stmt_annotations (graphviz_out *gv, const gimple *stmt,
bool within_row)
const FINAL OVERRIDE
{
if (!within_row)
return;
pretty_printer *pp = gv->get_pp ();
const supernode *snode
= m_eg.get_supergraph ().get_supernode_for_stmt (stmt);
unsigned i;
exploded_node *enode;
bool had_td = false;
FOR_EACH_VEC_ELT (*m_enodes_per_snodes[snode->m_index], i, enode)
{
const program_point &point = enode->get_point ();
if (point.get_kind () != PK_BEFORE_STMT)
continue;
if (point.get_stmt () != stmt)
continue;
print_enode (gv, enode);
had_td = true;
}
pp_flush (pp);
if (!had_td)
{
gv->begin_td ();
gv->end_td ();
}
}
/* Show exploded nodes for AFTER_SUPERNODE points after N. */
bool add_after_node_annotations (graphviz_out *gv, const supernode &n)
const FINAL OVERRIDE
{
gv->begin_tr ();
pretty_printer *pp = gv->get_pp ();
gv->begin_td ();
pp_string (pp, "AFTER");
gv->end_td ();
unsigned i;
exploded_node *enode;
FOR_EACH_VEC_ELT (*m_enodes_per_snodes[n.m_index], i, enode)
{
gcc_assert (enode->get_supernode () == &n);
const program_point &point = enode->get_point ();
if (point.get_kind () != PK_AFTER_SUPERNODE)
continue;
print_enode (gv, enode);
}
pp_flush (pp);
gv->end_tr ();
return true;
}
private:
/* Concisely print a TD element for ENODE, showing the index, status,
and any saved_diagnostics at the enode. Colorize it to show sm-state.
Ideally we'd dump ENODE's state here, hidden behind some kind of
interactive disclosure method like a tooltip, so that the states
can be explored without overwhelming the graph.
However, I wasn't able to get graphviz/xdot to show tooltips on
individual elements within a HTML-like label. */
void print_enode (graphviz_out *gv, const exploded_node *enode) const
{
pretty_printer *pp = gv->get_pp ();
pp_printf (pp, "<TD BGCOLOR=\"%s\">",
enode->get_dot_fillcolor ());
pp_printf (pp, "<TABLE BORDER=\"0\">");
gv->begin_trtd ();
pp_printf (pp, "EN: %i", enode->m_index);
switch (enode->get_status ())
{
default:
gcc_unreachable ();
case exploded_node::STATUS_WORKLIST:
pp_string (pp, "(W)");
break;
case exploded_node::STATUS_PROCESSED:
break;
case exploded_node::STATUS_MERGER:
pp_string (pp, "(M)");
break;
case exploded_node::STATUS_BULK_MERGED:
pp_string (pp, "(BM)");
break;
}
gv->end_tdtr ();
/* Dump any saved_diagnostics at this enode. */
{
const diagnostic_manager &dm = m_eg.get_diagnostic_manager ();
for (unsigned i = 0; i < dm.get_num_diagnostics (); i++)
{
const saved_diagnostic *sd = dm.get_saved_diagnostic (i);
if (sd->m_enode == enode)
print_saved_diagnostic (gv, sd);
}
}
pp_printf (pp, "</TABLE>");
pp_printf (pp, "</TD>");
}
/* Print a TABLE element for SD, showing the kind, the length of the
exploded_path, whether the path was feasible, and if infeasible,
what the problem was. */
void print_saved_diagnostic (graphviz_out *gv,
const saved_diagnostic *sd) const
{
pretty_printer *pp = gv->get_pp ();
gv->begin_trtd ();
pp_printf (pp, "<TABLE BORDER=\"0\">");
gv->begin_tr ();
pp_string (pp, "<TD BGCOLOR=\"green\">");
pp_printf (pp, "DIAGNOSTIC: %s", sd->m_d->get_kind ());
gv->end_tdtr ();
gv->begin_trtd ();
if (sd->get_best_epath ())
pp_printf (pp, "epath length: %i", sd->get_epath_length ());
else
pp_printf (pp, "no best epath");
gv->end_tdtr ();
if (const feasibility_problem *p = sd->get_feasibility_problem ())
{
gv->begin_trtd ();
pp_printf (pp, "INFEASIBLE at eedge %i: EN:%i -> EN:%i",
p->m_eedge_idx,
p->m_eedge.m_src->m_index,
p->m_eedge.m_dest->m_index);
pp_write_text_as_html_like_dot_to_stream (pp);
gv->end_tdtr ();
gv->begin_trtd ();
p->m_eedge.m_sedge->dump (pp);
pp_write_text_as_html_like_dot_to_stream (pp);
gv->end_tdtr ();
gv->begin_trtd ();
pp_gimple_stmt_1 (pp, p->m_last_stmt, 0, (dump_flags_t)0);
pp_write_text_as_html_like_dot_to_stream (pp);
gv->end_tdtr ();
/* Ideally we'd print p->m_model here; see the notes above about
tooltips. */
}
pp_printf (pp, "</TABLE>");
gv->end_tdtr ();
}
const exploded_graph &m_eg;
auto_delete_vec<auto_vec <exploded_node *> > m_enodes_per_snodes;
};
/* Implement -fdump-analyzer-json. */
static void
dump_analyzer_json (const supergraph &sg,
const exploded_graph &eg)
{
auto_timevar tv (TV_ANALYZER_DUMP);
char *filename = concat (dump_base_name, ".analyzer.json.gz", NULL);
gzFile output = gzopen (filename, "w");
if (!output)
{
error_at (UNKNOWN_LOCATION, "unable to open %qs for writing", filename);
free (filename);
return;
}
json::object *toplev_obj = new json::object ();
toplev_obj->set ("sgraph", sg.to_json ());
toplev_obj->set ("egraph", eg.to_json ());
pretty_printer pp;
toplev_obj->print (&pp);
pp_formatted_text (&pp);
delete toplev_obj;
if (gzputs (output, pp_formatted_text (&pp)) == EOF
|| gzclose (output))
error_at (UNKNOWN_LOCATION, "error writing %qs", filename);
free (filename);
}
/* Concrete subclass of plugin_analyzer_init_iface, allowing plugins
to register new state machines. */
class plugin_analyzer_init_impl : public plugin_analyzer_init_iface
{
public:
plugin_analyzer_init_impl (auto_delete_vec <state_machine> *checkers,
logger *logger)
: m_checkers (checkers),
m_logger (logger)
{}
void register_state_machine (state_machine *sm) FINAL OVERRIDE
{
m_checkers->safe_push (sm);
}
logger *get_logger () const FINAL OVERRIDE
{
return m_logger;
}
private:
auto_delete_vec <state_machine> *m_checkers;
logger *m_logger;
};
/* Run the analysis "engine". */
void
impl_run_checkers (logger *logger)
{
LOG_SCOPE (logger);
/* If using LTO, ensure that the cgraph nodes have function bodies. */
cgraph_node *node;
FOR_EACH_FUNCTION_WITH_GIMPLE_BODY (node)
node->get_untransformed_body ();
engine eng;
/* Create the supergraph. */
supergraph sg (logger);
state_purge_map *purge_map = NULL;
if (flag_analyzer_state_purge)
purge_map = new state_purge_map (sg, logger);
if (flag_dump_analyzer_supergraph)
{
/* Dump supergraph pre-analysis. */
auto_timevar tv (TV_ANALYZER_DUMP);
char *filename = concat (dump_base_name, ".supergraph.dot", NULL);
supergraph::dump_args_t args ((enum supergraph_dot_flags)0, NULL);
sg.dump_dot (filename, args);
free (filename);
}
if (flag_dump_analyzer_state_purge)
{
auto_timevar tv (TV_ANALYZER_DUMP);
state_purge_annotator a (purge_map);
char *filename = concat (dump_base_name, ".state-purge.dot", NULL);
supergraph::dump_args_t args ((enum supergraph_dot_flags)0, &a);
sg.dump_dot (filename, args);
free (filename);
}
auto_delete_vec <state_machine> checkers;
make_checkers (checkers, logger);
plugin_analyzer_init_impl data (&checkers, logger);
invoke_plugin_callbacks (PLUGIN_ANALYZER_INIT, &data);
if (logger)
{
int i;
state_machine *sm;
FOR_EACH_VEC_ELT (checkers, i, sm)
logger->log ("checkers[%i]: %s", i, sm->get_name ());
}
/* Extrinsic state shared by nodes in the graph. */
const extrinsic_state ext_state (checkers, &eng, logger);
const analysis_plan plan (sg, logger);
/* The exploded graph. */
exploded_graph eg (sg, logger, ext_state, purge_map, plan,
analyzer_verbosity);
/* Add entrypoints to the graph for externally-callable functions. */
eg.build_initial_worklist ();
/* Now process the worklist, exploring the <point, state> graph. */
eg.process_worklist ();
if (flag_dump_analyzer_exploded_graph)
{
auto_timevar tv (TV_ANALYZER_DUMP);
char *filename
= concat (dump_base_name, ".eg.dot", NULL);
exploded_graph::dump_args_t args (eg);
root_cluster c;
eg.dump_dot (filename, &c, args);
free (filename);
}
/* Now emit any saved diagnostics. */
eg.get_diagnostic_manager ().emit_saved_diagnostics (eg);
eg.dump_exploded_nodes ();
eg.log_stats ();
if (flag_dump_analyzer_callgraph)
dump_callgraph (sg, &eg);
if (flag_dump_analyzer_supergraph)
{
/* Dump post-analysis form of supergraph. */
auto_timevar tv (TV_ANALYZER_DUMP);
char *filename = concat (dump_base_name, ".supergraph-eg.dot", NULL);
exploded_graph_annotator a (eg);
supergraph::dump_args_t args ((enum supergraph_dot_flags)0, &a);
sg.dump_dot (filename, args);
free (filename);
}
if (flag_dump_analyzer_json)
dump_analyzer_json (sg, eg);
delete purge_map;
}
/* External entrypoint to the analysis "engine".
Set up any dumps, then call impl_run_checkers. */
void
run_checkers ()
{
/* Save input_location. */
location_t saved_input_location = input_location;
/* Handle -fdump-analyzer and -fdump-analyzer-stderr. */
FILE *dump_fout = NULL;
/* Track if we're responsible for closing dump_fout. */
bool owns_dump_fout = false;
if (flag_dump_analyzer_stderr)
dump_fout = stderr;
else if (flag_dump_analyzer)
{
char *dump_filename = concat (dump_base_name, ".analyzer.txt", NULL);
dump_fout = fopen (dump_filename, "w");
free (dump_filename);
if (dump_fout)
owns_dump_fout = true;
}
{
log_user the_logger (NULL);
if (dump_fout)
the_logger.set_logger (new logger (dump_fout, 0, 0,
*global_dc->printer));
LOG_SCOPE (the_logger.get_logger ());
impl_run_checkers (the_logger.get_logger ());
/* end of lifetime of the_logger (so that dump file is closed after the
various dtors run). */
}
if (owns_dump_fout)
fclose (dump_fout);
/* Restore input_location. Subsequent passes may assume that input_location
is some arbitrary value *not* in the block tree, which might be violated
if we didn't restore it. */
input_location = saved_input_location;
}
} // namespace ana
#endif /* #if ENABLE_ANALYZER */
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