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/* Regions of memory.
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 "diagnostic-core.h"
#include "gimple-pretty-print.h"
#include "function.h"
#include "basic-block.h"
#include "gimple.h"
#include "gimple-iterator.h"
#include "diagnostic-core.h"
#include "graphviz.h"
#include "options.h"
#include "cgraph.h"
#include "tree-dfa.h"
#include "stringpool.h"
#include "convert.h"
#include "target.h"
#include "fold-const.h"
#include "tree-pretty-print.h"
#include "diagnostic-color.h"
#include "diagnostic-metadata.h"
#include "tristate.h"
#include "bitmap.h"
#include "selftest.h"
#include "function.h"
#include "json.h"
#include "analyzer/analyzer.h"
#include "analyzer/analyzer-logging.h"
#include "ordered-hash-map.h"
#include "options.h"
#include "cgraph.h"
#include "cfg.h"
#include "digraph.h"
#include "analyzer/supergraph.h"
#include "sbitmap.h"
#include "analyzer/call-string.h"
#include "analyzer/program-point.h"
#include "analyzer/store.h"
#include "analyzer/region.h"
#include "analyzer/region-model.h"
#if ENABLE_ANALYZER
namespace ana {
/* class region and its various subclasses. */
/* class region. */
region::~region ()
{
delete m_cached_offset;
}
/* Compare REG1 and REG2 by id. */
int
region::cmp_ids (const region *reg1, const region *reg2)
{
return (long)reg1->get_id () - (long)reg2->get_id ();
}
/* Determine the base region for this region: when considering bindings
for this region, the base region is the ancestor which identifies
which cluster they should be partitioned into.
Regions within the same struct/union/array are in the same cluster.
Different decls are in different clusters. */
const region *
region::get_base_region () const
{
const region *iter = this;
while (iter)
{
switch (iter->get_kind ())
{
case RK_FIELD:
case RK_ELEMENT:
case RK_OFFSET:
case RK_SIZED:
iter = iter->get_parent_region ();
continue;
case RK_CAST:
iter = iter->dyn_cast_cast_region ()->get_original_region ();
continue;
default:
return iter;
}
}
return iter;
}
/* Return true if get_base_region() == this for this region. */
bool
region::base_region_p () const
{
switch (get_kind ())
{
/* Region kinds representing a descendent of a base region. */
case RK_FIELD:
case RK_ELEMENT:
case RK_OFFSET:
case RK_SIZED:
case RK_CAST:
return false;
default:
return true;
}
}
/* Return true if this region is ELDER or one of its descendents. */
bool
region::descendent_of_p (const region *elder) const
{
const region *iter = this;
while (iter)
{
if (iter == elder)
return true;
if (iter->get_kind () == RK_CAST)
iter = iter->dyn_cast_cast_region ()->get_original_region ();
else
iter = iter->get_parent_region ();
}
return false;
}
/* If this region is a frame_region, or a descendent of one, return it.
Otherwise return NULL. */
const frame_region *
region::maybe_get_frame_region () const
{
const region *iter = this;
while (iter)
{
if (const frame_region *frame_reg = iter->dyn_cast_frame_region ())
return frame_reg;
if (iter->get_kind () == RK_CAST)
iter = iter->dyn_cast_cast_region ()->get_original_region ();
else
iter = iter->get_parent_region ();
}
return NULL;
}
/* Get the memory space of this region. */
enum memory_space
region::get_memory_space () const
{
const region *iter = this;
while (iter)
{
switch (iter->get_kind ())
{
default:
break;
case RK_GLOBALS:
return MEMSPACE_GLOBALS;
case RK_CODE:
case RK_FUNCTION:
case RK_LABEL:
return MEMSPACE_CODE;
case RK_FRAME:
case RK_STACK:
case RK_ALLOCA:
return MEMSPACE_STACK;
case RK_HEAP:
case RK_HEAP_ALLOCATED:
return MEMSPACE_HEAP;
case RK_STRING:
return MEMSPACE_READONLY_DATA;
}
if (iter->get_kind () == RK_CAST)
iter = iter->dyn_cast_cast_region ()->get_original_region ();
else
iter = iter->get_parent_region ();
}
return MEMSPACE_UNKNOWN;
}
/* Subroutine for use by region_model_manager::get_or_create_initial_value.
Return true if this region has an initial_svalue.
Return false if attempting to use INIT_VAL(this_region) should give
the "UNINITIALIZED" poison value. */
bool
region::can_have_initial_svalue_p () const
{
const region *base_reg = get_base_region ();
/* Check for memory spaces that are uninitialized by default. */
enum memory_space mem_space = base_reg->get_memory_space ();
switch (mem_space)
{
default:
gcc_unreachable ();
case MEMSPACE_UNKNOWN:
case MEMSPACE_CODE:
case MEMSPACE_GLOBALS:
case MEMSPACE_READONLY_DATA:
/* Such regions have initial_svalues. */
return true;
case MEMSPACE_HEAP:
/* Heap allocations are uninitialized by default. */
return false;
case MEMSPACE_STACK:
if (tree decl = base_reg->maybe_get_decl ())
{
/* See the assertion in frame_region::get_region_for_local for the
tree codes we need to handle here. */
switch (TREE_CODE (decl))
{
default:
gcc_unreachable ();
case PARM_DECL:
/* Parameters have initial values. */
return true;
case VAR_DECL:
case RESULT_DECL:
/* Function locals don't have initial values. */
return false;
case SSA_NAME:
{
tree ssa_name = decl;
/* SSA names that are the default defn of a PARM_DECL
have initial_svalues; other SSA names don't. */
if (SSA_NAME_IS_DEFAULT_DEF (ssa_name)
&& SSA_NAME_VAR (ssa_name)
&& TREE_CODE (SSA_NAME_VAR (ssa_name)) == PARM_DECL)
return true;
else
return false;
}
}
}
/* If we have an on-stack region that isn't associated with a decl
or SSA name, then we have VLA/alloca, which is uninitialized. */
return false;
}
}
/* If this region is a decl_region, return the decl.
Otherwise return NULL. */
tree
region::maybe_get_decl () const
{
if (const decl_region *decl_reg = dyn_cast_decl_region ())
return decl_reg->get_decl ();
return NULL_TREE;
}
/* Get the region_offset for this region (calculating it on the
first call and caching it internally). */
region_offset
region::get_offset () const
{
if(!m_cached_offset)
m_cached_offset = new region_offset (calc_offset ());
return *m_cached_offset;
}
/* Base class implementation of region::get_byte_size vfunc.
If the size of this region (in bytes) is known statically, write it to *OUT
and return true.
Otherwise return false. */
bool
region::get_byte_size (byte_size_t *out) const
{
tree type = get_type ();
/* Bail out e.g. for heap-allocated regions. */
if (!type)
return false;
HOST_WIDE_INT bytes = int_size_in_bytes (type);
if (bytes == -1)
return false;
*out = bytes;
return true;
}
/* Base implementation of region::get_byte_size_sval vfunc. */
const svalue *
region::get_byte_size_sval (region_model_manager *mgr) const
{
tree type = get_type ();
/* Bail out e.g. for heap-allocated regions. */
if (!type)
return mgr->get_or_create_unknown_svalue (size_type_node);
HOST_WIDE_INT bytes = int_size_in_bytes (type);
if (bytes == -1)
return mgr->get_or_create_unknown_svalue (size_type_node);
tree byte_size = size_in_bytes (type);
if (TREE_TYPE (byte_size) != size_type_node)
byte_size = fold_build1 (NOP_EXPR, size_type_node, byte_size);
return mgr->get_or_create_constant_svalue (byte_size);
}
/* Attempt to get the size of TYPE in bits.
If successful, return true and write the size to *OUT.
Otherwise return false. */
bool
int_size_in_bits (const_tree type, bit_size_t *out)
{
if (INTEGRAL_TYPE_P (type))
{
*out = TYPE_PRECISION (type);
return true;
}
tree sz = TYPE_SIZE (type);
if (sz && tree_fits_uhwi_p (sz))
{
*out = TREE_INT_CST_LOW (sz);
return true;
}
else
return false;
}
/* If the size of this region (in bits) is known statically, write it to *OUT
and return true.
Otherwise return false. */
bool
region::get_bit_size (bit_size_t *out) const
{
tree type = get_type ();
/* Bail out e.g. for heap-allocated regions. */
if (!type)
return false;
return int_size_in_bits (type, out);
}
/* Get the field within RECORD_TYPE at BIT_OFFSET. */
tree
get_field_at_bit_offset (tree record_type, bit_offset_t bit_offset)
{
gcc_assert (TREE_CODE (record_type) == RECORD_TYPE);
if (bit_offset < 0)
return NULL;
/* Find the first field that has an offset > BIT_OFFSET,
then return the one preceding it.
Skip other trees within the chain, such as FUNCTION_DECLs. */
tree last_field = NULL_TREE;
for (tree iter = TYPE_FIELDS (record_type); iter != NULL_TREE;
iter = DECL_CHAIN (iter))
{
if (TREE_CODE (iter) == FIELD_DECL)
{
int iter_field_offset = int_bit_position (iter);
if (bit_offset < iter_field_offset)
return last_field;
last_field = iter;
}
}
return last_field;
}
/* Populate *OUT with descendent regions of type TYPE that match
RELATIVE_BIT_OFFSET and SIZE_IN_BITS within this region. */
void
region::get_subregions_for_binding (region_model_manager *mgr,
bit_offset_t relative_bit_offset,
bit_size_t size_in_bits,
tree type,
auto_vec <const region *> *out) const
{
if (get_type () == NULL_TREE || type == NULL_TREE)
return;
if (relative_bit_offset == 0
&& types_compatible_p (get_type (), type))
{
out->safe_push (this);
return;
}
switch (TREE_CODE (get_type ()))
{
case ARRAY_TYPE:
{
tree element_type = TREE_TYPE (get_type ());
HOST_WIDE_INT hwi_byte_size = int_size_in_bytes (element_type);
if (hwi_byte_size > 0)
{
HOST_WIDE_INT bits_per_element
= hwi_byte_size << LOG2_BITS_PER_UNIT;
HOST_WIDE_INT element_index
= (relative_bit_offset.to_shwi () / bits_per_element);
tree element_index_cst
= build_int_cst (integer_type_node, element_index);
HOST_WIDE_INT inner_bit_offset
= relative_bit_offset.to_shwi () % bits_per_element;
const region *subregion = mgr->get_element_region
(this, element_type,
mgr->get_or_create_constant_svalue (element_index_cst));
subregion->get_subregions_for_binding (mgr, inner_bit_offset,
size_in_bits, type, out);
}
}
break;
case RECORD_TYPE:
{
/* The bit offset might be *within* one of the fields (such as
with nested structs).
So we want to find the enclosing field, adjust the offset,
and repeat. */
if (tree field = get_field_at_bit_offset (get_type (),
relative_bit_offset))
{
int field_bit_offset = int_bit_position (field);
const region *subregion = mgr->get_field_region (this, field);
subregion->get_subregions_for_binding
(mgr, relative_bit_offset - field_bit_offset,
size_in_bits, type, out);
}
}
break;
case UNION_TYPE:
{
for (tree field = TYPE_FIELDS (get_type ()); field != NULL_TREE;
field = DECL_CHAIN (field))
{
if (TREE_CODE (field) != FIELD_DECL)
continue;
const region *subregion = mgr->get_field_region (this, field);
subregion->get_subregions_for_binding (mgr,
relative_bit_offset,
size_in_bits,
type,
out);
}
}
break;
default:
/* Do nothing. */
break;
}
}
/* Walk from this region up to the base region within its cluster, calculating
the offset relative to the base region, either as an offset in bits,
or a symbolic offset. */
region_offset
region::calc_offset () const
{
const region *iter_region = this;
bit_offset_t accum_bit_offset = 0;
while (iter_region)
{
switch (iter_region->get_kind ())
{
case RK_FIELD:
{
const field_region *field_reg
= (const field_region *)iter_region;
iter_region = iter_region->get_parent_region ();
bit_offset_t rel_bit_offset;
if (!field_reg->get_relative_concrete_offset (&rel_bit_offset))
return region_offset::make_symbolic (iter_region);
accum_bit_offset += rel_bit_offset;
}
continue;
case RK_ELEMENT:
{
const element_region *element_reg
= (const element_region *)iter_region;
iter_region = iter_region->get_parent_region ();
bit_offset_t rel_bit_offset;
if (!element_reg->get_relative_concrete_offset (&rel_bit_offset))
return region_offset::make_symbolic (iter_region);
accum_bit_offset += rel_bit_offset;
}
continue;
case RK_OFFSET:
{
const offset_region *offset_reg
= (const offset_region *)iter_region;
iter_region = iter_region->get_parent_region ();
bit_offset_t rel_bit_offset;
if (!offset_reg->get_relative_concrete_offset (&rel_bit_offset))
return region_offset::make_symbolic (iter_region);
accum_bit_offset += rel_bit_offset;
}
continue;
case RK_SIZED:
iter_region = iter_region->get_parent_region ();
continue;
case RK_CAST:
{
const cast_region *cast_reg
= as_a <const cast_region *> (iter_region);
iter_region = cast_reg->get_original_region ();
}
continue;
default:
return region_offset::make_concrete (iter_region, accum_bit_offset);
}
}
return region_offset::make_concrete (iter_region, accum_bit_offset);
}
/* Base implementation of region::get_relative_concrete_offset vfunc. */
bool
region::get_relative_concrete_offset (bit_offset_t *) const
{
return false;
}
/* Copy from SRC_REG to DST_REG, using CTXT for any issues that occur. */
void
region_model::copy_region (const region *dst_reg, const region *src_reg,
region_model_context *ctxt)
{
gcc_assert (dst_reg);
gcc_assert (src_reg);
if (dst_reg == src_reg)
return;
const svalue *sval = get_store_value (src_reg, ctxt);
set_value (dst_reg, sval, ctxt);
}
/* Dump a description of this region to stderr. */
DEBUG_FUNCTION void
region::dump (bool simple) const
{
pretty_printer pp;
pp_format_decoder (&pp) = default_tree_printer;
pp_show_color (&pp) = pp_show_color (global_dc->printer);
pp.buffer->stream = stderr;
dump_to_pp (&pp, simple);
pp_newline (&pp);
pp_flush (&pp);
}
/* Return a new json::string describing the region. */
json::value *
region::to_json () const
{
label_text desc = get_desc (true);
json::value *reg_js = new json::string (desc.m_buffer);
desc.maybe_free ();
return reg_js;
}
/* Generate a description of this region. */
DEBUG_FUNCTION label_text
region::get_desc (bool simple) const
{
pretty_printer pp;
pp_format_decoder (&pp) = default_tree_printer;
dump_to_pp (&pp, simple);
return label_text::take (xstrdup (pp_formatted_text (&pp)));
}
/* Base implementation of region::accept vfunc.
Subclass implementations should chain up to this. */
void
region::accept (visitor *v) const
{
v->visit_region (this);
if (m_parent)
m_parent->accept (v);
}
/* Return true if this is a symbolic region for deferencing an
unknown ptr.
We shouldn't attempt to bind values for this region (but
can unbind values for other regions). */
bool
region::symbolic_for_unknown_ptr_p () const
{
if (const symbolic_region *sym_reg = dyn_cast_symbolic_region ())
if (sym_reg->get_pointer ()->get_kind () == SK_UNKNOWN)
return true;
return false;
}
/* region's ctor. */
region::region (complexity c, unsigned id, const region *parent, tree type)
: m_complexity (c), m_id (id), m_parent (parent), m_type (type),
m_cached_offset (NULL)
{
gcc_assert (type == NULL_TREE || TYPE_P (type));
}
/* Comparator for use by vec<const region *>::qsort,
using their IDs to order them. */
int
region::cmp_ptr_ptr (const void *p1, const void *p2)
{
const region * const *reg1 = (const region * const *)p1;
const region * const *reg2 = (const region * const *)p2;
return cmp_ids (*reg1, *reg2);
}
/* Determine if a pointer to this region must be non-NULL.
Generally, pointers to regions must be non-NULL, but pointers
to symbolic_regions might, in fact, be NULL.
This allows us to simulate functions like malloc and calloc with:
- only one "outcome" from each statement,
- the idea that the pointer is on the heap if non-NULL
- the possibility that the pointer could be NULL
- the idea that successive values returned from malloc are non-equal
- to be able to zero-fill for calloc. */
bool
region::non_null_p () const
{
switch (get_kind ())
{
default:
return true;
case RK_SYMBOLIC:
/* Are we within a symbolic_region? If so, it could be NULL, and we
have to fall back on the constraints. */
return false;
case RK_HEAP_ALLOCATED:
return false;
}
}
/* Return true iff this region is defined in terms of SVAL. */
bool
region::involves_p (const svalue *sval) const
{
if (const symbolic_region *symbolic_reg = dyn_cast_symbolic_region ())
{
if (symbolic_reg->get_pointer ()->involves_p (sval))
return true;
}
return false;
}
/* Comparator for trees to impose a deterministic ordering on
T1 and T2. */
static int
tree_cmp (const_tree t1, const_tree t2)
{
gcc_assert (t1);
gcc_assert (t2);
/* Test tree codes first. */
if (TREE_CODE (t1) != TREE_CODE (t2))
return TREE_CODE (t1) - TREE_CODE (t2);
/* From this point on, we know T1 and T2 have the same tree code. */
if (DECL_P (t1))
{
if (DECL_NAME (t1) && DECL_NAME (t2))
return strcmp (IDENTIFIER_POINTER (DECL_NAME (t1)),
IDENTIFIER_POINTER (DECL_NAME (t2)));
else
{
if (DECL_NAME (t1))
return -1;
else if (DECL_NAME (t2))
return 1;
else
return DECL_UID (t1) - DECL_UID (t2);
}
}
switch (TREE_CODE (t1))
{
case SSA_NAME:
{
if (SSA_NAME_VAR (t1) && SSA_NAME_VAR (t2))
{
int var_cmp = tree_cmp (SSA_NAME_VAR (t1), SSA_NAME_VAR (t2));
if (var_cmp)
return var_cmp;
return SSA_NAME_VERSION (t1) - SSA_NAME_VERSION (t2);
}
else
{
if (SSA_NAME_VAR (t1))
return -1;
else if (SSA_NAME_VAR (t2))
return 1;
else
return SSA_NAME_VERSION (t1) - SSA_NAME_VERSION (t2);
}
}
break;
case INTEGER_CST:
return tree_int_cst_compare (t1, t2);
case REAL_CST:
{
const real_value *rv1 = TREE_REAL_CST_PTR (t1);
const real_value *rv2 = TREE_REAL_CST_PTR (t2);
if (real_compare (UNORDERED_EXPR, rv1, rv2))
{
/* Impose an arbitrary order on NaNs relative to other NaNs
and to non-NaNs. */
if (int cmp_isnan = real_isnan (rv1) - real_isnan (rv2))
return cmp_isnan;
if (int cmp_issignaling_nan
= real_issignaling_nan (rv1) - real_issignaling_nan (rv2))
return cmp_issignaling_nan;
return real_isneg (rv1) - real_isneg (rv2);
}
if (real_compare (LT_EXPR, rv1, rv2))
return -1;
if (real_compare (GT_EXPR, rv1, rv2))
return 1;
return 0;
}
case STRING_CST:
return strcmp (TREE_STRING_POINTER (t1),
TREE_STRING_POINTER (t2));
default:
gcc_unreachable ();
break;
}
gcc_unreachable ();
return 0;
}
/* qsort comparator for trees to impose a deterministic ordering on
P1 and P2. */
int
tree_cmp (const void *p1, const void *p2)
{
const_tree t1 = *(const_tree const *)p1;
const_tree t2 = *(const_tree const *)p2;
return tree_cmp (t1, t2);
}
/* class frame_region : public space_region. */
frame_region::~frame_region ()
{
for (map_t::iterator iter = m_locals.begin ();
iter != m_locals.end ();
++iter)
delete (*iter).second;
}
void
frame_region::accept (visitor *v) const
{
region::accept (v);
if (m_calling_frame)
m_calling_frame->accept (v);
}
/* Implementation of region::dump_to_pp vfunc for frame_region. */
void
frame_region::dump_to_pp (pretty_printer *pp, bool simple) const
{
if (simple)
pp_printf (pp, "frame: %qs@%i", function_name (m_fun), get_stack_depth ());
else
pp_printf (pp, "frame_region(%qs, index: %i, depth: %i)",
function_name (m_fun), m_index, get_stack_depth ());
}
const decl_region *
frame_region::get_region_for_local (region_model_manager *mgr,
tree expr) const
{
// TODO: could also check that VAR_DECLs are locals
gcc_assert (TREE_CODE (expr) == PARM_DECL
|| TREE_CODE (expr) == VAR_DECL
|| TREE_CODE (expr) == SSA_NAME
|| TREE_CODE (expr) == RESULT_DECL);
/* Ideally we'd use mutable here. */
map_t &mutable_locals = const_cast <map_t &> (m_locals);
if (decl_region **slot = mutable_locals.get (expr))
return *slot;
decl_region *reg
= new decl_region (mgr->alloc_region_id (), this, expr);
mutable_locals.put (expr, reg);
return reg;
}
/* class globals_region : public space_region. */
/* Implementation of region::dump_to_pp vfunc for globals_region. */
void
globals_region::dump_to_pp (pretty_printer *pp, bool simple) const
{
if (simple)
pp_string (pp, "::");
else
pp_string (pp, "globals");
}
/* class code_region : public map_region. */
/* Implementation of region::dump_to_pp vfunc for code_region. */
void
code_region::dump_to_pp (pretty_printer *pp, bool simple) const
{
if (simple)
pp_string (pp, "code region");
else
pp_string (pp, "code_region()");
}
/* class function_region : public region. */
/* Implementation of region::dump_to_pp vfunc for function_region. */
void
function_region::dump_to_pp (pretty_printer *pp, bool simple) const
{
if (simple)
{
dump_quoted_tree (pp, m_fndecl);
}
else
{
pp_string (pp, "function_region(");
dump_quoted_tree (pp, m_fndecl);
pp_string (pp, ")");
}
}
/* class label_region : public region. */
/* Implementation of region::dump_to_pp vfunc for label_region. */
void
label_region::dump_to_pp (pretty_printer *pp, bool simple) const
{
if (simple)
{
dump_quoted_tree (pp, m_label);
}
else
{
pp_string (pp, "label_region(");
dump_quoted_tree (pp, m_label);
pp_string (pp, ")");
}
}
/* class stack_region : public region. */
/* Implementation of region::dump_to_pp vfunc for stack_region. */
void
stack_region::dump_to_pp (pretty_printer *pp, bool simple) const
{
if (simple)
pp_string (pp, "stack region");
else
pp_string (pp, "stack_region()");
}
/* class heap_region : public region. */
/* Implementation of region::dump_to_pp vfunc for heap_region. */
void
heap_region::dump_to_pp (pretty_printer *pp, bool simple) const
{
if (simple)
pp_string (pp, "heap region");
else
pp_string (pp, "heap_region()");
}
/* class root_region : public region. */
/* root_region's ctor. */
root_region::root_region (unsigned id)
: region (complexity (1, 1), id, NULL, NULL_TREE)
{
}
/* Implementation of region::dump_to_pp vfunc for root_region. */
void
root_region::dump_to_pp (pretty_printer *pp, bool simple) const
{
if (simple)
pp_string (pp, "root region");
else
pp_string (pp, "root_region()");
}
/* class symbolic_region : public map_region. */
/* symbolic_region's ctor. */
symbolic_region::symbolic_region (unsigned id, region *parent,
const svalue *sval_ptr)
: region (complexity::from_pair (parent, sval_ptr), id, parent,
TREE_TYPE (sval_ptr->get_type ())),
m_sval_ptr (sval_ptr)
{
}
/* Implementation of region::accept vfunc for symbolic_region. */
void
symbolic_region::accept (visitor *v) const
{
region::accept (v);
m_sval_ptr->accept (v);
}
/* Implementation of region::dump_to_pp vfunc for symbolic_region. */
void
symbolic_region::dump_to_pp (pretty_printer *pp, bool simple) const
{
if (simple)
{
pp_string (pp, "(*");
m_sval_ptr->dump_to_pp (pp, simple);
pp_string (pp, ")");
}
else
{
pp_string (pp, "symbolic_region(");
get_parent_region ()->dump_to_pp (pp, simple);
pp_string (pp, ", ");
print_quoted_type (pp, get_type ());
pp_string (pp, ", ");
m_sval_ptr->dump_to_pp (pp, simple);
pp_string (pp, ")");
}
}
/* class decl_region : public region. */
/* Implementation of region::dump_to_pp vfunc for decl_region. */
void
decl_region::dump_to_pp (pretty_printer *pp, bool simple) const
{
if (simple)
pp_printf (pp, "%E", m_decl);
else
{
pp_string (pp, "decl_region(");
get_parent_region ()->dump_to_pp (pp, simple);
pp_string (pp, ", ");
print_quoted_type (pp, get_type ());
pp_printf (pp, ", %qE)", m_decl);
}
}
/* Get the stack depth for the frame containing this decl, or 0
for a global. */
int
decl_region::get_stack_depth () const
{
if (get_parent_region () == NULL)
return 0;
if (const frame_region *frame_reg
= get_parent_region ()->dyn_cast_frame_region ())
return frame_reg->get_stack_depth ();
return 0;
}
/* If the underlying decl is in the global constant pool,
return an svalue representing the constant value.
Otherwise return NULL. */
const svalue *
decl_region::maybe_get_constant_value (region_model_manager *mgr) const
{
if (TREE_CODE (m_decl) == VAR_DECL
&& DECL_IN_CONSTANT_POOL (m_decl)
&& DECL_INITIAL (m_decl)
&& TREE_CODE (DECL_INITIAL (m_decl)) == CONSTRUCTOR)
return get_svalue_for_constructor (DECL_INITIAL (m_decl), mgr);
return NULL;
}
/* Get an svalue for CTOR, a CONSTRUCTOR for this region's decl. */
const svalue *
decl_region::get_svalue_for_constructor (tree ctor,
region_model_manager *mgr) const
{
gcc_assert (!TREE_CLOBBER_P (ctor));
/* Create a binding map, applying ctor to it, using this
decl_region as the base region when building child regions
for offset calculations. */
binding_map map;
if (!map.apply_ctor_to_region (this, ctor, mgr))
return mgr->get_or_create_unknown_svalue (get_type ());
/* Return a compound svalue for the map we built. */
return mgr->get_or_create_compound_svalue (get_type (), map);
}
/* For use on decl_regions for global variables.
Get an svalue for the initial value of this region at entry to
"main" (either based on DECL_INITIAL, or implicit initialization to
zero.
Return NULL if there is a problem. */
const svalue *
decl_region::get_svalue_for_initializer (region_model_manager *mgr) const
{
tree init = DECL_INITIAL (m_decl);
if (!init)
{
/* If we have an "extern" decl then there may be an initializer in
another TU. */
if (DECL_EXTERNAL (m_decl))
return NULL;
/* Implicit initialization to zero; use a compound_svalue for it.
Doing so requires that we have a concrete binding for this region,
which can fail if we have a region with unknown size
(e.g. "extern const char arr[];"). */
const binding_key *binding
= binding_key::make (mgr->get_store_manager (), this);
if (binding->symbolic_p ())
return NULL;
binding_cluster c (this);
c.zero_fill_region (mgr->get_store_manager (), this);
return mgr->get_or_create_compound_svalue (TREE_TYPE (m_decl),
c.get_map ());
}
/* LTO can write out error_mark_node as the DECL_INITIAL for simple scalar
values (to avoid writing out an extra section). */
if (init == error_mark_node)
return NULL;
if (TREE_CODE (init) == CONSTRUCTOR)
return get_svalue_for_constructor (init, mgr);
/* Reuse the get_rvalue logic from region_model. */
region_model m (mgr);
return m.get_rvalue (path_var (init, 0), NULL);
}
/* class field_region : public region. */
/* Implementation of region::dump_to_pp vfunc for field_region. */
void
field_region::dump_to_pp (pretty_printer *pp, bool simple) const
{
if (simple)
{
get_parent_region ()->dump_to_pp (pp, simple);
pp_string (pp, ".");
pp_printf (pp, "%E", m_field);
}
else
{
pp_string (pp, "field_region(");
get_parent_region ()->dump_to_pp (pp, simple);
pp_string (pp, ", ");
print_quoted_type (pp, get_type ());
pp_printf (pp, ", %qE)", m_field);
}
}
/* Implementation of region::get_relative_concrete_offset vfunc
for field_region. */
bool
field_region::get_relative_concrete_offset (bit_offset_t *out) const
{
/* Compare with e.g. gimple-fold.c's
fold_nonarray_ctor_reference. */
tree byte_offset = DECL_FIELD_OFFSET (m_field);
if (TREE_CODE (byte_offset) != INTEGER_CST)
return false;
tree field_offset = DECL_FIELD_BIT_OFFSET (m_field);
/* Compute bit offset of the field. */
offset_int bitoffset
= (wi::to_offset (field_offset)
+ (wi::to_offset (byte_offset) << LOG2_BITS_PER_UNIT));
*out = bitoffset;
return true;
}
/* class element_region : public region. */
/* Implementation of region::accept vfunc for element_region. */
void
element_region::accept (visitor *v) const
{
region::accept (v);
m_index->accept (v);
}
/* Implementation of region::dump_to_pp vfunc for element_region. */
void
element_region::dump_to_pp (pretty_printer *pp, bool simple) const
{
if (simple)
{
//pp_string (pp, "(");
get_parent_region ()->dump_to_pp (pp, simple);
pp_string (pp, "[");
m_index->dump_to_pp (pp, simple);
pp_string (pp, "]");
//pp_string (pp, ")");
}
else
{
pp_string (pp, "element_region(");
get_parent_region ()->dump_to_pp (pp, simple);
pp_string (pp, ", ");
print_quoted_type (pp, get_type ());
pp_string (pp, ", ");
m_index->dump_to_pp (pp, simple);
pp_printf (pp, ")");
}
}
/* Implementation of region::get_relative_concrete_offset vfunc
for element_region. */
bool
element_region::get_relative_concrete_offset (bit_offset_t *out) const
{
if (tree idx_cst = m_index->maybe_get_constant ())
{
gcc_assert (TREE_CODE (idx_cst) == INTEGER_CST);
tree elem_type = get_type ();
offset_int element_idx = wi::to_offset (idx_cst);
/* First, use int_size_in_bytes, to reject the case where we
have an incomplete type, or a non-constant value. */
HOST_WIDE_INT hwi_byte_size = int_size_in_bytes (elem_type);
if (hwi_byte_size > 0)
{
offset_int element_bit_size
= hwi_byte_size << LOG2_BITS_PER_UNIT;
offset_int element_bit_offset
= element_idx * element_bit_size;
*out = element_bit_offset;
return true;
}
}
return false;
}
/* class offset_region : public region. */
/* Implementation of region::accept vfunc for offset_region. */
void
offset_region::accept (visitor *v) const
{
region::accept (v);
m_byte_offset->accept (v);
}
/* Implementation of region::dump_to_pp vfunc for offset_region. */
void
offset_region::dump_to_pp (pretty_printer *pp, bool simple) const
{
if (simple)
{
//pp_string (pp, "(");
get_parent_region ()->dump_to_pp (pp, simple);
pp_string (pp, "+");
m_byte_offset->dump_to_pp (pp, simple);
//pp_string (pp, ")");
}
else
{
pp_string (pp, "offset_region(");
get_parent_region ()->dump_to_pp (pp, simple);
pp_string (pp, ", ");
print_quoted_type (pp, get_type ());
pp_string (pp, ", ");
m_byte_offset->dump_to_pp (pp, simple);
pp_printf (pp, ")");
}
}
/* Implementation of region::get_relative_concrete_offset vfunc
for offset_region. */
bool
offset_region::get_relative_concrete_offset (bit_offset_t *out) const
{
if (tree byte_offset_cst = m_byte_offset->maybe_get_constant ())
{
gcc_assert (TREE_CODE (byte_offset_cst) == INTEGER_CST);
/* Use a signed value for the byte offset, to handle
negative offsets. */
HOST_WIDE_INT byte_offset
= wi::to_offset (byte_offset_cst).to_shwi ();
HOST_WIDE_INT bit_offset = byte_offset * BITS_PER_UNIT;
*out = bit_offset;
return true;
}
return false;
}
/* class sized_region : public region. */
/* Implementation of region::accept vfunc for sized_region. */
void
sized_region::accept (visitor *v) const
{
region::accept (v);
m_byte_size_sval->accept (v);
}
/* Implementation of region::dump_to_pp vfunc for sized_region. */
void
sized_region::dump_to_pp (pretty_printer *pp, bool simple) const
{
if (simple)
{
pp_string (pp, "SIZED_REG(");
get_parent_region ()->dump_to_pp (pp, simple);
pp_string (pp, ", ");
m_byte_size_sval->dump_to_pp (pp, simple);
pp_string (pp, ")");
}
else
{
pp_string (pp, "sized_region(");
get_parent_region ()->dump_to_pp (pp, simple);
pp_string (pp, ", ");
m_byte_size_sval->dump_to_pp (pp, simple);
pp_printf (pp, ")");
}
}
/* Implementation of region::get_byte_size vfunc for sized_region. */
bool
sized_region::get_byte_size (byte_size_t *out) const
{
if (tree cst = m_byte_size_sval->maybe_get_constant ())
{
gcc_assert (TREE_CODE (cst) == INTEGER_CST);
*out = tree_to_uhwi (cst);
return true;
}
return false;
}
/* Implementation of region::get_bit_size vfunc for sized_region. */
bool
sized_region::get_bit_size (bit_size_t *out) const
{
byte_size_t byte_size;
if (!get_byte_size (&byte_size))
return false;
*out = byte_size * BITS_PER_UNIT;
return true;
}
/* class cast_region : public region. */
/* Implementation of region::accept vfunc for cast_region. */
void
cast_region::accept (visitor *v) const
{
region::accept (v);
m_original_region->accept (v);
}
/* Implementation of region::dump_to_pp vfunc for cast_region. */
void
cast_region::dump_to_pp (pretty_printer *pp, bool simple) const
{
if (simple)
{
pp_string (pp, "CAST_REG(");
print_quoted_type (pp, get_type ());
pp_string (pp, ", ");
m_original_region->dump_to_pp (pp, simple);
pp_string (pp, ")");
}
else
{
pp_string (pp, "cast_region(");
m_original_region->dump_to_pp (pp, simple);
pp_string (pp, ", ");
print_quoted_type (pp, get_type ());
pp_printf (pp, ")");
}
}
/* class heap_allocated_region : public region. */
/* Implementation of region::dump_to_pp vfunc for heap_allocated_region. */
void
heap_allocated_region::dump_to_pp (pretty_printer *pp, bool simple) const
{
if (simple)
pp_printf (pp, "HEAP_ALLOCATED_REGION(%i)", get_id ());
else
pp_printf (pp, "heap_allocated_region(%i)", get_id ());
}
/* class alloca_region : public region. */
/* Implementation of region::dump_to_pp vfunc for alloca_region. */
void
alloca_region::dump_to_pp (pretty_printer *pp, bool simple) const
{
if (simple)
pp_string (pp, "ALLOCA_REGION");
else
pp_string (pp, "alloca_region()");
}
/* class string_region : public region. */
/* Implementation of region::dump_to_pp vfunc for string_region. */
void
string_region::dump_to_pp (pretty_printer *pp, bool simple) const
{
if (simple)
dump_tree (pp, m_string_cst);
else
{
pp_string (pp, "string_region(");
dump_tree (pp, m_string_cst);
if (!flag_dump_noaddr)
{
pp_string (pp, " (");
pp_pointer (pp, m_string_cst);
pp_string (pp, "))");
}
}
}
/* class unknown_region : public region. */
/* Implementation of region::dump_to_pp vfunc for unknown_region. */
void
unknown_region::dump_to_pp (pretty_printer *pp, bool /*simple*/) const
{
pp_string (pp, "UNKNOWN_REGION");
}
} // namespace ana
#endif /* #if ENABLE_ANALYZER */