/* Consolidation of svalues and regions.
Copyright (C) 2020-2025 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/>. */
#ifndef GCC_ANALYZER_REGION_MODEL_MANAGER_H
#define GCC_ANALYZER_REGION_MODEL_MANAGER_H
namespace ana {
/* A class responsible for owning and consolidating region and svalue
instances.
region and svalue instances are immutable as far as clients are
concerned, so they are provided as "const" ptrs. */
class region_model_manager
{
public:
region_model_manager (logger *logger = NULL);
~region_model_manager ();
unsigned get_num_symbols () const { return m_next_symbol_id; }
unsigned alloc_symbol_id () { return m_next_symbol_id++; }
/* call_string consolidation. */
const call_string &get_empty_call_string () const
{
return m_empty_call_string;
}
/* svalue consolidation. */
const svalue *get_or_create_constant_svalue (tree type, tree cst_expr);
const svalue *get_or_create_constant_svalue (tree cst_expr);
const svalue *get_or_create_int_cst (tree type, const poly_wide_int_ref &cst);
const svalue *get_or_create_null_ptr (tree pointer_type);
const svalue *get_or_create_unknown_svalue (tree type);
const svalue *get_or_create_setjmp_svalue (const setjmp_record &r,
tree type);
const svalue *get_or_create_poisoned_svalue (enum poison_kind kind,
tree type);
const svalue *get_or_create_initial_value (const region *reg,
bool check_poisoned = true);
const svalue *get_ptr_svalue (tree ptr_type, const region *pointee);
const svalue *get_or_create_unaryop (tree type, enum tree_code op,
const svalue *arg);
const svalue *get_or_create_cast (tree type, const svalue *arg);
const svalue *get_or_create_binop (tree type,
enum tree_code op,
const svalue *arg0, const svalue *arg1);
const svalue *get_or_create_sub_svalue (tree type,
const svalue *parent_svalue,
const region *subregion);
const svalue *get_or_create_repeated_svalue (tree type,
const svalue *outer_size,
const svalue *inner_svalue);
const svalue *get_or_create_bits_within (tree type,
const bit_range &bits,
const svalue *inner_svalue);
const svalue *get_or_create_unmergeable (const svalue *arg);
const svalue *get_or_create_widening_svalue (tree type,
const function_point &point,
const svalue *base_svalue,
const svalue *iter_svalue);
const svalue *get_or_create_compound_svalue (tree type,
const binding_map &map);
const svalue *get_or_create_conjured_svalue (tree type, const gimple *stmt,
const region *id_reg,
const conjured_purge &p,
unsigned idx = 0);
const svalue *
get_or_create_asm_output_svalue (tree type,
const gasm *asm_stmt,
unsigned output_idx,
const vec<const svalue *> &inputs);
const svalue *
get_or_create_asm_output_svalue (tree type,
const char *asm_string,
unsigned output_idx,
unsigned num_outputs,
const vec<const svalue *> &inputs);
const svalue *
get_or_create_const_fn_result_svalue (tree type,
tree fndecl,
const vec<const svalue *> &inputs);
const svalue *maybe_get_char_from_cst (tree data_cst,
tree byte_offset_cst);
const svalue *maybe_get_char_from_string_cst (tree string_cst,
tree byte_offset_cst);
const svalue *maybe_get_char_from_raw_data_cst (tree raw_data_cst,
tree byte_offset_cst);
/* Dynamically-allocated svalue instances.
The number of these within the analysis can grow arbitrarily.
They are still owned by the manager. */
const svalue *create_unique_svalue (tree type);
/* region consolidation. */
const root_region *get_root_region () const { return &m_root_region; }
const stack_region * get_stack_region () const { return &m_stack_region; }
const heap_region *get_heap_region () const { return &m_heap_region; }
const code_region *get_code_region () const { return &m_code_region; }
const globals_region *get_globals_region () const
{
return &m_globals_region;
}
const errno_region *get_errno_region () const { return &m_errno_region; }
const function_region *get_region_for_fndecl (tree fndecl);
const label_region *get_region_for_label (tree label);
const decl_region *get_region_for_global (tree expr);
const region *get_field_region (const region *parent, tree field);
const region *get_element_region (const region *parent,
tree element_type,
const svalue *index);
const region *get_offset_region (const region *parent,
tree type,
const svalue *byte_offset);
const region *get_sized_region (const region *parent,
tree type,
const svalue *byte_size_sval);
const region *get_cast_region (const region *original_region,
tree type);
const frame_region *get_frame_region (const frame_region *calling_frame,
const function &fun);
const region *get_symbolic_region (const svalue *sval);
const string_region *get_region_for_string (tree string_cst);
const region *get_bit_range (const region *parent, tree type,
const bit_range &bits);
const var_arg_region *get_var_arg_region (const frame_region *parent,
unsigned idx);
const region *get_unknown_symbolic_region (tree region_type);
const region *
get_region_for_unexpected_tree_code (region_model_context *ctxt,
tree t,
const dump_location_t &loc);
store_manager *get_store_manager () { return &m_store_mgr; }
bounded_ranges_manager *get_range_manager () const { return m_range_mgr; }
known_function_manager *get_known_function_manager ()
{
return &m_known_fn_mgr;
}
/* Dynamically-allocated region instances.
The number of these within the analysis can grow arbitrarily.
They are still owned by the manager. */
const region *
get_or_create_region_for_heap_alloc (const bitmap &base_regs_in_use);
const region *create_region_for_alloca (const frame_region *frame);
void log_stats (logger *logger, bool show_objs) const;
void begin_checking_feasibility (void) { m_checking_feasibility = true; }
void end_checking_feasibility (void) { m_checking_feasibility = false; }
logger *get_logger () const { return m_logger; }
void dump_untracked_regions () const;
const svalue *maybe_fold_binop (tree type, enum tree_code op,
const svalue *arg0, const svalue *arg1);
private:
bool too_complex_p (const complexity &c) const;
bool reject_if_too_complex (svalue *sval);
const svalue *maybe_fold_unaryop (tree type, enum tree_code op,
const svalue *arg);
const svalue *maybe_fold_sub_svalue (tree type,
const svalue *parent_svalue,
const region *subregion);
const svalue *maybe_fold_repeated_svalue (tree type,
const svalue *outer_size,
const svalue *inner_svalue);
const svalue *maybe_fold_bits_within_svalue (tree type,
const bit_range &bits,
const svalue *inner_svalue);
const svalue *maybe_undo_optimize_bit_field_compare (tree type,
const compound_svalue *compound_sval,
tree cst, const svalue *arg1);
const svalue *maybe_fold_asm_output_svalue (tree type,
const vec<const svalue *> &inputs);
logger *m_logger;
unsigned m_next_symbol_id;
const call_string m_empty_call_string;
root_region m_root_region;
stack_region m_stack_region;
heap_region m_heap_region;
/* svalue consolidation. */
typedef hash_map<constant_svalue::key_t, constant_svalue *> constants_map_t;
constants_map_t m_constants_map;
typedef hash_map<tree, unknown_svalue *> unknowns_map_t;
unknowns_map_t m_unknowns_map;
const unknown_svalue *m_unknown_NULL;
typedef hash_map<poisoned_svalue::key_t,
poisoned_svalue *> poisoned_values_map_t;
poisoned_values_map_t m_poisoned_values_map;
typedef hash_map<setjmp_svalue::key_t,
setjmp_svalue *> setjmp_values_map_t;
setjmp_values_map_t m_setjmp_values_map;
typedef hash_map<const region *, initial_svalue *> initial_values_map_t;
initial_values_map_t m_initial_values_map;
typedef hash_map<region_svalue::key_t, region_svalue *> pointer_values_map_t;
pointer_values_map_t m_pointer_values_map;
typedef hash_map<unaryop_svalue::key_t,
unaryop_svalue *> unaryop_values_map_t;
unaryop_values_map_t m_unaryop_values_map;
typedef hash_map<binop_svalue::key_t, binop_svalue *> binop_values_map_t;
binop_values_map_t m_binop_values_map;
typedef hash_map<sub_svalue::key_t, sub_svalue *> sub_values_map_t;
sub_values_map_t m_sub_values_map;
typedef hash_map<repeated_svalue::key_t,
repeated_svalue *> repeated_values_map_t;
repeated_values_map_t m_repeated_values_map;
typedef hash_map<bits_within_svalue::key_t,
bits_within_svalue *> bits_within_values_map_t;
bits_within_values_map_t m_bits_within_values_map;
typedef hash_map<const svalue *,
unmergeable_svalue *> unmergeable_values_map_t;
unmergeable_values_map_t m_unmergeable_values_map;
typedef hash_map<widening_svalue::key_t,
widening_svalue */*,
widening_svalue::key_t::hash_map_traits*/>
widening_values_map_t;
widening_values_map_t m_widening_values_map;
typedef hash_map<compound_svalue::key_t,
compound_svalue *> compound_values_map_t;
compound_values_map_t m_compound_values_map;
typedef hash_map<conjured_svalue::key_t,
conjured_svalue *> conjured_values_map_t;
conjured_values_map_t m_conjured_values_map;
typedef hash_map<asm_output_svalue::key_t,
asm_output_svalue *> asm_output_values_map_t;
asm_output_values_map_t m_asm_output_values_map;
typedef hash_map<const_fn_result_svalue::key_t,
const_fn_result_svalue *> const_fn_result_values_map_t;
const_fn_result_values_map_t m_const_fn_result_values_map;
bool m_checking_feasibility;
/* "Dynamically-allocated" svalue instances.
The number of these within the analysis can grow arbitrarily.
They are still owned by the manager. */
auto_delete_vec<svalue> m_managed_dynamic_svalues;
/* Maximum complexity of svalues that weren't rejected. */
complexity m_max_complexity;
/* region consolidation. */
code_region m_code_region;
typedef hash_map<tree, function_region *> fndecls_map_t;
typedef fndecls_map_t::iterator fndecls_iterator_t;
fndecls_map_t m_fndecls_map;
typedef hash_map<tree, label_region *> labels_map_t;
typedef labels_map_t::iterator labels_iterator_t;
labels_map_t m_labels_map;
globals_region m_globals_region;
typedef hash_map<tree, decl_region *> globals_map_t;
typedef globals_map_t::iterator globals_iterator_t;
globals_map_t m_globals_map;
thread_local_region m_thread_local_region;
errno_region m_errno_region;
consolidation_map<field_region> m_field_regions;
consolidation_map<element_region> m_element_regions;
consolidation_map<offset_region> m_offset_regions;
consolidation_map<sized_region> m_sized_regions;
consolidation_map<cast_region> m_cast_regions;
consolidation_map<frame_region> m_frame_regions;
consolidation_map<symbolic_region> m_symbolic_regions;
typedef hash_map<tree, string_region *> string_map_t;
string_map_t m_string_map;
consolidation_map<bit_range_region> m_bit_range_regions;
consolidation_map<var_arg_region> m_var_arg_regions;
store_manager m_store_mgr;
bounded_ranges_manager *m_range_mgr;
known_function_manager m_known_fn_mgr;
/* "Dynamically-allocated" region instances.
The number of these within the analysis can grow arbitrarily.
They are still owned by the manager. */
auto_delete_vec<region> m_managed_dynamic_regions;
};
} // namespace ana
#endif /* GCC_ANALYZER_REGION_MODEL_MANAGER_H */