Module InferIR.Sil

module F = Format

Programs and Types

type if_kind =
| Ik_bexp

(** boolean expressions, and exp ? exp : exp *)

| Ik_dowhile
| Ik_for
| Ik_if
| Ik_land_lor

(** obtained from translation of && or || *)

| Ik_while
| Ik_switch

Kind of prune instruction

include sig ... end
val compare_if_kind : if_kind ‑> if_kind ‑> int
val is_loop : if_kind ‑> bool
type instr =
| Load of Ident.t * Exp.t * Typ.t * InferBase.Location.t

(** Load a value from the heap into an identifier. x = *lexp:typ where lexp is an expression denoting a heap address typ is the root type of lexp. *)

| Store of Exp.t * Typ.t * Exp.t * InferBase.Location.t

(** Store the value of an expression into the heap. *lexp1:typ = exp2 where lexp1 is an expression denoting a heap address typ is the root type of lexp1exp2 is the expression whose value is store. *)

| Prune of Exp.t * InferBase.Location.t * bool * if_kind

(** prune the state based on exp=1, the boolean indicates whether true branch *)

| Call of Ident.t * Typ.t * Exp.t * (Exp.t * Typ.t) list * InferBase.Location.t * CallFlags.t

(** Call ((ret_id, ret_typ), e_fun, arg_ts, loc, call_flags) represents an instruction ret_id = e_fun(arg_ts); *)

| Nullify of Pvar.t * InferBase.Location.t

(** nullify stack variable *)

| Abstract of InferBase.Location.t

(** apply abstraction *)

| Remove_temps of Ident.t list * InferBase.Location.t

(** remove temporaries *)

| Declare_locals of (Pvar.t * Typ.t) list * InferBase.Location.t

(** declare local variables *)

An instruction.

include sig ... end
val compare_instr : instr ‑> instr ‑> int
val equal_instr : instr ‑> instr ‑> bool
val skip_instr : instr
val instr_is_auxiliary : instr ‑> bool

Check if an instruction is auxiliary, or if it comes from source instructions.

type offset =
| Off_fld of Typ.Fieldname.t * Typ.t
| Off_index of Exp.t

Offset for an lvalue.

Components of Propositions

type atom =
| Aeq of Exp.t * Exp.t

(** equality *)

| Aneq of Exp.t * Exp.t

(** disequality *)

| Apred of PredSymb.t * Exp.t list

(** predicate symbol applied to exps *)

| Anpred of PredSymb.t * Exp.t list

(** negated predicate symbol applied to exps *)

an atom is a pure atomic formula

include sig ... end
val compare_atom : atom ‑> atom ‑> int
val equal_atom : atom ‑> atom ‑> bool
val atom_has_local_addr : atom ‑> bool
type lseg_kind =
| Lseg_NE

(** nonempty (possibly circular) listseg *)

| Lseg_PE

(** possibly empty (possibly circular) listseg *)

kind of lseg or dllseg predicates

include sig ... end
val compare_lseg_kind : lseg_kind ‑> lseg_kind ‑> int
val equal_lseg_kind : lseg_kind ‑> lseg_kind ‑> bool
type zero_flag = bool option

The boolean is true when the pointer was dereferenced without testing for zero.

type null_case_flag = bool

True when the value was obtained by doing case analysis on null in a procedure call.

type inst =
| Iabstraction
| Iactual_precondition
| Ialloc
| Iformal of zero_flag * null_case_flag
| Iinitial
| Ilookup
| Inone
| Inullify
| Irearrange of zero_flag * null_case_flag * int * PredSymb.path_pos
| Itaint
| Iupdate of zero_flag * null_case_flag * int * PredSymb.path_pos
| Ireturn_from_call of int

instrumentation of heap values

include sig ... end
val compare_inst : inst ‑> inst ‑> int
val equal_inst : inst ‑> inst ‑> bool
val inst_actual_precondition : inst
val inst_formal : inst
val inst_initial : inst

for formal parameters and heap values at the beginning of the function

val inst_lookup : inst

for initial values

val inst_none : inst
val inst_nullify : inst
val inst_rearrange : bool ‑> InferBase.Location.t ‑> PredSymb.path_pos ‑> inst

the boolean indicates whether the pointer is known nonzero

val inst_update : InferBase.Location.t ‑> PredSymb.path_pos ‑> inst
val inst_set_null_case_flag : inst ‑> inst

Set the null case flag of the inst.

val inst_new_loc : InferBase.Location.t ‑> inst ‑> inst

update the location of the instrumentation

val update_inst : inst ‑> inst ‑> inst

Update inst_old to inst_new preserving the zero flag

exception JoinFail
val inst_partial_join : inst ‑> inst ‑> inst

join of instrumentations, can raise JoinFail

val inst_partial_meet : inst ‑> inst ‑> inst

meet of instrumentations

type 'inst strexp0 =
| Eexp of Exp.t * 'inst

(** Base case: expression with instrumentation *)

| Estruct of (Typ.Fieldname.t * 'inst strexp0) list * 'inst

(** C structure *)

| Earray of Exp.t * (Exp.t * 'inst strexp0) list * 'inst

(** Array of given length There are two conditions imposed / used in the array case. First, if some index and value pair appears inside an array in a strexp, then the index is less than the length of the array. For instance, x |->10 | e1: v1 implies that e1 <= 9. Second, if two indices appear in an array, they should be different. For instance, x |->10 | e1: v1, e2: v2 implies that e1 != e2. *)

structured expressions represent a value of structured type, such as an array or a struct.

include sig ... end
val compare_strexp0 : ('inst ‑> 'inst ‑> int) ‑> 'inst strexp0 ‑> 'inst strexp0 ‑> int
type strexp = inst strexp0
val compare_strexp : ?⁠inst:bool ‑> strexp ‑> strexp ‑> int

Comparison function for strexp. The inst:: parameter specifies whether instumentations should also be considered (false by default).

val equal_strexp : ?⁠inst:bool ‑> strexp ‑> strexp ‑> bool

Equality function for strexp. The inst:: parameter specifies whether instumentations should also be considered (false by default).

type 'inst hpred0 =
| Hpointsto of Exp.t * 'inst strexp0 * Exp.t

(** represents exp|->strexp:typexp where typexp is an expression representing a type, e.h. sizeof(t). *)

| Hlseg of lseg_kind * 'inst hpara0 * Exp.t * Exp.t * Exp.t list

(** higher - order predicate for singly - linked lists. Should ensure that exp1!= exp2 implies that exp1 is allocated. This assumption is used in the rearrangement. The last exp list parameter is used to denote the shared links by all the nodes in the list. *)

| Hdllseg of lseg_kind * 'inst hpara_dll0 * Exp.t * Exp.t * Exp.t * Exp.t * Exp.t list

(** higher-order predicate for doubly-linked lists. Parameter for the higher-order singly-linked list predicate. Means "lambda (root,next,svars). Exists evars. body". Assume that root, next, svars, evars are disjoint sets of primed identifiers, and include all the free primed identifiers in body. body should not contain any non - primed identifiers or program variables (i.e. pvars). *)

an atomic heap predicate

type 'inst hpara0 = {
root : Ident.t;
next : Ident.t;
svars : Ident.t list;
evars : Ident.t list;
body : 'inst hpred0 list;
}
type 'inst hpara_dll0 = {
cell : Ident.t;

(** address cell *)

svars_dll : Ident.t list;
evars_dll : Ident.t list;
body_dll : 'inst hpred0 list;
}

parameter for the higher-order doubly-linked list predicates. Assume that all the free identifiers in body_dll should belong to cell, blink, flink, svars_dll, evars_dll.

include sig ... end
val compare_hpred0 : ('inst ‑> 'inst ‑> int) ‑> 'inst hpred0 ‑> 'inst hpred0 ‑> int
val compare_hpara0 : ('inst ‑> 'inst ‑> int) ‑> 'inst hpara0 ‑> 'inst hpara0 ‑> int
val compare_hpara_dll0 : ('inst ‑> 'inst ‑> int) ‑> 'inst hpara_dll0 ‑> 'inst hpara_dll0 ‑> int
val compare_hpred0 : ('inst ‑> 'inst ‑> int) ‑> 'inst hpred0 ‑> 'inst hpred0 ‑> int
val compare_hpara0 : ('inst ‑> 'inst ‑> int) ‑> 'inst hpara0 ‑> 'inst hpara0 ‑> int
val compare_hpara_dll0 : ('inst ‑> 'inst ‑> int) ‑> 'inst hpara_dll0 ‑> 'inst hpara_dll0 ‑> int
val compare_hpred0 : ('inst ‑> 'inst ‑> int) ‑> 'inst hpred0 ‑> 'inst hpred0 ‑> int
val compare_hpara0 : ('inst ‑> 'inst ‑> int) ‑> 'inst hpara0 ‑> 'inst hpara0 ‑> int
val compare_hpara_dll0 : ('inst ‑> 'inst ‑> int) ‑> 'inst hpara_dll0 ‑> 'inst hpara_dll0 ‑> int
type hpred = inst hpred0
type hpara = inst hpara0
type hpara_dll = inst hpara_dll0
val compare_hpred : ?⁠inst:bool ‑> hpred ‑> hpred ‑> int

Comparison function for hpred. The inst:: parameter specifies whether instumentations should also be considered (false by default).

val equal_hpred : ?⁠inst:bool ‑> hpred ‑> hpred ‑> bool

Equality function for hpred. The inst:: parameter specifies whether instumentations should also be considered (false by default).

module HpredSet : InferStdlib.IStd.Caml.Set.S with type HpredSet.elt = hpred

Sets of heap predicates

Compaction

type sharing_env
val create_sharing_env : unit ‑> sharing_env

Create a sharing env to store canonical representations

val hpred_compact : sharing_env ‑> hpred ‑> hpred

Return a compact representation of the exp

val is_objc_object : hpred ‑> bool

Comparision And Inspection Functions

val is_static_local_name : string ‑> Pvar.t ‑> bool

Check if a pvar is a local static in objc

val is_block_pvar : Pvar.t ‑> bool

Check if a pvar is a local pointing to a block in objc

val add_with_block_parameters_flag : instr ‑> instr

Adds a with_blocks_parameters flag to a method call, when the arguments contain an Objective-C block, and the method is an Objective-C method (to be extended to other methods)

Pretty Printing

val color_pre_wrapper : InferStdlib.Pp.env ‑> F.formatter ‑> 'a ‑> InferStdlib.Pp.env * bool

Begin change color if using diff printing, return updated printenv and change status

val color_post_wrapper : bool ‑> F.formatter ‑> unit

Close color annotation if changed

val pp_exp_printenv : InferStdlib.Pp.env ‑> F.formatter ‑> Exp.t ‑> unit

Pretty print an expression.

val d_exp : Exp.t ‑> unit

dump an expression.

val pp_texp : InferStdlib.Pp.env ‑> F.formatter ‑> Exp.t ‑> unit

Pretty print a type.

val pp_texp_full : InferStdlib.Pp.env ‑> F.formatter ‑> Exp.t ‑> unit

Pretty print a type with all the details.

val d_texp_full : Exp.t ‑> unit

Dump a type expression with all the details.

val pp_exp_list : InferStdlib.Pp.env ‑> F.formatter ‑> Exp.t list ‑> unit

Pretty print a list of expressions.

val d_exp_list : Exp.t list ‑> unit

Dump a list of expressions.

val pp_offset : InferStdlib.Pp.env ‑> F.formatter ‑> offset ‑> unit

Pretty print an offset

val offset_to_string : offset ‑> string

Convert an offset to a string

val pp_offset_list : InferStdlib.Pp.env ‑> F.formatter ‑> offset list ‑> unit

Pretty print a list of offsets

val d_offset_list : offset list ‑> unit

Dump a list of offsets

val instr_get_loc : instr ‑> InferBase.Location.t

Get the location of the instruction

val instr_get_exps : instr ‑> Exp.t list

get the expressions occurring in the instruction

val if_kind_to_string : if_kind ‑> string

Pretty print an if_kind

val pp_instr : InferStdlib.Pp.env ‑> F.formatter ‑> instr ‑> unit

Pretty print an instruction.

val d_instr : instr ‑> unit

Dump an instruction.

val pp_atom : InferStdlib.Pp.env ‑> F.formatter ‑> atom ‑> unit

Pretty print an atom.

val d_atom : atom ‑> unit

Dump an atom.

val inst_to_string : inst ‑> string

return a string representing the inst

val pp_sexp : InferStdlib.Pp.env ‑> F.formatter ‑> strexp ‑> unit

Pretty print a strexp.

val d_sexp : strexp ‑> unit

Dump a strexp.

val pp_sexp_list : InferStdlib.Pp.env ‑> F.formatter ‑> strexp list ‑> unit

Pretty print a strexp list.

val pp_hpred : InferStdlib.Pp.env ‑> F.formatter ‑> hpred ‑> unit

Pretty print a hpred.

val d_hpred : hpred ‑> unit

Dump a hpred.

val pp_hpara : InferStdlib.Pp.env ‑> F.formatter ‑> hpara ‑> unit

Pretty print a hpara.

val pp_hpara_dll : InferStdlib.Pp.env ‑> F.formatter ‑> hpara_dll ‑> unit

Pretty print a hpara_dll.

module Predicates : sig ... end

Module Predicates records the occurrences of predicates as parameters of (doubly -)linked lists and Epara. Provides unique numbering for predicates and an iterator.

val pp_hpred_env : InferStdlib.Pp.env ‑> Predicates.env option ‑> F.formatter ‑> hpred ‑> unit

Pretty print a hpred with optional predicate env

Functions for traversing SIL data types

val array_clean_new_index : bool ‑> Exp.t ‑> Exp.t

This function should be used before adding a new index to Earray. The exp is the newly created index. This function "cleans" exp according to whether it is the footprint or current part of the prop. The function faults in the re - execution mode, as an internal check of the tool.

val strexp_expmap : ((Exp.t * inst option) ‑> Exp.t * inst option) ‑> strexp ‑> strexp

Change exps in strexp using f. WARNING: the result might not be normalized.

val hpred_expmap : ((Exp.t * inst option) ‑> Exp.t * inst option) ‑> hpred ‑> hpred

Change exps in hpred by f. WARNING: the result might not be normalized.

val hpred_instmap : (inst ‑> inst) ‑> hpred ‑> hpred

Change instrumentations in hpred using f.

val hpred_list_expmap : ((Exp.t * inst option) ‑> Exp.t * inst option) ‑> hpred list ‑> hpred list

Change exps in hpred list by f. WARNING: the result might not be normalized.

val atom_expmap : (Exp.t ‑> Exp.t) ‑> atom ‑> atom

Change exps in atom by f. WARNING: the result might not be normalized.

val hpred_list_get_lexps : (Exp.t ‑> bool) ‑> hpred list ‑> Exp.t list
val hpred_entries : hpred ‑> Exp.t list
val atom_free_vars : atom ‑> Ident.t InferStdlib.IStd.Sequence.t
val atom_gen_free_vars : atom ‑> (unit, Ident.tInferStdlib.IStd.Sequence.Generator.t
val hpred_free_vars : hpred ‑> Ident.t InferStdlib.IStd.Sequence.t
val hpred_gen_free_vars : hpred ‑> (unit, Ident.tInferStdlib.IStd.Sequence.Generator.t
val hpara_shallow_free_vars : hpara ‑> Ident.t InferStdlib.IStd.Sequence.t
val hpara_dll_shallow_free_vars : hpara_dll ‑> Ident.t InferStdlib.IStd.Sequence.t

Variables in hpara_dll, excluding bound vars in the body

Substitution

type exp_subst = private (Ident.t * Exp.t) list
include sig ... end
val compare_exp_subst : exp_subst ‑> exp_subst ‑> int
type subst = [
| `Exp of exp_subst
| `Typ of Typ.type_subst_t
]
include sig ... end
val compare_subst : subst ‑> subst ‑> int
val equal_exp_subst : exp_subst ‑> exp_subst ‑> bool

Equality for substitutions.

val exp_subst_of_list : (Ident.t * Exp.t) list ‑> exp_subst

Create a substitution from a list of pairs. For all (id1, e1), (id2, e2) in the input list, if id1 = id2, then e1 = e2.

val subst_of_list : (Ident.t * Exp.t) list ‑> subst
val exp_subst_of_list_duplicates : (Ident.t * Exp.t) list ‑> exp_subst

like exp_subst_of_list, but allow duplicate ids and only keep the first occurrence

val sub_to_list : exp_subst ‑> (Ident.t * Exp.t) list

Convert a subst to a list of pairs.

val sub_empty : subst

The empty substitution.

val exp_sub_empty : exp_subst
val is_sub_empty : subst ‑> bool
val sub_join : exp_subst ‑> exp_subst ‑> exp_subst

Compute the common id-exp part of two inputs subst1 and subst2. The first component of the output is this common part. The second and third components are the remainder of subst1 and subst2, respectively.

val sub_symmetric_difference : exp_subst ‑> exp_subst ‑> exp_subst * exp_subst * exp_subst

Compute the common id-exp part of two inputs subst1 and subst2. The first component of the output is this common part. The second and third components are the remainder of subst1 and subst2, respectively.

val sub_find : (Ident.t ‑> bool) ‑> exp_subst ‑> Exp.t

sub_find filter sub returns the expression associated to the first identifier that satisfies filter. Raise Not_found if there isn't one.

val sub_filter : (Ident.t ‑> bool) ‑> exp_subst ‑> exp_subst

sub_filter filter sub restricts the domain of sub to the identifiers satisfying filter.

val sub_filter_pair : exp_subst ‑> f:((Ident.t * Exp.t) ‑> bool) ‑> exp_subst

sub_filter_exp filter sub restricts the domain of sub to the identifiers satisfying filter(id, sub(id)).

val sub_range_partition : (Exp.t ‑> bool) ‑> exp_subst ‑> exp_subst * exp_subst

sub_range_partition filter sub partitions sub according to whether range expressions satisfy filter.

val sub_domain_partition : (Ident.t ‑> bool) ‑> exp_subst ‑> exp_subst * exp_subst

sub_domain_partition filter sub partitions sub according to whether domain identifiers satisfy filter.

val sub_domain : exp_subst ‑> Ident.t list

Return the list of identifiers in the domain of the substitution.

val sub_range : exp_subst ‑> Exp.t list

Return the list of expressions in the range of the substitution.

val sub_range_map : (Exp.t ‑> Exp.t) ‑> exp_subst ‑> exp_subst

sub_range_map f sub applies f to the expressions in the range of sub.

val sub_map : (Ident.t ‑> Ident.t) ‑> (Exp.t ‑> Exp.t) ‑> exp_subst ‑> exp_subst

sub_map f g sub applies the renaming f to identifiers in the domain of sub and the substitution g to the expressions in the range of sub.

val extend_sub : exp_subst ‑> Ident.t ‑> Exp.t ‑> exp_subst option

Extend substitution and return None if not possible.

val exp_subst_free_vars : exp_subst ‑> Ident.t InferStdlib.IStd.Sequence.t
val exp_subst_gen_free_vars : exp_subst ‑> (unit, Ident.tInferStdlib.IStd.Sequence.Generator.t

substitution functions WARNING: these functions do not ensure that the results are normalized.

val exp_sub : subst ‑> Exp.t ‑> Exp.t
val atom_sub : subst ‑> atom ‑> atom
val instr_sub : subst ‑> instr ‑> instr

apply subst to all id's in instr, including LHS id's

val hpred_sub : subst ‑> hpred ‑> hpred

Functions for replacing occurrences of expressions.

val atom_replace_exp : (Exp.t * Exp.t) list ‑> atom ‑> atom
val hpred_replace_exp : (Exp.t * Exp.t) list ‑> hpred ‑> hpred

Functions for constructing or destructing entities in this module

val exp_get_offsets : Exp.t ‑> offset list

Compute the offset list of an expression

val exp_add_offsets : Exp.t ‑> offset list ‑> Exp.t

Add the offset list to an expression

val sigma_to_sigma_ne : hpred list ‑> (atom list * hpred list) list
val hpara_instantiate : hpara ‑> Exp.t ‑> Exp.t ‑> Exp.t list ‑> Ident.t list * hpred list

hpara_instantiate para e1 e2 elist instantiates para with e1, e2 and elist. If para = lambda (x, y, xs). exists zs. b, then the result of the instantiation is b[e1 / x, e2 / y, elist / xs, _zs'/ zs] for some fresh _zs'.

val hpara_dll_instantiate : hpara_dll ‑> Exp.t ‑> Exp.t ‑> Exp.t ‑> Exp.t list ‑> Ident.t list * hpred list

hpara_dll_instantiate para cell blink flink elist instantiates para with cell, blink, flink, and elist. If para = lambda (x, y, z, xs). exists zs. b, then the result of the instantiation is b[cell / x, blink / y, flink / z, elist / xs, _zs'/ zs] for some fresh _zs'.

val custom_error : Pvar.t