Module Pulselib.PulsePathCondition
module AbstractValue = PulseAbstractValue
module SatUnsat = PulseSatUnsat
module ValueHistory = PulseValueHistory
type new_eqs
= PulseFormula.new_eqs
Building arithmetic constraints
val and_nonnegative : AbstractValue.t -> t -> t * new_eqs
and_nonnegative v phi
isphi ∧ v≥0
val and_positive : AbstractValue.t -> t -> t * new_eqs
and_positive v phi
isphi ∧ v>0
val and_eq_int : AbstractValue.t -> IR.IntLit.t -> t -> t * new_eqs
and_eq_int v i phi
isphi ∧ v=i
val and_eq_vars : AbstractValue.t -> AbstractValue.t -> t -> t * new_eqs
val simplify : IR.Tenv.t -> can_be_pruned:AbstractValue.Set.t -> keep:AbstractValue.Set.t -> get_dynamic_type:(AbstractValue.t -> IR.Typ.t option) -> t -> (t * AbstractValue.Set.t * new_eqs) SatUnsat.t
simplify ~can_be_pruned ~keep phi
attempts to get rid of as many variables infv phi
but not inkeep
as possible, and tries to eliminate variables not incan_be_pruned
from the "pruned" part of the formula
val and_callee : (AbstractValue.t * ValueHistory.t) AbstractValue.Map.t -> t -> callee:t -> (AbstractValue.t * ValueHistory.t) AbstractValue.Map.t * t * new_eqs
Operations
type operand
=
|
LiteralOperand of IR.IntLit.t
|
AbstractValueOperand of AbstractValue.t
val pp_operand : IStdlib.IStd.Formatter.t -> operand -> unit
val eval_binop : AbstractValue.t -> IR.Binop.t -> operand -> operand -> t -> t * new_eqs
val eval_unop : AbstractValue.t -> IR.Unop.t -> AbstractValue.t -> t -> t * new_eqs
val prune_binop : negated:bool -> IR.Binop.t -> operand -> operand -> t -> t * new_eqs
val and_eq_instanceof : AbstractValue.t -> AbstractValue.t -> IR.Typ.t -> t -> t * new_eqs
Queries
val is_known_zero : t -> AbstractValue.t -> bool
is_known_zero phi t
returnstrue
ifphi |- t = 0
,false
if we don't know for sure
val is_known_not_equal_zero : t -> AbstractValue.t -> bool
is_known_not_equal_zero phi t
returnstrue
ifphi |- t != 0
,false
if we don't know for sure
val is_unsat_cheap : t -> bool
whether the state contains a contradiction, call this as often as you want
val is_unsat_expensive : IR.Tenv.t -> get_dynamic_type:(AbstractValue.t -> IR.Typ.t option) -> t -> t * bool * new_eqs
whether the state contains a contradiction, only call this when you absolutely have to
val has_no_assumptions : t -> bool
whether the current path is independent of any calling context
val get_known_var_repr : t -> AbstractValue.t -> AbstractValue.t
get the canonical representative for the variable according to the equality relation in the "known" part of the formula
val get_both_var_repr : t -> AbstractValue.t -> AbstractValue.t
get the canonical representative for the variable according to the equality relation in the "both" (known + pruned) part of the formula