Module `InferModules.CTL`

type transitions = | AccessorForProperty of ALVar.alexp decl to decl | Body decl to stmt | FieldName of ALVar.alexp stmt to stmt, decl to decl | Fields stmt to stmt, decl to decl | InitExpr decl to stmt | Super decl to decl | ParameterName of ALVar.alexp stmt to stmt, decl to decl | ParameterPos of ALVar.alexp stmt to stmt, decl to decl | Parameters stmt to stmt, decl to decl | Cond | PointerToDecl stmt to decl | Protocol decl to decl | SourceExpr: Transition labels used for example to switch from decl to stmt

val compare_transitions : transitions -> transitions -> int

type t = | True | False | Atomic of CPredicates.t Atomic formula | Not of t | And of t * t | Or of t * t | Implies of t * t | InNode of ALVar.alexp list * t | AX of transitions option * t AX phi <=> for all children of the current node phi holds | EX of transitions option * t EX phi <=> exist a child of the current node such that phi holds | AF of transitions option * t AF phi <=> for all path from the current node there is a descendant where phi holds | EF of transitions option * t EF phi <=> there exits a a path from the current node with a descendant where phi hold | AG of transitions option * t AG phi <=> for all discendant of the current node phi hold | EG of transitions option * t EG phi <=> there exists a path (of descendants) from the current node where phi hold at each node of the path | AU of transitions option * t * t AU(phi1, phi2) <=> for all paths from the current node phi1 holds in every node until ph2 holds | EU of transitions option * t * t EU(phi1, phi2) <=> there exists a path from the current node such that phi1 holds until phi2 holds | EH of ALVar.alexp list * t EHclassesphi <=> there exists a node defining a super class in the hierarchy of the class defined by the current node (if any) where phi holds | ET of ALVar.alexp list * transitions option * t ET T l phi <=> there exists a descentant an of the current node such that an is of type in set T making a transition to a node an' via label l, such that in an phi holds. | InObjCClass of t * t: A ctl formula

val compare : t -> t -> int

val equal : t -> t -> bool

type clause = | CLet of ALVar.formula_id * ALVar.t list * t Let clause: let id = definifion; | CSet of ALVar.keyword * t Set clause: set id = definition | CDesc of ALVar.keyword * string Description clause eg: set message = "..." | CPath of [ `WhitelistPath | `BlacklistPath ] * ALVar.t list
type ctl_checker = { id : string; Checker's id definitions : clause list; A list of let/set definitions }
type al_file = { import_files : string list; global_macros : clause list; global_paths : (string * ALVar.alexp list) list; checkers : ctl_checker list; }

val print_checker : ctl_checker -> unit
val eval_formula : t -> Ctl_parser_types.ast_node -> CLintersContext.context -> Ctl_parser_types.ast_node option: return the evaluation of the formula and a witness

val save_dotty_when_in_debug_mode : InferBase.SourceFile.t -> unit
val next_state_via_transition : Ctl_parser_types.ast_node -> transitions -> Ctl_parser_types.ast_node list
val create_ctl_evaluation_tracker : InferBase.SourceFile.t -> unit

module Debug : sig ... end

`\|` `AccessorForProperty of ALVar.alexp`	decl to decl
`\|` `Body`	decl to stmt
`\|` `FieldName of ALVar.alexp`	stmt to stmt, decl to decl
`\|` `Fields`	stmt to stmt, decl to decl
`\|` `InitExpr`	decl to stmt
`\|` `Super`	decl to decl
`\|` `ParameterName of ALVar.alexp`	stmt to stmt, decl to decl
`\|` `ParameterPos of ALVar.alexp`	stmt to stmt, decl to decl
`\|` `Parameters`	stmt to stmt, decl to decl
`\|` `Cond`
`\|` `PointerToDecl`	stmt to decl
`\|` `Protocol`	decl to decl
`\|` `SourceExpr`

`\|` `True`
`\|` `False`
`\|` `Atomic of CPredicates.t`	Atomic formula
`\|` `Not of t`
`\|` `And of t * t`
`\|` `Or of t * t`
`\|` `Implies of t * t`
`\|` `InNode of ALVar.alexp list * t`
`\|` `AX of transitions option * t`	AX phi <=> for all children of the current node phi holds
`\|` `EX of transitions option * t`	EX phi <=> exist a child of the current node such that phi holds
`\|` `AF of transitions option * t`	AF phi <=> for all path from the current node there is a descendant where phi holds
`\|` `EF of transitions option * t`	EF phi <=> there exits a a path from the current node with a descendant where phi hold
`\|` `AG of transitions option * t`	AG phi <=> for all discendant of the current node phi hold
`\|` `EG of transitions option * t`	EG phi <=> there exists a path (of descendants) from the current node where phi hold at each node of the path
`\|` `AU of transitions option * t * t`	AU(phi1, phi2) <=> for all paths from the current node phi1 holds in every node until ph2 holds
`\|` `EU of transitions option * t * t`	EU(phi1, phi2) <=> there exists a path from the current node such that phi1 holds until phi2 holds
`\|` `EH of ALVar.alexp list * t`	EH`classes`phi <=> there exists a node defining a super class in the hierarchy of the class defined by the current node (if any) where phi holds
`\|` `ET of ALVar.alexp list * transitions option * t`	ET `T` `l` phi <=> there exists a descentant an of the current node such that an is of type in set T making a transition to a node an' via label l, such that in an phi holds.
`\|` `InObjCClass of t * t`

`\|` `CLet of ALVar.formula_id * ALVar.t list * t`	Let clause: let id = definifion;
`\|` `CSet of ALVar.keyword * t`	Set clause: set id = definition
`\|` `CDesc of ALVar.keyword * string`	Description clause eg: set message = "..."
`\|` CPath of [ `WhitelistPath \| `BlacklistPath ] * ALVar.t list

`id : string;`	Checker's id
`definitions : clause list;`	A list of let/set definitions