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i want to use frama-c wp plugin api to get proof obligations of a c file like the wp plugin, one example(using swap.c example from frama-c wp website):

$ frama-c -wp -wp-rte -wp-proof alt-ergo swap.c -wp-print
(....)
------------------------------------------------------------
  Function swap
------------------------------------------------------------

Goal Post-condition 'A' in 'swap':
Let x_0 = Mint_0[b_0].
Let x_1 = Mint_0[a_0].
Let x_2 = Mint_0[a_0->x_0][b_0->x_1][a_0].
Assume {
  (* Domain *)
  Type: (is_sint32 x_1) /\ (is_sint32 x_0) /\ (is_sint32 x_2).
  (* Heap *)
  Have: (linked Malloc_0).
  (* Pre-condition (file swap.c, line 3) in 'swap' *)
  (* Pre-condition: *)
  Have: (valid_rw Malloc_0 a_0 1) /\ (valid_rw Malloc_0 b_0 1).
  (* Assertion 'rte,mem_access' (file swap.c, line 11) *)
  (* swap.c:11: Assertion 'rte,mem_access': *)
  Have: (valid_rd Malloc_0 a_0 1).
  (* Assertion 'rte,mem_access' (file swap.c, line 12) *)
  (* swap.c:12: Assertion 'rte,mem_access': *)
  Have: (valid_rd Malloc_0 b_0 1).
}
Prove: x_0=x_2.
Prover Alt-Ergo returns Valid (25ms) (15)

------------------------------------------------------------

Goal Post-condition 'B' in 'swap':
Let x_0 = Mint_0[a_0].
Let x_1 = Mint_0[b_0].
Assume {
  (* Domain *)
  Type: (is_sint32 x_0) /\ (is_sint32 x_1)
        /\ (is_sint32 Mint_0[a_0->x_1][b_0->x_0][a_0]).
  (* Heap *)
  Have: (linked Malloc_0).
  (* Pre-condition (file swap.c, line 3) in 'swap' *)
  (* Pre-condition: *)
  Have: (valid_rw Malloc_0 a_0 1) /\ (valid_rw Malloc_0 b_0 1).
  (* Assertion 'rte,mem_access' (file swap.c, line 11) *)
  (* swap.c:11: Assertion 'rte,mem_access': *)
  Have: (valid_rd Malloc_0 a_0 1).
  (* Assertion 'rte,mem_access' (file swap.c, line 12) *)
  (* swap.c:12: Assertion 'rte,mem_access': *)
  Have: (valid_rd Malloc_0 b_0 1).
}
Prove: true.
Prover Qed returns Valid

------------------------------------------------------------

Goal Assertion 'rte,mem_access' (file swap.c, line 11):
Assume {
  (* Domain *)
  Type: (is_sint32 Mint_0[a_2]) /\ (is_sint32 Mint_0[b_0])
        /\ (is_sint32 Mint_1[a_2]) /\ (is_sint32 Mint_1[b_0]).
  (* Heap *)
  Have: (linked Malloc_1).
  (* Pre-condition (file swap.c, line 3) in 'swap' *)
  (* Pre-condition: *)
  Have: (valid_rw Malloc_1 a_2 1) /\ (valid_rw Malloc_1 b_0 1).
}
Prove: (valid_rd Malloc_1 a_2 1).
Prover Alt-Ergo returns Valid (26ms) (17)

------------------------------------------------------------

Goal Assertion 'rte,mem_access' (file swap.c, line 12):
Assume {
  (* Domain *)
  Type: (is_sint32 Mint_0[a_2]) /\ (is_sint32 Mint_0[b_0])
        /\ (is_sint32 Mint_1[a_2]) /\ (is_sint32 Mint_1[b_0]).
  (* Heap *)
  Have: (linked Malloc_1).
  (* Pre-condition (file swap.c, line 3) in 'swap' *)
  (* Pre-condition: *)
  Have: (valid_rw Malloc_1 a_2 1) /\ (valid_rw Malloc_1 b_0 1).
  (* Assertion 'rte,mem_access' (file swap.c, line 11) *)
  (* swap.c:11: Assertion 'rte,mem_access': *)
  Have: (valid_rd Malloc_1 a_2 1).
}
Prove: true.
Prover Qed returns Valid

------------------------------------------------------------

Goal Assertion 'rte,mem_access' (file swap.c, line 12):
Assume {
  (* Domain *)
  Type: (is_sint32 Mint_0[a_0]) /\ (is_sint32 Mint_0[b_2])
        /\ (is_sint32 Mint_1[a_0]) /\ (is_sint32 Mint_1[b_2]).
  (* Heap *)
  Have: (linked Malloc_1).
  (* Pre-condition (file swap.c, line 3) in 'swap' *)
  (* Pre-condition: *)
  Have: (valid_rw Malloc_1 a_0 1) /\ (valid_rw Malloc_1 b_2 1).
  (* Assertion 'rte,mem_access' (file swap.c, line 11) *)
  (* swap.c:11: Assertion 'rte,mem_access': *)
  Have: (valid_rd Malloc_1 a_0 1).
}
Prove: (valid_rd Malloc_1 b_2 1).
Prover Alt-Ergo returns Valid (26ms) (17)

------------------------------------------------------------

Goal Assertion 'rte,mem_access' (file swap.c, line 13):
Assume {
  (* Domain *)
  Type: (is_sint32 Mint_0[a_0]) /\ (is_sint32 Mint_0[b_2])
        /\ (is_sint32 Mint_1[a_0]) /\ (is_sint32 Mint_1[b_2]).
  (* Heap *)
  Have: (linked Malloc_1).
  (* Pre-condition (file swap.c, line 3) in 'swap' *)
  (* Pre-condition: *)
  Have: (valid_rw Malloc_1 a_0 1) /\ (valid_rw Malloc_1 b_2 1).
  (* Assertion 'rte,mem_access' (file swap.c, line 11) *)
  (* swap.c:11: Assertion 'rte,mem_access': *)
  Have: (valid_rd Malloc_1 a_0 1).
  (* Assertion 'rte,mem_access' (file swap.c, line 12) *)
  (* swap.c:12: Assertion 'rte,mem_access': *)
  Have: (valid_rd Malloc_1 b_2 1).
}
Prove: true.
Prover Qed returns Valid

------------------------------------------------------------

Goal Assigns (file swap.c, line 6) in 'swap' (1/3):
Effect at line 11
Assume {
  (* Domain *)
  Type: (is_sint32 Mint_0[a_0]) /\ (is_sint32 Mint_0[b_0])
        /\ (is_sint32 Mint_1[a_0]) /\ (is_sint32 Mint_1[b_0]).
  (* Heap *)
  Have: (linked Malloc_0).
  (* Pre-condition (file swap.c, line 3) in 'swap' *)
  (* Pre-condition: *)
  Have: (valid_rw Malloc_0 a_0 1) /\ (valid_rw Malloc_0 b_0 1).
  (* Assertion 'rte,mem_access' (file swap.c, line 11) *)
  (* swap.c:11: Assertion 'rte,mem_access': *)
  Have: (valid_rd Malloc_0 a_0 1).
}
Prove: true.
Prover Qed returns Valid

------------------------------------------------------------

Goal Assigns (file swap.c, line 6) in 'swap' (2/3):
Effect at line 12
Assume {
  (* Domain *)
  Type: (is_sint32 Mint_0[a_0]) /\ (is_sint32 Mint_0[b_0])
        /\ (is_sint32 Mint_1[a_0]) /\ (is_sint32 Mint_1[b_0]).
  (* Goal *)
  When: (valid_rd Malloc_0 a_0 1).
  (* Heap *)
  Have: (linked Malloc_0).
  (* Pre-condition (file swap.c, line 3) in 'swap' *)
  (* Pre-condition: *)
  Have: (valid_rw Malloc_0 a_0 1) /\ (valid_rw Malloc_0 b_0 1).
  (* Assertion 'rte,mem_access' (file swap.c, line 12) *)
  (* swap.c:12: Assertion 'rte,mem_access': *)
  Have: (valid_rd Malloc_0 b_0 1).
}
Prove: (included a_0 1 a_0 1) \/ (included a_0 1 b_0 1).
Prover Alt-Ergo returns Valid (Qed:1ms) (23ms) (22)

------------------------------------------------------------

Goal Assigns (file swap.c, line 6) in 'swap' (3/3):
Effect at line 13
Assume {
  (* Domain *)
  Type: (is_sint32 Mint_0[a_0]) /\ (is_sint32 Mint_0[b_0])
        /\ (is_sint32 Mint_1[a_0]) /\ (is_sint32 Mint_1[b_0]).
  (* Goal *)
  When: (valid_rd Malloc_0 b_0 1).
  (* Heap *)
  Have: (linked Malloc_0).
  (* Pre-condition (file swap.c, line 3) in 'swap' *)
  (* Pre-condition: *)
  Have: (valid_rw Malloc_0 a_0 1) /\ (valid_rw Malloc_0 b_0 1).
  (* Assertion 'rte,mem_access' (file swap.c, line 11) *)
  (* swap.c:11: Assertion 'rte,mem_access': *)
  Have: (valid_rd Malloc_0 a_0 1).
}
Prove: (included b_0 1 a_0 1) \/ (included b_0 1 b_0 1).
Prover Alt-Ergo returns Valid (Qed:3ms) (21ms) (22)

------------------------------------------------------------

I want to do the same thing but with a frama-c script using wpo api i am having difficult understanding how to use the wpo api to do this. I already now how to load the dynamic api:

(* Load wp and wpo *)

let () = Dynamic.load_module "Wp" 

module Wpo = Type.Abstract(struct let name = "Wpo.po" end) 

 (*let module Result = Type.Make(struct let name = Wpo.result end)
 let module Po = Type.Make(struct let name = Wpo.po end)
 let module Prover = Type.Make(struct let name = Wpo.prover end) *)
(* Wpo Result *)


(* wp api *)

let wp_compute_cf = Dynamic.get ~plugin:"Wp" "wp_compute_kf" (Datatype.func (Datatype.option Kernel_function.ty) (Datatype.func (Datatype.list Datatype.string) (Datatype.func (Datatype.list Datatype.string) Datatype.unit)))

let wp_iter_session = Dynamic.get ~plugin:"Wp" "wp_iter_session" (Datatype.func (Datatype.func Wpo.ty Datatype.unit) Datatype.unit)

let wp_compute = Dynamic.get ~plugin:"Wp" "wp_compute" (Datatype.func (Datatype.option Kernel_function.ty) (Datatype.func (Datatype.list Datatype.string) (Datatype.func (Datatype.option Property.ty) Datatype.unit))) 

let wp_compute_call = Dynamic.get ~plugin:"Wp" "wp_compute_call" (Datatype.func Cil_datatype.Stmt.ty Datatype.unit)

let wp_run = Dynamic.get ~plugin:"Wp" "run" (Datatype.func Datatype.unit Datatype.unit)

let wp_begin_session = Dynamic.get ~plugin:"Wp" "wp_begin_session" (Datatype.func Datatype.unit Datatype.unit)

(* wpo api *)

let iter_on_goals = Dynamic.get ~plugin:"Wp" "Wpo.iter_on_goals" (Datatype.func (Datatype.func Wpo.ty Datatype.unit) Datatype.unit)

let goals_of_property = Dynamic.get ~plugin:"Wp" "Wpo.goals_of_property" (Datatype.func Property.ty (Datatype.list Wpo.ty))

let get_result =  Dynamic.get ~plugin:"Wp" "Wpo.get_result" (Datatype.func Wpo.ty (Datatype.func Wpo.ty Wpo.ty))

let get_property =  Dynamic.get ~plugin:"Wp" "Wpo.get_property" (Datatype.func Wpo.ty Property.ty)

For what i understand of reading the frama-c wpo api what i want to use is goals_of_property, so what i want to know is how to use it and where in the visitor of the ast. If anyone could explain me or give me an example, i would be grateful.

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