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(** [betree_main]: templates for the decreases clauses *)
module Betree.Clauses
open Primitives
open Betree.Types
#set-options "--z3rlimit 50 --fuel 0 --ifuel 1"
(*** Well-founded relations *)
(* We had a few issues when proving termination of the mutually recursive functions:
* - betree_Internal_flush
* - betree_Node_apply_messages
*
* The quantity which effectively decreases is:
* (betree_size, messages_length)
* where messages_length is 0 when there are no messages
* (and where we use the lexicographic ordering, of course)
*
* However, the `%[...]` and `{:well-founded ...} notations are not available outside
* of `decrease` clauses.
*
* We thus resorted to writing and proving correct a well-founded relation over
* pairs of natural numbers. The trick is that `<<` can be used outside of decrease
* clauses, and can be used to trigger SMT patterns.
*
* What follows is adapted from:
* https://www.fstar-lang.org/tutorial/book/part2/part2_well_founded.html
*
* Also, the following PR might make things easier:
* https://github.com/FStarLang/FStar/pull/2561
*)
module P = FStar.Preorder
module W = FStar.WellFounded
module L = FStar.LexicographicOrdering
let lt_nat (x y:nat) : Type = x < y == true
let rec wf_lt_nat (x:nat)
: W.acc lt_nat x
= W.AccIntro (fun y _ -> wf_lt_nat y)
// A type abbreviation for a pair of nats
let nat_pair = (x:nat & nat)
// Making a lexicographic ordering from a pair of nat ordering
let lex_order_nat_pair : P.relation nat_pair =
L.lex_t lt_nat (fun _ -> lt_nat)
// The lex order on nat pairs is well-founded, using our general proof
// of lexicographic composition of well-founded orders
let lex_order_nat_pair_wf : W.well_founded lex_order_nat_pair =
L.lex_t_wf wf_lt_nat (fun _ -> wf_lt_nat)
// A utility to introduce lt_nat
let mk_lt_nat (x:nat) (y:nat { x < y }) : lt_nat x y =
let _ : equals (x < y) true = Refl in
()
// A utility to make a lex ordering of nat pairs
let mk_lex_order_nat_pair (xy0:nat_pair)
(xy1:nat_pair {
let (|x0, y0|) = xy0 in
let (|x1, y1|) = xy1 in
x0 < x1 \/ (x0 == x1 /\ y0 < y1)
}) : lex_order_nat_pair xy0 xy1 =
let (|x0, y0|) = xy0 in
let (|x1, y1|) = xy1 in
if x0 < x1 then L.Left_lex x0 x1 y0 y1 (mk_lt_nat x0 x1)
else L.Right_lex x0 y0 y1 (mk_lt_nat y0 y1)
let rec coerce #a #r #x (p:W.acc #a r x) : Tot (W.acc r x) (decreases p) =
W.AccIntro (fun y r -> coerce (p.access_smaller y r))
let coerce_wf #a #r (p: (x:a -> W.acc r x)) : x:a -> W.acc r x =
fun x -> coerce (p x)
(* We need this axiom, which comes from the following discussion:
* https://github.com/FStarLang/FStar/issues/1916
* An issue here is that the `{well-founded ... }` notation
*)
assume
val axiom_well_founded (a : Type) (rel : a -> a -> Type0)
(rwf : W.well_founded #a rel) (x y : a) :
Lemma (requires (rel x y)) (ensures (x << y))
(* This lemma has a pattern (which makes it work) *)
let wf_nat_pair_lem (p0 p1 : nat_pair) :
Lemma
(requires (
let (|x0, y0|) = p0 in
let (|x1, y1|) = p1 in
x0 < x1 || (x0 = x1 && y0 < y1)))
(ensures (p0 << p1))
[SMTPat (p0 << p1)] =
let rel = lex_order_nat_pair in
let rel_wf = lex_order_nat_pair_wf in
let _ = mk_lex_order_nat_pair p0 p1 in
assert(rel p0 p1);
axiom_well_founded nat_pair rel rel_wf p0 p1
(*** Decrease clauses *)
/// "Standard" decrease clauses
(** [betree_main::betree::List::{1}::len]: decreases clause *)
unfold
let betree_List_len_decreases (t : Type0) (self : betree_List_t t) : betree_List_t t =
self
(** [betree_main::betree::List::{1}::split_at]: decreases clause *)
unfold
let betree_List_split_at_decreases (t : Type0) (self : betree_List_t t)
(n : u64) : nat =
n
(** [betree_main::betree::List::{2}::partition_at_pivot]: decreases clause *)
unfold
let betree_ListPairU64T_partition_at_pivot_decreases (t : Type0)
(self : betree_List_t (u64 & t)) (pivot : u64) : betree_List_t (u64 & t) =
self
(** [betree_main::betree::Node::{5}::lookup_in_bindings]: decreases clause *)
unfold
let betree_Node_lookup_in_bindings_decreases (key : u64)
(bindings : betree_List_t (u64 & u64)) : betree_List_t (u64 & u64) =
bindings
(** [betree_main::betree::Node::{5}::lookup_first_message_for_key]: decreases clause *)
unfold
let betree_Node_lookup_first_message_for_key_decreases (key : u64)
(msgs : betree_List_t (u64 & betree_Message_t)) : betree_List_t (u64 & betree_Message_t) =
msgs
(** [betree_main::betree::Node::{5}::apply_upserts]: decreases clause *)
unfold
let betree_Node_apply_upserts_decreases
(msgs : betree_List_t (u64 & betree_Message_t)) (prev : option u64)
(key : u64) : betree_List_t (u64 & betree_Message_t) =
msgs
(** [betree_main::betree::Internal::{4}::lookup_in_children]: decreases clause *)
unfold
let betree_Internal_lookup_in_children_decreases (self : betree_Internal_t)
(key : u64) (st : state) : betree_Internal_t =
self
(** [betree_main::betree::Node::{5}::lookup]: decreases clause *)
unfold
let betree_Node_lookup_decreases (self : betree_Node_t) (key : u64)
(st : state) : betree_Node_t =
self
(** [betree_main::betree::Node::{5}::lookup_mut_in_bindings]: decreases clause *)
unfold
let betree_Node_lookup_mut_in_bindings_decreases (key : u64)
(bindings : betree_List_t (u64 & u64)) : betree_List_t (u64 & u64) =
bindings
unfold
let betree_Node_apply_messages_to_leaf_decreases
(bindings : betree_List_t (u64 & u64))
(new_msgs : betree_List_t (u64 & betree_Message_t)) : betree_List_t (u64 & betree_Message_t) =
new_msgs
(** [betree_main::betree::Node::{5}::filter_messages_for_key]: decreases clause *)
unfold
let betree_Node_filter_messages_for_key_decreases (key : u64)
(msgs : betree_List_t (u64 & betree_Message_t)) : betree_List_t (u64 & betree_Message_t) =
msgs
(** [betree_main::betree::Node::{5}::lookup_first_message_after_key]: decreases clause *)
unfold
let betree_Node_lookup_first_message_after_key_decreases (key : u64)
(msgs : betree_List_t (u64 & betree_Message_t)) : betree_List_t (u64 & betree_Message_t) =
msgs
let betree_Node_apply_messages_to_internal_decreases
(msgs : betree_List_t (u64 & betree_Message_t))
(new_msgs : betree_List_t (u64 & betree_Message_t)) : betree_List_t (u64 & betree_Message_t) =
new_msgs
(*** Decrease clauses - nat_pair *)
/// The following decrease clauses use the [nat_pair] definition and the well-founded
/// relation proven above.
let rec betree_size (bt : betree_Node_t) : nat =
match bt with
| Betree_Node_Internal node -> 1 + betree_Internal_size node
| Betree_Node_Leaf _ -> 1
and betree_Internal_size (node : betree_Internal_t) : nat =
1 + betree_size node.left + betree_size node.right
let rec betree_List_len (#a : Type0) (ls : betree_List_t a) : nat =
match ls with
| Betree_List_Cons _ tl -> 1 + betree_List_len tl
| Betree_List_Nil -> 0
(** [betree_main::betree::Internal::{4}::flush]: decreases clause *)
unfold
let betree_Internal_flush_decreases (self : betree_Internal_t)
(params : betree_Params_t) (node_id_cnt : betree_NodeIdCounter_t)
(content : betree_List_t (u64 & betree_Message_t)) (st : state) : nat_pair =
(|betree_Internal_size self, 0|)
(** [betree_main::betree::Node::{5}::apply_messages]: decreases clause *)
unfold
let betree_Node_apply_messages_decreases (self : betree_Node_t)
(params : betree_Params_t) (node_id_cnt : betree_NodeIdCounter_t)
(msgs : betree_List_t (u64 & betree_Message_t)) (st : state) : nat_pair =
(|betree_size self, betree_List_len msgs|)
|