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author | Son Ho | 2022-02-12 21:20:57 +0100 |
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committer | Son Ho | 2022-02-12 21:20:57 +0100 |
commit | bc6d82ecd6163f0784085b0f4a33b2e867595235 (patch) | |
tree | b446887e23bc75bc2359d76ce6119ba949d5ce83 /tests | |
parent | fc53c6cd9b697b896003340af510ae444dcc35c6 (diff) |
Make minor updates and fix an unstable proof
Diffstat (limited to '')
-rw-r--r-- | tests/hashmap/Hashmap.Properties.fst | 113 |
1 files changed, 85 insertions, 28 deletions
diff --git a/tests/hashmap/Hashmap.Properties.fst b/tests/hashmap/Hashmap.Properties.fst index 272819dc..48b125d1 100644 --- a/tests/hashmap/Hashmap.Properties.fst +++ b/tests/hashmap/Hashmap.Properties.fst @@ -133,6 +133,7 @@ module InteractiveHelpers = FStar.InteractiveHelpers /// 1. See [hash_map_slots_s_nes] below: it is simply a definition with a refinment. /// For some reason, at some places if we use this type abbreviation some proofs /// break, meaning we have to write the unfolded version instead. +/// In particular, it made [hash_map_move_elements_fwd_back_lem_refin] annoying. /// /// I guess this specific type has something to do with the fact that F*'s type /// inference yields a different result, in combination with the poor support for @@ -663,10 +664,10 @@ let hash_map_t_base_inv (#t : Type0) (hm : hash_map_t t) : Type0 = /// Invariant for the hashmap let hash_map_t_inv (#t : Type0) (hm : hash_map_t t) : Type0 = // Base invariant - hash_map_t_base_inv hm + hash_map_t_base_inv hm /\ // The hash map is either: not overloaded, or we can't resize it -// (hm.hash_map_num_entries <= hm.hash_map_max_load -// || length hm.hash_map_slots * 2 > usize_max) + (hm.hash_map_num_entries <= hm.hash_map_max_load + || length hm.hash_map_slots * 2 > usize_max) /// The following predicate links the hashmap to an associative list. /// Note that it does not compute the representant: different (permuted) @@ -877,13 +878,15 @@ let rec hash_map_clear_slots_fwd_back_lem val hash_map_clear_fwd_back_lem_fun (t : Type0) (self : hash_map_t t) : Lemma - (requires (hash_map_t_inv self)) + (requires (hash_map_t_base_inv self)) (ensures ( match hash_map_clear_fwd_back t self with | Fail -> False | Return hm -> // The hash map invariant is satisfied - hash_map_t_inv hm /\ + hash_map_t_base_inv hm /\ + // We preserved the parameters + hash_map_same_params hm self /\ // The hash map has 0 values hash_map_t_len_s hm = 0 /\ // It contains no bindings @@ -1367,7 +1370,7 @@ val hash_map_insert_no_resize_fwd_back_lem_s (t : Type0) (self : hash_map_t t) (key : usize) (value : t) : Lemma (requires ( - hash_map_t_inv self /\ + hash_map_t_base_inv self /\ hash_map_slots_s_len (hash_map_t_slots_v self) = hash_map_t_len_s self)) (ensures ( begin @@ -1376,7 +1379,7 @@ val hash_map_insert_no_resize_fwd_back_lem_s with | Fail, Fail -> True | Return hm, Return hm_v -> - hash_map_t_inv hm /\ + hash_map_t_base_inv hm /\ hash_map_same_params hm self /\ hash_map_t_slots_v hm == hm_v /\ hash_map_slots_s_len hm_v == hash_map_t_len_s hm @@ -1580,14 +1583,14 @@ let rec hash_map_move_elements_from_list_s /// Refinement lemma val hash_map_move_elements_from_list_fwd_back_lem (t : Type0) (ntable : hash_map_t_nes t) (ls : list_t t) : - Lemma (requires (hash_map_t_inv ntable)) + Lemma (requires (hash_map_t_base_inv ntable)) (ensures ( match hash_map_move_elements_from_list_fwd_back t ntable ls, hash_map_move_elements_from_list_s (hash_map_t_slots_v ntable) (slot_t_v ls) with | Fail, Fail -> True | Return hm', Return hm_v -> - hash_map_t_inv hm' /\ + hash_map_t_base_inv hm' /\ hash_map_t_slots_v hm' == hm_v /\ hash_map_same_params hm' ntable | _ -> False)) @@ -1648,14 +1651,14 @@ val hash_map_move_elements_fwd_back_lem_refin (slots : vec (list_t t)) (i : usize{i <= length slots}) : Lemma (requires ( - hash_map_t_inv ntable)) + hash_map_t_base_inv ntable)) (ensures ( match hash_map_move_elements_fwd_back t ntable slots i, hash_map_move_elements_s (hash_map_t_slots_v ntable) (slots_t_v slots) i with | Fail, Fail -> True // We will prove later that this is not possible | Return (ntable', _), Return ntable'_v -> - hash_map_t_inv ntable' /\ + hash_map_t_base_inv ntable' /\ hash_map_t_slots_v ntable' == ntable'_v /\ hash_map_same_params ntable' ntable | _ -> False)) @@ -1663,13 +1666,37 @@ val hash_map_move_elements_fwd_back_lem_refin // Rk.: if above we update some definitions to use [hash_map_slots_s_nes] // instead of writing refinements explicitly, it makes the proof breaks. -// I guess it is because F* does a different type inference, which combines -// poorly with its poor support for subtyping. Problem is: I have no idea -// where this happens and it is extremely hard to debug. +// I guess it is because +// +// This proof was super unstable for some reasons. +// +// For instance, a type abbreviation instead of the same type but expanded +// led to a failure. This behaviour led me to the hypothesis that maybe it +// it made F*'s type inference end up with a different result, which combined +// with its poor support for subtyping made the proof failed. +// +// However, later, unwrapping a definition led to another failure. +// +// I thus tried to manually unfold some postconditions because it +// seemed to work for [hash_map_move_elements_fwd_back_lem] but it didn't +// succeed. +// +// I tried to increase the ifuel to 2, 3: it didn't work, and I fell back to +// other methods. Finally out of angriness I swiched the ifuel to 4 for some +// reason: everything worked fine. +// I have *no clue* why 4 is the magic number. +// +// The terrible thing is that this refinement proof is conceptually super simple: +// - there are maybe two arithmetic proofs, which are directly solved by the +// precondition +// - we need to refine the call to [hash_map_move_elements_from_list_fwd_back]: +// this is proven by another refinement lemma we proved above +// - there is the recursive call (trivial) +// Huge waste of time... #restart-solver -#push-options "--z3rlimit 200 --fuel 1" +#push-options "--z3rlimit 300 --fuel 1 --ifuel 4" let rec hash_map_move_elements_fwd_back_lem_refin t ntable slots i = - assert(hash_map_t_inv ntable); + assert(hash_map_t_base_inv ntable); let i0 = vec_len (list_t t) slots in let b = i < i0 in if b @@ -1680,6 +1707,17 @@ let rec hash_map_move_elements_fwd_back_lem_refin t ntable slots i = let l0 = mem_replace_fwd (list_t t) l ListNil in assert(l0 == l); hash_map_move_elements_from_list_fwd_back_lem t ntable l0; + begin + match hash_map_move_elements_from_list_fwd_back t ntable l0, + hash_map_move_elements_from_list_s (hash_map_t_slots_v ntable) (slot_t_v l0) + with + | Fail, Fail -> () + | Return hm', Return hm_v -> + assert(hash_map_t_base_inv hm'); + assert(hash_map_t_slots_v hm' == hm_v); + assert(hash_map_same_params hm' ntable) + | _ -> assert(False) + end; begin match hash_map_move_elements_from_list_fwd_back t ntable l0 with | Fail -> () | Return h -> @@ -1692,9 +1730,28 @@ let rec hash_map_move_elements_fwd_back_lem_refin t ntable slots i = | Fail -> () | Return i1 -> hash_map_move_elements_fwd_back_lem_refin t h v i1; + begin + match hash_map_move_elements_fwd_back t h v i1, + hash_map_move_elements_s (hash_map_t_slots_v h) (slots_t_v v) i1 + with + | Fail, Fail -> () + | Return (ntable', _), Return ntable'_v -> + assert(hash_map_t_base_inv ntable'); + assert(hash_map_t_slots_v ntable' == ntable'_v); + assert(hash_map_same_params ntable' ntable) + | _ -> assert(False) + end; begin match hash_map_move_elements_fwd_back t h v i1 with - | Fail -> () - | Return (h0, v0) -> () + | Fail -> + assert(hash_map_move_elements_fwd_back t ntable slots i == Fail); + () + | Return (ntable', v0) -> + begin + // Trying to prove the postcondition + match hash_map_move_elements_fwd_back t ntable slots i with + | Fail -> assert(False) + | Return (ntable'', _) -> assert(ntable'' == ntable') + end end end end @@ -2017,12 +2074,12 @@ let slots_t_inv_implies_slots_s_inv #t slots = // Problem is: I can never really predict for sure with F*... () -val hash_map_t_inv_implies_hash_map_slots_s_inv +val hash_map_t_base_inv_implies_hash_map_slots_s_inv (#t : Type0) (hm : hash_map_t t) : - Lemma (requires (hash_map_t_inv hm)) + Lemma (requires (hash_map_t_base_inv hm)) (ensures (hash_map_slots_s_inv (hash_map_t_slots_v hm))) -let hash_map_t_inv_implies_hash_map_slots_s_inv #t hm = () // same as previous +let hash_map_t_base_inv_implies_hash_map_slots_s_inv #t hm = () // same as previous /// Introducing a "partial" version of the hash map invariant, which operates on /// a suffix of the hash map. @@ -2076,12 +2133,12 @@ val hash_map_slots_s_inv_implies_assoc_list_lem let hash_map_slots_s_inv_implies_assoc_list_lem #t hm = partial_hash_map_slots_s_inv_implies_assoc_list_lem (length hm) 0 hm -val hash_map_t_inv_implies_assoc_list_lem +val hash_map_t_base_inv_implies_assoc_list_lem (#t : Type0) (hm : hash_map_t t): - Lemma (requires (hash_map_t_inv hm)) + Lemma (requires (hash_map_t_base_inv hm)) (ensures (assoc_list_inv (hash_map_t_v hm))) -let hash_map_t_inv_implies_assoc_list_lem #t hm = +let hash_map_t_base_inv_implies_assoc_list_lem #t hm = hash_map_slots_s_inv_implies_assoc_list_lem (hash_map_t_slots_v hm) /// For some reason, we can't write the below [forall] directly in the [ensures] @@ -2099,7 +2156,7 @@ val hash_map_move_elements_fwd_back_lem Lemma (requires ( let al = flatten (slots_t_v slots) in - hash_map_t_inv ntable /\ + hash_map_t_base_inv ntable /\ length al <= usize_max /\ assoc_list_inv al /\ // The table is empty @@ -2112,7 +2169,7 @@ val hash_map_move_elements_fwd_back_lem with | Return (ntable', _), Return ntable'_v -> // The invariant is preserved - hash_map_t_inv ntable' /\ + hash_map_t_base_inv ntable' /\ // The table has the same number of slots length ntable'.hash_map_slots = length ntable.hash_map_slots /\ // The count is good @@ -2144,7 +2201,7 @@ let hash_map_move_elements_fwd_back_lem t ntable slots = with | Fail, Fail -> () | Return (ntable', _), Return ntable'_v -> - assert(hash_map_t_inv ntable'); + assert(hash_map_t_base_inv ntable'); assert(hash_map_t_slots_v ntable' == ntable'_v) | _ -> assert(False) end; @@ -2163,7 +2220,7 @@ let hash_map_move_elements_fwd_back_lem t ntable slots = hash_map_move_elements_s_flat ntable_v al with | Return (ntable', _), Return ntable'_v -> - assert(hash_map_t_inv ntable'); + assert(hash_map_t_base_inv ntable'); assert(length ntable'.hash_map_slots = length ntable.hash_map_slots); // Rk.: Adding the following let binding makes the proof fails even with a huge // rlitmit. Really having fun here... |