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authorSon Ho2023-05-11 12:34:14 +0200
committerSon HO2023-06-04 21:54:38 +0200
commit97604d14f467458240732a4c0a733d381d72fbbe (patch)
tree8b0b9b83c10caebab6a02f73143aebae770296d7 /backends
parent73fd1921f90824e481c0f8e0c52003d37af5a2e5 (diff)
Start working on more general fixed-point combinators
Diffstat (limited to 'backends')
-rw-r--r--backends/hol4/divDefProto2Script.sml678
-rw-r--r--backends/hol4/divDefProto2Theory.sig225
-rw-r--r--backends/hol4/primitivesArithScript.sml1
3 files changed, 904 insertions, 0 deletions
diff --git a/backends/hol4/divDefProto2Script.sml b/backends/hol4/divDefProto2Script.sml
new file mode 100644
index 00000000..985b930f
--- /dev/null
+++ b/backends/hol4/divDefProto2Script.sml
@@ -0,0 +1,678 @@
+(* Prototype: divDefLib but with general combinators *)
+
+open HolKernel boolLib bossLib Parse
+open boolTheory arithmeticTheory integerTheory intLib listTheory stringTheory
+
+open primitivesArithTheory primitivesBaseTacLib ilistTheory primitivesTheory
+open primitivesLib
+
+val _ = new_theory "divDefProto2"
+
+
+(*
+ * Test with a general validity predicate.
+ *
+ * TODO: this works! Cleanup.
+ *)
+val fix_fuel_def = Define ‘
+ (fix_fuel (0 : num) (f : ('a -> 'a result) -> 'a -> 'a result) (x : 'a) : 'a result = Diverge) ∧
+ (fix_fuel (SUC n) (f : ('a -> 'a result) -> 'a -> 'a result) (x : 'a) : 'a result = f (fix_fuel n f) x)
+’
+
+val fix_fuel_P_def = Define ‘
+ fix_fuel_P f x n = ~(is_diverge (fix_fuel n f x))
+’
+
+val fix_def = Define ‘
+ fix (f : ('a -> 'a result) -> 'a -> 'a result) (x : 'a) : 'a result =
+ if (∃ n. fix_fuel_P f x n) then fix_fuel ($LEAST (fix_fuel_P f x)) f x else Diverge
+’
+
+val is_valid_fp_body_def = Define ‘
+ (is_valid_fp_body (0 : num) (f : ('a -> 'a result) -> 'a -> 'a result) = F) ∧
+
+ (is_valid_fp_body (SUC n) (f : ('a -> 'a result) -> 'a -> 'a result) =
+ ∀x. (∀g h. f g x = f h x) ∨
+ (∃ h y. is_valid_fp_body n h ∧
+ ∀g. f g x = do z <- g y; h g z od))
+’
+
+(* Auxiliary lemma.
+ We generalize the goal of fix_fuel_mono in the case the fuel is non-empty
+ (this allows us to unfold definitions like ‘fix_fuel’ once, and reveal
+ a first intermediate function).
+
+ Important: the structure of the proof is induction over ‘n’ then ‘N’.
+ *)
+Theorem fix_fuel_mono_aux:
+ ∀n.
+ ∀N M g f. is_valid_fp_body M f ⇒
+ is_valid_fp_body N g ⇒
+ ∀x. ~(is_diverge (g (fix_fuel n f) x)) ⇒
+ ∀m. n ≤ m ⇒
+ g (fix_fuel n f) x = g (fix_fuel m f) x
+Proof
+ Induct_on ‘n’ >>
+ Induct_on ‘N’ >- fs [is_valid_fp_body_def]
+ >-(
+ rw [] >>
+ fs [is_valid_fp_body_def, is_diverge_def] >>
+ first_x_assum (qspec_assume ‘x’) >>
+ rw []
+ >-((* Case 1: the continuation doesn't matter *) fs []) >>
+ (* Case 2: the continuation *does* matter (i.e., there is a recursive call *)
+ (* Instantiate the validity property with the different continuations *)
+ first_assum (qspec_assume ‘fix_fuel n f’) >>
+ first_assum (qspec_assume ‘fix_fuel n' f’) >>
+ fs [] >>
+ ntac 3 (pop_assum ignore_tac) >>
+ fs [bind_def] >>
+ fs [fix_fuel_def])
+ >-(fs [is_valid_fp_body_def]) >>
+ rw [] >>
+ qpat_assum ‘is_valid_fp_body (SUC N) g’ mp_tac >>
+ pure_rewrite_tac [is_valid_fp_body_def] >>
+ fs [is_diverge_def] >>
+ rw [] >>
+ first_x_assum (qspec_assume ‘x’) >>
+ rw []
+ >-((* Case 1: the continuation doesn't matter *) fs []) >>
+ (* Case 2: the continuation *does* matter (i.e., there is a recursive call *)
+ (* Use the validity property with the different continuations *)
+ fs [] >> pop_assum ignore_tac >>
+ fs [bind_def, fix_fuel_def] >>
+ Cases_on ‘m’ >- int_tac >>
+ fs [fix_fuel_def] >>
+ (* *)
+ last_x_assum (qspecl_assume [‘M’, ‘M’, ‘f’, ‘f’]) >>
+ gvs [] >>
+ first_x_assum (qspec_assume ‘y’) >>
+ Cases_on ‘f (fix_fuel n f) y’ >> fs [] >>
+ first_x_assum (qspec_assume ‘n'’) >> gvs [] >> Cases_on ‘f (fix_fuel n' f) y’ >> fs [] >>
+ (* *)
+ first_assum (qspecl_assume [‘M’, ‘h’, ‘f’]) >>
+ gvs []
+QED
+
+Theorem fix_fuel_mono:
+ ∀N f. is_valid_fp_body N f ⇒
+ ∀n x. fix_fuel_P f x n ⇒
+ ∀ m. n ≤ m ⇒
+ fix_fuel n f x = fix_fuel m f x
+Proof
+ rw [] >>
+ Cases_on ‘n’
+ >-(fs [fix_fuel_P_def, is_diverge_def, fix_fuel_def]) >>
+ fs [fix_fuel_P_def, fix_fuel_def] >> rw [] >>
+ qspecl_assume [‘n'’, ‘N’, ‘N’, ‘f’, ‘f’] fix_fuel_mono_aux >>
+ Cases_on ‘m’ >- fs [] >>
+ gvs [fix_fuel_def]
+QED
+
+(* TODO: remove? *)
+Theorem fix_fuel_mono_least:
+ ∀N f. is_valid_fp_body N f ⇒
+ ∀n x. fix_fuel_P f x n ⇒
+ fix_fuel n f x = fix_fuel ($LEAST (fix_fuel_P f x)) f x
+Proof
+ rw [] >>
+ pure_once_rewrite_tac [EQ_SYM_EQ] >>
+ irule fix_fuel_mono >> fs [] >>
+ (* Use the "fundamental" property about $LEAST *)
+ qspec_assume ‘fix_fuel_P f x’ whileTheory.LEAST_EXISTS_IMP >>
+ (* Prove the premise *)
+ pop_assum sg_premise_tac >- metis_tac [] >> fs [] >>
+ conj_tac
+ >- (spose_not_then assume_tac >> fs [not_le_eq_gt]) >>
+ metis_tac []
+QED
+
+Theorem fix_fuel_eq_fix:
+ ∀N f. is_valid_fp_body N f ⇒
+ ∀n x. fix_fuel_P f x n ⇒
+ fix_fuel n f x = fix f x
+Proof
+ fs [fix_def] >>
+ rw [] >>
+ imp_res_tac fix_fuel_mono_least >>
+ fs [fix_fuel_P_def, is_diverge_def] >>
+ case_tac >> fs []
+QED
+
+Theorem fix_fuel_P_least:
+ ∀f n x. fix_fuel n f x ≠ Diverge ⇒ fix_fuel_P f x ($LEAST (fix_fuel_P f x))
+Proof
+ rw [] >>
+ qspec_assume ‘fix_fuel_P f x’ whileTheory.LEAST_EXISTS_IMP >>
+ (* Prove the premise *)
+ pop_assum sg_premise_tac
+ >-(fs [fix_fuel_P_def, is_diverge_def] >> qexists ‘n’ >> fs [] >> case_tac >> fs []) >>
+ rw []
+QED
+
+(* If ‘g (fix f) x’ doesn't diverge, we can exhibit some fuel *)
+Theorem fix_not_diverge_implies_fix_fuel_aux:
+ ∀N M g f. is_valid_fp_body M f ⇒
+ is_valid_fp_body N g ⇒
+ ∀x. g (fix f) x ≠ Diverge ⇒
+ ∃n. g (fix f) x = g (fix_fuel n f) x ∧
+ ∀m. n ≤ m ⇒ g (fix_fuel m f) x = g (fix_fuel n f) x
+Proof
+ Induct_on ‘N’
+ >-(fs [is_valid_fp_body_def]) >>
+ rw [is_valid_fp_body_def] >>
+ first_x_assum (qspec_assume ‘x’) >> rw []
+ >-(first_assum (qspecl_assume [‘fix f’, ‘fix_fuel 0 f’]) >> fs []) >>
+ (* Use the validity hypothesis *)
+ fs [] >> pop_assum ignore_tac >>
+ (* Use the induction hypothesis *)
+ last_x_assum (qspecl_assume [‘M’, ‘h’, ‘f’]) >> gvs [] >>
+ (* Case disjunction on ‘fix f ÿ’*)
+ Cases_on ‘fix f y’ >> fs [bind_def] >~ [‘fix f y = Fail _’]
+ >-(
+ (* Fail case: easy, the call to ‘h’ is ignored *)
+ fs [fix_def] >> pop_assum mp_tac >> rw [] >>
+ qexists ‘$LEAST (fix_fuel_P f y)’ >>
+ fs [] >>
+ (* Use the monotonicity property for ‘f’ *)
+ rw [] >>
+ qspecl_assume [‘M’, ‘f’] fix_fuel_mono >> gvs [] >>
+ first_x_assum (qspecl_assume [‘$LEAST (fix_fuel_P f y)’, ‘y’]) >> gvs [] >>
+ fs [fix_fuel_P_def, is_diverge_def] >> gvs [] >>
+ first_x_assum (qspecl_assume [‘m’]) >> gvs [] >>
+ first_x_assum (fn th => assume_tac (GSYM th)) >> fs []
+ ) >>
+ (* Return case: we must take the maximum of the fuel for ‘f’ and ‘h’, and use
+ the monotonicity property *)
+ fs [fix_def] >> pop_assum mp_tac >> rw [] >>
+ first_x_assum (qspec_assume ‘a’) >> gvs [] >>
+ qexists ‘MAX ($LEAST (fix_fuel_P f y)) n'’ >> fs [] >>
+ (* Use the monotonicity properties *)
+ (* Instantiate the Monotonicity property for ‘f’ (the induction hypothesis gives
+ the one for ‘h’) *)
+ qspecl_assume [‘M’, ‘f’] fix_fuel_mono >> gvs [] >>
+ first_x_assum (qspecl_assume [‘$LEAST (fix_fuel_P f y)’, ‘y’]) >> gvs [] >>
+ fs [fix_fuel_P_def, is_diverge_def] >> gvs [] >>
+ first_x_assum (qspecl_assume [‘MAX ($LEAST (fix_fuel_P f y)) n'’]) >> gvs [] >>
+ first_x_assum (fn th => assume_tac (GSYM th)) >> fs [] >>
+ (* Prove the monotonicity property for ‘do z <- fix f y; h (fix f) z’ *)
+ rw [] >>
+ (* First, one of the ‘fix_fuel ... f y’ doesn't use the proper fuel *)
+ sg ‘fix_fuel ($LEAST (fix_fuel_P f y)) f y = Return a’
+ >-(
+ qspecl_assume [‘f’, ‘MAX ($LEAST (fix_fuel_P f y)) n'’, ‘y’] fix_fuel_P_least >>
+ gvs [fix_fuel_P_def, is_diverge_def] >>
+ Cases_on ‘fix_fuel ($LEAST (fix_fuel_P f y)) f y’ >> fs [] >>
+ (* Use the monotonicity property - there are two goals here *)
+ qspecl_assume [‘M’, ‘f’] fix_fuel_mono >> gvs [] >>
+ first_x_assum (qspecl_assume [‘$LEAST (fix_fuel_P f y)’, ‘y’]) >> gvs [] >>
+ fs [fix_fuel_P_def, is_diverge_def] >> gvs [] >>
+ first_x_assum (qspecl_assume [‘MAX ($LEAST (fix_fuel_P f y)) n'’]) >> gvs []) >>
+ (* Instantiate the monotonicity property for ‘f’ *)
+ qspecl_assume [‘M’, ‘f’] fix_fuel_mono >> gvs [] >>
+ first_x_assum (qspecl_assume [‘$LEAST (fix_fuel_P f y)’, ‘y’]) >> gvs [] >>
+ gvs [fix_fuel_P_def, is_diverge_def] >> gvs [] >>
+ first_x_assum (qspecl_assume [‘m’]) >> gvs [] >>
+ first_x_assum (fn th => assume_tac (GSYM th)) >> fs []
+QED
+
+(* If ‘g (fix f) x’ doesn't diverge, we can exhibit some fuel *)
+Theorem fix_not_diverge_implies_fix_fuel:
+ ∀N f. is_valid_fp_body N f ⇒
+ ∀x. f (fix f) x ≠ Diverge ⇒
+ ∃n. f (fix f) x = f (fix_fuel n f) x
+Proof
+ metis_tac [fix_not_diverge_implies_fix_fuel_aux]
+QED
+
+Theorem fix_fixed_diverges:
+ ∀N f. is_valid_fp_body N f ⇒ ∀x. ~(∃ n. fix_fuel_P f x n) ⇒ fix f x = f (fix f) x
+Proof
+ (* We do the proof by contraposition: if ‘f (fix f) x’ doesn't diverge, we
+ can exhibit some fuel (lemma [fix_not_diverge_implies_fix_fuel]) *)
+ rw [fix_def] >>
+ imp_res_tac fix_not_diverge_implies_fix_fuel >>
+ pop_assum (qspec_assume ‘x’) >>
+ fs [fix_fuel_P_def, is_diverge_def] >>
+ (* Case analysis: we have to prove that the ‘Return’ and ‘Fail’ cases lead
+ to a contradiction *)
+ Cases_on ‘f (fix f) x’ >> gvs [] >>
+ first_x_assum (qspec_assume ‘SUC n’) >> fs [fix_fuel_def] >>
+ pop_assum mp_tac >> case_tac >> fs []
+QED
+
+(* If ‘g (fix_fuel n f) x’ doesn't diverge, then it is equal to ‘g (fix f) x’ *)
+Theorem fix_fuel_not_diverge_eq_fix_aux:
+ ∀N M g f. is_valid_fp_body M f ⇒
+ is_valid_fp_body N g ⇒
+ ∀n x. g (fix_fuel n f) x ≠ Diverge ⇒
+ g (fix f) x = g (fix_fuel n f) x
+Proof
+ Induct_on ‘N’
+ >-(fs [is_valid_fp_body_def]) >>
+ rw [is_valid_fp_body_def] >>
+ first_x_assum (qspec_assume ‘x’) >> rw []
+ >-(first_assum (qspecl_assume [‘fix f’, ‘fix_fuel 0 f’]) >> fs []) >>
+ (* Use the validity hypothesis *)
+ fs [] >> pop_assum ignore_tac >>
+ (* For ‘fix f y = fix_fuel n f y’: use the monotonicity property *)
+ sg ‘fix_fuel_P f y n’
+ >-(Cases_on ‘fix_fuel n f y’ >> fs [fix_fuel_P_def, is_diverge_def, bind_def]) >>
+ sg ‘fix f y = fix_fuel n f y’ >-(metis_tac [fix_fuel_eq_fix])>>
+ (* Case disjunction on the call to ‘f’ *)
+ Cases_on ‘fix_fuel n f y’ >> gvs [bind_def] >>
+ (* We have to prove that: ‘h (fix f) a = h (fix_fuel n f) a’: use the induction hypothesis *)
+ metis_tac []
+QED
+
+Theorem fix_fuel_not_diverge_eq_fix:
+ ∀N f. is_valid_fp_body N f ⇒
+ ∀n x. f (fix_fuel n f) x ≠ Diverge ⇒
+ f (fix f) x = f (fix_fuel n f) x
+Proof
+ metis_tac [fix_fuel_not_diverge_eq_fix_aux]
+QED
+
+Theorem fix_fixed_terminates:
+ ∀N f. is_valid_fp_body N f ⇒ ∀x n. fix_fuel_P f x n ⇒ fix f x = f (fix f) x
+Proof
+ (* The proof simply uses the lemma [fix_fuel_not_diverge_eq_fix] *)
+ rw [fix_fuel_P_def, is_diverge_def, fix_def] >> case_tac >> fs [] >>
+ (* We can prove that ‘fix_fuel ($LEAST ...) f x ≠ Diverge’ *)
+ qspecl_assume [‘f’, ‘n’, ‘x’] fix_fuel_P_least >>
+ pop_assum sg_premise_tac >-(Cases_on ‘fix_fuel n f x’ >> fs []) >>
+ fs [fix_fuel_P_def, is_diverge_def] >>
+ (* *)
+ Cases_on ‘($LEAST (fix_fuel_P f x))’ >> fs [fix_fuel_def] >>
+ irule (GSYM fix_fuel_not_diverge_eq_fix) >>
+ Cases_on ‘f (fix_fuel n'' f) x’ >> fs [] >> metis_tac []
+QED
+
+(*
+Type ft = ``: 'a -> ('a result + (num # num # 'a))``
+
+val fix_fuel_def = Define ‘
+ (fix_fuel (0 : num) (fs : ('a ft) list)
+ (i : num) (x : 'a) : 'a result = Diverge) ∧
+
+ (fix_fuel (SUC n) fs i x =
+ case EL i fs x of
+ | INL r => r
+ | INR (j, k, y) =>
+ case fix_fuel n fs j y of
+ | Fail e => Fail e
+ | Diverge => Diverge
+ | Return z =>
+ fix_fuel n fs k z)
+’
+
+val fix_fuel_P_def = Define ‘
+ fix_fuel_P fs i x n = ~(is_diverge (fix_fuel n fs i x))
+’
+
+val fix_def = Define ‘
+ fix (fs : ('a ft) list) (i : num) (x : 'a) : 'a result =
+ if (∃ n. fix_fuel_P fs i x n)
+ then fix_fuel ($LEAST (fix_fuel_P fs i x)) fs i x
+ else Diverge
+’
+
+Theorem fix_fuel_mono:
+ ∀f. is_valid_fp_body f ⇒
+ ∀n x. fix_fuel_P f x n ⇒
+ ∀ m. n ≤ m ⇒
+ fix_fuel n f x = fix_fuel m f x
+Proof
+ ntac 2 strip_tac >>
+ Induct_on ‘n’ >> rpt strip_tac
+ >- (fs [fix_fuel_P_def, is_diverge_def, fix_fuel_def]) >>
+ Cases_on ‘m’ >- int_tac >> fs [] >>
+ fs [is_valid_fp_body_def] >>
+ fs [fix_fuel_P_def, is_diverge_def, fix_fuel_def] >>
+
+ (*(* Use the validity property *)
+ last_assum (qspec_assume ‘x’) >> (* TODO: consume? *) *)
+
+ (*pop_assum ignore_tac >> (* TODO: not sure *) *)
+ Induct_on ‘N’ >- fs [eval_ftree_def] >>
+ rw [] >>
+ rw [eval_ftree_def] >>
+ Cases_on ‘h x’ >> fs [] >>
+ Cases_on ‘y’ >> fs [] >>
+ Cases_on ‘y'’ >> fs [] >>
+
+ last_assum (qspec_assume ‘q’) >>
+ Cases_on ‘fix_fuel n f q’ >> fs [] >>
+
+ Cases_on ‘N’ >> fs [eval_ftree_def] >>
+
+ Cases_on ‘y’ >> fs [] >>
+ Cases_on ‘y'’ >> fs [] >>
+ rw [] >>
+ (* This makes a case disjunction on the validity property *)
+ rw []
+ >-((* Case 1: the continuation doesn't matter *) fs []) >>
+ (* Case 2: the continuation *does* matter (i.e., there is a recursive call *)
+ (* Instantiate the validity property with the different continuations *)
+ first_assum (qspec_assume ‘fix_fuel n f’) >>
+ first_assum (qspec_assume ‘fix_fuel n' f’) >>
+ last_assum (qspec_assume ‘y’) >>
+ fs []
+QED
+
+
+
+Type ft = ``: ('a -> 'a result) -> 'a -> ('a result + (num # 'a))``
+
+val fix_fuel_def = Define ‘
+ (fix_fuel (0 : num) (fs : ('a ft) list) (g : 'a -> 'a result)
+ (i : num) (x : 'a) : 'a result = Diverge) ∧
+
+ (fix_fuel (SUC n) fs g i x =
+ case EL i fs g x of
+ | INL r => r
+ | INR (j, y) =>
+ case g y of
+ | Fail e => Fail e
+ | Diverge => Diverge
+ | Return z => fix_fuel n fs g j z)
+’
+
+val fix_fuel_def = Define ‘
+ (fix_fuel (0 : num) (fs : ('a ft) list) g (i : num) (x : 'a) : 'a result = Diverge) ∧
+
+ (fix_fuel (SUC n) fs g i x =
+ case EL i fs x of
+ | INL r => r
+ | INR (j, y) =>
+ case g y of
+ | Fail e => Fail e
+ | Diverge => Diverge
+ | Return z => fix_fuel n fs g j z)
+’
+
+val fix_fuel_def = Define ‘
+ (fix_fuel (0 : num) (f : ('a -> 'a result) -> 'a -> 'a result) (x : 'a) : 'a result = Diverge) ∧
+ (fix_fuel (SUC n) (f : ('a -> 'a result) -> 'a -> 'a result) (x : 'a) : 'a result = f (fix_fuel n f) x)
+’
+
+val fix_fuel_P_def = Define ‘
+ fix_fuel_P f x n = ~(is_diverge (fix_fuel n f x))
+’
+
+val fix_def = Define ‘
+ fix (f : ('a -> 'a result) -> 'a -> 'a result) (x : 'a) : 'a result =
+ if (∃ n. fix_fuel_P f x n) then fix_fuel ($LEAST (fix_fuel_P f x)) f x else Diverge
+’
+
+(*Datatype:
+ ftree = Rec (('a -> ('a result + ('a # num))) # ftree list) | NRec ('a -> 'a result)
+End
+
+Type frtree = ``: ('b -> ('b result + ('a # num))) list``
+Type ftree = “: ('a, 'b) frtree # ('b result + ('a # num))”
+*)
+
+val eval_ftree_def = Define ‘
+ (eval_ftree 0 (g : 'a -> 'a result)
+ (fs : ('a -> ('a result + ('a # num))) list) x = Diverge) ∧
+
+ (eval_ftree (SUC n) g fs x =
+ case x of
+ | INL r => r
+ | INR (y, i) =>
+ case g y of
+ | Fail e => Fail e
+ | Diverge => Diverge
+ | Return z =>
+ let f = EL i fs in
+ eval_ftree n g fs (f z))
+’
+
+Theorem fix_fuel_mono:
+ ∀N fs i.
+ let f = (\g x. eval_ftree N g fs (INR (x, i))) in
+ ∀n x. fix_fuel_P f x n ⇒
+ ∀ m. n ≤ m ⇒ fix_fuel n f x = fix_fuel m f x
+Proof
+ Induct_on ‘N’
+ >-(
+ fs [eval_ftree_def] >>
+
+ ntac 2 strip_tac >>
+ Induct_on ‘n’ >> rpt strip_tac
+ >- (fs [fix_fuel_P_def, is_diverge_def, fix_fuel_def]) >>
+ Cases_on ‘m’ >- int_tac >> fs [] >>
+ fs [is_valid_fp_body_def] >>
+ fs [fix_fuel_P_def, is_diverge_def, fix_fuel_def] >>
+
+
+val is_valid_fp_body_def = Define ‘
+ is_valid_fp_body (f : ('a -> 'b result) -> 'a -> 'b result) =
+ (∃N ft. ∀x g. f g x = eval_ftree N g ft (x, i))
+’
+
+val eval_ftree_def = Define ‘
+ (eval_ftree 0 (g : 'a -> 'b result)
+ (fs : ('b -> ('b result + ('a # num))) list, x : 'b result + ('a # num)) = Diverge) ∧
+
+ (eval_ftree (SUC n) g (fs, x) =
+ case x of
+ | INL r => r
+ | INR (y, i) =>
+ case g y of
+ | Fail e => Fail e
+ | Diverge => Diverge
+ | Return z =>
+ let f = EL i fs in
+ eval_ftree n g (fs, f z))
+’
+
+val is_valid_fp_body_def = Define ‘
+ is_valid_fp_body (f : ('a -> 'b result) -> 'a -> 'b result) =
+ (∃N ft h. ∀x g. f g x = eval_ftree N g (ft, h x))
+’
+
+Theorem fix_fuel_mono:
+ let f = (\x. eval_ftree N g (ft, h x)) in
+ ∀n x. fix_fuel_P f x n ⇒
+ ∀ m. n ≤ m ⇒ fix_fuel n f x = fix_fuel m f x
+Proof
+
+
+Theorem fix_fuel_mono:
+ ∀f. is_valid_fp_body f ⇒
+ ∀n x. fix_fuel_P f x n ⇒
+ ∀ m. n ≤ m ⇒
+ fix_fuel n f x = fix_fuel m f x
+Proof
+ ntac 2 strip_tac >>
+ Induct_on ‘n’ >> rpt strip_tac
+ >- (fs [fix_fuel_P_def, is_diverge_def, fix_fuel_def]) >>
+ Cases_on ‘m’ >- int_tac >> fs [] >>
+ fs [is_valid_fp_body_def] >>
+ fs [fix_fuel_P_def, is_diverge_def, fix_fuel_def] >>
+
+ (*(* Use the validity property *)
+ last_assum (qspec_assume ‘x’) >> (* TODO: consume? *) *)
+
+ (*pop_assum ignore_tac >> (* TODO: not sure *) *)
+ Induct_on ‘N’ >- fs [eval_ftree_def] >>
+ rw [] >>
+ rw [eval_ftree_def] >>
+ Cases_on ‘h x’ >> fs [] >>
+ Cases_on ‘y’ >> fs [] >>
+ Cases_on ‘y'’ >> fs [] >>
+
+ last_assum (qspec_assume ‘q’) >>
+ Cases_on ‘fix_fuel n f q’ >> fs [] >>
+
+ Cases_on ‘N’ >> fs [eval_ftree_def] >>
+
+ Cases_on ‘y’ >> fs [] >>
+ Cases_on ‘y'’ >> fs [] >>
+ rw [] >>
+ (* This makes a case disjunction on the validity property *)
+ rw []
+ >-((* Case 1: the continuation doesn't matter *) fs []) >>
+ (* Case 2: the continuation *does* matter (i.e., there is a recursive call *)
+ (* Instantiate the validity property with the different continuations *)
+ first_assum (qspec_assume ‘fix_fuel n f’) >>
+ first_assum (qspec_assume ‘fix_fuel n' f’) >>
+ last_assum (qspec_assume ‘y’) >>
+ fs []
+QED
+
+
+val length_ftree = “
+(
+ [
+ (\n. INL (return (1 + n)))
+ ],
+ (case ls of
+ | ListCons x tl =>
+ INR (tl, 0)
+ | ListNil => INL (return 0))
+) : ('a list_t, int) ftree
+”
+
+val eval_length_ftree = mk_icomb (“eval_ftree 1 g”, length_ftree)
+
+Theorem length_body_eq:
+ eval_ftree (SUC (SUC 0)) g
+ (
+ [
+ (\n. INL (Return (1 + n)))
+ ],
+ (case ls of
+ | ListCons x tl =>
+ INR (tl, 0)
+ | ListNil => INL (Return 0))
+ ) =
+ case ls of
+ | ListCons x tl =>
+ do
+ n <- g tl;
+ Return (1 + n)
+ od
+ | ListNil => Return 0
+Proof
+ fs [eval_ftree_def, bind_def] >>
+ Cases_on ‘ls’ >> fs []
+QED
+
+val eval_ftree_def = Define ‘
+ eval_ftree 0 (fs : ('a, 'b) ftree) (g : 'a -> 'b result) (x : 'b result + ('a # num)) = Diverge ∧
+
+ eval_ftree (SUC n) fs g x =
+ case x of
+ | INL r => r
+ | INR (y, i) =>
+ case g y of
+ | Fail e => Fail e
+ | Diverge => Diverge
+ | Return z =>
+ let f = EL i fs in
+ eval_ftree n fs g (f z)
+’
+
+val length_body_funs_def = Define
+
+“
+[
+ (\ls. case ls of
+ | ListCons x tl =>
+ INR (tl, 1)
+ | ListNil => INL (return 0)),
+ (\n. INL (return (1 + n)))
+]
+”
+
+
+
+“:('a, 'b) FT”
+
+Define
+
+val nth_body = Define ‘
+
+
+’
+
+“INL”
+“INR”
+
+“
+ Rec (
+ case ls of
+ | ListCons x tl =>
+ do
+ INR (tl, 0)
+ od
+ | ListNil => INL (return 0),
+ [NRec (\n. return (1 + n))])
+”
+
+“
+ case ls of
+ | ListCons x tl =>
+ if u32_to_int i = (0:int)
+ then (Return x)
+ else
+ do
+ i0 <- u32_sub i (int_to_u32 1);
+ y <- nth tl i0;
+ return y
+ od
+ | ListNil => Fail Failure
+”
+
+
+“:'a + 'b”
+“:'a # 'b”
+
+(*** Encoding of a function *)
+Datatype:
+ ('a, 'b) test = Return ('a -> 'b)
+End
+
+val tyax =
+ new_type_definition ("three",
+ Q.prove(`?p. (\(x,y). ~(x /\ y)) p`, cheat))
+
+val three_bij = define_new_type_bijections
+ {name="three_tybij", ABS="abs3", REP="rep3", tyax=tyax}
+type_of “rep3”
+type_of “abs3”
+
+m “”
+
+ Q.EXISTS_TAC `(F,F)` THEN GEN_BETA_TAC THEN REWRITE_TAC []));
+
+“Return (\x. x)”
+
+Datatype:
+ ftree = Rec ('a -> ('a result + ('a # ftree))) | NRec ('a -> 'a result)
+End
+
+Datatype:
+ 'a ftree = Rec ('a -> ('a result + ('a # ftree))) | NRec ('a -> 'a result)
+End
+
+Datatype:
+ ftree = Rec ('a -> ('a result + ('a # ftree))) | NRec ('a -> 'a result)
+End
+
+Datatype:
+ result = Return 'a | Fail error | Diverge
+End
+
+Type M = ``: 'a result``
+
+
+val fix_def = Define ‘
+ fix (f : ('a -> 'b result) -> 'a -> 'b result) (x : 'a) : 'b result =
+ if (∃ n. fix_fuel_P f x n) then fix_fuel ($LEAST (fix_fuel_P f x)) f x else Diverge
+’
+
+val _ = export_theory ()
diff --git a/backends/hol4/divDefProto2Theory.sig b/backends/hol4/divDefProto2Theory.sig
new file mode 100644
index 00000000..349aabf7
--- /dev/null
+++ b/backends/hol4/divDefProto2Theory.sig
@@ -0,0 +1,225 @@
+signature divDefProto2Theory =
+sig
+ type thm = Thm.thm
+
+ (* Definitions *)
+ val fix_def : thm
+ val fix_fuel_P_def : thm
+ val fix_fuel_def : thm
+ val ftree_TY_DEF : thm
+ val ftree_case_def : thm
+ val ftree_size_def : thm
+ val is_valid_fp_body_def : thm
+
+ (* Theorems *)
+ val datatype_ftree : thm
+ val eval_ftree_compute : thm
+ val eval_ftree_def : thm
+ val eval_ftree_ind : thm
+ val fix_fuel_compute : thm
+ val ftree_11 : thm
+ val ftree_Axiom : thm
+ val ftree_case_cong : thm
+ val ftree_case_eq : thm
+ val ftree_distinct : thm
+ val ftree_induction : thm
+ val ftree_nchotomy : thm
+ val ftree_size_eq : thm
+
+ val divDefProto2_grammars : type_grammar.grammar * term_grammar.grammar
+(*
+ [primitives] Parent theory of "divDefProto2"
+
+ [fix_def] Definition
+
+ ⊢ ∀f x.
+ fix f x =
+ if ∃n. fix_fuel_P f x n then
+ fix_fuel ($LEAST (fix_fuel_P f x)) f x
+ else Diverge
+
+ [fix_fuel_P_def] Definition
+
+ ⊢ ∀f x n. fix_fuel_P f x n ⇔ ¬is_diverge (fix_fuel n f x)
+
+ [fix_fuel_def] Definition
+
+ ⊢ (∀f x. fix_fuel 0 f x = Diverge) ∧
+ ∀n f x. fix_fuel (SUC n) f x = f (fix_fuel n f) x
+
+ [ftree_TY_DEF] Definition
+
+ ⊢ ∃rep.
+ TYPE_DEFINITION
+ (λa0'.
+ ∀ $var$('ftree') $var$('@temp @ind_typedivDefProto20prod')
+ $var$('@temp @ind_typedivDefProto21list').
+ (∀a0'.
+ (∃a. a0' =
+ (λa.
+ ind_type$CONSTR 0 (ARB,ARB)
+ (ind_type$FCONS a (λn. ind_type$BOTTOM)))
+ a ∧
+ $var$('@temp @ind_typedivDefProto20prod') a) ∨
+ (∃a. a0' =
+ (λa.
+ ind_type$CONSTR (SUC 0) (a,ARB)
+ (λn. ind_type$BOTTOM)) a) ⇒
+ $var$('ftree') a0') ∧
+ (∀a1'.
+ (∃a0 a1.
+ a1' =
+ (λa0 a1.
+ ind_type$CONSTR (SUC (SUC 0)) (ARB,a0)
+ (ind_type$FCONS a1 (λn. ind_type$BOTTOM)))
+ a0 a1 ∧
+ $var$('@temp @ind_typedivDefProto21list') a1) ⇒
+ $var$('@temp @ind_typedivDefProto20prod') a1') ∧
+ (∀a2.
+ a2 =
+ ind_type$CONSTR (SUC (SUC (SUC 0))) (ARB,ARB)
+ (λn. ind_type$BOTTOM) ∨
+ (∃a0 a1.
+ a2 =
+ (λa0 a1.
+ ind_type$CONSTR (SUC (SUC (SUC (SUC 0))))
+ (ARB,ARB)
+ (ind_type$FCONS a0
+ (ind_type$FCONS a1 (λn. ind_type$BOTTOM))))
+ a0 a1 ∧ $var$('ftree') a0 ∧
+ $var$('@temp @ind_typedivDefProto21list') a1) ⇒
+ $var$('@temp @ind_typedivDefProto21list') a2) ⇒
+ $var$('ftree') a0') rep
+
+ [ftree_case_def] Definition
+
+ ⊢ (∀a f f1. ftree_CASE (Rec a) f f1 = f a) ∧
+ ∀a f f1. ftree_CASE (NRec a) f f1 = f1 a
+
+ [ftree_size_def] Definition
+
+ ⊢ (∀f a. ftree_size f (Rec a) = 1 + ftree1_size f a) ∧
+ (∀f a. ftree_size f (NRec a) = 1) ∧
+ (∀f a0 a1. ftree1_size f (a0,a1) = 1 + ftree2_size f a1) ∧
+ (∀f. ftree2_size f [] = 0) ∧
+ ∀f a0 a1.
+ ftree2_size f (a0::a1) = 1 + (ftree_size f a0 + ftree2_size f a1)
+
+ [is_valid_fp_body_def] Definition
+
+ ⊢ ∀f. is_valid_fp_body f ⇔ ∀x. ∃n ft. ∀g. f g x = eval_ftree n g ft
+
+ [datatype_ftree] Theorem
+
+ ⊢ DATATYPE (ftree Rec NRec)
+
+ [eval_ftree_compute] Theorem
+
+ ⊢ (∀x g fs. eval_ftree 0 g (fs,x) = Diverge) ∧
+ (∀x n g fs.
+ eval_ftree (NUMERAL (BIT1 n)) g (fs,x) =
+ case x of
+ INL r => r
+ | INR (y,i) =>
+ case g y of
+ Return z =>
+ (let
+ f = EL i fs
+ in
+ eval_ftree (NUMERAL (BIT1 n) − 1) g (fs,f z))
+ | Fail e => Fail e
+ | Diverge => Diverge) ∧
+ ∀x n g fs.
+ eval_ftree (NUMERAL (BIT2 n)) g (fs,x) =
+ case x of
+ INL r => r
+ | INR (y,i) =>
+ case g y of
+ Return z =>
+ (let
+ f = EL i fs
+ in
+ eval_ftree (NUMERAL (BIT1 n)) g (fs,f z))
+ | Fail e => Fail e
+ | Diverge => Diverge
+
+ [eval_ftree_def] Theorem
+
+ ⊢ (∀x g fs. eval_ftree 0 g (fs,x) = Diverge) ∧
+ ∀x n g fs.
+ eval_ftree (SUC n) g (fs,x) =
+ case x of
+ INL r => r
+ | INR (y,i) =>
+ case g y of
+ Return z => (let f = EL i fs in eval_ftree n g (fs,f z))
+ | Fail e => Fail e
+ | Diverge => Diverge
+
+ [eval_ftree_ind] Theorem
+
+ ⊢ ∀P. (∀g fs x. P 0 g (fs,x)) ∧
+ (∀n g fs x.
+ (∀v1 y i z f.
+ x = INR v1 ∧ v1 = (y,i) ∧ g y = Return z ∧ f = EL i fs ⇒
+ P n g (fs,f z)) ⇒
+ P (SUC n) g (fs,x)) ⇒
+ ∀v v1 v2 v3. P v v1 (v2,v3)
+
+ [fix_fuel_compute] Theorem
+
+ ⊢ (∀f x. fix_fuel 0 f x = Diverge) ∧
+ (∀n f x.
+ fix_fuel (NUMERAL (BIT1 n)) f x =
+ f (fix_fuel (NUMERAL (BIT1 n) − 1) f) x) ∧
+ ∀n f x.
+ fix_fuel (NUMERAL (BIT2 n)) f x =
+ f (fix_fuel (NUMERAL (BIT1 n)) f) x
+
+ [ftree_11] Theorem
+
+ ⊢ (∀a a'. Rec a = Rec a' ⇔ a = a') ∧ ∀a a'. NRec a = NRec a' ⇔ a = a'
+
+ [ftree_Axiom] Theorem
+
+ ⊢ ∀f0 f1 f2 f3 f4. ∃fn0 fn1 fn2.
+ (∀a. fn0 (Rec a) = f0 a (fn1 a)) ∧ (∀a. fn0 (NRec a) = f1 a) ∧
+ (∀a0 a1. fn1 (a0,a1) = f2 a0 a1 (fn2 a1)) ∧ fn2 [] = f3 ∧
+ ∀a0 a1. fn2 (a0::a1) = f4 a0 a1 (fn0 a0) (fn2 a1)
+
+ [ftree_case_cong] Theorem
+
+ ⊢ ∀M M' f f1.
+ M = M' ∧ (∀a. M' = Rec a ⇒ f a = f' a) ∧
+ (∀a. M' = NRec a ⇒ f1 a = f1' a) ⇒
+ ftree_CASE M f f1 = ftree_CASE M' f' f1'
+
+ [ftree_case_eq] Theorem
+
+ ⊢ ftree_CASE x f f1 = v ⇔
+ (∃p. x = Rec p ∧ f p = v) ∨ ∃f'. x = NRec f' ∧ f1 f' = v
+
+ [ftree_distinct] Theorem
+
+ ⊢ ∀a' a. Rec a ≠ NRec a'
+
+ [ftree_induction] Theorem
+
+ ⊢ ∀P0 P1 P2.
+ (∀p. P1 p ⇒ P0 (Rec p)) ∧ (∀f. P0 (NRec f)) ∧
+ (∀l. P2 l ⇒ ∀f. P1 (f,l)) ∧ P2 [] ∧
+ (∀f l. P0 f ∧ P2 l ⇒ P2 (f::l)) ⇒
+ (∀f. P0 f) ∧ (∀p. P1 p) ∧ ∀l. P2 l
+
+ [ftree_nchotomy] Theorem
+
+ ⊢ ∀ff. (∃p. ff = Rec p) ∨ ∃f. ff = NRec f
+
+ [ftree_size_eq] Theorem
+
+ ⊢ ftree1_size f = pair_size (λv. 0) (list_size (ftree_size f)) ∧
+ ftree2_size f = list_size (ftree_size f)
+
+
+*)
+end
diff --git a/backends/hol4/primitivesArithScript.sml b/backends/hol4/primitivesArithScript.sml
index 2682e507..b7b44b25 100644
--- a/backends/hol4/primitivesArithScript.sml
+++ b/backends/hol4/primitivesArithScript.sml
@@ -18,6 +18,7 @@ val le_eq_ge = store_thm("le_eq_ge", “!(x y : int). x <= y <=> y >= x”, coop
val gt_eq_lt = store_thm("gt_eq_lt", “!(x y : int). x > y <=> y < x”, cooper_tac)
val lt_eq_gt = store_thm("lt_eq_gt", “!(x y : int). x < y <=> y > x”, cooper_tac)
+(* Miscelleanous *)
Theorem int_add_minus_same_eq:
∀ (i j : int). i + j - j = i
Proof